/* 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 #include #include #include "util/sstream.h" #include "util/lean_path.h" #include "util/sexpr/option_declarations.h" #include "kernel/find_fn.h" #include "kernel/kernel_exception.h" #include "kernel/normalizer.h" #include "kernel/type_checker.h" #include "library/placeholder.h" #include "library/io_state_stream.h" #include "frontends/lean/parser_imp.h" #include "frontends/lean/frontend.h" #include "frontends/lean/pp.h" #include "frontends/lean/environment_scope.h" namespace lean { // ========================================== // Builtin commands static name g_alias_kwd("alias"); static name g_definition_kwd("definition"); static name g_variable_kwd("variable"); static name g_variables_kwd("variables"); static name g_theorem_kwd("theorem"); static name g_axiom_kwd("axiom"); static name g_universe_kwd("universe"); static name g_eval_kwd("eval"); static name g_check_kwd("check"); static name g_infix_kwd("infix"); static name g_infixl_kwd("infixl"); static name g_infixr_kwd("infixr"); static name g_notation_kwd("notation"); static name g_set_option_kwd("set_option"); static name g_set_opaque_kwd("set_opaque"); static name g_options_kwd("options"); static name g_env_kwd("environment"); static name g_import_kwd("import"); static name g_help_kwd("help"); static name g_coercion_kwd("coercion"); static name g_exit_kwd("exit"); static name g_print_kwd("print"); static name g_pop_kwd("pop_scope"); static name g_scope_kwd("scope"); static name g_builtin_kwd("builtin"); static name g_namespace_kwd("namespace"); static name g_end_kwd("end"); static name g_using_kwd("using"); /** \brief Table/List with all builtin command keywords */ static list g_command_keywords = {g_definition_kwd, g_variable_kwd, g_variables_kwd, g_theorem_kwd, g_axiom_kwd, g_universe_kwd, g_eval_kwd, g_check_kwd, g_infix_kwd, g_infixl_kwd, g_infixr_kwd, g_notation_kwd, g_set_option_kwd, g_set_opaque_kwd, g_env_kwd, g_options_kwd, g_import_kwd, g_help_kwd, g_coercion_kwd, g_exit_kwd, g_print_kwd, g_pop_kwd, g_scope_kwd, g_alias_kwd, g_builtin_kwd, g_namespace_kwd, g_end_kwd, g_using_kwd}; // ========================================== list const & parser_imp::get_command_keywords() { return g_command_keywords; } /** \brief Register implicit arguments for the definition or postulate named \c n. The fourth element in the tuple parameters is a flag indiciating whether the argument is implicit or not. */ void parser_imp::register_implicit_arguments(name const & n, parameter_buffer & parameters) { bool found = false; buffer imp_args; for (unsigned i = 0; i < parameters.size(); i++) { imp_args.push_back(parameters[i].m_implicit); if (imp_args.back()) found = true; } if (found) mark_implicit_arguments(m_env, n, imp_args.size(), imp_args.data()); } /** \brief Throw an exception if \c e contains a metavariable */ void parser_imp::check_no_metavar(expr const & e, metavar_env const &, char const * msg) { if (has_metavar(e)) throw unsolved_metavar_exception(msg, e); } void parser_imp::check_no_metavar(std::pair const & p, char const * msg) { check_no_metavar(p.first, p.second, msg); } /** \brief Return a fully qualified name (i.e., include current namespace) */ name parser_imp::mk_full_name(name const & n) { return m_namespace_prefixes.back() + n; } /** \brief Auxiliary method used for parsing definitions and theorems. */ void parser_imp::parse_def_core(bool is_definition) { next(); expr pre_type, pre_val; name id = check_identifier_next("invalid definition, identifier expected"); parameter_buffer parameters; if (curr_is_colon()) { next(); pre_type = parse_expr(); if (!is_definition && curr_is_period()) { pre_val = save(mk_placeholder(), pos()); } else { check_assign_next("invalid definition, ':=' expected"); pre_val = parse_expr(); } } else if (is_definition && curr_is_assign()) { auto p = pos(); next(); pre_type = save(mk_placeholder(), p); pre_val = parse_expr(); } else { mk_scope scope(*this); parse_definition_parameters(parameters); expr type_body; if (curr_is_colon()) { next(); type_body = parse_expr(); } else { auto p = pos(); type_body = save(mk_placeholder(), p); } pre_type = mk_abstraction(false, parameters, type_body); if (!is_definition && curr_is_period()) { pre_val = mk_abstraction(true, parameters, mk_placeholder()); } else { check_assign_next("invalid definition, ':=' expected"); expr val_body = parse_expr(); pre_val = mk_abstraction(true, parameters, val_body); } } auto r = m_elaborator(id, pre_type, pre_val); expr type = std::get<0>(r); expr val = std::get<1>(r); metavar_env menv = std::get<2>(r); check_no_metavar(type, menv, "invalid definition, type still contains metavariables after elaboration"); if (has_metavar(val)) { val = apply_tactics(val, menv); } else { check_no_metavar(val, menv, "invalid definition, value still contains metavariables after elaboration"); } lean_assert(!has_metavar(val)); name full_id = mk_full_name(id); if (is_definition) { m_env->add_definition(full_id, type, val); if (m_verbose) regular(m_io_state) << " Defined: " << full_id << endl; } else { m_env->add_theorem(full_id, type, val); if (m_verbose) regular(m_io_state) << " Proved: " << full_id << endl; } register_implicit_arguments(full_id, parameters); } /** \brief Parse a Definition. It has one of the following two forms: 1) 'Definition' ID ':' expr ':=' expr 2) 'Definition' ID parameters ':' expr ':=' expr */ void parser_imp::parse_definition() { parse_def_core(true); } /** \brief Parse a Theorem. It has one of the following two forms: 1) 'Theorem' ID ':' expr ':=' expr 2) 'Theorem' ID parameters ':' expr ':=' expr */ void parser_imp::parse_theorem() { parse_def_core(false); } /** \brief Auxiliary method for parsing Variable and axiom declarations. */ void parser_imp::parse_variable_core(bool is_var) { next(); name id = check_identifier_next("invalid variable/axiom declaration, identifier expected"); parameter_buffer parameters; expr type; if (curr_is_colon()) { next(); auto p = m_elaborator(parse_expr()); check_no_metavar(p, "invalid declaration, type still contains metavariables after elaboration"); type = p.first; } else { mk_scope scope(*this); parse_var_decl_parameters(parameters); check_colon_next("invalid variable/axiom declaration, ':' expected"); expr type_body = parse_expr(); auto p = m_elaborator(mk_abstraction(false, parameters, type_body)); check_no_metavar(p, "invalid declaration, type still contains metavariables after elaboration"); type = p.first; } name full_id = mk_full_name(id); if (is_var) m_env->add_var(full_id, type); else m_env->add_axiom(full_id, type); if (m_verbose) regular(m_io_state) << " Assumed: " << full_id << endl; register_implicit_arguments(full_id, parameters); } /** \brief Parse one of the two forms: 1) 'Variable' ID ':' type 2) 'Variable' ID parameters ':' type */ void parser_imp::parse_variable() { parse_variable_core(true); } /** \brief Parse the form: 'Variables' ID+ ':' type */ void parser_imp::parse_variables() { next(); mk_scope scope(*this); parameter_buffer parameters; parse_simple_parameters(parameters, false, false); for (auto p : parameters) { name full_id = mk_full_name(p.m_name); if (m_env->find_object(full_id)) throw already_declared_exception(m_env, full_id); } for (auto p : parameters) { name full_id = mk_full_name(p.m_name); expr const & type = p.m_type; m_env->add_var(full_id, type); if (m_verbose) regular(m_io_state) << " Assumed: " << full_id << endl; } } /** \brief Parse one of the two forms: 1) 'Axiom' ID ':' type 2) 'Axiom' ID parameters ':' type */ void parser_imp::parse_axiom() { parse_variable_core(false); } /** \brief Parse 'Eval' expr */ void parser_imp::parse_eval() { next(); expr v = m_elaborator(parse_expr()).first; normalizer norm(m_env); expr r = norm(v, context(), true); regular(m_io_state) << r << endl; } /** \brief Return true iff \c obj is an object that should be ignored by the Show command */ bool parser_imp::is_hidden_object(object const & obj) const { return (obj.is_definition() && is_explicit(m_env, obj.get_name())) || !supported_by_pp(obj); } /** \brief Parse 'print' expr 'print' Environment [num] 'print' Environment all 'print' Options 'print' [string] */ void parser_imp::parse_print() { next(); if (curr() == scanner::token::CommandId) { name opt_id = curr_name(); next(); if (opt_id == g_env_kwd) { buffer to_display; bool all = false; unsigned end = m_env->get_num_objects(false); unsigned i; if (curr_is_nat()) { i = parse_unsigned("invalid argument, value does not fit in a machine integer"); } else if (curr_is_identifier() && curr_name() == "all") { next(); i = std::numeric_limits::max(); all = true; } else { i = std::numeric_limits::max(); } unsigned it = end; unsigned num_imports = 0; while (it != 0 && i != 0) { --it; auto obj = m_env->get_object(it, false); if (is_begin_import(obj)) { lean_assert(num_imports > 0); num_imports--; if (num_imports == 0) to_display.push_back(obj); } else if (is_begin_builtin_import(obj)) { lean_assert(num_imports > 0); num_imports--; } else if (is_end_import(obj)) { num_imports++; } else if (is_hidden_object(obj)) { // skip } else if (num_imports == 0 || all) { to_display.push_back(obj); --i; } } std::reverse(to_display.begin(), to_display.end()); for (auto obj : to_display) { if (is_begin_import(obj)) { regular(m_io_state) << "import \"" << *get_imported_module(obj) << "\"" << endl; } else { regular(m_io_state) << obj << endl; } } } else if (opt_id == g_options_kwd) { regular(m_io_state) << pp(m_io_state.get_options()) << endl; } else { throw parser_error("invalid Show command, expression, 'Options' or 'Environment' expected", m_last_cmd_pos); } } else if (curr() == scanner::token::StringVal) { std::string msg = curr_string(); next(); regular(m_io_state) << msg << endl; } else { expr v = m_elaborator(parse_expr()).first; regular(m_io_state) << v << endl; } } /** \brief Parse 'Check' expr */ void parser_imp::parse_check() { next(); auto p = m_elaborator(parse_expr()); check_no_metavar(p, "invalid expression, it still contains metavariables after elaboration"); expr v = p.first; expr t = type_check(v, m_env); formatter fmt = m_io_state.get_formatter(); options opts = m_io_state.get_options(); unsigned indent = get_pp_indent(opts); format r = group(format{fmt(v, opts), space(), colon(), nest(indent, compose(line(), fmt(t, opts)))}); regular(m_io_state) << mk_pair(r, opts) << endl; } /** \brief Return the (optional) precedence of a user-defined operator. */ unsigned parser_imp::parse_precedence() { if (curr_is_nat()) { return parse_unsigned("invalid operator definition, precedence does not fit in a machine integer"); } else { return 0; } } /** \brief Throw an error if the current token is not an identifier. If it is, move to next token. */ name parser_imp::parse_op_id() { return check_identifier_next("invalid operator definition, identifier expected"); } /** \brief Parse prefix/postfix/infix/infixl/infixr user operator definitions. These definitions have the form: - fixity [Num] ID ':' ID */ void parser_imp::parse_op(fixity fx) { next(); unsigned prec = parse_precedence(); name op_id = parse_op_id(); check_colon_next("invalid operator definition, ':' expected"); auto name_pos = pos(); name name_id = check_identifier_next("invalid operator definition, identifier expected"); expr d = get_name_ref(name_id, name_pos, false); switch (fx) { case fixity::Infix: add_infix(m_env, m_io_state, op_id, prec, d); break; case fixity::Infixl: add_infixl(m_env, m_io_state, op_id, prec, d); break; case fixity::Infixr: add_infixr(m_env, m_io_state, op_id, prec, d); break; default: lean_unreachable(); // LCOV_EXCL_LINE } } /** \brief