CSE505/Assignment2/README.md
2024-03-09 23:27:50 +08:00

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Assignment 1

Part A

clingo

clingo tsp.lp
size ans time
5 38 0.001
10 48 0.050
15 29 0.351
20 unknown too long to solve

time grows exponentialy.

swi-prolog

size ans time
5 38 very fast
10 48 10+s
15 unknow too long to solve
20 unknown too long to solve

I didn't find a way to calculate runtime in swi-prolog. But it is clearly to see that it is way slower than clingo.

Google OR-Tools

  1. Local Optimum
size ans time
5 38 0.0077
10 48 0.0085
15 37 0.009
20 48 0.010
  1. Global Optimum
size ans time
5 38 time limit exceeded
10 48 time limit exceeded
15 29 time limit exceeded
20 46 time limit exceeded

It is great to have two different mode. Though the approximate result is not as good as the exact one. But it is way faster and uses way less resource. We can switch between different mode at different case.

AMPL

size ans time
5 38 very fast
10 48 very fast
15 29 very fast
20 46 very fast

Very fast.

Part B

clingo

clingo task.lp
size processors deadline result time
10 3 20 yes 0.031
20 6 30 no 4.498
20 8 30 yes 0.233
30 6 60 unknown too long to solve
30 8 60 yes 2.961
30 8 80 yes 6.701
30 8 90 yes 9.245

With either too high or too low constrain, the runtime grows exponentially. If the constrain is too low, it must iterate through all answers to find one correct result. If it is too high, then it may waste too much time fill the first processor.

Google OR-Tools

size processors deadline result time
10 3 20 yes 0.035
20 6 30 no 0.037
20 8 30 yes 0.0474
30 6 60 no 0.0413
30 8 60 yes 0.0469
30 8 80 yes 0.0481
30 8 90 yes 0.0552

Unlike clingo, Google OR-Tools is much faster on this question. And too high/low constrain does not increase the run time by a lot.

Part C

clingo

clingo cut.lp
size ans time
5 5 0.678
10 9 0.866
15 13 1.122
20 17 1.902
25 21 6.379
30 25 34.466

One important factor of the runtime is the max number of cut to check. If we set max = 10 with size = 30, we get the time of 0.914. However, it is impossible to get the max size before running, I believe this time would be a great representation of the runtime of clingo.

AMPL

size ans time
5 5 very fast
10 9 very fast
15 13 very fast
20 17 very fast
25 21 very fast
30 25 very fast
100000 80393 very fast

Very fast.

Conclusion

AMPL is the fastest implementation in part 1 and 3, much faster than the others. clingo is the clearest and the easiest way to write it but it is not that fastest one. Each language has its own pros and cons so it is hard to create a single language with all the pros but no cons.