media/formats/mp2t/es_parser_h264.cc - chromium/src - Git at Google

 // Copyright 2014 The Chromium Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 #include "media/formats/mp2t/es_parser_h264.h"

 #include <limits>

 #include "base/logging.h"
 #include "base/numerics/safe_conversions.h"
 #include "base/optional.h"
 #include "media/base/decrypt_config.h"
 #include "media/base/encryption_scheme.h"
 #include "media/base/media_util.h"
 #include "media/base/stream_parser_buffer.h"
 #include "media/base/timestamp_constants.h"
 #include "media/base/video_frame.h"
 #include "media/filters/h264_parser.h"
 #include "media/formats/common/offset_byte_queue.h"
 #include "media/formats/mp2t/mp2t_common.h"
 #include "ui/gfx/geometry/rect.h"
 #include "ui/gfx/geometry/size.h"

 namespace media {
 namespace mp2t {

 #if BUILDFLAG(ENABLE_HLS_SAMPLE_AES)
 namespace {

 const int kSampleAESMaxUnprotectedNALULength = 48;
 const int kSampleAESClearLeaderSize = 32;
 const int kSampleAESEncryptBlocks = 1;
 const int kSampleAESSkipBlocks = 9;
 const int kSampleAESPatternUnit =
     (kSampleAESEncryptBlocks + kSampleAESSkipBlocks) * 16;

 // Attempts to find the first or only EP3B (emulation prevention 3 byte) in
 // the part of the |buffer| between |start_pos| and |end_pos|. Returns the
 // position of the EP3B, or 0 if there are none.
 // Note: the EP3B always follows two zero bytes, so the value 0 can never be a
 // valid position.
 int FindEP3B(const uint8_t* buffer, int start_pos, int end_pos) {
   const uint8_t* data = buffer + start_pos;
   int data_size = end_pos - start_pos;
   DCHECK_GE(data_size, 0);
   int bytes_left = data_size;

   while (bytes_left >= 4) {
     if (data[0] == 0x00 && data[1] == 0x00 && data[2] == 0x03 &&
         data[3] <= 0x03) {
       return (data - buffer) + 2;
     }
     ++data;
     --bytes_left;
   }
   return 0;
 }

 // Remove the byte at |pos| in the |buffer| and close up the gap, moving all the
 // bytes from [pos + 1, end_pos) to [pos, end_pos - 1).
 void RemoveByte(uint8_t* buffer, int pos, int end_pos) {
   memmove(&buffer[pos], &buffer[pos + 1], end_pos - pos - 1);
 }

 // Given an Access Unit pointed to by |au| of size |au_size|, removes emulation
 // prevention 3 bytes (EP3B) from within the |protected_blocks|. Also computes
 // the |subsamples| vector describing the resulting AU.
 // Returns the allocated buffer holding the adjusted copy, or NULL if no size
 // adjustment was necessary.
 std::unique_ptr<uint8_t[]> AdjustAUForSampleAES(
     const uint8_t* au,
     int* au_size,
     const Ranges<int>& protected_blocks,
     std::vector<SubsampleEntry>* subsamples) {
   DCHECK(subsamples);
   DCHECK(au_size);
   std::unique_ptr<uint8_t[]> result;
   int& au_end_pos = *au_size;

   // 1. Considering each protected block in turn, find any emulation prevention
   // 3 bytes (EP3B) within it, keeping track of their positions. While doing so,
   // produce a revised Ranges<int> reflecting the new protected block positions
   // that will apply after we have removed the EP3Bs.
   Ranges<int> adjusted_protected_blocks;
   std::vector<int> epbs;
   int adjustment = 0;
   for (size_t i = 0; i < protected_blocks.size(); i++) {
     int start_pos = protected_blocks.start(i);
     int end_pos = protected_blocks.end(i);
     int search_pos = start_pos;
     int epb_pos;
     int block_adjustment = 0;
     while ((epb_pos = FindEP3B(au, search_pos, end_pos))) {
       epbs.push_back(epb_pos);
       block_adjustment++;
       search_pos = epb_pos + 2;
     }
     // adjust the start_pos and end_pos to accommodate the EPBs that will be
     // removed.
     start_pos -= adjustment;
     adjustment += block_adjustment;
     end_pos -= adjustment;
     if (end_pos - start_pos > kSampleAESMaxUnprotectedNALULength)
       adjusted_protected_blocks.Add(start_pos, end_pos);
     else
       VLOG(1) << "Ignoring short protected block of length: "
               << (end_pos - start_pos);
   }

   // 2. If we actually found any EP3Bs, make a copy of the AU and then remove
   // the EP3Bs in the copy (we can't modify the original).
   if (adjustment) {
     result.reset(new uint8_t[au_end_pos]);
     uint8_t* temp = result.get();
     memcpy(temp, au, au_end_pos);
     for (auto epb_pos = epbs.rbegin(); epb_pos != epbs.rend(); ++epb_pos) {
       RemoveByte(temp, *epb_pos, au_end_pos);
       au_end_pos--;
     }
     au = temp;
     VLOG(2) << "Copied AU and removed emulation prevention bytes: "
             << adjustment;
   }

   // We now have either the original AU, or a copy with the EP3Bs removed.
   // We also have an updated Ranges<int> indicating the protected blocks.
   // Also au_end_pos has been adjusted to indicate the new au_size.

