CS 3343: Analysis of Algorithms Lecture 19: Introduction to Greedy Algorithms.
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Transcript of CS 3343: Analysis of Algorithms Lecture 19: Introduction to Greedy Algorithms.
CS 3343: Analysis of Algorithms
Lecture 19: Introduction to Greedy Algorithms
Outline
• Review of DP
• Greedy algorithms– Similar to DP, not an actual algorithm, but a
meta algorithm
Two steps to dynamic programming
• Formulate the solution as a recurrence relation of solutions to subproblems.
• Specify an order of evaluation for the recurrence so you always have what you need.
Restaurant location problem
• You work in the fast food business• Your company plans to open up new restaurants in
Texas along I-35
• Many towns along the highway, call them t1, t2, …, tn
• Restaurants at ti has estimated annual profit pi
• No two restaurants can be located within 10 miles of each other due to regulation
• Your boss wants to maximize the total profit• You want a big bonus
10 mile
A DP algorithm
• Suppose you’ve already found the optimal solution
• It will either include tn or not include tn
• Case 1: tn not included in optimal solution
– Best solution same as best solution for t1 , …, tn-1
• Case 2: tn included in optimal solution
– Best solution is pn + best solution for t1 , …, tj , where j < n is the largest index so that dist(tj, tn) ≥ 10
Recurrence formulation
• Let S(i) be the total profit of the optimal solution when the first i towns are considered (not necessarily selected)– S(n) is the optimal solution to the complete problem
S(n-1)
S(j) + pn j < n & dist (tj, tn) ≥ 10S(n) = max
S(i-1)
S(j) + pi j < i & dist (tj, ti) ≥ 10S(i) = max
Generalize
Number of sub-problems: n. Boundary condition: S(0) = 0.
Dependency: ii-1jS
Example
5 2 2 6 6 63 10 7
6 7 9 8 3 3 2 4 12 5
Distance (mi)
Profit (100k)
6 7 9 9 10 12 12 14 26 26S(i)
S(i-1)
S(j) + pi j < i & dist (tj, ti) ≥ 10S(i) = max
100
07 3 4 12
dummy
Optimal: 26
Complexity
• Time: O(nk), where k is the maximum number of towns that are within 10 miles to the left of any town– In the worst case, O(n2)
– Can be reduced to O(n) by pre-processing
• Memory: Θ(n)
Knapsack problem
Three versions:
0-1 knapsack problem: take each item or leave it
Fractional knapsack problem: items are divisible
Unbounded knapsack problem: unlimited supplies of each item.
Which one is easiest to solve?
•Each item has a value and a weight•Objective: maximize value•Constraint: knapsack has a weight
limitation
We studied the 0-1 problem.
Formal definition (0-1 problem)
• Knapsack has weight limit W• Items labeled 1, 2, …, n (arbitrarily)
• Items have weights w1, w2, …, wn
– Assume all weights are integers
– For practical reason, only consider wi < W
• Items have values v1, v2, …, vn
• Objective: find a subset of items, S, such that iS wi W and iS vi is maximal among all such (feasible) subsets
A DP algorithm
• Suppose you’ve find the optimal solution S
• Case 1: item n is included
• Case 2: item n is not included
Total weight limit:W
wn
Total weight limit:W
Find an optimal solution using items 1, 2, …, n-1 with weight limit W - wn
wn
Find an optimal solution using items 1, 2, …, n-1 with weight limit W
Recursive formulation
• Let V[i, w] be the optimal total value when items 1, 2, …, i are considered for a knapsack with weight limit w
=> V[n, W] is the optimal solution
V[n, W] = maxV[n-1, W-wn] + vn
V[n-1, W]
Generalize
V[i, w] = maxV[i-1, w-wi] + vi item i is taken
V[i-1, w] item i not taken
V[i-1, w] if wi > w item i not taken
Boundary condition: V[i, 0] = 0, V[0, w] = 0. Number of sub-problems = ?
