mercurial/revlog.py
author Patrick Mezard <pmezard@gmail.com>
Fri, 04 Jan 2008 23:43:55 +0100
changeset 5805 e422305e0853
parent 5659 3da652f2039c
child 5909 f45f7390c1c5
permissions -rw-r--r--
test-convert: test before() and after() conversion actions

"""
revlog.py - storage back-end for mercurial

This provides efficient delta storage with O(1) retrieve and append
and O(changes) merge between branches

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, incorporated herein by reference.
"""

from node import *
from i18n import _
import binascii, changegroup, errno, ancestor, mdiff, os
import sha, struct, util, zlib

_pack = struct.pack
_unpack = struct.unpack
_compress = zlib.compress
_decompress = zlib.decompress
_sha = sha.new

# revlog flags
REVLOGV0 = 0
REVLOGNG = 1
REVLOGNGINLINEDATA = (1 << 16)
REVLOG_DEFAULT_FLAGS = REVLOGNGINLINEDATA
REVLOG_DEFAULT_FORMAT = REVLOGNG
REVLOG_DEFAULT_VERSION = REVLOG_DEFAULT_FORMAT | REVLOG_DEFAULT_FLAGS

class RevlogError(Exception):
    pass

class LookupError(RevlogError):
    def __init__(self, name, message=None):
        if message is None:
            message = _('not found: %s') % name
        RevlogError.__init__(self, message)
        self.name = name

def getoffset(q):
    return int(q >> 16)

def gettype(q):
    return int(q & 0xFFFF)

def offset_type(offset, type):
    return long(long(offset) << 16 | type)

def hash(text, p1, p2):
    """generate a hash from the given text and its parent hashes

    This hash combines both the current file contents and its history
    in a manner that makes it easy to distinguish nodes with the same
    content in the revision graph.
    """
    l = [p1, p2]
    l.sort()
    s = _sha(l[0])
    s.update(l[1])
    s.update(text)
    return s.digest()

def compress(text):
    """ generate a possibly-compressed representation of text """
    if not text:
        return ("", text)
    l = len(text)
    bin = None
    if l < 44:
        pass
    elif l > 1000000:
        # zlib makes an internal copy, thus doubling memory usage for
        # large files, so lets do this in pieces
        z = zlib.compressobj()
        p = []
        pos = 0
        while pos < l:
            pos2 = pos + 2**20
            p.append(z.compress(text[pos:pos2]))
            pos = pos2
        p.append(z.flush())
        if sum(map(len, p)) < l:
            bin = "".join(p)
    else:
        bin = _compress(text)
    if bin is None or len(bin) > l:
        if text[0] == '\0':
            return ("", text)
        return ('u', text)
    return ("", bin)

def decompress(bin):
    """ decompress the given input """
    if not bin:
        return bin
    t = bin[0]
    if t == '\0':
        return bin
    if t == 'x':
        return _decompress(bin)
    if t == 'u':
        return bin[1:]
    raise RevlogError(_("unknown compression type %r") % t)

class lazyparser(object):
    """
    this class avoids the need to parse the entirety of large indices
    """

    # lazyparser is not safe to use on windows if win32 extensions not
    # available. it keeps file handle open, which make it not possible
    # to break hardlinks on local cloned repos.

    def __init__(self, dataf, size):
        self.dataf = dataf
        self.s = struct.calcsize(indexformatng)
        self.datasize = size
        self.l = size/self.s
        self.index = [None] * self.l
        self.map = {nullid: nullrev}
        self.allmap = 0
        self.all = 0
        self.mapfind_count = 0

    def loadmap(self):
        """
        during a commit, we need to make sure the rev being added is
        not a duplicate.  This requires loading the entire index,
        which is fairly slow.  loadmap can load up just the node map,
        which takes much less time.
        """
        if self.allmap:
            return
        end = self.datasize
        self.allmap = 1
        cur = 0
        count = 0
        blocksize = self.s * 256
        self.dataf.seek(0)
        while cur < end:
            data = self.dataf.read(blocksize)
            off = 0
            for x in xrange(256):
                n = data[off + ngshaoffset:off + ngshaoffset + 20]
                self.map[n] = count
                count += 1
                if count >= self.l:
                    break
                off += self.s
            cur += blocksize

    def loadblock(self, blockstart, blocksize, data=None):
        if self.all:
            return
        if data is None:
            self.dataf.seek(blockstart)
            if blockstart + blocksize > self.datasize:
                # the revlog may have grown since we've started running,
                # but we don't have space in self.index for more entries.
                # limit blocksize so that we don't get too much data.
                blocksize = max(self.datasize - blockstart, 0)
            data = self.dataf.read(blocksize)
        lend = len(data) / self.s
        i = blockstart / self.s
        off = 0
        # lazyindex supports __delitem__
        if lend > len(self.index) - i:
            lend = len(self.index) - i
        for x in xrange(lend):
            if self.index[i + x] == None:
                b = data[off : off + self.s]
                self.index[i + x] = b
                n = b[ngshaoffset:ngshaoffset + 20]
                self.map[n] = i + x
            off += self.s

    def findnode(self, node):
        """search backwards through the index file for a specific node"""
        if self.allmap:
            return None

