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chromium / chromium / src / 482e518fcd554147d41e60dcc38bc0821fe15ab3 / . / sql / database_unittest.cc
blob: 2c9819f18566e7462a1fa92d73e190ec0e077815 [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 "sql/database.h"
#include <stddef.h>
#include <stdint.h>
#include <cstdint>
#include "base/bind.h"
#include "base/callback_helpers.h"
#include "base/files/file_util.h"
#include "base/files/scoped_temp_dir.h"
#include "base/logging.h"
#include "base/memory/raw_ptr.h"
#include "base/sequence_checker.h"
#include "base/strings/string_number_conversions.h"
#include "base/test/bind.h"
#include "base/test/gtest_util.h"
#include "base/test/metrics/histogram_tester.h"
#include "base/thread_annotations.h"
#include "base/trace_event/process_memory_dump.h"
#include "build/build_config.h"
#include "sql/database_memory_dump_provider.h"
#include "sql/meta_table.h"
#include "sql/sql_features.h"
#include "sql/statement.h"
#include "sql/test/database_test_peer.h"
#include "sql/test/scoped_error_expecter.h"
#include "sql/test/test_helpers.h"
#include "sql/transaction.h"
#include "testing/gmock/include/gmock/gmock.h"
#include "testing/gtest/include/gtest/gtest.h"
#include "third_party/sqlite/sqlite3.h"
namespace sql {
namespace {
using sql::test::ExecuteWithResult;
// Helper to return the count of items in sqlite_schema. Return -1 in
// case of error.
int SqliteSchemaCount(Database* db) {
const char* kSchemaCount = "SELECT COUNT(*) FROM sqlite_schema";
Statement s(db->GetUniqueStatement(kSchemaCount));
return s.Step() ? s.ColumnInt(0) : -1;
}
// Handle errors by blowing away the database.
void RazeErrorCallback(Database* db,
int expected_error,
int error,
Statement* stmt) {
// Nothing here needs extended errors at this time.
EXPECT_EQ(expected_error, expected_error & 0xff);
EXPECT_EQ(expected_error, error & 0xff);
db->RazeAndClose();
}
#if BUILDFLAG(IS_POSIX)
// Set a umask and restore the old mask on destruction. Cribbed from
// shared_memory_unittest.cc. Used by POSIX-only UserPermission test.
class ScopedUmaskSetter {
public:
explicit ScopedUmaskSetter(mode_t target_mask) {
old_umask_ = umask(target_mask);
}
~ScopedUmaskSetter() { umask(old_umask_); }
ScopedUmaskSetter(const ScopedUmaskSetter&) = delete;
ScopedUmaskSetter& operator=(const ScopedUmaskSetter&) = delete;
private:
mode_t old_umask_;
};
#endif // BUILDFLAG(IS_POSIX)
} // namespace
// We use the parameter to run all tests with WAL mode on and off.
class SQLDatabaseTest : public testing::Test,
public testing::WithParamInterface<bool> {
public:
enum class OverwriteType {
kTruncate,
kOverwrite,
};
~SQLDatabaseTest() override = default;
void SetUp() override {
db_ = std::make_unique<Database>(GetDBOptions());
ASSERT_TRUE(temp_dir_.CreateUniqueTempDir());
db_path_ = temp_dir_.GetPath().AppendASCII("database_test.sqlite");
ASSERT_TRUE(db_->Open(db_path_));
}
DatabaseOptions GetDBOptions() {
DatabaseOptions options;
options.wal_mode = IsWALEnabled();
// TODO(crbug.com/1120969): Remove after switching to exclusive mode on by
// default.
options.exclusive_locking = false;
#if BUILDFLAG(IS_FUCHSIA) // Exclusive mode needs to be enabled to enter WAL
// mode on Fuchsia
if (IsWALEnabled()) {
options.exclusive_locking = true;
}
#endif // BUILDFLAG(IS_FUCHSIA)
return options;
}
bool IsWALEnabled() { return GetParam(); }
bool TruncateDatabase() {
base::File file(db_path_,
base::File::FLAG_CREATE_ALWAYS | base::File::FLAG_WRITE);
return file.SetLength(0);
}
bool OverwriteDatabaseHeader(OverwriteType type) {
base::File file(db_path_,
base::File::FLAG_CREATE_ALWAYS | base::File::FLAG_WRITE);
if (type == OverwriteType::kTruncate) {
if (!file.SetLength(0))
return false;
}
static constexpr char kText[] = "Now is the winter of our discontent.";
constexpr int kTextBytes = sizeof(kText) - 1;
return file.Write(0, kText, kTextBytes) == kTextBytes;
}
protected:
base::ScopedTempDir temp_dir_;
base::FilePath db_path_;
std::unique_ptr<Database> db_;
};
TEST_P(SQLDatabaseTest, Execute_ValidStatement) {
ASSERT_TRUE(db_->Execute("CREATE TABLE data(contents TEXT)"));
EXPECT_EQ(SQLITE_OK, db_->GetErrorCode());
}
TEST_P(SQLDatabaseTest, Execute_InvalidStatement) {
{
sql::test::ScopedErrorExpecter error_expecter;
error_expecter.ExpectError(SQLITE_ERROR);
EXPECT_FALSE(db_->Execute("CREATE TABLE data("));
EXPECT_TRUE(error_expecter.SawExpectedErrors());
}
EXPECT_EQ(SQLITE_ERROR, db_->GetErrorCode());
}
TEST_P(SQLDatabaseTest, ExecuteScriptForTesting_OneLineValid) {
ASSERT_TRUE(db_->ExecuteScriptForTesting("CREATE TABLE data(contents TEXT)"));
EXPECT_EQ(SQLITE_OK, db_->GetErrorCode());
}
TEST_P(SQLDatabaseTest, ExecuteScriptForTesting_OneLineInvalid) {
ASSERT_FALSE(db_->ExecuteScriptForTesting("CREATE TABLE data("));
EXPECT_EQ(SQLITE_ERROR, db_->GetErrorCode());
}
TEST_P(SQLDatabaseTest, ExecuteScriptForTesting_ExtraContents) {
EXPECT_TRUE(db_->ExecuteScriptForTesting("CREATE TABLE data1(id)"))
<< "Minimal statement";
EXPECT_TRUE(db_->ExecuteScriptForTesting("CREATE TABLE data2(id);"))
<< "Extra semicolon";
EXPECT_TRUE(db_->ExecuteScriptForTesting("CREATE TABLE data3(id) -- Comment"))
<< "Trailing comment";
EXPECT_TRUE(db_->ExecuteScriptForTesting(
"CREATE TABLE data4(id);CREATE TABLE data5(id)"))
<< "Extra statement without whitespace";
EXPECT_TRUE(db_->ExecuteScriptForTesting(
"CREATE TABLE data6(id); CREATE TABLE data7(id)"))
<< "Extra statement separated by whitespace";
EXPECT_TRUE(db_->ExecuteScriptForTesting("CREATE TABLE data8(id);-- Comment"))
<< "Comment without whitespace";
EXPECT_TRUE(
db_->ExecuteScriptForTesting("CREATE TABLE data9(id); -- Comment"))
<< "Comment sepatated by whitespace";
}
TEST_P(SQLDatabaseTest, ExecuteScriptForTesting_MultipleValidLines) {
EXPECT_TRUE(db_->ExecuteScriptForTesting(R"(
CREATE TABLE data1(contents TEXT);
CREATE TABLE data2(contents TEXT);
CREATE TABLE data3(contents TEXT);
)"));
EXPECT_EQ(SQLITE_OK, db_->GetErrorCode());
// DoesColumnExist() is implemented directly on top of a SQLite call. The
// other schema functions use sql::Statement infrastructure to query the
// schema table.
EXPECT_TRUE(db_->DoesColumnExist("data1", "contents"));
EXPECT_TRUE(db_->DoesColumnExist("data2", "contents"));
EXPECT_TRUE(db_->DoesColumnExist("data3", "contents"));
}
TEST_P(SQLDatabaseTest, ExecuteScriptForTesting_StopsOnCompileError) {
EXPECT_FALSE(db_->ExecuteScriptForTesting(R"(
CREATE TABLE data1(contents TEXT);
CREATE TABLE data1();
CREATE TABLE data3(contents TEXT);
)"));
EXPECT_EQ(SQLITE_ERROR, db_->GetErrorCode());
EXPECT_TRUE(db_->DoesColumnExist("data1", "contents"));
EXPECT_FALSE(db_->DoesColumnExist("data3", "contents"));
}
TEST_P(SQLDatabaseTest, ExecuteScriptForTesting_StopsOnStepError) {
EXPECT_FALSE(db_->ExecuteScriptForTesting(R"(
CREATE TABLE data1(contents TEXT UNIQUE);
INSERT INTO data1(contents) VALUES('value1');
INSERT INTO data1(contents) VALUES('value1');
CREATE TABLE data3(contents TEXT);
)"));
EXPECT_EQ(SQLITE_CONSTRAINT_UNIQUE, db_->GetErrorCode());
EXPECT_TRUE(db_->DoesColumnExist("data1", "contents"));
EXPECT_FALSE(db_->DoesColumnExist("data3", "contents"));
}
TEST_P(SQLDatabaseTest, CachedStatement) {
StatementID id1 = SQL_FROM_HERE;
StatementID id2 = SQL_FROM_HERE;
static const char kId1Sql[] = "SELECT a FROM foo";
static const char kId2Sql[] = "SELECT b FROM foo";
ASSERT_TRUE(db_->Execute("CREATE TABLE foo (a, b)"));
ASSERT_TRUE(db_->Execute("INSERT INTO foo(a, b) VALUES (12, 13)"));
sqlite3_stmt* raw_id1_statement;
sqlite3_stmt* raw_id2_statement;
{
scoped_refptr<Database::StatementRef> ref_from_id1 =
db_->GetCachedStatement(id1, kId1Sql);
raw_id1_statement = ref_from_id1->stmt();
Statement from_id1(std::move(ref_from_id1));
ASSERT_TRUE(from_id1.is_valid());
ASSERT_TRUE(from_id1.Step());
EXPECT_EQ(12, from_id1.ColumnInt(0));
scoped_refptr<Database::StatementRef> ref_from_id2 =
db_->GetCachedStatement(id2, kId2Sql);
raw_id2_statement = ref_from_id2->stmt();
EXPECT_NE(raw_id1_statement, raw_id2_statement);
Statement from_id2(std::move(ref_from_id2));
ASSERT_TRUE(from_id2.is_valid());
ASSERT_TRUE(from_id2.Step());
EXPECT_EQ(13, from_id2.ColumnInt(0));
}
{
scoped_refptr<Database::StatementRef> ref_from_id1 =
db_->GetCachedStatement(id1, kId1Sql);
EXPECT_EQ(raw_id1_statement, ref_from_id1->stmt())
<< "statement was not cached";
Statement from_id1(std::move(ref_from_id1));
ASSERT_TRUE(from_id1.is_valid());
ASSERT_TRUE(from_id1.Step()) << "cached statement was not reset";
EXPECT_EQ(12, from_id1.ColumnInt(0));
scoped_refptr<Database::StatementRef> ref_from_id2 =
db_->GetCachedStatement(id2, kId2Sql);
EXPECT_EQ(raw_id2_statement, ref_from_id2->stmt())
<< "statement was not cached";
Statement from_id2(std::move(ref_from_id2));
ASSERT_TRUE(from_id2.is_valid());
ASSERT_TRUE(from_id2.Step()) << "cached statement was not reset";
EXPECT_EQ(13, from_id2.ColumnInt(0));
}
EXPECT_DCHECK_DEATH(db_->GetCachedStatement(id1, kId2Sql))
<< "Using a different SQL with the same statement ID should DCHECK";
EXPECT_DCHECK_DEATH(db_->GetCachedStatement(id2, kId1Sql))
<< "Using a different SQL with the same statement ID should DCHECK";
}
TEST_P(SQLDatabaseTest, IsSQLValidTest) {
ASSERT_TRUE(db_->Execute("CREATE TABLE foo (a, b)"));
ASSERT_TRUE(db_->IsSQLValid("SELECT a FROM foo"));
ASSERT_FALSE(db_->IsSQLValid("SELECT no_exist FROM foo"));
}
TEST_P(SQLDatabaseTest, DoesTableExist) {
EXPECT_FALSE(db_->DoesTableExist("foo"));
EXPECT_FALSE(db_->DoesTableExist("foo_index"));
ASSERT_TRUE(db_->Execute("CREATE TABLE foo (a, b)"));
ASSERT_TRUE(db_->Execute("CREATE INDEX foo_index ON foo (a)"));
EXPECT_TRUE(db_->DoesTableExist("foo"));
EXPECT_FALSE(db_->DoesTableExist("foo_index"));
// DoesTableExist() is case-sensitive.
