// 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 #include #include #include #include "base/bind.h" #include "base/callback.h" #include "base/files/file_path.h" #include "base/files/file_util.h" #include "base/location.h" #include "base/logging.h" #include "base/macros.h" #include "base/memory/ref_counted.h" #include "base/metrics/histogram_macros.h" #include "base/sequenced_task_runner.h" #include "base/strings/string_util.h" #include "base/strings/stringprintf.h" #include "base/synchronization/atomic_flag.h" #include "base/synchronization/lock.h" #include "base/time/time.h" #include "net/cookies/canonical_cookie.h" #include "net/cookies/cookie_constants.h" #include "net/cookies/cookie_util.h" #include "net/extras/sqlite/cookie_crypto_delegate.h" #include "sql/error_delegate_util.h" #include "sql/meta_table.h" #include "sql/statement.h" #include "sql/transaction.h" #include "url/gurl.h" using base::Time; namespace { // Used to populate a histogram for problems when loading cookies. // // Please do not reorder or remove entries. New entries must be added to the // end of the list, just before COOKIE_LOAD_PROBLEM_LAST_ENTRY. enum CookieLoadProblem { COOKIE_LOAD_PROBLEM_DECRYPT_FAILED = 0, COOKIE_LOAD_PROBLEM_DECRYPT_TIMEOUT = 1, COOKIE_LOAD_PROBLEM_NON_CANONICAL = 2, COOKIE_LOAD_PROBLEM_OPEN_DB = 3, COOKIE_LOAD_PROBLEM_RECOVERY_FAILED = 4, COOKIE_LOAD_PROBLEM_LAST_ENTRY }; // Used to populate a histogram for problems when committing cookies. // // Please do not reorder or remove entries. New entries must be added to the // end of the list, just before COOKIE_COMMIT_PROBLEM_LAST_ENTRY. enum CookieCommitProblem { COOKIE_COMMIT_PROBLEM_ENCRYPT_FAILED = 0, COOKIE_COMMIT_PROBLEM_ADD = 1, COOKIE_COMMIT_PROBLEM_UPDATE_ACCESS = 2, COOKIE_COMMIT_PROBLEM_DELETE = 3, COOKIE_COMMIT_PROBLEM_LAST_ENTRY }; // Used to report a histogram on status of cookie commit to disk. // // Please do not reorder or remove entries. New entries must be added to the // end of the list, just before BACKING_STORE_RESULTS_LAST_ENTRY. enum BackingStoreResults { BACKING_STORE_RESULTS_SUCCESS = 0, BACKING_STORE_RESULTS_FAILURE = 1, BACKING_STORE_RESULTS_MIXED = 2, BACKING_STORE_RESULTS_LAST_ENTRY }; void RecordCookieLoadProblem(CookieLoadProblem event) { UMA_HISTOGRAM_ENUMERATION("Cookie.LoadProblem", event, COOKIE_LOAD_PROBLEM_LAST_ENTRY); } void RecordCookieCommitProblem(CookieCommitProblem event) { UMA_HISTOGRAM_ENUMERATION("Cookie.CommitProblem", event, COOKIE_COMMIT_PROBLEM_LAST_ENTRY); } // The persistent cookie store is loaded into memory on eTLD at a time. This // variable controls the delay between loading eTLDs, so as to not overload the // CPU or I/O with these low priority requests immediately after start up. #if defined(OS_IOS) // TODO(ellyjones): This should be 200ms, but currently CookieStoreIOS is // waiting for -FinishedLoadingCookies to be called after all eTLD cookies are // loaded before making any network requests. Changing to 0ms for now. // crbug.com/462593 const int kLoadDelayMilliseconds = 0; #else const int kLoadDelayMilliseconds = 0; #endif // A little helper to help us log (on client thread) if the background runner // gets stuck. class TimeoutTracker : public base::RefCountedThreadSafe { public: // Runs on background runner. static scoped_refptr Begin( const scoped_refptr& client_task_runner) { scoped_refptr tracker = new TimeoutTracker; client_task_runner->PostDelayedTask( FROM_HERE, base::BindOnce(&TimeoutTracker::TimerElapsed, tracker), base::TimeDelta::FromSeconds(60)); return tracker; } // Runs on background runner. void End() { done_.Set(); } private: friend class base::RefCountedThreadSafe; TimeoutTracker() {} ~TimeoutTracker() { DCHECK(done_.IsSet()); } // Run on client runner. void TimerElapsed() { if (!done_.IsSet()) RecordCookieLoadProblem(COOKIE_LOAD_PROBLEM_DECRYPT_TIMEOUT); } base::AtomicFlag done_; DISALLOW_COPY_AND_ASSIGN(TimeoutTracker); }; } // namespace namespace net { // This class is designed to be shared between any client thread and the // background task runner. It batches operations and commits them on a timer. // // SQLitePersistentCookieStore::Load is called to load all cookies. It // delegates to Backend::Load, which posts a Backend::LoadAndNotifyOnDBThread // task to the background runner. This task calls Backend::ChainLoadCookies(), // which repeatedly posts itself to the BG runner to load each eTLD+1's cookies // in separate tasks. When this is complete, Backend::CompleteLoadOnIOThread is // posted to the client runner, which notifies the caller of // SQLitePersistentCookieStore::Load that the load is complete. // // If a priority load request is invoked via SQLitePersistentCookieStore:: // LoadCookiesForKey, it is delegated to Backend::LoadCookiesForKey, which posts // Backend::LoadKeyAndNotifyOnDBThread to the BG runner. That routine loads just // that single domain key (eTLD+1)'s cookies, and posts a Backend:: // CompleteLoadForKeyOnIOThread to the client runner to notify the caller of // SQLitePersistentCookieStore::LoadCookiesForKey that that load is complete. // // Subsequent to loading, mutations may be queued by any thread using // AddCookie, UpdateCookieAccessTime, and DeleteCookie. These are flushed to // disk on the BG runner every 30 seconds, 512 operations, or call to Flush(), // whichever occurs first. class SQLitePersistentCookieStore::Backend : public base::RefCountedThreadSafe { public: Backend( const base::FilePath& path, const scoped_refptr& client_task_runner, const scoped_refptr& background_task_runner, bool restore_old_session_cookies, CookieCryptoDelegate* crypto_delegate) : path_(path), num_pending_(0), initialized_(false), corruption_detected_(false), restore_old_session_cookies_(restore_old_session_cookies), num_cookies_read_(0), client_task_runner_(client_task_runner), background_task_runner_(background_task_runner), num_priority_waiting_(0), total_priority_requests_(0), crypto_(crypto_delegate) {} // Creates or loads the SQLite database. void Load(const LoadedCallback& loaded_callback); // Loads cookies for the domain key (eTLD+1). void LoadCookiesForKey(const std::string& domain, const LoadedCallback& loaded_callback); // Steps through all results of |smt|, makes a cookie from each, and adds the // cookie to |cookies|. Returns true if everything loaded successfully. // Always updates |num_cookies_read_|. bool MakeCookiesFromSQLStatement( std::vector>* cookies, sql::Statement* statement); // Batch a cookie addition. void AddCookie(const