libomptarget/plugins-nextgen/host/src/rtl.cpp - llvm-project/openmp - Git at Google

 //===-RTLs/generic-64bit/src/rtl.cpp - Target RTLs Implementation - 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
 //
 //===----------------------------------------------------------------------===//
 //
 // RTL NextGen for generic 64-bit machine
 //
 //===----------------------------------------------------------------------===//

 #include <cassert>
 #include <cstddef>
 #include <ffi.h>
 #include <string>
 #include <unordered_map>

 #include "Shared/Debug.h"
 #include "Shared/Environment.h"

 #include "GlobalHandler.h"
 #include "OpenMP/OMPT/Callback.h"
 #include "PluginInterface.h"
 #include "omptarget.h"

 #include "llvm/ADT/SmallVector.h"
 #include "llvm/Frontend/OpenMP/OMPConstants.h"
 #include "llvm/Frontend/OpenMP/OMPDeviceConstants.h"
 #include "llvm/Frontend/OpenMP/OMPGridValues.h"
 #include "llvm/Support/DynamicLibrary.h"

 // The number of devices in this plugin.
 #define NUM_DEVICES 4

 // The ELF ID should be defined at compile-time by the build system.
 #ifndef TARGET_ELF_ID
 #define TARGET_ELF_ID EM_NONE
 #endif

 // The target triple should be defined at compile-time by the build system.
 #ifndef LIBOMPTARGET_NEXTGEN_GENERIC_PLUGIN_TRIPLE
 #define LIBOMPTARGET_NEXTGEN_GENERIC_PLUGIN_TRIPLE ""
 #endif

 namespace llvm {
 namespace omp {
 namespace target {
 namespace plugin {

 /// Forward declarations for all specialized data structures.
 struct GenELF64KernelTy;
 struct GenELF64DeviceTy;
 struct GenELF64PluginTy;

 using llvm::sys::DynamicLibrary;

 /// Class implementing kernel functionalities for GenELF64.
 struct GenELF64KernelTy : public GenericKernelTy {
   /// Construct the kernel with a name and an execution mode.
   GenELF64KernelTy(const char *Name) : GenericKernelTy(Name), Func(nullptr) {}

   /// Initialize the kernel.
   Error initImpl(GenericDeviceTy &Device, DeviceImageTy &Image) override {
     // Functions have zero size.
     GlobalTy Global(getName(), 0);

     // Get the metadata (address) of the kernel function.
     GenericGlobalHandlerTy &GHandler = Device.Plugin.getGlobalHandler();
     if (auto Err = GHandler.getGlobalMetadataFromDevice(Device, Image, Global))
       return Err;

     // Check that the function pointer is valid.
     if (!Global.getPtr())
       return Plugin::error("Invalid function for kernel %s", getName());

     // Save the function pointer.
     Func = (void (*)())Global.getPtr();

     KernelEnvironment.Configuration.ExecMode = OMP_TGT_EXEC_MODE_GENERIC;
     KernelEnvironment.Configuration.MayUseNestedParallelism = /*Unknown=*/2;
     KernelEnvironment.Configuration.UseGenericStateMachine = /*Unknown=*/2;

     // Set the maximum number of threads to a single.
     MaxNumThreads = 1;
     return Plugin::success();
   }

   /// Launch the kernel using the libffi.
   Error launchImpl(GenericDeviceTy &GenericDevice, uint32_t NumThreads,
                    uint64_t NumBlocks, KernelArgsTy &KernelArgs, void *Args,
                    AsyncInfoWrapperTy &AsyncInfoWrapper) const override {
     // Create a vector of ffi_types, one per argument.
     SmallVector<ffi_type *, 16> ArgTypes(KernelArgs.NumArgs, &ffi_type_pointer);
     ffi_type **ArgTypesPtr = (ArgTypes.size()) ? &ArgTypes[0] : nullptr;

     // Prepare the cif structure before running the kernel function.
     ffi_cif Cif;
     ffi_status Status = ffi_prep_cif(&Cif, FFI_DEFAULT_ABI, KernelArgs.NumArgs,
                                      &ffi_type_void, ArgTypesPtr);
     if (Status != FFI_OK)
       return Plugin::error("Error in ffi_prep_cif: %d", Status);

