cpp-peglib/pl0/pl0.cc
2018-01-17 00:01:53 -05:00

968 lines
27 KiB
C++

//
// pl0.cc - PL/0 language (https://en.wikipedia.org/wiki/PL/0)
//
// Copyright (c) 2018 Yuji Hirose. All rights reserved.
// MIT License
//
#include <peglib.h>
#include <fstream>
#include <iostream>
#include <sstream>
#include "llvm/ExecutionEngine/ExecutionEngine.h"
#include "llvm/ExecutionEngine/GenericValue.h"
#include "llvm/ExecutionEngine/MCJIT.h"
#include "llvm/IR/IRBuilder.h"
#include "llvm/IR/ValueSymbolTable.h"
#include "llvm/Support/TargetSelect.h"
using namespace peg;
using namespace peg::udl;
using namespace llvm;
using namespace std;
/*
* PEG Grammar
*/
auto grammar = R"(
program <- _ block '.' _
block <- const var procedure statement
const <- ('CONST' __ ident '=' _ number (',' _ ident '=' _ number)* ';' _)?
var <- ('VAR' __ ident (',' _ ident)* ';' _)?
procedure <- ('PROCEDURE' __ ident ';' _ block ';' _)*
statement <- (assignment / call / statements / if / while / out / in)?
assignment <- ident ':=' _ expression
call <- 'CALL' __ ident
statements <- 'BEGIN' __ statement (';' _ statement )* 'END' __
if <- 'IF' __ condition 'THEN' __ statement
while <- 'WHILE' __ condition 'DO' __ statement
out <- ('out' __ / 'write' __ / '!' _) expression
in <- ('in' __ / 'read' __ / '?' _) ident
condition <- odd / compare
odd <- 'ODD' __ expression
compare <- expression compare_op expression
compare_op <- < '=' / '#' / '<=' / '<' / '>=' / '>' > _
expression <- sign term (term_op term)*
sign <- < [-+]? > _
term_op <- < [-+] > _
term <- factor (factor_op factor)*
factor_op <- < [*/] > _
factor <- ident / number / '(' _ expression ')' _
ident <- < [a-z] [a-z0-9]* > _
number <- < [0-9]+ > _
~_ <- [ \t\r\n]*
~__ <- ![a-z0-9_] _
)";
/*
* Utilities
*/
string format_error_message(const string& path, size_t ln, size_t col,
const string& msg) {
stringstream ss;
ss << path << ":" << ln << ":" << col << ": " << msg << endl;
return ss.str();
}
/*
* Ast
*/
struct SymbolScope;
struct Annotation {
shared_ptr<SymbolScope> scope;
};
typedef AstBase<Annotation> AstPL0;
shared_ptr<SymbolScope> get_closest_scope(shared_ptr<AstPL0> ast) {
ast = ast->parent;
while (ast->tag != "block"_) {
ast = ast->parent;
}
return ast->scope;
}
/*
* Symbol Table
*/
struct SymbolScope {
SymbolScope(shared_ptr<SymbolScope> outer) : outer(outer) {}
bool has_symbol(const string& ident, bool extend = true) const {
auto ret = constants.count(ident) || variables.count(ident);
return ret ? true : (extend && outer ? outer->has_symbol(ident) : false);
}
bool has_constant(const string& ident, bool extend = true) const {
return constants.count(ident)
? true
: (extend && outer ? outer->has_constant(ident) : false);
}
bool has_variable(const string& ident, bool extend = true) const {
return variables.count(ident)
? true
: (extend && outer ? outer->has_variable(ident) : false);
}
bool has_procedure(const string& ident, bool extend = true) const {
return procedures.count(ident)
? true
: (extend && outer ? outer->has_procedure(ident) : false);
}
shared_ptr<AstPL0> get_procedure(const string& ident) const {
auto it = procedures.find(ident);
return it != procedures.end() ? it->second : outer->get_procedure(ident);
}
map<string, int> constants;
set<string> variables;
map<string, shared_ptr<AstPL0>> procedures;
set<string> free_variables;
private:
shared_ptr<SymbolScope> outer;
};
void throw_runtime_error(const shared_ptr<AstPL0> node, const string& msg) {
