// 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 "content/browser/appcache/appcache_database.h"
#include "base/auto_reset.h"
#include "base/bind.h"
#include "base/command_line.h"
#include "base/files/file_util.h"
#include "base/logging.h"
#include "base/strings/utf_string_conversions.h"
#include "content/browser/appcache/appcache_entry.h"
#include "content/browser/appcache/appcache_histograms.h"
#include "sql/connection.h"
#include "sql/error_delegate_util.h"
#include "sql/meta_table.h"
#include "sql/statement.h"
#include "sql/transaction.h"
namespace content {
// Schema -------------------------------------------------------------------
namespace {
#if defined(APPCACHE_USE_SIMPLE_CACHE)
const int kCurrentVersion = 6;
const int kCompatibleVersion = 6;
#else
const int kCurrentVersion = 5;
const int kCompatibleVersion = 5;
#endif
// A mechanism to run experiments that may affect in data being persisted
// in different ways such that when the experiment is toggled on/off via
// cmd line flags, the database gets reset. The active flags are stored at
// the time of database creation and compared when reopening. If different
// the database is reset.
const char kExperimentFlagsKey[] = "ExperimentFlags";
const char kGroupsTable[] = "Groups";
const char kCachesTable[] = "Caches";
const char kEntriesTable[] = "Entries";
const char kNamespacesTable[] = "Namespaces";
const char kOnlineWhiteListsTable[] = "OnlineWhiteLists";
const char kDeletableResponseIdsTable[] = "DeletableResponseIds";
struct TableInfo {
const char* table_name;
const char* columns;
};
struct IndexInfo {
const char* index_name;
const char* table_name;
const char* columns;
bool unique;
};
const TableInfo kTables[] = {
{ kGroupsTable,
"(group_id INTEGER PRIMARY KEY,"
" origin TEXT,"
" manifest_url TEXT,"
" creation_time INTEGER,"
" last_access_time INTEGER)" },
{ kCachesTable,
"(cache_id INTEGER PRIMARY KEY,"
" group_id INTEGER,"
" online_wildcard INTEGER CHECK(online_wildcard IN (0, 1)),"
" update_time INTEGER,"
" cache_size INTEGER)" }, // intentionally not normalized
{ kEntriesTable,
"(cache_id INTEGER,"
" url TEXT,"
" flags INTEGER,"
" response_id INTEGER,"
" response_size INTEGER)" },
{ kNamespacesTable,
"(cache_id INTEGER,"
" origin TEXT," // intentionally not normalized
" type INTEGER,"
" namespace_url TEXT,"
" target_url TEXT,"
" is_pattern INTEGER CHECK(is_pattern IN (0, 1)))" },
{ kOnlineWhiteListsTable,
"(cache_id INTEGER,"
" namespace_url TEXT,"
" is_pattern INTEGER CHECK(is_pattern IN (0, 1)))" },
{ kDeletableResponseIdsTable,
"(response_id INTEGER NOT NULL)" },
};
const IndexInfo kIndexes[] = {
{ "GroupsOriginIndex",
kGroupsTable,
"(origin)",
false },
{ "GroupsManifestIndex",
kGroupsTable,
"(manifest_url)",
true },
{ "CachesGroupIndex",
kCachesTable,
"(group_id)",
false },
{ "EntriesCacheIndex",
kEntriesTable,
"(cache_id)",
false },
{ "EntriesCacheAndUrlIndex",
kEntriesTable,
"(cache_id, url)",
true },
{ "EntriesResponseIdIndex",
kEntriesTable,
"(response_id)",
true },
{ "NamespacesCacheIndex",
kNamespacesTable,
"(cache_id)",
false },
{ "NamespacesOriginIndex",
kNamespacesTable,
"(origin)",
false },
{ "NamespacesCacheAndUrlIndex",
kNamespacesTable,
"(cache_id, namespace_url)",
true },
{ "OnlineWhiteListCacheIndex",
kOnlineWhiteListsTable,
"(cache_id)",
false },
{ "DeletableResponsesIdIndex",
kDeletableResponseIdsTable,
"(response_id)",
true },
};
const int kTableCount = ARRAYSIZE_UNSAFE(kTables);
const int kIndexCount = ARRAYSIZE_UNSAFE(kIndexes);
bool CreateTable(sql::Connection* db, const TableInfo& info) {
std::string sql("CREATE TABLE ");
sql += info.table_name;
sql += info.columns;
return db->Execute(sql.c_str());
}
bool CreateIndex(sql::Connection* db, const IndexInfo& info) {
std::string sql;
if (info.unique)
sql += "CREATE UNIQUE INDEX ";
else
sql += "CREATE INDEX ";
sql += info.index_name;
sql += " ON ";
sql += info.table_name;
sql += info.columns;
return db->Execute(sql.c_str());
}
std::string GetActiveExperimentFlags() {
if (base::CommandLine::ForCurrentProcess()->HasSwitch(
kEnableExecutableHandlers))
return std::string("executableHandlersEnabled");
return std::string();
}
} // anon namespace
// AppCacheDatabase ----------------------------------------------------------
AppCacheDatabase::GroupRecord::GroupRecord()
