Difference between revisions of "TADM2E 4.10"
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| + | Here the main thing to notice is that we need a O(<math>n^{k-1}logn</math>) solution. <br /> | ||
| + | For various values of k, <br /> | ||
| + | k Solution Time Complexity <br /> | ||
| + | 1 O(<math>n^0logn</math>) <br /> | ||
| + | 2 O(<math>n^1logn</math>) <br /> | ||
| + | 3 O(<math>n^2logn</math>) <br /> | ||
| + | 4 O(<math>n^3logn</math>) <br /> | ||
| + | for k = 2 onwards <br /> | ||
| + | 1. sort the array ( nlogn ) <br /> | ||
| + | 2. use k-1 loops for iterating over array, where ith loop starts from i-1 + 1 element of array, and then use binary search <br /> | ||
| + | eg: <br /> | ||
| + | for k = 3 <br /> | ||
| + | for( i = 0; i < n; i++ ) <br /> | ||
| + | for( j = i+1; j < n; j++ ) <br /> | ||
| + | # now use binary search to find ( T - a[i] - a[j] ) from j+1 element to end of array <br /> | ||
| + | |||
| + | <h3>Another recursive solution</h3> | ||
| + | First, we note that [[ TADM2E 4.8 | an O(<math>n \lg n</math>) solution for <math>k = 2</math> exists ]], which is already within the required bounds. Now, for <math>k \ge 3</math>, we can do something like this: | ||
| + | |||
| + | <pre> | ||
| + | sort S ascending; | ||
| + | CheckSumOfK(S, k, T); // defined below | ||
| + | |||
| + | // S must be aorted array of integers | ||
| + | function CheckSumOfK(S, k, T) | ||
| + | if k <= 2: | ||
| + | Use any method in the solution of ex 4.8 and return the result. This can be done in O(n) time because S is sorted. | ||
| + | |||
| + | Initialize array A of n - 1 elements; | ||
| + | for i from 0 to n - 1: | ||
| + | k = 0 | ||
| + | // Collect in A all numbers in S but S[i]. Note that A will still be sorted. | ||
| + | for j from 0 to n - 1: | ||
| + | if i != j: | ||
| + | A[k] = S[j]; | ||
| + | k = k + 1 | ||
| + | // If S[i] is included in the k integers that sum up to T, then there must | ||
| + | // exactly (k - 1) integers in the rest of S (i.e., A) that sum to (T - S[i]). | ||
| + | // We can find that out by calling ourselves recursively. | ||
| + | if CheckSumOfK(A, k - 1, T - S[i]): | ||
| + | return True | ||
| + | return False | ||
| + | </pre> | ||
| + | |||
| + | <h3>Complexity</h3> | ||
| + | For each item in S, there is <math>O(n)</math> work done in assembling the array A, except at the <math>{k - 1}^{th}</math> recursive call, which completes in <math>O(n \lg n)</math> time. So, for each number in S, we have <math>O(kn) + O(n \lg n)</math> work, and since <math>k <= n</math>, each iteration of the outer loop takes <math>O(n^2) + O(n \lg n) = O(n^2)</math> | ||
| + | work. Now since the outer loop goes on for at most <math>n</math> iterations, we have a total runtime of <math>O(n^3)</math>. | ||
| + | |||
| + | A trick can be used to lower this runtime to <math>O(n^2 \lg n)</math> by having the routines in [[ TADM2E 4.8 | this solution ]] take an index to ignore when iterating in their inner loops. With this, we save the <math>O(n)</math> construction of A for every | ||
| + | item, and then each iteration of the outer loop becomes <math>O(n \lg n)</math> (How? <math>O(k) = O(n)</math> constant time recursive calls plus <math>O(n \lg n)</math> time spent in the <math>{k - 1}^{th}</math> calls), giving a total runtime of <math>O(n^2 \lg n)</math> for <math>n</math> elements in S. | ||
| + | |||
| + | Note that this cost includes the initial <math>O(n \lg n)</math> cost for sorting S. Also, this algorithm is always going to be <math>O(n^{k-1} \lg n)</math> for all <math>k >= 2</math>. The exercise just states an upper bound. | ||
Revision as of 12:10, 2 August 2020
Here the main thing to notice is that we need a O($ n^{k-1}logn $) solution.
For various values of k,
k Solution Time Complexity
1 O($ n^0logn $)
2 O($ n^1logn $)
3 O($ n^2logn $)
4 O($ n^3logn $)
for k = 2 onwards
1. sort the array ( nlogn )
2. use k-1 loops for iterating over array, where ith loop starts from i-1 + 1 element of array, and then use binary search
eg:
for k = 3
for( i = 0; i < n; i++ )
for( j = i+1; j < n; j++ )
- now use binary search to find ( T - a[i] - a[j] ) from j+1 element to end of array
Another recursive solution
First, we note that an O($ n \lg n $) solution for $ k = 2 $ exists , which is already within the required bounds. Now, for $ k \ge 3 $, we can do something like this:
sort S ascending;
CheckSumOfK(S, k, T); // defined below
// S must be aorted array of integers
function CheckSumOfK(S, k, T)
if k <= 2:
Use any method in the solution of ex 4.8 and return the result. This can be done in O(n) time because S is sorted.
Initialize array A of n - 1 elements;
for i from 0 to n - 1:
k = 0
// Collect in A all numbers in S but S[i]. Note that A will still be sorted.
for j from 0 to n - 1:
if i != j:
A[k] = S[j];
k = k + 1
// If S[i] is included in the k integers that sum up to T, then there must
// exactly (k - 1) integers in the rest of S (i.e., A) that sum to (T - S[i]).
// We can find that out by calling ourselves recursively.
if CheckSumOfK(A, k - 1, T - S[i]):
return True
return False
Complexity
For each item in S, there is $ O(n) $ work done in assembling the array A, except at the $ {k - 1}^{th} $ recursive call, which completes in $ O(n \lg n) $ time. So, for each number in S, we have $ O(kn) + O(n \lg n) $ work, and since $ k <= n $, each iteration of the outer loop takes $ O(n^2) + O(n \lg n) = O(n^2) $ work. Now since the outer loop goes on for at most $ n $ iterations, we have a total runtime of $ O(n^3) $.
A trick can be used to lower this runtime to $ O(n^2 \lg n) $ by having the routines in this solution take an index to ignore when iterating in their inner loops. With this, we save the $ O(n) $ construction of A for every item, and then each iteration of the outer loop becomes $ O(n \lg n) $ (How? $ O(k) = O(n) $ constant time recursive calls plus $ O(n \lg n) $ time spent in the $ {k - 1}^{th} $ calls), giving a total runtime of $ O(n^2 \lg n) $ for $ n $ elements in S.
Note that this cost includes the initial $ O(n \lg n) $ cost for sorting S. Also, this algorithm is always going to be $ O(n^{k-1} \lg n) $ for all $ k >= 2 $. The exercise just states an upper bound.