Parse notation declaration unified format 'Notation' [Num] parts ':' ID */ void parser_imp::parse_notation_decl() { auto p = pos(); next(); unsigned prec = parse_precedence(); bool first = true; bool prev_placeholder = false; bool first_placeholder = false; buffer parts; while (true) { if (first) { if (curr_is_placeholder()) { prev_placeholder = true; first_placeholder = true; next(); } else { parts.push_back(check_identifier_next("invalid notation declaration, identifier or '_' expected")); prev_placeholder = false; first_placeholder = false; } first = false; } else { if (curr_is_colon()) { next(); if (parts.size() == 0) { throw parser_error("invalid notation declaration, it must have at least one identifier", p); } auto id_pos = pos(); name name_id = check_identifier_next("invalid notation declaration, identifier expected"); expr d = get_name_ref(name_id, id_pos, false); if (parts.size() == 1) { if (first_placeholder && prev_placeholder) { // infix: _ ID _ add_infix(m_env, m_io_state, parts[0], prec, d); } else if (first_placeholder) { // postfix: _ ID add_postfix(m_env, m_io_state, parts[0], prec, d); } else if (prev_placeholder) { // prefix: ID _ add_prefix(m_env, m_io_state, parts[0], prec, d); } else { throw parser_error("invalid notation declaration, at least one placeholder expected", p); } } else { if (first_placeholder && prev_placeholder) { // mixfixo: _ ID ... ID _ add_mixfixo(m_env, m_io_state, parts.size(), parts.data(), prec, d); } else if (first_placeholder) { // mixfixr: _ ID ... ID add_mixfixr(m_env, m_io_state, parts.size(), parts.data(), prec, d); } else if (prev_placeholder) { // mixfixl: ID _ ... ID _ add_mixfixl(m_env, m_io_state, parts.size(), parts.data(), prec, d); } else { // mixfixc: ID _ ... _ ID add_mixfixc(m_env, m_io_state, parts.size(), parts.data(), prec, d); } } return; } else { if (prev_placeholder) { parts.push_back(check_identifier_next("invalid notation declaration, identifier or ':' expected")); prev_placeholder = false; } else { check_placeholder_next("invalid notation declaration, '_' or ':' expected"); prev_placeholder = true; } } } } } /** Parse 'SetOption' [id] [value] */ void parser_imp::parse_set_option() { next(); auto id_pos = pos(); name id = check_identifier_next("invalid set options, identifier (i.e., option name) expected"); auto decl_it = get_option_declarations().find(id); if (decl_it == get_option_declarations().end()) { // add "lean" prefix name lean_id = name("lean") + id; decl_it = get_option_declarations().find(lean_id); if (decl_it == get_option_declarations().end()) { throw parser_error(sstream() << "unknown option '" << id << "', type 'Help Options.' for list of available options", id_pos); } else { id = lean_id; } } option_kind k = decl_it->second.kind(); switch (curr()) { case scanner::token::Id: if (k != BoolOption) throw parser_error(sstream() << "invalid option value, given option is not Boolean", pos()); if (curr_name() == "true") m_io_state.set_option(id, true); else if (curr_name() == "false") m_io_state.set_option(id, false); else throw parser_error("invalid Boolean option value, 'true' or 'false' expected", pos()); next(); break; case scanner::token::StringVal: if (k != StringOption) throw parser_error("invalid option value, given option is not a string", pos()); m_io_state.set_option(id, curr_string()); next(); break; case scanner::token::IntVal: if (k != IntOption && k != UnsignedOption) throw parser_error("invalid option value, given option is not an integer", pos()); m_io_state.set_option(id, parse_unsigned("invalid option value, value does not fit in a machine integer")); break; case scanner::token::DecimalVal: if (k != DoubleOption) throw parser_error("invalid option value, given option is not floating point value", pos()); m_io_state.set_option(id, parse_double()); break; default: throw parser_error("invalid option value, 'true', 