1.23
2.0
main
test-branch
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| 1 | /* Commandline execution:
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| 2 | * civl verify -inputnum_elements=5 secondDerivative.cvl
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| 3 | *
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| 4 | * Note: based on Quarteroni, Sacco, Saleri. "Numerical Mathematics" 2nd ed. sec 10.10.1
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| 5 | *
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| 6 | * */
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| 7 | #include<civlc.cvh>
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| 8 |
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| 9 | $input double h;
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| 10 | $input int num_elements = 5;
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| 11 | $input double initial[num_elements];
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| 12 | double working[num_elements];
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| 13 | $abstract $contin(4) $real rho($real x);
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| 14 | $assume h > 0;
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| 15 |
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| 16 | void secondDerivative(double h, int n, double y[], double result[]){
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| 17 | int i;
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| 18 |
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| 19 | $assume $forall {m=0 .. n-1} y[m] == rho(m*h);
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| 20 | for(i = 1; i < n-1; i++)
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| 21 | {
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| 22 | result[i] = (y[i+1]-2*y[i]+y[i-1])/(h*h);
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| 23 | }
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| 24 | result[0] = (y[2]-2*y[1]+y[0])/h;
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| 25 | result[n-1] = (y[n-3] - 2*y[n-2]-y[n-1])/h;
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| 26 | $assert($uniform {k=1 .. n-2} result[k]-$D[rho,{x,2}](k*h) == $O(h*h));
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| 27 | }
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| 28 |
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| 29 | void main() {
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| 30 | secondDerivative(h, num_elements, initial, working);
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| 31 | }
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