merge.mergestate: perform all premerges before any merges (BC)
We perform all that we can non-interactively before prompting the user for input
via their merge tool. This allows for a maximally consistent state when the user
is first prompted.
The test output changes indicate the actual behavior change happening.
# encoding.py - character transcoding support for Mercurial
#
# Copyright 2005-2009 Matt Mackall <mpm@selenic.com> and others
#
# This software may be used and distributed according to the terms of the
# GNU General Public License version 2 or any later version.
import error
import unicodedata, locale, os
# These unicode characters are ignored by HFS+ (Apple Technote 1150,
# "Unicode Subtleties"), so we need to ignore them in some places for
# sanity.
_ignore = [unichr(int(x, 16)).encode("utf-8") for x in
"200c 200d 200e 200f 202a 202b 202c 202d 202e "
"206a 206b 206c 206d 206e 206f feff".split()]
# verify the next function will work
assert set([i[0] for i in _ignore]) == set(["\xe2", "\xef"])
def hfsignoreclean(s):
"""Remove codepoints ignored by HFS+ from s.
>>> hfsignoreclean(u'.h\u200cg'.encode('utf-8'))
'.hg'
>>> hfsignoreclean(u'.h\ufeffg'.encode('utf-8'))
'.hg'
"""
if "\xe2" in s or "\xef" in s:
for c in _ignore:
s = s.replace(c, '')
return s
def _getpreferredencoding():
'''
On darwin, getpreferredencoding ignores the locale environment and
always returns mac-roman. http://bugs.python.org/issue6202 fixes this
for Python 2.7 and up. This is the same corrected code for earlier
Python versions.
However, we can't use a version check for this method, as some distributions
patch Python to fix this. Instead, we use it as a 'fixer' for the mac-roman
encoding, as it is unlikely that this encoding is the actually expected.
'''
try:
locale.CODESET
except AttributeError:
# Fall back to parsing environment variables :-(
return locale.getdefaultlocale()[1]
oldloc = locale.setlocale(locale.LC_CTYPE)
locale.setlocale(locale.LC_CTYPE, "")
result = locale.nl_langinfo(locale.CODESET)
locale.setlocale(locale.LC_CTYPE, oldloc)
return result
_encodingfixers = {
'646': lambda: 'ascii',
'ANSI_X3.4-1968': lambda: 'ascii',
'mac-roman': _getpreferredencoding
}
try:
encoding = os.environ.get("HGENCODING")
if not encoding:
encoding = locale.getpreferredencoding() or 'ascii'
encoding = _encodingfixers.get(encoding, lambda: encoding)()
except locale.Error:
encoding = 'ascii'
encodingmode = os.environ.get("HGENCODINGMODE", "strict")
fallbackencoding = 'ISO-8859-1'
class localstr(str):
'''This class allows strings that are unmodified to be
round-tripped to the local encoding and back'''
def __new__(cls, u, l):
s = str.__new__(cls, l)
s._utf8 = u
return s
def __hash__(self):
return hash(self._utf8) # avoid collisions in local string space
def tolocal(s):
"""
Convert a string from internal UTF-8 to local encoding
All internal strings should be UTF-8 but some repos before the
implementation of locale support may contain latin1 or possibly
other character sets. We attempt to decode everything strictly
using UTF-8, then Latin-1, and failing that, we use UTF-8 and
replace unknown characters.
The localstr class is used to cache the known UTF-8 encoding of
strings next to their local representation to allow lossless
round-trip conversion back to UTF-8.
>>> u = 'foo: \\xc3\\xa4' # utf-8
>>> l = tolocal(u)
>>> l
'foo: ?'
>>> fromlocal(l)
'foo: \\xc3\\xa4'
>>> u2 = 'foo: \\xc3\\xa1'
>>> d = { l: 1, tolocal(u2): 2 }
>>> len(d) # no collision
2
>>> 'foo: ?' in d
False
>>> l1 = 'foo: \\xe4' # historical latin1 fallback
>>> l = tolocal(l1)
>>> l
'foo: ?'
