| // Copyright 2012-2015 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 <LICENSE-APACHE or |
| // http://www.apache.org/licenses/LICENSE-2.0> or the MIT license |
| // <LICENSE-MIT or http://opensource.org/licenses/MIT>, at your |
| // option. This file may not be copied, modified, or distributed |
| // except according to those terms. |
| |
| //! The implementation of the query system itself. Defines the macros |
| //! that generate the actual methods on tcx which find and execute the |
| //! provider, manage the caches, and so forth. |
| |
| use dep_graph::{DepNodeIndex, DepNode, DepKind}; |
| use errors::{Diagnostic, DiagnosticBuilder}; |
| use ty::{TyCtxt}; |
| use ty::maps::Query; // NB: actually generated by the macros in this file |
| use ty::maps::config::QueryDescription; |
| use ty::item_path; |
| |
| use rustc_data_structures::fx::{FxHashMap}; |
| use std::cell::{RefMut, Cell}; |
| use std::marker::PhantomData; |
| use std::mem; |
| use syntax_pos::Span; |
| |
| pub(super) struct QueryMap<D: QueryDescription> { |
| phantom: PhantomData<D>, |
| pub(super) map: FxHashMap<D::Key, QueryValue<D::Value>>, |
| } |
| |
| pub(super) struct QueryValue<T> { |
| pub(super) value: T, |
| pub(super) index: DepNodeIndex, |
| pub(super) diagnostics: Option<Box<QueryDiagnostics>>, |
| } |
| |
| impl<T> QueryValue<T> { |
| pub(super) fn new(value: T, |
| dep_node_index: DepNodeIndex, |
| diagnostics: Vec<Diagnostic>) |
| -> QueryValue<T> { |
| QueryValue { |
| value, |
| index: dep_node_index, |
| diagnostics: if diagnostics.len() == 0 { |
| None |
| } else { |
| Some(Box::new(QueryDiagnostics { |
| diagnostics, |
| emitted_diagnostics: Cell::new(true), |
| })) |
| }, |
| } |
| } |
| } |
| |
| pub(super) struct QueryDiagnostics { |
| pub(super) diagnostics: Vec<Diagnostic>, |
| pub(super) emitted_diagnostics: Cell<bool>, |
| } |
| |
| impl<M: QueryDescription> QueryMap<M> { |
| pub(super) fn new() -> QueryMap<M> { |
| QueryMap { |
| phantom: PhantomData, |
| map: FxHashMap(), |
| } |
| } |
| } |
| |
| pub(super) struct CycleError<'a, 'tcx: 'a> { |
| span: Span, |
| cycle: RefMut<'a, [(Span, Query<'tcx>)]>, |
| } |
| |
| impl<'a, 'gcx, 'tcx> TyCtxt<'a, 'gcx, 'tcx> { |
| pub(super) fn report_cycle(self, CycleError { span, cycle }: CycleError) |
| -> DiagnosticBuilder<'a> |
| { |
| // Subtle: release the refcell lock before invoking `describe()` |
| // below by dropping `cycle`. |
| let stack = cycle.to_vec(); |
| mem::drop(cycle); |
| |
| assert!(!stack.is_empty()); |
| |
| // Disable naming impls with types in this path, since that |
| // sometimes cycles itself, leading to extra cycle errors. |
| // (And cycle errors around impls tend to occur during the |
| // collect/coherence phases anyhow.) |
| item_path::with_forced_impl_filename_line(|| { |
| let mut err = |
| struct_span_err!(self.sess, span, E0391, |
| "unsupported cyclic reference between types/traits detected"); |
| err.span_label(span, "cyclic reference"); |
| |
| err.span_note(stack[0].0, &format!("the cycle begins when {}...", |
| stack[0].1.describe(self))); |
| |
| for &(span, ref query) in &stack[1..] { |
| err.span_note(span, &format!("...which then requires {}...", |
| query.describe(self))); |
| } |
| |
| err.note(&format!("...which then again requires {}, completing the cycle.", |
| stack[0].1.describe(self))); |
| |
| return err |
| }) |
| } |
| |
| pub(super) fn cycle_check<F, R>(self, span: Span, query: Query<'gcx>, compute: F) |
| -> Result<R, CycleError<'a, 'gcx>> |
| where F: FnOnce() -> R |
| { |
