/* Copyright (c) 2014 Microsoft Corporation. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Author: Leonardo de Moura */ #include #include "util/sstream.h" #include "util/name_map.h" #include "kernel/replace_fn.h" #include "kernel/type_checker.h" #include "kernel/instantiate.h" #include "kernel/inductive/inductive.h" #include "kernel/abstract.h" #include "kernel/free_vars.h" #include "library/scoped_ext.h" #include "library/locals.h" #include "library/deep_copy.h" #include "library/placeholder.h" #include "library/aliases.h" #include "library/protected.h" #include "library/explicit.h" #include "library/reducible.h" #include "library/class.h" #include "library/util.h" #include "library/definitional/rec_on.h" #include "library/definitional/induction_on.h" #include "library/definitional/cases_on.h" #include "library/definitional/brec_on.h" #include "library/definitional/no_confusion.h" #include "frontends/lean/decl_cmds.h" #include "frontends/lean/util.h" #include "frontends/lean/parser.h" #include "frontends/lean/tokens.h" #include "frontends/lean/type_util.h" namespace lean { using inductive::intro_rule; using inductive::inductive_decl; using inductive::inductive_decl_name; using inductive::inductive_decl_type; using inductive::inductive_decl_intros; using inductive::intro_rule_name; using inductive::intro_rule_type; inductive_decl update_inductive_decl(inductive_decl const & d, expr const & t) { return inductive_decl(inductive_decl_name(d), t, inductive_decl_intros(d)); } inductive_decl update_inductive_decl(inductive_decl const & d, buffer const & irs) { return inductive_decl(inductive_decl_name(d), inductive_decl_type(d), to_list(irs.begin(), irs.end())); } intro_rule update_intro_rule(intro_rule const & r, expr const & t) { return intro_rule(intro_rule_name(r), t); } static name * g_tmp_prefix = nullptr; static name * g_inductive = nullptr; static name * g_definition = nullptr; static name * g_intro = nullptr; static name * g_recursor = nullptr; void initialize_inductive_cmd() { g_tmp_prefix = new name(name::mk_internal_unique_name()); g_inductive = new name("inductive"); g_intro = new name("intro"); g_recursor = new name("recursor"); g_definition = new name("definition"); } void finalize_inductive_cmd() { delete g_recursor; delete g_intro; delete g_inductive; delete g_definition; delete g_tmp_prefix; } struct inductive_cmd_fn { typedef std::unique_ptr type_checker_ptr; typedef name_map implicit_infer_map; typedef type_modifiers modifiers; parser & m_p; environment m_env; type_checker_ptr m_tc; name m_namespace; // current namespace pos_info m_pos; // current position for reporting errors bool m_first; // true if parsing the first inductive type in a mutually recursive inductive decl. buffer m_explicit_levels; buffer m_levels; buffer m_params; // parameters unsigned m_num_params; // number of parameters bool m_using_explicit_levels; // true if the user is providing explicit universe levels level m_u; // temporary auxiliary global universe used for inferring the result universe of // an inductive datatype declaration. bool m_infer_result_universe; implicit_infer_map m_implicit_infer_map; // implicit argument inference mode name_map m_modifiers; name_map m_decl_pos_map; typedef std::tuple decl_info; buffer m_decl_info; // auxiliary buffer used to populate declaration_index inductive_cmd_fn(parser & p):m_p(p) { m_env = p.env(); m_first = true; m_using_explicit_levels = false; m_num_params = 0; name u_name(*g_tmp_prefix, "u"); m_env = m_env.add_universe(u_name); m_u = mk_global_univ(u_name); m_infer_result_universe = false; m_namespace = get_namespace(m_env); m_tc = mk_type_checker(m_env, m_p.mk_ngen(), false); } [[ noreturn ]] void throw_error(char const * error_msg) { throw parser_error(error_msg, m_pos); } [[ noreturn ]] void throw_error(sstream const & strm) { throw