CanonicalCookie& cc); // Batch a cookie access time update. void UpdateCookieAccessTime(const CanonicalCookie& cc); // Batch a cookie deletion. void DeleteCookie(const CanonicalCookie& cc); // Sets callback to run at the beginning of Commit. void SetBeforeFlushCallback(base::RepeatingClosure callback); // Commit pending operations as soon as possible. void Flush(base::OnceClosure callback); // Commit any pending operations and close the database. This must be called // before the object is destructed. void Close(const base::Closure& callback); // Post background delete of all cookies that match |cookies|. void DeleteAllInList(const std::list& cookies); private: friend class base::RefCountedThreadSafe; // You should call Close() before destructing this object. ~Backend() { DCHECK(!db_.get()) << "Close should have already been called."; DCHECK_EQ(0u, num_pending_); DCHECK(pending_.empty()); } // Database upgrade statements. bool EnsureDatabaseVersion(); class PendingOperation { public: enum OperationType { COOKIE_ADD, COOKIE_UPDATEACCESS, COOKIE_DELETE, }; PendingOperation(OperationType op, const CanonicalCookie& cc) : op_(op), cc_(cc) {} OperationType op() const { return op_; } const CanonicalCookie& cc() const { return cc_; } private: OperationType op_; CanonicalCookie cc_; }; private: // Creates or loads the SQLite database on background runner. void LoadAndNotifyInBackground(const LoadedCallback& loaded_callback, const base::Time& posted_at); // Loads cookies for the domain key (eTLD+1) on background runner. void LoadKeyAndNotifyInBackground(const std::string& domains, const LoadedCallback& loaded_callback, const base::Time& posted_at); // Notifies the CookieMonster when loading completes for a specific domain key // or for all domain keys. Triggers the callback and passes it all cookies // that have been loaded from DB since last IO notification. void Notify(const LoadedCallback& loaded_callback, bool load_success); // Flushes (Commits) pending operations on the background runner, and invokes // |callback| on the client thread when done. void FlushAndNotifyInBackground(base::OnceClosure callback); // Sends notification when the entire store is loaded, and reports metrics // for the total time to load and aggregated results from any priority loads // that occurred. void CompleteLoadInForeground(const LoadedCallback& loaded_callback, bool load_success); // Sends notification when a single priority load completes. Updates priority // load metric data. The data is sent only after the final load completes. void CompleteLoadForKeyInForeground(const LoadedCallback& loaded_callback, bool load_success, const base::Time& requested_at); // Sends all metrics, including posting a ReportMetricsInBackground task. // Called after all priority and regular loading is complete. void ReportMetrics(); // Sends background-runner owned metrics (i.e., the combined duration of all // BG-runner tasks). void ReportMetricsInBackground(); // Initialize the data base. bool InitializeDatabase(); // Loads cookies for the next domain key from the DB, then either reschedules // itself or schedules the provided callback to run on the client runner (if // all domains are loaded). void ChainLoadCookies(const LoadedCallback& loaded_callback); // Load all cookies for a set of domains/hosts. The error recovery code // assumes |key| includes all related domains within an eTLD + 1. bool LoadCookiesForDomains(const std::set& key); // Batch a cookie operation (add or delete) void BatchOperation(PendingOperation::OperationType op, const CanonicalCookie& cc); // Commit our pending operations to the database. void Commit(); // Close() executed on the background runner. void InternalBackgroundClose(const base::Closure& callback); void DeleteSessionCookiesOnStartup(); void BackgroundDeleteAllInList(const std::list& cookies); void DatabaseErrorCallback(int error, sql::Statement* stmt); void KillDatabase(); void PostBackgroundTask(const base::Location& origin, base::OnceClosure task); void PostClientTask(const base::Location& origin, base::OnceClosure task); // Shared code between the different load strategies to be used after all // cookies have been loaded. void FinishedLoadingCookies(const LoadedCallback& loaded_callback, bool success); const base::FilePath path_; std::unique_ptr db_; sql::MetaTable meta_table_; typedef std::list> PendingOperationsList; PendingOperationsList pending_; PendingOperationsList::size_type num_pending_; // Guard |cookies_|, |pending_|, |num_pending_|. base::Lock lock_; // Temporary buffer for cookies loaded from DB. Accumulates cookies to reduce // the number of messages sent to the client runner. Sent back in response to // individual load requests for domain keys or when all loading completes. std::vector> cookies_; // Map of domain keys(eTLD+1) to domains/hosts that are to be loaded from DB. std::map> keys_to_load_; // Indicates if DB has been initialized. bool initialized_; // Indicates if the kill-database callback has been scheduled. bool corruption_detected_; // If false, we should filter out session cookies when reading the DB. bool restore_old_session_cookies_; // The cumulative time spent loading the cookies on the background runner. // Incremented and reported from the background runner. base::TimeDelta cookie_load_duration_; // The total number of cookies read. Incremented and reported on the // background runner. Includes those that were malformed, not decrypted // correctly, etc. int num_cookies_read_; scoped_refptr client_task_runner_; scoped_refptr background_task_runner_; // Guards the following metrics-related properties (only accessed when // starting/completing priority loads or completing the total load). base::Lock metrics_lock_; int num_priority_waiting_; // The total number of priority requests. int total_priority_requests_; // The time when |num_priority_waiting_| incremented to 1. base::Time current_priority_wait_start_; // The cumulative duration of time when |num_priority_waiting_| was greater // than 1. base::TimeDelta priority_wait_duration_; // Class with functions that do cryptographic operations (for protecting // cookies stored persistently). // // Not owned. CookieCryptoDelegate* crypto_; // Callback to run before Commit. base::RepeatingClosure before_flush_callback_; // Guards |before_flush_callback_|. base::Lock before_flush_callback_lock_; DISALLOW_COPY_AND_ASSIGN(Backend); }; namespace { // Version number of the database. // // Version 10 - 2018/02/13 - https://chromium-review.googlesource.com/906675 // Version 9 - 2015/04/17 - https://codereview.chromium.org/1083623003 // Version 8 - 2015/02/23 - https://codereview.chromium.org/876973003 // Version 7 - 2013/12/16 - https://codereview.chromium.org/24734007 // Version 6 - 2013/04/23 - https://codereview.chromium.org/14208017 // Version 5 - 2011/12/05 - https://codereview.chromium.org/8533013 // Version 4 - 2009/09/01 - https://codereview.chromium.org/183021 // // Version 10 removes the uniqueness constraint on the creation time (which // was not propagated up the stack and caused problems in // http://crbug.com/800414 and others). It replaces that constraint by a // constraint on (name, domain, path), which is spec-compliant (see // https://tools.ietf.org/html/rfc6265#section-5.3 step 11). Those fields // can then be used in place of the creation time for updating access // time and deleting cookies. // Version 10 also marks all booleans in the store with an "is_" prefix // to indicated their booleanness, as SQLite has no such concept. // // Version 9 adds a partial index to track non-persistent cookies. // Non-persistent cookies sometimes need to be deleted on startup. There are // frequently few or no non-persistent cookies, so the partial index allows the // deletion to be sped up or skipped, without having to page in the DB. // // Version 8 adds "first-party only" cookies. // // Version 7 adds encrypted values. Old values will continue to be used but // all new values written will be encrypted on selected operating systems. New // records read by old clients will simply get an empty cookie value while old // records read by new clients will continue to operate with the unencrypted // version. New and old clients alike will always write/update records with // what they support. // // Version 6 adds cookie priorities. This allows developers to influence the // order in which cookies are evicted in order to meet domain cookie limits. // // Version 5 adds the columns has_expires and is_persistent, so that the // database can store session cookies as well as persistent cookies. Databases // of version 5 are incompatible with older versions of code. If a database of // version 5 is read by older code, session cookies will be treated as normal // cookies. Currently, these fields are written, but not read anymore. // // In version 4, we migrated the time epoch. If you open the DB with an older // version on Mac or Linux, the times will look wonky, but the file will likely // be usable. On Windows version 3 and 4 are the same. // // Version 3 updated the database to include the last access time, so we can // expire them in decreasing order of use when we've reached the maximum // number of cookies. const int kCurrentVersionNumber = 10; const int kCompatibleVersionNumber = 10; // Possible values for the 'priority' column. enum DBCookiePriority { kCookiePriorityLow = 0, kCookiePriorityMedium = 1, kCookiePriorityHigh = 2, }; DBCookiePriority CookiePriorityToDBCookiePriority(CookiePriority value) { switch (value) { case COOKIE_PRIORITY_LOW: return kCookiePriorityLow; case COOKIE_PRIORITY_MEDIUM: return kCookiePriorityMedium; case COOKIE_PRIORITY_HIGH: return kCookiePriorityHigh; } NOTREACHED(); return kCookiePriorityMedium; } CookiePriority DBCookiePriorityToCookiePriority(DBCookiePriority value) { switch (value) { case kCookiePriorityLow: return COOKIE_PRIORITY_LOW; case kCookiePriorityMedium: return COOKIE_PRIORITY_MEDIUM; case kCookiePriorityHigh: return COOKIE_PRIORITY_HIGH; } NOTREACHED(); return COOKIE_PRIORITY_DEFAULT; } // Possible values for the 'samesite' column enum DBCookieSameSite { kCookieSameSiteNoRestriction = 0, kCookieSameSiteLax = 1, kCookieSameSiteStrict = 2, }; DBCookieSameSite CookieSameSiteToDBCookieSameSite(CookieSameSite value) { switch (value) { case CookieSameSite::NO_RESTRICTION: return kCookieSameSiteNoRestriction; case CookieSameSite::LAX_MODE: return kCookieSameSiteLax; case CookieSameSite::STRICT_MODE: return kCookieSameSiteStrict; } NOTREACHED(); return kCookieSameSiteNoRestriction; } CookieSameSite DBCookieSameSiteToCookieSameSite(DBCookieSameSite value) { switch (value) { case kCookieSameSiteNoRestriction: return CookieSameSite::NO_RESTRICTION; case kCookieSameSiteLax: return CookieSameSite::LAX_MODE; case kCookieSameSiteStrict: return CookieSameSite::STRICT_MODE; } NOTREACHED(); return CookieSameSite::DEFAULT_MODE; } // Increments a specified TimeDelta by the duration between this object's // constructor and destructor. Not thread safe. Multiple instances may be // created with the same delta instance as long as their lifetimes are nested. // The shortest lived instances have no impact. class IncrementTimeDelta { public: explicit IncrementTimeDelta(base::TimeDelta* delta) : delta_(delta), original_value_(*delta), start_(base::Time::Now()) {} ~IncrementTimeDelta() { *delta_ = original_value_ + base::Time::Now() - start_; } private: base::TimeDelta* delta_; base::TimeDelta original_value_; base::Time start_; DISALLOW_COPY_AND_ASSIGN(IncrementTimeDelta); }; // Initializes the cookies table, returning true on success. // The table cannot exist when calling this function. bool CreateV10Schema(sql::Connection* db) { DCHECK(!db->DoesTableExist("cookies")); std::string stmt(base::StringPrintf( "CREATE TABLE cookies (" "creation_utc INTEGER NOT NULL," "host_key TEXT NOT NULL," "name TEXT NOT NULL," "value TEXT NOT NULL," "path TEXT NOT NULL," "expires_utc INTEGER NOT NULL," "is_secure INTEGER NOT NULL," "is_httponly INTEGER NOT NULL," "last_access_utc INTEGER NOT NULL, " "has_expires INTEGER NOT NULL DEFAULT 1, " "is_persistent INTEGER NOT NULL DEFAULT 1," "priority INTEGER NOT NULL DEFAULT %d," "encrypted_value BLOB DEFAULT ''," "firstpartyonly INTEGER NOT NULL DEFAULT %d," "UNIQUE (host_key, name, path))", CookiePriorityToDBCookiePriority(COOKIE_PRIORITY_DEFAULT), CookieSameSiteToDBCookieSameSite(CookieSameSite::DEFAULT_MODE))); if (!db->Execute(stmt.c_str())) return false; return true; } bool InitTable(sql::Connection* db) { if (db->DoesTableExist("cookies")) return true; return CreateV10Schema(db); } } // namespace void SQLitePersistentCookieStore::Backend::Load( const LoadedCallback& loaded_callback) { PostBackgroundTask(FROM_HERE, base::Bind(&Backend::LoadAndNotifyInBackground, this, loaded_callback, base::Time::Now())); } void SQLitePersistentCookieStore::Backend::LoadCookiesForKey( const std::string& key, const LoadedCallback& loaded_callback) { { base::AutoLock locked(metrics_lock_); if (num_priority_waiting_ == 