third_party/chromium/media/video/h265_nalu_parser.cc - cobalt - Git at Google

 // Copyright 2021 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/video/h265_nalu_parser.h"

 #include <stddef.h>

 #include <algorithm>
 #include <cmath>

 #include "base/bits.h"
 #include "base/cxx17_backports.h"
 #include "base/logging.h"
 #include "media/base/decrypt_config.h"

 namespace media {

 namespace {

 // Converts [|start|, |end|) range with |encrypted_ranges| into a vector of
 // SubsampleEntry. |encrypted_ranges| must be with in the range defined by
 // |start| and |end|.
 // It is OK to pass in empty |encrypted_ranges|; this will return a vector
 // with single SubsampleEntry with clear_bytes set to the size of the buffer.
 std::vector<SubsampleEntry> EncryptedRangesToSubsampleEntry(
     const uint8_t* start,
     const uint8_t* end,
     const Ranges<const uint8_t*>& encrypted_ranges) {
   std::vector<SubsampleEntry> subsamples(encrypted_ranges.size());
   const uint8_t* cur = start;
   for (size_t i = 0; i < encrypted_ranges.size(); ++i) {
     const uint8_t* encrypted_start = encrypted_ranges.start(i);
     DCHECK_GE(encrypted_start, cur)
         << "Encrypted range started before the current buffer pointer.";
     subsamples[i].clear_bytes = encrypted_start - cur;

     const uint8_t* encrypted_end = encrypted_ranges.end(i);
     subsamples[i].cypher_bytes = encrypted_end - encrypted_start;

     cur = encrypted_end;
     DCHECK_LE(cur, end) << "Encrypted range is outside the buffer range.";
   }

   // If there is more data in the buffer but not covered by encrypted_ranges,
   // then it must be in the clear.
   if (cur < end)
     subsamples.emplace_back(end - cur, 0);

   return subsamples;
 }

 }  // namespace

 #define READ_BITS_OR_RETURN(num_bits, out)                                 \
   do {                                                                     \
     int _out;                                                              \
     if (!br_.ReadBits(num_bits, &_out)) {                                  \
       DVLOG(1)                                                             \
           << "Error in stream: unexpected EOS while trying to read " #out; \
       return kInvalidStream;                                               \
     }                                                                      \
     *out = _out;                                                           \
   } while (0)

 #define TRUE_OR_RETURN(a)                                            \
   do {                                                               \
     if (!(a)) {                                                      \
       DVLOG(1) << "Error in stream: invalid value, expected " << #a; \
       return kInvalidStream;                                         \
     }                                                                \
   } while (0)

 H265NALU::H265NALU() {
   memset(reinterpret_cast<void*>(this), 0, sizeof(*this));
 }

 H265NaluParser::H265NaluParser() {
   Reset();
 }

 H265NaluParser::~H265NaluParser() {}

 void H265NaluParser::Reset() {
   stream_ = NULL;
   bytes_left_ = 0;
   encrypted_ranges_.clear();
   previous_nalu_range_.clear();
 }

 void H265NaluParser::SetStream(const uint8_t* stream, off_t stream_size) {
   std::vector<SubsampleEntry> subsamples;
   SetEncryptedStream(stream, stream_size, subsamples);
 }

 void H265NaluParser::SetEncryptedStream(
     const uint8_t* stream,
     off_t stream_size,
     const std::vector<SubsampleEntry>& subsamples) {
   DCHECK(stream);
   DCHECK_GT(stream_size, 0);

   stream_ = stream;
   bytes_left_ = stream_size;
   previous_nalu_range_.clear();

   encrypted_ranges_.clear();
   const uint8_t* start = stream;
   const uint8_t* stream_end = stream_ + bytes_left_;
   for (size_t i = 0; i < subsamples.size() && start < stream_end; ++i) {
     start += subsamples[i].clear_bytes;

     const uint8_t* end =
         std::min(start + subsamples[i].cypher_bytes, stream_end);
     encrypted_ranges_.Add(start, end);
     start = end;
   }
 }

 bool H265NaluParser::LocateNALU(off_t* nalu_size, off_t* start_code_size) {
   // Find the start code of next NALU.
   off_t nalu_start_off = 0;
   off_t annexb_start_code_size = 0;

   if (!H264Parser::FindStartCodeInClearRanges(
           stream_, bytes_left_, encrypted_ranges_, &nalu_start_off,
           &annexb_start_code_size)) {
     DVLOG(4) << "Could not find start code, end of stream?";
     return false;
   }

