const bool V3SvrBoolector::solve() { double ctime = (double)clock() / CLOCKS_PER_SEC; uint32_t result = boolector_sat(_Solver); ++_solves; _runTime += (((double)clock() / CLOCKS_PER_SEC) - ctime); return (BOOLECTOR_SAT == result); }
int main (void) { Btor *btor; BtorNode *array, *read, *max, *temp, *ugt, *formula, *index; BtorNode *indices[ARRAY1_EXAMPLE_ARRAY_SIZE]; int i, result; btor = boolector_new (); /* We create all possible constants that are used as read indices */ for (i = 0; i < ARRAY1_EXAMPLE_ARRAY_SIZE; i++) indices[i] = boolector_int (btor, i, ARRAY1_EXAMPLE_INDEX_BW); array = boolector_array (btor, ARRAY1_EXAMPLE_VALUE_BW, ARRAY1_EXAMPLE_INDEX_BW, NULL); /* Current maximum is first element of array */ max = boolector_read (btor, array, indices[0]); /* Symbolic loop unrolling */ for (i = 1; i < ARRAY1_EXAMPLE_ARRAY_SIZE; i++) { read = boolector_read (btor, array, indices[i]); ugt = boolector_ugt (btor, read, max); /* found a new maximum? */ temp = boolector_cond (btor, ugt, read, max); boolector_release (btor, max); max = temp; boolector_release (btor, read); boolector_release (btor, ugt); } /* Now we show that 'max' is indeed a maximum */ /* We read at an arbitrary position */ index = boolector_var (btor, ARRAY1_EXAMPLE_INDEX_BW, NULL); read = boolector_read (btor, array, index); /* We assume that it is possible that the read value is greater than 'max' */ formula = boolector_ugt (btor, read, max); /* We assert the formula and call Boolector */ boolector_assert (btor, formula); result = boolector_sat (btor); if (result == BOOLECTOR_UNSAT) printf ("Formula is unsatisfiable\n"); else abort (); /* clean up */ for (i = 0; i < ARRAY1_EXAMPLE_ARRAY_SIZE; i++) boolector_release (btor, indices[i]); boolector_release (btor, formula); boolector_release (btor, read); boolector_release (btor, index); boolector_release (btor, max); boolector_release (btor, array); assert (boolector_get_refs (btor) == 0); boolector_delete (btor); return 0; }
int main (void) { Btor *btor; BtorNode *x, *y, *temp, *old_x, *old_y, *eq1, *eq2, *and, *formula; int result; btor = boolector_new (); x = boolector_var (btor, BV1_EXAMPLE_NUM_BITS, NULL); y = boolector_var (btor, BV1_EXAMPLE_NUM_BITS, NULL); /* remember initial values of x and y */ old_x = boolector_copy (btor, x); old_y = boolector_copy (btor, y); /* x = x ^ y */ temp = boolector_xor (btor, x, y); boolector_release (btor, x); x = temp; /* y = x ^ y */ temp = boolector_xor (btor, x, y); boolector_release (btor, y); y = temp; /* x = x ^ y */ temp = boolector_xor (btor, x, y); boolector_release (btor, x); x = temp; /* Now, we have to show that old_x = y and old_y = x */ eq1 = boolector_eq (btor, old_x, y); eq2 = boolector_eq (btor, old_y, x); and = boolector_and (btor, eq1, eq2); /* In order to prove that this is a theorem, we negate the whole * formula and show that the negation is unsatisfiable */ formula = boolector_not (btor, and); /* We assert the formula and call Boolector */ boolector_assert (btor, formula); result = boolector_sat (btor); if (result == BOOLECTOR_UNSAT) printf ("Formula is unsatisfiable\n"); else abort (); /* cleanup */ boolector_release (btor, x); boolector_release (btor, old_x); boolector_release (btor, y); boolector_release (btor, old_y); boolector_release (btor, eq1); boolector_release (btor, eq2); boolector_release (btor, and); boolector_release (btor, formula); assert (boolector_get_refs (btor) == 0); boolector_delete (btor); return 0; }
