magnetar/magnetar_mmm_parser/src/lib.rs

use nom::branch::alt;
use nom::bytes::complete::tag;
use nom::character::complete::{
    alpha1, alphanumeric1, anychar, char as one_char, line_ending, not_line_ending, one_of, space1,
    tab,
};
use nom::combinator::{eof, fail, map, not, opt, recognize};
use nom::error::ErrorKind;
use nom::multi::{many0, many0_count, many1, many1_count, separated_list1};
use nom::sequence::tuple;
use nom::{IResult, Offset, Slice};
use nom_locate::LocatedSpan;
use std::borrow::Cow;
use std::collections::HashMap;
use unicode_segmentation::UnicodeSegmentation;

#[derive(Copy, Clone, Debug)]
pub enum MentionType {
    Community,
    User,
}

impl MentionType {
    pub fn to_char(&self) -> char {
        match self {
            MentionType::Community => '!',
            MentionType::User => '@',
        }
    }
}

#[derive(Clone, Debug)]
pub enum Token<'a> {
    PlainText(Cow<'a, str>),
    Sequence(Vec<Token<'a>>),
    Quote(Box<Token<'a>>),
    Small(Box<Token<'a>>),
    Big(Box<Token<'a>>),
    BoldItalic(Box<Token<'a>>),
    Bold(Box<Token<'a>>),
    Italic(Box<Token<'a>>),
    Center(Box<Token<'a>>),
    Strikethrough(Box<Token<'a>>),
    PlainTag(Cow<'a, str>),
    InlineCode(Cow<'a, str>),
    InlineMath(Cow<'a, str>),
    UrlRaw(Cow<'a, str>),
    UrlNoEmbed(Cow<'a, str>),
    Link {
        label: Cow<'a, str>,
        href: Cow<'a, str>,
        embed: bool,
    },
    BlockCode {
        lang: Option<Cow<'a, str>>,
        inner: Cow<'a, str>,
    },
    BlockMath(Cow<'a, str>),
    Function {
        name: Cow<'a, str>,
        params: HashMap<Cow<'a, str>, Option<Cow<'a, str>>>,
        inner: Box<Token<'a>>,
    },
    Mention {
        name: Cow<'a, str>,
        host: Option<Cow<'a, str>>,
        mention_type: MentionType,
    },
    UnicodeEmoji(Cow<'a, str>),
    ShortcodeEmoji(Cow<'a, str>),
    Hashtag(Cow<'a, str>),
}

impl Token<'_> {
    fn owned(&self) -> Token<'static> {
        match self {
            Token::PlainText(text) => Token::PlainText(Cow::Owned(text.clone().into_owned())),
            Token::Sequence(tokens) => Token::Sequence(tokens.iter().map(Token::owned).collect()),
            Token::Quote(inner) => Token::Quote(Box::new(inner.owned())),
            Token::Small(inner) => Token::Small(Box::new(inner.owned())),
            Token::Big(inner) => Token::Big(Box::new(inner.owned())),
            Token::BoldItalic(inner) => Token::BoldItalic(Box::new(inner.owned())),
            Token::Bold(inner) => Token::Bold(Box::new(inner.owned())),
            Token::Italic(inner) => Token::Italic(Box::new(inner.owned())),
            Token::Center(inner) => Token::Center(Box::new(inner.owned())),
            Token::Strikethrough(inner) => Token::Strikethrough(Box::new(inner.owned())),
            Token::PlainTag(tag) => Token::PlainTag(Cow::Owned(tag.clone().into_owned())),
            Token::InlineCode(code) => Token::InlineCode(Cow::Owned(code.clone().into_owned())),
            Token::InlineMath(math) => Token::InlineMath(Cow::Owned(math.clone().into_owned())),
            Token::UrlRaw(url) => Token::UrlRaw(Cow::Owned(url.clone().into_owned())),
            Token::UrlNoEmbed(url) => Token::UrlNoEmbed(Cow::Owned(url.clone().into_owned())),
            Token::Link { embed, label, href } => Token::Link {
                embed: *embed,
                label: Cow::Owned(label.clone().into_owned()),
                href: Cow::Owned(href.clone().into_owned()),
            },
            Token::BlockCode { inner, lang } => Token::BlockCode {
                lang: lang.as_ref().map(|l| Cow::Owned(l.clone().into_owned())),
                inner: Cow::Owned(inner.clone().into_owned()),
            },
            Token::BlockMath(math) => Token::BlockMath(Cow::Owned(math.clone().into_owned())),
            Token::Function {
                name,
                params,
                inner,
            } => Token::Function {
                name: Cow::Owned(name.clone().into_owned()),
                params: params
                    .iter()
                    .map(|(k, v)| {
                        (
                            Cow::Owned(k.clone().into_owned()),
                            v.as_ref().map(|val| Cow::Owned(val.clone().into_owned())),
                        )
                    })
                    .collect(),
                inner: Box::new(inner.owned()),
            },
            Token::Mention {
                name,
                host,
                mention_type,
            } => Token::Mention {
                name: Cow::Owned(name.clone().into_owned()),
                host: host.as_ref().map(|v| Cow::Owned(v.clone().into_owned())),
                mention_type: *mention_type,
            },
            Token::UnicodeEmoji(code) => Token::UnicodeEmoji(Cow::Owned(code.clone().into_owned())),
            Token::ShortcodeEmoji(shortcode) => {
                Token::ShortcodeEmoji(Cow::Owned(shortcode.clone().into_owned()))
            }
            Token::Hashtag(url) => Token::Hashtag(Cow::Owned(url.clone().into_owned())),
        }
    }
}

