shaka-packager/packager/media/base/widevine_key_source.cc

608 lines
22 KiB
C++

// Copyright 2014 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/base/widevine_key_source.h"
#include <set>
#include "packager/base/base64.h"
#include "packager/base/bind.h"
#include "packager/base/json/json_reader.h"
#include "packager/base/json/json_writer.h"
#include "packager/media/base/fixed_key_source.h"
#include "packager/media/base/http_key_fetcher.h"
#include "packager/media/base/network_util.h"
#include "packager/media/base/producer_consumer_queue.h"
#include "packager/media/base/protection_system_specific_info.h"
#include "packager/media/base/rcheck.h"
#include "packager/media/base/request_signer.h"
#include "packager/media/base/widevine_pssh_data.pb.h"
namespace shaka {
namespace {
const bool kEnableKeyRotation = true;
const char kLicenseStatusOK[] = "OK";
// Server may return INTERNAL_ERROR intermittently, which is a transient error
// and the next client request may succeed without problem.
const char kLicenseStatusTransientError[] = "INTERNAL_ERROR";
// Number of times to retry requesting keys in case of a transient error from
// the server.
const int kNumTransientErrorRetries = 5;
const int kFirstRetryDelayMilliseconds = 1000;
// Default crypto period count, which is the number of keys to fetch on every
// key rotation enabled request.
const int kDefaultCryptoPeriodCount = 10;
const int kGetKeyTimeoutInSeconds = 5 * 60; // 5 minutes.
const int kKeyFetchTimeoutInSeconds = 60; // 1 minute.
std::vector<uint8_t> StringToBytes(const std::string& string) {
return std::vector<uint8_t>(string.begin(), string.end());
}
std::vector<uint8_t> WidevinePsshFromKeyId(
const std::vector<std::vector<uint8_t>>& key_ids) {
media::WidevinePsshData widevine_pssh_data;
for (const std::vector<uint8_t>& key_id : key_ids)
widevine_pssh_data.add_key_id(key_id.data(), key_id.size());
return StringToBytes(widevine_pssh_data.SerializeAsString());
}
bool Base64StringToBytes(const std::string& base64_string,
std::vector<uint8_t>* bytes) {
DCHECK(bytes);
std::string str;
if (!base::Base64Decode(base64_string, &str))
return false;
bytes->assign(str.begin(), str.end());
return true;
}
void BytesToBase64String(const std::vector<uint8_t>& bytes,
std::string* base64_string) {
DCHECK(base64_string);
base::Base64Encode(base::StringPiece(reinterpret_cast<const char*>
(bytes.data()), bytes.size()),
base64_string);
}
bool GetKeyFromTrack(const base::DictionaryValue& track_dict,
std::vector<uint8_t>* key) {
DCHECK(key);
std::string key_base64_string;
RCHECK(track_dict.GetString("key", &key_base64_string));
VLOG(2) << "Key:" << key_base64_string;
RCHECK(Base64StringToBytes(key_base64_string, key));
return true;
}
bool GetKeyIdFromTrack(const base::DictionaryValue& track_dict,
std::vector<uint8_t>* key_id) {
DCHECK(key_id);
std::string key_id_base64_string;
RCHECK(track_dict.GetString("key_id", &key_id_base64_string));
VLOG(2) << "Keyid:" << key_id_base64_string;
RCHECK(Base64StringToBytes(key_id_base64_string, key_id));
return true;
}
bool GetPsshDataFromTrack(const base::DictionaryValue& track_dict,
std::vector<uint8_t>* pssh_data) {
DCHECK(pssh_data);
const base::ListValue* pssh_list;
RCHECK(track_dict.GetList("pssh", &pssh_list));
// Invariant check. We don't want to crash in release mode if possible.
// The following code handles it gracefully if GetSize() does not return 1.