| { |
| let mut stack = self.maps.query_stack.borrow_mut(); |
| if let Some((i, _)) = stack.iter().enumerate().rev() |
| .find(|&(_, &(_, ref q))| *q == query) { |
| return Err(CycleError { |
| span, |
| cycle: RefMut::map(stack, |stack| &mut stack[i..]) |
| }); |
| } |
| stack.push((span, query)); |
| } |
| |
| let result = compute(); |
| |
| self.maps.query_stack.borrow_mut().pop(); |
| |
| Ok(result) |
| } |
| } |
| |
| // If enabled, send a message to the profile-queries thread |
| macro_rules! profq_msg { |
| ($tcx:expr, $msg:expr) => { |
| if cfg!(debug_assertions) { |
| if $tcx.sess.profile_queries() { |
| profq_msg($msg) |
| } |
| } |
| } |
| } |
| |
| // If enabled, format a key using its debug string, which can be |
| // expensive to compute (in terms of time). |
| macro_rules! profq_key { |
| ($tcx:expr, $key:expr) => { |
| if cfg!(debug_assertions) { |
| if $tcx.sess.profile_queries_and_keys() { |
| Some(format!("{:?}", $key)) |
| } else { None } |
| } else { None } |
| } |
| } |
| |
| macro_rules! define_maps { |
| (<$tcx:tt> |
| $($(#[$attr:meta])* |
| [$($modifiers:tt)*] fn $name:ident: $node:ident($K:ty) -> $V:ty,)*) => { |
| |
| use dep_graph::DepNodeIndex; |
| use std::cell::RefCell; |
| |
| define_map_struct! { |
| tcx: $tcx, |
| input: ($(([$($modifiers)*] [$($attr)*] [$name]))*) |
| } |
| |
| impl<$tcx> Maps<$tcx> { |
| pub fn new(providers: IndexVec<CrateNum, Providers<$tcx>>) |
| -> Self { |
| Maps { |
| providers, |
| query_stack: RefCell::new(vec![]), |
| $($name: RefCell::new(QueryMap::new())),* |
| } |
| } |
| } |
| |
| #[allow(bad_style)] |
| #[derive(Copy, Clone, Debug, PartialEq, Eq)] |
| pub enum Query<$tcx> { |
| $($(#[$attr])* $name($K)),* |
| } |
| |
| #[allow(bad_style)] |
| #[derive(Clone, Debug, PartialEq, Eq)] |
| pub enum QueryMsg { |
| $($name(Option<String>)),* |
| } |
| |
| impl<$tcx> Query<$tcx> { |
| pub fn describe(&self, tcx: TyCtxt) -> String { |
| let (r, name) = match *self { |
| $(Query::$name(key) => { |
| (queries::$name::describe(tcx, key), stringify!($name)) |
| })* |
| }; |
| if tcx.sess.verbose() { |
| format!("{} [{}]", r, name) |
| } else { |
| r |
| } |
| } |
| } |
| |
| pub mod queries { |
| use std::marker::PhantomData; |
| |
| $(#[allow(bad_style)] |
| pub struct $name<$tcx> { |
| data: PhantomData<&$tcx ()> |
| })* |
| } |
| |
| $(impl<$tcx> QueryConfig for queries::$name<$tcx> { |
| type Key = $K; |
| type Value = $V; |
| } |
| |
| impl<'a, $tcx, 'lcx> queries::$name<$tcx> { |
| |
| #[allow(unused)] |
| fn to_dep_node(tcx: TyCtxt<'a, $tcx, 'lcx>, key: &$K) -> DepNode { |
| use dep_graph::DepConstructor::*; |
| |
| DepNode::new(tcx, $node(*key)) |
| } |
| |
| fn try_get_with(tcx: TyCtxt<'a, $tcx, 'lcx>, |
| mut span: Span, |
| key: $K) |
| -> Result<$V, CycleError<'a, $tcx>> |
| { |
| debug!("ty::queries::{}::try_get_with(key={:?}, span={:?})", |
| stringify!($name), |
| key, |
| span); |
| |
| profq_msg!(tcx, |
| ProfileQueriesMsg::QueryBegin( |
| span.data(), |
| QueryMsg::$name(profq_key!(tcx, key)) |
| ) |
| ); |
| |
| if let Some(value) = tcx.maps.$name.borrow().map.get(&key) { |
| if let Some(ref d) = value.diagnostics { |
| if !d.emitted_diagnostics.get() { |
| d.emitted_diagnostics.set(true); |
| let handle = tcx.sess.diagnostic(); |
| for diagnostic in d.diagnostics.iter() { |
| DiagnosticBuilder::new_diagnostic(handle, diagnostic.clone()) |
| .emit(); |
| } |
| } |
| } |
| profq_msg!(tcx, ProfileQueriesMsg::CacheHit); |
| tcx.dep_graph.read_index(value.index); |
| return Ok((&value.value).clone()); |
| } |
