lean2/src/kernel/environment.cpp

579 lines
19 KiB
C++
Raw Normal View History

/*
Copyright (c) 2013 Microsoft Corporation. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Author: Leonardo de Moura
*/
#include <algorithm>
#include <vector>
#include <atomic>
2013-10-26 18:07:06 +00:00
#include <tuple>
#include <unordered_map>
#include <mutex>
#include "util/safe_arith.h"
#include "kernel/for_each.h"
#include "kernel/kernel_exception.h"
#include "kernel/environment.h"
#include "kernel/threadsafe_environment.h"
#include "kernel/type_checker.h"
#include "kernel/normalizer.h"
namespace lean {
class extension_factory {
std::vector<environment::mk_extension> m_makers;
std::mutex m_makers_mutex;
public:
unsigned register_extension(environment::mk_extension mk) {
std::lock_guard<std::mutex> lock(m_makers_mutex);
unsigned r = m_makers.size();
m_makers.push_back(mk);
return r;
}
std::unique_ptr<environment::extension> mk(unsigned extid) {
std::lock_guard<std::mutex> lock(m_makers_mutex);
return m_makers[extid]();
}
};
static std::unique_ptr<extension_factory> g_extension_factory;
static extension_factory & get_extension_factory() {
if (!g_extension_factory)
g_extension_factory.reset(new extension_factory());
return *g_extension_factory;
}
unsigned environment::register_extension(mk_extension mk) {
return get_extension_factory().register_extension(mk);
}
/** \brief Implementation of the Lean environment. */
struct environment::imp {
// Remark: only named objects are stored in the dictionary.
typedef std::unordered_map<name, object, name_hash, name_eq> object_dictionary;
typedef std::tuple<level, level, int> constraint;
// Universe variable management
std::vector<constraint> m_constraints;
std::vector<level> m_uvars;
// Children environment management
#ifdef LEAN_THREAD_UNSAFE
unsigned m_num_children;
#else
std::atomic<unsigned> m_num_children;
#endif
std::shared_ptr<imp> m_parent;
// Object management
std::vector<object> m_objects;
object_dictionary m_object_dictionary;
std::unique_ptr<type_checker> m_type_checker;
std::vector<std::unique_ptr<extension>> m_extensions;
friend class extension;
// This mutex is only used to implement threadsafe environment objects
// in the external APIs
shared_mutex m_mutex;
extension & get_extension_core(unsigned extid) {
if (extid >= m_extensions.size())
m_extensions.resize(extid+1);
if (!m_extensions[extid]) {
std::unique_ptr<extension> ext = get_extension_factory().mk(extid);
ext->m_extid = extid;
ext->m_env = this;
m_extensions[extid].swap(ext);
}
return *(m_extensions[extid].get());
}
unsigned get_max_weight(expr const & e) {
unsigned w = 0;
auto proc = [&](expr const & c, unsigned) {
if (is_constant(c)) {
object const & obj = get_object_core(const_name(c));
if (obj)
w = std::max(w, obj.get_weight());
}
return true;
};
for_each_fn<decltype(proc)> visitor(proc);
visitor(e);
return w;
}
/**
\brief Return true iff this environment has children.
\remark If an environment has children than it cannot be
updated. That is, it is read-only.
*/
bool has_children() const { return m_num_children > 0; }
void inc_children() { m_num_children++; }
void dec_children() { m_num_children--; }
/** \brief Return true iff this environment has a parent environment */
bool has_parent() const { return m_parent != nullptr; }
/** \brief Throw exception if environment or its ancestors already have an object with the given name. */
void check_name_core(name const & n, environment const & env) {
if (has_parent())
m_parent->check_name_core(n, env);
if (m_object_dictionary.find(n) != m_object_dictionary.end())
throw already_declared_exception(env, n);
}
void check_name(name const & n, environment const & env) {
if (has_children())
throw read_only_environment_exception(env);
check_name_core(n, env);
}
/** \brief Store new named object inside internal data-structures */
void register_named_object(object const & new_obj) {
m_objects.push_back(new_obj);
m_object_dictionary.insert(std::make_pair(new_obj.get_name(), new_obj));
}
/**
\brief Return the object named \c n in the environment or its
ancestors. Return null object if there is no object with the
given name.