: group_id(0) {
}
AppCacheDatabase::GroupRecord::~GroupRecord() {
}
AppCacheDatabase::NamespaceRecord::NamespaceRecord()
: cache_id(0) {
}
AppCacheDatabase::NamespaceRecord::~NamespaceRecord() {
}
AppCacheDatabase::AppCacheDatabase(const base::FilePath& path)
: db_file_path_(path),
is_disabled_(false),
is_recreating_(false),
was_corruption_detected_(false) {
}
AppCacheDatabase::~AppCacheDatabase() {
}
void AppCacheDatabase::Disable() {
VLOG(1) << "Disabling appcache database.";
is_disabled_ = true;
ResetConnectionAndTables();
}
int64 AppCacheDatabase::GetOriginUsage(const GURL& origin) {
std::vector<CacheRecord> records;
if (!FindCachesForOrigin(origin, &records))
return 0;
int64 origin_usage = 0;
std::vector<CacheRecord>::const_iterator iter = records.begin();
while (iter != records.end()) {
origin_usage += iter->cache_size;
++iter;
}
return origin_usage;
}
bool AppCacheDatabase::GetAllOriginUsage(std::map<GURL, int64>* usage_map) {
std::set<GURL> origins;
if (!FindOriginsWithGroups(&origins))
return false;
for (std::set<GURL>::const_iterator origin = origins.begin();
origin != origins.end(); ++origin) {
(*usage_map)[*origin] = GetOriginUsage(*origin);
}
return true;
}
bool AppCacheDatabase::FindOriginsWithGroups(std::set<GURL>* origins) {
DCHECK(origins && origins->empty());
if (!LazyOpen(false))
return false;
const char* kSql =
"SELECT DISTINCT(origin) FROM Groups";
sql::Statement statement(db_->GetUniqueStatement(kSql));
while (statement.Step())
origins->insert(GURL(statement.ColumnString(0)));
return statement.Succeeded();
}
bool AppCacheDatabase::FindLastStorageIds(
int64* last_group_id, int64* last_cache_id, int64* last_response_id,
int64* last_deletable_response_rowid) {
DCHECK(last_group_id && last_cache_id && last_response_id &&
last_deletable_response_rowid);
*last_group_id = 0;
*last_cache_id = 0;
*last_response_id = 0;
*last_deletable_response_rowid = 0;
if (!LazyOpen(false))
return false;
const char* kMaxGroupIdSql = "SELECT MAX(group_id) FROM Groups";
const char* kMaxCacheIdSql = "SELECT MAX(cache_id) FROM Caches";
const char* kMaxResponseIdFromEntriesSql =
"SELECT MAX(response_id) FROM Entries";
const char* kMaxResponseIdFromDeletablesSql =
"SELECT MAX(response_id) FROM DeletableResponseIds";
const char* kMaxDeletableResponseRowIdSql =
"SELECT MAX(rowid) FROM DeletableResponseIds";
int64 max_group_id;
int64 max_cache_id;
int64 max_response_id_from_entries;
int64 max_response_id_from_deletables;
int64 max_deletable_response_rowid;
if (!RunUniqueStatementWithInt64Result(kMaxGroupIdSql, &max_group_id) ||
!RunUniqueStatementWithInt64Result(kMaxCacheIdSql, &max_cache_id) ||
!RunUniqueStatementWithInt64Result(kMaxResponseIdFromEntriesSql,
&max_response_id_from_entries) ||
!RunUniqueStatementWithInt64Result(kMaxResponseIdFromDeletablesSql,
&max_response_id_from_deletables) ||
!RunUniqueStatementWithInt64Result(kMaxDeletableResponseRowIdSql,
&max_deletable_response_rowid)) {
return false;
}
*last_group_id = max_group_id;
*last_cache_id = max_cache_id;
*last_response_id = std::max(max_response_id_from_entries,
max_response_id_from_deletables);
*last_deletable_response_rowid = max_deletable_response_rowid;
return true;
}
bool AppCacheDatabase::FindGroup(int64 group_id, GroupRecord* record) {
DCHECK(record);
if (!LazyOpen(false))
return false;
const char* kSql =
"SELECT group_id, origin, manifest_url,"
" creation_time, last_access_time"
" FROM Groups WHERE group_id = ?";
sql::Statement statement(db_->GetCachedStatement(SQL_FROM_HERE, kSql));
statement.BindInt64(0, group_id);
if (!statement.Step())
return false;
ReadGroupRecord(statement, record);
DCHECK(record->group_id == group_id);
return true;
}
bool AppCacheDatabase::FindGroupForManifestUrl(
const GURL& manifest_url, GroupRecord* record) {
DCHECK(record);
if (!LazyOpen(false))
return false;
const char* kSql =
"SELECT group_id, origin, manifest_url,"
" creation_time, last_access_time"
" FROM Groups WHERE manifest_url = ?";
sql::Statement statement(db_->GetCachedStatement(SQL_FROM_HERE, kSql));
statement.BindString(0, manifest_url.spec());
if (!statement.Step())
return false;
ReadGroupRecord(statement, record);
DCHECK(record->manifest_url == manifest_url);
return true;
}
bool AppCacheDatabase::FindGroupsForOrigin(
const GURL& origin, std::vector<GroupRecord>* records) {