>>> fromlocal(l) # magically in utf-8
'foo: \\xc3\\xa4'
"""
try:
try:
# make sure string is actually stored in UTF-8
u = s.decode('UTF-8')
if encoding == 'UTF-8':
# fast path
return s
r = u.encode(encoding, "replace")
if u == r.decode(encoding):
# r is a safe, non-lossy encoding of s
return r
return localstr(s, r)
except UnicodeDecodeError:
# we should only get here if we're looking at an ancient changeset
try:
u = s.decode(fallbackencoding)
r = u.encode(encoding, "replace")
if u == r.decode(encoding):
# r is a safe, non-lossy encoding of s
return r
return localstr(u.encode('UTF-8'), r)
except UnicodeDecodeError:
u = s.decode("utf-8", "replace") # last ditch
return u.encode(encoding, "replace") # can't round-trip
except LookupError as k:
raise error.Abort(k, hint="please check your locale settings")
def fromlocal(s):
"""
Convert a string from the local character encoding to UTF-8
We attempt to decode strings using the encoding mode set by
HGENCODINGMODE, which defaults to 'strict'. In this mode, unknown
characters will cause an error message. Other modes include
'replace', which replaces unknown characters with a special
Unicode character, and 'ignore', which drops the character.
"""
# can we do a lossless round-trip?
if isinstance(s, localstr):
return s._utf8
try:
return s.decode(encoding, encodingmode).encode("utf-8")
except UnicodeDecodeError as inst:
sub = s[max(0, inst.start - 10):inst.start + 10]
raise error.Abort("decoding near '%s': %s!" % (sub, inst))
except LookupError as k:
raise error.Abort(k, hint="please check your locale settings")
# How to treat ambiguous-width characters. Set to 'wide' to treat as wide.
wide = (os.environ.get("HGENCODINGAMBIGUOUS", "narrow") == "wide"
and "WFA" or "WF")
def colwidth(s):
"Find the column width of a string for display in the local encoding"
return ucolwidth(s.decode(encoding, 'replace'))
def ucolwidth(d):
"Find the column width of a Unicode string for display"
eaw = getattr(unicodedata, 'east_asian_width', None)
if eaw is not None:
return sum([eaw(c) in wide and 2 or 1 for c in d])
return len(d)
def getcols(s, start, c):
'''Use colwidth to find a c-column substring of s starting at byte
index start'''
for x in xrange(start + c, len(s)):
t = s[start:x]
if colwidth(t) == c:
return t
def trim(s, width, ellipsis='', leftside=False):
"""Trim string 's' to at most 'width' columns (including 'ellipsis').
If 'leftside' is True, left side of string 's' is trimmed.
'ellipsis' is always placed at trimmed side.
>>> ellipsis = '+++'
>>> from mercurial import encoding
>>> encoding.encoding = 'utf-8'
>>> t= '1234567890'
>>> print trim(t, 12, ellipsis=ellipsis)
1234567890
>>> print trim(t, 10, ellipsis=ellipsis)
1234567890
>>> print trim(t, 8, ellipsis=ellipsis)
12345+++
>>> print trim(t, 8, ellipsis=ellipsis, leftside=True)
+++67890
>>> print trim(t, 8)
12345678
>>> print trim(t, 8, leftside=True)
34567890
>>> print trim(t, 3, ellipsis=ellipsis)
+++
>>> print trim(t, 1, ellipsis=ellipsis)
+
>>> u = u'\u3042\u3044\u3046\u3048\u304a' # 2 x 5 = 10 columns
>>> t = u.encode(encoding.encoding)
>>> print trim(t, 12, ellipsis=ellipsis)
\xe3\x81\x82\xe3\x81\x84\xe3\x81\x86\xe3\x81\x88\xe3\x81\x8a
>>> print trim(t, 10, ellipsis=ellipsis)
\xe3\x81\x82\xe3\x81\x84\xe3\x81\x86\xe3\x81\x88\xe3\x81\x8a
>>> print trim(t, 8, ellipsis=ellipsis)
\xe3\x81\x82\xe3\x81\x84+++
>>> print trim(t, 8, ellipsis=ellipsis, leftside=True)
+++\xe3\x81\x88\xe3\x81\x8a
>>> print trim(t, 5)
\xe3\x81\x82\xe3\x81\x84
>>> print trim(t, 5, leftside=True)
\xe3\x81\x88\xe3\x81\x8a
