diff options
Diffstat (limited to 'media/libtheora')
66 files changed, 19176 insertions, 0 deletions
diff --git a/media/libtheora/AUTHORS b/media/libtheora/AUTHORS new file mode 100644 index 0000000000..8a4e529b5a --- /dev/null +++ b/media/libtheora/AUTHORS @@ -0,0 +1,56 @@ +Monty <monty@xiph.org> + - Original VP3 port + +Timothy B. Terriberry +Gregory Maxwell +Ralph Giles +Monty + - Ongoing development + +Dan B. Miller + - Pre alpha3 development + +Rudolf Marek +Wim Tayman +Dan Lenski +Nils Pipenbrinck +Monty + - MMX optimized functions + +David Schleef + - C64x port + +Aaron Colwell +Thomas Vander Stichele +Jan Gerber +Conrad Parker +Cristian Adam +Sebastian Pippin +Simon Hosie +Brad Smith + - Bug fixes, enhancements, build systems. + +Mauricio Piacentini + - Original win32 projects and example ports + - VP3->Theora transcoder + +Silvia Pfeiffer + - Figures for the spec + +Michael Smith +Andre Pang +calc +Chris Cheney +Brendan Cully +Edward Hervey +Adam Moss +Colin Ward +Jeremy C. Reed +Arc Riley +Rodolphe Ortalo + - Bug fixes + +Robin Watts + - ARM code optimisations + +and other Xiph.org contributors diff --git a/media/libtheora/CHANGES b/media/libtheora/CHANGES new file mode 100644 index 0000000000..fb09793a3e --- /dev/null +++ b/media/libtheora/CHANGES @@ -0,0 +1,255 @@ +libteora 1.2.0alpha1 (2010 September 23) + +- New 'ptalarbvorm' encoder with better rate/distortion optimization +- New th_encode_ctl option for copying configuration from an existing + setup header, useful for splicing streams. +- Returns TH_DUPFRAME in more cases. +- Add ARM optimizations +- Add TI C64x+ DSP optimizations +- Other performance improvements +- Rename speedlevel 2 to 3 and provide a new speedlevel 2 +- Various minor bug fixes + +libtheora 1.1.2 (unreleased snapshot) + + - Fix Huffman table decoding with OC_HUFF_SLUSH is set to 0 + - Fix a frame size bug in player_example + - Add support for passing a buffer the size of the picture + region, rather than a full padded frame to th_encode_ycbcr_in() + as was possible with the legacy pre-1.0 API. + - 4:4:4 support in player_example using software yuv->rgb + - Better rgb->yuv conversion in png2theora + - Clean up warnings and local variables + - Build and documentation fixes + +libtheora 1.1.1 (2009 October 1) + + - Fix problems with MSVC inline assembly + - Add the missing encoder_disabled.c to the distribution + - build updates: autogen.sh should work better after switching systems + and the MSVC project now defaults to the dynamic runtime library + - Namespace some variables to avoid conflicts on wince. + +libtheora 1.1.0 (2009 September 24) + + - Fix various small issues with the example and telemetry code + - Fix handing a zero-byte packet as the first frame + - Documentation cleanup + - Two minor build fixes + +libtheora 1.1beta3 (2009 August 22) + + - Rate control fixes to smooth quality + - MSVC build now exports all of the 1.0 api + - Assorted small bug fixes + +libtheora 1.1beta2 (2009 August 12) + + - Fix a rate control problem with difficult input + - Build fixes for OpenBSD and Apple Xcode + - Examples now all use the 1.0 api + - TH_ENCCTL_SET_SPLEVEL works again + - Various bug fixes and source tree rearrangement + +libtheora 1.1beta1 (2009 August 5) + + - Support for two-pass encoding + - Performance optimization of both encoder and decoder + - Encoder supports dynamic adjustment of quality and + bitrate targets + - Encoder is generally more configurable, and all + rate control modes perform better + - Encoder now accepts 4:2:2 and 4:4:4 chroma sampling + - Decoder telemetry output shows quantization choice + and a breakdown of bitrate usage in the frame + - MSVC assembly optimizations up to date and functional + +libtheora 1.1alpha2 (2009 May 26) + + - Reduce lambda for small quantizers. + - New encoder fDCT does better on smooth gradients + - Use SATD for mode decisions (1-2% bitrate reduction) + - Assembly rewrite for new features and general speed up + - Share code between the encoder and decoder for performance + - Fix 4:2:2 decoding and telemetry + - MSVC project files updated, but assembly is disabled. + - New configure option --disable-spec to work around toolchain + detection failures. + - Limit symbol exports on MacOS X. + - Port remaining unit tests from the 1.0 release. + +libtheora 1.1alpha1 (2009 March 27) + + - Encoder rewrite with much improved vbr quality/bitrate and + better tracking of the target rate in cbr mode. + - MSVC project files do not work in this release. + +libtheora 1.0 (2008 November 3) + + - Merge x86 assembly for forward DCT from Thusnelda branch. + - Update 32 bit MMX with loop filter fix. + - Check for an uninitialized state before dereferencing in propagating + decode calls. + - Remove all TH_DEBUG statements. + - Rename the bitpacker source files copied from libogg to avoid + confusing simple build systems using both libraries. + - Declare bitfield entries to be explicitly signed for Solaris cc. + - Set quantization parameters to default values when an empty buffer is + passed with TH_ENCCTL_SET_QUANT_PARAMS. + - Split encoder and decoder tests depending on configure settings. + - Return lstylex.sty to the distribution. + - Disable inline assembly on gcc versions prior to 3.1. + - Remove extern references for OC_*_QUANT_MIN. + - Make various data tables static const so they can be read-only. + - Remove ENCCTL codes from the old encoder API. + - Implement TH_ENCCTL_SET_KEYFRAME_FREQUENCY_FORCE ctl. + - Fix segfault when exactly one of the width or height is not a multiple + of 16, but the other is. + - Compute the correct vertical offset for chroma. + - cpuid assembly fix for MSVC. + - Add VS2008 project files. + - Build updates for 64-bit platforms, Mingw32, VS and XCode. + - Do not clobber the cropping rectangle. + - Declare ourselves 1.0final to pkg-config to sort after beta releases. + - Fix the scons build to include asm in libtheoradec/enc. + +libtheora 1.0beta3 (2008 April 16) + + - Build new libtheoradec and libtheoraenc libraries + supporting the new API from theora-exp. This API should + not be considered stable yet. + - Change granule_frame() to return an index as documented. + This is a change of behaviour from 1.0beta1. + - Document that granule_time() returns the end of the + presentation interval. + - Use a custom copy of the libogg bitpacker in the decoder + to avoid function call overhead. + - MMX code improved and ported to MSVC. + - Fix a problem with the MMX code on SELinux. + - Fix a problem with decoder quantizer initialization. + - Fix a page queue problem with png2theora. + - Improved robustness. + - Updated VS2005 project files. + - Dropped build support for Microsoft VS2003. + - Dropped build support for the unreleased libogg2. + - Added the specification to the autotools build. + - Specification corrections. + +libtheora 1.0beta2 (2007 October 12) + + - Fix a crash bug on char-is-unsigned architectures (PowerPC) + - Fix a buffer sizing issue that caused rare encoder crashes + - Fix a buffer alignment issue + - Build fixes for MingW32, MSVC + - Improved format documentation. + +libtheora 1.0beta1 (2007 September 22) + + - Granulepos scheme modified to match other codecs. This bumps + the bitstream revision to 3.2.1. Bitstreams marked 3.2.0 are + handled correctly by this decoder. Older decoders will show + a one frame sync error in the less noticeable direction. + +libtheora 1.0alpha8 (2007 September 18) + + - Switch to new spec compliant decoder from theora-exp branch. + Written by Dr. Timothy Terriberry. + - Add support to the encoder for using quantization settings + provided by the application. + - more assembly optimizations + +libtheora 1.0alpha7 (2006 June 20) + + - Enable mmx assembly by default + - Avoid some relocations that caused problems on SELinux + - Other build fixes + - time testing mode (-f) for the dump_video example + +libtheora 1.0alpha6 (2006 May 30) + + * Merge theora-mmx simd acceleration (x86_32 and x86_64) + * Major RTP payload specification update + * Minor format specification updates + * Fix some spurious calls to free() instead of _ogg_free() + * Fix invalid array indexing in PixelLineSearch() + * Improve robustness against invalid input + * General warning cleanup + * The offset_y member now means what every application thought it meant + (offset from the top). This will mean some old files (those with a + non-centered image created with a buggy encoder) will display differently. + +libtheora 1.0alpha5 (2005 August 20) + + * Fixed bitrate management bugs that caused popping and encode + errors + * Fixed a crash problem with the theora_state internals not + being intialized properly. + * new utility function: + - theora_granule_shift() + * dump_video example now makes YUV4MPEG files by default, so + the results can be fed back to encoder_example and similar + tools. The old behavior is restored through the '-r' switch. + * ./configure now prints a summary + * simple unit test of the comment api under 'make check' + * misc code cleanup, warning and leak fixes + +libtheora 1.0alpha4 (2004 December 15) + + * first draft of the Theora I Format Specification + * API documentation generated from theora.h with Doxygen + * fix a double-update bug in the motion analysis + * apply the loop filter before filling motion vector border + in the reference frame + * new utility functions: + - theora_packet_isheader(), + - theora_packet_iskeyframe() + - theora_granule_frame() + * optional support for building without floating point + * optional support for building without encode support + * various build and packaging fixes + * pkg-config support + * SymbianOS build support + +libtheora 1.0alpha3 (2004 March 20) + + UPDATE: on 2004 July 1 the Theora I bitstream format was frozen. Files + produced by the libtheora 1.0alpha3 reference encoder will always be + decodable by the Theora I spec. + + * Bitstream info header FORMAT CHANGES: + - move the granulepos shift field to maintain byte alignment longer. + - reserve 5 additional bits for subsampling and interlace flags. + * Bitstream setup header FORMAT CHANGES: + - support for a range of interpolated quant matricies. + - include the in-loop block filter coeff. + * Bitsteam data packet FORMAT CHANGES: + - Reserve a bit for per-block Q index selection. + - Flip the coded image orientation for compatibility with VP3. + This allows lossless transcoding of VP3 content, but files + encoded with earlier theora releases would play upside down. + * example VP3 lossless transcoder + * optional support for libogg2 + * timing improvements in the example player + * packaging and build system updates and fixes + +libtheora 1.0alpha2 (2003 June 9) + + * bitstream FORMAT CHANGES: + - store the quant tables in a third setup header for + future encoder flexibility + - store the huffman tables in the third setup header + - add a field for marking the colorspace to the info header + - add crop parameters for non-multiple-of-16 frame sizes + - add a second vorbiscomment-style metadata header + * API changes to handle multiple headers with a single + theora_decode_header() call, like libvorbis + * code cleanup and minor fixes + * new dump_video code example/utility + * experimental win32 code examples + +libtheora 1.0alpha1 (2002 September 25) + + * First release of the theora reference implementation + * Port of the newly opened VP3 code to the Ogg container + * Rewrite of the code for portability and to use the libogg bitpacker + diff --git a/media/libtheora/COPYING b/media/libtheora/COPYING new file mode 100644 index 0000000000..c8ccce4ffb --- /dev/null +++ b/media/libtheora/COPYING @@ -0,0 +1,28 @@ +Copyright (C) 2002-2009 Xiph.org Foundation + +Redistribution and use in source and binary forms, with or without +modification, are permitted provided that the following conditions +are met: + +- Redistributions of source code must retain the above copyright +notice, this list of conditions and the following disclaimer. + +- Redistributions in binary form must reproduce the above copyright +notice, this list of conditions and the following disclaimer in the +documentation and/or other materials provided with the distribution. + +- Neither the name of the Xiph.org Foundation nor the names of its +contributors may be used to endorse or promote products derived from +this software without specific prior written permission. + +THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS +``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT +LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR +A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE FOUNDATION +OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, +SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT +LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, +DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY +THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT +(INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE +OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. diff --git a/media/libtheora/LICENSE b/media/libtheora/LICENSE new file mode 100644 index 0000000000..97e8431790 --- /dev/null +++ b/media/libtheora/LICENSE @@ -0,0 +1,18 @@ +Please see the file COPYING for the copyright license for this software. + +In addition to and irrespective of the copyright license associated +with this software, On2 Technologies, Inc. makes the following statement +regarding technology used in this software: + + On2 represents and warrants that it shall not assert any rights + relating to infringement of On2's registered patents, nor initiate + any litigation asserting such rights, against any person who, or + entity which utilizes the On2 VP3 Codec Software, including any + use, distribution, and sale of said Software; which make changes, + modifications, and improvements in said Software; and to use, + distribute, and sell said changes as well as applications for other + fields of use. + +This reference implementation is originally derived from the On2 VP3 +Codec Software, and the Theora video format is essentially compatible +with the VP3 video format, consisting of a backward-compatible superset. diff --git a/media/libtheora/Makefile.in b/media/libtheora/Makefile.in new file mode 100644 index 0000000000..006310491d --- /dev/null +++ b/media/libtheora/Makefile.in @@ -0,0 +1,24 @@ +# This Source Code Form is subject to the terms of the Mozilla Public +# License, v. 2.0. If a copy of the MPL was not distributed with this +# file, You can obtain one at http://mozilla.org/MPL/2.0/. + + +ifdef GNU_AS +ifeq ($(CPU_ARCH),arm) + +armfrag-gnu.s: armopts-gnu.S +armidct-gnu.s: armopts-gnu.S +armloop-gnu.s: armopts-gnu.S + +# armopts needs a specific rule, because arm2gnu.pl will always add the .S +# suffix when translating the files that include it. +armopts-gnu.S: $(srcdir)/lib/arm/armopts.s + $(PERL) $(srcdir)/lib/arm/arm2gnu.pl < $< > $@ +# For all others, we can use an implicit rule +%-gnu.s: $(srcdir)/lib/arm/%.s + $(PERL) $(srcdir)/lib/arm/arm2gnu.pl < $< > $@ + +endif +endif + +include $(topsrcdir)/config/rules.mk diff --git a/media/libtheora/README.md b/media/libtheora/README.md new file mode 100644 index 0000000000..b136f7114c --- /dev/null +++ b/media/libtheora/README.md @@ -0,0 +1,148 @@ +# Xiph.org Foundation's libtheora + +### What is Theora? + +Theora was Xiph.Org's first publicly released video codec, intended +for use within the Foundation's Ogg multimedia streaming system. +Theora is derived directly from On2's VP3 codec, adds new features +while allowing it a longer useful lifetime. + +The 1.0 release decoder supported all the new features, but the +encoder is nearly identical to the VP3 code. + +The 1.1 release featured a completely rewritten encoder, offering +better performance and compression, and making more complete use +of the format's feature set. + +The 1.2 release features significant additional improvements in +compression and performance. Files produced by newer encoders can +be decoded by earlier releases. + +### Where is Theora? + +Theora's main site is https://www.theora.org. Releases of Theora +and related libraries can be found on the +[download page](https://www.theora.org/downloads/) or the +[main Xiph.Org site](https://xiph.org/downloads/). + +Development source is kept at https://gitlab.xiph.org/xiph/theora. + +## Getting started with the code + +### What do I need to build the source? + +Requirements summary: + +For libtheora: + +* libogg 1.1 or newer. + +For example encoder: + +* as above, +* libvorbis and libvorbisenc 1.0.1 or newer. + (libvorbis 1.3.1 or newer for 5.1 audio) + +For creating a source distribution package: + +* as above, +* Doxygen to build the API documentation, +* pdflatex and fig2dev to build the format specification + (transfig package in Ubuntu). + +For the player only: + +* as above, +* SDL (Simple Direct media Layer) libraries and headers, +* OSS audio driver and development headers. + +The provided build system is the GNU automake/autoconf system, and +the main library, libtheora, should already build smoothly on any +system. Failure of libtheora to build on a GNU-enabled system is +considered a bug; please report problems to theora-dev@xiph.org. + +Windows build support is included in the win32 directory. + +Project files for Apple XCode are included in the macosx directory. + +There is also a more limited scons build. + +### How do I use the sample encoder? + +The sample encoder takes raw video in YUV4MPEG2 format, as used by +lavtools, mjpeg-tools and other packages. The encoder expects audio, +if any, in a separate wave WAV file. Try 'encoder_example -h' for a +complete list of options. + +An easy way to get raw video and audio files is to use MPlayer as an +export utility. The options " -ao pcm -vo yuv4mpeg " will export a +wav file named audiodump.wav and a YUV video file in the correct +format for encoder_example as stream.yuv. Be careful when exporting +video alone; MPlayer may drop frames to 'keep up' with the audio +timer. The example encoder can't properly synchronize input audio and +video file that aren't in sync to begin with. + +The encoder will also take video or audio on stdin if '-' is specified +as the input file name. + +There is also a 'png2theora' example which accepts a set of image +files in that format. + +### How do I use the sample player? + +The sample player takes an Ogg file on standard in; the file may be +audio alone, video alone or video with audio. + +### What other tools are available? + +The programs in the examples directory are intended as tutorial source +for developers using the library. As such they sacrifice features and +robustness in the interests of comprehension and should not be +considered serious applications. + +If you're wanting to just use theora, consider the programs linked +from https://www.theora.org/. There is playback support in a number +of common free players, and plugins for major media frameworks. +Jan Gerber's ffmpeg2theora is an excellent encoding front end. + +## Troubleshooting the build process + +### Compile error, such as: + +encoder_internal.h:664: parse error before `ogg_uint16_t` + +This means you have version of libogg prior to 1.1. A *complete* new Ogg +install, libs and headers is needed. + +Also be sure that there aren't multiple copies of Ogg installed in +/usr and /usr/local; an older one might be first on the search path +for libs and headers. + +### Link error, such as: + +undefined reference to `oggpackB_stream` + +See above; you need libogg 1.1 or later. + +### Link error, such as: + +undefined reference to `vorbis_granule_time` + +You need libvorbis and libvorbisenc from the 1.0.1 release or later. + +### Link error, such as: + +/usr/lib/libSDL.a(SDL_esdaudio.lo): In function `ESD_OpenAudio`: +SDL_esdaudio.lo(.text+0x25d): undefined reference to `esd_play_stream` + +Be sure to use an SDL that's built to work with OSS. If you use an +SDL that is also built with ESD and/or ALSA support, it will try to +suck in all those extra libraries at link time too. That will only +work if the extra libraries are also installed. + +### Link warning, such as: + +libtool: link: warning: library `/usr/lib/libogg.la` was moved. +libtool: link: warning: library `/usr/lib/libogg.la` was moved. + +Re-run theora/autogen.sh after an Ogg or Vorbis rebuild/reinstall diff --git a/media/libtheora/clang-arm.patch b/media/libtheora/clang-arm.patch new file mode 100644 index 0000000000..0fd97ebb1b --- /dev/null +++ b/media/libtheora/clang-arm.patch @@ -0,0 +1,277 @@ +diff --git a/lib/arm/arm2gnu.pl b/lib/arm/arm2gnu.pl +index 8cb68e4..d6fe09c 100755 +--- a/lib/arm/arm2gnu.pl ++++ b/lib/arm/arm2gnu.pl +@@ -25,6 +25,8 @@ $n=0; + $thumb = 0; # ARM mode by default, not Thumb. + @proc_stack = (); + ++printf (" .syntax unified\n"); ++ + LINE: + while (<>) { + +diff --git a/lib/arm/armbits.s b/lib/arm/armbits.s +index 9400722..fd6e444 100644 +--- a/lib/arm/armbits.s ++++ b/lib/arm/armbits.s +@@ -67,28 +67,28 @@ oc_pack_read_refill + ; negative. + CMP r10,r11 ; ptr<stop => HI + CMPHI r3,#7 ; available<=24 => HI +- LDRHIB r14,[r11],#1 ; r14 = *ptr++ ++ LDRBHI r14,[r11],#1 ; r14 = *ptr++ + SUBHI r3,#8 ; available += 8 + ; (HI) Stall... +- ORRHI r2,r14,LSL r3 ; r2 = window|=r14<<32-available ++ ORRHI r2,r2,r14,LSL r3 ; r2 = window|=r14<<32-available + CMPHI r10,r11 ; ptr<stop => HI + CMPHI r3,#7 ; available<=24 => HI +- LDRHIB r14,[r11],#1 ; r14 = *ptr++ ++ LDRBHI r14,[r11],#1 ; r14 = *ptr++ + SUBHI r3,#8 ; available += 8 + ; (HI) Stall... +- ORRHI r2,r14,LSL r3 ; r2 = window|=r14<<32-available ++ ORRHI r2,r2,r14,LSL r3 ; r2 = window|=r14<<32-available + CMPHI r10,r11 ; ptr<stop => HI + CMPHI r3,#7 ; available<=24 => HI +- LDRHIB r14,[r11],#1 ; r14 = *ptr++ ++ LDRBHI r14,[r11],#1 ; r14 = *ptr++ + SUBHI r3,#8 ; available += 8 + ; (HI) Stall... +- ORRHI r2,r14,LSL r3 ; r2 = window|=r14<<32-available ++ ORRHI r2,r2,r14,LSL r3 ; r2 = window|=r14<<32-available + CMPHI r10,r11 ; ptr<stop => HI + CMPHI r3,#7 ; available<=24 => HI +- LDRHIB r14,[r11],#1 ; r14 = *ptr++ ++ LDRBHI r14,[r11],#1 ; r14 = *ptr++ + SUBHI r3,#8 ; available += 8 + ; (HI) Stall... +- ORRHI r2,r14,LSL r3 ; r2 = window|=r14<<32-available ++ ORRHI r2,r2,r14,LSL r3 ; r2 = window|=r14<<32-available + SUBS r3,r0,r3 ; r3 = available-=_bits, available<bits => GT + BLT oc_pack_read_refill_last + MOV r0,r2,LSR r0 ; r0 = window>>32-_bits +@@ -104,14 +104,14 @@ oc_pack_read_refill_last + CMP r11,r10 ; ptr<stop => LO + ; If we didn't hit the end of the packet, then pull enough of the next byte to + ; to fill up the window. +- LDRLOB r14,[r11] ; (LO) r14 = *ptr ++ LDRBLO r14,[r11] ; (LO) r14 = *ptr + ; Otherwise, set the EOF flag and pretend we have lots of available bits. + MOVHS r14,#1 ; (HS) r14 = 1 + ADDLO r10,r3,r1 ; (LO) r10 = available + STRHS r14,[r12,#8] ; (HS) eof = 1 + ANDLO r10,r10,#7 ; (LO) r10 = available&7 + MOVHS r3,#1<<30 ; (HS) available = OC_LOTS_OF_BITS +- ORRLO r2,r14,LSL r10 ; (LO) r2 = window|=*ptr>>(available&7) ++ ORRLO r2,r2,r14,LSL r10 ; (LO) r2 = window|=*ptr>>(available&7) + MOV r0,r2,LSR r0 ; r0 = window>>32-_bits + MOV r2,r2,LSL r1 ; r2 = window<<=_bits + STR r11,[r12,#-4] ; ptr = r11 +@@ -183,32 +183,32 @@ oc_huff_token_decode_refill + ; We can't possibly need more than 15 bits, so available must be <= 15. + ; Therefore we can load at least two bytes without checking it. + CMP r2,r3 ; ptr<stop => HI +- LDRHIB r14,[r3],#1 ; r14 = *ptr++ ++ LDRBHI r14,[r3],#1 ; r14 = *ptr++ + RSBHI r5,r5,#24 ; (HI) available = 32-(available+=8) + RSBLS r5,r5,#32 ; (LS) r5 = 32-available +- ORRHI r4,r14,LSL r5 ; r4 = window|=r14<<32-available ++ ORRHI r4,r4,r14,LSL r5 ; r4 = window|=r14<<32-available + CMPHI r2,r3 ; ptr<stop => HI +- LDRHIB r14,[r3],#1 ; r14 = *ptr++ ++ LDRBHI r14,[r3],#1 ; r14 = *ptr++ + SUBHI r5,#8 ; available += 8 + ; (HI) Stall... +- ORRHI r4,r14,LSL r5 ; r4 = window|=r14<<32-available ++ ORRHI r4,r4,r14,LSL r5 ; r4 = window|=r14<<32-available + ; We can use unsigned compares for both the pointers and for available + ; (allowing us to chain condition codes) because available will never be + ; larger than 32 (or we wouldn't be here), and thus 32-available will never be + ; negative. + CMPHI r2,r3 ; ptr<stop => HI + CMPHI r5,#7 ; available<=24 => HI +- LDRHIB r14,[r3],#1 ; r14 = *ptr++ ++ LDRBHI r14,[r3],#1 ; r14 = *ptr++ + SUBHI r5,#8 ; available += 8 + ; (HI) Stall... +- ORRHI r4,r14,LSL r5 ; r4 = window|=r14<<32-available ++ ORRHI r4,r4,r14,LSL r5 ; r4 = window|=r14<<32-available + CMP r2,r3 ; ptr<stop => HI + MOVLS r5,#-1<<30 ; (LS) available = OC_LOTS_OF_BITS+32 + CMPHI r5,#7 ; (HI) available<=24 => HI +- LDRHIB r14,[r3],#1 ; (HI) r14 = *ptr++ ++ LDRBHI r14,[r3],#1 ; (HI) r14 = *ptr++ + SUBHI r5,#8 ; (HI) available += 8 + ; (HI) Stall... +- ORRHI r4,r14,LSL r5 ; (HI) r4 = window|=r14<<32-available ++ ORRHI r4,r4,r14,LSL r5 ; (HI) r4 = window|=r14<<32-available + RSB r14,r10,#32 ; r14 = 32-n + MOV r14,r4,LSR r14 ; r14 = bits=window>>32-n + ADD r12,r12,r14 ; +diff --git a/lib/arm/armfrag.s b/lib/arm/armfrag.s +index 38627ed..38ee775 100644 +--- a/lib/arm/armfrag.s ++++ b/lib/arm/armfrag.s +@@ -357,7 +357,7 @@ ofrintra_v6_lp + ORR r5, r5, r5, LSR #8 ; r5 = __777766 + PKHBT r2, r2, r3, LSL #16 ; r2 = 33221100 + PKHBT r3, r4, r5, LSL #16 ; r3 = 77665544 +- STRD r2, [r0], r1 ++ STRD r2, r3, [r0], r1 + BGT ofrintra_v6_lp + LDMFD r13!,{r4-r6,PC} + ENDP +@@ -397,7 +397,7 @@ ofrinter_v6_lp + USAT16 r12,#8, r12 ; r12= __66__44 + USAT16 r5, #8, r5 ; r4 = __77__55 + ORR r5, r12,r5, LSL #8 ; r5 = 33221100 +- STRD r4, [r0], r2 ++ STRD r4, r5, [r0], r2 + BGT ofrinter_v6_lp + LDMFD r13!,{r4-r7,PC} + ENDP +@@ -439,7 +439,7 @@ ofrinter2_v6_lp + USAT16 r8, #8, r8 ; r8 = __22__00 + USAT16 r7, #8, r7 ; r7 = __33__11 + ORR r8, r8, r7, LSL #8 ; r8 = 33221100 +- STRD r8, [r0], r3 ++ STRD r8, r9, [r0], r3 + BGT ofrinter2_v6_lp + LDMFD r13!,{r4-r9,PC} + ENDP +diff --git a/lib/arm/armidct.s b/lib/arm/armidct.s +index 68530c7..269f74b 100644 +--- a/lib/arm/armidct.s ++++ b/lib/arm/armidct.s +@@ -875,7 +875,7 @@ idct2_1core_v6 PROC + LDR r3, OC_C4S4 + LDRSH r6, [r1], #16 ; r6 = x[1,0] + SMULWB r12,r3, r2 ; r12= t[0,0]=OC_C4S4*x[0,0]>>16 +- LDRD r4, OC_C7S1 ; r4 = OC_C7S1; r5 = OC_C1S7 ++ LDRD r4, r5, OC_C7S1 ; r4 = OC_C7S1; r5 = OC_C1S7 + SMULWB r6, r3, r6 ; r6 = t[1,0]=OC_C4S4*x[1,0]>>16 + SMULWT r4, r4, r2 ; r4 = t[0,4]=OC_C7S1*x[0,1]>>16 + SMULWT r7, r5, r2 ; r7 = t[0,7]=OC_C1S7*x[0,1]>>16 +@@ -937,7 +937,7 @@ idct2_2core_down_v6 PROC + MOV r7 ,#8 ; r7 = 8 + LDR r6, [r1], #16 ; r6 = <x[1,1]|x[1,0]> + SMLAWB r12,r3, r2, r7 ; r12= (t[0,0]=OC_C4S4*x[0,0]>>16)+8 +- LDRD r4, OC_C7S1 ; r4 = OC_C7S1; r5 = OC_C1S7 ++ LDRD r4, r5, OC_C7S1 ; r4 = OC_C7S1; r5 = OC_C1S7 + SMLAWB r7, r3, r6, r7 ; r7 = (t[1,0]=OC_C4S4*x[1,0]>>16)+8 + SMULWT r5, r5, r2 ; r2 = t[0,7]=OC_C1S7*x[0,1]>>16 + PKHBT r12,r12,r7, LSL #16 ; r12= <t[1,0]+8|t[0,0]+8> +@@ -1053,7 +1053,7 @@ idct3_2core_v6 PROC + ; r1 = const ogg_int16_t *_x (source) + ; Stage 1: + LDRD r4, [r1], #16 ; r4 = <x[0,1]|x[0,0]>; r5 = <*|x[0,2]> +- LDRD r10,OC_C6S2_3_v6 ; r10= OC_C6S2; r11= OC_C2S6 ++ LDRD r10, r11, OC_C6S2_3_v6 ; r10= OC_C6S2; r11= OC_C2S6 + ; Stall + SMULWB r3, r11,r5 ; r3 = t[0,3]=OC_C2S6*x[0,2]>>16 + LDR r11,OC_C4S4 +@@ -1132,12 +1132,12 @@ idct4_3core_v6 PROC + ; r1 = const ogg_int16_t *_x (source) + ; Stage 1: + LDRD r10,[r1], #16 ; r10= <x[0,1]|x[0,0]>; r11= <x[0,3]|x[0,2]> +- LDRD r2, OC_C5S3_4_v6 ; r2 = OC_C5S3; r3 = OC_C3S5 ++ LDRD r2, r3, OC_C5S3_4_v6 ; r2 = OC_C5S3; r3 = OC_C3S5 + LDRD r4, [r1], #16 ; r4 = <x[1,1]|x[1,0]>; r5 = <??|x[1,2]> + SMULWT r9, r3, r11 ; r9 = t[0,6]=OC_C3S5*x[0,3]>>16 + SMULWT r8, r2, r11 ; r8 = -t[0,5]=OC_C5S3*x[0,3]>>16 + PKHBT r9, r9, r2 ; r9 = <0|t[0,6]> +- LDRD r6, OC_C6S2_4_v6 ; r6 = OC_C6S2; r7 = OC_C2S6 ++ LDRD r6, r7, OC_C6S2_4_v6 ; r6 = OC_C6S2; r7 = OC_C2S6 + PKHBT r8, r8, r2 ; r9 = <0|-t[0,5]> + SMULWB r3, r7, r11 ; r3 = t[0,3]=OC_C2S6*x[0,2]>>16 + SMULWB r2, r6, r11 ; r2 = t[0,2]=OC_C6S2*x[0,2]>>16 +@@ -1148,7 +1148,7 @@ idct4_3core_v6 PROC + SMULWB r12,r11,r10 ; r12= t[0,0]=OC_C4S4*x[0,0]>>16 + PKHBT r2, r2, r5, LSL #16 ; r2 = <t[1,2]|t[0,2]> + SMULWB r5, r11,r4 ; r5 = t[1,0]=OC_C4S4*x[1,0]>>16 +- LDRD r6, OC_C7S1_4_v6 ; r6 = OC_C7S1; r7 = OC_C1S7 ++ LDRD r6, r7, OC_C7S1_4_v6 ; r6 = OC_C7S1; r7 = OC_C1S7 + PKHBT r12,r12,r5, LSL #16 ; r12= <t[1,0]|t[0,0]> + SMULWT r5, r7, r4 ; r5 = t[1,7]=OC_C1S7*x[1,1]>>16 + SMULWT r7, r7, r10 ; r7 = t[0,7]=OC_C1S7*x[0,1]>>16 +@@ -1216,10 +1216,10 @@ idct4_4core_down_v6 PROC + ; r1 = const ogg_int16_t *_x (source) + ; Stage 1: + LDRD r10,[r1], #16 ; r10= <x[0,1]|x[0,0]>; r11= <x[0,3]|x[0,2]> +- LDRD r2, OC_C5S3_4_v6 ; r2 = OC_C5S3; r3 = OC_C3S5 ++ LDRD r2, r3, OC_C5S3_4_v6 ; r2 = OC_C5S3; r3 = OC_C3S5 + LDRD r4, [r1], #16 ; r4 = <x[1,1]|x[1,0]>; r5 = <x[1,3]|x[1,2]> + SMULWT r9, r3, r11 ; r9 = t[0,6]=OC_C3S5*x[0,3]>>16 +- LDRD r6, OC_C6S2_4_v6 ; r6 = OC_C6S2; r7 = OC_C2S6 ++ LDRD r6, r7, OC_C6S2_4_v6 ; r6 = OC_C6S2; r7 = OC_C2S6 + SMULWT r8, r2, r11 ; r8 = -t[0,5]=OC_C5S3*x[0,3]>>16 + ; Here we cheat: row 3 had just a DC, so x[0,3]==x[1,3] by definition. + PKHBT r9, r9, r9, LSL #16 ; r9 = <t[0,6]|t[0,6]> +@@ -1234,7 +1234,7 @@ idct4_4core_down_v6 PROC + SMLAWB r12,r11,r10,r7 ; r12= t[0,0]+8=(OC_C4S4*x[0,0]>>16)+8 + PKHBT r2, r2, r5, LSL #16 ; r2 = <t[1,2]|t[0,2]> + SMLAWB r5, r11,r4 ,r7 ; r5 = t[1,0]+8=(OC_C4S4*x[1,0]>>16)+8 +- LDRD r6, OC_C7S1_4_v6 ; r6 = OC_C7S1; r7 = OC_C1S7 ++ LDRD r6, r7, OC_C7S1_4_v6 ; r6 = OC_C7S1; r7 = OC_C1S7 + PKHBT r12,r12,r5, LSL #16 ; r12= <t[1,0]+8|t[0,0]+8> + SMULWT r5, r7, r4 ; r5 = t[1,7]=OC_C1S7*x[1,1]>>16 + SMULWT r7, r7, r10 ; r7 = t[0,7]=OC_C1S7*x[0,1]>>16 +@@ -1264,7 +1264,7 @@ idct8_8core_v6 PROC + STMFD r13!,{r0,r14} + ; Stage 1: + ;5-6 rotation by 3pi/16 +- LDRD r10,OC_C5S3_4_v6 ; r10= OC_C5S3, r11= OC_C3S5 ++ LDRD r10, r11, OC_C5S3_4_v6 ; r10= OC_C5S3, r11= OC_C3S5 + LDR r4, [r1,#8] ; r4 = <x[0,5]|x[0,4]> + LDR r7, [r1,#24] ; r7 = <x[1,5]|x[1,4]> + SMULWT r5, r11,r4 ; r5 = OC_C3S5*x[0,5]>>16 +@@ -1281,7 +1281,7 @@ idct8_8core_v6 PROC + PKHBT r6, r6, r11,LSL #16 ; r6 = <t[1,6]|t[0,6]> + SMULWT r8, r10,r12 ; r8 = OC_C5S3*x[1,3]>>16 + ;2-3 rotation by 6pi/16 +- LDRD r10,OC_C6S2_4_v6 ; r10= OC_C6S2, r11= OC_C2S6 ++ LDRD r10, r11, OC_C6S2_4_v6 ; r10= OC_C6S2, r11= OC_C2S6 + PKHBT r3, r3, r8, LSL #16 ; r3 = <r8|r3> + LDR r8, [r1,#12] ; r8 = <x[0,7]|x[0,6]> + SMULWB r2, r10,r0 ; r2 = OC_C6S2*x[0,2]>>16 +@@ -1297,7 +1297,7 @@ idct8_8core_v6 PROC + PKHBT r3, r3, r10,LSL #16 ; r3 = <t[1,6]|t[0,6]> + SMULWB r12,r11,r7 ; r12= OC_C2S6*x[1,6]>>16 + ;4-7 rotation by 7pi/16 +- LDRD r10,OC_C7S1_8_v6 ; r10= OC_C7S1, r11= OC_C1S7 ++ LDRD r10, r11, OC_C7S1_8_v6 ; r10= OC_C7S1, r11= OC_C1S7 + PKHBT r9, r9, r12,LSL #16 ; r9 = <r9|r12> + LDR r0, [r1],#16 ; r0 = <x[0,1]|x[0,0]> + PKHTB r7, r7, r8, ASR #16 ; r7 = <x[1,7]|x[0,7]> +@@ -1363,7 +1363,7 @@ idct8_8core_down_v6 PROC + STMFD r13!,{r0,r14} + ; Stage 1: + ;5-6 rotation by 3pi/16 +- LDRD r10,OC_C5S3_8_v6 ; r10= OC_C5S3, r11= OC_C3S5 ++ LDRD r10, r11, OC_C5S3_8_v6 ; r10= OC_C5S3, r11= OC_C3S5 + LDR r4, [r1,#8] ; r4 = <x[0,5]|x[0,4]> + LDR r7, [r1,#24] ; r7 = <x[1,5]|x[1,4]> + SMULWT r5, r11,r4 ; r5 = OC_C3S5*x[0,5]>>16 +@@ -1380,7 +1380,7 @@ idct8_8core_down_v6 PROC + PKHBT r6, r6, r11,LSL #16 ; r6 = <t[1,6]|t[0,6]> + SMULWT r8, r10,r12 ; r8 = OC_C5S3*x[1,3]>>16 + ;2-3 rotation by 6pi/16 +- LDRD r10,OC_C6S2_8_v6 ; r10= OC_C6S2, r11= OC_C2S6 ++ LDRD r10, r11, OC_C6S2_8_v6 ; r10= OC_C6S2, r11= OC_C2S6 + PKHBT r3, r3, r8, LSL #16 ; r3 = <r8|r3> + LDR r8, [r1,#12] ; r8 = <x[0,7]|x[0,6]> + SMULWB r2, r10,r0 ; r2 = OC_C6S2*x[0,2]>>16 +@@ -1396,7 +1396,7 @@ idct8_8core_down_v6 PROC + PKHBT r3, r3, r10,LSL #16 ; r3 = <t[1,6]|t[0,6]> + SMULWB r12,r11,r7 ; r12= OC_C2S6*x[1,6]>>16 + ;4-7 rotation by 7pi/16 +- LDRD r10,OC_C7S1_8_v6 ; r10= OC_C7S1, r11= OC_C1S7 ++ LDRD r10, r11, OC_C7S1_8_v6 ; r10= OC_C7S1, r11= OC_C1S7 + PKHBT r9, r9, r12,LSL #16 ; r9 = <r9|r12> + LDR r0, [r1],#16 ; r0 = <x[0,1]|x[0,0]> + PKHTB r7, r7, r8, ASR #16 ; r7 = <x[1,7]|x[0,7]> +-- +2.39.1 + diff --git a/media/libtheora/include/theora/codec.h b/media/libtheora/include/theora/codec.h new file mode 100644 index 0000000000..29b8602325 --- /dev/null +++ b/media/libtheora/include/theora/codec.h @@ -0,0 +1,606 @@ +/******************************************************************** + * * + * THIS FILE IS PART OF THE OggTheora SOFTWARE CODEC SOURCE CODE. * + * USE, DISTRIBUTION AND REPRODUCTION OF THIS LIBRARY SOURCE IS * + * GOVERNED BY A BSD-STYLE SOURCE LICENSE INCLUDED WITH THIS SOURCE * + * IN 'COPYING'. PLEASE READ THESE TERMS BEFORE DISTRIBUTING. * + * * + * THE Theora SOURCE CODE IS COPYRIGHT (C) 2002-2009 * + * by the Xiph.Org Foundation http://www.xiph.org/ * + * * + ******************************************************************** + + function: + last mod: $Id: theora.h,v 1.8 2004/03/15 22:17:32 derf Exp $ + + ********************************************************************/ + +/**\mainpage + * + * \section intro Introduction + * + * This is the documentation for the <tt>libtheora</tt> C API. + * + * The \c libtheora package is the current reference + * implementation for <a href="http://www.theora.org/">Theora</a>, a free, + * patent-unencumbered video codec. + * Theora is derived from On2's VP3 codec with additional features and + * integration with Ogg multimedia formats by + * <a href="http://www.xiph.org/">the Xiph.Org Foundation</a>. + * Complete documentation of the format itself is available in + * <a href="http://www.theora.org/doc/Theora.pdf">the Theora + * specification</a>. + * + * \section Organization + * + * The functions documented here are divided between two + * separate libraries: + * - \c libtheoraenc contains the encoder interface, + * described in \ref encfuncs. + * - \c libtheoradec contains the decoder interface, + * described in \ref decfuncs, \n + * and additional \ref basefuncs. + * + * New code should link to \c libtheoradec. If using encoder + * features, it must also link to \c libtheoraenc. + * + * During initial development, prior to the 1.0 release, + * \c libtheora exported a different \ref oldfuncs which + * combined both encode and decode functions. + * In general, legacy API symbols can be indentified + * by their \c theora_ or \c OC_ namespace prefixes. + * The current API uses \c th_ or \c TH_ instead. + * + * While deprecated, \c libtheoraenc and \c libtheoradec + * together export the legacy api as well at the one documented above. + * Likewise, the legacy \c libtheora included with this package + * exports the new 1.x API. Older code and build scripts can therefore + * but updated independently to the current scheme. + */ + +/**\file + * The shared <tt>libtheoradec</tt> and <tt>libtheoraenc</tt> C API. + * You don't need to include this directly.*/ + +#if !defined(_O_THEORA_CODEC_H_) +# define _O_THEORA_CODEC_H_ (1) +# include <ogg/ogg.h> + +#if defined(__cplusplus) +extern "C" { +#endif + + + +/**\name Return codes*/ +/*@{*/ +/**An invalid pointer was provided.*/ +#define TH_EFAULT (-1) +/**An invalid argument was provided.*/ +#define TH_EINVAL (-10) +/**The contents of the header were incomplete, invalid, or unexpected.*/ +#define TH_EBADHEADER (-20) +/**The header does not belong to a Theora stream.*/ +#define TH_ENOTFORMAT (-21) +/**The bitstream version is too high.*/ +#define TH_EVERSION (-22) +/**The specified function is not implemented.*/ +#define TH_EIMPL (-23) +/**There were errors in the video data packet.*/ +#define TH_EBADPACKET (-24) +/**The decoded packet represented a dropped frame. + The player can continue to display the current frame, as the contents of the + decoded frame buffer have not changed.*/ +#define TH_DUPFRAME (1) +/*@}*/ + +/**The currently defined color space tags. + * See <a href="http://www.theora.org/doc/Theora.pdf">the Theora + * specification</a>, Chapter 4, for exact details on the meaning + * of each of these color spaces.*/ +typedef enum{ + /**The color space was not specified at the encoder. + It may be conveyed by an external means.*/ + TH_CS_UNSPECIFIED, + /**A color space designed for NTSC content.*/ + TH_CS_ITU_REC_470M, + /**A color space designed for PAL/SECAM content.*/ + TH_CS_ITU_REC_470BG, + /**The total number of currently defined color spaces.*/ + TH_CS_NSPACES +}th_colorspace; + +/**The currently defined pixel format tags. + * See <a href="http://www.theora.org/doc/Theora.pdf">the Theora + * specification</a>, Section 4.4, for details on the precise sample + * locations.*/ +typedef enum{ + /**Chroma decimation by 2 in both the X and Y directions (4:2:0). + The Cb and Cr chroma planes are half the width and half the + height of the luma plane.*/ + TH_PF_420, + /**Currently reserved.*/ + TH_PF_RSVD, + /**Chroma decimation by 2 in the X direction (4:2:2). + The Cb and Cr chroma planes are half the width of the luma plane, but full + height.*/ + TH_PF_422, + /**No chroma decimation (4:4:4). + The Cb and Cr chroma planes are full width and full height.*/ + TH_PF_444, + /**The total number of currently defined pixel formats.*/ + TH_PF_NFORMATS +}th_pixel_fmt; + + + +/**A buffer for a single color plane in an uncompressed image. + * This contains the image data in a left-to-right, top-down format. + * Each row of pixels is stored contiguously in memory, but successive + * rows need not be. + * Use \a stride to compute the offset of the next row. + * The encoder accepts both positive \a stride values (top-down in memory) + * and negative (bottom-up in memory). + * The decoder currently always generates images with positive strides.*/ +typedef struct{ + /**The width of this plane.*/ + int width; + /**The height of this plane.*/ + int height; + /**The offset in bytes between successive rows.*/ + int stride; + /**A pointer to the beginning of the first row.*/ + unsigned char *data; +}th_img_plane; + +/**A complete image buffer for an uncompressed frame. + * The chroma planes may be decimated by a factor of two in either + * direction, as indicated by th_info#pixel_fmt. + * The width and height of the Y' plane must be multiples of 16. + * They may need to be cropped for display, using the rectangle + * specified by th_info#pic_x, th_info#pic_y, th_info#pic_width, + * and th_info#pic_height. + * All samples are 8 bits. + * \note The term YUV often used to describe a colorspace is ambiguous. + * The exact parameters of the RGB to YUV conversion process aside, in + * many contexts the U and V channels actually have opposite meanings. + * To avoid this confusion, we are explicit: the name of the color + * channels are Y'CbCr, and they appear in that order, always. + * The prime symbol denotes that the Y channel is non-linear. + * Cb and Cr stand for "Chroma blue" and "Chroma red", respectively.*/ +typedef th_img_plane th_ycbcr_buffer[3]; + +/**Theora bitstream information. + * This contains the basic playback parameters for a stream, and corresponds to + * the initial 'info' header packet. + * To initialize an encoder, the application fills in this structure and + * passes it to th_encode_alloc(). + * A default encoding mode is chosen based on the values of the #quality and + * #target_bitrate fields. + * On decode, it is filled in by th_decode_headerin(), and then passed to + * th_decode_alloc(). + * + * Encoded Theora frames must be a multiple of 16 in size; + * this is what the #frame_width and #frame_height members represent. + * To handle arbitrary picture sizes, a crop rectangle is specified in the + * #pic_x, #pic_y, #pic_width and #pic_height members. + * + * All frame buffers contain pointers to the full, padded frame. + * However, the current encoder <em>will not</em> reference pixels outside of + * the cropped picture region, and the application does not need to fill them + * in. + * The decoder <em>will</em> allocate storage for a full frame, but the + * application <em>should not</em> rely on the padding containing sensible + * data. + * + * It is also generally recommended that the offsets and sizes should still be + * multiples of 2 to avoid chroma sampling shifts when chroma is sub-sampled. + * See <a href="http://www.theora.org/doc/Theora.pdf">the Theora + * specification</a>, Section 4.4, for more details. + * + * Frame rate, in frames per second, is stored as a rational fraction, as is + * the pixel aspect ratio. + * Note that this refers to the aspect ratio of the individual pixels, not of + * the overall frame itself. + * The frame aspect ratio can be computed from pixel aspect ratio using the + * image dimensions.*/ +typedef struct{ + /**\name Theora version + * Bitstream version information.*/ + /*@{*/ + unsigned char version_major; + unsigned char version_minor; + unsigned char version_subminor; + /*@}*/ + /**The encoded frame width. + * This must be a multiple of 16, and less than 1048576.*/ + ogg_uint32_t frame_width; + /**The encoded frame height. + * This must be a multiple of 16, and less than 1048576.*/ + ogg_uint32_t frame_height; + /**The displayed picture width. + * This must be no larger than width.*/ + ogg_uint32_t pic_width; + /**The displayed picture height. + * This must be no larger than height.*/ + ogg_uint32_t pic_height; + /**The X offset of the displayed picture. + * This must be no larger than #frame_width-#pic_width or 255, whichever is + * smaller.*/ + ogg_uint32_t pic_x; + /**The Y offset of the displayed picture. + * This must be no larger than #frame_height-#pic_height, and + * #frame_height-#pic_height-#pic_y must be no larger than 255. + * This slightly funny restriction is due to the fact that the offset is + * specified from the top of the image for consistency with the standard + * graphics left-handed coordinate system used throughout this API, while + * it is stored in the encoded stream as an offset from the bottom.*/ + ogg_uint32_t pic_y; + /**\name Frame rate + * The frame rate, as a fraction. + * If either is 0, the frame rate is undefined.*/ + /*@{*/ + ogg_uint32_t fps_numerator; + ogg_uint32_t fps_denominator; + /*@}*/ + /**\name Aspect ratio + * The aspect ratio of the pixels. + * If either value is zero, the aspect ratio is undefined. + * If not specified by any external means, 1:1 should be assumed. + * The aspect ratio of the full picture can be computed as + * \code + * aspect_numerator*pic_width/(aspect_denominator*pic_height). + * \endcode */ + /*@{*/ + ogg_uint32_t aspect_numerator; + ogg_uint32_t aspect_denominator; + /*@}*/ + /**The color space.*/ + th_colorspace colorspace; + /**The pixel format.*/ + th_pixel_fmt pixel_fmt; + /**The target bit-rate in bits per second. + If initializing an encoder with this struct, set this field to a non-zero + value to activate CBR encoding by default.*/ + int target_bitrate; + /**The target quality level. + Valid values range from 0 to 63, inclusive, with higher values giving + higher quality. + If initializing an encoder with this struct, and #target_bitrate is set + to zero, VBR encoding at this quality will be activated by default.*/ + /*Currently this is set so that a qi of 0 corresponds to distortions of 24 + times the JND, and each increase by 16 halves that value. + This gives us fine discrimination at low qualities, yet effective rate + control at high qualities. + The qi value 63 is special, however. + For this, the highest quality, we use one half of a JND for our threshold. + Due to the lower bounds placed on allowable quantizers in Theora, we will + not actually be able to achieve quality this good, but this should + provide as close to visually lossless quality as Theora is capable of. + We could lift the quantizer restrictions without breaking VP3.1 + compatibility, but this would result in quantized coefficients that are + too large for the current bitstream to be able to store. + We'd have to redesign the token syntax to store these large coefficients, + which would make transcoding complex.*/ + int quality; + /**The amount to shift to extract the last keyframe number from the granule + * position. + * This can be at most 31. + * th_info_init() will set this to a default value (currently <tt>6</tt>, + * which is good for streaming applications), but you can set it to 0 to + * make every frame a keyframe. + * The maximum distance between key frames is + * <tt>1<<#keyframe_granule_shift</tt>. + * The keyframe frequency can be more finely controlled with + * #TH_ENCCTL_SET_KEYFRAME_FREQUENCY_FORCE, which can also be adjusted + * during encoding (for example, to force the next frame to be a keyframe), + * but it cannot be set larger than the amount permitted by this field after + * the headers have been output.*/ + int keyframe_granule_shift; +}th_info; + +/**The comment information. + * + * This structure holds the in-stream metadata corresponding to + * the 'comment' header packet. + * The comment header is meant to be used much like someone jotting a quick + * note on the label of a video. + * It should be a short, to the point text note that can be more than a couple + * words, but not more than a short paragraph. + * + * The metadata is stored as a series of (tag, value) pairs, in + * length-encoded string vectors. + * The first occurrence of the '=' character delimits the tag and value. + * A particular tag may occur more than once, and order is significant. + * The character set encoding for the strings is always UTF-8, but the tag + * names are limited to ASCII, and treated as case-insensitive. + * See <a href="http://www.theora.org/doc/Theora.pdf">the Theora + * specification</a>, Section 6.3.3 for details. + * + * In filling in this structure, th_decode_headerin() will null-terminate + * the user_comment strings for safety. + * However, the bitstream format itself treats them as 8-bit clean vectors, + * possibly containing null characters, so the length array should be + * treated as their authoritative length. + */ +typedef struct th_comment{ + /**The array of comment string vectors.*/ + char **user_comments; + /**An array of the corresponding length of each vector, in bytes.*/ + int *comment_lengths; + /**The total number of comment strings.*/ + int comments; + /**The null-terminated vendor string. + This identifies the software used to encode the stream.*/ + char *vendor; +}th_comment; + + + +/**A single base matrix.*/ +typedef unsigned char th_quant_base[64]; + +/**A set of \a qi ranges.*/ +typedef struct{ + /**The number of ranges in the set.*/ + int nranges; + /**The size of each of the #nranges ranges. + These must sum to 63.*/ + const int *sizes; + /**#nranges <tt>+1</tt> base matrices. + Matrices \a i and <tt>i+1</tt> form the endpoints of range \a i.*/ + const th_quant_base *base_matrices; +}th_quant_ranges; + +/**A complete set of quantization parameters. + The quantizer for each coefficient is calculated as: + \code + Q=MAX(MIN(qmin[qti][ci!=0],scale[ci!=0][qi]*base[qti][pli][qi][ci]/100), + 1024). + \endcode + + \a qti is the quantization type index: 0 for intra, 1 for inter. + <tt>ci!=0</tt> is 0 for the DC coefficient and 1 for AC coefficients. + \a qi is the quality index, ranging between 0 (low quality) and 63 (high + quality). + \a pli is the color plane index: 0 for Y', 1 for Cb, 2 for Cr. + \a ci is the DCT coefficient index. + Coefficient indices correspond to the normal 2D DCT block + ordering--row-major with low frequencies first--\em not zig-zag order. + + Minimum quantizers are constant, and are given by: + \code + qmin[2][2]={{4,2},{8,4}}. + \endcode + + Parameters that can be stored in the bitstream are as follows: + - The two scale matrices ac_scale and dc_scale. + \code + scale[2][64]={dc_scale,ac_scale}. + \endcode + - The base matrices for each \a qi, \a qti and \a pli (up to 384 in all). + In order to avoid storing a full 384 base matrices, only a sparse set of + matrices are stored, and the rest are linearly interpolated. + This is done as follows. + For each \a qti and \a pli, a series of \a n \a qi ranges is defined. + The size of each \a qi range can vary arbitrarily, but they must sum to + 63. + Then, <tt>n+1</tt> matrices are specified, one for each endpoint of the + ranges. + For interpolation purposes, each range's endpoints are the first \a qi + value it contains and one past the last \a qi value it contains. + Fractional values are rounded to the nearest integer, with ties rounded + away from zero. + + Base matrices are stored by reference, so if the same matrices are used + multiple times, they will only appear once in the bitstream. + The bitstream is also capable of omitting an entire set of ranges and + its associated matrices if they are the same as either the previous + set (indexed in row-major order) or if the inter set is the same as the + intra set. + + - Loop filter limit values. + The same limits are used for the loop filter in all color planes, despite + potentially differing levels of quantization in each. + + For the current encoder, <tt>scale[ci!=0][qi]</tt> must be no greater + than <tt>scale[ci!=0][qi-1]</tt> and <tt>base[qti][pli][qi][ci]</tt> must + be no greater than <tt>base[qti][pli][qi-1][ci]</tt>. + These two conditions ensure that the actual quantizer for a given \a qti, + \a pli, and \a ci does not increase as \a qi increases. + This is not required by the decoder.*/ +typedef struct{ + /**The DC scaling factors.*/ + ogg_uint16_t dc_scale[64]; + /**The AC scaling factors.*/ + ogg_uint16_t ac_scale[64]; + /**The loop filter limit values.*/ + unsigned char loop_filter_limits[64]; + /**The \a qi ranges for each \a ci and \a pli.*/ + th_quant_ranges qi_ranges[2][3]; +}th_quant_info; + + + +/**The number of Huffman tables used by Theora.*/ +#define TH_NHUFFMAN_TABLES (80) +/**The number of DCT token values in each table.*/ +#define TH_NDCT_TOKENS (32) + +/**A Huffman code for a Theora DCT token. + * Each set of Huffman codes in a given table must form a complete, prefix-free + * code. + * There is no requirement that all the tokens in a table have a valid code, + * but the current encoder is not optimized to take advantage of this. + * If each of the five grouops of 16 tables does not contain at least one table + * with a code for every token, then the encoder may fail to encode certain + * frames. + * The complete table in the first group of 16 does not have to be in the same + * place as the complete table in the other groups, but the complete tables in + * the remaining four groups must all be in the same place.*/ +typedef struct{ + /**The bit pattern for the code, with the LSbit of the pattern aligned in + * the LSbit of the word.*/ + ogg_uint32_t pattern; + /**The number of bits in the code. + * This must be between 0 and 32, inclusive.*/ + int nbits; +}th_huff_code; + + + +/**\defgroup basefuncs Functions Shared by Encode and Decode*/ +/*@{*/ +/**\name Basic shared functions + * These functions return information about the library itself, + * or provide high-level information about codec state + * and packet type. + * + * You must link to \c libtheoradec if you use any of the + * functions in this section.*/ +/*@{*/ +/**Retrieves a human-readable string to identify the library vendor and + * version. + * \return the version string.*/ +extern const char *th_version_string(void); +/**Retrieves the library version number. + * This is the highest bitstream version that the encoder library will produce, + * or that the decoder library can decode. + * This number is composed of a 16-bit major version, 8-bit minor version + * and 8 bit sub-version, composed as follows: + * \code + * (VERSION_MAJOR<<16)+(VERSION_MINOR<<8)+(VERSION_SUBMINOR) + * \endcode + * \return the version number.*/ +extern ogg_uint32_t th_version_number(void); +/**Converts a granule position to an absolute frame index, starting at + * <tt>0</tt>. + * The granule position is interpreted in the context of a given + * #th_enc_ctx or #th_dec_ctx handle (either will suffice). + * \param _encdec A previously allocated #th_enc_ctx or #th_dec_ctx + * handle. + * \param _granpos The granule position to convert. + * \returns The absolute frame index corresponding to \a _granpos. + * \retval -1 The given granule position was invalid (i.e. negative).*/ +extern ogg_int64_t th_granule_frame(void *_encdec,ogg_int64_t _granpos); +/**Converts a granule position to an absolute time in seconds. + * The granule position is interpreted in the context of a given + * #th_enc_ctx or #th_dec_ctx handle (either will suffice). + * \param _encdec A previously allocated #th_enc_ctx or #th_dec_ctx + * handle. + * \param _granpos The granule position to convert. + * \return The absolute time in seconds corresponding to \a _granpos. + * This is the "end time" for the frame, or the latest time it should + * be displayed. + * It is not the presentation time. + * \retval -1 The given granule position was invalid (i.e. negative).*/ +extern double th_granule_time(void *_encdec,ogg_int64_t _granpos); +/**Determines whether a Theora packet is a header or not. + * This function does no verification beyond checking the packet type bit, so + * it should not be used for bitstream identification; use + * th_decode_headerin() for that. + * As per the Theora specification, an empty (0-byte) packet is treated as a + * data packet (a delta frame with no coded blocks). + * \param _op An <tt>ogg_packet</tt> containing encoded Theora data. + * \retval 1 The packet is a header packet + * \retval 0 The packet is a video data packet.*/ +extern int th_packet_isheader(ogg_packet *_op); +/**Determines whether a theora packet is a key frame or not. + * This function does no verification beyond checking the packet type and + * key frame bits, so it should not be used for bitstream identification; use + * th_decode_headerin() for that. + * As per the Theora specification, an empty (0-byte) packet is treated as a + * delta frame (with no coded blocks). + * \param _op An <tt>ogg_packet</tt> containing encoded Theora data. + * \retval 1 The packet contains a key frame. + * \retval 0 The packet contains a delta frame. + * \retval -1 The packet is not a video data packet.*/ +extern int th_packet_iskeyframe(ogg_packet *_op); +/*@}*/ + + +/**\name Functions for manipulating header data + * These functions manipulate the #th_info and #th_comment structures + * which describe video parameters and key-value metadata, respectively. + * + * You must link to \c libtheoradec if you use any of the + * functions in this section.*/ +/*@{*/ +/**Initializes a th_info structure. + * This should be called on a freshly allocated #th_info structure before + * attempting to use it. + * \param _info The #th_info struct to initialize.*/ +extern void th_info_init(th_info *_info); +/**Clears a #th_info structure. + * This should be called on a #th_info structure after it is no longer + * needed. + * \param _info The #th_info struct to clear.*/ +extern void th_info_clear(th_info *_info); + +/**Initialize a #th_comment structure. + * This should be called on a freshly allocated #th_comment structure + * before attempting to use it. + * \param _tc The #th_comment struct to initialize.*/ +extern void th_comment_init(th_comment *_tc); +/**Add a comment to an initialized #th_comment structure. + * \note Neither th_comment_add() nor th_comment_add_tag() support + * comments containing null values, although the bitstream format does + * support them. + * To add such comments you will need to manipulate the #th_comment + * structure directly. + * \param _tc The #th_comment struct to add the comment to. + * \param _comment Must be a null-terminated UTF-8 string containing the + * comment in "TAG=the value" form.*/ +extern void th_comment_add(th_comment *_tc,const char *_comment); +/**Add a comment to an initialized #th_comment structure. + * \note Neither th_comment_add() nor th_comment_add_tag() support + * comments containing null values, although the bitstream format does + * support them. + * To add such comments you will need to manipulate the #th_comment + * structure directly. + * \param _tc The #th_comment struct to add the comment to. + * \param _tag A null-terminated string containing the tag associated with + * the comment. + * \param _val The corresponding value as a null-terminated string.*/ +extern void th_comment_add_tag(th_comment *_tc,const char *_tag, + const char *_val); +/**Look up a comment value by its tag. + * \param _tc An initialized #th_comment structure. + * \param _tag The tag to look up. + * \param _count The instance of the tag. + * The same tag can appear multiple times, each with a distinct + * value, so an index is required to retrieve them all. + * The order in which these values appear is significant and + * should be preserved. + * Use th_comment_query_count() to get the legal range for + * the \a _count parameter. + * \return A pointer to the queried tag's value. + * This points directly to data in the #th_comment structure. + * It should not be modified or freed by the application, and + * modifications to the structure may invalidate the pointer. + * \retval NULL If no matching tag is found.*/ +extern char *th_comment_query(th_comment *_tc,const char *_tag,int _count); +/**Look up the number of instances of a tag. + * Call this first when querying for a specific tag and then iterate over the + * number of instances with separate calls to th_comment_query() to + * retrieve all the values for that tag in order. + * \param _tc An initialized #th_comment structure. + * \param _tag The tag to look up. + * \return The number of instances of this particular tag.*/ +extern int th_comment_query_count(th_comment *_tc,const char *_tag); +/**Clears a #th_comment structure. + * This should be called on a #th_comment structure after it is no longer + * needed. + * It will free all memory used by the structure members. + * \param _tc The #th_comment struct to clear.*/ +extern void th_comment_clear(th_comment *_tc); +/*@}*/ +/*@}*/ + + + +#if defined(__cplusplus) +} +#endif + +#endif diff --git a/media/libtheora/include/theora/theora.h b/media/libtheora/include/theora/theora.h new file mode 100644 index 0000000000..a729a76890 --- /dev/null +++ b/media/libtheora/include/theora/theora.h @@ -0,0 +1,786 @@ +/******************************************************************** + * * + * THIS FILE IS PART OF THE OggTheora SOFTWARE CODEC SOURCE CODE. * + * USE, DISTRIBUTION AND REPRODUCTION OF THIS LIBRARY SOURCE IS * + * GOVERNED BY A BSD-STYLE SOURCE LICENSE INCLUDED WITH THIS SOURCE * + * IN 'COPYING'. PLEASE READ THESE TERMS BEFORE DISTRIBUTING. * + * * + * THE Theora SOURCE CODE IS COPYRIGHT (C) 2002-2009 * + * by the Xiph.Org Foundation http://www.xiph.org/ * + * * + ******************************************************************** + + function: + last mod: $Id: theora.h,v 1.17 2003/12/06 18:06:19 arc Exp $ + + ********************************************************************/ + +#ifndef _O_THEORA_H_ +#define _O_THEORA_H_ + +#ifdef __cplusplus +extern "C" +{ +#endif /* __cplusplus */ + +#include <stddef.h> /* for size_t */ + +#include <ogg/ogg.h> + +/** \file + * The libtheora pre-1.0 legacy C API. + * + * \ingroup oldfuncs + * + * \section intro Introduction + * + * This is the documentation for the libtheora legacy C API, declared in + * the theora.h header, which describes the old interface used before + * the 1.0 release. This API was widely deployed for several years and + * remains supported, but for new code we recommend the cleaner API + * declared in theoradec.h and theoraenc.h. + * + * libtheora is the reference implementation for + * <a href="http://www.theora.org/">Theora</a>, a free video codec. + * Theora is derived from On2's VP3 codec with improved integration with + * Ogg multimedia formats by <a href="http://www.xiph.org/">Xiph.Org</a>. + * + * \section overview Overview + * + * This library will both decode and encode theora packets to/from raw YUV + * frames. In either case, the packets will most likely either come from or + * need to be embedded in an Ogg stream. Use + * <a href="http://xiph.org/ogg/">libogg</a> or + * <a href="http://www.annodex.net/software/liboggz/index.html">liboggz</a> + * to extract/package these packets. + * + * \section decoding Decoding Process + * + * Decoding can be separated into the following steps: + * -# initialise theora_info and theora_comment structures using + * theora_info_init() and theora_comment_init(): + \verbatim + theora_info info; + theora_comment comment; + + theora_info_init(&info); + theora_comment_init(&comment); + \endverbatim + * -# retrieve header packets from Ogg stream (there should be 3) and decode + * into theora_info and theora_comment structures using + * theora_decode_header(). See \ref identification for more information on + * identifying which packets are theora packets. + \verbatim + int i; + for (i = 0; i < 3; i++) + { + (get a theora packet "op" from the Ogg stream) + theora_decode_header(&info, &comment, op); + } + \endverbatim + * -# initialise the decoder based on the information retrieved into the + * theora_info struct by theora_decode_header(). You will need a + * theora_state struct. + \verbatim + theora_state state; + + theora_decode_init(&state, &info); + \endverbatim + * -# pass in packets and retrieve decoded frames! See the yuv_buffer + * documentation for information on how to retrieve raw YUV data. + \verbatim + yuf_buffer buffer; + while (last packet was not e_o_s) { + (get a theora packet "op" from the Ogg stream) + theora_decode_packetin(&state, op); + theora_decode_YUVout(&state, &buffer); + } + \endverbatim + * + * + * \subsection identification Identifying Theora Packets + * + * All streams inside an Ogg file have a unique serial_no attached to the + * stream. Typically, you will want to + * - retrieve the serial_no for each b_o_s (beginning of stream) page + * encountered within the Ogg file; + * - test the first (only) packet on that page to determine if it is a theora + * packet; + * - once you have found a theora b_o_s page then use the retrieved serial_no + * to identify future packets belonging to the same theora stream. + * + * Note that you \e cannot use theora_packet_isheader() to determine if a + * packet is a theora packet or not, as this function does not perform any + * checking beyond whether a header bit is present. Instead, use the + * theora_decode_header() function and check the return value; or examine the + * header bytes at the beginning of the Ogg page. + */ + + +/** \defgroup oldfuncs Legacy pre-1.0 C API */ +/* @{ */ + +/** + * A YUV buffer for passing uncompressed frames to and from the codec. + * This holds a Y'CbCr frame in planar format. The CbCr planes can be + * subsampled and have their own separate dimensions and row stride + * offsets. Note that the strides may be negative in some + * configurations. For theora the width and height of the largest plane + * must be a multiple of 16. The actual meaningful picture size and + * offset are stored in the theora_info structure; frames returned by + * the decoder may need to be cropped for display. + * + * All samples are 8 bits. Within each plane samples are ordered by + * row from the top of the frame to the bottom. Within each row samples + * are ordered from left to right. + * + * During decode, the yuv_buffer struct is allocated by the user, but all + * fields (including luma and chroma pointers) are filled by the library. + * These pointers address library-internal memory and their contents should + * not be modified. + * + * Conversely, during encode the user allocates the struct and fills out all + * fields. The user also manages the data addressed by the luma and chroma + * pointers. See the encoder_example.c and dump_video.c example files in + * theora/examples/ for more information. + */ +typedef struct { + int y_width; /**< Width of the Y' luminance plane */ + int y_height; /**< Height of the luminance plane */ + int y_stride; /**< Offset in bytes between successive rows */ + + int uv_width; /**< Width of the Cb and Cr chroma planes */ + int uv_height; /**< Height of the chroma planes */ + int uv_stride; /**< Offset between successive chroma rows */ + unsigned char *y; /**< Pointer to start of luminance data */ + unsigned char *u; /**< Pointer to start of Cb data */ + unsigned char *v; /**< Pointer to start of Cr data */ + +} yuv_buffer; + +/** + * A Colorspace. + */ +typedef enum { + OC_CS_UNSPECIFIED, /**< The colorspace is unknown or unspecified */ + OC_CS_ITU_REC_470M, /**< This is the best option for 'NTSC' content */ + OC_CS_ITU_REC_470BG, /**< This is the best option for 'PAL' content */ + OC_CS_NSPACES /**< This marks the end of the defined colorspaces */ +} theora_colorspace; + +/** + * A Chroma subsampling + * + * These enumerate the available chroma subsampling options supported + * by the theora format. See Section 4.4 of the specification for + * exact definitions. + */ +typedef enum { + OC_PF_420, /**< Chroma subsampling by 2 in each direction (4:2:0) */ + OC_PF_RSVD, /**< Reserved value */ + OC_PF_422, /**< Horizonatal chroma subsampling by 2 (4:2:2) */ + OC_PF_444 /**< No chroma subsampling at all (4:4:4) */ +} theora_pixelformat; + +/** + * Theora bitstream info. + * Contains the basic playback parameters for a stream, + * corresponding to the initial 'info' header packet. + * + * Encoded theora frames must be a multiple of 16 in width and height. + * To handle other frame sizes, a crop rectangle is specified in + * frame_height and frame_width, offset_x and * offset_y. The offset + * and size should still be a multiple of 2 to avoid chroma sampling + * shifts. Offset values in this structure are measured from the + * upper left of the image. + * + * Frame rate, in frames per second, is stored as a rational + * fraction. Aspect ratio is also stored as a rational fraction, and + * refers to the aspect ratio of the frame pixels, not of the + * overall frame itself. + * + * See <a href="http://svn.xiph.org/trunk/theora/examples/encoder_example.c"> + * examples/encoder_example.c</a> for usage examples of the + * other parameters and good default settings for the encoder parameters. + */ +typedef struct { + ogg_uint32_t width; /**< encoded frame width */ + ogg_uint32_t height; /**< encoded frame height */ + ogg_uint32_t frame_width; /**< display frame width */ + ogg_uint32_t frame_height; /**< display frame height */ + ogg_uint32_t offset_x; /**< horizontal offset of the displayed frame */ + ogg_uint32_t offset_y; /**< vertical offset of the displayed frame */ + ogg_uint32_t fps_numerator; /**< frame rate numerator **/ + ogg_uint32_t fps_denominator; /**< frame rate denominator **/ + ogg_uint32_t aspect_numerator; /**< pixel aspect ratio numerator */ + ogg_uint32_t aspect_denominator; /**< pixel aspect ratio denominator */ + theora_colorspace colorspace; /**< colorspace */ + int target_bitrate; /**< nominal bitrate in bits per second */ + int quality; /**< Nominal quality setting, 0-63 */ + int quick_p; /**< Quick encode/decode */ + + /* decode only */ + unsigned char version_major; + unsigned char version_minor; + unsigned char version_subminor; + + void *codec_setup; + + /* encode only */ + int dropframes_p; + int keyframe_auto_p; + ogg_uint32_t keyframe_frequency; + ogg_uint32_t keyframe_frequency_force; /* also used for decode init to + get granpos shift correct */ + ogg_uint32_t keyframe_data_target_bitrate; + ogg_int32_t keyframe_auto_threshold; + ogg_uint32_t keyframe_mindistance; + ogg_int32_t noise_sensitivity; + ogg_int32_t sharpness; + + theora_pixelformat pixelformat; /**< chroma subsampling mode to expect */ + +} theora_info; + +/** Codec internal state and context. + */ +typedef struct{ + theora_info *i; + ogg_int64_t granulepos; + + void *internal_encode; + void *internal_decode; + +} theora_state; + +/** + * Comment header metadata. + * + * This structure holds the in-stream metadata corresponding to + * the 'comment' header packet. + * + * Meta data is stored as a series of (tag, value) pairs, in + * length-encoded string vectors. The first occurence of the + * '=' character delimits the tag and value. A particular tag + * may occur more than once. The character set encoding for + * the strings is always UTF-8, but the tag names are limited + * to case-insensitive ASCII. See the spec for details. + * + * In filling in this structure, theora_decode_header() will + * null-terminate the user_comment strings for safety. However, + * the bitstream format itself treats them as 8-bit clean, + * and so the length array should be treated as authoritative + * for their length. + */ +typedef struct theora_comment{ + char **user_comments; /**< An array of comment string vectors */ + int *comment_lengths; /**< An array of corresponding string vector lengths in bytes */ + int comments; /**< The total number of comment string vectors */ + char *vendor; /**< The vendor string identifying the encoder, null terminated */ + +} theora_comment; + + +/**\name theora_control() codes */ +/* \anchor decctlcodes_old + * These are the available request codes for theora_control() + * when called with a decoder instance. + * By convention decoder control codes are odd, to distinguish + * them from \ref encctlcodes_old "encoder control codes" which + * are even. + * + * Note that since the 1.0 release, both the legacy and the final + * implementation accept all the same control codes, but only the + * final API declares the newer codes. + * + * Keep any experimental or vendor-specific values above \c 0x8000.*/ + +/*@{*/ + +/**Get the maximum post-processing level. + * The decoder supports a post-processing filter that can improve + * the appearance of the decoded images. This returns the highest + * level setting for this post-processor, corresponding to maximum + * improvement and computational expense. + */ +#define TH_DECCTL_GET_PPLEVEL_MAX (1) + +/**Set the post-processing level. + * Sets the level of post-processing to use when decoding the + * compressed stream. This must be a value between zero (off) + * and the maximum returned by TH_DECCTL_GET_PPLEVEL_MAX. + */ +#define TH_DECCTL_SET_PPLEVEL (3) + +/**Sets the maximum distance between key frames. + * This can be changed during an encode, but will be bounded by + * <tt>1<<th_info#keyframe_granule_shift</tt>. + * If it is set before encoding begins, th_info#keyframe_granule_shift will + * be enlarged appropriately. + * + * \param[in] buf <tt>ogg_uint32_t</tt>: The maximum distance between key + * frames. + * \param[out] buf <tt>ogg_uint32_t</tt>: The actual maximum distance set. + * \retval OC_FAULT \a theora_state or \a buf is <tt>NULL</tt>. + * \retval OC_EINVAL \a buf_sz is not <tt>sizeof(ogg_uint32_t)</tt>. + * \retval OC_IMPL Not supported by this implementation.*/ +#define TH_ENCCTL_SET_KEYFRAME_FREQUENCY_FORCE (4) + +/**Set the granule position. + * Call this after a seek, to update the internal granulepos + * in the decoder, to insure that subsequent frames are marked + * properly. If you track timestamps yourself and do not use + * the granule postion returned by the decoder, then you do + * not need to use this control. + */ +#define TH_DECCTL_SET_GRANPOS (5) + +/**\anchor encctlcodes_old */ + +/**Sets the quantization parameters to use. + * The parameters are copied, not stored by reference, so they can be freed + * after this call. + * <tt>NULL</tt> may be specified to revert to the default parameters. + * + * \param[in] buf #th_quant_info + * \retval OC_FAULT \a theora_state is <tt>NULL</tt>. + * \retval OC_EINVAL Encoding has already begun, the quantization parameters + * are not acceptable to this version of the encoder, + * \a buf is <tt>NULL</tt> and \a buf_sz is not zero, + * or \a buf is non-<tt>NULL</tt> and \a buf_sz is + * not <tt>sizeof(#th_quant_info)</tt>. + * \retval OC_IMPL Not supported by this implementation.*/ +#define TH_ENCCTL_SET_QUANT_PARAMS (2) + +/**Disables any encoder features that would prevent lossless transcoding back + * to VP3. + * This primarily means disabling block-level QI values and not using 4MV mode + * when any of the luma blocks in a macro block are not coded. + * It also includes using the VP3 quantization tables and Huffman codes; if you + * set them explicitly after calling this function, the resulting stream will + * not be VP3-compatible. + * If you enable VP3-compatibility when encoding 4:2:2 or 4:4:4 source + * material, or when using a picture region smaller than the full frame (e.g. + * a non-multiple-of-16 width or height), then non-VP3 bitstream features will + * still be disabled, but the stream will still not be VP3-compatible, as VP3 + * was not capable of encoding such formats. + * If you call this after encoding has already begun, then the quantization + * tables and codebooks cannot be changed, but the frame-level features will + * be enabled or disabled as requested. + * + * \param[in] buf <tt>int</tt>: a non-zero value to enable VP3 compatibility, + * or 0 to disable it (the default). + * \param[out] buf <tt>int</tt>: 1 if all bitstream features required for + * VP3-compatibility could be set, and 0 otherwise. + * The latter will be returned if the pixel format is not + * 4:2:0, the picture region is smaller than the full frame, + * or if encoding has begun, preventing the quantization + * tables and codebooks from being set. + * \retval OC_FAULT \a theora_state or \a buf is <tt>NULL</tt>. + * \retval OC_EINVAL \a buf_sz is not <tt>sizeof(int)</tt>. + * \retval OC_IMPL Not supported by this implementation.*/ +#define TH_ENCCTL_SET_VP3_COMPATIBLE (10) + +/**Gets the maximum speed level. + * Higher speed levels favor quicker encoding over better quality per bit. + * Depending on the encoding mode, and the internal algorithms used, quality + * may actually improve, but in this case bitrate will also likely increase. + * In any case, overall rate/distortion performance will probably decrease. + * The maximum value, and the meaning of each value, may change depending on + * the current encoding mode (VBR vs. CQI, etc.). + * + * \param[out] buf int: The maximum encoding speed level. + * \retval OC_FAULT \a theora_state or \a buf is <tt>NULL</tt>. + * \retval OC_EINVAL \a buf_sz is not <tt>sizeof(int)</tt>. + * \retval OC_IMPL Not supported by this implementation in the current + * encoding mode.*/ +#define TH_ENCCTL_GET_SPLEVEL_MAX (12) + +/**Sets the speed level. + * By default a speed value of 1 is used. + * + * \param[in] buf int: The new encoding speed level. + * 0 is slowest, larger values use less CPU. + * \retval OC_FAULT \a theora_state or \a buf is <tt>NULL</tt>. + * \retval OC_EINVAL \a buf_sz is not <tt>sizeof(int)</tt>, or the + * encoding speed level is out of bounds. + * The maximum encoding speed level may be + * implementation- and encoding mode-specific, and can be + * obtained via #TH_ENCCTL_GET_SPLEVEL_MAX. + * \retval OC_IMPL Not supported by this implementation in the current + * encoding mode.