Advanced Algorithm Design and Analysis - PowerPoint PPT Presentation

1 / 94
About This Presentation
Title:

Advanced Algorithm Design and Analysis

Description:

Title: Machine Models Author: Valued Sony Customer Last modified by: lu Created Date: 4/26/2001 4:38:43 AM Document presentation format: – PowerPoint PPT presentation

Number of Views:75
Avg rating:3.0/5.0
Slides: 95
Provided by: ValuedSon8
Category:

less

Transcript and Presenter's Notes

Title: Advanced Algorithm Design and Analysis


1
Advanced Algorithm Design and Analysis
Jiaheng Lu Renmin University of China
www.jiahenglu.net
2
Directed Acyclic Graphs
  • A directed acyclic graph or DAG is a directed
    graph with no directed cycles

3
DFS and DAGs
  • Argue that a directed graph G is acyclic iff a
    DFS of G yields no back edges
  • Forward if G is acyclic, will be no back edges
  • Trivial a back edge implies a cycle
  • Backward if no back edges, G is acyclic
  • Argue contrapositive G has a cycle ? ? a back
    edge
  • Let v be the vertex on the cycle first
    discovered, and u be the predecessor of v on the
    cycle
  • When v discovered, whole cycle is white
  • Must visit everything reachable from v before
    returning from DFS-Visit()
  • So path from u?v is yellow?yellow, thus (u, v) is
    a back edge

4
Topological Sort
  • Topological sort of a DAG
  • Linear ordering of all vertices in graph G such
    that vertex u comes before vertex v if edge (u,
    v) ? G
  • Real-world example getting dressed

5
Getting Dressed
Underwear
Socks
Watch
Shoes
Pants
Shirt
Belt
Tie
Jacket
6
Getting Dressed
Underwear
Socks
Watch
Shoes
Pants
Shirt
Belt
Tie
Jacket
Socks
Underwear
Pants
Shoes
Watch
Shirt
Belt
Tie
Jacket
7
Topological Sort Algorithm
  • Topological-Sort()
  • Run DFS
  • When a vertex is finished, output it
  • Vertices are output in reverse topological order
  • Time O(VE)
  • Correctness Want to prove that (u,v) ? G ? u?f
    gt v?f

8
Correctness of Topological Sort
  • Claim (u,v) ? G ? u?f gt v?f
  • When (u,v) is explored, u is yellow
  • v yellow ? (u,v) is back edge. Contradiction
    (Why?)
  • v white ? v becomes descendent of u ? v?f lt u?f
    (since must finish v before backtracking and
    finishing u)
  • v black ? v already finished ? v?f lt u?f

9
Minimum Spanning Tree
  • Problem given a connected, undirected, weighted
    graph

6
4
5
9
14
2
10
15
3
8
10
Minimum Spanning Tree
  • Problem given a connected, undirected, weighted
    graph, find a spanning tree using edges that
    minimize the total weight

6
4
5
9
14
2
10
15
3
8
11
Minimum Spanning Tree
  • Which edges form the minimum spanning tree (MST)
    of the below graph?

A
6
4
5
9
H
B
C
14
2
10
15
G
E
D
3
8
F
12
Minimum Spanning Tree
  • Answer

A
6
4
5
9
H
B
C
14
2
10
15
G
E
D
3
8
F
13
Minimum Spanning Tree
  • MSTs satisfy the optimal substructure property
    an optimal tree is composed of optimal subtrees
  • Let T be an MST of G with an edge (u,v) in the
    middle
  • Removing (u,v) partitions T into two trees T1 and
    T2
  • Claim T1 is an MST of G1 (V1,E1), and T2 is an
    MST of G2 (V2,E2) (Do V1 and V2
    share vertices? Why?)
  • Proof w(T) w(u,v) w(T1) w(T2)(There cant
    be a better tree than T1 or T2, or T would be
    suboptimal)

