use std::cmp::Ordering; use std::fmt::{self, Display, Write as _}; use std::iter; use askama::Template; use rustc_abi::VariantIdx; use rustc_ast::join_path_syms; use rustc_data_structures::fx::{FxHashMap, FxIndexSet}; use rustc_hir as hir; use rustc_hir::def::CtorKind; use rustc_hir::def_id::DefId; use rustc_index::IndexVec; use rustc_middle::ty::{self, TyCtxt}; use rustc_span::hygiene::MacroKind; use rustc_span::symbol::{Symbol, sym}; use tracing::{debug, info}; use super::type_layout::document_type_layout; use super::{ AssocItemLink, AssocItemRender, Context, ImplRenderingParameters, RenderMode, collect_paths_for_type, document, ensure_trailing_slash, get_filtered_impls_for_reference, item_ty_to_section, notable_traits_button, notable_traits_json, render_all_impls, render_assoc_item, render_assoc_items, render_attributes_in_code, render_impl, render_repr_attribute_in_code, render_rightside, render_stability_since_raw, render_stability_since_raw_with_extra, write_section_heading, }; use crate::clean; use crate::config::ModuleSorting; use crate::display::{Joined as _, MaybeDisplay as _}; use crate::formats::Impl; use crate::formats::item_type::ItemType; use crate::html::escape::{Escape, EscapeBodyTextWithWbr}; use crate::html::format::{ Ending, PrintWithSpace, print_abi_with_space, print_constness_with_space, print_where_clause, visibility_print_with_space, }; use crate::html::markdown::{HeadingOffset, MarkdownSummaryLine}; use crate::html::render::sidebar::filters; use crate::html::render::{document_full, document_item_info}; use crate::html::url_parts_builder::UrlPartsBuilder; /// Generates an Askama template struct for rendering items with common methods. /// /// Usage: /// ```ignore (illustrative) /// item_template!( /// #[template(path = "", /* additional values */)] /// /* additional meta items */ /// struct MyItem<'a, 'cx> { /// cx: RefCell<&'a mut Context<'cx>>, /// it: &'a clean::Item, /// /* additional fields */ /// }, /// methods = [ /* method names (comma separated; refer to macro definition of `item_template_methods!()`) */ ] /// ) /// ``` /// /// NOTE: ensure that the generic lifetimes (`'a`, `'cx`) and /// required fields (`cx`, `it`) are identical (in terms of order and definition). macro_rules! item_template { ( $(#[$meta:meta])* struct $name:ident<'a, 'cx> { cx: &'a Context<'cx>, it: &'a clean::Item, $($field_name:ident: $field_ty:ty),*, }, methods = [$($methods:tt),* $(,)?] ) => { #[derive(Template)] $(#[$meta])* struct $name<'a, 'cx> { cx: &'a Context<'cx>, it: &'a clean::Item, $($field_name: $field_ty),* } impl<'a, 'cx: 'a> ItemTemplate<'a, 'cx> for $name<'a, 'cx> { fn item_and_cx(&self) -> (&'a clean::Item, &'a Context<'cx>) { (&self.it, &self.cx) } } impl<'a, 'cx: 'a> $name<'a, 'cx> { item_template_methods!($($methods)*); } }; } /// Implement common methods for item template structs generated by `item_template!()`. /// /// NOTE: this macro is intended to be used only by `item_template!()`. macro_rules! item_template_methods { () => {}; (document $($rest:tt)*) => { fn document(&self) -> impl fmt::Display { let (item, cx) = self.item_and_cx(); document(cx, item, None, HeadingOffset::H2) } item_template_methods!($($rest)*); }; (document_type_layout $($rest:tt)*) => { fn document_type_layout(&self) -> impl fmt::Display { let (item, cx) = self.item_and_cx(); let def_id = item.item_id.expect_def_id(); document_type_layout(cx, def_id) } item_template_methods!($($rest)*); }; (render_assoc_items $($rest:tt)*) => { fn render_assoc_items(&self) -> impl fmt::Display { let (item, cx) = self.item_and_cx(); let def_id = item.item_id.expect_def_id(); render_assoc_items(cx, item, def_id, AssocItemRender::All) } item_template_methods!($($rest)*); }; ($method:ident $($rest:tt)*) => { compile_error!(concat!("unknown method: ", stringify!($method))); }; ($token:tt $($rest:tt)*) => { compile_error!(concat!("unexpected token: ", stringify!($token))); }; } const ITEM_TABLE_OPEN: &str = "
"; const REEXPORTS_TABLE_OPEN: &str = "
"; const ITEM_TABLE_CLOSE: &str = "
"; // A component in a `use` path, like `string` in std::string::ToString struct PathComponent { path: String, name: Symbol, } #[derive(Template)] #[template(path = "print_item.html")] struct ItemVars<'a> { typ: &'a str, name: &'a str, item_type: &'a str, path_components: Vec, stability_since_raw: &'a str, src_href: Option<&'a str>, } pub(super) fn print_item(cx: &Context<'_>, item: &clean::Item) -> impl fmt::Display { debug_assert!(!item.is_stripped()); fmt::from_fn(|buf| { let typ = match item.kind { clean::ModuleItem(_) => { if item.is_crate() { "Crate " } else { "Module " } } clean::FunctionItem(..) | clean::ForeignFunctionItem(..) => "Function ", clean::TraitItem(..) => "Trait ", clean::StructItem(..) => "Struct ", clean::UnionItem(..) => "Union ", clean::EnumItem(..) => "Enum ", clean::TypeAliasItem(..) => "Type Alias ", clean::MacroItem(..) => "Macro ", clean::ProcMacroItem(ref mac) => match mac.kind { MacroKind::Bang => "Macro ", MacroKind::Attr => "Attribute Macro ", MacroKind::Derive => "Derive Macro ", }, clean::PrimitiveItem(..) => "Primitive Type ", clean::StaticItem(..) | clean::ForeignStaticItem(..) => "Static ", clean::ConstantItem(..) => "Constant ", clean::ForeignTypeItem => "Foreign Type ", clean::KeywordItem => "Keyword ", clean::AttributeItem => "Attribute ", clean::TraitAliasItem(..) => "Trait Alias ", _ => { // We don't generate pages for any other type. unreachable!(); } }; let stability_since_raw = render_stability_since_raw(item.stable_since(cx.tcx()), item.const_stability(cx.tcx())) .maybe_display() .to_string(); // Write source tag // // When this item is part of a `crate use` in a downstream crate, the // source link in the downstream documentation will actually come back to // this page, and this link will be auto-clicked. The `id` attribute is // used to find the link to auto-click. let src_href = if cx.info.include_sources && !item.is_primitive() { cx.src_href(item) } else { None }; let path_components = if item.is_fake_item() { vec![] } else { let cur = &cx.current; let amt = if item.is_mod() { cur.len() - 1 } else { cur.len() }; cur.iter() .enumerate() .take(amt) .map(|(i, component)| PathComponent { path: "../".repeat(cur.len() - i - 1), name: *component, }) .collect() }; let item_vars = ItemVars { typ, name: item.name.as_ref().unwrap().as_str(), item_type: &item.type_().to_string(), path_components, stability_since_raw: &stability_since_raw, src_href: src_href.as_deref(), }; item_vars.render_into(buf).unwrap(); match &item.kind { clean::ModuleItem(m) => { write!(buf, "{}", item_module(cx, item, &m.items)) } clean::FunctionItem(f) | clean::ForeignFunctionItem(f, _) => { write!(buf, "{}", item_function(cx, item, f)) } clean::TraitItem(t) => write!(buf, "{}", item_trait(cx, item, t)), clean::StructItem(s) => { write!(buf, "{}", item_struct(cx, item, s)) } clean::UnionItem(s) => write!(buf, "{}", item_union(cx, item, s)), clean::EnumItem(e) => write!(buf, "{}", item_enum(cx, item, e)), clean::TypeAliasItem(t) => { write!(buf, "{}", item_type_alias(cx, item, t)) } clean::MacroItem(m) => write!(buf, "{}", item_macro(cx, item, m)), clean::ProcMacroItem(m) => { write!(buf, "{}", item_proc_macro(cx, item, m)) } clean::PrimitiveItem(_) => write!(buf, "{}", item_primitive(cx, item)), clean::StaticItem(i) => { write!(buf, "{}", item_static(cx, item, i, None)) } clean::ForeignStaticItem(i, safety) => { write!(buf, "{}", item_static(cx, item, i, Some(*safety))) } clean::ConstantItem(ci) => { write!(buf, "{}", item_constant(cx, item, &ci.generics, &ci.type_, &ci.kind)) } clean::ForeignTypeItem => { write!(buf, "{}", item_foreign_type(cx, item)) } clean::KeywordItem | clean::AttributeItem => { write!(buf, "{}", item_keyword_or_attribute(cx, item)) } clean::TraitAliasItem(ta) => { write!(buf, "{}", item_trait_alias(cx, item, ta)) } _ => { // We don't generate pages for any other type. unreachable!(); } }?; // Render notable-traits.js used for all methods in this module. let mut types_with_notable_traits = cx.types_with_notable_traits.borrow_mut(); if !types_with_notable_traits.is_empty() { write!( buf, r#""#, notable_traits_json(types_with_notable_traits.iter(), cx), )?; types_with_notable_traits.clear(); } Ok(()) }) } /// For large structs, enums, unions, etc, determine whether to hide their fields fn should_hide_fields(n_fields: usize) -> bool { n_fields > 12 } fn toggle_open(mut w: impl fmt::Write, text: impl Display) { write!( w, "
