Python recursive function exceeds recursion limit. How can I convert it to iteration

I have created a function that reads lists of ID pairs (i.e. [("A","B"),("B","C"),("C","D"),...] and sequences the ID's from start to finish including any branches.

Each list of ordered ID's is held in a class called an Alignment and this function uses recursion to handle branches by creating a new alignment starting at the ID at which the branch splits from the main list.

I have found that with certain inputs it is possible to reach the maximum recursion limit set by Python. I know I could just increase this limit using sys.setrecursionlimit(), but as I do not know how many combinations of branches are possible, I'd like to avoid this tactic.

I have been reading several articles about converting recursive functions to iterative functions, but I have not been able to determine the best way to handle this particular function because the recursion takes place in the middle of the function and can be exponential.

Could any of you offer any suggestions?

Thanks, Brian

Code is posted below:

``````def buildAlignments(alignment, alignmentList, endIDs):
while alignment.start in endIDs:

#If endID only has one preceding ID: add preceding ID to alignment
if len(endIDs[alignment.start]) == 1:

else:

#List to hold all branches that end at spanEnd
branches = []

for each in endIDs[alignment.start]:

#New alignment for each branch
al = Alignment(each)

#Recursively process each new alignment
buildAlignments(al, branches, endIDs)

branches.append(al)
count = len(branches)
i = 0
index = 0

#Loop through branches by length
for branch in branches:
if i < count - 1:

#Create copy of original alignment and add branch to alignment
al = Alignment(alignment)
al += branch #branches[index]
alignmentList.append(al)
i += 1

#Add single branch to existing original alignment
else: alignment += branch #branches[index]
index += 1

def main():
IDs = [("L", "G"), ("A", "B"), ("B", "I"), ("B", "H"), ("B", "C"), ("F", "G"), ("D", "E"), ("D", "J"), ("E", "L"), ("C", "D"), ("E", "F"), ("J", "K")]

#Gather all startIDs with corresponding endIDs and vice versa
startIDs = {}
endIDs = {}
for pair in IDs:
if not pair[0] in startIDs: startIDs[pair[0]] = []
startIDs[pair[0]].append(pair[1])
if not pair[1] in endIDs: endIDs[pair[1]] = []
endIDs[pair[1]].append(pair[0])

#Create Alignment objects from any endID that does not start another pair (i.e. final ID in sequence)
alignments = [Alignment(end) for end in endIDs if not end in startIDs]

#Build build sequences in each original Alignment
i = len(alignments)
while i:
buildAlignments(alignments[i-1], alignments, endIDs)
i -= 1
``````

EDIT: I should point out that the provided IDs are just a small sample I used for testing this algorithm. In actuality, the sequences of IDs may be several thousand long with many branches and branches off of branches.

RESOLUTION: Thanks to Andrew Cooke. The new method seems to be much simpler and much easier on the call stack. I did make some minor adjustments to his code to better suit my purposes. I have included the completed solution below:

``````from collections import defaultdict

def expand(line, have_successors, known):
#print line
known.append(line)
for child in have_successors[line[-1]]:
newline = line + [child]
if line in known: known.remove(line)
yield expand(newline, have_successors, known)

def trampoline(generator):
stack = [generator]
while stack:
try:
generator = stack.pop()
child = next(generator)
stack.append(generator)
stack.append(child)
except StopIteration:
pass

def main(pairs):
have_successors = defaultdict(lambda: set())
for (start, end) in pairs:
known = []
for node in set(have_successors.keys()):
trampoline(expand([node], have_successors, known))
for line in known:
print line

if __name__ == '__main__':
main([("L", "G"), ("A", "B"), ("B", "I"), ("B", "H"), ("B", "C"), ("F", "G"), ("D", "E"), ("D", "J"), ("E", "L"), ("C", "D"), ("E", "F"), ("J", "K")])
``````

SUMMARY OF CHANGES: swapped links and have_successors to create list from start to end added `if line in known: known.remove(line)` to expand in order to retain only the complete series changed line variable from string to list in order to handle multiple characters in a single ID.

