smartset.py
1066 lines
| 31.9 KiB
| text/x-python
|
PythonLexer
/ mercurial / smartset.py
Yuya Nishihara
|
r30881 | # smartset.py - data structure for revision set | ||
# | ||||
# Copyright 2010 Matt Mackall <mpm@selenic.com> | ||||
# | ||||
# This software may be used and distributed according to the terms of the | ||||
# GNU General Public License version 2 or any later version. | ||||
from __future__ import absolute_import | ||||
from . import ( | ||||
util, | ||||
) | ||||
def _formatsetrepr(r): | ||||
"""Format an optional printable representation of a set | ||||
======== ================================= | ||||
type(r) example | ||||
======== ================================= | ||||
tuple ('<not %r>', other) | ||||
str '<branch closed>' | ||||
callable lambda: '<branch %r>' % sorted(b) | ||||
object other | ||||
======== ================================= | ||||
""" | ||||
if r is None: | ||||
return '' | ||||
elif isinstance(r, tuple): | ||||
return r[0] % r[1:] | ||||
elif isinstance(r, str): | ||||
return r | ||||
elif callable(r): | ||||
return r() | ||||
else: | ||||
return repr(r) | ||||
class abstractsmartset(object): | ||||
def __nonzero__(self): | ||||
"""True if the smartset is not empty""" | ||||
raise NotImplementedError() | ||||
Gregory Szorc
|
r31476 | __bool__ = __nonzero__ | ||
Yuya Nishihara
|
r30881 | def __contains__(self, rev): | ||
"""provide fast membership testing""" | ||||
raise NotImplementedError() | ||||
def __iter__(self): | ||||
"""iterate the set in the order it is supposed to be iterated""" | ||||
raise NotImplementedError() | ||||
# Attributes containing a function to perform a fast iteration in a given | ||||
# direction. A smartset can have none, one, or both defined. | ||||
# | ||||
# Default value is None instead of a function returning None to avoid | ||||
# initializing an iterator just for testing if a fast method exists. | ||||
fastasc = None | ||||
fastdesc = None | ||||
def isascending(self): | ||||
"""True if the set will iterate in ascending order""" | ||||
raise NotImplementedError() | ||||
def isdescending(self): | ||||
"""True if the set will iterate in descending order""" | ||||
raise NotImplementedError() | ||||
def istopo(self): | ||||
"""True if the set will iterate in topographical order""" | ||||
raise NotImplementedError() | ||||
def min(self): | ||||
"""return the minimum element in the set""" | ||||
if self.fastasc is None: | ||||
v = min(self) | ||||
else: | ||||
for v in self.fastasc(): | ||||
break | ||||
else: | ||||
raise ValueError('arg is an empty sequence') | ||||
self.min = lambda: v | ||||
return v | ||||
def max(self): | ||||
"""return the maximum element in the set""" | ||||
if self.fastdesc is None: | ||||
return max(self) | ||||
else: | ||||
for v in self.fastdesc(): | ||||
break | ||||
else: | ||||
raise ValueError('arg is an empty sequence') | ||||
self.max = lambda: v | ||||
return v | ||||
def first(self): | ||||
"""return the first element in the set (user iteration perspective) | ||||
Return None if the set is empty""" | ||||
raise NotImplementedError() | ||||
def last(self): | ||||
"""return the last element in the set (user iteration perspective) | ||||
Return None if the set is empty""" | ||||
raise NotImplementedError() | ||||
def __len__(self): | ||||
"""return the length of the smartsets | ||||
This can be expensive on smartset that could be lazy otherwise.""" | ||||
raise NotImplementedError() | ||||
def reverse(self): | ||||
"""reverse the expected iteration order""" | ||||
raise NotImplementedError() | ||||
def sort(self, reverse=True): | ||||
"""get the set to iterate in an ascending or descending order""" | ||||
raise NotImplementedError() | ||||
def __and__(self, other): | ||||
"""Returns a new object with the intersection of the two collections. | ||||
This is part of the mandatory API for smartset.""" | ||||
if isinstance(other, fullreposet): | ||||
return self | ||||
return self.filter(other.__contains__, condrepr=other, cache=False) | ||||
def __add__(self, other): | ||||
"""Returns a new object with the union of the two collections. | ||||
