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|
use std::collections::hash_map::Entry;
use std::collections::BTreeMap;
use rustc_data_structures::fx::FxHashMap;
use rustc_middle::ty::TyCtxt;
use rustc_span::symbol::Symbol;
use serde::ser::{Serialize, SerializeStruct, Serializer};
use crate::clean;
use crate::clean::types::{
FnRetTy, Function, GenericBound, Generics, ItemId, Type, WherePredicate,
};
use crate::formats::cache::{Cache, OrphanImplItem};
use crate::formats::item_type::ItemType;
use crate::html::format::join_with_double_colon;
use crate::html::markdown::short_markdown_summary;
use crate::html::render::{IndexItem, IndexItemFunctionType, RenderType, RenderTypeId};
/// Builds the search index from the collected metadata
pub(crate) fn build_index<'tcx>(
krate: &clean::Crate,
cache: &mut Cache,
tcx: TyCtxt<'tcx>,
) -> String {
let mut itemid_to_pathid = FxHashMap::default();
let mut primitives = FxHashMap::default();
let mut crate_paths = vec![];
// Attach all orphan items to the type's definition if the type
// has since been learned.
for &OrphanImplItem { parent, ref item, ref impl_generics } in &cache.orphan_impl_items {
if let Some((fqp, _)) = cache.paths.get(&parent) {
let desc = item
.doc_value()
.map_or_else(String::new, |s| short_markdown_summary(&s, &item.link_names(cache)));
cache.search_index.push(IndexItem {
ty: item.type_(),
name: item.name.unwrap(),
path: join_with_double_colon(&fqp[..fqp.len() - 1]),
desc,
parent: Some(parent),
parent_idx: None,
search_type: get_function_type_for_search(item, tcx, impl_generics.as_ref(), cache),
aliases: item.attrs.get_doc_aliases(),
});
}
}
let crate_doc = krate
.module
.doc_value()
.map_or_else(String::new, |s| short_markdown_summary(&s, &krate.module.link_names(cache)));
// Aliases added through `#[doc(alias = "...")]`. Since a few items can have the same alias,
// we need the alias element to have an array of items.
let mut aliases: BTreeMap<String, Vec<usize>> = BTreeMap::new();
// Sort search index items. This improves the compressibility of the search index.
cache.search_index.sort_unstable_by(|k1, k2| {
// `sort_unstable_by_key` produces lifetime errors
let k1 = (&k1.path, k1.name.as_str(), &k1.ty, &k1.parent);
let k2 = (&k2.path, k2.name.as_str(), &k2.ty, &k2.parent);
std::cmp::Ord::cmp(&k1, &k2)
});
// Set up alias indexes.
for (i, item) in cache.search_index.iter().enumerate() {
for alias in &item.aliases[..] {
aliases.entry(alias.as_str().to_lowercase()).or_default().push(i);
}
}
// Reduce `DefId` in paths into smaller sequential numbers,
// and prune the paths that do not appear in the index.
let mut lastpath = "";
let mut lastpathid = 0usize;
// First, on function signatures
let mut search_index = std::mem::replace(&mut cache.search_index, Vec::new());
for item in search_index.iter_mut() {
fn insert_into_map<F: std::hash::Hash + Eq>(
ty: &mut RenderType,
map: &mut FxHashMap<F, usize>,
itemid: F,
lastpathid: &mut usize,
crate_paths: &mut Vec<(ItemType, Symbol)>,
item_type: ItemType,
path: Symbol,
) {
match map.entry(itemid) {
Entry::Occupied(entry) => ty.id = Some(RenderTypeId::Index(*entry.get())),
Entry::Vacant(entry) => {
let pathid = *lastpathid;
entry.insert(pathid);
*lastpathid += 1;
crate_paths.push((item_type, path));
ty.id = Some(RenderTypeId::Index(pathid));
}
}
}
fn convert_render_type(
ty: &mut RenderType,
cache: &mut Cache,
itemid_to_pathid: &mut FxHashMap<ItemId, usize>,
primitives: &mut FxHashMap<Symbol, usize>,
lastpathid: &mut usize,
crate_paths: &mut Vec<(ItemType, Symbol)>,
) {
if let Some(generics) = &mut ty.generics {
for item in generics {
convert_render_type(
item,
cache,
itemid_to_pathid,
primitives,
lastpathid,
crate_paths,
);
}
}
let Cache { ref paths, ref external_paths, .. } = *cache;
let Some(id) = ty.id.clone() else {
assert!(ty.generics.is_some());
return;
};
match id {
RenderTypeId::DefId(defid) => {
if let Some(&(ref fqp, item_type)) =
paths.get(&defid).or_else(|| external_paths.get(&defid))
{
insert_into_map(