\ \ Show {text}\ ", ) .unwrap(); } fn toggle_close(mut w: impl fmt::Write) { w.write_str("
").unwrap(); } trait ItemTemplate<'a, 'cx: 'a>: askama::Template + Display { fn item_and_cx(&self) -> (&'a clean::Item, &'a Context<'cx>); } fn item_module(cx: &Context<'_>, item: &clean::Item, items: &[clean::Item]) -> impl fmt::Display { fmt::from_fn(|w| { write!(w, "{}", document(cx, item, None, HeadingOffset::H2))?; let mut not_stripped_items = items.iter().filter(|i| !i.is_stripped()).enumerate().collect::>(); // the order of item types in the listing fn reorder(ty: ItemType) -> u8 { match ty { ItemType::ExternCrate => 0, ItemType::Import => 1, ItemType::Primitive => 2, ItemType::Module => 3, ItemType::Macro => 4, ItemType::Struct => 5, ItemType::Enum => 6, ItemType::Constant => 7, ItemType::Static => 8, ItemType::Trait => 9, ItemType::Function => 10, ItemType::TypeAlias => 12, ItemType::Union => 13, _ => 14 + ty as u8, } } fn cmp(i1: &clean::Item, i2: &clean::Item, tcx: TyCtxt<'_>) -> Ordering { let rty1 = reorder(i1.type_()); let rty2 = reorder(i2.type_()); if rty1 != rty2 { return rty1.cmp(&rty2); } let is_stable1 = i1.stability(tcx).as_ref().map(|s| s.level.is_stable()).unwrap_or(true); let is_stable2 = i2.stability(tcx).as_ref().map(|s| s.level.is_stable()).unwrap_or(true); if is_stable1 != is_stable2 { // true is bigger than false in the standard bool ordering, // but we actually want stable items to come first return is_stable2.cmp(&is_stable1); } match (i1.name, i2.name) { (Some(name1), Some(name2)) => compare_names(name1.as_str(), name2.as_str()), (Some(_), None) => Ordering::Greater, (None, Some(_)) => Ordering::Less, (None, None) => Ordering::Equal, } } let tcx = cx.tcx(); match cx.shared.module_sorting { ModuleSorting::Alphabetical => { not_stripped_items.sort_by(|(_, i1), (_, i2)| cmp(i1, i2, tcx)); } ModuleSorting::DeclarationOrder => {} } // This call is to remove re-export duplicates in cases such as: // // ``` // pub(crate) mod foo { // pub(crate) mod bar { // pub(crate) trait Double { fn foo(); } // } // } // // pub(crate) use foo::bar::*; // pub(crate) use foo::*; // ``` // // `Double` will appear twice in the generated docs. // // FIXME: This code is quite ugly and could be improved. Small issue: DefId // can be identical even if the elements are different (mostly in imports). // So in case this is an import, we keep everything by adding a "unique id" // (which is the position in the vector). not_stripped_items.dedup_by_key(|(idx, i)| { ( i.item_id, if i.name.is_some() { Some(full_path(cx, i)) } else { None }, i.type_(), if i.is_import() { *idx } else { 0 }, ) }); debug!("{not_stripped_items:?}"); let mut last_section = None; for (_, myitem) in ¬_stripped_items { let my_section = item_ty_to_section(myitem.type_()); if Some(my_section) != last_section { if last_section.is_some() { w.write_str(ITEM_TABLE_CLOSE)?; } last_section = Some(my_section); let section_id = my_section.id(); let tag = if section_id == "reexports" { REEXPORTS_TABLE_OPEN } else { ITEM_TABLE_OPEN }; write!( w, "{}", write_section_heading(my_section.name(), &cx.derive_id(section_id), None, tag) )?; } match myitem.kind { clean::ExternCrateItem { ref src } => { use crate::html::format::print_anchor; match *src { Some(src) => { write!( w, "
{}extern crate {} as {};", visibility_print_with_space(myitem, cx), print_anchor(myitem.item_id.expect_def_id(), src, cx), EscapeBodyTextWithWbr(myitem.name.unwrap().as_str()) )?; } None => { write!( w, "
{}extern crate {};", visibility_print_with_space(myitem, cx), print_anchor( myitem.item_id.expect_def_id(), myitem.name.unwrap(), cx ) )?; } } w.write_str("
")?; } clean::ImportItem(ref import) => { let stab_tags = import.source.did.map_or_else(String::new, |import_def_id| { print_extra_info_tags(tcx, myitem, item, Some(import_def_id)).to_string() }); let id = match import.kind { clean::ImportKind::Simple(s) => { format!(" id=\"{}\"", cx.derive_id(format!("reexport.{s}"))) } clean::ImportKind::Glob => String::new(), }; write!( w, "\ " )?; render_attributes_in_code(w, myitem, "", cx); write!( w, "{vis}{imp}{stab_tags}\ ", vis = visibility_print_with_space(myitem, cx), imp = import.print(cx) )?; } _ => { if myitem.name.is_none() { continue; } let unsafety_flag = match myitem.kind { clean::FunctionItem(_) | clean::ForeignFunctionItem(..) if myitem.fn_header(tcx).unwrap().safety == hir::HeaderSafety::Normal(hir::Safety::Unsafe) => { "โš " } clean::ForeignStaticItem(_, hir::Safety::Unsafe) => { "โš " } _ => "", }; let visibility_and_hidden = match myitem.visibility(tcx) { Some(ty::Visibility::Restricted(_)) => { if myitem.is_doc_hidden() { // Don't separate with a space when there are two of them " ๐Ÿ”’๐Ÿ‘ป " } else { " ๐Ÿ”’ " } } _ if myitem.is_doc_hidden() => { " ๐Ÿ‘ป " } _ => "", }; let docs = MarkdownSummaryLine(&myitem.doc_value(), &myitem.links(cx)).into_string(); let (docs_before, docs_after) = if docs.is_empty() { ("", "") } else { ("
", "
") }; write!( w, "
\ \ {name}\ \ {visibility_and_hidden}\ {unsafety_flag}\ {stab_tags}\
\ {docs_before}{docs}{docs_after}", name = EscapeBodyTextWithWbr(myitem.name.unwrap().as_str()), visibility_and_hidden = visibility_and_hidden, stab_tags = print_extra_info_tags(tcx, myitem, item, None), class = myitem.type_(), unsafety_flag = unsafety_flag, href = print_item_path(myitem.type_(), myitem.name.unwrap().as_str()), title1 = myitem.type_(), title2 = full_path(cx, myitem), )?; } } } if last_section.is_some() { w.write_str(ITEM_TABLE_CLOSE)?; } Ok(()) }) } /// Render the stability, deprecation and portability tags that are displayed in the item's summary /// at the module level. fn print_extra_info_tags( tcx: TyCtxt<'_>, item: &clean::Item, parent: &clean::Item, import_def_id: Option, ) -> impl Display { fmt::from_fn(move |f| { fn tag_html(class: &str, title: &str, contents: &str) -> impl Display { fmt::from_fn(move |f| { write!( f, r#"{contents}"#, title = Escape(title), ) }) } // The trailing space after each tag is to space it properly against the rest of the docs. let deprecation = import_def_id .map_or_else(|| item.deprecation(tcx), |import_did| tcx.lookup_deprecation(import_did)); if let Some(depr) = deprecation { let message = if depr.is_in_effect() { "Deprecated" } else { "Deprecation planned" }; write!(f, "{}", tag_html("deprecated", "", message))?; } // The "rustc_private" crates are permanently unstable so it makes no sense // to render "unstable" everywhere. let stability = import_def_id .map_or_else(|| item.stability(tcx), |import_did| tcx.lookup_stability(import_did)); if stability.is_some_and(|s| s.is_unstable() && s.feature != sym::rustc_private) { write!(f, "{}", tag_html("unstable", "", "Experimental"))?; } let cfg = match (&item.cfg, parent.cfg.as_ref()) { (Some(cfg), Some(parent_cfg)) => cfg.simplify_with(parent_cfg), (cfg, _) => cfg.as_deref().cloned(), }; debug!( "Portability name={name:?} {cfg:?} - {parent_cfg:?} = {cfg:?}", name = item.name, cfg = item.cfg, parent_cfg = parent.cfg ); if let Some(ref cfg) = cfg { write!( f, "{}", tag_html("portability", &cfg.render_long_plain(), &cfg.render_short_html()) ) } else { Ok(()) } }) } fn item_function(cx: &Context<'_>, it: &clean::Item, f: &clean::Function) -> impl fmt::Display { fmt::from_fn(|w| { let tcx = cx.tcx(); let header = it.fn_header(tcx).expect("printing a function which isn't a function"); debug!( "item_function/const: {:?} {:?} {:?} {:?