/* Copyright (c) 2013 Microsoft Corporation. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Author: Leonardo de Moura */ #pragma once #include #include #include "object.h" #include "level.h" namespace lean { /** \brief Lean environment for defining constants, inductive datatypes, universe variables, et.c */ class environment { private: struct imp; std::shared_ptr m_imp; void check_type(name const & n, expr const & t, expr const & v); explicit environment(std::shared_ptr const & ptr); explicit environment(imp * new_ptr); unsigned get_num_objects(bool local) const; object const & get_object(unsigned i, bool local) const; public: environment(); ~environment(); // ======================================= // Parent/Child environment management /** \brief Create a child environment. This environment will only allow "read-only" operations until all children environments are deleted. */ environment mk_child() const; /** \brief Return true iff this environment has children environments. */ bool has_children() const; /** \brief Return true iff this environment has a parent environment. */ bool has_parent() const; /** \brief Return parent environment of this environment. \pre has_parent() */ environment parent() const; // ======================================= // ======================================= // Universe variables /** \brief Add a new universe variable with name \c n and constraint n >= l. Return the new variable. \remark An exception is thrown if a universe inconsistency is detected. */ level add_uvar(name const & n, level const & l); level add_uvar(name const & n) { return add_uvar(n, level()); } /** \brief Return true iff the constraint l1 >= l2 is implied by the constraints in the environment. */ bool is_ge(level const & l1, level const & l2) const; /** \brief Return universal variable with the given name. Throw an exception if variable is not defined in this environment. */ level get_uvar(name const & n) const; // ======================================= // ======================================= // Environment Objects /** \brief Add a new definition n : t := v. It throws an exception if v does not have type t. It throws an exception if there is already an object with the given name. If opaque == true, then definition is not used by normalizer. */ void add_definition(name const & n, expr const & t, expr const & v, bool opaque = false); void add_theorem(name const & n, expr const & t, expr const & v); /** \brief Add a new definition n : infer_type(v) := v. It throws an exception if there is already an object with the given name. If opaque == true, then definition is not used by normalizer. */ void add_definition(name const & n, expr const & v, bool opaque = false); /** \brief Add a new fact (Axiom or Fact) to the environment. It throws an exception if there is already an object with the given name. */ void add_axiom(name const & n, expr const & t); void add_var(name const & n, expr const & t); /** \brief Register the given unanymous object in this environment. The environment assume the object ownership. */ void add_neutral_object(neutral_object_cell * o); /** \brief Return the object with the given name. It throws an exception if the environment does not have an object with the given name. */ object const & get_object(name const & n) const; /** \brief Find a given object in the environment. Return the null object if there is no object with the given name. \remark Object implements operator bool(), and the null object returns false. */ object const & find_object(name const & n) const; /** \brief Return true iff the environment has an object with the given name */ bool has_object(name const & n) const { return find_object(n); } /** \brief Iterator for Lean environment objects. */ class object_iterator { environment const & m_env; unsigned m_idx; bool m_local; friend class environment; object_iterator(environment const & env, unsigned idx, bool local):m_env(env), m_idx(idx), m_local(local) {} public: object_iterator(object_iterator const & s):m_env(s.m_env), m_idx(s.m_idx), m_local(s.m_local) {} object_iterator & operator++() { ++m_idx; return *this; } object_iterator operator++(int) { object_iterator tmp(*this); operator++(); return tmp; } bool operator==(object_iterator const & s) const { lean_assert(&m_env == &(s.m_env)); return m_idx == s.m_idx; } bool operator!=(object_iterator const & s) const { return !operator==(s); } object const & operator*() { return m_env.get_object(m_idx, m_local); } }; /** \brief Return an iterator to the beginning of the sequence of objects stored in this environment. \remark The objects in this environment and ancestor environments are considered */ object_iterator begin_objects() const { return object_iterator(*this, 0, false); } /** \brief Return an iterator to the end of the sequence of objects stored in this environment. \remark The objects in this environment and ancestor environments are considered */ object_iterator end_objects() const { return object_iterator(*this, get_num_objects(false), false); } /** \brief Return an iterator to the beginning of the sequence of objects stored in this environment (objects in ancestor environments are ingored). */ object_iterator begin_local_objects() const { return object_iterator(*this, 0, true); } /** \brief Return an iterator to the end of the sequence of objects stored in this environment (objects in ancestor environments are ingored). */ object_iterator end_local_objects() const { return object_iterator(*this, get_num_objects(true), true); } // ======================================= /** \brief Display universal variable constraints and objects stored in this environment and its parents. */ void display(std::ostream & out) const; }; }