parser_error(strm, m_pos); } implicit_infer_kind get_implicit_infer_kind(name const & n) { if (auto it = m_implicit_infer_map.find(n)) return *it; else return implicit_infer_kind::Implicit; } name mk_rec_name(name const & n) { return ::lean::inductive::get_elim_name(n); } /** \brief Parse the name of an inductive datatype or introduction rule, prefix the current namespace to it and return it. */ pair parse_decl_name(optional const & ind_name) { m_pos = m_p.pos(); name id = m_p.check_id_next("invalid declaration, identifier expected"); if (ind_name) { // for intro rules, we append the name of the inductive datatype check_atomic(id); name full_id = *ind_name + id; m_decl_info.emplace_back(full_id, *g_intro, m_pos); return mk_pair(id, full_id); } else { name full_id = m_namespace + id; m_decl_info.emplace_back(full_id, *g_inductive, m_pos); m_decl_info.emplace_back(mk_rec_name(full_id), *g_recursor, m_pos); return mk_pair(id, full_id); } } pair parse_inductive_decl_name() { return parse_decl_name(optional()); } name parse_intro_decl_name(name const & ind_name) { return parse_decl_name(optional(ind_name)).second; } /** \brief Parse inductive declaration universe parameters. If this is the first declaration in a mutually recursive block, then this method stores the levels in m_explicit_levels, and set m_using_explicit_levels to true (iff they were provided). If this is not the first declaration, then this function just checks if the user is not providing explicit universe levels again. */ void parse_inductive_univ_params() { buffer curr_ls_buffer; if (parse_univ_params(m_p, curr_ls_buffer)) { if (!m_first) { throw_error("invalid mutually recursive declaration, " "explicit universe levels should only be provided to first inductive type in this declaration"); } m_using_explicit_levels = true; m_explicit_levels.append(curr_ls_buffer); } } /** \brief Parse the type of an inductive datatype */ expr parse_datatype_type() { expr type; buffer ps; m_pos = m_p.pos(); if (m_p.curr_is_token(get_assign_tk())) { type = mk_sort(mk_level_placeholder()); } else if (m_first && !m_p.curr_is_token(get_colon_tk())) { lean_assert(m_params.empty()); unsigned rbp = 0; m_p.parse_binders(ps, rbp); m_num_params = ps.size(); if (m_p.curr_is_token(get_colon_tk())) { m_p.next(); type = m_p.parse_scoped_expr(ps); } else { type = mk_sort(mk_level_placeholder()); } type = Pi(ps, type, m_p); } else { m_p.check_token_next(get_colon_tk(), "invalid mutually recursive inductive declaration, " "':' expected (remark: parameters should be provided only to first datatype)"); type = m_p.parse_expr(); } if (!m_first) type = Pi(m_params, type, m_p); return type; } /** \brief Return the universe level of the given type, if it is not a sort, then raise an exception. */ level get_datatype_result_level(expr d_type) { d_type = m_tc->whnf(d_type).first; while (is_pi(d_type)) { d_type = m_tc->whnf(binding_body(d_type)).first; } if (!is_sort(d_type)) throw_error(sstream() << "invalid inductive datatype, resultant type is not a sort"); return sort_level(d_type); } /** \brief Create a local constant based on the given binding */ expr mk_local_for(expr const & b) { return mk_local(m_p.mk_fresh_name(), binding_name(b), binding_domain(b), binding_info(b), b.get_tag()); } /** \brief Set explicit datatype parameters as local constants in m_params */ void set_params(expr d_type) { lean_assert(m_params.empty()); for (unsigned i = 0; i < m_num_params; i++) { expr l = mk_local(binding_name(d_type), binding_name(d_type), binding_domain(d_type), binding_info(d_type), d_type.get_tag()); m_params.push_back(l); d_type = instantiate(binding_body(d_type), l); } } /** \brief Add the parameters (in m_params) to parser local scope */ void add_params_to_local_scope() { for (expr const & l : m_params) m_p.add_local(l); } /** \brief Parse introduction rules in the scope of m_params. Introduction