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# Copyright (C) 2006, 2007 Canonical Ltd
#
# This program is free software; you can redistribute it and/or modify
# it under the terms of the GNU General Public License as published by
# the Free Software Foundation; either version 2 of the License, or
# (at your option) any later version.
#
# This program is distributed in the hope that it will be useful,
# but WITHOUT ANY WARRANTY; without even the implied warranty of
# MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
# GNU General Public License for more details.
#
# You should have received a copy of the GNU General Public License
# along with this program; if not, write to the Free Software
# Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
"""DirState objects record the state of a directory and its bzr metadata.
Pseudo EBNF grammar for the state file. Fields are separated by NULLs, and
lines by NL. The field delimiters are ommitted in the grammar, line delimiters
are not - this is done for clarity of reading. All string data is in utf8.
MINIKIND = "f" | "d" | "l" | "a" | "r" | "t";
NL = "\n";
NULL = "\0";
WHOLE_NUMBER = {digit}, digit;
BOOLEAN = "y" | "n";
REVISION_ID = a non-empty utf8 string;
dirstate format = header line, full checksum, row count, parent details,
ghost_details, entries;
header line = "#bazaar dirstate flat format 2", NL;
full checksum = "crc32: ", ["-"], WHOLE_NUMBER, NL;
row count = "num_entries: ", digit, NL;
parent_details = WHOLE NUMBER, {REVISION_ID}* NL;
ghost_details = WHOLE NUMBER, {REVISION_ID}*, NL;
entries = {entry};
entry = entry_key, current_entry_details, {parent_entry_details};
entry_key = dirname, basename, fileid;
current_entry_details = common_entry_details, working_entry_details;
parent_entry_details = common_entry_details, history_entry_details;
common_entry_details = MINIKIND, fingerprint, size, executable
working_entry_details = packed_stat
history_entry_details = REVISION_ID;
executable = BOOLEAN;
size = WHOLE_NUMBER;
fingerprint = a nonempty utf8 sequence with meaning defined by minikind.
Given this definition, the following is useful to know:
entry (aka row) - all the data for a given key.
entry[0]: The key (dirname, basename, fileid)
entry[0][0]: dirname
entry[0][1]: basename
entry[0][2]: fileid
entry[1]: The tree(s) data for this path and id combination.
entry[1][0]: The current tree
entry[1][1]: The second tree
For an entry for a tree, we have (using tree 0 - current tree) to demonstrate:
entry[1][0][0]: minikind
entry[1][0][1]: fingerprint
entry[1][0][2]: size
entry[1][0][3]: executable
entry[1][0][4]: packed_stat
OR (for non tree-0)
entry[1][1][4]: revision_id
There may be multiple rows at the root, one per id present in the root, so the
in memory root row is now:
self._dirblocks[0] -> ('', [entry ...]),
and the entries in there are
entries[0][0]: ''
entries[0][1]: ''
entries[0][2]: file_id
entries[1][0]: The tree data for the current tree for this fileid at /
etc.
Kinds:
'r' is a relocated entry: This path is not present in this tree with this id,
but the id can be found at another location. The fingerprint is used to
point to the target location.
'a' is an absent entry: In that tree the id is not present at this path.
'd' is a directory entry: This path in this tree is a directory with the
current file id. There is no fingerprint for directories.
'f' is a file entry: As for directory, but its a file. The fingerprint is a
sha1 value.
'l' is a symlink entry: As for directory, but a symlink. The fingerprint is the
link target.
't' is a reference to a nested subtree; the fingerprint is the referenced
revision.
Ordering:
The entries on disk and in memory are ordered according to the following keys:
directory, as a list of components
filename
file-id
--- Format 1 had the following different definition: ---
rows = dirname, NULL, basename, NULL, MINIKIND, NULL, fileid_utf8, NULL,
WHOLE NUMBER (* size *), NULL, packed stat, NULL, sha1|symlink target,
{PARENT ROW}
PARENT ROW = NULL, revision_utf8, NULL, MINIKIND, NULL, dirname, NULL,
basename, NULL, WHOLE NUMBER (* size *), NULL, "y" | "n", NULL,
SHA1
PARENT ROW's are emitted for every parent that is not in the ghosts details
line. That is, if the parents are foo, bar, baz, and the ghosts are bar, then
each row will have a PARENT ROW for foo and baz, but not for bar.
In any tree, a kind of 'moved' indicates that the fingerprint field
(which we treat as opaque data specific to the 'kind' anyway) has the
details for the id of this row in that tree.
I'm strongly tempted to add a id->path index as well, but I think that
where we need id->path mapping; we also usually read the whole file, so
I'm going to skip that for the moment, as we have the ability to locate
via bisect any path in any tree, and if we lookup things by path, we can
accumulate a id->path mapping as we go, which will tend to match what we
looked for.
I plan to implement this asap, so please speak up now to alter/tweak the
design - and once we stabilise on this, I'll update the wiki page for
it.
The rationale for all this is that we want fast operations for the
common case (diff/status/commit/merge on all files) and extremely fast
operations for the less common but still occurs a lot status/diff/commit
on specific files). Operations on specific files involve a scan for all
the children of a path, *in every involved tree*, which the current
format did not accommodate.
----
Design priorities:
1) Fast end to end use for bzr's top 5 uses cases. (commmit/diff/status/merge/???)
2) fall back current object model as needed.
3) scale usably to the largest trees known today - say 50K entries. (mozilla
is an example of this)
Locking:
Eventually reuse dirstate objects across locks IFF the dirstate file has not
been modified, but will require that we flush/ignore cached stat-hit data
because we wont want to restat all files on disk just because a lock was
acquired, yet we cannot trust the data after the previous lock was released.
Memory representation:
vector of all directories, and vector of the childen ?
i.e.
root_entrie = (direntry for root, [parent_direntries_for_root]),
dirblocks = [
('', ['data for achild', 'data for bchild', 'data for cchild'])
('dir', ['achild', 'cchild', 'echild'])
]
- single bisect to find N subtrees from a path spec
- in-order for serialisation - this is 'dirblock' grouping.
- insertion of a file '/a' affects only the '/' child-vector, that is, to
insert 10K elements from scratch does not generates O(N^2) memoves of a
single vector, rather each individual, which tends to be limited to a
manageable number. Will scale badly on trees with 10K entries in a
single directory. compare with Inventory.InventoryDirectory which has
a dictionary for the children. No bisect capability, can only probe for
exact matches, or grab all elements and sorta.
- Whats the risk of error here? Once we have the base format being processed
we should have a net win regardless of optimality. So we are going to
go with what seems reasonably.
open questions:
maybe we should do a test profile of these core structure - 10K simulated searches/lookups/etc?
Objects for each row?
The lifetime of Dirstate objects is current per lock, but see above for
possible extensions. The lifetime of a row from a dirstate is expected to be
very short in the optimistic case: which we are optimising for. For instance,
subtree status will determine from analysis of the disk data what rows need to
be examined at all, and will be able to determine from a single row whether
that file has altered or not, so we are aiming to process tens of thousands of
entries each second within the dirstate context, before exposing anything to
the larger codebase. This suggests we want the time for a single file
comparison to be < 0.1 milliseconds. That would give us 10000 paths per second
processed, and to scale to 100 thousand we'll another order of magnitude to do
that. Now, as the lifetime for all unchanged entries is the time to parse, stat
the file on disk, and then immediately discard, the overhead of object creation
becomes a significant cost.
Figures: Creating a tuple from from 3 elements was profiled at 0.0625
microseconds, whereas creating a object which is subclassed from tuple was
0.500 microseconds, and creating an object with 3 elements and slots was 3
microseconds long. 0.1 milliseconds is 100 microseconds, and ideally we'll get
down to 10 microseconds for the total processing - having 33% of that be object
creation is a huge overhead. There is a potential cost in using tuples within
each row which is that the conditional code to do comparisons may be slower
than method invocation, but method invocation is known to be slow due to stack
frame creation, so avoiding methods in these tight inner loops in unfortunately
desirable. We can consider a pyrex version of this with objects in future if
desired.
"""
import base64
import bisect
import errno
import os
from stat import S_IEXEC
import struct
import sys
import time
import zlib
from bzrlib import (
errors,
inventory,
lock,
osutils,
trace,
)
class _Bisector(object):
"""This just keeps track of information as we are bisecting."""
class DirState(object):
"""Record directory and metadata state for fast access.
A dirstate is a specialised data structure for managing local working
tree state information. Its not yet well defined whether it is platform
specific, and if it is how we detect/parameterise that.
Dirstates use the usual lock_write, lock_read and unlock mechanisms.
Unlike most bzr disk formats, DirStates must be locked for reading, using
lock_read. (This is an os file lock internally.) This is necessary
because the file can be rewritten in place.
DirStates must be explicitly written with save() to commit changes; just
unlocking them does not write the changes to disk.
"""
_kind_to_minikind = {
'absent': 'a',
'file': 'f',
'directory': 'd',
'relocated': 'r',
'symlink': 'l',
'tree-reference': 't',
}
_minikind_to_kind = {
'a': 'absent',
'f': 'file',
'd': 'directory',
'l':'symlink',
'r': 'relocated',
't': 'tree-reference',
}
_to_yesno = {True:'y', False: 'n'} # TODO profile the performance gain
# of using int conversion rather than a dict here. AND BLAME ANDREW IF
# it is faster.
# TODO: jam 20070221 Figure out what to do if we have a record that exceeds
# the BISECT_PAGE_SIZE. For now, we just have to make it large enough
# that we are sure a single record will always fit.
BISECT_PAGE_SIZE = 4096
NOT_IN_MEMORY = 0
IN_MEMORY_UNMODIFIED = 1
IN_MEMORY_MODIFIED = 2
# A pack_stat (the x's) that is just noise and will never match the output
# of base64 encode.
NULLSTAT = 'x' * 32
NULL_PARENT_DETAILS = ('a', '', 0, False, '')
HEADER_FORMAT_2 = '#bazaar dirstate flat format 2\n'
HEADER_FORMAT_3 = '#bazaar dirstate flat format 3\n'
def __init__(self, path):
"""Create a DirState object.
