lean2/src/frontends/lean/parser_config.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 <string>
#include "util/sstream.h"
#include "util/list_fn.h"
#include "library/scoped_ext.h"
#include "library/kernel_serializer.h"
#include "frontends/lean/parser_config.h"
#include "frontends/lean/builtin_exprs.h"
#include "frontends/lean/builtin_cmds.h"
namespace lean {
using notation::transition;
using notation::action;
using notation::action_kind;
notation_entry replace(notation_entry const & e, std::function<expr(expr const &)> const & f) {
if (e.is_numeral())
return notation_entry(e.get_num(), f(e.get_expr()), e.overload());
else
return notation_entry(e.is_nud(),
map(e.get_transitions(), [&](transition const & t) { return notation::replace(t, f); }),
f(e.get_expr()), e.overload(), e.reserve());
}
notation_entry::notation_entry():m_kind(notation_entry_kind::NuD) {}
notation_entry::notation_entry(notation_entry const & e):
m_kind(e.m_kind), m_expr(e.m_expr), m_overload(e.m_overload),
m_safe_ascii(e.m_safe_ascii), m_reserve(e.m_reserve) {
if (is_numeral())
new (&m_num) mpz(e.m_num);
else
new (&m_transitions) list<transition>(e.m_transitions);
}
notation_entry::notation_entry(bool is_nud, list<transition> const & ts, expr const & e, bool overload, bool reserve):
m_kind(is_nud ? notation_entry_kind::NuD : notation_entry_kind::LeD),
m_expr(e), m_overload(overload), m_reserve(reserve) {
new (&m_transitions) list<transition>(ts);
m_safe_ascii = std::all_of(ts.begin(), ts.end(), [](transition const & t) { return t.is_safe_ascii(); });
}
notation_entry::notation_entry(notation_entry const & e, bool overload):
notation_entry(e) {
m_overload = overload;
}
notation_entry::notation_entry(mpz const & val, expr const & e, bool overload):
m_kind(notation_entry_kind::Numeral), m_expr(e), m_overload(overload), m_safe_ascii(true), m_reserve(false) {
new (&m_num) mpz(val);
}
notation_entry::~notation_entry() {
if (is_numeral())
m_num.~mpz();
else
m_transitions.~list<transition>();
}
bool operator==(notation_entry const & e1, notation_entry const & e2) {
if (e1.kind() != e2.kind() || e1.overload() != e2.overload() || e1.get_expr() != e2.get_expr() ||
e1.reserve() != e2.reserve())
return false;
if (e1.is_numeral())
return e1.get_num() == e2.get_num();
else
return e1.get_transitions() == e2.get_transitions();
}
struct token_state {
token_table m_table;
token_state() { m_table = mk_default_token_table(); }
};
struct token_config {
typedef token_state state;
typedef token_entry entry;
static name * g_class_name;
static std::string * g_key;
static void add_entry(environment const &, io_state const &, state & s, entry const & e) {
s.m_table = add_token(s.m_table, e.m_token.c_str(), e.m_prec);
}
static name const & get_class_name() {
return *g_class_name;
}
static std::string const & get_serialization_key() {
return *g_key;
}
static void write_entry(serializer & s, entry const & e) {
s << e.m_token.c_str() << e.m_prec;
}
static entry read_entry(deserializer & d) {
std::string tk = d.read_string();
unsigned prec = d.read_unsigned();
return entry(tk, prec);
}
static optional<unsigned> get_fingerprint(entry const &) {
return optional<unsigned>();
}
};
name * token_config::g_class_name = nullptr;
std::string * token_config::g_key = nullptr;
template class scoped_ext<token_config>;
typedef scoped_ext<token_config> token_ext;
environment add_token(environment const & env, token_entry const & e) {
return token_ext::add_entry(env, get_dummy_ios(), e);
}
environment add_token(environment const & env, char const * val, unsigned prec) {
return add_token(env, token_entry(val, prec));
}
token_table const & get_token_table(environment const & env) {
return token_ext::get_state(env).m_table;
}
serializer & operator<<(serializer & s, action const & a) {
s << static_cast<char>(a.kind());
switch (a.kind()) {
case action_kind::Skip: case action_kind::Binder: case action_kind::Binders:
break;
case action_kind::Expr:
s << a.rbp();
break;
case action_kind::Exprs:
s << a.get_sep() << a.get_rec() << a.get_initial() << a.is_fold_right() << a.rbp();
if (auto t = a.get_terminator()) {
s << true << *t;
} else {
