//! 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::cell::Cell;
use std::fmt;
use std::iter;
use rustc_attr::{ConstStability, StabilityLevel};
use rustc_data_structures::captures::Captures;
use rustc_data_structures::fx::FxHashSet;
use rustc_hir as hir;
use rustc_hir::def::DefKind;
use rustc_hir::def_id::DefId;
use rustc_middle::ty;
use rustc_middle::ty::DefIdTree;
use rustc_middle::ty::TyCtxt;
use rustc_span::def_id::CRATE_DEF_INDEX;
use rustc_span::{sym, Symbol};
use rustc_target::spec::abi::Abi;
use crate::clean::{
self, types::ExternalLocation, utils::find_nearest_parent_module, ExternalCrate, ItemId,
PrimitiveType,
};
use crate::formats::item_type::ItemType;
use crate::html::escape::Escape;
use crate::html::render::Context;
use super::url_parts_builder::UrlPartsBuilder;
crate trait Print {
fn print(self, buffer: &mut Buffer);
}
impl Print for F
where
F: FnOnce(&mut Buffer),
{
fn print(self, buffer: &mut Buffer) {
(self)(buffer)
}
}
impl Print for String {
fn print(self, buffer: &mut Buffer) {
buffer.write_str(&self);
}
}
impl Print for &'_ str {
fn print(self, buffer: &mut Buffer) {
buffer.write_str(self);
}
}
#[derive(Debug, Clone)]
crate struct Buffer {
for_html: bool,
buffer: String,
}
impl Buffer {
crate fn empty_from(v: &Buffer) -> Buffer {
Buffer { for_html: v.for_html, buffer: String::new() }
}
crate fn html() -> Buffer {
Buffer { for_html: true, buffer: String::new() }
}
crate fn new() -> Buffer {
Buffer { for_html: false, buffer: String::new() }
}
crate fn is_empty(&self) -> bool {
self.buffer.is_empty()
}
crate fn into_inner(self) -> String {
self.buffer
}
crate fn insert_str(&mut self, idx: usize, s: &str) {
self.buffer.insert_str(idx, s);
}
crate fn push_str(&mut self, s: &str) {
self.buffer.push_str(s);
}
crate fn push_buffer(&mut self, other: Buffer) {
self.buffer.push_str(&other.buffer);
}
// Intended for consumption by write! and writeln! (std::fmt) but without
// the fmt::Result return type imposed by fmt::Write (and avoiding the trait
// import).
crate fn write_str(&mut self, s: &str) {
self.buffer.push_str(s);
}
// Intended for consumption by write! and writeln! (std::fmt) but without
// the fmt::Result return type imposed by fmt::Write (and avoiding the trait
// import).
crate fn write_fmt(&mut self, v: fmt::Arguments<'_>) {
use fmt::Write;
self.buffer.write_fmt(v).unwrap();
}
crate fn to_display(mut self, t: T) -> String {
t.print(&mut self);
self.into_inner()
}
crate fn is_for_html(&self) -> bool {
self.for_html
}
crate fn reserve(&mut self, additional: usize) {
self.buffer.reserve(additional)
}
}
fn comma_sep(items: impl Iterator- ) -> impl fmt::Display {
display_fn(move |f| {
for (i, item) in items.enumerate() {
if i != 0 {
write!(f, ", ")?;
}
fmt::Display::fmt(&item, f)?;
}
Ok(())
})
}
crate fn print_generic_bounds<'a, 'tcx: 'a>(
bounds: &'a [clean::GenericBound],
cx: &'a Context<'tcx>,
) -> impl fmt::Display + 'a + Captures<'tcx> {
display_fn(move |f| {
let mut bounds_dup = FxHashSet::default();
for (i, bound) in bounds.iter().filter(|b| bounds_dup.insert(b.clone())).enumerate() {
if i > 0 {
f.write_str(" + ")?;
}
fmt::Display::fmt(&bound.print(cx), f)?;
}
Ok(())
})
}
impl clean::GenericParamDef {
crate fn print<'a, 'tcx: 'a>(
&'a self,
cx: &'a Context<'tcx>,
) -> impl fmt::Display + 'a + Captures<'tcx> {
display_fn(move |f| match &self.kind {
clean::GenericParamDefKind::Lifetime { outlives } => {
write!(f, "{}", self.name)?;
if !outlives.is_empty() {
f.write_str(": ")?;
for (i, lt) in outlives.iter().enumerate() {
if i != 0 {
f.write_str(" + ")?;
}
write!(f, "{}", lt.print())?;
}
}
Ok(())
}
clean::GenericParamDefKind::Type { bounds, default, .. } => {
f.write_str(self.name.as_str())?;
if !bounds.is_empty() {
if f.alternate() {
write!(f, ": {:#}", print_generic_bounds(bounds, cx))?;
} else {
write!(f, ": {}", print_generic_bounds(bounds, cx))?;
}
}
if let Some(ref ty) = default {
if f.alternate() {
write!(f, " = {:#}", ty.print(cx))?;
} else {
write!(f, " = {}", ty.print(cx))?;
}
}
Ok(())
}
clean::GenericParamDefKind::Const { ty, default, .. } => {
if f.alternate() {
write!(f, "const {}: {:#}", self.name, ty.print(cx))?;
} else {
write!(f, "const {}: {}", self.name, ty.print(cx))?;
}
if let Some(default) = default {
if f.alternate() {
write!(f, " = {:#}", default)?;
} else {
write!(f, " = {}", default)?;
}
}
Ok(())
}
})
}
}
impl clean::Generics {
crate fn print<'a, 'tcx: 'a>(
&'a self,
cx: &'a Context<'tcx>,
) -> impl fmt::Display + 'a + Captures<'tcx> {
display_fn(move |f| {
let mut real_params =
self.params.iter().filter(|p| !p.is_synthetic_type_param()).peekable();
if real_params.peek().is_none() {
return Ok(());
}
if f.alternate() {
write!(f, "<{:#}>", comma_sep(real_params.map(|g| g.print(cx))))
} else {
write!(f, "<{}>", comma_sep(real_params.map(|g| g.print(cx))))
}
})
}
}
/// * The Generics from which to emit a where-clause.
