use super::chunk::Chunk;
use super::errors::{Error, ErrorKind, LoxResult};
use super::interner::Interner;
use super::opcode::OpCode;
use super::value::Value;
use crate::scanner::{self, Token, TokenKind};
#[cfg(feature = "disassemble")]
use super::chunk;
struct Compiler<T: Iterator<Item = Token>> {
tokens: T,
chunk: Chunk,
panic: bool,
errors: Vec<Error>,
strings: Interner,
current: Option<Token>,
previous: Option<Token>,
}
#[derive(Debug, PartialEq, PartialOrd)]
enum Precedence {
None,
Assignment, // =
Or, // or
And, // and
Equality, // == !=
Comparison, // < > <= >=
Term, // + -
Factor, // * /
Unary, // ! -
Call, // . ()
Primary,
}
type ParseFn<T> = fn(&mut Compiler<T>) -> LoxResult<()>;
struct ParseRule<T: Iterator<Item = Token>> {
prefix: Option<ParseFn<T>>,
infix: Option<ParseFn<T>>,
precedence: Precedence,
}
impl<T: Iterator<Item = Token>> ParseRule<T> {
fn new(
prefix: Option<ParseFn<T>>,
infix: Option<ParseFn<T>>,
precedence: Precedence,
) -> Self {
ParseRule {
prefix,
infix,
precedence,
}
}
}
impl Precedence {
// Return the next highest precedence, if there is one.
fn next(&self) -> Self {
match self {
Precedence::None => Precedence::Assignment,
Precedence::Assignment => Precedence::Or,
Precedence::Or => Precedence::And,
Precedence::And => Precedence::Equality,
Precedence::Equality => Precedence::Comparison,
Precedence::Comparison => Precedence::Term,
Precedence::Term => Precedence::Factor,
Precedence::Factor => Precedence::Unary,
Precedence::Unary => Precedence::Call,
Precedence::Call => Precedence::Primary,
Precedence::Primary => panic!(
"invalid parser state: no higher precedence than Primary"
),
}
}
}
fn rule_for<T: Iterator<Item = Token>>(token: &TokenKind) -> ParseRule<T> {
match token {
TokenKind::LeftParen => {
ParseRule::new(Some(Compiler::grouping), None, Precedence::None)
}
TokenKind::Minus => ParseRule::new(
Some(Compiler::unary),
Some(Compiler::binary),
Precedence::Term,
),
TokenKind::Plus => {
ParseRule::new(None, Some(Compiler::binary), Precedence::Term)
}
TokenKind::Slash => {
ParseRule::new(None, Some(Compiler::binary), Precedence::Factor)
}
TokenKind::Star => {
ParseRule::new(None, Some(Compiler::binary), Precedence::Factor)
}
TokenKind::Number(_) => {
ParseRule::new(Some(Compiler::number), None, Precedence::None)
}
TokenKind::True => {
ParseRule::new(Some(Compiler::literal), None, Precedence::None)
}
TokenKind::False => {
ParseRule::new(Some(Compiler::literal), None, Precedence::None)
}
TokenKind::Nil => {
ParseRule::new(Some(Compiler::literal), None, Precedence::None)
}
TokenKind::Bang => {
ParseRule::new(Some(Compiler::unary), None, Precedence::None)
}
TokenKind::BangEqual => {
ParseRule::new(None, Some(Compiler::binary), Precedence::Equality)
}
TokenKind::EqualEqual => {
ParseRule::new(None, Some(Compiler::binary), Precedence::Equality)
}
TokenKind::Greater => {
ParseRule::new(None, Some(Compiler::binary), Precedence::Comparison)
}
TokenKind::GreaterEqual => {
ParseRule::new(None, Some(Compiler::binary), Precedence::Comparison)
}
TokenKind::Less => {
ParseRule::new(None, Some(Compiler::binary), Precedence::Comparison)
}
TokenKind::LessEqual => {
ParseRule::new(None, Some(Compiler::binary), Precedence::Comparison)
}
TokenKind::String(_) => {
ParseRule::new(Some(Compiler::string), None, Precedence::None)
}
_ => ParseRule::new(None, None, Precedence::None),
}
}
impl<T: Iterator<Item = Token>> Compiler<T> {
fn compile(&mut self) -> LoxResult<()> {
self.advance();
while !self.match_token(&TokenKind::Eof) {
self.declaration()?;
}
self.end_compiler()
}
fn advance(&mut self) {
self.previous = self.current.take();
self.current = self.tokens.next();
}
fn expression(&mut self) -> LoxResult<()> {
self.parse_precedence(Precedence::Assignment)
}
fn declaration(&mut self) -> LoxResult<()> {
self.statement()?;
if self.panic {
self.synchronise();
}
Ok(())
}
fn statement(&mut self) -> LoxResult<()> {
if self.match_token(&TokenKind::Print) {
self.print_statement()
} else {
self.expression_statement()
}
}
fn print_statement(&mut self) -> LoxResult<()> {
self.expression()?;
self.consume(
&TokenKind::Semicolon,
ErrorKind::ExpectedToken("Expected ';' after value"),
);
self.emit_op(OpCode::OpPrint);
Ok(())
}
fn expression_statement(&mut self) -> LoxResult<()> {
self.expression()?;
self.consume(
&TokenKind::Semicolon,
ErrorKind::ExpectedToken("Expected ';' after expression"),
);
self.emit_op(OpCode::OpPop);
Ok(())
}
fn number(&mut self) -> LoxResult<()> {
if let TokenKind::Number(num) = self.previous().kind {
self.emit_constant(Value::Number(num));
return Ok(());
}
unreachable!("internal parser error: entered number() incorrectly")
}
fn grouping(&mut self) -> LoxResult<()> {
self.expression()?;
self.consume(
&TokenKind::RightParen,
