src/librustdoc/json/mod.rs - toolchain/rustc - Git at Google

 //! Rustdoc's JSON backend
 //!
 //! This module contains the logic for rendering a crate as JSON rather than the normal static HTML
 //! output. See [the RFC](https://github.com/rust-lang/rfcs/pull/2963) and the [`types`] module
 //! docs for usage and details.

 mod conversions;
 mod import_finder;

 use std::cell::RefCell;
 use std::fs::{File, create_dir_all};
 use std::io::{BufWriter, Write, stdout};
 use std::path::PathBuf;
 use std::rc::Rc;

 use rustc_hir::def_id::{DefId, DefIdSet};
 use rustc_middle::ty::TyCtxt;
 use rustc_session::Session;
 use rustc_span::Symbol;
 use rustc_span::def_id::LOCAL_CRATE;
 use rustdoc_json_types as types;
 // It's important to use the FxHashMap from rustdoc_json_types here, instead of
 // the one from rustc_data_structures, as they're different types due to sysroots.
 // See #110051 and #127456 for details
 use rustdoc_json_types::FxHashMap;
 use tracing::{debug, trace};

 use crate::clean::ItemKind;
 use crate::clean::types::{ExternalCrate, ExternalLocation};
 use crate::config::RenderOptions;
 use crate::docfs::PathError;
 use crate::error::Error;
 use crate::formats::FormatRenderer;
 use crate::formats::cache::Cache;
 use crate::json::conversions::IntoJson;
 use crate::{clean, try_err};

 #[derive(Debug, Clone, Copy, Hash, PartialEq, Eq)]
 struct FullItemId {
     def_id: DefId,
     name: Option<Symbol>,
     /// Used to distinguish imports of different items with the same name
     extra: Option<types::Id>,
 }

 #[derive(Clone)]
 pub(crate) struct JsonRenderer<'tcx> {
     tcx: TyCtxt<'tcx>,
     /// A mapping of IDs that contains all local items for this crate which gets output as a top
     /// level field of the JSON blob.
     index: Rc<RefCell<FxHashMap<types::Id, types::Item>>>,
     /// The directory where the JSON blob should be written to.
     ///
     /// If this is `None`, the blob will be printed to `stdout` instead.
     out_dir: Option<PathBuf>,
     cache: Rc<Cache>,
     imported_items: DefIdSet,
     id_interner: Rc<RefCell<FxHashMap<(FullItemId, Option<FullItemId>), types::Id>>>,
 }

 impl<'tcx> JsonRenderer<'tcx> {
     fn sess(&self) -> &'tcx Session {
         self.tcx.sess
     }

     fn get_trait_implementors(&mut self, id: DefId) -> Vec<types::Id> {
         Rc::clone(&self.cache)
             .implementors
             .get(&id)
             .map(|implementors| {
                 implementors
                     .iter()
                     .map(|i| {
                         let item = &i.impl_item;
                         self.item(item.clone()).unwrap();
                         self.id_from_item(&item)
                     })
                     .collect()
             })
             .unwrap_or_default()
     }

     fn get_impls(&mut self, id: DefId) -> Vec<types::Id> {
         Rc::clone(&self.cache)
             .impls
             .get(&id)
             .map(|impls| {
                 impls
                     .iter()
                     .filter_map(|i| {
                         let item = &i.impl_item;

                         // HACK(hkmatsumoto): For impls of primitive types, we index them
                         // regardless of whether they're local. This is because users can
                         // document primitive items in an arbitrary crate by using
                         // `rustc_doc_primitive`.
                         let mut is_primitive_impl = false;
                         if let clean::types::ItemKind::ImplItem(ref impl_) = item.kind
                             && impl_.trait_.is_none()
                             && let clean::types::Type::Primitive(_) = impl_.for_
                         {
                             is_primitive_impl = true;
                         }

