# How to determine the sum of a group of integers without using recursion

This is my first post on Stack Overflow, and I'm hoping that it'll be a good one.

This is a problem that I thought up myself, and now I'm a bit embarrassed to say, but it's beating the living daylights out of me. Please note that this is not a homework exercise, scout's honor.

Basically, the program takes (as input) a string made up of integers from 0 to 9.

``````strInput = '2415043'
``````

Then you need to break up that string of numbers into smaller groups of numbers, until eventually, the sum of those groups give you a pre-defined total. In the case of the above string, the target is 289.

``````iTarget = 289
``````

For this example, there are two correct answers (but most likely only one will be displayed, since the program stops once the target has been reached):

``````Answer 1 = 241, 5, 043    (241 + 5 + 043    = 289)
``````

Answer 2 = 241, 5, 0, 43 (241 + 5 + 0 + 43 = 289)

Note that the integers do not change position. They are still in the same order that they were in the original string.

Now, I know how to solve this problem using recursion. But the frustrating part is that I'm NOT ALLOWED to use recursion.

This needs to be solved using only 'while' and 'for' loops. And obviously lists and functions are okay as well.

Below is some of the code that I have so far:

My Code:

``````                                         #Pre-defined input values, for the sake of simplicity
lstInput = ['2','4','1','5','0','4','3'] #This is the kind of list the user will input
sJoinedList = "".join(lstInput)          #sJoinedList = '2415043'
lstWorkingList = []                      #All further calculuations are performed on lstWorkingList
lstWorkingList.append(sJoinedList)       #lstWorkingList = ['2415043']
iTarget = 289                            #Target is pre-defined
``````

-

``````def SumAll(_lst):          #Adds up all the elements in a list
iAnswer = 0             #E.g. lstEg = [2,41,82]
for r in _lst:        #     SumAll(lstEg) = 125
``````

-

``````def AddComma(_lst):
#Adds 1 more comma to a list and resets all commas to start of list
#E.g. lstEg = [5,1001,300]  (Note only 3 groups / 2 commas)
#     [5,1,0,001300] (Now 4 groups / 3 commas)
iNoOfCommas = len(_lst) - 1   #Current number of commas in list
sResetString = "".join(_lst)  #Make a string with all the elements in the list
lstTemporaryList = []
sTemp = ""
i = 0
while i < iNoOfCommas +1:
sTemp += sResetString[i]+','    #Add a comma after every element
i += 1
sTemp += sResetString[i:]
lstTemporaryList = sTemp.split(',') #Split sTemp into a list, using ',' as a separator
#Returns list in format ['2', '415043'] or ['2', '4', '15043']
return(lstTemporaryList)
``````

So basically, the Pseudo-code will look something like this:

Pseudo-Code:

``````while SumAll(lstWorkingList) != iTarget:      #While Sum != 289
if(len(lstWorkingList[0]) == iMaxLength): #If max possible length of first element is reached
Reset(lstWorkingList)                 #reset all the commas to the beginning of the list to start again
else:
ShiftGroups()                         #Keep shifting the comma's until all possible combinations
#for this number of comma's have been tried
#Otherwise, Add another comma and repeat the whole process
``````

Phew! That was quite a mouthfull .

I have worked through the process that the program will follow on a piece of paper, so below is the expected output:

OUTPUT:

``````[2415043]  #Element 0 has reached maximum size, so add another group
#Reset()
[2, 415043] #ShiftGroups()
[24, 15043] #ShiftGroups()
[241, 5043] #ShiftGroups()
#...etc...etc...
[241504, 3] #Element 0 has reached maximum size, so add another group
#Reset()
[2, 4, 15043] #ShiftGroups()
[2, 41, 5043] #ShiftGroups()
#etc...etc...

[2, 41504, 3] #Tricky part
``````

Now here is the tricky part. In the next step, the first element must become 24, and the other two must reset.

``````#Increase Element 0
#All other elements Reset()
[24, 1, 5043] #ShiftGroups()
[24, 15, 043] #ShiftGroups()
#...etc...etc

[24, 1504, 3]
#Increase Element 0
#All other elements Reset()
[241, 5, 043] #BINGO!!!!
``````

Okay. That is the basic flow of the program logic. Now the only thing I need to figure out, is how to get it to work without recursion.

For those of you that have been reading up to this point, I sincerely thank you and hope that you still have the energy left to help me solve this problem. If anything is unclear, please ask and I'll clarify (probably in excruciating detail X-D).

Thanks again!

Edit: 1 Sept 2011

Thank you everyone for responding and for your answers. They are all very good, and definitely more elegant than the route I was following. However, my students have never worked with 'import' or any data-structures more advanced than lists. They do, however, know quite a few list functions. I should also point out that the students are quite gifted mathematically, many of them have competed and placed in international math olympiads. So this assignment is not beyond the scope of their intelligence, perhaps only beyond the scope of their python knowledge.

Last night I had a Eureka! moment. I have not implemented it yet, but will do so over the course of the weekend and then post my results here. It may be somewhat crude, but I think it will get the job done.

