mirror of
https://github.com/danog/ton.git
synced 2024-12-02 09:28:02 +01:00
1106 lines
34 KiB
C++
1106 lines
34 KiB
C++
/*
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This file is part of TON Blockchain Library.
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TON Blockchain Library is free software: you can redistribute it and/or modify
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it under the terms of the GNU Lesser General Public License as published by
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the Free Software Foundation, either version 2 of the License, or
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(at your option) any later version.
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TON Blockchain Library is distributed in the hope that it will be useful,
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but WITHOUT ANY WARRANTY; without even the implied warranty of
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MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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GNU Lesser General Public License for more details.
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You should have received a copy of the GNU Lesser General Public License
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along with TON Blockchain Library. If not, see <http://www.gnu.org/licenses/>.
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Copyright 2017-2019 Telegram Systems LLP
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*/
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#include "func.h"
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#include "td/utils/crypto.h"
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#include <fstream>
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namespace sym {
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int compute_symbol_subclass(std::string str) {
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using funC::IdSc;
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if (str.size() < 2) {
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return IdSc::undef;
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} else if (str[0] == '.') {
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return IdSc::dotid;
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} else if (str[0] == '~') {
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return IdSc::tildeid;
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} else {
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return IdSc::undef;
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}
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}
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} // namespace sym
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namespace funC {
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using namespace std::literals::string_literals;
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using src::Lexer;
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using sym::symbols;
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using td::Ref;
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inline bool is_dot_ident(sym_idx_t idx) {
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return symbols.get_subclass(idx) == IdSc::dotid;
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}
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inline bool is_tilde_ident(sym_idx_t idx) {
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return symbols.get_subclass(idx) == IdSc::tildeid;
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}
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inline bool is_special_ident(sym_idx_t idx) {
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return symbols.get_subclass(idx) != IdSc::undef;
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}
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/*
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*
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* PARSE SOURCE
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*
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*/
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// TE ::= TA | TA -> TE
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// TA ::= int | ... | cont | var | _ | () | ( TE { , TE } )
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TypeExpr* parse_type(Lexer& lex);
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TypeExpr* parse_type1(Lexer& lex) {
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switch (lex.tp()) {
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case _Int:
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lex.next();
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return TypeExpr::new_atomic(_Int);
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case _Cell:
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lex.next();
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return TypeExpr::new_atomic(_Cell);
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case _Slice:
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lex.next();
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return TypeExpr::new_atomic(_Slice);
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case _Builder:
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lex.next();
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return TypeExpr::new_atomic(_Builder);
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case _Cont:
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lex.next();
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return TypeExpr::new_atomic(_Cont);
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case _Tuple:
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lex.next();
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return TypeExpr::new_atomic(_Tuple);
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case _Var:
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case '_':
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lex.next();
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return TypeExpr::new_hole();
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}
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lex.expect('(');
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if (lex.tp() == ')') {
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lex.next();
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return TypeExpr::new_unit();
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}
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auto t1 = parse_type(lex);
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if (lex.tp() != ',') {
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lex.expect(')');
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return t1;
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}
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std::vector<TypeExpr*> tlist{1, t1};
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while (lex.tp() == ',') {
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lex.next();
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tlist.push_back(parse_type(lex));
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}
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lex.expect(')');
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return TypeExpr::new_tensor(std::move(tlist));
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}
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TypeExpr* parse_type(Lexer& lex) {
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auto res = parse_type1(lex);
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if (lex.tp() == _Mapsto) {
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lex.next();
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auto to = parse_type(lex);
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return TypeExpr::new_map(res, to);
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} else {
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return res;
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}
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}
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FormalArg parse_formal_arg(Lexer& lex, int fa_idx) {
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TypeExpr* arg_type = 0;
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SrcLocation loc = lex.cur().loc;
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if (lex.tp() == '_') {
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lex.next();
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if (lex.tp() == ',' || lex.tp() == ')') {
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return std::make_tuple(TypeExpr::new_hole(), (SymDef*)nullptr, loc);
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}
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arg_type = TypeExpr::new_hole();
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loc = lex.cur().loc;
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} else if (lex.tp() != _Ident) {
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arg_type = parse_type(lex);
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} else {
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arg_type = TypeExpr::new_hole();
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}
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if (lex.tp() == '_' || lex.tp() == ',' || lex.tp() == ')') {
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if (lex.tp() == '_') {
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loc = lex.cur().loc;
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lex.next();
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}
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return std::make_tuple(arg_type, (SymDef*)nullptr, loc);
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}
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if (lex.tp() != _Ident) {
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lex.expect(_Ident, "formal parameter name");
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}
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loc = lex.cur().loc;
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SymDef* new_sym_def = sym::define_symbol(lex.cur().val, true, loc);
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if (new_sym_def->value) {
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lex.cur().error_at("redefined formal parameter `", "`");
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}
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new_sym_def->value = new SymVal{SymVal::_Param, fa_idx, arg_type};
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lex.next();
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return std::make_tuple(arg_type, new_sym_def, loc);
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}
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FormalArgList parse_formal_args(Lexer& lex) {
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FormalArgList args;
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lex.expect('(', "formal argument list");
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if (lex.tp() == ')') {
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lex.next();
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return args;
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}
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int fa_idx = 0;
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args.push_back(parse_formal_arg(lex, fa_idx++));
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while (lex.tp() == ',') {
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lex.next();
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args.push_back(parse_formal_arg(lex, fa_idx++));
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}
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lex.expect(')');
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return args;
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}
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TypeExpr* extract_total_arg_type(const FormalArgList& arg_list) {
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if (arg_list.empty()) {
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return TypeExpr::new_unit();
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}
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if (arg_list.size() == 1) {
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return std::get<0>(arg_list[0]);
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}
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std::vector<TypeExpr*> type_list;
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for (auto& x : arg_list) {
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type_list.push_back(std::get<0>(x));
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}
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return TypeExpr::new_tensor(std::move(type_list));
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}
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SymValCodeFunc* make_new_glob_func(SymDef* func_sym, TypeExpr* func_type, bool impure = false) {
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SymValCodeFunc* res = new SymValCodeFunc{glob_func_cnt, func_type, impure};
