// Copyright 2013 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 #include "base/bind.h" #include "base/files/file_path.h" #include "base/files/file_util.h" #include "base/files/scoped_temp_dir.h" #include "base/path_service.h" #include "base/strings/string_number_conversions.h" #include "sql/connection.h" #include "sql/meta_table.h" #include "sql/recovery.h" #include "sql/statement.h" #include "sql/test/paths.h" #include "sql/test/scoped_error_ignorer.h" #include "sql/test/sql_test_base.h" #include "sql/test/test_helpers.h" #include "testing/gtest/include/gtest/gtest.h" #include "third_party/sqlite/sqlite3.h" namespace { // Execute |sql|, and stringify the results with |column_sep| between // columns and |row_sep| between rows. // TODO(shess): Promote this to a central testing helper. std::string ExecuteWithResults(sql::Connection* db, const char* sql, const char* column_sep, const char* row_sep) { sql::Statement s(db->GetUniqueStatement(sql)); std::string ret; while (s.Step()) { if (!ret.empty()) ret += row_sep; for (int i = 0; i < s.ColumnCount(); ++i) { if (i > 0) ret += column_sep; if (s.ColumnType(i) == sql::COLUMN_TYPE_NULL) { ret += ""; } else if (s.ColumnType(i) == sql::COLUMN_TYPE_BLOB) { ret += " recovery = sql::Recovery::Begin(&db(), db_path()); ASSERT_TRUE(recovery.get()); } EXPECT_FALSE(db().is_open()); ASSERT_TRUE(Reopen()); EXPECT_TRUE(db().is_open()); ASSERT_EQ("", GetSchema(&db())); // Recreate the database. ASSERT_TRUE(db().Execute(kCreateSql)); ASSERT_TRUE(db().Execute(kInsertSql)); ASSERT_EQ("CREATE TABLE x (t TEXT)", GetSchema(&db())); // Unrecoverable() also razes. { scoped_ptr recovery = sql::Recovery::Begin(&db(), db_path()); ASSERT_TRUE(recovery.get()); sql::Recovery::Unrecoverable(recovery.Pass()); // TODO(shess): Test that calls to recover.db() start failing. } EXPECT_FALSE(db().is_open()); ASSERT_TRUE(Reopen()); EXPECT_TRUE(db().is_open()); ASSERT_EQ("", GetSchema(&db())); // Recreate the database. ASSERT_TRUE(db().Execute(kCreateSql)); ASSERT_TRUE(db().Execute(kInsertSql)); ASSERT_EQ("CREATE TABLE x (t TEXT)", GetSchema(&db())); // Recovered() replaces the original with the "recovered" version. { scoped_ptr recovery = sql::Recovery::Begin(&db(), db_path()); ASSERT_TRUE(recovery.get()); // Create the new version of the table. ASSERT_TRUE(recovery->db()->Execute(kCreateSql)); // Insert different data to distinguish from original database. const char kAltInsertSql[] = "INSERT INTO x VALUES ('That was a test')"; ASSERT_TRUE(recovery->db()->Execute(kAltInsertSql)); // Successfully recovered. ASSERT_TRUE(sql::Recovery::Recovered(recovery.Pass())); } EXPECT_FALSE(db().is_open()); ASSERT_TRUE(Reopen()); EXPECT_TRUE(db().is_open()); ASSERT_EQ("CREATE TABLE x (t TEXT)", GetSchema(&db())); const char* kXSql = "SELECT * FROM x ORDER BY 1"; ASSERT_EQ("That was a test", ExecuteWithResults(&db(), kXSql, "|", "\n")); } // The recovery virtual table is only supported for Chromium's SQLite. #if !defined(USE_SYSTEM_SQLITE) // Run recovery through its paces on a valid database. TEST_F(SQLRecoveryTest, VirtualTable) { const char kCreateSql[] = "CREATE TABLE x (t TEXT)"; ASSERT_TRUE(db().Execute(kCreateSql)); ASSERT_TRUE(db().Execute("INSERT INTO x VALUES ('This is a test')")); ASSERT_TRUE(db().Execute("INSERT INTO x VALUES ('That was