| |
| // FIXME(eddyb) Get more valid Span's on queries. |
| // def_span guard is necessary to prevent a recursive loop, |
| // default_span calls def_span query internally. |
| if span == DUMMY_SP && stringify!($name) != "def_span" { |
| span = key.default_span(tcx) |
| } |
| |
| // Fast path for when incr. comp. is off. `to_dep_node` is |
| // expensive for some DepKinds. |
| if !tcx.dep_graph.is_fully_enabled() { |
| let null_dep_node = DepNode::new_no_params(::dep_graph::DepKind::Null); |
| return Self::force(tcx, key, span, null_dep_node) |
| .map(|(v, _)| v); |
| } |
| |
| let dep_node = Self::to_dep_node(tcx, &key); |
| |
| if dep_node.kind.is_anon() { |
| profq_msg!(tcx, ProfileQueriesMsg::ProviderBegin); |
| |
| let res = tcx.cycle_check(span, Query::$name(key), || { |
| tcx.sess.diagnostic().track_diagnostics(|| { |
| tcx.dep_graph.with_anon_task(dep_node.kind, || { |
| Self::compute_result(tcx.global_tcx(), key) |
| }) |
| }) |
| })?; |
| |
| profq_msg!(tcx, ProfileQueriesMsg::ProviderEnd); |
| let ((result, dep_node_index), diagnostics) = res; |
| |
| tcx.dep_graph.read_index(dep_node_index); |
| let value = QueryValue::new(result, dep_node_index, diagnostics); |
| |
| return Ok((&tcx.maps |
| .$name |
| .borrow_mut() |
| .map |
| .entry(key) |
| .or_insert(value) |
| .value).clone()); |
| } |
| |
| if !dep_node.kind.is_input() { |
| use dep_graph::DepNodeColor; |
| if let Some(DepNodeColor::Green(dep_node_index)) = tcx.dep_graph |
| .node_color(&dep_node) { |
| profq_msg!(tcx, ProfileQueriesMsg::CacheHit); |
| tcx.dep_graph.read_index(dep_node_index); |
| return Self::load_from_disk_and_cache_in_memory(tcx, |
| key, |
| span, |
| dep_node_index) |
| } |
| |
| debug!("ty::queries::{}::try_get_with(key={:?}) - running try_mark_green", |
| stringify!($name), |
| key); |
| |
| if let Some(dep_node_index) = tcx.dep_graph.try_mark_green(tcx, &dep_node) { |
| debug_assert!(tcx.dep_graph.is_green(dep_node_index)); |
| profq_msg!(tcx, ProfileQueriesMsg::CacheHit); |
| tcx.dep_graph.read_index(dep_node_index); |
| return Self::load_from_disk_and_cache_in_memory(tcx, |
| key, |
| span, |
| dep_node_index) |
| } |
| } |
| |
| match Self::force(tcx, key, span, dep_node) { |
| Ok((result, dep_node_index)) => { |
| tcx.dep_graph.read_index(dep_node_index); |
| Ok(result) |
| } |
| Err(e) => Err(e) |
| } |
| } |
| |
| /// Ensure that either this query has all green inputs or been executed. |
| /// Executing query::ensure(D) is considered a read of the dep-node D. |
| /// |
| /// This function is particularly useful when executing passes for their |
| /// side-effects -- e.g., in order to report errors for erroneous programs. |
| /// |
| /// Note: The optimization is only available during incr. comp. |
| pub fn ensure(tcx: TyCtxt<'a, $tcx, 'lcx>, key: $K) -> () { |
| let dep_node = Self::to_dep_node(tcx, &key); |
| |
| // Ensuring an "input" or anonymous query makes no sense |
| assert!(!dep_node.kind.is_anon()); |
| assert!(!dep_node.kind.is_input()); |
| use dep_graph::DepNodeColor; |
| match tcx.dep_graph.node_color(&dep_node) { |
| Some(DepNodeColor::Green(dep_node_index)) => { |
| tcx.dep_graph.read_index(dep_node_index); |
| } |
| Some(DepNodeColor::Red) => { |
| // A DepNodeColor::Red DepNode means that this query was executed |
| // before. We can not call `dep_graph.read()` here as we don't have |
| // the DepNodeIndex. Instead, We call the query again to issue the |
| // appropriate `dep_graph.read()` call. The performance cost this |