*/ +#define TH_ENCCTL_SET_SPLEVEL (14) + +/*@}*/ + +#define OC_FAULT -1 /**< General failure */ +#define OC_EINVAL -10 /**< Library encountered invalid internal data */ +#define OC_DISABLED -11 /**< Requested action is disabled */ +#define OC_BADHEADER -20 /**< Header packet was corrupt/invalid */ +#define OC_NOTFORMAT -21 /**< Packet is not a theora packet */ +#define OC_VERSION -22 /**< Bitstream version is not handled */ +#define OC_IMPL -23 /**< Feature or action not implemented */ +#define OC_BADPACKET -24 /**< Packet is corrupt */ +#define OC_NEWPACKET -25 /**< Packet is an (ignorable) unhandled extension */ +#define OC_DUPFRAME 1 /**< Packet is a dropped frame */ + +/** + * Retrieve a human-readable string to identify the encoder vendor and version. + * \returns A version string. + */ +extern const char *theora_version_string(void); + +/** + * Retrieve a 32-bit version number. + * This number is composed of a 16-bit major version, 8-bit minor version + * and 8 bit sub-version, composed as follows: +<pre> + (VERSION_MAJOR<<16) + (VERSION_MINOR<<8) + (VERSION_SUB) +</pre> +* \returns The version number. +*/ +extern ogg_uint32_t theora_version_number(void); + +/** + * Initialize the theora encoder. + * \param th The theora_state handle to initialize for encoding. + * \param ti A theora_info struct filled with the desired encoding parameters. + * \retval 0 Success + */ +extern int theora_encode_init(theora_state *th, theora_info *ti); + +/** + * Submit a YUV buffer to the theora encoder. + * \param t A theora_state handle previously initialized for encoding. + * \param yuv A buffer of YUV data to encode. Note that both the yuv_buffer + * struct and the luma/chroma buffers within should be allocated by + * the user. + * \retval OC_EINVAL Encoder is not ready, or is finished. + * \retval -1 The size of the given frame differs from those previously input + * \retval 0 Success + */ +extern int theora_encode_YUVin(theora_state *t, yuv_buffer *yuv); + +/** + * Request the next packet of encoded video. + * The encoded data is placed in a user-provided ogg_packet structure. + * \param t A theora_state handle previously initialized for encoding. + * \param last_p whether this is the last packet the encoder should produce. + * \param op An ogg_packet structure to fill. libtheora will set all + * elements of this structure, including a pointer to encoded + * data. The memory for the encoded data is owned by libtheora. + * \retval 0 No internal storage exists OR no packet is ready + * \retval -1 The encoding process has completed + * \retval 1 Success + */ +extern int theora_encode_packetout( theora_state *t, int last_p, + ogg_packet *op); + +/** + * Request a packet containing the initial header. + * A pointer to the header data is placed in a user-provided ogg_packet + * structure. + * \param t A theora_state handle previously initialized for encoding. + * \param op An ogg_packet structure to fill. libtheora will set all + * elements of this structure, including a pointer to the header + * data. The memory for the header data is owned by libtheora. + * \retval 0 Success + */ +extern int theora_encode_header(theora_state *t, ogg_packet *op); + +/** + * Request a comment header packet from provided metadata. + * A pointer to the comment data is placed in a user-provided ogg_packet + * structure. + * \param tc A theora_comment structure filled with the desired metadata + * \param op An ogg_packet structure to fill. libtheora will set all + * elements of this structure, including a pointer to the encoded + * comment data. The memory for the comment data is owned by + * the application, and must be freed by it using _ogg_free(). + * On some systems (such as Windows when using dynamic linking), this + * may mean the free is executed in a different module from the + * malloc, which will crash; there is no way to free this memory on + * such systems. + * \retval 0 Success + */ +extern int theora_encode_comment(theora_comment *tc, ogg_packet *op); + +/** + * Request a packet containing the codebook tables for the stream. + * A pointer to the codebook data is placed in a user-provided ogg_packet + * structure. + * \param t A theora_state handle previously initialized for encoding. + * \param op An ogg_packet structure to fill. libtheora will set all + * elements of this structure, including a pointer to the codebook + * data. The memory for the header data is owned by libtheora. + * \retval 0 Success + */ +extern int theora_encode_tables(theora_state *t, ogg_packet *op); + +/** + * Decode an Ogg packet, with the expectation that the packet contains + * an initial header, comment data or codebook tables. + * + * \param ci A theora_info structure to fill. This must have been previously + * initialized with theora_info_init(). If \a op contains an initial + * header, theora_decode_header() will fill \a ci with the + * parsed header values. If \a op contains codebook tables, + * theora_decode_header() will parse these and attach an internal + * representation to \a ci->codec_setup. + * \param cc A theora_comment structure to fill. If \a op contains comment + * data, theora_decode_header() will fill \a cc with the parsed + * comments. + * \param op An ogg_packet structure which you expect contains an initial + * header, comment data or codebook tables. + * + * \retval OC_BADHEADER \a op is NULL; OR the first byte of \a op->packet + * has the signature of an initial packet, but op is + * not a b_o_s packet; OR this packet has the signature + * of an initial header packet, but an initial header + * packet has already been seen; OR this packet has the + * signature of a comment packet, but the initial header + * has not yet been seen; OR this packet has the signature + * of a comment packet, but contains invalid data; OR + * this packet has the signature of codebook tables, + * but the initial header or comments have not yet + * been seen; OR this packet has the signature of codebook + * tables, but contains invalid data; + * OR the stream being decoded has a compatible version + * but this packet does not have the signature of a + * theora initial header, comments, or codebook packet + * \retval OC_VERSION The packet data of \a op is an initial header with + * a version which is incompatible with this version of + * libtheora. + * \retval OC_NEWPACKET the stream being decoded has an incompatible (future) + * version and contains an unknown signature. + * \retval 0 Success + * + * \note The normal usage is that theora_decode_header() be called on the + * first three packets of a theora logical bitstream in succession. + */ +extern int theora_decode_header(theora_info *ci, theora_comment *cc, + ogg_packet *op); + +/** + * Initialize a theora_state handle for decoding. + * \param th The theora_state handle to initialize. + * \param c A theora_info struct filled with the desired decoding parameters. + * This is of course usually obtained from a previous call to + * theora_decode_header(). + * \retval 0 Success + */ +extern int theora_decode_init(theora_state *th, theora_info *c); + +/** + * Input a packet containing encoded data into the theora decoder. + * \param th A theora_state handle previously initialized for decoding. + * \param op An ogg_packet containing encoded theora data. + * \retval 0 Success + * \retval OC_BADPACKET \a op does not contain encoded video data + */ +extern int theora_decode_packetin(theora_state *th,ogg_packet *op); + +/** + * Output the next available frame of decoded YUV data. + * \param th A theora_state handle previously initialized for decoding. + * \param yuv A yuv_buffer in which libtheora should place the decoded data. + * Note that the buffer struct itself is allocated by the user, but + * that the luma and chroma pointers will be filled in by the + * library. Also note that these luma and chroma regions should be + * considered read-only by the user. + * \retval 0 Success + */ +extern int theora_decode_YUVout(theora_state *th,yuv_buffer *yuv); + +/** + * Report whether a theora packet is a header or not + * This function does no verification beyond checking the header + * flag bit so it should not be used for bitstream identification; + * use theora_decode_header() for that. + * + * \param op An ogg_packet containing encoded theora data. + * \retval 1 The packet is a header packet + * \retval 0 The packet is not a header packet (and so contains frame data) + * + * Thus function was added in the 1.0alpha4 release. + */ +extern int theora_packet_isheader(ogg_packet *op); + +/** + * Report whether a theora packet is a keyframe or not + * + * \param op An ogg_packet containing encoded theora data. + * \retval 1 The packet contains a keyframe image + * \retval 0 The packet is contains an interframe delta + * \retval -1 The packet is not an image data packet at all + * + * Thus function was added in the 1.0alpha4 release. + */ +extern int theora_packet_iskeyframe(ogg_packet *op); + +/** + * Report the granulepos shift radix + * + * When embedded in Ogg, Theora uses a two-part granulepos, + * splitting the 64-bit field into two pieces. The more-significant + * section represents the frame count at the last keyframe, + * and the less-significant section represents the count of + * frames since the last keyframe. In this way the overall + * field is still non-decreasing with time, but usefully encodes + * a pointer to the last keyframe, which is necessary for + * correctly restarting decode after a seek. + * + * This function reports the number of bits used to represent + * the distance to the last keyframe, and thus how the granulepos + * field must be shifted or masked to obtain the two parts. + * + * Since libtheora returns compressed data in an ogg_packet + * structure, this may be generally useful even if the Theora + * packets are not being used in an Ogg container. + * + * \param ti A previously initialized theora_info struct + * \returns The bit shift dividing the two granulepos fields + * + * This function was added in the 1.0alpha5 release. + */ +int theora_granule_shift(theora_info *ti); + +/** + * Convert a granulepos to an absolute frame index, starting at 0. + * The granulepos is interpreted in the context of a given theora_state handle. + * + * Note that while the granulepos encodes the frame count (i.e. starting + * from 1) this call returns the frame index, starting from zero. Thus + * One can calculate the presentation time by multiplying the index by + * the rate. + * + * \param th A previously initialized theora_state handle (encode or decode) + * \param granulepos The granulepos to convert. + * \returns The frame index corresponding to \a granulepos. + * \retval -1 The given granulepos is undefined (i.e. negative) + * + * Thus function was added in the 1.0alpha4 release. + */ +extern ogg_int64_t theora_granule_frame(theora_state *th,ogg_int64_t granulepos); + +/** + * Convert a granulepos to absolute time in seconds. The granulepos is + * interpreted in the context of a given theora_state handle, and gives + * the end time of a frame's presentation as used in Ogg mux ordering. + * + * \param th A previously initialized theora_state handle (encode or decode) + * \param granulepos The granulepos to convert. + * \returns The absolute time in seconds corresponding to \a granulepos. + * This is the "end time" for the frame, or the latest time it should + * be displayed. + * It is not the presentation time. + * \retval -1. The given granulepos is undefined (i.e. negative). + */ +extern double theora_granule_time(theora_state *th,ogg_int64_t granulepos); + +/** + * Initialize a theora_info structure. All values within the given theora_info + * structure are initialized, and space is allocated within libtheora for + * internal codec setup data. + * \param c A theora_info struct to initialize. + */ +extern void theora_info_init(theora_info *c); + +/** + * Clear a theora_info structure. All values within the given theora_info + * structure are cleared, and associated internal codec setup data is freed. + * \param c A theora_info struct to initialize. + */ +extern void theora_info_clear(theora_info *c); + +/** + * Free all internal data associated with a theora_state handle. + * \param t A theora_state handle. + */ +extern void theora_clear(theora_state *t); + +/** + * Initialize an allocated theora_comment structure + * \param tc An allocated theora_comment structure + **/ +extern void theora_comment_init(theora_comment *tc); + +/** + * Add a comment to an initialized theora_comment structure + * \param tc A previously initialized theora comment structure + * \param comment A null-terminated string encoding the comment in the form + * "TAG=the value" + * + * Neither theora_comment_add() nor theora_comment_add_tag() support + * comments containing null values, although the bitstream format + * supports this. To add such comments you will need to manipulate + * the theora_comment structure directly. + **/ + +extern void theora_comment_add(theora_comment *tc, char *comment); + +/** + * Add a comment to an initialized theora_comment structure. + * \param tc A previously initialized theora comment structure + * \param tag A null-terminated string containing the tag + * associated with the comment. + * \param value The corresponding value as a null-terminated string + * + * Neither theora_comment_add() nor theora_comment_add_tag() support + * comments containing null values, although the bitstream format + * supports this. To add such comments you will need to manipulate + * the theora_comment structure directly. + **/ +extern void theora_comment_add_tag(theora_comment *tc, + char *tag, char *value); + +/** + * Look up a comment value by tag. + * \param tc Tn initialized theora_comment structure + * \param tag The tag to look up + * \param count The instance of the tag. The same tag can appear multiple + * times, each with a distinct and ordered value, so an index + * is required to retrieve them all. + * \returns A pointer to the queried tag's value + * \retval NULL No matching tag is found + * + * \note Use theora_comment_query_count() to get the legal range for the + * count parameter. + **/ + +extern char *theora_comment_query(theora_comment *tc, char *tag, int count); + +/** Look up the number of instances of a tag. + * \param tc An initialized theora_comment structure + * \param tag The tag to look up + * \returns The number on instances of a particular tag. + * + * Call this first when querying for a specific tag and then interate + * over the number of instances with separate calls to + * theora_comment_query() to retrieve all instances in order. + **/ +extern int theora_comment_query_count(theora_comment *tc, char *tag); + +/** + * Clear an allocated theora_comment struct so that it can be freed. + * \param tc An allocated theora_comment structure. + **/ +extern void theora_comment_clear(theora_comment *tc); + +/**Encoder control function. + * This is used to provide advanced control the encoding process. + * \param th A #theora_state handle. + * \param req The control code to process. + * See \ref encctlcodes_old "the list of available + * control codes" for details. + * \param buf The parameters for this control code. + * \param buf_sz The size of the parameter buffer.*/ +extern int theora_control(theora_state *th,int req,void *buf,size_t buf_sz); + +/* @} */ /* end oldfuncs doxygen group */ + +#ifdef __cplusplus +} +#endif /* __cplusplus */ + +#endif /* _O_THEORA_H_ */ diff --git a/media/libtheora/include/theora/theoradec.h b/media/libtheora/include/theora/theoradec.h new file mode 100644 index 0000000000..77bef81909 --- /dev/null +++ b/media/libtheora/include/theora/theoradec.h @@ -0,0 +1,333 @@ +/******************************************************************** + * * + * THIS FILE IS PART OF THE OggTheora SOFTWARE CODEC SOURCE CODE. * + * USE, DISTRIBUTION AND REPRODUCTION OF THIS LIBRARY SOURCE IS * + * GOVERNED BY A BSD-STYLE SOURCE LICENSE INCLUDED WITH THIS SOURCE * + * IN 'COPYING'. PLEASE READ THESE TERMS BEFORE DISTRIBUTING. * + * * + * THE Theora SOURCE CODE IS COPYRIGHT (C) 2002-2009 * + * by the Xiph.Org Foundation http://www.xiph.org/ * + * * + ******************************************************************** + + function: + last mod: $Id: theora.h,v 1.8 2004/03/15 22:17:32 derf Exp $ + + ********************************************************************/ + +/**\file + * The <tt>libtheoradec</tt> C decoding API.*/ + +#if !defined(_O_THEORA_THEORADEC_H_) +# define _O_THEORA_THEORADEC_H_ (1) +# include <stddef.h> +# include <ogg/ogg.h> +# include "codec.h" + +#if defined(__cplusplus) +extern "C" { +#endif + + + +/**\name th_decode_ctl() codes + * \anchor decctlcodes + * These are the available request codes for th_decode_ctl(). + * By convention, these are odd, to distinguish them from the + * \ref encctlcodes "encoder control codes". + * Keep any experimental or vendor-specific values above \c 0x8000.*/ +/*@{*/ +/**Gets the maximum post-processing level. + * The decoder supports a post-processing filter that can improve + * the appearance of the decoded images. This returns the highest + * level setting for this post-processor, corresponding to maximum + * improvement and computational expense. + * + * \param[out] _buf int: The maximum post-processing level. + * \retval TH_EFAULT \a _dec_ctx or \a _buf is <tt>NULL</tt>. + * \retval TH_EINVAL \a _buf_sz is not <tt>sizeof(int)</tt>. + * \retval TH_EIMPL Not supported by this implementation.*/ +#define TH_DECCTL_GET_PPLEVEL_MAX (1) +/**Sets the post-processing level. + * By default, post-processing is disabled. + * + * Sets the level of post-processing to use when decoding the + * compressed stream. This must be a value between zero (off) + * and the maximum returned by TH_DECCTL_GET_PPLEVEL_MAX. + * + * \param[in] _buf int: The new post-processing level. + * 0 to disable; larger values use more CPU. + * \retval TH_EFAULT \a _dec_ctx or \a _buf is <tt>NULL</tt>. + * \retval TH_EINVAL \a _buf_sz is not <tt>sizeof(int)</tt>, or the + * post-processing level is out of bounds. + * The maximum post-processing level may be + * implementation-specific, and can be obtained via + * #TH_DECCTL_GET_PPLEVEL_MAX. + * \retval TH_EIMPL Not supported by this implementation.*/ +#define TH_DECCTL_SET_PPLEVEL (3) +/**Sets the granule position. + * Call this after a seek, before decoding the first frame, to ensure that the + * proper granule position is returned for all subsequent frames. + * If you track timestamps yourself and do not use the granule position + * returned by the decoder, then you need not call this function. + * + * \param[in] _buf <tt>ogg_int64_t</tt>: The granule position of the next + * frame. + * \retval TH_EFAULT \a _dec_ctx or \a _buf is <tt>NULL</tt>. + * \retval TH_EINVAL \a _buf_sz is not <tt>sizeof(ogg_int64_t)</tt>, or the + * granule position is negative.*/ +#define TH_DECCTL_SET_GRANPOS (5) +/**Sets the striped decode callback function. + * If set, this function will be called as each piece of a frame is fully + * decoded in th_decode_packetin(). + * You can pass in a #th_stripe_callback with + * th_stripe_callback#stripe_decoded set to <tt>NULL</tt> to disable the + * callbacks at any point. + * Enabling striped decode does not prevent you from calling + * th_decode_ycbcr_out() after the frame is fully decoded. + * + * \param[in] _buf #th_stripe_callback: The callback parameters. + * \retval TH_EFAULT \a _dec_ctx or \a _buf is <tt>NULL</tt>. + * \retval TH_EINVAL \a _buf_sz is not + * <tt>sizeof(th_stripe_callback)</tt>.*/ +#define TH_DECCTL_SET_STRIPE_CB (7) + +/**Sets the macroblock display mode. Set to 0 to disable displaying + * macroblocks.*/ +#define TH_DECCTL_SET_TELEMETRY_MBMODE (9) +/**Sets the motion vector display mode. Set to 0 to disable displaying motion + * vectors.*/ +#define TH_DECCTL_SET_TELEMETRY_MV (11) +/**Sets the adaptive quantization display mode. Set to 0 to disable displaying + * adaptive quantization. */ +#define TH_DECCTL_SET_TELEMETRY_QI (13) +/**Sets the bitstream breakdown visualization mode. Set to 0 to disable + * displaying bitstream breakdown.*/ +#define TH_DECCTL_SET_TELEMETRY_BITS (15) +/*@}*/ + + + +/**A callback function for striped decode. + * This is a function pointer to an application-provided function that will be + * called each time a section of the image is fully decoded in + * th_decode_packetin(). + * This allows the application to process the section immediately, while it is + * still in cache. + * Note that the frame is decoded bottom to top, so \a _yfrag0 will steadily + * decrease with each call until it reaches 0, at which point the full frame + * is decoded. + * The number of fragment rows made available in each call depends on the pixel + * format and the number of post-processing filters enabled, and may not even + * be constant for the entire frame. + * If a non-<tt>NULL</tt> \a _granpos pointer is passed to + * th_decode_packetin(), the granule position for the frame will be stored + * in it before the first callback is made. + * If an entire frame is dropped (a 0-byte packet), then no callbacks will be + * made at all for that frame. + * \param _ctx An application-provided context pointer. + * \param _buf The image buffer for the decoded frame. + * \param _yfrag0 The Y coordinate of the first row of 8x8 fragments + * decoded. + * Multiply this by 8 to obtain the pixel row number in the + * luma plane. + * If the chroma planes are subsampled in the Y direction, + * this will always be divisible by two. + * \param _yfrag_end The Y coordinate of the first row of 8x8 fragments past + * the newly decoded section. + * If the chroma planes are subsampled in the Y direction, + * this will always be divisible by two. + * I.e., this section contains fragment rows + * <tt>\a _yfrag0 ...\a _yfrag_end -1</tt>.*/ +typedef void (*th_stripe_decoded_func)(void *_ctx,th_ycbcr_buffer _buf, + int _yfrag0,int _yfrag_end); + +/**The striped decode callback data to pass to #TH_DECCTL_SET_STRIPE_CB.*/ +typedef struct{ + /**An application-provided context pointer. + * This will be passed back verbatim to the application.*/ + void *ctx; + /**The callback function pointer.*/ + th_stripe_decoded_func stripe_decoded; +}th_stripe_callback; + + + +/**\name Decoder state + The following data structures are opaque, and their contents are not + publicly defined by this API. + Referring to their internals directly is unsupported, and may break without + warning.*/ +/*@{*/ +/**The decoder context.*/ +typedef struct th_dec_ctx th_dec_ctx; +/**Setup information. + This contains auxiliary information (Huffman tables and quantization + parameters) decoded from the setup header by th_decode_headerin() to be + passed to th_decode_alloc(). + It can be re-used to initialize any number of decoders, and can be freed + via th_setup_free() at any time.*/ +typedef struct th_setup_info th_setup_info; +/*@}*/ + + + +/**\defgroup decfuncs Functions for Decoding*/ +/*@{*/ +/**\name Functions for decoding + * You must link to <tt>libtheoradec</tt> if you use any of the + * functions in this section. + * + * The functions are listed in the order they are used in a typical decode. + * The basic steps are: + * - Parse the header packets by repeatedly calling th_decode_headerin(). + * - Allocate a #th_dec_ctx handle with th_decode_alloc(). + * - Call th_setup_free() to free any memory used for codec setup + * information. + * - Perform any additional decoder configuration with th_decode_ctl(). + * - For each video data packet: + * - Submit the packet to the decoder via th_decode_packetin(). + * - Retrieve the uncompressed video data via th_decode_ycbcr_out(). + * - Call th_decode_free() to release all decoder memory.*/ +/*@{*/ +/**Decodes the header packets of a Theora stream. + * This should be called on the initial packets of the stream, in succession, + * until it returns <tt>0</tt>, indicating that all headers have been + * processed, or an error is encountered. + * At least three header packets are required, and additional optional header + * packets may follow. + * This can be used on the first packet of any logical stream to determine if + * that stream is a Theora stream. + * \param _info A #th_info structure to fill in. + * This must have been previously initialized with + * th_info_init(). + * The application may immediately begin using the contents of + * this structure after the first header is decoded, though it + * must continue to be passed in on all subsequent calls. + * \param _tc A #th_comment structure to fill in. + * The application may immediately begin using the contents of + * this structure after the second header is decoded, though it + * must continue to be passed in on all subsequent calls. + * \param _setup Returns a pointer to additional, private setup information + * needed by the decoder. + * The contents of this pointer must be initialized to + * <tt>NULL</tt> on the first call, and the returned value must + * continue to be passed in on all subsequent calls. + * \param _op An <tt>ogg_packet</tt> structure which contains one of the + * initial packets of an Ogg logical stream. + * \return A positive value indicates that a Theora header was successfully + * processed. + * \retval 0 The first video data packet was encountered after all + * required header packets were parsed. + * The packet just passed in on this call should be saved + * and fed to th_decode_packetin() to begin decoding + * video data. + * \retval TH_EFAULT One of \a _info, \a _tc, or \a _setup was + * <tt>NULL</tt>. + * \retval TH_EBADHEADER \a _op was <tt>NULL</tt>, the packet was not the next + * header packet in the expected sequence, or the format + * of the header data was invalid. + * \retval TH_EVERSION The packet data was a Theora info header, but for a + * bitstream version not decodable with this version of + * <tt>libtheoradec</tt>. + * \retval TH_ENOTFORMAT The packet was not a Theora header. + */ +extern int th_decode_headerin(th_info *_info,th_comment *_tc, + th_setup_info **_setup,ogg_packet *_op); +/**Allocates a decoder instance. + * + * <b>Security Warning:</b> The Theora format supports very large frame sizes, + * potentially even larger than the address space of a 32-bit machine, and + * creating a decoder context allocates the space for several frames of data. + * If the allocation fails here, your program will crash, possibly at some + * future point because the OS kernel returned a valid memory range and will + * only fail when it tries to map the pages in it the first time they are + * used. + * Even if it succeeds, you may experience a denial of service if the frame + * size is large enough to cause excessive paging. + * If you are integrating libtheora in a larger application where such things + * are undesirable, it is highly recommended that you check the frame size in + * \a _info before calling this function and refuse to decode streams where it + * is larger than some reasonable maximum. + * libtheora will not check this for you, because there may be machines that + * can handle such streams and applications that wish to. + * \param _info A #th_info struct filled via th_decode_headerin(). + * \param _setup A #th_setup_info handle returned via + * th_decode_headerin(). + * \return The initialized #th_dec_ctx handle. + * \retval NULL If the decoding parameters were invalid.*/ +extern th_dec_ctx *th_decode_alloc(const th_info *_info, + const th_setup_info *_setup); +/**Releases all storage used for the decoder setup information. + * This should be called after you no longer want to create any decoders for + * a stream whose headers you have parsed with th_decode_headerin(). + * \param _setup The setup information to free. + * This can safely be <tt>NULL</tt>.*/ +extern void th_setup_free(th_setup_info *_setup); +/**Decoder control function. + * This is used to provide advanced control of the decoding process. + * \param _dec A #th_dec_ctx handle. + * \param _req The control code to process. + * See \ref decctlcodes "the list of available control codes" + * for details. + * \param _buf The parameters for this control code. + * \param _buf_sz The size of the parameter buffer. + * \return Possible return values depend on the control code used. + * See \ref decctlcodes "the list of control codes" for + * specific values. Generally 0 indicates success.*/ +extern int th_decode_ctl(th_dec_ctx *_dec,int _req,void *_buf, + size_t _buf_sz); +/**Submits a packet containing encoded video data to the decoder. + * \param _dec A #th_dec_ctx handle. + * \param _op An <tt>ogg_packet</tt> containing encoded video data. + * \param _granpos Returns the granule position of the decoded packet. + * If non-<tt>NULL</tt>, the granule position for this specific + * packet is stored in this location. + * This is computed incrementally from previously decoded + * packets. + * After a seek, the correct granule position must be set via + * #TH_DECCTL_SET_GRANPOS for this to work properly. + * \retval 0 Success. + * A new decoded frame can be retrieved by calling + * th_decode_ycbcr_out(). + * \retval TH_DUPFRAME The packet represented a dropped frame (either a + * 0-byte frame or an INTER frame with no coded blocks). + * The player can skip the call to th_decode_ycbcr_out(), + * as the contents of the decoded frame buffer have not + * changed. + * \retval TH_EFAULT \a _dec or \a _op was <tt>NULL</tt>. + * \retval TH_EBADPACKET \a _op does not contain encoded video data. + * \retval TH_EIMPL The video data uses bitstream features which this + * library does not support.*/ +extern int th_decode_packetin(th_dec_ctx *_dec,const ogg_packet *_op, + ogg_int64_t *_granpos); +/**Outputs the next available frame of decoded Y'CbCr data. + * If a striped decode callback has been set with #TH_DECCTL_SET_STRIPE_CB, + * then the application does not need to call this function. + * \param _dec A #th_dec_ctx handle. + * \param _ycbcr A video buffer structure to fill in. + * <tt>libtheoradec</tt> will fill in all the members of this + * structure, including the pointers to the uncompressed video + * data. + * The memory for this video data is owned by + * <tt>libtheoradec</tt>. + * It may be freed or overwritten without notification when + * subsequent frames are decoded. + * \retval 0 Success + * \retval TH_EFAULT \a _dec or \a _ycbcr was <tt>NULL</tt>. + */ +extern int th_decode_ycbcr_out(th_dec_ctx *_dec, + th_ycbcr_buffer _ycbcr); +/**Frees an allocated decoder instance. + * \param _dec A #th_dec_ctx handle.*/ +extern void th_decode_free(th_dec_ctx *_dec); +/*@}*/ +/*@}*/ + + + +#if defined(__cplusplus) +} +#endif + +#endif diff --git a/media/libtheora/lib/arm/arm2gnu.pl b/media/libtheora/lib/arm/arm2gnu.pl new file mode 100755 index 0000000000..d6fe09c4df --- /dev/null +++ b/media/libtheora/lib/arm/arm2gnu.pl @@ -0,0 +1,306 @@ +#!/usr/bin/perl + +my $bigend; # little/big endian +my $nxstack; + +$nxstack = 0; + +eval 'exec /usr/local/bin/perl -S $0 ${1+"$@"}' + if $running_under_some_shell; + +while ($ARGV[0] =~ /^-/) { + $_ = shift; + last if /^--/; + if (/^-n/) { + $nflag++; + next; + } + die "I don't recognize this switch: $_\\n"; +} +$printit++ unless $nflag; + +$\ = "\n"; # automatically add newline on print +$n=0; + +$thumb = 0; # ARM mode by default, not Thumb. +@proc_stack = (); + +printf (" .syntax unified\n"); + +LINE: +while (<>) { + + # For ADRLs we need to add a new line after the substituted one. + $addPadding = 0; + + # First, we do not dare to touch *anything* inside double quotes, do we? + # Second, if you want a dollar character in the string, + # insert two of them -- that's how ARM C and assembler treat strings. + s/^([A-Za-z_]\w*)[ \t]+DCB[ \t]*\"/$1: .ascii \"/ && do { s/\$\$/\$/g; next }; + s/\bDCB\b[ \t]*\"/.ascii \"/ && do { s/\$\$/\$/g; next }; + s/^(\S+)\s+RN\s+(\S+)/$1 .req r$2/ && do { s/\$\$/\$/g; next }; + # If there's nothing on a line but a comment, don't try to apply any further + # substitutions (this is a cheap hack to avoid mucking up the license header) + s/^([ \t]*);/$1@/ && do { s/\$\$/\$/g; next }; + # If substituted -- leave immediately ! + + s/@/,:/; + s/;/@/; + while ( /@.*'/ ) { + s/(@.*)'/$1/g; + } + s/\{FALSE\}/0/g; + s/\{TRUE\}/1/g; + s/\{(\w\w\w\w+)\}/$1/g; + s/\bINCLUDE[ \t]*([^ \t\n]+)/.include \"$1\"/; + s/\bGET[ \t]*([^ \t\n]+)/.include \"${ my $x=$1; $x =~ s|\.s|-gnu.S|; \$x }\"/; + s/\bIMPORT\b/.extern/; + s/\bEXPORT\b/.global/; + s/^(\s+)\[/$1IF/; + s/^(\s+)\|/$1ELSE/; + s/^(\s+)\]/$1ENDIF/; + s/IF *:DEF:/ .ifdef/; + s/IF *:LNOT: *:DEF:/ .ifndef/; + s/ELSE/ .else/; + s/ENDIF/ .endif/; + + if( /\bIF\b/ ) { + s/\bIF\b/ .if/; + s/=/==/; + } + if ( $n == 2) { + s/\$/\\/g; + } + if ($n == 1) { + s/\$//g; + s/label//g; + $n = 2; + } + if ( /MACRO/ ) { + s/MACRO *\n/.macro/; + $n=1; + } + if ( /\bMEND\b/ ) { + s/\bMEND\b/.endm/; + $n=0; + } + + # ".rdata" doesn't work in 'as' version 2.13.2, as it is ".rodata" there. + # + if ( /\bAREA\b/ ) { + my $align; + $align = "2"; + if ( /ALIGN=(\d+)/ ) { + $align = $1; + } + if ( /CODE/ ) { + $nxstack = 1; + } + s/^(.+)CODE(.+)READONLY(.*)/ .text/; + s/^(.+)DATA(.+)READONLY(.*)/ .section .rdata/; + s/^(.+)\|\|\.data\|\|(.+)/ .data/; + s/^(.+)\|\|\.bss\|\|(.+)/ .bss/; + s/$/; .p2align $align/; + } + + s/\|\|\.constdata\$(\d+)\|\|/.L_CONST$1/; # ||.constdata$3|| + s/\|\|\.bss\$(\d+)\|\|/.L_BSS$1/; # ||.bss$2|| + s/\|\|\.data\$(\d+)\|\|/.L_DATA$1/; # ||.data$2|| + s/\|\|([a-zA-Z0-9_]+)\@([a-zA-Z0-9_]+)\|\|/@ $&/; + s/^(\s+)\%(\s)/ .space $1/; + + s/\|(.+)\.(\d+)\|/\.$1_$2/; # |L80.123| -> .L80_123 + s/\bCODE32\b/.code 32/ && do {$thumb = 0}; + s/\bCODE16\b/.code 16/ && do {$thumb = 1}; + if (/\bPROC\b/) + { + my $prefix; + my $proc; + /^([A-Za-z_\.]\w+)\b/; + $proc = $1; + $prefix = ""; + if ($proc) + { + $prefix = $prefix.sprintf("\t.type\t%s, %%function; ",$proc); + push(@proc_stack, $proc); + s/^[A-Za-z_\.]\w+/$&:/; + } + $prefix = $prefix."\t.thumb_func; " if ($thumb); + s/\bPROC\b/@ $&/; + $_ = $prefix.$_; + } + s/^(\s*)(S|Q|SH|U|UQ|UH)ASX\b/$1$2ADDSUBX/; + s/^(\s*)(S|Q|SH|U|UQ|UH)SAX\b/$1$2SUBADDX/; + if (/\bENDP\b/) + { + my $proc; + s/\bENDP\b/@ $&/; + $proc = pop(@proc_stack); + $_ = "\t.size $proc, .-$proc".$_ if ($proc); + } + s/\bSUBT\b/@ $&/; + s/\bDATA\b/@ $&/; # DATA directive is deprecated -- Asm guide, p.7-25 + s/\bKEEP\b/@ $&/; + s/\bEXPORTAS\b/@ $&/; + s/\|\|(.)+\bEQU\b/@ $&/; + s/\|\|([\w\$]+)\|\|/$1/; + s/\bENTRY\b/@ $&/; + s/\bASSERT\b/@ $&/; + s/\bGBLL\b/@ $&/; + s/\bGBLA\b/@ $&/; + s/^\W+OPT\b/@ $&/; + s/:OR:/|/g; + s/:SHL:/<</g; + s/:SHR:/>>/g; + s/:AND:/&/g; + s/:LAND:/&&/g; + s/CPSR/cpsr/; + s/SPSR/spsr/; + s/ALIGN$/.balign 4/; + s/ALIGN\s+([0-9x]+)$/.balign $1/; + s/psr_cxsf/psr_all/; + s/LTORG/.ltorg/; + s/^([A-Za-z_]\w*)[ \t]+EQU/ .set $1,/; + s/^([A-Za-z_]\w*)[ \t]+SETL/ .set $1,/; + s/^([A-Za-z_]\w*)[ \t]+SETA/ .set $1,/; + s/^([A-Za-z_]\w*)[ \t]+\*/ .set $1,/; + + # {PC} + 0xdeadfeed --> . + 0xdeadfeed + s/\{PC\} \+/ \. +/; + + # Single hex constant on the line ! + # + # >>> NOTE <<< + # Double-precision floats in gcc are always mixed-endian, which means + # bytes in two words are little-endian, but words are big-endian. + # So, 0x0000deadfeed0000 would be stored as 0x0000dead at low address + # and 0xfeed0000 at high address. + # + s/\bDCFD\b[ \t]+0x([a-fA-F0-9]{8})([a-fA-F0-9]{8})/.long 0x$1, 0x$2/; + # Only decimal constants on the line, no hex ! + s/\bDCFD\b[ \t]+([0-9\.\-]+)/.double $1/; + + # Single hex constant on the line ! +# s/\bDCFS\b[ \t]+0x([a-f0-9]{8})([a-f0-9]{8})/.long 0x$1, 0x$2/; + # Only decimal constants on the line, no hex ! +# s/\bDCFS\b[ \t]+([0-9\.\-]+)/.double $1/; + s/\bDCFS[ \t]+0x/.word 0x/; + s/\bDCFS\b/.float/; + + s/^([A-Za-z_]\w*)[ \t]+DCD/$1 .word/; + s/\bDCD\b/.word/; + s/^([A-Za-z_]\w*)[ \t]+DCW/$1 .short/; + s/\bDCW\b/.short/; + s/^([A-Za-z_]\w*)[ \t]+DCB/$1 .byte/; + s/\bDCB\b/.byte/; + s/^([A-Za-z_]\w*)[ \t]+\%/.comm $1,/; + s/^[A-Za-z_\.]\w+/$&:/; + s/^(\d+)/$1:/; + s/\%(\d+)/$1b_or_f/; + s/\%[Bb](\d+)/$1b/; + s/\%[Ff](\d+)/$1f/; + s/\%[Ff][Tt](\d+)/$1f/; + s/&([\dA-Fa-f]+)/0x$1/; + if ( /\b2_[01]+\b/ ) { + s/\b2_([01]+)\b/conv$1&&&&/g; + while ( /[01][01][01][01]&&&&/ ) { + s/0000&&&&/&&&&0/g; + s/0001&&&&/&&&&1/g; + s/0010&&&&/&&&&2/g; + s/0011&&&&/&&&&3/g; + s/0100&&&&/&&&&4/g; + s/0101&&&&/&&&&5/g; + s/0110&&&&/&&&&6/g; + s/0111&&&&/&&&&7/g; + s/1000&&&&/&&&&8/g; + s/1001&&&&/&&&&9/g; + s/1010&&&&/&&&&A/g; + s/1011&&&&/&&&&B/g; + s/1100&&&&/&&&&C/g; + s/1101&&&&/&&&&D/g; + s/1110&&&&/&&&&E/g; + s/1111&&&&/&&&&F/g; + } + s/000&&&&/&&&&0/g; + s/001&&&&/&&&&1/g; + s/010&&&&/&&&&2/g; + s/011&&&&/&&&&3/g; + s/100&&&&/&&&&4/g; + s/101&&&&/&&&&5/g; + s/110&&&&/&&&&6/g; + s/111&&&&/&&&&7/g; + s/00&&&&/&&&&0/g; + s/01&&&&/&&&&1/g; + s/10&&&&/&&&&2/g; + s/11&&&&/&&&&3/g; + s/0&&&&/&&&&0/g; + s/1&&&&/&&&&1/g; + s/conv&&&&/0x/g; + } + + if ( /commandline/) + { + if( /-bigend/) + { + $bigend=1; + } + } + + if ( /\bDCDU\b/ ) + { + my $cmd=$_; + my $value; + my $prefix; + my $w1; + my $w2; + my $w3; + my $w4; + + s/\s+DCDU\b/@ $&/; + + $cmd =~ /\bDCDU\b\s+0x(\d+)/; + $value = $1; + $value =~ /(\w\w)(\w\w)(\w\w)(\w\w)/; + $w1 = $1; + $w2 = $2; + $w3 = $3; + $w4 = $4; + + if( $bigend ne "") + { + # big endian + $prefix = "\t.byte\t0x".$w1.";". + "\t.byte\t0x".$w2.";". + "\t.byte\t0x".$w3.";". + "\t.byte\t0x".$w4."; "; + } + else + { + # little endian + $prefix = "\t.byte\t0x".$w4.";". + "\t.byte\t0x".$w3.";". + "\t.byte\t0x".$w2.";". + "\t.byte\t0x".$w1."; "; + } + $_=$prefix.$_; + } + + if ( /\badrl\b/i ) + { + s/\badrl\s+(\w+)\s*,\s*(\w+)/ldr $1,=$2/i; + $addPadding = 1; + } + s/\bEND\b/@ END/; +} continue { + printf ("%s", $_) if $printit; + if ($addPadding != 0) + { + printf (" mov r0,r0\n"); + $addPadding = 0; + } +} +#If we had a code section, mark that this object doesn't need an executable +# stack. +if ($nxstack) { + printf (" .section\t.note.GNU-stack,\"\",\%\%progbits\n"); +} diff --git a/media/libtheora/lib/arm/armbits.h b/media/libtheora/lib/arm/armbits.h new file mode 100644 index 0000000000..1540d7eb57 --- /dev/null +++ b/media/libtheora/lib/arm/armbits.h @@ -0,0 +1,32 @@ +/******************************************************************** + * * + * THIS FILE IS PART OF THE OggTheora SOFTWARE CODEC SOURCE CODE. * + * USE, DISTRIBUTION AND REPRODUCTION OF THIS LIBRARY SOURCE IS * + * GOVERNED BY A BSD-STYLE SOURCE LICENSE INCLUDED WITH THIS SOURCE * + * IN 'COPYING'. PLEASE READ THESE TERMS BEFORE DISTRIBUTING. * + * * + * THE Theora SOURCE CODE IS COPYRIGHT (C) 2002-2010 * + * by the Xiph.Org Foundation and contributors http://www.xiph.org/ * + * * + ******************************************************************** + + function: + last mod: $Id: x86int.h 17344 2010-07-21 01:42:18Z tterribe $ + + ********************************************************************/ +#if !defined(_arm_armbits_H) +# define _arm_armbits_H (1) +# include "../bitpack.h" +# include "armcpu.h" + +# if defined(OC_ARM_ASM) +# define oc_pack_read oc_pack_read_arm +# define oc_pack_read1 oc_pack_read1_arm +# define oc_huff_token_decode oc_huff_token_decode_arm +# endif + +long oc_pack_read_arm(oc_pack_buf *_b,int _bits); +int oc_pack_read1_arm(oc_pack_buf *_b); +int oc_huff_token_decode_arm(oc_pack_buf *_b,const ogg_int16_t *_tree); + +#endif diff --git a/media/libtheora/lib/arm/armbits.s b/media/libtheora/lib/arm/armbits.s new file mode 100644 index 0000000000..fd6e4440cc --- /dev/null +++ b/media/libtheora/lib/arm/armbits.s @@ -0,0 +1,230 @@ +;******************************************************************** +;* * +;* THIS FILE IS PART OF THE OggTheora SOFTWARE CODEC SOURCE CODE. * +;* USE, DISTRIBUTION AND REPRODUCTION OF THIS LIBRARY SOURCE IS * +;* GOVERNED BY A BSD-STYLE SOURCE LICENSE INCLUDED WITH THIS SOURCE * +;* IN 'COPYING'. PLEASE READ THESE TERMS BEFORE DISTRIBUTING. * +;* * +;* THE Theora SOURCE CODE IS COPYRIGHT (C) 2002-2010 * +;* by the Xiph.Org Foundation and contributors http://www.xiph.org/ * +;* * +;******************************************************************** +; +; function: +; last mod: $Id$ +; +;******************************************************************** + + AREA |.text|, CODE, READONLY + + EXPORT oc_pack_read_arm + EXPORT oc_pack_read1_arm + EXPORT oc_huff_token_decode_arm + +oc_pack_read1_arm PROC + ; r0 = oc_pack_buf *_b + ADD r12,r0,#8 + LDMIA r12,{r2,r3} ; r2 = window + ; Stall... ; r3 = available + ; Stall... + SUBS r3,r3,#1 ; r3 = available-1, available<1 => LT + BLT oc_pack_read1_refill + MOV r0,r2,LSR #31 ; r0 = window>>31 + MOV r2,r2,LSL #1 ; r2 = window<<=1 + STMIA r12,{r2,r3} ; window = r2 + ; available = r3 + MOV PC,r14 + ENDP + +oc_pack_read_arm PROC + ; r0 = oc_pack_buf *_b + ; r1 = int _bits + ADD r12,r0,#8 + LDMIA r12,{r2,r3} ; r2 = window + ; Stall... ; r3 = available + ; Stall... + SUBS r3,r3,r1 ; r3 = available-_bits, available<_bits => LT + BLT oc_pack_read_refill + RSB r0,r1,#32 ; r0 = 32-_bits + MOV r0,r2,LSR r0 ; r0 = window>>32-_bits + MOV r2,r2,LSL r1 ; r2 = window<<=_bits + STMIA r12,{r2,r3} ; window = r2 + ; available = r3 + MOV PC,r14 + +; We need to refill window. +oc_pack_read1_refill + MOV r1,#1 +oc_pack_read_refill + STMFD r13!,{r10,r11,r14} + LDMIA r0,{r10,r11} ; r10 = stop + ; r11 = ptr + RSB r0,r1,#32 ; r0 = 32-_bits + RSB r3,r3,r0 ; r3 = 32-available +; We can use unsigned compares for both the pointers and for available +; (allowing us to chain condition codes) because available will never be +; larger than 32 (or we wouldn't be here), and thus 32-available will never be +; negative. + CMP r10,r11 ; ptr<stop => HI + CMPHI r3,#7 ; available<=24 => HI + LDRBHI r14,[r11],#1 ; r14 = *ptr++ + SUBHI r3,#8 ; available += 8 + ; (HI) Stall... + ORRHI r2,r2,r14,LSL r3 ; r2 = window|=r14<<32-available + CMPHI r10,r11 ; ptr<stop => HI + CMPHI r3,#7 ; available<=24 => HI + LDRBHI r14,[r11],#1 ; r14 = *ptr++ + SUBHI r3,#8 ; available += 8 + ; (HI) Stall... + ORRHI r2,r2,r14,LSL r3 ; r2 = window|=r14<<32-available + CMPHI r10,r11 ; ptr<stop => HI + CMPHI r3,#7 ; available<=24 => HI + LDRBHI r14,[r11],#1 ; r14 = *ptr++ + SUBHI r3,#8 ; available += 8 + ; (HI) Stall... + ORRHI r2,r2,r14,LSL r3 ; r2 = window|=r14<<32-available + CMPHI r10,r11 ; ptr<stop => HI + CMPHI r3,#7 ; available<=24 => HI + LDRBHI r14,[r11],#1 ; r14 = *ptr++ + SUBHI r3,#8 ; available += 8 + ; (HI) Stall... + ORRHI r2,r2,r14,LSL r3 ; r2 = window|=r14<<32-available + SUBS r3,r0,r3 ; r3 = available-=_bits, available<bits => GT + BLT oc_pack_read_refill_last + MOV r0,r2,LSR r0 ; r0 = window>>32-_bits + MOV r2,r2,LSL r1 ; r2 = window<<=_bits + STR r11,[r12,#-4] ; ptr = r11 + STMIA r12,{r2,r3} ; window = r2 + ; available = r3 + LDMFD r13!,{r10,r11,PC} + +; Either we wanted to read more than 24 bits and didn't have enough room to +; stuff the last byte into the window, or we hit the end of the packet. +oc_pack_read_refill_last + CMP r11,r10 ; ptr<stop => LO +; If we didn't hit the end of the packet, then pull enough of the next byte to +; to fill up the window. + LDRBLO r14,[r11] ; (LO) r14 = *ptr +; Otherwise, set the EOF flag and pretend we have lots of available bits. + MOVHS r14,#1 ; (HS) r14 = 1 + ADDLO r10,r3,r1 ; (LO) r10 = available + STRHS r14,[r12,#8] ; (HS) eof = 1 + ANDLO r10,r10,#7 ; (LO) r10 = available&7 + MOVHS r3,#1<<30 ; (HS) available = OC_LOTS_OF_BITS + ORRLO r2,r2,r14,LSL r10 ; (LO) r2 = window|=*ptr>>(available&7) + MOV r0,r2,LSR r0 ; r0 = window>>32-_bits + MOV r2,r2,LSL r1 ; r2 = window<<=_bits + STR r11,[r12,#-4] ; ptr = r11 + STMIA r12,{r2,r3} ; window = r2 + ; available = r3 + LDMFD r13!,{r10,r11,PC} + ENDP + + + +oc_huff_token_decode_arm PROC + ; r0 = oc_pack_buf *_b + ; r1 = const ogg_int16_t *_tree + STMFD r13!,{r4,r5,r10,r14} + LDRSH r10,[r1] ; r10 = n=_tree[0] + LDMIA r0,{r2-r5} ; r2 = stop + ; Stall... ; r3 = ptr + ; Stall... ; r4 = window + ; r5 = available + CMP r10,r5 ; n>available => GT + BGT oc_huff_token_decode_refill0 + RSB r14,r10,#32 ; r14 = 32-n + MOV r14,r4,LSR r14 ; r14 = bits=window>>32-n + ADD r14,r1,r14,LSL #1 ; r14 = _tree+bits + LDRSH r12,[r14,#2] ; r12 = node=_tree[1+bits] + ; Stall... + ; Stall... + RSBS r14,r12,#0 ; r14 = -node, node>0 => MI + BMI oc_huff_token_decode_continue + MOV r10,r14,LSR #8 ; r10 = n=node>>8 + MOV r4,r4,LSL r10 ; r4 = window<<=n + SUB r5,r10 ; r5 = available-=n + STMIB r0,{r3-r5} ; ptr = r3 + ; window = r4 + ; available = r5 + AND r0,r14,#255 ; r0 = node&255 + LDMFD r13!,{r4,r5,r10,pc} + +; The first tree node wasn't enough to reach a leaf, read another +oc_huff_token_decode_continue + ADD r12,r1,r12,LSL #1 ; r12 = _tree+node + MOV r4,r4,LSL r10 ; r4 = window<<=n + SUB r5,r5,r10 ; r5 = available-=n + LDRSH r10,[r12],#2 ; r10 = n=_tree[node] + ; Stall... ; r12 = _tree+node+1 + ; Stall... + CMP r10,r5 ; n>available => GT + BGT oc_huff_token_decode_refill + RSB r14,r10,#32 ; r14 = 32-n + MOV r14,r4,LSR r14 ; r14 = bits=window>>32-n + ADD r12,r12,r14 ; + LDRSH r12,[r12,r14] ; r12 = node=_tree[node+1+bits] + ; Stall... + ; Stall... + RSBS r14,r12,#0 ; r14 = -node, node>0 => MI + BMI oc_huff_token_decode_continue + MOV r10,r14,LSR #8 ; r10 = n=node>>8 + MOV r4,r4,LSL r10 ; r4 = window<<=n + SUB r5,r10 ; r5 = available-=n + STMIB r0,{r3-r5} ; ptr = r3 + ; window = r4 + ; available = r5 + AND r0,r14,#255 ; r0 = node&255 + LDMFD r13!,{r4,r5,r10,pc} + +oc_huff_token_decode_refill0 + ADD r12,r1,#2 ; r12 = _tree+1 +oc_huff_token_decode_refill +; We can't possibly need more than 15 bits, so available must be <= 15. +; Therefore we can load at least two bytes without checking it. + CMP r2,r3 ; ptr<stop => HI + LDRBHI r14,[r3],#1 ; r14 = *ptr++ + RSBHI r5,r5,#24 ; (HI) available = 32-(available+=8) + RSBLS r5,r5,#32 ; (LS) r5 = 32-available + ORRHI r4,r4,r14,LSL r5 ; r4 = window|=r14<<32-available + CMPHI r2,r3 ; ptr<stop => HI + LDRBHI r14,[r3],#1 ; r14 = *ptr++ + SUBHI r5,#8 ; available += 8 + ; (HI) Stall... + ORRHI r4,r4,r14,LSL r5 ; r4 = window|=r14<<32-available +; We can use unsigned compares for both the pointers and for available +; (allowing us to chain condition codes) because available will never be +; larger than 32 (or we wouldn't be here), and thus 32-available will never be +; negative. + CMPHI r2,r3 ; ptr<stop => HI + CMPHI r5,#7 ; available<=24 => HI + LDRBHI r14,[r3],#1 ; r14 = *ptr++ + SUBHI r5,#8 ; available += 8 + ; (HI) Stall... + ORRHI r4,r4,r14,LSL r5 ; r4 = window|=r14<<32-available + CMP r2,r3 ; ptr<stop => HI + MOVLS r5,#-1<<30 ; (LS) available = OC_LOTS_OF_BITS+32 + CMPHI r5,#7 ; (HI) available<=24 => HI + LDRBHI r14,[r3],#1 ; (HI) r14 = *ptr++ + SUBHI r5,#8 ; (HI) available += 8 + ; (HI) Stall... + ORRHI r4,r4,r14,LSL r5 ; (HI) r4 = window|=r14<<32-available + RSB r14,r10,#32 ; r14 = 32-n + MOV r14,r4,LSR r14 ; r14 = bits=window>>32-n + ADD r12,r12,r14 ; + LDRSH r12,[r12,r14] ; r12 = node=_tree[node+1+bits] + RSB r5,r5,#32 ; r5 = available + ; Stall... + RSBS r14,r12,#0 ; r14 = -node, node>0 => MI + BMI oc_huff_token_decode_continue + MOV r10,r14,LSR #8 ; r10 = n=node>>8 + MOV r4,r4,LSL r10 ; r4 = window<<=n + SUB r5,r10 ; r5 = available-=n + STMIB r0,{r3-r5} ; ptr = r3 + ; window = r4 + ; available = r5 + AND r0,r14,#255 ; r0 = node&255 + LDMFD r13!,{r4,r5,r10,pc} + ENDP + + END diff --git a/media/libtheora/lib/arm/armcpu.c b/media/libtheora/lib/arm/armcpu.c new file mode 100644 index 0000000000..f1941bdc15 --- /dev/null +++ b/media/libtheora/lib/arm/armcpu.c @@ -0,0 +1,154 @@ +/******************************************************************** + * * + * THIS FILE IS PART OF THE OggTheora SOFTWARE CODEC SOURCE CODE. * + * USE, DISTRIBUTION AND REPRODUCTION OF THIS LIBRARY SOURCE IS * + * GOVERNED BY A BSD-STYLE SOURCE LICENSE INCLUDED WITH THIS SOURCE * + * IN 'COPYING'. PLEASE READ THESE TERMS BEFORE DISTRIBUTING. * + * * + * THE Theora SOURCE CODE IS COPYRIGHT (C) 2002-2010 * + * by the Xiph.Org Foundation and contributors http://www.xiph.org/ * + * * + ******************************************************************** + + CPU capability detection for ARM processors. + + function: + last mod: $Id: cpu.c 17344 2010-07-21 01:42:18Z tterribe $ + + ********************************************************************/ + +#include "armcpu.h" + +#if !defined(OC_ARM_ASM)|| \ + !defined(OC_ARM_ASM_EDSP)&&!defined(OC_ARM_ASM_MEDIA)&& \ + !defined(OC_ARM_ASM_NEON) +ogg_uint32_t oc_cpu_flags_get(void){ + return 0; +} + +#elif defined(_MSC_VER) +/*For GetExceptionCode() and EXCEPTION_ILLEGAL_INSTRUCTION.*/ +# define WIN32_LEAN_AND_MEAN +# define WIN32_EXTRA_LEAN +# include <windows.h> + +ogg_uint32_t oc_cpu_flags_get(void){ + ogg_uint32_t flags; + flags=0; + /*MSVC has no inline __asm support for ARM, but it does let you __emit + instructions via their assembled hex code. + All of these instructions should be essentially nops.*/ +# if defined(OC_ARM_ASM_EDSP) + __try{ + /*PLD [r13]*/ + __emit(0xF5DDF000); + flags|=OC_CPU_ARM_EDSP; + } + __except(GetExceptionCode()==EXCEPTION_ILLEGAL_INSTRUCTION){ + /*Ignore exception.*/ + } +# if defined(OC_ARM_ASM_MEDIA) + __try{ + /*SHADD8 r3,r3,r3*/ + __emit(0xE6333F93); + flags|=OC_CPU_ARM_MEDIA; + } + __except(GetExceptionCode()==EXCEPTION_ILLEGAL_INSTRUCTION){ + /*Ignore exception.*/ + } +# if defined(OC_ARM_ASM_NEON) + __try{ + /*VORR q0,q0,q0*/ + __emit(0xF2200150); + flags|=OC_CPU_ARM_NEON; + } + __except(GetExceptionCode()==EXCEPTION_ILLEGAL_INSTRUCTION){ + /*Ignore exception.*/ + } +# endif +# endif +# endif + return flags; +} + +#elif defined(__linux__) +# include <stdio.h> +# include <stdlib.h> +# include <string.h> + +ogg_uint32_t oc_cpu_flags_get(void){ + ogg_uint32_t flags; + FILE *fin; + flags=0; + /*Reading /proc/self/auxv would be easier, but that doesn't work reliably on + Android. + This also means that detection will fail in Scratchbox.*/ + fin=fopen("/proc/cpuinfo","r"); + if(fin!=NULL){ + /*512 should be enough for anybody (it's even enough for all the flags that + x86 has accumulated... so far).*/ + char buf[512]; + while(fgets(buf,511,fin)!=NULL){ + if(memcmp(buf,"Features",8)==0){ + char *p; + p=strstr(buf," edsp"); + if(p!=NULL&&(p[5]==' '||p[5]=='\n'))flags|=OC_CPU_ARM_EDSP; + p=strstr(buf," neon"); + if(p!=NULL&&(p[5]==' '||p[5]=='\n'))flags|=OC_CPU_ARM_NEON; + } + if(memcmp(buf,"CPU architecture:",17)==0){ + int version; + version=atoi(buf+17); + if(version>=6)flags|=OC_CPU_ARM_MEDIA; + } + } + fclose(fin); + } + return flags; +} + +#elif defined(__riscos__) +#include <kernel.h> +#include <swis.h> + +ogg_uint32_t oc_cpu_flags_get(void) { + ogg_uint32_t flags = 0; + +#if defined(OC_ARM_ASM_EDSP) || defined(OC_ARM_ASM_MEDIA) + + if (_swi(OS_Byte,_IN(0)|_IN(2)|_RETURN(1), 129, 0xFF) <= 0xA9) + _swix(OS_Module, _INR(0,1), 1, "System:Modules.CallASWI"); + + ogg_uint32_t features; + _kernel_oserror* test = _swix(OS_PlatformFeatures, _IN(0)|_OUT(0), 0, &features); + if (test == NULL) { +#if defined(OC_ARM_ASM_EDSP) + if((features>>10 & 1) == 1)flags|=OC_CPU_ARM_EDSP; +#endif + +#if defined(OC_ARM_ASM_MEDIA) + if ((features>>31 & 1) == 1) { + ogg_uint32_t shadd = 0; + test =_swix(OS_PlatformFeatures, _INR(0,1)|_OUT(0), 34, 29, &shadd); + if (test==NULL && shadd==1)flags|=OC_CPU_ARM_MEDIA; + } +#endif + } +#endif + +#if defined(OC_ARM_ASM_NEON) + ogg_uint32_t mvfr1; + test = _swix(VFPSupport_Features, _IN(0)|_OUT(2), 0, &mvfr1); + if (test==NULL && (mvfr1 & 0xFFF00)==0x11100)flags|=OC_CPU_ARM_NEON; +#endif + + return flags; +} + +#else +/*The feature registers which can tell us what the processor supports are + accessible in priveleged modes only, so we can't have a general user-space + detection method like on x86.*/ +# error "Configured to use ARM asm but no CPU detection method available for " \ + "your platform. Reconfigure with --disable-asm (or send patches)." +#endif diff --git a/media/libtheora/lib/arm/armcpu.h b/media/libtheora/lib/arm/armcpu.h new file mode 100644 index 0000000000..18dd958210 --- /dev/null +++ b/media/libtheora/lib/arm/armcpu.h @@ -0,0 +1,29 @@ +/******************************************************************** + * * + * THIS FILE IS PART OF THE OggTheora SOFTWARE CODEC SOURCE CODE. * + * USE, DISTRIBUTION AND REPRODUCTION OF THIS LIBRARY SOURCE IS * + * GOVERNED BY A BSD-STYLE SOURCE LICENSE INCLUDED WITH THIS SOURCE * + * IN 'COPYING'. PLEASE READ THESE TERMS BEFORE DISTRIBUTING. * + * * + * THE Theora SOURCE CODE IS COPYRIGHT (C) 2002-2010 * + * by the Xiph.Org Foundation and contributors http://www.xiph.org/ * + * * + ******************************************************************** + function: + last mod: $Id: cpu.h 17344 2010-07-21 01:42:18Z tterribe $ + + ********************************************************************/ + +#if !defined(_arm_armcpu_H) +# define _arm_armcpu_H (1) +#include "../internal.h" + +/*"Parallel instructions" from ARM v6 and above.*/ +#define OC_CPU_ARM_MEDIA (1<<24) +/*Flags chosen to match arch/arm/include/asm/hwcap.h in the Linux kernel.*/ +#define OC_CPU_ARM_EDSP (1<<7) +#define OC_CPU_ARM_NEON (1<<12) + +ogg_uint32_t oc_cpu_flags_get(void); + +#endif diff --git a/media/libtheora/lib/arm/armfrag.s b/media/libtheora/lib/arm/armfrag.s new file mode 100644 index 0000000000..38ee77597c --- /dev/null +++ b/media/libtheora/lib/arm/armfrag.s @@ -0,0 +1,655 @@ +;******************************************************************** +;* * +;* THIS FILE IS PART OF THE OggTheora SOFTWARE CODEC SOURCE CODE. * +;* USE, DISTRIBUTION AND REPRODUCTION OF THIS LIBRARY SOURCE IS * +;* GOVERNED BY A BSD-STYLE SOURCE LICENSE INCLUDED WITH THIS SOURCE * +;* IN 'COPYING'. PLEASE READ THESE TERMS BEFORE DISTRIBUTING. * +;* * +;* THE Theora SOURCE CODE IS COPYRIGHT (C) 2002-2010 * +;* by the Xiph.Org Foundation and contributors http://www.xiph.org/ * +;* * +;******************************************************************** +; Original implementation: +; Copyright (C) 2009 Robin Watts for Pinknoise Productions Ltd +; last mod: $Id$ +;******************************************************************** + + AREA |.text|, CODE, READONLY + + GET armopts.s + +; Vanilla ARM v4 versions + EXPORT oc_frag_copy_list_arm + EXPORT oc_frag_recon_intra_arm + EXPORT oc_frag_recon_inter_arm + EXPORT oc_frag_recon_inter2_arm + +oc_frag_copy_list_arm PROC + ; r0 = _dst_frame + ; r1 = _src_frame + ; r2 = _ystride + ; r3 = _fragis + ; <> = _nfragis + ; <> = _frag_buf_offs + LDR r12,[r13] ; r12 = _nfragis + STMFD r13!,{r4-r6,r11,r14} + SUBS r12, r12, #1 + LDR r4,[r3],#4 ; r4 = _fragis[fragii] + LDRGE r14,[r13,#4*6] ; r14 = _frag_buf_offs + BLT ofcl_arm_end + SUB r2, r2, #4 +ofcl_arm_lp + LDR r11,[r14,r4,LSL #2] ; r11 = _frag_buf_offs[_fragis[fragii]] + SUBS r12, r12, #1 + ; Stall (on XScale) + ADD r4, r1, r11 ; r4 = _src_frame+frag_buf_off + LDR r6, [r4], #4 + ADD r11,r0, r11 ; r11 = _dst_frame+frag_buf_off + LDR r5, [r4], r2 + STR r6, [r11],#4 + LDR r6, [r4], #4 + STR r5, [r11],r2 + LDR r5, [r4], r2 + STR r6, [r11],#4 + LDR r6, [r4], #4 + STR r5, [r11],r2 + LDR r5, [r4], r2 + STR r6, [r11],#4 + LDR r6, [r4], #4 + STR r5, [r11],r2 + LDR r5, [r4], r2 + STR r6, [r11],#4 + LDR r6, [r4], #4 + STR r5, [r11],r2 + LDR r5, [r4], r2 + STR r6, [r11],#4 + LDR r6, [r4], #4 + STR r5, [r11],r2 + LDR r5, [r4], r2 + STR r6, [r11],#4 + LDR r6, [r4], #4 + STR r5, [r11],r2 + LDR r5, [r4], r2 + STR r6, [r11],#4 + LDR r6, [r4], #4 + STR r5, [r11],r2 + LDR r5, [r4] + LDRGE r4,[r3],#4 ; r4 = _fragis[fragii] + STR r6, [r11],#4 + STR r5, [r11] + BGE ofcl_arm_lp +ofcl_arm_end + LDMFD r13!,{r4-r6,r11,PC} +oc_frag_recon_intra_arm + ; r0 = unsigned char *_dst + ; r1 = int _ystride + ; r2 = const ogg_int16_t _residue[64] + STMFD r13!,{r4,r5,r14} + MOV r14,#8 + MOV r5, #255 + SUB r1, r1, #7 +ofrintra_lp_arm + LDRSH r3, [r2], #2 + LDRSH r4, [r2], #2 + LDRSH r12,[r2], #2 + ADDS r3, r3, #128 + CMPGT r5, r3 + EORLT r3, r5, r3, ASR #32 + STRB r3, [r0], #1 + ADDS r4, r4, #128 + CMPGT r5, r4 + EORLT r4, r5, r4, ASR #32 + LDRSH r3, [r2], #2 + STRB r4, [r0], #1 + ADDS r12,r12,#128 + CMPGT r5, r12 + EORLT r12,r5, r12,ASR #32 + LDRSH r4, [r2], #2 + STRB r12,[r0], #1 + ADDS r3, r3, #128 + CMPGT r5, r3 + EORLT r3, r5, r3, ASR #32 + LDRSH r12,[r2], #2 + STRB r3, [r0], #1 + ADDS r4, r4, #128 + CMPGT r5, r4 + EORLT r4, r5, r4, ASR #32 + LDRSH r3, [r2], #2 + STRB r4, [r0], #1 + ADDS r12,r12,#128 + CMPGT r5, r12 + EORLT r12,r5, r12,ASR #32 + LDRSH r4, [r2], #2 + STRB r12,[r0], #1 + ADDS r3, r3, #128 + CMPGT r5, r3 + EORLT r3, r5, r3, ASR #32 + STRB r3, [r0], #1 + ADDS r4, r4, #128 + CMPGT r5, r4 + EORLT r4, r5, r4, ASR #32 + STRB r4, [r0], r1 + SUBS r14,r14,#1 + BGT ofrintra_lp_arm + LDMFD r13!,{r4,r5,PC} + ENDP + +oc_frag_recon_inter_arm PROC + ; r0 = unsigned char *dst + ; r1 = const unsigned char *src + ; r2 = int ystride + ; r3 = const ogg_int16_t residue[64] + STMFD r13!,{r5,r9-r11,r14} + MOV r9, #8 + MOV r5, #255 + SUB r2, r2, #7 +ofrinter_lp_arm + LDRSH r12,[r3], #2 + LDRB r14,[r1], #1 + LDRSH r11,[r3], #2 + LDRB r10,[r1], #1 + ADDS r12,r12,r14 + CMPGT r5, r12 + EORLT r12,r5, r12,ASR #32 + STRB r12,[r0], #1 + ADDS r11,r11,r10 + CMPGT r5, r11 + LDRSH r12,[r3], #2 + LDRB r14,[r1], #1 + EORLT r11,r5, r11,ASR #32 + STRB r11,[r0], #1 + ADDS r12,r12,r14 + CMPGT r5, r12 + LDRSH r11,[r3], #2 + LDRB r10,[r1], #1 + EORLT r12,r5, r12,ASR #32 + STRB r12,[r0], #1 + ADDS r11,r11,r10 + CMPGT r5, r11 + LDRSH r12,[r3], #2 + LDRB r14,[r1], #1 + EORLT r11,r5, r11,ASR #32 + STRB r11,[r0], #1 + ADDS r12,r12,r14 + CMPGT r5, r12 + LDRSH r11,[r3], #2 + LDRB r10,[r1], #1 + EORLT r12,r5, r12,ASR #32 + STRB r12,[r0], #1 + ADDS r11,r11,r10 + CMPGT r5, r11 + LDRSH r12,[r3], #2 + LDRB r14,[r1], #1 + EORLT r11,r5, r11,ASR #32 + STRB r11,[r0], #1 + ADDS r12,r12,r14 + CMPGT r5, r12 + LDRSH r11,[r3], #2 + LDRB r10,[r1], r2 + EORLT r12,r5, r12,ASR #32 + STRB r12,[r0], #1 + ADDS r11,r11,r10 + CMPGT r5, r11 + EORLT r11,r5, r11,ASR #32 + STRB r11,[r0], r2 + SUBS r9, r9, #1 + BGT ofrinter_lp_arm + LDMFD r13!,{r5,r9-r11,PC} + ENDP + +oc_frag_recon_inter2_arm PROC + ; r0 = unsigned char *dst + ; r1 = const unsigned char *src1 + ; r2 = const unsigned char *src2 + ; r3 = int ystride + LDR r12,[r13] + ; r12= const ogg_int16_t residue[64] + STMFD r13!,{r4-r8,r14} + MOV r14,#8 + MOV r8, #255 + SUB r3, r3, #7 +ofrinter2_lp_arm + LDRB r5, [r1], #1 + LDRB r6, [r2], #1 + LDRSH r4, [r12],#2 + LDRB r7, [r1], #1 + ADD r5, r5, r6 + ADDS r5, r4, r5, LSR #1 + CMPGT r8, r5 + LDRB r6, [r2], #1 + LDRSH r4, [r12],#2 + EORLT r5, r8, r5, ASR #32 + STRB r5, [r0], #1 + ADD r7, r7, r6 + ADDS r7, r4, r7, LSR #1 + CMPGT r8, r7 + LDRB r5, [r1], #1 + LDRB r6, [r2], #1 + LDRSH r4, [r12],#2 + EORLT r7, r8, r7, ASR #32 + STRB r7, [r0], #1 + ADD r5, r5, r6 + ADDS r5, r4, r5, LSR #1 + CMPGT r8, r5 + LDRB r7, [r1], #1 + LDRB r6, [r2], #1 + LDRSH r4, [r12],#2 + EORLT r5, r8, r5, ASR #32 + STRB r5, [r0], #1 + ADD r7, r7, r6 + ADDS r7, r4, r7, LSR #1 + CMPGT r8, r7 + LDRB r5, [r1], #1 + LDRB r6, [r2], #1 + LDRSH r4, [r12],#2 + EORLT r7, r8, r7, ASR #32 + STRB r7, [r0], #1 + ADD r5, r5, r6 + ADDS r5, r4, r5, LSR #1 + CMPGT r8, r5 + LDRB r7, [r1], #1 + LDRB r6, [r2], #1 + LDRSH r4, [r12],#2 + EORLT r5, r8, r5, ASR #32 + STRB r5, [r0], #1 + ADD r7, r7, r6 + ADDS r7, r4, r7, LSR #1 + CMPGT r8, r7 + LDRB r5, [r1], #1 + LDRB r6, [r2], #1 + LDRSH r4, [r12],#2 + EORLT r7, r8, r7, ASR #32 + STRB r7, [r0], #1 + ADD r5, r5, r6 + ADDS r5, r4, r5, LSR #1 + CMPGT r8, r5 + LDRB r7, [r1], r3 + LDRB r6, [r2], r3 + LDRSH r4, [r12],#2 + EORLT r5, r8, r5, ASR #32 + STRB r5, [r0], #1 + ADD r7, r7, r6 + ADDS r7, r4, r7, LSR #1 + CMPGT r8, r7 + EORLT r7, r8, r7, ASR #32 + STRB r7, [r0], r3 + SUBS r14,r14,#1 + BGT ofrinter2_lp_arm + LDMFD r13!,{r4-r8,PC} + ENDP + + [ OC_ARM_ASM_EDSP + EXPORT oc_frag_copy_list_edsp + +oc_frag_copy_list_edsp PROC + ; r0 = _dst_frame + ; r1 = _src_frame + ; r2 = _ystride + ; r3 = _fragis + ; <> = _nfragis + ; <> = _frag_buf_offs + LDR r12,[r13] ; r12 = _nfragis + STMFD r13!,{r4-r11,r14} + SUBS r12, r12, #1 + LDRGE r5, [r3],#4 ; r5 = _fragis[fragii] + LDRGE r14,[r13,#4*10] ; r14 = _frag_buf_offs + BLT ofcl_edsp_end +ofcl_edsp_lp + MOV r4, r1 + LDR r5, [r14,r5, LSL #2] ; r5 = _frag_buf_offs[_fragis[fragii]] + SUBS r12, r12, #1 + ; Stall (on XScale) + LDRD r6, [r4, r5]! ; r4 = _src_frame+frag_buf_off + LDRD r8, [r4, r2]! + ; Stall + STRD r6, [r5, r0]! ; r5 = _dst_frame+frag_buf_off + STRD r8, [r5, r2]! + ; Stall + LDRD r6, [r4, r2]! ; On Xscale at least, doing 3 consecutive + LDRD r8, [r4, r2]! ; loads causes a stall, but that's no worse + LDRD r10,[r4, r2]! ; than us only doing 2, and having to do + ; another pair of LDRD/STRD later on. + ; Stall + STRD r6, [r5, r2]! + STRD r8, [r5, r2]! + STRD r10,[r5, r2]! + LDRD r6, [r4, r2]! + LDRD r8, [r4, r2]! + LDRD r10,[r4, r2]! + STRD r6, [r5, r2]! + STRD r8, [r5, r2]! + STRD r10,[r5, r2]! + LDRGE r5, [r3],#4 ; r5 = _fragis[fragii] + BGE ofcl_edsp_lp +ofcl_edsp_end + LDMFD r13!,{r4-r11,PC} + ENDP + ] + + [ OC_ARM_ASM_MEDIA + EXPORT oc_frag_recon_intra_v6 + EXPORT oc_frag_recon_inter_v6 + EXPORT oc_frag_recon_inter2_v6 + +oc_frag_recon_intra_v6 PROC + ; r0 = unsigned char *_dst + ; r1 = int _ystride + ; r2 = const ogg_int16_t _residue[64] + STMFD r13!,{r4-r6,r14} + MOV r14,#8 + MOV r12,r2 + LDR r6, =0x00800080 +ofrintra_v6_lp + LDRD r2, [r12],#8 ; r2 = 11110000 r3 = 33332222 + LDRD r4, [r12],#8 ; r4 = 55554444 r5 = 77776666 + SUBS r14,r14,#1 + QADD16 r2, r2, r6 + QADD16 r3, r3, r6 + QADD16 r4, r4, r6 + QADD16 r5, r5, r6 + USAT16 r2, #8, r2 ; r2 = __11__00 + USAT16 r3, #8, r3 ; r3 = __33__22 + USAT16 r4, #8, r4 ; r4 = __55__44 + USAT16 r5, #8, r5 ; r5 = __77__66 + ORR r2, r2, r2, LSR #8 ; r2 = __111100 + ORR r3, r3, r3, LSR #8 ; r3 = __333322 + ORR r4, r4, r4, LSR #8 ; r4 = __555544 + ORR r5, r5, r5, LSR #8 ; r5 = __777766 + PKHBT r2, r2, r3, LSL #16 ; r2 = 33221100 + PKHBT r3, r4, r5, LSL #16 ; r3 = 77665544 + STRD r2, r3, [r0], r1 + BGT ofrintra_v6_lp + LDMFD r13!,{r4-r6,PC} + ENDP + +oc_frag_recon_inter_v6 PROC + ; r0 = unsigned char *_dst + ; r1 = const unsigned char *_src + ; r2 = int _ystride + ; r3 = const ogg_int16_t _residue[64] + STMFD r13!,{r4-r7,r14} + MOV r14,#8 +ofrinter_v6_lp + LDRD r6, [r3], #8 ; r6 = 11110000 r7 = 33332222 + SUBS r14,r14,#1 + [ OC_ARM_CAN_UNALIGN_LDRD + LDRD r4, [r1], r2 ; Unaligned ; r4 = 33221100 r5 = 77665544 + | + LDR r5, [r1, #4] + LDR r4, [r1], r2 + ] + PKHBT r12,r6, r7, LSL #16 ; r12= 22220000 + PKHTB r7, r7, r6, ASR #16 ; r7 = 33331111 + UXTB16 r6,r4 ; r6 = __22__00 + UXTB16 r4,r4, ROR #8 ; r4 = __33__11 + QADD16 r12,r12,r6 ; r12= xx22xx00 + QADD16 r4, r7, r4 ; r4 = xx33xx11 + LDRD r6, [r3], #8 ; r6 = 55554444 r7 = 77776666 + USAT16 r4, #8, r4 ; r4 = __33__11 + USAT16 r12,#8,r12 ; r12= __22__00 + ORR r4, r12,r4, LSL #8 ; r4 = 33221100 + PKHBT r12,r6, r7, LSL #16 ; r12= 66664444 + PKHTB r7, r7, r6, ASR #16 ; r7 = 77775555 + UXTB16 r6,r5 ; r6 = __66__44 + UXTB16 r5,r5, ROR #8 ; r5 = __77__55 + QADD16 r12,r12,r6 ; r12= xx66xx44 + QADD16 r5, r7, r5 ; r5 = xx77xx55 + USAT16 r12,#8, r12 ; r12= __66__44 + USAT16 r5, #8, r5 ; r4 = __77__55 + ORR r5, r12,r5, LSL #8 ; r5 = 33221100 + STRD r4, r5, [r0], r2 + BGT ofrinter_v6_lp + LDMFD r13!,{r4-r7,PC} + ENDP + +oc_frag_recon_inter2_v6 PROC + ; r0 = unsigned char *_dst + ; r1 = const unsigned char *_src1 + ; r2 = const unsigned char *_src2 + ; r3 = int _ystride + LDR r12,[r13] + ; r12= const ogg_int16_t _residue[64] + STMFD r13!,{r4-r9,r14} + MOV r14,#8 +ofrinter2_v6_lp + LDRD r6, [r12,#8] ; r6 = 55554444 r7 = 77776666 + SUBS r14,r14,#1 + LDR r4, [r1, #4] ; Unaligned ; r4 = src1[1] = 77665544 + LDR r5, [r2, #4] ; Unaligned ; r5 = src2[1] = 77665544 + PKHBT r8, r6, r7, LSL #16 ; r8 = 66664444 + PKHTB r9, r7, r6, ASR #16 ; r9 = 77775555 + UHADD8 r4, r4, r5 ; r4 = (src1[7,6,5,4] + src2[7,6,5,4])>>1 + UXTB16 r5, r4 ; r5 = __66__44 + UXTB16 r4, r4, ROR #8 ; r4 = __77__55 + QADD16 r8, r8, r5 ; r8 = xx66xx44 + QADD16 r9, r9, r4 ; r9 = xx77xx55 + LDRD r6,[r12],#16 ; r6 = 33332222 r7 = 11110000 + USAT16 r8, #8, r8 ; r8 = __66__44 + LDR r4, [r1], r3 ; Unaligned ; r4 = src1[0] = 33221100 + USAT16 r9, #8, r9 ; r9 = __77__55 + LDR r5, [r2], r3 ; Unaligned ; r5 = src2[0] = 33221100 + ORR r9, r8, r9, LSL #8 ; r9 = 77665544 + PKHBT r8, r6, r7, LSL #16 ; r8 = 22220000 + UHADD8 r4, r4, r5 ; r4 = (src1[3,2,1,0] + src2[3,2,1,0])>>1 + PKHTB r7, r7, r6, ASR #16 ; r7 = 33331111 + UXTB16 r5, r4 ; r5 = __22__00 + UXTB16 r4, r4, ROR #8 ; r4 = __33__11 + QADD16 r8, r8, r5 ; r8 = xx22xx00 + QADD16 r7, r7, r4 ; r7 = xx33xx11 + USAT16 r8, #8, r8 ; r8 = __22__00 + USAT16 r7, #8, r7 ; r7 = __33__11 + ORR r8, r8, r7, LSL #8 ; r8 = 33221100 + STRD r8, r9, [r0], r3 + BGT ofrinter2_v6_lp + LDMFD r13!,{r4-r9,PC} + ENDP + ] + + [ OC_ARM_ASM_NEON + EXPORT oc_frag_copy_list_neon + EXPORT oc_frag_recon_intra_neon + EXPORT oc_frag_recon_inter_neon + EXPORT oc_frag_recon_inter2_neon + +oc_frag_copy_list_neon PROC + ; r0 = _dst_frame + ; r1 = _src_frame + ; r2 = _ystride + ; r3 = _fragis + ; <> = _nfragis + ; <> = _frag_buf_offs + LDR r12,[r13] ; r12 = _nfragis + STMFD r13!,{r4-r7,r14} + CMP r12, #1 + LDRGE r6, [r3] ; r6 = _fragis[fragii] + LDRGE r14,[r13,#4*6] ; r14 = _frag_buf_offs + BLT ofcl_neon_end + ; Stall (2 on Xscale) + LDR r6, [r14,r6, LSL #2] ; r6 = _frag_buf_offs[_fragis[fragii]] + ; Stall (on XScale) + MOV r7, r6 ; Guarantee PLD points somewhere valid. +ofcl_neon_lp + ADD r4, r1, r6 + VLD1.64 {D0}, [r4@64], r2 + ADD r5, r0, r6 + VLD1.64 {D1}, [r4@64], r2 + SUBS r12, r12, #1 + VLD1.64 {D2}, [r4@64], r2 + LDRGT r6, [r3,#4]! ; r6 = _fragis[fragii] + VLD1.64 {D3}, [r4@64], r2 + LDRGT r6, [r14,r6, LSL #2] ; r6 = _frag_buf_offs[_fragis[fragii]] + VLD1.64 {D4}, [r4@64], r2 + ADDGT r7, r1, r6 + VLD1.64 {D5}, [r4@64], r2 + PLD [r7] + VLD1.64 {D6}, [r4@64], r2 + PLD [r7, r2] + VLD1.64 {D7}, [r4@64] + PLD [r7, r2, LSL #1] + VST1.64 {D0}, [r5@64], r2 + ADDGT r7, r7, r2, LSL #2 + VST1.64 {D1}, [r5@64], r2 + PLD [r7, -r2] + VST1.64 {D2}, [r5@64], r2 + PLD [r7] + VST1.64 {D3}, [r5@64], r2 + PLD [r7, r2] + VST1.64 {D4}, [r5@64], r2 + PLD [r7, r2, LSL #1] + VST1.64 {D5}, [r5@64], r2 + ADDGT r7, r7, r2, LSL #2 + VST1.64 {D6}, [r5@64], r2 + PLD [r7, -r2] + VST1.64 {D7}, [r5@64] + BGT ofcl_neon_lp +ofcl_neon_end + LDMFD r13!,{r4-r7,PC} + ENDP + +oc_frag_recon_intra_neon PROC + ; r0 = unsigned char *_dst + ; r1 = int _ystride + ; r2 = const ogg_int16_t _residue[64] + VMOV.I16 Q0, #128 + VLDMIA r2, {D16-D31} ; D16= 3333222211110000 etc ; 9(8) cycles + VQADD.S16 Q8, Q8, Q0 + VQADD.S16 Q9, Q9, Q0 + VQADD.S16 Q10,Q10,Q0 + VQADD.S16 Q11,Q11,Q0 + VQADD.S16 Q12,Q12,Q0 + VQADD.S16 Q13,Q13,Q0 + VQADD.S16 Q14,Q14,Q0 + VQADD.S16 Q15,Q15,Q0 + VQMOVUN.S16 D16,Q8 ; D16= 7766554433221100 ; 1 cycle + VQMOVUN.S16 D17,Q9 ; D17= FFEEDDCCBBAA9988 ; 1 cycle + VQMOVUN.S16 D18,Q10 ; D18= NNMMLLKKJJIIHHGG ; 1 cycle + VST1.64 {D16},[r0@64], r1 + VQMOVUN.S16 D19,Q11 ; D19= VVUUTTSSRRQQPPOO ; 1 cycle + VST1.64 {D17},[r0@64], r1 + VQMOVUN.S16 D20,Q12 ; D20= ddccbbaaZZYYXXWW ; 1 cycle + VST1.64 {D18},[r0@64], r1 + VQMOVUN.S16 D21,Q13 ; D21= llkkjjiihhggffee ; 1 cycle + VST1.64 {D19},[r0@64], r1 + VQMOVUN.S16 D22,Q14 ; D22= ttssrrqqppoonnmm ; 1 cycle + VST1.64 {D20},[r0@64], r1 + VQMOVUN.S16 D23,Q15 ; D23= !!@@zzyyxxwwvvuu ; 1 cycle + VST1.64 {D21},[r0@64], r1 + VST1.64 {D22},[r0@64], r1 + VST1.64 {D23},[r0@64], r1 + MOV PC,R14 + ENDP + +oc_frag_recon_inter_neon PROC + ; r0 = unsigned char *_dst + ; r1 = const unsigned char *_src + ; r2 = int _ystride + ; r3 = const ogg_int16_t _residue[64] + VLDMIA r3, {D16-D31} ; D16= 3333222211110000 etc ; 9(8) cycles + VLD1.64 {D0}, [r1], r2 + VLD1.64 {D2}, [r1], r2 + VMOVL.U8 Q0, D0 ; Q0 = __77__66__55__44__33__22__11__00 + VLD1.64 {D4}, [r1], r2 + VMOVL.U8 Q1, D2 ; etc + VLD1.64 {D6}, [r1], r2 + VMOVL.U8 Q2, D4 + VMOVL.U8 Q3, D6 + VQADD.S16 Q8, Q8, Q0 + VLD1.64 {D0}, [r1], r2 + VQADD.S16 Q9, Q9, Q1 + VLD1.64 {D2}, [r1], r2 + VQADD.S16 Q10,Q10,Q2 + VLD1.64 {D4}, [r1], r2 + VQADD.S16 Q11,Q11,Q3 + VLD1.64 {D6}, [r1], r2 + VMOVL.U8 Q0, D0 + VMOVL.U8 Q1, D2 + VMOVL.U8 Q2, D4 + VMOVL.U8 Q3, D6 + VQADD.S16 Q12,Q12,Q0 + VQADD.S16 Q13,Q13,Q1 + VQADD.S16 Q14,Q14,Q2 + VQADD.S16 Q15,Q15,Q3 + VQMOVUN.S16 D16,Q8 + VQMOVUN.S16 D17,Q9 + VQMOVUN.S16 D18,Q10 + VST1.64 {D16},[r0@64], r2 + VQMOVUN.S16 D19,Q11 + VST1.64 {D17},[r0@64], r2 + VQMOVUN.S16 D20,Q12 + VST1.64 {D18},[r0@64], r2 + VQMOVUN.S16 D21,Q13 + VST1.64 {D19},[r0@64], r2 + VQMOVUN.S16 D22,Q14 + VST1.64 {D20},[r0@64], r2 + VQMOVUN.S16 D23,Q15 + VST1.64 {D21},[r0@64], r2 + VST1.64 {D22},[r0@64], r2 + VST1.64 {D23},[r0@64], r2 + MOV PC,R14 + ENDP + +oc_frag_recon_inter2_neon PROC + ; r0 = unsigned char *_dst + ; r1 = const unsigned char *_src1 + ; r2 = const unsigned char *_src2 + ; r3 = int _ystride + LDR r12,[r13] + ; r12= const ogg_int16_t _residue[64] + VLDMIA r12,{D16-D31} + VLD1.64 {D0}, [r1], r3 + VLD1.64 {D4}, [r2], r3 + VLD1.64 {D1}, [r1], r3 + VLD1.64 {D5}, [r2], r3 + VHADD.U8 Q2, Q0, Q2 ; Q2 = FFEEDDCCBBAA99887766554433221100 + VLD1.64 {D2}, [r1], r3 + VLD1.64 {D6}, [r2], r3 + VMOVL.U8 Q0, D4 ; Q0 = __77__66__55__44__33__22__11__00 + VLD1.64 {D3}, [r1], r3 + VMOVL.U8 Q2, D5 ; etc + VLD1.64 {D7}, [r2], r3 + VHADD.U8 Q3, Q1, Q3 + VQADD.S16 Q8, Q8, Q0 + VQADD.S16 Q9, Q9, Q2 + VLD1.64 {D0}, [r1], r3 + VMOVL.U8 Q1, D6 + VLD1.64 {D4}, [r2], r3 + VMOVL.U8 Q3, D7 + VLD1.64 {D1}, [r1], r3 + VQADD.S16 Q10,Q10,Q1 + VLD1.64 {D5}, [r2], r3 + VQADD.S16 Q11,Q11,Q3 + VLD1.64 {D2}, [r1], r3 + VHADD.U8 Q2, Q0, Q2 + VLD1.64 {D6}, [r2], r3 + VLD1.64 {D3}, [r1], r3 + VMOVL.U8 Q0, D4 + VLD1.64 {D7}, [r2], r3 + VMOVL.U8 Q2, D5 + VHADD.U8 Q3, Q1, Q3 + VQADD.S16 Q12,Q12,Q0 + VQADD.S16 Q13,Q13,Q2 + VMOVL.U8 Q1, D6 + VMOVL.U8 Q3, D7 + VQADD.S16 Q14,Q14,Q1 + VQADD.S16 Q15,Q15,Q3 + VQMOVUN.S16 D16,Q8 + VQMOVUN.S16 D17,Q9 + VQMOVUN.S16 D18,Q10 + VST1.64 {D16},[r0@64], r3 + VQMOVUN.S16 D19,Q11 + VST1.64 {D17},[r0@64], r3 + VQMOVUN.S16 D20,Q12 + VST1.64 {D18},[r0@64], r3 + VQMOVUN.S16 D21,Q13 + VST1.64 {D19},[r0@64], r3 + VQMOVUN.S16 D22,Q14 + VST1.64 {D20},[r0@64], r3 + VQMOVUN.S16 D23,Q15 + VST1.64 {D21},[r0@64], r3 + VST1.64 {D22},[r0@64], r3 + VST1.64 {D23},[r0@64], r3 + MOV PC,R14 + ENDP + ] + + END diff --git a/media/libtheora/lib/arm/armidct.s b/media/libtheora/lib/arm/armidct.s new file mode 100644 index 0000000000..269f74b8b1 --- /dev/null +++ b/media/libtheora/lib/arm/armidct.s @@ -0,0 +1,1853 @@ +;******************************************************************** +;* * +;* THIS FILE IS PART OF THE OggTheora SOFTWARE CODEC SOURCE CODE. * +;* USE, DISTRIBUTION AND REPRODUCTION OF THIS LIBRARY SOURCE IS * +;* GOVERNED BY A BSD-STYLE SOURCE LICENSE INCLUDED WITH THIS SOURCE * +;* IN 'COPYING'. PLEASE READ THESE TERMS BEFORE DISTRIBUTING. * +;* * +;* THE Theora SOURCE CODE IS COPYRIGHT (C) 2002-2010 * +;* by the Xiph.Org Foundation and contributors http://www.xiph.org/ * +;* * +;******************************************************************** +; Original implementation: +; Copyright (C) 2009 Robin Watts for Pinknoise Productions Ltd +; last mod: $Id$ +;******************************************************************** + + AREA |.text|, CODE, READONLY + + GET armopts.s + + EXPORT oc_idct8x8_1_arm + EXPORT oc_idct8x8_arm + +oc_idct8x8_1_arm PROC + ; r0 = ogg_int16_t *_y + ; r1 = ogg_uint16_t _dc + ORR r1, r1, r1, LSL #16 + MOV r2, r1 + MOV r3, r1 + MOV r12,r1 + STMIA r0!,{r1,r2,r3,r12} + STMIA r0!,{r1,r2,r3,r12} + STMIA r0!,{r1,r2,r3,r12} + STMIA r0!,{r1,r2,r3,r12} + STMIA r0!,{r1,r2,r3,r12} + STMIA r0!,{r1,r2,r3,r12} + STMIA r0!,{r1,r2,r3,r12} + STMIA r0!,{r1,r2,r3,r12} + MOV PC, r14 + ENDP + +oc_idct8x8_arm PROC + ; r0 = ogg_int16_t *_y + ; r1 = ogg_int16_t *_x + ; r2 = int _last_zzi + CMP r2, #3 + BLE oc_idct8x8_3_arm + CMP r2, #6 + BLE oc_idct8x8_6_arm + CMP r2, #10 + BLE oc_idct8x8_10_arm +oc_idct8x8_slow_arm + STMFD r13!,{r4-r11,r14} + SUB r13,r13,#64*2 +; Row transforms + STR r0, [r13,#-4]! + ADD r0, r13, #4 ; Write to temp storage. + BL idct8core_arm + BL idct8core_arm + BL idct8core_arm + BL idct8core_arm + BL idct8core_arm + BL idct8core_arm + BL idct8core_arm + BL idct8core_arm + LDR r0, [r13], #4 ; Write to the final destination. + SUB r2, r1, #8*16 + ; Clear input data for next block. + MOV r4, #0 + MOV r5, #0 + MOV r6, #0 + MOV r7, #0 + STMIA r2!,{r4,r5,r6,r7} + STMIA r2!,{r4,r5,r6,r7} + STMIA r2!,{r4,r5,r6,r7} + STMIA r2!,{r4,r5,r6,r7} + STMIA r2!,{r4,r5,r6,r7} + STMIA r2!,{r4,r5,r6,r7} + STMIA r2!,{r4,r5,r6,r7} + STMIA r2!,{r4,r5,r6,r7} + MOV r1, r13 ; And read from temp storage. +; Column transforms + BL idct8core_down_arm + BL idct8core_down_arm + BL idct8core_down_arm + BL idct8core_down_arm + BL idct8core_down_arm + BL idct8core_down_arm + BL idct8core_down_arm + BL idct8core_down_arm + ADD r13,r13,#64*2 + LDMFD r13!,{r4-r11,PC} + ENDP + +oc_idct8x8_10_arm PROC + STMFD r13!,{r4-r11,r14} + SUB r13,r13,#64*2 +; Row transforms + MOV r2, r0 + MOV r0, r13 ; Write to temp storage. + BL idct4core_arm + BL idct3core_arm + BL idct2core_arm + BL idct1core_arm + ; Clear input data for next block. + MOV r4, #0 + STR r4, [r1,#-4*16]! + STR r4, [r1,#4] + STR r4, [r1,#16] + STR r4, [r1,#20] + STR r4, [r1,#32] + STR r4, [r1,#48] + MOV r1, r13 ; Read from temp storage. + MOV r0, r2 ; Write to the final destination +oc_idct8x8_10_arm_cols +; Column transforms + BL idct4core_down_arm + BL idct4core_down_arm + BL idct4core_down_arm + BL idct4core_down_arm + BL idct4core_down_arm + BL idct4core_down_arm + BL idct4core_down_arm + BL idct4core_down_arm + ADD r13,r13,#64*2 + LDMFD r13!,{r4-r11,PC} + ENDP + +oc_idct8x8_6_arm PROC + STMFD r13!,{r4-r7,r9-r11,r14} + SUB r13,r13,#64*2 +; Row transforms + MOV r2, r0 + MOV r0, r13 ; Write to temp storage. + BL idct3core_arm + BL idct2core_arm + BL idct1core_arm + ; Clear input data for next block. + MOV r4, #0 + STR r4, [r1,#-3*16]! + STR r4, [r1,#4] + STR r4, [r1,#16] + STR r4, [r1,#32] + MOV r1, r13 ; Read from temp storage. + MOV r0, r2 ; Write to the final destination +; Column transforms + BL idct3core_down_arm + BL idct3core_down_arm + BL idct3core_down_arm + BL idct3core_down_arm + BL idct3core_down_arm + BL idct3core_down_arm + BL idct3core_down_arm + BL idct3core_down_arm + ADD r13,r13,#64*2 + LDMFD r13!,{r4-r7,r9-r11,PC} + ENDP + +oc_idct8x8_3_arm PROC + STMFD r13!,{r4-r7,r9-r11,r14} + SUB r13,r13,#64*2 +; Row transforms + MOV r2, r0 + MOV r0, r13 ; Write to temp storage. + BL idct2core_arm + BL idct1core_arm + ; Clear input data for next block. + MOV r4, #0 + STR r4, [r1,#-2*16]! + STR r4, [r1,#16] + MOV r1, r13 ; Read from temp storage. + MOV r0, r2 ; Write to the final destination +; Column transforms + BL idct2core_down_arm + BL idct2core_down_arm + BL idct2core_down_arm + BL idct2core_down_arm + BL idct2core_down_arm + BL idct2core_down_arm + BL idct2core_down_arm + BL idct2core_down_arm + ADD r13,r13,#64*2 + LDMFD r13!,{r4-r7,r9-r11,PC} + ENDP + +idct1core_arm PROC + ; r0 = ogg_int16_t *_y (destination) + ; r1 = const ogg_int16_t *_x (source) + LDRSH r3, [r1], #16 + MOV r12,#0x05 + ORR r12,r12,#0xB500 + MUL r3, r12, r3 + ; Stall ? + MOV r3, r3, ASR #16 + STRH r3, [r0], #2 + STRH r3, [r0, #14] + STRH r3, [r0, #30] + STRH r3, [r0, #46] + STRH r3, [r0, #62] + STRH r3, [r0, #78] + STRH r3, [r0, #94] + STRH r3, [r0, #110] + MOV PC,R14 + ENDP + +idct2core_arm PROC + ; r0 = ogg_int16_t *_y (destination) + ; r1 = const ogg_int16_t *_x (source) + LDRSH r9, [r1], #16 ; r9 = x[0] + LDR r12,OC_C4S4 + LDRSH r11,[r1, #-14] ; r11= x[1] + LDR r3, OC_C7S1 + MUL r9, r12,r9 ; r9 = t[0]<<16 = OC_C4S4*x[0] + LDR r10,OC_C1S7 + MUL r3, r11,r3 ; r3 = t[4]<<16 = OC_C7S1*x[1] + MOV r9, r9, ASR #16 ; r9 = t[0] + MUL r11,r10,r11 ; r11= t[7]<<16 = OC_C1S7*x[1] + MOV r3, r3, ASR #16 ; r3 = t[4] + MUL r10,r12,r3 ; r10= t[5]<<16 = OC_C4S4*t[4] + MOV r11,r11,ASR #16 ; r11= t[7] + MUL r12,r11,r12 ; r12= t[6]<<16 = OC_C4S4*t[7] + MOV r10,r10,ASR #16 ; r10= t[5] + ADD r12,r9,r12,ASR #16 ; r12= t[0]+t[6] + ADD r12,r12,r10 ; r12= t[0]+t2[6] = t[0]+t[6]+t[5] + SUB r10,r12,r10,LSL #1 ; r10= t[0]+t2[5] = t[0]+t[6]-t[5] + ADD r3, r3, r9 ; r3 = t[0]+t[4] + ADD r11,r11,r9 ; r11= t[0]+t[7] + STRH r11,[r0], #2 ; y[0] = t[0]+t[7] + STRH r12,[r0, #14] ; y[1] = t[0]+t[6] + STRH r10,[r0, #30] ; y[2] = t[0]+t[5] + STRH r3, [r0, #46] ; y[3] = t[0]+t[4] + RSB r3, r3, r9, LSL #1 ; r3 = t[0]*2-(t[0]+t[4])=t[0]-t[4] + RSB r10,r10,r9, LSL #1 ; r10= t[0]*2-(t[0]+t[5])=t[0]-t[5] + RSB r12,r12,r9, LSL #1 ; r12= t[0]*2-(t[0]+t[6])=t[0]-t[6] + RSB r11,r11,r9, LSL #1 ; r1 = t[0]*2-(t[0]+t[7])=t[0]-t[7] + STRH r3, [r0, #62] ; y[4] = t[0]-t[4] + STRH r10,[r0, #78] ; y[5] = t[0]-t[5] + STRH r12,[r0, #94] ; y[6] = t[0]-t[6] + STRH r11,[r0, #110] ; y[7] = t[0]-t[7] + MOV PC,r14 + ENDP + +idct2core_down_arm PROC + ; r0 = ogg_int16_t *_y (destination) + ; r1 = const ogg_int16_t *_x (source) + LDRSH r9, [r1], #16 ; r9 = x[0] + LDR r12,OC_C4S4 + LDRSH r11,[r1, #-14] ; r11= x[1] + LDR r3, OC_C7S1 + MUL r9, r12,r9 ; r9 = t[0]<<16 = OC_C4S4*x[0] + LDR r10,OC_C1S7 + MUL r3, r11,r3 ; r3 = t[4]<<16 = OC_C7S1*x[1] + MOV r9, r9, ASR #16 ; r9 = t[0] + MUL r11,r10,r11 ; r11= t[7]<<16 = OC_C1S7*x[1] + ADD r9, r9, #8 ; r9 = t[0]+8 + MOV r3, r3, ASR #16 ; r3 = t[4] + MUL r10,r12,r3 ; r10= t[5]<<16 = OC_C4S4*t[4] + MOV r11,r11,ASR #16 ; r11= t[7] + MUL r12,r11,r12 ; r12= t[6]<<16 = OC_C4S4*t[7] + MOV r10,r10,ASR #16 ; r10= t[5] + ADD r12,r9,r12,ASR #16 ; r12= t[0]+t[6]+8 + ADD r12,r12,r10 ; r12= t[0]+t2[6] = t[0]+t[6]+t[5]+8 + SUB r10,r12,r10,LSL #1 ; r10= t[0]+t2[5] = t[0]+t[6]-t[5]+8 + ADD r3, r3, r9 ; r3 = t[0]+t[4]+8 + ADD r11,r11,r9 ; r11= t[0]+t[7]+8 + ; TODO: This is wrong. + ; The C code truncates to 16 bits by storing to RAM and doing the + ; shifts later; we've got an extra 4 bits here. + MOV r4, r11,ASR #4 + MOV r5, r12,ASR #4 + MOV r6, r10,ASR #4 + MOV r7, r3, ASR #4 + RSB r3, r3, r9, LSL #1 ;r3 =t[0]*2+8-(t[0]+t[4])=t[0]-t[4]+8 + RSB r10,r10,r9, LSL #1 ;r10=t[0]*2+8-(t[0]+t[5])=t[0]-t[5]+8 + RSB r12,r12,r9, LSL #1 ;r12=t[0]*2+8-(t[0]+t[6])=t[0]-t[6]+8 + RSB r11,r11,r9, LSL #1 ;r11=t[0]*2+8-(t[0]+t[7])=t[0]-t[7]+8 + MOV r3, r3, ASR #4 + MOV r10,r10,ASR #4 + MOV r12,r12,ASR #4 + MOV r11,r11,ASR #4 + STRH r4, [r0], #2 ; y[0] = t[0]+t[7] + STRH r5, [r0, #14] ; y[1] = t[0]+t[6] + STRH r6, [r0, #30] ; y[2] = t[0]+t[5] + STRH r7, [r0, #46] ; y[3] = t[0]+t[4] + STRH r3, [r0, #62] ; y[4] = t[0]-t[4] + STRH r10,[r0, #78] ; y[5] = t[0]-t[5] + STRH r12,[r0, #94] ; y[6] = t[0]-t[6] + STRH r11,[r0, #110] ; y[7] = t[0]-t[7] + MOV PC,r14 + ENDP + +idct3core_arm PROC + LDRSH r9, [r1], #16 ; r9 = x[0] + LDR r12,OC_C4S4 ; r12= OC_C4S4 + LDRSH r3, [r1, #-12] ; r3 = x[2] + LDR r10,OC_C6S2 ; r10= OC_C6S2 + MUL r9, r12,r9 ; r9 = t[0]<<16 = OC_C4S4*x[0] + LDR r4, OC_C2S6 ; r4 = OC_C2S6 + MUL r10,r3, r10 ; r10= t[2]<<16 = OC_C6S2*x[2] + LDRSH r11,[r1, #-14] ; r11= x[1] + MUL r3, r4, r3 ; r3 = t[3]<<16 = OC_C2S6*x[2] + LDR r4, OC_C7S1 ; r4 = OC_C7S1 + LDR r5, OC_C1S7 ; r5 = OC_C1S7 + MOV r9, r9, ASR #16 ; r9 = t[0] + MUL r4, r11,r4 ; r4 = t[4]<<16 = OC_C7S1*x[1] + ADD r3, r9, r3, ASR #16 ; r3 = t[0]+t[3] + MUL r11,r5, r11 ; r11= t[7]<<16 = OC_C1S7*x[1] + MOV r4, r4, ASR #16 ; r4 = t[4] + MUL r5, r12,r4 ; r5 = t[5]<<16 = OC_C4S4*t[4] + MOV r11,r11,ASR #16 ; r11= t[7] + MUL r12,r11,r12 ; r12= t[6]<<16 = OC_C4S4*t[7] + ADD r10,r9, r10,ASR #16 ; r10= t[1] = t[0]+t[2] + RSB r6, r10,r9, LSL #1 ; r6 = t[2] = t[0]-t[2] + ; r3 = t2[0] = t[0]+t[3] + RSB r9, r3, r9, LSL #1 ; r9 = t2[3] = t[0]-t[3] + MOV r12,r12,ASR #16 ; r12= t[6] + ADD r5, r12,r5, ASR #16 ; r5 = t2[6] = t[6]+t[5] + RSB r12,r5, r12,LSL #1 ; r12= t2[5] = t[6]-t[5] + ADD r11,r3, r11 ; r11= t2[0]+t[7] + ADD r5, r10,r5 ; r5 = t[1]+t2[6] + ADD r12,r6, r12 ; r12= t[2]+t2[5] + ADD r4, r9, r4 ; r4 = t2[3]+t[4] + STRH r11,[r0], #2 ; y[0] = t[0]+t[7] + STRH r5, [r0, #14] ; y[1] = t[1]+t2[6] + STRH r12,[r0, #30] ; y[2] = t[2]+t2[5] + STRH r4, [r0, #46] ; y[3] = t2[3]+t[4] + RSB r11,r11,r3, LSL #1 ; r11= t2[0] - t[7] + RSB r5, r5, r10,LSL #1 ; r5 = t[1] - t2[6] + RSB r12,r12,r6, LSL #1 ; r6 = t[2] - t2[5] + RSB r4, r4, r9, LSL #1 ; r4 = t2[3] - t[4] + STRH r4, [r0, #62] ; y[4] = t2[3]-t[4] + STRH r12,[r0, #78] ; y[5] = t[2]-t2[5] + STRH r5, [r0, #94] ; y[6] = t[1]-t2[6] + STRH r11,[r0, #110] ; y[7] = t2[0]-t[7] + MOV PC,R14 + ENDP + +idct3core_down_arm PROC + LDRSH r9, [r1], #16 ; r9 = x[0] + LDR r12,OC_C4S4 ; r12= OC_C4S4 + LDRSH r3, [r1, #-12] ; r3 = x[2] + LDR r10,OC_C6S2 ; r10= OC_C6S2 + MUL r9, r12,r9 ; r9 = t[0]<<16 = OC_C4S4*x[0] + LDR r4, OC_C2S6 ; r4 = OC_C2S6 + MUL r10,r3, r10 ; r10= t[2]<<16 = OC_C6S2*x[2] + LDRSH r11,[r1, #-14] ; r11= x[1] + MUL r3, r4, r3 ; r3 = t[3]<<16 = OC_C2S6*x[2] + LDR r4, OC_C7S1 ; r4 = OC_C7S1 + LDR r5, OC_C1S7 ; r5 = OC_C1S7 + MOV r9, r9, ASR #16 ; r9 = t[0] + MUL r4, r11,r4 ; r4 = t[4]<<16 = OC_C7S1*x[1] + ADD r9, r9, #8 ; r9 = t[0]+8 + MUL r11,r5, r11 ; r11= t[7]<<16 = OC_C1S7*x[1] + ADD r3, r9, r3, ASR #16 ; r3 = t[0]+t[3]+8 + MOV r4, r4, ASR #16 ; r4 = t[4] + MUL r5, r12,r4 ; r5 = t[5]<<16 = OC_C4S4*t[4] + MOV r11,r11,ASR #16 ; r11= t[7] + MUL r12,r11,r12 ; r12= t[6]<<16 = OC_C4S4*t[7] + ADD r10,r9, r10,ASR #16 ; r10= t[1]+8 = t[0]+t[2]+8 + RSB r6, r10,r9, LSL #1 ; r6 = t[2]+8 = t[0]-t[2]+8 + ; r3 = t2[0]+8 = t[0]+t[3]+8 + RSB r9, r3, r9, LSL #1 ; r9 = t2[3]+8 = t[0]-t[3]+8 + MOV r12,r12,ASR #16 ; r12= t[6] + ADD r5, r12,r5, ASR #16 ; r5 = t2[6] = t[6]+t[5] + RSB r12,r5, r12,LSL #1 ; r12= t2[5] = t[6]-t[5] + ADD r11,r3, r11 ; r11= t2[0]+t[7] +8 + ADD r5, r10,r5 ; r5 = t[1] +t2[6]+8 + ADD r12,r6, r12 ; r12= t[2] +t2[5]+8 + ADD r4, r9, r4 ; r4 = t2[3]+t[4] +8 + RSB r3, r11,r3, LSL #1 ; r11= t2[0] - t[7] + 8 + RSB r10,r5, r10,LSL #1 ; r5 = t[1] - t2[6] + 8 + RSB r6, r12,r6, LSL #1 ; r6 = t[2] - t2[5] + 8 + RSB r9, r4, r9, LSL #1 ; r4 = t2[3] - t[4] + 8 + ; TODO: This is wrong. + ; The C code truncates to 16 bits by storing to RAM and doing the + ; shifts later; we've got an extra 4 bits here. + MOV r11,r11,ASR #4 + MOV r5, r5, ASR #4 + MOV r12,r12,ASR #4 + MOV r4, r4, ASR #4 + MOV r9, r9, ASR #4 + MOV r6, r6, ASR #4 + MOV r10,r10,ASR #4 + MOV r3, r3, ASR #4 + STRH r11,[r0], #2 ; y[0] = t[0]+t[7] + STRH r5, [r0, #14] ; y[1] = t[1]+t2[6] + STRH r12,[r0, #30] ; y[2] = t[2]+t2[5] + STRH r4, [r0, #46] ; y[3] = t2[3]+t[4] + STRH r9, [r0, #62] ; y[4] = t2[3]-t[4] + STRH r6, [r0, #78] ; y[5] = t[2]-t2[5] + STRH r10,[r0, #94] ; y[6] = t[1]-t2[6] + STRH r3, [r0, #110] ; y[7] = t2[0]-t[7] + MOV PC,R14 + ENDP + +idct4core_arm PROC + ; r0 = ogg_int16_t *_y (destination) + ; r1 = const ogg_int16_t *_x (source) + LDRSH r9, [r1], #16 ; r9 = x[0] + LDR r10,OC_C4S4 ; r10= OC_C4S4 + LDRSH r12,[r1, #-12] ; r12= x[2] + LDR r4, OC_C6S2 ; r4 = OC_C6S2 + MUL r9, r10,r9 ; r9 = t[0]<<16 = OC_C4S4*x[0] + LDR r5, OC_C2S6 ; r5 = OC_C2S6 + MUL r4, r12,r4 ; r4 = t[2]<<16 = OC_C6S2*x[2] + LDRSH r3, [r1, #-14] ; r3 = x[1] + MUL r5, r12,r5 ; r5 = t[3]<<16 = OC_C2S6*x[2] + LDR r6, OC_C7S1 ; r6 = OC_C7S1 + LDR r12,OC_C1S7 ; r12= OC_C1S7 + LDRSH r11,[r1, #-10] ; r11= x[3] + MUL r6, r3, r6 ; r6 = t[4]<<16 = OC_C7S1*x[1] + LDR r7, OC_C5S3 ; r7 = OC_C5S3 + MUL r3, r12,r3 ; r3 = t[7]<<16 = OC_C1S7*x[1] + LDR r8, OC_C3S5 ; r8 = OC_C3S5 + MUL r7, r11,r7 ; r7 = -t[5]<<16 = OC_C5S3*x[3] + MOV r9, r9, ASR #16 ; r9 = t[0] + MUL r11,r8, r11 ; r11= t[6]<<16 = OC_C3S5*x[3] + MOV r6, r6, ASR #16 ; r6 = t[4] +; TODO: This is wrong; t[4]-t[5] and t[7]-t[6] need to be truncated to 16-bit +; before multiplying, not after (this is not equivalent) + SUB r7, r6, r7, ASR #16 ; r7 = t2[4]=t[4]+t[5] (as r7=-t[5]) + RSB r6, r7, r6, LSL #1 ; r6 = t[4]-t[5] + MUL r6, r10,r6 ; r6 = t2[5]<<16 =OC_C4S4*(t[4]-t[5]) + MOV r3, r3, ASR #16 ; r3 = t[7] + ADD r11,r3, r11,ASR #16 ; r11= t2[7]=t[7]+t[6] + RSB r3, r11,r3, LSL #1 ; r3 = t[7]-t[6] + MUL r3, r10,r3 ; r3 = t2[6]<<16 =OC_C4S4*(t[7]-t[6]) + ADD r4, r9, r4, ASR #16 ; r4 = t[1] = t[0] + t[2] + RSB r10,r4, r9, LSL #1 ; r10= t[2] = t[0] - t[2] + ADD r5, r9, r5, ASR #16 ; r5 = t[0] = t[0] + t[3] + RSB r9, r5, r9, LSL #1 ; r9 = t[3] = t[0] - t[3] + MOV r3, r3, ASR #16 ; r3 = t2[6] + ADD r6, r3, r6, ASR #16 ; r6 = t3[6] = t2[6]+t2[5] + RSB r3, r6, r3, LSL #1 ; r3 = t3[5] = t2[6]-t2[5] + ADD r11,r5, r11 ; r11= t[0]+t2[7] + ADD r6, r4, r6 ; r6 = t[1]+t3[6] + ADD r3, r10,r3 ; r3 = t[2]+t3[5] + ADD r7, r9, r7 ; r7 = t[3]+t2[4] + STRH r11,[r0], #2 ; y[0] = t[0]+t[7] + STRH r6, [r0, #14] ; y[1] = t[1]+t2[6] + STRH r3, [r0, #30] ; y[2] = t[2]+t2[5] + STRH r7, [r0, #46] ; y[3] = t2[3]+t[4] + RSB r11,r11,r5, LSL #1 ; r11= t[0]-t2[7] + RSB r6, r6, r4, LSL #1 ; r6 = t[1]-t3[6] + RSB r3, r3, r10,LSL #1 ; r3 = t[2]-t3[5] + RSB r7, r7, r9, LSL #1 ; r7 = t[3]-t2[4] + STRH r7, [r0, #62] ; y[4] = t2[3]-t[4] + STRH r3, [r0, #78] ; y[5] = t[2]-t2[5] + STRH r6, [r0, #94] ; y[6] = t[1]-t2[6] + STRH r11, [r0, #110] ; y[7] = t2[0]-t[7] + MOV PC,r14 + ENDP + +idct4core_down_arm PROC + ; r0 = ogg_int16_t *_y (destination) + ; r1 = const ogg_int16_t *_x (source) + LDRSH r9, [r1], #16 ; r9 = x[0] + LDR r10,OC_C4S4 ; r10= OC_C4S4 + LDRSH r12,[r1, #-12] ; r12= x[2] + LDR r4, OC_C6S2 ; r4 = OC_C6S2 + MUL r9, r10,r9 ; r9 = t[0]<<16 = OC_C4S4*x[0] + LDR r5, OC_C2S6 ; r5 = OC_C2S6 + MUL r4, r12,r4 ; r4 = t[2]<<16 = OC_C6S2*x[2] + LDRSH r3, [r1, #-14] ; r3 = x[1] + MUL r5, r12,r5 ; r5 = t[3]<<16 = OC_C2S6*x[2] + LDR r6, OC_C7S1 ; r6 = OC_C7S1 + LDR r12,OC_C1S7 ; r12= OC_C1S7 + LDRSH r11,[r1, #-10] ; r11= x[3] + MUL r6, r3, r6 ; r6 = t[4]<<16 = OC_C7S1*x[1] + LDR r7, OC_C5S3 ; r7 = OC_C5S3 + MUL r3, r12,r3 ; r3 = t[7]<<16 = OC_C1S7*x[1] + LDR r8, OC_C3S5 ; r8 = OC_C3S5 + MUL r7, r11,r7 ; r7 = -t[5]<<16 = OC_C5S3*x[3] + MOV r9, r9, ASR #16 ; r9 = t[0] + MUL r11,r8, r11 ; r11= t[6]<<16 = OC_C3S5*x[3] + MOV r6, r6, ASR #16 ; r6 = t[4] +; TODO: This is wrong; t[4]-t[5] and t[7]-t[6] need to be truncated to 16-bit +; before multiplying, not after (this is not equivalent) + SUB r7, r6, r7, ASR #16 ; r7 = t2[4]=t[4]+t[5] (as r7=-t[5]) + RSB r6, r7, r6, LSL #1 ; r6 = t[4]-t[5] + MUL r6, r10,r6 ; r6 = t2[5]<<16 =OC_C4S4*(t[4]-t[5]) + MOV r3, r3, ASR #16 ; r3 = t[7] + ADD r11,r3, r11,ASR #16 ; r11= t2[7]=t[7]+t[6] + RSB r3, r11,r3, LSL #1 ; r3 = t[7]-t[6] + ADD r9, r9, #8 ; r9 = t[0]+8 + MUL r3, r10,r3 ; r3 = t2[6]<<16 =OC_C4S4*(t[7]-t[6]) + ADD r4, r9, r4, ASR #16 ; r4 = t[1] = t[0] + t[2] + 8 + RSB r10,r4, r9, LSL #1 ; r10= t[2] = t[0] - t[2] + 8 + ADD r5, r9, r5, ASR #16 ; r5 = t[0] = t[0] + t[3] + 8 + RSB r9, r5, r9, LSL #1 ; r9 = t[3] = t[0] - t[3] + 8 + MOV r3, r3, ASR #16 ; r3 = t2[6] + ADD r6, r3, r6, ASR #16 ; r6 = t3[6] = t2[6]+t2[5] + RSB r3, r6, r3, LSL #1 ; r3 = t3[5] = t2[6]-t2[5] + ADD r5, r5, r11 ; r5 = t[0]+t2[7]+8 + ADD r4, r4, r6 ; r4 = t[1]+t3[6]+8 + ADD r10,r10,r3 ; r10= t[2]+t3[5]+8 + ADD r9, r9, r7 ; r9 = t[3]+t2[4]+8 + SUB r11,r5, r11,LSL #1 ; r11= t[0]-t2[7]+8 + SUB r6, r4, r6, LSL #1 ; r6 = t[1]-t3[6]+8 + SUB r3, r10,r3, LSL #1 ; r3 = t[2]-t3[5]+8 + SUB r7, r9, r7, LSL #1 ; r7 = t[3]-t2[4]+8 + ; TODO: This is wrong. + ; The C code truncates to 16 bits by storing to RAM and doing the + ; shifts later; we've got an extra 4 bits here. + MOV r11,r11,ASR #4 + MOV r6, r6, ASR #4 + MOV r3, r3, ASR #4 + MOV r7, r7, ASR #4 + MOV r9, r9, ASR #4 + MOV r10,r10,ASR #4 + MOV r4, r4, ASR #4 + MOV r5, r5, ASR #4 + STRH r5,[r0], #2 ; y[0] = t[0]+t[7] + STRH r4, [r0, #14] ; y[1] = t[1]+t2[6] + STRH r10,[r0, #30] ; y[2] = t[2]+t2[5] + STRH r9, [r0, #46] ; y[3] = t2[3]+t[4] + STRH r7, [r0, #62] ; y[4] = t2[3]-t[4] + STRH r3, [r0, #78] ; y[5] = t[2]-t2[5] + STRH r6, [r0, #94] ; y[6] = t[1]-t2[6] + STRH r11,[r0, #110] ; y[7] = t2[0]-t[7] + MOV PC,r14 + ENDP + +idct8core_arm PROC + ; r0 = ogg_int16_t *_y (destination) + ; r1 = const ogg_int16_t *_x (source) + LDRSH r2, [r1],#16 ; r2 = x[0] + STMFD r13!,{r1,r14} + LDRSH r6, [r1, #-8] ; r6 = x[4] + LDR r12,OC_C4S4 ; r12= C4S4 + LDRSH r4, [r1, #-12] ; r4 = x[2] + ADD r2, r2, r6 ; r2 = x[0] + x[4] + SUB r6, r2, r6, LSL #1 ; r6 = x[0] - x[4] + ; For spec compliance, these sums must be truncated to 16-bit precision + ; _before_ the multiply (not after). + ; Sadly, ARMv4 provides no simple way to do that. + MOV r2, r2, LSL #16 + MOV r6, r6, LSL #16 + MOV r2, r2, ASR #16 + MOV r6, r6, ASR #16 + MUL r2, r12,r2 ; r2 = t[0]<<16 = C4S4*(x[0]+x[4]) + LDRSH r8, [r1, #-4] ; r8 = x[6] + LDR r7, OC_C6S2 ; r7 = OC_C6S2 + MUL r6, r12,r6 ; r6 = t[1]<<16 = C4S4*(x[0]-x[4]) + LDR r14,OC_C2S6 ; r14= OC_C2S6 + MUL r3, r4, r7 ; r3 = OC_C6S2*x[2] + LDR r5, OC_C7S1 ; r5 = OC_C7S1 + MUL r4, r14,r4 ; r4 = OC_C2S6*x[2] + MOV r3, r3, ASR #16 ; r3 = OC_C6S2*x[2]>>16 + MUL r14,r8, r14 ; r14= OC_C2S6*x[6] + MOV r4, r4, ASR #16 ; r4 = OC_C2S6*x[2]>>16 + MUL r8, r7, r8 ; r8 = OC_C6S2*x[6] + LDR r7, OC_C1S7 ; r7 = OC_C1S7 + SUB r3, r3, r14,ASR #16 ; r3=t[2]=C6S2*x[2]>>16-C2S6*x[6]>>16 + LDRSH r14,[r1, #-14] ; r14= x[1] + ADD r4, r4, r8, ASR #16 ; r4=t[3]=C2S6*x[2]>>16+C6S2*x[6]>>16 + LDRSH r8, [r1, #-2] ; r8 = x[7] + MUL r9, r5, r14 ; r9 = OC_C7S1*x[1] + LDRSH r10,[r1, #-6] ; r10= x[5] + MUL r14,r7, r14 ; r14= OC_C1S7*x[1] + MOV r9, r9, ASR #16 ; r9 = OC_C7S1*x[1]>>16 + MUL r7, r8, r7 ; r7 = OC_C1S7*x[7] + MOV r14,r14,ASR #16 ; r14= OC_C1S7*x[1]>>16 + MUL r8, r5, r8 ; r8 = OC_C7S1*x[7] + LDRSH r1, [r1, #-10] ; r1 = x[3] + LDR r5, OC_C3S5 ; r5 = OC_C3S5 + LDR r11,OC_C5S3 ; r11= OC_C5S3 + ADD r8, r14,r8, ASR #16 ; r8=t[7]=C1S7*x[1]>>16+C7S1*x[7]>>16 + MUL r14,r5, r10 ; r14= OC_C3S5*x[5] + SUB r9, r9, r7, ASR #16 ; r9=t[4]=C7S1*x[1]>>16-C1S7*x[7]>>16 + MUL r10,r11,r10 ; r10= OC_C5S3*x[5] + MOV r14,r14,ASR #16 ; r14= OC_C3S5*x[5]>>16 + MUL r11,r1, r11 ; r11= OC_C5S3*x[3] + MOV r10,r10,ASR #16 ; r10= OC_C5S3*x[5]>>16 + MUL r1, r5, r1 ; r1 = OC_C3S5*x[3] + SUB r14,r14,r11,ASR #16 ;r14=t[5]=C3S5*x[5]>>16-C5S3*x[3]>>16 + ADD r10,r10,r1, ASR #16 ;r10=t[6]=C5S3*x[5]>>16+C3S5*x[3]>>16 + ; r2=t[0]<<16 r3=t[2] r4=t[3] r6=t[1]<<16 r8=t[7] r9=t[4] + ; r10=t[6] r12=C4S4 r14=t[5] +; TODO: This is wrong; t[4]-t[5] and t[7]-t[6] need to be truncated to 16-bit +; before multiplying, not after (this is not equivalent) + ; Stage 2 + ; 4-5 butterfly + ADD r9, r9, r14 ; r9 = t2[4] = t[4]+t[5] + SUB r14,r9, r14, LSL #1 ; r14= t[4]-t[5] + MUL r14,r12,r14 ; r14= t2[5]<<16 = C4S4*(t[4]-t[5]) + ; 7-6 butterfly + ADD r8, r8, r10 ; r8 = t2[7] = t[7]+t[6] + SUB r10,r8, r10, LSL #1 ; r10= t[7]-t[6] + MUL r10,r12,r10 ; r10= t2[6]<<16 = C4S4*(t[7]+t[6]) + ; r2=t[0]<<16 r3=t[2] r4=t[3] r6=t[1]<<16 r8=t2[7] r9=t2[4] + ; r10=t2[6]<<16 r12=C4S4 r14=t2[5]<<16 + ; Stage 3 + ; 0-3 butterfly + ADD r2, r4, r2, ASR #16 ; r2 = t2[0] = t[0] + t[3] + SUB r4, r2, r4, LSL #1 ; r4 = t2[3] = t[0] - t[3] + ; 1-2 butterfly + ADD r6, r3, r6, ASR #16 ; r6 = t2[1] = t[1] + t[2] + SUB r3, r6, r3, LSL #1 ; r3 = t2[2] = t[1] - t[2] + ; 6-5 butterfly + MOV r14,r14,ASR #16 ; r14= t2[5] + ADD r10,r14,r10,ASR #16 ; r10= t3[6] = t[6] + t[5] + SUB r14,r10,r14,LSL #1 ; r14= t3[5] = t[6] - t[5] + ; r2=t2[0] r3=t2[2] r4=t2[3] r6=t2[1] r8=t2[7] r9=t2[4] + ; r10=t3[6] r14=t3[5] + ; Stage 4 + ADD r2, r2, r8 ; r2 = t[0] + t[7] + ADD r6, r6, r10 ; r6 = t[1] + t[6] + ADD r3, r3, r14 ; r3 = t[2] + t[5] + ADD r4, r4, r9 ; r4 = t[3] + t[4] + SUB r8, r2, r8, LSL #1 ; r8 = t[0] - t[7] + SUB r10,r6, r10,LSL #1 ; r10= t[1] - t[6] + SUB r14,r3, r14,LSL #1 ; r14= t[2] - t[5] + SUB r9, r4, r9, LSL #1 ; r9 = t[3] - t[4] + STRH r2, [r0], #2 ; y[0] = t[0]+t[7] + STRH r6, [r0, #14] ; y[1] = t[1]+t[6] + STRH r3, [r0, #30] ; y[2] = t[2]+t[5] + STRH r4, [r0, #46] ; y[3] = t[3]+t[4] + STRH r9, [r0, #62] ; y[4] = t[3]-t[4] + STRH r14,[r0, #78] ; y[5] = t[2]-t[5] + STRH r10,[r0, #94] ; y[6] = t[1]-t[6] + STRH r8, [r0, #110] ; y[7] = t[0]-t[7] + LDMFD r13!,{r1,PC} + ENDP + +idct8core_down_arm PROC + ; r0 = ogg_int16_t *_y (destination) + ; r1 = const ogg_int16_t *_x (source) + LDRSH r2, [r1],#16 ; r2 = x[0] + STMFD r13!,{r1,r14} + LDRSH r6, [r1, #-8] ; r6 = x[4] + LDR r12,OC_C4S4 ; r12= C4S4 + LDRSH r4, [r1, #-12] ; r4 = x[2] + ADD r2, r2, r6 ; r2 = x[0] + x[4] + SUB r6, r2, r6, LSL #1 ; r6 = x[0] - x[4] + ; For spec compliance, these sums must be truncated to 16-bit precision + ; _before_ the multiply (not after). + ; Sadly, ARMv4 provides no simple way to do that. + MOV r2, r2, LSL #16 + MOV r6, r6, LSL #16 + MOV r2, r2, ASR #16 + MOV r6, r6, ASR #16 + MUL r2, r12,r2 ; r2 = t[0]<<16 = C4S4*(x[0]+x[4]) + LDRSH r8, [r1, #-4] ; r8 = x[6] + LDR r7, OC_C6S2 ; r7 = OC_C6S2 + MUL r6, r12,r6 ; r6 = t[1]<<16 = C4S4*(x[0]-x[4]) + LDR r14,OC_C2S6 ; r14= OC_C2S6 + MUL r3, r4, r7 ; r3 = OC_C6S2*x[2] + LDR r5, OC_C7S1 ; r5 = OC_C7S1 + MUL r4, r14,r4 ; r4 = OC_C2S6*x[2] + MOV r3, r3, ASR #16 ; r3 = OC_C6S2*x[2]>>16 + MUL r14,r8, r14 ; r14= OC_C2S6*x[6] + MOV r4, r4, ASR #16 ; r4 = OC_C2S6*x[2]>>16 + MUL r8, r7, r8 ; r8 = OC_C6S2*x[6] + LDR r7, OC_C1S7 ; r7 = OC_C1S7 + SUB r3, r3, r14,ASR #16 ; r3=t[2]=C6S2*x[2]>>16-C2S6*x[6]>>16 + LDRSH r14,[r1, #-14] ; r14= x[1] + ADD r4, r4, r8, ASR #16 ; r4=t[3]=C2S6*x[2]>>16+C6S2*x[6]>>16 + LDRSH r8, [r1, #-2] ; r8 = x[7] + MUL r9, r5, r14 ; r9 = OC_C7S1*x[1] + LDRSH r10,[r1, #-6] ; r10= x[5] + MUL r14,r7, r14 ; r14= OC_C1S7*x[1] + MOV r9, r9, ASR #16 ; r9 = OC_C7S1*x[1]>>16 + MUL r7, r8, r7 ; r7 = OC_C1S7*x[7] + MOV r14,r14,ASR #16 ; r14= OC_C1S7*x[1]>>16 + MUL r8, r5, r8 ; r8 = OC_C7S1*x[7] + LDRSH r1, [r1, #-10] ; r1 = x[3] + LDR r5, OC_C3S5 ; r5 = OC_C3S5 + LDR r11,OC_C5S3 ; r11= OC_C5S3 + ADD r8, r14,r8, ASR #16 ; r8=t[7]=C1S7*x[1]>>16+C7S1*x[7]>>16 + MUL r14,r5, r10 ; r14= OC_C3S5*x[5] + SUB r9, r9, r7, ASR #16 ; r9=t[4]=C7S1*x[1]>>16-C1S7*x[7]>>16 + MUL r10,r11,r10 ; r10= OC_C5S3*x[5] + MOV r14,r14,ASR #16 ; r14= OC_C3S5*x[5]>>16 + MUL r11,r1, r11 ; r11= OC_C5S3*x[3] + MOV r10,r10,ASR #16 ; r10= OC_C5S3*x[5]>>16 + MUL r1, r5, r1 ; r1 = OC_C3S5*x[3] + SUB r14,r14,r11,ASR #16 ;r14=t[5]=C3S5*x[5]>>16-C5S3*x[3]>>16 + ADD r10,r10,r1, ASR #16 ;r10=t[6]=C5S3*x[5]>>16+C3S5*x[3]>>16 + ; r2=t[0]<<16 r3=t[2] r4=t[3] r6=t[1]<<16 r8=t[7] r9=t[4] + ; r10=t[6] r12=C4S4 r14=t[5] + ; Stage 2 +; TODO: This is wrong; t[4]-t[5] and t[7]-t[6] need to be truncated to 16-bit +; before multiplying, not after (this is not equivalent) + ; 4-5 butterfly + ADD r9, r9, r14 ; r9 = t2[4] = t[4]+t[5] + SUB r14,r9, r14, LSL #1 ; r14= t[4]-t[5] + MUL r14,r12,r14 ; r14= t2[5]<<16 = C4S4*(t[4]-t[5]) + ; 7-6 butterfly + ADD r8, r8, r10 ; r8 = t2[7] = t[7]+t[6] + SUB r10,r8, r10, LSL #1 ; r10= t[7]-t[6] + MUL r10,r12,r10 ; r10= t2[6]<<16 = C4S4*(t[7]+t[6]) + ; r2=t[0]<<16 r3=t[2] r4=t[3] r6=t[1]<<16 r8=t2[7] r9=t2[4] + ; r10=t2[6]<<16 r12=C4S4 r14=t2[5]<<16 + ; Stage 3 + ADD r2, r2, #8<<16 ; r2 = t[0]+8<<16 + ADD r6, r6, #8<<16 ; r6 = t[1]+8<<16 + ; 0-3 butterfly + ADD r2, r4, r2, ASR #16 ; r2 = t2[0] = t[0] + t[3] + 8 + SUB r4, r2, r4, LSL #1 ; r4 = t2[3] = t[0] - t[3] + 8 + ; 1-2 butterfly + ADD r6, r3, r6, ASR #16 ; r6 = t2[1] = t[1] + t[2] + 8 + SUB r3, r6, r3, LSL #1 ; r3 = t2[2] = t[1] - t[2] + 8 + ; 6-5 butterfly + MOV r14,r14,ASR #16 ; r14= t2[5] + ADD r10,r14,r10,ASR #16 ; r10= t3[6] = t[6] + t[5] + SUB r14,r10,r14,LSL #1 ; r14= t3[5] = t[6] - t[5] + ; r2=t2[0] r3=t2[2] r4=t2[3] r6=t2[1] r8=t2[7] r9=t2[4] + ; r10=t3[6] r14=t3[5] + ; Stage 4 + ADD r2, r2, r8 ; r2 = t[0] + t[7] + 8 + ADD r6, r6, r10 ; r6 = t[1] + t[6] + 8 + ADD r3, r3, r14 ; r3 = t[2] + t[5] + 8 + ADD r4, r4, r9 ; r4 = t[3] + t[4] + 8 + SUB r8, r2, r8, LSL #1 ; r8 = t[0] - t[7] + 8 + SUB r10,r6, r10,LSL #1 ; r10= t[1] - t[6] + 8 + SUB r14,r3, r14,LSL #1 ; r14= t[2] - t[5] + 8 + SUB r9, r4, r9, LSL #1 ; r9 = t[3] - t[4] + 8 + ; TODO: This is wrong. + ; The C code truncates to 16 bits by storing to RAM and doing the + ; shifts later; we've got an extra 4 bits here. + MOV r2, r2, ASR #4 + MOV r6, r6, ASR #4 + MOV r3, r3, ASR #4 + MOV r4, r4, ASR #4 + MOV r8, r8, ASR #4 + MOV r10,r10,ASR #4 + MOV r14,r14,ASR #4 + MOV r9, r9, ASR #4 + STRH r2, [r0], #2 ; y[0] = t[0]+t[7] + STRH r6, [r0, #14] ; y[1] = t[1]+t[6] + STRH r3, [r0, #30] ; y[2] = t[2]+t[5] + STRH r4, [r0, #46] ; y[3] = t[3]+t[4] + STRH r9, [r0, #62] ; y[4] = t[3]-t[4] + STRH r14,[r0, #78] ; y[5] = t[2]-t[5] + STRH r10,[r0, #94] ; y[6] = t[1]-t[6] + STRH r8, [r0, #110] ; y[7] = t[0]-t[7] + LDMFD r13!,{r1,PC} + ENDP + + [ OC_ARM_ASM_MEDIA + EXPORT oc_idct8x8_1_v6 + EXPORT oc_idct8x8_v6 + +oc_idct8x8_1_v6 PROC + ; r0 = ogg_int16_t *_y + ; r1 = ogg_uint16_t _dc + ORR r2, r1, r1, LSL #16 + ORR r3, r1, r1, LSL #16 + STRD r2, [r0], #8 + STRD r2, [r0], #8 + STRD r2, [r0], #8 + STRD r2, [r0], #8 + STRD r2, [r0], #8 + STRD r2, [r0], #8 + STRD r2, [r0], #8 + STRD r2, [r0], #8 + STRD r2, [r0], #8 + STRD r2, [r0], #8 + STRD r2, [r0], #8 + STRD r2, [r0], #8 + STRD r2, [r0], #8 + STRD r2, [r0], #8 + STRD r2, [r0], #8 + STRD r2, [r0], #8 + MOV PC, r14 + ENDP + +oc_idct8x8_v6 PROC + ; r0 = ogg_int16_t *_y + ; r1 = ogg_int16_t *_x + ; r2 = int _last_zzi + CMP r2, #3 + BLE oc_idct8x8_3_v6 + ;CMP r2, #6 + ;BLE oc_idct8x8_6_v6 + CMP r2, #10 + BLE oc_idct8x8_10_v6 +oc_idct8x8_slow_v6 + STMFD r13!,{r4-r11,r14} + SUB r13,r13,#64*2 +; Row transforms + STR r0, [r13,#-4]! + ADD r0, r13, #4 ; Write to temp storage. + BL idct8_8core_v6 + BL idct8_8core_v6 + BL idct8_8core_v6 + BL idct8_8core_v6 + LDR r0, [r13], #4 ; Write to the final destination. + ; Clear input data for next block. + MOV r4, #0 + MOV r5, #0 + STRD r4, [r1,#-8*16]! + STRD r4, [r1,#8] + STRD r4, [r1,#16] + STRD r4, [r1,#24] + STRD r4, [r1,#32] + STRD r4, [r1,#40] + STRD r4, [r1,#48] + STRD r4, [r1,#56] + STRD r4, [r1,#64] + STRD r4, [r1,#72] + STRD r4, [r1,#80] + STRD r4, [r1,#88] + STRD r4, [r1,#96] + STRD r4, [r1,#104] + STRD r4, [r1,#112] + STRD r4, [r1,#120] + MOV r1, r13 ; And read from temp storage. +; Column transforms + BL idct8_8core_down_v6 + BL idct8_8core_down_v6 + BL idct8_8core_down_v6 + BL idct8_8core_down_v6 + ADD r13,r13,#64*2 + LDMFD r13!,{r4-r11,PC} + ENDP + +oc_idct8x8_10_v6 PROC + STMFD r13!,{r4-r11,r14} + SUB r13,r13,#64*2+4 +; Row transforms + MOV r2, r13 + STR r0, [r13,#-4]! + AND r0, r2, #4 ; Align the stack. + ADD r0, r0, r2 ; Write to temp storage. + BL idct4_3core_v6 + BL idct2_1core_v6 + LDR r0, [r13], #4 ; Write to the final destination. + ; Clear input data for next block. + MOV r4, #0 + MOV r5, #0 + STRD r4, [r1,#-4*16]! + STRD r4, [r1,#16] + STR r4, [r1,#32] + STR r4, [r1,#48] + AND r1, r13,#4 ; Align the stack. + ADD r1, r1, r13 ; And read from temp storage. +; Column transforms + BL idct4_4core_down_v6 + BL idct4_4core_down_v6 + BL idct4_4core_down_v6 + BL idct4_4core_down_v6 + ADD r13,r13,#64*2+4 + LDMFD r13!,{r4-r11,PC} + ENDP + +oc_idct8x8_3_v6 PROC + STMFD r13!,{r4-r8,r14} + SUB r13,r13,#64*2 +; Row transforms + MOV r8, r0 + MOV r0, r13 ; Write to temp storage. + BL idct2_1core_v6 + ; Clear input data for next block. + MOV r4, #0 + STR r4, [r1,#-2*16]! + STR r4, [r1,#16] + MOV r1, r13 ; Read from temp storage. + MOV r0, r8 ; Write to the final destination. +; Column transforms + BL idct2_2core_down_v6 + BL idct2_2core_down_v6 + BL idct2_2core_down_v6 + BL idct2_2core_down_v6 + ADD r13,r13,#64*2 + LDMFD r13!,{r4-r8,PC} + ENDP + +idct2_1core_v6 PROC + ; r0 = ogg_int16_t *_y (destination) + ; r1 = const ogg_int16_t *_x (source) +; Stage 1: + LDR r2, [r1], #16 ; r2 = <x[0,1]|x[0,0]> + LDR r3, OC_C4S4 + LDRSH r6, [r1], #16 ; r6 = x[1,0] + SMULWB r12,r3, r2 ; r12= t[0,0]=OC_C4S4*x[0,0]>>16 + LDRD r4, r5, OC_C7S1 ; r4 = OC_C7S1; r5 = OC_C1S7 + SMULWB r6, r3, r6 ; r6 = t[1,0]=OC_C4S4*x[1,0]>>16 + SMULWT r4, r4, r2 ; r4 = t[0,4]=OC_C7S1*x[0,1]>>16 + SMULWT r7, r5, r2 ; r7 = t[0,7]=OC_C1S7*x[0,1]>>16 +; Stage 2: + SMULWB r5, r3, r4 ; r5 = t[0,5]=OC_C4S4*t[0,4]>>16 + PKHBT r12,r12,r6, LSL #16 ; r12= <t[1,0]|t[0,0]> + SMULWB r6, r3, r7 ; r6 = t[0,6]=OC_C4S4*t[0,7]>>16 + PKHBT r7, r7, r3 ; r7 = <0|t[0,7]> +; Stage 3: + PKHBT r5, r6, r5, LSL #16 ; r5 = <t[0,5]|t[0,6]> + PKHBT r4, r4, r3 ; r4 = <0|t[0,4]> + SASX r5, r5, r5 ; r5 = <t[0,6]+t[0,5]|t[0,6]-t[0,5]> +; Stage 4: + PKHTB r6, r3, r5, ASR #16 ; r6 = <0|t[0,6]> + PKHBT r5, r5, r3 ; r5 = <0|t[0,5]> + SADD16 r3, r12,r7 ; r3 = t[0]+t[7] + STR r3, [r0], #4 ; y[0<<3] = t[0]+t[7] + SADD16 r3, r12,r6 ; r3 = t[0]+t[6] + STR r3, [r0, #12] ; y[1<<3] = t[0]+t[6] + SADD16 r3, r12,r5 ; r3 = t[0]+t[5] + STR r3, [r0, #28] ; y[2<<3] = t[0]+t[5] + SADD16 r3, r12,r4 ; r3 = t[0]+t[4] + STR r3, [r0, #44] ; y[3<<3] = t[0]+t[4] + SSUB16 r4, r12,r4 ; r4 = t[0]-t[4] + STR r4, [r0, #60] ; y[4<<3] = t[0]-t[4] + SSUB16 r5, r12,r5 ; r5 = t[0]-t[5] + STR r5, [r0, #76] ; y[5<<3] = t[0]-t[5] + SSUB16 r6, r12,r6 ; r6 = t[0]-t[6] + STR r6, [r0, #92] ; y[6<<3] = t[0]-t[6] + SSUB16 r7, r12,r7 ; r7 = t[0]-t[7] + STR r7, [r0, #108] ; y[7<<3] = t[0]-t[7] + MOV PC,r14 + ENDP + ] + + ALIGN 8 +OC_C7S1 + DCD 12785 ; 31F1 +OC_C1S7 + DCD 64277 ; FB15 +OC_C6S2 + DCD 25080 ; 61F8 +OC_C2S6 + DCD 60547 ; EC83 +OC_C5S3 + DCD 36410 ; 8E3A +OC_C3S5 + DCD 54491 ; D4DB +OC_C4S4 + DCD 46341 ; B505 + + [ OC_ARM_ASM_MEDIA +idct2_2core_down_v6 PROC + ; r0 = ogg_int16_t *_y (destination) + ; r1 = const ogg_int16_t *_x (source) +; Stage 1: + LDR r2, [r1], #16 ; r2 = <x[0,1]|x[0,0]> + LDR r3, OC_C4S4 + MOV r7 ,#8 ; r7 = 8 + LDR r6, [r1], #16 ; r6 = <x[1,1]|x[1,0]> + SMLAWB r12,r3, r2, r7 ; r12= (t[0,0]=OC_C4S4*x[0,0]>>16)+8 + LDRD r4, r5, OC_C7S1 ; r4 = OC_C7S1; r5 = OC_C1S7 + SMLAWB r7, r3, r6, r7 ; r7 = (t[1,0]=OC_C4S4*x[1,0]>>16)+8 + SMULWT r5, r5, r2 ; r2 = t[0,7]=OC_C1S7*x[0,1]>>16 + PKHBT r12,r12,r7, LSL #16 ; r12= <t[1,0]+8|t[0,0]+8> + SMULWT r4, r4, r2 ; r4 = t[0,4]=OC_C7S1*x[0,1]>>16 +; Here we cheat: row 1 had just a DC, so x[0,1]==x[1,1] by definition. + PKHBT r7, r5, r5, LSL #16 ; r7 = <t[0,7]|t[0,7]> +; Stage 2: + SMULWB r6, r3, r7 ; r6 = t[0,6]=OC_C4S4*t[0,7]>>16 + PKHBT r4, r4, r4, LSL #16 ; r4 = <t[0,4]|t[0,4]> + SMULWT r2, r3, r7 ; r2 = t[1,6]=OC_C4S4*t[1,7]>>16 + SMULWB r5, r3, r4 ; r5 = t[0,5]=OC_C4S4*t[0,4]>>16 + PKHBT r6, r6, r2, LSL #16 ; r6 = <t[1,6]|t[0,6]> + SMULWT r2, r3, r4 ; r2 = t[1,5]=OC_C4S4*t[1,4]>>16 + PKHBT r2, r5, r2, LSL #16 ; r2 = <t[1,5]|t[0,5]> +; Stage 3: + SSUB16 r5, r6, r2 ; r5 = <t[1,6]-t[1,5]|t[0,6]-t[0,5]> + SADD16 r6, r6, r2 ; r6 = <t[1,6]+t[1,5]|t[0,6]+t[0,5]> +; Stage 4: + SADD16 r2, r12,r7 ; r2 = t[0]+t[7]+8 + MOV r3, r2, ASR #4 + MOV r2, r2, LSL #16 + PKHTB r3, r3, r2, ASR #20 ; r3 = t[0]+t[7]+8>>4 + STR r3, [r0], #4 ; y[0<<3] = t[0]+t[7]+8>>4 + SADD16 r2, r12,r6 ; r2 = t[0]+t[6]+8 + MOV r3, r2, ASR #4 + MOV r2, r2, LSL #16 + PKHTB r3, r3, r2, ASR #20 ; r3 = t[0]+t[6]+8>>4 + STR r3, [r0, #12] ; y[1<<3] = t[0]+t[6]+8>>4 + SADD16 r2, r12,r5 ; r2 = t[0]+t[5]+8 + MOV r3, r2, ASR #4 + MOV r2, r2, LSL #16 + PKHTB r3, r3, r2, ASR #20 ; r3 = t[0]+t[5]+8>>4 + STR r3, [r0, #28] ; y[2<<3] = t[0]+t[5]+8>>4 + SADD16 r2, r12,r4 ; r2 = t[0]+t[4]+8 + MOV r3, r2, ASR #4 + MOV r2, r2, LSL #16 + PKHTB r3, r3, r2, ASR #20 ; r3 = t[0]+t[4]+8>>4 + STR r3, [r0, #44] ; y[3<<3] = t[0]+t[4]+8>>4 + SSUB16 r4, r12,r4 ; r4 = t[0]-t[4]+8 + MOV r3, r4, ASR #4 + MOV r4, r4, LSL #16 + PKHTB r3, r3, r4, ASR #20 ; r3 = t[0]-t[4]+8>>4 + STR r3, [r0, #60] ; y[4<<3] = t[0]-t[4]+8>>4 + SSUB16 r5, r12,r5 ; r5 = t[0]-t[5]+8 + MOV r3, r5, ASR #4 + MOV r5, r5, LSL #16 + PKHTB r3, r3, r5, ASR #20 ; r3 = t[0]-t[5]+8>>4 + STR r3, [r0, #76] ; y[5<<3] = t[0]-t[5]+8>>4 + SSUB16 r6, r12,r6 ; r6 = t[0]-t[6]+8 + MOV r3, r6, ASR #4 + MOV r6, r6, LSL #16 + PKHTB r3, r3, r6, ASR #20 ; r3 = t[0]-t[6]+8>>4 + STR r3, [r0, #92] ; y[6<<3] = t[0]-t[6]+8>>4 + SSUB16 r7, r12,r7 ; r7 = t[0]-t[7]+8 + MOV r3, r7, ASR #4 + MOV r7, r7, LSL #16 + PKHTB r3, r3, r7, ASR #20 ; r3 = t[0]-t[7]+8>>4 + STR r3, [r0, #108] ; y[7<<3] = t[0]-t[7]+8>>4 + MOV PC,r14 + ENDP + +; In theory this should save ~75 cycles over oc_idct8x8_10, more than enough to +; pay for increased branch mis-prediction to get here, but in practice it +; doesn't seem to slow anything down to take it out, and it's less code this +; way. + [ 0 +oc_idct8x8_6_v6 PROC + STMFD r13!,{r4-r8,r10,r11,r14} + SUB r13,r13,#64*2+4 +; Row transforms + MOV r8, r0 + AND r0, r13,#4 ; Align the stack. + ADD r0, r0, r13 ; Write to temp storage. + BL idct3_2core_v6 + BL idct1core_v6 + ; Clear input data for next block. + MOV r4, #0 + MOV r5, #0 + STRD r4, [r1,#-3*16]! + STR r4, [r1,#16] + STR r4, [r1,#32] + AND r1, r13,#4 ; Align the stack. + MOV r0, r8 ; Write to the final destination. + ADD r1, r1, r13 ; And read from temp storage. +; Column transforms + BL idct3_3core_down_v6 + BL idct3_3core_down_v6 + BL idct3_3core_down_v6 + BL idct3_3core_down_v6 + ADD r13,r13,#64*2+4 + LDMFD r13!,{r4-r8,r10,r11,PC} + ENDP + +idct1core_v6 PROC + ; r0 = ogg_int16_t *_y (destination) + ; r1 = const ogg_int16_t *_x (source) + LDRSH r3, [r1], #16 + MOV r12,#0x05 + ORR r12,r12,#0xB500 + MUL r3, r12, r3 + ; Stall ? + MOV r3, r3, ASR #16 + ; Don't need to actually store the odd lines; they won't be read. + STRH r3, [r0], #2 + STRH r3, [r0, #30] + STRH r3, [r0, #62] + STRH r3, [r0, #94] + MOV PC,R14 + ENDP + +idct3_2core_v6 PROC + ; r0 = ogg_int16_t *_y (destination) + ; r1 = const ogg_int16_t *_x (source) +; Stage 1: + LDRD r4, [r1], #16 ; r4 = <x[0,1]|x[0,0]>; r5 = <*|x[0,2]> + LDRD r10, r11, OC_C6S2_3_v6 ; r10= OC_C6S2; r11= OC_C2S6 + ; Stall + SMULWB r3, r11,r5 ; r3 = t[0,3]=OC_C2S6*x[0,2]>>16 + LDR r11,OC_C4S4 + SMULWB r2, r10,r5 ; r2 = t[0,2]=OC_C6S2*x[0,2]>>16 + LDR r5, [r1], #16 ; r5 = <x[1,1]|x[1,0]> + SMULWB r12,r11,r4 ; r12= (t[0,0]=OC_C4S4*x[0,0]>>16) + LDRD r6, OC_C7S1_3_v6 ; r6 = OC_C7S1; r7 = OC_C1S7 + SMULWB r10,r11,r5 ; r10= (t[1,0]=OC_C4S4*x[1,0]>>16) + PKHBT r12,r12,r10,LSL #16 ; r12= <t[1,0]|t[0,0]> + SMULWT r10,r7, r5 ; r10= t[1,7]=OC_C1S7*x[1,1]>>16 + PKHBT r2, r2, r11 ; r2 = <0|t[0,2]> + SMULWT r7, r7, r4 ; r7 = t[0,7]=OC_C1S7*x[0,1]>>16 + PKHBT r3, r3, r11 ; r3 = <0|t[0,3]> + SMULWT r5, r6, r5 ; r10= t[1,4]=OC_C7S1*x[1,1]>>16 + PKHBT r7, r7, r10,LSL #16 ; r7 = <t[1,7]|t[0,7]> + SMULWT r4, r6, r4 ; r4 = t[0,4]=OC_C7S1*x[0,1]>>16 +; Stage 2: + SMULWB r6, r11,r7 ; r6 = t[0,6]=OC_C4S4*t[0,7]>>16 + PKHBT r4, r4, r5, LSL #16 ; r4 = <t[1,4]|t[0,4]> + SMULWT r10,r11,r7 ; r10= t[1,6]=OC_C4S4*t[1,7]>>16 + SMULWB r5, r11,r4 ; r5 = t[0,5]=OC_C4S4*t[0,4]>>16 + PKHBT r6, r6, r10,LSL #16 ; r6 = <t[1,6]|t[0,6]> + SMULWT r10,r11,r4 ; r10= t[1,5]=OC_C4S4*t[1,4]>>16 +; Stage 3: + B idct4_3core_stage3_v6 + ENDP + +; Another copy so the LDRD offsets are less than +/- 255. + ALIGN 8 +OC_C7S1_3_v6 + DCD 12785 ; 31F1 +OC_C1S7_3_v6 + DCD 64277 ; FB15 +OC_C6S2_3_v6 + DCD 25080 ; 61F8 +OC_C2S6_3_v6 + DCD 60547 ; EC83 + +idct3_3core_down_v6 PROC + ; r0 = ogg_int16_t *_y (destination) + ; r1 = const ogg_int16_t *_x (source) +; Stage 1: + LDRD r10,[r1], #16 ; r10= <x[0,1]|x[0,0]>; r11= <??|x[0,2]> + LDRD r6, OC_C6S2_3_v6 ; r6 = OC_C6S2; r7 = OC_C2S6 + LDR r4, [r1], #16 ; r4 = <x[1,1]|x[1,0]> + SMULWB r3, r7, r11 ; r3 = t[0,3]=OC_C2S6*x[0,2]>>16 + MOV r7,#8 + SMULWB r2, r6, r11 ; r2 = t[0,2]=OC_C6S2*x[0,2]>>16 + LDR r11,OC_C4S4 + SMLAWB r12,r11,r10,r7 ; r12= t[0,0]+8=(OC_C4S4*x[0,0]>>16)+8 +; Here we cheat: row 2 had just a DC, so x[0,2]==x[1,2] by definition. + PKHBT r3, r3, r3, LSL #16 ; r3 = <t[0,3]|t[0,3]> + SMLAWB r5, r11,r4, r7 ; r5 = t[1,0]+8=(OC_C4S4*x[1,0]>>16)+8 + PKHBT r2, r2, r2, LSL #16 ; r2 = <t[0,2]|t[0,2]> + LDRD r6, OC_C7S1_3_v6 ; r6 = OC_C7S1; r7 = OC_C1S7 + PKHBT r12,r12,r5, LSL #16 ; r12= <t[1,0]+8|t[0,0]+8> + SMULWT r5, r7, r4 ; r5 = t[1,7]=OC_C1S7*x[1,1]>>16 + SMULWT r7, r7, r10 ; r7 = t[0,7]=OC_C1S7*x[0,1]>>16 + SMULWT r10,r6, r10 ; r10= t[0,4]=OC_C7S1*x[0,1]>>16 + PKHBT r7, r7, r5, LSL #16 ; r7 = <t[1,7]|t[0,7]> + SMULWT r4, r6, r4 ; r4 = t[1,4]=OC_C7S1*x[1,1]>>16 +; Stage 2: + SMULWB r6, r11,r7 ; r6 = t[0,6]=OC_C4S4*t[0,7]>>16 + PKHBT r4, r10,r4, LSL #16 ; r4 = <t[1,4]|t[0,4]> + SMULWT r10,r11,r7 ; r10= t[1,6]=OC_C4S4*t[1,7]>>16 + SMULWB r5, r11,r4 ; r5 = t[0,5]=OC_C4S4*t[0,4]>>16 + PKHBT r6, r6, r10,LSL #16 ; r6 = <t[1,6]|t[0,6]> + SMULWT r10,r11,r4 ; r10= t[1,5]=OC_C4S4*t[1,4]>>16 +; Stage 3: + B idct4_4core_down_stage3_v6 + ENDP + ] + +idct4_3core_v6 PROC + ; r0 = ogg_int16_t *_y (destination) + ; r1 = const ogg_int16_t *_x (source) +; Stage 1: + LDRD r10,[r1], #16 ; r10= <x[0,1]|x[0,0]>; r11= <x[0,3]|x[0,2]> + LDRD r2, r3, OC_C5S3_4_v6 ; r2 = OC_C5S3; r3 = OC_C3S5 + LDRD r4, [r1], #16 ; r4 = <x[1,1]|x[1,0]>; r5 = <??|x[1,2]> + SMULWT r9, r3, r11 ; r9 = t[0,6]=OC_C3S5*x[0,3]>>16 + SMULWT r8, r2, r11 ; r8 = -t[0,5]=OC_C5S3*x[0,3]>>16 + PKHBT r9, r9, r2 ; r9 = <0|t[0,6]> + LDRD r6, r7, OC_C6S2_4_v6 ; r6 = OC_C6S2; r7 = OC_C2S6 + PKHBT r8, r8, r2 ; r9 = <0|-t[0,5]> + SMULWB r3, r7, r11 ; r3 = t[0,3]=OC_C2S6*x[0,2]>>16 + SMULWB r2, r6, r11 ; r2 = t[0,2]=OC_C6S2*x[0,2]>>16 + LDR r11,OC_C4S4 + SMULWB r12,r7, r5 ; r12= t[1,3]=OC_C2S6*x[1,2]>>16 + SMULWB r5, r6, r5 ; r5 = t[1,2]=OC_C6S2*x[1,2]>>16 + PKHBT r3, r3, r12,LSL #16 ; r3 = <t[1,3]|t[0,3]> + SMULWB r12,r11,r10 ; r12= t[0,0]=OC_C4S4*x[0,0]>>16 + PKHBT r2, r2, r5, LSL #16 ; r2 = <t[1,2]|t[0,2]> + SMULWB r5, r11,r4 ; r5 = t[1,0]=OC_C4S4*x[1,0]>>16 + LDRD r6, r7, OC_C7S1_4_v6 ; r6 = OC_C7S1; r7 = OC_C1S7 + PKHBT r12,r12,r5, LSL #16 ; r12= <t[1,0]|t[0,0]> + SMULWT r5, r7, r4 ; r5 = t[1,7]=OC_C1S7*x[1,1]>>16 + SMULWT r7, r7, r10 ; r7 = t[0,7]=OC_C1S7*x[0,1]>>16 + SMULWT r10,r6, r10 ; r10= t[0,4]=OC_C7S1*x[0,1]>>16 + PKHBT r7, r7, r5, LSL #16 ; r7 = <t[1,7]|t[0,7]> + SMULWT r4, r6, r4 ; r4 = t[1,4]=OC_C7S1*x[1,1]>>16 +; Stage 2: + SSUB16 r6, r7, r9 ; r6 = t[7]-t[6] + PKHBT r4, r10,r4, LSL #16 ; r4 = <t[1,4]|t[0,4]> + SADD16 r7, r7, r9 ; r7 = t[7]=t[7]+t[6] + SMULWT r9, r11,r6 ; r9 = t[1,6]=OC_C4S4*r6T>>16 + SADD16 r5, r4, r8 ; r5 = t[4]-t[5] + SMULWB r6, r11,r6 ; r6 = t[0,6]=OC_C4S4*r6B>>16 + SSUB16 r4, r4, r8 ; r4 = t[4]=t[4]+t[5] + SMULWT r10,r11,r5 ; r10= t[1,5]=OC_C4S4*r5T>>16 + PKHBT r6, r6, r9, LSL #16 ; r6 = <t[1,6]|t[0,6]> + SMULWB r5, r11,r5 ; r5 = t[0,5]=OC_C4S4*r5B>>16 +; Stage 3: +idct4_3core_stage3_v6 + SADD16 r11,r12,r2 ; r11= t[1]=t[0]+t[2] + PKHBT r10,r5, r10,LSL #16 ; r10= <t[1,5]|t[0,5]> + SSUB16 r2, r12,r2 ; r2 = t[2]=t[0]-t[2] +idct4_3core_stage3_5_v6 + SSUB16 r5, r6, r10 ; r5 = t[5]'=t[6]-t[5] + SADD16 r6, r6, r10 ; r6 = t[6]=t[6]+t[5] + SADD16 r10,r12,r3 ; r10= t[0]'=t[0]+t[3] + SSUB16 r3, r12,r3 ; r3 = t[3]=t[0]-t[3] +; Stage 4: + SADD16 r12,r10,r7 ; r12= t[0]+t[7] + STR r12,[r0], #4 ; y[0<<3] = t[0]+t[7] + SADD16 r12,r11,r6 ; r12= t[1]+t[6] + STR r12,[r0, #12] ; y[1<<3] = t[1]+t[6] + SADD16 r12,r2, r5 ; r12= t[2]+t[5] + STR r12,[r0, #28] ; y[2<<3] = t[2]+t[5] + SADD16 r12,r3, r4 ; r12= t[3]+t[4] + STR r12,[r0, #44] ; y[3<<3] = t[3]+t[4] + SSUB16 r4, r3, r4 ; r4 = t[3]-t[4] + STR r4, [r0, #60] ; y[4<<3] = t[3]-t[4] + SSUB16 r5, r2, r5 ; r5 = t[2]-t[5] + STR r5, [r0, #76] ; y[5<<3] = t[2]-t[5] + SSUB16 r6, r11,r6 ; r6 = t[1]-t[6] + STR r6, [r0, #92] ; y[6<<3] = t[1]-t[6] + SSUB16 r7, r10,r7 ; r7 = t[0]-t[7] + STR r7, [r0, #108] ; y[7<<3] = t[0]-t[7] + MOV PC,r14 + ENDP + +; Another copy so the LDRD offsets are less than +/- 255. + ALIGN 8 +OC_C7S1_4_v6 + DCD 12785 ; 31F1 +OC_C1S7_4_v6 + DCD 64277 ; FB15 +OC_C6S2_4_v6 + DCD 25080 ; 61F8 +OC_C2S6_4_v6 + DCD 60547 ; EC83 +OC_C5S3_4_v6 + DCD 36410 ; 8E3A +OC_C3S5_4_v6 + DCD 54491 ; D4DB + +idct4_4core_down_v6 PROC + ; r0 = ogg_int16_t *_y (destination) + ; r1 = const ogg_int16_t *_x (source) +; Stage 1: + LDRD r10,[r1], #16 ; r10= <x[0,1]|x[0,0]>; r11= <x[0,3]|x[0,2]> + LDRD r2, r3, OC_C5S3_4_v6 ; r2 = OC_C5S3; r3 = OC_C3S5 + LDRD r4, [r1], #16 ; r4 = <x[1,1]|x[1,0]>; r5 = <x[1,3]|x[1,2]> + SMULWT r9, r3, r11 ; r9 = t[0,6]=OC_C3S5*x[0,3]>>16 + LDRD r6, r7, OC_C6S2_4_v6 ; r6 = OC_C6S2; r7 = OC_C2S6 + SMULWT r8, r2, r11 ; r8 = -t[0,5]=OC_C5S3*x[0,3]>>16 +; Here we cheat: row 3 had just a DC, so x[0,3]==x[1,3] by definition. + PKHBT r9, r9, r9, LSL #16 ; r9 = <t[0,6]|t[0,6]> + SMULWB r3, r7, r11 ; r3 = t[0,3]=OC_C2S6*x[0,2]>>16 + PKHBT r8, r8, r8, LSL #16 ; r8 = <-t[0,5]|-t[0,5]> + SMULWB r2, r6, r11 ; r2 = t[0,2]=OC_C6S2*x[0,2]>>16 + LDR r11,OC_C4S4 + SMULWB r12,r7, r5 ; r12= t[1,3]=OC_C2S6*x[1,2]>>16 + MOV r7,#8 + SMULWB r5, r6, r5 ; r5 = t[1,2]=OC_C6S2*x[1,2]>>16 + PKHBT r3, r3, r12,LSL #16 ; r3 = <t[1,3]|t[0,3]> + SMLAWB r12,r11,r10,r7 ; r12= t[0,0]+8=(OC_C4S4*x[0,0]>>16)+8 + PKHBT r2, r2, r5, LSL #16 ; r2 = <t[1,2]|t[0,2]> + SMLAWB r5, r11,r4 ,r7 ; r5 = t[1,0]+8=(OC_C4S4*x[1,0]>>16)+8 + LDRD r6, r7, OC_C7S1_4_v6 ; r6 = OC_C7S1; r7 = OC_C1S7 + PKHBT r12,r12,r5, LSL #16 ; r12= <t[1,0]+8|t[0,0]+8> + SMULWT r5, r7, r4 ; r5 = t[1,7]=OC_C1S7*x[1,1]>>16 + SMULWT r7, r7, r10 ; r7 = t[0,7]=OC_C1S7*x[0,1]>>16 + SMULWT r10,r6, r10 ; r10= t[0,4]=OC_C7S1*x[0,1]>>16 + PKHBT r7, r7, r5, LSL #16 ; r7 = <t[1,7]|t[0,7]> + SMULWT r4, r6, r4 ; r4 = t[1,4]=OC_C7S1*x[1,1]>>16 +; Stage 2: + SSUB16 r6, r7, r9 ; r6 = t[7]-t[6] + PKHBT r4, r10,r4, LSL #16 ; r4 = <t[1,4]|t[0,4]> + SADD16 r7, r7, r9 ; r7 = t[7]=t[7]+t[6] + SMULWT r9, r11,r6 ; r9 = t[1,6]=OC_C4S4*r6T>>16 + SADD16 r5, r4, r8 ; r5 = t[4]-t[5] + SMULWB r6, r11,r6 ; r6 = t[0,6]=OC_C4S4*r6B>>16 + SSUB16 r4, r4, r8 ; r4 = t[4]=t[4]+t[5] + SMULWT r10,r11,r5 ; r10= t[1,5]=OC_C4S4*r5T>>16 + PKHBT r6, r6, r9, LSL #16 ; r6 = <t[1,6]|t[0,6]> + SMULWB r5, r11,r5 ; r5 = t[0,5]=OC_C4S4*r5B>>16 +; Stage 3: +idct4_4core_down_stage3_v6 + SADD16 r11,r12,r2 ; r11= t[1]+8=t[0]+t[2]+8 + PKHBT r10,r5, r10,LSL #16 ; r10= <t[1,5]|t[0,5]> + SSUB16 r2, r12,r2 ; r2 = t[2]+8=t[0]-t[2]+8 + B idct8_8core_down_stage3_5_v6 + ENDP + +idct8_8core_v6 PROC + STMFD r13!,{r0,r14} +; Stage 1: + ;5-6 rotation by 3pi/16 + LDRD r10, r11, OC_C5S3_4_v6 ; r10= OC_C5S3, r11= OC_C3S5 + LDR r4, [r1,#8] ; r4 = <x[0,5]|x[0,4]> + LDR r7, [r1,#24] ; r7 = <x[1,5]|x[1,4]> + SMULWT r5, r11,r4 ; r5 = OC_C3S5*x[0,5]>>16 + LDR r0, [r1,#4] ; r0 = <x[0,3]|x[0,2]> + SMULWT r3, r11,r7 ; r3 = OC_C3S5*x[1,5]>>16 + LDR r12,[r1,#20] ; r12= <x[1,3]|x[1,2]> + SMULWT r6, r11,r0 ; r6 = OC_C3S5*x[0,3]>>16 + SMULWT r11,r11,r12 ; r11= OC_C3S5*x[1,3]>>16 + SMLAWT r6, r10,r4, r6 ; r6 = t[0,6]=r6+(OC_C5S3*x[0,5]>>16) + PKHBT r5, r5, r3, LSL #16 ; r5 = <r3|r5> + SMLAWT r11,r10,r7, r11 ; r11= t[1,6]=r11+(OC_C5S3*x[1,5]>>16) + PKHBT r4, r4, r7, LSL #16 ; r4 = <x[1,4]|x[0,4]> + SMULWT r3, r10,r0 ; r3 = OC_C5S3*x[0,3]>>16 + PKHBT r6, r6, r11,LSL #16 ; r6 = <t[1,6]|t[0,6]> + SMULWT r8, r10,r12 ; r8 = OC_C5S3*x[1,3]>>16 + ;2-3 rotation by 6pi/16 + LDRD r10, r11, OC_C6S2_4_v6 ; r10= OC_C6S2, r11= OC_C2S6 + PKHBT r3, r3, r8, LSL #16 ; r3 = <r8|r3> + LDR r8, [r1,#12] ; r8 = <x[0,7]|x[0,6]> + SMULWB r2, r10,r0 ; r2 = OC_C6S2*x[0,2]>>16 + SSUB16 r5, r5, r3 ; r5 = <t[1,5]|t[0,5]> + SMULWB r9, r10,r12 ; r9 = OC_C6S2*x[1,2]>>16 + LDR r7, [r1,#28] ; r7 = <x[1,7]|x[1,6]> + SMULWB r3, r10,r8 ; r3 = OC_C6S2*x[0,6]>>16 + SMULWB r10,r10,r7 ; r10= OC_C6S2*x[1,6]>>16 + PKHBT r2, r2, r9, LSL #16 ; r2 = <r2|r9> + SMLAWB r3, r11,r0, r3 ; r3 = t[0,3]=r3+(OC_C2S6*x[0,2]>>16) + SMLAWB r10,r11,r12,r10 ; r10= t[1,3]=r10+(OC_C2S6*x[1,2]>>16) + SMULWB r9, r11,r8 ; r9 = OC_C2S6*x[0,6]>>16 + PKHBT r3, r3, r10,LSL #16 ; r3 = <t[1,6]|t[0,6]> + SMULWB r12,r11,r7 ; r12= OC_C2S6*x[1,6]>>16 + ;4-7 rotation by 7pi/16 + LDRD r10, r11, OC_C7S1_8_v6 ; r10= OC_C7S1, r11= OC_C1S7 + PKHBT r9, r9, r12,LSL #16 ; r9 = <r9|r12> + LDR r0, [r1],#16 ; r0 = <x[0,1]|x[0,0]> + PKHTB r7, r7, r8, ASR #16 ; r7 = <x[1,7]|x[0,7]> + SSUB16 r2, r2, r9 ; r2 = <t[1,2]|t[0,2]> + SMULWB r9, r10,r7 ; r9 = OC_C7S1*x[0,7]>>16 + LDR r14,[r1],#16 ; r14= <x[1,1]|x[1,0]> + SMULWT r12,r10,r7 ; r12= OC_C7S1*x[1,7]>>16 + SMULWT r8, r10,r0 ; r8 = OC_C7S1*x[0,1]>>16 + SMULWT r10,r10,r14 ; r10= OC_C7S1*x[1,1]>>16 + SMLAWT r9, r11,r0, r9 ; r9 = t[0,7]=r9+(OC_C1S7*x[0,1]>>16) + PKHBT r8, r8, r10,LSL #16 ; r8 = <r12|r8> + SMLAWT r12,r11,r14,r12 ; r12= t[1,7]=r12+(OC_C1S7*x[1,1]>>16) + PKHBT r0, r0, r14,LSL #16 ; r0 = <x[1,0]|x[0,0]> + SMULWB r10,r11,r7 ; r10= OC_C1S7*x[0,6]>>16 + PKHBT r9, r9, r12,LSL #16 ; r9 = <t[1,7]|t[0,7]> + SMULWT r12,r11,r7 ; r12= OC_C1S7*x[1,6]>>16 + ;0-1 butterfly + LDR r11,OC_C4S4 + PKHBT r10,r10,r12,LSL #16 ; r10= <r12|r10> + SADD16 r7, r0, r4 ; r7 = x[0]+x[4] + SSUB16 r10,r8, r10 ; r10= <t[1,4]|t[0,4]> + SSUB16 r4, r0, r4 ; r4 = x[0]-x[4] + SMULWB r8, r11,r7 ; r8 = t[0,0]=OC_C4S4*r7B>>16 + SMULWT r12,r11,r7 ; r12= t[1,0]=OC_C4S4*r7T>>16 + SMULWB r7, r11,r4 ; r7 = t[0,1]=OC_C4S4*r4B>>16 + PKHBT r12,r8, r12,LSL #16 ; r12= <t[1,0]|t[0,0]> + SMULWT r8, r11,r4 ; r8 = t[1,1]=OC_C4S4*r4T>>16 +; Stage 2: + SADD16 r4, r10,r5 ; r4 = t[4]'=t[4]+t[5] + PKHBT r8, r7, r8, LSL #16 ; r8 = <t[1,0]|t[0,0]> + SSUB16 r5, r10,r5 ; r5 = t[4]-t[5] + SMULWB r10,r11,r5 ; r10= t[0,5]=OC_C4S4*r5B>>16 + SADD16 r7, r9, r6 ; r7 = t[7]'=t[7]+t[6] + SMULWT r5, r11,r5 ; r5 = t[1,5]=OC_C4S4*r5T>>16 + SSUB16 r6, r9, r6 ; r6 = t[7]-t[6] + SMULWB r9, r11,r6 ; r9 = t[0,6]=OC_C4S4*r6B>>16 + PKHBT r10,r10,r5, LSL #16 ; r10= <t[1,5]|t[0,5]> + SMULWT r6, r11,r6 ; r6 = t[1,6]=OC_C4S4*r6T>>16 +; Stage 3: + SADD16 r11,r8, r2 ; r11= t[1]'=t[1]+t[2] + PKHBT r6, r9, r6, LSL #16 ; r6 = <t[1,6]|t[0,6]> + SSUB16 r2, r8, r2 ; r2 = t[2]=t[1]-t[2] + LDMFD r13!,{r0,r14} + B idct4_3core_stage3_5_v6 + ENDP + +; Another copy so the LDRD offsets are less than +/- 255. + ALIGN 8 +OC_C7S1_8_v6 + DCD 12785 ; 31F1 +OC_C1S7_8_v6 + DCD 64277 ; FB15 +OC_C6S2_8_v6 + DCD 25080 ; 61F8 +OC_C2S6_8_v6 + DCD 60547 ; EC83 +OC_C5S3_8_v6 + DCD 36410 ; 8E3A +OC_C3S5_8_v6 + DCD 54491 ; D4DB + +idct8_8core_down_v6 PROC + STMFD r13!,{r0,r14} +; Stage 1: + ;5-6 rotation by 3pi/16 + LDRD r10, r11, OC_C5S3_8_v6 ; r10= OC_C5S3, r11= OC_C3S5 + LDR r4, [r1,#8] ; r4 = <x[0,5]|x[0,4]> + LDR r7, [r1,#24] ; r7 = <x[1,5]|x[1,4]> + SMULWT r5, r11,r4 ; r5 = OC_C3S5*x[0,5]>>16 + LDR r0, [r1,#4] ; r0 = <x[0,3]|x[0,2]> + SMULWT r3, r11,r7 ; r3 = OC_C3S5*x[1,5]>>16 + LDR r12,[r1,#20] ; r12= <x[1,3]|x[1,2]> + SMULWT r6, r11,r0 ; r6 = OC_C3S5*x[0,3]>>16 + SMULWT r11,r11,r12 ; r11= OC_C3S5*x[1,3]>>16 + SMLAWT r6, r10,r4, r6 ; r6 = t[0,6]=r6+(OC_C5S3*x[0,5]>>16) + PKHBT r5, r5, r3, LSL #16 ; r5 = <r3|r5> + SMLAWT r11,r10,r7, r11 ; r11= t[1,6]=r11+(OC_C5S3*x[1,5]>>16) + PKHBT r4, r4, r7, LSL #16 ; r4 = <x[1,4]|x[0,4]> + SMULWT r3, r10,r0 ; r3 = OC_C5S3*x[0,3]>>16 + PKHBT r6, r6, r11,LSL #16 ; r6 = <t[1,6]|t[0,6]> + SMULWT r8, r10,r12 ; r8 = OC_C5S3*x[1,3]>>16 + ;2-3 rotation by 6pi/16 + LDRD r10, r11, OC_C6S2_8_v6 ; r10= OC_C6S2, r11= OC_C2S6 + PKHBT r3, r3, r8, LSL #16 ; r3 = <r8|r3> + LDR r8, [r1,#12] ; r8 = <x[0,7]|x[0,6]> + SMULWB r2, r10,r0 ; r2 = OC_C6S2*x[0,2]>>16 + SSUB16 r5, r5, r3 ; r5 = <t[1,5]|t[0,5]> + SMULWB r9, r10,r12 ; r9 = OC_C6S2*x[1,2]>>16 + LDR r7, [r1,#28] ; r7 = <x[1,7]|x[1,6]> + SMULWB r3, r10,r8 ; r3 = OC_C6S2*x[0,6]>>16 + SMULWB r10,r10,r7 ; r10= OC_C6S2*x[1,6]>>16 + PKHBT r2, r2, r9, LSL #16 ; r2 = <r2|r9> + SMLAWB r3, r11,r0, r3 ; r3 = t[0,3]=r3+(OC_C2S6*x[0,2]>>16) + SMLAWB r10,r11,r12,r10 ; r10= t[1,3]=r10+(OC_C2S6*x[1,2]>>16) + SMULWB r9, r11,r8 ; r9 = OC_C2S6*x[0,6]>>16 + PKHBT r3, r3, r10,LSL #16 ; r3 = <t[1,6]|t[0,6]> + SMULWB r12,r11,r7 ; r12= OC_C2S6*x[1,6]>>16 + ;4-7 rotation by 7pi/16 + LDRD r10, r11, OC_C7S1_8_v6 ; r10= OC_C7S1, r11= OC_C1S7 + PKHBT r9, r9, r12,LSL #16 ; r9 = <r9|r12> + LDR r0, [r1],#16 ; r0 = <x[0,1]|x[0,0]> + PKHTB r7, r7, r8, ASR #16 ; r7 = <x[1,7]|x[0,7]> + SSUB16 r2, r2, r9 ; r2 = <t[1,2]|t[0,2]> + SMULWB r9, r10,r7 ; r9 = OC_C7S1*x[0,7]>>16 + LDR r14,[r1],#16 ; r14= <x[1,1]|x[1,0]> + SMULWT r12,r10,r7 ; r12= OC_C7S1*x[1,7]>>16 + SMULWT r8, r10,r0 ; r8 = OC_C7S1*x[0,1]>>16 + SMULWT r10,r10,r14 ; r10= OC_C7S1*x[1,1]>>16 + SMLAWT r9, r11,r0, r9 ; r9 = t[0,7]=r9+(OC_C1S7*x[0,1]>>16) + PKHBT r8, r8, r10,LSL #16 ; r8 = <r12|r8> + SMLAWT r12,r11,r14,r12 ; r12= t[1,7]=r12+(OC_C1S7*x[1,1]>>16) + PKHBT r0, r0, r14,LSL #16 ; r0 = <x[1,0]|x[0,0]> + SMULWB r10,r11,r7 ; r10= OC_C1S7*x[0,6]>>16 + PKHBT r9, r9, r12,LSL #16 ; r9 = <t[1,7]|t[0,7]> + SMULWT r12,r11,r7 ; r12= OC_C1S7*x[1,6]>>16 + ;0-1 butterfly + LDR r11,OC_C4S4 + MOV r14,#8 + PKHBT r10,r10,r12,LSL #16 ; r10= <r12|r10> + SADD16 r7, r0, r4 ; r7 = x[0]+x[4] + SSUB16 r10,r8, r10 ; r10= <t[1,4]|t[0,4]> + SMLAWB r8, r11,r7, r14 ; r8 = t[0,0]+8=(OC_C4S4*r7B>>16)+8 + SSUB16 r4, r0, r4 ; r4 = x[0]-x[4] + SMLAWT r12,r11,r7, r14 ; r12= t[1,0]+8=(OC_C4S4*r7T>>16)+8 + SMLAWB r7, r11,r4, r14 ; r7 = t[0,1]+8=(OC_C4S4*r4B>>16)+8 + PKHBT r12,r8, r12,LSL #16 ; r12= <t[1,0]+8|t[0,0]+8> + SMLAWT r8, r11,r4, r14 ; r8 = t[1,1]+8=(OC_C4S4*r4T>>16)+8 +; Stage 2: + SADD16 r4, r10,r5 ; r4 = t[4]'=t[4]+t[5] + PKHBT r8, r7, r8, LSL #16 ; r8 = <t[1,0]+8|t[0,0]+8> + SSUB16 r5, r10,r5 ; r5 = t[4]-t[5] + SMULWB r10,r11,r5 ; r10= t[0,5]=OC_C4S4*r5B>>16 + SADD16 r7, r9, r6 ; r7 = t[7]'=t[7]+t[6] + SMULWT r5, r11,r5 ; r5 = t[1,5]=OC_C4S4*r5T>>16 + SSUB16 r6, r9, r6 ; r6 = t[7]-t[6] + SMULWB r9, r11,r6 ; r9 = t[0,6]=OC_C4S4*r6B>>16 + PKHBT r10,r10,r5, LSL #16 ; r10= <t[1,5]|t[0,5]> + SMULWT r6, r11,r6 ; r6 = t[1,6]=OC_C4S4*r6T>>16 +; Stage 3: + SADD16 r11,r8, r2 ; r11= t[1]'+8=t[1]+t[2]+8 + PKHBT r6, r9, r6, LSL #16 ; r6 = <t[1,6]|t[0,6]> + SSUB16 r2, r8, r2 ; r2 = t[2]+8=t[1]-t[2]+8 + LDMFD r13!,{r0,r14} +idct8_8core_down_stage3_5_v6 + SSUB16 r5, r6, r10 ; r5 = t[5]'=t[6]-t[5] + SADD16 r6, r6, r10 ; r6 = t[6]=t[6]+t[5] + SADD16 r10,r12,r3 ; r10= t[0]'+8=t[0]+t[3]+8 + SSUB16 r3, r12,r3 ; r3 = t[3]+8=t[0]-t[3]+8 +; Stage 4: + SADD16 r12,r10,r7 ; r12= t[0]+t[7]+8 + SSUB16 r7, r10,r7 ; r7 = t[0]-t[7]+8 + MOV r10,r12,ASR #4 + MOV r12,r12,LSL #16 + PKHTB r10,r10,r12,ASR #20 ; r10= t[0]+t[7]+8>>4 + STR r10,[r0], #4 ; y[0<<3] = t[0]+t[7]+8>>4 + SADD16 r12,r11,r6 ; r12= t[1]+t[6]+8 + SSUB16 r6, r11,r6 ; r6 = t[1]-t[6]+8 + MOV r10,r12,ASR #4 + MOV r12,r12,LSL #16 + PKHTB r10,r10,r12,ASR #20 ; r10= t[1]+t[6]+8>>4 + STR r10,[r0, #12] ; y[1<<3] = t[1]+t[6]+8>>4 + SADD16 r12,r2, r5 ; r12= t[2]+t[5]+8 + SSUB16 r5, r2, r5 ; r5 = t[2]-t[5]+8 + MOV r10,r12,ASR #4 + MOV r12,r12,LSL #16 + PKHTB r10,r10,r12,ASR #20 ; r10= t[2]+t[5]+8>>4 + STR r10,[r0, #28] ; y[2<<3] = t[2]+t[5]+8>>4 + SADD16 r12,r3, r4 ; r12= t[3]+t[4]+8 + SSUB16 r4, r3, r4 ; r4 = t[3]-t[4]+8 + MOV r10,r12,ASR #4 + MOV r12,r12,LSL #16 + PKHTB r10,r10,r12,ASR #20 ; r10= t[3]+t[4]+8>>4 + STR r10,[r0, #44] ; y[3<<3] = t[3]+t[4]+8>>4 + MOV r10,r4, ASR #4 + MOV r4, r4, LSL #16 + PKHTB r10,r10,r4, ASR #20 ; r10= t[3]-t[4]+8>>4 + STR r10,[r0, #60] ; y[4<<3] = t[3]-t[4]+8>>4 + MOV r10,r5, ASR #4 + MOV r5, r5, LSL #16 + PKHTB r10,r10,r5, ASR #20 ; r10= t[2]-t[5]+8>>4 + STR r10,[r0, #76] ; y[5<<3] = t[2]-t[5]+8>>4 + MOV r10,r6, ASR #4 + MOV r6, r6, LSL #16 + PKHTB r10,r10,r6, ASR #20 ; r10= t[1]-t[6]+8>>4 + STR r10,[r0, #92] ; y[6<<3] = t[1]-t[6]+8>>4 + MOV r10,r7, ASR #4 + MOV r7, r7, LSL #16 + PKHTB r10,r10,r7, ASR #20 ; r10= t[0]-t[7]+8>>4 + STR r10,[r0, #108] ; y[7<<3] = t[0]-t[7]+8>>4 + MOV PC,r14 + ENDP + ] + + [ OC_ARM_ASM_NEON + EXPORT oc_idct8x8_1_neon + EXPORT oc_idct8x8_neon + + ALIGN 16 +OC_IDCT_CONSTS_NEON + DCW 8 + DCW 64277 ; FB15 (C1S7) + DCW 60547 ; EC83 (C2S6) + DCW 54491 ; D4DB (C3S5) + DCW 46341 ; B505 (C4S4) + DCW 36410 ; 471D (C5S3) + DCW 25080 ; 30FC (C6S2) + DCW 12785 ; 31F1 (C7S1) + +oc_idct8x8_1_neon PROC + ; r0 = ogg_int16_t *_y + ; r1 = ogg_uint16_t _dc + VDUP.S16 Q0, r1 + VMOV Q1, Q0 + VST1.64 {D0, D1, D2, D3}, [r0@128]! + VST1.64 {D0, D1, D2, D3}, [r0@128]! + VST1.64 {D0, D1, D2, D3}, [r0@128]! + VST1.64 {D0, D1, D2, D3}, [r0@128] + MOV PC, r14 + ENDP + +oc_idct8x8_neon PROC + ; r0 = ogg_int16_t *_y + ; r1 = ogg_int16_t *_x + ; r2 = int _last_zzi + CMP r2, #10 + BLE oc_idct8x8_10_neon +oc_idct8x8_slow_neon + VPUSH {D8-D15} + MOV r2, r1 + ADR r3, OC_IDCT_CONSTS_NEON + ; Row transforms (input is pre-transposed) + VLD1.64 {D16,D17,D18,D19}, [r2@128]! + VLD1.64 {D20,D21,D22,D23}, [r2@128]! + VLD1.64 {D24,D25,D26,D27}, [r2@128]! + VSUB.S16 Q1, Q8, Q12 ; Q8 = x[0]-x[4] + VLD1.64 {D28,D29,D30,D31}, [r2@128] + VADD.S16 Q8, Q8, Q12 ; Q1 = x[0]+x[4] + VLD1.64 {D0,D1}, [r3@128] + MOV r12, r14 + BL oc_idct8x8_stage123_neon +; Stage 4 + VSUB.S16 Q15,Q8, Q7 ; Q15 = y[7]=t[0]'-t[7]' + VADD.S16 Q8, Q8, Q7 ; Q8 = y[0]=t[0]'+t[7]' + VSUB.S16 Q14,Q9, Q3 ; Q14 = y[6]=t[1]'-t[6]'' + VADD.S16 Q9, Q9, Q3 ; Q9 = y[1]=t[1]'+t[6]'' + VSUB.S16 Q13,Q10,Q5 ; Q13 = y[5]=t[2]'-t[5]'' + VADD.S16 Q10,Q10,Q5 ; Q10 = y[2]=t[2]'+t[5]'' + VTRN.16 Q14,Q15 + VSUB.S16 Q12,Q11,Q4 ; Q12 = y[4]=t[3]'-t[4]' + VADD.S16 Q11,Q11,Q4 ; Q11 = y[3]=t[3]'+t[4]' + ; 8x8 Transpose + VTRN.16 Q8, Q9 + VTRN.16 Q10,Q11 + VTRN.16 Q12,Q13 + VTRN.32 Q8, Q10 + VTRN.32 Q9, Q11 + VTRN.32 Q12,Q14 + VTRN.32 Q13,Q15 + VSWP D17,D24 + VSUB.S16 Q1, Q8, Q12 ; Q8 = x[0]-x[4] + VSWP D19,D26 + VADD.S16 Q8, Q8, Q12 ; Q1 = x[0]+x[4] + VSWP D21,D28 + VSWP D23,D30 + ; Column transforms + BL oc_idct8x8_stage123_neon + ; We have to put the return address back in the LR, or the branch + ; predictor will not recognize the function return and mis-predict the + ; entire call stack. + MOV r14, r12 +; Stage 4 + VSUB.S16 Q15,Q8, Q7 ; Q15 = y[7]=t[0]'-t[7]' + VADD.S16 Q8, Q8, Q7 ; Q8 = y[0]=t[0]'+t[7]' + VSUB.S16 Q14,Q9, Q3 ; Q14 = y[6]=t[1]'-t[6]'' + VADD.S16 Q9, Q9, Q3 ; Q9 = y[1]=t[1]'+t[6]'' + VSUB.S16 Q13,Q10,Q5 ; Q13 = y[5]=t[2]'-t[5]'' + VADD.S16 Q10,Q10,Q5 ; Q10 = y[2]=t[2]'+t[5]'' + VSUB.S16 Q12,Q11,Q4 ; Q12 = y[4]=t[3]'-t[4]' + VADD.S16 Q11,Q11,Q4 ; Q11 = y[3]=t[3]'+t[4]' + VMOV.I8 Q2,#0 + VPOP {D8-D15} + VMOV.I8 Q3,#0 + VRSHR.S16 Q8, Q8, #4 ; Q8 = y[0]+8>>4 + VST1.64 {D4, D5, D6, D7}, [r1@128]! + VRSHR.S16 Q9, Q9, #4 ; Q9 = y[1]+8>>4 + VRSHR.S16 Q10,Q10,#4 ; Q10 = y[2]+8>>4 + VST1.64 {D4, D5, D6, D7}, [r1@128]! + VRSHR.S16 Q11,Q11,#4 ; Q11 = y[3]+8>>4 + VRSHR.S16 Q12,Q12,#4 ; Q12 = y[4]+8>>4 + VST1.64 {D4, D5, D6, D7}, [r1@128]! + VRSHR.S16 Q13,Q13,#4 ; Q13 = y[5]+8>>4 + VRSHR.S16 Q14,Q14,#4 ; Q14 = y[6]+8>>4 + VST1.64 {D4, D5, D6, D7}, [r1@128] + VRSHR.S16 Q15,Q15,#4 ; Q15 = y[7]+8>>4 + VSTMIA r0, {D16-D31} + MOV PC, r14 + ENDP + +oc_idct8x8_stage123_neon PROC +; Stages 1 & 2 + VMULL.S16 Q4, D18,D1[3] + VMULL.S16 Q5, D19,D1[3] + VMULL.S16 Q7, D30,D1[3] + VMULL.S16 Q6, D31,D1[3] + VMULL.S16 Q2, D30,D0[1] + VMULL.S16 Q3, D31,D0[1] + VSHRN.S32 D8, Q4, #16 + VSHRN.S32 D9, Q5, #16 ; Q4 = (OC_C7S1*x[1]>>16) + VSHRN.S32 D14,Q7, #16 + VSHRN.S32 D15,Q6, #16 ; Q7 = (OC_C7S1*x[7]>>16) + VSHRN.S32 D4, Q2, #16 + VSHRN.S32 D5, Q3, #16 ; Q2 = (OC_C1S7*x[7]>>16)-x[7] + VSUB.S16 Q4, Q4, Q15 + VADD.S16 Q7, Q7, Q9 + VSUB.S16 Q4, Q4, Q2 ; Q4 = t[4] + VMULL.S16 Q2, D18,D0[1] + VMULL.S16 Q9, D19,D0[1] + VMULL.S16 Q5, D26,D0[3] + VMULL.S16 Q3, D27,D0[3] + VMULL.S16 Q6, D22,D0[3] + VMULL.S16 Q12,D23,D0[3] + VSHRN.S32 D4, Q2, #16 + VSHRN.S32 D5, Q9, #16 ; Q2 = (OC_C1S7*x[1]>>16)-x[1] + VSHRN.S32 D10,Q5, #16 + VSHRN.S32 D11,Q3, #16 ; Q5 = (OC_C3S5*x[5]>>16)-x[5] + VSHRN.S32 D12,Q6, #16 + VSHRN.S32 D13,Q12,#16 ; Q6 = (OC_C3S5*x[3]>>16)-x[3] + VADD.S16 Q7, Q7, Q2 ; Q7 = t[7] + VSUB.S16 Q5, Q5, Q11 + VADD.S16 Q6, Q6, Q11 + VADD.S16 Q5, Q5, Q13 + VADD.S16 Q6, Q6, Q13 + VMULL.S16 Q9, D22,D1[1] + VMULL.S16 Q11,D23,D1[1] + VMULL.S16 Q15,D26,D1[1] + VMULL.S16 Q13,D27,D1[1] + VMULL.S16 Q2, D20,D1[2] + VMULL.S16 Q12,D21,D1[2] + VSHRN.S32 D18,Q9, #16 + VSHRN.S32 D19,Q11,#16 ; Q9 = (OC_C5S3*x[3]>>16)-x[3] + VSHRN.S32 D30,Q15,#16 + VSHRN.S32 D31,Q13,#16 ; Q15= (OC_C5S3*x[5]>>16)-x[5] + VSHRN.S32 D4, Q2, #16 + VSHRN.S32 D5, Q12,#16 ; Q2 = (OC_C6S2*x[2]>>16) + VSUB.S16 Q5, Q5, Q9 ; Q5 = t[5] + VADD.S16 Q6, Q6, Q15 ; Q6 = t[6] + VSUB.S16 Q2, Q2, Q14 + VMULL.S16 Q3, D28,D1[2] + VMULL.S16 Q11,D29,D1[2] + VMULL.S16 Q12,D28,D0[2] + VMULL.S16 Q9, D29,D0[2] + VMULL.S16 Q13,D20,D0[2] + VMULL.S16 Q15,D21,D0[2] + VSHRN.S32 D6, Q3, #16 + VSHRN.S32 D7, Q11,#16 ; Q3 = (OC_C6S2*x[6]>>16) + VSHRN.S32 D24,Q12,#16 + VSHRN.S32 D25,Q9, #16 ; Q12= (OC_C2S6*x[6]>>16)-x[6] + VSHRN.S32 D26,Q13,#16 + VSHRN.S32 D27,Q15,#16 ; Q13= (OC_C2S6*x[2]>>16)-x[2] + VSUB.S16 Q9, Q4, Q5 ; Q9 = t[4]-t[5] + VSUB.S16 Q11,Q7, Q6 ; Q11= t[7]-t[6] + VADD.S16 Q3, Q3, Q10 + VADD.S16 Q4, Q4, Q5 ; Q4 = t[4]'=t[4]+t[5] + VADD.S16 Q7, Q7, Q6 ; Q7 = t[7]'=t[7]+t[6] + VSUB.S16 Q2, Q2, Q12 ; Q2 = t[2] + VADD.S16 Q3, Q3, Q13 ; Q3 = t[3] + VMULL.S16 Q12,D16,D1[0] + VMULL.S16 Q13,D17,D1[0] + VMULL.S16 Q14,D2, D1[0] + VMULL.S16 Q15,D3, D1[0] + VMULL.S16 Q5, D18,D1[0] + VMULL.S16 Q6, D22,D1[0] + VSHRN.S32 D24,Q12,#16 + VSHRN.S32 D25,Q13,#16 + VSHRN.S32 D28,Q14,#16 + VSHRN.S32 D29,Q15,#16 + VMULL.S16 Q13,D19,D1[0] + VMULL.S16 Q15,D23,D1[0] + VADD.S16 Q8, Q8, Q12 ; Q8 = t[0] + VADD.S16 Q1, Q1, Q14 ; Q1 = t[1] + VSHRN.S32 D10,Q5, #16 + VSHRN.S32 D12,Q6, #16 + VSHRN.S32 D11,Q13,#16 + VSHRN.S32 D13,Q15,#16 + VADD.S16 Q5, Q5, Q9 ; Q5 = t[5]'=OC_C4S4*(t[4]-t[5])>>16 + VADD.S16 Q6, Q6, Q11 ; Q6 = t[6]'=OC_C4S4*(t[7]-t[6])>>16 +; Stage 3 + VSUB.S16 Q11,Q8, Q3 ; Q11 = t[3]''=t[0]-t[3] + VADD.S16 Q8, Q8, Q3 ; Q8 = t[0]''=t[0]+t[3] + VADD.S16 Q9, Q1, Q2 ; Q9 = t[1]''=t[1]+t[2] + VADD.S16 Q3, Q6, Q5 ; Q3 = t[6]''=t[6]'+t[5]' + VSUB.S16 Q10,Q1, Q2 ; Q10 = t[2]''=t[1]-t[2] + VSUB.S16 Q5, Q6, Q5 ; Q5 = t[5]''=t[6]'-t[5]' + MOV PC, r14 + ENDP + +oc_idct8x8_10_neon PROC + ADR r3, OC_IDCT_CONSTS_NEON + VLD1.64 {D0,D1}, [r3@128] + MOV r2, r1 + ; Row transforms (input is pre-transposed) +; Stage 1 + VLD1.64 {D16,D17,D18,D19},[r2@128]! + MOV r12, #16 + VMULL.S16 Q15,D16,D1[0] ; Q15= OC_C4S4*x[0]-(x[0]<<16) + VLD1.64 {D17}, [r2@64], r12 + VMULL.S16 Q2, D18,D0[1] ; Q2 = OC_C1S7*x[1]-(x[1]<<16) + VLD1.64 {D19}, [r2@64] + VMULL.S16 Q14,D17,D0[2] ; Q14= OC_C2S6*x[2]-(x[2]<<16) + VMULL.S16 Q3, D19,D0[3] ; Q3 = OC_C3S5*x[3]-(x[3]<<16) + VMULL.S16 Q13,D19,D1[1] ; Q13= OC_C5S3*x[3]-(x[3]<<16) + VMULL.S16 Q12,D18,D1[3] ; Q12= OC_C7S1*x[1] + VMULL.S16 Q1, D17,D1[2] ; Q1 = OC_C6S2*x[2] + VSHRN.S32 D30,Q15,#16 ; D30= t[0]-x[0] + VSHRN.S32 D4, Q2, #16 ; D4 = t[7]-x[1] + VSHRN.S32 D31,Q14,#16 ; D31= t[3]-x[2] + VSHRN.S32 D6, Q3, #16 ; D6 = t[6]-x[3] + VSHRN.S32 D7, Q13,#16 ; D7 = -t[5]-x[3] + VSHRN.S32 D5, Q12,#16 ; D5 = t[4] + VSHRN.S32 D2, Q1, #16 ; D2 = t[2] + VADD.S16 D4, D4, D18 ; D4 = t[7] + VADD.S16 D6, D6, D19 ; D6 = t[6] + VADD.S16 D7, D7, D19 ; D7 = -t[5] + VADD.S16 Q15,Q15,Q8 ; D30= t[0] + ; D31= t[3] +; Stages 2 & 3 + VSUB.S16 Q12,Q2, Q3 ; D24= t[7]-t[6] + ; D25= t[4]'=t[4]+t[5] + VADD.S16 Q13,Q2, Q3 ; D26= t[7]'=t[7]+t[6] + ; D27= t[4]-t[5] + VMULL.S16 Q11,D24,D1[0] ; Q11= OC_C4S4*(t[7]-t[6]) + ; -(t[7]-t[6]<<16) + VMULL.S16 Q14,D27,D1[0] ; Q14= OC_C4S4*(t[4]-t[5]) + ; -(t[4]-t[5]<<16) + VADD.S16 D16,D30,D31 ; D16= t[0]'=t[0]+t[3] + VSUB.S16 D17,D30,D2 ; D17= t[2]'=t[0]-t[2] + VADD.S16 D18,D30,D2 ; D18= t[1]'=t[0]+t[2] + VSHRN.S32 D22,Q11,#16 ; D22= (OC_C4S4*(t[7]-t[6])>>16) + ; -(t[7]-t[6]) + VSHRN.S32 D23,Q14,#16 ; D23= (OC_C4S4*(t[4]-t[5])>>16) + ; -(t[4]-t[5]) + VSUB.S16 D19,D30,D31 ; D19= t[3]'=t[0]-t[3] + VADD.S16 D22,D22,D24 ; D22= t[6]'=OC_C4S4*(t[7]-t[6])>>16 + VADD.S16 D23,D23,D27 ; D23= t[5]'=OC_C4S4*(t[4]-t[5])>>16 + VSUB.S16 D27,D22,D23 ; D27= t[5]''=t[6]'-t[5]' + VADD.S16 D24,D22,D23 ; D24= t[6]''=t[6]'+t[5]' +; Stage 4 + VSUB.S16 Q11,Q8, Q13 ; D22= y[7]=t[0]'-t[7]' + ; D23= y[5]=t[2]'-t[5]'' + VSUB.S16 Q10,Q9, Q12 ; D20= y[6]=t[1]'-t[6]' + ; D21= y[4]=t[3]'-t[4]'' + VADD.S16 Q8, Q8, Q13 ; D16= y[0]=t[0]'+t[7]' + ; D17= y[2]=t[2]'+t[5]'' + VADD.S16 Q9, Q9, Q12 ; D18= y[1]=t[1]'-t[6]' + ; D19= y[3]=t[3]'-t[4]'' + ; 8x4 transpose + VTRN.16 Q10,Q11 ; Q10= c5c4a5a4 c7c6a7a6 + ; Q11= d5d4b5b4 d7d6b7b6 + VTRN.16 Q8, Q9 ; Q8 = c3c2a3a2 c1c0a1a0 + ; Q9 = d3d2b3b2 d1d0b1b0 + VSWP D20,D21 ; Q10= c7c6a7a6 c5c4a5a4 + VSWP D22,D23 ; Q11= d7d6b7b6 d5d4b5b4 + VUZP.32 Q9, Q11 ; Q9 = b7b6b5b4 b3b2b1b0 + ; Q11= d7d6d5d4 d3d2d1d0 + VMULL.S16 Q15,D18,D0[1] + VMULL.S16 Q13,D22,D1[1] + VUZP.32 Q8, Q10 ; Q8 = a7a6a5a4 a3a2a1a0 + ; Q10= c7c6c5c4 c3c2c1c0 + ; Column transforms +; Stages 1, 2, & 3 + VMULL.S16 Q14,D19,D0[1] ; Q14:Q15= OC_C1S7*x[1]-(x[1]<<16) + VMULL.S16 Q12,D23,D1[1] ; Q12:Q13= OC_C5S3*x[3]-(x[3]<<16) + VMULL.S16 Q3, D22,D0[3] + VMULL.S16 Q2, D23,D0[3] ; Q2:Q3 = OC_C3S5*x[3]-(x[3]<<16) + VSHRN.S32 D30,Q15,#16 + VSHRN.S32 D31,Q14,#16 ; Q15= (OC_C1S7*x[1]>>16)-x[1] + VSHRN.S32 D26,Q13,#16 + VSHRN.S32 D27,Q12,#16 ; Q13= (OC_C5S3*x[3]>>16)-x[3] + VSHRN.S32 D28,Q3, #16 + VSHRN.S32 D29,Q2, #16 ; Q14= (OC_C3S5*x[3]>>16)-x[3] + VADD.S16 Q15,Q15,Q9 ; Q15= t[7] + VADD.S16 Q13,Q13,Q11 ; Q13= -t[5] + VADD.S16 Q14,Q14,Q11 ; Q14= t[6] + VMULL.S16 Q12,D18,D1[3] + VMULL.S16 Q2, D19,D1[3] ; Q2:Q12= OC_C7S1*x[1] + VMULL.S16 Q1, D16,D1[0] + VMULL.S16 Q11,D17,D1[0] ; Q11:Q1 = OC_C4S4*x[0]-(x[0]<<16) + VMULL.S16 Q3, D20,D0[2] + VMULL.S16 Q9, D21,D0[2] ; Q9:Q3 = OC_C2S6*x[2]-(x[2]<<16) + VSHRN.S32 D24,Q12,#16 + VSHRN.S32 D25,Q2, #16 ; Q12= t[4] + VMULL.S16 Q2, D20,D1[2] + VSHRN.S32 D2, Q1, #16 + VSHRN.S32 D3, Q11,#16 ; Q1 = (OC_C4S4*x[0]>>16)-x[0] + VMULL.S16 Q11,D21,D1[2] ; Q2:Q11= OC_C6S2*x[2] + VSHRN.S32 D6, Q3, #16 + VSHRN.S32 D7, Q9, #16 ; Q3 = (OC_C2S6*x[2]>>16)-x[2] + VSUB.S16 Q9, Q15,Q14 ; Q9 = t[7]-t[6] + VADD.S16 Q15,Q15,Q14 ; Q15= t[7]'=t[7]+t[6] + VSHRN.S32 D4, Q2, #16 + VSHRN.S32 D5, Q11,#16 ; Q2 = t[2] + VADD.S16 Q1, Q1, Q8 ; Q1 = t[0] + VADD.S16 Q8, Q12,Q13 ; Q8 = t[4]-t[5] + VADD.S16 Q3, Q3, Q10 ; Q3 = t[3] + VMULL.S16 Q10,D16,D1[0] + VMULL.S16 Q11,D17,D1[0] ; Q11:Q10= OC_C4S4*(t[4]-t[5]) + ; -(t[4]-t[5]<<16) + VSUB.S16 Q12,Q12,Q13 ; Q12= t[4]'=t[4]+t[5] + VMULL.S16 Q14,D18,D1[0] + VMULL.S16 Q13,D19,D1[0] ; Q13:Q14= OC_C4S4*(t[6]-t[7]) + ; -(t[6]-t[7]<<16) + VSHRN.S32 D20,Q10,#16 + VSHRN.S32 D21,Q11,#16 ; Q10= (OC_C4S4*(t[4]-t[5])>>16) + ; -(t[4]-t[5]) + VADD.S16 Q11,Q1, Q3 ; Q11= t[0]'=t[0]+t[3] + VSUB.S16 Q3, Q1, Q3 ; Q3 = t[3]'=t[0]-t[3] + VSHRN.S32 D28,Q14,#16 + VSHRN.S32 D29,Q13,#16 ; Q14= (OC_C4S4*(t[7]-t[6])>>16) + ; -(t[7]-t[6]) + VADD.S16 Q10,Q10,Q8 ; Q10=t[5]' + VADD.S16 Q14,Q14,Q9 ; Q14=t[6]' + VSUB.S16 Q13,Q14,Q10 ; Q13=t[5]''=t[6]'-t[5]' + VADD.S16 Q14,Q14,Q10 ; Q14=t[6]''=t[6]'+t[5]' + VADD.S16 Q10,Q1, Q2 ; Q10= t[1]'=t[0]+t[2] + VSUB.S16 Q2, Q1, Q2 ; Q2 = t[2]'=t[0]-t[2] +; Stage 4 + VADD.S16 Q8, Q11,Q15 ; Q8 = y[0]=t[0]'+t[7]' + VADD.S16 Q9, Q10,Q14 ; Q9 = y[1]=t[1]'+t[6]'' + VSUB.S16 Q15,Q11,Q15 ; Q15 = y[7]=t[0]'-t[7]' + VSUB.S16 Q14,Q10,Q14 ; Q14 = y[6]=t[1]'-t[6]'' + VADD.S16 Q10,Q2, Q13 ; Q10 = y[2]=t[2]'+t[5]'' + VADD.S16 Q11,Q3, Q12 ; Q11 = y[3]=t[3]'+t[4]' + VSUB.S16 Q12,Q3, Q12 ; Q12 = y[4]=t[3]'-t[4]' + VSUB.S16 Q13,Q2, Q13 ; Q13 = y[5]=t[2]'-t[5]'' + VMOV.I8 D2, #0 + VRSHR.S16 Q8, Q8, #4 ; Q8 = y[0]+8>>4 + VST1.64 {D2}, [r1@64], r12 + VRSHR.S16 Q9, Q9, #4 ; Q9 = y[1]+8>>4 + VRSHR.S16 Q10,Q10,#4 ; Q10 = y[2]+8>>4 + VST1.64 {D2}, [r1@64], r12 + VRSHR.S16 Q11,Q11,#4 ; Q11 = y[3]+8>>4 + VRSHR.S16 Q12,Q12,#4 ; Q12 = y[4]+8>>4 + VST1.64 {D2}, [r1@64], r12 + VRSHR.S16 Q13,Q13,#4 ; Q13 = y[5]+8>>4 + VRSHR.S16 Q14,Q14,#4 ; Q14 = y[6]+8>>4 + VST1.64 {D2}, [r1@64] + VRSHR.S16 Q15,Q15,#4 ; Q15 = y[7]+8>>4 + VSTMIA r0, {D16-D31} + MOV PC, r14 + ENDP + ] + + END diff --git a/media/libtheora/lib/arm/armint.h b/media/libtheora/lib/arm/armint.h new file mode 100644 index 0000000000..cc62d24381 --- /dev/null +++ b/media/libtheora/lib/arm/armint.h @@ -0,0 +1,126 @@ +/******************************************************************** + * * + * THIS FILE IS PART OF THE OggTheora SOFTWARE CODEC SOURCE CODE. * + * USE, DISTRIBUTION AND REPRODUCTION OF THIS LIBRARY SOURCE IS * + * GOVERNED BY A BSD-STYLE SOURCE LICENSE INCLUDED WITH THIS SOURCE * + * IN 'COPYING'. PLEASE READ THESE TERMS BEFORE DISTRIBUTING. * + * * + * THE Theora SOURCE CODE IS COPYRIGHT (C) 2002-2010 * + * by the Xiph.Org Foundation and contributors http://www.xiph.org/ * + * * + ******************************************************************** + + function: + last mod: $Id: x86int.h 17344 2010-07-21 01:42:18Z tterribe $ + + ********************************************************************/ +#if !defined(_arm_armint_H) +# define _arm_armint_H (1) +# include "../internal.h" + +# if defined(OC_ARM_ASM) + +# if defined(__ARMEB__) +# error "Big-endian configurations are not supported by the ARM asm. " \ + "Reconfigure with --disable-asm or undefine OC_ARM_ASM." +# endif + +# define oc_state_accel_init oc_state_accel_init_arm +/*This function is implemented entirely in asm, so it's helpful to pull out all + of the things that depend on structure offsets. + We reuse the function pointer with the wrong prototype, though.*/ +# define oc_state_loop_filter_frag_rows(_state,_bv,_refi,_pli, \ + _fragy0,_fragy_end) \ + ((oc_loop_filter_frag_rows_arm_func) \ + (_state)->opt_vtable.state_loop_filter_frag_rows)( \ + (_state)->ref_frame_data[(_refi)],(_state)->ref_ystride[(_pli)], \ + (_bv), \ + (_state)->frags, \ + (_state)->fplanes[(_pli)].froffset \ + +(_fragy0)*(ptrdiff_t)(_state)->fplanes[(_pli)].nhfrags, \ + (_state)->fplanes[(_pli)].froffset \ + +(_fragy_end)*(ptrdiff_t)(_state)->fplanes[(_pli)].nhfrags, \ + (_state)->fplanes[(_pli)].froffset, \ + (_state)->fplanes[(_pli)].froffset+(_state)->fplanes[(_pli)].nfrags, \ + (_state)->frag_buf_offs, \ + (_state)->fplanes[(_pli)].nhfrags) +/*For everything else the default vtable macros are fine.*/ +# define OC_STATE_USE_VTABLE (1) +# endif + +# include "../state.h" +# include "armcpu.h" + +# if defined(OC_ARM_ASM) +typedef void (*oc_loop_filter_frag_rows_arm_func)( + unsigned char *_ref_frame_data,int _ystride,signed char _bv[256], + const oc_fragment *_frags,ptrdiff_t _fragi0,ptrdiff_t _fragi0_end, + ptrdiff_t _fragi_top,ptrdiff_t _fragi_bot, + const ptrdiff_t *_frag_buf_offs,int _nhfrags); + +void oc_state_accel_init_arm(oc_theora_state *_state); +void oc_frag_copy_list_arm(unsigned char *_dst_frame, + const unsigned char *_src_frame,int _ystride, + const ptrdiff_t *_fragis,ptrdiff_t _nfragis,const ptrdiff_t *_frag_buf_offs); +void oc_frag_recon_intra_arm(unsigned char *_dst,int _ystride, + const ogg_int16_t *_residue); +void oc_frag_recon_inter_arm(unsigned char *_dst,const unsigned char *_src, + int _ystride,const ogg_int16_t *_residue); +void oc_frag_recon_inter2_arm(unsigned char *_dst,const unsigned char *_src1, + const unsigned char *_src2,int _ystride,const ogg_int16_t *_residue); +void oc_idct8x8_1_arm(ogg_int16_t _y[64],ogg_uint16_t _dc); +void oc_idct8x8_arm(ogg_int16_t _y[64],ogg_int16_t _x[64],int _last_zzi); +void oc_state_frag_recon_arm(const oc_theora_state *_state,ptrdiff_t _fragi, + int _pli,ogg_int16_t _dct_coeffs[128],int _last_zzi,ogg_uint16_t _dc_quant); +void oc_loop_filter_frag_rows_arm(unsigned char *_ref_frame_data, + int _ystride,signed char *_bv,const oc_fragment *_frags,ptrdiff_t _fragi0, + ptrdiff_t _fragi0_end,ptrdiff_t _fragi_top,ptrdiff_t _fragi_bot, + const ptrdiff_t *_frag_buf_offs,int _nhfrags); + +# if defined(OC_ARM_ASM_EDSP) +void oc_frag_copy_list_edsp(unsigned char *_dst_frame, + const unsigned char *_src_frame,int _ystride, + const ptrdiff_t *_fragis,ptrdiff_t _nfragis,const ptrdiff_t *_frag_buf_offs); + +# if defined(OC_ARM_ASM_MEDIA) +void oc_frag_recon_intra_v6(unsigned char *_dst,int _ystride, + const ogg_int16_t *_residue); +void oc_frag_recon_inter_v6(unsigned char *_dst,const unsigned char *_src, + int _ystride,const ogg_int16_t *_residue); +void oc_frag_recon_inter2_v6(unsigned char *_dst,const unsigned char *_src1, + const unsigned char *_src2,int _ystride,const ogg_int16_t *_residue); +void oc_idct8x8_1_v6(ogg_int16_t _y[64],ogg_uint16_t _dc); +void oc_idct8x8_v6(ogg_int16_t _y[64],ogg_int16_t _x[64],int _last_zzi); +void oc_state_frag_recon_v6(const oc_theora_state *_state,ptrdiff_t _fragi, + int _pli,ogg_int16_t _dct_coeffs[128],int _last_zzi,ogg_uint16_t _dc_quant); +void oc_loop_filter_init_v6(signed char *_bv,int _flimit); +void oc_loop_filter_frag_rows_v6(unsigned char *_ref_frame_data, + int _ystride,signed char *_bv,const oc_fragment *_frags,ptrdiff_t _fragi0, + ptrdiff_t _fragi0_end,ptrdiff_t _fragi_top,ptrdiff_t _fragi_bot, + const ptrdiff_t *_frag_buf_offs,int _nhfrags); + +# if defined(OC_ARM_ASM_NEON) +void oc_frag_copy_list_neon(unsigned char *_dst_frame, + const unsigned char *_src_frame,int _ystride, + const ptrdiff_t *_fragis,ptrdiff_t _nfragis,const ptrdiff_t *_frag_buf_offs); +void oc_frag_recon_intra_neon(unsigned char *_dst,int _ystride, + const ogg_int16_t *_residue); +void oc_frag_recon_inter_neon(unsigned char *_dst,const unsigned char *_src, + int _ystride,const ogg_int16_t *_residue); +void oc_frag_recon_inter2_neon(unsigned char *_dst,const unsigned char *_src1, + const unsigned char *_src2,int _ystride,const ogg_int16_t *_residue); +void oc_idct8x8_1_neon(ogg_int16_t _y[64],ogg_uint16_t _dc); +void oc_idct8x8_neon(ogg_int16_t _y[64],ogg_int16_t _x[64],int _last_zzi); +void oc_state_frag_recon_neon(const oc_theora_state *_state,ptrdiff_t _fragi, + int _pli,ogg_int16_t _dct_coeffs[128],int _last_zzi,ogg_uint16_t _dc_quant); +void oc_loop_filter_init_neon(signed char *_bv,int _flimit); +void oc_loop_filter_frag_rows_neon(unsigned char *_ref_frame_data, + int _ystride,signed char *_bv,const oc_fragment *_frags,ptrdiff_t _fragi0, + ptrdiff_t _fragi0_end,ptrdiff_t _fragi_top,ptrdiff_t _fragi_bot, + const ptrdiff_t *_frag_buf_offs,int _nhfrags); +# endif +# endif +# endif +# endif + +#endif diff --git a/media/libtheora/lib/arm/armloop.s b/media/libtheora/lib/arm/armloop.s new file mode 100644 index 0000000000..bbd4d630ed --- /dev/null +++ b/media/libtheora/lib/arm/armloop.s @@ -0,0 +1,676 @@ +;******************************************************************** +;* * +;* THIS FILE IS PART OF THE OggTheora SOFTWARE CODEC SOURCE CODE. * +;* USE, DISTRIBUTION AND REPRODUCTION OF THIS LIBRARY SOURCE IS * +;* GOVERNED BY A BSD-STYLE SOURCE LICENSE INCLUDED WITH THIS SOURCE * +;* IN 'COPYING'. PLEASE READ THESE TERMS BEFORE DISTRIBUTING. * +;* * +;* THE Theora SOURCE CODE IS COPYRIGHT (C) 2002-2010 * +;* by the Xiph.Org Foundation and contributors http://www.xiph.org/ * +;* * +;******************************************************************** +; Original implementation: +; Copyright (C) 2009 Robin Watts for Pinknoise Productions Ltd +; last mod: $Id$ +;******************************************************************** + + AREA |.text|, CODE, READONLY + + GET armopts.s + + EXPORT oc_loop_filter_frag_rows_arm + +; Which bit this is depends on the order of packing within a bitfield. +; Hopefully that doesn't change among any of the relevant compilers. +OC_FRAG_CODED_FLAG * 1 + + ; Vanilla ARM v4 version +loop_filter_h_arm PROC + ; r0 = unsigned char *_pix + ; r1 = int _ystride + ; r2 = int *_bv + ; preserves r0-r3 + STMFD r13!,{r3-r6,r14} + MOV r14,#8 + MOV r6, #255 +lfh_arm_lp + LDRB r3, [r0, #-2] ; r3 = _pix[0] + LDRB r12,[r0, #1] ; r12= _pix[3] + LDRB r4, [r0, #-1] ; r4 = _pix[1] + LDRB r5, [r0] ; r5 = _pix[2] + SUB r3, r3, r12 ; r3 = _pix[0]-_pix[3]+4 + ADD r3, r3, #4 + SUB r12,r5, r4 ; r12= _pix[2]-_pix[1] + ADD r12,r12,r12,LSL #1 ; r12= 3*(_pix[2]-_pix[1]) + ADD r12,r12,r3 ; r12= _pix[0]-_pix[3]+3*(_pix[2]-_pix[1])+4 + MOV r12,r12,ASR #3 + LDRSB r12,[r2, r12] + ; Stall (2 on Xscale) + ADDS r4, r4, r12 + CMPGT r6, r4 + EORLT r4, r6, r4, ASR #32 + SUBS r5, r5, r12 + CMPGT r6, r5 + EORLT r5, r6, r5, ASR #32 + STRB r4, [r0, #-1] + STRB r5, [r0], r1 + SUBS r14,r14,#1 + BGT lfh_arm_lp + SUB r0, r0, r1, LSL #3 + LDMFD r13!,{r3-r6,PC} + ENDP + +loop_filter_v_arm PROC + ; r0 = unsigned char *_pix + ; r1 = int _ystride + ; r2 = int *_bv + ; preserves r0-r3 + STMFD r13!,{r3-r6,r14} + MOV r14,#8 + MOV r6, #255 +lfv_arm_lp + LDRB r3, [r0, -r1, LSL #1] ; r3 = _pix[0] + LDRB r12,[r0, r1] ; r12= _pix[3] + LDRB r4, [r0, -r1] ; r4 = _pix[1] + LDRB r5, [r0] ; r5 = _pix[2] + SUB r3, r3, r12 ; r3 = _pix[0]-_pix[3]+4 + ADD r3, r3, #4 + SUB r12,r5, r4 ; r12= _pix[2]-_pix[1] + ADD r12,r12,r12,LSL #1 ; r12= 3*(_pix[2]-_pix[1]) + ADD r12,r12,r3 ; r12= _pix[0]-_pix[3]+3*(_pix[2]-_pix[1])+4 + MOV r12,r12,ASR #3 + LDRSB r12,[r2, r12] + ; Stall (2 on Xscale) + ADDS r4, r4, r12 + CMPGT r6, r4 + EORLT r4, r6, r4, ASR #32 + SUBS r5, r5, r12 + CMPGT r6, r5 + EORLT r5, r6, r5, ASR #32 + STRB r4, [r0, -r1] + STRB r5, [r0], #1 + SUBS r14,r14,#1 + BGT lfv_arm_lp + SUB r0, r0, #8 + LDMFD r13!,{r3-r6,PC} + ENDP + +oc_loop_filter_frag_rows_arm PROC + ; r0 = _ref_frame_data + ; r1 = _ystride + ; r2 = _bv + ; r3 = _frags + ; r4 = _fragi0 + ; r5 = _fragi0_end + ; r6 = _fragi_top + ; r7 = _fragi_bot + ; r8 = _frag_buf_offs + ; r9 = _nhfrags + MOV r12,r13 + STMFD r13!,{r0,r4-r11,r14} + LDMFD r12,{r4-r9} + ADD r2, r2, #127 ; _bv += 127 + CMP r4, r5 ; if(_fragi0>=_fragi0_end) + BGE oslffri_arm_end ; bail + SUBS r9, r9, #1 ; r9 = _nhfrags-1 if (r9<=0) + BLE oslffri_arm_end ; bail + ADD r3, r3, r4, LSL #2 ; r3 = &_frags[fragi] + ADD r8, r8, r4, LSL #2 ; r8 = &_frag_buf_offs[fragi] + SUB r7, r7, r9 ; _fragi_bot -= _nhfrags; +oslffri_arm_lp1 + MOV r10,r4 ; r10= fragi = _fragi0 + ADD r11,r4, r9 ; r11= fragi_end-1=fragi+_nhfrags-1 +oslffri_arm_lp2 + LDR r14,[r3], #4 ; r14= _frags[fragi] _frags++ + LDR r0, [r13] ; r0 = _ref_frame_data + LDR r12,[r8], #4 ; r12= _frag_buf_offs[fragi] _frag_buf_offs++ + TST r14,#OC_FRAG_CODED_FLAG + BEQ oslffri_arm_uncoded + CMP r10,r4 ; if (fragi>_fragi0) + ADD r0, r0, r12 ; r0 = _ref_frame_data + _frag_buf_offs[fragi] + BLGT loop_filter_h_arm + CMP r4, r6 ; if (_fragi0>_fragi_top) + BLGT loop_filter_v_arm + CMP r10,r11 ; if(fragi+1<fragi_end)===(fragi<fragi_end-1) + LDRLT r12,[r3] ; r12 = _frags[fragi+1] + ADD r0, r0, #8 + ADD r10,r10,#1 ; r10 = fragi+1; + ANDLT r12,r12,#OC_FRAG_CODED_FLAG + CMPLT r12,#OC_FRAG_CODED_FLAG ; && _frags[fragi+1].coded==0 + BLLT loop_filter_h_arm + CMP r10,r7 ; if (fragi<_fragi_bot) + LDRLT r12,[r3, r9, LSL #2] ; r12 = _frags[fragi+1+_nhfrags-1] + SUB r0, r0, #8 + ADD r0, r0, r1, LSL #3 + ANDLT r12,r12,#OC_FRAG_CODED_FLAG + CMPLT r12,#OC_FRAG_CODED_FLAG + BLLT loop_filter_v_arm + CMP r10,r11 ; while(fragi<=fragi_end-1) + BLE oslffri_arm_lp2 + MOV r4, r10 ; r4 = fragi0 += _nhfrags + CMP r4, r5 + BLT oslffri_arm_lp1 +oslffri_arm_end + LDMFD r13!,{r0,r4-r11,PC} +oslffri_arm_uncoded + ADD r10,r10,#1 + CMP r10,r11 + BLE oslffri_arm_lp2 + MOV r4, r10 ; r4 = _fragi0 += _nhfrags + CMP r4, r5 + BLT oslffri_arm_lp1 + LDMFD r13!,{r0,r4-r11,PC} + ENDP + + [ OC_ARM_ASM_MEDIA + EXPORT oc_loop_filter_init_v6 + EXPORT oc_loop_filter_frag_rows_v6 + +oc_loop_filter_init_v6 PROC + ; r0 = _bv + ; r1 = _flimit (=L from the spec) + MVN r1, r1, LSL #1 ; r1 = <0xFFFFFF|255-2*L> + AND r1, r1, #255 ; r1 = ll=r1&0xFF + ORR r1, r1, r1, LSL #8 ; r1 = <ll|ll> + PKHBT r1, r1, r1, LSL #16 ; r1 = <ll|ll|ll|ll> + STR r1, [r0] + MOV PC,r14 + ENDP + +; We could use the same strategy as the v filter below, but that would require +; 40 instructions to load the data and transpose it into columns and another +; 32 to write out the results at the end, plus the 52 instructions to do the +; filtering itself. +; This is slightly less, and less code, even assuming we could have shared the +; 52 instructions in the middle with the other function. +; It executes slightly fewer instructions than the ARMv6 approach David Conrad +; proposed for FFmpeg, but not by much: +; http://lists.mplayerhq.hu/pipermail/ffmpeg-devel/2010-February/083141.html +; His is a lot less code, though, because it only does two rows at once instead +; of four. +loop_filter_h_v6 PROC + ; r0 = unsigned char *_pix + ; r1 = int _ystride + ; r2 = int _ll + ; preserves r0-r3 + STMFD r13!,{r4-r11,r14} + LDR r12,=0x10003 + BL loop_filter_h_core_v6 + ADD r0, r0, r1, LSL #2 + BL loop_filter_h_core_v6 + SUB r0, r0, r1, LSL #2 + LDMFD r13!,{r4-r11,PC} + ENDP + +loop_filter_h_core_v6 PROC + ; r0 = unsigned char *_pix + ; r1 = int _ystride + ; r2 = int _ll + ; r12= 0x10003 + ; Preserves r0-r3, r12; Clobbers r4-r11. + LDR r4,[r0, #-2]! ; r4 = <p3|p2|p1|p0> + ; Single issue + LDR r5,[r0, r1]! ; r5 = <q3|q2|q1|q0> + UXTB16 r6, r4, ROR #16 ; r6 = <p0|p2> + UXTB16 r4, r4, ROR #8 ; r4 = <p3|p1> + UXTB16 r7, r5, ROR #16 ; r7 = <q0|q2> + UXTB16 r5, r5, ROR #8 ; r5 = <q3|q1> + PKHBT r8, r4, r5, LSL #16 ; r8 = <__|q1|__|p1> + PKHBT r9, r6, r7, LSL #16 ; r9 = <__|q2|__|p2> + SSUB16 r6, r4, r6 ; r6 = <p3-p0|p1-p2> + SMLAD r6, r6, r12,r12 ; r6 = <????|(p3-p0)+3*(p1-p2)+3> + SSUB16 r7, r5, r7 ; r7 = <q3-q0|q1-q2> + SMLAD r7, r7, r12,r12 ; r7 = <????|(q0-q3)+3*(q2-q1)+4> + LDR r4,[r0, r1]! ; r4 = <r3|r2|r1|r0> + MOV r6, r6, ASR #3 ; r6 = <??????|(p3-p0)+3*(p1-p2)+3>>3> + LDR r5,[r0, r1]! ; r5 = <s3|s2|s1|s0> + PKHBT r11,r6, r7, LSL #13 ; r11= <??|-R_q|??|-R_p> + UXTB16 r6, r4, ROR #16 ; r6 = <r0|r2> + UXTB16 r11,r11 ; r11= <__|-R_q|__|-R_p> + UXTB16 r4, r4, ROR #8 ; r4 = <r3|r1> + UXTB16 r7, r5, ROR #16 ; r7 = <s0|s2> + PKHBT r10,r6, r7, LSL #16 ; r10= <__|s2|__|r2> + SSUB16 r6, r4, r6 ; r6 = <r3-r0|r1-r2> + UXTB16 r5, r5, ROR #8 ; r5 = <s3|s1> + SMLAD r6, r6, r12,r12 ; r6 = <????|(r3-r0)+3*(r2-r1)+3> + SSUB16 r7, r5, r7 ; r7 = <r3-r0|r1-r2> + SMLAD r7, r7, r12,r12 ; r7 = <????|(s0-s3)+3*(s2-s1)+4> + ORR r9, r9, r10, LSL #8 ; r9 = <s2|q2|r2|p2> + MOV r6, r6, ASR #3 ; r6 = <??????|(r0-r3)+3*(r2-r1)+4>>3> + PKHBT r10,r4, r5, LSL #16 ; r10= <__|s1|__|r1> + PKHBT r6, r6, r7, LSL #13 ; r6 = <??|-R_s|??|-R_r> + ORR r8, r8, r10, LSL #8 ; r8 = <s1|q1|r1|p1> + UXTB16 r6, r6 ; r6 = <__|-R_s|__|-R_r> + MOV r10,#0 + ORR r6, r11,r6, LSL #8 ; r6 = <-R_s|-R_q|-R_r|-R_p> + ; Single issue + ; There's no min, max or abs instruction. + ; SSUB8 and SEL will work for abs, and we can do all the rest with + ; unsigned saturated adds, which means the GE flags are still all + ; set when we're done computing lflim(abs(R_i),L). + ; This allows us to both add and subtract, and split the results by + ; the original sign of R_i. + SSUB8 r7, r10,r6 + ; Single issue + SEL r7, r7, r6 ; r7 = abs(R_i) + ; Single issue + UQADD8 r4, r7, r2 ; r4 = 255-max(2*L-abs(R_i),0) + ; Single issue + UQADD8 r7, r7, r4 + ; Single issue + UQSUB8 r7, r7, r4 ; r7 = min(abs(R_i),max(2*L-abs(R_i),0)) + ; Single issue + UQSUB8 r4, r8, r7 + UQADD8 r5, r9, r7 + UQADD8 r8, r8, r7 + UQSUB8 r9, r9, r7 + SEL r8, r8, r4 ; r8 = p1+lflim(R_i,L) + SEL r9, r9, r5 ; r9 = p2-lflim(R_i,L) + MOV r5, r9, LSR #24 ; r5 = s2 + STRB r5, [r0,#2]! + MOV r4, r8, LSR #24 ; r4 = s1 + STRB r4, [r0,#-1] + MOV r5, r9, LSR #8 ; r5 = r2 + STRB r5, [r0,-r1]! + MOV r4, r8, LSR #8 ; r4 = r1 + STRB r4, [r0,#-1] + MOV r5, r9, LSR #16 ; r5 = q2 + STRB r5, [r0,-r1]! + MOV r4, r8, LSR #16 ; r4 = q1 + STRB r4, [r0,#-1] + ; Single issue + STRB r9, [r0,-r1]! + ; Single issue + STRB r8, [r0,#-1] + MOV PC,r14 + ENDP + +; This uses the same strategy as the MMXEXT version for x86, except that UHADD8 +; computes (a+b>>1) instead of (a+b+1>>1) like PAVGB. +; This works just as well, with the following procedure for computing the +; filter value, f: +; u = ~UHADD8(p1,~p2); +; v = UHADD8(~p1,p2); +; m = v-u; +; a = m^UHADD8(m^p0,m^~p3); +; f = UHADD8(UHADD8(a,u1),v1); +; where f = 127+R, with R in [-127,128] defined as in the spec. +; This is exactly the same amount of arithmetic as the version that uses PAVGB +; as the basic operator. +; It executes about 2/3 the number of instructions of David Conrad's approach, +; but requires more code, because it does all eight columns at once, instead +; of four at a time. +loop_filter_v_v6 PROC + ; r0 = unsigned char *_pix + ; r1 = int _ystride + ; r2 = int _ll + ; preserves r0-r11 + STMFD r13!,{r4-r11,r14} + LDRD r6, [r0, -r1]! ; r7, r6 = <p5|p1> + LDRD r4, [r0, -r1] ; r5, r4 = <p4|p0> + LDRD r8, [r0, r1]! ; r9, r8 = <p6|p2> + MVN r14,r6 ; r14= ~p1 + LDRD r10,[r0, r1] ; r11,r10= <p7|p3> + ; Filter the first four columns. + MVN r12,r8 ; r12= ~p2 + UHADD8 r14,r14,r8 ; r14= v1=~p1+p2>>1 + UHADD8 r12,r12,r6 ; r12= p1+~p2>>1 + MVN r10, r10 ; r10=~p3 + MVN r12,r12 ; r12= u1=~p1+p2+1>>1 + SSUB8 r14,r14,r12 ; r14= m1=v1-u1 + ; Single issue + EOR r4, r4, r14 ; r4 = m1^p0 + EOR r10,r10,r14 ; r10= m1^~p3 + UHADD8 r4, r4, r10 ; r4 = (m1^p0)+(m1^~p3)>>1 + ; Single issue + EOR r4, r4, r14 ; r4 = a1=m1^((m1^p0)+(m1^~p3)>>1) + SADD8 r14,r14,r12 ; r14= v1=m1+u1 + UHADD8 r4, r4, r12 ; r4 = a1+u1>>1 + MVN r12,r9 ; r12= ~p6 + UHADD8 r4, r4, r14 ; r4 = f1=(a1+u1>>1)+v1>>1 + ; Filter the second four columns. + MVN r14,r7 ; r14= ~p5 + UHADD8 r12,r12,r7 ; r12= p5+~p6>>1 + UHADD8 r14,r14,r9 ; r14= v2=~p5+p6>>1 + MVN r12,r12 ; r12= u2=~p5+p6+1>>1 + MVN r11,r11 ; r11=~p7 + SSUB8 r10,r14,r12 ; r10= m2=v2-u2 + ; Single issue + EOR r5, r5, r10 ; r5 = m2^p4 + EOR r11,r11,r10 ; r11= m2^~p7 + UHADD8 r5, r5, r11 ; r5 = (m2^p4)+(m2^~p7)>>1 + ; Single issue + EOR r5, r5, r10 ; r5 = a2=m2^((m2^p4)+(m2^~p7)>>1) + ; Single issue + UHADD8 r5, r5, r12 ; r5 = a2+u2>>1 + LDR r12,=0x7F7F7F7F ; r12 = {127}x4 + UHADD8 r5, r5, r14 ; r5 = f2=(a2+u2>>1)+v2>>1 + ; Now split f[i] by sign. + ; There's no min or max instruction. + ; We could use SSUB8 and SEL, but this is just as many instructions and + ; dual issues more (for v7 without NEON). + UQSUB8 r10,r4, r12 ; r10= R_i>0?R_i:0 + UQSUB8 r4, r12,r4 ; r4 = R_i<0?-R_i:0 + UQADD8 r11,r10,r2 ; r11= 255-max(2*L-abs(R_i<0),0) + UQADD8 r14,r4, r2 ; r14= 255-max(2*L-abs(R_i>0),0) + UQADD8 r10,r10,r11 + UQADD8 r4, r4, r14 + UQSUB8 r10,r10,r11 ; r10= min(abs(R_i<0),max(2*L-abs(R_i<0),0)) + UQSUB8 r4, r4, r14 ; r4 = min(abs(R_i>0),max(2*L-abs(R_i>0),0)) + UQSUB8 r11,r5, r12 ; r11= R_i>0?R_i:0 + UQADD8 r6, r6, r10 + UQSUB8 r8, r8, r10 + UQSUB8 r5, r12,r5 ; r5 = R_i<0?-R_i:0 + UQSUB8 r6, r6, r4 ; r6 = p1+lflim(R_i,L) + UQADD8 r8, r8, r4 ; r8 = p2-lflim(R_i,L) + UQADD8 r10,r11,r2 ; r10= 255-max(2*L-abs(R_i<0),0) + UQADD8 r14,r5, r2 ; r14= 255-max(2*L-abs(R_i>0),0) + UQADD8 r11,r11,r10 + UQADD8 r5, r5, r14 + UQSUB8 r11,r11,r10 ; r11= min(abs(R_i<0),max(2*L-abs(R_i<0),0)) + UQSUB8 r5, r5, r14 ; r5 = min(abs(R_i>0),max(2*L-abs(R_i>0),0)) + UQADD8 r7, r7, r11 + UQSUB8 r9, r9, r11 + UQSUB8 r7, r7, r5 ; r7 = p5+lflim(R_i,L) + STRD r6, [r0, -r1] ; [p5:p1] = [r7: r6] + UQADD8 r9, r9, r5 ; r9 = p6-lflim(R_i,L) + STRD r8, [r0] ; [p6:p2] = [r9: r8] + LDMFD r13!,{r4-r11,PC} + ENDP + +oc_loop_filter_frag_rows_v6 PROC + ; r0 = _ref_frame_data + ; r1 = _ystride + ; r2 = _bv + ; r3 = _frags + ; r4 = _fragi0 + ; r5 = _fragi0_end + ; r6 = _fragi_top + ; r7 = _fragi_bot + ; r8 = _frag_buf_offs + ; r9 = _nhfrags + MOV r12,r13 + STMFD r13!,{r0,r4-r11,r14} + LDMFD r12,{r4-r9} + LDR r2, [r2] ; ll = *(int *)_bv + CMP r4, r5 ; if(_fragi0>=_fragi0_end) + BGE oslffri_v6_end ; bail + SUBS r9, r9, #1 ; r9 = _nhfrags-1 if (r9<=0) + BLE oslffri_v6_end ; bail + ADD r3, r3, r4, LSL #2 ; r3 = &_frags[fragi] + ADD r8, r8, r4, LSL #2 ; r8 = &_frag_buf_offs[fragi] + SUB r7, r7, r9 ; _fragi_bot -= _nhfrags; +oslffri_v6_lp1 + MOV r10,r4 ; r10= fragi = _fragi0 + ADD r11,r4, r9 ; r11= fragi_end-1=fragi+_nhfrags-1 +oslffri_v6_lp2 + LDR r14,[r3], #4 ; r14= _frags[fragi] _frags++ + LDR r0, [r13] ; r0 = _ref_frame_data + LDR r12,[r8], #4 ; r12= _frag_buf_offs[fragi] _frag_buf_offs++ + TST r14,#OC_FRAG_CODED_FLAG + BEQ oslffri_v6_uncoded + CMP r10,r4 ; if (fragi>_fragi0) + ADD r0, r0, r12 ; r0 = _ref_frame_data + _frag_buf_offs[fragi] + BLGT loop_filter_h_v6 + CMP r4, r6 ; if (fragi0>_fragi_top) + BLGT loop_filter_v_v6 + CMP r10,r11 ; if(fragi+1<fragi_end)===(fragi<fragi_end-1) + LDRLT r12,[r3] ; r12 = _frags[fragi+1] + ADD r0, r0, #8 + ADD r10,r10,#1 ; r10 = fragi+1; + ANDLT r12,r12,#OC_FRAG_CODED_FLAG + CMPLT r12,#OC_FRAG_CODED_FLAG ; && _frags[fragi+1].coded==0 + BLLT loop_filter_h_v6 + CMP r10,r7 ; if (fragi<_fragi_bot) + LDRLT r12,[r3, r9, LSL #2] ; r12 = _frags[fragi+1+_nhfrags-1] + SUB r0, r0, #8 + ADD r0, r0, r1, LSL #3 + ANDLT r12,r12,#OC_FRAG_CODED_FLAG + CMPLT r12,#OC_FRAG_CODED_FLAG + BLLT loop_filter_v_v6 + CMP r10,r11 ; while(fragi<=fragi_end-1) + BLE oslffri_v6_lp2 + MOV r4, r10 ; r4 = fragi0 += nhfrags + CMP r4, r5 + BLT oslffri_v6_lp1 +oslffri_v6_end + LDMFD r13!,{r0,r4-r11,PC} +oslffri_v6_uncoded + ADD r10,r10,#1 + CMP r10,r11 + BLE oslffri_v6_lp2 + MOV r4, r10 ; r4 = fragi0 += nhfrags + CMP r4, r5 + BLT oslffri_v6_lp1 + LDMFD r13!,{r0,r4-r11,PC} + ENDP + ] + + [ OC_ARM_ASM_NEON + EXPORT oc_loop_filter_init_neon + EXPORT oc_loop_filter_frag_rows_neon + +oc_loop_filter_init_neon PROC + ; r0 = _bv + ; r1 = _flimit (=L from the spec) + MOV r1, r1, LSL #1 ; r1 = 2*L + VDUP.S16 Q15, r1 ; Q15= 2L in U16s + VST1.64 {D30,D31}, [r0@128] + MOV PC,r14 + ENDP + +loop_filter_h_neon PROC + ; r0 = unsigned char *_pix + ; r1 = int _ystride + ; r2 = int *_bv + ; preserves r0-r3 + ; We assume Q15= 2*L in U16s + ; My best guesses at cycle counts (and latency)--vvv + SUB r12,r0, #2 + ; Doing a 2-element structure load saves doing two VTRN's below, at the + ; cost of using two more slower single-lane loads vs. the faster + ; all-lane loads. + ; It's less code this way, though, and benches a hair faster, but it + ; leaves D2 and D4 swapped. + VLD2.16 {D0[],D2[]}, [r12], r1 ; D0 = ____________1100 2,1 + ; D2 = ____________3322 + VLD2.16 {D4[],D6[]}, [r12], r1 ; D4 = ____________5544 2,1 + ; D6 = ____________7766 + VLD2.16 {D0[1],D2[1]},[r12], r1 ; D0 = ________99881100 3,1 + ; D2 = ________BBAA3322 + VLD2.16 {D4[1],D6[1]},[r12], r1 ; D4 = ________DDCC5544 3,1 + ; D6 = ________FFEE7766 + VLD2.16 {D0[2],D2[2]},[r12], r1 ; D0 = ____GGHH99881100 3,1 + ; D2 = ____JJIIBBAA3322 + VLD2.16 {D4[2],D6[2]},[r12], r1 ; D4 = ____KKLLDDCC5544 3,1 + ; D6 = ____NNMMFFEE7766 + VLD2.16 {D0[3],D2[3]},[r12], r1 ; D0 = PPOOGGHH99881100 3,1 + ; D2 = RRQQJJIIBBAA3322 + VLD2.16 {D4[3],D6[3]},[r12], r1 ; D4 = TTSSKKLLDDCC5544 3,1 + ; D6 = VVUUNNMMFFEE7766 + VTRN.8 D0, D4 ; D0 = SSOOKKGGCC884400 D4 = TTPPLLHHDD995511 1,1 + VTRN.8 D2, D6 ; D2 = UUQQMMIIEEAA6622 D6 = VVRRNNJJFFBB7733 1,1 + VSUBL.U8 Q0, D0, D6 ; Q0 = 00 - 33 in S16s 1,3 + VSUBL.U8 Q8, D2, D4 ; Q8 = 22 - 11 in S16s 1,3 + ADD r12,r0, #8 + VADD.S16 Q0, Q0, Q8 ; 1,3 + PLD [r12] + VADD.S16 Q0, Q0, Q8 ; 1,3 + PLD [r12,r1] + VADD.S16 Q0, Q0, Q8 ; Q0 = [0-3]+3*[2-1] 1,3 + PLD [r12,r1, LSL #1] + VRSHR.S16 Q0, Q0, #3 ; Q0 = f = ([0-3]+3*[2-1]+4)>>3 1,4 + ADD r12,r12,r1, LSL #2 + ; We want to do + ; f = CLAMP(MIN(-2L-f,0), f, MAX(2L-f,0)) + ; = ((f >= 0) ? MIN( f ,MAX(2L- f ,0)) : MAX( f , MIN(-2L- f ,0))) + ; = ((f >= 0) ? MIN(|f|,MAX(2L-|f|,0)) : MAX(-|f|, MIN(-2L+|f|,0))) + ; = ((f >= 0) ? MIN(|f|,MAX(2L-|f|,0)) :-MIN( |f|,-MIN(-2L+|f|,0))) + ; = ((f >= 0) ? MIN(|f|,MAX(2L-|f|,0)) :-MIN( |f|, MAX( 2L-|f|,0))) + ; So we've reduced the left and right hand terms to be the same, except + ; for a negation. + ; Stall x3 + VABS.S16 Q9, Q0 ; Q9 = |f| in U16s 1,4 + PLD [r12,-r1] + VSHR.S16 Q0, Q0, #15 ; Q0 = -1 or 0 according to sign 1,3 + PLD [r12] + VQSUB.U16 Q10,Q15,Q9 ; Q10= MAX(2L-|f|,0) in U16s 1,4 + PLD [r12,r1] + VMOVL.U8 Q1, D2 ; Q2 = __UU__QQ__MM__II__EE__AA__66__22 2,3 + PLD [r12,r1,LSL #1] + VMIN.U16 Q9, Q10,Q9 ; Q9 = MIN(|f|,MAX(2L-|f|)) 1,4 + ADD r12,r12,r1, LSL #2 + ; Now we need to correct for the sign of f. + ; For negative elements of Q0, we want to subtract the appropriate + ; element of Q9. For positive elements we want to add them. No NEON + ; instruction exists to do this, so we need to negate the negative + ; elements, and we can then just add them. a-b = a-(1+!b) = a-1+!b + VADD.S16 Q9, Q9, Q0 ; 1,3 + PLD [r12,-r1] + VEOR.S16 Q9, Q9, Q0 ; Q9 = real value of f 1,3 + ; Bah. No VRSBW.U8 + ; Stall (just 1 as Q9 not needed to second pipeline stage. I think.) + VADDW.U8 Q2, Q9, D4 ; Q1 = xxTTxxPPxxLLxxHHxxDDxx99xx55xx11 1,3 + VSUB.S16 Q1, Q1, Q9 ; Q2 = xxUUxxQQxxMMxxIIxxEExxAAxx66xx22 1,3 + VQMOVUN.S16 D4, Q2 ; D4 = TTPPLLHHDD995511 1,1 + VQMOVUN.S16 D2, Q1 ; D2 = UUQQMMIIEEAA6622 1,1 + SUB r12,r0, #1 + VTRN.8 D4, D2 ; D4 = QQPPIIHHAA992211 D2 = MMLLEEDD6655 1,1 + VST1.16 {D4[0]}, [r12], r1 + VST1.16 {D2[0]}, [r12], r1 + VST1.16 {D4[1]}, [r12], r1 + VST1.16 {D2[1]}, [r12], r1 + VST1.16 {D4[2]}, [r12], r1 + VST1.16 {D2[2]}, [r12], r1 + VST1.16 {D4[3]}, [r12], r1 + VST1.16 {D2[3]}, [r12], r1 + MOV PC,r14 + ENDP + +loop_filter_v_neon PROC + ; r0 = unsigned char *_pix + ; r1 = int _ystride + ; r2 = int *_bv + ; preserves r0-r3 + ; We assume Q15= 2*L in U16s + ; My best guesses at cycle counts (and latency)--vvv + SUB r12,r0, r1, LSL #1 + VLD1.64 {D0}, [r12@64], r1 ; D0 = SSOOKKGGCC884400 2,1 + VLD1.64 {D2}, [r12@64], r1 ; D2 = TTPPLLHHDD995511 2,1 + VLD1.64 {D4}, [r12@64], r1 ; D4 = UUQQMMIIEEAA6622 2,1 + VLD1.64 {D6}, [r12@64] ; D6 = VVRRNNJJFFBB7733 2,1 + VSUBL.U8 Q8, D4, D2 ; Q8 = 22 - 11 in S16s 1,3 + VSUBL.U8 Q0, D0, D6 ; Q0 = 00 - 33 in S16s 1,3 + ADD r12, #8 + VADD.S16 Q0, Q0, Q8 ; 1,3 + PLD [r12] + VADD.S16 Q0, Q0, Q8 ; 1,3 + PLD [r12,r1] + VADD.S16 Q0, Q0, Q8 ; Q0 = [0-3]+3*[2-1] 1,3 + SUB r12, r0, r1 + VRSHR.S16 Q0, Q0, #3 ; Q0 = f = ([0-3]+3*[2-1]+4)>>3 1,4 + ; We want to do + ; f = CLAMP(MIN(-2L-f,0), f, MAX(2L-f,0)) + ; = ((f >= 0) ? MIN( f ,MAX(2L- f ,0)) : MAX( f , MIN(-2L- f ,0))) + ; = ((f >= 0) ? MIN(|f|,MAX(2L-|f|,0)) : MAX(-|f|, MIN(-2L+|f|,0))) + ; = ((f >= 0) ? MIN(|f|,MAX(2L-|f|,0)) :-MIN( |f|,-MIN(-2L+|f|,0))) + ; = ((f >= 0) ? MIN(|f|,MAX(2L-|f|,0)) :-MIN( |f|, MAX( 2L-|f|,0))) + ; So we've reduced the left and right hand terms to be the same, except + ; for a negation. + ; Stall x3 + VABS.S16 Q9, Q0 ; Q9 = |f| in U16s 1,4 + VSHR.S16 Q0, Q0, #15 ; Q0 = -1 or 0 according to sign 1,3 + ; Stall x2 + VQSUB.U16 Q10,Q15,Q9 ; Q10= MAX(2L-|f|,0) in U16s 1,4 + VMOVL.U8 Q2, D4 ; Q2 = __UU__QQ__MM__II__EE__AA__66__22 2,3 + ; Stall x2 + VMIN.U16 Q9, Q10,Q9 ; Q9 = MIN(|f|,MAX(2L-|f|)) 1,4 + ; Now we need to correct for the sign of f. + ; For negative elements of Q0, we want to subtract the appropriate + ; element of Q9. For positive elements we want to add them. No NEON + ; instruction exists to do this, so we need to negate the negative + ; elements, and we can then just add them. a-b = a-(1+!b) = a-1+!b + ; Stall x3 + VADD.S16 Q9, Q9, Q0 ; 1,3 + ; Stall x2 + VEOR.S16 Q9, Q9, Q0 ; Q9 = real value of f 1,3 + ; Bah. No VRSBW.U8 + ; Stall (just 1 as Q9 not needed to second pipeline stage. I think.) + VADDW.U8 Q1, Q9, D2 ; Q1 = xxTTxxPPxxLLxxHHxxDDxx99xx55xx11 1,3 + VSUB.S16 Q2, Q2, Q9 ; Q2 = xxUUxxQQxxMMxxIIxxEExxAAxx66xx22 1,3 + VQMOVUN.S16 D2, Q1 ; D2 = TTPPLLHHDD995511 1,1 + VQMOVUN.S16 D4, Q2 ; D4 = UUQQMMIIEEAA6622 1,1 + VST1.64 {D2}, [r12@64], r1 + VST1.64 {D4}, [r12@64], r1 + MOV PC,r14 + ENDP + +oc_loop_filter_frag_rows_neon PROC + ; r0 = _ref_frame_data + ; r1 = _ystride + ; r2 = _bv + ; r3 = _frags + ; r4 = _fragi0 + ; r5 = _fragi0_end + ; r6 = _fragi_top + ; r7 = _fragi_bot + ; r8 = _frag_buf_offs + ; r9 = _nhfrags + MOV r12,r13 + STMFD r13!,{r0,r4-r11,r14} + LDMFD r12,{r4-r9} + CMP r4, r5 ; if(_fragi0>=_fragi0_end) + BGE oslffri_neon_end; bail + SUBS r9, r9, #1 ; r9 = _nhfrags-1 if (r9<=0) + BLE oslffri_neon_end ; bail + VLD1.64 {D30,D31}, [r2@128] ; Q15= 2L in U16s + ADD r3, r3, r4, LSL #2 ; r3 = &_frags[fragi] + ADD r8, r8, r4, LSL #2 ; r8 = &_frag_buf_offs[fragi] + SUB r7, r7, r9 ; _fragi_bot -= _nhfrags; +oslffri_neon_lp1 + MOV r10,r4 ; r10= fragi = _fragi0 + ADD r11,r4, r9 ; r11= fragi_end-1=fragi+_nhfrags-1 +oslffri_neon_lp2 + LDR r14,[r3], #4 ; r14= _frags[fragi] _frags++ + LDR r0, [r13] ; r0 = _ref_frame_data + LDR r12,[r8], #4 ; r12= _frag_buf_offs[fragi] _frag_buf_offs++ + TST r14,#OC_FRAG_CODED_FLAG + BEQ oslffri_neon_uncoded + CMP r10,r4 ; if (fragi>_fragi0) + ADD r0, r0, r12 ; r0 = _ref_frame_data + _frag_buf_offs[fragi] + BLGT loop_filter_h_neon + CMP r4, r6 ; if (_fragi0>_fragi_top) + BLGT loop_filter_v_neon + CMP r10,r11 ; if(fragi+1<fragi_end)===(fragi<fragi_end-1) + LDRLT r12,[r3] ; r12 = _frags[fragi+1] + ADD r0, r0, #8 + ADD r10,r10,#1 ; r10 = fragi+1; + ANDLT r12,r12,#OC_FRAG_CODED_FLAG + CMPLT r12,#OC_FRAG_CODED_FLAG ; && _frags[fragi+1].coded==0 + BLLT loop_filter_h_neon + CMP r10,r7 ; if (fragi<_fragi_bot) + LDRLT r12,[r3, r9, LSL #2] ; r12 = _frags[fragi+1+_nhfrags-1] + SUB r0, r0, #8 + ADD r0, r0, r1, LSL #3 + ANDLT r12,r12,#OC_FRAG_CODED_FLAG + CMPLT r12,#OC_FRAG_CODED_FLAG + BLLT loop_filter_v_neon + CMP r10,r11 ; while(fragi<=fragi_end-1) + BLE oslffri_neon_lp2 + MOV r4, r10 ; r4 = _fragi0 += _nhfrags + CMP r4, r5 + BLT oslffri_neon_lp1 +oslffri_neon_end + LDMFD r13!,{r0,r4-r11,PC} +oslffri_neon_uncoded + ADD r10,r10,#1 + CMP r10,r11 + BLE oslffri_neon_lp2 + MOV r4, r10 ; r4 = _fragi0 += _nhfrags + CMP r4, r5 + BLT oslffri_neon_lp1 + LDMFD r13!,{r0,r4-r11,PC} + ENDP + ] + + END diff --git a/media/libtheora/lib/arm/armopts.s b/media/libtheora/lib/arm/armopts.s new file mode 100644 index 0000000000..4dfdca9608 --- /dev/null +++ b/media/libtheora/lib/arm/armopts.s @@ -0,0 +1,39 @@ +;******************************************************************** +;* * +;* THIS FILE IS PART OF THE OggTheora SOFTWARE CODEC SOURCE CODE. * +;* USE, DISTRIBUTION AND REPRODUCTION OF THIS LIBRARY SOURCE IS * +;* GOVERNED BY A BSD-STYLE SOURCE LICENSE INCLUDED WITH THIS SOURCE * +;* IN 'COPYING'. PLEASE READ THESE TERMS BEFORE DISTRIBUTING. * +;* * +;* THE Theora SOURCE CODE IS COPYRIGHT (C) 2002-2010 * +;* by the Xiph.Org Foundation and contributors http://www.xiph.org/ * +;* * +;******************************************************************** +; Original implementation: +; Copyright (C) 2009 Robin Watts for Pinknoise Productions Ltd +; last mod: $Id$ +;******************************************************************** + +; Set the following to 1 if we have EDSP instructions +; (LDRD/STRD, etc., ARMv5E and later). +OC_ARM_ASM_EDSP * 1 + +; Set the following to 1 if we have ARMv6 media instructions. +OC_ARM_ASM_MEDIA * 1 + +; Set the following to 1 if we have NEON (some ARMv7) +OC_ARM_ASM_NEON * 1 + +; Set the following to 1 if LDR/STR can work on unaligned addresses +; This is assumed to be true for ARMv6 and later code +OC_ARM_CAN_UNALIGN * 0 + +; Large unaligned loads and stores are often configured to cause an exception. +; They cause an 8 cycle stall when they cross a 128-bit (load) or 64-bit (store) +; boundary, so it's usually a bad idea to use them anyway if they can be +; avoided. + +; Set the following to 1 if LDRD/STRD can work on unaligned addresses +OC_ARM_CAN_UNALIGN_LDRD * 0 + + END diff --git a/media/libtheora/lib/arm/armopts.s.in b/media/libtheora/lib/arm/armopts.s.in new file mode 100644 index 0000000000..ed91116ec6 --- /dev/null +++ b/media/libtheora/lib/arm/armopts.s.in @@ -0,0 +1,39 @@ +;******************************************************************** +;* * +;* THIS FILE IS PART OF THE OggTheora SOFTWARE CODEC SOURCE CODE. * +;* USE, DISTRIBUTION AND REPRODUCTION OF THIS LIBRARY SOURCE IS * +;* GOVERNED BY A BSD-STYLE SOURCE LICENSE INCLUDED WITH THIS SOURCE * +;* IN 'COPYING'. PLEASE READ THESE TERMS BEFORE DISTRIBUTING. * +;* * +;* THE Theora SOURCE CODE IS COPYRIGHT (C) 2002-2010 * +;* by the Xiph.Org Foundation and contributors http://www.xiph.org/ * +;* * +;******************************************************************** +; Original implementation: +; Copyright (C) 2009 Robin Watts for Pinknoise Productions Ltd +; last mod: $Id$ +;******************************************************************** + +; Set the following to 1 if we have EDSP instructions +; (LDRD/STRD, etc., ARMv5E and later). +OC_ARM_ASM_EDSP * @HAVE_ARM_ASM_EDSP@ + +; Set the following to 1 if we have ARMv6 media instructions. +OC_ARM_ASM_MEDIA * @HAVE_ARM_ASM_MEDIA@ + +; Set the following to 1 if we have NEON (some ARMv7) +OC_ARM_ASM_NEON * @HAVE_ARM_ASM_NEON@ + +; Set the following to 1 if LDR/STR can work on unaligned addresses +; This is assumed to be true for ARMv6 and later code +OC_ARM_CAN_UNALIGN * 0 + +; Large unaligned loads and stores are often configured to cause an exception. +; They cause an 8 cycle stall when they cross a 128-bit (load) or 64-bit (store) +; boundary, so it's usually a bad idea to use them anyway if they can be +; avoided. + +; Set the following to 1 if LDRD/STRD can work on unaligned addresses +OC_ARM_CAN_UNALIGN_LDRD * 0 + + END diff --git a/media/libtheora/lib/arm/armstate.c b/media/libtheora/lib/arm/armstate.c new file mode 100644 index 0000000000..a560608386 --- /dev/null +++ b/media/libtheora/lib/arm/armstate.c @@ -0,0 +1,219 @@ +/******************************************************************** + * * + * THIS FILE IS PART OF THE OggTheora SOFTWARE CODEC SOURCE CODE. * + * USE, DISTRIBUTION AND REPRODUCTION OF THIS LIBRARY SOURCE IS * + * GOVERNED BY A BSD-STYLE SOURCE LICENSE INCLUDED WITH THIS SOURCE * + * IN 'COPYING'. PLEASE READ THESE TERMS BEFORE DISTRIBUTING. * + * * + * THE Theora SOURCE CODE IS COPYRIGHT (C) 2002-2010 * + * by the Xiph.Org Foundation and contributors http://www.xiph.org/ * + * * + ******************************************************************** + + function: + last mod: $Id: x86state.c 17344 2010-07-21 01:42:18Z tterribe $ + + ********************************************************************/ +#include "armint.h" + +#if defined(OC_ARM_ASM) + +# if defined(OC_ARM_ASM_NEON) +/*This table has been modified from OC_FZIG_ZAG by baking an 8x8 transpose into + the destination.*/ +static const unsigned char OC_FZIG_ZAG_NEON[128]={ + 0, 8, 1, 2, 9,16,24,17, + 10, 3, 4,11,18,25,32,40, + 33,26,19,12, 5, 6,13,20, + 27,34,41,48,56,49,42,35, + 28,21,14, 7,15,22,29,36, + 43,50,57,58,51,44,37,30, + 23,31,38,45,52,59,60,53, + 46,39,47,54,61,62,55,63, + 64,64,64,64,64,64,64,64, + 64,64,64,64,64,64,64,64, + 64,64,64,64,64,64,64,64, + 64,64,64,64,64,64,64,64, + 64,64,64,64,64,64,64,64, + 64,64,64,64,64,64,64,64, + 64,64,64,64,64,64,64,64, + 64,64,64,64,64,64,64,64 +}; +# endif + +void oc_state_accel_init_arm(oc_theora_state *_state){ + oc_state_accel_init_c(_state); + _state->cpu_flags=oc_cpu_flags_get(); +# if defined(OC_STATE_USE_VTABLE) + _state->opt_vtable.frag_copy_list=oc_frag_copy_list_arm; + _state->opt_vtable.frag_recon_intra=oc_frag_recon_intra_arm; + _state->opt_vtable.frag_recon_inter=oc_frag_recon_inter_arm; + _state->opt_vtable.frag_recon_inter2=oc_frag_recon_inter2_arm; + _state->opt_vtable.idct8x8=oc_idct8x8_arm; + _state->opt_vtable.state_frag_recon=oc_state_frag_recon_arm; + /*Note: We _must_ set this function pointer, because the macro in armint.h + calls it with different arguments, so the C version will segfault.*/ + _state->opt_vtable.state_loop_filter_frag_rows= + (oc_state_loop_filter_frag_rows_func)oc_loop_filter_frag_rows_arm; +# endif +# if defined(OC_ARM_ASM_EDSP) + if(_state->cpu_flags&OC_CPU_ARM_EDSP){ +# if defined(OC_STATE_USE_VTABLE) + _state->opt_vtable.frag_copy_list=oc_frag_copy_list_edsp; +# endif + } +# if defined(OC_ARM_ASM_MEDIA) + if(_state->cpu_flags&OC_CPU_ARM_MEDIA){ +# if defined(OC_STATE_USE_VTABLE) + _state->opt_vtable.frag_recon_intra=oc_frag_recon_intra_v6; + _state->opt_vtable.frag_recon_inter=oc_frag_recon_inter_v6; + _state->opt_vtable.frag_recon_inter2=oc_frag_recon_inter2_v6; + _state->opt_vtable.idct8x8=oc_idct8x8_v6; + _state->opt_vtable.state_frag_recon=oc_state_frag_recon_v6; + _state->opt_vtable.loop_filter_init=oc_loop_filter_init_v6; + _state->opt_vtable.state_loop_filter_frag_rows= + (oc_state_loop_filter_frag_rows_func)oc_loop_filter_frag_rows_v6; +# endif + } +# if defined(OC_ARM_ASM_NEON) + if(_state->cpu_flags&OC_CPU_ARM_NEON){ +# if defined(OC_STATE_USE_VTABLE) + _state->opt_vtable.frag_copy_list=oc_frag_copy_list_neon; + _state->opt_vtable.frag_recon_intra=oc_frag_recon_intra_neon; + _state->opt_vtable.frag_recon_inter=oc_frag_recon_inter_neon; + _state->opt_vtable.frag_recon_inter2=oc_frag_recon_inter2_neon; + _state->opt_vtable.state_frag_recon=oc_state_frag_recon_neon; + _state->opt_vtable.loop_filter_init=oc_loop_filter_init_neon; + _state->opt_vtable.state_loop_filter_frag_rows= + (oc_state_loop_filter_frag_rows_func)oc_loop_filter_frag_rows_neon; + _state->opt_vtable.idct8x8=oc_idct8x8_neon; +# endif + _state->opt_data.dct_fzig_zag=OC_FZIG_ZAG_NEON; + } +# endif +# endif +# endif +} + +void oc_state_frag_recon_arm(const oc_theora_state *_state,ptrdiff_t _fragi, + int _pli,ogg_int16_t _dct_coeffs[128],int _last_zzi,ogg_uint16_t _dc_quant){ + unsigned char *dst; + ptrdiff_t frag_buf_off; + int ystride; + int refi; + /*Apply the inverse transform.