# Ternary search recursion isn't correct

I learned about ternary search from Wikipedia. I'm not sure what they mean by the parameter absolute precision. They didn't elaborate. But here is the pseudocode:

def ternarySearch(f, left, right, absolutePrecision):
#left and right are the current bounds; the maximum is between them
if (right - left) < absolutePrecision:
return (left + right)/2

leftThird = (2*left + right)/3
rightThird = (left + 2*right)/3

if f(leftThird) < f(rightThird):
return ternarySearch(f, leftThird, right, absolutePrecision)

return ternarySearch(f, left, rightThird, absolutePrecision)

I want to find max value from a unimodal function. That means I want to print the border point of the increasing and decreasing sequence. If the sequence is

1 2 3 4 5 -1 -2 -3 -4

then I want to print 5 as output.

Here is my attempt. It isn't giving output. Can you please help or give me link that contains good tutorial on ternary search for self learning?

#include<iostream>

using namespace std;
int ternary_search(int[], int, int, int);
int precval = 1;

int main()
{
int n, arr[100], target;
cout << "\t\t\tTernary Search\n\n" << endl;
//cout << "This program will find max element in an unidomal array." << endl;
cout << "How many integers: ";
cin >> n;
for (int i=0; i<n; i++)
cin >> arr[i];
cout << endl << "The max number in the array is: ";
int res = ternary_search(arr,0,n-1,precval)+0;
cout << res << endl;
return 0;
}

int ternary_search(int arr[], int left, int right, int precval)
{
if (right-left <= precval)
return (arr[right] > arr[left]) ? arr[right] : arr[left];
int first_third = (left * 2 + right) / 3;
int last_third = (left + right * 2) / 3;
if(arr[first_third] < arr[last_third])
return ternary_search(arr, first_third, right, precval);
else
return ternary_search(arr, left, last_third, precval);
}

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Absolute precision means the maximum error between the returned result and the true result i.e. max | returned_result - true_result |. In that context, f is a continuous function.

Since you are looking at a discrete function, you can't do much better than get to the point where right - left <= 1. Then, just compare the two resultant values and return the value corresponding to the larger one (since you're looking for max).

EDIT

The first partition point, being mathematically 2/3*left + right/3, should be discretized to ceil(2/3*left + right/3) (so that the relationship is left < first_third <= last_third < right

So first_third = (left*2+right)/3 should be changed to first_third = (left*2 + right + 2)/3.

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>Since you are looking at a discrete function, you can't do much better than get to the >point where right - left <= 1. Then, just compare the two resultant values and return the >value corresponding to the larger one (since you're looking for max). Thank you, I edited the code writing if(right-left<=precval) //I decleared 'precval' a global variable having value 1 return (arr[right]>arr[left])?arr[right]:arr[left]; but it also doesn't give any output. –  nerd Nov 26 '10 at 2:47
can you edit your question to include the changes? when I trace by hand, it works (the last recursive call has (left, right) = (4, 5). –  lijie Nov 26 '10 at 5:09
Here is what happened: In ternary search when there are <=3 values left you have to handle it in base case. Otherwise it may cause stack overflow because function with same parameter is called again and again.[Remember in binary search base case is when <=2 values are left] Example: N = 3 values are 0 2 1 first call-> ternary_search(arr, 0, 2) first_third = 0 // observe left and first_third has become same, so you have to handle this as a base case i.e. right-left<=2 is base case. second_third = 1 arr[first_third] < arr[second_third] So you again call ternary_search(arr, 0, 2) –  nerd Nov 28 '10 at 12:15
I see. Yes that reasoning of the second half of your comment is right. –  lijie Nov 28 '10 at 13:15
oh you are right. um. actually the other way of solving it is to compute the thirds in another way... i'll edit my solution. –  lijie Nov 28 '10 at 13:19

Try Golden Section search (or Fibonacci search for discrete functions). It has a smaller number of recursions AND a 50% reduction in evaluations of f, compared to the above ternary search.

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