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chromium / chromium / src / 71.0.3578.80 / . / net / disk_cache / entry_unittest.cc
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// 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 <utility>
#include "base/bind.h"
#include "base/bind_helpers.h"
#include "base/files/file.h"
#include "base/files/file_util.h"
#include "base/macros.h"
#include "base/metrics/field_trial.h"
#include "base/metrics/field_trial_param_associator.h"
#include "base/run_loop.h"
#include "base/strings/string_number_conversions.h"
#include "base/strings/string_util.h"
#include "base/test/metrics/histogram_tester.h"
#include "base/test/mock_entropy_provider.h"
#include "base/test/scoped_feature_list.h"
#include "base/threading/platform_thread.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/blockfile/backend_impl.h"
#include "net/disk_cache/blockfile/entry_impl.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_entry_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_entry_impl.h"
#include "net/disk_cache/simple/simple_histogram_enums.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 base::Time;
using disk_cache::ScopedEntryPtr;
// Tests that can run with different types of caches.
class DiskCacheEntryTest : public DiskCacheTestWithCache {
public:
void InternalSyncIOBackground(disk_cache::Entry* entry);
void ExternalSyncIOBackground(disk_cache::Entry* entry);
protected:
void InternalSyncIO();
void InternalAsyncIO();
void ExternalSyncIO();
void ExternalAsyncIO();
void ReleaseBuffer(int stream_index);
void StreamAccess();
void GetKey();
void GetTimes(int stream_index);
void GrowData(int stream_index);
void TruncateData(int stream_index);
void ZeroLengthIO(int stream_index);
void Buffering();
void SizeAtCreate();
void SizeChanges(int stream_index);
void ReuseEntry(int size, int stream_index);
void InvalidData(int stream_index);
void ReadWriteDestroyBuffer(int stream_index);
void DoomNormalEntry();
void DoomEntryNextToOpenEntry();
void DoomedEntry(int stream_index);
void BasicSparseIO();
void HugeSparseIO();
void GetAvailableRange();
void CouldBeSparse();
void UpdateSparseEntry();
void DoomSparseEntry();
void PartialSparseEntry();
bool SimpleCacheMakeBadChecksumEntry(const std::string& key, int data_size);
bool SimpleCacheThirdStreamFileExists(const char* key);
void SyncDoomEntry(const char* key);
void UseAfterBackendDestruction();
};
// This part of the test runs on the background thread.
void DiskCacheEntryTest::InternalSyncIOBackground(disk_cache::Entry* entry) {
const int kSize1 = 10;
scoped_refptr<net::IOBuffer> buffer1 =
base::MakeRefCounted<net::IOBuffer>(kSize1);
CacheTestFillBuffer(buffer1->data(), kSize1, false);
EXPECT_EQ(0, entry->ReadData(0, 0, buffer1.get(), kSize1,
net::CompletionOnceCallback()));
base::strlcpy(buffer1->data(), "the data", kSize1);
EXPECT_EQ(10, entry->WriteData(0, 0, buffer1.get(), kSize1,
net::CompletionOnceCallback(), false));
memset(buffer1->data(), 0, kSize1);
EXPECT_EQ(10, entry->ReadData(0, 0, buffer1.get(), kSize1,
net::CompletionOnceCallback()));
EXPECT_STREQ("the data", buffer1->data());
const int kSize2 = 5000;
const int kSize3 = 10000;
scoped_refptr<net::IOBuffer> buffer2 =
base::MakeRefCounted<net::IOBuffer>(kSize2);
scoped_refptr<net::IOBuffer> buffer3 =
base::MakeRefCounted<net::IOBuffer>(kSize3);
memset(buffer3->data(), 0, kSize3);
CacheTestFillBuffer(buffer2->data(), kSize2, false);
base::strlcpy(buffer2->data(), "The really big data goes here", kSize2);
EXPECT_EQ(5000, entry->WriteData(1, 1500, buffer2.get(), kSize2,
net::CompletionOnceCallback(), false));
memset(buffer2->data(), 0, kSize2);
EXPECT_EQ(4989, entry->ReadData(1, 1511, buffer2.get(), kSize2,
net::CompletionOnceCallback()));
EXPECT_STREQ("big data goes here", buffer2->data());
EXPECT_EQ(5000, entry->ReadData(1, 0, buffer2.get(), kSize2,
net::CompletionOnceCallback()));
EXPECT_EQ(0, memcmp(buffer2->data(), buffer3->data(), 1500));
EXPECT_EQ(1500, entry->ReadData(1, 5000, buffer2.get(), kSize2,
net::CompletionOnceCallback()));
EXPECT_EQ(0, entry->ReadData(1, 6500, buffer2.get(), kSize2,
net::CompletionOnceCallback()));
EXPECT_EQ(6500, entry->ReadData(1, 0, buffer3.get(), kSize3,
net::CompletionOnceCallback()));
EXPECT_EQ(8192, entry->WriteData(1, 0, buffer3.get(), 8192,
net::CompletionOnceCallback(), false));
EXPECT_EQ(8192, entry->ReadData(1, 0, buffer3.get(), kSize3,
net::CompletionOnceCallback()));
EXPECT_EQ(8192, entry->GetDataSize(1));
// We need to delete the memory buffer on this thread.
EXPECT_EQ(
0, entry->WriteData(0, 0, NULL, 0, net::CompletionOnceCallback(), true));
EXPECT_EQ(
0, entry->WriteData(1, 0, NULL, 0, net::CompletionOnceCallback(), true));
}
// We need to support synchronous IO even though it is not a supported operation
// from the point of view of the disk cache's public interface, because we use
// it internally, not just by a few tests, but as part of the implementation
// (see sparse_control.cc, for example).
void DiskCacheEntryTest::InternalSyncIO() {
disk_cache::Entry* entry = NULL;
ASSERT_THAT(CreateEntry("the first key", &entry), IsOk());
ASSERT_TRUE(NULL != entry);
// The bulk of the test runs from within the callback, on the cache thread.
RunTaskForTest(base::Bind(&DiskCacheEntryTest::InternalSyncIOBackground,
base::Unretained(this),
entry));
entry->Doom();
entry->Close();
FlushQueueForTest();
EXPECT_EQ(0, cache_->GetEntryCount());
}
TEST_F(DiskCacheEntryTest, InternalSyncIO) {
InitCache();
InternalSyncIO();
}
TEST_F(DiskCacheEntryTest, MemoryOnlyInternalSyncIO) {
SetMemoryOnlyMode();
InitCache();
InternalSyncIO();
}
void DiskCacheEntryTest::InternalAsyncIO() {
disk_cache::Entry* entry = NULL;
ASSERT_THAT(CreateEntry("the first key", &entry), IsOk());
ASSERT_TRUE(NULL != entry);
// Avoid using internal buffers for the test. We have to write something to
// the entry and close it so that we flush the internal buffer to disk. After
// that, IO operations will be really hitting the disk. We don't care about
// the content, so just extending the entry is enough (all extensions zero-
// fill any holes).
EXPECT_EQ(0, WriteData(entry, 0, 15 * 1024, NULL, 0, false));
EXPECT_EQ(0, WriteData(entry, 1, 15 * 1024, NULL, 0, false));
entry->Close();
ASSERT_THAT(OpenEntry("the first key", &entry), IsOk());
MessageLoopHelper helper;
// Let's verify that each IO goes to the right callback object.
CallbackTest callback1(&helper, false);
CallbackTest callback2(&helper, false);
CallbackTest callback3(&helper, false);
CallbackTest callback4(&helper, false);
CallbackTest callback5(&helper, false);
CallbackTest callback6(&helper, false);
CallbackTest callback7(&helper, false);
CallbackTest callback8(&helper, false);
CallbackTest callback9(&helper, false);
CallbackTest callback10(&helper, false);
CallbackTest callback11(&helper, false);
CallbackTest callback12(&helper, false);
CallbackTest callback13(&helper, false);
const int kSize1 = 10;
const int kSize2 = 5000;
const int kSize3 = 10000;
scoped_refptr<net::IOBuffer> buffer1 =
base::MakeRefCounted<net::IOBuffer>(kSize1);
scoped_refptr<net::IOBuffer> buffer2 =
base::MakeRefCounted<net::IOBuffer>(kSize2);
scoped_refptr<net::IOBuffer> buffer3 =
base::MakeRefCounted<net::IOBuffer>(kSize3);
CacheTestFillBuffer(buffer1->data(), kSize1, false);
CacheTestFillBuffer(buffer2->data(), kSize2, false);
CacheTestFillBuffer(buffer3->data(), kSize3, false);
EXPECT_EQ(0,
entry->ReadData(
0,
15 * 1024,
buffer1.get(),
kSize1,
base::Bind(&CallbackTest::Run, base::Unretained(&callback1))));
base::strlcpy(buffer1->data(), "the data", kSize1);
int expected = 0;
int ret = entry->WriteData(
0,
0,
buffer1.get(),
kSize1,
base::Bind(&CallbackTest::Run, base::Unretained(&callback2)),
false);
EXPECT_TRUE(10 == ret || net::ERR_IO_PENDING == ret);
if (net::ERR_IO_PENDING == ret)
expected++;
EXPECT_TRUE(helper.WaitUntilCacheIoFinished(expected));
memset(buffer2->data(), 0, kSize2);
ret = entry->ReadData(
0,
0,
buffer2.get(),
kSize1,
base::Bind(&CallbackTest::Run, base::Unretained(&callback3)));
EXPECT_TRUE(10 == ret || net::ERR_IO_PENDING == ret);
if (net::ERR_IO_PENDING == ret)
expected++;
EXPECT_TRUE(helper.WaitUntilCacheIoFinished(expected));
EXPECT_STREQ("the data", buffer2->data());
base::strlcpy(buffer2->data(), "The really big data goes here", kSize2);
ret = entry->WriteData(
1,
1500,
buffer2.get(),
kSize2,
base::Bind(&CallbackTest::Run, base::Unretained(&callback4)),
true);
EXPECT_TRUE(5000 == ret || net::ERR_IO_PENDING == ret);
if (net::ERR_IO_PENDING == ret)
expected++;
EXPECT_TRUE(helper.WaitUntilCacheIoFinished(expected));
memset(buffer3->data(), 0, kSize3);
ret = entry->ReadData(
1,
1511,
buffer3.get(),
kSize2,
base::Bind(&CallbackTest::Run, base::Unretained(&callback5)));
EXPECT_TRUE(4989 == ret || net::ERR_IO_PENDING == ret);
if (net::ERR_IO_PENDING == ret)
expected++;
EXPECT_TRUE(helper.WaitUntilCacheIoFinished(expected));
EXPECT_STREQ("big data goes here", buffer3->data());
ret = entry->ReadData(
1,
0,
buffer2.get(),
kSize2,
base::Bind(&CallbackTest::Run, base::Unretained(&callback6)));
EXPECT_TRUE(5000 == ret || net::ERR_IO_PENDING == ret);
if (net::ERR_IO_PENDING == ret)
expected++;
memset(buffer3->data(), 0, kSize3);
EXPECT_TRUE(helper.WaitUntilCacheIoFinished(expected));
EXPECT_EQ(0, memcmp(buffer2->data(), buffer3->data(), 1500));
ret = entry->ReadData(
1,
5000,
buffer2.get(),
kSize2,
base::Bind(&CallbackTest::Run, base::Unretained(&callback7)));
EXPECT_TRUE(1500 == ret || net::ERR_IO_PENDING == ret);
if (net::ERR_IO_PENDING == ret)
expected++;
ret = entry->ReadData(
1,
0,
buffer3.get(),
kSize3,
base::Bind(&CallbackTest::Run, base::Unretained(&callback9)));
EXPECT_TRUE(6500 == ret || net::ERR_IO_PENDING == ret);
if (net::ERR_IO_PENDING == ret)
expected++;
ret = entry->WriteData(
1,
0,
buffer3.get(),
8192,
base::Bind(&CallbackTest::Run, base::Unretained(&callback10)),
true);
EXPECT_TRUE(8192 == ret || net::ERR_IO_PENDING == ret);
if (net::ERR_IO_PENDING == ret)
expected++;
EXPECT_TRUE(helper.WaitUntilCacheIoFinished(expected));
ret = entry->ReadData(
1,
0,
buffer3.get(),
kSize3,
base::Bind(&CallbackTest::Run, base::Unretained(&callback11)));
EXPECT_TRUE(8192 == ret || net::ERR_IO_PENDING == ret);
if (net::ERR_IO_PENDING == ret)
expected++;
EXPECT_EQ(8192, entry->GetDataSize(1));
ret = entry->ReadData(
0,
0,
buffer1.get(),
kSize1,
base::Bind(&CallbackTest::Run, base::Unretained(&callback12)));
EXPECT_TRUE(10 == ret || net::ERR_IO_PENDING == ret);
if (net::ERR_IO_PENDING == ret)
expected++;
ret = entry->ReadData(
1,
0,
buffer2.get(),
kSize2,
base::Bind(&CallbackTest::Run, base::Unretained(&callback13)));
EXPECT_TRUE(5000 == ret || net::ERR_IO_PENDING == ret);
if (net::ERR_IO_PENDING == ret)
expected++;
EXPECT_TRUE(helper.WaitUntilCacheIoFinished(expected));
EXPECT_FALSE(helper.callback_reused_error());
entry->Doom();
entry->Close();
FlushQueueForTest();
EXPECT_EQ(0, cache_->GetEntryCount());
}
TEST_F(DiskCacheEntryTest, InternalAsyncIO) {
InitCache();
InternalAsyncIO();
}
TEST_F(DiskCacheEntryTest, MemoryOnlyInternalAsyncIO) {
SetMemoryOnlyMode();
InitCache();
InternalAsyncIO();
}
// This part of the test runs on the background thread.
void DiskCacheEntryTest::ExternalSyncIOBackground(disk_cache::Entry* entry) {
const int kSize1 = 17000;
const int kSize2 = 25000;
scoped_refptr<net::IOBuffer> buffer1 =
base::MakeRefCounted<net::IOBuffer>(kSize1);
scoped_refptr<net::IOBuffer> buffer2 =
base::MakeRefCounted<net::IOBuffer>(kSize2);
CacheTestFillBuffer(buffer1->data(), kSize1, false);
CacheTestFillBuffer(buffer2->data(), kSize2, false);
base::strlcpy(buffer1->data(), "the data", kSize1);
EXPECT_EQ(17000, entry->WriteData(0, 0, buffer1.get(), kSize1,
net::CompletionOnceCallback(), false));
memset(buffer1->data(), 0, kSize1);
EXPECT_EQ(17000, entry->ReadData(0, 0, buffer1.get(), kSize1,
net::CompletionOnceCallback()));
EXPECT_STREQ("the data", buffer1->data());
base::strlcpy(buffer2->data(), "The really big data goes here", kSize2);
EXPECT_EQ(25000, entry->WriteData(1, 10000, buffer2.get(), kSize2,
net::CompletionOnceCallback(), false));
memset(buffer2->data(), 0, kSize2);
EXPECT_EQ(24989, entry->ReadData(1, 10011, buffer2.get(), kSize2,
net::CompletionOnceCallback()));
EXPECT_STREQ("big data goes here", buffer2->data());
EXPECT_EQ(25000, entry->ReadData(1, 0, buffer2.get(), kSize2,
net::CompletionOnceCallback()));
EXPECT_EQ(5000, entry->ReadData(1, 30000, buffer2.get(), kSize2,
net::CompletionOnceCallback()));
EXPECT_EQ(0, entry->ReadData(1, 35000, buffer2.get(), kSize2,
net::CompletionOnceCallback()));
EXPECT_EQ(17000, entry->ReadData(1, 0, buffer1.get(), kSize1,
net::CompletionOnceCallback()));
EXPECT_EQ(17000, entry->WriteData(1, 20000, buffer1.get(), kSize1,
net::CompletionOnceCallback(), false));
EXPECT_EQ(37000, entry->GetDataSize(1));
// We need to delete the memory buffer on this thread.
EXPECT_EQ(
0, entry->WriteData(0, 0, NULL, 0, net::CompletionOnceCallback(), true));
EXPECT_EQ(
0, entry->WriteData(1, 0, NULL, 0, net::CompletionOnceCallback(), true));
}
void DiskCacheEntryTest::ExternalSyncIO() {
disk_cache::Entry* entry;
ASSERT_THAT(CreateEntry("the first key", &entry), IsOk());
// The bulk of the test runs from within the callback, on the cache thread.
RunTaskForTest(base::Bind(&DiskCacheEntryTest::ExternalSyncIOBackground,
base::Unretained(this),
entry));
entry->Doom();
entry->Close();
FlushQueueForTest();
EXPECT_EQ(0, cache_->GetEntryCount());
}
TEST_F(DiskCacheEntryTest, ExternalSyncIO) {
InitCache();
ExternalSyncIO();
}
TEST_F(DiskCacheEntryTest, ExternalSyncIONoBuffer) {
InitCache();
cache_impl_->SetFlags(disk_cache::kNoBuffering);
ExternalSyncIO();
}
TEST_F(DiskCacheEntryTest, MemoryOnlyExternalSyncIO) {
SetMemoryOnlyMode();
InitCache();
ExternalSyncIO();
}
void DiskCacheEntryTest::ExternalAsyncIO() {
disk_cache::Entry* entry;
ASSERT_THAT(CreateEntry("the first key", &entry), IsOk());
int expected = 0;
MessageLoopHelper helper;
// Let's verify that each IO goes to the right callback object.
CallbackTest callback1(&helper, false);
CallbackTest callback2(&helper, false);
CallbackTest callback3(&helper, false);
CallbackTest callback4(&helper, false);
CallbackTest callback5(&helper, false);
CallbackTest callback6(&helper, false);
CallbackTest callback7(&helper, false);
CallbackTest callback8(&helper, false);
CallbackTest callback9(&helper, false);
const int kSize1 = 17000;
const int kSize2 = 25000;
const int kSize3 = 25000;
scoped_refptr<net::IOBuffer> buffer1 =
base::MakeRefCounted<net::IOBuffer>(kSize1);
scoped_refptr<net::IOBuffer> buffer2 =
base::MakeRefCounted<net::IOBuffer>(kSize2);
scoped_refptr<net::IOBuffer> buffer3 =
base::MakeRefCounted<net::IOBuffer>(kSize3);
CacheTestFillBuffer(buffer1->data(), kSize1, false);
CacheTestFillBuffer(buffer2->data(), kSize2, false);
CacheTestFillBuffer(buffer3->data(), kSize3, false);
base::strlcpy(buffer1->data(), "the data", kSize1);
int ret = entry->WriteData(
0,
0,
buffer1.get(),
kSize1,
base::Bind(&CallbackTest::Run, base::Unretained(&callback1)),
false);
EXPECT_TRUE(17000 == ret || net::ERR_IO_PENDING == ret);
if (net::ERR_IO_PENDING == ret)
expected++;
EXPECT_TRUE(helper.WaitUntilCacheIoFinished(expected));
memset(buffer2->data(), 0, kSize1);
ret = entry->ReadData(
0,
0,
buffer2.get(),
kSize1,
base::Bind(&CallbackTest::Run, base::Unretained(&callback2)));
EXPECT_TRUE(17000 == ret || net::ERR_IO_PENDING == ret);
if (net::ERR_IO_PENDING == ret)
expected++;
EXPECT_TRUE(helper.WaitUntilCacheIoFinished(expected));
EXPECT_STREQ("the data", buffer2->data());
base::strlcpy(buffer2->data(), "The really big data goes here", kSize2);
ret = entry->WriteData(
1,
10000,
buffer2.get(),
kSize2,
base::Bind(&CallbackTest::Run, base::Unretained(&callback3)),
false);
EXPECT_TRUE(25000 == ret || net::ERR_IO_PENDING == ret);
if (net::ERR_IO_PENDING == ret)
expected++;
EXPECT_TRUE(helper.WaitUntilCacheIoFinished(expected));
memset(buffer3->data(), 0, kSize3);
ret = entry->ReadData(
1,
10011,
buffer3.get(),
kSize3,
base::Bind(&CallbackTest::Run, base::Unretained(&callback4)));
EXPECT_TRUE(24989 == ret || net::ERR_IO_PENDING == ret);
if (net::ERR_IO_PENDING == ret)
expected++;
EXPECT_TRUE(helper.WaitUntilCacheIoFinished(expected));
EXPECT_STREQ("big data goes here", buffer3->data());
ret = entry->ReadData(
1,
0,
buffer2.get(),
kSize2,
base::Bind(&CallbackTest::Run, base::Unretained(&callback5)));
EXPECT_TRUE(25000 == ret || net::ERR_IO_PENDING == ret);
if (net::ERR_IO_PENDING == ret)
expected++;
EXPECT_TRUE(helper.WaitUntilCacheIoFinished(expected));
memset(buffer3->data(), 0, kSize3);
EXPECT_EQ(0, memcmp(buffer2->data(), buffer3->data(), 10000));
ret = entry->ReadData(
1,
30000,
buffer2.get(),
kSize2,
base::Bind(&CallbackTest::Run, base::Unretained(&callback6)));
EXPECT_TRUE(5000 == ret || net::ERR_IO_PENDING == ret);
if (net::ERR_IO_PENDING == ret)
expected++;
ret = entry->ReadData(
1, 35000, buffer2.get(), kSize2,
base::Bind(&CallbackTest::Run, base::Unretained(&callback7)));
EXPECT_TRUE(0 == ret || net::ERR_IO_PENDING == ret);
if (net::ERR_IO_PENDING == ret)
expected++;
ret = entry->ReadData(
1,
0,
buffer1.get(),
kSize1,
base::Bind(&CallbackTest::Run, base::Unretained(&callback8)));
EXPECT_TRUE(17000 == ret || net::ERR_IO_PENDING == ret);
if (net::ERR_IO_PENDING == ret)
expected++;
ret = entry->WriteData(
1,
20000,
buffer3.get(),
kSize1,
base::Bind(&CallbackTest::Run, base::Unretained(&callback9)),
false);
EXPECT_TRUE(17000 == ret || net::ERR_IO_PENDING == ret);
if (net::ERR_IO_PENDING == ret)
expected++;
EXPECT_TRUE(helper.WaitUntilCacheIoFinished(expected));
EXPECT_EQ(37000, entry->GetDataSize(1));
EXPECT_FALSE(helper.callback_reused_error());
entry->Doom();
entry->Close();
FlushQueueForTest();
EXPECT_EQ(0, cache_->GetEntryCount());
}
TEST_F(DiskCacheEntryTest, ExternalAsyncIO) {
InitCache();
ExternalAsyncIO();
}
// TODO(http://crbug.com/497101): This test is flaky.
#if defined(OS_IOS)
#define MAYBE_ExternalAsyncIONoBuffer DISABLED_ExternalAsyncIONoBuffer
#else
#define MAYBE_ExternalAsyncIONoBuffer ExternalAsyncIONoBuffer
#endif
TEST_F(DiskCacheEntryTest, MAYBE_ExternalAsyncIONoBuffer) {
InitCache();
cache_impl_->SetFlags(disk_cache::kNoBuffering);
ExternalAsyncIO();
}
TEST_F(DiskCacheEntryTest, MemoryOnlyExternalAsyncIO) {
SetMemoryOnlyMode();
InitCache();
ExternalAsyncIO();
}
// Tests that IOBuffers are not referenced after IO completes.
void DiskCacheEntryTest::ReleaseBuffer(int stream_index) {
disk_cache::Entry* entry = NULL;
ASSERT_THAT(CreateEntry("the first key", &entry), IsOk());
ASSERT_TRUE(NULL != entry);
const int kBufferSize = 1024;
scoped_refptr<net::IOBuffer> buffer =
base::MakeRefCounted<net::IOBuffer>(kBufferSize);
CacheTestFillBuffer(buffer->data(), kBufferSize, false);
net::ReleaseBufferCompletionCallback cb(buffer.get());
int rv = entry->WriteData(
stream_index, 0, buffer.get(), kBufferSize, cb.callback(), false);
EXPECT_EQ(kBufferSize, cb.GetResult(rv));
entry->Close();
}
TEST_F(DiskCacheEntryTest, ReleaseBuffer) {
InitCache();
cache_impl_->SetFlags(disk_cache::kNoBuffering);
ReleaseBuffer(0);
}
TEST_F(DiskCacheEntryTest, MemoryOnlyReleaseBuffer) {
SetMemoryOnlyMode();
InitCache();
ReleaseBuffer(0);
}
void DiskCacheEntryTest::StreamAccess() {
disk_cache::Entry* entry = NULL;
ASSERT_THAT(CreateEntry("the first key", &entry), IsOk());
ASSERT_TRUE(NULL != entry);
const int kBufferSize = 1024;
const int kNumStreams = 3;
scoped_refptr<net::IOBuffer> reference_buffers[kNumStreams];
for (int i = 0; i < kNumStreams; i++) {
reference_buffers[i] = base::MakeRefCounted<net::IOBuffer>(kBufferSize);
CacheTestFillBuffer(reference_buffers[i]->data(), kBufferSize, false);
}
scoped_refptr<net::IOBuffer> buffer1 =
base::MakeRefCounted<net::IOBuffer>(kBufferSize);
for (int i = 0; i < kNumStreams; i++) {
EXPECT_EQ(
kBufferSize,
WriteData(entry, i, 0, reference_buffers[i].get(), kBufferSize, false));
memset(buffer1->data(), 0, kBufferSize);
EXPECT_EQ(kBufferSize, ReadData(entry, i, 0, buffer1.get(), kBufferSize));
EXPECT_EQ(
0, memcmp(reference_buffers[i]->data(), buffer1->data(), kBufferSize));
}
EXPECT_EQ(net::ERR_INVALID_ARGUMENT,
ReadData(entry, kNumStreams, 0, buffer1.get(), kBufferSize));
entry->Close();
// Open the entry and read it in chunks, including a read past the end.
