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Algorithms analysis and design

Algorithms analysis and design. BY Lecturer: Aisha Dawood. 7. 10. i = [7,10]; i  low = 7; i  high = 10. 5. 11. 17. 19. 4. 8. 15. 18. 21. 23. Interval Trees. The problem: maintain a set of intervals E.g., time intervals for a scheduling program:. 7. 10.

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Algorithms analysis and design

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  1. Algorithms analysis and design BY Lecturer: Aisha Dawood 64

  2. 7 10 i = [7,10]; i low = 7; ihigh = 10 5 11 17 19 4 8 15 18 21 23 Interval Trees • The problem: maintain a set of intervals • E.g., time intervals for a scheduling program: 64

  3. 7 10 i = [7,10]; i low = 7; ihigh = 10 5 11 17 19 4 8 15 18 21 23 Review: Interval Trees • The problem: maintain a set of intervals • E.g., time intervals for a scheduling program: • Query: find an interval in the set that overlaps a given query interval • [14,16]  [15,18] • [16,19]  [15,18] or [17,19] • [12,14]  NULL 64

  4. Review: Interval Trees • Following the methodology: • Pick underlying data structure • Red-black trees will store intervals, keyed on ilow • Decide what additional information to store • Store the maximum endpoint in the subtree rooted at i • Figure out how to maintain the information • Update max as traverse down during insert • Recalculate max after delete with a traversal up the tree • Develop the desired new operations 64

  5. Review: Interval Trees intmax [17,19]23 [5,11]18 [21,23]23 [4,8]8 [15,18]18 [7,10]10 Note that: 64

  6. Review: Searching Interval Trees IntervalSearch(T, i) { x = T->root; while (x != NULL && !overlap(i, x->interval)) if (x->left != NULL && x->left->max  i->low) x = x->left; else x = x->right; return x } • What will be the running time? 64

  7. Review: Correctness of IntervalSearch() • Key idea: need to check only 1 of node’s 2 children • Case 1: search goes right • Show that  overlap in right subtree, or no overlap at all • Case 2: search goes left • Show that  overlap in left subtree, or no overlap at all 64

  8. Correctness of IntervalSearch() • Case 1: if search goes right,  overlap in the right subtree or no overlap in either subtree • If  overlap in right subtree, we’re done • Otherwise: • xleft = NULL, or x  left  max < i  low (Why?) • Thus, no overlap in left subtree! while (x != NULL && !overlap(i, x->interval)) if (x->left != NULL && x->left->max  i->low) x = x->left; else x = x->right; return x; 64

  9. Review: Correctness of IntervalSearch() • Case 2: if search goes left,  overlap in the left subtree or no overlap in either subtree • If  overlap in left subtree, we’re done • Otherwise: • i low  x left max, by branch condition • x left max = y high for some y in left subtree • Since i and y don’t overlap and i low  y high,i high < y low • Since tree is sorted by low’s, i high < any low in right subtree • Thus, no overlap in right subtree while (x != NULL && !overlap(i, x->interval)) if (x->left != NULL && x->left->max  i->low) x = x->left; else x = x->right; return x; 64

  10. Graphs • A graph G = (V, E) • V = set of vertices • E = set of edges = subset of V  V • Thus |E| = O(|V|2) 64

  11. Graph Variations • Variations: • A connected graphhas a path from every vertex to every other • In an undirected graph: • Edge (u,v) = edge (v,u) • No self-loops • In a directed graph: • Edge (u,v) goes from vertex u to vertex v, notated uv 64

  12. Graph Variations • More variations: • A weighted graph associates weights with either the edges or the vertices • E.g., a road map: edges might be weighted w/ distance • A multigraph allows multiple edges between the same vertices • E.g., the call graph in a program (a function can get called from multiple points in another function) 64

  13. Graphs • We will typically express running times in terms of |E| and |V| (often dropping the |’s) • If |E|  |V|2 the graph is dense • If |E|  |V| the graph is sparse • If you know you are dealing with dense or sparse graphs, different data structures may make sense 64