This is part of the mandatory API for smartset.""" | ||||
return addset(self, other) | ||||
def __sub__(self, other): | ||||
"""Returns a new object with the substraction of the two collections. | ||||
This is part of the mandatory API for smartset.""" | ||||
c = other.__contains__ | ||||
return self.filter(lambda r: not c(r), condrepr=('<not %r>', other), | ||||
cache=False) | ||||
def filter(self, condition, condrepr=None, cache=True): | ||||
"""Returns this smartset filtered by condition as a new smartset. | ||||
`condition` is a callable which takes a revision number and returns a | ||||
boolean. Optional `condrepr` provides a printable representation of | ||||
the given `condition`. | ||||
This is part of the mandatory API for smartset.""" | ||||
# builtin cannot be cached. but do not needs to | ||||
if cache and util.safehasattr(condition, 'func_code'): | ||||
condition = util.cachefunc(condition) | ||||
return filteredset(self, condition, condrepr) | ||||
class baseset(abstractsmartset): | ||||
"""Basic data structure that represents a revset and contains the basic | ||||
operation that it should be able to perform. | ||||
Every method in this class should be implemented by any smartset class. | ||||
Jun Wu
|
r31019 | |||
This class could be constructed by an (unordered) set, or an (ordered) | ||||
list-like object. If a set is provided, it'll be sorted lazily. | ||||
>>> x = [4, 0, 7, 6] | ||||
>>> y = [5, 6, 7, 3] | ||||
Construct by a set: | ||||
>>> xs = baseset(set(x)) | ||||
>>> ys = baseset(set(y)) | ||||
>>> [list(i) for i in [xs + ys, xs & ys, xs - ys]] | ||||
[[0, 4, 6, 7, 3, 5], [6, 7], [0, 4]] | ||||
>>> [type(i).__name__ for i in [xs + ys, xs & ys, xs - ys]] | ||||
Jun Wu
|
r31020 | ['addset', 'baseset', 'baseset'] | ||
Jun Wu
|
r31019 | |||
Construct by a list-like: | ||||
>>> xs = baseset(x) | ||||
>>> ys = baseset(i for i in y) | ||||
>>> [list(i) for i in [xs + ys, xs & ys, xs - ys]] | ||||
[[4, 0, 7, 6, 5, 3], [7, 6], [4, 0]] | ||||
>>> [type(i).__name__ for i in [xs + ys, xs & ys, xs - ys]] | ||||
['addset', 'filteredset', 'filteredset'] | ||||
Populate "_set" fields in the lists so set optimization may be used: | ||||
>>> [1 in xs, 3 in ys] | ||||
[False, True] | ||||
Without sort(), results won't be changed: | ||||
>>> [list(i) for i in [xs + ys, xs & ys, xs - ys]] | ||||
[[4, 0, 7, 6, 5, 3], [7, 6], [4, 0]] | ||||
>>> [type(i).__name__ for i in [xs + ys, xs & ys, xs - ys]] | ||||
['addset', 'filteredset', 'filteredset'] | ||||
Jun Wu
|
r31020 | With sort(), set optimization could be used: | ||
Jun Wu
|
r31019 | >>> xs.sort(reverse=True) | ||
>>> [list(i) for i in [xs + ys, xs & ys, xs - ys]] | ||||
[[7, 6, 4, 0, 5, 3], [7, 6], [4, 0]] | ||||
>>> [type(i).__name__ for i in [xs + ys, xs & ys, xs - ys]] | ||||
Jun Wu
|
r31020 | ['addset', 'baseset', 'baseset'] | ||
Jun Wu
|
r31019 | |||
>>> ys.sort() | ||||
>>> [list(i) for i in [xs + ys, xs & ys, xs - ys]] | ||||
[[7, 6, 4, 0, 3, 5], [7, 6], [4, 0]] | ||||
>>> [type(i).__name__ for i in [xs + ys, xs & ys, xs - ys]] | ||||
Jun Wu
|
r31020 | ['addset', 'baseset', 'baseset'] | ||
Jun Wu
|
r31066 | |||
istopo is preserved across set operations | ||||
>>> xs = baseset(set(x), istopo=True) | ||||
>>> rs = xs & ys | ||||
>>> type(rs).__name__ | ||||
'baseset' | ||||
>>> rs._istopo | ||||
True | ||||
Yuya Nishihara
|
r30881 | """ | ||
def __init__(self, data=(), datarepr=None, istopo=False): | ||||
""" | ||||
datarepr: a tuple of (format, obj, ...), a function or an object that | ||||
provides a printable representation of the given data. | ||||
""" | ||||
self._ascending = None | ||||
self._istopo = istopo | ||||
Yuya Nishihara
|
r31127 | if isinstance(data, set): | ||
# converting set to list has a cost, do it lazily | ||||
self._set = data | ||||
# set has no order we pick one for stability purpose | ||||
self._ascending = True | ||||
else: | ||||
if not isinstance(data, list): | ||||
Jun Wu
|
r31015 | data = list(data) | ||
self._list = data | ||||
Yuya Nishihara
|
r30881 | self._datarepr = datarepr | ||
