view mercurial/tags.py @ 27776:6fe2da48a6dd

bundlerepo: use context manager for file I/O in _writetempbundle
author Bryan O'Sullivan <bryano@fb.com>
date Tue, 12 Jan 2016 14:48:27 -0800
parents 8a256cee72c8
children a9dd92c48a1c
line wrap: on
line source

# tags.py - read tag info from local repository
#
# Copyright 2009 Matt Mackall <mpm@selenic.com>
# Copyright 2009 Greg Ward <greg@gerg.ca>
#
# This software may be used and distributed according to the terms of the
# GNU General Public License version 2 or any later version.

# Currently this module only deals with reading and caching tags.
# Eventually, it could take care of updating (adding/removing/moving)
# tags too.

from __future__ import absolute_import

import array
import errno
import time

from .i18n import _
from .node import (
    bin,
    hex,
    nullid,
    short,
)
from . import (
    encoding,
    error,
    util,
)

array = array.array

# Tags computation can be expensive and caches exist to make it fast in
# the common case.
#
# The "hgtagsfnodes1" cache file caches the .hgtags filenode values for
# each revision in the repository. The file is effectively an array of
# fixed length records. Read the docs for "hgtagsfnodescache" for technical
# details.
#
# The .hgtags filenode cache grows in proportion to the length of the
# changelog. The file is truncated when the # changelog is stripped.
#
# The purpose of the filenode cache is to avoid the most expensive part
# of finding global tags, which is looking up the .hgtags filenode in the
# manifest for each head. This can take dozens or over 100ms for
# repositories with very large manifests. Multiplied by dozens or even
# hundreds of heads and there is a significant performance concern.
#
# There also exist a separate cache file for each repository filter.
# These "tags-*" files store information about the history of tags.
#
# The tags cache files consists of a cache validation line followed by
# a history of tags.
#
# The cache validation line has the format:
#
#   <tiprev> <tipnode> [<filteredhash>]
#
# <tiprev> is an integer revision and <tipnode> is a 40 character hex
# node for that changeset. These redundantly identify the repository
# tip from the time the cache was written. In addition, <filteredhash>,
# if present, is a 40 character hex hash of the contents of the filtered
# revisions for this filter. If the set of filtered revs changes, the
# hash will change and invalidate the cache.
#
# The history part of the tags cache consists of lines of the form:
#
#   <node> <tag>
#
# (This format is identical to that of .hgtags files.)
#
# <tag> is the tag name and <node> is the 40 character hex changeset
# the tag is associated with.
#
# Tags are written sorted by tag name.
#
# Tags associated with multiple changesets have an entry for each changeset.
# The most recent changeset (in terms of revlog ordering for the head
# setting it) for each tag is last.

def findglobaltags(ui, repo, alltags, tagtypes):
    '''Find global tags in a repo.

    "alltags" maps tag name to (node, hist) 2-tuples.

    "tagtypes" maps tag name to tag type. Global tags always have the
    "global" tag type.

    The "alltags" and "tagtypes" dicts are updated in place. Empty dicts
    should be passed in.

    The tags cache is read and updated as a side-effect of calling.
    '''
    # This is so we can be lazy and assume alltags contains only global
    # tags when we pass it to _writetagcache().
    assert len(alltags) == len(tagtypes) == 0, \
           "findglobaltags() should be called first"

    (heads, tagfnode, valid, cachetags, shouldwrite) = _readtagcache(ui, repo)
    if cachetags is not None:
        assert not shouldwrite
        # XXX is this really 100% correct?  are there oddball special
        # cases where a global tag should outrank a local tag but won't,
        # because cachetags does not contain rank info?
        _updatetags(cachetags, 'global', alltags, tagtypes)
        return

    seen = set()  # set of fnode
    fctx = None
    for head in reversed(heads):  # oldest to newest
        assert head in repo.changelog.nodemap, \
               "tag cache returned bogus head %s" % short(head)

        fnode = tagfnode.get(head)
        if fnode and fnode not in seen:
            seen.add(fnode)
            if not fctx:
                fctx = repo.filectx('.hgtags', fileid=fnode)
            else:
                fctx = fctx.filectx(fnode)

            filetags = _readtags(ui, repo, fctx.data().splitlines(), fctx)
            _updatetags(filetags, 'global', alltags, tagtypes)

    # and update the cache (if necessary)
    if shouldwrite:
        _writetagcache(ui, repo, valid, alltags)

def readlocaltags(ui, repo, alltags, tagtypes):
    '''Read local tags in repo. Update alltags and tagtypes.'''
    try:
        data = repo.vfs.read("localtags")
    except IOError as inst:
        if inst.errno != errno.ENOENT:
            raise
        return

    # localtags is in the local encoding; re-encode to UTF-8 on
    # input for consistency with the rest of this module.
    filetags = _readtags(
        ui, repo, data.splitlines(), "localtags",
        recode=encoding.fromlocal)

    # remove tags pointing to invalid nodes
    cl = repo.changelog
    for t in filetags.keys():
        try:
            cl.rev(filetags[t][0])
        except (LookupError, ValueError):
            del filetags[t]

    _updatetags(filetags, "local", alltags, tagtypes)

def _readtaghist(ui, repo, lines, fn, recode=None, calcnodelines=False):
    '''Read tag definitions from a file (or any source of lines).

