armv7a/usr/include/llvm/ExecutionEngine/JITLink/JITLinkMemoryManager.h - manifest_repos/toolchain - Git at Google

 //===-- JITLinkMemoryManager.h - JITLink mem manager interface --*- C++ -*-===//
 //
 // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
 // See https://llvm.org/LICENSE.txt for license information.
 // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
 //
 //===----------------------------------------------------------------------===//
 //
 // Contains the JITLinkMemoryManager interface.
 //
 //===----------------------------------------------------------------------===//

 #ifndef LLVM_EXECUTIONENGINE_JITLINK_JITLINKMEMORYMANAGER_H
 #define LLVM_EXECUTIONENGINE_JITLINK_JITLINKMEMORYMANAGER_H

 #include "llvm/ADT/FunctionExtras.h"
 #include "llvm/ADT/SmallVector.h"
 #include "llvm/ExecutionEngine/JITLink/JITLinkDylib.h"
 #include "llvm/ExecutionEngine/JITLink/MemoryFlags.h"
 #include "llvm/ExecutionEngine/Orc/Shared/AllocationActions.h"
 #include "llvm/ExecutionEngine/Orc/Shared/ExecutorAddress.h"
 #include "llvm/Support/Allocator.h"
 #include "llvm/Support/Error.h"
 #include "llvm/Support/MSVCErrorWorkarounds.h"
 #include "llvm/Support/Memory.h"
 #include "llvm/Support/RecyclingAllocator.h"

 #include <cstdint>
 #include <future>
 #include <mutex>

 namespace llvm {
 namespace jitlink {

 class Block;
 class LinkGraph;
 class Section;

 /// Manages allocations of JIT memory.
 ///
 /// Instances of this class may be accessed concurrently from multiple threads
 /// and their implemetations should include any necessary synchronization.
 class JITLinkMemoryManager {
 public:

   /// Represents a finalized allocation.
   ///
   /// Finalized allocations must be passed to the
   /// JITLinkMemoryManager:deallocate method prior to being destroyed.
   ///
   /// The interpretation of the Address associated with the finalized allocation
   /// is up to the memory manager implementation. Common options are using the
   /// base address of the allocation, or the address of a memory management
   /// object that tracks the allocation.
   class FinalizedAlloc {
     friend class JITLinkMemoryManager;

     static constexpr auto InvalidAddr = ~uint64_t(0);

   public:
     FinalizedAlloc() = default;
     explicit FinalizedAlloc(orc::ExecutorAddr A) : A(A) {
       assert(A.getValue() != InvalidAddr &&
              "Explicitly creating an invalid allocation?");
     }
     FinalizedAlloc(const FinalizedAlloc &) = delete;
     FinalizedAlloc(FinalizedAlloc &&Other) : A(Other.A) {
       Other.A.setValue(InvalidAddr);
     }
     FinalizedAlloc &operator=(const FinalizedAlloc &) = delete;
     FinalizedAlloc &operator=(FinalizedAlloc &&Other) {
       assert(A.getValue() == InvalidAddr &&
              "Cannot overwrite active finalized allocation");
       std::swap(A, Other.A);
       return *this;
     }
     ~FinalizedAlloc() {
       assert(A.getValue() == InvalidAddr &&
              "Finalized allocation was not deallocated");
     }

     /// FinalizedAllocs convert to false for default-constructed, and
     /// true otherwise. Default-constructed allocs need not be deallocated.
     explicit operator bool() const { return A.getValue() != InvalidAddr; }

     /// Returns the address associated with this finalized allocation.
     /// The allocation is unmodified.
     orc::ExecutorAddr getAddress() const { return A; }

     /// Returns the address associated with this finalized allocation and
     /// resets this object to the default state.
     /// This should only be used by allocators when deallocating memory.
     orc::ExecutorAddr release() {
       orc::ExecutorAddr Tmp = A;
       A.setValue(InvalidAddr);
       return Tmp;
     }

   private:
     orc::ExecutorAddr A{InvalidAddr};
   };