ty,
itemid_to_pathid,
ItemId::DefId(defid),
lastpathid,
crate_paths,
item_type,
*fqp.last().unwrap(),
);
} else {
ty.id = None;
}
}
RenderTypeId::Primitive(primitive) => {
let sym = primitive.as_sym();
insert_into_map(
ty,
primitives,
sym,
lastpathid,
crate_paths,
ItemType::Primitive,
sym,
);
}
RenderTypeId::Index(_) => {}
}
}
if let Some(search_type) = &mut item.search_type {
for item in &mut search_type.inputs {
convert_render_type(
item,
cache,
&mut itemid_to_pathid,
&mut primitives,
&mut lastpathid,
&mut crate_paths,
);
}
for item in &mut search_type.output {
convert_render_type(
item,
cache,
&mut itemid_to_pathid,
&mut primitives,
&mut lastpathid,
&mut crate_paths,
);
}
}
}
let Cache { ref paths, .. } = *cache;
// Then, on parent modules
let crate_items: Vec<&IndexItem> = search_index
.iter_mut()
.map(|item| {
item.parent_idx =
item.parent.and_then(|defid| match itemid_to_pathid.entry(ItemId::DefId(defid)) {
Entry::Occupied(entry) => Some(*entry.get()),
Entry::Vacant(entry) => {
let pathid = lastpathid;
entry.insert(pathid);
lastpathid += 1;
if let Some(&(ref fqp, short)) = paths.get(&defid) {
crate_paths.push((short, *fqp.last().unwrap()));
Some(pathid)
} else {
None
}
}
});
// Omit the parent path if it is same to that of the prior item.
if lastpath == &item.path {
item.path.clear();
} else {
lastpath = &item.path;
}
&*item
})
.collect();
struct CrateData<'a> {
doc: String,
items: Vec<&'a IndexItem>,
paths: Vec<(ItemType, Symbol)>,
// The String is alias name and the vec is the list of the elements with this alias.
//
// To be noted: the `usize` elements are indexes to `items`.
aliases: &'a BTreeMap<String, Vec<usize>>,
}
impl<'a> Serialize for CrateData<'a> {
fn serialize<S>(&self, serializer: S) -> Result<S::Ok, S::Error>
where
S: Serializer,
{
let has_aliases = !self.aliases.is_empty();
let mut crate_data =
serializer.serialize_struct("CrateData", if has_aliases { 9 } else { 8 })?;
crate_data.serialize_field("doc", &self.doc)?;
crate_data.serialize_field(
"t",
&self
.items
.iter()
.map(|item| {
let n = item.ty as u8;
let c = char::try_from(n + b'A').expect("item types must fit in ASCII");
assert!(c <= 'z', "item types must fit within ASCII printables");
c
})
.collect::<String>(),
)?;
crate_data.serialize_field(
"n",
&self.items.iter().map(|item| item.name.as_str()).collect::<Vec<_>>(),
)?;
crate_data.serialize_field(
"q",
&self.items.iter().map(|item| &item.path).collect::<Vec<_>>(),
)?;
crate_data.serialize_field(
"d",
&self.items.iter().map(|item| &item.desc).collect::<Vec<_>>(),
)?;
crate_data.serialize_field(
"i",
&self
.items
.iter()
.map(|item| {
assert_eq!(
item.parent.is_some(),
item.parent_idx.is_some(),
"`{}` is missing idx",
item.name
);
// 0 is a sentinel, everything else is one-indexed
item.parent_idx.map(|x| x + 1).unwrap_or(0)
})
.collect::<Vec<_>>(),
)?;
crate_data.serialize_field(
"f",
&self
.items
.iter()
.map(|item| {
// Fake option to get `0` out as a sentinel instead of `null`.
// We want to use `0` because it's three less bytes.
enum FunctionOption<'a> {
Function(&'a IndexItemFunctionType),
None,
}
impl<'a> Serialize for FunctionOption<'a> {
fn serialize<S>(&self, serializer: S) -> Result<S::Ok, S::Error>
where
S: Serializer,
{
match self {
FunctionOption::None => 0.serialize(serializer),
FunctionOption::Function(ty) => ty.serialize(serializer),
}
}
}
match &item.search_type {
Some(ty) => FunctionOption::Function(ty),
None => FunctionOption::None,
}
})
.collect::<Vec<_>>(),
)?;
crate_data.serialize_field(
"p",
&self.paths.iter().map(|(it, s)| (it, s.as_str())).collect::<Vec<_>>(),
)?;
if has_aliases {
crate_data.serialize_field("a", &self.aliases)?;
}
crate_data.end()
}
}
// Collect the index into a string
format!(
r#""{}":{}"#,
krate.name(tcx),
serde_json::to_string(&CrateData {
doc: crate_doc,
items: crate_items,
paths: crate_paths,
aliases: &aliases,
})
.expect("failed serde conversion")
// All these `replace` calls are because we have to go through JS string for JSON content.
