Mercurial > hg
view mercurial/revlogutils/nodemap.py @ 45275:8e8d513941b4
merge: introduce 'commitinfo' in mergeresult
commitinfo will be used to pass information which is required on commit phase
from the merge phase.
One common example is, merge chooses filenode from second parent and we need to
tell commit to choose that. Right now this one and related cases are not very
neatly implement and there is no clear line on how to pass on such information.
Upcoming patches will try to work on in this area and make things easier.
Differential Revision: https://phab.mercurial-scm.org/D8742
author | Pulkit Goyal <7895pulkit@gmail.com> |
---|---|
date | Tue, 14 Jul 2020 16:21:08 +0530 |
parents | 5e3c718692bb |
children | 89a2afe31e82 |
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# nodemap.py - nodemap related code and utilities # # Copyright 2019 Pierre-Yves David <pierre-yves.david@octobus.net> # Copyright 2019 George Racinet <georges.racinet@octobus.net> # # 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 errno import os import re import struct from ..i18n import _ from .. import ( error, node as nodemod, util, ) class NodeMap(dict): def __missing__(self, x): raise error.RevlogError(b'unknown node: %s' % x) def persisted_data(revlog): """read the nodemap for a revlog from disk""" if revlog.nodemap_file is None: return None pdata = revlog.opener.tryread(revlog.nodemap_file) if not pdata: return None offset = 0 (version,) = S_VERSION.unpack(pdata[offset : offset + S_VERSION.size]) if version != ONDISK_VERSION: return None offset += S_VERSION.size headers = S_HEADER.unpack(pdata[offset : offset + S_HEADER.size]) uid_size, tip_rev, data_length, data_unused, tip_node_size = headers offset += S_HEADER.size docket = NodeMapDocket(pdata[offset : offset + uid_size]) offset += uid_size docket.tip_rev = tip_rev docket.tip_node = pdata[offset : offset + tip_node_size] docket.data_length = data_length docket.data_unused = data_unused filename = _rawdata_filepath(revlog, docket) use_mmap = revlog.opener.options.get(b"persistent-nodemap.mmap") try: with revlog.opener(filename) as fd: if use_mmap: data = util.buffer(util.mmapread(fd, data_length)) else: data = fd.read(data_length) except OSError as e: if e.errno != errno.ENOENT: raise if len(data) < data_length: return None return docket, data def setup_persistent_nodemap(tr, revlog): """Install whatever is needed transaction side to persist a nodemap on disk (only actually persist the nodemap if this is relevant for this revlog) """ if revlog._inline: return # inlined revlog are too small for this to be relevant if revlog.nodemap_file is None: return # we do not use persistent_nodemap on this revlog # we need to happen after the changelog finalization, in that use "cl-" callback_id = b"nm-revlog-persistent-nodemap-%s" % revlog.nodemap_file if tr.hasfinalize(callback_id): return # no need to register again tr.addpending( callback_id, lambda tr: _persist_nodemap(tr, revlog, pending=True) ) tr.addfinalize(callback_id, lambda tr: _persist_nodemap(tr, revlog)) class _NoTransaction(object): """transaction like object to update the nodemap outside a transaction """ def __init__(self): self._postclose = {} def addpostclose(self, callback_id, callback_func): self._postclose[callback_id] = callback_func def registertmp(self, *args, **kwargs): pass def addbackup(self, *args, **kwargs): pass def add(self, *args, **kwargs): pass def addabort(self, *args, **kwargs): pass def _report(self, *args): pass def update_persistent_nodemap(revlog): """update the persistent nodemap right now To be used for updating the nodemap on disk outside of a normal transaction setup (eg, `debugupdatecache`). """ if revlog._inline: return # inlined revlog are too small for this to be relevant if revlog.nodemap_file is None: return # we do not use persistent_nodemap on this revlog notr = _NoTransaction() _persist_nodemap(notr, revlog) for k in sorted(notr._postclose): notr._postclose[k](None) def _persist_nodemap(tr, revlog, pending=False): """Write nodemap data on disk for a given revlog """ if getattr(revlog, 'filteredrevs', ()): raise error.ProgrammingError( "cannot persist nodemap of a filtered changelog" ) if revlog.nodemap_file is None: msg = "calling persist nodemap on a revlog without the feature enableb" raise error.ProgrammingError(msg) can_incremental = util.safehasattr(revlog.index, "nodemap_data_incremental") ondisk_docket = revlog._nodemap_docket feed_data = util.safehasattr(revlog.index, "update_nodemap_data") use_mmap = revlog.opener.options.get(b"persistent-nodemap.mmap") mode = revlog.opener.options.get(b"persistent-nodemap.mode") if not can_incremental: msg = _(b"persistent nodemap in strict mode without efficient method") if mode == b'warn': tr._report(b"%s\n" % msg) elif mode == b'strict': raise error.Abort(msg) data = None # first attemp an incremental update of the data if can_incremental and ondisk_docket is not None: target_docket = revlog._nodemap_docket.copy() ( src_docket, data_changed_count, data, ) = revlog.index.nodemap_data_incremental() new_length = target_docket.data_length + len(data) new_unused = target_docket.data_unused + data_changed_count if src_docket != target_docket: data = None elif new_length <= (new_unused * 10): # under 10% of unused data data = None else: datafile = _rawdata_filepath(revlog, target_docket) # EXP-TODO: if this is a cache, this should use a cache vfs, not a # store vfs tr.add(datafile, target_docket.data_length) with revlog.opener(datafile, b'r+') as fd: fd.seek(target_docket.data_length) fd.write(data) if feed_data: if use_mmap: fd.seek(0) new_data = fd.read(new_length) else: fd.flush() new_data = util.buffer(util.mmapread(fd, new_length)) target_docket.data_length = new_length target_docket.data_unused = new_unused if data is None: # otherwise fallback to a full new export target_docket = NodeMapDocket() datafile = _rawdata_filepath(revlog, target_docket) if util.safehasattr(revlog.index, "nodemap_data_all"): data = revlog.index.nodemap_data_all() else: data = persistent_data(revlog.index) # EXP-TODO: if this is a cache, this should use a cache vfs, not a # store vfs tryunlink = revlog.opener.tryunlink def abortck(tr): tryunlink(datafile) callback_id = b"delete-%s" % datafile # some flavor of the transaction abort does not cleanup new file, it # simply empty them. tr.addabort(callback_id, abortck) with revlog.opener(datafile, b'w+') as fd: fd.write(data) if feed_data: if use_mmap: new_data = data else: fd.flush() new_data = util.buffer(util.mmapread(fd, len(data))) target_docket.data_length = len(data) target_docket.tip_rev = revlog.tiprev() target_docket.tip_node = revlog.node(target_docket.tip_rev) # EXP-TODO: if this is a cache, this should use a cache vfs, not a # store vfs file_path = revlog.nodemap_file if pending: file_path += b'.a' tr.registertmp(file_path) else: tr.addbackup(file_path) with revlog.opener(file_path, b'w', atomictemp=True) as fp: fp.write(target_docket.serialize()) revlog._nodemap_docket = target_docket if feed_data: revlog.index.update_nodemap_data(target_docket, new_data) # search for old index file in all cases, some older process might have # left one behind. olds = _other_rawdata_filepath(revlog, target_docket) if olds: realvfs = getattr(revlog, '_realopener', revlog.opener) def cleanup(tr): for oldfile in olds: realvfs.tryunlink(oldfile) callback_id = b"revlog-cleanup-nodemap-%s" % revlog.nodemap_file tr.addpostclose(callback_id, cleanup) ### Nodemap docket file # # The nodemap data are stored on disk using 2 files: # # * a raw data files containing a persistent nodemap # (see `Nodemap Trie` section) # # * a small "docket" file containing medatadata # # While the nodemap data can be multiple tens of megabytes, the "docket" is # small, it is easy to update it automatically or to duplicated its content # during a transaction. # # Multiple raw data can exist at the same time (The currently valid one and a # new one beind used by an in progress transaction). To accomodate this, the # filename hosting the raw data has a variable parts. The exact filename is # specified inside the "docket" file. # # The docket file contains information to find, qualify and validate the raw # data. Its content is currently very light, but it will expand as the on disk # nodemap gains the necessary features to be used in production. ONDISK_VERSION = 1 S_VERSION = struct.Struct(">B") S_HEADER = struct.Struct(">BQQQQ") ID_SIZE = 8 def _make_uid(): """return a new unique identifier. The identifier is random and composed of ascii characters.""" return nodemod.hex(os.urandom(ID_SIZE)) class NodeMapDocket(object): """metadata associated with persistent nodemap data The persistent data may come from disk or be on their way to disk. """ def __init__(self, uid=None): if uid is None: uid = _make_uid() # a unique identifier for the data file: # - When new data are appended, it is preserved. # - When a new data file is created, a new identifier is generated. self.uid = uid # the tipmost revision stored in the data file. This revision and all # revision before it are expected to be encoded in the data file. self.tip_rev = None # the node of that tipmost revision, if it