rule_set * mk_coalesce::operator()(rule_set const & source, model_converter_ref& mc, proof_converter_ref& pc) {
m_pc = 0;
ref<replace_proof_converter> rpc;
if (pc) {
rpc = alloc(replace_proof_converter, m);
m_pc = rpc.get();
}
rule_set* rules = alloc(rule_set, m_ctx);
rule_set::decl2rules::iterator it = source.begin_grouped_rules(), end = source.end_grouped_rules();
for (; it != end; ++it) {
rule_ref_vector d_rules(rm);
d_rules.append(it->m_value->size(), it->m_value->c_ptr());
for (unsigned i = 0; i < d_rules.size(); ++i) {
rule_ref r1(d_rules[i].get(), rm);
for (unsigned j = i + 1; j < d_rules.size(); ++j) {
if (same_body(*r1.get(), *d_rules[j].get())) {
merge_rules(r1, *d_rules[j].get());
d_rules[j] = d_rules.back();
d_rules.pop_back();
--j;
}
}
rules->add_rule(r1.get());
}
}
if (pc) {
pc = concat(pc.get(), rpc.get());
}
return rules;
}
void mk_coalesce::merge_rules(rule_ref& tgt, rule const& src) {
SASSERT(same_body(*tgt.get(), src));
m_sub1.reset();
m_sub2.reset();
m_idx = 0;
app_ref pred(m), head(m);
expr_ref fml1(m), fml2(m), fml(m);
app_ref_vector tail(m);
ptr_vector<sort> sorts1, sorts2;
expr_ref_vector conjs1(m), conjs(m);
rule_ref res(rm);
bool_rewriter bwr(m);
svector<bool> is_neg;
tgt->get_vars(sorts1);
src.get_vars(sorts2);
mk_pred(head, src.get_head(), tgt->get_head());
for (unsigned i = 0; i < src.get_uninterpreted_tail_size(); ++i) {
mk_pred(pred, src.get_tail(i), tgt->get_tail(i));
tail.push_back(pred);
is_neg.push_back(src.is_neg_tail(i));
}
extract_conjs(m_sub1, src, fml1);
extract_conjs(m_sub2, *tgt.get(), fml2);
bwr.mk_or(fml1, fml2, fml);
SASSERT(is_app(fml));
tail.push_back(to_app(fml));
is_neg.push_back(false);
res = rm.mk(head, tail.size(), tail.c_ptr(), is_neg.c_ptr(), tgt->name());
if (m_ctx.generate_proof_trace()) {
src.to_formula(fml1);
tgt->to_formula(fml2);
res->to_formula(fml);
#if 0
sort* ps = m.mk_proof_sort();
sort* domain[3] = { ps, ps, m.mk_bool_sort() };
func_decl* merge = m.mk_func_decl(symbol("merge-clauses"), 3, domain, ps); // TBD: ad-hoc proof rule
expr* args[3] = { m.mk_asserted(fml1), m.mk_asserted(fml2), fml };
// ...m_pc->insert(m.mk_app(merge, 3, args));
#else
svector<std::pair<unsigned, unsigned> > pos;
vector<expr_ref_vector> substs;
proof* p = src.get_proof();
p = m.mk_hyper_resolve(1, &p, fml, pos, substs);
res->set_proof(m, p);
#endif
}
tgt = res;
}
rule_set * mk_coalesce::operator()(rule_set const & source) {
rule_set* rules = alloc(rule_set, m_ctx);
rules->inherit_predicates(source);
rule_set::decl2rules::iterator it = source.begin_grouped_rules(), end = source.end_grouped_rules();
for (; it != end; ++it) {
rule_ref_vector d_rules(rm);
d_rules.append(it->m_value->size(), it->m_value->c_ptr());
for (unsigned i = 0; i < d_rules.size(); ++i) {
rule_ref r1(d_rules[i].get(), rm);
for (unsigned j = i + 1; j < d_rules.size(); ++j) {
if (same_body(*r1.get(), *d_rules[j].get())) {
merge_rules(r1, *d_rules[j].get());
d_rules[j] = d_rules.back();
d_rules.pop_back();
--j;
}
}
rules->add_rule(r1.get());
}
}
return rules;
}
