// Copyright (c) 2017 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 "net/http/http_cache_writers.h" #include #include #include "base/auto_reset.h" #include "base/logging.h" #include "net/base/net_errors.h" #include "net/disk_cache/disk_cache.h" #include "net/http/http_cache_transaction.h" #include "net/http/http_response_info.h" #include "net/http/partial_data.h" namespace net { namespace { bool IsValidResponseForWriter(bool is_partial, const HttpResponseInfo* response_info) { if (!response_info->headers.get()) return false; // Return false if the response code sent by the server is garbled. // Both 200 and 304 are valid since concurrent writing is supported. if (!is_partial && (response_info->headers->response_code() != 200 && response_info->headers->response_code() != 304)) { return false; } return true; } } // namespace HttpCache::Writers::TransactionInfo::TransactionInfo(PartialData* partial_data, const bool is_truncated, HttpResponseInfo info) : partial(partial_data), truncated(is_truncated), response_info(info) {} HttpCache::Writers::TransactionInfo::~TransactionInfo() = default; HttpCache::Writers::TransactionInfo::TransactionInfo(const TransactionInfo&) = default; HttpCache::Writers::Writers(HttpCache* cache, HttpCache::ActiveEntry* entry) : cache_(cache), entry_(entry), weak_factory_(this) {} HttpCache::Writers::~Writers() = default; int HttpCache::Writers::Read(scoped_refptr buf, int buf_len, CompletionOnceCallback callback, Transaction* transaction) { DCHECK(buf); DCHECK_GT(buf_len, 0); DCHECK(!callback.is_null()); DCHECK(transaction); // If another transaction invoked a Read which is currently ongoing, then // this transaction waits for the read to complete and gets its buffer filled // with the data returned from that read. if (next_state_ != State::NONE) { WaitingForRead read_info(buf, buf_len, std::move(callback)); waiting_for_read_.insert(std::make_pair(transaction, std::move(read_info))); return ERR_IO_PENDING; } DCHECK_EQ(next_state_, State::NONE); DCHECK(callback_.is_null()); DCHECK_EQ(nullptr, active_transaction_); DCHECK(HasTransaction(transaction)); active_transaction_ = transaction; read_buf_ = std::move(buf); io_buf_len_ = buf_len; next_state_ = State::NETWORK_READ; int rv = DoLoop(OK); if (rv == ERR_IO_PENDING) callback_ = std::move(callback); return rv; } bool HttpCache::Writers::StopCaching(bool keep_entry) { // If this is the only transaction in Writers, then stopping will be // successful. If not, then we will not stop caching since there are // other consumers waiting to read from the cache. if (all_writers_.size() != 1) return false; network_read_only_ = true; if (!keep_entry) { should_keep_entry_ = false; cache_->WritersDoomEntryRestartTransactions(entry_); } return true; } void HttpCache::Writers::AddTransaction( Transaction* transaction, ParallelWritingPattern initial_writing_pattern, RequestPriority priority, const TransactionInfo& info) { DCHECK(transaction); ParallelWritingPattern writers_pattern; DCHECK(CanAddWriters(&writers_pattern)); DCHECK_EQ(0u, all_writers_.count(transaction)); // Set truncation related information. response_info_truncation_ = info.response_info; should_keep_entry_ = IsValidResponseForWriter(info.partial != nullptr, &(info.response_info)); if (all_writers_.empty()) { DCHECK_EQ(PARALLEL_WRITING_NONE, parallel_writing_pattern_); parallel_writing_pattern_ = initial_writing_pattern; if (parallel_writing_pattern_ != PARALLEL_WRITING_JOIN) is_exclusive_ = true; } else { DCHECK_EQ(PARALLEL_WRITING_JOIN, parallel_writing_pattern_); } if (info.partial && !info.truncated) { DCHECK(!partial_do_not_truncate_); partial_do_not_truncate_ = true; } std::pair writer(transaction, info); all_writers_.insert(writer); priority_ = std::max(priority, priority_); if (network_transaction_) { network_transaction_->SetPriority(priority_); } } void HttpCache::Writers::SetNetworkTransaction( Transaction* transaction, std::unique_ptr