EXPECT_FALSE(db_->DoesTableExist("Foo"));
EXPECT_FALSE(db_->DoesTableExist("FOO"));
}
TEST_P(SQLDatabaseTest, DoesIndexExist) {
ASSERT_TRUE(db_->Execute("CREATE TABLE foo (a, b)"));
EXPECT_FALSE(db_->DoesIndexExist("foo"));
EXPECT_FALSE(db_->DoesIndexExist("foo_ubdex"));
ASSERT_TRUE(db_->Execute("CREATE INDEX foo_index ON foo (a)"));
EXPECT_TRUE(db_->DoesIndexExist("foo_index"));
EXPECT_FALSE(db_->DoesIndexExist("foo"));
// DoesIndexExist() is case-sensitive.
EXPECT_FALSE(db_->DoesIndexExist("Foo_index"));
EXPECT_FALSE(db_->DoesIndexExist("Foo_Index"));
EXPECT_FALSE(db_->DoesIndexExist("FOO_INDEX"));
}
TEST_P(SQLDatabaseTest, DoesViewExist) {
EXPECT_FALSE(db_->DoesViewExist("voo"));
ASSERT_TRUE(db_->Execute("CREATE VIEW voo (a) AS SELECT 1"));
EXPECT_FALSE(db_->DoesIndexExist("voo"));
EXPECT_FALSE(db_->DoesTableExist("voo"));
EXPECT_TRUE(db_->DoesViewExist("voo"));
// DoesTableExist() is case-sensitive.
EXPECT_FALSE(db_->DoesViewExist("Voo"));
EXPECT_FALSE(db_->DoesViewExist("VOO"));
}
TEST_P(SQLDatabaseTest, DoesColumnExist) {
ASSERT_TRUE(db_->Execute("CREATE TABLE foo (a, b)"));
EXPECT_FALSE(db_->DoesColumnExist("foo", "bar"));
EXPECT_TRUE(db_->DoesColumnExist("foo", "a"));
ASSERT_FALSE(db_->DoesTableExist("bar"));
EXPECT_FALSE(db_->DoesColumnExist("bar", "b"));
// SQLite resolves table/column names without case sensitivity.
EXPECT_TRUE(db_->DoesColumnExist("FOO", "A"));
EXPECT_TRUE(db_->DoesColumnExist("FOO", "a"));
EXPECT_TRUE(db_->DoesColumnExist("foo", "A"));
}
TEST_P(SQLDatabaseTest, GetLastInsertRowId) {
ASSERT_TRUE(db_->Execute("CREATE TABLE foo (id INTEGER PRIMARY KEY, value)"));
ASSERT_TRUE(db_->Execute("INSERT INTO foo (value) VALUES (12)"));
// Last insert row ID should be valid.
int64_t row = db_->GetLastInsertRowId();
EXPECT_LT(0, row);
// It should be the primary key of the row we just inserted.
Statement s(db_->GetUniqueStatement("SELECT value FROM foo WHERE id=?"));
s.BindInt64(0, row);
ASSERT_TRUE(s.Step());
EXPECT_EQ(12, s.ColumnInt(0));
}
// Test the scoped error expecter by attempting to insert a duplicate
// value into an index.
TEST_P(SQLDatabaseTest, ScopedErrorExpecter) {
const char* kCreateSql = "CREATE TABLE foo (id INTEGER UNIQUE)";
ASSERT_TRUE(db_->Execute(kCreateSql));
ASSERT_TRUE(db_->Execute("INSERT INTO foo (id) VALUES (12)"));
{
sql::test::ScopedErrorExpecter expecter;
expecter.ExpectError(SQLITE_CONSTRAINT);
ASSERT_FALSE(db_->Execute("INSERT INTO foo (id) VALUES (12)"));
ASSERT_TRUE(expecter.SawExpectedErrors());
}
}
TEST_P(SQLDatabaseTest, SchemaIntrospectionUsesErrorExpecter) {
const char* kCreateSql = "CREATE TABLE foo (id INTEGER UNIQUE)";
ASSERT_TRUE(db_->Execute(kCreateSql));
ASSERT_FALSE(db_->DoesTableExist("bar"));
ASSERT_TRUE(db_->DoesTableExist("foo"));
ASSERT_TRUE(db_->DoesColumnExist("foo", "id"));
db_->Close();
// Corrupt the database so that nothing works, including PRAGMAs.
ASSERT_TRUE(sql::test::CorruptSizeInHeader(db_path_));
{
sql::test::ScopedErrorExpecter expecter;
expecter.ExpectError(SQLITE_CORRUPT);
ASSERT_TRUE(db_->Open(db_path_));
ASSERT_FALSE(db_->DoesTableExist("bar"));
ASSERT_FALSE(db_->DoesTableExist("foo"));
ASSERT_FALSE(db_->DoesColumnExist("foo", "id"));
ASSERT_TRUE(expecter.SawExpectedErrors());
}
}
TEST_P(SQLDatabaseTest, SetErrorCallback) {
static constexpr char kCreateSql[] =
"CREATE TABLE rows(id INTEGER PRIMARY KEY NOT NULL)";
ASSERT_TRUE(db_->Execute(kCreateSql));
ASSERT_TRUE(db_->Execute("INSERT INTO rows(id) VALUES(12)"));
bool error_callback_called = false;
int error = SQLITE_OK;
db_->set_error_callback(base::BindLambdaForTesting(
[&](int sqlite_error, sql::Statement* statement) {
error_callback_called = true;
error = sqlite_error;
}));
EXPECT_FALSE(db_->Execute("INSERT INTO rows(id) VALUES(12)"))
<< "Inserting a duplicate primary key should have failed";
EXPECT_TRUE(error_callback_called)
<< "Execute() should report errors to the database error callback";
EXPECT_EQ(SQLITE_CONSTRAINT_PRIMARYKEY, error)
<< "Execute() should report errors to the database error callback";
}
TEST_P(SQLDatabaseTest, SetErrorCallbackDchecksOnExistingCallback) {
db_->set_error_callback(base::DoNothing());
EXPECT_DCHECK_DEATH(db_->set_error_callback(base::DoNothing()))
<< "set_error_callback() should DCHECK if error callback already exists";
}
TEST_P(SQLDatabaseTest, ResetErrorCallback) {
static constexpr char kCreateSql[] =
"CREATE TABLE rows(id INTEGER PRIMARY KEY NOT NULL)";
ASSERT_TRUE(db_->Execute(kCreateSql));
ASSERT_TRUE(db_->Execute("INSERT INTO rows(id) VALUES(12)"));
bool error_callback_called = false;
int error = SQLITE_OK;
db_->set_error_callback(
base::BindLambdaForTesting([&](int sqlite_error, Statement* statement) {
error_callback_called = true;
error = sqlite_error;
}));
db_->reset_error_callback();
{
sql::test::ScopedErrorExpecter expecter;
expecter.ExpectError(SQLITE_CONSTRAINT);
EXPECT_FALSE(db_->Execute("INSERT INTO rows(id) VALUES(12)"))
<< "Inserting a duplicate primary key should have failed";
EXPECT_TRUE(expecter.SawExpectedErrors())
<< "Inserting a duplicate primary key should have failed";
}
EXPECT_FALSE(error_callback_called)
<< "Execute() should not report errors after reset_error_callback()";
EXPECT_EQ(SQLITE_OK, error)
<< "Execute() should not report errors after reset_error_callback()";
}
// Sets a flag to true/false to track being alive.
class LifeTracker {
public:
explicit LifeTracker(bool* flag_ptr) : flag_ptr_(flag_ptr) {
DCHECK(flag_ptr != nullptr);
DCHECK(!*flag_ptr)
<< "LifeTracker's flag should be set to false prior to construction";
*flag_ptr_ = true;
}
LifeTracker(LifeTracker&& rhs) {
DCHECK_CALLED_ON_VALID_SEQUENCE(sequence_checker_);
DCHECK_CALLED_ON_VALID_SEQUENCE(rhs.sequence_checker_);
flag_ptr_ = rhs.flag_ptr_;
rhs.flag_ptr_ = nullptr;
}
// base::RepeatingCallback only requires move-construction support.
LifeTracker& operator=(const LifeTracker& rhs) = delete;
~LifeTracker() {
DCHECK_CALLED_ON_VALID_SEQUENCE(sequence_checker_);
if (flag_ptr_)
*flag_ptr_ = false;
}
private:
SEQUENCE_CHECKER(sequence_checker_);
raw_ptr<bool> flag_ptr_ GUARDED_BY_CONTEXT(sequence_checker_);
};
// base::BindRepeating() can curry arguments to be passed by const reference to
// the callback function. If the error callback function calls
// reset_error_callback() and the Database doesn't hang onto the callback while
// running it, the storage for those arguments may be deleted while the callback
// function is executing. This test ensures that the database is hanging onto
// the callback while running it.
