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chromium / chromium / src / e1a295845cbc338a564dc04e6e3e69b29ba7862f / . / net / extras / sqlite / sqlite_persistent_cookie_store_unittest.cc
blob: 8315d74e10e5b8c50fadb41267b5f3d97400455a [file] [log] [blame]
// Copyright (c) 2012 The Chromium Authors. All rights reserved.
// Use of this source code is governed by a BSD-style license that can be
// found in the LICENSE file.
#include "net/extras/sqlite/sqlite_persistent_cookie_store.h"
#include <map>
#include <set>
#include "base/bind.h"
#include "base/callback.h"
#include "base/files/file_util.h"
#include "base/files/scoped_temp_dir.h"
#include "base/location.h"
#include "base/memory/ref_counted.h"
#include "base/sequenced_task_runner.h"
#include "base/stl_util.h"
#include "base/synchronization/waitable_event.h"
#include "base/test/sequenced_worker_pool_owner.h"
#include "base/threading/sequenced_worker_pool.h"
#include "base/time/time.h"
#include "crypto/encryptor.h"
#include "crypto/symmetric_key.h"
#include "net/cookies/canonical_cookie.h"
#include "net/cookies/cookie_constants.h"
#include "net/extras/sqlite/cookie_crypto_delegate.h"
#include "sql/connection.h"
#include "sql/meta_table.h"
#include "sql/statement.h"
#include "testing/gtest/include/gtest/gtest.h"
#include "url/gurl.h"
namespace net {
namespace {
const base::FilePath::CharType kCookieFilename[] = FILE_PATH_LITERAL("Cookies");
class CookieCryptor : public CookieCryptoDelegate {
public:
CookieCryptor();
bool ShouldEncrypt() override;
bool EncryptString(const std::string& plaintext,
std::string* ciphertext) override;
bool DecryptString(const std::string& ciphertext,
std::string* plaintext) override;
bool should_encrypt_;
private:
scoped_ptr<crypto::SymmetricKey> key_;
crypto::Encryptor encryptor_;
};
CookieCryptor::CookieCryptor()
: should_encrypt_(true),
key_(
crypto::SymmetricKey::DeriveKeyFromPassword(crypto::SymmetricKey::AES,
"password",
"saltiest",
1000,
256)) {
std::string iv("the iv: 16 bytes");
encryptor_.Init(key_.get(), crypto::Encryptor::CBC, iv);
}
bool CookieCryptor::ShouldEncrypt() {
return should_encrypt_;
}
bool CookieCryptor::EncryptString(const std::string& plaintext,
std::string* ciphertext) {
return encryptor_.Encrypt(plaintext, ciphertext);
}
bool CookieCryptor::DecryptString(const std::string& ciphertext,
std::string* plaintext) {
return encryptor_.Decrypt(ciphertext, plaintext);
}
} // namespace
typedef std::vector<CanonicalCookie*> CanonicalCookieVector;
class SQLitePersistentCookieStoreTest : public testing::Test {
public:
SQLitePersistentCookieStoreTest()
: pool_owner_(new base::SequencedWorkerPoolOwner(3, "Background Pool")),
loaded_event_(false, false),
key_loaded_event_(false, false),
db_thread_event_(false, false) {}
void OnLoaded(const CanonicalCookieVector& cookies) {
cookies_ = cookies;
loaded_event_.Signal();
}
void OnKeyLoaded(const CanonicalCookieVector& cookies) {
cookies_ = cookies;
key_loaded_event_.Signal();
}
void Load(CanonicalCookieVector* cookies) {
EXPECT_FALSE(loaded_event_.IsSignaled());
store_->Load(base::Bind(&SQLitePersistentCookieStoreTest::OnLoaded,
base::Unretained(this)));
loaded_event_.Wait();
*cookies = cookies_;
}
void Flush() {
base::WaitableEvent event(false, false);
store_->Flush(
base::Bind(&base::WaitableEvent::Signal, base::Unretained(&event)));
event.Wait();
}
scoped_refptr<base::SequencedTaskRunner> background_task_runner() {
return pool_owner_->pool()->GetSequencedTaskRunner(
pool_owner_->pool()->GetNamedSequenceToken("background"));
}
scoped_refptr<base::SequencedTaskRunner> client_task_runner() {
return pool_owner_->pool()->GetSequencedTaskRunner(
pool_owner_->pool()->GetNamedSequenceToken("client"));
}
void DestroyStore() {
store_ = nullptr;
// Make sure we wait until the destructor has run by shutting down the pool
// resetting the owner (whose destructor blocks on the pool completion).
