blob: 3e9b43bb954929aeb4df4e5452786ed3f61bb1d9 [file] [log] [blame]
// 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 "base/bind_helpers.h"
#include "base/files/file.h"
#include "base/files/file_util.h"
#include "base/memory/memory_pressure_listener.h"
#include "base/metrics/field_trial.h"
#include "base/run_loop.h"
#include "base/sequenced_task_runner.h"
#include "base/strings/string_number_conversions.h"
#include "base/strings/string_split.h"
#include "base/strings/string_util.h"
#include "base/strings/stringprintf.h"
#include "base/task/post_task.h"
#include "base/test/metrics/histogram_tester.h"
#include "base/test/mock_entropy_provider.h"
#include "base/test/scoped_feature_list.h"
#include "base/third_party/dynamic_annotations/dynamic_annotations.h"
#include "base/threading/platform_thread.h"
#include "base/threading/thread_restrictions.h"
#include "base/threading/thread_task_runner_handle.h"
#include "base/trace_event/memory_allocator_dump.h"
#include "base/trace_event/process_memory_dump.h"
#include "base/trace_event/trace_event_argument.h"
#include "build/build_config.h"
#include "net/base/cache_type.h"
#include "net/base/completion_once_callback.h"
#include "net/base/io_buffer.h"
#include "net/base/net_errors.h"
#include "net/base/request_priority.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/blockfile/entry_impl.h"
#include "net/disk_cache/blockfile/experiments.h"
#include "net/disk_cache/blockfile/histogram_macros.h"
#include "net/disk_cache/blockfile/mapped_file.h"
#include "net/disk_cache/cache_util.h"
#include "net/disk_cache/disk_cache_test_base.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_entry_format.h"
#include "net/disk_cache/simple/simple_histogram_enums.h"
#include "net/disk_cache/simple/simple_index.h"
#include "net/disk_cache/simple/simple_synchronous_entry.h"
#include "net/disk_cache/simple/simple_test_util.h"
#include "net/disk_cache/simple/simple_util.h"
#include "net/test/gtest_util.h"
#include "testing/gmock/include/gmock/gmock.h"
#include "testing/gtest/include/gtest/gtest.h"
using net::test::IsError;
using net::test::IsOk;
using testing::Contains;
using testing::Eq;
using testing::Field;
using testing::Contains;
using testing::ByRef;
#if defined(OS_WIN)
#include "base/win/scoped_handle.h"
#include "starboard/memory.h"
#include "starboard/types.h"
#endif
// Provide a BackendImpl object to macros from histogram_macros.h.
#define CACHE_UMA_BACKEND_IMPL_OBJ backend_
using base::Time;
namespace {
const char kExistingEntryKey[] = "existing entry key";
std::unique_ptr<disk_cache::BackendImpl> CreateExistingEntryCache(
const base::FilePath& cache_path) {
net::TestCompletionCallback cb;
std::unique_ptr<disk_cache::BackendImpl> cache(
std::make_unique<disk_cache::BackendImpl>(cache_path,
/* cleanup_tracker = */ nullptr,
/* cache_thread = */ nullptr,
/* net_log = */ nullptr));
int rv = cache->Init(cb.callback());
if (cb.GetResult(rv) != net::OK)
return std::unique_ptr<disk_cache::BackendImpl>();
disk_cache::Entry* entry = NULL;
rv = cache->CreateEntry(kExistingEntryKey, net::HIGHEST, &entry,
cb.callback());
if (cb.GetResult(rv) != net::OK)
return std::unique_ptr<disk_cache::BackendImpl>();
entry->Close();
return cache;
}
#if defined(OS_FUCHSIA)
// Load tests with large numbers of file descriptors perform poorly on
// virtualized test execution environments.
// TODO(807882): Remove this workaround when virtualized test performance
// improves.
const int kLargeNumEntries = 100;
#else
const int kLargeNumEntries = 512;
#endif
} // namespace
// Tests that can run with different types of caches.
class DiskCacheBackendTest : public DiskCacheTestWithCache {
protected:
// Some utility methods:
// Perform IO operations on the cache until there is pending IO.
int GeneratePendingIO(net::TestCompletionCallback* cb);
// Adds 5 sparse entries. |doomed_start| and |doomed_end| if not NULL,
// will be filled with times, used by DoomEntriesSince and DoomEntriesBetween.
// There are 4 entries after doomed_start and 2 after doomed_end.
void InitSparseCache(base::Time* doomed_start, base::Time* doomed_end);
bool CreateSetOfRandomEntries(std::set<std::string>* key_pool);
bool EnumerateAndMatchKeys(int max_to_open,
TestIterator* iter,
std::set<std::string>* keys_to_match,
size_t* count);
// Computes the expected size of entry metadata, i.e. the total size without
// the actual data stored. This depends only on the entry's |key| size.
int GetEntryMetadataSize(std::string key);
// The Simple Backend only tracks the approximate sizes of entries. This
// rounds the exact size appropriately.
int GetRoundedSize(int exact_size);
// Actual tests:
void BackendBasics();
void BackendKeying();
void BackendShutdownWithPendingFileIO(bool fast);
void BackendShutdownWithPendingIO(bool fast);
void BackendShutdownWithPendingCreate(bool fast);
void BackendShutdownWithPendingDoom();
void BackendSetSize();
void BackendLoad();
void BackendChain();
void BackendValidEntry();
void BackendInvalidEntry();
void BackendInvalidEntryRead();
void BackendInvalidEntryWithLoad();
void BackendTrimInvalidEntry();
void BackendTrimInvalidEntry2();
void BackendEnumerations();
void BackendEnumerations2();
void BackendDoomMidEnumeration();
void BackendInvalidEntryEnumeration();
void BackendFixEnumerators();
void BackendDoomRecent();
void BackendDoomBetween();
void BackendCalculateSizeOfAllEntries();
void BackendCalculateSizeOfEntriesBetween();
void BackendTransaction(const std::string& name, int num_entries, bool load);
void BackendRecoverInsert();
void BackendRecoverRemove();
void BackendRecoverWithEviction();
void BackendInvalidEntry2();
void BackendInvalidEntry3();
void BackendInvalidEntry7();
void BackendInvalidEntry8();
void BackendInvalidEntry9(bool eviction);
void BackendInvalidEntry10(bool eviction);
void BackendInvalidEntry11(bool eviction);
void BackendTrimInvalidEntry12();
void BackendDoomAll();
void BackendDoomAll2();
void BackendInvalidRankings();
void BackendInvalidRankings2();
void BackendDisable();
void BackendDisable2();
void BackendDisable3();
void BackendDisable4();
void BackendDisabledAPI();
void BackendEviction();
};
int DiskCacheBackendTest::GeneratePendingIO(net::TestCompletionCallback* cb) {
if (!use_current_thread_ && !simple_cache_mode_) {
ADD_FAILURE();
return net::ERR_FAILED;
}
disk_cache::Entry* entry;
int rv =
cache_->CreateEntry("some key", net::HIGHEST, &entry, cb->callback());
if (cb->GetResult(rv) != net::OK)
return net::ERR_CACHE_CREATE_FAILURE;
const int kSize = 25000;
scoped_refptr<net::IOBuffer> buffer =
base::MakeRefCounted<net::IOBuffer>(kSize);
CacheTestFillBuffer(buffer->data(), kSize, false);
for (int i = 0; i < 10 * 1024 * 1024; i += 64 * 1024) {
// We are using the current thread as the cache thread because we want to
// be able to call directly this method to make sure that the OS (instead
// of us switching thread) is returning IO pending.
if (!simple_cache_mode_) {
rv = static_cast<disk_cache::EntryImpl*>(entry)->WriteDataImpl(
0, i, buffer.get(), kSize, cb->callback(), false);
} else {
rv = entry->WriteData(0, i, buffer.get(), kSize, cb->callback(), false);
}
if (rv == net::ERR_IO_PENDING)
break;
if (rv != kSize)
rv = net::ERR_FAILED;
}
// Don't call Close() to avoid going through the queue or we'll deadlock
// waiting for the operation to finish.
if (!simple_cache_mode_)
static_cast<disk_cache::EntryImpl*>(entry)->Release();
else
entry->Close();
return rv;
}
void DiskCacheBackendTest::InitSparseCache(base::Time* doomed_start,
base::Time* doomed_end) {
InitCache();
const int kSize = 50;
// This must be greater than MemEntryImpl::kMaxSparseEntrySize.
const int kOffset = 10 + 1024 * 1024;
disk_cache::Entry* entry0 = NULL;
disk_cache::Entry* entry1 = NULL;
disk_cache::Entry* entry2 = NULL;
scoped_refptr<net::IOBuffer> buffer =
base::MakeRefCounted<net::IOBuffer>(kSize);
CacheTestFillBuffer(buffer->data(), kSize, false);
ASSERT_THAT(CreateEntry("zeroth", &entry0), IsOk());
ASSERT_EQ(kSize, WriteSparseData(entry0, 0, buffer.get(), kSize));
ASSERT_EQ(kSize,
WriteSparseData(entry0, kOffset + kSize, buffer.get(), kSize));
entry0->Close();
FlushQueueForTest();
AddDelay();
if (doomed_start)
*doomed_start = base::Time::Now();
// Order in rankings list:
// first_part1, first_part2, second_part1, second_part2
ASSERT_THAT(CreateEntry("first", &entry1), IsOk());
ASSERT_EQ(kSize, WriteSparseData(entry1, 0, buffer.get(), kSize));
ASSERT_EQ(kSize,
WriteSparseData(entry1, kOffset + kSize, buffer.get(), kSize));
entry1->Close();
ASSERT_THAT(CreateEntry("second", &entry2), IsOk());
ASSERT_EQ(kSize, WriteSparseData(entry2, 0, buffer.get(), kSize));
ASSERT_EQ(kSize,
WriteSparseData(entry2, kOffset + kSize, buffer.get(), kSize));
entry2->Close();
FlushQueueForTest();
AddDelay();
if (doomed_end)
*doomed_end = base::Time::Now();
// Order in rankings list:
// third_part1, fourth_part1, third_part2, fourth_part2
disk_cache::Entry* entry3 = NULL;
disk_cache::Entry* entry4 = NULL;
ASSERT_THAT(CreateEntry("third", &entry3), IsOk());
ASSERT_EQ(kSize, WriteSparseData(entry3, 0, buffer.get(), kSize));
ASSERT_THAT(CreateEntry("fourth", &entry4), IsOk());
ASSERT_EQ(kSize, WriteSparseData(entry4, 0, buffer.get(), kSize));
ASSERT_EQ(kSize,
WriteSparseData(entry3, kOffset + kSize, buffer.get(), kSize));
ASSERT_EQ(kSize,
WriteSparseData(entry4, kOffset + kSize, buffer.get(), kSize));
entry3->Close();
entry4->Close();
FlushQueueForTest();
AddDelay();
}
// Creates entries based on random keys. Stores these keys in |key_pool|.
bool DiskCacheBackendTest::CreateSetOfRandomEntries(
std::set<std::string>* key_pool) {
const int kNumEntries = 10;
const int initial_entry_count = cache_->GetEntryCount();
for (int i = 0; i < kNumEntries; ++i) {
std::string key = GenerateKey(true);
disk_cache::Entry* entry;
if (CreateEntry(key, &entry) != net::OK) {
return false;
}
key_pool->insert(key);
entry->Close();
}
return key_pool->size() ==
static_cast<size_t>(cache_->GetEntryCount() - initial_entry_count);
}
// Performs iteration over the backend and checks that the keys of entries
// opened are in |keys_to_match|, then erases them. Up to |max_to_open| entries
// will be opened, if it is positive. Otherwise, iteration will continue until
// OpenNextEntry stops returning net::OK.
bool DiskCacheBackendTest::EnumerateAndMatchKeys(
int max_to_open,
TestIterator* iter,
std::set<std::string>* keys_to_match,
size_t* count) {
disk_cache::Entry* entry;
if (!iter)
return false;
while (iter->OpenNextEntry(&entry) == net::OK) {
if (!entry)
return false;
EXPECT_EQ(1U, keys_to_match->erase(entry->GetKey()));
entry->Close();
++(*count);
if (max_to_open >= 0 && static_cast<int>(*count) >= max_to_open)
break;
};
return true;
}
int DiskCacheBackendTest::GetEntryMetadataSize(std::string key) {
// For blockfile and memory backends, it is just the key size.
if (!simple_cache_mode_)
return key.size();
// For the simple cache, we must add the file header and EOF, and that for
// every stream.