TEST_P(SQLDatabaseTest, ErrorCallbackStorageProtectedWhileRun) {
bool is_alive = false;
db_->set_error_callback(base::BindRepeating(
[](Database* db, bool* life_tracker_is_alive,
const LifeTracker& life_tracker, int sqlite_error,
Statement* statement) {
EXPECT_TRUE(*life_tracker_is_alive)
<< "The error callback storage should be alive when it is Run()";
db->reset_error_callback();
EXPECT_TRUE(*life_tracker_is_alive)
<< "The error storage should remain alive during Run() after "
<< "reset_error_callback()";
},
base::Unretained(db_.get()), base::Unretained(&is_alive),
LifeTracker(&is_alive)));
EXPECT_TRUE(is_alive)
<< "The error callback storage should be alive after creation";
EXPECT_FALSE(db_->Execute("INSERT INTO rows(id) VALUES(12)"));
EXPECT_FALSE(is_alive)
<< "The error callback storage should be released after Run() completes";
}
TEST_P(SQLDatabaseTest, Execute_CompilationError) {
bool error_callback_called = false;
db_->set_error_callback(base::BindLambdaForTesting([&](int error,
sql::Statement*
statement) {
EXPECT_EQ(SQLITE_ERROR, error);
EXPECT_EQ(nullptr, statement);
EXPECT_FALSE(error_callback_called)
<< "SQL compilation errors should call the error callback exactly once";
error_callback_called = true;
}));
{
sql::test::ScopedErrorExpecter expecter;
expecter.ExpectError(SQLITE_ERROR);
EXPECT_FALSE(db_->Execute("SELECT missing_column FROM missing_table"));
EXPECT_TRUE(expecter.SawExpectedErrors());
}
EXPECT_TRUE(error_callback_called)
<< "SQL compilation errors should call the error callback";
}
TEST_P(SQLDatabaseTest, GetUniqueStatement_CompilationError) {
bool error_callback_called = false;
db_->set_error_callback(base::BindLambdaForTesting([&](int error,
sql::Statement*
statement) {
EXPECT_EQ(SQLITE_ERROR, error);
EXPECT_EQ(nullptr, statement);
EXPECT_FALSE(error_callback_called)
<< "SQL compilation errors should call the error callback exactly once";
error_callback_called = true;
}));
{
sql::test::ScopedErrorExpecter expecter;
expecter.ExpectError(SQLITE_ERROR);
sql::Statement statement(
db_->GetUniqueStatement("SELECT missing_column FROM missing_table"));
EXPECT_FALSE(statement.is_valid());
EXPECT_TRUE(expecter.SawExpectedErrors());
}
EXPECT_TRUE(error_callback_called)
<< "SQL compilation errors should call the error callback";
}
TEST_P(SQLDatabaseTest, GetCachedStatement_CompilationError) {
bool error_callback_called = false;
db_->set_error_callback(base::BindLambdaForTesting([&](int error,
sql::Statement*
statement) {
EXPECT_EQ(SQLITE_ERROR, error);
EXPECT_EQ(nullptr, statement);
EXPECT_FALSE(error_callback_called)
<< "SQL compilation errors should call the error callback exactly once";
error_callback_called = true;
}));
{
sql::test::ScopedErrorExpecter expecter;
expecter.ExpectError(SQLITE_ERROR);
sql::Statement statement(db_->GetCachedStatement(
SQL_FROM_HERE, "SELECT missing_column FROM missing_table"));
EXPECT_FALSE(statement.is_valid());
EXPECT_TRUE(expecter.SawExpectedErrors());
}
EXPECT_TRUE(error_callback_called)
<< "SQL compilation errors should call the error callback";
}
TEST_P(SQLDatabaseTest, GetUniqueStatement_ExtraContents) {
sql::Statement minimal(db_->GetUniqueStatement("SELECT 1"));
sql::Statement extra_semicolon(db_->GetUniqueStatement("SELECT 1;"));
// It would be nice to flag trailing comments too, as they cost binary size.
// However, there's no easy way of doing that.
sql::Statement trailing_comment(
db_->GetUniqueStatement("SELECT 1 -- Comment"));
EXPECT_DCHECK_DEATH(db_->GetUniqueStatement("SELECT 1;SELECT 2"))
<< "Extra statement without whitespace";
EXPECT_DCHECK_DEATH(db_->GetUniqueStatement("SELECT 1; SELECT 2"))
<< "Extra statement separated by whitespace";
EXPECT_DCHECK_DEATH(db_->GetUniqueStatement("SELECT 1;-- Comment"))
<< "Comment without whitespace";
EXPECT_DCHECK_DEATH(db_->GetUniqueStatement("SELECT 1; -- Comment"))
<< "Comment separated by whitespace";
}
TEST_P(SQLDatabaseTest, GetCachedStatement_ExtraContents) {
sql::Statement minimal(db_->GetCachedStatement(SQL_FROM_HERE, "SELECT 1"));
sql::Statement extra_semicolon(
db_->GetCachedStatement(SQL_FROM_HERE, "SELECT 1;"));
// It would be nice to flag trailing comments too, as they cost binary size.
// However, there's no easy way of doing that.
sql::Statement trailing_comment(
db_->GetCachedStatement(SQL_FROM_HERE, "SELECT 1 -- Comment"));
EXPECT_DCHECK_DEATH(
db_->GetCachedStatement(SQL_FROM_HERE, "SELECT 1;SELECT 2"))
<< "Extra statement without whitespace";
EXPECT_DCHECK_DEATH(
db_->GetCachedStatement(SQL_FROM_HERE, "SELECT 1; SELECT 2"))
<< "Extra statement separated by whitespace";
EXPECT_DCHECK_DEATH(
db_->GetCachedStatement(SQL_FROM_HERE, "SELECT 1;-- Comment"))
<< "Comment without whitespace";
EXPECT_DCHECK_DEATH(
db_->GetCachedStatement(SQL_FROM_HERE, "SELECT 1; -- Comment"))
<< "Comment separated by whitespace";
}
TEST_P(SQLDatabaseTest, IsSQLValid_ExtraContents) {
EXPECT_TRUE(db_->IsSQLValid("SELECT 1"));
EXPECT_TRUE(db_->IsSQLValid("SELECT 1;"))
<< "Trailing semicolons are currently tolerated";
// It would be nice to flag trailing comments too, as they cost binary size.
// However, there's no easy way of doing that.
EXPECT_TRUE(db_->IsSQLValid("SELECT 1 -- Comment"))
<< "Trailing comments are currently tolerated";
EXPECT_DCHECK_DEATH(db_->IsSQLValid("SELECT 1;SELECT 2"))
<< "Extra statement without whitespace";
EXPECT_DCHECK_DEATH(db_->IsSQLValid("SELECT 1; SELECT 2"))
<< "Extra statement separated by whitespace";
EXPECT_DCHECK_DEATH(db_->IsSQLValid("SELECT 1;-- Comment"))
<< "Comment without whitespace";
EXPECT_DCHECK_DEATH(db_->IsSQLValid("SELECT 1; -- Comment"))
<< "Comment separated by whitespace";
}
TEST_P(SQLDatabaseTest, GetUniqueStatement_NoContents) {
EXPECT_DCHECK_DEATH(db_->GetUniqueStatement("")) << "Empty string";
EXPECT_DCHECK_DEATH(db_->GetUniqueStatement(" ")) << "Space";
EXPECT_DCHECK_DEATH(db_->GetUniqueStatement("\n")) << "Newline";
EXPECT_DCHECK_DEATH(db_->GetUniqueStatement("-- Comment")) << "Comment";
}
TEST_P(SQLDatabaseTest, GetCachedStatement_NoContents) {
EXPECT_DCHECK_DEATH(db_->GetCachedStatement(SQL_FROM_HERE, ""))
<< "Empty string";
EXPECT_DCHECK_DEATH(db_->GetCachedStatement(SQL_FROM_HERE, " ")) << "Space";
EXPECT_DCHECK_DEATH(db_->GetCachedStatement(SQL_FROM_HERE, "\n"))
<< "Newline";
EXPECT_DCHECK_DEATH(db_->GetCachedStatement(SQL_FROM_HERE, "-- Comment"))
<< "Comment";
}
TEST_P(SQLDatabaseTest, GetReadonlyStatement) {
const char* kCreateSql = "CREATE TABLE foo (id INTEGER PRIMARY KEY, value)";
ASSERT_TRUE(db_->Execute(kCreateSql));
ASSERT_TRUE(db_->Execute("INSERT INTO foo (value) VALUES (12)"));
// PRAGMA statements do not change the database file.
{
Statement s(db_->GetReadonlyStatement("PRAGMA analysis_limit"));
ASSERT_TRUE(s.Step());
}
{
Statement s(db_->GetReadonlyStatement("PRAGMA analysis_limit=100"));
ASSERT_TRUE(s.is_valid());
}
// Create and insert statements should fail, while the same queries as unique
// statement succeeds.
{
Statement s(db_->GetReadonlyStatement(
"CREATE TABLE IF NOT EXISTS foo (id INTEGER PRIMARY KEY, value)"));
ASSERT_FALSE(s.is_valid());
Statement s1(db_->GetUniqueStatement(
"CREATE TABLE IF NOT EXISTS foo (id INTEGER PRIMARY KEY, value)"));
ASSERT_TRUE(s1.is_valid());
}
{
Statement s(
db_->GetReadonlyStatement("INSERT INTO foo (value) VALUES (12)"));
ASSERT_FALSE(s.is_valid());
Statement s1(
db_->GetUniqueStatement("INSERT INTO foo (value) VALUES (12)"));
ASSERT_TRUE(s1.is_valid());
}
{
Statement s(
db_->GetReadonlyStatement("CREATE VIRTUAL TABLE bar USING module"));
ASSERT_FALSE(s.is_valid());
Statement s1(
db_->GetUniqueStatement("CREATE VIRTUAL TABLE bar USING module"));
ASSERT_TRUE(s1.is_valid());
}
// Select statement is successful.
{
Statement s(db_->GetReadonlyStatement("SELECT * FROM foo"));
ASSERT_TRUE(s.Step());
EXPECT_EQ(s.ColumnInt(1), 12);
}
}
TEST_P(SQLDatabaseTest, IsSQLValid_NoContents) {
EXPECT_DCHECK_DEATH(db_->IsSQLValid("")) << "Empty string";
EXPECT_DCHECK_DEATH(db_->IsSQLValid(" ")) << "Space";
EXPECT_DCHECK_DEATH(db_->IsSQLValid("\n")) << "Newline";
EXPECT_DCHECK_DEATH(db_->IsSQLValid("-- Comment")) << "Comment";
}
// Test that Database::Raze() results in a database without the
// tables from the original database.
TEST_P(SQLDatabaseTest, Raze) {
const char* kCreateSql = "CREATE TABLE foo (id INTEGER PRIMARY KEY, value)";
ASSERT_TRUE(db_->Execute(kCreateSql));
ASSERT_TRUE(db_->Execute("INSERT INTO foo (value) VALUES (12)"));
int pragma_auto_vacuum = 0;
{
Statement s(db_->GetUniqueStatement("PRAGMA auto_vacuum"));
ASSERT_TRUE(s.Step());
pragma_auto_vacuum = s.ColumnInt(0);
ASSERT_TRUE(pragma_auto_vacuum == 0 || pragma_auto_vacuum == 1);
}
// If auto_vacuum is set, there's an extra page to maintain a freelist.
const int kExpectedPageCount = 2 + pragma_auto_vacuum;
{
Statement s(db_->GetUniqueStatement("PRAGMA page_count"));
ASSERT_TRUE(s.Step());
EXPECT_EQ(kExpectedPageCount, s.ColumnInt(0));
}
{
Statement s(db_->GetUniqueStatement("SELECT * FROM sqlite_schema"));
ASSERT_TRUE(s.Step());
EXPECT_EQ("table", s.ColumnString(0));
EXPECT_EQ("foo", s.ColumnString(1));
EXPECT_EQ("foo", s.ColumnString(2));
// Table "foo" is stored in the last page of the file.
EXPECT_EQ(kExpectedPageCount, s.ColumnInt(3));
EXPECT_EQ(kCreateSql, s.ColumnString(4));
}
ASSERT_TRUE(db_->Raze());
{
Statement s(db_->GetUniqueStatement("PRAGMA page_count"));
ASSERT_TRUE(s.Step());
EXPECT_EQ(1, s.ColumnInt(0));
}
ASSERT_EQ(0, SqliteSchemaCount(db_.get()));
{
Statement s(db_->GetUniqueStatement("PRAGMA auto_vacuum"));
ASSERT_TRUE(s.Step());
// The new database has the same auto_vacuum as a fresh database.
