/** * FreeRDP: A Remote Desktop Protocol Implementation * ZGFX (RDP8) Bulk Data Compression * * Copyright 2014 Marc-Andre Moreau * Copyright 2017 Armin Novak * Copyright 2017 Thincast Technologies GmbH * * 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 #include #define TAG FREERDP_TAG("codec") /** * RDP8 Compressor Limits: * * Maximum number of uncompressed bytes in a single segment: 65535 * Maximum match distance / minimum history size: 2500000 bytes. * Maximum number of segments: 65535 * Maximum expansion of a segment (when compressed size exceeds uncompressed): 1000 bytes * Minimum match length: 3 bytes */ typedef struct { UINT32 prefixLength; UINT32 prefixCode; UINT32 valueBits; UINT32 tokenType; UINT32 valueBase; } ZGFX_TOKEN; struct S_ZGFX_CONTEXT { BOOL Compressor; const BYTE* pbInputCurrent; const BYTE* pbInputEnd; UINT32 bits; UINT32 cBitsRemaining; UINT32 BitsCurrent; UINT32 cBitsCurrent; BYTE OutputBuffer[65536]; UINT32 OutputCount; BYTE HistoryBuffer[2500000]; UINT32 HistoryIndex; UINT32 HistoryBufferSize; }; static const ZGFX_TOKEN ZGFX_TOKEN_TABLE[] = { // len code vbits type vbase { 1, 0, 8, 0, 0 }, // 0 { 5, 17, 5, 1, 0 }, // 10001 { 5, 18, 7, 1, 32 }, // 10010 { 5, 19, 9, 1, 160 }, // 10011 { 5, 20, 10, 1, 672 }, // 10100 { 5, 21, 12, 1, 1696 }, // 10101 { 5, 24, 0, 0, 0x00 }, // 11000 { 5, 25, 0, 0, 0x01 }, // 11001 { 6, 44, 14, 1, 5792 }, // 101100 { 6, 45, 15, 1, 22176 }, // 101101 { 6, 52, 0, 0, 0x02 }, // 110100 { 6, 53, 0, 0, 0x03 }, // 110101 { 6, 54, 0, 0, 0xFF }, // 110110 { 7, 92, 18, 1, 54944 }, // 1011100 { 7, 93, 20, 1, 317088 }, // 1011101 { 7, 110, 0, 0, 0x04 }, // 1101110 { 7, 111, 0, 0, 0x05 }, // 1101111 { 7, 112, 0, 0, 0x06 }, // 1110000 { 7, 113, 0, 0, 0x07 }, // 1110001 { 7, 114, 0, 0, 0x08 }, // 1110010 { 7, 115, 0, 0, 0x09 }, // 1110011 { 7, 116, 0, 0, 0x0A }, // 1110100 { 7, 117, 0, 0, 0x0B }, // 1110101 { 7, 118, 0, 0, 0x3A }, // 1110110 { 7, 119, 0, 0, 0x3B }, // 1110111 { 7, 120, 0, 0, 0x3C }, // 1111000 { 7, 121, 0, 0, 0x3D }, // 1111001 { 7, 122, 0, 0, 0x3E }, // 1111010 { 7, 123, 0, 0, 0x3F }, // 1111011 { 7, 124, 0, 0, 0x40 }, // 1111100 { 7, 125, 0, 0, 0x80 }, // 1111101 { 8, 188, 20, 1, 1365664 }, // 10111100 { 8, 189, 21, 1, 2414240 }, // 10111101 { 8, 252, 0, 0, 0x0C }, // 11111100 { 8, 253, 0, 0, 0x38 }, // 11111101 { 8, 254, 0, 0, 0x39 }, // 11111110 { 8, 255, 0, 0, 0x66 }, // 11111111 { 9, 380, 22, 1, 4511392 }, // 101111100 { 9, 381, 23, 1, 8705696 }, // 101111101 { 9, 382, 24, 1, 17094304 }, // 101111110 { 0 } }; static INLINE BOOL zgfx_GetBits(ZGFX_CONTEXT* zgfx, UINT32 nbits) { if (!zgfx) return FALSE; while (zgfx->cBitsCurrent < nbits) { zgfx->BitsCurrent <<= 8; if (zgfx->pbInputCurrent < zgfx->pbInputEnd) zgfx->BitsCurrent += *(zgfx->pbInputCurrent)++; zgfx->cBitsCurrent += 8; } zgfx->cBitsRemaining -= nbits; zgfx->cBitsCurrent -= nbits; zgfx->bits = zgfx->BitsCurrent >> zgfx->cBitsCurrent; zgfx->BitsCurrent &= ((1 << zgfx->cBitsCurrent) - 1); return TRUE; } static void zgfx_history_buffer_ring_write(ZGFX_CONTEXT* zgfx, const BYTE* src, size_t count) { UINT32 front = 0; if (count <= 0) return; if (count > zgfx->HistoryBufferSize) { const size_t residue = count - zgfx->HistoryBufferSize; count = zgfx->HistoryBufferSize; src += residue; zgfx->HistoryIndex = (zgfx->HistoryIndex + residue) % zgfx->HistoryBufferSize; } if (zgfx->HistoryIndex + count <= zgfx->HistoryBufferSize) { CopyMemory(&(zgfx->HistoryBuffer[zgfx->HistoryIndex]), src, count); if ((zgfx->HistoryIndex += count) == zgfx->HistoryBufferSize) zgfx->HistoryIndex = 0; } else { front = zgfx->HistoryBufferSize - zgfx->HistoryIndex; CopyMemory(&(zgfx->HistoryBuffer[zgfx->HistoryIndex]), src, front); CopyMemory(zgfx->HistoryBuffer, &src[front], count - front); zgfx->HistoryIndex = count - front; } } static void zgfx_history_buffer_ring_read(ZGFX_CONTEXT* zgfx, int offset, BYTE* dst, UINT32 count) { UINT32 front = 0; UINT32 index = 0; INT32 bytes = 0; UINT32 valid = 0; INT32 bytesLeft = 0; BYTE* dptr = dst; BYTE* origDst = dst; if ((count <= 0) || (count > INT32_MAX)) return; bytesLeft = (INT32)count; index = (zgfx->HistoryIndex + zgfx->HistoryBufferSize - offset) % zgfx->HistoryBufferSize; bytes = MIN(bytesLeft, offset); if ((index + bytes) <= zgfx->HistoryBufferSize) { CopyMemory(dptr, &(zgfx->HistoryBuffer[index]), bytes); } else { front = zgfx->HistoryBufferSize - index; CopyMemory(dptr, &(zgfx->HistoryBuffer[index]), front); CopyMemory(&dptr[front], zgfx->HistoryBuffer, bytes - front); } if ((bytesLeft -= bytes) == 0) return; dptr += bytes; valid = bytes; do { bytes = valid; if (bytes > bytesLeft) bytes = bytesLeft; CopyMemory(dptr, origDst, bytes); dptr += bytes; valid <<= 1; } while ((bytesLeft -= bytes) > 0); } static BOOL zgfx_decompress_segment(ZGFX_CONTEXT* zgfx, wStream* stream, size_t segmentSize) { BYTE c = 0; BYTE flags = 0; UINT32 extra = 0; int opIndex = 0; UINT32 haveBits = 0; UINT32 inPrefix = 0; UINT32 count = 0; UINT32 distance = 0; BYTE* pbSegment = NULL; size_t cbSegment = 0; WINPR_ASSERT(zgfx); WINPR_ASSERT(stream); if (segmentSize < 2) return FALSE; cbSegment = segmentSize - 1; if (!Stream_CheckAndLogRequiredLength(TAG, stream, segmentSize) || (segmentSize > UINT32_MAX)) return FALSE; Stream_Read_UINT8(stream, flags); /* header (1 byte) */ zgfx->OutputCount = 0; pbSegment = Stream_Pointer(stream); if (!Stream_SafeSeek(stream, cbSegment)) return FALSE; if (!