@util.propertycache | ||||
def _set(self): | ||||
return set(self._list) | ||||
@util.propertycache | ||||
def _asclist(self): | ||||
asclist = self._list[:] | ||||
asclist.sort() | ||||
return asclist | ||||
Jun Wu
|
r31015 | @util.propertycache | ||
def _list(self): | ||||
# _list is only lazily constructed if we have _set | ||||
assert '_set' in self.__dict__ | ||||
return list(self._set) | ||||
Yuya Nishihara
|
r30881 | def __iter__(self): | ||
if self._ascending is None: | ||||
return iter(self._list) | ||||
elif self._ascending: | ||||
return iter(self._asclist) | ||||
else: | ||||
return reversed(self._asclist) | ||||
def fastasc(self): | ||||
return iter(self._asclist) | ||||
def fastdesc(self): | ||||
return reversed(self._asclist) | ||||
@util.propertycache | ||||
def __contains__(self): | ||||
return self._set.__contains__ | ||||
def __nonzero__(self): | ||||
Jun Wu
|
r31015 | return bool(len(self)) | ||
Yuya Nishihara
|
r30881 | |||
Gregory Szorc
|
r31476 | __bool__ = __nonzero__ | ||
Yuya Nishihara
|
r30881 | def sort(self, reverse=False): | ||
self._ascending = not bool(reverse) | ||||
self._istopo = False | ||||
def reverse(self): | ||||
if self._ascending is None: | ||||
self._list.reverse() | ||||
else: | ||||
self._ascending = not self._ascending | ||||
self._istopo = False | ||||
def __len__(self): | ||||
Jun Wu
|
r31015 | if '_list' in self.__dict__: | ||
return len(self._list) | ||||
else: | ||||
return len(self._set) | ||||
Yuya Nishihara
|
r30881 | |||
def isascending(self): | ||||
"""Returns True if the collection is ascending order, False if not. | ||||
This is part of the mandatory API for smartset.""" | ||||
if len(self) <= 1: | ||||
return True | ||||
return self._ascending is not None and self._ascending | ||||
def isdescending(self): | ||||
"""Returns True if the collection is descending order, False if not. | ||||
This is part of the mandatory API for smartset.""" | ||||
if len(self) <= 1: | ||||
return True | ||||
return self._ascending is not None and not self._ascending | ||||
def istopo(self): | ||||
"""Is the collection is in topographical order or not. | ||||
This is part of the mandatory API for smartset.""" | ||||
if len(self) <= 1: | ||||
return True | ||||
return self._istopo | ||||
def first(self): | ||||
if self: | ||||
if self._ascending is None: | ||||
return self._list[0] | ||||
elif self._ascending: | ||||
return self._asclist[0] | ||||
else: | ||||
return self._asclist[-1] | ||||
return None | ||||
def last(self): | ||||
if self: | ||||
if self._ascending is None: | ||||
return self._list[-1] | ||||
elif self._ascending: | ||||
return self._asclist[-1] | ||||
else: | ||||
return self._asclist[0] | ||||
return None | ||||
Jun Wu
|
r31020 | def _fastsetop(self, other, op): | ||
# try to use native set operations as fast paths | ||||
if (type(other) is baseset and '_set' in other.__dict__ and '_set' in | ||||
self.__dict__ and self._ascending is not None): | ||||
Jun Wu
|
r31066 | s = baseset(data=getattr(self._set, op)(other._set), | ||
istopo=self._istopo) | ||||
Jun Wu
|
r31020 | s._ascending = self._ascending | ||
else: | ||||
s = getattr(super(baseset, self), op)(other) | ||||
return s | ||||
def __and__(self, other): | ||||
return self._fastsetop(other, '__and__') | ||||
def __sub__(self, other): | ||||
return self._fastsetop(other, '__sub__') | ||||
Yuya Nishihara
|
r30881 | def __repr__(self): | ||
d = {None: '', False: '-', True: '+'}[self._ascending] | ||||
s = _formatsetrepr(self._datarepr) | ||||
if not s: | ||||
l = self._list | ||||
# if _list has been built from a set, it might have a different | ||||
# order from one python implementation to another. | ||||
# We fallback to the sorted version for a stable output. | ||||
if self._ascending is not None: | ||||
l = self._asclist | ||||
s = repr(l) | ||||
return '<%s%s %s>' % (type(self).__name__, d, s) | ||||
class filteredset(abstractsmartset): | ||||
"""Duck type for baseset class which iterates lazily over the revisions in | ||||
the subset and contains a function which tests for membership in the | ||||
