// Copyright 2013-2014 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. //! HTML formatting module //! //! This module contains a large number of `fmt::Display` implementations for //! various types in `rustdoc::clean`. These implementations all currently //! assume that HTML output is desired, although it may be possible to redesign //! them in the future to instead emit any format desired. use std::fmt; use std::iter::repeat; use rustc::hir::def_id::DefId; use syntax::abi::Abi; use rustc::hir; use clean::{self, PrimitiveType}; use core::DocAccessLevels; use html::item_type::ItemType; use html::escape::Escape; use html::render; use html::render::{cache, CURRENT_LOCATION_KEY}; /// Helper to render an optional visibility with a space after it (if the /// visibility is preset) #[derive(Copy, Clone)] pub struct VisSpace<'a>(pub &'a Option); /// Similarly to VisSpace, this structure is used to render a function style with a /// space after it. #[derive(Copy, Clone)] pub struct UnsafetySpace(pub hir::Unsafety); /// Similarly to VisSpace, this structure is used to render a function constness /// with a space after it. #[derive(Copy, Clone)] pub struct ConstnessSpace(pub hir::Constness); /// Wrapper struct for properly emitting a method declaration. pub struct Method<'a>(pub &'a clean::FnDecl, pub usize); /// Similar to VisSpace, but used for mutability #[derive(Copy, Clone)] pub struct MutableSpace(pub clean::Mutability); /// Similar to VisSpace, but used for mutability #[derive(Copy, Clone)] pub struct RawMutableSpace(pub clean::Mutability); /// Wrapper struct for emitting a where clause from Generics. pub struct WhereClause<'a>(pub &'a clean::Generics, pub usize); /// Wrapper struct for emitting type parameter bounds. pub struct TyParamBounds<'a>(pub &'a [clean::TyParamBound]); /// Wrapper struct for emitting a comma-separated list of items pub struct CommaSep<'a, T: 'a>(pub &'a [T]); pub struct AbiSpace(pub Abi); pub struct HRef<'a> { pub did: DefId, pub text: &'a str, } impl<'a> VisSpace<'a> { pub fn get(self) -> &'a Option { let VisSpace(v) = self; v } } impl UnsafetySpace { pub fn get(&self) -> hir::Unsafety { let UnsafetySpace(v) = *self; v } } impl ConstnessSpace { pub fn get(&self) -> hir::Constness { let ConstnessSpace(v) = *self; v } } impl<'a, T: fmt::Display> fmt::Display for CommaSep<'a, T> { fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { for (i, item) in self.0.iter().enumerate() { if i != 0 { write!(f, ", ")?; } fmt::Display::fmt(item, f)?; } Ok(()) } } impl<'a> fmt::Display for TyParamBounds<'a> { fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { let &TyParamBounds(bounds) = self; for (i, bound) in bounds.iter().enumerate() { if i > 0 { f.write_str(" + ")?; } fmt::Display::fmt(bound, f)?; } Ok(()) } } impl fmt::Display for clean::Generics { fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { if self.lifetimes.is_empty() && self.type_params.is_empty() { return Ok(()) } if f.alternate() { f.write_str("<")?; } else { f.write_str("<")?; } for (i, life) in self.lifetimes.iter().enumerate() { if i > 0 { f.write_str(", ")?; } write!(f, "{}", *life)?; } if !self.type_params.is_empty() { if !self.lifetimes.is_empty() { f.write_str(", ")?; } for (i, tp) in self.type_params.iter().enumerate() { if i > 0 { f.write_str(", ")? } f.write_str(&tp.name)?; if !tp.bounds.is_empty() { if f.alternate() { write!(f, ": {:#}", TyParamBounds(&tp.bounds))?; } else { write!(f, ": {}", TyParamBounds(&tp.bounds))?; } } if let Some(ref ty) = tp.default { if f.alternate() { write!(f, " = {:#}", ty)?; } else { write!(f, " = {}", ty)?; } }; } } if f.alternate() { f.write_str(">")?; } else { f.write_str(">")?; } Ok(()) } } impl<'a> fmt::Display for WhereClause<'a> { fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { let &WhereClause(gens, pad) = self; if gens.where_predicates.is_empty() { return Ok(()); } let mut clause = String::new(); if f.alternate() { clause.push_str(" where "); } else { clause.push_str(" where "); } for (i, pred) in gens.where_predicates.iter().enumerate() { if i > 0 { if f.alternate() { clause.push_str(", "); } else { clause.push_str(",