(flags & PACKET_COMPRESSED)) { zgfx_history_buffer_ring_write(zgfx, pbSegment, cbSegment); if (cbSegment > sizeof(zgfx->OutputBuffer)) return FALSE; CopyMemory(zgfx->OutputBuffer, pbSegment, cbSegment); zgfx->OutputCount = cbSegment; return TRUE; } zgfx->pbInputCurrent = pbSegment; zgfx->pbInputEnd = &pbSegment[cbSegment - 1]; /* NumberOfBitsToDecode = ((NumberOfBytesToDecode - 1) * 8) - ValueOfLastByte */ const UINT32 bits = 8u * (cbSegment - 1u); if (bits < *zgfx->pbInputEnd) return FALSE; zgfx->cBitsRemaining = bits - *zgfx->pbInputEnd; zgfx->cBitsCurrent = 0; zgfx->BitsCurrent = 0; while (zgfx->cBitsRemaining) { haveBits = 0; inPrefix = 0; for (opIndex = 0; ZGFX_TOKEN_TABLE[opIndex].prefixLength != 0; opIndex++) { while (haveBits < ZGFX_TOKEN_TABLE[opIndex].prefixLength) { zgfx_GetBits(zgfx, 1); inPrefix = (inPrefix << 1) + zgfx->bits; haveBits++; } if (inPrefix == ZGFX_TOKEN_TABLE[opIndex].prefixCode) { if (ZGFX_TOKEN_TABLE[opIndex].tokenType == 0) { /* Literal */ zgfx_GetBits(zgfx, ZGFX_TOKEN_TABLE[opIndex].valueBits); c = (BYTE)(ZGFX_TOKEN_TABLE[opIndex].valueBase + zgfx->bits); zgfx->HistoryBuffer[zgfx->HistoryIndex] = c; if (++zgfx->HistoryIndex == zgfx->HistoryBufferSize) zgfx->HistoryIndex = 0; if (zgfx->OutputCount >= sizeof(zgfx->OutputBuffer)) return FALSE; zgfx->OutputBuffer[zgfx->OutputCount++] = c; } else { zgfx_GetBits(zgfx, ZGFX_TOKEN_TABLE[opIndex].valueBits); distance = ZGFX_TOKEN_TABLE[opIndex].valueBase + zgfx->bits; if (distance != 0) { /* Match */ zgfx_GetBits(zgfx, 1); if (zgfx->bits == 0) { count = 3; } else { count = 4; extra = 2; zgfx_GetBits(zgfx, 1); while (zgfx->bits == 1) { count *= 2; extra++; zgfx_GetBits(zgfx, 1); } zgfx_GetBits(zgfx, extra); count += zgfx->bits; } if (count > sizeof(zgfx->OutputBuffer) - zgfx->OutputCount) return FALSE; zgfx_history_buffer_ring_read( zgfx, distance, &(zgfx->OutputBuffer[zgfx->OutputCount]), count); zgfx_history_buffer_ring_write( zgfx, &(zgfx->OutputBuffer[zgfx->OutputCount]), count); zgfx->OutputCount += count; } else { /* Unencoded */ zgfx_GetBits(zgfx, 15); count = zgfx->bits; zgfx->cBitsRemaining -= zgfx->cBitsCurrent; zgfx->cBitsCurrent = 0; zgfx->BitsCurrent = 0; if (count > sizeof(zgfx->OutputBuffer) - zgfx->OutputCount) return FALSE; else if (count > zgfx->cBitsRemaining / 8) return FALSE; else if (zgfx->pbInputCurrent + count > zgfx->pbInputEnd) return FALSE; CopyMemory(&(zgfx->OutputBuffer[zgfx->OutputCount]), zgfx->pbInputCurrent, count); zgfx_history_buffer_ring_write(zgfx, zgfx->pbInputCurrent, count); zgfx->pbInputCurrent += count; zgfx->cBitsRemaining -= (8 * count); zgfx->OutputCount += count; } } break; } } } return TRUE; } /* Allocate the buffers a bit larger. * * Due to optimizations