/// * The number of spaces to indent each line with.
/// * Whether the where-clause needs to add a comma and newline after the last bound.
crate fn print_where_clause<'a, 'tcx: 'a>(
gens: &'a clean::Generics,
cx: &'a Context<'tcx>,
indent: usize,
end_newline: bool,
) -> impl fmt::Display + 'a + Captures<'tcx> {
display_fn(move |f| {
if gens.where_predicates.is_empty() {
return Ok(());
}
let mut clause = String::new();
if f.alternate() {
clause.push_str(" where");
} else {
if end_newline {
clause.push_str(" where");
} else {
clause.push_str(" where");
}
}
for (i, pred) in gens.where_predicates.iter().enumerate() {
if f.alternate() {
clause.push(' ');
} else {
clause.push_str("
");
}
match pred {
clean::WherePredicate::BoundPredicate { ty, bounds, bound_params } => {
let bounds = bounds;
let for_prefix = match bound_params.len() {
0 => String::new(),
_ if f.alternate() => {
format!(
"for<{:#}> ",
comma_sep(bound_params.iter().map(|lt| lt.print()))
)
}
_ => format!(
"for<{}> ",
comma_sep(bound_params.iter().map(|lt| lt.print()))
),
};
if f.alternate() {
clause.push_str(&format!(
"{}{:#}: {:#}",
for_prefix,
ty.print(cx),
print_generic_bounds(bounds, cx)
));
} else {
clause.push_str(&format!(
"{}{}: {}",
for_prefix,
ty.print(cx),
print_generic_bounds(bounds, cx)
));
}
}
clean::WherePredicate::RegionPredicate { lifetime, bounds } => {
clause.push_str(&format!(
"{}: {}",
lifetime.print(),
bounds
.iter()
.map(|b| b.print(cx).to_string())
.collect::>()
.join(" + ")
));
}
clean::WherePredicate::EqPredicate { lhs, rhs } => {
if f.alternate() {
clause.push_str(&format!("{:#} == {:#}", lhs.print(cx), rhs.print(cx),));
} else {
clause.push_str(&format!("{} == {}", lhs.print(cx), rhs.print(cx),));
}
}
}
if i < gens.where_predicates.len() - 1 || end_newline {
clause.push(',');
}
}
if end_newline {
// add a space so stripping
tags and breaking spaces still renders properly
if f.alternate() {
clause.push(' ');
} else {
clause.push_str(" ");
}
}
if !f.alternate() {
clause.push_str("");
let padding = " ".repeat(indent + 4);
clause = clause.replace("
", &format!("
{}", padding));
clause.insert_str(0, &" ".repeat(indent.saturating_sub(1)));
if !end_newline {
clause.insert_str(0, "
");
}
}
write!(f, "{}", clause)
})
}
impl clean::Lifetime {
crate fn print(&self) -> impl fmt::Display + '_ {
self.0.as_str()
}
}
impl clean::Constant {
crate fn print(&self, tcx: TyCtxt<'_>) -> impl fmt::Display + '_ {
let expr = self.expr(tcx);
display_fn(
move |f| {
if f.alternate() { f.write_str(&expr) } else { write!(f, "{}", Escape(&expr)) }
},
)
}
}
impl clean::PolyTrait {
fn print<'a, 'tcx: 'a>(
&'a self,
cx: &'a Context<'tcx>,
) -> impl fmt::Display + 'a + Captures<'tcx> {
display_fn(move |f| {
if !self.generic_params.is_empty() {
if f.alternate() {
write!(
f,
"for<{:#}> ",
comma_sep(self.generic_params.iter().map(|g| g.print(cx)))
)?;
} else {
write!(
f,
"for<{}> ",
comma_sep(self.generic_params.iter().map(|g| g.print(cx)))
)?;
}
}
if f.alternate() {
write!(f, "{:#}", self.trait_.print(cx))
} else {
write!(f, "{}", self.trait_.print(cx))
}
})
}
}
impl clean::GenericBound {
crate fn print<'a, 'tcx: 'a>(
&'a self,
cx: &'a Context<'tcx>,
) -> impl fmt::Display + 'a + Captures<'tcx> {
display_fn(move |f| match self {
clean::GenericBound::Outlives(lt) => write!(f, "{}", lt.print()),
clean::GenericBound::TraitBound(ty, modifier) => {
let modifier_str = match modifier {
hir::TraitBoundModifier::None => "",
hir::TraitBoundModifier::Maybe => "?",
hir::TraitBoundModifier::MaybeConst => "~const",
};
if f.alternate() {
write!(f, "{}{:#}", modifier_str, ty.print(cx))
} else {
write!(f, "{}{}", modifier_str, ty.print(cx))
}
}
})
}
}
impl clean::GenericArgs {
fn print<'a, 'tcx: 'a>(
&'a self,
cx: &'a Context<'tcx>,
) -> impl fmt::Display + 'a + Captures<'tcx> {
display_fn(move |f| {
match self {
clean::GenericArgs::AngleBracketed { args, bindings } => {
if !args.is_empty() || !bindings.is_empty() {
if f.alternate() {
f.write_str("<")?;
} else {
f.write_str("<")?;
}
let mut comma = false;
for arg in args {
if comma {
f.write_str(", ")?;
}
comma = true;
if f.alternate() {
write!(f, "{:#}", arg.print(cx))?;