     // Call the kernel function through libffi.
     long Return;
     ffi_call(&Cif, Func, &Return, (void **)Args);

     return Plugin::success();
   }

 private:
   /// The kernel function to execute.
   void (*Func)(void);
 };

 /// Class implementing the GenELF64 device images properties.
 struct GenELF64DeviceImageTy : public DeviceImageTy {
   /// Create the GenELF64 image with the id and the target image pointer.
   GenELF64DeviceImageTy(int32_t ImageId, GenericDeviceTy &Device,
                         const __tgt_device_image *TgtImage)
       : DeviceImageTy(ImageId, Device, TgtImage), DynLib() {}

   /// Getter and setter for the dynamic library.
   DynamicLibrary &getDynamicLibrary() { return DynLib; }
   void setDynamicLibrary(const DynamicLibrary &Lib) { DynLib = Lib; }

 private:
   /// The dynamic library that loaded the image.
   DynamicLibrary DynLib;
 };

 /// Class implementing the device functionalities for GenELF64.
 struct GenELF64DeviceTy : public GenericDeviceTy {
   /// Create the device with a specific id.
   GenELF64DeviceTy(GenericPluginTy &Plugin, int32_t DeviceId,
                    int32_t NumDevices)
       : GenericDeviceTy(Plugin, DeviceId, NumDevices, GenELF64GridValues) {}

   ~GenELF64DeviceTy() {}

   /// Initialize the device, which is a no-op
   Error initImpl(GenericPluginTy &Plugin) override { return Plugin::success(); }

   /// Deinitialize the device, which is a no-op
   Error deinitImpl() override { return Plugin::success(); }

   /// See GenericDeviceTy::getComputeUnitKind().
   std::string getComputeUnitKind() const override { return "generic-64bit"; }

   /// Construct the kernel for a specific image on the device.
   Expected<GenericKernelTy &> constructKernel(const char *Name) override {
     // Allocate and construct the kernel.
     GenELF64KernelTy *GenELF64Kernel = Plugin.allocate<GenELF64KernelTy>();
     if (!GenELF64Kernel)
       return Plugin::error("Failed to allocate memory for GenELF64 kernel");

     new (GenELF64Kernel) GenELF64KernelTy(Name);

     return *GenELF64Kernel;
   }

   /// Set the current context to this device, which is a no-op.
   Error setContext() override { return Plugin::success(); }

   /// Load the binary image into the device and allocate an image object.
   Expected<DeviceImageTy *> loadBinaryImpl(const __tgt_device_image *TgtImage,
                                            int32_t ImageId) override {
     // Allocate and initialize the image object.
     GenELF64DeviceImageTy *Image = Plugin.allocate<GenELF64DeviceImageTy>();
     new (Image) GenELF64DeviceImageTy(ImageId, *this, TgtImage);

     // Create a temporary file.
     char TmpFileName[] = "/tmp/tmpfile_XXXXXX";
     int TmpFileFd = mkstemp(TmpFileName);
     if (TmpFileFd == -1)
       return Plugin::error("Failed to create tmpfile for loading target image");

     // Open the temporary file.
     FILE *TmpFile = fdopen(TmpFileFd, "wb");
     if (!TmpFile)
       return Plugin::error("Failed to open tmpfile %s for loading target image",
                            TmpFileName);

     // Write the image into the temporary file.
     size_t Written = fwrite(Image->getStart(), Image->getSize(), 1, TmpFile);
     if (Written != 1)
       return Plugin::error("Failed to write target image to tmpfile %s",
                            TmpFileName);

     // Close the temporary file.
     int Ret = fclose(TmpFile);
     if (Ret)
       return Plugin::error("Failed to close tmpfile %s with the target image",
                            TmpFileName);

     // Load the temporary file as a dynamic library.
     std::string ErrMsg;
     DynamicLibrary DynLib =
         DynamicLibrary::getPermanentLibrary(TmpFileName, &ErrMsg);

     // Check if the loaded library is valid.
     if (!DynLib.isValid())
       return Plugin::error("Failed to load target image: %s", ErrMsg.c_str());

