// 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 #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/base/memory/ref_counted.h" #include "packager/base/stl_util.h" #include "packager/media/base/fixed_key_source.h" #include "packager/media/base/http_key_fetcher.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. bool Base64StringToBytes(const std::string& base64_string, std::vector* 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& bytes, std::string* base64_string) { DCHECK(base64_string); base::Base64Encode(base::StringPiece(reinterpret_cast (bytes.data()), bytes.size()), base64_string); } bool GetKeyFromTrack(const base::DictionaryValue& track_dict, std::vector* 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* 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* 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 { // A ref counted wrapper for EncryptionKeyMap. class WidevineKeySource::RefCountedEncryptionKeyMap : public base::RefCountedThreadSafe { public: explicit RefCountedEncryptionKeyMap(EncryptionKeyMap* encryption_key_map) { DCHECK(encryption_key_map); encryption_key_map_.swap(*encryption_key_map); } std::map& map() { return encryption_key_map_; } private: friend class base::RefCountedThreadSafe; ~RefCountedEncryptionKeyMap() { STLDeleteValues(&encryption_key_map_); } EncryptionKeyMap encryption_key_map_; DISALLOW_COPY_AND_ASSIGN(RefCountedEncryptionKeyMap); }; 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_(false, false), 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(); } STLDeleteValues(&encryption_key_map_); } Status WidevineKeySource::FetchKeys(const std::vector& 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(const std::vector& pssh_box) { const std::vector widevine_system_id( kWidevineSystemId, kWidevineSystemId + arraysize(kWidevineSystemId)); ProtectionSystemSpecificInfo info; if (!info.Parse(pssh_box.data(), pssh_box.size())) return Status(error::PARSER_FAILURE, "Error parsing the PSSH box."); if (info.system_id() == widevine_system_id) { base::AutoLock scoped_lock(lock_); request_dict_.Clear(); std::string pssh_data_base64_string; BytesToBase64String(info.pssh_data(), &pssh_data_base64_string); request_dict_.SetString("pssh_data", pssh_data_base64_string); return FetchKeysInternal(!kEnableKeyRotation, 0, false); } else if (!info.key_ids().empty()) { // This is not a Widevine PSSH box. Try making the request for the key-IDs. // Even if this is a different key-system, it should still work. Either // the server will not recognize it and return an error, or it will // recognize it and the key must be correct (or the content is bad). return FetchKeys(info.key_ids()); } else { return Status(error::NOT_FOUND, "No key IDs given in PSSH box."); } } Status WidevineKeySource::FetchKeys( const std::vector>& key_ids) { base::AutoLock scoped_lock(lock_); request_dict_.Clear(); std::string pssh_data_base64_string; // Generate Widevine PSSH data from the key-IDs. WidevinePsshData widevine_pssh_data; for (size_t i = 0; i < key_ids.size(); i++) { widevine_pssh_data.add_key_id(key_ids[i].data(), key_ids[i].size()); } const std::string serialized_string = widevine_pssh_data.SerializeAsString(); std::vector pssh_data(serialized_string.begin(), serialized_string.end()); BytesToBase64String(pssh_data, &pssh_data_base64_string); request_dict_.SetString("pssh_data", pssh_data_base64_string); return FetchKeysInternal(!kEnableKeyRotation, 0, false); } Status WidevineKeySource::FetchKeys(uint32_t asset_id) { base::AutoLock scoped_lock(lock_); request_dict_.Clear(); // 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); return FetchKeysInternal(!kEnableKeyRotation, 0, true); } 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& key_id, EncryptionKey* key) { DCHECK(key); for (std::map::iterator iter = encryption_key_map_.begin(); iter != encryption_key_map_.end(); ++iter) { if (iter->second->key_id == key_id) { *key = *iter->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 signer) { signer_ = std::move(signer); } void WidevineKeySource::set_key_fetcher( std::unique_ptr 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); scoped_refptr ref_counted_encryption_key_map; Status status = key_pool_->Peek(crypto_period_index, &ref_counted_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; } EncryptionKeyMap& encryption_key_map = ref_counted_encryption_key_map->map(); 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; } 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_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. // TODO(kqyang): Remove ".release()" when base is updated to use unique_ptr. std::unique_ptr root( base::JSONReader::Read(raw_response).release()); 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; // TODO(kqyang): Remove ".release()" when base is updated to use unique_ptr. std::unique_ptr root(base::JSONReader::Read(response).release()); 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 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 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] = encryption_key.release(); } // 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> 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& 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) { encryption_key_map_ = encryption_key_map; return true; } return PushToKeyPool(&encryption_key_map); } bool WidevineKeySource::PushToKeyPool( EncryptionKeyMap* encryption_key_map) { DCHECK(key_pool_); DCHECK(encryption_key_map); Status status = key_pool_->Push(scoped_refptr( new RefCountedEncryptionKeyMap(encryption_key_map)), kInfiniteTimeout); encryption_key_map->clear(); if (!status.ok()) { DCHECK_EQ(error::STOPPED, status.error_code()); return false; } return true; } } // namespace media } // namespace shaka