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func_sym->value = res;
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glob_func.push_back(func_sym);
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glob_func_cnt++;
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return res;
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}
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bool check_global_func(const Lexem& cur, sym_idx_t func_name = 0) {
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if (!func_name) {
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func_name = cur.val;
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}
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SymDef* def = sym::lookup_symbol(func_name);
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if (!def) {
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cur.loc.show_error(std::string{"undefined function `"} + symbols.get_name(func_name) +
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"`, defining a global function of unknown type");
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def = sym::define_global_symbol(func_name, 0, cur.loc);
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assert(def && "cannot define global function");
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++undef_func_cnt;
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make_new_glob_func(def, TypeExpr::new_hole()); // was: ... ::new_func()
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return true;
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}
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SymVal* val = dynamic_cast<SymVal*>(def->value);
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if (!val) {
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cur.error(std::string{"symbol `"} + symbols.get_name(func_name) + "` has no value and no type");
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return false;
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} else if (!val->get_type()) {
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cur.error(std::string{"symbol `"} + symbols.get_name(func_name) + "` has no type, possibly not a function");
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return false;
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} else {
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return true;
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}
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}
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Expr* parse_expr(Lexer& lex, CodeBlob& code, bool nv = false);
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// parse ( E { , E } ) | () | id | num | _
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Expr* parse_expr100(Lexer& lex, CodeBlob& code, bool nv) {
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if (lex.tp() == '(') {
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SrcLocation loc{lex.cur().loc};
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lex.next();
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if (lex.tp() == ')') {
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lex.next();
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Expr* res = new Expr{Expr::_Tuple, {}};
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res->flags = Expr::_IsRvalue;
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res->here = loc;
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res->e_type = TypeExpr::new_unit();
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return res;
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}
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Expr* res = parse_expr(lex, code, nv);
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if (lex.tp() != ',') {
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lex.expect(')');
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return res;
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}
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std::vector<TypeExpr*> type_list;
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type_list.push_back(res->e_type);
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int f = res->flags;
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res = new Expr{Expr::_Tuple, {res}};
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while (lex.tp() == ',') {
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lex.next();
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auto x = parse_expr(lex, code, nv);
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res->pb_arg(x);
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if ((f ^ x->flags) & Expr::_IsType) {
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lex.cur().error("mixing type and non-type expressions inside the same tuple");
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}
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f &= x->flags;
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type_list.push_back(x->e_type);
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}
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res->here = loc;
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res->flags = f;
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res->e_type = TypeExpr::new_tensor(std::move(type_list));
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lex.expect(')');
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return res;
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}
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int t = lex.tp();
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if (t == Lexem::Number) {
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Expr* res = new Expr{Expr::_Const, lex.cur().loc};
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res->flags = Expr::_IsRvalue;
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res->intval = td::string_to_int256(lex.cur().str);
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if (res->intval.is_null()) {
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lex.cur().error_at("invalid integer constant `", "`");
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}
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res->e_type = TypeExpr::new_atomic(_Int);
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lex.next();
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return res;
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}
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if (t == '_') {
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Expr* res = new Expr{Expr::_Hole, lex.cur().loc};
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res->val = -1;
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res->flags = (Expr::_IsLvalue | Expr::_IsHole | Expr::_IsNewVar);
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res->e_type = TypeExpr::new_hole();
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lex.next();
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return res;
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}
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if (t == _Var) {
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Expr* res = new Expr{Expr::_Type, lex.cur().loc};
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res->flags = Expr::_IsType;
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res->e_type = TypeExpr::new_hole();
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lex.next();
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return res;
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}
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if (t == _Int || t == _Cell || t == _Slice || t == _Builder || t == _Cont || t == _Type) {
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Expr* res = new Expr{Expr::_Type, lex.cur().loc};
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res->flags = Expr::_IsType;
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res->e_type = TypeExpr::new_atomic(t);
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lex.next();
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return res;
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}
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if (t == _Ident) {
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Expr* res = new Expr{Expr::_Var, lex.cur().loc};
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if (nv) {
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res->val = ~lex.cur().val;
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res->e_type = TypeExpr::new_hole();
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res->flags = Expr::_IsLvalue | Expr::_IsNewVar;
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// std::cerr << "defined new variable " << lex.cur().str << " : " << res->e_type << std::endl;
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} else {
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res->sym = sym::lookup_symbol(lex.cur().val);
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if (!res->sym) {
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check_global_func(lex.cur());
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res->sym = sym::lookup_symbol(lex.cur().val);
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}
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SymVal* val = nullptr;
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if (res->sym) {
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val = dynamic_cast<SymVal*>(res->sym->value);
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}
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if (!val) {
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lex.cur().error_at("undefined identifier `", "`");
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} else if (val->type == SymVal::_Func) {
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res->e_type = val->get_type();
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res->cls = Expr::_Glob;
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} else if (val->idx < 0) {
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lex.cur().error_at("accessing variable `", "` being defined");
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} else {
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res->val = val->idx;
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res->e_type = val->get_type();
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// std::cerr << "accessing variable " << lex.cur().str << " : " << res->e_type << std::endl;
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}
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// std::cerr << "accessing symbol " << lex.cur().str << " : " << res->e_type << (val->impure ? " (impure)" : " (pure)") << std::endl;
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res->flags = Expr::_IsLvalue | Expr::_IsRvalue | (val->impure ? Expr::_IsImpure : 0);
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}
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res->deduce_type(lex.cur());
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lex.next();
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return res;
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}
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lex.expect(Lexem::Ident);
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return nullptr;
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}
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Expr* make_func_apply(Expr* fun, Expr* x) {
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Expr* res;
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if (fun->cls == Expr::_Glob) {
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if (x->cls == Expr::_Tuple) {
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res = new Expr{Expr::_Apply, fun->sym, x->args};
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} else {
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res = new Expr{Expr::_Apply, fun->sym, {x}};
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}
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res->flags = Expr::_IsRvalue | (fun->flags & Expr::_IsImpure);
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} else {
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res = new Expr{Expr::_VarApply, {fun, x}};
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res->flags = Expr::_IsRvalue;
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}
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return res;
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}
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// parse E { E }
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Expr* parse_expr90(Lexer& lex, CodeBlob& code, bool nv) {
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Expr* res = parse_expr100(lex, code, nv);
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while (lex.tp() == '(' || (lex.tp() == _Ident && !is_special_ident(lex.cur().val))) {
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if (res->is_type()) {
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Expr* x = parse_expr100(lex, code, true);
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x->chk_lvalue(lex.cur()); // chk_lrvalue() ?