} else {
write!(f, "{}", arg.print(cx))?;
}
}
for binding in bindings {
if comma {
f.write_str(", ")?;
}
comma = true;
if f.alternate() {
write!(f, "{:#}", binding.print(cx))?;
} else {
write!(f, "{}", binding.print(cx))?;
}
}
if f.alternate() {
f.write_str(">")?;
} else {
f.write_str(">")?;
}
}
}
clean::GenericArgs::Parenthesized { inputs, 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.print(cx))?;
} else {
write!(f, "{}", ty.print(cx))?;
}
}
f.write_str(")")?;
if let Some(ref ty) = *output {
if f.alternate() {
write!(f, " -> {:#}", ty.print(cx))?;
} else {
write!(f, " -> {}", ty.print(cx))?;
}
}
}
}
Ok(())
})
}
}
// Possible errors when computing href link source for a `DefId`
crate enum HrefError {
/// This item is known to rustdoc, but from a crate that does not have documentation generated.
///
/// This can only happen for non-local items.
DocumentationNotBuilt,
/// This can only happen for non-local items when `--document-private-items` is not passed.
Private,
// Not in external cache, href link should be in same page
NotInExternalCache,
}
// This mostly works with sequences of symbols, but sometimes the first item
// comes from a string, and in that case we want to trim any trailing `/`.
// `syms` can be empty.
crate fn join_with_slash(first: Option<&str>, syms: &[Symbol]) -> String {
// 64 bytes covers 99.9%+ of cases.
let mut s = String::with_capacity(64);
if let Some(first) = first {
s.push_str(first.trim_end_matches('/'));
if !syms.is_empty() {
s.push('/');
}
}
if !syms.is_empty() {
s.push_str(&syms[0].as_str());
for sym in &syms[1..] {
s.push('/');
s.push_str(&sym.as_str());
}
}
s
}
// Panics if `syms` is empty.
crate fn join_with_double_colon(syms: &[Symbol]) -> String {
// 64 bytes covers 99.9%+ of cases.
let mut s = String::with_capacity(64);
s.push_str(&syms[0].as_str());
for sym in &syms[1..] {
s.push_str("::");
s.push_str(&sym.as_str());
}
s
}
crate fn href_with_root_path(
did: DefId,
cx: &Context<'_>,
root_path: Option<&str>,
) -> Result<(String, ItemType, Vec), HrefError> {
let tcx = cx.tcx();
let def_kind = tcx.def_kind(did);
let did = match def_kind {
DefKind::AssocTy | DefKind::AssocFn | DefKind::AssocConst | DefKind::Variant => {
// documented on their parent's page
tcx.parent(did).unwrap()
}
_ => did,
};
let cache = cx.cache();
let relative_to = &cx.current;
fn to_module_fqp(shortty: ItemType, fqp: &[Symbol]) -> &[Symbol] {
if shortty == ItemType::Module { fqp } else { &fqp[..fqp.len() - 1] }
}
if !did.is_local()
&& !cache.access_levels.is_public(did)
&& !cache.document_private
&& !cache.primitive_locations.values().any(|&id| id == did)
{
return Err(HrefError::Private);
}
let mut is_remote = false;
let (fqp, shortty, mut url_parts) = match cache.paths.get(&did) {
Some(&(ref fqp, shortty)) => (fqp, shortty, {
let module_fqp = to_module_fqp(shortty, fqp.as_slice());
debug!(?fqp, ?shortty, ?module_fqp);
href_relative_parts(module_fqp, relative_to).collect()
}),
None => {
if let Some(&(ref fqp, shortty)) = cache.external_paths.get(&did) {
let module_fqp = to_module_fqp(shortty, fqp);
(
fqp,
shortty,
match cache.extern_locations[&did.krate] {
ExternalLocation::Remote(ref s) => {
is_remote = true;
let s = s.trim_end_matches('/');
let mut builder = UrlPartsBuilder::singleton(s);
builder.extend(module_fqp.iter().copied());
builder
}
ExternalLocation::Local => {
href_relative_parts(module_fqp, relative_to).collect()
}
ExternalLocation::Unknown => return Err(HrefError::DocumentationNotBuilt),
},
)
} else {
return Err(HrefError::NotInExternalCache);
}
}
};
if !is_remote {
if let Some(root_path) = root_path {
let root = root_path.trim_end_matches('/');
url_parts.push_front(root);
}
}
debug!(?url_parts);
match shortty {
ItemType::Module => {
url_parts.push("index.html");
}
_ => {
let prefix = shortty.as_str();
let last = fqp.last().unwrap();
url_parts.push_fmt(format_args!("{}.{}.html", prefix, last));
}
}
Ok((url_parts.finish(), shortty, fqp.to_vec()))
}
crate fn href(did: DefId, cx: &Context<'_>) -> Result<(String, ItemType, Vec), HrefError> {
href_with_root_path(did, cx, None)
}
/// Both paths should only be modules.
