Mercurial > kallithea
view rhodecode/lib/compat.py @ 3181:efe23d6c178c rhodecode-0.0.1.5.2
merged with beta
| author | Marcin Kuzminski <marcin@python-works.com> |
|---|---|
| date | Mon, 21 Jan 2013 00:49:59 +0100 |
| parents | 4b7ad342e53b |
| children | d7488551578e |
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# -*- coding: utf-8 -*- """ rhodecode.lib.compat ~~~~~~~~~~~~~~~~~~~~ Python backward compatibility functions and common libs :created_on: Oct 7, 2011 :author: marcink :copyright: (C) 2010-2010 Marcin Kuzminski <marcin@python-works.com> :license: GPLv3, see COPYING for more details. """ # 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 3 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, see <http://www.gnu.org/licenses/>. import os from rhodecode import __platform__, PLATFORM_WIN, __py_version__ #============================================================================== # json #============================================================================== from rhodecode.lib.ext_json import json import array #============================================================================== # izip_longest #============================================================================== try: from itertools import izip_longest except ImportError: import itertools def izip_longest(*args, **kwds): fillvalue = kwds.get("fillvalue") def sentinel(counter=([fillvalue] * (len(args) - 1)).pop): yield counter() # yields the fillvalue, or raises IndexError fillers = itertools.repeat(fillvalue) iters = [itertools.chain(it, sentinel(), fillers) for it in args] try: for tup in itertools.izip(*iters): yield tup except IndexError: pass #============================================================================== # OrderedDict #============================================================================== # Python Software Foundation License # XXX: it feels like using the class with "is" and "is not" instead of "==" and # "!=" should be faster. class _Nil(object): def __repr__(self): return "nil" def __eq__(self, other): if (isinstance(other, _Nil)): return True else: return NotImplemented def __ne__(self, other): if (isinstance(other, _Nil)): return False else: return NotImplemented _nil = _Nil() class _odict(object): """Ordered dict data structure, with O(1) complexity for dict operations that modify one element. Overwriting values doesn't change their original sequential order. """ def _dict_impl(self): return None def __init__(self, data=(), **kwds): """This doesn't accept keyword initialization as normal dicts to avoid a trap - inside a function or method the keyword args are accessible only as a dict, without a defined order, so their original order is lost. """ if kwds: raise TypeError("__init__() of ordered dict takes no keyword " "arguments to avoid an ordering trap.") self._dict_impl().__init__(self) # If you give a normal dict, then the order of elements is undefined if hasattr(data, "iteritems"): for key, val in data.iteritems(): self[key] = val else: for key, val in data: self[key] = val # Double-linked list header def _get_lh(self): dict_impl = self._dict_impl() if not hasattr(self, '_lh'): dict_impl.__setattr__(self, '_lh', _nil) return dict_impl.__getattribute__(self, '_lh') def _set_lh(self, val): self._dict_impl().__setattr__(self, '_lh', val) lh = property(_get_lh, _set_lh) # Double-linked list tail def _get_lt(self): dict_impl = self._dict_impl() if not hasattr(self, '_lt'): dict_impl.__setattr__(self, '_lt', _nil) return dict_impl.__getattribute__(self, '_lt') def _set_lt(self, val): self._dict_impl().__setattr__(self, '_lt', val) lt = property(_get_lt, _set_lt) def __getitem__(self, key): return self._dict_impl().__getitem__(self, key)[1] def __setitem__(self, key, val): dict_impl = self._dict_impl() try: dict_impl.__getitem__(self, key)[1] = val except KeyError: new = [dict_impl.__getattribute__(self, 'lt'), val, _nil] dict_impl.__setitem__(self, key, new) if dict_impl.__getattribute__(self, 'lt') == _nil: dict_impl.__setattr__(self, 'lh', key) else: dict_impl.__getitem__( self, dict_impl.__getattribute__(self, 'lt'))[2] = key dict_impl.__setattr__(self, 'lt', key) def __delitem__(self, key): dict_impl = self._dict_impl() pred, _, succ = self._dict_impl().