feat(library/defitional): add no_confusion construction for inductive datatypes that are not propositions
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10 changed files with 134 additions and 77 deletions
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@ -653,10 +653,9 @@ struct inductive_cmd_fn {
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env = mk_cases_on(env, inductive_decl_name(d));
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save_def_info(name(n, "cases_on"), pos);
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if (has_eq && has_heq) {
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env = mk_no_confusion(env, inductive_decl_name(d));
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name no_confusion_type_name{n, "no_confusion_type"};
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if (env.find(no_confusion_type_name)) {
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save_def_info(no_confusion_type_name, pos);
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if (optional<environment> new_env = mk_no_confusion(env, inductive_decl_name(d))) {
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env = *new_env;
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save_def_info(name{n, "no_confusion_type"}, pos);
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// save_def_info(name(n, "no_confusion"), pos);
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}
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}
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@ -18,7 +18,7 @@ static void throw_corrupted(name const & n) {
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throw exception(sstream() << "error in 'no_confusion' generation, '" << n << "' inductive datatype declaration is corrupted");
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}
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environment mk_no_confusion_type(environment const & env, name const & n) {
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optional<environment> mk_no_confusion_type(environment const & env, name const & n) {
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optional<inductive::inductive_decls> decls = inductive::is_inductive_decl(env, n);
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if (!decls)
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throw exception(sstream() << "error in 'no_confusion' generation, '" << n << "' is not an inductive datatype");
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@ -30,12 +30,10 @@ environment mk_no_confusion_type(environment const & env, name const & n) {
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level rlvl = mk_param_univ(head(lps));
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levels ilvls = param_names_to_levels(tail(lps));
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if (length(ilvls) != length(ind_decl.get_univ_params()))
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return env; // type is a proposition
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return optional<environment>(); // type is a proposition
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expr ind_type = instantiate_type_univ_params(ind_decl, ilvls);
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name eq_name("eq");
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name heq_name("heq");
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name eq_refl_name{"eq", "refl"};
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name heq_refl_name{"heq", "refl"};
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// All inductive datatype parameters and indices are arguments
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buffer<expr> args;
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while (is_pi(ind_type)) {
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@ -46,7 +44,7 @@ environment mk_no_confusion_type(environment const & env, name const & n) {
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if (!is_sort(ind_type) || args.size() < nparams)
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throw_corrupted(n);
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if (env.impredicative() && is_zero(sort_level(ind_type)))
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return env; // do nothing, inductive type is a proposition
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return optional<environment>(); // do nothing, inductive type is a proposition
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unsigned nindices = args.size() - nparams;
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// Create inductive datatype
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expr I = mk_app(mk_constant(n, ilvls), args);
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@ -135,10 +133,127 @@ environment mk_no_confusion_type(environment const & env, name const & n) {
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declaration new_d = mk_definition(env, no_confusion_type_name, lps, no_confusion_type_type, no_confusion_type_value,
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opaque, ind_decl.get_module_idx(), use_conv_opt);
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environment new_env = module::add(env, check(env, new_d));
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return add_protected(new_env, no_confusion_type_name);
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return some(add_protected(new_env, no_confusion_type_name));
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}
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environment mk_no_confusion(environment const & env, name const & n) {
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return mk_no_confusion_type(env, n);
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optional<environment> mk_no_confusion(environment const & env, name const & n) {
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optional<environment> env1 = mk_no_confusion_type(env, n);
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if (!env1)
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return env1;
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environment new_env = *env1;
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type_checker tc(new_env);
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inductive::inductive_decls decls = *inductive::is_inductive_decl(new_env, n);
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unsigned nparams = std::get<1>(decls);
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name_generator ngen;
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declaration no_confusion_type_decl = new_env.get(name{n, "no_confusion_type"});
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declaration cases_decl = new_env.get(name(n, "cases_on"));
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level_param_names lps = no_confusion_type_decl.get_univ_params();
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levels ls = param_names_to_levels(lps);
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expr no_confusion_type_type = instantiate_type_univ_params(no_confusion_type_decl, ls);
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name eq_name("eq");
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name heq_name("heq");
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name eq_refl_name{"eq", "refl"};
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name heq_refl_name{"heq", "refl"};
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buffer<expr> args;
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expr type = no_confusion_type_type;
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while (is_pi(type)) {
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expr arg = mk_local(ngen.next(), binding_name(type), binding_domain(type), mk_implicit_binder_info());
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args.push_back(arg);
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type = instantiate(binding_body(type), arg);
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}
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lean_assert(args.size() >= nparams + 3);
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unsigned nindices = args.size() - nparams - 3; // 3 is for P v1 v2
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expr range = mk_app(mk_constant(no_confusion_type_decl.get_name(), ls), args);
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expr P = args[args.size()-3];
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expr v1 = args[args.size()-2];
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expr v2 = args[args.size()-1];
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expr v_type = mlocal_type(v1);
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level v_lvl = sort_level(tc.ensure_type(v_type).first);
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expr eq_v = mk_app(mk_constant(eq_name, to_list(v_lvl)), v_type);
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expr H12 = mk_local(ngen.next(), "H12", mk_app(eq_v, v1, v2), binder_info());
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args.push_back(H12);
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name no_confusion_name{n, "no_confusion"};
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expr no_confusion_ty = Pi(args, range);
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// The gen proof is of the form
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// (fun H11 : v1 = v1, cases_on Params (fun Indices v1, no_confusion_type Params Indices P v1 v1) Indices v1
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// <for-each case>
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// (fun H : (equations -> P), H (refl) ... (refl))
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// ...