/// This is because modules get their own directories; that is, `std::vec` and `std::vec::Vec` will
/// both need `../iter/trait.Iterator.html` to get at the iterator trait.
crate fn href_relative_parts<'fqp>(
fqp: &'fqp [Symbol],
relative_to_fqp: &[Symbol],
) -> Box + 'fqp> {
for (i, (f, r)) in fqp.iter().zip(relative_to_fqp.iter()).enumerate() {
// e.g. linking to std::iter from std::vec (`dissimilar_part_count` will be 1)
if f != r {
let dissimilar_part_count = relative_to_fqp.len() - i;
let fqp_module = &fqp[i..fqp.len()];
return box iter::repeat(sym::dotdot)
.take(dissimilar_part_count)
.chain(fqp_module.iter().copied());
}
}
// e.g. linking to std::sync::atomic from std::sync
if relative_to_fqp.len() < fqp.len() {
box fqp[relative_to_fqp.len()..fqp.len()].iter().copied()
// e.g. linking to std::sync from std::sync::atomic
} else if fqp.len() < relative_to_fqp.len() {
let dissimilar_part_count = relative_to_fqp.len() - fqp.len();
box iter::repeat(sym::dotdot).take(dissimilar_part_count)
// linking to the same module
} else {
box iter::empty()
}
}
/// Used to render a [`clean::Path`].
fn resolved_path<'cx>(
w: &mut fmt::Formatter<'_>,
did: DefId,
path: &clean::Path,
print_all: bool,
use_absolute: bool,
cx: &'cx Context<'_>,
) -> fmt::Result {
let last = path.segments.last().unwrap();
if print_all {
for seg in &path.segments[..path.segments.len() - 1] {
write!(w, "{}::", seg.name)?;
}
}
if w.alternate() {
write!(w, "{}{:#}", &last.name, last.args.print(cx))?;
} else {
let path = if use_absolute {
if let Ok((_, _, fqp)) = href(did, cx) {
format!(
"{}::{}",
join_with_double_colon(&fqp[..fqp.len() - 1]),
anchor(did, *fqp.last().unwrap(), cx)
)
} else {
last.name.to_string()
}
} else {
anchor(did, last.name, cx).to_string()
};
write!(w, "{}{}", path, last.args.print(cx))?;
}
Ok(())
}
fn primitive_link(
f: &mut fmt::Formatter<'_>,
prim: clean::PrimitiveType,
name: &str,
cx: &Context<'_>,
) -> fmt::Result {
let m = &cx.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 = cx.current.len();
let len = if len == 0 { 0 } else { len - 1 };
write!(
f,
"",
"../".repeat(len),
prim.as_sym()
)?;
needs_termination = true;
}
Some(&def_id) => {
let loc = match m.extern_locations[&def_id.krate] {
ExternalLocation::Remote(ref s) => {
let cname_sym = ExternalCrate { crate_num: def_id.krate }.name(cx.tcx());
let builder: UrlPartsBuilder =
[s.as_str().trim_end_matches('/'), cname_sym.as_str()]
.into_iter()
.collect();
Some(builder)
}
ExternalLocation::Local => {
let cname_sym = ExternalCrate { crate_num: def_id.krate }.name(cx.tcx());
Some(if cx.current.first() == Some(&cname_sym) {
iter::repeat(sym::dotdot).take(cx.current.len() - 1).collect()
} else {
iter::repeat(sym::dotdot)
.take(cx.current.len())
.chain(iter::once(cname_sym))
.collect()
})
}
ExternalLocation::Unknown => None,
};
if let Some(mut loc) = loc {
loc.push_fmt(format_args!("primitive.{}.html", prim.as_sym()));
write!(f, "", loc.finish())?;
needs_termination = true;
}
}
None => {}
}
}
write!(f, "{}", name)?;
if needs_termination {
write!(f, "")?;
}
Ok(())
}
/// Helper to render type parameters
fn tybounds<'a, 'tcx: 'a>(
bounds: &'a [clean::PolyTrait],
lt: &'a Option,
cx: &'a Context<'tcx>,
) -> impl fmt::Display + 'a + Captures<'tcx> {
display_fn(move |f| {
for (i, bound) in bounds.iter().enumerate() {
if i > 0 {
write!(f, " + ")?;
}
fmt::Display::fmt(&bound.print(cx), f)?;
}
if let Some(lt) = lt {
write!(f, " + ")?;
fmt::Display::fmt(<.print(), f)?;
}
Ok(())
})
}
crate fn anchor<'a, 'cx: 'a>(
did: DefId,
text: Symbol,
cx: &'cx Context<'_>,
) -> impl fmt::Display + 'a {
let parts = href(did, cx);
display_fn(move |f| {
if let Ok((url, short_ty, fqp)) = parts {
write!(
f,
r#"{}"#,
short_ty,
url,
short_ty,
join_with_double_colon(&fqp),
&*text.as_str()
)
} else {
write!(f, "{}", text)
}
})
}
fn fmt_type<'cx>(
t: &clean::Type,
f: &mut fmt::Formatter<'_>,
use_absolute: bool,
cx: &'cx Context<'_>,
) -> fmt::Result {
trace!("fmt_type(t = {:?})", t);
match *t {
clean::Generic(name) => write!(f, "{}", name),
clean::Type::Path { ref path } => {
// Paths like `T::Output` and `Self::Output` should be rendered with all segments.
