//! Nodes in the dependency graph. //! //! A node in the [dependency graph] is represented by a [`DepNode`]. //! 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. The fingerprinting approach 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. Each `DepKind` has its own parameters that are //! needed at runtime in order to construct a valid `DepNode` fingerprint. //! However, only `CompileCodegenUnit` and `CompileMonoItem` are constructed //! explicitly (with `make_compile_codegen_unit` cq `make_compile_mono_item`). //! //! 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 could 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. //! //! `make_compile_codegen_unit` and `make_compile_mono_items`, 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. //! //! [dependency graph]: https://rustc-dev-guide.rust-lang.org/query.html use crate::mir::mono::MonoItem; use crate::ty::TyCtxt; use rustc_data_structures::fingerprint::Fingerprint; use rustc_hir::def_id::{CrateNum, DefId, LocalDefId}; use rustc_hir::definitions::DefPathHash; use rustc_hir::HirId; use rustc_query_system::dep_graph::FingerprintStyle; use rustc_span::symbol::Symbol; use std::hash::Hash; pub use rustc_query_system::dep_graph::{DepContext, DepNodeParams}; /// This struct stores metadata about each DepKind. /// /// Information is retrieved by indexing the `DEP_KINDS` array using the integer value /// of the `DepKind`. Overall, this allows to implement `DepContext` using this manual /// jump table instead of large matches. pub struct DepKindStruct<'tcx> { /// Anonymous queries cannot be replayed from one compiler invocation to the next. /// When their result is needed, it is recomputed. They are useful for fine-grained /// dependency tracking, and caching within one compiler invocation. pub is_anon: bool, /// Eval-always queries do not track their dependencies, and are always recomputed, even if /// their inputs have not changed since the last compiler invocation. The result is still /// cached within one compiler invocation. pub is_eval_always: bool, /// Whether the query key can be recovered from the hashed fingerprint. /// See [DepNodeParams] trait for the behaviour of each key type. pub fingerprint_style: FingerprintStyle, /// The red/green evaluation system will try to mark a specific DepNode in the /// dependency graph as green by recursively trying to mark the dependencies of /// that `DepNode` as green. While doing so, it will sometimes encounter a `DepNode` /// where we don't know if it is red or green and we therefore actually have /// to recompute its value in order to find out. Since the only piece of /// information that we have at that point is the `DepNode` we are trying to /// re-evaluate, we need some way to re-run a query from just that. This is what /// `force_from_dep_node()` implements. /// /// In the general case, a `DepNode` consists of a `DepKind` and an opaque /// GUID/fingerprint that will uniquely identify the node. This GUID/fingerprint /// is usually constructed by computing a stable hash of the query-key that the /// `DepNode` corresponds to. Consequently, it is not in general possible to go /// back from hash to query-key (since hash functions are not reversible). For /// this reason `force_from_dep_node()` is expected to fail from time to time /// because we just cannot find out, from the `DepNode` alone, what the /// corresponding query-key is and therefore cannot re-run the query. /// /// The system deals with this case letting `try_mark_green` fail which forces /// the root query to be re-evaluated. /// /// Now, if `force_from_dep_node()` would always fail, it would be pretty useless. /// Fortunately, we can use some contextual information that will allow us to /// reconstruct query-keys for certain kinds of `DepNode`s. In particular, we /// enforce by construction that the GUID/fingerprint of certain `DepNode`s is a /// valid `DefPathHash`. Since we also always build a huge table that maps every /// `DefPathHash` in the current codebase to the corresponding `DefId`, we have /// everything we need to re-run the query. /// /// Take the `mir_promoted` query as an example. Like many other queries, it /// just has a single parameter: the `DefId` of the item it will compute the /// validated MIR for. Now, when we call `force_from_dep_node()` on a `DepNode` /// with kind `MirValidated`, we know that the GUID/fingerprint of the `DepNode` /// is actually a `DefPathHash`, and can therefore just look up the corresponding /// `DefId` in `tcx.def_path_hash_to_def_id`. pub force_from_dep_node: Option, dep_node: DepNode) -> bool>, /// Invoke a query to put the on-disk cached value in memory. pub try_load_from_on_disk_cache: Option, DepNode)>, } impl DepKind { #[inline(always)] pub fn fingerprint_style(self, tcx: TyCtxt<'_>) -> FingerprintStyle { // Only fetch the DepKindStruct once. let data = tcx.query_kind(self); if data.is_anon { return FingerprintStyle::Opaque; } data.fingerprint_style } } macro_rules! define_dep_nodes { ( $($(#[$attr:meta])* [$($modifiers:tt)*] fn $variant:ident($($K:tt)*) -> $V:ty,)*) => { #[macro_export] macro_rules! make_dep_kind_array { ($mod:ident) => {[ $($mod::$variant()),* ]}; } /// This enum serves as an index into arrays built by `make_dep_kind_array`. #[derive(Clone, Copy, Debug, PartialEq, Eq, Hash, Encodable, Decodable)] #[allow(non_camel_case_types)] pub enum DepKind { $( $( #[$attr] )* $variant),* } fn dep_kind_from_label_string(label: &str) -> Result { match label { $(stringify!($variant) => Ok(DepKind::$variant),)* _ => Err(()), } } /// Contains variant => str representations for constructing /// DepNode groups for tests. #[allow(dead_code, non_upper_case_globals)] pub mod label_strs { $( pub const $variant: &str = stringify!($variant); )* } }; } rustc_query_append!(define_dep_nodes![ /// We use this for most things when incr. comp. is turned off. [] fn Null() -> (), /// We use this to create a forever-red node. [] fn Red() -> (), [] fn TraitSelect() -> (), [] fn CompileCodegenUnit() -> (), [] fn CompileMonoItem() -> (), ]); // WARNING: `construct` is generic and does not know that `CompileCodegenUnit` takes `Symbol`s as keys. // Be very careful changing this type signature! pub(crate) fn make_compile_codegen_unit(tcx: TyCtxt<'_>, name: Symbol) -> DepNode { DepNode::construct(tcx, DepKind::CompileCodegenUnit, &name) } // WARNING: `construct` is generic and does not know that `CompileMonoItem` takes `MonoItem`s as keys. // Be very careful changing this type signature! pub(crate) fn make_compile_mono_item<'tcx>( tcx: TyCtxt<'tcx>, mono_item: &MonoItem<'tcx>, ) -> DepNode { DepNode::construct(tcx, DepKind::CompileMonoItem, mono_item) } pub type DepNode = rustc_query_system::dep_graph::DepNode; // We keep a lot of `DepNode`s in memory during compilation. It's not // required that their size stay the same, but we don't want to change // it inadvertently. This assert just ensures we're aware of any change. #[cfg(any(target_arch = "x86", target_arch = "x86_64"))] static_assert_size!(DepNode, 18); #[cfg(not(any(target_arch = "x86", target_arch = "x86_64")))] static_assert_size!(DepNode, 24); pub trait DepNodeExt: Sized { /// Construct a DepNode from the given DepKind and DefPathHash. This /// method will assert that the given DepKind actually requires a /// single DefId/DefPathHash parameter. fn from_def_path_hash(tcx: TyCtxt<'_>, def_path_hash: DefPathHash, kind: DepKind) -> Self; /// Extracts 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. fn extract_def_id(&self, tcx: TyCtxt<'_>) -> Option; /// Used in testing fn from_label_string( tcx: TyCtxt<'_>, label: &str, def_path_hash: DefPathHash, ) -> Result; /// Used in testing fn has_label_string(label: &str) -> bool; } impl DepNodeExt for DepNode { /// Construct a DepNode from the given DepKind and DefPathHash. This /// method will assert that the given DepKind actually requires a /// single DefId/DefPathHash parameter. fn from_def_path_hash(tcx: TyCtxt<'_>, def_path_hash: DefPathHash, kind: DepKind) -> DepNode { debug_assert!