type Span<'a> = LocatedSpan<&'a str>;

trait SliceOffset {
    fn up_to(&self, other: &Self) -> Self;

    fn fragment_between<'a>(&self, other: &Self) -> &'a str
    where
        Self: 'a;
}

impl SliceOffset for Span<'_> {
    fn up_to(&self, other: &Self) -> Self {
        self.slice(..self.offset(other))
    }

    fn fragment_between<'a>(&self, other: &Self) -> &'a str
    where
        Self: 'a,
    {
        self.up_to(other).into_fragment()
    }
}

const fn boxing_sequence<'a>(
    func: impl Fn(Box<Token<'a>>) -> Token<'a>,
) -> impl Fn(Vec<Token<'a>>) -> Token<'a> {
    move |tokens| func(Box::new(Token::Sequence(tokens)))
}

const fn collect_char_sequence<'a>(
    func: impl Fn(Cow<'a, str>) -> Token<'a>,
) -> impl Fn(Vec<char>) -> Token<'a> {
    move |chars| func(Cow::Owned(chars.into_iter().collect()))
}

fn spliced<'a>(
    segments: &[Span<'a>],
    func: impl Fn(Span) -> IResult<Span, Token>,
    output_mapper: impl Fn(Box<Token<'static>>) -> Token<'static>,
    parent: Span<'a>,
) -> IResult<Span<'a>, Token<'static>, nom::error::Error<Span<'a>>> {
    let combined = segments
        .iter()
        .copied()
        .map(Span::into_fragment)
        .collect::<String>();
    let cum_offset_combined = segments
        .iter()
        .scan(0, |acc, &x| {
            *acc += x.len();
            Some(*acc)
        })
        .collect::<Vec<_>>();
    let current_seg = |input: Span| {
        cum_offset_combined
            .iter()
            .enumerate()
            .filter(|(_, &o)| o >= input.location_offset())
            .map(|(i, o)| (segments[i], o))
            .last()
    };

    type NE<E> = nom::Err<E>;
    type NomError<'x> = nom::error::Error<Span<'x>>;

    let quote_span = Span::new(&combined);
    let (input, inner) = match func(quote_span) {
        Ok((input, token)) => (input, token.owned()),
        Err(e) => {
            return match e {
                NE::Error(e) => {
                    let offset_new = e.input.location_offset();
                    if let Some((seg_parent, offset_seg_new)) = current_seg(e.input) {
                        let offset = offset_new - offset_seg_new;
                        let offset_orig = offset + seg_parent.location_offset();
                        Err(NE::Error(NomError::new(
                            Span::new(&parent.into_fragment()[offset_orig..]),
                            e.code,
                        )))
                    } else {
                        // ???
                        Err(NE::Failure(NomError::new(parent, ErrorKind::Fail)))
                    }
                }
                NE::Failure(e) => Err(NE::Error(NomError::new(parent, e.code))),
                NE::Incomplete(i) => Err(NE::Incomplete(i)),
            };
        }
    };

    let out = if let Some((seg_parent, offset_seg_new)) = current_seg(input) {
        let offset = input.location_offset() - offset_seg_new;
        let offset_orig = offset + seg_parent.location_offset();
        parent.slice(offset_orig..)
    } else {
        parent
    };

