openmp/libomptarget/src/device.h - llvm-project - Git at Google

 //===----------- device.h - Target independent OpenMP target RTL ----------===//
 //
 // 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
 //
 //===----------------------------------------------------------------------===//
 //
 // Declarations for managing devices that are handled by RTL plugins.
 //
 //===----------------------------------------------------------------------===//

 #ifndef _OMPTARGET_DEVICE_H
 #define _OMPTARGET_DEVICE_H

 #include <cassert>
 #include <cstddef>
 #include <list>
 #include <map>
 #include <memory>
 #include <mutex>
 #include <set>
 #include <vector>

 #include "omptarget.h"
 #include "rtl.h"

 // Forward declarations.
 struct RTLInfoTy;
 struct __tgt_bin_desc;
 struct __tgt_target_table;

 using map_var_info_t = void *;

 // enum for OMP_TARGET_OFFLOAD; keep in sync with kmp.h definition
 enum kmp_target_offload_kind {
   tgt_disabled = 0,
   tgt_default = 1,
   tgt_mandatory = 2
 };
 typedef enum kmp_target_offload_kind kmp_target_offload_kind_t;

 /// Map between host data and target data.
 struct HostDataToTargetTy {
   const uintptr_t HstPtrBase; // host info.
   const uintptr_t HstPtrBegin;
   const uintptr_t HstPtrEnd;       // non-inclusive.
   const map_var_info_t HstPtrName; // Optional source name of mapped variable.

   const uintptr_t TgtPtrBegin; // target info.

 private:
   static const uint64_t INFRefCount = ~(uint64_t)0;
   static std::string refCountToStr(uint64_t RefCount) {
     return RefCount == INFRefCount ? "INF" : std::to_string(RefCount);
   }

   struct StatesTy {
     StatesTy(uint64_t DRC, uint64_t HRC)
         : DynRefCount(DRC), HoldRefCount(HRC) {}
     /// The dynamic reference count is the standard reference count as of OpenMP
     /// 4.5.  The hold reference count is an OpenMP extension for the sake of
     /// OpenACC support.
     ///
     /// The 'ompx_hold' map type modifier is permitted only on "omp target" and
     /// "omp target data", and "delete" is permitted only on "omp target exit
     /// data" and associated runtime library routines.  As a result, we really
     /// need to implement "reset" functionality only for the dynamic reference
     /// counter.  Likewise, only the dynamic reference count can be infinite
     /// because, for example, omp_target_associate_ptr and "omp declare target
     /// link" operate only on it.  Nevertheless, it's actually easier to follow
     /// the code (and requires less assertions for special cases) when we just
     /// implement these features generally across both reference counters here.
     /// Thus, it's the users of this class that impose those restrictions.
     ///
     uint64_t DynRefCount;
     uint64_t HoldRefCount;
     /// This mutex will be locked when data movement is issued. For targets that
     /// doesn't support async data movement, this mutex can guarantee that after
     /// it is released, memory region on the target is update to date. For
     /// targets that support async data movement, this can guarantee that data
     /// movement has been issued. This mutex *must* be locked right before
     /// releasing the mapping table lock.
     std::mutex UpdateMtx;
   };
   // When HostDataToTargetTy is used by std::set, std::set::iterator is const
   // use unique_ptr to make States mutable.
   const std::unique_ptr<StatesTy> States;

 public:
   HostDataToTargetTy(uintptr_t BP, uintptr_t B, uintptr_t E, uintptr_t TB,
                      bool UseHoldRefCount, map_var_info_t Name = nullptr,
                      bool IsINF = false)
       : HstPtrBase(BP), HstPtrBegin(B), HstPtrEnd(E), HstPtrName(Name),
         TgtPtrBegin(TB), States(std::make_unique<StatesTy>(UseHoldRefCount ? 0
                                                            : IsINF ? INFRefCount
                                                                    : 1,
                                                            !UseHoldRefCount ? 0
                                                            : IsINF ? INFRefCount
                                                                    : 1)) {}

   /// Get the total reference count.  This is smarter than just getDynRefCount()
   /// + getHoldRefCount() because it handles the case where at least one is
   /// infinity and the other is non-zero.
   uint64_t getTotalRefCount() const {
     if (States->DynRefCount == INFRefCount ||
         States->HoldRefCount == INFRefCount)
       return INFRefCount;
     return States->DynRefCount + States->HoldRefCount;
   }

