// Copyright 2014-2016 The Rust Project Developers. See the COPYRIGHT // file at the top-level directory of this distribution and at // http://rust-lang.org/COPYRIGHT. // // Licensed under the Apache License, Version 2.0 or the MIT license // , at your // option. This file may not be copied, modified, or distributed // except according to those terms. //! Basic syntax highlighting functionality. //! //! This module uses libsyntax's lexer to provide token-based highlighting for //! the HTML documentation generated by rustdoc. //! //! If you just want to syntax highlighting for a Rust program, then you can use //! the `render_inner_with_highlighting` or `render_with_highlighting` //! functions. For more advanced use cases (if you want to supply your own css //! classes or control how the HTML is generated, or even generate something //! other then HTML), then you should implement the the `Writer` trait and use a //! `Classifier`. use html::escape::Escape; use std::fmt::Display; use std::io; use std::io::prelude::*; use syntax::codemap::{CodeMap, Span}; use syntax::parse::lexer::{self, Reader, TokenAndSpan}; use syntax::parse::token; use syntax::parse; /// Highlights `src`, returning the HTML output. pub fn render_with_highlighting(src: &str, class: Option<&str>, id: Option<&str>) -> String { debug!("highlighting: ================\n{}\n==============", src); let sess = parse::ParseSess::new(); let fm = sess.codemap().new_filemap("".to_string(), None, src.to_string()); let mut out = Vec::new(); write_header(class, id, &mut out).unwrap(); let mut classifier = Classifier::new(lexer::StringReader::new(&sess.span_diagnostic, fm), sess.codemap()); if let Err(_) = classifier.write_source(&mut out) { return format!("
{}
", src); } write_footer(&mut out).unwrap(); String::from_utf8_lossy(&out[..]).into_owned() } /// Highlights `src`, returning the HTML output. Returns only the inner html to /// be inserted into an element. C.f., `render_with_highlighting` which includes /// an enclosing `
` block.
pub fn render_inner_with_highlighting(src: &str) -> io::Result {
    let sess = parse::ParseSess::new();
    let fm = sess.codemap().new_filemap("".to_string(), None, src.to_string());

    let mut out = Vec::new();
    let mut classifier = Classifier::new(lexer::StringReader::new(&sess.span_diagnostic, fm),
                                         sess.codemap());
    classifier.write_source(&mut out)?;

    Ok(String::from_utf8_lossy(&out).into_owned())
}

/// Processes a program (nested in the internal `lexer`), classifying strings of
/// text by highlighting category (`Class`). Calls out to a `Writer` to write
/// each span of text in sequence.
pub struct Classifier<'a> {
    lexer: lexer::StringReader<'a>,
    codemap: &'a CodeMap,

    // State of the classifier.
    in_attribute: bool,
    in_macro: bool,
    in_macro_nonterminal: bool,
}

/// How a span of text is classified. Mostly corresponds to token kinds.
#[derive(Clone, Copy, Debug, Eq, PartialEq)]
pub enum Class {
    None,
    Comment,
    DocComment,
    Attribute,
    KeyWord,
    // Keywords that do pointer/reference stuff.
    RefKeyWord,
    Self_,
    Op,
    Macro,
    MacroNonTerminal,
    String,
    Number,
    Bool,
    Ident,
    Lifetime,
    PreludeTy,
    PreludeVal,
}

/// Trait that controls writing the output of syntax highlighting. Users should
/// implement this trait to customise writing output.
///
/// The classifier will call into the `Writer` implementation as it finds spans
/// of text to highlight. Exactly how that text should be highlighted is up to
/// the implemention.
pub trait Writer {
    /// Called when we start processing a span of text that should be highlighted.
    /// The `Class` argument specifies how it should be highlighted.
    fn enter_span(&mut self, Class) -> io::Result<()>;

    /// Called at the end of a span of highlighted text.
    fn exit_span(&mut self) -> io::Result<()>;