   // Move the stream to the beginning of the NALU (pointing at the start code).
   stream_ += nalu_start_off;
   bytes_left_ -= nalu_start_off;

   const uint8_t* nalu_data = stream_ + annexb_start_code_size;
   off_t max_nalu_data_size = bytes_left_ - annexb_start_code_size;
   if (max_nalu_data_size <= 0) {
     DVLOG(3) << "End of stream";
     return false;
   }

   // Find the start code of next NALU;
   // if successful, |nalu_size_without_start_code| is the number of bytes from
   // after previous start code to before this one;
   // if next start code is not found, it is still a valid NALU since there
   // are some bytes left after the first start code: all the remaining bytes
   // belong to the current NALU.
   off_t next_start_code_size = 0;
   off_t nalu_size_without_start_code = 0;
   if (!H264Parser::FindStartCodeInClearRanges(
           nalu_data, max_nalu_data_size, encrypted_ranges_,
           &nalu_size_without_start_code, &next_start_code_size)) {
     nalu_size_without_start_code = max_nalu_data_size;
   }
   *nalu_size = nalu_size_without_start_code + annexb_start_code_size;
   *start_code_size = annexb_start_code_size;
   return true;
 }

 H265NaluParser::Result H265NaluParser::AdvanceToNextNALU(H265NALU* nalu) {
   off_t start_code_size;
   off_t nalu_size_with_start_code;
   if (!LocateNALU(&nalu_size_with_start_code, &start_code_size)) {
     DVLOG(4) << "Could not find next NALU, bytes left in stream: "
              << bytes_left_;
     return kEOStream;
   }

   DCHECK(nalu);
   nalu->data = stream_ + start_code_size;
   nalu->size = nalu_size_with_start_code - start_code_size;
   DVLOG(4) << "NALU found: size=" << nalu_size_with_start_code;

   // Initialize bit reader at the start of found NALU.
   if (!br_.Initialize(nalu->data, nalu->size))
     return kEOStream;

   // Move parser state to after this NALU, so next time AdvanceToNextNALU
   // is called, we will effectively be skipping it;
   // other parsing functions will use the position saved
   // in bit reader for parsing, so we don't have to remember it here.
   stream_ += nalu_size_with_start_code;
   bytes_left_ -= nalu_size_with_start_code;

   // Read NALU header, skip the forbidden_zero_bit, but check for it.
   int data;
   READ_BITS_OR_RETURN(1, &data);
   TRUE_OR_RETURN(data == 0);

   READ_BITS_OR_RETURN(6, &nalu->nal_unit_type);
   READ_BITS_OR_RETURN(6, &nalu->nuh_layer_id);
   READ_BITS_OR_RETURN(3, &nalu->nuh_temporal_id_plus1);

   DVLOG(4) << "NALU type: " << static_cast<int>(nalu->nal_unit_type)
            << " at: " << reinterpret_cast<const void*>(nalu->data)
            << " size: " << nalu->size;

   previous_nalu_range_.clear();
   previous_nalu_range_.Add(nalu->data, nalu->data + nalu->size);
   return kOk;
 }

 std::vector<SubsampleEntry> H265NaluParser::GetCurrentSubsamples() {
   DCHECK_EQ(previous_nalu_range_.size(), 1u)
       << "This should only be called after a "
          "successful call to AdvanceToNextNalu()";

   auto intersection = encrypted_ranges_.IntersectionWith(previous_nalu_range_);
   return EncryptedRangesToSubsampleEntry(
       previous_nalu_range_.start(0), previous_nalu_range_.end(0), intersection);
 }