a test')")); // Successfully recover the database. { scoped_ptr recovery = sql::Recovery::Begin(&db(), db_path()); // Tables to recover original DB, now at [corrupt]. const char kRecoveryCreateSql[] = "CREATE VIRTUAL TABLE temp.recover_x using recover(" " corrupt.x," " t TEXT STRICT" ")"; ASSERT_TRUE(recovery->db()->Execute(kRecoveryCreateSql)); // Re-create the original schema. ASSERT_TRUE(recovery->db()->Execute(kCreateSql)); // Copy the data from the recovery tables to the new database. const char kRecoveryCopySql[] = "INSERT INTO x SELECT t FROM recover_x"; ASSERT_TRUE(recovery->db()->Execute(kRecoveryCopySql)); // Successfully recovered. ASSERT_TRUE(sql::Recovery::Recovered(recovery.Pass())); } // Since the database was not corrupt, the entire schema and all // data should be recovered. ASSERT_TRUE(Reopen()); ASSERT_EQ("CREATE TABLE x (t TEXT)", GetSchema(&db())); const char* kXSql = "SELECT * FROM x ORDER BY 1"; ASSERT_EQ("That was a test\nThis is a test", ExecuteWithResults(&db(), kXSql, "|", "\n")); } void RecoveryCallback(sql::Connection* db, const base::FilePath& db_path, int* record_error, int error, sql::Statement* stmt) { *record_error = error; // Clear the error callback to prevent reentrancy. db->reset_error_callback(); scoped_ptr recovery = sql::Recovery::Begin(db, db_path); ASSERT_TRUE(recovery.get()); const char kRecoveryCreateSql[] = "CREATE VIRTUAL TABLE temp.recover_x using recover(" " corrupt.x," " id INTEGER STRICT," " v INTEGER STRICT" ")"; const char kCreateTable[] = "CREATE TABLE x (id INTEGER, v INTEGER)"; const char kCreateIndex[] = "CREATE UNIQUE INDEX x_id ON x (id)"; // Replicate data over. const char kRecoveryCopySql[] = "INSERT OR REPLACE INTO x SELECT id, v FROM recover_x"; ASSERT_TRUE(recovery->db()->Execute(kRecoveryCreateSql)); ASSERT_TRUE(recovery->db()->Execute(kCreateTable)); ASSERT_TRUE(recovery->db()->Execute(kCreateIndex)); ASSERT_TRUE(recovery->db()->Execute(kRecoveryCopySql)); ASSERT_TRUE(sql::Recovery::Recovered(recovery.Pass())); } // Build a database, corrupt it by making an index reference to // deleted row, then recover when a query selects that row. TEST_F(SQLRecoveryTest, RecoverCorruptIndex) { const char kCreateTable[] = "CREATE TABLE x (id INTEGER, v INTEGER)"; const char kCreateIndex[] = "CREATE UNIQUE INDEX x_id ON x (id)"; ASSERT_TRUE(db().Execute(kCreateTable)); ASSERT_TRUE(db().Execute(kCreateIndex)); // Insert a bit of data. { ASSERT_TRUE(db().BeginTransaction()); const char kInsertSql[] = "INSERT INTO x (id, v) VALUES (?, ?)"; sql::Statement s(db().GetUniqueStatement(kInsertSql)); for (int i = 0; i < 10; ++i) { s.Reset(true); s.BindInt(0, i); s.BindInt(1, i); EXPECT_FALSE(s.Step()); EXPECT_TRUE(s.Succeeded()); } ASSERT_TRUE(db().CommitTransaction()); } db().Close(); // Delete a row from the table, while leaving the index entry which // references it. const char kDeleteSql[] = "DELETE FROM x WHERE id = 0"; ASSERT_TRUE(sql::test::CorruptTableOrIndex(db_path(), "x_id", kDeleteSql)); ASSERT_TRUE(Reopen()); int error = SQLITE_OK; db().set_error_callback(base::Bind(&RecoveryCallback, &db(), db_path(), &error)); // This works before the callback is called. const char kTrivialSql[] = "SELECT COUNT(*) FROM sqlite_master"; EXPECT_TRUE(db().IsSQLValid(kTrivialSql)); // TODO(shess): Could this be