"); } } match pred { &clean::WherePredicate::BoundPredicate { ref ty, ref bounds } => { let bounds = bounds; if f.alternate() { clause.push_str(&format!("{:#}: {:#}", ty, TyParamBounds(bounds))); } else { clause.push_str(&format!("{}: {}", ty, TyParamBounds(bounds))); } } &clean::WherePredicate::RegionPredicate { ref lifetime, ref bounds } => { clause.push_str(&format!("{}: ", lifetime)); for (i, lifetime) in bounds.iter().enumerate() { if i > 0 { clause.push_str(" + "); } clause.push_str(&format!("{}", lifetime)); } } &clean::WherePredicate::EqPredicate { ref lhs, ref rhs } => { if f.alternate() { clause.push_str(&format!("{:#} == {:#}", lhs, rhs)); } else { clause.push_str(&format!("{} == {}", lhs, rhs)); } } } } if !f.alternate() { clause.push_str(""); let plain = format!("{:#}", self); if plain.len() + pad > 80 { //break it onto its own line regardless, but make sure method impls and trait //blocks keep their fixed padding (2 and 9, respectively) let padding = if pad > 10 { clause = clause.replace("class='where'", "class='where fmt-newline'"); repeat(" ").take(8).collect::() } else { repeat(" ").take(pad + 6).collect::() }; clause = clause.replace("
", &format!("
{}", padding)); } else { clause = clause.replace("
", " "); } } write!(f, "{}", clause) } } impl fmt::Display for clean::Lifetime { fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { f.write_str(self.get_ref())?; Ok(()) } } impl fmt::Display for clean::PolyTrait { fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { if !self.lifetimes.is_empty() { if f.alternate() { f.write_str("for<")?; } else { f.write_str("for<")?; } for (i, lt) in self.lifetimes.iter().enumerate() { if i > 0 { f.write_str(", ")?; } write!(f, "{}", lt)?; } if f.alternate() { f.write_str("> ")?; } else { f.write_str("> ")?; } } if f.alternate() { write!(f, "{:#}", self.trait_) } else { write!(f, "{}", self.trait_) } } } impl fmt::Display for clean::TyParamBound { fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { match *self { clean::RegionBound(ref lt) => { write!(f, "{}", *lt) } clean::TraitBound(ref ty, modifier) => { let modifier_str = match modifier { hir::TraitBoundModifier::None => "", hir::TraitBoundModifier::Maybe => "?", }; if f.alternate() { write!(f, "{}{:#}", modifier_str, *ty) } else { write!(f, "{}{}", modifier_str, *ty) } } } } } impl fmt::Display for clean::PathParameters { fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { match *self { clean::PathParameters::AngleBracketed { ref lifetimes, ref types, ref bindings } => { if !lifetimes.is_empty() || !types.is_empty() || !bindings.is_empty() { if f.alternate() { f.write_str("<")?; } else { f.write_str("<")?; } let mut comma = false; for lifetime in lifetimes { if comma { f.write_str(", ")?; } comma = true; write!(f, "{}", *lifetime)?; } for ty in types { if comma { f.write_str(", ")?; } comma = true; if f.alternate() { write!(f, "{:#}", *ty)?; } else { write!(f, "{}", *ty)?; } } for binding in bindings { if comma { f.write_str(", ")?; } comma = true; if f.alternate() { write!(f, "{:#}", *binding)?; } else { write!(f, "{}", *binding)?; } } if f.alternate() { f.write_str(">")?; } else { f.write_str(">")?; } } } clean::PathParameters::Parenthesized { ref inputs, ref output } => { f.write_str("(")?; let mut comma = false; for ty in inputs { if comma { f.write_str(", ")?; } comma = true; if f.alternate() { write!(f, "{:#}", *ty)?; } else { write!(f, "{}", *ty)?; } } f.write_str(")")?; if let Some(ref ty) = *output { if f.alternate() { write!(f, " -> {:#}", ty)?; } else { write!(f, " -> {}", ty)?; } } } } Ok(()) } } impl fmt::Display for clean::PathSegment { fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { f.write_str(&self.name)?; if f.alternate() { write!(f, "{:#}", self.params) } else { write!