/* Copyright (c) 2013 Microsoft Corporation. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Author: Leonardo de Moura */ #include "kernel/kernel.h" #include "library/placeholder.h" #include "library/io_state_stream.h" #include "frontends/lean/parser_calc.h" #include "frontends/lean/parser_imp.h" #include "frontends/lean/operator_info.h" #include "frontends/lean/frontend.h" namespace lean { bool calc_proof_parser::supports(expr const & op1) const { return std::find_if(m_supported_operators.begin(), m_supported_operators.end(), [&](op_data const & op2) { return op1 == op2.m_fn; }) != m_supported_operators.end(); } void calc_proof_parser::add_supported_operator(op_data const & op1) { if (supports(op1.m_fn)) throw exception("operator already supported in the calculational proof manager"); m_supported_operators = cons(op1, m_supported_operators); } optional calc_proof_parser::find_trans_data(expr const & op1, expr const & op2) const { auto it = std::find_if(m_trans_ops.begin(), m_trans_ops.end(), [&](std::tuple const & entry) { return std::get<0>(entry) == op1 && std::get<1>(entry) == op2; }); if (it == m_trans_ops.end()) return optional(); else return optional(std::get<2>(*it)); } void calc_proof_parser::add_trans_step(expr const & op1, expr const & op2, trans_data const & d) { if (!supports(op1) || !supports(op2) || !supports(d.m_rop)) throw exception("invalid transitivity step in calculational proof manager, operator not supported"); if (find_trans_data(op1, op2)) throw exception("transitivity step is already supported in the calculational proof manager"); if (d.m_num_args < 5) throw exception("transitivity step must have at least 5 arguments"); m_trans_ops.emplace_front(op1, op2, d); } calc_proof_parser::calc_proof_parser() { expr imp = mk_implies_fn(); expr eq = mk_eq_fn(); expr neq = mk_neq_fn(); add_supported_operator(op_data(imp, 2)); add_supported_operator(op_data(eq, 3)); add_supported_operator(op_data(neq, 3)); add_trans_step(eq, eq, trans_data(mk_trans_fn(), 6, eq)); add_trans_step(eq, imp, trans_data(mk_eq_imp_trans_fn(), 5, imp)); add_trans_step(imp, eq, trans_data(mk_imp_eq_trans_fn(), 5, imp)); add_trans_step(imp, imp, trans_data(mk_imp_trans_fn(), 5, imp)); add_trans_step(eq, neq, trans_data(mk_eq_ne_trans_fn(), 6, neq)); add_trans_step(neq, eq, trans_data(mk_ne_eq_trans_fn(), 6, neq)); } optional calc_proof_parser::find_op(operator_info const & op, pos_info const & p) const { if (!op) return none_expr(); for (auto d : op.get_denotations()) { // TODO(Leo): I'm ignoring overloading. if (supports(d)) return some_expr(d); } throw parser_error("invalid calculational proof, operator is not supported", p); return none_expr(); } expr calc_proof_parser::parse_op(parser_imp & imp) const { environment const & env = imp.get_environment(); auto p = imp.pos(); name id = imp.check_identifier_next("invalid calculational proof, identifier expected"); if (auto r = find_op(find_led(env, id), p)) return *r; if (auto r = find_op(find_nud(env, id), p)) return *r; expr e = imp.get_name_ref(id, p, false /* do not process implicit args */); if (!supports(e)) throw parser_error("invalid calculational proof, operator is not supported", p); return e; } static expr parse_step_pr(parser_imp & imp, expr const & lhs) { auto p = imp.pos(); imp.check_colon_next("invalid calculational proof, ':' expected"); if (imp.curr_is_lcurly()) { imp.next(); expr eq_pr = imp.parse_expr(); imp.check_rcurly_next("invalid calculational proof, '}' expected"); // Using axiom Subst {A : TypeU} {a b : A} {P : A → Bool} (H1 : P a) (H2 : a == b) : P b. return imp.save(mk_subst_th(imp.save(mk_placeholder(), p), imp.save(mk_placeholder(), p), imp.save(mk_placeholder(), p), imp.save(mk_placeholder(), p), // let elaborator compute the first four arguments imp.save(mk_refl_th(imp.save(mk_placeholder(), p), lhs), p), eq_pr), p); } else { return imp.parse_expr(); } } /** \brief Parse calc expr op expr : proof1 ... op expr : proof2 ... op expr : proofn */ expr calc_proof_parser::parse(parser_imp & imp) const { auto p = imp.pos(); expr first = imp.parse_expr(); if (!is_app(first)) throw parser_error("invalid calculational proof, first expression must be an application", p); expr op = arg(first, 0); if (!supports(op)) throw parser_error("invalid calculational proof, first expression is not an application of a supported operator", p); if (num_args(first) < 3) throw parser_error("invalid calculational proof, first expression must be an application of a binary operator (modulo implicit arguments)", p); unsigned num = num_args(first); expr lhs = arg(first, num - 2); expr rhs = arg(first, num - 1); expr result = parse_step_pr(imp, lhs); while (imp.curr() == scanner::token::Ellipsis) { imp.next(); p = imp.pos(); expr new_op = parse_op(imp); auto tdata = find_trans_data(op, new_op); if (!tdata) throw parser_error("invalid calculational proof, operators cannot be combined", p); expr new_rhs = imp.parse_expr(); expr step_pr = parse_step_pr(imp, rhs); buffer args; args.push_back(tdata->m_fn); for (unsigned i = 0; i < tdata->m_num_args - 5; i++) { // transitivity step has implicit arguments args.push_back(imp.save(mk_placeholder(), p)); } args.push_back(lhs); args.push_back(rhs); args.push_back(new_rhs); args.push_back(result); args.push_back(step_pr); result = imp.save(mk_app(args), p); op = tdata->m_rop; rhs = new_rhs; } return result; } }