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fca6fd0b85
This includes a protocol for creating LibGC Heap allocated Swift objects. Pay no attention to the Unmanaged shenanigans, they are all behind the curtain.
209 lines
6.6 KiB
C++
209 lines
6.6 KiB
C++
/*
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* Copyright (c) 2020-2024, Andreas Kling <andreas@ladybird.org>
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*
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* SPDX-License-Identifier: BSD-2-Clause
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*/
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#pragma once
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#include <AK/Badge.h>
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#include <AK/Function.h>
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#include <AK/HashTable.h>
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#include <AK/IntrusiveList.h>
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#include <AK/Noncopyable.h>
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#include <AK/NonnullOwnPtr.h>
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#include <AK/StackInfo.h>
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#include <AK/Swift.h>
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#include <AK/Types.h>
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#include <AK/Vector.h>
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#include <LibCore/Forward.h>
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#include <LibGC/Cell.h>
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#include <LibGC/CellAllocator.h>
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#include <LibGC/ConservativeVector.h>
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#include <LibGC/Forward.h>
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#include <LibGC/HeapRoot.h>
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#include <LibGC/Internals.h>
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#include <LibGC/MarkedVector.h>
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#include <LibGC/Root.h>
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#include <LibGC/WeakContainer.h>
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namespace GC {
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class Heap : public HeapBase {
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AK_MAKE_NONCOPYABLE(Heap);
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AK_MAKE_NONMOVABLE(Heap);
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public:
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explicit Heap(void* private_data, AK::Function<void(HashMap<Cell*, GC::HeapRoot>&)> gather_embedder_roots);
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~Heap();
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template<typename T, typename... Args>
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Ref<T> allocate(Args&&... args)
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{
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auto* memory = allocate_cell<T>();
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defer_gc();
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new (memory) T(forward<Args>(args)...);
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undefer_gc();
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return *static_cast<T*>(memory);
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}
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enum class CollectionType {
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CollectGarbage,
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CollectEverything,
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};
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void collect_garbage(CollectionType = CollectionType::CollectGarbage, bool print_report = false);
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AK::JsonObject dump_graph();
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bool should_collect_on_every_allocation() const { return m_should_collect_on_every_allocation; }
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void set_should_collect_on_every_allocation(bool b) { m_should_collect_on_every_allocation = b; }
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void did_create_root(Badge<RootImpl>, RootImpl&);
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void did_destroy_root(Badge<RootImpl>, RootImpl&);
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void did_create_marked_vector(Badge<MarkedVectorBase>, MarkedVectorBase&);
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void did_destroy_marked_vector(Badge<MarkedVectorBase>, MarkedVectorBase&);
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void did_create_conservative_vector(Badge<ConservativeVectorBase>, ConservativeVectorBase&);
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void did_destroy_conservative_vector(Badge<ConservativeVectorBase>, ConservativeVectorBase&);
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void did_create_weak_container(Badge<WeakContainer>, WeakContainer&);
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void did_destroy_weak_container(Badge<WeakContainer>, WeakContainer&);
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void register_cell_allocator(Badge<CellAllocator>, CellAllocator&);
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void uproot_cell(Cell* cell);
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bool is_gc_deferred() const { return m_gc_deferrals > 0; }
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private:
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friend class MarkingVisitor;
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friend class GraphConstructorVisitor;
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friend class DeferGC;
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friend class ForeignCell;
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void defer_gc();
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void undefer_gc();
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static bool cell_must_survive_garbage_collection(Cell const&);
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template<typename T>
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Cell* allocate_cell()
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{
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will_allocate(sizeof(T));
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if constexpr (requires { T::cell_allocator.allocator.get().allocate_cell(*this); }) {
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if constexpr (IsSame<T, typename decltype(T::cell_allocator)::CellType>) {
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return T::cell_allocator.allocator.get().allocate_cell(*this);
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}
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}
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return allocator_for_size(sizeof(T)).allocate_cell(*this);
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}
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void will_allocate(size_t);
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void find_min_and_max_block_addresses(FlatPtr& min_address, FlatPtr& max_address);
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void gather_roots(HashMap<Cell*, HeapRoot>&);
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void gather_conservative_roots(HashMap<Cell*, HeapRoot>&);
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void gather_asan_fake_stack_roots(HashMap<FlatPtr, HeapRoot>&, FlatPtr, FlatPtr min_block_address, FlatPtr max_block_address);
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void mark_live_cells(HashMap<Cell*, HeapRoot> const& live_cells);
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void finalize_unmarked_cells();
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void sweep_dead_cells(bool print_report, Core::ElapsedTimer const&);
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ALWAYS_INLINE CellAllocator& allocator_for_size(size_t cell_size)
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{
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// FIXME: Use binary search?
