/* Copyright (c) 2013 Microsoft Corporation. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Author: Soonho Kong */ #include #include "util/trace.h" #include "kernel/expr.h" #include "kernel/context.h" #include "library/all/all.h" #include "library/arith/nat.h" #include "library/arith/arith.h" #include "library/rewriter/fo_match.h" #include "library/rewriter/rewriter.h" #include "library/printer.h" using std::cout; using std::endl; namespace lean { std::ostream & operator<<(std::ostream & out, subst_map & s) { out << "{"; for (auto it = s.begin(); it != s.end(); it++) { out << it->first << " => "; out << it->second << "; "; } out << "}"; return out; } bool fo_match::match_var(expr const & p, expr const & t, unsigned o, subst_map & s) { lean_trace("fo_match", tout << "match_var : (" << p << ", " << t << ", " << o << ", " << s << ")" << endl;); unsigned idx = var_idx(p); if (idx < o) { // Current variable is the one created by lambda inside of pattern // and it is *not* a target of pattern matching. return p == t; } else { auto it = s.find(idx); if (it != s.end()) { // This variable already has an entry in the substitution // map. We need to make sure that 't' and s[idx] are the // same lean_trace("fo_match", tout << "match_var exist:" << idx << " |-> " << it->second << endl;); return it->second == t; } // This variable has no entry in the substituition map. Let's // add one. s.insert(std::make_pair(idx, t)); lean_trace("fo_match", tout << "match_var MATCHED : " << s << endl;); return true; } } bool fo_match::match_constant(expr const & p, expr const & t, unsigned, subst_map &) { lean_trace("fo_match", tout << "match_constant : (" << p << ", " << t << ")" << endl;); return p == t; } bool fo_match::match_value(expr const & p, expr const & t, unsigned, subst_map &) { lean_trace("fo_match", tout << "match_value : (" << p << ", " << t << ")" << endl;); return p == t; } bool fo_match::match_app(expr const & p, expr const & t, unsigned o, subst_map & s) { lean_trace("fo_match", tout << "match_app : (" << p << ", " << t << ", " << o << ", " << s << ")" << endl;); if (!is_app(t)) return false; unsigned num_p = num_args(p); unsigned num_t = num_args(t); if (num_p != num_t) { return false; } for (unsigned i = 0; i < num_p; i++) { if (!match(arg(p, i), arg(t, i), o, s)) return false; } return true; } bool fo_match::match_lambda(expr const & p, expr const & t, unsigned o, subst_map & s) { lean_trace("fo_match", tout << "match_lambda : (" << p << ", " << t << ", " << o << ", " << s << ")" << endl;); lean_trace("fo_match", tout << "fun (" << abst_name(p) << " : " << abst_domain(p) << "), " << abst_body(p) << endl;); if (!is_lambda(t)) { return false; } else { // First match the domain part auto p_domain = abst_domain(p); auto t_domain = abst_domain(t); if (!match(p_domain, t_domain, o, s)) return false; // Then match the body part, increase offset by 1. auto p_body = abst_body(p); auto t_body = abst_body(t); return match(p_domain, t_domain, o + 1, s); } } bool fo_match::match_pi(expr const & p, expr const & t, unsigned o, subst_map & s) { lean_trace("fo_match", tout << "match_pi : (" << p << ", " << t << ", " << o << ", " << s << ")" << endl;); lean_trace("fo_match", tout << "Pi (" << abst_name(p) << " : " << abst_domain(p) << "), " << abst_body(p) << endl;); if (!is_pi(t)) { return false; } else { // First match the domain part auto p_domain = abst_domain(p); auto t_domain = abst_domain(t); if (!match(p_domain, t_domain, o, s)) return false; // Then match the body part, increase offset by 1. auto p_body = abst_body(p); auto t_body = abst_body(t); return match(p_domain, t_domain, o + 1, s); } } bool fo_match::match_type(expr const & p, expr const & t, unsigned, subst_map &) { lean_trace("fo_match", tout << "match_type : (" << p << ", " << t << ")" << endl;); return p == t; } bool fo_match::match_eq(expr const & p, expr const & t, unsigned o, subst_map & s) { lean_trace("fo_match", tout << "match_eq : (" << p << ", " << t << ", " << o << ", " << s << ")" << endl;); if (!is_eq(t)) return false; return match(eq_lhs(p), eq_lhs(t), o, s) && match(eq_rhs(p), eq_rhs(t), o, s); } bool fo_match::match_let(expr const & p, expr const & t, unsigned o, subst_map & s) { lean_trace("fo_match", tout << "match_let : (" << p << ", " << t << ", " << o << ", " << s << ")" << endl;); if (!is_let(t)) { return false; } else { // First match the type part auto p_type = let_type(p); auto t_type = let_type(t); if (!match(p_type, t_type, o, s)) return false; // then match the value part auto p_value = let_value(p); auto t_value = let_value(t); if (!match(p_value, t_value, o, s)) return false; // then match the value part auto p_body = let_body(p); auto t_body = let_body(t); return match(p_body, t_body, o + 1, s); } } bool fo_match::match_metavar(expr const & p, expr const & t, unsigned, subst_map &) { lean_trace("fo_match", tout << "match_meta : (" << p << ", " << t << ")" << endl;); return p == t; } bool fo_match::match(expr const & p, expr const & t, unsigned o, subst_map & s) { lean_trace("fo_match", tout << "match : (" << p << ", " << t << ", " << o << ", " << s << ")" << endl;); switch (p.kind()) { case expr_kind::Var: return match_var(p, t, o, s); case expr_kind::Constant: return match_constant(p, t, o, s); case expr_kind::Value: return match_value(p, t, o, s); case expr_kind::App: return match_app(p, t, o, s); case expr_kind::Lambda: return match_lambda(p, t, o, s); case expr_kind::Pi: return match_pi(p, t, o, s); case expr_kind::Type: return match_type(p, t, o, s); case expr_kind::Eq: return match_eq(p, t, o, s); case expr_kind::Let: return match_let(p, t, o, s); case expr_kind::MetaVar: return match_metavar(p, t, o, s); } lean_unreachable(); } }