ErrorKind::ExpectedToken("Expected ')' after expression"),
);
Ok(())
}
fn unary(&mut self) -> LoxResult<()> {
// TODO(tazjin): Avoid clone
let kind = self.previous().kind.clone();
// Compile the operand
self.parse_precedence(Precedence::Unary)?;
// Emit operator instruction
match kind {
TokenKind::Bang => self.emit_op(OpCode::OpNot),
TokenKind::Minus => self.emit_op(OpCode::OpNegate),
_ => unreachable!("only called for unary operator tokens"),
}
Ok(())
}
fn binary(&mut self) -> LoxResult<()> {
// Remember the operator
let operator = self.previous().kind.clone();
// Compile the right operand
let rule: ParseRule<T> = rule_for(&operator);
self.parse_precedence(rule.precedence.next())?;
// Emit operator instruction
match operator {
TokenKind::Minus => self.emit_op(OpCode::OpSubtract),
TokenKind::Plus => self.emit_op(OpCode::OpAdd),
TokenKind::Star => self.emit_op(OpCode::OpMultiply),
TokenKind::Slash => self.emit_op(OpCode::OpDivide),
TokenKind::BangEqual => {
self.emit_op(OpCode::OpEqual);
self.emit_op(OpCode::OpNot);
}
TokenKind::EqualEqual => self.emit_op(OpCode::OpEqual),
TokenKind::Greater => self.emit_op(OpCode::OpGreater),
TokenKind::GreaterEqual => {
self.emit_op(OpCode::OpLess);
self.emit_op(OpCode::OpNot);
}
TokenKind::Less => self.emit_op(OpCode::OpLess),
TokenKind::LessEqual => {
self.emit_op(OpCode::OpGreater);
self.emit_op(OpCode::OpNot);
}
_ => unreachable!("only called for binary operator tokens"),
}
Ok(())
}
fn literal(&mut self) -> LoxResult<()> {
match self.previous().kind {
TokenKind::Nil => self.emit_op(OpCode::OpNil),
TokenKind::True => self.emit_op(OpCode::OpTrue),
TokenKind::False => self.emit_op(OpCode::OpFalse),
_ => unreachable!("only called for literal value tokens"),
}
Ok(())
}
fn string(&mut self) -> LoxResult<()> {
let val = match &self.previous().kind {
TokenKind::String(s) => s.clone(),
_ => unreachable!("only called for strings"),
};
let id = self.strings.intern(val);
self.emit_constant(Value::String(id.into()));
Ok(())
}
fn parse_precedence(&mut self, precedence: Precedence) -> LoxResult<()> {
self.advance();
let rule: ParseRule<T> = rule_for(&self.previous().kind);
let prefix_fn = match rule.prefix {
None => unimplemented!("expected expression or something, unclear"),
Some(func) => func,
};
prefix_fn(self)?;
while precedence <= rule_for::<T>(&self.current().kind).precedence {
self.advance();
match rule_for::<T>(&self.previous().kind).infix {
Some(func) => {
func(self)?;
}
None => {
unreachable!("invalid compiler state: error in parse rules")
}
}
}
Ok(())
}
fn consume(&mut self, expected: &TokenKind, err: ErrorKind) {
if self.current().kind == *expected {
self.advance();
return;
}
self.error_at(self.current().line, err);
}
fn current_chunk(&mut self) -> &mut Chunk {
&mut self.chunk
}
fn end_compiler(&mut self) -> LoxResult<()> {
self.emit_op(OpCode::OpReturn);
#[cfg(feature = "disassemble")]
{
chunk::disassemble_chunk(&self.chunk);
println!("== compilation finished ==");
}
Ok(())
}
fn emit_op(&mut self, op: OpCode) {
let line = self.previous().line;
self.current_chunk().add_op(op, line);
}
fn emit_constant(&mut self, val: Value) {
let idx = self.chunk.add_constant(val);
self.emit_op(OpCode::OpConstant(idx));
}
fn previous(&self) -> &Token {
self.previous
.as_ref()
.expect("invalid internal compiler state: missing previous token")
}
fn current(&self) -> &Token {
self.current
.as_ref()
.expect("invalid internal compiler state: missing current token")
}
fn error_at(&mut self, line: usize, kind: ErrorKind) {
if self.panic {
return;
}
self.panic = true;
self.errors.push(Error { kind, line })
}
fn match_token(&mut self, token: &TokenKind) -> bool {
if !self.check(token) {
return false;
}
self.advance();
true
}
fn check(&self, token: &TokenKind) -> bool {
return self.current().kind == *token;
}
fn synchronise(&mut self) {
self.panic = false;
while self.current().kind != TokenKind::Eof {
if self.previous().kind == TokenKind::Semicolon {
return;
}
match self.current().kind {
TokenKind::Class
| TokenKind::Fun
| TokenKind::Var
| TokenKind::For
| TokenKind::If
| TokenKind::While
| TokenKind::Print
| TokenKind::Return => return,
_ => {
self.advance();
}
}
}
}
}
pub fn compile(code: &str) -> Result<(Interner, Chunk), Vec<Error>> {
let chars = code.chars().collect::<Vec<char>>();
let tokens = scanner::scan(&chars).map_err(|errors| {
errors.into_iter().map(Into::into).collect::<Vec<Error>>()
})?;
let mut compiler = Compiler {
tokens: tokens.into_iter().peekable(),
chunk: Default::default(),
panic: false,
errors: vec![],
strings: Interner::with_capacity(1024),
current: None,
previous: None,
};
compiler.compile()?;
if compiler.errors.is_empty() {
Ok((compiler.strings, compiler.chunk))
} else {
Err(compiler.errors)
}
}