// Copyright (c) 2012 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/disk_cache/disk_cache_test_base.h" #include #include "base/files/file_util.h" #include "base/path_service.h" #include "base/run_loop.h" #include "base/single_thread_task_runner.h" #include "base/threading/platform_thread.h" #include "base/threading/thread_task_runner_handle.h" #include "net/base/io_buffer.h" #include "net/base/net_errors.h" #include "net/base/test_completion_callback.h" #include "net/disk_cache/backend_cleanup_tracker.h" #include "net/disk_cache/blockfile/backend_impl.h" #include "net/disk_cache/cache_util.h" #include "net/disk_cache/disk_cache.h" #include "net/disk_cache/disk_cache_test_util.h" #include "net/disk_cache/memory/mem_backend_impl.h" #include "net/disk_cache/simple/simple_backend_impl.h" #include "net/disk_cache/simple/simple_file_tracker.h" #include "net/disk_cache/simple/simple_index.h" #include "net/test/gtest_util.h" #include "testing/gmock/include/gmock/gmock.h" #include "testing/gtest/include/gtest/gtest.h" using net::test::IsOk; DiskCacheTest::DiskCacheTest() { CHECK(temp_dir_.CreateUniqueTempDir()); cache_path_ = temp_dir_.GetPath(); } DiskCacheTest::~DiskCacheTest() = default; bool DiskCacheTest::CopyTestCache(const std::string& name) { base::FilePath path; base::PathService::Get(base::DIR_SOURCE_ROOT, &path); path = path.AppendASCII("net"); path = path.AppendASCII("data"); path = path.AppendASCII("cache_tests"); path = path.AppendASCII(name); if (!CleanupCacheDir()) return false; return base::CopyDirectory(path, cache_path_, false); } bool DiskCacheTest::CleanupCacheDir() { return DeleteCache(cache_path_); } void DiskCacheTest::TearDown() { base::RunLoop().RunUntilIdle(); } DiskCacheTestWithCache::TestIterator::TestIterator( std::unique_ptr iterator) : iterator_(std::move(iterator)) {} DiskCacheTestWithCache::TestIterator::~TestIterator() = default; int DiskCacheTestWithCache::TestIterator::OpenNextEntry( disk_cache::Entry** next_entry) { net::TestCompletionCallback cb; int rv = iterator_->OpenNextEntry(next_entry, cb.callback()); return cb.GetResult(rv); } DiskCacheTestWithCache::DiskCacheTestWithCache() : cache_impl_(NULL), simple_cache_impl_(NULL), mem_cache_(NULL), mask_(0), size_(0), type_(net::DISK_CACHE), memory_only_(false), simple_cache_mode_(false), simple_cache_wait_for_index_(true), force_creation_(false), new_eviction_(false), first_cleanup_(true), integrity_(true), use_current_thread_(false) {} DiskCacheTestWithCache::~DiskCacheTestWithCache() = default; void DiskCacheTestWithCache::InitCache() { if (memory_only_) InitMemoryCache(); else InitDiskCache(); ASSERT_TRUE(NULL != cache_); if (first_cleanup_) ASSERT_EQ(0, cache_->GetEntryCount()); } // We are expected to leak memory when simulating crashes. void DiskCacheTestWithCache::SimulateCrash() { ASSERT_TRUE(!memory_only_); net::TestCompletionCallback cb; int rv = cache_impl_->FlushQueueForTest(cb.callback()); ASSERT_THAT(cb.GetResult(rv), IsOk()); cache_impl_->ClearRefCountForTest(); cache_.reset(); EXPECT_TRUE(CheckCacheIntegrity(cache_path_, new_eviction_, size_, mask_)); CreateBackend(disk_cache::kNoRandom); } void DiskCacheTestWithCache::SetTestMode() { ASSERT_TRUE(!memory_only_); cache_impl_->SetUnitTestMode(); } void DiskCacheTestWithCache::SetMaxSize(int size) { size_ = size; if (simple_cache_impl_) EXPECT_TRUE(simple_cache_impl_->SetMaxSize(size)); if (cache_impl_) EXPECT_TRUE(cache_impl_->SetMaxSize(size)); if (mem_cache_) EXPECT_TRUE(mem_cache_->SetMaxSize(size)); } int DiskCacheTestWithCache::OpenEntry(const std::string& key, disk_cache::Entry** entry) { net::TestCompletionCallback cb; int rv = cache_->OpenEntry(key, entry, cb.callback()); return cb.GetResult(rv); } int DiskCacheTestWithCache::CreateEntry(const std::string& key, disk_cache::Entry** entry) { net::TestCompletionCallback cb; int rv = cache_->CreateEntry(key, entry, cb.callback()); return cb.GetResult(rv); } int DiskCacheTestWithCache::DoomEntry(const std::string& key) { net::TestCompletionCallback cb; int rv = cache_->DoomEntry(key, cb.callback()); return cb.GetResult(rv); } int DiskCacheTestWithCache::DoomAllEntries() { net::TestCompletionCallback cb; int rv = cache_->DoomAllEntries(cb.callback()); return cb.GetResult(rv); } int DiskCacheTestWithCache::DoomEntriesBetween(const base::Time initial_time, const base::Time end_time) { net::TestCompletionCallback cb; int rv = cache_->DoomEntriesBetween(initial_time, end_time, cb.callback()); return cb.GetResult(rv); } int DiskCacheTestWithCache::DoomEntriesSince(const base::Time initial_time) { net::TestCompletionCallback cb; int rv = cache_->DoomEntriesSince(initial_time, cb.callback()); return cb.GetResult(rv); } int DiskCacheTestWithCache::CalculateSizeOfAllEntries() { net::TestCompletionCallback cb; int rv = cache_->CalculateSizeOfAllEntries(cb.callback()); return cb.GetResult(rv); } int DiskCacheTestWithCache::CalculateSizeOfEntriesBetween( const base::Time initial_time, const base::Time end_time) { net::TestCompletionCallback cb; int rv = cache_->CalculateSizeOfEntriesBetween(initial_time, end_time, cb.callback()); return cb.GetResult(rv); } std::unique_ptr DiskCacheTestWithCache::CreateIterator() { return std::unique_ptr( new TestIterator(cache_->CreateIterator())); } void DiskCacheTestWithCache::FlushQueueForTest() { if (memory_only_ || !cache_impl_) return; net::TestCompletionCallback cb; int rv = cache_impl_->FlushQueueForTest(cb.callback()); EXPECT_THAT(cb.GetResult(rv), IsOk()); } void DiskCacheTestWithCache::RunTaskForTest(const base::Closure& closure) { if (memory_only_ || !cache_impl_) { closure.Run(); return; } net::TestCompletionCallback cb; int rv = cache_impl_->RunTaskForTest(closure, cb.callback()); EXPECT_THAT(cb.GetResult(rv), IsOk()); } int DiskCacheTestWithCache::ReadData(disk_cache::Entry* entry, int index, int offset, net::IOBuffer* buf, int len) { net::TestCompletionCallback cb; int rv = entry->ReadData(index, offset, buf, len, cb.callback()); return cb.GetResult(rv); } int DiskCacheTestWithCache::WriteData(disk_cache::Entry* entry, int index, int offset, net::IOBuffer* buf, int len, bool truncate) { net::TestCompletionCallback cb; int rv = entry->WriteData(index, offset, buf, len, cb.callback(), truncate); return cb.GetResult(rv); } int DiskCacheTestWithCache::ReadSparseData(disk_cache::Entry* entry, int64_t offset, net::IOBuffer* buf, int len) { net::TestCompletionCallback cb; int rv = entry->ReadSparseData(offset, buf, len, cb.callback()); return cb.GetResult(rv); } int DiskCacheTestWithCache::WriteSparseData(disk_cache::Entry* entry, int64_t offset, net::IOBuffer* buf, int len) { net::TestCompletionCallback cb; int rv = entry->WriteSparseData(offset, buf, len, cb.callback()); return