##// END OF EJS Templates
upgrade: move descriptions and selection logic in individual classes...
upgrade: move descriptions and selection logic in individual classes Our goal here is to get top level definition for all the format variants. Having them defined outside of the function enabled other users of that logic. They are two keys components of a format variant: 1) the name and various descriptions of its effect, 2) the code that checks if the repo is using this variant and if the config enables it. That second items make us pick a class-based approach, since different variants requires different code (even if in practice, many can reuse the same logic). Each variants define its own class that is then used like a singleton. The class-based approach also clarify the definitions part a bit since each are simple assignment in an indented block. The 'fromdefault' and 'fromconfig' are respectively replaced by a class attribute and a method to be called at the one place where "fromconfig" matters. Overall, they are many viable approach for this, but this is the one I picked.

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pycompat.py
412 lines | 12.2 KiB | text/x-python | PythonLexer
# pycompat.py - portability shim for python 3
#
# This software may be used and distributed according to the terms of the
# GNU General Public License version 2 or any later version.
"""Mercurial portability shim for python 3.
This contains aliases to hide python version-specific details from the core.
"""
from __future__ import absolute_import
import getopt
import os
import shlex
import sys
ispy3 = (sys.version_info[0] >= 3)
if not ispy3:
import cookielib
import cPickle as pickle
import httplib
import Queue as _queue
import SocketServer as socketserver
import xmlrpclib
else:
import http.cookiejar as cookielib
import http.client as httplib
import pickle
import queue as _queue
import socketserver
import xmlrpc.client as xmlrpclib
def identity(a):
return a
if ispy3:
import builtins
import functools
import io
import struct
fsencode = os.fsencode
fsdecode = os.fsdecode
# A bytes version of os.name.
oslinesep = os.linesep.encode('ascii')
osname = os.name.encode('ascii')
ospathsep = os.pathsep.encode('ascii')
ossep = os.sep.encode('ascii')
osaltsep = os.altsep
if osaltsep:
osaltsep = osaltsep.encode('ascii')
# os.getcwd() on Python 3 returns string, but it has os.getcwdb() which
# returns bytes.
getcwd = os.getcwdb
sysplatform = sys.platform.encode('ascii')
sysexecutable = sys.executable
if sysexecutable:
sysexecutable = os.fsencode(sysexecutable)
stringio = io.BytesIO
maplist = lambda *args: list(map(*args))
# TODO: .buffer might not exist if std streams were replaced; we'll need
# a silly wrapper to make a bytes stream backed by a unicode one.
stdin = sys.stdin.buffer
stdout = sys.stdout.buffer
stderr = sys.stderr.buffer
# Since Python 3 converts argv to wchar_t type by Py_DecodeLocale() on Unix,
# we can use os.fsencode() to get back bytes argv.
#
# https://hg.python.org/cpython/file/v3.5.1/Programs/python.c#l55
#
# TODO: On Windows, the native argv is wchar_t, so we'll need a different
# workaround to simulate the Python 2 (i.e. ANSI Win32 API) behavior.
if getattr(sys, 'argv', None) is not None:
sysargv = list(map(os.fsencode, sys.argv))
bytechr = struct.Struct('>B').pack
class bytestr(bytes):
"""A bytes which mostly acts as a Python 2 str
>>> bytestr(), bytestr(bytearray(b'foo')), bytestr(u'ascii'), bytestr(1)
(b'', b'foo', b'ascii', b'1')
>>> s = bytestr(b'foo')
>>> assert s is bytestr(s)
There's no implicit conversion from non-ascii str as its encoding is
unknown:
>>> bytestr(chr(0x80)) # doctest: +ELLIPSIS
Traceback (most recent call last):
...
UnicodeEncodeError: ...
Comparison between bytestr and bytes should work:
>>> assert bytestr(b'foo') == b'foo'
>>> assert b'foo' == bytestr(b'foo')
>>> assert b'f' in bytestr(b'foo')
>>> assert bytestr(b'f') in b'foo'
Sliced elements should be bytes, not integer:
>>> s[1], s[:2]
(b'o', b'fo')
>>> list(s), list(reversed(s))
([b'f', b'o', b'o'], [b'o', b'o', b'f'])
As bytestr type isn't propagated across operations, you need to cast
bytes to bytestr explicitly:
>>> s = bytestr(b'foo').upper()
>>> t = bytestr(s)
>>> s[0], t[0]
(70, b'F')
Be careful to not pass a bytestr object to a function which expects
bytearray-like behavior.
