[Python-checkins] r46021 - in python/trunk: Doc/lib/sqlite3/adapter_datetime.py Doc/lib/sqlite3/adapter_point_1.py Doc/lib/sqlite3/adapter_point_2.py Doc/lib/sqlite3/collation_reverse.py Doc/lib/sqlite3/complete_statement.py Doc/lib/sqlite3/connect_db_1.py Doc/lib/sqlite3/connect_db_2.py Doc/lib/sqlite3/converter_point.py Doc/lib/sqlite3/countcursors.py Doc/lib/sqlite3/createdb.py Doc/lib/sqlite3/execsql_fetchonerow.py Doc/lib/sqlite3/execsql_printall_1.py Doc/lib/sqlite3/execute_1.py Doc/lib/sqlite3/execute_2.py Doc/lib/sqlite3/execute_3.py Doc/lib/sqlite3/executemany_1.py Doc/lib/sqlite3/executemany_2.py Doc/lib/sqlite3/executescript.py Doc/lib/sqlite3/insert_more_people.py Doc/lib/sqlite3/md5func.py Doc/lib/sqlite3/mysumaggr.py Doc/lib/sqlite3/parse_colnames.py Doc/lib/sqlite3/pysqlite_datetime.py Doc/lib/sqlite3/row_factory.py Doc/lib/sqlite3/rowclass.py Doc/lib/sqlite3/shared_cache.py Doc/lib/sqlite3/shortcut_methods.py Doc/lib/sqlite3/simple_tableprinter.py Doc/lib/sqlite3/text_factory.py Lib/test/test_bigmem.py Mac/OSX/Icons/ReadMe.txt
tim.peters
python-checkins at python.org
Wed May 17 01:24:10 CEST 2006
Author: tim.peters
Date: Wed May 17 01:24:08 2006
New Revision: 46021
Modified:
python/trunk/Doc/lib/sqlite3/adapter_datetime.py (contents, props changed)
python/trunk/Doc/lib/sqlite3/adapter_point_1.py (contents, props changed)
python/trunk/Doc/lib/sqlite3/adapter_point_2.py (contents, props changed)
python/trunk/Doc/lib/sqlite3/collation_reverse.py (contents, props changed)
python/trunk/Doc/lib/sqlite3/complete_statement.py (props changed)
python/trunk/Doc/lib/sqlite3/connect_db_1.py (contents, props changed)
python/trunk/Doc/lib/sqlite3/connect_db_2.py (contents, props changed)
python/trunk/Doc/lib/sqlite3/converter_point.py (contents, props changed)
python/trunk/Doc/lib/sqlite3/countcursors.py (contents, props changed)
python/trunk/Doc/lib/sqlite3/createdb.py (contents, props changed)
python/trunk/Doc/lib/sqlite3/execsql_fetchonerow.py (contents, props changed)
python/trunk/Doc/lib/sqlite3/execsql_printall_1.py (contents, props changed)
python/trunk/Doc/lib/sqlite3/execute_1.py (contents, props changed)
python/trunk/Doc/lib/sqlite3/execute_2.py (contents, props changed)
python/trunk/Doc/lib/sqlite3/execute_3.py (contents, props changed)
python/trunk/Doc/lib/sqlite3/executemany_1.py (contents, props changed)
python/trunk/Doc/lib/sqlite3/executemany_2.py (contents, props changed)
python/trunk/Doc/lib/sqlite3/executescript.py (contents, props changed)
python/trunk/Doc/lib/sqlite3/insert_more_people.py (contents, props changed)
python/trunk/Doc/lib/sqlite3/md5func.py (contents, props changed)
python/trunk/Doc/lib/sqlite3/mysumaggr.py (contents, props changed)
python/trunk/Doc/lib/sqlite3/parse_colnames.py (contents, props changed)
python/trunk/Doc/lib/sqlite3/pysqlite_datetime.py (contents, props changed)
python/trunk/Doc/lib/sqlite3/row_factory.py (contents, props changed)
python/trunk/Doc/lib/sqlite3/rowclass.py (props changed)
python/trunk/Doc/lib/sqlite3/shared_cache.py (props changed)
python/trunk/Doc/lib/sqlite3/shortcut_methods.py (contents, props changed)
python/trunk/Doc/lib/sqlite3/simple_tableprinter.py (contents, props changed)
python/trunk/Doc/lib/sqlite3/text_factory.py (contents, props changed)
python/trunk/Lib/test/test_bigmem.py (contents, props changed)
python/trunk/Mac/OSX/Icons/ReadMe.txt (props changed)
Log:
Text files missing the SVN eol-style property.
Modified: python/trunk/Doc/lib/sqlite3/adapter_datetime.py
==============================================================================
--- python/trunk/Doc/lib/sqlite3/adapter_datetime.py (original)
+++ python/trunk/Doc/lib/sqlite3/adapter_datetime.py Wed May 17 01:24:08 2006
@@ -1,14 +1,14 @@
-import sqlite3
-import datetime, time
-
-def adapt_datetime(ts):
- return time.mktime(ts.timetuple())
-
-sqlite3.register_adapter(datetime.datetime, adapt_datetime)
-
-con = sqlite3.connect(":memory:")
-cur = con.cursor()
-
-now = datetime.datetime.now()
-cur.execute("select ?", (now,))
-print cur.fetchone()[0]
+import sqlite3
+import datetime, time
+
+def adapt_datetime(ts):
+ return time.mktime(ts.timetuple())
+
+sqlite3.register_adapter(datetime.datetime, adapt_datetime)
+
+con = sqlite3.connect(":memory:")
+cur = con.cursor()
+
+now = datetime.datetime.now()
+cur.execute("select ?", (now,))
+print cur.fetchone()[0]
Modified: python/trunk/Doc/lib/sqlite3/adapter_point_1.py
==============================================================================
--- python/trunk/Doc/lib/sqlite3/adapter_point_1.py (original)
+++ python/trunk/Doc/lib/sqlite3/adapter_point_1.py Wed May 17 01:24:08 2006
@@ -1,16 +1,16 @@
-import sqlite3
-
-class Point(object):
- def __init__(self, x, y):
- self.x, self.y = x, y
-
- def __conform__(self, protocol):
- if protocol is sqlite3.PrepareProtocol:
- return "%f;%f" % (self.x, self.y)
-
-con = sqlite3.connect(":memory:")
-cur = con.cursor()
-
-p = Point(4.0, -3.2)
-cur.execute("select ?", (p,))
-print cur.fetchone()[0]
+import sqlite3
+
+class Point(object):
+ def __init__(self, x, y):
+ self.x, self.y = x, y
+
+ def __conform__(self, protocol):
+ if protocol is sqlite3.PrepareProtocol:
+ return "%f;%f" % (self.x, self.y)
+
+con = sqlite3.connect(":memory:")
+cur = con.cursor()
+
+p = Point(4.0, -3.2)
+cur.execute("select ?", (p,))
+print cur.fetchone()[0]
Modified: python/trunk/Doc/lib/sqlite3/adapter_point_2.py
==============================================================================
--- python/trunk/Doc/lib/sqlite3/adapter_point_2.py (original)
+++ python/trunk/Doc/lib/sqlite3/adapter_point_2.py Wed May 17 01:24:08 2006
@@ -1,17 +1,17 @@
-import sqlite3
-
-class Point(object):
- def __init__(self, x, y):
- self.x, self.y = x, y
-
-def adapt_point(point):
- return "%f;%f" % (point.x, point.y)
-
-sqlite3.register_adapter(Point, adapt_point)
-
-con = sqlite3.connect(":memory:")
-cur = con.cursor()
-
-p = Point(4.0, -3.2)
-cur.execute("select ?", (p,))
-print cur.fetchone()[0]
+import sqlite3
+
+class Point(object):
+ def __init__(self, x, y):
+ self.x, self.y = x, y
+
+def adapt_point(point):
+ return "%f;%f" % (point.x, point.y)
+
+sqlite3.register_adapter(Point, adapt_point)
+
+con = sqlite3.connect(":memory:")
+cur = con.cursor()
+
+p = Point(4.0, -3.2)
+cur.execute("select ?", (p,))
+print cur.fetchone()[0]
Modified: python/trunk/Doc/lib/sqlite3/collation_reverse.py
==============================================================================
--- python/trunk/Doc/lib/sqlite3/collation_reverse.py (original)
+++ python/trunk/Doc/lib/sqlite3/collation_reverse.py Wed May 17 01:24:08 2006
@@ -1,15 +1,15 @@
-import sqlite3
-
-def collate_reverse(string1, string2):
- return -cmp(string1, string2)
-
-con = sqlite3.connect(":memory:")
-con.create_collation("reverse", collate_reverse)
-
-cur = con.cursor()
-cur.execute("create table test(x)")
-cur.executemany("insert into test(x) values (?)", [("a",), ("b",)])
-cur.execute("select x from test order by x collate reverse")
-for row in cur:
- print row
-con.close()
+import sqlite3
+
+def collate_reverse(string1, string2):
+ return -cmp(string1, string2)
+
+con = sqlite3.connect(":memory:")
+con.create_collation("reverse", collate_reverse)
+
+cur = con.cursor()
+cur.execute("create table test(x)")
+cur.executemany("insert into test(x) values (?)", [("a",), ("b",)])
+cur.execute("select x from test order by x collate reverse")
+for row in cur:
+ print row
+con.close()
Modified: python/trunk/Doc/lib/sqlite3/connect_db_1.py
==============================================================================
--- python/trunk/Doc/lib/sqlite3/connect_db_1.py (original)
+++ python/trunk/Doc/lib/sqlite3/connect_db_1.py Wed May 17 01:24:08 2006
@@ -1,3 +1,3 @@
-import sqlite3
-
-con = sqlite3.connect("mydb")
+import sqlite3
+
+con = sqlite3.connect("mydb")
Modified: python/trunk/Doc/lib/sqlite3/connect_db_2.py
==============================================================================
--- python/trunk/Doc/lib/sqlite3/connect_db_2.py (original)
+++ python/trunk/Doc/lib/sqlite3/connect_db_2.py Wed May 17 01:24:08 2006
@@ -1,3 +1,3 @@
-import sqlite3
-
-con = sqlite3.connect(":memory:")
+import sqlite3
+
+con = sqlite3.connect(":memory:")
Modified: python/trunk/Doc/lib/sqlite3/converter_point.py
==============================================================================
--- python/trunk/Doc/lib/sqlite3/converter_point.py (original)
+++ python/trunk/Doc/lib/sqlite3/converter_point.py Wed May 17 01:24:08 2006
@@ -1,47 +1,47 @@
-import sqlite3
-
-class Point(object):
- def __init__(self, x, y):
- self.x, self.y = x, y
-
- def __repr__(self):
- return "(%f;%f)" % (self.x, self.y)
-
-def adapt_point(point):
- return "%f;%f" % (point.x, point.y)
-
-def convert_point(s):
- x, y = map(float, s.split(";"))
- return Point(x, y)
-
-# Register the adapter
-sqlite3.register_adapter(Point, adapt_point)
-
-# Register the converter
-sqlite3.register_converter("point", convert_point)
-
-p = Point(4.0, -3.2)
-
-#########################
-# 1) Using declared types
-con = sqlite3.connect(":memory:", detect_types=sqlite3.PARSE_DECLTYPES)
-cur = con.cursor()
-cur.execute("create table test(p point)")
-
-cur.execute("insert into test(p) values (?)", (p,))
-cur.execute("select p from test")
-print "with declared types:", cur.fetchone()[0]
-cur.close()
-con.close()
-
-#######################
-# 1) Using column names
-con = sqlite3.connect(":memory:", detect_types=sqlite3.PARSE_COLNAMES)
-cur = con.cursor()
-cur.execute("create table test(p)")
-
-cur.execute("insert into test(p) values (?)", (p,))
-cur.execute('select p as "p [point]" from test')
-print "with column names:", cur.fetchone()[0]
-cur.close()
-con.close()
+import sqlite3
+
+class Point(object):
+ def __init__(self, x, y):
+ self.x, self.y = x, y
+
+ def __repr__(self):
+ return "(%f;%f)" % (self.x, self.y)
+
+def adapt_point(point):
+ return "%f;%f" % (point.x, point.y)
+
+def convert_point(s):
+ x, y = map(float, s.split(";"))
+ return Point(x, y)
+
+# Register the adapter
+sqlite3.register_adapter(Point, adapt_point)
+
+# Register the converter
+sqlite3.register_converter("point", convert_point)
+
+p = Point(4.0, -3.2)
+
+#########################
+# 1) Using declared types
+con = sqlite3.connect(":memory:", detect_types=sqlite3.PARSE_DECLTYPES)
+cur = con.cursor()
+cur.execute("create table test(p point)")
+
+cur.execute("insert into test(p) values (?)", (p,))
+cur.execute("select p from test")
+print "with declared types:", cur.fetchone()[0]
+cur.close()
+con.close()
+
+#######################
+# 1) Using column names
+con = sqlite3.connect(":memory:", detect_types=sqlite3.PARSE_COLNAMES)
+cur = con.cursor()
+cur.execute("create table test(p)")
+
+cur.execute("insert into test(p) values (?)", (p,))
+cur.execute('select p as "p [point]" from test')
+print "with column names:", cur.fetchone()[0]
+cur.close()
+con.close()
Modified: python/trunk/Doc/lib/sqlite3/countcursors.py
==============================================================================
--- python/trunk/Doc/lib/sqlite3/countcursors.py (original)
+++ python/trunk/Doc/lib/sqlite3/countcursors.py Wed May 17 01:24:08 2006
@@ -1,15 +1,15 @@
-import sqlite3
-
-class CountCursorsConnection(sqlite3.Connection):
- def __init__(self, *args, **kwargs):
- sqlite3.Connection.__init__(self, *args, **kwargs)
- self.numcursors = 0
-
- def cursor(self, *args, **kwargs):
- self.numcursors += 1
- return sqlite3.Connection.cursor(self, *args, **kwargs)
-
-con = sqlite3.connect(":memory:", factory=CountCursorsConnection)
-cur1 = con.cursor()
-cur2 = con.cursor()
-print con.numcursors
+import sqlite3
+
+class CountCursorsConnection(sqlite3.Connection):
+ def __init__(self, *args, **kwargs):
+ sqlite3.Connection.__init__(self, *args, **kwargs)
+ self.numcursors = 0
+
+ def cursor(self, *args, **kwargs):
+ self.numcursors += 1
+ return sqlite3.Connection.cursor(self, *args, **kwargs)
+
+con = sqlite3.connect(":memory:", factory=CountCursorsConnection)
+cur1 = con.cursor()
+cur2 = con.cursor()
+print con.numcursors
Modified: python/trunk/Doc/lib/sqlite3/createdb.py
==============================================================================
--- python/trunk/Doc/lib/sqlite3/createdb.py (original)
+++ python/trunk/Doc/lib/sqlite3/createdb.py Wed May 17 01:24:08 2006
@@ -1,28 +1,28 @@
-# Not referenced from the documentation, but builds the database file the other
-# code snippets expect.