    Ok((out, output_mapper(Box::new(inner.owned()))))
}

fn space(input: Span) -> IResult<Span, Token> {
    let (input, frag) = recognize(alt((one_char('\u{0020}'), one_char('\u{3000}'), tab)))(input)?;
    Ok((input, Token::PlainText(frag.into_fragment().into())))
}

struct Context;

impl Context {
    #[inline]
    const fn partial<'a>(
        &self,
        func: impl Fn(&Self, Span<'a>) -> IResult<Span<'a>, Token<'a>> + 'static,
    ) -> impl Fn(Span<'a>) -> IResult<Span<'a>, Token<'a>> + '_ {
        move |input| func(self, input)
    }

    fn root<'a>(&self, input: Span<'a>) -> IResult<Span<'a>, Token<'a>> {
        let (input, token) = alt((self.partial(Self::tag_quote),))(input)?;
        Ok((input, token))
    }

    fn inline<'a>(&self, input: Span<'a>) -> IResult<Span<'a>, Token<'a>> {
        let (input, token) = alt((self.partial(Self::tag_small), self.partial(Self::text)))(input)?;
        Ok((input, token))
    }

    fn inline_no_link<'a>(&self, input: Span<'a>) -> IResult<Span<'a>, Token<'a>> {
        let (input, token) = alt((self.partial(Self::tag_small), self.partial(Self::text)))(input)?;
        Ok((input, token))
    }

    fn tag_quote<'a>(&self, input: Span<'a>) -> IResult<Span<'a>, Token<'a>> {
        let (input, leading_spaces) = tuple((opt(line_ending), opt(line_ending)))(input)?;

        if let (None, None) = leading_spaces {
            if input.get_column() != 0 {
                return fail(input);
            }
        }

        let quote_line = |input| tuple((tag(">"), opt(space), not_line_ending))(input);

        let orig_input = input;
        let (input, lines) = separated_list1(line_ending, quote_line)(input)?;

        let quote_lines = lines
            .into_iter()
            .map(|(_, _, text)| text)
            .collect::<Vec<_>>();

        if quote_lines.len() == 1
            && quote_lines
                .iter()
                .map(Span::fragment)
                .copied()
                .any(&str::is_empty)
        {
            return fail(input);
        }

        let (_, inner) = spliced(&quote_lines, space, Token::Quote, orig_input)?;

        let (input, _) = tuple((opt(line_ending), opt(line_ending)))(input)?;

        Ok((input, Token::Quote(Box::new(inner))))
    }

    fn tag_block_center<'a>(&self, input: Span<'a>) -> IResult<Span<'a>, Token<'a>> {
        let tag_start = &tag("<center>");
        let tag_end = &tag("</center>");

        let (input, _) = opt(line_ending)(input)?;

        if input.get_column() != 0 {
            return fail(input);
        }

        let (input, _) = tag_start(input)?;
        let (input, _) = opt(line_ending)(input)?;

        let (input, center_seq) = many0(tuple((
            not(tuple((opt(line_ending), tag_end))),
            self.partial(Self::inline),
        )))(input)?;

        let (input, _) = opt(line_ending)(input)?;
        let (input, _) = tag_end(input)?;
        let (input, _) = many0(space)(input)?;
        let (input, _) = not(not_line_ending)(input)?;
        let (input, _) = opt(line_ending)(input)?;

        let tokens = center_seq.into_iter().map(|(_, v)| v).collect::<Vec<_>>();

        Ok((input, boxing_sequence(Token::Center)(tokens)))
    }

    fn tag_block_code<'a>(&self, input: Span<'a>) -> IResult<Span<'a>, Token<'a>> {
        let delim = &tag("```");

        let (input, _) = opt(line_ending)(input)?;

        if input.get_column() != 0 {
            return fail(input);
        }

        let (input, _) = delim(input)?;
        let (input, lang) = opt(map(
            recognize(many1(tuple((not(delim), not_line_ending)))),
            Span::into_fragment,
        ))(input)?;
        let (input, _) = line_ending(input)?;

        let (input, code) = map(
            recognize(many1_count(tuple((
                not(tuple((line_ending, delim))),
                anychar,
            )))),
            Span::into_fragment,
        )(input)?;

        let (input, _) = line_ending(input)?;
        let (input, _) = delim(input)?;
        let (input, _) = many0(space)(input)?;
        let (input, _) = not(not_line_ending)(input)?;
        let (input, _) = opt(line_ending)(input)?;

