from __future__ import generators execfile("static.py") import os, stat, types ####################################################################### # # lazy - Define some lazy data structures and functions acting on them # class Iter: """Hold static methods for the manipulation of lazy iterators""" def filter(predicate, iterator): """Like filter in a lazy functional programming language""" for i in iterator: if predicate(i): yield i def map(function, iterator): """Like map in a lazy functional programming language""" for i in iterator: yield function(i) def foreach(function, iterator): """Run function on each element in iterator""" for i in iterator: function(i) def cat(*iters): """Lazily concatenate iterators""" for iter in iters: for i in iter: yield i def cat2(iter_of_iters): """Lazily concatenate iterators, iterated by big iterator""" for iter in iter_of_iters: for i in iter: yield i def empty(iter): """True if iterator has length 0""" for i in iter: return None return 1 def equal(iter1, iter2, verbose = None, operator = lambda x, y: x == y): """True if iterator 1 has same elements as iterator 2 Use equality operator, or == if it is unspecified. """ for i1 in iter1: try: i2 = iter2.next() except StopIteration: if verbose: print "End when i1 = %s" % i1 return None if not operator(i1, i2): if verbose: print "%s not equal to %s" % (i1, i2) return None try: i2 = iter2.next() except StopIteration: return 1 if verbose: print "End when i2 = %s" % i2 return None def Or(iter): """True if any element in iterator is true. Short circuiting""" i = None for i in iter: if i: return i return i def And(iter): """True if all elements in iterator are true. Short circuiting""" i = 1 for i in iter: if not i: return i return i def len(iter): """Return length of iterator""" i = 0 while 1: try: iter.next() except StopIteration: return i i = i+1 def foldr(f, default, iter): """foldr the "fundamental list recursion operator"?""" try: next = iter.next() except StopIteration: return default return f(next, Iter.foldr(f, default, iter)) def foldl(f, default, iter): """the fundamental list iteration operator..""" while 1: try: next = iter.next() except StopIteration: return default default = f(default, next) def multiplex(iter, num_of_forks, final_func = None, closing_func = None): """Split a single iterater into a number of streams The return val will be a list with length num_of_forks, each of which will be an iterator like iter. final_func is the function that will be called on each element in iter just as it is being removed from the buffer. closing_func is called when all the streams are finished. """ if num_of_forks == 2 and not final_func and not closing_func: im2 = IterMultiplex2(iter) return (im2.yielda(), im2.yieldb()) if not final_func: final_func = lambda i: None if not closing_func: closing_func = lambda: None # buffer is a list of elements that some iterators need and others # don't buffer = [] # buffer[forkposition[i]] is the next element yieled by iterator # i. If it is -1, yield from the original iter starting_forkposition = [-1] * num_of_forks forkposition = starting_forkposition[:] called_closing_func = [None] def get_next(fork_num): """Return the next element requested by fork_num""" if forkposition[fork_num] == -1: try: buffer.insert(0, iter.next()) except StopIteration: # call closing_func if necessary if (forkposition == starting_forkposition and not called_closing_func[0]): closing_func() called_closing_func[0] = None raise StopIteration for i in range(num_of_forks): forkposition[i] += 1 return_val = buffer[forkposition[fork_num]] forkposition[fork_num] -= 1 blen = len(buffer) if not (blen-1) in forkposition: # Last position in buffer no longer needed assert forkposition[fork_num] == blen-2 final_func(buffer[blen-1]) del buffer[blen-1] return return_val def make_iterator(fork_num): while(1): yield get_next(fork_num) return tuple(map(make_iterator, range(num_of_forks))) MakeStatic(Iter) class IterMultiplex2: """Multiplex an iterator into 2 parts This is a special optimized case of the Iter.multiplex function, used when there is no closing_func or final_func, and we only want to split it into 2. By profiling, this is a time sensitive class. """ def __init__(self, iter): self.a_leading_by = 0 # How many places a is ahead of b self.buffer = [] self.iter = iter def yielda(self): """Return first iterator""" buf, iter = self.buffer, self.iter while(1): if self.a_leading_by >= 0: # a is in front, add new element elem = iter.next() # exception will be passed buf.append(elem) else: elem = buf.pop(0) # b is in front, subtract an element self.a_leading_by += 1 yield elem def yieldb(self): """Return second iterator""" buf, iter = self.buffer, self.iter while(1): if self.a_leading_by <= 0: # b is in front, add new element elem = iter.next() # exception will be passed buf.append(elem) else: elem = buf.pop(0) # a is in front, subtract an element self.a_leading_by -= 1 yield elem class IterTreeReducer: """Tree style reducer object for iterator The indicies of a RORPIter form a tree type structure. This class can be used on each element of an iter in sequence and the result will be as if the corresponding tree was reduced. This tries to bridge the gap between the tree nature of directories, and the iterator nature of the connection between hosts and the temporal order in which the files are processed. The elements of the iterator are required to have a tuple-style .index, called "indexed elem" below. """ def __init__(self, base_init, branch_reducer, branch_base, base_final, initial_state = None): """ITR initializer base_init is a function of one argument, an indexed elem. It is called immediately on any elem in the iterator. It should return some value type A. branch_reducer and branch_base are used to form a value on a bunch of reduced branches, in the way that a linked list of type C can be folded to form a value type B. base_final is called when leaving a tree. It takes three arguments, the indexed elem, the output (type A) of base_init, the output of branch_reducer on all the branches (type B) and returns a value type C. """ self.base_init = base_init self.branch_reducer = branch_reducer self.base_final = base_final self.branch_base = branch_base if initial_state: self.setstate(initial_state) else: self.state = IterTreeReducerState(branch_base) self.subreducer = None def setstate(self, state): """Update with new state, recursive if necessary""" self.state = state if state.substate: self.subreducer = self.newinstance(state.substate) else: self.subreducer = None def getstate(self): return self.state def getresult(self): """Return results of calculation""" if not self.state.calculated: self.calculate_final_val() return self.state.final_val def intree(self, index): """Return true if index is still in current tree""" return self.state.base_index == index[:len(self.state.base_index)] def newinstance(self, state = None): """Return reducer of same type as self If state is None, sets substate of self.state, otherwise assume this is already set. """ new = self.__class__(self.base_init, self.branch_reducer, self.branch_base, self.base_final, state) if state is None: self.state.substate = new.state return new def process_w_subreducer(self, indexed_elem): """Give object to subreducer, if necessary update branch_val""" if not self.subreducer: self.subreducer = self.newinstance() if not self.subreducer(indexed_elem): self.state.branch_val = self.branch_reducer(self.state.branch_val, self.subreducer.getresult()) self.subreducer = self.newinstance() assert self.subreducer(indexed_elem) def calculate_final_val(self): """Set final value""" if self.subreducer: self.state.branch_val = self.branch_reducer(self.state.branch_val, self.subreducer.getresult()) if self.state.current_index is None: # No input, set None as default value self.state.final_val = None else: self.state.final_val = self.base_final(self.state.base_elem, self.state.base_init_val, self.state.branch_val) self.state.calculated = 1 def __call__(self, indexed_elem): """Process elem, current position in iterator Returns true if elem successfully processed, false if elem is not in the current tree and thus the final result is available. """ index = indexed_elem.index assert type(index) is types.TupleType if self.state.current_index is None: # must be at base self.state.base_init_val = self.base_init(indexed_elem) # Do most crash-prone op first, so we don't leave inconsistent self.state.current_index = index self.state.base_index = index self.state.base_elem = indexed_elem return 1 elif not index > self.state.current_index: Log("Warning: oldindex %s >= newindex %s" % (self.state.current_index, index), 2) if not self.intree(index): self.calculate_final_val() return None else: self.process_w_subreducer(indexed_elem) self.state.current_index = index return 1 class IterTreeReducerState: """Holds the state for IterTreeReducers An IterTreeReducer cannot be pickled directly because it holds some anonymous functions. This class contains the relevant data that is likely to be picklable, so the ITR can be saved and loaded if the associated functions are known. """ def __init__(self, branch_base): """ITRS initializer Class variables: self.current_index - last index processing started on, or None self.base_index - index of first element processed self.base_elem - first element processed self.branch_val - default branch reducing value self.calculated - true iff the final value has been calculated self.base_init_val - return value of base_init function self.final_val - Final value once it's calculated self.substate - IterTreeReducerState when subreducer active """ self.current_index = None self.calculated = None self.branch_val = branch_base self.substate = None