#!/usr/bin/env python # # Public Domain 2014-2016 MongoDB, Inc. # Public Domain 2008-2014 WiredTiger, Inc. # # This is free and unencumbered software released into the public domain. # # Anyone is free to copy, modify, publish, use, compile, sell, or # distribute this software, either in source code form or as a compiled # binary, for any purpose, commercial or non-commercial, and by any # means. # # In jurisdictions that recognize copyright laws, the author or authors # of this software dedicate any and all copyright interest in the # software to the public domain. We make this dedication for the benefit # of the public at large and to the detriment of our heirs and # successors. We intend this dedication to be an overt act of # relinquishment in perpetuity of all present and future rights to this # software under copyright law. # # THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, # EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF # MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. # IN NO EVENT SHALL THE AUTHORS BE LIABLE FOR ANY CLAIM, DAMAGES OR # OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, # ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR # OTHER DEALINGS IN THE SOFTWARE. # # test_bug008.py # Regression tests. import wiredtiger, wttest from wtdataset import SimpleDataSet from wtscenario import make_scenarios # Test search/search-near operations, including invisible values and keys # past the end of the table. class test_bug008(wttest.WiredTigerTestCase): uri = 'file:test_bug008' # This is a btree layer test. scenarios = make_scenarios([ ('fix', dict(key_format='r', value_format='8t', empty=1, colvar=0)), ('row', dict(key_format='S', value_format='S', empty=0, colvar=0)), ('var', dict(key_format='r', value_format='S', empty=0, colvar=1)) ]) # Verify cursor search and search-near operations in an empty table. def test_search_empty(self): # Create the object and open a cursor. ds = SimpleDataSet(self, self.uri, 0, key_format=self.key_format, value_format=self.value_format) ds.create() cursor = self.session.open_cursor(self.uri, None) # Search for a record past the end of the table, which should fail. cursor.set_key(ds.key(100)) self.assertEqual(cursor.search(), wiredtiger.WT_NOTFOUND) # Search-near for a record past the end of the table, which should fail. cursor.set_key(ds.key(100)) self.assertEqual(cursor.search_near(), wiredtiger.WT_NOTFOUND) # Verify cursor search and search-near operations at and past the end of # a file, with a set of on-page visible records. def test_search_eot(self): # Populate the tree and reopen the connection, forcing it to disk # and moving the records to an on-page format. ds = SimpleDataSet(self, self.uri, 100, key_format=self.key_format, value_format=self.value_format) ds.populate() self.reopen_conn() # Open a cursor. cursor = self.session.open_cursor(self.uri, None) # Search for a record at the end of the table, which should succeed. cursor.set_key(ds.key(100)) self.assertEqual(cursor.search(), 0) self.assertEqual(cursor.get_key(), ds.key(100)) self.assertEqual(cursor.get_value(), ds.value(100)) # Search-near for a record at the end of the table, which should # succeed, returning the last record. cursor.set_key(ds.key(100)) self.assertEqual(cursor.search_near(), 0) self.assertEqual(cursor.get_key(), ds.key(100)) self.assertEqual(cursor.get_value(), ds.value(100)) # Search for a record past the end of the table, which should fail. cursor.set_key(ds.key(200)) self.assertEqual(cursor.search(), wiredtiger.WT_NOTFOUND) # Search-near for a record past the end of the table, which should # succeed, returning the last record. cursor.set_key(ds.key(200)) self.assertEqual(cursor.search_near(), -1) self.assertEqual(cursor.get_key(), ds.key(100)) self.assertEqual(cursor.get_value(), ds.value(100)) # Verify cursor search-near operations before and after a set of # column-store duplicates. def test_search_duplicate(self): if self.colvar == 0: return # Populate the tree. ds = SimpleDataSet(self, self.uri, 105, key_format=self.key_format, value_format=self.value_format) ds.populate() # Set up deleted records before and after a set of duplicate records, # and make sure search/search-near returns the correct record. cursor = self.session.open_cursor(self.uri, None) for i in range(20, 100): cursor[ds.key(i)] = '=== IDENTICAL VALUE ===' for i in range(15, 25): cursor.set_key(ds.key(i)) self.assertEqual(cursor.remove(), 0) for i in range(95, 106): cursor.set_key(ds.key(i)) self.assertEqual(cursor.remove(), 0) cursor.close() # Reopen the connection, forcing it to disk and moving the records to # an on-page format. self.reopen_conn() # Open a cursor. cursor = self.session.open_cursor(self.uri, None) # Search-near for a record in the deleted set before the duplicate set, # which should succeed, returning the first record in the duplicate set. cursor.set_key(ds.key(18)) self.assertEqual(cursor.search_near(), 1) self.assertEqual(cursor.get_key(), ds.key(25)) # Search-near for a record in the deleted set after the duplicate set, # which should succeed, returning the last record in the duplicate set. cursor.set_key(ds.key(98)) self.assertEqual(cursor.search_near(), -1) self.assertEqual(cursor.get_key(), ds.key(94)) # Verify cursor search and search-near operations on a file with a set of # on-page visible records, and a set of insert-list invisible records. def test_search_invisible_one(self): # Populate the tree. ds = SimpleDataSet(self, self.uri, 100, key_format=self.key_format, value_format=self.value_format) ds.populate() # Delete a range of records. for i in range(5, 10): cursor = self.session.open_cursor(self.uri, None) cursor.set_key(ds.key(i)) self.assertEqual(cursor.remove(), 