view mercurial/manifest.py @ 23848:c5456b64eb07

discovery: run discovery on filtered repository We have been running discovery on unfiltered repository for quite some time. This was aimed at two things: - save some bandwith by prevent the repushing of common but hidden changesets - allow phases changes on secret/hidden changeset on bare push. The cost of this unfiltered discovery combined with evolution is actually really high. Evolution likely create thousand of hidden heads, and the discovery is going to try to discovery if each of them are common or not. For example, pushing from my development mercurial repository implies 17 discovery round-trip. The benefit are rare corner cases while the drawback are massive. So we run the discovery on a filtered repository again. We add some hack to detect remote heads that are known locally and adds them to the common set anyway, so the good behavior of most of the corner case should remains. But this will not work in all cases. This bring my discovery phase back from 17 round-trips to 1 or 2.
author Pierre-Yves David <pierre-yves.david@fb.com>
date Wed, 07 Jan 2015 00:07:29 -0800
parents 399a8403cb54
children ed5e8a9598ce
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# manifest.py - manifest revision class for mercurial
#
# Copyright 2005-2007 Matt Mackall <mpm@selenic.com>
#
# This software may be used and distributed according to the terms of the
# GNU General Public License version 2 or any later version.

from i18n import _
import mdiff, parsers, error, revlog, util
import array, struct

class manifestdict(dict):
    def __init__(self, mapping=None, flags=None):
        if mapping is None:
            mapping = {}
        if flags is None:
            flags = {}
        dict.__init__(self, mapping)
        self._flags = flags
    def __setitem__(self, k, v):
        assert v is not None
        dict.__setitem__(self, k, v)
    def flags(self, f):
        return self._flags.get(f, "")
    def setflag(self, f, flags):
        """Set the flags (symlink, executable) for path f."""
        self._flags[f] = flags
    def copy(self):
        return manifestdict(self, dict.copy(self._flags))
    def intersectfiles(self, files):
        '''make a new manifestdict with the intersection of self with files

        The algorithm assumes that files is much smaller than self.'''
        ret = manifestdict()
        for fn in files:
            if fn in self:
                ret[fn] = self[fn]
                flags = self._flags.get(fn, None)
                if flags:
                    ret._flags[fn] = flags
        return ret

    def matches(self, match):
        '''generate a new manifest filtered by the match argument'''
        if match.always():
            return self.copy()

        files = match.files()
        if (match.matchfn == match.exact or
            (not match.anypats() and util.all(fn in self for fn in files))):
            return self.intersectfiles(files)

        mf = self.copy()
        for fn in mf.keys():
            if not match(fn):
                del mf[fn]
        return mf

    def diff(self, m2, clean=False):
        '''Finds changes between the current manifest and m2.

        Args:
          m2: the manifest to which this manifest should be compared.
          clean: if true, include files unchanged between these manifests
                 with a None value in the returned dictionary.

        The result is returned as a dict with filename as key and
        values of the form ((n1,fl1),(n2,fl2)), where n1/n2 is the
        nodeid in the current/other manifest and fl1/fl2 is the flag
        in the current/other manifest. Where the file does not exist,
        the nodeid will be None and the flags will be the empty
        string.
        '''
        diff = {}

        for fn, n1 in self.iteritems():
            fl1 = self._flags.get(fn, '')
            n2 = m2.get(fn, None)
            fl2 = m2._flags.get(fn, '')
            if n2 is None:
                fl2 = ''
            if n1 != n2 or fl1 != fl2:
                diff[fn] = ((n1, fl1), (n2, fl2))
            elif clean:
                diff[fn] = None

        for fn, n2 in m2.iteritems():
            if fn not in self:
                fl2 = m2._flags.get(fn, '')
                diff[fn] = ((None, ''), (n2, fl2))

        return diff

    def text(self):
        """Get the full data of this manifest as a bytestring."""
        fl = sorted(self)
        _checkforbidden(fl)

        hex, flags = revlog.hex, self.flags
        # if this is changed to support newlines in filenames,
        # be sure to check the templates/ dir again (especially *-raw.tmpl)
        return ''.join("%s\0%s%s\n" % (f, hex(self[f]), flags(f)) for f in fl)

    def fastdelta(self, base, changes):
        """Given a base manifest text as an array.array and a list of changes
        relative to that text, compute a delta that can be used by revlog.
        """
        delta = []
        dstart = None
        dend = None
        dline = [""]
        start = 0
        # zero copy representation of base as a buffer
        addbuf = util.buffer(base)

        # start with a readonly loop that finds the offset of
        # each line and creates the deltas
        for f, todelete in changes:
            # bs will either be the index of the item or the insert point
            start, end = _msearch(addbuf, f, start)
            if not todelete:
                l = "%s\0%s%s\n" % (f, revlog.hex(self[f]), self.flags(f))
            else:
                if start == end:
                    # item we want to delete was not found, error out
                    raise AssertionError(
                            _("failed to remove %s from manifest") % f)
                l = ""
            if dstart is not None and dstart <= start and dend >= start:
                if dend < end:
                    dend = end
                if l:
                    dline.append(l)
            else:
                if dstart is not None:
                    delta.append([dstart, dend, "".join(dline)])
                dstart = start
                dend = end
                dline = [l]

        if dstart is not None:
            delta.append([dstart, dend, "".join(dline)])
        # apply the delta to the base, and get a delta for addrevision
        deltatext, arraytext = _addlistdelta(base, delta)
        return arraytext, deltatext

def _msearch(m, s, lo=0, hi=None):
    '''return a tuple (start, end) that says where to find s within m.