return disk_cache::kSimpleEntryStreamCount *
(sizeof(disk_cache::SimpleFileHeader) +
sizeof(disk_cache::SimpleFileEOF) + key.size());
}
int DiskCacheBackendTest::GetRoundedSize(int exact_size) {
if (!simple_cache_mode_)
return exact_size;
return (exact_size + 255) & 0xFFFFFF00;
}
void DiskCacheBackendTest::BackendBasics() {
InitCache();
disk_cache::Entry *entry1 = NULL, *entry2 = NULL;
EXPECT_NE(net::OK, OpenEntry("the first key", &entry1));
ASSERT_THAT(CreateEntry("the first key", &entry1), IsOk());
ASSERT_TRUE(NULL != entry1);
entry1->Close();
entry1 = NULL;
ASSERT_THAT(OpenEntry("the first key", &entry1), IsOk());
ASSERT_TRUE(NULL != entry1);
entry1->Close();
entry1 = NULL;
EXPECT_NE(net::OK, CreateEntry("the first key", &entry1));
ASSERT_THAT(OpenEntry("the first key", &entry1), IsOk());
EXPECT_NE(net::OK, OpenEntry("some other key", &entry2));
ASSERT_THAT(CreateEntry("some other key", &entry2), IsOk());
ASSERT_TRUE(NULL != entry1);
ASSERT_TRUE(NULL != entry2);
EXPECT_EQ(2, cache_->GetEntryCount());
disk_cache::Entry* entry3 = NULL;
ASSERT_THAT(OpenEntry("some other key", &entry3), IsOk());
ASSERT_TRUE(NULL != entry3);
EXPECT_TRUE(entry2 == entry3);
EXPECT_THAT(DoomEntry("some other key"), IsOk());
EXPECT_EQ(1, cache_->GetEntryCount());
entry1->Close();
entry2->Close();
entry3->Close();
EXPECT_THAT(DoomEntry("the first key"), IsOk());
EXPECT_EQ(0, cache_->GetEntryCount());
ASSERT_THAT(CreateEntry("the first key", &entry1), IsOk());
ASSERT_THAT(CreateEntry("some other key", &entry2), IsOk());
entry1->Doom();
entry1->Close();
EXPECT_THAT(DoomEntry("some other key"), IsOk());
EXPECT_EQ(0, cache_->GetEntryCount());
entry2->Close();
}
TEST_F(DiskCacheBackendTest, Basics) {
BackendBasics();
}
TEST_F(DiskCacheBackendTest, NewEvictionBasics) {
SetNewEviction();
BackendBasics();
}
TEST_F(DiskCacheBackendTest, MemoryOnlyBasics) {
SetMemoryOnlyMode();
BackendBasics();
}
TEST_F(DiskCacheBackendTest, AppCacheBasics) {
SetCacheType(net::APP_CACHE);
BackendBasics();
}
TEST_F(DiskCacheBackendTest, ShaderCacheBasics) {
SetCacheType(net::SHADER_CACHE);
BackendBasics();
}
void DiskCacheBackendTest::BackendKeying() {
InitCache();
const char kName1[] = "the first key";
const char kName2[] = "the first Key";
disk_cache::Entry *entry1, *entry2;
ASSERT_THAT(CreateEntry(kName1, &entry1), IsOk());
ASSERT_THAT(CreateEntry(kName2, &entry2), IsOk());
EXPECT_TRUE(entry1 != entry2) << "Case sensitive";
entry2->Close();
char buffer[30];
base::strlcpy(buffer, kName1, arraysize(buffer));
ASSERT_THAT(OpenEntry(buffer, &entry2), IsOk());
EXPECT_TRUE(entry1 == entry2);
entry2->Close();
base::strlcpy(buffer + 1, kName1, arraysize(buffer) - 1);
ASSERT_THAT(OpenEntry(buffer + 1, &entry2), IsOk());
EXPECT_TRUE(entry1 == entry2);
entry2->Close();
base::strlcpy(buffer + 3, kName1, arraysize(buffer) - 3);
ASSERT_THAT(OpenEntry(buffer + 3, &entry2), IsOk());
EXPECT_TRUE(entry1 == entry2);
entry2->Close();
// Now verify long keys.
char buffer2[20000];
memset(buffer2, 's', sizeof(buffer2));
buffer2[1023] = '\0';
ASSERT_EQ(net::OK, CreateEntry(buffer2, &entry2)) << "key on block file";
entry2->Close();
buffer2[1023] = 'g';
buffer2[19999] = '\0';
ASSERT_EQ(net::OK, CreateEntry(buffer2, &entry2)) << "key on external file";
entry2->Close();
entry1->Close();
}
TEST_F(DiskCacheBackendTest, Keying) {
BackendKeying();
}
TEST_F(DiskCacheBackendTest, NewEvictionKeying) {
SetNewEviction();
BackendKeying();
}
TEST_F(DiskCacheBackendTest, MemoryOnlyKeying) {
SetMemoryOnlyMode();
BackendKeying();
}
TEST_F(DiskCacheBackendTest, AppCacheKeying) {
SetCacheType(net::APP_CACHE);
BackendKeying();
}
TEST_F(DiskCacheBackendTest, ShaderCacheKeying) {
SetCacheType(net::SHADER_CACHE);
BackendKeying();
}
TEST_F(DiskCacheTest, CreateBackend) {
net::TestCompletionCallback cb;
{
ASSERT_TRUE(CleanupCacheDir());
// Test the private factory method(s).
std::unique_ptr<disk_cache::Backend> cache;
cache = disk_cache::MemBackendImpl::CreateBackend(0, NULL);
ASSERT_TRUE(cache.get());
cache.reset();
// Now test the public API.
int rv = disk_cache::CreateCacheBackend(
net::DISK_CACHE, net::CACHE_BACKEND_DEFAULT, cache_path_, 0, false,
NULL, &cache, cb.callback());
ASSERT_THAT(cb.GetResult(rv), IsOk());
ASSERT_TRUE(cache.get());
cache.reset();
rv = disk_cache::CreateCacheBackend(
net::MEMORY_CACHE, net::CACHE_BACKEND_DEFAULT, base::FilePath(), 0,
false, NULL, &cache, cb.callback());
ASSERT_THAT(cb.GetResult(rv), IsOk());
ASSERT_TRUE(cache.get());
cache.reset();
}
base::RunLoop().RunUntilIdle();
}
TEST_F(DiskCacheTest, MemBackendPostCleanupCallback) {
net::TestCompletionCallback cb;
net::TestClosure on_cleanup;
std::unique_ptr<disk_cache::Backend> cache;
int rv = disk_cache::CreateCacheBackend(
net::MEMORY_CACHE, net::CACHE_BACKEND_DEFAULT, base::FilePath(), 0, false,
nullptr, &cache, on_cleanup.closure(), cb.callback());
ASSERT_THAT(cb.GetResult(rv), IsOk());
ASSERT_TRUE(cache.get());
// The callback should be posted after backend is destroyed.
base::RunLoop().RunUntilIdle();
EXPECT_FALSE(on_cleanup.have_result());
cache.reset();
EXPECT_FALSE(on_cleanup.have_result());
base::RunLoop().RunUntilIdle();
EXPECT_TRUE(on_cleanup.have_result());
}
TEST_F(DiskCacheTest, CreateBackendDouble) {
// Make sure that creation for the second backend for same path happens
// after the first one completes.
net::TestCompletionCallback cb, cb2;
std::unique_ptr<disk_cache::Backend> cache, cache2;
int rv = disk_cache::CreateCacheBackend(
net::APP_CACHE, net::CACHE_BACKEND_DEFAULT, cache_path_, 0, false,
nullptr, &cache, cb.callback());
int rv2 = disk_cache::CreateCacheBackend(
net::APP_CACHE, net::CACHE_BACKEND_DEFAULT, cache_path_, 0, false,
nullptr, &cache2, cb2.callback());
EXPECT_THAT(cb.GetResult(rv), IsOk());
EXPECT_TRUE(cache.get());
disk_cache::FlushCacheThreadForTesting();
// No cache 2 yet.
EXPECT_EQ(net::ERR_IO_PENDING, rv2);
EXPECT_FALSE(cb2.have_result());
cache.reset();
// Now cache2 should exist.
EXPECT_THAT(cb2.GetResult(rv2), IsOk());
EXPECT_TRUE(cache2.get());
}
TEST_F(DiskCacheBackendTest, CreateBackendDoubleOpenEntry) {
// Demonstrate the creation sequencing with an open entry. This is done
// with SimpleCache since the block-file cache cancels most of I/O on
// destruction and blocks for what it can't cancel.
// Don't try to sanity-check things as a blockfile cache
SetSimpleCacheMode();
// Make sure that creation for the second backend for same path happens
// after the first one completes, and all of its ops complete.
net::TestCompletionCallback cb, cb2;
std::unique_ptr<disk_cache::Backend> cache, cache2;
int rv = disk_cache::CreateCacheBackend(
net::APP_CACHE, net::CACHE_BACKEND_SIMPLE, cache_path_, 0, false, nullptr,
&cache, cb.callback());
int rv2 = disk_cache::CreateCacheBackend(
net::APP_CACHE, net::CACHE_BACKEND_SIMPLE, cache_path_, 0, false, nullptr,
&cache2, cb2.callback());
EXPECT_THAT(cb.GetResult(rv), IsOk());
ASSERT_TRUE(cache.get());
disk_cache::FlushCacheThreadForTesting();
// No cache 2 yet.
EXPECT_EQ(net::ERR_IO_PENDING, rv2);
EXPECT_FALSE(cb2.have_result());
disk_cache::Entry* entry = nullptr;
rv = cache->CreateEntry("key", net::HIGHEST, &entry, cb.callback());
ASSERT_EQ(net::OK, cb.GetResult(rv));
cache.reset();
// Still doesn't exist.
EXPECT_FALSE(cb2.have_result());
entry->Close();
// Now should exist.
EXPECT_THAT(cb2.GetResult(rv2), IsOk());
EXPECT_TRUE(cache2.get());
}
TEST_F(DiskCacheBackendTest, CreateBackendPostCleanup) {
// Test for the explicit PostCleanupCallback parameter to CreateCacheBackend.
// Extravagant size payload to make reproducing races easier.
const int kBufSize = 256 * 1024;
scoped_refptr<net::IOBuffer> buffer =
base::MakeRefCounted<net::IOBuffer>(kBufSize);
CacheTestFillBuffer(buffer->data(), kBufSize, true);
SetSimpleCacheMode();
CleanupCacheDir();
base::RunLoop run_loop;
net::TestCompletionCallback cb;
std::unique_ptr<disk_cache::Backend> cache;
int rv = disk_cache::CreateCacheBackend(
net::APP_CACHE, net::CACHE_BACKEND_SIMPLE, cache_path_, 0, false, nullptr,
&cache, run_loop.QuitClosure(), cb.callback());
EXPECT_THAT(cb.GetResult(rv), IsOk());
ASSERT_TRUE(cache.get());
disk_cache::Entry* entry = nullptr;
rv = cache->CreateEntry("key", net::HIGHEST, &entry, cb.callback());
ASSERT_EQ(net::OK, cb.GetResult(rv));
EXPECT_EQ(kBufSize, WriteData(entry, 0, 0, buffer.get(), kBufSize, false));
entry->Close();
cache.reset();
// Wait till the post-cleanup callback.
run_loop.Run();
// All of the payload should be on disk, despite stream 0 being written
// back in the async Close()
base::FilePath entry_path = cache_path_.AppendASCII(
disk_cache::simple_util::GetFilenameFromKeyAndFileIndex("key", 0));
int64_t size = 0;
EXPECT_TRUE(base::GetFileSize(entry_path, &size));
EXPECT_GT(size, kBufSize);
}
// Tests that |BackendImpl| fails to initialize with a missing file.
TEST_F(DiskCacheBackendTest, CreateBackend_MissingFile) {
ASSERT_TRUE(CopyTestCache("bad_entry"));
base::FilePath filename = cache_path_.AppendASCII("data_1");
base::DeleteFile(filename, false);
net::TestCompletionCallback cb;
bool prev = base::ThreadRestrictions::SetIOAllowed(false);
std::unique_ptr<disk_cache::BackendImpl> cache(
std::make_unique<disk_cache::BackendImpl>(cache_path_, nullptr, nullptr,
nullptr));
int rv = cache->Init(cb.callback());
EXPECT_THAT(cb.GetResult(rv), IsError(net::ERR_FAILED));
base::ThreadRestrictions::SetIOAllowed(prev);
cache.reset();
DisableIntegrityCheck();
}
TEST_F(DiskCacheBackendTest, MemCacheMemoryDump) {
SetMemoryOnlyMode();
BackendBasics();
base::trace_event::MemoryDumpArgs args = {
base::trace_event::MemoryDumpLevelOfDetail::BACKGROUND};
base::trace_event::ProcessMemoryDump pmd(args);
base::trace_event::MemoryAllocatorDump* parent =
pmd.CreateAllocatorDump("net/url_request_context/main/0x123/http_cache");
ASSERT_LT(0u, cache_->DumpMemoryStats(&pmd, parent->absolute_name()));
EXPECT_EQ(2u, pmd.allocator_dumps().size());
const base::trace_event::MemoryAllocatorDump* sub_dump =
pmd.GetAllocatorDump(parent->absolute_name() + "/memory_backend");
ASSERT_NE(nullptr, sub_dump);
using MADEntry = base::trace_event::MemoryAllocatorDump::Entry;
const std::vector<MADEntry>& entries = sub_dump->entries();
ASSERT_THAT(
entries,
Contains(Field(&MADEntry::name,
Eq(base::trace_event::MemoryAllocatorDump::kNameSize))));
ASSERT_THAT(entries,
Contains(Field(&MADEntry::name, Eq("mem_backend_max_size"))));
ASSERT_THAT(entries,
Contains(Field(&MADEntry::name, Eq("mem_backend_size"))));
}
TEST_F(DiskCacheBackendTest, SimpleCacheMemoryDump) {
simple_cache_mode_ = true;
BackendBasics();
base::trace_event::MemoryDumpArgs args = {
base::trace_event::MemoryDumpLevelOfDetail::BACKGROUND};
base::trace_event::ProcessMemoryDump pmd(args);
base::trace_event::MemoryAllocatorDump* parent =
pmd.CreateAllocatorDump("net/url_request_context/main/0x123/http_cache");
ASSERT_LT(0u, cache_->DumpMemoryStats(&pmd, parent->absolute_name()));
EXPECT_EQ(2u, pmd.allocator_dumps().size());
const base::trace_event::MemoryAllocatorDump* sub_dump =
pmd.GetAllocatorDump(parent->absolute_name() + "/simple_backend");
ASSERT_NE(nullptr, sub_dump);
using MADEntry = base::trace_event::MemoryAllocatorDump::Entry;
const std::vector<MADEntry>& entries = sub_dump->entries();
ASSERT_THAT(entries,
ElementsAre(Field(
&MADEntry::name,
Eq(base::trace_event::MemoryAllocatorDump::kNameSize))));
}
TEST_F(DiskCacheBackendTest, BlockFileCacheMemoryDump) {
// TODO(jkarlin): If the blockfile cache gets memory dump support, update
// this test.
