// Copyright 2012 Google Inc. All Rights Reserved. // // Use of this source code is governed by a BSD-style license // that can be found in the COPYING file in the root of the source // tree. An additional intellectual property rights grant can be found // in the file PATENTS. All contributing project authors may // be found in the AUTHORS file in the root of the source tree. // ----------------------------------------------------------------------------- // // WebP container demux. // #ifdef HAVE_CONFIG_H #include "config.h" #endif #include #include #include #include "../utils/utils.h" #include "../webp/decode.h" // WebPGetFeatures #include "../webp/demux.h" #include "../webp/format_constants.h" #define DMUX_MAJ_VERSION 0 #define DMUX_MIN_VERSION 2 #define DMUX_REV_VERSION 0 typedef struct { size_t start_; // start location of the data size_t end_; // end location size_t riff_end_; // riff chunk end location, can be > end_. size_t buf_size_; // size of the buffer const uint8_t* buf_; } MemBuffer; typedef struct { size_t offset_; size_t size_; } ChunkData; typedef struct Frame { int x_offset_, y_offset_; int width_, height_; int has_alpha_; int duration_; WebPMuxAnimDispose dispose_method_; WebPMuxAnimBlend blend_method_; int is_fragment_; // this is a frame fragment (and not a full frame). int frame_num_; // the referent frame number for use in assembling fragments. int complete_; // img_components_ contains a full image. ChunkData img_components_[2]; // 0=VP8{,L} 1=ALPH struct Frame* next_; } Frame; typedef struct Chunk { ChunkData data_; struct Chunk* next_; } Chunk; struct WebPDemuxer { MemBuffer mem_; WebPDemuxState state_; int is_ext_format_; uint32_t feature_flags_; int canvas_width_, canvas_height_; int loop_count_; uint32_t bgcolor_; int num_frames_; Frame* frames_; Frame** frames_tail_; Chunk* chunks_; // non-image chunks Chunk** chunks_tail_; }; typedef enum { PARSE_OK, PARSE_NEED_MORE_DATA, PARSE_ERROR } ParseStatus; typedef struct ChunkParser { uint8_t id[4]; ParseStatus (*parse)(WebPDemuxer* const dmux); int (*valid)(const WebPDemuxer* const dmux); } ChunkParser; static ParseStatus ParseSingleImage(WebPDemuxer* const dmux); static ParseStatus ParseVP8X(WebPDemuxer* const dmux); static int IsValidSimpleFormat(const WebPDemuxer* const dmux); static int IsValidExtendedFormat(const WebPDemuxer* const dmux); static const ChunkParser kMasterChunks[] = { { { 'V', 'P', '8', ' ' }, ParseSingleImage, IsValidSimpleFormat }, { { 'V', 'P', '8', 'L' }, ParseSingleImage, IsValidSimpleFormat }, { { 'V', 'P', '8', 'X' }, ParseVP8X, IsValidExtendedFormat }, { { '0', '0', '0', '0' }, NULL, NULL }, }; //------------------------------------------------------------------------------ int WebPGetDemuxVersion(void) { return (DMUX_MAJ_VERSION << 16) | (DMUX_MIN_VERSION << 8) | DMUX_REV_VERSION; } // ----------------------------------------------------------------------------- // MemBuffer static int RemapMemBuffer(MemBuffer* const mem, const uint8_t* data, size_t size) { if (size < mem->buf_size_) return 0; // can't remap to a shorter buffer! mem->buf_ = data; mem->end_ = mem->buf_size_ = size; return 1; } static int InitMemBuffer(MemBuffer* const mem, const uint8_t* data, size_t size) { memset(mem, 0, sizeof(*mem)); return RemapMemBuffer(mem, data, size); } // Return the remaining data size available in 'mem'. static WEBP_INLINE size_t MemDataSize(const MemBuffer* const mem) { return (mem->end_ - mem->start_); } // Return true if 'size' exceeds the end of the RIFF chunk. static WEBP_INLINE int SizeIsInvalid(const MemBuffer* const mem, size_t size) { return (size > mem->riff_end_ - mem->start_); } static WEBP_INLINE void Skip(MemBuffer* const mem, size_t size) { mem->start_ += size; } static WEBP_INLINE void Rewind(MemBuffer* const mem, size_t size) { mem->start_ -= size; } static WEBP_INLINE const uint8_t* GetBuffer(MemBuffer* const mem) { return mem->buf_ + mem->start_; } // Read from 'mem' and skip the read bytes. static WEBP_INLINE uint8_t ReadByte(MemBuffer* const mem) { const uint8_t byte = mem->buf_[mem->start_]; Skip(mem, 1); return byte; } static WEBP_INLINE int ReadLE16s(MemBuffer* const mem) { const uint8_t* const data = mem->buf_ + mem->start_; const int val = GetLE16(data); Skip(mem, 2); return val; } static WEBP_INLINE int ReadLE24s(MemBuffer* const mem) { const uint8_t* const data = mem->buf_ + mem->start_; const int val = GetLE24(data); Skip(mem, 3); return val; } static WEBP_INLINE uint32_t ReadLE32(MemBuffer* const mem) { const uint8_t* const data = mem->buf_ + mem->start_; const uint32_t val = GetLE32(data); Skip(mem, 4); return val; } // ----------------------------------------------------------------------------- // Secondary chunk parsing static void AddChunk(WebPDemuxer* const dmux, Chunk* const chunk) { *dmux->chunks_tail_ = chunk; chunk->next_ = NULL; dmux->chunks_tail_ = &chunk->next_; } // Add a frame to the end of the list, ensuring the last frame is complete. // Returns true on success, false otherwise. static int AddFrame(WebPDemuxer* const dmux, Frame* const frame) { const Frame* const last_frame = *dmux->frames_tail_; if (last_frame != NULL && !last_frame->complete_) return 0; *dmux->frames_tail_ = frame; frame->next_ = NULL; dmux->frames_tail_ = &frame->next_; return 1; } // Store image bearing chunks to 'frame'. static ParseStatus StoreFrame(int frame_num, uint32_t min_size, MemBuffer* const mem, Frame* const frame) { int alpha_chunks = 0; int image_chunks = 0; int done = (MemDataSize(mem) < min_size); ParseStatus status = PARSE_OK; if (done) return PARSE_NEED_MORE_DATA; do { const size_t chunk_start_offset = mem->start_; const uint32_t fourcc = ReadLE32(mem); const uint32_t payload_size = ReadLE32(mem); const uint32_t payload_size_padded = payload_size + (payload_size & 1); const size_t payload_available = (payload_size_padded > MemDataSize(mem)) ? MemDataSize(mem) : payload_size_padded; const size_t chunk_size = CHUNK_HEADER_SIZE + payload_available; if (payload_size > MAX_CHUNK_PAYLOAD) return PARSE_ERROR; if (SizeIsInvalid(mem, payload_size_padded)) return PARSE_ERROR; if (payload_size_padded > MemDataSize(mem)) status = PARSE_NEED_MORE_DATA; switch (fourcc) { case MKFOURCC('A', 'L', 'P', 'H'): if (alpha_chunks == 0) { ++alpha_chunks; frame->img_components_[1].offset_ = chunk_start_offset; frame->img_components_[1].size_ = chunk_size; frame->has_alpha_ = 1; frame->frame_num_ = frame_num; Skip(mem, payload_available); } else { goto Done; } break; case MKFOURCC('V', 'P', '8', 'L'): if (alpha_chunks > 0) return PARSE_ERROR; // VP8L has its own alpha // fall through case MKFOURCC('V', 'P', '8', ' '): if (image_chunks == 0) { // Extract the bitstream features, tolerating failures when the data // is incomplete. WebPBitstreamFeatures features; const VP8StatusCode vp8_status = WebPGetFeatures(mem->buf_ + chunk_start_offset, chunk_size, &features); if (status == PARSE_NEED_MORE_DATA && vp8_status == VP8_STATUS_NOT_ENOUGH_DATA) { return PARSE_NEED_MORE_DATA; } else if (vp8_status != VP8_STATUS_OK) { // We have enough data, and yet WebPGetFeatures() failed. return PARSE_ERROR; } ++image_chunks; frame->img_components_[0].offset_ = chunk_start_offset; frame->img_components_[0].size_ = chunk_size; frame->width_ = features.width; frame->height_ = features.height; frame->has_alpha_ |= features.has_alpha; frame->frame_num_ = frame_num; frame->complete_ = (status == PARSE_OK); Skip(mem, payload_available); } else { goto Done; } break; Done: default: // Restore fourcc/size when moving up one level in parsing. Rewind(mem, CHUNK_HEADER_SIZE); done = 1; break; } if (mem->start_ == mem->riff_end_) { done = 1; } else if (MemDataSize(mem) < CHUNK_HEADER_SIZE) { status = PARSE_NEED_MORE_DATA; } } while (!done && status == PARSE_OK); return status; } // Creates a new Frame if 'actual_size' is within bounds and 'mem' contains // enough data ('min_size') to parse the payload. // Returns PARSE_OK on success with *frame pointing to the new Frame. // Returns PARSE_NEED_MORE_DATA with insufficient data, PARSE_ERROR otherwise. static ParseStatus NewFrame(const MemBuffer* const mem, uint32_t min_size, uint32_t actual_size, Frame** frame) { if (SizeIsInvalid(mem, min_size)) return PARSE_ERROR; if (actual_size < min_size) return PARSE_ERROR; if (MemDataSize(mem) < min_size) return PARSE_NEED_MORE_DATA; *frame = (Frame*)calloc(1, sizeof(**frame)); return (*frame == NULL) ? PARSE_ERROR : PARSE_OK; } // Parse a 'ANMF' chunk and any image bearing chunks that immediately follow. // 'frame_chunk_size' is the previously validated, padded chunk size. static ParseStatus ParseAnimationFrame( WebPDemuxer* const dmux, uint32_t frame_chunk_size) { const int is_animation = !!(dmux->feature_flags_ & ANIMATION_FLAG); const uint32_t anmf_payload_size = frame_chunk_size - ANMF_CHUNK_SIZE; int added_frame = 0; int bits; MemBuffer* const mem = &dmux->mem_; Frame* frame; ParseStatus status = NewFrame(mem, ANMF_CHUNK_SIZE, frame_chunk_size, &frame); if (status != PARSE_OK) return status; frame->x_offset_ = 2 * ReadLE24s(mem); frame->y_offset_ = 2 * ReadLE24s(mem); frame->width_ = 1 + ReadLE24s(mem); frame->height_ = 1 + ReadLE24s(mem); frame->duration_ = ReadLE24s(mem); bits = ReadByte(mem); frame->dispose_method_ = (bits & 1) ? WEBP_MUX_DISPOSE_BACKGROUND : WEBP_MUX_DISPOSE_NONE; frame->blend_method_ = (bits & 2) ? WEBP_MUX_NO_BLEND : WEBP_MUX_BLEND; if (frame->width_ * (uint64_t)frame->height_ >= MAX_IMAGE_AREA) { free(frame); return PARSE_ERROR; } // Store a frame only if the animation flag is set there is some data for // this frame is available. status = StoreFrame(dmux->num_frames_ + 1, anmf_payload_size, mem, frame); if (status != PARSE_ERROR && is_animation && frame->frame_num_ > 0) { added_frame = AddFrame(dmux, frame); if (added_frame) { ++dmux->num_frames_; } else { status = PARSE_ERROR; } } if (!added_frame) free(frame); return status; } #ifdef WEBP_EXPERIMENTAL_FEATURES // Parse a 'FRGM' chunk and any image bearing chunks that immediately follow. // 'fragment_chunk_size' is the previously validated, padded chunk size. static ParseStatus ParseFragment(WebPDemuxer* const dmux, uint32_t fragment_chunk_size) { const int frame_num = 1; // All fragments belong to the 1st (and only) frame. const int is_fragmented = !!(dmux->feature_flags_ & FRAGMENTS_FLAG); const uint32_t frgm_payload_size = fragment_chunk_size - FRGM_CHUNK_SIZE; int added_fragment = 0; MemBuffer* const mem = &dmux->mem_; Frame* frame; ParseStatus status = NewFrame(mem, FRGM_CHUNK_SIZE, fragment_chunk_size, &frame); if (status != PARSE_OK) return status; frame->is_fragment_ = 1; frame->x_offset_ = 2 * ReadLE24s(mem); frame->y_offset_ = 2 * ReadLE24s(mem); // Store a fragment only if the 'fragments' flag is set and there is some // data available. status = StoreFrame(frame_num, frgm_payload_size, mem, frame); if (status != PARSE_ERROR && is_fragmented && frame->frame_num_ > 0) { added_fragment = AddFrame(dmux, frame); if (!added_fragment) { status = PARSE_ERROR; } else { dmux->num_frames_ = 1; } } if (!added_fragment) free(frame); return status; } #endif // WEBP_EXPERIMENTAL_FEATURES // General chunk storage, starting with the header at 'start_offset', allowing // the user to request the payload via a fourcc string. 