pool_owner_->pool()->Shutdown();
// Create a new pool for the few tests that create multiple stores. In other
// cases this is wasted but harmless.
pool_owner_.reset(new base::SequencedWorkerPoolOwner(3, "Background Pool"));
}
void Create(bool crypt_cookies, bool restore_old_session_cookies) {
if (crypt_cookies)
cookie_crypto_delegate_.reset(new CookieCryptor());
store_ = new SQLitePersistentCookieStore(
temp_dir_.path().Append(kCookieFilename), client_task_runner(),
background_task_runner(), restore_old_session_cookies,
cookie_crypto_delegate_.get());
}
void CreateAndLoad(bool crypt_cookies,
bool restore_old_session_cookies,
CanonicalCookieVector* cookies) {
Create(crypt_cookies, restore_old_session_cookies);
Load(cookies);
}
void InitializeStore(bool crypt, bool restore_old_session_cookies) {
CanonicalCookieVector cookies;
CreateAndLoad(crypt, restore_old_session_cookies, &cookies);
EXPECT_EQ(0U, cookies.size());
}
// We have to create this method to wrap WaitableEvent::Wait, since we cannot
// bind a non-void returning method as a Closure.
void WaitOnDBEvent() { db_thread_event_.Wait(); }
// Adds a persistent cookie to store_.
void AddCookie(const std::string& name,
const std::string& value,
const std::string& domain,
const std::string& path,
const base::Time& creation) {
store_->AddCookie(CanonicalCookie(
GURL(), name, value, domain, path, creation, creation, creation, false,
false, CookieSameSite::DEFAULT_MODE, COOKIE_PRIORITY_DEFAULT));
}
void AddCookieWithExpiration(const std::string& name,
const std::string& value,
const std::string& domain,
const std::string& path,
const base::Time& creation,
const base::Time& expiration) {
store_->AddCookie(CanonicalCookie(
GURL(), name, value, domain, path, creation, expiration, creation,
false, false, CookieSameSite::DEFAULT_MODE, COOKIE_PRIORITY_DEFAULT));
}
std::string ReadRawDBContents() {
std::string contents;
if (!base::ReadFileToString(temp_dir_.path().Append(kCookieFilename),
&contents))
return std::string();
return contents;
}
void SetUp() override { ASSERT_TRUE(temp_dir_.CreateUniqueTempDir()); }
void TearDown() override {
DestroyStore();
}
protected:
scoped_ptr<base::SequencedWorkerPoolOwner> pool_owner_;
base::WaitableEvent loaded_event_;
base::WaitableEvent key_loaded_event_;
base::WaitableEvent db_thread_event_;
CanonicalCookieVector cookies_;
base::ScopedTempDir temp_dir_;
scoped_refptr<SQLitePersistentCookieStore> store_;
scoped_ptr<CookieCryptor> cookie_crypto_delegate_;
};
TEST_F(SQLitePersistentCookieStoreTest, TestInvalidMetaTableRecovery) {
InitializeStore(false, false);
AddCookie("A", "B", "foo.bar", "/", base::Time::Now());
DestroyStore();
// Load up the store and verify that it has good data in it.
CanonicalCookieVector cookies;
CreateAndLoad(false, false, &cookies);
ASSERT_EQ(1U, cookies.size());
ASSERT_STREQ("foo.bar", cookies[0]->Domain().c_str());
ASSERT_STREQ("A", cookies[0]->Name().c_str());
ASSERT_STREQ("B", cookies[0]->Value().c_str());
DestroyStore();
STLDeleteElements(&cookies);
// Now corrupt the meta table.
{
sql::Connection db;
ASSERT_TRUE(db.Open(temp_dir_.path().Append(kCookieFilename)));
sql::MetaTable meta_table_;
meta_table_.Init(&db, 1, 1);
ASSERT_TRUE(db.Execute("DELETE FROM meta"));
db.Close();
}
// Upon loading, the database should be reset to a good, blank state.
