//===------ omptarget.cpp - Target independent OpenMP target RTL -- C++ -*-===// // // The LLVM Compiler Infrastructure // // This file is dual licensed under the MIT and the University of Illinois Open // Source Licenses. See LICENSE.txt for details. // //===----------------------------------------------------------------------===// // // Implementation of the interface to be used by Clang during the codegen of a // target region. // //===----------------------------------------------------------------------===// #include #include #include #include #include #include #include #include #include #include #include // Header file global to this project #include "omptarget.h" #define DP(...) DEBUGP("Libomptarget", __VA_ARGS__) #define INF_REF_CNT (LONG_MAX>>1) // leave room for additions/subtractions #define CONSIDERED_INF(x) (x > (INF_REF_CNT>>1)) // List of all plugins that can support offloading. static const char *RTLNames[] = { /* PowerPC target */ "libomptarget.rtl.ppc64.so", /* x86_64 target */ "libomptarget.rtl.x86_64.so", /* CUDA target */ "libomptarget.rtl.cuda.so", /* AArch64 target */ "libomptarget.rtl.aarch64.so"}; // forward declarations struct RTLInfoTy; static int target(int32_t device_id, void *host_ptr, int32_t arg_num, void **args_base, void **args, int64_t *arg_sizes, int64_t *arg_types, int32_t team_num, int32_t thread_limit, int IsTeamConstruct); /// Map between host data and target data. struct HostDataToTargetTy { uintptr_t HstPtrBase; // host info. uintptr_t HstPtrBegin; uintptr_t HstPtrEnd; // non-inclusive. uintptr_t TgtPtrBegin; // target info. long RefCount; HostDataToTargetTy() : HstPtrBase(0), HstPtrBegin(0), HstPtrEnd(0), TgtPtrBegin(0), RefCount(0) {} HostDataToTargetTy(uintptr_t BP, uintptr_t B, uintptr_t E, uintptr_t TB) : HstPtrBase(BP), HstPtrBegin(B), HstPtrEnd(E), TgtPtrBegin(TB), RefCount(1) {} HostDataToTargetTy(uintptr_t BP, uintptr_t B, uintptr_t E, uintptr_t TB, long RF) : HstPtrBase(BP), HstPtrBegin(B), HstPtrEnd(E), TgtPtrBegin(TB), RefCount(RF) {} }; typedef std::list HostDataToTargetListTy; struct LookupResult { struct { unsigned IsContained : 1; unsigned ExtendsBefore : 1; unsigned ExtendsAfter : 1; } Flags; HostDataToTargetListTy::iterator Entry; LookupResult() : Flags({0,0,0}), Entry() {} }; /// Map for shadow pointers struct ShadowPtrValTy { void *HstPtrVal; void *TgtPtrAddr; void *TgtPtrVal; }; typedef std::map ShadowPtrListTy; /// struct PendingCtorDtorListsTy { std::list PendingCtors; std::list 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; uint64_t loopTripCnt; DeviceTy(RTLInfoTy *RTL) : DeviceID(-1), RTL(RTL), RTLDeviceID(-1), IsInit(false), InitFlag(), HasPendingGlobals(false), HostDataToTargetMap(), PendingCtorsDtors(), ShadowPtrMap(), DataMapMtx(), PendingGlobalsMtx(), ShadowMtx(), loopTripCnt(0) {} // The existence of mutexes makes DeviceTy non-copyable. We need to // provide a copy constructor and an assignment operator explicitly. DeviceTy(const DeviceTy &d) : DeviceID(d.DeviceID), RTL(d.RTL), RTLDeviceID(d.RTLDeviceID), IsInit(d.IsInit), InitFlag(), HasPendingGlobals(d.HasPendingGlobals), HostDataToTargetMap(d.HostDataToTargetMap), PendingCtorsDtors(d.PendingCtorsDtors), ShadowPtrMap(d.ShadowPtrMap), DataMapMtx(), PendingGlobalsMtx(), ShadowMtx(), loopTripCnt(d.loopTripCnt) {} DeviceTy& operator=(const