*/ + /*Special case only having a DC component.*/ + if(_last_zzi<2){ + ogg_uint16_t p; + /*We round this dequant product (and not any of the others) because there's + no iDCT rounding.*/ + p=(ogg_uint16_t)(_dct_coeffs[0]*(ogg_int32_t)_dc_quant+15>>5); + oc_idct8x8_1_arm(_dct_coeffs+64,p); + } + else{ + /*First, dequantize the DC coefficient.*/ + _dct_coeffs[0]=(ogg_int16_t)(_dct_coeffs[0]*(int)_dc_quant); + oc_idct8x8_arm(_dct_coeffs+64,_dct_coeffs,_last_zzi); + } + /*Fill in the target buffer.*/ + frag_buf_off=_state->frag_buf_offs[_fragi]; + refi=_state->frags[_fragi].refi; + ystride=_state->ref_ystride[_pli]; + dst=_state->ref_frame_data[OC_FRAME_SELF]+frag_buf_off; + if(refi==OC_FRAME_SELF)oc_frag_recon_intra_arm(dst,ystride,_dct_coeffs+64); + else{ + const unsigned char *ref; + int mvoffsets[2]; + ref=_state->ref_frame_data[refi]+frag_buf_off; + if(oc_state_get_mv_offsets(_state,mvoffsets,_pli, + _state->frag_mvs[_fragi])>1){ + oc_frag_recon_inter2_arm(dst,ref+mvoffsets[0],ref+mvoffsets[1],ystride, + _dct_coeffs+64); + } + else oc_frag_recon_inter_arm(dst,ref+mvoffsets[0],ystride,_dct_coeffs+64); + } +} + +# if defined(OC_ARM_ASM_MEDIA) +void oc_state_frag_recon_v6(const oc_theora_state *_state,ptrdiff_t _fragi, + int _pli,ogg_int16_t _dct_coeffs[128],int _last_zzi,ogg_uint16_t _dc_quant){ + unsigned char *dst; + ptrdiff_t frag_buf_off; + int ystride; + int refi; + /*Apply the inverse transform.*/ + /*Special case only having a DC component.*/ + if(_last_zzi<2){ + ogg_uint16_t p; + /*We round this dequant product (and not any of the others) because there's + no iDCT rounding.*/ + p=(ogg_uint16_t)(_dct_coeffs[0]*(ogg_int32_t)_dc_quant+15>>5); + oc_idct8x8_1_v6(_dct_coeffs+64,p); + } + else{ + /*First, dequantize the DC coefficient.*/ + _dct_coeffs[0]=(ogg_int16_t)(_dct_coeffs[0]*(int)_dc_quant); + oc_idct8x8_v6(_dct_coeffs+64,_dct_coeffs,_last_zzi); + } + /*Fill in the target buffer.*/ + frag_buf_off=_state->frag_buf_offs[_fragi]; + refi=_state->frags[_fragi].refi; + ystride=_state->ref_ystride[_pli]; + dst=_state->ref_frame_data[OC_FRAME_SELF]+frag_buf_off; + if(refi==OC_FRAME_SELF)oc_frag_recon_intra_v6(dst,ystride,_dct_coeffs+64); + else{ + const unsigned char *ref; + int mvoffsets[2]; + ref=_state->ref_frame_data[refi]+frag_buf_off; + if(oc_state_get_mv_offsets(_state,mvoffsets,_pli, + _state->frag_mvs[_fragi])>1){ + oc_frag_recon_inter2_v6(dst,ref+mvoffsets[0],ref+mvoffsets[1],ystride, + _dct_coeffs+64); + } + else oc_frag_recon_inter_v6(dst,ref+mvoffsets[0],ystride,_dct_coeffs+64); + } +} + +# if defined(OC_ARM_ASM_NEON) +void oc_state_frag_recon_neon(const oc_theora_state *_state,ptrdiff_t _fragi, + int _pli,ogg_int16_t _dct_coeffs[128],int _last_zzi,ogg_uint16_t _dc_quant){ + unsigned char *dst; + ptrdiff_t frag_buf_off; + int ystride; + int refi; + /*Apply the inverse transform.*/ + /*Special case only having a DC component.*/ + if(_last_zzi<2){ + ogg_uint16_t p; + /*We round this dequant product (and not any of the others) because there's + no iDCT rounding.*/ + p=(ogg_uint16_t)(_dct_coeffs[0]*(ogg_int32_t)_dc_quant+15>>5); + oc_idct8x8_1_neon(_dct_coeffs+64,p); + } + else{ + /*First, dequantize the DC coefficient.*/ + _dct_coeffs[0]=(ogg_int16_t)(_dct_coeffs[0]*(int)_dc_quant); + oc_idct8x8_neon(_dct_coeffs+64,_dct_coeffs,_last_zzi); + } + /*Fill in the target buffer.*/ + frag_buf_off=_state->frag_buf_offs[_fragi]; + refi=_state->frags[_fragi].refi; + ystride=_state->ref_ystride[_pli]; + dst=_state->ref_frame_data[OC_FRAME_SELF]+frag_buf_off; + if(refi==OC_FRAME_SELF)oc_frag_recon_intra_neon(dst,ystride,_dct_coeffs+64); + else{ + const unsigned char *ref; + int mvoffsets[2]; + ref=_state->ref_frame_data[refi]+frag_buf_off; + if(oc_state_get_mv_offsets(_state,mvoffsets,_pli, + _state->frag_mvs[_fragi])>1){ + oc_frag_recon_inter2_neon(dst,ref+mvoffsets[0],ref+mvoffsets[1],ystride, + _dct_coeffs+64); + } + else oc_frag_recon_inter_neon(dst,ref+mvoffsets[0],ystride,_dct_coeffs+64); + } +} +# endif +# endif + +#endif diff --git a/media/libtheora/lib/bitpack.c b/media/libtheora/lib/bitpack.c new file mode 100644 index 0000000000..5125dde6b0 --- /dev/null +++ b/media/libtheora/lib/bitpack.c @@ -0,0 +1,114 @@ +/******************************************************************** + * * + * THIS FILE IS PART OF THE OggTheora SOFTWARE CODEC SOURCE CODE. * + * USE, DISTRIBUTION AND REPRODUCTION OF THIS LIBRARY SOURCE IS * + * GOVERNED BY A BSD-STYLE SOURCE LICENSE INCLUDED WITH THIS SOURCE * + * IN 'COPYING'. PLEASE READ THESE TERMS BEFORE DISTRIBUTING. * + * * + * THE OggTheora SOURCE CODE IS (C) COPYRIGHT 1994-2009 * + * by the Xiph.Org Foundation and contributors http://www.xiph.org/ * + * * + ******************************************************************** + + function: packing variable sized words into an octet stream + last mod: $Id$ + + ********************************************************************/ +#include <string.h> +#include <stdlib.h> +#include "bitpack.h" + +/*We're 'MSb' endian; if we write a word but read individual bits, + then we'll read the MSb first.*/ + +void oc_pack_readinit(oc_pack_buf *_b,unsigned char *_buf,long _bytes){ + memset(_b,0,sizeof(*_b)); + _b->ptr=_buf; + _b->stop=_buf+_bytes; +} + +static oc_pb_window oc_pack_refill(oc_pack_buf *_b,int _bits){ + const unsigned char *ptr; + const unsigned char *stop; + oc_pb_window window; + int available; + unsigned shift; + stop=_b->stop; + ptr=_b->ptr; + window=_b->window; + available=_b->bits; + shift=OC_PB_WINDOW_SIZE-available; + while(7<shift&&ptr<stop){ + shift-=8; + window|=(oc_pb_window)*ptr++<<shift; + } + _b->ptr=ptr; + available=OC_PB_WINDOW_SIZE-shift; + if(_bits>available){ + if(ptr>=stop){ + _b->eof=1; + available=OC_LOTS_OF_BITS; + } + else window|=*ptr>>(available&7); + } + _b->bits=available; + return window; +} + +int oc_pack_look1(oc_pack_buf *_b){ + oc_pb_window window; + int available; + window=_b->window; + available=_b->bits; + if(available<1)_b->window=window=oc_pack_refill(_b,1); + return window>>OC_PB_WINDOW_SIZE-1; +} + +void oc_pack_adv1(oc_pack_buf *_b){ + _b->window<<=1; + _b->bits--; +} + +/*Here we assume that 0<=_bits&&_bits<=32.*/ +long oc_pack_read_c(oc_pack_buf *_b,int _bits){ + oc_pb_window window; + int available; + long result; + window=_b->window; + available=_b->bits; + if(_bits==0)return 0; + if(available<_bits){ + window=oc_pack_refill(_b,_bits); + available=_b->bits; + } + result=window>>OC_PB_WINDOW_SIZE-_bits; + available-=_bits; + window<<=1; + window<<=_bits-1; + _b->window=window; + _b->bits=available; + return result; +} + +int oc_pack_read1_c(oc_pack_buf *_b){ + oc_pb_window window; + int available; + int result; + window=_b->window; + available=_b->bits; + if(available<1){ + window=oc_pack_refill(_b,1); + available=_b->bits; + } + result=window>>OC_PB_WINDOW_SIZE-1; + available--; + window<<=1; + _b->window=window; + _b->bits=available; + return result; +} + +long oc_pack_bytes_left(oc_pack_buf *_b){ + if(_b->eof)return -1; + return _b->stop-_b->ptr+(_b->bits>>3); +} diff --git a/media/libtheora/lib/bitpack.h b/media/libtheora/lib/bitpack.h new file mode 100644 index 0000000000..237b584055 --- /dev/null +++ b/media/libtheora/lib/bitpack.h @@ -0,0 +1,76 @@ +/******************************************************************** + * * + * THIS FILE IS PART OF THE OggTheora SOFTWARE CODEC SOURCE CODE. * + * USE, DISTRIBUTION AND REPRODUCTION OF THIS LIBRARY SOURCE IS * + * GOVERNED BY A BSD-STYLE SOURCE LICENSE INCLUDED WITH THIS SOURCE * + * IN 'COPYING'. PLEASE READ THESE TERMS BEFORE DISTRIBUTING. * + * * + * THE OggTheora SOURCE CODE IS (C) COPYRIGHT 1994-2009 * + * by the Xiph.Org Foundation and contributors http://www.xiph.org/ * + * * + ******************************************************************** + + function: packing variable sized words into an octet stream + last mod: $Id: bitwise.c 7675 2004-09-01 00:34:39Z xiphmont $ + + ********************************************************************/ +#if !defined(_bitpack_H) +# define _bitpack_H (1) +# include <stddef.h> +# include <limits.h> +# include "internal.h" + + + +typedef size_t oc_pb_window; +typedef struct oc_pack_buf oc_pack_buf; + + + +/*Custom bitpacker implementations.*/ +# if defined(OC_ARM_ASM) +# include "arm/armbits.h" +# endif + +# if !defined(oc_pack_read) +# define oc_pack_read oc_pack_read_c +# endif +# if !defined(oc_pack_read1) +# define oc_pack_read1 oc_pack_read1_c +# endif +# if !defined(oc_huff_token_decode) +# define oc_huff_token_decode oc_huff_token_decode_c +# endif + +# define OC_PB_WINDOW_SIZE ((int)sizeof(oc_pb_window)*CHAR_BIT) +/*This is meant to be a large, positive constant that can still be efficiently + loaded as an immediate (on platforms like ARM, for example). + Even relatively modest values like 100 would work fine.*/ +# define OC_LOTS_OF_BITS (0x40000000) + + + +struct oc_pack_buf{ + const unsigned char *stop; + const unsigned char *ptr; + oc_pb_window window; + int bits; + int eof; +}; + +void oc_pack_readinit(oc_pack_buf *_b,unsigned char *_buf,long _bytes); +int oc_pack_look1(oc_pack_buf *_b); +void oc_pack_adv1(oc_pack_buf *_b); +/*Here we assume 0<=_bits&&_bits<=32.*/ +long oc_pack_read_c(oc_pack_buf *_b,int _bits); +int oc_pack_read1_c(oc_pack_buf *_b); +/* returns -1 for read beyond EOF, or the number of whole bytes available */ +long oc_pack_bytes_left(oc_pack_buf *_b); + +/*These two functions are implemented locally in huffdec.c*/ +/*Read in bits without advancing the bitptr. + Here we assume 0<=_bits&&_bits<=32.*/ +/*static int oc_pack_look(oc_pack_buf *_b,int _bits);*/ +/*static void oc_pack_adv(oc_pack_buf *_b,int _bits);*/ + +#endif diff --git a/media/libtheora/lib/config.h b/media/libtheora/lib/config.h new file mode 100644 index 0000000000..e331b9977f --- /dev/null +++ b/media/libtheora/lib/config.h @@ -0,0 +1,103 @@ +/* config.h. Generated from config.h.in by configure. */ +/* config.h.in. Generated from configure.ac by autoheader. */ + +/* libcairo is available for visual debugging output */ +/* #undef HAVE_CAIRO */ + +/* Define to 1 if you have the <dlfcn.h> header file. */ +#define HAVE_DLFCN_H 1 + +/* Define to 1 if you have the <inttypes.h> header file. */ +#define HAVE_INTTYPES_H 1 + +/* Define to 1 if you have the <machine/soundcard.h> header file. */ +/* #undef HAVE_MACHINE_SOUNDCARD_H */ + +/* Abort if size exceeds 16384x16384 (for fuzzing only) */ +/* #undef HAVE_MEMORY_CONSTRAINT */ + +/* Define to 1 if you have the <soundcard.h> header file. */ +/* #undef HAVE_SOUNDCARD_H */ + +/* Define to 1 if you have the <stdint.h> header file. */ +#define HAVE_STDINT_H 1 + +/* Define to 1 if you have the <stdio.h> header file. */ +#define HAVE_STDIO_H 1 + +/* Define to 1 if you have the <stdlib.h> header file. */ +#define HAVE_STDLIB_H 1 + +/* Define to 1 if you have the <strings.h> header file. */ +#define HAVE_STRINGS_H 1 + +/* Define to 1 if you have the <string.h> header file. */ +#define HAVE_STRING_H 1 + +/* Define to 1 if you have the <sys/soundcard.h> header file. */ +#define HAVE_SYS_SOUNDCARD_H 1 + +/* Define to 1 if you have the <sys/stat.h> header file. */ +#define HAVE_SYS_STAT_H 1 + +/* Define to 1 if you have the <sys/types.h> header file. */ +#define HAVE_SYS_TYPES_H 1 + +/* Define to 1 if you have the <unistd.h> header file. */ +#define HAVE_UNISTD_H 1 + +/* Define to the sub-directory where libtool stores uninstalled libraries. */ +/* #undef LT_OBJDIR */ + +/* make use of arm asm optimization */ +/* #undef OC_ARM_ASM */ + +/* Define if assembler supports EDSP instructions */ +/* #undef OC_ARM_ASM_EDSP */ + +/* Define if assembler supports ARMv6 media instructions */ +/* #undef OC_ARM_ASM_MEDIA */ + +/* Define if compiler supports NEON instructions */ +/* #undef OC_ARM_ASM_NEON */ + +/* make use of c64x+ asm optimization */ +/* #undef OC_C64X_ASM */ + +/* make use of x86_64 asm optimization */ +/* #undef OC_X86_64_ASM */ + +/* make use of x86 asm optimization */ +/* #undef OC_X86_ASM */ + +/* Name of package */ +#define PACKAGE "libtheora" + +/* Define to the address where bug reports for this package should be sent. */ +#define PACKAGE_BUGREPORT "" + +/* Define to the full name of this package. */ +#define PACKAGE_NAME "libtheora" + +/* Define to the full name and version of this package. */ +#define PACKAGE_STRING "libtheora 1.2.0alpha1+git" + +/* Define to the one symbol short name of this package. */ +#define PACKAGE_TARNAME "libtheora" + +/* Define to the home page for this package. */ +#define PACKAGE_URL "" + +/* Define to the version of this package. */ +#define PACKAGE_VERSION "1.2.0alpha1+git" + +/* Define to 1 if all of the C90 standard headers exist (not just the ones + required in a freestanding environment). This macro is provided for + backward compatibility; new code need not use it. */ +#define STDC_HEADERS 1 + +/* Define to exclude encode support from the build */ +/* #undef THEORA_DISABLE_ENCODE */ + +/* Version number of package */ +#define VERSION "1.2.0alpha1+git" diff --git a/media/libtheora/lib/dct.h b/media/libtheora/lib/dct.h new file mode 100644 index 0000000000..8052ea6bc1 --- /dev/null +++ b/media/libtheora/lib/dct.h @@ -0,0 +1,31 @@ +/******************************************************************** + * * + * THIS FILE IS PART OF THE OggTheora SOFTWARE CODEC SOURCE CODE. * + * USE, DISTRIBUTION AND REPRODUCTION OF THIS LIBRARY SOURCE IS * + * GOVERNED BY A BSD-STYLE SOURCE LICENSE INCLUDED WITH THIS SOURCE * + * IN 'COPYING'. PLEASE READ THESE TERMS BEFORE DISTRIBUTING. * + * * + * THE Theora SOURCE CODE IS COPYRIGHT (C) 2002-2009 * + * by the Xiph.Org Foundation and contributors http://www.xiph.org/ * + * * + ******************************************************************** + + function: + last mod: $Id$ + + ********************************************************************/ + +/*Definitions shared by the forward and inverse DCT transforms.*/ +#if !defined(_dct_H) +# define _dct_H (1) + +/*cos(n*pi/16) (resp. sin(m*pi/16)) scaled by 65536.*/ +#define OC_C1S7 ((ogg_int32_t)64277) +#define OC_C2S6 ((ogg_int32_t)60547) +#define OC_C3S5 ((ogg_int32_t)54491) +#define OC_C4S4 ((ogg_int32_t)46341) +#define OC_C5S3 ((ogg_int32_t)36410) +#define OC_C6S2 ((ogg_int32_t)25080) +#define OC_C7S1 ((ogg_int32_t)12785) + +#endif diff --git a/media/libtheora/lib/decinfo.c b/media/libtheora/lib/decinfo.c new file mode 100644 index 0000000000..a91e740b15 --- /dev/null +++ b/media/libtheora/lib/decinfo.c @@ -0,0 +1,274 @@ +/******************************************************************** + * * + * THIS FILE IS PART OF THE OggTheora SOFTWARE CODEC SOURCE CODE. * + * USE, DISTRIBUTION AND REPRODUCTION OF THIS LIBRARY SOURCE IS * + * GOVERNED BY A BSD-STYLE SOURCE LICENSE INCLUDED WITH THIS SOURCE * + * IN 'COPYING'. PLEASE READ THESE TERMS BEFORE DISTRIBUTING. * + * * + * THE Theora SOURCE CODE IS COPYRIGHT (C) 2002-2009 * + * by the Xiph.Org Foundation and contributors http://www.xiph.org/ * + * * + ******************************************************************** + + function: + last mod: $Id$ + + ********************************************************************/ + +#include <stdlib.h> +#include <string.h> +#include <limits.h> +#include "decint.h" + +/*Only used for fuzzing.*/ +#if defined(HAVE_MEMORY_CONSTRAINT) +static const int MAX_FUZZING_WIDTH = 16384; +static const int MAX_FUZZING_HEIGHT = 16384; +#endif + + +/*Unpacks a series of octets from a given byte array into the pack buffer. + No checking is done to ensure the buffer contains enough data. + _opb: The pack buffer to read the octets from. + _buf: The byte array to store the unpacked bytes in. + _len: The number of octets to unpack.*/ +static void oc_unpack_octets(oc_pack_buf *_opb,char *_buf,size_t _len){ + while(_len-->0){ + long val; + val=oc_pack_read(_opb,8); + *_buf++=(char)val; + } +} + +/*Unpacks a 32-bit integer encoded by octets in little-endian form.*/ +static long oc_unpack_length(oc_pack_buf *_opb){ + long ret[4]; + int i; + for(i=0;i<4;i++)ret[i]=oc_pack_read(_opb,8); + return ret[0]|ret[1]<<8|ret[2]<<16|ret[3]<<24; +} + +static int oc_info_unpack(oc_pack_buf *_opb,th_info *_info){ + long val; + /*Check the codec bitstream version.*/ + val=oc_pack_read(_opb,8); + _info->version_major=(unsigned char)val; + val=oc_pack_read(_opb,8); + _info->version_minor=(unsigned char)val; + val=oc_pack_read(_opb,8); + _info->version_subminor=(unsigned char)val; + /*verify we can parse this bitstream version. + We accept earlier minors and all subminors, by spec*/ + if(_info->version_major>TH_VERSION_MAJOR|| + (_info->version_major==TH_VERSION_MAJOR&& + _info->version_minor>TH_VERSION_MINOR)){ + return TH_EVERSION; + } + /*Read the encoded frame description.*/ + val=oc_pack_read(_opb,16); + _info->frame_width=(ogg_uint32_t)val<<4; + val=oc_pack_read(_opb,16); + _info->frame_height=(ogg_uint32_t)val<<4; + val=oc_pack_read(_opb,24); + _info->pic_width=(ogg_uint32_t)val; + val=oc_pack_read(_opb,24); + _info->pic_height=(ogg_uint32_t)val; + val=oc_pack_read(_opb,8); + _info->pic_x=(ogg_uint32_t)val; + val=oc_pack_read(_opb,8); + _info->pic_y=(ogg_uint32_t)val; + val=oc_pack_read(_opb,32); + _info->fps_numerator=(ogg_uint32_t)val; + val=oc_pack_read(_opb,32); + _info->fps_denominator=(ogg_uint32_t)val; + if(_info->frame_width==0||_info->frame_height==0|| + _info->pic_width+_info->pic_x>_info->frame_width|| + _info->pic_height+_info->pic_y>_info->frame_height|| + _info->fps_numerator==0||_info->fps_denominator==0){ + return TH_EBADHEADER; + } +#if defined(HAVE_MEMORY_CONSTRAINT) + if(_info->frame_width>=MAX_FUZZING_WIDTH&&_info->frame_height>=MAX_FUZZING_HEIGHT){ + return TH_EBADHEADER; + } +#endif + /*Note: The sense of pic_y is inverted in what we pass back to the + application compared to how it is stored in the bitstream. + This is because the bitstream uses a right-handed coordinate system, while + applications expect a left-handed one.*/ + _info->pic_y=_info->frame_height-_info->pic_height-_info->pic_y; + val=oc_pack_read(_opb,24); + _info->aspect_numerator=(ogg_uint32_t)val; + val=oc_pack_read(_opb,24); + _info->aspect_denominator=(ogg_uint32_t)val; + val=oc_pack_read(_opb,8); + _info->colorspace=(th_colorspace)val; + val=oc_pack_read(_opb,24); + _info->target_bitrate=(int)val; + val=oc_pack_read(_opb,6); + _info->quality=(int)val; + val=oc_pack_read(_opb,5); + _info->keyframe_granule_shift=(int)val; + val=oc_pack_read(_opb,2); + _info->pixel_fmt=(th_pixel_fmt)val; + if(_info->pixel_fmt==TH_PF_RSVD)return TH_EBADHEADER; + val=oc_pack_read(_opb,3); + if(val!=0||oc_pack_bytes_left(_opb)<0)return TH_EBADHEADER; + return 0; +} + +static int oc_comment_unpack(oc_pack_buf *_opb,th_comment *_tc){ + long len; + int i; + /*Read the vendor string.*/ + len=oc_unpack_length(_opb); + if(len<0||len>oc_pack_bytes_left(_opb))return TH_EBADHEADER; + _tc->vendor=_ogg_malloc((size_t)len+1); + if(_tc->vendor==NULL)return TH_EFAULT; + oc_unpack_octets(_opb,_tc->vendor,len); + _tc->vendor[len]='\0'; + /*Read the user comments.*/ + _tc->comments=(int)oc_unpack_length(_opb); + len=_tc->comments; + if(len<0||len>(LONG_MAX>>2)||len<<2>oc_pack_bytes_left(_opb)){ + _tc->comments=0; + return TH_EBADHEADER; + } + _tc->comment_lengths=(int *)_ogg_malloc( + _tc->comments*sizeof(_tc->comment_lengths[0])); + _tc->user_comments=(char **)_ogg_malloc( + _tc->comments*sizeof(_tc->user_comments[0])); + if(_tc->comment_lengths==NULL||_tc->user_comments==NULL){ + _tc->comments=0; + return TH_EFAULT; + } + for(i=0;i<_tc->comments;i++){ + len=oc_unpack_length(_opb); + if(len<0||len>oc_pack_bytes_left(_opb)){ + _tc->comments=i; + return TH_EBADHEADER; + } + _tc->comment_lengths[i]=len; + _tc->user_comments[i]=_ogg_malloc((size_t)len+1); + if(_tc->user_comments[i]==NULL){ + _tc->comments=i; + return TH_EFAULT; + } + oc_unpack_octets(_opb,_tc->user_comments[i],len); + _tc->user_comments[i][len]='\0'; + } + return oc_pack_bytes_left(_opb)<0?TH_EBADHEADER:0; +} + +static int oc_setup_unpack(oc_pack_buf *_opb,th_setup_info *_setup){ + int ret; + /*Read the quantizer tables.*/ + ret=oc_quant_params_unpack(_opb,&_setup->qinfo); + if(ret<0)return ret; + /*Read the Huffman trees.*/ + return oc_huff_trees_unpack(_opb,_setup->huff_tables); +} + +static void oc_setup_clear(th_setup_info *_setup){ + oc_quant_params_clear(&_setup->qinfo); + oc_huff_trees_clear(_setup->huff_tables); +} + +static int oc_dec_headerin(oc_pack_buf *_opb,th_info *_info, + th_comment *_tc,th_setup_info **_setup,ogg_packet *_op){ + char buffer[6]; + long val; + int packtype; + int ret; + val=oc_pack_read(_opb,8); + packtype=(int)val; + /*If we're at a data packet...*/ + if(!(packtype&0x80)){ + /*Check to make sure we received all three headers... + If we haven't seen any valid headers, assume this is not actually + Theora.*/ + if(_info->frame_width<=0)return TH_ENOTFORMAT; + /*Follow our documentation, which says we'll return TH_EFAULT if this + are NULL (_info was checked by our caller).*/ + if(_tc==NULL)return TH_EFAULT; + /*And if any other headers were missing, declare this packet "out of + sequence" instead.*/ + if(_tc->vendor==NULL)return TH_EBADHEADER; + /*Don't check this until it's needed, since we allow passing NULL for the + arguments that we're not expecting the next header to fill in yet.*/ + if(_setup==NULL)return TH_EFAULT; + if(*_setup==NULL)return TH_EBADHEADER; + /*If we got everything, we're done.*/ + return 0; + } + /*Check the codec string.*/ + oc_unpack_octets(_opb,buffer,6); + if(memcmp(buffer,"theora",6)!=0)return TH_ENOTFORMAT; + switch(packtype){ + /*Codec info header.*/ + case 0x80:{ + /*This should be the first packet, and we should not already be + initialized.*/ + if(!_op->b_o_s||_info->frame_width>0)return TH_EBADHEADER; + ret=oc_info_unpack(_opb,_info); + if(ret<0)th_info_clear(_info); + else ret=3; + }break; + /*Comment header.*/ + case 0x81:{ + if(_tc==NULL)return TH_EFAULT; + /*We shoud have already decoded the info header, and should not yet have + decoded the comment header.*/ + if(_info->frame_width==0||_tc->vendor!=NULL)return TH_EBADHEADER; + ret=oc_comment_unpack(_opb,_tc); + if(ret<0)th_comment_clear(_tc); + else ret=2; + }break; + /*Codec setup header.*/ + case 0x82:{ + oc_setup_info *setup; + if(_tc==NULL||_setup==NULL)return TH_EFAULT; + /*We should have already decoded the info header and the comment header, + and should not yet have decoded the setup header.*/ + if(_info->frame_width==0||_tc->vendor==NULL||*_setup!=NULL){ + return TH_EBADHEADER; + } + setup=(oc_setup_info *)_ogg_calloc(1,sizeof(*setup)); + if(setup==NULL)return TH_EFAULT; + ret=oc_setup_unpack(_opb,setup); + if(ret<0){ + oc_setup_clear(setup); + _ogg_free(setup); + } + else{ + *_setup=setup; + ret=1; + } + }break; + default:{ + /*We don't know what this header is.*/ + return TH_EBADHEADER; + }break; + } + return ret; +} + + +/*Decodes one header packet. + This should be called repeatedly with the packets at the beginning of the + stream until it returns 0.*/ +int th_decode_headerin(th_info *_info,th_comment *_tc, + th_setup_info **_setup,ogg_packet *_op){ + oc_pack_buf opb; + if(_op==NULL)return TH_EBADHEADER; + if(_info==NULL)return TH_EFAULT; + oc_pack_readinit(&opb,_op->packet,_op->bytes); + return oc_dec_headerin(&opb,_info,_tc,_setup,_op); +} + +void th_setup_free(th_setup_info *_setup){ + if(_setup!=NULL){ + oc_setup_clear(_setup); + _ogg_free(_setup); + } +} diff --git a/media/libtheora/lib/decint.h b/media/libtheora/lib/decint.h new file mode 100644 index 0000000000..3cea6b1439 --- /dev/null +++ b/media/libtheora/lib/decint.h @@ -0,0 +1,185 @@ +/******************************************************************** + * * + * THIS FILE IS PART OF THE OggTheora SOFTWARE CODEC SOURCE CODE. * + * USE, DISTRIBUTION AND REPRODUCTION OF THIS LIBRARY SOURCE IS * + * GOVERNED BY A BSD-STYLE SOURCE LICENSE INCLUDED WITH THIS SOURCE * + * IN 'COPYING'. PLEASE READ THESE TERMS BEFORE DISTRIBUTING. * + * * + * THE Theora SOURCE CODE IS COPYRIGHT (C) 2002-2009 * + * by the Xiph.Org Foundation and contributors http://www.xiph.org/ * + * * + ******************************************************************** + + function: + last mod: $Id$ + + ********************************************************************/ + +#include <limits.h> +#if !defined(_decint_H) +# define _decint_H (1) +# include "theora/theoradec.h" +# include "state.h" +# include "bitpack.h" +# include "huffdec.h" +# include "dequant.h" + +typedef struct th_setup_info oc_setup_info; +typedef struct oc_dec_opt_vtable oc_dec_opt_vtable; +typedef struct oc_dec_pipeline_state oc_dec_pipeline_state; +typedef struct th_dec_ctx oc_dec_ctx; + + + +/*Decoder-specific accelerated functions.*/ +# if defined(OC_C64X_ASM) +# include "c64x/c64xdec.h" +# endif + +# if !defined(oc_dec_accel_init) +# define oc_dec_accel_init oc_dec_accel_init_c +# endif +# if defined(OC_DEC_USE_VTABLE) +# if !defined(oc_dec_dc_unpredict_mcu_plane) +# define oc_dec_dc_unpredict_mcu_plane(_dec,_pipe,_pli) \ + ((*(_dec)->opt_vtable.dc_unpredict_mcu_plane)(_dec,_pipe,_pli)) +# endif +# else +# if !defined(oc_dec_dc_unpredict_mcu_plane) +# define oc_dec_dc_unpredict_mcu_plane oc_dec_dc_unpredict_mcu_plane_c +# endif +# endif + + + +/*Constants for the packet-in state machine specific to the decoder.*/ + +/*Next packet to read: Data packet.*/ +#define OC_PACKET_DATA (0) + + + +struct th_setup_info{ + /*The Huffman codes.*/ + ogg_int16_t *huff_tables[TH_NHUFFMAN_TABLES]; + /*The quantization parameters.*/ + th_quant_info qinfo; +}; + + + +/*Decoder specific functions with accelerated variants.*/ +struct oc_dec_opt_vtable{ + void (*dc_unpredict_mcu_plane)(oc_dec_ctx *_dec, + oc_dec_pipeline_state *_pipe,int _pli); +}; + + + +struct oc_dec_pipeline_state{ + /*Decoded DCT coefficients. + These are placed here instead of on the stack so that they can persist + between blocks, which makes clearing them back to zero much faster when + only a few non-zero coefficients were decoded. + It requires at least 65 elements because the zig-zag index array uses the + 65th element as a dumping ground for out-of-range indices to protect us + from buffer overflow. + We make it fully twice as large so that the second half can serve as the + reconstruction buffer, which saves passing another parameter to all the + acceleration functios. + It also solves problems with 16-byte alignment for NEON on ARM. + gcc (as of 4.2.1) only seems to be able to give stack variables 8-byte + alignment, and silently produces incorrect results if you ask for 16. + Finally, keeping it off the stack means there's less likely to be a data + hazard beween the NEON co-processor and the regular ARM core, which avoids + unnecessary stalls.*/ + OC_ALIGN16(ogg_int16_t dct_coeffs[128]); + OC_ALIGN16(signed char bounding_values[256]); + ptrdiff_t ti[3][64]; + ptrdiff_t ebi[3][64]; + ptrdiff_t eob_runs[3][64]; + const ptrdiff_t *coded_fragis[3]; + const ptrdiff_t *uncoded_fragis[3]; + ptrdiff_t ncoded_fragis[3]; + ptrdiff_t nuncoded_fragis[3]; + const ogg_uint16_t *dequant[3][3][2]; + int fragy0[3]; + int fragy_end[3]; + int pred_last[3][4]; + int mcu_nvfrags; + int loop_filter; + int pp_level; +}; + + +struct th_dec_ctx{ + /*Shared encoder/decoder state.*/ + oc_theora_state state; + /*Whether or not packets are ready to be emitted. + This takes on negative values while there are remaining header packets to + be emitted, reaches 0 when the codec is ready for input, and goes to 1 + when a frame has been processed and a data packet is ready.*/ + int packet_state; + /*Buffer in which to assemble packets.*/ + oc_pack_buf opb; + /*Huffman decode trees.*/ + ogg_int16_t *huff_tables[TH_NHUFFMAN_TABLES]; + /*The index of the first token in each plane for each coefficient.*/ + ptrdiff_t ti0[3][64]; + /*The number of outstanding EOB runs at the start of each coefficient in each + plane.*/ + ptrdiff_t eob_runs[3][64]; + /*The DCT token lists.*/ + unsigned char *dct_tokens; + /*The extra bits associated with DCT tokens.*/ + unsigned char *extra_bits; + /*The number of dct tokens unpacked so far.*/ + int dct_tokens_count; + /*The out-of-loop post-processing level.*/ + int pp_level; + /*The DC scale used for out-of-loop deblocking.*/ + int pp_dc_scale[64]; + /*The sharpen modifier used for out-of-loop deringing.*/ + int pp_sharp_mod[64]; + /*The DC quantization index of each block.*/ + unsigned char *dc_qis; + /*The variance of each block.*/ + int *variances; + /*The storage for the post-processed frame buffer.*/ + unsigned char *pp_frame_data; + /*Whether or not the post-processsed frame buffer has space for chroma.*/ + int pp_frame_state; + /*The buffer used for the post-processed frame. + Note that this is _not_ guaranteed to have the same strides and offsets as + the reference frame buffers.*/ + th_ycbcr_buffer pp_frame_buf; + /*The striped decode callback function.*/ + th_stripe_callback stripe_cb; + oc_dec_pipeline_state pipe; +# if defined(OC_DEC_USE_VTABLE) + /*Table for decoder acceleration functions.*/ + oc_dec_opt_vtable opt_vtable; +# endif +# if defined(HAVE_CAIRO) + /*Output metrics for debugging.*/ + int telemetry_mbmode; + int telemetry_mv; + int telemetry_qi; + int telemetry_bits; + int telemetry_frame_bytes; + int telemetry_coding_bytes; + int telemetry_mode_bytes; + int telemetry_mv_bytes; + int telemetry_qi_bytes; + int telemetry_dc_bytes; + unsigned char *telemetry_frame_data; +# endif +}; + +/*Default pure-C implementations of decoder-specific accelerated functions.*/ +void oc_dec_accel_init_c(oc_dec_ctx *_dec); + +void oc_dec_dc_unpredict_mcu_plane_c(oc_dec_ctx *_dec, + oc_dec_pipeline_state *_pipe,int _pli); + +#endif diff --git a/media/libtheora/lib/decode.c b/media/libtheora/lib/decode.c new file mode 100644 index 0000000000..fad26e0927 --- /dev/null +++ b/media/libtheora/lib/decode.c @@ -0,0 +1,2992 @@ +/******************************************************************** + * * + * THIS FILE IS PART OF THE OggTheora SOFTWARE CODEC SOURCE CODE. * + * USE, DISTRIBUTION AND REPRODUCTION OF THIS LIBRARY SOURCE IS * + * GOVERNED BY A BSD-STYLE SOURCE LICENSE INCLUDED WITH THIS SOURCE * + * IN 'COPYING'. PLEASE READ THESE TERMS BEFORE DISTRIBUTING. * + * * + * THE Theora SOURCE CODE IS COPYRIGHT (C) 2002-2009 * + * by the Xiph.Org Foundation and contributors http://www.xiph.org/ * + * * + ******************************************************************** + + function: + last mod: $Id$ + + ********************************************************************/ + +#include <stdlib.h> +#include <string.h> +#include <ogg/ogg.h> +#include "decint.h" +#if defined(OC_DUMP_IMAGES) +# include <stdio.h> +# include "png.h" +#endif +#if defined(HAVE_CAIRO) +# include <cairo.h> +#endif + + +/*No post-processing.*/ +#define OC_PP_LEVEL_DISABLED (0) +/*Keep track of DC qi for each block only.*/ +#define OC_PP_LEVEL_TRACKDCQI (1) +/*Deblock the luma plane.*/ +#define OC_PP_LEVEL_DEBLOCKY (2) +/*Dering the luma plane.*/ +#define OC_PP_LEVEL_DERINGY (3) +/*Stronger luma plane deringing.*/ +#define OC_PP_LEVEL_SDERINGY (4) +/*Deblock the chroma planes.*/ +#define OC_PP_LEVEL_DEBLOCKC (5) +/*Dering the chroma planes.*/ +#define OC_PP_LEVEL_DERINGC (6) +/*Stronger chroma plane deringing.*/ +#define OC_PP_LEVEL_SDERINGC (7) +/*Maximum valid post-processing level.*/ +#define OC_PP_LEVEL_MAX (7) + + + +/*The mode alphabets for the various mode coding schemes. + Scheme 0 uses a custom alphabet, which is not stored in this table.*/ +static const unsigned char OC_MODE_ALPHABETS[7][OC_NMODES]={ + /*Last MV dominates */ + { + OC_MODE_INTER_MV_LAST,OC_MODE_INTER_MV_LAST2,OC_MODE_INTER_MV, + OC_MODE_INTER_NOMV,OC_MODE_INTRA,OC_MODE_GOLDEN_NOMV,OC_MODE_GOLDEN_MV, + OC_MODE_INTER_MV_FOUR + }, + { + OC_MODE_INTER_MV_LAST,OC_MODE_INTER_MV_LAST2,OC_MODE_INTER_NOMV, + OC_MODE_INTER_MV,OC_MODE_INTRA,OC_MODE_GOLDEN_NOMV,OC_MODE_GOLDEN_MV, + OC_MODE_INTER_MV_FOUR + }, + { + OC_MODE_INTER_MV_LAST,OC_MODE_INTER_MV,OC_MODE_INTER_MV_LAST2, + OC_MODE_INTER_NOMV,OC_MODE_INTRA,OC_MODE_GOLDEN_NOMV,OC_MODE_GOLDEN_MV, + OC_MODE_INTER_MV_FOUR + }, + { + OC_MODE_INTER_MV_LAST,OC_MODE_INTER_MV,OC_MODE_INTER_NOMV, + OC_MODE_INTER_MV_LAST2,OC_MODE_INTRA,OC_MODE_GOLDEN_NOMV, + OC_MODE_GOLDEN_MV,OC_MODE_INTER_MV_FOUR + }, + /*No MV dominates.*/ + { + OC_MODE_INTER_NOMV,OC_MODE_INTER_MV_LAST,OC_MODE_INTER_MV_LAST2, + OC_MODE_INTER_MV,OC_MODE_INTRA,OC_MODE_GOLDEN_NOMV,OC_MODE_GOLDEN_MV, + OC_MODE_INTER_MV_FOUR + }, + { + OC_MODE_INTER_NOMV,OC_MODE_GOLDEN_NOMV,OC_MODE_INTER_MV_LAST, + OC_MODE_INTER_MV_LAST2,OC_MODE_INTER_MV,OC_MODE_INTRA,OC_MODE_GOLDEN_MV, + OC_MODE_INTER_MV_FOUR + }, + /*Default ordering.*/ + { + OC_MODE_INTER_NOMV,OC_MODE_INTRA,OC_MODE_INTER_MV,OC_MODE_INTER_MV_LAST, + OC_MODE_INTER_MV_LAST2,OC_MODE_GOLDEN_NOMV,OC_MODE_GOLDEN_MV, + OC_MODE_INTER_MV_FOUR + } +}; + + +/*The original DCT tokens are extended and reordered during the construction of + the Huffman tables. + The extension means more bits can be read with fewer calls to the bitpacker + during the Huffman decoding process (at the cost of larger Huffman tables), + and fewer tokens require additional extra bits (reducing the average storage + per decoded token). + The revised ordering reveals essential information in the token value + itself; specifically, whether or not there are additional extra bits to read + and the parameter to which those extra bits are applied. + The token is used to fetch a code word from the OC_DCT_CODE_WORD table below. + The extra bits are added into code word at the bit position inferred from the + token value, giving the final code word from which all required parameters + are derived. + The number of EOBs and the leading zero run length can be extracted directly. + The coefficient magnitude is optionally negated before extraction, according + to a 'flip' bit.*/ + +/*The number of additional extra bits that are decoded with each of the + internal DCT tokens.*/ +static const unsigned char OC_INTERNAL_DCT_TOKEN_EXTRA_BITS[15]={ + 12,4,3,3,4,4,5,5,8,8,8,8,3,3,6 +}; + +/*Whether or not an internal token needs any additional extra bits.*/ +#define OC_DCT_TOKEN_NEEDS_MORE(token) \ + (token<(int)(sizeof(OC_INTERNAL_DCT_TOKEN_EXTRA_BITS)/ \ + sizeof(*OC_INTERNAL_DCT_TOKEN_EXTRA_BITS))) + +/*This token (OC_DCT_REPEAT_RUN3_TOKEN) requires more than 8 extra bits.*/ +#define OC_DCT_TOKEN_FAT_EOB (0) + +/*The number of EOBs to use for an end-of-frame token. + Note: We want to set eobs to PTRDIFF_MAX here, but that requires C99, which + is not yet available everywhere; this should be equivalent.*/ +#define OC_DCT_EOB_FINISH (~(size_t)0>>1) + +/*The location of the (6) run length bits in the code word. + These are placed at index 0 and given 8 bits (even though 6 would suffice) + because it may be faster to extract the lower byte on some platforms.*/ +#define OC_DCT_CW_RLEN_SHIFT (0) +/*The location of the (12) EOB bits in the code word.*/ +#define OC_DCT_CW_EOB_SHIFT (8) +/*The location of the (1) flip bit in the code word. + This must be right under the magnitude bits.*/ +#define OC_DCT_CW_FLIP_BIT (20) +/*The location of the (11) token magnitude bits in the code word. + These must be last, and rely on a sign-extending right shift.*/ +#define OC_DCT_CW_MAG_SHIFT (21) + +/*Pack the given fields into a code word.*/ +#define OC_DCT_CW_PACK(_eobs,_rlen,_mag,_flip) \ + ((_eobs)<<OC_DCT_CW_EOB_SHIFT| \ + (_rlen)<<OC_DCT_CW_RLEN_SHIFT| \ + (_flip)<<OC_DCT_CW_FLIP_BIT| \ + (_mag)-(_flip)<<OC_DCT_CW_MAG_SHIFT) + +/*A special code word value that signals the end of the frame (a long EOB run + of zero).*/ +#define OC_DCT_CW_FINISH (0) + +/*The position at which to insert the extra bits in the code word. + We use this formulation because Intel has no useful cmov. + A real architecture would probably do better with two of those. + This translates to 11 instructions(!), and is _still_ faster than either a + table lookup (just barely) or the naive double-ternary implementation (which + gcc translates to a jump and a cmov). + This assumes OC_DCT_CW_RLEN_SHIFT is zero, but could easily be reworked if + you want to make one of the other shifts zero.*/ +#define OC_DCT_TOKEN_EB_POS(_token) \ + ((OC_DCT_CW_EOB_SHIFT-OC_DCT_CW_MAG_SHIFT&-((_token)<2)) \ + +(OC_DCT_CW_MAG_SHIFT&-((_token)<12))) + +/*The code words for each internal token. + See the notes at OC_DCT_TOKEN_MAP for the reasons why things are out of + order.*/ +static const ogg_int32_t OC_DCT_CODE_WORD[92]={ + /*These tokens require additional extra bits for the EOB count.*/ + /*OC_DCT_REPEAT_RUN3_TOKEN (12 extra bits)*/ + OC_DCT_CW_FINISH, + /*OC_DCT_REPEAT_RUN2_TOKEN (4 extra bits)*/ + OC_DCT_CW_PACK(16, 0, 0,0), + /*These tokens require additional extra bits for the magnitude.*/ + /*OC_DCT_VAL_CAT5 (4 extra bits-1 already read)*/ + OC_DCT_CW_PACK( 0, 0, 13,0), + OC_DCT_CW_PACK( 0, 0, 13,1), + /*OC_DCT_VAL_CAT6 (5 extra bits-1 already read)*/ + OC_DCT_CW_PACK( 0, 0, 21,0), + OC_DCT_CW_PACK( 0, 0, 21,1), + /*OC_DCT_VAL_CAT7 (6 extra bits-1 already read)*/ + OC_DCT_CW_PACK( 0, 0, 37,0), + OC_DCT_CW_PACK( 0, 0, 37,1), + /*OC_DCT_VAL_CAT8 (10 extra bits-2 already read)*/ + OC_DCT_CW_PACK( 0, 0, 69,0), + OC_DCT_CW_PACK( 0, 0,325,0), + OC_DCT_CW_PACK( 0, 0, 69,1), + OC_DCT_CW_PACK( 0, 0,325,1), + /*These tokens require additional extra bits for the run length.*/ + /*OC_DCT_RUN_CAT1C (4 extra bits-1 already read)*/ + OC_DCT_CW_PACK( 0,10, +1,0), + OC_DCT_CW_PACK( 0,10, -1,0), + /*OC_DCT_ZRL_TOKEN (6 extra bits) + Flip is set to distinguish this from OC_DCT_CW_FINISH.*/ + OC_DCT_CW_PACK( 0, 0, 0,1), + /*The remaining tokens require no additional extra bits.*/ + /*OC_DCT_EOB1_TOKEN (0 extra bits)*/ + OC_DCT_CW_PACK( 1, 0, 0,0), + /*OC_DCT_EOB2_TOKEN (0 extra bits)*/ + OC_DCT_CW_PACK( 2, 0, 0,0), + /*OC_DCT_EOB3_TOKEN (0 extra bits)*/ + OC_DCT_CW_PACK( 3, 0, 0,0), + /*OC_DCT_RUN_CAT1A (1 extra bit-1 already read)x5*/ + OC_DCT_CW_PACK( 0, 1, +1,0), + OC_DCT_CW_PACK( 0, 1, -1,0), + OC_DCT_CW_PACK( 0, 2, +1,0), + OC_DCT_CW_PACK( 0, 2, -1,0), + OC_DCT_CW_PACK( 0, 3, +1,0), + OC_DCT_CW_PACK( 0, 3, -1,0), + OC_DCT_CW_PACK( 0, 4, +1,0), + OC_DCT_CW_PACK( 0, 4, -1,0), + OC_DCT_CW_PACK( 0, 5, +1,0), + OC_DCT_CW_PACK( 0, 5, -1,0), + /*OC_DCT_RUN_CAT2A (2 extra bits-2 already read)*/ + OC_DCT_CW_PACK( 0, 1, +2,0), + OC_DCT_CW_PACK( 0, 1, +3,0), + OC_DCT_CW_PACK( 0, 1, -2,0), + OC_DCT_CW_PACK( 0, 1, -3,0), + /*OC_DCT_RUN_CAT1B (3 extra bits-3 already read)*/ + OC_DCT_CW_PACK( 0, 6, +1,0), + OC_DCT_CW_PACK( 0, 7, +1,0), + OC_DCT_CW_PACK( 0, 8, +1,0), + OC_DCT_CW_PACK( 0, 9, +1,0), + OC_DCT_CW_PACK( 0, 6, -1,0), + OC_DCT_CW_PACK( 0, 7, -1,0), + OC_DCT_CW_PACK( 0, 8, -1,0), + OC_DCT_CW_PACK( 0, 9, -1,0), + /*OC_DCT_RUN_CAT2B (3 extra bits-3 already read)*/ + OC_DCT_CW_PACK( 0, 2, +2,0), + OC_DCT_CW_PACK( 0, 3, +2,0), + OC_DCT_CW_PACK( 0, 2, +3,0), + OC_DCT_CW_PACK( 0, 3, +3,0), + OC_DCT_CW_PACK( 0, 2, -2,0), + OC_DCT_CW_PACK( 0, 3, -2,0), + OC_DCT_CW_PACK( 0, 2, -3,0), + OC_DCT_CW_PACK( 0, 3, -3,0), + /*OC_DCT_SHORT_ZRL_TOKEN (3 extra bits-3 already read) + Flip is set on the first one to distinguish it from OC_DCT_CW_FINISH.*/ + OC_DCT_CW_PACK( 0, 0, 0,1), + OC_DCT_CW_PACK( 0, 1, 0,0), + OC_DCT_CW_PACK( 0, 2, 0,0), + OC_DCT_CW_PACK( 0, 3, 0,0), + OC_DCT_CW_PACK( 0, 4, 0,0), + OC_DCT_CW_PACK( 0, 5, 0,0), + OC_DCT_CW_PACK( 0, 6, 0,0), + OC_DCT_CW_PACK( 0, 7, 0,0), + /*OC_ONE_TOKEN (0 extra bits)*/ + OC_DCT_CW_PACK( 0, 0, +1,0), + /*OC_MINUS_ONE_TOKEN (0 extra bits)*/ + OC_DCT_CW_PACK( 0, 0, -1,0), + /*OC_TWO_TOKEN (0 extra bits)*/ + OC_DCT_CW_PACK( 0, 0, +2,0), + /*OC_MINUS_TWO_TOKEN (0 extra bits)*/ + OC_DCT_CW_PACK( 0, 0, -2,0), + /*OC_DCT_VAL_CAT2 (1 extra bit-1 already read)x4*/ + OC_DCT_CW_PACK( 0, 0, +3,0), + OC_DCT_CW_PACK( 0, 0, -3,0), + OC_DCT_CW_PACK( 0, 0, +4,0), + OC_DCT_CW_PACK( 0, 0, -4,0), + OC_DCT_CW_PACK( 0, 0, +5,0), + OC_DCT_CW_PACK( 0, 0, -5,0), + OC_DCT_CW_PACK( 0, 0, +6,0), + OC_DCT_CW_PACK( 0, 0, -6,0), + /*OC_DCT_VAL_CAT3 (2 extra bits-2 already read)*/ + OC_DCT_CW_PACK( 0, 0, +7,0), + OC_DCT_CW_PACK( 0, 0, +8,0), + OC_DCT_CW_PACK( 0, 0, -7,0), + OC_DCT_CW_PACK( 0, 0, -8,0), + /*OC_DCT_VAL_CAT4 (3 extra bits-3 already read)*/ + OC_DCT_CW_PACK( 0, 0, +9,0), + OC_DCT_CW_PACK( 0, 0,+10,0), + OC_DCT_CW_PACK( 0, 0,+11,0), + OC_DCT_CW_PACK( 0, 0,+12,0), + OC_DCT_CW_PACK( 0, 0, -9,0), + OC_DCT_CW_PACK( 0, 0,-10,0), + OC_DCT_CW_PACK( 0, 0,-11,0), + OC_DCT_CW_PACK( 0, 0,-12,0), + /*OC_DCT_REPEAT_RUN1_TOKEN (3 extra bits-3 already read)*/ + OC_DCT_CW_PACK( 8, 0, 0,0), + OC_DCT_CW_PACK( 9, 0, 0,0), + OC_DCT_CW_PACK(10, 0, 0,0), + OC_DCT_CW_PACK(11, 0, 0,0), + OC_DCT_CW_PACK(12, 0, 0,0), + OC_DCT_CW_PACK(13, 0, 0,0), + OC_DCT_CW_PACK(14, 0, 0,0), + OC_DCT_CW_PACK(15, 0, 0,0), + /*OC_DCT_REPEAT_RUN0_TOKEN (2 extra bits-2 already read)*/ + OC_DCT_CW_PACK( 4, 0, 0,0), + OC_DCT_CW_PACK( 5, 0, 0,0), + OC_DCT_CW_PACK( 6, 0, 0,0), + OC_DCT_CW_PACK( 7, 0, 0,0), +}; + + + +static int oc_sb_run_unpack(oc_pack_buf *_opb){ + /*Coding scheme: + Codeword Run Length + 0 1 + 10x 2-3 + 110x 4-5 + 1110xx 6-9 + 11110xxx 10-17 + 111110xxxx 18-33 + 111111xxxxxxxxxxxx 34-4129*/ + static const ogg_int16_t OC_SB_RUN_TREE[22]={ + 4, + -(1<<8|1),-(1<<8|1),-(1<<8|1),-(1<<8|1), + -(1<<8|1),-(1<<8|1),-(1<<8|1),-(1<<8|1), + -(3<<8|2),-(3<<8|2),-(3<<8|3),-(3<<8|3), + -(4<<8|4),-(4<<8|5),-(4<<8|2<<4|6-6),17, + 2, + -(2<<8|2<<4|10-6),-(2<<8|2<<4|14-6),-(2<<8|4<<4|18-6),-(2<<8|12<<4|34-6) + }; + int ret; + ret=oc_huff_token_decode(_opb,OC_SB_RUN_TREE); + if(ret>=0x10){ + int offs; + offs=ret&0x1F; + ret=6+offs+(int)oc_pack_read(_opb,ret-offs>>4); + } + return ret; +} + +static int oc_block_run_unpack(oc_pack_buf *_opb){ + /*Coding scheme: + Codeword Run Length + 0x 1-2 + 10x 3-4 + 110x 5-6 + 1110xx 7-10 + 11110xx 11-14 + 11111xxxx 15-30*/ + static const ogg_int16_t OC_BLOCK_RUN_TREE[61]={ + 5, + -(2<<8|1),-(2<<8|1),-(2<<8|1),-(2<<8|1), + -(2<<8|1),-(2<<8|1),-(2<<8|1),-(2<<8|1), + -(2<<8|2),-(2<<8|2),-(2<<8|2),-(2<<8|2), + -(2<<8|2),-(2<<8|2),-(2<<8|2),-(2<<8|2), + -(3<<8|3),-(3<<8|3),-(3<<8|3),-(3<<8|3), + -(3<<8|4),-(3<<8|4),-(3<<8|4),-(3<<8|4), + -(4<<8|5),-(4<<8|5),-(4<<8|6),-(4<<8|6), + 33, 36, 39, 44, + 1,-(1<<8|7),-(1<<8|8), + 1,-(1<<8|9),-(1<<8|10), + 2,-(2<<8|11),-(2<<8|12),-(2<<8|13),-(2<<8|14), + 4, + -(4<<8|15),-(4<<8|16),-(4<<8|17),-(4<<8|18), + -(4<<8|19),-(4<<8|20),-(4<<8|21),-(4<<8|22), + -(4<<8|23),-(4<<8|24),-(4<<8|25),-(4<<8|26), + -(4<<8|27),-(4<<8|28),-(4<<8|29),-(4<<8|30) + }; + return oc_huff_token_decode(_opb,OC_BLOCK_RUN_TREE); +} + + + +void oc_dec_accel_init_c(oc_dec_ctx *_dec){ +# if defined(OC_DEC_USE_VTABLE) + _dec->opt_vtable.dc_unpredict_mcu_plane= + oc_dec_dc_unpredict_mcu_plane_c; +# endif +} + +static int oc_dec_init(oc_dec_ctx *_dec,const th_info *_info, + const th_setup_info *_setup){ + int qti; + int pli; + int qi; + int ret; + ret=oc_state_init(&_dec->state,_info,3); + if(ret<0)return ret; + ret=oc_huff_trees_copy(_dec->huff_tables, + (const ogg_int16_t *const *)_setup->huff_tables); + if(ret<0){ + oc_state_clear(&_dec->state); + return ret; + } + /*For each fragment, allocate one byte for every DCT coefficient token, plus + one byte for extra-bits for each token, plus one more byte for the long + EOB run, just in case it's the very last token and has a run length of + one.*/ + _dec->dct_tokens=(unsigned char *)_ogg_malloc((64+64+1)* + _dec->state.nfrags*sizeof(_dec->dct_tokens[0])); + if(_dec->dct_tokens==NULL){ + oc_huff_trees_clear(_dec->huff_tables); + oc_state_clear(&_dec->state); + return TH_EFAULT; + } + for(qi=0;qi<64;qi++)for(pli=0;pli<3;pli++)for(qti=0;qti<2;qti++){ + _dec->state.dequant_tables[qi][pli][qti]= + _dec->state.dequant_table_data[qi][pli][qti]; + } + oc_dequant_tables_init(_dec->state.dequant_tables,_dec->pp_dc_scale, + &_setup->qinfo); + for(qi=0;qi<64;qi++){ + int qsum; + qsum=0; + for(qti=0;qti<2;qti++)for(pli=0;pli<3;pli++){ + qsum+=_dec->state.dequant_tables[qi][pli][qti][12]+ + _dec->state.dequant_tables[qi][pli][qti][17]+ + _dec->state.dequant_tables[qi][pli][qti][18]+ + _dec->state.dequant_tables[qi][pli][qti][24]<<(pli==0); + } + _dec->pp_sharp_mod[qi]=-(qsum>>11); + } + memcpy(_dec->state.loop_filter_limits,_setup->qinfo.loop_filter_limits, + sizeof(_dec->state.loop_filter_limits)); + oc_dec_accel_init(_dec); + _dec->pp_level=OC_PP_LEVEL_DISABLED; + _dec->dc_qis=NULL; + _dec->variances=NULL; + _dec->pp_frame_data=NULL; + _dec->stripe_cb.ctx=NULL; + _dec->stripe_cb.stripe_decoded=NULL; +#if defined(HAVE_CAIRO) + _dec->telemetry_bits=0; + _dec->telemetry_qi=0; + _dec->telemetry_mbmode=0; + _dec->telemetry_mv=0; + _dec->telemetry_frame_data=NULL; +#endif + return 0; +} + +static void oc_dec_clear(oc_dec_ctx *_dec){ +#if defined(HAVE_CAIRO) + _ogg_free(_dec->telemetry_frame_data); +#endif + _ogg_free(_dec->pp_frame_data); + _ogg_free(_dec->variances); + _ogg_free(_dec->dc_qis); + _ogg_free(_dec->dct_tokens); + oc_huff_trees_clear(_dec->huff_tables); + oc_state_clear(&_dec->state); +} + + +static int oc_dec_frame_header_unpack(oc_dec_ctx *_dec){ + long val; + /*Check to make sure this is a data packet.*/ + val=oc_pack_read1(&_dec->opb); + if(val!=0)return TH_EBADPACKET; + /*Read in the frame type (I or P).*/ + val=oc_pack_read1(&_dec->opb); + _dec->state.frame_type=(int)val; + /*Read in the qi list.*/ + val=oc_pack_read(&_dec->opb,6); + _dec->state.qis[0]=(unsigned char)val; + val=oc_pack_read1(&_dec->opb); + if(!val)_dec->state.nqis=1; + else{ + val=oc_pack_read(&_dec->opb,6); + _dec->state.qis[1]=(unsigned char)val; + val=oc_pack_read1(&_dec->opb); + if(!val)_dec->state.nqis=2; + else{ + val=oc_pack_read(&_dec->opb,6); + _dec->state.qis[2]=(unsigned char)val; + _dec->state.nqis=3; + } + } + if(_dec->state.frame_type==OC_INTRA_FRAME){ + /*Keyframes have 3 unused configuration bits, holdovers from VP3 days. + Most of the other unused bits in the VP3 headers were eliminated. + I don't know why these remain.*/ + /*I wanted to eliminate wasted bits, but not all config wiggle room + --Monty.*/ + val=oc_pack_read(&_dec->opb,3); + if(val!=0)return TH_EIMPL; + } + return 0; +} + +/*Mark all fragments as coded and in OC_MODE_INTRA. + This also builds up the coded fragment list (in coded order), and clears the + uncoded fragment list. + It does not update the coded macro block list nor the super block flags, as + those are not used when decoding INTRA frames.*/ +static void oc_dec_mark_all_intra(oc_dec_ctx *_dec){ + const oc_sb_map *sb_maps; + const oc_sb_flags *sb_flags; + oc_fragment *frags; + ptrdiff_t *coded_fragis; + ptrdiff_t ncoded_fragis; + ptrdiff_t prev_ncoded_fragis; + unsigned nsbs; + unsigned sbi; + int pli; + coded_fragis=_dec->state.coded_fragis; + prev_ncoded_fragis=ncoded_fragis=0; + sb_maps=(const oc_sb_map *)_dec->state.sb_maps; + sb_flags=_dec->state.sb_flags; + frags=_dec->state.frags; + sbi=nsbs=0; + for(pli=0;pli<3;pli++){ + nsbs+=_dec->state.fplanes[pli].nsbs; + for(;sbi<nsbs;sbi++){ + int quadi; + for(quadi=0;quadi<4;quadi++)if(sb_flags[sbi].quad_valid&1<<quadi){ + int bi; + for(bi=0;bi<4;bi++){ + ptrdiff_t fragi; + fragi=sb_maps[sbi][quadi][bi]; + if(fragi>=0){ + frags[fragi].coded=1; + frags[fragi].refi=OC_FRAME_SELF; + frags[fragi].mb_mode=OC_MODE_INTRA; + coded_fragis[ncoded_fragis++]=fragi; + } + } + } + } + _dec->state.ncoded_fragis[pli]=ncoded_fragis-prev_ncoded_fragis; + prev_ncoded_fragis=ncoded_fragis; + } + _dec->state.ntotal_coded_fragis=ncoded_fragis; +} + +/*Decodes the bit flags indicating whether each super block is partially coded + or not. + Return: The number of partially coded super blocks.*/ +static unsigned oc_dec_partial_sb_flags_unpack(oc_dec_ctx *_dec){ + oc_sb_flags *sb_flags; + unsigned nsbs; + unsigned sbi; + unsigned npartial; + unsigned run_count; + long val; + int flag; + val=oc_pack_read1(&_dec->opb); + flag=(int)val; + sb_flags=_dec->state.sb_flags; + nsbs=_dec->state.nsbs; + sbi=npartial=0; + while(sbi<nsbs){ + int full_run; + run_count=oc_sb_run_unpack(&_dec->opb); + full_run=run_count>=4129; + do{ + sb_flags[sbi].coded_partially=flag; + sb_flags[sbi].coded_fully=0; + npartial+=flag; + sbi++; + } + while(--run_count>0&&sbi<nsbs); + if(full_run&&sbi<nsbs){ + val=oc_pack_read1(&_dec->opb); + flag=(int)val; + } + else flag=!flag; + } + /*TODO: run_count should be 0 here. + If it's not, we should issue a warning of some kind.*/ + return npartial; +} + +/*Decodes the bit flags for whether or not each non-partially-coded super + block is fully coded or not. + This function should only be called if there is at least one + non-partially-coded super block. + Return: The number of partially coded super blocks.*/ +static void oc_dec_coded_sb_flags_unpack(oc_dec_ctx *_dec){ + oc_sb_flags *sb_flags; + unsigned nsbs; + unsigned sbi; + unsigned run_count; + long val; + int flag; + sb_flags=_dec->state.sb_flags; + nsbs=_dec->state.nsbs; + /*Skip partially coded super blocks.*/ + for(sbi=0;sb_flags[sbi].coded_partially;sbi++); + val=oc_pack_read1(&_dec->opb); + flag=(int)val; + do{ + int full_run; + run_count=oc_sb_run_unpack(&_dec->opb); + full_run=run_count>=4129; + for(;sbi<nsbs;sbi++){ + if(sb_flags[sbi].coded_partially)continue; + if(run_count--<=0)break; + sb_flags[sbi].coded_fully=flag; + } + if(full_run&&sbi<nsbs){ + val=oc_pack_read1(&_dec->opb); + flag=(int)val; + } + else flag=!flag; + } + while(sbi<nsbs); + /*TODO: run_count should be 0 here. + If it's not, we should issue a warning of some kind.*/ +} + +static void oc_dec_coded_flags_unpack(oc_dec_ctx *_dec){ + const oc_sb_map *sb_maps; + const oc_sb_flags *sb_flags; + signed char *mb_modes; + oc_fragment *frags; + unsigned nsbs; + unsigned sbi; + unsigned npartial; + long val; + int pli; + int flag; + int run_count; + ptrdiff_t *coded_fragis; + ptrdiff_t *uncoded_fragis; + ptrdiff_t ncoded_fragis; + ptrdiff_t nuncoded_fragis; + ptrdiff_t prev_ncoded_fragis; + npartial=oc_dec_partial_sb_flags_unpack(_dec); + if(npartial<_dec->state.nsbs)oc_dec_coded_sb_flags_unpack(_dec); + if(npartial>0){ + val=oc_pack_read1(&_dec->opb); + flag=!(int)val; + } + else flag=0; + sb_maps=(const oc_sb_map *)_dec->state.sb_maps; + sb_flags=_dec->state.sb_flags; + mb_modes=_dec->state.mb_modes; + frags=_dec->state.frags; + sbi=nsbs=run_count=0; + coded_fragis=_dec->state.coded_fragis; + uncoded_fragis=coded_fragis+_dec->state.nfrags; + prev_ncoded_fragis=ncoded_fragis=nuncoded_fragis=0; + for(pli=0;pli<3;pli++){ + nsbs+=_dec->state.fplanes[pli].nsbs; + for(;sbi<nsbs;sbi++){ + int quadi; + for(quadi=0;quadi<4;quadi++)if(sb_flags[sbi].quad_valid&1<<quadi){ + int quad_coded; + int bi; + quad_coded=0; + for(bi=0;bi<4;bi++){ + ptrdiff_t fragi; + fragi=sb_maps[sbi][quadi][bi]; + if(fragi>=0){ + int coded; + if(sb_flags[sbi].coded_fully)coded=1; + else if(!sb_flags[sbi].coded_partially)coded=0; + else{ + if(run_count<=0){ + run_count=oc_block_run_unpack(&_dec->opb); + flag=!flag; + } + run_count--; + coded=flag; + } + if(coded)coded_fragis[ncoded_fragis++]=fragi; + else *(uncoded_fragis-++nuncoded_fragis)=fragi; + quad_coded|=coded; + frags[fragi].coded=coded; + frags[fragi].refi=OC_FRAME_NONE; + } + } + /*Remember if there's a coded luma block in this macro block.*/ + if(!pli)mb_modes[sbi<<2|quadi]=quad_coded; + } + } + _dec->state.ncoded_fragis[pli]=ncoded_fragis-prev_ncoded_fragis; + prev_ncoded_fragis=ncoded_fragis; + } + _dec->state.ntotal_coded_fragis=ncoded_fragis; + /*TODO: run_count should be 0 here. + If it's not, we should issue a warning of some kind.*/ +} + + +/*Coding scheme: + Codeword Mode Index + 0 0 + 10 1 + 110 2 + 1110 3 + 11110 4 + 111110 5 + 1111110 6 + 1111111 7*/ +static const ogg_int16_t OC_VLC_MODE_TREE[26]={ + 4, + -(1<<8|0),-(1<<8|0),-(1<<8|0),-(1<<8|0), + -(1<<8|0),-(1<<8|0),-(1<<8|0),-(1<<8|0), + -(2<<8|1),-(2<<8|1),-(2<<8|1),-(2<<8|1), + -(3<<8|2),-(3<<8|2),-(4<<8|3),17, + 3, + -(1<<8|4),-(1<<8|4),-(1<<8|4),-(1<<8|4), + -(2<<8|5),-(2<<8|5),-(3<<8|6),-(3<<8|7) +}; + +static const ogg_int16_t OC_CLC_MODE_TREE[9]={ + 3, + -(3<<8|0),-(3<<8|1),-(3<<8|2),-(3<<8|3), + -(3<<8|4),-(3<<8|5),-(3<<8|6),-(3<<8|7) +}; + +/*Unpacks the list of macro block modes for INTER frames.*/ +static void oc_dec_mb_modes_unpack(oc_dec_ctx *_dec){ + signed char *mb_modes; + const unsigned char *alphabet; + unsigned char scheme0_alphabet[8]; + const ogg_int16_t *mode_tree; + size_t nmbs; + size_t mbi; + long val; + int mode_scheme; + val=oc_pack_read(&_dec->opb,3); + mode_scheme=(int)val; + if(mode_scheme==0){ + int mi; + /*Just in case, initialize the modes to something. + If the bitstream doesn't contain each index exactly once, it's likely + corrupt and the rest of the packet is garbage anyway, but this way we + won't crash, and we'll decode SOMETHING.*/ + /*LOOP VECTORIZES*/ + for(mi=0;mi<OC_NMODES;mi++)scheme0_alphabet[mi]=OC_MODE_INTER_NOMV; + for(mi=0;mi<OC_NMODES;mi++){ + val=oc_pack_read(&_dec->opb,3); + scheme0_alphabet[val]=OC_MODE_ALPHABETS[6][mi]; + } + alphabet=scheme0_alphabet; + } + else alphabet=OC_MODE_ALPHABETS[mode_scheme-1]; + mode_tree=mode_scheme==7?OC_CLC_MODE_TREE:OC_VLC_MODE_TREE; + mb_modes=_dec->state.mb_modes; + nmbs=_dec->state.nmbs; + for(mbi=0;mbi<nmbs;mbi++){ + if(mb_modes[mbi]>0){ + /*We have a coded luma block; decode a mode.*/ + mb_modes[mbi]=alphabet[oc_huff_token_decode(&_dec->opb,mode_tree)]; + } + /*For other valid macro blocks, INTER_NOMV is forced, but we rely on the + fact that OC_MODE_INTER_NOMV is already 0.*/ + } +} + + + +static const ogg_int16_t OC_VLC_MV_COMP_TREE[101]={ + 5, + -(3<<8|32+0),-(3<<8|32+0),-(3<<8|32+0),-(3<<8|32+0), + -(3<<8|32+1),-(3<<8|32+1),-(3<<8|32+1),-(3<<8|32+1), + -(3<<8|32-1),-(3<<8|32-1),-(3<<8|32-1),-(3<<8|32-1), + -(4<<8|32+2),-(4<<8|32+2),-(4<<8|32-2),-(4<<8|32-2), + -(4<<8|32+3),-(4<<8|32+3),-(4<<8|32-3),-(4<<8|32-3), + 33, 36, 39, 42, + 45, 50, 55, 60, + 65, 74, 83, 92, + 1,-(1<<8|32+4),-(1<<8|32-4), + 1,-(1<<8|32+5),-(1<<8|32-5), + 1,-(1<<8|32+6),-(1<<8|32-6), + 1,-(1<<8|32+7),-(1<<8|32-7), + 2,-(2<<8|32+8),-(2<<8|32-8),-(2<<8|32+9),-(2<<8|32-9), + 2,-(2<<8|32+10),-(2<<8|32-10),-(2<<8|32+11),-(2<<8|32-11), + 2,-(2<<8|32+12),-(2<<8|32-12),-(2<<8|32+13),-(2<<8|32-13), + 2,-(2<<8|32+14),-(2<<8|32-14),-(2<<8|32+15),-(2<<8|32-15), + 3, + -(3<<8|32+16),-(3<<8|32-16),-(3<<8|32+17),-(3<<8|32-17), + -(3<<8|32+18),-(3<<8|32-18),-(3<<8|32+19),-(3<<8|32-19), + 3, + -(3<<8|32+20),-(3<<8|32-20),-(3<<8|32+21),-(3<<8|32-21), + -(3<<8|32+22),-(3<<8|32-22),-(3<<8|32+23),-(3<<8|32-23), + 3, + -(3<<8|32+24),-(3<<8|32-24),-(3<<8|32+25),-(3<<8|32-25), + -(3<<8|32+26),-(3<<8|32-26),-(3<<8|32+27),-(3<<8|32-27), + 3, + -(3<<8|32+28),-(3<<8|32-28),-(3<<8|32+29),-(3<<8|32-29), + -(3<<8|32+30),-(3<<8|32-30),-(3<<8|32+31),-(3<<8|32-31) +}; + +static const ogg_int16_t OC_CLC_MV_COMP_TREE[65]={ + 6, + -(6<<8|32 +0),-(6<<8|32 -0),-(6<<8|32 +1),-(6<<8|32 -1), + -(6<<8|32 +2),-(6<<8|32 -2),-(6<<8|32 +3),-(6<<8|32 -3), + -(6<<8|32 +4),-(6<<8|32 -4),-(6<<8|32 +5),-(6<<8|32 -5), + -(6<<8|32 +6),-(6<<8|32 -6),-(6<<8|32 +7),-(6<<8|32 -7), + -(6<<8|32 +8),-(6<<8|32 -8),-(6<<8|32 +9),-(6<<8|32 -9), + -(6<<8|32+10),-(6<<8|32-10),-(6<<8|32+11),-(6<<8|32-11), + -(6<<8|32+12),-(6<<8|32-12),-(6<<8|32+13),-(6<<8|32-13), + -(6<<8|32+14),-(6<<8|32-14),-(6<<8|32+15),-(6<<8|32-15), + -(6<<8|32+16),-(6<<8|32-16),-(6<<8|32+17),-(6<<8|32-17), + -(6<<8|32+18),-(6<<8|32-18),-(6<<8|32+19),-(6<<8|32-19), + -(6<<8|32+20),-(6<<8|32-20),-(6<<8|32+21),-(6<<8|32-21), + -(6<<8|32+22),-(6<<8|32-22),-(6<<8|32+23),-(6<<8|32-23), + -(6<<8|32+24),-(6<<8|32-24),-(6<<8|32+25),-(6<<8|32-25), + -(6<<8|32+26),-(6<<8|32-26),-(6<<8|32+27),-(6<<8|32-27), + -(6<<8|32+28),-(6<<8|32-28),-(6<<8|32+29),-(6<<8|32-29), + -(6<<8|32+30),-(6<<8|32-30),-(6<<8|32+31),-(6<<8|32-31) +}; + + +static oc_mv oc_mv_unpack(oc_pack_buf *_opb,const ogg_int16_t *_tree){ + int dx; + int dy; + dx=oc_huff_token_decode(_opb,_tree)-32; + dy=oc_huff_token_decode(_opb,_tree)-32; + return OC_MV(dx,dy); +} + +/*Unpacks the list of motion vectors for INTER frames, and propagtes the macro + block modes and motion vectors to the individual fragments.*/ +static void oc_dec_mv_unpack_and_frag_modes_fill(oc_dec_ctx *_dec){ + const oc_mb_map *mb_maps; + const signed char *mb_modes; + oc_set_chroma_mvs_func set_chroma_mvs; + const ogg_int16_t *mv_comp_tree; + oc_fragment *frags; + oc_mv *frag_mvs; + const unsigned char *map_idxs; + int map_nidxs; + oc_mv last_mv; + oc_mv prior_mv; + oc_mv cbmvs[4]; + size_t nmbs; + size_t mbi; + long val; + set_chroma_mvs=OC_SET_CHROMA_MVS_TABLE[_dec->state.info.pixel_fmt]; + val=oc_pack_read1(&_dec->opb); + mv_comp_tree=val?OC_CLC_MV_COMP_TREE:OC_VLC_MV_COMP_TREE; + map_idxs=OC_MB_MAP_IDXS[_dec->state.info.pixel_fmt]; + map_nidxs=OC_MB_MAP_NIDXS[_dec->state.info.pixel_fmt]; + prior_mv=last_mv=0; + frags=_dec->state.frags; + frag_mvs=_dec->state.frag_mvs; + mb_maps=(const oc_mb_map *)_dec->state.mb_maps; + mb_modes=_dec->state.mb_modes; + nmbs=_dec->state.nmbs; + for(mbi=0;mbi<nmbs;mbi++){ + int mb_mode; + mb_mode=mb_modes[mbi]; + if(mb_mode!=OC_MODE_INVALID){ + oc_mv mbmv; + ptrdiff_t fragi; + int mapi; + int mapii; + int refi; + if(mb_mode==OC_MODE_INTER_MV_FOUR){ + oc_mv lbmvs[4]; + int bi; + prior_mv=last_mv; + for(bi=0;bi<4;bi++){ + fragi=mb_maps[mbi][0][bi]; + if(frags[fragi].coded){ + frags[fragi].refi=OC_FRAME_PREV; + frags[fragi].mb_mode=OC_MODE_INTER_MV_FOUR; + lbmvs[bi]=last_mv=oc_mv_unpack(&_dec->opb,mv_comp_tree); + frag_mvs[fragi]=lbmvs[bi]; + } + else lbmvs[bi]=0; + } + (*set_chroma_mvs)(cbmvs,lbmvs); + for(mapii=4;mapii<map_nidxs;mapii++){ + mapi=map_idxs[mapii]; + bi=mapi&3; + fragi=mb_maps[mbi][mapi>>2][bi]; + if(frags[fragi].coded){ + frags[fragi].refi=OC_FRAME_PREV; + frags[fragi].mb_mode=OC_MODE_INTER_MV_FOUR; + frag_mvs[fragi]=cbmvs[bi]; + } + } + } + else{ + switch(mb_mode){ + case OC_MODE_INTER_MV:{ + prior_mv=last_mv; + last_mv=mbmv=oc_mv_unpack(&_dec->opb,mv_comp_tree); + }break; + case OC_MODE_INTER_MV_LAST:mbmv=last_mv;break; + case OC_MODE_INTER_MV_LAST2:{ + mbmv=prior_mv; + prior_mv=last_mv; + last_mv=mbmv; + }break; + case OC_MODE_GOLDEN_MV:{ + mbmv=oc_mv_unpack(&_dec->opb,mv_comp_tree); + }break; + default:mbmv=0;break; + } + /*Fill in the MVs for the fragments.*/ + refi=OC_FRAME_FOR_MODE(mb_mode); + mapii=0; + do{ + mapi=map_idxs[mapii]; + fragi=mb_maps[mbi][mapi>>2][mapi&3]; + if(frags[fragi].coded){ + frags[fragi].refi=refi; + frags[fragi].mb_mode=mb_mode; + frag_mvs[fragi]=mbmv; + } + } + while(++mapii<map_nidxs); + } + } + } +} + +static void oc_dec_block_qis_unpack(oc_dec_ctx *_dec){ + oc_fragment *frags; + const ptrdiff_t *coded_fragis; + ptrdiff_t ncoded_fragis; + ptrdiff_t fragii; + ptrdiff_t fragi; + ncoded_fragis=_dec->state.ntotal_coded_fragis; + if(ncoded_fragis<=0)return; + frags=_dec->state.frags; + coded_fragis=_dec->state.coded_fragis; + if(_dec->state.nqis==1){ + /*If this frame has only a single qi value, then just use it for all coded + fragments.*/ + for(fragii=0;fragii<ncoded_fragis;fragii++){ + frags[coded_fragis[fragii]].qii=0; + } + } + else{ + long val; + int flag; + int nqi1; + int run_count; + /*Otherwise, we decode a qi index for each fragment, using two passes of + the same binary RLE scheme used for super-block coded bits. + The first pass marks each fragment as having a qii of 0 or greater than + 0, and the second pass (if necessary), distinguishes between a qii of + 1 and 2. + At first we just store the qii in the fragment. + After all the qii's are decoded, we make a final pass to replace them + with the corresponding qi's for this frame.*/ + val=oc_pack_read1(&_dec->opb); + flag=(int)val; + nqi1=0; + fragii=0; + while(fragii<ncoded_fragis){ + int full_run; + run_count=oc_sb_run_unpack(&_dec->opb); + full_run=run_count>=4129; + do{ + frags[coded_fragis[fragii++]].qii=flag; + nqi1+=flag; + } + while(--run_count>0&&fragii<ncoded_fragis); + if(full_run&&fragii<ncoded_fragis){ + val=oc_pack_read1(&_dec->opb); + flag=(int)val; + } + else flag=!flag; + } + /*TODO: run_count should be 0 here. + If it's not, we should issue a warning of some kind.*/ + /*If we have 3 different qi's for this frame, and there was at least one + fragment with a non-zero qi, make the second pass.*/ + if(_dec->state.nqis==3&&nqi1>0){ + /*Skip qii==0 fragments.*/ + for(fragii=0;frags[coded_fragis[fragii]].qii==0;fragii++); + val=oc_pack_read1(&_dec->opb); + flag=(int)val; + do{ + int full_run; + run_count=oc_sb_run_unpack(&_dec->opb); + full_run=run_count>=4129; + for(;fragii<ncoded_fragis;fragii++){ + fragi=coded_fragis[fragii]; + if(frags[fragi].qii==0)continue; + if(run_count--<=0)break; + frags[fragi].qii+=flag; + } + if(full_run&&fragii<ncoded_fragis){ + val=oc_pack_read1(&_dec->opb); + flag=(int)val; + } + else flag=!flag; + } + while(fragii<ncoded_fragis); + /*TODO: run_count should be 0 here. + If it's not, we should issue a warning of some kind.*/ + } + } +} + + + +/*Unpacks the DC coefficient tokens. + Unlike when unpacking the AC coefficient tokens, we actually need to decode + the DC coefficient values now so that we can do DC prediction. + _huff_idx: The index of the Huffman table to use for each color plane. + _ntoks_left: The number of tokens left to be decoded in each color plane for + each coefficient. + This is updated as EOB tokens and zero run tokens are decoded. + Return: The length of any outstanding EOB run.*/ +static ptrdiff_t oc_dec_dc_coeff_unpack(oc_dec_ctx *_dec,int _huff_idxs[2], + ptrdiff_t _ntoks_left[3][64]){ + unsigned char *dct_tokens; + oc_fragment *frags; + const ptrdiff_t *coded_fragis; + ptrdiff_t ncoded_fragis; + ptrdiff_t fragii; + ptrdiff_t eobs; + ptrdiff_t ti; + int pli; + dct_tokens=_dec->dct_tokens; + frags=_dec->state.frags; + coded_fragis=_dec->state.coded_fragis; + ncoded_fragis=fragii=eobs=ti=0; + for(pli=0;pli<3;pli++){ + ptrdiff_t run_counts[64]; + ptrdiff_t eob_count; + ptrdiff_t eobi; + int rli; + ncoded_fragis+=_dec->state.ncoded_fragis[pli]; + memset(run_counts,0,sizeof(run_counts)); + _dec->eob_runs[pli][0]=eobs; + _dec->ti0[pli][0]=ti; + /*Continue any previous EOB run, if there was one.*/ + eobi=eobs; + if(ncoded_fragis-fragii<eobi)eobi=ncoded_fragis-fragii; + eob_count=eobi; + eobs-=eobi; + while(eobi-->0)frags[coded_fragis[fragii++]].dc=0; + while(fragii<ncoded_fragis){ + int token; + int cw; + int eb; + int skip; + token=oc_huff_token_decode(&_dec->opb, + _dec->huff_tables[_huff_idxs[pli+1>>1]]); + dct_tokens[ti++]=(unsigned char)token; + if(OC_DCT_TOKEN_NEEDS_MORE(token)){ + eb=(int)oc_pack_read(&_dec->opb, + OC_INTERNAL_DCT_TOKEN_EXTRA_BITS[token]); + dct_tokens[ti++]=(unsigned char)eb; + if(token==OC_DCT_TOKEN_FAT_EOB)dct_tokens[ti++]=(unsigned char)(eb>>8); + eb<<=OC_DCT_TOKEN_EB_POS(token); + } + else eb=0; + cw=OC_DCT_CODE_WORD[token]+eb; + eobs=cw>>OC_DCT_CW_EOB_SHIFT&0xFFF; + if(cw==OC_DCT_CW_FINISH)eobs=OC_DCT_EOB_FINISH; + if(eobs){ + eobi=OC_MINI(eobs,ncoded_fragis-fragii); + eob_count+=eobi; + eobs-=eobi; + while(eobi-->0)frags[coded_fragis[fragii++]].dc=0; + } + else{ + int coeff; + skip=(unsigned char)(cw>>OC_DCT_CW_RLEN_SHIFT); + cw^=-(cw&1<<OC_DCT_CW_FLIP_BIT); + coeff=cw>>OC_DCT_CW_MAG_SHIFT; + if(skip)coeff=0; + run_counts[skip]++; + frags[coded_fragis[fragii++]].dc=coeff; + } + } + /*Add the total EOB count to the longest run length.*/ + run_counts[63]+=eob_count; + /*And convert the run_counts array to a moment table.*/ + for(rli=63;rli-->0;)run_counts[rli]+=run_counts[rli+1]; + /*Finally, subtract off the number of coefficients that have been + accounted for by runs started in this coefficient.*/ + for(rli=64;rli-->0;)_ntoks_left[pli][rli]-=run_counts[rli]; + } + _dec->dct_tokens_count=ti; + return eobs; +} + +/*Unpacks the AC coefficient tokens. + This can completely discard coefficient values while unpacking, and so is + somewhat simpler than unpacking the DC coefficient tokens. + _huff_idx: The index of the Huffman table to use for each color plane. + _ntoks_left: The number of tokens left to be decoded in each color plane for + each coefficient. + This is updated as EOB tokens and zero run tokens are decoded. + _eobs: The length of any outstanding EOB run from previous + coefficients. + Return: The length of any outstanding EOB run.*/ +static int oc_dec_ac_coeff_unpack(oc_dec_ctx *_dec,int _zzi,int _huff_idxs[2], + ptrdiff_t _ntoks_left[3][64],ptrdiff_t _eobs){ + unsigned char *dct_tokens; + ptrdiff_t ti; + int pli; + dct_tokens=_dec->dct_tokens; + ti=_dec->dct_tokens_count; + for(pli=0;pli<3;pli++){ + ptrdiff_t run_counts[64]; + ptrdiff_t eob_count; + size_t ntoks_left; + size_t ntoks; + int rli; + _dec->eob_runs[pli][_zzi]=_eobs; + _dec->ti0[pli][_zzi]=ti; + ntoks_left=_ntoks_left[pli][_zzi]; + memset(run_counts,0,sizeof(run_counts)); + eob_count=0; + ntoks=0; + while(ntoks+_eobs<ntoks_left){ + int token; + int cw; + int eb; + int skip; + ntoks+=_eobs; + eob_count+=_eobs; + token=oc_huff_token_decode(&_dec->opb, + _dec->huff_tables[_huff_idxs[pli+1>>1]]); + dct_tokens[ti++]=(unsigned char)token; + if(OC_DCT_TOKEN_NEEDS_MORE(token)){ + eb=(int)oc_pack_read(&_dec->opb, + OC_INTERNAL_DCT_TOKEN_EXTRA_BITS[token]); + dct_tokens[ti++]=(unsigned char)eb; + if(token==OC_DCT_TOKEN_FAT_EOB)dct_tokens[ti++]=(unsigned char)(eb>>8); + eb<<=OC_DCT_TOKEN_EB_POS(token); + } + else eb=0; + cw=OC_DCT_CODE_WORD[token]+eb; + skip=(unsigned char)(cw>>OC_DCT_CW_RLEN_SHIFT); + _eobs=cw>>OC_DCT_CW_EOB_SHIFT&0xFFF; + if(cw==OC_DCT_CW_FINISH)_eobs=OC_DCT_EOB_FINISH; + if(_eobs==0){ + run_counts[skip]++; + ntoks++; + } + } + /*Add the portion of the last EOB run actually used by this coefficient.*/ + eob_count+=ntoks_left-ntoks; + /*And remove it from the remaining EOB count.*/ + _eobs-=ntoks_left-ntoks; + /*Add the total EOB count to the longest run length.*/ + run_counts[63]+=eob_count; + /*And convert the run_counts array to a moment table.*/ + for(rli=63;rli-->0;)run_counts[rli]+=run_counts[rli+1]; + /*Finally, subtract off the number of coefficients that have been + accounted for by runs started in this coefficient.*/ + for(rli=64-_zzi;rli-->0;)_ntoks_left[pli][_zzi+rli]-=run_counts[rli]; + } + _dec->dct_tokens_count=ti; + return _eobs; +} + +/*Tokens describing the DCT coefficients that belong to each fragment are + stored in the bitstream grouped by coefficient, not by fragment. + + This means that we either decode all the tokens in order, building up a + separate coefficient list for each fragment as we go, and then go back and + do the iDCT on each fragment, or we have to create separate lists of tokens + for each coefficient, so that we can pull the next token required off the + head of the appropriate list when decoding a specific fragment. + + The former was VP3's choice, and it meant 2*w*h extra storage for all the + decoded coefficient values. + + We take the second option, which lets us store just one to three bytes per + token (generally far fewer than the number of coefficients, due to EOB + tokens and zero runs), and which requires us to only maintain a counter for + each of the 64 coefficients, instead of a counter for every fragment to + determine where the next token goes. + + We actually use 3 counters per coefficient, one for each color plane, so we + can decode all color planes simultaneously. + This lets color conversion, etc., be done as soon as a full MCU (one or + two super block rows) is decoded, while the image data is still in cache.*/ + +static void oc_dec_residual_tokens_unpack(oc_dec_ctx *_dec){ + static const unsigned char OC_HUFF_LIST_MAX[5]={1,6,15,28,64}; + ptrdiff_t ntoks_left[3][64]; + int huff_idxs[2]; + ptrdiff_t eobs; + long val; + int pli; + int zzi; + int hgi; + for(pli=0;pli<3;pli++)for(zzi=0;zzi<64;zzi++){ + ntoks_left[pli][zzi]=_dec->state.ncoded_fragis[pli]; + } + val=oc_pack_read(&_dec->opb,4); + huff_idxs[0]=(int)val; + val=oc_pack_read(&_dec->opb,4); + huff_idxs[1]=(int)val; + _dec->eob_runs[0][0]=0; + eobs=oc_dec_dc_coeff_unpack(_dec,huff_idxs,ntoks_left); +#if defined(HAVE_CAIRO) + _dec->telemetry_dc_bytes=oc_pack_bytes_left(&_dec->opb); +#endif + val=oc_pack_read(&_dec->opb,4); + huff_idxs[0]=(int)val; + val=oc_pack_read(&_dec->opb,4); + huff_idxs[1]=(int)val; + zzi=1; + for(hgi=1;hgi<5;hgi++){ + huff_idxs[0]+=16; + huff_idxs[1]+=16; + for(;zzi<OC_HUFF_LIST_MAX[hgi];zzi++){ + eobs=oc_dec_ac_coeff_unpack(_dec,zzi,huff_idxs,ntoks_left,eobs); + } + } + /*TODO: eobs should be exactly zero, or 4096 or greater. + The second case occurs when an EOB run of size zero is encountered, which + gets treated as an infinite EOB run (where infinity is PTRDIFF_MAX). + If neither of these conditions holds, then a warning should be issued.*/ +} + + +static int oc_dec_postprocess_init(oc_dec_ctx *_dec){ + /*musl libc malloc()/realloc() calls might use floating point, so make sure + we've cleared the MMX state for them.*/ + oc_restore_fpu(&_dec->state); + /*pp_level 0: disabled; free any memory used and return*/ + if(_dec->pp_level<=OC_PP_LEVEL_DISABLED){ + if(_dec->dc_qis!=NULL){ + _ogg_free(_dec->dc_qis); + _dec->dc_qis=NULL; + _ogg_free(_dec->variances); + _dec->variances=NULL; + _ogg_free(_dec->pp_frame_data); + _dec->pp_frame_data=NULL; + } + return 1; + } + if(_dec->dc_qis==NULL){ + /*If we haven't been tracking DC quantization indices, there's no point in + starting now.*/ + if(_dec->state.frame_type!=OC_INTRA_FRAME)return 1; + _dec->dc_qis=(unsigned char *)_ogg_malloc( + _dec->state.nfrags*sizeof(_dec->dc_qis[0])); + if(_dec->dc_qis==NULL)return 1; + memset(_dec->dc_qis,_dec->state.qis[0],_dec->state.nfrags); + } + else{ + unsigned char *dc_qis; + const ptrdiff_t *coded_fragis; + ptrdiff_t ncoded_fragis; + ptrdiff_t fragii; + unsigned char qi0; + /*Update the DC quantization index of each coded block.*/ + dc_qis=_dec->dc_qis; + coded_fragis=_dec->state.coded_fragis; + ncoded_fragis=_dec->state.ncoded_fragis[0]+ + _dec->state.ncoded_fragis[1]+_dec->state.ncoded_fragis[2]; + qi0=(unsigned char)_dec->state.qis[0]; + for(fragii=0;fragii<ncoded_fragis;fragii++){ + dc_qis[coded_fragis[fragii]]=qi0; + } + } + /*pp_level 1: Stop after updating DC quantization indices.*/ + if(_dec->pp_level<=OC_PP_LEVEL_TRACKDCQI){ + if(_dec->variances!=NULL){ + _ogg_free(_dec->variances); + _dec->variances=NULL; + _ogg_free(_dec->pp_frame_data); + _dec->pp_frame_data=NULL; + } + return 1; + } + if(_dec->variances==NULL){ + size_t frame_sz; + size_t c_sz; + int c_w; + int c_h; + frame_sz=_dec->state.info.frame_width*(size_t)_dec->state.info.frame_height; + c_w=_dec->state.info.frame_width>>!(_dec->state.info.pixel_fmt&1); + c_h=_dec->state.info.frame_height>>!(_dec->state.info.pixel_fmt&2); + c_sz=c_w*(size_t)c_h; + /*Allocate space for the chroma planes, even if we're not going to use + them; this simplifies allocation state management, though it may waste + memory on the few systems that don't overcommit pages.*/ + frame_sz+=c_sz<<1; + _dec->pp_frame_data=(unsigned char *)_ogg_malloc( + frame_sz*sizeof(_dec->pp_frame_data[0])); + _dec->variances=(int *)_ogg_malloc( + _dec->state.nfrags*sizeof(_dec->variances[0])); + if(_dec->variances==NULL||_dec->pp_frame_data==NULL){ + _ogg_free(_dec->pp_frame_data); + _dec->pp_frame_data=NULL; + _ogg_free(_dec->variances); + _dec->variances=NULL; + return 1; + } + /*Force an update of the PP buffer pointers.*/ + _dec->pp_frame_state=0; + } + /*Update the PP buffer pointers if necessary.*/ + if(_dec->pp_frame_state!=1+(_dec->pp_level>=OC_PP_LEVEL_DEBLOCKC)){ + if(_dec->pp_level<OC_PP_LEVEL_DEBLOCKC){ + /*If chroma processing is disabled, just use the PP luma plane.*/ + _dec->pp_frame_buf[0].width=_dec->state.info.frame_width; + _dec->pp_frame_buf[0].height=_dec->state.info.frame_height; + _dec->pp_frame_buf[0].stride=-_dec->pp_frame_buf[0].width; + _dec->pp_frame_buf[0].data=_dec->pp_frame_data+ + (1-_dec->pp_frame_buf[0].height)*(ptrdiff_t)_dec->pp_frame_buf[0].stride; + } + else{ + size_t y_sz; + size_t c_sz; + int c_w; + int c_h; + /*Otherwise, set up pointers to all three PP planes.*/ + y_sz=_dec->state.info.frame_width*(size_t)_dec->state.info.frame_height; + c_w=_dec->state.info.frame_width>>!(_dec->state.info.pixel_fmt&1); + c_h=_dec->state.info.frame_height>>!(_dec->state.info.pixel_fmt&2); + c_sz=c_w*(size_t)c_h; + _dec->pp_frame_buf[0].width=_dec->state.info.frame_width; + _dec->pp_frame_buf[0].height=_dec->state.info.frame_height; + _dec->pp_frame_buf[0].stride=_dec->pp_frame_buf[0].width; + _dec->pp_frame_buf[0].data=_dec->pp_frame_data; + _dec->pp_frame_buf[1].width=c_w; + _dec->pp_frame_buf[1].height=c_h; + _dec->pp_frame_buf[1].stride=_dec->pp_frame_buf[1].width; + _dec->pp_frame_buf[1].data=_dec->pp_frame_buf[0].data+y_sz; + _dec->pp_frame_buf[2].width=c_w; + _dec->pp_frame_buf[2].height=c_h; + _dec->pp_frame_buf[2].stride=_dec->pp_frame_buf[2].width; + _dec->pp_frame_buf[2].data=_dec->pp_frame_buf[1].data+c_sz; + oc_ycbcr_buffer_flip(_dec->pp_frame_buf,_dec->pp_frame_buf); + } + _dec->pp_frame_state=1+(_dec->pp_level>=OC_PP_LEVEL_DEBLOCKC); + } + /*If we're not processing chroma, copy the reference frame's chroma planes.*/ + if(_dec->pp_level<OC_PP_LEVEL_DEBLOCKC){ + memcpy(_dec->pp_frame_buf+1, + _dec->state.ref_frame_bufs[_dec->state.ref_frame_idx[OC_FRAME_SELF]]+1, + sizeof(_dec->pp_frame_buf[1])*2); + } + return 0; +} + + +/*Initialize the main decoding pipeline.*/ +static void oc_dec_pipeline_init(oc_dec_ctx *_dec, + oc_dec_pipeline_state *_pipe){ + const ptrdiff_t *coded_fragis; + const ptrdiff_t *uncoded_fragis; + int flimit; + int pli; + int qii; + int qti; + int zzi; + /*If chroma is sub-sampled in the vertical direction, we have to decode two + super block rows of Y' for each super block row of Cb and Cr.*/ + _pipe->mcu_nvfrags=4<<!(_dec->state.info.pixel_fmt&2); + /*Initialize the token and extra bits indices for each plane and + coefficient.*/ + memcpy(_pipe->ti,_dec->ti0,sizeof(_pipe->ti)); + /*Also copy over the initial the EOB run counts.*/ + memcpy(_pipe->eob_runs,_dec->eob_runs,sizeof(_pipe->eob_runs)); + /*Set up per-plane pointers to the coded and uncoded fragments lists.*/ + coded_fragis=_dec->state.coded_fragis; + uncoded_fragis=coded_fragis+_dec->state.nfrags; + for(pli=0;pli<3;pli++){ + ptrdiff_t ncoded_fragis; + _pipe->coded_fragis[pli]=coded_fragis; + _pipe->uncoded_fragis[pli]=uncoded_fragis; + ncoded_fragis=_dec->state.ncoded_fragis[pli]; + coded_fragis+=ncoded_fragis; + uncoded_fragis+=ncoded_fragis-_dec->state.fplanes[pli].nfrags; + } + /*Set up condensed quantizer tables.*/ + for(pli=0;pli<3;pli++){ + for(qii=0;qii<_dec->state.nqis;qii++){ + for(qti=0;qti<2;qti++){ + _pipe->dequant[pli][qii][qti]= + _dec->state.dequant_tables[_dec->state.qis[qii]][pli][qti]; + } + } + } + /*Set the previous DC predictor to 0 for all color planes and frame types.*/ + memset(_pipe->pred_last,0,sizeof(_pipe->pred_last)); + /*Initialize the bounding value array for the loop filter.*/ + flimit=_dec->state.loop_filter_limits[_dec->state.qis[0]]; + _pipe->loop_filter=flimit!=0; + if(flimit!=0)oc_loop_filter_init(&_dec->state,_pipe->bounding_values,flimit); + /*Initialize any buffers needed for post-processing. + We also save the current post-processing level, to guard against the user + changing it from a callback.*/ + if(!oc_dec_postprocess_init(_dec))_pipe->pp_level=_dec->pp_level; + /*If we don't have enough information to post-process, disable it, regardless + of the user-requested level.*/ + else{ + _pipe->pp_level=OC_PP_LEVEL_DISABLED; + memcpy(_dec->pp_frame_buf, + _dec->state.ref_frame_bufs[_dec->state.ref_frame_idx[OC_FRAME_SELF]], + sizeof(_dec->pp_frame_buf[0])*3); + } + /*Clear down the DCT coefficient buffer for the first block.*/ + for(zzi=0;zzi<64;zzi++)_pipe->dct_coeffs[zzi]=0; +} + +/*Undo the DC prediction in a single plane of an MCU (one or two super block + rows). + As a side effect, the number of coded and uncoded fragments in this plane of + the MCU is also computed.*/ +void oc_dec_dc_unpredict_mcu_plane_c(oc_dec_ctx *_dec, + oc_dec_pipeline_state *_pipe,int _pli){ + const oc_fragment_plane *fplane; + oc_fragment *frags; + int *pred_last; + ptrdiff_t ncoded_fragis; + ptrdiff_t fragi; + int fragx; + int fragy; + int fragy0; + int fragy_end; + int nhfrags; + /*Compute the first and last fragment row of the current MCU for this + plane.*/ + fplane=_dec->state.fplanes+_pli; + fragy0=_pipe->fragy0[_pli]; + fragy_end=_pipe->fragy_end[_pli]; + nhfrags=fplane->nhfrags; + pred_last=_pipe->pred_last[_pli]; + frags=_dec->state.frags; + ncoded_fragis=0; + fragi=fplane->froffset+fragy0*(ptrdiff_t)nhfrags; + for(fragy=fragy0;fragy<fragy_end;fragy++){ + if(fragy==0){ + /*For the first row, all of the cases reduce to just using the previous + predictor for the same reference frame.*/ + for(fragx=0;fragx<nhfrags;fragx++,fragi++){ + if(frags[fragi].coded){ + int refi; + refi=frags[fragi].refi; + pred_last[refi]=frags[fragi].dc+=pred_last[refi]; + ncoded_fragis++; + } + } + } + else{ + oc_fragment *u_frags; + int l_ref; + int ul_ref; + int u_ref; + u_frags=frags-nhfrags; + l_ref=-1; + ul_ref=-1; + u_ref=u_frags[fragi].refi; + for(fragx=0;fragx<nhfrags;fragx++,fragi++){ + int ur_ref; + if(fragx+1>=nhfrags)ur_ref=-1; + else ur_ref=u_frags[fragi+1].refi; + if(frags[fragi].coded){ + int pred; + int refi; + refi=frags[fragi].refi; + /*We break out a separate case based on which of our neighbors use + the same reference frames. + This is somewhat faster than trying to make a generic case which + handles all of them, since it reduces lots of poorly predicted + jumps to one switch statement, and also lets a number of the + multiplications be optimized out by strength reduction.*/ + switch((l_ref==refi)|(ul_ref==refi)<<1| + (u_ref==refi)<<2|(ur_ref==refi)<<3){ + default:pred=pred_last[refi];break; + case 1: + case 3:pred=frags[fragi-1].dc;break; + case 2:pred=u_frags[fragi-1].dc;break; + case 4: + case 6: + case 12:pred=u_frags[fragi].dc;break; + case 5:pred=(frags[fragi-1].dc+u_frags[fragi].dc)/2;break; + case 8:pred=u_frags[fragi+1].dc;break; + case 9: + case 11: + case 13:{ + /*The TI compiler mis-compiles this line.*/ + pred=(75*frags[fragi-1].dc+53*u_frags[fragi+1].dc)/128; + }break; + case 10:pred=(u_frags[fragi-1].dc+u_frags[fragi+1].dc)/2;break; + case 14:{ + pred=(3*(u_frags[fragi-1].dc+u_frags[fragi+1].dc) + +10*u_frags[fragi].dc)/16; + }break; + case 7: + case 15:{ + int p0; + int p1; + int p2; + p0=frags[fragi-1].dc; + p1=u_frags[fragi-1].dc; + p2=u_frags[fragi].dc; + pred=(29*(p0+p2)-26*p1)/32; + if(abs(pred-p2)>128)pred=p2; + else if(abs(pred-p0)>128)pred=p0; + else if(abs(pred-p1)>128)pred=p1; + }break; + } + pred_last[refi]=frags[fragi].dc+=pred; + ncoded_fragis++; + l_ref=refi; + } + else l_ref=-1; + ul_ref=u_ref; + u_ref=ur_ref; + } + } + } + _pipe->ncoded_fragis[_pli]=ncoded_fragis; + /*Also save the number of uncoded fragments so we know how many to copy.*/ + _pipe->nuncoded_fragis[_pli]= + (fragy_end-fragy0)*(ptrdiff_t)nhfrags-ncoded_fragis; +} + +/*Reconstructs all coded fragments in a single MCU (one or two super block + rows). + This requires that each coded fragment have a proper macro block mode and + motion vector (if not in INTRA mode), and have its DC value decoded, with + the DC prediction process reversed, and the number of coded and uncoded + fragments in this plane of the MCU be counted. + The token lists for each color plane and coefficient should also be filled + in, along with initial token offsets, extra bits offsets, and EOB run + counts.*/ +static void oc_dec_frags_recon_mcu_plane(oc_dec_ctx *_dec, + oc_dec_pipeline_state *_pipe,int _pli){ + unsigned char *dct_tokens; + const unsigned char *dct_fzig_zag; + ogg_uint16_t dc_quant[2]; + const oc_fragment *frags; + const ptrdiff_t *coded_fragis; + ptrdiff_t ncoded_fragis; + ptrdiff_t fragii; + ptrdiff_t *ti; + ptrdiff_t *eob_runs; + int qti; + dct_tokens=_dec->dct_tokens; + dct_fzig_zag=_dec->state.opt_data.dct_fzig_zag; + frags=_dec->state.frags; + coded_fragis=_pipe->coded_fragis[_pli]; + ncoded_fragis=_pipe->ncoded_fragis[_pli]; + ti=_pipe->ti[_pli]; + eob_runs=_pipe->eob_runs[_pli]; + for(qti=0;qti<2;qti++)dc_quant[qti]=_pipe->dequant[_pli][0][qti][0]; + for(fragii=0;fragii<ncoded_fragis;fragii++){ + const ogg_uint16_t *ac_quant; + ptrdiff_t fragi; + int last_zzi; + int zzi; + fragi=coded_fragis[fragii]; + qti=frags[fragi].mb_mode!=OC_MODE_INTRA; + ac_quant=_pipe->dequant[_pli][frags[fragi].qii][qti]; + /*Decode the AC coefficients.*/ + for(zzi=0;zzi<64;){ + int token; + last_zzi=zzi; + if(eob_runs[zzi]){ + eob_runs[zzi]--; + break; + } + else{ + ptrdiff_t eob; + int cw; + int rlen; + int coeff; + int lti; + lti=ti[zzi]; + token=dct_tokens[lti++]; + cw=OC_DCT_CODE_WORD[token]; + /*These parts could be done branchless, but the branches are fairly + predictable and the C code translates into more than a few + instructions, so it's worth it to avoid them.*/ + if(OC_DCT_TOKEN_NEEDS_MORE(token)){ + cw+=dct_tokens[lti++]<<OC_DCT_TOKEN_EB_POS(token); + } + eob=cw>>OC_DCT_CW_EOB_SHIFT&0xFFF; + if(token==OC_DCT_TOKEN_FAT_EOB){ + eob+=dct_tokens[lti++]<<8; + if(eob==0)eob=OC_DCT_EOB_FINISH; + } + rlen=(unsigned char)(cw>>OC_DCT_CW_RLEN_SHIFT); + cw^=-(cw&1<<OC_DCT_CW_FLIP_BIT); + coeff=cw>>OC_DCT_CW_MAG_SHIFT; + eob_runs[zzi]=eob; + ti[zzi]=lti; + zzi+=rlen; + _pipe->dct_coeffs[dct_fzig_zag[zzi]]= + (ogg_int16_t)(coeff*(int)ac_quant[zzi]); + zzi+=!eob; + } + } + /*TODO: zzi should be exactly 64 here. + If it's not, we should report some kind of warning.