let did = path.def_id();
resolved_path(f, did, path, path.is_assoc_ty(), use_absolute, cx)
}
clean::DynTrait(ref bounds, ref lt) => {
f.write_str("dyn ")?;
fmt::Display::fmt(&tybounds(bounds, lt, cx), f)
}
clean::Infer => write!(f, "_"),
clean::Primitive(clean::PrimitiveType::Never) => {
primitive_link(f, PrimitiveType::Never, "!", cx)
}
clean::Primitive(prim) => primitive_link(f, prim, prim.as_sym().as_str(), cx),
clean::BareFunction(ref decl) => {
if f.alternate() {
write!(
f,
"{:#}{}{:#}fn{:#}",
decl.print_hrtb_with_space(cx),
decl.unsafety.print_with_space(),
print_abi_with_space(decl.abi),
decl.decl.print(cx),
)
} else {
write!(
f,
"{}{}{}",
decl.print_hrtb_with_space(cx),
decl.unsafety.print_with_space(),
print_abi_with_space(decl.abi)
)?;
primitive_link(f, PrimitiveType::Fn, "fn", cx)?;
write!(f, "{}", decl.decl.print(cx))
}
}
clean::Tuple(ref typs) => {
match &typs[..] {
&[] => primitive_link(f, PrimitiveType::Unit, "()", cx),
&[ref one] => {
primitive_link(f, PrimitiveType::Tuple, "(", cx)?;
// Carry `f.alternate()` into this display w/o branching manually.
fmt::Display::fmt(&one.print(cx), f)?;
primitive_link(f, PrimitiveType::Tuple, ",)", cx)
}
many => {
primitive_link(f, PrimitiveType::Tuple, "(", cx)?;
for (i, item) in many.iter().enumerate() {
if i != 0 {
write!(f, ", ")?;
}
fmt::Display::fmt(&item.print(cx), f)?;
}
primitive_link(f, PrimitiveType::Tuple, ")", cx)
}
}
}
clean::Slice(ref t) => {
primitive_link(f, PrimitiveType::Slice, "[", cx)?;
fmt::Display::fmt(&t.print(cx), f)?;
primitive_link(f, PrimitiveType::Slice, "]", cx)
}
clean::Array(ref t, ref n) => {
primitive_link(f, PrimitiveType::Array, "[", cx)?;
fmt::Display::fmt(&t.print(cx), f)?;
if f.alternate() {
primitive_link(f, PrimitiveType::Array, &format!("; {}]", n), cx)
} else {
primitive_link(f, PrimitiveType::Array, &format!("; {}]", Escape(n)), cx)
}
}
clean::RawPointer(m, ref t) => {
let m = match m {
hir::Mutability::Mut => "mut",
hir::Mutability::Not => "const",
};
if matches!(**t, clean::Generic(_)) || t.is_assoc_ty() {
let text = if f.alternate() {
format!("*{} {:#}", m, t.print(cx))
} else {
format!("*{} {}", m, t.print(cx))
};
primitive_link(f, clean::PrimitiveType::RawPointer, &text, cx)
} else {
primitive_link(f, clean::PrimitiveType::RawPointer, &format!("*{} ", m), cx)?;
fmt::Display::fmt(&t.print(cx), f)
}
}
clean::BorrowedRef { lifetime: ref l, mutability, type_: ref ty } => {
let lt = match l {
Some(l) => format!("{} ", l.print()),
_ => String::new(),
};
let m = mutability.print_with_space();
let amp = if f.alternate() { "&".to_string() } else { "&".to_string() };
match **ty {
clean::Slice(ref bt) => {
// `BorrowedRef{ ... Slice(T) }` is `&[T]`
match **bt {
clean::Generic(_) => {
if f.alternate() {
primitive_link(
f,
PrimitiveType::Slice,
&format!("{}{}{}[{:#}]", amp, lt, m, bt.print(cx)),
cx,
)
} else {
primitive_link(
f,
PrimitiveType::Slice,
&format!("{}{}{}[{}]", amp, lt, m, bt.print(cx)),
cx,
)
}
}
_ => {
primitive_link(
f,
PrimitiveType::Slice,
&format!("{}{}{}[", amp, lt, m),
cx,
)?;
if f.alternate() {
write!(f, "{:#}", bt.print(cx))?;
} else {
write!(f, "{}", bt.print(cx))?;
}
primitive_link(f, PrimitiveType::Slice, "]", cx)
}
}
}
clean::DynTrait(ref bounds, ref trait_lt)
if bounds.len() > 1 || trait_lt.is_some() =>
{
write!(f, "{}{}{}(", amp, lt, m)?;
fmt_type(ty, f, use_absolute, cx)?;
write!(f, ")")
}
clean::Generic(..) => {
primitive_link(
f,
PrimitiveType::Reference,
&format!("{}{}{}", amp, lt, m),
cx,
)?;
fmt_type(ty, f, use_absolute, cx)
}
_ => {
write!(f, "{}{}{}", amp, lt, m)?;
fmt_type(ty, f, use_absolute, cx)
}
}
}
clean::ImplTrait(ref bounds) => {
if f.alternate() {
write!(f, "impl {:#}", print_generic_bounds(bounds, cx))
} else {
write!(f, "impl {}", print_generic_bounds(bounds, cx))
}
}
clean::QPath { ref name, ref self_type, ref trait_, ref self_def_id } => {
let should_show_cast = !trait_.segments.is_empty()
&& self_def_id
.zip(Some(trait_.def_id()))
.map_or(!self_type.is_self_type(), |(id, trait_)| id != trait_);
if f.alternate() {
if should_show_cast {
write!(f, "<{:#} as {:#}>::", self_type.print(cx), trait_.print(cx))?
