Lib/heapq.py - platform/external/python/cpython2 - Gitiles

 # -*- coding: Latin-1 -*-

 """Heap queue algorithm (a.k.a. priority queue).

 Heaps are arrays for which a[k] <= a[2*k+1] and a[k] <= a[2*k+2] for
 all k, counting elements from 0.  For the sake of comparison,
 non-existing elements are considered to be infinite.  The interesting
 property of a heap is that a[0] is always its smallest element.

 Usage:

 heap = []            # creates an empty heap
 heappush(heap, item) # pushes a new item on the heap
 item = heappop(heap) # pops the smallest item from the heap
 item = heap[0]       # smallest item on the heap without popping it
 heapify(x)           # transforms list into a heap, in-place, in linear time
 item = heapreplace(heap, item) # pops and returns smallest item, and adds
                                # new item; the heap size is unchanged

 Our API differs from textbook heap algorithms as follows:

 - We use 0-based indexing.  This makes the relationship between the
   index for a node and the indexes for its children slightly less
   obvious, but is more suitable since Python uses 0-based indexing.

 - Our heappop() method returns the smallest item, not the largest.

 These two make it possible to view the heap as a regular Python list
 without surprises: heap[0] is the smallest item, and heap.sort()
 maintains the heap invariant!
 """

 # Original code by Kevin O'Connor, augmented by Tim Peters

 __about__ = """Heap queues

 [explanation by François Pinard]

 Heaps are arrays for which a[k] <= a[2*k+1] and a[k] <= a[2*k+2] for
 all k, counting elements from 0.  For the sake of comparison,
 non-existing elements are considered to be infinite.  The interesting
 property of a heap is that a[0] is always its smallest element.

 The strange invariant above is meant to be an efficient memory
 representation for a tournament.  The numbers below are `k', not a[k]:

                                    0

                   1                                 2

           3               4                5               6

       7       8       9       10      11      12      13      14

     15 16   17 18   19 20   21 22   23 24   25 26   27 28   29 30


 In the tree above, each cell `k' is topping `2*k+1' and `2*k+2'.  In
 an usual binary tournament we see in sports, each cell is the winner
 over the two cells it tops, and we can trace the winner down the tree
 to see all opponents s/he had.  However, in many computer applications
 of such tournaments, we do not need to trace the history of a winner.
 To be more memory efficient, when a winner is promoted, we try to
 replace it by something else at a lower level, and the rule becomes
 that a cell and the two cells it tops contain three different items,
 but the top cell "wins" over the two topped cells.

 If this heap invariant is protected at all time, index 0 is clearly
 the overall winner.  The simplest algorithmic way to remove it and
 find the "next" winner is to move some loser (let's say cell 30 in the
 diagram above) into the 0 position, and then percolate this new 0 down
 the tree, exchanging values, until the invariant is re-established.
 This is clearly logarithmic on the total number of items in the tree.
 By iterating over all items, you get an O(n ln n) sort.

 A nice feature of this sort is that you can efficiently insert new
 items while the sort is going on, provided that the inserted items are
 not "better" than the last 0'th element you extracted.  This is
 especially useful in simulation contexts, where the tree holds all
 incoming events, and the "win" condition means the smallest scheduled
 time.  When an event schedule other events for execution, they are
 scheduled into the future, so they can easily go into the heap.  So, a
 heap is a good structure for implementing schedulers (this is what I
 used for my MIDI sequencer :-).

 Various structures for implementing schedulers have been extensively
 studied, and heaps are good for this, as they are reasonably speedy,
 the speed is almost constant, and the worst case is not much different
 than the average case.  However, there are other representations which
 are more efficient overall, yet the worst cases might be terrible.

 Heaps are also very useful in big disk sorts.  You most probably all
 know that a big sort implies producing "runs" (which are pre-sorted
 sequences, which size is usually related to the amount of CPU memory),
 followed by a merging passes for these runs, which merging is often
 very cleverly organised[1].  It is very important that the initial
 sort produces the longest runs possible.  Tournaments are a good way
 to that.  If, using all the memory available to hold a tournament, you
 replace and percolate items that happen to fit the current run, you'll
 produce runs which are twice the size of the memory for random input,
 and much better for input fuzzily ordered.

