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https://github.com/Z3Prover/z3
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329 lines
11 KiB
C++
329 lines
11 KiB
C++
/*++
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Copyright (c) 2013 Microsoft Corporation
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Module Name:
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aig_exporter.cpp
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Abstract:
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Export AIG files from horn clauses
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--*/
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#include "aig_exporter.h"
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#include "dl_context.h"
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#include <set>
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namespace datalog {
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aig_exporter::aig_exporter(const rule_set& rules, context& ctx, const fact_vector *facts) :
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m_rules(rules), m_facts(facts), m(ctx.get_manager()), m_rm(ctx.get_rule_manager()),
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m_aigm(m), m_next_decl_id(1), m_next_aig_expr_id(2), m_num_and_gates(0),
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m_latch_vars(m), m_latch_varsp(m), m_ruleid_var_set(m), m_ruleid_varp_set(m)
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{
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std::set<func_decl*> predicates;
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for (rule_set::decl2rules::iterator I = m_rules.begin_grouped_rules(),
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E = m_rules.end_grouped_rules(); I != E; ++I) {
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predicates.insert(I->m_key);
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}
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for (fact_vector::const_iterator I = facts->begin(), E = facts->end(); I != E; ++I) {
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predicates.insert(I->first);
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}
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// reserve pred id = 0 for initalization purposes
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unsigned num_preds = (unsigned)predicates.size() + 1;
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// poor's man round-up log2
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unsigned preds_bitsize = log2(num_preds);
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if ((1U << preds_bitsize) < num_preds)
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++preds_bitsize;
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SASSERT((1U << preds_bitsize) >= num_preds);
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for (unsigned i = 0; i < preds_bitsize; ++i) {
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m_ruleid_var_set.push_back(m.mk_fresh_const("rule_id", m.mk_bool_sort()));
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m_ruleid_varp_set.push_back(m.mk_fresh_const("rule_id_p", m.mk_bool_sort()));
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}
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}
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void aig_exporter::mk_latch_vars(unsigned n) {
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for (unsigned i = m_latch_vars.size(); i <= n; ++i) {
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m_latch_vars.push_back(m.mk_fresh_const("latch_var", m.mk_bool_sort()));
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m_latch_varsp.push_back(m.mk_fresh_const("latch_varp", m.mk_bool_sort()));
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}
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SASSERT(m_latch_vars.size() > n);
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}
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expr* aig_exporter::get_latch_var(unsigned i, const expr_ref_vector& vars) {
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mk_latch_vars(i);
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return vars.get(i);
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}
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void aig_exporter::assert_pred_id(func_decl *decl, const expr_ref_vector& vars, expr_ref_vector& exprs) {
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unsigned id = 0;
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if (decl && !m_decl_id_map.find(decl, id)) {
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id = m_next_decl_id++;
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SASSERT(id < (1U << vars.size()));
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m_decl_id_map.insert(decl, id);
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}
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for (unsigned i = 0; i < vars.size(); ++i) {
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exprs.push_back((id & (1U << i)) ? vars[i] : m.mk_not(vars[i]));
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}
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}
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void aig_exporter::collect_var_substs(substitution& subst, const app *h,
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const expr_ref_vector& vars, expr_ref_vector& eqs) {
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for (unsigned i = 0; i < h->get_num_args(); ++i) {
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expr *arg = h->get_arg(i);
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expr *latchvar = get_latch_var(i, vars);
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if (is_var(arg)) {
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var *v = to_var(arg);
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expr_offset othervar;
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if (subst.find(v, 0, othervar)) {
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eqs.push_back(m.mk_eq(latchvar, othervar.get_expr()));
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} else {
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subst.insert(v, 0, expr_offset(latchvar, 0));
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}
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} else {
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eqs.push_back(m.mk_eq(latchvar, arg));
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}
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}
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}
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void aig_exporter::operator()(std::ostream& out) {
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expr_ref_vector transition_function(m), output_preds(m);
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var_ref_vector input_vars(m);
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rule_counter& vc = m_rm.get_counter();
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expr_ref_vector exprs(m);
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substitution subst(m);
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for (rule_set::decl2rules::iterator I = m_rules.begin_grouped_rules(),
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E = m_rules.end_grouped_rules(); I != E; ++I) {
