// Copyright 2014 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. //! This module defines the `DepNode` type which the compiler uses to represent //! nodes in the dependency graph. A `DepNode` consists of a `DepKind` (which //! specifies the kind of thing it represents, like a piece of HIR, MIR, etc) //! and a `Fingerprint`, a 128 bit hash value the exact meaning of which //! depends on the node's `DepKind`. Together, the kind and the fingerprint //! fully identify a dependency node, even across multiple compilation sessions. //! In other words, the value of the fingerprint does not depend on anything //! that is specific to a given compilation session, like an unpredictable //! interning key (e.g. NodeId, DefId, Symbol) or the numeric value of a //! pointer. The concept behind this could be compared to how git commit hashes //! uniquely identify a given commit and has a few advantages: //! //! * A `DepNode` can simply be serialized to disk and loaded in another session //! without the need to do any "rebasing (like we have to do for Spans and //! NodeIds) or "retracing" like we had to do for `DefId` in earlier //! implementations of the dependency graph. //! * A `Fingerprint` is just a bunch of bits, which allows `DepNode` to //! implement `Copy`, `Sync`, `Send`, `Freeze`, etc. //! * Since we just have a bit pattern, `DepNode` can be mapped from disk into //! memory without any post-processing (e.g. "abomination-style" pointer //! reconstruction). //! * Because a `DepNode` is self-contained, we can instantiate `DepNodes` that //! refer to things that do not exist anymore. In previous implementations //! `DepNode` contained a `DefId`. A `DepNode` referring to something that //! had been removed between the previous and the current compilation session //! could not be instantiated because the current compilation session //! contained no `DefId` for thing that had been removed. //! //! `DepNode` definition happens in the `define_dep_nodes!()` macro. This macro //! defines the `DepKind` enum and a corresponding `DepConstructor` enum. The //! `DepConstructor` enum links a `DepKind` to the parameters that are needed at //! runtime in order to construct a valid `DepNode` fingerprint. //! //! Because the macro sees what parameters a given `DepKind` requires, it can //! "infer" some properties for each kind of `DepNode`: //! //! * Whether a `DepNode` of a given kind has any parameters at all. Some //! `DepNode`s, like `Krate`, represent global concepts with only one value. //! * Whether it is possible, in principle, to reconstruct a query key from a //! given `DepNode`. Many `DepKind`s only require a single `DefId` parameter, //! in which case it is possible to map the node's fingerprint back to the //! `DefId` it was computed from. In other cases, too much information gets //! lost during fingerprint computation. //! //! The `DepConstructor` enum, together with `DepNode::new()` ensures that only //! valid `DepNode` instances can be constructed. For example, the API does not //! allow for constructing parameterless `DepNode`s with anything other //! than a zeroed out fingerprint. More generally speaking, it relieves the //! user of the `DepNode` API of having to know how to compute the expected //! fingerprint for a given set of node parameters. use hir::def_id::{CrateNum, DefId, DefIndex, CRATE_DEF_INDEX}; use hir::map::DefPathHash; use hir::{HirId, ItemLocalId}; use ich::Fingerprint; use ty::{TyCtxt, Instance, InstanceDef, ParamEnv, ParamEnvAnd, PolyTraitRef, Ty}; use ty::subst::Substs; use rustc_data_structures::stable_hasher::{StableHasher, HashStable}; use ich::StableHashingContext; use std::fmt; use std::hash::Hash; use syntax_pos::symbol::InternedString; // erase!