(f, "{}", self.params) } } } impl fmt::Display for clean::Path { fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { if self.global { f.write_str("::")? } for (i, seg) in self.segments.iter().enumerate() { if i > 0 { f.write_str("::")? } if f.alternate() { write!(f, "{:#}", seg)?; } else { write!(f, "{}", seg)?; } } Ok(()) } } pub fn href(did: DefId) -> Option<(String, ItemType, Vec)> { let cache = cache(); if !did.is_local() && !cache.access_levels.is_doc_reachable(did) { return None } let loc = CURRENT_LOCATION_KEY.with(|l| l.borrow().clone()); let (fqp, shortty, mut url) = match cache.paths.get(&did) { Some(&(ref fqp, shortty)) => { (fqp, shortty, repeat("../").take(loc.len()).collect()) } None => match cache.external_paths.get(&did) { Some(&(ref fqp, shortty)) => { (fqp, shortty, match cache.extern_locations[&did.krate] { (.., render::Remote(ref s)) => s.to_string(), (.., render::Local) => repeat("../").take(loc.len()).collect(), (.., render::Unknown) => return None, }) } None => return None, } }; for component in &fqp[..fqp.len() - 1] { url.push_str(component); url.push_str("/"); } match shortty { ItemType::Module => { url.push_str(fqp.last().unwrap()); url.push_str("/index.html"); } _ => { url.push_str(shortty.css_class()); url.push_str("."); url.push_str(fqp.last().unwrap()); url.push_str(".html"); } } Some((url, shortty, fqp.to_vec())) } /// Used when rendering a `ResolvedPath` structure. This invokes the `path` /// rendering function with the necessary arguments for linking to a local path. fn resolved_path(w: &mut fmt::Formatter, did: DefId, path: &clean::Path, print_all: bool, use_absolute: bool) -> fmt::Result { let last = path.segments.last().unwrap(); let rel_root = match &*path.segments[0].name { "self" => Some("./".to_string()), _ => None, }; if print_all { let amt = path.segments.len() - 1; match rel_root { Some(mut root) => { for seg in &path.segments[..amt] { if "super" == seg.name || "self" == seg.name || w.alternate() { write!(w, "{}::", seg.name)?; } else { root.push_str(&seg.name); root.push_str("/"); write!(w, "{}::", root, seg.name)?; } } } None => { for seg in &path.segments[..amt] { write!(w, "{}::", seg.name)?; } } } } if w.alternate() { write!(w, "{:#}{:#}", HRef::new(did, &last.name), last.params)?; } else { let path = if use_absolute { match href(did) { Some((_, _, fqp)) => format!("{}::{}", fqp[..fqp.len()-1].join("::"), HRef::new(did, fqp.last().unwrap())), None => format!("{}", HRef::new(did, &last.name)), } } else { format!("{}", HRef::new(did, &last.name)) }; write!(w, "{}{}", path, last.params)?; } Ok(()) } fn primitive_link(f: &mut fmt::Formatter, prim: clean::PrimitiveType, name: &str) -> fmt::Result { let m = cache(); let mut needs_termination = false; if !f.alternate() { match m.primitive_locations.get(&prim) { Some(&def_id) if def_id.is_local() => { let len = CURRENT_LOCATION_KEY.with(|s| s.borrow().len()); let len = if len == 0 {0} else {len - 1}; write!(f, "", repeat("../").take(len).collect::(), prim.to_url_str())?; needs_termination = true; } Some(&def_id) => { let loc = match m.extern_locations[&def_id.krate] { (ref cname, _, render::Remote(ref s)) => { Some((cname, s.to_string())) } (ref cname, _, render::Local) => { let len = CURRENT_LOCATION_KEY.with(|s| s.borrow().len()); Some((cname, repeat("../").take(len).collect::())) } (.., render::Unknown) => None, }; if let Some((cname, root)) = loc { write!(f, "", root, cname, prim.to_url_str())?; needs_termination = true; } } None => {} } } write!(f, "{}", name)?; if needs_termination { write!(f, "")?; } Ok(()) } /// Helper to render type parameters fn tybounds(w: &mut fmt::Formatter, typarams: &Option >) -> fmt::Result { match *typarams { Some(ref params) => { for param in params { write!(w, " + ")?; fmt::Display::fmt(param, w)?; } Ok(()) } None => Ok(()) } } impl<'a> HRef<'a> { pub fn new(did: DefId, text: &'a str) -> HRef<'a> { HRef { did: did, text: text } } } impl<'a> fmt::Display for HRef<'a> { fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { match href(self.did) { Some((url, shortty, fqp)) => if !f.alternate() { write!