*/ + zzi=OC_MINI(zzi,64); + _pipe->dct_coeffs[0]=(ogg_int16_t)frags[fragi].dc; + /*last_zzi is always initialized. + If your compiler thinks otherwise, it is dumb.*/ + oc_state_frag_recon(&_dec->state,fragi,_pli, + _pipe->dct_coeffs,last_zzi,dc_quant[qti]); + } + _pipe->coded_fragis[_pli]+=ncoded_fragis; + /*Right now the reconstructed MCU has only the coded blocks in it.*/ + /*TODO: We make the decision here to always copy the uncoded blocks into it + from the reference frame. + We could also copy the coded blocks back over the reference frame, if we + wait for an additional MCU to be decoded, which might be faster if only a + small number of blocks are coded. + However, this introduces more latency, creating a larger cache footprint. + It's unknown which decision is better, but this one results in simpler + code, and the hard case (high bitrate, high resolution) is handled + correctly.*/ + /*Copy the uncoded blocks from the previous reference frame.*/ + if(_pipe->nuncoded_fragis[_pli]>0){ + _pipe->uncoded_fragis[_pli]-=_pipe->nuncoded_fragis[_pli]; + oc_frag_copy_list(&_dec->state, + _dec->state.ref_frame_data[OC_FRAME_SELF], + _dec->state.ref_frame_data[OC_FRAME_PREV], + _dec->state.ref_ystride[_pli],_pipe->uncoded_fragis[_pli], + _pipe->nuncoded_fragis[_pli],_dec->state.frag_buf_offs); + } +} + +/*Filter a horizontal block edge.*/ +static void oc_filter_hedge(unsigned char *_dst,int _dst_ystride, + const unsigned char *_src,int _src_ystride,int _qstep,int _flimit, + int *_variance0,int *_variance1){ + unsigned char *rdst; + const unsigned char *rsrc; + unsigned char *cdst; + const unsigned char *csrc; + int r[10]; + int sum0; + int sum1; + int bx; + int by; + rdst=_dst; + rsrc=_src; + for(bx=0;bx<8;bx++){ + cdst=rdst; + csrc=rsrc; + for(by=0;by<10;by++){ + r[by]=*csrc; + csrc+=_src_ystride; + } + sum0=sum1=0; + for(by=0;by<4;by++){ + sum0+=abs(r[by+1]-r[by]); + sum1+=abs(r[by+5]-r[by+6]); + } + *_variance0+=OC_MINI(255,sum0); + *_variance1+=OC_MINI(255,sum1); + if(sum0<_flimit&&sum1<_flimit&&r[5]-r[4]<_qstep&&r[4]-r[5]<_qstep){ + *cdst=(unsigned char)(r[0]*3+r[1]*2+r[2]+r[3]+r[4]+4>>3); + cdst+=_dst_ystride; + *cdst=(unsigned char)(r[0]*2+r[1]+r[2]*2+r[3]+r[4]+r[5]+4>>3); + cdst+=_dst_ystride; + for(by=0;by<4;by++){ + *cdst=(unsigned char)(r[by]+r[by+1]+r[by+2]+r[by+3]*2+ + r[by+4]+r[by+5]+r[by+6]+4>>3); + cdst+=_dst_ystride; + } + *cdst=(unsigned char)(r[4]+r[5]+r[6]+r[7]*2+r[8]+r[9]*2+4>>3); + cdst+=_dst_ystride; + *cdst=(unsigned char)(r[5]+r[6]+r[7]+r[8]*2+r[9]*3+4>>3); + } + else{ + for(by=1;by<=8;by++){ + *cdst=(unsigned char)r[by]; + cdst+=_dst_ystride; + } + } + rdst++; + rsrc++; + } +} + +/*Filter a vertical block edge.*/ +static void oc_filter_vedge(unsigned char *_dst,int _dst_ystride, + int _qstep,int _flimit,int *_variances){ + unsigned char *rdst; + const unsigned char *rsrc; + unsigned char *cdst; + int r[10]; + int sum0; + int sum1; + int bx; + int by; + cdst=_dst; + for(by=0;by<8;by++){ + rsrc=cdst-1; + rdst=cdst; + for(bx=0;bx<10;bx++)r[bx]=*rsrc++; + sum0=sum1=0; + for(bx=0;bx<4;bx++){ + sum0+=abs(r[bx+1]-r[bx]); + sum1+=abs(r[bx+5]-r[bx+6]); + } + _variances[0]+=OC_MINI(255,sum0); + _variances[1]+=OC_MINI(255,sum1); + if(sum0<_flimit&&sum1<_flimit&&r[5]-r[4]<_qstep&&r[4]-r[5]<_qstep){ + *rdst++=(unsigned char)(r[0]*3+r[1]*2+r[2]+r[3]+r[4]+4>>3); + *rdst++=(unsigned char)(r[0]*2+r[1]+r[2]*2+r[3]+r[4]+r[5]+4>>3); + for(bx=0;bx<4;bx++){ + *rdst++=(unsigned char)(r[bx]+r[bx+1]+r[bx+2]+r[bx+3]*2+ + r[bx+4]+r[bx+5]+r[bx+6]+4>>3); + } + *rdst++=(unsigned char)(r[4]+r[5]+r[6]+r[7]*2+r[8]+r[9]*2+4>>3); + *rdst=(unsigned char)(r[5]+r[6]+r[7]+r[8]*2+r[9]*3+4>>3); + } + cdst+=_dst_ystride; + } +} + +static void oc_dec_deblock_frag_rows(oc_dec_ctx *_dec, + th_img_plane *_dst,th_img_plane *_src,int _pli,int _fragy0, + int _fragy_end){ + oc_fragment_plane *fplane; + int *variance; + unsigned char *dc_qi; + unsigned char *dst; + const unsigned char *src; + ptrdiff_t froffset; + int dst_ystride; + int src_ystride; + int nhfrags; + int width; + int notstart; + int notdone; + int flimit; + int qstep; + int y_end; + int y; + int x; + _dst+=_pli; + _src+=_pli; + fplane=_dec->state.fplanes+_pli; + nhfrags=fplane->nhfrags; + froffset=fplane->froffset+_fragy0*(ptrdiff_t)nhfrags; + variance=_dec->variances+froffset; + dc_qi=_dec->dc_qis+froffset; + notstart=_fragy0>0; + notdone=_fragy_end<fplane->nvfrags; + /*We want to clear an extra row of variances, except at the end.*/ + memset(variance+(nhfrags&-notstart),0, + (_fragy_end+notdone-_fragy0-notstart)*(nhfrags*sizeof(variance[0]))); + /*Except for the first time, we want to point to the middle of the row.*/ + y=(_fragy0<<3)+(notstart<<2); + dst_ystride=_dst->stride; + src_ystride=_src->stride; + dst=_dst->data+y*(ptrdiff_t)dst_ystride; + src=_src->data+y*(ptrdiff_t)src_ystride; + width=_dst->width; + for(;y<4;y++){ + memcpy(dst,src,width*sizeof(dst[0])); + dst+=dst_ystride; + src+=src_ystride; + } + /*We also want to skip the last row in the frame for this loop.*/ + y_end=_fragy_end-!notdone<<3; + for(;y<y_end;y+=8){ + qstep=_dec->pp_dc_scale[*dc_qi]; + flimit=(qstep*3)>>2; + oc_filter_hedge(dst,dst_ystride,src-src_ystride,src_ystride, + qstep,flimit,variance,variance+nhfrags); + variance++; + dc_qi++; + for(x=8;x<width;x+=8){ + qstep=_dec->pp_dc_scale[*dc_qi]; + flimit=(qstep*3)>>2; + oc_filter_hedge(dst+x,dst_ystride,src+x-src_ystride,src_ystride, + qstep,flimit,variance,variance+nhfrags); + oc_filter_vedge(dst+x-(dst_ystride<<2)-4,dst_ystride, + qstep,flimit,variance-1); + variance++; + dc_qi++; + } + dst+=dst_ystride<<3; + src+=src_ystride<<3; + } + /*And finally, handle the last row in the frame, if it's in the range.*/ + if(!notdone){ + int height; + height=_dst->height; + for(;y<height;y++){ + memcpy(dst,src,width*sizeof(dst[0])); + dst+=dst_ystride; + src+=src_ystride; + } + /*Filter the last row of vertical block edges.*/ + dc_qi++; + for(x=8;x<width;x+=8){ + qstep=_dec->pp_dc_scale[*dc_qi++]; + flimit=(qstep*3)>>2; + oc_filter_vedge(dst+x-(dst_ystride<<3)-4,dst_ystride, + qstep,flimit,variance++); + } + } +} + +static void oc_dering_block(unsigned char *_idata,int _ystride,int _b, + int _dc_scale,int _sharp_mod,int _strong){ + static const unsigned char OC_MOD_MAX[2]={24,32}; + static const unsigned char OC_MOD_SHIFT[2]={1,0}; + const unsigned char *psrc; + const unsigned char *src; + const unsigned char *nsrc; + unsigned char *dst; + int vmod[72]; + int hmod[72]; + int mod_hi; + int by; + int bx; + mod_hi=OC_MINI(3*_dc_scale,OC_MOD_MAX[_strong]); + dst=_idata; + src=dst; + psrc=src-(_ystride&-!(_b&4)); + for(by=0;by<9;by++){ + for(bx=0;bx<8;bx++){ + int mod; + mod=32+_dc_scale-(abs(src[bx]-psrc[bx])<<OC_MOD_SHIFT[_strong]); + vmod[(by<<3)+bx]=mod<-64?_sharp_mod:OC_CLAMPI(0,mod,mod_hi); + } + psrc=src; + src+=_ystride&-(!(_b&8)|by<7); + } + nsrc=dst; + psrc=dst-!(_b&1); + for(bx=0;bx<9;bx++){ + src=nsrc; + for(by=0;by<8;by++){ + int mod; + mod=32+_dc_scale-(abs(*src-*psrc)<<OC_MOD_SHIFT[_strong]); + hmod[(bx<<3)+by]=mod<-64?_sharp_mod:OC_CLAMPI(0,mod,mod_hi); + psrc+=_ystride; + src+=_ystride; + } + psrc=nsrc; + nsrc+=!(_b&2)|bx<7; + } + src=dst; + psrc=src-(_ystride&-!(_b&4)); + nsrc=src+_ystride; + for(by=0;by<8;by++){ + int a; + int b; + int w; + a=128; + b=64; + w=hmod[by]; + a-=w; + b+=w**(src-!(_b&1)); + w=vmod[by<<3]; + a-=w; + b+=w*psrc[0]; + w=vmod[by+1<<3]; + a-=w; + b+=w*nsrc[0]; + w=hmod[(1<<3)+by]; + a-=w; + b+=w*src[1]; + dst[0]=OC_CLAMP255(a*src[0]+b>>7); + for(bx=1;bx<7;bx++){ + a=128; + b=64; + w=hmod[(bx<<3)+by]; + a-=w; + b+=w*src[bx-1]; + w=vmod[(by<<3)+bx]; + a-=w; + b+=w*psrc[bx]; + w=vmod[(by+1<<3)+bx]; + a-=w; + b+=w*nsrc[bx]; + w=hmod[(bx+1<<3)+by]; + a-=w; + b+=w*src[bx+1]; + dst[bx]=OC_CLAMP255(a*src[bx]+b>>7); + } + a=128; + b=64; + w=hmod[(7<<3)+by]; + a-=w; + b+=w*src[6]; + w=vmod[(by<<3)+7]; + a-=w; + b+=w*psrc[7]; + w=vmod[(by+1<<3)+7]; + a-=w; + b+=w*nsrc[7]; + w=hmod[(8<<3)+by]; + a-=w; + b+=w*src[7+!(_b&2)]; + dst[7]=OC_CLAMP255(a*src[7]+b>>7); + dst+=_ystride; + psrc=src; + src=nsrc; + nsrc+=_ystride&-(!(_b&8)|by<6); + } +} + +#define OC_DERING_THRESH1 (384) +#define OC_DERING_THRESH2 (4*OC_DERING_THRESH1) +#define OC_DERING_THRESH3 (5*OC_DERING_THRESH1) +#define OC_DERING_THRESH4 (10*OC_DERING_THRESH1) + +static void oc_dec_dering_frag_rows(oc_dec_ctx *_dec,th_img_plane *_img, + int _pli,int _fragy0,int _fragy_end){ + th_img_plane *iplane; + oc_fragment_plane *fplane; + oc_fragment *frag; + int *variance; + unsigned char *idata; + ptrdiff_t froffset; + int ystride; + int nhfrags; + int sthresh; + int strong; + int y_end; + int width; + int height; + int y; + int x; + iplane=_img+_pli; + fplane=_dec->state.fplanes+_pli; + nhfrags=fplane->nhfrags; + froffset=fplane->froffset+_fragy0*(ptrdiff_t)nhfrags; + variance=_dec->variances+froffset; + frag=_dec->state.frags+froffset; + strong=_dec->pp_level>=(_pli?OC_PP_LEVEL_SDERINGC:OC_PP_LEVEL_SDERINGY); + sthresh=_pli?OC_DERING_THRESH4:OC_DERING_THRESH3; + y=_fragy0<<3; + ystride=iplane->stride; + idata=iplane->data+y*(ptrdiff_t)ystride; + y_end=_fragy_end<<3; + width=iplane->width; + height=iplane->height; + for(;y<y_end;y+=8){ + for(x=0;x<width;x+=8){ + int b; + int qi; + int var; + qi=_dec->state.qis[frag->qii]; + var=*variance; + b=(x<=0)|(x+8>=width)<<1|(y<=0)<<2|(y+8>=height)<<3; + if(strong&&var>sthresh){ + oc_dering_block(idata+x,ystride,b, + _dec->pp_dc_scale[qi],_dec->pp_sharp_mod[qi],1); + if(_pli||!(b&1)&&*(variance-1)>OC_DERING_THRESH4|| + !(b&2)&&variance[1]>OC_DERING_THRESH4|| + !(b&4)&&*(variance-nhfrags)>OC_DERING_THRESH4|| + !(b&8)&&variance[nhfrags]>OC_DERING_THRESH4){ + oc_dering_block(idata+x,ystride,b, + _dec->pp_dc_scale[qi],_dec->pp_sharp_mod[qi],1); + oc_dering_block(idata+x,ystride,b, + _dec->pp_dc_scale[qi],_dec->pp_sharp_mod[qi],1); + } + } + else if(var>OC_DERING_THRESH2){ + oc_dering_block(idata+x,ystride,b, + _dec->pp_dc_scale[qi],_dec->pp_sharp_mod[qi],1); + } + else if(var>OC_DERING_THRESH1){ + oc_dering_block(idata+x,ystride,b, + _dec->pp_dc_scale[qi],_dec->pp_sharp_mod[qi],0); + } + frag++; + variance++; + } + idata+=ystride<<3; + } +} + + + +th_dec_ctx *th_decode_alloc(const th_info *_info,const th_setup_info *_setup){ + oc_dec_ctx *dec; + if(_info==NULL||_setup==NULL)return NULL; + dec=oc_aligned_malloc(sizeof(*dec),16); + if(dec==NULL||oc_dec_init(dec,_info,_setup)<0){ + oc_aligned_free(dec); + return NULL; + } + dec->state.curframe_num=0; + return dec; +} + +void th_decode_free(th_dec_ctx *_dec){ + if(_dec!=NULL){ + oc_dec_clear(_dec); + oc_aligned_free(_dec); + } +} + +int th_decode_ctl(th_dec_ctx *_dec,int _req,void *_buf, + size_t _buf_sz){ + switch(_req){ + case TH_DECCTL_GET_PPLEVEL_MAX:{ + if(_dec==NULL||_buf==NULL)return TH_EFAULT; + if(_buf_sz!=sizeof(int))return TH_EINVAL; + (*(int *)_buf)=OC_PP_LEVEL_MAX; + return 0; + }break; + case TH_DECCTL_SET_PPLEVEL:{ + int pp_level; + if(_dec==NULL||_buf==NULL)return TH_EFAULT; + if(_buf_sz!=sizeof(int))return TH_EINVAL; + pp_level=*(int *)_buf; + if(pp_level<0||pp_level>OC_PP_LEVEL_MAX)return TH_EINVAL; + _dec->pp_level=pp_level; + return 0; + }break; + case TH_DECCTL_SET_GRANPOS:{ + ogg_int64_t granpos; + if(_dec==NULL||_buf==NULL)return TH_EFAULT; + if(_buf_sz!=sizeof(ogg_int64_t))return TH_EINVAL; + granpos=*(ogg_int64_t *)_buf; + if(granpos<0)return TH_EINVAL; + _dec->state.granpos=granpos; + _dec->state.keyframe_num=(granpos>>_dec->state.info.keyframe_granule_shift) + -_dec->state.granpos_bias; + _dec->state.curframe_num=_dec->state.keyframe_num + +(granpos&(1<<_dec->state.info.keyframe_granule_shift)-1); + return 0; + }break; + case TH_DECCTL_SET_STRIPE_CB:{ + th_stripe_callback *cb; + if(_dec==NULL||_buf==NULL)return TH_EFAULT; + if(_buf_sz!=sizeof(th_stripe_callback))return TH_EINVAL; + cb=(th_stripe_callback *)_buf; + _dec->stripe_cb.ctx=cb->ctx; + _dec->stripe_cb.stripe_decoded=cb->stripe_decoded; + return 0; + }break; +#ifdef HAVE_CAIRO + case TH_DECCTL_SET_TELEMETRY_MBMODE:{ + if(_dec==NULL||_buf==NULL)return TH_EFAULT; + if(_buf_sz!=sizeof(int))return TH_EINVAL; + _dec->telemetry_mbmode=*(int *)_buf; + return 0; + }break; + case TH_DECCTL_SET_TELEMETRY_MV:{ + if(_dec==NULL||_buf==NULL)return TH_EFAULT; + if(_buf_sz!=sizeof(int))return TH_EINVAL; + _dec->telemetry_mv=*(int *)_buf; + return 0; + }break; + case TH_DECCTL_SET_TELEMETRY_QI:{ + if(_dec==NULL||_buf==NULL)return TH_EFAULT; + if(_buf_sz!=sizeof(int))return TH_EINVAL; + _dec->telemetry_qi=*(int *)_buf; + return 0; + }break; + case TH_DECCTL_SET_TELEMETRY_BITS:{ + if(_dec==NULL||_buf==NULL)return TH_EFAULT; + if(_buf_sz!=sizeof(int))return TH_EINVAL; + _dec->telemetry_bits=*(int *)_buf; + return 0; + }break; +#endif + default:return TH_EIMPL; + } +} + +/*We're decoding an INTER frame, but have no initialized reference + buffers (i.e., decoding did not start on a key frame). + We initialize them to a solid gray here.*/ +static void oc_dec_init_dummy_frame(th_dec_ctx *_dec){ + th_info *info; + size_t yplane_sz; + size_t cplane_sz; + ptrdiff_t yoffset; + int yhstride; + int yheight; + int chstride; + int cheight; + _dec->state.ref_frame_idx[OC_FRAME_GOLD]=0; + _dec->state.ref_frame_idx[OC_FRAME_PREV]=0; + _dec->state.ref_frame_idx[OC_FRAME_SELF]=0; + _dec->state.ref_frame_data[OC_FRAME_GOLD]= + _dec->state.ref_frame_data[OC_FRAME_PREV]= + _dec->state.ref_frame_data[OC_FRAME_SELF]= + _dec->state.ref_frame_bufs[0][0].data; + memcpy(_dec->pp_frame_buf,_dec->state.ref_frame_bufs[0], + sizeof(_dec->pp_frame_buf[0])*3); + info=&_dec->state.info; + yhstride=abs(_dec->state.ref_ystride[0]); + yheight=info->frame_height+2*OC_UMV_PADDING; + chstride=abs(_dec->state.ref_ystride[1]); + cheight=yheight>>!(info->pixel_fmt&2); + yplane_sz=yhstride*(size_t)yheight+16; + cplane_sz=chstride*(size_t)cheight; + yoffset=yhstride*(ptrdiff_t)(yheight-OC_UMV_PADDING-1)+OC_UMV_PADDING; + memset(_dec->state.ref_frame_data[0]-yoffset,0x80,yplane_sz+2*cplane_sz); +} + +#if defined(HAVE_CAIRO) +static void oc_render_telemetry(th_dec_ctx *_dec,th_ycbcr_buffer _ycbcr, + int _telemetry){ + /*Stuff the plane into cairo.*/ + cairo_surface_t *cs; + unsigned char *data; + unsigned char *y_row; + unsigned char *u_row; + unsigned char *v_row; + unsigned char *rgb_row; + int cstride; + int w; + int h; + int x; + int y; + int hdec; + int vdec; + w=_ycbcr[0].width; + h=_ycbcr[0].height; + hdec=!(_dec->state.info.pixel_fmt&1); + vdec=!(_dec->state.info.pixel_fmt&2); + /*Lazy data buffer init. + We could try to re-use the post-processing buffer, which would save + memory, but complicate the allocation logic there. + I don't think anyone cares about memory usage when using telemetry; it is + not meant for embedded devices.*/ + if(_dec->telemetry_frame_data==NULL){ + _dec->telemetry_frame_data=_ogg_malloc( + (w*h+2*(w>>hdec)*(h>>vdec))*sizeof(*_dec->telemetry_frame_data)); + if(_dec->telemetry_frame_data==NULL)return; + } + cs=cairo_image_surface_create(CAIRO_FORMAT_RGB24,w,h); + /*Sadly, no YUV support in Cairo (yet); convert into the RGB buffer.*/ + data=cairo_image_surface_get_data(cs); + if(data==NULL){ + cairo_surface_destroy(cs); + return; + } + cstride=cairo_image_surface_get_stride(cs); + y_row=_ycbcr[0].data; + u_row=_ycbcr[1].data; + v_row=_ycbcr[2].data; + rgb_row=data; + for(y=0;y<h;y++){ + for(x=0;x<w;x++){ + int r; + int g; + int b; + r=(1904000*y_row[x]+2609823*v_row[x>>hdec]-363703744)/1635200; + g=(3827562*y_row[x]-1287801*u_row[x>>hdec] + -2672387*v_row[x>>hdec]+447306710)/3287200; + b=(952000*y_row[x]+1649289*u_row[x>>hdec]-225932192)/817600; + rgb_row[4*x+0]=OC_CLAMP255(b); + rgb_row[4*x+1]=OC_CLAMP255(g); + rgb_row[4*x+2]=OC_CLAMP255(r); + } + y_row+=_ycbcr[0].stride; + u_row+=_ycbcr[1].stride&-((y&1)|!vdec); + v_row+=_ycbcr[2].stride&-((y&1)|!vdec); + rgb_row+=cstride; + } + /*Draw coded identifier for each macroblock (stored in Hilbert order).*/ + { + cairo_t *c; + const oc_fragment *frags; + oc_mv *frag_mvs; + const signed char *mb_modes; + oc_mb_map *mb_maps; + size_t nmbs; + size_t mbi; + int row2; + int col2; + int qim[3]={0,0,0}; + if(_dec->state.nqis==2){ + int bqi; + bqi=_dec->state.qis[0]; + if(_dec->state.qis[1]>bqi)qim[1]=1; + if(_dec->state.qis[1]<bqi)qim[1]=-1; + } + if(_dec->state.nqis==3){ + int bqi; + int cqi; + int dqi; + bqi=_dec->state.qis[0]; + cqi=_dec->state.qis[1]; + dqi=_dec->state.qis[2]; + if(cqi>bqi&&dqi>bqi){ + if(dqi>cqi){ + qim[1]=1; + qim[2]=2; + } + else{ + qim[1]=2; + qim[2]=1; + } + } + else if(cqi<bqi&&dqi<bqi){ + if(dqi<cqi){ + qim[1]=-1; + qim[2]=-2; + } + else{ + qim[1]=-2; + qim[2]=-1; + } + } + else{ + if(cqi<bqi)qim[1]=-1; + else qim[1]=1; + if(dqi<bqi)qim[2]=-1; + else qim[2]=1; + } + } + c=cairo_create(cs); + frags=_dec->state.frags; + frag_mvs=_dec->state.frag_mvs; + mb_modes=_dec->state.mb_modes; + mb_maps=_dec->state.mb_maps; + nmbs=_dec->state.nmbs; + row2=0; + col2=0; + for(mbi=0;mbi<nmbs;mbi++){ + float x; + float y; + int bi; + y=h-(row2+((col2+1>>1)&1))*16-16; + x=(col2>>1)*16; + cairo_set_line_width(c,1.); + /*Keyframe (all intra) red box.*/ + if(_dec->state.frame_type==OC_INTRA_FRAME){ + if(_dec->telemetry_mbmode&0x02){ + cairo_set_source_rgba(c,1.,0,0,.5); + cairo_rectangle(c,x+2.5,y+2.5,11,11); + cairo_stroke_preserve(c); + cairo_set_source_rgba(c,1.,0,0,.25); + cairo_fill(c); + } + } + else{ + ptrdiff_t fragi; + int frag_mvx; + int frag_mvy; + for(bi=0;bi<4;bi++){ + fragi=mb_maps[mbi][0][bi]; + if(fragi>=0&&frags[fragi].coded){ + frag_mvx=OC_MV_X(frag_mvs[fragi]); + frag_mvy=OC_MV_Y(frag_mvs[fragi]); + break; + } + } + if(bi<4){ + switch(mb_modes[mbi]){ + case OC_MODE_INTRA:{ + if(_dec->telemetry_mbmode&0x02){ + cairo_set_source_rgba(c,1.,0,0,.5); + cairo_rectangle(c,x+2.5,y+2.5,11,11); + cairo_stroke_preserve(c); + cairo_set_source_rgba(c,1.,0,0,.25); + cairo_fill(c); + } + }break; + case OC_MODE_INTER_NOMV:{ + if(_dec->telemetry_mbmode&0x01){ + cairo_set_source_rgba(c,0,0,1.,.5); + cairo_rectangle(c,x+2.5,y+2.5,11,11); + cairo_stroke_preserve(c); + cairo_set_source_rgba(c,0,0,1.,.25); + cairo_fill(c); + } + }break; + case OC_MODE_INTER_MV:{ + if(_dec->telemetry_mbmode&0x04){ + cairo_rectangle(c,x+2.5,y+2.5,11,11); + cairo_set_source_rgba(c,0,1.,0,.5); + cairo_stroke(c); + } + if(_dec->telemetry_mv&0x04){ + cairo_move_to(c,x+8+frag_mvx,y+8-frag_mvy); + cairo_set_source_rgba(c,1.,1.,1.,.9); + cairo_set_line_width(c,3.); + cairo_line_to(c,x+8+frag_mvx*.66,y+8-frag_mvy*.66); + cairo_stroke_preserve(c); + cairo_set_line_width(c,2.); + cairo_line_to(c,x+8+frag_mvx*.33,y+8-frag_mvy*.33); + cairo_stroke_preserve(c); + cairo_set_line_width(c,1.); + cairo_line_to(c,x+8,y+8); + cairo_stroke(c); + } + }break; + case OC_MODE_INTER_MV_LAST:{ + if(_dec->telemetry_mbmode&0x08){ + cairo_rectangle(c,x+2.5,y+2.5,11,11); + cairo_set_source_rgba(c,0,1.,0,.5); + cairo_move_to(c,x+13.5,y+2.5); + cairo_line_to(c,x+2.5,y+8); + cairo_line_to(c,x+13.5,y+13.5); + cairo_stroke(c); + } + if(_dec->telemetry_mv&0x08){ + cairo_move_to(c,x+8+frag_mvx,y+8-frag_mvy); + cairo_set_source_rgba(c,1.,1.,1.,.9); + cairo_set_line_width(c,3.); + cairo_line_to(c,x+8+frag_mvx*.66,y+8-frag_mvy*.66); + cairo_stroke_preserve(c); + cairo_set_line_width(c,2.); + cairo_line_to(c,x+8+frag_mvx*.33,y+8-frag_mvy*.33); + cairo_stroke_preserve(c); + cairo_set_line_width(c,1.); + cairo_line_to(c,x+8,y+8); + cairo_stroke(c); + } + }break; + case OC_MODE_INTER_MV_LAST2:{ + if(_dec->telemetry_mbmode&0x10){ + cairo_rectangle(c,x+2.5,y+2.5,11,11); + cairo_set_source_rgba(c,0,1.,0,.5); + cairo_move_to(c,x+8,y+2.5); + cairo_line_to(c,x+2.5,y+8); + cairo_line_to(c,x+8,y+13.5); + cairo_move_to(c,x+13.5,y+2.5); + cairo_line_to(c,x+8,y+8); + cairo_line_to(c,x+13.5,y+13.5); + cairo_stroke(c); + } + if(_dec->telemetry_mv&0x10){ + cairo_move_to(c,x+8+frag_mvx,y+8-frag_mvy); + cairo_set_source_rgba(c,1.,1.,1.,.9); + cairo_set_line_width(c,3.); + cairo_line_to(c,x+8+frag_mvx*.66,y+8-frag_mvy*.66); + cairo_stroke_preserve(c); + cairo_set_line_width(c,2.); + cairo_line_to(c,x+8+frag_mvx*.33,y+8-frag_mvy*.33); + cairo_stroke_preserve(c); + cairo_set_line_width(c,1.); + cairo_line_to(c,x+8,y+8); + cairo_stroke(c); + } + }break; + case OC_MODE_GOLDEN_NOMV:{ + if(_dec->telemetry_mbmode&0x20){ + cairo_set_source_rgba(c,1.,1.,0,.5); + cairo_rectangle(c,x+2.5,y+2.5,11,11); + cairo_stroke_preserve(c); + cairo_set_source_rgba(c,1.,1.,0,.25); + cairo_fill(c); + } + }break; + case OC_MODE_GOLDEN_MV:{ + if(_dec->telemetry_mbmode&0x40){ + cairo_rectangle(c,x+2.5,y+2.5,11,11); + cairo_set_source_rgba(c,1.,1.,0,.5); + cairo_stroke(c); + } + if(_dec->telemetry_mv&0x40){ + cairo_move_to(c,x+8+frag_mvx,y+8-frag_mvy); + cairo_set_source_rgba(c,1.,1.,1.,.9); + cairo_set_line_width(c,3.); + cairo_line_to(c,x+8+frag_mvx*.66,y+8-frag_mvy*.66); + cairo_stroke_preserve(c); + cairo_set_line_width(c,2.); + cairo_line_to(c,x+8+frag_mvx*.33,y+8-frag_mvy*.33); + cairo_stroke_preserve(c); + cairo_set_line_width(c,1.); + cairo_line_to(c,x+8,y+8); + cairo_stroke(c); + } + }break; + case OC_MODE_INTER_MV_FOUR:{ + if(_dec->telemetry_mbmode&0x80){ + cairo_rectangle(c,x+2.5,y+2.5,4,4); + cairo_rectangle(c,x+9.5,y+2.5,4,4); + cairo_rectangle(c,x+2.5,y+9.5,4,4); + cairo_rectangle(c,x+9.5,y+9.5,4,4); + cairo_set_source_rgba(c,0,1.,0,.5); + cairo_stroke(c); + } + /*4mv is odd, coded in raster order.*/ + fragi=mb_maps[mbi][0][0]; + if(frags[fragi].coded&&_dec->telemetry_mv&0x80){ + frag_mvx=OC_MV_X(frag_mvs[fragi]); + frag_mvx=OC_MV_Y(frag_mvs[fragi]); + cairo_move_to(c,x+4+frag_mvx,y+12-frag_mvy); + cairo_set_source_rgba(c,1.,1.,1.,.9); + cairo_set_line_width(c,3.); + cairo_line_to(c,x+4+frag_mvx*.66,y+12-frag_mvy*.66); + cairo_stroke_preserve(c); + cairo_set_line_width(c,2.); + cairo_line_to(c,x+4+frag_mvx*.33,y+12-frag_mvy*.33); + cairo_stroke_preserve(c); + cairo_set_line_width(c,1.); + cairo_line_to(c,x+4,y+12); + cairo_stroke(c); + } + fragi=mb_maps[mbi][0][1]; + if(frags[fragi].coded&&_dec->telemetry_mv&0x80){ + frag_mvx=OC_MV_X(frag_mvs[fragi]); + frag_mvx=OC_MV_Y(frag_mvs[fragi]); + cairo_move_to(c,x+12+frag_mvx,y+12-frag_mvy); + cairo_set_source_rgba(c,1.,1.,1.,.9); + cairo_set_line_width(c,3.); + cairo_line_to(c,x+12+frag_mvx*.66,y+12-frag_mvy*.66); + cairo_stroke_preserve(c); + cairo_set_line_width(c,2.); + cairo_line_to(c,x+12+frag_mvx*.33,y+12-frag_mvy*.33); + cairo_stroke_preserve(c); + cairo_set_line_width(c,1.); + cairo_line_to(c,x+12,y+12); + cairo_stroke(c); + } + fragi=mb_maps[mbi][0][2]; + if(frags[fragi].coded&&_dec->telemetry_mv&0x80){ + frag_mvx=OC_MV_X(frag_mvs[fragi]); + frag_mvx=OC_MV_Y(frag_mvs[fragi]); + cairo_move_to(c,x+4+frag_mvx,y+4-frag_mvy); + cairo_set_source_rgba(c,1.,1.,1.,.9); + cairo_set_line_width(c,3.); + cairo_line_to(c,x+4+frag_mvx*.66,y+4-frag_mvy*.66); + cairo_stroke_preserve(c); + cairo_set_line_width(c,2.); + cairo_line_to(c,x+4+frag_mvx*.33,y+4-frag_mvy*.33); + cairo_stroke_preserve(c); + cairo_set_line_width(c,1.); + cairo_line_to(c,x+4,y+4); + cairo_stroke(c); + } + fragi=mb_maps[mbi][0][3]; + if(frags[fragi].coded&&_dec->telemetry_mv&0x80){ + frag_mvx=OC_MV_X(frag_mvs[fragi]); + frag_mvx=OC_MV_Y(frag_mvs[fragi]); + cairo_move_to(c,x+12+frag_mvx,y+4-frag_mvy); + cairo_set_source_rgba(c,1.,1.,1.,.9); + cairo_set_line_width(c,3.); + cairo_line_to(c,x+12+frag_mvx*.66,y+4-frag_mvy*.66); + cairo_stroke_preserve(c); + cairo_set_line_width(c,2.); + cairo_line_to(c,x+12+frag_mvx*.33,y+4-frag_mvy*.33); + cairo_stroke_preserve(c); + cairo_set_line_width(c,1.); + cairo_line_to(c,x+12,y+4); + cairo_stroke(c); + } + }break; + } + } + } + /*qii illustration.*/ + if(_dec->telemetry_qi&0x2){ + cairo_set_line_cap(c,CAIRO_LINE_CAP_SQUARE); + for(bi=0;bi<4;bi++){ + ptrdiff_t fragi; + int qiv; + int xp; + int yp; + xp=x+(bi&1)*8; + yp=y+8-(bi&2)*4; + fragi=mb_maps[mbi][0][bi]; + if(fragi>=0&&frags[fragi].coded){ + qiv=qim[frags[fragi].qii]; + cairo_set_line_width(c,3.); + cairo_set_source_rgba(c,0.,0.,0.,.5); + switch(qiv){ + /*Double plus:*/ + case 2:{ + if((bi&1)^((bi&2)>>1)){ + cairo_move_to(c,xp+2.5,yp+1.5); + cairo_line_to(c,xp+2.5,yp+3.5); + cairo_move_to(c,xp+1.5,yp+2.5); + cairo_line_to(c,xp+3.5,yp+2.5); + cairo_move_to(c,xp+5.5,yp+4.5); + cairo_line_to(c,xp+5.5,yp+6.5); + cairo_move_to(c,xp+4.5,yp+5.5); + cairo_line_to(c,xp+6.5,yp+5.5); + cairo_stroke_preserve(c); + cairo_set_source_rgba(c,0.,1.,1.,1.); + } + else{ + cairo_move_to(c,xp+5.5,yp+1.5); + cairo_line_to(c,xp+5.5,yp+3.5); + cairo_move_to(c,xp+4.5,yp+2.5); + cairo_line_to(c,xp+6.5,yp+2.5); + cairo_move_to(c,xp+2.5,yp+4.5); + cairo_line_to(c,xp+2.5,yp+6.5); + cairo_move_to(c,xp+1.5,yp+5.5); + cairo_line_to(c,xp+3.5,yp+5.5); + cairo_stroke_preserve(c); + cairo_set_source_rgba(c,0.,1.,1.,1.); + } + }break; + /*Double minus:*/ + case -2:{ + cairo_move_to(c,xp+2.5,yp+2.5); + cairo_line_to(c,xp+5.5,yp+2.5); + cairo_move_to(c,xp+2.5,yp+5.5); + cairo_line_to(c,xp+5.5,yp+5.5); + cairo_stroke_preserve(c); + cairo_set_source_rgba(c,1.,1.,1.,1.); + }break; + /*Plus:*/ + case 1:{ + if((bi&2)==0)yp-=2; + if((bi&1)==0)xp-=2; + cairo_move_to(c,xp+4.5,yp+2.5); + cairo_line_to(c,xp+4.5,yp+6.5); + cairo_move_to(c,xp+2.5,yp+4.5); + cairo_line_to(c,xp+6.5,yp+4.5); + cairo_stroke_preserve(c); + cairo_set_source_rgba(c,.1,1.,.3,1.); + break; + } + /*Fall through.*/ + /*Minus:*/ + case -1:{ + cairo_move_to(c,xp+2.5,yp+4.5); + cairo_line_to(c,xp+6.5,yp+4.5); + cairo_stroke_preserve(c); + cairo_set_source_rgba(c,1.,.3,.1,1.); + }break; + default:continue; + } + cairo_set_line_width(c,1.); + cairo_stroke(c); + } + } + } + col2++; + if((col2>>1)>=_dec->state.nhmbs){ + col2=0; + row2+=2; + } + } + /*Bit usage indicator[s]:*/ + if(_dec->telemetry_bits){ + int widths[6]; + int fpsn; + int fpsd; + int mult; + int fullw; + int padw; + int i; + fpsn=_dec->state.info.fps_numerator; + fpsd=_dec->state.info.fps_denominator; + mult=(_dec->telemetry_bits>=0xFF?1:_dec->telemetry_bits); + fullw=250.f*h*fpsd*mult/fpsn; + padw=w-24; + /*Header and coded block bits.*/ + if(_dec->telemetry_frame_bytes<0|| + _dec->telemetry_frame_bytes==OC_LOTS_OF_BITS){ + _dec->telemetry_frame_bytes=0; + } + if(_dec->telemetry_coding_bytes<0|| + _dec->telemetry_coding_bytes>_dec->telemetry_frame_bytes){ + _dec->telemetry_coding_bytes=0; + } + if(_dec->telemetry_mode_bytes<0|| + _dec->telemetry_mode_bytes>_dec->telemetry_frame_bytes){ + _dec->telemetry_mode_bytes=0; + } + if(_dec->telemetry_mv_bytes<0|| + _dec->telemetry_mv_bytes>_dec->telemetry_frame_bytes){ + _dec->telemetry_mv_bytes=0; + } + if(_dec->telemetry_qi_bytes<0|| + _dec->telemetry_qi_bytes>_dec->telemetry_frame_bytes){ + _dec->telemetry_qi_bytes=0; + } + if(_dec->telemetry_dc_bytes<0|| + _dec->telemetry_dc_bytes>_dec->telemetry_frame_bytes){ + _dec->telemetry_dc_bytes=0; + } + widths[0]=padw* + (_dec->telemetry_frame_bytes-_dec->telemetry_coding_bytes)/fullw; + widths[1]=padw* + (_dec->telemetry_coding_bytes-_dec->telemetry_mode_bytes)/fullw; + widths[2]=padw* + (_dec->telemetry_mode_bytes-_dec->telemetry_mv_bytes)/fullw; + widths[3]=padw*(_dec->telemetry_mv_bytes-_dec->telemetry_qi_bytes)/fullw; + widths[4]=padw*(_dec->telemetry_qi_bytes-_dec->telemetry_dc_bytes)/fullw; + widths[5]=padw*(_dec->telemetry_dc_bytes)/fullw; + for(i=0;i<6;i++)if(widths[i]>w)widths[i]=w; + cairo_set_source_rgba(c,.0,.0,.0,.6); + cairo_rectangle(c,10,h-33,widths[0]+1,5); + cairo_rectangle(c,10,h-29,widths[1]+1,5); + cairo_rectangle(c,10,h-25,widths[2]+1,5); + cairo_rectangle(c,10,h-21,widths[3]+1,5); + cairo_rectangle(c,10,h-17,widths[4]+1,5); + cairo_rectangle(c,10,h-13,widths[5]+1,5); + cairo_fill(c); + cairo_set_source_rgb(c,1,0,0); + cairo_rectangle(c,10.5,h-32.5,widths[0],4); + cairo_fill(c); + cairo_set_source_rgb(c,0,1,0); + cairo_rectangle(c,10.5,h-28.5,widths[1],4); + cairo_fill(c); + cairo_set_source_rgb(c,0,0,1); + cairo_rectangle(c,10.5,h-24.5,widths[2],4); + cairo_fill(c); + cairo_set_source_rgb(c,.6,.4,.0); + cairo_rectangle(c,10.5,h-20.5,widths[3],4); + cairo_fill(c); + cairo_set_source_rgb(c,.3,.3,.3); + cairo_rectangle(c,10.5,h-16.5,widths[4],4); + cairo_fill(c); + cairo_set_source_rgb(c,.5,.5,.8); + cairo_rectangle(c,10.5,h-12.5,widths[5],4); + cairo_fill(c); + } + /*Master qi indicator[s]:*/ + if(_dec->telemetry_qi&0x1){ + cairo_text_extents_t extents; + char buffer[10]; + int p; + int y; + p=0; + y=h-7.5; + if(_dec->state.qis[0]>=10)buffer[p++]=48+_dec->state.qis[0]/10; + buffer[p++]=48+_dec->state.qis[0]%10; + if(_dec->state.nqis>=2){ + buffer[p++]=' '; + if(_dec->state.qis[1]>=10)buffer[p++]=48+_dec->state.qis[1]/10; + buffer[p++]=48+_dec->state.qis[1]%10; + } + if(_dec->state.nqis==3){ + buffer[p++]=' '; + if(_dec->state.qis[2]>=10)buffer[p++]=48+_dec->state.qis[2]/10; + buffer[p++]=48+_dec->state.qis[2]%10; + } + buffer[p++]='\0'; + cairo_select_font_face(c,"sans", + CAIRO_FONT_SLANT_NORMAL,CAIRO_FONT_WEIGHT_BOLD); + cairo_set_font_size(c,18); + cairo_text_extents(c,buffer,&extents); + cairo_set_source_rgb(c,1,1,1); + cairo_move_to(c,w-extents.x_advance-10,y); + cairo_show_text(c,buffer); + cairo_set_source_rgb(c,0,0,0); + cairo_move_to(c,w-extents.x_advance-10,y); + cairo_text_path(c,buffer); + cairo_set_line_width(c,.8); + cairo_set_line_join(c,CAIRO_LINE_JOIN_ROUND); + cairo_stroke(c); + } + cairo_destroy(c); + } + /*Out of the Cairo plane into the telemetry YUV buffer.*/ + _ycbcr[0].data=_dec->telemetry_frame_data; + _ycbcr[0].stride=_ycbcr[0].width; + _ycbcr[1].data=_ycbcr[0].data+h*_ycbcr[0].stride; + _ycbcr[1].stride=_ycbcr[1].width; + _ycbcr[2].data=_ycbcr[1].data+(h>>vdec)*_ycbcr[1].stride; + _ycbcr[2].stride=_ycbcr[2].width; + y_row=_ycbcr[0].data; + u_row=_ycbcr[1].data; + v_row=_ycbcr[2].data; + rgb_row=data; + /*This is one of the few places it's worth handling chroma on a + case-by-case basis.*/ + switch(_dec->state.info.pixel_fmt){ + case TH_PF_420:{ + for(y=0;y<h;y+=2){ + unsigned char *y_row2; + unsigned char *rgb_row2; + y_row2=y_row+_ycbcr[0].stride; + rgb_row2=rgb_row+cstride; + for(x=0;x<w;x+=2){ + int y; + int u; + int v; + y=(65481*rgb_row[4*x+2]+128553*rgb_row[4*x+1] + +24966*rgb_row[4*x+0]+4207500)/255000; + y_row[x]=OC_CLAMP255(y); + y=(65481*rgb_row[4*x+6]+128553*rgb_row[4*x+5] + +24966*rgb_row[4*x+4]+4207500)/255000; + y_row[x+1]=OC_CLAMP255(y); + y=(65481*rgb_row2[4*x+2]+128553*rgb_row2[4*x+1] + +24966*rgb_row2[4*x+0]+4207500)/255000; + y_row2[x]=OC_CLAMP255(y); + y=(65481*rgb_row2[4*x+6]+128553*rgb_row2[4*x+5] + +24966*rgb_row2[4*x+4]+4207500)/255000; + y_row2[x+1]=OC_CLAMP255(y); + u=(-8372*(rgb_row[4*x+2]+rgb_row[4*x+6] + +rgb_row2[4*x+2]+rgb_row2[4*x+6]) + -16436*(rgb_row[4*x+1]+rgb_row[4*x+5] + +rgb_row2[4*x+1]+rgb_row2[4*x+5]) + +24808*(rgb_row[4*x+0]+rgb_row[4*x+4] + +rgb_row2[4*x+0]+rgb_row2[4*x+4])+29032005)/225930; + v=(39256*(rgb_row[4*x+2]+rgb_row[4*x+6] + +rgb_row2[4*x+2]+rgb_row2[4*x+6]) + -32872*(rgb_row[4*x+1]+rgb_row[4*x+5] + +rgb_row2[4*x+1]+rgb_row2[4*x+5]) + -6384*(rgb_row[4*x+0]+rgb_row[4*x+4] + +rgb_row2[4*x+0]+rgb_row2[4*x+4])+45940035)/357510; + u_row[x>>1]=OC_CLAMP255(u); + v_row[x>>1]=OC_CLAMP255(v); + } + y_row+=_ycbcr[0].stride<<1; + u_row+=_ycbcr[1].stride; + v_row+=_ycbcr[2].stride; + rgb_row+=cstride<<1; + } + }break; + case TH_PF_422:{ + for(y=0;y<h;y++){ + for(x=0;x<w;x+=2){ + int y; + int u; + int v; + y=(65481*rgb_row[4*x+2]+128553*rgb_row[4*x+1] + +24966*rgb_row[4*x+0]+4207500)/255000; + y_row[x]=OC_CLAMP255(y); + y=(65481*rgb_row[4*x+6]+128553*rgb_row[4*x+5] + +24966*rgb_row[4*x+4]+4207500)/255000; + y_row[x+1]=OC_CLAMP255(y); + u=(-16744*(rgb_row[4*x+2]+rgb_row[4*x+6]) + -32872*(rgb_row[4*x+1]+rgb_row[4*x+5]) + +49616*(rgb_row[4*x+0]+rgb_row[4*x+4])+29032005)/225930; + v=(78512*(rgb_row[4*x+2]+rgb_row[4*x+6]) + -65744*(rgb_row[4*x+1]+rgb_row[4*x+5]) + -12768*(rgb_row[4*x+0]+rgb_row[4*x+4])+45940035)/357510; + u_row[x>>1]=OC_CLAMP255(u); + v_row[x>>1]=OC_CLAMP255(v); + } + y_row+=_ycbcr[0].stride; + u_row+=_ycbcr[1].stride; + v_row+=_ycbcr[2].stride; + rgb_row+=cstride; + } + }break; + /*case TH_PF_444:*/ + default:{ + for(y=0;y<h;y++){ + for(x=0;x<w;x++){ + int y; + int u; + int v; + y=(65481*rgb_row[4*x+2]+128553*rgb_row[4*x+1] + +24966*rgb_row[4*x+0]+4207500)/255000; + u=(-33488*rgb_row[4*x+2]-65744*rgb_row[4*x+1] + +99232*rgb_row[4*x+0]+29032005)/225930; + v=(157024*rgb_row[4*x+2]-131488*rgb_row[4*x+1] + -25536*rgb_row[4*x+0]+45940035)/357510; + y_row[x]=OC_CLAMP255(y); + u_row[x]=OC_CLAMP255(u); + v_row[x]=OC_CLAMP255(v); + } + y_row+=_ycbcr[0].stride; + u_row+=_ycbcr[1].stride; + v_row+=_ycbcr[2].stride; + rgb_row+=cstride; + } + }break; + } + /*Finished. + Destroy the surface.*/ + cairo_surface_destroy(cs); +} +#endif + +int th_decode_packetin(th_dec_ctx *_dec,const ogg_packet *_op, + ogg_int64_t *_granpos){ + int ret; + if(_dec==NULL||_op==NULL)return TH_EFAULT; + /*A completely empty packet indicates a dropped frame and is treated exactly + like an inter frame with no coded blocks.*/ + if(_op->bytes==0){ + _dec->state.frame_type=OC_INTER_FRAME; + _dec->state.ntotal_coded_fragis=0; + } + else{ + oc_pack_readinit(&_dec->opb,_op->packet,_op->bytes); + ret=oc_dec_frame_header_unpack(_dec); + if(ret<0)return ret; + if(_dec->state.frame_type==OC_INTRA_FRAME)oc_dec_mark_all_intra(_dec); + else oc_dec_coded_flags_unpack(_dec); + } + /*If there have been no reference frames, and we need one, initialize one.*/ + if(_dec->state.frame_type!=OC_INTRA_FRAME&& + (_dec->state.ref_frame_idx[OC_FRAME_GOLD]<0|| + _dec->state.ref_frame_idx[OC_FRAME_PREV]<0)){ + oc_dec_init_dummy_frame(_dec); + } + /*If this was an inter frame with no coded blocks...*/ + if(_dec->state.ntotal_coded_fragis<=0){ + /*Just update the granule position and return.*/ + _dec->state.granpos=(_dec->state.keyframe_num+_dec->state.granpos_bias<< + _dec->state.info.keyframe_granule_shift) + +(_dec->state.curframe_num-_dec->state.keyframe_num); + _dec->state.curframe_num++; + if(_granpos!=NULL)*_granpos=_dec->state.granpos; + return TH_DUPFRAME; + } + else{ + th_ycbcr_buffer stripe_buf; + int stripe_fragy; + int refi; + int pli; + int notstart; + int notdone; +#ifdef HAVE_CAIRO + int telemetry; + /*Save the current telemetry state. + This prevents it from being modified in the middle of decoding this + frame, which could cause us to skip calls to the striped decoding + callback.*/ + telemetry=_dec->telemetry_mbmode||_dec->telemetry_mv|| + _dec->telemetry_qi||_dec->telemetry_bits; +#endif + /*Select a free buffer to use for the reconstructed version of this frame.*/ + for(refi=0;refi==_dec->state.ref_frame_idx[OC_FRAME_GOLD]|| + refi==_dec->state.ref_frame_idx[OC_FRAME_PREV];refi++); + _dec->state.ref_frame_idx[OC_FRAME_SELF]=refi; + _dec->state.ref_frame_data[OC_FRAME_SELF]= + _dec->state.ref_frame_bufs[refi][0].data; +#if defined(HAVE_CAIRO) + _dec->telemetry_frame_bytes=_op->bytes; +#endif + if(_dec->state.frame_type==OC_INTRA_FRAME){ + _dec->state.keyframe_num=_dec->state.curframe_num; +#if defined(HAVE_CAIRO) + _dec->telemetry_coding_bytes= + _dec->telemetry_mode_bytes= + _dec->telemetry_mv_bytes=oc_pack_bytes_left(&_dec->opb); +#endif + } + else{ +#if defined(HAVE_CAIRO) + _dec->telemetry_coding_bytes=oc_pack_bytes_left(&_dec->opb); +#endif + oc_dec_mb_modes_unpack(_dec); +#if defined(HAVE_CAIRO) + _dec->telemetry_mode_bytes=oc_pack_bytes_left(&_dec->opb); +#endif + oc_dec_mv_unpack_and_frag_modes_fill(_dec); +#if defined(HAVE_CAIRO) + _dec->telemetry_mv_bytes=oc_pack_bytes_left(&_dec->opb); +#endif + } + oc_dec_block_qis_unpack(_dec); +#if defined(HAVE_CAIRO) + _dec->telemetry_qi_bytes=oc_pack_bytes_left(&_dec->opb); +#endif + oc_dec_residual_tokens_unpack(_dec); + /*Update granule position. + This must be done before the striped decode callbacks so that the + application knows what to do with the frame data.*/ + _dec->state.granpos=(_dec->state.keyframe_num+_dec->state.granpos_bias<< + _dec->state.info.keyframe_granule_shift) + +(_dec->state.curframe_num-_dec->state.keyframe_num); + _dec->state.curframe_num++; + if(_granpos!=NULL)*_granpos=_dec->state.granpos; + /*All of the rest of the operations -- DC prediction reversal, + reconstructing coded fragments, copying uncoded fragments, loop + filtering, extending borders, and out-of-loop post-processing -- should + be pipelined. + I.e., DC prediction reversal, reconstruction, and uncoded fragment + copying are done for one or two super block rows, then loop filtering is + run as far as it can, then bordering copying, then post-processing. + For 4:2:0 video a Minimum Codable Unit or MCU contains two luma super + block rows, and one chroma. + Otherwise, an MCU consists of one super block row from each plane. + Inside each MCU, we perform all of the steps on one color plane before + moving on to the next. + After reconstruction, the additional filtering stages introduce a delay + since they need some pixels from the next fragment row. + Thus the actual number of decoded rows available is slightly smaller for + the first MCU, and slightly larger for the last. + + This entire process allows us to operate on the data while it is still in + cache, resulting in big performance improvements. + An application callback allows further application processing (blitting + to video memory, color conversion, etc.) to also use the data while it's + in cache.*/ + oc_dec_pipeline_init(_dec,&_dec->pipe); + oc_ycbcr_buffer_flip(stripe_buf,_dec->pp_frame_buf); + notstart=0; + notdone=1; + for(stripe_fragy=0;notdone;stripe_fragy+=_dec->pipe.mcu_nvfrags){ + int avail_fragy0; + int avail_fragy_end; + avail_fragy0=avail_fragy_end=_dec->state.fplanes[0].nvfrags; + notdone=stripe_fragy+_dec->pipe.mcu_nvfrags<avail_fragy_end; + for(pli=0;pli<3;pli++){ + oc_fragment_plane *fplane; + int frag_shift; + int pp_offset; + int sdelay; + int edelay; + fplane=_dec->state.fplanes+pli; + /*Compute the first and last fragment row of the current MCU for this + plane.*/ + frag_shift=pli!=0&&!(_dec->state.info.pixel_fmt&2); + _dec->pipe.fragy0[pli]=stripe_fragy>>frag_shift; + _dec->pipe.fragy_end[pli]=OC_MINI(fplane->nvfrags, + _dec->pipe.fragy0[pli]+(_dec->pipe.mcu_nvfrags>>frag_shift)); + oc_dec_dc_unpredict_mcu_plane(_dec,&_dec->pipe,pli); + oc_dec_frags_recon_mcu_plane(_dec,&_dec->pipe,pli); + sdelay=edelay=0; + if(_dec->pipe.loop_filter){ + sdelay+=notstart; + edelay+=notdone; + oc_state_loop_filter_frag_rows(&_dec->state, + _dec->pipe.bounding_values,OC_FRAME_SELF,pli, + _dec->pipe.fragy0[pli]-sdelay,_dec->pipe.fragy_end[pli]-edelay); + } + /*To fill the borders, we have an additional two pixel delay, since a + fragment in the next row could filter its top edge, using two pixels + from a fragment in this row. + But there's no reason to delay a full fragment between the two.*/ + oc_state_borders_fill_rows(&_dec->state,refi,pli, + (_dec->pipe.fragy0[pli]-sdelay<<3)-(sdelay<<1), + (_dec->pipe.fragy_end[pli]-edelay<<3)-(edelay<<1)); + /*Out-of-loop post-processing.*/ + pp_offset=3*(pli!=0); + if(_dec->pipe.pp_level>=OC_PP_LEVEL_DEBLOCKY+pp_offset){ + /*Perform de-blocking in one plane.*/ + sdelay+=notstart; + edelay+=notdone; + oc_dec_deblock_frag_rows(_dec,_dec->pp_frame_buf, + _dec->state.ref_frame_bufs[refi],pli, + _dec->pipe.fragy0[pli]-sdelay,_dec->pipe.fragy_end[pli]-edelay); + if(_dec->pipe.pp_level>=OC_PP_LEVEL_DERINGY+pp_offset){ + /*Perform de-ringing in one plane.*/ + sdelay+=notstart; + edelay+=notdone; + oc_dec_dering_frag_rows(_dec,_dec->pp_frame_buf,pli, + _dec->pipe.fragy0[pli]-sdelay,_dec->pipe.fragy_end[pli]-edelay); + } + } + /*If no post-processing is done, we still need to delay a row for the + loop filter, thanks to the strange filtering order VP3 chose.*/ + else if(_dec->pipe.loop_filter){ + sdelay+=notstart; + edelay+=notdone; + } + /*Compute the intersection of the available rows in all planes. + If chroma is sub-sampled, the effect of each of its delays is + doubled, but luma might have more post-processing filters enabled + than chroma, so we don't know up front which one is the limiting + factor.*/ + avail_fragy0=OC_MINI(avail_fragy0, + _dec->pipe.fragy0[pli]-sdelay<<frag_shift); + avail_fragy_end=OC_MINI(avail_fragy_end, + _dec->pipe.fragy_end[pli]-edelay<<frag_shift); + } +#ifdef HAVE_CAIRO + if(_dec->stripe_cb.stripe_decoded!=NULL&&!telemetry){ +#else + if(_dec->stripe_cb.stripe_decoded!=NULL){ +#endif + /*The callback might want to use the FPU, so let's make sure they can. + We violate all kinds of ABI restrictions by not doing this until + now, but none of them actually matter since we don't use floating + point ourselves.*/ + oc_restore_fpu(&_dec->state); + /*Make the callback, ensuring we flip the sense of the "start" and + "end" of the available region upside down.*/ + (*_dec->stripe_cb.stripe_decoded)(_dec->stripe_cb.ctx,stripe_buf, + _dec->state.fplanes[0].nvfrags-avail_fragy_end, + _dec->state.fplanes[0].nvfrags-avail_fragy0); + } + notstart=1; + } + /*Finish filling in the reference frame borders.*/ + for(pli=0;pli<3;pli++)oc_state_borders_fill_caps(&_dec->state,refi,pli); + /*Update the reference frame indices.*/ + if(_dec->state.frame_type==OC_INTRA_FRAME){ + /*The new frame becomes both the previous and gold reference frames.*/ + _dec->state.ref_frame_idx[OC_FRAME_GOLD]= + _dec->state.ref_frame_idx[OC_FRAME_PREV]= + _dec->state.ref_frame_idx[OC_FRAME_SELF]; + _dec->state.ref_frame_data[OC_FRAME_GOLD]= + _dec->state.ref_frame_data[OC_FRAME_PREV]= + _dec->state.ref_frame_data[OC_FRAME_SELF]; + } + else{ + /*Otherwise, just replace the previous reference frame.*/ + _dec->state.ref_frame_idx[OC_FRAME_PREV]= + _dec->state.ref_frame_idx[OC_FRAME_SELF]; + _dec->state.ref_frame_data[OC_FRAME_PREV]= + _dec->state.ref_frame_data[OC_FRAME_SELF]; + } + /*Restore the FPU before dump_frame, since that _does_ use the FPU (for PNG + gamma values, if nothing else).*/ + oc_restore_fpu(&_dec->state); +#ifdef HAVE_CAIRO + /*If telemetry ioctls are active, we need to draw to the output buffer.*/ + if(telemetry){ + oc_render_telemetry(_dec,stripe_buf,telemetry); + oc_ycbcr_buffer_flip(_dec->pp_frame_buf,stripe_buf); + /*If we had a striped decoding callback, we skipped calling it above + (because the telemetry wasn't rendered yet). + Call it now with the whole frame.*/ + if(_dec->stripe_cb.stripe_decoded!=NULL){ + (*_dec->stripe_cb.stripe_decoded)(_dec->stripe_cb.ctx, + stripe_buf,0,_dec->state.fplanes[0].nvfrags); + } + } +#endif +#if defined(OC_DUMP_IMAGES) + /*We only dump images if there were some coded blocks.*/ + oc_state_dump_frame(&_dec->state,OC_FRAME_SELF,"dec"); +#endif + return 0; + } +} + +int th_decode_ycbcr_out(th_dec_ctx *_dec,th_ycbcr_buffer _ycbcr){ + if(_dec==NULL||_ycbcr==NULL)return TH_EFAULT; + oc_ycbcr_buffer_flip(_ycbcr,_dec->pp_frame_buf); + return 0; +} diff --git a/media/libtheora/lib/dequant.c b/media/libtheora/lib/dequant.c new file mode 100644 index 0000000000..860536f72d --- /dev/null +++ b/media/libtheora/lib/dequant.c @@ -0,0 +1,182 @@ +/******************************************************************** + * * + * THIS FILE IS PART OF THE OggTheora SOFTWARE CODEC SOURCE CODE. * + * USE, DISTRIBUTION AND REPRODUCTION OF THIS LIBRARY SOURCE IS * + * GOVERNED BY A BSD-STYLE SOURCE LICENSE INCLUDED WITH THIS SOURCE * + * IN 'COPYING'. PLEASE READ THESE TERMS BEFORE DISTRIBUTING. * + * * + * THE Theora SOURCE CODE IS COPYRIGHT (C) 2002-2009 * + * by the Xiph.Org Foundation and contributors http://www.xiph.org/ * + * * + ******************************************************************** + + function: + last mod: $Id$ + + ********************************************************************/ + +#include <stdlib.h> +#include <string.h> +#include <ogg/ogg.h> +#include "dequant.h" +#include "decint.h" + +int oc_quant_params_unpack(oc_pack_buf *_opb,th_quant_info *_qinfo){ + th_quant_base *base_mats; + long val; + int nbase_mats; + int sizes[64]; + int indices[64]; + int nbits; + int bmi; + int ci; + int qti; + int pli; + int qri; + int qi; + int i; + val=oc_pack_read(_opb,3); + nbits=(int)val; + for(qi=0;qi<64;qi++){ + val=oc_pack_read(_opb,nbits); + _qinfo->loop_filter_limits[qi]=(unsigned char)val; + } + val=oc_pack_read(_opb,4); + nbits=(int)val+1; + for(qi=0;qi<64;qi++){ + val=oc_pack_read(_opb,nbits); + _qinfo->ac_scale[qi]=(ogg_uint16_t)val; + } + val=oc_pack_read(_opb,4); + nbits=(int)val+1; + for(qi=0;qi<64;qi++){ + val=oc_pack_read(_opb,nbits); + _qinfo->dc_scale[qi]=(ogg_uint16_t)val; + } + val=oc_pack_read(_opb,9); + nbase_mats=(int)val+1; + base_mats=_ogg_malloc(nbase_mats*sizeof(base_mats[0])); + if(base_mats==NULL)return TH_EFAULT; + for(bmi=0;bmi<nbase_mats;bmi++){ + for(ci=0;ci<64;ci++){ + val=oc_pack_read(_opb,8); + base_mats[bmi][ci]=(unsigned char)val; + } + } + nbits=oc_ilog(nbase_mats-1); + for(i=0;i<6;i++){ + th_quant_ranges *qranges; + th_quant_base *qrbms; + int *qrsizes; + qti=i/3; + pli=i%3; + qranges=_qinfo->qi_ranges[qti]+pli; + if(i>0){ + val=oc_pack_read1(_opb); + if(!val){ + int qtj; + int plj; + if(qti>0){ + val=oc_pack_read1(_opb); + if(val){ + qtj=qti-1; + plj=pli; + } + else{ + qtj=(i-1)/3; + plj=(i-1)%3; + } + } + else{ + qtj=(i-1)/3; + plj=(i-1)%3; + } + *qranges=*(_qinfo->qi_ranges[qtj]+plj); + continue; + } + } + val=oc_pack_read(_opb,nbits); + indices[0]=(int)val; + for(qi=qri=0;qi<63;){ + val=oc_pack_read(_opb,oc_ilog(62-qi)); + sizes[qri]=(int)val+1; + qi+=(int)val+1; + val=oc_pack_read(_opb,nbits); + indices[++qri]=(int)val; + } + /*Note: The caller is responsible for cleaning up any partially + constructed qinfo.*/ + if(qi>63){ + _ogg_free(base_mats); + return TH_EBADHEADER; + } + qranges->nranges=qri; + qranges->sizes=qrsizes=(int *)_ogg_malloc(qri*sizeof(qrsizes[0])); + if(qranges->sizes==NULL){ + /*Note: The caller is responsible for cleaning up any partially + constructed qinfo.*/ + _ogg_free(base_mats); + return TH_EFAULT; + } + memcpy(qrsizes,sizes,qri*sizeof(qrsizes[0])); + qrbms=(th_quant_base *)_ogg_malloc((qri+1)*sizeof(qrbms[0])); + if(qrbms==NULL){ + /*Note: The caller is responsible for cleaning up any partially + constructed qinfo.*/ + _ogg_free(base_mats); + return TH_EFAULT; + } + qranges->base_matrices=(const th_quant_base *)qrbms; + do{ + bmi=indices[qri]; + /*Note: The caller is responsible for cleaning up any partially + constructed qinfo.*/ + if(bmi>=nbase_mats){ + _ogg_free(base_mats); + return TH_EBADHEADER; + } + memcpy(qrbms[qri],base_mats[bmi],sizeof(qrbms[qri])); + } + while(qri-->0); + } + _ogg_free(base_mats); + return 0; +} + +void oc_quant_params_clear(th_quant_info *_qinfo){ + int i; + for(i=6;i-->0;){ + int qti; + int pli; + qti=i/3; + pli=i%3; + /*Clear any duplicate pointer references.*/ + if(i>0){ + int qtj; + int plj; + qtj=(i-1)/3; + plj=(i-1)%3; + if(_qinfo->qi_ranges[qti][pli].sizes== + _qinfo->qi_ranges[qtj][plj].sizes){ + _qinfo->qi_ranges[qti][pli].sizes=NULL; + } + if(_qinfo->qi_ranges[qti][pli].base_matrices== + _qinfo->qi_ranges[qtj][plj].base_matrices){ + _qinfo->qi_ranges[qti][pli].base_matrices=NULL; + } + } + if(qti>0){ + if(_qinfo->qi_ranges[1][pli].sizes== + _qinfo->qi_ranges[0][pli].sizes){ + _qinfo->qi_ranges[1][pli].sizes=NULL; + } + if(_qinfo->qi_ranges[1][pli].base_matrices== + _qinfo->qi_ranges[0][pli].base_matrices){ + _qinfo->qi_ranges[1][pli].base_matrices=NULL; + } + } + /*Now free all the non-duplicate storage.*/ + _ogg_free((void *)_qinfo->qi_ranges[qti][pli].sizes); + _ogg_free((void *)_qinfo->qi_ranges[qti][pli].base_matrices); + } +} diff --git a/media/libtheora/lib/dequant.h b/media/libtheora/lib/dequant.h new file mode 100644 index 0000000000..9d6cd6be56 --- /dev/null +++ b/media/libtheora/lib/dequant.h @@ -0,0 +1,27 @@ +/******************************************************************** + * * + * THIS FILE IS PART OF THE OggTheora SOFTWARE CODEC SOURCE CODE. * + * USE, DISTRIBUTION AND REPRODUCTION OF THIS LIBRARY SOURCE IS * + * GOVERNED BY A BSD-STYLE SOURCE LICENSE INCLUDED WITH THIS SOURCE * + * IN 'COPYING'. PLEASE READ THESE TERMS BEFORE DISTRIBUTING. * + * * + * THE Theora SOURCE CODE IS COPYRIGHT (C) 2002-2009 * + * by the Xiph.Org Foundation and contributors http://www.xiph.org/ * + * * + ******************************************************************** + + function: + last mod: $Id$ + + ********************************************************************/ + +#if !defined(_dequant_H) +# define _dequant_H (1) +# include "quant.h" +# include "bitpack.h" + +int oc_quant_params_unpack(oc_pack_buf *_opb, + th_quant_info *_qinfo); +void oc_quant_params_clear(th_quant_info *_qinfo); + +#endif diff --git a/media/libtheora/lib/fragment.c b/media/libtheora/lib/fragment.c new file mode 100644 index 0000000000..14c38be507 --- /dev/null +++ b/media/libtheora/lib/fragment.c @@ -0,0 +1,82 @@ +/******************************************************************** + * * + * THIS FILE IS PART OF THE OggTheora SOFTWARE CODEC SOURCE CODE. * + * USE, DISTRIBUTION AND REPRODUCTION OF THIS LIBRARY SOURCE IS * + * GOVERNED BY A BSD-STYLE SOURCE LICENSE INCLUDED WITH THIS SOURCE * + * IN 'COPYING'. PLEASE READ THESE TERMS BEFORE DISTRIBUTING. * + * * + * THE Theora SOURCE CODE IS COPYRIGHT (C) 2002-2009 * + * by the Xiph.Org Foundation and contributors http://www.xiph.org/ * + * * + ******************************************************************** + + function: + last mod: $Id$ + + ********************************************************************/ +#include <string.h> +#include "internal.h" + +void oc_frag_copy_c(unsigned char *_dst,const unsigned char *_src,int _ystride){ + int i; + for(i=8;i-->0;){ + memcpy(_dst,_src,8*sizeof(*_dst)); + _dst+=_ystride; + _src+=_ystride; + } +} + +/*Copies the fragments specified by the lists of fragment indices from one + frame to another. + _dst_frame: The reference frame to copy to. + _src_frame: The reference frame to copy from. + _ystride: The row stride of the reference frames. + _fragis: A pointer to a list of fragment indices. + _nfragis: The number of fragment indices to copy. + _frag_buf_offs: The offsets of fragments in the reference frames.*/ +void oc_frag_copy_list_c(unsigned char *_dst_frame, + const unsigned char *_src_frame,int _ystride, + const ptrdiff_t *_fragis,ptrdiff_t _nfragis,const ptrdiff_t *_frag_buf_offs){ + ptrdiff_t fragii; + for(fragii=0;fragii<_nfragis;fragii++){ + ptrdiff_t frag_buf_off; + frag_buf_off=_frag_buf_offs[_fragis[fragii]]; + oc_frag_copy_c(_dst_frame+frag_buf_off, + _src_frame+frag_buf_off,_ystride); + } +} + +void oc_frag_recon_intra_c(unsigned char *_dst,int _ystride, + const ogg_int16_t _residue[64]){ + int i; + for(i=0;i<8;i++){ + int j; + for(j=0;j<8;j++)_dst[j]=OC_CLAMP255(_residue[i*8+j]+128); + _dst+=_ystride; + } +} + +void oc_frag_recon_inter_c(unsigned char *_dst, + const unsigned char *_src,int _ystride,const ogg_int16_t _residue[64]){ + int i; + for(i=0;i<8;i++){ + int j; + for(j=0;j<8;j++)_dst[j]=OC_CLAMP255(_residue[i*8+j]+_src[j]); + _dst+=_ystride; + _src+=_ystride; + } +} + +void oc_frag_recon_inter2_c(unsigned char *_dst,const unsigned char *_src1, + const unsigned char *_src2,int _ystride,const ogg_int16_t _residue[64]){ + int i; + for(i=0;i<8;i++){ + int j; + for(j=0;j<8;j++)_dst[j]=OC_CLAMP255(_residue[i*8+j]+(_src1[j]+_src2[j]>>1)); + _dst+=_ystride; + _src1+=_ystride; + _src2+=_ystride; + } +} + +void oc_restore_fpu_c(void){} diff --git a/media/libtheora/lib/huffdec.c b/media/libtheora/lib/huffdec.c new file mode 100644 index 0000000000..5a83c5f150 --- /dev/null +++ b/media/libtheora/lib/huffdec.c @@ -0,0 +1,515 @@ +/******************************************************************** + * * + * THIS FILE IS PART OF THE OggTheora SOFTWARE CODEC SOURCE CODE. * + * USE, DISTRIBUTION AND REPRODUCTION OF THIS LIBRARY SOURCE IS * + * GOVERNED BY A BSD-STYLE SOURCE LICENSE INCLUDED WITH THIS SOURCE * + * IN 'COPYING'. PLEASE READ THESE TERMS BEFORE DISTRIBUTING. * + * * + * THE Theora SOURCE CODE IS COPYRIGHT (C) 2002-2009 * + * by the Xiph.Org Foundation and contributors http://www.xiph.org/ * + * * + ******************************************************************** + + function: + last mod: $Id$ + + ********************************************************************/ + +#include <stdlib.h> +#include <string.h> +#include <ogg/ogg.h> +#include "huffdec.h" +#include "decint.h" + + + +/*Instead of storing every branching in the tree, subtrees can be collapsed + into one node, with a table of size 1<<nbits pointing directly to its + descedents nbits levels down. + This allows more than one bit to be read at a time, and avoids following all + the intermediate branches with next to no increased code complexity once + the collapsed tree has been built. + We do _not_ require that a subtree be complete to be collapsed, but instead + store duplicate pointers in the table, and record the actual depth of the + node below its parent. + This tells us the number of bits to advance the stream after reaching it. + + This turns out to be equivalent to the method described in \cite{Hash95}, + without the requirement that codewords be sorted by length. + If the codewords were sorted by length (so-called ``canonical-codes''), they + could be decoded much faster via either Lindell and Moffat's approach or + Hashemian's Condensed Huffman Code approach, the latter of which has an + extremely small memory footprint. + We can't use Choueka et al.'s finite state machine approach, which is + extremely fast, because we can't allow multiple symbols to be output at a + time; the codebook can and does change between symbols. + It also has very large memory requirements, which impairs cache coherency. + + We store the tree packed in an array of 16-bit integers (words). + Each node consists of a single word, followed consecutively by two or more + indices of its children. + Let n be the value of this first word. + This is the number of bits that need to be read to traverse the node, and + must be positive. + 1<<n entries follow in the array, each an index to a child node. + If the child is positive, then it is the index of another internal node in + the table. + If the child is negative or zero, then it is a leaf node. + These are stored directly in the child pointer to save space, since they only + require a single word. + If a leaf node would have been encountered before reading n bits, then it is + duplicated the necessary number of times in this table. + Leaf nodes pack both a token value and their actual depth in the tree. + The token in the leaf node is (-leaf&255). + The number of bits that need to be consumed to reach the leaf, starting from + the current node, is (-leaf>>8). + + @ARTICLE{Hash95, + author="Reza Hashemian", + title="Memory Efficient and High-Speed Search {Huffman} Coding", + journal="{IEEE} Transactions on Communications", + volume=43, + number=10, + pages="2576--2581", + month=Oct, + year=1995 + }*/ + + + +/*The map from external spec-defined tokens to internal tokens. + This is constructed so that any extra bits read with the original token value + can be masked off the least significant bits of its internal token index. + In addition, all of the tokens which require additional extra bits are placed + at the start of the list, and grouped by type. + OC_DCT_REPEAT_RUN3_TOKEN is placed first, as it is an extra-special case, so + giving it index 0 may simplify comparisons on some architectures. + These requirements require some substantial reordering.*/ +static const unsigned char OC_DCT_TOKEN_MAP[TH_NDCT_TOKENS]={ + /*OC_DCT_EOB1_TOKEN (0 extra bits)*/ + 15, + /*OC_DCT_EOB2_TOKEN (0 extra bits)*/ + 16, + /*OC_DCT_EOB3_TOKEN (0 extra bits)*/ + 17, + /*OC_DCT_REPEAT_RUN0_TOKEN (2 extra bits)*/ + 88, + /*OC_DCT_REPEAT_RUN1_TOKEN (3 extra bits)*/ + 80, + /*OC_DCT_REPEAT_RUN2_TOKEN (4 extra bits)*/ + 1, + /*OC_DCT_REPEAT_RUN3_TOKEN (12 extra bits)*/ + 0, + /*OC_DCT_SHORT_ZRL_TOKEN (3 extra bits)*/ + 48, + /*OC_DCT_ZRL_TOKEN (6 extra bits)*/ + 14, + /*OC_ONE_TOKEN (0 extra bits)*/ + 56, + /*OC_MINUS_ONE_TOKEN (0 extra bits)*/ + 57, + /*OC_TWO_TOKEN (0 extra bits)*/ + 58, + /*OC_MINUS_TWO_TOKEN (0 extra bits)*/ + 59, + /*OC_DCT_VAL_CAT2 (1 extra bit)*/ + 60, + 62, + 64, + 66, + /*OC_DCT_VAL_CAT3 (2 extra bits)*/ + 68, + /*OC_DCT_VAL_CAT4 (3 extra bits)*/ + 72, + /*OC_DCT_VAL_CAT5 (4 extra bits)*/ + 2, + /*OC_DCT_VAL_CAT6 (5 extra bits)*/ + 4, + /*OC_DCT_VAL_CAT7 (6 extra bits)*/ + 6, + /*OC_DCT_VAL_CAT8 (10 extra bits)*/ + 8, + /*OC_DCT_RUN_CAT1A (1 extra bit)*/ + 18, + 20, + 22, + 24, + 26, + /*OC_DCT_RUN_CAT1B (3 extra bits)*/ + 32, + /*OC_DCT_RUN_CAT1C (4 extra bits)*/ + 12, + /*OC_DCT_RUN_CAT2A (2 extra bits)*/ + 28, + /*OC_DCT_RUN_CAT2B (3 extra bits)*/ + 40 +}; + +/*The log base 2 of number of internal tokens associated with each of the spec + tokens (i.e., how many of the extra bits are folded into the token value). + Increasing the maximum value beyond 3 will enlarge the amount of stack + required for tree construction.*/ +static const unsigned char OC_DCT_TOKEN_MAP_LOG_NENTRIES[TH_NDCT_TOKENS]={ + 0,0,0,2,3,0,0,3,0,0,0,0,0,1,1,1,1,2,3,1,1,1,2,1,1,1,1,1,3,1,2,3 +}; + + +/*The size a lookup table is allowed to grow to relative to the number of + unique nodes it contains. + E.g., if OC_HUFF_SLUSH is 4, then at most 75% of the space in the tree is + wasted (1/4 of the space must be used). + Larger numbers can decode tokens with fewer read operations, while smaller + numbers may save more space. + With a sample file: + 32233473 read calls are required when no tree collapsing is done (100.0%). + 19269269 read calls are required when OC_HUFF_SLUSH is 1 (59.8%). + 11144969 read calls are required when OC_HUFF_SLUSH is 2 (34.6%). + 10538563 read calls are required when OC_HUFF_SLUSH is 4 (32.7%). + 10192578 read calls are required when OC_HUFF_SLUSH is 8 (31.6%). + Since a value of 2 gets us the vast majority of the speed-up with only a + small amount of wasted memory, this is what we use. + This value must be less than 128, or you could create a tree with more than + 32767 entries, which would overflow the 16-bit words used to index it.*/ +#define OC_HUFF_SLUSH (2) +/*The root of the tree is on the fast path, and a larger value here is more + beneficial than elsewhere in the tree. + 7 appears to give the best performance, trading off between increased use of + the single-read fast path and cache footprint for the tables, though + obviously this will depend on your cache size. + Using 7 here, the VP3 tables are about twice as large compared to using 2.*/ +#define OC_ROOT_HUFF_SLUSH (7) + + + +/*Unpacks a Huffman codebook. + _opb: The buffer to unpack from. + _tokens: Stores a list of internal tokens, in the order they were found in + the codebook, and the lengths of their corresponding codewords. + This is enough to completely define the codebook, while minimizing + stack usage and avoiding temporary allocations (for platforms + where free() is a no-op). + Return: The number of internal tokens in the codebook, or a negative value + on error.*/ +int oc_huff_tree_unpack(oc_pack_buf *_opb,unsigned char _tokens[256][2]){ + ogg_uint32_t code; + int len; + int ntokens; + int nleaves; + code=0; + len=ntokens=nleaves=0; + for(;;){ + long bits; + bits=oc_pack_read1(_opb); + /*Only process nodes so long as there's more bits in the buffer.*/ + if(oc_pack_bytes_left(_opb)<0)return TH_EBADHEADER; + /*Read an internal node:*/ + if(!bits){ + len++; + /*Don't allow codewords longer than 32 bits.*/ + if(len>32)return TH_EBADHEADER; + } + /*Read a leaf node:*/ + else{ + ogg_uint32_t code_bit; + int neb; + int nentries; + int token; + /*Don't allow more than 32 spec-tokens per codebook.*/ + if(++nleaves>32)return TH_EBADHEADER; + bits=oc_pack_read(_opb,OC_NDCT_TOKEN_BITS); + neb=OC_DCT_TOKEN_MAP_LOG_NENTRIES[bits]; + token=OC_DCT_TOKEN_MAP[bits]; + nentries=1<<neb; + while(nentries-->0){ + _tokens[ntokens][0]=(unsigned char)token++; + _tokens[ntokens][1]=(unsigned char)(len+neb); + ntokens++; + } + code_bit=0x80000000U>>len-1; + while(len>0&&(code&code_bit)){ + code^=code_bit; + code_bit<<=1; + len--; + } + if(len<=0)break; + code|=code_bit; + } + } + return ntokens; +} + +/*Count how many tokens would be required to fill a subtree at depth _depth. + _tokens: A list of internal tokens, in the order they are found in the + codebook, and the lengths of their corresponding codewords. + _depth: The depth of the desired node in the corresponding tree structure. + Return: The number of tokens that belong to that subtree.*/ +static int oc_huff_subtree_tokens(unsigned char _tokens[][2],int _depth){ + ogg_uint32_t code; + int ti; + code=0; + ti=0; + do{ + if(_tokens[ti][1]-_depth<32)code+=0x80000000U>>_tokens[ti++][1]-_depth; + else{ + /*Because of the expanded internal tokens, we can have codewords as long + as 35 bits. + A single recursion here is enough to advance past them.*/ + code++; + ti+=oc_huff_subtree_tokens(_tokens+ti,_depth+31); + } + } + while(code<0x80000000U); + return ti; +} + +/*Compute the number of bits to use for a collapsed tree node at the given + depth. + _tokens: A list of internal tokens, in the order they are found in the + codebook, and the lengths of their corresponding codewords. + _ntokens: The number of tokens corresponding to this tree node. + _depth: The depth of this tree node. + Return: The number of bits to use for a collapsed tree node rooted here. + This is always at least one, even if this was a leaf node.*/ +static int oc_huff_tree_collapse_depth(unsigned char _tokens[][2], + int _ntokens,int _depth){ + int got_leaves; + int loccupancy; + int occupancy; + int slush; + int nbits; + int best_nbits; + slush=_depth>0?OC_HUFF_SLUSH:OC_ROOT_HUFF_SLUSH; + /*It's legal to have a tree with just a single node, which requires no bits + to decode and always returns the same token. + However, no encoder actually does this (yet). + To avoid a special case in oc_huff_token_decode(), we force the number of + lookahead bits to be at least one. + This will produce a tree that looks ahead one bit and then advances the + stream zero bits.*/ + nbits=1; + occupancy=2; + got_leaves=1; + do{ + int ti; + if(got_leaves)best_nbits=nbits; + nbits++; + got_leaves=0; + loccupancy=occupancy; + for(occupancy=ti=0;ti<_ntokens;occupancy++){ + if(_tokens[ti][1]<_depth+nbits)ti++; + else if(_tokens[ti][1]==_depth+nbits){ + got_leaves=1; + ti++; + } + else ti+=oc_huff_subtree_tokens(_tokens+ti,_depth+nbits); + } + } + while(occupancy>loccupancy&&occupancy*slush>=1<<nbits); + return best_nbits; +} + +/*Determines the size in words of a Huffman tree node that represents a + subtree of depth _nbits. + _nbits: The depth of the subtree. + This must be greater than zero. + Return: The number of words required to store the node.*/ +static size_t oc_huff_node_size(int _nbits){ + return 1+(1<<_nbits); +} + +/*Produces a collapsed-tree representation of the given token list. + _tree: The storage for the collapsed Huffman tree. + This may be NULL to compute the required storage size instead of + constructing the tree. + _tokens: A list of internal tokens, in the order they are found in the + codebook, and the lengths of their corresponding codewords. + _ntokens: The number of tokens corresponding to this tree node. + Return: The number of words required to store the tree.*/ +static size_t oc_huff_tree_collapse(ogg_int16_t *_tree, + unsigned char _tokens[][2],int _ntokens){ + ogg_int16_t node[34]; + unsigned char depth[34]; + unsigned char last[34]; + size_t ntree; + int ti; + int l; + depth[0]=0; + last[0]=(unsigned char)(_ntokens-1); + ntree=0; + ti=0; + l=0; + do{ + int nbits; + nbits=oc_huff_tree_collapse_depth(_tokens+ti,last[l]+1-ti,depth[l]); + node[l]=(ogg_int16_t)ntree; + ntree+=oc_huff_node_size(nbits); + if(_tree!=NULL)_tree[node[l]++]=(ogg_int16_t)nbits; + do{ + while(ti<=last[l]&&_tokens[ti][1]<=depth[l]+nbits){ + if(_tree!=NULL){ + ogg_int16_t leaf; + int nentries; + nentries=1<<depth[l]+nbits-_tokens[ti][1]; + leaf=(ogg_int16_t)-(_tokens[ti][1]-depth[l]<<8|_tokens[ti][0]); + while(nentries-->0)_tree[node[l]++]=leaf; + } + ti++; + } + if(ti<=last[l]){ + /*We need to recurse*/ + depth[l+1]=(unsigned char)(depth[l]+nbits); + if(_tree!=NULL)_tree[node[l]++]=(ogg_int16_t)ntree; + l++; + last[l]= + (unsigned char)(ti+oc_huff_subtree_tokens(_tokens+ti,depth[l])-1); + break; + } + /*Pop back up a level of recursion.*/ + else if(l-->0)nbits=depth[l+1]-depth[l]; + } + while(l>=0); + } + while(l>=0); + return ntree; +} + +/*Unpacks a set of Huffman trees, and reduces them to a collapsed + representation. + _opb: The buffer to unpack the trees from. + _nodes: The table to fill with the Huffman trees. + Return: 0 on success, or a negative value on error. + The caller is responsible for cleaning up any partially initialized + _nodes on failure.*/ +int oc_huff_trees_unpack(oc_pack_buf *_opb, + ogg_int16_t *_nodes[TH_NHUFFMAN_TABLES]){ + int i; + for(i=0;i<TH_NHUFFMAN_TABLES;i++){ + unsigned char tokens[256][2]; + int ntokens; + ogg_int16_t *tree; + size_t size; + /*Unpack the full tree into a temporary buffer.*/ + ntokens=oc_huff_tree_unpack(_opb,tokens); + if(ntokens<0)return ntokens; + /*Figure out how big the collapsed tree will be and allocate space for it.*/ + size=oc_huff_tree_collapse(NULL,tokens,ntokens); + /*This should never happen; if it does it means you set OC_HUFF_SLUSH or + OC_ROOT_HUFF_SLUSH too large.*/ + if(size>32767)return TH_EIMPL; + tree=(ogg_int16_t *)_ogg_malloc(size*sizeof(*tree)); + if(tree==NULL)return TH_EFAULT; + /*Construct the collapsed the tree.*/ + oc_huff_tree_collapse(tree,tokens,ntokens); + _nodes[i]=tree; + } + return 0; +} + +/*Determines the size in words of a Huffman subtree. + _tree: The complete Huffman tree. + _node: The index of the root of the desired subtree. + Return: The number of words required to store the tree.*/ +static size_t oc_huff_tree_size(const ogg_int16_t *_tree,int _node){ + size_t size; + int nchildren; + int n; + int i; + n=_tree[_node]; + size=oc_huff_node_size(n); + nchildren=1<<n; + i=0; + do{ + int child; + child=_tree[_node+i+1]; + if(child<=0)i+=1<<n-(-child>>8); + else{ + size+=oc_huff_tree_size(_tree,child); + i++; + } + } + while(i<nchildren); + return size; +} + +/*Makes a copy of the given set of Huffman trees. + _dst: The array to store the copy in. + _src: The array of trees to copy.*/ +int oc_huff_trees_copy(ogg_int16_t *_dst[TH_NHUFFMAN_TABLES], + const ogg_int16_t *const _src[TH_NHUFFMAN_TABLES]){ + int total; + int i; + total=0; + for(i=0;i<TH_NHUFFMAN_TABLES;i++){ + size_t size; + size=oc_huff_tree_size(_src[i],0); + total+=size; + _dst[i]=(ogg_int16_t *)_ogg_malloc(size*sizeof(*_dst[i])); + if(_dst[i]==NULL){ + while(i-->0)_ogg_free(_dst[i]); + return TH_EFAULT; + } + memcpy(_dst[i],_src[i],size*sizeof(*_dst[i])); + } + return 0; +} + +/*Frees the memory used by a set of Huffman trees. + _nodes: The array of trees to free.*/ +void oc_huff_trees_clear(ogg_int16_t *_nodes[TH_NHUFFMAN_TABLES]){ + int i; + for(i=0;i<TH_NHUFFMAN_TABLES;i++)_ogg_free(_nodes[i]); +} + + +/*Unpacks a single token using the given Huffman tree. + _opb: The buffer to unpack the token from. + _node: The tree to unpack the token with. + Return: The token value.*/ +int oc_huff_token_decode_c(oc_pack_buf *_opb,const ogg_int16_t *_tree){ + const unsigned char *ptr; + const unsigned char *stop; + oc_pb_window window; + int available; + long bits; + int node; + int n; + ptr=_opb->ptr; + window=_opb->window; + stop=_opb->stop; + available=_opb->bits; + node=0; + for(;;){ + n=_tree[node]; + if(n>available){ + unsigned shift; + shift=OC_PB_WINDOW_SIZE-available; + do{ + /*We don't bother setting eof because we won't check for it after we've + started decoding DCT tokens.*/ + if(ptr>=stop){ + shift=(unsigned)-OC_LOTS_OF_BITS; + break; + } + shift-=8; + window|=(oc_pb_window)*ptr++<<shift; + } + while(shift>=8); + /*Note: We never request more than 24 bits, so there's no need to fill in + the last partial byte here.*/ + available=OC_PB_WINDOW_SIZE-shift; + } + bits=window>>OC_PB_WINDOW_SIZE-n; + node=_tree[node+1+bits]; + if(node<=0)break; + window<<=n; + available-=n; + } + node=-node; + n=node>>8; + window<<=n; + available-=n; + _opb->ptr=ptr; + _opb->window=window; + _opb->bits=available; + return node&255; +} diff --git a/media/libtheora/lib/huffdec.h b/media/libtheora/lib/huffdec.h new file mode 100644 index 0000000000..03d25dcd1e --- /dev/null +++ b/media/libtheora/lib/huffdec.h @@ -0,0 +1,32 @@ +/******************************************************************** + * * + * THIS FILE IS PART OF THE OggTheora SOFTWARE CODEC SOURCE CODE. * + * USE, DISTRIBUTION AND REPRODUCTION OF THIS LIBRARY SOURCE IS * + * GOVERNED BY A BSD-STYLE SOURCE LICENSE INCLUDED WITH THIS SOURCE * + * IN 'COPYING'. PLEASE READ THESE TERMS BEFORE DISTRIBUTING. * + * * + * THE Theora SOURCE CODE IS COPYRIGHT (C) 2002-2009 * + * by the Xiph.Org Foundation and contributors http://www.xiph.org/ * + * * + ******************************************************************** + + function: + last mod: $Id$ + + ********************************************************************/ + +#if !defined(_huffdec_H) +# define _huffdec_H (1) +# include "huffman.h" +# include "bitpack.h" + + + +int oc_huff_trees_unpack(oc_pack_buf *_opb, + ogg_int16_t *_nodes[TH_NHUFFMAN_TABLES]); +int oc_huff_trees_copy(ogg_int16_t *_dst[TH_NHUFFMAN_TABLES], + const ogg_int16_t *const _src[TH_NHUFFMAN_TABLES]); +void oc_huff_trees_clear(ogg_int16_t *_nodes[TH_NHUFFMAN_TABLES]); +int oc_huff_token_decode_c(oc_pack_buf *_opb,const ogg_int16_t *_node); + +#endif diff --git a/media/libtheora/lib/huffman.h b/media/libtheora/lib/huffman.h new file mode 100644 index 0000000000..eb805866b9 --- /dev/null +++ b/media/libtheora/lib/huffman.h @@ -0,0 +1,70 @@ +/******************************************************************** + * * + * THIS FILE IS PART OF THE OggTheora SOFTWARE CODEC SOURCE CODE. * + * USE, DISTRIBUTION AND REPRODUCTION OF THIS LIBRARY SOURCE IS * + * GOVERNED BY A BSD-STYLE SOURCE LICENSE INCLUDED WITH THIS SOURCE * + * IN 'COPYING'. PLEASE READ THESE TERMS BEFORE DISTRIBUTING. * + * * + * THE Theora SOURCE CODE IS COPYRIGHT (C) 2002-2009 * + * by the Xiph.Org Foundation and contributors http://www.xiph.org/ * + * * + ******************************************************************** + + function: + last mod: $Id$ + + ********************************************************************/ + +#if !defined(_huffman_H) +# define _huffman_H (1) +# include "theora/codec.h" +# include "ocintrin.h" + +/*The range of valid quantized DCT coefficient values. + VP3 used 511 in the encoder, but the bitstream is capable of 580.*/ +#define OC_DCT_VAL_RANGE (580) + +#define OC_NDCT_TOKEN_BITS (5) + +#define OC_DCT_EOB1_TOKEN (0) +#define OC_DCT_EOB2_TOKEN (1) +#define OC_DCT_EOB3_TOKEN (2) +#define OC_DCT_REPEAT_RUN0_TOKEN (3) +#define OC_DCT_REPEAT_RUN1_TOKEN (4) +#define OC_DCT_REPEAT_RUN2_TOKEN (5) +#define OC_DCT_REPEAT_RUN3_TOKEN (6) + +#define OC_DCT_SHORT_ZRL_TOKEN (7) +#define OC_DCT_ZRL_TOKEN (8) + +#define OC_ONE_TOKEN (9) +#define OC_MINUS_ONE_TOKEN (10) +#define OC_TWO_TOKEN (11) +#define OC_MINUS_TWO_TOKEN (12) + +#define OC_DCT_VAL_CAT2 (13) +#define OC_DCT_VAL_CAT3 (17) +#define OC_DCT_VAL_CAT4 (18) +#define OC_DCT_VAL_CAT5 (19) +#define OC_DCT_VAL_CAT6 (20) +#define OC_DCT_VAL_CAT7 (21) +#define OC_DCT_VAL_CAT8 (22) + +#define OC_DCT_RUN_CAT1A (23) +#define OC_DCT_RUN_CAT1B (28) +#define OC_DCT_RUN_CAT1C (29) +#define OC_DCT_RUN_CAT2A (30) +#define OC_DCT_RUN_CAT2B (31) + +#define OC_NDCT_EOB_TOKEN_MAX (7) +#define OC_NDCT_ZRL_TOKEN_MAX (9) +#define OC_NDCT_VAL_MAX (23) +#define OC_NDCT_VAL_CAT1_MAX (13) +#define OC_NDCT_VAL_CAT2_MAX (17) +#define OC_NDCT_VAL_CAT2_SIZE (OC_NDCT_VAL_CAT2_MAX-OC_DCT_VAL_CAT2) +#define OC_NDCT_RUN_MAX (32) +#define OC_NDCT_RUN_CAT1A_MAX (28) + +extern const unsigned char OC_DCT_TOKEN_EXTRA_BITS[TH_NDCT_TOKENS]; + +#endif diff --git a/media/libtheora/lib/idct.c b/media/libtheora/lib/idct.c new file mode 100644 index 0000000000..838e3ad8ca --- /dev/null +++ b/media/libtheora/lib/idct.c @@ -0,0 +1,330 @@ +/******************************************************************** + * * + * THIS FILE IS PART OF THE OggTheora SOFTWARE CODEC SOURCE CODE. * + * USE, DISTRIBUTION AND REPRODUCTION OF THIS LIBRARY SOURCE IS * + * GOVERNED BY A BSD-STYLE SOURCE LICENSE INCLUDED WITH THIS SOURCE * + * IN 'COPYING'. PLEASE READ THESE TERMS BEFORE DISTRIBUTING. * + * * + * THE Theora SOURCE CODE IS COPYRIGHT (C) 2002-2009 * + * by the Xiph.Org Foundation and contributors http://www.xiph.org/ * + * * + ******************************************************************** + + function: + last mod: $Id$ + + ********************************************************************/ + +#include <string.h> +#include "internal.h" +#include "dct.h" + +/*Performs an inverse 8 point Type-II DCT transform. + The output is scaled by a factor of 2 relative to the orthonormal version of + the transform. + _y: The buffer to store the result in. + Data will be placed in every 8th entry (e.g., in a column of an 8x8 + block). + _x: The input coefficients. + The first 8 entries are used (e.g., from a row of an 8x8 block).*/ +static void idct8(ogg_int16_t *_y,const ogg_int16_t _x[8]){ + ogg_int32_t t[8]; + ogg_int32_t r; + /*Stage 1:*/ + /*0-1 butterfly.*/ + t[0]=OC_C4S4*(ogg_int16_t)(_x[0]+_x[4])>>16; + t[1]=OC_C4S4*(ogg_int16_t)(_x[0]-_x[4])>>16; + /*2-3 rotation by 6pi/16.*/ + t[2]=(OC_C6S2*_x[2]>>16)-(OC_C2S6*_x[6]>>16); + t[3]=(OC_C2S6*_x[2]>>16)+(OC_C6S2*_x[6]>>16); + /*4-7 rotation by 7pi/16.*/ + t[4]=(OC_C7S1*_x[1]>>16)-(OC_C1S7*_x[7]>>16); + /*5-6 rotation by 3pi/16.*/ + t[5]=(OC_C3S5*_x[5]>>16)-(OC_C5S3*_x[3]>>16); + t[6]=(OC_C5S3*_x[5]>>16)+(OC_C3S5*_x[3]>>16); + t[7]=(OC_C1S7*_x[1]>>16)+(OC_C7S1*_x[7]>>16); + /*Stage 2:*/ + /*4-5 butterfly.*/ + r=t[4]+t[5]; + t[5]=OC_C4S4*(ogg_int16_t)(t[4]-t[5])>>16; + t[4]=r; + /*7-6 butterfly.*/ + r=t[7]+t[6]; + t[6]=OC_C4S4*(ogg_int16_t)(t[7]-t[6])>>16; + t[7]=r; + /*Stage 3:*/ + /*0-3 butterfly.*/ + r=t[0]+t[3]; + t[3]=t[0]-t[3]; + t[0]=r; + /*1-2 butterfly.*/ + r=t[1]+t[2]; + t[2]=t[1]-t[2]; + t[1]=r; + /*6-5 butterfly.*/ + r=t[6]+t[5]; + t[5]=t[6]-t[5]; + t[6]=r; + /*Stage 4:*/ + /*0-7 butterfly.*/ + _y[0<<3]=(ogg_int16_t)(t[0]+t[7]); + /*1-6 butterfly.*/ + _y[1<<3]=(ogg_int16_t)(t[1]+t[6]); + /*2-5 butterfly.*/ + _y[2<<3]=(ogg_int16_t)(t[2]+t[5]); + /*3-4 butterfly.*/ + _y[3<<3]=(ogg_int16_t)(t[3]+t[4]); + _y[4<<3]=(ogg_int16_t)(t[3]-t[4]); + _y[5<<3]=(ogg_int16_t)(t[2]-t[5]); + _y[6<<3]=(ogg_int16_t)(t[1]-t[6]); + _y[7<<3]=(ogg_int16_t)(t[0]-t[7]); +} + +/*Performs an inverse 8 point Type-II DCT transform. + The output is scaled by a factor of 2 relative to the orthonormal version of + the transform. + _y: The buffer to store the result in. + Data will be placed in every 8th entry (e.g., in a column of an 8x8 + block). + _x: The input coefficients. + Only the first 4 entries are used. + The other 4 are assumed to be 0.*/ +static void idct8_4(ogg_int16_t *_y,const ogg_int16_t _x[8]){ + ogg_int32_t t[8]; + ogg_int32_t r; + /*Stage 1:*/ + t[0]=OC_C4S4*_x[0]>>16; + t[2]=OC_C6S2*_x[2]>>16; + t[3]=OC_C2S6*_x[2]>>16; + t[4]=OC_C7S1*_x[1]>>16; + t[5]=-(OC_C5S3*_x[3]>>16); + t[6]=OC_C3S5*_x[3]>>16; + t[7]=OC_C1S7*_x[1]>>16; + /*Stage 2:*/ + r=t[4]+t[5]; + t[5]=OC_C4S4*(ogg_int16_t)(t[4]-t[5])>>16; + t[4]=r; + r=t[7]+t[6]; + t[6]=OC_C4S4*(ogg_int16_t)(t[7]-t[6])>>16; + t[7]=r; + /*Stage 3:*/ + t[1]=t[0]+t[2]; + t[2]=t[0]-t[2]; + r=t[0]+t[3]; + t[3]=t[0]-t[3]; + t[0]=r; + r=t[6]+t[5]; + t[5]=t[6]-t[5]; + t[6]=r; + /*Stage 4:*/ + _y[0<<3]=(ogg_int16_t)(t[0]+t[7]); + _y[1<<3]=(ogg_int16_t)(t[1]+t[6]); + _y[2<<3]=(ogg_int16_t)(t[2]+t[5]); + _y[3<<3]=(ogg_int16_t)(t[3]+t[4]); + _y[4<<3]=(ogg_int16_t)(t[3]-t[4]); + _y[5<<3]=(ogg_int16_t)(t[2]-t[5]); + _y[6<<3]=(ogg_int16_t)(t[1]-t[6]); + _y[7<<3]=(ogg_int16_t)(t[0]-t[7]); +} + +/*Performs an inverse 8 point Type-II DCT transform. + The output is scaled by a factor of 2 relative to the orthonormal version of + the transform. + _y: The buffer to store the result in. + Data will be placed in every 8th entry (e.g., in a column of an 8x8 + block). + _x: The input coefficients. + Only the first 3 entries are used. + The other 5 are assumed to be 0.*/ +static void idct8_3(ogg_int16_t *_y,const ogg_int16_t _x[8]){ + ogg_int32_t t[8]; + ogg_int32_t r; + /*Stage 1:*/ + t[0]=OC_C4S4*_x[0]>>16; + t[2]=OC_C6S2*_x[2]>>16; + t[3]=OC_C2S6*_x[2]>>16; + t[4]=OC_C7S1*_x[1]>>16; + t[7]=OC_C1S7*_x[1]>>16; + /*Stage 2:*/ + t[5]=OC_C4S4*t[4]>>16; + t[6]=OC_C4S4*t[7]>>16; + /*Stage 3:*/ + t[1]=t[0]+t[2]; + t[2]=t[0]-t[2]; + r=t[0]+t[3]; + t[3]=t[0]-t[3]; + t[0]=r; + r=t[6]+t[5]; + t[5]=t[6]-t[5]; + t[6]=r; + /*Stage 4:*/ + _y[0<<3]=(ogg_int16_t)(t[0]+t[7]); + _y[1<<3]=(ogg_int16_t)(t[1]+t[6]); + _y[2<<3]=(ogg_int16_t)(t[2]+t[5]); + _y[3<<3]=(ogg_int16_t)(t[3]+t[4]); + _y[4<<3]=(ogg_int16_t)(t[3]-t[4]); + _y[5<<3]=(ogg_int16_t)(t[2]-t[5]); + _y[6<<3]=(ogg_int16_t)(t[1]-t[6]); + _y[7<<3]=(ogg_int16_t)(t[0]-t[7]); +} + +/*Performs an inverse 8 point Type-II DCT transform. + The output is scaled by a factor of 2 relative to the orthonormal version of + the transform. + _y: The buffer to store the result in. + Data will be placed in every 8th entry (e.g., in a column of an 8x8 + block). + _x: The input coefficients. + Only the first 2 entries are used. + The other 6 are assumed to be 0.*/ +static void idct8_2(ogg_int16_t *_y,const ogg_int16_t _x[8]){ + ogg_int32_t t[8]; + ogg_int32_t r; + /*Stage 1:*/ + t[0]=OC_C4S4*_x[0]>>16; + t[4]=OC_C7S1*_x[1]>>16; + t[7]=OC_C1S7*_x[1]>>16; + /*Stage 2:*/ + t[5]=OC_C4S4*t[4]>>16; + t[6]=OC_C4S4*t[7]>>16; + /*Stage 3:*/ + r=t[6]+t[5]; + t[5]=t[6]-t[5]; + t[6]=r; + /*Stage 4:*/ + _y[0<<3]=(ogg_int16_t)(t[0]+t[7]); + _y[1<<3]=(ogg_int16_t)(t[0]+t[6]); + _y[2<<3]=(ogg_int16_t)(t[0]+t[5]); + _y[3<<3]=(ogg_int16_t)(t[0]+t[4]); + _y[4<<3]=(ogg_int16_t)(t[0]-t[4]); + _y[5<<3]=(ogg_int16_t)(t[0]-t[5]); + _y[6<<3]=(ogg_int16_t)(t[0]-t[6]); + _y[7<<3]=(ogg_int16_t)(t[0]-t[7]); +} + +/*Performs an inverse 8 point Type-II DCT transform. + The output is scaled by a factor of 2 relative to the orthonormal version of + the transform. + _y: The buffer to store the result in. + Data will be placed in every 8th entry (e.g., in a column of an 8x8 + block). + _x: The input coefficients. + Only the first entry is used. + The other 7 are assumed to be 0.*/ +static void idct8_1(ogg_int16_t *_y,const ogg_int16_t _x[1]){ + _y[0<<3]=_y[1<<3]=_y[2<<3]=_y[3<<3]= + _y[4<<3]=_y[5<<3]=_y[6<<3]=_y[7<<3]=(ogg_int16_t)(OC_C4S4*_x[0]>>16); +} + +/*Performs an inverse 8x8 Type-II DCT transform. + The input is assumed to be scaled by a factor of 4 relative to orthonormal + version of the transform. + All coefficients but the first 3 in zig-zag scan order are assumed to be 0: + x x 0 0 0 0 0 0 + x 0 0 0 0 0 0 0 + 0 0 0 0 0 0 0 0 + 0 0 0 0 0 0 0 0 + 0 0 0 0 0 0 0 0 + 0 0 0 0 0 0 0 0 + 0 0 0 0 0 0 0 0 + 0 0 0 0 0 0 0 0 + _y: The buffer to store the result in. + This may be the same as _x. + _x: The input coefficients.*/ +static void oc_idct8x8_3(ogg_int16_t _y[64],ogg_int16_t _x[64]){ + ogg_int16_t w[64]; + int i; + /*Transform rows of x into columns of w.*/ + idct8_2(w,_x); + idct8_1(w+1,_x+8); + /*Transform rows of w into columns of y.*/ + for(i=0;i<8;i++)idct8_2(_y+i,w+i*8); + /*Adjust for the scale factor.*/ + for(i=0;i<64;i++)_y[i]=(ogg_int16_t)(_y[i]+8>>4); + /*Clear input data for next block.*/ + _x[0]=_x[1]=_x[8]=0; +} + +/*Performs an inverse 8x8 Type-II DCT transform. + The input is assumed to be scaled by a factor of 4 relative to orthonormal + version of the transform. + All coefficients but the first 10 in zig-zag scan order are assumed to be 0: + x x x x 0 0 0 0 + x x x 0 0 0 0 0 + x x 0 0 0 0 0 0 + x 0 0 0 0 0 0 0 + 0 0 0 0 0 0 0 0 + 0 0 0 0 0 0 0 0 + 0 0 0 0 0 0 0 0 + 0 0 0 0 0 0 0 0 + _y: The buffer to store the result in. + This may be the same as _x. + _x: The input coefficients.*/ +static void oc_idct8x8_10(ogg_int16_t _y[64],ogg_int16_t _x[64]){ + ogg_int16_t w[64]; + int i; + /*Transform rows of x into columns of w.*/ + idct8_4(w,_x); + idct8_3(w+1,_x+8); + idct8_2(w+2,_x+16); + idct8_1(w+3,_x+24); + /*Transform rows of w into columns of y.*/ + for(i=0;i<8;i++)idct8_4(_y+i,w+i*8); + /*Adjust for the scale factor.*/ + for(i=0;i<64;i++)_y[i]=(ogg_int16_t)(_y[i]+8>>4); + /*Clear input data for next block.*/ + _x[0]=_x[1]=_x[2]=_x[3]=_x[8]=_x[9]=_x[10]=_x[16]=_x[17]=_x[24]=0; +} + +/*Performs an inverse 8x8 Type-II DCT transform. + The input is assumed to be scaled by a factor of 4 relative to orthonormal + version of the transform. + _y: The buffer to store the result in. + This may be the same as _x. + _x: The input coefficients.*/ +static void oc_idct8x8_slow(ogg_int16_t _y[64],ogg_int16_t _x[64]){ + ogg_int16_t w[64]; + int i; + /*Transform rows of x into columns of w.*/ + for(i=0;i<8;i++)idct8(w+i,_x+i*8); + /*Transform rows of w into columns of y.*/ + for(i=0;i<8;i++)idct8(_y+i,w+i*8); + /*Adjust for the scale factor.*/ + for(i=0;i<64;i++)_y[i]=(ogg_int16_t)(_y[i]+8>>4); + /*Clear input data for next block.*/ + for(i=0;i<64;i++)_x[i]=0; +} + +/*Performs an inverse 8x8 Type-II DCT transform. + The input is assumed to be scaled by a factor of 4 relative to orthonormal + version of the transform.