        # hg log will cause many many searches for the manifest
        # nodes.  After we get called a few times, just load the whole
        # thing.
        if self.mapfind_count > 8:
            self.loadmap()
            if node in self.map:
                return node
            return None
        self.mapfind_count += 1
        last = self.l - 1
        while self.index[last] != None:
            if last == 0:
                self.all = 1
                self.allmap = 1
                return None
            last -= 1
        end = (last + 1) * self.s
        blocksize = self.s * 256
        while end >= 0:
            start = max(end - blocksize, 0)
            self.dataf.seek(start)
            data = self.dataf.read(end - start)
            findend = end - start
            while True:
                # we're searching backwards, so we have to make sure
                # we don't find a changeset where this node is a parent
                off = data.find(node, 0, findend)
                findend = off
                if off >= 0:
                    i = off / self.s
                    off = i * self.s
                    n = data[off + ngshaoffset:off + ngshaoffset + 20]
                    if n == node:
                        self.map[n] = i + start / self.s
                        return node
                else:
                    break
            end -= blocksize
        return None

    def loadindex(self, i=None, end=None):
        if self.all:
            return
        all = False
        if i == None:
            blockstart = 0
            blocksize = (65536 / self.s) * self.s
            end = self.datasize
            all = True
        else:
            if end:
                blockstart = i * self.s
                end = end * self.s
                blocksize = end - blockstart
            else:
                blockstart = (i & ~1023) * self.s
                blocksize = self.s * 1024
                end = blockstart + blocksize
        while blockstart < end:
            self.loadblock(blockstart, blocksize)
            blockstart += blocksize
        if all:
            self.all = True

class lazyindex(object):
    """a lazy version of the index array"""
    def __init__(self, parser):
        self.p = parser
    def __len__(self):
        return len(self.p.index)
    def load(self, pos):
        if pos < 0:
            pos += len(self.p.index)
        self.p.loadindex(pos)
        return self.p.index[pos]
    def __getitem__(self, pos):
        return _unpack(indexformatng, self.p.index[pos] or self.load(pos))
    def __setitem__(self, pos, item):
        self.p.index[pos] = _pack(indexformatng, *item)
    def __delitem__(self, pos):
        del self.p.index[pos]
    def insert(self, pos, e):
        self.p.index.insert(pos, _pack(indexformatng, *e))
    def append(self, e):
        self.p.index.append(_pack(indexformatng, *e))

class lazymap(object):
    """a lazy version of the node map"""
    def __init__(self, parser):
        self.p = parser
    def load(self, key):
        n = self.p.findnode(key)
        if n == None:
            raise KeyError(key)
    def __contains__(self, key):
        if key in self.p.map:
            return True
        self.p.loadmap()
        return key in self.p.map
    def __iter__(self):
        yield nullid
        for i in xrange(self.p.l):
            ret = self.p.index[i]
            if not ret:
                self.p.loadindex(i)
                ret = self.p.index[i]
            if isinstance(ret, str):
                ret = _unpack(indexformatng, ret)
            yield ret[7]
    def __getitem__(self, key):
        try:
            return self.p.map[key]
        except KeyError:
            try:
                self.load(key)
                return self.p.map[key]
            except KeyError:
                raise KeyError("node " + hex(key))
    def __setitem__(self, key, val):
        self.p.map[key] = val
    def __delitem__(self, key):
        del self.p.map[key]

indexformatv0 = ">4l20s20s20s"
v0shaoffset = 56

class revlogoldio(object):
    def __init__(self):
        self.size = struct.calcsize(indexformatv0)

    def parseindex(self, fp, inline):
        s = self.size
        index = []
        nodemap =  {nullid: nullrev}
        n = off = 0
        data = fp.read()
        l = len(data)
        while off + s <= l:
            cur = data[off:off + s]
            off += s
            e = _unpack(indexformatv0, cur)
            # transform to revlogv1 format
            e2 = (offset_type(e[0], 0), e[1], -1, e[2], e[3],
                  nodemap.get(e[4], nullrev), nodemap.get(e[5], nullrev), e[6])
            index.append(e2)
            nodemap[e[6]] = n
            n += 1

        return index, nodemap, None

    def packentry(self, entry, node, version, rev):
        e2 = (getoffset(entry[0]), entry[1], entry[3], entry[4],
              node(entry[5]), node(entry[6]), entry[7])
        return _pack(indexformatv0, *e2)