0) current_priority_wait_start_ = base::Time::Now(); num_priority_waiting_++; total_priority_requests_++; } PostBackgroundTask( FROM_HERE, base::Bind(&Backend::LoadKeyAndNotifyInBackground, this, key, loaded_callback, base::Time::Now())); } void SQLitePersistentCookieStore::Backend::LoadAndNotifyInBackground( const LoadedCallback& loaded_callback, const base::Time& posted_at) { DCHECK(background_task_runner_->RunsTasksInCurrentSequence()); IncrementTimeDelta increment(&cookie_load_duration_); UMA_HISTOGRAM_CUSTOM_TIMES("Cookie.TimeLoadDBQueueWait", base::Time::Now() - posted_at, base::TimeDelta::FromMilliseconds(1), base::TimeDelta::FromMinutes(1), 50); if (!InitializeDatabase()) { PostClientTask(FROM_HERE, base::Bind(&Backend::CompleteLoadInForeground, this, loaded_callback, false)); } else { ChainLoadCookies(loaded_callback); } } void SQLitePersistentCookieStore::Backend::LoadKeyAndNotifyInBackground( const std::string& key, const LoadedCallback& loaded_callback, const base::Time& posted_at) { DCHECK(background_task_runner_->RunsTasksInCurrentSequence()); IncrementTimeDelta increment(&cookie_load_duration_); UMA_HISTOGRAM_CUSTOM_TIMES("Cookie.TimeKeyLoadDBQueueWait", base::Time::Now() - posted_at, base::TimeDelta::FromMilliseconds(1), base::TimeDelta::FromMinutes(1), 50); bool success = false; if (InitializeDatabase()) { std::map>::iterator it = keys_to_load_.find(key); if (it != keys_to_load_.end()) { success = LoadCookiesForDomains(it->second); keys_to_load_.erase(it); } else { success = true; } } PostClientTask( FROM_HERE, base::Bind( &SQLitePersistentCookieStore::Backend::CompleteLoadForKeyInForeground, this, loaded_callback, success, posted_at)); } void SQLitePersistentCookieStore::Backend::FlushAndNotifyInBackground( base::OnceClosure callback) { Commit(); if (!callback.is_null()) PostClientTask(FROM_HERE, std::move(callback)); } void SQLitePersistentCookieStore::Backend::CompleteLoadForKeyInForeground( const LoadedCallback& loaded_callback, bool load_success, const ::Time& requested_at) { DCHECK(client_task_runner_->RunsTasksInCurrentSequence()); UMA_HISTOGRAM_CUSTOM_TIMES("Cookie.TimeKeyLoadTotalWait", base::Time::Now() - requested_at, base::TimeDelta::FromMilliseconds(1), base::TimeDelta::FromMinutes(1), 50); Notify(loaded_callback, load_success); { base::AutoLock locked(metrics_lock_); num_priority_waiting_--; if (num_priority_waiting_ == 0) { priority_wait_duration_ += base::Time::Now() - current_priority_wait_start_; } } } void SQLitePersistentCookieStore::Backend::ReportMetricsInBackground() { UMA_HISTOGRAM_CUSTOM_TIMES("Cookie.TimeLoad", cookie_load_duration_, base::TimeDelta::FromMilliseconds(1), base::TimeDelta::FromMinutes(1), 50); } void SQLitePersistentCookieStore::Backend::ReportMetrics() { PostBackgroundTask( FROM_HERE, base::Bind( &SQLitePersistentCookieStore::Backend::ReportMetricsInBackground, this)); { base::AutoLock locked(metrics_lock_); UMA_HISTOGRAM_CUSTOM_TIMES("Cookie.PriorityBlockingTime", priority_wait_duration_, base::TimeDelta::FromMilliseconds(1), base::TimeDelta::FromMinutes(1), 50); UMA_HISTOGRAM_COUNTS_100("Cookie.PriorityLoadCount", total_priority_requests_); UMA_HISTOGRAM_COUNTS_10000("Cookie.NumberOfLoadedCookies", num_cookies_read_); } } void SQLitePersistentCookieStore::Backend::CompleteLoadInForeground( const LoadedCallback& loaded_callback, bool load_success) { Notify(loaded_callback, load_success); if (load_success) ReportMetrics(); } void SQLitePersistentCookieStore::Backend::Notify( const LoadedCallback& loaded_callback, bool load_success) { DCHECK(client_task_runner_->RunsTasksInCurrentSequence()); std::vector> cookies; { base::AutoLock locked(lock_); cookies.swap(cookies_); } loaded_callback.Run(std::move(cookies)); } bool SQLitePersistentCookieStore::Backend::InitializeDatabase() { DCHECK(background_task_runner_->RunsTasksInCurrentSequence()); if (initialized_ || corruption_detected_) { // Return false if we were previously initialized but the DB has since been // closed, or if corruption caused a database reset during initialization. return db_ != NULL; } base::Time start = base::Time::Now(); const base::FilePath dir = path_.DirName(); if (!base::PathExists(dir) && !base::CreateDirectory(dir)) { return false; } int64_t db_size = 0; if (base::GetFileSize(path_, &db_size)) UMA_HISTOGRAM_COUNTS_1M("Cookie.DBSizeInKB", db_size / 1024); db_.reset(new sql::Connection); db_->set_histogram_tag("Cookie"); // Unretained to avoid a ref loop with |db_|. db_->set_error_callback( base::Bind(&SQLitePersistentCookieStore::Backend::DatabaseErrorCallback, base::Unretained(this))); if (!db_->Open(path_)) { DLOG(ERROR) << "Unable to open cookie DB."; RecordCookieLoadProblem(COOKIE_LOAD_PROBLEM_OPEN_DB); if (corruption_detected_) db_->Raze(); meta_table_.Reset(); db_.reset(); return false; } if (!EnsureDatabaseVersion() || !InitTable(db_.get())) { DLOG(ERROR) << "Unable to open cookie DB."; RecordCookieLoadProblem(COOKIE_LOAD_PROBLEM_OPEN_DB); if (corruption_detected_) db_->Raze(); meta_table_.Reset(); db_.reset(); return false; } UMA_HISTOGRAM_CUSTOM_TIMES("Cookie.TimeInitializeDB", base::Time::Now() - start, base::TimeDelta::FromMilliseconds(1), base::TimeDelta::FromMinutes(1), 50); start = base::Time::Now(); // Retrieve all the domains sql::Statement smt( db_->GetUniqueStatement("SELECT DISTINCT host_key FROM cookies")); if (!smt.is_valid()) { if (corruption_detected_) db_->Raze(); meta_table_.Reset(); db_.reset(); return false; } std::vector host_keys; while (smt.Step()) host_keys.push_back(smt.ColumnString(0)); UMA_HISTOGRAM_CUSTOM_TIMES("Cookie.TimeLoadDomains", base::Time::Now() - start, base::TimeDelta::FromMilliseconds(1), base::TimeDelta::FromMinutes(1), 50); base::Time start_parse = base::Time::Now(); // Build a map of domain keys (always eTLD+1) to domains. for (size_t idx = 0; idx < host_keys.size(); ++idx) { const std::string& domain = host_keys[idx]; std::string key = CookieMonster::GetKey(domain); keys_to_load_[key].insert(domain); } UMA_HISTOGRAM_CUSTOM_TIMES("Cookie.TimeParseDomains", base::Time::Now() - start_parse, base::TimeDelta::FromMilliseconds(1), base::TimeDelta::FromMinutes(1), 50); UMA_HISTOGRAM_CUSTOM_TIMES("Cookie.TimeInitializeDomainMap", base::Time::Now() - start, base::TimeDelta::FromMilliseconds(1), base::TimeDelta::FromMinutes(1), 50); initialized_ = true; if (!restore_old_session_cookies_) DeleteSessionCookiesOnStartup(); return true; } void SQLitePersistentCookieStore::Backend::ChainLoadCookies( const