'false', string, integer or decimal value expected", pos()); } updt_options(); if (m_verbose) regular(m_io_state) << " Set: " << id << endl; } /** Parse 'SetOpaque' [id] [true/false] */ void parser_imp::parse_set_opaque() { next(); name id; if (curr() == scanner::token::Exists) { id = "exists"; } else { check_identifier("invalid set opaque, identifier expected"); id = curr_name(); } next(); name full_id = mk_full_name(id); auto val_pos = pos(); name val = check_identifier_next("invalid opaque flag, true/false expected"); if (val == "true") m_env->set_opaque(full_id, true); else if (val == "false") m_env->set_opaque(full_id, false); else throw parser_error("invalid opaque flag, true/false expected", val_pos); } optional parser_imp::find_lua_file(std::string const & fname) { try { return some(find_file(fname, {".lua"})); } catch (...) { return optional(); } } void parser_imp::parse_import() { next(); std::string fname; if (curr_is_identifier()) { fname = name_to_file(curr_name()); next(); } else { fname = check_string_next("invalid import command, string (i.e., file name) or identifier expected"); } bool r = false; if (auto lua_fname = find_lua_file(fname)) { if (!m_script_state) throw parser_error(sstream() << "failed to import Lua file '" << *lua_fname << "', parser does not have an intepreter", m_last_cmd_pos); r = m_script_state->import_explicit(lua_fname->c_str()); } else { r = m_env->import(fname, m_io_state); } if (m_verbose && r) { regular(m_io_state) << " Imported '" << fname << "'" << endl; } } void parser_imp::parse_help() { next(); if (curr() == scanner::token::CommandId) { name opt_id = curr_name(); next(); if (opt_id == g_options_kwd) { regular(m_io_state) << "Available options:" << endl; for (auto p : get_option_declarations()) { auto opt = p.second; regular(m_io_state) << " " << opt.get_name() << " (" << opt.kind() << ") " << opt.get_description() << " (default: " << opt.get_default_value() << ")" << endl; } } else { throw parser_error("invalid help command", m_last_cmd_pos); } } else { regular(m_io_state) << "Available commands:" << endl << " alias [id] : [expr] define an alias for the given expression" << endl << " axiom [id] : [type] assert/postulate a new axiom" << endl << " check [expr] type check the given expression" << endl << " definition [id] : [type] := [expr] define a new element" << endl << " end end the current scope/namespace" << endl << " eval [expr] evaluate the given expression" << endl << " exit exit" << endl << " help display this message" << endl << " help options display available options" << endl << " help notation describe commands for defining infix, mixfix, postfix operators" << endl << " import [string] load the given file" << endl << " pop::scope discard the current scope" << endl << " print [expr] pretty print the given expression" << endl << " print Options print current the set of assigned options" << endl << " print [string] print the given string" << endl << " print Environment print objects in the environment, if [Num] provided, then show only the last [Num] objects" << endl << " print Environment [num] show the last num objects in the environment" << endl << " scope create a scope" << endl << " set::option [id] [value] set option [id] with value [value]" << endl << " set::opaque [id] [bool] set the given definition as opaque/transparent" << endl << " theorem [id] : [type] := [expr] define a new theorem" << endl << " variable [id] : [type] declare/postulate an element of the given type" << endl << " universe [id] >= [level] declare a new universe constraint" << endl << " using [id]_1 [id]_2? create an alias for object starting with the prefix [id]_1 using the [id]_2" << endl; #if !defined(LEAN_WINDOWS) regular(m_io_state) << "Type Ctrl-D to exit" << endl; #endif } } /** \brief Parse 'Coercion' expr */ void parser_imp::parse_coercion() { next(); expr coercion = parse_expr(); add_coercion(m_env, coercion); if (m_verbose) regular(m_io_state) << " Coercion " << coercion << endl; } void parser_imp::reset_env(environment env) { m_env = env; m_elaborator.reset(env); m_io_state.set_formatter(mk_pp_formatter(env)); } void parser_imp::parse_cmd_macro(name cmd_id, pos_info const & p) { lean_assert(m_cmd_macros && m_cmd_macros->find(cmd_id) != m_cmd_macros->end()); next(); auto m = m_cmd_macros->find(cmd_id)->second; macro_arg_stack args; parse_macro(m.m_arg_kinds, m.m_fn, m.m_precedence, args, p); } static name g_geq_unicode("\u2265"); // ≥ static name g_geq(">="); void parser_imp::parse_universe() { next(); name id = check_identifier_next("invalid universe constraint, identifier expected"); if (curr_is_identifier()) { name geq = check_identifier_next("invalid universe constraint, '>=' expected"); if (geq != g_geq && geq != g_geq_unicode) throw parser_error("invalid universe constraint, '>=' expected", m_last_cmd_pos); level lvl = parse_level(); m_env->add_uvar_cnstr(id, lvl); } else { m_env->add_uvar_cnstr(id); } } void parser_imp::parse_alias() { next(); name id = check_identifier_next("invalid alias declaration, identifier expected"); check_colon_next("invalid alias declaration, ':' expected"); expr e = parse_expr(); add_alias(m_env, id, e); } void parser_imp::parse_builtin() { next(); auto id_pos = pos(); name id = check_identifier_next("invalid builtin declaration, identifier expected"); name full_id = mk_full_name(id); auto d = get_builtin(full_id); if (!d) throw parser_error(sstream() << "unknown builtin '" << full_id << "'", id_pos); expr b = d->first; if (d->second) { m_env->add_builtin_set(b); return; } parameter_buffer parameters; expr type; if (curr_is_colon()) { next(); auto p = m_elaborator(parse_expr()); check_no_metavar(p, "invalid builtin declaration, type still contains metavariables after elaboration"); type = p.first; } else { mk_scope scope(*this); parse_var_decl_parameters(parameters); check_colon_next("invalid builtin declaration, ':' expected"); expr type_body = parse_expr(); auto p = m_elaborator(mk_abstraction(false, parameters, type_body)); check_no_metavar(p, "invalid declaration, type still contains metavariables after elaboration"); type = p.first; } if (to_value(b).get_type() != type) { diagnostic(m_io_state) << "Error, builtin expected type: " << to_value(b).get_type() << ", given: " << type << "\n"; throw parser_error(sstream() << "given type does not match builtin type", id_pos); } m_env->add_builtin(d->first); if (m_verbose) regular(m_io_state) << " Added: " << full_id << endl; register_implicit_arguments(full_id, parameters); } void parser_imp::parse_scope() { next(); m_scope_kinds.push_back(scope_kind::Scope); reset_env(m_env->mk_child()); m_using_decls.push(); } void parser_imp::parse_pop() { next(); if (m_scope_kinds.empty()) throw parser_error("main scope cannot be removed", m_last_cmd_pos); if (m_scope_kinds.back() != scope_kind::Scope) throw parser_error("invalid pop command, it is not inside of a scope", m_last_cmd_pos); if (!m_env->has_parent()) throw parser_error("main scope cannot be removed", m_last_cmd_pos); m_scope_kinds.pop_back(); reset_env(m_env->parent()); m_using_decls.pop(); m_script_state->apply([&](lua_State * L) { lua_gc(L, LUA_GCCOLLECT, 0); }); } void parser_imp::parse_namespace() { next(); name id = check_identifier_next("invalid namespace declaration, identifier expected"); m_scope_kinds.push_back(scope_kind::Namespace); m_namespace_prefixes.push_back(m_namespace_prefixes.back() + id); m_using_decls.push(); } void parser_imp::parse_end() { next(); if (m_scope_kinds.empty()) throw parser_error("invalid 'end', not inside of a scope or namespace", m_last_cmd_pos); scope_kind k = m_scope_kinds.back(); m_scope_kinds.pop_back(); m_script_state->apply([&](lua_State * L) { lua_gc(L, LUA_GCCOLLECT, 0); }); switch (k) { case