*/ +void oc_idct8x8_c(ogg_int16_t _y[64],ogg_int16_t _x[64],int _last_zzi){ + /*_last_zzi is subtly different from an actual count of the number of + coefficients we decoded for this block. + It contains the value of zzi BEFORE the final token in the block was + decoded. + In most cases this is an EOB token (the continuation of an EOB run from a + previous block counts), and so this is the same as the coefficient count. + However, in the case that the last token was NOT an EOB token, but filled + the block up with exactly 64 coefficients, _last_zzi will be less than 64. + Provided the last token was not a pure zero run, the minimum value it can + be is 46, and so that doesn't affect any of the cases in this routine. + However, if the last token WAS a pure zero run of length 63, then _last_zzi + will be 1 while the number of coefficients decoded is 64. + Thus, we will trigger the following special case, where the real + coefficient count would not. + Note also that a zero run of length 64 will give _last_zzi a value of 0, + but we still process the DC coefficient, which might have a non-zero value + due to DC prediction. + Although convoluted, this is arguably the correct behavior: it allows us to + use a smaller transform when the block ends with a long zero run instead + of a normal EOB token. + It could be smarter... multiple separate zero runs at the end of a block + will fool it, but an encoder that generates these really deserves what it + gets. + Needless to say we inherited this approach from VP3.*/ + /*Then perform the iDCT.*/ + if(_last_zzi<=3)oc_idct8x8_3(_y,_x); + else if(_last_zzi<=10)oc_idct8x8_10(_y,_x); + else oc_idct8x8_slow(_y,_x); +} diff --git a/media/libtheora/lib/info.c b/media/libtheora/lib/info.c new file mode 100644 index 0000000000..e5cecd2de5 --- /dev/null +++ b/media/libtheora/lib/info.c @@ -0,0 +1,131 @@ +/******************************************************************** + * * + * THIS FILE IS PART OF THE OggTheora SOFTWARE CODEC SOURCE CODE. * + * USE, DISTRIBUTION AND REPRODUCTION OF THIS LIBRARY SOURCE IS * + * GOVERNED BY A BSD-STYLE SOURCE LICENSE INCLUDED WITH THIS SOURCE * + * IN 'COPYING'. PLEASE READ THESE TERMS BEFORE DISTRIBUTING. * + * * + * THE Theora SOURCE CODE IS COPYRIGHT (C) 2002-2009 * + * by the Xiph.Org Foundation and contributors http://www.xiph.org/ * + * * + ******************************************************************** + + function: + last mod: $Id$ + + ********************************************************************/ + +#include <stdlib.h> +#include <ctype.h> +#include <string.h> +#include "internal.h" + + + +/*This is more or less the same as strncasecmp, but that doesn't exist + everywhere, and this is a fairly trivial function, so we include it. + Note: We take advantage of the fact that we know _n is less than or equal to + the length of at least one of the strings.*/ +static int oc_tagcompare(const char *_s1,const char *_s2,int _n){ + int c; + for(c=0;c<_n;c++){ + if(toupper(_s1[c])!=toupper(_s2[c]))return !0; + } + return _s1[c]!='='; +} + + + +void th_info_init(th_info *_info){ + memset(_info,0,sizeof(*_info)); + _info->version_major=TH_VERSION_MAJOR; + _info->version_minor=TH_VERSION_MINOR; + _info->version_subminor=TH_VERSION_SUB; + _info->keyframe_granule_shift=6; +} + +void th_info_clear(th_info *_info){ + memset(_info,0,sizeof(*_info)); +} + + + +void th_comment_init(th_comment *_tc){ + memset(_tc,0,sizeof(*_tc)); +} + +void th_comment_add(th_comment *_tc,const char *_comment){ + char **user_comments; + int *comment_lengths; + int comment_len; + user_comments=_ogg_realloc(_tc->user_comments, + (_tc->comments+2)*sizeof(*_tc->user_comments)); + if(user_comments==NULL)return; + _tc->user_comments=user_comments; + comment_lengths=_ogg_realloc(_tc->comment_lengths, + (_tc->comments+2)*sizeof(*_tc->comment_lengths)); + if(comment_lengths==NULL)return; + _tc->comment_lengths=comment_lengths; + comment_len=strlen(_comment); + comment_lengths[_tc->comments]=comment_len; + user_comments[_tc->comments]=_ogg_malloc(comment_len+1); + if(user_comments[_tc->comments]==NULL)return; + memcpy(_tc->user_comments[_tc->comments],_comment,comment_len+1); + _tc->comments++; + _tc->user_comments[_tc->comments]=NULL; +} + +void th_comment_add_tag(th_comment *_tc,const char *_tag,const char *_val){ + char *comment; + int tag_len; + int val_len; + tag_len=strlen(_tag); + val_len=strlen(_val); + /*+2 for '=' and '\0'.*/ + comment=_ogg_malloc(tag_len+val_len+2); + if(comment==NULL)return; + memcpy(comment,_tag,tag_len); + comment[tag_len]='='; + memcpy(comment+tag_len+1,_val,val_len+1); + th_comment_add(_tc,comment); + _ogg_free(comment); +} + +char *th_comment_query(th_comment *_tc,const char *_tag,int _count){ + long i; + int found; + int tag_len; + tag_len=strlen(_tag); + found=0; + for(i=0;i<_tc->comments;i++){ + if(!oc_tagcompare(_tc->user_comments[i],_tag,tag_len)){ + /*We return a pointer to the data, not a copy.*/ + if(_count==found++)return _tc->user_comments[i]+tag_len+1; + } + } + /*Didn't find anything.*/ + return NULL; +} + +int th_comment_query_count(th_comment *_tc,const char *_tag){ + long i; + int tag_len; + int count; + tag_len=strlen(_tag); + count=0; + for(i=0;i<_tc->comments;i++){ + if(!oc_tagcompare(_tc->user_comments[i],_tag,tag_len))count++; + } + return count; +} + +void th_comment_clear(th_comment *_tc){ + if(_tc!=NULL){ + long i; + for(i=0;i<_tc->comments;i++)_ogg_free(_tc->user_comments[i]); + _ogg_free(_tc->user_comments); + _ogg_free(_tc->comment_lengths); + _ogg_free(_tc->vendor); + memset(_tc,0,sizeof(*_tc)); + } +} diff --git a/media/libtheora/lib/internal.c b/media/libtheora/lib/internal.c new file mode 100644 index 0000000000..afbb6efae7 --- /dev/null +++ b/media/libtheora/lib/internal.c @@ -0,0 +1,210 @@ +/******************************************************************** + * * + * THIS FILE IS PART OF THE OggTheora SOFTWARE CODEC SOURCE CODE. * + * USE, DISTRIBUTION AND REPRODUCTION OF THIS LIBRARY SOURCE IS * + * GOVERNED BY A BSD-STYLE SOURCE LICENSE INCLUDED WITH THIS SOURCE * + * IN 'COPYING'. PLEASE READ THESE TERMS BEFORE DISTRIBUTING. * + * * + * THE Theora SOURCE CODE IS COPYRIGHT (C) 2002-2009 * + * by the Xiph.Org Foundation and contributors http://www.xiph.org/ * + * * + ******************************************************************** + + function: + last mod: $Id$ + + ********************************************************************/ + +#include <stdlib.h> +#include <limits.h> +#include <string.h> +#include "internal.h" + + + +/*A map from the index in the zig zag scan to the coefficient number in a + block. + All zig zag indices beyond 63 are sent to coefficient 64, so that zero runs + past the end of a block in bogus streams get mapped to a known location.*/ +const unsigned char OC_FZIG_ZAG[128]={ + 0, 1, 8,16, 9, 2, 3,10, + 17,24,32,25,18,11, 4, 5, + 12,19,26,33,40,48,41,34, + 27,20,13, 6, 7,14,21,28, + 35,42,49,56,57,50,43,36, + 29,22,15,23,30,37,44,51, + 58,59,52,45,38,31,39,46, + 53,60,61,54,47,55,62,63, + 64,64,64,64,64,64,64,64, + 64,64,64,64,64,64,64,64, + 64,64,64,64,64,64,64,64, + 64,64,64,64,64,64,64,64, + 64,64,64,64,64,64,64,64, + 64,64,64,64,64,64,64,64, + 64,64,64,64,64,64,64,64, + 64,64,64,64,64,64,64,64 +}; + +/*A map from the coefficient number in a block to its index in the zig zag + scan.*/ +const unsigned char OC_IZIG_ZAG[64]={ + 0, 1, 5, 6,14,15,27,28, + 2, 4, 7,13,16,26,29,42, + 3, 8,12,17,25,30,41,43, + 9,11,18,24,31,40,44,53, + 10,19,23,32,39,45,52,54, + 20,22,33,38,46,51,55,60, + 21,34,37,47,50,56,59,61, + 35,36,48,49,57,58,62,63 +}; + +/*A map from physical macro block ordering to bitstream macro block + ordering within a super block.*/ +const unsigned char OC_MB_MAP[2][2]={{0,3},{1,2}}; + +/*A list of the indices in the oc_mb.map array that can be valid for each of + the various chroma decimation types.*/ +const unsigned char OC_MB_MAP_IDXS[TH_PF_NFORMATS][12]={ + {0,1,2,3,4,8}, + {0,1,2,3,4,5,8,9}, + {0,1,2,3,4,6,8,10}, + {0,1,2,3,4,5,6,7,8,9,10,11} +}; + +/*The number of indices in the oc_mb.map array that can be valid for each of + the various chroma decimation types.*/ +const unsigned char OC_MB_MAP_NIDXS[TH_PF_NFORMATS]={6,8,8,12}; + +/*The number of extra bits that are coded with each of the DCT tokens. + Each DCT token has some fixed number of additional bits (possibly 0) stored + after the token itself, containing, for example, coefficient magnitude, + sign bits, etc.*/ +const unsigned char OC_DCT_TOKEN_EXTRA_BITS[TH_NDCT_TOKENS]={ + 0,0,0,2,3,4,12,3,6, + 0,0,0,0, + 1,1,1,1,2,3,4,5,6,10, + 1,1,1,1,1,3,4, + 2,3 +}; + + + +int oc_ilog(unsigned _v){ + int ret; + for(ret=0;_v;ret++)_v>>=1; + return ret; +} + + + +void *oc_aligned_malloc(size_t _sz,size_t _align){ + unsigned char *p; + if(_align-1>UCHAR_MAX||(_align&_align-1)||_sz>~(size_t)0-_align)return NULL; + p=(unsigned char *)_ogg_malloc(_sz+_align); + if(p!=NULL){ + int offs; + offs=((p-(unsigned char *)0)-1&_align-1); + p[offs]=offs; + p+=offs+1; + } + return p; +} + +void oc_aligned_free(void *_ptr){ + unsigned char *p; + p=(unsigned char *)_ptr; + if(p!=NULL){ + int offs; + offs=*--p; + _ogg_free(p-offs); + } +} + + +void **oc_malloc_2d(size_t _height,size_t _width,size_t _sz){ + size_t rowsz; + size_t colsz; + size_t datsz; + char *ret; + colsz=_height*sizeof(void *); + rowsz=_sz*_width; + datsz=rowsz*_height; + /*Alloc array and row pointers.*/ + ret=(char *)_ogg_malloc(datsz+colsz); + /*Initialize the array.*/ + if(ret!=NULL){ + size_t i; + void **p; + char *datptr; + p=(void **)ret; + i=_height; + for(datptr=ret+colsz;i-->0;p++,datptr+=rowsz)*p=(void *)datptr; + } + return (void **)ret; +} + +void **oc_calloc_2d(size_t _height,size_t _width,size_t _sz){ + size_t colsz; + size_t rowsz; + size_t datsz; + char *ret; + colsz=_height*sizeof(void *); + rowsz=_sz*_width; + datsz=rowsz*_height; + /*Alloc array and row pointers.*/ + ret=(char *)_ogg_calloc(datsz+colsz,1); + /*Initialize the array.*/ + if(ret!=NULL){ + size_t i; + void **p; + char *datptr; + p=(void **)ret; + i=_height; + for(datptr=ret+colsz;i-->0;p++,datptr+=rowsz)*p=(void *)datptr; + } + return (void **)ret; +} + +void oc_free_2d(void *_ptr){ + _ogg_free(_ptr); +} + +/*Fills in a Y'CbCr buffer with a pointer to the image data in the first + buffer, but with the opposite vertical orientation. + _dst: The destination buffer. + This can be the same as _src. + _src: The source buffer.*/ +void oc_ycbcr_buffer_flip(th_ycbcr_buffer _dst, + const th_ycbcr_buffer _src){ + int pli; + for(pli=0;pli<3;pli++){ + _dst[pli].width=_src[pli].width; + _dst[pli].height=_src[pli].height; + _dst[pli].stride=-_src[pli].stride; + _dst[pli].data=_src[pli].data + +(1-_dst[pli].height)*(ptrdiff_t)_dst[pli].stride; + } +} + +const char *th_version_string(void){ + return OC_VENDOR_STRING; +} + +ogg_uint32_t th_version_number(void){ + return (TH_VERSION_MAJOR<<16)+(TH_VERSION_MINOR<<8)+TH_VERSION_SUB; +} + +/*Determines the packet type. + Note that this correctly interprets a 0-byte packet as a video data packet. + Return: 1 for a header packet, 0 for a data packet.*/ +int th_packet_isheader(ogg_packet *_op){ + return _op->bytes>0?_op->packet[0]>>7:0; +} + +/*Determines the frame type of a video data packet. + Note that this correctly interprets a 0-byte packet as a delta frame. + Return: 1 for a key frame, 0 for a delta frame, and -1 for a header + packet.*/ +int th_packet_iskeyframe(ogg_packet *_op){ + return _op->bytes<=0?0:_op->packet[0]&0x80?-1:!(_op->packet[0]&0x40); +} diff --git a/media/libtheora/lib/internal.h b/media/libtheora/lib/internal.h new file mode 100644 index 0000000000..53c77b88be --- /dev/null +++ b/media/libtheora/lib/internal.h @@ -0,0 +1,116 @@ +/******************************************************************** + * * + * THIS FILE IS PART OF THE OggTheora SOFTWARE CODEC SOURCE CODE. * + * USE, DISTRIBUTION AND REPRODUCTION OF THIS LIBRARY SOURCE IS * + * GOVERNED BY A BSD-STYLE SOURCE LICENSE INCLUDED WITH THIS SOURCE * + * IN 'COPYING'. PLEASE READ THESE TERMS BEFORE DISTRIBUTING. * + * * + * THE Theora SOURCE CODE IS COPYRIGHT (C) 2002-2009 * + * by the Xiph.Org Foundation and contributors http://www.xiph.org/ * + * * + ******************************************************************** + + function: + last mod: $Id$ + + ********************************************************************/ +#if !defined(_internal_H) +# define _internal_H (1) +# include <stdlib.h> +# include <limits.h> +# if defined(HAVE_CONFIG_H) +# include "config.h" +# endif +# include "theora/codec.h" +# include "theora/theora.h" +# include "ocintrin.h" + +# if !defined(__GNUC_PREREQ) +# if defined(__GNUC__)&&defined(__GNUC_MINOR__) +# define __GNUC_PREREQ(_maj,_min) \ + ((__GNUC__<<16)+__GNUC_MINOR__>=((_maj)<<16)+(_min)) +# else +# define __GNUC_PREREQ(_maj,_min) 0 +# endif +# endif + +# if defined(_MSC_VER) +/*Disable missing EMMS warnings.*/ +# pragma warning(disable:4799) +/*Thank you Microsoft, I know the order of operations.*/ +# pragma warning(disable:4554) +# endif +/*You, too, gcc.*/ +# if __GNUC_PREREQ(4,2) +# pragma GCC diagnostic ignored "-Wparentheses" +# endif + +/*Some assembly constructs require aligned operands. + The following macros are _only_ intended for structure member declarations. + Although they will sometimes work on stack variables, gcc will often silently + ignore them. + A separate set of macros could be made for manual stack alignment, but we + don't actually require it anywhere.*/ +# if defined(OC_X86_ASM)||defined(OC_ARM_ASM) +# if defined(__GNUC__) +# define OC_ALIGN8(expr) expr __attribute__((aligned(8))) +# define OC_ALIGN16(expr) expr __attribute__((aligned(16))) +# elif defined(_MSC_VER) +# define OC_ALIGN8(expr) __declspec (align(8)) expr +# define OC_ALIGN16(expr) __declspec (align(16)) expr +# else +# error "Alignment macros required for this platform." +# endif +# endif +# if !defined(OC_ALIGN8) +# define OC_ALIGN8(expr) expr +# endif +# if !defined(OC_ALIGN16) +# define OC_ALIGN16(expr) expr +# endif + + + +/*This library's version.*/ +# define OC_VENDOR_STRING "Xiph.Org libtheora 1.2.0alpha 20100924 (Ptalarbvorm)" + +/*Theora bitstream version.*/ +# define TH_VERSION_MAJOR (3) +# define TH_VERSION_MINOR (2) +# define TH_VERSION_SUB (1) +# define TH_VERSION_CHECK(_info,_maj,_min,_sub) \ + ((_info)->version_major>(_maj)||(_info)->version_major==(_maj)&& \ + ((_info)->version_minor>(_min)||(_info)->version_minor==(_min)&& \ + (_info)->version_subminor>=(_sub))) + + + +/*A map from the index in the zig zag scan to the coefficient number in a + block.*/ +extern const unsigned char OC_FZIG_ZAG[128]; +/*A map from the coefficient number in a block to its index in the zig zag + scan.*/ +extern const unsigned char OC_IZIG_ZAG[64]; +/*A map from physical macro block ordering to bitstream macro block + ordering within a super block.*/ +extern const unsigned char OC_MB_MAP[2][2]; +/*A list of the indices in the oc_mb_map array that can be valid for each of + the various chroma decimation types.*/ +extern const unsigned char OC_MB_MAP_IDXS[TH_PF_NFORMATS][12]; +/*The number of indices in the oc_mb_map array that can be valid for each of + the various chroma decimation types.*/ +extern const unsigned char OC_MB_MAP_NIDXS[TH_PF_NFORMATS]; + + + +int oc_ilog(unsigned _v); +void *oc_aligned_malloc(size_t _sz,size_t _align); +void oc_aligned_free(void *_ptr); +void **oc_malloc_2d(size_t _height,size_t _width,size_t _sz); +void **oc_calloc_2d(size_t _height,size_t _width,size_t _sz); +void oc_free_2d(void *_ptr); + +void oc_ycbcr_buffer_flip(th_ycbcr_buffer _dst, + const th_ycbcr_buffer _src); + +#endif diff --git a/media/libtheora/lib/mathops.h b/media/libtheora/lib/mathops.h new file mode 100644 index 0000000000..a1a4f9df0e --- /dev/null +++ b/media/libtheora/lib/mathops.h @@ -0,0 +1,143 @@ +#if !defined(_mathops_H) +# define _mathops_H (1) +# include <ogg/ogg.h> + +# if __GNUC_PREREQ(3,4) +# include <limits.h> +/*Note the casts to (int) below: this prevents OC_CLZ{32|64}_OFFS from + "upgrading" the type of an entire expression to an (unsigned) size_t.*/ +# if INT_MAX>=2147483647 +# define OC_CLZ32_OFFS ((int)sizeof(unsigned)*CHAR_BIT) +# define OC_CLZ32(_x) (__builtin_clz(_x)) +# elif LONG_MAX>=2147483647L +# define OC_CLZ32_OFFS ((int)sizeof(unsigned long)*CHAR_BIT) +# define OC_CLZ32(_x) (__builtin_clzl(_x)) +# endif +# if INT_MAX>=9223372036854775807LL +# define OC_CLZ64_OFFS ((int)sizeof(unsigned)*CHAR_BIT) +# define OC_CLZ64(_x) (__builtin_clz(_x)) +# elif LONG_MAX>=9223372036854775807LL +# define OC_CLZ64_OFFS ((int)sizeof(unsigned long)*CHAR_BIT) +# define OC_CLZ64(_x) (__builtin_clzl(_x)) +# elif LLONG_MAX>=9223372036854775807LL|| \ + __LONG_LONG_MAX__>=9223372036854775807LL +# define OC_CLZ64_OFFS ((int)sizeof(unsigned long long)*CHAR_BIT) +# define OC_CLZ64(_x) (__builtin_clzll(_x)) +# endif +# endif + + + +/** + * oc_ilog32 - Integer binary logarithm of a 32-bit value. + * @_v: A 32-bit value. + * Returns floor(log2(_v))+1, or 0 if _v==0. + * This is the number of bits that would be required to represent _v in two's + * complement notation with all of the leading zeros stripped. + * The OC_ILOG_32() or OC_ILOGNZ_32() macros may be able to use a builtin + * function instead, which should be faster. + */ +int oc_ilog32(ogg_uint32_t _v); +/** + * oc_ilog64 - Integer binary logarithm of a 64-bit value. + * @_v: A 64-bit value. + * Returns floor(log2(_v))+1, or 0 if _v==0. + * This is the number of bits that would be required to represent _v in two's + * complement notation with all of the leading zeros stripped. + * The OC_ILOG_64() or OC_ILOGNZ_64() macros may be able to use a builtin + * function instead, which should be faster. + */ +int oc_ilog64(ogg_int64_t _v); + + +# if defined(OC_CLZ32) +/** + * OC_ILOGNZ_32 - Integer binary logarithm of a non-zero 32-bit value. + * @_v: A non-zero 32-bit value. + * Returns floor(log2(_v))+1. + * This is the number of bits that would be required to represent _v in two's + * complement notation with all of the leading zeros stripped. + * If _v is zero, the return value is undefined; use OC_ILOG_32() instead. + */ +# define OC_ILOGNZ_32(_v) (OC_CLZ32_OFFS-OC_CLZ32(_v)) +/** + * OC_ILOG_32 - Integer binary logarithm of a 32-bit value. + * @_v: A 32-bit value. + * Returns floor(log2(_v))+1, or 0 if _v==0. + * This is the number of bits that would be required to represent _v in two's + * complement notation with all of the leading zeros stripped. + */ +# define OC_ILOG_32(_v) (OC_ILOGNZ_32(_v)&-!!(_v)) +# else +# define OC_ILOGNZ_32(_v) (oc_ilog32(_v)) +# define OC_ILOG_32(_v) (oc_ilog32(_v)) +# endif + +# if defined(CLZ64) +/** + * OC_ILOGNZ_64 - Integer binary logarithm of a non-zero 64-bit value. + * @_v: A non-zero 64-bit value. + * Returns floor(log2(_v))+1. + * This is the number of bits that would be required to represent _v in two's + * complement notation with all of the leading zeros stripped. + * If _v is zero, the return value is undefined; use OC_ILOG_64() instead. + */ +# define OC_ILOGNZ_64(_v) (CLZ64_OFFS-CLZ64(_v)) +/** + * OC_ILOG_64 - Integer binary logarithm of a 64-bit value. + * @_v: A 64-bit value. + * Returns floor(log2(_v))+1, or 0 if _v==0. + * This is the number of bits that would be required to represent _v in two's + * complement notation with all of the leading zeros stripped. + */ +# define OC_ILOG_64(_v) (OC_ILOGNZ_64(_v)&-!!(_v)) +# else +# define OC_ILOGNZ_64(_v) (oc_ilog64(_v)) +# define OC_ILOG_64(_v) (oc_ilog64(_v)) +# endif + +# define OC_STATIC_ILOG0(_v) (!!(_v)) +# define OC_STATIC_ILOG1(_v) (((_v)&0x2)?2:OC_STATIC_ILOG0(_v)) +# define OC_STATIC_ILOG2(_v) \ + (((_v)&0xC)?2+OC_STATIC_ILOG1((_v)>>2):OC_STATIC_ILOG1(_v)) +# define OC_STATIC_ILOG3(_v) \ + (((_v)&0xF0)?4+OC_STATIC_ILOG2((_v)>>4):OC_STATIC_ILOG2(_v)) +# define OC_STATIC_ILOG4(_v) \ + (((_v)&0xFF00)?8+OC_STATIC_ILOG3((_v)>>8):OC_STATIC_ILOG3(_v)) +# define OC_STATIC_ILOG5(_v) \ + (((_v)&0xFFFF0000)?16+OC_STATIC_ILOG4((_v)>>16):OC_STATIC_ILOG4(_v)) +# define OC_STATIC_ILOG6(_v) \ + (((_v)&0xFFFFFFFF00000000ULL)?32+OC_STATIC_ILOG5((_v)>>32):OC_STATIC_ILOG5(_v)) +/** + * OC_STATIC_ILOG_32 - The integer logarithm of an (unsigned, 32-bit) constant. + * @_v: A non-negative 32-bit constant. + * Returns floor(log2(_v))+1, or 0 if _v==0. + * This is the number of bits that would be required to represent _v in two's + * complement notation with all of the leading zeros stripped. + * This macro is suitable for evaluation at compile time, but it should not be + * used on values that can change at runtime, as it operates via exhaustive + * search. + */ +# define OC_STATIC_ILOG_32(_v) (OC_STATIC_ILOG5((ogg_uint32_t)(_v))) +/** + * OC_STATIC_ILOG_64 - The integer logarithm of an (unsigned, 64-bit) constant. + * @_v: A non-negative 64-bit constant. + * Returns floor(log2(_v))+1, or 0 if _v==0. + * This is the number of bits that would be required to represent _v in two's + * complement notation with all of the leading zeros stripped. + * This macro is suitable for evaluation at compile time, but it should not be + * used on values that can change at runtime, as it operates via exhaustive + * search. + */ +# define OC_STATIC_ILOG_64(_v) (OC_STATIC_ILOG6((ogg_int64_t)(_v))) + +#define OC_Q57(_v) ((ogg_int64_t)(_v)<<57) +#define OC_Q10(_v) ((_v)<<10) + +ogg_int64_t oc_bexp64(ogg_int64_t _z); +ogg_int64_t oc_blog64(ogg_int64_t _w); + +ogg_uint32_t oc_bexp32_q10(int _z); +int oc_blog32_q10(ogg_uint32_t _w); + +#endif diff --git a/media/libtheora/lib/ocintrin.h b/media/libtheora/lib/ocintrin.h new file mode 100644 index 0000000000..b200ceafce --- /dev/null +++ b/media/libtheora/lib/ocintrin.h @@ -0,0 +1,128 @@ +/******************************************************************** + * * + * THIS FILE IS PART OF THE OggTheora SOFTWARE CODEC SOURCE CODE. * + * USE, DISTRIBUTION AND REPRODUCTION OF THIS LIBRARY SOURCE IS * + * GOVERNED BY A BSD-STYLE SOURCE LICENSE INCLUDED WITH THIS SOURCE * + * IN 'COPYING'. PLEASE READ THESE TERMS BEFORE DISTRIBUTING. * + * * + * THE Theora SOURCE CODE IS COPYRIGHT (C) 2002-2009 * + * by the Xiph.Org Foundation and contributors http://www.xiph.org/ * + * * + ******************************************************************** + + function: + last mod: $Id$ + + ********************************************************************/ + +/*Some common macros for potential platform-specific optimization.*/ +#include <math.h> +#if !defined(_ocintrin_H) +# define _ocintrin_H (1) + +/*Some specific platforms may have optimized intrinsic or inline assembly + versions of these functions which can substantially improve performance. + We define macros for them to allow easy incorporation of these non-ANSI + features.*/ + +/*Note that we do not provide a macro for abs(), because it is provided as a + library function, which we assume is translated into an intrinsic to avoid + the function call overhead and then implemented in the smartest way for the + target platform. + With modern gcc (4.x), this is true: it uses cmov instructions if the + architecture supports it and branchless bit-twiddling if it does not (the + speed difference between the two approaches is not measurable). + Interestingly, the bit-twiddling method was patented in 2000 (US 6,073,150) + by Sun Microsystems, despite prior art dating back to at least 1996: + http://web.archive.org/web/19961201174141/www.x86.org/ftp/articles/pentopt/PENTOPT.TXT + On gcc 3.x, however, our assumption is not true, as abs() is translated to a + conditional jump, which is horrible on deeply piplined architectures (e.g., + all consumer architectures for the past decade or more). + Also be warned that -C*abs(x) where C is a constant is mis-optimized as + abs(C*x) on every gcc release before 4.2.3. + See bug http://gcc.gnu.org/bugzilla/show_bug.cgi?id=34130 */ + +/*Modern gcc (4.x) can compile the naive versions of min and max with cmov if + given an appropriate architecture, but the branchless bit-twiddling versions + are just as fast, and do not require any special target architecture. + Earlier gcc versions (3.x) compiled both code to the same assembly + instructions, because of the way they represented ((_b)>(_a)) internally.*/ +#define OC_MAXI(_a,_b) ((_a)-((_a)-(_b)&-((_b)>(_a)))) +#define OC_MINI(_a,_b) ((_a)+((_b)-(_a)&-((_b)<(_a)))) +/*Clamps an integer into the given range. + If _a>_c, then the lower bound _a is respected over the upper bound _c (this + behavior is required to meet our documented API behavior). + _a: The lower bound. + _b: The value to clamp. + _c: The upper boud.*/ +#define OC_CLAMPI(_a,_b,_c) (OC_MAXI(_a,OC_MINI(_b,_c))) +#define OC_CLAMP255(_x) ((unsigned char)((((_x)<0)-1)&((_x)|-((_x)>255)))) +/*This has a chance of compiling branchless, and is just as fast as the + bit-twiddling method, which is slightly less portable, since it relies on a + sign-extended rightshift, which is not guaranteed by ANSI (but present on + every relevant platform).*/ +#define OC_SIGNI(_a) (((_a)>0)-((_a)<0)) +/*Slightly more portable than relying on a sign-extended right-shift (which is + not guaranteed by ANSI), and just as fast, since gcc (3.x and 4.x both) + compile it into the right-shift anyway.*/ +#define OC_SIGNMASK(_a) (-((_a)<0)) +/*Divides an integer by a power of two, truncating towards 0. + _dividend: The integer to divide. + _shift: The non-negative power of two to divide by. + _rmask: (1<<_shift)-1*/ +#define OC_DIV_POW2(_dividend,_shift,_rmask)\ + ((_dividend)+(OC_SIGNMASK(_dividend)&(_rmask))>>(_shift)) +/*Divides _x by 65536, truncating towards 0.*/ +#define OC_DIV2_16(_x) OC_DIV_POW2(_x,16,0xFFFF) +/*Divides _x by 2, truncating towards 0.*/ +#define OC_DIV2(_x) OC_DIV_POW2(_x,1,0x1) +/*Divides _x by 8, truncating towards 0.*/ +#define OC_DIV8(_x) OC_DIV_POW2(_x,3,0x7) +/*Divides _x by 16, truncating towards 0.*/ +#define OC_DIV16(_x) OC_DIV_POW2(_x,4,0xF) +/*Right shifts _dividend by _shift, adding _rval, and subtracting one for + negative dividends first. + When _rval is (1<<_shift-1), this is equivalent to division with rounding + ties away from zero.*/ +#define OC_DIV_ROUND_POW2(_dividend,_shift,_rval)\ + ((_dividend)+OC_SIGNMASK(_dividend)+(_rval)>>(_shift)) +/*Divides a _x by 2, rounding towards even numbers.*/ +#define OC_DIV2_RE(_x) ((_x)+((_x)>>1&1)>>1) +/*Divides a _x by (1<<(_shift)), rounding towards even numbers.*/ +#define OC_DIV_POW2_RE(_x,_shift) \ + ((_x)+((_x)>>(_shift)&1)+((1<<(_shift))-1>>1)>>(_shift)) +/*Swaps two integers _a and _b if _a>_b.*/ +#define OC_SORT2I(_a,_b) \ + do{ \ + int t__; \ + t__=((_a)^(_b))&-((_b)<(_a)); \ + (_a)^=t__; \ + (_b)^=t__; \ + } \ + while(0) + +/*Accesses one of four (signed) bytes given an index. + This can be used to avoid small lookup tables.*/ +#define OC_BYTE_TABLE32(_a,_b,_c,_d,_i) \ + ((signed char) \ + (((_a)&0xFF|((_b)&0xFF)<<8|((_c)&0xFF)<<16|((_d)&0xFF)<<24)>>(_i)*8)) +/*Accesses one of eight (unsigned) nibbles given an index. + This can be used to avoid small lookup tables.*/ +#define OC_UNIBBLE_TABLE32(_a,_b,_c,_d,_e,_f,_g,_h,_i) \ + ((((_a)&0xF|((_b)&0xF)<<4|((_c)&0xF)<<8|((_d)&0xF)<<12| \ + ((_e)&0xF)<<16|((_f)&0xF)<<20|((_g)&0xF)<<24|((_h)&0xF)<<28)>>(_i)*4)&0xF) + + + +/*All of these macros should expect floats as arguments.*/ +#define OC_MAXF(_a,_b) ((_a)<(_b)?(_b):(_a)) +#define OC_MINF(_a,_b) ((_a)>(_b)?(_b):(_a)) +#define OC_CLAMPF(_a,_b,_c) (OC_MINF(_a,OC_MAXF(_b,_c))) +#define OC_FABSF(_f) ((float)fabs(_f)) +#define OC_SQRTF(_f) ((float)sqrt(_f)) +#define OC_POWF(_b,_e) ((float)pow(_b,_e)) +#define OC_LOGF(_f) ((float)log(_f)) +#define OC_IFLOORF(_f) ((int)floor(_f)) +#define OC_ICEILF(_f) ((int)ceil(_f)) + +#endif diff --git a/media/libtheora/lib/quant.c b/media/libtheora/lib/quant.c new file mode 100644 index 0000000000..e206202844 --- /dev/null +++ b/media/libtheora/lib/quant.c @@ -0,0 +1,127 @@ +/******************************************************************** + * * + * THIS FILE IS PART OF THE OggTheora SOFTWARE CODEC SOURCE CODE. * + * USE, DISTRIBUTION AND REPRODUCTION OF THIS LIBRARY SOURCE IS * + * GOVERNED BY A BSD-STYLE SOURCE LICENSE INCLUDED WITH THIS SOURCE * + * IN 'COPYING'. PLEASE READ THESE TERMS BEFORE DISTRIBUTING. * + * * + * THE Theora SOURCE CODE IS COPYRIGHT (C) 2002-2009 * + * by the Xiph.Org Foundation and contributors http://www.xiph.org/ * + * * + ******************************************************************** + + function: + last mod: $Id$ + + ********************************************************************/ + +#include <stdlib.h> +#include <string.h> +#include <ogg/ogg.h> +#include "quant.h" +#include "decint.h" + +/*The maximum output of the DCT with +/- 255 inputs is +/- 8157. + These minimum quantizers ensure the result after quantization (and after + prediction for DC) will be no more than +/- 510. + The tokenization system can handle values up to +/- 580, so there is no need + to do any coefficient clamping. + I would rather have allowed smaller quantizers and had to clamp, but these + minimums were required when constructing the original VP3 matrices and have + been formalized in the spec.*/ +static const unsigned OC_DC_QUANT_MIN[2]={4<<2,8<<2}; +static const unsigned OC_AC_QUANT_MIN[2]={2<<2,4<<2}; + +/*Initializes the dequantization tables from a set of quantizer info. + Currently the dequantizer (and elsewhere enquantizer) tables are expected to + be initialized as pointing to the storage reserved for them in the + oc_theora_state (resp. oc_enc_ctx) structure. + If some tables are duplicates of others, the pointers will be adjusted to + point to a single copy of the tables, but the storage for them will not be + freed. + If you're concerned about the memory footprint, the obvious thing to do is + to move the storage out of its fixed place in the structures and allocate + it on demand. + However, a much, much better option is to only store the quantization + matrices being used for the current frame, and to recalculate these as the + qi values change between frames (this is what VP3 did).*/ +void oc_dequant_tables_init(ogg_uint16_t *_dequant[64][3][2], + int _pp_dc_scale[64],const th_quant_info *_qinfo){ + /*Coding mode: intra or inter.*/ + int qti; + /*Y', C_b, C_r*/ + int pli; + for(qti=0;qti<2;qti++)for(pli=0;pli<3;pli++){ + /*Quality index.*/ + int qi; + /*Range iterator.*/ + int qri; + for(qi=0,qri=0;qri<=_qinfo->qi_ranges[qti][pli].nranges;qri++){ + th_quant_base base; + ogg_uint32_t q; + int qi_start; + int qi_end; + memcpy(base,_qinfo->qi_ranges[qti][pli].base_matrices[qri], + sizeof(base)); + qi_start=qi; + if(qri==_qinfo->qi_ranges[qti][pli].nranges)qi_end=qi+1; + else qi_end=qi+_qinfo->qi_ranges[qti][pli].sizes[qri]; + /*Iterate over quality indicies in this range.*/ + for(;;){ + ogg_uint32_t qfac; + int zzi; + int ci; + /*In the original VP3.2 code, the rounding offset and the size of the + dead zone around 0 were controlled by a "sharpness" parameter. + The size of our dead zone is now controlled by the per-coefficient + quality thresholds returned by our HVS module. + We round down from a more accurate value when the quality of the + reconstruction does not fall below our threshold and it saves bits. + Hence, all of that VP3.2 code is gone from here, and the remaining + floating point code has been implemented as equivalent integer code + with exact precision.*/ + qfac=(ogg_uint32_t)_qinfo->dc_scale[qi]*base[0]; + /*For postprocessing, not dequantization.*/ + if(_pp_dc_scale!=NULL)_pp_dc_scale[qi]=(int)(qfac/160); + /*Scale DC the coefficient from the proper table.*/ + q=(qfac/100)<<2; + q=OC_CLAMPI(OC_DC_QUANT_MIN[qti],q,OC_QUANT_MAX); + _dequant[qi][pli][qti][0]=(ogg_uint16_t)q; + /*Now scale AC coefficients from the proper table.*/ + for(zzi=1;zzi<64;zzi++){ + q=((ogg_uint32_t)_qinfo->ac_scale[qi]*base[OC_FZIG_ZAG[zzi]]/100)<<2; + q=OC_CLAMPI(OC_AC_QUANT_MIN[qti],q,OC_QUANT_MAX); + _dequant[qi][pli][qti][zzi]=(ogg_uint16_t)q; + } + /*If this is a duplicate of a previous matrix, use that instead. + This simple check helps us improve cache coherency later.*/ + { + int dupe; + int qtj; + int plj; + dupe=0; + for(qtj=0;qtj<=qti;qtj++){ + for(plj=0;plj<(qtj<qti?3:pli);plj++){ + if(!memcmp(_dequant[qi][pli][qti],_dequant[qi][plj][qtj], + sizeof(oc_quant_table))){ + dupe=1; + break; + } + } + if(dupe)break; + } + if(dupe)_dequant[qi][pli][qti]=_dequant[qi][plj][qtj]; + } + if(++qi>=qi_end)break; + /*Interpolate the next base matrix.*/ + for(ci=0;ci<64;ci++){ + base[ci]=(unsigned char)( + (2*((qi_end-qi)*_qinfo->qi_ranges[qti][pli].base_matrices[qri][ci]+ + (qi-qi_start)*_qinfo->qi_ranges[qti][pli].base_matrices[qri+1][ci]) + +_qinfo->qi_ranges[qti][pli].sizes[qri])/ + (2*_qinfo->qi_ranges[qti][pli].sizes[qri])); + } + } + } + } +} diff --git a/media/libtheora/lib/quant.h b/media/libtheora/lib/quant.h new file mode 100644 index 0000000000..247210eaae --- /dev/null +++ b/media/libtheora/lib/quant.h @@ -0,0 +1,33 @@ +/******************************************************************** + * * + * THIS FILE IS PART OF THE OggTheora SOFTWARE CODEC SOURCE CODE. * + * USE, DISTRIBUTION AND REPRODUCTION OF THIS LIBRARY SOURCE IS * + * GOVERNED BY A BSD-STYLE SOURCE LICENSE INCLUDED WITH THIS SOURCE * + * IN 'COPYING'. PLEASE READ THESE TERMS BEFORE DISTRIBUTING. * + * * + * THE Theora SOURCE CODE IS COPYRIGHT (C) 2002-2009 * + * by the Xiph.Org Foundation and contributors http://www.xiph.org/ * + * * + ******************************************************************** + + function: + last mod: $Id$ + + ********************************************************************/ + +#if !defined(_quant_H) +# define _quant_H (1) +# include "theora/codec.h" +# include "ocintrin.h" + +typedef ogg_uint16_t oc_quant_table[64]; + + +/*Maximum scaled quantizer value.*/ +#define OC_QUANT_MAX (1024<<2) + + +void oc_dequant_tables_init(ogg_uint16_t *_dequant[64][3][2], + int _pp_dc_scale[64],const th_quant_info *_qinfo); + +#endif diff --git a/media/libtheora/lib/state.c b/media/libtheora/lib/state.c new file mode 100644 index 0000000000..f4c6240387 --- /dev/null +++ b/media/libtheora/lib/state.c @@ -0,0 +1,1267 @@ +/******************************************************************** + * * + * THIS FILE IS PART OF THE OggTheora SOFTWARE CODEC SOURCE CODE. * + * USE, DISTRIBUTION AND REPRODUCTION OF THIS LIBRARY SOURCE IS * + * GOVERNED BY A BSD-STYLE SOURCE LICENSE INCLUDED WITH THIS SOURCE * + * IN 'COPYING'. PLEASE READ THESE TERMS BEFORE DISTRIBUTING. * + * * + * THE Theora SOURCE CODE IS COPYRIGHT (C) 2002-2009 * + * by the Xiph.Org Foundation and contributors http://www.xiph.org/ * + * * + ******************************************************************** + + function: + last mod: $Id$ + + ********************************************************************/ + +#include <stdlib.h> +#include <string.h> +#include "state.h" +#if defined(OC_DUMP_IMAGES) +# include <stdio.h> +# include "png.h" +# include "zlib.h" +#endif + +/*The function used to fill in the chroma plane motion vectors for a macro + block when 4 different motion vectors are specified in the luma plane. + This version is for use with chroma decimated in the X and Y directions + (4:2:0). + _cbmvs: The chroma block-level motion vectors to fill in. + _lbmvs: The luma block-level motion vectors.*/ +static void oc_set_chroma_mvs00(oc_mv _cbmvs[4],const oc_mv _lbmvs[4]){ + int dx; + int dy; + dx=OC_MV_X(_lbmvs[0])+OC_MV_X(_lbmvs[1]) + +OC_MV_X(_lbmvs[2])+OC_MV_X(_lbmvs[3]); + dy=OC_MV_Y(_lbmvs[0])+OC_MV_Y(_lbmvs[1]) + +OC_MV_Y(_lbmvs[2])+OC_MV_Y(_lbmvs[3]); + _cbmvs[0]=OC_MV(OC_DIV_ROUND_POW2(dx,2,2),OC_DIV_ROUND_POW2(dy,2,2)); +} + +/*The function used to fill in the chroma plane motion vectors for a macro + block when 4 different motion vectors are specified in the luma plane. + This version is for use with chroma decimated in the Y direction. + _cbmvs: The chroma block-level motion vectors to fill in. + _lbmvs: The luma block-level motion vectors.*/ +static void oc_set_chroma_mvs01(oc_mv _cbmvs[4],const oc_mv _lbmvs[4]){ + int dx; + int dy; + dx=OC_MV_X(_lbmvs[0])+OC_MV_X(_lbmvs[2]); + dy=OC_MV_Y(_lbmvs[0])+OC_MV_Y(_lbmvs[2]); + _cbmvs[0]=OC_MV(OC_DIV_ROUND_POW2(dx,1,1),OC_DIV_ROUND_POW2(dy,1,1)); + dx=OC_MV_X(_lbmvs[1])+OC_MV_X(_lbmvs[3]); + dy=OC_MV_Y(_lbmvs[1])+OC_MV_Y(_lbmvs[3]); + _cbmvs[1]=OC_MV(OC_DIV_ROUND_POW2(dx,1,1),OC_DIV_ROUND_POW2(dy,1,1)); +} + +/*The function used to fill in the chroma plane motion vectors for a macro + block when 4 different motion vectors are specified in the luma plane. + This version is for use with chroma decimated in the X direction (4:2:2). + _cbmvs: The chroma block-level motion vectors to fill in. + _lbmvs: The luma block-level motion vectors.*/ +static void oc_set_chroma_mvs10(oc_mv _cbmvs[4],const oc_mv _lbmvs[4]){ + int dx; + int dy; + dx=OC_MV_X(_lbmvs[0])+OC_MV_X(_lbmvs[1]); + dy=OC_MV_Y(_lbmvs[0])+OC_MV_Y(_lbmvs[1]); + _cbmvs[0]=OC_MV(OC_DIV_ROUND_POW2(dx,1,1),OC_DIV_ROUND_POW2(dy,1,1)); + dx=OC_MV_X(_lbmvs[2])+OC_MV_X(_lbmvs[3]); + dy=OC_MV_Y(_lbmvs[2])+OC_MV_Y(_lbmvs[3]); + _cbmvs[2]=OC_MV(OC_DIV_ROUND_POW2(dx,1,1),OC_DIV_ROUND_POW2(dy,1,1)); +} + +/*The function used to fill in the chroma plane motion vectors for a macro + block when 4 different motion vectors are specified in the luma plane. + This version is for use with no chroma decimation (4:4:4). + _cbmvs: The chroma block-level motion vectors to fill in. + _lmbmv: The luma macro-block level motion vector to fill in for use in + prediction. + _lbmvs: The luma block-level motion vectors.*/ +static void oc_set_chroma_mvs11(oc_mv _cbmvs[4],const oc_mv _lbmvs[4]){ + _cbmvs[0]=_lbmvs[0]; + _cbmvs[1]=_lbmvs[1]; + _cbmvs[2]=_lbmvs[2]; + _cbmvs[3]=_lbmvs[3]; +} + +/*A table of functions used to fill in the chroma plane motion vectors for a + macro block when 4 different motion vectors are specified in the luma + plane.*/ +const oc_set_chroma_mvs_func OC_SET_CHROMA_MVS_TABLE[TH_PF_NFORMATS]={ + (oc_set_chroma_mvs_func)oc_set_chroma_mvs00, + (oc_set_chroma_mvs_func)oc_set_chroma_mvs01, + (oc_set_chroma_mvs_func)oc_set_chroma_mvs10, + (oc_set_chroma_mvs_func)oc_set_chroma_mvs11 +}; + + + +/*Returns the fragment index of the top-left block in a macro block. + This can be used to test whether or not the whole macro block is valid. + _sb_map: The super block map. + _quadi: The quadrant number. + Return: The index of the fragment of the upper left block in the macro + block, or -1 if the block lies outside the coded frame.*/ +static ptrdiff_t oc_sb_quad_top_left_frag(oc_sb_map_quad _sb_map[4],int _quadi){ + /*It so happens that under the Hilbert curve ordering described below, the + upper-left block in each macro block is at index 0, except in macro block + 3, where it is at index 2.*/ + return _sb_map[_quadi][_quadi&_quadi<<1]; +} + +/*Fills in the mapping from block positions to fragment numbers for a single + color plane. + This function also fills in the "valid" flag of each quadrant in the super + block flags. + _sb_maps: The array of super block maps for the color plane. + _sb_flags: The array of super block flags for the color plane. + _frag0: The index of the first fragment in the plane. + _hfrags: The number of horizontal fragments in a coded frame. + _vfrags: The number of vertical fragments in a coded frame.*/ +static void oc_sb_create_plane_mapping(oc_sb_map _sb_maps[], + oc_sb_flags _sb_flags[],ptrdiff_t _frag0,int _hfrags,int _vfrags){ + /*Contains the (macro_block,block) indices for a 4x4 grid of + fragments. + The pattern is a 4x4 Hilbert space-filling curve. + A Hilbert curve has the nice property that as the curve grows larger, its + fractal dimension approaches 2. + The intuition is that nearby blocks in the curve are also close spatially, + with the previous element always an immediate neighbor, so that runs of + blocks should be well correlated.*/ + static const int SB_MAP[4][4][2]={ + {{0,0},{0,1},{3,2},{3,3}}, + {{0,3},{0,2},{3,1},{3,0}}, + {{1,0},{1,3},{2,0},{2,3}}, + {{1,1},{1,2},{2,1},{2,2}} + }; + ptrdiff_t yfrag; + unsigned sbi; + int y; + sbi=0; + yfrag=_frag0; + for(y=0;;y+=4){ + int imax; + int x; + /*Figure out how many columns of blocks in this super block lie within the + image.*/ + imax=_vfrags-y; + if(imax>4)imax=4; + else if(imax<=0)break; + for(x=0;;x+=4,sbi++){ + ptrdiff_t xfrag; + int jmax; + int quadi; + int i; + /*Figure out how many rows of blocks in this super block lie within the + image.*/ + jmax=_hfrags-x; + if(jmax>4)jmax=4; + else if(jmax<=0)break; + /*By default, set all fragment indices to -1.*/ + memset(_sb_maps[sbi],0xFF,sizeof(_sb_maps[sbi])); + /*Fill in the fragment map for this super block.*/ + xfrag=yfrag+x; + for(i=0;i<imax;i++){ + int j; + for(j=0;j<jmax;j++){ + _sb_maps[sbi][SB_MAP[i][j][0]][SB_MAP[i][j][1]]=xfrag+j; + } + xfrag+=_hfrags; + } + /*Mark which quadrants of this super block lie within the image.*/ + for(quadi=0;quadi<4;quadi++){ + _sb_flags[sbi].quad_valid|= + (oc_sb_quad_top_left_frag(_sb_maps[sbi],quadi)>=0)<<quadi; + } + } + yfrag+=_hfrags<<2; + } +} + +/*Fills in the Y plane fragment map for a macro block given the fragment + coordinates of its upper-left hand corner. + _mb_map: The macro block map to fill. + _fplane: The description of the Y plane. + _xfrag0: The X location of the upper-left hand fragment in the luma plane. + _yfrag0: The Y location of the upper-left hand fragment in the luma plane.*/ +static void oc_mb_fill_ymapping(oc_mb_map_plane _mb_map[3], + const oc_fragment_plane *_fplane,int _xfrag0,int _yfrag0){ + int i; + int j; + for(i=0;i<2;i++)for(j=0;j<2;j++){ + _mb_map[0][i<<1|j]=(_yfrag0+i)*(ptrdiff_t)_fplane->nhfrags+_xfrag0+j; + } +} + +/*Fills in the chroma plane fragment maps for a macro block. + This version is for use with chroma decimated in the X and Y directions + (4:2:0). + _mb_map: The macro block map to fill. + _fplanes: The descriptions of the fragment planes. + _xfrag0: The X location of the upper-left hand fragment in the luma plane. + _yfrag0: The Y location of the upper-left hand fragment in the luma plane.*/ +static void oc_mb_fill_cmapping00(oc_mb_map_plane _mb_map[3], + const oc_fragment_plane _fplanes[3],int _xfrag0,int _yfrag0){ + ptrdiff_t fragi; + _xfrag0>>=1; + _yfrag0>>=1; + fragi=_yfrag0*(ptrdiff_t)_fplanes[1].nhfrags+_xfrag0; + _mb_map[1][0]=fragi+_fplanes[1].froffset; + _mb_map[2][0]=fragi+_fplanes[2].froffset; +} + +/*Fills in the chroma plane fragment maps for a macro block. + This version is for use with chroma decimated in the Y direction. + _mb_map: The macro block map to fill. + _fplanes: The descriptions of the fragment planes. + _xfrag0: The X location of the upper-left hand fragment in the luma plane. + _yfrag0: The Y location of the upper-left hand fragment in the luma plane.*/ +static void oc_mb_fill_cmapping01(oc_mb_map_plane _mb_map[3], + const oc_fragment_plane _fplanes[3],int _xfrag0,int _yfrag0){ + ptrdiff_t fragi; + int j; + _yfrag0>>=1; + fragi=_yfrag0*(ptrdiff_t)_fplanes[1].nhfrags+_xfrag0; + for(j=0;j<2;j++){ + _mb_map[1][j]=fragi+_fplanes[1].froffset; + _mb_map[2][j]=fragi+_fplanes[2].froffset; + fragi++; + } +} + +/*Fills in the chroma plane fragment maps for a macro block. + This version is for use with chroma decimated in the X direction (4:2:2). + _mb_map: The macro block map to fill. + _fplanes: The descriptions of the fragment planes. + _xfrag0: The X location of the upper-left hand fragment in the luma plane. + _yfrag0: The Y location of the upper-left hand fragment in the luma plane.*/ +static void oc_mb_fill_cmapping10(oc_mb_map_plane _mb_map[3], + const oc_fragment_plane _fplanes[3],int _xfrag0,int _yfrag0){ + ptrdiff_t fragi; + int i; + _xfrag0>>=1; + fragi=_yfrag0*(ptrdiff_t)_fplanes[1].nhfrags+_xfrag0; + for(i=0;i<2;i++){ + _mb_map[1][i<<1]=fragi+_fplanes[1].froffset; + _mb_map[2][i<<1]=fragi+_fplanes[2].froffset; + fragi+=_fplanes[1].nhfrags; + } +} + +/*Fills in the chroma plane fragment maps for a macro block. + This version is for use with no chroma decimation (4:4:4). + This uses the already filled-in luma plane values. + _mb_map: The macro block map to fill. + _fplanes: The descriptions of the fragment planes. + _xfrag0: The X location of the upper-left hand fragment in the luma plane. + _yfrag0: The Y location of the upper-left hand fragment in the luma plane.*/ +static void oc_mb_fill_cmapping11(oc_mb_map_plane _mb_map[3], + const oc_fragment_plane _fplanes[3],int _xfrag0,int _yfrag0){ + int k; + (void)_xfrag0; + (void)_yfrag0; + for(k=0;k<4;k++){ + _mb_map[1][k]=_mb_map[0][k]+_fplanes[1].froffset; + _mb_map[2][k]=_mb_map[0][k]+_fplanes[2].froffset; + } +} + +/*The function type used to fill in the chroma plane fragment maps for a + macro block. + _mb_map: The macro block map to fill. + _fplanes: The descriptions of the fragment planes. + _xfrag0: The X location of the upper-left hand fragment in the luma plane. + _yfrag0: The Y location of the upper-left hand fragment in the luma plane.*/ +typedef void (*oc_mb_fill_cmapping_func)(oc_mb_map_plane _mb_map[3], + const oc_fragment_plane _fplanes[3],int _xfrag0,int _yfrag0); + +/*A table of functions used to fill in the chroma plane fragment maps for a + macro block for each type of chrominance decimation.*/ +static const oc_mb_fill_cmapping_func OC_MB_FILL_CMAPPING_TABLE[4]={ + oc_mb_fill_cmapping00, + oc_mb_fill_cmapping01, + oc_mb_fill_cmapping10, + oc_mb_fill_cmapping11 +}; + +/*Fills in the mapping from macro blocks to their corresponding fragment + numbers in each plane. + _mb_maps: The list of macro block maps. + _mb_modes: The list of macro block modes; macro blocks completely outside + the coded region are marked invalid. + _fplanes: The descriptions of the fragment planes. + _pixel_fmt: The chroma decimation type.*/ +static void oc_mb_create_mapping(oc_mb_map _mb_maps[], + signed char _mb_modes[],const oc_fragment_plane _fplanes[3],int _pixel_fmt){ + oc_mb_fill_cmapping_func mb_fill_cmapping; + unsigned sbi; + int y; + mb_fill_cmapping=OC_MB_FILL_CMAPPING_TABLE[_pixel_fmt]; + /*Loop through the luma plane super blocks.*/ + for(sbi=y=0;y<_fplanes[0].nvfrags;y+=4){ + int x; + for(x=0;x<_fplanes[0].nhfrags;x+=4,sbi++){ + int ymb; + /*Loop through the macro blocks in each super block in display order.*/ + for(ymb=0;ymb<2;ymb++){ + int xmb; + for(xmb=0;xmb<2;xmb++){ + unsigned mbi; + int mbx; + int mby; + mbi=sbi<<2|OC_MB_MAP[ymb][xmb]; + mbx=x|xmb<<1; + mby=y|ymb<<1; + /*Initialize fragment indices to -1.*/ + memset(_mb_maps[mbi],0xFF,sizeof(_mb_maps[mbi])); + /*Make sure this macro block is within the encoded region.*/ + if(mbx>=_fplanes[0].nhfrags||mby>=_fplanes[0].nvfrags){ + _mb_modes[mbi]=OC_MODE_INVALID; + continue; + } + /*Fill in the fragment indices for the luma plane.*/ + oc_mb_fill_ymapping(_mb_maps[mbi],_fplanes,mbx,mby); + /*Fill in the fragment indices for the chroma planes.*/ + (*mb_fill_cmapping)(_mb_maps[mbi],_fplanes,mbx,mby); + } + } + } + } +} + +/*Marks the fragments which fall all or partially outside the displayable + region of the frame. + _state: The Theora state containing the fragments to be marked.*/ +static void oc_state_border_init(oc_theora_state *_state){ + oc_fragment *frag; + oc_fragment *yfrag_end; + oc_fragment *xfrag_end; + oc_fragment_plane *fplane; + int crop_x0; + int crop_y0; + int crop_xf; + int crop_yf; + int pli; + int y; + int x; + /*The method we use here is slow, but the code is dead simple and handles + all the special cases easily. + We only ever need to do it once.*/ + /*Loop through the fragments, marking those completely outside the + displayable region and constructing a border mask for those that straddle + the border.*/ + _state->nborders=0; + yfrag_end=frag=_state->frags; + for(pli=0;pli<3;pli++){ + fplane=_state->fplanes+pli; + /*Set up the cropping rectangle for this plane.*/ + crop_x0=_state->info.pic_x; + crop_xf=_state->info.pic_x+_state->info.pic_width; + crop_y0=_state->info.pic_y; + crop_yf=_state->info.pic_y+_state->info.pic_height; + if(pli>0){ + if(!(_state->info.pixel_fmt&1)){ + crop_x0=crop_x0>>1; + crop_xf=crop_xf+1>>1; + } + if(!(_state->info.pixel_fmt&2)){ + crop_y0=crop_y0>>1; + crop_yf=crop_yf+1>>1; + } + } + y=0; + for(yfrag_end+=fplane->nfrags;frag<yfrag_end;y+=8){ + x=0; + for(xfrag_end=frag+fplane->nhfrags;frag<xfrag_end;frag++,x+=8){ + /*First check to see if this fragment is completely outside the + displayable region.*/ + /*Note the special checks for an empty cropping rectangle. + This guarantees that if we count a fragment as straddling the + border below, at least one pixel in the fragment will be inside + the displayable region.*/ + if(x+8<=crop_x0||crop_xf<=x||y+8<=crop_y0||crop_yf<=y|| + crop_x0>=crop_xf||crop_y0>=crop_yf){ + frag->invalid=1; + } + /*Otherwise, check to see if it straddles the border.*/ + else if(x<crop_x0&&crop_x0<x+8||x<crop_xf&&crop_xf<x+8|| + y<crop_y0&&crop_y0<y+8||y<crop_yf&&crop_yf<y+8){ + ogg_int64_t mask; + int npixels; + int i; + mask=npixels=0; + for(i=0;i<8;i++){ + int j; + for(j=0;j<8;j++){ + if(x+j>=crop_x0&&x+j<crop_xf&&y+i>=crop_y0&&y+i<crop_yf){ + mask|=(ogg_int64_t)1<<(i<<3|j); + npixels++; + } + } + } + /*Search the fragment array for border info with the same pattern. + In general, there will be at most 8 different patterns (per + plane).*/ + for(i=0;;i++){ + if(i>=_state->nborders){ + _state->nborders++; + _state->borders[i].mask=mask; + _state->borders[i].npixels=npixels; + } + else if(_state->borders[i].mask!=mask)continue; + frag->borderi=i; + break; + } + } + else frag->borderi=-1; + } + } + } +} + +static int oc_state_frarray_init(oc_theora_state *_state){ + int yhfrags; + int yvfrags; + int chfrags; + int cvfrags; + ptrdiff_t yfrags; + ptrdiff_t cfrags; + ptrdiff_t nfrags; + unsigned yhsbs; + unsigned yvsbs; + unsigned chsbs; + unsigned cvsbs; + unsigned ysbs; + unsigned csbs; + unsigned nsbs; + size_t nmbs; + int hdec; + int vdec; + int pli; + /*Figure out the number of fragments in each plane.*/ + /*These parameters have already been validated to be multiples of 16.*/ + yhfrags=_state->info.frame_width>>3; + yvfrags=_state->info.frame_height>>3; + hdec=!(_state->info.pixel_fmt&1); + vdec=!(_state->info.pixel_fmt&2); + chfrags=yhfrags+hdec>>hdec; + cvfrags=yvfrags+vdec>>vdec; + yfrags=yhfrags*(ptrdiff_t)yvfrags; + cfrags=chfrags*(ptrdiff_t)cvfrags; + nfrags=yfrags+2*cfrags; + /*Figure out the number of super blocks in each plane.*/ + yhsbs=yhfrags+3>>2; + yvsbs=yvfrags+3>>2; + chsbs=chfrags+3>>2; + cvsbs=cvfrags+3>>2; + ysbs=yhsbs*yvsbs; + csbs=chsbs*cvsbs; + nsbs=ysbs+2*csbs; + nmbs=(size_t)ysbs<<2; + /*Check for overflow. + We support the ridiculous upper limits of the specification (1048560 by + 1048560, or 3 TB frames) if the target architecture has 64-bit pointers, + but for those with 32-bit pointers (or smaller!) we have to check. + If the caller wants to prevent denial-of-service by imposing a more + reasonable upper limit on the size of attempted allocations, they must do + so themselves; we have no platform independent way to determine how much + system memory there is nor an application-independent way to decide what a + "reasonable" allocation is.*/ + if(yfrags/yhfrags!=yvfrags||2*cfrags<cfrags||nfrags<yfrags|| + ysbs/yhsbs!=yvsbs||2*csbs<csbs||nsbs<ysbs||nmbs>>2!=ysbs){ + return TH_EIMPL; + } + /*Initialize the fragment array.*/ + _state->fplanes[0].nhfrags=yhfrags; + _state->fplanes[0].nvfrags=yvfrags; + _state->fplanes[0].froffset=0; + _state->fplanes[0].nfrags=yfrags; + _state->fplanes[0].nhsbs=yhsbs; + _state->fplanes[0].nvsbs=yvsbs; + _state->fplanes[0].sboffset=0; + _state->fplanes[0].nsbs=ysbs; + _state->fplanes[1].nhfrags=_state->fplanes[2].nhfrags=chfrags; + _state->fplanes[1].nvfrags=_state->fplanes[2].nvfrags=cvfrags; + _state->fplanes[1].froffset=yfrags; + _state->fplanes[2].froffset=yfrags+cfrags; + _state->fplanes[1].nfrags=_state->fplanes[2].nfrags=cfrags; + _state->fplanes[1].nhsbs=_state->fplanes[2].nhsbs=chsbs; + _state->fplanes[1].nvsbs=_state->fplanes[2].nvsbs=cvsbs; + _state->fplanes[1].sboffset=ysbs; + _state->fplanes[2].sboffset=ysbs+csbs; + _state->fplanes[1].nsbs=_state->fplanes[2].nsbs=csbs; + _state->nfrags=nfrags; + _state->frags=_ogg_calloc(nfrags,sizeof(*_state->frags)); + _state->frag_mvs=_ogg_malloc(nfrags*sizeof(*_state->frag_mvs)); + _state->nsbs=nsbs; + _state->sb_maps=_ogg_malloc(nsbs*sizeof(*_state->sb_maps)); + _state->sb_flags=_ogg_calloc(nsbs,sizeof(*_state->sb_flags)); + _state->nhmbs=yhsbs<<1; + _state->nvmbs=yvsbs<<1; + _state->nmbs=nmbs; + _state->mb_maps=_ogg_calloc(nmbs,sizeof(*_state->mb_maps)); + _state->mb_modes=_ogg_calloc(nmbs,sizeof(*_state->mb_modes)); + _state->coded_fragis=_ogg_malloc(nfrags*sizeof(*_state->coded_fragis)); + if(_state->frags==NULL||_state->frag_mvs==NULL||_state->sb_maps==NULL|| + _state->sb_flags==NULL||_state->mb_maps==NULL||_state->mb_modes==NULL|| + _state->coded_fragis==NULL){ + return TH_EFAULT; + } + /*Create the mapping from super blocks to fragments.*/ + for(pli=0;pli<3;pli++){ + oc_fragment_plane *fplane; + fplane=_state->fplanes+pli; + oc_sb_create_plane_mapping(_state->sb_maps+fplane->sboffset, + _state->sb_flags+fplane->sboffset,fplane->froffset, + fplane->nhfrags,fplane->nvfrags); + } + /*Create the mapping from macro blocks to fragments.*/ + oc_mb_create_mapping(_state->mb_maps,_state->mb_modes, + _state->fplanes,_state->info.pixel_fmt); + /*Initialize the invalid and borderi fields of each fragment.*/ + oc_state_border_init(_state); + return 0; +} + +static void oc_state_frarray_clear(oc_theora_state *_state){ + _ogg_free(_state->coded_fragis); + _ogg_free(_state->mb_modes); + _ogg_free(_state->mb_maps); + _ogg_free(_state->sb_flags); + _ogg_free(_state->sb_maps); + _ogg_free(_state->frag_mvs); + _ogg_free(_state->frags); +} + + +/*Initializes the buffers used for reconstructed frames. + These buffers are padded with 16 extra pixels on each side, to allow + unrestricted motion vectors without special casing the boundary. + If chroma is decimated in either direction, the padding is reduced by a + factor of 2 on the appropriate sides. + _nrefs: The number of reference buffers to init; must be in the range 3...6.*/ +static int oc_state_ref_bufs_init(oc_theora_state *_state,int _nrefs){ + th_info *info; + unsigned char *ref_frame_data; + size_t ref_frame_data_sz; + size_t ref_frame_sz; + size_t yplane_sz; + size_t cplane_sz; + int yhstride; + int yheight; + int chstride; + int cheight; + ptrdiff_t align; + ptrdiff_t yoffset; + ptrdiff_t coffset; + ptrdiff_t *frag_buf_offs; + ptrdiff_t fragi; + int hdec; + int vdec; + int rfi; + int pli; + if(_nrefs<3||_nrefs>6)return TH_EINVAL; + info=&_state->info; + /*Compute the image buffer parameters for each plane.*/ + hdec=!(info->pixel_fmt&1); + vdec=!(info->pixel_fmt&2); + yhstride=info->frame_width+2*OC_UMV_PADDING; + yheight=info->frame_height+2*OC_UMV_PADDING; + /*Require 16-byte aligned rows in the chroma planes.*/ + chstride=(yhstride>>hdec)+15&~15; + cheight=yheight>>vdec; + yplane_sz=yhstride*(size_t)yheight; + cplane_sz=chstride*(size_t)cheight; + yoffset=OC_UMV_PADDING+OC_UMV_PADDING*(ptrdiff_t)yhstride; + coffset=(OC_UMV_PADDING>>hdec)+(OC_UMV_PADDING>>vdec)*(ptrdiff_t)chstride; + /*Although we guarantee the rows of the chroma planes are a multiple of 16 + bytes, the initial padding on the first row may only be 8 bytes. + Compute the offset needed to the actual image data to a multiple of 16.*/ + align=-coffset&15; + ref_frame_sz=yplane_sz+2*cplane_sz+16; + ref_frame_data_sz=_nrefs*ref_frame_sz; + /*Check for overflow. + The same caveats apply as for oc_state_frarray_init().*/ + if(yplane_sz/yhstride!=(size_t)yheight||2*cplane_sz+16<cplane_sz|| + ref_frame_sz<yplane_sz||ref_frame_data_sz/_nrefs!=ref_frame_sz){ + return TH_EIMPL; + } + ref_frame_data=oc_aligned_malloc(ref_frame_data_sz,16); + frag_buf_offs=_state->frag_buf_offs= + _ogg_malloc(_state->nfrags*sizeof(*frag_buf_offs)); + if(ref_frame_data==NULL||frag_buf_offs==NULL){ + _ogg_free(frag_buf_offs); + oc_aligned_free(ref_frame_data); + return TH_EFAULT; + } + /*Set up the width, height and stride for the image buffers.*/ + _state->ref_frame_bufs[0][0].width=info->frame_width; + _state->ref_frame_bufs[0][0].height=info->frame_height; + _state->ref_frame_bufs[0][0].stride=yhstride; + _state->ref_frame_bufs[0][1].width=_state->ref_frame_bufs[0][2].width= + info->frame_width>>hdec; + _state->ref_frame_bufs[0][1].height=_state->ref_frame_bufs[0][2].height= + info->frame_height>>vdec; + _state->ref_frame_bufs[0][1].stride=_state->ref_frame_bufs[0][2].stride= + chstride; + for(rfi=1;rfi<_nrefs;rfi++){ + memcpy(_state->ref_frame_bufs[rfi],_state->ref_frame_bufs[0], + sizeof(_state->ref_frame_bufs[0])); + } + _state->ref_frame_handle=ref_frame_data; + /*Set up the data pointers for the image buffers.*/ + for(rfi=0;rfi<_nrefs;rfi++){ + _state->ref_frame_bufs[rfi][0].data=ref_frame_data+yoffset; + ref_frame_data+=yplane_sz+align; + _state->ref_frame_bufs[rfi][1].data=ref_frame_data+coffset; + ref_frame_data+=cplane_sz; + _state->ref_frame_bufs[rfi][2].data=ref_frame_data+coffset; + ref_frame_data+=cplane_sz+(16-align); + /*Flip the buffer upside down. + This allows us to decode Theora's bottom-up frames in their natural + order, yet return a top-down buffer with a positive stride to the user.*/ + oc_ycbcr_buffer_flip(_state->ref_frame_bufs[rfi], + _state->ref_frame_bufs[rfi]); + } + _state->ref_ystride[0]=-yhstride; + _state->ref_ystride[1]=_state->ref_ystride[2]=-chstride; + /*Initialize the fragment buffer offsets.*/ + ref_frame_data=_state->ref_frame_bufs[0][0].data; + fragi=0; + for(pli=0;pli<3;pli++){ + th_img_plane *iplane; + oc_fragment_plane *fplane; + unsigned char *vpix; + ptrdiff_t stride; + ptrdiff_t vfragi_end; + int nhfrags; + iplane=_state->ref_frame_bufs[0]+pli; + fplane=_state->fplanes+pli; + vpix=iplane->data; + vfragi_end=fplane->froffset+fplane->nfrags; + nhfrags=fplane->nhfrags; + stride=iplane->stride; + while(fragi<vfragi_end){ + ptrdiff_t hfragi_end; + unsigned char *hpix; + hpix=vpix; + for(hfragi_end=fragi+nhfrags;fragi<hfragi_end;fragi++){ + frag_buf_offs[fragi]=hpix-ref_frame_data; + hpix+=8; + } + vpix+=stride<<3; + } + } + /*Initialize the reference frame pointers and indices.*/ + _state->ref_frame_idx[OC_FRAME_GOLD]= + _state->ref_frame_idx[OC_FRAME_PREV]= + _state->ref_frame_idx[OC_FRAME_GOLD_ORIG]= + _state->ref_frame_idx[OC_FRAME_PREV_ORIG]= + _state->ref_frame_idx[OC_FRAME_SELF]= + _state->ref_frame_idx[OC_FRAME_IO]=-1; + _state->ref_frame_data[OC_FRAME_GOLD]= + _state->ref_frame_data[OC_FRAME_PREV]= + _state->ref_frame_data[OC_FRAME_GOLD_ORIG]= + _state->ref_frame_data[OC_FRAME_PREV_ORIG]= + _state->ref_frame_data[OC_FRAME_SELF]= + _state->ref_frame_data[OC_FRAME_IO]=NULL; + return 0; +} + +static void oc_state_ref_bufs_clear(oc_theora_state *_state){ + _ogg_free(_state->frag_buf_offs); + oc_aligned_free(_state->ref_frame_handle); +} + + +void oc_state_accel_init_c(oc_theora_state *_state){ + _state->cpu_flags=0; +#if defined(OC_STATE_USE_VTABLE) + _state->opt_vtable.frag_copy=oc_frag_copy_c; + _state->opt_vtable.frag_copy_list=oc_frag_copy_list_c; + _state->opt_vtable.frag_recon_intra=oc_frag_recon_intra_c; + _state->opt_vtable.frag_recon_inter=oc_frag_recon_inter_c; + _state->opt_vtable.frag_recon_inter2=oc_frag_recon_inter2_c; + _state->opt_vtable.idct8x8=oc_idct8x8_c; + _state->opt_vtable.state_frag_recon=oc_state_frag_recon_c; + _state->opt_vtable.loop_filter_init=oc_loop_filter_init_c; + _state->opt_vtable.state_loop_filter_frag_rows= + oc_state_loop_filter_frag_rows_c; + _state->opt_vtable.restore_fpu=oc_restore_fpu_c; +#endif + _state->opt_data.dct_fzig_zag=OC_FZIG_ZAG; +} + + +int oc_state_init(oc_theora_state *_state,const th_info *_info,int _nrefs){ + int ret; + /*First validate the parameters.*/ + if(_info==NULL)return TH_EFAULT; + /*The width and height of the encoded frame must be multiples of 16. + They must also, when divided by 16, fit into a 16-bit unsigned integer. + The displayable frame offset coordinates must fit into an 8-bit unsigned + integer. + Note that the offset Y in the API is specified on the opposite side from + how it is specified in the bitstream, because the Y axis is flipped in + the bitstream. + The displayable frame must fit inside the encoded frame. + The color space must be one known by the encoder. + The framerate ratio must not contain a zero value.*/ + if((_info->frame_width&0xF)||(_info->frame_height&0xF)|| + _info->frame_width<=0||_info->frame_width>=0x100000|| + _info->frame_height<=0||_info->frame_height>=0x100000|| + _info->pic_x+_info->pic_width>_info->frame_width|| + _info->pic_y+_info->pic_height>_info->frame_height|| + _info->pic_x>255||_info->frame_height-_info->pic_height-_info->pic_y>255|| + /*Note: the following <0 comparisons may generate spurious warnings on + platforms where enums are unsigned. + We could cast them to unsigned and just use the following >= comparison, + but there are a number of compilers which will mis-optimize this. + It's better to live with the spurious warnings.*/ + _info->colorspace<0||_info->colorspace>=TH_CS_NSPACES|| + _info->pixel_fmt<0||_info->pixel_fmt>=TH_PF_NFORMATS|| + _info->fps_numerator<1||_info->fps_denominator<1){ + return TH_EINVAL; + } + memset(_state,0,sizeof(*_state)); + memcpy(&_state->info,_info,sizeof(*_info)); + /*Invert the sense of pic_y to match Theora's right-handed coordinate + system.*/ + _state->info.pic_y=_info->frame_height-_info->pic_height-_info->pic_y; + _state->frame_type=OC_UNKWN_FRAME; + oc_state_accel_init(_state); + ret=oc_state_frarray_init(_state); + if(ret>=0)ret=oc_state_ref_bufs_init(_state,_nrefs); + if(ret<0){ + oc_state_frarray_clear(_state); + return ret; + } + /*If the keyframe_granule_shift is out of range, use the maximum allowable + value.*/ + if(_info->keyframe_granule_shift<0||_info->keyframe_granule_shift>31){ + _state->info.keyframe_granule_shift=31; + } + _state->keyframe_num=0; + _state->curframe_num=-1; + /*3.2.0 streams mark the frame index instead of the frame count. + This was changed with stream version 3.2.1 to conform to other Ogg + codecs. + We add an extra bias when computing granule positions for new streams.*/ + _state->granpos_bias=TH_VERSION_CHECK(_info,3,2,1); + return 0; +} + +void oc_state_clear(oc_theora_state *_state){ + oc_state_ref_bufs_clear(_state); + oc_state_frarray_clear(_state); +} + + +/*Duplicates the pixels on the border of the image plane out into the + surrounding padding for use by unrestricted motion vectors. + This function only adds the left and right borders, and only for the fragment + rows specified. + _refi: The index of the reference buffer to pad. + _pli: The color plane. + _y0: The Y coordinate of the first row to pad. + _yend: The Y coordinate of the row to stop padding at.*/ +void oc_state_borders_fill_rows(oc_theora_state *_state,int _refi,int _pli, + int _y0,int _yend){ + th_img_plane *iplane; + unsigned char *apix; + unsigned char *bpix; + unsigned char *epix; + int stride; + int hpadding; + hpadding=OC_UMV_PADDING>>(_pli!=0&&!(_state->info.pixel_fmt&1)); + iplane=_state->ref_frame_bufs[_refi]+_pli; + stride=iplane->stride; + apix=iplane->data+_y0*(ptrdiff_t)stride; + bpix=apix+iplane->width-1; + epix=iplane->data+_yend*(ptrdiff_t)stride; + /*Note the use of != instead of <, which allows the stride to be negative.*/ + while(apix!=epix){ + memset(apix-hpadding,apix[0],hpadding); + memset(bpix+1,bpix[0],hpadding); + apix+=stride; + bpix+=stride; + } +} + +/*Duplicates the pixels on the border of the image plane out into the + surrounding padding for use by unrestricted motion vectors. + This function only adds the top and bottom borders, and must be called after + the left and right borders are added. + _refi: The index of the reference buffer to pad. + _pli: The color plane.*/ +void oc_state_borders_fill_caps(oc_theora_state *_state,int _refi,int _pli){ + th_img_plane *iplane; + unsigned char *apix; + unsigned char *bpix; + unsigned char *epix; + int stride; + int hpadding; + int vpadding; + int fullw; + hpadding=OC_UMV_PADDING>>(_pli!=0&&!(_state->info.pixel_fmt&1)); + vpadding=OC_UMV_PADDING>>(_pli!=0&&!(_state->info.pixel_fmt&2)); + iplane=_state->ref_frame_bufs[_refi]+_pli; + stride=iplane->stride; + fullw=iplane->width+(hpadding<<1); + apix=iplane->data-hpadding; + bpix=iplane->data+(iplane->height-1)*(ptrdiff_t)stride-hpadding; + epix=apix-stride*(ptrdiff_t)vpadding; + while(apix!=epix){ + memcpy(apix-stride,apix,fullw); + memcpy(bpix+stride,bpix,fullw); + apix-=stride; + bpix+=stride; + } +} + +/*Duplicates the pixels on the border of the given reference image out into + the surrounding padding for use by unrestricted motion vectors. + _state: The context containing the reference buffers. + _refi: The index of the reference buffer to pad.*/ +void oc_state_borders_fill(oc_theora_state *_state,int _refi){ + int pli; + for(pli=0;pli<3;pli++){ + oc_state_borders_fill_rows(_state,_refi,pli,0, + _state->ref_frame_bufs[_refi][pli].height); + oc_state_borders_fill_caps(_state,_refi,pli); + } +} + +/*Determines the offsets in an image buffer to use for motion compensation. + _state: The Theora state the offsets are to be computed with. + _offsets: Returns the offset for the buffer(s). + _offsets[0] is always set. + _offsets[1] is set if the motion vector has non-zero fractional + components. + _pli: The color plane index. + _mv: The motion vector. + Return: The number of offsets returned: 1 or 2.*/ +int oc_state_get_mv_offsets(const oc_theora_state *_state,int _offsets[2], + int _pli,oc_mv _mv){ + /*Here is a brief description of how Theora handles motion vectors: + Motion vector components are specified to half-pixel accuracy in + undecimated directions of each plane, and quarter-pixel accuracy in + decimated directions. + Integer parts are extracted by dividing (not shifting) by the + appropriate amount, with truncation towards zero. + These integer values are used to calculate the first offset. + + If either of the fractional parts are non-zero, then a second offset is + computed. + No third or fourth offsets are computed, even if both components have + non-zero fractional parts. + The second offset is computed by dividing (not shifting) by the + appropriate amount, always truncating _away_ from zero.*/ +#if 0 + /*This version of the code doesn't use any tables, but is slower.*/ + int ystride; + int xprec; + int yprec; + int xfrac; + int yfrac; + int offs; + int dx; + int dy; + ystride=_state->ref_ystride[_pli]; + /*These two variables decide whether we are in half- or quarter-pixel + precision in each component.*/ + xprec=1+(_pli!=0&&!(_state->info.pixel_fmt&1)); + yprec=1+(_pli!=0&&!(_state->info.pixel_fmt&2)); + dx=OC_MV_X(_mv); + dy=OC_MV_Y(_mv); + /*These two variables are either 0 if all the fractional bits are zero or -1 + if any of them are non-zero.*/ + xfrac=OC_SIGNMASK(-(dx&(xprec|1))); + yfrac=OC_SIGNMASK(-(dy&(yprec|1))); + offs=(dx>>xprec)+(dy>>yprec)*ystride; + if(xfrac||yfrac){ + int xmask; + int ymask; + xmask=OC_SIGNMASK(dx); + ymask=OC_SIGNMASK(dy); + yfrac&=ystride; + _offsets[0]=offs-(xfrac&xmask)+(yfrac&ymask); + _offsets[1]=offs-(xfrac&~xmask)+(yfrac&~ymask); + return 2; + } + else{ + _offsets[0]=offs; + return 1; + } +#else + /*Using tables simplifies the code, and there's enough arithmetic to hide the + latencies of the memory references.*/ + static const signed char OC_MVMAP[2][64]={ + { + -15,-15,-14,-14,-13,-13,-12,-12,-11,-11,-10,-10, -9, -9, -8, + -8, -7, -7, -6, -6, -5, -5, -4, -4, -3, -3, -2, -2, -1, -1, 0, + 0, 0, 1, 1, 2, 2, 3, 3, 4, 4, 5, 5, 6, 6, 7, 7, + 8, 8, 9, 9, 10, 10, 11, 11, 12, 12, 13, 13, 14, 14, 15, 15 + }, + { + -7, -7, -7, -7, -6, -6, -6, -6, -5, -5, -5, -5, -4, -4, -4, + -4, -3, -3, -3, -3, -2, -2, -2, -2, -1, -1, -1, -1, 0, 0, 0, + 0, 0, 0, 0, 1, 1, 1, 1, 2, 2, 2, 2, 3, 3, 3, 3, + 4, 4, 4, 4, 5, 5, 5, 5, 6, 6, 6, 6, 7, 7, 7, 7 + } + }; + static const signed char OC_MVMAP2[2][64]={ + { + -1, 0,-1, 0,-1, 0,-1, 0,-1, 0,-1, 0,-1, 0,-1, + 0,-1, 0,-1, 0,-1, 0,-1, 0,-1, 0,-1, 0,-1, 0,-1, + 0, 1, 0, 1, 0, 1, 0, 1, 0, 1, 0, 1, 0, 1, 0, 1, + 0, 1, 0, 1, 0, 1, 0, 1, 0, 1, 0, 1, 0, 1, 0, 1 + }, + { + -1,-1,-1, 0,-1,-1,-1, 0,-1,-1,-1, 0,-1,-1,-1, + 0,-1,-1,-1, 0,-1,-1,-1, 0,-1,-1,-1, 0,-1,-1,-1, + 0, 1, 1, 1, 0, 1, 1, 1, 0, 1, 1, 1, 0, 1, 1, 1, + 0, 1, 1, 1, 0, 1, 1, 1, 0, 1, 1, 1, 0, 1, 1, 1 + } + }; + int ystride; + int qpx; + int qpy; + int mx; + int my; + int mx2; + int my2; + int offs; + int dx; + int dy; + ystride=_state->ref_ystride[_pli]; + qpy=_pli!=0&&!(_state->info.pixel_fmt&2); + dx=OC_MV_X(_mv); + dy=OC_MV_Y(_mv); + my=OC_MVMAP[qpy][dy+31]; + my2=OC_MVMAP2[qpy][dy+31]; + qpx=_pli!=0&&!(_state->info.pixel_fmt&1); + mx=OC_MVMAP[qpx][dx+31]; + mx2=OC_MVMAP2[qpx][dx+31]; + offs=my*ystride+mx; + if(mx2||my2){ + _offsets[1]=offs+my2*ystride+mx2; + _offsets[0]=offs; + return 2; + } + _offsets[0]=offs; + return 1; +#endif +} + +void oc_state_frag_recon_c(const oc_theora_state *_state,ptrdiff_t _fragi, + int _pli,ogg_int16_t _dct_coeffs[128],int _last_zzi,ogg_uint16_t _dc_quant){ + unsigned char *dst; + ptrdiff_t frag_buf_off; + int ystride; + int refi; + /*Apply the inverse transform.*/ + /*Special case only having a DC component.*/ + if(_last_zzi<2){ + ogg_int16_t p; + int ci; + /*We round this dequant product (and not any of the others) because there's + no iDCT rounding.*/ + p=(ogg_int16_t)(_dct_coeffs[0]*(ogg_int32_t)_dc_quant+15>>5); + /*LOOP VECTORIZES.*/ + for(ci=0;ci<64;ci++)_dct_coeffs[64+ci]=p; + } + else{ + /*First, dequantize the DC coefficient.*/ + _dct_coeffs[0]=(ogg_int16_t)(_dct_coeffs[0]*(int)_dc_quant); + oc_idct8x8(_state,_dct_coeffs+64,_dct_coeffs,_last_zzi); + } + /*Fill in the target buffer.*/ + frag_buf_off=_state->frag_buf_offs[_fragi]; + refi=_state->frags[_fragi].refi; + ystride=_state->ref_ystride[_pli]; + dst=_state->ref_frame_data[OC_FRAME_SELF]+frag_buf_off; + if(refi==OC_FRAME_SELF)oc_frag_recon_intra(_state,dst,ystride,_dct_coeffs+64); + else{ + const unsigned char *ref; + int mvoffsets[2]; + ref=_state->ref_frame_data[refi]+frag_buf_off; + if(oc_state_get_mv_offsets(_state,mvoffsets,_pli, + _state->frag_mvs[_fragi])>1){ + oc_frag_recon_inter2(_state, + dst,ref+mvoffsets[0],ref+mvoffsets[1],ystride,_dct_coeffs+64); + } + else{ + oc_frag_recon_inter(_state,dst,ref+mvoffsets[0],ystride,_dct_coeffs+64); + } + } +} + +static void loop_filter_h(unsigned char *_pix,int _ystride,signed char *_bv){ + int y; + _pix-=2; + for(y=0;y<8;y++){ + int f; + f=_pix[0]-_pix[3]+3*(_pix[2]-_pix[1]); + /*The _bv array is used to compute the function + f=OC_CLAMPI(OC_MINI(-_2flimit-f,0),f,OC_MAXI(_2flimit-f,0)); + where _2flimit=_state->loop_filter_limits[_state->qis[0]]<<1;*/ + f=*(_bv+(f+4>>3)); + _pix[1]=OC_CLAMP255(_pix[1]+f); + _pix[2]=OC_CLAMP255(_pix[2]-f); + _pix+=_ystride; + } +} + +static void loop_filter_v(unsigned char *_pix,int _ystride,signed char *_bv){ + int x; + _pix-=_ystride*2; + for(x=0;x<8;x++){ + int f; + f=_pix[x]-_pix[_ystride*3+x]+3*(_pix[_ystride*2+x]-_pix[_ystride+x]); + /*The _bv array is used to compute the function + f=OC_CLAMPI(OC_MINI(-_2flimit-f,0),f,OC_MAXI(_2flimit-f,0)); + where _2flimit=_state->loop_filter_limits[_state->qis[0]]<<1;*/ + f=*(_bv+(f+4>>3)); + _pix[_ystride+x]=OC_CLAMP255(_pix[_ystride+x]+f); + _pix[_ystride*2+x]=OC_CLAMP255(_pix[_ystride*2+x]-f); + } +} + +/*Initialize the bounding values array used by the loop filter. + _bv: Storage for the array. + _flimit: The filter limit as defined in Section 7.10 of the spec.*/ +void oc_loop_filter_init_c(signed char _bv[256],int _flimit){ + int i; + memset(_bv,0,sizeof(_bv[0])*256); + for(i=0;i<_flimit;i++){ + if(127-i-_flimit>=0)_bv[127-i-_flimit]=(signed char)(i-_flimit); + _bv[127-i]=(signed char)(-i); + _bv[127+i]=(signed char)(i); + if(127+i+_flimit<256)_bv[127+i+_flimit]=(signed char)(_flimit-i); + } +} + +/*Apply the loop filter to a given set of fragment rows in the given plane. + The filter may be run on the bottom edge, affecting pixels in the next row of + fragments, so this row also needs to be available. + _bv: The bounding values array. + _refi: The index of the frame buffer to filter. + _pli: The color plane to filter. + _fragy0: The Y coordinate of the first fragment row to filter. + _fragy_end: The Y coordinate of the fragment row to stop filtering at.*/ +void oc_state_loop_filter_frag_rows_c(const oc_theora_state *_state, + signed char *_bv,int _refi,int _pli,int _fragy0,int _fragy_end){ + const oc_fragment_plane *fplane; + const oc_fragment *frags; + const ptrdiff_t *frag_buf_offs; + unsigned char *ref_frame_data; + ptrdiff_t fragi_top; + ptrdiff_t fragi_bot; + ptrdiff_t fragi0; + ptrdiff_t fragi0_end; + int ystride; + int nhfrags; + _bv+=127; + fplane=_state->fplanes+_pli; + nhfrags=fplane->nhfrags; + fragi_top=fplane->froffset; + fragi_bot=fragi_top+fplane->nfrags; + fragi0=fragi_top+_fragy0*(ptrdiff_t)nhfrags; + fragi0_end=fragi_top+_fragy_end*(ptrdiff_t)nhfrags; + ystride=_state->ref_ystride[_pli]; + frags=_state->frags; + frag_buf_offs=_state->frag_buf_offs; + ref_frame_data=_state->ref_frame_data[_refi]; + /*The following loops are constructed somewhat non-intuitively on purpose. + The main idea is: if a block boundary has at least one coded fragment on + it, the filter is applied to it. + However, the order that the filters are applied in matters, and VP3 chose + the somewhat strange ordering used below.*/ + while(fragi0<fragi0_end){ + ptrdiff_t fragi; + ptrdiff_t fragi_end; + fragi=fragi0; + fragi_end=fragi+nhfrags; + while(fragi<fragi_end){ + if(frags[fragi].coded){ + unsigned char *ref; + ref=ref_frame_data+frag_buf_offs[fragi]; + if(fragi>fragi0)loop_filter_h(ref,ystride,_bv); + if(fragi0>fragi_top)loop_filter_v(ref,ystride,_bv); + if(fragi+1<fragi_end&&!frags[fragi+1].coded){ + loop_filter_h(ref+8,ystride,_bv); + } + if(fragi+nhfrags<fragi_bot&&!frags[fragi+nhfrags].coded){ + loop_filter_v(ref+(ystride<<3),ystride,_bv); + } + } + fragi++; + } + fragi0+=nhfrags; + } +} + +#if defined(OC_DUMP_IMAGES) +int oc_state_dump_frame(const oc_theora_state *_state,int _frame, + const char *_suf){ + /*Dump a PNG of the reconstructed image.*/ + png_structp png; + png_infop info; + png_bytep *image; + FILE *fp; + char fname[16]; + unsigned char *y_row; + unsigned char *u_row; + unsigned char *v_row; + unsigned char *y; + unsigned char *u; + unsigned char *v; + ogg_int64_t iframe; + ogg_int64_t pframe; + int y_stride; + int u_stride; + int v_stride; + int framei; + int width; + int height; + int imgi; + int imgj; + width=_state->info.frame_width; + height=_state->info.frame_height; + iframe=_state->granpos>>_state->info.keyframe_granule_shift; + pframe=_state->granpos-(iframe<<_state->info.keyframe_granule_shift); + sprintf(fname,"%08i%s.png",(int)(iframe+pframe),_suf); + fp=fopen(fname,"wb"); + if(fp==NULL)return TH_EFAULT; + image=(png_bytep *)oc_malloc_2d(height,6*width,sizeof(**image)); + if(image==NULL){ + fclose(fp); + return TH_EFAULT; + } + png=png_create_write_struct(PNG_LIBPNG_VER_STRING,NULL,NULL,NULL); + if(png==NULL){ + oc_free_2d(image); + fclose(fp); + return TH_EFAULT; + } + info=png_create_info_struct(png); + if(info==NULL){ + png_destroy_write_struct(&png,NULL); + oc_free_2d(image); + fclose(fp); + return TH_EFAULT; + } + if(setjmp(png_jmpbuf(png))){ + png_destroy_write_struct(&png,&info); + oc_free_2d(image); + fclose(fp); + return TH_EFAULT; + } + framei=_state->ref_frame_idx[_frame]; + y_row=_state->ref_frame_bufs[framei][0].data; + u_row=_state->ref_frame_bufs[framei][1].data; + v_row=_state->ref_frame_bufs[framei][2].data; + y_stride=_state->ref_frame_bufs[framei][0].stride; + u_stride=_state->ref_frame_bufs[framei][1].stride; + v_stride=_state->ref_frame_bufs[framei][2].stride; + /*Chroma up-sampling is just done with a box filter. + This is very likely what will actually be used in practice on a real + display, and also removes one more layer to search in for the source of + artifacts. + As an added bonus, it's dead simple.*/ + for(imgi=height;imgi-->0;){ + int dc; + y=y_row; + u=u_row; + v=v_row; + for(imgj=0;imgj<6*width;){ + float yval; + float uval; + float vval; + unsigned rval; + unsigned gval; + unsigned bval; + /*This is intentionally slow and very accurate.*/ + yval=(*y-16)*(1.0F/219); + uval=(*u-128)*(2*(1-0.114F)/224); + vval=(*v-128)*(2*(1-0.299F)/224); + rval=OC_CLAMPI(0,(int)(65535*(yval+vval)+0.5F),65535); + gval=OC_CLAMPI(0,(int)(65535*( + yval-uval*(0.114F/0.587F)-vval*(0.299F/0.587F))+0.5F),65535); + bval=OC_CLAMPI(0,(int)(65535*(yval+uval)+0.5F),65535); + image[imgi][imgj++]=(unsigned char)(rval>>8); + image[imgi][imgj++]=(unsigned char)(rval&0xFF); + image[imgi][imgj++]=(unsigned char)(gval>>8); + image[imgi][imgj++]=(unsigned char)(gval&0xFF); + image[imgi][imgj++]=(unsigned char)(bval>>8); + image[imgi][imgj++]=(unsigned char)(bval&0xFF); + dc=(y-y_row&1)|(_state->info.pixel_fmt&1); + y++; + u+=dc; + v+=dc; + } + dc=-((height-1-imgi&1)|_state->info.pixel_fmt>>1); + y_row+=y_stride; + u_row+=dc&u_stride; + v_row+=dc&v_stride; + } + png_init_io(png,fp); + png_set_compression_level(png,Z_BEST_COMPRESSION); + png_set_IHDR(png,info,width,height,16,PNG_COLOR_TYPE_RGB, + PNG_INTERLACE_NONE,PNG_COMPRESSION_TYPE_DEFAULT,PNG_FILTER_TYPE_DEFAULT); + switch(_state->info.colorspace){ + case TH_CS_ITU_REC_470M:{ + png_set_gAMA(png,info,2.2); + png_set_cHRM_fixed(png,info,31006,31616, + 67000,32000,21000,71000,14000,8000); + }break; + case TH_CS_ITU_REC_470BG:{ + png_set_gAMA(png,info,2.67); + png_set_cHRM_fixed(png,info,31271,32902, + 64000,33000,29000,60000,15000,6000); + }break; + default:break; + } + png_set_pHYs(png,info,_state->info.aspect_numerator, + _state->info.aspect_denominator,0); + png_set_rows(png,info,image); + png_write_png(png,info,PNG_TRANSFORM_IDENTITY,NULL); + png_write_end(png,info); + png_destroy_write_struct(&png,&info); + oc_free_2d(image); + fclose(fp); + return 0; +} +#endif + + + +ogg_int64_t th_granule_frame(void *_encdec,ogg_int64_t _granpos){ + oc_theora_state *state; + state=(oc_theora_state *)_encdec; + if(_granpos>=0){ + ogg_int64_t iframe; + ogg_int64_t pframe; + iframe=_granpos>>state->info.keyframe_granule_shift; + pframe=_granpos-(iframe<<state->info.keyframe_granule_shift); + /*3.2.0 streams store the frame index in the granule position. + 3.2.1 and later store the frame count. + We return the index, so adjust the value if we have a 3.2.1 or later + stream.*/ + return iframe+pframe-TH_VERSION_CHECK(&state->info,3,2,1); + } + return -1; +} + +double th_granule_time(void *_encdec,ogg_int64_t _granpos){ + oc_theora_state *state; + state=(oc_theora_state *)_encdec; + if(_granpos>=0){ + return (th_granule_frame(_encdec, _granpos)+1)*( + (double)state->info.fps_denominator/state->info.fps_numerator); + } + return -1; +} diff --git a/media/libtheora/lib/state.h b/media/libtheora/lib/state.h new file mode 100644 index 0000000000..f176a53ce9 --- /dev/null +++ b/media/libtheora/lib/state.h @@ -0,0 +1,552 @@ +/******************************************************************** + * * + * THIS FILE IS PART OF THE OggTheora SOFTWARE CODEC SOURCE CODE. * + * USE, DISTRIBUTION AND REPRODUCTION OF THIS LIBRARY SOURCE IS * + * GOVERNED BY A BSD-STYLE SOURCE LICENSE INCLUDED WITH THIS SOURCE * + * IN 'COPYING'. PLEASE READ THESE TERMS BEFORE DISTRIBUTING. * + * * + * THE Theora SOURCE CODE IS COPYRIGHT (C) 2002-2009 * + * by the Xiph.Org Foundation and contributors http://www.xiph.org/ * + * * + ******************************************************************** + + function: + last mod: $Id: internal.h 17337 2010-07-19 16:08:54Z tterribe $ + + ********************************************************************/ +#if !defined(_state_H) +# define _state_H (1) +# include "internal.h" +# include "huffman.h" +# include "quant.h" + + + +/*A single quadrant of the map from a super block to fragment numbers.*/ +typedef ptrdiff_t oc_sb_map_quad[4]; +/*A map from a super block to fragment numbers.*/ +typedef oc_sb_map_quad oc_sb_map[4]; +/*A single plane of the map from a macro block to fragment numbers.*/ +typedef ptrdiff_t oc_mb_map_plane[4]; +/*A map from a macro block to fragment numbers.*/ +typedef oc_mb_map_plane oc_mb_map[3]; +/*A motion vector.*/ +typedef ogg_int16_t oc_mv; + +typedef struct oc_sb_flags oc_sb_flags; +typedef struct oc_border_info oc_border_info; +typedef struct oc_fragment oc_fragment; +typedef struct oc_fragment_plane oc_fragment_plane; +typedef struct oc_base_opt_vtable oc_base_opt_vtable; +typedef struct oc_base_opt_data oc_base_opt_data; +typedef struct oc_state_dispatch_vtable oc_state_dispatch_vtable; +typedef struct oc_theora_state oc_theora_state; + + + +/*Shared accelerated functions.