>>> print trim(t, 4, ellipsis=ellipsis)
+++
>>> print trim(t, 4, ellipsis=ellipsis, leftside=True)
+++
>>> t = '\x11\x22\x33\x44\x55\x66\x77\x88\x99\xaa' # invalid byte sequence
>>> print trim(t, 12, ellipsis=ellipsis)
\x11\x22\x33\x44\x55\x66\x77\x88\x99\xaa
>>> print trim(t, 10, ellipsis=ellipsis)
\x11\x22\x33\x44\x55\x66\x77\x88\x99\xaa
>>> print trim(t, 8, ellipsis=ellipsis)
\x11\x22\x33\x44\x55+++
>>> print trim(t, 8, ellipsis=ellipsis, leftside=True)
+++\x66\x77\x88\x99\xaa
>>> print trim(t, 8)
\x11\x22\x33\x44\x55\x66\x77\x88
>>> print trim(t, 8, leftside=True)
\x33\x44\x55\x66\x77\x88\x99\xaa
>>> print trim(t, 3, ellipsis=ellipsis)
+++
>>> print trim(t, 1, ellipsis=ellipsis)
+
"""
try:
u = s.decode(encoding)
except UnicodeDecodeError:
if len(s) <= width: # trimming is not needed
return s
width -= len(ellipsis)
if width <= 0: # no enough room even for ellipsis
return ellipsis[:width + len(ellipsis)]
if leftside:
return ellipsis + s[-width:]
return s[:width] + ellipsis
if ucolwidth(u) <= width: # trimming is not needed
return s
width -= len(ellipsis)
if width <= 0: # no enough room even for ellipsis
return ellipsis[:width + len(ellipsis)]
if leftside:
uslice = lambda i: u[i:]
concat = lambda s: ellipsis + s
else:
uslice = lambda i: u[:-i]
concat = lambda s: s + ellipsis
for i in xrange(1, len(u)):
usub = uslice(i)
if ucolwidth(usub) <= width:
return concat(usub.encode(encoding))
return ellipsis # no enough room for multi-column characters
def _asciilower(s):
'''convert a string to lowercase if ASCII
Raises UnicodeDecodeError if non-ASCII characters are found.'''
s.decode('ascii')
return s.lower()
def asciilower(s):
# delay importing avoids cyclic dependency around "parsers" in
# pure Python build (util => i18n => encoding => parsers => util)
import parsers
impl = getattr(parsers, 'asciilower', _asciilower)
global asciilower
asciilower = impl
return impl(s)
def _asciiupper(s):
'''convert a string to uppercase if ASCII
Raises UnicodeDecodeError if non-ASCII characters are found.'''
s.decode('ascii')
return s.upper()
def asciiupper(s):
# delay importing avoids cyclic dependency around "parsers" in
# pure Python build (util => i18n => encoding => parsers => util)
import parsers
impl = getattr(parsers, 'asciiupper', _asciiupper)
global asciiupper
asciiupper = impl
return impl(s)
def lower(s):
"best-effort encoding-aware case-folding of local string s"
try:
return asciilower(s)
except UnicodeDecodeError:
pass
try:
if isinstance(s, localstr):
u = s._utf8.decode("utf-8")
else:
u = s.decode(encoding, encodingmode)
lu = u.lower()
if u == lu:
return s # preserve localstring
return lu.encode(encoding)
except UnicodeError:
return s.lower() # we don't know how to fold this except in ASCII
except LookupError as k:
raise error.Abort(k, hint="please check your locale settings")
def upper(s):
"best-effort encoding-aware case-folding of local string s"
try:
return asciiupper(s)
except UnicodeDecodeError:
return upperfallback(s)
def upperfallback(s):
try:
if isinstance(s, localstr):
u = s._utf8.decode("utf-8")
else:
u = s.decode(encoding, encodingmode)
uu = u.upper()
if u == uu:
return s # preserve localstring
return uu.encode(encoding)
except UnicodeError:
return s.upper() # we don't know how to fold this except in ASCII
except LookupError as k:
raise error.Abort(k, hint="please check your locale settings")
class normcasespecs(object):
'''what a platform's normcase does to ASCII strings
This is specified per platform, and should be consistent with what normcase
on that platform actually does.