delete? Anything which fails should work. const char kSelectSql[] = "SELECT v FROM x WHERE id = 0"; ASSERT_FALSE(db().Execute(kSelectSql)); EXPECT_EQ(SQLITE_CORRUPT, error); // Database handle has been poisoned. EXPECT_FALSE(db().IsSQLValid(kTrivialSql)); ASSERT_TRUE(Reopen()); // The recovered table should reflect the deletion. const char kSelectAllSql[] = "SELECT v FROM x ORDER BY id"; EXPECT_EQ("1,2,3,4,5,6,7,8,9", ExecuteWithResults(&db(), kSelectAllSql, "|", ",")); // The failing statement should now succeed, with no results. EXPECT_EQ("", ExecuteWithResults(&db(), kSelectSql, "|", ",")); } // Build a database, corrupt it by making a table contain a row not // referenced by the index, then recover the database. TEST_F(SQLRecoveryTest, RecoverCorruptTable) { const char kCreateTable[] = "CREATE TABLE x (id INTEGER, v INTEGER)"; const char kCreateIndex[] = "CREATE UNIQUE INDEX x_id ON x (id)"; ASSERT_TRUE(db().Execute(kCreateTable)); ASSERT_TRUE(db().Execute(kCreateIndex)); // Insert a bit of data. { ASSERT_TRUE(db().BeginTransaction()); const char kInsertSql[] = "INSERT INTO x (id, v) VALUES (?, ?)"; sql::Statement s(db().GetUniqueStatement(kInsertSql)); for (int i = 0; i < 10; ++i) { s.Reset(true); s.BindInt(0, i); s.BindInt(1, i); EXPECT_FALSE(s.Step()); EXPECT_TRUE(s.Succeeded()); } ASSERT_TRUE(db().CommitTransaction()); } db().Close(); // Delete a row from the index while leaving a table entry. const char kDeleteSql[] = "DELETE FROM x WHERE id = 0"; ASSERT_TRUE(sql::test::CorruptTableOrIndex(db_path(), "x", kDeleteSql)); // TODO(shess): Figure out a query which causes SQLite to notice // this organically. Meanwhile, just handle it manually. ASSERT_TRUE(Reopen()); // Index shows one less than originally inserted. const char kCountSql[] = "SELECT COUNT (*) FROM x"; EXPECT_EQ("9", ExecuteWithResults(&db(), kCountSql, "|", ",")); // A full table scan shows all of the original data. Using column [v] to // force use of the table rather than the index. const char kDistinctSql[] = "SELECT DISTINCT COUNT (v) FROM x"; EXPECT_EQ("10", ExecuteWithResults(&db(), kDistinctSql, "|", ",")); // Insert id 0 again. Since it is not in the index, the insert // succeeds, but results in a duplicate value in the table. const char kInsertSql[] = "INSERT INTO x (id, v) VALUES (0, 100)"; ASSERT_TRUE(db().Execute(kInsertSql)); // Duplication is visible. EXPECT_EQ("10", ExecuteWithResults(&db(), kCountSql, "|", ",")); EXPECT_EQ("11", ExecuteWithResults(&db(), kDistinctSql, "|", ",")); // This works before the callback is called. const char kTrivialSql[] = "SELECT COUNT(*) FROM sqlite_master"; EXPECT_TRUE(db().IsSQLValid(kTrivialSql)); // Call the recovery callback manually. int error = SQLITE_OK; RecoveryCallback(&db(), db_path(), &error, SQLITE_CORRUPT, NULL); EXPECT_EQ(SQLITE_CORRUPT, error); // Database handle has been poisoned. EXPECT_FALSE(db().IsSQLValid(kTrivialSql)); ASSERT_TRUE(Reopen()); // The recovered table has consistency between the index and the table. EXPECT_EQ("10", ExecuteWithResults(&db(), kCountSql, "|", ",")); EXPECT_EQ("10", ExecuteWithResults(&db(), kDistinctSql, "|", ",")); // The expected value was retained. const char kSelectSql[] = "SELECT v FROM x WHERE id = 0"; EXPECT_EQ("100", ExecuteWithResults(&db(), kSelectSql, "|", ",")); } TEST_F(SQLRecoveryTest, Meta) { const