cb.GetResult(rv); } void DiskCacheTestWithCache::TrimForTest(bool empty) { RunTaskForTest(base::Bind(&disk_cache::BackendImpl::TrimForTest, base::Unretained(cache_impl_), empty)); } void DiskCacheTestWithCache::TrimDeletedListForTest(bool empty) { RunTaskForTest(base::Bind(&disk_cache::BackendImpl::TrimDeletedListForTest, base::Unretained(cache_impl_), empty)); } void DiskCacheTestWithCache::AddDelay() { if (simple_cache_mode_) { // The simple cache uses second resolution for many timeouts, so it's safest // to advance by at least whole seconds before falling back into the normal // disk cache epsilon advance. const base::Time initial_time = base::Time::Now(); do { base::PlatformThread::YieldCurrentThread(); } while (base::Time::Now() - initial_time < base::TimeDelta::FromSeconds(1)); } base::Time initial = base::Time::Now(); while (base::Time::Now() <= initial) { base::PlatformThread::Sleep(base::TimeDelta::FromMilliseconds(1)); }; } void DiskCacheTestWithCache::TearDown() { RunUntilIdle(); cache_.reset(); if (!memory_only_ && !simple_cache_mode_ && integrity_) { EXPECT_TRUE(CheckCacheIntegrity(cache_path_, new_eviction_, size_, mask_)); } RunUntilIdle(); if (simple_cache_mode_ && simple_file_tracker_) EXPECT_TRUE(simple_file_tracker_->IsEmptyForTesting()); DiskCacheTest::TearDown(); } void DiskCacheTestWithCache::InitMemoryCache() { mem_cache_ = new disk_cache::MemBackendImpl(NULL); cache_.reset(mem_cache_); ASSERT_TRUE(cache_); if (size_) EXPECT_TRUE(mem_cache_->SetMaxSize(size_)); ASSERT_TRUE(mem_cache_->Init()); } void DiskCacheTestWithCache::InitDiskCache() { if (first_cleanup_) ASSERT_TRUE(CleanupCacheDir()); CreateBackend(disk_cache::kNoRandom); } void DiskCacheTestWithCache::CreateBackend(uint32_t flags) { scoped_refptr runner; if (use_current_thread_) runner = base::ThreadTaskRunnerHandle::Get(); else runner = nullptr; // let the backend sort it out. if (simple_cache_mode_) { DCHECK(!use_current_thread_) << "Using current thread unsupported by SimpleCache"; net::TestCompletionCallback cb; // We limit ourselves to 64 fds since OS X by default gives us 256. // (Chrome raises the number on startup, but the test fixture doesn't). if (!simple_file_tracker_) simple_file_tracker_ = std::make_unique(64); std::unique_ptr simple_backend = std::make_unique( cache_path_, /* cleanup_tracker = */ nullptr, simple_file_tracker_.get(), size_, type_, /*net_log = */ nullptr); int rv = simple_backend->Init(cb.callback()); ASSERT_THAT(cb.GetResult(rv), IsOk()); simple_cache_impl_ = simple_backend.get(); cache_ = std::move(simple_backend); if (simple_cache_wait_for_index_) { net::TestCompletionCallback wait_for_index_cb; rv = simple_cache_impl_->index()->ExecuteWhenReady( wait_for_index_cb.callback()); ASSERT_THAT(wait_for_index_cb.GetResult(rv), IsOk()); } return; } if (mask_) cache_impl_ = new disk_cache::BackendImpl(cache_path_, mask_, runner, /* net_log = */ nullptr); else cache_impl_ = new disk_cache::BackendImpl(cache_path_, /* cleanup_tracker = */ nullptr, runner, /* net_log = */ nullptr); cache_.reset(cache_impl_); ASSERT_TRUE(cache_); if (size_) EXPECT_TRUE(cache_impl_->SetMaxSize(size_)); if (new_eviction_) cache_impl_->SetNewEviction(); cache_impl_->SetType(type_); cache_impl_->SetFlags(flags); net::TestCompletionCallback cb; int rv = cache_impl_->Init(cb.callback()); ASSERT_THAT(cb.GetResult(rv), IsOk()); }