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| author | bors <bors@rust-lang.org> | 2023-06-22 08:34:32 +0000 |
|---|---|---|
| committer | bors <bors@rust-lang.org> | 2023-06-22 08:34:32 +0000 |
| commit | fa06a371b715f137c952577cfded4e49cb7e76c4 (patch) | |
| tree | 7f9353a82ce25584517df9980411752acecc8247 /compiler/rustc_monomorphize/src/partitioning.rs | |
| parent | 0928a1f7574f5ca019b5443b3a90008588d18c8c (diff) | |
| parent | abde9ba527704449ae84848673b52a8ab0f5cbd1 (diff) | |
| download | rust-fa06a371b715f137c952577cfded4e49cb7e76c4.tar.gz rust-fa06a371b715f137c952577cfded4e49cb7e76c4.zip | |
Auto merge of #112695 - nnethercote:inline-before-merging-cgus, r=wesleywiser
Inline before merging cgus Because CGU merging relies on CGU sizes, but the CGU sizes before inlining aren't accurate. This change doesn't have much effect on compile perf, but it makes follow-on changes that involve more sophisticated reasoning about CGU sizes much easier. r? `@wesleywiser`
Diffstat (limited to 'compiler/rustc_monomorphize/src/partitioning.rs')
| -rw-r--r-- | compiler/rustc_monomorphize/src/partitioning.rs | 137 |
1 files changed, 56 insertions, 81 deletions
diff --git a/compiler/rustc_monomorphize/src/partitioning.rs b/compiler/rustc_monomorphize/src/partitioning.rs index 531644f0b84..97e3748b8b8 100644 --- a/compiler/rustc_monomorphize/src/partitioning.rs +++ b/compiler/rustc_monomorphize/src/partitioning.rs @@ -125,7 +125,7 @@ struct PartitioningCx<'a, 'tcx> { usage_map: &'a UsageMap<'tcx>, } -struct PlacedRootMonoItems<'tcx> { +struct PlacedMonoItems<'tcx> { /// The codegen units, sorted by name to make things deterministic. codegen_units: Vec<CodegenUnit<'tcx>>, @@ -150,18 +150,13 @@ where let cx = &PartitioningCx { tcx, usage_map }; - // In the first step, we place all regular monomorphizations into their - // respective 'home' codegen unit. Regular monomorphizations are all - // functions and statics defined in the local crate. - let PlacedRootMonoItems { mut codegen_units, internalization_candidates, unique_inlined_stats } = { - let _prof_timer = tcx.prof.generic_activity("cgu_partitioning_place_roots"); - let mut placed = place_root_mono_items(cx, mono_items); + // Place all mono items into a codegen unit. `place_mono_items` is + // responsible for initializing the CGU size estimates. + let PlacedMonoItems { mut codegen_units, internalization_candidates, unique_inlined_stats } = { + let _prof_timer = tcx.prof.generic_activity("cgu_partitioning_place_items"); + let placed = place_mono_items(cx, mono_items); - for cgu in &mut placed.codegen_units { - cgu.create_size_estimate(tcx); - } - - debug_dump(tcx, "ROOTS", &placed.codegen_units, placed.unique_inlined_stats); + debug_dump(tcx, "PLACE", &placed.codegen_units, placed.unique_inlined_stats); placed }; @@ -175,23 +170,8 @@ where debug_dump(tcx, "MERGE", &codegen_units, unique_inlined_stats); } - // In the next step, we use the inlining map to determine which additional - // monomorphizations have to go into each codegen unit. These additional - // monomorphizations can be drop-glue, functions from external crates, and - // local functions the definition of which is marked with `#[inline]`. - { - let _prof_timer = tcx.prof.generic_activity("cgu_partitioning_place_inline_items"); - place_inlined_mono_items(cx, &mut codegen_units); - - for cgu in &mut codegen_units { - cgu.create_size_estimate(tcx); - } - - debug_dump(tcx, "INLINE", &codegen_units, unique_inlined_stats); - } - - // Next we try to make as many symbols "internal" as possible, so LLVM has - // more freedom to optimize. + // Make as many symbols "internal" as possible, so LLVM has more freedom to + // optimize. if !tcx.sess.link_dead_code() { let _prof_timer = tcx.prof.generic_activity("cgu_partitioning_internalize_symbols"); internalize_symbols(cx, &mut codegen_units, internalization_candidates); @@ -212,10 +192,7 @@ where codegen_units } -fn place_root_mono_items<'tcx, I>( - cx: &PartitioningCx<'_, 'tcx>, - mono_items: I, -) -> PlacedRootMonoItems<'tcx> +fn place_mono_items<'tcx, I>(cx: &PartitioningCx<'_, 'tcx>, mono_items: I) -> PlacedMonoItems<'tcx> where I: Iterator<Item = MonoItem<'tcx>>, { @@ -236,6 +213,8 @@ where let mut num_unique_inlined_items = 0; let mut unique_inlined_items_size = 0; for mono_item in mono_items { + // Handle only root items directly here. Inlined items are handled at + // the bottom of the loop based on reachability. match mono_item.instantiation_mode(cx.tcx) { InstantiationMode::GloballyShared { .. } => {} InstantiationMode::LocalCopy => { @@ -248,7 +227,7 @@ where let characteristic_def_id = characteristic_def_id_of_mono_item(cx.tcx, mono_item); let is_volatile = is_incremental_build && mono_item.is_generic_fn(); - let codegen_unit_name = match characteristic_def_id { + let cgu_name = match characteristic_def_id { Some(def_id) => compute_codegen_unit_name( cx.tcx, cgu_name_builder, @@ -259,9 +238,7 @@ where None => fallback_cgu_name(cgu_name_builder), }; - let codegen_unit = codegen_units - .entry(codegen_unit_name) - .or_insert_with(|| CodegenUnit::new(codegen_unit_name)); + let cgu = codegen_units.entry(cgu_name).or_insert_with(|| CodegenUnit::new(cgu_name)); let mut can_be_internalized = true; let (linkage, visibility) = mono_item_linkage_and_visibility( @@ -274,23 +251,56 @@ where internalization_candidates.insert(mono_item); } - codegen_unit.items_mut().insert(mono_item, (linkage, visibility)); + cgu.items_mut().insert(mono_item, (linkage, visibility)); + + // Get all inlined items that are reachable from `mono_item` without + // going via another root item. This includes drop-glue, functions from + // external crates, and local functions the definition of which is + // marked with `#[inline]`. + let mut reachable_inlined_items = FxHashSet::default(); + get_reachable_inlined_items(cx.tcx, mono_item, cx.usage_map, &mut reachable_inlined_items); + + // Add those inlined items. It's possible an inlined item is reachable + // from multiple root items within a CGU, which is fine, it just means + // the `insert` will be a no-op. + for inlined_item in reachable_inlined_items { + // This is a CGU-private copy. + cgu.items_mut().insert(inlined_item, (Linkage::Internal, Visibility::Default)); + } } // Always ensure we have at least one CGU; otherwise, if we have a // crate with just types (for example), we could wind up with no CGU. if codegen_units.is_empty() { - let codegen_unit_name = fallback_cgu_name(cgu_name_builder); - codegen_units.insert(codegen_unit_name, CodegenUnit::new(codegen_unit_name)); + let cgu_name = fallback_cgu_name(cgu_name_builder); + codegen_units.insert(cgu_name, CodegenUnit::new(cgu_name)); } let mut codegen_units: Vec<_> = codegen_units.into_values().collect(); codegen_units.sort_by(|a, b| a.name().as_str().cmp(b.name().as_str())); - PlacedRootMonoItems { + for cgu in codegen_units.iter_mut() { + cgu.compute_size_estimate(cx.tcx); + } + + return PlacedMonoItems { codegen_units, internalization_candidates, unique_inlined_stats: (num_unique_inlined_items, unique_inlined_items_size), + }; + + fn get_reachable_inlined_items<'tcx>( + tcx: TyCtxt<'tcx>, + item: MonoItem<'tcx>, + usage_map: &UsageMap<'tcx>, + visited: &mut FxHashSet<MonoItem<'tcx>>, + ) { + usage_map.for_each_inlined_used_item(tcx, item, |inlined_item| { + let is_new = visited.insert(inlined_item); + if is_new { + get_reachable_inlined_items(tcx, inlined_item, usage_map, visited); + } + }); } } @@ -314,7 +324,7 @@ fn merge_codegen_units<'tcx>( // worse generated code. So we don't allow CGUs smaller than this (unless // there is just one CGU, of course). Note that CGU sizes of 100,000+ are // common in larger programs, so this isn't all that large. - const NON_INCR_MIN_CGU_SIZE: usize = 1000; + const NON_INCR_MIN_CGU_SIZE: usize = 1800; // Repeatedly merge the two smallest codegen units as long as: // - we have more CGUs than the upper limit, or @@ -338,9 +348,11 @@ fn merge_codegen_units<'tcx>( let mut smallest = codegen_units.pop().unwrap(); let second_smallest = codegen_units.last_mut().unwrap(); - // Move the mono-items from `smallest` to `second_smallest` - second_smallest.modify_size_estimate(smallest.size_estimate()); + // Move the items from `smallest` to `second_smallest`. Some of them + // may be duplicate inlined items, in which case the destination CGU is + // unaffected. Recalculate size estimates afterwards. second_smallest.items_mut().extend(smallest.items_mut().drain()); + second_smallest.compute_size_estimate(cx.tcx); // Record that `second_smallest` now contains all the stuff that was // in `smallest` before. @@ -406,43 +418,6 @@ fn merge_codegen_units<'tcx>( codegen_units.sort_by(|a, b| a.name().as_str().cmp(b.name().as_str())); } -fn place_inlined_mono_items<'tcx>( - cx: &PartitioningCx<'_, 'tcx>, - codegen_units: &mut [CodegenUnit<'tcx>], -) { - for cgu in codegen_units.iter_mut() { - // Collect all inlined items that need to be available in this codegen unit. - let mut reachable_inlined_items = FxHashSet::default(); - for root in cgu.items().keys() { - // Get all inlined items that are reachable from it without going - // via another root item. - get_reachable_inlined_items(cx.tcx, *root, cx.usage_map, &mut reachable_inlined_items); - } - - // Add all monomorphizations that are not already there. - for inlined_item in reachable_inlined_items { - assert!(!cgu.items().contains_key(&inlined_item)); - - // This is a CGU-private copy. - cgu.items_mut().insert(inlined_item, (Linkage::Internal, Visibility::Default)); - } - } - - fn get_reachable_inlined_items<'tcx>( - tcx: TyCtxt<'tcx>, - item: MonoItem<'tcx>, - usage_map: &UsageMap<'tcx>, - visited: &mut FxHashSet<MonoItem<'tcx>>, - ) { - usage_map.for_each_inlined_used_item(tcx, item, |inlined_item| { - let is_new = visited.insert(inlined_item); - if is_new { - get_reachable_inlined_items(tcx, inlined_item, usage_map, visited); - } - }); - } -} - fn internalize_symbols<'tcx>( cx: &PartitioningCx<'_, 'tcx>, codegen_units: &mut [CodegenUnit<'tcx>], |