int kVersion = 3; const int kCompatibleVersion = 2; { sql::MetaTable meta; EXPECT_TRUE(meta.Init(&db(), kVersion, kCompatibleVersion)); EXPECT_EQ(kVersion, meta.GetVersionNumber()); } // Test expected case where everything works. { scoped_ptr recovery = sql::Recovery::Begin(&db(), db_path()); EXPECT_TRUE(recovery->SetupMeta()); int version = 0; EXPECT_TRUE(recovery->GetMetaVersionNumber(&version)); EXPECT_EQ(kVersion, version); sql::Recovery::Rollback(recovery.Pass()); } ASSERT_TRUE(Reopen()); // Handle was poisoned. // Test version row missing. EXPECT_TRUE(db().Execute("DELETE FROM meta WHERE key = 'version'")); { scoped_ptr recovery = sql::Recovery::Begin(&db(), db_path()); EXPECT_TRUE(recovery->SetupMeta()); int version = 0; EXPECT_FALSE(recovery->GetMetaVersionNumber(&version)); EXPECT_EQ(0, version); sql::Recovery::Rollback(recovery.Pass()); } ASSERT_TRUE(Reopen()); // Handle was poisoned. // Test meta table missing. EXPECT_TRUE(db().Execute("DROP TABLE meta")); { sql::ScopedErrorIgnorer ignore_errors; ignore_errors.IgnoreError(SQLITE_CORRUPT); // From virtual table. scoped_ptr recovery = sql::Recovery::Begin(&db(), db_path()); EXPECT_FALSE(recovery->SetupMeta()); ASSERT_TRUE(ignore_errors.CheckIgnoredErrors()); } } // Baseline AutoRecoverTable() test. TEST_F(SQLRecoveryTest, AutoRecoverTable) { // BIGINT and VARCHAR to test type affinity. const char kCreateSql[] = "CREATE TABLE x (id BIGINT, t TEXT, v VARCHAR)"; ASSERT_TRUE(db().Execute(kCreateSql)); ASSERT_TRUE(db().Execute("INSERT INTO x VALUES (11, 'This is', 'a test')")); ASSERT_TRUE(db().Execute("INSERT INTO x VALUES (5, 'That was', 'a test')")); // Save aside a copy of the original schema and data. const std::string orig_schema(GetSchema(&db())); const char kXSql[] = "SELECT * FROM x ORDER BY 1"; const std::string orig_data(ExecuteWithResults(&db(), kXSql, "|", "\n")); // Create a lame-duck table which will not be propagated by recovery to // detect that the recovery code actually ran. ASSERT_TRUE(db().Execute("CREATE TABLE y (c TEXT)")); ASSERT_NE(orig_schema, GetSchema(&db())); { scoped_ptr recovery = sql::Recovery::Begin(&db(), db_path()); ASSERT_TRUE(recovery->db()->Execute(kCreateSql)); // Save a copy of the temp db's schema before recovering the table. const char kTempSchemaSql[] = "SELECT name, sql FROM sqlite_temp_master"; const std::string temp_schema( ExecuteWithResults(recovery->db(), kTempSchemaSql, "|", "\n")); size_t rows = 0; EXPECT_TRUE(recovery->AutoRecoverTable("x", 0, &rows)); EXPECT_EQ(2u, rows); // Test that any additional temp tables were cleaned up. EXPECT_EQ(temp_schema, ExecuteWithResults(recovery->db(), kTempSchemaSql, "|", "\n")); ASSERT_TRUE(sql::Recovery::Recovered(recovery.Pass())); } // Since the database was not corrupt, the entire schema and all // data should be recovered. ASSERT_TRUE(Reopen()); ASSERT_EQ(orig_schema, GetSchema(&db())); ASSERT_EQ(orig_data, ExecuteWithResults(&db(), kXSql, "|", "\n")); // Recovery fails if the target table doesn't exist. { scoped_ptr recovery = sql::Recovery::Begin(&db(), db_path()); ASSERT_TRUE(recovery->db()->Execute(kCreateSql)); // TODO(shess): Should this failure implicitly lead to Raze()? size_t rows = 0; EXPECT_FALSE(recovery->AutoRecoverTable("y", 0, &rows)); sql::Recovery::Unrecoverable(recovery.Pass()); } } // Test