   // 3. Use a new Ranges<int> to collect all the clear ranges. They will
   // automatically be coalesced to minimize the number of (disjoint) ranges.
   Ranges<int> clear_ranges;
   int previous_pos = 0;
   for (size_t i = 0; i < adjusted_protected_blocks.size(); i++) {
     int start_pos = adjusted_protected_blocks.start(i);
     int end_pos = adjusted_protected_blocks.end(i);
     // Add the clear range prior to this protected block.
     clear_ranges.Add(previous_pos, start_pos);
     int block_size = end_pos - start_pos;
     DCHECK_GT(block_size, kSampleAESMaxUnprotectedNALULength);
     // Add the clear leader.
     clear_ranges.Add(start_pos, start_pos + kSampleAESClearLeaderSize);
     block_size -= kSampleAESClearLeaderSize;
     // The bytes beyond an integral multiple of AES blocks (16 bytes) are to be
     // left clear. Also, if the last 16 bytes would be the only block in a
     // pattern unit (160 bytes), they are also left clear.
     int residual_bytes = block_size % kSampleAESPatternUnit;
     if (residual_bytes > 16)
       residual_bytes = residual_bytes % 16;
     clear_ranges.Add(end_pos - residual_bytes, end_pos);
     previous_pos = end_pos;
   }
   // Add the trailing bytes, if any, beyond the last protected block.
   clear_ranges.Add(previous_pos, au_end_pos);

   // 4. Convert the disjoint set of clear ranges into subsample entries. Each
   // subsample entry is a count of clear bytes followed by a count of protected
   // bytes.
   subsamples->clear();
   for (size_t i = 0; i < clear_ranges.size(); i++) {
     int start_pos = clear_ranges.start(i);
     int end_pos = clear_ranges.end(i);
     int clear_size = end_pos - start_pos;
     int encrypt_end_pos = au_end_pos;

     if (i + 1 < clear_ranges.size())
       encrypt_end_pos = clear_ranges.start(i + 1);
     SubsampleEntry subsample(clear_size, encrypt_end_pos - end_pos);
     subsamples->push_back(subsample);
   }
   return result;
 }

 }  // namespace
 #endif  // BUILDFLAG(ENABLE_HLS_SAMPLE_AES)

 // An AUD NALU is at least 4 bytes:
 // 3 bytes for the start code + 1 byte for the NALU type.
 const int kMinAUDSize = 4;

 EsParserH264::EsParserH264(const NewVideoConfigCB& new_video_config_cb,
                            const EmitBufferCB& emit_buffer_cb)
     : es_adapter_(new_video_config_cb, emit_buffer_cb),
       h264_parser_(new H264Parser()),
       current_access_unit_pos_(0),
       next_access_unit_pos_(0)
 #if BUILDFLAG(ENABLE_HLS_SAMPLE_AES)
       ,
       use_hls_sample_aes_(false),
       get_decrypt_config_cb_()
 #endif
 {
 }

 #if BUILDFLAG(ENABLE_HLS_SAMPLE_AES)
 EsParserH264::EsParserH264(const NewVideoConfigCB& new_video_config_cb,
                            const EmitBufferCB& emit_buffer_cb,
                            bool use_hls_sample_aes,
                            const GetDecryptConfigCB& get_decrypt_config_cb)
     : es_adapter_(new_video_config_cb, emit_buffer_cb),
       h264_parser_(new H264Parser()),
       current_access_unit_pos_(0),
       next_access_unit_pos_(0),
       use_hls_sample_aes_(use_hls_sample_aes),
       get_decrypt_config_cb_(get_decrypt_config_cb) {
   DCHECK_EQ(!get_decrypt_config_cb_.is_null(), use_hls_sample_aes_);
 }
 #endif

 EsParserH264::~EsParserH264() {
 }

 void EsParserH264::Flush() {
   DVLOG(1) << __func__;
   if (!FindAUD(&current_access_unit_pos_))
     return;

   // Simulate an additional AUD to force emitting the last access unit
   // which is assumed to be complete at this point.
   uint8_t aud[] = {0x00, 0x00, 0x01, 0x09};
   es_queue_->Push(aud, sizeof(aud));
   ParseFromEsQueue();

   es_adapter_.Flush();
 }

 void EsParserH264::ResetInternal() {
   DVLOG(1) << __func__;
   h264_parser_.reset(new H264Parser());
   current_access_unit_pos_ = 0;
   next_access_unit_pos_ = 0;
   last_video_decoder_config_ = VideoDecoderConfig();
   es_adapter_.Reset();
 }

 bool EsParserH264::FindAUD(int64_t* stream_pos) {
   while (true) {
     const uint8_t* es;
     int size;
     es_queue_->PeekAt(*stream_pos, &es, &size);

     // Find a start code and move the stream to the start code parser position.
     off_t start_code_offset;
     off_t start_code_size;
     bool start_code_found = H264Parser::FindStartCode(
         es, size, &start_code_offset, &start_code_size);
     *stream_pos += start_code_offset;

     // No H264 start code found or NALU type not available yet.
     if (!start_code_found || start_code_offset + start_code_size >= size)
       return false;

     // Exit the parser loop when an AUD is found.
     // Note: NALU header for an AUD:
     // - nal_ref_idc must be 0
     // - nal_unit_type must be H264NALU::kAUD
     if (es[start_code_offset + start_code_size] == H264NALU::kAUD)
       break;

     // The current NALU is not an AUD, skip the start code
     // and continue parsing the stream.
     *stream_pos += start_code_size;
   }

   return true;
 }

 bool EsParserH264::ParseFromEsQueue() {
   DCHECK_LE(es_queue_->head(), current_access_unit_pos_);
   DCHECK_LE(current_access_unit_pos_, next_access_unit_pos_);
   DCHECK_LE(next_access_unit_pos_, es_queue_->tail());