DeviceTy &d) { DeviceID = d.DeviceID; RTL = d.RTL; RTLDeviceID = d.RTLDeviceID; IsInit = d.IsInit; HasPendingGlobals = d.HasPendingGlobals; HostDataToTargetMap = d.HostDataToTargetMap; PendingCtorsDtors = d.PendingCtorsDtors; ShadowPtrMap = d.ShadowPtrMap; loopTripCnt = d.loopTripCnt; return *this; } long getMapEntryRefCnt(void *HstPtrBegin); LookupResult lookupMapping(void *HstPtrBegin, int64_t Size); void *getOrAllocTgtPtr(void *HstPtrBegin, void *HstPtrBase, int64_t Size, bool &IsNew, bool IsImplicit, bool UpdateRefCount = true); void *getTgtPtrBegin(void *HstPtrBegin, int64_t Size); void *getTgtPtrBegin(void *HstPtrBegin, int64_t Size, bool &IsLast, bool UpdateRefCount); int deallocTgtPtr(void *TgtPtrBegin, int64_t Size, bool ForceDelete); 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); int32_t data_submit(void *TgtPtrBegin, void *HstPtrBegin, int64_t Size); int32_t data_retrieve(void *HstPtrBegin, void *TgtPtrBegin, int64_t Size); int32_t run_region(void *TgtEntryPtr, void **TgtVarsPtr, ptrdiff_t *TgtOffsets, int32_t TgtVarsSize); int32_t run_team_region(void *TgtEntryPtr, void **TgtVarsPtr, ptrdiff_t *TgtOffsets, int32_t TgtVarsSize, int32_t NumTeams, int32_t ThreadLimit, uint64_t LoopTripCount); private: // Call to RTL void init(); // To be called only via DeviceTy::initOnce() }; /// Map between Device ID (i.e. openmp device id) and its DeviceTy. typedef std::vector DevicesTy; static DevicesTy Devices; struct RTLInfoTy { typedef int32_t(is_valid_binary_ty)(void *); typedef int32_t(number_of_devices_ty)(); typedef int32_t(init_device_ty)(int32_t); typedef __tgt_target_table *(load_binary_ty)(int32_t, void *); typedef void *(data_alloc_ty)(int32_t, int64_t, void *); typedef int32_t(data_submit_ty)(int32_t, void *, void *, int64_t); typedef int32_t(data_retrieve_ty)(int32_t, void *, void *, int64_t); typedef int32_t(data_delete_ty)(int32_t, void *); typedef int32_t(run_region_ty)(int32_t, void *, void **, ptrdiff_t *, int32_t); typedef int32_t(run_team_region_ty)(int32_t, void *, void **, ptrdiff_t *, int32_t, int32_t, int32_t, uint64_t); int32_t Idx; // RTL index, index is the number of devices // of other RTLs that were registered before, // i.e. the OpenMP index of the first device // to be registered with this RTL. int32_t NumberOfDevices; // Number of devices this RTL deals with. std::vector Devices; // one per device (NumberOfDevices in total). void *LibraryHandler; #ifdef OMPTARGET_DEBUG std::string RTLName; #endif // Functions implemented in the RTL. is_valid_binary_ty *is_valid_binary; number_of_devices_ty *number_of_devices; init_device_ty *init_device; load_binary_ty *load_binary; data_alloc_ty *data_alloc; data_submit_ty *data_submit; data_retrieve_ty *data_retrieve; data_delete_ty *data_delete; run_region_ty *run_region; run_team_region_ty *run_team_region; // Are there images associated with this RTL. bool isUsed; // Mutex for thread-safety when calling RTL interface functions. // It is easier to enforce thread-safety at the libomptarget level, // so that developers of new RTLs do not have to worry about it. std::mutex Mtx; // The existence of the mutex above makes RTLInfoTy non-copyable. // We need