ASSERT_THAT(OpenEntry("the first key", &entry), IsOk());
ASSERT_TRUE(NULL != entry);
const int kReadBufferSize = 600;
const int kFinalReadSize = kBufferSize - kReadBufferSize;
static_assert(kFinalReadSize < kReadBufferSize,
"should be exactly two reads");
scoped_refptr<net::IOBuffer> buffer2 =
base::MakeRefCounted<net::IOBuffer>(kReadBufferSize);
for (int i = 0; i < kNumStreams; i++) {
memset(buffer2->data(), 0, kReadBufferSize);
EXPECT_EQ(kReadBufferSize,
ReadData(entry, i, 0, buffer2.get(), kReadBufferSize));
EXPECT_EQ(
0,
memcmp(reference_buffers[i]->data(), buffer2->data(), kReadBufferSize));
memset(buffer2->data(), 0, kReadBufferSize);
EXPECT_EQ(
kFinalReadSize,
ReadData(entry, i, kReadBufferSize, buffer2.get(), kReadBufferSize));
EXPECT_EQ(0,
memcmp(reference_buffers[i]->data() + kReadBufferSize,
buffer2->data(),
kFinalReadSize));
}
entry->Close();
}
TEST_F(DiskCacheEntryTest, StreamAccess) {
InitCache();
StreamAccess();
}
TEST_F(DiskCacheEntryTest, MemoryOnlyStreamAccess) {
SetMemoryOnlyMode();
InitCache();
StreamAccess();
}
void DiskCacheEntryTest::GetKey() {
std::string key("the first key");
disk_cache::Entry* entry;
ASSERT_THAT(CreateEntry(key, &entry), IsOk());
EXPECT_EQ(key, entry->GetKey()) << "short key";
entry->Close();
int seed = static_cast<int>(Time::Now().ToInternalValue());
srand(seed);
char key_buffer[20000];
CacheTestFillBuffer(key_buffer, 3000, true);
key_buffer[1000] = '\0';
key = key_buffer;
ASSERT_THAT(CreateEntry(key, &entry), IsOk());
EXPECT_TRUE(key == entry->GetKey()) << "1000 bytes key";
entry->Close();
key_buffer[1000] = 'p';
key_buffer[3000] = '\0';
key = key_buffer;
ASSERT_THAT(CreateEntry(key, &entry), IsOk());
EXPECT_TRUE(key == entry->GetKey()) << "medium size key";
entry->Close();
CacheTestFillBuffer(key_buffer, sizeof(key_buffer), true);
key_buffer[19999] = '\0';
key = key_buffer;
ASSERT_THAT(CreateEntry(key, &entry), IsOk());
EXPECT_TRUE(key == entry->GetKey()) << "long key";
entry->Close();
CacheTestFillBuffer(key_buffer, 0x4000, true);
key_buffer[0x4000] = '\0';
key = key_buffer;
ASSERT_THAT(CreateEntry(key, &entry), IsOk());
EXPECT_TRUE(key == entry->GetKey()) << "16KB key";
entry->Close();
}
TEST_F(DiskCacheEntryTest, GetKey) {
InitCache();
GetKey();
}
TEST_F(DiskCacheEntryTest, MemoryOnlyGetKey) {
SetMemoryOnlyMode();
InitCache();
GetKey();
}
void DiskCacheEntryTest::GetTimes(int stream_index) {
std::string key("the first key");
disk_cache::Entry* entry;
Time t1 = Time::Now();
ASSERT_THAT(CreateEntry(key, &entry), IsOk());
EXPECT_TRUE(entry->GetLastModified() >= t1);
EXPECT_TRUE(entry->GetLastModified() == entry->GetLastUsed());
AddDelay();
Time t2 = Time::Now();
EXPECT_TRUE(t2 > t1);
EXPECT_EQ(0, WriteData(entry, stream_index, 200, NULL, 0, false));
if (type_ == net::APP_CACHE) {
EXPECT_TRUE(entry->GetLastModified() < t2);
} else {
EXPECT_TRUE(entry->GetLastModified() >= t2);
}
EXPECT_TRUE(entry->GetLastModified() == entry->GetLastUsed());
AddDelay();
Time t3 = Time::Now();
EXPECT_TRUE(t3 > t2);
const int kSize = 200;
scoped_refptr<net::IOBuffer> buffer =
base::MakeRefCounted<net::IOBuffer>(kSize);
EXPECT_EQ(kSize, ReadData(entry, stream_index, 0, buffer.get(), kSize));
if (type_ == net::APP_CACHE) {
EXPECT_TRUE(entry->GetLastUsed() < t2);
EXPECT_TRUE(entry->GetLastModified() < t2);
} else if (type_ == net::SHADER_CACHE) {
EXPECT_TRUE(entry->GetLastUsed() < t3);
EXPECT_TRUE(entry->GetLastModified() < t3);
} else {
EXPECT_TRUE(entry->GetLastUsed() >= t3);
EXPECT_TRUE(entry->GetLastModified() < t3);
}
entry->Close();
}
TEST_F(DiskCacheEntryTest, GetTimes) {
InitCache();
GetTimes(0);
}
TEST_F(DiskCacheEntryTest, MemoryOnlyGetTimes) {
SetMemoryOnlyMode();
InitCache();
GetTimes(0);
}
TEST_F(DiskCacheEntryTest, AppCacheGetTimes) {
SetCacheType(net::APP_CACHE);
InitCache();
GetTimes(0);
}
TEST_F(DiskCacheEntryTest, ShaderCacheGetTimes) {
SetCacheType(net::SHADER_CACHE);
InitCache();
GetTimes(0);
}
void DiskCacheEntryTest::GrowData(int stream_index) {
std::string key1("the first key");
disk_cache::Entry* entry;
ASSERT_THAT(CreateEntry(key1, &entry), IsOk());
const int kSize = 20000;
scoped_refptr<net::IOBuffer> buffer1 =
base::MakeRefCounted<net::IOBuffer>(kSize);
scoped_refptr<net::IOBuffer> buffer2 =
base::MakeRefCounted<net::IOBuffer>(kSize);
CacheTestFillBuffer(buffer1->data(), kSize, false);
memset(buffer2->data(), 0, kSize);
base::strlcpy(buffer1->data(), "the data", kSize);
EXPECT_EQ(10, WriteData(entry, stream_index, 0, buffer1.get(), 10, false));
EXPECT_EQ(10, ReadData(entry, stream_index, 0, buffer2.get(), 10));
EXPECT_STREQ("the data", buffer2->data());
EXPECT_EQ(10, entry->GetDataSize(stream_index));
EXPECT_EQ(2000,
WriteData(entry, stream_index, 0, buffer1.get(), 2000, false));
EXPECT_EQ(2000, entry->GetDataSize(stream_index));
EXPECT_EQ(2000, ReadData(entry, stream_index, 0, buffer2.get(), 2000));
EXPECT_TRUE(!memcmp(buffer1->data(), buffer2->data(), 2000));
EXPECT_EQ(20000,
WriteData(entry, stream_index, 0, buffer1.get(), kSize, false));
EXPECT_EQ(20000, entry->GetDataSize(stream_index));
EXPECT_EQ(20000, ReadData(entry, stream_index, 0, buffer2.get(), kSize));
EXPECT_TRUE(!memcmp(buffer1->data(), buffer2->data(), kSize));
entry->Close();
memset(buffer2->data(), 0, kSize);
std::string key2("Second key");
ASSERT_THAT(CreateEntry(key2, &entry), IsOk());
EXPECT_EQ(10, WriteData(entry, stream_index, 0, buffer1.get(), 10, false));
EXPECT_EQ(10, entry->GetDataSize(stream_index));
entry->Close();
// Go from an internal address to a bigger block size.
ASSERT_THAT(OpenEntry(key2, &entry), IsOk());
EXPECT_EQ(2000,
WriteData(entry, stream_index, 0, buffer1.get(), 2000, false));
EXPECT_EQ(2000, entry->GetDataSize(stream_index));
EXPECT_EQ(2000, ReadData(entry, stream_index, 0, buffer2.get(), 2000));
EXPECT_TRUE(!memcmp(buffer1->data(), buffer2->data(), 2000));
entry->Close();
memset(buffer2->data(), 0, kSize);
// Go from an internal address to an external one.
ASSERT_THAT(OpenEntry(key2, &entry), IsOk());
EXPECT_EQ(20000,
WriteData(entry, stream_index, 0, buffer1.get(), kSize, false));
EXPECT_EQ(20000, entry->GetDataSize(stream_index));
EXPECT_EQ(20000, ReadData(entry, stream_index, 0, buffer2.get(), kSize));
EXPECT_TRUE(!memcmp(buffer1->data(), buffer2->data(), kSize));
entry->Close();
// Double check the size from disk.
ASSERT_THAT(OpenEntry(key2, &entry), IsOk());
EXPECT_EQ(20000, entry->GetDataSize(stream_index));
// Now extend the entry without actual data.
EXPECT_EQ(0, WriteData(entry, stream_index, 45500, buffer1.get(), 0, false));
entry->Close();
// And check again from disk.
ASSERT_THAT(OpenEntry(key2, &entry), IsOk());
EXPECT_EQ(45500, entry->GetDataSize(stream_index));
entry->Close();
}
TEST_F(DiskCacheEntryTest, GrowData) {
InitCache();
GrowData(0);
}
TEST_F(DiskCacheEntryTest, GrowDataNoBuffer) {
InitCache();
cache_impl_->SetFlags(disk_cache::kNoBuffering);
GrowData(0);
}
TEST_F(DiskCacheEntryTest, MemoryOnlyGrowData) {
SetMemoryOnlyMode();
InitCache();
GrowData(0);
}
void DiskCacheEntryTest::TruncateData(int stream_index) {
std::string key("the first key");
disk_cache::Entry* entry;
ASSERT_THAT(CreateEntry(key, &entry), IsOk());
const int kSize1 = 20000;
const int kSize2 = 20000;
scoped_refptr<net::IOBuffer> buffer1 =
base::MakeRefCounted<net::IOBuffer>(kSize1);
scoped_refptr<net::IOBuffer> buffer2 =
base::MakeRefCounted<net::IOBuffer>(kSize2);
CacheTestFillBuffer(buffer1->data(), kSize1, false);
memset(buffer2->data(), 0, kSize2);
// Simple truncation:
EXPECT_EQ(200, WriteData(entry, stream_index, 0, buffer1.get(), 200, false));
EXPECT_EQ(200, entry->GetDataSize(stream_index));
EXPECT_EQ(100, WriteData(entry, stream_index, 0, buffer1.get(), 100, false));
EXPECT_EQ(200, entry->GetDataSize(stream_index));
EXPECT_EQ(100, WriteData(entry, stream_index, 0, buffer1.get(), 100, true));
EXPECT_EQ(100, entry->GetDataSize(stream_index));
EXPECT_EQ(0, WriteData(entry, stream_index, 50, buffer1.get(), 0, true));
EXPECT_EQ(50, entry->GetDataSize(stream_index));
EXPECT_EQ(0, WriteData(entry, stream_index, 0, buffer1.get(), 0, true));
EXPECT_EQ(0, entry->GetDataSize(stream_index));
entry->Close();
ASSERT_THAT(OpenEntry(key, &entry), IsOk());
// Go to an external file.
EXPECT_EQ(20000,
WriteData(entry, stream_index, 0, buffer1.get(), 20000, true));
EXPECT_EQ(20000, entry->GetDataSize(stream_index));
EXPECT_EQ(20000, ReadData(entry, stream_index, 0, buffer2.get(), 20000));
EXPECT_TRUE(!memcmp(buffer1->data(), buffer2->data(), 20000));
memset(buffer2->data(), 0, kSize2);
// External file truncation
EXPECT_EQ(18000,
WriteData(entry, stream_index, 0, buffer1.get(), 18000, false));
EXPECT_EQ(20000, entry->GetDataSize(stream_index));
EXPECT_EQ(18000,
WriteData(entry, stream_index, 0, buffer1.get(), 18000, true));
EXPECT_EQ(18000, entry->GetDataSize(stream_index));
EXPECT_EQ(0, WriteData(entry, stream_index, 17500, buffer1.get(), 0, true));
EXPECT_EQ(17500, entry->GetDataSize(stream_index));
// And back to an internal block.
EXPECT_EQ(600,
WriteData(entry, stream_index, 1000, buffer1.get(), 600, true));
EXPECT_EQ(1600, entry->GetDataSize(stream_index));
EXPECT_EQ(600, ReadData(entry, stream_index, 1000, buffer2.get(), 600));
EXPECT_TRUE(!memcmp(buffer1->data(), buffer2->data(), 600));
EXPECT_EQ(1000, ReadData(entry, stream_index, 0, buffer2.get(), 1000));
EXPECT_TRUE(!memcmp(buffer1->data(), buffer2->data(), 1000))
<< "Preserves previous data";
// Go from external file to zero length.
EXPECT_EQ(20000,
WriteData(entry, stream_index, 0, buffer1.get(), 20000, true));
EXPECT_EQ(20000, entry->GetDataSize(stream_index));
EXPECT_EQ(0, WriteData(entry, stream_index, 0, buffer1.get(), 0, true));
EXPECT_EQ(0, entry->GetDataSize(stream_index));
entry->Close();
}
TEST_F(DiskCacheEntryTest, TruncateData) {
InitCache();
TruncateData(0);
}
TEST_F(DiskCacheEntryTest, TruncateDataNoBuffer) {
InitCache();
cache_impl_->SetFlags(disk_cache::kNoBuffering);
TruncateData(0);
}
TEST_F(DiskCacheEntryTest, MemoryOnlyTruncateData) {
SetMemoryOnlyMode();
InitCache();
TruncateData(0);
}
void DiskCacheEntryTest::ZeroLengthIO(int stream_index) {
std::string key("the first key");
disk_cache::Entry* entry;
ASSERT_THAT(CreateEntry(key, &entry), IsOk());
EXPECT_EQ(0, ReadData(entry, stream_index, 0, NULL, 0));
EXPECT_EQ(0, WriteData(entry, stream_index, 0, NULL, 0, false));
// This write should extend the entry.
EXPECT_EQ(0, WriteData(entry, stream_index, 1000, NULL, 0, false));
EXPECT_EQ(0, ReadData(entry, stream_index, 500, NULL, 0));
EXPECT_EQ(0, ReadData(entry, stream_index, 2000, NULL, 0));
EXPECT_EQ(1000, entry->GetDataSize(stream_index));
EXPECT_EQ(0, WriteData(entry, stream_index, 100000, NULL, 0, true));
EXPECT_EQ(0, ReadData(entry, stream_index, 50000, NULL, 0));
EXPECT_EQ(100000, entry->GetDataSize(stream_index));
// Let's verify the actual content.
const int kSize = 20;
const char zeros[kSize] = {};
scoped_refptr<net::IOBuffer> buffer =
base::MakeRefCounted<net::IOBuffer>(kSize);
CacheTestFillBuffer(buffer->data(), kSize, false);
EXPECT_EQ(kSize, ReadData(entry, stream_index, 500, buffer.get(), kSize));
EXPECT_TRUE(!memcmp(buffer->data(), zeros, kSize));
CacheTestFillBuffer(buffer->data(), kSize, false);
EXPECT_EQ(kSize, ReadData(entry, stream_index, 5000, buffer.get(), kSize));
EXPECT_TRUE(!memcmp(buffer->data(), zeros, kSize));
CacheTestFillBuffer(buffer->data(), kSize, false);
EXPECT_EQ(kSize, ReadData(entry, stream_index, 50000, buffer.get(), kSize));
EXPECT_TRUE(!memcmp(buffer->data(), zeros, kSize));
entry->Close();
}
TEST_F(DiskCacheEntryTest, ZeroLengthIO) {
InitCache();
ZeroLengthIO(0);
}
TEST_F(DiskCacheEntryTest, ZeroLengthIONoBuffer) {
InitCache();
cache_impl_->SetFlags(disk_cache::kNoBuffering);
ZeroLengthIO(0);
}
TEST_F(DiskCacheEntryTest, MemoryOnlyZeroLengthIO) {
SetMemoryOnlyMode();
InitCache();
ZeroLengthIO(0);
}
// Tests that we handle the content correctly when buffering, a feature of the
// standard cache that permits fast responses to certain reads.
void DiskCacheEntryTest::Buffering() {
std::string key("the first key");
disk_cache::Entry* entry;
ASSERT_THAT(CreateEntry(key, &entry), IsOk());
const int kSize = 200;
scoped_refptr<net::IOBuffer> buffer1 =
base::MakeRefCounted<net::IOBuffer>(kSize);
scoped_refptr<net::IOBuffer> buffer2 =
base::MakeRefCounted<net::IOBuffer>(kSize);
CacheTestFillBuffer(buffer1->data(), kSize, true);
CacheTestFillBuffer(buffer2->data(), kSize, true);
EXPECT_EQ(kSize, WriteData(entry, 1, 0, buffer1.get(), kSize, false));
entry->Close();
// Write a little more and read what we wrote before.
ASSERT_THAT(OpenEntry(key, &entry), IsOk());
EXPECT_EQ(kSize, WriteData(entry, 1, 5000, buffer1.get(), kSize, false));
EXPECT_EQ(kSize, ReadData(entry, 1, 0, buffer2.get(), kSize));
EXPECT_TRUE(!memcmp(buffer2->data(), buffer1->data(), kSize));
// Now go to an external file.
EXPECT_EQ(kSize, WriteData(entry, 1, 18000, buffer1.get(), kSize, false));
entry->Close();
// Write something else and verify old data.
ASSERT_THAT(OpenEntry(key, &entry), IsOk());
EXPECT_EQ(kSize, WriteData(entry, 1, 10000, buffer1.get(), kSize, false));
CacheTestFillBuffer(buffer2->data(), kSize, true);
EXPECT_EQ(kSize, ReadData(entry, 1, 5000, buffer2.get(), kSize));
EXPECT_TRUE(!memcmp(buffer2->data(), buffer1->data(), kSize));
CacheTestFillBuffer(buffer2->data(), kSize, true);
EXPECT_EQ(kSize, ReadData(entry, 1, 0, buffer2.get(), kSize));
EXPECT_TRUE(!memcmp(buffer2->data(), buffer1->data(), kSize));
CacheTestFillBuffer(buffer2->data(), kSize, true);
EXPECT_EQ(kSize, ReadData(entry, 1, 18000, buffer2.get(), kSize));
EXPECT_TRUE(!memcmp(buffer2->data(), buffer1->data(), kSize));
// Extend the file some more.
EXPECT_EQ(kSize, WriteData(entry, 1, 23000, buffer1.get(), kSize, false));
entry->Close();
// And now make sure that we can deal with data in both places (ram/disk).
ASSERT_THAT(OpenEntry(key, &entry), IsOk());
EXPECT_EQ(kSize, WriteData(entry, 1, 17000, buffer1.get(), kSize, false));
// We should not overwrite the data at 18000 with this.
EXPECT_EQ(kSize, WriteData(entry, 1, 19000, buffer1.get(), kSize, false));
CacheTestFillBuffer(buffer2->data(), kSize, true);
EXPECT_EQ(kSize, ReadData(entry, 1, 18000, buffer2.get(), kSize));
EXPECT_TRUE(!memcmp(buffer2->data(), buffer1->data(), kSize));
CacheTestFillBuffer(buffer2->data(), kSize, true);
EXPECT_EQ(kSize, ReadData(entry, 1, 17000, buffer2.get(), kSize));
EXPECT_TRUE(!memcmp(buffer2->data(), buffer1->data(), kSize));
EXPECT_EQ(kSize, WriteData(entry, 1, 22900, buffer1.get(), kSize, false));
CacheTestFillBuffer(buffer2->data(), kSize, true);
EXPECT_EQ(100, ReadData(entry, 1, 23000, buffer2.get(), kSize));
EXPECT_TRUE(!memcmp(buffer2->data(), buffer1->data() + 100, 100));
CacheTestFillBuffer(buffer2->data(), kSize, true);
EXPECT_EQ(100, ReadData(entry, 1, 23100, buffer2.get(), kSize));
EXPECT_TRUE(!memcmp(buffer2->data(), buffer1->data() + 100, 100));
// Extend the file again and read before without closing the entry.
EXPECT_EQ(kSize, WriteData(entry, 1, 25000, buffer1.get(), kSize, false));
EXPECT_EQ(kSize, WriteData(entry, 1, 45000, buffer1.get(), kSize, false));
CacheTestFillBuffer(buffer2->data(), kSize, true);
EXPECT_EQ(kSize, ReadData(entry, 1, 25000, buffer2.get(), kSize));
EXPECT_TRUE(!memcmp(buffer2->data(), buffer1->data(), kSize));
CacheTestFillBuffer(buffer2->data(), kSize, true);
EXPECT_EQ(kSize, ReadData(entry, 1, 45000, buffer2.get(), kSize));
EXPECT_TRUE(!memcmp(buffer2->data(), buffer1->data(), kSize));
entry->Close();
}
TEST_F(DiskCacheEntryTest, Buffering) {
InitCache();
Buffering();
}
TEST_F(DiskCacheEntryTest, BufferingNoBuffer) {
InitCache();
cache_impl_->SetFlags(disk_cache::kNoBuffering);
Buffering();
}
// Checks that entries are zero length when created.
void DiskCacheEntryTest::SizeAtCreate() {
const char key[] = "the first key";
disk_cache::Entry* entry;
ASSERT_THAT(CreateEntry(key, &entry), IsOk());
const int kNumStreams = 3;
for (int i = 0; i < kNumStreams; ++i)
EXPECT_EQ(0, entry->GetDataSize(i));
entry->Close();
}
TEST_F(DiskCacheEntryTest, SizeAtCreate) {
InitCache();
SizeAtCreate();
}
TEST_F(DiskCacheEntryTest, MemoryOnlySizeAtCreate) {
SetMemoryOnlyMode();
InitCache();
SizeAtCreate();
}
// Some extra tests to make sure that buffering works properly when changing
// the entry size.
void DiskCacheEntryTest::SizeChanges(int stream_index) {
std::string key("the first key");
disk_cache::Entry* entry;
ASSERT_THAT(CreateEntry(key, &entry), IsOk());
const int kSize = 200;
const char zeros[kSize] = {};
scoped_refptr<net::IOBuffer> buffer1 =
base::MakeRefCounted<net::IOBuffer>(kSize);
scoped_refptr<net::IOBuffer> buffer2 =
base::MakeRefCounted<net::IOBuffer>(kSize);
CacheTestFillBuffer(buffer1->data(), kSize, true);
CacheTestFillBuffer(buffer2->data(), kSize, true);
EXPECT_EQ(kSize,
WriteData(entry, stream_index, 0, buffer1.get(), kSize, true));
EXPECT_EQ(kSize,
WriteData(entry, stream_index, 17000, buffer1.get(), kSize, true));
EXPECT_EQ(kSize,
WriteData(entry, stream_index, 23000, buffer1.get(), kSize, true));
entry->Close();
// Extend the file and read between the old size and the new write.
ASSERT_THAT(OpenEntry(key, &entry), IsOk());
EXPECT_EQ(23000 + kSize, entry->GetDataSize(stream_index));
EXPECT_EQ(kSize,
WriteData(entry, stream_index, 25000, buffer1.get(), kSize, true));
EXPECT_EQ(25000 + kSize, entry->GetDataSize(stream_index));
EXPECT_EQ(kSize, ReadData(entry, stream_index, 24000, buffer2.get(), kSize));
EXPECT_TRUE(!memcmp(buffer2->data(), zeros, kSize));
// Read at the end of the old file size.
EXPECT_EQ(
kSize,
ReadData(entry, stream_index, 23000 + kSize - 35, buffer2.get(), kSize));
EXPECT_TRUE(!memcmp(buffer2->data(), buffer1->data() + kSize - 35, 35));
// Read slightly before the last write.
CacheTestFillBuffer(buffer2->data(), kSize, true);
EXPECT_EQ(kSize, ReadData(entry, stream_index, 24900, buffer2.get(), kSize));
EXPECT_TRUE(!memcmp(buffer2->data(), zeros, 100));
EXPECT_TRUE(!memcmp(buffer2->data() + 100, buffer1->data(), kSize - 100));
// Extend the entry a little more.
EXPECT_EQ(kSize,
WriteData(entry, stream_index, 26000, buffer1.get(), kSize, true));
EXPECT_EQ(26000 + kSize, entry->GetDataSize(stream_index));
CacheTestFillBuffer(buffer2->data(), kSize, true);
EXPECT_EQ(kSize, ReadData(entry, stream_index, 25900, buffer2.get(), kSize));
EXPECT_TRUE(!memcmp(buffer2->data(), zeros, 100));
EXPECT_TRUE(!memcmp(buffer2->data() + 100, buffer1->data(), kSize - 100));
// And now reduce the size.
EXPECT_EQ(kSize,
WriteData(entry, stream_index, 25000, buffer1.get(), kSize, true));
EXPECT_EQ(25000 + kSize, entry->GetDataSize(stream_index));
EXPECT_EQ(
28,
ReadData(entry, stream_index, 25000 + kSize - 28, buffer2.get(), kSize));
EXPECT_TRUE(!memcmp(buffer2->data(), buffer1->data() + kSize - 28, 28));
// Reduce the size with a buffer that is not extending the size.
EXPECT_EQ(kSize,
WriteData(entry, stream_index, 24000, buffer1.get(), kSize, false));
EXPECT_EQ(25000 + kSize, entry->GetDataSize(stream_index));
EXPECT_EQ(kSize,
WriteData(entry, stream_index, 24500, buffer1.get(), kSize, true));
EXPECT_EQ(24500 + kSize, entry->GetDataSize(stream_index));
EXPECT_EQ(kSize, ReadData(entry, stream_index, 23900, buffer2.get(), kSize));
EXPECT_TRUE(!memcmp(buffer2->data(), zeros, 100));
EXPECT_TRUE(!memcmp(buffer2->data() + 100, buffer1->data(), kSize - 100));
// And now reduce the size below the old size.
EXPECT_EQ(kSize,
WriteData(entry, stream_index, 19000, buffer1.get(), kSize, true));
EXPECT_EQ(19000 + kSize, entry->GetDataSize(stream_index));
EXPECT_EQ(kSize, ReadData(entry, stream_index, 18900, buffer2.get(), kSize));
EXPECT_TRUE(!memcmp(buffer2->data(), zeros, 100));
EXPECT_TRUE(!memcmp(buffer2->data() + 100, buffer1->data(), kSize - 100));
// Verify that the actual file is truncated.
entry->Close();
ASSERT_THAT(OpenEntry(key, &entry), IsOk());
EXPECT_EQ(19000 + kSize, entry->GetDataSize(stream_index));
// Extend the newly opened file with a zero length write, expect zero fill.
