Z3_probe Z3_API Z3_probe_const(Z3_context c, double val) {
Z3_TRY;
LOG_Z3_probe_const(c, val);
RESET_ERROR_CODE();
probe * new_p = mk_const_probe(val);
RETURN_PROBE(new_p);
Z3_CATCH_RETURN(0);
}
static tactic * mk_pb_tactic(ast_manager & m) {
params_ref pb2bv_p;
pb2bv_p.set_bool("ite_extra", true);
pb2bv_p.set_uint("pb2bv_all_clauses_limit", 8);
return and_then(fail_if_not(mk_is_pb_probe()),
fail_if(mk_produce_proofs_probe()),
fail_if(mk_produce_unsat_cores_probe()),
or_else(and_then(fail_if(mk_ge(mk_num_exprs_probe(), mk_const_probe(SMALL_SIZE))),
fail_if_not(mk_is_ilp_probe()),
// try_for(mk_mip_tactic(m), 8000),
mk_fail_if_undecided_tactic()),
and_then(using_params(mk_pb2bv_tactic(m), pb2bv_p),
fail_if_not(mk_is_qfbv_probe()),
mk_bv2sat_tactic(m))));
}
tactic * mk_qfbv_tactic(ast_manager& m, params_ref const & p, tactic* sat, tactic* smt) {
params_ref local_ctx_p = p;
local_ctx_p.set_bool("local_ctx", true);
params_ref solver_p;
solver_p.set_bool("preprocess", false); // preprocessor of smt::context is not needed.
params_ref no_flat_p;
no_flat_p.set_bool("flat", false);
params_ref ctx_simp_p;
ctx_simp_p.set_uint("max_depth", 32);
ctx_simp_p.set_uint("max_steps", 50000000);
params_ref big_aig_p;
big_aig_p.set_bool("aig_per_assertion", false);
tactic* preamble_st = mk_qfbv_preamble(m, p);
tactic * st = main_p(and_then(preamble_st,
// If the user sets HI_DIV0=false, then the formula may contain uninterpreted function
// symbols. In this case, we should not use the `sat', but instead `smt'. Alternatively,
// the UFs can be eliminated by eager ackermannization in the preamble.
cond(mk_is_qfbv_eq_probe(),
and_then(mk_bv1_blaster_tactic(m),
using_params(smt, solver_p)),
cond(mk_is_qfbv_probe(),
and_then(mk_bit_blaster_tactic(m),
when(mk_lt(mk_memory_probe(), mk_const_probe(MEMLIMIT)),
and_then(using_params(and_then(mk_simplify_tactic(m),
mk_solve_eqs_tactic(m)),
local_ctx_p),
if_no_proofs(cond(mk_produce_unsat_cores_probe(),
mk_aig_tactic(),
using_params(mk_aig_tactic(),
big_aig_p))))),
sat),
smt))));
st->updt_params(p);
return st;
}
return st;
}
tactic * mk_uflra_tactic(ast_manager & m, params_ref const & p) {
tactic * st = and_then(mk_quant_preprocessor(m),
mk_smt_tactic());
st->updt_params(p);
return st;
}
tactic * mk_auflia_tactic(ast_manager & m, params_ref const & p) {
params_ref qi_p;
qi_p.set_str("qi.cost", "0");
TRACE("qi_cost", qi_p.display(tout); tout << "\n" << qi_p.get_str("qi.cost", "<null>") << "\n";);
tactic * st = and_then(mk_no_solve_eq_preprocessor(m),
or_else(and_then(fail_if(mk_gt(mk_num_exprs_probe(), mk_const_probe(static_cast<double>(128)))),
using_params(mk_smt_tactic(), qi_p),
mk_fail_if_undecided_tactic()),
mk_smt_tactic()));
st->updt_params(p);
return st;
}
tactic * mk_auflira_tactic(ast_manager & m, params_ref const & p) {
tactic * st = and_then(mk_quant_preprocessor(m),
mk_smt_tactic());
st->updt_params(p);
return st;
}
tactic * mk_aufnira_tactic(ast_manager & m, params_ref const & p) {
tactic * mk_qfidl_tactic(ast_manager & m, params_ref const & p) {
params_ref main_p;
main_p.set_bool("elim_and", true);
main_p.set_bool("blast_distinct", true);
main_p.set_bool("som", true);
params_ref lhs_p;
lhs_p.set_bool("arith_lhs", true);
params_ref lia2pb_p;
lia2pb_p.set_uint("lia2pb_max_bits", 4);
params_ref pb2bv_p;
pb2bv_p.set_uint("pb2bv_all_clauses_limit", 8);
params_ref pull_ite_p;
pull_ite_p.set_bool("pull_cheap_ite", true);
pull_ite_p.set_bool("local_ctx", true);
pull_ite_p.set_uint("local_ctx_limit", 10000000);
tactic * preamble_st = and_then(and_then(mk_simplify_tactic(m),
mk_fix_dl_var_tactic(m),
mk_propagate_values_tactic(m),
mk_elim_uncnstr_tactic(m)
),
and_then(mk_solve_eqs_tactic(m),
using_params(mk_simplify_tactic(m), lhs_p),
mk_propagate_values_tactic(m),
mk_normalize_bounds_tactic(m),
mk_solve_eqs_tactic(m)));
params_ref bv_solver_p;
// The cardinality constraint encoding generates a lot of shared if-then-else's that can be flattened.