network_transaction) { DCHECK_EQ(1u, all_writers_.count(transaction)); DCHECK(network_transaction); DCHECK(!network_transaction_); network_transaction_ = std::move(network_transaction); network_transaction_->SetPriority(priority_); } void HttpCache::Writers::ResetNetworkTransaction() { DCHECK(is_exclusive_); DCHECK_EQ(1u, all_writers_.size()); DCHECK(all_writers_.begin()->second.partial); network_transaction_.reset(); } void HttpCache::Writers::RemoveTransaction(Transaction* transaction, bool success) { EraseTransaction(transaction, OK); if (!all_writers_.empty()) return; if (!success && ShouldTruncate()) TruncateEntry(); cache_->WritersDoneWritingToEntry(entry_, success, should_keep_entry_, TransactionSet()); } void HttpCache::Writers::EraseTransaction(Transaction* transaction, int result) { // The transaction should be part of all_writers. auto it = all_writers_.find(transaction); DCHECK(it != all_writers_.end()); EraseTransaction(it, result); } HttpCache::Writers::TransactionMap::iterator HttpCache::Writers::EraseTransaction(TransactionMap::iterator it, int result) { Transaction* transaction = it->first; transaction->WriterAboutToBeRemovedFromEntry(result); TransactionMap::iterator return_it = all_writers_.erase(it); if (all_writers_.empty() && next_state_ == State::NONE) { // This needs to be called to handle the edge case where even before Read is // invoked all transactions are removed. In that case the // network_transaction_ will still have a valid request info and so it // should be destroyed before its consumer is destroyed (request info // is a raw pointer owned by its consumer). network_transaction_.reset(); } else { UpdatePriority(); } if (active_transaction_ == transaction) { active_transaction_ = nullptr; } else { // If waiting for read, remove it from the map. waiting_for_read_.erase(transaction); } return return_it; } void HttpCache::Writers::UpdatePriority() { // Get the current highest priority. RequestPriority current_highest = MINIMUM_PRIORITY; for (auto& writer : all_writers_) { Transaction* transaction = writer.first; current_highest = std::max(transaction->priority(), current_highest); } if (priority_ != current_highest) { if (network_transaction_) network_transaction_->SetPriority(current_highest); priority_ = current_highest; } } bool HttpCache::Writers::ContainsOnlyIdleWriters() const { return waiting_for_read_.empty() && !active_transaction_; } bool HttpCache::Writers::CanAddWriters(ParallelWritingPattern* reason) { *reason = parallel_writing_pattern_; if (all_writers_.empty()) return true; return !is_exclusive_ && !network_read_only_; } void HttpCache::Writers::ProcessFailure(int error) { // Notify waiting_for_read_ of the failure. Tasks will be posted for all the // transactions. CompleteWaitingForReadTransactions(error); // Idle readers should fail when Read is invoked on them. RemoveIdleWriters(error); } void HttpCache::Writers::TruncateEntry() { DCHECK(ShouldTruncate()); scoped_refptr data(new PickledIOBuffer()); response_info_truncation_.Persist(data->pickle(), true /* skip_transient_headers*/, true /* response_truncated */); data->Done(); io_buf_len_ = data->pickle()->size(); entry_->disk_entry->WriteData(kResponseInfoIndex, 0, data.get(), io_buf_len_, base::DoNothing(), true); } bool HttpCache::Writers::ShouldTruncate() { // Don't set the flag for sparse entries or for entries that cannot be // resumed. if (!should_keep_entry_ || partial_do_not_truncate_) return false; // Check the response headers for strong validators. // Note that if this is a 206, content-length was already fixed after calling // PartialData::ResponseHeadersOK(). if (response_info_truncation_.headers->GetContentLength() <= 0 || response_info_truncation_.headers->HasHeaderValue("Accept-Ranges", "none") || !response_info_truncation_.headers->HasStrongValidators()) { should_keep_entry_ = false; return false; } // Double check that there is something worth keeping. int current_size = entry_->disk_entry->GetDataSize(kResponseContentIndex); if (!current_size) { should_keep_entry_ = false; return false; } if (response_info_truncation_.headers->HasHeader("Content-Encoding")) { should_keep_entry_ = false; return false; } int64_t content_length = response_info_truncation_.headers->GetContentLength(); if (content_length >= 0 && content_length <= current_size) return false; return true; } LoadState HttpCache::Writers::GetLoadState() const { if (network_transaction_) return network_transaction_->GetLoadState(); return LOAD_STATE_IDLE; } HttpCache::Writers::WaitingForRead::WaitingForRead( scoped_refptr buf, int len, CompletionOnceCallback consumer_callback) : read_buf(std::move(buf)), read_buf_len(len), write_len(0), callback(std::move(consumer_callback)) { DCHECK(read_buf); DCHECK_GT(len, 0); DCHECK(!callback.is_null()); } HttpCache::Writers::WaitingForRead::~WaitingForRead() = default; HttpCache::Writers::WaitingForRead::WaitingForRead(WaitingForRead&&) = default; int HttpCache::Writers::DoLoop(int result) { DCHECK_NE(State::UNSET, next_state_); DCHECK_NE(State::NONE, next_state_); int rv = result; do { State state = next_state_; next_state_ = State::UNSET; switch (state) { case State::NETWORK_READ: DCHECK_EQ(OK, rv); rv = DoNetworkRead(); break; case State::NETWORK_READ_COMPLETE: rv = DoNetworkReadComplete(rv); break; case State::CACHE_WRITE_DATA: rv = DoCacheWriteData(rv); break; case State::CACHE_WRITE_DATA_COMPLETE: rv = DoCacheWriteDataComplete(rv); break; case State::UNSET: NOTREACHED() << "bad state"; rv = ERR_FAILED; break; case State::NONE: // Do Nothing. break; } } while (next_state_ != State::NONE && rv != ERR_IO_PENDING); if (next_state_ != State::NONE) { if (rv != ERR_IO_PENDING && !callback_.is_null()) { std::move(callback_).Run(rv); } return rv; } // Save the callback as |this| may be destroyed when |cache_callback_| is run. // Note that |callback_| is intentionally reset even if it is not run. CompletionOnceCallback callback = std::move(callback_); read_buf_ = NULL; DCHECK(!all_writers_.empty() || cache_callback_); if (cache_callback_) std::move(cache_callback_).Run(); // |this| may have been destroyed in the |cache_callback_|. if (rv != ERR_IO_PENDING && !callback.is_null()) std::move(callback).Run(rv); return rv; } int HttpCache::Writers::DoNetworkRead() { DCHECK(network_transaction_); next_state_ = State::NETWORK_READ_COMPLETE; CompletionOnceCallback io_callback = base::BindOnce( &HttpCache::Writers::OnIOComplete, weak_factory_.GetWeakPtr()); return network_transaction_->Read(read_buf_.get(), io_buf_len_, std::move(io_callback)); } int HttpCache::Writers::DoNetworkReadComplete(int result) { if (result < 0) { next_state_ = State::NONE; OnNetworkReadFailure(result); return result; } next_state_ = State::CACHE_WRITE_DATA; return result; } void HttpCache::Writers::OnNetworkReadFailure(int result) { ProcessFailure(result); if (active_transaction_) EraseTransaction(active_transaction_, result); active_transaction_ = nullptr; if (ShouldTruncate()) TruncateEntry(); SetCacheCallback(false, TransactionSet()); } int HttpCache::Writers::DoCacheWriteData(int num_bytes) { next_state_ = State::CACHE_WRITE_DATA_COMPLETE; write_len_ = num_bytes; if (!num_bytes || network_read_only_) return num_bytes; int current_size = entry_->disk_entry->GetDataSize(kResponseContentIndex); CompletionOnceCallback io_callback = base::BindOnce( &HttpCache::Writers::OnIOComplete, weak_factory_.GetWeakPtr()); int rv = 0; PartialData* partial = nullptr; // The active transaction must be alive if this is a partial request, as // partial requests are exclusive and hence will always be the active // transaction. // TODO(shivanisha): When partial requests support parallel writing, this // assumption will not be true. if (active_transaction_) partial = all_writers_.find(active_transaction_)->second.partial; if (!partial) { rv = entry_->disk_entry->WriteData(kResponseContentIndex, current_size, read_buf_.get(), num_bytes, std::move(io_callback), true); } else { rv = partial->CacheWrite(entry_->disk_entry, read_buf_.get(), num_bytes, std::move(io_callback)); } return rv; } int