    This function returns two sortdicts with similar information:

    - the first dict, bintaghist, contains the tag information as expected by
      the _readtags function, i.e. a mapping from tag name to (node, hist):
        - node is the node id from the last line read for that name,
        - hist is the list of node ids previously associated with it (in file
          order). All node ids are binary, not hex.

    - the second dict, hextaglines, is a mapping from tag name to a list of
      [hexnode, line number] pairs, ordered from the oldest to the newest node.

    When calcnodelines is False the hextaglines dict is not calculated (an
    empty dict is returned). This is done to improve this function's
    performance in cases where the line numbers are not needed.
    '''

    bintaghist = util.sortdict()
    hextaglines = util.sortdict()
    count = 0

    def warn(msg):
        ui.warn(_("%s, line %s: %s\n") % (fn, count, msg))

    for nline, line in enumerate(lines):
        count += 1
        if not line:
            continue
        try:
            (nodehex, name) = line.split(" ", 1)
        except ValueError:
            warn(_("cannot parse entry"))
            continue
        name = name.strip()
        if recode:
            name = recode(name)
        try:
            nodebin = bin(nodehex)
        except TypeError:
            warn(_("node '%s' is not well formed") % nodehex)
            continue

        # update filetags
        if calcnodelines:
            # map tag name to a list of line numbers
            if name not in hextaglines:
                hextaglines[name] = []
            hextaglines[name].append([nodehex, nline])
            continue
        # map tag name to (node, hist)
        if name not in bintaghist:
            bintaghist[name] = []
        bintaghist[name].append(nodebin)
    return bintaghist, hextaglines

def _readtags(ui, repo, lines, fn, recode=None, calcnodelines=False):
    '''Read tag definitions from a file (or any source of lines).

    Returns a mapping from tag name to (node, hist).

    "node" is the node id from the last line read for that name. "hist"
    is the list of node ids previously associated with it (in file order).
    All node ids are binary, not hex.
    '''
    filetags, nodelines = _readtaghist(ui, repo, lines, fn, recode=recode,
                                       calcnodelines=calcnodelines)
    # util.sortdict().__setitem__ is much slower at replacing then inserting
    # new entries. The difference can matter if there are thousands of tags.
    # Create a new sortdict to avoid the performance penalty.
    newtags = util.sortdict()
    for tag, taghist in filetags.items():
        newtags[tag] = (taghist[-1], taghist[:-1])
    return newtags

def _updatetags(filetags, tagtype, alltags, tagtypes):
    '''Incorporate the tag info read from one file into the two
    dictionaries, alltags and tagtypes, that contain all tag
    info (global across all heads plus local).'''

    for name, nodehist in filetags.iteritems():
        if name not in alltags:
            alltags[name] = nodehist
            tagtypes[name] = tagtype
            continue

        # we prefer alltags[name] if:
        #  it supersedes us OR
        #  mutual supersedes and it has a higher rank
        # otherwise we win because we're tip-most
        anode, ahist = nodehist
        bnode, bhist = alltags[name]
        if (bnode != anode and anode in bhist and
            (bnode not in ahist or len(bhist) > len(ahist))):
            anode = bnode
        else:
            tagtypes[name] = tagtype
        ahist.extend([n for n in bhist if n not in ahist])
        alltags[name] = anode, ahist

def _filename(repo):
    """name of a tagcache file for a given repo or repoview"""
    filename = 'cache/tags2'
    if repo.filtername:
        filename = '%s-%s' % (filename, repo.filtername)
    return filename

def _readtagcache(ui, repo):
    '''Read the tag cache.

    Returns a tuple (heads, fnodes, validinfo, cachetags, shouldwrite).

    If the cache is completely up-to-date, "cachetags" is a dict of the
    form returned by _readtags() and "heads", "fnodes", and "validinfo" are
    None and "shouldwrite" is False.

    If the cache is not up to date, "cachetags" is None. "heads" is a list
    of all heads currently in the repository, ordered from tip to oldest.
    "validinfo" is a tuple describing cache validation info. This is used
    when writing the tags cache. "fnodes" is a mapping from head to .hgtags
    filenode. "shouldwrite" is True.