DCHECK(records && records->empty());
if (!LazyOpen(false))
return false;
const char* kSql =
"SELECT group_id, origin, manifest_url,"
" creation_time, last_access_time"
" FROM Groups WHERE origin = ?";
sql::Statement statement(db_->GetCachedStatement(SQL_FROM_HERE, kSql));
statement.BindString(0, origin.spec());
while (statement.Step()) {
records->push_back(GroupRecord());
ReadGroupRecord(statement, &records->back());
DCHECK(records->back().origin == origin);
}
return statement.Succeeded();
}
bool AppCacheDatabase::FindGroupForCache(int64 cache_id, GroupRecord* record) {
DCHECK(record);
if (!LazyOpen(false))
return false;
const char* kSql =
"SELECT g.group_id, g.origin, g.manifest_url,"
" g.creation_time, g.last_access_time"
" FROM Groups g, Caches c"
" WHERE c.cache_id = ? AND c.group_id = g.group_id";
sql::Statement statement(db_->GetCachedStatement(SQL_FROM_HERE, kSql));
statement.BindInt64(0, cache_id);
if (!statement.Step())
return false;
ReadGroupRecord(statement, record);
return true;
}
bool AppCacheDatabase::UpdateGroupLastAccessTime(
int64 group_id, base::Time time) {
if (!LazyOpen(true))
return false;
const char* kSql =
"UPDATE Groups SET last_access_time = ? WHERE group_id = ?";
sql::Statement statement(db_->GetCachedStatement(SQL_FROM_HERE, kSql));
statement.BindInt64(0, time.ToInternalValue());
statement.BindInt64(1, group_id);
return statement.Run() && db_->GetLastChangeCount();
}
bool AppCacheDatabase::InsertGroup(const GroupRecord* record) {
if (!LazyOpen(true))
return false;
const char* kSql =
"INSERT INTO Groups"
" (group_id, origin, manifest_url, creation_time, last_access_time)"
" VALUES(?, ?, ?, ?, ?)";
sql::Statement statement(db_->GetCachedStatement(SQL_FROM_HERE, kSql));
statement.BindInt64(0, record->group_id);
statement.BindString(1, record->origin.spec());
statement.BindString(2, record->manifest_url.spec());
statement.BindInt64(3, record->creation_time.ToInternalValue());
statement.BindInt64(4, record->last_access_time.ToInternalValue());
return statement.Run();
}
bool AppCacheDatabase::DeleteGroup(int64 group_id) {
if (!LazyOpen(false))
return false;
const char* kSql =
"DELETE FROM Groups WHERE group_id = ?";
sql::Statement statement(db_->GetCachedStatement(SQL_FROM_HERE, kSql));
statement.BindInt64(0, group_id);
return statement.Run();
}
bool AppCacheDatabase::FindCache(int64 cache_id, CacheRecord* record) {
DCHECK(record);
if (!LazyOpen(false))
return false;
const char* kSql =
"SELECT cache_id, group_id, online_wildcard, update_time, cache_size"
" FROM Caches WHERE cache_id = ?";
sql::Statement statement(db_->GetCachedStatement(SQL_FROM_HERE, kSql));
statement.BindInt64(0, cache_id);
if (!statement.Step())
return false;
ReadCacheRecord(statement, record);
return true;
}
bool AppCacheDatabase::FindCacheForGroup(int64 group_id, CacheRecord* record) {
DCHECK(record);
if (!LazyOpen(false))
return false;
const char* kSql =
"SELECT cache_id, group_id, online_wildcard, update_time, cache_size"
" FROM Caches WHERE group_id = ?";
sql::Statement statement(db_->GetCachedStatement(SQL_FROM_HERE, kSql));
statement.BindInt64(0, group_id);
if (!statement.Step())
return false;
ReadCacheRecord(statement, record);
return true;
}
bool AppCacheDatabase::FindCachesForOrigin(
const GURL& origin, std::vector<CacheRecord>* records) {
DCHECK(records);
std::vector<GroupRecord> group_records;
if (!FindGroupsForOrigin(origin, &group_records))
return false;
CacheRecord cache_record;
std::vector<GroupRecord>::const_iterator iter = group_records.begin();
while (iter != group_records.end()) {
if (FindCacheForGroup(iter->group_id, &cache_record))
records->push_back(cache_record);
++iter;
}
return true;
}
bool AppCacheDatabase::InsertCache(const CacheRecord* record) {
if (!LazyOpen(true))
return false;
const char* kSql =
"INSERT INTO Caches (cache_id, group_id, online_wildcard,"
" update_time, cache_size)"
" VALUES(?, ?, ?, ?, ?)";
sql::Statement statement(db_->GetCachedStatement(SQL_FROM_HERE, kSql));
statement.BindInt64(0, record->cache_id);
statement.BindInt64(1, record->group_id);
statement.BindBool(2, record->online_wildcard);
statement.BindInt64(3, record->update_time.ToInternalValue());
statement.BindInt64(4, record->cache_size);
return statement.Run();
}
bool AppCacheDatabase::DeleteCache(int64 cache_id) {