BackendBasics();
base::trace_event::MemoryDumpArgs args = {
base::trace_event::MemoryDumpLevelOfDetail::BACKGROUND};
base::trace_event::ProcessMemoryDump pmd(args);
base::trace_event::MemoryAllocatorDump* parent =
pmd.CreateAllocatorDump("net/url_request_context/main/0x123/http_cache");
ASSERT_EQ(0u, cache_->DumpMemoryStats(&pmd, parent->absolute_name()));
EXPECT_EQ(1u, pmd.allocator_dumps().size());
}
TEST_F(DiskCacheBackendTest, MemoryListensToMemoryPressure) {
const int kLimit = 16 * 1024;
const int kEntrySize = 256;
SetMaxSize(kLimit);
SetMemoryOnlyMode();
InitCache();
// Fill in to about 80-90% full.
scoped_refptr<net::IOBuffer> buffer =
base::MakeRefCounted<net::IOBuffer>(kEntrySize);
CacheTestFillBuffer(buffer->data(), kEntrySize, false);
for (int i = 0; i < 0.9 * (kLimit / kEntrySize); ++i) {
disk_cache::Entry* entry = nullptr;
ASSERT_EQ(net::OK, CreateEntry(base::IntToString(i), &entry));
EXPECT_EQ(kEntrySize,
WriteData(entry, 0, 0, buffer.get(), kEntrySize, true));
entry->Close();
}
EXPECT_GT(CalculateSizeOfAllEntries(), 0.8 * kLimit);
// Signal low-memory of various sorts, and see how small it gets.
base::MemoryPressureListener::NotifyMemoryPressure(
base::MemoryPressureListener::MEMORY_PRESSURE_LEVEL_MODERATE);
base::RunLoop().RunUntilIdle();
EXPECT_LT(CalculateSizeOfAllEntries(), 0.5 * kLimit);
base::MemoryPressureListener::NotifyMemoryPressure(
base::MemoryPressureListener::MEMORY_PRESSURE_LEVEL_CRITICAL);
base::RunLoop().RunUntilIdle();
EXPECT_LT(CalculateSizeOfAllEntries(), 0.1 * kLimit);
}
TEST_F(DiskCacheBackendTest, ExternalFiles) {
InitCache();
// First, let's create a file on the folder.
base::FilePath filename = cache_path_.AppendASCII("f_000001");
const int kSize = 50;
scoped_refptr<net::IOBuffer> buffer1 =
base::MakeRefCounted<net::IOBuffer>(kSize);
CacheTestFillBuffer(buffer1->data(), kSize, false);
ASSERT_EQ(kSize, base::WriteFile(filename, buffer1->data(), kSize));
// Now let's create a file with the cache.
disk_cache::Entry* entry;
ASSERT_THAT(CreateEntry("key", &entry), IsOk());
ASSERT_EQ(0, WriteData(entry, 0, 20000, buffer1.get(), 0, false));
entry->Close();
// And verify that the first file is still there.
scoped_refptr<net::IOBuffer> buffer2(
base::MakeRefCounted<net::IOBuffer>(kSize));
ASSERT_EQ(kSize, base::ReadFile(filename, buffer2->data(), kSize));
EXPECT_EQ(0, memcmp(buffer1->data(), buffer2->data(), kSize));
}
// Tests that we deal with file-level pending operations at destruction time.
void DiskCacheBackendTest::BackendShutdownWithPendingFileIO(bool fast) {
ASSERT_TRUE(CleanupCacheDir());
uint32_t flags = disk_cache::kNoBuffering;
if (!fast)
flags |= disk_cache::kNoRandom;
if (!simple_cache_mode_)
UseCurrentThread();
CreateBackend(flags);
net::TestCompletionCallback cb;
int rv = GeneratePendingIO(&cb);
// The cache destructor will see one pending operation here.
cache_.reset();
if (rv == net::ERR_IO_PENDING) {
if (fast || simple_cache_mode_)
EXPECT_FALSE(cb.have_result());
else
EXPECT_TRUE(cb.have_result());
}
base::RunLoop().RunUntilIdle();
#if !defined(OS_IOS)
// Wait for the actual operation to complete, or we'll keep a file handle that
// may cause issues later. Note that on iOS systems even though this test
// uses a single thread, the actual IO is posted to a worker thread and the
// cache destructor breaks the link to reach cb when the operation completes.
rv = cb.GetResult(rv);
#endif
}
TEST_F(DiskCacheBackendTest, ShutdownWithPendingFileIO) {
BackendShutdownWithPendingFileIO(false);
}
// Here and below, tests that simulate crashes are not compiled in LeakSanitizer
// builds because they contain a lot of intentional memory leaks.
#if !defined(LEAK_SANITIZER)
// We'll be leaking from this test.
TEST_F(DiskCacheBackendTest, ShutdownWithPendingFileIO_Fast) {
// The integrity test sets kNoRandom so there's a version mismatch if we don't
// force new eviction.
SetNewEviction();
BackendShutdownWithPendingFileIO(true);
}
#endif
// See crbug.com/330074
#if !defined(OS_IOS)
// Tests that one cache instance is not affected by another one going away.
TEST_F(DiskCacheBackendTest, MultipleInstancesWithPendingFileIO) {
base::ScopedTempDir store;
ASSERT_TRUE(store.CreateUniqueTempDir());
net::TestCompletionCallback cb;
std::unique_ptr<disk_cache::Backend> extra_cache;
int rv = disk_cache::CreateCacheBackend(
net::DISK_CACHE, net::CACHE_BACKEND_DEFAULT, store.GetPath(), 0, false,
/* net_log = */ nullptr, &extra_cache, cb.callback());
ASSERT_THAT(cb.GetResult(rv), IsOk());
ASSERT_TRUE(extra_cache.get() != NULL);
ASSERT_TRUE(CleanupCacheDir());
SetNewEviction(); // Match the expected behavior for integrity verification.
UseCurrentThread();
CreateBackend(disk_cache::kNoBuffering);
rv = GeneratePendingIO(&cb);
// cache_ has a pending operation, and extra_cache will go away.
extra_cache.reset();
if (rv == net::ERR_IO_PENDING)
EXPECT_FALSE(cb.have_result());
disk_cache::FlushCacheThreadForTesting();
base::RunLoop().RunUntilIdle();
// Wait for the actual operation to complete, or we'll keep a file handle that
// may cause issues later.
rv = cb.GetResult(rv);
}
#endif
// Tests that we deal with background-thread pending operations.
void DiskCacheBackendTest::BackendShutdownWithPendingIO(bool fast) {
net::TestCompletionCallback cb;
{
ASSERT_TRUE(CleanupCacheDir());
uint32_t flags = disk_cache::kNoBuffering;
if (!fast)
flags |= disk_cache::kNoRandom;
CreateBackend(flags);
disk_cache::Entry* entry;
int rv =
cache_->CreateEntry("some key", net::HIGHEST, &entry, cb.callback());
ASSERT_THAT(cb.GetResult(rv), IsOk());
entry->Close();
// The cache destructor will see one pending operation here.
cache_.reset();
}
base::RunLoop().RunUntilIdle();
EXPECT_FALSE(cb.have_result());
}
TEST_F(DiskCacheBackendTest, ShutdownWithPendingIO) {
BackendShutdownWithPendingIO(false);
}
#if !defined(LEAK_SANITIZER)
// We'll be leaking from this test.
TEST_F(DiskCacheBackendTest, ShutdownWithPendingIO_Fast) {
// The integrity test sets kNoRandom so there's a version mismatch if we don't
// force new eviction.
SetNewEviction();
BackendShutdownWithPendingIO(true);
}
#endif
// Tests that we deal with create-type pending operations.
void DiskCacheBackendTest::BackendShutdownWithPendingCreate(bool fast) {
net::TestCompletionCallback cb;
{
ASSERT_TRUE(CleanupCacheDir());
disk_cache::BackendFlags flags =
fast ? disk_cache::kNone : disk_cache::kNoRandom;
CreateBackend(flags);
disk_cache::Entry* entry;
int rv =
cache_->CreateEntry("some key", net::HIGHEST, &entry, cb.callback());
ASSERT_THAT(rv, IsError(net::ERR_IO_PENDING));
cache_.reset();
EXPECT_FALSE(cb.have_result());
}
base::RunLoop().RunUntilIdle();
EXPECT_FALSE(cb.have_result());
}
TEST_F(DiskCacheBackendTest, ShutdownWithPendingCreate) {
BackendShutdownWithPendingCreate(false);
}
#if !defined(LEAK_SANITIZER)
// We'll be leaking an entry from this test.
TEST_F(DiskCacheBackendTest, ShutdownWithPendingCreate_Fast) {
// The integrity test sets kNoRandom so there's a version mismatch if we don't
// force new eviction.
SetNewEviction();
BackendShutdownWithPendingCreate(true);
}
#endif
void DiskCacheBackendTest::BackendShutdownWithPendingDoom() {
net::TestCompletionCallback cb;
{
ASSERT_TRUE(CleanupCacheDir());
disk_cache::BackendFlags flags = disk_cache::kNoRandom;
CreateBackend(flags);
disk_cache::Entry* entry;
int rv =
cache_->CreateEntry("some key", net::HIGHEST, &entry, cb.callback());
ASSERT_THAT(cb.GetResult(rv), IsOk());
entry->Close();
entry = nullptr;
rv = cache_->DoomEntry("some key", net::HIGHEST, cb.callback());
ASSERT_THAT(rv, IsError(net::ERR_IO_PENDING));
cache_.reset();
EXPECT_FALSE(cb.have_result());
}
base::RunLoop().RunUntilIdle();
EXPECT_FALSE(cb.have_result());
}
TEST_F(DiskCacheBackendTest, ShutdownWithPendingDoom) {
BackendShutdownWithPendingDoom();
}
// Disabled on android since this test requires cache creator to create
// blockfile caches.
#if !defined(OS_ANDROID)
TEST_F(DiskCacheTest, TruncatedIndex) {
ASSERT_TRUE(CleanupCacheDir());
base::FilePath index = cache_path_.AppendASCII("index");
ASSERT_EQ(5, base::WriteFile(index, "hello", 5));
net::TestCompletionCallback cb;
std::unique_ptr<disk_cache::Backend> backend;
int rv = disk_cache::CreateCacheBackend(
net::DISK_CACHE, net::CACHE_BACKEND_BLOCKFILE, cache_path_, 0, false,
nullptr, &backend, cb.callback());
ASSERT_NE(net::OK, cb.GetResult(rv));
ASSERT_FALSE(backend);
}
#endif
void DiskCacheBackendTest::BackendSetSize() {
const int cache_size = 0x10000; // 64 kB
SetMaxSize(cache_size);
InitCache();
std::string first("some key");
std::string second("something else");
disk_cache::Entry* entry;
ASSERT_THAT(CreateEntry(first, &entry), IsOk());
scoped_refptr<net::IOBuffer> buffer =
base::MakeRefCounted<net::IOBuffer>(cache_size);
memset(buffer->data(), 0, cache_size);
EXPECT_EQ(cache_size / 10,
WriteData(entry, 0, 0, buffer.get(), cache_size / 10, false))
<< "normal file";
EXPECT_EQ(net::ERR_FAILED,
WriteData(entry, 1, 0, buffer.get(), cache_size / 5, false))
<< "file size above the limit";
// By doubling the total size, we make this file cacheable.
SetMaxSize(cache_size * 2);
EXPECT_EQ(cache_size / 5,
WriteData(entry, 1, 0, buffer.get(), cache_size / 5, false));
// Let's fill up the cache!.
SetMaxSize(cache_size * 10);
EXPECT_EQ(cache_size * 3 / 4,
WriteData(entry, 0, 0, buffer.get(), cache_size * 3 / 4, false));
entry->Close();
FlushQueueForTest();
SetMaxSize(cache_size);
// The cache is 95% full.
ASSERT_THAT(CreateEntry(second, &entry), IsOk());
EXPECT_EQ(cache_size / 10,
WriteData(entry, 0, 0, buffer.get(), cache_size / 10, false));
disk_cache::Entry* entry2;
ASSERT_THAT(CreateEntry("an extra key", &entry2), IsOk());
EXPECT_EQ(cache_size / 10,
WriteData(entry2, 0, 0, buffer.get(), cache_size / 10, false));
entry2->Close(); // This will trigger the cache trim.
