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rust / rust / refs/heads/beta / . / src / librustdoc / html / format.rs
blob: 493fdc6fb1b330947a52f6caeb75375d3d34e9a4 [file] [log] [blame]
//! HTML formatting module
//!
//! This module contains a large number of `Display` implementations for
//! various types in `rustdoc::clean`.
//!
//! These implementations all emit HTML. As an internal implementation detail,
//! some of them support an alternate format that emits text, but that should
//! not be used external to this module.
use std::cmp::Ordering;
use std::fmt::{self, Display, Write};
use std::iter::{self, once};
use std::slice;
use itertools::{Either, Itertools};
use rustc_abi::ExternAbi;
use rustc_ast::join_path_syms;
use rustc_data_structures::fx::FxHashSet;
use rustc_hir as hir;
use rustc_hir::def::DefKind;
use rustc_hir::def_id::{DefId, LOCAL_CRATE};
use rustc_hir::{ConstStability, StabilityLevel, StableSince};
use rustc_metadata::creader::{CStore, LoadedMacro};
use rustc_middle::ty::{self, TyCtxt, TypingMode};
use rustc_span::symbol::kw;
use rustc_span::{Symbol, sym};
use tracing::{debug, trace};
use super::url_parts_builder::UrlPartsBuilder;
use crate::clean::types::ExternalLocation;
use crate::clean::utils::find_nearest_parent_module;
use crate::clean::{self, ExternalCrate, PrimitiveType};
use crate::display::{Joined as _, MaybeDisplay as _};
use crate::formats::cache::Cache;
use crate::formats::item_type::ItemType;
use crate::html::escape::{Escape, EscapeBodyText};
use crate::html::render::Context;
use crate::passes::collect_intra_doc_links::UrlFragment;
pub(crate) fn write_str(s: &mut String, f: fmt::Arguments<'_>) {
s.write_fmt(f).unwrap();
}
pub(crate) fn print_generic_bounds(
bounds: &[clean::GenericBound],
cx: &Context<'_>,
) -> impl Display {
fmt::from_fn(move |f| {
let mut bounds_dup = FxHashSet::default();
bounds
.iter()
.filter(move |b| bounds_dup.insert(*b))
.map(|bound| bound.print(cx))
.joined(" + ", f)
})
}
impl clean::GenericParamDef {
pub(crate) fn print(&self, cx: &Context<'_>) -> impl Display {
fmt::from_fn(move |f| match &self.kind {
clean::GenericParamDefKind::Lifetime { outlives } => {
write!(f, "{}", self.name)?;
if !outlives.is_empty() {
f.write_str(": ")?;
outlives.iter().map(|lt| lt.print()).joined(" + ", f)?;
}
Ok(())
}
clean::GenericParamDefKind::Type { bounds, default, .. } => {
f.write_str(self.name.as_str())?;
if !bounds.is_empty() {
f.write_str(": ")?;
print_generic_bounds(bounds, cx).fmt(f)?;
}
if let Some(ty) = default {
f.write_str(" = ")?;
ty.print(cx).fmt(f)?;
}
Ok(())
}
clean::GenericParamDefKind::Const { ty, default, .. } => {
write!(f, "const {}: ", self.name)?;
ty.print(cx).fmt(f)?;
if let Some(default) = default {
f.write_str(" = ")?;
if f.alternate() {
write!(f, "{default}")?;
} else {
write!(f, "{}", Escape(default))?;
}
}
Ok(())
}
})
}
}
impl clean::Generics {
pub(crate) fn print(&self, cx: &Context<'_>) -> impl Display {
fmt::from_fn(move |f| {
let mut real_params = self.params.iter().filter(|p| !p.is_synthetic_param()).peekable();
if real_params.peek().is_none() {
return Ok(());
}
let real_params =
fmt::from_fn(|f| real_params.clone().map(|g| g.print(cx)).joined(", ", f));
if f.alternate() {
write!(f, "<{real_params:#}>")
} else {
write!(f, "&lt;{real_params}&gt;")
}
})
}
}
#[derive(Clone, Copy, PartialEq, Eq)]
pub(crate) enum Ending {
Newline,
NoNewline,
}
fn print_where_predicate(predicate: &clean::WherePredicate, cx: &Context<'_>) -> impl Display {
fmt::from_fn(move |f| {
match predicate {
clean::WherePredicate::BoundPredicate { ty, bounds, bound_params } => {
print_higher_ranked_params_with_space(bound_params, cx, "for").fmt(f)?;
ty.print(cx).fmt(f)?;
f.write_str(":")?;
if !bounds.is_empty() {
f.write_str(" ")?;
print_generic_bounds(bounds, cx).fmt(f)?;
}
Ok(())
}
clean::WherePredicate::RegionPredicate { lifetime, bounds } => {
// We don't need to check `alternate` since we can be certain that neither
// the lifetime nor the bounds contain any characters which need escaping.
write!(f, "{}:", lifetime.print())?;
if !bounds.is_empty() {
write!(f, " {}", print_generic_bounds(bounds, cx))?;
}
Ok(())
}
clean::WherePredicate::EqPredicate { lhs, rhs } => {
if f.alternate() {
write!(f, "{:#} == {:#}", lhs.print(cx), rhs.print(cx))
} else {
write!(f, "{} == {}", lhs.print(cx), rhs.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.