| // introduces should be negligible as we'll immediately hit the |
| // in-memory cache. |
| let _ = tcx.$name(key); |
| } |
| None => { |
| // Huh |
| if !tcx.dep_graph.is_fully_enabled() { |
| let _ = tcx.$name(key); |
| return; |
| } |
| match tcx.dep_graph.try_mark_green(tcx, &dep_node) { |
| Some(dep_node_index) => { |
| debug_assert!(tcx.dep_graph.is_green(dep_node_index)); |
| tcx.dep_graph.read_index(dep_node_index); |
| } |
| None => { |
| let _ = tcx.$name(key); |
| } |
| } |
| } |
| } |
| } |
| |
| fn compute_result(tcx: TyCtxt<'a, $tcx, 'lcx>, key: $K) -> $V { |
| let provider = tcx.maps.providers[key.map_crate()].$name; |
| provider(tcx.global_tcx(), key) |
| } |
| |
| fn load_from_disk_and_cache_in_memory(tcx: TyCtxt<'a, $tcx, 'lcx>, |
| key: $K, |
| span: Span, |
| dep_node_index: DepNodeIndex) |
| -> Result<$V, CycleError<'a, $tcx>> |
| { |
| debug_assert!(tcx.dep_graph.is_green(dep_node_index)); |
| |
| // We don't do any caching yet, so recompute |
| let (result, diagnostics) = tcx.cycle_check(span, Query::$name(key), || { |
| tcx.sess.diagnostic().track_diagnostics(|| { |
| // The dep-graph for this computation is already in place |
| tcx.dep_graph.with_ignore(|| { |
| Self::compute_result(tcx, key) |
| }) |
| }) |
| })?; |
| |
| if tcx.sess.opts.debugging_opts.query_dep_graph { |
| tcx.dep_graph.mark_loaded_from_cache(dep_node_index, true); |
| } |
| |
| let value = QueryValue::new(result, dep_node_index, diagnostics); |
| |
| Ok((&tcx.maps |
| .$name |
| .borrow_mut() |
| .map |
| .entry(key) |
| .or_insert(value) |
| .value).clone()) |
| } |
| |
| fn force(tcx: TyCtxt<'a, $tcx, 'lcx>, |
| key: $K, |
| span: Span, |
| dep_node: DepNode) |
| -> Result<($V, DepNodeIndex), CycleError<'a, $tcx>> { |
| debug_assert!(tcx.dep_graph.node_color(&dep_node).is_none()); |
| |
| profq_msg!(tcx, ProfileQueriesMsg::ProviderBegin); |
| let res = tcx.cycle_check(span, Query::$name(key), || { |
| tcx.sess.diagnostic().track_diagnostics(|| { |
| tcx.dep_graph.with_task(dep_node, |
| tcx, |
| key, |
| Self::compute_result) |
| }) |
| })?; |
| profq_msg!(tcx, ProfileQueriesMsg::ProviderEnd); |
| |
| let ((result, dep_node_index), diagnostics) = res; |
| |
| if tcx.sess.opts.debugging_opts.query_dep_graph { |
| tcx.dep_graph.mark_loaded_from_cache(dep_node_index, false); |
| } |
| |
| let value = QueryValue::new(result, dep_node_index, diagnostics); |
| |
| Ok(((&tcx.maps |
| .$name |
| .borrow_mut() |
| .map |
| .entry(key) |
| .or_insert(value) |
| .value).clone(), |
| dep_node_index)) |
| } |
| |
| pub fn try_get(tcx: TyCtxt<'a, $tcx, 'lcx>, span: Span, key: $K) |
| -> Result<$V, DiagnosticBuilder<'a>> { |
| match Self::try_get_with(tcx, span, key) { |
| Ok(e) => Ok(e), |
| Err(e) => Err(tcx.report_cycle(e)), |
| } |
| } |
| })* |
| |
| #[derive(Copy, Clone)] |
| pub struct TyCtxtAt<'a, 'gcx: 'a+'tcx, 'tcx: 'a> { |
| pub tcx: TyCtxt<'a, 'gcx, 'tcx>, |
| pub span: Span, |
| } |
| |
| impl<'a, 'gcx, 'tcx> Deref for TyCtxtAt<'a, 'gcx, 'tcx> { |
| type Target = TyCtxt<'a, 'gcx, 'tcx>; |
| fn deref(&self) -> &Self::Target { |
| &self.tcx |
| } |
| } |
| |
| impl<'a, $tcx, 'lcx> TyCtxt<'a, $tcx, 'lcx> { |
| /// Return a transparent wrapper for `TyCtxt` which uses |
| /// `span` as the location of queries performed through it. |
| pub fn at(self, span: Span) -> TyCtxtAt<'a, $tcx, 'lcx> { |
| TyCtxtAt { |
| tcx: self, |
| span |
| } |
| } |
| |
| $($(#[$attr])* |
| pub fn $name(self, key: $K) -> $V { |
| self.at(DUMMY_SP).$name(key) |
| })* |
| } |
| |
| impl<'a, $tcx, 'lcx> TyCtxtAt<'a, $tcx, 'lcx> { |