CreateAndLoad(false, false, &cookies);
ASSERT_EQ(0U, cookies.size());
// Verify that, after, recovery, the database persists properly.
AddCookie("X", "Y", "foo.bar", "/", base::Time::Now());
DestroyStore();
CreateAndLoad(false, false, &cookies);
ASSERT_EQ(1U, cookies.size());
ASSERT_STREQ("foo.bar", cookies[0]->Domain().c_str());
ASSERT_STREQ("X", cookies[0]->Name().c_str());
ASSERT_STREQ("Y", cookies[0]->Value().c_str());
STLDeleteElements(&cookies);
}
// Test if data is stored as expected in the SQLite database.
TEST_F(SQLitePersistentCookieStoreTest, TestPersistance) {
InitializeStore(false, false);
AddCookie("A", "B", "foo.bar", "/", base::Time::Now());
// Replace the store effectively destroying the current one and forcing it
// to write its data to disk. Then we can see if after loading it again it
// is still there.
DestroyStore();
// Reload and test for persistence
CanonicalCookieVector cookies;
CreateAndLoad(false, false, &cookies);
ASSERT_EQ(1U, cookies.size());
ASSERT_STREQ("foo.bar", cookies[0]->Domain().c_str());
ASSERT_STREQ("A", cookies[0]->Name().c_str());
ASSERT_STREQ("B", cookies[0]->Value().c_str());
// Now delete the cookie and check persistence again.
store_->DeleteCookie(*cookies[0]);
DestroyStore();
STLDeleteElements(&cookies);
// Reload and check if the cookie has been removed.
CreateAndLoad(false, false, &cookies);
ASSERT_EQ(0U, cookies.size());
}
TEST_F(SQLitePersistentCookieStoreTest, TestSessionCookiesDeletedOnStartup) {
// Initialize the cookie store with 3 persistent cookies, 5 transient
// cookies.
InitializeStore(false, false);
// Add persistent cookies.
base::Time t = base::Time::Now();
AddCookie("A", "B", "a1.com", "/", t);
t += base::TimeDelta::FromInternalValue(10);
AddCookie("A", "B", "a2.com", "/", t);
t += base::TimeDelta::FromInternalValue(10);
AddCookie("A", "B", "a3.com", "/", t);
// Add transient cookies.
t += base::TimeDelta::FromInternalValue(10);
AddCookieWithExpiration("A", "B", "b1.com", "/", t, base::Time());
t += base::TimeDelta::FromInternalValue(10);
AddCookieWithExpiration("A", "B", "b2.com", "/", t, base::Time());
t += base::TimeDelta::FromInternalValue(10);
AddCookieWithExpiration("A", "B", "b3.com", "/", t, base::Time());
t += base::TimeDelta::FromInternalValue(10);
AddCookieWithExpiration("A", "B", "b4.com", "/", t, base::Time());
t += base::TimeDelta::FromInternalValue(10);
AddCookieWithExpiration("A", "B", "b5.com", "/", t, base::Time());
DestroyStore();
// Load the store a second time. Before the store finishes loading, add a
// transient cookie and flush it to disk.
store_ = new SQLitePersistentCookieStore(
temp_dir_.path().Append(kCookieFilename), client_task_runner(),
background_task_runner(), false, nullptr);
// Posting a blocking task to db_thread_ makes sure that the DB thread waits
// until both Load and Flush have been posted to its task queue.
background_task_runner()->PostTask(
FROM_HERE, base::Bind(&SQLitePersistentCookieStoreTest::WaitOnDBEvent,
base::Unretained(this)));
store_->Load(base::Bind(&SQLitePersistentCookieStoreTest::OnLoaded,
base::Unretained(this)));
t += base::TimeDelta::FromInternalValue(10);
AddCookieWithExpiration("A", "B", "c.com", "/", t, base::Time());
base::WaitableEvent event(false, false);
store_->Flush(
base::Bind(&base::WaitableEvent::Signal, base::Unretained(&event)));
// Now the DB-thread queue contains:
// (active:)
// 1. Wait (on db_event)
// (pending:)
// 2. "Init And Chain-Load First Domain"
// 3. Add Cookie (c.com)
// 4. Flush Cookie (c.com)
db_thread_event_.Signal();
event.Wait();
loaded_event_.Wait();
STLDeleteElements(&cookies_);
DestroyStore();
// Load the store a third time, this time restoring session cookies. The
// store should contain exactly 4 cookies: the 3 persistent, and "c.com",
// which was added during the second cookie store load.