pub(crate) fn print_where_clause(
gens: &clean::Generics,
cx: &Context<'_>,
indent: usize,
ending: Ending,
) -> Option<impl Display> {
if gens.where_predicates.is_empty() {
return None;
}
Some(fmt::from_fn(move |f| {
let where_preds = fmt::from_fn(|f| {
gens.where_predicates
.iter()
.map(|predicate| {
fmt::from_fn(|f| {
if f.alternate() {
f.write_str(" ")?;
} else {
f.write_str("\n")?;
}
print_where_predicate(predicate, cx).fmt(f)
})
})
.joined(",", f)
});
let clause = if f.alternate() {
if ending == Ending::Newline {
format!(" where{where_preds},")
} else {
format!(" where{where_preds}")
}
} else {
let mut br_with_padding = String::with_capacity(6 * indent + 28);
br_with_padding.push('\n');
let where_indent = 3;
let padding_amount = if ending == Ending::Newline {
indent + 4
} else if indent == 0 {
4
} else {
indent + where_indent + "where ".len()
};
for _ in 0..padding_amount {
br_with_padding.push(' ');
}
let where_preds = where_preds.to_string().replace('\n', &br_with_padding);
if ending == Ending::Newline {
let mut clause = " ".repeat(indent.saturating_sub(1));
write!(clause, "<div class=\"where\">where{where_preds},</div>")?;
clause
} else {
// insert a newline after a single space but before multiple spaces at the start
if indent == 0 {
format!("\n<span class=\"where\">where{where_preds}</span>")
} else {
// put the first one on the same line as the 'where' keyword
let where_preds = where_preds.replacen(&br_with_padding, " ", 1);
let mut clause = br_with_padding;
// +1 is for `\n`.
clause.truncate(indent + 1 + where_indent);
write!(clause, "<span class=\"where\">where{where_preds}</span>")?;
clause
}
}
};
write!(f, "{clause}")
}))
}
impl clean::Lifetime {
pub(crate) fn print(&self) -> impl Display {
self.0.as_str()
}
}
impl clean::ConstantKind {
pub(crate) fn print(&self, tcx: TyCtxt<'_>) -> impl Display {
let expr = self.expr(tcx);
fmt::from_fn(move |f| {
if f.alternate() { f.write_str(&expr) } else { write!(f, "{}", Escape(&expr)) }
})
}
}
impl clean::PolyTrait {
fn print(&self, cx: &Context<'_>) -> impl Display {
fmt::from_fn(move |f| {
print_higher_ranked_params_with_space(&self.generic_params, cx, "for").fmt(f)?;
self.trait_.print(cx).fmt(f)
})
}
}
impl clean::GenericBound {
pub(crate) fn print(&self, cx: &Context<'_>) -> impl Display {
fmt::from_fn(move |f| match self {
clean::GenericBound::Outlives(lt) => write!(f, "{}", lt.print()),
clean::GenericBound::TraitBound(ty, modifiers) => {
// `const` and `[const]` trait bounds are experimental; don't render them.
let hir::TraitBoundModifiers { polarity, constness: _ } = modifiers;
f.write_str(match polarity {
hir::BoundPolarity::Positive => "",
hir::BoundPolarity::Maybe(_) => "?",
hir::BoundPolarity::Negative(_) => "!",
})?;
ty.print(cx).fmt(f)
}
clean::GenericBound::Use(args) => {
if f.alternate() {
f.write_str("use<")?;
} else {
f.write_str("use&lt;")?;
}
args.iter().map(|arg| arg.name()).joined(", ", f)?;
if f.alternate() { f.write_str(">") } else { f.write_str("&gt;") }
}
})
}
}
impl clean::GenericArgs {
fn print(&self, cx: &Context<'_>) -> impl Display {
fmt::from_fn(move |f| {
match self {
clean::GenericArgs::AngleBracketed { args, constraints } => {
if !args.is_empty() || !constraints.is_empty() {
if f.alternate() {
f.write_str("<")?;
} else {
f.write_str("&lt;")?;
}
[Either::Left(args), Either::Right(constraints)]
.into_iter()
.flat_map(Either::factor_into_iter)
.map(|either| {
either.map_either(
|arg| arg.print(cx),
|constraint| constraint.print(cx),
)
})
.joined(", ", f)?;
if f.alternate() {
f.write_str(">")?;
} else {
f.write_str("&gt;")?;
}
}
}
clean::GenericArgs::Parenthesized { inputs, output } => {
f.write_str("(")?;
inputs.iter().map(|ty| ty.print(cx)).joined(", ", f)?;
f.write_str(")")?;
if let Some(ref ty) = *output {
if f.alternate() {
write!(f, " -> {:#}", ty.print(cx))?;
} else {
write!(f, " -&gt; {}", ty.print(cx))?;
}
}
}
clean::GenericArgs::ReturnTypeNotation => {
f.write_str("(..)")?;
}
}
Ok(())
})
}
}
// Possible errors when computing href link source for a `DefId`
#[derive(PartialEq, Eq)]
pub(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.
///
/// # Example
///
/// Crate `a` defines a public trait and crate `b` – the target crate that depends on `a` –
/// implements it for a local type.
/// We document `b` but **not** `a` (we only _build_ the latter – with `rustc`):
///
/// ```sh
/// rustc a.rs --crate-type=lib
/// rustdoc b.rs --crate-type=lib --extern=a=liba.rlib
/// ```
///
/// Now, the associated items in the trait impl want to link to the corresponding item in the
/// trait declaration (see `html::render::assoc_href_attr`) but it's not available since their
/// *documentation (was) not built*.
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,
/// Refers to an unnamable item, such as one defined within a function or const block.
UnnamableItem,
}
/// This function is to get the external macro path because they are not in the cache used in
/// `href_with_root_path`.
fn generate_macro_def_id_path(
def_id: DefId,
cx: &Context<'_>,
root_path: Option<&str>,
) -> Result<(String, ItemType, Vec<Symbol>), HrefError> {
let tcx = cx.tcx();
let crate_name = tcx.crate_name(def_id.krate);
let cache = cx.cache();
let fqp = clean::inline::item_relative_path(tcx, def_id);
let mut relative = fqp.iter().copied();
let cstore = CStore::from_tcx(tcx);
// We need this to prevent a `panic` when this function is used from intra doc links...
if !cstore.has_crate_data(def_id.krate) {
debug!("No data for crate {crate_name}");
return Err(HrefError::NotInExternalCache);
}
// Check to see if it is a macro 2.0 or built-in macro.