throw runtime_error(
format_error_message(node->path, node->line, node->column, msg));
}
struct SymbolTable {
static void build_on_ast(const shared_ptr<AstPL0> ast,
shared_ptr<SymbolScope> scope = nullptr) {
switch (ast->tag) {
case "block"_:
block(ast, scope);
break;
case "assignment"_:
assignment(ast, scope);
break;
case "call"_:
call(ast, scope);
break;
case "ident"_:
ident(ast, scope);
break;
default:
for (auto node : ast->nodes) {
build_on_ast(node, scope);
}
break;
}
}
private:
static void block(const shared_ptr<AstPL0> ast,
shared_ptr<SymbolScope> outer) {
// block <- const var procedure statement
auto scope = make_shared<SymbolScope>(outer);
const auto& nodes = ast->nodes;
constants(nodes[0], scope);
variables(nodes[1], scope);
procedures(nodes[2], scope);
build_on_ast(nodes[3], scope);
ast->scope = scope;
}
static void constants(const shared_ptr<AstPL0> ast,
shared_ptr<SymbolScope> scope) {
// const <- ('CONST' __ ident '=' _ number(',' _ ident '=' _ number)* ';'
// _)?
const auto& nodes = ast->nodes;
for (auto i = 0u; i < nodes.size(); i += 2) {
const auto& ident = nodes[i + 0]->token;
if (scope->has_symbol(ident)) {
throw_runtime_error(nodes[i], "'" + ident + "' is already defined...");
}
auto number = stoi(nodes[i + 1]->token);
scope->constants.emplace(ident, number);
}
}
static void variables(const shared_ptr<AstPL0> ast,
shared_ptr<SymbolScope> scope) {
// var <- ('VAR' __ ident(',' _ ident)* ';' _) ?
const auto& nodes = ast->nodes;
for (auto i = 0u; i < nodes.size(); i += 1) {
const auto& ident = nodes[i]->token;
if (scope->has_symbol(ident)) {
throw_runtime_error(nodes[i], "'" + ident + "' is already defined...");
}
scope->variables.emplace(ident);
}
}
static void procedures(const shared_ptr<AstPL0> ast,
shared_ptr<SymbolScope> scope) {
// procedure <- ('PROCEDURE' __ ident ';' _ block ';' _)*
const auto& nodes = ast->nodes;
for (auto i = 0u; i < nodes.size(); i += 2) {
const auto& ident = nodes[i + 0]->token;
auto block = nodes[i + 1];
scope->procedures[ident] = block;
build_on_ast(block, scope);
}
}
static void assignment(const shared_ptr<AstPL0> ast,
shared_ptr<SymbolScope> scope) {
// assignment <- ident ':=' _ expression
const auto& ident = ast->nodes[0]->token;
if (scope->has_constant(ident)) {
throw_runtime_error(ast->nodes[0],
"cannot modify constant value '" + ident + "'...");
} else if (!scope->has_variable(ident)) {
throw_runtime_error(ast->nodes[0],
"undefined variable '" + ident + "'...");
}
build_on_ast(ast->nodes[1], scope);
if (!scope->has_symbol(ident, false)) {
scope->free_variables.emplace(ident);
}
}
static void call(const shared_ptr<AstPL0> ast,
shared_ptr<SymbolScope> scope) {
// call <- 'CALL' __ ident
const auto& ident = ast->nodes[0]->token;
if (!scope->has_procedure(ident)) {
throw_runtime_error(ast->nodes[0],
"undefined procedure '" + ident + "'...");
}
auto block = scope->get_procedure(ident);
if (block->scope) {
for (const auto& free : block->scope->free_variables) {
if (!scope->has_symbol(free, false)) {
scope->free_variables.emplace(free);
}
}
}
}
static void ident(const shared_ptr<AstPL0> ast,
shared_ptr<SymbolScope> scope) {
const auto& ident = ast->token;
if (!scope->has_symbol(ident)) {
throw_runtime_error(ast, "undefined variable '" + ident + "'...");
}
if (!scope->has_symbol(ident, false)) {
scope->free_variables.emplace(ident);
}
}
};
/*
* Interpreter
*/
struct Environment {