UPDATE: So I just discovered the reason I was having an issue with all this in the first place is do to circular references in the list of IDs I was provided. Now that the circular reference is fixed, either method works as expected. - Thanks again for all your help.

-
I think you mean offshoots. –  user671110 Aug 16 '11 at 18:33
Is this your actual code? It throws IndexError at `i = len(alignments)` ... `buildAlignments(alignments[i]` before it even starts recursing. –  Baffe Boyois Aug 16 '11 at 19:34
@Erin - thanks for pointing that out. I have changed off-chutes to branches as it is a better description. –  Brian Aug 16 '11 at 19:44
@Baffe - thank you for catching that. This was a typo when converting code to the forum. I have fixed this as well. –  Brian Aug 16 '11 at 19:45
what's the section at the end (with "index" and comments about length) supposed to do? can you describe the logic? it seems like the "else" is done for the last branch. is that the idea? –  andrew cooke Aug 16 '11 at 22:33

your code is a disorganised muddle. i can't tell what it is supposed to be doing in detail. if you were more careful (neater, clearer) then you would probably also find it easier to refactor.

anyway, this may do something like what you want:

``````from collections import defaultdict

print 'expand'
known.append(line)
newline = line + child

def trampoline(generator):
stack = [generator]
while stack:
try:
generator = stack.pop()
print 'next'
child = next(generator)
stack.append(generator)
stack.append(child)
except StopIteration:
pass

def main(pairs):
have_successors = set()
for (start, end) in pairs:
known = []
if node not in have_successors:
for line in known:
print line

if __name__ == '__main__':
main([("L", "G"), ("A", "B"), ("B", "I"), ("B", "H"), ("B", "C"), ("F", "G"), ("D", "E"), ("D", "J"), ("E", "L"), ("C", "D"), ("E", "F"), ("J", "K")])
``````

i used python2.7 - with earlier versions you may need to replace `next(foo)` with `foo.__next__()` or similar.

on writing cleaner code

first, i too am a self-taught programmer who started out as an academic (an astronomer), so you have my sympathy. and if you keep going, you can catch up and pass many "taught" programmers. it's not as hard as you might think...

second there's a difference between using "tricks" like defaultdict, which is just a matter of experience / practice, and being "tidy". i don't expect you to know about defaultdict - that will come with time.

but what you should be able to do now is write clean, simple code:

• i think that you have comments that are about earlier versions of the code. one mentions "max length" but i don't see any length calculations. so either the comment is out of date (in which case why is it there) or it needs to be clearer (why are those things of max length?). in general, you should comment as little as possible, because otherwise it does get out of date. but at the same time you should use comments where it's not clear what the "ideas" are behind the code. the code should speak for itself, so don't say "i am adding two numbers here", but do say "fragments here must be maximum length because ..." if there is some "hidden" logic.

• be careful with the pictures you use. for some reason your code starts with known terminals. so you're building things from the end back towards the start. why? that's a strange way of looking at the problem. wouldn't it be clearer to start with points that are in start, but not in end? and then use "startIDs" to grow them? that way you are "walking forwards". it might seem like a little thing, but it makes reading the code confusing.

• use the right tools for the job. you didn't use startIDs, so why are you building a map? all you needed there was a set. perhaps you didn't know about sets, in which case OK (but you do now! :o). but otherwise, that too is confusing - someone reading your code expects you to be doing things for a reason. so when you do more than is necessary they wonder why.

• avoid counting things when you don't need to. you have `i` and `index` and `count`. are they all needed? these kinds of counters are the easiest way to have bugs, because they can have silly little logic errors. and they make the code unclear. is `if i < count - 1:` really saying "is this the last branch"? if so, it would be much nicer to write `if branch == branches [-1]:` because that's clear about what you're thinking.

• similarly with looping over alignments in main. using `i` just complicates things. you are processing each alignment, so just say `for each alignment in alignments`. if that gives an error because alignments is changing, make an unchanging copy: `for each alignment in list(alignments)`.