   // Find the next AUD located at or after |current_access_unit_pos_|. This is
   // needed since initially |current_access_unit_pos_| might not point to
   // an AUD.
   // Discard all the data before the updated |current_access_unit_pos_|
   // since it won't be used again.
   bool aud_found = FindAUD(&current_access_unit_pos_);
   es_queue_->Trim(current_access_unit_pos_);
   if (next_access_unit_pos_ < current_access_unit_pos_)
     next_access_unit_pos_ = current_access_unit_pos_;

   // Resume parsing later if no AUD was found.
   if (!aud_found)
     return true;

   // Find the next AUD to make sure we have a complete access unit.
   if (next_access_unit_pos_ < current_access_unit_pos_ + kMinAUDSize) {
     next_access_unit_pos_ = current_access_unit_pos_ + kMinAUDSize;
     DCHECK_LE(next_access_unit_pos_, es_queue_->tail());
   }
   if (!FindAUD(&next_access_unit_pos_))
     return true;

   // At this point, we know we have a full access unit.
   bool is_key_frame = false;
   int pps_id_for_access_unit = -1;

   const uint8_t* es;
   int size;
   es_queue_->PeekAt(current_access_unit_pos_, &es, &size);
   int access_unit_size = base::checked_cast<int>(
       next_access_unit_pos_ - current_access_unit_pos_);
   DCHECK_LE(access_unit_size, size);
   h264_parser_->SetStream(es, access_unit_size);

   while (true) {
     bool is_eos = false;
     H264NALU nalu;
     switch (h264_parser_->AdvanceToNextNALU(&nalu)) {
       case H264Parser::kOk:
         break;
       case H264Parser::kInvalidStream:
       case H264Parser::kUnsupportedStream:
         return false;
       case H264Parser::kEOStream:
         is_eos = true;
         break;
     }
     if (is_eos)
       break;

     switch (nalu.nal_unit_type) {
       case H264NALU::kAUD: {
         DVLOG(LOG_LEVEL_ES) << "NALU: AUD";
         break;
       }
       case H264NALU::kSPS: {
         DVLOG(LOG_LEVEL_ES) << "NALU: SPS";
         int sps_id;
         if (h264_parser_->ParseSPS(&sps_id) != H264Parser::kOk)
           return false;
         break;
       }
       case H264NALU::kPPS: {
         DVLOG(LOG_LEVEL_ES) << "NALU: PPS";
         int pps_id;
         if (h264_parser_->ParsePPS(&pps_id) != H264Parser::kOk)
           return false;
         break;
       }
       case H264NALU::kIDRSlice:
       case H264NALU::kNonIDRSlice: {
         is_key_frame = (nalu.nal_unit_type == H264NALU::kIDRSlice);
         DVLOG(LOG_LEVEL_ES) << "NALU: slice IDR=" << is_key_frame;
         H264SliceHeader shdr;
         if (h264_parser_->ParseSliceHeader(nalu, &shdr) != H264Parser::kOk) {
           // Only accept an invalid SPS/PPS at the beginning when the stream
           // does not necessarily start with an SPS/PPS/IDR.
           // TODO(damienv): Should be able to differentiate a missing SPS/PPS
           // from a slice header parsing error.
           if (last_video_decoder_config_.IsValidConfig())
             return false;
         } else {
           pps_id_for_access_unit = shdr.pic_parameter_set_id;
         }
 #if BUILDFLAG(ENABLE_HLS_SAMPLE_AES)
         // With HLS SampleAES, protected blocks in H.264 consist of IDR and non-
         // IDR slices that are more than 48 bytes in length.
         if (use_hls_sample_aes_ &&
             nalu.size > kSampleAESMaxUnprotectedNALULength) {
           int64_t nal_begin = nalu.data - es;
           protected_blocks_.Add(nal_begin, nal_begin + nalu.size);
         }
 #endif
         break;
       }
       default: {
         DVLOG(LOG_LEVEL_ES) << "NALU: " << nalu.nal_unit_type;
       }
     }
   }

   // Emit a frame and move the stream to the next AUD position.
   RCHECK(EmitFrame(current_access_unit_pos_, access_unit_size,
                    is_key_frame, pps_id_for_access_unit));
   current_access_unit_pos_ = next_access_unit_pos_;
   es_queue_->Trim(current_access_unit_pos_);

   return true;
 }

 bool EsParserH264::EmitFrame(int64_t access_unit_pos,
                              int access_unit_size,
                              bool is_key_frame,
                              int pps_id) {
   // Get the access unit timing info.
   // Note: |current_timing_desc.pts| might be |kNoTimestamp| at this point
   // if:
   // - the stream is not fully MPEG-2 compliant.
   // - or if the stream relies on H264 VUI parameters to compute the timestamps.
   //   See H.222 spec: section 2.7.5 "Conditional coding of timestamps".
   //   This part is not yet implemented in EsParserH264.
   // |es_adapter_| will take care of the missing timestamps.
   TimingDesc current_timing_desc = GetTimingDescriptor(access_unit_pos);
   DVLOG_IF(1, current_timing_desc.pts == kNoTimestamp) << "Missing timestamp";

   // If only the PTS is provided, copy the PTS into the DTS.
   if (current_timing_desc.dts == kNoDecodeTimestamp()) {
     current_timing_desc.dts =
         DecodeTimestamp::FromPresentationTime(current_timing_desc.pts);
   }