*/
object const & get_object_core(name const & n) const {
auto it = m_object_dictionary.find(n);
if (it == m_object_dictionary.end()) {
if (has_parent())
return m_parent->get_object_core(n);
else
return object::null();
} else {
return it->second;
}
}
object const & get_object(name const & n, environment const & env) const {
object const & obj = get_object_core(n);
if (obj)
return obj;
else
throw unknown_object_exception(env, n);
}
/**
\brief Return true if u >= v + k is implied by constraints
\pre is_uvar(u) && is_uvar(v)
*/
bool is_implied(level const & u, level const & v, int k) {
lean_assert(is_uvar(u) && is_uvar(v));
if (u == v)
return k <= 0;
else
return std::any_of(m_constraints.begin(), m_constraints.end(),
[&](constraint const & c) { return std::get<0>(c) == u && std::get<1>(c) == v && std::get<2>(c) >= k; });
}
/** \brief Return true iff l1 >= l2 + k by asserted universe constraints. */
bool is_ge(level const & l1, level const & l2, int k) {
if (l1 == l2)
return k <= 0;
switch (kind(l2)) {
case level_kind::UVar:
switch (kind(l1)) {
case level_kind::UVar: return is_implied(l1, l2, k);
case level_kind::Lift: return is_ge(lift_of(l1), l2, safe_sub(k, lift_offset(l1)));
case level_kind::Max: return std::any_of(max_begin_levels(l1), max_end_levels(l1), [&](level const & l) { return is_ge(l, l2, k); });
}
case level_kind::Lift: return is_ge(l1, lift_of(l2), safe_add(k, lift_offset(l2)));
case level_kind::Max: return std::all_of(max_begin_levels(l2), max_end_levels(l2), [&](level const & l) { return is_ge(l1, l, k); });
}
lean_unreachable(); // LCOV_EXCL_LINE
}
/** \brief Return true iff l1 >= l2 is implied by asserted universe constraints. */
bool is_ge(level const & l1, level const & l2) {
if (has_parent())
return m_parent->is_ge(l1, l2);
else
return is_ge(l1, l2, 0);
}
/** \brief Add a new universe variable */
level add_uvar(name const & n, environment const & env) {
check_name(n, env);
level r(n);
m_uvars.push_back(r);
return r;
}
/**
\brief Add basic constraint u >= v + d, and all basic
constraints implied by transitivity.
\pre is_uvar(u) && is_uvar(v)
*/
void add_constraint(level const & u, level const & v, int d) {
lean_assert(is_uvar(u) && is_uvar(v));
if (is_implied(u, v, d))
return; // redundant
buffer<constraint> to_add;
for (constraint const & c : m_constraints) {
if (std::get<0>(c) == v) {
level const & l3 = std::get<1>(c);
int u_l3_d = safe_add(d, std::get<2>(c));
if (!is_implied(u, l3, u_l3_d))
to_add.emplace_back(u, l3, u_l3_d);
}
}
m_constraints.emplace_back(u, v, d);
2013-09-13 23:14:24 +00:00
for (constraint const & c : to_add) {
m_constraints.push_back(c);
}
}
/**
\brief Add all basic constraints implied by n >= l + k
A basic constraint is a constraint of the form u >= v + k
where u and v are universe variables.
*/
void add_constraints(level const & n, level const & l, int k) {
lean_assert(is_uvar(n));
switch (kind(l)) {
case level_kind::UVar: add_constraint(n, l, k); return;
case level_kind::Lift: add_constraints(n, lift_of(l), safe_add(k, lift_offset(l))); return;
case level_kind::Max: std::for_each(max_begin_levels(l), max_end_levels(l), [&](level const & l1) { add_constraints(n, l1, k); }); return;
}
lean_unreachable(); // LCOV_EXCL_LINE
}
/** \brief Add a new universe variable with constraint n >= l */
level add_uvar(name const & n, level const & l, environment const & env) {
if (has_parent())
throw kernel_exception(env, "invalid universe declaration, universe variables can only be declared in top-level environments");
if (has_children())
throw read_only_environment_exception(env);
level r = add_uvar(n, env);
add_constraints(r, l, 0);
register_named_object(mk_uvar_decl(n, l));
return r;
}
/**
\brief Return the universe variable with given name. Throw an
exception if the environment and its ancestors do not
contain a universe variable named \c n.