     // Save a reference of the image's dynamic library.
     Image->setDynamicLibrary(DynLib);

     return Image;
   }

   /// Allocate memory. Use std::malloc in all cases.
   void *allocate(size_t Size, void *, TargetAllocTy Kind) override {
     if (Size == 0)
       return nullptr;

     void *MemAlloc = nullptr;
     switch (Kind) {
     case TARGET_ALLOC_DEFAULT:
     case TARGET_ALLOC_DEVICE:
     case TARGET_ALLOC_HOST:
     case TARGET_ALLOC_SHARED:
     case TARGET_ALLOC_DEVICE_NON_BLOCKING:
       MemAlloc = std::malloc(Size);
       break;
     }
     return MemAlloc;
   }

   /// Free the memory. Use std::free in all cases.
   int free(void *TgtPtr, TargetAllocTy Kind) override {
     std::free(TgtPtr);
     return OFFLOAD_SUCCESS;
   }

   /// This plugin does nothing to lock buffers. Do not return an error, just
   /// return the same pointer as the device pointer.
   Expected<void *> dataLockImpl(void *HstPtr, int64_t Size) override {
     return HstPtr;
   }

   /// Nothing to do when unlocking the buffer.
   Error dataUnlockImpl(void *HstPtr) override { return Plugin::success(); }

   /// Indicate that the buffer is not pinned.
   Expected<bool> isPinnedPtrImpl(void *HstPtr, void *&BaseHstPtr,
                                  void *&BaseDevAccessiblePtr,
                                  size_t &BaseSize) const override {
     return false;
   }

   /// Submit data to the device (host to device transfer).
   Error dataSubmitImpl(void *TgtPtr, const void *HstPtr, int64_t Size,
                        AsyncInfoWrapperTy &AsyncInfoWrapper) override {
     std::memcpy(TgtPtr, HstPtr, Size);
     return Plugin::success();
   }

   /// Retrieve data from the device (device to host transfer).
   Error dataRetrieveImpl(void *HstPtr, const void *TgtPtr, int64_t Size,
                          AsyncInfoWrapperTy &AsyncInfoWrapper) override {
     std::memcpy(HstPtr, TgtPtr, Size);
     return Plugin::success();
   }

   /// Exchange data between two devices within the plugin. This function is not
   /// supported in this plugin.
   Error dataExchangeImpl(const void *SrcPtr, GenericDeviceTy &DstGenericDevice,
                          void *DstPtr, int64_t Size,
                          AsyncInfoWrapperTy &AsyncInfoWrapper) override {
     // This function should never be called because the function
     // GenELF64PluginTy::isDataExchangable() returns false.
     return Plugin::error("dataExchangeImpl not supported");
   }

   /// All functions are already synchronous. No need to do anything on this
   /// synchronization function.
   Error synchronizeImpl(__tgt_async_info &AsyncInfo) override {
     return Plugin::success();
   }

   /// All functions are already synchronous. No need to do anything on this
   /// query function.
   Error queryAsyncImpl(__tgt_async_info &AsyncInfo) override {
     return Plugin::success();
   }

   /// This plugin does not support interoperability
   Error initAsyncInfoImpl(AsyncInfoWrapperTy &AsyncInfoWrapper) override {
     return Plugin::error("initAsyncInfoImpl not supported");
   }

   /// This plugin does not support interoperability
   Error initDeviceInfoImpl(__tgt_device_info *DeviceInfo) override {
     return Plugin::error("initDeviceInfoImpl not supported");
   }

   /// This plugin does not support the event API. Do nothing without failing.
   Error createEventImpl(void **EventPtrStorage) override {
     *EventPtrStorage = nullptr;
     return Plugin::success();
   }
   Error destroyEventImpl(void *EventPtr) override { return Plugin::success(); }
   Error recordEventImpl(void *EventPtr,
                         AsyncInfoWrapperTy &AsyncInfoWrapper) override {
     return Plugin::success();
   }
   Error waitEventImpl(void *EventPtr,
                       AsyncInfoWrapperTy &AsyncInfoWrapper) override {
     return Plugin::success();
   }
   Error syncEventImpl(void *EventPtr) override { return Plugin::success(); }

   /// Print information about the device.
   Error obtainInfoImpl(InfoQueueTy &Info) override {
     Info.add("Device Type", "Generic-elf-64bit");
     return Plugin::success();
   }

   /// This plugin should not setup the device environment or memory pool.
   virtual bool shouldSetupDeviceEnvironment() const override { return false; };
   virtual bool shouldSetupDeviceMemoryPool() const override { return false; };

