dynamic programming 2 mani chandy mani@cs.caltech.edu
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Dynamic Programming 2
Mani Chandy
mani@cs.caltech.edu
The Pattern
• Given a problem P, obtain a sequence of problems Q0, Q1, …., Qm, where:
– You have a solution to Q0
– The solution to P can be obtained from the solution to Qm,
– The solution to a problem Qj, j > 0, can be obtained from solutions to problems Qk, k < j, that appear earlier in the sequence.
Dynamic Progamming Pattern
PGiven problem P
Propose a partial ordering of problems
Q0Qm
You know how to compute solution to Q0
You can compute thesolution to P from the solution to Qm
Creative Step
Finding problems Qi from problem P
More mechanical step: Determining the function that computes the solution Sk for problem Qk from the solutions Sj of problems Qj for j < k.
Example: Matrix Multiplication
1 X N
N X N N X NNX1
What is the cost of multiplying matrices of these sizes?
Cost of multiplying 2 matrices
p x q
q x r
p rows and q columns.
Cost is 2pqr because resultant matrix has pr elements, andThe cost of computing each element is 2q operations.
Parenthesization
1 X N
N X N N X NNX1
If we multiply these matrices first the cost is 2N3.
N X NResulting matrix
Parenthesization1 X N
NX1
N X N
Cost of multiplication is N2.
Thus, total cost is proportional to N3 + N2 + N if we parenthesizethe expression in this way.
Different Ordering
1 X N
N X N N X NNX1
Cost is proportional to N2
The Ordering Matters!
One ordering costs O(N3)
The other ordering costs O(N2)
1 X N
N X N N X NNX1
1 X NN X N N X N
NX1
Generalization: Parenthesization
A1 op An A3 A2 op op …. op
Associative operation
Cost of operation depends on parameters of the operands.
Parenthesize to minimize total cost.
( ) ( )( )
Creative Step
Come up with partial-ordering of problems Qi given problem P.
Propose a partial ordering of problems
Q0Qm
Creative Step: Solution
Qi,j is: optimally parenthesize the expression Ai op ….. op Aj
Relatively “mechanical” steps:1. Find partial ordering of problems Qi,j 2. Find function f that computes solution Si,j from solutions of problems earlier in the ordering.
Partial Ordering Structure
Q1,1 Q2,2Q3,3 Q4,4
Q1,2 Q2,3 Q3,4
Q1,3 Q2,4
Q1,4
Depends on
Solutions known
Solution to givenproblem obtainedfrom solution to thisproblem Q1,n.
The Recurrence Relation
Let C[j,k] be the minimum cost of executing Aj op … op Ak.
Base Case: ???? C[j,j] = 0
Induction Step: ????C[j,k] for k > j is: min over all v of C[j,v]+C[v+1,k] + cost of the operation combining [j…v] and [v+1 … k]
Proof: ???
For matrix multiplication
Let j-th matrix have size: p(j-1) X pj
Then the size of matrix obtained by combining [ j … v] is: ?
p (j-1) X pv
Then the size of matrix obtained by combining [ v+1 … k] is: ?
pv X pk
Cost of multiplying [j … v] and [v+1 … k] is p (j-1) X pv X pk
Computational ComplexityRecurrence Relation for matrix multiplication:
C[j,k] for k > j is: min over all v of (C[j,v]+C[v+1,k] + p(j-1)pvpk)
Time to compute C[j,k] is proportional to (k-j)
Total time to compute C, for all j,k is:0 x N {for bottom level, i.e., for C[j,j] } +1 x (N-1) { for first level, i.e., for C[j,j+1]} + …. +k x (N-k) {for k-th level, i.e., for C[j, j+ k]} + …..
Show that total time is proportional to O(N3).
Proof Structure
What is the theorem that we are proving?
We make an assertion about the meaning of a term.
For instance, C[j,k] is the minimum cost of executing Aj op …. op Ak
We are proving that this assertion is correct.
Proof Structure
Almost always, we use induction.
Base case: establish that the value of C[j,j] is correct.
Induction step: Assume that the value of C[j, j+u] is correct for all u where u is less than V, and prove that the value of C[j, j+V] iscorrect.
Remember what we are proving:C[j,k] is the minimum cost of executing Aj op …. op Ak
The Central Idea
Bellman’s optimality principle
Qi,j Qu,v
Pick optimal
Discard others
Qa,z
The discarded solutions forthe smaller problem remaindiscarded because the optimalsolution dominates them.
All-Points Shortest Path
Given a weighted directed graph. • The edge-weight W[j,k] represents the distance from vertex j to vertex k.• There are no cycles of negative weight.• For all j, k, compute D[j,k] where D[j,k] is the length of the shortest path from vertex j to vertex k.