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for (rule_vector::iterator II = I->get_value()->begin(),
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EE = I->get_value()->end(); II != EE; ++II) {
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rule *r = *II;
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unsigned numqs = r->get_positive_tail_size();
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if (numqs > 1) {
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std::cerr << "non-linear clauses not supported\n";
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exit(-1);
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}
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if (numqs != r->get_uninterpreted_tail_size()) {
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std::cerr << "negation of queries not supported\n";
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exit(-1);
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}
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exprs.reset();
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assert_pred_id(numqs ? r->get_tail(0)->get_decl() : 0, m_ruleid_var_set, exprs);
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assert_pred_id(r->get_head()->get_decl(), m_ruleid_varp_set, exprs);
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subst.reset();
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subst.reserve(1, vc.get_max_rule_var(*r)+1);
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if (numqs)
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collect_var_substs(subst, r->get_tail(0), m_latch_vars, exprs);
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collect_var_substs(subst, r->get_head(), m_latch_varsp, exprs);
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for (unsigned i = numqs; i < r->get_tail_size(); ++i) {
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expr_ref e(m);
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subst.apply(r->get_tail(i), e);
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exprs.push_back(e);
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}
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transition_function.push_back(m.mk_and(exprs.size(), exprs.c_ptr()));
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}
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}
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// collect table facts
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if (m_facts) {
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for (fact_vector::const_iterator I = m_facts->begin(), E = m_facts->end(); I != E; ++I) {
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exprs.reset();
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assert_pred_id(0, m_ruleid_var_set, exprs);
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assert_pred_id(I->first, m_ruleid_varp_set, exprs);
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for (unsigned i = 0; i < I->second.size(); ++i) {
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exprs.push_back(m.mk_eq(get_latch_var(i, m_latch_varsp), I->second[i]));
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}
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transition_function.push_back(m.mk_and(exprs.size(), exprs.c_ptr()));
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}
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}
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expr *tr = m.mk_or(transition_function.size(), transition_function.c_ptr());
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aig_ref aig = m_aigm.mk_aig(tr);
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expr_ref aig_expr(m);
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m_aigm.to_formula(aig, aig_expr);
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#if 0
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std::cout << mk_pp(tr, m) << "\n\n";
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std::cout << mk_pp(aig_expr, m) << "\n\n";
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#endif
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// make rule_id vars latches
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for (unsigned i = 0; i < m_ruleid_var_set.size(); ++i) {
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m_latch_vars.push_back(m_ruleid_var_set.get(i));
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m_latch_varsp.push_back(m_ruleid_varp_set.get(i));
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}
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// create vars for latches
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for (unsigned i = 0; i < m_latch_vars.size(); ++i) {
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mk_var(m_latch_vars.get(i));
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mk_input_var(m_latch_varsp.get(i));
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}
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unsigned tr_id = expr_to_aig(aig_expr);
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// create latch next state variables: (ite tr varp var)
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unsigned_vector latch_varp_ids;
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for (unsigned i = 0; i < m_latch_vars.size(); ++i) {
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unsigned in_val = mk_and(tr_id, get_var(m_latch_varsp.get(i)));
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unsigned latch_val = mk_and(neg(tr_id), get_var(m_latch_vars.get(i)));
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latch_varp_ids.push_back(mk_or(in_val, latch_val));
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}
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m_latch_varsp.reset();
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// create output variable (true iff an output predicate is derivable)
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unsigned output_id = 0;
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{
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expr_ref_vector output(m);
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const func_decl_set& preds = m_rules.get_output_predicates();
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for (func_decl_set::iterator I = preds.begin(), E = preds.end(); I != E; ++I) {
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exprs.reset();
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assert_pred_id(*I, m_ruleid_var_set, exprs);
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output.push_back(m.mk_and(exprs.size(), exprs.c_ptr()));
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}
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expr *out = m.mk_or(output.size(), output.c_ptr());
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aig = m_aigm.mk_aig(out);
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m_aigm.to_formula(aig, aig_expr);
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output_id = expr_to_aig(aig_expr);
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#if 0
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std::cout << "output formula\n";
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std::cout << mk_pp(out, m) << "\n\n";
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std::cout << mk_pp(aig_expr, m) << "\n\n";
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#endif
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}