Environment(shared_ptr<SymbolScope> scope, shared_ptr<Environment> outer)
: scope(scope), outer(outer) {}
int get_value(const shared_ptr<AstPL0> ast, const string& ident) const {
auto it = scope->constants.find(ident);
if (it != scope->constants.end()) {
return it->second;
} else if (scope->variables.count(ident)) {
if (variables.find(ident) == variables.end()) {
throw_runtime_error(ast, "uninitialized variable '" + ident + "'...");
}
return variables.at(ident);
}
return outer->get_value(ast, ident);
}
void set_variable(const string& ident, int val) {
if (scope->variables.count(ident)) {
variables[ident] = val;
} else {
outer->set_variable(ident, val);
}
}
shared_ptr<AstPL0> get_procedure(const string& ident) const {
return scope->get_procedure(ident);
}
private:
shared_ptr<SymbolScope> scope;
shared_ptr<Environment> outer;
map<string, int> variables;
};
struct Interpreter {
static void exec(const shared_ptr<AstPL0> ast,
shared_ptr<Environment> env = nullptr) {
switch (ast->tag) {
case "block"_:
exec_block(ast, env);
break;
case "statement"_:
exec_statement(ast, env);
break;
case "assignment"_:
exec_assignment(ast, env);
break;
case "call"_:
exec_call(ast, env);
break;
case "statements"_:
exec_statements(ast, env);
break;
case "if"_:
exec_if(ast, env);
break;
case "while"_:
exec_while(ast, env);
break;
case "out"_:
exec_out(ast, env);
break;
case "in"_:
exec_in(ast, env);
break;
default:
exec(ast->nodes[0], env);
break;
}
}
private:
static void exec_block(const shared_ptr<AstPL0> ast,
shared_ptr<Environment> outer) {
// block <- const var procedure statement
exec(ast->nodes[3], make_shared<Environment>(ast->scope, outer));
}
static void exec_statement(const shared_ptr<AstPL0> ast,
shared_ptr<Environment> env) {
// statement <- (assignment / call / statements / if / while / out / in)?
if (!ast->nodes.empty()) {
exec(ast->nodes[0], env);
}
}
static void exec_assignment(const shared_ptr<AstPL0> ast,
shared_ptr<Environment> env) {
// assignment <- ident ':=' _ expression
env->set_variable(ast->nodes[0]->token, eval(ast->nodes[1], env));
}
static void exec_call(const shared_ptr<AstPL0> ast,
shared_ptr<Environment> env) {
// call <- 'CALL' __ ident
exec_block(env->get_procedure(ast->nodes[0]->token), env);
}
static void exec_statements(const shared_ptr<AstPL0> ast,
shared_ptr<Environment> env) {
// statements <- 'BEGIN' __ statement (';' _ statement )* 'END' __
for (auto stmt : ast->nodes) {
exec(stmt, env);
}
}
static void exec_if(const shared_ptr<AstPL0> ast,
shared_ptr<Environment> env) {
// if <- 'IF' __ condition 'THEN' __ statement
if (eval_condition(ast->nodes[0], env)) {
exec(ast->nodes[1], env);
}
}
static void exec_while(const shared_ptr<AstPL0> ast,
shared_ptr<Environment> env) {
// while <- 'WHILE' __ condition 'DO' __ statement
auto cond = ast->nodes[0];
auto stmt = ast->nodes[1];
while (eval_condition(cond, env)) {
exec(stmt, env);
}
}
static void exec_out(const shared_ptr<AstPL0> ast,
shared_ptr<Environment> env) {
// out <- ('out' __ / 'write' __ / '!' _) expression
cout << eval(ast->nodes[0], env) << endl;
}
static void exec_in(const shared_ptr<AstPL0> ast,
shared_ptr<Environment> env) {
// in <- ('in' __ / 'read' __ / '?' _) ident
int val;
cin >> val;
env->set_variable(ast->nodes[0]->token, val);
}
static bool eval_condition(const shared_ptr<AstPL0> ast,
shared_ptr<Environment> env) {
// condition <- odd / compare
const auto& node = ast->nodes[0];
switch (node->tag) {
case "odd"_:
return eval_odd(node, env);
case "compare"_:
return eval_compare(node, env);
default:
throw logic_error("invalid AstPL0 type");
}
}
static bool eval_odd(const shared_ptr<AstPL0> ast,
shared_ptr<Environment> env) {
// odd <- 'ODD' __ expression
return eval_expression(ast->nodes[0], env) != 0;
}
static bool eval_compare(const shared_ptr<AstPL0> ast,
shared_ptr<Environment> env) {
// compare <- expression compare_op expression
const auto& nodes = ast->nodes;
auto lval = eval_expression(nodes[0], env);
auto op = peg::str2tag(nodes[1]->token.c_str());
auto rval = eval_expression(nodes[2], env);
switch (op) {
case "="_:
return lval == rval;
case "#"_:
return lval != rval;
case "<="_:
return lval <= rval;
case "<"_:
return lval < rval;
case ">="_:
return lval >= rval;
case ">"_:
return lval > rval;
default:
throw logic_error("invalid operator");
}
}
static int eval(const shared_ptr<AstPL0> ast, shared_ptr<Environment> env) {
switch (ast->tag) {
case "expression"_:
return eval_expression(ast, env);
case "term"_:
return eval_term(ast, env);
case "ident"_:
return eval_ident(ast, env);
case "number"_:
return eval_number(ast, env);
default:
return eval(ast->nodes[0], env);
}
}
static int eval_expression(const shared_ptr<AstPL0> ast,
shared_ptr<Environment> env) {
// expression <- sign term (term_op term)*
const auto& nodes = ast->nodes;
auto sign = nodes[0]->token;
auto sign_val = (sign.empty() || sign == "+") ? 1 : -1;
auto val = eval(nodes[1], env) * sign_val;
for (auto i = 2u; i < nodes.size(); i += 2) {
auto ope = nodes[i + 0]->token[0];
auto rval = eval(nodes[i + 1], env);
switch (ope) {
case '+':
val = val + rval;
break;
case '-':
val = val - rval;
break;
}
}
return val;
}
static int eval_term(const shared_ptr<AstPL0> ast,
shared_ptr<Environment> env) {
// term <- factor (factor_op factor)*
const auto& nodes = ast->nodes;
auto val = eval(nodes[0], env);
for (auto i = 1u; i < nodes.size(); i += 2) {
auto ope = nodes[i + 0]->token[0];
auto rval = eval(nodes[i + 1], env);
switch (ope) {
case '*':
val = val * rval;
break;
case '/':
if (rval == 0) {
throw_runtime_error(ast, "divide by 0 error");
}
val = val / rval;
break;
}
}
return val;
}
static int eval_ident(const shared_ptr<AstPL0> ast,
shared_ptr<Environment> env) {
return env->get_value(ast, ast->token);
}
static int eval_number(const shared_ptr<AstPL0> ast,
shared_ptr<Environment> env) {
return stol(ast->token);
}
};
/*
* LLVM
*/
struct LLVM {
LLVM(const shared_ptr<AstPL0> ast) : builder_(context_) {
module_ = make_unique<Module>("pl0", context_);
compile(ast);
}
void dump() { module_->print(llvm::errs(), nullptr); }
void exec() {
unique_ptr<ExecutionEngine> ee(EngineBuilder(std::move(module_)).create());
std::vector<GenericValue> noargs;
auto fn = ee->FindFunctionNamed("main");
auto ret = ee->runFunction(fn, noargs);
}
private:
LLVMContext context_;
IRBuilder<> builder_;
unique_ptr<Module> module_;
void compile(const shared_ptr<AstPL0> ast) {
InitializeNativeTarget();
InitializeNativeTargetAsmPrinter();
compile_libs();
compile_program(ast);
}
void compile_switch(const shared_ptr<AstPL0> ast) {
switch (ast->tag) {
case "assignment"_:
compile_assignment(ast);
break;
case "call"_:
compile_call(ast);
break;
case "statements"_:
compile_statements(ast);
break;
case "if"_:
compile_if(ast);
break;
case "while"_:
compile_while(ast);
break;
case "out"_:
compile_out(ast);
break;
default:
compile_switch(ast->nodes[0]);
break;