 Moreover, if you output the 0'th item on disk and get an input which
 may not fit in the current tournament (because the value "wins" over
 the last output value), it cannot fit in the heap, so the size of the
 heap decreases.  The freed memory could be cleverly reused immediately
 for progressively building a second heap, which grows at exactly the
 same rate the first heap is melting.  When the first heap completely
 vanishes, you switch heaps and start a new run.  Clever and quite
 effective!

 In a word, heaps are useful memory structures to know.  I use them in
 a few applications, and I think it is good to keep a `heap' module
 around. :-)

 --------------------
 [1] The disk balancing algorithms which are current, nowadays, are
 more annoying than clever, and this is a consequence of the seeking
 capabilities of the disks.  On devices which cannot seek, like big
 tape drives, the story was quite different, and one had to be very
 clever to ensure (far in advance) that each tape movement will be the
 most effective possible (that is, will best participate at
 "progressing" the merge).  Some tapes were even able to read
 backwards, and this was also used to avoid the rewinding time.
 Believe me, real good tape sorts were quite spectacular to watch!
 From all times, sorting has always been a Great Art! :-)
 """

 __all__ = ['heappush', 'heappop', 'heapify', 'heapreplace']

 def heappush(heap, item):
     """Push item onto heap, maintaining the heap invariant."""
     heap.append(item)
     _siftdown(heap, 0, len(heap)-1)

 def heappop(heap):
     """Pop the smallest item off the heap, maintaining the heap invariant."""
     lastelt = heap.pop()    # raises appropriate IndexError if heap is empty
     if heap:
         returnitem = heap[0]
         heap[0] = lastelt
         _siftup(heap, 0)
     else:
         returnitem = lastelt
     return returnitem

 def heapreplace(heap, item):
     """Pop and return the current smallest value, and add the new item.

     This is more efficient than heappop() followed by heappush(), and can be
     more appropriate when using a fixed-size heap.  Note that the value
     returned may be larger than item!  That constrains reasonable uses of
     this routine.
     """
     returnitem = heap[0]    # raises appropriate IndexError if heap is empty
     heap[0] = item
     _siftup(heap, 0)
     return returnitem

 def heapify(x):
     """Transform list into a heap, in-place, in O(len(heap)) time."""
     n = len(x)
     # Transform bottom-up.  The largest index there's any point to looking at
     # is the largest with a child index in-range, so must have 2*i + 1 < n,
     # or i < (n-1)/2.  If n is even = 2*j, this is (2*j-1)/2 = j-1/2 so
     # j-1 is the largest, which is n//2 - 1.  If n is odd = 2*j+1, this is
     # (2*j+1-1)/2 = j so j-1 is the largest, and that's again n//2-1.
     for i in xrange(n//2 - 1, -1, -1):
         _siftup(x, i)

 # 'heap' is a heap at all indices >= startpos, except possibly for pos.  pos
 # is the index of a leaf with a possibly out-of-order value.  Restore the
 # heap invariant.
 def _siftdown(heap, startpos, pos):
     newitem = heap[pos]
     # Follow the path to the root, moving parents down until finding a place
     # newitem fits.
     while pos > startpos:
         parentpos = (pos - 1) >> 1
         parent = heap[parentpos]
         if parent <= newitem:
             break
         heap[pos] = parent
         pos = parentpos
     heap[pos] = newitem