| $($(#[$attr])* |
| pub fn $name(self, key: $K) -> $V { |
| queries::$name::try_get(self.tcx, self.span, key).unwrap_or_else(|mut e| { |
| e.emit(); |
| Value::from_cycle_error(self.global_tcx()) |
| }) |
| })* |
| } |
| |
| define_provider_struct! { |
| tcx: $tcx, |
| input: ($(([$($modifiers)*] [$name] [$K] [$V]))*) |
| } |
| |
| impl<$tcx> Copy for Providers<$tcx> {} |
| impl<$tcx> Clone for Providers<$tcx> { |
| fn clone(&self) -> Self { *self } |
| } |
| } |
| } |
| |
| macro_rules! define_map_struct { |
| (tcx: $tcx:tt, |
| input: ($(([$(modifiers:tt)*] [$($attr:tt)*] [$name:ident]))*)) => { |
| pub struct Maps<$tcx> { |
| providers: IndexVec<CrateNum, Providers<$tcx>>, |
| query_stack: RefCell<Vec<(Span, Query<$tcx>)>>, |
| $($(#[$attr])* $name: RefCell<QueryMap<queries::$name<$tcx>>>,)* |
| } |
| }; |
| } |
| |
| macro_rules! define_provider_struct { |
| (tcx: $tcx:tt, |
| input: ($(([$($modifiers:tt)*] [$name:ident] [$K:ty] [$R:ty]))*)) => { |
| pub struct Providers<$tcx> { |
| $(pub $name: for<'a> fn(TyCtxt<'a, $tcx, $tcx>, $K) -> $R,)* |
| } |
| |
| impl<$tcx> Default for Providers<$tcx> { |
| fn default() -> Self { |
| $(fn $name<'a, $tcx>(_: TyCtxt<'a, $tcx, $tcx>, key: $K) -> $R { |
| bug!("tcx.maps.{}({:?}) unsupported by its crate", |
| stringify!($name), key); |
| })* |
| Providers { $($name),* } |
| } |
| } |
| }; |
| } |
| |
| |
| /// 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 DepNodes. In particular, we |
| /// enforce by construction that the GUID/fingerprint of certain DepNodes 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_validated` 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 dep-node |
| /// with kind `MirValidated`, we know that the GUID/fingerprint of the dep-node |
| /// is actually a DefPathHash, and can therefore just look up the corresponding |
| /// DefId in `tcx.def_path_hash_to_def_id`. |
| /// |
| /// When you implement a new query, it will likely have a corresponding new |
| /// DepKind, and you'll have to support it here in `force_from_dep_node()`. As |
| /// a rule of thumb, if your query takes a DefId or DefIndex as sole parameter, |
| /// then `force_from_dep_node()` should not fail for it. Otherwise, you can just |
| /// add it to the "We don't have enough information to reconstruct..." group in |
| /// the match below. |
| pub fn force_from_dep_node<'a, 'gcx, 'lcx>(tcx: TyCtxt<'a, 'gcx, 'lcx>, |
| dep_node: &DepNode) |
| -> bool { |
| use ty::maps::keys::Key; |
| use hir::def_id::LOCAL_CRATE; |
| |
| // We must avoid ever having to call force_from_dep_node() for a |
| // DepNode::CodegenUnit: |
| // Since we cannot reconstruct the query key of a DepNode::CodegenUnit, we |
| // would always end up having to evaluate the first caller of the |
| // `codegen_unit` query that *is* reconstructible. This might very well be |
| // the `compile_codegen_unit` query, thus re-translating the whole CGU just |
| // to re-trigger calling the `codegen_unit` query with the right key. At |
| // that point we would already have re-done all the work we are trying to |
| // avoid doing in the first place. |
| // The solution is simple: Just explicitly call the `codegen_unit` query for |
| // each CGU, right after partitioning. This way `try_mark_green` will always |
| // hit the cache instead of having to go through `force_from_dep_node`. |
| // This assertion makes sure, we actually keep applying the solution above. |
| debug_assert!(dep_node.kind != DepKind::CodegenUnit, |
| "calling force_from_dep_node() on DepKind::CodegenUnit"); |