EXPECT_EQ(pragma_auto_vacuum, s.ColumnInt(0));
}
}
TEST_P(SQLDatabaseTest, RazeDuringSelect) {
ASSERT_TRUE(
db_->Execute("CREATE TABLE rows(id INTEGER PRIMARY KEY NOT NULL)"));
ASSERT_TRUE(db_->Execute("INSERT INTO rows(id) VALUES(1)"));
ASSERT_TRUE(db_->Execute("INSERT INTO rows(id) VALUES(2)"));
{
// SELECT implicitly creates a transaction while it's executing. This
// implicit transaction will not be caught by Raze()'s checks.
Statement select(db_->GetUniqueStatement("SELECT id FROM rows"));
ASSERT_TRUE(select.Step());
EXPECT_FALSE(db_->Raze()) << "Raze() should fail while SELECT is executing";
}
{
Statement count(db_->GetUniqueStatement("SELECT COUNT(*) FROM rows"));
ASSERT_TRUE(count.Step());
EXPECT_EQ(2, count.ColumnInt(0)) << "Raze() deleted some data";
}
}
// Helper for SQLDatabaseTest.RazePageSize. Creates a fresh db based on
// db_prefix, with the given initial page size, and verifies it against the
// expected size. Then changes to the final page size and razes, verifying that
// the fresh database ends up with the expected final page size.
void TestPageSize(const base::FilePath& db_prefix,
int initial_page_size,
const std::string& expected_initial_page_size,
int final_page_size,
const std::string& expected_final_page_size) {
static const char kCreateSql[] = "CREATE TABLE x (t TEXT)";
static const char kInsertSql1[] = "INSERT INTO x VALUES ('This is a test')";
static const char kInsertSql2[] = "INSERT INTO x VALUES ('That was a test')";
const base::FilePath db_path = db_prefix.InsertBeforeExtensionASCII(
base::NumberToString(initial_page_size));
Database::Delete(db_path);
Database db({.page_size = initial_page_size});
ASSERT_TRUE(db.Open(db_path));
ASSERT_TRUE(db.Execute(kCreateSql));
ASSERT_TRUE(db.Execute(kInsertSql1));
ASSERT_TRUE(db.Execute(kInsertSql2));
ASSERT_EQ(expected_initial_page_size,
ExecuteWithResult(&db, "PRAGMA page_size"));
db.Close();
// Re-open the database while setting a new |options.page_size| in the object.
Database razed_db({.page_size = final_page_size});
ASSERT_TRUE(razed_db.Open(db_path));
// Raze will use the page size set in the connection object, which may not
// match the file's page size.
ASSERT_TRUE(razed_db.Raze());
// SQLite 3.10.2 (at least) has a quirk with the sqlite3_backup() API (used by
// Raze()) which causes the destination database to remember the previous
// page_size, even if the overwriting database changed the page_size. Access
// the actual database to cause the cached value to be updated.
EXPECT_EQ("0",
ExecuteWithResult(&razed_db, "SELECT COUNT(*) FROM sqlite_schema"));
EXPECT_EQ(expected_final_page_size,
ExecuteWithResult(&razed_db, "PRAGMA page_size"));
EXPECT_EQ("1", ExecuteWithResult(&razed_db, "PRAGMA page_count"));
}
// Verify that Recovery maintains the page size, and the virtual table
// works with page sizes other than SQLite's default. Also verify the case
// where the default page size has changed.
TEST_P(SQLDatabaseTest, RazePageSize) {
const std::string default_page_size =
ExecuteWithResult(db_.get(), "PRAGMA page_size");
// Sync uses 32k pages.
EXPECT_NO_FATAL_FAILURE(
TestPageSize(db_path_, 32768, "32768", 32768, "32768"));
// Many clients use 4k pages. This is the SQLite default after 3.12.0.
EXPECT_NO_FATAL_FAILURE(TestPageSize(db_path_, 4096, "4096", 4096, "4096"));
// 1k is the default page size before 3.12.0.
EXPECT_NO_FATAL_FAILURE(TestPageSize(db_path_, 1024, "1024", 1024, "1024"));
EXPECT_NO_FATAL_FAILURE(TestPageSize(db_path_, 2048, "2048", 4096, "4096"));
// Databases with no page size specified should result in the default
// page size. 2k has never been the default page size.
ASSERT_NE("2048", default_page_size);
EXPECT_NO_FATAL_FAILURE(TestPageSize(db_path_, 2048, "2048",
DatabaseOptions::kDefaultPageSize,
default_page_size));
}
// Test that Raze() results are seen in other connections.
TEST_P(SQLDatabaseTest, RazeMultiple) {
const char* kCreateSql = "CREATE TABLE foo (id INTEGER PRIMARY KEY, value)";
ASSERT_TRUE(db_->Execute(kCreateSql));
Database other_db(GetDBOptions());
ASSERT_TRUE(other_db.Open(db_path_));
// Check that the second connection sees the table.
ASSERT_EQ(1, SqliteSchemaCount(&other_db));
ASSERT_TRUE(db_->Raze());
// The second connection sees the updated database.
ASSERT_EQ(0, SqliteSchemaCount(&other_db));
}
TEST_P(SQLDatabaseTest, Raze_OtherConnectionHasWriteLock) {
ASSERT_TRUE(db_->Execute("CREATE TABLE rows(id INTEGER PRIMARY KEY)"));
Database other_db(GetDBOptions());
ASSERT_TRUE(other_db.Open(db_path_));
Transaction other_db_transaction(&other_db);
ASSERT_TRUE(other_db_transaction.Begin());
ASSERT_TRUE(other_db.Execute("INSERT INTO rows(id) VALUES(1)"));
EXPECT_FALSE(db_->Raze())
<< "Raze() should fail while another connection has a write lock";
ASSERT_TRUE(other_db_transaction.Commit());
EXPECT_TRUE(db_->Raze())
<< "Raze() should succeed after the other connection releases the lock";
}
TEST_P(SQLDatabaseTest, Raze_OtherConnectionHasReadLock) {
ASSERT_TRUE(db_->Execute("CREATE TABLE rows(id INTEGER PRIMARY KEY)"));
ASSERT_TRUE(db_->Execute("INSERT INTO rows(id) VALUES(1)"));
if (IsWALEnabled()) {
// In WAL mode, read transactions in other connections do not block a write
// transaction.
return;
}
Database other_db(GetDBOptions());
ASSERT_TRUE(other_db.Open(db_path_));
Statement select(other_db.GetUniqueStatement("SELECT id FROM rows"));
ASSERT_TRUE(select.Step());
EXPECT_FALSE(db_->Raze())
<< "Raze() should fail while another connection has a read lock";
ASSERT_FALSE(select.Step())
<< "The SELECT statement should not produce more than one row";
EXPECT_TRUE(db_->Raze())
<< "Raze() should succeed after the other connection releases the lock";
}
TEST_P(SQLDatabaseTest, Raze_EmptyDatabaseFile) {
ASSERT_TRUE(
db_->Execute("CREATE TABLE rows(id INTEGER PRIMARY KEY NOT NULL)"));
db_->Close();
ASSERT_TRUE(TruncateDatabase());
ASSERT_TRUE(db_->Open(db_path_))
<< "Failed to reopen database after truncating";
EXPECT_TRUE(db_->Raze()) << "Raze() failed on an empty file";
EXPECT_TRUE(
db_->Execute("CREATE TABLE rows(id INTEGER PRIMARY KEY NOT NULL)"))
<< "Raze() did not produce a healthy empty database";
}
// Verify that Raze() can handle a file of junk.
// Need exclusive mode off here as there are some subtleties (by design) around
// how the cache is used with it on which causes the test to fail.
TEST_P(SQLDatabaseTest, RazeNOTADB) {
db_->Close();
Database::Delete(db_path_);
ASSERT_FALSE(base::PathExists(db_path_));
ASSERT_TRUE(OverwriteDatabaseHeader(OverwriteType::kTruncate));
ASSERT_TRUE(base::PathExists(db_path_));
// SQLite will successfully open the handle, but fail when running PRAGMA
// statements that access the database.
{
sql::test::ScopedErrorExpecter expecter;
expecter.ExpectError(SQLITE_NOTADB);
EXPECT_TRUE(db_->Open(db_path_));
ASSERT_TRUE(expecter.SawExpectedErrors());
}
EXPECT_TRUE(db_->Raze());
db_->Close();
// Now empty, the open should open an empty database.
EXPECT_TRUE(db_->Open(db_path_));
EXPECT_EQ(0, SqliteSchemaCount(db_.get()));
}
// Verify that Raze() can handle a database overwritten with garbage.
TEST_P(SQLDatabaseTest, RazeNOTADB2) {
const char* kCreateSql = "CREATE TABLE foo (id INTEGER PRIMARY KEY, value)";
ASSERT_TRUE(db_->Execute(kCreateSql));
ASSERT_EQ(1, SqliteSchemaCount(db_.get()));
db_->Close();
ASSERT_TRUE(OverwriteDatabaseHeader(OverwriteType::kOverwrite));
// SQLite will successfully open the handle, but will fail with
// SQLITE_NOTADB on pragma statemenets which attempt to read the
// corrupted header.
{
sql::test::ScopedErrorExpecter expecter;
expecter.ExpectError(SQLITE_NOTADB);
EXPECT_TRUE(db_->Open(db_path_));
ASSERT_TRUE(expecter.SawExpectedErrors());
}
EXPECT_TRUE(db_->Raze());
db_->Close();
// Now empty, the open should succeed with an empty database.
EXPECT_TRUE(db_->Open(db_path_));
EXPECT_EQ(0, SqliteSchemaCount(db_.get()));
}
// Test that a callback from Open() can raze the database. This is
// essential for cases where the Open() can fail entirely, so the
// Raze() cannot happen later. Additionally test that when the
// callback does this during Open(), the open is retried and succeeds.
TEST_P(SQLDatabaseTest, RazeCallbackReopen) {
const char* kCreateSql = "CREATE TABLE foo (id INTEGER PRIMARY KEY, value)";
ASSERT_TRUE(db_->Execute(kCreateSql));
ASSERT_EQ(1, SqliteSchemaCount(db_.get()));
db_->Close();
// Corrupt the database so that nothing works, including PRAGMAs.
ASSERT_TRUE(sql::test::CorruptSizeInHeader(db_path_));
// Open() will succeed, even though the PRAGMA calls within will
// fail with SQLITE_CORRUPT, as will this PRAGMA.
{
sql::test::ScopedErrorExpecter expecter;
expecter.ExpectError(SQLITE_CORRUPT);
ASSERT_TRUE(db_->Open(db_path_));
ASSERT_FALSE(db_->Execute("PRAGMA auto_vacuum"));
db_->Close();
ASSERT_TRUE(expecter.SawExpectedErrors());
}
db_->set_error_callback(
base::BindRepeating(&RazeErrorCallback, db_.get(), SQLITE_CORRUPT));
// When the PRAGMA calls in Open() raise SQLITE_CORRUPT, the error
// callback will call RazeAndClose(). Open() will then fail and be
// retried. The second Open() on the empty database will succeed
// cleanly.
