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I was trying to write a program for the problem I mentioned above, the numbers (i.e the lists) can be of unequal length, I was not able to figure out a way to do this other than the most commonly thought of approach i.e

  1. reverse list-1
  2. reverse list-2
  3. find the sum and store it in a new list represented by list-3
  4. reverse the list.

The complexity of this should be of the O(n+m). Is there anyway to reduce it, or do it better?

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Yeah, can you explain what is actually in these linked lists? Also, probably the answer is: no, you cannot do better than O(n); but this depends on how you are representing these things. –  BobbyShaftoe Oct 18 '09 at 4:17
    
What do you mean by "numbers represented as linked lists"? Do you mean that you have a linked list, with one digit stored in each element? Also, if you need to do something that involves each element of two linked lists, the best running time you're ever possibly going to get is O(n+m), because it takes that many operations just to look at all of the elements. –  Brian Campbell Oct 18 '09 at 4:17
    
yeah Brian that is what I mean. –  Shiv Oct 18 '09 at 4:18
    
Bobby I hope that answers your question. –  Shiv Oct 18 '09 at 4:20
1  
Since this is tagged C++, can you use std::list? Then you already know the size of the lists and can use reverse iterators. –  Duck Oct 18 '09 at 5:47

5 Answers 5

up vote 3 down vote accepted

Ideally the first thing I would do is store the numbers in reverse digit order, so 43,712 is stored as:

2 -> 1 -> 7 -> 3 -> 4

It makes arithmetic operations much easier.

Displaying a number can be done either iteratively or more simply with a recursive algorithm. Note: all this assumes singly-linked lists.

Edit: But you've since stated you have no choice in the storage format. As such, your best bet is to reverse both the lists, do the addition and then reverse the result.

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I am assuming that he doesn't get to pick how they are stored, which is why he starts with reversing the list, otherwise yours is the simplest approach. –  James Black Oct 18 '09 at 4:20
    
yup thats right James –  Shiv Oct 18 '09 at 4:27
    
But what about the time it takes to reverse them, since you don't know the length ahead of time, so you can't do it in place. You end up removing the head of the source, and pushing them back into the other order, but that means you fully traverse the list twice, doing a minor operation. –  James Black Oct 18 '09 at 5:50
    
Traversing a list twice is still an O(n) operation. Other approaches end up just copying the list anyway (eg if you push nodes onto a stack to de facto reverse them) or if you recursively walk backwards that's actually an O(n^2) operation. –  cletus Oct 18 '09 at 5:52

You can do better without list reversal. WLOG I'll assume that both lists have equal length (prepend with 0 if necessary).

Start the addition from left to right (from most significant to least significant digit). You have three cases, depending of the sum of two digits:

  1. = 9: keep the nine and increase a counter
  2. < 9: write counter x nine, write sum, reset counter
  3. > 9: increase last digit, write counter x zero, write sum (modulo 10), reset counter

I'll work on the following example:

2 568 794 +
1 438 204
--------- =
4 006 998
  1. Add 2 + 1 = 3: case 3.
    • list = (3), counter = 0
  2. Add 5 + 4 = 9: case 1
    • list = (3), counter = 1
  3. Add 6 + 4 = 9: case 1
    • list = (3), counter = 2
  4. Add 8 + 8 = 16: case 3
    • list = (4, 0, 0, 6), counter = 0
  5. Add 7 + 2 = 9: case 1
    • list = (4, 0, 0, 6), counter = 1
  6. Add 9 + 0 = 9: case 1
    • list = (4, 0, 0, 6), counter = 2
  7. Add 4 + 4 = 8: case 2
    • list = (4, 0, 0, 6, 9, 9, 8), counter = 0
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Thats great, but how will this method work for unequal length lists? –  Shiv Nov 2 '09 at 15:49
    
You still need to know the sizes of the list and make them the equal by prepending 0 to the shorter (or, put the first m - n elements (m > n) in the final list). –  Alexandru Nov 3 '09 at 0:25

If you can use a doubly-linked list then you can quickly traverse to the end of each list, and then just work your way back, adding the numbers at each point and add that to a new list.

You will need to determine which list is longer, and add up based on the length of the shorter list, and then just finish summing and adding the longer list.

But, you will have some issues with the fact that the sum may go over one digit, so if that happens you will need to keep track of the overflow and add that to the next node.

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im using only a singly linked list. –  Shiv Oct 18 '09 at 4:20
    
Then determine the length, find the longest, add the nodes that are in excess to the new list, then go through adding them, but, you need to keep track of the earlier node in case of overflow, and if that overflow overflows, then you have a problem. –  James Black Oct 18 '09 at 4:23
    
That will involve traversing the list multiple times, first to find the lengths, and then to do additions, I am trying to however minimize the number of times I traverse the list. Thanks for your suggestion though, I had thought of that initially. –  Shiv Oct 18 '09 at 4:27
    
@Shiv - It is only traversing twice, the first time is fast in that you just count the nodes in each list, and the second will involve math and adding new nodes. Reversing the list will be more expensive as you are creating a new list since you can't just swap in-place, since you don't know the end, and have a singly linked list. –  James Black Oct 18 '09 at 4:41
    
@James - you can reverse a linked list without allocating new objects. –  Stephen C Oct 18 '09 at 6:16

I don't think of a better solution to the problem as stated. The root problem is that you have to process the list elements in the reverse order. In theory you could implement the algorithm recursively, avoiding the need for explicit reversal steps. But that requires O(max(m,n)) stack space, and would most likely be slower.

But I think that is really saying that you've chosen a poor representation. If you represent the numbers as doubly linked lists of int or arrays of int (with an explicit size), the complexity will be O(max(m,n)) with a smaller constant of proportionality.

Note: O(max(m,n)) and O(m+n) are both abuses of O notation. Strictly speaking, O is a defined in terms of a limit as a single variable goes to infinity. Looked at it this way, O(max(m,n)) and O(m+n) both reduce to O(m) or O(n). However, I understand what you are trying to say :-).

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well thats a design constraint, im not at liberty to choose the method of representation, its something that came up in a discussion with a friend a few hours ago.:) –  Shiv Oct 18 '09 at 4:22

The only potential optimization, which would come at the cost of some code clarity, would be to combine the initial reversals into a single loop. You then go from O(n+m+m) to O(m+m), although the steps inside the loop are costlier.

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@jfawcett - I'm pretty sure this would give no improvement ... assuming that you are doing list reversal by pointer reversal. –  Stephen C Oct 18 '09 at 6:14
    
@jfawcett, can you explain your solution a little more, i thought along these lines but was at loss to see how I could combine the initial steps of reversing both the lists in a single loop. since I dont know which number is longer, maybe some pseudocode would help. –  Shiv Oct 18 '09 at 15:23
    
The method you proposed was reverse/count 1 (len=x), then reverse/count 2 (len=y), then sum/store the new (len=max(x,y)). If, instead, you have a single loop that reverses both 1 and 2 at the same time. When reversing a single, you do something like while( currentHead != NULL ) { <reverse> } Replace this with while( currentHead1 != NULL || currentHead2 != NULL) { if (currentHead1) { reverse 1 } if (currentHead2) { reverse 2 } } This only works with non-recursive reversal, of course. –  jfawcett Oct 18 '09 at 15:49

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