// Copyright 2015 The Rust Project Developers. See the COPYRIGHT // file at the top-level directory of this distribution and at // http://rust-lang.org/COPYRIGHT. // // Licensed under the Apache License, Version 2.0 or the MIT license // , at your // option. This file may not be copied, modified, or distributed // except according to those terms. use cstore; use encoder; use link_args; use native_libs; use schema; use rustc::ty::maps::QueryConfig; use rustc::middle::cstore::{CrateStore, DepKind, MetadataLoader, LinkMeta, LoadedMacro, EncodedMetadata, EncodedMetadataHashes, NativeLibraryKind}; use rustc::middle::stability::DeprecationEntry; use rustc::hir::def; use rustc::session::Session; use rustc::ty::{self, TyCtxt}; use rustc::ty::maps::Providers; use rustc::hir::def_id::{CrateNum, DefId, LOCAL_CRATE, CRATE_DEF_INDEX}; use rustc::hir::map::{DefKey, DefPath, DefPathHash}; use rustc::hir::map::blocks::FnLikeNode; use rustc::hir::map::definitions::DefPathTable; use rustc::util::nodemap::{NodeSet, DefIdMap}; use std::any::Any; use std::rc::Rc; use syntax::ast; use syntax::attr; use syntax::ext::base::SyntaxExtension; use syntax::parse::filemap_to_stream; use syntax::symbol::Symbol; use syntax_pos::{Span, NO_EXPANSION}; use rustc_data_structures::indexed_set::IdxSetBuf; use rustc::hir; macro_rules! provide { (<$lt:tt> $tcx:ident, $def_id:ident, $other:ident, $cdata:ident, $($name:ident => $compute:block)*) => { pub fn provide<$lt>(providers: &mut Providers<$lt>) { $(fn $name<'a, $lt:$lt, T>($tcx: TyCtxt<'a, $lt, $lt>, def_id_arg: T) -> as QueryConfig>::Value where T: IntoArgs, { #[allow(unused_variables)] let ($def_id, $other) = def_id_arg.into_args(); assert!(!$def_id.is_local()); let def_path_hash = $tcx.def_path_hash($def_id); let dep_node = def_path_hash.to_dep_node(::rustc::dep_graph::DepKind::MetaData); $tcx.dep_graph.read(dep_node); let $cdata = $tcx.crate_data_as_rc_any($def_id.krate); let $cdata = $cdata.downcast_ref::() .expect("CrateStore crated ata is not a CrateMetadata"); $compute })* *providers = Providers { $($name,)* ..*providers }; } } } // small trait to work around different signature queries all being defined via // the macro above. trait IntoArgs { fn into_args(self) -> (DefId, DefId); } impl IntoArgs for DefId { fn into_args(self) -> (DefId, DefId) { (self, self) } } impl IntoArgs for CrateNum { fn into_args(self) -> (DefId, DefId) { (self.as_def_id(), self.as_def_id()) } } impl IntoArgs for (CrateNum, DefId) { fn into_args(self) -> (DefId, DefId) { (self.0.as_def_id(), self.1) } } provide! { <'tcx> tcx, def_id, other, cdata, type_of => { cdata.get_type(def_id.index, tcx) } generics_of => { tcx.alloc_generics(cdata.get_generics(def_id.index)) } predicates_of => { cdata.get_predicates(def_id.index, tcx) } super_predicates_of => { cdata.get_super_predicates(def_id.index, tcx) } trait_def => { tcx.alloc_trait_def(cdata.get_trait_def(def_id.index)) } adt_def => { cdata.get_adt_def(def_id.index, tcx) } adt_destructor => { let _ = cdata; tcx.calculate_dtor(def_id, &mut |_,_| Ok(())) } variances_of => { Rc::new(cdata.get_item_variances(def_id.index)) } associated_item_def_ids => { let mut result = vec![]; cdata.each_child_of_item(def_id.index, |child| result.push(child.def.def_id()), tcx.sess); Rc::new(result) } associated_item => { cdata.get_associated_item(def_id.index) } impl_trait_ref => { cdata.get_impl_trait(def_id.index, tcx) } impl_polarity => { cdata.get_impl_polarity(def_id.index) } coerce_unsized_info => { cdata.get_coerce_unsized_info(def_id.index).unwrap_or_else(|| { bug!("coerce_unsized_info: `{:?