   // Update the video decoder configuration if needed.
   const H264PPS* pps = h264_parser_->GetPPS(pps_id);
   if (!pps) {
     // Only accept an invalid PPS at the beginning when the stream
     // does not necessarily start with an SPS/PPS/IDR.
     // In this case, the initial frames are conveyed to the upper layer with
     // an invalid VideoDecoderConfig and it's up to the upper layer
     // to process this kind of frame accordingly.
     if (last_video_decoder_config_.IsValidConfig())
       return false;
   } else {
     const H264SPS* sps = h264_parser_->GetSPS(pps->seq_parameter_set_id);
     if (!sps)
       return false;
     EncryptionScheme scheme = Unencrypted();
 #if BUILDFLAG(ENABLE_HLS_SAMPLE_AES)
     if (use_hls_sample_aes_) {
       // Note that for SampleAES the (encrypt,skip) pattern is constant.
       scheme =
           EncryptionScheme(EncryptionScheme::CIPHER_MODE_AES_CBC,
                            EncryptionScheme::Pattern(kSampleAESEncryptBlocks,
                                                      kSampleAESSkipBlocks));
     }
 #endif
     RCHECK(UpdateVideoDecoderConfig(sps, scheme));
   }

   // Emit a frame.
   DVLOG(LOG_LEVEL_ES) << "Emit frame: stream_pos=" << current_access_unit_pos_
                       << " size=" << access_unit_size;
   int es_size;
   const uint8_t* es;
   es_queue_->PeekAt(current_access_unit_pos_, &es, &es_size);
   CHECK_GE(es_size, access_unit_size);

 #if BUILDFLAG(ENABLE_HLS_SAMPLE_AES)
   std::unique_ptr<uint8_t[]> adjusted_au;
   std::vector<SubsampleEntry> subsamples;
   if (use_hls_sample_aes_) {
     adjusted_au = AdjustAUForSampleAES(es, &access_unit_size, protected_blocks_,
                                        &subsamples);
     protected_blocks_.clear();
     if (adjusted_au)
       es = adjusted_au.get();
   }
 #endif

   // TODO(wolenetz/acolwell): Validate and use a common cross-parser TrackId
   // type and allow multiple video tracks. See https://crbug.com/341581.
   scoped_refptr<StreamParserBuffer> stream_parser_buffer =
       StreamParserBuffer::CopyFrom(es, access_unit_size, is_key_frame,
                                    DemuxerStream::VIDEO, kMp2tVideoTrackId);
   stream_parser_buffer->SetDecodeTimestamp(current_timing_desc.dts);
   stream_parser_buffer->set_timestamp(current_timing_desc.pts);
 #if BUILDFLAG(ENABLE_HLS_SAMPLE_AES)
   if (use_hls_sample_aes_) {
     DCHECK(!get_decrypt_config_cb_.is_null());
     const DecryptConfig* base_decrypt_config = get_decrypt_config_cb_.Run();
     RCHECK(base_decrypt_config);
     std::unique_ptr<DecryptConfig> decrypt_config(new DecryptConfig(
         base_decrypt_config->key_id(), base_decrypt_config->iv(), subsamples));
     stream_parser_buffer->set_decrypt_config(std::move(decrypt_config));
   }
 #endif
   return es_adapter_.OnNewBuffer(stream_parser_buffer);
 }

 bool EsParserH264::UpdateVideoDecoderConfig(const H264SPS* sps,
                                             const EncryptionScheme& scheme) {
   // Set the SAR to 1 when not specified in the H264 stream.
   int sar_width = (sps->sar_width == 0) ? 1 : sps->sar_width;
   int sar_height = (sps->sar_height == 0) ? 1 : sps->sar_height;

   base::Optional<gfx::Size> coded_size = sps->GetCodedSize();
   if (!coded_size)
     return false;

   base::Optional<gfx::Rect> visible_rect = sps->GetVisibleRect();
   if (!visible_rect)
     return false;

   if (visible_rect->width() > std::numeric_limits<int>::max() / sar_width) {
     DVLOG(1) << "Integer overflow detected: visible_rect.width()="
              << visible_rect->width() << " sar_width=" << sar_width;
     return false;
   }
   gfx::Size natural_size((visible_rect->width() * sar_width) / sar_height,
                          visible_rect->height());
   if (natural_size.width() == 0)
     return false;

   VideoDecoderConfig video_decoder_config(
       kCodecH264, H264Parser::ProfileIDCToVideoCodecProfile(sps->profile_idc),
       PIXEL_FORMAT_YV12, COLOR_SPACE_HD_REC709, coded_size.value(),
       visible_rect.value(), natural_size, EmptyExtraData(), scheme);

   if (!video_decoder_config.Matches(last_video_decoder_config_)) {
     DVLOG(1) << "Profile IDC: " << sps->profile_idc;
     DVLOG(1) << "Level IDC: " << sps->level_idc;
     DVLOG(1) << "Pic width: " << coded_size->width();
     DVLOG(1) << "Pic height: " << coded_size->height();
     DVLOG(1) << "log2_max_frame_num_minus4: "
              << sps->log2_max_frame_num_minus4;
     DVLOG(1) << "SAR: width=" << sps->sar_width
              << " height=" << sps->sar_height;
     last_video_decoder_config_ = video_decoder_config;
     es_adapter_.OnConfigChanged(video_decoder_config);
   }

   return true;
 }

 }  // namespace mp2t
 }  // namespace media
	// Copyright 2014 The Chromium Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	#include "media/formats/mp2t/es_parser_h264.h"