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// )
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// H11 is for creating the generalization
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expr H11 = mk_local(ngen.next(), "H11", mk_app(eq_v, v1, v1), binder_info());
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// Create the type former (fun Indices v1, no_confusion_type Params Indices P v1 v1)
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buffer<expr> type_former_args;
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for (unsigned i = nparams; i < nparams + nindices; i++)
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type_former_args.push_back(args[i]);
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type_former_args.push_back(v1);
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buffer<expr> no_confusion_type_args;
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for (unsigned i = 0; i < nparams + nindices; i++)
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no_confusion_type_args.push_back(args[i]);
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no_confusion_type_args.push_back(P);
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no_confusion_type_args.push_back(v1);
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no_confusion_type_args.push_back(v1);
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expr no_confusion_type_app = mk_app(mk_constant(no_confusion_type_decl.get_name(), ls), no_confusion_type_args);
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expr type_former = Fun(type_former_args, no_confusion_type_app);
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// create cases_on
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levels clvls = ls;
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expr cases_on = mk_app(mk_app(mk_constant(cases_decl.get_name(), clvls), nparams, args.data()), type_former);
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cases_on = mk_app(mk_app(cases_on, nindices, args.data() + nparams), v1);
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expr cot = tc.infer(cases_on).first;
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while (is_pi(cot)) {
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expr minor = tc.whnf(binding_domain(cot)).first;
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buffer<expr> minor_args;
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while (is_pi(minor)) {
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expr arg = mk_local(ngen.next(), binding_name(minor), binding_domain(minor), binding_info(minor));
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minor_args.push_back(arg);
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minor = tc.whnf(instantiate(binding_body(minor), arg)).first;
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}
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lean_assert(!minor_args.empty());
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expr H = minor_args.back();
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expr Ht = mlocal_type(H);
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buffer<expr> refl_args;
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while (is_pi(Ht)) {
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buffer<expr> eq_args;
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expr eq_fn = get_app_args(binding_domain(Ht), eq_args);
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if (const_name(eq_fn) == eq_name) {
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refl_args.push_back(mk_app(mk_constant(eq_refl_name, const_levels(eq_fn)), eq_args[0], eq_args[1]));
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} else {
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refl_args.push_back(mk_app(mk_constant(heq_refl_name, const_levels(eq_fn)), eq_args[0], eq_args[1]));
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}
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Ht = binding_body(Ht);
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}
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expr pr = mk_app(H, refl_args);
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cases_on = mk_app(cases_on, Fun(minor_args, pr));
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cot = binding_body(cot);
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}
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expr gen = Fun(H11, cases_on);
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// Now, we use gen to build the final proof using eq.rec
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//
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// eq.rec InductiveType v1 (fun (a : InductiveType), v1 = a -> no_confusion_type Params Indices v1 a) gen v2 H12 H12
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//
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name eq_rec_name{"eq", "rec"};
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expr eq_rec = mk_app(mk_constant(eq_rec_name, {head(ls), v_lvl}), v_type, v1);
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// create eq_rec type_former
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// (fun (a : InductiveType), v1 = a -> no_confusion_type Params Indices v1 a)
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expr a = mk_local(ngen.next(), "a", v_type, binder_info());
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expr H1a = mk_local(ngen.next(), "H1a", mk_app(eq_v, v1, a), binder_info());
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// reusing no_confusion_type_args... we just replace the last argument with a
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no_confusion_type_args.pop_back();
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no_confusion_type_args.push_back(a);
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expr no_confusion_type_app_1a = mk_app(mk_constant(no_confusion_type_decl.get_name(), ls), no_confusion_type_args);
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expr rec_type_former = Fun(a, Pi(H1a, no_confusion_type_app_1a));
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// finalize eq_rec
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eq_rec = mk_app(mk_app(eq_rec, rec_type_former, gen, v2, H12), H12);
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//
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expr no_confusion_val = Fun(args, eq_rec);
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bool opaque = false;
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bool use_conv_opt = true;
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declaration new_d = mk_definition(new_env, no_confusion_name, lps, no_confusion_ty, no_confusion_val,
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opaque, no_confusion_type_decl.get_module_idx(), use_conv_opt);
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new_env = module::add(new_env, check(new_env, new_d));
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return some(add_protected(new_env, no_confusion_name));
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}
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}
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@ -12,6 +12,8 @@ namespace lean {
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<tt>n.no_confusion_type</tt> and <tt>n.no_confusion</tt> to the environment.