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// 1) print header
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// aag var_index inputs latches outputs andgates
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out << "aag " << (m_next_aig_expr_id-1)/2 << ' ' << m_input_vars.size()
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<< ' ' << m_latch_vars.size() << " 1 " << m_num_and_gates << '\n';
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// 2) print inputs
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for (unsigned i = 0; i < m_input_vars.size(); ++i) {
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out << m_input_vars[i] << '\n';
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}
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// 3) print latches
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for (unsigned i = 0; i < m_latch_vars.size(); ++i) {
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out << get_var(m_latch_vars.get(i)) << ' ' << latch_varp_ids[i] << '\n';
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}
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// 4) print outputs (just one for now)
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out << output_id << '\n';
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// 5) print formula
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out << m_buffer.str();
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}
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unsigned aig_exporter::expr_to_aig(const expr *e) {
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unsigned id;
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if (m_aig_expr_id_map.find(e, id))
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return id;
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if (is_uninterp_const(e))
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return get_var(e);
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switch (e->get_kind()) {
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case AST_APP: {
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const app *a = to_app(e);
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switch (a->get_decl_kind()) {
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case OP_OR:
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SASSERT(a->get_num_args() > 0);
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id = expr_to_aig(a->get_arg(0));
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for (unsigned i = 1; i < a->get_num_args(); ++i) {
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id = mk_or(id, expr_to_aig(a->get_arg(i)));
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}
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m_aig_expr_id_map.insert(e, id);
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return id;
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case OP_NOT:
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return neg(expr_to_aig(a->get_arg(0)));
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case OP_FALSE:
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return 0;
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case OP_TRUE:
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return 1;
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}
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break;}
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case AST_VAR:
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return get_var(e);
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default:
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UNREACHABLE();
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}
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UNREACHABLE();
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return 0;
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}
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unsigned aig_exporter::neg(unsigned id) const {
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return (id % 2) ? (id-1) : (id+1);
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}
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unsigned aig_exporter::mk_and(unsigned id1, unsigned id2) {
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if (id1 > id2)
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std::swap(id1, id2);
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std::pair<unsigned,unsigned> key(id1, id2);
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and_gates_map::const_iterator I = m_and_gates_map.find(key);
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if (I != m_and_gates_map.end())
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return I->second;
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unsigned id = mk_expr_id();
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m_buffer << id << ' ' << id1 << ' ' << id2 << '\n';
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m_and_gates_map[key] = id;
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++m_num_and_gates;
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return id;
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}
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unsigned aig_exporter::mk_or(unsigned id1, unsigned id2) {
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return neg(mk_and(neg(id1), neg(id2)));
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}
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unsigned aig_exporter::get_var(const expr *e) {
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unsigned id;
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if (m_aig_expr_id_map.find(e, id))
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return id;
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return mk_input_var(e);
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}
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unsigned aig_exporter::mk_var(const expr *e) {
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SASSERT(!m_aig_expr_id_map.contains(e));
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unsigned id = mk_expr_id();
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m_aig_expr_id_map.insert(e, id);
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return id;
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}
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unsigned aig_exporter::mk_input_var(const expr *e) {
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SASSERT(!m_aig_expr_id_map.contains(e));
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unsigned id = mk_expr_id();
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m_input_vars.push_back(id);
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if (e)
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m_aig_expr_id_map.insert(e, id);
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return id;
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}
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unsigned aig_exporter::mk_expr_id() {
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unsigned id = m_next_aig_expr_id;
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m_next_aig_expr_id += 2;
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return id;
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}
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}
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