EXPECT_NE(net::OK, OpenEntry(first, &entry2));
FlushQueueForTest(); // Make sure that we are done trimming the cache.
FlushQueueForTest(); // We may have posted two tasks to evict stuff.
entry->Close();
ASSERT_THAT(OpenEntry(second, &entry), IsOk());
EXPECT_EQ(cache_size / 10, entry->GetDataSize(0));
entry->Close();
}
TEST_F(DiskCacheBackendTest, SetSize) {
BackendSetSize();
}
TEST_F(DiskCacheBackendTest, NewEvictionSetSize) {
SetNewEviction();
BackendSetSize();
}
TEST_F(DiskCacheBackendTest, MemoryOnlySetSize) {
SetMemoryOnlyMode();
BackendSetSize();
}
void DiskCacheBackendTest::BackendLoad() {
InitCache();
int seed = static_cast<int>(Time::Now().ToInternalValue());
srand(seed);
disk_cache::Entry* entries[kLargeNumEntries];
for (int i = 0; i < kLargeNumEntries; i++) {
std::string key = GenerateKey(true);
ASSERT_THAT(CreateEntry(key, &entries[i]), IsOk());
}
EXPECT_EQ(kLargeNumEntries, cache_->GetEntryCount());
for (int i = 0; i < kLargeNumEntries; i++) {
int source1 = rand() % kLargeNumEntries;
int source2 = rand() % kLargeNumEntries;
disk_cache::Entry* temp = entries[source1];
entries[source1] = entries[source2];
entries[source2] = temp;
}
for (int i = 0; i < kLargeNumEntries; i++) {
disk_cache::Entry* entry;
ASSERT_THAT(OpenEntry(entries[i]->GetKey(), &entry), IsOk());
EXPECT_TRUE(entry == entries[i]);
entry->Close();
entries[i]->Doom();
entries[i]->Close();
}
FlushQueueForTest();
EXPECT_EQ(0, cache_->GetEntryCount());
}
TEST_F(DiskCacheBackendTest, Load) {
// Work with a tiny index table (16 entries)
SetMask(0xf);
SetMaxSize(0x100000);
BackendLoad();
}
TEST_F(DiskCacheBackendTest, NewEvictionLoad) {
SetNewEviction();
// Work with a tiny index table (16 entries)
SetMask(0xf);
SetMaxSize(0x100000);
BackendLoad();
}
TEST_F(DiskCacheBackendTest, MemoryOnlyLoad) {
SetMaxSize(0x100000);
SetMemoryOnlyMode();
BackendLoad();
}
TEST_F(DiskCacheBackendTest, AppCacheLoad) {
SetCacheType(net::APP_CACHE);
// Work with a tiny index table (16 entries)
SetMask(0xf);
SetMaxSize(0x100000);
BackendLoad();
}
TEST_F(DiskCacheBackendTest, ShaderCacheLoad) {
SetCacheType(net::SHADER_CACHE);
// Work with a tiny index table (16 entries)
SetMask(0xf);
SetMaxSize(0x100000);
BackendLoad();
}
// Tests the chaining of an entry to the current head.
void DiskCacheBackendTest::BackendChain() {
SetMask(0x1); // 2-entry table.
SetMaxSize(0x3000); // 12 kB.
InitCache();
disk_cache::Entry* entry;
ASSERT_THAT(CreateEntry("The first key", &entry), IsOk());
entry->Close();
ASSERT_THAT(CreateEntry("The Second key", &entry), IsOk());
entry->Close();
}
TEST_F(DiskCacheBackendTest, Chain) {
BackendChain();
}
TEST_F(DiskCacheBackendTest, NewEvictionChain) {
SetNewEviction();
BackendChain();
}
TEST_F(DiskCacheBackendTest, AppCacheChain) {
SetCacheType(net::APP_CACHE);
BackendChain();
}
TEST_F(DiskCacheBackendTest, ShaderCacheChain) {
SetCacheType(net::SHADER_CACHE);
BackendChain();
}
TEST_F(DiskCacheBackendTest, NewEvictionTrim) {
SetNewEviction();
InitCache();
disk_cache::Entry* entry;
for (int i = 0; i < 100; i++) {
std::string name(base::StringPrintf("Key %d", i));
ASSERT_THAT(CreateEntry(name, &entry), IsOk());
entry->Close();
if (i < 90) {
// Entries 0 to 89 are in list 1; 90 to 99 are in list 0.
ASSERT_THAT(OpenEntry(name, &entry), IsOk());
entry->Close();
}
}
// The first eviction must come from list 1 (10% limit), the second must come
// from list 0.
TrimForTest(false);
EXPECT_NE(net::OK, OpenEntry("Key 0", &entry));
TrimForTest(false);
EXPECT_NE(net::OK, OpenEntry("Key 90", &entry));
// Double check that we still have the list tails.
ASSERT_THAT(OpenEntry("Key 1", &entry), IsOk());
entry->Close();
ASSERT_THAT(OpenEntry("Key 91", &entry), IsOk());
entry->Close();
}
// Before looking for invalid entries, let's check a valid entry.
void DiskCacheBackendTest::BackendValidEntry() {
InitCache();
std::string key("Some key");
disk_cache::Entry* entry;
ASSERT_THAT(CreateEntry(key, &entry), IsOk());
const int kSize = 50;
scoped_refptr<net::IOBuffer> buffer1 =
base::MakeRefCounted<net::IOBuffer>(kSize);
memset(buffer1->data(), 0, kSize);
base::strlcpy(buffer1->data(), "And the data to save", kSize);
EXPECT_EQ(kSize, WriteData(entry, 0, 0, buffer1.get(), kSize, false));
entry->Close();
SimulateCrash();
ASSERT_THAT(OpenEntry(key, &entry), IsOk());
scoped_refptr<net::IOBuffer> buffer2 =
base::MakeRefCounted<net::IOBuffer>(kSize);
memset(buffer2->data(), 0, kSize);
EXPECT_EQ(kSize, ReadData(entry, 0, 0, buffer2.get(), kSize));
entry->Close();
EXPECT_STREQ(buffer1->data(), buffer2->data());
}
TEST_F(DiskCacheBackendTest, ValidEntry) {
BackendValidEntry();
}
TEST_F(DiskCacheBackendTest, NewEvictionValidEntry) {
SetNewEviction();
BackendValidEntry();
}
// The same logic of the previous test (ValidEntry), but this time force the
// entry to be invalid, simulating a crash in the middle.
// We'll be leaking memory from this test.
void DiskCacheBackendTest::BackendInvalidEntry() {
InitCache();
std::string key("Some key");
disk_cache::Entry* entry;
ASSERT_THAT(CreateEntry(key, &entry), IsOk());
const int kSize = 50;
scoped_refptr<net::IOBuffer> buffer =
base::MakeRefCounted<net::IOBuffer>(kSize);
memset(buffer->data(), 0, kSize);
base::strlcpy(buffer->data(), "And the data to save", kSize);
EXPECT_EQ(kSize, WriteData(entry, 0, 0, buffer.get(), kSize, false));
SimulateCrash();
EXPECT_NE(net::OK, OpenEntry(key, &entry));
EXPECT_EQ(0, cache_->GetEntryCount());
}
#if !defined(LEAK_SANITIZER)
// We'll be leaking memory from this test.
TEST_F(DiskCacheBackendTest, InvalidEntry) {
BackendInvalidEntry();
}
// We'll be leaking memory from this test.
TEST_F(DiskCacheBackendTest, NewEvictionInvalidEntry) {
SetNewEviction();
BackendInvalidEntry();
}
// We'll be leaking memory from this test.
TEST_F(DiskCacheBackendTest, AppCacheInvalidEntry) {
SetCacheType(net::APP_CACHE);
BackendInvalidEntry();
}
// We'll be leaking memory from this test.
TEST_F(DiskCacheBackendTest, ShaderCacheInvalidEntry) {
SetCacheType(net::SHADER_CACHE);
BackendInvalidEntry();
}
// Almost the same test, but this time crash the cache after reading an entry.
// We'll be leaking memory from this test.
void DiskCacheBackendTest::BackendInvalidEntryRead() {
InitCache();
std::string key("Some key");
disk_cache::Entry* entry;
ASSERT_THAT(CreateEntry(key, &entry), IsOk());
const int kSize = 50;
scoped_refptr<net::IOBuffer> buffer =
base::MakeRefCounted<net::IOBuffer>(kSize);
memset(buffer->data(), 0, kSize);
base::strlcpy(buffer->data(), "And the data to save", kSize);
EXPECT_EQ(kSize, WriteData(entry, 0, 0, buffer.get(), kSize, false));
entry->Close();
ASSERT_THAT(OpenEntry(key, &entry), IsOk());
EXPECT_EQ(kSize, ReadData(entry, 0, 0, buffer.get(), kSize));
SimulateCrash();
if (type_ == net::APP_CACHE) {
// Reading an entry and crashing should not make it dirty.
ASSERT_THAT(OpenEntry(key, &entry), IsOk());
EXPECT_EQ(1, cache_->GetEntryCount());
entry->Close();
} else {
EXPECT_NE(net::OK, OpenEntry(key, &entry));
EXPECT_EQ(0, cache_->GetEntryCount());
}
}
// We'll be leaking memory from this test.
TEST_F(DiskCacheBackendTest, InvalidEntryRead) {
BackendInvalidEntryRead();
}
// We'll be leaking memory from this test.
TEST_F(DiskCacheBackendTest, NewEvictionInvalidEntryRead) {
SetNewEviction();
BackendInvalidEntryRead();
}
// We'll be leaking memory from this test.
TEST_F(DiskCacheBackendTest, AppCacheInvalidEntryRead) {
SetCacheType(net::APP_CACHE);
BackendInvalidEntryRead();
}
// We'll be leaking memory from this test.
TEST_F(DiskCacheBackendTest, ShaderCacheInvalidEntryRead) {
SetCacheType(net::SHADER_CACHE);
BackendInvalidEntryRead();
}
// We'll be leaking memory from this test.
void DiskCacheBackendTest::BackendInvalidEntryWithLoad() {
// Work with a tiny index table (16 entries)
SetMask(0xf);
SetMaxSize(0x100000);
InitCache();
int seed = static_cast<int>(Time::Now().ToInternalValue());
srand(seed);
const int kNumEntries = 100;
disk_cache::Entry* entries[kNumEntries];
for (int i = 0; i < kNumEntries; i++) {
std::string key = GenerateKey(true);
ASSERT_THAT(CreateEntry(key, &entries[i]), IsOk());
}
EXPECT_EQ(kNumEntries, cache_->GetEntryCount());
for (int i = 0; i < kNumEntries; i++) {
int source1 = rand() % kNumEntries;
int source2 = rand() % kNumEntries;
disk_cache::Entry* temp = entries[source1];
entries[source1] = entries[source2];
entries[source2] = temp;
}
std::string keys[kNumEntries];
for (int i = 0; i < kNumEntries; i++) {
keys[i] = entries[i]->GetKey();
if (i < kNumEntries / 2)
entries[i]->Close();
}
SimulateCrash();
for (int i = kNumEntries / 2; i < kNumEntries; i++) {
disk_cache::Entry* entry;
EXPECT_NE(net::OK, OpenEntry(keys[i], &entry));
}
for (int i = 0; i < kNumEntries / 2; i++) {
disk_cache::Entry* entry;
ASSERT_THAT(OpenEntry(keys[i], &entry), IsOk());
entry->Close();
}
EXPECT_EQ(kNumEntries / 2, cache_->GetEntryCount());
}
// We'll be leaking memory from this test.
TEST_F(DiskCacheBackendTest, InvalidEntryWithLoad) {
BackendInvalidEntryWithLoad();
}
// We'll be leaking memory from this test.
TEST_F(DiskCacheBackendTest, NewEvictionInvalidEntryWithLoad) {
SetNewEviction();
BackendInvalidEntryWithLoad();
}
// We'll be leaking memory from this test.
TEST_F(DiskCacheBackendTest, AppCacheInvalidEntryWithLoad) {
SetCacheType(net::APP_CACHE);
BackendInvalidEntryWithLoad();
}
// We'll be leaking memory from this test.
TEST_F(DiskCacheBackendTest, ShaderCacheInvalidEntryWithLoad) {
SetCacheType(net::SHADER_CACHE);
BackendInvalidEntryWithLoad();
}
// We'll be leaking memory from this test.
void DiskCacheBackendTest::BackendTrimInvalidEntry() {
const int kSize = 0x3000; // 12 kB
SetMaxSize(kSize * 10);
InitCache();
std::string first("some key");
std::string second("something else");
disk_cache::Entry* entry;
ASSERT_THAT(CreateEntry(first, &entry), IsOk());
scoped_refptr<net::IOBuffer> buffer =
base::MakeRefCounted<net::IOBuffer>(kSize);
memset(buffer->data(), 0, kSize);
EXPECT_EQ(kSize, WriteData(entry, 0, 0, buffer.get(), kSize, false));
// Simulate a crash.
SimulateCrash();
ASSERT_THAT(CreateEntry(second, &entry), IsOk());
EXPECT_EQ(kSize, WriteData(entry, 0, 0, buffer.get(), kSize, false));
EXPECT_EQ(2, cache_->GetEntryCount());
SetMaxSize(kSize);
entry->Close(); // Trim the cache.