__getitem__(self, key) if pred == _nil: dict_impl.__setattr__(self, 'lh', succ) else: dict_impl.__getitem__(self, pred)[2] = succ if succ == _nil: dict_impl.__setattr__(self, 'lt', pred) else: dict_impl.__getitem__(self, succ)[0] = pred dict_impl.__delitem__(self, key) def __contains__(self, key): return key in self.keys() def __len__(self): return len(self.keys()) def __str__(self): pairs = ("%r: %r" % (k, v) for k, v in self.iteritems()) return "{%s}" % ", ".join(pairs) def __repr__(self): if self: pairs = ("(%r, %r)" % (k, v) for k, v in self.iteritems()) return "odict([%s])" % ", ".join(pairs) else: return "odict()" def get(self, k, x=None): if k in self: return self._dict_impl().__getitem__(self, k)[1] else: return x def __iter__(self): dict_impl = self._dict_impl() curr_key = dict_impl.__getattribute__(self, 'lh') while curr_key != _nil: yield curr_key curr_key = dict_impl.__getitem__(self, curr_key)[2] iterkeys = __iter__ def keys(self): return list(self.iterkeys()) def itervalues(self): dict_impl = self._dict_impl() curr_key = dict_impl.__getattribute__(self, 'lh') while curr_key != _nil: _, val, curr_key = dict_impl.__getitem__(self, curr_key) yield val def values(self): return list(self.itervalues()) def iteritems(self): dict_impl = self._dict_impl() curr_key = dict_impl.__getattribute__(self, 'lh') while curr_key != _nil: _, val, next_key = dict_impl.__getitem__(self, curr_key) yield curr_key, val curr_key = next_key def items(self): return list(self.iteritems()) def sort(self, cmp=None, key=None, reverse=False): items = [(k, v) for k, v in self.items()] if cmp is not None: items = sorted(items, cmp=cmp) elif key is not None: items = sorted(items, key=key) else: items = sorted(items, key=lambda x: x[1]) if reverse: items.reverse() self.clear() self.__init__(items) def clear(self): dict_impl = self._dict_impl() dict_impl.clear(self) dict_impl.__setattr__(self, 'lh', _nil) dict_impl.__setattr__(self, 'lt', _nil) def copy(self): return self.__class__(self) def update(self, data=(), **kwds): if kwds: raise TypeError("update() of ordered dict takes no keyword " "arguments to avoid an ordering trap.") if hasattr(data, "iteritems"): data = data.iteritems() for key, val in data: self[key] = val def setdefault(self, k, x=None): try: return self[k] except KeyError: self[k] = x return x def pop(self, k, x=_nil): try: val = self[k] del self[k] return val except KeyError: if x == _nil: raise return x def popitem(self): try: dict_impl = self._dict_impl() key = dict_impl.__getattribute__(self, 'lt') return key, self.pop(key) except KeyError: raise KeyError("'popitem(): ordered dictionary is empty'") def riterkeys(self): """To iterate on keys in reversed order. """ dict_impl = self._dict_impl() curr_key = dict_impl.__getattribute__(self, 'lt') while curr_key != _nil: yield curr_key curr_key = dict_impl.__getitem__(self, curr_key)[0] __reversed__ = riterkeys def rkeys(self): """List of the keys in reversed order. """ return list(self.riterkeys()) def ritervalues(self): """To iterate on values in reversed order. """ dict_impl = self._dict_impl() curr_key = dict_impl.__getattribute__(self, 'lt') while curr_key != _nil: curr_key, val, _ = dict_impl.__getitem__(self, curr_key) yield val def rvalues(self): """List of the values in reversed order. """ return list(self.ritervalues()) def riteritems(self): """To iterate on (key, value) in reversed order. """ dict_impl = self._dict_impl() curr_key = dict_impl.__getattribute__(self, 'lt') while curr_key != _nil: pred_key, val, _ = dict_impl.__getitem__(self, curr_key) yield curr_key, val curr_key = pred_key def ritems(self): """List of the (key, value) in reversed order. """ return list(self.riteritems()) def firstkey(self): if self: return self._dict_impl().__getattribute__(self, 'lh') else: raise KeyError("'firstkey(): ordered dictionary is empty'") def lastkey(self): if self: return self._dict_impl().__getattribute__(self, 'lt') else: raise KeyError("'lastkey(): ordered dictionary is empty'") def as_dict(self): return self._dict_impl()(self.items()) def _repr(self): """_repr(): low level repr of the whole data contained in the odict. Useful for debugging. """ dict_impl = self._dict_impl() form = "odict low level repr lh,lt,data: %r, %r, %s" return form % (dict_impl.