EXPECT_EQ(
0,
WriteData(entry, stream_index, 20000 + kSize, buffer1.get(), 0, false));
EXPECT_EQ(kSize,
ReadData(entry, stream_index, 19000 + kSize, buffer1.get(), kSize));
EXPECT_EQ(0, memcmp(buffer1->data(), zeros, kSize));
entry->Close();
}
TEST_F(DiskCacheEntryTest, SizeChanges) {
InitCache();
SizeChanges(1);
}
TEST_F(DiskCacheEntryTest, SizeChangesNoBuffer) {
InitCache();
cache_impl_->SetFlags(disk_cache::kNoBuffering);
SizeChanges(1);
}
// Write more than the total cache capacity but to a single entry. |size| is the
// amount of bytes to write each time.
void DiskCacheEntryTest::ReuseEntry(int size, int stream_index) {
std::string key1("the first key");
disk_cache::Entry* entry;
ASSERT_THAT(CreateEntry(key1, &entry), IsOk());
entry->Close();
std::string key2("the second key");
ASSERT_THAT(CreateEntry(key2, &entry), IsOk());
scoped_refptr<net::IOBuffer> buffer =
base::MakeRefCounted<net::IOBuffer>(size);
CacheTestFillBuffer(buffer->data(), size, false);
for (int i = 0; i < 15; i++) {
EXPECT_EQ(0, WriteData(entry, stream_index, 0, buffer.get(), 0, true));
EXPECT_EQ(size,
WriteData(entry, stream_index, 0, buffer.get(), size, false));
entry->Close();
ASSERT_THAT(OpenEntry(key2, &entry), IsOk());
}
entry->Close();
ASSERT_EQ(net::OK, OpenEntry(key1, &entry)) << "have not evicted this entry";
entry->Close();
}
TEST_F(DiskCacheEntryTest, ReuseExternalEntry) {
SetMaxSize(200 * 1024);
InitCache();
ReuseEntry(20 * 1024, 0);
}
TEST_F(DiskCacheEntryTest, MemoryOnlyReuseExternalEntry) {
SetMemoryOnlyMode();
SetMaxSize(200 * 1024);
InitCache();
ReuseEntry(20 * 1024, 0);
}
TEST_F(DiskCacheEntryTest, ReuseInternalEntry) {
SetMaxSize(100 * 1024);
InitCache();
ReuseEntry(10 * 1024, 0);
}
TEST_F(DiskCacheEntryTest, MemoryOnlyReuseInternalEntry) {
SetMemoryOnlyMode();
SetMaxSize(100 * 1024);
InitCache();
ReuseEntry(10 * 1024, 0);
}
// Reading somewhere that was not written should return zeros.
void DiskCacheEntryTest::InvalidData(int stream_index) {
std::string key("the first key");
disk_cache::Entry* entry;
ASSERT_THAT(CreateEntry(key, &entry), IsOk());
const int kSize1 = 20000;
const int kSize2 = 20000;
const int kSize3 = 20000;
scoped_refptr<net::IOBuffer> buffer1 =
base::MakeRefCounted<net::IOBuffer>(kSize1);
scoped_refptr<net::IOBuffer> buffer2 =
base::MakeRefCounted<net::IOBuffer>(kSize2);
scoped_refptr<net::IOBuffer> buffer3 =
base::MakeRefCounted<net::IOBuffer>(kSize3);
CacheTestFillBuffer(buffer1->data(), kSize1, false);
memset(buffer2->data(), 0, kSize2);
// Simple data grow:
EXPECT_EQ(200,
WriteData(entry, stream_index, 400, buffer1.get(), 200, false));
EXPECT_EQ(600, entry->GetDataSize(stream_index));
EXPECT_EQ(100, ReadData(entry, stream_index, 300, buffer3.get(), 100));
EXPECT_TRUE(!memcmp(buffer3->data(), buffer2->data(), 100));
entry->Close();
ASSERT_THAT(OpenEntry(key, &entry), IsOk());
// The entry is now on disk. Load it and extend it.
EXPECT_EQ(200,
WriteData(entry, stream_index, 800, buffer1.get(), 200, false));
EXPECT_EQ(1000, entry->GetDataSize(stream_index));
EXPECT_EQ(100, ReadData(entry, stream_index, 700, buffer3.get(), 100));
EXPECT_TRUE(!memcmp(buffer3->data(), buffer2->data(), 100));
entry->Close();
ASSERT_THAT(OpenEntry(key, &entry), IsOk());
// This time using truncate.
EXPECT_EQ(200,
WriteData(entry, stream_index, 1800, buffer1.get(), 200, true));
EXPECT_EQ(2000, entry->GetDataSize(stream_index));
EXPECT_EQ(100, ReadData(entry, stream_index, 1500, buffer3.get(), 100));
EXPECT_TRUE(!memcmp(buffer3->data(), buffer2->data(), 100));
// Go to an external file.
EXPECT_EQ(200,
WriteData(entry, stream_index, 19800, buffer1.get(), 200, false));
EXPECT_EQ(20000, entry->GetDataSize(stream_index));
EXPECT_EQ(4000, ReadData(entry, stream_index, 14000, buffer3.get(), 4000));
EXPECT_TRUE(!memcmp(buffer3->data(), buffer2->data(), 4000));
// And back to an internal block.
EXPECT_EQ(600,
WriteData(entry, stream_index, 1000, buffer1.get(), 600, true));
EXPECT_EQ(1600, entry->GetDataSize(stream_index));
EXPECT_EQ(600, ReadData(entry, stream_index, 1000, buffer3.get(), 600));
EXPECT_TRUE(!memcmp(buffer3->data(), buffer1->data(), 600));
// Extend it again.
EXPECT_EQ(600,
WriteData(entry, stream_index, 2000, buffer1.get(), 600, false));
EXPECT_EQ(2600, entry->GetDataSize(stream_index));
EXPECT_EQ(200, ReadData(entry, stream_index, 1800, buffer3.get(), 200));
EXPECT_TRUE(!memcmp(buffer3->data(), buffer2->data(), 200));
// And again (with truncation flag).
EXPECT_EQ(600,
WriteData(entry, stream_index, 3000, buffer1.get(), 600, true));
EXPECT_EQ(3600, entry->GetDataSize(stream_index));
EXPECT_EQ(200, ReadData(entry, stream_index, 2800, buffer3.get(), 200));
EXPECT_TRUE(!memcmp(buffer3->data(), buffer2->data(), 200));
entry->Close();
}
TEST_F(DiskCacheEntryTest, InvalidData) {
InitCache();
InvalidData(0);
}
TEST_F(DiskCacheEntryTest, InvalidDataNoBuffer) {
InitCache();
cache_impl_->SetFlags(disk_cache::kNoBuffering);
InvalidData(0);
}
TEST_F(DiskCacheEntryTest, MemoryOnlyInvalidData) {
SetMemoryOnlyMode();
InitCache();
InvalidData(0);
}
// Tests that the cache preserves the buffer of an IO operation.
void DiskCacheEntryTest::ReadWriteDestroyBuffer(int stream_index) {
std::string key("the first key");
disk_cache::Entry* entry;
ASSERT_THAT(CreateEntry(key, &entry), IsOk());
const int kSize = 200;
scoped_refptr<net::IOBuffer> buffer =
base::MakeRefCounted<net::IOBuffer>(kSize);
CacheTestFillBuffer(buffer->data(), kSize, false);
net::TestCompletionCallback cb;
EXPECT_EQ(net::ERR_IO_PENDING,
entry->WriteData(
stream_index, 0, buffer.get(), kSize, cb.callback(), false));
// Release our reference to the buffer.
buffer = NULL;
EXPECT_EQ(kSize, cb.WaitForResult());
// And now test with a Read().
buffer = base::MakeRefCounted<net::IOBuffer>(kSize);
CacheTestFillBuffer(buffer->data(), kSize, false);
EXPECT_EQ(
net::ERR_IO_PENDING,
entry->ReadData(stream_index, 0, buffer.get(), kSize, cb.callback()));
buffer = NULL;
EXPECT_EQ(kSize, cb.WaitForResult());
entry->Close();
}
TEST_F(DiskCacheEntryTest, ReadWriteDestroyBuffer) {
InitCache();
ReadWriteDestroyBuffer(0);
}
void DiskCacheEntryTest::DoomNormalEntry() {
std::string key("the first key");
disk_cache::Entry* entry;
ASSERT_THAT(CreateEntry(key, &entry), IsOk());
entry->Doom();
entry->Close();
const int kSize = 20000;
scoped_refptr<net::IOBuffer> buffer =
base::MakeRefCounted<net::IOBuffer>(kSize);
CacheTestFillBuffer(buffer->data(), kSize, true);
buffer->data()[19999] = '\0';
key = buffer->data();
ASSERT_THAT(CreateEntry(key, &entry), IsOk());
EXPECT_EQ(20000, WriteData(entry, 0, 0, buffer.get(), kSize, false));
EXPECT_EQ(20000, WriteData(entry, 1, 0, buffer.get(), kSize, false));
entry->Doom();
entry->Close();
FlushQueueForTest();
EXPECT_EQ(0, cache_->GetEntryCount());
}
TEST_F(DiskCacheEntryTest, DoomEntry) {
InitCache();
DoomNormalEntry();
}
TEST_F(DiskCacheEntryTest, MemoryOnlyDoomEntry) {
SetMemoryOnlyMode();
InitCache();
DoomNormalEntry();
}
// Tests dooming an entry that's linked to an open entry.
void DiskCacheEntryTest::DoomEntryNextToOpenEntry() {
disk_cache::Entry* entry1;
disk_cache::Entry* entry2;
ASSERT_THAT(CreateEntry("fixed", &entry1), IsOk());
entry1->Close();
ASSERT_THAT(CreateEntry("foo", &entry1), IsOk());
entry1->Close();
ASSERT_THAT(CreateEntry("bar", &entry1), IsOk());
entry1->Close();
ASSERT_THAT(OpenEntry("foo", &entry1), IsOk());
ASSERT_THAT(OpenEntry("bar", &entry2), IsOk());
entry2->Doom();
entry2->Close();
ASSERT_THAT(OpenEntry("foo", &entry2), IsOk());
entry2->Doom();
entry2->Close();
entry1->Close();
ASSERT_THAT(OpenEntry("fixed", &entry1), IsOk());
entry1->Close();
}
TEST_F(DiskCacheEntryTest, DoomEntryNextToOpenEntry) {
InitCache();
DoomEntryNextToOpenEntry();
}
TEST_F(DiskCacheEntryTest, NewEvictionDoomEntryNextToOpenEntry) {
SetNewEviction();
InitCache();
DoomEntryNextToOpenEntry();
}
TEST_F(DiskCacheEntryTest, AppCacheDoomEntryNextToOpenEntry) {
SetCacheType(net::APP_CACHE);
InitCache();
DoomEntryNextToOpenEntry();
}
// Verify that basic operations work as expected with doomed entries.
void DiskCacheEntryTest::DoomedEntry(int stream_index) {
std::string key("the first key");
disk_cache::Entry* entry;
ASSERT_THAT(CreateEntry(key, &entry), IsOk());
entry->Doom();
FlushQueueForTest();
EXPECT_EQ(0, cache_->GetEntryCount());
Time initial = Time::Now();
AddDelay();
const int kSize1 = 2000;
const int kSize2 = 2000;
scoped_refptr<net::IOBuffer> buffer1 =
base::MakeRefCounted<net::IOBuffer>(kSize1);
scoped_refptr<net::IOBuffer> buffer2 =
base::MakeRefCounted<net::IOBuffer>(kSize2);
CacheTestFillBuffer(buffer1->data(), kSize1, false);
memset(buffer2->data(), 0, kSize2);
EXPECT_EQ(2000,
WriteData(entry, stream_index, 0, buffer1.get(), 2000, false));
EXPECT_EQ(2000, ReadData(entry, stream_index, 0, buffer2.get(), 2000));
EXPECT_EQ(0, memcmp(buffer1->data(), buffer2->data(), kSize1));
EXPECT_EQ(key, entry->GetKey());
EXPECT_TRUE(initial < entry->GetLastModified());
EXPECT_TRUE(initial < entry->GetLastUsed());
entry->Close();
}
TEST_F(DiskCacheEntryTest, DoomedEntry) {
InitCache();
DoomedEntry(0);
}
TEST_F(DiskCacheEntryTest, MemoryOnlyDoomedEntry) {
SetMemoryOnlyMode();
InitCache();
DoomedEntry(0);
}
// Tests that we discard entries if the data is missing.
TEST_F(DiskCacheEntryTest, MissingData) {
InitCache();
std::string key("the first key");
disk_cache::Entry* entry;
ASSERT_THAT(CreateEntry(key, &entry), IsOk());
// Write to an external file.
const int kSize = 20000;
scoped_refptr<net::IOBuffer> buffer =
base::MakeRefCounted<net::IOBuffer>(kSize);
CacheTestFillBuffer(buffer->data(), kSize, false);
EXPECT_EQ(kSize, WriteData(entry, 0, 0, buffer.get(), kSize, false));
entry->Close();
FlushQueueForTest();
disk_cache::Addr address(0x80000001);
base::FilePath name = cache_impl_->GetFileName(address);
EXPECT_TRUE(base::DeleteFile(name, false));
// Attempt to read the data.
ASSERT_THAT(OpenEntry(key, &entry), IsOk());
EXPECT_EQ(net::ERR_FILE_NOT_FOUND,
ReadData(entry, 0, 0, buffer.get(), kSize));
entry->Close();
// The entry should be gone.
ASSERT_NE(net::OK, OpenEntry(key, &entry));
}
// Test that child entries in a memory cache backend are not visible from
// enumerations.
TEST_F(DiskCacheEntryTest, MemoryOnlyEnumerationWithSparseEntries) {
SetMemoryOnlyMode();
InitCache();
const int kSize = 4096;
scoped_refptr<net::IOBuffer> buf = base::MakeRefCounted<net::IOBuffer>(kSize);
CacheTestFillBuffer(buf->data(), kSize, false);
std::string key("the first key");
disk_cache::Entry* parent_entry;
ASSERT_THAT(CreateEntry(key, &parent_entry), IsOk());
// Writes to the parent entry.
EXPECT_EQ(kSize, parent_entry->WriteSparseData(
0, buf.get(), kSize, net::CompletionOnceCallback()));
// This write creates a child entry and writes to it.
EXPECT_EQ(kSize, parent_entry->WriteSparseData(
8192, buf.get(), kSize, net::CompletionOnceCallback()));
parent_entry->Close();
// Perform the enumerations.
std::unique_ptr<TestIterator> iter = CreateIterator();
disk_cache::Entry* entry = NULL;
int count = 0;
while (iter->OpenNextEntry(&entry) == net::OK) {
ASSERT_TRUE(entry != NULL);
++count;
disk_cache::MemEntryImpl* mem_entry =
reinterpret_cast<disk_cache::MemEntryImpl*>(entry);
EXPECT_EQ(disk_cache::MemEntryImpl::PARENT_ENTRY, mem_entry->type());
mem_entry->Close();
}
EXPECT_EQ(1, count);
}
// Writes |buf_1| to offset and reads it back as |buf_2|.
void VerifySparseIO(disk_cache::Entry* entry,
int64_t offset,
net::IOBuffer* buf_1,
int size,
net::IOBuffer* buf_2) {
net::TestCompletionCallback cb;
memset(buf_2->data(), 0, size);
int ret = entry->ReadSparseData(offset, buf_2, size, cb.callback());
EXPECT_EQ(0, cb.GetResult(ret));
ret = entry->WriteSparseData(offset, buf_1, size, cb.callback());
EXPECT_EQ(size, cb.GetResult(ret));
ret = entry->ReadSparseData(offset, buf_2, size, cb.callback());
EXPECT_EQ(size, cb.GetResult(ret));
EXPECT_EQ(0, memcmp(buf_1->data(), buf_2->data(), size));
}
// Reads |size| bytes from |entry| at |offset| and verifies that they are the
// same as the content of the provided |buffer|.
void VerifyContentSparseIO(disk_cache::Entry* entry,
int64_t offset,
char* buffer,
int size) {
net::TestCompletionCallback cb;
scoped_refptr<net::IOBuffer> buf_1 =
base::MakeRefCounted<net::IOBuffer>(size);
memset(buf_1->data(), 0, size);
int ret = entry->ReadSparseData(offset, buf_1.get(), size, cb.callback());
EXPECT_EQ(size, cb.GetResult(ret));
EXPECT_EQ(0, memcmp(buf_1->data(), buffer, size));
}
void DiskCacheEntryTest::BasicSparseIO() {
std::string key("the first key");
disk_cache::Entry* entry;
ASSERT_THAT(CreateEntry(key, &entry), IsOk());
const int kSize = 2048;
scoped_refptr<net::IOBuffer> buf_1 =
base::MakeRefCounted<net::IOBuffer>(kSize);
scoped_refptr<net::IOBuffer> buf_2 =
base::MakeRefCounted<net::IOBuffer>(kSize);
CacheTestFillBuffer(buf_1->data(), kSize, false);
// Write at offset 0.
VerifySparseIO(entry, 0, buf_1.get(), kSize, buf_2.get());
// Write at offset 0x400000 (4 MB).
VerifySparseIO(entry, 0x400000, buf_1.get(), kSize, buf_2.get());
// Write at offset 0x800000000 (32 GB).
VerifySparseIO(entry, 0x800000000LL, buf_1.get(), kSize, buf_2.get());
entry->Close();
// Check everything again.
ASSERT_THAT(OpenEntry(key, &entry), IsOk());
VerifyContentSparseIO(entry, 0, buf_1->data(), kSize);
VerifyContentSparseIO(entry, 0x400000, buf_1->data(), kSize);
VerifyContentSparseIO(entry, 0x800000000LL, buf_1->data(), kSize);
entry->Close();
}
TEST_F(DiskCacheEntryTest, BasicSparseIO) {
InitCache();
BasicSparseIO();
}
TEST_F(DiskCacheEntryTest, MemoryOnlyBasicSparseIO) {
SetMemoryOnlyMode();
InitCache();
BasicSparseIO();
}
void DiskCacheEntryTest::HugeSparseIO() {
std::string key("the first key");
disk_cache::Entry* entry;
ASSERT_THAT(CreateEntry(key, &entry), IsOk());
// Write 1.2 MB so that we cover multiple entries.
const int kSize = 1200 * 1024;
scoped_refptr<net::IOBuffer> buf_1 =
base::MakeRefCounted<net::IOBuffer>(kSize);
scoped_refptr<net::IOBuffer> buf_2 =
base::MakeRefCounted<net::IOBuffer>(kSize);
CacheTestFillBuffer(buf_1->data(), kSize, false);
// Write at offset 0x20F0000 (33 MB - 64 KB).
VerifySparseIO(entry, 0x20F0000, buf_1.get(), kSize, buf_2.get());
entry->Close();
// Check it again.
ASSERT_THAT(OpenEntry(key, &entry), IsOk());
VerifyContentSparseIO(entry, 0x20F0000, buf_1->data(), kSize);
entry->Close();
}
TEST_F(DiskCacheEntryTest, HugeSparseIO) {
InitCache();
HugeSparseIO();
}
TEST_F(DiskCacheEntryTest, MemoryOnlyHugeSparseIO) {
SetMemoryOnlyMode();
InitCache();
HugeSparseIO();
}
void DiskCacheEntryTest::GetAvailableRange() {
std::string key("the first key");
disk_cache::Entry* entry;
ASSERT_THAT(CreateEntry(key, &entry), IsOk());
const int kSize = 16 * 1024;
scoped_refptr<net::IOBuffer> buf = base::MakeRefCounted<net::IOBuffer>(kSize);
CacheTestFillBuffer(buf->data(), kSize, false);
// Write at offset 0x20F0000 (33 MB - 64 KB), and 0x20F4400 (33 MB - 47 KB).
EXPECT_EQ(kSize, WriteSparseData(entry, 0x20F0000, buf.get(), kSize));
EXPECT_EQ(kSize, WriteSparseData(entry, 0x20F4400, buf.get(), kSize));
// We stop at the first empty block.
int64_t start;
net::TestCompletionCallback cb;
int rv = entry->GetAvailableRange(
0x20F0000, kSize * 2, &start, cb.callback());
EXPECT_EQ(kSize, cb.GetResult(rv));
EXPECT_EQ(0x20F0000, start);
start = 0;
rv = entry->GetAvailableRange(0, kSize, &start, cb.callback());
EXPECT_EQ(0, cb.GetResult(rv));
rv = entry->GetAvailableRange(
0x20F0000 - kSize, kSize, &start, cb.callback());
EXPECT_EQ(0, cb.GetResult(rv));
rv = entry->GetAvailableRange(0, 0x2100000, &start, cb.callback());
EXPECT_EQ(kSize, cb.GetResult(rv));
EXPECT_EQ(0x20F0000, start);
// We should be able to Read based on the results of GetAvailableRange.
start = -1;
rv = entry->GetAvailableRange(0x2100000, kSize, &start, cb.callback());
EXPECT_EQ(0, cb.GetResult(rv));
rv = entry->ReadSparseData(start, buf.get(), kSize, cb.callback());
EXPECT_EQ(0, cb.GetResult(rv));
start = 0;
rv = entry->GetAvailableRange(0x20F2000, kSize, &start, cb.callback());
EXPECT_EQ(0x2000, cb.GetResult(rv));
EXPECT_EQ(0x20F2000, start);
EXPECT_EQ(0x2000, ReadSparseData(entry, start, buf.get(), kSize));
// Make sure that we respect the |len| argument.
start = 0;
rv = entry->GetAvailableRange(
0x20F0001 - kSize, kSize, &start, cb.callback());
EXPECT_EQ(1, cb.GetResult(rv));
EXPECT_EQ(0x20F0000, start);
// Use very small ranges. Write at offset 50.
const int kTinyLen = 10;
EXPECT_EQ(kTinyLen, WriteSparseData(entry, 50, buf.get(), kTinyLen));
start = -1;
rv = entry->GetAvailableRange(kTinyLen * 2, kTinyLen, &start, cb.callback());
EXPECT_EQ(0, cb.GetResult(rv));
EXPECT_EQ(kTinyLen * 2, start);
// Get a huge range with maximum boundary
start = -1;
rv = entry->GetAvailableRange(0x2100000, std::numeric_limits<int32_t>::max(),
&start, cb.callback());
EXPECT_EQ(0, cb.GetResult(rv));
entry->Close();
}
TEST_F(DiskCacheEntryTest, GetAvailableRange) {
InitCache();
GetAvailableRange();
}
TEST_F(DiskCacheEntryTest, MemoryOnlyGetAvailableRange) {
SetMemoryOnlyMode();
InitCache();
GetAvailableRange();
}
TEST_F(DiskCacheEntryTest, GetAvailableRangeBlockFileDiscontinuous) {
// crbug.com/791056 --- blockfile problem when there is a sub-KiB write before
// a bunch of full 1KiB blocks, and a GetAvailableRange is issued to which
// both are a potentially relevant.
InitCache();
std::string key("the first key");
disk_cache::Entry* entry;
ASSERT_THAT(CreateEntry(key, &entry), IsOk());
scoped_refptr<net::IOBuffer> buf_2k =
base::MakeRefCounted<net::IOBuffer>(2 * 1024);
CacheTestFillBuffer(buf_2k->data(), 2 * 1024, false);
const int kSmallSize = 612; // sub-1k
scoped_refptr<net::IOBuffer> buf_small =
base::MakeRefCounted<net::IOBuffer>(kSmallSize);
CacheTestFillBuffer(buf_small->data(), kSmallSize, false);
// Sets some bits for blocks representing 1K ranges [1024, 3072),
// which will be relevant for the next GetAvailableRange call.
EXPECT_EQ(2 * 1024, WriteSparseData(entry, /* offset = */ 1024, buf_2k.get(),
/* size = */ 2 * 1024));
// Now record a partial write from start of the first kb.
EXPECT_EQ(kSmallSize, WriteSparseData(entry, /* offset = */ 0,
buf_small.get(), kSmallSize));
// Try to query a range starting from that block 0.
// The cache tracks: [0, 612) [1024, 3072).
// The request is for: [812, 2059) so response should be [1024, 2059), which
// has lenth = 1035. Previously this return a negative number for rv.
int64_t start = -1;
net::TestCompletionCallback cb;
int rv = entry->GetAvailableRange(812, 1247, &start, cb.callback());
EXPECT_EQ(1035, cb.GetResult(rv));
EXPECT_EQ(1024, start);
// Now query [512, 1536). This matches both [512, 612) and [1024, 1536),
// so this should return [512, 612).
rv = entry->GetAvailableRange(512, 1024, &start, cb.callback());
EXPECT_EQ(100, cb.GetResult(rv));
EXPECT_EQ(512, start);
// Now query next portion, [612, 1636). This now just should produce
// [1024, 1636)
rv = entry->GetAvailableRange(612, 1024, &start, cb.callback());
EXPECT_EQ(612, cb.GetResult(rv));
EXPECT_EQ(1024, start);
// Do a continuous small write, this one at [3072, 3684).
// This means the cache tracks [1024, 3072) via bitmaps and [3072, 3684)
// as the last write.
EXPECT_EQ(kSmallSize, WriteSparseData(entry, /* offset = */ 3072,
buf_small.get(), kSmallSize));
// Query [2048, 4096). Should get [2048, 3684)
rv = entry->GetAvailableRange(2048, 2048, &start, cb.callback());
EXPECT_EQ(1636, cb.GetResult(rv));
EXPECT_EQ(2048, start);
// Now write at [4096, 4708). Since only one sub-kb thing is tracked, this
// now tracks [1024, 3072) via bitmaps and [4096, 4708) as the last write.
EXPECT_EQ(kSmallSize, WriteSparseData(entry, /* offset = */ 4096,
buf_small.get(), kSmallSize));
// Query [2048, 4096). Should get [2048, 3072)
rv = entry->GetAvailableRange(2048, 2048, &start, cb.callback());
EXPECT_EQ(1024, cb.GetResult(rv));
EXPECT_EQ(2048, start);
// Query 2K more after that: [3072, 5120). Should get [4096, 4708)
rv = entry->GetAvailableRange(3072, 2048, &start, cb.callback());
EXPECT_EQ(612, cb.GetResult(rv));
EXPECT_EQ(4096, start);
// Also double-check that offsets within later children are correctly
// computed.
EXPECT_EQ(kSmallSize, WriteSparseData(entry, /* offset = */ 0x200400,
buf_small.get(), kSmallSize));
rv = entry->GetAvailableRange(0x100000, 0x200000, &start, cb.callback());
EXPECT_EQ(kSmallSize, cb.GetResult(rv));
EXPECT_EQ(0x200400, start);
entry->Close();
}
// Tests that non-sequential writes that are not aligned with the minimum sparse
// data granularity (1024 bytes) do in fact result in dropped data.