14
Minimum Spanning Tree
  • Thm
  • Let T be MST of G, and let A ? T be subtree of T
  • Let (u,v) be min-weight edge connecting A to V-A
  • Then (u,v) ? T

15
Minimum Spanning Tree
  • Thm
  • Let T be MST of G, and let A ? T be subtree of T
  • Let (u,v) be min-weight edge connecting A to V-A
  • Then (u,v) ? T

16
Prims Algorithm
  • MST-Prim(G, w, r)
  • Q VG
  • for each u ? Q
  • keyu ?
  • keyr 0
  • pr NULL
  • while (Q not empty)
  • u ExtractMin(Q)
  • for each v ? Adju
  • if (v ? Q and w(u,v) lt keyv)
  • pv u
  • keyv w(u,v)

17
Prims Algorithm
6
4
9
5
  • MST-Prim(G, w, r)
  • Q VG
  • for each u ? Q
  • keyu ?
  • keyr 0
  • pr NULL
  • while (Q not empty)
  • u ExtractMin(Q)
  • for each v ? Adju
  • if (v ? Q and w(u,v) lt keyv)
  • pv u
  • keyv w(u,v)

14
2
10
15
3
8
Run on example graph
18
Prims Algorithm
?
6
4
9
5
  • MST-Prim(G, w, r)
  • Q VG
  • for each u ? Q
  • keyu ?
  • keyr 0
  • pr NULL
  • while (Q not empty)
  • u ExtractMin(Q)
  • for each v ? Adju
  • if (v ? Q and w(u,v) lt keyv)
  • pv u
  • keyv w(u,v)

?
?
?
14
2
10
15
?
?
?
3
8
?
Run on example graph
19
Prims Algorithm
?
6
4
9
5
  • MST-Prim(G, w, r)
  • Q VG
  • for each u ? Q
  • keyu ?
  • keyr 0
  • pr NULL
  • while (Q not empty)
  • u ExtractMin(Q)
  • for each v ? Adju
  • if (v ? Q and w(u,v) lt keyv)
  • pv u
  • keyv w(u,v)

?
?
?
14
2
10
15
r
0
?
?
3
8
?
Pick a start vertex r
20
Prims Algorithm
?
6
4
9
5
  • MST-Prim(G, w, r)
  • Q VG
  • for each u ? Q
  • keyu ?
  • keyr 0
  • pr NULL
  • while (Q not empty)
  • u ExtractMin(Q)
  • for each v ? Adju
  • if (v ? Q and w(u,v) lt keyv)
  • pv u
  • keyv w(u,v)

?
?
?
14
2
10
15
u
0
?
?
3
8
?
Red vertices have been removed from Q
21
Prims Algorithm
?
6
4
9
5
  • MST-Prim(G, w, r)
  • Q VG
  • for each u ? Q
  • keyu ?
  • keyr 0
  • pr NULL
  • while (Q not empty)
  • u ExtractMin(Q)
  • for each v ? Adju
  • if (v ? Q and w(u,v) lt keyv)
  • pv u
  • keyv w(u,v)

?
?
?
14
2
10
15
u
0
?
?
3
8
3
Red arrows indicate parent pointers
22
Prims Algorithm
?
6
4
9
5
  • MST-Prim(G, w, r)
  • Q VG
  • for each u ? Q
  • keyu ?
  • keyr 0
  • pr NULL
  • while (Q not empty)
  • u ExtractMin(Q)
  • for each v ? Adju
  • if (v ? Q and w(u,v) lt keyv)
  • pv u
  • keyv w(u,v)

14
?
?
14
2
10
15
u
0
?
?
3
8
3
23
Prims Algorithm
?
6
4
9
5
  • MST-Prim(G, w, r)
  • Q VG
  • for each u ? Q
  • keyu ?
  • keyr 0
  • pr NULL
  • while (Q not empty)
  • u ExtractMin(Q)
  • for each v ? Adju
  • if (v ? Q and w(u,v) lt keyv)
  • pv u
  • keyv w(u,v)