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TypeExpr* tp = res->e_type;
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delete res;
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res = new Expr{Expr::_TypeApply, {x}};
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res->e_type = tp;
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res->here = lex.cur().loc;
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try {
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unify(res->e_type, x->e_type);
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} catch (UnifyError& ue) {
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std::ostringstream os;
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os << "cannot transform expression of type " << x->e_type << " to explicitly requested type " << res->e_type
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<< ": " << ue;
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lex.cur().error(os.str());
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}
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res->flags = x->flags;
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} else {
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Expr* x = parse_expr100(lex, code, false);
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x->chk_rvalue(lex.cur());
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res = make_func_apply(res, x);
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res->here = lex.cur().loc;
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res->deduce_type(lex.cur());
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}
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}
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return res;
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}
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// parse E { .method E | ~method E }
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Expr* parse_expr80(Lexer& lex, CodeBlob& code, bool nv) {
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Expr* res = parse_expr90(lex, code, nv);
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while (lex.tp() == _Ident && is_special_ident(lex.cur().val)) {
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auto modify = is_tilde_ident(lex.cur().val);
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auto obj = res;
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if (modify) {
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obj->chk_lvalue(lex.cur());
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} else {
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obj->chk_rvalue(lex.cur());
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}
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auto loc = lex.cur().loc;
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auto name = lex.cur().val;
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auto sym = sym::lookup_symbol(name);
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if (!sym || !dynamic_cast<SymValFunc*>(sym->value)) {
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auto name1 = symbols.lookup(lex.cur().str.substr(1));
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if (name1) {
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auto sym1 = sym::lookup_symbol(name1);
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if (sym1 && dynamic_cast<SymValFunc*>(sym1->value)) {
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name = name1;
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sym = sym1;
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}
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}
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}
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check_global_func(lex.cur(), name);
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if (verbosity >= 2) {
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std::cerr << "using symbol `" << symbols.get_name(name) << "` for method call of " << lex.cur().str << std::endl;
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}
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sym = sym::lookup_symbol(name);
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SymValFunc* val = sym ? dynamic_cast<SymValFunc*>(sym->value) : nullptr;
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if (!val) {
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lex.cur().error_at("undefined method identifier `", "`");
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}
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lex.next();
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auto x = parse_expr100(lex, code, false);
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x->chk_rvalue(lex.cur());
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if (x->cls == Expr::_Tuple) {
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res = new Expr{Expr::_Apply, name, {obj}};