Attributes of note:
:attr _root_entrie: The root row of the directory/file information,
- contains the path to / - '', ''
- kind of 'directory',
- the file id of the root in utf8
- size of 0
- a packed state
- and no sha information.
:param path: The path at which the dirstate file on disk should live.
"""
# _header_state and _dirblock_state represent the current state
# of the dirstate metadata and the per-row data respectiely.
# NOT_IN_MEMORY indicates that no data is in memory
# IN_MEMORY_UNMODIFIED indicates that what we have in memory
# is the same as is on disk
# IN_MEMORY_MODIFIED indicates that we have a modified version
# of what is on disk.
# In future we will add more granularity, for instance _dirblock_state
# will probably support partially-in-memory as a separate variable,
# allowing for partially-in-memory unmodified and partially-in-memory
# modified states.
self._header_state = DirState.NOT_IN_MEMORY
self._dirblock_state = DirState.NOT_IN_MEMORY
self._dirblocks = []
self._ghosts = []
self._parents = []
self._state_file = None
self._filename = path
self._lock_token = None
self._lock_state = None
self._id_index = None
self._end_of_header = None
self._cutoff_time = None
self._split_path_cache = {}
self._bisect_page_size = DirState.BISECT_PAGE_SIZE
def __repr__(self):
return "%s(%r)" % \
(self.__class__.__name__, self._filename)
def add(self, path, file_id, kind, stat, fingerprint):
"""Add a path to be tracked.
:param path: The path within the dirstate - '' is the root, 'foo' is the
path foo within the root, 'foo/bar' is the path bar within foo
within the root.
:param file_id: The file id of the path being added.
:param kind: The kind of the path, as a string like 'file',
'directory', etc.
:param stat: The output of os.lstat for the path.
:param fingerprint: The sha value of the file,
or the target of a symlink,
or the referenced revision id for tree-references,
or '' for directories.
"""
# adding a file:
# find the block its in.
# find the location in the block.
# check its not there
# add it.
#------- copied from inventory.make_entry
# --- normalized_filename wants a unicode basename only, so get one.
dirname, basename = osutils.split(path)
# we dont import normalized_filename directly because we want to be
# able to change the implementation at runtime for tests.
norm_name, can_access = osutils.normalized_filename(basename)
if norm_name != basename:
if can_access:
basename = norm_name
else:
raise errors.InvalidNormalization(path)
# you should never have files called . or ..; just add the directory
# in the parent, or according to the special treatment for the root
if basename == '.' or basename == '..':
raise errors.InvalidEntryName(path)
# now that we've normalised, we need the correct utf8 path and
# dirname and basename elements. This single encode and split should be
# faster than three separate encodes.
utf8path = (dirname + '/' + basename).strip('/').encode('utf8')
dirname, basename = osutils.split(utf8path)
assert file_id.__class__ == str, \
"must be a utf8 file_id not %s" % (type(file_id))
# Make sure the file_id does not exist in this tree
file_id_entry = self._get_entry(0, fileid_utf8=file_id)
if file_id_entry != (None, None):
path = osutils.pathjoin(file_id_entry[0][0], file_id_entry[0][1])
kind = DirState._minikind_to_kind[file_id_entry[1][0][0]]
info = '%s:%s' % (kind, path)
raise errors.DuplicateFileId(file_id, info)
first_key = (dirname, basename, '')
block_index, present = self._find_block_index_from_key(first_key)
if present:
# check the path is not in the tree
block = self._dirblocks[block_index][1]
entry_index, _ = self._find_entry_index(first_key, block)
while (entry_index < len(block) and
block[entry_index][0][0:2] == first_key[0:2]):
if block[entry_index][1][0][0] not in 'ar':
# this path is in the dirstate in the current tree.
raise Exception, "adding already added path!"
entry_index += 1
else:
# The block where we want to put the file is not present. But it
# might be because the directory was empty, or not loaded yet. Look
# for a parent entry, if not found, raise NotVersionedError
parent_dir, parent_base = osutils.split(dirname)
parent_block_idx, parent_entry_idx, _, parent_present = \
self._get_block_entry_index(parent_dir, parent_base, 0)
if not parent_present:
raise errors.NotVersionedError(path, str(self))
self._ensure_block(parent_block_idx, parent_entry_idx, dirname)
block = self._dirblocks[block_index][1]
entry_key = (dirname, basename, file_id)
if stat is None:
size = 0
packed_stat = DirState.NULLSTAT
else:
size = stat.st_size
packed_stat = pack_stat(stat)
parent_info = self._empty_parent_info()
minikind = DirState._kind_to_minikind[kind]
if kind == 'file':
entry_data = entry_key, [
(minikind, fingerprint, size, False, packed_stat),
] + parent_info
elif kind == 'directory':
entry_data = entry_key, [
(minikind, '', 0, False, packed_stat),
] + parent_info
elif kind == 'symlink':
entry_data = entry_key, [
(minikind, fingerprint, size, False, packed_stat),
] + parent_info
elif kind == 'tree-reference':
entry_data = entry_key, [
(minikind, fingerprint, 0, False, packed_stat),
] + parent_info
else:
raise errors.BzrError('unknown kind %r' % kind)
entry_index, present = self._find_entry_index(entry_key, block)
assert not present, "basename %r already added" % basename
block.insert(entry_index, entry_data)
if kind == 'directory':
# insert a new dirblock
self._ensure_block(block_index, entry_index, utf8path)
self._dirblock_state = DirState.IN_MEMORY_MODIFIED
if self._id_index:
self._id_index.setdefault(entry_key[2], set()).add(entry_key)
def _bisect(self, dir_name_list):
"""Bisect through the disk structure for specific rows.
:param dir_name_list: A list of (dir, name) pairs.
:return: A dict mapping (dir, name) => entry for found entries. Missing
entries will not be in the map.
"""
self._requires_lock()
# We need the file pointer to be right after the initial header block
self._read_header_if_needed()
# If _dirblock_state was in memory, we should just return info from
# there, this function is only meant to handle when we want to read
# part of the disk.
assert self._dirblock_state == DirState.NOT_IN_MEMORY
# The disk representation is generally info + '\0\n\0' at the end. But
# for bisecting, it is easier to treat this as '\0' + info + '\0\n'
# Because it means we can sync on the '\n'
state_file = self._state_file
file_size = os.fstat(state_file.fileno()).st_size
# We end up with 2 extra fields, we should have a trailing '\n' to
# ensure that we read the whole record, and we should have a precursur
# '' which ensures that we start after the previous '\n'
entry_field_count = self._fields_per_entry() + 1
low = self._end_of_header
high = file_size - 1 # Ignore the final '\0'
# Map from (dir, name) => entry
found = {}
# Avoid infinite seeking
max_count = 30*len(dir_name_list)
count = 0
# pending is a list of places to look.
# each entry is a tuple of low, high, dir_names
# low -> the first byte offset to read (inclusive)
# high -> the last byte offset (inclusive)
# dir_names -> The list of (dir, name) pairs that should be found in
# the [low, high] range
pending = [(low, high, dir_name_list)]
page_size = self._bisect_page_size
fields_to_entry = self._get_fields_to_entry()
while pending:
low, high, cur_files = pending.pop()
if not cur_files or low >= high:
# Nothing to find
continue
count += 1
if count > max_count:
raise errors.BzrError('Too many seeks, most likely a bug.')
mid = max(low, (low+high-page_size)/2)
state_file.seek(mid)
# limit the read size, so we don't end up reading data that we have
# already read.
read_size = min(page_size, (high-mid)+1)
block = state_file.read(read_size)
start = mid
entries = block.split('\n')
if len(entries) < 2:
# We didn't find a '\n', so we cannot have found any records.
# So put this range back and try again. But we know we have to
# increase the page size, because a single read did not contain
# a record break (so records must be larger than page_size)
page_size *= 2
pending.append((low, high, cur_files))
continue
# Check the first and last entries, in case they are partial, or if
# we don't care about the rest of this page
first_entry_num = 0
first_fields = entries[0].split('\0')
if len(first_fields) < entry_field_count:
# We didn't get the complete first entry
# so move start, and grab the next, which
# should be a full entry
start += len(entries[0])+1
first_fields = entries[1].split('\0')
first_entry_num = 1
if len(first_fields) <= 2:
# We didn't even get a filename here... what do we do?
# Try a large page size and repeat this query
page_size *= 2
pending.append((low, high, cur_files))
continue
else:
# Find what entries we are looking for, which occur before and
# after this first record.
after = start
first_dir_name = (first_fields[1], first_fields[2])
first_loc = bisect.bisect_left(cur_files, first_dir_name)
# These exist before the current location
pre = cur_files[:first_loc]
# These occur after the current location, which may be in the
# data we read, or might be after the last entry
post = cur_files[first_loc:]
if post and len(first_fields) >= entry_field_count:
# We have files after the first entry
# Parse the last entry
last_entry_num = len(entries)-1
last_fields = entries[last_entry_num].split('\0')
if len(last_fields) < entry_field_count:
# The very last hunk was not complete,
# read the previous hunk
after = mid + len(block) - len(entries[-1])
last_entry_num -= 1
last_fields = entries[last_entry_num].split('\0')
else:
after = mid + len(block)
last_dir_name = (last_fields[1], last_fields[2])
last_loc = bisect.bisect_right(post, last_dir_name)
middle_files = post[:last_loc]
post = post[last_loc:]
if middle_files:
# We have files that should occur in this block
# (>= first, <= last)
# Either we will find them here, or we can mark them as
# missing.
if middle_files[0] == first_dir_name:
# We might need to go before this location
pre.append(first_dir_name)
if middle_files[-1] == last_dir_name:
post.insert(0, last_dir_name)
# Find out what paths we have
paths = {first_dir_name:[first_fields]}
# last_dir_name might == first_dir_name so we need to be
# careful if we should append rather than overwrite
if last_entry_num != first_entry_num:
paths.setdefault(last_dir_name, []).append(last_fields)
for num in xrange(first_entry_num+1, last_entry_num):
# TODO: jam 20070223 We are already splitting here, so
# shouldn't we just split the whole thing rather
# than doing the split again in add_one_record?
fields = entries[num].split('\0')
dir_name = (fields[1], fields[2])
paths.setdefault(dir_name, []).append(fields)
for dir_name in middle_files:
for fields in paths.get(dir_name, []):
# offset by 1 because of the opening '\0'
# consider changing fields_to_entry to avoid the
# extra list slice
entry = fields_to_entry(fields[1:])
found.setdefault(dir_name, []).append(entry)
# Now we have split up everything into pre, middle, and post, and
# we have handled everything that fell in 'middle'.
# We add 'post' first, so that we prefer to seek towards the
# beginning, so that we will tend to go as early as we need, and
# then only seek forward after that.
if post:
pending.append((after, high, post))
if pre:
pending.append((low, start-1, pre))
# Consider that we may want to return the directory entries in sorted
# order. For now, we just return them in whatever order we found them,
# and leave it up to the caller if they care if it is ordered or not.
return found
def _bisect_dirblocks(self, dir_list):
"""Bisect through the disk structure to find entries in given dirs.