to provide a copy constructor explicitly. RTLInfoTy() : Idx(-1), NumberOfDevices(-1), Devices(), LibraryHandler(0), #ifdef OMPTARGET_DEBUG RTLName(), #endif is_valid_binary(0), number_of_devices(0), init_device(0), load_binary(0), data_alloc(0), data_submit(0), data_retrieve(0), data_delete(0), run_region(0), run_team_region(0), isUsed(false), Mtx() {} RTLInfoTy(const RTLInfoTy &r) : Mtx() { Idx = r.Idx; NumberOfDevices = r.NumberOfDevices; Devices = r.Devices; LibraryHandler = r.LibraryHandler; #ifdef OMPTARGET_DEBUG RTLName = r.RTLName; #endif is_valid_binary = r.is_valid_binary; number_of_devices = r.number_of_devices; init_device = r.init_device; load_binary = r.load_binary; data_alloc = r.data_alloc; data_submit = r.data_submit; data_retrieve = r.data_retrieve; data_delete = r.data_delete; run_region = r.run_region; run_team_region = r.run_team_region; isUsed = r.isUsed; } }; /// RTLs identified in the system. class RTLsTy { private: // Mutex-like object to guarantee thread-safety and unique initialization // (i.e. the library attempts to load the RTLs (plugins) only once). std::once_flag initFlag; void LoadRTLs(); // not thread-safe public: // List of the detected runtime libraries. std::list AllRTLs; // Array of pointers to the detected runtime libraries that have compatible // binaries. std::vector UsedRTLs; explicit RTLsTy() {} // Load all the runtime libraries (plugins) if not done before. void LoadRTLsOnce(); }; void RTLsTy::LoadRTLs() { // Parse environment variable OMP_TARGET_OFFLOAD (if set) char *envStr = getenv("OMP_TARGET_OFFLOAD"); if (envStr && !strcmp(envStr, "DISABLED")) { DP("Target offloading disabled by environment\n"); return; } DP("Loading RTLs...\n"); // Attempt to open all the plugins and, if they exist, check if the interface // is correct and if they are supporting any devices. for (auto *Name : RTLNames) { DP("Loading library '%s'...\n", Name); void *dynlib_handle = dlopen(Name, RTLD_NOW); if (!dynlib_handle) { // Library does not exist or cannot be found. DP("Unable to load library '%s': %s!\n", Name, dlerror()); continue; } DP("Successfully loaded library '%s'!\n", Name); // Retrieve the RTL information from the runtime library. RTLInfoTy R; R.LibraryHandler = dynlib_handle; R.isUsed = false; #ifdef OMPTARGET_DEBUG R.RTLName = Name; #endif if (!(*((void**) &R.is_valid_binary) = dlsym( dynlib_handle, "__tgt_rtl_is_valid_binary"))) continue; if (!(*((void**) &R.number_of_devices) = dlsym( dynlib_handle, "__tgt_rtl_number_of_devices"))) continue; if (!(*((void**) &R.init_device) = dlsym( dynlib_handle, "__tgt_rtl_init_device"))) continue; if (!(*((void**) &R.load_binary) = dlsym( dynlib_handle, "__tgt_rtl_load_binary"))) continue; if (!(*((void**) &R.data_alloc) = dlsym( dynlib_handle, "__tgt_rtl_data_alloc"))) continue; if (!(*((void**) &R.data_submit) = dlsym( dynlib_handle, "__tgt_rtl_data_submit"))) continue; if (!(*((void**) &R.data_retrieve) = dlsym( dynlib_handle, "__tgt_rtl_data_retrieve"))) continue; if (!(*((void**) &R.data_delete) = dlsym( dynlib_handle, "__tgt_rtl_data_delete"))) continue; if (!(*((void**) &R.run_region) = dlsym( dynlib_handle, "__tgt_rtl_run_target_region"))) continue; if (!