/*++ Copyright (c) 2016 Microsoft Corporation Module Name: enum2bv_rewriter.cpp Abstract: Conversion from enumeration types to bit-vectors. Author: Nikolaj Bjorner (nbjorner) 2016-10-18 Notes: --*/ #include"rewriter.h" #include"rewriter_def.h" #include"enum2bv_rewriter.h" #include"ast_util.h" #include"ast_pp.h" struct enum2bv_rewriter::imp { ast_manager& m; params_ref m_params; obj_map m_enum2bv; obj_map m_bv2enum; obj_map m_enum2def; expr_ref_vector m_bounds; datatype_util m_dt; func_decl_ref_vector m_enum_consts; func_decl_ref_vector m_enum_bvs; expr_ref_vector m_enum_defs; unsigned_vector m_enum_consts_lim; unsigned m_num_translated; i_sort_pred* m_sort_pred; struct rw_cfg : public default_rewriter_cfg { imp& m_imp; ast_manager& m; datatype_util m_dt; bv_util m_bv; rw_cfg(imp& i, ast_manager & m) : m_imp(i), m(m), m_dt(m), m_bv(m) {} br_status reduce_app(func_decl * f, unsigned num, expr * const * args, expr_ref & result, proof_ref & result_pr) { expr_ref a0(m), a1(m); expr_ref_vector _args(m); if (m.is_eq(f) && reduce_arg(args[0], a0) && reduce_arg(args[1], a1)) { result = m.mk_eq(a0, a1); return BR_DONE; } else if (m.is_distinct(f) && reduce_args(num, args, _args)) { result = m.mk_distinct(_args.size(), _args.c_ptr()); return BR_DONE; } else if (m_dt.is_recognizer(f) && reduce_arg(args[0], a0)) { unsigned idx = m_dt.get_recognizer_constructor_idx(f); a1 = m_bv.mk_numeral(rational(idx), get_sort(a0)); result = m.mk_eq(a0, a1); return BR_DONE; } else { check_for_fd(num, args); return BR_FAILED; } } bool reduce_args(unsigned sz, expr*const* as, expr_ref_vector& result) { expr_ref tmp(m); for (unsigned i = 0; i < sz; ++i) { if (!reduce_arg(as[i], tmp)) return false; result.push_back(tmp); } return true; } void throw_non_fd(expr* e) { std::stringstream strm; strm << "unable to handle nested data-type expression " << mk_pp(e, m); throw rewriter_exception(strm.str().c_str()); } void check_for_fd(unsigned n, expr* const* args) { for (unsigned i = 0; i < n; ++i) { if (m_imp.is_fd(get_sort(args[i]))) { throw_non_fd(args[i]); } } } bool reduce_arg(expr* a, expr_ref& result) { sort* s = get_sort(a); if (!m_imp.is_fd(s)) { return false; } unsigned bv_size = get_bv_size(s); if (is_var(a)) { result = m.mk_var(to_var(a)->get_idx(), m_bv.mk_sort(bv_size)); return true; } SASSERT(is_app(a)); func_decl* f = to_app(a)->get_decl(); if (m_dt.is_constructor(f)) { unsigned idx = m_dt.get_constructor_idx(f); result = m_bv.mk_numeral(idx, bv_size); } else if (is_uninterp_const(a)) { func_decl* f_fresh; if (m_imp.m_enum2bv.find(f, f_fresh)) { result = m.mk_const(f_fresh); return true; } // create a fresh variable, add bounds constraints for it. unsigned nc = m_dt.get_datatype_num_constructors(s); result = m.mk_fresh_const(f->get_name().str().c_str(), m_bv.mk_sort(bv_size)); f_fresh = to_app(result)->get_decl(); if (!is_power_of_two(nc) || nc == 1) { m_imp.m_bounds.push_back(m_bv.mk_ule(result, m_bv.mk_numeral(nc-1, bv_size))); } expr_ref f_def(m); ptr_vector const& cs = *m_dt.get_datatype_constructors(s); f_def = m.mk_const(cs[nc-1]); for (unsigned i = nc - 1; i > 0; ) { --i; f_def = m.mk_ite(m.mk_eq(result, m_bv.mk_numeral(i,bv_size)), m.mk_const(cs[i]), f_def); } m_imp.m_enum2def.insert(f, f_def); m_imp.m_enum2bv.insert(f, f_fresh); m_imp.m_bv2enum.insert(f_fresh, f); m_imp.m_enum_consts.push_back(f); m_imp.m_enum_bvs.push_back(f_fresh); m_imp.m_enum_defs.push_back(f_def); } else { throw_non_fd(a); } ++m_imp.m_num_translated; return true; } ptr_buffer m_sorts; bool reduce_quantifier( quantifier * q, expr * old_body, expr * const * new_patterns, expr * const * new_no_patterns, expr_ref & result, proof_ref & result_pr) { m_sorts.reset(); expr_ref_vector bounds(m); bool found = false; for (unsigned i = 0; i < q->get_num_decls(); ++i) { sort* s = q->get_decl_sort(i); if (m_imp.is_fd(s)) { unsigned bv_size = get_bv_size(s); m_sorts.push_back(m_bv.mk_sort(bv_size)); unsigned nc = m_dt.get_datatype_num_constructors(s); if (!is_power_of_two(nc) || nc == 1) { bounds.push_back(m_bv.mk_ule(m.mk_var(q->get_num_decls()-i-1, m_sorts[i]), m_bv.mk_numeral(nc-1, bv_size))); } found = true; } else { m_sorts.push_back(s); } } if (!found) { return false; } expr_ref new_body_ref(old_body, m), tmp(m); if (!bounds.empty()) { if (q->is_forall()) { new_body_ref = m.mk_implies(mk_and(bounds), new_body_ref); } else { bounds.push_back(new_body_ref); new_body_ref = mk_and(bounds); } } result = m.mk_quantifier(q->is_forall(), q->get_num_decls(), m_sorts.c_ptr(), q->get_decl_names(), new_body_ref, q->get_weight(), q->get_qid(), q->get_skid(), q->get_num_patterns(), new_patterns, q->get_num_no_patterns(), new_no_patterns); result_pr = 0; return true; } unsigned get_bv_size(sort* s) { unsigned nc = m_dt.get_datatype_num_constructors(s); unsigned bv_size = 1; while ((unsigned)(1 << bv_size) < nc) { ++bv_size; } return bv_size; } }; struct rw : public rewriter_tpl { rw_cfg m_cfg; rw(imp& t, ast_manager & m, params_ref const & p) : rewriter_tpl(m, m.proofs_enabled(), m_cfg), m_cfg(t, m) { } }; rw m_rw; imp(ast_manager& m, params_ref const& p): m(m), m_params(p), m_bounds(m), m_dt(m), m_enum_consts(m), m_enum_bvs(m), m_enum_defs(m), m_num_translated(0), m_sort_pred(0), m_rw(*this, m, p) { } void updt_params(params_ref const & p) {} unsigned get_num_steps() const { return m_rw.get_num_steps(); } void cleanup() { m_rw.cleanup(); } void operator()(expr * e, expr_ref & result, proof_ref & result_proof) { m_rw(e, result, result_proof); } void push() { m_enum_consts_lim.push_back(m_enum_consts.size()); } void pop(unsigned num_scopes) { SASSERT(m_bounds.empty()); // bounds must be flushed before pop. if (num_scopes > 0) { SASSERT(num_scopes <= m_enum_consts_lim.size()); unsigned new_sz = m_enum_consts_lim.size() - num_scopes; unsigned lim = m_enum_consts_lim[new_sz]; for (unsigned i = m_enum_consts.size(); i > lim; ) { --i; func_decl* f = m_enum_consts[i].get(); func_decl* f_fresh = m_enum2bv.find(f); m_bv2enum.erase(f_fresh); m_enum2bv.erase(f); m_enum2def.erase(f); } m_enum_consts_lim.resize(new_sz); m_enum_consts.resize(lim); m_enum_defs.resize(lim); m_enum_bvs.resize(lim); } m_rw.reset(); } void flush_side_constraints(expr_ref_vector& side_constraints) { side_constraints.append(m_bounds); m_bounds.reset(); } bool is_fd(sort* s) { return m_dt.is_enum_sort(s) && (!m_sort_pred || (*m_sort_pred)(s)); } void set_is_fd(i_sort_pred* sp) { m_sort_pred = sp; } }; enum2bv_rewriter::enum2bv_rewriter(ast_manager & m, params_ref const& p) { m_imp = alloc(imp, m, p); } enum2bv_rewriter::~enum2bv_rewriter() { dealloc(m_imp); } void enum2bv_rewriter::updt_params(params_ref const & p) { m_imp->updt_params(p); } ast_manager & enum2bv_rewriter::m() const { return m_imp->m; } unsigned enum2bv_rewriter::get_num_steps() const { return m_imp->get_num_steps(); } void enum2bv_rewriter::cleanup() { ast_manager& mgr = m(); params_ref p = m_imp->m_params; dealloc(m_imp); m_imp = alloc(imp, mgr, p); } obj_map const& enum2bv_rewriter::enum2bv() const { return m_imp->m_enum2bv; } obj_map const& enum2bv_rewriter::bv2enum() const { return m_imp->m_bv2enum; } obj_map const& enum2bv_rewriter::enum2def() const { return m_imp->m_enum2def; } void enum2bv_rewriter::operator()(expr * e, expr_ref & result, proof_ref & result_proof) { (*m_imp)(e, result, result_proof); } void enum2bv_rewriter::push() { m_imp->push(); } void enum2bv_rewriter::pop(unsigned num_scopes) { m_imp->pop(num_scopes); } void enum2bv_rewriter::flush_side_constraints(expr_ref_vector& side_constraints) { m_imp->flush_side_constraints(side_constraints); } unsigned enum2bv_rewriter::num_translated() const { return m_imp->m_num_translated; } void enum2bv_rewriter::set_is_fd(i_sort_pred* sp) const { m_imp->set_is_fd(sp); }