rules with the annotation '{}' are marked for relaxed (aka non-strict) implicit parameter inference. Introduction rules with the annotation '()' are marked for no implicit parameter inference. */ list parse_intro_rules(name const & ind_name) { buffer intros; while (true) { name intro_name = parse_intro_decl_name(ind_name); implicit_infer_kind k = parse_implicit_infer_modifier(m_p); m_implicit_infer_map.insert(intro_name, k); if (!m_params.empty() || m_p.curr_is_token(get_colon_tk())) { m_p.check_token_next(get_colon_tk(), "invalid introduction rule, ':' expected"); expr intro_type = m_p.parse_expr(); intros.push_back(intro_rule(intro_name, intro_type)); } else { expr intro_type = mk_constant(ind_name); intros.push_back(intro_rule(intro_name, intro_type)); } if (!m_p.curr_is_token(get_comma_tk())) break; m_p.next(); } return to_list(intros.begin(), intros.end()); } void parse_inductive_decls(buffer & decls) { while (true) { parser::local_scope l_scope(m_p); auto pos = m_p.pos(); pair d_names = parse_inductive_decl_name(); name d_short_name = d_names.first; name d_name = d_names.second; m_decl_pos_map.insert(d_name, pos); parse_inductive_univ_params(); if (!m_first) { add_params_to_local_scope(); for (name const & lvl_name : m_explicit_levels) m_p.add_local_level(lvl_name, mk_param_univ(lvl_name)); } modifiers mods; mods.parse(m_p); m_modifiers.insert(d_name, mods); expr d_type = parse_datatype_type(); bool empty_type = true; if (m_p.curr_is_token(get_assign_tk())) { empty_type = false; m_p.next(); } if (m_first) { m_levels.append(m_explicit_levels); set_params(d_type); } if (empty_type) { decls.push_back(inductive_decl(d_name, d_type, list())); } else { if (m_first) add_params_to_local_scope(); expr d_const = mk_constant(d_name, param_names_to_levels(to_list(m_explicit_levels.begin(), m_explicit_levels.end()))); m_p.add_local_expr(d_short_name, d_const); auto d_intro_rules = parse_intro_rules(d_name); decls.push_back(inductive_decl(d_name, d_type, d_intro_rules)); } if (!m_p.curr_is_token(get_with_tk())) { break; } m_p.next(); m_first = false; } } /** \brief Include in m_levels any local level referenced by decls. */ void include_local_levels(buffer const & decls, buffer const & locals) { if (!m_p.has_locals()) return; name_set all_lvl_params; for (auto const & local : locals) { all_lvl_params = collect_univ_params(mlocal_type(local), all_lvl_params); } for (auto const & d : decls) { all_lvl_params = collect_univ_params(inductive_decl_type(d), all_lvl_params); for (auto const & ir : inductive_decl_intros(d)) { all_lvl_params = collect_univ_params(intro_rule_type(ir), all_lvl_params); } } buffer local_lvls; all_lvl_params.for_each([&](name const & l) { if (std::find(m_levels.begin(), m_levels.end(), l) == m_levels.end()) local_lvls.push_back(l); }); std::sort(local_lvls.begin(), local_lvls.end(), [&](name const & n1, name const & n2) { return m_p.get_local_level_index(n1) < m_p.get_local_level_index(n2); }); buffer new_levels; new_levels.append(local_lvls); new_levels.append(m_levels); m_levels.clear(); m_levels.append(new_levels); } /** \brief Collect local constants used in the inductive decls. */ void collect_locals_core(buffer const & decls, expr_struct_set & ls) { buffer include_vars; m_p.get_include_variables(include_vars); for (expr const & param : include_vars) { ::lean::collect_locals(mlocal_type(param), ls); ls.insert(param); } for (auto const & d : decls) { ::lean::collect_locals(inductive_decl_type(d), ls); for (auto const & ir : inductive_decl_intros(d)) { expr ir_type = intro_rule_type(ir); bool use_cache = false; ir_type = Pi(m_params, ir_type, use_cache); ::lean::collect_locals(ir_type, ls); } } } /** \brief Collect local constants used in the declaration as extra parameters, and update inductive datatype types with them. */ void collect_locals(buffer & decls, buffer & locals) { if (!m_p.has_locals()) return; expr_struct_set local_set; collect_locals_core(decls, local_set); if (local_set.empty()) return; sort_locals(local_set, m_p, locals); m_num_params += locals.size(); } /** \brief Update the result sort of the given type */ expr update_result_sort(expr t, level const & l) { t = m_tc->whnf(t).first; if (is_pi(t)) { return update_binding(t, binding_domain(t), update_result_sort(binding_body(t), l)); } else if (is_sort(t)) { return update_sort(t, l); } else { lean_unreachable(); } } /** \brief Conservative test for checking whether a datatype that may be Prop for some universe parameter instantiations will be able to eliminate to any Type. TODO(Leo): implement a more complete version */ bool is_prop_as_type(buffer const & decls) { if (decls.size() != 1) return false; inductive_decl const & decl = decls[0]; unsigned nintro = length(inductive_decl_intros(decl)); if (nintro == 0) return true; if (nintro > 1) return false; expr intro_type = intro_rule_type(head(inductive_decl_intros(decl))); return !is_pi(m_tc->whnf(intro_type).first); } /** \brief Convert inductive datatype declarations into local constants, and store them into \c r and \c map. \c map is a mapping from inductive datatype name into local constant. */ void inductive_types_to_locals(buffer const & decls, buffer & r, name_map & map) { for (inductive_decl const & decl : decls) { name const & n = inductive_decl_name(decl); expr type = inductive_decl_type(decl); for (unsigned i = 0; i < m_params.size(); i++) { lean_assert(is_pi(type)); type = binding_body(type); } type = instantiate_rev(type, m_params.size(), m_params.data()); level l = get_datatype_result_level(type); if (is_placeholder(l)) { if (m_using_explicit_levels) throw_error("resultant universe must be provided, when using explicit universe levels"); type = update_result_sort(type, m_u); m_infer_result_universe = true; } else if (m_env.impredicative() && !is_zero(l) && !is_not_zero(l)) { // If the resultant universe can be Prop for some parameter instantiations, then // the kernel will produce an eliminator that only eliminates to Prop. // There is on exception the singleton case. We perform a concervative check here, // we generate the error only if decls is not the singleton case if (!is_prop_as_type(decls)) throw_error("invalid universe polymorphic inductive declaration, the resultant universe is not Prop (i.e., 0), but it may " "be Prop for some parameter values (solution: use 'l+1' or 'max 1 l')"); } expr local = mk_local(m_p.mk_fresh_name(), n, type, binder_info(), type.get_tag()); r.push_back(local); map.insert(n, local); } } /** \brief Replace every occurrences of the inductive datatypes (in decls) in \c type with a local constant */ expr fix_intro_rule_type(expr const & type, name_map const & ind_to_local) { buffer explicit_params; for (expr const & param : m_params) { if (is_explicit(local_info(param))) explicit_params.push_back(param); } unsigned neparams = explicit_params.size(); return replace(type, [&](expr const & e) { expr const & fn = get_app_fn(e); if (!is_constant(fn)) return none_expr(); if (auto it = ind_to_local.find(const_name(fn))) { buffer args; get_app_args(e, args); if (args.size() < neparams) throw parser_error(sstream() << "invalid datatype declaration, " << "incorrect number of arguments to datatype '" << const_name(fn) << "'", m_p.pos_of(e)); for (unsigned i = 0; i < neparams; i++) { if (args[i] != explicit_params[i]) throw parser_error(sstream() << "invalid datatype declaration, " << "mismatch in the #" << (i+1) << " explicit parameter", m_p.pos_of(e)); } pos_info pos = m_p.pos_of(e); expr r = m_p.save_pos(copy(*it), pos); for (unsigned i = neparams; i < args.size(); i++) r = m_p.mk_app(r, args[i], pos); return some_expr(r); } else { return none_expr(); } }); } void intro_rules_to_locals(buffer const & decls, name_map const & ind_to_local, buffer & r) { for (inductive_decl const & decl : decls) { for (intro_rule const & rule : inductive_decl_intros(decl)) { expr type = fix_intro_rule_type(intro_rule_type(rule), ind_to_local); expr local = mk_local(m_p.mk_fresh_name(), intro_rule_name(rule), type, binder_info()); r.push_back(local); } } } /* \brief Add \c lvl to \c r_lvls (if it is not already there. \pre lvl does not contain m_u. */ void accumulate_level(level const & lvl, buffer & r_lvls) { if (occurs(m_u, lvl)) { throw exception("failed to infer inductive datatype resultant universe, " "provide the universe levels explicitly"); } else if (std::find(r_lvls.begin(), r_lvls.end(), lvl) == r_lvls.end()) { r_lvls.push_back(lvl); } } /** \bried Accumulate the universe levels occurring in an introduction rule argument universe. In general, the argument of an introduction rule has type Pi (a_1 : A_1) (a_2 : A_1[a_1]) ..., B[a_1, a_2, ...] The universe associated with it will be imax(l_1, imax(l_2, ..., r)) where l_1 is the unvierse of A_1, l_2 of A_2, and r of B[a_1, ..., a_n]. The result placeholder m_u must only appear as r. */ void accumulate_levels(level const & lvl, buffer & r_lvls) { if (lvl == m_u) { // ignore this is the auxiliary lvl } else if (is_imax(lvl)) { level lhs = imax_lhs(lvl); level rhs = imax_rhs(lvl); accumulate_level(lhs, r_lvls); accumulate_levels(rhs, r_lvls); } else { accumulate_level(lvl, r_lvls); } } /** \brief Traverse the introduction rule type and collect the universes where arguments reside in \c r_lvls. This information is used to compute the resultant universe level for the inductive datatype declaration. */ void accumulate_levels(expr intro_type, buffer & r_lvls) { while (is_pi(intro_type)) { expr s = m_tc->ensure_type(binding_domain(intro_type)).first; accumulate_levels(sort_level(s), r_lvls); intro_type = instantiate(binding_body(intro_type), mk_local_for(intro_type)); } } /** \brief Given a sequence of introduction rules (encoded as local constants), compute the resultant universe for the inductive datatype declaration. */ level infer_resultant_universe(unsigned num_intro_rules, expr const * intro_rules) { lean_assert(m_infer_result_universe); buffer r_lvls; for (unsigned i = 0; i < num_intro_rules; i++) { accumulate_levels(mlocal_type(intro_rules[i]), r_lvls); } return mk_result_level(m_env, r_lvls); } /** \brief Create a mapping from inductive datatype temporary name (used in local constants) to an application C.{ls} locals params, where \c C is the real name of the inductive datatype, and \c ls are the universe level parameters in \c m_levels. */ name_map locals_to_inductive_types(buffer const & locals, unsigned nparams, expr const * params, unsigned num_decls, expr const * decls) { buffer buffer_ls; for (name const & l : m_levels) { buffer_ls.push_back(mk_param_univ(l)); } levels ls = to_list(buffer_ls.begin(), buffer_ls.end()); name_map r; for (unsigned i = 0; i < num_decls; i++) { expr c = mk_constant(local_pp_name(decls[i]), ls); c = mk_app(c, locals); c = mk_app(c, nparams, params); r.insert(mlocal_name(decls[i]), c); } return r; } /** \brief Create the "final" introduction rule type. It will apply the mapping \c local_to_ind built using locals_to_inductive_types, and abstract locals and parameters. */ expr mk_intro_rule_type(name const & ir_name, buffer const & locals, unsigned nparams, expr const * params, name_map const & local_to_ind, expr type) { type = replace(type, [&](expr const & e) { if (!is_local(e)) { return none_expr(); } else if (auto it = local_to_ind.find(mlocal_name(e))) { return some_expr(*it); } else { return none_expr(); } }); bool use_cache = false; type = Pi(nparams, params, type, use_cache); type = Pi(locals, type, use_cache); implicit_infer_kind k = get_implicit_infer_kind(ir_name); return infer_implicit_params(type, locals.size() + nparams, k); } level