}", it.name, &header.constness, it.stable_since(tcx), it.const_stability(tcx), ); let constness = print_constness_with_space( &header.constness, it.stable_since(tcx), it.const_stability(tcx), ); let safety = header.safety.print_with_space(); let abi = print_abi_with_space(header.abi).to_string(); let asyncness = header.asyncness.print_with_space(); let visibility = visibility_print_with_space(it, cx).to_string(); let name = it.name.unwrap(); let generics_len = format!("{:#}", f.generics.print(cx)).len(); let header_len = "fn ".len() + visibility.len() + constness.len() + asyncness.len() + safety.len() + abi.len() + name.as_str().len() + generics_len; let notable_traits = notable_traits_button(&f.decl.output, cx).maybe_display(); wrap_item(w, |w| { render_attributes_in_code(w, it, "", cx); write!( w, "{vis}{constness}{asyncness}{safety}{abi}fn \ {name}{generics}{decl}{notable_traits}{where_clause}", vis = visibility, constness = constness, asyncness = asyncness, safety = safety, abi = abi, name = name, generics = f.generics.print(cx), where_clause = print_where_clause(&f.generics, cx, 0, Ending::Newline).maybe_display(), decl = f.decl.full_print(header_len, 0, cx), ) })?; write!(w, "{}", document(cx, it, None, HeadingOffset::H2)) }) } fn item_trait(cx: &Context<'_>, it: &clean::Item, t: &clean::Trait) -> impl fmt::Display { fmt::from_fn(|w| { let tcx = cx.tcx(); let bounds = print_bounds(&t.bounds, false, cx); let required_types = t.items.iter().filter(|m| m.is_required_associated_type()).collect::>(); let provided_types = t.items.iter().filter(|m| m.is_associated_type()).collect::>(); let required_consts = t.items.iter().filter(|m| m.is_required_associated_const()).collect::>(); let provided_consts = t.items.iter().filter(|m| m.is_associated_const()).collect::>(); let required_methods = t.items.iter().filter(|m| m.is_ty_method()).collect::>(); let provided_methods = t.items.iter().filter(|m| m.is_method()).collect::>(); let count_types = required_types.len() + provided_types.len(); let count_consts = required_consts.len() + provided_consts.len(); let count_methods = required_methods.len() + provided_methods.len(); let must_implement_one_of_functions = &tcx.trait_def(t.def_id).must_implement_one_of; // Output the trait definition wrap_item(w, |mut w| { render_attributes_in_code(&mut w, it, "", cx); write!( w, "{vis}{safety}{is_auto}trait {name}{generics}{bounds}", vis = visibility_print_with_space(it, cx), safety = t.safety(tcx).print_with_space(), is_auto = if t.is_auto(tcx) { "auto " } else { "" }, name = it.name.unwrap(), generics = t.generics.print(cx), )?; if !t.generics.where_predicates.is_empty() { write!( w, "{}", print_where_clause(&t.generics, cx, 0, Ending::Newline).maybe_display() )?; } else { w.write_char(' ')?; } if t.items.is_empty() { w.write_str("{ }") } else { // FIXME: we should be using a derived_id for the Anchors here w.write_str("{\n")?; let mut toggle = false; // If there are too many associated types, hide _everything_ if should_hide_fields(count_types) { toggle = true; toggle_open( &mut w, format_args!( "{} associated items", count_types + count_consts + count_methods ), ); } for types in [&required_types, &provided_types] { for t in types { writeln!( w, "{};", render_assoc_item( t, AssocItemLink::Anchor(None), ItemType::Trait, cx, RenderMode::Normal, ) )?; } } // If there are too many associated constants, hide everything after them // We also do this if the types + consts is large because otherwise we could // render a bunch of types and _then_ a bunch of consts just because both were // _just_ under the limit if !toggle && should_hide_fields(count_types + count_consts) { toggle = true; toggle_open( &mut w, format_args!( "{count_consts} associated constant{plural_const} and \ {count_methods} method{plural_method}", plural_const = pluralize(count_consts), plural_method = pluralize(count_methods), ), ); } if count_types != 0 && (count_consts != 0 || count_methods != 0) { w.write_str("\n")?; } for consts in [&required_consts, &provided_consts] { for c in consts { writeln!( w, "{};", render_assoc_item( c, AssocItemLink::Anchor(None), ItemType::Trait, cx, RenderMode::Normal, ) )?; } } if !toggle && should_hide_fields(count_methods) { toggle = true; toggle_open(&mut w, format_args!("{count_methods} methods")); } if count_consts != 0 && count_methods != 0 { w.write_str("\n")?; } if !required_methods.is_empty() { writeln!(w, " // Required method{}", pluralize(required_methods.len()))?; } for (pos, m) in required_methods.iter().enumerate() { writeln!( w, "{};", render_assoc_item( m, AssocItemLink::Anchor(None), ItemType::Trait, cx, RenderMode::Normal, ) )?; if pos < required_methods.len() - 1 { w.write_str("")?; } } if !required_methods.is_empty() && !provided_methods.is_empty() { w.write_str("\n")?; } if !provided_methods.is_empty() { writeln!(w, " // Provided method{}", pluralize(provided_methods.len()))?; } for (pos, m) in provided_methods.iter().enumerate() { writeln!( w, "{} {{ ... }}", render_assoc_item( m, AssocItemLink::Anchor(None), ItemType::Trait, cx, RenderMode::Normal, ) )?; if pos < provided_methods.len() - 1 { w.write_str("")?; } } if toggle { toggle_close(&mut w); } w.write_str("}") } })?; // Trait documentation write!(w, "{}", document(cx, it, None, HeadingOffset::H2))?; fn trait_item(cx: &Context<'_>, m: &clean::Item, t: &clean::Item) -> impl fmt::Display { fmt::from_fn(|w| { let name = m.name.unwrap(); info!("Documenting {name} on {ty_name:?}", ty_name = t.name); let item_type = m.type_(); let id = cx.derive_id(format!("{item_type}.{name}")); let content = document_full(m, cx, HeadingOffset::H5).to_string(); let toggled = !content.is_empty(); if toggled { let method_toggle_class = if item_type.is_method() { " method-toggle" } else { "" }; write!(w, "
")?; } write!( w, "
\ {}\

{}

", render_rightside(cx, m, RenderMode::Normal), render_assoc_item( m, AssocItemLink::Anchor(Some(&id)), ItemType::Impl, cx, RenderMode::Normal, ) )?; document_item_info(cx, m, Some(t)).render_into(w).unwrap(); if toggled { write!(w, "{content}
")?; } Ok(()) }) } if !required_consts.is_empty() { write!( w, "{}", write_section_heading( "Required Associated Constants", "required-associated-consts", None, "
", ) )?; for t in required_consts { write!(w, "{}", trait_item(cx, t, it))?; } w.write_str("
")?; } if !provided_consts.is_empty() { write!( w, "{}", write_section_heading( "Provided Associated Constants", "provided-associated-consts", None, "
", ) )?; for t in provided_consts { write!(w, "{}", trait_item(cx, t, it))?; } w.write_str("
")?; } if !required_types.is_empty() { write!( w, "{}", write_section_heading( "Required Associated Types", "required-associated-types", None, "
", ) )?; for t in required_types { write!(w, "{}", trait_item(cx, t, it))?; } w.write_str("
")?; } if !provided_types.is_empty() { write!( w, "{}", write_section_heading( "Provided Associated Types", "provided-associated-types", None, "
", ) )?; for t in provided_types { write!(w, "{}", trait_item(cx, t, it))?; } w.write_str("
")?; } // Output the documentation for each function individually if !required_methods.is_empty() || must_implement_one_of_functions.is_some() { write!( w, "{}", write_section_heading( "Required Methods", "required-methods", None, "
", ) )?; if let Some(list) = must_implement_one_of_functions.as_deref() { write!( w, "
At least one of the `{}` methods is required.
", fmt::from_fn(|f| list.iter().joined("`, `", f)), )?; } for m in required_methods { write!(w, "{}", trait_item(cx, m, it))?; } w.write_str("
")?; } if !provided_methods.is_empty() { write!( w, "{}", write_section_heading( "Provided Methods", "provided-methods", None, "
", ) )?; for m in provided_methods { write!(w, "{}", trait_item(cx, m, it))?; } w.write_str("
")?; } // If there are methods directly on this trait object, render them here. write!( w, "{}", render_assoc_items(cx, it, it.item_id.expect_def_id(), AssocItemRender::All) )?; let mut extern_crates = FxIndexSet::default(); if !t.is_dyn_compatible(cx.tcx()) { write!( w, "{}", write_section_heading( "Dyn Compatibility", "dyn-compatibility", None, format!( "

This trait is not \ dyn compatible.