store_ = new SQLitePersistentCookieStore(
temp_dir_.path().Append(kCookieFilename), client_task_runner(),
background_task_runner(), true, nullptr);
store_->Load(base::Bind(&SQLitePersistentCookieStoreTest::OnLoaded,
base::Unretained(this)));
loaded_event_.Wait();
ASSERT_EQ(4u, cookies_.size());
STLDeleteElements(&cookies_);
}
// Test that priority load of cookies for a specfic domain key could be
// completed before the entire store is loaded
TEST_F(SQLitePersistentCookieStoreTest, TestLoadCookiesForKey) {
InitializeStore(false, false);
base::Time t = base::Time::Now();
AddCookie("A", "B", "foo.bar", "/", t);
t += base::TimeDelta::FromInternalValue(10);
AddCookie("A", "B", "www.aaa.com", "/", t);
t += base::TimeDelta::FromInternalValue(10);
AddCookie("A", "B", "travel.aaa.com", "/", t);
t += base::TimeDelta::FromInternalValue(10);
AddCookie("A", "B", "www.bbb.com", "/", t);
DestroyStore();
store_ = new SQLitePersistentCookieStore(
temp_dir_.path().Append(kCookieFilename), client_task_runner(),
background_task_runner(), false, nullptr);
// Posting a blocking task to db_thread_ makes sure that the DB thread waits
// until both Load and LoadCookiesForKey have been posted to its task queue.
background_task_runner()->PostTask(
FROM_HERE, base::Bind(&SQLitePersistentCookieStoreTest::WaitOnDBEvent,
base::Unretained(this)));
store_->Load(base::Bind(&SQLitePersistentCookieStoreTest::OnLoaded,
base::Unretained(this)));
store_->LoadCookiesForKey(
"aaa.com", base::Bind(&SQLitePersistentCookieStoreTest::OnKeyLoaded,
base::Unretained(this)));
background_task_runner()->PostTask(
FROM_HERE, base::Bind(&SQLitePersistentCookieStoreTest::WaitOnDBEvent,
base::Unretained(this)));
// Now the DB-thread queue contains:
// (active:)
// 1. Wait (on db_event)
// (pending:)
// 2. "Init And Chain-Load First Domain"
// 3. Priority Load (aaa.com)
// 4. Wait (on db_event)
db_thread_event_.Signal();
key_loaded_event_.Wait();
ASSERT_EQ(loaded_event_.IsSignaled(), false);
std::set<std::string> cookies_loaded;
for (CanonicalCookieVector::const_iterator it = cookies_.begin();
it != cookies_.end(); ++it) {
cookies_loaded.insert((*it)->Domain().c_str());
}
STLDeleteElements(&cookies_);
ASSERT_GT(4U, cookies_loaded.size());
ASSERT_EQ(true, cookies_loaded.find("www.aaa.com") != cookies_loaded.end());
ASSERT_EQ(true,
cookies_loaded.find("travel.aaa.com") != cookies_loaded.end());
db_thread_event_.Signal();
loaded_event_.Wait();
for (CanonicalCookieVector::const_iterator it = cookies_.begin();
it != cookies_.end(); ++it) {
cookies_loaded.insert((*it)->Domain().c_str());
}
ASSERT_EQ(4U, cookies_loaded.size());
ASSERT_EQ(cookies_loaded.find("foo.bar") != cookies_loaded.end(), true);
ASSERT_EQ(cookies_loaded.find("www.bbb.com") != cookies_loaded.end(), true);
STLDeleteElements(&cookies_);
}
// Test that we can force the database to be written by calling Flush().