() just makes tokens go away. It's used to specify which macro argument // is repeated (i.e. which sub-expression of the macro we are in) but don't need // to actually use any of the arguments. macro_rules! erase { ($x:tt) => ({}) } macro_rules! is_anon_attr { (anon) => (true); ($attr:ident) => (false); } macro_rules! is_input_attr { (input) => (true); ($attr:ident) => (false); } macro_rules! contains_anon_attr { ($($attr:ident),*) => ({$(is_anon_attr!($attr) | )* false}); } macro_rules! contains_input_attr { ($($attr:ident),*) => ({$(is_input_attr!($attr) | )* false}); } macro_rules! define_dep_nodes { (<$tcx:tt> $( [$($attr:ident),* ] $variant:ident $(( $($tuple_arg:tt),* ))* $({ $($struct_arg_name:ident : $struct_arg_ty:ty),* })* ,)* ) => ( #[derive(Clone, Copy, Debug, PartialEq, Eq, PartialOrd, Ord, Hash, RustcEncodable, RustcDecodable)] pub enum DepKind { $($variant),* } impl DepKind { #[allow(unreachable_code)] #[inline] pub fn can_reconstruct_query_key<$tcx>(&self) -> bool { match *self { $( DepKind :: $variant => { if contains_anon_attr!($($attr),*) { return false; } // tuple args $({ return <( $($tuple_arg,)* ) as DepNodeParams> ::CAN_RECONSTRUCT_QUERY_KEY; })* // struct args $({ return <( $($struct_arg_ty,)* ) as DepNodeParams> ::CAN_RECONSTRUCT_QUERY_KEY; })* true } )* } } #[inline] pub fn is_anon(&self) -> bool { match *self { $( DepKind :: $variant => { contains_anon_attr!($($attr),*) } )* } } #[inline] pub fn is_input(&self) -> bool { match *self { $( DepKind :: $variant => { contains_input_attr!($($attr),*) } )* } } #[allow(unreachable_code)] #[inline] pub fn has_params(&self) -> bool { match *self { $( DepKind :: $variant => { // tuple args $({ $(erase!($tuple_arg);)* return true; })* // struct args $({ $(erase!($struct_arg_name);)* return true; })* false } )* } } } pub enum DepConstructor<$tcx> { $( $variant $(( $($tuple_arg),* ))* $({ $($struct_arg_name : $struct_arg_ty),* })* ),* } #[derive(Clone, Copy, PartialEq, Eq, PartialOrd, Ord, Hash, RustcEncodable, RustcDecodable)] pub struct DepNode { pub kind: DepKind, pub hash: Fingerprint, } impl DepNode { #[allow(unreachable_code, non_snake_case)] pub fn new<'a, 'gcx, 'tcx>(tcx: TyCtxt<'a, 'gcx, 'tcx>, dep: DepConstructor<'gcx>) -> DepNode where 'gcx: 'a + 'tcx, 'tcx: 'a { match dep { $( DepConstructor :: $variant $(( $($tuple_arg),* ))* $({ $($struct_arg_name),* })* => { // tuple args $({ let tupled_args = ( $($tuple_arg,)* ); let hash = DepNodeParams::to_fingerprint(&tupled_args, tcx); let dep_node = DepNode { kind: DepKind::$variant, hash }; if cfg!(debug_assertions) && !dep_node.kind.can_reconstruct_query_key() && (tcx.sess.opts.debugging_opts.incremental_info || tcx.sess.opts.debugging_opts.query_dep_graph) { tcx.dep_graph.register_dep_node_debug_str(dep_node, || { tupled_args.to_debug_str(tcx) }); } return dep_node; })* // struct args $({ let tupled_args = ( $($struct_arg_name,)* ); let hash = DepNodeParams::to_fingerprint(&tupled_args, tcx); let dep_node = DepNode { kind: DepKind::$variant, hash }; if cfg!(debug_assertions) && !dep_node.kind.can_reconstruct_query_key() && (tcx.sess.opts.debugging_opts.incremental_info || tcx.sess.opts.debugging_opts.query_dep_graph) { tcx.dep_graph.register_dep_node_debug_str(dep_node, || { tupled_args.to_debug_str(tcx) }); } return dep_node; })* DepNode { kind: DepKind::$variant, hash: Fingerprint::zero(), } } )* } } /// Construct a DepNode from the given DepKind and DefPathHash. This /// method will assert that the given DepKind actually requires a /// single DefId/DefPathHash parameter. #[inline] pub fn from_def_path_hash(kind: DepKind, def_path_hash: DefPathHash) -> DepNode { assert!