# index ng:
# 6 bytes offset
# 2 bytes flags
# 4 bytes compressed length
# 4 bytes uncompressed length
# 4 bytes: base rev
# 4 bytes link rev
# 4 bytes parent 1 rev
# 4 bytes parent 2 rev
# 32 bytes: nodeid
indexformatng = ">Qiiiiii20s12x"
ngshaoffset = 32
versionformat = ">I"

class revlogio(object):
    def __init__(self):
        self.size = struct.calcsize(indexformatng)

    def parseindex(self, fp, inline):
        try:
            size = util.fstat(fp).st_size
        except AttributeError:
            size = 0

        if util.openhardlinks() and not inline and size > 1000000:
            # big index, let's parse it on demand
            parser = lazyparser(fp, size)
            index = lazyindex(parser)
            nodemap = lazymap(parser)
            e = list(index[0])
            type = gettype(e[0])
            e[0] = offset_type(0, type)
            index[0] = e
            return index, nodemap, None

        s = self.size
        cache = None
        index = []
        nodemap =  {nullid: nullrev}
        n = off = 0
        # if we're not using lazymap, always read the whole index
        data = fp.read()
        l = len(data) - s
        append = index.append
        if inline:
            cache = (0, data)
            while off <= l:
                e = _unpack(indexformatng, data[off:off + s])
                nodemap[e[7]] = n
                append(e)
                n += 1
                if e[1] < 0:
                    break
                off += e[1] + s
        else:
            while off <= l:
                e = _unpack(indexformatng, data[off:off + s])
                nodemap[e[7]] = n
                append(e)
                n += 1
                off += s

        e = list(index[0])
        type = gettype(e[0])
        e[0] = offset_type(0, type)
        index[0] = e

        return index, nodemap, cache

    def packentry(self, entry, node, version, rev):
        p = _pack(indexformatng, *entry)
        if rev == 0:
            p = _pack(versionformat, version) + p[4:]
        return p

class revlog(object):
    """
    the underlying revision storage object

    A revlog consists of two parts, an index and the revision data.

    The index is a file with a fixed record size containing
    information on each revision, includings its nodeid (hash), the
    nodeids of its parents, the position and offset of its data within
    the data file, and the revision it's based on. Finally, each entry
    contains a linkrev entry that can serve as a pointer to external
    data.

    The revision data itself is a linear collection of data chunks.
    Each chunk represents a revision and is usually represented as a
    delta against the previous chunk. To bound lookup time, runs of
    deltas are limited to about 2 times the length of the original
    version data. This makes retrieval of a version proportional to
    its size, or O(1) relative to the number of revisions.

    Both pieces of the revlog are written to in an append-only
    fashion, which means we never need to rewrite a file to insert or
    remove data, and can use some simple techniques to avoid the need
    for locking while reading.
    """
    def __init__(self, opener, indexfile):
        """
        create a revlog object

        opener is a function that abstracts the file opening operation
        and can be used to implement COW semantics or the like.
        """
        self.indexfile = indexfile
        self.datafile = indexfile[:-2] + ".d"
        self.opener = opener
        self._cache = None
        self._chunkcache = None
        self.nodemap = {nullid: nullrev}
        self.index = []

        v = REVLOG_DEFAULT_VERSION
        if hasattr(opener, "defversion"):
            v = opener.defversion
            if v & REVLOGNG:
                v |= REVLOGNGINLINEDATA

        i = ""
        try:
            f = self.opener(self.indexfile)
            i = f.read(4)
            f.seek(0)
            if len(i) > 0:
                v = struct.unpack(versionformat, i)[0]
        except IOError, inst:
            if inst.errno != errno.ENOENT:
                raise

        self.version = v
        self._inline = v & REVLOGNGINLINEDATA
        flags = v & ~0xFFFF
        fmt = v & 0xFFFF
        if fmt == REVLOGV0 and flags:
            raise RevlogError(_("index %s unknown flags %#04x for format v0")
                              % (self.indexfile, flags >> 16))
        elif fmt == REVLOGNG and flags & ~REVLOGNGINLINEDATA:
            raise RevlogError(_("index %s unknown flags %#04x for revlogng")
                              % (self.indexfile, flags >> 16))
        elif fmt > REVLOGNG:
            raise RevlogError(_("index %s unknown format %d")
                              % (self.indexfile, fmt))

        self._io = revlogio()
        if self.version == REVLOGV0:
            self._io = revlogoldio()
        if i:
            d = self._io.parseindex(f, self._inline)
            self.index, self.nodemap, self._chunkcache = d