that default values correctly replace nulls. The recovery // virtual table reads directly from the database, so DEFAULT is not // interpretted at that level. TEST_F(SQLRecoveryTest, AutoRecoverTableWithDefault) { ASSERT_TRUE(db().Execute("CREATE TABLE x (id INTEGER)")); ASSERT_TRUE(db().Execute("INSERT INTO x VALUES (5)")); ASSERT_TRUE(db().Execute("INSERT INTO x VALUES (15)")); // ALTER effectively leaves the new columns NULL in the first two // rows. The row with 17 will get the default injected at insert // time, while the row with 42 will get the actual value provided. // Embedded "'" to make sure default-handling continues to be quoted // correctly. ASSERT_TRUE(db().Execute("ALTER TABLE x ADD COLUMN t TEXT DEFAULT 'a''a'")); ASSERT_TRUE(db().Execute("ALTER TABLE x ADD COLUMN b BLOB DEFAULT x'AA55'")); ASSERT_TRUE(db().Execute("ALTER TABLE x ADD COLUMN i INT DEFAULT 93")); ASSERT_TRUE(db().Execute("INSERT INTO x (id) VALUES (17)")); ASSERT_TRUE(db().Execute("INSERT INTO x VALUES (42, 'b', x'1234', 12)")); // Save aside a copy of the original schema and data. const std::string orig_schema(GetSchema(&db())); const char kXSql[] = "SELECT * FROM x ORDER BY 1"; const std::string orig_data(ExecuteWithResults(&db(), kXSql, "|", "\n")); // Create a lame-duck table which will not be propagated by recovery to // detect that the recovery code actually ran. ASSERT_TRUE(db().Execute("CREATE TABLE y (c TEXT)")); ASSERT_NE(orig_schema, GetSchema(&db())); // Mechanically adjust the stored schema and data to allow detecting // where the default value is coming from. The target table is just // like the original with the default for [t] changed, to signal // defaults coming from the recovery system. The two %5 rows should // get the target-table default for [t], while the others should get // the source-table default. std::string final_schema(orig_schema); std::string final_data(orig_data); size_t pos; while ((pos = final_schema.find("'a''a'")) != std::string::npos) { final_schema.replace(pos, 6, "'c''c'"); } while ((pos = final_data.find("5|a'a")) != std::string::npos) { final_data.replace(pos, 5, "5|c'c"); } { scoped_ptr recovery = sql::Recovery::Begin(&db(), db_path()); // Different default to detect which table provides the default. ASSERT_TRUE(recovery->db()->Execute(final_schema.c_str())); size_t rows = 0; EXPECT_TRUE(recovery->AutoRecoverTable("x", 0, &rows)); EXPECT_EQ(4u, rows); ASSERT_TRUE(sql::Recovery::Recovered(recovery.Pass())); } // Since the database was not corrupt, the entire schema and all // data should be recovered. ASSERT_TRUE(Reopen()); ASSERT_EQ(final_schema, GetSchema(&db())); ASSERT_EQ(final_data, ExecuteWithResults(&db(), kXSql, "|", "\n")); } // Test that rows with NULL in a NOT NULL column are filtered // correctly. In the wild, this would probably happen due to // corruption, but here it is simulated by recovering a table which // allowed nulls into a table which does not. TEST_F(SQLRecoveryTest, AutoRecoverTableNullFilter) { const char kOrigSchema[] = "CREATE TABLE x (id INTEGER, t TEXT)"; const char kFinalSchema[] = "CREATE TABLE x (id INTEGER, t TEXT NOT NULL)"; ASSERT_TRUE(db().Execute(kOrigSchema)); ASSERT_TRUE(db().Execute("INSERT INTO x VALUES (5, null)")); ASSERT_TRUE(db().Execute("INSERT INTO x