14
?
?
14
2
10
15
0
?
?
3
8
3
u
24
Prims Algorithm
?
6
4
9
5
  • MST-Prim(G, w, r)
  • Q VG
  • for each u ? Q
  • keyu ?
  • keyr 0
  • pr NULL
  • while (Q not empty)
  • u ExtractMin(Q)
  • for each v ? Adju
  • if (v ? Q and w(u,v) lt keyv)
  • pv u
  • keyv w(u,v)

14
?
?
14
2
10
15
0
8
?
3
8
3
u
25
Prims Algorithm
?
6
4
9
5
  • MST-Prim(G, w, r)
  • Q VG
  • for each u ? Q
  • keyu ?
  • keyr 0
  • pr NULL
  • while (Q not empty)
  • u ExtractMin(Q)
  • for each v ? Adju
  • if (v ? Q and w(u,v) lt keyv)
  • pv u
  • keyv w(u,v)

10
?
?
14
2
10
15
0
8
?
3
8
3
u
26
Prims Algorithm
?
6
4
9
5
  • MST-Prim(G, w, r)
  • Q VG
  • for each u ? Q
  • keyu ?
  • keyr 0
  • pr NULL
  • while (Q not empty)
  • u ExtractMin(Q)
  • for each v ? Adju
  • if (v ? Q and w(u,v) lt keyv)
  • pv u
  • keyv w(u,v)

10
?
?
14
2
10
15
0
8
?
3
8
3
u
27
Prims Algorithm
?
6
4
9
5
  • MST-Prim(G, w, r)
  • Q VG
  • for each u ? Q
  • keyu ?
  • keyr 0
  • pr NULL
  • while (Q not empty)
  • u ExtractMin(Q)
  • for each v ? Adju
  • if (v ? Q and w(u,v) lt keyv)
  • pv u
  • keyv w(u,v)

10
2
?
14
2
10
15
0
8
?
3
8
3
u
28
Prims Algorithm
?
6
4
9
5
  • MST-Prim(G, w, r)
  • Q VG
  • for each u ? Q
  • keyu ?
  • keyr 0
  • pr NULL
  • while (Q not empty)
  • u ExtractMin(Q)
  • for each v ? Adju
  • if (v ? Q and w(u,v) lt keyv)
  • pv u
  • keyv w(u,v)

10
2
?
14
2
10
15
0
8
15
3
8
3
u
29
Prims Algorithm
u
?
6
4
9
5
  • MST-Prim(G, w, r)
  • Q VG
  • for each u ? Q
  • keyu ?
  • keyr 0
  • pr NULL
  • while (Q not empty)
  • u ExtractMin(Q)
  • for each v ? Adju
  • if (v ? Q and w(u,v) lt keyv)
  • pv u
  • keyv w(u,v)

10
2
?
14
2
10
15
0
8
15
3
8
3
30
Prims Algorithm
u
?
6
4
9
5
  • MST-Prim(G, w, r)
  • Q VG
  • for each u ? Q
  • keyu ?
  • keyr 0
  • pr NULL
  • while (Q not empty)
  • u ExtractMin(Q)
  • for each v ? Adju
  • if (v ? Q and w(u,v) lt keyv)
  • pv u
  • keyv w(u,v)

10
2
9
14
2
10
15
0
8
15
3
8
3
31
Prims Algorithm
u
4
6
4
9
5
  • MST-Prim(G, w, r)
  • Q VG
  • for each u ? Q
  • keyu ?
  • keyr 0
  • pr NULL
  • while (Q not empty)
  • u ExtractMin(Q)
  • for each v ? Adju
  • if (v ? Q and w(u,v) lt keyv)
  • pv u
  • keyv w(u,v)