_bisect_dirblocks is meant to find the contents of directories, which
differs from _bisect, which only finds individual entries.
:param dir_list: An sorted list of directory names ['', 'dir', 'foo'].
:return: A map from dir => entries_for_dir
"""
# TODO: jam 20070223 A lot of the bisecting logic could be shared
# between this and _bisect. It would require parameterizing the
# inner loop with a function, though. We should evaluate the
# performance difference.
self._requires_lock()
# We need the file pointer to be right after the initial header block
self._read_header_if_needed()
# If _dirblock_state was in memory, we should just return info from
# there, this function is only meant to handle when we want to read
# part of the disk.
assert self._dirblock_state == DirState.NOT_IN_MEMORY
# The disk representation is generally info + '\0\n\0' at the end. But
# for bisecting, it is easier to treat this as '\0' + info + '\0\n'
# Because it means we can sync on the '\n'
state_file = self._state_file
file_size = os.fstat(state_file.fileno()).st_size
# We end up with 2 extra fields, we should have a trailing '\n' to
# ensure that we read the whole record, and we should have a precursur
# '' which ensures that we start after the previous '\n'
entry_field_count = self._fields_per_entry() + 1
low = self._end_of_header
high = file_size - 1 # Ignore the final '\0'
# Map from dir => entry
found = {}
# Avoid infinite seeking
max_count = 30*len(dir_list)
count = 0
# pending is a list of places to look.
# each entry is a tuple of low, high, dir_names
# low -> the first byte offset to read (inclusive)
# high -> the last byte offset (inclusive)
# dirs -> The list of directories that should be found in
# the [low, high] range
pending = [(low, high, dir_list)]
page_size = self._bisect_page_size
fields_to_entry = self._get_fields_to_entry()
while pending:
low, high, cur_dirs = pending.pop()
if not cur_dirs or low >= high:
# Nothing to find
continue
count += 1
if count > max_count:
raise errors.BzrError('Too many seeks, most likely a bug.')
mid = max(low, (low+high-page_size)/2)
state_file.seek(mid)
# limit the read size, so we don't end up reading data that we have
# already read.
read_size = min(page_size, (high-mid)+1)
block = state_file.read(read_size)
start = mid
entries = block.split('\n')
if len(entries) < 2:
# We didn't find a '\n', so we cannot have found any records.
# So put this range back and try again. But we know we have to
# increase the page size, because a single read did not contain
# a record break (so records must be larger than page_size)
page_size *= 2
pending.append((low, high, cur_dirs))
continue
# Check the first and last entries, in case they are partial, or if
# we don't care about the rest of this page
first_entry_num = 0
first_fields = entries[0].split('\0')
if len(first_fields) < entry_field_count:
# We didn't get the complete first entry
# so move start, and grab the next, which
# should be a full entry
start += len(entries[0])+1
first_fields = entries[1].split('\0')
first_entry_num = 1
if len(first_fields) <= 1:
# We didn't even get a dirname here... what do we do?
# Try a large page size and repeat this query
page_size *= 2
pending.append((low, high, cur_dirs))
continue
else:
# Find what entries we are looking for, which occur before and
# after this first record.
after = start
first_dir = first_fields[1]
first_loc = bisect.bisect_left(cur_dirs, first_dir)
# These exist before the current location
pre = cur_dirs[:first_loc]
# These occur after the current location, which may be in the
# data we read, or might be after the last entry
post = cur_dirs[first_loc:]
if post and len(first_fields) >= entry_field_count:
# We have records to look at after the first entry
# Parse the last entry
last_entry_num = len(entries)-1
last_fields = entries[last_entry_num].split('\0')
if len(last_fields) < entry_field_count:
# The very last hunk was not complete,
# read the previous hunk
after = mid + len(block) - len(entries[-1])
last_entry_num -= 1
last_fields = entries[last_entry_num].split('\0')
else:
after = mid + len(block)
last_dir = last_fields[1]
last_loc = bisect.bisect_right(post, last_dir)
middle_files = post[:last_loc]
post = post[last_loc:]
if middle_files:
# We have files that should occur in this block
# (>= first, <= last)
# Either we will find them here, or we can mark them as
# missing.
if middle_files[0] == first_dir:
# We might need to go before this location
pre.append(first_dir)
if middle_files[-1] == last_dir:
post.insert(0, last_dir)
# Find out what paths we have
paths = {first_dir:[first_fields]}
# last_dir might == first_dir so we need to be
# careful if we should append rather than overwrite
if last_entry_num != first_entry_num:
paths.setdefault(last_dir, []).append(last_fields)
for num in xrange(first_entry_num+1, last_entry_num):
# TODO: jam 20070223 We are already splitting here, so
# shouldn't we just split the whole thing rather
# than doing the split again in add_one_record?
fields = entries[num].split('\0')
paths.setdefault(fields[1], []).append(fields)
for cur_dir in middle_files:
for fields in paths.get(cur_dir, []):
# offset by 1 because of the opening '\0'
# consider changing fields_to_entry to avoid the
# extra list slice
entry = fields_to_entry(fields[1:])
found.setdefault(cur_dir, []).append(entry)
# Now we have split up everything into pre, middle, and post, and
# we have handled everything that fell in 'middle'.
# We add 'post' first, so that we prefer to seek towards the
# beginning, so that we will tend to go as early as we need, and
# then only seek forward after that.
if post:
pending.append((after, high, post))
if pre:
pending.append((low, start-1, pre))
return found
def _bisect_recursive(self, dir_name_list):
"""Bisect for entries for all paths and their children.
This will use bisect to find all records for the supplied paths. It
will then continue to bisect for any records which are marked as
directories. (and renames?)
:param paths: A sorted list of (dir, name) pairs
eg: [('', 'a'), ('', 'f'), ('a/b', 'c')]
:return: A dictionary mapping (dir, name, file_id) => [tree_info]
"""
# Map from (dir, name, file_id) => [tree_info]
found = {}
found_dir_names = set()
# Directories that have been read
processed_dirs = set()
# Get the ball rolling with the first bisect for all entries.
newly_found = self._bisect(dir_name_list)
while newly_found:
# Directories that need to be read
pending_dirs = set()
paths_to_search = set()
for entry_list in newly_found.itervalues():
for dir_name_id, trees_info in entry_list:
found[dir_name_id] = trees_info
found_dir_names.add(dir_name_id[:2])
is_dir = False
for tree_info in trees_info:
minikind = tree_info[0]
if minikind == 'd':
if is_dir:
# We already processed this one as a directory,
# we don't need to do the extra work again.
continue
subdir, name, file_id = dir_name_id
path = osutils.pathjoin(subdir, name)
is_dir = True
if path not in processed_dirs:
pending_dirs.add(path)
elif minikind == 'r':
# Rename, we need to directly search the target
# which is contained in the fingerprint column
dir_name = osutils.split(tree_info[1])
if dir_name[0] in pending_dirs:
# This entry will be found in the dir search
continue
# TODO: We need to check if this entry has
# already been found. Otherwise we might be
# hitting infinite recursion.
if dir_name not in found_dir_names:
paths_to_search.add(dir_name)
# Now we have a list of paths to look for directly, and
# directory blocks that need to be read.
# newly_found is mixing the keys between (dir, name) and path
# entries, but that is okay, because we only really care about the
# targets.
newly_found = self._bisect(sorted(paths_to_search))
newly_found.update(self._bisect_dirblocks(sorted(pending_dirs)))
processed_dirs.update(pending_dirs)
return found
def _empty_parent_info(self):
return [DirState.NULL_PARENT_DETAILS] * (len(self._parents) -
len(self._ghosts))
def _ensure_block(self, parent_block_index, parent_row_index, dirname):
"""Ensure a block for dirname exists.
This function exists to let callers which know that there is a
directory dirname ensure that the block for it exists. This block can
fail to exist because of demand loading, or because a directory had no
children. In either case it is not an error. It is however an error to
call this if there is no parent entry for the directory, and thus the
function requires the coordinates of such an entry to be provided.
The root row is special cased and can be indicated with a parent block
and row index of -1
:param parent_block_index: The index of the block in which dirname's row
exists.
:param parent_row_index: The index in the parent block where the row
exists.
:param dirname: The utf8 dirname to ensure there is a block for.
:return: The index for the block.
