#include "vm.hpp"
#include "arch.hpp"
#include <cstdint>
#include <cstdlib>
#include <format>
#include <iostream>
#include <string>
#include <utility>
#include <vector>
using namespace sliger;
inline auto maybe_op_to_string(uint32_t value) -> std::string
{
switch (static_cast<Op>(value)) {
/* clang-format off */
case Op::Nop: return "Nop";
case Op::PushNull: return "PushNull";
case Op::PushInt: return "PushInt";
case Op::PushBool: return "PushBool";
case Op::PushString: return "PushString";
case Op::PushPtr: return "PushPtr";
case Op::Pop: return "Pop";
case Op::ReserveStatic: return "ReserveStatic";
case Op::LoadStatic: return "LoadStatic";
case Op::StoreStatic: return "StoreStatic";
case Op::LoadLocal: return "LoadLocal";
case Op::StoreLocal: return "StoreLocal";
case Op::Call: return "Call";
case Op::Return: return "Return";
case Op::Jump: return "Jump";
case Op::JumpIfTrue: return "JumpIfTrue";
case Op::Builtin: return "Builtin";
case Op::Add: return "Add";
case Op::Subtract: return "Subtract";
case Op::Multiply: return "Multiply";
case Op::Divide: return "Divide";
case Op::Remainder: return "Remainder";
case Op::Equal: return "Equal";
case Op::LessThan: return "LessThan";
case Op::And: return "And";
case Op::Or: return "Or";
case Op::Xor: return "Xor";
case Op::Not: return "Not";
case Op::SourceMap: return "SourceMap";
/* clang-format on */
default:
return std::to_string(value);
}
}
void VM::run_until_done()
{
while (!done()) {
run_instruction();
}
this->flame_graph.calculate_midway_result(this->instruction_counter);
}
void VM::run_n_instructions(size_t amount)
{
for (size_t i = 0; !done() and i < amount; ++i) {
run_instruction();
}
this->flame_graph.calculate_midway_result(this->instruction_counter);
}
void VM::run_instruction()
{
if (this->opts.print_stack_debug) {
std::cout << std::format(" {:>4}: {:<12}{}\n", this->pc,
maybe_op_to_string(this->program[this->pc]), stack_repr_string(8));
}
auto op = eat_op();
switch (op) {
case Op::Nop:
// nothing
break;
case Op::PushNull:
this->stack.push_back(Null {});
break;
case Op::PushInt: {
assert_program_has(1);
auto value = eat_int32();
this->stack.push_back(Int { value });
break;
}
case Op::PushBool: {
assert_program_has(1);
auto value = eat_int32();
this->stack.push_back(Bool { .value = value != 0 });
break;
}
case Op::PushString: {
assert_program_has(1);
auto string_length = eat_uint32();
assert_program_has(string_length);
auto value = std::string();
for (uint32_t i = 0; i < string_length; ++i) {
auto ch = eat_uint32();
value.push_back(static_cast<char>(ch));
}
stack_push(String { .value = std::move(value) });
break;
}
case Op::PushPtr: {
assert_program_has(1);
auto value = eat_uint32();
this->stack.push_back(Ptr { value });
break;
}
case Op::Pop: {
assert_stack_has(1);
this->stack.pop_back();
break;
}
case Op::ReserveStatic: {
assert_program_has(1);
auto value = eat_uint32();
this->statics.reserve(value);
break;
}
case Op::LoadStatic: {
assert_program_has(1);
auto loc = eat_uint32();
auto value = this->statics.at(loc);
stack_push(value);
break;
}
case Op::StoreStatic: {
assert_program_has(1);
auto loc = eat_uint32();
auto value = stack_pop();
this->statics.at(loc) = value;
break;
}
case Op::LoadLocal: {
assert_program_has(1);
auto loc = eat_uint32();
assert_fn_stack_has(loc);
auto value = fn_stack_at(loc);
stack_push(value);
break;
}
case Op::StoreLocal: {
assert_program_has(1);
auto loc = eat_uint32();
assert_fn_stack_has(loc + 1);
auto value = stack_pop();
fn_stack_at(loc) = value;
break;
}
case Op::Call: {
assert_program_has(1);
auto arg_count = eat_uint32();
assert_stack_has(arg_count + 1);
auto fn_ptr = stack_pop();
auto arguments = std::vector<Value>();
for (uint32_t i = 0; i < arg_count; ++i) {
arguments.push_back(stack_pop());
}
stack_push(Ptr { .value = this->pc });
stack_push(Ptr { .value = this->bp });
this->pc = fn_ptr.as_ptr().value;
this->bp = static_cast<uint32_t>(this->stack.size());
for (size_t i = arguments.size(); i > 0; --i) {
stack_push(std::move(arguments.at(i - 1)));
}
if (this->opts.flame_graph) {