10
2
9
14
2
10
15
0
8
15
3
8
3
32
Prims Algorithm
u
4
6
4
9
5
  • MST-Prim(G, w, r)
  • Q VG
  • for each u ? Q
  • keyu ?
  • keyr 0
  • pr NULL
  • while (Q not empty)
  • u ExtractMin(Q)
  • for each v ? Adju
  • if (v ? Q and w(u,v) lt keyv)
  • pv u
  • keyv w(u,v)

5
2
9
14
2
10
15
0
8
15
3
8
3
33
Prims Algorithm
u
4
6
4
9
5
  • MST-Prim(G, w, r)
  • Q VG
  • for each u ? Q
  • keyu ?
  • keyr 0
  • pr NULL
  • while (Q not empty)
  • u ExtractMin(Q)
  • for each v ? Adju
  • if (v ? Q and w(u,v) lt keyv)
  • pv u
  • keyv w(u,v)

5
2
9
14
2
10
15
0
8
15
3
8
3
34
Prims Algorithm
u
4
6
4
9
5
  • MST-Prim(G, w, r)
  • Q VG
  • for each u ? Q
  • keyu ?
  • keyr 0
  • pr NULL
  • while (Q not empty)
  • u ExtractMin(Q)
  • for each v ? Adju
  • if (v ? Q and w(u,v) lt keyv)
  • pv u
  • keyv w(u,v)

5
2
9
14
2
10
15
0
8
15
3
8
3
35
Prims Algorithm
u
4
6
4
9
5
  • MST-Prim(G, w, r)
  • Q VG
  • for each u ? Q
  • keyu ?
  • keyr 0
  • pr NULL
  • while (Q not empty)
  • u ExtractMin(Q)
  • for each v ? Adju
  • if (v ? Q and w(u,v) lt keyv)
  • pv u
  • keyv w(u,v)

5
2
9
14
2
10
15
0
8
15
3
8
3
36
Prims Algorithm
4
6
4
9
5
  • MST-Prim(G, w, r)
  • Q VG
  • for each u ? Q
  • keyu ?
  • keyr 0
  • pr NULL
  • while (Q not empty)
  • u ExtractMin(Q)
  • for each v ? Adju
  • if (v ? Q and w(u,v) lt keyv)
  • pv u
  • keyv w(u,v)

5
2
9
14
u
2
10
15
0
8
15
3
8
3
37
Review Prims Algorithm
  • MST-Prim(G, w, r)
  • Q VG
  • for each u ? Q
  • keyu ?
  • keyr 0
  • pr NULL
  • while (Q not empty)
  • u ExtractMin(Q)
  • for each v ? Adju
  • if (v ? Q and w(u,v) lt keyv)
  • pv u
  • keyv w(u,v)

What is the hidden cost in this code?
38
Review Prims Algorithm
  • MST-Prim(G, w, r)
  • Q VG
  • for each u ? Q
  • keyu ?
  • keyr 0
  • pr NULL
  • while (Q not empty)
  • u ExtractMin(Q)
  • for each v ? Adju
  • if (v ? Q and w(u,v) lt keyv)
  • pv u
  • DecreaseKey(v, w(u,v))

39
Review Prims Algorithm
  • MST-Prim(G, w, r)
  • Q VG
  • for each u ? Q
  • keyu ?
  • keyr 0
  • pr NULL
  • while (Q not empty)
  • u ExtractMin(Q)
  • for each v ? Adju
  • if (v ? Q and w(u,v) lt keyv)
  • pv u
  • DecreaseKey(v, w(u,v))

How often is ExtractMin() called? How often is
DecreaseKey() called?
40
Review Prims Algorithm
  • MST-Prim(G, w, r)
  • Q VG
  • for each u ? Q
  • keyu ?
  • keyr 0
  • pr NULL
  • while (Q not empty)
  • u ExtractMin(Q)
  • for each v ? Adju
  • if (v ? Q and w(u,v) lt keyv)
  • pv u
  • keyv w(u,v)

What will be the running time?A Depends on
queue binary heap O(E lg V) Fibonacci heap
O(V lg V E)
41
Single-Source Shortest Path
  • Problem given a weighted directed graph G, find
    the minimum-weight path from a given source
    vertex s to another vertex v
  • Shortest-path minimum weight
  • Weight of path is sum of edges
  • E.g., a road map what is the shortest path from
    Chapel Hill to Charlottesville?