LoadedCallback& loaded_callback) { DCHECK(background_task_runner_->RunsTasksInCurrentSequence()); IncrementTimeDelta increment(&cookie_load_duration_); bool load_success = true; if (!db_) { // Close() has been called on this store. load_success = false; } else if (keys_to_load_.size() > 0) { // Load cookies for the first domain key. std::map>::iterator it = keys_to_load_.begin(); load_success = LoadCookiesForDomains(it->second); keys_to_load_.erase(it); } // If load is successful and there are more domain keys to be loaded, // then post a background task to continue chain-load; // Otherwise notify on client runner. if (load_success && keys_to_load_.size() > 0) { bool success = background_task_runner_->PostDelayedTask( FROM_HERE, base::Bind(&Backend::ChainLoadCookies, this, loaded_callback), base::TimeDelta::FromMilliseconds(kLoadDelayMilliseconds)); if (!success) { LOG(WARNING) << "Failed to post task from " << FROM_HERE.ToString() << " to background_task_runner_."; } } else { FinishedLoadingCookies(loaded_callback, load_success); } } bool SQLitePersistentCookieStore::Backend::LoadCookiesForDomains( const std::set& domains) { DCHECK(background_task_runner_->RunsTasksInCurrentSequence()); sql::Statement smt, del_smt; if (restore_old_session_cookies_) { smt.Assign(db_->GetCachedStatement( SQL_FROM_HERE, "SELECT creation_utc, host_key, name, value, encrypted_value, path, " "expires_utc, is_secure, is_httponly, firstpartyonly, " "last_access_utc, has_expires, is_persistent, priority " "FROM cookies WHERE host_key = ?")); } else { smt.Assign(db_->GetCachedStatement( SQL_FROM_HERE, "SELECT creation_utc, host_key, name, value, encrypted_value, path, " "expires_utc, is_secure, is_httponly, firstpartyonly, last_access_utc, " "has_expires, is_persistent, priority FROM cookies WHERE host_key = ? " "AND is_persistent = 1")); } del_smt.Assign(db_->GetCachedStatement( SQL_FROM_HERE, "DELETE FROM cookies WHERE host_key = ?")); if (!smt.is_valid() || !del_smt.is_valid()) { del_smt.Clear(); smt.Clear(); // Disconnect smt_ref from db_. meta_table_.Reset(); db_.reset(); return false; } std::vector> cookies; std::set::const_iterator it = domains.begin(); bool ok = true; for (; it != domains.end() && ok; ++it) { smt.BindString(0, *it); ok = MakeCookiesFromSQLStatement(&cookies, &smt); smt.Reset(true); } if (ok) { base::AutoLock locked(lock_); std::move(cookies.begin(), cookies.end(), std::back_inserter(cookies_)); } else { // There were some cookies that were in database but could not be loaded // and handed over to CookieMonster. This is trouble since it means that // if some website tries to send them again, CookieMonster won't know to // issue a delete, and then the addition would violate the uniqueness // constraints and not go through. // // For data consistency, we drop the entire eTLD group. for (const std::string& domain : domains) { del_smt.BindString(0, domain); if (!del_smt.Run()) { // TODO(morlovich): Is something more drastic called for here? RecordCookieLoadProblem(COOKIE_LOAD_PROBLEM_RECOVERY_FAILED); } del_smt.Reset(true); } } return true; } bool SQLitePersistentCookieStore::Backend::MakeCookiesFromSQLStatement( std::vector>* cookies, sql::Statement* statement) { DCHECK(background_task_runner_->RunsTasksInCurrentSequence()); sql::Statement& smt = *statement; bool ok = true; while (smt.Step()) { ++num_cookies_read_; std::string value; std::string encrypted_value = smt.ColumnString(4); if (!encrypted_value.empty() && crypto_) { scoped_refptr timeout_tracker = TimeoutTracker::Begin(client_task_runner_); bool decrypt_ok = crypto_->DecryptString(encrypted_value, &value); timeout_tracker->End(); if (!decrypt_ok) { RecordCookieLoadProblem(COOKIE_LOAD_PROBLEM_DECRYPT_FAILED); ok = false; continue; } } else { value = smt.ColumnString(3); } std::unique_ptr cc(std::make_unique( smt.ColumnString(2), // name value, // value smt.ColumnString(1), // domain smt.ColumnString(5), // path Time::FromInternalValue(smt.ColumnInt64(0)), // creation_utc Time::FromInternalValue(smt.ColumnInt64(6)), // expires_utc Time::FromInternalValue(smt.ColumnInt64(10)), // last_access_utc smt.ColumnInt(7) != 0, // secure smt.ColumnInt(8) != 0, // http_only DBCookieSameSiteToCookieSameSite( static_cast(smt.ColumnInt(9))), // samesite DBCookiePriorityToCookiePriority( static_cast(smt.ColumnInt(13))))); // priority DLOG_IF(WARNING, cc->CreationDate() > Time::Now()) << L"CreationDate too recent"; if (cc->IsCanonical()) { cookies->push_back(std::move(cc)); } else { RecordCookieLoadProblem(COOKIE_LOAD_PROBLEM_NON_CANONICAL); ok = false; } } return ok; } bool SQLitePersistentCookieStore::Backend::EnsureDatabaseVersion() { // Version check. if (!meta_table_.Init(db_.get(), kCurrentVersionNumber, kCompatibleVersionNumber)) { return false; } if (meta_table_.GetCompatibleVersionNumber() > kCurrentVersionNumber) { LOG(WARNING) << "Cookie database is too new."; return false; } int cur_version = meta_table_.GetVersionNumber(); if (cur_version == 2) { sql::Transaction transaction(db_.get()); if (!transaction.Begin()) return false; if (!db_->Execute( "ALTER TABLE cookies ADD COLUMN last_access_utc " "INTEGER DEFAULT 0") || !db_->Execute("UPDATE cookies SET last_access_utc = creation_utc")) { LOG(WARNING) << "Unable to update cookie database to version 3."; return false; } ++cur_version; meta_table_.SetVersionNumber(cur_version); meta_table_.SetCompatibleVersionNumber( std::min(cur_version, kCompatibleVersionNumber)); transaction.Commit(); } if (cur_version == 3) { // The time epoch changed for Mac & Linux in this version to match Windows. // This patch came after the main epoch change happened, so some // developers have "good" times for cookies added by the more recent // versions. So we have to be careful to only update times that are under // the old system (which will appear to be from before 1970 in the new // system). The magic number used below is 1970 in our time units. sql::Transaction transaction(db_.get()); transaction.Begin(); #if !defined(OS_WIN) ignore_result(db_->Execute( "UPDATE cookies " "SET creation_utc = creation_utc + 11644473600000000 " "WHERE rowid IN " "(SELECT rowid FROM cookies WHERE " "creation_utc > 0 AND creation_utc < 11644473600000000)")); ignore_result(db_->Execute( "UPDATE cookies " "SET expires_utc = expires_utc + 11644473600000000 " "WHERE rowid IN " "(SELECT rowid FROM cookies WHERE " "expires_utc > 0 AND expires_utc < 11644473600000000)")); ignore_result(db_->Execute( "UPDATE cookies " "SET last_access_utc = last_access_utc + 11644473600000000 " "WHERE rowid IN " "(SELECT rowid