(kind.can_reconstruct_query_key() && kind.has_params()); DepNode { kind, hash: def_path_hash.0, } } /// Create a new, parameterless DepNode. This method will assert /// that the DepNode corresponding to the given DepKind actually /// does not require any parameters. #[inline] pub fn new_no_params(kind: DepKind) -> DepNode { assert!(!kind.has_params()); DepNode { kind, hash: Fingerprint::zero(), } } /// Extract the DefId corresponding to this DepNode. This will work /// if two conditions are met: /// /// 1. The Fingerprint of the DepNode actually is a DefPathHash, and /// 2. the item that the DefPath refers to exists in the current tcx. /// /// Condition (1) is determined by the DepKind variant of the /// DepNode. Condition (2) might not be fulfilled if a DepNode /// refers to something from the previous compilation session that /// has been removed. #[inline] pub fn extract_def_id(&self, tcx: TyCtxt) -> Option { if self.kind.can_reconstruct_query_key() { let def_path_hash = DefPathHash(self.hash); if let Some(ref def_path_map) = tcx.def_path_hash_to_def_id.as_ref() { def_path_map.get(&def_path_hash).cloned() } else { None } } else { None } } /// Used in testing pub fn from_label_string(label: &str, def_path_hash: DefPathHash) -> Result { let kind = match label { $( stringify!($variant) => DepKind::$variant, )* _ => return Err(()), }; if !kind.can_reconstruct_query_key() { return Err(()); } if kind.has_params() { Ok(def_path_hash.to_dep_node(kind)) } else { Ok(DepNode::new_no_params(kind)) } } /// Used in testing pub fn has_label_string(label: &str) -> bool { match label { $( stringify!($variant) => true, )* _ => false, } } } /// Contains variant => str representations for constructing /// DepNode groups for tests. #[allow(dead_code, non_upper_case_globals)] pub mod label_strs { $( pub const $variant: &'static str = stringify!($variant); )* } ); } impl fmt::Debug for DepNode { fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { write!(f, "{:?}", self.kind)?; if !self.kind.has_params() && !self.kind.is_anon() { return Ok(()); } write!(f, "(")?; ::ty::tls::with_opt(|opt_tcx| { if let Some(tcx) = opt_tcx { if let Some(def_id) = self.extract_def_id(tcx) { write!(f, "{}", tcx.def_path_debug_str(def_id))?; } else if let Some(ref s) = tcx.dep_graph.dep_node_debug_str(*self) { write!(f, "{}", s)?; } else { write!(f, "{}", self.hash)?; } } else { write!(f, "{}", self.hash)?; } Ok(()) })?; write!(f, ")") } } impl DefPathHash { #[inline] pub fn to_dep_node(self, kind: DepKind) -> DepNode { DepNode::from_def_path_hash(kind, self) } } impl DefId { #[inline] pub fn to_dep_node(self, tcx: TyCtxt, kind: DepKind) -> DepNode { DepNode::from_def_path_hash(kind, tcx.def_path_hash(self)) } } impl DepKind { #[inline] pub fn fingerprint_needed_for_crate_hash(self) -> bool { match self { DepKind::HirBody | DepKind::Krate => true, _ => false, } } } define_dep_nodes!( <'tcx> // Represents the `Krate` as a whole (the `hir::Krate` value) (as // distinct from the krate module). This is basically a hash of // the entire krate, so if you read from `Krate` (e.g., by calling // `tcx.hir.krate()`), we will have to assume that any change // means that you need to be recompiled. This is because the // `Krate` value gives you access to all other items. To avoid // this fate, do not call `tcx.hir.krate()`; instead, prefer // wrappers like `tcx.visit_all_items_in_krate()`. If there is no // suitable wrapper, you can use `tcx.dep_graph.ignore()` to gain // access to the krate, but you must remember to add suitable // edges yourself for the individual items that you read. [input] Krate, // Represents the