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This document describes prim's greedy algorithm for Graph Theory and C programming
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November 9, 2005 Copyright 2001-5 by Erik D. Demaine and Charles E. Leiserson L16.1
Introduction to Algorithms6.046J/18.401J
LECTURE 16Greedy Algorithms (and
Graphs) Graph representation Minimum spanning trees Optimal substructure Greedy choice Prims greedy MST
algorithmProf. Charles E. Leiserson
November 9, 2005 Copyright 2001-5 by Erik D. Demaine and Charles E. Leiserson L16.2
Graphs (review)Definition. A directed graph (digraph)G = (V, E) is an ordered pair consisting of a set V of vertices (singular: vertex), a set E V V of edges.In an undirected graph G = (V, E), the edge set E consists of unordered pairs of vertices.In either case, we have |E | = O(V 2). Moreover, if G is connected, then |E | |V | 1, which implies that lg |E | = (lgV). (Review CLRS, Appendix B.)
November 9, 2005 Copyright 2001-5 by Erik D. Demaine and Charles E. Leiserson L16.3
Adjacency-matrix representation
The adjacency matrix of a graph G = (V, E), where V = {1, 2, , n}, is the matrix A[1 . . n, 1 . . n]given by
A[i, j] = 1 if (i, j) E,0 if (i, j) E.
November 9, 2005 Copyright 2001-5 by Erik D. Demaine and Charles E. Leiserson L16.4
Adjacency-matrix representation
The adjacency matrix of a graph G = (V, E), where V = {1, 2, , n}, is the matrix A[1 . . n, 1 . . n]given by
A[i, j] = 1 if (i, j) E,0 if (i, j) E.
22 11
33 44
A 1 2 3 41234
0 1 1 00 0 1 00 0 0 00 0 1 0
(V 2) storage denserepresentation.
November 9, 2005 Copyright 2001-5 by Erik D. Demaine and Charles E. Leiserson L16.5
Adjacency-list representationAn adjacency list of a vertex v V is the list Adj[v]of vertices adjacent to v.
Adj[1] = {2, 3}Adj[2] = {3}Adj[3] = {}Adj[4] = {3}
22 11
33 44
November 9, 2005 Copyright 2001-5 by Erik D. Demaine and Charles E. Leiserson L16.6
Adjacency-list representationAn adjacency list of a vertex v V is the list Adj[v]of vertices adjacent to v.
Adj[1] = {2, 3}Adj[2] = {3}Adj[3] = {}Adj[4] = {3}
22 11
33 44
For undirected graphs, |Adj[v] | = degree(v).For digraphs, |Adj[v] | = out-degree(v).
November 9, 2005 Copyright 2001-5 by Erik D. Demaine and Charles E. Leiserson L16.7
Adjacency-list representationAn adjacency list of a vertex v V is the list Adj[v]of vertices adjacent to v.
Adj[1] = {2, 3}Adj[2] = {3}Adj[3] = {}Adj[4] = {3}
22 11
33 44
For undirected graphs, |Adj[v] | = degree(v).For digraphs, |Adj[v] | = out-degree(v).Handshaking Lemma: vV = 2 |E | for undirected graphs adjacency lists use (V + E) storage a sparse representation (for either type of graph).
November 9, 2005 Copyright 2001-5 by Erik D. Demaine and Charles E. Leiserson L16.8
Minimum spanning trees
Input: A connected, undirected graph G = (V, E)with weight function w : E R. For simplicity, assume that all edge weights are
distinct. (CLRS covers the general case.)
November 9, 2005 Copyright 2001-5 by Erik D. Demaine and Charles E. Leiserson L16.9
Minimum spanning trees
Input: A connected, undirected graph G = (V, E)with weight function w : E R. For simplicity, assume that all edge weights are
distinct. (CLRS covers the general case.)
=Tvu
vuwTw),(
),()( .
Output: A spanning tree T a tree that connects all vertices of minimum weight:
November 9, 2005 Copyright 2001-5 by Erik D. Demaine and Charles E. Leiserson L16.10
Example of MST
6 125
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November 9, 2005 Copyright 2001-5 by Erik D. Demaine and Charles E. Leiserson L16.11
Example of MST
6 125
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15
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November 9, 2005 Copyright 2001-5 by Erik D. Demaine and Charles E. Leiserson L16.12
Optimal substructureMST T:
(Other edges of Gare not shown.)
November 9, 2005 Copyright 2001-5 by Erik D. Demaine and Charles E. Leiserson L16.13
Optimal substructure
u
vRemove any edge (u, v) T.
(Other edges of Gare not shown.)