"""
if dirname == '' and parent_row_index == 0 and parent_block_index == 0:
# This is the signature of the root row, and the
# contents-of-root row is always index 1
return 1
# the basename of the directory must be the end of its full name.
if not (parent_block_index == -1 and
parent_block_index == -1 and dirname == ''):
assert dirname.endswith(
self._dirblocks[parent_block_index][1][parent_row_index][0][1])
block_index, present = self._find_block_index_from_key((dirname, '', ''))
if not present:
## In future, when doing partial parsing, this should load and
# populate the entire block.
self._dirblocks.insert(block_index, (dirname, []))
return block_index
def _entries_to_current_state(self, new_entries):
"""Load new_entries into self.dirblocks.
Process new_entries into the current state object, making them the active
state. The entries are grouped together by directory to form dirblocks.
:param new_entries: A sorted list of entries. This function does not sort
to prevent unneeded overhead when callers have a sorted list already.
:return: Nothing.
"""
assert new_entries[0][0][0:2] == ('', ''), \
"Missing root row %r" % (new_entries[0][0],)
# The two blocks here are deliberate: the root block and the
# contents-of-root block.
self._dirblocks = [('', []), ('', [])]
current_block = self._dirblocks[0][1]
current_dirname = ''
root_key = ('', '')
append_entry = current_block.append
for entry in new_entries:
if entry[0][0] != current_dirname:
# new block - different dirname
current_block = []
current_dirname = entry[0][0]
self._dirblocks.append((current_dirname, current_block))
append_entry = current_block.append
# append the entry to the current block
append_entry(entry)
self._split_root_dirblock_into_contents()
def _split_root_dirblock_into_contents(self):
"""Split the root dirblocks into root and contents-of-root.
After parsing by path, we end up with root entries and contents-of-root
entries in the same block. This loop splits them out again.
"""
# The above loop leaves the "root block" entries mixed with the
# "contents-of-root block". But we don't want an if check on
# all entries, so instead we just fix it up here.
assert self._dirblocks[1] == ('', [])
root_block = []
contents_of_root_block = []
for entry in self._dirblocks[0][1]:
if not entry[0][1]: # This is a root entry
root_block.append(entry)
else:
contents_of_root_block.append(entry)
self._dirblocks[0] = ('', root_block)
self._dirblocks[1] = ('', contents_of_root_block)
def _entry_to_line(self, entry):
"""Serialize entry to a NULL delimited line ready for _get_output_lines.
:param entry: An entry_tuple as defined in the module docstring.
"""
entire_entry = list(entry[0])
for tree_number, tree_data in enumerate(entry[1]):
# (minikind, fingerprint, size, executable, tree_specific_string)
entire_entry.extend(tree_data)
# 3 for the key, 5 for the fields per tree.
tree_offset = 3 + tree_number * 5
# minikind
entire_entry[tree_offset + 0] = tree_data[0]
# size
entire_entry[tree_offset + 2] = str(tree_data[2])
# executable
entire_entry[tree_offset + 3] = DirState._to_yesno[tree_data[3]]
return '\0'.join(entire_entry)
def _fields_per_entry(self):
"""How many null separated fields should be in each entry row.
Each line now has an extra '\n' field which is not used
so we just skip over it
entry size:
3 fields for the key
+ number of fields per tree_data (5) * tree count
+ newline
"""
tree_count = 1 + self._num_present_parents()
return 3 + 5 * tree_count + 1
def _find_block(self, key, add_if_missing=False):
"""Return the block that key should be present in.
:param key: A dirstate entry key.
:return: The block tuple.
"""
block_index, present = self._find_block_index_from_key(key)
if not present:
if not add_if_missing:
# check to see if key is versioned itself - we might want to
# add it anyway, because dirs with no entries dont get a
# dirblock at parse time.
# This is an uncommon branch to take: most dirs have children,
# and most code works with versioned paths.
parent_base, parent_name = osutils.split(key[0])
if not self._get_block_entry_index(parent_base, parent_name, 0)[3]:
# some parent path has not been added - its an error to add
# this child
raise errors.NotVersionedError(key[0:2], str(self))
self._dirblocks.insert(block_index, (key[0], []))
return self._dirblocks[block_index]
def _find_block_index_from_key(self, key):
"""Find the dirblock index for a key.
:return: The block index, True if the block for the key is present.
"""
if key[0:2] == ('', ''):
return 0, True
block_index = bisect_dirblock(self._dirblocks, key[0], 1,
cache=self._split_path_cache)
# _right returns one-past-where-key is so we have to subtract
# one to use it. we use _right here because there are two
# '' blocks - the root, and the contents of root
# we always have a minimum of 2 in self._dirblocks: root and
# root-contents, and for '', we get 2 back, so this is
# simple and correct:
present = (block_index < len(self._dirblocks) and
self._dirblocks[block_index][0] == key[0])
return block_index, present
def _find_entry_index(self, key, block):
"""Find the entry index for a key in a block.
:return: The entry index, True if the entry for the key is present.
"""
entry_index = bisect.bisect_left(block, (key, []))
present = (entry_index < len(block) and
block[entry_index][0] == key)
return entry_index, present
@staticmethod
def from_tree(tree, dir_state_filename):
"""Create a dirstate from a bzr Tree.
:param tree: The tree which should provide parent information and
inventory ids.
:return: a DirState object which is currently locked for writing.
(it was locked by DirState.initialize)
"""
result = DirState.initialize(dir_state_filename)
try:
tree.lock_read()
try:
parent_ids = tree.get_parent_ids()
num_parents = len(parent_ids)
parent_trees = []
for parent_id in parent_ids:
parent_tree = tree.branch.repository.revision_tree(parent_id)
parent_trees.append((parent_id, parent_tree))
parent_tree.lock_read()
result.set_parent_trees(parent_trees, [])
result.set_state_from_inventory(tree.inventory)
finally:
for revid, parent_tree in parent_trees:
parent_tree.unlock()
tree.unlock()
except:
# The caller won't have a chance to unlock this, so make sure we
# cleanup ourselves
result.unlock()
raise
return result
def update_entry(self, entry, abspath, stat_value=None):
"""Update the entry based on what is actually on disk.
:param entry: This is the dirblock entry for the file in question.
:param abspath: The path on disk for this file.
:param stat_value: (optional) if we already have done a stat on the
file, re-use it.
:return: The sha1 hexdigest of the file (40 bytes) or link target of a
symlink.
"""
# This code assumes that the entry passed in is directly held in one of
# the internal _dirblocks. So the dirblock state must have already been
# read.
assert self._dirblock_state != DirState.NOT_IN_MEMORY
if stat_value is None:
try:
# We could inline os.lstat but the common case is that
# stat_value will be passed in, not read here.
stat_value = self._lstat(abspath, entry)
except (OSError, IOError), e:
if e.errno in (errno.ENOENT, errno.EACCES,
errno.EPERM):
# The entry is missing, consider it gone
return None
raise
kind = osutils.file_kind_from_stat_mode(stat_value.st_mode)
try:
minikind = DirState._kind_to_minikind[kind]
except KeyError: # Unknown kind
return None
packed_stat = pack_stat(stat_value)
(saved_minikind, saved_link_or_sha1, saved_file_size,
saved_executable, saved_packed_stat) = entry[1][0]
if (minikind == saved_minikind
and packed_stat == saved_packed_stat
# size should also be in packed_stat
and saved_file_size == stat_value.st_size):
# The stat hasn't changed since we saved, so we can potentially
# re-use the saved sha hash.
if minikind == 'd':
return None
if self._cutoff_time is None:
self._sha_cutoff_time()
if (stat_value.st_mtime < self._cutoff_time
and stat_value.st_ctime < self._cutoff_time):
# Return the existing fingerprint
return saved_link_or_sha1
# If we have gotten this far, that means that we need to actually
# process this entry.
link_or_sha1 = None
if minikind == 'f':
link_or_sha1 = self._sha1_file(abspath, entry)
executable = self._is_executable(stat_value.st_mode,
saved_executable)
entry[1][0] = ('f', link_or_sha1, stat_value.st_size,
executable, packed_stat)
elif minikind == 'd':
link_or_sha1 = None
entry[1][0] = ('d', '', 0, False, packed_stat)
if saved_minikind != 'd':
# This changed from something into a directory. Make sure we
# have a directory block for it. This doesn't happen very
# often, so this doesn't have to be super fast.
block_index, entry_index, dir_present, file_present = \
self._get_block_entry_index(entry[0][0], entry[0][1], 0)
self._ensure_block(block_index, entry_index,
osutils.pathjoin(entry[0][0], entry[0][1]))
elif minikind == 'l':
link_or_sha1 = self._read_link(abspath, saved_link_or_sha1)
entry[1][0] = ('l', link_or_sha1, stat_value.st_size,
False, packed_stat)
self._dirblock_state = DirState.IN_MEMORY_MODIFIED
return link_or_sha1
def _sha_cutoff_time(self):
"""Return cutoff time.
Files modified more recently than this time are at risk of being
undetectably modified and so can't be cached.