TEST_F(DiskCacheEntryTest, SparseWriteDropped) {
InitCache();
std::string key("the first key");
disk_cache::Entry* entry;
ASSERT_THAT(CreateEntry(key, &entry), IsOk());
const int kSize = 180;
scoped_refptr<net::IOBuffer> buf_1 =
base::MakeRefCounted<net::IOBuffer>(kSize);
scoped_refptr<net::IOBuffer> buf_2 =
base::MakeRefCounted<net::IOBuffer>(kSize);
CacheTestFillBuffer(buf_1->data(), kSize, false);
// Do small writes (180 bytes) that get increasingly close to a 1024-byte
// boundary. All data should be dropped until a boundary is crossed, at which
// point the data after the boundary is saved (at least for a while).
int offset = 1024 - 500;
int rv = 0;
net::TestCompletionCallback cb;
int64_t start;
for (int i = 0; i < 5; i++) {
// Check result of last GetAvailableRange.
EXPECT_EQ(0, rv);
rv = entry->WriteSparseData(offset, buf_1.get(), kSize, cb.callback());
EXPECT_EQ(kSize, cb.GetResult(rv));
rv = entry->GetAvailableRange(offset - 100, kSize, &start, cb.callback());
EXPECT_EQ(0, cb.GetResult(rv));
rv = entry->GetAvailableRange(offset, kSize, &start, cb.callback());
rv = cb.GetResult(rv);
if (!rv) {
rv = entry->ReadSparseData(offset, buf_2.get(), kSize, cb.callback());
EXPECT_EQ(0, cb.GetResult(rv));
rv = 0;
}
offset += 1024 * i + 100;
}
// The last write started 100 bytes below a bundary, so there should be 80
// bytes after the boundary.
EXPECT_EQ(80, rv);
EXPECT_EQ(1024 * 7, start);
rv = entry->ReadSparseData(start, buf_2.get(), kSize, cb.callback());
EXPECT_EQ(80, cb.GetResult(rv));
EXPECT_EQ(0, memcmp(buf_1.get()->data() + 100, buf_2.get()->data(), 80));
// And even that part is dropped when another write changes the offset.
offset = start;
rv = entry->WriteSparseData(0, buf_1.get(), kSize, cb.callback());
EXPECT_EQ(kSize, cb.GetResult(rv));
rv = entry->GetAvailableRange(offset, kSize, &start, cb.callback());
EXPECT_EQ(0, cb.GetResult(rv));
entry->Close();
}
// Tests that small sequential writes are not dropped.
TEST_F(DiskCacheEntryTest, SparseSquentialWriteNotDropped) {
InitCache();
std::string key("the first key");
disk_cache::Entry* entry;
ASSERT_THAT(CreateEntry(key, &entry), IsOk());
const int kSize = 180;
scoped_refptr<net::IOBuffer> buf_1 =
base::MakeRefCounted<net::IOBuffer>(kSize);
scoped_refptr<net::IOBuffer> buf_2 =
base::MakeRefCounted<net::IOBuffer>(kSize);
CacheTestFillBuffer(buf_1->data(), kSize, false);
// Any starting offset is fine as long as it is 1024-bytes aligned.
int rv = 0;
net::TestCompletionCallback cb;
int64_t start;
int64_t offset = 1024 * 11;
for (; offset < 20000; offset += kSize) {
rv = entry->WriteSparseData(offset, buf_1.get(), kSize, cb.callback());
EXPECT_EQ(kSize, cb.GetResult(rv));
rv = entry->GetAvailableRange(offset, kSize, &start, cb.callback());
EXPECT_EQ(kSize, cb.GetResult(rv));
EXPECT_EQ(offset, start);
rv = entry->ReadSparseData(offset, buf_2.get(), kSize, cb.callback());
EXPECT_EQ(kSize, cb.GetResult(rv));
EXPECT_EQ(0, memcmp(buf_1.get()->data(), buf_2.get()->data(), kSize));
}
entry->Close();
FlushQueueForTest();
// Verify again the last write made.
ASSERT_THAT(OpenEntry(key, &entry), IsOk());
offset -= kSize;
rv = entry->GetAvailableRange(offset, kSize, &start, cb.callback());
EXPECT_EQ(kSize, cb.GetResult(rv));
EXPECT_EQ(offset, start);
rv = entry->ReadSparseData(offset, buf_2.get(), kSize, cb.callback());
EXPECT_EQ(kSize, cb.GetResult(rv));
EXPECT_EQ(0, memcmp(buf_1.get()->data(), buf_2.get()->data(), kSize));
entry->Close();
}
void DiskCacheEntryTest::CouldBeSparse() {
std::string key("the first key");
disk_cache::Entry* entry;
ASSERT_THAT(CreateEntry(key, &entry), IsOk());
const int kSize = 16 * 1024;
scoped_refptr<net::IOBuffer> buf = base::MakeRefCounted<net::IOBuffer>(kSize);
CacheTestFillBuffer(buf->data(), kSize, false);
// Write at offset 0x20F0000 (33 MB - 64 KB).
EXPECT_EQ(kSize, WriteSparseData(entry, 0x20F0000, buf.get(), kSize));
EXPECT_TRUE(entry->CouldBeSparse());
entry->Close();
ASSERT_THAT(OpenEntry(key, &entry), IsOk());
EXPECT_TRUE(entry->CouldBeSparse());
entry->Close();
// Now verify a regular entry.
key.assign("another key");
ASSERT_THAT(CreateEntry(key, &entry), IsOk());
EXPECT_FALSE(entry->CouldBeSparse());
EXPECT_EQ(kSize, WriteData(entry, 0, 0, buf.get(), kSize, false));
EXPECT_EQ(kSize, WriteData(entry, 1, 0, buf.get(), kSize, false));
EXPECT_EQ(kSize, WriteData(entry, 2, 0, buf.get(), kSize, false));
EXPECT_FALSE(entry->CouldBeSparse());
entry->Close();
ASSERT_THAT(OpenEntry(key, &entry), IsOk());
EXPECT_FALSE(entry->CouldBeSparse());
entry->Close();
}
TEST_F(DiskCacheEntryTest, CouldBeSparse) {
InitCache();
CouldBeSparse();
}
TEST_F(DiskCacheEntryTest, MemoryCouldBeSparse) {
SetMemoryOnlyMode();
InitCache();
CouldBeSparse();
}
TEST_F(DiskCacheEntryTest, MemoryOnlyMisalignedSparseIO) {
SetMemoryOnlyMode();
InitCache();
const int kSize = 8192;
scoped_refptr<net::IOBuffer> buf_1 =
base::MakeRefCounted<net::IOBuffer>(kSize);
scoped_refptr<net::IOBuffer> buf_2 =
base::MakeRefCounted<net::IOBuffer>(kSize);
CacheTestFillBuffer(buf_1->data(), kSize, false);
std::string key("the first key");
disk_cache::Entry* entry;
ASSERT_THAT(CreateEntry(key, &entry), IsOk());
// This loop writes back to back starting from offset 0 and 9000.
for (int i = 0; i < kSize; i += 1024) {
scoped_refptr<net::WrappedIOBuffer> buf_3 =
base::MakeRefCounted<net::WrappedIOBuffer>(buf_1->data() + i);
VerifySparseIO(entry, i, buf_3.get(), 1024, buf_2.get());
VerifySparseIO(entry, 9000 + i, buf_3.get(), 1024, buf_2.get());
}
// Make sure we have data written.
VerifyContentSparseIO(entry, 0, buf_1->data(), kSize);
VerifyContentSparseIO(entry, 9000, buf_1->data(), kSize);
// This tests a large write that spans 3 entries from a misaligned offset.
VerifySparseIO(entry, 20481, buf_1.get(), 8192, buf_2.get());
entry->Close();
}
TEST_F(DiskCacheEntryTest, MemoryOnlyMisalignedGetAvailableRange) {
SetMemoryOnlyMode();
InitCache();
const int kSize = 8192;
scoped_refptr<net::IOBuffer> buf = base::MakeRefCounted<net::IOBuffer>(kSize);
CacheTestFillBuffer(buf->data(), kSize, false);
disk_cache::Entry* entry;
std::string key("the first key");
ASSERT_THAT(CreateEntry(key, &entry), IsOk());
// Writes in the middle of an entry.
EXPECT_EQ(1024, entry->WriteSparseData(0, buf.get(), 1024,
net::CompletionOnceCallback()));
EXPECT_EQ(1024, entry->WriteSparseData(5120, buf.get(), 1024,
net::CompletionOnceCallback()));
EXPECT_EQ(1024, entry->WriteSparseData(10000, buf.get(), 1024,
net::CompletionOnceCallback()));
// Writes in the middle of an entry and spans 2 child entries.
EXPECT_EQ(8192, entry->WriteSparseData(50000, buf.get(), 8192,
net::CompletionOnceCallback()));
int64_t start;
net::TestCompletionCallback cb;
// Test that we stop at a discontinuous child at the second block.
int rv = entry->GetAvailableRange(0, 10000, &start, cb.callback());
EXPECT_EQ(1024, cb.GetResult(rv));
EXPECT_EQ(0, start);
// Test that number of bytes is reported correctly when we start from the
// middle of a filled region.
rv = entry->GetAvailableRange(512, 10000, &start, cb.callback());
EXPECT_EQ(512, cb.GetResult(rv));
EXPECT_EQ(512, start);
// Test that we found bytes in the child of next block.
rv = entry->GetAvailableRange(1024, 10000, &start, cb.callback());
EXPECT_EQ(1024, cb.GetResult(rv));
EXPECT_EQ(5120, start);
// Test that the desired length is respected. It starts within a filled
// region.
rv = entry->GetAvailableRange(5500, 512, &start, cb.callback());
EXPECT_EQ(512, cb.GetResult(rv));
EXPECT_EQ(5500, start);
// Test that the desired length is respected. It starts before a filled
// region.
rv = entry->GetAvailableRange(5000, 620, &start, cb.callback());
EXPECT_EQ(500, cb.GetResult(rv));
EXPECT_EQ(5120, start);
// Test that multiple blocks are scanned.
rv = entry->GetAvailableRange(40000, 20000, &start, cb.callback());
EXPECT_EQ(8192, cb.GetResult(rv));
EXPECT_EQ(50000, start);
entry->Close();
}
void DiskCacheEntryTest::UpdateSparseEntry() {
std::string key("the first key");
disk_cache::Entry* entry1;
ASSERT_THAT(CreateEntry(key, &entry1), IsOk());
const int kSize = 2048;
scoped_refptr<net::IOBuffer> buf_1 =
base::MakeRefCounted<net::IOBuffer>(kSize);
scoped_refptr<net::IOBuffer> buf_2 =
base::MakeRefCounted<net::IOBuffer>(kSize);
CacheTestFillBuffer(buf_1->data(), kSize, false);
// Write at offset 0.
VerifySparseIO(entry1, 0, buf_1.get(), kSize, buf_2.get());
entry1->Close();
// Write at offset 2048.
ASSERT_THAT(OpenEntry(key, &entry1), IsOk());
VerifySparseIO(entry1, 2048, buf_1.get(), kSize, buf_2.get());
disk_cache::Entry* entry2;
ASSERT_THAT(CreateEntry("the second key", &entry2), IsOk());
entry1->Close();
entry2->Close();
FlushQueueForTest();
if (memory_only_ || simple_cache_mode_)
EXPECT_EQ(2, cache_->GetEntryCount());
else
EXPECT_EQ(3, cache_->GetEntryCount());
}
TEST_F(DiskCacheEntryTest, UpdateSparseEntry) {
SetCacheType(net::MEDIA_CACHE);
InitCache();
UpdateSparseEntry();
}
TEST_F(DiskCacheEntryTest, MemoryOnlyUpdateSparseEntry) {
SetMemoryOnlyMode();
SetCacheType(net::MEDIA_CACHE);
InitCache();
UpdateSparseEntry();
}
void DiskCacheEntryTest::DoomSparseEntry() {
std::string key1("the first key");
std::string key2("the second key");
disk_cache::Entry *entry1, *entry2;
ASSERT_THAT(CreateEntry(key1, &entry1), IsOk());
ASSERT_THAT(CreateEntry(key2, &entry2), IsOk());
const int kSize = 4 * 1024;
scoped_refptr<net::IOBuffer> buf = base::MakeRefCounted<net::IOBuffer>(kSize);
CacheTestFillBuffer(buf->data(), kSize, false);
int64_t offset = 1024;
// Write to a bunch of ranges.
for (int i = 0; i < 12; i++) {
EXPECT_EQ(kSize, WriteSparseData(entry1, offset, buf.get(), kSize));
// Keep the second map under the default size.
if (i < 9)
EXPECT_EQ(kSize, WriteSparseData(entry2, offset, buf.get(), kSize));
offset *= 4;
}
if (memory_only_ || simple_cache_mode_)
EXPECT_EQ(2, cache_->GetEntryCount());
else
EXPECT_EQ(15, cache_->GetEntryCount());
// Doom the first entry while it's still open.
entry1->Doom();
entry1->Close();
entry2->Close();
// Doom the second entry after it's fully saved.
EXPECT_THAT(DoomEntry(key2), IsOk());
// Make sure we do all needed work. This may fail for entry2 if between Close
// and DoomEntry the system decides to remove all traces of the file from the
// system cache so we don't see that there is pending IO.
base::RunLoop().RunUntilIdle();
if (memory_only_) {
EXPECT_EQ(0, cache_->GetEntryCount());
} else {
if (5 == cache_->GetEntryCount()) {
// Most likely we are waiting for the result of reading the sparse info
// (it's always async on Posix so it is easy to miss). Unfortunately we
// don't have any signal to watch for so we can only wait.
base::PlatformThread::Sleep(base::TimeDelta::FromMilliseconds(500));
base::RunLoop().RunUntilIdle();
}
EXPECT_EQ(0, cache_->GetEntryCount());
}
}
TEST_F(DiskCacheEntryTest, DoomSparseEntry) {
UseCurrentThread();
InitCache();
DoomSparseEntry();
}
TEST_F(DiskCacheEntryTest, MemoryOnlyDoomSparseEntry) {
SetMemoryOnlyMode();
InitCache();
DoomSparseEntry();
}
// A TestCompletionCallback wrapper that deletes the cache from within the
// callback. The way TestCompletionCallback works means that all tasks (even
// new ones) are executed by the message loop before returning to the caller so
// the only way to simulate a race is to execute what we want on the callback.
class SparseTestCompletionCallback: public net::TestCompletionCallback {
public:
explicit SparseTestCompletionCallback(
std::unique_ptr<disk_cache::Backend> cache)
: cache_(std::move(cache)) {}
private:
void SetResult(int result) override {
cache_.reset();
TestCompletionCallback::SetResult(result);
}
std::unique_ptr<disk_cache::Backend> cache_;
DISALLOW_COPY_AND_ASSIGN(SparseTestCompletionCallback);
};
// Tests that we don't crash when the backend is deleted while we are working
// deleting the sub-entries of a sparse entry.
TEST_F(DiskCacheEntryTest, DoomSparseEntry2) {
UseCurrentThread();
InitCache();
std::string key("the key");
disk_cache::Entry* entry;
ASSERT_THAT(CreateEntry(key, &entry), IsOk());
const int kSize = 4 * 1024;
scoped_refptr<net::IOBuffer> buf = base::MakeRefCounted<net::IOBuffer>(kSize);
CacheTestFillBuffer(buf->data(), kSize, false);
int64_t offset = 1024;
// Write to a bunch of ranges.
for (int i = 0; i < 12; i++) {
EXPECT_EQ(kSize, entry->WriteSparseData(offset, buf.get(), kSize,
net::CompletionOnceCallback()));
offset *= 4;
}
EXPECT_EQ(9, cache_->GetEntryCount());
entry->Close();
disk_cache::Backend* cache = cache_.get();
SparseTestCompletionCallback cb(std::move(cache_));
int rv = cache->DoomEntry(key, net::HIGHEST, cb.callback());
EXPECT_THAT(rv, IsError(net::ERR_IO_PENDING));
EXPECT_THAT(cb.WaitForResult(), IsOk());
}
void DiskCacheEntryTest::PartialSparseEntry() {
std::string key("the first key");
disk_cache::Entry* entry;
ASSERT_THAT(CreateEntry(key, &entry), IsOk());
// We should be able to deal with IO that is not aligned to the block size
// of a sparse entry, at least to write a big range without leaving holes.
const int kSize = 4 * 1024;
const int kSmallSize = 128;
scoped_refptr<net::IOBuffer> buf1 =
base::MakeRefCounted<net::IOBuffer>(kSize);
CacheTestFillBuffer(buf1->data(), kSize, false);
// The first write is just to extend the entry. The third write occupies
// a 1KB block partially, it may not be written internally depending on the
// implementation.
EXPECT_EQ(kSize, WriteSparseData(entry, 20000, buf1.get(), kSize));
EXPECT_EQ(kSize, WriteSparseData(entry, 500, buf1.get(), kSize));
EXPECT_EQ(kSmallSize,
WriteSparseData(entry, 1080321, buf1.get(), kSmallSize));
entry->Close();
ASSERT_THAT(OpenEntry(key, &entry), IsOk());
scoped_refptr<net::IOBuffer> buf2 =
base::MakeRefCounted<net::IOBuffer>(kSize);
memset(buf2->data(), 0, kSize);
EXPECT_EQ(0, ReadSparseData(entry, 8000, buf2.get(), kSize));
EXPECT_EQ(500, ReadSparseData(entry, kSize, buf2.get(), kSize));
EXPECT_EQ(0, memcmp(buf2->data(), buf1->data() + kSize - 500, 500));
EXPECT_EQ(0, ReadSparseData(entry, 0, buf2.get(), kSize));
// This read should not change anything.
if (memory_only_ || simple_cache_mode_)
EXPECT_EQ(96, ReadSparseData(entry, 24000, buf2.get(), kSize));
else
EXPECT_EQ(0, ReadSparseData(entry, 24000, buf2.get(), kSize));
EXPECT_EQ(500, ReadSparseData(entry, kSize, buf2.get(), kSize));
EXPECT_EQ(0, ReadSparseData(entry, 99, buf2.get(), kSize));
int rv;
int64_t start;
net::TestCompletionCallback cb;
if (memory_only_ || simple_cache_mode_) {
rv = entry->GetAvailableRange(0, 600, &start, cb.callback());
EXPECT_EQ(100, cb.GetResult(rv));
EXPECT_EQ(500, start);
} else {
rv = entry->GetAvailableRange(0, 2048, &start, cb.callback());
EXPECT_EQ(1024, cb.GetResult(rv));
EXPECT_EQ(1024, start);
}
rv = entry->GetAvailableRange(kSize, kSize, &start, cb.callback());
EXPECT_EQ(500, cb.GetResult(rv));
EXPECT_EQ(kSize, start);
rv = entry->GetAvailableRange(20 * 1024, 10000, &start, cb.callback());
if (memory_only_ || simple_cache_mode_)
EXPECT_EQ(3616, cb.GetResult(rv));
else
EXPECT_EQ(3072, cb.GetResult(rv));
EXPECT_EQ(20 * 1024, start);
// 1. Query before a filled 1KB block.
// 2. Query within a filled 1KB block.
// 3. Query beyond a filled 1KB block.
if (memory_only_ || simple_cache_mode_) {
rv = entry->GetAvailableRange(19400, kSize, &start, cb.callback());
EXPECT_EQ(3496, cb.GetResult(rv));
EXPECT_EQ(20000, start);
} else {
rv = entry->GetAvailableRange(19400, kSize, &start, cb.callback());
EXPECT_EQ(3016, cb.GetResult(rv));
EXPECT_EQ(20480, start);
}
rv = entry->GetAvailableRange(3073, kSize, &start, cb.callback());
EXPECT_EQ(1523, cb.GetResult(rv));
EXPECT_EQ(3073, start);
rv = entry->GetAvailableRange(4600, kSize, &start, cb.callback());
EXPECT_EQ(0, cb.GetResult(rv));
EXPECT_EQ(4600, start);
// Now make another write and verify that there is no hole in between.
EXPECT_EQ(kSize, WriteSparseData(entry, 500 + kSize, buf1.get(), kSize));
rv = entry->GetAvailableRange(1024, 10000, &start, cb.callback());
EXPECT_EQ(7 * 1024 + 500, cb.GetResult(rv));
EXPECT_EQ(1024, start);
EXPECT_EQ(kSize, ReadSparseData(entry, kSize, buf2.get(), kSize));
EXPECT_EQ(0, memcmp(buf2->data(), buf1->data() + kSize - 500, 500));
EXPECT_EQ(0, memcmp(buf2->data() + 500, buf1->data(), kSize - 500));
entry->Close();
}
TEST_F(DiskCacheEntryTest, PartialSparseEntry) {
InitCache();
PartialSparseEntry();
}
TEST_F(DiskCacheEntryTest, MemoryPartialSparseEntry) {
SetMemoryOnlyMode();
InitCache();
PartialSparseEntry();
}
// Tests that corrupt sparse children are removed automatically.
TEST_F(DiskCacheEntryTest, CleanupSparseEntry) {
InitCache();
std::string key("the first key");
disk_cache::Entry* entry;
ASSERT_THAT(CreateEntry(key, &entry), IsOk());
const int kSize = 4 * 1024;
scoped_refptr<net::IOBuffer> buf1 =
base::MakeRefCounted<net::IOBuffer>(kSize);
CacheTestFillBuffer(buf1->data(), kSize, false);
const int k1Meg = 1024 * 1024;
EXPECT_EQ(kSize, WriteSparseData(entry, 8192, buf1.get(), kSize));
EXPECT_EQ(kSize, WriteSparseData(entry, k1Meg + 8192, buf1.get(), kSize));
EXPECT_EQ(kSize, WriteSparseData(entry, 2 * k1Meg + 8192, buf1.get(), kSize));
entry->Close();
EXPECT_EQ(4, cache_->GetEntryCount());
std::unique_ptr<TestIterator> iter = CreateIterator();
int count = 0;
std::string child_key[2];
while (iter->OpenNextEntry(&entry) == net::OK) {
ASSERT_TRUE(entry != NULL);
// Writing to an entry will alter the LRU list and invalidate the iterator.
if (entry->GetKey() != key && count < 2)
child_key[count++] = entry->GetKey();
entry->Close();
}
for (int i = 0; i < 2; i++) {
ASSERT_THAT(OpenEntry(child_key[i], &entry), IsOk());
// Overwrite the header's magic and signature.
EXPECT_EQ(12, WriteData(entry, 2, 0, buf1.get(), 12, false));
entry->Close();
}
EXPECT_EQ(4, cache_->GetEntryCount());
ASSERT_THAT(OpenEntry(key, &entry), IsOk());
// Two children should be gone. One while reading and one while writing.
EXPECT_EQ(0, ReadSparseData(entry, 2 * k1Meg + 8192, buf1.get(), kSize));
EXPECT_EQ(kSize, WriteSparseData(entry, k1Meg + 16384, buf1.get(), kSize));
EXPECT_EQ(0, ReadSparseData(entry, k1Meg + 8192, buf1.get(), kSize));
// We never touched this one.
EXPECT_EQ(kSize, ReadSparseData(entry, 8192, buf1.get(), kSize));
entry->Close();
// We re-created one of the corrupt children.
EXPECT_EQ(3, cache_->GetEntryCount());
}
TEST_F(DiskCacheEntryTest, CancelSparseIO) {
UseCurrentThread();
InitCache();
std::string key("the first key");
disk_cache::Entry* entry;
ASSERT_THAT(CreateEntry(key, &entry), IsOk());
const int kSize = 40 * 1024;
scoped_refptr<net::IOBuffer> buf = base::MakeRefCounted<net::IOBuffer>(kSize);
CacheTestFillBuffer(buf->data(), kSize, false);
// This will open and write two "real" entries.
net::TestCompletionCallback cb1, cb2, cb3, cb4, cb5;
int rv = entry->WriteSparseData(
1024 * 1024 - 4096, buf.get(), kSize, cb1.callback());
EXPECT_THAT(rv, IsError(net::ERR_IO_PENDING));
int64_t offset = 0;
rv = entry->GetAvailableRange(offset, kSize, &offset, cb5.callback());
rv = cb5.GetResult(rv);
if (!cb1.have_result()) {
// We may or may not have finished writing to the entry. If we have not,
// we cannot start another operation at this time.
EXPECT_THAT(rv, IsError(net::ERR_CACHE_OPERATION_NOT_SUPPORTED));
}
// We cancel the pending operation, and register multiple notifications.
entry->CancelSparseIO();
EXPECT_THAT(entry->ReadyForSparseIO(cb2.callback()),
IsError(net::ERR_IO_PENDING));
EXPECT_THAT(entry->ReadyForSparseIO(cb3.callback()),
IsError(net::ERR_IO_PENDING));
entry->CancelSparseIO(); // Should be a no op at this point.
EXPECT_THAT(entry->ReadyForSparseIO(cb4.callback()),
IsError(net::ERR_IO_PENDING));
if (!cb1.have_result()) {
EXPECT_EQ(net::ERR_CACHE_OPERATION_NOT_SUPPORTED,
entry->ReadSparseData(offset, buf.get(), kSize,
net::CompletionOnceCallback()));
EXPECT_EQ(net::ERR_CACHE_OPERATION_NOT_SUPPORTED,
entry->WriteSparseData(offset, buf.get(), kSize,
net::CompletionOnceCallback()));
}
// Now see if we receive all notifications. Note that we should not be able
// to write everything (unless the timing of the system is really weird).
rv = cb1.WaitForResult();
EXPECT_TRUE(rv == 4096 || rv == kSize);
EXPECT_THAT(cb2.WaitForResult(), IsOk());
EXPECT_THAT(cb3.WaitForResult(), IsOk());
EXPECT_THAT(cb4.WaitForResult(), IsOk());
rv = entry->GetAvailableRange(offset, kSize, &offset, cb5.callback());
EXPECT_EQ(0, cb5.GetResult(rv));
entry->Close();
}
// Tests that we perform sanity checks on an entry's key. Note that there are
// other tests that exercise sanity checks by using saved corrupt files.
TEST_F(DiskCacheEntryTest, KeySanityCheck) {
UseCurrentThread();
InitCache();
std::string key("the first key");
disk_cache::Entry* entry;
ASSERT_THAT(CreateEntry(key, &entry), IsOk());
disk_cache::EntryImpl* entry_impl =
static_cast<disk_cache::EntryImpl*>(entry);
disk_cache::EntryStore* store = entry_impl->entry()->Data();
// We have reserved space for a short key (one block), let's say that the key
// takes more than one block, and remove the NULLs after the actual key.
store->key_len = 800;
memset(store->key + key.size(), 'k', sizeof(store->key) - key.size());
entry_impl->entry()->set_modified();
entry->Close();
// We have a corrupt entry. Now reload it. We should NOT read beyond the
// allocated buffer here.