    If the cache is not up to date, the caller is responsible for reading tag
    info from each returned head. (See findglobaltags().)
    '''
    from . import scmutil  # avoid cycle

    try:
        cachefile = repo.vfs(_filename(repo), 'r')
        # force reading the file for static-http
        cachelines = iter(cachefile)
    except IOError:
        cachefile = None

    cacherev = None
    cachenode = None
    cachehash = None
    if cachefile:
        try:
            validline = cachelines.next()
            validline = validline.split()
            cacherev = int(validline[0])
            cachenode = bin(validline[1])
            if len(validline) > 2:
                cachehash = bin(validline[2])
        except Exception:
            # corruption of the cache, just recompute it.
            pass

    tipnode = repo.changelog.tip()
    tiprev = len(repo.changelog) - 1

    # Case 1 (common): tip is the same, so nothing has changed.
    # (Unchanged tip trivially means no changesets have been added.
    # But, thanks to localrepository.destroyed(), it also means none
    # have been destroyed by strip or rollback.)
    if (cacherev == tiprev
            and cachenode == tipnode
            and cachehash == scmutil.filteredhash(repo, tiprev)):
        tags = _readtags(ui, repo, cachelines, cachefile.name)
        cachefile.close()
        return (None, None, None, tags, False)
    if cachefile:
        cachefile.close()               # ignore rest of file

    valid = (tiprev, tipnode, scmutil.filteredhash(repo, tiprev))

    repoheads = repo.heads()
    # Case 2 (uncommon): empty repo; get out quickly and don't bother
    # writing an empty cache.
    if repoheads == [nullid]:
        return ([], {}, valid, {}, False)

    # Case 3 (uncommon): cache file missing or empty.

    # Case 4 (uncommon): tip rev decreased.  This should only happen
    # when we're called from localrepository.destroyed().  Refresh the
    # cache so future invocations will not see disappeared heads in the
    # cache.

    # Case 5 (common): tip has changed, so we've added/replaced heads.

    # As it happens, the code to handle cases 3, 4, 5 is the same.

    # N.B. in case 4 (nodes destroyed), "new head" really means "newly
    # exposed".
    if not len(repo.file('.hgtags')):
        # No tags have ever been committed, so we can avoid a
        # potentially expensive search.
        return ([], {}, valid, None, True)

    starttime = time.time()

    # Now we have to lookup the .hgtags filenode for every new head.
    # This is the most expensive part of finding tags, so performance
    # depends primarily on the size of newheads.  Worst case: no cache
    # file, so newheads == repoheads.
    fnodescache = hgtagsfnodescache(repo.unfiltered())
    cachefnode = {}
    for head in reversed(repoheads):
        fnode = fnodescache.getfnode(head)
        if fnode != nullid:
            cachefnode[head] = fnode

    fnodescache.write()

    duration = time.time() - starttime
    ui.log('tagscache',
           '%d/%d cache hits/lookups in %0.4f '
           'seconds\n',
           fnodescache.hitcount, fnodescache.lookupcount, duration)

    # Caller has to iterate over all heads, but can use the filenodes in
    # cachefnode to get to each .hgtags revision quickly.
    return (repoheads, cachefnode, valid, None, True)

def _writetagcache(ui, repo, valid, cachetags):
    filename = _filename(repo)
    try:
        cachefile = repo.vfs(filename, 'w', atomictemp=True)
    except (OSError, IOError):
        return

    ui.log('tagscache', 'writing .hg/%s with %d tags\n',
           filename, len(cachetags))

    if valid[2]:
        cachefile.write('%d %s %s\n' % (valid[0], hex(valid[1]), hex(valid[2])))
    else:
        cachefile.write('%d %s\n' % (valid[0], hex(valid[1])))

    # Tag names in the cache are in UTF-8 -- which is the whole reason
    # we keep them in UTF-8 throughout this module.  If we converted
    # them local encoding on input, we would lose info writing them to
    # the cache.
    for (name, (node, hist)) in sorted(cachetags.iteritems()):
        for n in hist:
            cachefile.write("%s %s\n" % (hex(n), name))
        cachefile.write("%s %s\n" % (hex(node), name))

    try:
        cachefile.close()
    except (OSError, IOError):
        pass

_fnodescachefile = 'cache/hgtagsfnodes1'
_fnodesrecsize = 4 + 20 # changeset fragment + filenode
_fnodesmissingrec = '\xff' * 24

class hgtagsfnodescache(object):
    """Persistent cache mapping revisions to .hgtags filenodes.

    The cache is an array of records. Each item in the array corresponds to
    a changelog revision. Values in the array contain the first 4 bytes of
    the node hash and the 20 bytes .hgtags filenode for that revision.