    /// Called for a span of text, usually, but not always, a single token. If
    /// the string of text (`T`) does correspond to a token, then the token will
    /// also be passed. If the text should be highlighted differently from the
    /// surrounding text, then the `Class` argument will be a value other than
    /// `None`.
    /// The following sequences of callbacks are equivalent:
    /// ```plain
    ///     enter_span(Foo), string("text", None), exit_span()
    ///     string("text", Foo)
    /// ```
    /// The latter can be thought of as a shorthand for the former, which is
    /// more flexible.
    fn string(&mut self, T, Class, Option<&TokenAndSpan>) -> io::Result<()>;
}

// Implement `Writer` for anthing that can be written to, this just implements
// the default rustdoc behaviour.
impl Writer for U {
    fn string(&mut self,
                          text: T,
                          klass: Class,
                          _tas: Option<&TokenAndSpan>)
                          -> io::Result<()> {
        match klass {
            Class::None => write!(self, "{}", text),
            klass => write!(self, "{}", klass.rustdoc_class(), text),
        }
    }

    fn enter_span(&mut self, klass: Class) -> io::Result<()> {
        write!(self, "", klass.rustdoc_class())
    }

    fn exit_span(&mut self) -> io::Result<()> {
        write!(self, "")
    }
}

impl<'a> Classifier<'a> {
    pub fn new(lexer: lexer::StringReader<'a>, codemap: &'a CodeMap) -> Classifier<'a> {
        Classifier {
            lexer: lexer,
            codemap: codemap,
            in_attribute: false,
            in_macro: false,
            in_macro_nonterminal: false,
        }
    }

    /// Exhausts the `lexer` writing the output into `out`.
    ///
    /// The general structure for this method is to iterate over each token,
    /// possibly giving it an HTML span with a class specifying what flavor of token
    /// is used. All source code emission is done as slices from the source map,
    /// not from the tokens themselves, in order to stay true to the original
    /// source.
    pub fn write_source(&mut self,
                                   out: &mut W)
                                   -> io::Result<()> {
        loop {
            let next = match self.lexer.try_next_token() {
                Ok(tas) => tas,
                Err(_) => {
                    self.lexer.emit_fatal_errors();
                    self.lexer.span_diagnostic.struct_warn("Backing out of syntax highlighting")
                                              .note("You probably did not intend to render this \
                                                     as a rust code-block")
                                              .emit();
                    return Err(io::Error::new(io::ErrorKind::Other, ""));
                }
            };

            if next.tok == token::Eof {
                break;
            }

            self.write_token(out, next)?;
        }

        Ok(())
    }

    // Handles an individual token from the lexer.
    fn write_token(&mut self,
                              out: &mut W,
                              tas: TokenAndSpan)
                              -> io::Result<()> {
        let klass = match tas.tok {
            token::Shebang(s) => {
                out.string(Escape(&s.as_str()), Class::None, Some(&tas))?;
                return Ok(());
            },

            token::Whitespace => Class::None,
            token::Comment => Class::Comment,
            token::DocComment(..) => Class::DocComment,

            // If this '&' token is directly adjacent to another token, assume
            // that it's the address-of operator instead of the and-operator.
            token::BinOp(token::And) if self.lexer.peek().sp.lo == tas.sp.hi => Class::RefKeyWord,

            // Consider this as part of a macro invocation if there was a
            // leading identifier.
            token::Not if self.in_macro => {
                self.in_macro = false;
                Class::Macro
            }

            // Operators.
            token::Eq | token::Lt | token::Le | token::EqEq | token::Ne | token::Ge | token::Gt |
                token::AndAnd | token::OrOr | token::Not | token::BinOp(..) | token::RArrow |
                token::BinOpEq(..) | token::FatArrow => Class::Op,

            // Miscellaneous, no highlighting.
            token::Dot | token::DotDot | token::DotDotDot | token::Comma | token::Semi |
                token::Colon | token::ModSep | token::LArrow | token::OpenDelim(_) |
                token::CloseDelim(token::Brace) | token::CloseDelim(token::Paren) |
                token::Question => Class::None,
            token::Dollar => {
                if self.lexer.peek().tok.is_ident() {
                    self.in_macro_nonterminal = true;
                    Class::MacroNonTerminal
                } else {
                    Class::None
                }
            }