TEST_F(SQLitePersistentCookieStoreTest, TestFlush) {
InitializeStore(false, false);
// File timestamps don't work well on all platforms, so we'll determine
// whether the DB file has been modified by checking its size.
base::FilePath path = temp_dir_.path().Append(kCookieFilename);
base::File::Info info;
ASSERT_TRUE(base::GetFileInfo(path, &info));
int64_t base_size = info.size;
// Write some large cookies, so the DB will have to expand by several KB.
for (char c = 'a'; c < 'z'; ++c) {
// Each cookie needs a unique timestamp for creation_utc (see DB schema).
base::Time t = base::Time::Now() + base::TimeDelta::FromMicroseconds(c);
std::string name(1, c);
std::string value(1000, c);
AddCookie(name, value, "foo.bar", "/", t);
}
Flush();
// We forced a write, so now the file will be bigger.
ASSERT_TRUE(base::GetFileInfo(path, &info));
ASSERT_GT(info.size, base_size);
}
// Test loading old session cookies from the disk.
TEST_F(SQLitePersistentCookieStoreTest, TestLoadOldSessionCookies) {
InitializeStore(false, true);
// Add a session cookie.
store_->AddCookie(CanonicalCookie(
GURL(), "C", "D", "sessioncookie.com", "/", base::Time::Now(),
base::Time(), base::Time::Now(), false, false,
CookieSameSite::DEFAULT_MODE, COOKIE_PRIORITY_DEFAULT));
// Force the store to write its data to the disk.
DestroyStore();
// Create a store that loads session cookies and test that the session cookie
// was loaded.
CanonicalCookieVector cookies;
CreateAndLoad(false, true, &cookies);
ASSERT_EQ(1U, cookies.size());
ASSERT_STREQ("sessioncookie.com", cookies[0]->Domain().c_str());
ASSERT_STREQ("C", cookies[0]->Name().c_str());
ASSERT_STREQ("D", cookies[0]->Value().c_str());
ASSERT_EQ(COOKIE_PRIORITY_DEFAULT, cookies[0]->Priority());
STLDeleteElements(&cookies);
}
// Test loading old session cookies from the disk.
TEST_F(SQLitePersistentCookieStoreTest, TestDontLoadOldSessionCookies) {
InitializeStore(false, true);
// Add a session cookie.
store_->AddCookie(CanonicalCookie(
GURL(), "C", "D", "sessioncookie.com", "/", base::Time::Now(),
base::Time(), base::Time::Now(), false, false,
CookieSameSite::DEFAULT_MODE, COOKIE_PRIORITY_DEFAULT));
// Force the store to write its data to the disk.
DestroyStore();
// Create a store that doesn't load old session cookies and test that the
// session cookie was not loaded.
CanonicalCookieVector cookies;
CreateAndLoad(false, false, &cookies);
ASSERT_EQ(0U, cookies.size());
// The store should also delete the session cookie. Wait until that has been
// done.
DestroyStore();
// Create a store that loads old session cookies and test that the session
// cookie is gone.
CreateAndLoad(false, true, &cookies);
ASSERT_EQ(0U, cookies.size());
}
TEST_F(SQLitePersistentCookieStoreTest, PersistIsPersistent) {
InitializeStore(false, true);
static const char kSessionName[] = "session";
static const char kPersistentName[] = "persistent";
// Add a session cookie.
store_->AddCookie(CanonicalCookie(
GURL(), kSessionName, "val", "sessioncookie.com", "/", base::Time::Now(),
base::Time(), base::Time::Now(), false, false,
CookieSameSite::DEFAULT_MODE, COOKIE_PRIORITY_DEFAULT));
// Add a persistent cookie.
store_->AddCookie(CanonicalCookie(
GURL(), kPersistentName, "val", "sessioncookie.com", "/",
base::Time::Now() - base::TimeDelta::FromDays(1),
base::Time::Now() + base::TimeDelta::FromDays(1), base::Time::Now(),
false, false, CookieSameSite::DEFAULT_MODE, COOKIE_PRIORITY_DEFAULT));
// Force the store to write its data to the disk.
DestroyStore();
// Create a store that loads session cookie and test that the IsPersistent
// attribute is restored.