 # The child indices of heap index pos are already heaps, and we want to make
 # a heap at index pos too.  We do this by bubbling the smaller child of
 # pos up (and so on with that child's children, etc) until hitting a leaf,
 # then using _siftdown to move the oddball originally at index pos into place.
 #
 # We *could* break out of the loop as soon as we find a pos where newitem <=
 # both its children, but turns out that's not a good idea, and despite that
 # many books write the algorithm that way.  During a heap pop, the last array
 # element is sifted in, and that tends to be large, so that comparing it
 # against values starting from the root usually doesn't pay (= usually doesn't
 # get us out of the loop early).  See Knuth, Volume 3, where this is
 # explained and quantified in an exercise.
 #
 # Cutting the # of comparisons is important, since these routines have no
 # way to extract "the priority" from an array element, so that intelligence
 # is likely to be hiding in custom __cmp__ methods, or in array elements
 # storing (priority, record) tuples.  Comparisons are thus potentially
 # expensive.
 #
 # On random arrays of length 1000, making this change cut the number of
 # comparisons made by heapify() a little, and those made by exhaustive
 # heappop() a lot, in accord with theory.  Here are typical results from 3
 # runs (3 just to demonstrate how small the variance is):
 #
 # Compares needed by heapify     Compares needed by 1000 heappops
 # --------------------------     --------------------------------
 # 1837 cut to 1663               14996 cut to 8680
 # 1855 cut to 1659               14966 cut to 8678
 # 1847 cut to 1660               15024 cut to 8703
 #
 # Building the heap by using heappush() 1000 times instead required
 # 2198, 2148, and 2219 compares:  heapify() is more efficient, when
 # you can use it.
 #
 # The total compares needed by list.sort() on the same lists were 8627,
 # 8627, and 8632 (this should be compared to the sum of heapify() and
 # heappop() compares):  list.sort() is (unsurprisingly!) more efficient
 # for sorting.

 def _siftup(heap, pos):
     endpos = len(heap)
     startpos = pos
     newitem = heap[pos]
     # Bubble up the smaller child until hitting a leaf.
     childpos = 2*pos + 1    # leftmost child position
     while childpos < endpos:
         # Set childpos to index of smaller child.
         rightpos = childpos + 1
         if rightpos < endpos and heap[rightpos] <= heap[childpos]:
             childpos = rightpos
         # Move the smaller child up.
         heap[pos] = heap[childpos]
         pos = childpos
         childpos = 2*pos + 1
     # The leaf at pos is empty now.  Put newitem there, and and bubble it up
     # to its final resting place (by sifting its parents down).
     heap[pos] = newitem
     _siftdown(heap, startpos, pos)

 if __name__ == "__main__":
     # Simple sanity test
     heap = []
     data = [1, 3, 5, 7, 9, 2, 4, 6, 8, 0]
     for item in data:
         heappush(heap, item)
     sort = []
     while heap:
         sort.append(heappop(heap))
     print sort
	# -- coding: Latin-1 --

	"""Heap queue algorithm (a.k.a. priority queue).

	Heaps are arrays for which a[k] <= a[2k+1] and a[k] <= a[2k+2] for
	all k, counting elements from 0. For the sake of comparison,
	non-existing elements are considered to be infinite. The interesting
	property of a heap is that a[0] is always its smallest element.

	Usage:

	heap = [] # creates an empty heap
	heappush(heap, item) # pushes a new item on the heap
	item = heappop(heap) # pops the smallest item from the heap
	item = heap[0] # smallest item on the heap without popping it
	heapify(x) # transforms list into a heap, in-place, in linear time
	item = heapreplace(heap, item) # pops and returns smallest item, and adds
	# new item; the heap size is unchanged

	Our API differs from textbook heap algorithms as follows:

	- We use 0-based indexing. This makes the relationship between the
	index for a node and the indexes for its children slightly less
	obvious, but is more suitable since Python uses 0-based indexing.

	- Our heappop() method returns the smallest item, not the largest.

	These two make it possible to view the heap as a regular Python list
	without surprises: heap[0] is the smallest item, and heap.sort()
	maintains the heap invariant!
	"""

	# Original code by Kevin O'Connor, augmented by Tim Peters

	__about__ = """Heap queues

	[explanation by François Pinard]

	Heaps are arrays for which a[k] <= a[2k+1] and a[k] <= a[2k+2] for
	all k, counting elements from 0. For the sake of comparison,
	non-existing elements are considered to be infinite. The interesting
	property of a heap is that a[0] is always its smallest element.