        # add the magic null revision at -1
        self.index.append((0, 0, 0, -1, -1, -1, -1, nullid))

    def _loadindex(self, start, end):
        """load a block of indexes all at once from the lazy parser"""
        if isinstance(self.index, lazyindex):
            self.index.p.loadindex(start, end)

    def _loadindexmap(self):
        """loads both the map and the index from the lazy parser"""
        if isinstance(self.index, lazyindex):
            p = self.index.p
            p.loadindex()
            self.nodemap = p.map

    def _loadmap(self):
        """loads the map from the lazy parser"""
        if isinstance(self.nodemap, lazymap):
            self.nodemap.p.loadmap()
            self.nodemap = self.nodemap.p.map

    def tip(self):
        return self.node(len(self.index) - 2)
    def count(self):
        return len(self.index) - 1

    def rev(self, node):
        try:
            return self.nodemap[node]
        except KeyError:
            raise LookupError(hex(node), _('%s: no node %s') % (self.indexfile, hex(node)))
    def node(self, rev):
        return self.index[rev][7]
    def linkrev(self, node):
        return self.index[self.rev(node)][4]
    def parents(self, node):
        d = self.index[self.rev(node)][5:7]
        return (self.node(d[0]), self.node(d[1]))
    def parentrevs(self, rev):
        return self.index[rev][5:7]
    def start(self, rev):
        return int(self.index[rev][0] >> 16)
    def end(self, rev):
        return self.start(rev) + self.length(rev)
    def length(self, rev):
        return self.index[rev][1]
    def base(self, rev):
        return self.index[rev][3]

    def size(self, rev):
        """return the length of the uncompressed text for a given revision"""
        l = self.index[rev][2]
        if l >= 0:
            return l

        t = self.revision(self.node(rev))
        return len(t)

        # alternate implementation, The advantage to this code is it
        # will be faster for a single revision.  But, the results are not
        # cached, so finding the size of every revision will be slower.
        """
        if self.cache and self.cache[1] == rev:
            return len(self.cache[2])

        base = self.base(rev)
        if self.cache and self.cache[1] >= base and self.cache[1] < rev:
            base = self.cache[1]
            text = self.cache[2]
        else:
            text = self.revision(self.node(base))

        l = len(text)
        for x in xrange(base + 1, rev + 1):
            l = mdiff.patchedsize(l, self.chunk(x))
        return l
        """

    def reachable(self, node, stop=None):
        """return a hash of all nodes ancestral to a given node, including
         the node itself, stopping when stop is matched"""
        reachable = {}
        visit = [node]
        reachable[node] = 1
        if stop:
            stopn = self.rev(stop)
        else:
            stopn = 0
        while visit:
            n = visit.pop(0)
            if n == stop:
                continue
            if n == nullid:
                continue
            for p in self.parents(n):
                if self.rev(p) < stopn:
                    continue
                if p not in reachable:
                    reachable[p] = 1
                    visit.append(p)
        return reachable

    def nodesbetween(self, roots=None, heads=None):
        """Return a tuple containing three elements. Elements 1 and 2 contain
        a final list bases and heads after all the unreachable ones have been
        pruned.  Element 0 contains a topologically sorted list of all

        nodes that satisfy these constraints:
        1. All nodes must be descended from a node in roots (the nodes on
           roots are considered descended from themselves).
        2. All nodes must also be ancestors of a node in heads (the nodes in
           heads are considered to be their own ancestors).

        If roots is unspecified, nullid is assumed as the only root.
        If heads is unspecified, it is taken to be the output of the
        heads method (i.e. a list of all nodes in the repository that
        have no children)."""
        nonodes = ([], [], [])
        if roots is not None:
            roots = list(roots)
            if not roots:
                return nonodes
            lowestrev = min([self.rev(n) for n in roots])
        else:
            roots = [nullid] # Everybody's a descendent of nullid
            lowestrev = nullrev
        if (lowestrev == nullrev) and (heads is None):
            # We want _all_ the nodes!
            return ([self.node(r) for r in xrange(0, self.count())],
                    [nullid], list(self.heads()))
        if heads is None:
            # All nodes are ancestors, so the latest ancestor is the last
            # node.
            highestrev = self.count() - 1
            # Set ancestors to None to signal that every node is an ancestor.
            ancestors = None
            # Set heads to an empty dictionary for later discovery of heads
            heads = {}
        else:
            heads = list(heads)
            if not heads:
                return nonodes
            ancestors = {}
            # Turn heads into a dictionary so we can remove 'fake' heads.
            # Also, later we will be using it to filter out the heads we can't
            # find from roots.
            heads = dict.fromkeys(heads, 0)
            # Start at the top and keep marking parents until we're done.
            nodestotag = heads.keys()
            # Remember where the top was so we can use it as a limit later.
            highestrev = max([self.rev(n) for n in nodestotag])
            while nodestotag:
                # grab a node to tag
                n = nodestotag.pop()
                # Never tag nullid
                if n == nullid:
                    continue
                # A node's revision number represents its place in a
                # topologically sorted list of nodes.
                r = self.rev(n)
                if r >= lowestrev:
                    if n not in ancestors:
                        # If we are possibly a descendent of one of the roots
                        # and we haven't already been marked as an ancestor
                        ancestors[n] = 1 # Mark as ancestor
                        # Add non-nullid parents to list of nodes to tag.
                        nodestotag.extend([p for p in self.parents(n) if
                                           p != nullid])
                    elif n in heads: # We've seen it before, is it a fake head?
                        # So it is, real heads should not be the ancestors of
                        # any other heads.
                        heads.pop(n)
            if not ancestors:
                return nonodes
            # Now that we have our set of ancestors, we want to remove any
            # roots that are not ancestors.