DCHECK_EQ(1u, pssh_list->GetSize());
const base::DictionaryValue* pssh_dict;
RCHECK(pssh_list->GetDictionary(0, &pssh_dict));
std::string drm_type;
RCHECK(pssh_dict->GetString("drm_type", &drm_type));
if (drm_type != "WIDEVINE") {
LOG(ERROR) << "Expecting drm_type 'WIDEVINE', get '" << drm_type << "'.";
return false;
}
std::string pssh_data_base64_string;
RCHECK(pssh_dict->GetString("data", &pssh_data_base64_string));
VLOG(2) << "Pssh Data:" << pssh_data_base64_string;
RCHECK(Base64StringToBytes(pssh_data_base64_string, pssh_data));
return true;
}
} // namespace
namespace media {
WidevineKeySource::WidevineKeySource(const std::string& server_url,
bool add_common_pssh)
: key_production_thread_("KeyProductionThread",
base::Bind(&WidevineKeySource::FetchKeysTask,
base::Unretained(this))),
key_fetcher_(new HttpKeyFetcher(kKeyFetchTimeoutInSeconds)),
server_url_(server_url),
crypto_period_count_(kDefaultCryptoPeriodCount),
add_common_pssh_(add_common_pssh),
key_production_started_(false),
start_key_production_(base::WaitableEvent::ResetPolicy::AUTOMATIC,
base::WaitableEvent::InitialState::NOT_SIGNALED),
first_crypto_period_index_(0) {
key_production_thread_.Start();
}
WidevineKeySource::~WidevineKeySource() {
if (key_pool_)
key_pool_->Stop();
if (key_production_thread_.HasBeenStarted()) {
// Signal the production thread to start key production if it is not
// signaled yet so the thread can be joined.
start_key_production_.Signal();
key_production_thread_.Join();
}
}
Status WidevineKeySource::FetchKeys(const std::vector<uint8_t>& content_id,
const std::string& policy) {
base::AutoLock scoped_lock(lock_);
request_dict_.Clear();
std::string content_id_base64_string;
BytesToBase64String(content_id, &content_id_base64_string);
request_dict_.SetString("content_id", content_id_base64_string);
request_dict_.SetString("policy", policy);
return FetchKeysInternal(!kEnableKeyRotation, 0, false);
}
Status WidevineKeySource::FetchKeys(EmeInitDataType init_data_type,
const std::vector<uint8_t>& init_data) {
std::vector<uint8_t> pssh_data;
uint32_t asset_id = 0;
switch (init_data_type) {
case EmeInitDataType::CENC: {
const std::vector<uint8_t> widevine_system_id(
kWidevineSystemId, kWidevineSystemId + arraysize(kWidevineSystemId));
std::vector<ProtectionSystemSpecificInfo> protection_systems_info;
if (!ProtectionSystemSpecificInfo::ParseBoxes(
init_data.data(), init_data.size(), &protection_systems_info)) {
return Status(error::PARSER_FAILURE, "Error parsing the PSSH boxes.");
}
for (const auto& info: protection_systems_info) {
// Use Widevine PSSH if available otherwise construct a Widevine PSSH
// from the first available key ids.
if (info.system_id() == widevine_system_id) {
pssh_data = info.pssh_data();
break;
} else if (pssh_data.empty() && !info.key_ids().empty()) {
pssh_data = WidevinePsshFromKeyId(info.key_ids());
// Continue to see if there is any Widevine PSSH. The KeyId generated
// PSSH is only used if a Widevine PSSH could not be found.
continue;
}
}
if (pssh_data.empty())
return Status(error::INVALID_ARGUMENT, "No supported PSSHs found.");
break;
}
case EmeInitDataType::WEBM:
pssh_data = WidevinePsshFromKeyId({init_data});
break;
case EmeInitDataType::WIDEVINE_CLASSIC:
if (init_data.size() < sizeof(asset_id))
return Status(error::INVALID_ARGUMENT, "Invalid asset id.");
asset_id = ntohlFromBuffer(init_data.data());
break;
default:
LOG(ERROR) << "Init data type " << static_cast<int>(init_data_type)
<< " not supported.";
return Status(error::INVALID_ARGUMENT, "Unsupported init data type.");
}
const bool widevine_classic =
init_data_type == EmeInitDataType::WIDEVINE_CLASSIC;
base::AutoLock scoped_lock(lock_);
request_dict_.Clear();
if (widevine_classic) {
// Javascript/JSON does not support int64_t or unsigned numbers. Use double
// instead as 32-bit integer can be lossless represented using double.