42
Binary Heap
  • A special kind of binary tree. It has two
    properties that are not generally true for other
    trees
  • Completeness
  • The tree is complete, which means that nodes are
    added from top to bottom, left to right, without
    leaving any spaces. A binary tree is completely
    full if it is of height, h, and has 2h1-1 nodes.
  • Heapness
  • The item in the tree with the highest priority
    is at the top of the tree, and the same is true
    for every subtree.

43
Binary Heap
  • Binary tree of height, h, is complete iff
  • it is empty
  • or
  • its left subtree is complete of height h-1 and
    its right subtree is completely full of height
    h-2
  • or
  • its left subtree is completely full of height
    h-1 and its right subtree is complete of
  • height h-1.

44
Binary Heap
  • In simple terms
  • A heap is a binary tree in which every parent is
    greater than its child(ren).
  • A Reverse Heap is one in which the rule is every
    parent is less than the child(ren).

45
Binary Heap
  • To build a heap, data is placed in the tree as it
    arrives.
  • Algorithm
  • add a new node at the next leaf position
  • use this new node as the current position
  • While new data is greater than that in the parent
    of the current node
  • ? move the parent down to the current node
  • ? make the parent (now vacant) the current
    node
  • ? Place data in current node

46
Binary Heap
  • New nodes are always added on the deepest level
  • in an orderly way.
  • The tree never becomes unbalanced.
  • There is no particular relationship among the
    data items
  • in the nodes on any given level, even the ones
    that have
  • the same parent
  • A heap is not a sorted structure. Can be regarded
    as
  • partially ordered.
  • A given set of data can be formed into many
    different
  • heaps (depends on the order in which the data
    arrives.)

47
Binary Heap
  • Example
  • Data arrives to be heaped in the order
  • 54, 87, 27, 67, 19, 31, 29, 18, 32, 56, 7, 12,
  • 31

48
Binary Heap
  • 54, 87, 27, 67, 19, 31, 29, 18, 32, 56, 7, 12, 31

54
49
Binary Heap
  • 54, 87, 27, 67, 19, 31, 29, 18, 32, 56, 7, 12, 31

31
50
Binary Heap
  • 54, 87, 27, 67, 19, 31, 29, 18, 32, 56, 7, 12, 31

18
32
etc
51
Binary Heap
  • To delete an element from the heap
  • Algorithm
  • If node is the last logical node in the tree,
    simply delete it
  • Else
  • ? Replace the node with the last logical
    node in the tree
  • ? Delete the last logical node from the tree
  • ? Re-heapify

52
Binary Heap
Example Deleting the root node, T
53
Binary Heap
54
Binary Heap
55
Binary Heap
56
  • Min-Max Heap
  • Deaps
  • Binomial Heaps
  • Fibonacci Heaps

57
MIN-MAX Heaps (1/10)
  • Definition
  • A double-ended priority queue is a data structure
    that supports the following operations
  • Insert an element with arbitrary key
  • Delete an element with the largest key
  • Delete an element with the smallest key
  • Min heap or Max heap
  • Only insertion and one of the two deletion
    operations are supported
  • Min-Max heap
  • Supports all of the operations just described.

58
  • Definition
  • A mix-max heap is a complete binary tree such
    that if it is not empty, each element has a field
    called key.
  • Alternating levels of this tree are min levels
    and max levels, respectively.
  • Let x be any node in a min-max heap. If x is on a
    min (max) level then the element in x has the
    minimum (maximum) key from amongall elements in
    the subtree with root x. We call this node a
    min (max) node.