"""
# Cache the cutoff time as long as we hold a lock.
# time.time() isn't super expensive (approx 3.38us), but
# when you call it 50,000 times it adds up.
# For comparison, os.lstat() costs 7.2us if it is hot.
self._cutoff_time = int(time.time()) - 3
return self._cutoff_time
def _lstat(self, abspath, entry):
"""Return the os.lstat value for this path."""
return os.lstat(abspath)
def _sha1_file(self, abspath, entry):
"""Calculate the SHA1 of a file by reading the full text"""
f = file(abspath, 'rb', buffering=65000)
try:
return osutils.sha_file(f)
finally:
f.close()
def _is_executable(self, mode, old_executable):
"""Is this file executable?"""
return bool(S_IEXEC & mode)
def _is_executable_win32(self, mode, old_executable):
"""On win32 the executable bit is stored in the dirstate."""
return old_executable
if sys.platform == 'win32':
_is_executable = _is_executable_win32
def _read_link(self, abspath, old_link):
"""Read the target of a symlink"""
# TODO: jam 200700301 On Win32, this could just return the value
# already in memory. However, this really needs to be done at a
# higher level, because there either won't be anything on disk,
# or the thing on disk will be a file.
return os.readlink(abspath)
def get_ghosts(self):
"""Return a list of the parent tree revision ids that are ghosts."""
self._read_header_if_needed()
return self._ghosts
def get_lines(self):
"""Serialise the entire dirstate to a sequence of lines."""
if (self._header_state == DirState.IN_MEMORY_UNMODIFIED and
self._dirblock_state == DirState.IN_MEMORY_UNMODIFIED):
# read whats on disk.
self._state_file.seek(0)
return self._state_file.readlines()
lines = []
lines.append(self._get_parents_line(self.get_parent_ids()))
lines.append(self._get_ghosts_line(self._ghosts))
# append the root line which is special cased
lines.extend(map(self._entry_to_line, self._iter_entries()))
return self._get_output_lines(lines)
def _get_ghosts_line(self, ghost_ids):
"""Create a line for the state file for ghost information."""
return '\0'.join([str(len(ghost_ids))] + ghost_ids)
def _get_parents_line(self, parent_ids):
"""Create a line for the state file for parents information."""
return '\0'.join([str(len(parent_ids))] + parent_ids)
def _get_fields_to_entry(self):
"""Get a function which converts entry fields into a entry record.
This handles size and executable, as well as parent records.
:return: A function which takes a list of fields, and returns an
appropriate record for storing in memory.
"""
# This is intentionally unrolled for performance
num_present_parents = self._num_present_parents()
if num_present_parents == 0:
def fields_to_entry_0_parents(fields, _int=int):
path_name_file_id_key = (fields[0], fields[1], fields[2])
return (path_name_file_id_key, [
( # Current tree
fields[3], # minikind
fields[4], # fingerprint
_int(fields[5]), # size
fields[6] == 'y', # executable
fields[7], # packed_stat or revision_id
)])
return fields_to_entry_0_parents
elif num_present_parents == 1:
def fields_to_entry_1_parent(fields, _int=int):
path_name_file_id_key = (fields[0], fields[1], fields[2])
return (path_name_file_id_key, [
( # Current tree
fields[3], # minikind
fields[4], # fingerprint
_int(fields[5]), # size
fields[6] == 'y', # executable
fields[7], # packed_stat or revision_id
),
( # Parent 1
fields[8], # minikind
fields[9], # fingerprint
_int(fields[10]), # size
fields[11] == 'y', # executable
fields[12], # packed_stat or revision_id
),
])
return fields_to_entry_1_parent
elif num_present_parents == 2:
def fields_to_entry_2_parents(fields, _int=int):
path_name_file_id_key = (fields[0], fields[1], fields[2])
return (path_name_file_id_key, [
( # Current tree
fields[3], # minikind
fields[4], # fingerprint
_int(fields[5]), # size
fields[6] == 'y', # executable
fields[7], # packed_stat or revision_id
),
( # Parent 1
fields[8], # minikind
fields[9], # fingerprint
_int(fields[10]), # size
fields[11] == 'y', # executable
fields[12], # packed_stat or revision_id
),
( # Parent 2
fields[13], # minikind
fields[14], # fingerprint
_int(fields[15]), # size
fields[16] == 'y', # executable
fields[17], # packed_stat or revision_id
),
])
return fields_to_entry_2_parents
else:
def fields_to_entry_n_parents(fields, _int=int):
path_name_file_id_key = (fields[0], fields[1], fields[2])
trees = [(fields[cur], # minikind
fields[cur+1], # fingerprint
_int(fields[cur+2]), # size
fields[cur+3] == 'y', # executable
fields[cur+4], # stat or revision_id
) for cur in xrange(3, len(fields)-1, 5)]
return path_name_file_id_key, trees
return fields_to_entry_n_parents
def get_parent_ids(self):
"""Return a list of the parent tree ids for the directory state."""
self._read_header_if_needed()
return list(self._parents)
def _get_block_entry_index(self, dirname, basename, tree_index):
"""Get the coordinates for a path in the state structure.
:param dirname: The utf8 dirname to lookup.
:param basename: The utf8 basename to lookup.
:param tree_index: The index of the tree for which this lookup should
be attempted.
:return: A tuple describing where the path is located, or should be
inserted. The tuple contains four fields: the block index, the row
index, anda two booleans are True when the directory is present, and
when the entire path is present. There is no guarantee that either
coordinate is currently reachable unless the found field for it is
True. For instance, a directory not present in the searched tree
may be returned with a value one greater than the current highest
block offset. The directory present field will always be True when
the path present field is True. The directory present field does
NOT indicate that the directory is present in the searched tree,
rather it indicates that there are at least some files in some
tree present there.
"""
self._read_dirblocks_if_needed()
key = dirname, basename, ''
block_index, present = self._find_block_index_from_key(key)
if not present:
# no such directory - return the dir index and 0 for the row.
return block_index, 0, False, False
block = self._dirblocks[block_index][1] # access the entries only
entry_index, present = self._find_entry_index(key, block)
# linear search through present entries at this path to find the one
# requested.
while entry_index < len(block) and block[entry_index][0][1] == basename:
if block[entry_index][1][tree_index][0] not in \
('a', 'r'): # absent, relocated
return block_index, entry_index, True, True
entry_index += 1
return block_index, entry_index, True, False
def _get_entry(self, tree_index, fileid_utf8=None, path_utf8=None):
"""Get the dirstate entry for path in tree tree_index
If either file_id or path is supplied, it is used as the key to lookup.
If both are supplied, the fastest lookup is used, and an error is
raised if they do not both point at the same row.
:param tree_index: The index of the tree we wish to locate this path
in. If the path is present in that tree, the entry containing its
details is returned, otherwise (None, None) is returned
0 is the working tree, higher indexes are successive parent
trees.
:param fileid_utf8: A utf8 file_id to look up.
:param path_utf8: An utf8 path to be looked up.
:return: The dirstate entry tuple for path, or (None, None)
"""
self._read_dirblocks_if_needed()
if path_utf8 is not None:
assert path_utf8.__class__ == str, 'path_utf8 is not a str: %s %s' % (type(path_utf8), path_utf8)
# path lookups are faster
dirname, basename = osutils.split(path_utf8)
block_index, entry_index, dir_present, file_present = \
self._get_block_entry_index(dirname, basename, tree_index)
if not file_present:
return None, None
entry = self._dirblocks[block_index][1][entry_index]
assert entry[0][2] and entry[1][tree_index][0] not in ('a', 'r'), 'unversioned entry?!?!'
if fileid_utf8:
if entry[0][2] != fileid_utf8:
raise errors.BzrError('integrity error ? : mismatching'
' tree_index, file_id and path')
return entry
else:
assert fileid_utf8 is not None
possible_keys = self._get_id_index().get(fileid_utf8, None)
if not possible_keys:
return None, None
for key in possible_keys:
block_index, present = \
self._find_block_index_from_key(key)
# strange, probably indicates an out of date
# id index - for now, allow this.
if not present:
continue
# WARNING: DO not change this code to use _get_block_entry_index
# as that function is not suitable: it does not use the key
# to lookup, and thus the wront coordinates are returned.
block = self._dirblocks[block_index][1]
entry_index, present = self._find_entry_index(key, block)
if present:
entry = self._dirblocks[block_index][1][entry_index]
if entry[1][tree_index][0] in 'fdlt':
# this is the result we are looking for: the
# real home of this file_id in this tree.
return entry
if entry[1][tree_index][0] == 'a':
# there is no home for this entry in this tree
return None, None
assert entry[1][tree_index][0] == 'r', \
"entry %r has invalid minikind %r for tree %r" \
% (entry,
entry[1][tree_index][0],
tree_index)
real_path = entry[1][tree_index][1]
return self._get_entry(tree_index, fileid_utf8=fileid_utf8,
path_utf8=real_path)
return None, None
@classmethod
def initialize(cls, path):
"""Create a new dirstate on path.
The new dirstate will be an empty tree - that is it has no parents,
and only a root node - which has id ROOT_ID.
The object will be write locked when returned to the caller,
unless there was an exception in the writing, in which case it
will be unlocked.
:param path: The name of the file for the dirstate.
:return: A DirState object.
"""
# This constructs a new DirState object on a path, sets the _state_file
# to a new empty file for that path. It then calls _set_data() with our
# stock empty dirstate information - a root with ROOT_ID, no children,
# and no parents. Finally it calls save() to ensure that this data will
# persist.
result = cls(path)
# root dir and root dir contents with no children.
empty_tree_dirblocks = [('', []), ('', [])]
# a new root directory, with a NULLSTAT.
empty_tree_dirblocks[0][1].append(
(('', '', inventory.ROOT_ID), [
('d', '', 0, False, DirState.NULLSTAT),
]))
result.lock_write()
try:
result._set_data([], empty_tree_dirblocks)
result.save()
except:
result.unlock()
raise
return result
def _inv_entry_to_details(self, inv_entry):
"""Convert an inventory entry (from a revision tree) to state details.
:param inv_entry: An inventory entry whose sha1 and link targets can be
relied upon, and which has a revision set.
:return: A details tuple - the details for a single tree at a path +
id.
"""
kind = inv_entry.kind
minikind = DirState._kind_to_minikind[kind]
tree_data = inv_entry.revision
assert len(tree_data) > 0, 'empty revision for the inv_entry.'
if kind == 'directory':
fingerprint = ''
size = 0
executable = False
elif kind == 'symlink':
fingerprint = inv_entry.symlink_target or ''
size = 0
executable = False
elif kind == 'file':
fingerprint = inv_entry.text_sha1 or ''
size = inv_entry.text_size or 0
executable = inv_entry.executable
elif kind == 'tree-reference':
fingerprint = inv_entry.reference_revision or ''
size = 0
executable = False
else:
raise Exception("can't pack %s" % inv_entry)
return (minikind, fingerprint, size, executable, tree_data)
def _iter_entries(self):
"""Iterate over all the entries in the dirstate.