// More information in <https://rust-lang.github.io/rfcs/1584-macros.html>.
let is_macro_2 = match cstore.load_macro_untracked(def_id, tcx) {
// If `def.macro_rules` is `true`, then it's not a macro 2.0.
LoadedMacro::MacroDef { def, .. } => !def.macro_rules,
_ => false,
};
let mut path = if is_macro_2 {
once(crate_name).chain(relative).collect()
} else {
vec![crate_name, relative.next_back().unwrap()]
};
if path.len() < 2 {
// The minimum we can have is the crate name followed by the macro name. If shorter, then
// it means that `relative` was empty, which is an error.
debug!("macro path cannot be empty!");
return Err(HrefError::NotInExternalCache);
}
if let Some(last) = path.last_mut() {
*last = Symbol::intern(&format!("macro.{last}.html"));
}
let url = match cache.extern_locations[&def_id.krate] {
ExternalLocation::Remote(ref s) => {
// `ExternalLocation::Remote` always end with a `/`.
format!("{s}{path}", path = fmt::from_fn(|f| path.iter().joined("/", f)))
}
ExternalLocation::Local => {
// `root_path` always end with a `/`.
format!(
"{root_path}{path}",
root_path = root_path.unwrap_or(""),
path = fmt::from_fn(|f| path.iter().joined("/", f))
)
}
ExternalLocation::Unknown => {
debug!("crate {crate_name} not in cache when linkifying macros");
return Err(HrefError::NotInExternalCache);
}
};
Ok((url, ItemType::Macro, fqp))
}
fn generate_item_def_id_path(
mut def_id: DefId,
original_def_id: DefId,
cx: &Context<'_>,
root_path: Option<&str>,
original_def_kind: DefKind,
) -> Result<(String, ItemType, Vec<Symbol>), HrefError> {
use rustc_middle::traits::ObligationCause;
use rustc_trait_selection::infer::TyCtxtInferExt;
use rustc_trait_selection::traits::query::normalize::QueryNormalizeExt;
let tcx = cx.tcx();
let crate_name = tcx.crate_name(def_id.krate);
// No need to try to infer the actual parent item if it's not an associated item from the `impl`
// block.
if def_id != original_def_id && matches!(tcx.def_kind(def_id), DefKind::Impl { .. }) {
let infcx = tcx.infer_ctxt().build(TypingMode::non_body_analysis());
def_id = infcx
.at(&ObligationCause::dummy(), tcx.param_env(def_id))
.query_normalize(ty::Binder::dummy(tcx.type_of(def_id).instantiate_identity()))
.map(|resolved| infcx.resolve_vars_if_possible(resolved.value))
.ok()
.and_then(|normalized| normalized.skip_binder().ty_adt_def())
.map(|adt| adt.did())
.unwrap_or(def_id);
}
let relative = clean::inline::item_relative_path(tcx, def_id);
let fqp: Vec<Symbol> = once(crate_name).chain(relative).collect();
let def_kind = tcx.def_kind(def_id);
let shortty = def_kind.into();
let module_fqp = to_module_fqp(shortty, &fqp);
let mut is_remote = false;
let url_parts = url_parts(cx.cache(), def_id, module_fqp, &cx.current, &mut is_remote)?;
let mut url_parts = make_href(root_path, shortty, url_parts, &fqp, is_remote);
if def_id != original_def_id {
let kind = ItemType::from_def_kind(original_def_kind, Some(def_kind));
url_parts = format!("{url_parts}#{kind}.{}", tcx.item_name(original_def_id))
};
Ok((url_parts, shortty, fqp))
}
/// Checks if the given defid refers to an item that is unnamable, such as one defined in a const block.
fn is_unnamable(tcx: TyCtxt<'_>, did: DefId) -> bool {
let mut cur_did = did;
while let Some(parent) = tcx.opt_parent(cur_did) {
match tcx.def_kind(parent) {
// items defined in these can be linked to, as long as they are visible
DefKind::Mod | DefKind::ForeignMod => cur_did = parent,
// items in impls can be linked to,
// as long as we can link to the item the impl is on.
// since associated traits are not a thing,
// it should not be possible to refer to an impl item if
// the base type is not namable.
DefKind::Impl { .. } => return false,
// everything else does not have docs generated for it
_ => return true,
}
}
return false;
}
fn to_module_fqp(shortty: ItemType, fqp: &[Symbol]) -> &[Symbol] {
if shortty == ItemType::Module { fqp } else { &fqp[..fqp.len() - 1] }
}
fn url_parts(
cache: &Cache,
def_id: DefId,
module_fqp: &[Symbol],
relative_to: &[Symbol],
is_remote: &mut bool,
) -> Result<UrlPartsBuilder, HrefError> {
match cache.extern_locations[&def_id.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());
Ok(builder)
}
ExternalLocation::Local => Ok(href_relative_parts(module_fqp, relative_to)),
ExternalLocation::Unknown => Err(HrefError::DocumentationNotBuilt),
}
}
fn make_href(
root_path: Option<&str>,
shortty: ItemType,
mut url_parts: UrlPartsBuilder,
fqp: &[Symbol],
is_remote: bool,
) -> String {
if !is_remote && 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 last = fqp.last().unwrap();
url_parts.push_fmt(format_args!("{shortty}.{last}.html"));
}
}
url_parts.finish()
}
pub(crate) fn href_with_root_path(
original_did: DefId,
cx: &Context<'_>,
root_path: Option<&str>,
) -> Result<(String, ItemType, Vec<Symbol>), HrefError> {
let tcx = cx.tcx();
let def_kind = tcx.def_kind(original_did);
let did = match def_kind {
DefKind::AssocTy | DefKind::AssocFn | DefKind::AssocConst | DefKind::Variant => {
// documented on their parent's page
tcx.parent(original_did)
}
// If this a constructor, we get the parent (either a struct or a variant) and then
// generate the link for this item.