   /// Getters and setters for stack size and heap size not relevant.
   Error getDeviceStackSize(uint64_t &Value) override {
     Value = 0;
     return Plugin::success();
   }
   Error setDeviceStackSize(uint64_t Value) override {
     return Plugin::success();
   }
   Error getDeviceHeapSize(uint64_t &Value) override {
     Value = 0;
     return Plugin::success();
   }
   Error setDeviceHeapSize(uint64_t Value) override { return Plugin::success(); }

 private:
   /// Grid values for Generic ELF64 plugins.
   static constexpr GV GenELF64GridValues = {
       1, // GV_Slot_Size
       1, // GV_Warp_Size
       1, // GV_Max_Teams
       1, // GV_Default_Num_Teams
       1, // GV_SimpleBufferSize
       1, // GV_Max_WG_Size
       1, // GV_Default_WG_Size
   };
 };

 class GenELF64GlobalHandlerTy final : public GenericGlobalHandlerTy {
 public:
   Error getGlobalMetadataFromDevice(GenericDeviceTy &GenericDevice,
                                     DeviceImageTy &Image,
                                     GlobalTy &DeviceGlobal) override {
     const char *GlobalName = DeviceGlobal.getName().data();
     GenELF64DeviceImageTy &GenELF64Image =
         static_cast<GenELF64DeviceImageTy &>(Image);

     // Get dynamic library that has loaded the device image.
     DynamicLibrary &DynLib = GenELF64Image.getDynamicLibrary();

     // Get the address of the symbol.
     void *Addr = DynLib.getAddressOfSymbol(GlobalName);
     if (Addr == nullptr) {
       return Plugin::error("Failed to load global '%s'", GlobalName);
     }

     // Save the pointer to the symbol.
     DeviceGlobal.setPtr(Addr);

     return Plugin::success();
   }
 };

 /// Class implementing the plugin functionalities for GenELF64.
 struct GenELF64PluginTy final : public GenericPluginTy {
   /// Create the GenELF64 plugin.
   GenELF64PluginTy() : GenericPluginTy(getTripleArch()) {}

   /// This class should not be copied.
   GenELF64PluginTy(const GenELF64PluginTy &) = delete;
   GenELF64PluginTy(GenELF64PluginTy &&) = delete;

   /// Initialize the plugin and return the number of devices.
   Expected<int32_t> initImpl() override {
 #ifdef OMPT_SUPPORT
     ompt::connectLibrary();
 #endif

 #ifdef USES_DYNAMIC_FFI
     if (auto Err = Plugin::check(ffi_init(), "Failed to initialize libffi"))
       return std::move(Err);
 #endif

     return NUM_DEVICES;
   }

   /// Deinitialize the plugin.
   Error deinitImpl() override { return Plugin::success(); }

   /// Creates a generic ELF device.
   GenericDeviceTy *createDevice(GenericPluginTy &Plugin, int32_t DeviceId,
                                 int32_t NumDevices) override {
     return new GenELF64DeviceTy(Plugin, DeviceId, NumDevices);
   }

   /// Creates a generic global handler.
   GenericGlobalHandlerTy *createGlobalHandler() override {
     return new GenELF64GlobalHandlerTy();
   }

   /// Get the ELF code to recognize the compatible binary images.
   uint16_t getMagicElfBits() const override { return ELF::TARGET_ELF_ID; }

   /// This plugin does not support exchanging data between two devices.
   bool isDataExchangable(int32_t SrcDeviceId, int32_t DstDeviceId) override {
     return false;
   }

   /// All images (ELF-compatible) should be compatible with this plugin.
   Expected<bool> isELFCompatible(StringRef) const override { return true; }

   Triple::ArchType getTripleArch() const override {
     return llvm::Triple(LIBOMPTARGET_NEXTGEN_GENERIC_PLUGIN_TRIPLE).getArch();
   }
 };

 GenericPluginTy *PluginTy::createPlugin() { return new GenELF64PluginTy(); }

 template <typename... ArgsTy>
 static Error Plugin::check(int32_t Code, const char *ErrMsg, ArgsTy... Args) {
   if (Code == 0)
     return Error::success();

   return createStringError<ArgsTy..., const char *>(
       inconvertibleErrorCode(), ErrMsg, Args..., std::to_string(Code).data());
 }