revset | ||||
""" | ||||
def __init__(self, subset, condition=lambda x: True, condrepr=None): | ||||
""" | ||||
condition: a function that decide whether a revision in the subset | ||||
belongs to the revset or not. | ||||
condrepr: a tuple of (format, obj, ...), a function or an object that | ||||
provides a printable representation of the given condition. | ||||
""" | ||||
self._subset = subset | ||||
self._condition = condition | ||||
self._condrepr = condrepr | ||||
def __contains__(self, x): | ||||
return x in self._subset and self._condition(x) | ||||
def __iter__(self): | ||||
return self._iterfilter(self._subset) | ||||
def _iterfilter(self, it): | ||||
cond = self._condition | ||||
for x in it: | ||||
if cond(x): | ||||
yield x | ||||
@property | ||||
def fastasc(self): | ||||
it = self._subset.fastasc | ||||
if it is None: | ||||
return None | ||||
return lambda: self._iterfilter(it()) | ||||
@property | ||||
def fastdesc(self): | ||||
it = self._subset.fastdesc | ||||
if it is None: | ||||
return None | ||||
return lambda: self._iterfilter(it()) | ||||
def __nonzero__(self): | ||||
fast = None | ||||
candidates = [self.fastasc if self.isascending() else None, | ||||
self.fastdesc if self.isdescending() else None, | ||||
self.fastasc, | ||||
self.fastdesc] | ||||
for candidate in candidates: | ||||
if candidate is not None: | ||||
fast = candidate | ||||
break | ||||
if fast is not None: | ||||
it = fast() | ||||
else: | ||||
it = self | ||||
for r in it: | ||||
return True | ||||
return False | ||||
Gregory Szorc
|
r31476 | __bool__ = __nonzero__ | ||
Yuya Nishihara
|
r30881 | def __len__(self): | ||
# Basic implementation to be changed in future patches. | ||||
# until this gets improved, we use generator expression | ||||
# here, since list comprehensions are free to call __len__ again | ||||
# causing infinite recursion | ||||
l = baseset(r for r in self) | ||||
return len(l) | ||||
def sort(self, reverse=False): | ||||
self._subset.sort(reverse=reverse) | ||||
def reverse(self): | ||||
self._subset.reverse() | ||||
def isascending(self): | ||||
return self._subset.isascending() | ||||
def isdescending(self): | ||||
return self._subset.isdescending() | ||||
def istopo(self): | ||||
return self._subset.istopo() | ||||
def first(self): | ||||
for x in self: | ||||
return x | ||||
return None | ||||
def last(self): | ||||
it = None | ||||
if self.isascending(): | ||||
it = self.fastdesc | ||||
elif self.isdescending(): | ||||
it = self.fastasc | ||||
if it is not None: | ||||
for x in it(): | ||||
return x | ||||
return None #empty case | ||||
else: | ||||
x = None | ||||
for x in self: | ||||
pass | ||||
return x | ||||
def __repr__(self): | ||||
xs = [repr(self._subset)] | ||||
s = _formatsetrepr(self._condrepr) | ||||
if s: | ||||
xs.append(s) | ||||
return '<%s %s>' % (type(self).__name__, ', '.join(xs)) | ||||
def _iterordered(ascending, iter1, iter2): | ||||
"""produce an ordered iteration from two iterators with the same order | ||||
The ascending is used to indicated the iteration direction. | ||||
""" | ||||
choice = max | ||||
if ascending: | ||||
choice = min | ||||
val1 = None | ||||
val2 = None | ||||
try: | ||||
# Consume both iterators in an ordered way until one is empty | ||||
while True: | ||||
if val1 is None: | ||||
val1 = next(iter1) | ||||
if val2 is None: | ||||
val2 = next(iter2) | ||||
n = choice(val1, val2) | ||||
yield n | ||||
if val1 == n: | ||||
val1 = None | ||||
if val2 == n: | ||||
val2 = None | ||||
except StopIteration: | ||||
# Flush any remaining values and consume the other one | ||||
it = iter2 | ||||
if val1 is not None: | ||||
yield val1 | ||||
it = iter1 | ||||
elif val2 is not None: | ||||
# might have been equality and both are empty | ||||
yield val2 | ||||
for val in it: | ||||
yield val | ||||
class addset(abstractsmartset): | ||||
"""Represent the addition of two sets | ||||
Wrapper structure for lazily adding two structures without losing much | ||||
performance on the __contains__ method | ||||
