# pysqlite2/test/dbapi.py: tests for DB-API compliance # # Copyright (C) 2004-2010 Gerhard Häring # # This file is part of pysqlite. # # This software is provided 'as-is', without any express or implied # warranty. In no event will the authors be held liable for any damages # arising from the use of this software. # # Permission is granted to anyone to use this software for any purpose, # including commercial applications, and to alter it and redistribute it # freely, subject to the following restrictions: # # 1. The origin of this software must not be misrepresented; you must not # claim that you wrote the original software. If you use this software # in a product, an acknowledgment in the product documentation would be # appreciated but is not required. # 2. Altered source versions must be plainly marked as such, and must not be # misrepresented as being the original software. # 3. This notice may not be removed or altered from any source distribution. import threading import unittest import sqlite3 as sqlite import sys from test.support.os_helper import TESTFN, unlink class ModuleTests(unittest.TestCase): def test_api_level(self): self.assertEqual(sqlite.apilevel, "2.0", "apilevel is %s, should be 2.0" % sqlite.apilevel) def test_thread_safety(self): self.assertEqual(sqlite.threadsafety, 1, "threadsafety is %d, should be 1" % sqlite.threadsafety) def test_param_style(self): self.assertEqual(sqlite.paramstyle, "qmark", "paramstyle is '%s', should be 'qmark'" % sqlite.paramstyle) def test_warning(self): self.assertTrue(issubclass(sqlite.Warning, Exception), "Warning is not a subclass of Exception") def test_error(self): self.assertTrue(issubclass(sqlite.Error, Exception), "Error is not a subclass of Exception") def test_interface_error(self): self.assertTrue(issubclass(sqlite.InterfaceError, sqlite.Error), "InterfaceError is not a subclass of Error") def test_database_error(self): self.assertTrue(issubclass(sqlite.DatabaseError, sqlite.Error), "DatabaseError is not a subclass of Error") def test_data_error(self): self.assertTrue(issubclass(sqlite.DataError, sqlite.DatabaseError), "DataError is not a subclass of DatabaseError") def test_operational_error(self): self.assertTrue(issubclass(sqlite.OperationalError, sqlite.DatabaseError), "OperationalError is not a subclass of DatabaseError") def test_integrity_error(self): self.assertTrue(issubclass(sqlite.IntegrityError, sqlite.DatabaseError), "IntegrityError is not a subclass of DatabaseError") def test_internal_error(self): self.assertTrue(issubclass(sqlite.InternalError, sqlite.DatabaseError), "InternalError is not a subclass of DatabaseError") def test_programming_error(self): self.assertTrue(issubclass(sqlite.ProgrammingError, sqlite.DatabaseError), "ProgrammingError is not a subclass of DatabaseError") def test_not_supported_error(self): self.assertTrue(issubclass(sqlite.NotSupportedError, sqlite.DatabaseError), "NotSupportedError is not a subclass of DatabaseError") # sqlite3_enable_shared_cache() is deprecated on macOS and calling it may raise # OperationalError on some buildbots. @unittest.skipIf(sys.platform == "darwin", "shared cache is deprecated on macOS") def test_shared_cache_deprecated(self): for enable in (True, False): with self.assertWarns(DeprecationWarning) as cm: sqlite.enable_shared_cache(enable) self.assertIn("dbapi.py", cm.filename) class ConnectionTests(unittest.TestCase): def setUp(self): self.cx = sqlite.connect(":memory:") cu = self.cx.cursor() cu.execute("create table test(id integer primary key, name text)") cu.execute("insert into test(name) values (?)", ("foo",)) def tearDown(self): self.cx.close() def test_commit(self): self.cx.commit() def test_commit_after_no_changes(self): """ A commit should also work when no changes were made to the database. """ self.cx.commit() self.cx.commit() def test_rollback(self): self.cx.rollback() def test_rollback_after_no_changes(self): """ A rollback should also work when no changes were made to the database. """ self.cx.rollback() self.cx.rollback() def test_cursor(self): cu = self.cx.cursor() def test_failed_open(self): YOU_CANNOT_OPEN_THIS = "/foo/bar/bla/23534/mydb.db" with self.assertRaises(sqlite.OperationalError): con = sqlite.connect(YOU_CANNOT_OPEN_THIS) def test_close(self): self.cx.close() def test_exceptions(self): # Optional DB-API extension. self.assertEqual(self.cx.Warning, sqlite.Warning) self.assertEqual(self.cx.Error, sqlite.Error) self.assertEqual(self.cx.InterfaceError, sqlite.InterfaceError) self.assertEqual(self.cx.DatabaseError, sqlite.DatabaseError) self.assertEqual(self.cx.DataError, sqlite.DataError) self.assertEqual(self.cx.OperationalError, sqlite.OperationalError) self.assertEqual(self.cx.IntegrityError, sqlite.IntegrityError) self.assertEqual(self.cx.InternalError, sqlite.InternalError) self.assertEqual(self.cx.ProgrammingError, sqlite.ProgrammingError) self.assertEqual(self.cx.NotSupportedError, sqlite.NotSupportedError) def test_in_transaction(self): # Can't use db from setUp because we want to test initial state. cx = sqlite.connect(":memory:") cu = cx.cursor() self.assertEqual(cx.in_transaction, False) cu.execute("create table transactiontest(id integer primary key, name text)") self.assertEqual(cx.in_transaction, False) cu.execute("insert into transactiontest(name) values (?)", ("foo",)) self.assertEqual(cx.in_transaction, True) cu.execute("select name from transactiontest where name=?", ["foo"]) row = cu.fetchone() self.assertEqual(cx.in_transaction, True) cx.commit() self.assertEqual(cx.in_transaction, False) cu.execute("select name from transactiontest where name=?", ["foo"]) row = cu.fetchone() self.assertEqual(cx.in_transaction, False) def test_in_transaction_ro(self): with self.assertRaises(AttributeError): self.cx.in_transaction = True def test_open_with_path_like_object(self): """ Checks that we can successfully connect to a database using an object that is PathLike, i.e. has __fspath__(). """ self.addCleanup(unlink, TESTFN) class Path: def __fspath__(self): return TESTFN path = Path() with sqlite.connect(path) as cx: cx.execute('create table test(id integer)') def test_open_uri(self): self.addCleanup(unlink, TESTFN) with sqlite.connect(TESTFN) as cx: cx.execute('create table test(id integer)') with sqlite.connect('file:' + TESTFN, uri=True) as cx: cx.execute('insert into test(id) values(0)') with sqlite.connect('file:' + TESTFN + '?mode=ro', uri=True) as cx: with self.assertRaises(sqlite.OperationalError): cx.execute('insert into test(id) values(1)') class CursorTests(unittest.TestCase): def setUp(self): self.cx = sqlite.connect(":memory:") self.cu = self.cx.cursor() self.cu.execute( "create table test(id integer primary key, name text, " "income number, unique_test text unique)" ) self.cu.execute("insert into test(name) values (?)", ("foo",)) def tearDown(self): self.cu.close() self.cx.close() def test_execute_no_args(self): self.cu.execute("delete from test") def test_execute_illegal_sql(self): with self.assertRaises(sqlite.OperationalError): self.cu.execute("select asdf") def test_execute_too_much_sql(self): with self.assertRaises(sqlite.Warning): self.cu.execute("select 5+4; select 4+5") def test_execute_too_much_sql2(self): self.cu.execute("select 5+4; -- foo bar") def test_execute_too_much_sql3(self): self.cu.execute(""" select 5+4; /* foo */ """) def test_execute_wrong_sql_arg(self): with self.assertRaises(TypeError): self.cu.execute(42) def test_execute_arg_int(self): self.cu.execute("insert into test(id) values (?)", (42,)) def test_execute_arg_float(self): self.cu.execute("insert into test(income) values (?)", (2500.32,)) def test_execute_arg_string(self): self.cu.execute("insert into test(name) values (?)", ("Hugo",)) def test_execute_arg_string_with_zero_byte(self): self.cu.execute("insert into test(name) values (?)", ("Hu\x00go",)) self.cu.execute("select name from test where id=?", (self.cu.lastrowid,)) row = self.cu.fetchone() self.assertEqual(row[0], "Hu\x00go") def test_execute_non_iterable(self): with self.assertRaises(ValueError) as cm: self.cu.execute("insert into test(id) values (?)", 