   /// Get the dynamic reference count.
   uint64_t getDynRefCount() const { return States->DynRefCount; }

   /// Get the hold reference count.
   uint64_t getHoldRefCount() const { return States->HoldRefCount; }

   /// Reset the specified reference count unless it's infinity.  Reset to 1
   /// (even if currently 0) so it can be followed by a decrement.
   void resetRefCount(bool UseHoldRefCount) const {
     uint64_t &ThisRefCount =
         UseHoldRefCount ? States->HoldRefCount : States->DynRefCount;
     if (ThisRefCount != INFRefCount)
       ThisRefCount = 1;
   }

   /// Increment the specified reference count unless it's infinity.
   void incRefCount(bool UseHoldRefCount) const {
     uint64_t &ThisRefCount =
         UseHoldRefCount ? States->HoldRefCount : States->DynRefCount;
     if (ThisRefCount != INFRefCount) {
       ++ThisRefCount;
       assert(ThisRefCount < INFRefCount && "refcount overflow");
     }
   }

   /// Decrement the specified reference count unless it's infinity or zero, and
   /// return the total reference count.
   uint64_t decRefCount(bool UseHoldRefCount) const {
     uint64_t &ThisRefCount =
         UseHoldRefCount ? States->HoldRefCount : States->DynRefCount;
     uint64_t OtherRefCount =
         UseHoldRefCount ? States->DynRefCount : States->HoldRefCount;
     (void)OtherRefCount;
     if (ThisRefCount != INFRefCount) {
       if (ThisRefCount > 0)
         --ThisRefCount;
       else
         assert(OtherRefCount > 0 && "total refcount underflow");
     }
     return getTotalRefCount();
   }

   /// Is the dynamic (and thus the total) reference count infinite?
   bool isDynRefCountInf() const { return States->DynRefCount == INFRefCount; }

   /// Convert the dynamic reference count to a debug string.
   std::string dynRefCountToStr() const {
     return refCountToStr(States->DynRefCount);
   }

   /// Convert the hold reference count to a debug string.
   std::string holdRefCountToStr() const {
     return refCountToStr(States->HoldRefCount);
   }

   /// Should one decrement of the specified reference count (after resetting it
   /// if \c AfterReset) remove this mapping?
   bool decShouldRemove(bool UseHoldRefCount, bool AfterReset = false) const {
     uint64_t ThisRefCount =
         UseHoldRefCount ? States->HoldRefCount : States->DynRefCount;
     uint64_t OtherRefCount =
         UseHoldRefCount ? States->DynRefCount : States->HoldRefCount;
     if (OtherRefCount > 0)
       return false;
     if (AfterReset)
       return ThisRefCount != INFRefCount;
     return ThisRefCount == 1;
   }

   void lock() const { States->UpdateMtx.lock(); }

   void unlock() const { States->UpdateMtx.unlock(); }
 };

 typedef uintptr_t HstPtrBeginTy;
 inline bool operator<(const HostDataToTargetTy &lhs, const HstPtrBeginTy &rhs) {
   return lhs.HstPtrBegin < rhs;
 }
 inline bool operator<(const HstPtrBeginTy &lhs, const HostDataToTargetTy &rhs) {
   return lhs < rhs.HstPtrBegin;
 }
 inline bool operator<(const HostDataToTargetTy &lhs,
                       const HostDataToTargetTy &rhs) {
   return lhs.HstPtrBegin < rhs.HstPtrBegin;
 }

 typedef std::set<HostDataToTargetTy, std::less<>> HostDataToTargetListTy;

 struct LookupResult {
   struct {
     unsigned IsContained : 1;
     unsigned ExtendsBefore : 1;
     unsigned ExtendsAfter : 1;
   } Flags;

   HostDataToTargetListTy::iterator Entry;

   LookupResult() : Flags({0, 0, 0}), Entry() {}
 };

 /// This struct will be returned by \p DeviceTy::getTargetPointer which provides
 /// more data than just a target pointer.
 struct TargetPointerResultTy {
   struct {
     /// If the map table entry is just created
     unsigned IsNewEntry : 1;
     /// If the pointer is actually a host pointer (when unified memory enabled)
     unsigned IsHostPointer : 1;
   } Flags = {0, 0};