                         if item.item_id.is_local() || is_primitive_impl {
                             self.item(item.clone()).unwrap();
                             Some(self.id_from_item(&item))
                         } else {
                             None
                         }
                     })
                     .collect()
             })
             .unwrap_or_default()
     }

     fn serialize_and_write<T: Write>(
         &self,
         output_crate: types::Crate,
         mut writer: BufWriter<T>,
         path: &str,
     ) -> Result<(), Error> {
         self.sess().time("rustdoc_json_serialize_and_write", || {
             try_err!(
                 serde_json::ser::to_writer(&mut writer, &output_crate).map_err(|e| e.to_string()),
                 path
             );
             try_err!(writer.flush(), path);
             Ok(())
         })
     }
 }

 impl<'tcx> FormatRenderer<'tcx> for JsonRenderer<'tcx> {
     fn descr() -> &'static str {
         "json"
     }

     const RUN_ON_MODULE: bool = false;

     fn init(
         krate: clean::Crate,
         options: RenderOptions,
         cache: Cache,
         tcx: TyCtxt<'tcx>,
     ) -> Result<(Self, clean::Crate), Error> {
         debug!("Initializing json renderer");

         let (krate, imported_items) = import_finder::get_imports(krate);

         Ok((
             JsonRenderer {
                 tcx,
                 index: Rc::new(RefCell::new(FxHashMap::default())),
                 out_dir: if options.output_to_stdout { None } else { Some(options.output) },
                 cache: Rc::new(cache),
                 imported_items,
                 id_interner: Default::default(),
             },
             krate,
         ))
     }

     fn make_child_renderer(&self) -> Self {
         self.clone()
     }

     /// Inserts an item into the index. This should be used rather than directly calling insert on
     /// the hashmap because certain items (traits and types) need to have their mappings for trait
     /// implementations filled out before they're inserted.
     fn item(&mut self, item: clean::Item) -> Result<(), Error> {
         let item_type = item.type_();
         let item_name = item.name;
         trace!("rendering {item_type} {item_name:?}");

         // Flatten items that recursively store other items. We include orphaned items from
         // stripped modules and etc that are otherwise reachable.
         if let ItemKind::StrippedItem(inner) = &item.kind {
             inner.inner_items().for_each(|i| self.item(i.clone()).unwrap());
         }

         // Flatten items that recursively store other items
         item.kind.inner_items().for_each(|i| self.item(i.clone()).unwrap());

         let item_id = item.item_id;
         if let Some(mut new_item) = self.convert_item(item) {
             let can_be_ignored = match new_item.inner {
                 types::ItemEnum::Trait(ref mut t) => {
                     t.implementations = self.get_trait_implementors(item_id.expect_def_id());
                     false
                 }
                 types::ItemEnum::Struct(ref mut s) => {
                     s.impls = self.get_impls(item_id.expect_def_id());
                     false
                 }
                 types::ItemEnum::Enum(ref mut e) => {
                     e.impls = self.get_impls(item_id.expect_def_id());
                     false
                 }
                 types::ItemEnum::Union(ref mut u) => {
                     u.impls = self.get_impls(item_id.expect_def_id());
                     false
                 }
                 types::ItemEnum::Primitive(ref mut p) => {
                     p.impls = self.get_impls(item_id.expect_def_id());
                     false
                 }

                 types::ItemEnum::Function(_)
                 | types::ItemEnum::Module(_)
                 | types::ItemEnum::Use(_)
                 | types::ItemEnum::AssocConst { .. }
                 | types::ItemEnum::AssocType { .. } => true,
                 types::ItemEnum::ExternCrate { .. }
                 | types::ItemEnum::StructField(_)
                 | types::ItemEnum::Variant(_)
                 | types::ItemEnum::TraitAlias(_)
                 | types::ItemEnum::Impl(_)
                 | types::ItemEnum::TypeAlias(_)
                 | types::ItemEnum::Constant { .. }
                 | types::ItemEnum::Static(_)
                 | types::ItemEnum::ExternType
                 | types::ItemEnum::Macro(_)
                 | types::ItemEnum::ProcMacro(_) => false,
             };
             let removed = self.index.borrow_mut().insert(new_item.id.clone(), new_item.clone());

