/* 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 #include "util/flet.h" #include "util/list_fn.h" #include "util/lazy_list_fn.h" #include "util/sstream.h" #include "util/name_map.h" #include "kernel/abstract.h" #include "kernel/instantiate.h" #include "kernel/type_checker.h" #include "kernel/for_each_fn.h" #include "kernel/replace_fn.h" #include "kernel/kernel_exception.h" #include "kernel/error_msgs.h" #include "kernel/expr_maps.h" #include "library/coercion.h" #include "library/placeholder.h" #include "library/choice.h" #include "library/explicit.h" #include "library/unifier.h" #include "library/opaque_hints.h" #include "library/locals.h" #include "library/deep_copy.h" #include "library/tactic/tactic.h" #include "library/tactic/expr_to_tactic.h" #include "library/error_handling/error_handling.h" #include "frontends/lean/local_decls.h" #include "frontends/lean/class.h" #include "frontends/lean/tactic_hint.h" #include "frontends/lean/info_manager.h" #include "frontends/lean/elaborator.h" #ifndef LEAN_DEFAULT_ELABORATOR_LOCAL_INSTANCES #define LEAN_DEFAULT_ELABORATOR_LOCAL_INSTANCES true #endif namespace lean { // ========================================== // elaborator configuration options static name g_elaborator_local_instances{"elaborator", "local_instances"}; RegisterBoolOption(g_elaborator_local_instances, LEAN_DEFAULT_ELABORATOR_LOCAL_INSTANCES, "(lean elaborator) use local declarates as class instances"); bool get_elaborator_local_instances(options const & opts) { return opts.get_bool(g_elaborator_local_instances, LEAN_DEFAULT_ELABORATOR_LOCAL_INSTANCES); } // ========================================== /** \brief Functional object for converting the universe metavariables in an expression in new universe parameters. The substitution is updated with the mapping metavar -> new param. The set of parameter names m_params and the buffer m_new_params are also updated. */ class univ_metavars_to_params_fn { environment const & m_env; local_decls const & m_lls; substitution & m_subst; name_set & m_params; buffer & m_new_params; unsigned m_next_idx; /** \brief Create a new universe parameter s.t. the new name does not occur in \c m_params, nor it is a global universe in \e m_env or in the local_decls m_lls. The new name is added to \c m_params, and the new level parameter is returned. The name is of the form "l_i" where \c i >= m_next_idx. */ level mk_new_univ_param() { name l("l"); name r = l.append_after(m_next_idx); while (m_lls.contains(r) || m_params.contains(r) || m_env.is_universe(r)) { m_next_idx++; r = l.append_after(m_next_idx); } m_params.insert(r); m_new_params.push_back(r); return mk_param_univ(r); } public: univ_metavars_to_params_fn(environment const & env, local_decls const & lls, substitution & s, name_set & ps, buffer & new_ps): m_env(env), m_lls(lls), m_subst(s), m_params(ps), m_new_params(new_ps), m_next_idx(1) {} level apply(level const & l) { return replace(l, [&](level const & l) { if (!has_meta(l)) return some_level(l); if (is_meta(l)) { if (auto it = m_subst.get_level(meta_id(l))) { return some_level(*it); } else { level new_p = mk_new_univ_param(); m_subst.assign(l, new_p); return some_level(new_p); } } return none_level(); }); } expr apply(expr const & e) { if (!has_univ_metavar(e)) { return e; } else { return replace(e, [&](expr const & e) { if (!has_univ_metavar(e)) { return some_expr(e); } else if (is_sort(e)) { return some_expr(update_sort(e, apply(sort_level(e)))); } else if (is_constant(e)) { levels ls = map(const_levels(e), [&](level const & l) { return apply(l); }); return some_expr(update_constant(e, ls)); } else { return none_expr(); } }); } } expr operator()(expr const & e) { return apply(e); } }; elaborator_context::elaborator_context(environment const & env, io_state const & ios, local_decls const & lls, pos_info_provider const * pp, info_manager * info, bool check_unassigned): m_env(env), m_ios(ios), m_lls(lls), m_pos_provider(pp), m_info_manager(info), m_check_unassigned(check_unassigned) { m_use_local_instances = get_elaborator_local_instances(ios.get_options()); } /** \brief Return a list of instances of the class \c cls_name that occur in \c ctx */ list get_local_instances(list const & ctx, name const & cls_name) { buffer buffer; for (auto const & l : ctx) { if (!is_local(l)) continue; expr inst_type = mlocal_type(l); if (!is_constant(get_app_fn(inst_type)) || const_name(get_app_fn(inst_type)) != cls_name) continue; buffer.push_back(l); } return to_list(buffer.begin(), buffer.end()); } /** \brief Helper class for implementing the \c elaborate functions. */ class elaborator { typedef name_map mvar2meta; /** \brief Auxiliary data-structure for storing the local context, and creating metavariables in the scope of the local context efficiently */ class context { name_generator & m_ngen; mvar2meta & m_mvar2meta; list m_ctx; // current local context: a list of local constants buffer m_ctx_buffer; // m_ctx as a buffer buffer m_ctx_domain_buffer; // m_ctx_domain_buffer[i] == abstract_locals(m_ctx_buffer[i], i, m_ctx_buffer.beg public: context(name_generator & ngen, mvar2meta & m, list const & ctx):m_ngen(ngen), m_mvar2meta(m) { set_ctx(ctx); } void set_ctx(list const & ctx) { m_ctx = ctx; m_ctx_buffer.clear(); m_ctx_domain_buffer.clear(); to_buffer(ctx, m_ctx_buffer); std::reverse(m_ctx_buffer.begin(), m_ctx_buffer.end()); for (unsigned i = 0; i < m_ctx_buffer.size(); i++) { m_ctx_domain_buffer.push_back(abstract_locals(m_ctx_buffer[i], i, m_ctx_buffer.data())); } } /** \brief Given e[l_1, ..., l_n] and assuming \c m_ctx is [l_n : A_n[l_1, ..., l_{n-1}], ..., l_1 : A_1 ], then the result is (Pi (x_1 : A_1) ... (x_n : A_n[x_1, ..., x_{n-1}]), e[x_1, ... x_n]). */ expr pi_abstract_context(expr e, tag g) { e = abstract_locals(e, m_ctx_buffer.size(), m_ctx_buffer.data()); unsigned i = m_ctx_domain_buffer.size(); while (i > 0) { --i; expr const & l = m_ctx_domain_buffer[i]; e = save_tag(mk_pi(local_pp_name(l), mlocal_type(l), e, local_info(l)), g); } return e; } /** \brief Assuming \c m_ctx is [l_n : A_n[l_1, ..., l_{n-1}], ..., l_1 : A_1 ], return (f l_1 ... l_n). */ expr apply_context(expr const & f, tag g) { expr r = f; for (unsigned i = 0; i < m_ctx_buffer.size(); i++) r = save_tag(::lean::mk_app(r, m_ctx_buffer[i]), g); return r; } /** \brief Assuming \c m_ctx is [l_n : A_n[l_1, ..., l_{n-1}], ..., l_1 : A_1 ], return a fresh metavariable \c ?m with type (Pi (x_1 : A_1) ... (x_n : A_n[x_1, ..., x_{n-1}]), Type.{?u}), where \c ?u is a fresh universe metavariable. */ expr mk_type_metavar(tag g) { name n = m_ngen.next(); expr s = save_tag(mk_sort(mk_meta_univ(m_ngen.next())), g); expr t = pi_abstract_context(s, g); return save_tag(::lean::mk_metavar(n, t), g); } /** \brief Assuming \c m_ctx is [l_n : A_n[l_1, ..., l_{n-1}], ..., l_1 : A_1 ], return (?m l_1 ... l_n) where \c ?m is a fresh metavariable with type (Pi (x_1 : A_1) ... (x_n : A_n[x_1, ..., x_{n-1}]), Type.{?u}), and \c ?u is a fresh universe metavariable. \remark The type of the resulting expression is Type.{?u} */ expr mk_type_meta(tag g) { return apply_context(mk_type_metavar(g), g); } /** \brief Given type[l_1, ..., l_n] and assuming \c m_ctx is [l_n : A_n[l_1, ..., l_{n-1}], ..., l_1 : A_1 ], then the result is a fresh metavariable \c ?m with type (Pi (x_1 : A_1) ... (x_n : A_n[x_1, ..., x_{n-1}]), type[x_1, ... x_n]). If type is none, then the result is a fresh metavariable \c ?m1 with type (Pi (x_1 : A_1) ... (x_n : A_n[x_1, ..., x_{n-1}]), ?m2 x1 .... xn), where ?m2 is another fresh metavariable with type (Pi (x_1 : A_1) ... (x_n : A_n[x_1, ..., x_{n-1}]), Type.{?u}), and \c ?u is a fresh universe metavariable. */ expr mk_metavar(optional const & type, tag g) { name n = m_ngen.next(); expr r_type = type ? *type : mk_type_meta(g); expr t = pi_abstract_context(r_type, g); return save_tag(::lean::mk_metavar(n, t), g); } /** \brief Given type[l_1, ..., l_n] and assuming \c m_ctx is [l_n : A_n[l_1, ..., l_{n-1}], ..., l_1 : A_1 ], return (?m l_1 ... l_n), where ?m is a fresh metavariable created using \c mk_metavar. \see mk_metavar */ expr mk_meta(optional const & type, tag g) { expr mvar = mk_metavar(type, g); expr meta = apply_context(mvar, g); m_mvar2meta.insert(mlocal_name(mvar), meta); return meta; } void add_local(expr const & l) { m_ctx = cons(l, m_ctx); m_ctx_domain_buffer.push_back(abstract_locals(l, m_ctx_buffer.size(), m_ctx_buffer.data())); m_ctx_buffer.push_back(l); } list const & get_data() const { return m_ctx; } /** \brief Scope object for restoring the content of the context */ class scope { context & m_main; list m_old_ctx; unsigned m_old_sz; public: scope(context & main):m_main(main), m_old_ctx(main.m_ctx), m_old_sz(main.m_ctx_buffer.size()) {} ~scope() { m_main.m_ctx = m_old_ctx; m_main.m_ctx_buffer.shrink(m_old_sz); m_main.m_ctx_domain_buffer.shrink(m_old_sz); } }; /** \brief Scope object for temporarily replacing the content of the context */ class scope_replace { context & m_main; list m_saved; public: scope_replace(context & main, list const & new_ctx):m_main(main), m_saved(m_main.m_ctx) { m_main.set_ctx(new_ctx); } ~scope_replace() { m_main.set_ctx(m_saved); } }; }; typedef std::vector constraint_vect; typedef name_map local_tactic_hints; typedef std::unique_ptr type_checker_ptr; elaborator_context & m_env; name_generator m_ngen; type_checker_ptr m_tc[2]; mvar2meta m_mvar2meta; // mapping from metavariable ?m to the (?m l_1 ... l_n) where [l_1 ... l_n] are the local constants // representing the context where ?m was created. context m_context; // current local context: a list of local constants context m_full_context; // superset of m_context, it also contains non-contextual locals. constraint_vect m_constraints; // constraints that must be solved for the elaborated term to be type correct. local_tactic_hints m_local_tactic_hints; // mapping from metavariable name ?m to tactic expression that should be used to solve it. // this mapping is populated by the 'by tactic-expr' expression. name_set m_displayed_errors; // set of metavariables that we already reported unsolved/unassigned bool m_relax_main_opaque; // if true, then treat opaque definitions from the main module as transparent std::vector m_pre_info_data; struct scope_ctx { context::scope m_scope1; context::scope m_scope2; scope_ctx(elaborator & e):m_scope1(e.m_context), m_scope2(e.m_full_context) {} }; /** \brief Auxiliary object for creating backtracking points, and replacing the local scopes. \remark A new scope can only be created when m_constraints is empty. */ struct new_scope { elaborator & m_main; context::scope_replace m_context_scope; context::scope_replace m_full_context_scope; new_scope(elaborator & e, list const & ctx, list const & full_ctx): m_main(e), m_context_scope(e.m_context, ctx), m_full_context_scope(e.m_full_context, full_ctx) { lean_assert(m_main.m_constraints.empty()); m_main.m_tc[0]->push(); m_main.m_tc[1]->push(); } ~new_scope() { m_main.m_tc[0]->pop(); m_main.m_tc[1]->pop(); m_main.m_constraints.clear(); lean_assert(m_main.m_constraints.empty()); } }; /* \brief Move all constraints generated by the type checker to the buffer m_constraints. */ void consume_tc_cnstrs() { for (unsigned i = 0; i < 2; i++) while (auto c = m_tc[i]->next_cnstr()) m_constraints.push_back(*c); } struct choice_elaborator { bool m_ignore_failure; choice_elaborator(bool ignore_failure = false):m_ignore_failure(ignore_failure) {} virtual optional next() = 0; }; /** \brief 'Choice' expressions (choice e_1 ... e_n) are mapped into a metavariable \c ?m and a choice constraints (?m in fn) where \c fn is a choice function. The choice function produces a stream of alternatives. In this case, it produces a stream of size \c n, one alternative for each \c e_i. This is a helper class for implementing this choice functions. */ struct choice_expr_elaborator : public choice_elaborator { elaborator & m_elab; expr m_mvar; expr m_choice; list m_ctx; list m_full_ctx; unsigned m_idx; bool m_relax_main_opaque; choice_expr_elaborator(elaborator & elab, expr const & mvar, expr const & c, list const & ctx, list const & full_ctx, bool relax): m_elab(elab), m_mvar(mvar), m_choice(c), m_ctx(ctx), m_full_ctx(full_ctx), m_idx(0), m_relax_main_opaque(relax) { } virtual optional next() { while (m_idx < get_num_choices(m_choice)) { expr const & c = get_choice(m_choice, m_idx); m_idx++; try { new_scope s(m_elab, m_ctx, m_full_ctx); expr r = m_elab.visit(c); m_elab.consume_tc_cnstrs(); list cs = to_list(m_elab.m_constraints.begin(), m_elab.m_constraints.end()); cs = cons(mk_eq_cnstr(m_mvar, r, justification(), m_relax_main_opaque), cs); return optional(cs); } catch (exception &) {} } return optional(); } }; /** \brief Whenever the elaborator finds a placeholder '_' or introduces an implicit argument, it creates a metavariable \c ?m. It also creates a delayed choice constraint (?m in fn). The function \c fn produces a stream of alternative solutions for ?m. In this case, \c fn will do the following: 1) if the elaborated type of ?m is a 'class' C, then the stream will start with a) all local instances of class C (if elaborator.local_instances == true) b) solutions produced by tactic_hints for class C 2) if the elaborated type of ?m is not a class, then the stream will only contain the solutions produced by tactic_hints. The unifier only process delayed choice constraints when there are no other kind of constraint to be processed. This is a helper class for implementing this choice function. */ struct placeholder_elaborator : public choice_elaborator { elaborator & m_elab; expr m_meta; expr m_meta_type; // elaborated type of the metavariable list m_local_instances; // local instances that should also be included in the class-instance resolution. list m_instances; // global declaration names that are class instances. // This information is retrieved using #get_class_instances. list m_tactics; proof_state_seq m_tactic_result; // result produce by last executed tactic. buffer m_mvars_in_meta_type; // metavariables that occur in m_meta_type, the tactics may instantiate some of them list m_ctx; // local context for m_meta list m_full_ctx; justification m_jst; bool m_relax_main_opaque; placeholder_elaborator(elaborator & elab, expr const & meta, expr const & meta_type, list const & local_insts, list const & instances, list const & tacs, list const & ctx, list const & full_ctx, justification const & j, bool ignore_failure, bool relax): choice_elaborator(ignore_failure), m_elab(elab), m_meta(meta), m_meta_type(meta_type), m_local_instances(local_insts), m_instances(instances), m_tactics(tacs), m_ctx(ctx), m_full_ctx(full_ctx), m_jst(j), m_relax_main_opaque(relax) { collect_metavars(meta_type, m_mvars_in_meta_type); } optional try_instance(name const & inst) { auto decl = m_elab.env().find(inst); if (!decl) return optional(); expr type = decl->get_type(); // create the term pre (inst _ ... _) expr pre = copy_tag(m_meta, mk_explicit(copy_tag(m_meta, mk_constant(inst)))); while (is_pi(type)) { type = binding_body(type); pre = copy_tag(m_meta, ::lean::mk_app(pre, copy_tag(m_meta, mk_strict_expr_placeholder()))); } try { new_scope s(m_elab, m_ctx, m_full_ctx); expr r = m_elab.visit(pre); // use elaborator to create metavariables, levels, etc. m_elab.consume_tc_cnstrs(); for (auto & c : m_elab.m_constraints) c = update_justification(c, mk_composite1(m_jst, c.get_justification())); list cs = to_list(m_elab.m_constraints.begin(), m_elab.m_constraints.end()); cs = cons(mk_eq_cnstr(m_meta, r, m_jst, m_relax_main_opaque), cs); return optional(cs); } catch (exception &) { return optional(); } } optional get_next_tactic_result() { while (auto next = m_tactic_result.pull()) { m_tactic_result = next->second; if (!empty(next->first.get_goals())) continue; // has unsolved goals substitution subst = next->first.get_subst(); buffer cs; expr const & mvar = get_app_fn(m_meta); cs.push_back(mk_eq_cnstr(mvar, subst.instantiate(mvar), m_jst, m_relax_main_opaque)); for (auto const & mvar : m_mvars_in_meta_type) cs.push_back(mk_eq_cnstr(mvar, subst.instantiate(mvar), m_jst, m_relax_main_opaque)); return optional(to_list(cs.begin(), cs.end())); } return optional(); } virtual optional next() { while (!empty(m_local_instances)) { expr