    If the string is found m[start:end] are the line containing
    that string.  If start == end the string was not found and
    they indicate the proper sorted insertion point.

    m should be a buffer or a string
    s is a string'''
    def advance(i, c):
        while i < lenm and m[i] != c:
            i += 1
        return i
    if not s:
        return (lo, lo)
    lenm = len(m)
    if not hi:
        hi = lenm
    while lo < hi:
        mid = (lo + hi) // 2
        start = mid
        while start > 0 and m[start - 1] != '\n':
            start -= 1
        end = advance(start, '\0')
        if m[start:end] < s:
            # we know that after the null there are 40 bytes of sha1
            # this translates to the bisect lo = mid + 1
            lo = advance(end + 40, '\n') + 1
        else:
            # this translates to the bisect hi = mid
            hi = start
    end = advance(lo, '\0')
    found = m[lo:end]
    if s == found:
        # we know that after the null there are 40 bytes of sha1
        end = advance(end + 40, '\n')
        return (lo, end + 1)
    else:
        return (lo, lo)

def _checkforbidden(l):
    """Check filenames for illegal characters."""
    for f in l:
        if '\n' in f or '\r' in f:
            raise error.RevlogError(
                _("'\\n' and '\\r' disallowed in filenames: %r") % f)


# apply the changes collected during the bisect loop to our addlist
# return a delta suitable for addrevision
def _addlistdelta(addlist, x):
    # for large addlist arrays, building a new array is cheaper
    # than repeatedly modifying the existing one
    currentposition = 0
    newaddlist = array.array('c')

    for start, end, content in x:
        newaddlist += addlist[currentposition:start]
        if content:
            newaddlist += array.array('c', content)

        currentposition = end

    newaddlist += addlist[currentposition:]

    deltatext = "".join(struct.pack(">lll", start, end, len(content))
                   + content for start, end, content in x)
    return deltatext, newaddlist

def _parse(lines):
    mfdict = manifestdict()
    parsers.parse_manifest(mfdict, mfdict._flags, lines)
    return mfdict

class manifest(revlog.revlog):
    def __init__(self, opener):
        # we expect to deal with not more than four revs at a time,
        # during a commit --amend
        self._mancache = util.lrucachedict(4)
        revlog.revlog.__init__(self, opener, "00manifest.i")

    def readdelta(self, node):
        r = self.rev(node)
        return _parse(mdiff.patchtext(self.revdiff(self.deltaparent(r), r)))

    def readfast(self, node):
        '''use the faster of readdelta or read'''
        r = self.rev(node)
        deltaparent = self.deltaparent(r)
        if deltaparent != revlog.nullrev and deltaparent in self.parentrevs(r):
            return self.readdelta(node)
        return self.read(node)

    def read(self, node):
        if node == revlog.nullid:
            return manifestdict() # don't upset local cache
        if node in self._mancache:
            return self._mancache[node][0]
        text = self.revision(node)
        arraytext = array.array('c', text)
        mapping = _parse(text)
        self._mancache[node] = (mapping, arraytext)
        return mapping

    def find(self, node, f):
        '''look up entry for a single file efficiently.
        return (node, flags) pair if found, (None, None) if not.'''
        if node in self._mancache:
            mapping = self._mancache[node][0]
            return mapping.get(f), mapping.flags(f)
        text = self.revision(node)
        start, end = _msearch(text, f)
        if start == end:
            return None, None
        l = text[start:end]
        f, n = l.split('\0')
        return revlog.bin(n[:40]), n[40:-1]

    def add(self, map, transaction, link, p1, p2, added, removed):
        if p1 in self._mancache:
            # If our first parent is in the manifest cache, we can
            # compute a delta here using properties we know about the
            # manifest up-front, which may save time later for the
            # revlog layer.

            _checkforbidden(added)
            # combine the changed lists into one list for sorting
            work = [(x, False) for x in added]
            work.extend((x, True) for x in removed)
            # this could use heapq.merge() (from Python 2.6+) or equivalent
            # since the lists are already sorted
            work.sort()

            arraytext, deltatext = map.fastdelta(self._mancache[p1][1], work)
            cachedelta = self.rev(p1), deltatext
            text = util.buffer(arraytext)
        else:
            # The first parent manifest isn't already loaded, so we'll
            # just encode a fulltext of the manifest and pass that
            # through to the revlog layer, and let it handle the delta
            # process.
            text = map.text()
            arraytext = array.array('c', text)
            cachedelta = None

        n = self.addrevision(text, transaction, link, p1, p2, cachedelta)
        self._mancache[n] = (map, arraytext)

        return n