FlushQueueForTest();
// If we evicted the entry in less than 20mS, we have one entry in the cache;
// if it took more than that, we posted a task and we'll delete the second
// entry too.
base::RunLoop().RunUntilIdle();
// This may be not thread-safe in general, but for now it's OK so add some
// ThreadSanitizer annotations to ignore data races on cache_.
// See http://crbug.com/55970
ANNOTATE_IGNORE_READS_BEGIN();
EXPECT_GE(1, cache_->GetEntryCount());
ANNOTATE_IGNORE_READS_END();
EXPECT_NE(net::OK, OpenEntry(first, &entry));
}
// We'll be leaking memory from this test.
TEST_F(DiskCacheBackendTest, TrimInvalidEntry) {
BackendTrimInvalidEntry();
}
// We'll be leaking memory from this test.
TEST_F(DiskCacheBackendTest, NewEvictionTrimInvalidEntry) {
SetNewEviction();
BackendTrimInvalidEntry();
}
// We'll be leaking memory from this test.
void DiskCacheBackendTest::BackendTrimInvalidEntry2() {
SetMask(0xf); // 16-entry table.
const int kSize = 0x3000; // 12 kB
SetMaxSize(kSize * 40);
InitCache();
scoped_refptr<net::IOBuffer> buffer =
base::MakeRefCounted<net::IOBuffer>(kSize);
memset(buffer->data(), 0, kSize);
disk_cache::Entry* entry;
// Writing 32 entries to this cache chains most of them.
for (int i = 0; i < 32; i++) {
std::string key(base::StringPrintf("some key %d", i));
ASSERT_THAT(CreateEntry(key, &entry), IsOk());
EXPECT_EQ(kSize, WriteData(entry, 0, 0, buffer.get(), kSize, false));
entry->Close();
ASSERT_THAT(OpenEntry(key, &entry), IsOk());
// Note that we are not closing the entries.
}
// Simulate a crash.
SimulateCrash();
ASSERT_THAT(CreateEntry("Something else", &entry), IsOk());
EXPECT_EQ(kSize, WriteData(entry, 0, 0, buffer.get(), kSize, false));
FlushQueueForTest();
EXPECT_EQ(33, cache_->GetEntryCount());
SetMaxSize(kSize);
// For the new eviction code, all corrupt entries are on the second list so
// they are not going away that easy.
if (new_eviction_) {
EXPECT_THAT(DoomAllEntries(), IsOk());
}
entry->Close(); // Trim the cache.
FlushQueueForTest();
// We may abort the eviction before cleaning up everything.
base::RunLoop().RunUntilIdle();
FlushQueueForTest();
// If it's not clear enough: we may still have eviction tasks running at this
// time, so the number of entries is changing while we read it.
ANNOTATE_IGNORE_READS_AND_WRITES_BEGIN();
EXPECT_GE(30, cache_->GetEntryCount());
ANNOTATE_IGNORE_READS_AND_WRITES_END();
// For extra messiness, the integrity check for the cache can actually cause
// evictions if it's over-capacity, which would race with above. So change the
// size we pass to CheckCacheIntegrity (but don't mess with existing backend's
// state.
size_ = 0;
}
// We'll be leaking memory from this test.
TEST_F(DiskCacheBackendTest, TrimInvalidEntry2) {
BackendTrimInvalidEntry2();
}
// We'll be leaking memory from this test.
TEST_F(DiskCacheBackendTest, NewEvictionTrimInvalidEntry2) {
SetNewEviction();
BackendTrimInvalidEntry2();
}
#endif // !defined(LEAK_SANITIZER)
void DiskCacheBackendTest::BackendEnumerations() {
InitCache();
Time initial = Time::Now();
const int kNumEntries = 100;
for (int i = 0; i < kNumEntries; i++) {
std::string key = GenerateKey(true);
disk_cache::Entry* entry;
ASSERT_THAT(CreateEntry(key, &entry), IsOk());
entry->Close();
}
EXPECT_EQ(kNumEntries, cache_->GetEntryCount());
Time final = Time::Now();
disk_cache::Entry* entry;
std::unique_ptr<TestIterator> iter = CreateIterator();
int count = 0;
Time last_modified[kNumEntries];
Time last_used[kNumEntries];
while (iter->OpenNextEntry(&entry) == net::OK) {
ASSERT_TRUE(NULL != entry);
if (count < kNumEntries) {
last_modified[count] = entry->GetLastModified();
last_used[count] = entry->GetLastUsed();
EXPECT_TRUE(initial <= last_modified[count]);
EXPECT_TRUE(final >= last_modified[count]);
}
entry->Close();
count++;
};
EXPECT_EQ(kNumEntries, count);
iter = CreateIterator();
count = 0;
// The previous enumeration should not have changed the timestamps.
while (iter->OpenNextEntry(&entry) == net::OK) {
ASSERT_TRUE(NULL != entry);
if (count < kNumEntries) {
EXPECT_TRUE(last_modified[count] == entry->GetLastModified());
EXPECT_TRUE(last_used[count] == entry->GetLastUsed());
}
entry->Close();
count++;
};
EXPECT_EQ(kNumEntries, count);
}
TEST_F(DiskCacheBackendTest, Enumerations) {
BackendEnumerations();
}
TEST_F(DiskCacheBackendTest, NewEvictionEnumerations) {
SetNewEviction();
BackendEnumerations();
}
TEST_F(DiskCacheBackendTest, MemoryOnlyEnumerations) {
SetMemoryOnlyMode();
BackendEnumerations();
}
TEST_F(DiskCacheBackendTest, ShaderCacheEnumerations) {
SetCacheType(net::SHADER_CACHE);
BackendEnumerations();
}
TEST_F(DiskCacheBackendTest, AppCacheEnumerations) {
SetCacheType(net::APP_CACHE);
BackendEnumerations();
}
// Verifies enumerations while entries are open.
void DiskCacheBackendTest::BackendEnumerations2() {
InitCache();
const std::string first("first");
const std::string second("second");
disk_cache::Entry *entry1, *entry2;
ASSERT_THAT(CreateEntry(first, &entry1), IsOk());
entry1->Close();
ASSERT_THAT(CreateEntry(second, &entry2), IsOk());
entry2->Close();
FlushQueueForTest();
// Make sure that the timestamp is not the same.
AddDelay();
ASSERT_THAT(OpenEntry(second, &entry1), IsOk());
std::unique_ptr<TestIterator> iter = CreateIterator();
ASSERT_THAT(iter->OpenNextEntry(&entry2), IsOk());
EXPECT_EQ(entry2->GetKey(), second);
// Two entries and the iterator pointing at "first".
entry1->Close();
entry2->Close();
// The iterator should still be valid, so we should not crash.
ASSERT_THAT(iter->OpenNextEntry(&entry2), IsOk());
EXPECT_EQ(entry2->GetKey(), first);
entry2->Close();
iter = CreateIterator();
// Modify the oldest entry and get the newest element.
ASSERT_THAT(OpenEntry(first, &entry1), IsOk());
EXPECT_EQ(0, WriteData(entry1, 0, 200, NULL, 0, false));
ASSERT_THAT(iter->OpenNextEntry(&entry2), IsOk());
if (type_ == net::APP_CACHE) {
// The list is not updated.
EXPECT_EQ(entry2->GetKey(), second);
} else {
EXPECT_EQ(entry2->GetKey(), first);
}
entry1->Close();
entry2->Close();
}
TEST_F(DiskCacheBackendTest, Enumerations2) {
BackendEnumerations2();
}
TEST_F(DiskCacheBackendTest, NewEvictionEnumerations2) {
SetNewEviction();
BackendEnumerations2();
}
TEST_F(DiskCacheBackendTest, AppCacheEnumerations2) {
SetCacheType(net::APP_CACHE);
BackendEnumerations2();
}
TEST_F(DiskCacheBackendTest, ShaderCacheEnumerations2) {
SetCacheType(net::SHADER_CACHE);
BackendEnumerations2();
}
void DiskCacheBackendTest::BackendDoomMidEnumeration() {
InitCache();
const int kNumEntries = 100;
std::set<std::string> keys;
for (int i = 0; i < kNumEntries; i++) {
std::string key = GenerateKey(true);
keys.insert(key);
disk_cache::Entry* entry;
ASSERT_THAT(CreateEntry(key, &entry), IsOk());
entry->Close();
}
disk_cache::Entry* entry;
std::unique_ptr<TestIterator> iter = CreateIterator();
int count = 0;
while (iter->OpenNextEntry(&entry) == net::OK) {
if (count == 0) {
// Delete a random entry from the cache while in the midst of iteration.
auto key_to_doom = keys.begin();
while (*key_to_doom == entry->GetKey())
key_to_doom++;
ASSERT_THAT(DoomEntry(*key_to_doom), IsOk());
ASSERT_EQ(1u, keys.erase(*key_to_doom));
}
ASSERT_NE(nullptr, entry);
EXPECT_EQ(1u, keys.erase(entry->GetKey()));
entry->Close();
count++;
};
EXPECT_EQ(kNumEntries - 1, cache_->GetEntryCount());
EXPECT_EQ(0u, keys.size());
}
TEST_F(DiskCacheBackendTest, DoomEnumerations) {
BackendDoomMidEnumeration();
}
TEST_F(DiskCacheBackendTest, NewEvictionDoomEnumerations) {
SetNewEviction();
BackendDoomMidEnumeration();
}
TEST_F(DiskCacheBackendTest, MemoryOnlyDoomEnumerations) {
SetMemoryOnlyMode();
BackendDoomMidEnumeration();
}
TEST_F(DiskCacheBackendTest, ShaderCacheDoomEnumerations) {
SetCacheType(net::SHADER_CACHE);
BackendDoomMidEnumeration();
}
TEST_F(DiskCacheBackendTest, AppCacheDoomEnumerations) {
SetCacheType(net::APP_CACHE);
BackendDoomMidEnumeration();
}
TEST_F(DiskCacheBackendTest, SimpleDoomEnumerations) {
SetSimpleCacheMode();
BackendDoomMidEnumeration();
}
// Verify that ReadData calls do not update the LRU cache
// when using the SHADER_CACHE type.
TEST_F(DiskCacheBackendTest, ShaderCacheEnumerationReadData) {
SetCacheType(net::SHADER_CACHE);
InitCache();
const std::string first("first");
const std::string second("second");
disk_cache::Entry *entry1, *entry2;
const int kSize = 50;
scoped_refptr<net::IOBuffer> buffer1 =
base::MakeRefCounted<net::IOBuffer>(kSize);
ASSERT_THAT(CreateEntry(first, &entry1), IsOk());
memset(buffer1->data(), 0, kSize);
base::strlcpy(buffer1->data(), "And the data to save", kSize);
EXPECT_EQ(kSize, WriteData(entry1, 0, 0, buffer1.get(), kSize, false));
ASSERT_THAT(CreateEntry(second, &entry2), IsOk());
entry2->Close();
FlushQueueForTest();
// Make sure that the timestamp is not the same.
AddDelay();
// Read from the last item in the LRU.
EXPECT_EQ(kSize, ReadData(entry1, 0, 0, buffer1.get(), kSize));
entry1->Close();
std::unique_ptr<TestIterator> iter = CreateIterator();
ASSERT_THAT(iter->OpenNextEntry(&entry2), IsOk());
EXPECT_EQ(entry2->GetKey(), second);
entry2->Close();
}
#if !defined(LEAK_SANITIZER)
// Verify handling of invalid entries while doing enumerations.
// We'll be leaking memory from this test.
void DiskCacheBackendTest::BackendInvalidEntryEnumeration() {
InitCache();
std::string key("Some key");
disk_cache::Entry *entry, *entry1, *entry2;
ASSERT_THAT(CreateEntry(key, &entry1), IsOk());
const int kSize = 50;
scoped_refptr<net::IOBuffer> buffer1 =
base::MakeRefCounted<net::IOBuffer>(kSize);
memset(buffer1->data(), 0, kSize);
base::strlcpy(buffer1->data(), "And the data to save", kSize);
EXPECT_EQ(kSize, WriteData(entry1, 0, 0, buffer1.get(), kSize, false));
entry1->Close();
ASSERT_THAT(OpenEntry(key, &entry1), IsOk());
EXPECT_EQ(kSize, ReadData(entry1, 0, 0, buffer1.get(), kSize));
std::string key2("Another key");
ASSERT_THAT(CreateEntry(key2, &entry2), IsOk());
entry2->Close();
ASSERT_EQ(2, cache_->GetEntryCount());
SimulateCrash();
std::unique_ptr<TestIterator> iter = CreateIterator();
int count = 0;
while (iter->OpenNextEntry(&entry) == net::OK) {
ASSERT_TRUE(NULL != entry);
EXPECT_EQ(key2, entry->GetKey());
entry->Close();
count++;
};
EXPECT_EQ(1, count);
EXPECT_EQ(1, cache_->GetEntryCount());
}
// We'll be leaking memory from this test.
TEST_F(DiskCacheBackendTest, InvalidEntryEnumeration) {
BackendInvalidEntryEnumeration();
}
// We'll be leaking memory from this test.