             // FIXME(adotinthevoid): Currently, the index is duplicated. This is a sanity check
             // to make sure the items are unique. The main place this happens is when an item, is
             // reexported in more than one place. See `rustdoc-json/reexport/in_root_and_mod`
             if let Some(old_item) = removed {
                 // In case of generic implementations (like `impl<T> Trait for T {}`), all the
                 // inner items will be duplicated so we can ignore if they are slightly different.
                 if !can_be_ignored {
                     assert_eq!(old_item, new_item);
                 }
                 trace!("replaced {old_item:?}\nwith {new_item:?}");
             }
         }

         trace!("done rendering {item_type} {item_name:?}");
         Ok(())
     }

     fn mod_item_in(&mut self, _item: &clean::Item) -> Result<(), Error> {
         unreachable!("RUN_ON_MODULE = false should never call mod_item_in")
     }

     fn after_krate(&mut self) -> Result<(), Error> {
         debug!("Done with crate");

         let e = ExternalCrate { crate_num: LOCAL_CRATE };
         let index = (*self.index).clone().into_inner();

         debug!("Constructing Output");
         let output_crate = types::Crate {
             root: self.id_from_item_default(e.def_id().into()),
             crate_version: self.cache.crate_version.clone(),
             includes_private: self.cache.document_private,
             index,
             paths: self
                 .cache
                 .paths
                 .iter()
                 .chain(&self.cache.external_paths)
                 .map(|(&k, &(ref path, kind))| {
                     (self.id_from_item_default(k.into()), types::ItemSummary {
                         crate_id: k.krate.as_u32(),
                         path: path.iter().map(|s| s.to_string()).collect(),
                         kind: kind.into_json(self),
                     })
                 })
                 .collect(),
             external_crates: self
                 .cache
                 .extern_locations
                 .iter()
                 .map(|(crate_num, external_location)| {
                     let e = ExternalCrate { crate_num: *crate_num };
                     (crate_num.as_u32(), types::ExternalCrate {
                         name: e.name(self.tcx).to_string(),
                         html_root_url: match external_location {
                             ExternalLocation::Remote(s) => Some(s.clone()),
                             _ => None,
                         },
                     })
                 })
                 .collect(),
             format_version: types::FORMAT_VERSION,
         };
         if let Some(ref out_dir) = self.out_dir {
             try_err!(create_dir_all(&out_dir), out_dir);

             let mut p = out_dir.clone();
             p.push(output_crate.index.get(&output_crate.root).unwrap().name.clone().unwrap());
             p.set_extension("json");

             self.serialize_and_write(
                 output_crate,
                 try_err!(File::create_buffered(&p), p),
                 &p.display().to_string(),
             )
         } else {
             self.serialize_and_write(output_crate, BufWriter::new(stdout().lock()), "<stdout>")
         }
     }

     fn cache(&self) -> &Cache {
         &self.cache
     }
 }
	//! Rustdoc's JSON backend
	//!
	//! This module contains the logic for rendering a crate as JSON rather than the normal static HTML
	//! output. See [the RFC](https://github.com/rust-lang/rfcs/pull/2963) and the [`types`] module
	//! docs for usage and details.

	mod conversions;
	mod import_finder;

	use std::cell::RefCell;
	use std::fs::{File, create_dir_all};
	use std::io::{BufWriter, Write, stdout};
	use std::path::PathBuf;
	use std::rc::Rc;

	use rustc_hir::def_id::{DefId, DefIdSet};
	use rustc_middle::ty::TyCtxt;
	use rustc_session::Session;
	use rustc_span::Symbol;
	use rustc_span::def_id::LOCAL_CRATE;
	use rustdoc_json_types as types;
	// It's important to use the FxHashMap from rustdoc_json_types here, instead of
	// the one from rustc_data_structures, as they're different types due to sysroots.
	// See #110051 and #127456 for details
	use rustdoc_json_types::FxHashMap;
	use tracing::{debug, trace};

	use crate::clean::ItemKind;
	use crate::clean::types::{ExternalCrate, ExternalLocation};
	use crate::config::RenderOptions;
	use crate::docfs::PathError;
	use crate::error::Error;
	use crate::formats::FormatRenderer;
	use crate::formats::cache::Cache;
	use crate::json::conversions::IntoJson;
	use crate::{clean, try_err};

	#[derive(Debug, Clone, Copy, Hash, PartialEq, Eq)]
	struct FullItemId {
	def_id: DefId,
	name: Option<Symbol>,
	/// Used to distinguish imports of different items with the same name
	extra: Option<types::Id>,
	}

