Copyright (c) 2016 Microsoft Corporation
Module Name:
enum2bv_solver.cpp
Abstract:
Finite domain solver.
Enumeration data-types are translated into bit-vectors, and then
the incremental sat-solver is applied to the resulting assertions.
Author:
Nikolaj Bjorner (nbjorner) 2016-10-17
Notes:
--*/
#include "ast/bv_decl_plugin.h"
#include "ast/datatype_decl_plugin.h"
#include "ast/ast_pp.h"
#include "ast/rewriter/enum2bv_rewriter.h"
#include "model/model_smt2_pp.h"
#include "tactic/tactic.h"
#include "tactic/generic_model_converter.h"
#include "tactic/fd_solver/enum2bv_solver.h"
#include "solver/solver_na2as.h"
class enum2bv_solver : public solver_na2as {
ast_manager& m;
ref<solver> m_solver;
enum2bv_rewriter m_rewriter;
public:
enum2bv_solver(ast_manager& m, params_ref const& p, solver* s):
solver_na2as(m),
m(m),
m_solver(s),
m_rewriter(m, p)
{
solver::updt_params(p);
}
~enum2bv_solver() override {}
solver* translate(ast_manager& dst_m, params_ref const& p) override {
solver* result = alloc(enum2bv_solver, dst_m, p, m_solver->translate(dst_m, p));
model_converter_ref mc = external_model_converter();
if (mc) {
ast_translation tr(m, dst_m);
result->set_model_converter(mc->translate(tr));
}
return result;
}
void assert_expr_core(expr * t) override {
expr_ref tmp(t, m);
expr_ref_vector bounds(m);
proof_ref tmp_proof(m);
m_rewriter(t, tmp, tmp_proof);
m_solver->assert_expr(tmp);
m_rewriter.flush_side_constraints(bounds);
m_solver->assert_expr(bounds);
}
void push_core() override {
m_rewriter.push();
m_solver->push();
}
void pop_core(unsigned n) override {
m_solver->pop(n);
m_rewriter.pop(n);
}
lbool check_sat_core2(unsigned num_assumptions, expr * const * assumptions) override {
m_solver->updt_params(get_params());
return m_solver->check_sat_core(num_assumptions, assumptions);
}
void updt_params(params_ref const & p) override { solver::updt_params(p); m_solver->updt_params(p); }
void collect_param_descrs(param_descrs & r) override { m_solver->collect_param_descrs(r); }
void set_produce_models(bool f) override { m_solver->set_produce_models(f); }
void set_progress_callback(progress_callback * callback) override { m_solver->set_progress_callback(callback); }
void collect_statistics(statistics & st) const override { m_solver->collect_statistics(st); }
void get_unsat_core(expr_ref_vector & r) override { m_solver->get_unsat_core(r); }
void set_phase(expr* e) override { m_solver->set_phase(e); }
phase* get_phase() override { return m_solver->get_phase(); }
void set_phase(phase* p) override { m_solver->set_phase(p); }
void move_to_front(expr* e) override { m_solver->move_to_front(e); }
void get_model_core(model_ref & mdl) override {
m_solver->get_model(mdl);
if (mdl) {
model_converter_ref mc = local_model_converter();
if (mc) (*mc)(mdl);
}
}
model_converter* local_model_converter() const {
if (m_rewriter.enum2def().empty() &&
m_rewriter.enum2bv().empty()) {
return nullptr;
}
generic_model_converter* mc = alloc(generic_model_converter, m, "enum2bv");
for (auto const& kv : m_rewriter.enum2bv())
mc->hide(kv.m_value);
for (auto const& kv : m_rewriter.enum2def())
mc->add(kv.m_key, kv.m_value);
return mc;
}
model_converter* external_model_converter() const {
return concat(mc0(), local_model_converter());
}
model_converter_ref get_model_converter() const override {
model_converter_ref mc = external_model_converter();
mc = concat(mc.get(), m_solver->get_model_converter().get());
return mc;
}
proof * get_proof() override { return m_solver->get_proof(); }
std::string reason_unknown() const override { return m_solver->reason_unknown(); }
void set_reason_unknown(char const* msg) override { m_solver->set_reason_unknown(msg); }
void get_labels(svector<symbol> & r) override { m_solver->get_labels(r); }
ast_manager& get_manager() const override { return m; }
lbool find_mutexes(expr_ref_vector const& vars, vector<expr_ref_vector>& mutexes) override {
return m_solver->find_mutexes(vars, mutexes);
}
expr_ref_vector cube(expr_ref_vector& vars, unsigned backtrack_level) override {
return m_solver->cube(vars, backtrack_level);
}
lbool get_consequences_core(expr_ref_vector const& asms, expr_ref_vector const& vars, expr_ref_vector& consequences) override {
datatype_util dt(m);
bv_util bv(m);
expr_ref_vector bvars(m), conseq(m), bounds(m);
for (expr* v : vars) {
expr_ref tmp(m.mk_eq(v, v), m);
proof_ref proof(m);
m_rewriter(tmp, tmp, proof);
}
m_rewriter.flush_side_constraints(bounds);
m_solver->assert_expr(bounds);
for (expr* v : vars) {
func_decl* f = nullptr;
if (is_app(v) && is_uninterp_const(v) && m_rewriter.enum2bv().find(to_app(v)->get_decl(), f)) {
bvars.push_back(m.mk_const(f));
}
else {
bvars.push_back(v);
}
}
lbool r = m_solver->get_consequences(asms, bvars, consequences);
unsigned i = 0;
for (expr* c : consequences) {
expr* a = nullptr, *b = nullptr, *u = nullptr, *v = nullptr;
func_decl* f;
rational num;
unsigned bvsize;
VERIFY(m.is_implies(c, a, b));
if (m.is_eq(b, u, v) && is_uninterp_const(u) && m_rewriter.bv2enum().find(to_app(u)->get_decl(), f) && bv.is_numeral(v, num, bvsize)) {
SASSERT(num.is_unsigned());
expr_ref head(m);
ptr_vector<func_decl> const& enums = *dt.get_datatype_constructors(f->get_range());
if (enums.size() > num.get_unsigned()) {
head = m.mk_eq(m.mk_const(f), m.mk_const(enums[num.get_unsigned()]));
consequences[i] = m.mk_implies(a, head);
}
}
++i;
}
return r;
}
void get_levels(ptr_vector<expr> const& vars, unsigned_vector& depth) override {
m_solver->get_levels(vars, depth);
}
expr_ref_vector get_trail() override {
return m_solver->get_trail();
}
unsigned get_num_assertions() const override {
return m_solver->get_num_assertions();
}
expr * get_assertion(unsigned idx) const override {
return m_solver->get_assertion(idx);
}
};
solver * mk_enum2bv_solver(ast_manager & m, params_ref const & p, solver* s) {
return alloc(enum2bv_solver, m, p, s);
}