some h264 decoders will read data beyond * the actual available data, so ensure that it will never be a * out of bounds read. */ static BYTE* aligned_zgfx_malloc(size_t size) { return malloc(size + 64); } int zgfx_decompress(ZGFX_CONTEXT* zgfx, const BYTE* pSrcData, UINT32 SrcSize, BYTE** ppDstData, UINT32* pDstSize, UINT32 flags) { int status = -1; BYTE descriptor = 0; wStream sbuffer = { 0 }; wStream* stream = Stream_StaticConstInit(&sbuffer, pSrcData, SrcSize); WINPR_ASSERT(zgfx); WINPR_ASSERT(stream); if (!Stream_CheckAndLogRequiredLength(TAG, stream, 1)) goto fail; Stream_Read_UINT8(stream, descriptor); /* descriptor (1 byte) */ if (descriptor == ZGFX_SEGMENTED_SINGLE) { if (!zgfx_decompress_segment(zgfx, stream, Stream_GetRemainingLength(stream))) goto fail; *ppDstData = NULL; if (zgfx->OutputCount > 0) *ppDstData = aligned_zgfx_malloc(zgfx->OutputCount); if (!*ppDstData) goto fail; *pDstSize = zgfx->OutputCount; CopyMemory(*ppDstData, zgfx->OutputBuffer, zgfx->OutputCount); } else if (descriptor == ZGFX_SEGMENTED_MULTIPART) { UINT32 segmentSize = 0; UINT16 segmentNumber = 0; UINT16 segmentCount = 0; UINT32 uncompressedSize = 0; BYTE* pConcatenated = NULL; size_t used = 0; if (!Stream_CheckAndLogRequiredLength(TAG, stream, 6)) goto fail; Stream_Read_UINT16(stream, segmentCount); /* segmentCount (2 bytes) */ Stream_Read_UINT32(stream, uncompressedSize); /* uncompressedSize (4 bytes) */ if (!Stream_CheckAndLogRequiredLengthOfSize(TAG, stream, segmentCount, sizeof(UINT32))) goto fail; pConcatenated = aligned_zgfx_malloc(uncompressedSize); if (!pConcatenated) goto fail; *ppDstData = pConcatenated; *pDstSize = uncompressedSize; for (segmentNumber = 0; segmentNumber < segmentCount; segmentNumber++) { if (!Stream_CheckAndLogRequiredLength(TAG, stream, sizeof(UINT32))) goto fail; Stream_Read_UINT32(stream, segmentSize); /* segmentSize (4 bytes) */ if (!zgfx_decompress_segment(zgfx, stream, segmentSize)) goto fail; if (zgfx->OutputCount > UINT32_MAX - used) goto fail; if (used + zgfx->OutputCount > uncompressedSize) goto fail; CopyMemory(pConcatenated, zgfx->OutputBuffer, zgfx->OutputCount); pConcatenated += zgfx->OutputCount; used += zgfx->OutputCount; } } else { goto fail; } status = 1; fail: return status; } static BOOL zgfx_compress_segment(ZGFX_CONTEXT* zgfx, wStream* s, const BYTE* pSrcData, UINT32 SrcSize, UINT32* pFlags) { /* FIXME: Currently compression not implemented. Just copy the raw source */ if (!Stream_EnsureRemainingCapacity(s, SrcSize + 1)) { WLog_ERR(TAG, "Stream_EnsureRemainingCapacity failed!"); return FALSE; } (*pFlags) |= ZGFX_PACKET_COMPR_TYPE_RDP8; /* RDP 8.0 compression format */ Stream_Write_UINT8(s, (*pFlags)); /* header (1 byte) */ Stream_Write(s, pSrcData, SrcSize); return TRUE; } int zgfx_compress_to_stream(ZGFX_CONTEXT* zgfx, wStream* sDst, const BYTE* pUncompressed, UINT32 uncompressedSize, UINT32* pFlags) { int fragment = 0; UINT16 maxLength = 0; UINT32 totalLength = 0; size_t posSegmentCount = 0; const BYTE* pSrcData = NULL; int status = 0; maxLength = ZGFX_SEGMENTED_MAXSIZE; totalLength = uncompressedSize; pSrcData = pUncompressed; for (; (totalLength > 0) || (fragment == 0); fragment++) { UINT32 SrcSize = 0; size_t posDstSize = 0; size_t posDataStart = 0; UINT32 DstSize = 0; SrcSize = (totalLength > maxLength) ? maxLength : totalLength; posDstSize = 0; totalLength -= SrcSize; /* Ensure we have enough space for headers */ if (!Stream_EnsureRemainingCapacity(sDst, 12)) { WLog_ERR(TAG, "Stream_EnsureRemainingCapacity failed!"); return -1; } if (fragment == 0) { /* First fragment */ /* descriptor (1 byte) */ Stream_Write_UINT8(sDst, (totalLength == 0) ? ZGFX_SEGMENTED_SINGLE : ZGFX_SEGMENTED_MULTIPART); if (totalLength > 0) { posSegmentCount = Stream_GetPosition(sDst); /* segmentCount (2 bytes) */ Stream_Seek(sDst, 2); Stream_Write_UINT32(sDst, uncompressedSize); /* uncompressedSize (4 bytes) */ } } if (fragment > 0 || totalLength > 0) { /* Multipart */ posDstSize = Stream_GetPosition(sDst); /* size (4 bytes) */ Stream_Seek(sDst, 4); } posDataStart = Stream_GetPosition(sDst); if (!zgfx_compress_segment(zgfx, sDst, pSrcData, SrcSize, pFlags)) return -1; if (posDstSize) { /* Fill segment data size */ DstSize = Stream_GetPosition(sDst) - posDataStart; Stream_SetPosition(sDst, posDstSize); Stream_Write_UINT32(sDst, DstSize); Stream_SetPosition(sDst, posDataStart + DstSize); } pSrcData += SrcSize; } Stream_SealLength(sDst); /* fill back segmentCount */ if (posSegmentCount) { Stream_SetPosition(sDst, posSegmentCount); Stream_Write_UINT16(sDst, fragment); Stream_SetPosition(sDst, Stream_Length(sDst)); } return status; } int zgfx_compress(ZGFX_CONTEXT* zgfx, const BYTE* pSrcData, UINT32 SrcSize, BYTE** ppDstData, UINT32* pDstSize, UINT32* pFlags) { int status = 0; wStream* s = Stream_New(NULL, SrcSize); status = zgfx_compress_to_stream(zgfx, s, pSrcData, SrcSize, pFlags); (*ppDstData) = Stream_Buffer(s); (*pDstSize) = Stream_GetPosition(s); Stream_Free(s, FALSE); return status; } void zgfx_context_reset(ZGFX_CONTEXT* zgfx, BOOL flush) { zgfx->HistoryIndex = 0; } ZGFX_CONTEXT* zgfx_context_new(BOOL Compressor) { ZGFX_CONTEXT* zgfx = NULL; zgfx = (ZGFX_CONTEXT*)calloc(1, sizeof(ZGFX_CONTEXT)); if (zgfx) { zgfx->Compressor = Compressor; zgfx->HistoryBufferSize = sizeof(zgfx->HistoryBuffer); zgfx_context_reset(zgfx, FALSE); } return zgfx; } void zgfx_context_free(ZGFX_CONTEXT* zgfx) { free(zgfx); }