Example
• n = 6 (# of items)• W = 10 (weight limit)• Items (weight, value):
2 24 33 35 62 46 9
0
0
0
0
0
0
00000000000
w 0 1 2 3 4 5 6 7 8 9 10
425
6
4
3
2
1
i
96
65
33
34
22
viwi
maxV[i-1, w-wi] + vi item i is taken
V[i-1, w] item i not taken
V[i-1, w] if wi > w item i not taken
V[i, w] =
V[i, w]
V[i-1, w]V[i-1, w-wi]
6
wi
5
107400
1310764400
9633200
8653200
555532200
2222222200
00000000000
w 0 1 2 3 4 5 6 7 8 9 10
i wi vi
1 2 2
2 4 3
3 3 3
4 5 6
5 2 4
6 6 9
maxV[i-1, w-wi] + vi item i is taken
V[i-1, w] item i not taken
V[i-1, w] if wi > w item i not taken
V[i, w] =
2
4
3
6
5
6
7
5
9
6
8
10
9 11
8
3
12 13
13 15
107400
1310764400
9633200
8653200
555532200
2222222200
00000000000
w 0 1 2 3 4 5 6 7 8 9 10
i wi vi
1 2 2
2 4 3
3 3 3
4 5 6
5 2 4
6 6 9
2
4
3
6
5
6
7
5
9
6
8
10
9 11
8
3
12 13
13 15
Item: 6, 5, 1
Weight: 6 + 2 + 2 = 10
Value: 9 + 4 + 2 = 15
Optimal value: 15
Time complexity
• Θ (nW)• Polynomial?
– Pseudo-polynomial– Works well if W is small
• Consider following items (weight, value):(10, 5), (15, 6), (20, 5), (18, 6)
• Weight limit 35– Optimal solution: item 2, 4 (value = 12). Iterate: 2^4 = 16 subsets– Dynamic programming: fill up a 4 x 35 = 140 table entries
• What’s the problem?– Many entries are unused: no such weight combination– Top-down may be better
Events scheduling problem
• A list of events to schedule– ei has start time si and finishing time fi
– Indexed such that fi < fj if i < j
• Each event has a value vi
• Schedule to make the largest value– You can attend only one event at any time
Time
e1 e2
e3e4 e5
e6
e7
e8
e9
s9 f9
s8 f8
s7 f7
Events scheduling problem
Time
e1 e2
e3e4 e5
e6
e7
e8
e9
• V(i) is the optimal value that can be achieved when the first i events are considered
• V(n) =
V(n-1) en not selected
en selectedV(j) + vn
max {
j < n and fj < sn
s9 f9
s8 f8
s7 f7
Restaurant location problem 2
• Now the objective is to maximize the number of new restaurants (subject to the distance constraint)– In other words, we assume that each
restaurant makes the same profit, no matter where it is opened
10 mile
A DP Algorithm
• Exactly as before, but pi = 1 for all i
S(i-1)
S(j) + 1 j < i & dist (tj, ti) ≥ 10S(i) = max
S(i-1)
S(j) + pi j < i & dist (tj, ti) ≥ 10S(i) = max
Example
• Natural greedy 1: 1 + 1 + 1 + 1 = 4• Maybe greedy is ok here? Does it work for all cases?
5 2 2 6 6 63 10 7
1 1 1 1 1 1 1 1 1 1
Distance (mi)
Profit (100k)
S(i)
S(i-1)
S(j) + 1 j < i & dist (tj, ti) ≥ 10S(i) = max
100
0
2 3 41
dummy
Optimal: 4
1 1 1 2 2 4
Comparison5 2 2 6 6 63 10 7
1 1 1 1 1 1 1 1 1 1
Dist(mi)
Profit (100k)
S(i)
100
0
2 3 41 1 1 1 2 2 4
5 2 2 6 6 63 10 7
6 7 9 8 3 3 2 4 12 5Profit (100k)
6 7 9 9 10 12 12 14 26 26S(i)
100
0
Benefit of taking t1 rather than t2?
Benefit of waiting to see t2?
Dist(mi)
t2 may have a bigger profit
t1 gives you more choices for the future
None!
t1 gives you more choices for the futureBenefit of taking t1 rather than t2?
Benefit of waiting to see t2?