| |
| if !dep_node.kind.can_reconstruct_query_key() { |
| return false |
| } |
| |
| macro_rules! def_id { |
| () => { |
| if let Some(def_id) = dep_node.extract_def_id(tcx) { |
| def_id |
| } else { |
| // return from the whole function |
| return false |
| } |
| } |
| }; |
| |
| macro_rules! krate { |
| () => { (def_id!()).krate } |
| }; |
| |
| macro_rules! force { |
| ($query:ident, $key:expr) => { |
| { |
| use $crate::util::common::{ProfileQueriesMsg, profq_msg}; |
| |
| // FIXME(eddyb) Get more valid Span's on queries. |
| // def_span guard is necessary to prevent a recursive loop, |
| // default_span calls def_span query internally. |
| let span = if stringify!($query) != "def_span" { |
| $key.default_span(tcx) |
| } else { |
| ::syntax_pos::DUMMY_SP |
| }; |
| |
| profq_msg!(tcx, |
| ProfileQueriesMsg::QueryBegin( |
| span.data(), |
| ::ty::maps::QueryMsg::$query(profq_key!(tcx, $key)) |
| ) |
| ); |
| |
| match ::ty::maps::queries::$query::force(tcx, $key, span, *dep_node) { |
| Ok(_) => {}, |
| Err(e) => { |
| tcx.report_cycle(e).emit(); |
| } |
| } |
| } |
| } |
| }; |
| |
| // FIXME(#45015): We should try move this boilerplate code into a macro |
| // somehow. |
| match dep_node.kind { |
| // These are inputs that are expected to be pre-allocated and that |
| // should therefore always be red or green already |
| DepKind::AllLocalTraitImpls | |
| DepKind::Krate | |
| DepKind::CrateMetadata | |
| DepKind::HirBody | |
| DepKind::Hir | |
| |
| // This are anonymous nodes |
| DepKind::TraitSelect | |
| |
| // We don't have enough information to reconstruct the query key of |
| // these |
| DepKind::IsCopy | |
| DepKind::IsSized | |
| DepKind::IsFreeze | |
| DepKind::NeedsDrop | |
| DepKind::Layout | |
| DepKind::ConstEval | |
| DepKind::InstanceSymbolName | |
| DepKind::MirShim | |
| DepKind::BorrowCheckKrate | |
| DepKind::Specializes | |
| DepKind::ImplementationsOfTrait | |
| DepKind::TypeParamPredicates | |
| DepKind::CodegenUnit | |
| DepKind::CompileCodegenUnit | |
| DepKind::FulfillObligation | |
| DepKind::VtableMethods | |
| |
| // These are just odd |
| DepKind::Null | |
| DepKind::WorkProduct => { |
| bug!("force_from_dep_node() - Encountered {:?}", dep_node.kind) |
| } |
| |
| // These are not queries |
| DepKind::CoherenceCheckTrait | |
| DepKind::ItemVarianceConstraints => { |
| return false |
| } |
| |
| DepKind::RegionScopeTree => { force!(region_scope_tree, def_id!()); } |
| |
| DepKind::Coherence => { force!(crate_inherent_impls, LOCAL_CRATE); } |
| DepKind::CoherenceInherentImplOverlapCheck => { |
| force!(crate_inherent_impls_overlap_check, LOCAL_CRATE) |
| }, |
| DepKind::PrivacyAccessLevels => { force!(privacy_access_levels, LOCAL_CRATE); } |
| DepKind::MirConstQualif => { force!(mir_const_qualif, def_id!()); } |
| DepKind::MirConst => { force!(mir_const, def_id!()); } |
| DepKind::MirValidated => { force!(mir_validated, def_id!()); } |
| DepKind::MirOptimized => { force!(optimized_mir, def_id!()); } |
| |
| DepKind::BorrowCheck => { force!(borrowck, def_id!()); } |
| DepKind::MirBorrowCheck => { force!(mir_borrowck, def_id!()); } |
| DepKind::UnsafetyViolations => { force!(unsafety_violations, def_id!()); } |
| DepKind::Reachability => { force!(reachable_set, LOCAL_CRATE); } |
| DepKind::MirKeys => { force!(mir_keys, LOCAL_CRATE); } |
| DepKind::CrateVariances => { force!(crate_variances, LOCAL_CRATE); } |
| DepKind::AssociatedItems => { force!(associated_item, def_id!()); } |
| DepKind::TypeOfItem => { force!(type_of, def_id!()); } |