\

In older versions of Rust, dyn compatibility was called \"object safety\", \ so this trait is not object safe.

", base = crate::clean::utils::DOC_RUST_LANG_ORG_VERSION ), ), )?; } if let Some(implementors) = cx.shared.cache.implementors.get(&it.item_id.expect_def_id()) { // The DefId is for the first Type found with that name. The bool is // if any Types with the same name but different DefId have been found. let mut implementor_dups: FxHashMap = FxHashMap::default(); for implementor in implementors { if let Some(did) = implementor.inner_impl().for_.without_borrowed_ref().def_id(&cx.shared.cache) && !did.is_local() { extern_crates.insert(did.krate); } match implementor.inner_impl().for_.without_borrowed_ref() { clean::Type::Path { path } if !path.is_assoc_ty() => { let did = path.def_id(); let &mut (prev_did, ref mut has_duplicates) = implementor_dups.entry(path.last()).or_insert((did, false)); if prev_did != did { *has_duplicates = true; } } _ => {} } } let (local, mut foreign) = implementors.iter().partition::, _>(|i| i.is_on_local_type(cx)); let (mut synthetic, mut concrete): (Vec<&&Impl>, Vec<&&Impl>) = local.iter().partition(|i| i.inner_impl().kind.is_auto()); synthetic.sort_by_cached_key(|i| ImplString::new(i, cx)); concrete.sort_by_cached_key(|i| ImplString::new(i, cx)); foreign.sort_by_cached_key(|i| ImplString::new(i, cx)); if !foreign.is_empty() { write!( w, "{}", write_section_heading( "Implementations on Foreign Types", "foreign-impls", None, "" ) )?; for implementor in foreign { let provided_methods = implementor.inner_impl().provided_trait_methods(tcx); let assoc_link = AssocItemLink::GotoSource(implementor.impl_item.item_id, &provided_methods); write!( w, "{}", render_impl( cx, implementor, it, assoc_link, RenderMode::Normal, None, &[], ImplRenderingParameters { show_def_docs: false, show_default_items: false, show_non_assoc_items: true, toggle_open_by_default: false, }, ) )?; } } write!( w, "{}", write_section_heading( "Implementors", "implementors", None, "
", ) )?; for implementor in concrete { write!(w, "{}", render_implementor(cx, implementor, it, &implementor_dups, &[]))?; } w.write_str("
")?; if t.is_auto(tcx) { write!( w, "{}", write_section_heading( "Auto implementors", "synthetic-implementors", None, "
", ) )?; for implementor in synthetic { write!( w, "{}", render_implementor( cx, implementor, it, &implementor_dups, &collect_paths_for_type( &implementor.inner_impl().for_, &cx.shared.cache, ), ) )?; } w.write_str("
")?; } } else { // even without any implementations to write in, we still want the heading and list, so the // implementors javascript file pulled in below has somewhere to write the impls into write!( w, "{}", write_section_heading( "Implementors", "implementors", None, "
", ) )?; if t.is_auto(tcx) { write!( w, "{}", write_section_heading( "Auto implementors", "synthetic-implementors", None, "
", ) )?; } } // [RUSTDOCIMPL] trait.impl // // Include implementors in crates that depend on the current crate. // // This is complicated by the way rustdoc is invoked, which is basically // the same way rustc is invoked: it gets called, one at a time, for each // crate. When building the rustdocs for the current crate, rustdoc can // see crate metadata for its dependencies, but cannot see metadata for its // dependents. // // To make this work, we generate a "hook" at this stage, and our // dependents can "plug in" to it when they build. For simplicity's sake, // it's [JSONP]: a JavaScript file with the data we need (and can parse), // surrounded by a tiny wrapper that the Rust side ignores, but allows the // JavaScript side to include without having to worry about Same Origin // Policy. The code for *that* is in `write_shared.rs`. // // This is further complicated by `#[doc(inline)]`. We want all copies // of an inlined trait to reference the same JS file, to address complex // dependency graphs like this one (lower crates depend on higher crates): // // ```text // -------------------------------------------- // | crate A: trait Foo | // -------------------------------------------- // | | // -------------------------------- | // | crate B: impl A::Foo for Bar | | // -------------------------------- | // | | // --------------------------------------------- // | crate C: #[doc(inline)] use A::Foo as Baz | // | impl Baz for Quux | // --------------------------------------------- // ``` // // Basically, we want `C::Baz` and `A::Foo` to show the same set of // impls, which is easier if they both treat `/trait.impl/A/trait.Foo.js` // as the Single Source of Truth. // // We also want the `impl Baz for Quux` to be written to // `trait.Foo.js`. However, when we generate plain HTML for `C::Baz`, // we're going to want to generate plain HTML for `impl Baz for Quux` too, // because that'll load faster, and it's better for SEO. And we don't want // the same impl to show up twice on the same page. // // To make this work, the trait.impl/A/trait.Foo.js JS file has a structure kinda // like this: // // ```js // JSONP({ // "B": {"impl A::Foo for Bar"}, // "C": {"impl Baz for Quux"}, // }); // ``` // // First of all, this means we can rebuild a crate, and it'll replace its own // data if something changes. That is, `rustdoc` is idempotent. The other // advantage is that we can list the crates that get included in the HTML, // and ignore them when doing the JavaScript-based part of rendering. // So C's HTML will have something like this: // // ```html // // ``` // // And, when the JS runs, anything in data-ignore-extern-crates is known // to already be in the HTML, and will be ignored. // // [JSONP]: https://en.wikipedia.org/wiki/JSONP let mut js_src_path: UrlPartsBuilder = iter::repeat_n("..", cx.current.len()).chain(iter::once("trait.impl")).collect(); if let Some(did) = it.item_id.as_def_id() && let get_extern = { || cx.shared.cache.external_paths.get(&did).map(|s| &s.0) } && let Some(fqp) = cx.shared.cache.exact_paths.get(&did).or_else(get_extern) { js_src_path.extend(fqp[..fqp.len() - 1].iter().copied()); js_src_path.push_fmt(format_args!("{}.{}.js", it.type_(), fqp.last().unwrap())); } else { js_src_path.extend(cx.current.iter().copied()); js_src_path.push_fmt(format_args!("{}.{}.js", it.type_(), it.name.unwrap())); } let extern_crates = fmt::from_fn(|f| { if !extern_crates.is_empty() { f.write_str(" data-ignore-extern-crates=\"")?; extern_crates.iter().map(|&cnum| tcx.crate_name(cnum)).joined(",", f)?; f.write_str("\"")?; } Ok(()) }); write!( w, "", src = js_src_path.finish() ) }) } fn item_trait_alias( cx: &Context<'_>, it: &clean::Item, t: &clean::TraitAlias, ) -> impl fmt::Display { fmt::from_fn(|w| { wrap_item(w, |w| { render_attributes_in_code(w, it, "", cx); write!( w, "trait {name}{generics} = {bounds}{where_clause};", name = it.name.unwrap(), generics = t.generics.print(cx), bounds = print_bounds(&t.bounds, true, cx), where_clause = print_where_clause(&t.generics, cx, 0, Ending::NoNewline).maybe_display(), ) })?; write!(w, "{}", document(cx, it, None, HeadingOffset::H2))?; // Render any items associated directly to this alias, as otherwise they // won't be visible anywhere in the docs. It would be nice to also show // associated items from the aliased type (see discussion in #32077), but // we need #14072 to make sense of the generics. write!( w, "{}", render_assoc_items(cx, it, it.item_id.expect_def_id(), AssocItemRender::All) ) }) } fn item_type_alias(cx: &Context<'_>, it: &clean::Item, t: &clean::TypeAlias) -> impl fmt::Display { fmt::from_fn(|w| { wrap_item(w, |w| { render_attributes_in_code(w, it, "", cx); write!( w, "{vis}type {name}{generics}{where_clause} = {type_};", vis = visibility_print_with_space(it, cx), name = it.name.unwrap(), generics = t.generics.print(cx), where_clause = print_where_clause(&t.generics, cx, 0, Ending::Newline).maybe_display(), type_ = t.type_.print(cx), ) })?; write!(w, "{}", document(cx, it, None, HeadingOffset::H2))?; if let Some(inner_type) = &t.inner_type { write!