(*((void**) &R.run_team_region) = dlsym( dynlib_handle, "__tgt_rtl_run_target_team_region"))) continue; // No devices are supported by this RTL? if (!(R.NumberOfDevices = R.number_of_devices())) { DP("No devices supported in this RTL\n"); continue; } DP("Registering RTL %s supporting %d devices!\n", R.RTLName.c_str(), R.NumberOfDevices); // The RTL is valid! Will save the information in the RTLs list. AllRTLs.push_back(R); } DP("RTLs loaded!\n"); return; } void RTLsTy::LoadRTLsOnce() { // RTL.LoadRTLs() is called only once in a thread-safe fashion. std::call_once(initFlag, &RTLsTy::LoadRTLs, this); } static RTLsTy RTLs; static std::mutex RTLsMtx; /// Map between the host entry begin and the translation table. Each /// registered library gets one TranslationTable. Use the map from /// __tgt_offload_entry so that we may quickly determine whether we /// are trying to (re)register an existing lib or really have a new one. struct TranslationTable { __tgt_target_table HostTable; // Image assigned to a given device. std::vector<__tgt_device_image *> TargetsImages; // One image per device ID. // Table of entry points or NULL if it was not already computed. std::vector<__tgt_target_table *> TargetsTable; // One table per device ID. }; typedef std::map<__tgt_offload_entry *, TranslationTable> HostEntriesBeginToTransTableTy; static HostEntriesBeginToTransTableTy HostEntriesBeginToTransTable; static std::mutex TrlTblMtx; /// Map between the host ptr and a table index struct TableMap { TranslationTable *Table; // table associated with the host ptr. uint32_t Index; // index in which the host ptr translated entry is found. TableMap() : Table(0), Index(0) {} TableMap(TranslationTable *table, uint32_t index) : Table(table), Index(index) {} }; typedef std::map HostPtrToTableMapTy; static HostPtrToTableMapTy HostPtrToTableMap; static std::mutex TblMapMtx; /// Check whether a device has an associated RTL and initialize it if it's not /// already initialized. static bool device_is_ready(int device_num) { DP("Checking whether device %d is ready.\n", device_num); // Devices.size() can only change while registering a new // library, so try to acquire the lock of RTLs' mutex. RTLsMtx.lock(); size_t Devices_size = Devices.size(); RTLsMtx.unlock(); if (Devices_size <= (size_t)device_num) { DP("Device ID %d does not have a matching RTL\n", device_num); return false; } // Get device info DeviceTy &Device = Devices[device_num]; DP("Is the device %d (local ID %d) initialized? %d\n", device_num, Device.RTLDeviceID, Device.IsInit); // Init the device if not done before if (!Device.IsInit && Device.initOnce() != OFFLOAD_SUCCESS) { DP("Failed to init device %d\n", device_num); return false; } DP("Device %d is ready to use.\n", device_num); return true; } //////////////////////////////////////////////////////////////////////////////// // Target API functions // EXTERN int omp_get_num_devices(void) { RTLsMtx.lock(); size_t Devices_size = Devices.size(); RTLsMtx.unlock(); DP("Call to omp_get_num_devices returning %zd\n", Devices_size); return Devices_size; } EXTERN int omp_get_initial_device(void) { DP("Call to omp_get_initial_device returning %d\n", HOST_DEVICE); return HOST_DEVICE; } EXTERN void *omp_target_alloc(size_t size, int device_num) { DP("Call to omp_target_alloc for device %d requesting %zu bytes\n", device_num, size); if (size <= 0) { DP("Call to omp_target_alloc with non-positive length\n"); return NULL; } void *rc = NULL; if (device_num == omp_get_initial_device()) { rc = malloc(size); DP("omp_target_alloc returns host ptr " DPxMOD "\n", DPxPTR(rc)); return rc; } if (!device_is_ready(device_num)) { DP("omp_target_alloc returns NULL ptr\n"); return NULL; } DeviceTy &Device = Devices[device_num]; rc = Device.RTL->data_alloc(Device.RTLDeviceID, size, NULL); DP("omp_target_alloc returns device ptr " DPxMOD "\n", DPxPTR(rc)); return rc; } EXTERN void omp_target_free(void *device_ptr, int device_num) { DP("Call to omp_target_free for device %d and address " DPxMOD "\n", device_num, DPxPTR(device_ptr)); if (!device_ptr) { DP("Call to omp_target_free with NULL ptr\n"); return; } if (device_num == omp_get_initial_device()) { free(device_ptr); DP("omp_target_free deallocated host ptr\n"); return; } if (!device_is_ready(device_num)) { DP("omp_target_free returns, nothing to do\n"); return; } DeviceTy &Device = Devices[device_num]; Device.RTL->data_delete(Device.RTLDeviceID, (void *)device_ptr); DP("omp_target_free deallocated device ptr\n"); } EXTERN int omp_target_is_present(void *ptr, int device_num) { DP("Call to omp_target_is_present for device %d and address " DPxMOD "\n", device_num, DPxPTR(ptr)); if (!ptr) { DP("Call to omp_target_is_present with NULL ptr, returning false\n"); return false; } if (device_num == omp_get_initial_device()) { DP("Call to omp_target_is_present on host, returning true\n"); return true; } RTLsMtx.lock(); size_t Devices_size = Devices.size(); RTLsMtx.unlock(); if (Devices_size <= (size_t)device_num) { DP("Call to omp_target_is_present with invalid device ID, returning " "false\n"); return false; } DeviceTy& Device = Devices[device_num]; bool IsLast; // not used int rc = (Device.getTgtPtrBegin(ptr, 0, IsLast, false) != NULL); DP("Call to omp_target_is_present returns %d\n", rc); return rc; } EXTERN int omp_target_memcpy(void *dst, void *src, size_t length, size_t dst_offset, size_t src_offset, int dst_device, int src_device) { DP("Call to omp_target_memcpy, dst device %d, src device %d, " "dst addr " DPxMOD ", src addr " DPxMOD ", dst offset %zu, " "src offset %zu, length %zu\n", dst_device, src_device, DPxPTR(dst), DPxPTR(src), dst_offset, src_offset, length); if (!dst || !src || length <= 0) { DP("Call to omp_target_memcpy with invalid arguments\n"); return OFFLOAD_FAIL; } if (src_device != omp_get_initial_device() && !device_is_ready(src_device)) { DP("omp_target_memcpy returns OFFLOAD_FAIL\n"); return OFFLOAD_FAIL; } if (dst_device != omp_get_initial_device() && !device_is_ready(dst_device)) { DP("omp_target_memcpy returns OFFLOAD_FAIL\n"); return OFFLOAD_FAIL; } int rc = OFFLOAD_SUCCESS; void *srcAddr = (char *)src + src_offset; void *dstAddr = (char *)dst + dst_offset; if (src_device == omp_get_initial_device() && dst_device == omp_get_initial_device()) { DP("copy from host to host\n"); const void *p = memcpy(dstAddr, srcAddr, length); if (p == NULL) rc = OFFLOAD_FAIL; } else if (src_device == omp_get_initial_device()) { DP("copy from host to device\n"); DeviceTy& DstDev = Devices[dst_device]; rc = DstDev.data_submit(dstAddr, srcAddr, length); } else