   /// Represents an allocation which has not been finalized yet.
   ///
   /// InFlightAllocs manage both executor memory allocations and working
   /// memory allocations.
   ///
   /// On finalization, the InFlightAlloc should transfer the content of
   /// working memory into executor memory, apply memory protections, and
   /// run any finalization functions.
   ///
   /// Working memory should be kept alive at least until one of the following
   /// happens: (1) the InFlightAlloc instance is destroyed, (2) the
   /// InFlightAlloc is abandoned, (3) finalized target memory is destroyed.
   ///
   /// If abandon is called then working memory and executor memory should both
   /// be freed.
   class InFlightAlloc {
   public:
     using OnFinalizedFunction = unique_function<void(Expected<FinalizedAlloc>)>;
     using OnAbandonedFunction = unique_function<void(Error)>;

     virtual ~InFlightAlloc();

     /// Called prior to finalization if the allocation should be abandoned.
     virtual void abandon(OnAbandonedFunction OnAbandoned) = 0;

     /// Called to transfer working memory to the target and apply finalization.
     virtual void finalize(OnFinalizedFunction OnFinalized) = 0;

     /// Synchronous convenience version of finalize.
     Expected<FinalizedAlloc> finalize() {
       std::promise<MSVCPExpected<FinalizedAlloc>> FinalizeResultP;
       auto FinalizeResultF = FinalizeResultP.get_future();
       finalize([&](Expected<FinalizedAlloc> Result) {
         FinalizeResultP.set_value(std::move(Result));
       });
       return FinalizeResultF.get();
     }
   };

   /// Typedef for the argument to be passed to OnAllocatedFunction.
   using AllocResult = Expected<std::unique_ptr<InFlightAlloc>>;

   /// Called when allocation has been completed.
   using OnAllocatedFunction = unique_function<void(AllocResult)>;

   /// Called when deallocation has completed.
   using OnDeallocatedFunction = unique_function<void(Error)>;

   virtual ~JITLinkMemoryManager();

   /// Start the allocation process.
   ///
   /// If the initial allocation is successful then the OnAllocated function will
   /// be called with a std::unique_ptr<InFlightAlloc> value. If the assocation
   /// is unsuccessful then the OnAllocated function will be called with an
   /// Error.
   virtual void allocate(const JITLinkDylib *JD, LinkGraph &G,
                         OnAllocatedFunction OnAllocated) = 0;

   /// Convenience function for blocking allocation.
   AllocResult allocate(const JITLinkDylib *JD, LinkGraph &G) {
     std::promise<MSVCPExpected<std::unique_ptr<InFlightAlloc>>> AllocResultP;
     auto AllocResultF = AllocResultP.get_future();
     allocate(JD, G, [&](AllocResult Alloc) {
       AllocResultP.set_value(std::move(Alloc));
     });
     return AllocResultF.get();
   }

   /// Deallocate a list of allocation objects.
   ///
   /// Dealloc actions will be run in reverse order (from the end of the vector
   /// to the start).
   virtual void deallocate(std::vector<FinalizedAlloc> Allocs,
                           OnDeallocatedFunction OnDeallocated) = 0;

   /// Convenience function for deallocation of a single alloc.
   void deallocate(FinalizedAlloc Alloc, OnDeallocatedFunction OnDeallocated) {
     std::vector<FinalizedAlloc> Allocs;
     Allocs.push_back(std::move(Alloc));
     deallocate(std::move(Allocs), std::move(OnDeallocated));
   }

   /// Convenience function for blocking deallocation.
   Error deallocate(std::vector<FinalizedAlloc> Allocs) {
     std::promise<MSVCPError> DeallocResultP;
     auto DeallocResultF = DeallocResultP.get_future();
     deallocate(std::move(Allocs),
                [&](Error Err) { DeallocResultP.set_value(std::move(Err)); });
     return DeallocResultF.get();
   }

   /// Convenience function for blocking deallocation of a single alloc.
   Error deallocate(FinalizedAlloc Alloc) {
     std::vector<FinalizedAlloc> Allocs;
     Allocs.push_back(std::move(Alloc));
     return deallocate(std::move(Allocs));
   }
 };

 /// BasicLayout simplifies the implementation of JITLinkMemoryManagers.
 ///
 /// BasicLayout groups Sections into Segments based on their memory protection
 /// and deallocation policies. JITLinkMemoryManagers can construct a BasicLayout
 /// from a Graph, and then assign working memory and addresses to each of the
 /// Segments. These addreses will be mapped back onto the Graph blocks in
 /// the apply method.
 class BasicLayout {
 public:
   /// The Alignment, ContentSize and ZeroFillSize of each segment will be
   /// pre-filled from the Graph. Clients must set the Addr and WorkingMem fields
   /// prior to calling apply.
   //
   // FIXME: The C++98 initializer is an attempt to work around compile failures
   // due to http://www.open-std.org/jtc1/sc22/wg21/docs/cwg_defects.html#1397.
   // We should be able to switch this back to member initialization once that
   // issue is fixed.
   class Segment {
     friend class BasicLayout;