ASSERT_TRUE(db_->Open(db_path_));
ASSERT_TRUE(db_->Execute("PRAGMA auto_vacuum"));
EXPECT_EQ(0, SqliteSchemaCount(db_.get()));
}
TEST_P(SQLDatabaseTest, RazeAndClose_DeletesData) {
ASSERT_TRUE(
db_->Execute("CREATE TABLE rows(id INTEGER PRIMARY KEY NOT NULL)"));
ASSERT_TRUE(db_->Execute("INSERT INTO rows(id) VALUES(12)"));
ASSERT_TRUE(db_->RazeAndClose());
// RazeAndClose() actually Poison()s. We need to call Close() in order to
// re-Open(). crbug.com/1311771 tracks renaming RazeAndClose().
db_->Close();
ASSERT_TRUE(db_->Open(db_path_))
<< "RazeAndClose() did not produce a healthy database";
EXPECT_TRUE(
db_->Execute("CREATE TABLE rows(id INTEGER PRIMARY KEY NOT NULL)"))
<< "RazeAndClose() did not produce a healthy empty database";
}
TEST_P(SQLDatabaseTest, RazeAndClose_IsOpen) {
ASSERT_TRUE(
db_->Execute("CREATE TABLE rows(id INTEGER PRIMARY KEY NOT NULL)"));
ASSERT_TRUE(db_->Execute("INSERT INTO rows(id) VALUES(12)"));
ASSERT_TRUE(db_->RazeAndClose());
EXPECT_FALSE(db_->is_open())
<< "RazeAndClose() did not mark the database as closed";
}
TEST_P(SQLDatabaseTest, RazeAndClose_Reopen_NoChanges) {
ASSERT_TRUE(db_->RazeAndClose());
EXPECT_FALSE(
db_->Execute("CREATE TABLE rows(id INTEGER PRIMARY KEY NOT NULL)"))
<< "Execute() should return false after RazeAndClose()";
// RazeAndClose() actually Poison()s. We need to call Close() in order to
// re-Open(). crbug.com/1311771 tracks renaming RazeAndClose().
db_->Close();
ASSERT_TRUE(db_->Open(db_path_))
<< "RazeAndClose() did not produce a healthy database";
EXPECT_TRUE(
db_->Execute("CREATE TABLE rows(id INTEGER PRIMARY KEY NOT NULL)"))
<< "Execute() returned false but went through after RazeAndClose()";
}
TEST_P(SQLDatabaseTest, RazeAndClose_OpenTransaction) {
ASSERT_TRUE(
db_->Execute("CREATE TABLE rows(id INTEGER PRIMARY KEY NOT NULL)"));
ASSERT_TRUE(db_->Execute("INSERT INTO rows(id) VALUES(12)"));
Transaction transaction(db_.get());
ASSERT_TRUE(transaction.Begin());
ASSERT_TRUE(db_->RazeAndClose());
EXPECT_FALSE(db_->is_open())
<< "RazeAndClose() did not mark the database as closed";
EXPECT_FALSE(transaction.Commit())
<< "RazeAndClose() did not cancel the transaction";
// RazeAndClose() actually Poison()s. We need to call Close() in order to
// re-Open(). crbug.com/1311771 tracks renaming RazeAndClose().
db_->Close();
ASSERT_TRUE(db_->Open(db_path_));
EXPECT_TRUE(
db_->Execute("CREATE TABLE rows(id INTEGER PRIMARY KEY NOT NULL)"))
<< "RazeAndClose() did not produce a healthy empty database";
}
TEST_P(SQLDatabaseTest, RazeAndClose_Preload_NoCrash) {
db_->Preload();
db_->RazeAndClose();
db_->Preload();
}
TEST_P(SQLDatabaseTest, RazeAndClose_DoesTableExist) {
ASSERT_TRUE(
db_->Execute("CREATE TABLE rows(id INTEGER PRIMARY KEY NOT NULL)"));
ASSERT_TRUE(db_->DoesTableExist("rows")) << "Incorrect test setup";
ASSERT_TRUE(db_->RazeAndClose());
EXPECT_FALSE(db_->DoesTableExist("rows"))
<< "DoesTableExist() should return false after RazeAndClose()";
}
TEST_P(SQLDatabaseTest, RazeAndClose_IsSQLValid) {
ASSERT_TRUE(db_->IsSQLValid("SELECT 1")) << "Incorrect test setup";
ASSERT_TRUE(db_->RazeAndClose());
EXPECT_FALSE(db_->IsSQLValid("SELECT 1"))
<< "IsSQLValid() should return false after RazeAndClose()";
}
TEST_P(SQLDatabaseTest, RazeAndClose_Execute) {
ASSERT_TRUE(db_->Execute("SELECT 1")) << "Incorrect test setup";
ASSERT_TRUE(db_->RazeAndClose());
EXPECT_FALSE(db_->Execute("SELECT 1"))
<< "Execute() should return false after RazeAndClose()";
}
TEST_P(SQLDatabaseTest, RazeAndClose_GetUniqueStatement) {
{
Statement select(db_->GetUniqueStatement("SELECT 1"));
ASSERT_TRUE(select.Step()) << "Incorrect test setup";
}
ASSERT_TRUE(db_->RazeAndClose());
{
Statement select(db_->GetUniqueStatement("SELECT 1"));
EXPECT_FALSE(select.Step())
<< "GetUniqueStatement() should return an invalid Statement after "
<< "RazeAndClose()";
}
}
TEST_P(SQLDatabaseTest, RazeAndClose_GetCachedStatement) {
{
Statement select(db_->GetCachedStatement(SQL_FROM_HERE, "SELECT 1"));
ASSERT_TRUE(select.Step()) << "Incorrect test setup";
}
ASSERT_TRUE(db_->RazeAndClose());
{
Statement select(db_->GetCachedStatement(SQL_FROM_HERE, "SELECT 1"));
EXPECT_FALSE(select.Step())
<< "GetCachedStatement() should return an invalid Statement after "
<< "RazeAndClose()";
}
}
TEST_P(SQLDatabaseTest, RazeAndClose_InvalidatesUniqueStatement) {
Statement select(db_->GetUniqueStatement("SELECT 1"));
ASSERT_TRUE(select.is_valid()) << "Incorrect test setup";
ASSERT_TRUE(select.Step()) << "Incorrect test setup";
select.Reset(/*clear_bound_vars=*/true);
ASSERT_TRUE(db_->RazeAndClose());
EXPECT_FALSE(select.is_valid())
<< "RazeAndClose() should invalidate live Statements";
EXPECT_FALSE(select.Step())
<< "RazeAndClose() should invalidate live Statements";
}
TEST_P(SQLDatabaseTest, RazeAndClose_InvalidatesCachedStatement) {
Statement select(db_->GetCachedStatement(SQL_FROM_HERE, "SELECT 1"));
ASSERT_TRUE(select.is_valid()) << "Incorrect test setup";
ASSERT_TRUE(select.Step()) << "Incorrect test setup";
select.Reset(/*clear_bound_vars=*/true);
ASSERT_TRUE(db_->RazeAndClose());
EXPECT_FALSE(select.is_valid())
<< "RazeAndClose() should invalidate live Statements";
EXPECT_FALSE(select.Step())
<< "RazeAndClose() should invalidate live Statements";
}
TEST_P(SQLDatabaseTest, RazeAndClose_TransactionBegin) {
{
Transaction transaction(db_.get());
ASSERT_TRUE(transaction.Begin()) << "Incorrect test setup";
ASSERT_TRUE(transaction.Commit()) << "Incorrect test setup";
}
ASSERT_TRUE(db_->RazeAndClose());
{
Transaction transaction(db_.get());
EXPECT_FALSE(transaction.Begin())
<< "Transaction::Begin() should return false after RazeAndClose()";
EXPECT_FALSE(transaction.IsActiveForTesting())
<< "RazeAndClose() should block transactions from starting";
}
}
TEST_P(SQLDatabaseTest, Close_IsSQLValid) {
ASSERT_TRUE(db_->IsSQLValid("SELECT 1")) << "Incorrect test setup";
db_->Close();
EXPECT_DCHECK_DEATH_WITH({ std::ignore = db_->IsSQLValid("SELECT 1"); },
"Illegal use of Database without a db");
}
// On Windows, truncate silently fails against a memory-mapped file. One goal
// of Raze() is to truncate the file to remove blocks which generate I/O errors.
// Test that Raze() turns off memory mapping so that the file is truncated.
// [This would not cover the case of multiple connections where one of the other
// connections is memory-mapped. That is infrequent in Chromium.]
TEST_P(SQLDatabaseTest, RazeTruncate) {
// The empty database has 0 or 1 pages. Raze() should leave it with exactly 1
// page. Not checking directly because auto_vacuum on Android adds a freelist
// page.
ASSERT_TRUE(db_->Raze());
int64_t expected_size;
ASSERT_TRUE(base::GetFileSize(db_path_, &expected_size));
ASSERT_GT(expected_size, 0);
// Cause the database to take a few pages.
const char* kCreateSql = "CREATE TABLE foo (id INTEGER PRIMARY KEY, value)";
ASSERT_TRUE(db_->Execute(kCreateSql));
for (size_t i = 0; i < 24; ++i) {
ASSERT_TRUE(
db_->Execute("INSERT INTO foo (value) VALUES (randomblob(1024))"));
}
// In WAL mode, writes don't reach the database file until a checkpoint
// happens.
ASSERT_TRUE(db_->CheckpointDatabase());
int64_t db_size;
ASSERT_TRUE(base::GetFileSize(db_path_, &db_size));
ASSERT_GT(db_size, expected_size);
// Make a query covering most of the database file to make sure that the
// blocks are actually mapped into memory. Empirically, the truncate problem
// doesn't seem to happen if no blocks are mapped.
EXPECT_EQ("24576",
ExecuteWithResult(db_.get(), "SELECT SUM(LENGTH(value)) FROM foo"));
ASSERT_TRUE(db_->Raze());
ASSERT_TRUE(base::GetFileSize(db_path_, &db_size));
ASSERT_EQ(expected_size, db_size);
}
#if BUILDFLAG(IS_ANDROID)
TEST_P(SQLDatabaseTest, SetTempDirForSQL) {
MetaTable meta_table;
// Below call needs a temporary directory in sqlite3
// On Android, it can pass only when the temporary directory is set.
// Otherwise, sqlite3 doesn't find the correct directory to store
// temporary files and will report the error 'unable to open
// database file'.
ASSERT_TRUE(meta_table.Init(db_.get(), 4, 4));
}
#endif // BUILDFLAG(IS_ANDROID)
TEST_P(SQLDatabaseTest, Delete) {
EXPECT_TRUE(db_->Execute("CREATE TABLE x (x)"));
db_->Close();
base::FilePath journal_path = Database::JournalPath(db_path_);
base::FilePath wal_path = Database::WriteAheadLogPath(db_path_);
// Should have both a main database file and a journal file if
// journal_mode is TRUNCATE. There is no WAL file as it is deleted on Close.
ASSERT_TRUE(base::PathExists(db_path_));
if (!IsWALEnabled()) { // TRUNCATE mode
ASSERT_TRUE(base::PathExists(journal_path));
}
Database::Delete(db_path_);
EXPECT_FALSE(base::PathExists(db_path_));
EXPECT_FALSE(base::PathExists(journal_path));
EXPECT_FALSE(base::PathExists(wal_path));
}
#if BUILDFLAG(IS_POSIX) // This test operates on POSIX file permissions.