if (dst_device == omp_get_initial_device()) { DP("copy from device to host\n"); DeviceTy& SrcDev = Devices[src_device]; rc = SrcDev.data_retrieve(dstAddr, srcAddr, length); } else { DP("copy from device to device\n"); void *buffer = malloc(length); DeviceTy& SrcDev = Devices[src_device]; DeviceTy& DstDev = Devices[dst_device]; rc = SrcDev.data_retrieve(buffer, srcAddr, length); if (rc == OFFLOAD_SUCCESS) rc = DstDev.data_submit(dstAddr, buffer, length); } DP("omp_target_memcpy returns %d\n", rc); return rc; } EXTERN int omp_target_memcpy_rect(void *dst, void *src, size_t element_size, int num_dims, const size_t *volume, const size_t *dst_offsets, const size_t *src_offsets, const size_t *dst_dimensions, const size_t *src_dimensions, int dst_device, int src_device) { DP("Call to omp_target_memcpy_rect, dst device %d, src device %d, " "dst addr " DPxMOD ", src addr " DPxMOD ", dst offsets " DPxMOD ", " "src offsets " DPxMOD ", dst dims " DPxMOD ", src dims " DPxMOD ", " "volume " DPxMOD ", element size %zu, num_dims %d\n", dst_device, src_device, DPxPTR(dst), DPxPTR(src), DPxPTR(dst_offsets), DPxPTR(src_offsets), DPxPTR(dst_dimensions), DPxPTR(src_dimensions), DPxPTR(volume), element_size, num_dims); if (!(dst || src)) { DP("Call to omp_target_memcpy_rect returns max supported dimensions %d\n", INT_MAX); return INT_MAX; } if (!dst || !src || element_size < 1 || num_dims < 1 || !volume || !dst_offsets || !src_offsets || !dst_dimensions || !src_dimensions) { DP("Call to omp_target_memcpy_rect with invalid arguments\n"); return OFFLOAD_FAIL; } int rc; if (num_dims == 1) { rc = omp_target_memcpy(dst, src, element_size * volume[0], element_size * dst_offsets[0], element_size * src_offsets[0], dst_device, src_device); } else { size_t dst_slice_size = element_size; size_t src_slice_size = element_size; for (int i=1; iHstPtrBegin) { // Mapping exists if (CONSIDERED_INF(ii->RefCount)) { DP("Association found, removing it\n"); HostDataToTargetMap.erase(ii); DataMapMtx.unlock(); return OFFLOAD_SUCCESS; } else { DP("Trying to disassociate a pointer which was not mapped via " "omp_target_associate_ptr\n"); break; } } } // Mapping not found DataMapMtx.unlock(); DP("Association not found\n"); return OFFLOAD_FAIL; } // Get ref count of map entry containing HstPtrBegin long DeviceTy::getMapEntryRefCnt(void *HstPtrBegin) { uintptr_t hp = (uintptr_t)HstPtrBegin; long RefCnt = -1; DataMapMtx.lock(); for (auto &HT : HostDataToTargetMap) { if (hp >= HT.HstPtrBegin && hp < HT.HstPtrEnd) { DP("DeviceTy::getMapEntry: requested entry found\n"); RefCnt = HT.RefCount; break; } } DataMapMtx.unlock(); if (RefCnt < 0) { DP("DeviceTy::getMapEntry: requested entry not found\n"); } return RefCnt; } LookupResult DeviceTy::lookupMapping(void *HstPtrBegin, int64_t Size) { uintptr_t hp = (uintptr_t)HstPtrBegin; LookupResult lr; DP("Looking up mapping(HstPtrBegin=" DPxMOD ", Size=%ld)...