            # If one of the roots was nullid, everything is included anyway.
            if lowestrev > nullrev:
                # But, since we weren't, let's recompute the lowest rev to not
                # include roots that aren't ancestors.

                # Filter out roots that aren't ancestors of heads
                roots = [n for n in roots if n in ancestors]
                # Recompute the lowest revision
                if roots:
                    lowestrev = min([self.rev(n) for n in roots])
                else:
                    # No more roots?  Return empty list
                    return nonodes
            else:
                # We are descending from nullid, and don't need to care about
                # any other roots.
                lowestrev = nullrev
                roots = [nullid]
        # Transform our roots list into a 'set' (i.e. a dictionary where the
        # values don't matter.
        descendents = dict.fromkeys(roots, 1)
        # Also, keep the original roots so we can filter out roots that aren't
        # 'real' roots (i.e. are descended from other roots).
        roots = descendents.copy()
        # Our topologically sorted list of output nodes.
        orderedout = []
        # Don't start at nullid since we don't want nullid in our output list,
        # and if nullid shows up in descedents, empty parents will look like
        # they're descendents.
        for r in xrange(max(lowestrev, 0), highestrev + 1):
            n = self.node(r)
            isdescendent = False
            if lowestrev == nullrev:  # Everybody is a descendent of nullid
                isdescendent = True
            elif n in descendents:
                # n is already a descendent
                isdescendent = True
                # This check only needs to be done here because all the roots
                # will start being marked is descendents before the loop.
                if n in roots:
                    # If n was a root, check if it's a 'real' root.
                    p = tuple(self.parents(n))
                    # If any of its parents are descendents, it's not a root.
                    if (p[0] in descendents) or (p[1] in descendents):
                        roots.pop(n)
            else:
                p = tuple(self.parents(n))
                # A node is a descendent if either of its parents are
                # descendents.  (We seeded the dependents list with the roots
                # up there, remember?)
                if (p[0] in descendents) or (p[1] in descendents):
                    descendents[n] = 1
                    isdescendent = True
            if isdescendent and ((ancestors is None) or (n in ancestors)):
                # Only include nodes that are both descendents and ancestors.
                orderedout.append(n)
                if (ancestors is not None) and (n in heads):
                    # We're trying to figure out which heads are reachable
                    # from roots.
                    # Mark this head as having been reached
                    heads[n] = 1
                elif ancestors is None:
                    # Otherwise, we're trying to discover the heads.
                    # Assume this is a head because if it isn't, the next step
                    # will eventually remove it.
                    heads[n] = 1
                    # But, obviously its parents aren't.
                    for p in self.parents(n):
                        heads.pop(p, None)
        heads = [n for n in heads.iterkeys() if heads[n] != 0]
        roots = roots.keys()
        assert orderedout
        assert roots
        assert heads
        return (orderedout, roots, heads)

    def heads(self, start=None, stop=None):
        """return the list of all nodes that have no children

        if start is specified, only heads that are descendants of
        start will be returned
        if stop is specified, it will consider all the revs from stop
        as if they had no children
        """
        if start is None and stop is None:
            count = self.count()
            if not count:
                return [nullid]
            ishead = [1] * (count + 1)
            index = self.index
            for r in xrange(count):
                e = index[r]
                ishead[e[5]] = ishead[e[6]] = 0
            return [self.node(r) for r in xrange(count) if ishead[r]]

        if start is None:
            start = nullid
        if stop is None:
            stop = []
        stoprevs = dict.fromkeys([self.rev(n) for n in stop])
        startrev = self.rev(start)
        reachable = {startrev: 1}
        heads = {startrev: 1}

        parentrevs = self.parentrevs
        for r in xrange(startrev + 1, self.count()):
            for p in parentrevs(r):
                if p in reachable:
                    if r not in stoprevs:
                        reachable[r] = 1
                    heads[r] = 1
                if p in heads and p not in stoprevs:
                    del heads[p]

        return [self.node(r) for r in heads]

    def children(self, node):
        """find the children of a given node"""
        c = []
        p = self.rev(node)
        for r in range(p + 1, self.count()):
            prevs = [pr for pr in self.parentrevs(r) if pr != nullrev]
            if prevs:
                for pr in prevs:
                    if pr == p:
                        c.append(self.node(r))
            elif p == nullrev:
                c.append(self.node(r))
        return c