(w, "{}", write_section_heading("Aliased Type", "aliased-type", None, ""),)?; match inner_type { clean::TypeAliasInnerType::Enum { variants, is_non_exhaustive } => { let ty = cx.tcx().type_of(it.def_id().unwrap()).instantiate_identity(); let enum_def_id = ty.ty_adt_def().unwrap().did(); DisplayEnum { variants, generics: &t.generics, is_non_exhaustive: *is_non_exhaustive, def_id: enum_def_id, } .render_into(cx, it, true, w)?; } clean::TypeAliasInnerType::Union { fields } => { let ty = cx.tcx().type_of(it.def_id().unwrap()).instantiate_identity(); let union_def_id = ty.ty_adt_def().unwrap().did(); ItemUnion { cx, it, fields, generics: &t.generics, is_type_alias: true, def_id: union_def_id, } .render_into(w)?; } clean::TypeAliasInnerType::Struct { ctor_kind, fields } => { let ty = cx.tcx().type_of(it.def_id().unwrap()).instantiate_identity(); let struct_def_id = ty.ty_adt_def().unwrap().did(); DisplayStruct { ctor_kind: *ctor_kind, generics: &t.generics, fields, def_id: struct_def_id, } .render_into(cx, it, true, w)?; } } } else { let def_id = it.item_id.expect_def_id(); // Render any items associated directly to this alias, as otherwise they // won't be visible anywhere in the docs. It would be nice to also show // associated items from the aliased type (see discussion in #32077), but // we need #14072 to make sense of the generics. write!( w, "{}{}", render_assoc_items(cx, it, def_id, AssocItemRender::All), document_type_layout(cx, def_id) )?; } // [RUSTDOCIMPL] type.impl // // Include type definitions from the alias target type. // // Earlier versions of this code worked by having `render_assoc_items` // include this data directly. That generates *O*`(types*impls)` of HTML // text, and some real crates have a lot of types and impls. // // To create the same UX without generating half a gigabyte of HTML for a // crate that only contains 20 megabytes of actual documentation[^115718], // rustdoc stashes these type-alias-inlined docs in a [JSONP] // "database-lite". The file itself is generated in `write_shared.rs`, // and hooks into functions provided by `main.js`. // // The format of `trait.impl` and `type.impl` JS files are superficially // similar. Each line, except the JSONP wrapper itself, belongs to a crate, // and they are otherwise separate (rustdoc should be idempotent). The // "meat" of the file is HTML strings, so the frontend code is very simple. // Links are relative to the doc root, though, so the frontend needs to fix // that up, and inlined docs can reuse these files. // // However, there are a few differences, caused by the sophisticated // features that type aliases have. Consider this crate graph: // // ```text // --------------------------------- // | crate A: struct Foo | // | type Bar = Foo | // | impl X for Foo | // | impl Y for Foo | // --------------------------------- // | // ---------------------------------- // | crate B: type Baz = A::Foo | // | type Xyy = A::Foo | // | impl Z for Xyy | // ---------------------------------- // ``` // // The type.impl/A/struct.Foo.js JS file has a structure kinda like this: // // ```js // JSONP({ // "A": [["impl Y for Foo", "Y", "A::Bar"]], // "B": [["impl X for Foo", "X", "B::Baz", "B::Xyy"], ["impl Z for Xyy", "Z", "B::Baz"]], // }); // ``` // // When the type.impl file is loaded, only the current crate's docs are // actually used. The main reason to bundle them together is that there's // enough duplication in them for DEFLATE to remove the redundancy. // // The contents of a crate are a list of impl blocks, themselves // represented as lists. The first item in the sublist is the HTML block, // the second item is the name of the trait (which goes in the sidebar), // and all others are the names of type aliases that successfully match. // // This way: // // - There's no need to generate these files for types that have no aliases // in the current crate. If a dependent crate makes a type alias, it'll // take care of generating its own docs. // - There's no need to reimplement parts of the type checker in // JavaScript. The Rust backend does the checking, and includes its // results in the file. // - Docs defined directly on the type alias are dropped directly in the // HTML by `render_assoc_items`, and are accessible without JavaScript. // The JSONP file will not list impl items that are known to be part // of the main HTML file already. // // [JSONP]: https://en.wikipedia.org/wiki/JSONP // [^115718]: https://github.com/rust-lang/rust/issues/115718 let cache = &cx.shared.cache; if let Some(target_did) = t.type_.def_id(cache) && let get_extern = { || cache.external_paths.get(&target_did) } && let Some(&(ref target_fqp, target_type)) = cache.paths.get(&target_did).or_else(get_extern) && target_type.is_adt() // primitives cannot be inlined && let Some(self_did) = it.item_id.as_def_id() && let get_local = { || cache.paths.get(&self_did).map(|(p, _)| p) } && let Some(self_fqp) = cache.exact_paths.get(&self_did).or_else(get_local) { let mut js_src_path: UrlPartsBuilder = iter::repeat_n("..", cx.current.len()).chain(iter::once("type.impl")).collect(); js_src_path.extend(target_fqp[..target_fqp.len() - 1].iter().copied()); js_src_path.push_fmt(format_args!("{target_type}.{}.js", target_fqp.last().unwrap())); let self_path = join_path_syms(self_fqp); write!( w, "", src = js_src_path.finish(), )?; } Ok(()) }) } item_template!( #[template(path = "item_union.html")] struct ItemUnion<'a, 'cx> { cx: &'a Context<'cx>, it: &'a clean::Item, fields: &'a [clean::Item], generics: &'a clean::Generics, is_type_alias: bool, def_id: DefId, }, methods = [document, document_type_layout, render_assoc_items] ); impl<'a, 'cx: 'a> ItemUnion<'a, 'cx> { fn render_union(&self) -> impl Display { render_union( self.it, Some(self.generics), self.fields, self.def_id, self.is_type_alias, self.cx, ) } fn print_field_attrs(&self, field: &'a clean::Item) -> impl Display { fmt::from_fn(move |w| { render_attributes_in_code(w, field, "", self.cx); Ok(()) }) } fn document_field(&self, field: &'a clean::Item) -> impl Display { document(self.cx, field, Some(self.it), HeadingOffset::H3) } fn stability_field(&self, field: &clean::Item) -> Option { field.stability_class(self.cx.tcx()) } fn print_ty(&self, ty: &'a clean::Type) -> impl Display { ty.print(self.cx) } // FIXME (GuillaumeGomez): When is implemented, // we can replace the returned value with: // // `iter::Peekable>` // // And update `item_union.html`. fn fields_iter(&self) -> impl Iterator { self.fields.iter().filter_map(|f| match f.kind { clean::StructFieldItem(ref ty) => Some((f, ty)), _ => None, }) } } fn item_union(cx: &Context<'_>, it: &clean::Item, s: &clean::Union) -> impl fmt::Display { fmt::from_fn(|w| { ItemUnion { cx, it, fields: &s.fields, generics: &s.generics, is_type_alias: false, def_id: it.def_id().unwrap(), } .render_into(w)?; Ok(()) }) } fn print_tuple_struct_fields(cx: &Context<'_>, s: &[clean::Item]) -> impl Display { fmt::from_fn(|f| { if !s.is_empty() && s.iter().all(|field| { matches!(field.kind, clean::StrippedItem(box clean::StructFieldItem(..))) }) { return f.write_str("/* private fields */"); } s.iter() .map(|ty| { fmt::from_fn(|f| match ty.kind { clean::StrippedItem(box clean::StructFieldItem(_)) => f.write_str("_"), clean::StructFieldItem(ref ty) => write!(f, "{}", ty.print(cx)), _ => unreachable!(), }) }) .joined(", ", f) }) } struct DisplayEnum<'clean> { variants: &'clean IndexVec, generics: &'clean clean::Generics, is_non_exhaustive: bool, def_id: DefId, } impl<'clean> DisplayEnum<'clean> { fn render_into( self, cx: &Context<'_>, it: &clean::Item, is_type_alias: bool, w: &mut W, ) -> fmt::Result { let non_stripped_variant_count = self.variants.iter().filter(|i| !i.is_stripped()).count(); let variants_len = self.variants.len(); let has_stripped_entries = variants_len != non_stripped_variant_count; wrap_item(w, |w| { if is_type_alias { // For now the only attributes we render for type aliases are `repr` attributes. render_repr_attribute_in_code(w, cx, self.def_id); } else { render_attributes_in_code(w, it, "", cx); } write!