lower: normcase lowercases ASCII strings
upper: normcase uppercases ASCII strings
other: the fallback function should always be called
This should be kept in sync with normcase_spec in util.h.'''
lower = -1
upper = 1
other = 0
_jsonmap = {}
def jsonescape(s):
'''returns a string suitable for JSON
JSON is problematic for us because it doesn't support non-Unicode
bytes. To deal with this, we take the following approach:
- localstr objects are converted back to UTF-8
- valid UTF-8/ASCII strings are passed as-is
- other strings are converted to UTF-8b surrogate encoding
- apply JSON-specified string escaping
(escapes are doubled in these tests)
>>> jsonescape('this is a test')
'this is a test'
>>> jsonescape('escape characters: \\0 \\x0b \\t \\n \\r \\" \\\\')
'escape characters: \\\\u0000 \\\\u000b \\\\t \\\\n \\\\r \\\\" \\\\\\\\'
>>> jsonescape('a weird byte: \\xdd')
'a weird byte: \\xed\\xb3\\x9d'
>>> jsonescape('utf-8: caf\\xc3\\xa9')
'utf-8: caf\\xc3\\xa9'
>>> jsonescape('')
''
'''
if not _jsonmap:
for x in xrange(32):
_jsonmap[chr(x)] = "\u%04x" %x
for x in xrange(32, 256):
c = chr(x)
_jsonmap[c] = c
_jsonmap['\t'] = '\\t'
_jsonmap['\n'] = '\\n'
_jsonmap['\"'] = '\\"'
_jsonmap['\\'] = '\\\\'
_jsonmap['\b'] = '\\b'
_jsonmap['\f'] = '\\f'
_jsonmap['\r'] = '\\r'
return ''.join(_jsonmap[c] for c in toutf8b(s))
def toutf8b(s):
'''convert a local, possibly-binary string into UTF-8b
This is intended as a generic method to preserve data when working
with schemes like JSON and XML that have no provision for
arbitrary byte strings. As Mercurial often doesn't know
what encoding data is in, we use so-called UTF-8b.
If a string is already valid UTF-8 (or ASCII), it passes unmodified.
Otherwise, unsupported bytes are mapped to UTF-16 surrogate range,
uDC00-uDCFF.
Principles of operation:
- ASCII and UTF-8 data successfully round-trips and is understood
by Unicode-oriented clients
- filenames and file contents in arbitrary other encodings can have
be round-tripped or recovered by clueful clients
- local strings that have a cached known UTF-8 encoding (aka
localstr) get sent as UTF-8 so Unicode-oriented clients get the
Unicode data they want
- because we must preserve UTF-8 bytestring in places such as
filenames, metadata can't be roundtripped without help
(Note: "UTF-8b" often refers to decoding a mix of valid UTF-8 and
arbitrary bytes into an internal Unicode format that can be
re-encoded back into the original. Here we are exposing the
internal surrogate encoding as a UTF-8 string.)
'''
if isinstance(s, localstr):
return s._utf8
try:
s.decode('utf-8')
return s
except UnicodeDecodeError:
# surrogate-encode any characters that don't round-trip
s2 = s.decode('utf-8', 'ignore').encode('utf-8')
r = ""
pos = 0
for c in s:
if s2[pos:pos + 1] == c:
r += c
pos += 1
else:
r += unichr(0xdc00 + ord(c)).encode('utf-8')
return r
def fromutf8b(s):
'''Given a UTF-8b string, return a local, possibly-binary string.
return the original binary string. This
is a round-trip process for strings like filenames, but metadata
that's was passed through tolocal will remain in UTF-8.
>>> m = "\\xc3\\xa9\\x99abcd"
>>> n = toutf8b(m)
>>> n
'\\xc3\\xa9\\xed\\xb2\\x99abcd'
>>> fromutf8b(n) == m
True
'''
# fast path - look for uDxxx prefixes in s
if "\xed" not in s:
return s
u = s.decode("utf-8")
r = ""
for c in u:
if ord(c) & 0xff00 == 0xdc00:
r += chr(ord(c) & 0xff)
else:
r += c.encode("utf-8")
return r