59
  • Insertion into a min-max heap (at a max level)
  • If it is smaller/greater than its father (a
    min), then it must be smaller/greater than all
    max/min above. So simply check the
    min/max ancestors
  • There exists a similar approach at a min level

60
  • Following the nodes the max node i to the root
    and insert into its proper place

item 80
i
13
3
grandparent
3
0
define MAX_SIZE 100define FALSE 0define TRUE
1define SWAP(x,y,t) ((t)(x), (x)(y),
(y)(t))typedef struct int key/ other
fields /elementelement heapMAX_SIZE
1
80
2
3
4
5
6
7
8
9
10
11
12
13
40
61
  • min_max_insert Insert item into the min-max heap

item.key
5
80
n
12
13
14
complexity O(log n)
parent
6
7
1
min
7
5
2
3
max
70
40
80
4
5
6
7
30
9
10
15
min
7
max
45
50
30
20
12
10
40
11
12
13
14
8
9
10
62
  • Deletion of min element
  • If we wish to delete the element with the
    smallest key, then this element is in the root.
  • In general situation, we are to reinsert an
    element item into a min-max-heap, heap, whose
    root is empty.
  • We consider the two cases
  • The root has no children
  • Item is to be inserted into the root.
  • The root has at least one child.
  • The smallest key in the min-max-heap is in one of
    the children or grandchildren of the root. We
    determine the node k has the smallest key.
  • The following possibilities need to be considered

63
  • item.key ? heapk.key
  • No element in heap with key smaller than item.key
  • Item may be inserted into the root.
  • item.key ? heapk.key, k is a child of the root
  • Since k is a max node, it has no descendants with
    key larger than heapk.key. Hence, node k has no
    descendants with key larger than item.key.
  • heapk may be moved to the root and item
    inserted into node k.

64
  • item.key ? heapk.key, k is a grandchild of
    the root
  • In this case, heapk may be moved to the root,
    now heapk is seen as presently empty.
  • Let parent be the parent of k.
  • If item.key ? heapparent.key, then interchange
    them. This ensures that the max node parent
    contains the largest key in the sub-heap with
    root parent.
  • At this point, we are faced with the problem of
    inserting item into the sub-heap with root k.
    Therefore, we repeat the above process.

65
  • delete_min
  • Delete the minimum element from the min-max heap

complexity O(log n)
n
12
11
i
1
5
last
5
k
5
11
parent
2
temp.key
x.key
12
1
0
7
7
9
2
3
70
40
4
5
6
7
30
9
10
15
12
45
50
30
20
12
8
9
10
11
12
66
  • Deletion of max element
  • Determine the children of the root which are
    located on max-level, and find the larger one
    (node) which is the largest one on the min-max
    heap
  • We would consider the node as the root of a
    max-min heap
  • There exist a similar approach (deletion of
    max element) as we mentioned above

max-min heap
67
Deaps(1/8)
  • Definition
  • The root contains no element
  • The left subtree is a min-heap
  • The right subtree is a max-heap
  • Constraint between the two trees
  • let i be any node in left subtree, j be the
    corresponding node in the right subtree.
  • if j not exists, let j corresponds to parent of i
  • i.key lt j.key

68
Deaps(2/8)
  • i min_partner(n)
  • j max_partner(n)
  • if j gt heapsize j / 2

69
Deaps Insert(3/8)
  • public void insert(int x)
  • int i
  • if (n 2)
  • deap2 x return
  • if (inMaxHeap(n))
  • i minPartner(n)
  • if (x lt deapi)
  • deapn deapi
  • minInsert(i, x)
  • else maxInsert(n, x)
  • else
  • i maxPartner(n)
  • if (x gt deapi)
  • deapn deapi
  • maxInsert(i, x)
  • else minInsert(n, x)

70
Deaps Insert(3/8)
  • public void insert(int x)
  • int i
  • if (n 2)
  • deap2 x return
  • if (inMaxHeap(n))
  • i minPartner(n)
  • if (x lt deapi)
  • deapn deapi
  • minInsert(i, x)
  • else maxInsert(n, x)