}` is missing its info", def_id); }) } optimized_mir => { let mir = cdata.maybe_get_optimized_mir(tcx, def_id.index).unwrap_or_else(|| { bug!("get_optimized_mir: missing MIR for `{:?}`", def_id) }); let mir = tcx.alloc_mir(mir); mir } generator_sig => { cdata.generator_sig(def_id.index, tcx) } mir_const_qualif => { (cdata.mir_const_qualif(def_id.index), Rc::new(IdxSetBuf::new_empty(0))) } typeck_tables_of => { cdata.item_body_tables(def_id.index, tcx) } closure_kind => { cdata.closure_kind(def_id.index) } fn_sig => { cdata.fn_sig(def_id.index, tcx) } inherent_impls => { Rc::new(cdata.get_inherent_implementations_for_type(def_id.index)) } is_const_fn => { cdata.is_const_fn(def_id.index) } is_foreign_item => { cdata.is_foreign_item(def_id.index) } is_default_impl => { cdata.is_default_impl(def_id.index) } describe_def => { cdata.get_def(def_id.index) } def_span => { cdata.get_span(def_id.index, &tcx.sess) } lookup_stability => { cdata.get_stability(def_id.index).map(|s| tcx.intern_stability(s)) } lookup_deprecation_entry => { cdata.get_deprecation(def_id.index).map(DeprecationEntry::external) } item_attrs => { cdata.get_item_attrs(def_id.index) } // FIXME(#38501) We've skipped a `read` on the `HirBody` of // a `fn` when encoding, so the dep-tracking wouldn't work. // This is only used by rustdoc anyway, which shouldn't have // incremental recompilation ever enabled. fn_arg_names => { cdata.get_fn_arg_names(def_id.index) } impl_parent => { cdata.get_parent_impl(def_id.index) } trait_of_item => { cdata.get_trait_of_item(def_id.index) } is_exported_symbol => { cdata.exported_symbols.contains(&def_id.index) } item_body_nested_bodies => { Rc::new(cdata.item_body_nested_bodies(def_id.index)) } const_is_rvalue_promotable_to_static => { cdata.const_is_rvalue_promotable_to_static(def_id.index) } is_mir_available => { cdata.is_item_mir_available(def_id.index) } dylib_dependency_formats => { Rc::new(cdata.get_dylib_dependency_formats()) } is_panic_runtime => { cdata.is_panic_runtime() } is_compiler_builtins => { cdata.is_compiler_builtins() } has_global_allocator => { cdata.has_global_allocator() } is_sanitizer_runtime => { cdata.is_sanitizer_runtime() } is_profiler_runtime => { cdata.is_profiler_runtime() } panic_strategy => { cdata.panic_strategy() } extern_crate => { Rc::new(cdata.extern_crate.get()) } is_no_builtins => { cdata.is_no_builtins() } impl_defaultness => { cdata.get_impl_defaultness(def_id.index) } exported_symbol_ids => { Rc::new(cdata.get_exported_symbols()) } native_libraries => { Rc::new(cdata.get_native_libraries()) } plugin_registrar_fn => { cdata.root.plugin_registrar_fn.map(|index| { DefId { krate: def_id.krate, index } }) } derive_registrar_fn => { cdata.root.macro_derive_registrar.map(|index| { DefId { krate: def_id.krate, index } }) } crate_disambiguator => { cdata.disambiguator() } crate_hash => { cdata.hash() } original_crate_name => { cdata.name() } implementations_of_trait => { let mut result = vec![]; let filter = Some(other); cdata.get_implementations_for_trait(filter, &mut result); Rc::new(result) } all_trait_implementations => { let mut result = vec![]; cdata.get_implementations_for_trait(None, &mut result); Rc::new(result) } is_dllimport_foreign_item => { cdata.is_dllimport_foreign_item(def_id.index) } visibility => { cdata.get_visibility(def_id.index) } dep_kind => { cdata.dep_kind.get() } crate_name => { cdata.name } item_children => { let mut result = vec![]; cdata.each_child_of_item(def_id.index, |child| result.push(child), tcx.sess); Rc::new(result) } defined_lang_items => { Rc::new(cdata.get_lang_items()) } missing_lang_items => { Rc::new(cdata.get_missing_lang_items()) } extern_const_body => { debug!("item_body({:?