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for (auto& allocator : m_size_based_cell_allocators) {
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if (allocator->cell_size() >= cell_size)
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return *allocator;
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}
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dbgln("Cannot get CellAllocator for cell size {}, largest available is {}!", cell_size, m_size_based_cell_allocators.last()->cell_size());
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VERIFY_NOT_REACHED();
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}
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template<typename Callback>
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void for_each_block(Callback callback)
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{
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for (auto& allocator : m_all_cell_allocators) {
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if (allocator.for_each_block(callback) == IterationDecision::Break)
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return;
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}
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}
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static constexpr size_t GC_MIN_BYTES_THRESHOLD { 4 * 1024 * 1024 };
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size_t m_gc_bytes_threshold { GC_MIN_BYTES_THRESHOLD };
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size_t m_allocated_bytes_since_last_gc { 0 };
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bool m_should_collect_on_every_allocation { false };
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Vector<NonnullOwnPtr<CellAllocator>> m_size_based_cell_allocators;
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CellAllocator::List m_all_cell_allocators;
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RootImpl::List m_roots;
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MarkedVectorBase::List m_marked_vectors;
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ConservativeVectorBase::List m_conservative_vectors;
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WeakContainer::List m_weak_containers;
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Vector<Ptr<Cell>> m_uprooted_cells;
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size_t m_gc_deferrals { 0 };
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bool m_should_gc_when_deferral_ends { false };
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bool m_collecting_garbage { false };
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StackInfo m_stack_info;
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AK::Function<void(HashMap<Cell*, GC::HeapRoot>&)> m_gather_embedder_roots;
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} SWIFT_IMMORTAL_REFERENCE;
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inline void Heap::did_create_root(Badge<RootImpl>, RootImpl& impl)
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{
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VERIFY(!m_roots.contains(impl));
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m_roots.append(impl);
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}
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inline void Heap::did_destroy_root(Badge<RootImpl>, RootImpl& impl)
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{
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VERIFY(m_roots.contains(impl));
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m_roots.remove(impl);
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}
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inline void Heap::did_create_marked_vector(Badge<MarkedVectorBase>, MarkedVectorBase& vector)
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{
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VERIFY(!m_marked_vectors.contains(vector));
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m_marked_vectors.append(vector);
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}
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inline void Heap::did_destroy_marked_vector(Badge<MarkedVectorBase>, MarkedVectorBase& vector)
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{
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VERIFY(m_marked_vectors.contains(vector));
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m_marked_vectors.remove(vector);
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}
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inline void Heap::did_create_conservative_vector(Badge<ConservativeVectorBase>, ConservativeVectorBase& vector)
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{
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VERIFY(!m_conservative_vectors.contains(vector));
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m_conservative_vectors.append(vector);
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}
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inline void Heap::did_destroy_conservative_vector(Badge<ConservativeVectorBase>, ConservativeVectorBase& vector)
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{
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VERIFY(m_conservative_vectors.contains(vector));
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m_conservative_vectors.remove(vector);
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}
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inline void Heap::did_create_weak_container(Badge<WeakContainer>, WeakContainer& set)
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{
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VERIFY(!m_weak_containers.contains(set));
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m_weak_containers.append(set);
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}
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inline void Heap::did_destroy_weak_container(Badge<WeakContainer>, WeakContainer& set)
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{
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VERIFY(m_weak_containers.contains(set));
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m_weak_containers.remove(set);
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}
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inline void Heap::register_cell_allocator(Badge<CellAllocator>, CellAllocator& allocator)
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{
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m_all_cell_allocators.append(allocator);
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}
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}
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