__getattribute__(self, 'lh'), dict_impl.__getattribute__(self, 'lt'), dict_impl.__repr__(self)) class OrderedDict(_odict, dict): def _dict_impl(self): return dict #============================================================================== # OrderedSet #============================================================================== from sqlalchemy.util import OrderedSet #============================================================================== # kill FUNCTIONS #============================================================================== if __platform__ in PLATFORM_WIN: import ctypes def kill(pid, sig): """kill function for Win32""" kernel32 = ctypes.windll.kernel32 handle = kernel32.OpenProcess(1, 0, pid) return (0 != kernel32.TerminateProcess(handle, 0)) else: kill = os.kill #============================================================================== # itertools.product #============================================================================== try: from itertools import product except ImportError: def product(*args, **kwds): # product('ABCD', 'xy') --> Ax Ay Bx By Cx Cy Dx Dy # product(range(2), repeat=3) --> 000 001 010 011 100 101 110 111 pools = map(tuple, args) * kwds.get('repeat', 1) result = [[]] for pool in pools: result = [x + [y] for x in result for y in pool] for prod in result: yield tuple(prod) #============================================================================== # BytesIO #============================================================================== try: from io import BytesIO except ImportError: from cStringIO import StringIO as BytesIO #============================================================================== # bytes #============================================================================== if __py_version__ >= (2, 6): _bytes = bytes else: # in py2.6 bytes is a synonim for str _bytes = str if __py_version__ >= (2, 6): _bytearray = bytearray else: # no idea if this is correct but all integration tests are passing # i think we never use bytearray anyway _bytearray = array #============================================================================== # deque #============================================================================== if __py_version__ >= (2, 6): from collections import deque else: #need to implement our own deque with maxlen class deque(object): def __init__(self, iterable=(), maxlen= -1): if not hasattr(self, 'data'): self.left = self.right = 0 self.data = {} self.maxlen = maxlen or -1 self.extend(iterable) def append(self, x): self.data[self.right] = x self.right += 1 if self.maxlen != -1 and len(self) > self.maxlen: self.popleft() def appendleft(self, x): self.left -= 1 self.data[self.left] = x if self.maxlen != -1 and len(self) > self.maxlen: self.pop() def pop(self): if self.left == self.right: raise IndexError('cannot pop from empty deque') self.right -= 1 elem = self.data[self.right] del self.data[self.right] return elem def popleft(self): if self.left == self.right: raise IndexError('cannot pop from empty deque') elem = self.data[self.left] del self.data[self.left] self.left += 1 return elem def clear(self): self.data.clear() self.left = self.right = 0 def extend(self, iterable): for elem in iterable: self.append(elem) def extendleft(self, iterable): for elem in iterable: self.appendleft(elem) def rotate(self, n=1): if self: n %= len(self) for i in xrange(n): self.appendleft(self.pop()) def __getitem__(self, i): if i < 0: i += len(self) try: return self.data[i + self.left] except KeyError: raise IndexError def __setitem__(self, i, value): if i < 0: i += len(self) try: self.data[i + self.left] = value except KeyError: raise IndexError def __delitem__(self, i): size = len(self) if not (-size <= i < size): raise IndexError data = self.data if i < 0: i += size for j in xrange(self.left + i, self.right - 1): data[j] = data[j + 1] self.pop() def __len__(self): return self.right - self.left def __cmp__(self, other): if type(self) != type(other): return cmp(type(self), type(other)) return cmp(list(self), list(other)) def __repr__(self, _track=[]): if id(self) in _track: return '...' _track.append(id(self)) r = 'deque(%r, maxlen=%s)' % (list(self), self.maxlen) _track.remove(id(self)) return r def __getstate__(self): return (tuple(self),) def __setstate__(self, s): self.