ASSERT_NE(net::OK, OpenEntry(key, &entry));
DisableIntegrityCheck();
}
TEST_F(DiskCacheEntryTest, SimpleCacheInternalAsyncIO) {
SetSimpleCacheMode();
InitCache();
InternalAsyncIO();
}
TEST_F(DiskCacheEntryTest, SimpleCacheExternalAsyncIO) {
SetSimpleCacheMode();
InitCache();
ExternalAsyncIO();
}
TEST_F(DiskCacheEntryTest, SimpleCacheReleaseBuffer) {
SetSimpleCacheMode();
InitCache();
for (int i = 0; i < disk_cache::kSimpleEntryStreamCount; ++i) {
EXPECT_THAT(DoomAllEntries(), IsOk());
ReleaseBuffer(i);
}
}
TEST_F(DiskCacheEntryTest, SimpleCacheStreamAccess) {
SetSimpleCacheMode();
InitCache();
StreamAccess();
}
TEST_F(DiskCacheEntryTest, SimpleCacheGetKey) {
SetSimpleCacheMode();
InitCache();
GetKey();
}
TEST_F(DiskCacheEntryTest, SimpleCacheGetTimes) {
SetSimpleCacheMode();
InitCache();
for (int i = 0; i < disk_cache::kSimpleEntryStreamCount; ++i) {
EXPECT_THAT(DoomAllEntries(), IsOk());
GetTimes(i);
}
}
TEST_F(DiskCacheEntryTest, SimpleCacheGrowData) {
SetSimpleCacheMode();
InitCache();
for (int i = 0; i < disk_cache::kSimpleEntryStreamCount; ++i) {
EXPECT_THAT(DoomAllEntries(), IsOk());
GrowData(i);
}
}
TEST_F(DiskCacheEntryTest, SimpleCacheTruncateData) {
SetSimpleCacheMode();
InitCache();
for (int i = 0; i < disk_cache::kSimpleEntryStreamCount; ++i) {
EXPECT_THAT(DoomAllEntries(), IsOk());
TruncateData(i);
}
}
TEST_F(DiskCacheEntryTest, SimpleCacheZeroLengthIO) {
SetSimpleCacheMode();
InitCache();
for (int i = 0; i < disk_cache::kSimpleEntryStreamCount; ++i) {
EXPECT_THAT(DoomAllEntries(), IsOk());
ZeroLengthIO(i);
}
}
TEST_F(DiskCacheEntryTest, SimpleCacheSizeAtCreate) {
SetSimpleCacheMode();
InitCache();
SizeAtCreate();
}
TEST_F(DiskCacheEntryTest, SimpleCacheReuseExternalEntry) {
SetSimpleCacheMode();
SetMaxSize(200 * 1024);
InitCache();
for (int i = 0; i < disk_cache::kSimpleEntryStreamCount; ++i) {
EXPECT_THAT(DoomAllEntries(), IsOk());
ReuseEntry(20 * 1024, i);
}
}
TEST_F(DiskCacheEntryTest, SimpleCacheReuseInternalEntry) {
SetSimpleCacheMode();
SetMaxSize(100 * 1024);
InitCache();
for (int i = 0; i < disk_cache::kSimpleEntryStreamCount; ++i) {
EXPECT_THAT(DoomAllEntries(), IsOk());
ReuseEntry(10 * 1024, i);
}
}
TEST_F(DiskCacheEntryTest, SimpleCacheGiantEntry) {
const int kBufSize = 32 * 1024;
scoped_refptr<net::IOBuffer> buffer =
base::MakeRefCounted<net::IOBuffer>(kBufSize);
CacheTestFillBuffer(buffer->data(), kBufSize, false);
// Make sure SimpleCache can write up to 5MiB entry even with a 20MiB cache
// size that Android WebView uses at the time of this test's writing.
SetSimpleCacheMode();
SetMaxSize(20 * 1024 * 1024);
InitCache();
{
std::string key1("the first key");
disk_cache::Entry* entry1 = nullptr;
ASSERT_THAT(CreateEntry(key1, &entry1), IsOk());
const int kSize1 = 5 * 1024 * 1024;
EXPECT_EQ(kBufSize, WriteData(entry1, 1 /* stream */, kSize1 - kBufSize,
buffer.get(), kBufSize, true /* truncate */));
entry1->Close();
}
// ... but not bigger than that.
{
std::string key2("the second key");
disk_cache::Entry* entry2 = nullptr;
ASSERT_THAT(CreateEntry(key2, &entry2), IsOk());
const int kSize2 = 5 * 1024 * 1024 + 1;
EXPECT_EQ(net::ERR_FAILED,
WriteData(entry2, 1 /* stream */, kSize2 - kBufSize, buffer.get(),
kBufSize, true /* truncate */));
entry2->Close();
}
}
TEST_F(DiskCacheEntryTest, SimpleCacheSizeChanges) {
SetSimpleCacheMode();
InitCache();
for (int i = 0; i < disk_cache::kSimpleEntryStreamCount; ++i) {
EXPECT_THAT(DoomAllEntries(), IsOk());
SizeChanges(i);
}
}
TEST_F(DiskCacheEntryTest, SimpleCacheInvalidData) {
SetSimpleCacheMode();
InitCache();
for (int i = 0; i < disk_cache::kSimpleEntryStreamCount; ++i) {
EXPECT_THAT(DoomAllEntries(), IsOk());
InvalidData(i);
}
}
TEST_F(DiskCacheEntryTest, SimpleCacheReadWriteDestroyBuffer) {
// Proving that the test works well with optimistic operations enabled is
// subtle, instead run only in APP_CACHE mode to disable optimistic
// operations. Stream 0 always uses optimistic operations, so the test is not
// run on stream 0.
SetCacheType(net::APP_CACHE);
SetSimpleCacheMode();
InitCache();
for (int i = 1; i < disk_cache::kSimpleEntryStreamCount; ++i) {
EXPECT_THAT(DoomAllEntries(), IsOk());
ReadWriteDestroyBuffer(i);
}
}
TEST_F(DiskCacheEntryTest, SimpleCacheDoomEntry) {
SetSimpleCacheMode();
InitCache();
DoomNormalEntry();
}
TEST_F(DiskCacheEntryTest, SimpleCacheDoomEntryNextToOpenEntry) {
SetSimpleCacheMode();
InitCache();
DoomEntryNextToOpenEntry();
}
TEST_F(DiskCacheEntryTest, SimpleCacheDoomedEntry) {
SetSimpleCacheMode();
InitCache();
// Stream 2 is excluded because the implementation does not support writing to
// it on a doomed entry, if it was previously lazily omitted.
for (int i = 0; i < disk_cache::kSimpleEntryStreamCount - 1; ++i) {
EXPECT_THAT(DoomAllEntries(), IsOk());
DoomedEntry(i);
}
}
// Creates an entry with corrupted last byte in stream 0.
// Requires SimpleCacheMode.
bool DiskCacheEntryTest::SimpleCacheMakeBadChecksumEntry(const std::string& key,
int data_size) {
disk_cache::Entry* entry = NULL;
if (CreateEntry(key, &entry) != net::OK || !entry) {
LOG(ERROR) << "Could not create entry";
return false;
}
scoped_refptr<net::IOBuffer> buffer =
base::MakeRefCounted<net::IOBuffer>(data_size);
memset(buffer->data(), 'A', data_size);
EXPECT_EQ(data_size, WriteData(entry, 1, 0, buffer.get(), data_size, false));
entry->Close();
entry = NULL;
// Corrupt the last byte of the data.
base::FilePath entry_file0_path = cache_path_.AppendASCII(
disk_cache::simple_util::GetFilenameFromKeyAndFileIndex(key, 0));
base::File entry_file0(entry_file0_path,
base::File::FLAG_WRITE | base::File::FLAG_OPEN);
if (!entry_file0.IsValid())
return false;
int64_t file_offset =
sizeof(disk_cache::SimpleFileHeader) + key.size() + data_size - 2;
EXPECT_EQ(1, entry_file0.Write(file_offset, "X", 1));
return true;
}
TEST_F(DiskCacheEntryTest, SimpleCacheBadChecksum) {
base::HistogramTester histogram_tester;
SetSimpleCacheMode();
InitCache();
const char key[] = "the first key";
const int kLargeSize = 50000;
ASSERT_TRUE(SimpleCacheMakeBadChecksumEntry(key, kLargeSize));
disk_cache::Entry* entry = NULL;
// Open the entry. Can't spot the checksum that quickly with it so
// huge.
ASSERT_THAT(OpenEntry(key, &entry), IsOk());
ScopedEntryPtr entry_closer(entry);
EXPECT_GE(kLargeSize, entry->GetDataSize(1));
scoped_refptr<net::IOBuffer> read_buffer =
base::MakeRefCounted<net::IOBuffer>(kLargeSize);
EXPECT_EQ(net::ERR_CACHE_CHECKSUM_MISMATCH,
ReadData(entry, 1, 0, read_buffer.get(), kLargeSize));
histogram_tester.ExpectUniqueSample(
"SimpleCache.Http.ReadResult",
disk_cache::READ_RESULT_SYNC_CHECKSUM_FAILURE, 1);
}
// Tests that an entry that has had an IO error occur can still be Doomed().
TEST_F(DiskCacheEntryTest, SimpleCacheErrorThenDoom) {
base::HistogramTester histogram_tester;
SetSimpleCacheMode();
InitCache();
const char key[] = "the first key";
const int kLargeSize = 50000;
ASSERT_TRUE(SimpleCacheMakeBadChecksumEntry(key, kLargeSize));
disk_cache::Entry* entry = NULL;
// Open the entry, forcing an IO error.
ASSERT_THAT(OpenEntry(key, &entry), IsOk());
ScopedEntryPtr entry_closer(entry);
EXPECT_GE(kLargeSize, entry->GetDataSize(1));
scoped_refptr<net::IOBuffer> read_buffer =
base::MakeRefCounted<net::IOBuffer>(kLargeSize);
EXPECT_EQ(net::ERR_CACHE_CHECKSUM_MISMATCH,
ReadData(entry, 1, 0, read_buffer.get(), kLargeSize));
histogram_tester.ExpectUniqueSample(
"SimpleCache.Http.ReadResult",
disk_cache::READ_RESULT_SYNC_CHECKSUM_FAILURE, 1);
entry->Doom(); // Should not crash.
}
TEST_F(DiskCacheEntryTest, SimpleCacheCreateAfterDiskLayerDoom) {
// Code coverage for what happens when a queued create runs after failure
// was noticed at SimpleSynchronousEntry layer.
SetSimpleCacheMode();
// Disable optimistic ops so we can block on CreateEntry and start
// WriteData off with an empty op queue.
SetCacheType(net::APP_CACHE);
InitCache();
const char key[] = "the key";
const int kSize1 = 10;
scoped_refptr<net::IOBuffer> buffer1 =
base::MakeRefCounted<net::IOBuffer>(kSize1);
CacheTestFillBuffer(buffer1->data(), kSize1, false);
disk_cache::Entry* entry = nullptr;
ASSERT_EQ(net::OK, CreateEntry(key, &entry));
ASSERT_TRUE(entry != nullptr);
// Make an empty _1 file, to cause a stream 2 write to fail.
base::FilePath entry_file1_path = cache_path_.AppendASCII(
disk_cache::simple_util::GetFilenameFromKeyAndFileIndex(key, 1));
base::File entry_file1(entry_file1_path,
base::File::FLAG_WRITE | base::File::FLAG_CREATE);
ASSERT_TRUE(entry_file1.IsValid());
entry->WriteData(2, 0, buffer1.get(), kSize1, net::CompletionOnceCallback(),
/* truncate= */ true);
entry->Close();
// At this point we have put WriteData & Close on the queue, and WriteData
// started, but we haven't given the event loop control so the failure
// hasn't been reported and handled here, so the entry is still active
// for the key. Queue up another create for same key, and run through the
// events.
disk_cache::Entry* entry2 = nullptr;
ASSERT_EQ(net::ERR_FAILED, CreateEntry(key, &entry2));
ASSERT_TRUE(entry2 == nullptr);
EXPECT_EQ(0, cache_->GetEntryCount());
// Should be able to create properly next time, though.
disk_cache::Entry* entry3 = nullptr;
ASSERT_EQ(net::OK, CreateEntry(key, &entry3));
ASSERT_TRUE(entry3 != nullptr);
entry3->Close();
}
TEST_F(DiskCacheEntryTest, SimpleCacheQueuedOpenOnDoomedEntry) {
// This tests the following sequence of ops:
// A = Create(K);
// Close(A);
// B = Open(K);
// Doom(K);
// Close(B);
//
// ... where the execution of the Open sits on the queue all the way till
// Doom. This now succeeds, as the doom is merely queued at time of Open,
// rather than completed.
SetSimpleCacheMode();
// Disable optimistic ops so we can block on CreateEntry and start
// WriteData off with an empty op queue.
SetCacheType(net::APP_CACHE);
InitCache();
const char key[] = "the key";
disk_cache::Entry* entry = nullptr;
ASSERT_EQ(net::OK, CreateEntry(key, &entry)); // event loop!
ASSERT_TRUE(entry != nullptr);
entry->Close();
disk_cache::Entry* entry2 = nullptr;
// Done via cache_ -> no event loop.
net::TestCompletionCallback cb;
ASSERT_EQ(net::ERR_IO_PENDING,
cache_->OpenEntry(key, net::HIGHEST, &entry2, cb.callback()));
net::TestCompletionCallback cb2;
cache_->DoomEntry(key, net::HIGHEST, cb2.callback());
// Now event loop.
EXPECT_EQ(net::OK, cb.WaitForResult());
ASSERT_TRUE(entry2 != nullptr);
entry2->Close();
EXPECT_EQ(net::OK, cb2.WaitForResult());
EXPECT_EQ(0, cache_->GetEntryCount());
}
TEST_F(DiskCacheEntryTest, SimpleCacheDoomErrorRace) {
// Code coverage for a doom racing with a doom induced by a failure.
SetSimpleCacheMode();
// Disable optimistic ops so we can block on CreateEntry and start
// WriteData off with an empty op queue.
SetCacheType(net::APP_CACHE);
InitCache();
const char kKey[] = "the first key";
const int kSize1 = 10;
scoped_refptr<net::IOBuffer> buffer1 =
base::MakeRefCounted<net::IOBuffer>(kSize1);
CacheTestFillBuffer(buffer1->data(), kSize1, false);
disk_cache::Entry* entry = nullptr;
ASSERT_EQ(net::OK, CreateEntry(kKey, &entry));
ASSERT_TRUE(entry != nullptr);
// Now an empty _1 file, to cause a stream 2 write to fail.
base::FilePath entry_file1_path = cache_path_.AppendASCII(
disk_cache::simple_util::GetFilenameFromKeyAndFileIndex(kKey, 1));
base::File entry_file1(entry_file1_path,
base::File::FLAG_WRITE | base::File::FLAG_CREATE);
ASSERT_TRUE(entry_file1.IsValid());
entry->WriteData(2, 0, buffer1.get(), kSize1, net::CompletionOnceCallback(),
/* truncate= */ true);
net::TestCompletionCallback cb;
cache_->DoomEntry(kKey, net::HIGHEST, cb.callback());
entry->Close();
EXPECT_EQ(0, cb.WaitForResult());
}
bool TruncatePath(const base::FilePath& file_path, int64_t length) {
base::File file(file_path, base::File::FLAG_WRITE | base::File::FLAG_OPEN);
if (!file.IsValid())
return false;
return file.SetLength(length);
}
TEST_F(DiskCacheEntryTest, SimpleCacheNoEOF) {
SetSimpleCacheMode();
InitCache();
const std::string key("the first key");
disk_cache::Entry* entry = NULL;
ASSERT_THAT(CreateEntry(key, &entry), IsOk());
disk_cache::Entry* null = NULL;
EXPECT_NE(null, entry);
entry->Close();
entry = NULL;
// Force the entry to flush to disk, so subsequent platform file operations
// succed.
ASSERT_THAT(OpenEntry(key, &entry), IsOk());
entry->Close();
entry = NULL;
// Truncate the file such that the length isn't sufficient to have an EOF
// record.
int kTruncationBytes = -static_cast<int>(sizeof(disk_cache::SimpleFileEOF));
const base::FilePath entry_path = cache_path_.AppendASCII(
disk_cache::simple_util::GetFilenameFromKeyAndFileIndex(key, 0));
const int64_t invalid_size = disk_cache::simple_util::GetFileSizeFromDataSize(
key.size(), kTruncationBytes);
EXPECT_TRUE(TruncatePath(entry_path, invalid_size));
EXPECT_THAT(OpenEntry(key, &entry), IsError(net::ERR_FAILED));
DisableIntegrityCheck();
}
TEST_F(DiskCacheEntryTest, SimpleCacheNonOptimisticOperationsBasic) {
// Test sequence:
// Create, Write, Read, Close.
SetCacheType(net::APP_CACHE); // APP_CACHE doesn't use optimistic operations.
SetSimpleCacheMode();
InitCache();
disk_cache::Entry* const null_entry = NULL;
disk_cache::Entry* entry = NULL;
EXPECT_THAT(CreateEntry("my key", &entry), IsOk());
ASSERT_NE(null_entry, entry);
ScopedEntryPtr entry_closer(entry);
const int kBufferSize = 10;
scoped_refptr<net::IOBufferWithSize> write_buffer =
base::MakeRefCounted<net::IOBufferWithSize>(kBufferSize);
CacheTestFillBuffer(write_buffer->data(), write_buffer->size(), false);
EXPECT_EQ(
write_buffer->size(),
WriteData(entry, 1, 0, write_buffer.get(), write_buffer->size(), false));
scoped_refptr<net::IOBufferWithSize> read_buffer =
base::MakeRefCounted<net::IOBufferWithSize>(kBufferSize);
EXPECT_EQ(read_buffer->size(),
ReadData(entry, 1, 0, read_buffer.get(), read_buffer->size()));
}
TEST_F(DiskCacheEntryTest, SimpleCacheNonOptimisticOperationsDontBlock) {
// Test sequence:
// Create, Write, Close.
SetCacheType(net::APP_CACHE); // APP_CACHE doesn't use optimistic operations.
SetSimpleCacheMode();
InitCache();
disk_cache::Entry* const null_entry = NULL;
MessageLoopHelper helper;
CallbackTest create_callback(&helper, false);
int expected_callback_runs = 0;
const int kBufferSize = 10;
scoped_refptr<net::IOBufferWithSize> write_buffer =
base::MakeRefCounted<net::IOBufferWithSize>(kBufferSize);
disk_cache::Entry* entry = NULL;
EXPECT_THAT(CreateEntry("my key", &entry), IsOk());
ASSERT_NE(null_entry, entry);
ScopedEntryPtr entry_closer(entry);
CacheTestFillBuffer(write_buffer->data(), write_buffer->size(), false);
CallbackTest write_callback(&helper, false);
int ret = entry->WriteData(
1,
0,
write_buffer.get(),
write_buffer->size(),
base::Bind(&CallbackTest::Run, base::Unretained(&write_callback)),
false);
ASSERT_THAT(ret, IsError(net::ERR_IO_PENDING));
helper.WaitUntilCacheIoFinished(++expected_callback_runs);
}
TEST_F(DiskCacheEntryTest,
SimpleCacheNonOptimisticOperationsBasicsWithoutWaiting) {
// Test sequence:
// Create, Write, Read, Close.
SetCacheType(net::APP_CACHE); // APP_CACHE doesn't use optimistic operations.
SetSimpleCacheMode();
InitCache();
disk_cache::Entry* const null_entry = NULL;
MessageLoopHelper helper;
disk_cache::Entry* entry = NULL;
// Note that |entry| is only set once CreateEntry() completed which is why we
// have to wait (i.e. use the helper CreateEntry() function).
EXPECT_THAT(CreateEntry("my key", &entry), IsOk());
ASSERT_NE(null_entry, entry);
ScopedEntryPtr entry_closer(entry);
const int kBufferSize = 10;
scoped_refptr<net::IOBufferWithSize> write_buffer =
base::MakeRefCounted<net::IOBufferWithSize>(kBufferSize);
CacheTestFillBuffer(write_buffer->data(), write_buffer->size(), false);
CallbackTest write_callback(&helper, false);
int ret = entry->WriteData(
1,
0,
write_buffer.get(),
write_buffer->size(),
base::Bind(&CallbackTest::Run, base::Unretained(&write_callback)),
false);
EXPECT_THAT(ret, IsError(net::ERR_IO_PENDING));
int expected_callback_runs = 1;
scoped_refptr<net::IOBufferWithSize> read_buffer =
base::MakeRefCounted<net::IOBufferWithSize>(kBufferSize);
CallbackTest read_callback(&helper, false);
ret = entry->ReadData(
1,
0,
read_buffer.get(),
read_buffer->size(),
base::Bind(&CallbackTest::Run, base::Unretained(&read_callback)));
EXPECT_THAT(ret, IsError(net::ERR_IO_PENDING));
++expected_callback_runs;
helper.WaitUntilCacheIoFinished(expected_callback_runs);
ASSERT_EQ(read_buffer->size(), write_buffer->size());
EXPECT_EQ(
0,
memcmp(read_buffer->data(), write_buffer->data(), read_buffer->size()));
}
TEST_F(DiskCacheEntryTest, SimpleCacheOptimistic) {
// Test sequence:
// Create, Write, Read, Write, Read, Close.
SetSimpleCacheMode();
InitCache();
disk_cache::Entry* null = NULL;
const char key[] = "the first key";
MessageLoopHelper helper;
CallbackTest callback1(&helper, false);
CallbackTest callback2(&helper, false);
CallbackTest callback3(&helper, false);
CallbackTest callback4(&helper, false);
CallbackTest callback5(&helper, false);
int expected = 0;
const int kSize1 = 10;
const int kSize2 = 20;
scoped_refptr<net::IOBuffer> buffer1 =
base::MakeRefCounted<net::IOBuffer>(kSize1);
scoped_refptr<net::IOBuffer> buffer1_read =
base::MakeRefCounted<net::IOBuffer>(kSize1);
scoped_refptr<net::IOBuffer> buffer2 =
base::MakeRefCounted<net::IOBuffer>(kSize2);
scoped_refptr<net::IOBuffer> buffer2_read =
base::MakeRefCounted<net::IOBuffer>(kSize2);
CacheTestFillBuffer(buffer1->data(), kSize1, false);
CacheTestFillBuffer(buffer2->data(), kSize2, false);
disk_cache::Entry* entry = NULL;
// Create is optimistic, must return OK.
ASSERT_EQ(net::OK,
cache_->CreateEntry(
key, net::HIGHEST, &entry,
base::Bind(&CallbackTest::Run, base::Unretained(&callback1))));
EXPECT_NE(null, entry);
ScopedEntryPtr entry_closer(entry);
// This write may or may not be optimistic (it depends if the previous
// optimistic create already finished by the time we call the write here).
int ret = entry->WriteData(
1,
0,
buffer1.get(),
kSize1,
base::Bind(&CallbackTest::Run, base::Unretained(&callback2)),
false);
EXPECT_TRUE(kSize1 == ret || net::ERR_IO_PENDING == ret);
if (net::ERR_IO_PENDING == ret)
expected++;
// This Read must not be optimistic, since we don't support that yet.
EXPECT_EQ(net::ERR_IO_PENDING,
entry->ReadData(
1,
0,
buffer1_read.get(),
kSize1,
base::Bind(&CallbackTest::Run, base::Unretained(&callback3))));
expected++;
EXPECT_TRUE(helper.WaitUntilCacheIoFinished(expected));
EXPECT_EQ(0, memcmp(buffer1->data(), buffer1_read->data(), kSize1));
// At this point after waiting, the pending operations queue on the entry
// should be empty, so the next Write operation must run as optimistic.
EXPECT_EQ(kSize2,
entry->WriteData(
1,
0,
buffer2.get(),
kSize2,
base::Bind(&CallbackTest::Run, base::Unretained(&callback4)),
false));
// Lets do another read so we block until both the write and the read
// operation finishes and we can then test for HasOneRef() below.
EXPECT_EQ(net::ERR_IO_PENDING,
entry->ReadData(
1,
0,
buffer2_read.get(),
kSize2,
base::Bind(&CallbackTest::Run, base::Unretained(&callback5))));
expected++;
EXPECT_TRUE(helper.WaitUntilCacheIoFinished(expected));
EXPECT_EQ(0, memcmp(buffer2->data(), buffer2_read->data(), kSize2));
// Check that we are not leaking.
EXPECT_NE(entry, null);
EXPECT_TRUE(
static_cast<disk_cache::SimpleEntryImpl*>(entry)->HasOneRef());
}
TEST_F(DiskCacheEntryTest, SimpleCacheOptimistic2) {
// Test sequence:
// Create, Open, Close, Close.
SetSimpleCacheMode();
InitCache();
disk_cache::Entry* null = NULL;
const char key[] = "the first key";
MessageLoopHelper helper;
CallbackTest callback1(&helper, false);
CallbackTest callback2(&helper, false);
disk_cache::Entry* entry = NULL;
ASSERT_EQ(net::OK,
cache_->CreateEntry(
key, net::HIGHEST, &entry,
base::Bind(&CallbackTest::Run, base::Unretained(&callback1))));
EXPECT_NE(null, entry);
ScopedEntryPtr entry_closer(entry);
disk_cache::Entry* entry2 = NULL;
ASSERT_EQ(net::ERR_IO_PENDING,
cache_->OpenEntry(
key, net::HIGHEST, &entry2,
base::Bind(&CallbackTest::Run, base::Unretained(&callback2))));
ASSERT_TRUE(helper.WaitUntilCacheIoFinished(1));
EXPECT_NE(null, entry2);
EXPECT_EQ(entry, entry2);
// We have to call close twice, since we called create and open above.
entry->Close();
// Check that we are not leaking.
EXPECT_TRUE(
static_cast<disk_cache::SimpleEntryImpl*>(entry)->HasOneRef());
}
TEST_F(DiskCacheEntryTest, SimpleCacheOptimistic3) {
// Test sequence:
// Create, Close, Open, Close.
SetSimpleCacheMode();
InitCache();
disk_cache::Entry* null = NULL;
const char key[] = "the first key";
disk_cache::Entry* entry = NULL;
ASSERT_EQ(net::OK, cache_->CreateEntry(key, net::HIGHEST, &entry,
net::CompletionOnceCallback()));
EXPECT_NE(null, entry);
entry->Close();
net::TestCompletionCallback cb;
disk_cache::Entry* entry2 = NULL;
ASSERT_EQ(net::ERR_IO_PENDING,
cache_->OpenEntry(key, net::HIGHEST, &entry2, cb.callback()));
ASSERT_THAT(cb.GetResult(net::ERR_IO_PENDING), IsOk());
ScopedEntryPtr entry_closer(entry2);
EXPECT_NE(null, entry2);
EXPECT_EQ(entry, entry2);
// Check that we are not leaking.