 } // namespace plugin
 } // namespace target
 } // namespace omp
 } // namespace llvm
	//===-RTLs/generic-64bit/src/rtl.cpp - Target RTLs Implementation - 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
	//
	//===----------------------------------------------------------------------===//
	//
	// RTL NextGen for generic 64-bit machine
	//
	//===----------------------------------------------------------------------===//

	#include <cassert>
	#include <cstddef>
	#include <ffi.h>
	#include <string>
	#include <unordered_map>

	#include "Shared/Debug.h"
	#include "Shared/Environment.h"

	#include "GlobalHandler.h"
	#include "OpenMP/OMPT/Callback.h"
	#include "PluginInterface.h"
	#include "omptarget.h"

	#include "llvm/ADT/SmallVector.h"
	#include "llvm/Frontend/OpenMP/OMPConstants.h"
	#include "llvm/Frontend/OpenMP/OMPDeviceConstants.h"
	#include "llvm/Frontend/OpenMP/OMPGridValues.h"
	#include "llvm/Support/DynamicLibrary.h"

	// The number of devices in this plugin.
	#define NUM_DEVICES 4

	// The ELF ID should be defined at compile-time by the build system.
	#ifndef TARGET_ELF_ID
	#define TARGET_ELF_ID EM_NONE
	#endif

	// The target triple should be defined at compile-time by the build system.
	#ifndef LIBOMPTARGET_NEXTGEN_GENERIC_PLUGIN_TRIPLE
	#define LIBOMPTARGET_NEXTGEN_GENERIC_PLUGIN_TRIPLE ""
	#endif

	namespace llvm {
	namespace omp {
	namespace target {
	namespace plugin {

	/// Forward declarations for all specialized data structures.
	struct GenELF64KernelTy;
	struct GenELF64DeviceTy;
	struct GenELF64PluginTy;

	using llvm::sys::DynamicLibrary;

	/// Class implementing kernel functionalities for GenELF64.
	struct GenELF64KernelTy : public GenericKernelTy {
	/// Construct the kernel with a name and an execution mode.
	GenELF64KernelTy(const char *Name) : GenericKernelTy(Name), Func(nullptr) {}

	/// Initialize the kernel.
	Error initImpl(GenericDeviceTy &Device, DeviceImageTy &Image) override {
	// Functions have zero size.
	GlobalTy Global(getName(), 0);

	// Get the metadata (address) of the kernel function.
	GenericGlobalHandlerTy &GHandler = Device.Plugin.getGlobalHandler();
	if (auto Err = GHandler.getGlobalMetadataFromDevice(Device, Image, Global))
	return Err;

	// Check that the function pointer is valid.
	if (!Global.getPtr())
	return Plugin::error("Invalid function for kernel %s", getName());

	// Save the function pointer.
	Func = (void (*)())Global.getPtr();

	KernelEnvironment.Configuration.ExecMode = OMP_TGT_EXEC_MODE_GENERIC;
	KernelEnvironment.Configuration.MayUseNestedParallelism = /Unknown=/2;
	KernelEnvironment.Configuration.UseGenericStateMachine = /Unknown=/2;

	// Set the maximum number of threads to a single.
	MaxNumThreads = 1;
	return Plugin::success();
	}

	/// Launch the kernel using the libffi.
	Error launchImpl(GenericDeviceTy &GenericDevice, uint32_t NumThreads,
	uint64_t NumBlocks, KernelArgsTy &KernelArgs, void *Args,
	AsyncInfoWrapperTy &AsyncInfoWrapper) const override {
	// Create a vector of ffi_types, one per argument.
	SmallVector<ffi_type *, 16> ArgTypes(KernelArgs.NumArgs, &ffi_type_pointer);
	ffi_type **ArgTypesPtr = (ArgTypes.size()) ? &ArgTypes[0] : nullptr;

	// Prepare the cif structure before running the kernel function.
	ffi_cif Cif;
	ffi_status Status = ffi_prep_cif(&Cif, FFI_DEFAULT_ABI, KernelArgs.NumArgs,
	&ffi_type_void, ArgTypesPtr);
	if (Status != FFI_OK)
	return Plugin::error("Error in ffi_prep_cif: %d", Status);