	The strange invariant above is meant to be an efficient memory
	representation for a tournament. The numbers below are `k', not a[k]:

	0

	1 2

	3 4 5 6

	7 8 9 10 11 12 13 14

	15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30


	In the tree above, each cell `k' is topping `2k+1' and `2k+2'. In
	an usual binary tournament we see in sports, each cell is the winner
	over the two cells it tops, and we can trace the winner down the tree
	to see all opponents s/he had. However, in many computer applications
	of such tournaments, we do not need to trace the history of a winner.
	To be more memory efficient, when a winner is promoted, we try to
	replace it by something else at a lower level, and the rule becomes
	that a cell and the two cells it tops contain three different items,
	but the top cell "wins" over the two topped cells.

	If this heap invariant is protected at all time, index 0 is clearly
	the overall winner. The simplest algorithmic way to remove it and
	find the "next" winner is to move some loser (let's say cell 30 in the
	diagram above) into the 0 position, and then percolate this new 0 down
	the tree, exchanging values, until the invariant is re-established.
	This is clearly logarithmic on the total number of items in the tree.
	By iterating over all items, you get an O(n ln n) sort.

	A nice feature of this sort is that you can efficiently insert new
	items while the sort is going on, provided that the inserted items are
	not "better" than the last 0'th element you extracted. This is
	especially useful in simulation contexts, where the tree holds all
	incoming events, and the "win" condition means the smallest scheduled
	time. When an event schedule other events for execution, they are
	scheduled into the future, so they can easily go into the heap. So, a
	heap is a good structure for implementing schedulers (this is what I
	used for my MIDI sequencer :-).

	Various structures for implementing schedulers have been extensively
	studied, and heaps are good for this, as they are reasonably speedy,
	the speed is almost constant, and the worst case is not much different
	than the average case. However, there are other representations which
	are more efficient overall, yet the worst cases might be terrible.

	Heaps are also very useful in big disk sorts. You most probably all
	know that a big sort implies producing "runs" (which are pre-sorted
	sequences, which size is usually related to the amount of CPU memory),
	followed by a merging passes for these runs, which merging is often
	very cleverly organised[1]. It is very important that the initial
	sort produces the longest runs possible. Tournaments are a good way
	to that. If, using all the memory available to hold a tournament, you
	replace and percolate items that happen to fit the current run, you'll
	produce runs which are twice the size of the memory for random input,
	and much better for input fuzzily ordered.

	Moreover, if you output the 0'th item on disk and get an input which
	may not fit in the current tournament (because the value "wins" over
	the last output value), it cannot fit in the heap, so the size of the
	heap decreases. The freed memory could be cleverly reused immediately
	for progressively building a second heap, which grows at exactly the
	same rate the first heap is melting. When the first heap completely
	vanishes, you switch heaps and start a new run. Clever and quite
	effective!

	In a word, heaps are useful memory structures to know. I use them in
	a few applications, and I think it is good to keep a `heap' module
	around. :-)

	--------------------
	[1] The disk balancing algorithms which are current, nowadays, are
	more annoying than clever, and this is a consequence of the seeking
	capabilities of the disks. On devices which cannot seek, like big
	tape drives, the story was quite different, and one had to be very
	clever to ensure (far in advance) that each tape movement will be the
	most effective possible (that is, will best participate at
	"progressing" the merge). Some tapes were even able to read
	backwards, and this was also used to avoid the rewinding time.
	Believe me, real good tape sorts were quite spectacular to watch!
	From all times, sorting has always been a Great Art! :-)
	"""

	__all__ = ['heappush', 'heappop', 'heapify', 'heapreplace']

	def heappush(heap, item):
	"""Push item onto heap, maintaining the heap invariant."""
	heap.append(item)
	_siftdown(heap, 0, len(heap)-1)

	def heappop(heap):
	"""Pop the smallest item off the heap, maintaining the heap invariant."""
	lastelt = heap.pop() # raises appropriate IndexError if heap is empty
	if heap:
	returnitem = heap[0]
	heap[0] = lastelt
	_siftup(heap, 0)
	else:
	returnitem = lastelt
	return returnitem

	def heapreplace(heap, item):
	"""Pop and return the current smallest value, and add the new item.