   /// The iterator to the corresponding map table entry
   HostDataToTargetListTy::iterator MapTableEntry{};

   /// The corresponding target pointer
   void *TargetPointer = nullptr;
 };

 /// Map for shadow pointers
 struct ShadowPtrValTy {
   void *HstPtrVal;
   void *TgtPtrAddr;
   void *TgtPtrVal;
 };
 typedef std::map<void *, ShadowPtrValTy> ShadowPtrListTy;

 ///
 struct PendingCtorDtorListsTy {
   std::list<void *> PendingCtors;
   std::list<void *> PendingDtors;
 };
 typedef std::map<__tgt_bin_desc *, PendingCtorDtorListsTy>
     PendingCtorsDtorsPerLibrary;

 struct DeviceTy {
   int32_t DeviceID;
   RTLInfoTy *RTL;
   int32_t RTLDeviceID;

   bool IsInit;
   std::once_flag InitFlag;
   bool HasPendingGlobals;

   HostDataToTargetListTy HostDataToTargetMap;
   PendingCtorsDtorsPerLibrary PendingCtorsDtors;

   ShadowPtrListTy ShadowPtrMap;

   std::mutex DataMapMtx, PendingGlobalsMtx, ShadowMtx;

   // NOTE: Once libomp gains full target-task support, this state should be
   // moved into the target task in libomp.
   std::map<int32_t, uint64_t> LoopTripCnt;

   DeviceTy(RTLInfoTy *RTL);
   // DeviceTy is not copyable
   DeviceTy(const DeviceTy &D) = delete;
   DeviceTy &operator=(const DeviceTy &D) = delete;

   ~DeviceTy();

   // Return true if data can be copied to DstDevice directly
   bool isDataExchangable(const DeviceTy &DstDevice);

   LookupResult lookupMapping(void *HstPtrBegin, int64_t Size);
   /// Get the target pointer based on host pointer begin and base. If the
   /// mapping already exists, the target pointer will be returned directly. In
   /// addition, if required, the memory region pointed by \p HstPtrBegin of size
   /// \p Size will also be transferred to the device. If the mapping doesn't
   /// exist, and if unified shared memory is not enabled, a new mapping will be
   /// created and the data will also be transferred accordingly. nullptr will be
   /// returned because of any of following reasons:
   /// - Data allocation failed;
   /// - The user tried to do an illegal mapping;
   /// - Data transfer issue fails.
   TargetPointerResultTy
   getTargetPointer(void *HstPtrBegin, void *HstPtrBase, int64_t Size,
                    map_var_info_t HstPtrName, bool HasFlagTo,
                    bool HasFlagAlways, bool IsImplicit, bool UpdateRefCount,
                    bool HasCloseModifier, bool HasPresentModifier,
                    bool HasHoldModifier, AsyncInfoTy &AsyncInfo);
   void *getTgtPtrBegin(void *HstPtrBegin, int64_t Size);
   void *getTgtPtrBegin(void *HstPtrBegin, int64_t Size, bool &IsLast,
                        bool UpdateRefCount, bool UseHoldRefCount,
                        bool &IsHostPtr, bool MustContain = false,
                        bool ForceDelete = false);
   /// For the map entry for \p HstPtrBegin, decrement the reference count
   /// specified by \p HasHoldModifier and, if the the total reference count is
   /// then zero, deallocate the corresponding device storage and remove the map
   /// entry.  Return \c OFFLOAD_SUCCESS if the map entry existed, and return
   /// \c OFFLOAD_FAIL if not.  It is the caller's responsibility to skip calling
   /// this function if the map entry is not expected to exist because
   /// \p HstPtrBegin uses shared memory.
   int deallocTgtPtr(void *HstPtrBegin, int64_t Size, bool HasHoldModifier);
   int associatePtr(void *HstPtrBegin, void *TgtPtrBegin, int64_t Size);
   int disassociatePtr(void *HstPtrBegin);

   // calls to RTL
   int32_t initOnce();
   __tgt_target_table *load_binary(void *Img);