    The first 4 bytes are present as a form of verification. Repository
    stripping and rewriting may change the node at a numeric revision in the
    changelog. The changeset fragment serves as a verifier to detect
    rewriting. This logic is shared with the rev branch cache (see
    branchmap.py).

    The instance holds in memory the full cache content but entries are
    only parsed on read.

    Instances behave like lists. ``c[i]`` works where i is a rev or
    changeset node. Missing indexes are populated automatically on access.
    """
    def __init__(self, repo):
        assert repo.filtername is None

        self._repo = repo

        # Only for reporting purposes.
        self.lookupcount = 0
        self.hitcount = 0

        self._raw = array('c')

        data = repo.vfs.tryread(_fnodescachefile)
        self._raw.fromstring(data)

        # The end state of self._raw is an array that is of the exact length
        # required to hold a record for every revision in the repository.
        # We truncate or extend the array as necessary. self._dirtyoffset is
        # defined to be the start offset at which we need to write the output
        # file. This offset is also adjusted when new entries are calculated
        # for array members.
        cllen = len(repo.changelog)
        wantedlen = cllen * _fnodesrecsize
        rawlen = len(self._raw)

        self._dirtyoffset = None

        if rawlen < wantedlen:
            self._dirtyoffset = rawlen
            self._raw.extend('\xff' * (wantedlen - rawlen))
        elif rawlen > wantedlen:
            # There's no easy way to truncate array instances. This seems
            # slightly less evil than copying a potentially large array slice.
            for i in range(rawlen - wantedlen):
                self._raw.pop()
            self._dirtyoffset = len(self._raw)

    def getfnode(self, node, computemissing=True):
        """Obtain the filenode of the .hgtags file at a specified revision.

        If the value is in the cache, the entry will be validated and returned.
        Otherwise, the filenode will be computed and returned unless
        "computemissing" is False, in which case None will be returned without
        any potentially expensive computation being performed.

        If an .hgtags does not exist at the specified revision, nullid is
        returned.
        """
        ctx = self._repo[node]
        rev = ctx.rev()

        self.lookupcount += 1

        offset = rev * _fnodesrecsize
        record = self._raw[offset:offset + _fnodesrecsize].tostring()
        properprefix = node[0:4]

        # Validate and return existing entry.
        if record != _fnodesmissingrec:
            fileprefix = record[0:4]

            if fileprefix == properprefix:
                self.hitcount += 1
                return record[4:]

            # Fall through.

        # If we get here, the entry is either missing or invalid.

        if not computemissing:
            return None

        # Populate missing entry.
        try:
            fnode = ctx.filenode('.hgtags')
        except error.LookupError:
            # No .hgtags file on this revision.
            fnode = nullid

        self._writeentry(offset, properprefix, fnode)
        return fnode

    def setfnode(self, node, fnode):
        """Set the .hgtags filenode for a given changeset."""
        assert len(fnode) == 20
        ctx = self._repo[node]

        # Do a lookup first to avoid writing if nothing has changed.
        if self.getfnode(ctx.node(), computemissing=False) == fnode:
            return

        self._writeentry(ctx.rev() * _fnodesrecsize, node[0:4], fnode)

    def _writeentry(self, offset, prefix, fnode):
        # Slices on array instances only accept other array.
        entry = array('c', prefix + fnode)
        self._raw[offset:offset + _fnodesrecsize] = entry
        # self._dirtyoffset could be None.
        self._dirtyoffset = min(self._dirtyoffset, offset) or 0

    def write(self):
        """Perform all necessary writes to cache file.

        This may no-op if no writes are needed or if a write lock could
        not be obtained.
        """
        if self._dirtyoffset is None:
            return

        data = self._raw[self._dirtyoffset:]
        if not data:
            return

        repo = self._repo

        try:
            lock = repo.wlock(wait=False)
        except error.LockError:
            repo.ui.log('tagscache',
                        'not writing .hg/%s because lock cannot be acquired\n' %
                        (_fnodescachefile))
            return

        try:
            f = repo.vfs.open(_fnodescachefile, 'ab')
            try:
                # if the file has been truncated
                actualoffset = f.tell()
                if actualoffset < self._dirtyoffset:
                    self._dirtyoffset = actualoffset
                    data = self._raw[self._dirtyoffset:]
                f.seek(self._dirtyoffset)
                f.truncate()
                repo.ui.log('tagscache',
                            'writing %d bytes to %s\n' % (
                            len(data), _fnodescachefile))
                f.write(data)
                self._dirtyoffset = None
            finally:
                f.close()
        except (IOError, OSError) as inst:
            repo.ui.log('tagscache',
                        "couldn't write %s: %s\n" % (
                        _fnodescachefile, inst))
        finally:
            lock.release()