DefKind::Ctor(..) => return href_with_root_path(tcx.parent(original_did), cx, root_path),
DefKind::ExternCrate => {
// Link to the crate itself, not the `extern crate` item.
if let Some(local_did) = original_did.as_local() {
tcx.extern_mod_stmt_cnum(local_did).unwrap_or(LOCAL_CRATE).as_def_id()
} else {
original_did
}
}
_ => original_did,
};
if is_unnamable(cx.tcx(), did) {
return Err(HrefError::UnnamableItem);
}
let cache = cx.cache();
let relative_to = &cx.current;
if !original_did.is_local() {
// If we are generating an href for the "jump to def" feature, then the only case we want
// to ignore is if the item is `doc(hidden)` because we can't link to it.
if root_path.is_some() {
if tcx.is_doc_hidden(original_did) {
return Err(HrefError::Private);
}
} else if !cache.effective_visibilities.is_directly_public(tcx, did)
&& !cache.document_private
&& !cache.primitive_locations.values().any(|&id| id == did)
{
return Err(HrefError::Private);
}
}
let mut is_remote = false;
let (fqp, shortty, 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)
}),
None => {
// Associated items are handled differently with "jump to def". The anchor is generated
// directly here whereas for intra-doc links, we have some extra computation being
// performed there.
let def_id_to_get = if root_path.is_some() { original_did } else { did };
if let Some(&(ref fqp, shortty)) = cache.external_paths.get(&def_id_to_get) {
let module_fqp = to_module_fqp(shortty, fqp);
(fqp, shortty, url_parts(cache, did, module_fqp, relative_to, &mut is_remote)?)
} else if matches!(def_kind, DefKind::Macro(_)) {
return generate_macro_def_id_path(did, cx, root_path);
} else if did.is_local() {
return Err(HrefError::Private);
} else {
return generate_item_def_id_path(did, original_did, cx, root_path, def_kind);
}
}
};
let url_parts = make_href(root_path, shortty, url_parts, fqp, is_remote);
Ok((url_parts, shortty, fqp.clone()))
}
pub(crate) fn href(
did: DefId,
cx: &Context<'_>,
) -> Result<(String, ItemType, Vec<Symbol>), 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.
pub(crate) fn href_relative_parts(fqp: &[Symbol], relative_to_fqp: &[Symbol]) -> UrlPartsBuilder {
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..];
return iter::repeat_n(sym::dotdot, dissimilar_part_count)
.chain(fqp_module.iter().copied())
.collect();
}
}
match relative_to_fqp.len().cmp(&fqp.len()) {
Ordering::Less => {
// e.g. linking to std::sync::atomic from std::sync
fqp[relative_to_fqp.len()..fqp.len()].iter().copied().collect()
}
Ordering::Greater => {
// e.g. linking to std::sync from std::sync::atomic
let dissimilar_part_count = relative_to_fqp.len() - fqp.len();
iter::repeat_n(sym::dotdot, dissimilar_part_count).collect()
}
Ordering::Equal => {
// linking to the same module
UrlPartsBuilder::new()
}
}
}
pub(crate) fn link_tooltip(
did: DefId,
fragment: &Option<UrlFragment>,
cx: &Context<'_>,
) -> impl fmt::Display {
fmt::from_fn(move |f| {
let cache = cx.cache();
let Some((fqp, shortty)) = cache.paths.get(&did).or_else(|| cache.external_paths.get(&did))
else {
return Ok(());
};
let fqp = if *shortty == ItemType::Primitive {
// primitives are documented in a crate, but not actually part of it
slice::from_ref(fqp.last().unwrap())
} else {
fqp
};
if let &Some(UrlFragment::Item(id)) = fragment {
write!(f, "{} ", cx.tcx().def_descr(id))?;
for component in fqp {
write!(f, "{component}::")?;
}
write!(f, "{}", cx.tcx().item_name(id))?;
} else if !fqp.is_empty() {
write!(f, "{shortty} ")?;
write!(f, "{}", join_path_syms(fqp))?;
}
Ok(())
})
}
/// Used to render a [`clean::Path`].
fn resolved_path(
w: &mut fmt::Formatter<'_>,
did: DefId,
path: &clean::Path,
print_all: bool,
use_absolute: bool,
cx: &Context<'_>,
) -> fmt::Result {
let last = path.segments.last().unwrap();
if print_all {
for seg in &path.segments[..path.segments.len() - 1] {
write!(w, "{}::", if seg.name == kw::PathRoot { "" } else { seg.name.as_str() })?;
}
}
if w.alternate() {
write!(w, "{}{:#}", last.name, last.args.print(cx))?;
} else {
let path = fmt::from_fn(|f| {
if use_absolute {
if let Ok((_, _, fqp)) = href(did, cx) {
write!(
f,
"{path}::{anchor}",
path = join_path_syms(&fqp[..fqp.len() - 1]),
anchor = print_anchor(did, *fqp.last().unwrap(), cx)
)
} else {
write!(f, "{}", last.name)
}
} else {
write!(f, "{}", print_anchor(did, last.name, cx))
}
});
write!(w, "{path}{args}", args = last.args.print(cx))?;
}
Ok(())
}
fn primitive_link(
f: &mut fmt::Formatter<'_>,
prim: clean::PrimitiveType,
name: fmt::Arguments<'_>,
cx: &Context<'_>,
) -> fmt::Result {
primitive_link_fragment(f, prim, name, "", cx)
}
fn primitive_link_fragment(
f: &mut fmt::Formatter<'_>,
prim: clean::PrimitiveType,
name: fmt::Arguments<'_>,
fragment: &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 path = fmt::from_fn(|f| {
if len == 0 {
let cname_sym = ExternalCrate { crate_num: def_id.krate }.name(cx.tcx());
write!(f, "{cname_sym}/")?;
} else {
for _ in 0..(len - 1) {
f.write_str("../")?;
}
}
Ok(())
});
write!(
f,
"<a class=\"primitive\" href=\"{path}primitive.{}.html{fragment}\">",
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_n(sym::dotdot, cx.current.len() - 1).collect()
} else {
iter::repeat_n(sym::dotdot, 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, "<a class=\"primitive\" href=\"{}{fragment}\">", loc.finish())?;
needs_termination = true;
}
}
None => {}
}
}
Display::fmt(&name, f)?;
if needs_termination {
write!(f, "</a>")?;
}
Ok(())
}
fn print_tybounds(
bounds: &[clean::PolyTrait],
lt: &Option<clean::Lifetime>,
cx: &Context<'_>,
) -> impl Display {
fmt::from_fn(move |f| {
bounds.iter().map(|bound| bound.print(cx)).joined(" + ", f)?;
if let Some(lt) = lt {
// We don't need to check `alternate` since we can be certain that
// the lifetime doesn't contain any characters which need escaping.