	// Call the kernel function through libffi.
	long Return;
	ffi_call(&Cif, Func, &Return, (void **)Args);

	return Plugin::success();
	}

	private:
	/// The kernel function to execute.
	void (*Func)(void);
	};

	/// Class implementing the GenELF64 device images properties.
	struct GenELF64DeviceImageTy : public DeviceImageTy {
	/// Create the GenELF64 image with the id and the target image pointer.
	GenELF64DeviceImageTy(int32_t ImageId, GenericDeviceTy &Device,
	const __tgt_device_image *TgtImage)
	: DeviceImageTy(ImageId, Device, TgtImage), DynLib() {}

	/// Getter and setter for the dynamic library.
	DynamicLibrary &getDynamicLibrary() { return DynLib; }
	void setDynamicLibrary(const DynamicLibrary &Lib) { DynLib = Lib; }

	private:
	/// The dynamic library that loaded the image.
	DynamicLibrary DynLib;
	};

	/// Class implementing the device functionalities for GenELF64.
	struct GenELF64DeviceTy : public GenericDeviceTy {
	/// Create the device with a specific id.
	GenELF64DeviceTy(GenericPluginTy &Plugin, int32_t DeviceId,
	int32_t NumDevices)
	: GenericDeviceTy(Plugin, DeviceId, NumDevices, GenELF64GridValues) {}

	~GenELF64DeviceTy() {}

	/// Initialize the device, which is a no-op
	Error initImpl(GenericPluginTy &Plugin) override { return Plugin::success(); }

	/// Deinitialize the device, which is a no-op
	Error deinitImpl() override { return Plugin::success(); }

	/// See GenericDeviceTy::getComputeUnitKind().
	std::string getComputeUnitKind() const override { return "generic-64bit"; }

	/// Construct the kernel for a specific image on the device.
	Expected<GenericKernelTy &> constructKernel(const char *Name) override {
	// Allocate and construct the kernel.
	GenELF64KernelTy *GenELF64Kernel = Plugin.allocate<GenELF64KernelTy>();
	if (!GenELF64Kernel)
	return Plugin::error("Failed to allocate memory for GenELF64 kernel");

	new (GenELF64Kernel) GenELF64KernelTy(Name);

	return *GenELF64Kernel;
	}

	/// Set the current context to this device, which is a no-op.
	Error setContext() override { return Plugin::success(); }

	/// Load the binary image into the device and allocate an image object.
	Expected<DeviceImageTy > loadBinaryImpl(const __tgt_device_image TgtImage,
	int32_t ImageId) override {
	// Allocate and initialize the image object.
	GenELF64DeviceImageTy *Image = Plugin.allocate<GenELF64DeviceImageTy>();
	new (Image) GenELF64DeviceImageTy(ImageId, *this, TgtImage);

	// Create a temporary file.
	char TmpFileName[] = "/tmp/tmpfile_XXXXXX";
	int TmpFileFd = mkstemp(TmpFileName);
	if (TmpFileFd == -1)
	return Plugin::error("Failed to create tmpfile for loading target image");

	// Open the temporary file.
	FILE *TmpFile = fdopen(TmpFileFd, "wb");
	if (!TmpFile)
	return Plugin::error("Failed to open tmpfile %s for loading target image",
	TmpFileName);

	// Write the image into the temporary file.
	size_t Written = fwrite(Image->getStart(), Image->getSize(), 1, TmpFile);
	if (Written != 1)
	return Plugin::error("Failed to write target image to tmpfile %s",
	TmpFileName);

	// Close the temporary file.
	int Ret = fclose(TmpFile);
	if (Ret)
	return Plugin::error("Failed to close tmpfile %s with the target image",
	TmpFileName);

	// Load the temporary file as a dynamic library.
	std::string ErrMsg;
	DynamicLibrary DynLib =
	DynamicLibrary::getPermanentLibrary(TmpFileName, &ErrMsg);

	// Check if the loaded library is valid.
	if (!DynLib.isValid())
	return Plugin::error("Failed to load target image: %s", ErrMsg.c_str());