int main () { int sat_result; BtorExp *array, *index1, *index2, *read1, *read2, *eq, *ne; Btor *btor; btor = boolector_new (); boolector_enable_inc_usage (btor); array = boolector_array (btor, ARRAY3_EXAMPLE_VALUE_BW, ARRAY3_EXAMPLE_INDEX_BW, NULL); index1 = boolector_var (btor, ARRAY3_EXAMPLE_INDEX_BW, NULL); index2 = boolector_var (btor, ARRAY3_EXAMPLE_INDEX_BW, NULL); read1 = boolector_read (btor, array, index1); read2 = boolector_read (btor, array, index2); eq = boolector_eq (btor, index1, index2); ne = boolector_ne (btor, read1, read2); /* we enforce that index1 is equal to index 2 */ boolector_assert (btor, eq); sat_result = boolector_sat (btor); assert (sat_result == BOOLECTOR_SAT); /* now we additionally assume that the read values differ * the instance is now unsatasfiable as read congruence is violated */ boolector_assume (btor, ne); sat_result = boolector_sat (btor); assert (sat_result == BOOLECTOR_UNSAT); /* after the SAT call the assumptions are gone * the instance is now satisfiable again */ sat_result = boolector_sat (btor); assert (sat_result == BOOLECTOR_SAT); boolector_release (btor, array); boolector_release (btor, index1); boolector_release (btor, index2); boolector_release (btor, read1); boolector_release (btor, read2); boolector_release (btor, eq); boolector_release (btor, ne); boolector_delete (btor); return 0; }
bool addTempConstraint(SOLVER_EXPR_TYPE expr) { _solver_called++; boolector_assume(_btor, expr); return boolector_sat(_btor) == BOOLECTOR_SAT; }
int main (void) { Btor *btor; BoolectorNode *array1, *array2, *zero, *one, *val1, *val2; BoolectorNode *write1, *write2, *formula; char **indices, **values; int result, size, i; btor = boolector_new (); boolector_set_opt (btor, "model_gen", 1); zero = boolector_zero (btor, ARRAY2_EXAMPLE_INDEX_BW); one = boolector_one (btor, ARRAY2_EXAMPLE_INDEX_BW); val1 = boolector_int (btor, 3, ARRAY2_EXAMPLE_VALUE_BW); val2 = boolector_int (btor, 5, ARRAY2_EXAMPLE_VALUE_BW); array1 = boolector_array (btor, ARRAY2_EXAMPLE_VALUE_BW, ARRAY2_EXAMPLE_INDEX_BW, NULL); array2 = boolector_array (btor, ARRAY2_EXAMPLE_VALUE_BW, ARRAY2_EXAMPLE_INDEX_BW, NULL); write1 = boolector_write (btor, array1, zero, val1); write2 = boolector_write (btor, array2, one, val2); /* Note: we compare two arrays for equality ---> needs extensional theory */ formula = boolector_eq (btor, write1, write2); boolector_assert (btor, formula); result = boolector_sat (btor); if (result == BOOLECTOR_SAT) printf ("Formula is satisfiable\n"); else abort (); /* Formula is satisfiable, we can obtain array models: */ boolector_array_assignment (btor, array1, &indices, &values, &size); if (size > 0) { printf ("Array1:\n"); for (i = 0; i < size; i++) printf ("Array1[%s] = %s\n", indices[i], values[i]); boolector_free_array_assignment (btor, indices, values, size); } boolector_array_assignment (btor, array2, &indices, &values, &size); if (size > 0) { printf ("\nArray2:\n"); for (i = 0; i < size; i++) printf ("Array2[%s] = %s\n", indices[i], values[i]); boolector_free_array_assignment (btor, indices, values, size); } boolector_array_assignment (btor, write1, &indices, &values, &size); if (size > 0) { printf ("\nWrite1:\n"); for (i = 0; i < size; i++) printf ("Write1[%s] = %s\n", indices[i], values[i]); boolector_free_array_assignment (btor, indices, values, size); } boolector_array_assignment (btor, write2, &indices, &values, &size); if (size > 0) { printf ("\nWrite2:\n"); for (i = 0; i < size; i++) printf ("Write2[%s] = %s\n", indices[i], values[i]); boolector_free_array_assignment (btor, indices, values, size); } /* clean up */ boolector_release (btor, formula); boolector_release (btor, write1); boolector_release (btor, write2); boolector_release (btor, array1); boolector_release (btor, array2); boolector_release (btor, val1); boolector_release (btor, val2); boolector_release (btor, zero); boolector_release (btor, one); assert (boolector_get_refs (btor) == 0); boolector_delete (btor); return 0; }
int main (void) { Btor *btor; BtorNode *v1, *v2, *add, *zero, *vars_sgt_zero, *impl; BtorNode *v1_sgt_zero, *v2_sgt_zero, *add_sgt_zero, *formula; char *assignments[10]; int result, i; btor = boolector_new (); boolector_enable_model_gen (btor); v1 = boolector_var (btor, BV2_EXAMPLE_NUM_BITS, NULL); v2 = boolector_var (btor, BV2_EXAMPLE_NUM_BITS, NULL); zero = boolector_zero (btor, BV2_EXAMPLE_NUM_BITS); v1_sgt_zero = boolector_sgt (btor, v1, zero); v2_sgt_zero = boolector_sgt (btor, v2, zero); vars_sgt_zero = boolector_and (btor, v1_sgt_zero, v2_sgt_zero); add = boolector_add (btor, v1, v2); add_sgt_zero = boolector_sgt (btor, add, zero); impl = boolector_implies (btor, vars_sgt_zero, add_sgt_zero); /* We negate the formula and try to show that the negation is unsatisfiable */ formula = boolector_not (btor, impl); /* We assert the formula and call Boolector */ boolector_assert (btor, formula); result = boolector_sat (btor); if (result == BOOLECTOR_SAT) printf ("Instance is satisfiable"); else abort (); /* The formula is not valid, we have found a counter-example. * Now, we are able to obtain assignments to arbitrary expressions */ i = 0; assignments[i++] = boolector_bv_assignment (btor, zero); assignments[i++] = boolector_bv_assignment (btor, v1); assignments[i++] = boolector_bv_assignment (btor, v2); assignments[i++] = boolector_bv_assignment (btor, add); assignments[i++] = boolector_bv_assignment (btor, v1_sgt_zero); assignments[i++] = boolector_bv_assignment (btor, v2_sgt_zero); assignments[i++] = boolector_bv_assignment (btor, vars_sgt_zero); assignments[i++] = boolector_bv_assignment (btor, add_sgt_zero); assignments[i++] = boolector_bv_assignment (btor, impl); assignments[i++] = boolector_bv_assignment (btor, formula); i = 0; printf ("Assignment to 0: %s\n", assignments[i++]); printf ("Assignment to v1: %s\n", assignments[i++]); printf ("Assignment to v2: %s\n", assignments[i++]); printf ("Assignment to v1 + v2: %s\n", assignments[i++]); printf ("Assignment to v1 > 0: %s\n", assignments[i++]); printf ("Assignment to v2 > 0: %s\n", assignments[i++]); printf ("Assignment to v1 > 0 & v2 > 0: %s\n", assignments[i++]); printf ("Assignment to v1 + v2 > 0: %s\n", assignments[i++]); printf ("Assignment to v1 > 0 & v2 > 0 => v1 + v2 > 0: %s\n", assignments[i++]); printf ("Assignment to !(v1 > 0 & v2 > 0 => v1 + v2 > 0): %s\n", assignments[i++]); for (i = 0; i < 10; i++) boolector_free_bv_assignment (btor, assignments[i]); /* cleanup */ boolector_release (btor, zero); boolector_release (btor, v1); boolector_release (btor, v2); boolector_release (btor, add); boolector_release (btor, impl); boolector_release (btor, formula); boolector_release (btor, v1_sgt_zero); boolector_release (btor, v2_sgt_zero); boolector_release (btor, vars_sgt_zero); boolector_release (btor, add_sgt_zero); assert (boolector_get_refs (btor) == 0); boolector_delete (btor); return 0; }