-
-import sqlite3
-import os
-
-DB_FILE = "mydb"
-
-if os.path.exists(DB_FILE):
- os.remove(DB_FILE)
-
-con = sqlite3.connect(DB_FILE)
-cur = con.cursor()
-cur.execute("""
- create table people
- (
- name_last varchar(20),
- age integer
- )
- """)
-
-cur.execute("insert into people (name_last, age) values ('Yeltsin', 72)")
-cur.execute("insert into people (name_last, age) values ('Putin', 51)")
-
-con.commit()
-
-cur.close()
-con.close()
+# Not referenced from the documentation, but builds the database file the other
+# code snippets expect.
+
+import sqlite3
+import os
+
+DB_FILE = "mydb"
+
+if os.path.exists(DB_FILE):
+ os.remove(DB_FILE)
+
+con = sqlite3.connect(DB_FILE)
+cur = con.cursor()
+cur.execute("""
+ create table people
+ (
+ name_last varchar(20),
+ age integer
+ )
+ """)
+
+cur.execute("insert into people (name_last, age) values ('Yeltsin', 72)")
+cur.execute("insert into people (name_last, age) values ('Putin', 51)")
+
+con.commit()
+
+cur.close()
+con.close()
Modified: python/trunk/Doc/lib/sqlite3/execsql_fetchonerow.py
==============================================================================
--- python/trunk/Doc/lib/sqlite3/execsql_fetchonerow.py (original)
+++ python/trunk/Doc/lib/sqlite3/execsql_fetchonerow.py Wed May 17 01:24:08 2006
@@ -1,17 +1,17 @@
-import sqlite3
-
-con = sqlite3.connect("mydb")
-
-cur = con.cursor()
-SELECT = "select name_last, age from people order by age, name_last"
-
-# 1. Iterate over the rows available from the cursor, unpacking the
-# resulting sequences to yield their elements (name_last, age):
-cur.execute(SELECT)
-for (name_last, age) in cur:
- print '%s is %d years old.' % (name_last, age)
-
-# 2. Equivalently:
-cur.execute(SELECT)
-for row in cur:
- print '%s is %d years old.' % (row[0], row[1])
+import sqlite3
+
+con = sqlite3.connect("mydb")
+
+cur = con.cursor()
+SELECT = "select name_last, age from people order by age, name_last"
+
+# 1. Iterate over the rows available from the cursor, unpacking the
+# resulting sequences to yield their elements (name_last, age):
+cur.execute(SELECT)
+for (name_last, age) in cur:
+ print '%s is %d years old.' % (name_last, age)
+
+# 2. Equivalently:
+cur.execute(SELECT)
+for row in cur:
+ print '%s is %d years old.' % (row[0], row[1])
Modified: python/trunk/Doc/lib/sqlite3/execsql_printall_1.py
==============================================================================
--- python/trunk/Doc/lib/sqlite3/execsql_printall_1.py (original)
+++ python/trunk/Doc/lib/sqlite3/execsql_printall_1.py Wed May 17 01:24:08 2006
@@ -1,13 +1,13 @@
-import sqlite3
-
-# Create a connection to the database file "mydb":
-con = sqlite3.connect("mydb")
-
-# Get a Cursor object that operates in the context of Connection con:
-cur = con.cursor()
-
-# Execute the SELECT statement:
-cur.execute("select * from people order by age")
-
-# Retrieve all rows as a sequence and print that sequence:
-print cur.fetchall()
+import sqlite3
+
+# Create a connection to the database file "mydb":
+con = sqlite3.connect("mydb")
+
+# Get a Cursor object that operates in the context of Connection con:
+cur = con.cursor()
+
+# Execute the SELECT statement:
+cur.execute("select * from people order by age")
+
+# Retrieve all rows as a sequence and print that sequence:
+print cur.fetchall()
Modified: python/trunk/Doc/lib/sqlite3/execute_1.py
==============================================================================
--- python/trunk/Doc/lib/sqlite3/execute_1.py (original)
+++ python/trunk/Doc/lib/sqlite3/execute_1.py Wed May 17 01:24:08 2006
@@ -1,11 +1,11 @@
-import sqlite3
-
-con = sqlite3.connect("mydb")
-
-cur = con.cursor()
-
-who = "Yeltsin"
-age = 72
-
-cur.execute("select name_last, age from people where name_last=? and age=?", (who, age))
-print cur.fetchone()
+import sqlite3
+
+con = sqlite3.connect("mydb")
+
+cur = con.cursor()
+
+who = "Yeltsin"
+age = 72
+
+cur.execute("select name_last, age from people where name_last=? and age=?", (who, age))
+print cur.fetchone()
Modified: python/trunk/Doc/lib/sqlite3/execute_2.py
==============================================================================
--- python/trunk/Doc/lib/sqlite3/execute_2.py (original)
+++ python/trunk/Doc/lib/sqlite3/execute_2.py Wed May 17 01:24:08 2006
@@ -1,12 +1,12 @@
-import sqlite3
-
-con = sqlite3.connect("mydb")
-
-cur = con.cursor()
-
-who = "Yeltsin"
-age = 72
-
-cur.execute("select name_last, age from people where name_last=:who and age=:age",
- {"who": who, "age": age})
-print cur.fetchone()
+import sqlite3
+
+con = sqlite3.connect("mydb")
+
+cur = con.cursor()
+
+who = "Yeltsin"
+age = 72
+
+cur.execute("select name_last, age from people where name_last=:who and age=:age",
+ {"who": who, "age": age})
+print cur.fetchone()
Modified: python/trunk/Doc/lib/sqlite3/execute_3.py
==============================================================================
--- python/trunk/Doc/lib/sqlite3/execute_3.py (original)
+++ python/trunk/Doc/lib/sqlite3/execute_3.py Wed May 17 01:24:08 2006
@@ -1,12 +1,12 @@
-import sqlite3
-
-con = sqlite3.connect("mydb")
-
-cur = con.cursor()
-
-who = "Yeltsin"
-age = 72
-
-cur.execute("select name_last, age from people where name_last=:who and age=:age",
- locals())
-print cur.fetchone()
+import sqlite3
+
+con = sqlite3.connect("mydb")
+
+cur = con.cursor()
+
+who = "Yeltsin"
+age = 72
+
+cur.execute("select name_last, age from people where name_last=:who and age=:age",
+ locals())
+print cur.fetchone()
Modified: python/trunk/Doc/lib/sqlite3/executemany_1.py
==============================================================================
--- python/trunk/Doc/lib/sqlite3/executemany_1.py (original)
+++ python/trunk/Doc/lib/sqlite3/executemany_1.py Wed May 17 01:24:08 2006
@@ -1,24 +1,24 @@
-import sqlite3
-
-class IterChars:
- def __init__(self):
- self.count = ord('a')
-
- def __iter__(self):
- return self
-
- def next(self):
- if self.count > ord('z'):
- raise StopIteration
- self.count += 1
- return (chr(self.count - 1),) # this is a 1-tuple
-
-con = sqlite3.connect(":memory:")
-cur = con.cursor()
-cur.execute("create table characters(c)")
-
-theIter = IterChars()
-cur.executemany("insert into characters(c) values (?)", theIter)
-
-cur.execute("select c from characters")
-print cur.fetchall()
+import sqlite3
+
+class IterChars:
+ def __init__(self):
+ self.count = ord('a')
+
+ def __iter__(self):
+ return self
+
+ def next(self):
+ if self.count > ord('z'):
+ raise StopIteration
+ self.count += 1
+ return (chr(self.count - 1),) # this is a 1-tuple
+
+con = sqlite3.connect(":memory:")
+cur = con.cursor()
+cur.execute("create table characters(c)")
+
+theIter = IterChars()
+cur.executemany("insert into characters(c) values (?)", theIter)
+
+cur.execute("select c from characters")
+print cur.fetchall()
Modified: python/trunk/Doc/lib/sqlite3/executemany_2.py
==============================================================================
--- python/trunk/Doc/lib/sqlite3/executemany_2.py (original)
+++ python/trunk/Doc/lib/sqlite3/executemany_2.py Wed May 17 01:24:08 2006
@@ -1,15 +1,15 @@
-import sqlite3
-
-def char_generator():
- import string
- for c in string.letters[:26]:
- yield (c,)
-
-con = sqlite3.connect(":memory:")
-cur = con.cursor()
-cur.execute("create table characters(c)")
-
-cur.executemany("insert into characters(c) values (?)", char_generator())
-
-cur.execute("select c from characters")
-print cur.fetchall()
+import sqlite3
+
+def char_generator():
+ import string
+ for c in string.letters[:26]:
+ yield (c,)
+
+con = sqlite3.connect(":memory:")
+cur = con.cursor()
+cur.execute("create table characters(c)")
+
+cur.executemany("insert into characters(c) values (?)", char_generator())
+
+cur.execute("select c from characters")
+print cur.fetchall()
Modified: python/trunk/Doc/lib/sqlite3/executescript.py
==============================================================================
--- python/trunk/Doc/lib/sqlite3/executescript.py (original)
+++ python/trunk/Doc/lib/sqlite3/executescript.py Wed May 17 01:24:08 2006
@@ -1,24 +1,24 @@
-import sqlite3
-
-con = sqlite3.connect(":memory:")
-cur = con.cursor()
-cur.executescript("""
- create table person(
- firstname,
- lastname,
- age
- );
-
- create table book(
- title,
- author,
- published
- );
-
- insert into book(title, author, published)
- values (
- 'Dirk Gently''s Holistic Detective Agency
- 'Douglas Adams',
- 1987
- );
- """)
+import sqlite3
+
+con = sqlite3.connect(":memory:")
+cur = con.cursor()
+cur.executescript("""
+ create table person(
+ firstname,
+ lastname,
+ age
+ );
+
+ create table book(
+ title,
+ author,
+ published
+ );
+
+ insert into book(title, author, published)
+ values (
+ 'Dirk Gently''s Holistic Detective Agency
+ 'Douglas Adams',
+ 1987
+ );
+ """)
Modified: python/trunk/Doc/lib/sqlite3/insert_more_people.py
==============================================================================
--- python/trunk/Doc/lib/sqlite3/insert_more_people.py (original)
+++ python/trunk/Doc/lib/sqlite3/insert_more_people.py Wed May 17 01:24:08 2006
@@ -1,16 +1,16 @@
-import sqlite3
-
-con = sqlite3.connect("mydb")
-
-cur = con.cursor()
-
-newPeople = (
- ('Lebed' , 53),
- ('Zhirinovsky' , 57),
- )
-
-for person in newPeople:
- cur.execute("insert into people (name_last, age) values (?, ?)", person)
-
-# The changes will not be saved unless the transaction is committed explicitly:
-con.commit()
+import sqlite3
+
+con = sqlite3.connect("mydb")
+
+cur = con.cursor()
+
+newPeople = (
+ ('Lebed' , 53),
+ ('Zhirinovsky' , 57),
+ )
+
+for person in newPeople:
+ cur.execute("insert into people (name_last, age) values (?, ?)", person)
+
+# The changes will not be saved unless the transaction is committed explicitly:
+con.commit()
Modified: python/trunk/Doc/lib/sqlite3/md5func.py
==============================================================================
--- python/trunk/Doc/lib/sqlite3/md5func.py (original)
+++ python/trunk/Doc/lib/sqlite3/md5func.py Wed May 17 01:24:08 2006
@@ -1,11 +1,11 @@
-import sqlite3
-import md5
-
-def md5sum(t):
- return md5.md5(t).hexdigest()
-
-con = sqlite3.connect(":memory:")
-con.create_function("md5", 1, md5sum)
-cur = con.cursor()
-cur.execute("select md5(?)", ("foo",))
-print cur.fetchone()[0]
+import sqlite3
+import md5
+
+def md5sum(t):
+ return md5.md5(t).hexdigest()
+
+con = sqlite3.connect(":memory:")
+con.create_function("md5", 1, md5sum)
+cur = con.cursor()
+cur.execute("select md5(?)", ("foo",))
+print cur.fetchone()[0]
Modified: python/trunk/Doc/lib/sqlite3/mysumaggr.py
==============================================================================
--- python/trunk/Doc/lib/sqlite3/mysumaggr.py (original)
+++ python/trunk/Doc/lib/sqlite3/mysumaggr.py Wed May 17 01:24:08 2006
@@ -1,20 +1,20 @@
-import sqlite3
-
-class MySum:
- def __init__(self):
- self.count = 0
-
- def step(self, value):
- self.count += value
-
- def finalize(self):
- return self.count
-
-con = sqlite3.connect(":memory:")
-con.create_aggregate("mysum", 1, MySum)
-cur = con.cursor()
-cur.execute("create table test(i)")
-cur.execute("insert into test(i) values (1)")
-cur.execute("insert into test(i) values (2)")
-cur.execute("select mysum(i) from test")
-print cur.fetchone()[0]
+import sqlite3
+
+class MySum:
+ def __init__(self):
+ self.count = 0
+
+ def step(self, value):
+ self.count += value
+
+ def finalize(self):
+ return self.count
+
+con = sqlite3.connect(":memory:")
+con.create_aggregate("mysum", 1, MySum)
+cur = con.cursor()
+cur.execute("create table test(i)")
+cur.execute("insert into test(i) values (1)")
+cur.execute("insert into test(i) values (2)")
+cur.execute("select mysum(i) from test")
+print cur.fetchone()[0]
Modified: python/trunk/Doc/lib/sqlite3/parse_colnames.py
==============================================================================
--- python/trunk/Doc/lib/sqlite3/parse_colnames.py (original)
+++ python/trunk/Doc/lib/sqlite3/parse_colnames.py Wed May 17 01:24:08 2006
@@ -1,8 +1,8 @@
-import sqlite3
-import datetime
-
-con = sqlite3.connect(":memory:", detect_types=sqlite3.PARSE_COLNAMES)
-cur = con.cursor()
-cur.execute('select ? as "x [timestamp]"', (datetime.datetime.now(),))
-dt = cur.fetchone()[0]
-print dt, type(dt)
+import sqlite3
+import datetime
+
+con = sqlite3.connect(":memory:", detect_types=sqlite3.PARSE_COLNAMES)
+cur = con.cursor()
+cur.execute('select ? as "x [timestamp]"', (datetime.datetime.now(),))
+dt = cur.fetchone()[0]
+print dt, type(dt)
Modified: python/trunk/Doc/lib/sqlite3/pysqlite_datetime.py
==============================================================================
--- python/trunk/Doc/lib/sqlite3/pysqlite_datetime.py (original)
+++ python/trunk/Doc/lib/sqlite3/pysqlite_datetime.py Wed May 17 01:24:08 2006
@@ -1,20 +1,20 @@
-import sqlite3
-import datetime
-
-con = sqlite3.connect(":memory:", detect_types=sqlite3.PARSE_DECLTYPES|sqlite3.PARSE_COLNAMES)
-cur = con.cursor()
-cur.execute("create table test(d date, ts timestamp)")
-
-today = datetime.date.today()
-now = datetime.datetime.now()
-
-cur.execute("insert into test(d, ts) values (?, ?)", (today, now))
-cur.execute("select d, ts from test")
-row = cur.fetchone()
-print today, "=>", row[0], type(row[0])
-print now, "=>", row[1], type(row[1])
-
-cur.execute('select current_date as "d [date]", current_timestamp as "ts [timestamp]"')
-row = cur.fetchone()
-print "current_date", row[0], type(row[0])
-print "current_timestamp", row[1], type(row[1])
+import sqlite3
+import datetime
+
+con = sqlite3.connect(":memory:", detect_types=sqlite3.PARSE_DECLTYPES|sqlite3.PARSE_COLNAMES)
+cur = con.cursor()
+cur.execute("create table test(d date, ts timestamp)")
+
+today = datetime.date.today()
+now = datetime.datetime.now()
+
+cur.execute("insert into test(d, ts) values (?, ?)", (today, now))
+cur.execute("select d, ts from test")
+row = cur.fetchone()
+print today, "=>", row[0], type(row[0])
+print now, "=>", row[1], type(row[1])
+
+cur.execute('select current_date as "d [date]", current_timestamp as "ts [timestamp]"')
+row = cur.fetchone()
+print "current_date", row[0], type(row[0])
+print "current_timestamp", row[1], type(row[1])
Modified: python/trunk/Doc/lib/sqlite3/row_factory.py
==============================================================================
--- python/trunk/Doc/lib/sqlite3/row_factory.py (original)
+++ python/trunk/Doc/lib/sqlite3/row_factory.py Wed May 17 01:24:08 2006
@@ -1,13 +1,13 @@
-import sqlite3
-
-def dict_factory(cursor, row):
- d = {}
- for idx, col in enumerate(cursor.description):
- d[col[0]] = row[idx]
- return d
-
-con = sqlite3.connect(":memory:")
-con.row_factory = dict_factory
-cur = con.cursor()
-cur.execute("select 1 as a")
-print cur.fetchone()["a"]
+import sqlite3
+
+def dict_factory(cursor, row):
+ d = {}
+ for idx, col in enumerate(cursor.description):
+ d[col[0]] = row[idx]
+ return d
+
+con = sqlite3.connect(":memory:")
+con.row_factory = dict_factory
+cur = con.cursor()
+cur.execute("select 1 as a")
+print cur.fetchone()["a"]
Modified: python/trunk/Doc/lib/sqlite3/shortcut_methods.py
==============================================================================
--- python/trunk/Doc/lib/sqlite3/shortcut_methods.py (original)
+++ python/trunk/Doc/lib/sqlite3/shortcut_methods.py Wed May 17 01:24:08 2006
@@ -1,21 +1,21 @@
-import sqlite3
-
-persons = [
- ("Hugo", "Boss"),
- ("Calvin", "Klein")
- ]
-
-con = sqlite3.connect(":memory:")
-
-# Create the table
-con.execute("create table person(firstname, lastname)")
-
-# Fill the table
-con.executemany("insert into person(firstname, lastname) values (?, ?)", persons)
-
-# Print the table contents
-for row in con.execute("select firstname, lastname from person"):
- print row
-
-# Using a dummy WHERE clause to not let SQLite take the shortcut table deletes.