(f, "{}", shortty, url, fqp.join("::"), self.text) } else { write!(f, "{}", self.text) }, _ => write!(f, "{}", self.text), } } } fn fmt_type(t: &clean::Type, f: &mut fmt::Formatter, use_absolute: bool) -> fmt::Result { match *t { clean::Generic(ref name) => { f.write_str(name) } clean::ResolvedPath{ did, ref typarams, ref path, is_generic } => { // Paths like T::Output and Self::Output should be rendered with all segments resolved_path(f, did, path, is_generic, use_absolute)?; tybounds(f, typarams) } clean::Infer => write!(f, "_"), clean::Primitive(prim) => primitive_link(f, prim, prim.as_str()), clean::BareFunction(ref decl) => { if f.alternate() { write!(f, "{}{}fn{:#}{:#}", UnsafetySpace(decl.unsafety), AbiSpace(decl.abi), decl.generics, decl.decl) } else { write!(f, "{}{}fn{}{}", UnsafetySpace(decl.unsafety), AbiSpace(decl.abi), decl.generics, decl.decl) } } clean::Tuple(ref typs) => { match &typs[..] { &[] => primitive_link(f, PrimitiveType::Tuple, "()"), &[ref one] => { primitive_link(f, PrimitiveType::Tuple, "(")?; //carry f.alternate() into this display w/o branching manually fmt::Display::fmt(one, f)?; primitive_link(f, PrimitiveType::Tuple, ",)") } many => { primitive_link(f, PrimitiveType::Tuple, "(")?; fmt::Display::fmt(&CommaSep(&many), f)?; primitive_link(f, PrimitiveType::Tuple, ")") } } } clean::Vector(ref t) => { primitive_link(f, PrimitiveType::Slice, &format!("["))?; fmt::Display::fmt(t, f)?; primitive_link(f, PrimitiveType::Slice, &format!("]")) } clean::FixedVector(ref t, ref s) => { primitive_link(f, PrimitiveType::Array, "[")?; fmt::Display::fmt(t, f)?; if f.alternate() { primitive_link(f, PrimitiveType::Array, &format!("; {}]", s)) } else { primitive_link(f, PrimitiveType::Array, &format!("; {}]", Escape(s))) } } clean::Never => f.write_str("!"), clean::RawPointer(m, ref t) => { match **t { clean::Generic(_) | clean::ResolvedPath {is_generic: true, ..} => { if f.alternate() { primitive_link(f, clean::PrimitiveType::RawPointer, &format!("*{}{:#}", RawMutableSpace(m), t)) } else { primitive_link(f, clean::PrimitiveType::RawPointer, &format!("*{}{}", RawMutableSpace(m), t)) } } _ => { primitive_link(f, clean::PrimitiveType::RawPointer, &format!("*{}", RawMutableSpace(m)))?; fmt::Display::fmt(t, f) } } } clean::BorrowedRef{ lifetime: ref l, mutability, type_: ref ty} => { let lt = match *l { Some(ref l) => format!("{} ", *l), _ => "".to_string(), }; let m = MutableSpace(mutability); match **ty { clean::Vector(ref bt) => { // BorrowedRef{ ... Vector(T) } is &[T] match **bt { clean::Generic(_) => if f.alternate() { primitive_link(f, PrimitiveType::Slice, &format!("&{}{}[{:#}]", lt, m, **bt)) } else { primitive_link(f, PrimitiveType::Slice, &format!("&{}{}[{}]", lt, m, **bt)) }, _ => { if f.alternate() { primitive_link(f, PrimitiveType::Slice, &format!("&{}{}[", lt, m))?; write!(f, "{:#}", **bt)?; } else { primitive_link(f, PrimitiveType::Slice, &format!("&{}{}[", lt, m))?; write!(f, "{}", **bt)?; } primitive_link(f, PrimitiveType::Slice, "]") } } } _ => { if f.alternate() { write!(f, "&{}{}{:#}", lt, m, **ty) } else { write!(f, "&{}{}{}", lt, m, **ty) } } } } clean::PolyTraitRef(ref bounds) => { for (i, bound) in bounds.iter().enumerate() { if i != 0 { write!(f, " + ")?; } if f.alternate() { write!(f, "{:#}", *bound)?; } else { write!(f, "{}", *bound)?; } } Ok(()) } clean::ImplTrait(ref bounds) => { write!(f, "impl ")?; for (i, bound) in bounds.iter().enumerate() { if i != 0 { write!(f, " + ")?; } if f.alternate() { write!(f, "{:#}", *bound)?; } else { write!(f, "{}", *bound)?; } } Ok(()) } // It's pretty unsightly to look at `::C` in output, and // we've got hyperlinking on our side, so try to avoid longer // notation as much as possible by making `C` a hyperlink to trait // `B` to disambiguate. // // FIXME: this is still a lossy conversion and there should probably // be a better way of representing this in general? Most of // the ugliness comes from inlining across crates where // everything comes in as a fully resolved QPath (hard to // look at). clean::QPath { ref name, ref self_type, trait_: box clean::ResolvedPath { did, ref typarams, .. }, } => { if f.alternate() { write!