| DepKind::GenericsOfItem => { force!(generics_of, def_id!()); } |
| DepKind::PredicatesOfItem => { force!(predicates_of, def_id!()); } |
| DepKind::SuperPredicatesOfItem => { force!(super_predicates_of, def_id!()); } |
| DepKind::TraitDefOfItem => { force!(trait_def, def_id!()); } |
| DepKind::AdtDefOfItem => { force!(adt_def, def_id!()); } |
| DepKind::IsDefaultImpl => { force!(is_default_impl, def_id!()); } |
| DepKind::ImplTraitRef => { force!(impl_trait_ref, def_id!()); } |
| DepKind::ImplPolarity => { force!(impl_polarity, def_id!()); } |
| DepKind::ClosureKind => { force!(closure_kind, def_id!()); } |
| DepKind::FnSignature => { force!(fn_sig, def_id!()); } |
| DepKind::GenSignature => { force!(generator_sig, def_id!()); } |
| DepKind::CoerceUnsizedInfo => { force!(coerce_unsized_info, def_id!()); } |
| DepKind::ItemVariances => { force!(variances_of, def_id!()); } |
| DepKind::IsConstFn => { force!(is_const_fn, def_id!()); } |
| DepKind::IsForeignItem => { force!(is_foreign_item, def_id!()); } |
| DepKind::SizedConstraint => { force!(adt_sized_constraint, def_id!()); } |
| DepKind::DtorckConstraint => { force!(adt_dtorck_constraint, def_id!()); } |
| DepKind::AdtDestructor => { force!(adt_destructor, def_id!()); } |
| DepKind::AssociatedItemDefIds => { force!(associated_item_def_ids, def_id!()); } |
| DepKind::InherentImpls => { force!(inherent_impls, def_id!()); } |
| DepKind::TypeckBodiesKrate => { force!(typeck_item_bodies, LOCAL_CRATE); } |
| DepKind::TypeckTables => { force!(typeck_tables_of, def_id!()); } |
| DepKind::HasTypeckTables => { force!(has_typeck_tables, def_id!()); } |
| DepKind::SymbolName => { force!(def_symbol_name, def_id!()); } |
| DepKind::SpecializationGraph => { force!(specialization_graph_of, def_id!()); } |
| DepKind::ObjectSafety => { force!(is_object_safe, def_id!()); } |
| DepKind::TraitImpls => { force!(trait_impls_of, def_id!()); } |
| |
| DepKind::ParamEnv => { force!(param_env, def_id!()); } |
| DepKind::DescribeDef => { force!(describe_def, def_id!()); } |
| DepKind::DefSpan => { force!(def_span, def_id!()); } |
| DepKind::LookupStability => { force!(lookup_stability, def_id!()); } |
| DepKind::LookupDeprecationEntry => { |
| force!(lookup_deprecation_entry, def_id!()); |
| } |
| DepKind::ItemBodyNestedBodies => { force!(item_body_nested_bodies, def_id!()); } |
| DepKind::ConstIsRvaluePromotableToStatic => { |
| force!(const_is_rvalue_promotable_to_static, def_id!()); |
| } |
| DepKind::ImplParent => { force!(impl_parent, def_id!()); } |
| DepKind::TraitOfItem => { force!(trait_of_item, def_id!()); } |
| DepKind::IsExportedSymbol => { force!(is_exported_symbol, def_id!()); } |
| DepKind::IsMirAvailable => { force!(is_mir_available, def_id!()); } |
| DepKind::ItemAttrs => { force!(item_attrs, def_id!()); } |
| DepKind::FnArgNames => { force!(fn_arg_names, def_id!()); } |
| DepKind::DylibDepFormats => { force!(dylib_dependency_formats, krate!()); } |
| DepKind::IsPanicRuntime => { force!(is_panic_runtime, krate!()); } |
| DepKind::IsCompilerBuiltins => { force!(is_compiler_builtins, krate!()); } |
| DepKind::HasGlobalAllocator => { force!(has_global_allocator, krate!()); } |
| DepKind::ExternCrate => { force!(extern_crate, def_id!()); } |
| DepKind::LintLevels => { force!(lint_levels, LOCAL_CRATE); } |
| DepKind::InScopeTraits => { force!(in_scope_traits_map, def_id!().index); } |
| DepKind::ModuleExports => { force!(module_exports, def_id!()); } |
| DepKind::IsSanitizerRuntime => { force!(is_sanitizer_runtime, krate!()); } |