body of a function or method. The def-id is that of the // function/method. [input] HirBody(DefId), // Represents the HIR node with the given node-id [input] Hir(DefId), // Represents metadata from an extern crate. [input] CrateMetadata(CrateNum), // Represents some artifact that we save to disk. Note that these // do not have a def-id as part of their identifier. [] WorkProduct(WorkProductId), // Represents different phases in the compiler. [] RegionScopeTree(DefId), [] Coherence, [] CoherenceInherentImplOverlapCheck, [] CoherenceCheckTrait(DefId), [] PrivacyAccessLevels(CrateNum), // Represents the MIR for a fn; also used as the task node for // things read/modify that MIR. [] MirConstQualif(DefId), [] MirConst(DefId), [] MirValidated(DefId), [] MirOptimized(DefId), [] MirShim { instance_def: InstanceDef<'tcx> }, [] BorrowCheckKrate, [] BorrowCheck(DefId), [] MirBorrowCheck(DefId), [] UnsafetyViolations(DefId), [] Reachability, [] MirKeys, [] CrateVariances, // Nodes representing bits of computed IR in the tcx. Each shared // table in the tcx (or elsewhere) maps to one of these // nodes. [] AssociatedItems(DefId), [] TypeOfItem(DefId), [] GenericsOfItem(DefId), [] PredicatesOfItem(DefId), [] InferredOutlivesOf(DefId), [] SuperPredicatesOfItem(DefId), [] TraitDefOfItem(DefId), [] AdtDefOfItem(DefId), [] IsDefaultImpl(DefId), [] ImplTraitRef(DefId), [] ImplPolarity(DefId), [] ClosureKind(DefId), [] FnSignature(DefId), [] GenSignature(DefId), [] CoerceUnsizedInfo(DefId), [] ItemVarianceConstraints(DefId), [] ItemVariances(DefId), [] IsConstFn(DefId), [] IsForeignItem(DefId), [] TypeParamPredicates { item_id: DefId, param_id: DefId }, [] SizedConstraint(DefId), [] DtorckConstraint(DefId), [] AdtDestructor(DefId), [] AssociatedItemDefIds(DefId), [] InherentImpls(DefId), [] TypeckBodiesKrate, [] TypeckTables(DefId), [] HasTypeckTables(DefId), [] ConstEval { param_env: ParamEnvAnd<'tcx, (DefId, &'tcx Substs<'tcx>)> }, [] SymbolName(DefId), [] InstanceSymbolName { instance: Instance<'tcx> }, [] SpecializationGraph(DefId), [] ObjectSafety(DefId), [] FulfillObligation { param_env: ParamEnv<'tcx>, trait_ref: PolyTraitRef<'tcx> }, [] VtableMethods { trait_ref: PolyTraitRef<'tcx> }, [] IsCopy { param_env: ParamEnvAnd<'tcx, Ty<'tcx>> }, [] IsSized { param_env: ParamEnvAnd<'tcx, Ty<'tcx>> }, [] IsFreeze { param_env: ParamEnvAnd<'tcx, Ty<'tcx>> }, [] NeedsDrop { param_env: ParamEnvAnd<'tcx, Ty<'tcx>> }, [] Layout { param_env: ParamEnvAnd<'tcx, Ty<'tcx>> }, // The set of impls for a given trait. [] TraitImpls(DefId), [] AllLocalTraitImpls, // Trait selection cache is a little funny. Given a trait // reference like `Foo: SomeTrait`, there could be // arbitrarily many def-ids to map on in there (e.g., `Foo`, // `SomeTrait`, `Bar`). We could have a vector of them, but it // requires heap-allocation, and trait sel in general can be a // surprisingly hot path. So instead we pick two def-ids: the // trait def-id, and the first def-id in the input types. If there // is no def-id in the input types, then we use the trait def-id // again. So for example: // // - `i32: Clone` -> `TraitSelect { trait_def_id: Clone, self_def_id: Clone }` // - `u32: Clone` -> `TraitSelect { trait_def_id: Clone, self_def_id: Clone }` // - `Clone: Clone` -> `TraitSelect { trait_def_id: Clone, self_def_id: Clone }` // - `Vec: Clone` -> `TraitSelect { trait_def_id: Clone, self_def_id: Vec }` // - `String: Clone` -> `TraitSelect { trait_def_id: Clone, self_def_id: String }` // - `Foo: Trait` -> `TraitSelect { trait_def_id: Trait, self_def_id: Foo }` // - `Foo: Trait` -> `TraitSelect { trait_def_id: Trait, self_def_id: Foo }` // - `(Foo, Bar): Trait` -> `TraitSelect { trait_def_id: Trait, self_def_id: Foo }` // - `i32: Trait` -> `TraitSelect { trait_def_id: Trait, self_def_id: Foo }` // // You can see that we map many trait refs to the same // trait-select node. This is not a problem, it just means // imprecision in our dep-graph tracking. The important thing is // that for any given trait-ref, we always map to the **same** // trait-select node. [anon] TraitSelect, [] ParamEnv(DefId), [] DescribeDef(DefId), [] DefSpan(DefId), [] LookupStability(DefId), [] LookupDeprecationEntry(DefId), [] ItemBodyNestedBodies(DefId), [] ConstIsRvaluePromotableToStatic(DefId), [] RvaluePromotableMap(DefId), [] ImplParent(DefId), [] TraitOfItem(DefId), [] IsExportedSymbol(DefId), [] IsMirAvailable(DefId), [] ItemAttrs(DefId), [] FnArgNames(DefId), [] DylibDepFormats(CrateNum), [] IsPanicRuntime(CrateNum), [] IsCompilerBuiltins(CrateNum), [] HasGlobalAllocator(CrateNum), [] ExternCrate(DefId), [] LintLevels, [] Specializes { impl1: DefId, impl2: DefId }, [input] InScopeTraits(DefIndex), [] ModuleExports(DefId), [] IsSanitizerRuntime(CrateNum), [] IsProfilerRuntime(CrateNum), [] GetPanicStrategy(CrateNum), [] IsNoBuiltins(CrateNum), [] ImplDefaultness(DefId), [] ExportedSymbolIds(CrateNum), [] NativeLibraries(CrateNum), [] PluginRegistrarFn(CrateNum), [] DeriveRegistrarFn(CrateNum), [] CrateDisambiguator(CrateNum), [] CrateHash(CrateNum), [] OriginalCrateName(CrateNum), [] ImplementationsOfTrait { krate: CrateNum, trait_id: DefId }, [] AllTraitImplementations(CrateNum), [] IsDllimportForeignItem(DefId), [] IsStaticallyIncludedForeignItem(DefId), [] NativeLibraryKind(DefId), [] LinkArgs, [] NamedRegion(DefIndex), [] IsLateBound(DefIndex), [] ObjectLifetimeDefaults(DefIndex), [] Visibility(DefId), [] DepKind(CrateNum), [] CrateName(CrateNum), [] ItemChildren(DefId), [] ExternModStmtCnum(DefId), [] GetLangItems, [] DefinedLangItems(CrateNum), [] MissingLangItems(CrateNum), [] ExternConstBody(DefId), [] VisibleParentMap, [] MissingExternCrateItem(CrateNum), [] UsedCrateSource(CrateNum), [] PostorderCnums, [] HasCloneClosures(CrateNum), [] HasCopyClosures(CrateNum), // This query is not expected to have inputs -- as a result, it's // not a good candidate for "replay" because it's essentially a // pure function of its input (and hence the expectation is that // no caller would be green **apart** from just this // query). Making it anonymous avoids hashing the result, which // may save a bit of time. [anon] EraseRegionsTy { ty: Ty<'tcx> }, [] Freevars(DefId), [] MaybeUnusedTraitImport(DefId), [] MaybeUnusedExternCrates, [] StabilityIndex, [] AllCrateNums, [] ExportedSymbols(CrateNum), [] CollectAndPartitionTranslationItems, [] ExportName(DefId), [] ContainsExternIndicator(DefId), [] IsTranslatedFunction(DefId), [] CodegenUnit(InternedString), [] CompileCodegenUnit(InternedString), [] OutputFilenames, // We use this for most things when incr. comp. is turned off. [] Null, ); trait DepNodeParams<'a, 'gcx: 'tcx + 'a, 'tcx: 'a> : fmt::Debug { const CAN_RECONSTRUCT_QUERY_KEY: bool; /// This method turns the parameters of a DepNodeConstructor into an opaque /// Fingerprint to be used in DepNode. /// Not all DepNodeParams support being turned into a Fingerprint (they /// don't need to if the corresponding DepNode is anonymous). fn to_fingerprint(&self, _: TyCtxt<'a, 'gcx, 'tcx>) -> Fingerprint { panic!("Not implemented. Accidentally called on anonymous node?") } fn to_debug_str(&self, _: TyCtxt<'a, 'gcx, 'tcx>) -> String { format!("{:?