TEST_F(DiskCacheBackendTest, NewEvictionInvalidEntryEnumeration) {
SetNewEviction();
BackendInvalidEntryEnumeration();
}
#endif // !defined(LEAK_SANITIZER)
// Tests that if for some reason entries are modified close to existing cache
// iterators, we don't generate fatal errors or reset the cache.
void DiskCacheBackendTest::BackendFixEnumerators() {
InitCache();
int seed = static_cast<int>(Time::Now().ToInternalValue());
srand(seed);
const int kNumEntries = 10;
for (int i = 0; i < kNumEntries; i++) {
std::string key = GenerateKey(true);
disk_cache::Entry* entry;
ASSERT_THAT(CreateEntry(key, &entry), IsOk());
entry->Close();
}
EXPECT_EQ(kNumEntries, cache_->GetEntryCount());
disk_cache::Entry *entry1, *entry2;
std::unique_ptr<TestIterator> iter1 = CreateIterator(),
iter2 = CreateIterator();
ASSERT_THAT(iter1->OpenNextEntry(&entry1), IsOk());
ASSERT_TRUE(NULL != entry1);
entry1->Close();
entry1 = NULL;
// Let's go to the middle of the list.
for (int i = 0; i < kNumEntries / 2; i++) {
if (entry1)
entry1->Close();
ASSERT_THAT(iter1->OpenNextEntry(&entry1), IsOk());
ASSERT_TRUE(NULL != entry1);
ASSERT_THAT(iter2->OpenNextEntry(&entry2), IsOk());
ASSERT_TRUE(NULL != entry2);
entry2->Close();
}
// Messing up with entry1 will modify entry2->next.
entry1->Doom();
ASSERT_THAT(iter2->OpenNextEntry(&entry2), IsOk());
ASSERT_TRUE(NULL != entry2);
// The link entry2->entry1 should be broken.
EXPECT_NE(entry2->GetKey(), entry1->GetKey());
entry1->Close();
entry2->Close();
// And the second iterator should keep working.
ASSERT_THAT(iter2->OpenNextEntry(&entry2), IsOk());
ASSERT_TRUE(NULL != entry2);
entry2->Close();
}
TEST_F(DiskCacheBackendTest, FixEnumerators) {
BackendFixEnumerators();
}
TEST_F(DiskCacheBackendTest, NewEvictionFixEnumerators) {
SetNewEviction();
BackendFixEnumerators();
}
void DiskCacheBackendTest::BackendDoomRecent() {
InitCache();
disk_cache::Entry* entry;
ASSERT_THAT(CreateEntry("first", &entry), IsOk());
entry->Close();
ASSERT_THAT(CreateEntry("second", &entry), IsOk());
entry->Close();
FlushQueueForTest();
AddDelay();
Time middle = Time::Now();
ASSERT_THAT(CreateEntry("third", &entry), IsOk());
entry->Close();
ASSERT_THAT(CreateEntry("fourth", &entry), IsOk());
entry->Close();
FlushQueueForTest();
AddDelay();
Time final = Time::Now();
ASSERT_EQ(4, cache_->GetEntryCount());
EXPECT_THAT(DoomEntriesSince(final), IsOk());
ASSERT_EQ(4, cache_->GetEntryCount());
EXPECT_THAT(DoomEntriesSince(middle), IsOk());
ASSERT_EQ(2, cache_->GetEntryCount());
ASSERT_THAT(OpenEntry("second", &entry), IsOk());
entry->Close();
}
TEST_F(DiskCacheBackendTest, DoomRecent) {
BackendDoomRecent();
}
TEST_F(DiskCacheBackendTest, NewEvictionDoomRecent) {
SetNewEviction();
BackendDoomRecent();
}
TEST_F(DiskCacheBackendTest, MemoryOnlyDoomRecent) {
SetMemoryOnlyMode();
BackendDoomRecent();
}
TEST_F(DiskCacheBackendTest, MemoryOnlyDoomEntriesSinceSparse) {
SetMemoryOnlyMode();
base::Time start;
InitSparseCache(&start, NULL);
DoomEntriesSince(start);
EXPECT_EQ(1, cache_->GetEntryCount());
}
TEST_F(DiskCacheBackendTest, DoomEntriesSinceSparse) {
base::Time start;
InitSparseCache(&start, NULL);
DoomEntriesSince(start);
// NOTE: BackendImpl counts child entries in its GetEntryCount(), while
// MemBackendImpl does not. Thats why expected value differs here from
// MemoryOnlyDoomEntriesSinceSparse.
EXPECT_EQ(3, cache_->GetEntryCount());
}
TEST_F(DiskCacheBackendTest, MemoryOnlyDoomAllSparse) {
SetMemoryOnlyMode();
InitSparseCache(NULL, NULL);
EXPECT_THAT(DoomAllEntries(), IsOk());
EXPECT_EQ(0, cache_->GetEntryCount());
}
TEST_F(DiskCacheBackendTest, DoomAllSparse) {
InitSparseCache(NULL, NULL);
EXPECT_THAT(DoomAllEntries(), IsOk());
EXPECT_EQ(0, cache_->GetEntryCount());
}
// This test is for https://crbug.com/827492.
TEST_F(DiskCacheBackendTest, InMemorySparseEvict) {
const int kMaxSize = 512;
SetMaxSize(kMaxSize);
SetMemoryOnlyMode();
InitCache();
scoped_refptr<net::IOBuffer> buffer = base::MakeRefCounted<net::IOBuffer>(64);
CacheTestFillBuffer(buffer->data(), 64, false /* no_nulls */);
std::vector<disk_cache::ScopedEntryPtr> entries;
disk_cache::Entry* entry = nullptr;
// Create a bunch of entries
for (size_t i = 0; i < 14; i++) {
std::string name = "http://www." + std::to_string(i) + ".com/";
ASSERT_THAT(CreateEntry(name, &entry), IsOk());
entries.push_back(disk_cache::ScopedEntryPtr(entry));
}
// Create several sparse entries and fill with enough data to
// pass eviction threshold
ASSERT_EQ(64, WriteSparseData(entries[0].get(), 0, buffer.get(), 64));
ASSERT_EQ(net::ERR_FAILED,
WriteSparseData(entries[0].get(), 10000, buffer.get(), 4));
ASSERT_EQ(63, WriteSparseData(entries[1].get(), 0, buffer.get(), 63));
ASSERT_EQ(64, WriteSparseData(entries[2].get(), 0, buffer.get(), 64));
ASSERT_EQ(64, WriteSparseData(entries[3].get(), 0, buffer.get(), 64));
// Close all the entries, leaving a populated LRU list
// with all entries having refcount 0 (doom implies deletion)
entries.clear();
// Create a new entry, triggering buggy eviction
ASSERT_THAT(CreateEntry("http://www.14.com/", &entry), IsOk());
entry->Close();
}
void DiskCacheBackendTest::BackendDoomBetween() {
InitCache();
disk_cache::Entry* entry;
ASSERT_THAT(CreateEntry("first", &entry), IsOk());
entry->Close();
FlushQueueForTest();
AddDelay();
Time middle_start = Time::Now();
ASSERT_THAT(CreateEntry("second", &entry), IsOk());
entry->Close();
ASSERT_THAT(CreateEntry("third", &entry), IsOk());
entry->Close();
FlushQueueForTest();
AddDelay();
Time middle_end = Time::Now();
ASSERT_THAT(CreateEntry("fourth", &entry), IsOk());
entry->Close();
ASSERT_THAT(OpenEntry("fourth", &entry), IsOk());
entry->Close();
FlushQueueForTest();
AddDelay();
Time final = Time::Now();
ASSERT_EQ(4, cache_->GetEntryCount());
EXPECT_THAT(DoomEntriesBetween(middle_start, middle_end), IsOk());
ASSERT_EQ(2, cache_->GetEntryCount());
ASSERT_THAT(OpenEntry("fourth", &entry), IsOk());
entry->Close();
EXPECT_THAT(DoomEntriesBetween(middle_start, final), IsOk());
ASSERT_EQ(1, cache_->GetEntryCount());
ASSERT_THAT(OpenEntry("first", &entry), IsOk());
entry->Close();
}
TEST_F(DiskCacheBackendTest, DoomBetween) {
BackendDoomBetween();
}
TEST_F(DiskCacheBackendTest, NewEvictionDoomBetween) {
SetNewEviction();
BackendDoomBetween();
}
TEST_F(DiskCacheBackendTest, MemoryOnlyDoomBetween) {
SetMemoryOnlyMode();
BackendDoomBetween();
}
TEST_F(DiskCacheBackendTest, MemoryOnlyDoomEntriesBetweenSparse) {
SetMemoryOnlyMode();
base::Time start, end;
InitSparseCache(&start, &end);
DoomEntriesBetween(start, end);
EXPECT_EQ(3, cache_->GetEntryCount());
start = end;
end = base::Time::Now();
DoomEntriesBetween(start, end);
EXPECT_EQ(1, cache_->GetEntryCount());
}
TEST_F(DiskCacheBackendTest, DoomEntriesBetweenSparse) {
base::Time start, end;
InitSparseCache(&start, &end);
DoomEntriesBetween(start, end);
EXPECT_EQ(9, cache_->GetEntryCount());
start = end;
end = base::Time::Now();
DoomEntriesBetween(start, end);
EXPECT_EQ(3, cache_->GetEntryCount());
}
void DiskCacheBackendTest::BackendCalculateSizeOfAllEntries() {
InitCache();
// The cache is initially empty.
EXPECT_EQ(0, CalculateSizeOfAllEntries());
// Generate random entries and populate them with data of respective
// sizes 0, 1, ..., count - 1 bytes.
std::set<std::string> key_pool;
CreateSetOfRandomEntries(&key_pool);
int count = 0;
int total_size = 0;
for (std::string key : key_pool) {
std::string data(count, ' ');
scoped_refptr<net::StringIOBuffer> buffer =
base::MakeRefCounted<net::StringIOBuffer>(data);
// Alternate between writing to first two streams to test that we do not
// take only one stream into account.
disk_cache::Entry* entry;
ASSERT_THAT(OpenEntry(key, &entry), IsOk());
ASSERT_EQ(count, WriteData(entry, count % 2, 0, buffer.get(), count, true));
entry->Close();
total_size += GetRoundedSize(count + GetEntryMetadataSize(key));
++count;
}
int result = CalculateSizeOfAllEntries();
EXPECT_EQ(total_size, result);
// Add another entry and test if the size is updated. Then remove it and test
// if the size is back to original value.
{
const int last_entry_size = 47;
std::string data(last_entry_size, ' ');
scoped_refptr<net::StringIOBuffer> buffer =
base::MakeRefCounted<net::StringIOBuffer>(data);
disk_cache::Entry* entry;
std::string key = GenerateKey(true);
ASSERT_THAT(CreateEntry(key, &entry), IsOk());
ASSERT_EQ(last_entry_size,
WriteData(entry, 0, 0, buffer.get(), last_entry_size, true));
entry->Close();
int new_result = CalculateSizeOfAllEntries();
EXPECT_EQ(
result + GetRoundedSize(last_entry_size + GetEntryMetadataSize(key)),
new_result);
DoomEntry(key);
new_result = CalculateSizeOfAllEntries();
EXPECT_EQ(result, new_result);
}
// After dooming the entries, the size should be back to zero.
ASSERT_THAT(DoomAllEntries(), IsOk());
EXPECT_EQ(0, CalculateSizeOfAllEntries());
}
TEST_F(DiskCacheBackendTest, CalculateSizeOfAllEntries) {
BackendCalculateSizeOfAllEntries();
}
TEST_F(DiskCacheBackendTest, MemoryOnlyCalculateSizeOfAllEntries) {
SetMemoryOnlyMode();
BackendCalculateSizeOfAllEntries();
}
TEST_F(DiskCacheBackendTest, SimpleCacheCalculateSizeOfAllEntries) {
// Use net::APP_CACHE to make size estimations deterministic via
// non-optimistic writes.
SetCacheType(net::APP_CACHE);
SetSimpleCacheMode();
BackendCalculateSizeOfAllEntries();
}
void DiskCacheBackendTest::BackendCalculateSizeOfEntriesBetween() {
InitCache();
EXPECT_EQ(0, CalculateSizeOfEntriesBetween(base::Time(), base::Time::Max()));
Time start = Time::Now();
disk_cache::Entry* entry;
ASSERT_THAT(CreateEntry("first", &entry), IsOk());
entry->Close();
FlushQueueForTest();
AddDelay();
Time middle = Time::Now();
AddDelay();
ASSERT_THAT(CreateEntry("second", &entry), IsOk());
entry->Close();
ASSERT_THAT(CreateEntry("third_entry", &entry), IsOk());
entry->Close();
FlushQueueForTest();
AddDelay();
Time end = Time::Now();
int size_1 = GetRoundedSize(GetEntryMetadataSize("first"));
int size_2 = GetRoundedSize(GetEntryMetadataSize("second"));
int size_3 = GetRoundedSize(GetEntryMetadataSize("third_entry"));
ASSERT_EQ(3, cache_->GetEntryCount());
ASSERT_EQ(CalculateSizeOfAllEntries(),
CalculateSizeOfEntriesBetween(base::Time(), base::Time::Max()));
int start_end = CalculateSizeOfEntriesBetween(start, end);
ASSERT_EQ(CalculateSizeOfAllEntries(), start_end);
ASSERT_EQ(size_1 + size_2 + size_3, start_end);
ASSERT_EQ(size_1, CalculateSizeOfEntriesBetween(start, middle));
ASSERT_EQ(size_2 + size_3, CalculateSizeOfEntriesBetween(middle, end));
// After dooming the entries, the size should be back to zero.