Each yelt item is an entry in the standard format described in the
docstring of bzrlib.dirstate.
"""
self._read_dirblocks_if_needed()
for directory in self._dirblocks:
for entry in directory[1]:
yield entry
def _get_id_index(self):
"""Get an id index of self._dirblocks."""
if self._id_index is None:
id_index = {}
for key, tree_details in self._iter_entries():
id_index.setdefault(key[2], set()).add(key)
self._id_index = id_index
return self._id_index
def _get_output_lines(self, lines):
"""format lines for final output.
:param lines: A sequece of lines containing the parents list and the
path lines.
"""
output_lines = [DirState.HEADER_FORMAT_3]
lines.append('') # a final newline
inventory_text = '\0\n\0'.join(lines)
output_lines.append('crc32: %s\n' % (zlib.crc32(inventory_text),))
# -3, 1 for num parents, 1 for ghosts, 1 for final newline
num_entries = len(lines)-3
output_lines.append('num_entries: %s\n' % (num_entries,))
output_lines.append(inventory_text)
return output_lines
def _make_deleted_row(self, fileid_utf8, parents):
"""Return a deleted for for fileid_utf8."""
return ('/', 'RECYCLED.BIN', 'file', fileid_utf8, 0, DirState.NULLSTAT,
''), parents
def _num_present_parents(self):
"""The number of parent entries in each record row."""
return len(self._parents) - len(self._ghosts)
@staticmethod
def on_file(path):
"""Construct a DirState on the file at path path.
:return: An unlocked DirState object, associated with the given path.
"""
result = DirState(path)
return result
def _read_dirblocks_if_needed(self):
"""Read in all the dirblocks from the file if they are not in memory.
This populates self._dirblocks, and sets self._dirblock_state to
IN_MEMORY_UNMODIFIED. It is not currently ready for incremental block
loading.
"""
self._read_header_if_needed()
if self._dirblock_state == DirState.NOT_IN_MEMORY:
# move the _state_file pointer to after the header (in case bisect
# has been called in the mean time)
self._state_file.seek(self._end_of_header)
text = self._state_file.read()
# TODO: check the crc checksums. crc_measured = zlib.crc32(text)
fields = text.split('\0')
# Remove the last blank entry
trailing = fields.pop()
assert trailing == ''
# consider turning fields into a tuple.
# skip the first field which is the trailing null from the header.
cur = 1
# Each line now has an extra '\n' field which is not used
# so we just skip over it
# entry size:
# 3 fields for the key
# + number of fields per tree_data (5) * tree count
# + newline
num_present_parents = self._num_present_parents()
tree_count = 1 + num_present_parents
entry_size = self._fields_per_entry()
expected_field_count = entry_size * self._num_entries
field_count = len(fields)
# this checks our adjustment, and also catches file too short.
assert field_count - cur == expected_field_count, \
'field count incorrect %s != %s, entry_size=%s, '\
'num_entries=%s fields=%r' % (
field_count - cur, expected_field_count, entry_size,
self._num_entries, fields)
if num_present_parents == 1:
# Bind external functions to local names
_int = int
# We access all fields in order, so we can just iterate over
# them. Grab an straight iterator over the fields. (We use an
# iterator because we don't want to do a lot of additions, nor
# do we want to do a lot of slicing)
next = iter(fields).next
# Move the iterator to the current position
for x in xrange(cur):
next()
# The two blocks here are deliberate: the root block and the
# contents-of-root block.
self._dirblocks = [('', []), ('', [])]
current_block = self._dirblocks[0][1]
current_dirname = ''
append_entry = current_block.append
for count in xrange(self._num_entries):
dirname = next()
name = next()
file_id = next()
if dirname != current_dirname:
# new block - different dirname
current_block = []
current_dirname = dirname
self._dirblocks.append((current_dirname, current_block))
append_entry = current_block.append
# we know current_dirname == dirname, so re-use it to avoid
# creating new strings
entry = ((current_dirname, name, file_id),
[(# Current Tree
next(), # minikind
next(), # fingerprint
_int(next()), # size
next() == 'y', # executable
next(), # packed_stat or revision_id
),
( # Parent 1
next(), # minikind
next(), # fingerprint
_int(next()), # size
next() == 'y', # executable
next(), # packed_stat or revision_id
),
])
trailing = next()
assert trailing == '\n'
# append the entry to the current block
append_entry(entry)
self._split_root_dirblock_into_contents()
else:
fields_to_entry = self._get_fields_to_entry()
entries = [fields_to_entry(fields[pos:pos+entry_size])
for pos in xrange(cur, field_count, entry_size)]
self._entries_to_current_state(entries)
# To convert from format 2 => format 3
# self._dirblocks = sorted(self._dirblocks,
# key=lambda blk:blk[0].split('/'))
# To convert from format 3 => format 2
# self._dirblocks = sorted(self._dirblocks)
self._dirblock_state = DirState.IN_MEMORY_UNMODIFIED
def _read_header(self):
"""This reads in the metadata header, and the parent ids.
After reading in, the file should be positioned at the null
just before the start of the first record in the file.
:return: (expected crc checksum, number of entries, parent list)
"""
self._read_prelude()
parent_line = self._state_file.readline()
info = parent_line.split('\0')
num_parents = int(info[0])
assert num_parents == len(info)-2, 'incorrect parent info line'
self._parents = info[1:-1]
ghost_line = self._state_file.readline()
info = ghost_line.split('\0')
num_ghosts = int(info[1])
assert num_ghosts == len(info)-3, 'incorrect ghost info line'
self._ghosts = info[2:-1]
self._header_state = DirState.IN_MEMORY_UNMODIFIED
self._end_of_header = self._state_file.tell()
def _read_header_if_needed(self):
"""Read the header of the dirstate file if needed."""
# inline this as it will be called a lot
if not self._lock_token:
raise errors.ObjectNotLocked(self)
if self._header_state == DirState.NOT_IN_MEMORY:
self._read_header()
def _read_prelude(self):
"""Read in the prelude header of the dirstate file
This only reads in the stuff that is not connected to the crc
checksum. The position will be correct to read in the rest of
the file and check the checksum after this point.
The next entry in the file should be the number of parents,
and their ids. Followed by a newline.
"""
header = self._state_file.readline()
assert header == DirState.HEADER_FORMAT_3, \
'invalid header line: %r' % (header,)
crc_line = self._state_file.readline()
assert crc_line.startswith('crc32: '), 'missing crc32 checksum'
self.crc_expected = int(crc_line[len('crc32: '):-1])
num_entries_line = self._state_file.readline()
assert num_entries_line.startswith('num_entries: '), 'missing num_entries line'
self._num_entries = int(num_entries_line[len('num_entries: '):-1])
def save(self):
"""Save any pending changes created during this session.
We reuse the existing file, because that prevents race conditions with
file creation, and use oslocks on it to prevent concurrent modification
and reads - because dirstates incremental data aggretation is not
compatible with reading a modified file, and replacing a file in use by
another process is impossible on windows.
A dirstate in read only mode should be smart enough though to validate
that the file has not changed, and otherwise discard its cache and
start over, to allow for fine grained read lock duration, so 'status'
wont block 'commit' - for example.
"""
if (self._header_state == DirState.IN_MEMORY_MODIFIED or
self._dirblock_state == DirState.IN_MEMORY_MODIFIED):
if self._lock_state == 'w':
out_file = self._state_file
wlock = None
else:
# Try to grab a write lock so that we can update the file.
try:
wlock = lock.WriteLock(self._filename)
except (errors.LockError, errors.LockContention), e:
# We couldn't grab the lock, so just leave things dirty in
# memory.
return
except IOError, e:
# This may be a read-only tree, or someone else may have a
# ReadLock. so handle the case when we cannot grab a write
# lock
if e.errno in (errno.ENOENT, errno.EPERM, errno.EACCES,
errno.EAGAIN):
# Ignore these errors and just don't save anything
return
raise
out_file = wlock.f
try:
out_file.seek(0)
out_file.writelines(self.get_lines())
out_file.truncate()
out_file.flush()
self._header_state = DirState.IN_MEMORY_UNMODIFIED
self._dirblock_state = DirState.IN_MEMORY_UNMODIFIED
finally:
if wlock is not None:
wlock.unlock()
def _set_data(self, parent_ids, dirblocks):
"""Set the full dirstate data in memory.
This is an internal function used to completely replace the objects
in memory state. It puts the dirstate into state 'full-dirty'.
:param parent_ids: A list of parent tree revision ids.
:param dirblocks: A list containing one tuple for each directory in the
tree. Each tuple contains the directory path and a list of entries
found in that directory.
"""
# our memory copy is now authoritative.
self._dirblocks = dirblocks
self._header_state = DirState.IN_MEMORY_MODIFIED
self._dirblock_state = DirState.IN_MEMORY_MODIFIED
self._parents = list(parent_ids)
self._id_index = None
def set_path_id(self, path, new_id):
"""Change the id of path to new_id in the current working tree.
:param path: The path inside the tree to set - '' is the root, 'foo'
is the path foo in the root.
:param new_id: The new id to assign to the path. This must be a utf8
file id (not unicode, and not None).
"""
assert new_id.__class__ == str, \
"path_id %r is not a plain string" % (new_id,)
self._read_dirblocks_if_needed()
if len(path):
# logic not written
raise NotImplementedError(self.set_path_id)
# TODO: check new id is unique
entry = self._get_entry(0, path_utf8=path)
if entry[0][2] == new_id:
# Nothing to change.
return
# mark the old path absent, and insert a new root path
self._make_absent(entry)
self.update_minimal(('', '', new_id), 'd',
path_utf8='', packed_stat=entry[1][0][4])
self._dirblock_state = DirState.IN_MEMORY_MODIFIED
if self._id_index is not None:
self._id_index.setdefault(new_id, set()).add(entry[0])
def set_parent_trees(self, trees, ghosts):
"""Set the parent trees for the dirstate.
