# Euler project #18 approach

I am looking into an Euler project. Specifically #18.
To sum up, the idea is to find the max path from a triangle:

``````   3
7 4
2 4 6
8 5 9 3
``````

3 + 7 + 4 + 9 = 23.

Reading for this, most people indicate that this is solved correctly by working bottom to top instead of using an algorithm that works "greedy" from top to bottom.

I can undertand that starting from top and going down selecting the max you find is "sortsighted" and may not be the overall max.

But why is the approach of going from bottom to top any better?
It seems to me it suffers from the same problem.

For example in the triangle in the example we would get (starting from bottom):
9+6+4+3=22 < 23

So why start from bottom-up?

-
When two Euler problems are connected, there is always a smart way to solve it. Always observe the question, always observe the time limit. In this case, you are asked about MAXIMUM PATH .. not the path itself. –  klang Nov 7 '11 at 13:16
What do you mean "When two Euler problems are connected"?Which is the other problem here?Also how can I find the maximum path, if I do not know what forms the max path?I.e. how to do the traversing to find the value of the MAX PATH? –  Cratylus Nov 7 '11 at 13:55
In the NOTE for problem 18, problem 67 is specified as a connected problem (18, 67, 81, 82 and 83 are different variations on the same problem. Solving problem 83 will provide the method to solve the others). `MAXIMUM PATH` is a really, really good hint in this case. Enjoy solving the problems. –  klang Nov 8 '11 at 10:26
That example is misleading, at first I thought of going top-down by choosing the max child value at every step –  Khaled A Khunaifer Jun 12 at 8:03

It's something called dynamic programming.

You have such triangle:

``````   3
7 4
2 4 6
8 5 9 3
``````

When you move from the bottom to the top, you can calculate the best choices on last iteration. In this case you take the last row `8 5 9 3` and maximize sum in addition to previous line.

Iteration 1: Assume that you are on `last-1` step.

You have line `2 4 6` let iterate on it.

From 2, you can go to either 8 or 5, so 8 is better (maximize you result from 3) so you calculate first sum 8 + 2 = 10

From 4, you can go to either 5 or 9, so 9 is better (maximize you result from 4) so you calculate second sum 9 + 4 = 13

From 6, you can go to either 9 or 3, so 9 is better again (maximize you result from 6) so you calculate third sum 9 + 6 = 15

This is the end of first iteration and you got the line of sums `10 13 15`.

Now you've got triangle of lower dimension:

``````    3
7  4
10 13 15
``````

Now go on until you get one value, which is exactly 23.

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this is the smartest solution –  Senthil Kumar Aug 1 '12 at 10:18

The difference is not between top-down and bottom-up. The difference is between greedy and 'frontier' methods.

A greedy algorithm won't necessarily help you, because you can't recover if the best part of the tree gets out of reach. For example: a greedy algorithm would choose the path 1-3 from top to bottom. It would miss the 9 entirely.

``````    1
2 3
9 1 1
``````

In order to find the true maximum, you'd have to essentially traverse nearly all paths.

The bottom-up approach, as it is described, doesn't have this problem. It examines at most n*(n-1) paths: 2 for each element. However, calling it the 'bottom-up' approach is misleading.

Why? Because there is a top-down approach that is equivalent. The essence is that you have a kind of 'frontier' with best results for all trees behind the frontier. Whether you move the frontier up or down is secondary. For the top-down approach in the above example, you calculate for each row the sum of each element and the maximum of the two best totals above it:

``````     1
3 4
12 5 5
``````

In the bottom-up approach, you calculate for each row the sum of each element and the maximum of the two best totals below it. In reverse order:

``````  9  1 1
11 4
12
``````

There is about equal work in both these top-down and bottom-up approaches.

-

Using your example, the "bottom up" way to approach it is:

Examining the bottom row, the most you can get from each element is

8,5,9,3

Examining the next-to-bottom row, the most you can get from each element is (depending on whether you go left or right from it):

2+max(8,5),4+max(5,9),6+max(9,3) = 10,13,15

So this is great; we've eliminated 2 rows by squishing them together to replace them with one row, reducing the problem to

``````     3
7   4
10  13  15
``````

Obviously we can just keep repeating this. Examining the next row up, the most you can get from each element is

7+max(10,13),4+max(13,15) = 20,19

And so from the top, the most you can get is

3+max(20,19) = 23

QED.