inst = head(m_local_instances); m_local_instances = tail(m_local_instances); constraints cs(mk_eq_cnstr(m_meta, inst, m_jst, m_relax_main_opaque)); return optional(cs); } while (!empty(m_instances)) { name inst = head(m_instances); m_instances = tail(m_instances); if (auto cs = try_instance(inst)) return cs; } if (auto cs = get_next_tactic_result()) return cs; while (!empty(m_tactics)) { tactic const & tac = head(m_tactics).get_tactic(); m_tactics = tail(m_tactics); proof_state ps(goals(goal(m_meta, m_meta_type)), substitution(), m_elab.m_ngen.mk_child()); try { m_tactic_result = tac(m_elab.env(), m_elab.ios(), ps); if (auto cs = get_next_tactic_result()) return cs; } catch (exception &) {} } return optional(); } }; lazy_list choose(std::shared_ptr c) { return mk_lazy_list([=]() { auto s = c->next(); if (s) { return some(mk_pair(*s, choose(c))); } else if (c->m_ignore_failure) { // return singleton empty list of constraints, and let tactic hints try to instantiate the metavariable. return lazy_list::maybe_pair(constraints(), lazy_list()); } else { return lazy_list::maybe_pair(); } }); } public: elaborator(elaborator_context & env, list const & ctx, name_generator const & ngen): m_env(env), m_ngen(ngen), m_context(m_ngen, m_mvar2meta, ctx), m_full_context(m_ngen, m_mvar2meta, ctx) { m_relax_main_opaque = false; m_tc[0] = mk_type_checker_with_hints(env.m_env, m_ngen.mk_child(), false); m_tc[1] = mk_type_checker_with_hints(env.m_env, m_ngen.mk_child(), true); } environment const & env() const { return m_env.m_env; } io_state const & ios() const { return m_env.m_ios; } local_decls const & lls() const { return m_env.m_lls; } bool use_local_instances() const { return m_env.m_use_local_instances; } info_manager * infom() const { return m_env.m_info_manager; } pos_info_provider const * pip() const { return m_env.m_pos_provider; } bool check_unassigned() const { return m_env.m_check_unassigned; } expr mk_local(name const & n, expr const & t, binder_info const & bi) { return ::lean::mk_local(m_ngen.next(), n, t, bi); } expr infer_type(expr const & e) { lean_assert(closed(e)); return m_tc[m_relax_main_opaque]->infer(e); } expr whnf(expr const & e) { return m_tc[m_relax_main_opaque]->whnf(e); } /** \brief Clear constraint buffer \c m_constraints */ void clear_constraints() { m_constraints.clear(); } void add_cnstr(constraint const & c) { m_constraints.push_back(c); } static expr save_tag(expr && e, tag g) { e.set_tag(g); return e; } expr mk_app(expr const & f, expr const & a, tag g) { return save_tag(::lean::mk_app(f, a), g); } list get_class_instances(expr const & type) { if (is_constant(get_app_fn(type))) { name const & c = const_name(get_app_fn(type)); return ::lean::get_class_instances(env(), c); } else { return list(); } } bool is_class(expr const & type) { expr f = get_app_fn(type); if (!is_constant(f)) return false; name const & cls_name = const_name(f); return ::lean::is_class(env(), cls_name) || !empty(get_tactic_hints(env(), cls_name)); } static expr instantiate_meta(expr const & meta, substitution & subst) { buffer locals; expr mvar = get_app_args(meta, locals); mvar = update_mlocal(mvar, subst.instantiate_all(mlocal_type(mvar))); for (auto & local : locals) local = subst.instantiate_all(local); return ::lean::mk_app(mvar, locals); } /** \brief Return a 'failed to synthesize placholder' justification for the given metavariable application \c m of the form (?m l_1 ... l_k) */ justification mk_failed_to_synthesize_jst(expr const & m) { environment _env = env(); return mk_justification(m, [=](formatter const & fmt, substitution const & subst) { substitution tmp(subst); expr new_m = instantiate_meta(m, tmp); expr new_type = type_checker(_env).infer(new_m); proof_state ps(goals(goal(new_m, new_type)), substitution(), name_generator("dontcare")); return format({format("failed to synthesize placeholder"), line(), ps.pp(fmt)}); }); } /** \brief Create a metavariable, and attach choice constraint for generating solutions using class-instances and tactic-hints. */ expr mk_placeholder_meta(optional const & type, tag g, bool is_strict = false) { expr m = m_context.mk_meta(type, g); list ctx = m_context.get_data(); list full_ctx = m_full_context.get_data(); justification j = mk_failed_to_synthesize_jst(m); auto choice_fn = [=](expr const & meta, expr const & meta_type, substitution const & s, name_generator const & /* ngen */) { expr const & mvar = get_app_fn(meta); if (is_class(meta_type)) { name const & cls_name = const_name(get_app_fn(meta_type)); list local_insts; if (use_local_instances()) local_insts = get_local_instances(ctx, cls_name); list insts = get_class_instances(meta_type); list tacs; if (!s.is_assigned(mvar)) tacs = get_tactic_hints(env(), cls_name); if (empty(local_insts) && empty(insts) && empty(tacs)) return lazy_list(); // nothing to be done bool ignore_failure = false; // we are always strict with placeholders associated with classes return choose(std::make_shared(*this, meta, meta_type, local_insts, insts, tacs, ctx, full_ctx, j, ignore_failure, m_relax_main_opaque)); } else if (s.is_assigned(mvar)) { // if the metavariable is assigned and it is not a class, then we just ignore it, and return // the an empty set of constraints. return lazy_list(constraints()); } else { list tacs = get_tactic_hints(env()); bool ignore_failure = !is_strict; return