write!(f, " + {}", lt.print())?;
}
Ok(())
})
}
fn print_higher_ranked_params_with_space(
params: &[clean::GenericParamDef],
cx: &Context<'_>,
keyword: &'static str,
) -> impl Display {
fmt::from_fn(move |f| {
if !params.is_empty() {
f.write_str(keyword)?;
f.write_str(if f.alternate() { "<" } else { "&lt;" })?;
params.iter().map(|lt| lt.print(cx)).joined(", ", f)?;
f.write_str(if f.alternate() { "> " } else { "&gt; " })?;
}
Ok(())
})
}
pub(crate) fn print_anchor(did: DefId, text: Symbol, cx: &Context<'_>) -> impl Display {
fmt::from_fn(move |f| {
let parts = href(did, cx);
if let Ok((url, short_ty, fqp)) = parts {
write!(
f,
r#"<a class="{short_ty}" href="{url}" title="{short_ty} {path}">{text}</a>"#,
path = join_path_syms(fqp),
text = EscapeBodyText(text.as_str()),
)
} else {
f.write_str(text.as_str())
}
})
}
fn fmt_type(
t: &clean::Type,
f: &mut fmt::Formatter<'_>,
use_absolute: bool,
cx: &Context<'_>,
) -> fmt::Result {
trace!("fmt_type(t = {t:?})");
match t {
clean::Generic(name) => f.write_str(name.as_str()),
clean::SelfTy => f.write_str("Self"),
clean::Type::Path { 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(bounds, lt) => {
f.write_str("dyn ")?;
print_tybounds(bounds, lt, cx).fmt(f)
}
clean::Infer => write!(f, "_"),
clean::Primitive(clean::PrimitiveType::Never) => {
primitive_link(f, PrimitiveType::Never, format_args!("!"), cx)
}
&clean::Primitive(prim) => primitive_link(f, prim, format_args!("{}", prim.as_sym()), cx),
clean::BareFunction(decl) => {
print_higher_ranked_params_with_space(&decl.generic_params, cx, "for").fmt(f)?;
decl.safety.print_with_space().fmt(f)?;
print_abi_with_space(decl.abi).fmt(f)?;
if f.alternate() {
f.write_str("fn")?;
} else {
primitive_link(f, PrimitiveType::Fn, format_args!("fn"), cx)?;
}
decl.decl.print(cx).fmt(f)
}
clean::UnsafeBinder(binder) => {
print_higher_ranked_params_with_space(&binder.generic_params, cx, "unsafe").fmt(f)?;
binder.ty.print(cx).fmt(f)
}
clean::Tuple(typs) => match &typs[..] {
&[] => primitive_link(f, PrimitiveType::Unit, format_args!("()"), cx),
[one] => {
if let clean::Generic(name) = one {
primitive_link(f, PrimitiveType::Tuple, format_args!("({name},)"), cx)
} else {
write!(f, "(")?;
one.print(cx).fmt(f)?;
write!(f, ",)")
}
}
many => {
let generic_names: Vec<Symbol> = many
.iter()
.filter_map(|t| match t {
clean::Generic(name) => Some(*name),
_ => None,
})
.collect();
let is_generic = generic_names.len() == many.len();
if is_generic {
primitive_link(
f,
PrimitiveType::Tuple,
format_args!(
"({})",
fmt::from_fn(|f| generic_names.iter().joined(", ", f))
),
cx,
)
} else {
f.write_str("(")?;
many.iter().map(|item| item.print(cx)).joined(", ", f)?;
f.write_str(")")
}
}
},
clean::Slice(box clean::Generic(name)) => {
primitive_link(f, PrimitiveType::Slice, format_args!("[{name}]"), cx)
}
clean::Slice(t) => {
write!(f, "[")?;
t.print(cx).fmt(f)?;
write!(f, "]")
}
clean::Type::Pat(t, pat) => {
fmt::Display::fmt(&t.print(cx), f)?;
write!(f, " is {pat}")
}
clean::Array(box clean::Generic(name), n) if !f.alternate() => primitive_link(
f,
PrimitiveType::Array,
format_args!("[{name}; {n}]", n = Escape(n)),
cx,
),
clean::Array(t, n) => {
write!(f, "[")?;
t.print(cx).fmt(f)?;
if f.alternate() {
write!(f, "; {n}")?;
} else {
write!(f, "; ")?;
primitive_link(f, PrimitiveType::Array, format_args!("{n}", n = Escape(n)), cx)?;
}
write!(f, "]")
}
clean::RawPointer(m, t) => {
let m = match m {
hir::Mutability::Mut => "mut",
hir::Mutability::Not => "const",
};
if matches!(**t, clean::Generic(_)) || t.is_assoc_ty() {
let ty = t.print(cx);
if f.alternate() {
primitive_link(
f,
clean::PrimitiveType::RawPointer,
format_args!("*{m} {ty:#}"),
cx,
)
} else {
primitive_link(
f,
clean::PrimitiveType::RawPointer,
format_args!("*{m} {ty}"),
cx,
)
}
} else {
primitive_link(f, clean::PrimitiveType::RawPointer, format_args!("*{m} "), cx)?;
t.print(cx).fmt(f)
}
}
clean::BorrowedRef { lifetime: l, mutability, type_: ty } => {
let lt = fmt::from_fn(|f| match l {
Some(l) => write!(f, "{} ", l.print()),
_ => Ok(()),
});
let m = mutability.print_with_space();
let amp = if f.alternate() { "&" } else { "&amp;" };
if let clean::Generic(name) = **ty {
return primitive_link(
f,
PrimitiveType::Reference,