If the ascending attribute is set, that means the two structures are | ||||
ordered in either an ascending or descending way. Therefore, we can add | ||||
them maintaining the order by iterating over both at the same time | ||||
>>> xs = baseset([0, 3, 2]) | ||||
>>> ys = baseset([5, 2, 4]) | ||||
>>> rs = addset(xs, ys) | ||||
>>> bool(rs), 0 in rs, 1 in rs, 5 in rs, rs.first(), rs.last() | ||||
(True, True, False, True, 0, 4) | ||||
>>> rs = addset(xs, baseset([])) | ||||
>>> bool(rs), 0 in rs, 1 in rs, rs.first(), rs.last() | ||||
(True, True, False, 0, 2) | ||||
>>> rs = addset(baseset([]), baseset([])) | ||||
>>> bool(rs), 0 in rs, rs.first(), rs.last() | ||||
(False, False, None, None) | ||||
iterate unsorted: | ||||
>>> rs = addset(xs, ys) | ||||
>>> # (use generator because pypy could call len()) | ||||
>>> list(x for x in rs) # without _genlist | ||||
[0, 3, 2, 5, 4] | ||||
>>> assert not rs._genlist | ||||
>>> len(rs) | ||||
5 | ||||
>>> [x for x in rs] # with _genlist | ||||
[0, 3, 2, 5, 4] | ||||
>>> assert rs._genlist | ||||
iterate ascending: | ||||
>>> rs = addset(xs, ys, ascending=True) | ||||
>>> # (use generator because pypy could call len()) | ||||
>>> list(x for x in rs), list(x for x in rs.fastasc()) # without _asclist | ||||
([0, 2, 3, 4, 5], [0, 2, 3, 4, 5]) | ||||
>>> assert not rs._asclist | ||||
>>> len(rs) | ||||
5 | ||||
>>> [x for x in rs], [x for x in rs.fastasc()] | ||||
([0, 2, 3, 4, 5], [0, 2, 3, 4, 5]) | ||||
>>> assert rs._asclist | ||||
iterate descending: | ||||
>>> rs = addset(xs, ys, ascending=False) | ||||
>>> # (use generator because pypy could call len()) | ||||
>>> list(x for x in rs), list(x for x in rs.fastdesc()) # without _asclist | ||||
([5, 4, 3, 2, 0], [5, 4, 3, 2, 0]) | ||||
>>> assert not rs._asclist | ||||
>>> len(rs) | ||||
5 | ||||
>>> [x for x in rs], [x for x in rs.fastdesc()] | ||||
([5, 4, 3, 2, 0], [5, 4, 3, 2, 0]) | ||||
>>> assert rs._asclist | ||||
iterate ascending without fastasc: | ||||
>>> rs = addset(xs, generatorset(ys), ascending=True) | ||||
>>> assert rs.fastasc is None | ||||
>>> [x for x in rs] | ||||
[0, 2, 3, 4, 5] | ||||
iterate descending without fastdesc: | ||||
>>> rs = addset(generatorset(xs), ys, ascending=False) | ||||
>>> assert rs.fastdesc is None | ||||
>>> [x for x in rs] | ||||
[5, 4, 3, 2, 0] | ||||
""" | ||||
def __init__(self, revs1, revs2, ascending=None): | ||||
self._r1 = revs1 | ||||
self._r2 = revs2 | ||||
self._iter = None | ||||
self._ascending = ascending | ||||
self._genlist = None | ||||
self._asclist = None | ||||
def __len__(self): | ||||
return len(self._list) | ||||
def __nonzero__(self): | ||||
return bool(self._r1) or bool(self._r2) | ||||
Gregory Szorc
|
r31476 | __bool__ = __nonzero__ | ||
Yuya Nishihara
|
r30881 | @util.propertycache | ||
def _list(self): | ||||
if not self._genlist: | ||||
self._genlist = baseset(iter(self)) | ||||
return self._genlist | ||||
def __iter__(self): | ||||
"""Iterate over both collections without repeating elements | ||||
If the ascending attribute is not set, iterate over the first one and | ||||
then over the second one checking for membership on the first one so we | ||||
dont yield any duplicates. | ||||
If the ascending attribute is set, iterate over both collections at the | ||||
same time, yielding only one value at a time in the given order. | ||||
""" | ||||
if self._ascending is None: | ||||
if self._genlist: | ||||
return iter(self._genlist) | ||||
def arbitraryordergen(): | ||||
for r in self._r1: | ||||
yield r | ||||
inr1 = self._r1.__contains__ | ||||
for r in self._r2: | ||||
if not inr1(r): | ||||
yield r | ||||
return arbitraryordergen() | ||||
# try to use our own fast iterator if it exists | ||||
self._trysetasclist() | ||||
if self._ascending: | ||||
attr = 'fastasc' | ||||
else: | ||||
attr = 'fastdesc' | ||||
it = getattr(self, attr) | ||||
if it is not None: | ||||
return it() | ||||
# maybe half of the component supports fast | ||||
# get iterator for _r1 | ||||
iter1 = getattr(self._r1, attr) | ||||
if iter1 is None: | ||||