    def _match(self, id):
        if isinstance(id, (long, int)):
            # rev
            return self.node(id)
        if len(id) == 20:
            # possibly a binary node
            # odds of a binary node being all hex in ASCII are 1 in 10**25
            try:
                node = id
                r = self.rev(node) # quick search the index
                return node
            except LookupError:
                pass # may be partial hex id
        try:
            # str(rev)
            rev = int(id)
            if str(rev) != id:
                raise ValueError
            if rev < 0:
                rev = self.count() + rev
            if rev < 0 or rev >= self.count():
                raise ValueError
            return self.node(rev)
        except (ValueError, OverflowError):
            pass
        if len(id) == 40:
            try:
                # a full hex nodeid?
                node = bin(id)
                r = self.rev(node)
                return node
            except TypeError:
                pass

    def _partialmatch(self, id):
        if len(id) < 40:
            try:
                # hex(node)[:...]
                bin_id = bin(id[:len(id) & ~1]) # grab an even number of digits
                node = None
                for n in self.nodemap:
                    if n.startswith(bin_id) and hex(n).startswith(id):
                        if node is not None:
                            raise LookupError(hex(node),
                                              _("Ambiguous identifier"))
                        node = n
                if node is not None:
                    return node
            except TypeError:
                pass

    def lookup(self, id):
        """locate a node based on:
            - revision number or str(revision number)
            - nodeid or subset of hex nodeid
        """
        n = self._match(id)
        if n is not None:
            return n
        n = self._partialmatch(id)
        if n:
            return n

        raise LookupError(id, _("No match found"))

    def cmp(self, node, text):
        """compare text with a given file revision"""
        p1, p2 = self.parents(node)
        return hash(text, p1, p2) != node

    def chunk(self, rev, df=None):
        def loadcache(df):
            if not df:
                if self._inline:
                    df = self.opener(self.indexfile)
                else:
                    df = self.opener(self.datafile)
            df.seek(start)
            self._chunkcache = (start, df.read(cache_length))

        start, length = self.start(rev), self.length(rev)
        if self._inline:
            start += (rev + 1) * self._io.size
        end = start + length

        offset = 0
        if not self._chunkcache:
            cache_length = max(65536, length)
            loadcache(df)
        else:
            cache_start = self._chunkcache[0]
            cache_length = len(self._chunkcache[1])
            cache_end = cache_start + cache_length
            if start >= cache_start and end <= cache_end:
                # it is cached
                offset = start - cache_start
            else:
                cache_length = max(65536, length)
                loadcache(df)

        # avoid copying large chunks
        c = self._chunkcache[1]
        if cache_length != length:
            c = c[offset:offset + length]

        return decompress(c)

    def delta(self, node):
        """return or calculate a delta between a node and its predecessor"""
        r = self.rev(node)
        return self.revdiff(r - 1, r)

    def revdiff(self, rev1, rev2):
        """return or calculate a delta between two revisions"""
        if rev1 + 1 == rev2 and self.base(rev1) == self.base(rev2):
            return self.chunk(rev2)

        return mdiff.textdiff(self.revision(self.node(rev1)),
                              self.revision(self.node(rev2)))

    def revision(self, node):
        """return an uncompressed revision of a given"""
        if node == nullid:
            return ""
        if self._cache and self._cache[0] == node:
            return str(self._cache[2])

        # look up what we need to read
        text = None
        rev = self.rev(node)
        base = self.base(rev)

        # check rev flags
        if self.index[rev][0] & 0xFFFF:
            raise RevlogError(_('incompatible revision flag %x') %
                              (self.index[rev][0] & 0xFFFF))

        if self._inline:
            # we probably have the whole chunk cached
            df = None
        else:
            df = self.opener(self.datafile)

        # do we have useful data cached?
        if self._cache and self._cache[1] >= base and self._cache[1] < rev:
            base = self._cache[1]
            text = str(self._cache[2])
            self._loadindex(base, rev + 1)
        else:
            self._loadindex(base, rev + 1)
            text = self.chunk(base, df=df)

        bins = [self.chunk(r, df) for r in xrange(base + 1, rev + 1)]
        text = mdiff.patches(text, bins)
        p1, p2 = self.parents(node)
        if node != hash(text, p1, p2):
            raise RevlogError(_("integrity check failed on %s:%d")
                              % (self.datafile, rev))

        self._cache = (node, rev, text)
        return text

    def checkinlinesize(self, tr, fp=None):
        if not self._inline:
            return
        if not fp:
            fp = self.opener(self.indexfile, 'r')
            fp.seek(0, 2)
        size = fp.tell()
        if size < 131072:
            return
        trinfo = tr.find(self.indexfile)
        if trinfo == None:
            raise RevlogError(_("%s not found in the transaction")
                              % self.indexfile)

        trindex = trinfo[2]
        dataoff = self.start(trindex)

        tr.add(self.datafile, dataoff)
        df = self.opener(self.datafile, 'w')
        calc = self._io.size
        for r in xrange(self.count()):
            start = self.start(r) + (r + 1) * calc
            length = self.length(r)
            fp.seek(start)
            d = fp.read(length)
            df.write(d)
        fp.close()
        df.close()
        fp = self.opener(self.indexfile, 'w', atomictemp=True)
        self.version &= ~(REVLOGNGINLINEDATA)
        self._inline = False
        for i in xrange(self.count()):
            e = self._io.packentry(self.index[i], self.node, self.version, i)
            fp.write(e)