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res->args.insert(res->args.end(), x->args.begin(), x->args.end());
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} else {
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res = new Expr{Expr::_Apply, name, {obj, x}};
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}
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res->here = loc;
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res->flags = Expr::_IsRvalue | (val->impure ? Expr::_IsImpure : 0);
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res->deduce_type(lex.cur());
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if (modify) {
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// FIXME (use _LetFirst instead of _Letop)
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auto tmp = res;
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res = new Expr{Expr::_LetFirst, {obj->copy(), tmp}};
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res->here = loc;
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res->flags = tmp->flags;
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res->set_val(name);
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res->deduce_type(lex.cur());
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}
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}
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return res;
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}
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|
// parse [ ~ ] E
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Expr* parse_expr75(Lexer& lex, CodeBlob& code, bool nv) {
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if (lex.tp() == '~') {
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sym_idx_t name = symbols.lookup_add("~_");
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check_global_func(lex.cur(), name);
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SrcLocation loc{lex.cur().loc};
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lex.next();
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auto x = parse_expr80(lex, code, false);
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x->chk_rvalue(lex.cur());
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auto res = new Expr{Expr::_Apply, name, {x}};
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res->here = loc;
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res->set_val('~');
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res->flags = Expr::_IsRvalue;
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res->deduce_type(lex.cur());
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return res;
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} else {
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return parse_expr80(lex, code, nv);
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}
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}
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// parse E { (* | / | % | /% ) E }
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Expr* parse_expr30(Lexer& lex, CodeBlob& code, bool nv) {
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Expr* res = parse_expr75(lex, code, nv);
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while (lex.tp() == '*' || lex.tp() == '/' || lex.tp() == '%' || lex.tp() == _DivMod || lex.tp() == _DivC ||
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lex.tp() == _DivR || lex.tp() == '&') {
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res->chk_rvalue(lex.cur());
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int t = lex.tp();
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sym_idx_t name = symbols.lookup_add(std::string{"_"} + lex.cur().str + "_");
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|
SrcLocation loc{lex.cur().loc};
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check_global_func(lex.cur(), name);
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|
lex.next();
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|
auto x = parse_expr75(lex, code, false);
|
|
x->chk_rvalue(lex.cur());
|
|
res = new Expr{Expr::_Apply, name, {res, x}};
|
|
res->here = loc;
|
|
res->set_val(t);
|
|
res->flags = Expr::_IsRvalue;
|
|
res->deduce_type(lex.cur());
|
|
}
|
|
return res;
|
|
}
|
|
|
|
// parse [-] E { (+ | - | `|` ) E }
|
|
Expr* parse_expr20(Lexer& lex, CodeBlob& code, bool nv) {
|
|
Expr* res;
|
|
int t = lex.tp();
|
|
if (t == '-') {
|
|
sym_idx_t name = symbols.lookup_add("-_");
|
|
check_global_func(lex.cur(), name);
|
|
SrcLocation loc{lex.cur().loc};
|
|
lex.next();
|
|
auto x = parse_expr30(lex, code, false);
|
|
x->chk_rvalue(lex.cur());
|
|
res = new Expr{Expr::_Apply, name, {x}};
|
|
res->here = loc;
|
|
res->set_val(t);
|
|
res->flags = Expr::_IsRvalue;
|
|
res->deduce_type(lex.cur());
|
|
} else {
|
|
res = parse_expr30(lex, code, nv);
|
|
}
|
|