        Ok((
            input,
            Token::BlockCode {
                lang: lang.map(<&str>::into),
                inner: code.into(),
            },
        ))
    }

    fn tag_block_math<'a>(&self, input: Span<'a>) -> IResult<Span<'a>, Token<'a>> {
        let start = &tag("\\[");
        let end = &tag("\\]");

        let (input, _) = opt(line_ending)(input)?;

        if input.get_column() != 0 {
            return fail(input);
        }

        let (input, _) = start(input)?;
        let (input, _) = opt(line_ending)(input)?;

        let (input, math_span) = recognize(many1_count(tuple((
            not(tuple((opt(line_ending), end))),
            not_line_ending,
        ))))(input)?;

        let (input, _) = opt(line_ending)(input)?;
        let (input, _) = end(input)?;
        let (input, _) = many0(space)(input)?;
        let (input, _) = not(not_line_ending)(input)?;
        let (input, _) = opt(line_ending)(input)?;

        Ok((
            input,
            Token::BlockMath(Cow::Borrowed(math_span.into_fragment())),
        ))
    }

    const fn tag_delimited<'a, 'b: 'a, T>(
        &'a self,
        start: &'b str,
        end: &'b str,
        escape: bool,
        matcher_inner: impl Fn(Span<'b>) -> IResult<Span<'b>, T> + 'a,
        mapper: impl Fn(Vec<T>) -> Token<'b> + 'a,
    ) -> impl Fn(Span<'b>) -> IResult<Span<'b>, Token<'b>> + '_ {
        move |input| {
            let opening_tag = &tag(start);
            let closing_tag = &tag(end);

            if escape {
                if let Ok((input_escaped, (_, mark))) = tuple((tag("\\"), opening_tag))(input) {
                    return Ok((input_escaped, Token::PlainText(Cow::Borrowed(&mark))));
                }
            }

            let begin = input;
            let (post_open, _) = opening_tag(input)?;

            let res = tuple((
                many1(tuple((not(closing_tag), &matcher_inner))),
                closing_tag,
            ))(post_open);

            if let Err(nom::Err::Error(nom::error::Error { .. })) = res {
                return Ok((
                    post_open,
                    Token::PlainText(begin.fragment_between(&post_open).into()),
                ));
            }

            let (input, (inner, _)) = res?;

            let inner = inner.into_iter().map(|(_, t)| t).collect::<Vec<_>>();

            Ok((input, mapper(inner)))
        }
    }

    fn tag_func<'a>(&self, input: Span<'a>) -> IResult<Span<'a>, Token<'a>> {
        let (input, _) = tag("$[")(input)?;

        let func_ident = |input| {
            recognize(tuple((
                many1_count(alt((alpha1, tag("_")))),
                many0_count(alt((alphanumeric1, tag("_")))),
            )))(input)
        };

        let param_value = recognize(many1_count(alt((
            alphanumeric1,
            tag("."),
            tag("-"),
            tag("_"),
        ))));

        let (input, func_name_span) = func_ident(input)?;
        let func_name = func_name_span.into_fragment();

        let arg = tuple((func_ident, opt(tuple((tag("="), param_value)))));

        let (input, args) =
            opt(tuple((one_char('.'), separated_list1(one_char(','), arg))))(input)?;

        let args_out = args.map_or_else(HashMap::new, |(_, items)| {
            items
                .into_iter()
                .map(|(k, v)| {
                    (
                        Cow::from(k.into_fragment()),
                        v.map(|(_, val)| Cow::from(val.into_fragment())),
                    )
                })
                .collect::<HashMap<_, _>>()
        });

        let (input, inner) = self.partial(Self::inline)(input)?;

        let (input, _) = tag("]")(input)?;