if (!LazyOpen(false))
return false;
const char* kSql =
"DELETE FROM Caches WHERE cache_id = ?";
sql::Statement statement(db_->GetCachedStatement(SQL_FROM_HERE, kSql));
statement.BindInt64(0, cache_id);
return statement.Run();
}
bool AppCacheDatabase::FindEntriesForCache(
int64 cache_id, std::vector<EntryRecord>* records) {
DCHECK(records && records->empty());
if (!LazyOpen(false))
return false;
const char* kSql =
"SELECT cache_id, url, flags, response_id, response_size FROM Entries"
" WHERE cache_id = ?";
sql::Statement statement(db_->GetCachedStatement(SQL_FROM_HERE, kSql));
statement.BindInt64(0, cache_id);
while (statement.Step()) {
records->push_back(EntryRecord());
ReadEntryRecord(statement, &records->back());
DCHECK(records->back().cache_id == cache_id);
}
return statement.Succeeded();
}
bool AppCacheDatabase::FindEntriesForUrl(
const GURL& url, std::vector<EntryRecord>* records) {
DCHECK(records && records->empty());
if (!LazyOpen(false))
return false;
const char* kSql =
"SELECT cache_id, url, flags, response_id, response_size FROM Entries"
" WHERE url = ?";
sql::Statement statement(db_->GetCachedStatement(SQL_FROM_HERE, kSql));
statement.BindString(0, url.spec());
while (statement.Step()) {
records->push_back(EntryRecord());
ReadEntryRecord(statement, &records->back());
DCHECK(records->back().url == url);
}
return statement.Succeeded();
}
bool AppCacheDatabase::FindEntry(
int64 cache_id, const GURL& url, EntryRecord* record) {
DCHECK(record);
if (!LazyOpen(false))
return false;
const char* kSql =
"SELECT cache_id, url, flags, response_id, response_size FROM Entries"
" WHERE cache_id = ? AND url = ?";
sql::Statement statement(db_->GetCachedStatement(SQL_FROM_HERE, kSql));
statement.BindInt64(0, cache_id);
statement.BindString(1, url.spec());
if (!statement.Step())
return false;
ReadEntryRecord(statement, record);
DCHECK(record->cache_id == cache_id);
DCHECK(record->url == url);
return true;
}
bool AppCacheDatabase::InsertEntry(const EntryRecord* record) {
if (!LazyOpen(true))
return false;
const char* kSql =
"INSERT INTO Entries (cache_id, url, flags, response_id, response_size)"
" VALUES(?, ?, ?, ?, ?)";
sql::Statement statement(db_->GetCachedStatement(SQL_FROM_HERE, kSql));
statement.BindInt64(0, record->cache_id);
statement.BindString(1, record->url.spec());
statement.BindInt(2, record->flags);
statement.BindInt64(3, record->response_id);
statement.BindInt64(4, record->response_size);
return statement.Run();
}
bool AppCacheDatabase::InsertEntryRecords(
const std::vector<EntryRecord>& records) {
if (records.empty())
return true;
sql::Transaction transaction(db_.get());
if (!transaction.Begin())
return false;
std::vector<EntryRecord>::const_iterator iter = records.begin();
while (iter != records.end()) {
if (!InsertEntry(&(*iter)))
return false;
++iter;
}
return transaction.Commit();
}
bool AppCacheDatabase::DeleteEntriesForCache(int64 cache_id) {
if (!LazyOpen(false))
return false;
const char* kSql =
"DELETE FROM Entries WHERE cache_id = ?";
sql::Statement statement(db_->GetCachedStatement(SQL_FROM_HERE, kSql));
statement.BindInt64(0, cache_id);
return statement.Run();
}
bool AppCacheDatabase::AddEntryFlags(
const GURL& entry_url, int64 cache_id, int additional_flags) {
if (!LazyOpen(false))
return false;
const char* kSql =
"UPDATE Entries SET flags = flags | ? WHERE cache_id = ? AND url = ?";
sql::Statement statement(db_->GetCachedStatement(SQL_FROM_HERE, kSql));
statement.BindInt(0, additional_flags);
statement.BindInt64(1, cache_id);
statement.BindString(2, entry_url.spec());
return statement.Run() && db_->GetLastChangeCount();
}
bool AppCacheDatabase::FindNamespacesForOrigin(
const GURL& origin,
std::vector<NamespaceRecord>* intercepts,
std::vector<NamespaceRecord>* fallbacks) {
DCHECK(intercepts && intercepts->empty());
DCHECK(fallbacks && fallbacks->empty());
if (!LazyOpen(false))
return false;
const char* kSql =
"SELECT cache_id, origin, type, namespace_url, target_url, is_pattern"
" FROM Namespaces WHERE origin = ?";
sql::Statement statement(db_->GetCachedStatement(SQL_FROM_HERE, kSql));
statement.BindString(0, origin.spec());
ReadNamespaceRecords(&statement, intercepts, fallbacks);
return statement.Succeeded();
}
bool AppCacheDatabase::FindNamespacesForCache(
int64 cache_id,