• avoid special cases if they are not needed. in buildAlignment you have a test right at the start for a special case. but was it really needed? would you have got the same result without it? often, when you write the code simply, it turns out that you don't need special cases. in my code i don't need to test whether there is one or no "links" because it works ok in all those cases. this gives you less code and less things to worry about and less chance for bugs.

more than all these things - you have to be obsessively tidy and methodical. you have lots of ideas, but rather than try out half of one then jump to another, write them down and work through them one by one. otherwise you end up with a mess and code that you don't understand. at first it feels like you are wasting time, but you start to see that as a result you are becoming faster because you spend less time confused...

on generators

[i modified the code slightly to separate out `newline` and to add `print` in a couple of places.]

first, did you run the code? is it doing the kind of thing you want? can you see how it connects with what you had before? my `expand` is similar to your `buildAlignment` (i hope).

``````: python2.7 recurse.py
next
expand
next
expand
next
expand
next
expand
next
expand
next
expand
next
expand
next
next
...
``````

which may give a clue about what is happening. the "trick" is the yield statement - the python compiler sees that and, instead of making an ordinary function, makes a generator.

a generator is a very strange thing. it's basically your function (in this case, `expand`), "bundled up" so that it can be run in stages. the running is done by `next()` and the function stops again each time a `yield` is reached.

so `trampoline` is passed this strange bundle. and it calls `next()`. that's the "magic" function that starts the function. so when `next` is called the function starts running, until it reaches the `yield`, where it returns a new bundle. the `trampoline()` command then saves the old bundle and starts working on the new one, calling `next()` on that, starting it... etc etc.

when a generator "runs out of things to do" it raises `StopIteration`. so when we reach a point where the expression cannot grow any more then we see that exception in `trampoline()`. at that point we return to the last "old" bundle (stored in our `stack`) and call `next()` again on that. this bundle restarts from where it was (just after `yield`) and continues, probably doing another loop in the `while`, until it hits `yield` again (or runs out and raises `StopIteration`).

so in the end, the code does the same as if the `yield` was not there! the only difference is that we keep making these bundles, and returning them. which seems pointless. except that we are no longer using the stack! because the bundle is returned the stack is not being "used up"! that is why we need to manage out own stack (the list `stack`) - otherwise there's no way to know what the previous call was.

ok, ok, i don't expect you to understand this at all. yes, it's kind-of crazy. now you need to go away and google for "python generators". and write some code of your own to test it out. but hopefully this points the way.

oh, also, i was thinking last night. and i suspect that if you were exhausting the stack it was actually because you have loops, not because the chains are so long. have you considered loops? A->B, B->C, C->A, ....

-
Thank you for your response. I am not familiar with defaultdicts, but based on what I just read in the documentation, they sound like the perfect tool for containing all the endIDs. Could you please explain the expand function, I am having trouble understanding what the line represents? Also, it appears as though you are still using recursion in this code, it has just been moved into a generator. Either way this may be a good start - thank you. –  Brian Aug 17 '11 at 12:38
Would you be willing to provide feedback as to how to best organize and cleanup this code? I am a self-taught programmer and I admit I sometimes struggle with how to best organize code and understanding all the code structuring best practices. Thank you. –  Brian Aug 17 '11 at 12:40
i'll add more to the answer because the space available here is small. i'm about to make breakfast, so give me a while... –  andrew cooke Aug 17 '11 at 12:45
I did run the code and it is close to what I am looking for. It actually resulted in more than I need. Each line in known is the previous ID plus the newest ID. Once I have the full series, I don't need the individual parts that were added to known beforehand. I have added a line to expand to accommodate this. I also tried reversing it so that it works from start to end as you suggested, but it did not produce any results. I simply swapped have_successors and links throughout. –  Brian Aug 17 '11 at 13:51
well, to go from start to end you need to build the links in the other direction. so it would be `links[start].add(end)` etc. also, i've finished the text now - hope it helps. –  andrew cooke Aug 17 '11 at 14:04