s << false;
}
break;
case action_kind::ScopedExpr:
s << a.get_rec() << a.rbp() << a.use_lambda_abstraction();
break;
case action_kind::LuaExt:
s << a.get_lua_fn();
break;
case action_kind::Ext:
lean_unreachable();
}
return s;
}
action read_action(deserializer & d) {
action_kind k = static_cast<action_kind>(d.read_char());
unsigned rbp;
switch (k) {
case action_kind::Skip:
return notation::mk_skip_action();
case action_kind::Binder:
return notation::mk_binder_action();
case action_kind::Binders:
return notation::mk_binders_action();
case action_kind::Expr:
d >> rbp;
return notation::mk_expr_action(rbp);
case action_kind::Exprs: {
name sep; expr rec, ini; bool is_fold_right;
d >> sep >> rec >> ini >> is_fold_right >> rbp;
optional<name> terminator;
if (d.read_bool())
terminator = read_name(d);
return notation::mk_exprs_action(sep, rec, ini, terminator, is_fold_right, rbp);
}
case action_kind::ScopedExpr: {
expr rec; bool use_lambda_abstraction;
d >> rec >> rbp >> use_lambda_abstraction;
return notation::mk_scoped_expr_action(rec, rbp, use_lambda_abstraction);
}
case action_kind::LuaExt:
return notation::mk_ext_lua_action(d.read_string().c_str());
case action_kind::Ext:
break;
}
lean_unreachable();
}
serializer & operator<<(serializer & s, transition const & t) {
s << t.get_token() << t.get_action();
return s;
}
transition read_transition(deserializer & d) {
name n = read_name(d);
action a = read_action(d);
return transition(n, a);
}
struct notation_state {
typedef rb_map<mpz, list<expr>, mpz_cmp_fn> num_map;
typedef head_map<notation_entry> head_to_entries;
parse_table m_nud;
parse_table m_led;
num_map m_num_map;
head_to_entries m_inv_map;
// The following two tables are used to implement `reserve notation` commands
parse_table m_reserved_nud;
parse_table m_reserved_led;
notation_state():
m_nud(get_builtin_nud_table()),
m_led(get_builtin_led_table()),
m_reserved_nud(true),
m_reserved_led(false) {
}
};
struct notation_config {
typedef notation_state state;
typedef notation_entry entry;
static name * g_class_name;
static std::string * g_key;
static void updt_inv_map(state & s, head_index const & idx, entry const & e) {
s.m_inv_map.insert(idx, e);
}
static void add_entry(environment const &, io_state const &, state & s, entry const & e) {
buffer<transition> ts;
switch (e.kind()) {
case notation_entry_kind::NuD: {
to_buffer(e.get_transitions(), ts);
if (auto idx = get_head_index(ts.size(), ts.data(), e.get_expr()))
updt_inv_map(s, *idx, e);
parse_table & nud = e.reserve() ? s.m_reserved_nud : s.m_nud;
nud = nud.add(ts.size(), ts.data(), e.get_expr(), e.overload());
break;
}
case notation_entry_kind::LeD: {
to_buffer(e.get_transitions(), ts);
if (auto idx = get_head_index(ts.size(), ts.data(), e.get_expr()))
updt_inv_map(s, *idx, e);
parse_table & led = e.reserve() ? s.m_reserved_led : s.m_led;
led = led.add(ts.size(), ts.data(), e.get_expr(), e.overload());
break;
}
case notation_entry_kind::Numeral:
if (!is_var(e.get_expr()))
updt_inv_map(s, head_index(e.get_expr()), e);
if (!e.overload()) {
s.m_num_map.insert(e.get_num(), list<expr>(e.get_expr()));
} else if (auto it = s.m_num_map.find(e.get_num())) {
list<expr> new_exprs = cons(e.get_expr(), filter(*it, [&](expr const & n) { return n != e.get_expr(); }));
s.m_num_map.insert(e.get_num(), new_exprs);
} else {
s.m_num_map.insert(e.get_num(), list<expr>(e.get_expr()));
}
}
}
static name const & get_class_name() {
return *g_class_name;
}
static std::string const & get_serialization_key() {
return *g_key;
}
static void write_entry(serializer & s, entry const & e) {
s << static_cast<char>(e.kind()) << e.overload() << e.get_expr();
if (e.is_numeral()) {
s << e.get_num();
} else {
s << e.reserve() << length(e.get_transitions());
for (auto const & t : e.get_transitions())
s << t;
}
}
static entry read_entry(deserializer & d) {
notation_entry_kind k = static_cast<notation_entry_kind>(d.read_char());
bool overload; expr e;
d >> overload >> e;
if (k == notation_entry_kind::Numeral) {
mpz val;
d >> val;
return entry(val, e, overload);
} else {
bool is_nud = k == notation_entry_kind::NuD;
bool reserve;
unsigned sz;
