// Copyright 2015 Google Inc. All rights reserved. // // Use of this source code is governed by a BSD-style // license that can be found in the LICENSE file or at // https://developers.google.com/open-source/licenses/bsd #include "packager/media/formats/webm/encryptor.h" #include #include "packager/media/base/aes_encryptor.h" #include "packager/media/base/buffer_writer.h" #include "packager/media/base/fourccs.h" #include "packager/media/base/media_sample.h" #include "packager/media/codecs/vp9_parser.h" #include "packager/media/formats/webm/webm_constants.h" namespace shaka { namespace media { namespace webm { namespace { const size_t kAesBlockSize = 16; Status CreateContentEncryption(mkvmuxer::Track* track, EncryptionKey* key) { if (!track->AddContentEncoding()) { return Status(error::INTERNAL_ERROR, "Could not add ContentEncoding to track."); } mkvmuxer::ContentEncoding* const encoding = track->GetContentEncodingByIndex(0); if (!encoding) { return Status(error::INTERNAL_ERROR, "Could not add ContentEncoding to track."); } mkvmuxer::ContentEncAESSettings* const aes = encoding->enc_aes_settings(); if (!aes) { return Status(error::INTERNAL_ERROR, "Error getting ContentEncAESSettings."); } if (aes->cipher_mode() != mkvmuxer::ContentEncAESSettings::kCTR) { return Status(error::INTERNAL_ERROR, "Cipher Mode is not CTR."); } if (!key->key_id.empty() && !encoding->SetEncryptionID( reinterpret_cast(key->key_id.data()), key->key_id.size())) { return Status(error::INTERNAL_ERROR, "Error setting encryption ID."); } return Status::OK; } } // namespace Encryptor::Encryptor() {} Encryptor::~Encryptor() {} Status Encryptor::Initialize(MuxerListener* muxer_listener, KeySource::TrackType track_type, Codec codec, KeySource* key_source, bool webm_subsample_encryption) { DCHECK(key_source); return CreateEncryptor(muxer_listener, track_type, codec, key_source, webm_subsample_encryption); } Status Encryptor::AddTrackInfo(mkvmuxer::Track* track) { DCHECK(key_); return CreateContentEncryption(track, key_.get()); } Status Encryptor::EncryptFrame(scoped_refptr sample, bool encrypt_frame) { DCHECK(encryptor_); const size_t sample_size = sample->data_size(); // We need to parse the frame (which also updates the vpx parser) even if the // frame is not encrypted as the next (encrypted) frame may be dependent on // this clear frame. std::vector vpx_frames; if (vpx_parser_) { if (!vpx_parser_->Parse(sample->data(), sample_size, &vpx_frames)) { return Status(error::MUXER_FAILURE, "Failed to parse VPx frame."); } } if (encrypt_frame) { const size_t iv_size = encryptor_->iv().size(); if (iv_size != kWebMIvSize) { return Status(error::MUXER_FAILURE, "Incorrect size WebM encryption IV."); } if (vpx_frames.size()) { // Use partitioned subsample encryption: | signal_byte(3) | iv // | num_partitions | partition_offset * n | enc_data | if (vpx_frames.size() > kWebMMaxSubsamples) { return Status(error::MUXER_FAILURE, "Maximum number of VPx encryption partitions exceeded."); } uint8_t num_partitions = vpx_frames.size() == 1 ? 1 : vpx_frames.size() * 2; size_t header_size = kWebMSignalByteSize + iv_size + kWebMNumPartitionsSize + (kWebMPartitionOffsetSize * num_partitions); sample->resize_data(header_size + sample_size); uint8_t* sample_data = sample->writable_data(); memmove(sample_data + header_size, sample_data, sample_size); sample_data[0] = kWebMEncryptedSignal | kWebMPartitionedSignal; memcpy(sample_data + kWebMSignalByteSize, encryptor_->iv().data(), iv_size); sample_data[kWebMSignalByteSize + kWebMIvSize] = num_partitions; uint32 partition_offset = 0; BufferWriter offsets_buffer(kWebMPartitionOffsetSize * num_partitions); for (const auto& vpx_frame : vpx_frames) { uint32_t encrypted_size = vpx_frame.frame_size - vpx_frame.uncompressed_header_size; encrypted_size -= encrypted_size % kAesBlockSize; uint32_t clear_size = vpx_frame.frame_size - encrypted_size; partition_offset += clear_size; offsets_buffer.AppendInt(partition_offset); if (encrypted_size > 0) { uint8_t* encrypted_ptr = sample_data + header_size + partition_offset; if (!encryptor_->Crypt(encrypted_ptr, encrypted_size, encrypted_ptr)) { return Status(error::MUXER_FAILURE, "Failed to encrypt the frame."); } partition_offset += encrypted_size; } if (num_partitions > 1) { offsets_buffer.AppendInt(partition_offset); } } DCHECK_EQ(num_partitions * kWebMPartitionOffsetSize, offsets_buffer.Size()); memcpy(sample_data + kWebMSignalByteSize + kWebMIvSize + kWebMNumPartitionsSize, offsets_buffer.Buffer(), offsets_buffer.Size()); } else { // Use whole-frame encryption: | signal_byte(1) | iv | enc_data | sample->resize_data(sample_size + iv_size + kWebMSignalByteSize); uint8_t* sample_data = sample->writable_data(); // Encrypt the data in-place. if (!encryptor_->Crypt(sample_data, sample_size, sample_data)) { return Status(error::MUXER_FAILURE, "Failed to encrypt the frame."); } // First move the sample data to after the IV; then write the IV and // signal byte. memmove(sample_data + iv_size + kWebMSignalByteSize, sample_data, sample_size); sample_data[0] = kWebMEncryptedSignal; memcpy(sample_data + 1, encryptor_->iv().data(), iv_size); } encryptor_->UpdateIv(); } else { // Clear sample: | signal_byte(0) | data | sample->resize_data(sample_size + 1); uint8_t* sample_data = sample->writable_data(); memmove(sample_data + 1, sample_data, sample_size); sample_data[0] = 0x00; } return Status::OK; } Status Encryptor::CreateEncryptor(MuxerListener* muxer_listener, KeySource::TrackType track_type, Codec codec, KeySource* key_source, bool webm_subsample_encryption) { std::unique_ptr encryption_key(new EncryptionKey()); Status status = key_source->GetKey(track_type, encryption_key.get()); if (!status.ok()) return status; if (encryption_key->iv.empty()) { if (!AesCryptor::GenerateRandomIv(FOURCC_cenc, &encryption_key->iv)) return Status(error::INTERNAL_ERROR, "Failed to generate random iv."); } DCHECK_EQ(kWebMIvSize, encryption_key->iv.size()); std::unique_ptr encryptor(new AesCtrEncryptor()); const bool initialized = encryptor->InitializeWithIv(encryption_key->key, encryption_key->iv); if (!initialized) return Status(error::INTERNAL_ERROR, "Failed to create the encryptor."); if (webm_subsample_encryption && codec == kCodecVP9) { // Allocate VP9 parser to do subsample encryption of VP9. vpx_parser_.reset(new VP9Parser); } if (muxer_listener) { const bool kInitialEncryptionInfo = true; muxer_listener->OnEncryptionInfoReady( kInitialEncryptionInfo, FOURCC_cenc, encryption_key->key_id, encryptor->iv(), encryption_key->key_system_info); } key_ = std::move(encryption_key); encryptor_ = std::move(encryptor); return Status::OK; } } // namespace webm } // namespace media } // namespace shaka