MST T:
November 9, 2005 Copyright 2001-5 by Erik D. Demaine and Charles E. Leiserson L16.14
Optimal substructure
u
vRemove any edge (u, v) T.
MST T: (Other edges of Gare not shown.)
November 9, 2005 Copyright 2001-5 by Erik D. Demaine and Charles E. Leiserson L16.15
u
vRemove any edge (u, v) T. Remove any edge (u, v) T. Then, T is partitioned into two subtrees T1 and T2.
T1T2
u
v
Optimal substructureMST T:
(Other edges of Gare not shown.)
November 9, 2005 Copyright 2001-5 by Erik D. Demaine and Charles E. Leiserson L16.16
u
vRemove any edge (u, v) T. Remove any edge (u, v) T. Then, T is partitioned into two subtrees T1 and T2.
T1T2
u
v
Optimal substructureMST T:
(Other edges of Gare not shown.)
Theorem. The subtree T1 is an MST of G1 = (V1, E1), the subgraph of G induced by the vertices of T1:
V1 = vertices of T1,E1 = { (x, y) E : x, y V1 }.
Similarly for T2.
November 9, 2005 Copyright 2001-5 by Erik D. Demaine and Charles E. Leiserson L16.17
Proof of optimal substructure
w(T) = w(u, v) + w(T1) + w(T2).Proof. Cut and paste:
If T1were a lower-weight spanning tree than T1 for G1, then T = {(u, v)} T1 T2 would be a lower-weight spanning tree than T for G.
November 9, 2005 Copyright 2001-5 by Erik D. Demaine and Charles E. Leiserson L16.18
Proof of optimal substructure
w(T) = w(u, v) + w(T1) + w(T2).Proof. Cut and paste:
If T1were a lower-weight spanning tree than T1 for G1, then T = {(u, v)} T1 T2 would be a lower-weight spanning tree than T for G.
Do we also have overlapping subproblems?Yes.
November 9, 2005 Copyright 2001-5 by Erik D. Demaine and Charles E. Leiserson L16.19
Proof of optimal substructure
w(T) = w(u, v) + w(T1) + w(T2).Proof. Cut and paste:
If T1were a lower-weight spanning tree than T1 for G1, then T = {(u, v)} T1 T2 would be a lower-weight spanning tree than T for G.
Great, then dynamic programming may work!Yes, but MST exhibits another powerful property which leads to an even more efficient algorithm.
Do we also have overlapping subproblems?Yes.
November 9, 2005 Copyright 2001-5 by Erik D. Demaine and Charles E. Leiserson L16.20
Hallmark for greedyalgorithms
Greedy-choice propertyA locally optimal choice
is globally optimal.
November 9, 2005 Copyright 2001-5 by Erik D. Demaine and Charles E. Leiserson L16.21
Hallmark for greedyalgorithms
Greedy-choice propertyA locally optimal choice
is globally optimal.
Theorem. Let T be the MST of G = (V, E), and let A V. Suppose that (u, v) E is the least-weight edge connecting A to V A. Then, (u, v) T.
November 9, 2005 Copyright 2001-5 by Erik D. Demaine and Charles E. Leiserson L16.22
Proof of theoremProof. Suppose (u, v) T. Cut and paste.
A V A
u
v
(u, v) = least-weight edge connecting A to V A
T:
November 9, 2005 Copyright 2001-5 by Erik D. Demaine and Charles E. Leiserson L16.23
Proof of theoremProof. Suppose (u, v) T. Cut and paste.
A V A
u
T:
(u, v) = least-weight edge connecting A to V A
v
Consider the unique simple path from u to v in T.
November 9, 2005 Copyright 2001-5 by Erik D. Demaine and Charles E. Leiserson L16.24
Proof of theoremProof. Suppose (u, v) T. Cut and paste.
A V A
u(u, v) = least-weight edge connecting A to V A
vT:
Consider the unique simple path from u to v in T. Swap (u, v) with the first edge on this path that connects a vertex in A to a vertex in V A.
November 9, 2005 Copyright 2001-5 by Erik D. Demaine and Charles E. Leiserson L16.25
Proof of theoremProof. Suppose (u, v) T. Cut and paste.
A V A
u(u, v) = least-weight edge connecting A to V A
vT :
Consider the unique simple path from u to v in T. Swap (u, v) with the first edge on this path that connects a vertex in A to a vertex in V A.A lighter-weight spanning tree than T results.