} else {
write!(f, "{:#}::", self_type.print(cx))?
}
} else {
if should_show_cast {
write!(f, "<{} as {}>::", self_type.print(cx), trait_.print(cx))?
} else {
write!(f, "{}::", self_type.print(cx))?
}
};
// 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).
match href(trait_.def_id(), cx) {
Ok((ref url, _, ref path)) if !f.alternate() => {
write!(
f,
"{name}",
url = url,
shortty = ItemType::AssocType,
name = name,
path = join_with_double_colon(path),
)?;
}
_ => write!(f, "{}", name)?,
}
Ok(())
}
}
}
impl clean::Type {
crate fn print<'b, 'a: 'b, 'tcx: 'a>(
&'a self,
cx: &'a Context<'tcx>,
) -> impl fmt::Display + 'b + Captures<'tcx> {
display_fn(move |f| fmt_type(self, f, false, cx))
}
}
impl clean::Path {
crate fn print<'b, 'a: 'b, 'tcx: 'a>(
&'a self,
cx: &'a Context<'tcx>,
) -> impl fmt::Display + 'b + Captures<'tcx> {
display_fn(move |f| resolved_path(f, self.def_id(), self, false, false, cx))
}
}
impl clean::Impl {
crate fn print<'a, 'tcx: 'a>(
&'a self,
use_absolute: bool,
cx: &'a Context<'tcx>,
) -> impl fmt::Display + 'a + Captures<'tcx> {
display_fn(move |f| {
if f.alternate() {
write!(f, "impl{:#} ", self.generics.print(cx))?;
} else {
write!(f, "impl{} ", self.generics.print(cx))?;
}
if let Some(ref ty) = self.trait_ {
match self.polarity {
ty::ImplPolarity::Positive | ty::ImplPolarity::Reservation => {}
ty::ImplPolarity::Negative => write!(f, "!")?,
}
fmt::Display::fmt(&ty.print(cx), f)?;
write!(f, " for ")?;
}
if let Some(ref ty) = self.kind.as_blanket_ty() {
fmt_type(ty, f, use_absolute, cx)?;
} else {
fmt_type(&self.for_, f, use_absolute, cx)?;
}
fmt::Display::fmt(&print_where_clause(&self.generics, cx, 0, true), f)?;
Ok(())
})
}
}
impl clean::Arguments {
crate fn print<'a, 'tcx: 'a>(
&'a self,
cx: &'a Context<'tcx>,
) -> impl fmt::Display + 'a + Captures<'tcx> {
display_fn(move |f| {
for (i, input) in self.values.iter().enumerate() {
if !input.name.is_empty() {
write!(f, "{}: ", input.name)?;
}
if f.alternate() {
write!(f, "{:#}", input.type_.print(cx))?;
} else {
write!(f, "{}", input.type_.print(cx))?;
}
if i + 1 < self.values.len() {
write!(f, ", ")?;
}
}
Ok(())
})
}
}
impl clean::FnRetTy {
crate fn print<'a, 'tcx: 'a>(
&'a self,
cx: &'a Context<'tcx>,
) -> impl fmt::Display + 'a + Captures<'tcx> {
display_fn(move |f| match self {
clean::Return(clean::Tuple(tys)) if tys.is_empty() => Ok(()),
clean::Return(ty) if f.alternate() => {
write!(f, " -> {:#}", ty.print(cx))
}
clean::Return(ty) => write!(f, " -> {}", ty.print(cx)),
clean::DefaultReturn => Ok(()),
})
}
}
impl clean::BareFunctionDecl {
fn print_hrtb_with_space<'a, 'tcx: 'a>(
&'a self,
cx: &'a Context<'tcx>,
) -> impl fmt::Display + 'a + Captures<'tcx> {
display_fn(move |f| {
if !self.generic_params.is_empty() {
write!(
f,
"for<{}> ",
comma_sep(self.generic_params.iter().map(|g| g.print(cx)))
)
} else {
Ok(())
}
})
}
}
impl clean::FnDecl {
crate fn print<'b, 'a: 'b, 'tcx: 'a>(
&'a self,
cx: &'a Context<'tcx>,
) -> impl fmt::Display + 'b + Captures<'tcx> {
display_fn(move |f| {
let ellipsis = if self.c_variadic { ", ..." } else { "" };
if f.alternate() {
write!(
f,
"({args:#}{ellipsis}){arrow:#}",
args = self.inputs.print(cx),
ellipsis = ellipsis,
arrow = self.output.print(cx)
)
} else {
write!(
f,
"({args}{ellipsis}){arrow}",
args = self.inputs.print(cx),
ellipsis = ellipsis,
arrow = self.output.print(cx)
)
}
})
}
/// * `header_len`: The length of the function header and name. In other words, the number of
/// characters in the function declaration up to but not including the parentheses.
///
Used to determine line-wrapping.
/// * `indent`: The number of spaces to indent each successive line with, if line-wrapping is
/// necessary.