}): inlining item", def_id); cdata.extern_const_body(tcx, def_id.index) } missing_extern_crate_item => { match cdata.extern_crate.get() { Some(extern_crate) if !extern_crate.direct => true, _ => false, } } used_crate_source => { Rc::new(cdata.source.clone()) } } pub fn provide_local<'tcx>(providers: &mut Providers<'tcx>) { fn is_const_fn<'a, 'tcx>(tcx: TyCtxt<'a, 'tcx, 'tcx>, def_id: DefId) -> bool { let node_id = tcx.hir.as_local_node_id(def_id) .expect("Non-local call to local provider is_const_fn"); if let Some(fn_like) = FnLikeNode::from_node(tcx.hir.get(node_id)) { fn_like.constness() == hir::Constness::Const } else { false } } // FIXME(#44234) - almost all of these queries have no sub-queries and // therefore no actual inputs, they're just reading tables calculated in // resolve! Does this work? Unsure! That's what the issue is about *providers = Providers { is_const_fn, is_dllimport_foreign_item: |tcx, id| { tcx.native_library_kind(id) == Some(NativeLibraryKind::NativeUnknown) }, is_statically_included_foreign_item: |tcx, id| { match tcx.native_library_kind(id) { Some(NativeLibraryKind::NativeStatic) | Some(NativeLibraryKind::NativeStaticNobundle) => true, _ => false, } }, native_library_kind: |tcx, id| { tcx.native_libraries(id.krate) .iter() .filter(|lib| native_libs::relevant_lib(&tcx.sess, lib)) .find(|l| l.foreign_items.contains(&id)) .map(|l| l.kind) }, native_libraries: |tcx, cnum| { assert_eq!(cnum, LOCAL_CRATE); Rc::new(native_libs::collect(tcx)) }, link_args: |tcx, cnum| { assert_eq!(cnum, LOCAL_CRATE); Rc::new(link_args::collect(tcx)) }, // Returns a map from a sufficiently visible external item (i.e. an // external item that is visible from at least one local module) to a // sufficiently visible parent (considering modules that re-export the // external item to be parents). visible_parent_map: |tcx, cnum| { use std::collections::vec_deque::VecDeque; use std::collections::hash_map::Entry; assert_eq!(cnum, LOCAL_CRATE); let mut visible_parent_map: DefIdMap = DefIdMap(); for &cnum in tcx.crates().iter() { // Ignore crates without a corresponding local `extern crate` item. if tcx.missing_extern_crate_item(cnum) { continue } let bfs_queue = &mut VecDeque::new(); let visible_parent_map = &mut visible_parent_map; let mut add_child = |bfs_queue: &mut VecDeque<_>, child: &def::Export, parent: DefId| { let child = child.def.def_id(); if tcx.visibility(child) != ty::Visibility::Public { return; } match visible_parent_map.entry(child) { Entry::Occupied(mut entry) => { // If `child` is defined in crate `cnum`, ensure // that it is mapped to a parent in `cnum`. if child.krate == cnum && entry.get().krate != cnum { entry.insert(parent); } } Entry::Vacant(entry) => { entry.insert(parent); bfs_queue.push_back(child); } } }; bfs_queue.push_back(DefId { krate: cnum, index: CRATE_DEF_INDEX }); while let Some(def) = bfs_queue.pop_front() { for child in tcx.item_children(def).iter() { add_child(bfs_queue, child, def); } } } Rc::new(visible_parent_map) }, ..*providers }; } impl CrateStore for cstore::CStore { fn crate_data_as_rc_any(&self, krate: CrateNum) -> Rc { self.get_crate_data(krate) } fn metadata_loader(&self) -> &MetadataLoader { &*self.metadata_loader } fn visibility_untracked(&self, def: DefId) -> ty::Visibility { self.get_crate_data(def.krate).get_visibility(def.index) } fn item_generics_cloned_untracked(&self, def: DefId) -> ty::Generics { self.get_crate_data(def.krate).get_generics(def.index) } fn associated_item_cloned_untracked(&self, def: DefId) -> ty::AssociatedItem { self.get_crate_data(def.krate).get_associated_item(def.index) } fn dep_kind_untracked(&self, cnum: CrateNum) -> DepKind { self.get_crate_data(cnum).dep_kind.get() } fn export_macros_untracked(&self, cnum: CrateNum) { let data = self.get_crate_data(cnum); if data.dep_kind.get() == DepKind::UnexportedMacrosOnly { data.dep_kind.set(DepKind::MacrosOnly) } } fn crate_name_untracked(&self, cnum: CrateNum) -> Symbol { self.get_crate_data(cnum).name } /// Returns the `DefKey` for a given `DefId`. This indicates the /// parent `DefId` as well as some idea of what kind of data the /// `DefId` refers to. fn def_key(&self, def: DefId) -> DefKey { // Note: loading the def-key (or def-path) for a def-id is not // a *read* of its metadata. This is because the def-id is // really just an interned shorthand for a def-path, which is the // canonical name for an item. // // self.dep_graph.read(DepNode::MetaData(def)); self.get_crate_data(def.krate).def_key(def.index) } fn def_path(&self, def: DefId) -> DefPath { // See `Note` above in `def_key()` for why this read is // commented out: // // self.dep_graph.read(DepNode::MetaData(def)); self.get_crate_data(def.krate).def_path(def.index) } fn def_path_hash(&self, def: DefId) -> DefPathHash { self.get_crate_data(def.krate).def_path_hash(def.index) } fn def_path_table(&self, cnum: CrateNum) -> Rc { self.get_crate_data(cnum).def_path_table.clone() } fn struct_field_names_untracked(&self, def: DefId) -> Vec { self.get_crate_data(def.krate).get_struct_field_names(def.index) } fn item_children_untracked(&self, def_id: DefId, sess: &Session) -> Vec { let mut result = vec![]; self.get_crate_data(def_id.krate) .each_child_of_item(def_id.index, |child| result.push(child), sess); result } fn load_macro_untracked(&self, id: DefId, sess: &Session) -> LoadedMacro { let data = self.get_crate_data(id.krate); if let Some(ref proc_macros) = data.proc_macros { return LoadedMacro::ProcMacro(proc_macros[id.index.as_usize() - 1].1.clone()); } else if data.name == "proc_macro" && self.get_crate_data(id.krate).item_name(id.index) == "quote" { let ext = SyntaxExtension::ProcMacro(Box::new(::proc_macro::__internal::Quoter)); return LoadedMacro::ProcMacro(Rc::new(ext)); } let (name, def) = data.get_macro(id.index); let source_name = format!("<{} macros>", name); let filemap = sess.parse_sess.codemap().new_filemap(source_name, def.body); let local_span = Span::new(filemap.start_pos, filemap.end_pos, NO_EXPANSION); let body = filemap_to_stream(&sess.parse_sess, filemap, None); // Mark the attrs as used let attrs = data.get_item_attrs(id.index); for attr in attrs.iter() { attr::mark_used(attr); } let name = data.def_key(id.index).disambiguated_data.data .get_opt_name().expect("no name in load_macro"); sess.imported_macro_spans.borrow_mut() .insert(local_span, (name.to_string(), data.get_span(id.index, sess))); LoadedMacro::MacroDef(ast::Item { ident: ast::Ident::from_str(&name), id: ast::DUMMY_NODE_ID, span: local_span, attrs: attrs.iter().cloned().collect(), node: ast::ItemKind::MacroDef(ast::MacroDef { tokens: body.into(), legacy: def.legacy, }), vis: ast::Visibility::Inherited, tokens: None, }) } fn crates_untracked(&self) -> Vec { let mut result = vec![]; self.iter_crate_data(|cnum, _| result.push(cnum)); result } fn extern_mod_stmt_cnum_untracked(&self, emod_id: ast::NodeId) -> Option { self.do_extern_mod_stmt_cnum(emod_id) } fn postorder_cnums_untracked(&self) -> Vec { self.do_postorder_cnums_untracked() } fn encode_metadata<'a, 'tcx>(&self, tcx: TyCtxt<'a, 'tcx, 'tcx>, link_meta: &LinkMeta, reachable: &NodeSet) -> (EncodedMetadata, EncodedMetadataHashes) { encoder::encode_metadata(tcx, link_meta, reachable) } fn metadata_encoding_version(&self) -> &[u8] { schema::METADATA_HEADER } }