format_args!("{amp}{lt}{m}{name}"),
cx,
);
}
write!(f, "{amp}{lt}{m}")?;
let needs_parens = match **ty {
clean::DynTrait(ref bounds, ref trait_lt)
if bounds.len() > 1 || trait_lt.is_some() =>
{
true
}
clean::ImplTrait(ref bounds) if bounds.len() > 1 => true,
_ => false,
};
if needs_parens {
f.write_str("(")?;
}
fmt_type(ty, f, use_absolute, cx)?;
if needs_parens {
f.write_str(")")?;
}
Ok(())
}
clean::ImplTrait(bounds) => {
f.write_str("impl ")?;
print_generic_bounds(bounds, cx).fmt(f)
}
clean::QPath(qpath) => qpath.print(cx).fmt(f),
}
}
impl clean::Type {
pub(crate) fn print(&self, cx: &Context<'_>) -> impl Display {
fmt::from_fn(move |f| fmt_type(self, f, false, cx))
}
}
impl clean::Path {
pub(crate) fn print(&self, cx: &Context<'_>) -> impl Display {
fmt::from_fn(move |f| resolved_path(f, self.def_id(), self, false, false, cx))
}
}
impl clean::QPathData {
fn print(&self, cx: &Context<'_>) -> impl Display {
let Self { ref assoc, ref self_type, should_fully_qualify, ref trait_ } = *self;
fmt::from_fn(move |f| {
// FIXME(inherent_associated_types): Once we support non-ADT self-types (#106719),
// we need to surround them with angle brackets in some cases (e.g. `<dyn …>::P`).
if f.alternate() {
if let Some(trait_) = trait_
&& should_fully_qualify
{
write!(f, "<{:#} as {:#}>::", self_type.print(cx), trait_.print(cx))?
} else {
write!(f, "{:#}::", self_type.print(cx))?
}
} else {
if let Some(trait_) = trait_
&& should_fully_qualify
{
write!(f, "&lt;{} as {}&gt;::", self_type.print(cx), trait_.print(cx))?
} else {
write!(f, "{}::", self_type.print(cx))?
}
};
// It's pretty unsightly to look at `<A as B>::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).
if !f.alternate() {
// FIXME(inherent_associated_types): We always link to the very first associated
// type (in respect to source order) that bears the given name (`assoc.name`) and that is
// affiliated with the computed `DefId`. This is obviously incorrect when we have
// multiple impl blocks. Ideally, we would thread the `DefId` of the assoc ty itself
// through here and map it to the corresponding HTML ID that was generated by
// `render::Context::derive_id` when the impl blocks were rendered.
// There is no such mapping unfortunately.
// As a hack, we could badly imitate `derive_id` here by keeping *count* when looking
// for the assoc ty `DefId` in `tcx.associated_items(self_ty_did).in_definition_order()`
// considering privacy, `doc(hidden)`, etc.
// I don't feel like that right now :cold_sweat:.
let parent_href = match trait_ {
Some(trait_) => href(trait_.def_id(), cx).ok(),
None => self_type.def_id(cx.cache()).and_then(|did| href(did, cx).ok()),
};
if let Some((url, _, path)) = parent_href {
write!(
f,
"<a class=\"associatedtype\" href=\"{url}#{shortty}.{name}\" \
title=\"type {path}::{name}\">{name}</a>",
shortty = ItemType::AssocType,
name = assoc.name,
path = join_path_syms(path),
)
} else {
write!(f, "{}", assoc.name)
}
} else {
write!(f, "{}", assoc.name)
}?;
assoc.args.print(cx).fmt(f)
})
}
}
impl clean::Impl {
pub(crate) fn print(&self, use_absolute: bool, cx: &Context<'_>) -> impl Display {
fmt::from_fn(move |f| {
f.write_str("impl")?;
self.generics.print(cx).fmt(f)?;
f.write_str(" ")?;
if let Some(ref ty) = self.trait_ {
if self.is_negative_trait_impl() {
write!(f, "!")?;
}
if self.kind.is_fake_variadic()
&& let Some(generics) = ty.generics()
&& let Ok(inner_type) = generics.exactly_one()
{
let last = ty.last();
if f.alternate() {
write!(f, "{last}<")?;
self.print_type(inner_type, f, use_absolute, cx)?;
write!(f, ">")?;
} else {
write!(f, "{}&lt;", print_anchor(ty.def_id(), last, cx))?;
self.print_type(inner_type, f, use_absolute, cx)?;
write!(f, "&gt;")?;
}
} else {
ty.print(cx).fmt(f)?;
}
write!(f, " for ")?;
}
if let Some(ty) = self.kind.as_blanket_ty() {
fmt_type(ty, f, use_absolute, cx)?;
} else {
self.print_type(&self.for_, f, use_absolute, cx)?;
}
print_where_clause(&self.generics, cx, 0, Ending::Newline).maybe_display().fmt(f)
})
}
fn print_type(
&self,
type_: &clean::Type,
f: &mut fmt::Formatter<'_>,
use_absolute: bool,
cx: &Context<'_>,
) -> Result<(), fmt::Error> {
if let clean::Type::Tuple(types) = type_
&& let [clean::Type::Generic(name)] = &types[..]