}
}
Value* compile_switch_value(const shared_ptr<AstPL0> ast) {
switch (ast->tag) {
case "odd"_:
return compile_odd(ast);
case "compare"_:
return compile_compare(ast);
case "expression"_:
return compile_expression(ast);
case "ident"_:
return compile_ident(ast);
case "number"_:
return compile_number(ast);
default:
return compile_switch_value(ast->nodes[0]);
}
}
void compile_libs() {
auto printfF = module_->getOrInsertFunction(
"printf",
FunctionType::get(builder_.getInt32Ty(),
PointerType::get(builder_.getInt8Ty(), 0), true));
auto outF = cast<Function>(module_->getOrInsertFunction(
"out", builder_.getVoidTy(), builder_.getInt32Ty()));
{
auto BB = BasicBlock::Create(context_, "entry", outF);
builder_.SetInsertPoint(BB);
auto val = &*outF->arg_begin();
auto fmt = builder_.CreateGlobalStringPtr("%d\n");
std::vector<Value*> args = {fmt, val};
builder_.CreateCall(printfF, args);
builder_.CreateRetVoid();
}
}
void compile_program(const shared_ptr<AstPL0> ast) {
auto fn = cast<Function>(
module_->getOrInsertFunction("main", builder_.getVoidTy()));
{
auto BB = BasicBlock::Create(context_, "entry", fn);
builder_.SetInsertPoint(BB);
compile_block(ast->nodes[0]);
builder_.CreateRetVoid();
}
}
void compile_block(const shared_ptr<AstPL0> ast) {
compile_const(ast->nodes[0]);
compile_var(ast->nodes[1]);
compile_procedure(ast->nodes[2]);
compile_statement(ast->nodes[3]);
}
void compile_const(const shared_ptr<AstPL0> ast) {
for (auto i = 0u; i < ast->nodes.size(); i += 2) {
auto ident = ast->nodes[i]->token;
auto number = stoi(ast->nodes[i + 1]->token);
auto alloca =
builder_.CreateAlloca(builder_.getInt32Ty(), nullptr, ident);
builder_.CreateStore(builder_.getInt32(number), alloca);
}
}
void compile_var(const shared_ptr<AstPL0> ast) {
for (const auto node : ast->nodes) {
auto ident = node->token;
builder_.CreateAlloca(builder_.getInt32Ty(), nullptr, ident);
}
}
void compile_procedure(const shared_ptr<AstPL0> ast) {
for (auto i = 0u; i < ast->nodes.size(); i += 2) {
auto ident = ast->nodes[i]->token;
auto block = ast->nodes[i + 1];
std::vector<Type*> pt(block->scope->free_variables.size(),
Type::getInt32PtrTy(context_));
auto ft = FunctionType::get(builder_.getVoidTy(), pt, false);
auto fn = cast<Function>(module_->getOrInsertFunction(ident, ft));
{
auto it = block->scope->free_variables.begin();
for (auto& arg : fn->args()) {
arg.setName(*it);
++it;
}
}
{
auto prevBB = builder_.GetInsertBlock();
auto BB = BasicBlock::Create(context_, "entry", fn);
builder_.SetInsertPoint(BB);
compile_block(block);
builder_.CreateRetVoid();
builder_.SetInsertPoint(prevBB);
}
}
}
void compile_statement(const shared_ptr<AstPL0> ast) {
if (!ast->nodes.empty()) {
compile_switch(ast->nodes[0]);
}
}
void compile_assignment(const shared_ptr<AstPL0> ast) {
auto ident = ast->nodes[0]->token;
auto fn = builder_.GetInsertBlock()->getParent();
auto tbl = fn->getValueSymbolTable();
auto var = tbl->lookup(ident);
if (!var) {
throw_runtime_error(ast, "'" + ident + "' is not defined...");
}
auto val = compile_expression(ast->nodes[1]);
builder_.CreateStore(val, var);
}
void compile_call(const shared_ptr<AstPL0> ast) {
auto ident = ast->nodes[0]->token;
auto scope = get_closest_scope(ast);
auto block = scope->get_procedure(ident);
std::vector<Value*> args;
for (auto& free : block->scope->free_variables) {
auto fn = builder_.GetInsertBlock()->getParent();
auto tbl = fn->getValueSymbolTable();
auto var = tbl->lookup(free);