-print "I just deleted", con.execute("delete from person where 1=1").rowcount, "rows"
+import sqlite3
+
+persons = [
+ ("Hugo", "Boss"),
+ ("Calvin", "Klein")
+ ]
+
+con = sqlite3.connect(":memory:")
+
+# Create the table
+con.execute("create table person(firstname, lastname)")
+
+# Fill the table
+con.executemany("insert into person(firstname, lastname) values (?, ?)", persons)
+
+# Print the table contents
+for row in con.execute("select firstname, lastname from person"):
+ print row
+
+# Using a dummy WHERE clause to not let SQLite take the shortcut table deletes.
+print "I just deleted", con.execute("delete from person where 1=1").rowcount, "rows"
Modified: python/trunk/Doc/lib/sqlite3/simple_tableprinter.py
==============================================================================
--- python/trunk/Doc/lib/sqlite3/simple_tableprinter.py (original)
+++ python/trunk/Doc/lib/sqlite3/simple_tableprinter.py Wed May 17 01:24:08 2006
@@ -1,26 +1,26 @@
-import sqlite3
-
-FIELD_MAX_WIDTH = 20
-TABLE_NAME = 'people'
-SELECT = 'select * from %s order by age, name_last' % TABLE_NAME
-
-con = sqlite3.connect("mydb")
-
-cur = con.cursor()
-cur.execute(SELECT)
-
-# Print a header.
-for fieldDesc in cur.description:
- print fieldDesc[0].ljust(FIELD_MAX_WIDTH) ,
-print # Finish the header with a newline.
-print '-' * 78
-
-# For each row, print the value of each field left-justified within
-# the maximum possible width of that field.
-fieldIndices = range(len(cur.description))
-for row in cur:
- for fieldIndex in fieldIndices:
- fieldValue = str(row[fieldIndex])
- print fieldValue.ljust(FIELD_MAX_WIDTH) ,
-
- print # Finish the row with a newline.
+import sqlite3
+
+FIELD_MAX_WIDTH = 20
+TABLE_NAME = 'people'
+SELECT = 'select * from %s order by age, name_last' % TABLE_NAME
+
+con = sqlite3.connect("mydb")
+
+cur = con.cursor()
+cur.execute(SELECT)
+
+# Print a header.
+for fieldDesc in cur.description:
+ print fieldDesc[0].ljust(FIELD_MAX_WIDTH) ,
+print # Finish the header with a newline.
+print '-' * 78
+
+# For each row, print the value of each field left-justified within
+# the maximum possible width of that field.
+fieldIndices = range(len(cur.description))
+for row in cur:
+ for fieldIndex in fieldIndices:
+ fieldValue = str(row[fieldIndex])
+ print fieldValue.ljust(FIELD_MAX_WIDTH) ,
+
+ print # Finish the row with a newline.
Modified: python/trunk/Doc/lib/sqlite3/text_factory.py
==============================================================================
--- python/trunk/Doc/lib/sqlite3/text_factory.py (original)
+++ python/trunk/Doc/lib/sqlite3/text_factory.py Wed May 17 01:24:08 2006
@@ -1,42 +1,42 @@
-import sqlite3
-
-con = sqlite3.connect(":memory:")
-cur = con.cursor()
-
-# Create the table
-con.execute("create table person(lastname, firstname)")
-
-AUSTRIA = u"\xd6sterreich"
-
-# by default, rows are returned as Unicode
-cur.execute("select ?", (AUSTRIA,))
-row = cur.fetchone()
-assert row[0] == AUSTRIA
-
-# but we can make pysqlite always return bytestrings ...
-con.text_factory = str
-cur.execute("select ?", (AUSTRIA,))
-row = cur.fetchone()
-assert type(row[0]) == str
-# the bytestrings will be encoded in UTF-8, unless you stored garbage in the
-# database ...
-assert row[0] == AUSTRIA.encode("utf-8")
-
-# we can also implement a custom text_factory ...
-# here we implement one that will ignore Unicode characters that cannot be
-# decoded from UTF-8
-con.text_factory = lambda x: unicode(x, "utf-8", "ignore")
-cur.execute("select ?", ("this is latin1 and would normally create errors" + u"\xe4\xf6\xfc".encode("latin1"),))
-row = cur.fetchone()
-assert type(row[0]) == unicode
-
-# pysqlite offers a builtin optimized text_factory that will return bytestring
-# objects, if the data is in ASCII only, and otherwise return unicode objects
-con.text_factory = sqlite3.OptimizedUnicode
-cur.execute("select ?", (AUSTRIA,))
-row = cur.fetchone()
-assert type(row[0]) == unicode
-
-cur.execute("select ?", ("Germany",))
-row = cur.fetchone()
-assert type(row[0]) == str
+import sqlite3
+
+con = sqlite3.connect(":memory:")
+cur = con.cursor()
+
+# Create the table
+con.execute("create table person(lastname, firstname)")
+
+AUSTRIA = u"\xd6sterreich"
+
+# by default, rows are returned as Unicode
+cur.execute("select ?", (AUSTRIA,))
+row = cur.fetchone()
+assert row[0] == AUSTRIA
+
+# but we can make pysqlite always return bytestrings ...
+con.text_factory = str
+cur.execute("select ?", (AUSTRIA,))
+row = cur.fetchone()
+assert type(row[0]) == str
+# the bytestrings will be encoded in UTF-8, unless you stored garbage in the
+# database ...
+assert row[0] == AUSTRIA.encode("utf-8")
+
+# we can also implement a custom text_factory ...
+# here we implement one that will ignore Unicode characters that cannot be
+# decoded from UTF-8
+con.text_factory = lambda x: unicode(x, "utf-8", "ignore")
+cur.execute("select ?", ("this is latin1 and would normally create errors" + u"\xe4\xf6\xfc".encode("latin1"),))
+row = cur.fetchone()
+assert type(row[0]) == unicode
+
+# pysqlite offers a builtin optimized text_factory that will return bytestring
+# objects, if the data is in ASCII only, and otherwise return unicode objects
+con.text_factory = sqlite3.OptimizedUnicode
+cur.execute("select ?", (AUSTRIA,))
+row = cur.fetchone()
+assert type(row[0]) == unicode
+
+cur.execute("select ?", ("Germany",))
+row = cur.fetchone()
+assert type(row[0]) == str
Modified: python/trunk/Lib/test/test_bigmem.py
==============================================================================
--- python/trunk/Lib/test/test_bigmem.py (original)
+++ python/trunk/Lib/test/test_bigmem.py Wed May 17 01:24:08 2006
@@ -1,964 +1,964 @@
-from test import test_support
-from test.test_support import bigmemtest, _1G, _2G
-
-import unittest
-import operator
-import string
-import sys
-
-# Bigmem testing houserules:
-#
-# - Try not to allocate too many large objects. It's okay to rely on
-# refcounting semantics, but don't forget that 's = create_largestring()'
-# doesn't release the old 's' (if it exists) until well after its new
-# value has been created. Use 'del s' before the create_largestring call.
-#
-# - Do *not* compare large objects using assertEquals or similar. It's a
-# lengty operation and the errormessage will be utterly useless due to
-# its size. To make sure whether a result has the right contents, better
-# to use the strip or count methods, or compare meaningful slices.
-#
-# - Don't forget to test for large indices, offsets and results and such,
-# in addition to large sizes.
-#
-# - When repeating an object (say, a substring, or a small list) to create
-# a large object, make the subobject of a length that is not a power of
-# 2. That way, int-wrapping problems are more easily detected.
-#
-# - While the bigmemtest decorator speaks of 'minsize', all tests will
-# actually be called with a much smaller number too, in the normal
-# test run (5Kb currently.) This is so the tests themselves get frequent
-# testing Consequently, always make all large allocations based on the
-# passed-in 'size', and don't rely on the size being very large. Also,
-# memuse-per-size should remain sane (less than a few thousand); if your
-# test uses more, adjust 'size' upward, instead.
-
-class StrTest(unittest.TestCase):
- @bigmemtest(minsize=_2G, memuse=2)
- def test_capitalize(self, size):
- SUBSTR = ' abc def ghi'
- s = '-' * size + SUBSTR
- caps = s.capitalize()
- self.assertEquals(caps[-len(SUBSTR):],
- SUBSTR.capitalize())
- self.assertEquals(caps.lstrip('-'), SUBSTR)
-
- @bigmemtest(minsize=_2G + 10, memuse=1)
- def test_center(self, size):
- SUBSTR = ' abc def ghi'
- s = SUBSTR.center(size)
- self.assertEquals(len(s), size)
- lpadsize = rpadsize = (len(s) - len(SUBSTR)) // 2
- if len(s) % 2:
- lpadsize += 1
- self.assertEquals(s[lpadsize:-rpadsize], SUBSTR)
- self.assertEquals(s.strip(), SUBSTR.strip())
-
- @bigmemtest(minsize=_2G, memuse=2)
- def test_count(self, size):
- SUBSTR = ' abc def ghi'
- s = '.' * size + SUBSTR
- self.assertEquals(s.count('.'), size)
- s += '.'
- self.assertEquals(s.count('.'), size + 1)
- self.assertEquals(s.count(' '), 3)
- self.assertEquals(s.count('i'), 1)
- self.assertEquals(s.count('j'), 0)
-
- @bigmemtest(minsize=0, memuse=1)
- def test_decode(self, size):
- pass
-
- @bigmemtest(minsize=0, memuse=1)
- def test_encode(self, size):
- pass
-
- @bigmemtest(minsize=_2G, memuse=2)
- def test_endswith(self, size):
- SUBSTR = ' abc def ghi'
- s = '-' * size + SUBSTR
- self.failUnless(s.endswith(SUBSTR))
- self.failUnless(s.endswith(s))
- s2 = '...' + s
- self.failUnless(s2.endswith(s))
- self.failIf(s.endswith('a' + SUBSTR))
- self.failIf(SUBSTR.endswith(s))
-
- @bigmemtest(minsize=_2G + 10, memuse=2)
- def test_expandtabs(self, size):
- s = '-' * size
- tabsize = 8
- self.assertEquals(s.expandtabs(), s)
- del s
- slen, remainder = divmod(size, tabsize)
- s = ' \t' * slen
- s = s.expandtabs(tabsize)
- self.assertEquals(len(s), size - remainder)
- self.assertEquals(len(s.strip(' ')), 0)
-
- @bigmemtest(minsize=_2G, memuse=2)
- def test_find(self, size):
- SUBSTR = ' abc def ghi'
- sublen = len(SUBSTR)
- s = ''.join([SUBSTR, '-' * size, SUBSTR])
- self.assertEquals(s.find(' '), 0)
- self.assertEquals(s.find(SUBSTR), 0)
- self.assertEquals(s.find(' ', sublen), sublen + size)
- self.assertEquals(s.find(SUBSTR, len(SUBSTR)), sublen + size)
- self.assertEquals(s.find('i'), SUBSTR.find('i'))
- self.assertEquals(s.find('i', sublen),
- sublen + size + SUBSTR.find('i'))
- self.assertEquals(s.find('i', size),
- sublen + size + SUBSTR.find('i'))
- self.assertEquals(s.find('j'), -1)
-
- @bigmemtest(minsize=_2G, memuse=2)
- def test_index(self, size):
- SUBSTR = ' abc def ghi'
- sublen = len(SUBSTR)
- s = ''.join([SUBSTR, '-' * size, SUBSTR])
- self.assertEquals(s.index(' '), 0)
- self.assertEquals(s.index(SUBSTR), 0)
- self.assertEquals(s.index(' ', sublen), sublen + size)
- self.assertEquals(s.index(SUBSTR, sublen), sublen + size)
- self.assertEquals(s.index('i'), SUBSTR.index('i'))
- self.assertEquals(s.index('i', sublen),
- sublen + size + SUBSTR.index('i'))
- self.assertEquals(s.index('i', size),
- sublen + size + SUBSTR.index('i'))
- self.assertRaises(ValueError, s.index, 'j')
-
- @bigmemtest(minsize=_2G, memuse=2)
- def test_isalnum(self, size):
- SUBSTR = '123456'
- s = 'a' * size + SUBSTR
- self.failUnless(s.isalnum())
- s += '.'