std::vector<NamespaceRecord>* intercepts,
std::vector<NamespaceRecord>* fallbacks) {
DCHECK(intercepts && intercepts->empty());
DCHECK(fallbacks && fallbacks->empty());
if (!LazyOpen(false))
return false;
const char* kSql =
"SELECT cache_id, origin, type, namespace_url, target_url, is_pattern"
" FROM Namespaces WHERE cache_id = ?";
sql::Statement statement(db_->GetCachedStatement(SQL_FROM_HERE, kSql));
statement.BindInt64(0, cache_id);
ReadNamespaceRecords(&statement, intercepts, fallbacks);
return statement.Succeeded();
}
bool AppCacheDatabase::InsertNamespace(
const NamespaceRecord* record) {
if (!LazyOpen(true))
return false;
const char* kSql =
"INSERT INTO Namespaces"
" (cache_id, origin, type, namespace_url, target_url, is_pattern)"
" VALUES (?, ?, ?, ?, ?, ?)";
// Note: quick and dirty storage for the 'executable' bit w/o changing
// schemas, we use the high bit of 'type' field.
int type_with_executable_bit = record->namespace_.type;
if (record->namespace_.is_executable) {
type_with_executable_bit |= 0x8000000;
DCHECK(base::CommandLine::ForCurrentProcess()->HasSwitch(
kEnableExecutableHandlers));
}
sql::Statement statement(db_->GetCachedStatement(SQL_FROM_HERE, kSql));
statement.BindInt64(0, record->cache_id);
statement.BindString(1, record->origin.spec());
statement.BindInt(2, type_with_executable_bit);
statement.BindString(3, record->namespace_.namespace_url.spec());
statement.BindString(4, record->namespace_.target_url.spec());
statement.BindBool(5, record->namespace_.is_pattern);
return statement.Run();
}
bool AppCacheDatabase::InsertNamespaceRecords(
const std::vector<NamespaceRecord>& records) {
if (records.empty())
return true;
sql::Transaction transaction(db_.get());
if (!transaction.Begin())
return false;
std::vector<NamespaceRecord>::const_iterator iter = records.begin();
while (iter != records.end()) {
if (!InsertNamespace(&(*iter)))
return false;
++iter;
}
return transaction.Commit();
}
bool AppCacheDatabase::DeleteNamespacesForCache(int64 cache_id) {
if (!LazyOpen(false))
return false;
const char* kSql =
"DELETE FROM Namespaces WHERE cache_id = ?";
sql::Statement statement(db_->GetCachedStatement(SQL_FROM_HERE, kSql));
statement.BindInt64(0, cache_id);
return statement.Run();
}
bool AppCacheDatabase::FindOnlineWhiteListForCache(
int64 cache_id, std::vector<OnlineWhiteListRecord>* records) {
DCHECK(records && records->empty());
if (!LazyOpen(false))
return false;
const char* kSql =
"SELECT cache_id, namespace_url, is_pattern FROM OnlineWhiteLists"
" WHERE cache_id = ?";
sql::Statement statement(db_->GetCachedStatement(SQL_FROM_HERE, kSql));
statement.BindInt64(0, cache_id);
while (statement.Step()) {
records->push_back(OnlineWhiteListRecord());
this->ReadOnlineWhiteListRecord(statement, &records->back());
DCHECK(records->back().cache_id == cache_id);
}
return statement.Succeeded();
}
bool AppCacheDatabase::InsertOnlineWhiteList(
const OnlineWhiteListRecord* record) {
if (!LazyOpen(true))
return false;
const char* kSql =
"INSERT INTO OnlineWhiteLists (cache_id, namespace_url, is_pattern)"
" VALUES (?, ?, ?)";
sql::Statement statement(db_->GetCachedStatement(SQL_FROM_HERE, kSql));
statement.BindInt64(0, record->cache_id);
statement.BindString(1, record->namespace_url.spec());
statement.BindBool(2, record->is_pattern);
return statement.Run();
}
bool AppCacheDatabase::InsertOnlineWhiteListRecords(
const std::vector<OnlineWhiteListRecord>& records) {
if (records.empty())
return true;
sql::Transaction transaction(db_.get());
if (!transaction.Begin())
return false;
std::vector<OnlineWhiteListRecord>::const_iterator iter = records.begin();
while (iter != records.end()) {
if (!InsertOnlineWhiteList(&(*iter)))
return false;
++iter;
}
return transaction.Commit();
}
bool AppCacheDatabase::DeleteOnlineWhiteListForCache(int64 cache_id) {
if (!LazyOpen(false))
return false;
const char* kSql =
"DELETE FROM OnlineWhiteLists WHERE cache_id = ?";
sql::Statement statement(db_->GetCachedStatement(SQL_FROM_HERE, kSql));
statement.BindInt64(0, cache_id);
return statement.Run();
}
bool AppCacheDatabase::GetDeletableResponseIds(
std::vector<int64>* response_ids, int64 max_rowid, int limit) {
if (!LazyOpen(false))
return false;
const char* kSql =
"SELECT response_id FROM DeletableResponseIds "
" WHERE rowid <= ?"