( w, "{}enum {}{}{}", visibility_print_with_space(it, cx), it.name.unwrap(), self.generics.print(cx), render_enum_fields( cx, Some(self.generics), self.variants, non_stripped_variant_count, has_stripped_entries, self.is_non_exhaustive, self.def_id, ), ) })?; let def_id = it.item_id.expect_def_id(); let layout_def_id = if is_type_alias { self.def_id } else { write!(w, "{}", document(cx, it, None, HeadingOffset::H2))?; // We don't return the same `DefId` since the layout size of the type alias might be // different since we might have more information on the generics. def_id }; if non_stripped_variant_count != 0 { write!(w, "{}", item_variants(cx, it, self.variants, self.def_id))?; } write!( w, "{}{}", render_assoc_items(cx, it, def_id, AssocItemRender::All), document_type_layout(cx, layout_def_id) ) } } fn item_enum(cx: &Context<'_>, it: &clean::Item, e: &clean::Enum) -> impl fmt::Display { fmt::from_fn(|w| { DisplayEnum { variants: &e.variants, generics: &e.generics, is_non_exhaustive: it.is_non_exhaustive(), def_id: it.def_id().unwrap(), } .render_into(cx, it, false, w) }) } /// It'll return false if any variant is not a C-like variant. Otherwise it'll return true if at /// least one of them has an explicit discriminant or if the enum has `#[repr(C)]` or an integer /// `repr`. fn should_show_enum_discriminant( cx: &Context<'_>, enum_def_id: DefId, variants: &IndexVec, ) -> bool { let mut has_variants_with_value = false; for variant in variants { if let clean::VariantItem(ref var) = variant.kind && matches!(var.kind, clean::VariantKind::CLike) { has_variants_with_value |= var.discriminant.is_some(); } else { return false; } } if has_variants_with_value { return true; } let repr = cx.tcx().adt_def(enum_def_id).repr(); repr.c() || repr.int.is_some() } fn display_c_like_variant( cx: &Context<'_>, item: &clean::Item, variant: &clean::Variant, index: VariantIdx, should_show_enum_discriminant: bool, enum_def_id: DefId, ) -> impl fmt::Display { fmt::from_fn(move |w| { let name = item.name.unwrap(); if let Some(ref value) = variant.discriminant { write!(w, "{} = {}", name.as_str(), value.value(cx.tcx(), true))?; } else if should_show_enum_discriminant { let adt_def = cx.tcx().adt_def(enum_def_id); let discr = adt_def.discriminant_for_variant(cx.tcx(), index); // Use `discr`'s `Display` impl to render the value with the correct // signedness, including proper sign-extension for signed types. write!(w, "{} = {}", name.as_str(), discr)?; } else { write!(w, "{name}")?; } Ok(()) }) } fn render_enum_fields( cx: &Context<'_>, g: Option<&clean::Generics>, variants: &IndexVec, count_variants: usize, has_stripped_entries: bool, is_non_exhaustive: bool, enum_def_id: DefId, ) -> impl fmt::Display { fmt::from_fn(move |w| { let should_show_enum_discriminant = should_show_enum_discriminant(cx, enum_def_id, variants); if let Some(generics) = g && let Some(where_clause) = print_where_clause(generics, cx, 0, Ending::Newline) { write!(w, "{where_clause}")?; } else { // If there wasn't a `where` clause, we add a whitespace. w.write_char(' ')?; } let variants_stripped = has_stripped_entries; if count_variants == 0 && !variants_stripped { w.write_str("{}") } else { w.write_str("{\n")?; let toggle = should_hide_fields(count_variants); if toggle { toggle_open(&mut *w, format_args!("{count_variants} variants")); } const TAB: &str = " "; for (index, v) in variants.iter_enumerated() { if v.is_stripped() { continue; } render_attributes_in_code(w, v, TAB, cx); w.write_str(TAB)?; match v.kind { clean::VariantItem(ref var) => match var.kind { clean::VariantKind::CLike => { write!( w, "{}", display_c_like_variant( cx, v, var, index, should_show_enum_discriminant, enum_def_id, ) )?; } clean::VariantKind::Tuple(ref s) => { write!(w, "{}({})", v.name.unwrap(), print_tuple_struct_fields(cx, s))?; } clean::VariantKind::Struct(ref s) => { write!( w, "{}", render_struct(v, None, None, &s.fields, TAB, false, cx) )?; } }, _ => unreachable!(), } w.write_str(",\n")?; } if variants_stripped && !is_non_exhaustive { w.write_str(" // some variants omitted\n")?; } if toggle { toggle_close(&mut *w); } w.write_str("}") } }) } fn item_variants( cx: &Context<'_>, it: &clean::Item, variants: &IndexVec, enum_def_id: DefId, ) -> impl fmt::Display { fmt::from_fn(move |w| { let tcx = cx.tcx(); write!( w, "{}", write_section_heading( &format!("Variants{}", document_non_exhaustive_header(it)), "variants", Some("variants"), format!("{}
", document_non_exhaustive(it)), ), )?; let should_show_enum_discriminant = should_show_enum_discriminant(cx, enum_def_id, variants); for (index, variant) in variants.iter_enumerated() { if variant.is_stripped() { continue; } let id = cx.derive_id(format!("{}.{}", ItemType::Variant, variant.name.unwrap())); write!( w, "
\ ยง\ {}\

", render_stability_since_raw_with_extra( variant.stable_since(tcx), variant.const_stability(tcx), " rightside", ) .maybe_display() )?; render_attributes_in_code(w, variant, "", cx); if let clean::VariantItem(ref var) = variant.kind && let clean::VariantKind::CLike = var.kind { write!( w, "{}", display_c_like_variant( cx, variant, var, index, should_show_enum_discriminant, enum_def_id, ) )?; } else { w.write_str(variant.name.unwrap().as_str())?; } let clean::VariantItem(variant_data) = &variant.kind else { unreachable!() }; if let clean::VariantKind::Tuple(ref s) = variant_data.kind { write!(w, "({})", print_tuple_struct_fields(cx, s))?; } w.write_str("

")?; write!(w, "{}", document(cx, variant, Some(it), HeadingOffset::H4))?; let heading_and_fields = match &variant_data.kind { clean::VariantKind::Struct(s) => { // If there is no field to display, no need to add the heading. if s.fields.iter().any(|f| !f.is_doc_hidden()) { Some(("Fields", &s.fields)) } else { None } } clean::VariantKind::Tuple(fields) => { // Documentation on tuple variant fields is rare, so to reduce noise we only emit // the section if at least one field is documented. if fields.iter().any(|f| !f.doc_value().is_empty()) { Some(("Tuple Fields", fields)) } else { None } } clean::VariantKind::CLike => None, }; if let Some((heading, fields)) = heading_and_fields { let variant_id = cx.derive_id(format!("{}.{}.fields", ItemType::Variant, variant.name.unwrap())); write!( w, "
\

{heading}

\ {}", document_non_exhaustive(variant) )?; for field in fields { match field.kind { clean::StrippedItem(box clean::StructFieldItem(_)) => {} clean::StructFieldItem(ref ty) => { let id = cx.derive_id(format!( "variant.{}.field.{}", variant.name.unwrap(), field.name.unwrap() )); write!( w, "
\ \ ยง\ " )?; render_attributes_in_code(w, field, "", cx); write!( w, "{f}: {t}\ \ {doc}\
", f = field.name.unwrap(), t = ty.print(cx), doc = document(cx, field, Some(variant), HeadingOffset::H5), )?; } _ => unreachable!(), } } w.write_str("
")?; } } w.write_str("
") }) } fn item_macro(cx: &Context<'_>, it: &clean::Item, t: &clean::Macro) -> impl fmt::Display { fmt::from_fn(|w| { wrap_item(w, |w| { // FIXME: Also print `#[doc(hidden)]` for `macro_rules!` if it `is_doc_hidden`. render_attributes_in_code(w, it, "", cx); if !t.macro_rules { write!(w, "{}", visibility_print_with_space(it, cx))?; } write!(w, "{}", Escape(&t.source)) })?; write!(w, "{}", document(cx, it, None, HeadingOffset::H2)) }) } fn item_proc_macro(cx: &Context<'_>, it: &clean::Item, m: &clean::ProcMacro) -> impl fmt::Display { fmt::from_fn(|w| { wrap_item(w, |w| { let name = it.name.expect("proc-macros always have names"); match m.kind { MacroKind::Bang => { write!(w, "{name}!() {{ /* proc-macro */ }}")?; } MacroKind::Attr => { write!(w, "#[{name}]")?; } MacroKind::Derive => { write!(w, "#[derive({name})]")?; if !m.helpers.is_empty() { w.write_str( "\n{\n \ // Attributes available to this derive:\n", )?; for attr in &m.helpers { writeln!(w, " #[{attr}]")?; } w.write_str("}\n")?; } } } fmt::Result::Ok(()) })?; write!(w, "{}", document(cx, it, None, HeadingOffset::H2)) }) } fn item_primitive(cx: &Context<'_>, it: &clean::Item) -> impl fmt::Display { fmt::from_fn(|w| { let def_id = it.item_id.expect_def_id(); write!(w, "{}", document(cx, it, None, HeadingOffset::H2))?; if it.name.map(|n| n.as_str() != "reference").unwrap_or(false) { write!