71
Deaps Insert(3/8)
  • http//www.csie.ntnu.edu.tw/swanky/ds/chap9.htm
  • Insert and delete algorithm

72
Deaps(4/8)
  • Insertion Into A Deap

73
Deaps(5/8)
74
Deaps(6/8)
75
Deaps delete min(7/8)
  • public int deleteMin()
  • int i, j, key deap2, x deapn--
  • // move smaller child to i
  • for (i 2 2i lt n deapi deapj, i
    j)
  • j i 2
  • if (j1 lt n (deapj gt deapj1)
    j
  • // try to put x at leaf i
  • j maxPartner(i)
  • if (x gt deapj)
  • deapi deapj
  • maxInsert(j, x)
  • else
  • minInsert(i, x)
  • return key

76
Deaps(8/8)
77
Binomial Heaps(1/10)
  • Cost Amortization(????)
  • actual cost of delete in Binomial Heap could be
    O(n), but insert and combine are O(1)
  • cost amortization charge some cost of a heavy
    operation to lightweight operations
  • amortized Binomial Heap delete is O(log2n)
  • A tighter bound could be achieved for a sequence
    of operations
  • actual cost of any sequence of i inserts, c
    combines, and dm delete in Binomial Heaps is
    O(icdmlogi)

78
Binomial Heaps(2/10)
  • Definition of Binomial Heap
  • Node degree, child ,left_link, right_link, data,
    parent
  • roots are doubly linked
  • a points to smallest root

79
Binomial Heaps(3/10)
80
Binomial Heaps(4/10)
  • Insertion Into A Binomial Heaps
  • make a new node into doubly linked circular list
    pointed at by a
  • set a to the root with smallest key
  • Combine two B-heaps a and b
  • combine two doubly linked circular lists to one
  • set a to the root with smallest key

81
Binomial Heaps(5/10)
  • Deletion Of Min Element

82
Binomial Heaps(6/10)
83
Binomial Heaps(7/10)
84
Binomial Heaps(8/10)
85
Binomial Heaps(9/10)
86
Binomial Heaps(10/10)
  • Trees in B-Heaps is Binomial tree
  • B0 has exactly one node
  • Bk, k gt 0, consists of a root with degree k and
    whose subtrees are B0, B1, , Bk-1
  • Bk has exactly 2k nodes
  • actual cost of a delete is O(logn s)
  • s number of min-trees in a (original roots - 1)
    and y (children of the removed node)

87
Fibonacci Heaps(1/8)
  • Definition
  • delete, delete the element in a specified node
  • decrease key
  • This two operations are followed by cascading cut

88
Fibonacci Heaps(2/8)
  • Deletion From An F-heap
  • min or not min

89
Fibonacci Heaps(3/8)
  • Decrease Key
  • if not min, and smaller than parent, then delete

90
Fibonacci Heap(4/8)
  • To prevent the amortized cost of delete min
    becomes O(n), each node can have only one child
    be deleted.
  • If two children of x were deleted, then x must be
    cut and moved to the ring of roots.
  • Using a flag (true of false) to indicate whether
    one of xs child has been cut

91
Fibonacci Heaps(5/8)
  • Cascading Cut

92
Fibonacci Heaps(6/8)
  • Lemma
  • the ith child of any node x in a F-Heap has a
    degree of at least i 2, except when i1 the
    degree is 0
  • Corollary
  • Let Sk be the minimum possible number of
    descendants of a node of degree k, then S01,
    S12. From the lemma above, we got
  • (2 comes from 1st
    child
  • and root)

93
Fibonacci Heaps(7/8)
  • Thats why the data structure is called Fibonacci
    Heap

94
Fibonacci Heaps(8/8)
  • Application Of F-heaps
Write a Comment
User Comments (0)
About PowerShow.com