# let's avoid side effect (not sure it matters) | ||||
iter1 = iter(sorted(self._r1, reverse=not self._ascending)) | ||||
else: | ||||
iter1 = iter1() | ||||
# get iterator for _r2 | ||||
iter2 = getattr(self._r2, attr) | ||||
if iter2 is None: | ||||
# let's avoid side effect (not sure it matters) | ||||
iter2 = iter(sorted(self._r2, reverse=not self._ascending)) | ||||
else: | ||||
iter2 = iter2() | ||||
return _iterordered(self._ascending, iter1, iter2) | ||||
def _trysetasclist(self): | ||||
"""populate the _asclist attribute if possible and necessary""" | ||||
if self._genlist is not None and self._asclist is None: | ||||
self._asclist = sorted(self._genlist) | ||||
@property | ||||
def fastasc(self): | ||||
self._trysetasclist() | ||||
if self._asclist is not None: | ||||
return self._asclist.__iter__ | ||||
iter1 = self._r1.fastasc | ||||
iter2 = self._r2.fastasc | ||||
if None in (iter1, iter2): | ||||
return None | ||||
return lambda: _iterordered(True, iter1(), iter2()) | ||||
@property | ||||
def fastdesc(self): | ||||
self._trysetasclist() | ||||
if self._asclist is not None: | ||||
return self._asclist.__reversed__ | ||||
iter1 = self._r1.fastdesc | ||||
iter2 = self._r2.fastdesc | ||||
if None in (iter1, iter2): | ||||
return None | ||||
return lambda: _iterordered(False, iter1(), iter2()) | ||||
def __contains__(self, x): | ||||
return x in self._r1 or x in self._r2 | ||||
def sort(self, reverse=False): | ||||
"""Sort the added set | ||||
For this we use the cached list with all the generated values and if we | ||||
know they are ascending or descending we can sort them in a smart way. | ||||
""" | ||||
self._ascending = not reverse | ||||
def isascending(self): | ||||
return self._ascending is not None and self._ascending | ||||
def isdescending(self): | ||||
return self._ascending is not None and not self._ascending | ||||
def istopo(self): | ||||
# not worth the trouble asserting if the two sets combined are still | ||||
# in topographical order. Use the sort() predicate to explicitly sort | ||||
# again instead. | ||||
return False | ||||
def reverse(self): | ||||
if self._ascending is None: | ||||
self._list.reverse() | ||||
else: | ||||
self._ascending = not self._ascending | ||||
def first(self): | ||||
for x in self: | ||||
return x | ||||
return None | ||||
def last(self): | ||||
self.reverse() | ||||
val = self.first() | ||||
self.reverse() | ||||
return val | ||||
def __repr__(self): | ||||
d = {None: '', False: '-', True: '+'}[self._ascending] | ||||
return '<%s%s %r, %r>' % (type(self).__name__, d, self._r1, self._r2) | ||||
class generatorset(abstractsmartset): | ||||
"""Wrap a generator for lazy iteration | ||||
Wrapper structure for generators that provides lazy membership and can | ||||
be iterated more than once. | ||||
When asked for membership it generates values until either it finds the | ||||
requested one or has gone through all the elements in the generator | ||||
""" | ||||
def __init__(self, gen, iterasc=None): | ||||
""" | ||||
gen: a generator producing the values for the generatorset. | ||||
""" | ||||
self._gen = gen | ||||
self._asclist = None | ||||
self._cache = {} | ||||
self._genlist = [] | ||||
self._finished = False | ||||
self._ascending = True | ||||
if iterasc is not None: | ||||
if iterasc: | ||||
self.fastasc = self._iterator | ||||
self.__contains__ = self._asccontains | ||||
else: | ||||
self.fastdesc = self._iterator | ||||
self.__contains__ = self._desccontains | ||||
def __nonzero__(self): | ||||
# Do not use 'for r in self' because it will enforce the iteration | ||||
# order (default ascending), possibly unrolling a whole descending | ||||
# iterator. | ||||
if self._genlist: | ||||
return True | ||||
for r in self._consumegen(): | ||||
return True | ||||
return False | ||||
Gregory Szorc
|
r31476 | __bool__ = __nonzero__ | ||
Yuya Nishihara
|
r30881 | def __contains__(self, x): | ||
if x in self._cache: | ||||
return self._cache[x] | ||||
# Use new values only, as existing values would be cached. | ||||
for l in self._consumegen(): | ||||
if l == x: | ||||
return True | ||||