            // This is the start of an attribute. We're going to want to
            // continue highlighting it as an attribute until the ending ']' is
            // seen, so skip out early. Down below we terminate the attribute
            // span when we see the ']'.
            token::Pound => {
                self.in_attribute = true;
                out.enter_span(Class::Attribute)?;
                out.string("#", Class::None, None)?;
                return Ok(());
            }
            token::CloseDelim(token::Bracket) => {
                if self.in_attribute {
                    self.in_attribute = false;
                    out.string("]", Class::None, None)?;
                    out.exit_span()?;
                    return Ok(());
                } else {
                    Class::None
                }
            }

            token::Literal(lit, _suf) => {
                match lit {
                    // Text literals.
                    token::Byte(..) | token::Char(..) |
                        token::ByteStr(..) | token::ByteStrRaw(..) |
                        token::Str_(..) | token::StrRaw(..) => Class::String,

                    // Number literals.
                    token::Integer(..) | token::Float(..) => Class::Number,
                }
            }

            // Keywords are also included in the identifier set.
            token::Ident(ident) => {
                match &*ident.name.as_str() {
                    "ref" | "mut" => Class::RefKeyWord,

                    "self" |"Self" => Class::Self_,
                    "false" | "true" => Class::Bool,

                    "Option" | "Result" => Class::PreludeTy,
                    "Some" | "None" | "Ok" | "Err" => Class::PreludeVal,

                    _ if tas.tok.is_any_keyword() => Class::KeyWord,
                    _ => {
                        if self.in_macro_nonterminal {
                            self.in_macro_nonterminal = false;
                            Class::MacroNonTerminal
                        } else if self.lexer.peek().tok == token::Not {
                            self.in_macro = true;
                            Class::Macro
                        } else {
                            Class::Ident
                        }
                    }
                }
            }

            // Special macro vars are like keywords.
            token::SpecialVarNt(_) => Class::KeyWord,

            token::Lifetime(..) => Class::Lifetime,

            token::Underscore | token::Eof | token::Interpolated(..) |
            token::MatchNt(..) | token::SubstNt(..) | token::Tilde | token::At => Class::None,
        };

        // Anything that didn't return above is the simple case where we the
        // class just spans a single token, so we can use the `string` method.
        out.string(Escape(&self.snip(tas.sp)), klass, Some(&tas))
    }

    // Helper function to get a snippet from the codemap.
    fn snip(&self, sp: Span) -> String {
        self.codemap.span_to_snippet(sp).unwrap()
    }
}

impl Class {
    /// Returns the css class expected by rustdoc for each `Class`.
    pub fn rustdoc_class(self) -> &'static str {
        match self {
            Class::None => "",
            Class::Comment => "comment",
            Class::DocComment => "doccomment",
            Class::Attribute => "attribute",
            Class::KeyWord => "kw",
            Class::RefKeyWord => "kw-2",
            Class::Self_ => "self",
            Class::Op => "op",
            Class::Macro => "macro",
            Class::MacroNonTerminal => "macro-nonterminal",
            Class::String => "string",
            Class::Number => "number",
            Class::Bool => "bool-val",
            Class::Ident => "ident",
            Class::Lifetime => "lifetime",
            Class::PreludeTy => "prelude-ty",
            Class::PreludeVal => "prelude-val",
        }
    }
}

fn write_header(class: Option<&str>,
                id: Option<&str>,
                out: &mut Write)
                -> io::Result<()> {
    write!(out, "
 write!(out, "id='{}' ", id)?,
        None => {}
    }
    write!(out, "class='rust {}'>\n", class.unwrap_or(""))
}

fn write_footer(out: &mut Write) -> io::Result<()> {
    write!(out, "
\n")
}