   public:
     Segment()
         : ContentSize(0), ZeroFillSize(0), Addr(0), WorkingMem(nullptr),
           NextWorkingMemOffset(0) {}
     Align Alignment;
     size_t ContentSize;
     uint64_t ZeroFillSize;
     orc::ExecutorAddr Addr;
     char *WorkingMem = nullptr;

   private:
     size_t NextWorkingMemOffset;
     std::vector<Block *> ContentBlocks, ZeroFillBlocks;
   };

   /// A convenience class that further groups segments based on memory
   /// deallocation policy. This allows clients to make two slab allocations:
   /// one for all standard segments, and one for all finalize segments.
   struct ContiguousPageBasedLayoutSizes {
     uint64_t StandardSegs = 0;
     uint64_t FinalizeSegs = 0;

     uint64_t total() const { return StandardSegs + FinalizeSegs; }
   };

 private:
   using SegmentMap = AllocGroupSmallMap<Segment>;

 public:
   BasicLayout(LinkGraph &G);

   /// Return a reference to the graph this allocation was created from.
   LinkGraph &getGraph() { return G; }

   /// Returns the total number of required to allocate all segments (with each
   /// segment padded out to page size) for all standard segments, and all
   /// finalize segments.
   ///
   /// This is a convenience function for the common case where the segments will
   /// be allocated contiguously.
   ///
   /// This function will return an error if any segment has an alignment that
   /// is higher than a page.
   Expected<ContiguousPageBasedLayoutSizes>
   getContiguousPageBasedLayoutSizes(uint64_t PageSize);

   /// Returns an iterator over the segments of the layout.
   iterator_range<SegmentMap::iterator> segments() {
     return {Segments.begin(), Segments.end()};
   }

   /// Apply the layout to the graph.
   Error apply();

   /// Returns a reference to the AllocActions in the graph.
   /// This convenience function saves callers from having to #include
   /// LinkGraph.h if all they need are allocation actions.
   orc::shared::AllocActions &graphAllocActions();

 private:
   LinkGraph &G;
   SegmentMap Segments;
 };

 /// A utility class for making simple allocations using JITLinkMemoryManager.
 ///
 /// SimpleSegementAlloc takes a mapping of AllocGroups to Segments and uses
 /// this to create a LinkGraph with one Section (containing one Block) per
 /// Segment. Clients can obtain a pointer to the working memory and executor
 /// address of that block using the Segment's AllocGroup. Once memory has been
 /// populated, clients can call finalize to finalize the memory.
 class SimpleSegmentAlloc {
 public:
   /// Describes a segment to be allocated.
   struct Segment {
     Segment() = default;
     Segment(size_t ContentSize, Align ContentAlign)
         : ContentSize(ContentSize), ContentAlign(ContentAlign) {}

     size_t ContentSize = 0;
     Align ContentAlign;
   };

   /// Describes the segment working memory and executor address.
   struct SegmentInfo {
     orc::ExecutorAddr Addr;
     MutableArrayRef<char> WorkingMem;
   };

   using SegmentMap = AllocGroupSmallMap<Segment>;

   using OnCreatedFunction = unique_function<void(Expected<SimpleSegmentAlloc>)>;

   using OnFinalizedFunction =
       JITLinkMemoryManager::InFlightAlloc::OnFinalizedFunction;

   static void Create(JITLinkMemoryManager &MemMgr, const JITLinkDylib *JD,
                      SegmentMap Segments, OnCreatedFunction OnCreated);

   static Expected<SimpleSegmentAlloc> Create(JITLinkMemoryManager &MemMgr,
                                              const JITLinkDylib *JD,
                                              SegmentMap Segments);

   SimpleSegmentAlloc(SimpleSegmentAlloc &&);
   SimpleSegmentAlloc &operator=(SimpleSegmentAlloc &&);
   ~SimpleSegmentAlloc();

   /// Returns the SegmentInfo for the given group.
   SegmentInfo getSegInfo(AllocGroup AG);

   /// Finalize all groups (async version).
   void finalize(OnFinalizedFunction OnFinalized) {
     Alloc->finalize(std::move(OnFinalized));
   }