self._cache[x] = False | ||||
return False | ||||
def _asccontains(self, x): | ||||
"""version of contains optimised for ascending generator""" | ||||
if x in self._cache: | ||||
return self._cache[x] | ||||
# Use new values only, as existing values would be cached. | ||||
for l in self._consumegen(): | ||||
if l == x: | ||||
return True | ||||
if l > x: | ||||
break | ||||
self._cache[x] = False | ||||
return False | ||||
def _desccontains(self, x): | ||||
"""version of contains optimised for descending generator""" | ||||
if x in self._cache: | ||||
return self._cache[x] | ||||
# Use new values only, as existing values would be cached. | ||||
for l in self._consumegen(): | ||||
if l == x: | ||||
return True | ||||
if l < x: | ||||
break | ||||
self._cache[x] = False | ||||
return False | ||||
def __iter__(self): | ||||
if self._ascending: | ||||
it = self.fastasc | ||||
else: | ||||
it = self.fastdesc | ||||
if it is not None: | ||||
return it() | ||||
# we need to consume the iterator | ||||
for x in self._consumegen(): | ||||
pass | ||||
# recall the same code | ||||
return iter(self) | ||||
def _iterator(self): | ||||
if self._finished: | ||||
return iter(self._genlist) | ||||
# We have to use this complex iteration strategy to allow multiple | ||||
# iterations at the same time. We need to be able to catch revision | ||||
# removed from _consumegen and added to genlist in another instance. | ||||
# | ||||
# Getting rid of it would provide an about 15% speed up on this | ||||
# iteration. | ||||
genlist = self._genlist | ||||
Yuya Nishihara
|
r31446 | nextgen = self._consumegen() | ||
_len, _next = len, next # cache global lookup | ||||
Yuya Nishihara
|
r30881 | def gen(): | ||
i = 0 | ||||
while True: | ||||
if i < _len(genlist): | ||||
yield genlist[i] | ||||
else: | ||||
Yuya Nishihara
|
r31446 | yield _next(nextgen) | ||
Yuya Nishihara
|
r30881 | i += 1 | ||
return gen() | ||||
def _consumegen(self): | ||||
cache = self._cache | ||||
genlist = self._genlist.append | ||||
for item in self._gen: | ||||
cache[item] = True | ||||
genlist(item) | ||||
yield item | ||||
if not self._finished: | ||||
self._finished = True | ||||
asc = self._genlist[:] | ||||
asc.sort() | ||||
self._asclist = asc | ||||
self.fastasc = asc.__iter__ | ||||
self.fastdesc = asc.__reversed__ | ||||
def __len__(self): | ||||
for x in self._consumegen(): | ||||
pass | ||||
return len(self._genlist) | ||||
def sort(self, reverse=False): | ||||
self._ascending = not reverse | ||||
def reverse(self): | ||||
self._ascending = not self._ascending | ||||
def isascending(self): | ||||
return self._ascending | ||||
def isdescending(self): | ||||
return not self._ascending | ||||
def istopo(self): | ||||
# not worth the trouble asserting if the two sets combined are still | ||||
# in topographical order. Use the sort() predicate to explicitly sort | ||||
# again instead. | ||||
return False | ||||
def first(self): | ||||
if self._ascending: | ||||
it = self.fastasc | ||||
else: | ||||
it = self.fastdesc | ||||
if it is None: | ||||
# we need to consume all and try again | ||||
for x in self._consumegen(): | ||||
pass | ||||
return self.first() | ||||
return next(it(), None) | ||||
def last(self): | ||||
if self._ascending: | ||||
it = self.fastdesc | ||||
else: | ||||
it = self.fastasc | ||||
if it is None: | ||||
# we need to consume all and try again | ||||
for x in self._consumegen(): | ||||
pass | ||||
return self.first() | ||||
return next(it(), None) | ||||
def __repr__(self): | ||||
d = {False: '-', True: '+'}[self._ascending] | ||||
return '<%s%s>' % (type(self).__name__, d) | ||||
class spanset(abstractsmartset): | ||||
"""Duck type for baseset class which represents a range of revisions and | ||||
can work lazily and without having all the range in memory | ||||
Note that spanset(x, y) behave almost like xrange(x, y) except for two | ||||
notable points: | ||||
- when x < y it will be automatically descending, | ||||
- revision filtered with this repoview will be skipped. | ||||
""" | ||||
def __init__(self, repo, start=0, end=None): | ||||
