lean2/src/library/definitional/util.cpp

/*
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 "kernel/find_fn.h"
#include "kernel/instantiate.h"
#include "kernel/inductive/inductive.h"

namespace lean {
/** \brief Return true if environment has a constructor named \c c that returns
    an element of the inductive datatype named \c I, and \c c must have \c nparams parameters.
*/
bool has_constructor(environment const & env, name const & c, name const & I, unsigned nparams) {
    auto d = env.find(c);
    if (!d || d->is_definition())
        return false;
    expr type = d->get_type();
    unsigned i = 0;
    while (is_pi(type)) {
        i++;
        type = binding_body(type);
    }
    if (i != nparams)
        return false;
    type = get_app_fn(type);
    return is_constant(type) && const_name(type) == I;
}

bool has_unit_decls(environment const & env) {
    return has_constructor(env, name{"unit", "star"}, "unit", 0);
}

bool has_eq_decls(environment const & env) {
    return has_constructor(env, name{"eq", "refl"}, "eq", 2);
}

bool has_heq_decls(environment const & env) {
    return has_constructor(env, name{"heq", "refl"}, "heq", 2);
}

bool has_prod_decls(environment const & env) {
    return has_constructor(env, name{"prod", "mk"}, "prod", 4);
}

bool is_recursive_datatype(environment const & env, name const & n) {
    optional<inductive::inductive_decls> decls = inductive::is_inductive_decl(env, n);
    if (!decls)
        return false;
    for (inductive::inductive_decl const & decl : std::get<2>(*decls)) {
        for (inductive::intro_rule const & intro : inductive::inductive_decl_intros(decl)) {
            expr type = inductive::intro_rule_type(intro);
            while (is_pi(type)) {
                if (find(binding_domain(type), [&](expr const & e, unsigned) {
                            return is_constant(e) && const_name(e) == n; })) {
                    return true;
                }
                type = binding_body(type);
            }
        }
    }
    return false;
}

level get_datatype_level(expr ind_type) {
    while (is_pi(ind_type))
        ind_type = binding_body(ind_type);
    return sort_level(ind_type);
}

bool is_inductive_predicate(environment const & env, name const & n) {
    if (!env.impredicative())
        return false; // environment does not have Prop
    if (!inductive::is_inductive_decl(env, n))
        return false; // n is not inductive datatype
    return is_zero(get_datatype_level(env.get(n).get_type()));
}

expr instantiate_univ_param (expr const & e, name const & p, level const & l) {
    return instantiate_univ_params(e, to_list(p), to_list(l));
}

expr to_telescope(name_generator & ngen, expr type, buffer<expr> & telescope, optional<binder_info> const & binfo) {
    while (is_pi(type)) {
        expr local;
        if (binfo)
            local = mk_local(ngen.next(), binding_name(type), binding_domain(type), *binfo);
        else
            local = mk_local(ngen.next(), binding_name(type), binding_domain(type), binder_info(type));
        telescope.push_back(local);
        type = instantiate(binding_body(type), local);
    }
    return type;
}
}
feat(library/definitional/util): add `is_recursive_datatype` auxiliary function 2014-11-11 20:26:26 +00:00			`/*`
			`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 "kernel/find_fn.h"`
feat(definitional/brec_on): add 'mk_below' skeleton 2014-11-11 22:55:21 +00:00			`#include "kernel/instantiate.h"`
feat(library/definitional/util): add `is_recursive_datatype` auxiliary function 2014-11-11 20:26:26 +00:00			`#include "kernel/inductive/inductive.h"`

			`namespace lean {`
refactor(library/definitional/util): remove code duplication 2014-11-11 21:53:41 +00:00			`/** \brief Return true if environment has a constructor named \c c that returns`
			`an element of the inductive datatype named \c I, and \c c must have \c nparams parameters.`
			`*/`
			`bool has_constructor(environment const & env, name const & c, name const & I, unsigned nparams) {`
			`auto d = env.find(c);`
			`if (!d \|\| d->is_definition())`
refactor(library/definitional): combine auxiliary functions used by definitional package in a single module 2014-11-11 21:46:36 +00:00			`return false;`
refactor(library/definitional/util): remove code duplication 2014-11-11 21:53:41 +00:00			`expr type = d->get_type();`
			`unsigned i = 0;`
			`while (is_pi(type)) {`
			`i++;`
			`type = binding_body(type);`
			`}`
			`if (i != nparams)`
refactor(library/definitional): combine auxiliary functions used by definitional package in a single module 2014-11-11 21:46:36 +00:00			`return false;`
refactor(library/definitional/util): remove code duplication 2014-11-11 21:53:41 +00:00			`type = get_app_fn(type);`
			`return is_constant(type) && const_name(type) == I;`
			`}`

