lean2/src/library/annotation.cpp

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/*
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 <unordered_map>
#include <memory>
#include <string>
#include "util/sstream.h"
#include "library/kernel_serializer.h"
#include "library/annotation.h"
namespace lean {
static name * g_annotation = nullptr;
static std::string * g_annotation_opcode = nullptr;
name const & get_annotation_name() { return *g_annotation; }
std::string const & get_annotation_opcode() { return *g_annotation_opcode; }
/** \brief We use a macro to mark expressions that denote "let" and "have"-expressions.
These marks have no real semantic meaning, but are useful for helping Lean's pretty printer.
*/
class annotation_macro_definition_cell : public macro_definition_cell {
name m_name;
void check_macro(expr const & m) const {
if (!is_macro(m) || macro_num_args(m) != 1)
throw exception(sstream() << "invalid '" << m_name << "' annotation, incorrect number of arguments");
}
public:
annotation_macro_definition_cell(name const & n):m_name(n) {}
name const & get_annotation_kind() const { return m_name; }
virtual name get_name() const { return get_annotation_name(); }
virtual format pp(formatter const &) const { return format(m_name); }
virtual void display(std::ostream & out) const { out << m_name; }
virtual pair<expr, constraint_seq> check_type(expr const & m, extension_context & ctx, bool infer_only) const {
check_macro(m);
return ctx.check_type(macro_arg(m, 0), infer_only);
}
virtual optional<expr> expand(expr const & m, extension_context &) const {
check_macro(m);
return some_expr(macro_arg(m, 0));
}
virtual void write(serializer & s) const {
s.write_string(get_annotation_opcode());
s << m_name;
}
virtual bool operator==(macro_definition_cell const & other) const {
if (auto other_ptr = dynamic_cast<annotation_macro_definition_cell const *>(&other)) {
return m_name == other_ptr->m_name;
} else {
return false;
}
}
virtual unsigned hash() const {
return ::lean::hash(m_name.hash(), g_annotation->hash());
}
};
typedef std::unordered_map<name, macro_definition, name_hash, name_eq> annotation_macros;
static annotation_macros * g_annotation_macros = nullptr;
annotation_macros & get_annotation_macros() { return *g_annotation_macros; }
void register_annotation(name const & n) {
annotation_macros & ms = get_annotation_macros();
lean_assert(ms.find(n) == ms.end());
ms.insert(mk_pair(n, macro_definition(new annotation_macro_definition_cell(n))));
}
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expr mk_annotation(name const & kind, expr const & e, tag g) {
annotation_macros & ms = get_annotation_macros();
auto it = ms.find(kind);
if (it != ms.end()) {
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return mk_macro(it->second, 1, &e, g);
} else {
throw exception(sstream() << "unknown annotation kind '" << kind << "'");
}
}
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expr mk_annotation(name const & kind, expr const & e) {
return mk_annotation(kind, e, e.get_tag());
}
bool is_annotation(expr const & e) {
return is_macro(e) && macro_def(e).get_name() == get_annotation_name();
}
name const & get_annotation_kind(expr const & e) {
lean_assert(is_annotation(e));
return static_cast<annotation_macro_definition_cell const*>(macro_def(e).raw())->get_annotation_kind();
}
bool is_annotation(expr const & e, name const & kind) {
return is_annotation(e) && get_annotation_kind(e) == kind;
}
expr const & get_annotation_arg(expr const & e) {
lean_assert(is_annotation(e));
return macro_arg(e, 0);
}
bool is_nested_annotation(expr const & e, name const & kind) {
expr const * it = &e;
while (is_annotation(*it)) {
if (get_annotation_kind(*it) == kind)
return true;
it = &get_annotation_arg(*it);
}
return false;
}
expr const & get_nested_annotation_arg(expr const & e) {
expr const * it = &e;
while (is_annotation(*it))
it = &get_annotation_arg(*it);
return *it;
}
expr copy_annotations(expr const & from, expr const & to) {
buffer<expr> trace;
expr const * it = &from;
while (is_annotation(*it)) {
trace.push_back(*it);
it = &get_annotation_arg(*it);
}
expr r = to;
unsigned i = trace.size();
while (i > 0) {
--i;
r = copy_tag(trace[i], mk_annotation(get_annotation_kind(trace[i]), r));
}
return r;
}
static name * g_have = nullptr;
static name * g_show = nullptr;
expr mk_have_annotation(expr const & e) { return mk_annotation(*g_have, e); }
expr mk_show_annotation(expr const & e) { return mk_annotation(*g_show, e); }
bool is_have_annotation(expr const & e) { return is_annotation(e, *g_have); }
bool is_show_annotation(expr const & e) { return is_annotation(e, *g_show); }
void initialize_annotation() {
g_annotation = new name("annotation");
g_annotation_opcode = new std::string("Annot");
g_annotation_macros = new annotation_macros();
g_have = new name("have");
g_show = new name("show");
register_annotation(*g_have);
register_annotation(*g_show);
register_macro_deserializer(get_annotation_opcode(),
[](deserializer & d, unsigned num, expr const * args) {
if (num != 1)
throw corrupted_stream_exception();
name k;
d >> k;
return mk_annotation(k, args[0]);
});
}
void finalize_annotation() {
delete g_show;
delete g_have;
delete g_annotation_macros;
delete g_annotation_opcode;
delete g_annotation;
}
}