November 9, 2005 Copyright 2001-5 by Erik D. Demaine and Charles E. Leiserson L16.26
Prims algorithmIDEA: Maintain V A as a priority queue Q. Key each vertex in Q with the weight of the least-weight edge connecting it to a vertex in A.Q Vkey[v] for all v Vkey[s] 0 for some arbitrary s Vwhile Q
do u EXTRACT-MIN(Q)for each v Adj[u]
do if v Q and w(u, v) < key[v]then key[v] w(u, v) DECREASE-KEY
[v] uAt the end, {(v, [v])} forms the MST.
November 9, 2005 Copyright 2001-5 by Erik D. Demaine and Charles E. Leiserson L16.27
Example of Prims algorithm
A V A
00
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November 9, 2005 Copyright 2001-5 by Erik D. Demaine and Charles E. Leiserson L16.28
Example of Prims algorithm
A V A
00
6 125
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November 9, 2005 Copyright 2001-5 by Erik D. Demaine and Charles E. Leiserson L16.29
Example of Prims algorithm
A V A
77
00
1010
1515
6 125
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November 9, 2005 Copyright 2001-5 by Erik D. Demaine and Charles E. Leiserson L16.30
Example of Prims algorithm
A V A
77
00
1010
1515
6 125
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3
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November 9, 2005 Copyright 2001-5 by Erik D. Demaine and Charles E. Leiserson L16.31
Example of Prims algorithm
A V A
1212
55 77
00
1010
99
1515
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November 9, 2005 Copyright 2001-5 by Erik D. Demaine and Charles E. Leiserson L16.32
Example of Prims algorithm
A V A
1212
55 77
00
1010
99
1515
6 125
14
3
8
10
15
9
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November 9, 2005 Copyright 2001-5 by Erik D. Demaine and Charles E. Leiserson L16.33
Example of Prims algorithm
A V A
66
55 77
1414 00
88
99
1515
6 125
14
3
8
10
15
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7
November 9, 2005 Copyright 2001-5 by Erik D. Demaine and Charles E. Leiserson L16.34
Example of Prims algorithm
A V A
66
55 77
1414 00
88
99
1515
6 125
14
3
8
10
15
9
7
November 9, 2005 Copyright 2001-5 by Erik D. Demaine and Charles E. Leiserson L16.35
Example of Prims algorithm
A V A
66
55 77
1414 00
88
99
1515
6 125
14
3
8
10
15
9
7
November 9, 2005 Copyright 2001-5 by Erik D. Demaine and Charles E. Leiserson L16.36
Example of Prims algorithm
A V A
66
55 77
33 00
88
99
1515
6 125
14
3
8
10
15
9
7
November 9, 2005 Copyright 2001-5 by Erik D. Demaine and Charles E. Leiserson L16.37
Example of Prims algorithm
A V A
66
55 77
33 00
88
99
1515
6 125
14
3
8
10
15
9
7
November 9, 2005 Copyright 2001-5 by Erik D. Demaine and Charles E. Leiserson L16.38
Example of Prims algorithm
A V A
66
55 77
33 00
88
99
1515
6 125
14
3
8
10
15
9
7
November 9, 2005 Copyright 2001-5 by Erik D. Demaine and Charles E. Leiserson L16.39
Example of Prims algorithm
A V A
66
55 77
33 00
88
99
1515
6 125
14
3
8
10
15
9
7
November 9, 2005 Copyright 2001-5 by Erik D. Demaine and Charles E. Leiserson L16.40
Analysis of PrimQ Vkey[v] for all v Vkey[s] 0 for some arbitrary s Vwhile Q
do u EXTRACT-MIN(Q)for each v Adj[u]
do if v Q and w(u, v) < key[v]then key[v] w(u, v)
[v] u
November 9, 2005 Copyright 2001-5 by Erik D. Demaine and Charles E. Leiserson L16.41
Analysis of PrimQ Vkey[v] for all v Vkey[s] 0 for some arbitrary s Vwhile Q
do u EXTRACT-MIN(Q)for each v Adj[u]
do if v Q and w(u, v) < key[v]then key[v] w(u, v)
[v] u
(V)total
November 9, 2005 Copyright 2001-5 by Erik D. Demaine and Charles E. Leiserson L16.42
Analysis of PrimQ Vkey[v] for all v Vkey[s] 0 for some arbitrary s Vwhile Q
do u EXTRACT-MIN(Q)for each v Adj[u]
do if v Q and w(u, v) < key[v]then key[v] w(u, v)
[v] u
(V)total
|V |times
November 9, 2005 Copyright 2001-5 by Erik D. Demaine and Charles E. Leiserson L16.43
Analysis of PrimQ Vkey[v] for all v Vkey[s] 0 for some arbitrary s Vwhile Q
do u EXTRACT-MIN(Q)for each v Adj[u]
do if v Q and w(u, v) < key[v]then key[v] w(u, v)
[v] u
degree(u)times
|V |times
(V)total
November 9, 2005 Copyright 2001-5 by Erik D. Demaine and Charles E. Leiserson L16.44
Analysis of Prim
Handshaking Lemma (E) implicit DECREASE-KEYs.