VALUES (15, 'this is a test')")); // Create a lame-duck table which will not be propagated by recovery to // detect that the recovery code actually ran. ASSERT_EQ(kOrigSchema, GetSchema(&db())); ASSERT_TRUE(db().Execute("CREATE TABLE y (c TEXT)")); ASSERT_NE(kOrigSchema, GetSchema(&db())); { scoped_ptr recovery = sql::Recovery::Begin(&db(), db_path()); ASSERT_TRUE(recovery->db()->Execute(kFinalSchema)); size_t rows = 0; EXPECT_TRUE(recovery->AutoRecoverTable("x", 0, &rows)); EXPECT_EQ(1u, rows); ASSERT_TRUE(sql::Recovery::Recovered(recovery.Pass())); } // The schema should be the same, but only one row of data should // have been recovered. ASSERT_TRUE(Reopen()); ASSERT_EQ(kFinalSchema, GetSchema(&db())); const char kXSql[] = "SELECT * FROM x ORDER BY 1"; ASSERT_EQ("15|this is a test", ExecuteWithResults(&db(), kXSql, "|", "\n")); } // Test AutoRecoverTable with a ROWID alias. TEST_F(SQLRecoveryTest, AutoRecoverTableWithRowid) { // The rowid alias is almost always the first column, intentionally // put it later. const char kCreateSql[] = "CREATE TABLE x (t TEXT, id INTEGER PRIMARY KEY NOT NULL)"; ASSERT_TRUE(db().Execute(kCreateSql)); ASSERT_TRUE(db().Execute("INSERT INTO x VALUES ('This is a test', null)")); ASSERT_TRUE(db().Execute("INSERT INTO x VALUES ('That was a test', null)")); // Save aside a copy of the original schema and data. const std::string orig_schema(GetSchema(&db())); const char kXSql[] = "SELECT * FROM x ORDER BY 1"; const std::string orig_data(ExecuteWithResults(&db(), kXSql, "|", "\n")); // Create a lame-duck table which will not be propagated by recovery to // detect that the recovery code actually ran. ASSERT_TRUE(db().Execute("CREATE TABLE y (c TEXT)")); ASSERT_NE(orig_schema, GetSchema(&db())); { scoped_ptr recovery = sql::Recovery::Begin(&db(), db_path()); ASSERT_TRUE(recovery->db()->Execute(kCreateSql)); size_t rows = 0; EXPECT_TRUE(recovery->AutoRecoverTable("x", 0, &rows)); EXPECT_EQ(2u, rows); ASSERT_TRUE(sql::Recovery::Recovered(recovery.Pass())); } // Since the database was not corrupt, the entire schema and all // data should be recovered. ASSERT_TRUE(Reopen()); ASSERT_EQ(orig_schema, GetSchema(&db())); ASSERT_EQ(orig_data, ExecuteWithResults(&db(), kXSql, "|", "\n")); } // Test that a compound primary key doesn't fire the ROWID code. TEST_F(SQLRecoveryTest, AutoRecoverTableWithCompoundKey) { const char kCreateSql[] = "CREATE TABLE x (" "id INTEGER NOT NULL," "id2 TEXT NOT NULL," "t TEXT," "PRIMARY KEY (id, id2)" ")"; ASSERT_TRUE(db().Execute(kCreateSql)); // NOTE(shess): Do not accidentally use [id] 1, 2, 3, as those will // be the ROWID values. ASSERT_TRUE(db().Execute("INSERT INTO x VALUES (1, 'a', 'This is a test')")); ASSERT_TRUE(db().Execute("INSERT INTO x VALUES (1, 'b', 'That was a test')")); ASSERT_TRUE(db().Execute("INSERT INTO x VALUES (2, 'a', 'Another test')")); // Save aside a copy of the original schema and data. const std::string orig_schema(GetSchema(&db())); const char kXSql[] = "SELECT * FROM x ORDER BY 1"; const std::string orig_data(ExecuteWithResults(&db(), kXSql, "|", "\n")); // Create a lame-duck table which will not be propagated by recovery to // detect that the recovery code actually ran. ASSERT_TRUE(db().Execute("CREATE TABLE y (c TEXT)")); ASSERT_NE(orig_schema, GetSchema(&db())); { scoped_ptr