   /// Finalize all groups.
   Expected<JITLinkMemoryManager::FinalizedAlloc> finalize() {
     return Alloc->finalize();
   }

 private:
   SimpleSegmentAlloc(
       std::unique_ptr<LinkGraph> G, AllocGroupSmallMap<Block *> ContentBlocks,
       std::unique_ptr<JITLinkMemoryManager::InFlightAlloc> Alloc);

   std::unique_ptr<LinkGraph> G;
   AllocGroupSmallMap<Block *> ContentBlocks;
   std::unique_ptr<JITLinkMemoryManager::InFlightAlloc> Alloc;
 };

 /// A JITLinkMemoryManager that allocates in-process memory.
 class InProcessMemoryManager : public JITLinkMemoryManager {
 public:
   class IPInFlightAlloc;

   /// Attempts to auto-detect the host page size.
   static Expected<std::unique_ptr<InProcessMemoryManager>> Create();

   /// Create an instance using the given page size.
   InProcessMemoryManager(uint64_t PageSize) : PageSize(PageSize) {}

   void allocate(const JITLinkDylib *JD, LinkGraph &G,
                 OnAllocatedFunction OnAllocated) override;

   // Use overloads from base class.
   using JITLinkMemoryManager::allocate;

   void deallocate(std::vector<FinalizedAlloc> Alloc,
                   OnDeallocatedFunction OnDeallocated) override;

   // Use overloads from base class.
   using JITLinkMemoryManager::deallocate;

 private:
   // FIXME: Use an in-place array instead of a vector for DeallocActions.
   //        There shouldn't need to be a heap alloc for this.
   struct FinalizedAllocInfo {
     sys::MemoryBlock StandardSegments;
     std::vector<orc::shared::WrapperFunctionCall> DeallocActions;
   };

   FinalizedAlloc createFinalizedAlloc(
       sys::MemoryBlock StandardSegments,
       std::vector<orc::shared::WrapperFunctionCall> DeallocActions);

   uint64_t PageSize;
   std::mutex FinalizedAllocsMutex;
   RecyclingAllocator<BumpPtrAllocator, FinalizedAllocInfo> FinalizedAllocInfos;
 };

 } // end namespace jitlink
 } // end namespace llvm

 #endif // LLVM_EXECUTIONENGINE_JITLINK_JITLINKMEMORYMANAGER_H
	//===-- JITLinkMemoryManager.h - JITLink mem manager interface --- C++ --===//
	//
	// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
	// See https://llvm.org/LICENSE.txt for license information.
	// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
	//
	//===----------------------------------------------------------------------===//
	//
	// Contains the JITLinkMemoryManager interface.
	//
	//===----------------------------------------------------------------------===//

	#ifndef LLVM_EXECUTIONENGINE_JITLINK_JITLINKMEMORYMANAGER_H
	#define LLVM_EXECUTIONENGINE_JITLINK_JITLINKMEMORYMANAGER_H

	#include "llvm/ADT/FunctionExtras.h"
	#include "llvm/ADT/SmallVector.h"
	#include "llvm/ExecutionEngine/JITLink/JITLinkDylib.h"
	#include "llvm/ExecutionEngine/JITLink/MemoryFlags.h"
	#include "llvm/ExecutionEngine/Orc/Shared/AllocationActions.h"
	#include "llvm/ExecutionEngine/Orc/Shared/ExecutorAddress.h"
	#include "llvm/Support/Allocator.h"
	#include "llvm/Support/Error.h"
	#include "llvm/Support/MSVCErrorWorkarounds.h"
	#include "llvm/Support/Memory.h"
	#include "llvm/Support/RecyclingAllocator.h"

	#include <cstdint>
	#include <future>
	#include <mutex>

	namespace llvm {
	namespace jitlink {

	class Block;
	class LinkGraph;
	class Section;

	/// Manages allocations of JIT memory.
	///
	/// Instances of this class may be accessed concurrently from multiple threads
	/// and their implemetations should include any necessary synchronization.
	class JITLinkMemoryManager {
	public:

	/// Represents a finalized allocation.
	///
	/// Finalized allocations must be passed to the
	/// JITLinkMemoryManager:deallocate method prior to being destroyed.
	///
	/// The interpretation of the Address associated with the finalized allocation
	/// is up to the memory manager implementation. Common options are using the
	/// base address of the allocation, or the address of a memory management
	/// object that tracks the allocation.
	class FinalizedAlloc {
	friend class JITLinkMemoryManager;

	static constexpr auto InvalidAddr = ~uint64_t(0);

	public:
	FinalizedAlloc() = default;
	explicit FinalizedAlloc(orc::ExecutorAddr A) : A(A) {
	assert(A.getValue() != InvalidAddr &&
	"Explicitly creating an invalid allocation?");
	}
	FinalizedAlloc(const FinalizedAlloc &) = delete;
	FinalizedAlloc(FinalizedAlloc &&Other) : A(Other.A) {
	Other.A.setValue(InvalidAddr);
	}
	FinalizedAlloc &operator=(const FinalizedAlloc &) = delete;
	FinalizedAlloc &operator=(FinalizedAlloc &&Other) {
	assert(A.getValue() == InvalidAddr &&
	"Cannot overwrite active finalized allocation");
	std::swap(A, Other.A);
	return *this;
	}
	~FinalizedAlloc() {
	assert(A.getValue() == InvalidAddr &&
	"Finalized allocation was not deallocated");
	}

	/// FinalizedAllocs convert to false for default-constructed, and
	/// true otherwise. Default-constructed allocs need not be deallocated.
	explicit operator bool() const { return A.getValue() != InvalidAddr; }

	/// Returns the address associated with this finalized allocation.
	/// The allocation is unmodified.
	orc::ExecutorAddr getAddress() const { return A; }

	/// Returns the address associated with this finalized allocation and
	/// resets this object to the default state.
	/// This should only be used by allocators when deallocating memory.
	orc::ExecutorAddr release() {
	orc::ExecutorAddr Tmp = A;
	A.setValue(InvalidAddr);
	return Tmp;
	}

	private:
	orc::ExecutorAddr A{InvalidAddr};
	};

	/// Represents an allocation which has not been finalized yet.
	///
	/// InFlightAllocs manage both executor memory allocations and working
	/// memory allocations.
	///
	/// On finalization, the InFlightAlloc should transfer the content of
	/// working memory into executor memory, apply memory protections, and
	/// run any finalization functions.
	///
	/// Working memory should be kept alive at least until one of the following
	/// happens: (1) the InFlightAlloc instance is destroyed, (2) the
	/// InFlightAlloc is abandoned, (3) finalized target memory is destroyed.
	///
	/// If abandon is called then working memory and executor memory should both
	/// be freed.
	class InFlightAlloc {
	public:
	using OnFinalizedFunction = unique_function<void(Expected<FinalizedAlloc>)>;
	using OnAbandonedFunction = unique_function<void(Error)>;

	virtual ~InFlightAlloc();

	/// Called prior to finalization if the allocation should be abandoned.
	virtual void abandon(OnAbandonedFunction OnAbandoned) = 0;

	/// Called to transfer working memory to the target and apply finalization.
	virtual void finalize(OnFinalizedFunction OnFinalized) = 0;

	/// Synchronous convenience version of finalize.
	Expected<FinalizedAlloc> finalize() {
	std::promise<MSVCPExpected<FinalizedAlloc>> FinalizeResultP;
	auto FinalizeResultF = FinalizeResultP.get_future();
	finalize([&](Expected<FinalizedAlloc> Result) {
	FinalizeResultP.set_value(std::move(Result));
	});
	return FinalizeResultF.get();
	}
	};

	/// Typedef for the argument to be passed to OnAllocatedFunction.
	using AllocResult = Expected<std::unique_ptr<InFlightAlloc>>;

	/// Called when allocation has been completed.
	using OnAllocatedFunction = unique_function<void(AllocResult)>;

	/// Called when deallocation has completed.
	using OnDeallocatedFunction = unique_function<void(Error)>;

	virtual ~JITLinkMemoryManager();

	/// Start the allocation process.
	///
	/// If the initial allocation is successful then the OnAllocated function will
	/// be called with a std::unique_ptr<InFlightAlloc> value. If the assocation
	/// is unsuccessful then the OnAllocated function will be called with an
	/// Error.
	virtual void allocate(const JITLinkDylib *JD, LinkGraph &G,
	OnAllocatedFunction OnAllocated) = 0;

	/// Convenience function for blocking allocation.
	AllocResult allocate(const JITLinkDylib *JD, LinkGraph &G) {
	std::promise<MSVCPExpected<std::unique_ptr<InFlightAlloc>>> AllocResultP;
	auto AllocResultF = AllocResultP.get_future();
	allocate(JD, G, [&](AllocResult Alloc) {
	AllocResultP.set_value(std::move(Alloc));
	});
	return AllocResultF.get();
	}