""" | ||||
start: first revision included the set | ||||
(default to 0) | ||||
end: first revision excluded (last+1) | ||||
(default to len(repo) | ||||
Spanset will be descending if `end` < `start`. | ||||
""" | ||||
if end is None: | ||||
end = len(repo) | ||||
self._ascending = start <= end | ||||
if not self._ascending: | ||||
start, end = end + 1, start +1 | ||||
self._start = start | ||||
self._end = end | ||||
self._hiddenrevs = repo.changelog.filteredrevs | ||||
def sort(self, reverse=False): | ||||
self._ascending = not reverse | ||||
def reverse(self): | ||||
self._ascending = not self._ascending | ||||
def istopo(self): | ||||
# not worth the trouble asserting if the two sets combined are still | ||||
# in topographical order. Use the sort() predicate to explicitly sort | ||||
# again instead. | ||||
return False | ||||
def _iterfilter(self, iterrange): | ||||
s = self._hiddenrevs | ||||
for r in iterrange: | ||||
if r not in s: | ||||
yield r | ||||
def __iter__(self): | ||||
if self._ascending: | ||||
return self.fastasc() | ||||
else: | ||||
return self.fastdesc() | ||||
def fastasc(self): | ||||
iterrange = xrange(self._start, self._end) | ||||
if self._hiddenrevs: | ||||
return self._iterfilter(iterrange) | ||||
return iter(iterrange) | ||||
def fastdesc(self): | ||||
iterrange = xrange(self._end - 1, self._start - 1, -1) | ||||
if self._hiddenrevs: | ||||
return self._iterfilter(iterrange) | ||||
return iter(iterrange) | ||||
def __contains__(self, rev): | ||||
hidden = self._hiddenrevs | ||||
return ((self._start <= rev < self._end) | ||||
and not (hidden and rev in hidden)) | ||||
def __nonzero__(self): | ||||
for r in self: | ||||
return True | ||||
return False | ||||
Gregory Szorc
|
r31476 | __bool__ = __nonzero__ | ||
Yuya Nishihara
|
r30881 | def __len__(self): | ||
if not self._hiddenrevs: | ||||
return abs(self._end - self._start) | ||||
else: | ||||
count = 0 | ||||
start = self._start | ||||
end = self._end | ||||
for rev in self._hiddenrevs: | ||||
if (end < rev <= start) or (start <= rev < end): | ||||
count += 1 | ||||
return abs(self._end - self._start) - count | ||||
def isascending(self): | ||||
return self._ascending | ||||
def isdescending(self): | ||||
return not self._ascending | ||||
def first(self): | ||||
if self._ascending: | ||||
it = self.fastasc | ||||
else: | ||||
it = self.fastdesc | ||||
for x in it(): | ||||
return x | ||||
return None | ||||
def last(self): | ||||
if self._ascending: | ||||
it = self.fastdesc | ||||
else: | ||||
it = self.fastasc | ||||
for x in it(): | ||||
return x | ||||
return None | ||||
def __repr__(self): | ||||
d = {False: '-', True: '+'}[self._ascending] | ||||
return '<%s%s %d:%d>' % (type(self).__name__, d, | ||||
self._start, self._end - 1) | ||||
class fullreposet(spanset): | ||||
"""a set containing all revisions in the repo | ||||
This class exists to host special optimization and magic to handle virtual | ||||
revisions such as "null". | ||||
""" | ||||
def __init__(self, repo): | ||||
super(fullreposet, self).__init__(repo) | ||||
def __and__(self, other): | ||||
"""As self contains the whole repo, all of the other set should also be | ||||
in self. Therefore `self & other = other`. | ||||
This boldly assumes the other contains valid revs only. | ||||
""" | ||||
# other not a smartset, make is so | ||||
if not util.safehasattr(other, 'isascending'): | ||||
# filter out hidden revision | ||||
# (this boldly assumes all smartset are pure) | ||||
# | ||||
# `other` was used with "&", let's assume this is a set like | ||||
# object. | ||||
other = baseset(other - self._hiddenrevs) | ||||
other.sort(reverse=self.isdescending()) | ||||
return other | ||||
def prettyformat(revs): | ||||
lines = [] | ||||
rs = repr(revs) | ||||
p = 0 | ||||
while p < len(rs): | ||||
q = rs.find('<', p + 1) | ||||
if q < 0: | ||||
q = len(rs) | ||||
l = rs.count('<', 0, p) - rs.count('>', 0, p) | ||||
assert l >= 0 | ||||
lines.append((l, rs[p:q].rstrip())) | ||||
p = q | ||||
return '\n'.join(' ' * l + s for l, s in lines) | ||||