ASSERT_THAT(DoomAllEntries(), IsOk());
EXPECT_EQ(0, CalculateSizeOfEntriesBetween(base::Time(), base::Time::Max()));
}
TEST_F(DiskCacheBackendTest, CalculateSizeOfEntriesBetween) {
InitCache();
ASSERT_EQ(net::ERR_NOT_IMPLEMENTED,
CalculateSizeOfEntriesBetween(base::Time(), base::Time::Max()));
}
TEST_F(DiskCacheBackendTest, MemoryOnlyCalculateSizeOfEntriesBetween) {
SetMemoryOnlyMode();
BackendCalculateSizeOfEntriesBetween();
}
TEST_F(DiskCacheBackendTest, SimpleCacheCalculateSizeOfEntriesBetween) {
// Use net::APP_CACHE to make size estimations deterministic via
// non-optimistic writes.
SetCacheType(net::APP_CACHE);
SetSimpleCacheMode();
BackendCalculateSizeOfEntriesBetween();
}
void DiskCacheBackendTest::BackendTransaction(const std::string& name,
int num_entries,
bool load) {
success_ = false;
ASSERT_TRUE(CopyTestCache(name));
DisableFirstCleanup();
uint32_t mask;
if (load) {
mask = 0xf;
SetMaxSize(0x100000);
} else {
// Clear the settings from the previous run.
mask = 0;
SetMaxSize(0);
}
SetMask(mask);
InitCache();
ASSERT_EQ(num_entries + 1, cache_->GetEntryCount());
std::string key("the first key");
disk_cache::Entry* entry1;
ASSERT_NE(net::OK, OpenEntry(key, &entry1));
int actual = cache_->GetEntryCount();
if (num_entries != actual) {
ASSERT_TRUE(load);
// If there is a heavy load, inserting an entry will make another entry
// dirty (on the hash bucket) so two entries are removed.
ASSERT_EQ(num_entries - 1, actual);
}
cache_.reset();
cache_impl_ = NULL;
ASSERT_TRUE(CheckCacheIntegrity(cache_path_, new_eviction_, MaxSize(), mask));
success_ = true;
}
void DiskCacheBackendTest::BackendRecoverInsert() {
// Tests with an empty cache.
BackendTransaction("insert_empty1", 0, false);
ASSERT_TRUE(success_) << "insert_empty1";
BackendTransaction("insert_empty2", 0, false);
ASSERT_TRUE(success_) << "insert_empty2";
BackendTransaction("insert_empty3", 0, false);
ASSERT_TRUE(success_) << "insert_empty3";
// Tests with one entry on the cache.
BackendTransaction("insert_one1", 1, false);
ASSERT_TRUE(success_) << "insert_one1";
BackendTransaction("insert_one2", 1, false);
ASSERT_TRUE(success_) << "insert_one2";
BackendTransaction("insert_one3", 1, false);
ASSERT_TRUE(success_) << "insert_one3";
// Tests with one hundred entries on the cache, tiny index.
BackendTransaction("insert_load1", 100, true);
ASSERT_TRUE(success_) << "insert_load1";
BackendTransaction("insert_load2", 100, true);
ASSERT_TRUE(success_) << "insert_load2";
}
TEST_F(DiskCacheBackendTest, RecoverInsert) {
BackendRecoverInsert();
}
TEST_F(DiskCacheBackendTest, NewEvictionRecoverInsert) {
SetNewEviction();
BackendRecoverInsert();
}
void DiskCacheBackendTest::BackendRecoverRemove() {
// Removing the only element.
BackendTransaction("remove_one1", 0, false);
ASSERT_TRUE(success_) << "remove_one1";
BackendTransaction("remove_one2", 0, false);
ASSERT_TRUE(success_) << "remove_one2";
BackendTransaction("remove_one3", 0, false);
ASSERT_TRUE(success_) << "remove_one3";
// Removing the head.
BackendTransaction("remove_head1", 1, false);
ASSERT_TRUE(success_) << "remove_head1";
BackendTransaction("remove_head2", 1, false);
ASSERT_TRUE(success_) << "remove_head2";
BackendTransaction("remove_head3", 1, false);
ASSERT_TRUE(success_) << "remove_head3";
// Removing the tail.
BackendTransaction("remove_tail1", 1, false);
ASSERT_TRUE(success_) << "remove_tail1";
BackendTransaction("remove_tail2", 1, false);
ASSERT_TRUE(success_) << "remove_tail2";
BackendTransaction("remove_tail3", 1, false);
ASSERT_TRUE(success_) << "remove_tail3";
// Removing with one hundred entries on the cache, tiny index.
BackendTransaction("remove_load1", 100, true);
ASSERT_TRUE(success_) << "remove_load1";
BackendTransaction("remove_load2", 100, true);
ASSERT_TRUE(success_) << "remove_load2";
BackendTransaction("remove_load3", 100, true);
ASSERT_TRUE(success_) << "remove_load3";
// This case cannot be reverted.
BackendTransaction("remove_one4", 0, false);
ASSERT_TRUE(success_) << "remove_one4";
BackendTransaction("remove_head4", 1, false);
ASSERT_TRUE(success_) << "remove_head4";
}
#if defined(OS_WIN)
// http://crbug.com/396392
#define MAYBE_RecoverRemove DISABLED_RecoverRemove
#else
#define MAYBE_RecoverRemove RecoverRemove
#endif
TEST_F(DiskCacheBackendTest, MAYBE_RecoverRemove) {
BackendRecoverRemove();
}
#if defined(OS_WIN)
// http://crbug.com/396392
#define MAYBE_NewEvictionRecoverRemove DISABLED_NewEvictionRecoverRemove
#else
#define MAYBE_NewEvictionRecoverRemove NewEvictionRecoverRemove
#endif
TEST_F(DiskCacheBackendTest, MAYBE_NewEvictionRecoverRemove) {
SetNewEviction();
BackendRecoverRemove();
}
void DiskCacheBackendTest::BackendRecoverWithEviction() {
success_ = false;
ASSERT_TRUE(CopyTestCache("insert_load1"));
DisableFirstCleanup();
SetMask(0xf);
SetMaxSize(0x1000);
// We should not crash here.
InitCache();
DisableIntegrityCheck();
}
TEST_F(DiskCacheBackendTest, RecoverWithEviction) {
BackendRecoverWithEviction();
}
TEST_F(DiskCacheBackendTest, NewEvictionRecoverWithEviction) {
SetNewEviction();
BackendRecoverWithEviction();
}
// Tests that the |BackendImpl| fails to start with the wrong cache version.
TEST_F(DiskCacheTest, WrongVersion) {
ASSERT_TRUE(CopyTestCache("wrong_version"));
net::TestCompletionCallback cb;
std::unique_ptr<disk_cache::BackendImpl> cache(
std::make_unique<disk_cache::BackendImpl>(cache_path_, nullptr, nullptr,
nullptr));
int rv = cache->Init(cb.callback());
ASSERT_THAT(cb.GetResult(rv), IsError(net::ERR_FAILED));
}
// Tests that the disk cache successfully joins the control group, dropping the
// existing cache in favour of a new empty cache.
// Disabled on android since this test requires cache creator to create
// blockfile caches.
#if !defined(OS_ANDROID)
TEST_F(DiskCacheTest, SimpleCacheControlJoin) {
std::unique_ptr<disk_cache::BackendImpl> cache =
CreateExistingEntryCache(cache_path_);
ASSERT_TRUE(cache.get());
cache.reset();
// Instantiate the SimpleCacheTrial, forcing this run into the
// ExperimentControl group.
base::FieldTrialList field_trial_list(
std::make_unique<base::MockEntropyProvider>());
base::FieldTrialList::CreateFieldTrial("SimpleCacheTrial",
"ExperimentControl");
net::TestCompletionCallback cb;
std::unique_ptr<disk_cache::Backend> base_cache;
int rv = disk_cache::CreateCacheBackend(
net::DISK_CACHE, net::CACHE_BACKEND_BLOCKFILE, cache_path_, 0, true, NULL,
&base_cache, cb.callback());
ASSERT_THAT(cb.GetResult(rv), IsOk());
EXPECT_EQ(0, base_cache->GetEntryCount());
}
#endif
// Tests that the disk cache can restart in the control group preserving
// existing entries.
TEST_F(DiskCacheTest, SimpleCacheControlRestart) {
// Instantiate the SimpleCacheTrial, forcing this run into the
// ExperimentControl group.
base::FieldTrialList field_trial_list(
std::make_unique<base::MockEntropyProvider>());
base::FieldTrialList::CreateFieldTrial("SimpleCacheTrial",
"ExperimentControl");
std::unique_ptr<disk_cache::BackendImpl> cache =
CreateExistingEntryCache(cache_path_);
ASSERT_TRUE(cache.get());
net::TestCompletionCallback cb;
const int kRestartCount = 5;
for (int i = 0; i < kRestartCount; ++i) {
cache.reset(
new disk_cache::BackendImpl(cache_path_, nullptr, nullptr, nullptr));
int rv = cache->Init(cb.callback());
ASSERT_THAT(cb.GetResult(rv), IsOk());
EXPECT_EQ(1, cache->GetEntryCount());
disk_cache::Entry* entry = NULL;
rv = cache->OpenEntry(kExistingEntryKey, net::HIGHEST, &entry,
cb.callback());
ASSERT_THAT(cb.GetResult(rv), IsOk());
EXPECT_NE(nullptr, entry);
entry->Close();
}
}
// Tests that the disk cache can leave the control group preserving existing
// entries.
TEST_F(DiskCacheTest, SimpleCacheControlLeave) {
{
// Instantiate the SimpleCacheTrial, forcing this run into the
// ExperimentControl group.
base::FieldTrialList field_trial_list(
std::make_unique<base::MockEntropyProvider>());
base::FieldTrialList::CreateFieldTrial("SimpleCacheTrial",
"ExperimentControl");
std::unique_ptr<disk_cache::BackendImpl> cache =
CreateExistingEntryCache(cache_path_);
ASSERT_TRUE(cache.get());
}
// Instantiate the SimpleCacheTrial, forcing this run into the
// ExperimentNo group.
base::FieldTrialList field_trial_list(
std::make_unique<base::MockEntropyProvider>());
base::FieldTrialList::CreateFieldTrial("SimpleCacheTrial", "ExperimentNo");
net::TestCompletionCallback cb;
const int kRestartCount = 5;
for (int i = 0; i < kRestartCount; ++i) {
std::unique_ptr<disk_cache::BackendImpl> cache(
std::make_unique<disk_cache::BackendImpl>(cache_path_, nullptr, nullptr,
nullptr));
int rv = cache->Init(cb.callback());
ASSERT_THAT(cb.GetResult(rv), IsOk());
EXPECT_EQ(1, cache->GetEntryCount());
disk_cache::Entry* entry = NULL;
rv = cache->OpenEntry(kExistingEntryKey, net::HIGHEST, &entry,
cb.callback());
ASSERT_THAT(cb.GetResult(rv), IsOk());
EXPECT_NE(nullptr, entry);
entry->Close();
}
}
// Tests that the cache is properly restarted on recovery error.
// Disabled on android since this test requires cache creator to create
// blockfile caches.
#if !defined(OS_ANDROID)
TEST_F(DiskCacheBackendTest, DeleteOld) {
ASSERT_TRUE(CopyTestCache("wrong_version"));
SetNewEviction();
net::TestCompletionCallback cb;
bool prev = base::ThreadRestrictions::SetIOAllowed(false);
base::FilePath path(cache_path_);
int rv = disk_cache::CreateCacheBackend(net::DISK_CACHE,
net::CACHE_BACKEND_BLOCKFILE, path, 0,
true, NULL, &cache_, cb.callback());
path.clear(); // Make sure path was captured by the previous call.
ASSERT_THAT(cb.GetResult(rv), IsOk());
base::ThreadRestrictions::SetIOAllowed(prev);
cache_.reset();
EXPECT_TRUE(CheckCacheIntegrity(cache_path_, new_eviction_, /*max_size = */ 0,
mask_));
}
#endif
// We want to be able to deal with messed up entries on disk.
void DiskCacheBackendTest::BackendInvalidEntry2() {
ASSERT_TRUE(CopyTestCache("bad_entry"));
DisableFirstCleanup();
InitCache();
disk_cache::Entry *entry1, *entry2;
ASSERT_THAT(OpenEntry("the first key", &entry1), IsOk());
EXPECT_NE(net::OK, OpenEntry("some other key", &entry2));
entry1->Close();
// CheckCacheIntegrity will fail at this point.
DisableIntegrityCheck();
}
TEST_F(DiskCacheBackendTest, InvalidEntry2) {
BackendInvalidEntry2();
}
TEST_F(DiskCacheBackendTest, NewEvictionInvalidEntry2) {
SetNewEviction();
BackendInvalidEntry2();
}
// Tests that we don't crash or hang when enumerating this cache.
void DiskCacheBackendTest::BackendInvalidEntry3() {
SetMask(0x1); // 2-entry table.
SetMaxSize(0x3000); // 12 kB.
DisableFirstCleanup();
InitCache();
disk_cache::Entry* entry;
std::unique_ptr<TestIterator> iter = CreateIterator();
while (iter->OpenNextEntry(&entry) == net::OK) {
entry->Close();
}
}
TEST_F(DiskCacheBackendTest, InvalidEntry3) {
ASSERT_TRUE(CopyTestCache("dirty_entry3"));
BackendInvalidEntry3();
}
TEST_F(DiskCacheBackendTest, NewEvictionInvalidEntry3) {
ASSERT_TRUE(CopyTestCache("dirty_entry4"));
SetNewEviction();
BackendInvalidEntry3();
DisableIntegrityCheck();
}
// Test that we handle a dirty entry on the LRU list, already replaced with
// the same key, and with hash collisions.