}", self) } } impl<'a, 'gcx: 'tcx + 'a, 'tcx: 'a, T> DepNodeParams<'a, 'gcx, 'tcx> for T where T: HashStable> + fmt::Debug { default const CAN_RECONSTRUCT_QUERY_KEY: bool = false; default fn to_fingerprint(&self, tcx: TyCtxt<'a, 'gcx, 'tcx>) -> Fingerprint { let mut hcx = tcx.create_stable_hashing_context(); let mut hasher = StableHasher::new(); self.hash_stable(&mut hcx, &mut hasher); hasher.finish() } default fn to_debug_str(&self, _: TyCtxt<'a, 'gcx, 'tcx>) -> String { format!("{:?}", *self) } } impl<'a, 'gcx: 'tcx + 'a, 'tcx: 'a> DepNodeParams<'a, 'gcx, 'tcx> for (DefId,) { const CAN_RECONSTRUCT_QUERY_KEY: bool = true; fn to_fingerprint(&self, tcx: TyCtxt) -> Fingerprint { tcx.def_path_hash(self.0).0 } fn to_debug_str(&self, tcx: TyCtxt<'a, 'gcx, 'tcx>) -> String { tcx.item_path_str(self.0) } } impl<'a, 'gcx: 'tcx + 'a, 'tcx: 'a> DepNodeParams<'a, 'gcx, 'tcx> for (DefIndex,) { const CAN_RECONSTRUCT_QUERY_KEY: bool = true; fn to_fingerprint(&self, tcx: TyCtxt) -> Fingerprint { tcx.hir.definitions().def_path_hash(self.0).0 } fn to_debug_str(&self, tcx: TyCtxt<'a, 'gcx, 'tcx>) -> String { tcx.item_path_str(DefId::local(self.0)) } } impl<'a, 'gcx: 'tcx + 'a, 'tcx: 'a> DepNodeParams<'a, 'gcx, 'tcx> for (CrateNum,) { const CAN_RECONSTRUCT_QUERY_KEY: bool = true; fn to_fingerprint(&self, tcx: TyCtxt) -> Fingerprint { let def_id = DefId { krate: self.0, index: CRATE_DEF_INDEX, }; tcx.def_path_hash(def_id).0 } fn to_debug_str(&self, tcx: TyCtxt<'a, 'gcx, 'tcx>) -> String { tcx.crate_name(self.0).as_str().to_string() } } impl<'a, 'gcx: 'tcx + 'a, 'tcx: 'a> DepNodeParams<'a, 'gcx, 'tcx> for (DefId, DefId) { const CAN_RECONSTRUCT_QUERY_KEY: bool = false; // We actually would not need to specialize the implementation of this // method but it's faster to combine the hashes than to instantiate a full // hashing context and stable-hashing state. fn to_fingerprint(&self, tcx: TyCtxt) -> Fingerprint { let (def_id_0, def_id_1) = *self; let def_path_hash_0 = tcx.def_path_hash(def_id_0); let def_path_hash_1 = tcx.def_path_hash(def_id_1); def_path_hash_0.0.combine(def_path_hash_1.0) } fn to_debug_str(&self, tcx: TyCtxt<'a, 'gcx, 'tcx>) -> String { let (def_id_0, def_id_1) = *self; format!("({}, {})", tcx.def_path_debug_str(def_id_0), tcx.def_path_debug_str(def_id_1)) } } impl<'a, 'gcx: 'tcx + 'a, 'tcx: 'a> DepNodeParams<'a, 'gcx, 'tcx> for (HirId,) { const CAN_RECONSTRUCT_QUERY_KEY: bool = false; // We actually would not need to specialize the implementation of this // method but it's faster to combine the hashes than to instantiate a full // hashing context and stable-hashing state. fn to_fingerprint(&self, tcx: TyCtxt) -> Fingerprint { let (HirId { owner, local_id: ItemLocalId(local_id), },) = *self; let def_path_hash = tcx.def_path_hash(DefId::local(owner)); let local_id = Fingerprint::from_smaller_hash(local_id as u64); def_path_hash.0.combine(local_id) } } /// A "work product" corresponds to a `.o` (or other) file that we /// save in between runs. These ids do not have a DefId but rather /// some independent path or string that persists between runs without /// the need to be mapped or unmapped. (This ensures we can serialize /// them even in the absence of a tcx.) #[derive(Clone, Copy, Debug, PartialEq, Eq, PartialOrd, Ord, Hash, RustcEncodable, RustcDecodable)] pub struct WorkProductId { hash: Fingerprint } impl WorkProductId { pub fn from_cgu_name(cgu_name: &str) -> WorkProductId { let mut hasher = StableHasher::new(); cgu_name.len().hash(&mut hasher); cgu_name.hash(&mut hasher); WorkProductId { hash: hasher.finish() } } pub fn from_fingerprint(fingerprint: Fingerprint) -> WorkProductId { WorkProductId { hash: fingerprint } } pub fn to_dep_node(self) -> DepNode { DepNode { kind: DepKind::WorkProduct, hash: self.hash, } } } impl_stable_hash_for!(struct ::dep_graph::WorkProductId { hash });