>>> t = bytes(t) # cast to bytes
>>> assert type(t) is bytes
"""
def __new__(cls, s=b''):
if isinstance(s, bytestr):
return s
if not isinstance(s, (bytes, bytearray)):
s = str(s).encode(u'ascii')
return bytes.__new__(cls, s)
def __getitem__(self, key):
s = bytes.__getitem__(self, key)
if not isinstance(s, bytes):
s = bytechr(s)
return s
def __iter__(self):
return iterbytestr(bytes.__iter__(self))
def iterbytestr(s):
"""Iterate bytes as if it were a str object of Python 2"""
return map(bytechr, s)
def sysbytes(s):
"""Convert an internal str (e.g. keyword, __doc__) back to bytes
This never raises UnicodeEncodeError, but only ASCII characters
can be round-trip by sysstr(sysbytes(s)).
"""
return s.encode(u'utf-8')
def sysstr(s):
"""Return a keyword str to be passed to Python functions such as
getattr() and str.encode()
This never raises UnicodeDecodeError. Non-ascii characters are
considered invalid and mapped to arbitrary but unique code points
such that 'sysstr(a) != sysstr(b)' for all 'a != b'.
"""
if isinstance(s, builtins.str):
return s
return s.decode(u'latin-1')
def _wrapattrfunc(f):
@functools.wraps(f)
def w(object, name, *args):
return f(object, sysstr(name), *args)
return w
# these wrappers are automagically imported by hgloader
delattr = _wrapattrfunc(builtins.delattr)
getattr = _wrapattrfunc(builtins.getattr)
hasattr = _wrapattrfunc(builtins.hasattr)
setattr = _wrapattrfunc(builtins.setattr)
xrange = builtins.range
unicode = str
def open(name, mode='r', buffering=-1):
return builtins.open(name, sysstr(mode), buffering)
# getopt.getopt() on Python 3 deals with unicodes internally so we cannot
# pass bytes there. Passing unicodes will result in unicodes as return
# values which we need to convert again to bytes.
def getoptb(args, shortlist, namelist):
args = [a.decode('latin-1') for a in args]
shortlist = shortlist.decode('latin-1')
namelist = [a.decode('latin-1') for a in namelist]
opts, args = getopt.getopt(args, shortlist, namelist)
opts = [(a[0].encode('latin-1'), a[1].encode('latin-1'))
for a in opts]
args = [a.encode('latin-1') for a in args]
return opts, args
# keys of keyword arguments in Python need to be strings which are unicodes
# Python 3. This function takes keyword arguments, convert the keys to str.
def strkwargs(dic):
dic = dict((k.decode('latin-1'), v) for k, v in dic.iteritems())
return dic
# keys of keyword arguments need to be unicode while passing into
# a function. This function helps us to convert those keys back to bytes
# again as we need to deal with bytes.
def byteskwargs(dic):
dic = dict((k.encode('latin-1'), v) for k, v in dic.iteritems())
return dic
# shlex.split() accepts unicodes on Python 3. This function takes bytes
# argument, convert it into unicodes, pass into shlex.split(), convert the
# returned value to bytes and return that.
# TODO: handle shlex.shlex().
def shlexsplit(s):
ret = shlex.split(s.decode('latin-1'))
return [a.encode('latin-1') for a in ret]
else:
import cStringIO
bytechr = chr
bytestr = str
iterbytestr = iter
sysbytes = identity
sysstr = identity
# Partial backport from os.py in Python 3, which only accepts bytes.
# In Python 2, our paths should only ever be bytes, a unicode path
# indicates a bug.
def fsencode(filename):
if isinstance(filename, str):
return filename
else:
raise TypeError(
"expect str, not %s" % type(filename).__name__)