'size' includes the // header and the unpadded payload size. // Returns true on success, false otherwise. static int StoreChunk(WebPDemuxer* const dmux, size_t start_offset, uint32_t size) { Chunk* const chunk = (Chunk*)calloc(1, sizeof(*chunk)); if (chunk == NULL) return 0; chunk->data_.offset_ = start_offset; chunk->data_.size_ = size; AddChunk(dmux, chunk); return 1; } // ----------------------------------------------------------------------------- // Primary chunk parsing static ParseStatus ReadHeader(MemBuffer* const mem) { const size_t min_size = RIFF_HEADER_SIZE + CHUNK_HEADER_SIZE; uint32_t riff_size; // Basic file level validation. if (MemDataSize(mem) < min_size) return PARSE_NEED_MORE_DATA; if (memcmp(GetBuffer(mem), "RIFF", CHUNK_SIZE_BYTES) || memcmp(GetBuffer(mem) + CHUNK_HEADER_SIZE, "WEBP", CHUNK_SIZE_BYTES)) { return PARSE_ERROR; } riff_size = GetLE32(GetBuffer(mem) + TAG_SIZE); if (riff_size < CHUNK_HEADER_SIZE) return PARSE_ERROR; if (riff_size > MAX_CHUNK_PAYLOAD) return PARSE_ERROR; // There's no point in reading past the end of the RIFF chunk mem->riff_end_ = riff_size + CHUNK_HEADER_SIZE; if (mem->buf_size_ > mem->riff_end_) { mem->buf_size_ = mem->end_ = mem->riff_end_; } Skip(mem, RIFF_HEADER_SIZE); return PARSE_OK; } static ParseStatus ParseSingleImage(WebPDemuxer* const dmux) { const size_t min_size = CHUNK_HEADER_SIZE; MemBuffer* const mem = &dmux->mem_; Frame* frame; ParseStatus status; int image_added = 0; if (dmux->frames_ != NULL) return PARSE_ERROR; if (SizeIsInvalid(mem, min_size)) return PARSE_ERROR; if (MemDataSize(mem) < min_size) return PARSE_NEED_MORE_DATA; frame = (Frame*)calloc(1, sizeof(*frame)); if (frame == NULL) return PARSE_ERROR; // For the single image case we allow parsing of a partial frame, but we need // at least CHUNK_HEADER_SIZE for parsing. status = StoreFrame(1, CHUNK_HEADER_SIZE, &dmux->mem_, frame); if (status != PARSE_ERROR) { const int has_alpha = !!(dmux->feature_flags_ & ALPHA_FLAG); // Clear any alpha when the alpha flag is missing. if (!has_alpha && frame->img_components_[1].size_ > 0) { frame->img_components_[1].offset_ = 0; frame->img_components_[1].size_ = 0; frame->has_alpha_ = 0; } // Use the frame width/height as the canvas values for non-vp8x files. // Also, set ALPHA_FLAG if this is a lossless image with alpha. if (!dmux->is_ext_format_ && frame->width_ > 0 && frame->height_ > 0) { dmux->state_ = WEBP_DEMUX_PARSED_HEADER; dmux->canvas_width_ = frame->width_; dmux->canvas_height_ = frame->height_; dmux->feature_flags_ |= frame->has_alpha_ ? ALPHA_FLAG : 0; } if (!AddFrame(dmux, frame)) { status = PARSE_ERROR; // last frame was left incomplete } else { image_added = 1; dmux->num_frames_ = 1; } } if (!image_added) free(frame); return status; } static ParseStatus ParseVP8XChunks(WebPDemuxer* const dmux) { const int is_animation = !!(dmux->feature_flags_ & ANIMATION_FLAG); MemBuffer* const mem = &dmux->mem_; int anim_chunks = 0; ParseStatus status = PARSE_OK; do { int store_chunk = 1; const size_t chunk_start_offset = mem->start_; const uint32_t fourcc = ReadLE32(mem); const uint32_t chunk_size = ReadLE32(mem); const uint32_t chunk_size_padded = chunk_size + (chunk_size & 1); if (chunk_size > MAX_CHUNK_PAYLOAD) return PARSE_ERROR; if (SizeIsInvalid(mem, chunk_size_padded)) return PARSE_ERROR; switch (fourcc) { case MKFOURCC('V', 'P', '8', 'X'): { return PARSE_ERROR; } case MKFOURCC('A', 'L', 'P', 'H'): case MKFOURCC('V', 'P', '8', ' '): case MKFOURCC('V', 'P', '8', 'L'): { // check that this isn't an animation (all frames should be in an ANMF). if (anim_chunks > 0 || is_animation) return