(w, "{}", render_assoc_items(cx, it, def_id, AssocItemRender::All))?; } else { // We handle the "reference" primitive type on its own because we only want to list // implementations on generic types. let (concrete, synthetic, blanket_impl) = get_filtered_impls_for_reference(&cx.shared, it); render_all_impls(w, cx, it, &concrete, &synthetic, &blanket_impl); } Ok(()) }) } fn item_constant( cx: &Context<'_>, it: &clean::Item, generics: &clean::Generics, ty: &clean::Type, c: &clean::ConstantKind, ) -> impl fmt::Display { fmt::from_fn(|w| { wrap_item(w, |w| { let tcx = cx.tcx(); render_attributes_in_code(w, it, "", cx); write!( w, "{vis}const {name}{generics}: {typ}{where_clause}", vis = visibility_print_with_space(it, cx), name = it.name.unwrap(), generics = generics.print(cx), typ = ty.print(cx), where_clause = print_where_clause(generics, cx, 0, Ending::NoNewline).maybe_display(), )?; // FIXME: The code below now prints // ` = _; // 100i32` // if the expression is // `50 + 50` // which looks just wrong. // Should we print // ` = 100i32;` // instead? let value = c.value(tcx); let is_literal = c.is_literal(tcx); let expr = c.expr(tcx); if value.is_some() || is_literal { write!(w, " = {expr};", expr = Escape(&expr))?; } else { w.write_str(";")?; } if !is_literal && let Some(value) = &value { let value_lowercase = value.to_lowercase(); let expr_lowercase = expr.to_lowercase(); if value_lowercase != expr_lowercase && value_lowercase.trim_end_matches("i32") != expr_lowercase { write!(w, " // {value}", value = Escape(value))?; } } Ok::<(), fmt::Error>(()) })?; write!(w, "{}", document(cx, it, None, HeadingOffset::H2)) }) } struct DisplayStruct<'a> { ctor_kind: Option, generics: &'a clean::Generics, fields: &'a [clean::Item], def_id: DefId, } impl<'a> DisplayStruct<'a> { fn render_into( self, cx: &Context<'_>, it: &clean::Item, is_type_alias: bool, w: &mut W, ) -> fmt::Result { wrap_item(w, |w| { if is_type_alias { // For now the only attributes we render for type aliases are `repr` attributes. render_repr_attribute_in_code(w, cx, self.def_id); } else { render_attributes_in_code(w, it, "", cx); } write!( w, "{}", render_struct(it, Some(self.generics), self.ctor_kind, self.fields, "", true, cx) ) })?; if !is_type_alias { write!(w, "{}", document(cx, it, None, HeadingOffset::H2))?; } let def_id = it.item_id.expect_def_id(); write!( w, "{}{}{}", item_fields(cx, it, self.fields, self.ctor_kind), render_assoc_items(cx, it, def_id, AssocItemRender::All), document_type_layout(cx, def_id), ) } } fn item_struct(cx: &Context<'_>, it: &clean::Item, s: &clean::Struct) -> impl fmt::Display { fmt::from_fn(|w| { DisplayStruct { ctor_kind: s.ctor_kind, generics: &s.generics, fields: s.fields.as_slice(), def_id: it.def_id().unwrap(), } .render_into(cx, it, false, w) }) } fn item_fields( cx: &Context<'_>, it: &clean::Item, fields: &[clean::Item], ctor_kind: Option, ) -> impl fmt::Display { fmt::from_fn(move |w| { let mut fields = fields .iter() .filter_map(|f| match f.kind { clean::StructFieldItem(ref ty) => Some((f, ty)), _ => None, }) .peekable(); if let None | Some(CtorKind::Fn) = ctor_kind && fields.peek().is_some() { let title = format!( "{}{}", if ctor_kind.is_none() { "Fields" } else { "Tuple Fields" }, document_non_exhaustive_header(it), ); write!( w, "{}", write_section_heading( &title, "fields", Some("fields"), document_non_exhaustive(it) ) )?; for (index, (field, ty)) in fields.enumerate() { let field_name = field.name.map_or_else(|| index.to_string(), |sym| sym.as_str().to_string()); let id = cx.derive_id(format!("{typ}.{field_name}", typ = ItemType::StructField)); write!( w, "\ ยง\ ", item_type = ItemType::StructField, )?; render_attributes_in_code(w, field, "", cx); write!( w, "{field_name}: {ty}\ \ {doc}", ty = ty.print(cx), doc = document(cx, field, Some(it), HeadingOffset::H3), )?; } } Ok(()) }) } fn item_static( cx: &Context<'_>, it: &clean::Item, s: &clean::Static, safety: Option, ) -> impl fmt::Display { fmt::from_fn(move |w| { wrap_item(w, |w| { render_attributes_in_code(w, it, "", cx); write!( w, "{vis}{safe}static {mutability}{name}: {typ}", vis = visibility_print_with_space(it, cx), safe = safety.map(|safe| safe.prefix_str()).unwrap_or(""), mutability = s.mutability.print_with_space(), name = it.name.unwrap(), typ = s.type_.print(cx) ) })?; write!(w, "{}", document(cx, it, None, HeadingOffset::H2)) }) } fn item_foreign_type(cx: &Context<'_>, it: &clean::Item) -> impl fmt::Display { fmt::from_fn(|w| { wrap_item(w, |w| { w.write_str("extern {\n")?; render_attributes_in_code(w, it, "", cx); write!(w, " {}type {};\n}}", visibility_print_with_space(it, cx), it.name.unwrap(),) })?; write!( w, "{}{}", document(cx, it, None, HeadingOffset::H2), render_assoc_items(cx, it, it.item_id.expect_def_id(), AssocItemRender::All) ) }) } fn item_keyword_or_attribute(cx: &Context<'_>, it: &clean::Item) -> impl fmt::Display { document(cx, it, None, HeadingOffset::H2) } /// Compare two strings treating multi-digit numbers as single units (i.e. natural sort order). /// /// This code is copied from [`rustfmt`], and should probably be released as a crate at some point. /// /// [`rustfmt`]:https://github.com/rust-lang/rustfmt/blob/rustfmt-2.0.0-rc.2/src/formatting/reorder.rs#L32 pub(crate) fn compare_names(left: &str, right: &str) -> Ordering { let mut left = left.chars().peekable(); let mut right = right.chars().peekable(); loop { // The strings are equal so far and not inside a number in both sides let (l, r) = match (left.next(), right.next()) { // Is this the end of both strings? (None, None) => return Ordering::Equal, // If for one, the shorter one is considered smaller (None, Some(_)) => return Ordering::Less, (Some(_), None) => return Ordering::Greater, (Some(l), Some(r)) => (l, r), }; let next_ordering = match (l.to_digit(10), r.to_digit(10)) { // If neither is a digit, just compare them (None, None) => Ord::cmp(&l, &r), // The one with shorter non-digit run is smaller // For `strverscmp` it's smaller iff next char in longer is greater than digits (None, Some(_)) => Ordering::Greater, (Some(_), None) => Ordering::Less, // If both start numbers, we have to compare the numbers (Some(l), Some(r)) => { if l == 0 || r == 0 { // Fraction mode: compare as if there was leading `0.` let ordering = Ord::cmp(&l, &r); if ordering != Ordering::Equal { return ordering; } loop { // Get next pair let (l, r) = match (left.peek(), right.peek()) { // Is this the end of both strings? (None, None) => return Ordering::Equal, // If for one, the shorter one is considered smaller (None, Some(_)) => return Ordering::Less, (Some(_), None) => return Ordering::Greater, (Some(l), Some(r)) => (l, r), }; // Are they digits? match (l.to_digit(10), r.to_digit(10)) { // If out of digits, use the stored ordering due to equal length (None, None) => break Ordering::Equal, // If one is shorter, it's smaller (None, Some(_)) => return Ordering::Less, (Some(_), None) => return Ordering::Greater, // If both are digits, consume them and take into account (Some(l), Some(r)) => { left.next(); right.next(); let ordering = Ord::cmp(&l, &r); if ordering != Ordering::Equal { return ordering; } } } } } else { // Integer mode let mut same_length_ordering = Ord::cmp(&l, &r); loop { // Get next pair let (l, r) = match (left.peek(), right.peek()) { // Is this the end of both strings? (None, None) => return same_length_ordering, // If for one, the shorter one is considered smaller (None, Some(_)) => return Ordering::Less, (Some(_), None) => return Ordering::Greater, (Some(l), Some(r)) => (l, r), }; // Are they digits? match (l.to_digit(10), r.to_digit(10)) { // If out of digits, use the stored ordering due to equal length (None, None) => break same_length_ordering, // If one is shorter, it's smaller (None, Some(_)) => return Ordering::Less, (Some(_), None) => return Ordering::Greater, // If both are digits, consume them and take into account (Some(l), Some(r)) => { left.next(); right.next(); same_length_ordering = same_length_ordering.then(Ord::cmp(&l, &r)); } } } } } }; if next_ordering != Ordering::Equal { return next_ordering; } } } pub(super) fn full_path(cx: &Context<'_>, item: &clean::Item) -> String { let mut s = join_path_syms(&cx.current); s.push_str("::"); s.push_str(item.name.unwrap().as_str()); s } pub(super) fn print_item_path(ty: ItemType, name: &str) -> impl Display { fmt::from_fn(move |f| match ty { ItemType::Module => write!(f, "{}index.html", ensure_trailing_slash(name)), _ => write!(f, "{ty}.{name}.html"), }) } fn print_bounds( bounds: &[clean::GenericBound], trait_alias: bool, cx: &Context<'_>, ) -> impl Display { (!bounds.is_empty()) .then_some(fmt::from_fn(move |f| { let has_lots_of_bounds = bounds.len() > 2; let inter_str = if has_lots_of_bounds { "\n + " } else { " + " }; if !trait_alias { if has_lots_of_bounds { f.write_str(":\n ")?; } else { f.write_str(": ")?; } } bounds.iter().map(|p| p.print(cx)).joined(inter_str, f) })) .maybe_display() } fn wrap_item(w: &mut W, f: F) -> T where W: fmt::Write, F: FnOnce(&mut W) -> T, { write!(w, r#"
