How do you iterate over a tree?

What is you preferred method of traversing a tree data structure, since recursive method calls can be pretty inefficient in some circumstances, I am simply using a generator like the one above. Do you have any hints to make it faster ?

``````def children(self):
stack = [self.entities]
while stack:
for e in stack.pop():
yield e
if e.entities:
stack.append(e.entities)
``````

here is some test data: first one is recursive, second uses the generator

``````s = time.time()
for i in range(100000):
e.inc_counter()
print time.time() - s

s = time.time()
for i in range(100000):
for e in e.children():
e.inc_counter_s()
print time.time() - s
``````

results:

0.416000127792

0.298999786377

test code:

``````import random

class Entity():
def __init__(self, name):
self.entities = []
self.name = name
self.counter = 1
self.depth = 0

e.depth = self.depth + 1
self.entities.append(e)

def inc_counter_r(self):
for e in self.entities:
e.counter += 1
e.inc_counter_r()

def children(self):
stack = [self.entities]
while stack:
for e in stack.pop():
yield e
if e.entities:
stack.append(e.entities)

root = Entity("main")
def fill_node(root, max_depth):
if root.depth <= max_depth:
for i in range(random.randint(10, 15)):
e = Entity("node_%s_%s" % (root.depth, i))
fill_node(e, max_depth)
fill_node(root, 3)

import time
s = time.time()
for i in range(100):
root.inc_counter_r()
print "recursive:", time.time() - s

s = time.time()
for i in range(100):
for e in root.children():
e.counter += 1
print "generator:",  time.time() - s
``````
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uneffective? do you mean inefficient? –  nickf Nov 26 '08 at 9:08

I can't think of any big algorithmic improvements, but a simple microoptimisation you can make is to bind frequently called methods (such as stack.append / stack.pop) to locals (this saves a dictionary lookup)

``````def children(self):
stack = [self.entities]
push = stack.append
pop = stack.pop
while stack:
for e in pop():
yield e
if e.entities:
push(e.entities)
``````

This gives a small (~15%) speedup by my tests (using 100 traversals of an 8-deep tree with 4 children at each node gives me the below timings:)

``````children     :  5.53942348004
children_bind:  4.77636131253
``````

Not huge, but worth doing if speed is important.

-
I have to admid my former in application profiling results were sharper, maybe becouse of the tree structure or the methods called. But it is not insignificant either, also the ability to cache can lead to pretty interesting optimizations. –  M. Utku ALTINKAYA Nov 26 '08 at 10:42

Here's a pair of small corrections.

``````def children(self):
stack = [self.entities]
for e in stack:
yield e
if e.entities:
stack.extend(e.entities)
``````

I actually think the generator, using append, isn't visiting all the nodes. I think you mean to `extend` the stack with all entities, not `append` a simple list of entities to the stack.

Also, when the `for` loop terminates, the `while` loop in your original example will also terminate because there's no change to the empty stack after the `for` loop.

-
Well, I did used a list of lists to prevent updating the list object I am interating over, I thought it is undefined to do that ? –  M. Utku ALTINKAYA Nov 26 '08 at 15:31
You might be thinking of Java, where messing with the structure confuses the iterator. –  S.Lott Nov 26 '08 at 16:24
ok, I have tested, it works, but it seems a little slower, becouse of the extend I suppose. recursive: 1.96200013161 generator: 1.68400001526 generator_new: 1.74000000954 –  M. Utku ALTINKAYA Nov 26 '08 at 18:05
At this point, it seems like you should close this question and start again with the corrected algorithms and current timing. These times are more what I'd expect -- relatively minor differences. –  S.Lott Nov 26 '08 at 18:41
Hello, as I mentioned in my comments, It changes bu the tree structure, I have used low max_depth in these tests, so difference is smaller. Besides, the topic also stands for caching, which is not possible using recursive way, we also did not discuss searching. –  M. Utku ALTINKAYA Nov 27 '08 at 3:37
show 2 more comments

Recursive function calls are not incredibly inefficient, that is an old programming myth. (If they're badly implemented, they may incur a larger overhead than necessary, but calling them "incredibly inefficient" is plain wrong.)

Remember: don't optimize prematurely, and never optimize without benchmarking first.

-

I don't know too much about Python internals of function calls, but I really can't imagine that your code snippet is faster than recursively traversing the tree.

The call stack (used for function calls, including recursive ones) is typically very fast. Going to the next object will only cost you a single function call. But in your snippet - where you use a stack object, going to the next object will cost you a stack.append (possibly allocating memory on heap), a stack.push (possibly freeing memory from heap), and a yield.

The main problem with recursive calls is that you might blow the stack if your tree gets too deep. This isn't likely to happen.

-
I have posted some simple test data. –  M. Utku ALTINKAYA Nov 26 '08 at 9:14
Function calls are actually pretty expensive. Each call must allocate a frame object (also on the heap), populate the parameters and then invoke it. Compare doing that N times for N children vs a single append of N items and you'll see why the stack method is faster. –  Brian Nov 26 '08 at 10:12
(continued) Yields are also much quicker than function calls, as they don't create new frames - the existing frame object is reused. –  Brian Nov 26 '08 at 10:13

I've written iterative tree-traversal code in the past: it's very ugly, and not fast, unless you know exactly how many children not only each subtree will have, but how many levels there are.

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I'm not sure if you can reduce the overhead much on a full in-order traversal of a tree, if you use recursion the call stack will grow some, otherwise you must manually use a stack to push references of the children while visiting each node. Which way is fastest and uses less memory, depends on the expensiveness of the call stack vs. a normal stack. (I would guess the callstack is faster since it should be optimized for its use, and recursion is much easier to implement)

If you don't care about the order you visit the nodes, some implementations of trees is actually stored in a dynamic array or linked list or stack wich you can traverse linearly if you don't care about the order it's traversed.

But why is it important to have a fast traversal anyway? Trees are good for searching, arrays/linked lists is good for full traversal. If you often need full in-order traversal but few searches and insertions/deletions, an ordered linked list might be best, if searching is what you do most you use a tree. If the data is really massive, so that memory overhead may render recursion impossible, you should use a database.

-

If you have a lot of RAM and the tree doesn't change often, you can cache the result of the call:

``````def children(self):
if self._children_cache is not None:
return self._children_cache
# Put your code into collectChildren()
self._children_cache = self.collectChildren()
return self._children_cache
``````

Whenever the tree changes, set the cache to None. In this case, using recursive calls might be more effective since the results will accumulate faster.

-
That is a good idea, also the generator can be changed to use the cache. if e has a children_cache than you iterate over the nodes instad of pushing it into stack. :) –  M. Utku ALTINKAYA Nov 26 '08 at 8:46