CanonicalCookieVector cookies;
CreateAndLoad(false, true, &cookies);
ASSERT_EQ(2U, cookies.size());
std::map<std::string, CanonicalCookie*> cookie_map;
for (CanonicalCookieVector::const_iterator it = cookies.begin();
it != cookies.end(); ++it) {
cookie_map[(*it)->Name()] = *it;
}
std::map<std::string, CanonicalCookie*>::const_iterator it =
cookie_map.find(kSessionName);
ASSERT_TRUE(it != cookie_map.end());
EXPECT_FALSE(cookie_map[kSessionName]->IsPersistent());
it = cookie_map.find(kPersistentName);
ASSERT_TRUE(it != cookie_map.end());
EXPECT_TRUE(cookie_map[kPersistentName]->IsPersistent());
STLDeleteElements(&cookies);
}
TEST_F(SQLitePersistentCookieStoreTest, PriorityIsPersistent) {
static const char kLowName[] = "low";
static const char kMediumName[] = "medium";
static const char kHighName[] = "high";
static const char kCookieDomain[] = "sessioncookie.com";
static const char kCookieValue[] = "value";
static const char kCookiePath[] = "/";
InitializeStore(false, true);
// Add a low-priority persistent cookie.
store_->AddCookie(CanonicalCookie(
GURL(), kLowName, kCookieValue, kCookieDomain, kCookiePath,
base::Time::Now() - base::TimeDelta::FromMinutes(1),
base::Time::Now() + base::TimeDelta::FromDays(1), base::Time::Now(),
false, false, CookieSameSite::DEFAULT_MODE, COOKIE_PRIORITY_LOW));
// Add a medium-priority persistent cookie.
store_->AddCookie(CanonicalCookie(
GURL(), kMediumName, kCookieValue, kCookieDomain, kCookiePath,
base::Time::Now() - base::TimeDelta::FromMinutes(2),
base::Time::Now() + base::TimeDelta::FromDays(1), base::Time::Now(),
false, false, CookieSameSite::DEFAULT_MODE, COOKIE_PRIORITY_MEDIUM));
// Add a high-priority peristent cookie.
store_->AddCookie(CanonicalCookie(
GURL(), kHighName, kCookieValue, kCookieDomain, kCookiePath,
base::Time::Now() - base::TimeDelta::FromMinutes(3),
base::Time::Now() + base::TimeDelta::FromDays(1), base::Time::Now(),
false, false, CookieSameSite::DEFAULT_MODE, COOKIE_PRIORITY_HIGH));
// Force the store to write its data to the disk.
DestroyStore();
// Create a store that loads session cookie and test that the priority
// attribute values are restored.
CanonicalCookieVector cookies;
CreateAndLoad(false, true, &cookies);
ASSERT_EQ(3U, cookies.size());
// Put the cookies into a map, by name, so we can easily find them.
std::map<std::string, CanonicalCookie*> cookie_map;
for (CanonicalCookieVector::const_iterator it = cookies.begin();
it != cookies.end(); ++it) {
cookie_map[(*it)->Name()] = *it;
}
// Validate that each cookie has the correct priority.
std::map<std::string, CanonicalCookie*>::const_iterator it =
cookie_map.find(kLowName);
ASSERT_TRUE(it != cookie_map.end());
EXPECT_EQ(COOKIE_PRIORITY_LOW, cookie_map[kLowName]->Priority());
it = cookie_map.find(kMediumName);
ASSERT_TRUE(it != cookie_map.end());
EXPECT_EQ(COOKIE_PRIORITY_MEDIUM, cookie_map[kMediumName]->Priority());
it = cookie_map.find(kHighName);
ASSERT_TRUE(it != cookie_map.end());
EXPECT_EQ(COOKIE_PRIORITY_HIGH, cookie_map[kHighName]->Priority());
STLDeleteElements(&cookies);
}
TEST_F(SQLitePersistentCookieStoreTest, SameSiteIsPersistent) {
const char kNoneName[] = "none";
const char kLaxName[] = "lax";
const char kStrictName[] = "strict";
const char kCookieDomain[] = "sessioncookie.com";
const char kCookieValue[] = "value";
const char kCookiePath[] = "/";
InitializeStore(false, true);
// Add a non-samesite cookie.
store_->AddCookie(CanonicalCookie(
GURL(), kNoneName, kCookieValue, kCookieDomain, kCookiePath,
base::Time::Now() - base::TimeDelta::FromMinutes(1),
base::Time::Now() + base::TimeDelta::FromDays(1), base::Time::Now(),
false, false, CookieSameSite::NO_RESTRICTION, COOKIE_PRIORITY_DEFAULT));
// Add a lax-samesite persistent cookie.