PARSE_ERROR; Rewind(mem, CHUNK_HEADER_SIZE); status = ParseSingleImage(dmux); break; } case MKFOURCC('A', 'N', 'I', 'M'): { if (chunk_size_padded < ANIM_CHUNK_SIZE) return PARSE_ERROR; if (MemDataSize(mem) < chunk_size_padded) { status = PARSE_NEED_MORE_DATA; } else if (anim_chunks == 0) { ++anim_chunks; dmux->bgcolor_ = ReadLE32(mem); dmux->loop_count_ = ReadLE16s(mem); Skip(mem, chunk_size_padded - ANIM_CHUNK_SIZE); } else { store_chunk = 0; goto Skip; } break; } case MKFOURCC('A', 'N', 'M', 'F'): { if (anim_chunks == 0) return PARSE_ERROR; // 'ANIM' precedes frames. status = ParseAnimationFrame(dmux, chunk_size_padded); break; } #ifdef WEBP_EXPERIMENTAL_FEATURES case MKFOURCC('F', 'R', 'G', 'M'): { status = ParseFragment(dmux, chunk_size_padded); break; } #endif case MKFOURCC('I', 'C', 'C', 'P'): { store_chunk = !!(dmux->feature_flags_ & ICCP_FLAG); goto Skip; } case MKFOURCC('E', 'X', 'I', 'F'): { store_chunk = !!(dmux->feature_flags_ & EXIF_FLAG); goto Skip; } case MKFOURCC('X', 'M', 'P', ' '): { store_chunk = !!(dmux->feature_flags_ & XMP_FLAG); goto Skip; } Skip: default: { if (chunk_size_padded <= MemDataSize(mem)) { if (store_chunk) { // Store only the chunk header and unpadded size as only the payload // will be returned to the user. if (!StoreChunk(dmux, chunk_start_offset, CHUNK_HEADER_SIZE + chunk_size)) { return PARSE_ERROR; } } Skip(mem, chunk_size_padded); } else { status = PARSE_NEED_MORE_DATA; } } } if (mem->start_ == mem->riff_end_) { break; } else if (MemDataSize(mem) < CHUNK_HEADER_SIZE) { status = PARSE_NEED_MORE_DATA; } } while (status == PARSE_OK); return status; } static ParseStatus ParseVP8X(WebPDemuxer* const dmux) { MemBuffer* const mem = &dmux->mem_; uint32_t vp8x_size; if (MemDataSize(mem) < CHUNK_HEADER_SIZE) return PARSE_NEED_MORE_DATA; dmux->is_ext_format_ = 1; Skip(mem, TAG_SIZE); // VP8X vp8x_size = ReadLE32(mem); if (vp8x_size > MAX_CHUNK_PAYLOAD) return PARSE_ERROR; if (vp8x_size < VP8X_CHUNK_SIZE) return PARSE_ERROR; vp8x_size += vp8x_size & 1; if (SizeIsInvalid(mem, vp8x_size)) return PARSE_ERROR; if (MemDataSize(mem) < vp8x_size) return PARSE_NEED_MORE_DATA; dmux->feature_flags_ = ReadByte(mem); Skip(mem, 3); // Reserved. dmux->canvas_width_ = 1 + ReadLE24s(mem); dmux->canvas_height_ = 1 + ReadLE24s(mem); if (dmux->canvas_width_ * (uint64_t)dmux->canvas_height_ >= MAX_IMAGE_AREA) { return PARSE_ERROR; // image final dimension is too large } Skip(mem, vp8x_size - VP8X_CHUNK_SIZE); // skip any trailing data. dmux->state_ = WEBP_DEMUX_PARSED_HEADER; if (SizeIsInvalid(mem, CHUNK_HEADER_SIZE)) return PARSE_ERROR; if (MemDataSize(mem) < CHUNK_HEADER_SIZE) return PARSE_NEED_MORE_DATA; return ParseVP8XChunks(dmux); } // ----------------------------------------------------------------------------- // Format validation static int IsValidSimpleFormat(const WebPDemuxer* const dmux) { const Frame* const frame = dmux->frames_; if (dmux->state_ == WEBP_DEMUX_PARSING_HEADER) return 1; if (dmux->canvas_width_ <= 0 || dmux->canvas_height_ <= 0) return 0; if (dmux->state_ == WEBP_DEMUX_DONE && frame == NULL) return 0; if (frame->width_ <= 0 || frame->height_ <= 0) return 0; return 1; } // If 'exact' is true, check that the image resolution matches the canvas. // If 'exact' is false, check that the x/y offsets do not exceed the canvas. // TODO(jzern): this is insufficient in the fragmented image case if the // expectation is that the fragments completely cover the canvas. static int CheckFrameBounds(const Frame* const frame, int exact, int canvas_width, int canvas_height) { if (exact) { if (frame->x_offset_ != 0 || frame->y_offset_ != 0) { return 0; } if (frame->width_ != canvas_width || frame->height_ != canvas_height) { return 0; } } else { if (frame->x_offset_ < 0 || frame->y_offset_ < 0) return 0; if (frame->width_ + frame->x_offset_ > canvas_width) return 0; if (frame->height_ + frame->y_offset_ > canvas_height) return 0; } return 1; } static int IsValidExtendedFormat(const WebPDemuxer* const dmux) { const int is_animation = !!