&& (self.kind.is_fake_variadic() || self.kind.is_auto())
{
// Hardcoded anchor library/core/src/primitive_docs.rs
// Link should match `# Trait implementations`
primitive_link_fragment(
f,
PrimitiveType::Tuple,
format_args!("({name}₁, {name}₂, …, {name}ₙ)"),
"#trait-implementations-1",
cx,
)?;
} else if let clean::Type::Array(ty, len) = type_
&& let clean::Type::Generic(name) = &**ty
&& &len[..] == "1"
&& (self.kind.is_fake_variadic() || self.kind.is_auto())
{
primitive_link(f, PrimitiveType::Array, format_args!("[{name}; N]"), cx)?;
} else if let clean::BareFunction(bare_fn) = &type_
&& let [clean::Parameter { type_: clean::Type::Generic(name), .. }] =
&bare_fn.decl.inputs[..]
&& (self.kind.is_fake_variadic() || self.kind.is_auto())
{
// Hardcoded anchor library/core/src/primitive_docs.rs
// Link should match `# Trait implementations`
print_higher_ranked_params_with_space(&bare_fn.generic_params, cx, "for").fmt(f)?;
bare_fn.safety.print_with_space().fmt(f)?;
print_abi_with_space(bare_fn.abi).fmt(f)?;
let ellipsis = if bare_fn.decl.c_variadic { ", ..." } else { "" };
primitive_link_fragment(
f,
PrimitiveType::Tuple,
format_args!("fn({name}₁, {name}₂, …, {name}ₙ{ellipsis})"),
"#trait-implementations-1",
cx,
)?;
// Write output.
if !bare_fn.decl.output.is_unit() {
write!(f, " -> ")?;
fmt_type(&bare_fn.decl.output, f, use_absolute, cx)?;
}
} else if let clean::Type::Path { path } = type_
&& let Some(generics) = path.generics()
&& let Ok(ty) = generics.exactly_one()
&& self.kind.is_fake_variadic()
{
let wrapper = print_anchor(path.def_id(), path.last(), cx);
if f.alternate() {
write!(f, "{wrapper:#}&lt;")?;
} else {
write!(f, "{wrapper}<")?;
}
self.print_type(ty, f, use_absolute, cx)?;
if f.alternate() {
write!(f, "&gt;")?;
} else {
write!(f, ">")?;
}
} else {
fmt_type(type_, f, use_absolute, cx)?;
}
Ok(())
}
}
pub(crate) fn print_params(params: &[clean::Parameter], cx: &Context<'_>) -> impl Display {
fmt::from_fn(move |f| {
params
.iter()
.map(|param| {
fmt::from_fn(|f| {
if let Some(name) = param.name {
write!(f, "{name}: ")?;
}
param.type_.print(cx).fmt(f)
})
})
.joined(", ", f)
})
}
// Implements Write but only counts the bytes "written".
struct WriteCounter(usize);
impl std::fmt::Write for WriteCounter {
fn write_str(&mut self, s: &str) -> fmt::Result {
self.0 += s.len();
Ok(())
}
}
// Implements Display by emitting the given number of spaces.
struct Indent(usize);
impl Display for Indent {
fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
(0..self.0).for_each(|_| {
f.write_char(' ').unwrap();
});
Ok(())
}
}
impl clean::FnDecl {
pub(crate) fn print(&self, cx: &Context<'_>) -> impl Display {
fmt::from_fn(move |f| {
let ellipsis = if self.c_variadic { ", ..." } else { "" };
if f.alternate() {
write!(
f,
"({params:#}{ellipsis}){arrow:#}",
params = print_params(&self.inputs, cx),
ellipsis = ellipsis,
arrow = self.print_output(cx)
)
} else {
write!(
f,
"({params}{ellipsis}){arrow}",
params = print_params(&self.inputs, cx),
ellipsis = ellipsis,
arrow = self.print_output(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.
/// This is expected to go into a `<pre>`/`code-header` block, so indentation and newlines
/// are preserved.
/// * `indent`: The number of spaces to indent each successive line with, if line-wrapping is
/// necessary.
pub(crate) fn full_print(
&self,
header_len: usize,
indent: usize,
cx: &Context<'_>,
) -> impl Display {
fmt::from_fn(move |f| {
// First, generate the text form of the declaration, with no line wrapping, and count the bytes.
let mut counter = WriteCounter(0);
write!(&mut counter, "{:#}", fmt::from_fn(|f| { self.inner_full_print(None, f, cx) }))
.unwrap();
// If the text form was over 80 characters wide, we will line-wrap our output.
let line_wrapping_indent =
if header_len + counter.0 > 80 { Some(indent) } else { None };
// Generate the final output. This happens to accept `{:#}` formatting to get textual
// output but in practice it is only formatted with `{}` to get HTML output.
self.inner_full_print(line_wrapping_indent, f, cx)
})
}
fn inner_full_print(
&self,
// For None, the declaration will not be line-wrapped. For Some(n),
// the declaration will be line-wrapped, with an indent of n spaces.