	#[derive(Clone)]
	pub(crate) struct JsonRenderer<'tcx> {
	tcx: TyCtxt<'tcx>,
	/// A mapping of IDs that contains all local items for this crate which gets output as a top
	/// level field of the JSON blob.
	index: Rc<RefCell<FxHashMap<types::Id, types::Item>>>,
	/// The directory where the JSON blob should be written to.
	///
	/// If this is `None`, the blob will be printed to `stdout` instead.
	out_dir: Option<PathBuf>,
	cache: Rc<Cache>,
	imported_items: DefIdSet,
	id_interner: Rc<RefCell<FxHashMap<(FullItemId, Option<FullItemId>), types::Id>>>,
	}

	impl<'tcx> JsonRenderer<'tcx> {
	fn sess(&self) -> &'tcx Session {
	self.tcx.sess
	}

	fn get_trait_implementors(&mut self, id: DefId) -> Vec<types::Id> {
	Rc::clone(&self.cache)
	.implementors
	.get(&id)
	.map(\|implementors\| {
	implementors
	.iter()
	.map(\|i\| {
	let item = &i.impl_item;
	self.item(item.clone()).unwrap();
	self.id_from_item(&item)
	})
	.collect()
	})
	.unwrap_or_default()
	}

	fn get_impls(&mut self, id: DefId) -> Vec<types::Id> {
	Rc::clone(&self.cache)
	.impls
	.get(&id)
	.map(\|impls\| {
	impls
	.iter()
	.filter_map(\|i\| {
	let item = &i.impl_item;

	// HACK(hkmatsumoto): For impls of primitive types, we index them
	// regardless of whether they're local. This is because users can
	// document primitive items in an arbitrary crate by using
	// `rustc_doc_primitive`.
	let mut is_primitive_impl = false;
	if let clean::types::ItemKind::ImplItem(ref impl_) = item.kind
	&& impl_.trait_.is_none()
	&& let clean::types::Type::Primitive(_) = impl_.for_
	{
	is_primitive_impl = true;
	}

	if item.item_id.is_local() \|\| is_primitive_impl {
	self.item(item.clone()).unwrap();
	Some(self.id_from_item(&item))
	} else {
	None
	}
	})
	.collect()
	})
	.unwrap_or_default()
	}

	fn serialize_and_write<T: Write>(
	&self,
	output_crate: types::Crate,
	mut writer: BufWriter<T>,
	path: &str,
	) -> Result<(), Error> {
	self.sess().time("rustdoc_json_serialize_and_write", \|\| {
	try_err!(
	serde_json::ser::to_writer(&mut writer, &output_crate).map_err(\|e\| e.to_string()),
	path
	);
	try_err!(writer.flush(), path);
	Ok(())
	})
	}
	}

	impl<'tcx> FormatRenderer<'tcx> for JsonRenderer<'tcx> {
	fn descr() -> &'static str {
	"json"
	}

	const RUN_ON_MODULE: bool = false;

	fn init(
	krate: clean::Crate,
	options: RenderOptions,
	cache: Cache,
	tcx: TyCtxt<'tcx>,
	) -> Result<(Self, clean::Crate), Error> {
	debug!("Initializing json renderer");

	let (krate, imported_items) = import_finder::get_imports(krate);

	Ok((
	JsonRenderer {
	tcx,
	index: Rc::new(RefCell::new(FxHashMap::default())),
	out_dir: if options.output_to_stdout { None } else { Some(options.output) },
	cache: Rc::new(cache),
	imported_items,
	id_interner: Default::default(),
	},
	krate,
	))
	}

	fn make_child_renderer(&self) -> Self {
	self.clone()
	}

	/// Inserts an item into the index. This should be used rather than directly calling insert on
	/// the hashmap because certain items (traits and types) need to have their mappings for trait
	/// implementations filled out before they're inserted.
	fn item(&mut self, item: clean::Item) -> Result<(), Error> {
	let item_type = item.type_();
	let item_name = item.name;
	trace!("rendering {item_type} {item_name:?}");

	// Flatten items that recursively store other items. We include orphaned items from
	// stripped modules and etc that are otherwise reachable.
	if let ItemKind::StrippedItem(inner) = &item.kind {
	inner.inner_items().for_each(\|i\| self.item(i.clone()).unwrap());
	}