        # if we don't call rename, the temp file will never replace the
        # real index
        fp.rename()

        tr.replace(self.indexfile, trindex * calc)
        self._chunkcache = None

    def addrevision(self, text, transaction, link, p1, p2, d=None):
        """add a revision to the log

        text - the revision data to add
        transaction - the transaction object used for rollback
        link - the linkrev data to add
        p1, p2 - the parent nodeids of the revision
        d - an optional precomputed delta
        """
        dfh = None
        if not self._inline:
            dfh = self.opener(self.datafile, "a")
        ifh = self.opener(self.indexfile, "a+")
        return self._addrevision(text, transaction, link, p1, p2, d, ifh, dfh)

    def _addrevision(self, text, transaction, link, p1, p2, d, ifh, dfh):
        node = hash(text, p1, p2)
        if node in self.nodemap:
            return node

        curr = self.count()
        prev = curr - 1
        base = self.base(prev)
        offset = self.end(prev)

        if curr:
            if not d:
                ptext = self.revision(self.node(prev))
                d = mdiff.textdiff(ptext, text)
            data = compress(d)
            l = len(data[1]) + len(data[0])
            dist = l + offset - self.start(base)

        # full versions are inserted when the needed deltas
        # become comparable to the uncompressed text
        if not curr or dist > len(text) * 2:
            data = compress(text)
            l = len(data[1]) + len(data[0])
            base = curr

        e = (offset_type(offset, 0), l, len(text),
             base, link, self.rev(p1), self.rev(p2), node)
        self.index.insert(-1, e)
        self.nodemap[node] = curr

        entry = self._io.packentry(e, self.node, self.version, curr)
        if not self._inline:
            transaction.add(self.datafile, offset)
            transaction.add(self.indexfile, curr * len(entry))
            if data[0]:
                dfh.write(data[0])
            dfh.write(data[1])
            dfh.flush()
            ifh.write(entry)
        else:
            offset += curr * self._io.size
            transaction.add(self.indexfile, offset, curr)
            ifh.write(entry)
            ifh.write(data[0])
            ifh.write(data[1])
            self.checkinlinesize(transaction, ifh)

        self._cache = (node, curr, text)
        return node

    def ancestor(self, a, b):
        """calculate the least common ancestor of nodes a and b"""

        def parents(rev):
            return [p for p in self.parentrevs(rev) if p != nullrev]

        c = ancestor.ancestor(self.rev(a), self.rev(b), parents)
        if c is None:
            return nullid

        return self.node(c)

    def group(self, nodelist, lookup, infocollect=None):
        """calculate a delta group

        Given a list of changeset revs, return a set of deltas and
        metadata corresponding to nodes. the first delta is
        parent(nodes[0]) -> nodes[0] the receiver is guaranteed to
        have this parent as it has all history before these
        changesets. parent is parent[0]
        """
        revs = [self.rev(n) for n in nodelist]

        # if we don't have any revisions touched by these changesets, bail
        if not revs:
            yield changegroup.closechunk()
            return

        # add the parent of the first rev
        p = self.parents(self.node(revs[0]))[0]
        revs.insert(0, self.rev(p))

        # build deltas
        for d in xrange(0, len(revs) - 1):
            a, b = revs[d], revs[d + 1]
            nb = self.node(b)

            if infocollect is not None:
                infocollect(nb)

            p = self.parents(nb)
            meta = nb + p[0] + p[1] + lookup(nb)
            if a == -1:
                d = self.revision(nb)
                meta += mdiff.trivialdiffheader(len(d))
            else:
                d = self.revdiff(a, b)
            yield changegroup.chunkheader(len(meta) + len(d))
            yield meta
            if len(d) > 2**20:
                pos = 0
                while pos < len(d):
                    pos2 = pos + 2 ** 18
                    yield d[pos:pos2]
                    pos = pos2
            else:
                yield d

        yield changegroup.closechunk()

    def addgroup(self, revs, linkmapper, transaction, unique=0):
        """
        add a delta group

        given a set of deltas, add them to the revision log. the
        first delta is against its parent, which should be in our
        log, the rest are against the previous delta.
        """

