narrow: only send the narrowspecs back if ACL in play
I am unable to think why we need to send narrowspecs back from the server. The
current state adds a 'narrow:spec' part to each changegroup which is generated
when narrow extension is enabled. So we are sending narrowspecs on pull also.
There is a problem with sending the narrowspecs the way we are doing it right
now. We add include and exclude as parameter of the 'narrow:spec' bundle2 part.
The the len of include or exclude string increase 255 which is obvious while
working on large repos, bundle2 generation code breaks. For more on that refer
issue5952 on bugzilla.
I was thinking why we need to send the narrowspecs back, and deleted the
'narrow:spec' bundle2 part generation code and found that only narrow-acl test
has some failure.
With this patch, we will only send the 'narrow:spec' bundle2 part if ACL is
enabled because the original narrowspecs in those cases can be a subset of
narrowspecs user requested.
There are phase related output change in couple of tests. The output change
shows that we are now dealing in public phases completely. So maybe sending the
narrow:spec bundle2 part was preventing phases being exchanged or phase bundle2
data being applied.
Differential Revision: https://phab.mercurial-scm.org/D4931
# parsers.py - Python implementation of parsers.c
#
# Copyright 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.
from __future__ import absolute_import
import struct
import zlib
from ..node import nullid
from .. import pycompat
stringio = pycompat.bytesio
_pack = struct.pack
_unpack = struct.unpack
_compress = zlib.compress
_decompress = zlib.decompress
# Some code below makes tuples directly because it's more convenient. However,
# code outside this module should always use dirstatetuple.
def dirstatetuple(*x):
# x is a tuple
return x
indexformatng = ">Qiiiiii20s12x"
indexfirst = struct.calcsize('Q')
sizeint = struct.calcsize('i')
indexsize = struct.calcsize(indexformatng)
def gettype(q):
return int(q & 0xFFFF)
def offset_type(offset, type):
return int(int(offset) << 16 | type)
class BaseIndexObject(object):
def __len__(self):
return self._lgt + len(self._extra)
def append(self, tup):
self._extra.append(tup)
def _check_index(self, i):
if not isinstance(i, int):
raise TypeError("expecting int indexes")
if i < 0 or i >= len(self):
raise IndexError
def __getitem__(self, i):
if i == -1:
return (0, 0, 0, -1, -1, -1, -1, nullid)
self._check_index(i)
if i >= self._lgt:
return self._extra[i - self._lgt]
index = self._calculate_index(i)
r = struct.unpack(indexformatng, self._data[index:index + indexsize])
if i == 0:
e = list(r)
type = gettype(e[0])
e[0] = offset_type(0, type)
return tuple(e)
return r
class IndexObject(BaseIndexObject):
def __init__(self, data):
assert len(data) % indexsize == 0
self._data = data
self._lgt = len(data) // indexsize
self._extra = []
def _calculate_index(self, i):
return i * indexsize
def __delitem__(self, i):
if not isinstance(i, slice) or not i.stop == -1 or i.step is not None:
raise ValueError("deleting slices only supports a:-1 with step 1")
i = i.start
self._check_index(i)
if i < self._lgt:
self._data = self._data[:i * indexsize]
self._lgt = i
self._extra = []
else:
self._extra = self._extra[:i - self._lgt]
class InlinedIndexObject(BaseIndexObject):
def __init__(self, data, inline=0):
self._data = data
self._lgt = self._inline_scan(None)
self._inline_scan(self._lgt)
self._extra = []
def _inline_scan(self, lgt):
off = 0
if lgt is not None:
self._offsets = [0] * lgt
count = 0
while off <= len(self._data) - indexsize:
s, = struct.unpack('>i',
self._data[off + indexfirst:off + sizeint + indexfirst])
if lgt is not None:
self._offsets[count] = off
count += 1
off += indexsize + s
if off != len(self._data):
raise ValueError("corrupted data")
return count
def __delitem__(self, i):
if not isinstance(i, slice) or not i.stop == -1 or i.step is not None:
raise ValueError("deleting slices only supports a:-1 with step 1")
i = i.start
self._check_index(i)
if i < self._lgt:
self._offsets = self._offsets[:i]
self._lgt = i
self._extra = []
else:
self._extra = self._extra[:i - self._lgt]
def _calculate_index(self, i):
return self._offsets[i]
def parse_index2(data, inline):
if not inline:
return IndexObject(data), None
return InlinedIndexObject(data, inline), (0, data)
def parse_dirstate(dmap, copymap, st):
parents = [st[:20], st[20: 40]]
# dereference fields so they will be local in loop
format = ">cllll"
e_size = struct.calcsize(format)
pos1 = 40
l = len(st)
# the inner loop
while pos1 < l:
pos2 = pos1 + e_size
e = _unpack(">cllll", st[pos1:pos2]) # a literal here is faster
pos1 = pos2 + e[4]
f = st[pos2:pos1]
if '\0' in f:
f, c = f.split('\0')
copymap[f] = c
dmap[f] = e[:4]
return parents
def pack_dirstate(dmap, copymap, pl, now):
now = int(now)
cs = stringio()
write = cs.write
write("".join(pl))
for f, e in dmap.iteritems():
if e[0] == 'n' and e[3] == now:
# The file was last modified "simultaneously" with the current
# write to dirstate (i.e. within the same second for file-
# systems with a granularity of 1 sec). This commonly happens
# for at least a couple of files on 'update'.
# The user could change the file without changing its size
# within the same second. Invalidate the file's mtime in
# dirstate, forcing future 'status' calls to compare the
# contents of the file if the size is the same. This prevents
# mistakenly treating such files as clean.
e = dirstatetuple(e[0], e[1], e[2], -1)
dmap[f] = e
if f in copymap:
f = "%s\0%s" % (f, copymap[f])
e = _pack(">cllll", e[0], e[1], e[2], e[3], len(f))
write(e)
write(f)
return cs.getvalue()