store_->AddCookie(CanonicalCookie(
GURL(), kLaxName, kCookieValue, kCookieDomain, kCookiePath,
base::Time::Now() - base::TimeDelta::FromMinutes(2),
base::Time::Now() + base::TimeDelta::FromDays(1), base::Time::Now(),
false, false, CookieSameSite::LAX_MODE, COOKIE_PRIORITY_DEFAULT));
// Add a strict-samesite peristent cookie.
store_->AddCookie(CanonicalCookie(
GURL(), kStrictName, kCookieValue, kCookieDomain, kCookiePath,
base::Time::Now() - base::TimeDelta::FromMinutes(3),
base::Time::Now() + base::TimeDelta::FromDays(1), base::Time::Now(),
false, false, CookieSameSite::STRICT_MODE, COOKIE_PRIORITY_DEFAULT));
// Force the store to write its data to the disk.
DestroyStore();
// Create a store that loads session cookie and test that the priority
// attribute values are restored.
CanonicalCookieVector cookies;
CreateAndLoad(false, true, &cookies);
ASSERT_EQ(3U, cookies.size());
// Put the cookies into a map, by name, for comparison below.
std::map<std::string, CanonicalCookie*> cookie_map;
for (const auto& cookie : cookies)
cookie_map[cookie->Name()] = cookie;
// Validate that each cookie has the correct SameSite.
ASSERT_EQ(1u, cookie_map.count(kNoneName));
EXPECT_EQ(CookieSameSite::NO_RESTRICTION, cookie_map[kNoneName]->SameSite());
ASSERT_EQ(1u, cookie_map.count(kLaxName));
EXPECT_EQ(CookieSameSite::LAX_MODE, cookie_map[kLaxName]->SameSite());
ASSERT_EQ(1u, cookie_map.count(kStrictName));
EXPECT_EQ(CookieSameSite::STRICT_MODE, cookie_map[kStrictName]->SameSite());
STLDeleteElements(&cookies);
}
TEST_F(SQLitePersistentCookieStoreTest, UpdateToEncryption) {
CanonicalCookieVector cookies;
// Create unencrypted cookie store and write something to it.
InitializeStore(false, false);
AddCookie("name", "value123XYZ", "foo.bar", "/", base::Time::Now());
DestroyStore();
// Verify that "value" is visible in the file. This is necessary in order to
// have confidence in a later test that "encrypted_value" is not visible.
std::string contents = ReadRawDBContents();
EXPECT_NE(0U, contents.length());
EXPECT_NE(contents.find("value123XYZ"), std::string::npos);
// Create encrypted cookie store and ensure old cookie still reads.
STLDeleteElements(&cookies_);
EXPECT_EQ(0U, cookies_.size());
CreateAndLoad(true, false, &cookies);
EXPECT_EQ(1U, cookies_.size());
EXPECT_EQ("name", cookies_[0]->Name());
EXPECT_EQ("value123XYZ", cookies_[0]->Value());
// Make sure we can update existing cookie and add new cookie as encrypted.
store_->DeleteCookie(*(cookies_[0]));
AddCookie("name", "encrypted_value123XYZ", "foo.bar", "/", base::Time::Now());
AddCookie("other", "something456ABC", "foo.bar", "/",
base::Time::Now() + base::TimeDelta::FromInternalValue(10));
DestroyStore();
STLDeleteElements(&cookies_);
CreateAndLoad(true, false, &cookies);
EXPECT_EQ(2U, cookies_.size());
CanonicalCookie* cookie_name = nullptr;
CanonicalCookie* cookie_other = nullptr;
if (cookies_[0]->Name() == "name") {
cookie_name = cookies_[0];
cookie_other = cookies_[1];
} else {
cookie_name = cookies_[1];
cookie_other = cookies_[0];
}
EXPECT_EQ("encrypted_value123XYZ", cookie_name->Value());
EXPECT_EQ("something456ABC", cookie_other->Value());
DestroyStore();
STLDeleteElements(&cookies_);
// Examine the real record to make sure plaintext version doesn't exist.