        #track the base of the current delta log
        r = self.count()
        t = r - 1
        node = None

        base = prev = nullrev
        start = end = textlen = 0
        if r:
            end = self.end(t)

        ifh = self.opener(self.indexfile, "a+")
        isize = r * self._io.size
        if self._inline:
            transaction.add(self.indexfile, end + isize, r)
            dfh = None
        else:
            transaction.add(self.indexfile, isize, r)
            transaction.add(self.datafile, end)
            dfh = self.opener(self.datafile, "a")

        # loop through our set of deltas
        chain = None
        for chunk in revs:
            node, p1, p2, cs = struct.unpack("20s20s20s20s", chunk[:80])
            link = linkmapper(cs)
            if node in self.nodemap:
                # this can happen if two branches make the same change
                # if unique:
                #    raise RevlogError(_("already have %s") % hex(node[:4]))
                chain = node
                continue
            delta = buffer(chunk, 80)
            del chunk

            for p in (p1, p2):
                if not p in self.nodemap:
                    raise LookupError(hex(p), _("unknown parent %s") % short(p))

            if not chain:
                # retrieve the parent revision of the delta chain
                chain = p1
                if not chain in self.nodemap:
                    raise LookupError(hex(chain), _("unknown base %s") % short(chain[:4]))

            # full versions are inserted when the needed deltas become
            # comparable to the uncompressed text or when the previous
            # version is not the one we have a delta against. We use
            # the size of the previous full rev as a proxy for the
            # current size.

            if chain == prev:
                cdelta = compress(delta)
                cdeltalen = len(cdelta[0]) + len(cdelta[1])
                textlen = mdiff.patchedsize(textlen, delta)

            if chain != prev or (end - start + cdeltalen) > textlen * 2:
                # flush our writes here so we can read it in revision
                if dfh:
                    dfh.flush()
                ifh.flush()
                text = self.revision(chain)
                if len(text) == 0:
                    # skip over trivial delta header
                    text = buffer(delta, 12)
                else:
                    text = mdiff.patches(text, [delta])
                del delta
                chk = self._addrevision(text, transaction, link, p1, p2, None,
                                        ifh, dfh)
                if not dfh and not self._inline:
                    # addrevision switched from inline to conventional
                    # reopen the index
                    dfh = self.opener(self.datafile, "a")
                    ifh = self.opener(self.indexfile, "a")
                if chk != node:
                    raise RevlogError(_("consistency error adding group"))
                textlen = len(text)
            else:
                e = (offset_type(end, 0), cdeltalen, textlen, base,
                     link, self.rev(p1), self.rev(p2), node)
                self.index.insert(-1, e)
                self.nodemap[node] = r
                entry = self._io.packentry(e, self.node, self.version, r)
                if self._inline:
                    ifh.write(entry)
                    ifh.write(cdelta[0])
                    ifh.write(cdelta[1])
                    self.checkinlinesize(transaction, ifh)
                    if not self._inline:
                        dfh = self.opener(self.datafile, "a")
                        ifh = self.opener(self.indexfile, "a")
                else:
                    dfh.write(cdelta[0])
                    dfh.write(cdelta[1])
                    ifh.write(entry)

            t, r, chain, prev = r, r + 1, node, node
            base = self.base(t)
            start = self.start(base)
            end = self.end(t)

        return node

    def strip(self, rev, minlink):
        if self.count() == 0 or rev >= self.count():
            return

        if isinstance(self.index, lazyindex):
            self._loadindexmap()

        # When stripping away a revision, we need to make sure it
        # does not actually belong to an older changeset.
        # The minlink parameter defines the oldest revision
        # we're allowed to strip away.
        while minlink > self.index[rev][4]:
            rev += 1
            if rev >= self.count():
                return

        # first truncate the files on disk
        end = self.start(rev)
        if not self._inline:
            df = self.opener(self.datafile, "a")
            df.truncate(end)
            end = rev * self._io.size
        else:
            end += rev * self._io.size

        indexf = self.opener(self.indexfile, "a")
        indexf.truncate(end)

        # then reset internal state in memory to forget those revisions
        self._cache = None
        self._chunkcache = None
        for x in xrange(rev, self.count()):
            del self.nodemap[self.node(x)]

        del self.index[rev:-1]

    def checksize(self):
        expected = 0
        if self.count():
            expected = max(0, self.end(self.count() - 1))

        try:
            f = self.opener(self.datafile)
            f.seek(0, 2)
            actual = f.tell()
            dd = actual - expected
        except IOError, inst:
            if inst.errno != errno.ENOENT:
                raise
            dd = 0

        try:
            f = self.opener(self.indexfile)
            f.seek(0, 2)
            actual = f.tell()
            s = self._io.size
            i = max(0, actual / s)
            di = actual - (i * s)
            if self._inline:
                databytes = 0
                for r in xrange(self.count()):
                    databytes += max(0, self.length(r))
                dd = 0
                di = actual - self.count() * s - databytes
        except IOError, inst:
            if inst.errno != errno.ENOENT:
                raise
            di = 0

        return (dd, di)