	/// Deallocate a list of allocation objects.
	///
	/// Dealloc actions will be run in reverse order (from the end of the vector
	/// to the start).
	virtual void deallocate(std::vector<FinalizedAlloc> Allocs,
	OnDeallocatedFunction OnDeallocated) = 0;

	/// Convenience function for deallocation of a single alloc.
	void deallocate(FinalizedAlloc Alloc, OnDeallocatedFunction OnDeallocated) {
	std::vector<FinalizedAlloc> Allocs;
	Allocs.push_back(std::move(Alloc));
	deallocate(std::move(Allocs), std::move(OnDeallocated));
	}

	/// Convenience function for blocking deallocation.
	Error deallocate(std::vector<FinalizedAlloc> Allocs) {
	std::promise<MSVCPError> DeallocResultP;
	auto DeallocResultF = DeallocResultP.get_future();
	deallocate(std::move(Allocs),
	[&](Error Err) { DeallocResultP.set_value(std::move(Err)); });
	return DeallocResultF.get();
	}

	/// Convenience function for blocking deallocation of a single alloc.
	Error deallocate(FinalizedAlloc Alloc) {
	std::vector<FinalizedAlloc> Allocs;
	Allocs.push_back(std::move(Alloc));
	return deallocate(std::move(Allocs));
	}
	};

	/// BasicLayout simplifies the implementation of JITLinkMemoryManagers.
	///
	/// BasicLayout groups Sections into Segments based on their memory protection
	/// and deallocation policies. JITLinkMemoryManagers can construct a BasicLayout
	/// from a Graph, and then assign working memory and addresses to each of the
	/// Segments. These addreses will be mapped back onto the Graph blocks in
	/// the apply method.
	class BasicLayout {
	public:
	/// The Alignment, ContentSize and ZeroFillSize of each segment will be
	/// pre-filled from the Graph. Clients must set the Addr and WorkingMem fields
	/// prior to calling apply.
	//
	// FIXME: The C++98 initializer is an attempt to work around compile failures
	// due to http://www.open-std.org/jtc1/sc22/wg21/docs/cwg_defects.html#1397.
	// We should be able to switch this back to member initialization once that
	// issue is fixed.
	class Segment {
	friend class BasicLayout;

	public:
	Segment()
	: ContentSize(0), ZeroFillSize(0), Addr(0), WorkingMem(nullptr),
	NextWorkingMemOffset(0) {}
	Align Alignment;
	size_t ContentSize;
	uint64_t ZeroFillSize;
	orc::ExecutorAddr Addr;
	char *WorkingMem = nullptr;

	private:
	size_t NextWorkingMemOffset;
	std::vector<Block *> ContentBlocks, ZeroFillBlocks;
	};

	/// A convenience class that further groups segments based on memory
	/// deallocation policy. This allows clients to make two slab allocations:
	/// one for all standard segments, and one for all finalize segments.
	struct ContiguousPageBasedLayoutSizes {
	uint64_t StandardSegs = 0;
	uint64_t FinalizeSegs = 0;

	uint64_t total() const { return StandardSegs + FinalizeSegs; }
	};

	private:
	using SegmentMap = AllocGroupSmallMap<Segment>;

	public:
	BasicLayout(LinkGraph &G);

	/// Return a reference to the graph this allocation was created from.
	LinkGraph &getGraph() { return G; }

	/// Returns the total number of required to allocate all segments (with each
	/// segment padded out to page size) for all standard segments, and all
	/// finalize segments.
	///
	/// This is a convenience function for the common case where the segments will
	/// be allocated contiguously.
	///
	/// This function will return an error if any segment has an alignment that
	/// is higher than a page.
	Expected<ContiguousPageBasedLayoutSizes>
	getContiguousPageBasedLayoutSizes(uint64_t PageSize);

	/// Returns an iterator over the segments of the layout.
	iterator_range<SegmentMap::iterator> segments() {
	return {Segments.begin(), Segments.end()};
	}

	/// Apply the layout to the graph.
	Error apply();

	/// Returns a reference to the AllocActions in the graph.
	/// This convenience function saves callers from having to #include
	/// LinkGraph.h if all they need are allocation actions.
	orc::shared::AllocActions &graphAllocActions();

	private:
	LinkGraph &G;
	SegmentMap Segments;
	};

