use crate::lisp::{
    error::LispError,
    lex::{Lexer, Span, Token},
    number::LispNumber,
    LispExpr,
};

pub struct Parser<'lex> {
    lexer: Lexer<'lex>,
    cur_token: Option<(Span, Token<'lex>)>,
}

// pub struct ParseError {
//     pub span: Span,
//     pub kind: ParseErrorKind,
// }
//
// pub enum ParseErrorKind {
//     InvalidLiteral,
//     InvalidToken,
//     LiteralParseError,
//     MissingCloseParen,
//     UnbalancedComma,
//     UnexpectedEof,
//     UnexpectedToken {
//         expected: &'static str,
//         found: &'static str,
//     },
//     UnmatchedParen,
//     UnterminatedString,
// }

enum Group {
    Backticks(i32),
    CommaAt,
    Quotes(u32),
    Parens(Vec<LispExpr>),
}

impl<'lex> Parser<'lex> {
    pub fn new(lexer: Lexer<'lex>) -> Self {
        Self {
            lexer,
            cur_token: None,
        }
    }

    pub fn parse_expr(&mut self) -> Result<LispExpr, LispError> {
        let mut stack = Vec::new();
        let mut total_backticks = 0;
        loop {
            let (_, token) = self.next()?;
            let r: Result<LispExpr, LispError> = match token {
                Token::LeftParen => {
                    stack.push(Group::Parens(Vec::new()));
                    continue;
                }
                Token::RightParen => {
                    let group = stack.pop().ok_or_else(
                        || LispError::ParseError, // unmatched paren here
                    )?;
                    match group {
                        Group::Parens(v) => Ok(LispExpr::List(v)),
                        _ => Err(LispError::ParseError),
                    }
                }
                Token::Float(f) => f
                    .parse::<f64>()
                    .map(|n| LispExpr::Number(LispNumber::Float(n)))
                    .map_err(|_| LispError::ParseError),
                Token::Integer(i) => i
                    .parse::<i64>()
                    .map(|n| LispExpr::Number(LispNumber::Integer(n)))
                    .map_err(|_| LispError::ParseError),
                Token::String(s) => Ok(LispExpr::StringLit(s.into())),
                Token::Name(n) => Ok(name_expr(n)),
                Token::BackQuote => {
                    total_backticks += 1;
                    if let Some(&mut Group::Backticks(ref mut n)) = stack.last_mut() {
                        *n += 1;
                        continue;
                    }
                    stack.push(Group::Backticks(1));
                    continue;
                }
                Token::Comma => {
                    if total_backticks <= 0 {
                        return Err(LispError::ParseError); // unbalanced comma
                    }
                    total_backticks -= 1;
                    if let Some(&mut Group::Backticks(ref mut n)) = stack.last_mut() {
                        *n -= 1;
                        continue;
                    }
                    stack.push(Group::Backticks(-1));
                    continue;
                }
                Token::CommaAt => {
                    if total_backticks <= 0 {
                        return Err(LispError::ParseError); // unbalanced comma
                    }
                    total_backticks -= 1;
                    stack.push(Group::CommaAt);
                    continue;
                }
                Token::Quote => {
                    if let Some(&mut Group::Quotes(ref mut n)) = stack.last_mut() {
                        *n += 1;
                        continue;
                    }
                    stack.push(Group::Quotes(1));
                    continue;
                }
                Token::End => {
                    let any_paren = stack.iter().any(|group| match *group {
                        Group::Parens(_) => true,
                        _ => false,
                    });

                    if any_paren {
                        Err(LispError::ParseError) // unbalanced paren
                    } else {
                        Err(LispError::ParseError) // unexpected eof
                    }
                }
            };
            let mut v = r?;
            loop {
                match stack.last_mut() {
                    None => return Ok(v),
                    Some(&mut Group::Parens(ref mut values)) => {
                        values.push(v);
                        break;
                    }
                    _ => (),
                }

                let group = stack.pop().unwrap();

                match group {
                    Group::Backticks(n) if n > 0 => {
                        total_backticks -= n;
                        v = v.quasiquote(n as u32);
                    }
                    Group::Backticks(n) if n < 0 => {
                        total_backticks -= n;
                        v = v.comma((-n) as u32);
                    }
                    Group::CommaAt => {
                        total_backticks += 1;
                        v = v.comma_at(1);
                    }
                    Group::Quotes(n) => v = v.quote(n),
                    _ => (),
                }
            }
        }
    }

    fn next(&mut self) -> Result<(Span, Token<'lex>), LispError> {
        let r = self.peek()?;
        self.cur_token = None;
        Ok(r)
    }

    fn peek(&mut self) -> Result<(Span, Token<'lex>), LispError> {
        if let Some(tok) = self.cur_token {
            Ok(tok)
        } else {
            let tok = self.lexer.next_token()?;
            self.cur_token = Some(tok);
            Ok(tok)
        }
    }

    pub fn parse_single_expr(&mut self) -> Result<LispExpr, LispError> {
        let expr = self.parse_expr()?;

        match self.next()? {
            (_, Token::End) => Ok(expr),
            _ => Err(LispError::ParseError), // too many tokens
        }
    }

    pub fn parse_exprs(&mut self) -> Result<Vec<LispExpr>, LispError> {
        let mut res = Vec::new();
        loop {
            match self.peek()? {
                (_, Token::End) => break,
                _ => res.push(self.parse_expr()?),
            }
        }
        Ok(res)
    }
}

fn name_expr(input: &str) -> LispExpr {
    match input {
        "#t" => LispExpr::BoolLit(true),
        "#f" => LispExpr::BoolLit(false),
        _ => LispExpr::Ident(input.into()),
    }
}

#[cfg(test)]
mod tests {
    use super::*;
    fn parse(input: &str) -> Result<LispExpr, LispError> {
        let mut parser = Parser::new(Lexer::new(input, 0));

        parser.parse_single_expr()
    }

    #[test]
    // fn parse_lisp_expr() {
    //     assert_eq!(
    //         parse("1.5").unwrap(),
    //         LispExpr::Number(LispNumber::Float(1.5))
    //     );

    //     assert_eq!(
    //         parse(r#""hello""#).unwrap(),
    //         LispExpr::StringLit(r#""hello""#.into())
    //     );

    //     assert_eq!(parse("foo").unwrap(), LispExpr::Ident("foo".into()));

    //     let items = (1..=5)
    //         .map(LispNumber::Integer)
    //         .map(LispExpr::Number)
    //         .collect::<Vec<_>>();
    //     assert_eq!(parse("(1 2 3 4 5)").unwrap(), LispExpr::List(items));

    //     let foo = LispExpr::Ident("foo".into());
    //     let bar = LispExpr::Comma(Box::new(LispExpr::Ident("bar".into())), 1);
    //     assert_eq!(
    //         parse("`(foo ,bar)").unwrap(),
    //         LispExpr::Quasiquote(Box::new(LispExpr::List(vec![foo, bar])), 1)
    //     )
    // }
    #[should_panic]
    #[test]
    fn unbalanced_comma() {
        parse("`(foo ,,bar)").unwrap();
    }

    #[should_panic]
    #[test]
    fn unbalanced_paren() {
        parse("(foo").unwrap();
    }
}