(dmux->feature_flags_ & ANIMATION_FLAG); const int is_fragmented = !!(dmux->feature_flags_ & FRAGMENTS_FLAG); const Frame* f = dmux->frames_; if (dmux->state_ == WEBP_DEMUX_PARSING_HEADER) return 1; if (dmux->canvas_width_ <= 0 || dmux->canvas_height_ <= 0) return 0; if (dmux->loop_count_ < 0) return 0; if (dmux->state_ == WEBP_DEMUX_DONE && dmux->frames_ == NULL) return 0; #ifndef WEBP_EXPERIMENTAL_FEATURES if (is_fragmented) return 0; #endif while (f != NULL) { const int cur_frame_set = f->frame_num_; int frame_count = 0, fragment_count = 0; // Check frame properties and if the image is composed of fragments that // each fragment came from a fragment. for (; f != NULL && f->frame_num_ == cur_frame_set; f = f->next_) { const ChunkData* const image = f->img_components_; const ChunkData* const alpha = f->img_components_ + 1; if (is_fragmented && !f->is_fragment_) return 0; if (!is_fragmented && f->is_fragment_) return 0; if (!is_animation && f->frame_num_ > 1) return 0; if (f->complete_) { if (alpha->size_ == 0 && image->size_ == 0) return 0; // Ensure alpha precedes image bitstream. if (alpha->size_ > 0 && alpha->offset_ > image->offset_) { return 0; } if (f->width_ <= 0 || f->height_ <= 0) return 0; } else { // There shouldn't be a partial frame in a complete file. if (dmux->state_ == WEBP_DEMUX_DONE) return 0; // Ensure alpha precedes image bitstream. if (alpha->size_ > 0 && image->size_ > 0 && alpha->offset_ > image->offset_) { return 0; } // There shouldn't be any frames after an incomplete one. if (f->next_ != NULL) return 0; } if (f->width_ > 0 && f->height_ > 0 && !CheckFrameBounds(f, !(is_animation || is_fragmented), dmux->canvas_width_, dmux->canvas_height_)) { return 0; } fragment_count += f->is_fragment_; ++frame_count; } if (!is_fragmented && frame_count > 1) return 0; if (fragment_count > 0 && frame_count != fragment_count) return 0; } return 1; } // ----------------------------------------------------------------------------- // WebPDemuxer object static void InitDemux(WebPDemuxer* const dmux, const MemBuffer* const mem) { dmux->state_ = WEBP_DEMUX_PARSING_HEADER; dmux->loop_count_ = 1; dmux->bgcolor_ = 0xFFFFFFFF; // White background by default. dmux->canvas_width_ = -1; dmux->canvas_height_ = -1; dmux->frames_tail_ = &dmux->frames_; dmux->chunks_tail_ = &dmux->chunks_; dmux->mem_ = *mem; } WebPDemuxer* WebPDemuxInternal(const WebPData* data, int allow_partial, WebPDemuxState* state, int version) { const ChunkParser* parser; int partial; ParseStatus status = PARSE_ERROR; MemBuffer mem; WebPDemuxer* dmux; if (state != NULL) *state = WEBP_DEMUX_PARSE_ERROR; if (WEBP_ABI_IS_INCOMPATIBLE(version, WEBP_DEMUX_ABI_VERSION)) return NULL; if (data == NULL || data->bytes == NULL || data->size == 0) return NULL; if (!InitMemBuffer(&mem, data->bytes, data->size)) return NULL; status = ReadHeader(&mem); if (status != PARSE_OK) { if (state != NULL) { *state = (status == PARSE_NEED_MORE_DATA) ? WEBP_DEMUX_PARSING_HEADER : WEBP_DEMUX_PARSE_ERROR; } return NULL; } partial = (mem.buf_size_ < mem.riff_end_); if (!allow_partial && partial) return NULL; dmux = (WebPDemuxer*)calloc(1, sizeof(*dmux)); if (dmux == NULL) return NULL; InitDemux(dmux, &mem); status = PARSE_ERROR; for (parser = kMasterChunks; parser->parse != NULL; ++parser) { if (!memcmp(parser->id, GetBuffer(&dmux->mem_), TAG_SIZE)) { status = parser->parse(dmux); if (status == PARSE_OK) dmux->state_ = WEBP_DEMUX_DONE; if (status == PARSE_NEED_MORE_DATA && !partial) status = PARSE_ERROR; if (status != PARSE_ERROR && !parser->valid(dmux)) status = PARSE_ERROR; if (status == PARSE_ERROR) dmux->state_ = WEBP_DEMUX_PARSE_ERROR; break; } } if (state != NULL) *state = dmux->state_; if (status == PARSE_ERROR) { WebPDemuxDelete(dmux); return NULL; } return dmux; } void WebPDemuxDelete(WebPDemuxer* dmux) { Chunk* c; Frame* f; if (dmux == NULL) return; for (f = dmux->frames_; f != NULL;) { Frame* const cur_frame = f; f = f->next_; free(cur_frame); } for (c = dmux->chunks_; c != NULL;) { Chunk* const cur_chunk = c; c = c->next_; free(cur_chunk); } free(dmux); } // ----------------------------------------------------------------------------- uint32_t WebPDemuxGetI(const WebPDemuxer* dmux, WebPFormatFeature feature) { if (dmux == NULL) return 0; switch (feature) { case WEBP_FF_FORMAT_FLAGS: return dmux->feature_flags_; case WEBP_FF_CANVAS_WIDTH: return (uint32_t)dmux->canvas_width_; case WEBP_FF_CANVAS_HEIGHT: return (uint32_t)dmux->canvas_height_; case WEBP_FF_LOOP_COUNT: return (uint32_t)dmux->loop_count_; case WEBP_FF_BACKGROUND_COLOR: return dmux->bgcolor_; case WEBP_FF_FRAME_COUNT: return (uint32_t)dmux->num_frames_; } return 0; } // ----------------------------------------------------------------------------- // Frame iteration // Find the first 'frame_num' frame. There may be multiple such frames in a // fragmented frame. static const Frame* GetFrame(const WebPDemuxer* const dmux, int frame_num) { const Frame* f; for (f = dmux->frames_; f != NULL; f = f->next_) { if (frame_num == f->frame_num_) break; } return f; } // Returns fragment 'fragment_num' and the total count. static const Frame* GetFragment( const Frame* const frame_set, int fragment_num, int* const count) { const int this_frame = frame_set->frame_num_; const Frame* f = frame_set; const Frame* fragment = NULL; int total; for (total = 0; f != NULL && f->frame_num_ == this_frame; f = f->next_) { if (++total == fragment_num) fragment = f; } *count = total; return fragment; } static const uint8_t* GetFramePayload(const uint8_t* const mem_buf, const Frame* const frame, size_t* const data_size) { *data_size = 0; if (frame != NULL) { const ChunkData* const image = frame->img_components_; const ChunkData* const alpha = frame->img_components_ + 1; size_t start_offset = image->offset_; *data_size = image->size_; // if alpha exists it precedes image, update the size allowing for // intervening chunks. if (alpha->size_ > 0) { const size_t inter_size = (image->offset_ > 0) ? image->offset_ - (alpha->offset_ + alpha->size_) : 0; start_offset = alpha->offset_; *data_size += alpha->size_ + inter_size; } return mem_buf + start_offset; } return NULL; } // Create a whole 'frame' from VP8 (+ alpha) or lossless. static int SynthesizeFrame(const WebPDemuxer* const dmux, const Frame* const first_frame, int fragment_num, WebPIterator* const iter) { const uint8_t* const mem_buf = dmux->mem_.buf_; int num_fragments; size_t payload_size = 0; const Frame* const fragment = GetFragment(first_frame, fragment_num, &num_fragments); const uint8_t* const payload = GetFramePayload(mem_buf, fragment, &payload_size); if (payload == NULL) return 0; assert(first_frame != NULL); iter->frame_num = first_frame->frame_num_; iter->num_frames = dmux->num_frames_; iter->fragment_num = fragment_num; iter->num_fragments = num_fragments; iter->x_offset = fragment->x_offset_; iter->y_offset = fragment->y_offset_; iter->width = fragment->width_; iter->height = fragment->height_; iter->has_alpha = fragment->has_alpha_; iter->duration = fragment->duration_; iter->dispose_method = fragment->dispose_method_; iter->blend_method = fragment->blend_method_; iter->complete = fragment->complete_; iter->fragment.bytes = payload; iter->fragment.size = payload_size; // TODO(jzern): adjust offsets for 'FRGM's embedded in 'ANMF's return 1; } static int SetFrame(int frame_num, WebPIterator* const iter) { const Frame* frame; const WebPDemuxer* const dmux = (WebPDemuxer*)iter->private_; if (dmux == NULL || frame_num < 0) return 0; if (frame_num > dmux->num_frames_) return 0; if (frame_num == 0) frame_num = dmux->num_frames_; frame = GetFrame(dmux, frame_num); if (frame == NULL) return 0; return SynthesizeFrame(dmux, frame, 1, iter); } int WebPDemuxGetFrame(const WebPDemuxer* dmux, int frame, WebPIterator* iter) { if (iter == NULL) return 0; memset(iter, 0, sizeof(*iter)); iter->private_ = (void*)dmux; return SetFrame(frame, iter); } int WebPDemuxNextFrame(WebPIterator* iter) { if (iter == NULL) return 0; return SetFrame(iter->frame_num + 1, iter); } int WebPDemuxPrevFrame(WebPIterator* iter) { if (iter == NULL) return 0; if (iter->frame_num <= 1) return 0; return SetFrame(iter->frame_num - 1, iter); } int WebPDemuxSelectFragment(WebPIterator* iter, int fragment_num) { if (iter != NULL && iter->private_ != NULL && fragment_num > 0) { const WebPDemuxer* const dmux = (WebPDemuxer*)iter->private_; const Frame* const frame = GetFrame(dmux, iter->frame_num); if (frame == NULL) return 0; return SynthesizeFrame(dmux, frame, fragment_num, iter); } return 0; } void WebPDemuxReleaseIterator(WebPIterator* iter) { (void)iter; } // ----------------------------------------------------------------------------- // Chunk iteration static int ChunkCount(const WebPDemuxer* const dmux, const char fourcc[4]) { const uint8_t* const mem_buf = dmux->mem_.buf_; const Chunk* c; int count = 0; for (c = dmux->chunks_; c != NULL; c = c->next_) { const uint8_t* const header = mem_buf + c->data_.offset_; if (!memcmp(header, fourcc, TAG_SIZE)) ++count; } return count; } static const Chunk* GetChunk(const WebPDemuxer* const dmux, const char fourcc[4], int chunk_num) { const uint8_t* const mem_buf = dmux->mem_.buf_; const Chunk* c; int count = 0; for (c = dmux->chunks_; c != NULL; c = c->next_) { const uint8_t* const header = mem_buf + c->data_.offset_; if (!memcmp(header, fourcc, TAG_SIZE)) ++count; if (count == chunk_num) break; } return c; } static int SetChunk(const char fourcc[4], int chunk_num, WebPChunkIterator* const iter) { const WebPDemuxer* const dmux = (WebPDemuxer*)iter->private_; int count; if (dmux == NULL || fourcc == NULL || chunk_num < 0) return 0; count = ChunkCount(dmux, fourcc); if (count == 0) return 0; if (chunk_num == 0) chunk_num = count; if (chunk_num <= count) { const uint8_t* const mem_buf = dmux->mem_.buf_; const Chunk* const chunk = GetChunk(dmux, fourcc, chunk_num); iter->chunk.bytes = mem_buf + chunk->data_.offset_ + CHUNK_HEADER_SIZE; iter->chunk.size = chunk->data_.size_ - CHUNK_HEADER_SIZE; iter->num_chunks = count; iter->chunk_num = chunk_num; return 1; } return 0; } int WebPDemuxGetChunk(const WebPDemuxer* dmux, const char fourcc[4], int chunk_num, WebPChunkIterator* iter) { if (iter == NULL) return 0; memset(iter, 0, sizeof(*iter)); iter->private_ = (void*)dmux; return SetChunk(fourcc, chunk_num, iter); } int WebPDemuxNextChunk(WebPChunkIterator* iter) { if (iter != NULL) { const char* const fourcc = (const char*)iter->chunk.bytes - CHUNK_HEADER_SIZE; return SetChunk(fourcc, iter->chunk_num + 1, iter); } return 0; } int WebPDemuxPrevChunk(WebPChunkIterator* iter) { if (iter != NULL && iter->chunk_num > 1) { const char* const fourcc = (const char*)iter->chunk.bytes - CHUNK_HEADER_SIZE; return SetChunk(fourcc, iter->chunk_num - 1, iter); } return 0; } void WebPDemuxReleaseChunkIterator(WebPChunkIterator* iter) { (void)iter; }