  14. Representing Graphs • Assume V = {1, 2, …, n} • An adjacency matrixrepresents the graph as a n x n matrix A: • A[i, j] = 1 if edge (i, j)  E (or weight of edge) = 0 if edge (i, j)  E 64

  15. Graphs: Adjacency Matrix • Example: 1 a d 2 4 b c 3 64

  16. Graphs: Adjacency Matrix • Example: 1 a d 2 4 b c 3 64

  17. Graphs: Adjacency Matrix • How much storage does the adjacency matrix require? • A: O(V2) • What is the minimum amount of storage needed by an adjacency matrix representation of an undirected graph with 4 vertices? • A: 6 bits • Undirected graph  matrix is symmetric • No self-loops don’t need diagonal 64

  18. Graphs: Adjacency List • Adjacency list: for each vertex v  V, store a list of vertices adjacent to v • Example: • Adj[1] = {2,3} • Adj[2] = {3} • Adj[3] = {} • Adj[4] = {3} • Variation: can also keep a list of edges coming into vertex 1 2 4 3 64

  19. Graphs: Adjacency List • How much storage is required? • The degree of a vertex v = # incident edges • Directed graphs have in-degree, out-degree • For directed graphs, # of items in adjacency lists is out-degree(v) = |E|For undirected graphs, # items in adj lists is  degree(v) = 2 |E| (handshaking lemma) 64

  20. Graph Searching • Given: a graph G = (V, E), directed or undirected • Goal: methodically explore every vertex and every edge • Ultimately: build a tree on the graph • Pick a vertex as the root • Choose certain edges to produce a tree • Note: might also build a forest if graph is not connected 64

  21. Breadth-First Search • “Explore” a graph, turning it into a tree • One vertex at a time • Expand frontier of explored vertices across the breadth of the frontier • Builds a tree over the graph • Pick a source vertex to be the root • Find (“discover”) its children, then their children, etc. 64

  22. Breadth-First Search • Again will associate vertex “colors” to guide the algorithm • White vertices have not been discovered • All vertices start out white • Grey vertices are discovered but not fully explored • They may be adjacent to white vertices • Black vertices are discovered and fully explored • They are adjacent only to black and gray vertices • Explore vertices by scanning adjacency list of grey vertices 64

  23. Breadth-First Search BFS(G, s) { initialize vertices; Q = {s}; // Q is a queue (duh); initialize to s while (Q not empty) { u = RemoveTop(Q); for each v  u->adj { if (v->color == WHITE) v->color = GREY; v->d = u->d + 1; v->p = u; Enqueue(Q, v); } u->color = BLACK; } } v->d is the discovered v->p is the parent 64

  24. Breadth-First Search: Example r s t u         v w x y 64

  25. Breadth-First Search: Example r s t u  0       v w x y Q: s 64

  26. Breadth-First Search: Example r s t u 1 0    1   v w x y Q: w r 64

  27. Breadth-First Search: Example r s t u 1 0 2   1 2  v w x y Q: r t x 64

  28. Breadth-First Search: Example r s t u 1 0 2  2 1 2  v w x y Q: t x v 64

  29. Breadth-First Search: Example r s t u 1 0 2 3 2 1 2  v w x y Q: x v u 64

  30. Breadth-First Search: Example r s t u 1 0 2 3 2 1 2 3 v w x y Q: v u y 64

  31. Breadth-First Search: Example r s t u 1 0 2 3 2 1 2 3 v w x y Q: u y 64

  32. Breadth-First Search: Example r s t u 1 0 2 3 2 1 2 3 v w x y Q: y 64

  33. Breadth-First Search: Example r s t u 1 0 2 3 2 1 2 3 v w x y Q: Ø 64

  34. Touch every vertex: O(V) u = every vertex, but only once : O(V) So v = every vertex that appears in some other vert’s adjacency list: O(E) BFS: The Code Again BFS(G, s) { initialize vertices; Q = {s}; while (Q not empty) { u = RemoveTop(Q); for each v  u->adj { if (v->color == WHITE) v->color = GREY; v->d = u->d + 1; v->p = u; Enqueue(Q, v); } u->color = BLACK; } } What will be the running time? Total running time: O(2V+E) 64