	// Flatten items that recursively store other items
	item.kind.inner_items().for_each(\|i\| self.item(i.clone()).unwrap());

	let item_id = item.item_id;
	if let Some(mut new_item) = self.convert_item(item) {
	let can_be_ignored = match new_item.inner {
	types::ItemEnum::Trait(ref mut t) => {
	t.implementations = self.get_trait_implementors(item_id.expect_def_id());
	false
	}
	types::ItemEnum::Struct(ref mut s) => {
	s.impls = self.get_impls(item_id.expect_def_id());
	false
	}
	types::ItemEnum::Enum(ref mut e) => {
	e.impls = self.get_impls(item_id.expect_def_id());
	false
	}
	types::ItemEnum::Union(ref mut u) => {
	u.impls = self.get_impls(item_id.expect_def_id());
	false
	}
	types::ItemEnum::Primitive(ref mut p) => {
	p.impls = self.get_impls(item_id.expect_def_id());
	false
	}

	types::ItemEnum::Function(_)
	\| types::ItemEnum::Module(_)
	\| types::ItemEnum::Use(_)
	\| types::ItemEnum::AssocConst { .. }
	\| types::ItemEnum::AssocType { .. } => true,
	types::ItemEnum::ExternCrate { .. }
	\| types::ItemEnum::StructField(_)
	\| types::ItemEnum::Variant(_)
	\| types::ItemEnum::TraitAlias(_)
	\| types::ItemEnum::Impl(_)
	\| types::ItemEnum::TypeAlias(_)
	\| types::ItemEnum::Constant { .. }
	\| types::ItemEnum::Static(_)
	\| types::ItemEnum::ExternType
	\| types::ItemEnum::Macro(_)
	\| types::ItemEnum::ProcMacro(_) => false,
	};
	let removed = self.index.borrow_mut().insert(new_item.id.clone(), new_item.clone());

	// FIXME(adotinthevoid): Currently, the index is duplicated. This is a sanity check
	// to make sure the items are unique. The main place this happens is when an item, is
	// reexported in more than one place. See `rustdoc-json/reexport/in_root_and_mod`
	if let Some(old_item) = removed {
	// In case of generic implementations (like `impl<T> Trait for T {}`), all the
	// inner items will be duplicated so we can ignore if they are slightly different.
	if !can_be_ignored {
	assert_eq!(old_item, new_item);
	}
	trace!("replaced {old_item:?}\nwith {new_item:?}");
	}
	}

	trace!("done rendering {item_type} {item_name:?}");
	Ok(())
	}

	fn mod_item_in(&mut self, _item: &clean::Item) -> Result<(), Error> {
	unreachable!("RUN_ON_MODULE = false should never call mod_item_in")
	}

	fn after_krate(&mut self) -> Result<(), Error> {
	debug!("Done with crate");

	let e = ExternalCrate { crate_num: LOCAL_CRATE };
	let index = (*self.index).clone().into_inner();

	debug!("Constructing Output");
	let output_crate = types::Crate {
	root: self.id_from_item_default(e.def_id().into()),
	crate_version: self.cache.crate_version.clone(),
	includes_private: self.cache.document_private,
	index,
	paths: self
	.cache
	.paths
	.iter()
	.chain(&self.cache.external_paths)
	.map(\|(&k, &(ref path, kind))\| {
	(self.id_from_item_default(k.into()), types::ItemSummary {
	crate_id: k.krate.as_u32(),
	path: path.iter().map(\|s\| s.to_string()).collect(),
	kind: kind.into_json(self),
	})
	})
	.collect(),
	external_crates: self
	.cache
	.extern_locations
	.iter()
	.map(\|(crate_num, external_location)\| {
	let e = ExternalCrate { crate_num: *crate_num };
	(crate_num.as_u32(), types::ExternalCrate {
	name: e.name(self.tcx).to_string(),
	html_root_url: match external_location {
	ExternalLocation::Remote(s) => Some(s.clone()),
	_ => None,
	},
	})
	})
	.collect(),
	format_version: types::FORMAT_VERSION,
	};
	if let Some(ref out_dir) = self.out_dir {
	try_err!(create_dir_all(&out_dir), out_dir);

	let mut p = out_dir.clone();
	p.push(output_crate.index.get(&output_crate.root).unwrap().name.clone().unwrap());
	p.set_extension("json");

	self.serialize_and_write(
	output_crate,
	try_err!(File::create_buffered(&p), p),
	&p.display().to_string(),
	)
	} else {
	self.serialize_and_write(output_crate, BufWriter::new(stdout().lock()), "<stdout>")
	}
	}

	fn cache(&self) -> &Cache {
	&self.cache
	}
	}