/// * `asyncness`: Whether the function is async or not.
crate fn full_print<'a, 'tcx: 'a>(
&'a self,
header_len: usize,
indent: usize,
asyncness: hir::IsAsync,
cx: &'a Context<'tcx>,
) -> impl fmt::Display + 'a + Captures<'tcx> {
display_fn(move |f| self.inner_full_print(header_len, indent, asyncness, f, cx))
}
fn inner_full_print(
&self,
header_len: usize,
indent: usize,
asyncness: hir::IsAsync,
f: &mut fmt::Formatter<'_>,
cx: &Context<'_>,
) -> fmt::Result {
let amp = if f.alternate() { "&" } else { "&" };
let mut args = String::new();
let mut args_plain = String::new();
for (i, input) in self.inputs.values.iter().enumerate() {
if i == 0 {
args.push_str("
");
}
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.print(),
mtbl.print_with_space()
));
args_plain.push_str(&format!(
"&{} {}self",
lt.print(),
mtbl.print_with_space()
));
}
clean::SelfBorrowed(None, mtbl) => {
args.push_str(&format!("{}{}self", amp, mtbl.print_with_space()));
args_plain.push_str(&format!("&{}self", mtbl.print_with_space()));
}
clean::SelfExplicit(ref typ) => {
if f.alternate() {
args.push_str(&format!("self: {:#}", typ.print(cx)));
} else {
args.push_str(&format!("self: {}", typ.print(cx)));
}
args_plain.push_str(&format!("self: {:#}", typ.print(cx)));
}
}
} else {
if i > 0 {
args.push_str("
");
args_plain.push(' ');
}
if input.is_const {
args.push_str("const ");
args_plain.push_str("const ");
}
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_.print(cx)));
} else {
args.push_str(&input.type_.print(cx).to_string());
}
args_plain.push_str(&format!("{:#}", input.type_.print(cx)));
}
if i + 1 < self.inputs.values.len() {
args.push(',');
args_plain.push(',');
}
}
let mut args_plain = format!("({})", args_plain);
if self.c_variadic {
args.push_str(",
...");
args_plain.push_str(", ...");
}
let arrow_plain;
let arrow = if let hir::IsAsync::Async = asyncness {
let output = self.sugared_async_return_type();
arrow_plain = format!("{:#}", output.print(cx));
if f.alternate() { arrow_plain.clone() } else { format!("{}", output.print(cx)) }
} else {
arrow_plain = format!("{:#}", self.output.print(cx));
if f.alternate() { arrow_plain.clone() } else { format!("{}", self.output.print(cx)) }
};
let declaration_len = header_len + args_plain.len() + arrow_plain.len();
let output = if declaration_len > 80 {
let full_pad = format!("
{}", " ".repeat(indent + 4));
let close_pad = format!("
{}", " ".repeat(indent));
format!(
"({args}{close}){arrow}",
args = args.replace("
", &full_pad),
close = close_pad,
arrow = arrow
)
} else {
format!("({args}){arrow}", args = args.replace("
", ""), arrow = arrow)
};
if f.alternate() {
write!(f, "{}", output.replace("
", "\n"))
} else {
write!(f, "{}", output)
}
}
}
impl clean::Visibility {
crate fn print_with_space<'a, 'tcx: 'a>(
self,
item_did: ItemId,
cx: &'a Context<'tcx>,
) -> impl fmt::Display + 'a + Captures<'tcx> {
let to_print = match self {
clean::Public => "pub ".to_owned(),
clean::Inherited => String::new(),
clean::Visibility::Restricted(vis_did) => {
// FIXME(camelid): This may not work correctly if `item_did` is a module.
// However, rustdoc currently never displays a module's
// visibility, so it shouldn't matter.
let parent_module = find_nearest_parent_module(cx.tcx(), item_did.expect_def_id());
if vis_did.index == CRATE_DEF_INDEX {
"pub(crate) ".to_owned()
} else if parent_module == Some(vis_did) {
// `pub(in foo)` where `foo` is the parent module
// is the same as no visibility modifier
String::new()
} else if parent_module
.map(|parent| find_nearest_parent_module(cx.tcx(), parent))
.flatten()
== Some(vis_did)
{
"pub(super) ".to_owned()
} else {
let path = cx.tcx().def_path(vis_did);
debug!("path={:?}", path);
// modified from `resolved_path()` to work with `DefPathData`
let last_name = path.data.last().unwrap().data.get_opt_name().unwrap();
let anchor = anchor(vis_did, last_name, cx).to_string();
let mut s = "pub(in ".to_owned();
for seg in &path.data[..path.data.len() - 1] {
s.push_str(&format!("{}::", seg.data.get_opt_name().unwrap()));
}
s.push_str(&format!("{}) ", anchor));
s
}
}
};
display_fn(move |f| f.write_str(&to_print))
}
/// This function is the same as print_with_space, except that it renders no links.
/// It's used for macros' rendered source view, which is syntax highlighted and cannot have
/// any HTML in it.
crate fn to_src_with_space<'a, 'tcx: 'a>(
self,
tcx: TyCtxt<'tcx>,
item_did: DefId,
) -> impl fmt::Display + 'a + Captures<'tcx> {
let to_print = match self {
clean::Public => "pub ".to_owned(),
clean::Inherited => String::new(),
clean::Visibility::Restricted(vis_did) => {
// FIXME(camelid): This may not work correctly if `item_did` is a module.