- self.failIf(s.isalnum())
-
- @bigmemtest(minsize=_2G, memuse=2)
- def test_isalpha(self, size):
- SUBSTR = 'zzzzzzz'
- s = 'a' * size + SUBSTR
- self.failUnless(s.isalpha())
- s += '.'
- self.failIf(s.isalpha())
-
- @bigmemtest(minsize=_2G, memuse=2)
- def test_isdigit(self, size):
- SUBSTR = '123456'
- s = '9' * size + SUBSTR
- self.failUnless(s.isdigit())
- s += 'z'
- self.failIf(s.isdigit())
-
- @bigmemtest(minsize=_2G, memuse=2)
- def test_islower(self, size):
- chars = ''.join([ chr(c) for c in range(255) if not chr(c).isupper() ])
- repeats = size // len(chars) + 2
- s = chars * repeats
- self.failUnless(s.islower())
- s += 'A'
- self.failIf(s.islower())
-
- @bigmemtest(minsize=_2G, memuse=2)
- def test_isspace(self, size):
- whitespace = ' \f\n\r\t\v'
- repeats = size // len(whitespace) + 2
- s = whitespace * repeats
- self.failUnless(s.isspace())
- s += 'j'
- self.failIf(s.isspace())
-
- @bigmemtest(minsize=_2G, memuse=2)
- def test_istitle(self, size):
- SUBSTR = '123456'
- s = ''.join(['A', 'a' * size, SUBSTR])
- self.failUnless(s.istitle())
- s += 'A'
- self.failUnless(s.istitle())
- s += 'aA'
- self.failIf(s.istitle())
-
- @bigmemtest(minsize=_2G, memuse=2)
- def test_isupper(self, size):
- chars = ''.join([ chr(c) for c in range(255) if not chr(c).islower() ])
- repeats = size // len(chars) + 2
- s = chars * repeats
- self.failUnless(s.isupper())
- s += 'a'
- self.failIf(s.isupper())
-
- @bigmemtest(minsize=_2G, memuse=2)
- def test_join(self, size):
- s = 'A' * size
- x = s.join(['aaaaa', 'bbbbb'])
- self.assertEquals(x.count('a'), 5)
- self.assertEquals(x.count('b'), 5)
- self.failUnless(x.startswith('aaaaaA'))
- self.failUnless(x.endswith('Abbbbb'))
-
- @bigmemtest(minsize=_2G + 10, memuse=1)
- def test_ljust(self, size):
- SUBSTR = ' abc def ghi'
- s = SUBSTR.ljust(size)
- self.failUnless(s.startswith(SUBSTR + ' '))
- self.assertEquals(len(s), size)
- self.assertEquals(s.strip(), SUBSTR.strip())
-
- @bigmemtest(minsize=_2G + 10, memuse=2)
- def test_lower(self, size):
- s = 'A' * size
- s = s.lower()
- self.assertEquals(len(s), size)
- self.assertEquals(s.count('a'), size)
-
- @bigmemtest(minsize=_2G + 10, memuse=1)
- def test_lstrip(self, size):
- SUBSTR = 'abc def ghi'
- s = SUBSTR.rjust(size)
- self.assertEquals(len(s), size)
- self.assertEquals(s.lstrip(), SUBSTR.lstrip())
- del s
- s = SUBSTR.ljust(size)
- self.assertEquals(len(s), size)
- stripped = s.lstrip()
- self.failUnless(stripped is s)
-
- @bigmemtest(minsize=_2G + 10, memuse=2)
- def test_replace(self, size):
- replacement = 'a'
- s = ' ' * size
- s = s.replace(' ', replacement)
- self.assertEquals(len(s), size)
- self.assertEquals(s.count(replacement), size)
- s = s.replace(replacement, ' ', size - 4)
- self.assertEquals(len(s), size)
- self.assertEquals(s.count(replacement), 4)
- self.assertEquals(s[-10:], ' aaaa')
-
- @bigmemtest(minsize=_2G, memuse=2)
- def test_rfind(self, size):
- SUBSTR = ' abc def ghi'
- sublen = len(SUBSTR)
- s = ''.join([SUBSTR, '-' * size, SUBSTR])
- self.assertEquals(s.rfind(' '), sublen + size + SUBSTR.rfind(' '))
- self.assertEquals(s.rfind(SUBSTR), sublen + size)
- self.assertEquals(s.rfind(' ', 0, size), SUBSTR.rfind(' '))
- self.assertEquals(s.rfind(SUBSTR, 0, sublen + size), 0)
- self.assertEquals(s.rfind('i'), sublen + size + SUBSTR.rfind('i'))
- self.assertEquals(s.rfind('i', 0, sublen), SUBSTR.rfind('i'))
- self.assertEquals(s.rfind('i', 0, sublen + size),
- SUBSTR.rfind('i'))
- self.assertEquals(s.rfind('j'), -1)
-
- @bigmemtest(minsize=_2G, memuse=2)
- def test_rindex(self, size):
- SUBSTR = ' abc def ghi'
- sublen = len(SUBSTR)
- s = ''.join([SUBSTR, '-' * size, SUBSTR])
- self.assertEquals(s.rindex(' '),
- sublen + size + SUBSTR.rindex(' '))
- self.assertEquals(s.rindex(SUBSTR), sublen + size)
- self.assertEquals(s.rindex(' ', 0, sublen + size - 1),
- SUBSTR.rindex(' '))
- self.assertEquals(s.rindex(SUBSTR, 0, sublen + size), 0)
- self.assertEquals(s.rindex('i'),
- sublen + size + SUBSTR.rindex('i'))
- self.assertEquals(s.rindex('i', 0, sublen), SUBSTR.rindex('i'))
- self.assertEquals(s.rindex('i', 0, sublen + size),
- SUBSTR.rindex('i'))
- self.assertRaises(ValueError, s.rindex, 'j')
-
- @bigmemtest(minsize=_2G + 10, memuse=1)
- def test_rjust(self, size):
- SUBSTR = ' abc def ghi'
- s = SUBSTR.ljust(size)
- self.failUnless(s.startswith(SUBSTR + ' '))
- self.assertEquals(len(s), size)
- self.assertEquals(s.strip(), SUBSTR.strip())
-
- @bigmemtest(minsize=_2G + 10, memuse=1)
- def test_rstrip(self, size):
- SUBSTR = ' abc def ghi'
- s = SUBSTR.ljust(size)
- self.assertEquals(len(s), size)
- self.assertEquals(s.rstrip(), SUBSTR.rstrip())
- del s
- s = SUBSTR.rjust(size)
- self.assertEquals(len(s), size)
- stripped = s.rstrip()
- self.failUnless(stripped is s)
-
- # The test takes about size bytes to build a string, and then about
- # sqrt(size) substrings of sqrt(size) in size and a list to
- # hold sqrt(size) items. It's close but just over 2x size.
- @bigmemtest(minsize=_2G, memuse=2.1)
- def test_split_small(self, size):
- # Crudely calculate an estimate so that the result of s.split won't
- # take up an inordinate amount of memory
- chunksize = int(size ** 0.5 + 2)
- SUBSTR = 'a' + ' ' * chunksize
- s = SUBSTR * chunksize
- l = s.split()
- self.assertEquals(len(l), chunksize)
- self.assertEquals(set(l), set(['a']))
- del l
- l = s.split('a')
- self.assertEquals(len(l), chunksize + 1)
- self.assertEquals(set(l), set(['', ' ' * chunksize]))
-
- # Allocates a string of twice size (and briefly two) and a list of
- # size. Because of internal affairs, the s.split() call produces a
- # list of size times the same one-character string, so we only
- # suffer for the list size. (Otherwise, it'd cost another 48 times
- # size in bytes!) Nevertheless, a list of size takes
- # 8*size bytes.
- @bigmemtest(minsize=_2G + 5, memuse=10)
- def test_split_large(self, size):
- s = ' a' * size + ' '
- l = s.split()
- self.assertEquals(len(l), size)
- self.assertEquals(set(l), set(['a']))
- del l
- l = s.split('a')
- self.assertEquals(len(l), size + 1)
- self.assertEquals(set(l), set([' ']))
-
- @bigmemtest(minsize=_2G, memuse=2.1)
- def test_splitlines(self, size):
- # Crudely calculate an estimate so that the result of s.split won't
- # take up an inordinate amount of memory
- chunksize = int(size ** 0.5 + 2) // 2
- SUBSTR = ' ' * chunksize + '\n' + ' ' * chunksize + '\r\n'
- s = SUBSTR * chunksize
- l = s.splitlines()
- self.assertEquals(len(l), chunksize * 2)
- self.assertEquals(set(l), set([' ' * chunksize]))
-
- @bigmemtest(minsize=_2G, memuse=2)
- def test_startswith(self, size):
- SUBSTR = ' abc def ghi'
- s = '-' * size + SUBSTR
- self.failUnless(s.startswith(s))
- self.failUnless(s.startswith('-' * size))
- self.failIf(s.startswith(SUBSTR))
-
- @bigmemtest(minsize=_2G, memuse=1)
- def test_strip(self, size):
- SUBSTR = ' abc def ghi '
- s = SUBSTR.rjust(size)
- self.assertEquals(len(s), size)
- self.assertEquals(s.strip(), SUBSTR.strip())
- del s
- s = SUBSTR.ljust(size)
- self.assertEquals(len(s), size)
- self.assertEquals(s.strip(), SUBSTR.strip())
-
- @bigmemtest(minsize=_2G, memuse=2)
- def test_swapcase(self, size):
- SUBSTR = "aBcDeFG12.'\xa9\x00"
- sublen = len(SUBSTR)
- repeats = size // sublen + 2
- s = SUBSTR * repeats
- s = s.swapcase()
- self.assertEquals(len(s), sublen * repeats)
- self.assertEquals(s[:sublen * 3], SUBSTR.swapcase() * 3)
- self.assertEquals(s[-sublen * 3:], SUBSTR.swapcase() * 3)
-
- @bigmemtest(minsize=_2G, memuse=2)
- def test_title(self, size):
- SUBSTR = 'SpaaHAaaAaham'
- s = SUBSTR * (size // len(SUBSTR) + 2)
- s = s.title()
- self.failUnless(s.startswith((SUBSTR * 3).title()))
- self.failUnless(s.endswith(SUBSTR.lower() * 3))
-
- @bigmemtest(minsize=_2G, memuse=2)
- def test_translate(self, size):
- trans = string.maketrans('.aZ', '-!$')
- SUBSTR = 'aZz.z.Aaz.'
- sublen = len(SUBSTR)
- repeats = size // sublen + 2
- s = SUBSTR * repeats
- s = s.translate(trans)
- self.assertEquals(len(s), repeats * sublen)
- self.assertEquals(s[:sublen], SUBSTR.translate(trans))
- self.assertEquals(s[-sublen:], SUBSTR.translate(trans))
- self.assertEquals(s.count('.'), 0)
- self.assertEquals(s.count('!'), repeats * 2)
- self.assertEquals(s.count('z'), repeats * 3)
-
- @bigmemtest(minsize=_2G + 5, memuse=2)
- def test_upper(self, size):
- s = 'a' * size
- s = s.upper()
- self.assertEquals(len(s), size)
- self.assertEquals(s.count('A'), size)
-
- @bigmemtest(minsize=_2G + 20, memuse=1)
- def test_zfill(self, size):
- SUBSTR = '-568324723598234'
- s = SUBSTR.zfill(size)
- self.failUnless(s.endswith('0' + SUBSTR[1:]))
- self.failUnless(s.startswith('-0'))
- self.assertEquals(len(s), size)
- self.assertEquals(s.count('0'), size - len(SUBSTR))
-
- @bigmemtest(minsize=_2G + 10, memuse=2)
- def test_format(self, size):
- s = '-' * size
- sf = '%s' % (s,)
- self.failUnless(s == sf)
- del sf
- sf = '..%s..' % (s,)
- self.assertEquals(len(sf), len(s) + 4)
- self.failUnless(sf.startswith('..-'))
- self.failUnless(sf.endswith('-..'))
- del s, sf
-
- size //= 2
- edge = '-' * size
- s = ''.join([edge, '%s', edge])
- del edge
- s = s % '...'
- self.assertEquals(len(s), size * 2 + 3)
- self.assertEquals(s.count('.'), 3)
- self.assertEquals(s.count('-'), size * 2)
-
- @bigmemtest(minsize=_2G + 10, memuse=2)
- def test_repr_small(self, size):
- s = '-' * size
- s = repr(s)
- self.assertEquals(len(s), size + 2)
- self.assertEquals(s[0], "'")
- self.assertEquals(s[-1], "'")
- self.assertEquals(s.count('-'), size)
- del s
- # repr() will create a string four times as large as this 'binary
- # string', but we don't want to allocate much more than twice
- # size in total. (We do extra testing in test_repr_large())
- size = size // 5 * 2
- s = '\x00' * size
- s = repr(s)
- self.assertEquals(len(s), size * 4 + 2)
- self.assertEquals(s[0], "'")
- self.assertEquals(s[-1], "'")
- self.assertEquals(s.count('\\'), size)
- self.assertEquals(s.count('0'), size * 2)
-
- @bigmemtest(minsize=_2G + 10, memuse=5)
- def test_repr_large(self, size):
- s = '\x00' * size
- s = repr(s)
- self.assertEquals(len(s), size * 4 + 2)
- self.assertEquals(s[0], "'")
- self.assertEquals(s[-1], "'")
- self.assertEquals(s.count('\\'), size)
- self.assertEquals(s.count('0'), size * 2)
-
- # This test is meaningful even with size < 2G, as long as the
- # doubled string is > 2G (but it tests more if both are > 2G :)
- @bigmemtest(minsize=_1G + 2, memuse=3)
- def test_concat(self, size):
- s = '.' * size
- self.assertEquals(len(s), size)
- s = s + s
- self.assertEquals(len(s), size * 2)
- self.assertEquals(s.count('.'), size * 2)
-
- # This test is meaningful even with size < 2G, as long as the
- # repeated string is > 2G (but it tests more if both are > 2G :)
- @bigmemtest(minsize=_1G + 2, memuse=3)
- def test_repeat(self, size):
- s = '.' * size
- self.assertEquals(len(s), size)
- s = s * 2
- self.assertEquals(len(s), size * 2)
- self.assertEquals(s.count('.'), size * 2)
-
- @bigmemtest(minsize=_2G + 20, memuse=1)
- def test_slice_and_getitem(self, size):
- SUBSTR = '0123456789'
- sublen = len(SUBSTR)
- s = SUBSTR * (size // sublen)
- stepsize = len(s) // 100
- stepsize = stepsize - (stepsize % sublen)
- for i in range(0, len(s) - stepsize, stepsize):
- self.assertEquals(s[i], SUBSTR[0])
- self.assertEquals(s[i:i + sublen], SUBSTR)
- self.assertEquals(s[i:i + sublen:2], SUBSTR[::2])
- if i > 0:
- self.assertEquals(s[i + sublen - 1:i - 1:-3],
- SUBSTR[sublen::-3])
- # Make sure we do some slicing and indexing near the end of the
- # string, too.