while (lex.tp() == '-' || lex.tp() == '+' || lex.tp() == '|') {
|
|
res->chk_rvalue(lex.cur());
|
|
t = lex.tp();
|
|
sym_idx_t name = symbols.lookup_add(std::string{"_"} + lex.cur().str + "_");
|
|
check_global_func(lex.cur(), name);
|
|
SrcLocation loc{lex.cur().loc};
|
|
lex.next();
|
|
auto x = parse_expr30(lex, code, false);
|
|
x->chk_rvalue(lex.cur());
|
|
res = new Expr{Expr::_Apply, name, {res, x}};
|
|
res->here = loc;
|
|
res->set_val(t);
|
|
res->flags = Expr::_IsRvalue;
|
|
res->deduce_type(lex.cur());
|
|
}
|
|
return res;
|
|
}
|
|
|
|
// parse E { ( << | >> | >>~ | >>^ ) E }
|
|
Expr* parse_expr17(Lexer& lex, CodeBlob& code, bool nv) {
|
|
Expr* res = parse_expr20(lex, code, nv);
|
|
while (lex.tp() == _Lshift || lex.tp() == _Rshift || lex.tp() == _RshiftC || lex.tp() == _RshiftR) {
|
|
res->chk_rvalue(lex.cur());
|
|
int t = lex.tp();
|
|
sym_idx_t name = symbols.lookup_add(std::string{"_"} + lex.cur().str + "_");
|
|
check_global_func(lex.cur(), name);
|
|
SrcLocation loc{lex.cur().loc};
|
|
lex.next();
|
|
auto x = parse_expr20(lex, code, false);
|
|
x->chk_rvalue(lex.cur());
|
|
res = new Expr{Expr::_Apply, name, {res, x}};
|
|
res->here = loc;
|
|
res->set_val(t);
|
|
res->flags = Expr::_IsRvalue;
|
|
res->deduce_type(lex.cur());
|
|
}
|
|
return res;
|
|
}
|
|
|
|
// parse E [ (== | < | > | <= | >= | != | <=> ) E ]
|
|
Expr* parse_expr15(Lexer& lex, CodeBlob& code, bool nv) {
|
|
Expr* res = parse_expr17(lex, code, nv);
|
|
if (lex.tp() == _Eq || lex.tp() == '<' || lex.tp() == '>' || lex.tp() == _Leq || lex.tp() == _Geq ||
|
|
lex.tp() == _Neq || lex.tp() == _Spaceship) {
|
|
res->chk_rvalue(lex.cur());
|
|
int t = lex.tp();
|
|
sym_idx_t name = symbols.lookup_add(std::string{"_"} + lex.cur().str + "_");
|
|
check_global_func(lex.cur(), name);
|
|
SrcLocation loc{lex.cur().loc};
|
|
lex.next();
|
|
auto x = parse_expr17(lex, code, false);
|
|
x->chk_rvalue(lex.cur());
|
|
res = new Expr{Expr::_Apply, name, {res, x}};
|
|
res->here = loc;
|
|
res->set_val(t);
|
|
res->flags = Expr::_IsRvalue;
|
|
res->deduce_type(lex.cur());
|
|
}
|
|
return res;
|
|
}
|
|
|
|
// parse E [ ? E : E ]
|
|
Expr* parse_expr13(Lexer& lex, CodeBlob& code, bool nv) {
|
|
Expr* res = parse_expr15(lex, code, nv);
|
|
if (lex.tp() == '?') {
|
|
res->chk_rvalue(lex.cur());
|
|
SrcLocation loc{lex.cur().loc};
|
|
lex.next();
|
|
auto x = parse_expr(lex, code, false);
|
|
x->chk_rvalue(lex.cur());
|
|
lex.expect(':');
|
|
auto y = parse_expr13(lex, code, false);
|
|
y->chk_rvalue(lex.cur());
|
|
res = new Expr{Expr::_CondExpr, {res, x, y}};
|
|
res->here = loc;
|
|
res->flags = Expr::_IsRvalue;
|
|
res->deduce_type(lex.cur());
|
|
}
|
|
return res;
|
|
}
|
|
|
|
// parse LE1 (= | += | -= | ... ) E2
|
|
Expr* parse_expr10(Lexer& lex, CodeBlob& code, bool nv) {
|
|
auto x = parse_expr13(lex, code, nv);
|
|
int t = lex.tp();
|
|
if (t == _PlusLet || t == _MinusLet || t == _TimesLet || t == _DivLet || t == _DivRLet || t == _DivCLet ||
|
|
t == _ModLet || t == _LshiftLet || t == _RshiftLet || t == _RshiftCLet || t == _RshiftRLet) {
|
|
x->chk_lvalue(lex.cur());
|
|
x->chk_rvalue(lex.cur());
|
|
sym_idx_t name = symbols.lookup_add(std::string{"^_"} + lex.cur().str + "_");
|
|
check_global_func(lex.cur(), name);
|
|
SrcLocation loc{lex.cur().loc};
|
|
lex.next();
|
|
auto y = parse_expr10(lex, code, false);
|
|
y->chk_rvalue(lex.cur());
|
|
Expr* z = new Expr{Expr::_Apply, name, {x, y}};
|
|
z->here = loc;
|
|
z->set_val(t);
|
|
z->flags = Expr::_IsRvalue;
|
|
z->deduce_type(lex.cur());
|
|
Expr* res = new Expr{Expr::_Letop, {x->copy(), z}};
|
|
res->here = loc;
|
|
res->flags = (x->flags & ~Expr::_IsType) | Expr::_IsRvalue;
|
|
res->set_val(t);
|
|
res->deduce_type(lex.cur());
|
|
return res;
|
|
} else if (t == '=') {
|
|
x->chk_lvalue(lex.cur());
|
|
SrcLocation loc{lex.cur().loc};
|
|
lex.next();
|
|
auto y = parse_expr10(lex, code, false);
|
|
y->chk_rvalue(lex.cur());
|
|
x->predefine_vars();
|
|
x->define_new_vars(code);
|
|
Expr* res = new Expr{Expr::_Letop, {x, y}};
|
|
res->here = loc;
|
|
res->flags = (x->flags & ~Expr::_IsType) | Expr::_IsRvalue;
|
|
res->set_val(t);
|
|
res->deduce_type(lex.cur());
|
|
return res;
|
|
} else {
|
|
return x;
|
|
}
|
|
}
|
|
|
|
Expr* parse_expr(Lexer& lex, CodeBlob& code, bool nv) {
|
|
return parse_expr10(lex, code, nv);
|
|
}
|
|
|
|
namespace blk_fl {
|
|
enum { end = 1, ret = 2, empty = 4 };
|
|
typedef int val;
|
|
constexpr val init = end | empty;
|
|
void combine(val& x, const val y) {
|
|
x |= y & ret;
|
|
x &= y | ~(end | empty);
|
|
}
|
|
void combine_parallel(val& x, const val y) {
|
|
x &= y | ~(ret | empty);
|
|
x |= y & end;
|
|
}
|
|
} // namespace blk_fl
|
|
|
|
blk_fl::val parse_return_stmt(Lexer& lex, CodeBlob& code) {
|
|
auto expr = parse_expr(lex, code);
|
|
expr->chk_rvalue(lex.cur());
|
|
try {
|
|
// std::cerr << "in return: ";
|
|
unify(expr->e_type, code.ret_type);
|
|
} catch (UnifyError& ue) {
|
|
std::ostringstream os;
|
|
os << "previous function return type " << code.ret_type