*/ +# if defined(OC_X86_ASM) +# if defined(_MSC_VER) +# include "x86_vc/x86int.h" +# else +# include "x86/x86int.h" +# endif +# endif +# if defined(OC_ARM_ASM) +# include "arm/armint.h" +# endif +# if defined(OC_C64X_ASM) +# include "c64x/c64xint.h" +# endif + +# if !defined(oc_state_accel_init) +# define oc_state_accel_init oc_state_accel_init_c +# endif +# if defined(OC_STATE_USE_VTABLE) +# if !defined(oc_frag_copy) +# define oc_frag_copy(_state,_dst,_src,_ystride) \ + ((*(_state)->opt_vtable.frag_copy)(_dst,_src,_ystride)) +# endif +# if !defined(oc_frag_copy_list) +# define oc_frag_copy_list(_state,_dst_frame,_src_frame,_ystride, \ + _fragis,_nfragis,_frag_buf_offs) \ + ((*(_state)->opt_vtable.frag_copy_list)(_dst_frame,_src_frame,_ystride, \ + _fragis,_nfragis,_frag_buf_offs)) +# endif +# if !defined(oc_frag_recon_intra) +# define oc_frag_recon_intra(_state,_dst,_dst_ystride,_residue) \ + ((*(_state)->opt_vtable.frag_recon_intra)(_dst,_dst_ystride,_residue)) +# endif +# if !defined(oc_frag_recon_inter) +# define oc_frag_recon_inter(_state,_dst,_src,_ystride,_residue) \ + ((*(_state)->opt_vtable.frag_recon_inter)(_dst,_src,_ystride,_residue)) +# endif +# if !defined(oc_frag_recon_inter2) +# define oc_frag_recon_inter2(_state,_dst,_src1,_src2,_ystride,_residue) \ + ((*(_state)->opt_vtable.frag_recon_inter2)(_dst, \ + _src1,_src2,_ystride,_residue)) +# endif +# if !defined(oc_idct8x8) +# define oc_idct8x8(_state,_y,_x,_last_zzi) \ + ((*(_state)->opt_vtable.idct8x8)(_y,_x,_last_zzi)) +# endif +# if !defined(oc_state_frag_recon) +# define oc_state_frag_recon(_state,_fragi, \ + _pli,_dct_coeffs,_last_zzi,_dc_quant) \ + ((*(_state)->opt_vtable.state_frag_recon)(_state,_fragi, \ + _pli,_dct_coeffs,_last_zzi,_dc_quant)) +# endif +# if !defined(oc_loop_filter_init) +# define oc_loop_filter_init(_state,_bv,_flimit) \ + ((*(_state)->opt_vtable.loop_filter_init)(_bv,_flimit)) +# endif +# if !defined(oc_state_loop_filter_frag_rows) +# define oc_state_loop_filter_frag_rows(_state, \ + _bv,_refi,_pli,_fragy0,_fragy_end) \ + ((*(_state)->opt_vtable.state_loop_filter_frag_rows)(_state, \ + _bv,_refi,_pli,_fragy0,_fragy_end)) +# endif +# if !defined(oc_restore_fpu) +# define oc_restore_fpu(_state) \ + ((*(_state)->opt_vtable.restore_fpu)()) +# endif +# else +# if !defined(oc_frag_copy) +# define oc_frag_copy(_state,_dst,_src,_ystride) \ + oc_frag_copy_c(_dst,_src,_ystride) +# endif +# if !defined(oc_frag_copy_list) +# define oc_frag_copy_list(_state,_dst_frame,_src_frame,_ystride, \ + _fragis,_nfragis,_frag_buf_offs) \ + oc_frag_copy_list_c(_dst_frame,_src_frame,_ystride, \ + _fragis,_nfragis,_frag_buf_offs) +# endif +# if !defined(oc_frag_recon_intra) +# define oc_frag_recon_intra(_state,_dst,_dst_ystride,_residue) \ + oc_frag_recon_intra_c(_dst,_dst_ystride,_residue) +# endif +# if !defined(oc_frag_recon_inter) +# define oc_frag_recon_inter(_state,_dst,_src,_ystride,_residue) \ + oc_frag_recon_inter_c(_dst,_src,_ystride,_residue) +# endif +# if !defined(oc_frag_recon_inter2) +# define oc_frag_recon_inter2(_state,_dst,_src1,_src2,_ystride,_residue) \ + oc_frag_recon_inter2_c(_dst,_src1,_src2,_ystride,_residue) +# endif +# if !defined(oc_idct8x8) +# define oc_idct8x8(_state,_y,_x,_last_zzi) oc_idct8x8_c(_y,_x,_last_zzi) +# endif +# if !defined(oc_state_frag_recon) +# define oc_state_frag_recon oc_state_frag_recon_c +# endif +# if !defined(oc_loop_filter_init) +# define oc_loop_filter_init(_state,_bv,_flimit) \ + oc_loop_filter_init_c(_bv,_flimit) +# endif +# if !defined(oc_state_loop_filter_frag_rows) +# define oc_state_loop_filter_frag_rows oc_state_loop_filter_frag_rows_c +# endif +# if !defined(oc_restore_fpu) +# define oc_restore_fpu(_state) do{}while(0) +# endif +# endif + + + +/*A keyframe.*/ +# define OC_INTRA_FRAME (0) +/*A predicted frame.*/ +# define OC_INTER_FRAME (1) +/*A frame of unknown type (frame type decision has not yet been made).*/ +# define OC_UNKWN_FRAME (-1) + +/*The amount of padding to add to the reconstructed frame buffers on all + sides. + This is used to allow unrestricted motion vectors without special casing. + This must be a multiple of 2.*/ +# define OC_UMV_PADDING (16) + +/*Frame classification indices.*/ +/*The previous golden frame.*/ +# define OC_FRAME_GOLD (0) +/*The previous frame.*/ +# define OC_FRAME_PREV (1) +/*The current frame.*/ +# define OC_FRAME_SELF (2) +/*Used to mark uncoded fragments (for DC prediction).*/ +# define OC_FRAME_NONE (3) + +/*The input or output buffer.*/ +# define OC_FRAME_IO (3) +/*Uncompressed prev golden frame.*/ +# define OC_FRAME_GOLD_ORIG (4) +/*Uncompressed previous frame. */ +# define OC_FRAME_PREV_ORIG (5) + +/*Macroblock modes.*/ +/*Macro block is invalid: It is never coded.*/ +# define OC_MODE_INVALID (-1) +/*Encoded difference from the same macro block in the previous frame.*/ +# define OC_MODE_INTER_NOMV (0) +/*Encoded with no motion compensated prediction.*/ +# define OC_MODE_INTRA (1) +/*Encoded difference from the previous frame offset by the given motion + vector.*/ +# define OC_MODE_INTER_MV (2) +/*Encoded difference from the previous frame offset by the last coded motion + vector.*/ +# define OC_MODE_INTER_MV_LAST (3) +/*Encoded difference from the previous frame offset by the second to last + coded motion vector.*/ +# define OC_MODE_INTER_MV_LAST2 (4) +/*Encoded difference from the same macro block in the previous golden + frame.*/ +# define OC_MODE_GOLDEN_NOMV (5) +/*Encoded difference from the previous golden frame offset by the given motion + vector.*/ +# define OC_MODE_GOLDEN_MV (6) +/*Encoded difference from the previous frame offset by the individual motion + vectors given for each block.*/ +# define OC_MODE_INTER_MV_FOUR (7) +/*The number of (coded) modes.*/ +# define OC_NMODES (8) + +/*Determines the reference frame used for a given MB mode.*/ +# define OC_FRAME_FOR_MODE(_x) \ + OC_UNIBBLE_TABLE32(OC_FRAME_PREV,OC_FRAME_SELF,OC_FRAME_PREV,OC_FRAME_PREV, \ + OC_FRAME_PREV,OC_FRAME_GOLD,OC_FRAME_GOLD,OC_FRAME_PREV,(_x)) + +/*Constants for the packet state machine common between encoder and decoder.*/ + +/*Next packet to emit/read: Codec info header.*/ +# define OC_PACKET_INFO_HDR (-3) +/*Next packet to emit/read: Comment header.*/ +# define OC_PACKET_COMMENT_HDR (-2) +/*Next packet to emit/read: Codec setup header.*/ +# define OC_PACKET_SETUP_HDR (-1) +/*No more packets to emit/read.*/ +# define OC_PACKET_DONE (INT_MAX) + + + +#define OC_MV(_x,_y) ((oc_mv)((_x)&0xFF|(_y)<<8)) +#define OC_MV_X(_mv) ((signed char)(_mv)) +#define OC_MV_Y(_mv) ((_mv)>>8) +#define OC_MV_ADD(_mv1,_mv2) \ + OC_MV(OC_MV_X(_mv1)+OC_MV_X(_mv2), \ + OC_MV_Y(_mv1)+OC_MV_Y(_mv2)) +#define OC_MV_SUB(_mv1,_mv2) \ + OC_MV(OC_MV_X(_mv1)-OC_MV_X(_mv2), \ + OC_MV_Y(_mv1)-OC_MV_Y(_mv2)) + + + +/*Super blocks are 32x32 segments of pixels in a single color plane indexed + in image order. + Internally, super blocks are broken up into four quadrants, each of which + contains a 2x2 pattern of blocks, each of which is an 8x8 block of pixels. + Quadrants, and the blocks within them, are indexed in a special order called + a "Hilbert curve" within the super block. + + In order to differentiate between the Hilbert-curve indexing strategy and + the regular image order indexing strategy, blocks indexed in image order + are called "fragments". + Fragments are indexed in image order, left to right, then bottom to top, + from Y' plane to Cb plane to Cr plane. + + The co-located fragments in all image planes corresponding to the location + of a single quadrant of a luma plane super block form a macro block. + Thus there is only a single set of macro blocks for all planes, each of which + contains between 6 and 12 fragments, depending on the pixel format. + Therefore macro block information is kept in a separate set of arrays from + super blocks to avoid unused space in the other planes. + The lists are indexed in super block order. + That is, the macro block corresponding to the macro block mbi in (luma plane) + super block sbi is at index (sbi<<2|mbi). + Thus the number of macro blocks in each dimension is always twice the number + of super blocks, even when only an odd number fall inside the coded frame. + These "extra" macro blocks are just an artifact of our internal data layout, + and not part of the coded stream; they are flagged with a negative MB mode.*/ + + + +/*Super block information.*/ +struct oc_sb_flags{ + unsigned char coded_fully:1; + unsigned char coded_partially:1; + unsigned char quad_valid:4; +}; + + + +/*Information about a fragment which intersects the border of the displayable + region. + This marks which pixels belong to the displayable region.*/ +struct oc_border_info{ + /*A bit mask marking which pixels are in the displayable region. + Pixel (x,y) corresponds to bit (y<<3|x).*/ + ogg_int64_t mask; + /*The number of pixels in the displayable region. + This is always positive, and always less than 64.*/ + int npixels; +}; + + + +/*Fragment information.*/ +struct oc_fragment{ + /*A flag indicating whether or not this fragment is coded.*/ + unsigned coded:1; + /*A flag indicating that this entire fragment lies outside the displayable + region of the frame. + Note the contrast with an invalid macro block, which is outside the coded + frame, not just the displayable one. + There are no fragments outside the coded frame by construction.*/ + unsigned invalid:1; + /*The index of the quality index used for this fragment's AC coefficients.*/ + unsigned qii:4; + /*The index of the reference frame this fragment is predicted from.*/ + unsigned refi:2; + /*The mode of the macroblock this fragment belongs to.*/ + unsigned mb_mode:3; + /*The index of the associated border information for fragments which lie + partially outside the displayable region. + For fragments completely inside or outside this region, this is -1. + Note that the C standard requires an explicit signed keyword for bitfield + types, since some compilers may treat them as unsigned without it.*/ + signed int borderi:5; + /*The prediction-corrected DC component. + Note that the C standard requires an explicit signed keyword for bitfield + types, since some compilers may treat them as unsigned without it.*/ + signed int dc:16; +}; + + + +/*A description of each fragment plane.*/ +struct oc_fragment_plane{ + /*The number of fragments in the horizontal direction.*/ + int nhfrags; + /*The number of fragments in the vertical direction.*/ + int nvfrags; + /*The offset of the first fragment in the plane.*/ + ptrdiff_t froffset; + /*The total number of fragments in the plane.*/ + ptrdiff_t nfrags; + /*The number of super blocks in the horizontal direction.*/ + unsigned nhsbs; + /*The number of super blocks in the vertical direction.*/ + unsigned nvsbs; + /*The offset of the first super block in the plane.*/ + unsigned sboffset; + /*The total number of super blocks in the plane.*/ + unsigned nsbs; +}; + + +typedef void (*oc_state_loop_filter_frag_rows_func)( + const oc_theora_state *_state,signed char _bv[256],int _refi,int _pli, + int _fragy0,int _fragy_end); + +/*The shared (encoder and decoder) functions that have accelerated variants.*/ +struct oc_base_opt_vtable{ + void (*frag_copy)(unsigned char *_dst, + const unsigned char *_src,int _ystride); + void (*frag_copy_list)(unsigned char *_dst_frame, + const unsigned char *_src_frame,int _ystride, + const ptrdiff_t *_fragis,ptrdiff_t _nfragis,const ptrdiff_t *_frag_buf_offs); + void (*frag_recon_intra)(unsigned char *_dst,int _ystride, + const ogg_int16_t _residue[64]); + void (*frag_recon_inter)(unsigned char *_dst, + const unsigned char *_src,int _ystride,const ogg_int16_t _residue[64]); + void (*frag_recon_inter2)(unsigned char *_dst,const unsigned char *_src1, + const unsigned char *_src2,int _ystride,const ogg_int16_t _residue[64]); + void (*idct8x8)(ogg_int16_t _y[64],ogg_int16_t _x[64],int _last_zzi); + void (*state_frag_recon)(const oc_theora_state *_state,ptrdiff_t _fragi, + int _pli,ogg_int16_t _dct_coeffs[128],int _last_zzi,ogg_uint16_t _dc_quant); + void (*loop_filter_init)(signed char _bv[256],int _flimit); + oc_state_loop_filter_frag_rows_func state_loop_filter_frag_rows; + void (*restore_fpu)(void); +}; + +/*The shared (encoder and decoder) tables that vary according to which variants + of the above functions are used.*/ +struct oc_base_opt_data{ + const unsigned char *dct_fzig_zag; +}; + + +/*State information common to both the encoder and decoder.*/ +struct oc_theora_state{ + /*The stream information.*/ + th_info info; +# if defined(OC_STATE_USE_VTABLE) + /*Table for shared accelerated functions.*/ + oc_base_opt_vtable opt_vtable; +# endif + /*Table for shared data used by accelerated functions.*/ + oc_base_opt_data opt_data; + /*CPU flags to detect the presence of extended instruction sets.*/ + ogg_uint32_t cpu_flags; + /*The fragment plane descriptions.*/ + oc_fragment_plane fplanes[3]; + /*The list of fragments, indexed in image order.*/ + oc_fragment *frags; + /*The the offset into the reference frame buffer to the upper-left pixel of + each fragment.*/ + ptrdiff_t *frag_buf_offs; + /*The motion vector for each fragment.*/ + oc_mv *frag_mvs; + /*The total number of fragments in a single frame.*/ + ptrdiff_t nfrags; + /*The list of super block maps, indexed in image order.*/ + oc_sb_map *sb_maps; + /*The list of super block flags, indexed in image order.*/ + oc_sb_flags *sb_flags; + /*The total number of super blocks in a single frame.*/ + unsigned nsbs; + /*The fragments from each color plane that belong to each macro block. + Fragments are stored in image order (left to right then top to bottom). + When chroma components are decimated, the extra fragments have an index of + -1.*/ + oc_mb_map *mb_maps; + /*The list of macro block modes. + A negative number indicates the macro block lies entirely outside the + coded frame.*/ + signed char *mb_modes; + /*The number of macro blocks in the X direction.*/ + unsigned nhmbs; + /*The number of macro blocks in the Y direction.*/ + unsigned nvmbs; + /*The total number of macro blocks.*/ + size_t nmbs; + /*The list of coded fragments, in coded order. + Uncoded fragments are stored in reverse order from the end of the list.*/ + ptrdiff_t *coded_fragis; + /*The number of coded fragments in each plane.*/ + ptrdiff_t ncoded_fragis[3]; + /*The total number of coded fragments.*/ + ptrdiff_t ntotal_coded_fragis; + /*The actual buffers used for the reference frames.*/ + th_ycbcr_buffer ref_frame_bufs[6]; + /*The index of the buffers being used for each OC_FRAME_* reference frame.*/ + int ref_frame_idx[6]; + /*The storage for the reference frame buffers. + This is just ref_frame_bufs[ref_frame_idx[i]][0].data, but is cached here + for faster look-up.*/ + unsigned char *ref_frame_data[6]; + /*The handle used to allocate the reference frame buffers.*/ + unsigned char *ref_frame_handle; + /*The strides for each plane in the reference frames.*/ + int ref_ystride[3]; + /*The number of unique border patterns.*/ + int nborders; + /*The unique border patterns for all border fragments. + The borderi field of fragments which straddle the border indexes this + list.*/ + oc_border_info borders[16]; + /*The frame number of the last keyframe.*/ + ogg_int64_t keyframe_num; + /*The frame number of the current frame.*/ + ogg_int64_t curframe_num; + /*The granpos of the current frame.*/ + ogg_int64_t granpos; + /*The type of the current frame.*/ + signed char frame_type; + /*The bias to add to the frame count when computing granule positions.*/ + unsigned char granpos_bias; + /*The number of quality indices used in the current frame.*/ + unsigned char nqis; + /*The quality indices of the current frame.*/ + unsigned char qis[3]; + /*The dequantization tables, stored in zig-zag order, and indexed by + qi, pli, qti, and zzi.*/ + ogg_uint16_t *dequant_tables[64][3][2]; + OC_ALIGN16(oc_quant_table dequant_table_data[64][3][2]); + /*Loop filter strength parameters.*/ + unsigned char loop_filter_limits[64]; +}; + + + +/*The function type used to fill in the chroma plane motion vectors for a + macro block when 4 different motion vectors are specified in the luma + plane. + _cbmvs: The chroma block-level motion vectors to fill in. + _lmbmv: The luma macro-block level motion vector to fill in for use in + prediction. + _lbmvs: The luma block-level motion vectors.*/ +typedef void (*oc_set_chroma_mvs_func)(oc_mv _cbmvs[4],const oc_mv _lbmvs[4]); + + + +/*A table of functions used to fill in the Cb,Cr plane motion vectors for a + macro block when 4 different motion vectors are specified in the luma + plane.*/ +extern const oc_set_chroma_mvs_func OC_SET_CHROMA_MVS_TABLE[TH_PF_NFORMATS]; + + + +int oc_state_init(oc_theora_state *_state,const th_info *_info,int _nrefs); +void oc_state_clear(oc_theora_state *_state); +void oc_state_accel_init_c(oc_theora_state *_state); +void oc_state_borders_fill_rows(oc_theora_state *_state,int _refi,int _pli, + int _y0,int _yend); +void oc_state_borders_fill_caps(oc_theora_state *_state,int _refi,int _pli); +void oc_state_borders_fill(oc_theora_state *_state,int _refi); +void oc_state_fill_buffer_ptrs(oc_theora_state *_state,int _buf_idx, + th_ycbcr_buffer _img); +int oc_state_mbi_for_pos(oc_theora_state *_state,int _mbx,int _mby); +int oc_state_get_mv_offsets(const oc_theora_state *_state,int _offsets[2], + int _pli,oc_mv _mv); + +void oc_loop_filter_init_c(signed char _bv[256],int _flimit); +void oc_state_loop_filter(oc_theora_state *_state,int _frame); +# if defined(OC_DUMP_IMAGES) +int oc_state_dump_frame(const oc_theora_state *_state,int _frame, + const char *_suf); +# endif + +/*Default pure-C implementations of shared accelerated functions.*/ +void oc_frag_copy_c(unsigned char *_dst, + const unsigned char *_src,int _src_ystride); +void oc_frag_copy_list_c(unsigned char *_dst_frame, + const unsigned char *_src_frame,int _ystride, + const ptrdiff_t *_fragis,ptrdiff_t _nfragis,const ptrdiff_t *_frag_buf_offs); +void oc_frag_recon_intra_c(unsigned char *_dst,int _dst_ystride, + const ogg_int16_t _residue[64]); +void oc_frag_recon_inter_c(unsigned char *_dst, + const unsigned char *_src,int _ystride,const ogg_int16_t _residue[64]); +void oc_frag_recon_inter2_c(unsigned char *_dst,const unsigned char *_src1, + const unsigned char *_src2,int _ystride,const ogg_int16_t _residue[64]); +void oc_idct8x8_c(ogg_int16_t _y[64],ogg_int16_t _x[64],int _last_zzi); +void oc_state_frag_recon_c(const oc_theora_state *_state,ptrdiff_t _fragi, + int _pli,ogg_int16_t _dct_coeffs[128],int _last_zzi,ogg_uint16_t _dc_quant); +void oc_state_loop_filter_frag_rows_c(const oc_theora_state *_state, + signed char _bv[256],int _refi,int _pli,int _fragy0,int _fragy_end); +void oc_restore_fpu_c(void); + +/*We need a way to call a few encoder functions without introducing a link-time + dependency into the decoder, while still allowing the old alpha API which + does not distinguish between encoder and decoder objects to be used. + We do this by placing a function table at the start of the encoder object + which can dispatch into the encoder library. + We do a similar thing for the decoder in case we ever decide to split off a + common base library.*/ +typedef void (*oc_state_clear_func)(theora_state *_th); +typedef int (*oc_state_control_func)(theora_state *th,int _req, + void *_buf,size_t _buf_sz); +typedef ogg_int64_t (*oc_state_granule_frame_func)(theora_state *_th, + ogg_int64_t _granulepos); +typedef double (*oc_state_granule_time_func)(theora_state *_th, + ogg_int64_t _granulepos); + + +struct oc_state_dispatch_vtable{ + oc_state_clear_func clear; + oc_state_control_func control; + oc_state_granule_frame_func granule_frame; + oc_state_granule_time_func granule_time; +}; + +#endif diff --git a/media/libtheora/lib/x86/mmxfrag.c b/media/libtheora/lib/x86/mmxfrag.c new file mode 100644 index 0000000000..b3ec508956 --- /dev/null +++ b/media/libtheora/lib/x86/mmxfrag.c @@ -0,0 +1,368 @@ +/******************************************************************** + * * + * THIS FILE IS PART OF THE OggTheora SOFTWARE CODEC SOURCE CODE. * + * USE, DISTRIBUTION AND REPRODUCTION OF THIS LIBRARY SOURCE IS * + * GOVERNED BY A BSD-STYLE SOURCE LICENSE INCLUDED WITH THIS SOURCE * + * IN 'COPYING'. PLEASE READ THESE TERMS BEFORE DISTRIBUTING. * + * * + * THE Theora SOURCE CODE IS COPYRIGHT (C) 2002-2009 * + * by the Xiph.Org Foundation and contributors http://www.xiph.org/ * + * * + ******************************************************************** + + function: + last mod: $Id$ + + ********************************************************************/ + +/*MMX acceleration of fragment reconstruction for motion compensation. + Originally written by Rudolf Marek. + Additional optimization by Nils Pipenbrinck. + Note: Loops are unrolled for best performance. + The iteration each instruction belongs to is marked in the comments as #i.*/ +#include <stddef.h> +#include "x86int.h" + +#if defined(OC_X86_ASM) + +/*Copies an 8x8 block of pixels from _src to _dst, assuming _ystride bytes + between rows.*/ +# define OC_FRAG_COPY_MMX(_dst,_src,_ystride) \ + do{ \ + const unsigned char *src; \ + unsigned char *dst; \ + ptrdiff_t ystride3; \ + src=(_src); \ + dst=(_dst); \ + __asm__ __volatile__( \ + /*src+0*ystride*/ \ + "movq (%[src]),%%mm0\n\t" \ + /*src+1*ystride*/ \ + "movq (%[src],%[ystride]),%%mm1\n\t" \ + /*ystride3=ystride*3*/ \ + "lea (%[ystride],%[ystride],2),%[ystride3]\n\t" \ + /*src+2*ystride*/ \ + "movq (%[src],%[ystride],2),%%mm2\n\t" \ + /*src+3*ystride*/ \ + "movq (%[src],%[ystride3]),%%mm3\n\t" \ + /*dst+0*ystride*/ \ + "movq %%mm0,(%[dst])\n\t" \ + /*dst+1*ystride*/ \ + "movq %%mm1,(%[dst],%[ystride])\n\t" \ + /*Pointer to next 4.*/ \ + "lea (%[src],%[ystride],4),%[src]\n\t" \ + /*dst+2*ystride*/ \ + "movq %%mm2,(%[dst],%[ystride],2)\n\t" \ + /*dst+3*ystride*/ \ + "movq %%mm3,(%[dst],%[ystride3])\n\t" \ + /*Pointer to next 4.*/ \ + "lea (%[dst],%[ystride],4),%[dst]\n\t" \ + /*src+0*ystride*/ \ + "movq (%[src]),%%mm0\n\t" \ + /*src+1*ystride*/ \ + "movq (%[src],%[ystride]),%%mm1\n\t" \ + /*src+2*ystride*/ \ + "movq (%[src],%[ystride],2),%%mm2\n\t" \ + /*src+3*ystride*/ \ + "movq (%[src],%[ystride3]),%%mm3\n\t" \ + /*dst+0*ystride*/ \ + "movq %%mm0,(%[dst])\n\t" \ + /*dst+1*ystride*/ \ + "movq %%mm1,(%[dst],%[ystride])\n\t" \ + /*dst+2*ystride*/ \ + "movq %%mm2,(%[dst],%[ystride],2)\n\t" \ + /*dst+3*ystride*/ \ + "movq %%mm3,(%[dst],%[ystride3])\n\t" \ + :[dst]"+r"(dst),[src]"+r"(src),[ystride3]"=&r"(ystride3) \ + :[ystride]"r"((ptrdiff_t)(_ystride)) \ + :"memory" \ + ); \ + } \ + while(0) + +/*Copies an 8x8 block of pixels from _src to _dst, assuming _ystride bytes + between rows.*/ +void oc_frag_copy_mmx(unsigned char *_dst, + const unsigned char *_src,int _ystride){ + OC_FRAG_COPY_MMX(_dst,_src,_ystride); +} + +/*Copies the fragments specified by the lists of fragment indices from one + frame to another. + _dst_frame: The reference frame to copy to. + _src_frame: The reference frame to copy from. + _ystride: The row stride of the reference frames. + _fragis: A pointer to a list of fragment indices. + _nfragis: The number of fragment indices to copy. + _frag_buf_offs: The offsets of fragments in the reference frames.*/ +void oc_frag_copy_list_mmx(unsigned char *_dst_frame, + const unsigned char *_src_frame,int _ystride, + const ptrdiff_t *_fragis,ptrdiff_t _nfragis,const ptrdiff_t *_frag_buf_offs){ + ptrdiff_t fragii; + for(fragii=0;fragii<_nfragis;fragii++){ + ptrdiff_t frag_buf_off; + frag_buf_off=_frag_buf_offs[_fragis[fragii]]; + OC_FRAG_COPY_MMX(_dst_frame+frag_buf_off, + _src_frame+frag_buf_off,_ystride); + } +} + + +void oc_frag_recon_intra_mmx(unsigned char *_dst,int _ystride, + const ogg_int16_t *_residue){ + __asm__ __volatile__( + /*Set mm0 to 0xFFFFFFFFFFFFFFFF.*/ + "pcmpeqw %%mm0,%%mm0\n\t" + /*#0 Load low residue.*/ + "movq 0*8(%[residue]),%%mm1\n\t" + /*#0 Load high residue.*/ + "movq 1*8(%[residue]),%%mm2\n\t" + /*Set mm0 to 0x8000800080008000.*/ + "psllw $15,%%mm0\n\t" + /*#1 Load low residue.*/ + "movq 2*8(%[residue]),%%mm3\n\t" + /*#1 Load high residue.*/ + "movq 3*8(%[residue]),%%mm4\n\t" + /*Set mm0 to 0x0080008000800080.*/ + "psrlw $8,%%mm0\n\t" + /*#2 Load low residue.*/ + "movq 4*8(%[residue]),%%mm5\n\t" + /*#2 Load high residue.*/ + "movq 5*8(%[residue]),%%mm6\n\t" + /*#0 Bias low residue.*/ + "paddsw %%mm0,%%mm1\n\t" + /*#0 Bias high residue.*/ + "paddsw %%mm0,%%mm2\n\t" + /*#0 Pack to byte.*/ + "packuswb %%mm2,%%mm1\n\t" + /*#1 Bias low residue.*/ + "paddsw %%mm0,%%mm3\n\t" + /*#1 Bias high residue.*/ + "paddsw %%mm0,%%mm4\n\t" + /*#1 Pack to byte.*/ + "packuswb %%mm4,%%mm3\n\t" + /*#2 Bias low residue.*/ + "paddsw %%mm0,%%mm5\n\t" + /*#2 Bias high residue.*/ + "paddsw %%mm0,%%mm6\n\t" + /*#2 Pack to byte.*/ + "packuswb %%mm6,%%mm5\n\t" + /*#0 Write row.*/ + "movq %%mm1,(%[dst])\n\t" + /*#1 Write row.*/ + "movq %%mm3,(%[dst],%[ystride])\n\t" + /*#2 Write row.*/ + "movq %%mm5,(%[dst],%[ystride],2)\n\t" + /*#3 Load low residue.*/ + "movq 6*8(%[residue]),%%mm1\n\t" + /*#3 Load high residue.*/ + "movq 7*8(%[residue]),%%mm2\n\t" + /*#4 Load high residue.*/ + "movq 8*8(%[residue]),%%mm3\n\t" + /*#4 Load high residue.*/ + "movq 9*8(%[residue]),%%mm4\n\t" + /*#5 Load high residue.*/ + "movq 10*8(%[residue]),%%mm5\n\t" + /*#5 Load high residue.*/ + "movq 11*8(%[residue]),%%mm6\n\t" + /*#3 Bias low residue.*/ + "paddsw %%mm0,%%mm1\n\t" + /*#3 Bias high residue.*/ + "paddsw %%mm0,%%mm2\n\t" + /*#3 Pack to byte.*/ + "packuswb %%mm2,%%mm1\n\t" + /*#4 Bias low residue.*/ + "paddsw %%mm0,%%mm3\n\t" + /*#4 Bias high residue.*/ + "paddsw %%mm0,%%mm4\n\t" + /*#4 Pack to byte.*/ + "packuswb %%mm4,%%mm3\n\t" + /*#5 Bias low residue.*/ + "paddsw %%mm0,%%mm5\n\t" + /*#5 Bias high residue.*/ + "paddsw %%mm0,%%mm6\n\t" + /*#5 Pack to byte.*/ + "packuswb %%mm6,%%mm5\n\t" + /*#3 Write row.*/ + "movq %%mm1,(%[dst],%[ystride3])\n\t" + /*#4 Write row.*/ + "movq %%mm3,(%[dst4])\n\t" + /*#5 Write row.*/ + "movq %%mm5,(%[dst4],%[ystride])\n\t" + /*#6 Load low residue.*/ + "movq 12*8(%[residue]),%%mm1\n\t" + /*#6 Load high residue.*/ + "movq 13*8(%[residue]),%%mm2\n\t" + /*#7 Load low residue.*/ + "movq 14*8(%[residue]),%%mm3\n\t" + /*#7 Load high residue.*/ + "movq 15*8(%[residue]),%%mm4\n\t" + /*#6 Bias low residue.*/ + "paddsw %%mm0,%%mm1\n\t" + /*#6 Bias high residue.*/ + "paddsw %%mm0,%%mm2\n\t" + /*#6 Pack to byte.*/ + "packuswb %%mm2,%%mm1\n\t" + /*#7 Bias low residue.*/ + "paddsw %%mm0,%%mm3\n\t" + /*#7 Bias high residue.*/ + "paddsw %%mm0,%%mm4\n\t" + /*#7 Pack to byte.*/ + "packuswb %%mm4,%%mm3\n\t" + /*#6 Write row.*/ + "movq %%mm1,(%[dst4],%[ystride],2)\n\t" + /*#7 Write row.*/ + "movq %%mm3,(%[dst4],%[ystride3])\n\t" + : + :[residue]"r"(_residue), + [dst]"r"(_dst), + [dst4]"r"(_dst+(_ystride<<2)), + [ystride]"r"((ptrdiff_t)_ystride), + [ystride3]"r"((ptrdiff_t)_ystride*3) + :"memory" + ); +} + +void oc_frag_recon_inter_mmx(unsigned char *_dst,const unsigned char *_src, + int _ystride,const ogg_int16_t *_residue){ + int i; + /*Zero mm0.*/ + __asm__ __volatile__("pxor %%mm0,%%mm0\n\t"::); + for(i=4;i-->0;){ + __asm__ __volatile__( + /*#0 Load source.*/ + "movq (%[src]),%%mm3\n\t" + /*#1 Load source.*/ + "movq (%[src],%[ystride]),%%mm7\n\t" + /*#0 Get copy of src.*/ + "movq %%mm3,%%mm4\n\t" + /*#0 Expand high source.*/ + "punpckhbw %%mm0,%%mm4\n\t" + /*#0 Expand low source.*/ + "punpcklbw %%mm0,%%mm3\n\t" + /*#0 Add residue high.*/ + "paddsw 8(%[residue]),%%mm4\n\t" + /*#1 Get copy of src.*/ + "movq %%mm7,%%mm2\n\t" + /*#0 Add residue low.*/ + "paddsw (%[residue]), %%mm3\n\t" + /*#1 Expand high source.*/ + "punpckhbw %%mm0,%%mm2\n\t" + /*#0 Pack final row pixels.*/ + "packuswb %%mm4,%%mm3\n\t" + /*#1 Expand low source.*/ + "punpcklbw %%mm0,%%mm7\n\t" + /*#1 Add residue low.*/ + "paddsw 16(%[residue]),%%mm7\n\t" + /*#1 Add residue high.*/ + "paddsw 24(%[residue]),%%mm2\n\t" + /*Advance residue.*/ + "lea 32(%[residue]),%[residue]\n\t" + /*#1 Pack final row pixels.*/ + "packuswb %%mm2,%%mm7\n\t" + /*Advance src.*/ + "lea (%[src],%[ystride],2),%[src]\n\t" + /*#0 Write row.*/ + "movq %%mm3,(%[dst])\n\t" + /*#1 Write row.*/ + "movq %%mm7,(%[dst],%[ystride])\n\t" + /*Advance dst.*/ + "lea (%[dst],%[ystride],2),%[dst]\n\t" + :[residue]"+r"(_residue),[dst]"+r"(_dst),[src]"+r"(_src) + :[ystride]"r"((ptrdiff_t)_ystride) + :"memory" + ); + } +} + +void oc_frag_recon_inter2_mmx(unsigned char *_dst,const unsigned char *_src1, + const unsigned char *_src2,int _ystride,const ogg_int16_t *_residue){ + int i; + /*Zero mm7.*/ + __asm__ __volatile__("pxor %%mm7,%%mm7\n\t"::); + for(i=4;i-->0;){ + __asm__ __volatile__( + /*#0 Load src1.*/ + "movq (%[src1]),%%mm0\n\t" + /*#0 Load src2.*/ + "movq (%[src2]),%%mm2\n\t" + /*#0 Copy src1.*/ + "movq %%mm0,%%mm1\n\t" + /*#0 Copy src2.*/ + "movq %%mm2,%%mm3\n\t" + /*#1 Load src1.*/ + "movq (%[src1],%[ystride]),%%mm4\n\t" + /*#0 Unpack lower src1.*/ + "punpcklbw %%mm7,%%mm0\n\t" + /*#1 Load src2.*/ + "movq (%[src2],%[ystride]),%%mm5\n\t" + /*#0 Unpack higher src1.*/ + "punpckhbw %%mm7,%%mm1\n\t" + /*#0 Unpack lower src2.*/ + "punpcklbw %%mm7,%%mm2\n\t" + /*#0 Unpack higher src2.*/ + "punpckhbw %%mm7,%%mm3\n\t" + /*Advance src1 ptr.*/ + "lea (%[src1],%[ystride],2),%[src1]\n\t" + /*Advance src2 ptr.*/ + "lea (%[src2],%[ystride],2),%[src2]\n\t" + /*#0 Lower src1+src2.*/ + "paddsw %%mm2,%%mm0\n\t" + /*#0 Higher src1+src2.*/ + "paddsw %%mm3,%%mm1\n\t" + /*#1 Copy src1.*/ + "movq %%mm4,%%mm2\n\t" + /*#0 Build lo average.*/ + "psraw $1,%%mm0\n\t" + /*#1 Copy src2.*/ + "movq %%mm5,%%mm3\n\t" + /*#1 Unpack lower src1.*/ + "punpcklbw %%mm7,%%mm4\n\t" + /*#0 Build hi average.*/ + "psraw $1,%%mm1\n\t" + /*#1 Unpack higher src1.*/ + "punpckhbw %%mm7,%%mm2\n\t" + /*#0 low+=residue.*/ + "paddsw (%[residue]),%%mm0\n\t" + /*#1 Unpack lower src2.*/ + "punpcklbw %%mm7,%%mm5\n\t" + /*#0 high+=residue.*/ + "paddsw 8(%[residue]),%%mm1\n\t" + /*#1 Unpack higher src2.*/ + "punpckhbw %%mm7,%%mm3\n\t" + /*#1 Lower src1+src2.*/ + "paddsw %%mm4,%%mm5\n\t" + /*#0 Pack and saturate.*/ + "packuswb %%mm1,%%mm0\n\t" + /*#1 Higher src1+src2.*/ + "paddsw %%mm2,%%mm3\n\t" + /*#0 Write row.*/ + "movq %%mm0,(%[dst])\n\t" + /*#1 Build lo average.*/ + "psraw $1,%%mm5\n\t" + /*#1 Build hi average.*/ + "psraw $1,%%mm3\n\t" + /*#1 low+=residue.*/ + "paddsw 16(%[residue]),%%mm5\n\t" + /*#1 high+=residue.*/ + "paddsw 24(%[residue]),%%mm3\n\t" + /*#1 Pack and saturate.*/ + "packuswb %%mm3,%%mm5\n\t" + /*#1 Write row ptr.*/ + "movq %%mm5,(%[dst],%[ystride])\n\t" + /*Advance residue ptr.*/ + "add $32,%[residue]\n\t" + /*Advance dest ptr.*/ + "lea (%[dst],%[ystride],2),%[dst]\n\t" + :[dst]"+r"(_dst),[residue]"+r"(_residue), + [src1]"+r"(_src1),[src2]"+r"(_src2) + :[ystride]"r"((ptrdiff_t)_ystride) + :"memory" + ); + } +} + +void oc_restore_fpu_mmx(void){ + __asm__ __volatile__("emms\n\t"); +} +#endif diff --git a/media/libtheora/lib/x86/mmxidct.c b/media/libtheora/lib/x86/mmxidct.c new file mode 100644 index 0000000000..b8e3077066 --- /dev/null +++ b/media/libtheora/lib/x86/mmxidct.c @@ -0,0 +1,558 @@ +/******************************************************************** + * * + * THIS FILE IS PART OF THE OggTheora SOFTWARE CODEC SOURCE CODE. * + * USE, DISTRIBUTION AND REPRODUCTION OF THIS LIBRARY SOURCE IS * + * GOVERNED BY A BSD-STYLE SOURCE LICENSE INCLUDED WITH THIS SOURCE * + * IN 'COPYING'. PLEASE READ THESE TERMS BEFORE DISTRIBUTING. * + * * + * THE Theora SOURCE CODE IS COPYRIGHT (C) 2002-2009 * + * by the Xiph.Org Foundation and contributors http://www.xiph.org/ * + * * + ******************************************************************** + + function: + last mod: $Id$ + + ********************************************************************/ + +/*MMX acceleration of Theora's iDCT. + Originally written by Rudolf Marek, based on code from On2's VP3.*/ +#include "x86int.h" +#include "../dct.h" + +#if defined(OC_X86_ASM) + +/*These are offsets into the table of constants below.*/ +/*7 rows of cosines, in order: pi/16 * (1 ... 7).*/ +#define OC_COSINE_OFFSET (0) +/*A row of 8's.*/ +#define OC_EIGHT_OFFSET (56) + + + +/*38 cycles*/ +#define OC_IDCT_BEGIN(_y,_x) \ + "#OC_IDCT_BEGIN\n\t" \ + "movq "OC_I(3,_x)",%%mm2\n\t" \ + "movq "OC_MEM_OFFS(0x30,c)",%%mm6\n\t" \ + "movq %%mm2,%%mm4\n\t" \ + "movq "OC_J(5,_x)",%%mm7\n\t" \ + "pmulhw %%mm6,%%mm4\n\t" \ + "movq "OC_MEM_OFFS(0x50,c)",%%mm1\n\t" \ + "pmulhw %%mm7,%%mm6\n\t" \ + "movq %%mm1,%%mm5\n\t" \ + "pmulhw %%mm2,%%mm1\n\t" \ + "movq "OC_I(1,_x)",%%mm3\n\t" \ + "pmulhw %%mm7,%%mm5\n\t" \ + "movq "OC_MEM_OFFS(0x10,c)",%%mm0\n\t" \ + "paddw %%mm2,%%mm4\n\t" \ + "paddw %%mm7,%%mm6\n\t" \ + "paddw %%mm1,%%mm2\n\t" \ + "movq "OC_J(7,_x)",%%mm1\n\t" \ + "paddw %%mm5,%%mm7\n\t" \ + "movq %%mm0,%%mm5\n\t" \ + "pmulhw %%mm3,%%mm0\n\t" \ + "paddw %%mm7,%%mm4\n\t" \ + "pmulhw %%mm1,%%mm5\n\t" \ + "movq "OC_MEM_OFFS(0x70,c)",%%mm7\n\t" \ + "psubw %%mm2,%%mm6\n\t" \ + "paddw %%mm3,%%mm0\n\t" \ + "pmulhw %%mm7,%%mm3\n\t" \ + "movq "OC_I(2,_x)",%%mm2\n\t" \ + "pmulhw %%mm1,%%mm7\n\t" \ + "paddw %%mm1,%%mm5\n\t" \ + "movq %%mm2,%%mm1\n\t" \ + "pmulhw "OC_MEM_OFFS(0x20,c)",%%mm2\n\t" \ + "psubw %%mm5,%%mm3\n\t" \ + "movq "OC_J(6,_x)",%%mm5\n\t" \ + "paddw %%mm7,%%mm0\n\t" \ + "movq %%mm5,%%mm7\n\t" \ + "psubw %%mm4,%%mm0\n\t" \ + "pmulhw "OC_MEM_OFFS(0x20,c)",%%mm5\n\t" \ + "paddw %%mm1,%%mm2\n\t" \ + "pmulhw "OC_MEM_OFFS(0x60,c)",%%mm1\n\t" \ + "paddw %%mm4,%%mm4\n\t" \ + "paddw %%mm0,%%mm4\n\t" \ + "psubw %%mm6,%%mm3\n\t" \ + "paddw %%mm7,%%mm5\n\t" \ + "paddw %%mm6,%%mm6\n\t" \ + "pmulhw "OC_MEM_OFFS(0x60,c)",%%mm7\n\t" \ + "paddw %%mm3,%%mm6\n\t" \ + "movq %%mm4,"OC_I(1,_y)"\n\t" \ + "psubw %%mm5,%%mm1\n\t" \ + "movq "OC_MEM_OFFS(0x40,c)",%%mm4\n\t" \ + "movq %%mm3,%%mm5\n\t" \ + "pmulhw %%mm4,%%mm3\n\t" \ + "paddw %%mm2,%%mm7\n\t" \ + "movq %%mm6,"OC_I(2,_y)"\n\t" \ + "movq %%mm0,%%mm2\n\t" \ + "movq "OC_I(0,_x)",%%mm6\n\t" \ + "pmulhw %%mm4,%%mm0\n\t" \ + "paddw %%mm3,%%mm5\n\t" \ + "movq "OC_J(4,_x)",%%mm3\n\t" \ + "psubw %%mm1,%%mm5\n\t" \ + "paddw %%mm0,%%mm2\n\t" \ + "psubw %%mm3,%%mm6\n\t" \ + "movq %%mm6,%%mm0\n\t" \ + "pmulhw %%mm4,%%mm6\n\t" \ + "paddw %%mm3,%%mm3\n\t" \ + "paddw %%mm1,%%mm1\n\t" \ + "paddw %%mm0,%%mm3\n\t" \ + "paddw %%mm5,%%mm1\n\t" \ + "pmulhw %%mm3,%%mm4\n\t" \ + "paddw %%mm0,%%mm6\n\t" \ + "psubw %%mm2,%%mm6\n\t" \ + "paddw %%mm2,%%mm2\n\t" \ + "movq "OC_I(1,_y)",%%mm0\n\t" \ + "paddw %%mm6,%%mm2\n\t" \ + "paddw %%mm3,%%mm4\n\t" \ + "psubw %%mm1,%%mm2\n\t" \ + "#end OC_IDCT_BEGIN\n\t" \ + +/*38+8=46 cycles.*/ +#define OC_ROW_IDCT(_y,_x) \ + "#OC_ROW_IDCT\n" \ + OC_IDCT_BEGIN(_y,_x) \ + /*r3=D'*/ \ + "movq "OC_I(2,_y)",%%mm3\n\t" \ + /*r4=E'=E-G*/ \ + "psubw %%mm7,%%mm4\n\t" \ + /*r1=H'+H'*/ \ + "paddw %%mm1,%%mm1\n\t" \ + /*r7=G+G*/ \ + "paddw %%mm7,%%mm7\n\t" \ + /*r1=R1=A''+H'*/ \ + "paddw %%mm2,%%mm1\n\t" \ + /*r7=G'=E+G*/ \ + "paddw %%mm4,%%mm7\n\t" \ + /*r4=R4=E'-D'*/ \ + "psubw %%mm3,%%mm4\n\t" \ + "paddw %%mm3,%%mm3\n\t" \ + /*r6=R6=F'-B''*/ \ + "psubw %%mm5,%%mm6\n\t" \ + "paddw %%mm5,%%mm5\n\t" \ + /*r3=R3=E'+D'*/ \ + "paddw %%mm4,%%mm3\n\t" \ + /*r5=R5=F'+B''*/ \ + "paddw %%mm6,%%mm5\n\t" \ + /*r7=R7=G'-C'*/ \ + "psubw %%mm0,%%mm7\n\t" \ + "paddw %%mm0,%%mm0\n\t" \ + /*Save R1.*/ \ + "movq %%mm1,"OC_I(1,_y)"\n\t" \ + /*r0=R0=G.+C.*/ \ + "paddw %%mm7,%%mm0\n\t" \ + "#end OC_ROW_IDCT\n\t" \ + +/*The following macro does two 4x4 transposes in place. + At entry, we assume: + r0 = a3 a2 a1 a0 + I(1) = b3 b2 b1 b0 + r2 = c3 c2 c1 c0 + r3 = d3 d2 d1 d0 + + r4 = e3 e2 e1 e0 + r5 = f3 f2 f1 f0 + r6 = g3 g2 g1 g0 + r7 = h3 h2 h1 h0 + + At exit, we have: + I(0) = d0 c0 b0 a0 + I(1) = d1 c1 b1 a1 + I(2) = d2 c2 b2 a2 + I(3) = d3 c3 b3 a3 + + J(4) = h0 g0 f0 e0 + J(5) = h1 g1 f1 e1 + J(6) = h2 g2 f2 e2 + J(7) = h3 g3 f3 e3 + + I(0) I(1) I(2) I(3) is the transpose of r0 I(1) r2 r3. + J(4) J(5) J(6) J(7) is the transpose of r4 r5 r6 r7. + + Since r1 is free at entry, we calculate the Js first.*/ +/*19 cycles.*/ +#define OC_TRANSPOSE(_y) \ + "#OC_TRANSPOSE\n\t" \ + "movq %%mm4,%%mm1\n\t" \ + "punpcklwd %%mm5,%%mm4\n\t" \ + "movq %%mm0,"OC_I(0,_y)"\n\t" \ + "punpckhwd %%mm5,%%mm1\n\t" \ + "movq %%mm6,%%mm0\n\t" \ + "punpcklwd %%mm7,%%mm6\n\t" \ + "movq %%mm4,%%mm5\n\t" \ + "punpckldq %%mm6,%%mm4\n\t" \ + "punpckhdq %%mm6,%%mm5\n\t" \ + "movq %%mm1,%%mm6\n\t" \ + "movq %%mm4,"OC_J(4,_y)"\n\t" \ + "punpckhwd %%mm7,%%mm0\n\t" \ + "movq %%mm5,"OC_J(5,_y)"\n\t" \ + "punpckhdq %%mm0,%%mm6\n\t" \ + "movq "OC_I(0,_y)",%%mm4\n\t" \ + "punpckldq %%mm0,%%mm1\n\t" \ + "movq "OC_I(1,_y)",%%mm5\n\t" \ + "movq %%mm4,%%mm0\n\t" \ + "movq %%mm6,"OC_J(7,_y)"\n\t" \ + "punpcklwd %%mm5,%%mm0\n\t" \ + "movq %%mm1,"OC_J(6,_y)"\n\t" \ + "punpckhwd %%mm5,%%mm4\n\t" \ + "movq %%mm2,%%mm5\n\t" \ + "punpcklwd %%mm3,%%mm2\n\t" \ + "movq %%mm0,%%mm1\n\t" \ + "punpckldq %%mm2,%%mm0\n\t" \ + "punpckhdq %%mm2,%%mm1\n\t" \ + "movq %%mm4,%%mm2\n\t" \ + "movq %%mm0,"OC_I(0,_y)"\n\t" \ + "punpckhwd %%mm3,%%mm5\n\t" \ + "movq %%mm1,"OC_I(1,_y)"\n\t" \ + "punpckhdq %%mm5,%%mm4\n\t" \ + "punpckldq %%mm5,%%mm2\n\t" \ + "movq %%mm4,"OC_I(3,_y)"\n\t" \ + "movq %%mm2,"OC_I(2,_y)"\n\t" \ + "#end OC_TRANSPOSE\n\t" \ + +/*38+19=57 cycles.*/ +#define OC_COLUMN_IDCT(_y) \ + "#OC_COLUMN_IDCT\n" \ + OC_IDCT_BEGIN(_y,_y) \ + "paddw "OC_MEM_OFFS(0x00,c)",%%mm2\n\t" \ + /*r1=H'+H'*/ \ + "paddw %%mm1,%%mm1\n\t" \ + /*r1=R1=A''+H'*/ \ + "paddw %%mm2,%%mm1\n\t" \ + /*r2=NR2*/ \ + "psraw $4,%%mm2\n\t" \ + /*r4=E'=E-G*/ \ + "psubw %%mm7,%%mm4\n\t" \ + /*r1=NR1*/ \ + "psraw $4,%%mm1\n\t" \ + /*r3=D'*/ \ + "movq "OC_I(2,_y)",%%mm3\n\t" \ + /*r7=G+G*/ \ + "paddw %%mm7,%%mm7\n\t" \ + /*Store NR2 at I(2).*/ \ + "movq %%mm2,"OC_I(2,_y)"\n\t" \ + /*r7=G'=E+G*/ \ + "paddw %%mm4,%%mm7\n\t" \ + /*Store NR1 at I(1).*/ \ + "movq %%mm1,"OC_I(1,_y)"\n\t" \ + /*r4=R4=E'-D'*/ \ + "psubw %%mm3,%%mm4\n\t" \ + "paddw "OC_MEM_OFFS(0x00,c)",%%mm4\n\t" \ + /*r3=D'+D'*/ \ + "paddw %%mm3,%%mm3\n\t" \ + /*r3=R3=E'+D'*/ \ + "paddw %%mm4,%%mm3\n\t" \ + /*r4=NR4*/ \ + "psraw $4,%%mm4\n\t" \ + /*r6=R6=F'-B''*/ \ + "psubw %%mm5,%%mm6\n\t" \ + /*r3=NR3*/ \ + "psraw $4,%%mm3\n\t" \ + "paddw "OC_MEM_OFFS(0x00,c)",%%mm6\n\t" \ + /*r5=B''+B''*/ \ + "paddw %%mm5,%%mm5\n\t" \ + /*r5=R5=F'+B''*/ \ + "paddw %%mm6,%%mm5\n\t" \ + /*r6=NR6*/ \ + "psraw $4,%%mm6\n\t" \ + /*Store NR4 at J(4).*/ \ + "movq %%mm4,"OC_J(4,_y)"\n\t" \ + /*r5=NR5*/ \ + "psraw $4,%%mm5\n\t" \ + /*Store NR3 at I(3).*/ \ + "movq %%mm3,"OC_I(3,_y)"\n\t" \ + /*r7=R7=G'-C'*/ \ + "psubw %%mm0,%%mm7\n\t" \ + "paddw "OC_MEM_OFFS(0x00,c)",%%mm7\n\t" \ + /*r0=C'+C'*/ \ + "paddw %%mm0,%%mm0\n\t" \ + /*r0=R0=G'+C'*/ \ + "paddw %%mm7,%%mm0\n\t" \ + /*r7=NR7*/ \ + "psraw $4,%%mm7\n\t" \ + /*Store NR6 at J(6).*/ \ + "movq %%mm6,"OC_J(6,_y)"\n\t" \ + /*r0=NR0*/ \ + "psraw $4,%%mm0\n\t" \ + /*Store NR5 at J(5).*/ \ + "movq %%mm5,"OC_J(5,_y)"\n\t" \ + /*Store NR7 at J(7).*/ \ + "movq %%mm7,"OC_J(7,_y)"\n\t" \ + /*Store NR0 at I(0).*/ \ + "movq %%mm0,"OC_I(0,_y)"\n\t" \ + "#end OC_COLUMN_IDCT\n\t" \ + +static void oc_idct8x8_slow_mmx(ogg_int16_t _y[64],ogg_int16_t _x[64]){ + int i; + /*This routine accepts an 8x8 matrix, but in partially transposed form. + Every 4x4 block is transposed.*/ + __asm__ __volatile__( +#define OC_I(_k,_y) OC_MEM_OFFS((_k)*16,_y) +#define OC_J(_k,_y) OC_MEM_OFFS(((_k)-4)*16+8,_y) + OC_ROW_IDCT(y,x) + OC_TRANSPOSE(y) +#undef OC_I +#undef OC_J +#define OC_I(_k,_y) OC_MEM_OFFS((_k)*16+64,_y) +#define OC_J(_k,_y) OC_MEM_OFFS(((_k)-4)*16+72,_y) + OC_ROW_IDCT(y,x) + OC_TRANSPOSE(y) +#undef OC_I +#undef OC_J +#define OC_I(_k,_y) OC_MEM_OFFS((_k)*16,_y) +#define OC_J(_k,_y) OC_I(_k,_y) + OC_COLUMN_IDCT(y) +#undef OC_I +#undef OC_J +#define OC_I(_k,_y) OC_MEM_OFFS((_k)*16+8,_y) +#define OC_J(_k,_y) OC_I(_k,_y) + OC_COLUMN_IDCT(y) +#undef OC_I +#undef OC_J + :[y]"=m"OC_ARRAY_OPERAND(ogg_int16_t,_y,64) + :[x]"m"OC_CONST_ARRAY_OPERAND(ogg_int16_t,_x,64), + [c]"m"OC_CONST_ARRAY_OPERAND(ogg_int16_t,OC_IDCT_CONSTS,128) + ); + __asm__ __volatile__("pxor %%mm0,%%mm0\n\t"::); + for(i=0;i<4;i++){ + __asm__ __volatile__( + "movq %%mm0,"OC_MEM_OFFS(0x00,x)"\n\t" + "movq %%mm0,"OC_MEM_OFFS(0x08,x)"\n\t" + "movq %%mm0,"OC_MEM_OFFS(0x10,x)"\n\t" + "movq %%mm0,"OC_MEM_OFFS(0x18,x)"\n\t" + :[x]"=m"OC_ARRAY_OPERAND(ogg_int16_t,_x+16*i,16) + ); + } +} + +/*25 cycles.*/ +#define OC_IDCT_BEGIN_10(_y,_x) \ + "#OC_IDCT_BEGIN_10\n\t" \ + "movq "OC_I(3,_x)",%%mm2\n\t" \ + "nop\n\t" \ + "movq "OC_MEM_OFFS(0x30,c)",%%mm6\n\t" \ + "movq %%mm2,%%mm4\n\t" \ + "movq "OC_MEM_OFFS(0x50,c)",%%mm1\n\t" \ + "pmulhw %%mm6,%%mm4\n\t" \ + "movq "OC_I(1,_x)",%%mm3\n\t" \ + "pmulhw %%mm2,%%mm1\n\t" \ + "movq "OC_MEM_OFFS(0x10,c)",%%mm0\n\t" \ + "paddw %%mm2,%%mm4\n\t" \ + "pxor %%mm6,%%mm6\n\t" \ + "paddw %%mm1,%%mm2\n\t" \ + "movq "OC_I(2,_x)",%%mm5\n\t" \ + "pmulhw %%mm3,%%mm0\n\t" \ + "movq %%mm5,%%mm1\n\t" \ + "paddw %%mm3,%%mm0\n\t" \ + "pmulhw "OC_MEM_OFFS(0x70,c)",%%mm3\n\t" \ + "psubw %%mm2,%%mm6\n\t" \ + "pmulhw "OC_MEM_OFFS(0x20,c)",%%mm5\n\t" \ + "psubw %%mm4,%%mm0\n\t" \ + "movq "OC_I(2,_x)",%%mm7\n\t" \ + "paddw %%mm4,%%mm4\n\t" \ + "paddw %%mm5,%%mm7\n\t" \ + "paddw %%mm0,%%mm4\n\t" \ + "pmulhw "OC_MEM_OFFS(0x60,c)",%%mm1\n\t" \ + "psubw %%mm6,%%mm3\n\t" \ + "movq %%mm4,"OC_I(1,_y)"\n\t" \ + "paddw %%mm6,%%mm6\n\t" \ + "movq "OC_MEM_OFFS(0x40,c)",%%mm4\n\t" \ + "paddw %%mm3,%%mm6\n\t" \ + "movq %%mm3,%%mm5\n\t" \ + "pmulhw %%mm4,%%mm3\n\t" \ + "movq %%mm6,"OC_I(2,_y)"\n\t" \ + "movq %%mm0,%%mm2\n\t" \ + "movq "OC_I(0,_x)",%%mm6\n\t" \ + "pmulhw %%mm4,%%mm0\n\t" \ + "paddw %%mm3,%%mm5\n\t" \ + "paddw %%mm0,%%mm2\n\t" \ + "psubw %%mm1,%%mm5\n\t" \ + "pmulhw %%mm4,%%mm6\n\t" \ + "paddw "OC_I(0,_x)",%%mm6\n\t" \ + "paddw %%mm1,%%mm1\n\t" \ + "movq %%mm6,%%mm4\n\t" \ + "paddw %%mm5,%%mm1\n\t" \ + "psubw %%mm2,%%mm6\n\t" \ + "paddw %%mm2,%%mm2\n\t" \ + "movq "OC_I(1,_y)",%%mm0\n\t" \ + "paddw %%mm6,%%mm2\n\t" \ + "psubw %%mm1,%%mm2\n\t" \ + "nop\n\t" \ + "#end OC_IDCT_BEGIN_10\n\t" \ + +/*25+8=33 cycles.*/ +#define OC_ROW_IDCT_10(_y,_x) \ + "#OC_ROW_IDCT_10\n\t" \ + OC_IDCT_BEGIN_10(_y,_x) \ + /*r3=D'*/ \ + "movq "OC_I(2,_y)",%%mm3\n\t" \ + /*r4=E'=E-G*/ \ + "psubw %%mm7,%%mm4\n\t" \ + /*r1=H'+H'*/ \ + "paddw %%mm1,%%mm1\n\t" \ + /*r7=G+G*/ \ + "paddw %%mm7,%%mm7\n\t" \ + /*r1=R1=A''+H'*/ \ + "paddw %%mm2,%%mm1\n\t" \ + /*r7=G'=E+G*/ \ + "paddw %%mm4,%%mm7\n\t" \ + /*r4=R4=E'-D'*/ \ + "psubw %%mm3,%%mm4\n\t" \ + "paddw %%mm3,%%mm3\n\t" \ + /*r6=R6=F'-B''*/ \ + "psubw %%mm5,%%mm6\n\t" \ + "paddw %%mm5,%%mm5\n\t" \ + /*r3=R3=E'+D'*/ \ + "paddw %%mm4,%%mm3\n\t" \ + /*r5=R5=F'+B''*/ \ + "paddw %%mm6,%%mm5\n\t" \ + /*r7=R7=G'-C'*/ \ + "psubw %%mm0,%%mm7\n\t" \ + "paddw %%mm0,%%mm0\n\t" \ + /*Save R1.*/ \ + "movq %%mm1,"OC_I(1,_y)"\n\t" \ + /*r0=R0=G'+C'*/ \ + "paddw %%mm7,%%mm0\n\t" \ + "#end OC_ROW_IDCT_10\n\t" \ + +/*25+19=44 cycles'*/ +#define OC_COLUMN_IDCT_10(_y) \ + "#OC_COLUMN_IDCT_10\n\t" \ + OC_IDCT_BEGIN_10(_y,_y) \ + "paddw "OC_MEM_OFFS(0x00,c)",%%mm2\n\t" \ + /*r1=H'+H'*/ \ + "paddw %%mm1,%%mm1\n\t" \ + /*r1=R1=A''+H'*/ \ + "paddw %%mm2,%%mm1\n\t" \ + /*r2=NR2*/ \ + "psraw $4,%%mm2\n\t" \ + /*r4=E'=E-G*/ \ + "psubw %%mm7,%%mm4\n\t" \ + /*r1=NR1*/ \ + "psraw $4,%%mm1\n\t" \ + /*r3=D'*/ \ + "movq "OC_I(2,_y)",%%mm3\n\t" \ + /*r7=G+G*/ \ + "paddw %%mm7,%%mm7\n\t" \ + /*Store NR2 at I(2).*/ \ + "movq %%mm2,"OC_I(2,_y)"\n\t" \ + /*r7=G'=E+G*/ \ + "paddw %%mm4,%%mm7\n\t" \ + /*Store NR1 at I(1).*/ \ + "movq %%mm1,"OC_I(1,_y)"\n\t" \ + /*r4=R4=E'-D'*/ \ + "psubw %%mm3,%%mm4\n\t" \ + "paddw "OC_MEM_OFFS(0x00,c)",%%mm4\n\t" \ + /*r3=D'+D'*/ \ + "paddw %%mm3,%%mm3\n\t" \ + /*r3=R3=E'+D'*/ \ + "paddw %%mm4,%%mm3\n\t" \ + /*r4=NR4*/ \ + "psraw $4,%%mm4\n\t" \ + /*r6=R6=F'-B''*/ \ + "psubw %%mm5,%%mm6\n\t" \ + /*r3=NR3*/ \ + "psraw $4,%%mm3\n\t" \ + "paddw "OC_MEM_OFFS(0x00,c)",%%mm6\n\t" \ + /*r5=B''+B''*/ \ + "paddw %%mm5,%%mm5\n\t" \ + /*r5=R5=F'+B''*/ \ + "paddw %%mm6,%%mm5\n\t" \ + /*r6=NR6*/ \ + "psraw $4,%%mm6\n\t" \ + /*Store NR4 at J(4).*/ \ + "movq %%mm4,"OC_J(4,_y)"\n\t" \ + /*r5=NR5*/ \ + "psraw $4,%%mm5\n\t" \ + /*Store NR3 at I(3).*/ \ + "movq %%mm3,"OC_I(3,_y)"\n\t" \ + /*r7=R7=G'-C'*/ \ + "psubw %%mm0,%%mm7\n\t" \ + "paddw "OC_MEM_OFFS(0x00,c)",%%mm7\n\t" \ + /*r0=C'+C'*/ \ + "paddw %%mm0,%%mm0\n\t" \ + /*r0=R0=G'+C'*/ \ + "paddw %%mm7,%%mm0\n\t" \ + /*r7=NR7*/ \ + "psraw $4,%%mm7\n\t" \ + /*Store NR6 at J(6).*/ \ + "movq %%mm6,"OC_J(6,_y)"\n\t" \ + /*r0=NR0*/ \ + "psraw $4,%%mm0\n\t" \ + /*Store NR5 at J(5).*/ \ + "movq %%mm5,"OC_J(5,_y)"\n\t" \ + /*Store NR7 at J(7).*/ \ + "movq %%mm7,"OC_J(7,_y)"\n\t" \ + /*Store NR0 at I(0).*/ \ + "movq %%mm0,"OC_I(0,_y)"\n\t" \ + "#end OC_COLUMN_IDCT_10\n\t" \ + +static void oc_idct8x8_10_mmx(ogg_int16_t _y[64],ogg_int16_t _x[64]){ + __asm__ __volatile__( +#define OC_I(_k,_y) OC_MEM_OFFS((_k)*16,_y) +#define OC_J(_k,_y) OC_MEM_OFFS(((_k)-4)*16+8,_y) + /*Done with dequant, descramble, and partial transpose. + Now do the iDCT itself.*/ + OC_ROW_IDCT_10(y,x) + OC_TRANSPOSE(y) +#undef OC_I +#undef OC_J +#define OC_I(_k,_y) OC_MEM_OFFS((_k)*16,_y) +#define OC_J(_k,_y) OC_I(_k,_y) + OC_COLUMN_IDCT_10(y) +#undef OC_I +#undef OC_J +#define OC_I(_k,_y) OC_MEM_OFFS((_k)*16+8,_y) +#define OC_J(_k,_y) OC_I(_k,_y) + OC_COLUMN_IDCT_10(y) +#undef OC_I +#undef OC_J + :[y]"=m"OC_ARRAY_OPERAND(ogg_int16_t,_y,64) + :[x]"m"OC_CONST_ARRAY_OPERAND(ogg_int16_t,_x,64), + [c]"m"OC_CONST_ARRAY_OPERAND(ogg_int16_t,OC_IDCT_CONSTS,128) + ); + __asm__ __volatile__( + "pxor %%mm0,%%mm0\n\t" + "movq %%mm0,"OC_MEM_OFFS(0x00,x)"\n\t" + "movq %%mm0,"OC_MEM_OFFS(0x10,x)"\n\t" + "movq %%mm0,"OC_MEM_OFFS(0x20,x)"\n\t" + "movq %%mm0,"OC_MEM_OFFS(0x30,x)"\n\t" + :[x]"+m"OC_ARRAY_OPERAND(ogg_int16_t,_x,28) + ); +} + +/*Performs an inverse 8x8 Type-II DCT transform. + The input is assumed to be scaled by a factor of 4 relative to orthonormal + version of the transform.*/ +void oc_idct8x8_mmx(ogg_int16_t _y[64],ogg_int16_t _x[64],int _last_zzi){ + /*_last_zzi is subtly different from an actual count of the number of + coefficients we decoded for this block. + It contains the value of zzi BEFORE the final token in the block was + decoded. + In most cases this is an EOB token (the continuation of an EOB run from a + previous block counts), and so this is the same as the coefficient count. + However, in the case that the last token was NOT an EOB token, but filled + the block up with exactly 64 coefficients, _last_zzi will be less than 64. + Provided the last token was not a pure zero run, the minimum value it can + be is 46, and so that doesn't affect any of the cases in this routine. + However, if the last token WAS a pure zero run of length 63, then _last_zzi + will be 1 while the number of coefficients decoded is 64. + Thus, we will trigger the following special case, where the real + coefficient count would not. + Note also that a zero run of length 64 will give _last_zzi a value of 0, + but we still process the DC coefficient, which might have a non-zero value + due to DC prediction. + Although convoluted, this is arguably the correct behavior: it allows us to + use a smaller transform when the block ends with a long zero run instead + of a normal EOB token. + It could be smarter... multiple separate zero runs at the end of a block + will fool it, but an encoder that generates these really deserves what it + gets. + Needless to say we inherited this approach from VP3.*/ + /*Then perform the iDCT.*/ + if(_last_zzi<=10)oc_idct8x8_10_mmx(_y,_x); + else oc_idct8x8_slow_mmx(_y,_x); +} + +#endif diff --git a/media/libtheora/lib/x86/mmxloop.h b/media/libtheora/lib/x86/mmxloop.h new file mode 100644 index 0000000000..1f6090b567 --- /dev/null +++ b/media/libtheora/lib/x86/mmxloop.h @@ -0,0 +1,318 @@ +#if !defined(_x86_mmxloop_H) +# define _x86_mmxloop_H (1) +# include <stddef.h> +# include "x86int.h" + +#if defined(OC_X86_ASM) + +/*On entry, mm0={a0,...,a7}, mm1={b0,...,b7}, mm2={c0,...,c7}, mm3={d0,...d7}. + On exit, mm1={b0+lflim(R_0,L),...,b7+lflim(R_7,L)} and + mm2={c0-lflim(R_0,L),...,c7-lflim(R_7,L)}; mm0 and mm3 are clobbered.*/ +#define OC_LOOP_FILTER8_MMX \ + "#OC_LOOP_FILTER8_MMX\n\t" \ + /*mm7=0*/ \ + "pxor %%mm7,%%mm7\n\t" \ + /*mm6:mm0={a0,...,a7}*/ \ + "movq %%mm0,%%mm6\n\t" \ + "punpcklbw %%mm7,%%mm0\n\t" \ + "punpckhbw %%mm7,%%mm6\n\t" \ + /*mm3:mm5={d0,...,d7}*/ \ + "movq %%mm3,%%mm5\n\t" \ + "punpcklbw %%mm7,%%mm3\n\t" \ + "punpckhbw %%mm7,%%mm5\n\t" \ + /*mm6:mm0={a0-d0,...,a7-d7}*/ \ + "psubw %%mm3,%%mm0\n\t" \ + "psubw %%mm5,%%mm6\n\t" \ + /*mm3:mm1={b0,...,b7}*/ \ + "movq %%mm1,%%mm3\n\t" \ + "punpcklbw %%mm7,%%mm1\n\t" \ + "movq %%mm2,%%mm4\n\t" \ + "punpckhbw %%mm7,%%mm3\n\t" \ + /*mm5:mm4={c0,...,c7}*/ \ + "movq %%mm2,%%mm5\n\t" \ + "punpcklbw %%mm7,%%mm4\n\t" \ + "punpckhbw %%mm7,%%mm5\n\t" \ + /*mm7={3}x4 \ + mm5:mm4={c0-b0,...,c7-b7}*/ \ + "pcmpeqw %%mm7,%%mm7\n\t" \ + "psubw %%mm1,%%mm4\n\t" \ + "psrlw $14,%%mm7\n\t" \ + "psubw %%mm3,%%mm5\n\t" \ + /*Scale by 3.*/ \ + "pmullw %%mm7,%%mm4\n\t" \ + "pmullw %%mm7,%%mm5\n\t" \ + /*mm7={4}x4 \ + mm5:mm4=f={a0-d0+3*(c0-b0),...,a7-d7+3*(c7-b7)}*/ \ + "psrlw $1,%%mm7\n\t" \ + "paddw %%mm0,%%mm4\n\t" \ + "psllw $2,%%mm7\n\t" \ + "movq (%[ll]),%%mm0\n\t" \ + "paddw %%mm6,%%mm5\n\t" \ + /*R_i has the range [-127,128], so we compute -R_i instead. \ + mm4=-R_i=-(f+4>>3)=0xFF^(f-4>>3)*/ \ + "psubw %%mm7,%%mm4\n\t" \ + "psubw %%mm7,%%mm5\n\t" \ + "psraw $3,%%mm4\n\t" \ + "psraw $3,%%mm5\n\t" \ + "pcmpeqb %%mm7,%%mm7\n\t" \ + "packsswb %%mm5,%%mm4\n\t" \ + "pxor %%mm6,%%mm6\n\t" \ + "pxor %%mm7,%%mm4\n\t" \ + "packuswb %%mm3,%%mm1\n\t" \ + /*Now compute lflim of -mm4 cf. Section 7.10 of the sepc.*/ \ + /*There's no unsigned byte+signed byte with unsigned saturation op code, so \ + we have to split things by sign (the other option is to work in 16 bits, \ + but working in 8 bits gives much better parallelism). \ + We compute abs(R_i), but save a mask of which terms were negative in mm6. \ + Then we compute mm4=abs(lflim(R_i,L))=min(abs(R_i),max(2*L-abs(R_i),0)). \ + Finally, we split mm4 into positive and negative pieces using the mask in \ + mm6, and add and subtract them as appropriate.*/ \ + /*mm4=abs(-R_i)*/ \ + /*mm7=255-2*L*/ \ + "pcmpgtb %%mm4,%%mm6\n\t" \ + "psubb %%mm0,%%mm7\n\t" \ + "pxor %%mm6,%%mm4\n\t" \ + "psubb %%mm0,%%mm7\n\t" \ + "psubb %%mm6,%%mm4\n\t" \ + /*mm7=255-max(2*L-abs(R_i),0)*/ \ + "paddusb %%mm4,%%mm7\n\t" \ + /*mm4=min(abs(R_i),max(2*L-abs(R_i),0))*/ \ + "paddusb %%mm7,%%mm4\n\t" \ + "psubusb %%mm7,%%mm4\n\t" \ + /*Now split mm4 by the original sign of -R_i.*/ \ + "movq %%mm4,%%mm5\n\t" \ + "pand %%mm6,%%mm4\n\t" \ + "pandn %%mm5,%%mm6\n\t" \ + /*mm1={b0+lflim(R_0,L),...,b7+lflim(R_7,L)}*/ \ + /*mm2={c0-lflim(R_0,L),...,c7-lflim(R_7,L)}*/ \ + "paddusb %%mm4,%%mm1\n\t" \ + "psubusb %%mm4,%%mm2\n\t" \ + "psubusb %%mm6,%%mm1\n\t" \ + "paddusb %%mm6,%%mm2\n\t" \ + +/*On entry, mm0={a0,...,a7}, mm1={b0,...,b7}, mm2={c0,...,c7}, mm3={d0,...d7}. + On exit, mm1={b0+lflim(R_0,L),...,b7+lflim(R_7,L)} and + mm2={c0-lflim(R_0,L),...,c7-lflim(R_7,L)}. + All other MMX registers are clobbered.*/ +#define OC_LOOP_FILTER8_MMXEXT \ + "#OC_LOOP_FILTER8_MMXEXT\n\t" \ + /*R_i=(a_i-3*b_i+3*c_i-d_i+4>>3) has the range [-127,128], so we compute \ + -R_i=(-a_i+3*b_i-3*c_i+d_i+3>>3) instead.*/ \ + /*This first part is based on the transformation \ + f = -(3*(c-b)+a-d+4>>3) \ + = -(3*(c+255-b)+(a+255-d)+4-1020>>3) \ + = -(3*(c+~b)+(a+~d)-1016>>3) \ + = 127-(3*(c+~b)+(a+~d)>>3) \ + = 128+~(3*(c+~b)+(a+~d)>>3) (mod 256). \ + Although pavgb(a,b) = (a+b+1>>1) (biased up), we rely heavily on the \ + fact that ~pavgb(~a,~b) = (a+b>>1) (biased down). \ + Using this, the last expression above can be computed in 8 bits of working \ + precision via: \ + u = ~pavgb(~b,c); \ + v = pavgb(b,~c); \ + This mask is 0 or 0xFF, and controls whether t is biased up or down: \ + m = u-v; \ + t = m^pavgb(m^~a,m^d); \ + f = 128+pavgb(pavgb(t,u),v); \ + This required some careful analysis to ensure that carries are propagated \ + correctly in all cases, but has been checked exhaustively.*/ \ + /*input (a, b, c, d, ., ., ., .)*/ \ + /*ff=0xFF; \ + u=b; \ + v=c; \ + ll=255-2*L;*/ \ + "pcmpeqb %%mm7,%%mm7\n\t" \ + "movq %%mm1,%%mm4\n\t" \ + "movq %%mm2,%%mm5\n\t" \ + "movq (%[ll]),%%mm6\n\t" \ + /*allocated u, v, ll, ff: (a, b, c, d, u, v, ll, ff)*/ \ + /*u^=ff; \ + v^=ff;*/ \ + "pxor %%mm7,%%mm4\n\t" \ + "pxor %%mm7,%%mm5\n\t" \ + /*allocated ll: (a, b, c, d, u, v, ll, ff)*/ \ + /*u=pavgb(u,c); \ + v=pavgb(v,b);*/ \ + "pavgb %%mm2,%%mm4\n\t" \ + "pavgb %%mm1,%%mm5\n\t" \ + /*u^=ff; \ + a^=ff;*/ \ + "pxor %%mm7,%%mm4\n\t" \ + "pxor %%mm7,%%mm0\n\t" \ + /*m=u-v;*/ \ + "psubb %%mm5,%%mm4\n\t" \ + /*freed u, allocated m: (a, b, c, d, m, v, ll, ff)*/ \ + /*a^=m; \ + d^=m;*/ \ + "pxor %%mm4,%%mm0\n\t" \ + "pxor %%mm4,%%mm3\n\t" \ + /*t=pavgb(a,d);*/ \ + "pavgb %%mm3,%%mm0\n\t" \ + "psllw $7,%%mm7\n\t" \ + /*freed a, d, ff, allocated t, of: (t, b, c, ., m, v, ll, of)*/ \ + /*t^=m; \ + u=m+v;*/ \ + "pxor %%mm4,%%mm0\n\t" \ + "paddb %%mm5,%%mm4\n\t" \ + /*freed t, m, allocated f, u: (f, b, c, ., u, v, ll, of)*/ \ + /*f=pavgb(f,u); \ + of=128;*/ \ + "pavgb %%mm4,%%mm0\n\t" \ + "packsswb %%mm7,%%mm7\n\t" \ + /*freed u, ff, allocated ll: (f, b, c, ., ll, v, ll, of)*/ \ + /*f=pavgb(f,v);*/ \ + "pavgb %%mm5,%%mm0\n\t" \ + "movq %%mm7,%%mm3\n\t" \ + "movq %%mm6,%%mm4\n\t" \ + /*freed v, allocated of: (f, b, c, of, ll, ., ll, of)*/ \ + /*Now compute lflim of R_i=-(128+mm0) cf. Section 7.10 of the sepc.*/ \ + /*There's no unsigned byte+signed byte with unsigned saturation op code, so \ + we have to split things by sign (the other option is to work in 16 bits, \ + but staying in 8 bits gives much better parallelism).*/ \ + /*Instead of adding the offset of 128 in mm3, we use it to split mm0. \ + This is the same number of instructions as computing a mask and splitting \ + after the lflim computation, but has shorter dependency chains.*/ \ + /*mm0=R_i<0?-R_i:0 (denoted abs(R_i<0))\ + mm3=R_i>0?R_i:0* (denoted abs(R_i>0))*/ \ + "psubusb %%mm0,%%mm3\n\t" \ + "psubusb %%mm7,%%mm0\n\t" \ + /*mm6=255-max(2*L-abs(R_i<0),0) \ + mm4=255-max(2*L-abs(R_i>0),0)*/ \ + "paddusb %%mm3,%%mm4\n\t" \ + "paddusb %%mm0,%%mm6\n\t" \ + /*mm0=min(abs(R_i<0),max(2*L-abs(R_i<0),0)) \ + mm3=min(abs(R_i>0),max(2*L-abs(R_i>0),0))*/ \ + "paddusb %%mm4,%%mm3\n\t" \ + "paddusb %%mm6,%%mm0\n\t" \ + "psubusb %%mm4,%%mm3\n\t" \ + "psubusb %%mm6,%%mm0\n\t" \ + /*mm1={b0+lflim(R_0,L),...,b7+lflim(R_7,L)}*/ \ + /*mm2={c0-lflim(R_0,L),...,c7-lflim(R_7,L)}*/ \ + "paddusb %%mm3,%%mm1\n\t" \ + "psubusb %%mm3,%%mm2\n\t" \ + "psubusb %%mm0,%%mm1\n\t" \ + "paddusb %%mm0,%%mm2\n\t" \ + +#define OC_LOOP_FILTER_V(_filter,_pix,_ystride,_ll) \ + do{ \ + ptrdiff_t ystride3__; \ + __asm__ __volatile__( \ + /*mm0={a0,...,a7}*/ \ + "movq (%[pix]),%%mm0\n\t" \ + /*ystride3=_ystride*3*/ \ + "lea (%[ystride],%[ystride],2),%[ystride3]\n\t" \ + /*mm3={d0,...,d7}*/ \ + "movq (%[pix],%[ystride3]),%%mm3\n\t" \ + /*mm1={b0,...,b7}*/ \ + "movq (%[pix],%[ystride]),%%mm1\n\t" \ + /*mm2={c0,...,c7}*/ \ + "movq (%[pix],%[ystride],2),%%mm2\n\t" \ + _filter \ + /*Write it back out.*/ \ + "movq %%mm1,(%[pix],%[ystride])\n\t" \ + "movq %%mm2,(%[pix],%[ystride],2)\n\t" \ + :[ystride3]"=&r"(ystride3__) \ + :[pix]"r"(_pix-_ystride*2),[ystride]"r"((ptrdiff_t)(_ystride)), \ + [ll]"r"(_ll) \ + :"memory" \ + ); \ + } \ + while(0) + +#define OC_LOOP_FILTER_H(_filter,_pix,_ystride,_ll) \ + do{ \ + unsigned char *pix__; \ + ptrdiff_t ystride3__; \ + ptrdiff_t d__; \ + pix__=(_pix)-2; \ + __asm__ __volatile__( \ + /*x x x x d0 c0 b0 a0*/ \ + "movd (%[pix]),%%mm0\n\t" \ + /*x x x x d1 c1 b1 a1*/ \ + "movd (%[pix],%[ystride]),%%mm1\n\t" \ + /*ystride3=_ystride*3*/ \ + "lea (%[ystride],%[ystride],2),%[ystride3]\n\t" \ + /*x x x x d2 c2 b2 a2*/ \ + "movd (%[pix],%[ystride],2),%%mm2\n\t" \ + /*x x x x d3 c3 b3 a3*/ \ + "lea (%[pix],%[ystride],4),%[d]\n\t" \ + "movd (%[pix],%[ystride3]),%%mm3\n\t" \ + /*x x x x d4 c4 b4 a4*/ \ + "movd (%[d]),%%mm4\n\t" \ + /*x x x x d5 c5 b5 a5*/ \ + "movd (%[d],%[ystride]),%%mm5\n\t" \ + /*x x x x d6 c6 b6 a6*/ \ + "movd (%[d],%[ystride],2),%%mm6\n\t" \ + /*x x x x d7 c7 b7 a7*/ \ + "movd (%[d],%[ystride3]),%%mm7\n\t" \ + /*mm0=d1 d0 c1 c0 b1 b0 a1 a0*/ \ + "punpcklbw %%mm1,%%mm0\n\t" \ + /*mm2=d3 d2 c3 c2 b3 b2 a3 a2*/ \ + "punpcklbw %%mm3,%%mm2\n\t" \ + /*mm3=d1 d0 c1 c0 b1 b0 a1 a0*/ \ + "movq %%mm0,%%mm3\n\t" \ + /*mm0=b3 b2 b1 b0 a3 a2 a1 a0*/ \ + "punpcklwd %%mm2,%%mm0\n\t" \ + /*mm3=d3 d2 d1 d0 c3 c2 c1 c0*/ \ + "punpckhwd %%mm2,%%mm3\n\t" \ + /*mm1=b3 b2 b1 b0 a3 a2 a1 a0*/ \ + "movq %%mm0,%%mm1\n\t" \ + /*mm4=d5 d4 c5 c4 b5 b4 a5 a4*/ \ + "punpcklbw %%mm5,%%mm4\n\t" \ + /*mm6=d7 d6 c7 c6 b7 b6 a7 a6*/ \ + "punpcklbw %%mm7,%%mm6\n\t" \ + /*mm5=d5 d4 c5 c4 b5 b4 a5 a4*/ \ + "movq %%mm4,%%mm5\n\t" \ + /*mm4=b7 b6 b5 b4 a7 a6 a5 a4*/ \ + "punpcklwd %%mm6,%%mm4\n\t" \ + /*mm5=d7 d6 d5 d4 c7 c6 c5 c4*/ \ + "punpckhwd %%mm6,%%mm5\n\t" \ + /*mm2=d3 d2 d1 d0 c3 c2 c1 c0*/ \ + "movq %%mm3,%%mm2\n\t" \ + /*mm0=a7 a6 a5 a4 a3 a2 a1 a0*/ \ + "punpckldq %%mm4,%%mm0\n\t" \ + /*mm1=b7 b6 b5 b4 b3 b2 b1 b0*/ \ + "punpckhdq %%mm4,%%mm1\n\t" \ + /*mm2=c7 c6 c5 c4 c3 c2 c1 c0*/ \ + "punpckldq %%mm5,%%mm2\n\t" \ + /*mm3=d7 d6 d5 d4 d3 d2 d1 d0*/ \ + "punpckhdq %%mm5,%%mm3\n\t" \ + _filter \ + /*mm2={b0+R_0'',...,b7+R_7''}*/ \ + "movq %%mm1,%%mm0\n\t" \ + /*mm1={b0+R_0'',c0-R_0'',...,b3+R_3'',c3-R_3''}*/ \ + "punpcklbw %%mm2,%%mm1\n\t" \ + /*mm2={b4+R_4'',c4-R_4'',...,b7+R_7'',c7-R_7''}*/ \ + "punpckhbw %%mm2,%%mm0\n\t" \ + /*[d]=c1 b1 c0 b0*/ \ + "movd %%mm1,%[d]\n\t" \ + "movw %w[d],1(%[pix])\n\t" \ + "psrlq $32,%%mm1\n\t" \ + "shr $16,%[d]\n\t" \ + "movw %w[d],1(%[pix],%[ystride])\n\t" \ + /*[d]=c3 b3 c2 b2*/ \ + "movd %%mm1,%[d]\n\t" \ + "movw %w[d],1(%[pix],%[ystride],2)\n\t" \ + "shr $16,%[d]\n\t" \ + "movw %w[d],1(%[pix],%[ystride3])\n\t" \ + "lea (%[pix],%[ystride],4),%[pix]\n\t" \ + /*[d]=c5 b5 c4 b4*/ \ + "movd %%mm0,%[d]\n\t" \ + "movw %w[d],1(%[pix])\n\t" \ + "psrlq $32,%%mm0\n\t" \ + "shr $16,%[d]\n\t" \ + "movw %w[d],1(%[pix],%[ystride])\n\t" \ + /*[d]=c7 b7 c6 b6*/ \ + "movd %%mm0,%[d]\n\t" \ + "movw %w[d],1(%[pix],%[ystride],2)\n\t" \ + "shr $16,%[d]\n\t" \ + "movw %w[d],1(%[pix],%[ystride3])\n\t" \ + :[pix]"+r"(pix__),[ystride3]"=&r"(ystride3__),[d]"=&r"(d__) \ + :[ystride]"r"((ptrdiff_t)(_ystride)),[ll]"r"(_ll) \ + :"memory" \ + ); \ + } \ + while(0) + +# endif +#endif diff --git a/media/libtheora/lib/x86/mmxstate.c b/media/libtheora/lib/x86/mmxstate.c new file mode 100644 index 0000000000..eebea14fba --- /dev/null +++ b/media/libtheora/lib/x86/mmxstate.c @@ -0,0 +1,226 @@ +/******************************************************************** + * * + * THIS FILE IS PART OF THE OggTheora SOFTWARE CODEC SOURCE CODE. * + * USE, DISTRIBUTION AND REPRODUCTION OF THIS LIBRARY SOURCE IS * + * GOVERNED BY A BSD-STYLE SOURCE LICENSE INCLUDED WITH THIS SOURCE * + * IN 'COPYING'. PLEASE READ THESE TERMS BEFORE DISTRIBUTING. * + * * + * THE Theora SOURCE CODE IS COPYRIGHT (C) 2002-2009 * + * by the Xiph.Org Foundation and contributors http://www.xiph.org/ * + * * + ******************************************************************** + + function: + last mod: $Id$ + + ********************************************************************/ + +/*MMX acceleration of complete fragment reconstruction algorithm. + Originally written by Rudolf Marek.*/ +#include <string.h> +#include "x86int.h" +#include "mmxloop.h" + +#if defined(OC_X86_ASM) + +void oc_state_frag_recon_mmx(const oc_theora_state *_state,ptrdiff_t _fragi, + int _pli,ogg_int16_t _dct_coeffs[128],int _last_zzi,ogg_uint16_t _dc_quant){ + unsigned char *dst; + ptrdiff_t frag_buf_off; + int ystride; + int refi; + /*Apply the inverse transform.*/ + /*Special case only having a DC component.*/ + if(_last_zzi<2){ + /*Note that this value must be unsigned, to keep the __asm__ block from + sign-extending it when it puts it in a register.*/ + ogg_uint16_t p; + int i; + /*We round this dequant product (and not any of the others) because there's + no iDCT rounding.*/ + p=(ogg_int16_t)(_dct_coeffs[0]*(ogg_int32_t)_dc_quant+15>>5); + /*Fill _dct_coeffs with p.*/ + __asm__ __volatile__( + /*mm0=0000 0000 0000 AAAA*/ + "movd %[p],%%mm0\n\t" + /*mm0=0000 0000 AAAA AAAA*/ + "punpcklwd %%mm0,%%mm0\n\t" + /*mm0=AAAA AAAA AAAA AAAA*/ + "punpckldq %%mm0,%%mm0\n\t" + : + :[p]"r"((unsigned)p) + ); + for(i=0;i<4;i++){ + __asm__ __volatile__( + "movq %%mm0,"OC_MEM_OFFS(0x00,y)"\n\t" + "movq %%mm0,"OC_MEM_OFFS(0x08,y)"\n\t" + "movq %%mm0,"OC_MEM_OFFS(0x10,y)"\n\t" + "movq %%mm0,"OC_MEM_OFFS(0x18,y)"\n\t" + :[y]"=m"OC_ARRAY_OPERAND(ogg_int16_t,_dct_coeffs+64+16*i,16) + ); + } + } + else{ + /*Dequantize the DC coefficient.*/ + _dct_coeffs[0]=(ogg_int16_t)(_dct_coeffs[0]*(int)_dc_quant); + oc_idct8x8(_state,_dct_coeffs+64,_dct_coeffs,_last_zzi); + } + /*Fill in the target buffer.*/ + frag_buf_off=_state->frag_buf_offs[_fragi]; + refi=_state->frags[_fragi].refi; + ystride=_state->ref_ystride[_pli]; + dst=_state->ref_frame_data[OC_FRAME_SELF]+frag_buf_off; + if(refi==OC_FRAME_SELF)oc_frag_recon_intra_mmx(dst,ystride,_dct_coeffs+64); + else{ + const unsigned char *ref; + int mvoffsets[2]; + ref=_state->ref_frame_data[refi]+frag_buf_off; + if(oc_state_get_mv_offsets(_state,mvoffsets,_pli, + _state->frag_mvs[_fragi])>1){ + oc_frag_recon_inter2_mmx(dst,ref+mvoffsets[0],ref+mvoffsets[1],ystride, + _dct_coeffs+64); + } + else oc_frag_recon_inter_mmx(dst,ref+mvoffsets[0],ystride,_dct_coeffs+64); + } +} + +/*We copy these entire function to inline the actual MMX routines so that we + use only a single indirect call.*/ + +void oc_loop_filter_init_mmx(signed char _bv[256],int _flimit){ + memset(_bv,_flimit,8); +} + +/*Apply the loop filter to a given set of fragment rows in the given plane. + The filter may be run on the bottom edge, affecting pixels in the next row of + fragments, so this row also needs to be available. + _bv: The bounding values array. + _refi: The index of the frame buffer to filter. + _pli: The color plane to filter. + _fragy0: The Y coordinate of the first fragment row to filter. + _fragy_end: The Y coordinate of the fragment row to stop filtering at.*/ +void oc_state_loop_filter_frag_rows_mmx(const oc_theora_state *_state, + signed char _bv[256],int _refi,int _pli,int _fragy0,int _fragy_end){ + OC_ALIGN8(unsigned char ll[8]); + const oc_fragment_plane *fplane; + const oc_fragment *frags; + const ptrdiff_t *frag_buf_offs; + unsigned char *ref_frame_data; + ptrdiff_t fragi_top; + ptrdiff_t fragi_bot; + ptrdiff_t fragi0; + ptrdiff_t fragi0_end; + int ystride; + int nhfrags; + memset(ll,_state->loop_filter_limits[_state->qis[0]],sizeof(ll)); + fplane=_state->fplanes+_pli; + nhfrags=fplane->nhfrags; + fragi_top=fplane->froffset; + fragi_bot=fragi_top+fplane->nfrags; + fragi0=fragi_top+_fragy0*(ptrdiff_t)nhfrags; + fragi0_end=fragi0+(_fragy_end-_fragy0)*(ptrdiff_t)nhfrags; + ystride=_state->ref_ystride[_pli]; + frags=_state->frags; + frag_buf_offs=_state->frag_buf_offs; + ref_frame_data=_state->ref_frame_data[_refi]; + /*The following loops are constructed somewhat non-intuitively on purpose. + The main idea is: if a block boundary has at least one coded fragment on + it, the filter is applied to it. + However, the order that the filters are applied in matters, and VP3 chose + the somewhat strange ordering used below.*/ + while(fragi0<fragi0_end){ + ptrdiff_t fragi; + ptrdiff_t fragi_end; + fragi=fragi0; + fragi_end=fragi+nhfrags; + while(fragi<fragi_end){ + if(frags[fragi].coded){ + unsigned char *ref; + ref=ref_frame_data+frag_buf_offs[fragi]; + if(fragi>fragi0){ + OC_LOOP_FILTER_H(OC_LOOP_FILTER8_MMX,ref,ystride,ll); + } + if(fragi0>fragi_top){ + OC_LOOP_FILTER_V(OC_LOOP_FILTER8_MMX,ref,ystride,ll); + } + if(fragi+1<fragi_end&&!frags[fragi+1].coded){ + OC_LOOP_FILTER_H(OC_LOOP_FILTER8_MMX,ref+8,ystride,ll); + } + if(fragi+nhfrags<fragi_bot&&!frags[fragi+nhfrags].coded){ + OC_LOOP_FILTER_V(OC_LOOP_FILTER8_MMX,ref+(ystride<<3),ystride,ll); + } + } + fragi++; + } + fragi0+=nhfrags; + } +} + +void oc_loop_filter_init_mmxext(signed char _bv[256],int _flimit){ + memset(_bv,~(_flimit<<1),8); +} + +/*Apply the loop filter to a given set of fragment rows in the given plane. + The filter may be run on the bottom edge, affecting pixels in the next row of + fragments, so this row also needs to be available. + _bv: The bounding values array. + _refi: The index of the frame buffer to filter. + _pli: The color plane to filter. + _fragy0: The Y coordinate of the first fragment row to filter. + _fragy_end: The Y coordinate of the fragment row to stop filtering at.*/ +void oc_state_loop_filter_frag_rows_mmxext(const oc_theora_state *_state, + signed char _bv[256],int _refi,int _pli,int _fragy0,int _fragy_end){ + const oc_fragment_plane *fplane; + const oc_fragment *frags; + const ptrdiff_t *frag_buf_offs; + unsigned char *ref_frame_data; + ptrdiff_t fragi_top; + ptrdiff_t fragi_bot; + ptrdiff_t fragi0; + ptrdiff_t fragi0_end; + int ystride; + int nhfrags; + fplane=_state->fplanes+_pli; + nhfrags=fplane->nhfrags; + fragi_top=fplane->froffset; + fragi_bot=fragi_top+fplane->nfrags; + fragi0=fragi_top+_fragy0*(ptrdiff_t)nhfrags; + fragi0_end=fragi_top+_fragy_end*(ptrdiff_t)nhfrags; + ystride=_state->ref_ystride[_pli]; + frags=_state->frags; + frag_buf_offs=_state->frag_buf_offs; + ref_frame_data=_state->ref_frame_data[_refi]; + /*The following loops are constructed somewhat non-intuitively on purpose. + The main idea is: if a block boundary has at least one coded fragment on + it, the filter is applied to it. + However, the order that the filters are applied in matters, and VP3 chose + the somewhat strange ordering used below.*/ + while(fragi0<fragi0_end){ + ptrdiff_t fragi; + ptrdiff_t fragi_end; + fragi=fragi0; + fragi_end=fragi+nhfrags; + while(fragi<fragi_end){ + if(frags[fragi].coded){ + unsigned char *ref; + ref=ref_frame_data+frag_buf_offs[fragi]; + if(fragi>fragi0){ + OC_LOOP_FILTER_H(OC_LOOP_FILTER8_MMXEXT,ref,ystride,_bv); + } + if(fragi0>fragi_top){ + OC_LOOP_FILTER_V(OC_LOOP_FILTER8_MMXEXT,ref,ystride,_bv); + } + if(fragi+1<fragi_end&&!frags[fragi+1].coded){ + OC_LOOP_FILTER_H(OC_LOOP_FILTER8_MMXEXT,ref+8,ystride,_bv); + } + if(fragi+nhfrags<fragi_bot&&!frags[fragi+nhfrags].coded){ + OC_LOOP_FILTER_V(OC_LOOP_FILTER8_MMXEXT,ref+(ystride<<3),ystride,_bv); + } + } + fragi++; + } + fragi0+=nhfrags; + } +} + +#endif diff --git a/media/libtheora/lib/x86/sse2idct.c b/media/libtheora/lib/x86/sse2idct.c new file mode 100644 index 0000000000..4597ab074f --- /dev/null +++ b/media/libtheora/lib/x86/sse2idct.c @@ -0,0 +1,456 @@ +/******************************************************************** + * * + * THIS FILE IS PART OF THE OggTheora SOFTWARE CODEC SOURCE CODE. * + * USE, DISTRIBUTION AND REPRODUCTION OF THIS LIBRARY SOURCE IS * + * GOVERNED BY A BSD-STYLE SOURCE LICENSE INCLUDED WITH THIS SOURCE * + * IN 'COPYING'. PLEASE READ THESE TERMS BEFORE DISTRIBUTING. * + * * + * THE Theora SOURCE CODE IS COPYRIGHT (C) 2002-2009 * + * by the Xiph.Org Foundation and contributors http://www.xiph.org/ * + * * + ******************************************************************** + + function: + last mod: $Id: mmxidct.c 16503 2009-08-22 18:14:02Z giles $ + + ********************************************************************/ + +/*SSE2 acceleration of Theora's iDCT.*/ +#include "x86int.h" +#include "sse2trans.h" +#include "../dct.h" + +#if defined(OC_X86_ASM) + +/*A table of constants used by the MMX routines.*/ +const unsigned short __attribute__((aligned(16),used)) OC_IDCT_CONSTS[64]={ + 8, 8, 8, 8, 8, 8, 8, 8, + OC_C1S7,OC_C1S7,OC_C1S7,OC_C1S7,OC_C1S7,OC_C1S7,OC_C1S7,OC_C1S7, + OC_C2S6,OC_C2S6,OC_C2S6,OC_C2S6,OC_C2S6,OC_C2S6,OC_C2S6,OC_C2S6, + OC_C3S5,OC_C3S5,OC_C3S5,OC_C3S5,OC_C3S5,OC_C3S5,OC_C3S5,OC_C3S5, + OC_C4S4,OC_C4S4,OC_C4S4,OC_C4S4,OC_C4S4,OC_C4S4,OC_C4S4,OC_C4S4, + OC_C5S3,OC_C5S3,OC_C5S3,OC_C5S3,OC_C5S3,OC_C5S3,OC_C5S3,OC_C5S3, + OC_C6S2,OC_C6S2,OC_C6S2,OC_C6S2,OC_C6S2,OC_C6S2,OC_C6S2,OC_C6S2, + OC_C7S1,OC_C7S1,OC_C7S1,OC_C7S1,OC_C7S1,OC_C7S1,OC_C7S1,OC_C7S1 +}; + + +/*Performs the first three stages of the iDCT. + xmm2, xmm6, xmm3, and xmm5 must contain the corresponding rows of the input + (accessed in that order). + The remaining rows must be in _x at their corresponding locations. + On output, xmm7 down to xmm4 contain rows 0 through 3, and xmm0 up to xmm3 + contain rows 4 through 7.*/ +#define OC_IDCT_8x8_ABC(_x) \ + "#OC_IDCT_8x8_ABC\n\t" \ + /*Stage 1:*/ \ + /*2-3 rotation by 6pi/16. \ + xmm4=xmm7=C6, xmm0=xmm1=C2, xmm2=X2, xmm6=X6.*/ \ + "movdqa "OC_MEM_OFFS(0x20,c)",%%xmm1\n\t" \ + "movdqa "OC_MEM_OFFS(0x60,c)",%%xmm4\n\t" \ + "movdqa %%xmm1,%%xmm0\n\t" \ + "pmulhw %%xmm2,%%xmm1\n\t" \ + "movdqa %%xmm4,%%xmm7\n\t" \ + "pmulhw %%xmm6,%%xmm0\n\t" \ + "pmulhw %%xmm2,%%xmm7\n\t" \ + "pmulhw %%xmm6,%%xmm4\n\t" \ + "paddw %%xmm6,%%xmm0\n\t" \ + "movdqa "OC_MEM_OFFS(0x30,c)",%%xmm6\n\t" \ + "paddw %%xmm1,%%xmm2\n\t" \ + "psubw %%xmm0,%%xmm7\n\t" \ + "movdqa %%xmm7,"OC_MEM_OFFS(0x00,buf)"\n\t" \ + "paddw %%xmm4,%%xmm2\n\t" \ + "movdqa "OC_MEM_OFFS(0x50,c)",%%xmm4\n\t" \ + "movdqa %%xmm2,"OC_MEM_OFFS(0x10,buf)"\n\t" \ + /*5-6 rotation by 3pi/16. \ + xmm4=xmm2=C5, xmm1=xmm6=C3, xmm3=X3, xmm5=X5.*/ \ + "movdqa %%xmm4,%%xmm2\n\t" \ + "movdqa %%xmm6,%%xmm1\n\t" \ + "pmulhw %%xmm3,%%xmm4\n\t" \ + "pmulhw %%xmm5,%%xmm1\n\t" \ + "pmulhw %%xmm3,%%xmm6\n\t" \ + "pmulhw %%xmm5,%%xmm2\n\t" \ + "paddw %%xmm3,%%xmm4\n\t" \ + "paddw %%xmm5,%%xmm3\n\t" \ + "paddw %%xmm6,%%xmm3\n\t" \ + "movdqa "OC_MEM_OFFS(0x70,_x)",%%xmm6\n\t" \ + "paddw %%xmm5,%%xmm1\n\t" \ + "movdqa "OC_MEM_OFFS(0x10,_x)",%%xmm5\n\t" \ + "paddw %%xmm3,%%xmm2\n\t" \ + "movdqa "OC_MEM_OFFS(0x70,c)",%%xmm3\n\t" \ + "psubw %%xmm4,%%xmm1\n\t" \ + "movdqa "OC_MEM_OFFS(0x10,c)",%%xmm4\n\t" \ + /*4-7 rotation by 7pi/16. \ + xmm4=xmm7=C1, xmm3=xmm0=C7, xmm5=X1, xmm6=X7.*/ \ + "movdqa %%xmm3,%%xmm0\n\t" \ + "movdqa %%xmm4,%%xmm7\n\t" \ + "pmulhw %%xmm5,%%xmm3\n\t" \ + "pmulhw %%xmm5,%%xmm7\n\t" \ + "pmulhw %%xmm6,%%xmm4\n\t" \ + "pmulhw %%xmm6,%%xmm0\n\t" \ + "paddw %%xmm6,%%xmm4\n\t" \ + "movdqa "OC_MEM_OFFS(0x40,_x)",%%xmm6\n\t" \ + "paddw %%xmm5,%%xmm7\n\t" \ + "psubw %%xmm4,%%xmm3\n\t" \ + "movdqa "OC_MEM_OFFS(0x40,c)",%%xmm4\n\t" \ + "paddw %%xmm7,%%xmm0\n\t" \ + "movdqa "OC_MEM_OFFS(0x00,_x)",%%xmm7\n\t" \ + /*0-1 butterfly. \ + xmm4=xmm5=C4, xmm7=X0, xmm6=X4.*/ \ + "paddw %%xmm7,%%xmm6\n\t" \ + "movdqa %%xmm4,%%xmm5\n\t" \ + "pmulhw %%xmm6,%%xmm4\n\t" \ + "paddw %%xmm7,%%xmm7\n\t" \ + "psubw %%xmm6,%%xmm7\n\t" \ + "paddw %%xmm6,%%xmm4\n\t" \ + /*Stage 2:*/ \ + /*4-5 butterfly: xmm3=t[4], xmm1=t[5] \ + 7-6 butterfly: xmm2=t[6], xmm0=t[7]*/ \ + "movdqa %%xmm3,%%xmm6\n\t" \ + "paddw %%xmm1,%%xmm3\n\t" \ + "psubw %%xmm1,%%xmm6\n\t" \ + "movdqa %%xmm5,%%xmm1\n\t" \ + "pmulhw %%xmm7,%%xmm5\n\t" \ + "paddw %%xmm7,%%xmm5\n\t" \ + "movdqa %%xmm0,%%xmm7\n\t" \ + "paddw %%xmm2,%%xmm0\n\t" \ + "psubw %%xmm2,%%xmm7\n\t" \ + "movdqa %%xmm1,%%xmm2\n\t" \ + "pmulhw %%xmm6,%%xmm1\n\t" \ + "pmulhw %%xmm7,%%xmm2\n\t" \ + "paddw %%xmm6,%%xmm1\n\t" \ + "movdqa "OC_MEM_OFFS(0x00,buf)",%%xmm6\n\t" \ + "paddw %%xmm7,%%xmm2\n\t" \ + "movdqa "OC_MEM_OFFS(0x10,buf)",%%xmm7\n\t" \ + /*Stage 3: \ + 6-5 butterfly: xmm1=t[5], xmm2=t[6] -> xmm1=t[6]+t[5], xmm2=t[6]-t[5] \ + 0-3 butterfly: xmm4=t[0], xmm7=t[3] -> xmm7=t[0]+t[3], xmm4=t[0]-t[3] \ + 1-2 butterfly: xmm5=t[1], xmm6=t[2] -> xmm6=t[1]+t[2], xmm5=t[1]-t[2]*/ \ + "paddw %%xmm2,%%xmm1\n\t" \ + "paddw %%xmm5,%%xmm6\n\t" \ + "paddw %%xmm4,%%xmm7\n\t" \ + "paddw %%xmm2,%%xmm2\n\t" \ + "paddw %%xmm4,%%xmm4\n\t" \ + "paddw %%xmm5,%%xmm5\n\t" \ + "psubw %%xmm1,%%xmm2\n\t" \ + "psubw %%xmm7,%%xmm4\n\t" \ + "psubw %%xmm6,%%xmm5\n\t" \ + +/*Performs the last stage of the iDCT. + On input, xmm7 down to xmm4 contain rows 0 through 3, and xmm0 up to xmm3 + contain rows 4 through 7. + On output, xmm0 through xmm7 contain the corresponding rows.*/ +#define OC_IDCT_8x8_D \ + "#OC_IDCT_8x8_D\n\t" \ + /*Stage 4: \ + 0-7 butterfly: xmm7=t[0], xmm0=t[7] -> xmm0=t[0]+t[7], xmm7=t[0]-t[7] \ + 1-6 butterfly: xmm6=t[1], xmm1=t[6] -> xmm1=t[1]+t[6], xmm6=t[1]-t[6] \ + 2-5 butterfly: xmm5=t[2], xmm2=t[5] -> xmm2=t[2]+t[5], xmm5=t[2]-t[5] \ + 3-4 butterfly: xmm4=t[3], xmm3=t[4] -> xmm3=t[3]+t[4], xmm4=t[3]-t[4]*/ \ + "psubw %%xmm0,%%xmm7\n\t" \ + "psubw %%xmm1,%%xmm6\n\t" \ + "psubw %%xmm2,%%xmm5\n\t" \ + "psubw %%xmm3,%%xmm4\n\t" \ + "paddw %%xmm0,%%xmm0\n\t" \ + "paddw %%xmm1,%%xmm1\n\t" \ + "paddw %%xmm2,%%xmm2\n\t" \ + "paddw %%xmm3,%%xmm3\n\t" \ + "paddw %%xmm7,%%xmm0\n\t" \ + "paddw %%xmm6,%%xmm1\n\t" \ + "paddw %%xmm5,%%xmm2\n\t" \ + "paddw %%xmm4,%%xmm3\n\t" \ + +/*Performs the last stage of the iDCT. + On input, xmm7 down to xmm4 contain rows 0 through 3, and xmm0 up to xmm3 + contain rows 4 through 7. + On output, xmm0 through xmm7 contain the corresponding rows.*/ +#define OC_IDCT_8x8_D_STORE \ + "#OC_IDCT_8x8_D_STORE\n\t" \ + /*Stage 4: \ + 0-7 butterfly: xmm7=t[0], xmm0=t[7] -> xmm0=t[0]+t[7], xmm7=t[0]-t[7] \ + 1-6 butterfly: xmm6=t[1], xmm1=t[6] -> xmm1=t[1]+t[6], xmm6=t[1]-t[6] \ + 2-5 butterfly: xmm5=t[2], xmm2=t[5] -> xmm2=t[2]+t[5], xmm5=t[2]-t[5] \ + 3-4 butterfly: xmm4=t[3], xmm3=t[4] -> xmm3=t[3]+t[4], xmm4=t[3]-t[4]*/ \ + "psubw %%xmm3,%%xmm4\n\t" \ + "movdqa %%xmm4,"OC_MEM_OFFS(0x40,y)"\n\t" \ + "movdqa "OC_MEM_OFFS(0x00,c)",%%xmm4\n\t" \ + "psubw %%xmm0,%%xmm7\n\t" \ + "psubw %%xmm1,%%xmm6\n\t" \ + "psubw %%xmm2,%%xmm5\n\t" \ + "paddw %%xmm4,%%xmm7\n\t" \ + "paddw %%xmm4,%%xmm6\n\t" \ + "paddw %%xmm4,%%xmm5\n\t" \ + "paddw "OC_MEM_OFFS(0x40,y)",%%xmm4\n\t" \ + "paddw %%xmm0,%%xmm0\n\t" \ + "paddw %%xmm1,%%xmm1\n\t" \ + "paddw %%xmm2,%%xmm2\n\t" \ + "paddw %%xmm3,%%xmm3\n\t" \ + "paddw %%xmm7,%%xmm0\n\t" \ + "paddw %%xmm6,%%xmm1\n\t" \ + "psraw $4,%%xmm0\n\t" \ + "paddw %%xmm5,%%xmm2\n\t" \ + "movdqa %%xmm0,"OC_MEM_OFFS(0x00,y)"\n\t" \ + "psraw $4,%%xmm1\n\t" \ + "paddw %%xmm4,%%xmm3\n\t" \ + "movdqa %%xmm1,"OC_MEM_OFFS(0x10,y)"\n\t" \ + "psraw $4,%%xmm2\n\t" \ + "movdqa %%xmm2,"OC_MEM_OFFS(0x20,y)"\n\t" \ + "psraw $4,%%xmm3\n\t" \ + "movdqa %%xmm3,"OC_MEM_OFFS(0x30,y)"\n\t" \ + "psraw $4,%%xmm4\n\t" \ + "movdqa %%xmm4,"OC_MEM_OFFS(0x40,y)"\n\t" \ + "psraw $4,%%xmm5\n\t" \ + "movdqa %%xmm5,"OC_MEM_OFFS(0x50,y)"\n\t" \ + "psraw $4,%%xmm6\n\t" \ + "movdqa %%xmm6,"OC_MEM_OFFS(0x60,y)"\n\t" \ + "psraw $4,%%xmm7\n\t" \ + "movdqa %%xmm7,"OC_MEM_OFFS(0x70,y)"\n\t" \ + +static void oc_idct8x8_slow_sse2(ogg_int16_t _y[64],ogg_int16_t _x[64]){ + OC_ALIGN16(ogg_int16_t buf[16]); + int i; + /*This routine accepts an 8x8 matrix pre-transposed.*/ + __asm__ __volatile__( + /*Load rows 2, 3, 5, and 6 for the first stage of the iDCT.*/ + "movdqa "OC_MEM_OFFS(0x20,x)",%%xmm2\n\t" + "movdqa "OC_MEM_OFFS(0x60,x)",%%xmm6\n\t" + "movdqa "OC_MEM_OFFS(0x30,x)",%%xmm3\n\t" + "movdqa "OC_MEM_OFFS(0x50,x)",%%xmm5\n\t" + OC_IDCT_8x8_ABC(x) + OC_IDCT_8x8_D + OC_TRANSPOSE_8x8 + /*Clear out rows 0, 1, 4, and 7 for the first stage of the iDCT.*/ + "movdqa %%xmm7,"OC_MEM_OFFS(0x70,y)"\n\t" + "movdqa %%xmm4,"OC_MEM_OFFS(0x40,y)"\n\t" + "movdqa %%xmm1,"OC_MEM_OFFS(0x10,y)"\n\t" + "movdqa %%xmm0,"OC_MEM_OFFS(0x00,y)"\n\t" + OC_IDCT_8x8_ABC(y) + OC_IDCT_8x8_D_STORE + :[buf]"=m"(OC_ARRAY_OPERAND(ogg_int16_t,buf,16)), + [y]"=m"(OC_ARRAY_OPERAND(ogg_int16_t,_y,64)) + :[x]"m"(OC_CONST_ARRAY_OPERAND(ogg_int16_t,_x,64)), + [c]"m"(OC_CONST_ARRAY_OPERAND(ogg_int16_t,OC_IDCT_CONSTS,128)) + ); + __asm__ __volatile__("pxor %%xmm0,%%xmm0\n\t"::); + /*Clear input data for next block (decoder only).*/ + for(i=0;i<2;i++){ + __asm__ __volatile__( + "movdqa %%xmm0,"OC_MEM_OFFS(0x00,x)"\n\t" + "movdqa %%xmm0,"OC_MEM_OFFS(0x10,x)"\n\t" + "movdqa %%xmm0,"OC_MEM_OFFS(0x20,x)"\n\t" + "movdqa %%xmm0,"OC_MEM_OFFS(0x30,x)"\n\t" + :[x]"=m"(OC_ARRAY_OPERAND(ogg_int16_t,_x+i*32,32)) + ); + } +} + +/*For the first step of the 10-coefficient version of the 8x8 iDCT, we only + need to work with four columns at a time. + Doing this in MMX is faster on processors with a 64-bit data path.*/ +#define OC_IDCT_8x8_10_MMX \ + "#OC_IDCT_8x8_10_MMX\n\t" \ + /*Stage 1:*/ \ + /*2-3 rotation by 6pi/16. \ + mm7=C6, mm6=C2, mm2=X2, X6=0.*/ \ + "movq "OC_MEM_OFFS(0x60,c)",%%mm7\n\t" \ + "movq "OC_MEM_OFFS(0x20,c)",%%mm6\n\t" \ + "pmulhw %%mm2,%%mm6\n\t" \ + "pmulhw %%mm2,%%mm7\n\t" \ + "movq "OC_MEM_OFFS(0x50,c)",%%mm5\n\t" \ + "paddw %%mm6,%%mm2\n\t" \ + "movq %%mm2,"OC_MEM_OFFS(0x10,buf)"\n\t" \ + "movq "OC_MEM_OFFS(0x30,c)",%%mm2\n\t" \ + "movq %%mm7,"OC_MEM_OFFS(0x00,buf)"\n\t" \ + /*5-6 rotation by 3pi/16. \ + mm5=C5, mm2=C3, mm3=X3, X5=0.*/ \ + "pmulhw %%mm3,%%mm5\n\t" \ + "pmulhw %%mm3,%%mm2\n\t" \ + "movq "OC_MEM_OFFS(0x10,c)",%%mm7\n\t" \ + "paddw %%mm3,%%mm5\n\t" \ + "paddw %%mm3,%%mm2\n\t" \ + "movq "OC_MEM_OFFS(0x70,c)",%%mm3\n\t" \ + /*4-7 rotation by 7pi/16. \ + mm7=C1, mm3=C7, mm1=X1, X7=0.*/ \ + "pmulhw %%mm1,%%mm3\n\t" \ + "pmulhw %%mm1,%%mm7\n\t" \ + "movq "OC_MEM_OFFS(0x40,c)",%%mm4\n\t" \ + "movq %%mm3,%%mm6\n\t" \ + "paddw %%mm1,%%mm7\n\t" \ + /*0-1 butterfly. \ + mm4=C4, mm0=X0, X4=0.*/ \ + /*Stage 2:*/ \ + /*4-5 butterfly: mm3=t[4], mm5=t[5] \ + 7-6 butterfly: mm2=t[6], mm7=t[7]*/ \ + "psubw %%mm5,%%mm3\n\t" \ + "paddw %%mm5,%%mm6\n\t" \ + "movq %%mm4,%%mm1\n\t" \ + "pmulhw %%mm0,%%mm4\n\t" \ + "paddw %%mm0,%%mm4\n\t" \ + "movq %%mm7,%%mm0\n\t" \ + "movq %%mm4,%%mm5\n\t" \ + "paddw %%mm2,%%mm0\n\t" \ + "psubw %%mm2,%%mm7\n\t" \ + "movq %%mm1,%%mm2\n\t" \ + "pmulhw %%mm6,%%mm1\n\t" \ + "pmulhw %%mm7,%%mm2\n\t" \ + "paddw %%mm6,%%mm1\n\t" \ + "movq "OC_MEM_OFFS(0x00,buf)",%%mm6\n\t" \ + "paddw %%mm7,%%mm2\n\t" \ + "movq "OC_MEM_OFFS(0x10,buf)",%%mm7\n\t" \ + /*Stage 3: \ + 6-5 butterfly: mm1=t[5], mm2=t[6] -> mm1=t[6]+t[5], mm2=t[6]-t[5] \ + 0-3 butterfly: mm4=t[0], mm7=t[3] -> mm7=t[0]+t[3], mm4=t[0]-t[3] \ + 1-2 butterfly: mm5=t[1], mm6=t[2] -> mm6=t[1]+t[2], mm5=t[1]-t[2]*/ \ + "paddw %%mm2,%%mm1\n\t" \ + "paddw %%mm5,%%mm6\n\t" \ + "paddw %%mm4,%%mm7\n\t" \ + "paddw %%mm2,%%mm2\n\t" \ + "paddw %%mm4,%%mm4\n\t" \ + "paddw %%mm5,%%mm5\n\t" \ + "psubw %%mm1,%%mm2\n\t" \ + "psubw %%mm7,%%mm4\n\t" \ + "psubw %%mm6,%%mm5\n\t" \ + /*Stage 4: \ + 0-7 butterfly: mm7=t[0], mm0=t[7] -> mm0=t[0]+t[7], mm7=t[0]-t[7] \ + 1-6 butterfly: mm6=t[1], mm1=t[6] -> mm1=t[1]+t[6], mm6=t[1]-t[6] \ + 2-5 butterfly: mm5=t[2], mm2=t[5] -> mm2=t[2]+t[5], mm5=t[2]-t[5] \ + 3-4 butterfly: mm4=t[3], mm3=t[4] -> mm3=t[3]+t[4], mm4=t[3]-t[4]*/ \ + "psubw %%mm0,%%mm7\n\t" \ + "psubw %%mm1,%%mm6\n\t" \ + "psubw %%mm2,%%mm5\n\t" \ + "psubw %%mm3,%%mm4\n\t" \ + "paddw %%mm0,%%mm0\n\t" \ + "paddw %%mm1,%%mm1\n\t" \ + "paddw %%mm2,%%mm2\n\t" \ + "paddw %%mm3,%%mm3\n\t" \ + "paddw %%mm7,%%mm0\n\t" \ + "paddw %%mm6,%%mm1\n\t" \ + "paddw %%mm5,%%mm2\n\t" \ + "paddw %%mm4,%%mm3\n\t" \ + +#define OC_IDCT_8x8_10_ABC \ + "#OC_IDCT_8x8_10_ABC\n\t" \ + /*Stage 1:*/ \ + /*2-3 rotation by 6pi/16. \ + xmm7=C6, xmm6=C2, xmm2=X2, X6=0.*/ \ + "movdqa "OC_MEM_OFFS(0x60,c)",%%xmm7\n\t" \ + "movdqa "OC_MEM_OFFS(0x20,c)",%%xmm6\n\t" \ + "pmulhw %%xmm2,%%xmm6\n\t" \ + "pmulhw %%xmm2,%%xmm7\n\t" \ + "movdqa "OC_MEM_OFFS(0x50,c)",%%xmm5\n\t" \ + "paddw %%xmm6,%%xmm2\n\t" \ + "movdqa %%xmm2,"OC_MEM_OFFS(0x10,buf)"\n\t" \ + "movdqa "OC_MEM_OFFS(0x30,c)",%%xmm2\n\t" \ + "movdqa %%xmm7,"OC_MEM_OFFS(0x00,buf)"\n\t" \ + /*5-6 rotation by 3pi/16. \ + xmm5=C5, xmm2=C3, xmm3=X3, X5=0.*/ \ + "pmulhw %%xmm3,%%xmm5\n\t" \ + "pmulhw %%xmm3,%%xmm2\n\t" \ + "movdqa "OC_MEM_OFFS(0x10,c)",%%xmm7\n\t" \ + "paddw %%xmm3,%%xmm5\n\t" \ + "paddw %%xmm3,%%xmm2\n\t" \ + "movdqa "OC_MEM_OFFS(0x70,c)",%%xmm3\n\t" \ + /*4-7 rotation by 7pi/16. \ + xmm7=C1, xmm3=C7, xmm1=X1, X7=0.*/ \ + "pmulhw %%xmm1,%%xmm3\n\t" \ + "pmulhw %%xmm1,%%xmm7\n\t" \ + "movdqa "OC_MEM_OFFS(0x40,c)",%%xmm4\n\t" \ + "movdqa %%xmm3,%%xmm6\n\t" \ + "paddw %%xmm1,%%xmm7\n\t" \ + /*0-1 butterfly. \ + xmm4=C4, xmm0=X0, X4=0.*/ \ + /*Stage 2:*/ \ + /*4-5 butterfly: xmm3=t[4], xmm5=t[5] \ + 7-6 butterfly: xmm2=t[6], xmm7=t[7]*/ \ + "psubw %%xmm5,%%xmm3\n\t" \ + "paddw %%xmm5,%%xmm6\n\t" \ + "movdqa %%xmm4,%%xmm1\n\t" \ + "pmulhw %%xmm0,%%xmm4\n\t" \ + "paddw %%xmm0,%%xmm4\n\t" \ + "movdqa %%xmm7,%%xmm0\n\t" \ + "movdqa %%xmm4,%%xmm5\n\t" \ + "paddw %%xmm2,%%xmm0\n\t" \ + "psubw %%xmm2,%%xmm7\n\t" \ + "movdqa %%xmm1,%%xmm2\n\t" \ + "pmulhw %%xmm6,%%xmm1\n\t" \ + "pmulhw %%xmm7,%%xmm2\n\t" \ + "paddw %%xmm6,%%xmm1\n\t" \ + "movdqa "OC_MEM_OFFS(0x00,buf)",%%xmm6\n\t" \ + "paddw %%xmm7,%%xmm2\n\t" \ + "movdqa "OC_MEM_OFFS(0x10,buf)",%%xmm7\n\t" \ + /*Stage 3: \ + 6-5 butterfly: xmm1=t[5], xmm2=t[6] -> xmm1=t[6]+t[5], xmm2=t[6]-t[5] \ + 0-3 butterfly: xmm4=t[0], xmm7=t[3] -> xmm7=t[0]+t[3], xmm4=t[0]-t[3] \ + 1-2 butterfly: xmm5=t[1], xmm6=t[2] -> xmm6=t[1]+t[2], xmm5=t[1]-t[2]*/ \ + "paddw %%xmm2,%%xmm1\n\t" \ + "paddw %%xmm5,%%xmm6\n\t" \ + "paddw %%xmm4,%%xmm7\n\t" \ + "paddw %%xmm2,%%xmm2\n\t" \ + "paddw %%xmm4,%%xmm4\n\t" \ + "paddw %%xmm5,%%xmm5\n\t" \ + "psubw %%xmm1,%%xmm2\n\t" \ + "psubw %%xmm7,%%xmm4\n\t" \ + "psubw %%xmm6,%%xmm5\n\t" \ + +static void oc_idct8x8_10_sse2(ogg_int16_t _y[64],ogg_int16_t _x[64]){ + OC_ALIGN16(ogg_int16_t buf[16]); + /*This routine accepts an 8x8 matrix pre-transposed.*/ + __asm__ __volatile__( + "movq "OC_MEM_OFFS(0x20,x)",%%mm2\n\t" + "movq "OC_MEM_OFFS(0x30,x)",%%mm3\n\t" + "movq "OC_MEM_OFFS(0x10,x)",%%mm1\n\t" + "movq "OC_MEM_OFFS(0x00,x)",%%mm0\n\t" + OC_IDCT_8x8_10_MMX + OC_TRANSPOSE_8x4_MMX2SSE + OC_IDCT_8x8_10_ABC + OC_IDCT_8x8_D_STORE + :[buf]"=m"(OC_ARRAY_OPERAND(short,buf,16)), + [y]"=m"(OC_ARRAY_OPERAND(ogg_int16_t,_y,64)) + :[x]"m"OC_CONST_ARRAY_OPERAND(ogg_int16_t,_x,64), + [c]"m"(OC_CONST_ARRAY_OPERAND(ogg_int16_t,OC_IDCT_CONSTS,128)) + ); + /*Clear input data for next block (decoder only).*/ + __asm__ __volatile__( + "pxor %%mm0,%%mm0\n\t" + "movq %%mm0,"OC_MEM_OFFS(0x00,x)"\n\t" + "movq %%mm0,"OC_MEM_OFFS(0x10,x)"\n\t" + "movq %%mm0,"OC_MEM_OFFS(0x20,x)"\n\t" + "movq %%mm0,"OC_MEM_OFFS(0x30,x)"\n\t" + :[x]"+m"(OC_ARRAY_OPERAND(ogg_int16_t,_x,28)) + ); +} + +/*Performs an inverse 8x8 Type-II DCT transform. + The input is assumed to be scaled by a factor of 4 relative to orthonormal + version of the transform.*/ +void oc_idct8x8_sse2(ogg_int16_t _y[64],ogg_int16_t _x[64],int _last_zzi){ + /*_last_zzi is subtly different from an actual count of the number of + coefficients we decoded for this block. + It contains the value of zzi BEFORE the final token in the block was + decoded. + In most cases this is an EOB token (the continuation of an EOB run from a + previous block counts), and so this is the same as the coefficient count. + However, in the case that the last token was NOT an EOB token, but filled + the block up with exactly 64 coefficients, _last_zzi will be less than 64. + Provided the last token was not a pure zero run, the minimum value it can + be is 46, and so that doesn't affect any of the cases in this routine. + However, if the last token WAS a pure zero run of length 63, then _last_zzi + will be 1 while the number of coefficients decoded is 64. + Thus, we will trigger the following special case, where the real + coefficient count would not. + Note also that a zero run of length 64 will give _last_zzi a value of 0, + but we still process the DC coefficient, which might have a non-zero value + due to DC prediction. + Although convoluted, this is arguably the correct behavior: it allows us to + use a smaller transform when the block ends with a long zero run instead + of a normal EOB token. + It could be smarter... multiple separate zero runs at the end of a block + will fool it, but an encoder that generates these really deserves what it + gets. + Needless to say we inherited this approach from VP3.