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Is this a bottom-up.It seems recursive to me –  Cratylus Nov 3 '11 at 22:06
Recursion, iteration... it's all the same really and you're going to have to use one or the other. The point is it's a bottom up approach that works efficiently. (You could actually apply the same ideas to eliminate rows from the top, but it's not quite as clean because it doesn't reduce to a single number). –  timday Nov 3 '11 at 22:19
top-down works in the exact same way .. just select the maximum number from the last row .. that's your "single number" –  klang Nov 8 '11 at 11:29

Actually, you needn't start bottom-up; you may as well start top-down, providing you do it properly.

The way it works bottom up is best illustrated by the taking what happes at each level of the pyramid. The path surely must cross each level at some point.

``````    x
x x
x h x
x y y x
x y y y x
``````

Let's say it's `h`. From the definition of allowable paths, the path can only follow down into the `y`-marked places, which forms a problem similar to the original - if we find a maximal path through the `y`s and the maximal path of the whole triangle actually goes through `h`, it will surely follow along a maximal path in `y`s (if not, you can switch the part of path in the smaller triangle and get an overall better path).

So if you structure your algorithm top-down computing the maximal path from the current node down, you get the correct result (ie. maximal path value, from which you can easily get the path itself).

Now, this takes O(N) (N meaning the number of the numbers), because for each place, you just consider two paths and use the pre-computed values from the lower level.

Virtually the same algorithm can be implemented top down, where you start at the top and recurse down, provided you memoize the result.

``````best_length(node)
{
if(node is terminal)
return value(node)
int m = 0
for(next : lower neighbors of node)
m = max(best_length(next), m)
return m + value(node);
}
``````

Another possibility of doing this top-down would be just reverse the computation. You start at the top, for each node considering its upper neighbors, and get the path length from the top ending in this node (instead of the path going from this node down to the bottom row). At the end, you gather the data from the bottom row and you're done.

-

Taking a bottom up approach eliminates paths while going top-down only adds potential paths.

Because you're eliminating bad paths quicker, doing a breadth-first search becomes the optimal solution. A depth-first search in either direction is both wrong (as you've shown) and slow.

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I don't follow this explanation.Could you please elaborate? In the example I give the bottom up does not give the maximum.So what am I missing here? –  Cratylus Nov 3 '11 at 21:47
@user384706: Just updated –  Austin Salonen Nov 3 '11 at 21:52
So the bottom-up approach is not a depth-first search? –  Cratylus Nov 3 '11 at 21:54
@user384706: You can still do a DFS bottom-up. The point is that you shouldn't... I hesitate to provide much more without ruining it for other PE solvers. –  Austin Salonen Nov 3 '11 at 21:57
You can also solve it top-down in one pass. –  Jeffrey Sax Nov 3 '11 at 22:10

This is a problem that can be solved using graph theory. For each point, you can only travel to each of it's two 'children' (the left and right node below it). For all of the leaf nodes (the bottom row) include a path to an "end node" (with zero cost).

You want the largest number, which in turn is the longest path.

To do this, you implement a BFS (which is generally a shortest path algorithm), but instead of having the weight between a parent and child node being the value of the child node, you make it be the additive inverse of the child nodes value.

You cannot use Dijkstra easily here because Dijkstra is for non-negative paths only.

BFS has running time of O(|E|+|V|).
In a triangle there are 1+2+3+4+5+..+n = (1/2)(n)(n-1) nodes
This means that there are (n)(n-1) paths, plus the (n) for the final node connection
Total: (1/2)
(3n^2 -n) where n is the number of rows.

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I used dijkstra for problem 18, 67, 81, 82 and 83. It's all about representation. –  klang Nov 7 '11 at 13:21
I actually realised after I post this that you can modified Dikstra (the algorithm itself as opposed to the edge weighting) and that will also work fine, but in this case I think that their efficiency will be the same? It has to consider longer paths, so theres no place for a short-circuit [where Dijsktra culls longer paths]. –  Noxville Nov 8 '11 at 14:03