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\remark This procedure assumes the environment contains eq, heq, n.cases_on</tt>
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\remark Return none if did not create constructions because type is a proposition.
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*/
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environment mk_no_confusion(environment const & env, name const & n);
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optional<environment> mk_no_confusion(environment const & env, name const & n);
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}
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@ -6,7 +6,7 @@ vnil : vector A zero,
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vcons : Π {n : nat}, A → vector A n → vector A (succ n)
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namespace vector
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definition no_confusion {A : Type} {n : nat} {P : Type} {v₁ v₂ : vector A n} : v₁ = v₂ → no_confusion_type P v₁ v₂ :=
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definition no_confusion2 {A : Type} {n : nat} {P : Type} {v₁ v₂ : vector A n} : v₁ = v₂ → no_confusion_type P v₁ v₂ :=
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assume H₁₂ : v₁ = v₂,
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begin
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show no_confusion_type P v₁ v₂, from
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@ -37,19 +37,8 @@ namespace tree
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end
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set_option pp.universes true
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check no_confusion_type
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definition no_confusion {A : Type} (P : Type) (t₁ t₂ : tree A) : t₁ = t₂ → no_confusion_type P t₁ t₂ :=
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assume e₁ : t₁ = t₂,
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have aux₁ : t₁ = t₁ → no_confusion_type P t₁ t₁, from
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take h, cases_on t₁
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(λ a, assume h : a = a → P, h (eq.refl a))
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(λ l r, assume h : l = l → r = r → P, h (eq.refl l) (eq.refl r)),
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eq.rec aux₁ e₁ e₁
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check no_confusion
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theorem leaf_ne_tree {A : Type} (a : A) (l r : tree A) : leaf a ≠ node l r :=
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assume h : leaf a = node l r,
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no_confusion false (leaf a) (node l r) h
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no_confusion h
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end tree
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@ -36,17 +36,6 @@ namespace tree
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pr₁ general
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end
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set_option pp.universes true
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check no_confusion_type
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definition no_confusion {A : Type} {P : Type} {t₁ t₂ : tree A} : t₁ = t₂ → no_confusion_type P t₁ t₂ :=
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assume e₁ : t₁ = t₂,
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have aux₁ : t₁ = t₁ → no_confusion_type P t₁ t₁, from
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take h, cases_on t₁
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(λ a, assume h : a = a → P, h (eq.refl a))
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(λ l r, assume h : l = l → r = r → P, h (eq.refl l) (eq.refl r)),
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eq.rec aux₁ e₁ e₁
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check no_confusion
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theorem leaf_ne_tree {A : Type} (a : A) (l r : tree A) : leaf a ≠ node l r :=
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@ -36,17 +36,6 @@ namespace tree
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pr₁ general
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end
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set_option pp.universes true
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check no_confusion_type
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definition no_confusion {A : Type} {P : Type} {t₁ t₂ : tree A} : t₁ = t₂ → no_confusion_type P t₁ t₂ :=
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assume e₁ : t₁ = t₂,
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have aux₁ : t₁ = t₁ → no_confusion_type P t₁ t₁, from
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take h, cases_on t₁
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(λ a, assume h : a = a → P, h (eq.refl a))
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(λ l r, assume h : l = l → r = r → P, h (eq.refl l) (eq.refl r)),
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eq.rec aux₁ e₁ e₁
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check no_confusion