choose(std::make_shared(*this, meta, meta_type, list(), list(), tacs, ctx, full_ctx, j, ignore_failure, m_relax_main_opaque)); } }; add_cnstr(mk_choice_cnstr(m, choice_fn, to_delay_factor(cnstr_group::DelayedChoice2), false, j, m_relax_main_opaque)); return m; } /** \brief Convert the metavariable to the metavariable application that captures the context where it was defined. */ optional mvar_to_meta(expr mvar) { if (auto it = m_mvar2meta.find(mlocal_name(mvar))) return some_expr(*it); else return none_expr(); } expr visit_expecting_type(expr const & e) { if (is_placeholder(e) && !placeholder_type(e)) { expr r = m_context.mk_type_meta(e.get_tag()); save_info_data(e, r); return r; } else { return visit(e); } } expr visit_expecting_type_of(expr const & e, expr const & t) { if (is_placeholder(e) && !placeholder_type(e)) { expr r = mk_placeholder_meta(some_expr(t), e.get_tag(), is_strict_placeholder(e)); save_info_data(e, r); return r; } else if (is_choice(e)) { return visit_choice(e, some_expr(t)); } else if (is_by(e)) { return visit_by(e, some_expr(t)); } else { return visit(e); } } expr visit_choice(expr const & e, optional const & t) { lean_assert(is_choice(e)); // Possible optimization: try to lookahead and discard some of the alternatives. expr m = m_full_context.mk_meta(t, e.get_tag()); list ctx = m_context.get_data(); list full_ctx = m_full_context.get_data(); bool relax = m_relax_main_opaque; auto fn = [=](expr const & mvar, expr const & /* type */, substitution const & /* s */, name_generator const & /* ngen */) { return choose(std::make_shared(*this, mvar, e, ctx, full_ctx, relax)); }; justification j = mk_justification("none of the overloads is applicable", some_expr(e)); add_cnstr(mk_choice_cnstr(m, fn, to_delay_factor(cnstr_group::Basic), true, j, m_relax_main_opaque)); return m; } expr visit_by(expr const & e, optional const & t) { lean_assert(is_by(e)); expr tac = visit(get_by_arg(e)); expr m = m_context.mk_meta(t, e.get_tag()); m_local_tactic_hints.insert(mlocal_name(get_app_fn(m)), tac); return m; } /** \brief Make sure \c f is really a function, if it is not, try to apply coercions. The result is a pair new_f, f_type, where new_f is the new value for \c f, and \c f_type is its type (and a Pi-expression) */ std::pair ensure_fun(expr f) { expr f_type = infer_type(f); if (!is_pi(f_type)) f_type = whnf(f_type); if (!is_pi(f_type) && has_metavar(f_type)) { f_type = whnf(f_type); if (!is_pi(f_type) && is_meta(f_type)) { // let type checker add constraint f_type = m_tc[m_relax_main_opaque]->ensure_pi(f_type, f); } } if (!is_pi(f_type)) { // try coercion to function-class optional c = get_coercion_to_fun(env(), f_type); if (c) { f = mk_app(*c, f, f.get_tag()); f_type = infer_type(f); lean_assert(is_pi(f_type)); } else { throw_kernel_exception(env(), f, [=](formatter const & fmt) { return pp_function_expected(fmt, f); }); } } lean_assert(is_pi(f_type)); return mk_pair(f, f_type); } bool has_coercions_from(expr const & a_type) { expr const & a_cls = get_app_fn(whnf(a_type)); return is_constant(a_cls) && ::lean::has_coercions_from(env(), const_name(a_cls)); } bool has_coercions_to(expr const & d_type) { expr const & d_cls = get_app_fn(whnf(d_type)); return is_constant(d_cls) && ::lean::has_coercions_to(env(), const_name(d_cls)); } expr apply_coercion(expr const & a, expr a_type, expr d_type) { a_type = whnf(a_type); d_type = whnf(d_type); expr const & d_cls = get_app_fn(d_type); if (is_constant(d_cls)) { if (auto c = get_coercion(env(), a_type, const_name(d_cls))) return mk_app(*c, a, a.get_tag()); } return a; } constraint mk_delayed_coercion_cnstr(expr const & m, expr const & a, expr const & a_type, justification const & j, unsigned delay_factor) { bool relax = m_relax_main_opaque; auto choice_fn = [=](expr const & mvar, expr const & new_d_type, substitution const & /* s */, name_generator const & /* ngen */) { // Remark: we want the coercions solved before we start discarding FlexFlex constraints. So, we use PreFlexFlex as a max cap // for delaying coercions. if (is_meta(new_d_type) && delay_factor < to_delay_factor(cnstr_group::DelayedChoice1)) { // The type is still unknown, delay the constraint even more. return lazy_list(constraints(mk_delayed_coercion_cnstr(m, a, a_type, justification(), delay_factor+1))); } else { expr r = apply_coercion(a, a_type, new_d_type); return lazy_list(constraints(mk_eq_cnstr(mvar, r, justification(), relax))); } }; return mk_choice_cnstr(m, choice_fn, delay_factor, true, j, m_relax_main_opaque); } /** \brief Given a term a : a_type, and an expected type generate a metavariable with a delayed coercion. */ expr mk_delayed_coercion(expr const & a, expr const & a_type, expr const & expected_type, justification const & j) { expr m = m_full_context.mk_meta(some_expr(expected_type), a.get_tag()); add_cnstr(mk_delayed_coercion_cnstr(m, a, a_type, j, to_delay_factor(cnstr_group::Basic))); return m; } /** \brief Given a term a : a_type, ensure it has type \c expected_type. Apply coercions if needed \remark relax == true affects how opaque definitions in the main module are treated. */ expr ensure_type(expr const & a, expr const & a_type, expr const & expected_type, justification const & j, bool relax) { if (is_meta(expected_type) && has_coercions_from(a_type)) { return mk_delayed_coercion(a, a_type, expected_type, j); } else if (is_meta(a_type) && has_coercions_to(expected_type)) { return mk_delayed_coercion(a, a_type, expected_type, j); } else