        Ok((
            input,
            Token::Function {
                name: Cow::from(func_name),
                params: args_out,
                inner: Box::new(inner),
            },
        ))
    }

    fn tag_plain<'a>(&self, input: Span<'a>) -> IResult<Span<'a>, Token<'a>> {
        let opening_tag = &tag("<small>");
        let closing_tag = &tag("</small>");

        let (input, _) = opening_tag(input)?;
        let (input, text) = map(
            recognize(many1(tuple((not_line_ending, not(closing_tag))))),
            Span::into_fragment,
        )(input)?;
        let (input, _) = closing_tag(input)?;

        Ok((input, Token::PlainTag(text.into())))
    }

    fn tag_small<'a>(&self, input: Span<'a>) -> IResult<Span<'a>, Token<'a>> {
        self.tag_delimited(
            "<small>",
            "</small>",
            false,
            self.partial(Self::inline),
            boxing_sequence(Token::Small),
        )(input)
    }

    // TODO: CommonMark flanking rules
    fn tag_bold_italic_asterisk<'a>(&self, input: Span<'a>) -> IResult<Span<'a>, Token<'a>> {
        self.tag_delimited(
            "***",
            "***",
            true,
            self.partial(Self::inline),
            boxing_sequence(Token::BoldItalic),
        )(input)
    }

    // TODO: CommonMark flanking rules
    fn tag_bold_italic_underscore<'a>(&self, input: Span<'a>) -> IResult<Span<'a>, Token<'a>> {
        self.tag_delimited(
            "___",
            "___",
            true,
            self.partial(Self::inline),
            boxing_sequence(Token::BoldItalic),
        )(input)
    }

    fn tag_bold<'a>(&self, input: Span<'a>) -> IResult<Span<'a>, Token<'a>> {
        self.tag_delimited(
            "<b>",
            "</b>",
            false,
            self.partial(Self::inline),
            boxing_sequence(Token::Bold),
        )(input)
    }

    // TODO: CommonMark flanking rules
    fn tag_bold_asterisk<'a>(&self, input: Span<'a>) -> IResult<Span<'a>, Token<'a>> {
        self.tag_delimited(
            "**",
            "**",
            true,
            self.partial(Self::inline),
            boxing_sequence(Token::Bold),
        )(input)
    }

    // TODO: CommonMark flanking rules
    fn tag_bold_underscore<'a>(&self, input: Span<'a>) -> IResult<Span<'a>, Token<'a>> {
        self.tag_delimited(
            "__",
            "__",
            true,
            self.partial(Self::inline),
            boxing_sequence(Token::Bold),
        )(input)
    }

    fn tag_italic<'a>(&self, input: Span<'a>) -> IResult<Span<'a>, Token<'a>> {
        self.tag_delimited(
            "<i>",
            "</i>",
            false,
            self.partial(Self::inline),
            boxing_sequence(Token::Italic),
        )(input)
    }

    // TODO: CommonMark flanking rules
    fn tag_italic_asterisk<'a>(&self, input: Span<'a>) -> IResult<Span<'a>, Token<'a>> {
        self.tag_delimited(
            "*",
            "*",
            true,
            self.partial(Self::inline),
            boxing_sequence(Token::Italic),
        )(input)
    }

    // TODO: CommonMark flanking rules
    fn tag_italic_underscore<'a>(&self, input: Span<'a>) -> IResult<Span<'a>, Token<'a>> {
        self.tag_delimited(
            "_",
            "_",
            true,
            self.partial(Self::inline),
            boxing_sequence(Token::Italic),
        )(input)
    }

    fn tag_strikethrough<'a>(&self, input: Span<'a>) -> IResult<Span<'a>, Token<'a>> {
        self.tag_delimited(
            "<s>",
            "</s>",
            false,
            self.partial(Self::inline),
            boxing_sequence(Token::Strikethrough),
        )(input)
    }