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theorem leaf_ne_tree {A : Type} (a : A) (l r : tree A) : leaf a ≠ node l r :=
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@ -6,22 +6,15 @@ vnil : vector A zero,
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vcons : Π {n : nat}, A → vector A n → vector A (succ n)
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namespace vector
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definition no_confusion {A : Type} {n : nat} {P : Type} {v₁ v₂ : vector A n} : v₁ = v₂ → no_confusion_type P v₁ v₂ :=
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assume H₁₂ : v₁ = v₂,
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have aux : v₁ = v₁ → no_confusion_type P v₁ v₁, from
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take H₁₁, cases_on v₁
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(assume h : P, h)
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(take n₁ h₁ t₁, assume h : (Π (H : n₁ = n₁), h₁ = h₁ → t₁ == t₁ → P),
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h rfl rfl !heq.refl),
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eq.rec aux H₁₂ H₁₂
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print definition no_confusion
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theorem vcons.inj₁ {A : Type} {n : nat} (a₁ a₂ : A) (v₁ v₂ : vector A n) : vcons a₁ v₁ = vcons a₂ v₂ → a₁ = a₂ :=
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begin
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intro h, apply (no_confusion h), intros, assumption
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end
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theorem vcons.inj₂ {A : Type} {n : nat} (a₁ a₂ : A) (v₁ v₂ : vector A n) : vcons a₁ v₁ = vcons a₂ v₂ → v₁ == v₂ :=
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theorem vcons.inj₂ {A : Type} {n : nat} (a₁ a₂ : A) (v₁ v₂ : vector A n) : vcons a₁ v₁ = vcons a₂ v₂ → v₁ = v₂ :=
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begin
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intro h, apply (no_confusion h), intros, eassumption
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intro h, apply heq.to_eq, apply (no_confusion h), intros, eassumption,
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end
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end vector
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@ -6,15 +6,6 @@ vnil : vector A zero,
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vcons : Π {n : nat}, A → vector A n → vector A (succ n)
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namespace vector
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definition no_confusion {A : Type} {n : nat} {P : Type} {v₁ v₂ : vector A n} : v₁ = v₂ → no_confusion_type P v₁ v₂ :=
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assume H₁₂ : v₁ = v₂,
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have aux : v₁ = v₁ → no_confusion_type P v₁ v₁, from
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take H₁₁, cases_on v₁
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(assume h : P, h)
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(take n₁ h₁ t₁, assume h : (Π (H : n₁ = n₁), h₁ = h₁ → t₁ == t₁ → P),
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h rfl rfl !heq.refl),
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eq.rec aux H₁₂ H₁₂
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theorem vcons.inj₁ {A : Type} {n : nat} (a₁ a₂ : A) (v₁ v₂ : vector A n) : vcons a₁ v₁ = vcons a₂ v₂ → a₁ = a₂ :=
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assume h, no_confusion h (λ n h t, h)
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@ -6,19 +6,9 @@ vnil : vector A zero,
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vcons : Π {n : nat}, A → vector A n → vector A (succ n)
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namespace vector
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definition no_confusion {A : Type} {n : nat} {P : Type} {v₁ v₂ : vector A n} : v₁ = v₂ → no_confusion_type P v₁ v₂ :=
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assume H₁₂ : v₁ = v₂,
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have aux : v₁ = v₁ → no_confusion_type P v₁ v₁, from
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take H₁₁, cases_on v₁
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(assume h : P, h)
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(take n₁ h₁ t₁, assume h : (Π (H : n₁ = n₁), h₁ = h₁ → t₁ == t₁ → P),
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h rfl rfl !heq.refl),
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eq.rec aux H₁₂ H₁₂
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theorem vcons.inj₁ {A : Type} {n : nat} (a₁ a₂ : A) (v₁ v₂ : vector A n) : vcons a₁ v₁ = vcons a₂ v₂ → a₁ = a₂ :=
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assume h, no_confusion h (λ n h t, h)
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theorem vcons.inj₂ {A : Type} {n : nat} (a₁ a₂ : A) (v₁ v₂ : vector A n) : vcons a₁ v₁ = vcons a₂ v₂ → v₁ == v₂ :=
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assume h, no_confusion h (λ n h t, t)
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end vector
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