" LIMIT ?";
sql::Statement statement(db_->GetCachedStatement(SQL_FROM_HERE, kSql));
statement.BindInt64(0, max_rowid);
statement.BindInt64(1, limit);
while (statement.Step())
response_ids->push_back(statement.ColumnInt64(0));
return statement.Succeeded();
}
bool AppCacheDatabase::InsertDeletableResponseIds(
const std::vector<int64>& response_ids) {
const char* kSql =
"INSERT INTO DeletableResponseIds (response_id) VALUES (?)";
return RunCachedStatementWithIds(SQL_FROM_HERE, kSql, response_ids);
}
bool AppCacheDatabase::DeleteDeletableResponseIds(
const std::vector<int64>& response_ids) {
const char* kSql =
"DELETE FROM DeletableResponseIds WHERE response_id = ?";
return RunCachedStatementWithIds(SQL_FROM_HERE, kSql, response_ids);
}
bool AppCacheDatabase::RunCachedStatementWithIds(
const sql::StatementID& statement_id, const char* sql,
const std::vector<int64>& ids) {
DCHECK(sql);
if (!LazyOpen(true))
return false;
sql::Transaction transaction(db_.get());
if (!transaction.Begin())
return false;
sql::Statement statement(db_->GetCachedStatement(statement_id, sql));
std::vector<int64>::const_iterator iter = ids.begin();
while (iter != ids.end()) {
statement.BindInt64(0, *iter);
if (!statement.Run())
return false;
statement.Reset(true);
++iter;
}
return transaction.Commit();
}
bool AppCacheDatabase::RunUniqueStatementWithInt64Result(
const char* sql, int64* result) {
DCHECK(sql);
sql::Statement statement(db_->GetUniqueStatement(sql));
if (!statement.Step()) {
return false;
}
*result = statement.ColumnInt64(0);
return true;
}
bool AppCacheDatabase::FindResponseIdsForCacheHelper(
int64 cache_id, std::vector<int64>* ids_vector,
std::set<int64>* ids_set) {
DCHECK(ids_vector || ids_set);
DCHECK(!(ids_vector && ids_set));
if (!LazyOpen(false))
return false;
const char* kSql =
"SELECT response_id FROM Entries WHERE cache_id = ?";
sql::Statement statement(db_->GetCachedStatement(SQL_FROM_HERE, kSql));
statement.BindInt64(0, cache_id);
while (statement.Step()) {
int64 id = statement.ColumnInt64(0);
if (ids_set)
ids_set->insert(id);
else
ids_vector->push_back(id);
}
return statement.Succeeded();
}
void AppCacheDatabase::ReadGroupRecord(
const sql::Statement& statement, GroupRecord* record) {
record->group_id = statement.ColumnInt64(0);
record->origin = GURL(statement.ColumnString(1));
record->manifest_url = GURL(statement.ColumnString(2));
record->creation_time =
base::Time::FromInternalValue(statement.ColumnInt64(3));
record->last_access_time =
base::Time::FromInternalValue(statement.ColumnInt64(4));
}
void AppCacheDatabase::ReadCacheRecord(
const sql::Statement& statement, CacheRecord* record) {
record->cache_id = statement.ColumnInt64(0);
record->group_id = statement.ColumnInt64(1);
record->online_wildcard = statement.ColumnBool(2);
record->update_time =
base::Time::FromInternalValue(statement.ColumnInt64(3));
record->cache_size = statement.ColumnInt64(4);
}
void AppCacheDatabase::ReadEntryRecord(
const sql::Statement& statement, EntryRecord* record) {
record->cache_id = statement.ColumnInt64(0);
record->url = GURL(statement.ColumnString(1));
record->flags = statement.ColumnInt(2);
record->response_id = statement.ColumnInt64(3);
record->response_size = statement.ColumnInt64(4);
}
void AppCacheDatabase::ReadNamespaceRecords(
sql::Statement* statement,
NamespaceRecordVector* intercepts,
NamespaceRecordVector* fallbacks) {
while (statement->Step()) {
AppCacheNamespaceType type = static_cast<AppCacheNamespaceType>(
statement->ColumnInt(2));
NamespaceRecordVector* records =
(type == APPCACHE_FALLBACK_NAMESPACE) ? fallbacks : intercepts;
records->push_back(NamespaceRecord());
ReadNamespaceRecord(statement, &records->back());
}
}
void AppCacheDatabase::ReadNamespaceRecord(
const sql::Statement* statement, NamespaceRecord* record) {
record->cache_id = statement->ColumnInt64(0);
record->origin = GURL(statement->ColumnString(1));
int type_with_executable_bit = statement->ColumnInt(2);
record->namespace_.namespace_url = GURL(statement->ColumnString(3));
record->namespace_.target_url = GURL(statement->ColumnString(4));
record->namespace_.is_pattern = statement->ColumnBool(5);
// Note: quick and dirty storage for the 'executable' bit w/o changing
// schemas, we use the high bit of 'type' field.