   // device memory allocation/deallocation routines
   /// Allocates \p Size bytes on the device, host or shared memory space
   /// (depending on \p Kind) and returns the address/nullptr when
   /// succeeds/fails. \p HstPtr is an address of the host data which the
   /// allocated target data will be associated with. If it is unknown, the
   /// default value of \p HstPtr is nullptr. Note: this function doesn't do
   /// pointer association. Actually, all the __tgt_rtl_data_alloc
   /// implementations ignore \p HstPtr. \p Kind dictates what allocator should
   /// be used (host, shared, device).
   void *allocData(int64_t Size, void *HstPtr = nullptr,
                   int32_t Kind = TARGET_ALLOC_DEFAULT);
   /// Deallocates memory which \p TgtPtrBegin points at and returns
   /// OFFLOAD_SUCCESS/OFFLOAD_FAIL when succeeds/fails.
   int32_t deleteData(void *TgtPtrBegin);

   // Data transfer. When AsyncInfo is nullptr, the transfer will be
   // synchronous.
   // Copy data from host to device
   int32_t submitData(void *TgtPtrBegin, void *HstPtrBegin, int64_t Size,
                      AsyncInfoTy &AsyncInfo);
   // Copy data from device back to host
   int32_t retrieveData(void *HstPtrBegin, void *TgtPtrBegin, int64_t Size,
                        AsyncInfoTy &AsyncInfo);
   // Copy data from current device to destination device directly
   int32_t dataExchange(void *SrcPtr, DeviceTy &DstDev, void *DstPtr,
                        int64_t Size, AsyncInfoTy &AsyncInfo);

   int32_t runRegion(void *TgtEntryPtr, void **TgtVarsPtr, ptrdiff_t *TgtOffsets,
                     int32_t TgtVarsSize, AsyncInfoTy &AsyncInfo);
   int32_t runTeamRegion(void *TgtEntryPtr, void **TgtVarsPtr,
                         ptrdiff_t *TgtOffsets, int32_t TgtVarsSize,
                         int32_t NumTeams, int32_t ThreadLimit,
                         uint64_t LoopTripCount, AsyncInfoTy &AsyncInfo);

   /// Synchronize device/queue/event based on \p AsyncInfo and return
   /// OFFLOAD_SUCCESS/OFFLOAD_FAIL when succeeds/fails.
   int32_t synchronize(AsyncInfoTy &AsyncInfo);

   /// Calls the corresponding print in the \p RTLDEVID
   /// device RTL to obtain the information of the specific device.
   bool printDeviceInfo(int32_t RTLDevID);

   /// Event related interfaces.
   /// {
   /// Create an event.
   int32_t createEvent(void **Event);

   /// Record the event based on status in AsyncInfo->Queue at the moment the
   /// function is called.
   int32_t recordEvent(void *Event, AsyncInfoTy &AsyncInfo);

   /// Wait for an event. This function can be blocking or non-blocking,
   /// depending on the implmentation. It is expected to set a dependence on the
   /// event such that corresponding operations shall only start once the event
   /// is fulfilled.
   int32_t waitEvent(void *Event, AsyncInfoTy &AsyncInfo);

   /// Synchronize the event. It is expected to block the thread.
   int32_t syncEvent(void *Event);

   /// Destroy the event.
   int32_t destroyEvent(void *Event);
   /// }

 private:
   // Call to RTL
   void init(); // To be called only via DeviceTy::initOnce()
 };

 extern bool device_is_ready(int device_num);

 /// Struct for the data required to handle plugins
 struct PluginManager {
   /// RTLs identified on the host
   RTLsTy RTLs;

   /// Devices associated with RTLs
   std::vector<std::unique_ptr<DeviceTy>> Devices;
   std::mutex RTLsMtx; ///< For RTLs and Devices

   /// Translation table retreived from the binary
   HostEntriesBeginToTransTableTy HostEntriesBeginToTransTable;
   std::mutex TrlTblMtx; ///< For Translation Table
   /// Host offload entries in order of image registration
   std::vector<__tgt_offload_entry *> HostEntriesBeginRegistrationOrder;

   /// Map from ptrs on the host to an entry in the Translation Table
   HostPtrToTableMapTy HostPtrToTableMap;
   std::mutex TblMapMtx; ///< For HostPtrToTableMap

   // Store target policy (disabled, mandatory, default)
   kmp_target_offload_kind_t TargetOffloadPolicy = tgt_default;
   std::mutex TargetOffloadMtx; ///< For TargetOffloadPolicy
 };

 extern PluginManager *PM;