0) # Reopen the connection, forcing it to disk and moving the records to # an on-page format. self.reopen_conn() # Add updates to the existing records (in both the deleted an undeleted # range), as well as some new records after the end. Put the updates in # a separate transaction so they're invisible to another cursor. self.session.begin_transaction() cursor = self.session.open_cursor(self.uri, None) for i in range(5, 10): cursor[ds.key(i)] = ds.value(i + 1000) for i in range(30, 40): cursor[ds.key(i)] = ds.value(i + 1000) for i in range(100, 140): cursor[ds.key(i)] = ds.value(i + 1000) # Open a separate session and cursor. s = self.conn.open_session() cursor = s.open_cursor(self.uri, None) # Search for an existing record in the deleted range, should not find # it. for i in range(5, 10): cursor.set_key(ds.key(i)) if self.empty: # Fixed-length column-store rows always exist. self.assertEqual(cursor.search(), 0) self.assertEqual(cursor.get_key(), i) self.assertEqual(cursor.get_value(), 0) else: self.assertEqual(cursor.search(), wiredtiger.WT_NOTFOUND) # Search for an existing record in the updated range, should see the # original value. for i in range(30, 40): cursor.set_key(ds.key(i)) self.assertEqual(cursor.search(), 0) self.assertEqual(cursor.get_key(), ds.key(i)) # Search for a added record, should not find it. for i in range(120, 130): cursor.set_key(ds.key(i)) if self.empty: # Invisible updates to fixed-length column-store objects are # invisible to the reader, but the fact that they exist past # the end of the initial records causes the instantiation of # empty records: confirm successful return of an empty row. self.assertEqual(cursor.search(), 0) self.assertEqual(cursor.get_key(), i) self.assertEqual(cursor.get_value(), 0) else: # Otherwise, we should not find any matching records. self.assertEqual(cursor.search(), wiredtiger.WT_NOTFOUND) # Search-near for an existing record in the deleted range, should find # the next largest record. (This depends on the implementation behavior # which currently includes a bias to prefix search.) for i in range(5, 10): cursor.set_key(ds.key(i)) if self.empty: # Fixed-length column-store rows always exist. self.assertEqual(cursor.search_near(), 0) self.assertEqual(cursor.get_key(), i) self.assertEqual(cursor.get_value(), 0) else: self.assertEqual(cursor.search_near(), 1) self.assertEqual(cursor.get_key(), ds.key(10)) # Search-near for an existing record in the updated range, should see # the original value. for i in range(30, 40): cursor.set_key(ds.key(i)) self.assertEqual(cursor.search_near(), 0) self.assertEqual(cursor.get_key(), ds.key(i)) # Search-near for an added record, should find the previous largest # record. for i in range(120, 130): cursor.set_key(ds.key(i)) if self.empty: # Invisible updates to fixed-length column-store objects are # invisible to the reader, but the fact that they exist past # the end of the initial records causes the instantiation of # empty records: confirm successful return of an empty row. self.assertEqual(cursor.search_near(), 0) self.assertEqual(cursor.get_key(), i) self.assertEqual(cursor.get_value(), 0) else: self.assertEqual(cursor.search_near(), -1) self.assertEqual(cursor.get_key(), ds.key(100)) # Verify cursor search and search-near operations on a file with a set of # on-page visible records, a set of insert-list visible records, and a set # of insert-list invisible records. (The reason I'm adding this slightly # different test is because I want to confirm that if search positions the # the cursor in the insert list with a set of invisible updates, the right # fallback happens, whether the correct position is in the page slots or # the insert list.) def test_search_invisible_two(self): # Populate the tree and reopen the connection, forcing it to disk # and moving the records to an on-page format. ds = SimpleDataSet(self, self.uri, 100, key_format=self.key_format, value_format=self.value_format) ds.populate() self.reopen_conn() # Add some additional visible records. cursor = self.session.open_cursor(self.uri, None) for i in range(100, 120): cursor[ds.key(i)] = ds.value(i) cursor.close() # Begin a transaction, and add some additional records. self.session.begin_transaction() cursor = self.session.open_cursor(self.uri, None) for i in range(120, 140): cursor[ds.key(i)] = ds.value(i) # Open a separate session and cursor. s = self.conn.open_session() cursor = s.open_cursor(self.uri, None) # Search for an invisible record. cursor.set_key(ds.key(130)) if self.empty: # Invisible updates to fixed-length column-store objects are # invisible to the reader, but the fact that they exist past # the end of the initial records causes the instantiation of # empty records: confirm successful return of an empty row. cursor.search() self.assertEqual(cursor.get_key(), 130) self.assertEqual(cursor.get_value(), 0) else: # Otherwise, we should not find any matching records. self.assertEqual(cursor.search(), wiredtiger.WT_NOTFOUND) # Search-near for an invisible record, which should succeed, returning # the last visible record. cursor.set_key(ds.key(130)) cursor.search_near() if self.empty: # Invisible updates to fixed-length column-store objects are # invisible to the reader, but the fact that they exist past # the end of the initial records causes the instantiation of # empty records: confirm successful return of an empty row. cursor.search() self.assertEqual(cursor.get_key(), 130) self.assertEqual(cursor.get_value(), 0) else: # Otherwise, we should find the closest record for which we can see # the value. self.assertEqual(cursor.get_key(), ds.key(119)) self.assertEqual(cursor.get_value(), ds.value(119)) if __name__ == '__main__': wttest.run()