	#include <limits>

	#include "base/logging.h"
	#include "base/numerics/safe_conversions.h"
	#include "base/optional.h"
	#include "media/base/decrypt_config.h"
	#include "media/base/encryption_scheme.h"
	#include "media/base/media_util.h"
	#include "media/base/stream_parser_buffer.h"
	#include "media/base/timestamp_constants.h"
	#include "media/base/video_frame.h"
	#include "media/filters/h264_parser.h"
	#include "media/formats/common/offset_byte_queue.h"
	#include "media/formats/mp2t/mp2t_common.h"
	#include "ui/gfx/geometry/rect.h"
	#include "ui/gfx/geometry/size.h"

	namespace media {
	namespace mp2t {

	#if BUILDFLAG(ENABLE_HLS_SAMPLE_AES)
	namespace {

	const int kSampleAESMaxUnprotectedNALULength = 48;
	const int kSampleAESClearLeaderSize = 32;
	const int kSampleAESEncryptBlocks = 1;
	const int kSampleAESSkipBlocks = 9;
	const int kSampleAESPatternUnit =
	(kSampleAESEncryptBlocks + kSampleAESSkipBlocks) * 16;

	// Attempts to find the first or only EP3B (emulation prevention 3 byte) in
	// the part of the \|buffer\| between \|start_pos\| and \|end_pos\|. Returns the
	// position of the EP3B, or 0 if there are none.
	// Note: the EP3B always follows two zero bytes, so the value 0 can never be a
	// valid position.
	int FindEP3B(const uint8_t* buffer, int start_pos, int end_pos) {
	const uint8_t* data = buffer + start_pos;
	int data_size = end_pos - start_pos;
	DCHECK_GE(data_size, 0);
	int bytes_left = data_size;

	while (bytes_left >= 4) {
	if (data[0] == 0x00 && data[1] == 0x00 && data[2] == 0x03 &&
	data[3] <= 0x03) {
	return (data - buffer) + 2;
	}
	++data;
	--bytes_left;
	}
	return 0;
	}

	// Remove the byte at \|pos\| in the \|buffer\| and close up the gap, moving all the
	// bytes from [pos + 1, end_pos) to [pos, end_pos - 1).
	void RemoveByte(uint8_t* buffer, int pos, int end_pos) {
	memmove(&buffer[pos], &buffer[pos + 1], end_pos - pos - 1);
	}

	// Given an Access Unit pointed to by \|au\| of size \|au_size\|, removes emulation
	// prevention 3 bytes (EP3B) from within the \|protected_blocks\|. Also computes
	// the \|subsamples\| vector describing the resulting AU.
	// Returns the allocated buffer holding the adjusted copy, or NULL if no size
	// adjustment was necessary.
	std::unique_ptr<uint8_t[]> AdjustAUForSampleAES(
	const uint8_t* au,
	int* au_size,
	const Ranges<int>& protected_blocks,
	std::vector<SubsampleEntry>* subsamples) {
	DCHECK(subsamples);
	DCHECK(au_size);
	std::unique_ptr<uint8_t[]> result;
	int& au_end_pos = *au_size;

	// 1. Considering each protected block in turn, find any emulation prevention
	// 3 bytes (EP3B) within it, keeping track of their positions. While doing so,
	// produce a revised Ranges<int> reflecting the new protected block positions
	// that will apply after we have removed the EP3Bs.
	Ranges<int> adjusted_protected_blocks;
	std::vector<int> epbs;
	int adjustment = 0;
	for (size_t i = 0; i < protected_blocks.size(); i++) {
	int start_pos = protected_blocks.start(i);
	int end_pos = protected_blocks.end(i);
	int search_pos = start_pos;
	int epb_pos;
	int block_adjustment = 0;
	while ((epb_pos = FindEP3B(au, search_pos, end_pos))) {
	epbs.push_back(epb_pos);
	block_adjustment++;
	search_pos = epb_pos + 2;
	}
	// adjust the start_pos and end_pos to accommodate the EPBs that will be
	// removed.
	start_pos -= adjustment;
	adjustment += block_adjustment;
	end_pos -= adjustment;
	if (end_pos - start_pos > kSampleAESMaxUnprotectedNALULength)
	adjusted_protected_blocks.Add(start_pos, end_pos);
	else
	VLOG(1) << "Ignoring short protected block of length: "
	<< (end_pos - start_pos);
	}

	// 2. If we actually found any EP3Bs, make a copy of the AU and then remove
	// the EP3Bs in the copy (we can't modify the original).
	if (adjustment) {
	result.reset(new uint8_t[au_end_pos]);
	uint8_t* temp = result.get();
	memcpy(temp, au, au_end_pos);
	for (auto epb_pos = epbs.rbegin(); epb_pos != epbs.rend(); ++epb_pos) {
	RemoveByte(temp, *epb_pos, au_end_pos);
	au_end_pos--;
	}
	au = temp;
	VLOG(2) << "Copied AU and removed emulation prevention bytes: "
	<< adjustment;
	}

	// We now have either the original AU, or a copy with the EP3Bs removed.
	// We also have an updated Ranges<int> indicating the protected blocks.
	// Also au_end_pos has been adjusted to indicate the new au_size.