FROM cookies WHERE " "last_access_utc > 0 AND last_access_utc < 11644473600000000)")); #endif ++cur_version; meta_table_.SetVersionNumber(cur_version); transaction.Commit(); } if (cur_version == 4) { const base::TimeTicks start_time = base::TimeTicks::Now(); sql::Transaction transaction(db_.get()); if (!transaction.Begin()) return false; if (!db_->Execute( "ALTER TABLE cookies " "ADD COLUMN has_expires INTEGER DEFAULT 1") || !db_->Execute( "ALTER TABLE cookies " "ADD COLUMN persistent INTEGER DEFAULT 1")) { LOG(WARNING) << "Unable to update cookie database to version 5."; return false; } ++cur_version; meta_table_.SetVersionNumber(cur_version); meta_table_.SetCompatibleVersionNumber( std::min(cur_version, kCompatibleVersionNumber)); transaction.Commit(); UMA_HISTOGRAM_TIMES("Cookie.TimeDatabaseMigrationToV5", base::TimeTicks::Now() - start_time); } if (cur_version == 5) { const base::TimeTicks start_time = base::TimeTicks::Now(); sql::Transaction transaction(db_.get()); if (!transaction.Begin()) return false; // Alter the table to add the priority column with a default value. std::string stmt(base::StringPrintf( "ALTER TABLE cookies ADD COLUMN priority INTEGER DEFAULT %d", CookiePriorityToDBCookiePriority(COOKIE_PRIORITY_DEFAULT))); if (!db_->Execute(stmt.c_str())) { LOG(WARNING) << "Unable to update cookie database to version 6."; return false; } ++cur_version; meta_table_.SetVersionNumber(cur_version); meta_table_.SetCompatibleVersionNumber( std::min(cur_version, kCompatibleVersionNumber)); transaction.Commit(); UMA_HISTOGRAM_TIMES("Cookie.TimeDatabaseMigrationToV6", base::TimeTicks::Now() - start_time); } if (cur_version == 6) { const base::TimeTicks start_time = base::TimeTicks::Now(); sql::Transaction transaction(db_.get()); if (!transaction.Begin()) return false; // Alter the table to add empty "encrypted value" column. if (!db_->Execute( "ALTER TABLE cookies " "ADD COLUMN encrypted_value BLOB DEFAULT ''")) { LOG(WARNING) << "Unable to update cookie database to version 7."; return false; } ++cur_version; meta_table_.SetVersionNumber(cur_version); meta_table_.SetCompatibleVersionNumber( std::min(cur_version, kCompatibleVersionNumber)); transaction.Commit(); UMA_HISTOGRAM_TIMES("Cookie.TimeDatabaseMigrationToV7", base::TimeTicks::Now() - start_time); } if (cur_version == 7) { const base::TimeTicks start_time = base::TimeTicks::Now(); sql::Transaction transaction(db_.get()); if (!transaction.Begin()) return false; // Alter the table to add a 'firstpartyonly' column. if (!db_->Execute( "ALTER TABLE cookies " "ADD COLUMN firstpartyonly INTEGER DEFAULT 0")) { LOG(WARNING) << "Unable to update cookie database to version 8."; return false; } ++cur_version; meta_table_.SetVersionNumber(cur_version); meta_table_.SetCompatibleVersionNumber( std::min(cur_version, kCompatibleVersionNumber)); transaction.Commit(); UMA_HISTOGRAM_TIMES("Cookie.TimeDatabaseMigrationToV8", base::TimeTicks::Now() - start_time); } if (cur_version == 8) { const base::TimeTicks start_time = base::TimeTicks::Now(); sql::Transaction transaction(db_.get()); if (!transaction.Begin()) return false; if (!db_->Execute("DROP INDEX IF EXISTS cookie_times")) { LOG(WARNING) << "Unable to drop table cookie_times in update to version 9."; return false; } if (!db_->Execute( "CREATE INDEX IF NOT EXISTS domain ON cookies(host_key)")) { LOG(WARNING) << "Unable to create index domain in update to version 9."; return false; } if (!db_->Execute( "CREATE INDEX IF NOT EXISTS is_transient ON cookies(persistent) " "where persistent != 1")) { LOG(WARNING) << "Unable to create index is_transient in update to version 9."; return false; } ++cur_version; meta_table_.SetVersionNumber(cur_version); meta_table_.SetCompatibleVersionNumber( std::min(cur_version, kCompatibleVersionNumber)); transaction.Commit(); UMA_HISTOGRAM_TIMES("Cookie.TimeDatabaseMigrationToV9", base::TimeTicks::Now() - start_time); } if (cur_version == 9) { const base::TimeTicks start_time = base::TimeTicks::Now(); sql::Transaction transaction(db_.get()); if (!transaction.Begin()) return false; if (!db_->Execute("ALTER TABLE cookies RENAME TO cookies_old")) return false; if (!db_->Execute("DROP INDEX IF EXISTS domain")) return false; if (!db_->Execute("DROP INDEX IF EXISTS is_transient")) return false; if (!CreateV10Schema(db_.get())) { // Not clear what good a false return here will do since the calling // code will just init the table. // TODO(rdsmith): Also, wait, nothing drops the old table and // InitTable() just returns true if the table exists, so if // EnsureDatabaseVersion() fails, initting the table won't do any // further good. Fix? return false; } // If any cookies violate the new uniqueness constraints (no two // cookies with the same (name, domain, path)) erase the cookie store. // That "shouldn't happen", which means probably not too many users' // cookie stores will have it. // The choice to drop rather than pick one of the cookies randomly is // because it is expected that servers will be able to deal with a known // state (no cookies == first visit), and there may be cookie values they // may not be able to deal with. if (!db_->Execute( "INSERT OR FAIL INTO cookies " "(creation_utc, host_key, name, value, path, expires_utc, " "is_secure, is_httponly, last_access_utc, has_expires, " "is_persistent, priority, encrypted_value, firstpartyonly) " "SELECT creation_utc, host_key, name, value, path, expires_utc, " " secure, httponly, last_access_utc, has_expires, " " persistent, priority, encrypted_value, firstpartyonly " "FROM cookies_old")) { // The old database had duplicate cookies in a way that violates // the spec. Treat that as DB corruption and start with a clean slate. if (!db_->Execute("DELETE FROM COOKIES;")) return false; } if (!db_->Execute("DROP TABLE cookies_old")) return false; ++cur_version; meta_table_.SetVersionNumber(cur_version); meta_table_.SetCompatibleVersionNumber( std::min(cur_version, kCompatibleVersionNumber)); transaction.Commit(); UMA_HISTOGRAM_TIMES("Cookie.TimeDatabaseMigrationToV10", base::TimeTicks::Now() - start_time); } // Put future migration cases here. if (cur_version < kCurrentVersionNumber) { UMA_HISTOGRAM_COUNTS_100("Cookie.CorruptMetaTable", 1); meta_table_.Reset(); db_.reset(new sql::Connection); if (!sql::Connection::Delete(path_) || !db_->Open(path_) || !meta_table_.Init(db_.get(), kCurrentVersionNumber, kCompatibleVersionNumber)) { UMA_HISTOGRAM_COUNTS_100("Cookie.CorruptMetaTableRecoveryFailed", 1); NOTREACHED() << "Unable to reset the cookie