# Dynamic programming exercise for string cutting

I have been working on the following problem from this book.

A certain string-processing language offers a primitive operation which splits a string into two pieces. Since this operation involves copying the original string, it takes n units of time for a string of length n, regardless of the location of the cut. Suppose, now, that you want to break a string into many pieces. The order in which the breaks are made can affect the total running time. For example, if you want to cut a 20-character string at positions 3 and 10, then making the first cut at position 3 incurs a total cost of 20+17=37, while doing position 10 first has a better cost of 20+10=30.

I need a dynamic programming algorithm that given m cuts, finds the minimum cost of cutting a string into m+1 pieces.

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I don't understand your explanation of cutting cost of the string. Can you tell me how did you get `20+17` and `20+10`? – noMAD Apr 9 '12 at 3:29
a yet more optimal solution would involve having a dynamic algorithm running a constant time of n regardless of m, which would be even more efficient. Just a thought. – Yanick Rochon Apr 9 '12 at 3:32
@noMAD: for 20+17, 20 is from cost of cutting length 3 while 17 is from cost of cutting length 20-3 = 17. – Mark Apr 9 '12 at 3:38
@Mark: That raises one more question. Is the second or subsequent cutting relative to the previous cutting? Example, if its `3 and 10` the first `3rd` position is cut and then 17 remains and then `10th` position is cut (but with respect to original word `13th` is cut)?? – noMAD Apr 9 '12 at 4:27
@noMAD: The cutting positions are fixed. – Mark Apr 9 '12 at 4:44

The divide and conquer approach seems to me the best one for this kind of problem. Here is a Java implementation of the algorithm:

Note: the array `m` should be sorted in ascending order (use `Arrays.sort(m);`)

``````public int findMinCutCost(int[] m, int n) {
int cost = n * m.length;
for (int i=0; i<m.length; i++) {
cost = Math.min(findMinCutCostImpl(m, n, i), cost);
}
return cost;
}

private int findMinCutCostImpl(int[] m, int n, int i) {
if (m.length == 1) return n;
int cl = 0, cr = 0;
if (i > 0) {
cl = Integer.MAX_VALUE;
int[] ml = Arrays.copyOfRange(m, 0, i);
int nl = m[i];
for (int j=0; j<ml.length; j++) {
cl = Math.min(findMinCutCostImpl(ml, nl, j), cl);
}
}
if (i < m.length - 1) {
cr = Integer.MAX_VALUE;
int[] mr = Arrays.copyOfRange(m, i + 1, m.length);
int nr = n - m[i];
for (int j=0; j<mr.length; j++) {
mr[j] = mr[j] - m[i];
}
for (int j=0; j<mr.length; j++) {
cr = Math.min(findMinCutCostImpl(mr, nr, j), cr);
}
}
return n + cl + cr;
}
``````

For example :

`````` int n = 20;
int[] m = new int[] { 10, 3 };

System.out.println(findMinCutCost(m, n));
``````

Will print `30`

** Edit **

I have implemented two other methods to answer the problem in the question.

### 1. Median cut approximation

This method cut recursively always the biggest chunks. The results are not always the best solution, but offers a not negligible gain (in the order of +100000% gain from my tests) for a negligible minimal cut loss difference from the best cost.

``````public int findMinCutCost2(int[] m, int n) {
if (m.length == 0) return 0;
if (m.length == 1) return n;
float half = n/2f;
int bestIndex = 0;
for (int i=1; i<m.length; i++) {
if (Math.abs(half - m[bestIndex]) > Math.abs(half - m[i])) {
bestIndex = i;
}
}
int cl = 0, cr = 0;
if (bestIndex > 0) {
int[] ml = Arrays.copyOfRange(m, 0, bestIndex);
int nl = m[bestIndex];
cl = findMinCutCost2(ml, nl);
}
if (bestIndex < m.length - 1) {
int[] mr = Arrays.copyOfRange(m, bestIndex + 1, m.length);
int nr = n - m[bestIndex];
for (int j=0; j<mr.length; j++) {
mr[j] = mr[j] - m[bestIndex];
}
cr = findMinCutCost2(mr, nr);
}
return n + cl + cr;
}
``````

