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

 // Copyright 2015 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/ts_section_cets_ecm.h"

 #include "base/logging.h"
 #include "media/base/bit_reader.h"
 #include "media/formats/mp2t/mp2t_common.h"

 namespace media {
 namespace mp2t {

 TsSectionCetsEcm::TsSectionCetsEcm(
     const RegisterNewKeyIdAndIvCB& register_new_key_id_and_iv_cb)
     : register_new_key_id_and_iv_cb_(register_new_key_id_and_iv_cb) {}

 TsSectionCetsEcm::~TsSectionCetsEcm() {}

 bool TsSectionCetsEcm::Parse(bool payload_unit_start_indicator,
                              const uint8_t* buf,
                              int size) {
   DCHECK(buf);
   BitReader bit_reader(buf, size);
   int num_states;
   bool next_key_id_flag;
   bool no_byte_align;
   int iv_size;
   std::string key_id;
   int transport_scrambling_control;
   int num_au;
   bool key_id_flag;
   int au_byte_offset_size;
   std::string iv;
   // TODO(dougsteed). Currently we allow only a subset of the possible values.
   // When we flesh out this implementation to cover all of ISO/IEC 23001-9 we
   // will need to generalize this.
   RCHECK(bit_reader.ReadBits(2, &num_states));
   RCHECK(num_states == 1);
   RCHECK(bit_reader.ReadFlag(&next_key_id_flag) && !next_key_id_flag);
   // TODO(dougsteed). The standard (ISO/IEC 23001-9:2014) reserves 3 bits,
   // whereas it likely was intended to be 5 bits to follow the usual practice of
   // syncing to a byte boundary for the byte oriented fields that follow.
   // For now, we plan to use it with byte alignment for convenience. Rather than
   // just having an unadvertized deviation from the standard, I have repurposed
   // the first reserved bit as a flag. This approach gives flexibility for the
   // future if the standard is fixed or comes into wide use in its present form.
   RCHECK(bit_reader.ReadFlag(&no_byte_align));
   if (no_byte_align)
     RCHECK(bit_reader.SkipBits(2));
   else
     RCHECK(bit_reader.SkipBits(4));
   RCHECK(bit_reader.ReadBits(8, &iv_size));
   RCHECK(iv_size == 16);
   RCHECK(bit_reader.ReadString(128, &key_id));
   RCHECK(bit_reader.ReadBits(2, &transport_scrambling_control));
   RCHECK(transport_scrambling_control == 0);
   RCHECK(bit_reader.ReadBits(6, &num_au));
   RCHECK(num_au == 1);
   RCHECK(bit_reader.ReadFlag(&key_id_flag) && !key_id_flag);
   RCHECK(bit_reader.SkipBits(3));
   RCHECK(bit_reader.ReadBits(4, &au_byte_offset_size));
   RCHECK(au_byte_offset_size == 0);
   RCHECK(bit_reader.ReadString(128, &iv));
   // The CETS-ECM is supposed to  use adaptation field stuffing to fill the TS
   // packet, so there should be no data left to read.
   RCHECK(bit_reader.bits_available() == 0);
   register_new_key_id_and_iv_cb_.Run(key_id, iv);
   return true;
 }

 void TsSectionCetsEcm::Flush() {
   // No pending state.
 }

 void TsSectionCetsEcm::Reset() {
   // No state to clean up.
 }

 }  // namespace mp2t
 }  // namespace media
	// Copyright 2015 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/ts_section_cets_ecm.h"

	#include "base/logging.h"
	#include "media/base/bit_reader.h"
	#include "media/formats/mp2t/mp2t_common.h"

	namespace media {
	namespace mp2t {

	TsSectionCetsEcm::TsSectionCetsEcm(
	const RegisterNewKeyIdAndIvCB& register_new_key_id_and_iv_cb)
	: register_new_key_id_and_iv_cb_(register_new_key_id_and_iv_cb) {}

	TsSectionCetsEcm::~TsSectionCetsEcm() {}

	bool TsSectionCetsEcm::Parse(bool payload_unit_start_indicator,
	const uint8_t* buf,
	int size) {
	DCHECK(buf);
	BitReader bit_reader(buf, size);
	int num_states;
	bool next_key_id_flag;
	bool no_byte_align;
	int iv_size;
	std::string key_id;
	int transport_scrambling_control;
	int num_au;
	bool key_id_flag;
	int au_byte_offset_size;
	std::string iv;
	// TODO(dougsteed). Currently we allow only a subset of the possible values.
	// When we flesh out this implementation to cover all of ISO/IEC 23001-9 we
	// will need to generalize this.
	RCHECK(bit_reader.ReadBits(2, &num_states));
	RCHECK(num_states == 1);
	RCHECK(bit_reader.ReadFlag(&next_key_id_flag) && !next_key_id_flag);
	// TODO(dougsteed). The standard (ISO/IEC 23001-9:2014) reserves 3 bits,
	// whereas it likely was intended to be 5 bits to follow the usual practice of
	// syncing to a byte boundary for the byte oriented fields that follow.
	// For now, we plan to use it with byte alignment for convenience. Rather than
	// just having an unadvertized deviation from the standard, I have repurposed
	// the first reserved bit as a flag. This approach gives flexibility for the
	// future if the standard is fixed or comes into wide use in its present form.
	RCHECK(bit_reader.ReadFlag(&no_byte_align));
	if (no_byte_align)
	RCHECK(bit_reader.SkipBits(2));
	else
	RCHECK(bit_reader.SkipBits(4));
	RCHECK(bit_reader.ReadBits(8, &iv_size));
	RCHECK(iv_size == 16);
	RCHECK(bit_reader.ReadString(128, &key_id));
	RCHECK(bit_reader.ReadBits(2, &transport_scrambling_control));
	RCHECK(transport_scrambling_control == 0);
	RCHECK(bit_reader.ReadBits(6, &num_au));
	RCHECK(num_au == 1);
	RCHECK(bit_reader.ReadFlag(&key_id_flag) && !key_id_flag);
	RCHECK(bit_reader.SkipBits(3));
	RCHECK(bit_reader.ReadBits(4, &au_byte_offset_size));
	RCHECK(au_byte_offset_size == 0);
	RCHECK(bit_reader.ReadString(128, &iv));
	// The CETS-ECM is supposed to use adaptation field stuffing to fill the TS
	// packet, so there should be no data left to read.
	RCHECK(bit_reader.bits_available() == 0);
	register_new_key_id_and_iv_cb_.Run(key_id, iv);
	return true;
	}

	void TsSectionCetsEcm::Flush() {
	// No pending state.
	}

	void TsSectionCetsEcm::Reset() {
	// No state to clean up.
	}

	} // namespace mp2t
	} // namespace media