__init__(s[0]) def __hash__(self): raise TypeError def __copy__(self): return self.__class__(self) def __deepcopy__(self, memo={}): from copy import deepcopy result = self.__class__() memo[id(self)] = result result.__init__(deepcopy(tuple(self), memo)) return result #============================================================================== # threading.Event #============================================================================== if __py_version__ >= (2, 6): from threading import Event, Thread else: from threading import _Verbose, Condition, Lock, Thread, _time, \ _allocate_lock, RLock, _sleep def Condition(*args, **kwargs): return _Condition(*args, **kwargs) class _Condition(_Verbose): def __init__(self, lock=None, verbose=None): _Verbose.__init__(self, verbose) if lock is None: lock = RLock() self.__lock = lock # Export the lock's acquire() and release() methods self.acquire = lock.acquire self.release = lock.release # If the lock defines _release_save() and/or _acquire_restore(), # these override the default implementations (which just call # release() and acquire() on the lock). Ditto for _is_owned(). try: self._release_save = lock._release_save except AttributeError: pass try: self._acquire_restore = lock._acquire_restore except AttributeError: pass try: self._is_owned = lock._is_owned except AttributeError: pass self.__waiters = [] def __enter__(self): return self.__lock.__enter__() def __exit__(self, *args): return self.__lock.__exit__(*args) def __repr__(self): return "<Condition(%s, %d)>" % (self.__lock, len(self.__waiters)) def _release_save(self): self.__lock.release() # No state to save def _acquire_restore(self, x): self.__lock.acquire() # Ignore saved state def _is_owned(self): # Return True if lock is owned by current_thread. # This method is called only if __lock doesn't have _is_owned(). if self.__lock.acquire(0): self.__lock.release() return False else: return True def wait(self, timeout=None): if not self._is_owned(): raise RuntimeError("cannot wait on un-acquired lock") waiter = _allocate_lock() waiter.acquire() self.__waiters.append(waiter) saved_state = self._release_save() try: # restore state no matter what (e.g., KeyboardInterrupt) if timeout is None: waiter.acquire() if __debug__: self._note("%s.wait(): got it", self) else: # Balancing act: We can't afford a pure busy loop, so we # have to sleep; but if we sleep the whole timeout time, # we'll be unresponsive. The scheme here sleeps very # little at first, longer as time goes on, but never longer # than 20 times per second (or the timeout time remaining). endtime = _time() + timeout delay = 0.0005 # 500 us -> initial delay of 1 ms while True: gotit = waiter.acquire(0) if gotit: break remaining = endtime - _time() if remaining <= 0: break delay = min(delay * 2, remaining, .05) _sleep(delay) if not gotit: if __debug__: self._note("%s.wait(%s): timed out", self, timeout) try: self.__waiters.remove(waiter) except ValueError: pass else: if __debug__: self._note("%s.wait(%s): got it", self, timeout) finally: self._acquire_restore(saved_state) def notify(self, n=1): if not self._is_owned(): raise RuntimeError("cannot notify on un-acquired lock") __waiters = self.__waiters waiters = __waiters[:n] if not waiters: if __debug__: self._note("%s.notify(): no waiters", self) return self._note("%s.notify(): notifying %d waiter%s", self, n, n != 1 and "s" or "") for waiter in waiters: waiter.release() try: __waiters.remove(waiter) except ValueError: pass def notifyAll(self): self.notify(len(self.__waiters)) notify_all = notifyAll def Event(*args, **kwargs): return _Event(*args, **kwargs) class _Event(_Verbose): # After Tim Peters' event class (without is_posted()) def __init__(self, verbose=None): _Verbose.__init__(self, verbose) self.__cond = Condition(Lock()) self.__flag = False def isSet(self): return self.__flag is_set = isSet def set(self): self.__cond.acquire() try: self.__flag = True self.__cond.notify_all() finally: self.__cond.release() def clear(self): self.__cond.acquire() try: self.__flag = False finally: self.__cond.release() def wait(self, timeout=None): self.__cond.acquire() try: if not self.__flag: self.__cond.wait(timeout) finally: self.__cond.release()