(f, "{:#}::", self_type)?; } else { write!(f, "{}::", self_type)?; } let path = clean::Path::singleton(name.clone()); resolved_path(f, did, &path, true, use_absolute)?; // FIXME: `typarams` are not rendered, and this seems bad? drop(typarams); Ok(()) } clean::QPath { ref name, ref self_type, ref trait_ } => { if f.alternate() { write!(f, "<{:#} as {:#}>::{}", self_type, trait_, name) } else { write!(f, "<{} as {}>::{}", self_type, trait_, name) } } clean::Unique(..) => { panic!("should have been cleaned") } } } impl fmt::Display for clean::Type { fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { fmt_type(self, f, false) } } fn fmt_impl(i: &clean::Impl, f: &mut fmt::Formatter, link_trait: bool, use_absolute: bool) -> fmt::Result { let mut plain = String::new(); if f.alternate() { write!(f, "impl{:#} ", i.generics)?; } else { write!(f, "impl{} ", i.generics)?; } plain.push_str(&format!("impl{:#} ", i.generics)); if let Some(ref ty) = i.trait_ { if i.polarity == Some(clean::ImplPolarity::Negative) { write!(f, "!")?; plain.push_str("!"); } if link_trait { fmt::Display::fmt(ty, f)?; plain.push_str(&format!("{:#}", ty)); } else { match *ty { clean::ResolvedPath { typarams: None, ref path, is_generic: false, .. } => { let last = path.segments.last().unwrap(); fmt::Display::fmt(&last.name, f)?; fmt::Display::fmt(&last.params, f)?; plain.push_str(&format!("{:#}{:#}", last.name, last.params)); } _ => unreachable!(), } } write!(f, " for ")?; plain.push_str(" for "); } fmt_type(&i.for_, f, use_absolute)?; plain.push_str(&format!("{:#}", i.for_)); fmt::Display::fmt(&WhereClause(&i.generics, plain.len() + 1), f)?; Ok(()) } impl fmt::Display for clean::Impl { fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { fmt_impl(self, f, true, false) } } // The difference from above is that trait is not hyperlinked. pub fn fmt_impl_for_trait_page(i: &clean::Impl, f: &mut fmt::Formatter, use_absolute: bool) -> fmt::Result { fmt_impl(i, f, false, use_absolute) } impl fmt::Display for clean::Arguments { fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { for (i, input) in self.values.iter().enumerate() { if !input.name.is_empty() { write!(f, "{}: ", input.name)?; } if f.alternate() { write!(f, "{:#}", input.type_)?; } else { write!(f, "{}", input.type_)?; } if i + 1 < self.values.len() { write!(f, ", ")?; } } Ok(()) } } impl fmt::Display for clean::FunctionRetTy { fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { match *self { clean::Return(clean::Tuple(ref tys)) if tys.is_empty() => Ok(()), clean::Return(ref ty) if f.alternate() => write!(f, " -> {:#}", ty), clean::Return(ref ty) => write!(f, " -> {}", ty), clean::DefaultReturn => Ok(()), } } } impl fmt::Display for clean::FnDecl { fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { if self.variadic { if f.alternate() { write!(f, "({args:#}, ...){arrow:#}", args = self.inputs, arrow = self.output) } else { write!(f, "({args}, ...){arrow}", args = self.inputs, arrow = self.output) } } else { if f.alternate() { write!(f, "({args:#}){arrow:#}", args = self.inputs, arrow = self.output) } else { write!(f, "({args}){arrow}", args = self.inputs, arrow = self.output) } } } } impl<'a> fmt::Display for Method<'a> { fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { let decl = self.0; let indent = self.1; let amp = if f.alternate() { "&" } else { "&" }; let mut args = String::new(); let mut args_plain = String::new(); for (i, input) in decl.inputs.values.iter().enumerate() { if let Some(selfty) = input.to_self() { match selfty { clean::SelfValue => { args.push_str("self"); args_plain.push_str("self"); } clean::SelfBorrowed(Some(ref lt), mtbl) => { args.push_str(&format!("{}{} {}self", amp, *lt, MutableSpace(mtbl))); args_plain.push_str(&format!("&{} {}self", *lt, MutableSpace(mtbl))); } clean::SelfBorrowed(None, mtbl) => { args.push_str(&format!("{}{}self", amp, MutableSpace(mtbl))); args_plain.push_str(&format!("&{}self", MutableSpace(mtbl))); } clean::SelfExplicit(ref typ) => { if f.alternate() { args.push_str(&format!("self: {:#}", *typ)); } else { args.push_str(&format!("self: {}", *typ)); } args_plain.push_str(&format!("self: {:#}", *typ)); } } } else { if i > 0 { args.push_str("
