# Need assistance with algorithm to find the maximum path in a DAG

Suppose I had this Directed Acyclic Graph (DAG), where there is a directed edge from each node (other than the nodes in the bottom row) to the two nodes below it:

``````        7
3   8
8   1   0
2   7   4   4
4   5   2   6   5
``````

I need to find a path through this DAG where the sum of the nodes' weights is maximized. You can only move diagonally down-left or down-right from a node in this tree. So for example, 7, 3, 8, 7, 5, would give the maximum path in this tree.

The input file contains the DAG formatted in this way

``````7
3 8
8 1 0
2 7 4 4
4 5 2 6 5
``````

My question is, what algorithm would be best to find maximum path and also how would this tree be represented in C++?

The node weights are non-negative.

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What do you mean by "maximum path"? A traversal from the root to a leaf node that encounters the most intermediate nodes? –  Hunter McMillen Feb 6 '12 at 0:00
... the path with the maximum total sum? –  R. Martinho Fernandes Feb 6 '12 at 0:01
@HunterMcMillen apparently the path through which the numbers add up to the greatest value –  Seth Carnegie Feb 6 '12 at 0:02
@HunterMcMillen no, he meant that `7, 3, 8, 7, 5` all add up to a greater number than the sum of the numbers of any other path through the tree –  Seth Carnegie Feb 6 '12 at 0:05
FWIW, this graph is not a tree. A tree node has only one parent. This type of structure is called a direct acyclic graph: direct because every edge has a direction, and acyclic since there is no way to get back to a node. –  kkm Feb 6 '12 at 0:52

I'd represent this triangle with a vector of vectors of `int`s.

Start at the bottom row and compare each adjanced pair of numbers. Take the bigger one and add it to the number above the pair:

`````` 5 3             13  3
\
7 8 6  becomes  7  8  6
^ ^

13 3               13 11
/
Next iteration   7  8  6   becomes  7  8  6  etc.
^  ^
``````

Work your way to the top and when you're done, the tip of the triangle will contain the largest sum.

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This dynamic programming solution is simple and fast. It's how I solved Project Euler #18 and #67. –  Blastfurnace Feb 6 '12 at 0:40
+1 for effective and fast linear complexity solution. –  stinky472 Feb 6 '12 at 0:59
Shouldn't it be read '3' instead of '11' in the first intermediate result? –  Alexandre Hamez Feb 6 '12 at 13:57
@AlexandreHamez Indeed, corrected. Thanks. –  jrok Feb 6 '12 at 14:10

A two-dimensional array would work fine. You can approach this by using a breadth first traversal, and marking each visited node with the maximum path sum for that node.

For example:

• 7 can only be reached by starting at 7.
• 3 is marked with 10, 8 is marked with 15.
• 8 is marked with 18 (10+8), 1 is marked with 11, then replaced with 16, and 0 is marked with 15.

When the leaf nodes are marked, make a quick run through them to see which is maximal. Then, you start backtracking by comparing the current node's weight, the weight of the parent nodes, and the edge weight.

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Spoilers

If you wanted to solve this problem yourself, don't read the code.

One way you could solve it is to turn the data into a tree (graph actually) and write a recursive algorithm that will find the maximum path through the tree by reducing the tree into smaller subtrees (until you have a tree with only one node) and start going up from there.

I really like recursive algorithms and working with trees, so I went ahead and wrote a program to do it:

``````#include <algorithm>
#include <iostream>
#include <vector>
#include <iterator>

using namespace std;

struct node {
node(int i, node* left = NULL, node* right = NULL) : data(i), left(left), right(right) { }

node* left, *right;
int data;
};

/*
tree:

7
3   8
8   1   0
2   7   4   4
4   5   2   6   5

*/

std::vector<node*> maxpath(node* tree, int& sum) {
if (!tree) {
sum = -1;
return std::vector<node*>();
}

std::vector<node*> path;

path.push_back(tree);

if (!tree->left && !tree->right) {
sum = tree->data;
return path;
}

int leftsum = 0, rightsum = 0;

auto leftpath = maxpath(tree->left, leftsum);
auto rightpath = maxpath(tree->right, rightsum);

if (leftsum != -1 && leftsum > rightsum) {
sum = leftsum + tree->data;
copy(begin(leftpath), end(leftpath), back_inserter<vector<node*>>(path));
return path;
}

sum = rightsum + tree->data;
copy(begin(rightpath), end(rightpath), back_inserter<vector<node*>>(path));
return path;
}

int main()
{
// create the binary tree
// yay for binary trees on the stack
node b5[] = { node(4), node(5), node(2), node(6), node(5) };
node b4[] = { node(2, &b5[0], &b5[1]), node(7, &b5[1], &b5[2]), node(4, &b5[2], &b5[3]), node(4, &b5[3], &b5[4]) };
node b3[] = { node(8, &b4[0], &b4[1]), node(1, &b4[1], &b4[2]), node(0, &b4[2], &b4[3]) };
node b2[] = { node(3, &b3[0], &b3[1]), node(8, &b3[1], &b3[2]) };

node n(7, &b2[0], &b2[1]);

int sum = 0;

auto mpath = maxpath(&n, sum);

for (int i = 0; i < mpath.size(); ++i) {
cout << mpath[i]->data;

if (i != mpath.size() - 1)
cout << " -> ";
}

cout << endl << "path added up to " << sum << endl;
}
``````

It printed

7 -> 3 -> 8 -> 7 -> 5

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That solution is waaay too inefficient (exponential complexity versus linear). –  jpalecek Feb 6 '12 at 0:59
@jpalecek which one is linear? Also it's not too inefficient for me, and there were no efficiency requirements :) The program runs faster than I can blink. I just did it for fun anyways to show another way, and this problem is just for fun too. –  Seth Carnegie Feb 6 '12 at 1:02
The top voted answer (stackoverflow.com/a/9154380/51831) is linear, as well as all the answers on the Project Euler #18 question (stackoverflow.com/questions/8002252/euler-project-18-approach). Does it run faster than you can blink on trees of height 30? You may code whatever you want for fun, but this is not something a professional should accept. –  jpalecek Feb 6 '12 at 1:16
And BTW, with a small twist, your solution would be linear as well. Which is another point AGAINST accepting an exponential solution. –  jpalecek Feb 6 '12 at 1:18
@jpalecek I haven't tested it on trees of height 30 but I don't need to because this isn't being used on trees of height thirty. Forgive me, but I didn't read where he was a professional and the solution to his problem was going into a commercial product. I think your downvote is really needless. You say "You may code whatever you want for fun", but isn't this whole thing for fun? I think you are taking this way too seriously. –  Seth Carnegie Feb 6 '12 at 1:29
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the best algorithm would be to

``````open the file,
set a counter to 0.
read each line in the file.