:param trees: A list of revision_id, tree tuples. tree must be provided
even if the revision_id refers to a ghost: supply an empty tree in
this case.
:param ghosts: A list of the revision_ids that are ghosts at the time
of setting.
"""
self._validate()
# TODO: generate a list of parent indexes to preserve to save
# processing specific parent trees. In the common case one tree will
# be preserved - the left most parent.
# TODO: if the parent tree is a dirstate, we might want to walk them
# all by path in parallel for 'optimal' common-case performance.
# generate new root row.
self._read_dirblocks_if_needed()
# TODO future sketch: Examine the existing parents to generate a change
# map and then walk the new parent trees only, mapping them into the
# dirstate. Walk the dirstate at the same time to remove unreferenced
# entries.
# for now:
# sketch: loop over all entries in the dirstate, cherry picking
# entries from the parent trees, if they are not ghost trees.
# after we finish walking the dirstate, all entries not in the dirstate
# are deletes, so we want to append them to the end as per the design
# discussions. So do a set difference on ids with the parents to
# get deletes, and add them to the end.
# During the update process we need to answer the following questions:
# - find other keys containing a fileid in order to create cross-path
# links. We dont't trivially use the inventory from other trees
# because this leads to either double touching, or to accessing
# missing keys,
# - find other keys containing a path
# We accumulate each entry via this dictionary, including the root
by_path = {}
id_index = {}
# we could do parallel iterators, but because file id data may be
# scattered throughout, we dont save on index overhead: we have to look
# at everything anyway. We can probably save cycles by reusing parent
# data and doing an incremental update when adding an additional
# parent, but for now the common cases are adding a new parent (merge),
# and replacing completely (commit), and commit is more common: so
# optimise merge later.
# ---- start generation of full tree mapping data
# what trees should we use?
parent_trees = [tree for rev_id, tree in trees if rev_id not in ghosts]
# how many trees do we end up with
parent_count = len(parent_trees)
# one: the current tree
for entry in self._iter_entries():
# skip entries not in the current tree
if entry[1][0][0] in ('a', 'r'): # absent, relocated
continue
by_path[entry[0]] = [entry[1][0]] + \
[DirState.NULL_PARENT_DETAILS] * parent_count
id_index[entry[0][2]] = set([entry[0]])
# now the parent trees:
for tree_index, tree in enumerate(parent_trees):
# the index is off by one, adjust it.
tree_index = tree_index + 1
# when we add new locations for a fileid we need these ranges for
# any fileid in this tree as we set the by_path[id] to:
# already_processed_tree_details + new_details + new_location_suffix
# the suffix is from tree_index+1:parent_count+1.
new_location_suffix = [DirState.NULL_PARENT_DETAILS] * (parent_count - tree_index)
# now stitch in all the entries from this tree
for path, entry in tree.inventory.iter_entries_by_dir():
# here we process each trees details for each item in the tree.
# we first update any existing entries for the id at other paths,
# then we either create or update the entry for the id at the
# right path, and finally we add (if needed) a mapping from
# file_id to this path. We do it in this order to allow us to
# avoid checking all known paths for the id when generating a
# new entry at this path: by adding the id->path mapping last,
# all the mappings are valid and have correct relocation
# records where needed.
file_id = entry.file_id
path_utf8 = path.encode('utf8')
dirname, basename = osutils.split(path_utf8)
new_entry_key = (dirname, basename, file_id)
# tree index consistency: All other paths for this id in this tree
# index must point to the correct path.
for entry_key in id_index.setdefault(file_id, set()):
# TODO:PROFILING: It might be faster to just update
# rather than checking if we need to, and then overwrite
# the one we are located at.
if entry_key != new_entry_key:
# this file id is at a different path in one of the
# other trees, so put absent pointers there
# This is the vertical axis in the matrix, all pointing
# tot he real path.
by_path[entry_key][tree_index] = ('r', path_utf8, 0, False, '')
# by path consistency: Insert into an existing path record (trivial), or
# add a new one with relocation pointers for the other tree indexes.
if new_entry_key in id_index[file_id]:
# there is already an entry where this data belongs, just insert it.
by_path[new_entry_key][tree_index] = \
self._inv_entry_to_details(entry)
else:
# add relocated entries to the horizontal axis - this row
# mapping from path,id. We need to look up the correct path
# for the indexes from 0 to tree_index -1
new_details = []
for lookup_index in xrange(tree_index):
# boundary case: this is the first occurence of file_id
# so there are no id_indexs, possibly take this out of
# the loop?
if not len(id_index[file_id]):
new_details.append(DirState.NULL_PARENT_DETAILS)
else:
# grab any one entry, use it to find the right path.
# TODO: optimise this to reduce memory use in highly
# fragmented situations by reusing the relocation
# records.
a_key = iter(id_index[file_id]).next()
if by_path[a_key][lookup_index][0] in ('r', 'a'):
# its a pointer or missing statement, use it as is.
new_details.append(by_path[a_key][lookup_index])
else:
# we have the right key, make a pointer to it.
real_path = ('/'.join(a_key[0:2])).strip('/')
new_details.append(('r', real_path, 0, False, ''))
new_details.append(self._inv_entry_to_details(entry))
new_details.extend(new_location_suffix)
by_path[new_entry_key] = new_details
id_index[file_id].add(new_entry_key)
# --- end generation of full tree mappings
# sort and output all the entries
new_entries = self._sort_entries(by_path.items())
self._entries_to_current_state(new_entries)
self._parents = [rev_id for rev_id, tree in trees]
self._ghosts = list(ghosts)
self._header_state = DirState.IN_MEMORY_MODIFIED
self._dirblock_state = DirState.IN_MEMORY_MODIFIED
self._id_index = id_index
self._validate()
def _sort_entries(self, entry_list):
"""Given a list of entries, sort them into the right order.
This is done when constructing a new dirstate from trees - normally we
try to keep everything in sorted blocks all the time, but sometimes
it's easier to sort after the fact.
"""
# TODO: Might be faster to do a schwartzian transform?
def _key(entry):
# sort by: directory parts, file name, file id
return entry[0][0].split('/'), entry[0][1], entry[0][2]
return sorted(entry_list, key=_key)
def set_state_from_inventory(self, new_inv):
"""Set new_inv as the current state.
This API is called by tree transform, and will usually occur with
existing parent trees.
:param new_inv: The inventory object to set current state from.
"""
self._read_dirblocks_if_needed()
# sketch:
# incremental algorithm:
# two iterators: current data and new data, both in dirblock order.
new_iterator = new_inv.iter_entries_by_dir()
# we will be modifying the dirstate, so we need a stable iterator. In
# future we might write one, for now we just clone the state into a
# list - which is a shallow copy, so each
old_iterator = iter(list(self._iter_entries()))
# both must have roots so this is safe:
current_new = new_iterator.next()
current_old = old_iterator.next()
def advance(iterator):
try:
return iterator.next()
except StopIteration:
return None
while current_new or current_old:
# skip entries in old that are not really there
if current_old and current_old[1][0][0] in ('r', 'a'):
# relocated or absent
current_old = advance(old_iterator)
continue
if current_new:
# convert new into dirblock style
new_path_utf8 = current_new[0].encode('utf8')
new_dirname, new_basename = osutils.split(new_path_utf8)
new_id = current_new[1].file_id
new_entry_key = (new_dirname, new_basename, new_id)
current_new_minikind = \
DirState._kind_to_minikind[current_new[1].kind]
if current_new_minikind == 't':
fingerprint = current_new[1].reference_revision
else:
fingerprint = ''
else:
# for safety disable variables
new_path_utf8 = new_dirname = new_basename = new_id = new_entry_key = None
# 5 cases, we dont have a value that is strictly greater than everything, so
# we make both end conditions explicit
if not current_old:
# old is finished: insert current_new into the state.
self.update_minimal(new_entry_key, current_new_minikind,
executable=current_new[1].executable,
path_utf8=new_path_utf8, fingerprint=fingerprint)
current_new = advance(new_iterator)
elif not current_new:
# new is finished
self._make_absent(current_old)
current_old = advance(old_iterator)
elif new_entry_key == current_old[0]:
# same - common case
# TODO: update the record if anything significant has changed.
# the minimal required trigger is if the execute bit or cached
# kind has changed.
if (current_old[1][0][3] != current_new[1].executable or
current_old[1][0][0] != current_new_minikind):
self.update_minimal(current_old[0], current_new_minikind,
executable=current_new[1].executable,
path_utf8=new_path_utf8, fingerprint=fingerprint)
# both sides are dealt with, move on
current_old = advance(old_iterator)
current_new = advance(new_iterator)
elif new_entry_key < current_old[0]:
# new comes before:
# add a entry for this and advance new
self.update_minimal(new_entry_key, current_new_minikind,
executable=current_new[1].executable,
path_utf8=new_path_utf8, fingerprint=fingerprint)
current_new = advance(new_iterator)
else:
# old comes before:
self._make_absent(current_old)
current_old = advance(old_iterator)
self._dirblock_state = DirState.IN_MEMORY_MODIFIED
self._id_index = None
def _make_absent(self, current_old):
"""Mark current_old - an entry - as absent for tree 0.
:return: True if this was the last details entry for they entry key:
that is, if the underlying block has had the entry removed, thus
shrinking in length.