- self.assertEquals(s[len(s) - 1], SUBSTR[-1])
- self.assertEquals(s[-1], SUBSTR[-1])
- self.assertEquals(s[len(s) - 10], SUBSTR[0])
- self.assertEquals(s[-sublen], SUBSTR[0])
- self.assertEquals(s[len(s):], '')
- self.assertEquals(s[len(s) - 1:], SUBSTR[-1])
- self.assertEquals(s[-1:], SUBSTR[-1])
- self.assertEquals(s[len(s) - sublen:], SUBSTR)
- self.assertEquals(s[-sublen:], SUBSTR)
- self.assertEquals(len(s[:]), len(s))
- self.assertEquals(len(s[:len(s) - 5]), len(s) - 5)
- self.assertEquals(len(s[5:-5]), len(s) - 10)
-
- self.assertRaises(IndexError, operator.getitem, s, len(s))
- self.assertRaises(IndexError, operator.getitem, s, len(s) + 1)
- self.assertRaises(IndexError, operator.getitem, s, len(s) + 1<<31)
-
- @bigmemtest(minsize=_2G, memuse=2)
- def test_contains(self, size):
- SUBSTR = '0123456789'
- edge = '-' * (size // 2)
- s = ''.join([edge, SUBSTR, edge])
- del edge
- self.failUnless(SUBSTR in s)
- self.failIf(SUBSTR * 2 in s)
- self.failUnless('-' in s)
- self.failIf('a' in s)
- s += 'a'
- self.failUnless('a' in s)
-
- @bigmemtest(minsize=_2G + 10, memuse=2)
- def test_compare(self, size):
- s1 = '-' * size
- s2 = '-' * size
- self.failUnless(s1 == s2)
- del s2
- s2 = s1 + 'a'
- self.failIf(s1 == s2)
- del s2
- s2 = '.' * size
- self.failIf(s1 == s2)
-
- @bigmemtest(minsize=_2G + 10, memuse=1)
- def test_hash(self, size):
- # Not sure if we can do any meaningful tests here... Even if we
- # start relying on the exact algorithm used, the result will be
- # different depending on the size of the C 'long int'. Even this
- # test is dodgy (there's no *guarantee* that the two things should
- # have a different hash, even if they, in the current
- # implementation, almost always do.)
- s = '\x00' * size
- h1 = hash(s)
- del s
- s = '\x00' * (size + 1)
- self.failIf(h1 == hash(s))
-
-class TupleTest(unittest.TestCase):
-
- # Tuples have a small, fixed-sized head and an array of pointers to
- # data. Since we're testing 64-bit addressing, we can assume that the
- # pointers are 8 bytes, and that thus that the tuples take up 8 bytes
- # per size.
-
- # As a side-effect of testing long tuples, these tests happen to test
- # having more than 2<<31 references to any given object. Hence the
- # use of different types of objects as contents in different tests.
-
- @bigmemtest(minsize=_2G + 2, memuse=16)
- def test_compare(self, size):
- t1 = (u'',) * size
- t2 = (u'',) * size
- self.failUnless(t1 == t2)
- del t2
- t2 = (u'',) * (size + 1)
- self.failIf(t1 == t2)
- del t2
- t2 = (1,) * size
- self.failIf(t1 == t2)
-
- # Test concatenating into a single tuple of more than 2G in length,
- # and concatenating a tuple of more than 2G in length separately, so
- # the smaller test still gets run even if there isn't memory for the
- # larger test (but we still let the tester know the larger test is
- # skipped, in verbose mode.)
- def basic_concat_test(self, size):
- t = ((),) * size
- self.assertEquals(len(t), size)
- t = t + t
- self.assertEquals(len(t), size * 2)
-
- @bigmemtest(minsize=_2G // 2 + 2, memuse=24)
- def test_concat_small(self, size):
- return self.basic_concat_test(size)
-
- @bigmemtest(minsize=_2G + 2, memuse=24)
- def test_concat_large(self, size):
- return self.basic_concat_test(size)
-
- @bigmemtest(minsize=_2G // 5 + 10, memuse=8 * 5)
- def test_contains(self, size):
- t = (1, 2, 3, 4, 5) * size
- self.assertEquals(len(t), size * 5)
- self.failUnless(5 in t)
- self.failIf((1, 2, 3, 4, 5) in t)
- self.failIf(0 in t)
-
- @bigmemtest(minsize=_2G + 10, memuse=8)
- def test_hash(self, size):
- t1 = (0,) * size
- h1 = hash(t1)
- del t1
- t2 = (0,) * (size + 1)
- self.failIf(h1 == hash(t2))
-
- @bigmemtest(minsize=_2G + 10, memuse=8)
- def test_index_and_slice(self, size):
- t = (None,) * size
- self.assertEquals(len(t), size)
- self.assertEquals(t[-1], None)
- self.assertEquals(t[5], None)
- self.assertEquals(t[size - 1], None)
- self.assertRaises(IndexError, operator.getitem, t, size)
- self.assertEquals(t[:5], (None,) * 5)
- self.assertEquals(t[-5:], (None,) * 5)
- self.assertEquals(t[20:25], (None,) * 5)
- self.assertEquals(t[-25:-20], (None,) * 5)
- self.assertEquals(t[size - 5:], (None,) * 5)
- self.assertEquals(t[size - 5:size], (None,) * 5)
- self.assertEquals(t[size - 6:size - 2], (None,) * 4)
- self.assertEquals(t[size:size], ())
- self.assertEquals(t[size:size+5], ())
-
- # Like test_concat, split in two.
- def basic_test_repeat(self, size):
- t = ('',) * size
- self.assertEquals(len(t), size)
- t = t * 2
- self.assertEquals(len(t), size * 2)
-
- @bigmemtest(minsize=_2G // 2 + 2, memuse=24)
- def test_repeat_small(self, size):
- return self.basic_test_repeat(size)
-
- @bigmemtest(minsize=_2G + 2, memuse=24)
- def test_repeat_large(self, size):
- return self.basic_test_repeat(size)
-
- # Like test_concat, split in two.
- def basic_test_repr(self, size):
- t = (0,) * size
- s = repr(t)
- # The repr of a tuple of 0's is exactly three times the tuple length.
- self.assertEquals(len(s), size * 3)
- self.assertEquals(s[:5], '(0, 0')
- self.assertEquals(s[-5:], '0, 0)')
- self.assertEquals(s.count('0'), size)
-
- @bigmemtest(minsize=_2G // 3 + 2, memuse=8 + 3)
- def test_repr_small(self, size):
- return self.basic_test_repr(size)
-
- @bigmemtest(minsize=_2G + 2, memuse=8 + 3)
- def test_repr_large(self, size):
- return self.basic_test_repr(size)
-
-class ListTest(unittest.TestCase):
-
- # Like tuples, lists have a small, fixed-sized head and an array of
- # pointers to data, so 8 bytes per size. Also like tuples, we make the
- # lists hold references to various objects to test their refcount
- # limits.
-
- @bigmemtest(minsize=_2G + 2, memuse=16)
- def test_compare(self, size):
- l1 = [u''] * size
- l2 = [u''] * size
- self.failUnless(l1 == l2)
- del l2
- l2 = [u''] * (size + 1)
- self.failIf(l1 == l2)
- del l2
- l2 = [2] * size
- self.failIf(l1 == l2)
-
- # Test concatenating into a single list of more than 2G in length,
- # and concatenating a list of more than 2G in length separately, so
- # the smaller test still gets run even if there isn't memory for the
- # larger test (but we still let the tester know the larger test is
- # skipped, in verbose mode.)
- def basic_test_concat(self, size):
- l = [[]] * size
- self.assertEquals(len(l), size)
- l = l + l
- self.assertEquals(len(l), size * 2)
-
- @bigmemtest(minsize=_2G // 2 + 2, memuse=24)
- def test_concat_small(self, size):
- return self.basic_test_concat(size)
-
- @bigmemtest(minsize=_2G + 2, memuse=24)
- def test_concat_large(self, size):
- return self.basic_test_concat(size)
-
- def basic_test_inplace_concat(self, size):
- l = [sys.stdout] * size
- l += l
- self.assertEquals(len(l), size * 2)
- self.failUnless(l[0] is l[-1])
- self.failUnless(l[size - 1] is l[size + 1])
-
- @bigmemtest(minsize=_2G // 2 + 2, memuse=24)
- def test_inplace_concat_small(self, size):
- return self.basic_test_inplace_concat(size)
-
- @bigmemtest(minsize=_2G + 2, memuse=24)
- def test_inplace_concat_large(self, size):
- return self.basic_test_inplace_concat(size)
-
- @bigmemtest(minsize=_2G // 5 + 10, memuse=8 * 5)
- def test_contains(self, size):
- l = [1, 2, 3, 4, 5] * size
- self.assertEquals(len(l), size * 5)
- self.failUnless(5 in l)
- self.failIf([1, 2, 3, 4, 5] in l)
- self.failIf(0 in l)
-
- @bigmemtest(minsize=_2G + 10, memuse=8)
- def test_hash(self, size):
- l = [0] * size
- self.failUnlessRaises(TypeError, hash, l)
-
- @bigmemtest(minsize=_2G + 10, memuse=8)
- def test_index_and_slice(self, size):
- l = [None] * size
- self.assertEquals(len(l), size)
- self.assertEquals(l[-1], None)
- self.assertEquals(l[5], None)
- self.assertEquals(l[size - 1], None)
- self.assertRaises(IndexError, operator.getitem, l, size)
- self.assertEquals(l[:5], [None] * 5)
- self.assertEquals(l[-5:], [None] * 5)
- self.assertEquals(l[20:25], [None] * 5)
- self.assertEquals(l[-25:-20], [None] * 5)
- self.assertEquals(l[size - 5:], [None] * 5)
- self.assertEquals(l[size - 5:size], [None] * 5)
- self.assertEquals(l[size - 6:size - 2], [None] * 4)
- self.assertEquals(l[size:size], [])
- self.assertEquals(l[size:size+5], [])
-
- l[size - 2] = 5
- self.assertEquals(len(l), size)
- self.assertEquals(l[-3:], [None, 5, None])
- self.assertEquals(l.count(5), 1)
- self.assertRaises(IndexError, operator.setitem, l, size, 6)
- self.assertEquals(len(l), size)
-
- l[size - 7:] = [1, 2, 3, 4, 5]
- size -= 2
- self.assertEquals(len(l), size)
- self.assertEquals(l[-7:], [None, None, 1, 2, 3, 4, 5])
-
- l[:7] = [1, 2, 3, 4, 5]
- size -= 2
- self.assertEquals(len(l), size)
- self.assertEquals(l[:7], [1, 2, 3, 4, 5, None, None])
-
- del l[size - 1]
- size -= 1
- self.assertEquals(len(l), size)
- self.assertEquals(l[-1], 4)
-
- del l[-2:]
- size -= 2
- self.assertEquals(len(l), size)
- self.assertEquals(l[-1], 2)
-
- del l[0]
- size -= 1
- self.assertEquals(len(l), size)
- self.assertEquals(l[0], 2)
-
- del l[:2]
- size -= 2
- self.assertEquals(len(l), size)
- self.assertEquals(l[0], 4)
-
- # Like test_concat, split in two.
- def basic_test_repeat(self, size):
- l = [] * size
- self.failIf(l)
- l = [''] * size
- self.assertEquals(len(l), size)
- l = l * 2
- self.assertEquals(len(l), size * 2)
-
- @bigmemtest(minsize=_2G // 2 + 2, memuse=24)
- def test_repeat_small(self, size):
- return self.basic_test_repeat(size)
-
- @bigmemtest(minsize=_2G + 2, memuse=24)
- def test_repeat_large(self, size):
- return self.basic_test_repeat(size)
-
- def basic_test_inplace_repeat(self, size):
- l = ['']
- l *= size
- self.assertEquals(len(l), size)
- self.failUnless(l[0] is l[-1])
- del l
-
- l = [''] * size
- l *= 2
- self.assertEquals(len(l), size * 2)
- self.failUnless(l[size - 1] is l[-1])
-
- @bigmemtest(minsize=_2G // 2 + 2, memuse=16)
- def test_inplace_repeat_small(self, size):
- return self.basic_test_inplace_repeat(size)
-
- @bigmemtest(minsize=_2G + 2, memuse=16)
- def test_inplace_repeat_large(self, size):
- return self.basic_test_inplace_repeat(size)
-
- def basic_test_repr(self, size):
- l = [0] * size
- s = repr(l)
- # The repr of a list of 0's is exactly three times the list length.
- self.assertEquals(len(s), size * 3)
- self.assertEquals(s[:5], '[0, 0')
- self.assertEquals(s[-5:], '0, 0]')
- self.assertEquals(s.count('0'), size)
-
- @bigmemtest(minsize=_2G // 3 + 2, memuse=8 + 3)
- def test_repr_small(self, size):
- return self.basic_test_repr(size)
-
- @bigmemtest(minsize=_2G + 2, memuse=8 + 3)
- def test_repr_large(self, size):
- return self.basic_test_repr(size)
-
- # list overallocates ~1/8th of the total size (on first expansion) so
- # the single list.append call puts memuse at 9 bytes per size.