42) self.assertEqual(str(cm.exception), 'parameters are of unsupported type') def test_execute_wrong_no_of_args1(self): # too many parameters with self.assertRaises(sqlite.ProgrammingError): self.cu.execute("insert into test(id) values (?)", (17, "Egon")) def test_execute_wrong_no_of_args2(self): # too little parameters with self.assertRaises(sqlite.ProgrammingError): self.cu.execute("insert into test(id) values (?)") def test_execute_wrong_no_of_args3(self): # no parameters, parameters are needed with self.assertRaises(sqlite.ProgrammingError): self.cu.execute("insert into test(id) values (?)") def test_execute_param_list(self): self.cu.execute("insert into test(name) values ('foo')") self.cu.execute("select name from test where name=?", ["foo"]) row = self.cu.fetchone() self.assertEqual(row[0], "foo") def test_execute_param_sequence(self): class L: def __len__(self): return 1 def __getitem__(self, x): assert x == 0 return "foo" self.cu.execute("insert into test(name) values ('foo')") self.cu.execute("select name from test where name=?", L()) row = self.cu.fetchone() self.assertEqual(row[0], "foo") def test_execute_param_sequence_bad_len(self): # Issue41662: Error in __len__() was overridden with ProgrammingError. class L: def __len__(self): 1/0 def __getitem__(slf, x): raise AssertionError self.cu.execute("insert into test(name) values ('foo')") with self.assertRaises(ZeroDivisionError): self.cu.execute("select name from test where name=?", L()) def test_execute_dict_mapping(self): self.cu.execute("insert into test(name) values ('foo')") self.cu.execute("select name from test where name=:name", {"name": "foo"}) row = self.cu.fetchone() self.assertEqual(row[0], "foo") def test_execute_dict_mapping_mapping(self): class D(dict): def __missing__(self, key): return "foo" self.cu.execute("insert into test(name) values ('foo')") self.cu.execute("select name from test where name=:name", D()) row = self.cu.fetchone() self.assertEqual(row[0], "foo") def test_execute_dict_mapping_too_little_args(self): self.cu.execute("insert into test(name) values ('foo')") with self.assertRaises(sqlite.ProgrammingError): self.cu.execute("select name from test where name=:name and id=:id", {"name": "foo"}) def test_execute_dict_mapping_no_args(self): self.cu.execute("insert into test(name) values ('foo')") with self.assertRaises(sqlite.ProgrammingError): self.cu.execute("select name from test where name=:name") def test_execute_dict_mapping_unnamed(self): self.cu.execute("insert into test(name) values ('foo')") with self.assertRaises(sqlite.ProgrammingError): self.cu.execute("select name from test where name=?", {"name": "foo"}) def test_close(self): self.cu.close() def test_rowcount_execute(self): self.cu.execute("delete from test") self.cu.execute("insert into test(name) values ('foo')") self.cu.execute("insert into test(name) values ('foo')") self.cu.execute("update test set name='bar'") self.assertEqual(self.cu.rowcount, 2) def test_rowcount_select(self): """ pysqlite does not know the rowcount of SELECT statements, because we don't fetch all rows after executing the select statement. The rowcount has thus to be -1. """ self.cu.execute("select 5 union select 6") self.assertEqual(self.cu.rowcount, -1) def test_rowcount_executemany(self): self.cu.execute("delete from test") self.cu.executemany("insert into test(name) values (?)", [(1,), (2,), (3,)]) self.assertEqual(self.cu.rowcount, 3) def test_total_changes(self): self.cu.execute("insert into test(name) values ('foo')") self.cu.execute("insert into test(name) values ('foo')") self.assertLess(2, self.cx.total_changes, msg='total changes reported wrong value') # Checks for executemany: # Sequences are required by the DB-API, iterators # enhancements in pysqlite. def test_execute_many_sequence(self): self.cu.executemany("insert into test(income) values (?)", [(x,) for x in range(100, 110)]) def test_execute_many_iterator(self): class MyIter: def __init__(self): self.value = 5 def __next__(self): if self.value == 10: raise StopIteration else: self.value += 1 return (self.value,) self.cu.executemany("insert into test(income) values (?)", MyIter()) def test_execute_many_generator(self): def mygen(): for i in range(5): yield (i,) self.cu.executemany("insert into test(income) values (?)", mygen()) def test_execute_many_wrong_sql_arg(self): with self.assertRaises(TypeError): self.cu.executemany(42, [(3,)]) def test_execute_many_select(self): with self.assertRaises(sqlite.ProgrammingError): self.cu.executemany("select ?", [(3,)]) def test_execute_many_not_iterable(self): with self.assertRaises(TypeError): self.cu.executemany("insert into test(income) values (?)", 42) def test_fetch_iter(self): # Optional DB-API extension. self.cu.execute("delete from test") self.cu.execute("insert into test(id) values (?)", (5,)) self.cu.execute("insert into test(id) values (?)", (6,)) self.cu.execute("select id from test order by id") lst = [] for row in self.cu: lst.append(row[0]) self.assertEqual(lst[0], 5) self.assertEqual(lst[1], 6) def test_fetchone(self): self.cu.execute("select name from test") row = self.cu.fetchone() self.assertEqual(row[0], "foo") row = self.cu.fetchone() self.assertEqual(row, None) def test_fetchone_no_statement(self): cur = self.cx.cursor() row = cur.fetchone() self.assertEqual(row, None) def test_array_size(self): # must default ot 1 self.assertEqual(self.cu.arraysize, 1) # now set to 2 self.cu.arraysize = 2 # now make the query return 3 rows self.cu.execute("delete from test") self.cu.execute("insert into test(name) values ('A')") self.cu.execute("insert into test(name) values ('B')") self.cu.execute("insert into test(name) values ('C')") self.cu.execute("select name from test") res = self.cu.fetchmany() self.assertEqual(len(res), 2) def test_fetchmany(self): self.cu.execute("select name from test") res = self.cu.fetchmany(100) self.assertEqual(len(res), 1) res = self.cu.fetchmany(100) self.assertEqual(res, []) def test_fetchmany_kw_arg(self): """Checks if fetchmany works with keyword arguments""" self.cu.execute("select name from test") res = self.cu.fetchmany(size=100) self.assertEqual(len(res), 1) def test_fetchall(self): self.cu.execute("select name from test") res = self.cu.fetchall() self.assertEqual(len(res), 1) res = self.cu.fetchall() self.assertEqual(res, []) def test_setinputsizes(self): self.cu.setinputsizes([3, 4, 5]) def test_setoutputsize(self): self.cu.setoutputsize(5, 0) def test_setoutputsize_no_column(self): self.cu.setoutputsize(42) def test_cursor_connection(self): # Optional DB-API extension. self.assertEqual(self.cu.connection, self.cx) def test_wrong_cursor_callable(self): with self.assertRaises(TypeError): def f(): pass cur = self.cx.cursor(f) def test_cursor_wrong_class(self): class Foo: pass foo = Foo() with self.assertRaises(TypeError): cur = sqlite.Cursor(foo) def test_last_row_id_on_replace(self): """ INSERT OR REPLACE and REPLACE INTO should produce the same behavior. """ sql = '{} INTO test(id, unique_test) VALUES (?, ?)' for statement in ('INSERT OR REPLACE', 'REPLACE'): with self.subTest(statement=statement): self.cu.execute(sql.format(statement), (1, 'foo')) self.assertEqual(self.cu.lastrowid, 1) def test_last_row_id_on_ignore(self): self.cu.execute( "insert or ignore into test(unique_test) values (?)", ('test',)) self.assertEqual(self.cu.lastrowid, 2) self.cu.execute( "insert or ignore into test(unique_test) values (?)", ('test',)) self.assertEqual(self.cu.lastrowid, 2) def test_last_row_id_insert_o_r(self): results = [] for statement in ('FAIL', 'ABORT', 'ROLLBACK'): sql = 'INSERT OR {} INTO test(unique_test) VALUES (?)' with self.subTest(statement='INSERT OR {}'.format(statement)): self.cu.execute(sql.format(statement), (statement,)) results.append((statement, self.cu.lastrowid)) with self.assertRaises(sqlite.IntegrityError): self.cu.execute(sql.format(statement), (statement,)) results.append((statement, self.cu.lastrowid)) expected = [ ('FAIL', 2), ('FAIL', 2), ('ABORT', 3), ('ABORT', 3), ('ROLLBACK', 4), ('ROLLBACK', 4), ] self.assertEqual(results, expected) class ThreadTests(unittest.TestCase): def