*/ + /*Then perform the iDCT.*/ + if(_last_zzi<=10)oc_idct8x8_10_sse2(_y,_x); + else oc_idct8x8_slow_sse2(_y,_x); +} + +#endif diff --git a/media/libtheora/lib/x86/sse2trans.h b/media/libtheora/lib/x86/sse2trans.h new file mode 100644 index 0000000000..e76da5140b --- /dev/null +++ b/media/libtheora/lib/x86/sse2trans.h @@ -0,0 +1,242 @@ +/******************************************************************** + * * + * THIS FILE IS PART OF THE OggTheora SOFTWARE CODEC SOURCE CODE. * + * USE, DISTRIBUTION AND REPRODUCTION OF THIS LIBRARY SOURCE IS * + * GOVERNED BY A BSD-STYLE SOURCE LICENSE INCLUDED WITH THIS SOURCE * + * IN 'COPYING'. PLEASE READ THESE TERMS BEFORE DISTRIBUTING. * + * * + * THE Theora SOURCE CODE IS COPYRIGHT (C) 2002-2009 * + * by the Xiph.Org Foundation and contributors http://www.xiph.org/ * + * * + ******************************************************************** + + function: + last mod: $Id: sse2trans.h 15675 2009-02-06 09:43:27Z tterribe $ + + ********************************************************************/ + +#if !defined(_x86_sse2trans_H) +# define _x86_sse2trans_H (1) +# include "x86int.h" + +# if defined(OC_X86_64_ASM) +/*On x86-64 we can transpose in-place without spilling registers. + By clever choices of the order to apply the butterflies and the order of + their outputs, we can take the rows in order and output the columns in order + without any extra operations and using just one temporary register.*/ +# define OC_TRANSPOSE_8x8 \ + "#OC_TRANSPOSE_8x8\n\t" \ + "movdqa %%xmm4,%%xmm8\n\t" \ + /*xmm4 = f3 e3 f2 e2 f1 e1 f0 e0*/ \ + "punpcklwd %%xmm5,%%xmm4\n\t" \ + /*xmm8 = f7 e7 f6 e6 f5 e5 f4 e4*/ \ + "punpckhwd %%xmm5,%%xmm8\n\t" \ + /*xmm5 is free.*/ \ + "movdqa %%xmm0,%%xmm5\n\t" \ + /*xmm0 = b3 a3 b2 a2 b1 a1 b0 a0*/ \ + "punpcklwd %%xmm1,%%xmm0\n\t" \ + /*xmm5 = b7 a7 b6 a6 b5 a5 b4 a4*/ \ + "punpckhwd %%xmm1,%%xmm5\n\t" \ + /*xmm1 is free.*/ \ + "movdqa %%xmm6,%%xmm1\n\t" \ + /*xmm6 = h3 g3 h2 g2 h1 g1 h0 g0*/ \ + "punpcklwd %%xmm7,%%xmm6\n\t" \ + /*xmm1 = h7 g7 h6 g6 h5 g5 h4 g4*/ \ + "punpckhwd %%xmm7,%%xmm1\n\t" \ + /*xmm7 is free.*/ \ + "movdqa %%xmm2,%%xmm7\n\t" \ + /*xmm2 = d7 c7 d6 c6 d5 c5 d4 c4*/ \ + "punpckhwd %%xmm3,%%xmm2\n\t" \ + /*xmm7 = d3 c3 d2 c2 d1 c1 d0 c0*/ \ + "punpcklwd %%xmm3,%%xmm7\n\t" \ + /*xmm3 is free.*/ \ + "movdqa %%xmm0,%%xmm3\n\t" \ + /*xmm0 = d1 c1 b1 a1 d0 c0 b0 a0*/ \ + "punpckldq %%xmm7,%%xmm0\n\t" \ + /*xmm3 = d3 c3 b3 a3 d2 c2 b2 a2*/ \ + "punpckhdq %%xmm7,%%xmm3\n\t" \ + /*xmm7 is free.*/ \ + "movdqa %%xmm5,%%xmm7\n\t" \ + /*xmm5 = d5 c5 b5 a5 d4 c4 b4 a4*/ \ + "punpckldq %%xmm2,%%xmm5\n\t" \ + /*xmm7 = d7 c7 b7 a7 d6 c6 b6 a6*/ \ + "punpckhdq %%xmm2,%%xmm7\n\t" \ + /*xmm2 is free.*/ \ + "movdqa %%xmm4,%%xmm2\n\t" \ + /*xmm4 = h3 g3 f3 e3 h2 g2 f2 e2*/ \ + "punpckhdq %%xmm6,%%xmm4\n\t" \ + /*xmm2 = h1 g1 f1 e1 h0 g0 f0 e0*/ \ + "punpckldq %%xmm6,%%xmm2\n\t" \ + /*xmm6 is free.*/ \ + "movdqa %%xmm8,%%xmm6\n\t" \ + /*xmm6 = h5 g5 f5 e5 h4 g4 f4 e4*/ \ + "punpckldq %%xmm1,%%xmm6\n\t" \ + /*xmm8 = h7 g7 f7 e7 h6 g6 f6 e6*/ \ + "punpckhdq %%xmm1,%%xmm8\n\t" \ + /*xmm1 is free.*/ \ + "movdqa %%xmm0,%%xmm1\n\t" \ + /*xmm0 = h0 g0 f0 e0 d0 c0 b0 a0*/ \ + "punpcklqdq %%xmm2,%%xmm0\n\t" \ + /*xmm1 = h1 g1 f1 e1 d1 c1 b1 a1*/ \ + "punpckhqdq %%xmm2,%%xmm1\n\t" \ + /*xmm2 is free.*/ \ + "movdqa %%xmm3,%%xmm2\n\t" \ + /*xmm3 = h3 g3 f3 e3 d3 c3 b3 a3*/ \ + "punpckhqdq %%xmm4,%%xmm3\n\t" \ + /*xmm2 = h2 g2 f2 e2 d2 c2 b2 a2*/ \ + "punpcklqdq %%xmm4,%%xmm2\n\t" \ + /*xmm4 is free.*/ \ + "movdqa %%xmm5,%%xmm4\n\t" \ + /*xmm5 = h5 g5 f5 e5 d5 c5 b5 a5*/ \ + "punpckhqdq %%xmm6,%%xmm5\n\t" \ + /*xmm4 = h4 g4 f4 e4 d4 c4 b4 a4*/ \ + "punpcklqdq %%xmm6,%%xmm4\n\t" \ + /*xmm6 is free.*/ \ + "movdqa %%xmm7,%%xmm6\n\t" \ + /*xmm7 = h7 g7 f7 e7 d7 c7 b7 a7*/ \ + "punpckhqdq %%xmm8,%%xmm7\n\t" \ + /*xmm6 = h6 g6 f6 e6 d6 c6 b6 a6*/ \ + "punpcklqdq %%xmm8,%%xmm6\n\t" \ + /*xmm8 is free.*/ \ + +# else +/*Otherwise, we need to spill some values to %[buf] temporarily. + Again, the butterflies are carefully arranged to get the columns to come out + in order, minimizing register spills and maximizing the delay between a load + and when the value loaded is actually used.*/ +# define OC_TRANSPOSE_8x8 \ + "#OC_TRANSPOSE_8x8\n\t" \ + /*buf[0] = a7 a6 a5 a4 a3 a2 a1 a0*/ \ + "movdqa %%xmm0,"OC_MEM_OFFS(0x00,buf)"\n\t" \ + /*xmm0 is free.*/ \ + "movdqa %%xmm2,%%xmm0\n\t" \ + /*xmm2 = d7 c7 d6 c6 d5 c5 d4 c4*/ \ + "punpckhwd %%xmm3,%%xmm2\n\t" \ + /*xmm0 = d3 c3 d2 c2 d1 c1 d0 c0*/ \ + "punpcklwd %%xmm3,%%xmm0\n\t" \ + /*xmm3 = a7 a6 a5 a4 a3 a2 a1 a0*/ \ + "movdqa "OC_MEM_OFFS(0x00,buf)",%%xmm3\n\t" \ + /*buf[1] = d7 c7 d6 c6 d5 c5 d4 c4*/ \ + "movdqa %%xmm2,"OC_MEM_OFFS(0x10,buf)"\n\t" \ + /*xmm2 is free.*/ \ + "movdqa %%xmm6,%%xmm2\n\t" \ + /*xmm6 = h3 g3 h2 g2 h1 g1 h0 g0*/ \ + "punpcklwd %%xmm7,%%xmm6\n\t" \ + /*xmm2 = h7 g7 h6 g6 h5 g5 h4 g4*/ \ + "punpckhwd %%xmm7,%%xmm2\n\t" \ + /*xmm7 is free.*/ \ + "movdqa %%xmm4,%%xmm7\n\t" \ + /*xmm4 = f3 e3 f2 e2 f1 e1 f0 e0*/ \ + "punpcklwd %%xmm5,%%xmm4\n\t" \ + /*xmm7 = f7 e7 f6 e6 f5 e5 f4 e4*/ \ + "punpckhwd %%xmm5,%%xmm7\n\t" \ + /*xmm5 is free.*/ \ + "movdqa %%xmm3,%%xmm5\n\t" \ + /*xmm3 = b3 a3 b2 a2 b1 a1 b0 a0*/ \ + "punpcklwd %%xmm1,%%xmm3\n\t" \ + /*xmm5 = b7 a7 b6 a6 b5 a5 b4 a4*/ \ + "punpckhwd %%xmm1,%%xmm5\n\t" \ + /*xmm1 is free.*/ \ + "movdqa %%xmm7,%%xmm1\n\t" \ + /*xmm7 = h5 g5 f5 e5 h4 g4 f4 e4*/ \ + "punpckldq %%xmm2,%%xmm7\n\t" \ + /*xmm1 = h7 g7 f7 e7 h6 g6 f6 e6*/ \ + "punpckhdq %%xmm2,%%xmm1\n\t" \ + /*xmm2 = d7 c7 d6 c6 d5 c5 d4 c4*/ \ + "movdqa "OC_MEM_OFFS(0x10,buf)",%%xmm2\n\t" \ + /*buf[0] = h7 g7 f7 e7 h6 g6 f6 e6*/ \ + "movdqa %%xmm1,"OC_MEM_OFFS(0x00,buf)"\n\t" \ + /*xmm1 is free.*/ \ + "movdqa %%xmm3,%%xmm1\n\t" \ + /*xmm3 = d3 c3 b3 a3 d2 c2 b2 a2*/ \ + "punpckhdq %%xmm0,%%xmm3\n\t" \ + /*xmm1 = d1 c1 b1 a1 d0 c0 b0 a0*/ \ + "punpckldq %%xmm0,%%xmm1\n\t" \ + /*xmm0 is free.*/ \ + "movdqa %%xmm4,%%xmm0\n\t" \ + /*xmm4 = h3 g3 f3 e3 h2 g2 f2 e2*/ \ + "punpckhdq %%xmm6,%%xmm4\n\t" \ + /*xmm0 = h1 g1 f1 e1 h0 g0 f0 e0*/ \ + "punpckldq %%xmm6,%%xmm0\n\t" \ + /*xmm6 is free.*/ \ + "movdqa %%xmm5,%%xmm6\n\t" \ + /*xmm5 = d5 c5 b5 a5 d4 c4 b4 a4*/ \ + "punpckldq %%xmm2,%%xmm5\n\t" \ + /*xmm6 = d7 c7 b7 a7 d6 c6 b6 a6*/ \ + "punpckhdq %%xmm2,%%xmm6\n\t" \ + /*xmm2 is free.*/ \ + "movdqa %%xmm1,%%xmm2\n\t" \ + /*xmm1 = h1 g1 f1 e1 d1 c1 b1 a1*/ \ + "punpckhqdq %%xmm0,%%xmm1\n\t" \ + /*xmm2 = h0 g0 f0 e0 d0 c0 b0 a0*/ \ + "punpcklqdq %%xmm0,%%xmm2\n\t" \ + /*xmm0 = h7 g7 f7 e7 h6 g6 f6 e6*/ \ + "movdqa "OC_MEM_OFFS(0x00,buf)",%%xmm0\n\t" \ + /*buf[1] = h0 g0 f0 e0 d0 c0 b0 a0*/ \ + "movdqa %%xmm2,"OC_MEM_OFFS(0x10,buf)"\n\t" \ + /*xmm2 is free.*/ \ + "movdqa %%xmm3,%%xmm2\n\t" \ + /*xmm3 = h3 g3 f3 e3 d3 c3 b3 a3*/ \ + "punpckhqdq %%xmm4,%%xmm3\n\t" \ + /*xmm2 = h2 g2 f2 e2 d2 c2 b2 a2*/ \ + "punpcklqdq %%xmm4,%%xmm2\n\t" \ + /*xmm4 is free.*/ \ + "movdqa %%xmm5,%%xmm4\n\t" \ + /*xmm5 = h5 g5 f5 e5 d5 c5 b5 a5*/ \ + "punpckhqdq %%xmm7,%%xmm5\n\t" \ + /*xmm4 = h4 g4 f4 e4 d4 c4 b4 a4*/ \ + "punpcklqdq %%xmm7,%%xmm4\n\t" \ + /*xmm7 is free.*/ \ + "movdqa %%xmm6,%%xmm7\n\t" \ + /*xmm6 = h6 g6 f6 e6 d6 c6 b6 a6*/ \ + "punpcklqdq %%xmm0,%%xmm6\n\t" \ + /*xmm7 = h7 g7 f7 e7 d7 c7 b7 a7*/ \ + "punpckhqdq %%xmm0,%%xmm7\n\t" \ + /*xmm0 = h0 g0 f0 e0 d0 c0 b0 a0*/ \ + "movdqa "OC_MEM_OFFS(0x10,buf)",%%xmm0\n\t" \ + +# endif + +/*Transpose 4 values in each of 8 MMX registers into 8 values in the first + four SSE registers. + No need to be clever here; we have plenty of room.*/ +# define OC_TRANSPOSE_8x4_MMX2SSE \ + "#OC_TRANSPOSE_8x4_MMX2SSE\n\t" \ + "movq2dq %%mm0,%%xmm0\n\t" \ + "movq2dq %%mm1,%%xmm1\n\t" \ + /*xmmA = b3 a3 b2 a2 b1 a1 b0 a0*/ \ + "punpcklwd %%xmm1,%%xmm0\n\t" \ + "movq2dq %%mm2,%%xmm3\n\t" \ + "movq2dq %%mm3,%%xmm2\n\t" \ + /*xmmC = d3 c3 d2 c2 d1 c1 d0 c0*/ \ + "punpcklwd %%xmm2,%%xmm3\n\t" \ + "movq2dq %%mm4,%%xmm4\n\t" \ + "movq2dq %%mm5,%%xmm5\n\t" \ + /*xmmE = f3 e3 f2 e2 f1 e1 f0 e0*/ \ + "punpcklwd %%xmm5,%%xmm4\n\t" \ + "movq2dq %%mm6,%%xmm7\n\t" \ + "movq2dq %%mm7,%%xmm6\n\t" \ + /*xmmG = h3 g3 h2 g2 h1 g1 h0 g0*/ \ + "punpcklwd %%xmm6,%%xmm7\n\t" \ + "movdqa %%xmm0,%%xmm2\n\t" \ + /*xmm0 = d1 c1 b1 a1 d0 c0 b0 a0*/ \ + "punpckldq %%xmm3,%%xmm0\n\t" \ + /*xmm2 = d3 c3 b3 a3 d2 c2 b2 a2*/ \ + "punpckhdq %%xmm3,%%xmm2\n\t" \ + "movdqa %%xmm4,%%xmm5\n\t" \ + /*xmm4 = h1 g1 f1 e1 h0 g0 f0 e0*/ \ + "punpckldq %%xmm7,%%xmm4\n\t" \ + /*xmm3 = h3 g3 f3 e3 h2 g2 f2 e2*/ \ + "punpckhdq %%xmm7,%%xmm5\n\t" \ + "movdqa %%xmm0,%%xmm1\n\t" \ + /*xmm0 = h0 g0 f0 e0 d0 c0 b0 a0*/ \ + "punpcklqdq %%xmm4,%%xmm0\n\t" \ + /*xmm1 = h1 g1 f1 e1 d1 c1 b1 a1*/ \ + "punpckhqdq %%xmm4,%%xmm1\n\t" \ + "movdqa %%xmm2,%%xmm3\n\t" \ + /*xmm2 = h2 g2 f2 e2 d2 c2 b2 a2*/ \ + "punpcklqdq %%xmm5,%%xmm2\n\t" \ + /*xmm3 = h3 g3 f3 e3 d3 c3 b3 a3*/ \ + "punpckhqdq %%xmm5,%%xmm3\n\t" \ + +#endif diff --git a/media/libtheora/lib/x86/x86cpu.c b/media/libtheora/lib/x86/x86cpu.c new file mode 100644 index 0000000000..49fd76d0ac --- /dev/null +++ b/media/libtheora/lib/x86/x86cpu.c @@ -0,0 +1,182 @@ +/******************************************************************** + * * + * THIS FILE IS PART OF THE OggTheora SOFTWARE CODEC SOURCE CODE. * + * USE, DISTRIBUTION AND REPRODUCTION OF THIS LIBRARY SOURCE IS * + * GOVERNED BY A BSD-STYLE SOURCE LICENSE INCLUDED WITH THIS SOURCE * + * IN 'COPYING'. PLEASE READ THESE TERMS BEFORE DISTRIBUTING. * + * * + * THE Theora SOURCE CODE IS COPYRIGHT (C) 2002-2009 * + * by the Xiph.Org Foundation and contributors http://www.xiph.org/ * + * * + ******************************************************************** + + CPU capability detection for x86 processors. + Originally written by Rudolf Marek. + + function: + last mod: $Id$ + + ********************************************************************/ + +#include "x86cpu.h" + +#if !defined(OC_X86_ASM) +ogg_uint32_t oc_cpu_flags_get(void){ + return 0; +} +#else +# if defined(__amd64__)||defined(__x86_64__) +/*On x86-64, gcc seems to be able to figure out how to save %rbx for us when + compiling with -fPIC.*/ +# define cpuid(_op,_eax,_ebx,_ecx,_edx) \ + __asm__ __volatile__( \ + "cpuid\n\t" \ + :[eax]"=a"(_eax),[ebx]"=b"(_ebx),[ecx]"=c"(_ecx),[edx]"=d"(_edx) \ + :"a"(_op) \ + :"cc" \ + ) +# else +/*On x86-32, not so much.*/ +# define cpuid(_op,_eax,_ebx,_ecx,_edx) \ + __asm__ __volatile__( \ + "xchgl %%ebx,%[ebx]\n\t" \ + "cpuid\n\t" \ + "xchgl %%ebx,%[ebx]\n\t" \ + :[eax]"=a"(_eax),[ebx]"=r"(_ebx),[ecx]"=c"(_ecx),[edx]"=d"(_edx) \ + :"a"(_op) \ + :"cc" \ + ) +# endif + +static ogg_uint32_t oc_parse_intel_flags(ogg_uint32_t _edx,ogg_uint32_t _ecx){ + ogg_uint32_t flags; + /*If there isn't even MMX, give up.*/ + if(!(_edx&0x00800000))return 0; + flags=OC_CPU_X86_MMX; + if(_edx&0x02000000)flags|=OC_CPU_X86_MMXEXT|OC_CPU_X86_SSE; + if(_edx&0x04000000)flags|=OC_CPU_X86_SSE2; + if(_ecx&0x00000001)flags|=OC_CPU_X86_PNI; + if(_ecx&0x00000100)flags|=OC_CPU_X86_SSSE3; + if(_ecx&0x00080000)flags|=OC_CPU_X86_SSE4_1; + if(_ecx&0x00100000)flags|=OC_CPU_X86_SSE4_2; + return flags; +} + +static ogg_uint32_t oc_parse_amd_flags(ogg_uint32_t _edx,ogg_uint32_t _ecx){ + ogg_uint32_t flags; + /*If there isn't even MMX, give up.*/ + if(!(_edx&0x00800000))return 0; + flags=OC_CPU_X86_MMX; + if(_edx&0x00400000)flags|=OC_CPU_X86_MMXEXT; + if(_edx&0x80000000)flags|=OC_CPU_X86_3DNOW; + if(_edx&0x40000000)flags|=OC_CPU_X86_3DNOWEXT; + if(_ecx&0x00000040)flags|=OC_CPU_X86_SSE4A; + if(_ecx&0x00000800)flags|=OC_CPU_X86_SSE5; + return flags; +} + +ogg_uint32_t oc_cpu_flags_get(void){ + ogg_uint32_t flags; + ogg_uint32_t eax; + ogg_uint32_t ebx; + ogg_uint32_t ecx; + ogg_uint32_t edx; +# if !defined(__amd64__)&&!defined(__x86_64__) + /*Not all x86-32 chips support cpuid, so we have to check.*/ + __asm__ __volatile__( + "pushfl\n\t" + "pushfl\n\t" + "popl %[a]\n\t" + "movl %[a],%[b]\n\t" + "xorl $0x200000,%[a]\n\t" + "pushl %[a]\n\t" + "popfl\n\t" + "pushfl\n\t" + "popl %[a]\n\t" + "popfl\n\t" + :[a]"=r"(eax),[b]"=r"(ebx) + : + :"cc" + ); + /*No cpuid.*/ + if(eax==ebx)return 0; +# endif + cpuid(0,eax,ebx,ecx,edx); + /* l e t n I e n i u n e G*/ + if(ecx==0x6C65746E&&edx==0x49656E69&&ebx==0x756E6547|| + /* 6 8 x M T e n i u n e G*/ + ecx==0x3638784D&&edx==0x54656E69&&ebx==0x756E6547){ + int family; + int model; + /*Intel, Transmeta (tested with Crusoe TM5800):*/ + cpuid(1,eax,ebx,ecx,edx); + flags=oc_parse_intel_flags(edx,ecx); + family=(eax>>8)&0xF; + model=(eax>>4)&0xF; + /*The SSE unit on the Pentium M and Core Duo is much slower than the MMX + unit, so don't use it.*/ + if(family==6&&(model==9||model==13||model==14)){ + flags&=~(OC_CPU_X86_SSE2|OC_CPU_X86_PNI); + } + } + /* D M A c i t n e h t u A*/ + else if(ecx==0x444D4163&&edx==0x69746E65&&ebx==0x68747541|| + /* C S N y b e d o e G*/ + ecx==0x43534e20&&edx==0x79622065&&ebx==0x646f6547){ + /*AMD, Geode:*/ + cpuid(0x80000000,eax,ebx,ecx,edx); + if(eax<0x80000001)flags=0; + else{ + cpuid(0x80000001,eax,ebx,ecx,edx); + flags=oc_parse_amd_flags(edx,ecx); + } + /*Also check for SSE.*/ + cpuid(1,eax,ebx,ecx,edx); + flags|=oc_parse_intel_flags(edx,ecx); + } + /*Technically some VIA chips can be configured in the BIOS to return any + string here the user wants. + There is a special detection method that can be used to identify such + processors, but in my opinion, if the user really wants to change it, they + deserve what they get.*/ + /* s l u a H r u a t n e C*/ + else if(ecx==0x736C7561&&edx==0x48727561&&ebx==0x746E6543){ + /*VIA:*/ + /*I only have documentation for the C7 (Esther) and Isaiah (forthcoming) + chips (thanks to the engineers from Centaur Technology who provided it). + These chips support Intel-like cpuid info. + The C3-2 (Nehemiah) cores appear to, as well.*/ + cpuid(1,eax,ebx,ecx,edx); + flags=oc_parse_intel_flags(edx,ecx); + if(eax>=0x80000001){ + /*The (non-Nehemiah) C3 processors support AMD-like cpuid info. + We need to check this even if the Intel test succeeds to pick up 3DNow! + support on these processors. + Unlike actual AMD processors, we cannot _rely_ on this info, since + some cores (e.g., the 693 stepping of the Nehemiah) claim to support + this function, yet return edx=0, despite the Intel test indicating + MMX support. + Therefore the features detected here are strictly added to those + detected by the Intel test.*/ + /*TODO: How about earlier chips?*/ + cpuid(0x80000001,eax,ebx,ecx,edx); + /*Note: As of the C7, this function returns Intel-style extended feature + flags, not AMD-style. + Currently, this only defines bits 11, 20, and 29 (0x20100800), which + do not conflict with any of the AMD flags we inspect. + For the remaining bits, Intel tells us, "Do not count on their value", + but VIA assures us that they will all be zero (at least on the C7 and + Isaiah chips). + In the (unlikely) event a future processor uses bits 18, 19, 30, or 31 + (0xC0C00000) for something else, we will have to add code to detect + the model to decide when it is appropriate to inspect them.*/ + flags|=oc_parse_amd_flags(edx,ecx); + } + } + else{ + /*Implement me.*/ + flags=0; + } + return flags; +} +#endif diff --git a/media/libtheora/lib/x86/x86cpu.h b/media/libtheora/lib/x86/x86cpu.h new file mode 100644 index 0000000000..e0192d52e2 --- /dev/null +++ b/media/libtheora/lib/x86/x86cpu.h @@ -0,0 +1,36 @@ +/******************************************************************** + * * + * THIS FILE IS PART OF THE OggTheora SOFTWARE CODEC SOURCE CODE. * + * USE, DISTRIBUTION AND REPRODUCTION OF THIS LIBRARY SOURCE IS * + * GOVERNED BY A BSD-STYLE SOURCE LICENSE INCLUDED WITH THIS SOURCE * + * IN 'COPYING'. PLEASE READ THESE TERMS BEFORE DISTRIBUTING. * + * * + * THE Theora SOURCE CODE IS COPYRIGHT (C) 2002-2009 * + * by the Xiph.Org Foundation and contributors http://www.xiph.org/ * + * * + ******************************************************************** + function: + last mod: $Id$ + + ********************************************************************/ + +#if !defined(_x86_x86cpu_H) +# define _x86_x86cpu_H (1) +#include "../internal.h" + +#define OC_CPU_X86_MMX (1<<0) +#define OC_CPU_X86_3DNOW (1<<1) +#define OC_CPU_X86_3DNOWEXT (1<<2) +#define OC_CPU_X86_MMXEXT (1<<3) +#define OC_CPU_X86_SSE (1<<4) +#define OC_CPU_X86_SSE2 (1<<5) +#define OC_CPU_X86_PNI (1<<6) +#define OC_CPU_X86_SSSE3 (1<<7) +#define OC_CPU_X86_SSE4_1 (1<<8) +#define OC_CPU_X86_SSE4_2 (1<<9) +#define OC_CPU_X86_SSE4A (1<<10) +#define OC_CPU_X86_SSE5 (1<<11) + +ogg_uint32_t oc_cpu_flags_get(void); + +#endif diff --git a/media/libtheora/lib/x86/x86int.h b/media/libtheora/lib/x86/x86int.h new file mode 100644 index 0000000000..ceb2dbb0ec --- /dev/null +++ b/media/libtheora/lib/x86/x86int.h @@ -0,0 +1,122 @@ +/******************************************************************** + * * + * THIS FILE IS PART OF THE OggTheora SOFTWARE CODEC SOURCE CODE. * + * USE, DISTRIBUTION AND REPRODUCTION OF THIS LIBRARY SOURCE IS * + * GOVERNED BY A BSD-STYLE SOURCE LICENSE INCLUDED WITH THIS SOURCE * + * IN 'COPYING'. PLEASE READ THESE TERMS BEFORE DISTRIBUTING. * + * * + * THE Theora SOURCE CODE IS COPYRIGHT (C) 2002-2009 * + * by the Xiph.Org Foundation and contributors http://www.xiph.org/ * + * * + ******************************************************************** + + function: + last mod: $Id$ + + ********************************************************************/ + +#if !defined(_x86_x86int_H) +# define _x86_x86int_H (1) +# include "../internal.h" + +# if defined(OC_X86_ASM) +# define oc_state_accel_init oc_state_accel_init_x86 +# if defined(OC_X86_64_ASM) +/*x86-64 guarantees SIMD support up through at least SSE2. + If the best routine we have available only needs SSE2 (which at the moment + covers all of them), then we can avoid runtime detection and the indirect + call.*/ +# define oc_frag_copy(_state,_dst,_src,_ystride) \ + oc_frag_copy_mmx(_dst,_src,_ystride) +# define oc_frag_copy_list(_state,_dst_frame,_src_frame,_ystride, \ + _fragis,_nfragis,_frag_buf_offs) \ + oc_frag_copy_list_mmx(_dst_frame,_src_frame,_ystride, \ + _fragis,_nfragis,_frag_buf_offs) +# define oc_frag_recon_intra(_state,_dst,_ystride,_residue) \ + oc_frag_recon_intra_mmx(_dst,_ystride,_residue) +# define oc_frag_recon_inter(_state,_dst,_src,_ystride,_residue) \ + oc_frag_recon_inter_mmx(_dst,_src,_ystride,_residue) +# define oc_frag_recon_inter2(_state,_dst,_src1,_src2,_ystride,_residue) \ + oc_frag_recon_inter2_mmx(_dst,_src1,_src2,_ystride,_residue) +# define oc_idct8x8(_state,_y,_x,_last_zzi) \ + oc_idct8x8_sse2(_y,_x,_last_zzi) +# define oc_state_frag_recon oc_state_frag_recon_mmx +# define oc_loop_filter_init(_state,_bv,_flimit) \ + oc_loop_filter_init_mmxext(_bv,_flimit) +# define oc_state_loop_filter_frag_rows oc_state_loop_filter_frag_rows_mmxext +# define oc_restore_fpu(_state) \ + oc_restore_fpu_mmx() +# else +# define OC_STATE_USE_VTABLE (1) +# endif +# endif + +# include "../state.h" +# include "x86cpu.h" + +/*Converts the expression in the argument to a string.*/ +#define OC_M2STR(_s) #_s + +/*Memory operands do not always include an offset. + To avoid warnings, we force an offset with %H (which adds 8).*/ +# if __GNUC_PREREQ(4,0) +# define OC_MEM_OFFS(_offs,_name) \ + OC_M2STR(_offs-8+%H[_name]) +# endif +/*If your gcc version does't support %H, then you get to suffer the warnings. + Note that Apple's gas breaks on things like _offs+(%esp): it throws away the + whole offset, instead of substituting in 0 for the missing operand to +.*/ +# if !defined(OC_MEM_OFFS) +# define OC_MEM_OFFS(_offs,_name) \ + OC_M2STR(_offs+%[_name]) +# endif + +/*Declare an array operand with an exact size. + This tells gcc we're going to clobber this memory region, without having to + clobber all of "memory" and lets us access local buffers directly using the + stack pointer, without allocating a separate register to point to them.*/ +#define OC_ARRAY_OPERAND(_type,_ptr,_size) \ + (*({ \ + struct{_type array_value__[(_size)];} *array_addr__=(void *)(_ptr); \ + array_addr__; \ + })) + +/*Declare an array operand with an exact size. + This tells gcc we're going to clobber this memory region, without having to + clobber all of "memory" and lets us access local buffers directly using the + stack pointer, without allocating a separate register to point to them.*/ +#define OC_CONST_ARRAY_OPERAND(_type,_ptr,_size) \ + (*({ \ + const struct{_type array_value__[(_size)];} *array_addr__= \ + (const void *)(_ptr); \ + array_addr__; \ + })) + +extern const unsigned short __attribute__((aligned(16))) OC_IDCT_CONSTS[64]; + +void oc_state_accel_init_x86(oc_theora_state *_state); + +void oc_frag_copy_mmx(unsigned char *_dst, + const unsigned char *_src,int _ystride); +void oc_frag_copy_list_mmx(unsigned char *_dst_frame, + const unsigned char *_src_frame,int _ystride, + const ptrdiff_t *_fragis,ptrdiff_t _nfragis,const ptrdiff_t *_frag_buf_offs); +void oc_frag_recon_intra_mmx(unsigned char *_dst,int _ystride, + const ogg_int16_t *_residue); +void oc_frag_recon_inter_mmx(unsigned char *_dst, + const unsigned char *_src,int _ystride,const ogg_int16_t *_residue); +void oc_frag_recon_inter2_mmx(unsigned char *_dst,const unsigned char *_src1, + const unsigned char *_src2,int _ystride,const ogg_int16_t *_residue); +void oc_idct8x8_mmx(ogg_int16_t _y[64],ogg_int16_t _x[64],int _last_zzi); +void oc_idct8x8_sse2(ogg_int16_t _y[64],ogg_int16_t _x[64],int _last_zzi); +void oc_state_frag_recon_mmx(const oc_theora_state *_state,ptrdiff_t _fragi, + int _pli,ogg_int16_t _dct_coeffs[128],int _last_zzi,ogg_uint16_t _dc_quant); +void oc_loop_filter_init_mmx(signed char _bv[256],int _flimit); +void oc_loop_filter_init_mmxext(signed char _bv[256],int _flimit); +void oc_state_loop_filter_frag_rows_mmx(const oc_theora_state *_state, + signed char _bv[256],int _refi,int _pli,int _fragy0,int _fragy_end); +void oc_state_loop_filter_frag_rows_mmxext(const oc_theora_state *_state, + signed char _bv[256],int _refi,int _pli,int _fragy0,int _fragy_end); +void oc_restore_fpu_mmx(void); + +#endif diff --git a/media/libtheora/lib/x86/x86state.c b/media/libtheora/lib/x86/x86state.c new file mode 100644 index 0000000000..9f8bceb534 --- /dev/null +++ b/media/libtheora/lib/x86/x86state.c @@ -0,0 +1,97 @@ +/******************************************************************** + * * + * THIS FILE IS PART OF THE OggTheora SOFTWARE CODEC SOURCE CODE. * + * USE, DISTRIBUTION AND REPRODUCTION OF THIS LIBRARY SOURCE IS * + * GOVERNED BY A BSD-STYLE SOURCE LICENSE INCLUDED WITH THIS SOURCE * + * IN 'COPYING'. PLEASE READ THESE TERMS BEFORE DISTRIBUTING. * + * * + * THE Theora SOURCE CODE IS COPYRIGHT (C) 2002-2009 * + * by the Xiph.Org Foundation and contributors http://www.xiph.org/ * + * * + ******************************************************************** + + function: + last mod: $Id$ + + ********************************************************************/ + +#include "x86int.h" + +#if defined(OC_X86_ASM) + +#if defined(OC_STATE_USE_VTABLE) +/*This table has been modified from OC_FZIG_ZAG by baking a 4x4 transpose into + each quadrant of the destination.*/ +static const unsigned char OC_FZIG_ZAG_MMX[128]={ + 0, 8, 1, 2, 9,16,24,17, + 10, 3,32,11,18,25, 4,12, + 5,26,19,40,33,34,41,48, + 27, 6,13,20,28,21,14, 7, + 56,49,42,35,43,50,57,36, + 15,22,29,30,23,44,37,58, + 51,59,38,45,52,31,60,53, + 46,39,47,54,61,62,55,63, + 64,64,64,64,64,64,64,64, + 64,64,64,64,64,64,64,64, + 64,64,64,64,64,64,64,64, + 64,64,64,64,64,64,64,64, + 64,64,64,64,64,64,64,64, + 64,64,64,64,64,64,64,64, + 64,64,64,64,64,64,64,64, + 64,64,64,64,64,64,64,64 +}; +#endif + +/*This table has been modified from OC_FZIG_ZAG by baking an 8x8 transpose into + the destination.*/ +static const unsigned char OC_FZIG_ZAG_SSE2[128]={ + 0, 8, 1, 2, 9,16,24,17, + 10, 3, 4,11,18,25,32,40, + 33,26,19,12, 5, 6,13,20, + 27,34,41,48,56,49,42,35, + 28,21,14, 7,15,22,29,36, + 43,50,57,58,51,44,37,30, + 23,31,38,45,52,59,60,53, + 46,39,47,54,61,62,55,63, + 64,64,64,64,64,64,64,64, + 64,64,64,64,64,64,64,64, + 64,64,64,64,64,64,64,64, + 64,64,64,64,64,64,64,64, + 64,64,64,64,64,64,64,64, + 64,64,64,64,64,64,64,64, + 64,64,64,64,64,64,64,64, + 64,64,64,64,64,64,64,64 +}; + +void oc_state_accel_init_x86(oc_theora_state *_state){ + oc_state_accel_init_c(_state); + _state->cpu_flags=oc_cpu_flags_get(); +# if defined(OC_STATE_USE_VTABLE) + if(_state->cpu_flags&OC_CPU_X86_MMX){ + _state->opt_vtable.frag_copy=oc_frag_copy_mmx; + _state->opt_vtable.frag_copy_list=oc_frag_copy_list_mmx; + _state->opt_vtable.frag_recon_intra=oc_frag_recon_intra_mmx; + _state->opt_vtable.frag_recon_inter=oc_frag_recon_inter_mmx; + _state->opt_vtable.frag_recon_inter2=oc_frag_recon_inter2_mmx; + _state->opt_vtable.idct8x8=oc_idct8x8_mmx; + _state->opt_vtable.state_frag_recon=oc_state_frag_recon_mmx; + _state->opt_vtable.loop_filter_init=oc_loop_filter_init_mmx; + _state->opt_vtable.state_loop_filter_frag_rows= + oc_state_loop_filter_frag_rows_mmx; + _state->opt_vtable.restore_fpu=oc_restore_fpu_mmx; + _state->opt_data.dct_fzig_zag=OC_FZIG_ZAG_MMX; + } + if(_state->cpu_flags&OC_CPU_X86_MMXEXT){ + _state->opt_vtable.loop_filter_init=oc_loop_filter_init_mmxext; + _state->opt_vtable.state_loop_filter_frag_rows= + oc_state_loop_filter_frag_rows_mmxext; + } + if(_state->cpu_flags&OC_CPU_X86_SSE2){ + _state->opt_vtable.idct8x8=oc_idct8x8_sse2; +# endif + _state->opt_data.dct_fzig_zag=OC_FZIG_ZAG_SSE2; +# if defined(OC_STATE_USE_VTABLE) + } +# endif +} +#endif diff --git a/media/libtheora/lib/x86_vc/mmxfrag.c b/media/libtheora/lib/x86_vc/mmxfrag.c new file mode 100644 index 0000000000..248312ff90 --- /dev/null +++ b/media/libtheora/lib/x86_vc/mmxfrag.c @@ -0,0 +1,416 @@ +/******************************************************************** + * * + * THIS FILE IS PART OF THE OggTheora SOFTWARE CODEC SOURCE CODE. * + * USE, DISTRIBUTION AND REPRODUCTION OF THIS LIBRARY SOURCE IS * + * GOVERNED BY A BSD-STYLE SOURCE LICENSE INCLUDED WITH THIS SOURCE * + * IN 'COPYING'. PLEASE READ THESE TERMS BEFORE DISTRIBUTING. * + * * + * THE Theora SOURCE CODE IS COPYRIGHT (C) 2002-2009 * + * by the Xiph.Org Foundation and contributors http://www.xiph.org/ * + * * + ******************************************************************** + + function: + last mod: $Id$ + + ********************************************************************/ + +/*MMX acceleration of fragment reconstruction for motion compensation. + Originally written by Rudolf Marek. + Additional optimization by Nils Pipenbrinck. + Note: Loops are unrolled for best performance. + The iteration each instruction belongs to is marked in the comments as #i.*/ +#include <stddef.h> +#include "x86int.h" + +#if defined(OC_X86_ASM) + +/*Copies an 8x8 block of pixels from _src to _dst, assuming _ystride bytes + between rows.*/ +# define OC_FRAG_COPY_MMX(_dst,_src,_ystride) \ + do{ \ + const unsigned char *src; \ + unsigned char *dst; \ + src=(_src); \ + dst=(_dst); \ + __asm mov SRC,src \ + __asm mov DST,dst \ + __asm mov YSTRIDE,_ystride \ + /*src+0*ystride*/ \ + __asm movq mm0,[SRC] \ + /*src+1*ystride*/ \ + __asm movq mm1,[SRC+YSTRIDE] \ + /*ystride3=ystride*3*/ \ + __asm lea YSTRIDE3,[YSTRIDE+YSTRIDE*2] \ + /*src+2*ystride*/ \ + __asm movq mm2,[SRC+YSTRIDE*2] \ + /*src+3*ystride*/ \ + __asm movq mm3,[SRC+YSTRIDE3] \ + /*dst+0*ystride*/ \ + __asm movq [DST],mm0 \ + /*dst+1*ystride*/ \ + __asm movq [DST+YSTRIDE],mm1 \ + /*Pointer to next 4.*/ \ + __asm lea SRC,[SRC+YSTRIDE*4] \ + /*dst+2*ystride*/ \ + __asm movq [DST+YSTRIDE*2],mm2 \ + /*dst+3*ystride*/ \ + __asm movq [DST+YSTRIDE3],mm3 \ + /*Pointer to next 4.*/ \ + __asm lea DST,[DST+YSTRIDE*4] \ + /*src+0*ystride*/ \ + __asm movq mm0,[SRC] \ + /*src+1*ystride*/ \ + __asm movq mm1,[SRC+YSTRIDE] \ + /*src+2*ystride*/ \ + __asm movq mm2,[SRC+YSTRIDE*2] \ + /*src+3*ystride*/ \ + __asm movq mm3,[SRC+YSTRIDE3] \ + /*dst+0*ystride*/ \ + __asm movq [DST],mm0 \ + /*dst+1*ystride*/ \ + __asm movq [DST+YSTRIDE],mm1 \ + /*dst+2*ystride*/ \ + __asm movq [DST+YSTRIDE*2],mm2 \ + /*dst+3*ystride*/ \ + __asm movq [DST+YSTRIDE3],mm3 \ + } \ + while(0) + +/*Copies an 8x8 block of pixels from _src to _dst, assuming _ystride bytes + between rows.*/ +void oc_frag_copy_mmx(unsigned char *_dst, + const unsigned char *_src,int _ystride){ +#define SRC edx +#define DST eax +#define YSTRIDE ecx +#define YSTRIDE3 esi + OC_FRAG_COPY_MMX(_dst,_src,_ystride); +#undef SRC +#undef DST +#undef YSTRIDE +#undef YSTRIDE3 +} + +/*Copies the fragments specified by the lists of fragment indices from one + frame to another. + _dst_frame: The reference frame to copy to. + _src_frame: The reference frame to copy from. + _ystride: The row stride of the reference frames. + _fragis: A pointer to a list of fragment indices. + _nfragis: The number of fragment indices to copy. + _frag_buf_offs: The offsets of fragments in the reference frames.*/ +void oc_frag_copy_list_mmx(unsigned char *_dst_frame, + const unsigned char *_src_frame,int _ystride, + const ptrdiff_t *_fragis,ptrdiff_t _nfragis,const ptrdiff_t *_frag_buf_offs){ + ptrdiff_t fragii; + for(fragii=0;fragii<_nfragis;fragii++){ + ptrdiff_t frag_buf_off; + frag_buf_off=_frag_buf_offs[_fragis[fragii]]; +#define SRC edx +#define DST eax +#define YSTRIDE ecx +#define YSTRIDE3 edi + OC_FRAG_COPY_MMX(_dst_frame+frag_buf_off, + _src_frame+frag_buf_off,_ystride); +#undef SRC +#undef DST +#undef YSTRIDE +#undef YSTRIDE3 + } +} + +void oc_frag_recon_intra_mmx(unsigned char *_dst,int _ystride, + const ogg_int16_t *_residue){ + __asm{ +#define DST edx +#define DST4 esi +#define YSTRIDE eax +#define YSTRIDE3 edi +#define RESIDUE ecx + mov DST,_dst + mov YSTRIDE,_ystride + mov RESIDUE,_residue + lea DST4,[DST+YSTRIDE*4] + lea YSTRIDE3,[YSTRIDE+YSTRIDE*2] + /*Set mm0 to 0xFFFFFFFFFFFFFFFF.*/ + pcmpeqw mm0,mm0 + /*#0 Load low residue.*/ + movq mm1,[0*8+RESIDUE] + /*#0 Load high residue.*/ + movq mm2,[1*8+RESIDUE] + /*Set mm0 to 0x8000800080008000.*/ + psllw mm0,15 + /*#1 Load low residue.*/ + movq mm3,[2*8+RESIDUE] + /*#1 Load high residue.*/ + movq mm4,[3*8+RESIDUE] + /*Set mm0 to 0x0080008000800080.*/ + psrlw mm0,8 + /*#2 Load low residue.*/ + movq mm5,[4*8+RESIDUE] + /*#2 Load high residue.*/ + movq mm6,[5*8+RESIDUE] + /*#0 Bias low residue.*/ + paddsw mm1,mm0 + /*#0 Bias high residue.*/ + paddsw mm2,mm0 + /*#0 Pack to byte.*/ + packuswb mm1,mm2 + /*#1 Bias low residue.*/ + paddsw mm3,mm0 + /*#1 Bias high residue.*/ + paddsw mm4,mm0 + /*#1 Pack to byte.*/ + packuswb mm3,mm4 + /*#2 Bias low residue.*/ + paddsw mm5,mm0 + /*#2 Bias high residue.*/ + paddsw mm6,mm0 + /*#2 Pack to byte.*/ + packuswb mm5,mm6 + /*#0 Write row.*/ + movq [DST],mm1 + /*#1 Write row.*/ + movq [DST+YSTRIDE],mm3 + /*#2 Write row.*/ + movq [DST+YSTRIDE*2],mm5 + /*#3 Load low residue.*/ + movq mm1,[6*8+RESIDUE] + /*#3 Load high residue.*/ + movq mm2,[7*8+RESIDUE] + /*#4 Load high residue.*/ + movq mm3,[8*8+RESIDUE] + /*#4 Load high residue.*/ + movq mm4,[9*8+RESIDUE] + /*#5 Load high residue.*/ + movq mm5,[10*8+RESIDUE] + /*#5 Load high residue.*/ + movq mm6,[11*8+RESIDUE] + /*#3 Bias low residue.*/ + paddsw mm1,mm0 + /*#3 Bias high residue.*/ + paddsw mm2,mm0 + /*#3 Pack to byte.*/ + packuswb mm1,mm2 + /*#4 Bias low residue.*/ + paddsw mm3,mm0 + /*#4 Bias high residue.*/ + paddsw mm4,mm0 + /*#4 Pack to byte.*/ + packuswb mm3,mm4 + /*#5 Bias low residue.*/ + paddsw mm5,mm0 + /*#5 Bias high residue.*/ + paddsw mm6,mm0 + /*#5 Pack to byte.*/ + packuswb mm5,mm6 + /*#3 Write row.*/ + movq [DST+YSTRIDE3],mm1 + /*#4 Write row.*/ + movq [DST4],mm3 + /*#5 Write row.*/ + movq [DST4+YSTRIDE],mm5 + /*#6 Load low residue.*/ + movq mm1,[12*8+RESIDUE] + /*#6 Load high residue.*/ + movq mm2,[13*8+RESIDUE] + /*#7 Load low residue.*/ + movq mm3,[14*8+RESIDUE] + /*#7 Load high residue.*/ + movq mm4,[15*8+RESIDUE] + /*#6 Bias low residue.*/ + paddsw mm1,mm0 + /*#6 Bias high residue.*/ + paddsw mm2,mm0 + /*#6 Pack to byte.*/ + packuswb mm1,mm2 + /*#7 Bias low residue.*/ + paddsw mm3,mm0 + /*#7 Bias high residue.*/ + paddsw mm4,mm0 + /*#7 Pack to byte.*/ + packuswb mm3,mm4 + /*#6 Write row.*/ + movq [DST4+YSTRIDE*2],mm1 + /*#7 Write row.*/ + movq [DST4+YSTRIDE3],mm3 +#undef DST +#undef DST4 +#undef YSTRIDE +#undef YSTRIDE3 +#undef RESIDUE + } +} + +void oc_frag_recon_inter_mmx(unsigned char *_dst,const unsigned char *_src, + int _ystride,const ogg_int16_t *_residue){ + int i; + /*Zero mm0.*/ + __asm pxor mm0,mm0; + for(i=4;i-->0;){ + __asm{ +#define DST edx +#define SRC ecx +#define YSTRIDE edi +#define RESIDUE eax + mov DST,_dst + mov SRC,_src + mov YSTRIDE,_ystride + mov RESIDUE,_residue + /*#0 Load source.*/ + movq mm3,[SRC] + /*#1 Load source.*/ + movq mm7,[SRC+YSTRIDE] + /*#0 Get copy of src.*/ + movq mm4,mm3 + /*#0 Expand high source.*/ + punpckhbw mm4,mm0 + /*#0 Expand low source.*/ + punpcklbw mm3,mm0 + /*#0 Add residue high.*/ + paddsw mm4,[8+RESIDUE] + /*#1 Get copy of src.*/ + movq mm2,mm7 + /*#0 Add residue low.*/ + paddsw mm3,[RESIDUE] + /*#1 Expand high source.*/ + punpckhbw mm2,mm0 + /*#0 Pack final row pixels.*/ + packuswb mm3,mm4 + /*#1 Expand low source.*/ + punpcklbw mm7,mm0 + /*#1 Add residue low.*/ + paddsw mm7,[16+RESIDUE] + /*#1 Add residue high.*/ + paddsw mm2,[24+RESIDUE] + /*Advance residue.*/ + lea RESIDUE,[32+RESIDUE] + /*#1 Pack final row pixels.*/ + packuswb mm7,mm2 + /*Advance src.*/ + lea SRC,[SRC+YSTRIDE*2] + /*#0 Write row.*/ + movq [DST],mm3 + /*#1 Write row.*/ + movq [DST+YSTRIDE],mm7 + /*Advance dst.*/ + lea DST,[DST+YSTRIDE*2] + mov _residue,RESIDUE + mov _dst,DST + mov _src,SRC +#undef DST +#undef SRC +#undef YSTRIDE +#undef RESIDUE + } + } +} + +void oc_frag_recon_inter2_mmx(unsigned char *_dst,const unsigned char *_src1, + const unsigned char *_src2,int _ystride,const ogg_int16_t *_residue){ + int i; + /*Zero mm7.*/ + __asm pxor mm7,mm7; + for(i=4;i-->0;){ + __asm{ +#define SRC1 ecx +#define SRC2 edi +#define YSTRIDE esi +#define RESIDUE edx +#define DST eax + mov YSTRIDE,_ystride + mov DST,_dst + mov RESIDUE,_residue + mov SRC1,_src1 + mov SRC2,_src2 + /*#0 Load src1.*/ + movq mm0,[SRC1] + /*#0 Load src2.*/ + movq mm2,[SRC2] + /*#0 Copy src1.*/ + movq mm1,mm0 + /*#0 Copy src2.*/ + movq mm3,mm2 + /*#1 Load src1.*/ + movq mm4,[SRC1+YSTRIDE] + /*#0 Unpack lower src1.*/ + punpcklbw mm0,mm7 + /*#1 Load src2.*/ + movq mm5,[SRC2+YSTRIDE] + /*#0 Unpack higher src1.*/ + punpckhbw mm1,mm7 + /*#0 Unpack lower src2.*/ + punpcklbw mm2,mm7 + /*#0 Unpack higher src2.*/ + punpckhbw mm3,mm7 + /*Advance src1 ptr.*/ + lea SRC1,[SRC1+YSTRIDE*2] + /*Advance src2 ptr.*/ + lea SRC2,[SRC2+YSTRIDE*2] + /*#0 Lower src1+src2.*/ + paddsw mm0,mm2 + /*#0 Higher src1+src2.*/ + paddsw mm1,mm3 + /*#1 Copy src1.*/ + movq mm2,mm4 + /*#0 Build lo average.*/ + psraw mm0,1 + /*#1 Copy src2.*/ + movq mm3,mm5 + /*#1 Unpack lower src1.*/ + punpcklbw mm4,mm7 + /*#0 Build hi average.*/ + psraw mm1,1 + /*#1 Unpack higher src1.*/ + punpckhbw mm2,mm7 + /*#0 low+=residue.*/ + paddsw mm0,[RESIDUE] + /*#1 Unpack lower src2.*/ + punpcklbw mm5,mm7 + /*#0 high+=residue.*/ + paddsw mm1,[8+RESIDUE] + /*#1 Unpack higher src2.*/ + punpckhbw mm3,mm7 + /*#1 Lower src1+src2.*/ + paddsw mm5,mm4 + /*#0 Pack and saturate.*/ + packuswb mm0,mm1 + /*#1 Higher src1+src2.*/ + paddsw mm3,mm2 + /*#0 Write row.*/ + movq [DST],mm0 + /*#1 Build lo average.*/ + psraw mm5,1 + /*#1 Build hi average.*/ + psraw mm3,1 + /*#1 low+=residue.*/ + paddsw mm5,[16+RESIDUE] + /*#1 high+=residue.*/ + paddsw mm3,[24+RESIDUE] + /*#1 Pack and saturate.*/ + packuswb mm5,mm3 + /*#1 Write row ptr.*/ + movq [DST+YSTRIDE],mm5 + /*Advance residue ptr.*/ + add RESIDUE,32 + /*Advance dest ptr.*/ + lea DST,[DST+YSTRIDE*2] + mov _dst,DST + mov _residue,RESIDUE + mov _src1,SRC1 + mov _src2,SRC2 +#undef SRC1 +#undef SRC2 +#undef YSTRIDE +#undef RESIDUE +#undef DST + } + } +} + +void oc_restore_fpu_mmx(void){ + __asm emms; +} + +#endif diff --git a/media/libtheora/lib/x86_vc/mmxidct.c b/media/libtheora/lib/x86_vc/mmxidct.c new file mode 100644 index 0000000000..55e00aedcf --- /dev/null +++ b/media/libtheora/lib/x86_vc/mmxidct.c @@ -0,0 +1,592 @@ +/******************************************************************** + * * + * THIS FILE IS PART OF THE OggTheora SOFTWARE CODEC SOURCE CODE. * + * USE, DISTRIBUTION AND REPRODUCTION OF THIS LIBRARY SOURCE IS * + * GOVERNED BY A BSD-STYLE SOURCE LICENSE INCLUDED WITH THIS SOURCE * + * IN 'COPYING'. PLEASE READ THESE TERMS BEFORE DISTRIBUTING. * + * * + * THE Theora SOURCE CODE IS COPYRIGHT (C) 2002-2009 * + * by the Xiph.Org Foundation and contributors http://www.xiph.org/ * + * * + ******************************************************************** + + function: + last mod: $Id$ + + ********************************************************************/ + +/*MMX acceleration of Theora's iDCT. + Originally written by Rudolf Marek, based on code from On2's VP3.*/ +#include "x86int.h" +#include "../dct.h" + +#if defined(OC_X86_ASM) + +/*These are offsets into the table of constants below.*/ +/*7 rows of cosines, in order: pi/16 * (1 ... 7).*/ +#define OC_COSINE_OFFSET (8) +/*A row of 8's.*/ +#define OC_EIGHT_OFFSET (0) + + + +/*A table of constants used by the MMX routines.*/ +static const OC_ALIGN16(ogg_uint16_t) OC_IDCT_CONSTS[(1+7)*4]={ + 8, 8, 8, 8, + (ogg_uint16_t)OC_C1S7,(ogg_uint16_t)OC_C1S7, + (ogg_uint16_t)OC_C1S7,(ogg_uint16_t)OC_C1S7, + (ogg_uint16_t)OC_C2S6,(ogg_uint16_t)OC_C2S6, + (ogg_uint16_t)OC_C2S6,(ogg_uint16_t)OC_C2S6, + (ogg_uint16_t)OC_C3S5,(ogg_uint16_t)OC_C3S5, + (ogg_uint16_t)OC_C3S5,(ogg_uint16_t)OC_C3S5, + (ogg_uint16_t)OC_C4S4,(ogg_uint16_t)OC_C4S4, + (ogg_uint16_t)OC_C4S4,(ogg_uint16_t)OC_C4S4, + (ogg_uint16_t)OC_C5S3,(ogg_uint16_t)OC_C5S3, + (ogg_uint16_t)OC_C5S3,(ogg_uint16_t)OC_C5S3, + (ogg_uint16_t)OC_C6S2,(ogg_uint16_t)OC_C6S2, + (ogg_uint16_t)OC_C6S2,(ogg_uint16_t)OC_C6S2, + (ogg_uint16_t)OC_C7S1,(ogg_uint16_t)OC_C7S1, + (ogg_uint16_t)OC_C7S1,(ogg_uint16_t)OC_C7S1 +}; + +/*38 cycles*/ +#define OC_IDCT_BEGIN(_y,_x) __asm{ \ + __asm movq mm2,OC_I(3,_x) \ + __asm movq mm6,OC_C(3) \ + __asm movq mm4,mm2 \ + __asm movq mm7,OC_J(5,_x) \ + __asm pmulhw mm4,mm6 \ + __asm movq mm1,OC_C(5) \ + __asm pmulhw mm6,mm7 \ + __asm movq mm5,mm1 \ + __asm pmulhw mm1,mm2 \ + __asm movq mm3,OC_I(1,_x) \ + __asm pmulhw mm5,mm7 \ + __asm movq mm0,OC_C(1) \ + __asm paddw mm4,mm2 \ + __asm paddw mm6,mm7 \ + __asm paddw mm2,mm1 \ + __asm movq mm1,OC_J(7,_x) \ + __asm paddw mm7,mm5 \ + __asm movq mm5,mm0 \ + __asm pmulhw mm0,mm3 \ + __asm paddw mm4,mm7 \ + __asm pmulhw mm5,mm1 \ + __asm movq mm7,OC_C(7) \ + __asm psubw mm6,mm2 \ + __asm paddw mm0,mm3 \ + __asm pmulhw mm3,mm7 \ + __asm movq mm2,OC_I(2,_x) \ + __asm pmulhw mm7,mm1 \ + __asm paddw mm5,mm1 \ + __asm movq mm1,mm2 \ + __asm pmulhw mm2,OC_C(2) \ + __asm psubw mm3,mm5 \ + __asm movq mm5,OC_J(6,_x) \ + __asm paddw mm0,mm7 \ + __asm movq mm7,mm5 \ + __asm psubw mm0,mm4 \ + __asm pmulhw mm5,OC_C(2) \ + __asm paddw mm2,mm1 \ + __asm pmulhw mm1,OC_C(6) \ + __asm paddw mm4,mm4 \ + __asm paddw mm4,mm0 \ + __asm psubw mm3,mm6 \ + __asm paddw mm5,mm7 \ + __asm paddw mm6,mm6 \ + __asm pmulhw mm7,OC_C(6) \ + __asm paddw mm6,mm3 \ + __asm movq OC_I(1,_y),mm4 \ + __asm psubw mm1,mm5 \ + __asm movq mm4,OC_C(4) \ + __asm movq mm5,mm3 \ + __asm pmulhw mm3,mm4 \ + __asm paddw mm7,mm2 \ + __asm movq OC_I(2,_y),mm6 \ + __asm movq mm2,mm0 \ + __asm movq mm6,OC_I(0,_x) \ + __asm pmulhw mm0,mm4 \ + __asm paddw mm5,mm3 \ + __asm movq mm3,OC_J(4,_x) \ + __asm psubw mm5,mm1 \ + __asm paddw mm2,mm0 \ + __asm psubw mm6,mm3 \ + __asm movq mm0,mm6 \ + __asm pmulhw mm6,mm4 \ + __asm paddw mm3,mm3 \ + __asm paddw mm1,mm1 \ + __asm paddw mm3,mm0 \ + __asm paddw mm1,mm5 \ + __asm pmulhw mm4,mm3 \ + __asm paddw mm6,mm0 \ + __asm psubw mm6,mm2 \ + __asm paddw mm2,mm2 \ + __asm movq mm0,OC_I(1,_y) \ + __asm paddw mm2,mm6 \ + __asm paddw mm4,mm3 \ + __asm psubw mm2,mm1 \ +} + +/*38+8=46 cycles.*/ +#define OC_ROW_IDCT(_y,_x) __asm{ \ + OC_IDCT_BEGIN(_y,_x) \ + /*r3=D'*/ \ + __asm movq mm3,OC_I(2,_y) \ + /*r4=E'=E-G*/ \ + __asm psubw mm4,mm7 \ + /*r1=H'+H'*/ \ + __asm paddw mm1,mm1 \ + /*r7=G+G*/ \ + __asm paddw mm7,mm7 \ + /*r1=R1=A''+H'*/ \ + __asm paddw mm1,mm2 \ + /*r7=G'=E+G*/ \ + __asm paddw mm7,mm4 \ + /*r4=R4=E'-D'*/ \ + __asm psubw mm4,mm3 \ + __asm paddw mm3,mm3 \ + /*r6=R6=F'-B''*/ \ + __asm psubw mm6,mm5 \ + __asm paddw mm5,mm5 \ + /*r3=R3=E'+D'*/ \ + __asm paddw mm3,mm4 \ + /*r5=R5=F'+B''*/ \ + __asm paddw mm5,mm6 \ + /*r7=R7=G'-C'*/ \ + __asm psubw mm7,mm0 \ + __asm paddw mm0,mm0 \ + /*Save R1.*/ \ + __asm movq OC_I(1,_y),mm1 \ + /*r0=R0=G.+C.*/ \ + __asm paddw mm0,mm7 \ +} + +/*The following macro does two 4x4 transposes in place. + At entry, we assume: + r0 = a3 a2 a1 a0 + I(1) = b3 b2 b1 b0 + r2 = c3 c2 c1 c0 + r3 = d3 d2 d1 d0 + + r4 = e3 e2 e1 e0 + r5 = f3 f2 f1 f0 + r6 = g3 g2 g1 g0 + r7 = h3 h2 h1 h0 + + At exit, we have: + I(0) = d0 c0 b0 a0 + I(1) = d1 c1 b1 a1 + I(2) = d2 c2 b2 a2 + I(3) = d3 c3 b3 a3 + + J(4) = h0 g0 f0 e0 + J(5) = h1 g1 f1 e1 + J(6) = h2 g2 f2 e2 + J(7) = h3 g3 f3 e3 + + I(0) I(1) I(2) I(3) is the transpose of r0 I(1) r2 r3. + J(4) J(5) J(6) J(7) is the transpose of r4 r5 r6 r7. + + Since r1 is free at entry, we calculate the Js first.*/ +/*19 cycles.*/ +#define OC_TRANSPOSE(_y) __asm{ \ + __asm movq mm1,mm4 \ + __asm punpcklwd mm4,mm5 \ + __asm movq OC_I(0,_y),mm0 \ + __asm punpckhwd mm1,mm5 \ + __asm movq mm0,mm6 \ + __asm punpcklwd mm6,mm7 \ + __asm movq mm5,mm4 \ + __asm punpckldq mm4,mm6 \ + __asm punpckhdq mm5,mm6 \ + __asm movq mm6,mm1 \ + __asm movq OC_J(4,_y),mm4 \ + __asm punpckhwd mm0,mm7 \ + __asm movq OC_J(5,_y),mm5 \ + __asm punpckhdq mm6,mm0 \ + __asm movq mm4,OC_I(0,_y) \ + __asm punpckldq mm1,mm0 \ + __asm movq mm5,OC_I(1,_y) \ + __asm movq mm0,mm4 \ + __asm movq OC_J(7,_y),mm6 \ + __asm punpcklwd mm0,mm5 \ + __asm movq OC_J(6,_y),mm1 \ + __asm punpckhwd mm4,mm5 \ + __asm movq mm5,mm2 \ + __asm punpcklwd mm2,mm3 \ + __asm movq mm1,mm0 \ + __asm punpckldq mm0,mm2 \ + __asm punpckhdq mm1,mm2 \ + __asm movq mm2,mm4 \ + __asm movq OC_I(0,_y),mm0 \ + __asm punpckhwd mm5,mm3 \ + __asm movq OC_I(1,_y),mm1 \ + __asm punpckhdq mm4,mm5 \ + __asm punpckldq mm2,mm5 \ + __asm movq OC_I(3,_y),mm4 \ + __asm movq OC_I(2,_y),mm2 \ +} + +/*38+19=57 cycles.*/ +#define OC_COLUMN_IDCT(_y) __asm{ \ + OC_IDCT_BEGIN(_y,_y) \ + __asm paddw mm2,OC_8 \ + /*r1=H'+H'*/ \ + __asm paddw mm1,mm1 \ + /*r1=R1=A''+H'*/ \ + __asm paddw mm1,mm2 \ + /*r2=NR2*/ \ + __asm psraw mm2,4 \ + /*r4=E'=E-G*/ \ + __asm psubw mm4,mm7 \ + /*r1=NR1*/ \ + __asm psraw mm1,4 \ + /*r3=D'*/ \ + __asm movq mm3,OC_I(2,_y) \ + /*r7=G+G*/ \ + __asm paddw mm7,mm7 \ + /*Store NR2 at I(2).*/ \ + __asm movq OC_I(2,_y),mm2 \ + /*r7=G'=E+G*/ \ + __asm paddw mm7,mm4 \ + /*Store NR1 at I(1).*/ \ + __asm movq OC_I(1,_y),mm1 \ + /*r4=R4=E'-D'*/ \ + __asm psubw mm4,mm3 \ + __asm paddw mm4,OC_8 \ + /*r3=D'+D'*/ \ + __asm paddw mm3,mm3 \ + /*r3=R3=E'+D'*/ \ + __asm paddw mm3,mm4 \ + /*r4=NR4*/ \ + __asm psraw mm4,4 \ + /*r6=R6=F'-B''*/ \ + __asm psubw mm6,mm5 \ + /*r3=NR3*/ \ + __asm psraw mm3,4 \ + __asm paddw mm6,OC_8 \ + /*r5=B''+B''*/ \ + __asm paddw mm5,mm5 \ + /*r5=R5=F'+B''*/ \ + __asm paddw mm5,mm6 \ + /*r6=NR6*/ \ + __asm psraw mm6,4 \ + /*Store NR4 at J(4).*/ \ + __asm movq OC_J(4,_y),mm4 \ + /*r5=NR5*/ \ + __asm psraw mm5,4 \ + /*Store NR3 at I(3).*/ \ + __asm movq OC_I(3,_y),mm3 \ + /*r7=R7=G'-C'*/ \ + __asm psubw mm7,mm0 \ + __asm paddw mm7,OC_8 \ + /*r0=C'+C'*/ \ + __asm paddw mm0,mm0 \ + /*r0=R0=G'+C'*/ \ + __asm paddw mm0,mm7 \ + /*r7=NR7*/ \ + __asm psraw mm7,4 \ + /*Store NR6 at J(6).*/ \ + __asm movq OC_J(6,_y),mm6 \ + /*r0=NR0*/ \ + __asm psraw mm0,4 \ + /*Store NR5 at J(5).*/ \ + __asm movq OC_J(5,_y),mm5 \ + /*Store NR7 at J(7).*/ \ + __asm movq OC_J(7,_y),mm7 \ + /*Store NR0 at I(0).*/ \ + __asm movq OC_I(0,_y),mm0 \ +} + +#define OC_MID(_m,_i) [CONSTS+_m+(_i)*8] +#define OC_C(_i) OC_MID(OC_COSINE_OFFSET,_i-1) +#define OC_8 OC_MID(OC_EIGHT_OFFSET,0) + +static void oc_idct8x8_slow(ogg_int16_t _y[64],ogg_int16_t _x[64]){ + int i; + /*This routine accepts an 8x8 matrix, but in partially transposed form. + Every 4x4 block is transposed.*/ + __asm{ +#define CONSTS eax +#define Y edx +#define X ecx + mov CONSTS,offset OC_IDCT_CONSTS + mov Y,_y + mov X,_x +#define OC_I(_k,_y) [(_y)+(_k)*16] +#define OC_J(_k,_y) [(_y)+((_k)-4)*16+8] + OC_ROW_IDCT(Y,X) + OC_TRANSPOSE(Y) +#undef OC_I +#undef OC_J +#define OC_I(_k,_y) [(_y)+(_k)*16+64] +#define OC_J(_k,_y) [(_y)+((_k)-4)*16+72] + OC_ROW_IDCT(Y,X) + OC_TRANSPOSE(Y) +#undef OC_I +#undef OC_J +#define OC_I(_k,_y) [(_y)+(_k)*16] +#define OC_J(_k,_y) OC_I(_k,_y) + OC_COLUMN_IDCT(Y) +#undef OC_I +#undef OC_J +#define OC_I(_k,_y) [(_y)+(_k)*16+8] +#define OC_J(_k,_y) OC_I(_k,_y) + OC_COLUMN_IDCT(Y) +#undef OC_I +#undef OC_J +#undef CONSTS +#undef Y +#undef X + } + __asm pxor mm0,mm0; + for(i=0;i<4;i++){ + ogg_int16_t *x; + x=_x+16*i; +#define X ecx + __asm{ + mov X,x + movq [X+0x00],mm0 + movq [X+0x08],mm0 + movq [X+0x10],mm0 + movq [X+0x18],mm0 + } +#undef X + } +} + +/*25 cycles.*/ +#define OC_IDCT_BEGIN_10(_y,_x) __asm{ \ + __asm movq mm2,OC_I(3,_x) \ + __asm nop \ + __asm movq mm6,OC_C(3) \ + __asm movq mm4,mm2 \ + __asm movq mm1,OC_C(5) \ + __asm pmulhw mm4,mm6 \ + __asm movq mm3,OC_I(1,_x) \ + __asm pmulhw mm1,mm2 \ + __asm movq mm0,OC_C(1) \ + __asm paddw mm4,mm2 \ + __asm pxor mm6,mm6 \ + __asm paddw mm2,mm1 \ + __asm movq mm5,OC_I(2,_x) \ + __asm pmulhw mm0,mm3 \ + __asm movq mm1,mm5 \ + __asm paddw mm0,mm3 \ + __asm pmulhw mm3,OC_C(7) \ + __asm psubw mm6,mm2 \ + __asm pmulhw mm5,OC_C(2) \ + __asm psubw mm0,mm4 \ + __asm movq mm7,OC_I(2,_x) \ + __asm paddw mm4,mm4 \ + __asm paddw mm7,mm5 \ + __asm paddw mm4,mm0 \ + __asm pmulhw mm1,OC_C(6) \ + __asm psubw mm3,mm6 \ + __asm movq OC_I(1,_y),mm4 \ + __asm paddw mm6,mm6 \ + __asm movq mm4,OC_C(4) \ + __asm paddw mm6,mm3 \ + __asm movq mm5,mm3 \ + __asm pmulhw mm3,mm4 \ + __asm movq OC_I(2,_y),mm6 \ + __asm movq mm2,mm0 \ + __asm movq mm6,OC_I(0,_x) \ + __asm pmulhw mm0,mm4 \ + __asm paddw mm5,mm3 \ + __asm paddw mm2,mm0 \ + __asm psubw mm5,mm1 \ + __asm pmulhw mm6,mm4 \ + __asm paddw mm6,OC_I(0,_x) \ + __asm paddw mm1,mm1 \ + __asm movq mm4,mm6 \ + __asm paddw mm1,mm5 \ + __asm psubw mm6,mm2 \ + __asm paddw mm2,mm2 \ + __asm movq mm0,OC_I(1,_y) \ + __asm paddw mm2,mm6 \ + __asm psubw mm2,mm1 \ + __asm nop \ +} + +/*25+8=33 cycles.*/ +#define OC_ROW_IDCT_10(_y,_x) __asm{ \ + OC_IDCT_BEGIN_10(_y,_x) \ + /*r3=D'*/ \ + __asm movq mm3,OC_I(2,_y) \ + /*r4=E'=E-G*/ \ + __asm psubw mm4,mm7 \ + /*r1=H'+H'*/ \ + __asm paddw mm1,mm1 \ + /*r7=G+G*/ \ + __asm paddw mm7,mm7 \ + /*r1=R1=A''+H'*/ \ + __asm paddw mm1,mm2 \ + /*r7=G'=E+G*/ \ + __asm paddw mm7,mm4 \ + /*r4=R4=E'-D'*/ \ + __asm psubw mm4,mm3 \ + __asm paddw mm3,mm3 \ + /*r6=R6=F'-B''*/ \ + __asm psubw mm6,mm5 \ + __asm paddw mm5,mm5 \ + /*r3=R3=E'+D'*/ \ + __asm paddw mm3,mm4 \ + /*r5=R5=F'+B''*/ \ + __asm paddw mm5,mm6 \ + /*r7=R7=G'-C'*/ \ + __asm psubw mm7,mm0 \ + __asm paddw mm0,mm0 \ + /*Save R1.*/ \ + __asm movq OC_I(1,_y),mm1 \ + /*r0=R0=G'+C'*/ \ + __asm paddw mm0,mm7 \ +} + +/*25+19=44 cycles'*/ +#define OC_COLUMN_IDCT_10(_y) __asm{ \ + OC_IDCT_BEGIN_10(_y,_y) \ + __asm paddw mm2,OC_8 \ + /*r1=H'+H'*/ \ + __asm paddw mm1,mm1 \ + /*r1=R1=A''+H'*/ \ + __asm paddw mm1,mm2 \ + /*r2=NR2*/ \ + __asm psraw mm2,4 \ + /*r4=E'=E-G*/ \ + __asm psubw mm4,mm7 \ + /*r1=NR1*/ \ + __asm psraw mm1,4 \ + /*r3=D'*/ \ + __asm movq mm3,OC_I(2,_y) \ + /*r7=G+G*/ \ + __asm paddw mm7,mm7 \ + /*Store NR2 at I(2).*/ \ + __asm movq OC_I(2,_y),mm2 \ + /*r7=G'=E+G*/ \ + __asm paddw mm7,mm4 \ + /*Store NR1 at I(1).*/ \ + __asm movq OC_I(1,_y),mm1 \ + /*r4=R4=E'-D'*/ \ + __asm psubw mm4,mm3 \ + __asm paddw mm4,OC_8 \ + /*r3=D'+D'*/ \ + __asm paddw mm3,mm3 \ + /*r3=R3=E'+D'*/ \ + __asm paddw mm3,mm4 \ + /*r4=NR4*/ \ + __asm psraw mm4,4 \ + /*r6=R6=F'-B''*/ \ + __asm psubw mm6,mm5 \ + /*r3=NR3*/ \ + __asm psraw mm3,4 \ + __asm paddw mm6,OC_8 \ + /*r5=B''+B''*/ \ + __asm paddw mm5,mm5 \ + /*r5=R5=F'+B''*/ \ + __asm paddw mm5,mm6 \ + /*r6=NR6*/ \ + __asm psraw mm6,4 \ + /*Store NR4 at J(4).*/ \ + __asm movq OC_J(4,_y),mm4 \ + /*r5=NR5*/ \ + __asm psraw mm5,4 \ + /*Store NR3 at I(3).*/ \ + __asm movq OC_I(3,_y),mm3 \ + /*r7=R7=G'-C'*/ \ + __asm psubw mm7,mm0 \ + __asm paddw mm7,OC_8 \ + /*r0=C'+C'*/ \ + __asm paddw mm0,mm0 \ + /*r0=R0=G'+C'*/ \ + __asm paddw mm0,mm7 \ + /*r7=NR7*/ \ + __asm psraw mm7,4 \ + /*Store NR6 at J(6).*/ \ + __asm movq OC_J(6,_y),mm6 \ + /*r0=NR0*/ \ + __asm psraw mm0,4 \ + /*Store NR5 at J(5).*/ \ + __asm movq OC_J(5,_y),mm5 \ + /*Store NR7 at J(7).*/ \ + __asm movq OC_J(7,_y),mm7 \ + /*Store NR0 at I(0).*/ \ + __asm movq OC_I(0,_y),mm0 \ +} + +static void oc_idct8x8_10(ogg_int16_t _y[64],ogg_int16_t _x[64]){ + __asm{ +#define CONSTS eax +#define Y edx +#define X ecx + mov CONSTS,offset OC_IDCT_CONSTS + mov Y,_y + mov X,_x +#define OC_I(_k,_y) [(_y)+(_k)*16] +#define OC_J(_k,_y) [(_y)+((_k)-4)*16+8] + /*Done with dequant, descramble, and partial transpose. + Now do the iDCT itself.*/ + OC_ROW_IDCT_10(Y,X) + OC_TRANSPOSE(Y) +#undef OC_I +#undef OC_J +#define OC_I(_k,_y) [(_y)+(_k)*16] +#define OC_J(_k,_y) OC_I(_k,_y) + OC_COLUMN_IDCT_10(Y) +#undef OC_I +#undef OC_J +#define OC_I(_k,_y) [(_y)+(_k)*16+8] +#define OC_J(_k,_y) OC_I(_k,_y) + OC_COLUMN_IDCT_10(Y) +#undef OC_I +#undef OC_J +#undef CONSTS +#undef Y +#undef X + } +#define X ecx + __asm{ + pxor mm0,mm0; + mov X,_x + movq [X+0x00],mm0 + movq [X+0x10],mm0 + movq [X+0x20],mm0 + movq [X+0x30],mm0 + } +#undef X +} + +/*Performs an inverse 8x8 Type-II DCT transform. + The input is assumed to be scaled by a factor of 4 relative to orthonormal + version of the transform.*/ +void oc_idct8x8_mmx(ogg_int16_t _y[64],ogg_int16_t _x[64],int _last_zzi){ + /*_last_zzi is subtly different from an actual count of the number of + coefficients we decoded for this block. + It contains the value of zzi BEFORE the final token in the block was + decoded. + In most cases this is an EOB token (the continuation of an EOB run from a + previous block counts), and so this is the same as the coefficient count. + However, in the case that the last token was NOT an EOB token, but filled + the block up with exactly 64 coefficients, _last_zzi will be less than 64. + Provided the last token was not a pure zero run, the minimum value it can + be is 46, and so that doesn't affect any of the cases in this routine. + However, if the last token WAS a pure zero run of length 63, then _last_zzi + will be 1 while the number of coefficients decoded is 64. + Thus, we will trigger the following special case, where the real + coefficient count would not. + Note also that a zero run of length 64 will give _last_zzi a value of 0, + but we still process the DC coefficient, which might have a non-zero value + due to DC prediction. + Although convoluted, this is arguably the correct behavior: it allows us to + use a smaller transform when the block ends with a long zero run instead + of a normal EOB token. + It could be smarter... multiple separate zero runs at the end of a block + will fool it, but an encoder that generates these really deserves what it + gets. + Needless to say we inherited this approach from VP3.*/ + /*Perform the iDCT.*/ + if(_last_zzi<=10)oc_idct8x8_10(_y,_x); + else oc_idct8x8_slow(_y,_x); +} + +#endif diff --git a/media/libtheora/lib/x86_vc/mmxloop.h b/media/libtheora/lib/x86_vc/mmxloop.h new file mode 100644 index 0000000000..2561fca2ae --- /dev/null +++ b/media/libtheora/lib/x86_vc/mmxloop.h @@ -0,0 +1,219 @@ +#if !defined(_x86_vc_mmxloop_H) +# define _x86_vc_mmxloop_H (1) +# include <stddef.h> +# include "x86int.h" + +#if defined(OC_X86_ASM) + +/*On entry, mm0={a0,...,a7}, mm1={b0,...,b7}, mm2={c0,...,c7}, mm3={d0,...d7}. + On exit, mm1={b0+lflim(R_0,L),...,b7+lflim(R_7,L)} and + mm2={c0-lflim(R_0,L),...,c7-lflim(R_7,L)}; mm0 and mm3 are clobbered.*/ +#define OC_LOOP_FILTER8_MMX __asm{ \ + /*mm7=0*/ \ + __asm pxor mm7,mm7 \ + /*mm6:mm0={a0,...,a7}*/ \ + __asm movq mm6,mm0 \ + __asm punpcklbw mm0,mm7 \ + __asm punpckhbw mm6,mm7 \ + /*mm3:mm5={d0,...,d7}*/ \ + __asm movq mm5,mm3 \ + __asm punpcklbw mm3,mm7 \ + __asm punpckhbw mm5,mm7 \ + /*mm6:mm0={a0-d0,...,a7-d7}*/ \ + __asm psubw mm0,mm3 \ + __asm psubw mm6,mm5 \ + /*mm3:mm1={b0,...,b7}*/ \ + __asm movq mm3,mm1 \ + __asm punpcklbw mm1,mm7 \ + __asm movq mm4,mm2 \ + __asm punpckhbw mm3,mm7 \ + /*mm5:mm4={c0,...,c7}*/ \ + __asm movq mm5,mm2 \ + __asm punpcklbw mm4,mm7 \ + __asm punpckhbw mm5,mm7 \ + /*mm7={3}x4 \ + mm5:mm4={c0-b0,...,c7-b7}*/ \ + __asm pcmpeqw mm7,mm7 \ + __asm psubw mm4,mm1 \ + __asm psrlw mm7,14 \ + __asm psubw mm5,mm3 \ + /*Scale by 3.*/ \ + __asm pmullw mm4,mm7 \ + __asm pmullw mm5,mm7 \ + /*mm7={4}x4 \ + mm5:mm4=f={a0-d0+3*(c0-b0),...,a7-d7+3*(c7-b7)}*/ \ + __asm psrlw mm7,1 \ + __asm paddw mm4,mm0 \ + __asm psllw mm7,2 \ + __asm movq mm0,[LL] \ + __asm paddw mm5,mm6 \ + /*R_i has the range [-127,128], so we compute -R_i instead. \ + mm4=-R_i=-(f+4>>3)=0xFF^(f-4>>3)*/ \ + __asm psubw mm4,mm7 \ + __asm psubw mm5,mm7 \ + __asm psraw mm4,3 \ + __asm psraw mm5,3 \ + __asm pcmpeqb mm7,mm7 \ + __asm packsswb mm4,mm5 \ + __asm pxor mm6,mm6 \ + __asm pxor mm4,mm7 \ + __asm packuswb mm1,mm3 \ + /*Now compute lflim of -mm4 cf. Section 7.10 of the sepc.*/ \ + /*There's no unsigned byte+signed byte with unsigned saturation op code, so \ + we have to split things by sign (the other option is to work in 16 bits, \ + but working in 8 bits gives much better parallelism). \ + We compute abs(R_i), but save a mask of which terms were negative in mm6. \ + Then we compute mm4=abs(lflim(R_i,L))=min(abs(R_i),max(2*L-abs(R_i),0)). \ + Finally, we split mm4 into positive and negative pieces using the mask in \ + mm6, and add and subtract them as appropriate.*/ \ + /*mm4=abs(-R_i)*/ \ + /*mm7=255-2*L*/ \ + __asm pcmpgtb mm6,mm4 \ + __asm psubb mm7,mm0 \ + __asm pxor mm4,mm6 \ + __asm psubb mm7,mm0 \ + __asm psubb mm4,mm6 \ + /*mm7=255-max(2*L-abs(R_i),0)*/ \ + __asm paddusb mm7,mm4 \ + /*mm4=min(abs(R_i),max(2*L-abs(R_i),0))*/ \ + __asm paddusb mm4,mm7 \ + __asm psubusb mm4,mm7 \ + /*Now split mm4 by the original sign of -R_i.*/ \ + __asm movq mm5,mm4 \ + __asm pand mm4,mm6 \ + __asm pandn mm6,mm5 \ + /*mm1={b0+lflim(R_0,L),...,b7+lflim(R_7,L)}*/ \ + /*mm2={c0-lflim(R_0,L),...,c7-lflim(R_7,L)}*/ \ + __asm paddusb mm1,mm4 \ + __asm psubusb mm2,mm4 \ + __asm psubusb mm1,mm6 \ + __asm paddusb mm2,mm6 \ +} + +#define OC_LOOP_FILTER_V_MMX(_pix,_ystride,_ll) \ + do{ \ + /*Used local variable pix__ in order to fix compilation errors like: \ + "error C2425: 'SHL' : non-constant expression in 'second operand'".*/ \ + unsigned char *pix__; \ + unsigned char *ll__; \ + ll__=(_ll); \ + pix__=(_pix); \ + __asm mov YSTRIDE,_ystride \ + __asm mov LL,ll__ \ + __asm mov PIX,pix__ \ + __asm sub PIX,YSTRIDE \ + __asm sub PIX,YSTRIDE \ + /*mm0={a0,...,a7}*/ \ + __asm movq mm0,[PIX] \ + /*ystride3=_ystride*3*/ \ + __asm lea YSTRIDE3,[YSTRIDE+YSTRIDE*2] \ + /*mm3={d0,...,d7}*/ \ + __asm movq mm3,[PIX+YSTRIDE3] \ + /*mm1={b0,...,b7}*/ \ + __asm movq mm1,[PIX+YSTRIDE] \ + /*mm2={c0,...,c7}*/ \ + __asm movq mm2,[PIX+YSTRIDE*2] \ + OC_LOOP_FILTER8_MMX \ + /*Write it back out.*/ \ + __asm movq [PIX+YSTRIDE],mm1 \ + __asm movq [PIX+YSTRIDE*2],mm2 \ + } \ + while(0) + +#define OC_LOOP_FILTER_H_MMX(_pix,_ystride,_ll) \ + do{ \ + /*Used local variable ll__ in order to fix compilation errors like: \ + "error C2443: operand size conflict".*/ \ + unsigned char *ll__; \ + unsigned char *pix__; \ + ll__=(_ll); \ + pix__=(_pix)-2; \ + __asm mov PIX,pix__ \ + __asm mov YSTRIDE,_ystride \ + __asm mov LL,ll__ \ + /*x x x x d0 c0 b0 a0*/ \ + __asm movd mm0,[PIX] \ + /*x x x x d1 c1 b1 a1*/ \ + __asm movd mm1,[PIX+YSTRIDE] \ + /*ystride3=_ystride*3*/ \ + __asm lea YSTRIDE3,[YSTRIDE+YSTRIDE*2] \ + /*x x x x d2 c2 b2 a2*/ \ + __asm movd mm2,[PIX+YSTRIDE*2] \ + /*x x x x d3 c3 b3 a3*/ \ + __asm lea D,[PIX+YSTRIDE*4] \ + __asm movd mm3,[PIX+YSTRIDE3] \ + /*x x x x d4 c4 b4 a4*/ \ + __asm movd mm4,[D] \ + /*x x x x d5 c5 b5 a5*/ \ + __asm movd mm5,[D+YSTRIDE] \ + /*x x x x d6 c6 b6 a6*/ \ + __asm movd mm6,[D+YSTRIDE*2] \ + /*x x x x d7 c7 b7 a7*/ \ + __asm movd mm7,[D+YSTRIDE3] \ + /*mm0=d1 d0 c1 c0 b1 b0 a1 a0*/ \ + __asm punpcklbw mm0,mm1 \ + /*mm2=d3 d2 c3 c2 b3 b2 a3 a2*/ \ + __asm punpcklbw mm2,mm3 \ + /*mm3=d1 d0 c1 c0 b1 b0 a1 a0*/ \ + __asm movq mm3,mm0 \ + /*mm0=b3 b2 b1 b0 a3 a2 a1 a0*/ \ + __asm punpcklwd mm0,mm2 \ + /*mm3=d3 d2 d1 d0 c3 c2 c1 c0*/ \ + __asm punpckhwd mm3,mm2 \ + /*mm1=b3 b2 b1 b0 a3 a2 a1 a0*/ \ + __asm movq mm1,mm0 \ + /*mm4=d5 d4 c5 c4 b5 b4 a5 a4*/ \ + __asm punpcklbw mm4,mm5 \ + /*mm6=d7 d6 c7 c6 b7 b6 a7 a6*/ \ + __asm punpcklbw mm6,mm7 \ + /*mm5=d5 d4 c5 c4 b5 b4 a5 a4*/ \ + __asm movq mm5,mm4 \ + /*mm4=b7 b6 b5 b4 a7 a6 a5 a4*/ \ + __asm punpcklwd mm4,mm6 \ + /*mm5=d7 d6 d5 d4 c7 c6 c5 c4*/ \ + __asm punpckhwd mm5,mm6 \ + /*mm2=d3 d2 d1 d0 c3 c2 c1 c0*/ \ + __asm movq mm2,mm3 \ + /*mm0=a7 a6 a5 a4 a3 a2 a1 a0*/ \ + __asm punpckldq mm0,mm4 \ + /*mm1=b7 b6 b5 b4 b3 b2 b1 b0*/ \ + __asm punpckhdq mm1,mm4 \ + /*mm2=c7 c6 c5 c4 c3 c2 c1 c0*/ \ + __asm punpckldq mm2,mm5 \ + /*mm3=d7 d6 d5 d4 d3 d2 d1 d0*/ \ + __asm punpckhdq mm3,mm5 \ + OC_LOOP_FILTER8_MMX \ + /*mm2={b0+R_0'',...,b7+R_7''}*/ \ + __asm movq mm0,mm1 \ + /*mm1={b0+R_0'',c0-R_0'',...,b3+R_3'',c3-R_3''}*/ \ + __asm punpcklbw mm1,mm2 \ + /*mm2={b4+R_4'',c4-R_4'',...,b7+R_7'',c7-R_7''}*/ \ + __asm punpckhbw mm0,mm2 \ + /*[d]=c1 b1 c0 b0*/ \ + __asm movd D,mm1 \ + __asm mov [PIX+1],D_WORD \ + __asm psrlq mm1,32 \ + __asm shr D,16 \ + __asm mov [PIX+YSTRIDE+1],D_WORD \ + /*[d]=c3 b3 c2 b2*/ \ + __asm movd D,mm1 \ + __asm mov [PIX+YSTRIDE*2+1],D_WORD \ + __asm shr D,16 \ + __asm mov [PIX+YSTRIDE3+1],D_WORD \ + __asm lea PIX,[PIX+YSTRIDE*4] \ + /*[d]=c5 b5 c4 b4*/ \ + __asm movd D,mm0 \ + __asm mov [PIX+1],D_WORD \ + __asm psrlq mm0,32 \ + __asm shr D,16 \ + __asm mov [PIX+YSTRIDE+1],D_WORD \ + /*[d]=c7 b7 c6 b6*/ \ + __asm movd D,mm0 \ + __asm mov [PIX+YSTRIDE*2+1],D_WORD \ + __asm shr D,16 \ + __asm mov [PIX+YSTRIDE3+1],D_WORD \ + } \ + while(0) + +# endif +#endif diff --git a/media/libtheora/lib/x86_vc/mmxstate.c b/media/libtheora/lib/x86_vc/mmxstate.c new file mode 100644 index 0000000000..f532ee1b6f --- /dev/null +++ b/media/libtheora/lib/x86_vc/mmxstate.c @@ -0,0 +1,176 @@ +/******************************************************************** + * * + * THIS FILE IS PART OF THE OggTheora SOFTWARE CODEC SOURCE CODE. * + * USE, DISTRIBUTION AND REPRODUCTION OF THIS LIBRARY SOURCE IS * + * GOVERNED BY A BSD-STYLE SOURCE LICENSE INCLUDED WITH THIS SOURCE * + * IN 'COPYING'. PLEASE READ THESE TERMS BEFORE DISTRIBUTING. * + * * + * THE Theora SOURCE CODE IS COPYRIGHT (C) 2002-2009 * + * by the Xiph.Org Foundation and contributors http://www.xiph.org/ * + * * + ******************************************************************** + + function: + last mod: $Id$ + + ********************************************************************/ + +/*MMX acceleration of complete fragment reconstruction algorithm. + Originally written by Rudolf Marek.*/ +#include <string.h> +#include "x86int.h" +#include "mmxloop.h" + +#if defined(OC_X86_ASM) + +void oc_state_frag_recon_mmx(const oc_theora_state *_state,ptrdiff_t _fragi, + int _pli,ogg_int16_t _dct_coeffs[128],int _last_zzi,ogg_uint16_t _dc_quant){ + unsigned char *dst; + ptrdiff_t frag_buf_off; + int ystride; + int refi; + /*Apply the inverse transform.*/ + /*Special case only having a DC component.*/ + if(_last_zzi<2){ + /*Note that this value must be unsigned, to keep the __asm__ block from + sign-extending it when it puts it in a register.*/ + ogg_uint16_t p; + /*We round this dequant product (and not any of the others) because there's + no iDCT rounding.*/ + p=(ogg_int16_t)(_dct_coeffs[0]*(ogg_int32_t)_dc_quant+15>>5); + /*Fill _dct_coeffs with p.*/ + __asm{ +#define Y eax +#define P ecx + mov Y,_dct_coeffs + movzx P,p + lea Y,[Y+128] + /*mm0=0000 0000 0000 AAAA*/ + movd mm0,P + /*mm0=0000 0000 AAAA AAAA*/ + punpcklwd mm0,mm0 + /*mm0=AAAA AAAA AAAA AAAA*/ + punpckldq mm0,mm0 + movq [Y],mm0 + movq [8+Y],mm0 + movq [16+Y],mm0 + movq [24+Y],mm0 + movq [32+Y],mm0 + movq [40+Y],mm0 + movq [48+Y],mm0 + movq [56+Y],mm0 + movq [64+Y],mm0 + movq [72+Y],mm0 + movq [80+Y],mm0 + movq [88+Y],mm0 + movq [96+Y],mm0 + movq [104+Y],mm0 + movq [112+Y],mm0 + movq [120+Y],mm0 +#undef Y +#undef P + } + } + else{ + /*Dequantize the DC coefficient.*/ + _dct_coeffs[0]=(ogg_int16_t)(_dct_coeffs[0]*(int)_dc_quant); + oc_idct8x8_mmx(_dct_coeffs+64,_dct_coeffs,_last_zzi); + } + /*Fill in the target buffer.*/ + frag_buf_off=_state->frag_buf_offs[_fragi]; + refi=_state->frags[_fragi].refi; + ystride=_state->ref_ystride[_pli]; + dst=_state->ref_frame_data[OC_FRAME_SELF]+frag_buf_off; + if(refi==OC_FRAME_SELF)oc_frag_recon_intra_mmx(dst,ystride,_dct_coeffs+64); + else{ + const unsigned char *ref; + int mvoffsets[2]; + ref=_state->ref_frame_data[refi]+frag_buf_off; + if(oc_state_get_mv_offsets(_state,mvoffsets,_pli, + _state->frag_mvs[_fragi])>1){ + oc_frag_recon_inter2_mmx(dst,ref+mvoffsets[0],ref+mvoffsets[1],ystride, + _dct_coeffs+64); + } + else oc_frag_recon_inter_mmx(dst,ref+mvoffsets[0],ystride,_dct_coeffs+64); + } +} + +/*We copy these entire function to inline the actual MMX routines so that we + use only a single indirect call.*/ + +void oc_loop_filter_init_mmx(signed char _bv[256],int _flimit){ + memset(_bv,~(_flimit<<1),8); +} + +/*Apply the loop filter to a given set of fragment rows in the given plane. + The filter may be run on the bottom edge, affecting pixels in the next row of + fragments, so this row also needs to be available. + _bv: The bounding values array. + _refi: The index of the frame buffer to filter. + _pli: The color plane to filter. + _fragy0: The Y coordinate of the first fragment row to filter. + _fragy_end: The Y coordinate of the fragment row to stop filtering at.*/ +void oc_state_loop_filter_frag_rows_mmx(const oc_theora_state *_state, + signed char _bv[256],int _refi,int _pli,int _fragy0,int _fragy_end){ + const oc_fragment_plane *fplane; + const oc_fragment *frags; + const ptrdiff_t *frag_buf_offs; + unsigned char *ref_frame_data; + ptrdiff_t fragi_top; + ptrdiff_t fragi_bot; + ptrdiff_t fragi0; + ptrdiff_t fragi0_end; + int ystride; + int nhfrags; + fplane=_state->fplanes+_pli; + nhfrags=fplane->nhfrags; + fragi_top=fplane->froffset; + fragi_bot=fragi_top+fplane->nfrags; + fragi0=fragi_top+_fragy0*(ptrdiff_t)nhfrags; + fragi0_end=fragi_top+_fragy_end*(ptrdiff_t)nhfrags; + ystride=_state->ref_ystride[_pli]; + frags=_state->frags; + frag_buf_offs=_state->frag_buf_offs; + ref_frame_data=_state->ref_frame_data[_refi]; + /*The following loops are constructed somewhat non-intuitively on purpose. + The main idea is: if a block boundary has at least one coded fragment on + it, the filter is applied to it. + However, the order that the filters are applied in matters, and VP3 chose + the somewhat strange ordering used below.*/ + while(fragi0<fragi0_end){ + ptrdiff_t fragi; + ptrdiff_t fragi_end; + fragi=fragi0; + fragi_end=fragi+nhfrags; + while(fragi<fragi_end){ + if(frags[fragi].coded){ + unsigned char *ref; + ref=ref_frame_data+frag_buf_offs[fragi]; +#define PIX eax +#define YSTRIDE3 edi +#define YSTRIDE ecx +#define LL edx +#define D esi +#define D_WORD si + if(fragi>fragi0)OC_LOOP_FILTER_H_MMX(ref,ystride,_bv); + if(fragi0>fragi_top)OC_LOOP_FILTER_V_MMX(ref,ystride,_bv); + if(fragi+1<fragi_end&&!frags[fragi+1].coded){ + OC_LOOP_FILTER_H_MMX(ref+8,ystride,_bv); + } + if(fragi+nhfrags<fragi_bot&&!frags[fragi+nhfrags].coded){ + OC_LOOP_FILTER_V_MMX(ref+(ystride<<3),ystride,_bv); + } +#undef PIX +#undef YSTRIDE3 +#undef YSTRIDE +#undef LL +#undef D +#undef D_WORD + } + fragi++; + } + fragi0+=nhfrags; + } +} + +#endif diff --git a/media/libtheora/lib/x86_vc/x86cpu.c b/media/libtheora/lib/x86_vc/x86cpu.c new file mode 100644 index 0000000000..6a1d8d850c --- /dev/null +++ b/media/libtheora/lib/x86_vc/x86cpu.c @@ -0,0 +1,192 @@ +/******************************************************************** + * * + * THIS FILE IS PART OF THE OggTheora SOFTWARE CODEC SOURCE CODE. * + * USE, DISTRIBUTION AND REPRODUCTION OF THIS LIBRARY SOURCE IS * + * GOVERNED BY A BSD-STYLE SOURCE LICENSE INCLUDED WITH THIS SOURCE * + * IN 'COPYING'. PLEASE READ THESE TERMS BEFORE DISTRIBUTING. * + * * + * THE Theora SOURCE CODE IS COPYRIGHT (C) 2002-2009 * + * by the Xiph.Org Foundation and contributors http://www.xiph.org/ * + * * + ******************************************************************** + + CPU capability detection for x86 processors. + Originally written by Rudolf Marek. + + function: + last mod: $Id$ + + ********************************************************************/ + +#include "x86cpu.h" + +#if !defined(OC_X86_ASM) +ogg_uint32_t oc_cpu_flags_get(void){ + return 0; +} +#else +/*Why does MSVC need this complicated rigamarole? + At this point I honestly do not care.*/ + +/*Visual C cpuid helper function. + For VS2005 we could as well use the _cpuid builtin, but that wouldn't work + for VS2003 users, so we do it in inline assembler.*/ +static void oc_cpuid_helper(ogg_uint32_t _cpu_info[4],ogg_uint32_t _op){ + _asm{ + mov eax,[_op] + mov esi,_cpu_info + cpuid + mov [esi+0],eax + mov [esi+4],ebx + mov [esi+8],ecx + mov [esi+12],edx + } +} + +# define cpuid(_op,_eax,_ebx,_ecx,_edx) \ + do{ \ + ogg_uint32_t cpu_info[4]; \ + oc_cpuid_helper(cpu_info,_op); \ + (_eax)=cpu_info[0]; \ + (_ebx)=cpu_info[1]; \ + (_ecx)=cpu_info[2]; \ + (_edx)=cpu_info[3]; \ + }while(0) + +static void oc_detect_cpuid_helper(ogg_uint32_t *_eax,ogg_uint32_t *_ebx){ + _asm{ + pushfd + pushfd + pop eax + mov ebx,eax + xor eax,200000h + push eax + popfd + pushfd + pop eax + popfd + mov ecx,_eax + mov [ecx],eax + mov ecx,_ebx + mov [ecx],ebx + } +} + +static ogg_uint32_t oc_parse_intel_flags(ogg_uint32_t _edx,ogg_uint32_t _ecx){ + ogg_uint32_t flags; + /*If there isn't even MMX, give up.*/ + if(!(_edx&0x00800000))return 0; + flags=OC_CPU_X86_MMX; + if(_edx&0x02000000)flags|=OC_CPU_X86_MMXEXT|OC_CPU_X86_SSE; + if(_edx&0x04000000)flags|=OC_CPU_X86_SSE2; + if(_ecx&0x00000001)flags|=OC_CPU_X86_PNI; + if(_ecx&0x00000100)flags|=OC_CPU_X86_SSSE3; + if(_ecx&0x00080000)flags|=OC_CPU_X86_SSE4_1; + if(_ecx&0x00100000)flags|=OC_CPU_X86_SSE4_2; + return flags; +} + +static ogg_uint32_t oc_parse_amd_flags(ogg_uint32_t _edx,ogg_uint32_t _ecx){ + ogg_uint32_t flags; + /*If there isn't even MMX, give up.*/ + if(!(_edx&0x00800000))return 0; + flags=OC_CPU_X86_MMX; + if(_edx&0x00400000)flags|=OC_CPU_X86_MMXEXT; + if(_edx&0x80000000)flags|=OC_CPU_X86_3DNOW; + if(_edx&0x40000000)flags|=OC_CPU_X86_3DNOWEXT; + if(_ecx&0x00000040)flags|=OC_CPU_X86_SSE4A; + if(_ecx&0x00000800)flags|=OC_CPU_X86_SSE5; + return flags; +} + +ogg_uint32_t oc_cpu_flags_get(void){ + ogg_uint32_t flags; + ogg_uint32_t eax; + ogg_uint32_t ebx; + ogg_uint32_t ecx; + ogg_uint32_t edx; +# if !defined(__amd64__)&&!defined(__x86_64__) + /*Not all x86-32 chips support cpuid, so we have to check.*/ + oc_detect_cpuid_helper(&eax,&ebx); + /*No cpuid.*/ + if(eax==ebx)return 0; +# endif + cpuid(0,eax,ebx,ecx,edx); + /* l e t n I e n i u n e G*/ + if(ecx==0x6C65746E&&edx==0x49656E69&&ebx==0x756E6547|| + /* 6 8 x M T e n i u n e G*/ + ecx==0x3638784D&&edx==0x54656E69&&ebx==0x756E6547){ + int family; + int model; + /*Intel, Transmeta (tested with Crusoe TM5800):*/ + cpuid(1,eax,ebx,ecx,edx); + flags=oc_parse_intel_flags(edx,ecx); + family=(eax>>8)&0xF; + model=(eax>>4)&0xF; + /*The SSE unit on the Pentium M and Core Duo is much slower than the MMX + unit, so don't use it.*/ + if(family==6&&(model==9||model==13||model==14)){ + flags&=~(OC_CPU_X86_SSE2|OC_CPU_X86_PNI); + } + } + /* D M A c i t n e h t u A*/ + else if(ecx==0x444D4163&&edx==0x69746E65&&ebx==0x68747541|| + /* C S N y b e d o e G*/ + ecx==0x43534e20&&edx==0x79622065&&ebx==0x646f6547){ + /*AMD, Geode:*/ + cpuid(0x80000000,eax,ebx,ecx,edx); + if(eax<0x80000001)flags=0; + else{ + cpuid(0x80000001,eax,ebx,ecx,edx); + flags=oc_parse_amd_flags(edx,ecx); + } + /*Also check for SSE.*/ + cpuid(1,eax,ebx,ecx,edx); + flags|=oc_parse_intel_flags(edx,ecx); + } + /*Technically some VIA chips can be configured in the BIOS to return any + string here the user wants. + There is a special detection method that can be used to identify such + processors, but in my opinion, if the user really wants to change it, they + deserve what they get.*/ + /* s l u a H r u a t n e C*/ + else if(ecx==0x736C7561&&edx==0x48727561&&ebx==0x746E6543){ + /*VIA:*/ + /*I only have documentation for the C7 (Esther) and Isaiah (forthcoming) + chips (thanks to the engineers from Centaur Technology who provided it). + These chips support Intel-like cpuid info. + The C3-2 (Nehemiah) cores appear to, as well.*/ + cpuid(1,eax,ebx,ecx,edx); + flags=oc_parse_intel_flags(edx,ecx); + if(eax>=0x80000001){ + /*The (non-Nehemiah) C3 processors support AMD-like cpuid info. + We need to check this even if the Intel test succeeds to pick up 3DNow! + support on these processors. + Unlike actual AMD processors, we cannot _rely_ on this info, since + some cores (e.g., the 693 stepping of the Nehemiah) claim to support + this function, yet return edx=0, despite the Intel test indicating + MMX support. + Therefore the features detected here are strictly added to those + detected by the Intel test.*/ + /*TODO: How about earlier chips?*/ + cpuid(0x80000001,eax,ebx,ecx,edx); + /*Note: As of the C7, this function returns Intel-style extended feature + flags, not AMD-style. + Currently, this only defines bits 11, 20, and 29 (0x20100800), which + do not conflict with any of the AMD flags we inspect. + For the remaining bits, Intel tells us, "Do not count on their value", + but VIA assures us that they will all be zero (at least on the C7 and + Isaiah chips). + In the (unlikely) event a future processor uses bits 18, 19, 30, or 31 + (0xC0C00000) for something else, we will have to add code to detect + the model to decide when it is appropriate to inspect them.*/ + flags|=oc_parse_amd_flags(edx,ecx); + } + } + else{ + /*Implement me.*/ + flags=0; + } + return flags; +} +#endif diff --git a/media/libtheora/lib/x86_vc/x86cpu.h b/media/libtheora/lib/x86_vc/x86cpu.h new file mode 100644 index 0000000000..eea261d448 --- /dev/null +++ b/media/libtheora/lib/x86_vc/x86cpu.h @@ -0,0 +1,36 @@ +/******************************************************************** + * * + * THIS FILE IS PART OF THE OggTheora SOFTWARE CODEC SOURCE CODE. * + * USE, DISTRIBUTION AND REPRODUCTION OF THIS LIBRARY SOURCE IS * + * GOVERNED BY A BSD-STYLE SOURCE LICENSE INCLUDED WITH THIS SOURCE * + * IN 'COPYING'. PLEASE READ THESE TERMS BEFORE DISTRIBUTING. * + * * + * THE Theora SOURCE CODE IS COPYRIGHT (C) 2002-2009 * + * by the Xiph.Org Foundation and contributors http://www.xiph.org/ * + * * + ******************************************************************** + function: + last mod: $Id$ + + ********************************************************************/ + +#if !defined(_x86_vc_x86cpu_H) +# define _x86_vc_x86cpu_H (1) +#include "../internal.h" + +#define OC_CPU_X86_MMX (1<<0) +#define OC_CPU_X86_3DNOW (1<<1) +#define OC_CPU_X86_3DNOWEXT (1<<2) +#define OC_CPU_X86_MMXEXT (1<<3) +#define OC_CPU_X86_SSE (1<<4) +#define OC_CPU_X86_SSE2 (1<<5) +#define OC_CPU_X86_PNI (1<<6) +#define OC_CPU_X86_SSSE3 (1<<7) +#define OC_CPU_X86_SSE4_1 (1<<8) +#define OC_CPU_X86_SSE4_2 (1<<9) +#define OC_CPU_X86_SSE4A (1<<10) +#define OC_CPU_X86_SSE5 (1<<11) + +ogg_uint32_t oc_cpu_flags_get(void); + +#endif diff --git a/media/libtheora/lib/x86_vc/x86int.h b/media/libtheora/lib/x86_vc/x86int.h new file mode 100644 index 0000000000..318a09dca0 --- /dev/null +++ b/media/libtheora/lib/x86_vc/x86int.h @@ -0,0 +1,49 @@ +/******************************************************************** + * * + * THIS FILE IS PART OF THE OggTheora SOFTWARE CODEC SOURCE CODE. * + * USE, DISTRIBUTION AND REPRODUCTION OF THIS LIBRARY SOURCE IS * + * GOVERNED BY A BSD-STYLE SOURCE LICENSE INCLUDED WITH THIS SOURCE * + * IN 'COPYING'. PLEASE READ THESE TERMS BEFORE DISTRIBUTING. * + * * + * THE Theora SOURCE CODE IS COPYRIGHT (C) 2002-2009 * + * by the Xiph.Org Foundation and contributors http://www.xiph.org/ * + * * + ******************************************************************** + + function: + last mod: $Id$ + + ********************************************************************/ + +#if !defined(_x86_vc_x86int_H) +# define _x86_vc_x86int_H (1) +# include "../internal.h" +# if defined(OC_X86_ASM) +# define oc_state_accel_init oc_state_accel_init_x86 +# define OC_STATE_USE_VTABLE (1) +# endif +# include "../state.h" +# include "x86cpu.h" + +void oc_state_accel_init_x86(oc_theora_state *_state); + +void oc_frag_copy_mmx(unsigned char *_dst, + const unsigned char *_src,int _ystride); +void oc_frag_copy_list_mmx(unsigned char *_dst_frame, + const unsigned char *_src_frame,int _ystride, + const ptrdiff_t *_fragis,ptrdiff_t _nfragis,const ptrdiff_t *_frag_buf_offs); +void oc_frag_recon_intra_mmx(unsigned char *_dst,int _ystride, + const ogg_int16_t *_residue); +void oc_frag_recon_inter_mmx(unsigned char *_dst, + const unsigned char *_src,int _ystride,const ogg_int16_t *_residue); +void oc_frag_recon_inter2_mmx(unsigned char *_dst,const unsigned char *_src1, + const unsigned char *_src2,int _ystride,const ogg_int16_t *_residue); +void oc_idct8x8_mmx(ogg_int16_t _y[64],ogg_int16_t _x[64],int _last_zzi); +void oc_state_frag_recon_mmx(const oc_theora_state *_state,ptrdiff_t _fragi, + int _pli,ogg_int16_t _dct_coeffs[128],int _last_zzi,ogg_uint16_t _dc_quant); +void oc_loop_filter_init_mmx(signed char _bv[256],int _flimit); +void oc_state_loop_filter_frag_rows_mmx(const oc_theora_state *_state, + signed char _bv[256],int _refi,int _pli,int _fragy0,int _fragy_end); +void oc_restore_fpu_mmx(void); + +#endif diff --git a/media/libtheora/lib/x86_vc/x86state.c b/media/libtheora/lib/x86_vc/x86state.c new file mode 100644 index 0000000000..fa3a0d42fc --- /dev/null +++ b/media/libtheora/lib/x86_vc/x86state.c @@ -0,0 +1,61 @@ +/******************************************************************** + * * + * THIS FILE IS PART OF THE OggTheora SOFTWARE CODEC SOURCE CODE. * + * USE, DISTRIBUTION AND REPRODUCTION OF THIS LIBRARY SOURCE IS * + * GOVERNED BY A BSD-STYLE SOURCE LICENSE INCLUDED WITH THIS SOURCE * + * IN 'COPYING'. PLEASE READ THESE TERMS BEFORE DISTRIBUTING. * + * * + * THE Theora SOURCE CODE IS COPYRIGHT (C) 2002-2009 * + * by the Xiph.Org Foundation and contributors http://www.xiph.org/ * + * * + ******************************************************************** + + function: + last mod: $Id$ + + ********************************************************************/ + +#include "x86int.h" + +#if defined(OC_X86_ASM) + +/*This table has been modified from OC_FZIG_ZAG by baking a 4x4 transpose into + each quadrant of the destination.*/ +static const unsigned char OC_FZIG_ZAG_MMX[128]={ + 0, 8, 1, 2, 9,16,24,17, + 10, 3,32,11,18,25, 4,12, + 5,26,19,40,33,34,41,48, + 27, 6,13,20,28,21,14, 7, + 56,49,42,35,43,50,57,36, + 15,22,29,30,23,44,37,58, + 51,59,38,45,52,31,60,53, + 46,39,47,54,61,62,55,63, + 64,64,64,64,64,64,64,64, + 64,64,64,64,64,64,64,64, + 64,64,64,64,64,64,64,64, + 64,64,64,64,64,64,64,64, + 64,64,64,64,64,64,64,64, + 64,64,64,64,64,64,64,64, + 64,64,64,64,64,64,64,64, + 64,64,64,64,64,64,64,64, +}; + +void oc_state_accel_init_x86(oc_theora_state *_state){ + _state->cpu_flags=oc_cpu_flags_get(); + if(_state->cpu_flags&OC_CPU_X86_MMX){ + _state->opt_vtable.frag_copy=oc_frag_copy_mmx; + _state->opt_vtable.frag_copy_list=oc_frag_copy_list_mmx; + _state->opt_vtable.frag_recon_intra=oc_frag_recon_intra_mmx; + _state->opt_vtable.frag_recon_inter=oc_frag_recon_inter_mmx; + _state->opt_vtable.frag_recon_inter2=oc_frag_recon_inter2_mmx; + _state->opt_vtable.idct8x8=oc_idct8x8_mmx; + _state->opt_vtable.state_frag_recon=oc_state_frag_recon_mmx; + _state->opt_vtable.loop_filter_init=oc_loop_filter_init_mmx; + _state->opt_vtable.state_loop_filter_frag_rows= + oc_state_loop_filter_frag_rows_mmx; + _state->opt_vtable.restore_fpu=oc_restore_fpu_mmx; + _state->opt_data.dct_fzig_zag=OC_FZIG_ZAG_MMX; + } + else oc_state_accel_init_c(_state); +} +#endif diff --git a/media/libtheora/moz.build b/media/libtheora/moz.build new file mode 100644 index 0000000000..7e76448db9 --- /dev/null +++ b/media/libtheora/moz.build @@ -0,0 +1,105 @@ +# -*- Mode: python; indent-tabs-mode: nil; tab-width: 40 -*- +# vim: set filetype=python: +# This Source Code Form is subject to the terms of the Mozilla Public +# License, v. 2.0. If a copy of the MPL was not distributed with this +# file, You can obtain one at http://mozilla.org/MPL/2.0/. + +with Files('*'): + BUG_COMPONENT = ('Core', 'Audio/Video') + +EXPORTS.theora += [ + 'include/theora/codec.h', + 'include/theora/theoradec.h', +] + +# We allow warnings for third-party code that can be updated from upstream. +AllowCompilerWarnings() + +FINAL_LIBRARY = 'gkmedias' + +# The encoder is currently not included. +DEFINES['THEORA_DISABLE_ENCODE'] = True + +# Suppress warnings in third-party code. +CFLAGS += ['-Wno-type-limits'] +if CONFIG['CC_TYPE'] in ('clang', 'clang-cl'): + CFLAGS += [ + '-Wno-shift-negative-value', + '-Wno-tautological-compare', + ] +if CONFIG['CC_TYPE'] == 'clang-cl': + CFLAGS += [ + '-Wno-parentheses', + '-Wno-pointer-sign', + ] + +UNIFIED_SOURCES += [ + 'lib/bitpack.c', + 'lib/decinfo.c', + 'lib/decode.c', + 'lib/dequant.c', + 'lib/fragment.c', + 'lib/huffdec.c', + 'lib/idct.c', + 'lib/info.c', + 'lib/internal.c', + 'lib/quant.c', + 'lib/state.c', +] + +LOCAL_INCLUDES += ['include'] + +if CONFIG['INTEL_ARCHITECTURE']: + if CONFIG['OS_ARCH'] != 'SunOS': + if CONFIG['CC_TYPE'] == 'clang-cl': + # clang-cl can't handle libtheora's inline asm. + pass + elif CONFIG['OS_ARCH'] != 'WINNT' or CONFIG['CPU_ARCH'] != 'x86_64': + DEFINES['OC_X86_ASM'] = True + if CONFIG['CPU_ARCH'] == 'x86_64': + DEFINES['OC_X86_64_ASM'] = True + if CONFIG['CC_TYPE'] == 'clang-cl': + # clang-cl can't handle libtheora's inline asm. + pass + #SOURCES += [ + # 'lib/x86_vc/mmxfrag.c', + # 'lib/x86_vc/mmxidct.c', + # 'lib/x86_vc/mmxstate.c', + # 'lib/x86_vc/x86cpu.c', + # 'lib/x86_vc/x86state.c', + #] + else: + SOURCES += [ + 'lib/x86/mmxfrag.c', + 'lib/x86/mmxidct.c', + 'lib/x86/mmxstate.c', + 'lib/x86/sse2idct.c', + 'lib/x86/x86cpu.c', + 'lib/x86/x86state.c', + ] + +if CONFIG['GNU_AS']: + if CONFIG['CPU_ARCH'] == 'arm': + SOURCES += [ + 'lib/arm/armcpu.c', + 'lib/arm/armstate.c', + ] + for var in ('OC_ARM_ASM', + 'OC_ARM_ASM_EDSP', + 'OC_ARM_ASM_MEDIA', + 'OC_ARM_ASM_NEON'): + DEFINES[var] = True + + SOURCES += [ '!%s.s' % f for f in [ + 'armbits-gnu', + 'armfrag-gnu', + 'armidct-gnu', + 'armloop-gnu', + ]] + + # These flags are a lie; they're just used to enable the requisite + # opcodes; actual arch detection is done at runtime. + ASFLAGS += [ + '-march=armv7-a', + ] + ASFLAGS += CONFIG['NEON_FLAGS'] diff --git a/media/libtheora/moz.yaml b/media/libtheora/moz.yaml new file mode 100644 index 0000000000..d537aeec4c --- /dev/null +++ b/media/libtheora/moz.yaml @@ -0,0 +1,106 @@ +schema: 1 + +bugzilla: + product: Core + component: "Audio/Video: Playback" + +origin: + name: theora + description: Video compression format from Xiph + url: https://www.theora.org/ + + release: 7180717276af1ebc7da15c83162d6c5d6203aabf (2020-10-27T09:17:42.000-07:00). + revision: 7180717276af1ebc7da15c83162d6c5d6203aabf + + license: BSD-3-Clause-Clear + license-file: COPYING + +updatebot: + maintainer-phab: kinetik + maintainer-bz: kinetik + tasks: + - type: vendoring + enabled: true + frequency: every + +vendoring: + url: https://gitlab.xiph.org/xiph/theora + source-hosting: gitlab + + exclude: + - doc + - examples + - lib/c64x + - m4 + - macosx + - symbian + - tests + - tools + - win32 + - autogen.sh + - .travis.yml + - configure.ac + - SConstruct + - Makefile.am + - "*.pc.in" + - "*.spec.in" + - include/theora/theoraenc.h + - include/theora/Makefile.* + - include/Makefile.* + - lib/analyze.c + - lib/apiwrapper.c + - lib/apiwrapper.h + - lib/arm/armenc.c + - lib/arm/armenc.h + - lib/arm/armencfrag.s + - lib/arm/armenquant.s + - lib/collect.c + - lib/collect.h + - lib/decapiwrapper.c + - lib/encapiwrapper.c + - lib/encfrag.c + - lib/encinfo.c + - lib/encint.h + - lib/encode.c + - lib/encoder_disabled.c + - lib/enquant.c + - lib/enquant.h + - lib/fdct.c + - lib/huffenc.c + - lib/huffenc.h + - lib/mathops.c + - lib/mcenc.c + - lib/modedec.h + - lib/rate.c + - lib/tokenize.c + - lib/x86/mmxencfrag.c + - lib/x86/mmxfdct.c + - lib/x86/sse2encfrag.c + - lib/x86/sse2fdct.c + - lib/x86/x86enc.c + - lib/x86/x86enc.h + - lib/x86/x86enquant.c + - lib/x86/x86zigzag.h + - lib/x86_vc/mmxencfrag.c + - lib/x86_vc/mmxfdct.c + - lib/x86_vc/x86enc.c + - lib/x86_vc/x86enc.h + - lib/x86_vc/x86zigzag.h + - lib/Makefile.* + - lib/Version_script* + - lib/*.awk + - lib/*.def + - lib/*.exp + + keep: + - Makefile.in + - lib/config.h + - update.sh + + patches: + - clang-arm.patch + + update-actions: + - action: run-script + script: '{yaml_dir}/update.sh' + cwd: '{yaml_dir}' diff --git a/media/libtheora/update.sh b/media/libtheora/update.sh new file mode 100755 index 0000000000..c77bb00ca1 --- /dev/null +++ b/media/libtheora/update.sh @@ -0,0 +1,10 @@ +#!/bin/sh +# This Source Code Form is subject to the terms of the Mozilla Public +# License, v. 2.0. If a copy of the MPL was not distributed with this +# file, You can obtain one at http://mozilla.org/MPL/2.0/. + +sed \ + -e s/@HAVE_ARM_ASM_EDSP@/1/g \ + -e s/@HAVE_ARM_ASM_MEDIA@/1/g \ + -e s/@HAVE_ARM_ASM_NEON@/1/g \ + lib/arm/armopts.s.in > lib/arm/armopts.s |