mismatch the current index # data the docket is not valid for the current index and should be # discarded. # # note: this method is not perfect as some destructive operation could # preserve the same tip_rev + tip_node while altering lower revision. # However this multiple other caches have the same vulnerability (eg: # brancmap cache). self.tip_node = None # the size (in bytes) of the persisted data to encode the nodemap valid # for `tip_rev`. # - data file shorter than this are corrupted, # - any extra data should be ignored. self.data_length = None # the amount (in bytes) of "dead" data, still in the data file but no # longer used for the nodemap. self.data_unused = 0 def copy(self): new = NodeMapDocket(uid=self.uid) new.tip_rev = self.tip_rev new.tip_node = self.tip_node new.data_length = self.data_length new.data_unused = self.data_unused return new def __cmp__(self, other): if self.uid < other.uid: return -1 if self.uid > other.uid: return 1 elif self.data_length < other.data_length: return -1 elif self.data_length > other.data_length: return 1 return 0 def __eq__(self, other): return self.uid == other.uid and self.data_length == other.data_length def serialize(self): """return serialized bytes for a docket using the passed uid""" data = [] data.append(S_VERSION.pack(ONDISK_VERSION)) headers = ( len(self.uid), self.tip_rev, self.data_length, self.data_unused, len(self.tip_node), ) data.append(S_HEADER.pack(*headers)) data.append(self.uid) data.append(self.tip_node) return b''.join(data) def _rawdata_filepath(revlog, docket): """The (vfs relative) nodemap's rawdata file for a given uid""" if revlog.nodemap_file.endswith(b'.n.a'): prefix = revlog.nodemap_file[:-4] else: prefix = revlog.nodemap_file[:-2] return b"%s-%s.nd" % (prefix, docket.uid) def _other_rawdata_filepath(revlog, docket): prefix = revlog.nodemap_file[:-2] pattern = re.compile(br"(^|/)%s-[0-9a-f]+\.nd$" % prefix) new_file_path = _rawdata_filepath(revlog, docket) new_file_name = revlog.opener.basename(new_file_path) dirpath = revlog.opener.dirname(new_file_path) others = [] for f in revlog.opener.listdir(dirpath): if pattern.match(f) and f != new_file_name: others.append(f) return others ### Nodemap Trie # # This is a simple reference implementation to compute and persist a nodemap # trie. This reference implementation is write only. The python version of this # is not expected to be actually used, since it wont provide performance # improvement over existing non-persistent C implementation. # # The nodemap is persisted as Trie using 4bits-address/16-entries block. each # revision can be adressed using its node shortest prefix. # # The trie is stored as a sequence of block. Each block contains 16 entries # (signed 64bit integer, big endian). Each entry can be one of the following: # # * value >= 0 -> index of sub-block # * value == -1 -> no value # * value < -1 -> a revision value: rev = -(value+10) # # The implementation focus on simplicity, not on performance. A Rust # implementation should provide a efficient version of the same binary # persistence. This reference python implementation is never meant to be # extensively use in production. def persistent_data(index): """return the persistent binary form for a nodemap for a given index """ trie = _build_trie(index) return _persist_trie(trie) def update_persistent_data(index, root, max_idx, last_rev): """return the incremental update for persistent nodemap from a given index """ changed_block, trie = _update_trie(index, root, last_rev) return ( changed_block * S_BLOCK.size, _persist_trie(trie, existing_idx=max_idx), ) S_BLOCK = struct.Struct(">" + ("l" * 16)) NO_ENTRY = -1 # rev 0 need to be -2 because 0 is used by block, -1 is a special value. REV_OFFSET = 2 def _transform_rev(rev): """Return the number used to represent the rev in the tree. (or retrieve a rev number from such representation) Note that this is an involution, a function equal to its inverse (i.e. which gives the identity when applied to itself). """ return -(rev + REV_OFFSET) def _to_int(hex_digit): """turn an hexadecimal digit into a proper integer""" return int(hex_digit, 16) class Block(dict): """represent a block of the Trie contains up to 16 entry indexed from 0 to 15""" def __init__(self): super(Block, self).