			`bool has_unit_decls(environment const & env) {`
			`return has_constructor(env, name{"unit", "star"}, "unit", 0);`
refactor(library/definitional): combine auxiliary functions used by definitional package in a single module 2014-11-11 21:46:36 +00:00			`}`

			`bool has_eq_decls(environment const & env) {`
refactor(library/definitional/util): remove code duplication 2014-11-11 21:53:41 +00:00			`return has_constructor(env, name{"eq", "refl"}, "eq", 2);`
refactor(library/definitional): combine auxiliary functions used by definitional package in a single module 2014-11-11 21:46:36 +00:00			`}`

			`bool has_heq_decls(environment const & env) {`
refactor(library/definitional/util): remove code duplication 2014-11-11 21:53:41 +00:00			`return has_constructor(env, name{"heq", "refl"}, "heq", 2);`
refactor(library/definitional): combine auxiliary functions used by definitional package in a single module 2014-11-11 21:46:36 +00:00			`}`

feat(definitional/brec_on): add 'mk_below' skeleton 2014-11-11 22:55:21 +00:00			`bool has_prod_decls(environment const & env) {`
			`return has_constructor(env, name{"prod", "mk"}, "prod", 4);`
			`}`

feat(library/definitional/util): add `is_recursive_datatype` auxiliary function 2014-11-11 20:26:26 +00:00			`bool is_recursive_datatype(environment const & env, name const & n) {`
			`optional<inductive::inductive_decls> decls = inductive::is_inductive_decl(env, n);`
			`if (!decls)`
			`return false;`
			`for (inductive::inductive_decl const & decl : std::get<2>(*decls)) {`
			`for (inductive::intro_rule const & intro : inductive::inductive_decl_intros(decl)) {`
			`expr type = inductive::intro_rule_type(intro);`
			`while (is_pi(type)) {`
			`if (find(binding_domain(type), [&](expr const & e, unsigned) {`
feat(definitional/brec_on): add 'mk_below' skeleton 2014-11-11 22:55:21 +00:00			`return is_constant(e) && const_name(e) == n; })) {`
feat(library/definitional/util): add `is_recursive_datatype` auxiliary function 2014-11-11 20:26:26 +00:00			`return true;`
feat(definitional/brec_on): add 'mk_below' skeleton 2014-11-11 22:55:21 +00:00			`}`
feat(library/definitional/util): add `is_recursive_datatype` auxiliary function 2014-11-11 20:26:26 +00:00			`type = binding_body(type);`
			`}`
			`}`
			`}`
			`return false;`
			`}`
feat(library/definitional/util): add is_inductive_predicate auxiliary predicate 2014-11-11 21:24:58 +00:00
refactor(library/definitional): add some helper functions 2014-11-12 20:24:22 +00:00			`level get_datatype_level(expr ind_type) {`
			`while (is_pi(ind_type))`
			`ind_type = binding_body(ind_type);`
			`return sort_level(ind_type);`
			`}`

feat(library/definitional/util): add is_inductive_predicate auxiliary predicate 2014-11-11 21:24:58 +00:00			`bool is_inductive_predicate(environment const & env, name const & n) {`
			`if (!env.impredicative())`
			`return false; // environment does not have Prop`
			`if (!inductive::is_inductive_decl(env, n))`
			`return false; // n is not inductive datatype`
refactor(library/definitional): add some helper functions 2014-11-12 20:24:22 +00:00			`return is_zero(get_datatype_level(env.get(n).get_type()));`
			`}`

			`expr instantiate_univ_param (expr const & e, name const & p, level const & l) {`
			`return instantiate_univ_params(e, to_list(p), to_list(l));`
feat(library/definitional/util): add is_inductive_predicate auxiliary predicate 2014-11-11 21:24:58 +00:00			`}`
feat(definitional/brec_on): add 'mk_below' skeleton 2014-11-11 22:55:21 +00:00
			`expr to_telescope(name_generator & ngen, expr type, buffer<expr> & telescope, optional<binder_info> const & binfo) {`
			`while (is_pi(type)) {`
			`expr local;`
			`if (binfo)`
			`local = mk_local(ngen.next(), binding_name(type), binding_domain(type), *binfo);`
			`else`
			`local = mk_local(ngen.next(), binding_name(type), binding_domain(type), binder_info(type));`
			`telescope.push_back(local);`
			`type = instantiate(binding_body(type), local);`
			`}`
			`return type;`
			`}`
feat(library/definitional/util): add `is_recursive_datatype` auxiliary function 2014-11-11 20:26:26 +00:00			`}`