The Creative Step
Come up with partial-ordering of problems Qi given problem P.
There are different problem sets Qi some better than others.
Creative Step
Let F[j,k,m] be the length of the shortest path that has 1. at most m hops, and2. is from vertex j to vertex k
What is the partial-ordering of problems Q[j,k,m]?
A recurrence relation
F[j,k,m] = min over all r of F[j,r,m-1] + W[r,k]
Base case: F[j,k,1] = ?????
W[j,k](assume W[j,j] = 0 for all j)
Obtaining solution for given problem P
D[j,k] = F[j,k,n-1]
Proof of Correctness
What are we proving?
We are proving that the meaning we gave to F[j,k,m] is correct
Base CaseWe show that F[j,k,1] is indeed the length of the shortest pathfrom vertex j to vertex k that traverses at most one edge.
Induction StepAssume that F[j,k,m] is the length of the shortest path from j to kthat traverses at most m edges, for all m less than p, and prove thatF[j,k,p] is the min length from j to k that traverses at most p edges
Proof of Induction Step
Consider any path Z from a vertex j to a different vertex kwhere the path traverses at most p edges.
We must prove: length(Z) is at least F[j,k,p]
Let r be the prefinal vertex in path Z, i.e., r is the last vertexbefore k in path Z. Partition the path Z into the path Z’ fromvertex j to vertex r followed by the edge (r,k).Then: length(Z) = length(Z’) + W[r,k]
By the induction assumption: length(Z’) ?????
Proof of induction step
length(Z’) >= F[j,r,p-1]From the induction hypothesis
jr
k
at most p-1 hops 1hop
Path Z
Path Z’
Proof of Induction Step
length(Z) = length(Z’) + W[r,k]
length(Z’) >= F[j,r,p-1]
Hence, length(Z) >= F[j,r,p-1] + W[r,k]
F[j,k,p] = min over all r of F[j,r,p-1] + W[r,k]
Hence, length(Z) >= F[j,k,p]
Proof of Induction Step
We have shown that any path with at most p hopsfrom vertex j to vertex k has length at least F[j,k,p].
Next, we show there exists a path with at most p hopsfrom vertex j to vertex k that has length F[j,k,p].
From these two we conclude that the minimum lengthpath with at most p hops from vertex j to vertex k haslength F[j,k,p].
Left to you
Complexity?
n4
Can you do better?
Come up with partial-ordering of problems Qi given problem P.
Let F[j,k,m] be the length of the shortest path from vertex j tovertex k that has at most m hops.
2m
Recurrence Relation
Let F[j,k,m] be the length of the shortest path from vertex j tovertex k that has at most 2m hops.
Derive a recurrence relation from this meaning of F[j,k,m].
F[j,k,0] = ??? Length of shortest path from vertex j to vertex k that has at most 1 edge.
W[j,k]
F[j,k,m] = ??? Length of shortest path from vertex j to vertex k that has at most 2m edges.
Derive Recurrence Relation
F[j,k,m] = ??? Length of shortest path from vertex j to vertex k that has at most 2m edges.
F[j,k,m+1] = min over all v of (F[j,v,m] + F[v,k,m])
Proof
Exactly the same proof structure as the previous case.
Consider any path Z from j to k with at most 2(m+1) hops.
Let the number of hops in the path be t.Partition path Z into path Y followed by path Y’ wherethe number of hops in path Y is floor(t/2). Let Y end atvertex r.
Y Y’
1
2
3
4
56
7 8Path Z
r
Proof
length(Z) = length(Y) + length(Y’)
From the induction hypothesis: length(Y) >= F[j,r,m] and length(Y’) >= F[r,k,m]
Since Z has at most 2(m+1) hops, Y and Y’ each have at most2m hops.
Hence length(Z) >= F[j,r,m] + F[r,k,m]
From recurrence relation, F[j,r,m]+F[r,k,m] >= F[j,k,m+1]
Hence, length(Z) >= F[j,k,m+1]
Proof
We have shown that every path with at most 2m hops fromvertex j to vertex k has length at least F[j,k,m].
Now show that there exists a path with at most 2m hops fromvertex j to vertex k that has length F[j,k,m].
Proof has the same structure and is left to you.
Complexity?
n3 log(n)
Can you do better?
Come up with partial-ordering of problems Qi given problem P.
Let F[j,k,m] be the length of the shortest path from vertex j tovertex k that traverses intermediate vertices only in set {1, … m-1}
Derive and Prove Recurrence
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