record->namespace_.type = static_cast<AppCacheNamespaceType>
(type_with_executable_bit & 0x7ffffff);
record->namespace_.is_executable =
(type_with_executable_bit & 0x80000000) != 0;
DCHECK(!record->namespace_.is_executable ||
base::CommandLine::ForCurrentProcess()->HasSwitch(
kEnableExecutableHandlers));
}
void AppCacheDatabase::ReadOnlineWhiteListRecord(
const sql::Statement& statement, OnlineWhiteListRecord* record) {
record->cache_id = statement.ColumnInt64(0);
record->namespace_url = GURL(statement.ColumnString(1));
record->is_pattern = statement.ColumnBool(2);
}
bool AppCacheDatabase::LazyOpen(bool create_if_needed) {
if (db_)
return true;
// If we tried and failed once, don't try again in the same session
// to avoid creating an incoherent mess on disk.
if (is_disabled_)
return false;
// Avoid creating a database at all if we can.
bool use_in_memory_db = db_file_path_.empty();
if (!create_if_needed &&
(use_in_memory_db || !base::PathExists(db_file_path_))) {
return false;
}
db_.reset(new sql::Connection);
meta_table_.reset(new sql::MetaTable);
db_->set_histogram_tag("AppCache");
bool opened = false;
if (use_in_memory_db) {
opened = db_->OpenInMemory();
} else if (!base::CreateDirectory(db_file_path_.DirName())) {
LOG(ERROR) << "Failed to create appcache directory.";
} else {
opened = db_->Open(db_file_path_);
if (opened)
db_->Preload();
}
if (!opened || !db_->QuickIntegrityCheck() || !EnsureDatabaseVersion()) {
LOG(ERROR) << "Failed to open the appcache database.";
AppCacheHistograms::CountInitResult(
AppCacheHistograms::SQL_DATABASE_ERROR);
// We're unable to open the database. This is a fatal error
// which we can't recover from. We try to handle it by deleting
// the existing appcache data and starting with a clean slate in
// this browser session.
if (!use_in_memory_db && DeleteExistingAndCreateNewDatabase())
return true;
Disable();
return false;
}
AppCacheHistograms::CountInitResult(AppCacheHistograms::INIT_OK);
was_corruption_detected_ = false;
db_->set_error_callback(
base::Bind(&AppCacheDatabase::OnDatabaseError, base::Unretained(this)));
return true;
}
bool AppCacheDatabase::EnsureDatabaseVersion() {
if (!sql::MetaTable::DoesTableExist(db_.get()))
return CreateSchema();
if (!meta_table_->Init(db_.get(), kCurrentVersion, kCompatibleVersion))
return false;
if (meta_table_->GetCompatibleVersionNumber() > kCurrentVersion) {
LOG(WARNING) << "AppCache database is too new.";
return false;
}
std::string stored_flags;
meta_table_->GetValue(kExperimentFlagsKey, &stored_flags);
if (stored_flags != GetActiveExperimentFlags())
return false;
if (meta_table_->GetVersionNumber() < kCurrentVersion)
return UpgradeSchema();
#ifndef NDEBUG
DCHECK(sql::MetaTable::DoesTableExist(db_.get()));
for (int i = 0; i < kTableCount; ++i) {
DCHECK(db_->DoesTableExist(kTables[i].table_name));
}
for (int i = 0; i < kIndexCount; ++i) {
DCHECK(db_->DoesIndexExist(kIndexes[i].index_name));
}
#endif
return true;
}
bool AppCacheDatabase::CreateSchema() {
sql::Transaction transaction(db_.get());
if (!transaction.Begin())
return false;
if (!meta_table_->Init(db_.get(), kCurrentVersion, kCompatibleVersion))
return false;
if (!meta_table_->SetValue(kExperimentFlagsKey,
GetActiveExperimentFlags())) {
return false;
}
for (int i = 0; i < kTableCount; ++i) {
if (!CreateTable(db_.get(), kTables[i]))
return false;
}
for (int i = 0; i < kIndexCount; ++i) {
if (!CreateIndex(db_.get(), kIndexes[i]))
return false;
}
return transaction.Commit();
}
bool AppCacheDatabase::UpgradeSchema() {