// However, rustdoc currently never displays a module's
// visibility, so it shouldn't matter.
let parent_module = find_nearest_parent_module(tcx, item_did);
if vis_did.index == CRATE_DEF_INDEX {
"pub(crate) ".to_owned()
} else if parent_module == Some(vis_did) {
// `pub(in foo)` where `foo` is the parent module
// is the same as no visibility modifier
String::new()
} else if parent_module
.map(|parent| find_nearest_parent_module(tcx, parent))
.flatten()
== Some(vis_did)
{
"pub(super) ".to_owned()
} else {
format!("pub(in {}) ", tcx.def_path_str(vis_did))
}
}
};
display_fn(move |f| f.write_str(&to_print))
}
}
crate trait PrintWithSpace {
fn print_with_space(&self) -> &str;
}
impl PrintWithSpace for hir::Unsafety {
fn print_with_space(&self) -> &str {
match self {
hir::Unsafety::Unsafe => "unsafe ",
hir::Unsafety::Normal => "",
}
}
}
impl PrintWithSpace for hir::IsAsync {
fn print_with_space(&self) -> &str {
match self {
hir::IsAsync::Async => "async ",
hir::IsAsync::NotAsync => "",
}
}
}
impl PrintWithSpace for hir::Mutability {
fn print_with_space(&self) -> &str {
match self {
hir::Mutability::Not => "",
hir::Mutability::Mut => "mut ",
}
}
}
crate fn print_constness_with_space(c: &hir::Constness, s: Option) -> &'static str {
match (c, s) {
// const stable or when feature(staged_api) is not set
(
hir::Constness::Const,
Some(ConstStability { level: StabilityLevel::Stable { .. }, .. }),
)
| (hir::Constness::Const, None) => "const ",
// const unstable or not const
_ => "",
}
}
impl clean::Import {
crate fn print<'a, 'tcx: 'a>(
&'a self,
cx: &'a Context<'tcx>,
) -> impl fmt::Display + 'a + Captures<'tcx> {
display_fn(move |f| match self.kind {
clean::ImportKind::Simple(name) => {
if name == self.source.path.last() {
write!(f, "use {};", self.source.print(cx))
} else {
write!(f, "use {} as {};", self.source.print(cx), name)
}
}
clean::ImportKind::Glob => {
if self.source.path.segments.is_empty() {
write!(f, "use *;")
} else {
write!(f, "use {}::*;", self.source.print(cx))
}
}
})
}
}
impl clean::ImportSource {
crate fn print<'a, 'tcx: 'a>(
&'a self,
cx: &'a Context<'tcx>,
) -> impl fmt::Display + 'a + Captures<'tcx> {
display_fn(move |f| match self.did {
Some(did) => resolved_path(f, did, &self.path, true, false, cx),
_ => {
for seg in &self.path.segments[..self.path.segments.len() - 1] {
write!(f, "{}::", seg.name)?;
}
let name = self.path.last();
if let hir::def::Res::PrimTy(p) = self.path.res {
primitive_link(f, PrimitiveType::from(p), name.as_str(), cx)?;
} else {
write!(f, "{}", name)?;
}
Ok(())
}
})
}
}
impl clean::TypeBinding {
crate fn print<'a, 'tcx: 'a>(
&'a self,
cx: &'a Context<'tcx>,
) -> impl fmt::Display + 'a + Captures<'tcx> {
display_fn(move |f| {
f.write_str(self.name.as_str())?;
match self.kind {
clean::TypeBindingKind::Equality { ref ty } => {
if f.alternate() {
write!(f, " = {:#}", ty.print(cx))?;
} else {
write!(f, " = {}", ty.print(cx))?;
}
}
clean::TypeBindingKind::Constraint { ref bounds } => {
if !bounds.is_empty() {
if f.alternate() {
write!(f, ": {:#}", print_generic_bounds(bounds, cx))?;
} else {
write!(f, ": {}", print_generic_bounds(bounds, cx))?;
}
}
}
}
Ok(())
})
}
}
crate fn print_abi_with_space(abi: Abi) -> impl fmt::Display {
display_fn(move |f| {
let quot = if f.alternate() { "\"" } else { """ };
match abi {
Abi::Rust => Ok(()),
abi => write!(f, "extern {0}{1}{0} ", quot, abi.name()),
}
})
}
crate fn print_default_space<'a>(v: bool) -> &'a str {
if v { "default " } else { "" }
}
impl clean::GenericArg {
crate fn print<'a, 'tcx: 'a>(
&'a self,
cx: &'a Context<'tcx>,
) -> impl fmt::Display + 'a + Captures<'tcx> {
display_fn(move |f| match self {
clean::GenericArg::Lifetime(lt) => fmt::Display::fmt(<.print(), f),
clean::GenericArg::Type(ty) => fmt::Display::fmt(&ty.print(cx), f),
clean::GenericArg::Const(ct) => fmt::Display::fmt(&ct.print(cx.tcx()), f),
clean::GenericArg::Infer => fmt::Display::fmt("_", f),
})
}
}
crate fn display_fn(f: impl FnOnce(&mut fmt::Formatter<'_>) -> fmt::Result) -> impl fmt::Display {
struct WithFormatter(Cell>);
impl fmt::Display for WithFormatter
where
F: FnOnce(&mut fmt::Formatter<'_>) -> fmt::Result,
{
fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
(self.0.take()).unwrap()(f)
}
}
WithFormatter(Cell::new(Some(f)))
}