HttpCache::Writers::DoCacheWriteDataComplete(int result) { DCHECK(!all_writers_.empty()); next_state_ = State::NONE; if (result != write_len_) { // Note that it is possible for cache write to fail if the size of the file // exceeds the per-file limit. OnCacheWriteFailure(); // |active_transaction_| can continue reading from the network. result = write_len_; } else { OnDataReceived(result); } return result; } void HttpCache::Writers::OnDataReceived(int result) { DCHECK(!all_writers_.empty()); auto it = all_writers_.find(active_transaction_); bool is_partial = active_transaction_ != nullptr && it->second.partial != nullptr; // Partial transaction will process the result, return from here. // This is done because partial requests handling require an awareness of both // headers and body state machines as they might have to go to the headers // phase for the next range, so it cannot be completely handled here. if (is_partial) { active_transaction_ = nullptr; return; } if (result == 0) { // Check if the response is actually completed or if not, attempt to mark // the entry as truncated in OnNetworkReadFailure. int current_size = entry_->disk_entry->GetDataSize(kResponseContentIndex); DCHECK(network_transaction_); const HttpResponseInfo* response_info = network_transaction_->GetResponseInfo(); int64_t content_length = response_info->headers->GetContentLength(); if (content_length >= 0 && content_length > current_size) { OnNetworkReadFailure(result); return; } if (active_transaction_) EraseTransaction(active_transaction_, result); active_transaction_ = nullptr; CompleteWaitingForReadTransactions(write_len_); // Invoke entry processing. DCHECK(ContainsOnlyIdleWriters()); TransactionSet make_readers; for (auto& writer : all_writers_) make_readers.insert(writer.first); all_writers_.clear(); SetCacheCallback(true, make_readers); return; } // Notify waiting_for_read_. Tasks will be posted for all the // transactions. CompleteWaitingForReadTransactions(write_len_); active_transaction_ = nullptr; } void HttpCache::Writers::OnCacheWriteFailure() { DLOG(ERROR) << "failed to write response data to cache"; ProcessFailure(ERR_CACHE_WRITE_FAILURE); // Now writers will only be reading from the network. network_read_only_ = true; active_transaction_ = nullptr; should_keep_entry_ = false; if (all_writers_.empty()) { SetCacheCallback(false, TransactionSet()); } else { cache_->WritersDoomEntryRestartTransactions(entry_); } } void HttpCache::Writers::CompleteWaitingForReadTransactions(int result) { for (auto it = waiting_for_read_.begin(); it != waiting_for_read_.end();) { Transaction* transaction = it->first; int callback_result = result; if (result >= 0) { // success // Save the data in the waiting transaction's read buffer. it->second.write_len = std::min(it->second.read_buf_len, result); memcpy(it->second.read_buf->data(), read_buf_->data(), it->second.write_len); callback_result = it->second.write_len; } // Post task to notify transaction. base::ThreadTaskRunnerHandle::Get()->PostTask( FROM_HERE, base::BindOnce(std::move(it->second.callback), callback_result)); it = waiting_for_read_.erase(it); // If its response completion or failure, this transaction needs to be // removed from writers. if (result <= 0) EraseTransaction(transaction, result); } } void HttpCache::Writers::RemoveIdleWriters(int result) { // Since this is only for idle transactions, waiting_for_read_ // should be empty. DCHECK(waiting_for_read_.empty()); for (auto it = all_writers_.begin(); it != all_writers_.end();) { Transaction* transaction = it->first; if (transaction == active_transaction_) { it++; continue; } it = EraseTransaction(it, result); } } void HttpCache::Writers::SetCacheCallback(bool success, const TransactionSet& make_readers) { DCHECK(!cache_callback_); cache_callback_ = base::BindOnce(&HttpCache::WritersDoneWritingToEntry, cache_->GetWeakPtr(), entry_, success, should_keep_entry_, make_readers); } void HttpCache::Writers::OnIOComplete(int result) { DoLoop(result); } } // namespace net