1 / 19

COSC 1030 Lecture 11

COSC 1030 Lecture 11. Sorting. Topics. Sorting Themes Low bound of sorting Priority queue methods Selection sort Heap sort Divide-and-conquer methods Merge sort Quick sort Insertion based methods Address-calculation methods. Sorting Themes. Why sort is an important theme of CS

dyawn
Download Presentation

COSC 1030 Lecture 11

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. COSC 1030 Lecture 11 Sorting

  2. Topics • Sorting Themes • Low bound of sorting • Priority queue methods • Selection sort • Heap sort • Divide-and-conquer methods • Merge sort • Quick sort • Insertion based methods • Address-calculation methods

  3. Sorting Themes • Why sort is an important theme of CS • Performance analysis • Low boundary of problems • Model to implementation • Comparison-based sorting • Insertion • Priority Queue • Divide-and-conquer • Address-calculation sorting

  4. Low Bound of Sorting • Low bound – of a problem P • A complexity class O(P), for any solution S to P, the complexity is of O(S) in the worst case, then O(S)  O(P) • There is a solution S such that O(S) = O(P) • To sorting, the low bound is O(n log n) • How do we find the low bound?

  5. Decision Tree • In-node represents comparison • Leaf represents an order • Extended binary tree • For n elements, there are n! orders • Every path determines an order • Minimal external path length   lg (n!)  • lg(n!) > ½ n lg n

  6. Priority Queue Sorting • Insert n elements into a priority queue • Remove elements from the priority queue one by one • Performance? • Dependent on priority queue implementation • List impl. – remove is of O(n)  SelectionSort • Heap impl. – remove is of O(lg n)  HeapSort • O(n lg n) if heap is used • Do we need additional space?

  7. void selectionSort(KeyType[] A) { KeyType key; int n = A.length; int i = n –1; // initially Q is empty while(i > 0) { // PQ has more element int j = i; // j point to last key of PQ for(int k = 0; k < I; k++) { // find max in PQ if(A[k].compareTo(A[j]) > 0) j = k; } temp = A[i]; A[i] = A[j]; A[j] = temp; // swap i--; // move boundary down } }

  8. void heapSort(KeyType[] A) { KeyType temp; int n = A.length; for(int j = n / 2; j>1; j--) { // heapify all sub trees siftUp(A, j, n); // except root tree } // only non-leaf sub tree need to heapify for(int i = n; i >1; i--) { // reheapify starting at root siftUp(A, 1, i); // to the last leaf temp = A[1]; A[1] = A[i]; A[i] = temp; // swap } }

  9. void siftUp(KeyType[] A, int i, int n) { // O(lg (n –i)) // i the index of root, n the last leaf index KeyType rootKey = A[i]; int j = 2*i; // point to left child of i boolean notFinished = (j <= n); // if j is in the range, not finished while(notFinished) { // if right child of i exists and it’s bigger than left, j point to right if(j<n && A[j+1].compareTo(A[j]) > 0) j ++; if(A[j].compareTo(rootKey) <= 0) { notFinished = false; // no more keys sift up } else { A[i] = A[j]; // sift A[j] up one level i = j; // i point to larger child j = 2*i; // j point to the new left child of i notFinshed = (j <= n); } // end of while A[i] = rootKey; }

  10. Divide-and-conquer void sort(KeyType[] A, int m, int n) { if(n-m > 1) { // if more than 1 element in the range // divide A[m:n] into subarrays: // A[m:i] and A[i+1:n] sort(A, m, i); sort(A, i, n); // combine two sorted array // to yield the sorted original array } }

  11. Merge Sort void mergeSort(KeyType[] A, int m, int n) { if(n - m > 1) { // if more than 1 element in the range // divide A[m:n] into subarrays: // A[m:i] and A[i+1:n] int i = (m + n)/2; // I point in the middle mergeSort(A, m, i); mergeSort(A, I+1, n); merge(A, m, i, n); } }

  12. Merge void merge(KeyType[] A, int m, int i, int n) { // O(n – m +1) KeyType[] temp = new KeyType[n – m + 1]; int k =0; int j = i + 1; int l = m; while(l <= i && j <= n) { if(A[l] <= A[j]) { // copy smaller one into temp temp[k++] = A[l++]; } else { temp[k++] = A[j++]; } } while(l <= i) temp[k++] = A[l++]; // copy remain part into temp while(j <= n) temp[k++] = A[j++]; // only one will be executed for(j = 0; j < k; j++) A[m+j] = temp[j]; // move back }

  13. Quick Sort Void quickSort(KeyType[] A, int m, int n) { if(m < n) { int p = partition(A, m, n); quickSort(A, m, p); quickSort(A, p+1, n); } }

  14. int partition(KeyType[] A, int i, int j) { // O( j – i + 1) KeyType pivot, temp; int k, middle, p; middle = (m +n) /2; pivot = A[middle]; A[middle] = A[i]; A[i] = pivot; p = i; // place pivot in the A[i], p is the pivot position for(k = i+1; k <= j; k++) { if(A[k].compareTo(pivot) < 0) { // swap the smaller one to left sub array temp = A[++p]; A[p] = A[k]; A[k] = temp; } // loop invariant (A[I+1:p] < pivot && A[p+1:k] >= pivot) } temp = A[i]; A[i] = A[p]; A[p] = temp; return p; }

  15. Quick Sort Performance • Average: O(n lg n) • Worst case: • if every time partition makes one sub array empty, the other size –1 • O(n ^ 2) • Why Quick Sort get the name? • Two times faster than HeapSort in average • Only one loop in partition • Coefficient less than other sort methods

  16. Insertion Sort • Assume A’s left part already sorted up to k. • Insert a[k+1] into A[0:k] by: • Extract A[k+1] and save it in temp • Compare temp to A[j], j = 0..k, to find the right position j • Shift A[j:k] one position right • Insert temp into A[j] • O( )?

  17. Address Calculation Sort • Proxmap sort – O(n) • Indexing – maps key domain into [0, n) • key   (key – min(KEY))/(max(KEY) – min(KEY)) *n  • Counting – number of keys in each slot • Positioning – shift position of each slot • Position(k)  Count(k-1) • Inserting – each key into its sub array • using insertSort

  18. Address Calculation Sort • Radix sort – O(n) • Sort a deck of cards • Each card is represented by <n, s> • where n  [2, 3, …, 10, J, Q, K, A] • and s  [Diamond, Club, Heart, Spear] • Separate cards by their shape • Put them back in order of shape • Separate them by number while maintain original order in each deck • Put them back in order of number

  19. Performance Comparison

More Related