    // TODO: CommonMark flanking rules
    fn tag_strikethrough_tilde<'a>(&self, input: Span<'a>) -> IResult<Span<'a>, Token<'a>> {
        self.tag_delimited(
            "~~",
            "~~",
            true,
            move |input| {
                tuple((not_line_ending, self.partial(Self::inline)))(input).map(|(i, t)| (i, t.1))
            },
            boxing_sequence(Token::Strikethrough),
        )(input)
    }

    fn tag_inline_code<'a>(&self, input: Span<'a>) -> IResult<Span<'a>, Token<'a>> {
        self.tag_delimited(
            "`",
            "",
            true,
            move |input| {
                tuple((not(alt((tag("`"), tag("´"), line_ending))), anychar))(input)
                    .map(|(i, (_skip, c))| (i, c))
            },
            collect_char_sequence(Token::InlineCode),
        )(input)
    }

    fn tag_inline_math<'a>(&self, input: Span<'a>) -> IResult<Span<'a>, Token<'a>> {
        self.tag_delimited(
            "\\(",
            "\\)",
            false,
            move |input| tuple((not_line_ending, anychar))(input).map(|(i, (_skip, c))| (i, c)),
            collect_char_sequence(Token::InlineMath),
        )(input)
    }

    fn text<'a>(&self, input: Span<'a>) -> IResult<Span<'a>, Token<'a>> {
        let before = input;
        let (input, _) = anychar(input)?;
        Ok((
            input,
            Token::PlainText(before.fragment_between(&input).into()),
        ))
    }

    fn url<'a>(&self, input: Span<'a>) -> IResult<Span<'a>, Token<'a>> {
        let (input, url_span) = recognize(tuple((
            protocol,
            url_chars(|input| not(url_chars_base)(input), false),
        )))(input)?;

        let url = url_span.into_fragment();
        let url_bytes = url.as_bytes();

        // Strip punctuation at the end of sentences that might have been consumed as a part of the URL
        let final_url = if matches!(url_bytes.last(), Some(b'.' | b',' | b'?')) {
            url.slice(..url.len() - 1)
        } else {
            url
        };

        Ok((input, Token::UrlRaw(Cow::from(final_url))))
    }

    fn url_no_embed<'a>(&self, input: Span<'a>) -> IResult<Span<'a>, Token<'a>> {
        let (input, _) = tag("<")(input)?;
        let (input, url_span) = recognize(tuple((protocol, url_chars(tag(">"), true))))(input)?;
        let (input, _) = tag(">")(input)?;

        Ok((input, Token::UrlRaw(Cow::from(url_span.into_fragment()))))
    }

    fn link<'a>(&self, input: Span<'a>) -> IResult<Span<'a>, Token<'a>> {
        let (input, no_embed) = opt(tag("?"))(input)?;
        let (input, _) = tag("[")(input)?;
        let (input, _) = not(tag("["))(input)?;
        let (input, label_span) =
            recognize(many1(tuple((not(tag("](")), not_line_ending))))(input)?;
        let (input, _) = tag("]")(input)?;
        let (input, _) = tag("(")(input)?;
        let (input, url_span) = recognize(tuple((protocol, url_chars(tag("]"), true))))(input)?;
        let (input, _) = tag(")")(input)?;

        Ok((
            input,
            Token::Link {
                label: label_span.into_fragment().into(),
                href: url_span.into_fragment().into(),
                embed: no_embed.is_none(),
            },
        ))
    }

    fn unicode_emoji<'a>(&self, input: Span<'a>) -> IResult<Span<'a>, Token<'a>> {
        let frag = input.fragment();
        let Some(grapheme) = frag.graphemes(true).next() else {
            return fail(input);
        };

        let emoji = emojis::get(grapheme);

        if emoji.is_none() {
            return fail(input);
        }

        Ok((
            input.slice(grapheme.len()..),
            Token::UnicodeEmoji(grapheme.into()),
        ))
    }

    fn mention<'a>(&self, input: Span<'a>) -> IResult<Span<'a>, Token<'a>> {
        // TODO: Escaping and skip when preceded by alphanumerics

        let tags = one_of("@!");
        let (input, mention_type) = map(tags, |c| match c {
            '@' => MentionType::User,
            '!' => MentionType::Community,
            _ => unreachable!(),
        })(input)?;

        let (input, name) = map(
            recognize(many1(alt((alphanumeric1, recognize(one_of("-_")))))),
            Span::into_fragment,
        )(input)?;

        let (input, host) = map(
            opt(tuple((
                tag("@"),
                map(
                    recognize(many1(alt((alphanumeric1, recognize(one_of("-_")))))),
                    Span::into_fragment,
                ),
            ))),
            |maybe_tag_host| maybe_tag_host.map(|(_, host)| host),
        )(input)?;