d >> reserve >> sz;
buffer<transition> ts;
for (unsigned i = 0; i < sz; i++)
ts.push_back(read_transition(d));
return entry(is_nud, to_list(ts.begin(), ts.end()), e, overload, reserve);
}
}
static optional<unsigned> get_fingerprint(entry const &) {
return optional<unsigned>();
}
};
name * notation_config::g_class_name = nullptr;
std::string * notation_config::g_key = nullptr;
template class scoped_ext<notation_config>;
typedef scoped_ext<notation_config> notation_ext;
environment add_notation(environment const & env, notation_entry const & e) {
return notation_ext::add_entry(env, get_dummy_ios(), e);
}
environment add_nud_notation(environment const & env, unsigned num, notation::transition const * ts,
expr const & a, bool overload, bool reserve) {
return add_notation(env, notation_entry(true, to_list(ts, ts+num), a, overload, reserve));
}
environment add_led_notation(environment const & env, unsigned num, notation::transition const * ts,
expr const & a, bool overload, bool reserve) {
return add_notation(env, notation_entry(false, to_list(ts, ts+num), a, overload, reserve));
}
environment add_nud_notation(environment const & env, std::initializer_list<notation::transition> const & ts,
expr const & a, bool overload) {
bool reserve = false;
return add_nud_notation(env, ts.size(), ts.begin(), a, overload, reserve);
}
environment add_led_notation(environment const & env, std::initializer_list<notation::transition> const & ts,
expr const & a, bool overload) {
bool reserve = false;
return add_led_notation(env, ts.size(), ts.begin(), a, overload, reserve);
}
parse_table const & get_nud_table(environment const & env) {
return notation_ext::get_state(env).m_nud;
}
parse_table const & get_led_table(environment const & env) {
return notation_ext::get_state(env).m_led;
}
parse_table const & get_reserved_nud_table(environment const & env) {
return notation_ext::get_state(env).m_reserved_nud;
}
parse_table const & get_reserved_led_table(environment const & env) {
return notation_ext::get_state(env).m_reserved_led;
}
environment add_mpz_notation(environment const & env, mpz const & n, expr const & e, bool overload) {
return add_notation(env, notation_entry(n, e, overload));
}
list<expr> get_mpz_notation(environment const & env, mpz const & n) {
if (auto it = notation_ext::get_state(env).m_num_map.find(n)) {
return *it;
} else {
return list<expr>();
}
}
list<notation_entry> get_notation_entries(environment const & env, head_index const & idx) {
if (auto it = notation_ext::get_state(env).m_inv_map.find(idx))
return *it;
else
return list<notation_entry>();
}
environment overwrite_notation(environment const & env, name const & n) {
environment r = env;
bool found = false;
if (auto it = token_ext::get_entries(r, n)) {
found = true;
for (token_entry e : *it) {
r = add_token(r, e);
}
}
if (auto it = notation_ext::get_entries(env, n)) {
found = true;
for (notation_entry const & e : *it) {
notation_entry new_e(e, false);
r = add_notation(r, new_e);
}
}
if (!found)
throw exception(sstream() << "unknown namespace '" << n << "'");
return r;
}
struct cmd_ext : public environment_extension {
cmd_table m_cmds;
cmd_ext() {
m_cmds = get_builtin_cmds();
}
};
struct cmd_ext_reg {
unsigned m_ext_id;
cmd_ext_reg() { m_ext_id = environment::register_extension(std::make_shared<cmd_ext>()); }
};
static cmd_ext_reg * g_ext = nullptr;
static cmd_ext const & get_extension(environment const & env) {
return static_cast<cmd_ext const &>(env.get_extension(g_ext->m_ext_id));
}
cmd_table const & get_cmd_table(environment const & env) {
return get_extension(env).m_cmds;
}
void initialize_parser_config() {
token_config::g_class_name = new name("notation");
token_config::g_key = new std::string("tk");
token_ext::initialize();
notation_config::g_class_name = new name("notation");
notation_config::g_key = new std::string("nota");
notation_ext::initialize();
g_ext = new cmd_ext_reg();
}
void finalize_parser_config() {
delete g_ext;
notation_ext::finalize();
delete notation_config::g_key;
delete notation_config::g_class_name;
token_ext::finalize();
delete token_config::g_key;
delete token_config::g_class_name;
}
}