recovery = sql::Recovery::Begin(&db(), db_path()); ASSERT_TRUE(recovery->db()->Execute(kCreateSql)); size_t rows = 0; EXPECT_TRUE(recovery->AutoRecoverTable("x", 0, &rows)); EXPECT_EQ(3u, rows); ASSERT_TRUE(sql::Recovery::Recovered(recovery.Pass())); } // Since the database was not corrupt, the entire schema and all // data should be recovered. ASSERT_TRUE(Reopen()); ASSERT_EQ(orig_schema, GetSchema(&db())); ASSERT_EQ(orig_data, ExecuteWithResults(&db(), kXSql, "|", "\n")); } // Test |extend_columns| support. TEST_F(SQLRecoveryTest, AutoRecoverTableExtendColumns) { const char kCreateSql[] = "CREATE TABLE x (id INTEGER PRIMARY KEY, t0 TEXT)"; ASSERT_TRUE(db().Execute(kCreateSql)); ASSERT_TRUE(db().Execute("INSERT INTO x VALUES (1, 'This is')")); ASSERT_TRUE(db().Execute("INSERT INTO x VALUES (2, 'That was')")); // Save aside a copy of the original schema and data. const std::string orig_schema(GetSchema(&db())); const char kXSql[] = "SELECT * FROM x ORDER BY 1"; const std::string orig_data(ExecuteWithResults(&db(), kXSql, "|", "\n")); // Modify the table to add a column, and add data to that column. ASSERT_TRUE(db().Execute("ALTER TABLE x ADD COLUMN t1 TEXT")); ASSERT_TRUE(db().Execute("UPDATE x SET t1 = 'a test'")); ASSERT_NE(orig_schema, GetSchema(&db())); ASSERT_NE(orig_data, ExecuteWithResults(&db(), kXSql, "|", "\n")); { scoped_ptr recovery = sql::Recovery::Begin(&db(), db_path()); ASSERT_TRUE(recovery->db()->Execute(kCreateSql)); size_t rows = 0; EXPECT_TRUE(recovery->AutoRecoverTable("x", 1, &rows)); EXPECT_EQ(2u, rows); ASSERT_TRUE(sql::Recovery::Recovered(recovery.Pass())); } // Since the database was not corrupt, the entire schema and all // data should be recovered. ASSERT_TRUE(Reopen()); ASSERT_EQ(orig_schema, GetSchema(&db())); ASSERT_EQ(orig_data, ExecuteWithResults(&db(), kXSql, "|", "\n")); } // Recover a golden file where an interior page has been manually modified so // that the number of cells is greater than will fit on a single page. This // case happened in . TEST_F(SQLRecoveryTest, Bug387868) { base::FilePath golden_path; ASSERT_TRUE(PathService::Get(sql::test::DIR_TEST_DATA, &golden_path)); golden_path = golden_path.AppendASCII("recovery_387868"); db().Close(); ASSERT_TRUE(base::CopyFile(golden_path, db_path())); ASSERT_TRUE(Reopen()); { scoped_ptr recovery = sql::Recovery::Begin(&db(), db_path()); ASSERT_TRUE(recovery.get()); // Create the new version of the table. const char kCreateSql[] = "CREATE TABLE x (id INTEGER PRIMARY KEY, t0 TEXT)"; ASSERT_TRUE(recovery->db()->Execute(kCreateSql)); size_t rows = 0; EXPECT_TRUE(recovery->AutoRecoverTable("x", 0, &rows)); EXPECT_EQ(43u, rows); // Successfully recovered. EXPECT_TRUE(sql::Recovery::Recovered(recovery.Pass())); } } #endif // !defined(USE_SYSTEM_SQLITE) // Memory-mapped I/O interacts poorly with I/O errors. Make sure the recovery // database doesn't accidentally enable it. TEST_F(SQLRecoveryTest, NoMmap) { scoped_ptr recovery = sql::Recovery::Begin(&db(), db_path()); ASSERT_TRUE(recovery.get()); // In the current implementation, the PRAGMA successfully runs with no result // rows. Running with a single result of |0| is also acceptable. sql::Statement s(recovery->db()->GetUniqueStatement("PRAGMA mmap_size")); EXPECT_TRUE(!s.Step() || !s.ColumnInt64(0)); } } // namespace