	// 3. Use a new Ranges<int> to collect all the clear ranges. They will
	// automatically be coalesced to minimize the number of (disjoint) ranges.
	Ranges<int> clear_ranges;
	int previous_pos = 0;
	for (size_t i = 0; i < adjusted_protected_blocks.size(); i++) {
	int start_pos = adjusted_protected_blocks.start(i);
	int end_pos = adjusted_protected_blocks.end(i);
	// Add the clear range prior to this protected block.
	clear_ranges.Add(previous_pos, start_pos);
	int block_size = end_pos - start_pos;
	DCHECK_GT(block_size, kSampleAESMaxUnprotectedNALULength);
	// Add the clear leader.
	clear_ranges.Add(start_pos, start_pos + kSampleAESClearLeaderSize);
	block_size -= kSampleAESClearLeaderSize;
	// The bytes beyond an integral multiple of AES blocks (16 bytes) are to be
	// left clear. Also, if the last 16 bytes would be the only block in a
	// pattern unit (160 bytes), they are also left clear.
	int residual_bytes = block_size % kSampleAESPatternUnit;
	if (residual_bytes > 16)
	residual_bytes = residual_bytes % 16;
	clear_ranges.Add(end_pos - residual_bytes, end_pos);
	previous_pos = end_pos;
	}
	// Add the trailing bytes, if any, beyond the last protected block.
	clear_ranges.Add(previous_pos, au_end_pos);

	// 4. Convert the disjoint set of clear ranges into subsample entries. Each
	// subsample entry is a count of clear bytes followed by a count of protected
	// bytes.
	subsamples->clear();
	for (size_t i = 0; i < clear_ranges.size(); i++) {
	int start_pos = clear_ranges.start(i);
	int end_pos = clear_ranges.end(i);
	int clear_size = end_pos - start_pos;
	int encrypt_end_pos = au_end_pos;

	if (i + 1 < clear_ranges.size())
	encrypt_end_pos = clear_ranges.start(i + 1);
	SubsampleEntry subsample(clear_size, encrypt_end_pos - end_pos);
	subsamples->push_back(subsample);
	}
	return result;
	}

	} // namespace
	#endif // BUILDFLAG(ENABLE_HLS_SAMPLE_AES)

	// An AUD NALU is at least 4 bytes:
	// 3 bytes for the start code + 1 byte for the NALU type.
	const int kMinAUDSize = 4;

	EsParserH264::EsParserH264(const NewVideoConfigCB& new_video_config_cb,
	const EmitBufferCB& emit_buffer_cb)
	: es_adapter_(new_video_config_cb, emit_buffer_cb),
	h264_parser_(new H264Parser()),
	current_access_unit_pos_(0),
	next_access_unit_pos_(0)
	#if BUILDFLAG(ENABLE_HLS_SAMPLE_AES)
	,
	use_hls_sample_aes_(false),
	get_decrypt_config_cb_()
	#endif
	{
	}

	#if BUILDFLAG(ENABLE_HLS_SAMPLE_AES)
	EsParserH264::EsParserH264(const NewVideoConfigCB& new_video_config_cb,
	const EmitBufferCB& emit_buffer_cb,
	bool use_hls_sample_aes,
	const GetDecryptConfigCB& get_decrypt_config_cb)
	: es_adapter_(new_video_config_cb, emit_buffer_cb),
	h264_parser_(new H264Parser()),
	current_access_unit_pos_(0),
	next_access_unit_pos_(0),
	use_hls_sample_aes_(use_hls_sample_aes),
	get_decrypt_config_cb_(get_decrypt_config_cb) {
	DCHECK_EQ(!get_decrypt_config_cb_.is_null(), use_hls_sample_aes_);
	}
	#endif

	EsParserH264::~EsParserH264() {
	}

	void EsParserH264::Flush() {
	DVLOG(1) << __func__;
	if (!FindAUD(&current_access_unit_pos_))
	return;

	// Simulate an additional AUD to force emitting the last access unit
	// which is assumed to be complete at this point.
	uint8_t aud[] = {0x00, 0x00, 0x01, 0x09};
	es_queue_->Push(aud, sizeof(aud));
	ParseFromEsQueue();

	es_adapter_.Flush();
	}

	void EsParserH264::ResetInternal() {
	DVLOG(1) << __func__;
	h264_parser_.reset(new H264Parser());
	current_access_unit_pos_ = 0;
	next_access_unit_pos_ = 0;
	last_video_decoder_config_ = VideoDecoderConfig();
	es_adapter_.Reset();
	}

	bool EsParserH264::FindAUD(int64_t* stream_pos) {
	while (true) {
	const uint8_t* es;
	int size;
	es_queue_->PeekAt(*stream_pos, &es, &size);

	// Find a start code and move the stream to the start code parser position.
	off_t start_code_offset;
	off_t start_code_size;
	bool start_code_found = H264Parser::FindStartCode(
	es, size, &start_code_offset, &start_code_size);
	*stream_pos += start_code_offset;

	// No H264 start code found or NALU type not available yet.
	if (!start_code_found \|\| start_code_offset + start_code_size >= size)
	return false;

	// Exit the parser loop when an AUD is found.
	// Note: NALU header for an AUD:
	// - nal_ref_idc must be 0
	// - nal_unit_type must be H264NALU::kAUD
	if (es[start_code_offset + start_code_size] == H264NALU::kAUD)
	break;

	// The current NALU is not an AUD, skip the start code
	// and continue parsing the stream.
	*stream_pos += start_code_size;
	}

	return true;
	}

	bool EsParserH264::ParseFromEsQueue() {
	DCHECK_LE(es_queue_->head(), current_access_unit_pos_);
	DCHECK_LE(current_access_unit_pos_, next_access_unit_pos_);
	DCHECK_LE(next_access_unit_pos_, es_queue_->tail());