	/// A utility class for making simple allocations using JITLinkMemoryManager.
	///
	/// SimpleSegementAlloc takes a mapping of AllocGroups to Segments and uses
	/// this to create a LinkGraph with one Section (containing one Block) per
	/// Segment. Clients can obtain a pointer to the working memory and executor
	/// address of that block using the Segment's AllocGroup. Once memory has been
	/// populated, clients can call finalize to finalize the memory.
	class SimpleSegmentAlloc {
	public:
	/// Describes a segment to be allocated.
	struct Segment {
	Segment() = default;
	Segment(size_t ContentSize, Align ContentAlign)
	: ContentSize(ContentSize), ContentAlign(ContentAlign) {}

	size_t ContentSize = 0;
	Align ContentAlign;
	};

	/// Describes the segment working memory and executor address.
	struct SegmentInfo {
	orc::ExecutorAddr Addr;
	MutableArrayRef<char> WorkingMem;
	};

	using SegmentMap = AllocGroupSmallMap<Segment>;

	using OnCreatedFunction = unique_function<void(Expected<SimpleSegmentAlloc>)>;

	using OnFinalizedFunction =
	JITLinkMemoryManager::InFlightAlloc::OnFinalizedFunction;

	static void Create(JITLinkMemoryManager &MemMgr, const JITLinkDylib *JD,
	SegmentMap Segments, OnCreatedFunction OnCreated);

	static Expected<SimpleSegmentAlloc> Create(JITLinkMemoryManager &MemMgr,
	const JITLinkDylib *JD,
	SegmentMap Segments);

	SimpleSegmentAlloc(SimpleSegmentAlloc &&);
	SimpleSegmentAlloc &operator=(SimpleSegmentAlloc &&);
	~SimpleSegmentAlloc();

	/// Returns the SegmentInfo for the given group.
	SegmentInfo getSegInfo(AllocGroup AG);

	/// Finalize all groups (async version).
	void finalize(OnFinalizedFunction OnFinalized) {
	Alloc->finalize(std::move(OnFinalized));
	}

	/// Finalize all groups.
	Expected<JITLinkMemoryManager::FinalizedAlloc> finalize() {
	return Alloc->finalize();
	}

	private:
	SimpleSegmentAlloc(
	std::unique_ptr<LinkGraph> G, AllocGroupSmallMap<Block *> ContentBlocks,
	std::unique_ptr<JITLinkMemoryManager::InFlightAlloc> Alloc);

	std::unique_ptr<LinkGraph> G;
	AllocGroupSmallMap<Block *> ContentBlocks;
	std::unique_ptr<JITLinkMemoryManager::InFlightAlloc> Alloc;
	};

	/// A JITLinkMemoryManager that allocates in-process memory.
	class InProcessMemoryManager : public JITLinkMemoryManager {
	public:
	class IPInFlightAlloc;

	/// Attempts to auto-detect the host page size.
	static Expected<std::unique_ptr<InProcessMemoryManager>> Create();

	/// Create an instance using the given page size.
	InProcessMemoryManager(uint64_t PageSize) : PageSize(PageSize) {}

	void allocate(const JITLinkDylib *JD, LinkGraph &G,
	OnAllocatedFunction OnAllocated) override;

	// Use overloads from base class.
	using JITLinkMemoryManager::allocate;

	void deallocate(std::vector<FinalizedAlloc> Alloc,
	OnDeallocatedFunction OnDeallocated) override;

	// Use overloads from base class.
	using JITLinkMemoryManager::deallocate;

	private:
	// FIXME: Use an in-place array instead of a vector for DeallocActions.
	// There shouldn't need to be a heap alloc for this.
	struct FinalizedAllocInfo {
	sys::MemoryBlock StandardSegments;
	std::vector<orc::shared::WrapperFunctionCall> DeallocActions;
	};

	FinalizedAlloc createFinalizedAlloc(
	sys::MemoryBlock StandardSegments,
	std::vector<orc::shared::WrapperFunctionCall> DeallocActions);

	uint64_t PageSize;
	std::mutex FinalizedAllocsMutex;
	RecyclingAllocator<BumpPtrAllocator, FinalizedAllocInfo> FinalizedAllocInfos;
	};

	} // end namespace jitlink
	} // end namespace llvm

	#endif // LLVM_EXECUTIONENGINE_JITLINK_JITLINKMEMORYMANAGER_H