line_wrapping_indent: Option<usize>,
f: &mut fmt::Formatter<'_>,
cx: &Context<'_>,
) -> fmt::Result {
let amp = if f.alternate() { "&" } else { "&amp;" };
write!(f, "(")?;
if let Some(n) = line_wrapping_indent
&& !self.inputs.is_empty()
{
write!(f, "\n{}", Indent(n + 4))?;
}
let last_input_index = self.inputs.len().checked_sub(1);
for (i, param) in self.inputs.iter().enumerate() {
if let Some(selfty) = param.to_receiver() {
match selfty {
clean::SelfTy => {
write!(f, "self")?;
}
clean::BorrowedRef { lifetime, mutability, type_: box clean::SelfTy } => {
write!(f, "{amp}")?;
if let Some(lt) = lifetime {
write!(f, "{lt} ", lt = lt.print())?;
}
write!(f, "{mutability}self", mutability = mutability.print_with_space())?;
}
_ => {
write!(f, "self: ")?;
selfty.print(cx).fmt(f)?;
}
}
} else {
if param.is_const {
write!(f, "const ")?;
}
if let Some(name) = param.name {
write!(f, "{name}: ")?;
}
param.type_.print(cx).fmt(f)?;
}
match (line_wrapping_indent, last_input_index) {
(_, None) => (),
(None, Some(last_i)) if i != last_i => write!(f, ", ")?,
(None, Some(_)) => (),
(Some(n), Some(last_i)) if i != last_i => write!(f, ",\n{}", Indent(n + 4))?,
(Some(_), Some(_)) => writeln!(f, ",")?,
}
}
if self.c_variadic {
match line_wrapping_indent {
None => write!(f, ", ...")?,
Some(n) => writeln!(f, "{}...", Indent(n + 4))?,
};
}
match line_wrapping_indent {
None => write!(f, ")")?,
Some(n) => write!(f, "{})", Indent(n))?,
};
self.print_output(cx).fmt(f)
}
fn print_output(&self, cx: &Context<'_>) -> impl Display {
fmt::from_fn(move |f| match &self.output {
clean::Tuple(tys) if tys.is_empty() => Ok(()),
ty if f.alternate() => {
write!(f, " -> {:#}", ty.print(cx))
}
ty => write!(f, " -&gt; {}", ty.print(cx)),
})
}
}
pub(crate) fn visibility_print_with_space(item: &clean::Item, cx: &Context<'_>) -> impl Display {
fmt::from_fn(move |f| {
if item.is_doc_hidden() {
f.write_str("#[doc(hidden)] ")?;
}
match item.visibility(cx.tcx()) {
None => {}
Some(ty::Visibility::Public) => f.write_str("pub ")?,
Some(ty::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.item_id.expect_def_id());
if vis_did.is_crate_root() {
f.write_str("pub(crate) ")?;
} else if parent_module == Some(vis_did) {
// `pub(in foo)` where `foo` is the parent module
// is the same as no visibility modifier; do nothing
} else if parent_module
.and_then(|parent| find_nearest_parent_module(cx.tcx(), parent))
== Some(vis_did)
{
f.write_str("pub(super) ")?;
} 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 = print_anchor(vis_did, last_name, cx);
f.write_str("pub(in ")?;
for seg in &path.data[..path.data.len() - 1] {
write!(f, "{}::", seg.data.get_opt_name().unwrap())?;
}
write!(f, "{anchor}) ")?;
}
}
}
Ok(())
})
}
pub(crate) trait PrintWithSpace {
fn print_with_space(&self) -> &str;
}
impl PrintWithSpace for hir::Safety {
fn print_with_space(&self) -> &str {
self.prefix_str()
}
}
impl PrintWithSpace for hir::HeaderSafety {
fn print_with_space(&self) -> &str {
match self {
hir::HeaderSafety::SafeTargetFeatures => "",
hir::HeaderSafety::Normal(safety) => safety.print_with_space(),
}
}
}
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 ",
}
}
}
pub(crate) fn print_constness_with_space(
c: &hir::Constness,
overall_stab: Option<StableSince>,
const_stab: Option<ConstStability>,
) -> &'static str {
match c {
hir::Constness::Const => match (overall_stab, const_stab) {
// const stable...
(_, Some(ConstStability { level: StabilityLevel::Stable { .. }, .. }))
// ...or when feature(staged_api) is not set...
| (_, None)
// ...or when const unstable, but overall unstable too
| (None, Some(ConstStability { level: StabilityLevel::Unstable { .. }, .. })) => {
"const "
}
// const unstable (and overall stable)
(Some(_), Some(ConstStability { level: StabilityLevel::Unstable { .. }, .. })) => "",
},
// not const
hir::Constness::NotConst => "",
}
}
impl clean::Import {
pub(crate) fn print(&self, cx: &Context<'_>) -> impl Display {
fmt::from_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 {source} as {name};", source = self.source.print(cx))
}
}
clean::ImportKind::Glob => {
if self.source.path.segments.is_empty() {
write!(f, "use *;")
} else {
write!(f, "use {}::*;", self.source.print(cx))
}
}
})
}
}
impl clean::ImportSource {
pub(crate) fn print(&self, cx: &Context<'_>) -> impl Display {
fmt::from_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), format_args!("{name}"), cx)?;
} else {
f.write_str(name.as_str())?;
}
Ok(())
}
})
}
}
impl clean::AssocItemConstraint {
pub(crate) fn print(&self, cx: &Context<'_>) -> impl Display {
fmt::from_fn(move |f| {
f.write_str(self.assoc.name.as_str())?;
self.assoc.args.print(cx).fmt(f)?;
match self.kind {
clean::AssocItemConstraintKind::Equality { ref term } => {
f.write_str(" = ")?;
term.print(cx).fmt(f)?;
}
clean::AssocItemConstraintKind::Bound { ref bounds } => {
if !bounds.is_empty() {
f.write_str(": ")?;
print_generic_bounds(bounds, cx).fmt(f)?;
}
}
}
Ok(())
})
}
}
pub(crate) fn print_abi_with_space(abi: ExternAbi) -> impl Display {
fmt::from_fn(move |f| {
let quot = if f.alternate() { "\"" } else { "&quot;" };
match abi {
ExternAbi::Rust => Ok(()),
abi => write!(f, "extern {0}{1}{0} ", quot, abi.name()),
}
})
}
pub(crate) fn print_default_space(v: bool) -> &'static str {
if v { "default " } else { "" }
}
impl clean::GenericArg {
pub(crate) fn print(&self, cx: &Context<'_>) -> impl Display {
fmt::from_fn(move |f| match self {
clean::GenericArg::Lifetime(lt) => lt.print().fmt(f),
clean::GenericArg::Type(ty) => ty.print(cx).fmt(f),
clean::GenericArg::Const(ct) => ct.print(cx.tcx()).fmt(f),
clean::GenericArg::Infer => Display::fmt("_", f),
})
}
}
impl clean::Term {
pub(crate) fn print(&self, cx: &Context<'_>) -> impl Display {
fmt::from_fn(move |f| match self {
clean::Term::Type(ty) => ty.print(cx).fmt(f),
clean::Term::Constant(ct) => ct.print(cx.tcx()).fmt(f),
})
}
}