	// Find the next AUD located at or after \|current_access_unit_pos_\|. This is
	// needed since initially \|current_access_unit_pos_\| might not point to
	// an AUD.
	// Discard all the data before the updated \|current_access_unit_pos_\|
	// since it won't be used again.
	bool aud_found = FindAUD(&current_access_unit_pos_);
	es_queue_->Trim(current_access_unit_pos_);
	if (next_access_unit_pos_ < current_access_unit_pos_)
	next_access_unit_pos_ = current_access_unit_pos_;

	// Resume parsing later if no AUD was found.
	if (!aud_found)
	return true;

	// Find the next AUD to make sure we have a complete access unit.
	if (next_access_unit_pos_ < current_access_unit_pos_ + kMinAUDSize) {
	next_access_unit_pos_ = current_access_unit_pos_ + kMinAUDSize;
	DCHECK_LE(next_access_unit_pos_, es_queue_->tail());
	}
	if (!FindAUD(&next_access_unit_pos_))
	return true;

	// At this point, we know we have a full access unit.
	bool is_key_frame = false;
	int pps_id_for_access_unit = -1;

	const uint8_t* es;
	int size;
	es_queue_->PeekAt(current_access_unit_pos_, &es, &size);
	int access_unit_size = base::checked_cast<int>(
	next_access_unit_pos_ - current_access_unit_pos_);
	DCHECK_LE(access_unit_size, size);
	h264_parser_->SetStream(es, access_unit_size);

	while (true) {
	bool is_eos = false;
	H264NALU nalu;
	switch (h264_parser_->AdvanceToNextNALU(&nalu)) {
	case H264Parser::kOk:
	break;
	case H264Parser::kInvalidStream:
	case H264Parser::kUnsupportedStream:
	return false;
	case H264Parser::kEOStream:
	is_eos = true;
	break;
	}
	if (is_eos)
	break;

	switch (nalu.nal_unit_type) {
	case H264NALU::kAUD: {
	DVLOG(LOG_LEVEL_ES) << "NALU: AUD";
	break;
	}
	case H264NALU::kSPS: {
	DVLOG(LOG_LEVEL_ES) << "NALU: SPS";
	int sps_id;
	if (h264_parser_->ParseSPS(&sps_id) != H264Parser::kOk)
	return false;
	break;
	}
	case H264NALU::kPPS: {
	DVLOG(LOG_LEVEL_ES) << "NALU: PPS";
	int pps_id;
	if (h264_parser_->ParsePPS(&pps_id) != H264Parser::kOk)
	return false;
	break;
	}
	case H264NALU::kIDRSlice:
	case H264NALU::kNonIDRSlice: {
	is_key_frame = (nalu.nal_unit_type == H264NALU::kIDRSlice);
	DVLOG(LOG_LEVEL_ES) << "NALU: slice IDR=" << is_key_frame;
	H264SliceHeader shdr;
	if (h264_parser_->ParseSliceHeader(nalu, &shdr) != H264Parser::kOk) {
	// Only accept an invalid SPS/PPS at the beginning when the stream
	// does not necessarily start with an SPS/PPS/IDR.
	// TODO(damienv): Should be able to differentiate a missing SPS/PPS
	// from a slice header parsing error.
	if (last_video_decoder_config_.IsValidConfig())
	return false;
	} else {
	pps_id_for_access_unit = shdr.pic_parameter_set_id;
	}
	#if BUILDFLAG(ENABLE_HLS_SAMPLE_AES)
	// With HLS SampleAES, protected blocks in H.264 consist of IDR and non-
	// IDR slices that are more than 48 bytes in length.
	if (use_hls_sample_aes_ &&
	nalu.size > kSampleAESMaxUnprotectedNALULength) {
	int64_t nal_begin = nalu.data - es;
	protected_blocks_.Add(nal_begin, nal_begin + nalu.size);
	}
	#endif
	break;
	}
	default: {
	DVLOG(LOG_LEVEL_ES) << "NALU: " << nalu.nal_unit_type;
	}
	}
	}

	// Emit a frame and move the stream to the next AUD position.
	RCHECK(EmitFrame(current_access_unit_pos_, access_unit_size,
	is_key_frame, pps_id_for_access_unit));
	current_access_unit_pos_ = next_access_unit_pos_;
	es_queue_->Trim(current_access_unit_pos_);

	return true;
	}

	bool EsParserH264::EmitFrame(int64_t access_unit_pos,
	int access_unit_size,
	bool is_key_frame,
	int pps_id) {
	// Get the access unit timing info.
	// Note: \|current_timing_desc.pts\| might be \|kNoTimestamp\| at this point
	// if:
	// - the stream is not fully MPEG-2 compliant.
	// - or if the stream relies on H264 VUI parameters to compute the timestamps.
	// See H.222 spec: section 2.7.5 "Conditional coding of timestamps".
	// This part is not yet implemented in EsParserH264.
	// \|es_adapter_\| will take care of the missing timestamps.
	TimingDesc current_timing_desc = GetTimingDescriptor(access_unit_pos);
	DVLOG_IF(1, current_timing_desc.pts == kNoTimestamp) << "Missing timestamp";

	// If only the PTS is provided, copy the PTS into the DTS.
	if (current_timing_desc.dts == kNoDecodeTimestamp()) {
	current_timing_desc.dts =
	DecodeTimestamp::FromPresentationTime(current_timing_desc.pts);
	}

