shaka-packager/packager/media/formats/webm/webm_crypto_helpers.cc

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// 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 "packager/media/formats/webm/webm_crypto_helpers.h"
#include "packager/base/logging.h"
#include "packager/base/sys_byteorder.h"
#include "packager/media/base/buffer_reader.h"
#include "packager/media/formats/webm/webm_constants.h"
namespace shaka {
namespace media {
namespace {
// Generates a 16 byte CTR counter block. The CTR counter block format is a
// CTR IV appended with a CTR block counter. |iv| is an 8 byte CTR IV.
// |iv_size| is the size of |iv| in btyes. Returns a string of
// kDecryptionKeySize bytes.
std::vector<uint8_t> GenerateWebMCounterBlock(const uint8_t* iv, int iv_size) {
std::vector<uint8_t> counter_block(iv, iv + iv_size);
counter_block.insert(counter_block.end(),
DecryptConfig::kDecryptionKeySize - iv_size, 0);
return counter_block;
}
} // namespace anonymous
// TODO(tinskip): Add unit test for this function.
bool WebMCreateDecryptConfig(const uint8_t* data,
int data_size,
const uint8_t* key_id,
size_t key_id_size,
std::unique_ptr<DecryptConfig>* decrypt_config,
int* data_offset) {
int header_size = kWebMSignalByteSize;
if (data_size < header_size) {
DVLOG(1) << "Empty WebM sample.";
return false;
}
uint8_t signal_byte = data[0];
if (signal_byte & kWebMEncryptedSignal) {
// Encrypted sample.
header_size += kWebMIvSize;
if (data_size < header_size) {
DVLOG(1) << "Encrypted WebM sample too small to hold IV: " << data_size;
return false;
}
std::vector<SubsampleEntry> subsamples;
if (signal_byte & kWebMPartitionedSignal) {
// Encrypted sample with subsamples / partitioning.
header_size += kWebMNumPartitionsSize;
if (data_size < header_size) {
DVLOG(1)
<< "Encrypted WebM sample too small to hold number of partitions: "
<< data_size;
return false;
}
uint8_t num_partitions = data[kWebMSignalByteSize + kWebMIvSize];
BufferReader offsets_buffer(data + header_size, data_size - header_size);
header_size += num_partitions * kWebMPartitionOffsetSize;
uint32_t subsample_offset = 0;
bool encrypted_subsample = false;
uint16_t clear_size = 0;
uint32_t encrypted_size = 0;
for (uint8_t partition_idx = 0; partition_idx < num_partitions;
++partition_idx) {
uint32_t partition_offset;
if (!offsets_buffer.Read4(&partition_offset)) {
DVLOG(1)
<< "Encrypted WebM sample too small to hold partition offsets: "
<< data_size;
return false;
}
if (partition_offset < subsample_offset) {
DVLOG(1) << "Partition offsets out of order.";
return false;
}
if (encrypted_subsample) {
encrypted_size = partition_offset - subsample_offset;
subsamples.push_back(SubsampleEntry(clear_size, encrypted_size));
} else {
clear_size = partition_offset - subsample_offset;
if (partition_idx == (num_partitions - 1)) {
encrypted_size = data_size - header_size - subsample_offset - clear_size;
subsamples.push_back(SubsampleEntry(clear_size, encrypted_size));
}
}
subsample_offset = partition_offset;
encrypted_subsample = !encrypted_subsample;
}
if (!(num_partitions % 2)) {
// Even number of partitions. Add one last all-clear subsample.
clear_size = data_size - header_size - subsample_offset;
encrypted_size = 0;
subsamples.push_back(SubsampleEntry(clear_size, encrypted_size));
}
}
decrypt_config->reset(new DecryptConfig(
std::vector<uint8_t>(key_id, key_id + key_id_size),
GenerateWebMCounterBlock(data + kWebMSignalByteSize, kWebMIvSize),
subsamples));
} else {
// Clear sample.
decrypt_config->reset();
}
*data_offset = header_size;
return true;
}
} // namespace media
} // namespace shaka