Sorry it took me this long to respond, my internet cap was reached and I had to wait until the 1st for it to reset. Which reminds me, happy Spring everyone (for those of you in the Southern Hempisphere).

Thanks again for your contributions. I will choose the top answer after the weekend. Regards!

-
Recursion creates an implicit stack -- how can it be done explicitly? –  user166390 Aug 31 '11 at 0:36
Why are you not allowed to use recursion if you thought it up yourself? Did you commit to using it for a class project or something? –  Tom Zych Aug 31 '11 at 1:05
Homework? Sure seems like it, if you are "not allowed to use recursion". –  Ken White Aug 31 '11 at 1:13
Pseudo-Hungarian Notation? `lstWorkingList`? Yuck! –  Johnsyweb Aug 31 '11 at 1:19
I assume you meant in `043` in decimal rather than octal? –  Mechanical snail Aug 31 '11 at 2:14

A program that finds all solutions can be expressed elegantly in functional style.

## Partitions

First, write a function that partitions your string in every possible way. (The following implementation is based on http://code.activestate.com/recipes/576795/.) Example:

``````def partitions(iterable):
'Returns a list of all partitions of the parameter.'
from itertools import chain, combinations
s = iterable if hasattr(iterable, '__getslice__') else tuple(iterable)
n = len(s)
first, middle, last = [0], range(1, n), [n]
return [map(s.__getslice__, chain(first, div), chain(div, last))
for i in range(n) for div in combinations(middle, i)]
``````

## Predicate

Now, you'll need to filter the list to find those partitions that add to the desired value. So write a little function to test whether a partition satisfies this criterion:

``````def pred(target):
'Returns a function that returns True iff the numbers in the partition sum to iTarget.'
return lambda partition: target == sum(map(int, partition))
``````

## Main program

``````strInput = '2415043'
iTarget = 289

# Run through the list of partitions and find partitions that satisfy pred
print filter(pred(iTarget), partitions(strInput))
``````

Note that the result is calculated in a single line of code.

Result: `[['241', '5', '043'], ['241', '5', '0', '43']]`

-
A neater version of the same method I used. –  agf Aug 31 '11 at 3:15

Recursion isn't the best tool for the job anyways. `itertools.product` is.

Here's how I search it:

Imagine the search space as all the binary strings of length l, where l is the length of your string minus one.

Take one of these binary strings

Write the numbers in the binary string in between the numbers of your search string.

``````2 4 1 5 0 4 3
1 0 1 0 1 0
``````

Turn the 1's into commas and the 0's into nothing.

``````2,4 1,5 0,4 3
``````

``````2,4 1,5 0,4 3 = 136
``````

Is it 289? Nope. Try again with a different binary string.

``````2 4 1 5 0 4 3
1 0 1 0 1 1
``````

You get the idea.

Onto the code!

``````import itertools

strInput = '2415043'
intInput = map(int,strInput)
correctOutput = 289

# Somewhat inelegant, but what the heck
JOIN = 0
COMMA = 1

for combo in itertools.product((JOIN, COMMA), repeat = len(strInput) - 1):
solution = []
# The first element is ALWAYS a new one.
for command, character in zip((COMMA,) + combo, intInput):
if command == JOIN:
# Append the new digit to the end of the most recent entry
newValue = (solution[-1] * 10) + character
solution[-1] = newValue
elif command == COMMA:
# Create a new entry
solution.append(character)
else:
# Should never happen
raise Exception("Invalid command code: " + command)
if sum(solution) == correctOutput:
print solution
``````

EDIT: agf posted another version of the code. It concatenates the string instead of my somewhat hacky multiply by 10 and add approach. Also, it uses true and false instead of my JOIN and COMMA constants. I'd say the two approaches are equally good, but of course I am biased. :)

``````import itertools
strInput = '2415043'
correctOutput = 289
for combo in itertools.product((True, False), repeat = len(strInput) - 1):
solution = []
for command, character in zip((False,) + combo, strInput):
if command:
solution[-1] += character
else:
solution.append(character)
solution = [int(x) for x in solution]
if sum(solution) == correctOutput:
print solution
``````
-
I like this method; I think it's the clearest. You can simplify it further (semicolons added to show line breaks): `import itertools; strInput = '2415043'; correctOutput = 289; for combo in itertools.product((True, False), repeat = len(strInput) - 1): solution = []; for command, character in zip((False,) + combo, strInput): if command: solution[-1] += character; else: solution.append(character); solution = [int(x) for x in solution]; if sum(solution) == correctOutput: print solution;` –  agf Sep 1 '11 at 20:15

To expand on pst's hint, instead of just using the call stack as recursion does, you can create an explicit stack and use it to implement a recursive algorithm without actually calling anything recursively. The details are left as an exercise for the student ;)

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Isn't that more complicated than actually using recursion? –  Nick ODell Aug 31 '11 at 5:59
@Nick ODell: Certainly. And now that the OP has told us the reason for this constraint, we can see that it's not a suitable approach. OTOH, if the OP were a student dealing with an arbitrarily imposed constraint ("find a way to do it without recursion"), this would be a valid solution. –  Tom Zych Aug 31 '11 at 9:21