- @bigmemtest(minsize=_2G, memuse=9)
- def test_append(self, size):
- l = [object()] * size
- l.append(object())
- self.assertEquals(len(l), size+1)
- self.failUnless(l[-3] is l[-2])
- self.failIf(l[-2] is l[-1])
-
- @bigmemtest(minsize=_2G // 5 + 2, memuse=8 * 5)
- def test_count(self, size):
- l = [1, 2, 3, 4, 5] * size
- self.assertEquals(l.count(1), size)
- self.assertEquals(l.count("1"), 0)
-
- def basic_test_extend(self, size):
- l = [file] * size
- l.extend(l)
- self.assertEquals(len(l), size * 2)
- self.failUnless(l[0] is l[-1])
- self.failUnless(l[size - 1] is l[size + 1])
-
- @bigmemtest(minsize=_2G // 2 + 2, memuse=16)
- def test_extend_small(self, size):
- return self.basic_test_extend(size)
-
- @bigmemtest(minsize=_2G + 2, memuse=16)
- def test_extend_large(self, size):
- return self.basic_test_extend(size)
-
- @bigmemtest(minsize=_2G // 5 + 2, memuse=8 * 5)
- def test_index(self, size):
- l = [1L, 2L, 3L, 4L, 5L] * size
- size *= 5
- self.assertEquals(l.index(1), 0)
- self.assertEquals(l.index(5, size - 5), size - 1)
- self.assertEquals(l.index(5, size - 5, size), size - 1)
- self.assertRaises(ValueError, l.index, 1, size - 4, size)
- self.assertRaises(ValueError, l.index, 6L)
-
- # This tests suffers from overallocation, just like test_append.
- @bigmemtest(minsize=_2G + 10, memuse=9)
- def test_insert(self, size):
- l = [1.0] * size
- l.insert(size - 1, "A")
- size += 1
- self.assertEquals(len(l), size)
- self.assertEquals(l[-3:], [1.0, "A", 1.0])
-
- l.insert(size + 1, "B")
- size += 1
- self.assertEquals(len(l), size)
- self.assertEquals(l[-3:], ["A", 1.0, "B"])
-
- l.insert(1, "C")
- size += 1
- self.assertEquals(len(l), size)
- self.assertEquals(l[:3], [1.0, "C", 1.0])
- self.assertEquals(l[size - 3:], ["A", 1.0, "B"])
-
- @bigmemtest(minsize=_2G // 5 + 4, memuse=8 * 5)
- def test_pop(self, size):
- l = [u"a", u"b", u"c", u"d", u"e"] * size
- size *= 5
- self.assertEquals(len(l), size)
-
- item = l.pop()
- size -= 1
- self.assertEquals(len(l), size)
- self.assertEquals(item, u"e")
- self.assertEquals(l[-2:], [u"c", u"d"])
-
- item = l.pop(0)
- size -= 1
- self.assertEquals(len(l), size)
- self.assertEquals(item, u"a")
- self.assertEquals(l[:2], [u"b", u"c"])
-
- item = l.pop(size - 2)
- size -= 1
- self.assertEquals(len(l), size)
- self.assertEquals(item, u"c")
- self.assertEquals(l[-2:], [u"b", u"d"])
-
- @bigmemtest(minsize=_2G + 10, memuse=8)
- def test_remove(self, size):
- l = [10] * size
- self.assertEquals(len(l), size)
-
- l.remove(10)
- size -= 1
- self.assertEquals(len(l), size)
-
- # Because of the earlier l.remove(), this append doesn't trigger
- # a resize.
- l.append(5)
- size += 1
- self.assertEquals(len(l), size)
- self.assertEquals(l[-2:], [10, 5])
- l.remove(5)
- size -= 1
- self.assertEquals(len(l), size)
- self.assertEquals(l[-2:], [10, 10])
-
- @bigmemtest(minsize=_2G // 5 + 2, memuse=8 * 5)
- def test_reverse(self, size):
- l = [1, 2, 3, 4, 5] * size
- l.reverse()
- self.assertEquals(len(l), size * 5)
- self.assertEquals(l[-5:], [5, 4, 3, 2, 1])
- self.assertEquals(l[:5], [5, 4, 3, 2, 1])
-
- @bigmemtest(minsize=_2G // 5 + 2, memuse=8 * 5)
- def test_sort(self, size):
- l = [1, 2, 3, 4, 5] * size
- l.sort()
- self.assertEquals(len(l), size * 5)
- self.assertEquals(l.count(1), size)
- self.assertEquals(l[:10], [1] * 10)
- self.assertEquals(l[-10:], [5] * 10)
-
-def test_main():
- test_support.run_unittest(StrTest, TupleTest, ListTest)
-
-if __name__ == '__main__':
- if len(sys.argv) > 1:
- test_support.set_memlimit(sys.argv[1])
- test_main()
+from test import test_support
+from test.test_support import bigmemtest, _1G, _2G
+
+import unittest
+import operator
+import string
+import sys
+
+# Bigmem testing houserules:
+#
+# - Try not to allocate too many large objects. It's okay to rely on
+# refcounting semantics, but don't forget that 's = create_largestring()'
+# doesn't release the old 's' (if it exists) until well after its new
+# value has been created. Use 'del s' before the create_largestring call.
+#
+# - Do *not* compare large objects using assertEquals or similar. It's a
+# lengty operation and the errormessage will be utterly useless due to
+# its size. To make sure whether a result has the right contents, better
+# to use the strip or count methods, or compare meaningful slices.
+#
+# - Don't forget to test for large indices, offsets and results and such,
+# in addition to large sizes.
+#
+# - When repeating an object (say, a substring, or a small list) to create
+# a large object, make the subobject of a length that is not a power of
+# 2. That way, int-wrapping problems are more easily detected.
+#
+# - While the bigmemtest decorator speaks of 'minsize', all tests will
+# actually be called with a much smaller number too, in the normal
+# test run (5Kb currently.) This is so the tests themselves get frequent
+# testing Consequently, always make all large allocations based on the
+# passed-in 'size', and don't rely on the size being very large. Also,
+# memuse-per-size should remain sane (less than a few thousand); if your
+# test uses more, adjust 'size' upward, instead.
+
+class StrTest(unittest.TestCase):
+ @bigmemtest(minsize=_2G, memuse=2)
+ def test_capitalize(self, size):
+ SUBSTR = ' abc def ghi'
+ s = '-' * size + SUBSTR
+ caps = s.capitalize()
+ self.assertEquals(caps[-len(SUBSTR):],
+ SUBSTR.capitalize())
+ self.assertEquals(caps.lstrip('-'), SUBSTR)
+
+ @bigmemtest(minsize=_2G + 10, memuse=1)
+ def test_center(self, size):
+ SUBSTR = ' abc def ghi'
+ s = SUBSTR.center(size)
+ self.assertEquals(len(s), size)
+ lpadsize = rpadsize = (len(s) - len(SUBSTR)) // 2
+ if len(s) % 2:
+ lpadsize += 1
+ self.assertEquals(s[lpadsize:-rpadsize], SUBSTR)
+ self.assertEquals(s.strip(), SUBSTR.strip())
+
+ @bigmemtest(minsize=_2G, memuse=2)
+ def test_count(self, size):
+ SUBSTR = ' abc def ghi'
+ s = '.' * size + SUBSTR
+ self.assertEquals(s.count('.'), size)
+ s += '.'
+ self.assertEquals(s.count('.'), size + 1)
+ self.assertEquals(s.count(' '), 3)
+ self.assertEquals(s.count('i'), 1)
+ self.assertEquals(s.count('j'), 0)
+
+ @bigmemtest(minsize=0, memuse=1)
+ def test_decode(self, size):
+ pass
+
+ @bigmemtest(minsize=0, memuse=1)
+ def test_encode(self, size):
+ pass
+
+ @bigmemtest(minsize=_2G, memuse=2)
+ def test_endswith(self, size):
+ SUBSTR = ' abc def ghi'
+ s = '-' * size + SUBSTR
+ self.failUnless(s.endswith(SUBSTR))
+ self.failUnless(s.endswith(s))
+ s2 = '...' + s
+ self.failUnless(s2.endswith(s))
+ self.failIf(s.endswith('a' + SUBSTR))
+ self.failIf(SUBSTR.endswith(s))
+
+ @bigmemtest(minsize=_2G + 10, memuse=2)
+ def test_expandtabs(self, size):
+ s = '-' * size
+ tabsize = 8
+ self.assertEquals(s.expandtabs(), s)
+ del s
+ slen, remainder = divmod(size, tabsize)
+ s = ' \t' * slen
+ s = s.expandtabs(tabsize)
+ self.assertEquals(len(s), size - remainder)
+ self.assertEquals(len(s.strip(' ')), 0)
+
+ @bigmemtest(minsize=_2G, memuse=2)
+ def test_find(self, size):
+ SUBSTR = ' abc def ghi'
+ sublen = len(SUBSTR)
+ s = ''.join([SUBSTR, '-' * size, SUBSTR])
+ self.assertEquals(s.find(' '), 0)
+ self.assertEquals(s.find(SUBSTR), 0)
+ self.assertEquals(s.find(' ', sublen), sublen + size)
+ self.assertEquals(s.find(SUBSTR, len(SUBSTR)), sublen + size)
+ self.assertEquals(s.find('i'), SUBSTR.find('i'))
+ self.assertEquals(s.find('i', sublen),
+ sublen + size + SUBSTR.find('i'))
+ self.assertEquals(s.find('i', size),
+ sublen + size + SUBSTR.find('i'))
+ self.assertEquals(s.find('j'), -1)
+
+ @bigmemtest(minsize=_2G, memuse=2)
+ def test_index(self, size):
+ SUBSTR = ' abc def ghi'
+ sublen = len(SUBSTR)
+ s = ''.join([SUBSTR, '-' * size, SUBSTR])
+ self.assertEquals(s.index(' '), 0)
+ self.assertEquals(s.index(SUBSTR), 0)
+ self.assertEquals(s.index(' ', sublen), sublen + size)
+ self.assertEquals(s.index(SUBSTR, sublen), sublen + size)
+ self.assertEquals(s.index('i'), SUBSTR.index('i'))
+ self.assertEquals(s.index('i', sublen),
+ sublen + size + SUBSTR.index('i'))
+ self.assertEquals(s.index('i', size),
+ sublen + size + SUBSTR.index('i'))
+ self.assertRaises(ValueError, s.index, 'j')
+
+ @bigmemtest(minsize=_2G, memuse=2)
+ def test_isalnum(self, size):
+ SUBSTR = '123456'
+ s = 'a' * size + SUBSTR
+ self.failUnless(s.isalnum())
+ s += '.'
+ self.failIf(s.isalnum())
+
+ @bigmemtest(minsize=_2G, memuse=2)
+ def test_isalpha(self, size):
+ SUBSTR = 'zzzzzzz'
+ s = 'a' * size + SUBSTR
+ self.failUnless(s.isalpha())
+ s += '.'
+ self.failIf(s.isalpha())
+
+ @bigmemtest(minsize=_2G, memuse=2)
+ def test_isdigit(self, size):
+ SUBSTR = '123456'
+ s = '9' * size + SUBSTR
+ self.failUnless(s.isdigit())
+ s += 'z'
+ self.failIf(s.isdigit())
+
+ @bigmemtest(minsize=_2G, memuse=2)
+ def test_islower(self, size):
+ chars = ''.join([ chr(c) for c in range(255) if not chr(c).isupper() ])
+ repeats = size // len(chars) + 2
+ s = chars * repeats
+ self.failUnless(s.islower())
+ s += 'A'
+ self.failIf(s.islower())
+
+ @bigmemtest(minsize=_2G, memuse=2)
+ def test_isspace(self, size):
+ whitespace = ' \f\n\r\t\v'
+ repeats = size // len(whitespace) + 2
+ s = whitespace * repeats
+ self.failUnless(s.isspace())
+ s += 'j'
+ self.failIf(s.isspace())
+
+ @bigmemtest(minsize=_2G, memuse=2)
+ def test_istitle(self, size):
+ SUBSTR = '123456'
+ s = ''.join(['A', 'a' * size, SUBSTR])
+ self.failUnless(s.istitle())
+ s += 'A'
+ self.failUnless(s.istitle())
+ s += 'aA'
+ self.failIf(s.istitle())
+
+ @bigmemtest(minsize=_2G, memuse=2)
+ def test_isupper(self, size):
+ chars = ''.join([ chr(c) for c in range(255) if not chr(c).islower() ])
+ repeats = size // len(chars) + 2
+ s = chars * repeats
+ self.failUnless(s.isupper())
+ s += 'a'
+ self.failIf(s.isupper())
+
+ @bigmemtest(minsize=_2G, memuse=2)
+ def test_join(self, size):
+ s = 'A' * size
+ x = s.join(['aaaaa', 'bbbbb'])
+ self.assertEquals(x.count('a'), 5)
+ self.assertEquals(x.count('b'), 5)
+ self.failUnless(x.startswith('aaaaaA'))
+ self.failUnless(x.endswith('Abbbbb'))
+
+ @bigmemtest(minsize=_2G + 10, memuse=1)
+ def test_ljust(self, size):
+ SUBSTR = ' abc def ghi'
+ s = SUBSTR.ljust(size)
+ self.failUnless(s.startswith(SUBSTR + ' '))
+ self.assertEquals(len(s), size)
+ self.assertEquals(s.strip(), SUBSTR.strip())
+
+ @bigmemtest(minsize=_2G + 10, memuse=2)
+ def test_lower(self, size):
+ s = 'A' * size
+ s = s.lower()
+ self.assertEquals(len(s), size)
+ self.assertEquals(s.count('a'), size)
+
+ @bigmemtest(minsize=_2G + 10, memuse=1)
+ def test_lstrip(self, size):
+ SUBSTR = 'abc def ghi'
+ s = SUBSTR.rjust(size)
+ self.assertEquals(len(s), size)
+ self.assertEquals(s.lstrip(), SUBSTR.lstrip())
+ del s
+ s = SUBSTR.ljust(size)
+ self.assertEquals(len(s), size)
+ stripped = s.lstrip()
+ self.failUnless(stripped is s)
+
+ @bigmemtest(minsize=_2G + 10, memuse=2)
+ def test_replace(self, size):
+ replacement = 'a'
+ s = ' ' * size
+ s = s.replace(' ', replacement)
+ self.assertEquals(len(s), size)
+ self.assertEquals(s.count(replacement), size)
+ s = s.replace(replacement, ' ', size - 4)
+ self.assertEquals(len(s), size)
+ self.assertEquals(s.count(replacement), 4)
+ self.assertEquals(s[-10:], ' aaaa')
+
+ @bigmemtest(minsize=_2G, memuse=2)
+ def test_rfind(self, size):
+ SUBSTR = ' abc def ghi'
+ sublen = len(SUBSTR)
+ s = ''.join([SUBSTR, '-' * size, SUBSTR])
+ self.assertEquals(s.rfind(' '), sublen + size + SUBSTR.rfind(' '))
+ self.assertEquals(s.rfind(SUBSTR), sublen + size)
+ self.assertEquals(s.rfind(' ', 0, size), SUBSTR.rfind(' '))
+ self.assertEquals(s.rfind(SUBSTR, 0, sublen + size), 0)
+ self.assertEquals(s.rfind('i'), sublen + size + SUBSTR.rfind('i'))
+ self.assertEquals(s.rfind('i', 0, sublen), SUBSTR.rfind('i'))
+ self.assertEquals(s.rfind('i', 0, sublen + size),
+ SUBSTR.rfind('i'))
+ self.assertEquals(s.rfind('j'), -1)
+
+ @bigmemtest(minsize=_2G, memuse=2)
+ def test_rindex(self, size):
+ SUBSTR = ' abc def ghi'
+ sublen = len(SUBSTR)
+ s = ''.join([SUBSTR, '-' * size, SUBSTR])
+ self.assertEquals(s.rindex(' '),
+ sublen + size + SUBSTR.rindex(' '))
+ self.assertEquals(s.rindex(SUBSTR), sublen + size)
+ self.assertEquals(s.rindex(' ', 0, sublen + size - 1),
+ SUBSTR.rindex(' '))
+ self.assertEquals(s.rindex(SUBSTR, 0, sublen + size), 0)
+ self.assertEquals(s.rindex('i'),
+ sublen + size + SUBSTR.rindex('i'))
+ self.assertEquals(s.rindex('i', 0, sublen), SUBSTR.rindex('i'))
+ self.assertEquals(s.rindex('i', 0, sublen + size),
+ SUBSTR.rindex('i'))
+ self.assertRaises(ValueError, s.rindex, 'j')
+
+ @bigmemtest(minsize=_2G + 10, memuse=1)
+ def test_rjust(self, size):
+ SUBSTR = ' abc def ghi'
+ s = SUBSTR.ljust(size)
+ self.failUnless(s.startswith(SUBSTR + ' '))
+ self.assertEquals(len(s), size)
+ self.assertEquals(s.strip(), SUBSTR.strip())
+
+ @bigmemtest(minsize=_2G + 10, memuse=1)
+ def test_rstrip(self, size):
+ SUBSTR = ' abc def ghi'
+ s = SUBSTR.ljust(size)
+ self.assertEquals(len(s), size)
+ self.assertEquals(s.rstrip(), SUBSTR.rstrip())
+ del s
+ s = SUBSTR.rjust(size)
+ self.assertEquals(len(s), size)
+ stripped = s.rstrip()
+ self.failUnless(stripped is s)
+
+ # The test takes about size bytes to build a string, and then about
+ # sqrt(size) substrings of sqrt(size) in size and a list to
+ # hold sqrt(size) items. It's close but just over 2x size.