"#).unwrap();
    let res = f(w);
    write!(w, "
").unwrap(); res } #[derive(PartialEq, Eq)] struct ImplString(String); impl ImplString { fn new(i: &Impl, cx: &Context<'_>) -> ImplString { ImplString(format!("{}", i.inner_impl().print(false, cx))) } } impl PartialOrd for ImplString { fn partial_cmp(&self, other: &Self) -> Option { Some(Ord::cmp(self, other)) } } impl Ord for ImplString { fn cmp(&self, other: &Self) -> Ordering { compare_names(&self.0, &other.0) } } fn render_implementor( cx: &Context<'_>, implementor: &Impl, trait_: &clean::Item, implementor_dups: &FxHashMap, aliases: &[String], ) -> impl fmt::Display { // If there's already another implementor that has the same abridged name, use the // full path, for example in `std::iter::ExactSizeIterator` let use_absolute = match implementor.inner_impl().for_ { clean::Type::Path { ref path, .. } | clean::BorrowedRef { type_: box clean::Type::Path { ref path, .. }, .. } if !path.is_assoc_ty() => { implementor_dups[&path.last()].1 } _ => false, }; render_impl( cx, implementor, trait_, AssocItemLink::Anchor(None), RenderMode::Normal, Some(use_absolute), aliases, ImplRenderingParameters { show_def_docs: false, show_default_items: false, show_non_assoc_items: false, toggle_open_by_default: false, }, ) } fn render_union( it: &clean::Item, g: Option<&clean::Generics>, fields: &[clean::Item], def_id: DefId, is_type_alias: bool, cx: &Context<'_>, ) -> impl Display { fmt::from_fn(move |mut f| { if is_type_alias { // For now the only attributes we render for type aliases are `repr` attributes. render_repr_attribute_in_code(f, cx, def_id); } else { render_attributes_in_code(f, it, "", cx); } write!(f, "{}union {}", visibility_print_with_space(it, cx), it.name.unwrap(),)?; let where_displayed = if let Some(generics) = g { write!(f, "{}", generics.print(cx))?; if let Some(where_clause) = print_where_clause(generics, cx, 0, Ending::Newline) { write!(f, "{where_clause}")?; true } else { false } } else { false }; // If there wasn't a `where` clause, we add a whitespace. if !where_displayed { f.write_str(" ")?; } writeln!(f, "{{")?; let count_fields = fields.iter().filter(|field| matches!(field.kind, clean::StructFieldItem(..))).count(); let toggle = should_hide_fields(count_fields); if toggle { toggle_open(&mut f, format_args!("{count_fields} fields")); } for field in fields { if let clean::StructFieldItem(ref ty) = field.kind { render_attributes_in_code(&mut f, field, " ", cx); writeln!( f, " {}{}: {},", visibility_print_with_space(field, cx), field.name.unwrap(), ty.print(cx) )?; } } if it.has_stripped_entries().unwrap() { writeln!(f, " /* private fields */")?; } if toggle { toggle_close(&mut f); } f.write_str("}").unwrap(); Ok(()) }) } fn render_struct( it: &clean::Item, g: Option<&clean::Generics>, ty: Option, fields: &[clean::Item], tab: &str, structhead: bool, cx: &Context<'_>, ) -> impl fmt::Display { fmt::from_fn(move |w| { write!( w, "{}{}{}", visibility_print_with_space(it, cx), if structhead { "struct " } else { "" }, it.name.unwrap() )?; if let Some(g) = g { write!(w, "{}", g.print(cx))?; } write!( w, "{}", render_struct_fields( g, ty, fields, tab, structhead, it.has_stripped_entries().unwrap_or(false), cx, ) ) }) } fn render_struct_fields( g: Option<&clean::Generics>, ty: Option, fields: &[clean::Item], tab: &str, structhead: bool, has_stripped_entries: bool, cx: &Context<'_>, ) -> impl fmt::Display { fmt::from_fn(move |w| { match ty { None => { let where_displayed = if let Some(generics) = g && let Some(where_clause) = print_where_clause(generics, cx, 0, Ending::Newline) { write!(w, "{where_clause}")?; true } else { false }; // If there wasn't a `where` clause, we add a whitespace. if !where_displayed { w.write_str(" {")?; } else { w.write_str("{")?; } let count_fields = fields.iter().filter(|f| matches!(f.kind, clean::StructFieldItem(..))).count(); let has_visible_fields = count_fields > 0; let toggle = should_hide_fields(count_fields); if toggle { toggle_open(&mut *w, format_args!("{count_fields} fields")); } if has_visible_fields { writeln!(w)?; } for field in fields { if let clean::StructFieldItem(ref ty) = field.kind { render_attributes_in_code(w, field, &format!("{tab} "), cx); writeln!( w, "{tab} {vis}{name}: {ty},", vis = visibility_print_with_space(field, cx), name = field.name.unwrap(), ty = ty.print(cx) )?; } } if has_visible_fields { if has_stripped_entries { writeln!( w, "{tab} /* private fields */" )?; } write!(w, "{tab}")?; } else if has_stripped_entries { write!(w, " /* private fields */ ")?; } if toggle { toggle_close(&mut *w); } w.write_str("}")?; } Some(CtorKind::Fn) => { w.write_str("(")?; if !fields.is_empty() && fields.iter().all(|field| { matches!(field.kind, clean::StrippedItem(box clean::StructFieldItem(..))) }) { write!(w, "/* private fields */")?; } else { for (i, field) in fields.iter().enumerate() { if i > 0 { w.write_str(", ")?; } match field.kind { clean::StrippedItem(box clean::StructFieldItem(..)) => { write!(w, "_")?; } clean::StructFieldItem(ref ty) => { write!( w, "{}{}", visibility_print_with_space(field, cx), ty.print(cx) )?; } _ => unreachable!(), } } } w.write_str(")")?; if let Some(g) = g { write!( w, "{}", print_where_clause(g, cx, 0, Ending::NoNewline).maybe_display() )?; } // We only want a ";" when we are displaying a tuple struct, not a variant tuple struct. if structhead { w.write_str(";")?; } } Some(CtorKind::Const) => { // Needed for PhantomData. if let Some(g) = g { write!( w, "{}", print_where_clause(g, cx, 0, Ending::NoNewline).maybe_display() )?; } w.write_str(";")?; } } Ok(()) }) } fn document_non_exhaustive_header(item: &clean::Item) -> &str { if item.is_non_exhaustive() { " (Non-exhaustive)" } else { "" } } fn document_non_exhaustive(item: &clean::Item) -> impl Display { fmt::from_fn(|f| { if item.is_non_exhaustive() { write!( f, "
\ {}\
", { if item.is_struct() { "This struct is marked as non-exhaustive" } else if item.is_enum() { "This enum is marked as non-exhaustive" } else if item.is_variant() { "This variant is marked as non-exhaustive" } else { "This type is marked as non-exhaustive" } } )?; if item.is_struct() { f.write_str( "Non-exhaustive structs could have additional fields added in future. \ Therefore, non-exhaustive structs cannot be constructed in external crates \ using the traditional Struct { .. } syntax; cannot be \ matched against without a wildcard ..; and \ struct update syntax will not work.", )?; } else if item.is_enum() { f.write_str( "Non-exhaustive enums could have additional variants added in future. \ Therefore, when matching against variants of non-exhaustive enums, an \ extra wildcard arm must be added to account for any future variants.", )?; } else if item.is_variant() { f.write_str( "Non-exhaustive enum variants could have additional fields added in future. \ Therefore, non-exhaustive enum variants cannot be constructed in external \ crates and cannot be matched against.", )?; } else { f.write_str( "This type will require a wildcard arm in any match statements or constructors.", )?; } f.write_str("
")?; } Ok(()) }) } fn pluralize(count: usize) -> &'static str { if count > 1 { "s" } else { "" } }