	// Save a reference of the image's dynamic library.
	Image->setDynamicLibrary(DynLib);

	return Image;
	}

	/// Allocate memory. Use std::malloc in all cases.
	void allocate(size_t Size, void , TargetAllocTy Kind) override {
	if (Size == 0)
	return nullptr;

	void *MemAlloc = nullptr;
	switch (Kind) {
	case TARGET_ALLOC_DEFAULT:
	case TARGET_ALLOC_DEVICE:
	case TARGET_ALLOC_HOST:
	case TARGET_ALLOC_SHARED:
	case TARGET_ALLOC_DEVICE_NON_BLOCKING:
	MemAlloc = std::malloc(Size);
	break;
	}
	return MemAlloc;
	}

	/// Free the memory. Use std::free in all cases.
	int free(void *TgtPtr, TargetAllocTy Kind) override {
	std::free(TgtPtr);
	return OFFLOAD_SUCCESS;
	}

	/// This plugin does nothing to lock buffers. Do not return an error, just
	/// return the same pointer as the device pointer.
	Expected<void > dataLockImpl(void HstPtr, int64_t Size) override {
	return HstPtr;
	}

	/// Nothing to do when unlocking the buffer.
	Error dataUnlockImpl(void *HstPtr) override { return Plugin::success(); }

	/// Indicate that the buffer is not pinned.
	Expected<bool> isPinnedPtrImpl(void HstPtr, void &BaseHstPtr,
	void *&BaseDevAccessiblePtr,
	size_t &BaseSize) const override {
	return false;
	}

	/// Submit data to the device (host to device transfer).
	Error dataSubmitImpl(void TgtPtr, const void HstPtr, int64_t Size,
	AsyncInfoWrapperTy &AsyncInfoWrapper) override {
	std::memcpy(TgtPtr, HstPtr, Size);
	return Plugin::success();
	}

	/// Retrieve data from the device (device to host transfer).
	Error dataRetrieveImpl(void HstPtr, const void TgtPtr, int64_t Size,
	AsyncInfoWrapperTy &AsyncInfoWrapper) override {
	std::memcpy(HstPtr, TgtPtr, Size);
	return Plugin::success();
	}

	/// Exchange data between two devices within the plugin. This function is not
	/// supported in this plugin.
	Error dataExchangeImpl(const void *SrcPtr, GenericDeviceTy &DstGenericDevice,
	void *DstPtr, int64_t Size,
	AsyncInfoWrapperTy &AsyncInfoWrapper) override {
	// This function should never be called because the function
	// GenELF64PluginTy::isDataExchangable() returns false.
	return Plugin::error("dataExchangeImpl not supported");
	}

	/// All functions are already synchronous. No need to do anything on this
	/// synchronization function.
	Error synchronizeImpl(__tgt_async_info &AsyncInfo) override {
	return Plugin::success();
	}

	/// All functions are already synchronous. No need to do anything on this
	/// query function.
	Error queryAsyncImpl(__tgt_async_info &AsyncInfo) override {
	return Plugin::success();
	}

	/// This plugin does not support interoperability
	Error initAsyncInfoImpl(AsyncInfoWrapperTy &AsyncInfoWrapper) override {
	return Plugin::error("initAsyncInfoImpl not supported");
	}

	/// This plugin does not support interoperability
	Error initDeviceInfoImpl(__tgt_device_info *DeviceInfo) override {
	return Plugin::error("initDeviceInfoImpl not supported");
	}

	/// This plugin does not support the event API. Do nothing without failing.
	Error createEventImpl(void **EventPtrStorage) override {
	*EventPtrStorage = nullptr;
	return Plugin::success();
	}
	Error destroyEventImpl(void *EventPtr) override { return Plugin::success(); }
	Error recordEventImpl(void *EventPtr,
	AsyncInfoWrapperTy &AsyncInfoWrapper) override {
	return Plugin::success();
	}
	Error waitEventImpl(void *EventPtr,
	AsyncInfoWrapperTy &AsyncInfoWrapper) override {
	return Plugin::success();
	}
	Error syncEventImpl(void *EventPtr) override { return Plugin::success(); }

	/// Print information about the device.
	Error obtainInfoImpl(InfoQueueTy &Info) override {
	Info.add("Device Type", "Generic-elf-64bit");
	return Plugin::success();
	}

	/// This plugin should not setup the device environment or memory pool.
	virtual bool shouldSetupDeviceEnvironment() const override { return false; };
	virtual bool shouldSetupDeviceMemoryPool() const override { return false; };