TEST_P(SQLDatabaseTest, PosixFilePermissions) {
db_->Close();
Database::Delete(db_path_);
ASSERT_FALSE(base::PathExists(db_path_));
// If the bots all had a restrictive umask setting such that databases are
// always created with only the owner able to read them, then the code could
// break without breaking the tests. Temporarily provide a more permissive
// umask.
ScopedUmaskSetter permissive_umask(S_IWGRP | S_IWOTH);
ASSERT_TRUE(db_->Open(db_path_));
// Cause the journal file to be created. If the default journal_mode is
// changed back to DELETE, this test will need to be updated.
EXPECT_TRUE(db_->Execute("CREATE TABLE x (x)"));
int mode;
ASSERT_TRUE(base::PathExists(db_path_));
EXPECT_TRUE(base::GetPosixFilePermissions(db_path_, &mode));
ASSERT_EQ(mode, 0600);
if (IsWALEnabled()) { // WAL mode
// The WAL file is created lazily on first change.
ASSERT_TRUE(db_->Execute("CREATE TABLE foo (a, b)"));
base::FilePath wal_path = Database::WriteAheadLogPath(db_path_);
ASSERT_TRUE(base::PathExists(wal_path));
EXPECT_TRUE(base::GetPosixFilePermissions(wal_path, &mode));
ASSERT_EQ(mode, 0600);
// The shm file doesn't exist in exclusive locking mode.
if (ExecuteWithResult(db_.get(), "PRAGMA locking_mode") == "normal") {
base::FilePath shm_path = Database::SharedMemoryFilePath(db_path_);
ASSERT_TRUE(base::PathExists(shm_path));
EXPECT_TRUE(base::GetPosixFilePermissions(shm_path, &mode));
ASSERT_EQ(mode, 0600);
}
} else { // Truncate mode
base::FilePath journal_path = Database::JournalPath(db_path_);
DLOG(ERROR) << "journal_path: " << journal_path;
ASSERT_TRUE(base::PathExists(journal_path));
EXPECT_TRUE(base::GetPosixFilePermissions(journal_path, &mode));
ASSERT_EQ(mode, 0600);
}
}
#endif // BUILDFLAG(IS_POSIX)
TEST_P(SQLDatabaseTest, Poison_IsOpen) {
db_->Poison();
EXPECT_FALSE(db_->is_open())
<< "Poison() did not mark the database as closed";
}
TEST_P(SQLDatabaseTest, Poison_Close_Reopen_NoChanges) {
db_->Poison();
EXPECT_FALSE(
db_->Execute("CREATE TABLE rows(id INTEGER PRIMARY KEY NOT NULL)"))
<< "Execute() should return false after Poison()";
db_->Close();
ASSERT_TRUE(db_->Open(db_path_)) << "Poison() damaged the database";
EXPECT_TRUE(
db_->Execute("CREATE TABLE rows(id INTEGER PRIMARY KEY NOT NULL)"))
<< "Execute() returned false but went through after Poison()";
}
TEST_P(SQLDatabaseTest, Poison_Preload_NoCrash) {
db_->Preload();
db_->Poison();
db_->Preload();
}
TEST_P(SQLDatabaseTest, Poison_DoesTableExist) {
ASSERT_TRUE(
db_->Execute("CREATE TABLE rows(id INTEGER PRIMARY KEY NOT NULL)"));
ASSERT_TRUE(db_->DoesTableExist("rows")) << "Incorrect test setup";
db_->Poison();
EXPECT_FALSE(db_->DoesTableExist("rows"))
<< "DoesTableExist() should return false after Poison()";
}
TEST_P(SQLDatabaseTest, Poison_IsSQLValid) {
ASSERT_TRUE(db_->IsSQLValid("SELECT 1")) << "Incorrect test setup";
db_->Poison();
EXPECT_FALSE(db_->IsSQLValid("SELECT 1"))
<< "IsSQLValid() should return false after Poison()";
}
TEST_P(SQLDatabaseTest, Poison_Execute) {
ASSERT_TRUE(db_->Execute("SELECT 1")) << "Incorrect test setup";
db_->Poison();
EXPECT_FALSE(db_->Execute("SELECT 1"))
<< "Execute() should return false after Poison()";
}
TEST_P(SQLDatabaseTest, Poison_GetUniqueStatement) {
{
Statement select(db_->GetUniqueStatement("SELECT 1"));
ASSERT_TRUE(select.Step()) << "Incorrect test setup";
}
db_->Poison();
{
Statement select(db_->GetUniqueStatement("SELECT 1"));
EXPECT_FALSE(select.Step())
<< "GetUniqueStatement() should return an invalid Statement after "
<< "Poison()";
}
}
TEST_P(SQLDatabaseTest, Poison_GetCachedStatement) {
{
Statement select(db_->GetCachedStatement(SQL_FROM_HERE, "SELECT 1"));
ASSERT_TRUE(select.Step()) << "Incorrect test setup";
}
db_->Poison();
{
Statement select(db_->GetCachedStatement(SQL_FROM_HERE, "SELECT 1"));
EXPECT_FALSE(select.Step())
<< "GetCachedStatement() should return an invalid Statement after "
<< "Poison()";
}
}
TEST_P(SQLDatabaseTest, Poison_InvalidatesUniqueStatement) {
Statement select(db_->GetUniqueStatement("SELECT 1"));
ASSERT_TRUE(select.is_valid()) << "Incorrect test setup";
ASSERT_TRUE(select.Step()) << "Incorrect test setup";
select.Reset(/*clear_bound_vars=*/true);
db_->Poison();
EXPECT_FALSE(select.is_valid())
<< "Poison() should invalidate live Statements";
EXPECT_FALSE(select.Step()) << "Poison() should invalidate live Statements";
}
TEST_P(SQLDatabaseTest, Poison_InvalidatesCachedStatement) {
Statement select(db_->GetCachedStatement(SQL_FROM_HERE, "SELECT 1"));
ASSERT_TRUE(select.is_valid()) << "Incorrect test setup";
ASSERT_TRUE(select.Step()) << "Incorrect test setup";
select.Reset(/*clear_bound_vars=*/true);
db_->Poison();
EXPECT_FALSE(select.is_valid())
<< "Poison() should invalidate live Statements";
EXPECT_FALSE(select.Step()) << "Poison() should invalidate live Statements";
}
TEST_P(SQLDatabaseTest, Poison_TransactionBegin) {
{
Transaction transaction(db_.get());
ASSERT_TRUE(transaction.Begin()) << "Incorrect test setup";
ASSERT_TRUE(transaction.Commit()) << "Incorrect test setup";
}
db_->Poison();
{
Transaction transaction(db_.get());
EXPECT_FALSE(transaction.Begin())
<< "Transaction::Begin() should return false after Poison()";
EXPECT_FALSE(transaction.IsActiveForTesting())
<< "Poison() should block transactions from starting";
}
}
TEST_P(SQLDatabaseTest, Poison_OpenTransaction) {
Transaction transaction(db_.get());
ASSERT_TRUE(transaction.Begin());
db_->Poison();
EXPECT_FALSE(transaction.Commit())
<< "Poison() did not cancel the transaction";
}
TEST_P(SQLDatabaseTest, AttachDatabase) {
ASSERT_TRUE(
db_->Execute("CREATE TABLE rows(id INTEGER PRIMARY KEY NOT NULL)"));
// Create a database to attach to.
base::FilePath attach_path =
db_path_.DirName().AppendASCII("attach_database_test.db");
static constexpr char kAttachmentPoint[] = "other";
{
Database other_db;
ASSERT_TRUE(other_db.Open(attach_path));
ASSERT_TRUE(
other_db.Execute("CREATE TABLE rows(id INTEGER PRIMARY KEY NOT NULL)"));
ASSERT_TRUE(other_db.Execute("INSERT INTO rows VALUES(42)"));
}
// Cannot see the attached database, yet.
EXPECT_FALSE(db_->IsSQLValid("SELECT COUNT(*) from other.rows"));
EXPECT_TRUE(DatabaseTestPeer::AttachDatabase(db_.get(), attach_path,
kAttachmentPoint));
EXPECT_TRUE(db_->IsSQLValid("SELECT COUNT(*) from other.rows"));
// Queries can touch both databases after the ATTACH.
EXPECT_TRUE(db_->Execute("INSERT INTO rows SELECT id FROM other.rows"));
{
Statement select(db_->GetUniqueStatement("SELECT COUNT(*) FROM rows"));
ASSERT_TRUE(select.Step());
EXPECT_EQ(1, select.ColumnInt(0));
}
EXPECT_TRUE(DatabaseTestPeer::DetachDatabase(db_.get(), kAttachmentPoint));
EXPECT_FALSE(db_->IsSQLValid("SELECT COUNT(*) from other.rows"));
}
TEST_P(SQLDatabaseTest, AttachDatabaseWithOpenTransaction) {
ASSERT_TRUE(
db_->Execute("CREATE TABLE rows(id INTEGER PRIMARY KEY NOT NULL)"));
// Create a database to attach to.
base::FilePath attach_path =
db_path_.DirName().AppendASCII("attach_database_test.db");
static constexpr char kAttachmentPoint[] = "other";
{
Database other_db;
ASSERT_TRUE(other_db.Open(attach_path));
ASSERT_TRUE(
other_db.Execute("CREATE TABLE rows(id INTEGER PRIMARY KEY NOT NULL)"));
ASSERT_TRUE(other_db.Execute("INSERT INTO rows VALUES(42)"));
}
// Cannot see the attached database, yet.
EXPECT_FALSE(db_->IsSQLValid("SELECT COUNT(*) from other.rows"));
// Attach succeeds in a transaction.
Transaction transaction(db_.get());
EXPECT_TRUE(transaction.Begin());
EXPECT_TRUE(DatabaseTestPeer::AttachDatabase(db_.get(), attach_path,
kAttachmentPoint));
EXPECT_TRUE(db_->IsSQLValid("SELECT COUNT(*) from other.rows"));
// Queries can touch both databases after the ATTACH.
EXPECT_TRUE(db_->Execute("INSERT INTO rows SELECT id FROM other.rows"));
{
Statement select(db_->GetUniqueStatement("SELECT COUNT(*) FROM rows"));
ASSERT_TRUE(select.Step());
EXPECT_EQ(1, select.ColumnInt(0));
}
// Detaching the same database fails, database is locked in the transaction.
