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use crate::ast::*;

// (λx:T.y): T z
pub fn parse(input: &str) -> Expression {
    return parse_str(input).expect("invalid expression");
}

/// Parses a lambda-calculus-like language into an AST.
pub fn parse_str(input: &str) -> Result<Expression, peg::error::ParseError<peg::str::LineCol>> {
    // this is kinda awful
    // i miss my nim pegs
    peg::parser!{
        grammar lambda() for str {
            rule identifier() -> String
            = i:['a'..='z' | 'A'..='Z' | '0'..='9']+ {
                i.iter().collect::<String>()
            }
            rule constant() -> Expression
            = p:"-"? c:['0'..='9']+ {
                let value = c.iter().collect::<String>().parse::<Value>().unwrap();
                Expression::Constant {
                    term: Term {
                        val: if let Some(_) = p {
                            value.wrapping_neg()
                        } else {
                            value
                        },
                        kind: Type::Empty
                    }
                }
            }
            // fucking awful but i don't know another way
            // k:("empty" / "unit" / etc) returns ()
            // and i can't seem to match and raise a parse error
            // so ¯\_(ツ)_/¯
            rule empty() -> Type = k:"empty" {Type::Empty}
            rule unit() -> Type = k:"unit" {Type::Unit}
            rule boolean() -> Type = k:"bool" {Type::Boolean}
            rule natural() -> Type = k:"nat" {Type::Natural}
            rule integer() -> Type = k:"int" {Type::Integer}
            rule kind() -> Type
             = k:(empty() / unit() / boolean() / natural() / integer()) {
                k
            }
            rule annotation() -> Expression
            = e:(conditional() / abstraction() / application() / constant() / variable()) " "* ":" " "* k:kind() {
                Expression::Annotation {
                    expr: Box::new(e),
                    kind: k
                }
            }
            rule variable() -> Expression
            = v:identifier() {
                Expression::Variable {
                    id: v
                }
            }
            rule abstraction() -> Expression
            = ("λ" / "lambda ") " "* p:identifier() " "* "." " "* f:expression() {
                Expression::Abstraction {
                    param: p,
                    func: Box::new(f)
                }
            }
            // fixme: more cases should parse, but how?
            rule application() -> Expression
            = "(" f:(annotation() / abstraction()) ")" " "* a:expression() {
                Expression::Application {
                    func: Box::new(f),
                    arg: Box::new(a)
                }
            }
            rule conditional() -> Expression
            = "if" " "+ c:expression() " "+ "then" " "+ t:expression() " "+ "else" " "+ e:expression() {
                Expression::Conditional {
                    if_cond: Box::new(c),
                    if_then: Box::new(t),
                    if_else: Box::new(e)
                }
            }
            pub rule expression() -> Expression
            = e:(conditional() / annotation() / abstraction() / application() / constant() / variable()) {
                e
            }
            pub rule ast() -> Vec<Expression>
            = expression() ** ("\n"+)
        }
    }
    // assert_eq!(lambda::expression("(λx:bool.x)").unwrap(), lambda::expression("(λx: bool . x)").unwrap());

    return lambda::expression(input.trim());
}

/// Parses a Nim-like language into an AST.
#[allow(unused_variables)]
pub fn parse_file(path: &str) -> Vec<Expression> {
    todo!();
}

/// Converts a whitespace-indented language into a regular bracketed language for matching with PEGs
/// Then, tokens are known to be separated by [\n ]+ (except strings. problem for later.)
pub fn lex(input: &str) -> Result<String, &'static str> {

    #[derive(Eq, PartialEq)]
    enum Previous {
        Start,
        Block,
        Line,
    }
    struct State {
        blank: bool,    // is the line entirely whitespace so far?
        level: usize,   // current indentation level
        count: usize,   // current whitespace count
        previous: Previous,
    }
    let indent_size: usize = 2;

    let mut state = State { blank: true, level: 0, count: 0, previous: Previous::Start };
    let mut buffer = String::new();
    let mut result = String::new();

    for c in input.chars() {
        match c {
            '\n' => {
                if !buffer.is_empty() {
                    if state.count == state.level {
                        if state.previous != Previous::Start {
                            result.push(';');
                            result.push('\n');
                        }
                        state.previous = Previous::Line;
                    } else if state.level + indent_size == state.count {
                        result.push(' ');
                        result.push('{');
                        result.push('\n');
                        state.level = state.count;
                        state.previous = Previous::Line;
                    } else if state.count > state.level + indent_size {
                        return Err("invalid jump in indentation");
                    } else if state.count % indent_size != 0 {
                        return Err("incorrect indentation offset, must be a multiple of indent_size");
                    } else if state.level > state.count {
                        while state.level > state.count {
                            if state.previous == Previous::Line {
                                result.push(';');
                            }
                            state.level -= indent_size;
                            result.push('\n');
                            result.push_str(" ".repeat(state.level).as_str());
                            result.push('}');
                            state.previous = Previous::Block;
                        }
                        result.push('\n');
                    } else {
                        return Err("unknown indentation error");
                    }

                    result.push_str(" ".repeat(state.count).as_str());
                    result.push_str(&buffer);

                    state.count = 0;
                    buffer.clear();
                }
                state.blank = true;
            },
            ' ' if state.blank => {
                state.count += 1;
            },
            _ => {
                if state.blank {
                    state.blank = false;
                }
                buffer.push(c);
            },
        }
    }
    if state.previous == Previous::Line {
        result.push(';');
    }
    while state.level != 0 {
        state.level -= 2;
        result.push('\n');
        result.push_str(" ".repeat(state.level).as_str());
        result.push('}');
    }
    return Ok(result);
}