/** * FreeRDP: A Remote Desktop Protocol Implementation * RemoteFX Codec Library - DWT * * Copyright 2011 Vic Lee * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ #include #include #include #include #include "rfx_dwt.h" static void rfx_dwt_2d_decode_block(INT16* buffer, INT16* idwt, size_t subband_width) { INT16* dst = NULL; INT16* l = NULL; INT16* h = NULL; INT16* l_dst = NULL; INT16* h_dst = NULL; INT16* hl = NULL; INT16* lh = NULL; INT16* hh = NULL; INT16* ll = NULL; const size_t total_width = subband_width << 1; /* Inverse DWT in horizontal direction, results in 2 sub-bands in L, H order in tmp buffer idwt. */ /* The 4 sub-bands are stored in HL(0), LH(1), HH(2), LL(3) order. */ /* The lower part L uses LL(3) and HL(0). */ /* The higher part H uses LH(1) and HH(2). */ ll = buffer + subband_width * subband_width * 3; hl = buffer; l_dst = idwt; lh = buffer + subband_width * subband_width; hh = buffer + subband_width * subband_width * 2; h_dst = idwt + subband_width * subband_width * 2; for (size_t y = 0; y < subband_width; y++) { /* Even coefficients */ l_dst[0] = ll[0] - ((hl[0] + hl[0] + 1) >> 1); h_dst[0] = lh[0] - ((hh[0] + hh[0] + 1) >> 1); for (size_t n = 1; n < subband_width; n++) { const size_t x = n << 1; l_dst[x] = ll[n] - ((hl[n - 1] + hl[n] + 1) >> 1); h_dst[x] = lh[n] - ((hh[n - 1] + hh[n] + 1) >> 1); } /* Odd coefficients */ size_t n = 0; for (; n < subband_width - 1; n++) { const size_t x = n << 1; l_dst[x + 1] = (hl[n] << 1) + ((l_dst[x] + l_dst[x + 2]) >> 1); h_dst[x + 1] = (hh[n] << 1) + ((h_dst[x] + h_dst[x + 2]) >> 1); } const size_t x = n << 1; l_dst[x + 1] = (hl[n] << 1) + (l_dst[x]); h_dst[x + 1] = (hh[n] << 1) + (h_dst[x]); ll += subband_width; hl += subband_width; l_dst += total_width; lh += subband_width; hh += subband_width; h_dst += total_width; } /* Inverse DWT in vertical direction, results are stored in original buffer. */ for (size_t x = 0; x < total_width; x++) { l = idwt + x; h = idwt + x + subband_width * total_width; dst = buffer + x; *dst = *l - ((*h * 2 + 1) >> 1); for (size_t n = 1; n < subband_width; n++) { l += total_width; h += total_width; /* Even coefficients */ dst[2 * total_width] = *l - ((*(h - total_width) + *h + 1) >> 1); /* Odd coefficients */ dst[total_width] = (*(h - total_width) << 1) + ((*dst + dst[2 * total_width]) >> 1); dst += 2 * total_width; } dst[total_width] = (*h << 1) + ((*dst * 2) >> 1); } } void rfx_dwt_2d_decode(INT16* buffer, INT16* dwt_buffer) { WINPR_ASSERT(buffer); WINPR_ASSERT(dwt_buffer); rfx_dwt_2d_decode_block(&buffer[3840], dwt_buffer, 8); rfx_dwt_2d_decode_block(&buffer[3072], dwt_buffer, 16); rfx_dwt_2d_decode_block(&buffer[0], dwt_buffer, 32); } static void rfx_dwt_2d_encode_block(INT16* buffer, INT16* dwt, UINT32 subband_width) { INT16* src = NULL; INT16* l = NULL; INT16* h = NULL; INT16* l_src = NULL; INT16* h_src = NULL; INT16* hl = NULL; INT16* lh = NULL; INT16* hh = NULL; INT16* ll = NULL; const UINT32 total_width = subband_width << 1; /* DWT in vertical direction, results in 2 sub-bands in L, H order in tmp buffer dwt. */ for (UINT32 x = 0; x < total_width; x++) { for (UINT32 n = 0; n < subband_width; n++) { UINT32 y = n << 1; l = dwt + n * total_width + x; h = l + subband_width * total_width; src = buffer + y * total_width + x; /* H */ *h = (src[total_width] - ((src[0] + src[n < subband_width - 1 ? 2 * total_width : 0]) >> 1)) >> 1; /* L */ *l = src[0] + (n == 0 ? *h : (*(h - total_width) + *h) >> 1); } } /* DWT in horizontal direction, results in 4 sub-bands in HL(0), LH(1), HH(2), LL(3) order, * stored in original buffer. */ /* The lower part L generates LL(3) and HL(0). */ /* The higher part H generates LH(1) and HH(2). */ ll = buffer + subband_width * subband_width * 3; hl = buffer; l_src = dwt; lh = buffer + subband_width * subband_width; hh = buffer + subband_width * subband_width * 2; h_src = dwt + subband_width * subband_width * 2; for (UINT32 y = 0; y < subband_width; y++) { /* L */ for (UINT32 n = 0; n < subband_width; n++) { UINT32 x = n << 1; /* HL */ hl[n] = (l_src[x + 1] - ((l_src[x] + l_src[n < subband_width - 1 ? x + 2 : x]) >> 1)) >> 1; /* LL */ ll[n] = l_src[x] + (n == 0 ? hl[n] : (hl[n - 1] + hl[n]) >> 1); } /* H */ for (UINT32 n = 0; n < subband_width; n++) { UINT32 x = n << 1; /* HH */ hh[n] = (h_src[x + 1] - ((h_src[x] + h_src[n < subband_width - 1 ? x + 2 : x]) >> 1)) >> 1; /* LH */ lh[n] = h_src[x] + (n == 0 ? hh[n] : (hh[n - 1] + hh[n]) >> 1); } ll += subband_width; hl += subband_width; l_src += total_width; lh += subband_width; hh += subband_width; h_src += total_width; } } void rfx_dwt_2d_encode(INT16* buffer, INT16* dwt_buffer) { WINPR_ASSERT(buffer); WINPR_ASSERT(dwt_buffer); rfx_dwt_2d_encode_block(&buffer[0], dwt_buffer, 32); rfx_dwt_2d_encode_block(&buffer[3072], dwt_buffer, 16); rfx_dwt_2d_encode_block(&buffer[3840], dwt_buffer, 8); }