\n", DPxPTR(hp), Size); for (lr.Entry = HostDataToTargetMap.begin(); lr.Entry != HostDataToTargetMap.end(); ++lr.Entry) { auto &HT = *lr.Entry; // Is it contained? lr.Flags.IsContained = hp >= HT.HstPtrBegin && hp < HT.HstPtrEnd && (hp+Size) <= HT.HstPtrEnd; // Does it extend into an already mapped region? lr.Flags.ExtendsBefore = hp < HT.HstPtrBegin && (hp+Size) > HT.HstPtrBegin; // Does it extend beyond the mapped region? lr.Flags.ExtendsAfter = hp < HT.HstPtrEnd && (hp+Size) > HT.HstPtrEnd; if (lr.Flags.IsContained || lr.Flags.ExtendsBefore || lr.Flags.ExtendsAfter) { break; } } if (lr.Flags.ExtendsBefore) { DP("WARNING: Pointer is not mapped but section extends into already " "mapped data\n"); } if (lr.Flags.ExtendsAfter) { DP("WARNING: Pointer is already mapped but section extends beyond mapped " "region\n"); } return lr; } // Used by target_data_begin // Return the target pointer begin (where the data will be moved). // Allocate memory if this is the first occurrence if this mapping. // Increment the reference counter. // If NULL is returned, then either data allocation failed or the user tried // to do an illegal mapping. void *DeviceTy::getOrAllocTgtPtr(void *HstPtrBegin, void *HstPtrBase, int64_t Size, bool &IsNew, bool IsImplicit, bool UpdateRefCount) { void *rc = NULL; DataMapMtx.lock(); LookupResult lr = lookupMapping(HstPtrBegin, Size); // Check if the pointer is contained. if (lr.Flags.IsContained || ((lr.Flags.ExtendsBefore || lr.Flags.ExtendsAfter) && IsImplicit)) { auto &HT = *lr.Entry; IsNew = false; if (UpdateRefCount) ++HT.RefCount; uintptr_t tp = HT.TgtPtrBegin + ((uintptr_t)HstPtrBegin - HT.HstPtrBegin); DP("Mapping exists%s with HstPtrBegin=" DPxMOD ", TgtPtrBegin=" DPxMOD ", " "Size=%ld,%s RefCount=%s\n", (IsImplicit ? " (implicit)" : ""), DPxPTR(HstPtrBegin), DPxPTR(tp), Size, (UpdateRefCount ? " updated" : ""), (CONSIDERED_INF(HT.RefCount)) ? "INF" : std::to_string(HT.RefCount).c_str()); rc = (void *)tp; } else if ((lr.Flags.ExtendsBefore || lr.Flags.ExtendsAfter) && !IsImplicit) { // Explicit extension of mapped data - not allowed. DP("Explicit extension of mapping is not allowed.\n"); } else if (Size) { // If it is not contained and Size > 0 we should create a new entry for it. IsNew = true; uintptr_t tp = (uintptr_t)RTL->data_alloc(RTLDeviceID, Size, HstPtrBegin); DP("Creating new map entry: HstBase=" DPxMOD ", HstBegin=" DPxMOD ", " "HstEnd=" DPxMOD ", TgtBegin=" DPxMOD "\n", DPxPTR(HstPtrBase), DPxPTR(HstPtrBegin), DPxPTR((uintptr_t)HstPtrBegin + Size), DPxPTR(tp)); HostDataToTargetMap.push_front(HostDataToTargetTy((uintptr_t)HstPtrBase, (uintptr_t)HstPtrBegin, (uintptr_t)HstPtrBegin + Size, tp)); rc = (void *)tp; } DataMapMtx.unlock(); return rc; } // Used by target_data_begin, target_data_end, target_data_update and target. // Return the target pointer begin (where the data will be moved). // Decrement the reference counter if called from target_data_end. void *DeviceTy::getTgtPtrBegin(void *HstPtrBegin, int64_t Size, bool &IsLast, bool UpdateRefCount) { void *rc = NULL; DataMapMtx.lock(); LookupResult lr = lookupMapping(HstPtrBegin, Size); if (lr.Flags.IsContained || lr.Flags.ExtendsBefore || lr.Flags.ExtendsAfter) { auto &HT = *lr.Entry; IsLast = !