request_dict_.SetDouble("asset_id", asset_id);
} else {
std::string pssh_data_base64_string;
BytesToBase64String(pssh_data, &pssh_data_base64_string);
request_dict_.SetString("pssh_data", pssh_data_base64_string);
}
return FetchKeysInternal(!kEnableKeyRotation, 0, widevine_classic);
}
Status WidevineKeySource::GetKey(TrackType track_type, EncryptionKey* key) {
DCHECK(key);
if (encryption_key_map_.find(track_type) == encryption_key_map_.end()) {
return Status(error::INTERNAL_ERROR,
"Cannot find key of type " + TrackTypeToString(track_type));
}
*key = *encryption_key_map_[track_type];
return Status::OK;
}
Status WidevineKeySource::GetKey(const std::vector<uint8_t>& key_id,
EncryptionKey* key) {
DCHECK(key);
for (const auto& pair : encryption_key_map_) {
if (pair.second->key_id == key_id) {
*key = *pair.second;
return Status::OK;
}
}
return Status(error::INTERNAL_ERROR,
"Cannot find key with specified key ID");
}
Status WidevineKeySource::GetCryptoPeriodKey(uint32_t crypto_period_index,
TrackType track_type,
EncryptionKey* key) {
DCHECK(key_production_thread_.HasBeenStarted());
// TODO(kqyang): This is not elegant. Consider refactoring later.
{
base::AutoLock scoped_lock(lock_);
if (!key_production_started_) {
// Another client may have a slightly smaller starting crypto period
// index. Set the initial value to account for that.
first_crypto_period_index_ =
crypto_period_index ? crypto_period_index - 1 : 0;
DCHECK(!key_pool_);
key_pool_.reset(new EncryptionKeyQueue(crypto_period_count_,
first_crypto_period_index_));
start_key_production_.Signal();
key_production_started_ = true;
}
}
return GetKeyInternal(crypto_period_index, track_type, key);
}
void WidevineKeySource::set_signer(std::unique_ptr<RequestSigner> signer) {
signer_ = std::move(signer);
}
void WidevineKeySource::set_key_fetcher(
std::unique_ptr<KeyFetcher> key_fetcher) {
key_fetcher_ = std::move(key_fetcher);
}
Status WidevineKeySource::GetKeyInternal(uint32_t crypto_period_index,
TrackType track_type,
EncryptionKey* key) {
DCHECK(key_pool_);
DCHECK(key);
DCHECK_LE(track_type, NUM_VALID_TRACK_TYPES);
DCHECK_NE(track_type, TRACK_TYPE_UNKNOWN);
std::shared_ptr<EncryptionKeyMap> encryption_key_map;
Status status = key_pool_->Peek(crypto_period_index, &encryption_key_map,
kGetKeyTimeoutInSeconds * 1000);
if (!status.ok()) {
if (status.error_code() == error::STOPPED) {
CHECK(!common_encryption_request_status_.ok());
return common_encryption_request_status_;
}
return status;
}
if (encryption_key_map->find(track_type) == encryption_key_map->end()) {
return Status(error::INTERNAL_ERROR,
"Cannot find key of type " + TrackTypeToString(track_type));
}
*key = *encryption_key_map->at(track_type);
return Status::OK;
}
void WidevineKeySource::FetchKeysTask() {
// Wait until key production is signaled.
start_key_production_.Wait();
if (!key_pool_ || key_pool_->Stopped())
return;
Status status = FetchKeysInternal(kEnableKeyRotation,
first_crypto_period_index_,
false);
while (status.ok()) {
first_crypto_period_index_ += crypto_period_count_;
status = FetchKeysInternal(kEnableKeyRotation,
first_crypto_period_index_,
false);
}
common_encryption_request_status_ = status;
key_pool_->Stop();
}
Status WidevineKeySource::FetchKeysInternal(bool enable_key_rotation,
uint32_t first_crypto_period_index,
bool widevine_classic) {
std::string request;
FillRequest(enable_key_rotation,
first_crypto_period_index,
&request);
std::string message;
Status status = GenerateKeyMessage(request, &message);
if (!status.ok())
return status;
VLOG(1) << "Message: " << message;
std::string raw_response;
int64_t sleep_duration = kFirstRetryDelayMilliseconds;
// Perform client side retries if seeing server transient error to workaround
// server limitation.