TEST_F(DiskCacheBackendTest, InvalidEntry4) {
ASSERT_TRUE(CopyTestCache("dirty_entry3"));
SetMask(0x1); // 2-entry table.
SetMaxSize(0x3000); // 12 kB.
DisableFirstCleanup();
InitCache();
TrimForTest(false);
}
// Test that we handle a dirty entry on the deleted list, already replaced with
// the same key, and with hash collisions.
TEST_F(DiskCacheBackendTest, InvalidEntry5) {
ASSERT_TRUE(CopyTestCache("dirty_entry4"));
SetNewEviction();
SetMask(0x1); // 2-entry table.
SetMaxSize(0x3000); // 12 kB.
DisableFirstCleanup();
InitCache();
TrimDeletedListForTest(false);
}
TEST_F(DiskCacheBackendTest, InvalidEntry6) {
ASSERT_TRUE(CopyTestCache("dirty_entry5"));
SetMask(0x1); // 2-entry table.
SetMaxSize(0x3000); // 12 kB.
DisableFirstCleanup();
InitCache();
// There is a dirty entry (but marked as clean) at the end, pointing to a
// deleted entry through the hash collision list. We should not re-insert the
// deleted entry into the index table.
TrimForTest(false);
// The cache should be clean (as detected by CheckCacheIntegrity).
}
// Tests that we don't hang when there is a loop on the hash collision list.
// The test cache could be a result of bug 69135.
TEST_F(DiskCacheBackendTest, BadNextEntry1) {
ASSERT_TRUE(CopyTestCache("list_loop2"));
SetMask(0x1); // 2-entry table.
SetMaxSize(0x3000); // 12 kB.
DisableFirstCleanup();
InitCache();
// The second entry points at itselft, and the first entry is not accessible
// though the index, but it is at the head of the LRU.
disk_cache::Entry* entry;
ASSERT_THAT(CreateEntry("The first key", &entry), IsOk());
entry->Close();
TrimForTest(false);
TrimForTest(false);
ASSERT_THAT(OpenEntry("The first key", &entry), IsOk());
entry->Close();
EXPECT_EQ(1, cache_->GetEntryCount());
}
// Tests that we don't hang when there is a loop on the hash collision list.
// The test cache could be a result of bug 69135.
TEST_F(DiskCacheBackendTest, BadNextEntry2) {
ASSERT_TRUE(CopyTestCache("list_loop3"));
SetMask(0x1); // 2-entry table.
SetMaxSize(0x3000); // 12 kB.
DisableFirstCleanup();
InitCache();
// There is a wide loop of 5 entries.
disk_cache::Entry* entry;
ASSERT_NE(net::OK, OpenEntry("Not present key", &entry));
}
TEST_F(DiskCacheBackendTest, NewEvictionInvalidEntry6) {
ASSERT_TRUE(CopyTestCache("bad_rankings3"));
DisableFirstCleanup();
SetNewEviction();
InitCache();
// The second entry is dirty, but removing it should not corrupt the list.
disk_cache::Entry* entry;
ASSERT_NE(net::OK, OpenEntry("the second key", &entry));
ASSERT_THAT(OpenEntry("the first key", &entry), IsOk());
// This should not delete the cache.
entry->Doom();
FlushQueueForTest();
entry->Close();
ASSERT_THAT(OpenEntry("some other key", &entry), IsOk());
entry->Close();
}
// Tests handling of corrupt entries by keeping the rankings node around, with
// a fatal failure.
void DiskCacheBackendTest::BackendInvalidEntry7() {
const int kSize = 0x3000; // 12 kB.
SetMaxSize(kSize * 10);
InitCache();
std::string first("some key");
std::string second("something else");
disk_cache::Entry* entry;
ASSERT_THAT(CreateEntry(first, &entry), IsOk());
entry->Close();
ASSERT_THAT(CreateEntry(second, &entry), IsOk());
// Corrupt this entry.
disk_cache::EntryImpl* entry_impl =
static_cast<disk_cache::EntryImpl*>(entry);
entry_impl->rankings()->Data()->next = 0;
entry_impl->rankings()->Store();
entry->Close();
FlushQueueForTest();
EXPECT_EQ(2, cache_->GetEntryCount());
// This should detect the bad entry.
EXPECT_NE(net::OK, OpenEntry(second, &entry));
EXPECT_EQ(1, cache_->GetEntryCount());
// We should delete the cache. The list still has a corrupt node.
std::unique_ptr<TestIterator> iter = CreateIterator();
EXPECT_NE(net::OK, iter->OpenNextEntry(&entry));
FlushQueueForTest();
EXPECT_EQ(0, cache_->GetEntryCount());
}
TEST_F(DiskCacheBackendTest, InvalidEntry7) {
BackendInvalidEntry7();
}
TEST_F(DiskCacheBackendTest, NewEvictionInvalidEntry7) {
SetNewEviction();
BackendInvalidEntry7();
}
// Tests handling of corrupt entries by keeping the rankings node around, with
// a non fatal failure.
void DiskCacheBackendTest::BackendInvalidEntry8() {
const int kSize = 0x3000; // 12 kB
SetMaxSize(kSize * 10);
InitCache();
std::string first("some key");
std::string second("something else");
disk_cache::Entry* entry;
ASSERT_THAT(CreateEntry(first, &entry), IsOk());
entry->Close();
ASSERT_THAT(CreateEntry(second, &entry), IsOk());
// Corrupt this entry.
disk_cache::EntryImpl* entry_impl =
static_cast<disk_cache::EntryImpl*>(entry);
entry_impl->rankings()->Data()->contents = 0;
entry_impl->rankings()->Store();
entry->Close();
FlushQueueForTest();
EXPECT_EQ(2, cache_->GetEntryCount());
// This should detect the bad entry.
EXPECT_NE(net::OK, OpenEntry(second, &entry));
EXPECT_EQ(1, cache_->GetEntryCount());
// We should not delete the cache.
std::unique_ptr<TestIterator> iter = CreateIterator();
ASSERT_THAT(iter->OpenNextEntry(&entry), IsOk());
entry->Close();
EXPECT_NE(net::OK, iter->OpenNextEntry(&entry));
EXPECT_EQ(1, cache_->GetEntryCount());
}
TEST_F(DiskCacheBackendTest, InvalidEntry8) {
BackendInvalidEntry8();
}
TEST_F(DiskCacheBackendTest, NewEvictionInvalidEntry8) {
SetNewEviction();
BackendInvalidEntry8();
}
// Tests handling of corrupt entries detected by enumerations. Note that these
// tests (xx9 to xx11) are basically just going though slightly different
// codepaths so they are tighlty coupled with the code, but that is better than
// not testing error handling code.
void DiskCacheBackendTest::BackendInvalidEntry9(bool eviction) {
const int kSize = 0x3000; // 12 kB.
SetMaxSize(kSize * 10);
InitCache();
std::string first("some key");
std::string second("something else");
disk_cache::Entry* entry;
ASSERT_THAT(CreateEntry(first, &entry), IsOk());
entry->Close();
ASSERT_THAT(CreateEntry(second, &entry), IsOk());
// Corrupt this entry.
disk_cache::EntryImpl* entry_impl =
static_cast<disk_cache::EntryImpl*>(entry);
entry_impl->entry()->Data()->state = 0xbad;
entry_impl->entry()->Store();
entry->Close();
FlushQueueForTest();
EXPECT_EQ(2, cache_->GetEntryCount());
if (eviction) {
TrimForTest(false);
EXPECT_EQ(1, cache_->GetEntryCount());
TrimForTest(false);
EXPECT_EQ(1, cache_->GetEntryCount());
} else {
// We should detect the problem through the list, but we should not delete
// the entry, just fail the iteration.
std::unique_ptr<TestIterator> iter = CreateIterator();
EXPECT_NE(net::OK, iter->OpenNextEntry(&entry));
// Now a full iteration will work, and return one entry.
ASSERT_THAT(iter->OpenNextEntry(&entry), IsOk());
entry->Close();
EXPECT_NE(net::OK, iter->OpenNextEntry(&entry));
// This should detect what's left of the bad entry.
EXPECT_NE(net::OK, OpenEntry(second, &entry));
EXPECT_EQ(2, cache_->GetEntryCount());
}
DisableIntegrityCheck();
}
TEST_F(DiskCacheBackendTest, InvalidEntry9) {
BackendInvalidEntry9(false);
}
TEST_F(DiskCacheBackendTest, NewEvictionInvalidEntry9) {
SetNewEviction();
BackendInvalidEntry9(false);
}
TEST_F(DiskCacheBackendTest, TrimInvalidEntry9) {
BackendInvalidEntry9(true);
}
TEST_F(DiskCacheBackendTest, NewEvictionTrimInvalidEntry9) {
SetNewEviction();
BackendInvalidEntry9(true);
}
// Tests handling of corrupt entries detected by enumerations.
void DiskCacheBackendTest::BackendInvalidEntry10(bool eviction) {
const int kSize = 0x3000; // 12 kB.
SetMaxSize(kSize * 10);
SetNewEviction();
InitCache();
std::string first("some key");
std::string second("something else");
disk_cache::Entry* entry;
ASSERT_THAT(CreateEntry(first, &entry), IsOk());
entry->Close();
ASSERT_THAT(OpenEntry(first, &entry), IsOk());
EXPECT_EQ(0, WriteData(entry, 0, 200, NULL, 0, false));
entry->Close();
ASSERT_THAT(CreateEntry(second, &entry), IsOk());
// Corrupt this entry.
disk_cache::EntryImpl* entry_impl =
static_cast<disk_cache::EntryImpl*>(entry);
entry_impl->entry()->Data()->state = 0xbad;
entry_impl->entry()->Store();
entry->Close();
ASSERT_THAT(CreateEntry("third", &entry), IsOk());
entry->Close();
EXPECT_EQ(3, cache_->GetEntryCount());
// We have:
// List 0: third -> second (bad).
// List 1: first.
if (eviction) {
// Detection order: second -> first -> third.
TrimForTest(false);
EXPECT_EQ(3, cache_->GetEntryCount());
TrimForTest(false);
EXPECT_EQ(2, cache_->GetEntryCount());
TrimForTest(false);
EXPECT_EQ(1, cache_->GetEntryCount());
} else {
// Detection order: third -> second -> first.
// We should detect the problem through the list, but we should not delete
// the entry.
std::unique_ptr<TestIterator> iter = CreateIterator();
ASSERT_THAT(iter->OpenNextEntry(&entry), IsOk());
entry->Close();
ASSERT_THAT(iter->OpenNextEntry(&entry), IsOk());
EXPECT_EQ(first, entry->GetKey());
entry->Close();
EXPECT_NE(net::OK, iter->OpenNextEntry(&entry));
}
DisableIntegrityCheck();
}
TEST_F(DiskCacheBackendTest, InvalidEntry10) {
BackendInvalidEntry10(false);
}
TEST_F(DiskCacheBackendTest, TrimInvalidEntry10) {
BackendInvalidEntry10(true);
}
// Tests handling of corrupt entries detected by enumerations.
void DiskCacheBackendTest::BackendInvalidEntry11(bool eviction) {
const int kSize = 0x3000; // 12 kB.
SetMaxSize(kSize * 10);
SetNewEviction();
InitCache();
std::string first("some key");
std::string second("something else");
disk_cache::Entry* entry;
ASSERT_THAT(CreateEntry(first, &entry), IsOk());
entry->Close();
ASSERT_THAT(OpenEntry(first, &entry), IsOk());
EXPECT_EQ(0, WriteData(entry, 0, 200, NULL, 0, false));
entry->Close();
ASSERT_THAT(CreateEntry(second, &entry), IsOk());
entry->Close();
ASSERT_THAT(OpenEntry(second, &entry), IsOk());
EXPECT_EQ(0, WriteData(entry, 0, 200, NULL, 0, false));
// Corrupt this entry.
disk_cache::EntryImpl* entry_impl =
static_cast<disk_cache::EntryImpl*>(entry);
entry_impl->entry()->Data()->state = 0xbad;
entry_impl->entry()->Store();
entry->Close();
ASSERT_THAT(CreateEntry("third", &entry), IsOk());
entry->Close();
FlushQueueForTest();
EXPECT_EQ(3, cache_->GetEntryCount());
// We have:
// List 0: third.
// List 1: second (bad) -> first.
if (eviction) {
// Detection order: third -> first -> second.
TrimForTest(false);
EXPECT_EQ(2, cache_->GetEntryCount());
TrimForTest(false);
EXPECT_EQ(1, cache_->GetEntryCount());
TrimForTest(false);
EXPECT_EQ(1, cache_->GetEntryCount());
} else {
// Detection order: third -> second.
// We should detect the problem through the list, but we should not delete
// the entry, just fail the iteration.
std::unique_ptr<TestIterator> iter = CreateIterator();
ASSERT_THAT(iter->OpenNextEntry(&entry), IsOk());
entry->Close();
EXPECT_NE(net::OK, iter->OpenNextEntry(&entry));
// Now a full iteration will work, and return two entries.
ASSERT_THAT(iter->OpenNextEntry(&entry),