  35. Breadth-First Search: Properties • BFS calculates the shortest-path distance to the source node • Shortest-path distance (s,v) = minimum number of edges from s to v. • BFS builds breadth-first tree, in which paths to root represent shortest paths in G • Thus can use BFS to calculate shortest path from one vertex to another in O(2V+E) time 64

  36. Depth-First Search • Depth-first search is another strategy for exploring a graph • Explore “deeper” in the graph whenever possible • Edges are explored out of the most recently discovered vertex v that still has unexplored edges • When all of v’s edges have been explored, backtrack to the vertex from which v was discovered 64

  37. Depth-First Search • Vertices initially colored white • Then colored gray when discovered • Then black when finished 64

  38. DFS(G) { for each vertex u  G->V { u->color = WHITE; } time = 0; for each vertex u  G->V { if (u->color == WHITE) DFS_Visit(u); } } DFS_Visit(u) { u->color = GREY; time = time+1; u->d = time; for each v  u->Adj[] { if (v->color == WHITE) DFS_Visit(v); } u->color = BLACK; time = time+1; u->f = time; } Depth-First Search: The Code u->d : discovered , u -> f : finished 64

  39. DFS(G) { for each vertex u  G->V { u->color = WHITE; } time = 0; for each vertex u  G->V { if (u->color == WHITE) DFS_Visit(u); } } DFS_Visit(u) { u->color = GREY; time = time+1; u->d = time; for each v  u->Adj[] { if (v->color == WHITE) DFS_Visit(v); } u->color = BLACK; time = time+1; u->f = time; } Depth-First Search: The Code Running time: O(n2) because call DFS_Visit on each vertex, and the loop over Adj[] can run as many as |V| times 64

  40. DFS(G) { for each vertex u  G->V { u->color = WHITE; } time = 0; for each vertex u  G->V { if (u->color == WHITE) DFS_Visit(u); } } DFS_Visit(u) { u->color = GREY; time = time+1; u->d = time; for each v  u->Adj[] { if (v->color == WHITE) DFS_Visit(v); } u->color = BLACK; time = time+1; u->f = time; } Depth-First Search: The Code BUT, there is actually a tighter bound. How many times will DFS_Visit() actually be called? 64

  41. DFS(G) { for each vertex u  G->V { u->color = WHITE; } time = 0; for each vertex u  G->V { if (u->color == WHITE) DFS_Visit(u); } } DFS_Visit(u) { u->color = GREY; time = time+1; u->d = time; for each v  u->Adj[] { if (v->color == WHITE) DFS_Visit(v); } u->color = BLACK; time = time+1; u->f = time; } Depth-First Search: The Code So, running time of DFS = O(V+E) 64

  42. Depth-First Sort Analysis • This running time argument is an example of amortized analysis • “Charge” the exploration of edge to the edge: • Each loop in DFS_Visit can be attributed to an edge in the graph • Runs once/edge if directed graph, twice if undirected • Thus loop will run in O(E) time, algorithm O(V+E) 64

  43. DFS Example sourcevertex 64

  44. DFS Example sourcevertex d f 1 | | | | | | | | 64

  45. DFS Example sourcevertex d f 1 | | | 2 | | | | | 64

  46. DFS Example sourcevertex d f 1 | | | 2 | | 3 | | | 64

  47. DFS Example sourcevertex d f 1 | | | 2 | | 3 | 4 | | 64

  48. DFS Example sourcevertex d f 1 | | | 2 | | 3 | 4 5 | | 64

  49. DFS Example sourcevertex d f 1 | | | 2 | | 3 | 4 5 | 6 | 64

  50. DFS Example sourcevertex d f 1 | 8 | | 2 | 7 | 3 | 4 5 | 6 | 64

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