__init__() # If this block exist on disk, here is its ID self.ondisk_id = None def __iter__(self): return iter(self.get(i) for i in range(16)) def _build_trie(index): """build a nodemap trie The nodemap stores revision number for each unique prefix. Each block is a dictionary with keys in `[0, 15]`. Values are either another block or a revision number. """ root = Block() for rev in range(len(index)): hex = nodemod.hex(index[rev][7]) _insert_into_block(index, 0, root, rev, hex) return root def _update_trie(index, root, last_rev): """consume""" changed = 0 for rev in range(last_rev + 1, len(index)): hex = nodemod.hex(index[rev][7]) changed += _insert_into_block(index, 0, root, rev, hex) return changed, root def _insert_into_block(index, level, block, current_rev, current_hex): """insert a new revision in a block index: the index we are adding revision for level: the depth of the current block in the trie block: the block currently being considered current_rev: the revision number we are adding current_hex: the hexadecimal representation of the of that revision """ changed = 1 if block.ondisk_id is not None: block.ondisk_id = None hex_digit = _to_int(current_hex[level : level + 1]) entry = block.get(hex_digit) if entry is None: # no entry, simply store the revision number block[hex_digit] = current_rev elif isinstance(entry, dict): # need to recurse to an underlying block changed += _insert_into_block( index, level + 1, entry, current_rev, current_hex ) else: # collision with a previously unique prefix, inserting new # vertices to fit both entry. other_hex = nodemod.hex(index[entry][7]) other_rev = entry new = Block() block[hex_digit] = new _insert_into_block(index, level + 1, new, other_rev, other_hex) _insert_into_block(index, level + 1, new, current_rev, current_hex) return changed def _persist_trie(root, existing_idx=None): """turn a nodemap trie into persistent binary data See `_build_trie` for nodemap trie structure""" block_map = {} if existing_idx is not None: base_idx = existing_idx + 1 else: base_idx = 0 chunks = [] for tn in _walk_trie(root): if tn.ondisk_id is not None: block_map[id(tn)] = tn.ondisk_id else: block_map[id(tn)] = len(chunks) + base_idx chunks.append(_persist_block(tn, block_map)) return b''.join(chunks) def _walk_trie(block): """yield all the block in a trie Children blocks are always yield before their parent block. """ for (__, item) in sorted(block.items()): if isinstance(item, dict): for sub_block in _walk_trie(item): yield sub_block yield block def _persist_block(block_node, block_map): """produce persistent binary data for a single block Children block are assumed to be already persisted and present in block_map. """ data = tuple(_to_value(v, block_map) for v in block_node) return S_BLOCK.pack(*data) def _to_value(item, block_map): """persist any value as an integer""" if item is None: return NO_ENTRY elif isinstance(item, dict): return block_map[id(item)] else: return _transform_rev(item) def parse_data(data): """parse parse nodemap data into a nodemap Trie""" if (len(data) % S_BLOCK.size) != 0: msg = "nodemap data size is not a multiple of block size (%d): %d" raise error.Abort(msg % (S_BLOCK.size, len(data))) if not data: return Block(), None block_map = {} new_blocks = [] for i in range(0, len(data), S_BLOCK.size): block = Block() block.ondisk_id = len(block_map) block_map[block.ondisk_id] = block block_data = data[i : i + S_BLOCK.size] values = S_BLOCK.unpack(block_data) new_blocks.append((block, values)) for b, values in new_blocks: for idx, v in enumerate(values): if v == NO_ENTRY: continue elif v >= 0: b[idx] = block_map[v] else: b[idx] = _transform_rev(v) return block, i // S_BLOCK.size # debug utility def check_data(ui, index, data): """verify that the provided nodemap data are valid for the given idex""" ret = 0 ui.status((b"revision in index: %d\n") % len(index)) root, __ = parse_data(data) all_revs = set(_all_revisions(root)) ui.status((b"revision in nodemap: %d\n") % len(all_revs)) for r in range(len(index)): if r not in all_revs: msg = b" revision missing from nodemap: %d\n" % r ui.write_err(msg) ret = 1 else: all_revs.remove(r) nm_rev = _find_node(root, nodemod.hex(index[r][7])) if nm_rev is None: msg = b" revision node does not match any entries: %d\n" % r ui.write_err(msg) ret = 1 elif nm_rev != r: msg = ( b" revision node does not match the expected revision: " b"%d != %d\n" % (r, nm_rev) ) ui.write_err(msg) ret = 1 if all_revs: for r in sorted(all_revs): msg = b" extra revision in nodemap: %d\n" % r ui.write_err(msg) ret = 1 return ret def _all_revisions(root): """return all revisions stored in a Trie""" for block in _walk_trie(root): for v in block: if v is None or isinstance(v, Block): continue yield v def _find_node(block, node): """find the revision associated with a given node""" entry = block.get(_to_int(node[0:1])) if isinstance(entry, dict): return _find_node(entry, node[1:]) return entry