"); args_plain.push_str(" "); } if !input.name.is_empty() { args.push_str(&format!("{}: ", input.name)); args_plain.push_str(&format!("{}: ", input.name)); } if f.alternate() { args.push_str(&format!("{:#}", input.type_)); } else { args.push_str(&format!("{}", input.type_)); } args_plain.push_str(&format!("{:#}", input.type_)); } if i + 1 < decl.inputs.values.len() { args.push_str(","); args_plain.push_str(","); } } if decl.variadic { args.push_str(",
..."); args_plain.push_str(", ..."); } let arrow_plain = format!("{:#}", decl.output); let arrow = if f.alternate() { format!("{:#}", decl.output) } else { format!("{}", decl.output) }; let mut output: String; let plain: String; let pad = repeat(" ").take(indent).collect::(); if arrow.is_empty() { output = format!("({})", args); plain = format!("{}({})", pad, args_plain); } else { output = format!("({args})
{arrow}", args = args, arrow = arrow); plain = format!("{pad}({args}){arrow}", pad = pad, args = args_plain, arrow = arrow_plain); } if plain.len() > 80 { let pad = repeat(" ").take(indent).collect::(); let pad = format!("
{}", pad); output = output.replace("
", &pad); } else { output = output.replace("
", ""); } if f.alternate() { write!(f, "{}", output.replace("
", "\n")) } else { write!(f, "{}", output) } } } impl<'a> fmt::Display for VisSpace<'a> { fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { match *self.get() { Some(clean::Public) => write!(f, "pub "), Some(clean::Inherited) | None => Ok(()) } } } impl fmt::Display for UnsafetySpace { fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { match self.get() { hir::Unsafety::Unsafe => write!(f, "unsafe "), hir::Unsafety::Normal => Ok(()) } } } impl fmt::Display for ConstnessSpace { fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { match self.get() { hir::Constness::Const => write!(f, "const "), hir::Constness::NotConst => Ok(()) } } } impl fmt::Display for clean::Import { fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { match *self { clean::Import::Simple(ref name, ref src) => { if *name == src.path.last_name() { write!(f, "use {};", *src) } else { write!(f, "use {} as {};", *src, *name) } } clean::Import::Glob(ref src) => { write!(f, "use {}::*;", *src) } } } } impl fmt::Display for clean::ImportSource { fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { match self.did { Some(did) => resolved_path(f, did, &self.path, true, false), _ => { for (i, seg) in self.path.segments.iter().enumerate() { if i > 0 { write!(f, "::")? } write!(f, "{}", seg.name)?; } Ok(()) } } } } impl fmt::Display for clean::TypeBinding { fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { if f.alternate() { write!(f, "{}={:#}", self.name, self.ty) } else { write!(f, "{}={}", self.name, self.ty) } } } impl fmt::Display for MutableSpace { fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { match *self { MutableSpace(clean::Immutable) => Ok(()), MutableSpace(clean::Mutable) => write!(f, "mut "), } } } impl fmt::Display for RawMutableSpace { fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { match *self { RawMutableSpace(clean::Immutable) => write!(f, "const "), RawMutableSpace(clean::Mutable) => write!(f, "mut "), } } } impl fmt::Display for AbiSpace { fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { let quot = if f.alternate() { "\"" } else { """ }; match self.0 { Abi::Rust => Ok(()), Abi::C => write!(f, "extern "), abi => write!(f, "extern {0}{1}{0} ", quot, abi.name()), } } }