{
sql::test::ScopedErrorExpecter expecter;
expecter.ExpectError(SQLITE_ERROR);
EXPECT_FALSE(DatabaseTestPeer::DetachDatabase(db_.get(), kAttachmentPoint));
ASSERT_TRUE(expecter.SawExpectedErrors());
}
EXPECT_TRUE(db_->IsSQLValid("SELECT COUNT(*) from other.rows"));
// Detach succeeds when the transaction is closed.
transaction.Rollback();
EXPECT_TRUE(DatabaseTestPeer::DetachDatabase(db_.get(), kAttachmentPoint));
EXPECT_FALSE(db_->IsSQLValid("SELECT COUNT(*) from other.rows"));
}
TEST_P(SQLDatabaseTest, FullIntegrityCheck) {
static constexpr char kTableSql[] =
"CREATE TABLE rows(id INTEGER PRIMARY KEY NOT NULL, value TEXT NOT NULL)";
ASSERT_TRUE(db_->Execute(kTableSql));
ASSERT_TRUE(db_->Execute("CREATE INDEX rows_by_value ON rows(value)"));
{
std::vector<std::string> messages;
EXPECT_TRUE(db_->FullIntegrityCheck(&messages))
<< "FullIntegrityCheck() failed before database was corrupted";
EXPECT_THAT(messages, testing::ElementsAre("ok"))
<< "FullIntegrityCheck() should report ok before database is corrupted";
}
db_->Close();
ASSERT_TRUE(sql::test::CorruptIndexRootPage(db_path_, "rows_by_value"));
ASSERT_TRUE(db_->Open(db_path_));
{
std::vector<std::string> messages;
EXPECT_TRUE(db_->FullIntegrityCheck(&messages))
<< "FullIntegrityCheck() failed on corrupted database";
EXPECT_THAT(messages, testing::Not(testing::ElementsAre("ok")))
<< "FullIntegrityCheck() should not report ok for a corrupted database";
}
}
TEST_P(SQLDatabaseTest, OnMemoryDump) {
base::trace_event::MemoryDumpArgs args = {
base::trace_event::MemoryDumpLevelOfDetail::DETAILED};
base::trace_event::ProcessMemoryDump pmd(args);
ASSERT_TRUE(db_->memory_dump_provider_->OnMemoryDump(args, &pmd));
EXPECT_GE(pmd.allocator_dumps().size(), 1u);
}
// Test that the functions to collect diagnostic data run to completion, without
// worrying too much about what they generate (since that will change).
TEST_P(SQLDatabaseTest, CollectDiagnosticInfo) {
const std::string corruption_info = db_->CollectCorruptionInfo();
EXPECT_NE(std::string::npos, corruption_info.find("SQLITE_CORRUPT"));
EXPECT_NE(std::string::npos, corruption_info.find("integrity_check"));
// A statement to see in the results.
const char* kSimpleSql = "SELECT 'mountain'";
Statement s(db_->GetCachedStatement(SQL_FROM_HERE, kSimpleSql));
// Error includes the statement.
const std::string readonly_info = db_->CollectErrorInfo(SQLITE_READONLY, &s);
EXPECT_NE(std::string::npos, readonly_info.find(kSimpleSql));
// Some other error doesn't include the statment.
// TODO(shess): This is weak.
const std::string full_info = db_->CollectErrorInfo(SQLITE_FULL, nullptr);
EXPECT_EQ(std::string::npos, full_info.find(kSimpleSql));
// A table to see in the SQLITE_ERROR results.
EXPECT_TRUE(db_->Execute("CREATE TABLE volcano (x)"));
// Version info to see in the SQLITE_ERROR results.
MetaTable meta_table;
ASSERT_TRUE(meta_table.Init(db_.get(), 4, 4));
const std::string error_info = db_->CollectErrorInfo(SQLITE_ERROR, &s);
EXPECT_NE(std::string::npos, error_info.find(kSimpleSql));
EXPECT_NE(std::string::npos, error_info.find("volcano"));
EXPECT_NE(std::string::npos, error_info.find("version: 4"));
}
// Test that a fresh database has mmap enabled by default, if mmap'ed I/O is
// enabled by SQLite.
TEST_P(SQLDatabaseTest, MmapInitiallyEnabled) {
{
Statement s(db_->GetUniqueStatement("PRAGMA mmap_size"));
ASSERT_TRUE(s.Step())
<< "All supported SQLite versions should have mmap support";
// If mmap I/O is not on, attempt to turn it on. If that succeeds, then
// Open() should have turned it on. If mmap support is disabled, 0 is
// returned. If the VFS does not understand SQLITE_FCNTL_MMAP_SIZE (for
// instance MojoVFS), -1 is returned.
if (s.ColumnInt(0) <= 0) {
ASSERT_TRUE(db_->Execute("PRAGMA mmap_size = 1048576"));
s.Reset(true);
ASSERT_TRUE(s.Step());
EXPECT_LE(s.ColumnInt(0), 0);
}
}
// Test that explicit disable prevents mmap'ed I/O.
db_->Close();
Database::Delete(db_path_);
db_->set_mmap_disabled();
ASSERT_TRUE(db_->Open(db_path_));
EXPECT_EQ("0", ExecuteWithResult(db_.get(), "PRAGMA mmap_size"));
}
// Test whether a fresh database gets mmap enabled when using alternate status
// storage.
TEST_P(SQLDatabaseTest, MmapInitiallyEnabledAltStatus) {
// Re-open fresh database with alt-status flag set.
db_->Close();
Database::Delete(db_path_);
DatabaseOptions options = GetDBOptions();
options.mmap_alt_status_discouraged = true;
options.enable_views_discouraged = true;
db_ = std::make_unique<Database>(options);
ASSERT_TRUE(db_->Open(db_path_));
{
Statement s(db_->GetUniqueStatement("PRAGMA mmap_size"));
ASSERT_TRUE(s.Step())
<< "All supported SQLite versions should have mmap support";
// If mmap I/O is not on, attempt to turn it on. If that succeeds, then
// Open() should have turned it on. If mmap support is disabled, 0 is
// returned. If the VFS does not understand SQLITE_FCNTL_MMAP_SIZE (for
// instance MojoVFS), -1 is returned.
if (s.ColumnInt(0) <= 0) {
ASSERT_TRUE(db_->Execute("PRAGMA mmap_size = 1048576"));
s.Reset(true);
ASSERT_TRUE(s.Step());
EXPECT_LE(s.ColumnInt(0), 0);
}
}
// Test that explicit disable overrides set_mmap_alt_status().
db_->Close();
Database::Delete(db_path_);
db_->set_mmap_disabled();
ASSERT_TRUE(db_->Open(db_path_));
EXPECT_EQ("0", ExecuteWithResult(db_.get(), "PRAGMA mmap_size"));
}
TEST_P(SQLDatabaseTest, ComputeMmapSizeForOpen) {
const size_t kMmapAlot = 25 * 1024 * 1024;
int64_t mmap_status = MetaTable::kMmapFailure;
// If there is no meta table (as for a fresh database), assume that everything
// should be mapped, and the status of the meta table is not affected.
ASSERT_TRUE(!db_->DoesTableExist("meta"));
ASSERT_GT(db_->ComputeMmapSizeForOpen(), kMmapAlot);
ASSERT_TRUE(!db_->DoesTableExist("meta"));
// When the meta table is first created, it sets up to map everything.
MetaTable().Init(db_.get(), 1, 1);
ASSERT_TRUE(db_->DoesTableExist("meta"));
ASSERT_GT(db_->ComputeMmapSizeForOpen(), kMmapAlot);
ASSERT_TRUE(MetaTable::GetMmapStatus(db_.get(), &mmap_status));
ASSERT_EQ(MetaTable::kMmapSuccess, mmap_status);
// Preload with partial progress of one page. Should map everything.
ASSERT_TRUE(db_->Execute("REPLACE INTO meta VALUES ('mmap_status', 1)"));
ASSERT_GT(db_->ComputeMmapSizeForOpen(), kMmapAlot);
ASSERT_TRUE(MetaTable::GetMmapStatus(db_.get(), &mmap_status));
ASSERT_EQ(MetaTable::kMmapSuccess, mmap_status);
// Failure status maps nothing.
ASSERT_TRUE(db_->Execute("REPLACE INTO meta VALUES ('mmap_status', -2)"));
ASSERT_EQ(0UL, db_->ComputeMmapSizeForOpen());
// Re-initializing the meta table does not re-create the key if the table
// already exists.
ASSERT_TRUE(db_->Execute("DELETE FROM meta WHERE key = 'mmap_status'"));
MetaTable().Init(db_.get(), 1, 1);
ASSERT_EQ(MetaTable::kMmapSuccess, mmap_status);
ASSERT_TRUE(MetaTable::GetMmapStatus(db_.get(), &mmap_status));
ASSERT_EQ(0, mmap_status);
// With no key, map everything and create the key.
// TODO(shess): This really should be "maps everything after validating it",
// but that is more complicated to structure.
ASSERT_GT(db_->ComputeMmapSizeForOpen(), kMmapAlot);
ASSERT_TRUE(MetaTable::GetMmapStatus(db_.get(), &mmap_status));
ASSERT_EQ(MetaTable::kMmapSuccess, mmap_status);
}
TEST_P(SQLDatabaseTest, ComputeMmapSizeForOpenAltStatus) {
const size_t kMmapAlot = 25 * 1024 * 1024;
// At this point, Database still expects a future [meta] table.
ASSERT_FALSE(db_->DoesTableExist("meta"));
ASSERT_FALSE(db_->DoesViewExist("MmapStatus"));
ASSERT_GT(db_->ComputeMmapSizeForOpen(), kMmapAlot);
ASSERT_FALSE(db_->DoesTableExist("meta"));
ASSERT_FALSE(db_->DoesViewExist("MmapStatus"));
// Using alt status, everything should be mapped, with state in the view.
DatabaseOptions options = GetDBOptions();
options.mmap_alt_status_discouraged = true;
options.enable_views_discouraged = true;
db_ = std::make_unique<Database>(options);
ASSERT_TRUE(db_->Open(db_path_));
ASSERT_GT(db_->ComputeMmapSizeForOpen(), kMmapAlot);
ASSERT_FALSE(db_->DoesTableExist("meta"));
ASSERT_TRUE(db_->DoesViewExist("MmapStatus"));
EXPECT_EQ(base::NumberToString(MetaTable::kMmapSuccess),
ExecuteWithResult(db_.get(), "SELECT * FROM MmapStatus"));
// Also maps everything when kMmapSuccess is already in the view.
ASSERT_GT(db_->ComputeMmapSizeForOpen(), kMmapAlot);
// Preload with partial progress of one page. Should map everything.
ASSERT_TRUE(db_->Execute("DROP VIEW MmapStatus"));
ASSERT_TRUE(db_->Execute("CREATE VIEW MmapStatus (value) AS SELECT 1"));
ASSERT_GT(db_->ComputeMmapSizeForOpen(), kMmapAlot);
EXPECT_EQ(base::NumberToString(MetaTable::kMmapSuccess),
ExecuteWithResult(db_.get(), "SELECT * FROM MmapStatus"));
// Failure status leads to nothing being mapped.
ASSERT_TRUE(db_->Execute("DROP VIEW MmapStatus"));
ASSERT_TRUE(db_->Execute("CREATE VIEW MmapStatus (value) AS SELECT -2"));
ASSERT_EQ(0UL, db_->ComputeMmapSizeForOpen());
EXPECT_EQ(base::NumberToString(MetaTable::kMmapFailure),
ExecuteWithResult(db_.get(), "SELECT * FROM MmapStatus"));
}
TEST_P(SQLDatabaseTest, GetMemoryUsage) {
// Databases with mmap enabled may not follow the assumptions below.
db_->Close();
db_->set_mmap_disabled();
ASSERT_TRUE(db_->Open(db_path_));
int initial_memory = db_->GetMemoryUsage();
EXPECT_GT(initial_memory, 0)
<< "SQLite should always use some memory for a database";
ASSERT_TRUE(db_->Execute("CREATE TABLE foo (a, b)"));
ASSERT_TRUE(db_->Execute("INSERT INTO foo(a, b) VALUES (12, 13)"));
int post_query_memory = db_->GetMemoryUsage();
EXPECT_GT(post_query_memory, initial_memory)
<< "Page cache usage should go up after executing queries";
db_->TrimMemory();
int post_trim_memory = db_->GetMemoryUsage();
EXPECT_GT(post_query_memory, post_trim_memory)
<< "Page cache usage should go down after calling TrimMemory()";
}
TEST_P(SQLDatabaseTest, DoubleQuotedStringLiteralsDisabledByDefault) {
ASSERT_TRUE(db_->Execute("CREATE TABLE data(item TEXT NOT NULL);"));
struct TestCase {
const char* sql;
bool is_valid;
};
std::vector<TestCase> test_cases = {
// DML tests.