Q Vkey[v] for all v Vkey[s] 0 for some arbitrary s Vwhile Q
do u EXTRACT-MIN(Q)for each v Adj[u]
do if v Q and w(u, v) < key[v]then key[v] w(u, v)
[v] u
degree(u)times
|V |times
(V)total
November 9, 2005 Copyright 2001-5 by Erik D. Demaine and Charles E. Leiserson L16.45
Analysis of Prim
Handshaking Lemma (E) implicit DECREASE-KEYs.
Q Vkey[v] for all v Vkey[s] 0 for some arbitrary s Vwhile Q
do u EXTRACT-MIN(Q)for each v Adj[u]
do if v Q and w(u, v) < key[v]then key[v] w(u, v)
[v] u
degree(u)times
|V |times
(V)total
Time = (V)TEXTRACT-MIN + (E)TDECREASE-KEY
November 9, 2005 Copyright 2001-5 by Erik D. Demaine and Charles E. Leiserson L16.46
Analysis of Prim (continued)
Time = (V)TEXTRACT-MIN + (E)TDECREASE-KEY
November 9, 2005 Copyright 2001-5 by Erik D. Demaine and Charles E. Leiserson L16.47
Analysis of Prim (continued)
Time = (V)TEXTRACT-MIN + (E)TDECREASE-KEYTotalQ T TDECREASE-KEYEXTRACT-MIN
November 9, 2005 Copyright 2001-5 by Erik D. Demaine and Charles E. Leiserson L16.48
Analysis of Prim (continued)
Time = (V)TEXTRACT-MIN + (E)TDECREASE-KEYTotalQ T TDECREASE-KEYEXTRACT-MIN
array O(V) O(1) O(V2)
November 9, 2005 Copyright 2001-5 by Erik D. Demaine and Charles E. Leiserson L16.49
Analysis of Prim (continued)
Time = (V)TEXTRACT-MIN + (E)TDECREASE-KEYTotalQ T TDECREASE-KEYEXTRACT-MIN
array O(V) O(1) O(V2)binary heap O(lg V) O(lg V) O(E lg V)
November 9, 2005 Copyright 2001-5 by Erik D. Demaine and Charles E. Leiserson L16.50
Analysis of Prim (continued)
Time = (V)TEXTRACT-MIN + (E)TDECREASE-KEYTotalQ T TDECREASE-KEYEXTRACT-MIN
array O(V) O(1) O(V2)binary heap O(lg V) O(lg V) O(E lg V)
Fibonacci heap
O(lg V)amortized
O(1)amortized
O(E + V lg V)worst case
November 9, 2005 Copyright 2001-5 by Erik D. Demaine and Charles E. Leiserson L16.51
MST algorithms
Kruskals algorithm (see CLRS): Uses the disjoint-set data structure (Lecture 10). Running time = O(E lg V).
November 9, 2005 Copyright 2001-5 by Erik D. Demaine and Charles E. Leiserson L16.52
MST algorithms
Kruskals algorithm (see CLRS): Uses the disjoint-set data structure (Lecture 10). Running time = O(E lg V).
Best to date: Karger, Klein, and Tarjan [1993]. Randomized algorithm. O(V + E) expected time.
Introduction to Algorithms6.046J/18.401JGraphs (review)Adjacency-matrix representationAdjacency-matrix representationAdjacency-list representationAdjacency-list representationAdjacency-list representationMinimum spanning treesMinimum spanning treesExample of MSTExample of MSTOptimal substructureOptimal substructureOptimal substructureOptimal substructureOptimal substructureProof of optimal substructureProof of optimal substructureProof of optimal substructureHallmark for greedy algorithmsHallmark for greedy algorithmsProof of theoremProof of theoremProof of theoremProof of theoremPrims algorithmExample of Prims algorithmExample of Prims algorithmExample of Prims algorithmExample of Prims algorithmExample of Prims algorithmExample of Prims algorithmExample of Prims algorithmExample of Prims algorithmExample of Prims algorithmExample of Prims algorithmExample of Prims algorithmExample of Prims algorithmExample of Prims algorithmAnalysis of PrimAnalysis of PrimAnalysis of PrimAnalysis of PrimAnalysis of PrimAnalysis of PrimAnalysis of Prim (continued)Analysis of Prim (continued)Analysis of Prim (continued)Analysis of Prim (continued)Analysis of Prim (continued)MST algorithmsMST algorithms
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