for (int i = 0; i < kNumTransientErrorRetries; ++i) {
status = key_fetcher_->FetchKeys(server_url_, message, &raw_response);
if (status.ok()) {
VLOG(1) << "Retry [" << i << "] Response:" << raw_response;
std::string response;
if (!DecodeResponse(raw_response, &response)) {
return Status(error::SERVER_ERROR,
"Failed to decode response '" + raw_response + "'.");
}
bool transient_error = false;
if (ExtractEncryptionKey(enable_key_rotation,
widevine_classic,
response,
&transient_error))
return Status::OK;
if (!transient_error) {
return Status(
error::SERVER_ERROR,
"Failed to extract encryption key from '" + response + "'.");
}
} else if (status.error_code() != error::TIME_OUT) {
return status;
}
// Exponential backoff.
if (i != kNumTransientErrorRetries - 1) {
base::PlatformThread::Sleep(
base::TimeDelta::FromMilliseconds(sleep_duration));
sleep_duration *= 2;
}
}
return Status(error::SERVER_ERROR,
"Failed to recover from server internal error.");
}
void WidevineKeySource::FillRequest(bool enable_key_rotation,
uint32_t first_crypto_period_index,
std::string* request) {
DCHECK(request);
DCHECK(!request_dict_.empty());
// Build tracks.
base::ListValue* tracks = new base::ListValue();
base::DictionaryValue* track_sd = new base::DictionaryValue();
track_sd->SetString("type", "SD");
tracks->Append(track_sd);
base::DictionaryValue* track_hd = new base::DictionaryValue();
track_hd->SetString("type", "HD");
tracks->Append(track_hd);
base::DictionaryValue* track_uhd1 = new base::DictionaryValue();
track_uhd1->SetString("type", "UHD1");
tracks->Append(track_uhd1);
base::DictionaryValue* track_uhd2 = new base::DictionaryValue();
track_uhd2->SetString("type", "UHD2");
tracks->Append(track_uhd2);
base::DictionaryValue* track_audio = new base::DictionaryValue();
track_audio->SetString("type", "AUDIO");
tracks->Append(track_audio);
request_dict_.Set("tracks", tracks);
// Build DRM types.
base::ListValue* drm_types = new base::ListValue();
drm_types->AppendString("WIDEVINE");
request_dict_.Set("drm_types", drm_types);
// Build key rotation fields.
if (enable_key_rotation) {
// Javascript/JSON does not support int64_t or unsigned numbers. Use double
// instead as 32-bit integer can be lossless represented using double.
request_dict_.SetDouble("first_crypto_period_index",
first_crypto_period_index);
request_dict_.SetInteger("crypto_period_count", crypto_period_count_);
}
base::JSONWriter::WriteWithOptions(
request_dict_,
// Write doubles that have no fractional part as a normal integer, i.e.
// without using exponential notation or appending a '.0'.
base::JSONWriter::OPTIONS_OMIT_DOUBLE_TYPE_PRESERVATION, request);
}
Status WidevineKeySource::GenerateKeyMessage(const std::string& request,
std::string* message) {
DCHECK(message);
std::string request_base64_string;
base::Base64Encode(request, &request_base64_string);
base::DictionaryValue request_dict;
request_dict.SetString("request", request_base64_string);
// Sign the request.
if (signer_) {
std::string signature;
if (!signer_->GenerateSignature(request, &signature))
return Status(error::INTERNAL_ERROR, "Signature generation failed.");
std::string signature_base64_string;
base::Base64Encode(signature, &signature_base64_string);
request_dict.SetString("signature", signature_base64_string);
request_dict.SetString("signer", signer_->signer_name());
}
base::JSONWriter::Write(request_dict, message);
return Status::OK;
}
bool WidevineKeySource::DecodeResponse(
const std::string& raw_response,
std::string* response) {
DCHECK(response);
// Extract base64 formatted response from JSON formatted raw response.
std::unique_ptr<base::Value> root(base::JSONReader::Read(raw_response));
if (!root) {
LOG(ERROR) << "'" << raw_response << "' is not in JSON format.";
return false;
}
const base::DictionaryValue* response_dict = NULL;
RCHECK(root->GetAsDictionary(&response_dict));
std::string response_base64_string;
RCHECK(response_dict->GetString("response", &response_base64_string));
RCHECK(base::Base64Decode(response_base64_string, response));
return true;
}
bool WidevineKeySource::ExtractEncryptionKey(
bool enable_key_rotation,
bool widevine_classic,
const std::string& response,
bool* transient_error) {
DCHECK(transient_error);
*transient_error = false;
std::unique_ptr<base::Value> root(base::JSONReader::Read(response));
if (!root) {
LOG(ERROR) << "'" << response << "' is not in JSON format.";
return false;
}
const base::DictionaryValue* license_dict = NULL;
RCHECK(root->GetAsDictionary(&license_dict));
std::string license_status;
RCHECK(license_dict->GetString("status", &license_status));
if (license_status != kLicenseStatusOK) {
LOG(ERROR) << "Received non-OK license response: " << response;
*transient_error = (license_status == kLicenseStatusTransientError);
return false;
}
const base::ListValue* tracks;
RCHECK(license_dict->GetList("tracks", &tracks));
// Should have at least one track per crypto_period.