|
|
<< " cannot be unified with return statement expression type " << expr->e_type << ": " << ue;
|
|
lex.cur().error(os.str());
|
|
}
|
|
std::vector<var_idx_t> tmp_vars = expr->pre_compile(code);
|
|
code.emplace_back(lex.cur().loc, Op::_Return, std::move(tmp_vars));
|
|
lex.expect(';');
|
|
return blk_fl::ret;
|
|
}
|
|
|
|
blk_fl::val parse_implicit_ret_stmt(Lexer& lex, CodeBlob& code) {
|
|
auto ret_type = TypeExpr::new_unit();
|
|
try {
|
|
// std::cerr << "in implicit return: ";
|
|
unify(ret_type, code.ret_type);
|
|
} catch (UnifyError& ue) {
|
|
std::ostringstream os;
|
|
os << "previous function return type " << code.ret_type
|
|
<< " cannot be unified with implicit end-of-block return type " << ret_type << ": " << ue;
|
|
lex.cur().error(os.str());
|
|
}
|
|
code.emplace_back(lex.cur().loc, Op::_Return);
|
|
return blk_fl::ret;
|
|
}
|
|
|
|
blk_fl::val parse_stmt(Lexer& lex, CodeBlob& code);
|
|
|
|
blk_fl::val parse_block_stmt(Lexer& lex, CodeBlob& code, bool no_new_scope = false) {
|
|
lex.expect('{');
|
|
if (!no_new_scope) {
|
|
sym::open_scope(lex);
|
|
}
|
|
blk_fl::val res = blk_fl::init;
|
|
bool warned = false;
|
|
while (lex.tp() != '}') {
|
|
if (!(res & blk_fl::end) && !warned) {
|
|
lex.cur().loc.show_warning("unreachable code");
|
|
warned = true;
|
|
}
|
|
blk_fl::combine(res, parse_stmt(lex, code));
|
|
}
|
|
if (!no_new_scope) {
|
|
sym::close_scope(lex);
|
|
}
|
|
lex.expect('}');
|
|
return res;
|
|
}
|
|
|
|
blk_fl::val parse_repeat_stmt(Lexer& lex, CodeBlob& code) {
|
|
SrcLocation loc{lex.cur().loc};
|
|
lex.expect(_Repeat);
|
|
auto expr = parse_expr(lex, code);
|
|
expr->chk_rvalue(lex.cur());
|
|
auto cnt_type = TypeExpr::new_atomic(_Int);
|
|
try {
|
|
unify(expr->e_type, cnt_type);
|
|
} catch (UnifyError& ue) {
|
|
std::ostringstream os;
|
|
os << "repeat count value of type " << expr->e_type << " is not an integer: " << ue;
|
|
lex.cur().error(os.str());
|
|
}
|
|
std::vector<var_idx_t> tmp_vars = expr->pre_compile(code);
|
|
if (tmp_vars.size() != 1) {
|
|
lex.cur().error("repeat count value is not a singleton");
|
|
}
|
|
Op& repeat_op = code.emplace_back(loc, Op::_Repeat, tmp_vars);
|
|
code.push_set_cur(repeat_op.block0);
|
|
blk_fl::val res = parse_block_stmt(lex, code);
|
|
code.close_pop_cur(lex.cur().loc);
|
|
return res | blk_fl::end;
|
|
}
|
|
|
|
blk_fl::val parse_while_stmt(Lexer& lex, CodeBlob& code) {
|
|
SrcLocation loc{lex.cur().loc};
|
|
lex.expect(_While);
|
|
auto expr = parse_expr(lex, code);
|
|
expr->chk_rvalue(lex.cur());
|
|
auto cnt_type = TypeExpr::new_atomic(_Int);
|
|
try {
|
|
unify(expr->e_type, cnt_type);
|
|
} catch (UnifyError& ue) {
|
|
std::ostringstream os;
|
|
os << "while condition value of type " << expr->e_type << " is not an integer: " << ue;
|
|
lex.cur().error(os.str());
|
|
}
|
|
Op& while_op = code.emplace_back(loc, Op::_While);
|
|
code.push_set_cur(while_op.block0);
|
|
while_op.left = expr->pre_compile(code);
|
|
code.close_pop_cur(lex.cur().loc);
|
|
if (while_op.left.size() != 1) {
|
|
lex.cur().error("while condition value is not a singleton");
|
|
}
|
|
code.push_set_cur(while_op.block1);
|
|
blk_fl::val res1 = parse_block_stmt(lex, code);
|
|
code.close_pop_cur(lex.cur().loc);
|
|
return res1 | blk_fl::end;
|
|
}
|
|
|
|
blk_fl::val parse_do_stmt(Lexer& lex, CodeBlob& code) {
|
|
Op& while_op = code.emplace_back(lex.cur().loc, Op::_Until);
|
|
lex.expect(_Do);
|
|
code.push_set_cur(while_op.block0);
|
|
sym::open_scope(lex);
|
|
blk_fl::val res = parse_block_stmt(lex, code, true);
|
|
lex.expect(_Until);
|
|
auto expr = parse_expr(lex, code);
|
|
expr->chk_rvalue(lex.cur());
|
|
sym::close_scope(lex);
|
|
auto cnt_type = TypeExpr::new_atomic(_Int);
|
|
try {
|
|
unify(expr->e_type, cnt_type);
|
|
} catch (UnifyError& ue) {
|
|
std::ostringstream os;
|
|
os << "`until` condition value of type " << expr->e_type << " is not an integer: " << ue;
|
|
lex.cur().error(os.str());
|
|
}
|
|
while_op.left = expr->pre_compile(code);
|
|
code.close_pop_cur(lex.cur().loc);
|
|
if (while_op.left.size() != 1) {
|
|
lex.cur().error("`until` condition value is not a singleton");
|
|
}
|
|
return res & ~blk_fl::empty;
|
|
}
|
|
|
|
blk_fl::val parse_if_stmt(Lexer& lex, CodeBlob& code, int first_lex = _If) {
|
|
SrcLocation loc{lex.cur().loc};
|
|
lex.expect(first_lex);
|
|
auto expr = parse_expr(lex, code);
|
|
expr->chk_rvalue(lex.cur());
|
|
auto flag_type = TypeExpr::new_atomic(_Int);
|
|
try {
|
|
unify(expr->e_type, flag_type);
|
|
} catch (UnifyError& ue) {
|
|
std::ostringstream os;
|
|
os << "`if` condition value of type " << expr->e_type << " is not an integer: " << ue;
|
|
lex.cur().error(os.str());
|
|
}
|
|
std::vector<var_idx_t> tmp_vars = expr->pre_compile(code);
|
|
if (tmp_vars.size() != 1) {
|
|
lex.cur().error("condition value is not a singleton");
|
|
}
|
|
Op& if_op = code.emplace_back(loc, Op::_If, tmp_vars);
|
|
code.push_set_cur(if_op.block0);
|
|
blk_fl::val res1 = parse_block_stmt(lex, code);