"""
# build up paths that this id will be left at after the change is made,
# so we can update their cross references in tree 0
all_remaining_keys = set()
# Dont check the working tree, because its going.
for details in current_old[1][1:]:
if details[0] not in ('a', 'r'): # absent, relocated
all_remaining_keys.add(current_old[0])
elif details[0] == 'r': # relocated
# record the key for the real path.
all_remaining_keys.add(tuple(osutils.split(details[1])) + (current_old[0][2],))
# absent rows are not present at any path.
last_reference = current_old[0] not in all_remaining_keys
if last_reference:
# the current row consists entire of the current item (being marked
# absent), and relocated or absent entries for the other trees:
# Remove it, its meaningless.
block = self._find_block(current_old[0])
entry_index, present = self._find_entry_index(current_old[0], block[1])
assert present, 'could not find entry for %s' % (current_old,)
block[1].pop(entry_index)
# if we have an id_index in use, remove this key from it for this id.
if self._id_index is not None:
self._id_index[current_old[0][2]].remove(current_old[0])
# update all remaining keys for this id to record it as absent. The
# existing details may either be the record we are making as deleted
# (if there were other trees with the id present at this path), or may
# be relocations.
for update_key in all_remaining_keys:
update_block_index, present = \
self._find_block_index_from_key(update_key)
assert present, 'could not find block for %s' % (update_key,)
update_entry_index, present = \
self._find_entry_index(update_key, self._dirblocks[update_block_index][1])
assert present, 'could not find entry for %s' % (update_key,)
update_tree_details = self._dirblocks[update_block_index][1][update_entry_index][1]
# it must not be absent at the moment
assert update_tree_details[0][0] != 'a' # absent
update_tree_details[0] = DirState.NULL_PARENT_DETAILS
self._dirblock_state = DirState.IN_MEMORY_MODIFIED
return last_reference
def update_minimal(self, key, minikind, executable=False, fingerprint='',
packed_stat=None, size=0, path_utf8=None):
"""Update an entry to the state in tree 0.
This will either create a new entry at 'key' or update an existing one.
It also makes sure that any other records which might mention this are
updated as well.
:param key: (dir, name, file_id) for the new entry
:param minikind: The type for the entry ('f' == 'file', 'd' ==
'directory'), etc.
:param executable: Should the executable bit be set?
:param fingerprint: Simple fingerprint for new entry.
:param packed_stat: packed stat value for new entry.
:param size: Size information for new entry
:param path_utf8: key[0] + '/' + key[1], just passed in to avoid doing
extra computation.
"""
block = self._find_block(key)[1]
if packed_stat is None:
packed_stat = DirState.NULLSTAT
entry_index, present = self._find_entry_index(key, block)
new_details = (minikind, fingerprint, size, executable, packed_stat)
id_index = self._get_id_index()
if not present:
# new entry, synthesis cross reference here,
existing_keys = id_index.setdefault(key[2], set())
if not existing_keys:
# not currently in the state, simplest case
new_entry = key, [new_details] + self._empty_parent_info()
else:
# present at one or more existing other paths.
# grab one of them and use it to generate parent
# relocation/absent entries.
new_entry = key, [new_details]
for other_key in existing_keys:
# change the record at other to be a pointer to this new
# record. The loop looks similar to the change to
# relocations when updating an existing record but its not:
# the test for existing kinds is different: this can be
# factored out to a helper though.
other_block_index, present = self._find_block_index_from_key(other_key)
assert present, 'could not find block for %s' % (other_key,)
other_entry_index, present = self._find_entry_index(other_key,
self._dirblocks[other_block_index][1])
assert present, 'could not find entry for %s' % (other_key,)
assert path_utf8 is not None
self._dirblocks[other_block_index][1][other_entry_index][1][0] = \
('r', path_utf8, 0, False, '')
num_present_parents = self._num_present_parents()
for lookup_index in xrange(1, num_present_parents + 1):
# grab any one entry, use it to find the right path.
# TODO: optimise this to reduce memory use in highly
# fragmented situations by reusing the relocation
# records.
update_block_index, present = \
self._find_block_index_from_key(other_key)
assert present, 'could not find block for %s' % (other_key,)
update_entry_index, present = \
self._find_entry_index(other_key, self._dirblocks[update_block_index][1])
assert present, 'could not find entry for %s' % (other_key,)
update_details = self._dirblocks[update_block_index][1][update_entry_index][1][lookup_index]
if update_details[0] in ('r', 'a'): # relocated, absent
# its a pointer or absent in lookup_index's tree, use
# it as is.
new_entry[1].append(update_details)
else:
# we have the right key, make a pointer to it.
pointer_path = osutils.pathjoin(*other_key[0:2])
new_entry[1].append(('r', pointer_path, 0, False, ''))
block.insert(entry_index, new_entry)
existing_keys.add(key)
else:
# Does the new state matter?
block[entry_index][1][0] = new_details
# parents cannot be affected by what we do.
# other occurences of this id can be found
# from the id index.
# ---
# tree index consistency: All other paths for this id in this tree
# index must point to the correct path. We have to loop here because
# we may have passed entries in the state with this file id already
# that were absent - where parent entries are - and they need to be
# converted to relocated.
assert path_utf8 is not None
for entry_key in id_index.setdefault(key[2], set()):
# TODO:PROFILING: It might be faster to just update
# rather than checking if we need to, and then overwrite
# the one we are located at.
if entry_key != key:
# this file id is at a different path in one of the
# other trees, so put absent pointers there
# This is the vertical axis in the matrix, all pointing
# to the real path.
block_index, present = self._find_block_index_from_key(entry_key)
assert present
entry_index, present = self._find_entry_index(entry_key, self._dirblocks[block_index][1])
assert present
self._dirblocks[block_index][1][entry_index][1][0] = \
('r', path_utf8, 0, False, '')
# add a containing dirblock if needed.
if new_details[0] == 'd':
subdir_key = (osutils.pathjoin(*key[0:2]), '', '')
block_index, present = self._find_block_index_from_key(subdir_key)
if not present:
self._dirblocks.insert(block_index, (subdir_key[0], []))
self._dirblock_state = DirState.IN_MEMORY_MODIFIED
def _validate(self):
"""Check that invariants on the dirblock are correct.
This can be useful in debugging; it shouldn't be necessary in
normal code.
"""
from pprint import pformat
if len(self._dirblocks) > 0:
assert self._dirblocks[0][0] == '', \
"dirblocks don't start with root block:\n" + \
pformat(dirblocks)
if len(self._dirblocks) > 1:
assert self._dirblocks[1][0] == '', \
"dirblocks missing root directory:\n" + \
pformat(dirblocks)
# the dirblocks are sorted by their path components, name, and dir id
dir_names = [d[0].split('/')
for d in self._dirblocks[1:]]
if dir_names != sorted(dir_names):
raise AssertionError(
"dir names are not in sorted order:\n" + \
pformat(self._dirblocks) + \
"\nkeys:\n" +
pformat(dir_names))
for dirblock in self._dirblocks:
# within each dirblock, the entries are sorted by filename and
# then by id.
assert dirblock[1] == sorted(dirblock[1]), \
"dirblock for %r is not sorted:\n%s" % \
(dirblock[0], pformat(dirblock))
def _wipe_state(self):
"""Forget all state information about the dirstate."""
self._header_state = DirState.NOT_IN_MEMORY
self._dirblock_state = DirState.NOT_IN_MEMORY
self._parents = []
self._ghosts = []
self._dirblocks = []
self._id_index = None
self._end_of_header = None
self._cutoff_time = None
self._split_path_cache = {}
def lock_read(self):
"""Acquire a read lock on the dirstate"""
if self._lock_token is not None:
raise errors.LockContention(self._lock_token)
# TODO: jam 20070301 Rather than wiping completely, if the blocks are
# already in memory, we could read just the header and check for
# any modification. If not modified, we can just leave things
# alone
self._lock_token = lock.ReadLock(self._filename)
self._lock_state = 'r'
self._state_file = self._lock_token.f
self._wipe_state()
def lock_write(self):
"""Acquire a write lock on the dirstate"""
if self._lock_token is not None:
raise errors.LockContention(self._lock_token)
# TODO: jam 20070301 Rather than wiping completely, if the blocks are
# already in memory, we could read just the header and check for
# any modification. If not modified, we can just leave things
# alone
self._lock_token = lock.WriteLock(self._filename)
self._lock_state = 'w'
self._state_file = self._lock_token.f
self._wipe_state()
def unlock(self):
"""Drop any locks held on the dirstate"""
if self._lock_token is None:
raise errors.LockNotHeld(self)
# TODO: jam 20070301 Rather than wiping completely, if the blocks are
# already in memory, we could read just the header and check for
# any modification. If not modified, we can just leave things
# alone
self._state_file = None
self._lock_state = None
self._lock_token.unlock()
self._lock_token = None
self._split_path_cache = {}
def _requires_lock(self):
"""Checks that a lock is currently held by someone on the dirstate"""
if not self._lock_token:
raise errors.ObjectNotLocked(self)
def bisect_dirblock(dirblocks, dirname, lo=0, hi=None, cache={}):
"""Return the index where to insert dirname into the dirblocks.
The return value idx is such that all directories blocks in dirblock[:idx]
have names < dirname, and all blocks in dirblock[idx:] have names >=
dirname.
Optional args lo (default 0) and hi (default len(dirblocks)) bound the
slice of a to be searched.
"""
if hi is None:
hi = len(dirblocks)
try:
dirname_split = cache[dirname]
except KeyError:
dirname_split = dirname.split('/')
cache[dirname] = dirname_split
while lo < hi:
mid = (lo+hi)//2
# Grab the dirname for the current dirblock
cur = dirblocks[mid][0]
try:
cur_split = cache[cur]
except KeyError:
cur_split = cur.split('/')
cache[cur] = cur_split
if cur_split < dirname_split: lo = mid+1
else: hi = mid
return lo
def pack_stat(st, _encode=base64.encodestring, _pack=struct.pack):
"""Convert stat values into a packed representation."""
# jam 20060614 it isn't really worth removing more entries if we
# are going to leave it in packed form.
# With only st_mtime and st_mode filesize is 5.5M and read time is 275ms
# With all entries filesize is 5.9M and read time is mabye 280ms
# well within the noise margin
# base64.encode always adds a final newline, so strip it off
return _encode(_pack('>llllll'
, st.st_size, int(st.st_mtime), int(st.st_ctime)
, st.st_dev, st.st_ino, st.st_mode))[:-1]
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