+ @bigmemtest(minsize=_2G, memuse=2.1)
+ def test_split_small(self, size):
+ # Crudely calculate an estimate so that the result of s.split won't
+ # take up an inordinate amount of memory
+ chunksize = int(size ** 0.5 + 2)
+ SUBSTR = 'a' + ' ' * chunksize
+ s = SUBSTR * chunksize
+ l = s.split()
+ self.assertEquals(len(l), chunksize)
+ self.assertEquals(set(l), set(['a']))
+ del l
+ l = s.split('a')
+ self.assertEquals(len(l), chunksize + 1)
+ self.assertEquals(set(l), set(['', ' ' * chunksize]))
+
+ # Allocates a string of twice size (and briefly two) and a list of
+ # size. Because of internal affairs, the s.split() call produces a
+ # list of size times the same one-character string, so we only
+ # suffer for the list size. (Otherwise, it'd cost another 48 times
+ # size in bytes!) Nevertheless, a list of size takes
+ # 8*size bytes.
+ @bigmemtest(minsize=_2G + 5, memuse=10)
+ def test_split_large(self, size):
+ s = ' a' * size + ' '
+ l = s.split()
+ self.assertEquals(len(l), size)
+ self.assertEquals(set(l), set(['a']))
+ del l
+ l = s.split('a')
+ self.assertEquals(len(l), size + 1)
+ self.assertEquals(set(l), set([' ']))
+
+ @bigmemtest(minsize=_2G, memuse=2.1)
+ def test_splitlines(self, size):
+ # Crudely calculate an estimate so that the result of s.split won't
+ # take up an inordinate amount of memory
+ chunksize = int(size ** 0.5 + 2) // 2
+ SUBSTR = ' ' * chunksize + '\n' + ' ' * chunksize + '\r\n'
+ s = SUBSTR * chunksize
+ l = s.splitlines()
+ self.assertEquals(len(l), chunksize * 2)
+ self.assertEquals(set(l), set([' ' * chunksize]))
+
+ @bigmemtest(minsize=_2G, memuse=2)
+ def test_startswith(self, size):
+ SUBSTR = ' abc def ghi'
+ s = '-' * size + SUBSTR
+ self.failUnless(s.startswith(s))
+ self.failUnless(s.startswith('-' * size))
+ self.failIf(s.startswith(SUBSTR))
+
+ @bigmemtest(minsize=_2G, memuse=1)
+ def test_strip(self, size):
+ SUBSTR = ' abc def ghi '
+ s = SUBSTR.rjust(size)
+ self.assertEquals(len(s), size)
+ self.assertEquals(s.strip(), SUBSTR.strip())
+ del s
+ s = SUBSTR.ljust(size)
+ self.assertEquals(len(s), size)
+ self.assertEquals(s.strip(), SUBSTR.strip())
+
+ @bigmemtest(minsize=_2G, memuse=2)
+ def test_swapcase(self, size):
+ SUBSTR = "aBcDeFG12.'\xa9\x00"
+ sublen = len(SUBSTR)
+ repeats = size // sublen + 2
+ s = SUBSTR * repeats
+ s = s.swapcase()
+ self.assertEquals(len(s), sublen * repeats)
+ self.assertEquals(s[:sublen * 3], SUBSTR.swapcase() * 3)
+ self.assertEquals(s[-sublen * 3:], SUBSTR.swapcase() * 3)
+
+ @bigmemtest(minsize=_2G, memuse=2)
+ def test_title(self, size):
+ SUBSTR = 'SpaaHAaaAaham'
+ s = SUBSTR * (size // len(SUBSTR) + 2)
+ s = s.title()
+ self.failUnless(s.startswith((SUBSTR * 3).title()))
+ self.failUnless(s.endswith(SUBSTR.lower() * 3))
+
+ @bigmemtest(minsize=_2G, memuse=2)
+ def test_translate(self, size):
+ trans = string.maketrans('.aZ', '-!$')
+ SUBSTR = 'aZz.z.Aaz.'
+ sublen = len(SUBSTR)
+ repeats = size // sublen + 2
+ s = SUBSTR * repeats
+ s = s.translate(trans)
+ self.assertEquals(len(s), repeats * sublen)
+ self.assertEquals(s[:sublen], SUBSTR.translate(trans))
+ self.assertEquals(s[-sublen:], SUBSTR.translate(trans))
+ self.assertEquals(s.count('.'), 0)
+ self.assertEquals(s.count('!'), repeats * 2)
+ self.assertEquals(s.count('z'), repeats * 3)
+
+ @bigmemtest(minsize=_2G + 5, memuse=2)
+ def test_upper(self, size):
+ s = 'a' * size
+ s = s.upper()
+ self.assertEquals(len(s), size)
+ self.assertEquals(s.count('A'), size)
+
+ @bigmemtest(minsize=_2G + 20, memuse=1)
+ def test_zfill(self, size):
+ SUBSTR = '-568324723598234'
+ s = SUBSTR.zfill(size)
+ self.failUnless(s.endswith('0' + SUBSTR[1:]))
+ self.failUnless(s.startswith('-0'))
+ self.assertEquals(len(s), size)
+ self.assertEquals(s.count('0'), size - len(SUBSTR))
+
+ @bigmemtest(minsize=_2G + 10, memuse=2)
+ def test_format(self, size):
+ s = '-' * size
+ sf = '%s' % (s,)
+ self.failUnless(s == sf)
+ del sf
+ sf = '..%s..' % (s,)
+ self.assertEquals(len(sf), len(s) + 4)
+ self.failUnless(sf.startswith('..-'))
+ self.failUnless(sf.endswith('-..'))
+ del s, sf
+
+ size //= 2
+ edge = '-' * size
+ s = ''.join([edge, '%s', edge])
+ del edge
+ s = s % '...'
+ self.assertEquals(len(s), size * 2 + 3)
+ self.assertEquals(s.count('.'), 3)
+ self.assertEquals(s.count('-'), size * 2)
+
+ @bigmemtest(minsize=_2G + 10, memuse=2)
+ def test_repr_small(self, size):
+ s = '-' * size
+ s = repr(s)
+ self.assertEquals(len(s), size + 2)
+ self.assertEquals(s[0], "'")
+ self.assertEquals(s[-1], "'")
+ self.assertEquals(s.count('-'), size)
+ del s
+ # repr() will create a string four times as large as this 'binary
+ # string', but we don't want to allocate much more than twice
+ # size in total. (We do extra testing in test_repr_large())
+ size = size // 5 * 2
+ s = '\x00' * size
+ s = repr(s)
+ self.assertEquals(len(s), size * 4 + 2)
+ self.assertEquals(s[0], "'")
+ self.assertEquals(s[-1], "'")
+ self.assertEquals(s.count('\\'), size)
+ self.assertEquals(s.count('0'), size * 2)
+
+ @bigmemtest(minsize=_2G + 10, memuse=5)
+ def test_repr_large(self, size):
+ s = '\x00' * size
+ s = repr(s)
+ self.assertEquals(len(s), size * 4 + 2)
+ self.assertEquals(s[0], "'")
+ self.assertEquals(s[-1], "'")
+ self.assertEquals(s.count('\\'), size)
+ self.assertEquals(s.count('0'), size * 2)
+
+ # This test is meaningful even with size < 2G, as long as the
+ # doubled string is > 2G (but it tests more if both are > 2G :)
+ @bigmemtest(minsize=_1G + 2, memuse=3)
+ def test_concat(self, size):
+ s = '.' * size
+ self.assertEquals(len(s), size)
+ s = s + s
+ self.assertEquals(len(s), size * 2)
+ self.assertEquals(s.count('.'), size * 2)
+
+ # This test is meaningful even with size < 2G, as long as the
+ # repeated string is > 2G (but it tests more if both are > 2G :)
+ @bigmemtest(minsize=_1G + 2, memuse=3)
+ def test_repeat(self, size):
+ s = '.' * size
+ self.assertEquals(len(s), size)
+ s = s * 2
+ self.assertEquals(len(s), size * 2)
+ self.assertEquals(s.count('.'), size * 2)
+
+ @bigmemtest(minsize=_2G + 20, memuse=1)
+ def test_slice_and_getitem(self, size):
+ SUBSTR = '0123456789'
+ sublen = len(SUBSTR)
+ s = SUBSTR * (size // sublen)
+ stepsize = len(s) // 100
+ stepsize = stepsize - (stepsize % sublen)
+ for i in range(0, len(s) - stepsize, stepsize):
+ self.assertEquals(s[i], SUBSTR[0])
+ self.assertEquals(s[i:i + sublen], SUBSTR)
+ self.assertEquals(s[i:i + sublen:2], SUBSTR[::2])
+ if i > 0:
+ self.assertEquals(s[i + sublen - 1:i - 1:-3],
+ SUBSTR[sublen::-3])
+ # Make sure we do some slicing and indexing near the end of the
+ # string, too.
+ self.assertEquals(s[len(s) - 1], SUBSTR[-1])
+ self.assertEquals(s[-1], SUBSTR[-1])
+ self.assertEquals(s[len(s) - 10], SUBSTR[0])
+ self.assertEquals(s[-sublen], SUBSTR[0])
+ self.assertEquals(s[len(s):], '')
+ self.assertEquals(s[len(s) - 1:], SUBSTR[-1])
+ self.assertEquals(s[-1:], SUBSTR[-1])
+ self.assertEquals(s[len(s) - sublen:], SUBSTR)
+ self.assertEquals(s[-sublen:], SUBSTR)
+ self.assertEquals(len(s[:]), len(s))
+ self.assertEquals(len(s[:len(s) - 5]), len(s) - 5)
+ self.assertEquals(len(s[5:-5]), len(s) - 10)
+
+ self.assertRaises(IndexError, operator.getitem, s, len(s))
+ self.assertRaises(IndexError, operator.getitem, s, len(s) + 1)
+ self.assertRaises(IndexError, operator.getitem, s, len(s) + 1<<31)
+
+ @bigmemtest(minsize=_2G, memuse=2)
+ def test_contains(self, size):
+ SUBSTR = '0123456789'
+ edge = '-' * (size // 2)
+ s = ''.join([edge, SUBSTR, edge])
+ del edge
+ self.failUnless(SUBSTR in s)
+ self.failIf(SUBSTR * 2 in s)
+ self.failUnless('-' in s)
+ self.failIf('a' in s)
+ s += 'a'
+ self.failUnless('a' in s)
+
+ @bigmemtest(minsize=_2G + 10, memuse=2)
+ def test_compare(self, size):
+ s1 = '-' * size
+ s2 = '-' * size
+ self.failUnless(s1 == s2)
+ del s2
+ s2 = s1 + 'a'
+ self.failIf(s1 == s2)
+ del s2
+ s2 = '.' * size
+ self.failIf(s1 == s2)
+
+ @bigmemtest(minsize=_2G + 10, memuse=1)
+ def test_hash(self, size):
+ # Not sure if we can do any meaningful tests here... Even if we
+ # start relying on the exact algorithm used, the result will be
+ # different depending on the size of the C 'long int'. Even this
+ # test is dodgy (there's no *guarantee* that the two things should
+ # have a different hash, even if they, in the current
+ # implementation, almost always do.)
+ s = '\x00' * size
+ h1 = hash(s)
+ del s
+ s = '\x00' * (size + 1)
+ self.failIf(h1 == hash(s))
+
+class TupleTest(unittest.TestCase):
+
+ # Tuples have a small, fixed-sized head and an array of pointers to
+ # data. Since we're testing 64-bit addressing, we can assume that the
+ # pointers are 8 bytes, and that thus that the tuples take up 8 bytes
+ # per size.
+
+ # As a side-effect of testing long tuples, these tests happen to test
+ # having more than 2<<31 references to any given object. Hence the
+ # use of different types of objects as contents in different tests.
+
+ @bigmemtest(minsize=_2G + 2, memuse=16)
+ def test_compare(self, size):
+ t1 = (u'',) * size
+ t2 = (u'',) * size
+ self.failUnless(t1 == t2)
+ del t2
+ t2 = (u'',) * (size + 1)
+ self.failIf(t1 == t2)
+ del t2
+ t2 = (1,) * size
+ self.failIf(t1 == t2)
+
+ # Test concatenating into a single tuple of more than 2G in length,
+ # and concatenating a tuple of more than 2G in length separately, so
+ # the smaller test still gets run even if there isn't memory for the
+ # larger test (but we still let the tester know the larger test is
+ # skipped, in verbose mode.)