.replace('\\', r"\\")
.replace('\'', r"\'")
// We need to escape double quotes for the JSON.
.replace("\\\"", "\\\\\"")
)
}
pub(crate) fn get_function_type_for_search<'tcx>(
item: &clean::Item,
tcx: TyCtxt<'tcx>,
impl_generics: Option<&(clean::Type, clean::Generics)>,
cache: &Cache,
) -> Option<IndexItemFunctionType> {
let (mut inputs, mut output) = match *item.kind {
clean::FunctionItem(ref f) => get_fn_inputs_and_outputs(f, tcx, impl_generics, cache),
clean::MethodItem(ref m, _) => get_fn_inputs_and_outputs(m, tcx, impl_generics, cache),
clean::TyMethodItem(ref m) => get_fn_inputs_and_outputs(m, tcx, impl_generics, cache),
_ => return None,
};
inputs.retain(|a| a.id.is_some() || a.generics.is_some());
output.retain(|a| a.id.is_some() || a.generics.is_some());
Some(IndexItemFunctionType { inputs, output })
}
fn get_index_type(clean_type: &clean::Type, generics: Vec<RenderType>) -> RenderType {
RenderType {
id: get_index_type_id(clean_type),
generics: if generics.is_empty() { None } else { Some(generics) },
}
}
fn get_index_type_id(clean_type: &clean::Type) -> Option<RenderTypeId> {
match *clean_type {
clean::Type::Path { ref path, .. } => Some(RenderTypeId::DefId(path.def_id())),
clean::DynTrait(ref bounds, _) => {
bounds.get(0).map(|b| RenderTypeId::DefId(b.trait_.def_id()))
}
clean::Primitive(p) => Some(RenderTypeId::Primitive(p)),
clean::BorrowedRef { ref type_, .. } | clean::RawPointer(_, ref type_) => {
get_index_type_id(type_)
}
clean::BareFunction(_)
| clean::Generic(_)
| clean::ImplTrait(_)
| clean::Tuple(_)
| clean::Slice(_)
| clean::Array(_, _)
| clean::QPath { .. }
| clean::Infer => None,
}
}
/// The point of this function is to replace bounds with types.
///
/// i.e. `[T, U]` when you have the following bounds: `T: Display, U: Option<T>` will return
/// `[Display, Option]`. If a type parameter has no trait bound, it is discarded.
///
/// Important note: It goes through generics recursively. So if you have
/// `T: Option<Result<(), ()>>`, it'll go into `Option` and then into `Result`.
#[instrument(level = "trace", skip(tcx, res, cache))]
fn add_generics_and_bounds_as_types<'tcx, 'a>(
self_: Option<&'a Type>,
generics: &Generics,
arg: &'a Type,
tcx: TyCtxt<'tcx>,
recurse: usize,
res: &mut Vec<RenderType>,
cache: &Cache,
) {
fn insert_ty(res: &mut Vec<RenderType>, ty: Type, mut generics: Vec<RenderType>) {
// generics and impl trait are both identified by their generics,
// rather than a type name itself
let anonymous = ty.is_full_generic() || ty.is_impl_trait();
let generics_empty = generics.is_empty();
if anonymous {
if generics_empty {
// This is a type parameter with no trait bounds (for example: `T` in
// `fn f<T>(p: T)`, so not useful for the rustdoc search because we would end up
// with an empty type with an empty name. Let's just discard it.
return;
} else if generics.len() == 1 {
// In this case, no need to go through an intermediate state if the type parameter
// contains only one trait bound.
//
// For example:
//
// `fn foo<T: Display>(r: Option<T>) {}`
//
// In this case, it would contain:
//
// ```
// [{
// name: "option",
// generics: [{
// name: "",
// generics: [
// name: "Display",
// generics: []
// }]
// }]
// }]
// ```
//
// After removing the intermediate (unnecessary) type parameter, it'll become:
//
// ```
// [{
// name: "option",
// generics: [{
// name: "Display",
// generics: []
// }]
// }]
// ```
//
// To be noted that it can work if there is ONLY ONE trait bound, otherwise we still
// need to keep it as is!
res.push(generics.pop().unwrap());
return;
}
}
let index_ty = get_index_type(&ty, generics);
if index_ty.id.is_none() && generics_empty {
return;
}
res.push(index_ty);
}
if recurse >= 10 {
// FIXME: remove this whole recurse thing when the recursion bug is fixed
// See #59502 for the original issue.
return;
}
// First, check if it's "Self".