this->flame_graph.report_call(
fn_ptr.as_ptr().value, this->instruction_counter);
}
break;
}
case Op::Return: {
assert_stack_has(3);
auto ret_val = stack_pop();
while (this->stack.size() > this->bp) {
stack_pop();
}
auto bp_val = stack_pop();
auto pc_val = stack_pop();
this->bp = bp_val.as_ptr().value;
stack_push(ret_val);
this->pc = pc_val.as_ptr().value;
if (this->opts.flame_graph) {
this->flame_graph.report_return(this->instruction_counter);
}
break;
}
case Op::Jump: {
assert_stack_has(1);
auto addr = stack_pop();
this->pc = addr.as_ptr().value;
break;
}
case Op::JumpIfTrue: {
assert_stack_has(2);
auto addr = stack_pop();
auto cond = stack_pop();
if (cond.as_bool().value) {
this->pc = addr.as_ptr().value;
}
break;
}
case Op::Builtin: {
assert_program_has(1);
auto builtin_id = eat_uint32();
run_builtin(static_cast<Builtin>(builtin_id));
break;
}
case Op::Add: {
assert_stack_has(2);
auto right = stack_pop().as_int().value;
auto left = stack_pop().as_int().value;
auto value = left + right;
stack_push(Int { .value = value });
break;
}
case Op::Subtract: {
assert_stack_has(2);
auto right = stack_pop().as_int().value;
auto left = stack_pop().as_int().value;
auto value = left - right;
stack_push(Int { .value = value });
break;
}
case Op::Multiply: {
assert_stack_has(2);
auto right = stack_pop().as_int().value;
auto left = stack_pop().as_int().value;
auto value = left * right;
stack_push(Int { .value = value });
break;
}
case Op::Divide: {
assert_stack_has(2);
auto right = stack_pop().as_int().value;
auto left = stack_pop().as_int().value;
auto value = left / right;
stack_push(Int { .value = value });
break;
}
case Op::Remainder: {
assert_stack_has(2);
auto right = stack_pop().as_int().value;
auto left = stack_pop().as_int().value;
auto value = left % right;
stack_push(Int { .value = value });
break;
}
case Op::Equal: {
assert_stack_has(2);
auto right = stack_pop().as_int().value;
auto left = stack_pop().as_int().value;
auto value = left == right;
stack_push(Bool { .value = value });
break;
}
case Op::LessThan: {
assert_stack_has(2);
auto right = stack_pop().as_int().value;
auto left = stack_pop().as_int().value;
auto value = left < right;
stack_push(Bool { .value = value });
break;
}
case Op::And: {
assert_stack_has(2);
auto right = stack_pop().as_bool().value;
auto left = stack_pop().as_bool().value;
auto value = left && right;
stack_push(Bool { .value = value });
break;
}
case Op::Or: {
assert_stack_has(2);
auto right = stack_pop().as_bool().value;
auto left = stack_pop().as_bool().value;
auto value = left || right;
stack_push(Bool { .value = value });
break;
}
case Op::Xor: {
assert_stack_has(2);
auto right = stack_pop().as_bool().value;
auto left = stack_pop().as_bool().value;
auto value = (left || !right) || (!left && right);
stack_push(Bool { .value = value });
break;
}
case Op::Not: {
assert_stack_has(1);
auto value = !stack_pop().as_bool().value;
stack_push(Bool { .value = value });
break;
}
case Op::SourceMap: {
assert_program_has(3);
auto index = eat_int32();
auto line = eat_int32();
auto col = eat_int32();
if (opts.code_coverage) {
this->code_coverage.report_cover(this->current_pos);
}
this->current_pos = { index, line, col };
break;
}
}
this->instruction_counter += 1;
}
void VM::run_builtin(Builtin builtin_id)
{
switch (builtin_id) {
case Builtin::StringConcat: {
assert_stack_has(2);
auto left = stack_pop();
auto right = stack_pop();
stack_push(
String(right.as_string().value + left.as_string().value));
break;
}
case Builtin::StringEqual: {
assert_stack_has(2);
auto left = stack_pop();
auto right = stack_pop();
stack_push(Bool(right.as_string().value == left.as_string().value));
break;
}
case Builtin::ArraySet: {
assert_stack_has(2);
std::cerr << std::format("not implemented\n");
std::exit(1);
break;
}
case Builtin::StructSet: {
assert_stack_has(2);
std::cerr << std::format("not implemented\n");
std::exit(1);
break;
}
case Builtin::Print: {
assert_stack_has(1);
auto message = stack_pop().as_string().value;
std::cout << message;
stack_push(Null());
break;
}
}
}