 #endif
	//===----------- device.h - Target independent OpenMP target RTL ----------===//
	//
	// 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
	//
	//===----------------------------------------------------------------------===//
	//
	// Declarations for managing devices that are handled by RTL plugins.
	//
	//===----------------------------------------------------------------------===//

	#ifndef _OMPTARGET_DEVICE_H
	#define _OMPTARGET_DEVICE_H

	#include <cassert>
	#include <cstddef>
	#include <list>
	#include <map>
	#include <memory>
	#include <mutex>
	#include <set>
	#include <vector>

	#include "omptarget.h"
	#include "rtl.h"

	// Forward declarations.
	struct RTLInfoTy;
	struct __tgt_bin_desc;
	struct __tgt_target_table;

	using map_var_info_t = void *;

	// enum for OMP_TARGET_OFFLOAD; keep in sync with kmp.h definition
	enum kmp_target_offload_kind {
	tgt_disabled = 0,
	tgt_default = 1,
	tgt_mandatory = 2
	};
	typedef enum kmp_target_offload_kind kmp_target_offload_kind_t;

	/// Map between host data and target data.
	struct HostDataToTargetTy {
	const uintptr_t HstPtrBase; // host info.
	const uintptr_t HstPtrBegin;
	const uintptr_t HstPtrEnd; // non-inclusive.
	const map_var_info_t HstPtrName; // Optional source name of mapped variable.

	const uintptr_t TgtPtrBegin; // target info.

	private:
	static const uint64_t INFRefCount = ~(uint64_t)0;
	static std::string refCountToStr(uint64_t RefCount) {
	return RefCount == INFRefCount ? "INF" : std::to_string(RefCount);
	}

	struct StatesTy {
	StatesTy(uint64_t DRC, uint64_t HRC)
	: DynRefCount(DRC), HoldRefCount(HRC) {}
	/// The dynamic reference count is the standard reference count as of OpenMP
	/// 4.5. The hold reference count is an OpenMP extension for the sake of
	/// OpenACC support.
	///
	/// The 'ompx_hold' map type modifier is permitted only on "omp target" and
	/// "omp target data", and "delete" is permitted only on "omp target exit
	/// data" and associated runtime library routines. As a result, we really
	/// need to implement "reset" functionality only for the dynamic reference
	/// counter. Likewise, only the dynamic reference count can be infinite
	/// because, for example, omp_target_associate_ptr and "omp declare target
	/// link" operate only on it. Nevertheless, it's actually easier to follow
	/// the code (and requires less assertions for special cases) when we just
	/// implement these features generally across both reference counters here.
	/// Thus, it's the users of this class that impose those restrictions.
	///
	uint64_t DynRefCount;
	uint64_t HoldRefCount;
	/// This mutex will be locked when data movement is issued. For targets that
	/// doesn't support async data movement, this mutex can guarantee that after
	/// it is released, memory region on the target is update to date. For
	/// targets that support async data movement, this can guarantee that data
	/// movement has been issued. This mutex must be locked right before
	/// releasing the mapping table lock.
	std::mutex UpdateMtx;
	};
	// When HostDataToTargetTy is used by std::set, std::set::iterator is const
	// use unique_ptr to make States mutable.
	const std::unique_ptr<StatesTy> States;

	public:
	HostDataToTargetTy(uintptr_t BP, uintptr_t B, uintptr_t E, uintptr_t TB,
	bool UseHoldRefCount, map_var_info_t Name = nullptr,
	bool IsINF = false)
	: HstPtrBase(BP), HstPtrBegin(B), HstPtrEnd(E), HstPtrName(Name),
	TgtPtrBegin(TB), States(std::make_unique<StatesTy>(UseHoldRefCount ? 0
	: IsINF ? INFRefCount
	: 1,
	!UseHoldRefCount ? 0
	: IsINF ? INFRefCount
	: 1)) {}

	/// Get the total reference count. This is smarter than just getDynRefCount()
	/// + getHoldRefCount() because it handles the case where at least one is
	/// infinity and the other is non-zero.
	uint64_t getTotalRefCount() const {
	if (States->DynRefCount == INFRefCount \|\|
	States->HoldRefCount == INFRefCount)
	return INFRefCount;
	return States->DynRefCount + States->HoldRefCount;
	}