| DepKind::IsProfilerRuntime => { force!(is_profiler_runtime, krate!()); } |
| DepKind::GetPanicStrategy => { force!(panic_strategy, krate!()); } |
| DepKind::IsNoBuiltins => { force!(is_no_builtins, krate!()); } |
| DepKind::ImplDefaultness => { force!(impl_defaultness, def_id!()); } |
| DepKind::ExportedSymbolIds => { force!(exported_symbol_ids, krate!()); } |
| DepKind::NativeLibraries => { force!(native_libraries, krate!()); } |
| DepKind::PluginRegistrarFn => { force!(plugin_registrar_fn, krate!()); } |
| DepKind::DeriveRegistrarFn => { force!(derive_registrar_fn, krate!()); } |
| DepKind::CrateDisambiguator => { force!(crate_disambiguator, krate!()); } |
| DepKind::CrateHash => { force!(crate_hash, krate!()); } |
| DepKind::OriginalCrateName => { force!(original_crate_name, krate!()); } |
| |
| DepKind::AllTraitImplementations => { |
| force!(all_trait_implementations, krate!()); |
| } |
| |
| DepKind::IsDllimportForeignItem => { |
| force!(is_dllimport_foreign_item, def_id!()); |
| } |
| DepKind::IsStaticallyIncludedForeignItem => { |
| force!(is_statically_included_foreign_item, def_id!()); |
| } |
| DepKind::NativeLibraryKind => { force!(native_library_kind, def_id!()); } |
| DepKind::LinkArgs => { force!(link_args, LOCAL_CRATE); } |
| |
| DepKind::NamedRegion => { force!(named_region_map, def_id!().index); } |
| DepKind::IsLateBound => { force!(is_late_bound_map, def_id!().index); } |
| DepKind::ObjectLifetimeDefaults => { |
| force!(object_lifetime_defaults_map, def_id!().index); |
| } |
| |
| DepKind::Visibility => { force!(visibility, def_id!()); } |
| DepKind::DepKind => { force!(dep_kind, krate!()); } |
| DepKind::CrateName => { force!(crate_name, krate!()); } |
| DepKind::ItemChildren => { force!(item_children, def_id!()); } |
| DepKind::ExternModStmtCnum => { force!(extern_mod_stmt_cnum, def_id!()); } |
| DepKind::GetLangItems => { force!(get_lang_items, LOCAL_CRATE); } |
| DepKind::DefinedLangItems => { force!(defined_lang_items, krate!()); } |
| DepKind::MissingLangItems => { force!(missing_lang_items, krate!()); } |
| DepKind::ExternConstBody => { force!(extern_const_body, def_id!()); } |
| DepKind::VisibleParentMap => { force!(visible_parent_map, LOCAL_CRATE); } |
| DepKind::MissingExternCrateItem => { |
| force!(missing_extern_crate_item, krate!()); |
| } |
| DepKind::UsedCrateSource => { force!(used_crate_source, krate!()); } |
| DepKind::PostorderCnums => { force!(postorder_cnums, LOCAL_CRATE); } |
| DepKind::HasCloneClosures => { force!(has_clone_closures, krate!()); } |
| DepKind::HasCopyClosures => { force!(has_copy_closures, krate!()); } |
| |
| DepKind::Freevars => { force!(freevars, def_id!()); } |
| DepKind::MaybeUnusedTraitImport => { |
| force!(maybe_unused_trait_import, def_id!()); |
| } |
| DepKind::MaybeUnusedExternCrates => { force!(maybe_unused_extern_crates, LOCAL_CRATE); } |
| DepKind::StabilityIndex => { force!(stability_index, LOCAL_CRATE); } |
| DepKind::AllCrateNums => { force!(all_crate_nums, LOCAL_CRATE); } |
| DepKind::ExportedSymbols => { force!(exported_symbols, krate!()); } |
| DepKind::CollectAndPartitionTranslationItems => { |
| force!(collect_and_partition_translation_items, LOCAL_CRATE); |
| } |
| DepKind::ExportName => { force!(export_name, def_id!()); } |
| DepKind::ContainsExternIndicator => { |
| force!(contains_extern_indicator, def_id!()); |
| } |
| DepKind::IsTranslatedFunction => { force!(is_translated_function, def_id!()); } |
| DepKind::OutputFilenames => { force!(output_filenames, LOCAL_CRATE); } |
| } |
| |
| true |
| } |
| |