 }  // namespace media
	// Copyright 2021 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/video/h265_nalu_parser.h"

	#include <stddef.h>

	#include <algorithm>
	#include <cmath>

	#include "base/bits.h"
	#include "base/cxx17_backports.h"
	#include "base/logging.h"
	#include "media/base/decrypt_config.h"

	namespace media {

	namespace {

	// Converts [\|start\|, \|end\|) range with \|encrypted_ranges\| into a vector of
	// SubsampleEntry. \|encrypted_ranges\| must be with in the range defined by
	// \|start\| and \|end\|.
	// It is OK to pass in empty \|encrypted_ranges\|; this will return a vector
	// with single SubsampleEntry with clear_bytes set to the size of the buffer.
	std::vector<SubsampleEntry> EncryptedRangesToSubsampleEntry(
	const uint8_t* start,
	const uint8_t* end,
	const Ranges<const uint8_t*>& encrypted_ranges) {
	std::vector<SubsampleEntry> subsamples(encrypted_ranges.size());
	const uint8_t* cur = start;
	for (size_t i = 0; i < encrypted_ranges.size(); ++i) {
	const uint8_t* encrypted_start = encrypted_ranges.start(i);
	DCHECK_GE(encrypted_start, cur)
	<< "Encrypted range started before the current buffer pointer.";
	subsamples[i].clear_bytes = encrypted_start - cur;

	const uint8_t* encrypted_end = encrypted_ranges.end(i);
	subsamples[i].cypher_bytes = encrypted_end - encrypted_start;

	cur = encrypted_end;
	DCHECK_LE(cur, end) << "Encrypted range is outside the buffer range.";
	}

	// If there is more data in the buffer but not covered by encrypted_ranges,
	// then it must be in the clear.
	if (cur < end)
	subsamples.emplace_back(end - cur, 0);

	return subsamples;
	}

	} // namespace

	#define READ_BITS_OR_RETURN(num_bits, out) \
	do { \
	int _out; \
	if (!br_.ReadBits(num_bits, &_out)) { \
	DVLOG(1) \
	<< "Error in stream: unexpected EOS while trying to read " #out; \
	return kInvalidStream; \
	} \
	*out = _out; \
	} while (0)

	#define TRUE_OR_RETURN(a) \
	do { \
	if (!(a)) { \
	DVLOG(1) << "Error in stream: invalid value, expected " << #a; \
	return kInvalidStream; \
	} \
	} while (0)

	H265NALU::H265NALU() {
	memset(reinterpret_cast<void>(this), 0, sizeof(this));
	}

	H265NaluParser::H265NaluParser() {
	Reset();
	}

	H265NaluParser::~H265NaluParser() {}

	void H265NaluParser::Reset() {
	stream_ = NULL;
	bytes_left_ = 0;
	encrypted_ranges_.clear();
	previous_nalu_range_.clear();
	}

	void H265NaluParser::SetStream(const uint8_t* stream, off_t stream_size) {
	std::vector<SubsampleEntry> subsamples;
	SetEncryptedStream(stream, stream_size, subsamples);
	}

	void H265NaluParser::SetEncryptedStream(
	const uint8_t* stream,
	off_t stream_size,
	const std::vector<SubsampleEntry>& subsamples) {
	DCHECK(stream);
	DCHECK_GT(stream_size, 0);

	stream_ = stream;
	bytes_left_ = stream_size;
	previous_nalu_range_.clear();

	encrypted_ranges_.clear();
	const uint8_t* start = stream;
	const uint8_t* stream_end = stream_ + bytes_left_;
	for (size_t i = 0; i < subsamples.size() && start < stream_end; ++i) {
	start += subsamples[i].clear_bytes;

	const uint8_t* end =
	std::min(start + subsamples[i].cypher_bytes, stream_end);
	encrypted_ranges_.Add(start, end);
	start = end;
	}
	}

	bool H265NaluParser::LocateNALU(off_t* nalu_size, off_t* start_code_size) {
	// Find the start code of next NALU.
	off_t nalu_start_off = 0;
	off_t annexb_start_code_size = 0;

	if (!H264Parser::FindStartCodeInClearRanges(
	stream_, bytes_left_, encrypted_ranges_, &nalu_start_off,
	&annexb_start_code_size)) {
	DVLOG(4) << "Could not find start code, end of stream?";
	return false;
	}