### 2. A constant time multi-cut

Instead of calculating the minimal cost, just use different indices and buffers. Since this method executes in a constant time, it always returns n. Plus, the method actually split the string in substrings.

``````public int findMinCutCost3(int[] m, int n) {
char[][] charArr = new char[m.length+1][];
charArr[0] = new char[m[0]];
for (int i=0, j=0, k=0; j<n; j++) {
//charArr[i][k++] = string[j];   // string is the actual string to split
if (i < m.length && j == m[i]) {
if (++i >= m.length) {
charArr[i] = new char[n - m[i-1]];
} else {
charArr[i] = new char[m[i] - m[i-1]];
}
k=0;
}
}
return n;
}
``````

Note: that this last method could easily be modified to accept a `String str` argument instead of `n` and set `n = str.length()`, and return a `String[]` array from `charArr[][]`.

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For dynamic programming, I claim that all you really need to know is what the state space should be - how to represent partial problems.

Here we are dividing a string up into m+1 pieces by creating new breaks. I claim that a good state space is a set of (a, b) pairs, where a is the location of the start of a substring and b is the location of the end of the same substring, counted as number of breaks in the final broken down string. The cost associated with each pair is the minimum cost of breaking it up. If b <= a + 1, then the cost is 0, because there are no more breaks to put in. If b is larger, then the possible locations for the next break in that substring are the points a+1, a+2,... b-1. The next break is going to cost b-a regardless of where we put it, but if we put it at position k the minimum cost of later breaks is (a, k) + (k, b).

So to solve this with dynamic programming, build up a table (a, b) of minimum costs, where you can work out the cost of breaks on strings with k sections by considering k - 1 possible breaks and then looking up the costs of strings with at most k - 1 sections.

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python code:

``````mincost(n, cut_list) =min {   n+ mincost(k,left_cut_list) + min(n-k, right_cut_list) }

import sys

def splitstr(n,cut_list):

if len(cut_list) == 0:
return [0,[]]
min_positions = []
min_cost = sys.maxint
for k in cut_list:
left_split = [ x for x in cut_list if x < k]
right_split = [ x-k for x in cut_list if x > k]
#print n,k, left_split, right_split
lcost = splitstr(k,left_split)
rcost = splitstr(n-k,right_split)
cost = n+lcost[0] + rcost[0]
positions = [k] + lcost[1]+ [x+k for x in rcost[1]]
#print "cost:", cost, " min: ", positions
if cost < min_cost:
min_cost = cost
min_positions = positions

return ( min_cost, min_positions)

print splitstr(20,[3,10,16])  # (40, [10, 3, 16])

print splitstr(20,[3,10]) # (30, [10, 3])

print splitstr(5,[1,2,3,4,5]) # (13, [2, 1, 3, 4, 5])

print splitstr(1,[1]) # (1, [1]) # m cuts m+1 substrings
``````
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A little bit of explanation would make your answer more valuable. – ForceMagic Oct 16 '12 at 1:26

Here is a c++ implementation. Its an O(n^3) Implementation using D.P . Assuming that the cut array is sorted . If it is not it takes O(n^3) time to sort it hence asymptotic time complexity remains same.

``````#include <iostream>
#include <string.h>
#include <stdio.h>
#include <limits.h>
using namespace std;
int main(){
int i,j,gap,k,l,m,n;
while(scanf("%d%d",&n,&k)!=EOF){

int a[n+1][n+1];
int cut[k];
memset(a,0,sizeof(a));
for(i=0;i<k;i++)
cin >> cut[i];
for(gap=1;gap<=n;gap++){
for(i=0,j=i+gap;j<=n;j++,i++){
if(gap==1)
a[i][j]=0;
else{
int min = INT_MAX;
for(m=0;m<k;m++){
if(cut[m]<j and cut[m] >i){
int cost=(j-i)+a[i][cut[m]]+a[cut[m]][j];

if(cost<min)
min=cost;
}
}
if(min>=INT_MAX)
a[i][j]=0;
else
a[i][j]=min;
}
}
}
cout << a[0][n] << endl;
}
return 0;
}
``````
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