	/// Get the dynamic reference count.
	uint64_t getDynRefCount() const { return States->DynRefCount; }

	/// Get the hold reference count.
	uint64_t getHoldRefCount() const { return States->HoldRefCount; }

	/// Reset the specified reference count unless it's infinity. Reset to 1
	/// (even if currently 0) so it can be followed by a decrement.
	void resetRefCount(bool UseHoldRefCount) const {
	uint64_t &ThisRefCount =
	UseHoldRefCount ? States->HoldRefCount : States->DynRefCount;
	if (ThisRefCount != INFRefCount)
	ThisRefCount = 1;
	}

	/// Increment the specified reference count unless it's infinity.
	void incRefCount(bool UseHoldRefCount) const {
	uint64_t &ThisRefCount =
	UseHoldRefCount ? States->HoldRefCount : States->DynRefCount;
	if (ThisRefCount != INFRefCount) {
	++ThisRefCount;
	assert(ThisRefCount < INFRefCount && "refcount overflow");
	}
	}

	/// Decrement the specified reference count unless it's infinity or zero, and
	/// return the total reference count.
	uint64_t decRefCount(bool UseHoldRefCount) const {
	uint64_t &ThisRefCount =
	UseHoldRefCount ? States->HoldRefCount : States->DynRefCount;
	uint64_t OtherRefCount =
	UseHoldRefCount ? States->DynRefCount : States->HoldRefCount;
	(void)OtherRefCount;
	if (ThisRefCount != INFRefCount) {
	if (ThisRefCount > 0)
	--ThisRefCount;
	else
	assert(OtherRefCount > 0 && "total refcount underflow");
	}
	return getTotalRefCount();
	}

	/// Is the dynamic (and thus the total) reference count infinite?
	bool isDynRefCountInf() const { return States->DynRefCount == INFRefCount; }

	/// Convert the dynamic reference count to a debug string.
	std::string dynRefCountToStr() const {
	return refCountToStr(States->DynRefCount);
	}

	/// Convert the hold reference count to a debug string.
	std::string holdRefCountToStr() const {
	return refCountToStr(States->HoldRefCount);
	}

	/// Should one decrement of the specified reference count (after resetting it
	/// if \c AfterReset) remove this mapping?
	bool decShouldRemove(bool UseHoldRefCount, bool AfterReset = false) const {
	uint64_t ThisRefCount =
	UseHoldRefCount ? States->HoldRefCount : States->DynRefCount;
	uint64_t OtherRefCount =
	UseHoldRefCount ? States->DynRefCount : States->HoldRefCount;
	if (OtherRefCount > 0)
	return false;
	if (AfterReset)
	return ThisRefCount != INFRefCount;
	return ThisRefCount == 1;
	}

	void lock() const { States->UpdateMtx.lock(); }

	void unlock() const { States->UpdateMtx.unlock(); }
	};

	typedef uintptr_t HstPtrBeginTy;
	inline bool operator<(const HostDataToTargetTy &lhs, const HstPtrBeginTy &rhs) {
	return lhs.HstPtrBegin < rhs;
	}
	inline bool operator<(const HstPtrBeginTy &lhs, const HostDataToTargetTy &rhs) {
	return lhs < rhs.HstPtrBegin;
	}
	inline bool operator<(const HostDataToTargetTy &lhs,
	const HostDataToTargetTy &rhs) {
	return lhs.HstPtrBegin < rhs.HstPtrBegin;
	}

	typedef std::set<HostDataToTargetTy, std::less<>> HostDataToTargetListTy;

	struct LookupResult {
	struct {
	unsigned IsContained : 1;
	unsigned ExtendsBefore : 1;
	unsigned ExtendsAfter : 1;
	} Flags;

	HostDataToTargetListTy::iterator Entry;

	LookupResult() : Flags({0, 0, 0}), Entry() {}
	};

	/// This struct will be returned by \p DeviceTy::getTargetPointer which provides
	/// more data than just a target pointer.
	struct TargetPointerResultTy {
	struct {
	/// If the map table entry is just created
	unsigned IsNewEntry : 1;
	/// If the pointer is actually a host pointer (when unified memory enabled)
	unsigned IsHostPointer : 1;
	} Flags = {0, 0};