(kind.fingerprint_style(tcx) == FingerprintStyle::DefPathHash); DepNode { kind, hash: def_path_hash.0.into() } } /// Extracts 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. fn extract_def_id<'tcx>(&self, tcx: TyCtxt<'tcx>) -> Option { if self.kind.fingerprint_style(tcx) == FingerprintStyle::DefPathHash { Some(tcx.def_path_hash_to_def_id(DefPathHash(self.hash.into()), &mut || { panic!("Failed to extract DefId: {:?} {}", self.kind, self.hash) })) } else { None } } /// Used in testing fn from_label_string( tcx: TyCtxt<'_>, label: &str, def_path_hash: DefPathHash, ) -> Result { let kind = dep_kind_from_label_string(label)?; match kind.fingerprint_style(tcx) { FingerprintStyle::Opaque => Err(()), FingerprintStyle::Unit => Ok(DepNode::new_no_params(tcx, kind)), FingerprintStyle::DefPathHash => { Ok(DepNode::from_def_path_hash(tcx, def_path_hash, kind)) } } } /// Used in testing fn has_label_string(label: &str) -> bool { dep_kind_from_label_string(label).is_ok() } } impl<'tcx> DepNodeParams> for () { #[inline(always)] fn fingerprint_style() -> FingerprintStyle { FingerprintStyle::Unit } #[inline(always)] fn to_fingerprint(&self, _: TyCtxt<'tcx>) -> Fingerprint { Fingerprint::ZERO } #[inline(always)] fn recover(_: TyCtxt<'tcx>, _: &DepNode) -> Option { Some(()) } } impl<'tcx> DepNodeParams> for DefId { #[inline(always)] fn fingerprint_style() -> FingerprintStyle { FingerprintStyle::DefPathHash } #[inline(always)] fn to_fingerprint(&self, tcx: TyCtxt<'tcx>) -> Fingerprint { tcx.def_path_hash(*self).0 } #[inline(always)] fn to_debug_str(&self, tcx: TyCtxt<'tcx>) -> String { tcx.def_path_str(*self) } #[inline(always)] fn recover(tcx: TyCtxt<'tcx>, dep_node: &DepNode) -> Option { dep_node.extract_def_id(tcx) } } impl<'tcx> DepNodeParams> for LocalDefId { #[inline(always)] fn fingerprint_style() -> FingerprintStyle { FingerprintStyle::DefPathHash } #[inline(always)] fn to_fingerprint(&self, tcx: TyCtxt<'tcx>) -> Fingerprint { self.to_def_id().to_fingerprint(tcx) } #[inline(always)] fn to_debug_str(&self, tcx: TyCtxt<'tcx>) -> String { self.to_def_id().to_debug_str(tcx) } #[inline(always)] fn recover(tcx: TyCtxt<'tcx>, dep_node: &DepNode) -> Option { dep_node.extract_def_id(tcx).map(|id| id.expect_local()) } } impl<'tcx> DepNodeParams> for CrateNum { #[inline(always)] fn fingerprint_style() -> FingerprintStyle { FingerprintStyle::DefPathHash } #[inline(always)] fn to_fingerprint(&self, tcx: TyCtxt<'tcx>) -> Fingerprint { let def_id = self.as_def_id(); def_id.to_fingerprint(tcx) } #[inline(always)] fn to_debug_str(&self, tcx: TyCtxt<'tcx>) -> String { tcx.crate_name(*self).to_string() } #[inline(always)] fn recover(tcx: TyCtxt<'tcx>, dep_node: &DepNode) -> Option { dep_node.extract_def_id(tcx).map(|id| id.krate) } } impl<'tcx> DepNodeParams> for (DefId, DefId) { #[inline(always)] fn fingerprint_style() -> FingerprintStyle { FingerprintStyle::Opaque } // 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. #[inline(always)] fn to_fingerprint(&self, tcx: TyCtxt<'tcx>) -> 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) } #[inline(always)] fn to_debug_str(&self, tcx: TyCtxt<'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<'tcx> DepNodeParams> for HirId { #[inline(always)] fn fingerprint_style() -> FingerprintStyle { FingerprintStyle::Opaque } // 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. #[inline(always)] fn to_fingerprint(&self, tcx: TyCtxt<'tcx>) -> Fingerprint { let HirId { owner, local_id } = *self; let def_path_hash = tcx.def_path_hash(owner.to_def_id()); let local_id = Fingerprint::from_smaller_hash(local_id.as_u32().into()); def_path_hash.0.combine(local_id) } }