*/
level get_uvar(name const & n, environment const & env) const {
if (has_parent()) {
return m_parent->get_uvar(n, env);
} else {
auto it = std::find_if(m_uvars.begin(), m_uvars.end(), [&](level const & l) { return uvar_name(l) == n; });
if (it == m_uvars.end())
throw unknown_universe_variable_exception(env, n);
else
return *it;
}
}
/**
\brief Initialize the set of universe variables with bottom
*/
void init_uvars() {
m_uvars.emplace_back();
}
/**
\brief Throw an exception if \c t is not a type or type of \c
v is not convertible to \c t.
\remark env is the smart pointer of imp. We need it because
infer_universe and infer_type expect an environment instead of environment::imp.
*/
void check_type(name const & n, expr const & t, expr const & v, environment const & env) {
m_type_checker->check_type(t);
expr v_t = m_type_checker->infer_type(v);
if (!m_type_checker->is_convertible(v_t, t))
throw def_type_mismatch_exception(env, n, t, v, v_t);
}
/** \brief Throw exception if it is not a valid new definition */
void check_new_definition(name const & n, expr const & t, expr const & v, environment const & env) {
check_name(n, env);
check_type(n, t, v, env);
}
/** \brief Add a new builtin value to this environment */
void add_builtin(expr const & v, environment const & env) {
if (!is_value(v))
throw invalid_builtin_value_declaration(env, v);
name const & n = to_value(v).get_name();
check_name(n, env);
name const & u = to_value(v).get_unicode_name();
check_name(u, env);
register_named_object(mk_builtin(v));
if (u != n) {
add_definition(u, to_value(v).get_type(), mk_constant(n), false, env);
}
}
/** \brief Add a new builtin value set to this environment */
void add_builtin_set(expr const & r, environment const & env) {
if (!is_value(r))
throw invalid_builtin_value_declaration(env, r);
check_name(to_value(r).get_name(), env);
register_named_object(mk_builtin_set(r));
}
/** \brief Add new definition. */
void add_definition(name const & n, expr const & t, expr const & v, bool opaque, environment const & env) {
check_new_definition(n, t, v, env);
unsigned w = get_max_weight(v) + 1;
register_named_object(mk_definition(n, t, v, opaque, w));
}
/**
\brief Add new definition.
The type of the new definition is the type of \c v.
*/
void add_definition(name const & n, expr const & v, bool opaque, environment const & env) {
check_name(n, env);
expr v_t = m_type_checker->infer_type(v);
unsigned w = get_max_weight(v) + 1;
register_named_object(mk_definition(n, v_t, v, opaque, w));
}
/** \brief Add new theorem. */
void add_theorem(name const & n, expr const & t, expr const & v, environment const & env) {
check_new_definition(n, t, v, env);
register_named_object(mk_theorem(n, t, v));
}
/** \brief Add new axiom. */
void add_axiom(name const & n, expr const & t, environment const & env) {
check_name(n, env);
m_type_checker->check_type(t);
register_named_object(mk_axiom(n, t));
}
/** \brief Add new variable. */
void add_var(name const & n, expr const & t, environment const & env) {
check_name(n, env);
m_type_checker->check_type(t);
register_named_object(mk_var_decl(n, t));
}
unsigned get_num_objects(bool local) const {
if (local || !has_parent()) {
return m_objects.size();
} else {
return m_objects.size() + m_parent->get_num_objects(false);
}
}
object const & get_object(unsigned i, bool local) const {
if (local || !has_parent()) {
return m_objects[i];
} else {
unsigned num_parent_objects = m_parent->get_num_objects(false);
if (i >= num_parent_objects)
return m_objects[i - num_parent_objects];
else
return m_parent->get_object(i, false);
}
}
expr infer_type(expr const & e, context const & ctx) {
return m_type_checker->infer_type(e, ctx);
}
expr normalize(expr const & e, context const & ctx) {
return m_type_checker->get_normalizer()(e, ctx);
}
/** \brief Display universal variable constraints and objects stored in this environment and its parents. */
void display(std::ostream & out, environment const & env) const {
if (has_parent())
m_parent->display(out, env);
for (object const & obj : m_objects) {
if (obj.has_name()) {
out << obj.keyword() << " " << obj.get_name() << "\n";