|
|
blk_fl::val res2 = blk_fl::init;
|
|
code.close_pop_cur(lex.cur().loc);
|
|
if (lex.tp() == _Else) {
|
|
lex.expect(_Else);
|
|
code.push_set_cur(if_op.block1);
|
|
res2 = parse_block_stmt(lex, code);
|
|
code.close_pop_cur(lex.cur().loc);
|
|
} else if (lex.tp() == _Elseif || lex.tp() == _Elseifnot) {
|
|
code.push_set_cur(if_op.block1);
|
|
res2 = parse_if_stmt(lex, code, lex.tp());
|
|
code.close_pop_cur(lex.cur().loc);
|
|
} else {
|
|
if_op.block1 = std::make_unique<Op>(lex.cur().loc, Op::_Nop);
|
|
}
|
|
if (first_lex == _Ifnot || first_lex == _Elseifnot) {
|
|
std::swap(if_op.block0, if_op.block1);
|
|
}
|
|
blk_fl::combine_parallel(res1, res2);
|
|
return res1;
|
|
}
|
|
|
|
blk_fl::val parse_stmt(Lexer& lex, CodeBlob& code) {
|
|
switch (lex.tp()) {
|
|
case _Return: {
|
|
lex.next();
|
|
return parse_return_stmt(lex, code);
|
|
}
|
|
case '{': {
|
|
return parse_block_stmt(lex, code);
|
|
}
|
|
case ';': {
|
|
lex.next();
|
|
return blk_fl::init;
|
|
}
|
|
case _Repeat:
|
|
return parse_repeat_stmt(lex, code);
|
|
case _If:
|
|
case _Ifnot:
|
|
return parse_if_stmt(lex, code, lex.tp());
|
|
case _Do:
|
|
return parse_do_stmt(lex, code);
|
|
case _While:
|
|
return parse_while_stmt(lex, code);
|
|
default: {
|
|
auto expr = parse_expr(lex, code);
|
|
expr->chk_rvalue(lex.cur());
|
|
expr->pre_compile(code);
|
|
lex.expect(';');
|
|
return blk_fl::end;
|
|
}
|
|
}
|
|
}
|
|
|
|
CodeBlob* parse_func_body(Lexer& lex, FormalArgList arg_list, TypeExpr* ret_type) {
|
|
lex.expect('{');
|
|
CodeBlob* blob = new CodeBlob{ret_type};
|
|
blob->import_params(std::move(arg_list));
|
|
blk_fl::val res = blk_fl::init;
|
|
bool warned = false;
|
|
while (lex.tp() != '}') {
|
|
if (!(res & blk_fl::end) && !warned) {
|
|
lex.cur().loc.show_warning("unreachable code");
|
|
warned = true;
|
|
}
|
|
blk_fl::combine(res, parse_stmt(lex, *blob));
|
|
}
|
|
if (res & blk_fl::end) {
|
|
parse_implicit_ret_stmt(lex, *blob);
|
|
}
|
|
blob->close_blk(lex.cur().loc);
|
|
lex.expect('}');
|
|
return blob;
|
|
}
|
|
|
|
SymValAsmFunc* parse_asm_func_body(Lexer& lex, TypeExpr* func_type, const FormalArgList& arg_list, TypeExpr* ret_type,
|
|
bool impure = false) {
|
|
auto loc = lex.cur().loc;
|
|
lex.expect(_Asm);
|
|
int cnt = (int)arg_list.size();
|
|
int width = ret_type->get_width();
|
|
if (width < 0 || width > 16) {
|
|
throw src::ParseError{loc, "return type of an assembler built-in function must have a well-defined fixed width"};
|
|
}
|
|
if (arg_list.size() > 16) {
|
|
throw src::ParseError{loc, "assembler built-in function must have at most 16 arguments"};
|
|
}
|
|
std::vector<int> cum_arg_width;
|
|
cum_arg_width.push_back(0);
|
|
int tot_width = 0;
|
|
for (auto& arg : arg_list) {
|
|
int arg_width = std::get<TypeExpr*>(arg)->get_width();
|
|
if (arg_width < 0 || arg_width > 16) {
|
|
throw src::ParseError{std::get<SrcLocation>(arg),
|
|
"parameters of an assembler built-in function must have a well-defined fixed width"};
|
|
}
|
|
cum_arg_width.push_back(tot_width += arg_width);
|
|
}
|
|
std::vector<AsmOp> asm_ops;
|
|
std::vector<int> arg_order, ret_order;
|
|
if (lex.tp() == '(') {
|
|
lex.expect('(');
|
|
if (lex.tp() != _Mapsto) {
|
|
std::vector<bool> visited(cnt, false);
|
|
for (int i = 0; i < cnt; i++) {
|
|
if (lex.tp() != _Ident) {
|
|
lex.expect(_Ident);
|
|
}
|
|
auto sym = sym::lookup_symbol(lex.cur().val);
|
|
int j;
|
|
for (j = 0; j < cnt; j++) {
|
|
if (std::get<SymDef*>(arg_list[j]) == sym) {
|
|
break;
|
|
}
|
|
}
|
|
if (j == cnt) {
|
|
lex.cur().error("formal argument name expected");
|
|
}
|
|
if (visited[j]) {
|
|
lex.cur().error("formal argument listed twice");
|
|
}
|
|
visited[j] = true;
|
|
int c1 = cum_arg_width[j], c2 = cum_arg_width[j + 1];
|
|
while (c1 < c2) {
|
|
arg_order.push_back(c1++);
|
|
}
|
|
lex.next();
|
|
}
|
|
assert(arg_order.size() == (unsigned)tot_width);
|
|
}
|
|
if (lex.tp() == _Mapsto) {
|
|
lex.expect(_Mapsto);
|
|
std::vector<bool> visited(width, false);
|
|
for (int i = 0; i < width; i++) {
|
|
if (lex.tp() != Lexem::Number || lex.cur().str.size() > 3) {
|
|
lex.expect(Lexem::Number);
|
|
}
|
|
int j = atoi(lex.cur().str.c_str());
|
|
if (j < 0 || j >= width || visited[j]) {
|
|
lex.cur().error("expected integer return value index 0 .. width-1");
|
|
}
|
|
visited[j] = true;
|
|
ret_order.push_back(j);
|
|
lex.next();
|
|
}
|
|
}
|
|
lex.expect(')');
|
|
}
|
|
while (lex.tp() == _String) {
|
|
asm_ops.push_back(AsmOp::Parse(lex.cur().str, cnt, width));
|
|
lex.next();
|
|
if (asm_ops.back().is_custom()) {
|
|
cnt = width;
|
|
}
|
|
}
|
|
if (asm_ops.empty()) {
|
|
throw src::ParseError{lex.cur().loc, "string with assembler instruction expected"};
|
|
}
|
|
lex.expect(';');
|
|
auto res = new SymValAsmFunc{func_type, asm_ops, impure};
|
|
res->arg_order = std::move(arg_order);
|
|
res->ret_order = std::move(ret_order);
|
|
return res;
|
|
}
|
|
|
|
void parse_func_def(Lexer& lex) {
|
|
SrcLocation loc{lex.cur().loc};
|
|
sym::open_scope(lex);
|