	// Move the stream to the beginning of the NALU (pointing at the start code).
	stream_ += nalu_start_off;
	bytes_left_ -= nalu_start_off;

	const uint8_t* nalu_data = stream_ + annexb_start_code_size;
	off_t max_nalu_data_size = bytes_left_ - annexb_start_code_size;
	if (max_nalu_data_size <= 0) {
	DVLOG(3) << "End of stream";
	return false;
	}

	// Find the start code of next NALU;
	// if successful, \|nalu_size_without_start_code\| is the number of bytes from
	// after previous start code to before this one;
	// if next start code is not found, it is still a valid NALU since there
	// are some bytes left after the first start code: all the remaining bytes
	// belong to the current NALU.
	off_t next_start_code_size = 0;
	off_t nalu_size_without_start_code = 0;
	if (!H264Parser::FindStartCodeInClearRanges(
	nalu_data, max_nalu_data_size, encrypted_ranges_,
	&nalu_size_without_start_code, &next_start_code_size)) {
	nalu_size_without_start_code = max_nalu_data_size;
	}
	*nalu_size = nalu_size_without_start_code + annexb_start_code_size;
	*start_code_size = annexb_start_code_size;
	return true;
	}

	H265NaluParser::Result H265NaluParser::AdvanceToNextNALU(H265NALU* nalu) {
	off_t start_code_size;
	off_t nalu_size_with_start_code;
	if (!LocateNALU(&nalu_size_with_start_code, &start_code_size)) {
	DVLOG(4) << "Could not find next NALU, bytes left in stream: "
	<< bytes_left_;
	return kEOStream;
	}

	DCHECK(nalu);
	nalu->data = stream_ + start_code_size;
	nalu->size = nalu_size_with_start_code - start_code_size;
	DVLOG(4) << "NALU found: size=" << nalu_size_with_start_code;

	// Initialize bit reader at the start of found NALU.
	if (!br_.Initialize(nalu->data, nalu->size))
	return kEOStream;

	// Move parser state to after this NALU, so next time AdvanceToNextNALU
	// is called, we will effectively be skipping it;
	// other parsing functions will use the position saved
	// in bit reader for parsing, so we don't have to remember it here.
	stream_ += nalu_size_with_start_code;
	bytes_left_ -= nalu_size_with_start_code;

	// Read NALU header, skip the forbidden_zero_bit, but check for it.
	int data;
	READ_BITS_OR_RETURN(1, &data);
	TRUE_OR_RETURN(data == 0);

	READ_BITS_OR_RETURN(6, &nalu->nal_unit_type);
	READ_BITS_OR_RETURN(6, &nalu->nuh_layer_id);
	READ_BITS_OR_RETURN(3, &nalu->nuh_temporal_id_plus1);

	DVLOG(4) << "NALU type: " << static_cast<int>(nalu->nal_unit_type)
	<< " at: " << reinterpret_cast<const void*>(nalu->data)
	<< " size: " << nalu->size;

	previous_nalu_range_.clear();
	previous_nalu_range_.Add(nalu->data, nalu->data + nalu->size);
	return kOk;
	}

	std::vector<SubsampleEntry> H265NaluParser::GetCurrentSubsamples() {
	DCHECK_EQ(previous_nalu_range_.size(), 1u)
	<< "This should only be called after a "
	"successful call to AdvanceToNextNalu()";

	auto intersection = encrypted_ranges_.IntersectionWith(previous_nalu_range_);
	return EncryptedRangesToSubsampleEntry(
	previous_nalu_range_.start(0), previous_nalu_range_.end(0), intersection);
	}

	} // namespace media