DB."; meta_table_.Reset(); db_.reset(); return false; } } return true; } void SQLitePersistentCookieStore::Backend::AddCookie( const CanonicalCookie& cc) { BatchOperation(PendingOperation::COOKIE_ADD, cc); } void SQLitePersistentCookieStore::Backend::UpdateCookieAccessTime( const CanonicalCookie& cc) { BatchOperation(PendingOperation::COOKIE_UPDATEACCESS, cc); } void SQLitePersistentCookieStore::Backend::DeleteCookie( const CanonicalCookie& cc) { BatchOperation(PendingOperation::COOKIE_DELETE, cc); } void SQLitePersistentCookieStore::Backend::BatchOperation( PendingOperation::OperationType op, const CanonicalCookie& cc) { // Commit every 30 seconds. static const int kCommitIntervalMs = 30 * 1000; // Commit right away if we have more than 512 outstanding operations. static const size_t kCommitAfterBatchSize = 512; DCHECK(!background_task_runner_->RunsTasksInCurrentSequence()); // We do a full copy of the cookie here, and hopefully just here. std::unique_ptr po(new PendingOperation(op, cc)); PendingOperationsList::size_type num_pending; { base::AutoLock locked(lock_); pending_.push_back(std::move(po)); num_pending = ++num_pending_; } if (num_pending == 1) { // We've gotten our first entry for this batch, fire off the timer. if (!background_task_runner_->PostDelayedTask( FROM_HERE, base::Bind(&Backend::Commit, this), base::TimeDelta::FromMilliseconds(kCommitIntervalMs))) { NOTREACHED() << "background_task_runner_ is not running."; } } else if (num_pending == kCommitAfterBatchSize) { // We've reached a big enough batch, fire off a commit now. PostBackgroundTask(FROM_HERE, base::Bind(&Backend::Commit, this)); } } void SQLitePersistentCookieStore::Backend::Commit() { DCHECK(background_task_runner_->RunsTasksInCurrentSequence()); { base::AutoLock locked(before_flush_callback_lock_); if (!before_flush_callback_.is_null()) before_flush_callback_.Run(); } PendingOperationsList ops; { base::AutoLock locked(lock_); pending_.swap(ops); num_pending_ = 0; } // Maybe an old timer fired or we are already Close()'ed. if (!db_.get() || ops.empty()) return; sql::Statement add_smt(db_->GetCachedStatement( SQL_FROM_HERE, "INSERT INTO cookies (creation_utc, host_key, name, value, " "encrypted_value, path, expires_utc, is_secure, is_httponly, " "firstpartyonly, last_access_utc, has_expires, is_persistent, priority) " "VALUES (?,?,?,?,?,?,?,?,?,?,?,?,?,?)")); if (!add_smt.is_valid()) return; sql::Statement update_access_smt( db_->GetCachedStatement(SQL_FROM_HERE, "UPDATE cookies SET last_access_utc=? WHERE " "name=? AND host_key=? AND path=?")); if (!update_access_smt.is_valid()) return; sql::Statement del_smt( db_->GetCachedStatement(SQL_FROM_HERE, "DELETE FROM cookies WHERE " "name=? AND host_key=? AND path=?")); if (!del_smt.is_valid()) return; sql::Transaction transaction(db_.get()); if (!transaction.Begin()) return; bool trouble = false; for (PendingOperationsList::iterator it = ops.begin(); it != ops.end(); ++it) { // Free the cookies as we commit them to the database. std::unique_ptr po(std::move(*it)); switch (po->op()) { case PendingOperation::COOKIE_ADD: add_smt.Reset(true); add_smt.BindInt64(0, po->cc().CreationDate().ToInternalValue()); add_smt.BindString(1, po->cc().Domain()); add_smt.BindString(2, po->cc().Name()); if (crypto_ && crypto_->ShouldEncrypt()) { std::string encrypted_value; if (!crypto_->EncryptString(po->cc().Value(), &encrypted_value)) { DLOG(WARNING) << "Could not encrypt a cookie, skipping add."; RecordCookieCommitProblem(COOKIE_COMMIT_PROBLEM_ENCRYPT_FAILED); trouble = true; continue; } add_smt.BindCString(3, ""); // value // BindBlob() immediately makes an internal copy of the data. add_smt.BindBlob(4, encrypted_value.data(), static_cast(encrypted_value.length())); } else { add_smt.BindString(3, po->cc().Value()); add_smt.BindBlob(4, "", 0); // encrypted_value } add_smt.BindString(5, po->cc().Path()); add_smt.BindInt64(6, po->cc().ExpiryDate().ToInternalValue()); add_smt.BindInt(7, po->cc().IsSecure()); add_smt.BindInt(8, po->cc().IsHttpOnly()); add_smt.BindInt(9, CookieSameSiteToDBCookieSameSite(po->cc().SameSite())); add_smt.BindInt64(10, po->cc().LastAccessDate().ToInternalValue()); add_smt.BindInt(11, po->cc().IsPersistent()); add_smt.BindInt(12, po->cc().IsPersistent()); add_smt.BindInt(13, CookiePriorityToDBCookiePriority(po->cc().Priority())); if (!add_smt.Run()) { DLOG(WARNING) << "Could not add a cookie to the DB."; RecordCookieCommitProblem(COOKIE_COMMIT_PROBLEM_ADD); trouble = true; } break; case PendingOperation::COOKIE_UPDATEACCESS: update_access_smt.Reset(true); update_access_smt.BindInt64( 0, po->cc().LastAccessDate().ToInternalValue()); update_access_smt.BindString(1, po->cc().Name()); update_access_smt.BindString(2, po->cc().Domain()); update_access_smt.BindString(3, po->cc().Path()); if (!update_access_smt.Run()) { DLOG(WARNING) << "Could not update cookie last access time in the DB."; RecordCookieCommitProblem(COOKIE_COMMIT_PROBLEM_UPDATE_ACCESS); trouble = true; } break; case PendingOperation::COOKIE_DELETE: del_smt.Reset(true); del_smt.BindString(0, po->cc().Name()); del_smt.BindString(1, po->cc().Domain()); del_smt.BindString(2, po->cc().Path()); if (!del_smt.Run()) { DLOG(WARNING) << "Could not delete a cookie from the DB."; RecordCookieCommitProblem(COOKIE_COMMIT_PROBLEM_DELETE); trouble = true; } break; default: NOTREACHED(); break; } } bool succeeded = transaction.Commit(); UMA_HISTOGRAM_ENUMERATION("Cookie.BackingStoreUpdateResults", succeeded ? (trouble ? BACKING_STORE_RESULTS_MIXED : BACKING_STORE_RESULTS_SUCCESS) : BACKING_STORE_RESULTS_FAILURE, BACKING_STORE_RESULTS_LAST_ENTRY); } void SQLitePersistentCookieStore::Backend::SetBeforeFlushCallback( base::RepeatingClosure callback) { base::AutoLock locked(before_flush_callback_lock_); before_flush_callback_ = std::move(callback); } void SQLitePersistentCookieStore::Backend::Flush(base::OnceClosure callback) { DCHECK(!background_task_runner_->RunsTasksInCurrentSequence()); PostBackgroundTask(FROM_HERE, base::BindOnce(&Backend::FlushAndNotifyInBackground, this, std::move(callback))); } // Fire off a close message to the background runner. We could still have a // pending commit timer or Load operations holding references on us, but if/when // this fires we will already have been cleaned up and it will be ignored. void SQLitePersistentCookieStore::Backend::Close( const base::Closure& callback) { if (background_task_runner_->RunsTasksInCurrentSequence()) { InternalBackgroundClose(callback); } else { // Must close the backend on