let arg = if let Some(self_) = self_ {
match &*arg {
Type::BorrowedRef { type_, .. } if type_.is_self_type() => self_,
type_ if type_.is_self_type() => self_,
arg => arg,
}
} else {
arg
};
// If this argument is a type parameter and not a trait bound or a type, we need to look
// for its bounds.
if let Type::Generic(arg_s) = *arg {
// First we check if the bounds are in a `where` predicate...
if let Some(where_pred) = generics.where_predicates.iter().find(|g| match g {
WherePredicate::BoundPredicate { ty, .. } => ty.def_id(cache) == arg.def_id(cache),
_ => false,
}) {
let mut ty_generics = Vec::new();
let bounds = where_pred.get_bounds().unwrap_or_else(|| &[]);
for bound in bounds.iter() {
if let GenericBound::TraitBound(poly_trait, _) = bound {
for param_def in poly_trait.generic_params.iter() {
match ¶m_def.kind {
clean::GenericParamDefKind::Type { default: Some(ty), .. } => {
add_generics_and_bounds_as_types(
self_,
generics,
ty,
tcx,
recurse + 1,
&mut ty_generics,
cache,
)
}
_ => {}
}
}
}
}
insert_ty(res, arg.clone(), ty_generics);
}
// Otherwise we check if the trait bounds are "inlined" like `T: Option<u32>`...
if let Some(bound) = generics.params.iter().find(|g| g.is_type() && g.name == arg_s) {
let mut ty_generics = Vec::new();
for bound in bound.get_bounds().unwrap_or(&[]) {
if let Some(path) = bound.get_trait_path() {
let ty = Type::Path { path };
add_generics_and_bounds_as_types(
self_,
generics,
&ty,
tcx,
recurse + 1,
&mut ty_generics,
cache,
);
}
}
insert_ty(res, arg.clone(), ty_generics);
}
} else if let Type::ImplTrait(ref bounds) = *arg {
let mut ty_generics = Vec::new();
for bound in bounds {
if let Some(path) = bound.get_trait_path() {
let ty = Type::Path { path };
add_generics_and_bounds_as_types(
self_,
generics,
&ty,
tcx,
recurse + 1,
&mut ty_generics,
cache,
);
}
}
insert_ty(res, arg.clone(), ty_generics);
} else {
// This is not a type parameter. So for example if we have `T, U: Option<T>`, and we're
// looking at `Option`, we enter this "else" condition, otherwise if it's `T`, we don't.
//
// So in here, we can add it directly and look for its own type parameters (so for `Option`,
// we will look for them but not for `T`).
let mut ty_generics = Vec::new();
if let Some(arg_generics) = arg.generics() {
for gen in arg_generics.iter() {
add_generics_and_bounds_as_types(
self_,
generics,
gen,
tcx,
recurse + 1,
&mut ty_generics,
cache,
);
}
}
insert_ty(res, arg.clone(), ty_generics);
}
}
/// Return the full list of types when bounds have been resolved.
///
/// i.e. `fn foo<A: Display, B: Option<A>>(x: u32, y: B)` will return
/// `[u32, Display, Option]`.
fn get_fn_inputs_and_outputs<'tcx>(
func: &Function,
tcx: TyCtxt<'tcx>,
impl_generics: Option<&(clean::Type, clean::Generics)>,
cache: &Cache,
) -> (Vec<RenderType>, Vec<RenderType>) {
let decl = &func.decl;
let combined_generics;
let (self_, generics) = if let Some((impl_self, impl_generics)) = impl_generics {
match (impl_generics.is_empty(), func.generics.is_empty()) {
(true, _) => (Some(impl_self), &func.generics),
(_, true) => (Some(impl_self), impl_generics),
(false, false) => {
let params =
func.generics.params.iter().chain(&impl_generics.params).cloned().collect();
let where_predicates = func
.generics
.where_predicates
.iter()
.chain(&impl_generics.where_predicates)
.cloned()
.collect();
combined_generics = clean::Generics { params, where_predicates };
(Some(impl_self), &combined_generics)
}
}
} else {
(None, &func.generics)
};
let mut all_types = Vec::new();
for arg in decl.inputs.values.iter() {
let mut args = Vec::new();
add_generics_and_bounds_as_types(self_, generics, &arg.type_, tcx, 0, &mut args, cache);
if !args.is_empty() {
all_types.extend(args);
} else {
all_types.push(get_index_type(&arg.type_, vec![]));
}
}
let mut ret_types = Vec::new();
match decl.output {
FnRetTy::Return(ref return_type) => {
add_generics_and_bounds_as_types(
self_,
generics,
return_type,
tcx,
0,
&mut ret_types,
cache,
);
if ret_types.is_empty() {
ret_types.push(get_index_type(return_type, vec![]));
}
}
_ => {}
};
(all_types, ret_types)
}
|