# In Python 2, fsdecode() has a very chance to receive bytes. So it's
# better not to touch Python 2 part as it's already working fine.
fsdecode = identity
def getoptb(args, shortlist, namelist):
return getopt.getopt(args, shortlist, namelist)
strkwargs = identity
byteskwargs = identity
oslinesep = os.linesep
osname = os.name
ospathsep = os.pathsep
ossep = os.sep
osaltsep = os.altsep
stdin = sys.stdin
stdout = sys.stdout
stderr = sys.stderr
if getattr(sys, 'argv', None) is not None:
sysargv = sys.argv
sysplatform = sys.platform
getcwd = os.getcwd
sysexecutable = sys.executable
shlexsplit = shlex.split
stringio = cStringIO.StringIO
maplist = map
empty = _queue.Empty
queue = _queue.Queue
class _pycompatstub(object):
def __init__(self):
self._aliases = {}
def _registeraliases(self, origin, items):
"""Add items that will be populated at the first access"""
items = map(sysstr, items)
self._aliases.update(
(item.replace(sysstr('_'), sysstr('')).lower(), (origin, item))
for item in items)
def _registeralias(self, origin, attr, name):
"""Alias ``origin``.``attr`` as ``name``"""
self._aliases[sysstr(name)] = (origin, sysstr(attr))
def __getattr__(self, name):
try:
origin, item = self._aliases[name]
except KeyError:
raise AttributeError(name)
self.__dict__[name] = obj = getattr(origin, item)
return obj
httpserver = _pycompatstub()
urlreq = _pycompatstub()
urlerr = _pycompatstub()
if not ispy3:
import BaseHTTPServer
import CGIHTTPServer
import SimpleHTTPServer
import urllib2
import urllib
import urlparse
urlreq._registeraliases(urllib, (
"addclosehook",
"addinfourl",
"ftpwrapper",
"pathname2url",
"quote",
"splitattr",
"splitpasswd",
"splitport",
"splituser",
"unquote",
"url2pathname",
"urlencode",
))
urlreq._registeraliases(urllib2, (
"AbstractHTTPHandler",
"BaseHandler",
"build_opener",
"FileHandler",
"FTPHandler",
"HTTPBasicAuthHandler",
"HTTPDigestAuthHandler",
"HTTPHandler",
"HTTPPasswordMgrWithDefaultRealm",
"HTTPSHandler",
"install_opener",
"ProxyHandler",
"Request",
"urlopen",
))
urlreq._registeraliases(urlparse, (
"urlparse",
"urlunparse",
))
urlerr._registeraliases(urllib2, (
"HTTPError",
"URLError",
))
httpserver._registeraliases(BaseHTTPServer, (
"HTTPServer",
"BaseHTTPRequestHandler",
))
httpserver._registeraliases(SimpleHTTPServer, (
"SimpleHTTPRequestHandler",
))
httpserver._registeraliases(CGIHTTPServer, (
"CGIHTTPRequestHandler",
))
else:
import urllib.parse
urlreq._registeraliases(urllib.parse, (
"splitattr",
"splitpasswd",
"splitport",
"splituser",
"urlparse",
"urlunparse",
))
urlreq._registeralias(urllib.parse, "unquote_to_bytes", "unquote")
import urllib.request
urlreq._registeraliases(urllib.request, (
"AbstractHTTPHandler",
"BaseHandler",
"build_opener",
"FileHandler",
"FTPHandler",
"ftpwrapper",
"HTTPHandler",
"HTTPSHandler",
"install_opener",
"pathname2url",
"HTTPBasicAuthHandler",
"HTTPDigestAuthHandler",
"HTTPPasswordMgrWithDefaultRealm",
"ProxyHandler",
"Request",
"url2pathname",
"urlopen",
))
import urllib.response
urlreq._registeraliases(urllib.response, (
"addclosehook",
"addinfourl",
))
import urllib.error
urlerr._registeraliases(urllib.error, (
"HTTPError",
"URLError",
))
import http.server
httpserver._registeraliases(http.server, (
"HTTPServer",
"BaseHTTPRequestHandler",
"SimpleHTTPRequestHandler",
"CGIHTTPRequestHandler",
))
# urllib.parse.quote() accepts both str and bytes, decodes bytes
# (if necessary), and returns str. This is wonky. We provide a custom
# implementation that only accepts bytes and emits bytes.
def quote(s, safe=r'/'):
s = urllib.parse.quote_from_bytes(s, safe=safe)
return s.encode('ascii', 'strict')
# urllib.parse.urlencode() returns str. We use this function to make
# sure we return bytes.
def urlencode(query, doseq=False):
s = urllib.parse.urlencode(query, doseq=doseq)
return s.encode('ascii')
urlreq.quote = quote
urlreq.urlencode = urlencode