25.4. 2to3 - Automated Python 2 to 3 code translation
2to3 is a Python program that reads Python 2.x source code and applies a series of fixers to transform it into valid Python 3.x code. The standard library contains a rich set of fixers that will handle almost all code. 2to3 supporting library lib2to3 is, however, a flexible and generic library, so it is possible to write your own fixers for 2to3. lib2to3 could also be adapted to custom applications in which Python code needs to be edited automatically.
25.4.1. Using 2to3
2to3 will usually be installed with the Python interpreter as a script. It is also located in the Tools/scripts directory of the Python root.
2to3’s basic arguments are a list of files or directories to transform. The directories are to recursively traversed for Python sources.
Here is a sample Python 2.x source file, example.py:
def greet(name):
print "Hello, {0}!".format(name)
print "What's your name?"
name = raw_input()
greet(name)
It can be converted to Python 3.x code via 2to3 on the command line:
$ 2to3 example.py
A diff against the original source file is printed. 2to3 can also write the needed modifications right back to the source file. (A backup of the original file is made unless -n is also given.) Writing the changes back is enabled with the -w flag:
$ 2to3 -w example.py
After transformation, example.py looks like this:
def greet(name):
print("Hello, {0}!".format(name))
print("What's your name?")
name = input()
greet(name)
Comments and exact indentation are preserved throughout the translation process.
By default, 2to3 runs a set of predefined fixers. The -l flag lists all available fixers. An explicit set of fixers to run can be given with -f. Likewise the -x explicitly disables a fixer. The following example runs only the imports and has_key fixers:
$ 2to3 -f imports -f has_key example.py
This command runs every fixer except the apply fixer:
$ 2to3 -x apply example.py
Some fixers are explicit, meaning they aren’t run by default and must be listed on the command line to be run. Here, in addition to the default fixers, the idioms fixer is run:
$ 2to3 -f all -f idioms example.py
Notice how passing all enables all default fixers.
Sometimes 2to3 will find a place in your source code that needs to be changed, but 2to3 cannot fix automatically. In this case, 2to3 will print a warning beneath the diff for a file. You should address the warning in order to have compliant 3.x code.
2to3 can also refactor doctests. To enable this mode, use the -d flag. Note that only doctests will be refactored. This also doesn’t require the module to be valid Python. For example, doctest like examples in a reST document could also be refactored with this option.
The -v option enables output of more information on the translation process.
Since some print statements can be parsed as function calls or statements, 2to3 cannot always read files containing the print function. When 2to3 detects the presence of the from __future__ import print_function compiler directive, it modifies its internal grammar to interpert print() as a function. This change can also be enabled manually with the -p flag. Use -p to run fixers on code that already has had its print statements converted.
25.4.2. Fixers
Each step of transforming code is encapsulated in a fixer. The command 2to3 -l lists them. As documented above, each can be turned on and off individually. They are described here in more detail.
- apply
- Removes usage of apply(). For example apply(function, *args, **kwargs) is converted to function(*args, **kwargs).
- basestring
- Converts basestring to str.
- buffer
- Converts buffer to memoryview. This fixer is optional because the memoryview API is similar but not exactly the same as that of buffer.
- callable
- Converts callable(x) to isinstance(x, collections.Callable), adding an import to collections if needed.
- dict
- Fixes dictionary iteration methods. dict.iteritems() is converted to dict.items(), dict.iterkeys() to dict.keys(), and dict.itervalues() to dict.values(). Similarly, dict.viewitems(), dict.viewkeys() and dict.viewvalues() are converted respectively to dict.items(), dict.keys() and dict.values(). It also wraps existing usages of dict.items(), dict.keys(), and dict.values() in a call to list.
- except
- Converts except X, T to except X as T.
- exec
- Converts the exec statement to the exec() function.
- execfile
- Removes usage of execfile(). The argument to execfile() is wrapped in calls to open(), compile(), and exec().
- exitfunc
- Changes assignment of sys.exitfunc to use of the atexit module.
- funcattrs
- Fixes function attributes that have been renamed. For example, my_function.func_closure is converted to my_function.__closure__.
- future
- Removes from __future__ import new_feature statements.
- getcwdu
- Renames os.getcwdu() to os.getcwd().
- has_key
- Changes dict.has_key(key) to key in dict.
- idioms
This optional fixer performs several transformations that make Python code more idiomatic. Type comparisons like type(x) is SomeClass and type(x) == SomeClass are converted to isinstance(x, SomeClass). while 1 becomes while True. This fixer also tries to make use of sorted() in appropriate places. For example, this block
L = list(some_iterable) L.sort()
is changed to
L = sorted(some_iterable)
- import
- Detects sibling imports and converts them to relative imports.
- imports
- Handles module renames in the standard library.
- imports2
- Handles other modules renames in the standard library. It is separate from the imports fixer only because of technical limitations.
- input
- Converts input(prompt) to eval(input(prompt))
- intern
- Converts intern() to sys.intern().
- isinstance
- Fixes duplicate types in the second argument of isinstance(). For example, isinstance(x, (int, int)) is converted to isinstance(x, (int)).
- itertools_imports
- Removes imports of itertools.ifilter(), itertools.izip(), and itertools.imap(). Imports of itertools.ifilterfalse() are also changed to itertools.filterfalse().
- itertools
- Changes usage of itertools.ifilter(), itertools.izip(), and itertools.imap() to their built-in equivalents. itertools.ifilterfalse() is changed to itertools.filterfalse().
- map
- Wraps map() in a list call. It also changes map(None, x) to list(x). Using from future_builtins import map disables this fixer.
- metaclass
- Converts the old metaclass syntax (__metaclass__ = Meta in the class body) to the new (class X(metaclass=Meta)).
- methodattrs
- Fixes old method attribute names. For example, meth.im_func is converted to meth.__func__.
- ne
- Converts the old not-equal syntax, <>, to !=.
- next
- Converts the use of iterator’s next() methods to the next() function. It also renames next() methods to __next__().
- nonzero
- Renames __nonzero__() to __bool__().
- numliterals
- Converts octal literals into the new syntax.
- paren
- Add extra parenthesis where they are required in list comprehensions. For example, [x for x in 1, 2] becomes [x for x in (1, 2)].
- raise
- Converts raise E, V to raise E(V), and raise E, V, T to raise E(V).with_traceback(T). If E is a tuple, the translation will be incorrect because substituting tuples for exceptions has been removed in 3.0.
- raw_input
- Converts raw_input() to input().
- reduce
- Handles the move of reduce() to functools.reduce().
- renames
- Changes sys.maxint to sys.maxsize.
- repr
- Replaces backtick repr with the repr() function.
- set_literal
- Replaces use of the set constructor with set literals. This fixer is optional.
- standard_error
- Renames StandardError to Exception.
- sys_exc
- Changes the deprecated sys.exc_value, sys.exc_type, sys.exc_traceback to use sys.exc_info().
- throw
- Fixes the API change in generator’s throw() method.
- tuple_params
- Removes implicit tuple parameter unpacking. This fixer inserts temporary variables.
- types
- Fixes code broken from the removal of some members in the types module.
- ws_comma
- Removes excess whitespace from comma separated items. This fixer is optional.
- xreadlines
- Changes for x in file.xreadlines() to for x in file.
25.4.3. lib2to3 - 2to3’s library
Note
The lib2to3 API should be considered unstable and may change drastically in the future.