if (m_tc[relax]->is_def_eq(a_type, expected_type, j)) { return a; } else { expr new_a = apply_coercion(a, a_type, expected_type); bool coercion_worked = false; if (!is_eqp(a, new_a)) { expr new_a_type = infer_type(new_a); coercion_worked = m_tc[relax]->is_def_eq(new_a_type, expected_type, j); } if (coercion_worked) { return new_a; } else if (has_metavar(a_type) || has_metavar(expected_type)) { // rely on unification hints to solve this constraint add_cnstr(mk_eq_cnstr(a_type, expected_type, j, relax)); return a; } else { throw unifier_exception(j, substitution()); } } } bool is_choice_app(expr const & e) { expr const & f = get_app_fn(e); return is_choice(f) || (is_explicit(f) && is_choice(get_explicit_arg(f))); } /** \brief Process ((choice f_1 ... f_n) a_1 ... a_k) as (choice (f_1 a_1 ... a_k) ... (f_n a_1 ... a_k)) */ expr visit_choice_app(expr const & e) { buffer args; expr f = get_app_rev_args(e, args); bool expl = is_explicit(f); if (expl) f = get_explicit_arg(f); lean_assert(is_choice(f)); buffer new_choices; unsigned num = get_num_choices(f); for (unsigned i = 0; i < num; i++) { expr f_i = get_choice(f, i); if (expl) f_i = copy_tag(f_i, mk_explicit(f_i)); new_choices.push_back(mk_rev_app(f_i, args)); } return visit_choice(copy_tag(e, mk_choice(new_choices.size(), new_choices.data())), none_expr()); } expr visit_app(expr const & e) { if (is_choice_app(e)) return visit_choice_app(e); bool expl = is_explicit(get_app_fn(e)); expr f = visit(app_fn(e)); auto f_t = ensure_fun(f); f = f_t.first; expr f_type = f_t.second; lean_assert(is_pi(f_type)); if (!expl) { bool first = true; while (binding_info(f_type).is_strict_implicit() || (!first && binding_info(f_type).is_implicit())) { tag g = f.get_tag(); expr imp_arg = mk_placeholder_meta(some_expr(binding_domain(f_type)), g); f = mk_app(f, imp_arg, g); auto f_t = ensure_fun(f); f = f_t.first; f_type = f_t.second; first = false; } if (!first) { // we save the info data again for application of functions with strict implicit arguments replace_info_data(get_app_fn(e), f); } } expr d_type = binding_domain(f_type); expr a = visit_expecting_type_of(app_arg(e), d_type); expr a_type = infer_type(a); expr r = mk_app(f, a, e.get_tag()); justification j = mk_app_justification(r, a, d_type, a_type); expr new_a = ensure_type(a, a_type, d_type, j, m_relax_main_opaque); return update_app(r, app_fn(r), new_a); } expr visit_placeholder(expr const & e) { expr r = mk_placeholder_meta(placeholder_type(e), e.get_tag(), is_strict_placeholder(e)); save_info_data(e, r); return r; } level replace_univ_placeholder(level const & l) { return replace(l, [&](level const & l) { if (is_placeholder(l)) return some_level(mk_meta_univ(m_ngen.next())); else return none_level(); }); } expr visit_sort(expr const & e) { return update_sort(e, replace_univ_placeholder(sort_level(e))); } expr visit_macro(expr const & e) { if (is_as_is(e)) { return get_as_is_arg(e); } else { // Remark: Macros are not meant to be used in the front end. // Perhaps, we should throw error. buffer args; for (unsigned i = 0; i < macro_num_args(e); i++) args.push_back(visit(macro_arg(e, i))); return update_macro(e, args.size(), args.data()); } } /** \brief Store the pair (pos(e), type(r)) in the info_data if m_info_manager is available. */ void save_info_data_core(expr const & e, expr const & r, bool replace) { if (infom() && pip() && (is_constant(e) || is_local(e) || is_placeholder(e))) { if (auto p = pip()->get_pos_info(e)) { type_checker::scope scope(*m_tc[m_relax_main_opaque]); expr t = m_tc[m_relax_main_opaque]->infer(r); if (replace) { while (!m_pre_info_data.empty() && m_pre_info_data.back().eq_pos(p->first, p->second)) m_pre_info_data.pop_back(); } m_pre_info_data.push_back(type_info_data(p->first, p->second, t)); } } } void save_info_data(expr const & e, expr const & r) { save_info_data_core(e, r, false); } void replace_info_data(expr const & e, expr const & r) { save_info_data_core(e, r, true); } expr visit_constant(expr const & e) { declaration d = env().get(const_name(e)); buffer ls; for (level const & l : const_levels(e)) ls.push_back(replace_univ_placeholder(l)); unsigned num_univ_params = length(d.get_univ_params()); if (num_univ_params < ls.size()) throw_kernel_exception(env(), sstream() << "incorrect number of universe levels parameters for '" << const_name(e) << "', #" << num_univ_params << " expected, #" << ls.size() << " provided"); // "fill" with meta universe parameters for (unsigned i = ls.size(); i < num_univ_params; i++) ls.push_back(mk_meta_univ(m_ngen.next())); lean_assert(num_univ_params == ls.size()); return update_constant(e, to_list(ls.begin(), ls.end())); } /** \brief Make sure \c e is a type. If it is not, then try to apply coercions. */ expr ensure_type(expr const & e) { expr t = infer_type(e); if (is_sort(t)) return e; t = whnf(t); if (is_sort(t)) return e; if (has_metavar(t)) { t = whnf(t); if (is_sort(t)) return e; if (is_meta(t)) { // let type checker add constraint m_tc[m_relax_main_opaque]->ensure_sort(t, e); return e; } } optional c = get_coercion_to_sort(env(), t); if (c) return mk_app(*c, e, e.get_tag()); throw_kernel_exception(env(), e, [=](formatter const & fmt) { return pp_type_expected(fmt, e); }); } /** \brief Similar to instantiate_rev, but assumes that subst contains only local constants. When replacing a variable with a local, we copy the local constant and inherit the tag