Parsing basic numbers!

This commit is contained in:
greg 2017-09-11 02:07:17 -07:00
parent cfefceabf9
commit 741e5f7f9b

View File

@ -25,6 +25,8 @@ pub enum TokenType {
Identifier(Rc<String>),
Keyword(Kw),
EOF,
Error(String),
}
@ -166,7 +168,7 @@ fn handle_alphabetic(c: char, input: &mut CharIter) -> TokenType {
let mut buf = String::new();
buf.push(c);
if c == '_' && input.peek().map(|&(_, c)| { !c.is_alphabetic() }).unwrap_or(true) {
return TokenType::Identifier(Rc::new(format!("_")))
return TokenType::Underscore
}
loop {
@ -206,6 +208,7 @@ mod schala_tokenizer_tests {
use super::TokenType::*;
use super::Kw::*;
macro_rules! digit { ($ident:expr) => { DigitGroup(Rc::new($ident.to_string())) } }
macro_rules! ident { ($ident:expr) => { Identifier(Rc::new($ident.to_string())) } }
macro_rules! op { ($ident:expr) => { Operator(Rc::new($ident.to_string())) } }
@ -216,17 +219,16 @@ mod schala_tokenizer_tests {
assert_eq!(token_types, vec![Keyword(Let), ident!("a"), Colon, ident!("A"),
LAngleBracket, ident!("B"), RAngleBracket, op!("="), ident!("c"), op!("++"), ident!("d")]);
}
#[test]
fn underscores() {
let token_types: Vec<TokenType> = tokenize("4_8").into_iter().map(move |t| t.token_type).collect();
assert_eq!(token_types, vec![digit!("4"), Underscore, digit!("8")]);
}
}
/*
Schala EBNF grammar
type alias <name> = <other type>
type <name> = struct { <field> : <type>,* }
type <name> = Variant1 | Variant2(type, type) | Variant3 struct { }
Schala (PROVISIONAL!!) EBNF grammar
'' = literal, all other symbols are nonterminals
@ -275,8 +277,45 @@ postop := ε | LParen exprlist RParen | LBracket expression RBracket
op := '+', '-', etc.
*/
/* Schala EBNF Grammar */
/*
program := (statement delimiter)* EOF
delimiter := NEWLINE | SEMICOLON
statement := expression | declaration
declaration := type_declaration | func_declaration
type_declaration := TYPE
func_declaration := FN
expression := primary
primary := literal
literal := TRUE | FALSE | number_literal | str_literal
// a float_literal can still be assigned to an int in type-checking
number_literal := int_literal | float_literal
int_literal = (HEX_SIGIL | BIN_SIGIL) digits
float_literal := digits (PERIOD digits)
digits := (digit_group underscore)+
*/
type TokenIter = Peekable<IntoIter<Token>>;
pub struct ParseError {
pub msg: String,
}
impl ParseError {
fn new<T>(msg: &str) -> ParseResult<T> {
Err(ParseError { msg: msg.to_string() })
}
}
pub type ParseResult<T> = Result<T, ParseError>;
struct Parser {
tokens: TokenIter,
}
@ -286,27 +325,24 @@ impl Parser {
Parser { tokens: input.into_iter().peekable() }
}
fn peek(&mut self) -> Option<TokenType> {
self.tokens.peek().map(|ref t| { t.token_type.clone() })
fn peek(&mut self) -> TokenType {
self.tokens.peek().map(|ref t| { t.token_type.clone() }).unwrap_or(TokenType::EOF)
}
fn next(&mut self) -> Option<TokenType> {
self.tokens.next().map(|ref t| { t.token_type.clone() })
}
fn program(&mut self) -> ParseResult<AST> {
use self::Statement::*; use self::Declaration::*; use self::Expression::*;
let statements = vec![Expression(UnsignedIntLiteral(1))];
Ok(AST(statements))
fn next(&mut self) -> TokenType {
self.tokens.next().map(|ref t| { t.token_type.clone() }).unwrap_or(TokenType::EOF)
}
}
pub struct ParseError {
pub msg: String,
macro_rules! expect {
($self:expr, $token_type:pat, $message:expr) => {
match $self.peek() {
Some($token_type) => {$self.next();},
_ => return ParseError { msg: $message.to_string() },
}
}
}
pub type ParseResult<T> = Result<T, ParseError>;
#[derive(Debug)]
pub struct AST(Vec<Statement>);
@ -329,6 +365,102 @@ pub enum Expression {
FloatLiteral(f64),
}
impl Parser {
fn program(&mut self) -> ParseResult<AST> {
use self::TokenType::*;
let mut statements = Vec::new();
loop {
match self.peek() {
EOF => break,
Newline | Semicolon => {
self.next();
continue;
},
_ => statements.push(self.statement()?),
}
}
Ok(AST(statements))
}
fn statement(&mut self) -> ParseResult<Statement> {
use self::TokenType::*;
use self::Kw::*;
//TODO handle error recovery here
match self.peek() {
Keyword(Type) => self.type_declaration().map(|decl| { Statement::Declaration(decl) }),
Keyword(Func)=> self.func_declaration().map(|func| { Statement::Declaration(func) }),
_ => self.expression().map(|expr| { Statement::Expression(expr) } ),
}
}
fn type_declaration(&mut self) -> ParseResult<Declaration> {
unimplemented!()
}
fn func_declaration(&mut self) -> ParseResult<Declaration> {
unimplemented!()
}
fn expression(&mut self) -> ParseResult<Expression> {
self.primary()
}
fn primary(&mut self) -> ParseResult<Expression> {
self.literal()
}
fn literal(&mut self) -> ParseResult<Expression> {
use self::TokenType::*;
match self.peek() {
DigitGroup(_) | HexNumberSigil | BinNumberSigil | Period => self.number_literal(),
_ => unimplemented!(),
}
}
fn number_literal(&mut self) -> ParseResult<Expression> {
use self::TokenType::*;
match self.peek() {
HexNumberSigil | BinNumberSigil => self.int_literal(),
_ => self.float_literal(),
}
}
fn int_literal(&mut self) -> ParseResult<Expression> {
use self::Expression::*;
let digits = self.digits()?;
match self.next() {
BinNumberSigil => {
unimplemented!()
},
HexNumberSigil => {
unimplemented!()
},
_ => return ParseError::new("Expected '0x' or '0b'"),
}
}
fn float_literal(&mut self) -> ParseResult<Expression> {
use self::Expression::*;
let digits = self.digits()?;
match digits.parse::<u64>() {
Ok(d) => Ok(UnsignedIntLiteral(d)),
Err(p) => unimplemented!("Need to handle numbers that don't parse to a Rust u64 {:?}", p),
}
}
fn digits(&mut self) -> ParseResult<String> {
use self::TokenType::*;
let mut ds = String::new();
loop {
let xxx = self.next();
match xxx {
Underscore => continue,
DigitGroup(ref s) => ds.push_str(s),
x => break,
}
}
Ok(ds)
}
}
pub fn parse(input: Vec<Token>) -> Result<AST, ParseError> {
let mut parser = Parser::new(input);