// Several of them are simplified to and/or. If we flat them, we increase a lot the memory consumption.
bv_solver_p.set_bool("flat", false);
bv_solver_p.set_bool("som", false);
// dynamic psm seems to work well.
bv_solver_p.set_sym("gc", symbol("dyn_psm"));
tactic * bv_solver = using_params(and_then(mk_simplify_tactic(m),
mk_propagate_values_tactic(m),
mk_solve_eqs_tactic(m),
mk_max_bv_sharing_tactic(m),
mk_bit_blaster_tactic(m),
mk_aig_tactic(),
mk_sat_tactic(m)),
bv_solver_p);
tactic * try2bv =
and_then(using_params(mk_lia2pb_tactic(m), lia2pb_p),
mk_propagate_ineqs_tactic(m),
using_params(mk_pb2bv_tactic(m), pb2bv_p),
fail_if(mk_not(mk_is_qfbv_probe())),
bv_solver);
params_ref diff_neq_p;
diff_neq_p.set_uint("diff_neq_max_k", 25);
tactic * st = cond(mk_and(mk_lt(mk_num_consts_probe(), mk_const_probe(static_cast<double>(BIG_PROBLEM))),
mk_and(mk_not(mk_produce_proofs_probe()),
mk_not(mk_produce_unsat_cores_probe()))),
using_params(and_then(preamble_st,
or_else(using_params(mk_diff_neq_tactic(m), diff_neq_p),
try2bv,
mk_smt_tactic())),
main_p),
mk_smt_tactic());
st->updt_params(p);
return st;
}
tactic * mk_qfbv_tactic(ast_manager & m, params_ref const & p) {
params_ref main_p;
main_p.set_bool("elim_and", true);
main_p.set_bool("push_ite_bv", true);
main_p.set_bool("blast_distinct", true);
params_ref simp2_p = p;
simp2_p.set_bool("som", true);
simp2_p.set_bool("pull_cheap_ite", true);
simp2_p.set_bool("push_ite_bv", false);
simp2_p.set_bool("local_ctx", true);
simp2_p.set_uint("local_ctx_limit", 10000000);
simp2_p.set_bool("flat", true); // required by som
simp2_p.set_bool("hoist_mul", false); // required by som
params_ref local_ctx_p = p;
local_ctx_p.set_bool("local_ctx", true);
params_ref solver_p;
solver_p.set_bool("preprocess", false); // preprocessor of smt::context is not needed.
params_ref no_flat_p;
no_flat_p.set_bool("flat", false);
params_ref ctx_simp_p;
ctx_simp_p.set_uint("max_depth", 32);
ctx_simp_p.set_uint("max_steps", 50000000);
params_ref hoist_p;
hoist_p.set_bool("hoist_mul", true);
hoist_p.set_bool("som", false);
params_ref solve_eq_p;
// conservative guassian elimination.
solve_eq_p.set_uint("solve_eqs_max_occs", 2);
params_ref big_aig_p;
big_aig_p.set_bool("aig_per_assertion", false);
tactic * preamble_st = and_then(and_then(mk_simplify_tactic(m),
mk_propagate_values_tactic(m),
using_params(mk_solve_eqs_tactic(m), solve_eq_p),
mk_elim_uncnstr_tactic(m),
if_no_proofs(if_no_unsat_cores(mk_bv_size_reduction_tactic(m))),
using_params(mk_simplify_tactic(m), simp2_p)),
// Z3 can solve a couple of extra benchmarks by using hoist_mul
// but the timeout in SMT-COMP is too small.
// Moreover, it impacted negatively some easy benchmarks.
// We should decide later, if we keep it or not.
using_params(mk_simplify_tactic(m), hoist_p),
mk_max_bv_sharing_tactic(m));
#ifdef USE_OLD_SAT_SOLVER
tactic * new_sat = and_then(mk_simplify_tactic(m),
mk_smt_tactic());
#else
tactic * new_sat = cond(mk_or(mk_produce_proofs_probe(), mk_produce_unsat_cores_probe()),
and_then(mk_simplify_tactic(m),
mk_smt_tactic()),
mk_sat_tactic(m));
#endif
tactic * st = using_params(and_then(preamble_st,
// If the user sets HI_DIV0=false, then the formula may contain uninterpreted function
// symbols. In this case, we should not use
cond(mk_is_qfbv_probe(),
cond(mk_is_qfbv_eq_probe(),
and_then(mk_bv1_blaster_tactic(m),
using_params(mk_smt_tactic(), solver_p)),
and_then(mk_bit_blaster_tactic(m),
when(mk_lt(mk_memory_probe(), mk_const_probe(MEMLIMIT)),
and_then(using_params(and_then(mk_simplify_tactic(m),
mk_solve_eqs_tactic(m)),
local_ctx_p),
if_no_proofs(cond(mk_produce_unsat_cores_probe(),
mk_aig_tactic(),
using_params(mk_aig_tactic(),
big_aig_p))))),
new_sat)),
mk_smt_tactic())),
main_p);
st->updt_params(p);
return st;
}