RCHECK(enable_key_rotation ? tracks->GetSize() >= 1 * crypto_period_count_
: tracks->GetSize() >= 1);
int current_crypto_period_index = first_crypto_period_index_;
EncryptionKeyMap encryption_key_map;
for (size_t i = 0; i < tracks->GetSize(); ++i) {
const base::DictionaryValue* track_dict;
RCHECK(tracks->GetDictionary(i, &track_dict));
if (enable_key_rotation) {
int crypto_period_index;
RCHECK(
track_dict->GetInteger("crypto_period_index", &crypto_period_index));
if (crypto_period_index != current_crypto_period_index) {
if (crypto_period_index != current_crypto_period_index + 1) {
LOG(ERROR) << "Expecting crypto period index "
<< current_crypto_period_index << " or "
<< current_crypto_period_index + 1 << "; Seen "
<< crypto_period_index << " at track " << i;
return false;
}
if (!PushToKeyPool(&encryption_key_map))
return false;
++current_crypto_period_index;
}
}
std::string track_type_str;
RCHECK(track_dict->GetString("type", &track_type_str));
TrackType track_type = GetTrackTypeFromString(track_type_str);
DCHECK_NE(TRACK_TYPE_UNKNOWN, track_type);
RCHECK(encryption_key_map.find(track_type) == encryption_key_map.end());
std::unique_ptr<EncryptionKey> encryption_key(new EncryptionKey());
if (!GetKeyFromTrack(*track_dict, &encryption_key->key))
return false;
// Get key ID and PSSH data for CENC content only.
if (!widevine_classic) {
if (!GetKeyIdFromTrack(*track_dict, &encryption_key->key_id))
return false;
ProtectionSystemSpecificInfo info;
info.add_key_id(encryption_key->key_id);
info.set_system_id(kWidevineSystemId, arraysize(kWidevineSystemId));
info.set_pssh_box_version(0);
std::vector<uint8_t> pssh_data;
if (!GetPsshDataFromTrack(*track_dict, &pssh_data))
return false;
info.set_pssh_data(pssh_data);
encryption_key->key_system_info.push_back(info);
}
encryption_key_map[track_type] = std::move(encryption_key);
}
// If the flag exists, create a common system ID PSSH box that contains the
// key IDs of all the keys.
if (add_common_pssh_ && !widevine_classic) {
std::set<std::vector<uint8_t>> key_ids;
for (const EncryptionKeyMap::value_type& pair : encryption_key_map) {
key_ids.insert(pair.second->key_id);
}
// Create a common system PSSH box.
ProtectionSystemSpecificInfo info;
info.set_system_id(kCommonSystemId, arraysize(kCommonSystemId));
info.set_pssh_box_version(1);
for (const std::vector<uint8_t>& key_id : key_ids) {
info.add_key_id(key_id);
}
for (const EncryptionKeyMap::value_type& pair : encryption_key_map) {
pair.second->key_system_info.push_back(info);
}
}
DCHECK(!encryption_key_map.empty());
if (!enable_key_rotation) {
// Merge with previously requested keys.
for (auto& pair : encryption_key_map)
encryption_key_map_[pair.first] = std::move(pair.second);
return true;
}
return PushToKeyPool(&encryption_key_map);
}
bool WidevineKeySource::PushToKeyPool(
EncryptionKeyMap* encryption_key_map) {
DCHECK(key_pool_);
DCHECK(encryption_key_map);
auto encryption_key_map_shared = std::make_shared<EncryptionKeyMap>();
encryption_key_map_shared->swap(*encryption_key_map);
Status status = key_pool_->Push(encryption_key_map_shared, kInfiniteTimeout);
if (!status.ok()) {
DCHECK_EQ(error::STOPPED, status.error_code());
return false;
}
return true;
}
} // namespace media
} // namespace shaka