replace_u(level const & l, level const & rlvl) { return replace(l, [&](level const & l) { if (l == m_u) return some_level(rlvl); else return none_level(); }); } expr replace_u(expr const & type, level const & rlvl) { return replace(type, [&](expr const & e) { if (is_sort(e)) { return some_expr(update_sort(e, replace_u(sort_level(e), rlvl))); } else if (is_constant(e)) { return some_expr(update_constant(e, map(const_levels(e), [&](level const & l) { return replace_u(l, rlvl); }))); } else { return none_expr(); } }); } /** \brief Elaborate inductive datatypes and their introduction rules. */ void elaborate_decls(buffer & decls, buffer const & locals) { // We create an elaboration problem of the form // Pi (params) (inductive_types) (intro_rules), Type buffer to_elab; to_elab.append(m_params); name_map ind_to_local; inductive_types_to_locals(decls, to_elab, ind_to_local); intro_rules_to_locals(decls, ind_to_local, to_elab); expr aux_type = Pi(to_elab, mk_Type(), m_p); list locals_ctx; for (expr const & local : locals) locals_ctx = cons(local, locals_ctx); level_param_names new_ls; std::tie(aux_type, new_ls) = m_p.elaborate_type(aux_type, locals_ctx); // save new levels for (auto l : new_ls) m_levels.push_back(l); // update to_elab for (expr & l : to_elab) { l = update_mlocal(l, binding_domain(aux_type)); aux_type = instantiate(binding_body(aux_type), l); } unsigned nparams = m_params.size(); unsigned num_decls = decls.size(); unsigned first_intro_idx = nparams + num_decls; lean_assert(first_intro_idx <= to_elab.size()); // compute resultant level level resultant_level; if (m_infer_result_universe) { unsigned num_intros = to_elab.size() - first_intro_idx; resultant_level = infer_resultant_universe(num_intros, to_elab.data() + first_intro_idx); } // update decls unsigned i = nparams; for (inductive_decl & decl : decls) { expr type = mlocal_type(to_elab[i]); if (m_infer_result_universe) type = update_result_sort(type, resultant_level); bool use_cache = false; type = Pi(nparams, to_elab.data(), type, use_cache); type = Pi(locals, type, use_cache); decl = update_inductive_decl(decl, type); i++; } // Create mapping for converting occurrences of inductive types (as local constants) // into the real ones. name_map local_to_ind = locals_to_inductive_types(locals, nparams, to_elab.data(), num_decls, to_elab.data() + nparams); i = nparams + num_decls; for (inductive_decl & decl : decls) { buffer new_irs; for (intro_rule const & ir : inductive_decl_intros(decl)) { expr type = mlocal_type(to_elab[i]); type = mk_intro_rule_type(intro_rule_name(ir), locals, nparams, to_elab.data(), local_to_ind, type); if (m_infer_result_universe) type = replace_u(type, resultant_level); new_irs.push_back(update_intro_rule(ir, type)); i++; } decl = update_inductive_decl(decl, new_irs); } } /** \brief Return true if eliminator/recursor can eliminate into any universe */ bool has_general_eliminator(environment const & env, name const & d_name) { declaration d = env.get(d_name); declaration r = env.get(mk_rec_name(d_name)); return length(d.get_univ_params()) != length(r.get_univ_params()); } /** \brief Add aliases for the inductive datatype, introduction and elimination rules */ environment add_aliases(environment env, level_param_names const & ls, buffer const & locals, buffer const & decls) { buffer params_only(locals); remove_local_vars(m_p, params_only); // Create aliases/local refs levels ctx_levels = collect_local_nonvar_levels(m_p, ls); for (auto & d : decls) { name d_name = inductive_decl_name(d); name d_short_name(d_name.get_string()); env = add_alias(m_p, env, false, d_name, ctx_levels, params_only); name rec_name = mk_rec_name(d_name); levels rec_ctx_levels = ctx_levels; if (ctx_levels && has_general_eliminator(env, d_name)) rec_ctx_levels = levels(mk_level_placeholder(), rec_ctx_levels); env = add_alias(m_p, env, true, rec_name, rec_ctx_levels, params_only); env = add_protected(env, rec_name); for (intro_rule const & ir : inductive_decl_intros(d)) { name ir_name = intro_rule_name(ir); env = add_alias(m_p, env, true, ir_name, ctx_levels, params_only); } } return env; } void update_declaration_index(environment const & env) { name n, k; pos_info p; for (auto const & info : m_decl_info) { std::tie(n, k, p) = info; expr type = env.get(n).get_type(); m_p.add_decl_index(n, p, k, type); } } environment apply_modifiers(environment env) { m_modifiers.for_each([&](name const & n, modifiers const & m) { if (m.is_class()) env = add_class(env, n); }); return env; } void save_def_info(name const & n, pos_info pos) { m_decl_info.emplace_back(n, *g_definition, pos); } void save_if_defined(name const & n, pos_info pos) { if (m_env.find(n)) { m_decl_info.emplace_back(n, *g_definition, pos); } } environment mk_aux_decls(environment env, buffer const & decls) { bool has_unit = has_unit_decls(env); bool has_eq = has_eq_decls(env); bool has_heq = has_heq_decls(env); bool has_prod = has_prod_decls(env); bool has_lift = has_lift_decls(env); for (inductive_decl const & d : decls) { name const & n = inductive_decl_name(d); pos_info pos = *m_decl_pos_map.find(n); env = mk_rec_on(env, n); save_def_info(name(n, "rec_on"), pos); if (env.impredicative()) { env = mk_induction_on(env, n); save_def_info(name(n, "induction_on"), pos); } if (has_unit) { env = mk_cases_on(env, n); save_def_info(name(n, "cases_on"), pos); if (has_eq && ((env.prop_proof_irrel() && has_heq) || (!env.prop_proof_irrel() && has_lift))) { env = mk_no_confusion(env, n); save_if_defined(name{n, "no_confusion_type"}, pos); save_if_defined(name(n, "no_confusion"), pos); } if (has_prod) { env = mk_below(env, n); save_if_defined(name{n, "below"}, pos); if (env.impredicative()) { env = mk_ibelow(env, n); save_if_defined(name(n, "ibelow"), pos); } } } } for (inductive_decl const & d : decls) { name const & n = inductive_decl_name(d); pos_info pos = *m_decl_pos_map.find(n); if (has_unit && has_prod) { env = mk_brec_on(env, n); save_if_defined(name{n, "brec_on"}, pos); if (env.impredicative()) { env = mk_binduction_on(env, n); save_if_defined(name(n, "binduction_on"), pos); } } } return env; } /** \brief Add a namespace for each inductive datatype */ environment add_namespaces(environment env, buffer const & decls) { for (inductive_decl const & d : decls) { env = add_namespace(env, inductive_decl_name(d)); } return env; } /** \brief Auxiliary method used for debugging */ void display(std::ostream & out, buffer const & decls) { if (!m_levels.empty()) { out << "inductive level params:"; for (auto l : m_levels) out << " " << l; out << "\n"; } for (auto const & d : decls) { name d_name; expr d_type; list d_irules; std::tie(d_name, d_type, d_irules) = d; out << "inductive " << d_name << " : " << d_type << "\n"; for (auto const & ir : d_irules) { name ir_name; expr ir_type; std::tie(ir_name, ir_type) = ir; out << " | " << ir_name << " : " << ir_type << "\n"; } } out << "\n"; } environment operator()() { parser::undef_id_to_const_scope err_scope(m_p); buffer decls; { parser::local_scope scope(m_p); parse_inductive_decls(decls); } buffer locals; collect_locals(decls, locals); include_local_levels(decls, locals); elaborate_decls(decls, locals); level_param_names ls = to_list(m_levels.begin(), m_levels.end()); environment env = module::add_inductive(m_p.env(), ls, m_num_params, to_list(decls.begin(), decls.end())); env = mk_aux_decls(env, decls); update_declaration_index(env); env = add_aliases(env, ls, locals, decls); env = add_namespaces(env, decls); return apply_modifiers(env); } }; environment inductive_cmd(parser & p) { return inductive_cmd_fn(p)(); } void register_inductive_cmd(cmd_table & r) { add_cmd(r, cmd_info("inductive", "declare an inductive datatype", inductive_cmd)); } }