if (!var) {
throw_runtime_error(ast, "'" + free + "' is not defined...");
}
args.push_back(var);
}
auto fn = module_->getFunction(ident);
builder_.CreateCall(fn, args);
}
void compile_statements(const shared_ptr<AstPL0> ast) {
for (auto node : ast->nodes) {
compile_statement(node);
}
}
void compile_if(const shared_ptr<AstPL0> ast) {
auto cond = compile_condition(ast->nodes[0]);
auto fn = builder_.GetInsertBlock()->getParent();
auto ifThen = BasicBlock::Create(context_, "if.then", fn);
auto ifEnd = BasicBlock::Create(context_, "if.end");
builder_.CreateCondBr(cond, ifThen, ifEnd);
builder_.SetInsertPoint(ifThen);
compile_statement(ast->nodes[1]);
builder_.CreateBr(ifEnd);
fn->getBasicBlockList().push_back(ifEnd);
builder_.SetInsertPoint(ifEnd);
}
void compile_while(const shared_ptr<AstPL0> ast) {
auto whileCond = BasicBlock::Create(context_, "while.cond");
builder_.CreateBr(whileCond);
auto fn = builder_.GetInsertBlock()->getParent();
fn->getBasicBlockList().push_back(whileCond);
builder_.SetInsertPoint(whileCond);
auto cond = compile_condition(ast->nodes[0]);
auto whileBody = BasicBlock::Create(context_, "while.body", fn);
auto whileEnd = BasicBlock::Create(context_, "while.end");
builder_.CreateCondBr(cond, whileBody, whileEnd);
builder_.SetInsertPoint(whileBody);
compile_statement(ast->nodes[1]);
builder_.CreateBr(whileCond);
fn->getBasicBlockList().push_back(whileEnd);
builder_.SetInsertPoint(whileEnd);
}
Value* compile_condition(const shared_ptr<AstPL0> ast) {
return compile_switch_value(ast->nodes[0]);
}
Value* compile_odd(const shared_ptr<AstPL0> ast) {
auto val = compile_expression(ast->nodes[0]);
return builder_.CreateICmpNE(val, builder_.getInt32(0), "icmpne");
}
Value* compile_compare(const shared_ptr<AstPL0> ast) {
auto lhs = compile_expression(ast->nodes[0]);
auto rhs = compile_expression(ast->nodes[2]);
const auto& ope = ast->nodes[1]->token;
switch (ope[0]) {
case '=':
return builder_.CreateICmpEQ(lhs, rhs, "icmpeq");
case '#':
return builder_.CreateICmpNE(lhs, rhs, "icmpne");
case '<':
if (ope.size() == 1) {
return builder_.CreateICmpSLT(lhs, rhs, "icmpslt");
}
// '<='
return builder_.CreateICmpSLE(lhs, rhs, "icmpsle");
case '>':
if (ope.size() == 1) {
return builder_.CreateICmpSGT(lhs, rhs, "icmpsgt");
}
// '>='
return builder_.CreateICmpSGE(lhs, rhs, "icmpsge");
}
return nullptr;
}
void compile_out(const shared_ptr<AstPL0> ast) {
auto val = compile_expression(ast->nodes[0]);
auto outF = module_->getFunction("out");
builder_.CreateCall(outF, val);
}
Value* compile_expression(const shared_ptr<AstPL0> ast) {
const auto& nodes = ast->nodes;
auto sign = nodes[0]->token;
auto negative = !(sign.empty() || sign == "+");
auto val = compile_term(nodes[1]);
if (negative) {
val = builder_.CreateNeg(val, "negative");
}
for (auto i = 2u; i < nodes.size(); i += 2) {
auto ope = nodes[i + 0]->token[0];
auto rval = compile_term(nodes[i + 1]);
switch (ope) {
case '+':
val = builder_.CreateAdd(val, rval, "add");
break;
case '-':
val = builder_.CreateSub(val, rval, "sub");
break;
}
}
return val;
}
Value* compile_term(const shared_ptr<AstPL0> ast) {
const auto& nodes = ast->nodes;
auto val = compile_factor(nodes[0]);
for (auto i = 1u; i < nodes.size(); i += 2) {
auto ope = nodes[i + 0]->token[0];
auto rval = compile_switch_value(nodes[i + 1]);
switch (ope) {
case '*':
val = builder_.CreateMul(val, rval, "mul");
break;
case '/': {
// TODO: Zero devide error?