	/// Getters and setters for stack size and heap size not relevant.
	Error getDeviceStackSize(uint64_t &Value) override {
	Value = 0;
	return Plugin::success();
	}
	Error setDeviceStackSize(uint64_t Value) override {
	return Plugin::success();
	}
	Error getDeviceHeapSize(uint64_t &Value) override {
	Value = 0;
	return Plugin::success();
	}
	Error setDeviceHeapSize(uint64_t Value) override { return Plugin::success(); }

	private:
	/// Grid values for Generic ELF64 plugins.
	static constexpr GV GenELF64GridValues = {
	1, // GV_Slot_Size
	1, // GV_Warp_Size
	1, // GV_Max_Teams
	1, // GV_Default_Num_Teams
	1, // GV_SimpleBufferSize
	1, // GV_Max_WG_Size
	1, // GV_Default_WG_Size
	};
	};

	class GenELF64GlobalHandlerTy final : public GenericGlobalHandlerTy {
	public:
	Error getGlobalMetadataFromDevice(GenericDeviceTy &GenericDevice,
	DeviceImageTy &Image,
	GlobalTy &DeviceGlobal) override {
	const char *GlobalName = DeviceGlobal.getName().data();
	GenELF64DeviceImageTy &GenELF64Image =
	static_cast<GenELF64DeviceImageTy &>(Image);

	// Get dynamic library that has loaded the device image.
	DynamicLibrary &DynLib = GenELF64Image.getDynamicLibrary();

	// Get the address of the symbol.
	void *Addr = DynLib.getAddressOfSymbol(GlobalName);
	if (Addr == nullptr) {
	return Plugin::error("Failed to load global '%s'", GlobalName);
	}

	// Save the pointer to the symbol.
	DeviceGlobal.setPtr(Addr);

	return Plugin::success();
	}
	};

	/// Class implementing the plugin functionalities for GenELF64.
	struct GenELF64PluginTy final : public GenericPluginTy {
	/// Create the GenELF64 plugin.
	GenELF64PluginTy() : GenericPluginTy(getTripleArch()) {}

	/// This class should not be copied.
	GenELF64PluginTy(const GenELF64PluginTy &) = delete;
	GenELF64PluginTy(GenELF64PluginTy &&) = delete;

	/// Initialize the plugin and return the number of devices.
	Expected<int32_t> initImpl() override {
	#ifdef OMPT_SUPPORT
	ompt::connectLibrary();
	#endif

	#ifdef USES_DYNAMIC_FFI
	if (auto Err = Plugin::check(ffi_init(), "Failed to initialize libffi"))
	return std::move(Err);
	#endif

	return NUM_DEVICES;
	}

	/// Deinitialize the plugin.
	Error deinitImpl() override { return Plugin::success(); }

	/// Creates a generic ELF device.
	GenericDeviceTy *createDevice(GenericPluginTy &Plugin, int32_t DeviceId,
	int32_t NumDevices) override {
	return new GenELF64DeviceTy(Plugin, DeviceId, NumDevices);
	}

	/// Creates a generic global handler.
	GenericGlobalHandlerTy *createGlobalHandler() override {
	return new GenELF64GlobalHandlerTy();
	}

	/// Get the ELF code to recognize the compatible binary images.
	uint16_t getMagicElfBits() const override { return ELF::TARGET_ELF_ID; }

	/// This plugin does not support exchanging data between two devices.
	bool isDataExchangable(int32_t SrcDeviceId, int32_t DstDeviceId) override {
	return false;
	}

	/// All images (ELF-compatible) should be compatible with this plugin.
	Expected<bool> isELFCompatible(StringRef) const override { return true; }

	Triple::ArchType getTripleArch() const override {
	return llvm::Triple(LIBOMPTARGET_NEXTGEN_GENERIC_PLUGIN_TRIPLE).getArch();
	}
	};

	GenericPluginTy *PluginTy::createPlugin() { return new GenELF64PluginTy(); }

	template <typename... ArgsTy>
	static Error Plugin::check(int32_t Code, const char *ErrMsg, ArgsTy... Args) {
	if (Code == 0)
	return Error::success();

	return createStringError<ArgsTy..., const char *>(
	inconvertibleErrorCode(), ErrMsg, Args..., std::to_string(Code).data());
	}

	} // namespace plugin
	} // namespace target
	} // namespace omp
	} // namespace llvm