scope_kind::Scope: { if (!m_env->has_parent()) throw parser_error("main scope cannot be removed", m_last_cmd_pos); auto new_objects = export_local_objects(m_env); reset_env(m_env->parent()); for (auto const & obj : new_objects) { if (obj.is_theorem()) m_env->add_theorem(obj.get_name(), obj.get_type(), obj.get_value()); else m_env->add_definition(obj.get_name(), obj.get_type(), obj.get_value(), obj.is_opaque()); } break; } case scope_kind::Namespace: if (m_namespace_prefixes.size() <= 1) throw parser_error("invalid end namespace command, there are no open namespaces", m_last_cmd_pos); m_namespace_prefixes.pop_back(); } m_using_decls.pop(); } static name replace_prefix(name const & n, name const & prefix, name const & new_prefix) { if (n == prefix) return new_prefix; name p = replace_prefix(n.get_prefix(), prefix, new_prefix); if (n.is_string()) return name(p, n.get_string()); else return name(p, n.get_numeral()); } void parser_imp::parse_using() { next(); name prefix = check_identifier_next("invalid using command, identifier expected"); name new_prefix; if (curr_is_identifier()) { new_prefix = curr_name(); next(); } buffer> to_add; for (auto it = m_env->begin_objects(); it != m_env->end_objects(); ++it) { if (it->has_type() && it->has_name() && !is_hidden_object(*it) && is_prefix_of(prefix, it->get_name())) { auto n = replace_prefix(it->get_name(), prefix, new_prefix); if (!n.is_anonymous()) to_add.emplace_back(n, mk_constant(it->get_name())); } } for (auto p : to_add) { auto n = p.first; if (m_verbose) { auto it = m_using_decls.find(n); if (it != m_using_decls.end()) diagnostic(m_io_state) << "warning: " << n << " will shadow " << it->second << endl; auto obj = m_env->find_object(n); if (obj) diagnostic(m_io_state) << "warning: " << n << " will shadow " << obj->get_name() << endl; } m_using_decls.insert(n, p.second); } if (m_verbose) regular(m_io_state) << " Using: " << prefix; if (new_prefix) regular(m_io_state) << " as " << new_prefix; regular(m_io_state) << endl; } /** \brief Parse a Lean command. */ bool parser_imp::parse_command() { m_elaborator.clear(); m_expr_pos_info.clear(); m_tactic_hints.clear(); m_last_cmd_pos = pos(); name const & cmd_id = curr_name(); if (cmd_id == g_definition_kwd) { parse_definition(); } else if (cmd_id == g_variable_kwd) { parse_variable(); } else if (cmd_id == g_variables_kwd) { parse_variables(); } else if (cmd_id == g_theorem_kwd) { parse_theorem(); } else if (cmd_id == g_axiom_kwd) { parse_axiom(); } else if (cmd_id == g_eval_kwd) { parse_eval(); } else if (cmd_id == g_print_kwd) { parse_print(); } else if (cmd_id == g_check_kwd) { parse_check(); } else if (cmd_id == g_infix_kwd) { parse_op(fixity::Infix); } else if (cmd_id == g_infixl_kwd) { parse_op(fixity::Infixl); } else if (cmd_id == g_infixr_kwd) { parse_op(fixity::Infixr); } else if (cmd_id == g_notation_kwd) { parse_notation_decl(); } else if (cmd_id == g_set_option_kwd) { parse_set_option(); } else if (cmd_id == g_set_opaque_kwd) { parse_set_opaque(); } else if (cmd_id == g_import_kwd) { parse_import(); } else if (cmd_id == g_help_kwd) { parse_help(); } else if (cmd_id == g_coercion_kwd) { parse_coercion(); } else if (cmd_id == g_exit_kwd) { next(); return false; } else if (cmd_id == g_scope_kwd) { parse_scope(); } else if (cmd_id == g_pop_kwd) { parse_pop(); } else if (cmd_id == g_universe_kwd) { parse_universe(); } else if (cmd_id == g_alias_kwd) { parse_alias(); } else if (cmd_id == g_builtin_kwd) { parse_builtin(); } else if (cmd_id == g_namespace_kwd) { parse_namespace(); } else if (cmd_id == g_end_kwd) { parse_end(); } else if (cmd_id == g_using_kwd) { parse_using(); } else if (m_cmd_macros && m_cmd_macros->find(cmd_id) != m_cmd_macros->end()) { parse_cmd_macro(cmd_id, m_last_cmd_pos); } else { next(); throw parser_error(sstream() << "invalid command '" << cmd_id << "'", m_last_cmd_pos); } return true; } }