}
}
}
imp():
m_num_children(0) {
init_uvars();
}
imp(std::shared_ptr<imp> const & parent):
m_num_children(0),
m_parent(parent) {
m_parent->inc_children();
}
~imp() {
if (m_parent)
m_parent->dec_children();
}
};
environment::environment():
m_ptr(new imp()) {
m_ptr->m_type_checker.reset(new type_checker(*this));
}
// used when creating a new child environment
environment::environment(std::shared_ptr<imp> const & parent, bool):
m_ptr(new imp(parent)) {
m_ptr->m_type_checker.reset(new type_checker(*this));
}
// used when creating a reference to the parent environment
environment::environment(std::shared_ptr<imp> const & ptr):
m_ptr(ptr) {
}
environment::environment(weak_ref const & r) {
if (r.expired())
throw exception("weak reference to environment object has expired (i.e., the environment has been deleted)");
m_ptr = r.lock();
}
environment::~environment() {
}
environment environment::mk_child() const {
return environment(m_ptr, true);
}
bool environment::has_children() const {
return m_ptr->has_children();
}
bool environment::has_parent() const {
return m_ptr->has_parent();
}
environment environment::parent() const {
lean_assert(has_parent());
return environment(m_ptr->m_parent);
}
level environment::add_uvar(name const & n, level const & l) {
return m_ptr->add_uvar(n, l, *this);
}
bool environment::is_ge(level const & l1, level const & l2) const {
return m_ptr->is_ge(l1, l2);
}
level environment::get_uvar(name const & n) const {
return m_ptr->get_uvar(n, *this);
}
void environment::add_builtin(expr const & v) {
return m_ptr->add_builtin(v, *this);
}
void environment::add_builtin_set(expr const & r) {
return m_ptr->add_builtin_set(r, *this);
}
void environment::add_definition(name const & n, expr const & t, expr const & v, bool opaque) {
m_ptr->add_definition(n, t, v, opaque, *this);
}
void environment::add_theorem(name const & n, expr const & t, expr const & v) {
m_ptr->add_theorem(n, t, v, *this);
}
void environment::add_definition(name const & n, expr const & v, bool opaque) {
m_ptr->add_definition(n, v, opaque, *this);
}
void environment::add_axiom(name const & n, expr const & t) {
m_ptr->add_axiom(n, t, *this);
}
void environment::add_var(name const & n, expr const & t) {
m_ptr->add_var(n, t, *this);
}
void environment::add_neutral_object(neutral_object_cell * o) {
m_ptr->m_objects.push_back(mk_neutral(o));
}
object const & environment::get_object(name const & n) const {
return m_ptr->get_object(n, *this);
}
object const & environment::find_object(name const & n) const {
return m_ptr->get_object_core(n);
}
unsigned environment::get_num_objects(bool local) const {
return m_ptr->get_num_objects(local);
}
object const & environment::get_object(unsigned i, bool local) const {
return m_ptr->get_object(i, local);
}
expr environment::infer_type(expr const & e, context const & ctx) const {
return m_ptr->infer_type(e, ctx);
}
expr environment::normalize(expr const & e, context const & ctx) const {
return m_ptr->normalize(e, ctx);
}
void environment::display(std::ostream & out) const {
m_ptr->display(out, *this);
}
environment::extension const & environment::get_extension_core(unsigned extid) const {
return m_ptr->get_extension_core(extid);
}
environment::extension & environment::get_extension_core(unsigned extid) {
return m_ptr->get_extension_core(extid);
}
environment::extension::extension():
m_env(nullptr),
m_extid(0) {
}
environment::extension::~extension() {
}
environment::extension const * environment::extension::get_parent_core() const {
if (m_env == nullptr)
return nullptr;
imp * parent = m_env->m_parent.get();
while (parent) {
if (m_extid < parent->m_extensions.size()) {
extension * ext = parent->m_extensions[m_extid].get();
if (ext)
return ext;
}
parent = parent->m_parent.get();
}
return nullptr;
}
read_only_environment::read_only_environment(environment const & env):
m_env(env),
m_lock(m_env.m_ptr->m_mutex) {
}
read_only_environment::~read_only_environment() {}
read_write_environment::read_write_environment(environment const & env):
m_env(env),
m_lock(m_env.m_ptr->m_mutex) {
}
read_write_environment::~read_write_environment() {}
}