setUp(self): self.con = sqlite.connect(":memory:") self.cur = self.con.cursor() self.cur.execute("create table test(id integer primary key, name text, bin binary, ratio number, ts timestamp)") def tearDown(self): self.cur.close() self.con.close() def test_con_cursor(self): def run(con, errors): try: cur = con.cursor() errors.append("did not raise ProgrammingError") return except sqlite.ProgrammingError: return except: errors.append("raised wrong exception") errors = [] t = threading.Thread(target=run, kwargs={"con": self.con, "errors": errors}) t.start() t.join() if len(errors) > 0: self.fail("\n".join(errors)) def test_con_commit(self): def run(con, errors): try: con.commit() errors.append("did not raise ProgrammingError") return except sqlite.ProgrammingError: return except: errors.append("raised wrong exception") errors = [] t = threading.Thread(target=run, kwargs={"con": self.con, "errors": errors}) t.start() t.join() if len(errors) > 0: self.fail("\n".join(errors)) def test_con_rollback(self): def run(con, errors): try: con.rollback() errors.append("did not raise ProgrammingError") return except sqlite.ProgrammingError: return except: errors.append("raised wrong exception") errors = [] t = threading.Thread(target=run, kwargs={"con": self.con, "errors": errors}) t.start() t.join() if len(errors) > 0: self.fail("\n".join(errors)) def test_con_close(self): def run(con, errors): try: con.close() errors.append("did not raise ProgrammingError") return except sqlite.ProgrammingError: return except: errors.append("raised wrong exception") errors = [] t = threading.Thread(target=run, kwargs={"con": self.con, "errors": errors}) t.start() t.join() if len(errors) > 0: self.fail("\n".join(errors)) def test_cur_implicit_begin(self): def run(cur, errors): try: cur.execute("insert into test(name) values ('a')") errors.append("did not raise ProgrammingError") return except sqlite.ProgrammingError: return except: errors.append("raised wrong exception") errors = [] t = threading.Thread(target=run, kwargs={"cur": self.cur, "errors": errors}) t.start() t.join() if len(errors) > 0: self.fail("\n".join(errors)) def test_cur_close(self): def run(cur, errors): try: cur.close() errors.append("did not raise ProgrammingError") return except sqlite.ProgrammingError: return except: errors.append("raised wrong exception") errors = [] t = threading.Thread(target=run, kwargs={"cur": self.cur, "errors": errors}) t.start() t.join() if len(errors) > 0: self.fail("\n".join(errors)) def test_cur_execute(self): def run(cur, errors): try: cur.execute("select name from test") errors.append("did not raise ProgrammingError") return except sqlite.ProgrammingError: return except: errors.append("raised wrong exception") errors = [] self.cur.execute("insert into test(name) values ('a')") t = threading.Thread(target=run, kwargs={"cur": self.cur, "errors": errors}) t.start() t.join() if len(errors) > 0: self.fail("\n".join(errors)) def test_cur_iter_next(self): def run(cur, errors): try: row = cur.fetchone() errors.append("did not raise ProgrammingError") return except sqlite.ProgrammingError: return except: errors.append("raised wrong exception") errors = [] self.cur.execute("insert into test(name) values ('a')") self.cur.execute("select name from test") t = threading.Thread(target=run, kwargs={"cur": self.cur, "errors": errors}) t.start() t.join() if len(errors) > 0: self.fail("\n".join(errors)) class ConstructorTests(unittest.TestCase): def test_date(self): d = sqlite.Date(2004, 10, 28) def test_time(self): t = sqlite.Time(12, 39, 35) def test_timestamp(self): ts = sqlite.Timestamp(2004, 10, 28, 12, 39, 35) def test_date_from_ticks(self): d = sqlite.DateFromTicks(42) def test_time_from_ticks(self): t = sqlite.TimeFromTicks(42) def test_timestamp_from_ticks(self): ts = sqlite.TimestampFromTicks(42) def test_binary(self): b = sqlite.Binary(b"\0'") class ExtensionTests(unittest.TestCase): def test_script_string_sql(self): con = sqlite.connect(":memory:") cur = con.cursor() cur.executescript(""" -- bla bla /* a stupid comment */ create table a(i); insert into a(i) values (5); """) cur.execute("select i from a") res = cur.fetchone()[0] self.assertEqual(res, 5) def test_script_syntax_error(self): con = sqlite.connect(":memory:") cur = con.cursor() with self.assertRaises(sqlite.OperationalError): cur.executescript("create table test(x); asdf; create table test2(x)") def test_script_error_normal(self): con = sqlite.connect(":memory:") cur = con.cursor() with self.assertRaises(sqlite.OperationalError): cur.executescript("create table test(sadfsadfdsa); select foo from hurz;") def test_cursor_executescript_as_bytes(self): con = sqlite.connect(":memory:") cur = con.cursor() with self.assertRaises(ValueError) as cm: cur.executescript(b"create table test(foo); insert into test(foo) values (5);") self.assertEqual(str(cm.exception), 'script argument must be unicode.') def test_connection_execute(self): con = sqlite.connect(":memory:") result = con.execute("select 5").fetchone()[0] self.assertEqual(result, 5, "Basic test of Connection.execute") def test_connection_executemany(self): con = sqlite.connect(":memory:") con.execute("create table test(foo)") con.executemany("insert into test(foo) values (?)", [(3,), (4,)]) result = con.execute("select foo from test order by foo").fetchall() self.assertEqual(result[0][0], 3, "Basic test of Connection.executemany") self.assertEqual(result[1][0], 4, "Basic test of Connection.executemany") def test_connection_executescript(self): con = sqlite.connect(":memory:") con.executescript("create table test(foo); insert into test(foo) values (5);") result = con.execute("select foo from test").fetchone()[0] self.assertEqual(result, 5, "Basic test of Connection.executescript") class ClosedConTests(unittest.TestCase): def test_closed_con_cursor(self): con = sqlite.connect(":memory:") con.close() with self.assertRaises(sqlite.ProgrammingError): cur = con.cursor() def test_closed_con_commit(self): con = sqlite.connect(":memory:") con.close() with self.assertRaises(sqlite.ProgrammingError): con.commit() def test_closed_con_rollback(self): con = sqlite.connect(":memory:") con.close() with self.assertRaises(sqlite.ProgrammingError): con.rollback() def test_closed_cur_execute(self): con = sqlite.connect(":memory:") cur = con.cursor() con.close() with self.assertRaises(sqlite.ProgrammingError): cur.execute("select 4") def test_closed_create_function(self): con = sqlite.connect(":memory:") con.close() def f(x): return 17 with self.assertRaises(sqlite.ProgrammingError): con.create_function("foo", 1, f) def test_closed_create_aggregate(self): con = sqlite.connect(":memory:") con.close() class Agg: def __init__(self): pass def step(self, x): pass def finalize(self): return 17 with self.assertRaises(sqlite.ProgrammingError): con.create_aggregate("foo", 1, Agg) def test_closed_set_authorizer(self): con = sqlite.connect(":memory:") con.close() def authorizer(*args): return sqlite.DENY with self.assertRaises(sqlite.ProgrammingError): con.set_authorizer(authorizer) def test_closed_set_progress_callback(self): con = sqlite.connect(":memory:") con.close() def progress(): pass with self.assertRaises(sqlite.ProgrammingError): con.set_progress_handler(progress, 100) def test_closed_call(self): con = sqlite.connect(":memory:") con.close() with self.assertRaises(sqlite.ProgrammingError): con() class ClosedCurTests(unittest.TestCase): def test_closed(self): con = sqlite.connect(":memory:") cur = con.cursor() cur.close() for method_name in ("execute", "executemany", "executescript", "fetchall", "fetchmany", "fetchone"): if method_name in ("execute", "executescript"): params = ("select 4 union select 5",) elif method_name == "executemany": params = ("insert into foo(bar) values (?)", [(3,), (4,)]) else: params = [] with self.assertRaises(sqlite.ProgrammingError): method = getattr(cur, method_name) method(*params) class SqliteOnConflictTests(unittest.TestCase): """ Tests for SQLite's "insert on conflict" feature. See https://www.sqlite.org/lang_conflict.html for details. """ def setUp(self): self.cx = sqlite.connect(":memory:") self.cu = self.cx.cursor() self.cu.execute(""" CREATE TABLE test( id INTEGER PRIMARY KEY, name TEXT, unique_name TEXT UNIQUE ); """) def tearDown(self): self.cu.close() self.cx.close() def test_on_conflict_rollback_with_explicit_transaction(self): self.cx.isolation_level = None # autocommit mode self.cu = self.cx.cursor() # Start an explicit transaction. self.cu.execute("BEGIN") self.cu.execute("INSERT INTO test(name) VALUES ('abort_test')") self.cu.execute("INSERT OR ROLLBACK INTO test(unique_name) VALUES ('foo')") with self.assertRaises(sqlite.IntegrityError): self.cu.execute("INSERT OR ROLLBACK INTO test(unique_name) VALUES ('foo')") # Use connection to commit. self.cx.commit() self.cu.execute("SELECT name, unique_name from test") # Transaction should have rolled back and nothing should be in table. self.assertEqual(self.cu.fetchall(), []) def test_on_conflict_abort_raises_with_explicit_transactions(self): # Abort cancels the current sql statement but doesn't change anything # about the current transaction. self.cx.isolation_level = None # autocommit mode self.cu = self.cx.cursor() # Start an explicit transaction. self.cu.execute("BEGIN") self.cu.execute("INSERT INTO test(name) VALUES ('abort_test')") self.cu.execute("INSERT OR ABORT INTO test(unique_name) VALUES ('foo')") with self.assertRaises(sqlite.IntegrityError): self.cu.execute("INSERT OR ABORT INTO test(unique_name) VALUES ('foo')") self.cx.commit() self.cu.execute("SELECT name, unique_name FROM test") # Expect the first two inserts to work, third to do nothing. self.assertEqual(self.cu.fetchall(), [('abort_test', None), (None, 'foo',)]) def test_on_conflict_rollback_without_transaction(self): # Start of implicit transaction self.cu.execute("INSERT INTO test(name) VALUES ('abort_test')") self.cu.execute("INSERT OR ROLLBACK INTO test(unique_name) VALUES ('foo')") with self.assertRaises(sqlite.IntegrityError): self.cu.execute("INSERT OR ROLLBACK INTO test(unique_name) VALUES ('foo')") self.cu.execute("SELECT name, unique_name FROM test") # Implicit transaction is rolled back on error. self.assertEqual(self.cu.fetchall(), []) def test_on_conflict_abort_raises_without_transactions(self): # Abort cancels the current sql statement but doesn't change anything # about the current transaction. self.cu.execute("INSERT INTO test(name) VALUES ('abort_test')") self.cu.execute("INSERT OR ABORT INTO test(unique_name) VALUES ('foo')") with self.assertRaises(sqlite.IntegrityError): self.cu.execute("INSERT OR ABORT INTO test(unique_name) VALUES ('foo')") # Make sure all other values were inserted. self.cu.execute("SELECT name, unique_name FROM test") self.assertEqual(self.cu.fetchall(), [('abort_test', None), (None, 'foo',)]) def test_on_conflict_fail(self): self.cu.execute("INSERT OR FAIL INTO test(unique_name) VALUES ('foo')") with self.assertRaises(sqlite.IntegrityError): self.cu.execute("INSERT OR FAIL INTO test(unique_name) VALUES ('foo')") self.assertEqual(self.cu.fetchall(), []) def test_on_conflict_ignore(self): self.cu.execute("INSERT OR IGNORE INTO test(unique_name) VALUES ('foo')") # Nothing should happen. self.cu.execute("INSERT OR IGNORE INTO test(unique_name) VALUES ('foo')") self.cu.execute("SELECT unique_name FROM test") self.assertEqual(self.cu.fetchall(), [('foo',)]) def test_on_conflict_replace(self): self.cu.execute("INSERT OR REPLACE INTO test(name, unique_name) VALUES ('Data!', 'foo')") # There shouldn't be an IntegrityError exception. self.cu.execute("INSERT OR REPLACE INTO test(name, unique_name) VALUES ('Very different data!', 'foo')") self.cu.execute("SELECT name, unique_name FROM test") self.assertEqual(self.cu.fetchall(), [('Very different data!', 'foo')]) def suite(): tests = [ ClosedConTests, ClosedCurTests, ConnectionTests, ConstructorTests, CursorTests, ExtensionTests, ModuleTests, SqliteOnConflictTests, ThreadTests, ] return unittest.TestSuite( [unittest.TestLoader().loadTestsFromTestCase(t) for t in tests] ) def test(): runner = unittest.TextTestRunner() runner.run(suite()) if __name__ == "__main__": test()