Moral of the story
• If a better opportunity may come out next, you may want to hold on your decision
• Otherwise, grasp the current opportunity immediately because there is no reason to wait …
Greedy algorithm
• For certain problems, DP is an overkill– Greedy algorithm may guarantee to give you
the optimal solution– Much more efficient
Formal argument• Claim 1: if A = [m1, m2, …, mk] is the optimal solution to the
restaurant location problem for a set of towns [t1, …, tn]
– m1 < m2 < … < mk are indices of the selected towns
– Then B = [m2, m3, …, mk] is the optimal solution to the sub-problem [tj, …, tn], where tj is the first town that are at least 10 miles to the right of tm1
• Proof by contradiction: suppose B is not the optimal solution to the sub-problem, which means there is a better solution B’ to the sub-problem
• Then A’ = m1 || B’ gives a better solution than A = m1 || B => A is not optimal => contradiction => B is optimal
m1 B’ (imaginary)A’
Bm1Am2 mk
Implication of Claim 1
• If we know the first town that needs to be chosen, we can reduce the problem to a smaller sub-problem– This is similar to dynamic programming– Optimal substructure
Formal argument (cont’d)
• Claim 2: for the uniform-profit restaurant location problem, there is an optimal solution that chooses t1
• Proof by contradiction: suppose that no optimal solution can be obtained by choosing t1
– Say the first town chosen by the optimal solution S is ti, i > 1
– Replace ti with t1 will not violate the distance constraint, and the total profit remains the same => S’ is an optimal solution
– Contradiction– Therefore claim 2 is valid
S
S’
Implication of Claim 2
• We can simply choose the first town as part of the optimal solution– This is different from DP– Decisions are made immediately
• By Claim 1, we then only need to repeat this strategy to the remaining sub-problem
Greedy algorithm for restaurant location problem
select t1
d = 0;
for (i = 2 to n)
d = d + dist(ti, ti-1);
if (d >= min_dist)
select ti
d = 0;
end
end
5 2 2 6 6 63 10 7
d 0 5 7 9 150
6 9 150
100
7
Complexity
• Time: Θ(n)
• Memory: – Θ(n) to store the input– Θ(1) for greedy selection
Events scheduling problem
• Objective: to schedule the maximal number of events• Let vi = 1 for all i and solve by DP, but overkill• Greedy strategy: choose the first-finishing event that is compatible with
previous selection (1, 2, 4, 6, 8 for the above example)• Why is this a valid strategy?
– Claim 1: optimal substructure– Claim 2: there is an optimal solution that chooses e1
– Proof by contradiction: Suppose that no optimal solution contains e1
– Say the first event chosen is ei => other chosen events start after ei finishes– Replace ei by e1 will result in another optimal solution (e1 finishes earlier than ei)– Contradiction
• Simple idea: attend the event that will left you with the most amount of time when finished
Time
e1 e2
e3e4 e5
e6
e7
e8
e9
Knapsack problem
Three versions:
0-1 knapsack problem: take each item or leave it
Fractional knapsack problem: items are divisible
Unbounded knapsack problem: unlimited supplies of each item.
Which one is easiest to solve?
•Each item has a value and a weight•Objective: maximize value•Constraint: knapsack has a weight
limitation
We can solve the fractional knapsack problem using greedy algorithm
Greedy algorithm for fractional knapsack problem
• Compute value/weight ratio for each item• Sort items by their value/weight ratio into
decreasing order– Call the remaining item with the highest ratio the most
valuable item (MVI)
• Iteratively: – If the weight limit can not be reached by adding MVI
• Select MVI
– Otherwise select MVI partially until weight limit
Example• Weight limit: 10
1.5
2
1.2
1
0.75
1
$ / LB
966
425
654
333
342
221
Value ($)
Weight (LB)
item
Example• Weight limit: 10
• Take item 5– 2 LB, $4
• Take item 6– 8 LB, $13
• Take 2 LB of item 4– 10 LB, 15.4
item Weight (LB)
Value ($)
$ / LB
5 2 4 2
6 6 9 1.5
4 5 6 1.2
1 2 2 1
3 3 3 1
2 4 3 0.75
Why is greedy algorithm for fractional knapsack problem valid?
• Claim: the optimal solution must contain the MVI as much as possible (either up to the weight limit or until MVI is exhausted)
• Proof by contradiction: suppose that the optimal solution does not use all available MVI (i.e., there is still w (w < W) units of MVI left while we choose other items)– We can replace w pounds of less valuable items by MVI– The total weight is the same, but with value higher than the
“optimal”– Contradiction
w w w w
Elements of greedy algorithm
1. Optimal substructure2. Locally optimal decision leads to globally
optimal solution
•For most optimization problems, greedy algorithm will not guarantee an optimal solution•But may give you a good starting point to use other optimization techniques•Starting from next lecture, we’ll study several problems in graph theory that can actually be solved by greedy algorithm