EXPECT_TRUE(
static_cast<disk_cache::SimpleEntryImpl*>(entry2)->HasOneRef());
}
TEST_F(DiskCacheEntryTest, SimpleCacheOptimistic4) {
// Test sequence:
// Create, Close, Write, Open, Open, Close, Write, Read, Close.
SetSimpleCacheMode();
InitCache();
disk_cache::Entry* null = NULL;
const char key[] = "the first key";
net::TestCompletionCallback cb;
const int kSize1 = 10;
scoped_refptr<net::IOBuffer> buffer1 =
base::MakeRefCounted<net::IOBuffer>(kSize1);
CacheTestFillBuffer(buffer1->data(), kSize1, false);
disk_cache::Entry* entry = NULL;
ASSERT_EQ(net::OK, cache_->CreateEntry(key, net::HIGHEST, &entry,
net::CompletionOnceCallback()));
EXPECT_NE(null, entry);
entry->Close();
// Lets do a Write so we block until both the Close and the Write
// operation finishes. Write must fail since we are writing in a closed entry.
EXPECT_EQ(
net::ERR_IO_PENDING,
entry->WriteData(1, 0, buffer1.get(), kSize1, cb.callback(), false));
EXPECT_THAT(cb.GetResult(net::ERR_IO_PENDING), IsError(net::ERR_FAILED));
// Finish running the pending tasks so that we fully complete the close
// operation and destroy the entry object.
base::RunLoop().RunUntilIdle();
// At this point the |entry| must have been destroyed, and called
// RemoveSelfFromBackend().
disk_cache::Entry* entry2 = NULL;
ASSERT_EQ(net::ERR_IO_PENDING,
cache_->OpenEntry(key, net::HIGHEST, &entry2, cb.callback()));
ASSERT_THAT(cb.GetResult(net::ERR_IO_PENDING), IsOk());
EXPECT_NE(null, entry2);
disk_cache::Entry* entry3 = NULL;
ASSERT_EQ(net::ERR_IO_PENDING,
cache_->OpenEntry(key, net::HIGHEST, &entry3, cb.callback()));
ASSERT_THAT(cb.GetResult(net::ERR_IO_PENDING), IsOk());
EXPECT_NE(null, entry3);
EXPECT_EQ(entry2, entry3);
entry3->Close();
// The previous Close doesn't actually closes the entry since we opened it
// twice, so the next Write operation must succeed and it must be able to
// perform it optimistically, since there is no operation running on this
// entry.
EXPECT_EQ(kSize1, entry2->WriteData(1, 0, buffer1.get(), kSize1,
net::CompletionOnceCallback(), false));
// Lets do another read so we block until both the write and the read
// operation finishes and we can then test for HasOneRef() below.
EXPECT_EQ(net::ERR_IO_PENDING,
entry2->ReadData(1, 0, buffer1.get(), kSize1, cb.callback()));
EXPECT_EQ(kSize1, cb.GetResult(net::ERR_IO_PENDING));
// Check that we are not leaking.
EXPECT_TRUE(
static_cast<disk_cache::SimpleEntryImpl*>(entry2)->HasOneRef());
entry2->Close();
}
TEST_F(DiskCacheEntryTest, SimpleCacheOptimistic5) {
// Test sequence:
// Create, Doom, Write, Read, Close.
SetSimpleCacheMode();
InitCache();
disk_cache::Entry* null = NULL;
const char key[] = "the first key";
net::TestCompletionCallback cb;
const int kSize1 = 10;
scoped_refptr<net::IOBuffer> buffer1 =
base::MakeRefCounted<net::IOBuffer>(kSize1);
CacheTestFillBuffer(buffer1->data(), kSize1, false);
disk_cache::Entry* entry = NULL;
ASSERT_EQ(net::OK, cache_->CreateEntry(key, net::HIGHEST, &entry,
net::CompletionOnceCallback()));
EXPECT_NE(null, entry);
ScopedEntryPtr entry_closer(entry);
entry->Doom();
EXPECT_EQ(
net::ERR_IO_PENDING,
entry->WriteData(1, 0, buffer1.get(), kSize1, cb.callback(), false));
EXPECT_EQ(kSize1, cb.GetResult(net::ERR_IO_PENDING));
EXPECT_EQ(net::ERR_IO_PENDING,
entry->ReadData(1, 0, buffer1.get(), kSize1, cb.callback()));
EXPECT_EQ(kSize1, cb.GetResult(net::ERR_IO_PENDING));
// Check that we are not leaking.
EXPECT_TRUE(
static_cast<disk_cache::SimpleEntryImpl*>(entry)->HasOneRef());
}
TEST_F(DiskCacheEntryTest, SimpleCacheOptimistic6) {
// Test sequence:
// Create, Write, Doom, Doom, Read, Doom, Close.
SetSimpleCacheMode();
InitCache();
disk_cache::Entry* null = NULL;
const char key[] = "the first key";
net::TestCompletionCallback cb;
const int kSize1 = 10;
scoped_refptr<net::IOBuffer> buffer1 =
base::MakeRefCounted<net::IOBuffer>(kSize1);
scoped_refptr<net::IOBuffer> buffer1_read =
base::MakeRefCounted<net::IOBuffer>(kSize1);
CacheTestFillBuffer(buffer1->data(), kSize1, false);
disk_cache::Entry* entry = NULL;
ASSERT_EQ(net::OK, cache_->CreateEntry(key, net::HIGHEST, &entry,
net::CompletionOnceCallback()));
EXPECT_NE(null, entry);
ScopedEntryPtr entry_closer(entry);
EXPECT_EQ(
net::ERR_IO_PENDING,
entry->WriteData(1, 0, buffer1.get(), kSize1, cb.callback(), false));
EXPECT_EQ(kSize1, cb.GetResult(net::ERR_IO_PENDING));
entry->Doom();
entry->Doom();
// This Read must not be optimistic, since we don't support that yet.
EXPECT_EQ(net::ERR_IO_PENDING,
entry->ReadData(1, 0, buffer1_read.get(), kSize1, cb.callback()));
EXPECT_EQ(kSize1, cb.GetResult(net::ERR_IO_PENDING));
EXPECT_EQ(0, memcmp(buffer1->data(), buffer1_read->data(), kSize1));
entry->Doom();
}
// Confirm that IO buffers are not referenced by the Simple Cache after a write
// completes.
TEST_F(DiskCacheEntryTest, SimpleCacheOptimisticWriteReleases) {
SetSimpleCacheMode();
InitCache();
const char key[] = "the first key";
disk_cache::Entry* entry = NULL;
// First, an optimistic create.
ASSERT_EQ(net::OK, cache_->CreateEntry(key, net::HIGHEST, &entry,
net::CompletionOnceCallback()));
ASSERT_TRUE(entry);
ScopedEntryPtr entry_closer(entry);
const int kWriteSize = 512;
scoped_refptr<net::IOBuffer> buffer1 =
base::MakeRefCounted<net::IOBuffer>(kWriteSize);
EXPECT_TRUE(buffer1->HasOneRef());
CacheTestFillBuffer(buffer1->data(), kWriteSize, false);
// An optimistic write happens only when there is an empty queue of pending
// operations. To ensure the queue is empty, we issue a write and wait until
// it completes.
EXPECT_EQ(kWriteSize,
WriteData(entry, 1, 0, buffer1.get(), kWriteSize, false));
EXPECT_TRUE(buffer1->HasOneRef());
// Finally, we should perform an optimistic write and confirm that all
// references to the IO buffer have been released.
EXPECT_EQ(kWriteSize, entry->WriteData(1, 0, buffer1.get(), kWriteSize,
net::CompletionOnceCallback(), false));
EXPECT_TRUE(buffer1->HasOneRef());
}
TEST_F(DiskCacheEntryTest, SimpleCacheCreateDoomRace) {
// Test sequence:
// Create, Doom, Write, Close, Check files are not on disk anymore.
SetSimpleCacheMode();
InitCache();
disk_cache::Entry* null = NULL;
const char key[] = "the first key";
net::TestCompletionCallback cb;
const int kSize1 = 10;
scoped_refptr<net::IOBuffer> buffer1 =
base::MakeRefCounted<net::IOBuffer>(kSize1);
CacheTestFillBuffer(buffer1->data(), kSize1, false);
disk_cache::Entry* entry = NULL;
ASSERT_EQ(net::OK, cache_->CreateEntry(key, net::HIGHEST, &entry,
net::CompletionOnceCallback()));
EXPECT_NE(null, entry);
EXPECT_THAT(cache_->DoomEntry(key, net::HIGHEST, cb.callback()),
IsError(net::ERR_IO_PENDING));
EXPECT_THAT(cb.GetResult(net::ERR_IO_PENDING), IsOk());
EXPECT_EQ(
kSize1,
entry->WriteData(0, 0, buffer1.get(), kSize1, cb.callback(), false));
entry->Close();
// Finish running the pending tasks so that we fully complete the close
// operation and destroy the entry object.
base::RunLoop().RunUntilIdle();
for (int i = 0; i < disk_cache::kSimpleEntryNormalFileCount; ++i) {
base::FilePath entry_file_path = cache_path_.AppendASCII(
disk_cache::simple_util::GetFilenameFromKeyAndFileIndex(key, i));
base::File::Info info;
EXPECT_FALSE(base::GetFileInfo(entry_file_path, &info));
}
}
TEST_F(DiskCacheEntryTest, SimpleCacheDoomCreateRace) {
// This test runs as APP_CACHE to make operations more synchronous. Test
// sequence:
// Create, Doom, Create.
SetCacheType(net::APP_CACHE);
SetSimpleCacheMode();
InitCache();
disk_cache::Entry* null = NULL;
const char key[] = "the first key";
net::TestCompletionCallback create_callback;
disk_cache::Entry* entry1 = NULL;
ASSERT_EQ(net::OK,
create_callback.GetResult(cache_->CreateEntry(
key, net::HIGHEST, &entry1, create_callback.callback())));
ScopedEntryPtr entry1_closer(entry1);
EXPECT_NE(null, entry1);
net::TestCompletionCallback doom_callback;
EXPECT_EQ(net::ERR_IO_PENDING,
cache_->DoomEntry(key, net::HIGHEST, doom_callback.callback()));
disk_cache::Entry* entry2 = NULL;
ASSERT_EQ(net::OK,
create_callback.GetResult(cache_->CreateEntry(
key, net::HIGHEST, &entry2, create_callback.callback())));
ScopedEntryPtr entry2_closer(entry2);
EXPECT_THAT(doom_callback.GetResult(net::ERR_IO_PENDING), IsOk());
}
TEST_F(DiskCacheEntryTest, SimpleCacheDoomCreateOptimistic) {
// Test that we optimize the doom -> create sequence when optimistic ops
// are on.
SetSimpleCacheMode();
InitCache();
const char kKey[] = "the key";
// Create entry and initiate its Doom.
disk_cache::Entry* entry1 = nullptr;
ASSERT_THAT(CreateEntry(kKey, &entry1), IsOk());
ASSERT_TRUE(entry1 != nullptr);
net::TestCompletionCallback doom_callback;
cache_->DoomEntry(kKey, net::HIGHEST, doom_callback.callback());
disk_cache::Entry* entry2 = nullptr;
net::TestCompletionCallback create_callback;
// Open entry2, with same key. With optimistic ops, this should succeed
// immediately, hence us using cache_->CreateEntry directly rather than using
// the DiskCacheTestWithCache::CreateEntry wrapper which blocks when needed.
ASSERT_EQ(net::OK, cache_->CreateEntry(kKey, net::HIGHEST, &entry2,
create_callback.callback()));
// Do some I/O to make sure it's alive.
const int kSize = 2048;
scoped_refptr<net::IOBuffer> buf_1 =
base::MakeRefCounted<net::IOBuffer>(kSize);
scoped_refptr<net::IOBuffer> buf_2 =
base::MakeRefCounted<net::IOBuffer>(kSize);
CacheTestFillBuffer(buf_1->data(), kSize, false);
EXPECT_EQ(kSize, WriteData(entry2, /* stream_index = */ 1, /* offset = */ 0,
buf_1.get(), kSize, /* truncate = */ false));
EXPECT_EQ(kSize, ReadData(entry2, /* stream_index = */ 1, /* offset = */ 0,
buf_2.get(), kSize));
doom_callback.WaitForResult();
entry1->Close();
entry2->Close();
}
TEST_F(DiskCacheEntryTest, SimpleCacheDoomCreateOptimisticMassDoom) {
// Test that shows that a certain DCHECK in mass doom code had to be removed
// once optimistic doom -> create was added.
SetSimpleCacheMode();
InitCache();
const char kKey[] = "the key";
// Create entry and initiate its Doom.
disk_cache::Entry* entry1 = nullptr;
ASSERT_THAT(CreateEntry(kKey, &entry1), IsOk());
ASSERT_TRUE(entry1 != nullptr);
net::TestCompletionCallback doom_callback;
cache_->DoomEntry(kKey, net::HIGHEST, doom_callback.callback());
disk_cache::Entry* entry2 = nullptr;
net::TestCompletionCallback create_callback;
// Open entry2, with same key. With optimistic ops, this should succeed
// immediately, hence us using cache_->CreateEntry directly rather than using
// the DiskCacheTestWithCache::CreateEntry wrapper which blocks when needed.
ASSERT_EQ(net::OK, cache_->CreateEntry(kKey, net::HIGHEST, &entry2,
create_callback.callback()));
net::TestCompletionCallback doomall_callback;
// This is what had code that had a no-longer valid DCHECK.
cache_->DoomAllEntries(doomall_callback.callback());
doom_callback.WaitForResult();
doomall_callback.WaitForResult();
entry1->Close();
entry2->Close();
}
TEST_F(DiskCacheEntryTest, SimpleCacheDoomOpenOptimistic) {
// Test that we optimize the doom -> optimize sequence when optimistic ops
// are on.
SetSimpleCacheMode();
InitCache();
const char kKey[] = "the key";
// Create entry and initiate its Doom.
disk_cache::Entry* entry1 = nullptr;
ASSERT_THAT(CreateEntry(kKey, &entry1), IsOk());
ASSERT_TRUE(entry1 != nullptr);
entry1->Close();
net::TestCompletionCallback doom_callback;
cache_->DoomEntry(kKey, net::HIGHEST, doom_callback.callback());
// Try to open entry. This should detect a miss immediately, since it's
// the only thing after a doom.
disk_cache::Entry* entry2 = nullptr;
net::TestCompletionCallback open_callback;
EXPECT_EQ(net::ERR_FAILED, cache_->OpenEntry(kKey, net::HIGHEST, &entry2,
open_callback.callback()));
doom_callback.WaitForResult();
}
TEST_F(DiskCacheEntryTest, SimpleCacheDoomDoom) {
// Test sequence:
// Create, Doom, Create, Doom (1st entry), Open.
SetSimpleCacheMode();
InitCache();
disk_cache::Entry* null = NULL;
const char key[] = "the first key";
disk_cache::Entry* entry1 = NULL;
ASSERT_THAT(CreateEntry(key, &entry1), IsOk());
ScopedEntryPtr entry1_closer(entry1);
EXPECT_NE(null, entry1);
EXPECT_THAT(DoomEntry(key), IsOk());
disk_cache::Entry* entry2 = NULL;
ASSERT_THAT(CreateEntry(key, &entry2), IsOk());
ScopedEntryPtr entry2_closer(entry2);
EXPECT_NE(null, entry2);
// Redundantly dooming entry1 should not delete entry2.
disk_cache::SimpleEntryImpl* simple_entry1 =
static_cast<disk_cache::SimpleEntryImpl*>(entry1);
net::TestCompletionCallback cb;
EXPECT_EQ(net::OK,
cb.GetResult(simple_entry1->DoomEntry(cb.callback())));
disk_cache::Entry* entry3 = NULL;
ASSERT_THAT(OpenEntry(key, &entry3), IsOk());
ScopedEntryPtr entry3_closer(entry3);
EXPECT_NE(null, entry3);
}
TEST_F(DiskCacheEntryTest, SimpleCacheDoomCreateDoom) {
// Test sequence:
// Create, Doom, Create, Doom.
SetSimpleCacheMode();
InitCache();
disk_cache::Entry* null = NULL;
const char key[] = "the first key";
disk_cache::Entry* entry1 = NULL;
ASSERT_THAT(CreateEntry(key, &entry1), IsOk());
ScopedEntryPtr entry1_closer(entry1);
EXPECT_NE(null, entry1);
entry1->Doom();
disk_cache::Entry* entry2 = NULL;
ASSERT_THAT(CreateEntry(key, &entry2), IsOk());
ScopedEntryPtr entry2_closer(entry2);
EXPECT_NE(null, entry2);
entry2->Doom();
// This test passes if it doesn't crash.
}
TEST_F(DiskCacheEntryTest, SimpleCacheDoomCloseCreateCloseOpen) {
// Test sequence: Create, Doom, Close, Create, Close, Open.
SetSimpleCacheMode();
InitCache();
disk_cache::Entry* null = NULL;
const char key[] = "this is a key";
disk_cache::Entry* entry1 = NULL;
ASSERT_THAT(CreateEntry(key, &entry1), IsOk());
ScopedEntryPtr entry1_closer(entry1);
EXPECT_NE(null, entry1);
entry1->Doom();
entry1_closer.reset();
entry1 = NULL;
disk_cache::Entry* entry2 = NULL;
ASSERT_THAT(CreateEntry(key, &entry2), IsOk());
ScopedEntryPtr entry2_closer(entry2);
EXPECT_NE(null, entry2);
entry2_closer.reset();
entry2 = NULL;
disk_cache::Entry* entry3 = NULL;
ASSERT_THAT(OpenEntry(key, &entry3), IsOk());
ScopedEntryPtr entry3_closer(entry3);
EXPECT_NE(null, entry3);
}
// Checks that an optimistic Create would fail later on a racing Open.
TEST_F(DiskCacheEntryTest, SimpleCacheOptimisticCreateFailsOnOpen) {
SetSimpleCacheMode();
InitCache();
// Create a corrupt file in place of a future entry. Optimistic create should
// initially succeed, but realize later that creation failed.
const std::string key = "the key";
net::TestCompletionCallback cb;
disk_cache::Entry* entry = NULL;
disk_cache::Entry* entry2 = NULL;
EXPECT_TRUE(disk_cache::simple_util::CreateCorruptFileForTests(
key, cache_path_));
EXPECT_THAT(cache_->CreateEntry(key, net::HIGHEST, &entry, cb.callback()),
IsOk());
ASSERT_TRUE(entry);
ScopedEntryPtr entry_closer(entry);
ASSERT_NE(net::OK, OpenEntry(key, &entry2));
// Check that we are not leaking.
EXPECT_TRUE(
static_cast<disk_cache::SimpleEntryImpl*>(entry)->HasOneRef());
DisableIntegrityCheck();
}
// Tests that old entries are evicted while new entries remain in the index.
// This test relies on non-mandatory properties of the simple Cache Backend:
// LRU eviction, specific values of high-watermark and low-watermark etc.
// When changing the eviction algorithm, the test will have to be re-engineered.
TEST_F(DiskCacheEntryTest, SimpleCacheEvictOldEntries) {
const int kMaxSize = 200 * 1024;
const int kWriteSize = kMaxSize / 10;
const int kNumExtraEntries = 12;
SetSimpleCacheMode();
SetMaxSize(kMaxSize);
InitCache();
std::string key1("the first key");
disk_cache::Entry* entry;
ASSERT_THAT(CreateEntry(key1, &entry), IsOk());
scoped_refptr<net::IOBuffer> buffer =
base::MakeRefCounted<net::IOBuffer>(kWriteSize);
CacheTestFillBuffer(buffer->data(), kWriteSize, false);
EXPECT_EQ(kWriteSize,
WriteData(entry, 1, 0, buffer.get(), kWriteSize, false));
entry->Close();
AddDelay();
std::string key2("the key prefix");
for (int i = 0; i < kNumExtraEntries; i++) {
if (i == kNumExtraEntries - 2) {
// Create a distinct timestamp for the last two entries. These entries
// will be checked for outliving the eviction.
AddDelay();
}
ASSERT_THAT(CreateEntry(key2 + base::IntToString(i), &entry), IsOk());
ScopedEntryPtr entry_closer(entry);
EXPECT_EQ(kWriteSize,
WriteData(entry, 1, 0, buffer.get(), kWriteSize, false));
}
// TODO(pasko): Find a way to wait for the eviction task(s) to finish by using
// the internal knowledge about |SimpleBackendImpl|.
ASSERT_NE(net::OK, OpenEntry(key1, &entry))
<< "Should have evicted the old entry";
for (int i = 0; i < 2; i++) {
int entry_no = kNumExtraEntries - i - 1;
// Generally there is no guarantee that at this point the backround eviction
// is finished. We are testing the positive case, i.e. when the eviction
// never reaches this entry, should be non-flaky.
ASSERT_EQ(net::OK, OpenEntry(key2 + base::IntToString(entry_no), &entry))
<< "Should not have evicted fresh entry " << entry_no;
entry->Close();
}
}
// Tests that if a read and a following in-flight truncate are both in progress
// simultaniously that they both can occur successfully. See
// http://crbug.com/239223
TEST_F(DiskCacheEntryTest, SimpleCacheInFlightTruncate) {
SetSimpleCacheMode();
InitCache();
const char key[] = "the first key";
// We use a very large entry size here to make sure this doesn't hit
// the prefetch path for any concievable setting. Hitting prefetch would
// make us serve the read below from memory entirely on I/O thread, missing
// the point of the test which coverred two concurrent disk ops, with
// portions of work happening on the workpool.
const int kBufferSize = 50000;
scoped_refptr<net::IOBuffer> write_buffer =
base::MakeRefCounted<net::IOBuffer>(kBufferSize);
CacheTestFillBuffer(write_buffer->data(), kBufferSize, false);
disk_cache::Entry* entry = NULL;
ASSERT_THAT(CreateEntry(key, &entry), IsOk());
EXPECT_EQ(kBufferSize,
WriteData(entry, 1, 0, write_buffer.get(), kBufferSize, false));
entry->Close();
entry = NULL;
ASSERT_THAT(OpenEntry(key, &entry), IsOk());
ScopedEntryPtr entry_closer(entry);
MessageLoopHelper helper;
int expected = 0;
// Make a short read.
const int kReadBufferSize = 512;
scoped_refptr<net::IOBuffer> read_buffer =
base::MakeRefCounted<net::IOBuffer>(kReadBufferSize);
CallbackTest read_callback(&helper, false);
EXPECT_EQ(net::ERR_IO_PENDING,
entry->ReadData(1,
0,
read_buffer.get(),
kReadBufferSize,
base::Bind(&CallbackTest::Run,
base::Unretained(&read_callback))));
++expected;
// Truncate the entry to the length of that read.
scoped_refptr<net::IOBuffer> truncate_buffer =
base::MakeRefCounted<net::IOBuffer>(kReadBufferSize);
CacheTestFillBuffer(truncate_buffer->data(), kReadBufferSize, false);
CallbackTest truncate_callback(&helper, false);
EXPECT_EQ(net::ERR_IO_PENDING,
entry->WriteData(1,
0,
truncate_buffer.get(),
kReadBufferSize,
base::Bind(&CallbackTest::Run,
base::Unretained(&truncate_callback)),
true));
++expected;
// Wait for both the read and truncation to finish, and confirm that both
// succeeded.
EXPECT_TRUE(helper.WaitUntilCacheIoFinished(expected));
EXPECT_EQ(kReadBufferSize, read_callback.last_result());
EXPECT_EQ(kReadBufferSize, truncate_callback.last_result());
EXPECT_EQ(0,
memcmp(write_buffer->data(), read_buffer->data(), kReadBufferSize));
}
// Tests that if a write and a read dependant on it are both in flight
// simultaneiously that they both can complete successfully without erroneous
// early returns. See http://crbug.com/239223
TEST_F(DiskCacheEntryTest, SimpleCacheInFlightRead) {
SetSimpleCacheMode();
InitCache();
const char key[] = "the first key";
disk_cache::Entry* entry = NULL;
ASSERT_EQ(net::OK, cache_->CreateEntry(key, net::HIGHEST, &entry,
net::CompletionOnceCallback()));
ScopedEntryPtr entry_closer(entry);
const int kBufferSize = 1024;
scoped_refptr<net::IOBuffer> write_buffer =
base::MakeRefCounted<net::IOBuffer>(kBufferSize);
CacheTestFillBuffer(write_buffer->data(), kBufferSize, false);
MessageLoopHelper helper;
int expected = 0;
CallbackTest write_callback(&helper, false);
EXPECT_EQ(net::ERR_IO_PENDING,
entry->WriteData(1,
0,
write_buffer.get(),
kBufferSize,
base::Bind(&CallbackTest::Run,
base::Unretained(&write_callback)),
true));
++expected;
scoped_refptr<net::IOBuffer> read_buffer =
base::MakeRefCounted<net::IOBuffer>(kBufferSize);
CallbackTest read_callback(&helper, false);
EXPECT_EQ(net::ERR_IO_PENDING,
entry->ReadData(1,
0,
read_buffer.get(),
kBufferSize,
base::Bind(&CallbackTest::Run,
base::Unretained(&read_callback))));
++expected;
EXPECT_TRUE(helper.WaitUntilCacheIoFinished(expected));
EXPECT_EQ(kBufferSize, write_callback.last_result());
EXPECT_EQ(kBufferSize, read_callback.last_result());
EXPECT_EQ(0, memcmp(write_buffer->data(), read_buffer->data(), kBufferSize));
}
TEST_F(DiskCacheEntryTest, SimpleCacheOpenCreateRaceWithNoIndex) {
SetSimpleCacheMode();
DisableSimpleCacheWaitForIndex();
DisableIntegrityCheck();
InitCache();
// Assume the index is not initialized, which is likely, since we are blocking
// the IO thread from executing the index finalization step.
disk_cache::Entry* entry1;
net::TestCompletionCallback cb1;
disk_cache::Entry* entry2;
net::TestCompletionCallback cb2;
int rv1 = cache_->OpenEntry("key", net::HIGHEST, &entry1, cb1.callback());
int rv2 = cache_->CreateEntry("key", net::HIGHEST, &entry2, cb2.callback());
EXPECT_THAT(cb1.GetResult(rv1), IsError(net::ERR_FAILED));
ASSERT_THAT(cb2.GetResult(rv2), IsOk());
// Try to get an alias for entry2. Open should succeed, and return the same
// pointer.
disk_cache::Entry* entry3 = nullptr;
ASSERT_EQ(net::OK, OpenEntry("key", &entry3));
EXPECT_EQ(entry3, entry2);
entry2->Close();
entry3->Close();
}
// Checking one more scenario of overlapped reading of a bad entry.