the background runner. PostBackgroundTask(FROM_HERE, base::Bind(&Backend::InternalBackgroundClose, this, callback)); } } void SQLitePersistentCookieStore::Backend::InternalBackgroundClose( const base::Closure& callback) { DCHECK(background_task_runner_->RunsTasksInCurrentSequence()); // Commit any pending operations Commit(); meta_table_.Reset(); db_.reset(); // We're clean now. if (!callback.is_null()) callback.Run(); } void SQLitePersistentCookieStore::Backend::DatabaseErrorCallback( int error, sql::Statement* stmt) { DCHECK(background_task_runner_->RunsTasksInCurrentSequence()); if (!sql::IsErrorCatastrophic(error)) return; // TODO(shess): Running KillDatabase() multiple times should be // safe. if (corruption_detected_) return; corruption_detected_ = true; // Don't just do the close/delete here, as we are being called by |db| and // that seems dangerous. // TODO(shess): Consider just calling RazeAndClose() immediately. // db_ may not be safe to reset at this point, but RazeAndClose() // would cause the stack to unwind safely with errors. PostBackgroundTask(FROM_HERE, base::Bind(&Backend::KillDatabase, this)); } void SQLitePersistentCookieStore::Backend::KillDatabase() { DCHECK(background_task_runner_->RunsTasksInCurrentSequence()); if (db_) { // This Backend will now be in-memory only. In a future run we will recreate // the database. Hopefully things go better then! bool success = db_->RazeAndClose(); UMA_HISTOGRAM_BOOLEAN("Cookie.KillDatabaseResult", success); meta_table_.Reset(); db_.reset(); } } void SQLitePersistentCookieStore::Backend::DeleteAllInList( const std::list& cookies) { if (cookies.empty()) return; if (background_task_runner_->RunsTasksInCurrentSequence()) { BackgroundDeleteAllInList(cookies); } else { // Perform deletion on background task runner. PostBackgroundTask( FROM_HERE, base::Bind(&Backend::BackgroundDeleteAllInList, this, cookies)); } } void SQLitePersistentCookieStore::Backend::DeleteSessionCookiesOnStartup() { DCHECK(background_task_runner_->RunsTasksInCurrentSequence()); base::Time start_time = base::Time::Now(); if (!db_->Execute("DELETE FROM cookies WHERE is_persistent != 1")) LOG(WARNING) << "Unable to delete session cookies."; UMA_HISTOGRAM_TIMES("Cookie.Startup.TimeSpentDeletingCookies", base::Time::Now() - start_time); UMA_HISTOGRAM_COUNTS_1M("Cookie.Startup.NumberOfCookiesDeleted", db_->GetLastChangeCount()); } void SQLitePersistentCookieStore::Backend::BackgroundDeleteAllInList( const std::list& cookies) { DCHECK(background_task_runner_->RunsTasksInCurrentSequence()); if (!db_) return; // Force a commit of any pending writes before issuing deletes. // TODO(rohitrao): Remove the need for this Commit() by instead pruning the // list of pending operations. https://crbug.com/486742. Commit(); sql::Statement del_smt(db_->GetCachedStatement( SQL_FROM_HERE, "DELETE FROM cookies WHERE host_key=? AND is_secure=?")); if (!del_smt.is_valid()) { LOG(WARNING) << "Unable to delete cookies on shutdown."; return; } sql::Transaction transaction(db_.get()); if (!transaction.Begin()) { LOG(WARNING) << "Unable to delete cookies on shutdown."; return; } for (const auto& cookie : cookies) { const GURL url(cookie_util::CookieOriginToURL(cookie.first, cookie.second)); if (!url.is_valid()) continue; del_smt.Reset(true); del_smt.BindString(0, cookie.first); del_smt.BindInt(1, cookie.second); if (!del_smt.Run()) NOTREACHED() << "Could not delete a cookie from the DB."; } if (!transaction.Commit()) LOG(WARNING) << "Unable to delete cookies on shutdown."; } void SQLitePersistentCookieStore::Backend::PostBackgroundTask( const base::Location& origin, base::OnceClosure task) { if (!background_task_runner_->PostTask(origin, std::move(task))) { LOG(WARNING) << "Failed to post task from " << origin.ToString() << " to background_task_runner_."; } } void SQLitePersistentCookieStore::Backend::PostClientTask( const base::Location& origin, base::OnceClosure task) { if (!client_task_runner_->PostTask(origin, std::move(task))) { LOG(WARNING) << "Failed to post task from " << origin.ToString() << " to client_task_runner_."; } } void SQLitePersistentCookieStore::Backend::FinishedLoadingCookies( const LoadedCallback& loaded_callback, bool success) { PostClientTask(FROM_HERE, base::Bind(&Backend::CompleteLoadInForeground, this, loaded_callback, success)); } SQLitePersistentCookieStore::SQLitePersistentCookieStore( const base::FilePath& path, const scoped_refptr& client_task_runner, const scoped_refptr& background_task_runner, bool restore_old_session_cookies, CookieCryptoDelegate* crypto_delegate) : backend_(new Backend(path, client_task_runner, background_task_runner, restore_old_session_cookies, crypto_delegate)) { } void SQLitePersistentCookieStore::DeleteAllInList( const std::list& cookies) { if (backend_) backend_->DeleteAllInList(cookies); } void SQLitePersistentCookieStore::Close(const base::Closure& callback) { if (backend_) { backend_->Close(callback); // We release our reference to the Backend, though it will probably still // have a reference if the background runner has not run // Backend::InternalBackgroundClose() yet. backend_ = nullptr; } } void SQLitePersistentCookieStore::Load(const LoadedCallback& loaded_callback) { DCHECK(!loaded_callback.is_null()); if (backend_) backend_->Load(loaded_callback); else loaded_callback.Run(std::vector>()); } void SQLitePersistentCookieStore::LoadCookiesForKey( const std::string& key, const LoadedCallback& loaded_callback) { DCHECK(!loaded_callback.is_null()); if (backend_) backend_->LoadCookiesForKey(key, loaded_callback); else loaded_callback.Run(std::vector>()); } void SQLitePersistentCookieStore::AddCookie(const CanonicalCookie& cc) { if (backend_) backend_->AddCookie(cc); } void SQLitePersistentCookieStore::UpdateCookieAccessTime( const CanonicalCookie& cc) { if (backend_) backend_->UpdateCookieAccessTime(cc); } void SQLitePersistentCookieStore::DeleteCookie(const CanonicalCookie& cc) { if (backend_) backend_->DeleteCookie(cc); } void SQLitePersistentCookieStore::SetForceKeepSessionState() { // This store never discards session-only cookies, so this call has no effect. } void SQLitePersistentCookieStore::SetBeforeFlushCallback( base::RepeatingClosure callback) { if (backend_) backend_->SetBeforeFlushCallback(std::move(callback)); } void SQLitePersistentCookieStore::Flush(base::OnceClosure callback) { if (backend_) backend_->Flush(std::move(callback)); } SQLitePersistentCookieStore::~SQLitePersistentCookieStore() { Close(base::Closure()); } } // namespace net