sql::Connection db;
sql::Statement smt;
int resultcount = 0;
ASSERT_TRUE(db.Open(temp_dir_.path().Append(kCookieFilename)));
smt.Assign(db.GetCachedStatement(SQL_FROM_HERE,
"SELECT * "
"FROM cookies "
"WHERE host_key = 'foo.bar'"));
while (smt.Step()) {
resultcount++;
for (int i = 0; i < smt.ColumnCount(); i++) {
EXPECT_EQ(smt.ColumnString(i).find("value"), std::string::npos);
EXPECT_EQ(smt.ColumnString(i).find("something"), std::string::npos);
}
}
EXPECT_EQ(2, resultcount);
// Verify that "encrypted_value" is NOT visible in the file.
contents = ReadRawDBContents();
EXPECT_NE(0U, contents.length());
EXPECT_EQ(contents.find("encrypted_value123XYZ"), std::string::npos);
EXPECT_EQ(contents.find("something456ABC"), std::string::npos);
}
TEST_F(SQLitePersistentCookieStoreTest, UpdateFromEncryption) {
CanonicalCookieVector cookies;
// Create unencrypted cookie store and write something to it.
InitializeStore(true, false);
AddCookie("name", "value123XYZ", "foo.bar", "/", base::Time::Now());
DestroyStore();
// Verify that "value" is not visible in the file.
std::string contents = ReadRawDBContents();
EXPECT_NE(0U, contents.length());
EXPECT_EQ(contents.find("value123XYZ"), std::string::npos);
// Create encrypted cookie store and ensure old cookie still reads.
STLDeleteElements(&cookies_);
EXPECT_EQ(0U, cookies_.size());
CreateAndLoad(true, false, &cookies);
EXPECT_EQ(1U, cookies_.size());
EXPECT_EQ("name", cookies_[0]->Name());
EXPECT_EQ("value123XYZ", cookies_[0]->Value());
// Make sure we can update existing cookie and it writes unencrypted.
cookie_crypto_delegate_->should_encrypt_ = false;
store_->DeleteCookie(*(cookies_[0]));
AddCookie("name", "plaintext_value123XYZ", "foo.bar", "/", base::Time::Now());
AddCookie("other", "something456ABC", "foo.bar", "/",
base::Time::Now() + base::TimeDelta::FromInternalValue(10));
DestroyStore();
STLDeleteElements(&cookies_);
CreateAndLoad(true, false, &cookies);
EXPECT_EQ(2U, cookies_.size());
CanonicalCookie* cookie_name = nullptr;
CanonicalCookie* cookie_other = nullptr;
if (cookies_[0]->Name() == "name") {
cookie_name = cookies_[0];
cookie_other = cookies_[1];
} else {
cookie_name = cookies_[1];
cookie_other = cookies_[0];
}
EXPECT_EQ("plaintext_value123XYZ", cookie_name->Value());
EXPECT_EQ("something456ABC", cookie_other->Value());
DestroyStore();
STLDeleteElements(&cookies_);
// Verify that "value" is now visible in the file.
contents = ReadRawDBContents();
EXPECT_NE(0U, contents.length());
EXPECT_NE(contents.find("value123XYZ"), std::string::npos);
}
namespace {
void WasCalledWithNoCookies(bool* was_called_with_no_cookies,
const std::vector<CanonicalCookie*>& cookies) {
*was_called_with_no_cookies = cookies.empty();
}
}
TEST_F(SQLitePersistentCookieStoreTest, EmptyLoadAfterClose) {
// Create unencrypted cookie store and write something to it.
InitializeStore(false, false);
AddCookie("name", "value123XYZ", "foo.bar", "/", base::Time::Now());
DestroyStore();
// Create the cookie store, but immediately close it.
Create(false, false);
store_->Close(base::Closure());
// Expect any attempt to call Load() to synchronously respond with an empty
// vector of cookies after we've Close()d the database.
bool was_called_with_no_cookies = false;
store_->Load(base::Bind(WasCalledWithNoCookies, &was_called_with_no_cookies));
EXPECT_TRUE(was_called_with_no_cookies);
// Same with trying to load a specific cookie.
was_called_with_no_cookies = false;
store_->LoadCookiesForKey("foo.bar", base::Bind(WasCalledWithNoCookies,
&was_called_with_no_cookies));
EXPECT_TRUE(was_called_with_no_cookies);
}
} // namespace net