// Differs from the |SimpleCacheMultipleReadersCheckCRC| only by the order of
// last two reads.
TEST_F(DiskCacheEntryTest, SimpleCacheMultipleReadersCheckCRC2) {
SetSimpleCacheMode();
InitCache();
const char key[] = "key";
int size = 50000;
ASSERT_TRUE(SimpleCacheMakeBadChecksumEntry(key, size));
scoped_refptr<net::IOBuffer> read_buffer1 =
base::MakeRefCounted<net::IOBuffer>(size);
scoped_refptr<net::IOBuffer> read_buffer2 =
base::MakeRefCounted<net::IOBuffer>(size);
// Advance the first reader a little.
disk_cache::Entry* entry = NULL;
ASSERT_THAT(OpenEntry(key, &entry), IsOk());
ScopedEntryPtr entry_closer(entry);
EXPECT_EQ(1, ReadData(entry, 1, 0, read_buffer1.get(), 1));
// Advance the 2nd reader by the same amount.
disk_cache::Entry* entry2 = NULL;
EXPECT_THAT(OpenEntry(key, &entry2), IsOk());
ScopedEntryPtr entry2_closer(entry2);
EXPECT_EQ(1, ReadData(entry2, 1, 0, read_buffer2.get(), 1));
// Continue reading 1st.
EXPECT_GT(0, ReadData(entry, 1, 1, read_buffer1.get(), size));
// This read should fail as well because we have previous read failures.
EXPECT_GT(0, ReadData(entry2, 1, 1, read_buffer2.get(), 1));
DisableIntegrityCheck();
}
// Test if we can sequentially read each subset of the data until all the data
// is read, then the CRC is calculated correctly and the reads are successful.
TEST_F(DiskCacheEntryTest, SimpleCacheReadCombineCRC) {
// Test sequence:
// Create, Write, Read (first half of data), Read (second half of data),
// Close.
SetSimpleCacheMode();
InitCache();
disk_cache::Entry* null = NULL;
const char key[] = "the first key";
const int kHalfSize = 200;
const int kSize = 2 * kHalfSize;
scoped_refptr<net::IOBuffer> buffer1 =
base::MakeRefCounted<net::IOBuffer>(kSize);
CacheTestFillBuffer(buffer1->data(), kSize, false);
disk_cache::Entry* entry = NULL;
ASSERT_THAT(CreateEntry(key, &entry), IsOk());
EXPECT_NE(null, entry);
EXPECT_EQ(kSize, WriteData(entry, 1, 0, buffer1.get(), kSize, false));
entry->Close();
disk_cache::Entry* entry2 = NULL;
ASSERT_THAT(OpenEntry(key, &entry2), IsOk());
EXPECT_EQ(entry, entry2);
// Read the first half of the data.
int offset = 0;
int buf_len = kHalfSize;
scoped_refptr<net::IOBuffer> buffer1_read1 =
base::MakeRefCounted<net::IOBuffer>(buf_len);
EXPECT_EQ(buf_len, ReadData(entry2, 1, offset, buffer1_read1.get(), buf_len));
EXPECT_EQ(0, memcmp(buffer1->data(), buffer1_read1->data(), buf_len));
// Read the second half of the data.
offset = buf_len;
buf_len = kHalfSize;
scoped_refptr<net::IOBuffer> buffer1_read2 =
base::MakeRefCounted<net::IOBuffer>(buf_len);
EXPECT_EQ(buf_len, ReadData(entry2, 1, offset, buffer1_read2.get(), buf_len));
char* buffer1_data = buffer1->data() + offset;
EXPECT_EQ(0, memcmp(buffer1_data, buffer1_read2->data(), buf_len));
// Check that we are not leaking.
EXPECT_NE(entry, null);
EXPECT_TRUE(
static_cast<disk_cache::SimpleEntryImpl*>(entry)->HasOneRef());
entry->Close();
entry = NULL;
}
// Test if we can write the data not in sequence and read correctly. In
// this case the CRC will not be present.
TEST_F(DiskCacheEntryTest, SimpleCacheNonSequentialWrite) {
// Test sequence:
// Create, Write (second half of data), Write (first half of data), Read,
// Close.
SetSimpleCacheMode();
InitCache();
disk_cache::Entry* null = NULL;
const char key[] = "the first key";
const int kHalfSize = 200;
const int kSize = 2 * kHalfSize;
scoped_refptr<net::IOBuffer> buffer1 =
base::MakeRefCounted<net::IOBuffer>(kSize);
scoped_refptr<net::IOBuffer> buffer2 =
base::MakeRefCounted<net::IOBuffer>(kSize);
CacheTestFillBuffer(buffer1->data(), kSize, false);
char* buffer1_data = buffer1->data() + kHalfSize;
memcpy(buffer2->data(), buffer1_data, kHalfSize);
disk_cache::Entry* entry = NULL;
ASSERT_THAT(CreateEntry(key, &entry), IsOk());
entry->Close();
for (int i = 0; i < disk_cache::kSimpleEntryStreamCount; ++i) {
ASSERT_THAT(OpenEntry(key, &entry), IsOk());
EXPECT_NE(null, entry);
int offset = kHalfSize;
int buf_len = kHalfSize;
EXPECT_EQ(buf_len,
WriteData(entry, i, offset, buffer2.get(), buf_len, false));
offset = 0;
buf_len = kHalfSize;
EXPECT_EQ(buf_len,
WriteData(entry, i, offset, buffer1.get(), buf_len, false));
entry->Close();
ASSERT_THAT(OpenEntry(key, &entry), IsOk());
scoped_refptr<net::IOBuffer> buffer1_read1 =
base::MakeRefCounted<net::IOBuffer>(kSize);
EXPECT_EQ(kSize, ReadData(entry, i, 0, buffer1_read1.get(), kSize));
EXPECT_EQ(0, memcmp(buffer1->data(), buffer1_read1->data(), kSize));
// Check that we are not leaking.
ASSERT_NE(entry, null);
EXPECT_TRUE(static_cast<disk_cache::SimpleEntryImpl*>(entry)->HasOneRef());
entry->Close();
}
}
// Test that changing stream1 size does not affect stream0 (stream0 and stream1
// are stored in the same file in Simple Cache).
TEST_F(DiskCacheEntryTest, SimpleCacheStream1SizeChanges) {
SetSimpleCacheMode();
InitCache();
disk_cache::Entry* entry = NULL;
const std::string key("the key");
const int kSize = 100;
scoped_refptr<net::IOBuffer> buffer =
base::MakeRefCounted<net::IOBuffer>(kSize);
scoped_refptr<net::IOBuffer> buffer_read =
base::MakeRefCounted<net::IOBuffer>(kSize);
CacheTestFillBuffer(buffer->data(), kSize, false);
ASSERT_THAT(CreateEntry(key, &entry), IsOk());
EXPECT_TRUE(entry);
// Write something into stream0.
EXPECT_EQ(kSize, WriteData(entry, 0, 0, buffer.get(), kSize, false));
EXPECT_EQ(kSize, ReadData(entry, 0, 0, buffer_read.get(), kSize));
EXPECT_EQ(0, memcmp(buffer->data(), buffer_read->data(), kSize));
entry->Close();
// Extend stream1.
ASSERT_THAT(OpenEntry(key, &entry), IsOk());
int stream1_size = 100;
EXPECT_EQ(0, WriteData(entry, 1, stream1_size, buffer.get(), 0, false));
EXPECT_EQ(stream1_size, entry->GetDataSize(1));
entry->Close();
// Check that stream0 data has not been modified and that the EOF record for
// stream 0 contains a crc.
// The entry needs to be reopened before checking the crc: Open will perform
// the synchronization with the previous Close. This ensures the EOF records
// have been written to disk before we attempt to read them independently.
ASSERT_THAT(OpenEntry(key, &entry), IsOk());
base::FilePath entry_file0_path = cache_path_.AppendASCII(
disk_cache::simple_util::GetFilenameFromKeyAndFileIndex(key, 0));
base::File entry_file0(entry_file0_path,
base::File::FLAG_READ | base::File::FLAG_OPEN);
ASSERT_TRUE(entry_file0.IsValid());
int data_size[disk_cache::kSimpleEntryStreamCount] = {kSize, stream1_size, 0};
int sparse_data_size = 0;
disk_cache::SimpleEntryStat entry_stat(
base::Time::Now(), base::Time::Now(), data_size, sparse_data_size);
int eof_offset = entry_stat.GetEOFOffsetInFile(key.size(), 0);
disk_cache::SimpleFileEOF eof_record;
ASSERT_EQ(static_cast<int>(sizeof(eof_record)),
entry_file0.Read(eof_offset, reinterpret_cast<char*>(&eof_record),
sizeof(eof_record)));
EXPECT_EQ(disk_cache::kSimpleFinalMagicNumber, eof_record.final_magic_number);
EXPECT_TRUE((eof_record.flags & disk_cache::SimpleFileEOF::FLAG_HAS_CRC32) ==
disk_cache::SimpleFileEOF::FLAG_HAS_CRC32);
buffer_read = base::MakeRefCounted<net::IOBuffer>(kSize);
EXPECT_EQ(kSize, ReadData(entry, 0, 0, buffer_read.get(), kSize));
EXPECT_EQ(0, memcmp(buffer->data(), buffer_read->data(), kSize));
// Shrink stream1.
stream1_size = 50;
EXPECT_EQ(0, WriteData(entry, 1, stream1_size, buffer.get(), 0, true));
EXPECT_EQ(stream1_size, entry->GetDataSize(1));
entry->Close();
// Check that stream0 data has not been modified.
buffer_read = base::MakeRefCounted<net::IOBuffer>(kSize);
ASSERT_THAT(OpenEntry(key, &entry), IsOk());
EXPECT_EQ(kSize, ReadData(entry, 0, 0, buffer_read.get(), kSize));
EXPECT_EQ(0, memcmp(buffer->data(), buffer_read->data(), kSize));
entry->Close();
entry = NULL;
}
// Test that writing within the range for which the crc has already been
// computed will properly invalidate the computed crc.
TEST_F(DiskCacheEntryTest, SimpleCacheCRCRewrite) {
// Test sequence:
// Create, Write (big data), Write (small data in the middle), Close.
// Open, Read (all), Close.
SetSimpleCacheMode();
InitCache();
disk_cache::Entry* null = NULL;
const char key[] = "the first key";
const int kHalfSize = 200;
const int kSize = 2 * kHalfSize;
scoped_refptr<net::IOBuffer> buffer1 =
base::MakeRefCounted<net::IOBuffer>(kSize);
scoped_refptr<net::IOBuffer> buffer2 =
base::MakeRefCounted<net::IOBuffer>(kHalfSize);
CacheTestFillBuffer(buffer1->data(), kSize, false);
CacheTestFillBuffer(buffer2->data(), kHalfSize, false);
disk_cache::Entry* entry = NULL;
ASSERT_THAT(CreateEntry(key, &entry), IsOk());
EXPECT_NE(null, entry);
entry->Close();
for (int i = 0; i < disk_cache::kSimpleEntryStreamCount; ++i) {
ASSERT_THAT(OpenEntry(key, &entry), IsOk());
int offset = 0;
int buf_len = kSize;
EXPECT_EQ(buf_len,
WriteData(entry, i, offset, buffer1.get(), buf_len, false));
offset = kHalfSize;
buf_len = kHalfSize;
EXPECT_EQ(buf_len,
WriteData(entry, i, offset, buffer2.get(), buf_len, false));
entry->Close();
ASSERT_THAT(OpenEntry(key, &entry), IsOk());
scoped_refptr<net::IOBuffer> buffer1_read1 =
base::MakeRefCounted<net::IOBuffer>(kSize);
EXPECT_EQ(kSize, ReadData(entry, i, 0, buffer1_read1.get(), kSize));
EXPECT_EQ(0, memcmp(buffer1->data(), buffer1_read1->data(), kHalfSize));
EXPECT_EQ(
0,
memcmp(buffer2->data(), buffer1_read1->data() + kHalfSize, kHalfSize));
entry->Close();
}
}
bool DiskCacheEntryTest::SimpleCacheThirdStreamFileExists(const char* key) {
int third_stream_file_index =
disk_cache::simple_util::GetFileIndexFromStreamIndex(2);
base::FilePath third_stream_file_path = cache_path_.AppendASCII(
disk_cache::simple_util::GetFilenameFromKeyAndFileIndex(
key, third_stream_file_index));
return PathExists(third_stream_file_path);
}
void DiskCacheEntryTest::SyncDoomEntry(const char* key) {
net::TestCompletionCallback callback;
cache_->DoomEntry(key, net::HIGHEST, callback.callback());
callback.WaitForResult();
}
void DiskCacheEntryTest::UseAfterBackendDestruction() {
disk_cache::Entry* entry = NULL;
ASSERT_THAT(CreateEntry("the first key", &entry), IsOk());
cache_.reset();
const int kSize = 100;
scoped_refptr<net::IOBuffer> buffer =
base::MakeRefCounted<net::IOBuffer>(kSize);
CacheTestFillBuffer(buffer->data(), kSize, false);
// Do some writes and reads, but don't change the result. We're OK
// with them failing, just not them crashing.
WriteData(entry, 1, 0, buffer.get(), kSize, false);
ReadData(entry, 1, 0, buffer.get(), kSize);
WriteSparseData(entry, 20000, buffer.get(), kSize);
entry->Close();
}
// Check that a newly-created entry with no third-stream writes omits the
// third stream file.
TEST_F(DiskCacheEntryTest, SimpleCacheOmittedThirdStream1) {
SetSimpleCacheMode();
InitCache();
const char key[] = "key";
disk_cache::Entry* entry;
// Create entry and close without writing: third stream file should be
// omitted, since the stream is empty.
ASSERT_THAT(CreateEntry(key, &entry), IsOk());
entry->Close();
EXPECT_FALSE(SimpleCacheThirdStreamFileExists(key));
SyncDoomEntry(key);
EXPECT_FALSE(SimpleCacheThirdStreamFileExists(key));
}
// Check that a newly-created entry with only a single zero-offset, zero-length
// write omits the third stream file.
TEST_F(DiskCacheEntryTest, SimpleCacheOmittedThirdStream2) {
SetSimpleCacheMode();
InitCache();
const int kHalfSize = 8;
const int kSize = kHalfSize * 2;
const char key[] = "key";
scoped_refptr<net::IOBuffer> buffer =
base::MakeRefCounted<net::IOBuffer>(kSize);
CacheTestFillBuffer(buffer->data(), kHalfSize, false);
disk_cache::Entry* entry;
// Create entry, write empty buffer to third stream, and close: third stream
// should still be omitted, since the entry ignores writes that don't modify
// data or change the length.
ASSERT_THAT(CreateEntry(key, &entry), IsOk());
EXPECT_EQ(0, WriteData(entry, 2, 0, buffer.get(), 0, true));
entry->Close();
EXPECT_FALSE(SimpleCacheThirdStreamFileExists(key));
SyncDoomEntry(key);
EXPECT_FALSE(SimpleCacheThirdStreamFileExists(key));
}
// Check that we can read back data written to the third stream.
TEST_F(DiskCacheEntryTest, SimpleCacheOmittedThirdStream3) {
SetSimpleCacheMode();
InitCache();
const int kHalfSize = 8;
const int kSize = kHalfSize * 2;
const char key[] = "key";
scoped_refptr<net::IOBuffer> buffer1 =
base::MakeRefCounted<net::IOBuffer>(kSize);
scoped_refptr<net::IOBuffer> buffer2 =
base::MakeRefCounted<net::IOBuffer>(kSize);
CacheTestFillBuffer(buffer1->data(), kHalfSize, false);
disk_cache::Entry* entry;
// Create entry, write data to third stream, and close: third stream should
// not be omitted, since it contains data. Re-open entry and ensure there
// are that many bytes in the third stream.
ASSERT_THAT(CreateEntry(key, &entry), IsOk());
EXPECT_EQ(kHalfSize, WriteData(entry, 2, 0, buffer1.get(), kHalfSize, true));
entry->Close();
EXPECT_TRUE(SimpleCacheThirdStreamFileExists(key));
ASSERT_THAT(OpenEntry(key, &entry), IsOk());
EXPECT_EQ(kHalfSize, ReadData(entry, 2, 0, buffer2.get(), kSize));
EXPECT_EQ(0, memcmp(buffer1->data(), buffer2->data(), kHalfSize));
entry->Close();
EXPECT_TRUE(SimpleCacheThirdStreamFileExists(key));
SyncDoomEntry(key);
EXPECT_FALSE(SimpleCacheThirdStreamFileExists(key));
}
// Check that we remove the third stream file upon opening an entry and finding
// the third stream empty. (This is the upgrade path for entries written
// before the third stream was optional.)
TEST_F(DiskCacheEntryTest, SimpleCacheOmittedThirdStream4) {
SetSimpleCacheMode();
InitCache();
const int kHalfSize = 8;
const int kSize = kHalfSize * 2;
const char key[] = "key";
scoped_refptr<net::IOBuffer> buffer1 =
base::MakeRefCounted<net::IOBuffer>(kSize);
scoped_refptr<net::IOBuffer> buffer2 =
base::MakeRefCounted<net::IOBuffer>(kSize);
CacheTestFillBuffer(buffer1->data(), kHalfSize, false);
disk_cache::Entry* entry;
// Create entry, write data to third stream, truncate third stream back to
// empty, and close: third stream will not initially be omitted, since entry
// creates the file when the first significant write comes in, and only
// removes it on open if it is empty. Reopen, ensure that the file is
// deleted, and that there's no data in the third stream.
ASSERT_THAT(CreateEntry(key, &entry), IsOk());
EXPECT_EQ(kHalfSize, WriteData(entry, 2, 0, buffer1.get(), kHalfSize, true));
EXPECT_EQ(0, WriteData(entry, 2, 0, buffer1.get(), 0, true));
entry->Close();
EXPECT_TRUE(SimpleCacheThirdStreamFileExists(key));
ASSERT_THAT(OpenEntry(key, &entry), IsOk());
EXPECT_FALSE(SimpleCacheThirdStreamFileExists(key));
EXPECT_EQ(0, ReadData(entry, 2, 0, buffer2.get(), kSize));
entry->Close();
EXPECT_FALSE(SimpleCacheThirdStreamFileExists(key));
SyncDoomEntry(key);
EXPECT_FALSE(SimpleCacheThirdStreamFileExists(key));
}
// Check that we don't accidentally create the third stream file once the entry
// has been doomed.
TEST_F(DiskCacheEntryTest, SimpleCacheOmittedThirdStream5) {
SetSimpleCacheMode();
InitCache();
const int kHalfSize = 8;
const int kSize = kHalfSize * 2;
const char key[] = "key";
scoped_refptr<net::IOBuffer> buffer =
base::MakeRefCounted<net::IOBuffer>(kSize);
CacheTestFillBuffer(buffer->data(), kHalfSize, false);
disk_cache::Entry* entry;
// Create entry, doom entry, write data to third stream, and close: third
// stream should not exist. (Note: We don't care if the write fails, just
// that it doesn't cause the file to be created on disk.)
ASSERT_THAT(CreateEntry(key, &entry), IsOk());
entry->Doom();
WriteData(entry, 2, 0, buffer.get(), kHalfSize, true);
entry->Close();
EXPECT_FALSE(SimpleCacheThirdStreamFileExists(key));
}
// There could be a race between Doom and an optimistic write.
TEST_F(DiskCacheEntryTest, SimpleCacheDoomOptimisticWritesRace) {
// Test sequence:
// Create, first Write, second Write, Close.
// Open, Close.
SetSimpleCacheMode();
InitCache();
disk_cache::Entry* null = NULL;
const char key[] = "the first key";
const int kSize = 200;
scoped_refptr<net::IOBuffer> buffer1 =
base::MakeRefCounted<net::IOBuffer>(kSize);
scoped_refptr<net::IOBuffer> buffer2 =
base::MakeRefCounted<net::IOBuffer>(kSize);
CacheTestFillBuffer(buffer1->data(), kSize, false);
CacheTestFillBuffer(buffer2->data(), kSize, false);
// The race only happens on stream 1 and stream 2.
for (int i = 0; i < disk_cache::kSimpleEntryStreamCount; ++i) {
ASSERT_THAT(DoomAllEntries(), IsOk());
disk_cache::Entry* entry = NULL;
ASSERT_THAT(CreateEntry(key, &entry), IsOk());
EXPECT_NE(null, entry);
entry->Close();
entry = NULL;
ASSERT_THAT(DoomAllEntries(), IsOk());
ASSERT_THAT(CreateEntry(key, &entry), IsOk());
EXPECT_NE(null, entry);
int offset = 0;
int buf_len = kSize;
// This write should not be optimistic (since create is).
EXPECT_EQ(buf_len,
WriteData(entry, i, offset, buffer1.get(), buf_len, false));
offset = kSize;
// This write should be optimistic.
EXPECT_EQ(buf_len,
WriteData(entry, i, offset, buffer2.get(), buf_len, false));
entry->Close();
ASSERT_THAT(OpenEntry(key, &entry), IsOk());
EXPECT_NE(null, entry);
entry->Close();
entry = NULL;
}
}
// Tests for a regression in crbug.com/317138 , in which deleting an already
// doomed entry was removing the active entry from the index.
TEST_F(DiskCacheEntryTest, SimpleCachePreserveActiveEntries) {
SetSimpleCacheMode();
InitCache();
disk_cache::Entry* null = NULL;
const char key[] = "this is a key";
disk_cache::Entry* entry1 = NULL;
ASSERT_THAT(CreateEntry(key, &entry1), IsOk());
ScopedEntryPtr entry1_closer(entry1);
EXPECT_NE(null, entry1);
entry1->Doom();
disk_cache::Entry* entry2 = NULL;
ASSERT_THAT(CreateEntry(key, &entry2), IsOk());
ScopedEntryPtr entry2_closer(entry2);
EXPECT_NE(null, entry2);
entry2_closer.reset();
// Closing then reopening entry2 insures that entry2 is serialized, and so
// it can be opened from files without error.
entry2 = NULL;
ASSERT_THAT(OpenEntry(key, &entry2), IsOk());
EXPECT_NE(null, entry2);
entry2_closer.reset(entry2);
scoped_refptr<disk_cache::SimpleEntryImpl>
entry1_refptr = static_cast<disk_cache::SimpleEntryImpl*>(entry1);
// If crbug.com/317138 has regressed, this will remove |entry2| from
// the backend's |active_entries_| while |entry2| is still alive and its
// files are still on disk.
entry1_closer.reset();
entry1 = NULL;
// Close does not have a callback. However, we need to be sure the close is
// finished before we continue the test. We can take advantage of how the ref
// counting of a SimpleEntryImpl works to fake out a callback: When the
// last Close() call is made to an entry, an IO operation is sent to the
// synchronous entry to close the platform files. This IO operation holds a
// ref pointer to the entry, which expires when the operation is done. So,
// we take a refpointer, and watch the SimpleEntry object until it has only
// one ref; this indicates the IO operation is complete.
while (!entry1_refptr->HasOneRef()) {
base::PlatformThread::YieldCurrentThread();
base::RunLoop().RunUntilIdle();
}
entry1_refptr = NULL;
// In the bug case, this new entry ends up being a duplicate object pointing
// at the same underlying files.
disk_cache::Entry* entry3 = NULL;
EXPECT_THAT(OpenEntry(key, &entry3), IsOk());
ScopedEntryPtr entry3_closer(entry3);
EXPECT_NE(null, entry3);
// The test passes if these two dooms do not crash.
entry2->Doom();
entry3->Doom();
}
TEST_F(DiskCacheEntryTest, SimpleCacheBasicSparseIO) {
SetSimpleCacheMode();
InitCache();
BasicSparseIO();
}
TEST_F(DiskCacheEntryTest, SimpleCacheHugeSparseIO) {
SetSimpleCacheMode();
InitCache();
HugeSparseIO();
}
TEST_F(DiskCacheEntryTest, SimpleCacheGetAvailableRange) {
SetSimpleCacheMode();
InitCache();
GetAvailableRange();
}
TEST_F(DiskCacheEntryTest, SimpleCacheUpdateSparseEntry) {
SetSimpleCacheMode();
InitCache();
UpdateSparseEntry();
}
TEST_F(DiskCacheEntryTest, SimpleCacheDoomSparseEntry) {
SetSimpleCacheMode();
InitCache();
DoomSparseEntry();
}
TEST_F(DiskCacheEntryTest, SimpleCachePartialSparseEntry) {
SetSimpleCacheMode();
InitCache();
PartialSparseEntry();
}
TEST_F(DiskCacheEntryTest, SimpleCacheTruncateLargeSparseFile) {
const int kSize = 1024;
SetSimpleCacheMode();
// An entry is allowed sparse data 1/10 the size of the cache, so this size
// allows for one |kSize|-sized range plus overhead, but not two ranges.
SetMaxSize(kSize * 15);
InitCache();
const char key[] = "key";
disk_cache::Entry* null = NULL;
disk_cache::Entry* entry;
ASSERT_THAT(CreateEntry(key, &entry), IsOk());
EXPECT_NE(null, entry);
scoped_refptr<net::IOBuffer> buffer =
base::MakeRefCounted<net::IOBuffer>(kSize);
CacheTestFillBuffer(buffer->data(), kSize, false);
net::TestCompletionCallback callback;
int ret;
// Verify initial conditions.
ret = entry->ReadSparseData(0, buffer.get(), kSize, callback.callback());
EXPECT_EQ(0, callback.GetResult(ret));
ret = entry->ReadSparseData(kSize, buffer.get(), kSize, callback.callback());
EXPECT_EQ(0, callback.GetResult(ret));
// Write a range and make sure it reads back.
ret = entry->WriteSparseData(0, buffer.get(), kSize, callback.callback());
EXPECT_EQ(kSize, callback.GetResult(ret));
ret = entry->ReadSparseData(0, buffer.get(), kSize, callback.callback());
EXPECT_EQ(kSize, callback.GetResult(ret));
// Write another range and make sure it reads back.
ret = entry->WriteSparseData(kSize, buffer.get(), kSize, callback.callback());
EXPECT_EQ(kSize, callback.GetResult(ret));
ret = entry->ReadSparseData(kSize, buffer.get(), kSize, callback.callback());
EXPECT_EQ(kSize, callback.GetResult(ret));
// Make sure the first range was removed when the second was written.
ret = entry->ReadSparseData(0, buffer.get(), kSize, callback.callback());
EXPECT_EQ(0, callback.GetResult(ret));
// Close and reopen the entry and make sure the first entry is still absent
// and the second entry is still present.
entry->Close();
ASSERT_THAT(OpenEntry(key, &entry), IsOk());
ret = entry->ReadSparseData(0, buffer.get(), kSize, callback.callback());
EXPECT_EQ(0, callback.GetResult(ret));
ret = entry->ReadSparseData(kSize, buffer.get(), kSize, callback.callback());
EXPECT_EQ(kSize, callback.GetResult(ret));
entry->Close();
}
TEST_F(DiskCacheEntryTest, SimpleCacheReadWithoutKeySHA256) {
// This test runs as APP_CACHE to make operations more synchronous.