// auto ret = builder_.CreateICmpEQ(rval, builder_.getInt32(0),
// "icmpeq");
// if (!ret) {
// throw_runtime_error(ast, "divide by 0 error");
// }
val = builder_.CreateSDiv(val, rval, "div");
break;
}
}
}
return val;
}
Value* compile_factor(const shared_ptr<AstPL0> ast) {
return compile_switch_value(ast->nodes[0]);
}
Value* compile_ident(const shared_ptr<AstPL0> ast) {
auto ident = ast->token;
auto fn = builder_.GetInsertBlock()->getParent();
auto tbl = fn->getValueSymbolTable();
auto var = tbl->lookup(ident);
if (!var) {
throw_runtime_error(ast, "'" + ident + "' is not defined...");
}
return builder_.CreateLoad(var);
}
Value* compile_number(const shared_ptr<AstPL0> ast) {
return ConstantInt::getIntegerValue(builder_.getInt32Ty(),
APInt(32, ast->token, 10));
}
};
/*
* Main
*/
int main(int argc, const char** argv) {
if (argc < 2) {
cout << "usage: pl0 PATH [--ast] [--llvm] [--jit]" << endl;
return 1;
}
// Parser commandline parameters
auto path = argv[1];
bool opt_jit = false;
bool opt_ast = false;
bool opt_llvm = false;
{
auto argi = 2;
while (argi < argc) {
if (string("--ast") == argv[argi]) {
opt_ast = true;
} else if (string("--jit") == argv[argi]) {
opt_jit = true;
} else if (string("--llvm") == argv[argi]) {
opt_llvm = true;
}
argi++;
}
}
// Read a source file into memory
vector<char> source;
ifstream ifs(path, ios::in | ios::binary);
if (ifs.fail()) {
cerr << "can't open the source file." << endl;
return -1;
}
source.resize(static_cast<unsigned int>(ifs.seekg(0, ios::end).tellg()));
if (!source.empty()) {
ifs.seekg(0, ios::beg)
.read(&source[0], static_cast<streamsize>(source.size()));
}
// Setup a PEG parser
parser parser(grammar);
parser.enable_ast<AstPL0>();
parser.log = [&](size_t ln, size_t col, const string& msg) {
cerr << format_error_message(path, ln, col, msg) << endl;
};
// Parse the source and make an AST
shared_ptr<AstPL0> ast;
if (parser.parse_n(source.data(), source.size(), ast, path)) {
try {
SymbolTable::build_on_ast(ast);
if (opt_ast) {
cout << ast_to_s<AstPL0>(ast);
}
if (opt_llvm || opt_jit) {
LLVM compiler(ast);
if (opt_llvm) {
compiler.dump();
}
if (opt_jit) {
compiler.exec();
}
} else {
Interpreter::exec(ast);
}
} catch (const runtime_error& e) {
cerr << e.what() << endl;
}
return 0;
}
return -1;
}