        Ok((
            input,
            Token::Mention {
                mention_type,
                name: name.into(),
                host: host.map(|h| h.into()),
            },
        ))
    }

    fn hashtag<'a>(&self, input: Span<'a>) -> IResult<Span<'a>, Token<'a>> {
        // TODO: Skip when preceded by alphanumerics

        let (input, _) = tag("#")(input)?;

        let (input, hashtag_text) =
            map(recognize(many1(hashtag_chars)), Span::into_fragment)(input)?;

        Ok((input, Token::Hashtag(hashtag_text.into())))
    }
}

#[inline]
fn hashtag_chars(input: Span) -> IResult<Span, Span> {
    recognize(alt((
        recognize(tuple((tag("("), hashtag_chars, tag(")")))),
        recognize(tuple((tag("["), hashtag_chars, tag("]")))),
        recognize(tuple((tag("「"), hashtag_chars, tag("」")))),
        recognize(tuple((tag("（"), hashtag_chars, tag("）")))),
        recognize(tuple((
            not(space1),
            not_line_ending,
            not(one_of(".,:;!?#?/[]【】()「」（）<>")),
            anychar,
        ))),
    )))(input)
}

#[inline]
fn protocol(input: Span) -> IResult<Span, Span> {
    alt((tag("https://"), tag("http://")))(input)
}

#[inline]
fn url_chars_base(input: Span) -> IResult<Span, Span> {
    recognize(alt((alpha1, recognize(one_of(".,_/:%#$&?!~=+-()[]@")))))(input)
}

#[inline]
fn url_chars<'a, T: 'a>(
    terminator: impl Fn(Span<'a>) -> IResult<Span<'a>, T> + 'a,
    spaces: bool,
) -> impl FnMut(Span<'a>) -> IResult<Span<'a>, Span<'a>> + 'a {
    let terminating = move |input| {
        tuple((
            &terminator,
            alt((
                space1,
                line_ending,
                eof,
                recognize(one_of("([<'\"")),
                recognize(tuple((
                    alt((alpha1, recognize(one_of("*")))),
                    alt((space1, line_ending, eof)),
                ))),
            )),
        ))(input)
    };

    let chars = tuple((
        not(tuple((space1, eof))),
        not(tuple((space1, tag("\"")))),
        not(tuple((opt(space1), terminating))),
        alt((url_chars_base, if spaces { space1 } else { fail })),
    ));

    recognize(many1_count(chars))
}

#[cfg(test)]
mod test {
    use crate::{url_chars, Context, Span};
    use nom::bytes::complete::tag;
    use nom::multi::many1;

    #[test]
    fn parse_url_chars() {
        let test1 = "https://en.wikipedia.org/wiki/Sandbox_(computer_security))";
        assert_eq!(
            "https://en.wikipedia.org/wiki/Sandbox_(computer_security)",
            url_chars(tag(")"), true)(Span::new(test1))
                .unwrap()
                .1
                .into_fragment()
        );

        let test2 = "https://en.wikipedia.org/wiki/Sandbox_(computer_security)))";
        assert_eq!(
            "https://en.wikipedia.org/wiki/Sandbox_(computer_security))",
            url_chars(tag(")"), true)(Span::new(test2))
                .unwrap()
                .1
                .into_fragment()
        );

        let test3 = "https://en.wikipedia.org/wiki/(";
        assert_eq!(
            test3,
            url_chars(tag(")"), true)(Span::new(test3))
                .unwrap()
                .1
                .into_fragment()
        );

        let test4 = "https://cs.wikipedia.org/wiki/Among_Us  ";
        assert_eq!(
            "https://cs.wikipedia.org/wiki/Among_Us",
            url_chars(tag(")"), true)(Span::new(test4))
                .unwrap()
                .1
                .into_fragment()
        );

        let test5 = "https://cs.wikipedia.org/wiki/Among Us  )";
        assert_eq!(
            "https://cs.wikipedia.org/wiki/Among Us",
            url_chars(tag(")"), true)(Span::new(test5))
                .unwrap()
                .1
                .into_fragment()
        );
    }

    #[test]
    fn parse_emoji() {
        let test = "🥺💜❤️🦊";
        let ctx = Context;
        let tokens = many1(ctx.partial(Context::unicode_emoji))(Span::from(test)).unwrap();

        println!("{:#?}", tokens.1)
    }
}