	/// The iterator to the corresponding map table entry
	HostDataToTargetListTy::iterator MapTableEntry{};

	/// The corresponding target pointer
	void *TargetPointer = nullptr;
	};

	/// Map for shadow pointers
	struct ShadowPtrValTy {
	void *HstPtrVal;
	void *TgtPtrAddr;
	void *TgtPtrVal;
	};
	typedef std::map<void *, ShadowPtrValTy> ShadowPtrListTy;

	///
	struct PendingCtorDtorListsTy {
	std::list<void *> PendingCtors;
	std::list<void *> PendingDtors;
	};
	typedef std::map<__tgt_bin_desc *, PendingCtorDtorListsTy>
	PendingCtorsDtorsPerLibrary;

	struct DeviceTy {
	int32_t DeviceID;
	RTLInfoTy *RTL;
	int32_t RTLDeviceID;

	bool IsInit;
	std::once_flag InitFlag;
	bool HasPendingGlobals;

	HostDataToTargetListTy HostDataToTargetMap;
	PendingCtorsDtorsPerLibrary PendingCtorsDtors;

	ShadowPtrListTy ShadowPtrMap;

	std::mutex DataMapMtx, PendingGlobalsMtx, ShadowMtx;

	// NOTE: Once libomp gains full target-task support, this state should be
	// moved into the target task in libomp.
	std::map<int32_t, uint64_t> LoopTripCnt;

	DeviceTy(RTLInfoTy *RTL);
	// DeviceTy is not copyable
	DeviceTy(const DeviceTy &D) = delete;
	DeviceTy &operator=(const DeviceTy &D) = delete;

	~DeviceTy();

	// Return true if data can be copied to DstDevice directly
	bool isDataExchangable(const DeviceTy &DstDevice);

	LookupResult lookupMapping(void *HstPtrBegin, int64_t Size);
	/// Get the target pointer based on host pointer begin and base. If the
	/// mapping already exists, the target pointer will be returned directly. In
	/// addition, if required, the memory region pointed by \p HstPtrBegin of size
	/// \p Size will also be transferred to the device. If the mapping doesn't
	/// exist, and if unified shared memory is not enabled, a new mapping will be
	/// created and the data will also be transferred accordingly. nullptr will be
	/// returned because of any of following reasons:
	/// - Data allocation failed;
	/// - The user tried to do an illegal mapping;
	/// - Data transfer issue fails.
	TargetPointerResultTy
	getTargetPointer(void HstPtrBegin, void HstPtrBase, int64_t Size,
	map_var_info_t HstPtrName, bool HasFlagTo,
	bool HasFlagAlways, bool IsImplicit, bool UpdateRefCount,
	bool HasCloseModifier, bool HasPresentModifier,
	bool HasHoldModifier, AsyncInfoTy &AsyncInfo);
	void getTgtPtrBegin(void HstPtrBegin, int64_t Size);
	void getTgtPtrBegin(void HstPtrBegin, int64_t Size, bool &IsLast,
	bool UpdateRefCount, bool UseHoldRefCount,
	bool &IsHostPtr, bool MustContain = false,
	bool ForceDelete = false);
	/// For the map entry for \p HstPtrBegin, decrement the reference count
	/// specified by \p HasHoldModifier and, if the the total reference count is
	/// then zero, deallocate the corresponding device storage and remove the map
	/// entry. Return \c OFFLOAD_SUCCESS if the map entry existed, and return
	/// \c OFFLOAD_FAIL if not. It is the caller's responsibility to skip calling
	/// this function if the map entry is not expected to exist because
	/// \p HstPtrBegin uses shared memory.
	int deallocTgtPtr(void *HstPtrBegin, int64_t Size, bool HasHoldModifier);
	int associatePtr(void HstPtrBegin, void TgtPtrBegin, int64_t Size);
	int disassociatePtr(void *HstPtrBegin);

	// calls to RTL
	int32_t initOnce();
	__tgt_target_table load_binary(void Img);