	This is more efficient than heappop() followed by heappush(), and can be
	more appropriate when using a fixed-size heap. Note that the value
	returned may be larger than item! That constrains reasonable uses of
	this routine.
	"""
	returnitem = heap[0] # raises appropriate IndexError if heap is empty
	heap[0] = item
	_siftup(heap, 0)
	return returnitem

	def heapify(x):
	"""Transform list into a heap, in-place, in O(len(heap)) time."""
	n = len(x)
	# Transform bottom-up. The largest index there's any point to looking at
	# is the largest with a child index in-range, so must have 2*i + 1 < n,
	# or i < (n-1)/2. If n is even = 2j, this is (2j-1)/2 = j-1/2 so
	# j-1 is the largest, which is n//2 - 1. If n is odd = 2*j+1, this is
	# (2*j+1-1)/2 = j so j-1 is the largest, and that's again n//2-1.
	for i in xrange(n//2 - 1, -1, -1):
	_siftup(x, i)

	# 'heap' is a heap at all indices >= startpos, except possibly for pos. pos
	# is the index of a leaf with a possibly out-of-order value. Restore the
	# heap invariant.
	def _siftdown(heap, startpos, pos):
	newitem = heap[pos]
	# Follow the path to the root, moving parents down until finding a place
	# newitem fits.
	while pos > startpos:
	parentpos = (pos - 1) >> 1
	parent = heap[parentpos]
	if parent <= newitem:
	break
	heap[pos] = parent
	pos = parentpos
	heap[pos] = newitem

	# The child indices of heap index pos are already heaps, and we want to make
	# a heap at index pos too. We do this by bubbling the smaller child of
	# pos up (and so on with that child's children, etc) until hitting a leaf,
	# then using _siftdown to move the oddball originally at index pos into place.
	#
	# We could break out of the loop as soon as we find a pos where newitem <=
	# both its children, but turns out that's not a good idea, and despite that
	# many books write the algorithm that way. During a heap pop, the last array
	# element is sifted in, and that tends to be large, so that comparing it
	# against values starting from the root usually doesn't pay (= usually doesn't
	# get us out of the loop early). See Knuth, Volume 3, where this is
	# explained and quantified in an exercise.
	#
	# Cutting the # of comparisons is important, since these routines have no
	# way to extract "the priority" from an array element, so that intelligence
	# is likely to be hiding in custom __cmp__ methods, or in array elements
	# storing (priority, record) tuples. Comparisons are thus potentially
	# expensive.
	#
	# On random arrays of length 1000, making this change cut the number of
	# comparisons made by heapify() a little, and those made by exhaustive
	# heappop() a lot, in accord with theory. Here are typical results from 3
	# runs (3 just to demonstrate how small the variance is):
	#
	# Compares needed by heapify Compares needed by 1000 heappops
	# -------------------------- --------------------------------
	# 1837 cut to 1663 14996 cut to 8680
	# 1855 cut to 1659 14966 cut to 8678
	# 1847 cut to 1660 15024 cut to 8703
	#
	# Building the heap by using heappush() 1000 times instead required
	# 2198, 2148, and 2219 compares: heapify() is more efficient, when
	# you can use it.
	#
	# The total compares needed by list.sort() on the same lists were 8627,
	# 8627, and 8632 (this should be compared to the sum of heapify() and
	# heappop() compares): list.sort() is (unsurprisingly!) more efficient
	# for sorting.

	def _siftup(heap, pos):
	endpos = len(heap)
	startpos = pos
	newitem = heap[pos]
	# Bubble up the smaller child until hitting a leaf.
	childpos = 2*pos + 1 # leftmost child position
	while childpos < endpos:
	# Set childpos to index of smaller child.
	rightpos = childpos + 1
	if rightpos < endpos and heap[rightpos] <= heap[childpos]:
	childpos = rightpos
	# Move the smaller child up.
	heap[pos] = heap[childpos]
	pos = childpos
	childpos = 2*pos + 1
	# The leaf at pos is empty now. Put newitem there, and and bubble it up
	# to its final resting place (by sifting its parents down).
	heap[pos] = newitem
	_siftdown(heap, startpos, pos)

	if __name__ == "__main__":
	# Simple sanity test
	heap = []
	data = [1, 3, 5, 7, 9, 2, 4, 6, 8, 0]
	for item in data:
	heappush(heap, item)
	sort = []
	while heap:
	sort.append(heappop(heap))
	print sort