SetCacheType(net::APP_CACHE);
SetSimpleCacheMode();
InitCache();
disk_cache::Entry* entry;
std::string key("a key");
ASSERT_THAT(CreateEntry(key, &entry), IsOk());
const std::string stream_0_data = "data for stream zero";
scoped_refptr<net::IOBuffer> stream_0_iobuffer =
base::MakeRefCounted<net::StringIOBuffer>(stream_0_data);
EXPECT_EQ(static_cast<int>(stream_0_data.size()),
WriteData(entry, 0, 0, stream_0_iobuffer.get(),
stream_0_data.size(), false));
const std::string stream_1_data = "FOR STREAM ONE, QUITE DIFFERENT THINGS";
scoped_refptr<net::IOBuffer> stream_1_iobuffer =
base::MakeRefCounted<net::StringIOBuffer>(stream_1_data);
EXPECT_EQ(static_cast<int>(stream_1_data.size()),
WriteData(entry, 1, 0, stream_1_iobuffer.get(),
stream_1_data.size(), false));
entry->Close();
base::RunLoop().RunUntilIdle();
disk_cache::SimpleBackendImpl::FlushWorkerPoolForTesting();
base::RunLoop().RunUntilIdle();
EXPECT_TRUE(
disk_cache::simple_util::RemoveKeySHA256FromEntry(key, cache_path_));
ASSERT_THAT(OpenEntry(key, &entry), IsOk());
ScopedEntryPtr entry_closer(entry);
EXPECT_EQ(static_cast<int>(stream_0_data.size()), entry->GetDataSize(0));
scoped_refptr<net::IOBuffer> check_stream_0_data =
base::MakeRefCounted<net::IOBuffer>(stream_0_data.size());
EXPECT_EQ(
static_cast<int>(stream_0_data.size()),
ReadData(entry, 0, 0, check_stream_0_data.get(), stream_0_data.size()));
EXPECT_EQ(0, stream_0_data.compare(0, std::string::npos,
check_stream_0_data->data(),
stream_0_data.size()));
EXPECT_EQ(static_cast<int>(stream_1_data.size()), entry->GetDataSize(1));
scoped_refptr<net::IOBuffer> check_stream_1_data =
base::MakeRefCounted<net::IOBuffer>(stream_1_data.size());
EXPECT_EQ(
static_cast<int>(stream_1_data.size()),
ReadData(entry, 1, 0, check_stream_1_data.get(), stream_1_data.size()));
EXPECT_EQ(0, stream_1_data.compare(0, std::string::npos,
check_stream_1_data->data(),
stream_1_data.size()));
}
TEST_F(DiskCacheEntryTest, SimpleCacheDoubleOpenWithoutKeySHA256) {
// This test runs as APP_CACHE to make operations more synchronous.
SetCacheType(net::APP_CACHE);
SetSimpleCacheMode();
InitCache();
disk_cache::Entry* entry;
std::string key("a key");
ASSERT_THAT(CreateEntry(key, &entry), IsOk());
entry->Close();
base::RunLoop().RunUntilIdle();
disk_cache::SimpleBackendImpl::FlushWorkerPoolForTesting();
base::RunLoop().RunUntilIdle();
EXPECT_TRUE(
disk_cache::simple_util::RemoveKeySHA256FromEntry(key, cache_path_));
ASSERT_THAT(OpenEntry(key, &entry), IsOk());
entry->Close();
base::RunLoop().RunUntilIdle();
disk_cache::SimpleBackendImpl::FlushWorkerPoolForTesting();
base::RunLoop().RunUntilIdle();
ASSERT_THAT(OpenEntry(key, &entry), IsOk());
entry->Close();
}
TEST_F(DiskCacheEntryTest, SimpleCacheReadCorruptKeySHA256) {
// This test runs as APP_CACHE to make operations more synchronous.
SetCacheType(net::APP_CACHE);
SetSimpleCacheMode();
InitCache();
disk_cache::Entry* entry;
std::string key("a key");
ASSERT_THAT(CreateEntry(key, &entry), IsOk());
entry->Close();
base::RunLoop().RunUntilIdle();
disk_cache::SimpleBackendImpl::FlushWorkerPoolForTesting();
base::RunLoop().RunUntilIdle();
EXPECT_TRUE(
disk_cache::simple_util::CorruptKeySHA256FromEntry(key, cache_path_));
EXPECT_NE(net::OK, OpenEntry(key, &entry));
}
TEST_F(DiskCacheEntryTest, SimpleCacheReadCorruptLength) {
SetCacheType(net::APP_CACHE);
SetSimpleCacheMode();
InitCache();
disk_cache::Entry* entry;
std::string key("a key");
ASSERT_EQ(net::OK, CreateEntry(key, &entry));
entry->Close();
base::RunLoop().RunUntilIdle();
disk_cache::SimpleBackendImpl::FlushWorkerPoolForTesting();
base::RunLoop().RunUntilIdle();
EXPECT_TRUE(
disk_cache::simple_util::CorruptStream0LengthFromEntry(key, cache_path_));
EXPECT_NE(net::OK, OpenEntry(key, &entry));
}
TEST_F(DiskCacheEntryTest, SimpleCacheCreateRecoverFromRmdir) {
// This test runs as APP_CACHE to make operations more synchronous.
// (in particular we want to see if create succeeded or not, so we don't
// want an optimistic one).
SetCacheType(net::APP_CACHE);
SetSimpleCacheMode();
InitCache();
// Pretend someone deleted the cache dir. This shouldn't be too scary in
// the test since cache_path_ is set as:
// CHECK(temp_dir_.CreateUniqueTempDir());
// cache_path_ = temp_dir_.GetPath();
disk_cache::DeleteCache(cache_path_,
true /* delete the dir, what we really want*/);
disk_cache::Entry* entry;
std::string key("a key");
ASSERT_THAT(CreateEntry(key, &entry), IsOk());
entry->Close();
}
TEST_F(DiskCacheEntryTest, SimpleCacheSparseErrorHandling) {
// If there is corruption in sparse file, we should delete all the files
// before returning the failure. Further additional sparse operations in
// failure state should fail gracefully.
SetSimpleCacheMode();
InitCache();
std::string key("a key");
disk_cache::SimpleFileTracker::EntryFileKey num_key(
disk_cache::simple_util::GetEntryHashKey(key));
base::FilePath path_0 = cache_path_.AppendASCII(
disk_cache::simple_util::GetFilenameFromEntryFileKeyAndFileIndex(num_key,
0));
base::FilePath path_s = cache_path_.AppendASCII(
disk_cache::simple_util::GetSparseFilenameFromEntryFileKey(num_key));
disk_cache::Entry* entry = nullptr;
ASSERT_THAT(CreateEntry(key, &entry), IsOk());
const int kSize = 1024;
scoped_refptr<net::IOBuffer> buffer =
base::MakeRefCounted<net::IOBuffer>(kSize);
CacheTestFillBuffer(buffer->data(), kSize, false);
EXPECT_EQ(kSize, WriteSparseData(entry, 0, buffer.get(), kSize));
entry->Close();
disk_cache::SimpleBackendImpl::FlushWorkerPoolForTesting();
EXPECT_TRUE(base::PathExists(path_0));
EXPECT_TRUE(base::PathExists(path_s));
// Now corrupt the _s file in a way that makes it look OK on open, but not on
// read.
base::File file_s(path_s, base::File::FLAG_OPEN | base::File::FLAG_READ |
base::File::FLAG_WRITE);
ASSERT_TRUE(file_s.IsValid());
file_s.SetLength(sizeof(disk_cache::SimpleFileHeader) +
sizeof(disk_cache::SimpleFileSparseRangeHeader) +
key.size());
file_s.Close();
// Re-open, it should still be fine.
ASSERT_THAT(OpenEntry(key, &entry), IsOk());
// Read should fail though.
EXPECT_EQ(net::ERR_CACHE_READ_FAILURE,
ReadSparseData(entry, 0, buffer.get(), kSize));
// At the point read returns to us, the files should already been gone.
EXPECT_FALSE(base::PathExists(path_0));
EXPECT_FALSE(base::PathExists(path_s));
// Re-trying should still fail. Not DCHECK-fail.
EXPECT_EQ(net::ERR_FAILED, ReadSparseData(entry, 0, buffer.get(), kSize));
// Similarly for other ops.
EXPECT_EQ(net::ERR_FAILED, WriteSparseData(entry, 0, buffer.get(), kSize));
net::TestCompletionCallback cb;
int64_t start;
int rv = entry->GetAvailableRange(0, 1024, &start, cb.callback());
EXPECT_EQ(net::ERR_FAILED, cb.GetResult(rv));
entry->Close();
disk_cache::FlushCacheThreadForTesting();
// Closing shouldn't resurrect files, either.
EXPECT_FALSE(base::PathExists(path_0));
EXPECT_FALSE(base::PathExists(path_s));
}
TEST_F(DiskCacheEntryTest, SimpleCacheCreateCollision) {
// These two keys collide; this test is that we properly handled creation
// of both.
const char kCollKey1[] =
"\xfb\x4e\x9c\x1d\x66\x71\xf7\x54\xa3\x11\xa0\x7e\x16\xa5\x68\xf6";
const char kCollKey2[] =
"\xbc\x60\x64\x92\xbc\xa0\x5c\x15\x17\x93\x29\x2d\xe4\x21\xbd\x03";
const int kSize = 256;
scoped_refptr<net::IOBuffer> buffer1 =
base::MakeRefCounted<net::IOBuffer>(kSize);
scoped_refptr<net::IOBuffer> buffer2 =
base::MakeRefCounted<net::IOBuffer>(kSize);
scoped_refptr<net::IOBuffer> read_buffer =
base::MakeRefCounted<net::IOBuffer>(kSize);
CacheTestFillBuffer(buffer1->data(), kSize, false);
CacheTestFillBuffer(buffer2->data(), kSize, false);
SetSimpleCacheMode();
InitCache();
disk_cache::Entry* entry1;
ASSERT_THAT(CreateEntry(kCollKey1, &entry1), IsOk());
disk_cache::Entry* entry2;
ASSERT_THAT(CreateEntry(kCollKey2, &entry2), IsOk());
// Make sure that entry was actually created and we didn't just succeed
// optimistically. (Oddly I can't seem to hit the sequence of events required
// for the bug that used to be here if I just set this to APP_CACHE).
EXPECT_EQ(kSize, WriteData(entry2, 0, 0, buffer2.get(), kSize, false));
// entry1 is still usable, though, and distinct (we just won't be able to
// re-open it).
EXPECT_EQ(kSize, WriteData(entry1, 0, 0, buffer1.get(), kSize, false));
EXPECT_EQ(kSize, ReadData(entry1, 0, 0, read_buffer.get(), kSize));
EXPECT_EQ(0, memcmp(buffer1->data(), read_buffer->data(), kSize));
EXPECT_EQ(kSize, ReadData(entry2, 0, 0, read_buffer.get(), kSize));
EXPECT_EQ(0, memcmp(buffer2->data(), read_buffer->data(), kSize));
entry1->Close();
entry2->Close();
}
TEST_F(DiskCacheEntryTest, SimpleCacheConvertToSparseStream2LeftOver) {
// Testcase for what happens when we have a sparse stream and a left over
// empty stream 2 file.
const int kSize = 10;
scoped_refptr<net::IOBuffer> buffer =
base::MakeRefCounted<net::IOBuffer>(kSize);
CacheTestFillBuffer(buffer->data(), kSize, false);
SetSimpleCacheMode();
InitCache();
disk_cache::Entry* entry;
std::string key("a key");
ASSERT_THAT(CreateEntry(key, &entry), IsOk());
// Create an empty stream 2. To do that, we first make a non-empty one, then
// truncate it (since otherwise the write would just get ignored).
EXPECT_EQ(kSize, WriteData(entry, /* stream = */ 2, /* offset = */ 0,
buffer.get(), kSize, false));
EXPECT_EQ(0, WriteData(entry, /* stream = */ 2, /* offset = */ 0,
buffer.get(), 0, true));
EXPECT_EQ(kSize, WriteSparseData(entry, 5, buffer.get(), kSize));
entry->Close();
// Reopen, and try to get the sparse data back.
ASSERT_THAT(OpenEntry(key, &entry), IsOk());
scoped_refptr<net::IOBuffer> buffer2 =
base::MakeRefCounted<net::IOBuffer>(kSize);
EXPECT_EQ(kSize, ReadSparseData(entry, 5, buffer2.get(), kSize));
EXPECT_EQ(0, memcmp(buffer->data(), buffer2->data(), kSize));
entry->Close();
}
TEST_F(DiskCacheEntryTest, SimpleCacheLazyStream2CreateFailure) {
// Testcase for what happens when lazy-creation of stream 2 fails.
const int kSize = 10;
scoped_refptr<net::IOBuffer> buffer =
base::MakeRefCounted<net::IOBuffer>(kSize);
CacheTestFillBuffer(buffer->data(), kSize, false);
// Synchronous ops, for ease of disk state;
SetCacheType(net::APP_CACHE);
SetSimpleCacheMode();
InitCache();
const char kKey[] = "a key";
disk_cache::Entry* entry = nullptr;
ASSERT_THAT(CreateEntry(kKey, &entry), IsOk());
// Create _1 file for stream 2; this should inject a failure when the cache
// tries to create it itself.
base::FilePath entry_file1_path = cache_path_.AppendASCII(
disk_cache::simple_util::GetFilenameFromKeyAndFileIndex(kKey, 1));
base::File entry_file1(entry_file1_path,
base::File::FLAG_WRITE | base::File::FLAG_CREATE);
ASSERT_TRUE(entry_file1.IsValid());
entry_file1.Close();
EXPECT_EQ(net::ERR_CACHE_WRITE_FAILURE,
WriteData(entry, /* index = */ 2, /* offset = */ 0, buffer.get(),
kSize, /* truncate = */ false));
entry->Close();
}
TEST_F(DiskCacheEntryTest, SimpleCacheChecksumpScrewUp) {
// Test for a bug that occurred during development of movement of CRC
// computation off I/O thread.
const int kSize = 10;
scoped_refptr<net::IOBuffer> buffer =
base::MakeRefCounted<net::IOBuffer>(kSize);
CacheTestFillBuffer(buffer->data(), kSize, false);
const int kDoubleSize = kSize * 2;
scoped_refptr<net::IOBuffer> big_buffer =
base::MakeRefCounted<net::IOBuffer>(kDoubleSize);
CacheTestFillBuffer(big_buffer->data(), kDoubleSize, false);
SetSimpleCacheMode();
InitCache();
const char kKey[] = "a key";
disk_cache::Entry* entry = nullptr;
ASSERT_THAT(CreateEntry(kKey, &entry), IsOk());
// Write out big_buffer for the double range. Checksum will be set to this.
ASSERT_EQ(kDoubleSize,
WriteData(entry, 1, 0, big_buffer.get(), kDoubleSize, false));
// Reset remembered position to 0 by writing at an earlier non-zero offset.
ASSERT_EQ(1, WriteData(entry, /* stream = */ 1, /* offset = */ 1,
big_buffer.get(), /* len = */ 1, false));
// Now write out the half-range twice. An intermediate revision would
// incorrectly compute checksum as if payload was buffer followed by buffer
// rather than buffer followed by end of big_buffer.
ASSERT_EQ(kSize, WriteData(entry, 1, 0, buffer.get(), kSize, false));
ASSERT_EQ(kSize, WriteData(entry, 1, 0, buffer.get(), kSize, false));
entry->Close();
ASSERT_THAT(OpenEntry(kKey, &entry), IsOk());
scoped_refptr<net::IOBuffer> buffer2 =
base::MakeRefCounted<net::IOBuffer>(kSize);
EXPECT_EQ(kSize, ReadData(entry, 1, 0, buffer2.get(), kSize));
EXPECT_EQ(0, memcmp(buffer->data(), buffer2->data(), kSize));
EXPECT_EQ(kSize, ReadData(entry, 1, kSize, buffer2.get(), kSize));
EXPECT_EQ(0, memcmp(big_buffer->data() + kSize, buffer2->data(), kSize));
entry->Close();
}
TEST_F(DiskCacheEntryTest, SimpleUseAfterBackendDestruction) {
SetSimpleCacheMode();
InitCache();
UseAfterBackendDestruction();
}
TEST_F(DiskCacheEntryTest, MemoryOnlyUseAfterBackendDestruction) {
// https://crbug.com/741620
SetMemoryOnlyMode();
InitCache();
UseAfterBackendDestruction();
}
class DiskCacheSimplePrefetchTest : public DiskCacheEntryTest {
public:
DiskCacheSimplePrefetchTest()
: field_trial_list_(std::make_unique<base::FieldTrialList>(
std::make_unique<base::MockEntropyProvider>())) {}
enum { kEntrySize = 1024 };
void SetUp() override {
payload_ = base::MakeRefCounted<net::IOBuffer>(kEntrySize);
CacheTestFillBuffer(payload_->data(), kEntrySize, false);
DiskCacheEntryTest::SetUp();
}
void SetupPrefetch(int size) {
std::map<std::string, std::string> params;
params[disk_cache::kSimplePrefetchBytesParam] = base::IntToString(size);
scoped_feature_list_.InitAndEnableFeatureWithParameters(
disk_cache::kSimpleCachePrefetchExperiment, params);
}
void InitCacheAndCreateEntry(const std::string& key) {
SetSimpleCacheMode();
InitCache();
disk_cache::Entry* entry;
ASSERT_EQ(net::OK, CreateEntry(key, &entry));
// Use stream 1 since that's what new prefetch stuff is about.
ASSERT_EQ(kEntrySize,
WriteData(entry, 1, 0, payload_.get(), kEntrySize, false));
entry->Close();
}
void InitCacheAndCreateEntryWithNoCrc(const std::string& key) {
const int kHalfSize = kEntrySize / 2;
const int kRemSize = kEntrySize - kHalfSize;
SetSimpleCacheMode();
InitCache();
disk_cache::Entry* entry;
ASSERT_EQ(net::OK, CreateEntry(key, &entry));
// Use stream 1 since that's what new prefetch stuff is about.
ASSERT_EQ(kEntrySize,
WriteData(entry, 1, 0, payload_.get(), kEntrySize, false));
// Overwrite later part of the buffer, since we can't keep track of
// the checksum in that case. Do it with identical contents, though,
// so that the only difference between here and InitCacheAndCreateEntry()
// would be whether the result has a checkum or not.
scoped_refptr<net::IOBuffer> second_half =
base::MakeRefCounted<net::IOBuffer>(kRemSize);
memcpy(second_half->data(), payload_->data() + kHalfSize, kRemSize);
ASSERT_EQ(kRemSize, WriteData(entry, 1, kHalfSize, second_half.get(),
kRemSize, false));
entry->Close();
}
void TryRead(const std::string& key) {
disk_cache::Entry* entry = NULL;
ASSERT_THAT(OpenEntry(key, &entry), IsOk());
scoped_refptr<net::IOBuffer> read_buf =
base::MakeRefCounted<net::IOBuffer>(kEntrySize);
EXPECT_EQ(kEntrySize, ReadData(entry, 1, 0, read_buf.get(), kEntrySize));
EXPECT_EQ(0, memcmp(read_buf->data(), payload_->data(), kEntrySize));
entry->Close();
}
protected:
scoped_refptr<net::IOBuffer> payload_;
// Need to have the one "global" trial list before we change things.
std::unique_ptr<base::FieldTrialList> field_trial_list_;
base::test::ScopedFeatureList scoped_feature_list_;
};
TEST_F(DiskCacheSimplePrefetchTest, NoPrefetch) {
base::HistogramTester histogram_tester;
SetupPrefetch(0);
const char kKey[] = "a key";
InitCacheAndCreateEntry(kKey);
TryRead(kKey);
histogram_tester.ExpectUniqueSample("SimpleCache.Http.SyncOpenDidPrefetch",
false, 1);
histogram_tester.ExpectUniqueSample(
"SimpleCache.Http.ReadStream1FromPrefetched", false, 1);
}
TEST_F(DiskCacheSimplePrefetchTest, YesPrefetch) {
base::HistogramTester histogram_tester;
SetupPrefetch(2 * kEntrySize);
const char kKey[] = "a key";
InitCacheAndCreateEntry(kKey);
TryRead(kKey);
histogram_tester.ExpectUniqueSample("SimpleCache.Http.SyncOpenDidPrefetch",
true, 1);
histogram_tester.ExpectUniqueSample(
"SimpleCache.Http.ReadStream1FromPrefetched", true, 1);
}
TEST_F(DiskCacheSimplePrefetchTest, YesPrefetchNoRead) {
base::HistogramTester histogram_tester;
SetupPrefetch(2 * kEntrySize);
const char kKey[] = "a key";
InitCacheAndCreateEntry(kKey);
disk_cache::Entry* entry = NULL;
ASSERT_THAT(OpenEntry(kKey, &entry), IsOk());
entry->Close();
histogram_tester.ExpectUniqueSample("SimpleCache.Http.SyncOpenDidPrefetch",
true, 1);
// Have to use GetHistogramSamplesSinceCreation here since it's the only
// API that handles the cases where the histogram hasn't even been created.
std::unique_ptr<base::HistogramSamples> samples(
histogram_tester.GetHistogramSamplesSinceCreation(
"SimpleCache.Http.ReadStream1FromPrefetched"));
EXPECT_EQ(0, samples->TotalCount());
}
// This makes sure we detect checksum error on entry that's small enough to be
// prefetched. This is like DiskCacheEntryTest.BadChecksum, but we make sure
// to configure prefetch explicitly.
TEST_F(DiskCacheSimplePrefetchTest, BadChecksumSmall) {
SetupPrefetch(1024); // bigger than stuff below.
SetSimpleCacheMode();
InitCache();
const char key[] = "the first key";
ASSERT_TRUE(SimpleCacheMakeBadChecksumEntry(key, 10));
disk_cache::Entry* entry = NULL;
// Open the entry. Since we made a small entry, we will detect the CRC
// problem at open.
EXPECT_THAT(OpenEntry(key, &entry), IsError(net::ERR_FAILED));
}
TEST_F(DiskCacheSimplePrefetchTest, ChecksumNoPrefetch) {
base::HistogramTester histogram_tester;
SetupPrefetch(0);
const char kKey[] = "a key";
InitCacheAndCreateEntry(kKey);
TryRead(kKey);
// Expect 2 CRCs --- stream 0 and stream 1.
histogram_tester.ExpectUniqueSample("SimpleCache.Http.SyncCheckEOFHasCrc",
true, 2);
histogram_tester.ExpectUniqueSample("SimpleCache.Http.SyncCheckEOFResult",
disk_cache::CHECK_EOF_RESULT_SUCCESS, 2);
}
TEST_F(DiskCacheSimplePrefetchTest, NoChecksumNoPrefetch) {
base::HistogramTester histogram_tester;
SetupPrefetch(0);
const char kKey[] = "a key";
InitCacheAndCreateEntryWithNoCrc(kKey);
TryRead(kKey);
// Stream 0 has CRC, stream 1 doesn't.
histogram_tester.ExpectBucketCount("SimpleCache.Http.SyncCheckEOFHasCrc",
true, 1);
histogram_tester.ExpectBucketCount("SimpleCache.Http.SyncCheckEOFHasCrc",
false, 1);
// EOF check is recorded even if there is no CRC there.
histogram_tester.ExpectUniqueSample("SimpleCache.Http.SyncCheckEOFResult",
disk_cache::CHECK_EOF_RESULT_SUCCESS, 2);
}
TEST_F(DiskCacheSimplePrefetchTest, ChecksumPrefetch) {
base::HistogramTester histogram_tester;
SetupPrefetch(2 * kEntrySize);
const char kKey[] = "a key";
InitCacheAndCreateEntry(kKey);
TryRead(kKey);
// Expect 2 CRCs --- stream 0 and stream 1.
histogram_tester.ExpectUniqueSample("SimpleCache.Http.SyncCheckEOFHasCrc",
true, 2);
histogram_tester.ExpectUniqueSample("SimpleCache.Http.SyncCheckEOFResult",
disk_cache::CHECK_EOF_RESULT_SUCCESS, 2);
}
TEST_F(DiskCacheSimplePrefetchTest, NoChecksumPrefetch) {
base::HistogramTester histogram_tester;
SetupPrefetch(2 * kEntrySize);
const char kKey[] = "a key";
InitCacheAndCreateEntryWithNoCrc(kKey);
TryRead(kKey);
// Stream 0 has CRC, stream 1 doesn't.
histogram_tester.ExpectBucketCount("SimpleCache.Http.SyncCheckEOFHasCrc",
true, 1);
histogram_tester.ExpectBucketCount("SimpleCache.Http.SyncCheckEOFHasCrc",
false, 1);
// EOF check is recorded even if there is no CRC there.
histogram_tester.ExpectUniqueSample("SimpleCache.Http.SyncCheckEOFResult",
disk_cache::CHECK_EOF_RESULT_SUCCESS, 2);
}
TEST_F(DiskCacheSimplePrefetchTest, PrefetchReadsSync) {
// Make sure we can read things synchronously after prefetch.
SetupPrefetch(32768); // way bigger than kEntrySize
const char kKey[] = "a key";
InitCacheAndCreateEntry(kKey);
disk_cache::Entry* entry = NULL;
ASSERT_THAT(OpenEntry(kKey, &entry), IsOk());
scoped_refptr<net::IOBuffer> read_buf =
base::MakeRefCounted<net::IOBuffer>(kEntrySize);
// That this is entry->ReadData(...) rather than ReadData(entry, ...) is
// meaningful here, as the latter is a helper in the test fixture that blocks
// if needed.
EXPECT_EQ(kEntrySize, entry->ReadData(1, 0, read_buf.get(), kEntrySize,
net::CompletionOnceCallback()));
EXPECT_EQ(0, memcmp(read_buf->data(), payload_->data(), kEntrySize));
entry->Close();
}