	// Update the video decoder configuration if needed.
	const H264PPS* pps = h264_parser_->GetPPS(pps_id);
	if (!pps) {
	// Only accept an invalid PPS at the beginning when the stream
	// does not necessarily start with an SPS/PPS/IDR.
	// In this case, the initial frames are conveyed to the upper layer with
	// an invalid VideoDecoderConfig and it's up to the upper layer
	// to process this kind of frame accordingly.
	if (last_video_decoder_config_.IsValidConfig())
	return false;
	} else {
	const H264SPS* sps = h264_parser_->GetSPS(pps->seq_parameter_set_id);
	if (!sps)
	return false;
	EncryptionScheme scheme = Unencrypted();
	#if BUILDFLAG(ENABLE_HLS_SAMPLE_AES)
	if (use_hls_sample_aes_) {
	// Note that for SampleAES the (encrypt,skip) pattern is constant.
	scheme =
	EncryptionScheme(EncryptionScheme::CIPHER_MODE_AES_CBC,
	EncryptionScheme::Pattern(kSampleAESEncryptBlocks,
	kSampleAESSkipBlocks));
	}
	#endif
	RCHECK(UpdateVideoDecoderConfig(sps, scheme));
	}

	// Emit a frame.
	DVLOG(LOG_LEVEL_ES) << "Emit frame: stream_pos=" << current_access_unit_pos_
	<< " size=" << access_unit_size;
	int es_size;
	const uint8_t* es;
	es_queue_->PeekAt(current_access_unit_pos_, &es, &es_size);
	CHECK_GE(es_size, access_unit_size);

	#if BUILDFLAG(ENABLE_HLS_SAMPLE_AES)
	std::unique_ptr<uint8_t[]> adjusted_au;
	std::vector<SubsampleEntry> subsamples;
	if (use_hls_sample_aes_) {
	adjusted_au = AdjustAUForSampleAES(es, &access_unit_size, protected_blocks_,
	&subsamples);
	protected_blocks_.clear();
	if (adjusted_au)
	es = adjusted_au.get();
	}
	#endif

	// TODO(wolenetz/acolwell): Validate and use a common cross-parser TrackId
	// type and allow multiple video tracks. See https://crbug.com/341581.
	scoped_refptr<StreamParserBuffer> stream_parser_buffer =
	StreamParserBuffer::CopyFrom(es, access_unit_size, is_key_frame,
	DemuxerStream::VIDEO, kMp2tVideoTrackId);
	stream_parser_buffer->SetDecodeTimestamp(current_timing_desc.dts);
	stream_parser_buffer->set_timestamp(current_timing_desc.pts);
	#if BUILDFLAG(ENABLE_HLS_SAMPLE_AES)
	if (use_hls_sample_aes_) {
	DCHECK(!get_decrypt_config_cb_.is_null());
	const DecryptConfig* base_decrypt_config = get_decrypt_config_cb_.Run();
	RCHECK(base_decrypt_config);
	std::unique_ptr<DecryptConfig> decrypt_config(new DecryptConfig(
	base_decrypt_config->key_id(), base_decrypt_config->iv(), subsamples));
	stream_parser_buffer->set_decrypt_config(std::move(decrypt_config));
	}
	#endif
	return es_adapter_.OnNewBuffer(stream_parser_buffer);
	}

	bool EsParserH264::UpdateVideoDecoderConfig(const H264SPS* sps,
	const EncryptionScheme& scheme) {
	// Set the SAR to 1 when not specified in the H264 stream.
	int sar_width = (sps->sar_width == 0) ? 1 : sps->sar_width;
	int sar_height = (sps->sar_height == 0) ? 1 : sps->sar_height;

	base::Optional<gfx::Size> coded_size = sps->GetCodedSize();
	if (!coded_size)
	return false;

	base::Optional<gfx::Rect> visible_rect = sps->GetVisibleRect();
	if (!visible_rect)
	return false;

	if (visible_rect->width() > std::numeric_limits<int>::max() / sar_width) {
	DVLOG(1) << "Integer overflow detected: visible_rect.width()="
	<< visible_rect->width() << " sar_width=" << sar_width;
	return false;
	}
	gfx::Size natural_size((visible_rect->width() * sar_width) / sar_height,
	visible_rect->height());
	if (natural_size.width() == 0)
	return false;

	VideoDecoderConfig video_decoder_config(
	kCodecH264, H264Parser::ProfileIDCToVideoCodecProfile(sps->profile_idc),
	PIXEL_FORMAT_YV12, COLOR_SPACE_HD_REC709, coded_size.value(),
	visible_rect.value(), natural_size, EmptyExtraData(), scheme);

	if (!video_decoder_config.Matches(last_video_decoder_config_)) {
	DVLOG(1) << "Profile IDC: " << sps->profile_idc;
	DVLOG(1) << "Level IDC: " << sps->level_idc;
	DVLOG(1) << "Pic width: " << coded_size->width();
	DVLOG(1) << "Pic height: " << coded_size->height();
	DVLOG(1) << "log2_max_frame_num_minus4: "
	<< sps->log2_max_frame_num_minus4;
	DVLOG(1) << "SAR: width=" << sps->sar_width
	<< " height=" << sps->sar_height;
	last_video_decoder_config_ = video_decoder_config;
	es_adapter_.OnConfigChanged(video_decoder_config);
	}

	return true;
	}

	} // namespace mp2t
	} // namespace media