+ def basic_concat_test(self, size):
+ t = ((),) * size
+ self.assertEquals(len(t), size)
+ t = t + t
+ self.assertEquals(len(t), size * 2)
+
+ @bigmemtest(minsize=_2G // 2 + 2, memuse=24)
+ def test_concat_small(self, size):
+ return self.basic_concat_test(size)
+
+ @bigmemtest(minsize=_2G + 2, memuse=24)
+ def test_concat_large(self, size):
+ return self.basic_concat_test(size)
+
+ @bigmemtest(minsize=_2G // 5 + 10, memuse=8 * 5)
+ def test_contains(self, size):
+ t = (1, 2, 3, 4, 5) * size
+ self.assertEquals(len(t), size * 5)
+ self.failUnless(5 in t)
+ self.failIf((1, 2, 3, 4, 5) in t)
+ self.failIf(0 in t)
+
+ @bigmemtest(minsize=_2G + 10, memuse=8)
+ def test_hash(self, size):
+ t1 = (0,) * size
+ h1 = hash(t1)
+ del t1
+ t2 = (0,) * (size + 1)
+ self.failIf(h1 == hash(t2))
+
+ @bigmemtest(minsize=_2G + 10, memuse=8)
+ def test_index_and_slice(self, size):
+ t = (None,) * size
+ self.assertEquals(len(t), size)
+ self.assertEquals(t[-1], None)
+ self.assertEquals(t[5], None)
+ self.assertEquals(t[size - 1], None)
+ self.assertRaises(IndexError, operator.getitem, t, size)
+ self.assertEquals(t[:5], (None,) * 5)
+ self.assertEquals(t[-5:], (None,) * 5)
+ self.assertEquals(t[20:25], (None,) * 5)
+ self.assertEquals(t[-25:-20], (None,) * 5)
+ self.assertEquals(t[size - 5:], (None,) * 5)
+ self.assertEquals(t[size - 5:size], (None,) * 5)
+ self.assertEquals(t[size - 6:size - 2], (None,) * 4)
+ self.assertEquals(t[size:size], ())
+ self.assertEquals(t[size:size+5], ())
+
+ # Like test_concat, split in two.
+ def basic_test_repeat(self, size):
+ t = ('',) * size
+ self.assertEquals(len(t), size)
+ t = t * 2
+ self.assertEquals(len(t), size * 2)
+
+ @bigmemtest(minsize=_2G // 2 + 2, memuse=24)
+ def test_repeat_small(self, size):
+ return self.basic_test_repeat(size)
+
+ @bigmemtest(minsize=_2G + 2, memuse=24)
+ def test_repeat_large(self, size):
+ return self.basic_test_repeat(size)
+
+ # Like test_concat, split in two.
+ def basic_test_repr(self, size):
+ t = (0,) * size
+ s = repr(t)
+ # The repr of a tuple of 0's is exactly three times the tuple length.
+ self.assertEquals(len(s), size * 3)
+ self.assertEquals(s[:5], '(0, 0')
+ self.assertEquals(s[-5:], '0, 0)')
+ self.assertEquals(s.count('0'), size)
+
+ @bigmemtest(minsize=_2G // 3 + 2, memuse=8 + 3)
+ def test_repr_small(self, size):
+ return self.basic_test_repr(size)
+
+ @bigmemtest(minsize=_2G + 2, memuse=8 + 3)
+ def test_repr_large(self, size):
+ return self.basic_test_repr(size)
+
+class ListTest(unittest.TestCase):
+
+ # Like tuples, lists have a small, fixed-sized head and an array of
+ # pointers to data, so 8 bytes per size. Also like tuples, we make the
+ # lists hold references to various objects to test their refcount
+ # limits.
+
+ @bigmemtest(minsize=_2G + 2, memuse=16)
+ def test_compare(self, size):
+ l1 = [u''] * size
+ l2 = [u''] * size
+ self.failUnless(l1 == l2)
+ del l2
+ l2 = [u''] * (size + 1)
+ self.failIf(l1 == l2)
+ del l2
+ l2 = [2] * size
+ self.failIf(l1 == l2)
+
+ # Test concatenating into a single list of more than 2G in length,
+ # and concatenating a list of more than 2G in length separately, so
+ # the smaller test still gets run even if there isn't memory for the
+ # larger test (but we still let the tester know the larger test is
+ # skipped, in verbose mode.)
+ def basic_test_concat(self, size):
+ l = [[]] * size
+ self.assertEquals(len(l), size)
+ l = l + l
+ self.assertEquals(len(l), size * 2)
+
+ @bigmemtest(minsize=_2G // 2 + 2, memuse=24)
+ def test_concat_small(self, size):
+ return self.basic_test_concat(size)
+
+ @bigmemtest(minsize=_2G + 2, memuse=24)
+ def test_concat_large(self, size):
+ return self.basic_test_concat(size)
+
+ def basic_test_inplace_concat(self, size):
+ l = [sys.stdout] * size
+ l += l
+ self.assertEquals(len(l), size * 2)
+ self.failUnless(l[0] is l[-1])
+ self.failUnless(l[size - 1] is l[size + 1])
+
+ @bigmemtest(minsize=_2G // 2 + 2, memuse=24)
+ def test_inplace_concat_small(self, size):
+ return self.basic_test_inplace_concat(size)
+
+ @bigmemtest(minsize=_2G + 2, memuse=24)
+ def test_inplace_concat_large(self, size):
+ return self.basic_test_inplace_concat(size)
+
+ @bigmemtest(minsize=_2G // 5 + 10, memuse=8 * 5)
+ def test_contains(self, size):
+ l = [1, 2, 3, 4, 5] * size
+ self.assertEquals(len(l), size * 5)
+ self.failUnless(5 in l)
+ self.failIf([1, 2, 3, 4, 5] in l)
+ self.failIf(0 in l)
+
+ @bigmemtest(minsize=_2G + 10, memuse=8)
+ def test_hash(self, size):
+ l = [0] * size
+ self.failUnlessRaises(TypeError, hash, l)
+
+ @bigmemtest(minsize=_2G + 10, memuse=8)
+ def test_index_and_slice(self, size):
+ l = [None] * size
+ self.assertEquals(len(l), size)
+ self.assertEquals(l[-1], None)
+ self.assertEquals(l[5], None)
+ self.assertEquals(l[size - 1], None)
+ self.assertRaises(IndexError, operator.getitem, l, size)
+ self.assertEquals(l[:5], [None] * 5)
+ self.assertEquals(l[-5:], [None] * 5)
+ self.assertEquals(l[20:25], [None] * 5)
+ self.assertEquals(l[-25:-20], [None] * 5)
+ self.assertEquals(l[size - 5:], [None] * 5)
+ self.assertEquals(l[size - 5:size], [None] * 5)
+ self.assertEquals(l[size - 6:size - 2], [None] * 4)
+ self.assertEquals(l[size:size], [])
+ self.assertEquals(l[size:size+5], [])
+
+ l[size - 2] = 5
+ self.assertEquals(len(l), size)
+ self.assertEquals(l[-3:], [None, 5, None])
+ self.assertEquals(l.count(5), 1)
+ self.assertRaises(IndexError, operator.setitem, l, size, 6)
+ self.assertEquals(len(l), size)
+
+ l[size - 7:] = [1, 2, 3, 4, 5]
+ size -= 2
+ self.assertEquals(len(l), size)
+ self.assertEquals(l[-7:], [None, None, 1, 2, 3, 4, 5])
+
+ l[:7] = [1, 2, 3, 4, 5]
+ size -= 2
+ self.assertEquals(len(l), size)
+ self.assertEquals(l[:7], [1, 2, 3, 4, 5, None, None])
+
+ del l[size - 1]
+ size -= 1
+ self.assertEquals(len(l), size)
+ self.assertEquals(l[-1], 4)
+
+ del l[-2:]
+ size -= 2
+ self.assertEquals(len(l), size)
+ self.assertEquals(l[-1], 2)
+
+ del l[0]
+ size -= 1
+ self.assertEquals(len(l), size)
+ self.assertEquals(l[0], 2)
+
+ del l[:2]
+ size -= 2
+ self.assertEquals(len(l), size)
+ self.assertEquals(l[0], 4)
+
+ # Like test_concat, split in two.
+ def basic_test_repeat(self, size):
+ l = [] * size
+ self.failIf(l)
+ l = [''] * size
+ self.assertEquals(len(l), size)
+ l = l * 2
+ self.assertEquals(len(l), size * 2)
+
+ @bigmemtest(minsize=_2G // 2 + 2, memuse=24)
+ def test_repeat_small(self, size):
+ return self.basic_test_repeat(size)
+
+ @bigmemtest(minsize=_2G + 2, memuse=24)
+ def test_repeat_large(self, size):
+ return self.basic_test_repeat(size)
+
+ def basic_test_inplace_repeat(self, size):
+ l = ['']
+ l *= size
+ self.assertEquals(len(l), size)
+ self.failUnless(l[0] is l[-1])
+ del l
+
+ l = [''] * size
+ l *= 2
+ self.assertEquals(len(l), size * 2)
+ self.failUnless(l[size - 1] is l[-1])
+
+ @bigmemtest(minsize=_2G // 2 + 2, memuse=16)
+ def test_inplace_repeat_small(self, size):
+ return self.basic_test_inplace_repeat(size)
+
+ @bigmemtest(minsize=_2G + 2, memuse=16)
+ def test_inplace_repeat_large(self, size):
+ return self.basic_test_inplace_repeat(size)
+
+ def basic_test_repr(self, size):
+ l = [0] * size
+ s = repr(l)
+ # The repr of a list of 0's is exactly three times the list length.
+ self.assertEquals(len(s), size * 3)
+ self.assertEquals(s[:5], '[0, 0')
+ self.assertEquals(s[-5:], '0, 0]')
+ self.assertEquals(s.count('0'), size)
+
+ @bigmemtest(minsize=_2G // 3 + 2, memuse=8 + 3)
+ def test_repr_small(self, size):
+ return self.basic_test_repr(size)
+
+ @bigmemtest(minsize=_2G + 2, memuse=8 + 3)
+ def test_repr_large(self, size):
+ return self.basic_test_repr(size)
+
+ # list overallocates ~1/8th of the total size (on first expansion) so
+ # the single list.append call puts memuse at 9 bytes per size.
+ @bigmemtest(minsize=_2G, memuse=9)
+ def test_append(self, size):
+ l = [object()] * size
+ l.append(object())
+ self.assertEquals(len(l), size+1)
+ self.failUnless(l[-3] is l[-2])
+ self.failIf(l[-2] is l[-1])
+
+ @bigmemtest(minsize=_2G // 5 + 2, memuse=8 * 5)
+ def test_count(self, size):
+ l = [1, 2, 3, 4, 5] * size
+ self.assertEquals(l.count(1), size)
+ self.assertEquals(l.count("1"), 0)
+
+ def basic_test_extend(self, size):
+ l = [file] * size
+ l.extend(l)
+ self.assertEquals(len(l), size * 2)
+ self.failUnless(l[0] is l[-1])
+ self.failUnless(l[size - 1] is l[size + 1])
+
+ @bigmemtest(minsize=_2G // 2 + 2, memuse=16)
+ def test_extend_small(self, size):
+ return self.basic_test_extend(size)
+
+ @bigmemtest(minsize=_2G + 2, memuse=16)
+ def test_extend_large(self, size):
+ return self.basic_test_extend(size)
+
+ @bigmemtest(minsize=_2G // 5 + 2, memuse=8 * 5)
+ def test_index(self, size):
+ l = [1L, 2L, 3L, 4L, 5L] * size
+ size *= 5
+ self.assertEquals(l.index(1), 0)
+ self.assertEquals(l.index(5, size - 5), size - 1)
+ self.assertEquals(l.index(5, size - 5, size), size - 1)
+ self.assertRaises(ValueError, l.index, 1, size - 4, size)
+ self.assertRaises(ValueError, l.index, 6L)
+
+ # This tests suffers from overallocation, just like test_append.
+ @bigmemtest(minsize=_2G + 10, memuse=9)
+ def test_insert(self, size):
+ l = [1.0] * size
+ l.insert(size - 1, "A")
+ size += 1
+ self.assertEquals(len(l), size)
+ self.assertEquals(l[-3:], [1.0, "A", 1.0])
+
+ l.insert(size + 1, "B")
+ size += 1
+ self.assertEquals(len(l), size)
+ self.assertEquals(l[-3:], ["A", 1.0, "B"])
+
+ l.insert(1, "C")
+ size += 1
+ self.assertEquals(len(l), size)
+ self.assertEquals(l[:3], [1.0, "C", 1.0])
+ self.assertEquals(l[size - 3:], ["A", 1.0, "B"])
+
+ @bigmemtest(minsize=_2G // 5 + 4, memuse=8 * 5)
+ def test_pop(self, size):
+ l = [u"a", u"b", u"c", u"d", u"e"] * size
+ size *= 5
+ self.assertEquals(len(l), size)
+
+ item = l.pop()
+ size -= 1
+ self.assertEquals(len(l), size)
+ self.assertEquals(item, u"e")
+ self.assertEquals(l[-2:], [u"c", u"d"])
+
+ item = l.pop(0)
+ size -= 1
+ self.assertEquals(len(l), size)
+ self.assertEquals(item, u"a")
+ self.assertEquals(l[:2], [u"b", u"c"])
+
+ item = l.pop(size - 2)
+ size -= 1
+ self.assertEquals(len(l), size)
+ self.assertEquals(item, u"c")
+ self.assertEquals(l[-2:], [u"b", u"d"])
+
+ @bigmemtest(minsize=_2G + 10, memuse=8)
+ def test_remove(self, size):
+ l = [10] * size
+ self.assertEquals(len(l), size)
+
+ l.remove(10)
+ size -= 1
+ self.assertEquals(len(l), size)
+
+ # Because of the earlier l.remove(), this append doesn't trigger
+ # a resize.
+ l.append(5)
+ size += 1
+ self.assertEquals(len(l), size)
+ self.assertEquals(l[-2:], [10, 5])
+ l.remove(5)
+ size -= 1
+ self.assertEquals(len(l), size)
+ self.assertEquals(l[-2:], [10, 10])
+
+ @bigmemtest(minsize=_2G // 5 + 2, memuse=8 * 5)
+ def test_reverse(self, size):
+ l = [1, 2, 3, 4, 5] * size
+ l.reverse()
+ self.assertEquals(len(l), size * 5)
+ self.assertEquals(l[-5:], [5, 4, 3, 2, 1])
+ self.assertEquals(l[:5], [5, 4, 3, 2, 1])
+
+ @bigmemtest(minsize=_2G // 5 + 2, memuse=8 * 5)
+ def test_sort(self, size):
+ l = [1, 2, 3, 4, 5] * size
+ l.sort()
+ self.assertEquals(len(l), size * 5)
+ self.assertEquals(l.count(1), size)
+ self.assertEquals(l[:10], [1] * 10)
+ self.assertEquals(l[-10:], [5] * 10)
+
+def test_main():
+ test_support.run_unittest(StrTest, TupleTest, ListTest)
+
+if __name__ == '__main__':
+ if len(sys.argv) > 1:
+ test_support.set_memlimit(sys.argv[1])
+ test_main()
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