webm/common/vp9_header_parser.cc
James Zern a5837e4dd0 vp9_header_parser: make SetFrame private
and call it from ParseUncompressedHeader. this avoids attempts to parse
a stale buffer should SetFrame fail.

BUG=webm:1493

Change-Id: I441ae9d0db3f0a01d73902a8f5b06812e2e93422
2018-02-02 00:39:52 -08:00

267 lines
7.2 KiB
C++

// Copyright (c) 2016 The WebM project authors. All Rights Reserved.
//
// Use of this source code is governed by a BSD-style license
// that can be found in the LICENSE 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.
#include "common/vp9_header_parser.h"
#include <stdio.h>
namespace vp9_parser {
bool Vp9HeaderParser::SetFrame(const uint8_t* frame, size_t length) {
if (!frame || length == 0)
return false;
frame_ = frame;
frame_size_ = length;
bit_offset_ = 0;
profile_ = -1;
show_existing_frame_ = 0;
key_ = 0;
altref_ = 0;
error_resilient_mode_ = 0;
intra_only_ = 0;
reset_frame_context_ = 0;
color_space_ = 0;
color_range_ = 0;
subsampling_x_ = 0;
subsampling_y_ = 0;
refresh_frame_flags_ = 0;
return true;
}
bool Vp9HeaderParser::ParseUncompressedHeader(const uint8_t* frame,
size_t length) {
if (!SetFrame(frame, length))
return false;
const int frame_marker = VpxReadLiteral(2);
if (frame_marker != kVp9FrameMarker) {
fprintf(stderr, "Invalid VP9 frame_marker:%d\n", frame_marker);
return false;
}
profile_ = ReadBit();
profile_ |= ReadBit() << 1;
if (profile_ > 2)
profile_ += ReadBit();
// TODO(fgalligan): Decide how to handle show existing frames.
show_existing_frame_ = ReadBit();
if (show_existing_frame_)
return true;
key_ = !ReadBit();
altref_ = !ReadBit();
error_resilient_mode_ = ReadBit();
if (key_) {
if (!ValidateVp9SyncCode()) {
fprintf(stderr, "Invalid Sync code!\n");
return false;
}
ParseColorSpace();
ParseFrameResolution();
ParseFrameParallelMode();
ParseTileInfo();
} else {
intra_only_ = altref_ ? ReadBit() : 0;
reset_frame_context_ = error_resilient_mode_ ? 0 : VpxReadLiteral(2);
if (intra_only_) {
if (!ValidateVp9SyncCode()) {
fprintf(stderr, "Invalid Sync code!\n");
return false;
}
if (profile_ > 0) {
ParseColorSpace();
} else {
// NOTE: The intra-only frame header does not include the specification
// of either the color format or color sub-sampling in profile 0. VP9
// specifies that the default color format should be YUV 4:2:0 in this
// case (normative).
color_space_ = kVpxCsBt601;
color_range_ = kVpxCrStudioRange;
subsampling_y_ = subsampling_x_ = 1;
bit_depth_ = 8;
}
refresh_frame_flags_ = VpxReadLiteral(kRefFrames);
ParseFrameResolution();
} else {
refresh_frame_flags_ = VpxReadLiteral(kRefFrames);
for (int i = 0; i < kRefsPerFrame; ++i) {
VpxReadLiteral(kRefFrames_LOG2); // Consume ref.
ReadBit(); // Consume ref sign bias.
}
bool found = false;
for (int i = 0; i < kRefsPerFrame; ++i) {
if (ReadBit()) {
// Found previous reference, width and height did not change since
// last frame.
found = true;
break;
}
}
if (!found)
ParseFrameResolution();
}
}
return true;
}
int Vp9HeaderParser::ReadBit() {
const size_t off = bit_offset_;
const size_t byte_offset = off >> 3;
const int bit_shift = 7 - static_cast<int>(off & 0x7);
if (byte_offset < frame_size_) {
const int bit = (frame_[byte_offset] >> bit_shift) & 1;
bit_offset_++;
return bit;
} else {
return 0;
}
}
int Vp9HeaderParser::VpxReadLiteral(int bits) {