{"SELECT item FROM data WHERE item >= 'string literal'", true},
{"SELECT item FROM data WHERE item >= \"string literal\"", false},
{"INSERT INTO data(item) VALUES('string literal')", true},
{"INSERT INTO data(item) VALUES(\"string literal\")", false},
{"UPDATE data SET item = 'string literal'", true},
{"UPDATE data SET item = \"string literal\"", false},
{"DELETE FROM data WHERE item >= 'string literal'", true},
{"DELETE FROM data WHERE item >= \"string literal\"", false},
// DDL tests.
{"CREATE INDEX data_item ON data(item) WHERE item >= 'string literal'",
true},
{"CREATE INDEX data_item ON data(item) WHERE item >= \"string literal\"",
false},
{"CREATE TABLE data2(item TEXT DEFAULT 'string literal')", true},
// This should be an invalid DDL statement, due to the double-quoted
// string literal. However, SQLite currently parses it.
{"CREATE TABLE data2(item TEXT DEFAULT \"string literal\")", true},
};
for (const TestCase& test_case : test_cases) {
SCOPED_TRACE(test_case.sql);
EXPECT_EQ(test_case.is_valid, db_->IsSQLValid(test_case.sql));
}
}
TEST_P(SQLDatabaseTest, ForeignKeyEnforcementDisabledByDefault) {
EXPECT_FALSE(GetDBOptions().enable_foreign_keys_discouraged);
ASSERT_TRUE(db_->Execute("CREATE TABLE targets(id INTEGER PRIMARY KEY)"));
// sqlite3_db_config() currently only disables foreign key enforcement. Schema
// operations on foreign keys are still allowed.
ASSERT_TRUE(
db_->Execute("CREATE TABLE refs("
"id INTEGER PRIMARY KEY,"
"target_id INTEGER REFERENCES targets(id))"));
ASSERT_TRUE(db_->Execute("INSERT INTO targets(id) VALUES(42)"));
ASSERT_TRUE(db_->Execute("INSERT INTO refs(id, target_id) VALUES(42, 42)"));
EXPECT_TRUE(db_->Execute("DELETE FROM targets WHERE id=42"))
<< "Foreign key enforcement is not disabled";
}
TEST_P(SQLDatabaseTest, ForeignKeyEnforcementEnabled) {
DatabaseOptions options = GetDBOptions();
options.enable_foreign_keys_discouraged = true;
db_ = std::make_unique<Database>(options);
ASSERT_TRUE(db_->Open(db_path_));
ASSERT_TRUE(db_->Execute("CREATE TABLE targets(id INTEGER PRIMARY KEY)"));
ASSERT_TRUE(
db_->Execute("CREATE TABLE refs("
"id INTEGER PRIMARY KEY,"
"target_id INTEGER REFERENCES targets(id))"));
ASSERT_TRUE(db_->Execute("INSERT INTO targets(id) VALUES(42)"));
ASSERT_TRUE(db_->Execute("INSERT INTO refs(id, target_id) VALUES(42, 42)"));
{
sql::test::ScopedErrorExpecter expecter;
expecter.ExpectError(SQLITE_CONSTRAINT_FOREIGNKEY);
EXPECT_FALSE(db_->Execute("DELETE FROM targets WHERE id=42"))
<< "Foreign key enforcement is disabled";
EXPECT_TRUE(expecter.SawExpectedErrors());
}
}
TEST_P(SQLDatabaseTest, TriggersDisabledByDefault) {
ASSERT_TRUE(db_->Execute("CREATE TABLE data(id INTEGER)"));
// sqlite3_db_config() currently only disables running triggers. Schema
// operations on triggers are still allowed.
EXPECT_TRUE(
db_->Execute("CREATE TRIGGER trigger AFTER INSERT ON data "
"BEGIN DELETE FROM data; END"));
ASSERT_TRUE(db_->Execute("INSERT INTO data(id) VALUES(42)"));
Statement select(db_->GetUniqueStatement("SELECT id FROM data"));
EXPECT_TRUE(select.Step())
<< "If the trigger did not run, the table should not be empty.";
EXPECT_EQ(42, select.ColumnInt64(0));
// sqlite3_db_config() currently only disables running triggers. Schema
// operations on triggers are still allowed.
EXPECT_TRUE(db_->Execute("DROP TRIGGER IF EXISTS trigger"));
}
class SQLDatabaseTestExclusiveMode : public testing::Test,
public testing::WithParamInterface<bool> {
public:
~SQLDatabaseTestExclusiveMode() override = default;
void SetUp() override {
db_ = std::make_unique<Database>(GetDBOptions());
ASSERT_TRUE(temp_dir_.CreateUniqueTempDir());
db_path_ = temp_dir_.GetPath().AppendASCII("recovery_test.sqlite");
ASSERT_TRUE(db_->Open(db_path_));
}
DatabaseOptions GetDBOptions() {
DatabaseOptions options;
options.wal_mode = IsWALEnabled();
options.exclusive_locking = true;
return options;
}
bool IsWALEnabled() { return GetParam(); }
protected:
base::ScopedTempDir temp_dir_;
base::FilePath db_path_;
std::unique_ptr<Database> db_;
};
TEST_P(SQLDatabaseTestExclusiveMode, LockingModeExclusive) {
EXPECT_EQ(ExecuteWithResult(db_.get(), "PRAGMA locking_mode"), "exclusive");
}
TEST_P(SQLDatabaseTest, LockingModeNormal) {
EXPECT_EQ(ExecuteWithResult(db_.get(), "PRAGMA locking_mode"), "normal");
}
TEST_P(SQLDatabaseTest, OpenedInCorrectMode) {
std::string expected_mode = IsWALEnabled() ? "wal" : "truncate";
EXPECT_EQ(ExecuteWithResult(db_.get(), "PRAGMA journal_mode"), expected_mode);
}
TEST_P(SQLDatabaseTest, CheckpointDatabase) {
if (!IsWALEnabled())
return;
base::FilePath wal_path = Database::WriteAheadLogPath(db_path_);
int64_t wal_size = 0;
// WAL file initially empty.
EXPECT_TRUE(base::PathExists(wal_path));
base::GetFileSize(wal_path, &wal_size);
EXPECT_EQ(wal_size, 0);
ASSERT_TRUE(
db_->Execute("CREATE TABLE foo (id INTEGER UNIQUE, value INTEGER)"));
ASSERT_TRUE(db_->Execute("INSERT INTO foo VALUES (1, 1)"));
ASSERT_TRUE(db_->Execute("INSERT INTO foo VALUES (2, 2)"));
// Writes reach WAL file but not db file.
base::GetFileSize(wal_path, &wal_size);
EXPECT_GT(wal_size, 0);
int64_t db_size = 0;
base::GetFileSize(db_path_, &db_size);
EXPECT_EQ(db_size, db_->page_size());
// Checkpoint database to immediately propagate writes to DB file.
EXPECT_TRUE(db_->CheckpointDatabase());
base::GetFileSize(db_path_, &db_size);
EXPECT_GT(db_size, db_->page_size());
EXPECT_EQ(ExecuteWithResult(db_.get(), "SELECT value FROM foo where id=1"),
"1");
EXPECT_EQ(ExecuteWithResult(db_.get(), "SELECT value FROM foo where id=2"),
"2");
}
TEST_P(SQLDatabaseTest, OpenFailsAfterCorruptSizeInHeader) {
// The database file ends up empty if we don't create at least one table.
ASSERT_TRUE(
db_->Execute("CREATE TABLE rows(i INTEGER PRIMARY KEY NOT NULL)"));
db_->Close();
ASSERT_TRUE(sql::test::CorruptSizeInHeader(db_path_));
{
sql::test::ScopedErrorExpecter expecter;
expecter.ExpectError(SQLITE_CORRUPT);
ASSERT_TRUE(db_->Open(db_path_));
EXPECT_TRUE(expecter.SawExpectedErrors());
}
}
TEST_P(SQLDatabaseTest, ExecuteFailsAfterCorruptSizeInHeader) {
ASSERT_TRUE(
db_->Execute("CREATE TABLE rows(i INTEGER PRIMARY KEY NOT NULL)"));
constexpr static char kSelectSql[] = "SELECT * from rows";
EXPECT_TRUE(db_->Execute(kSelectSql))
<< "The test Execute() statement fails before the header is corrupted";
db_->Close();
ASSERT_TRUE(sql::test::CorruptSizeInHeader(db_path_));
{
sql::test::ScopedErrorExpecter expecter;
expecter.ExpectError(SQLITE_CORRUPT);
ASSERT_TRUE(db_->Open(db_path_));
EXPECT_TRUE(expecter.SawExpectedErrors())
<< "Database::Open() did not encounter SQLITE_CORRUPT";
}
{
sql::test::ScopedErrorExpecter expecter;
expecter.ExpectError(SQLITE_CORRUPT);
EXPECT_FALSE(db_->Execute(kSelectSql));
EXPECT_TRUE(expecter.SawExpectedErrors())
<< "Database::Execute() did not encounter SQLITE_CORRUPT";
}
}
TEST_P(SQLDatabaseTest, SchemaFailsAfterCorruptSizeInHeader) {
ASSERT_TRUE(
db_->Execute("CREATE TABLE rows(i INTEGER PRIMARY KEY NOT NULL)"));
ASSERT_TRUE(db_->DoesTableExist("rows"))
<< "The test schema check fails before the header is corrupted";
db_->Close();
ASSERT_TRUE(sql::test::CorruptSizeInHeader(db_path_));
{
sql::test::ScopedErrorExpecter expecter;
expecter.ExpectError(SQLITE_CORRUPT);
ASSERT_TRUE(db_->Open(db_path_));
EXPECT_TRUE(expecter.SawExpectedErrors())
<< "Database::Open() did not encounter SQLITE_CORRUPT";
}
{
sql::test::ScopedErrorExpecter expecter;
expecter.ExpectError(SQLITE_CORRUPT);
EXPECT_FALSE(db_->DoesTableExist("rows"));
EXPECT_TRUE(expecter.SawExpectedErrors())
<< "Database::DoesTableExist() did not encounter SQLITE_CORRUPT";
}
}
// WAL mode is currently not supported on Fuchsia.
#if !BUILDFLAG(IS_FUCHSIA)
INSTANTIATE_TEST_SUITE_P(JournalMode, SQLDatabaseTest, testing::Bool());
INSTANTIATE_TEST_SUITE_P(JournalMode,
SQLDatabaseTestExclusiveMode,
testing::Bool());
#else
INSTANTIATE_TEST_SUITE_P(JournalMode, SQLDatabaseTest, testing::Values(false));
INSTANTIATE_TEST_SUITE_P(JournalMode,
SQLDatabaseTestExclusiveMode,
testing::Values(false));
#endif
} // namespace sql