|
auto ret_type = parse_type(lex);
|
|
if (lex.tp() != _Ident) {
|
|
throw src::ParseError{lex.cur().loc, "function name identifier expected"};
|
|
}
|
|
Lexem func_name = lex.cur();
|
|
lex.next();
|
|
FormalArgList arg_list = parse_formal_args(lex);
|
|
bool impure = (lex.tp() == _Impure);
|
|
if (impure) {
|
|
lex.next();
|
|
}
|
|
td::RefInt256 method_id;
|
|
std::string method_name;
|
|
if (lex.tp() == _MethodId) {
|
|
lex.next();
|
|
if (lex.tp() == '(') {
|
|
lex.expect('(');
|
|
if (lex.tp() == Lexem::String) {
|
|
method_name = lex.cur().str;
|
|
} else if (lex.tp() == Lexem::Number) {
|
|
method_name = lex.cur().str;
|
|
method_id = td::string_to_int256(method_name);
|
|
if (method_id.is_null()) {
|
|
lex.cur().error_at("invalid integer constant `", "`");
|
|
}
|
|
} else {
|
|
throw src::ParseError{lex.cur().loc, "integer or string method identifier expected"};
|
|
}
|
|
lex.next();
|
|
lex.expect(')');
|
|
} else {
|
|
method_name = func_name.str;
|
|
}
|
|
if (method_id.is_null()) {
|
|
unsigned crc = td::crc16(method_name);
|
|
method_id = td::make_refint((crc & 0xffff) | 0x10000);
|
|
}
|
|
}
|
|
if (lex.tp() != ';' && lex.tp() != '{' && lex.tp() != _Asm) {
|
|
lex.expect('{', "function body block expected");
|
|
}
|
|
TypeExpr* func_type = TypeExpr::new_map(extract_total_arg_type(arg_list), ret_type);
|
|
if (verbosity >= 1) {
|
|
std::cerr << "function " << func_name.str << " : " << func_type << std::endl;
|
|
}
|
|
SymDef* func_sym = sym::define_global_symbol(func_name.val, 0, loc);
|
|
assert(func_sym);
|
|
SymValFunc* func_sym_val = dynamic_cast<SymValFunc*>(func_sym->value);
|
|
if (func_sym->value) {
|
|
if (func_sym->value->type != SymVal::_Func || !func_sym_val) {
|
|
lex.cur().error("was not defined as a function before");
|
|
}
|
|
try {
|
|
unify(func_sym_val->sym_type, func_type);
|
|
} catch (UnifyError& ue) {
|
|
std::ostringstream os;
|
|
os << "previous type of function " << func_name.str << " : " << func_sym_val->sym_type
|
|
<< " cannot be unified with new type " << func_type << ": " << ue;
|
|
lex.cur().error(os.str());
|
|
}
|
|
}
|
|
if (lex.tp() == ';') {
|
|
make_new_glob_func(func_sym, func_type, impure);
|
|
lex.next();
|
|
} else if (lex.tp() == '{') {
|
|
if (dynamic_cast<SymValAsmFunc*>(func_sym_val)) {
|
|
lex.cur().error("function `"s + func_name.str + "` has been already defined as an assembler built-in");
|
|
}
|
|
SymValCodeFunc* func_sym_code;
|
|
if (func_sym_val) {
|
|
func_sym_code = dynamic_cast<SymValCodeFunc*>(func_sym_val);
|
|
if (!func_sym_code) {
|
|
lex.cur().error("function `"s + func_name.str + "` has been already defined in an yet-unknown way");
|
|
}
|
|
} else {
|
|
func_sym_code = make_new_glob_func(func_sym, func_type, impure);
|
|
}
|
|
if (func_sym_code->code) {
|
|
lex.cur().error("redefinition of function `"s + func_name.str + "`");
|
|
}
|
|
CodeBlob* code = parse_func_body(lex, arg_list, ret_type);
|
|
code->name = func_name.str;
|
|
code->loc = loc;
|
|
// code->print(std::cerr); // !!!DEBUG!!!
|
|
func_sym_code->code = code;
|
|
} else {
|
|
if (func_sym_val) {
|
|
if (dynamic_cast<SymValCodeFunc*>(func_sym_val)) {
|
|
lex.cur().error("function `"s + func_name.str + "` was already declared as an ordinary function");
|
|
}
|
|
if (dynamic_cast<SymValAsmFunc*>(func_sym_val)) {
|
|
lex.cur().error("redefinition of built-in assembler function `"s + func_name.str + "`");
|
|
}
|
|
lex.cur().error("redefinition of previously (somehow) defined function `"s + func_name.str + "`");
|
|
}
|
|
func_sym->value = parse_asm_func_body(lex, func_type, arg_list, ret_type, impure);
|
|
}
|
|
if (method_id.not_null()) {
|
|
auto val = dynamic_cast<SymVal*>(func_sym->value);
|
|
if (!val) {
|
|
lex.cur().error("cannot set method id for unknown function `"s + func_name.str + "`");
|
|
}
|
|
if (val->method_id.is_null()) {
|
|
val->method_id = std::move(method_id);
|
|
} else if (val->method_id != method_id) {
|
|
lex.cur().error("integer method identifier for `"s + func_name.str + "` changed to a different value");
|
|
}
|
|
}
|
|
if (verbosity >= 1) {
|
|
std::cerr << "new type of function " << func_name.str << " : " << func_type << std::endl;
|
|
}
|
|
sym::close_scope(lex);
|
|
}
|
|
|
|
bool parse_source(std::istream* is, const src::FileDescr* fdescr) {
|
|
src::SourceReader reader{is, fdescr};
|
|
Lexer lex{reader, true};
|
|
while (lex.tp() != _Eof) {
|
|
parse_func_def(lex);
|
|
}
|
|
return true;
|
|
}
|
|
|
|
bool parse_source_file(const char* filename) {
|
|
if (!filename || !*filename) {
|
|
throw src::Fatal{"source file name is an empty string"};
|
|
}
|
|
src::FileDescr* cur_source = new src::FileDescr{filename};
|
|
std::ifstream ifs{filename};
|
|
if (ifs.fail()) {
|
|
throw src::Fatal{std::string{"cannot open source file `"} + filename + "`"};
|
|
}
|
|
return parse_source(&ifs, cur_source);
|
|
}
|
|
|
|
bool parse_source_stdin() {
|
|
return parse_source(&std::cin, new src::FileDescr{"stdin", true});
|
|
}
|
|
|
|
} // namespace funC
|