int value = 0;
for (int bit = bits - 1; bit >= 0; --bit)
value |= ReadBit() << bit;
return value;
}
bool Vp9HeaderParser::ValidateVp9SyncCode() {
const int sync_code_0 = VpxReadLiteral(8);
const int sync_code_1 = VpxReadLiteral(8);
const int sync_code_2 = VpxReadLiteral(8);
return (sync_code_0 == 0x49 && sync_code_1 == 0x83 && sync_code_2 == 0x42);
}
void Vp9HeaderParser::ParseColorSpace() {
bit_depth_ = 0;
if (profile_ >= 2)
bit_depth_ = ReadBit() ? 12 : 10;
else
bit_depth_ = 8;
color_space_ = VpxReadLiteral(3);
if (color_space_ != kVpxCsSrgb) {
color_range_ = ReadBit();
if (profile_ == 1 || profile_ == 3) {
subsampling_x_ = ReadBit();
subsampling_y_ = ReadBit();
ReadBit();
} else {
subsampling_y_ = subsampling_x_ = 1;
}
} else {
color_range_ = kVpxCrFullRange;
if (profile_ == 1 || profile_ == 3) {
subsampling_y_ = subsampling_x_ = 0;
ReadBit();
}
}
}
void Vp9HeaderParser::ParseFrameResolution() {
width_ = VpxReadLiteral(16) + 1;
height_ = VpxReadLiteral(16) + 1;
}
void Vp9HeaderParser::ParseFrameParallelMode() {
if (ReadBit()) {
VpxReadLiteral(16); // display width
VpxReadLiteral(16); // display height
}
if (!error_resilient_mode_) {
ReadBit(); // Consume refresh frame context
frame_parallel_mode_ = ReadBit();
} else {
frame_parallel_mode_ = 1;
}
}
void Vp9HeaderParser::ParseTileInfo() {
VpxReadLiteral(2); // Consume frame context index
// loopfilter
VpxReadLiteral(6); // Consume filter level
VpxReadLiteral(3); // Consume sharpness level
const bool mode_ref_delta_enabled = ReadBit();
if (mode_ref_delta_enabled) {
const bool mode_ref_delta_update = ReadBit();
if (mode_ref_delta_update) {
const int kMaxRefLFDeltas = 4;
for (int i = 0; i < kMaxRefLFDeltas; ++i) {
if (ReadBit())
VpxReadLiteral(7); // Consume ref_deltas + sign
}
const int kMaxModeDeltas = 2;
for (int i = 0; i < kMaxModeDeltas; ++i) {
if (ReadBit())
VpxReadLiteral(7); // Consume mode_delta + sign
}
}
}
// quantization
VpxReadLiteral(8); // Consume base_q
SkipDeltaQ(); // y dc
SkipDeltaQ(); // uv ac
SkipDeltaQ(); // uv dc
// segmentation
const bool segmentation_enabled = ReadBit();
if (!segmentation_enabled) {
const int aligned_width = AlignPowerOfTwo(width_, kMiSizeLog2);
const int mi_cols = aligned_width >> kMiSizeLog2;
const int aligned_mi_cols = AlignPowerOfTwo(mi_cols, kMiSizeLog2);
const int sb_cols = aligned_mi_cols >> 3; // to_sbs(mi_cols);
int min_log2_n_tiles, max_log2_n_tiles;
for (max_log2_n_tiles = 0;
(sb_cols >> max_log2_n_tiles) >= kMinTileWidthB64;
max_log2_n_tiles++) {
}
max_log2_n_tiles--;
if (max_log2_n_tiles < 0)
max_log2_n_tiles = 0;
for (min_log2_n_tiles = 0; (kMaxTileWidthB64 << min_log2_n_tiles) < sb_cols;
min_log2_n_tiles++) {
}
// columns
const int max_log2_tile_cols = max_log2_n_tiles;
const int min_log2_tile_cols = min_log2_n_tiles;
int max_ones = max_log2_tile_cols - min_log2_tile_cols;
int log2_tile_cols = min_log2_tile_cols;
while (max_ones-- && ReadBit())
log2_tile_cols++;
// rows
int log2_tile_rows = ReadBit();
if (log2_tile_rows)
log2_tile_rows += ReadBit();
row_tiles_ = 1 << log2_tile_rows;
column_tiles_ = 1 << log2_tile_cols;
}
}
void Vp9HeaderParser::SkipDeltaQ() {
if (ReadBit())
VpxReadLiteral(4);
}
int Vp9HeaderParser::AlignPowerOfTwo(int value, int n) {
return (((value) + ((1 << (n)) - 1)) & ~((1 << (n)) - 1));
}
} // namespace vp9_parser