	// device memory allocation/deallocation routines
	/// Allocates \p Size bytes on the device, host or shared memory space
	/// (depending on \p Kind) and returns the address/nullptr when
	/// succeeds/fails. \p HstPtr is an address of the host data which the
	/// allocated target data will be associated with. If it is unknown, the
	/// default value of \p HstPtr is nullptr. Note: this function doesn't do
	/// pointer association. Actually, all the __tgt_rtl_data_alloc
	/// implementations ignore \p HstPtr. \p Kind dictates what allocator should
	/// be used (host, shared, device).
	void allocData(int64_t Size, void HstPtr = nullptr,
	int32_t Kind = TARGET_ALLOC_DEFAULT);
	/// Deallocates memory which \p TgtPtrBegin points at and returns
	/// OFFLOAD_SUCCESS/OFFLOAD_FAIL when succeeds/fails.
	int32_t deleteData(void *TgtPtrBegin);

	// Data transfer. When AsyncInfo is nullptr, the transfer will be
	// synchronous.
	// Copy data from host to device
	int32_t submitData(void TgtPtrBegin, void HstPtrBegin, int64_t Size,
	AsyncInfoTy &AsyncInfo);
	// Copy data from device back to host
	int32_t retrieveData(void HstPtrBegin, void TgtPtrBegin, int64_t Size,
	AsyncInfoTy &AsyncInfo);
	// Copy data from current device to destination device directly
	int32_t dataExchange(void SrcPtr, DeviceTy &DstDev, void DstPtr,
	int64_t Size, AsyncInfoTy &AsyncInfo);

	int32_t runRegion(void TgtEntryPtr, void TgtVarsPtr, ptrdiff_t TgtOffsets,
	int32_t TgtVarsSize, AsyncInfoTy &AsyncInfo);
	int32_t runTeamRegion(void TgtEntryPtr, void *TgtVarsPtr,
	ptrdiff_t *TgtOffsets, int32_t TgtVarsSize,
	int32_t NumTeams, int32_t ThreadLimit,
	uint64_t LoopTripCount, AsyncInfoTy &AsyncInfo);

	/// Synchronize device/queue/event based on \p AsyncInfo and return
	/// OFFLOAD_SUCCESS/OFFLOAD_FAIL when succeeds/fails.
	int32_t synchronize(AsyncInfoTy &AsyncInfo);

	/// Calls the corresponding print in the \p RTLDEVID
	/// device RTL to obtain the information of the specific device.
	bool printDeviceInfo(int32_t RTLDevID);

	/// Event related interfaces.
	/// {
	/// Create an event.
	int32_t createEvent(void **Event);

	/// Record the event based on status in AsyncInfo->Queue at the moment the
	/// function is called.
	int32_t recordEvent(void *Event, AsyncInfoTy &AsyncInfo);

	/// Wait for an event. This function can be blocking or non-blocking,
	/// depending on the implmentation. It is expected to set a dependence on the
	/// event such that corresponding operations shall only start once the event
	/// is fulfilled.
	int32_t waitEvent(void *Event, AsyncInfoTy &AsyncInfo);

	/// Synchronize the event. It is expected to block the thread.
	int32_t syncEvent(void *Event);

	/// Destroy the event.
	int32_t destroyEvent(void *Event);
	/// }

	private:
	// Call to RTL
	void init(); // To be called only via DeviceTy::initOnce()
	};

	extern bool device_is_ready(int device_num);

	/// Struct for the data required to handle plugins
	struct PluginManager {
	/// RTLs identified on the host
	RTLsTy RTLs;

	/// Devices associated with RTLs
	std::vector<std::unique_ptr<DeviceTy>> Devices;
	std::mutex RTLsMtx; ///< For RTLs and Devices

	/// Translation table retreived from the binary
	HostEntriesBeginToTransTableTy HostEntriesBeginToTransTable;
	std::mutex TrlTblMtx; ///< For Translation Table
	/// Host offload entries in order of image registration
	std::vector<__tgt_offload_entry *> HostEntriesBeginRegistrationOrder;

	/// Map from ptrs on the host to an entry in the Translation Table
	HostPtrToTableMapTy HostPtrToTableMap;
	std::mutex TblMapMtx; ///< For HostPtrToTableMap

	// Store target policy (disabled, mandatory, default)
	kmp_target_offload_kind_t TargetOffloadPolicy = tgt_default;
	std::mutex TargetOffloadMtx; ///< For TargetOffloadPolicy
	};

	extern PluginManager *PM;

	#endif