associated with the variable. This is a trick for getter better error messages */ expr instantiate_rev_locals(expr const & a, unsigned n, expr const * subst) { if (closed(a)) return a; return replace(a, [=](expr const & m, unsigned offset) -> optional { if (offset >= get_free_var_range(m)) return some_expr(m); // expression m does not contain free variables with idx >= offset if (is_var(m)) { unsigned vidx = var_idx(m); if (vidx >= offset) { unsigned h = offset + n; if (h < offset /* overflow, h is bigger than any vidx */ || vidx < h) { expr local = subst[n - (vidx - offset) - 1]; lean_assert(is_local(local)); return some_expr(copy_tag(m, copy(local))); } else { return some_expr(copy_tag(m, mk_var(vidx - n))); } } } return none_expr(); }); } expr visit_binding(expr e, expr_kind k) { scope_ctx scope(*this); buffer ds, ls, es; while (e.kind() == k) { es.push_back(e); expr d = binding_domain(e); d = instantiate_rev_locals(d, ls.size(), ls.data()); d = ensure_type(visit_expecting_type(d)); ds.push_back(d); expr l = mk_local(binding_name(e), d, binding_info(e)); if (binding_info(e).is_contextual()) m_context.add_local(l); m_full_context.add_local(l); ls.push_back(l); e = binding_body(e); } lean_assert(ls.size() == es.size() && ls.size() == ds.size()); e = instantiate_rev_locals(e, ls.size(), ls.data()); e = (k == expr_kind::Pi) ? ensure_type(visit_expecting_type(e)) : visit(e); e = abstract_locals(e, ls.size(), ls.data()); unsigned i = ls.size(); while (i > 0) { --i; e = update_binding(es[i], abstract_locals(ds[i], i, ls.data()), e); } return e; } expr visit_pi(expr const & e) { return visit_binding(e, expr_kind::Pi); } expr visit_lambda(expr const & e) { return visit_binding(e, expr_kind::Lambda); } expr visit_core(expr const & e) { if (is_placeholder(e)) { return visit_placeholder(e); } else if (is_choice(e)) { return visit_choice(e, none_expr()); } else if (is_by(e)) { return visit_by(e, none_expr()); } else { switch (e.kind()) { case expr_kind::Local: return e; case expr_kind::Meta: return e; case expr_kind::Sort: return visit_sort(e); case expr_kind::Var: lean_unreachable(); // LCOV_EXCL_LINE case expr_kind::Constant: return visit_constant(e); case expr_kind::Macro: return visit_macro(e); case expr_kind::Lambda: return visit_lambda(e); case expr_kind::Pi: return visit_pi(e); case expr_kind::App: return visit_app(e); } lean_unreachable(); // LCOV_EXCL_LINE } } expr visit(expr const & e) { expr r; expr b = e; if (is_explicit(e)) { b = get_explicit_arg(e); r = visit_core(get_explicit_arg(e)); } else if (is_explicit(get_app_fn(e))) { r = visit_core(e); } else { if (is_implicit(e)) { r = get_implicit_arg(e); if (is_explicit(r)) r = get_explicit_arg(r); b = r; r = visit_core(r); } else { r = visit_core(e); } if (!is_lambda(r)) { tag g = e.get_tag(); expr r_type = whnf(infer_type(r)); expr imp_arg; while (is_pi(r_type) && binding_info(r_type).is_implicit()) { imp_arg = mk_placeholder_meta(some_expr(binding_domain(r_type)), g); r = mk_app(r, imp_arg, g); r_type = whnf(instantiate(binding_body(r_type), imp_arg)); } } } save_info_data(b, r); return r; } lazy_list solve() { consume_tc_cnstrs(); buffer cs; cs.append(m_constraints); m_constraints.clear(); return unify(env(), cs.size(), cs.data(), m_ngen.mk_child(), true, ios().get_options()); } static void collect_metavars(expr const & e, buffer & mvars) { for_each(e, [&](expr const & e, unsigned) { if (is_metavar(e)) { mvars.push_back(e); return false; /* do not visit its type */ } return has_metavar(e); }); } void display_unsolved_proof_state(expr const & mvar, proof_state const & ps, char const * msg) { lean_assert(is_metavar(mvar)); if (!m_displayed_errors.contains(mlocal_name(mvar))) { m_displayed_errors.insert(mlocal_name(mvar)); auto out = regular(env(), ios()); flycheck_error err(out); display_error_pos(out, pip(), mvar); out << " unsolved placeholder, " << msg << "\n" << ps << endl; } } // For each occurrence of \c exact_tac in \c pre_tac, display its unassigned metavariables. // This is a trick to improve the quality of the error messages. void check_exact_tacs(expr const & pre_tac, substitution const & s) { for_each(pre_tac, [&](expr const & e, unsigned) { expr const & f = get_app_fn(e); if (is_constant(f) && const_name(f) == const_name(get_exact_tac_fn())) { display_unassigned_mvars(e, s); return false; } else { return true; } }); } optional get_pre_tactic_for(substitution & subst, expr const & mvar, name_set & visited) { if (auto it = m_local_tactic_hints.find(mlocal_name(mvar))) { expr pre_tac = subst.instantiate(*it); pre_tac = solve_unassigned_mvars(subst, pre_tac, visited); check_exact_tacs(pre_tac, subst); return some_expr(pre_tac); } else { return none_expr(); } } optional pre_tactic_to_tactic(expr const & pre_tac, expr const & mvar) { try { return optional(expr_to_tactic(env(), pre_tac, pip())); } catch (expr_to_tactic_exception & ex) { auto out = regular(env(), ios()); display_error_pos(out, pip(), mvar); out << " " << ex.what(); out << pp_indent_expr(out.get_formatter(), pre_tac) << endl << "failed at:" << pp_indent_expr(out.get_formatter(), ex.get_expr()) << endl; return optional(); } } optional get_local_tactic_hint(substitution & subst, expr const & mvar, name_set & visited) { if (auto pre_tac = get_pre_tactic_for(subst, mvar, visited)) { return pre_tactic_to_tactic(*pre_tac, mvar); } else { return optional(); } } /** \brief Try to instantiate meta-variable \c mvar (modulo its state ps) using the given tactic. If it succeeds, then update subst with the solution. Return true iff the metavariable \c mvar has been assigned. */ bool try_using(substitution & subst, expr const & mvar, proof_state const & ps, tactic const & tac) { lean_assert(length(ps.get_goals()) == 1); // make sure ps is a really a proof state for mvar. lean_assert(mlocal_name(get_app_fn(head(ps.get_goals()).get_meta())) == mlocal_name(mvar)); try { proof_state_seq seq = tac(env(), ios(), ps); auto r = seq.pull(); if (!r) { // tactic failed to produce any result display_unsolved_proof_state(mvar, ps, "tactic failed"); return false; } else if (!empty(r->first.get_goals())) { // tactic contains unsolved subgoals display_unsolved_proof_state(mvar, r->first, "unsolved subgoals"); return false; } else { subst = r->first.get_subst(); expr v = subst.instantiate(mvar); subst.assign(mlocal_name(mvar), v); return true; } } catch (tactic_exception & ex) { auto out = regular(env(), ios()); display_error_pos(out, pip(), ex.get_expr()); out << " tactic failed: " << ex.what() << "\n"; return false; } } void solve_unassigned_mvar(substitution & subst, expr mvar, name_set & visited) { if (visited.contains(mlocal_name(mvar))) return; visited.insert(mlocal_name(mvar)); if (auto local_hint = get_local_tactic_hint(subst, mvar, visited)) { auto meta = mvar_to_meta(mvar); if (!meta) return; meta = instantiate_meta(*meta, subst); expr type = m_tc[m_relax_main_opaque]->infer(*meta); // first solve unassigned metavariables in type type = solve_unassigned_mvars(subst, type, visited); proof_state ps(goals(goal(*meta, type)), subst, m_ngen.mk_child()); try_using(subst, mvar, ps, *local_hint); } } expr solve_unassigned_mvars(substitution & subst, expr e, name_set & visited) { e = subst.instantiate(e); buffer mvars; collect_metavars(e, mvars); if (mvars.empty()) return e; for (auto mvar : mvars) { check_interrupted(); solve_unassigned_mvar(subst, mvar, visited); } return subst.instantiate(e); } expr solve_unassigned_mvars(substitution & subst, expr const & e) { name_set visited; return solve_unassigned_mvars(subst, e, visited); } void display_unassigned_mvars(expr const & e, substitution const & s) { if (check_unassigned() && has_metavar(e)) { substitution tmp_s(s); for_each(e, [&](expr const & e, unsigned) { if (!is_metavar(e)) return has_metavar(e); if (auto it = m_mvar2meta.find(mlocal_name(e))) { expr meta = tmp_s.instantiate(*it); expr meta_type = tmp_s.instantiate(type_checker(env()).infer(meta)); goal g(meta, meta_type); display_unsolved_proof_state(e, proof_state(goals(g), substitution(), m_ngen), "don't know how to synthesize it"); } return false; }); } } /** \brief Apply substitution and solve remaining metavariables using tactics. */ expr apply(substitution & s, expr const & e, name_set & univ_params, buffer & new_params) { expr r = s.instantiate(e); if (has_univ_metavar(r)) r = univ_metavars_to_params_fn(env(), lls(), s, univ_params, new_params)(r); r = solve_unassigned_mvars(s, r); display_unassigned_mvars(r, s); return r; } std::tuple apply(substitution & s, expr const & e) { auto ps = collect_univ_params(e); buffer new_ps; expr r = apply(s, e, ps, new_ps); return std::make_tuple(r, to_list(new_ps.begin(), new_ps.end())); } void copy_info_to_manager(substitution s) { if (!infom()) return; for (auto & p : m_pre_info_data) p = type_info_data(p.get_line(), p.get_column(), s.instantiate(p.get_type())); infom()->append(m_pre_info_data); } std::tuple operator()(expr const & e, bool _ensure_type, bool relax_main_opaque) { flet set_relax(m_relax_main_opaque, relax_main_opaque && !get_hide_main_opaque(env())); expr r = visit(e); if (_ensure_type) r = ensure_type(r); auto p = solve().pull(); lean_assert(p); substitution s = p->first; auto result = apply(s, r); copy_info_to_manager(s); return result; } std::tuple operator()(expr const & t, expr const & v, name const & n, bool is_opaque) { lean_assert(!has_local(t)); lean_assert(!has_local(v)); expr r_t = ensure_type(visit(t)); // Opaque definitions in the main module may treat other opaque definitions (in the main module) as transparent. flet set_relax(m_relax_main_opaque, is_opaque && !get_hide_main_opaque(env())); expr r_v = visit(v); expr r_v_type = infer_type(r_v); justification j = mk_justification(r_v, [=](formatter const & fmt, substitution const & subst) { substitution s(subst); return pp_def_type_mismatch(fmt, n, s.instantiate(r_t), s.instantiate(r_v_type)); }); r_v = ensure_type(r_v, r_v_type, r_t, j, is_opaque); auto p = solve().pull(); lean_assert(p); substitution s = p->first; name_set univ_params = collect_univ_params(r_v, collect_univ_params(r_t)); buffer new_params; expr new_r_t = apply(s, r_t, univ_params, new_params); expr new_r_v = apply(s, r_v, univ_params, new_params); copy_info_to_manager(s); return std::make_tuple(new_r_t, new_r_v, to_list(new_params.begin(), new_params.end())); } }; static name g_tmp_prefix = name::mk_internal_unique_name(); std::tuple elaborate(elaborator_context & env, list const & ctx, expr const & e, bool relax_main_opaque, bool ensure_type) { return elaborator(env, ctx, name_generator(g_tmp_prefix))(e, ensure_type, relax_main_opaque); } std::tuple elaborate(elaborator_context & env, name const & n, expr const & t, expr const & v, bool is_opaque) { return elaborator(env, list(), name_generator(g_tmp_prefix))(t, v, n, is_opaque); } }