#if defined(APPCACHE_USE_SIMPLE_CACHE)
return DeleteExistingAndCreateNewDatabase();
#else
if (meta_table_->GetVersionNumber() == 3) {
// version 3 was pre 12/17/2011
DCHECK_EQ(strcmp(kNamespacesTable, kTables[3].table_name), 0);
DCHECK_EQ(strcmp(kNamespacesTable, kIndexes[6].table_name), 0);
DCHECK_EQ(strcmp(kNamespacesTable, kIndexes[7].table_name), 0);
DCHECK_EQ(strcmp(kNamespacesTable, kIndexes[8].table_name), 0);
const TableInfo kNamespaceTable_v4 = {
kNamespacesTable,
"(cache_id INTEGER,"
" origin TEXT," // intentionally not normalized
" type INTEGER,"
" namespace_url TEXT,"
" target_url TEXT)"
};
// Migrate from the old FallbackNameSpaces to the newer Namespaces table,
// but without the is_pattern column added in v5.
sql::Transaction transaction(db_.get());
if (!transaction.Begin() ||
!CreateTable(db_.get(), kNamespaceTable_v4)) {
return false;
}
// Move data from the old table to the new table, setting the
// 'type' for all current records to the value for
// APPCACHE_FALLBACK_NAMESPACE.
DCHECK_EQ(0, static_cast<int>(APPCACHE_FALLBACK_NAMESPACE));
if (!db_->Execute(
"INSERT INTO Namespaces"
" SELECT cache_id, origin, 0, namespace_url, fallback_entry_url"
" FROM FallbackNameSpaces")) {
return false;
}
// Drop the old table, indexes on that table are also removed by this.
if (!db_->Execute("DROP TABLE FallbackNameSpaces"))
return false;
// Create new indexes.
if (!CreateIndex(db_.get(), kIndexes[6]) ||
!CreateIndex(db_.get(), kIndexes[7]) ||
!CreateIndex(db_.get(), kIndexes[8])) {
return false;
}
meta_table_->SetVersionNumber(4);
meta_table_->SetCompatibleVersionNumber(4);
if (!transaction.Commit())
return false;
}
if (meta_table_->GetVersionNumber() == 4) {
// version 4 pre 3/30/2013
// Add the is_pattern column to the Namespaces and OnlineWhitelists tables.
DCHECK_EQ(strcmp(kNamespacesTable, "Namespaces"), 0);
sql::Transaction transaction(db_.get());
if (!transaction.Begin())
return false;
if (!db_->Execute(
"ALTER TABLE Namespaces ADD COLUMN"
" is_pattern INTEGER CHECK(is_pattern IN (0, 1))")) {
return false;
}
if (!db_->Execute(
"ALTER TABLE OnlineWhitelists ADD COLUMN"
" is_pattern INTEGER CHECK(is_pattern IN (0, 1))")) {
return false;
}
meta_table_->SetVersionNumber(5);
meta_table_->SetCompatibleVersionNumber(5);
return transaction.Commit();
}
// If there is no upgrade path for the version on disk to the current
// version, nuke everything and start over.
return DeleteExistingAndCreateNewDatabase();
#endif
}
void AppCacheDatabase::ResetConnectionAndTables() {
meta_table_.reset();
db_.reset();
}
bool AppCacheDatabase::DeleteExistingAndCreateNewDatabase() {
DCHECK(!db_file_path_.empty());
DCHECK(base::PathExists(db_file_path_));
VLOG(1) << "Deleting existing appcache data and starting over.";
ResetConnectionAndTables();
// This also deletes the disk cache data.
base::FilePath directory = db_file_path_.DirName();
if (!base::DeleteFile(directory, true))
return false;
// Make sure the steps above actually deleted things.
if (base::PathExists(directory))
return false;
if (!base::CreateDirectory(directory))
return false;
// So we can't go recursive.
if (is_recreating_)
return false;
base::AutoReset<bool> auto_reset(&is_recreating_, true);
return LazyOpen(true);
}
void AppCacheDatabase::OnDatabaseError(int err, sql::Statement* stmt) {
was_corruption_detected_ |= sql::IsErrorCatastrophic(err);
if (!db_->ShouldIgnoreSqliteError(err))
DLOG(ERROR) << db_->GetErrorMessage();
// TODO: Maybe use non-catostrophic errors to trigger a full integrity check?
}
} // namespace content