(HT.RefCount > 1); if (HT.RefCount > 1 && UpdateRefCount) --HT.RefCount; uintptr_t tp = HT.TgtPtrBegin + ((uintptr_t)HstPtrBegin - HT.HstPtrBegin); DP("Mapping exists with HstPtrBegin=" DPxMOD ", TgtPtrBegin=" DPxMOD ", " "Size=%ld,%s RefCount=%s\n", DPxPTR(HstPtrBegin), DPxPTR(tp), Size, (UpdateRefCount ? " updated" : ""), (CONSIDERED_INF(HT.RefCount)) ? "INF" : std::to_string(HT.RefCount).c_str()); rc = (void *)tp; } else { IsLast = false; } DataMapMtx.unlock(); return rc; } // Return the target pointer begin (where the data will be moved). // Lock-free version called when loading global symbols from the fat binary. void *DeviceTy::getTgtPtrBegin(void *HstPtrBegin, int64_t Size) { uintptr_t hp = (uintptr_t)HstPtrBegin; LookupResult lr = lookupMapping(HstPtrBegin, Size); if (lr.Flags.IsContained || lr.Flags.ExtendsBefore || lr.Flags.ExtendsAfter) { auto &HT = *lr.Entry; uintptr_t tp = HT.TgtPtrBegin + (hp - HT.HstPtrBegin); return (void *)tp; } return NULL; } int DeviceTy::deallocTgtPtr(void *HstPtrBegin, int64_t Size, bool ForceDelete) { // Check if the pointer is contained in any sub-nodes. int rc; DataMapMtx.lock(); LookupResult lr = lookupMapping(HstPtrBegin, Size); if (lr.Flags.IsContained || lr.Flags.ExtendsBefore || lr.Flags.ExtendsAfter) { auto &HT = *lr.Entry; if (ForceDelete) HT.RefCount = 1; if (--HT.RefCount <= 0) { assert(HT.RefCount == 0 && "did not expect a negative ref count"); DP("Deleting tgt data " DPxMOD " of size %ld\n", DPxPTR(HT.TgtPtrBegin), Size); RTL->data_delete(RTLDeviceID, (void *)HT.TgtPtrBegin); DP("Removing%s mapping with HstPtrBegin=" DPxMOD ", TgtPtrBegin=" DPxMOD ", Size=%ld\n", (ForceDelete ? " (forced)" : ""), DPxPTR(HT.HstPtrBegin), DPxPTR(HT.TgtPtrBegin), Size); HostDataToTargetMap.erase(lr.Entry); } rc = OFFLOAD_SUCCESS; } else { DP("Section to delete (hst addr " DPxMOD ") does not exist in the allocated" " memory\n", DPxPTR(HstPtrBegin)); rc = OFFLOAD_FAIL; } DataMapMtx.unlock(); return rc; } /// Init device, should not be called directly. void DeviceTy::init() { int32_t rc = RTL->init_device(RTLDeviceID); if (rc == OFFLOAD_SUCCESS) { IsInit = true; } } /// Thread-safe method to initialize the device only once. int32_t DeviceTy::initOnce() { std::call_once(InitFlag, &DeviceTy::init, this); // At this point, if IsInit is true, then either this thread or some other // thread in the past successfully initialized the device, so we can return // OFFLOAD_SUCCESS. If this thread executed init() via call_once() and it // failed, return OFFLOAD_FAIL. If call_once did not invoke init(), it means // that some other thread already attempted to execute init() and if IsInit // is still false, return OFFLOAD_FAIL. if (IsInit) return OFFLOAD_SUCCESS; else return OFFLOAD_FAIL; } // Load binary to device. __tgt_target_table *DeviceTy::load_binary(void *Img) { RTL->Mtx.lock(); __tgt_target_table *rc = RTL->load_binary(RTLDeviceID, Img); RTL->Mtx.unlock(); return rc; } // Submit data to device. int32_t DeviceTy::data_submit(void *TgtPtrBegin, void *HstPtrBegin, int64_t Size) { return RTL->data_submit(RTLDeviceID, TgtPtrBegin, HstPtrBegin, Size); } // Retrieve data from device. int32_t DeviceTy::data_retrieve(void *HstPtrBegin, void *TgtPtrBegin, int64_t Size) { return RTL->data_retrieve(RTLDeviceID, HstPtrBegin, TgtPtrBegin, Size); } // Run region on device int32_t DeviceTy::run_region(void *TgtEntryPtr, void **TgtVarsPtr, ptrdiff_t *TgtOffsets, int32_t TgtVarsSize) { return RTL->run_region(RTLDeviceID, TgtEntryPtr, TgtVarsPtr, TgtOffsets, TgtVarsSize); } // Run team region on device. int32_t DeviceTy::run_team_region(void *TgtEntryPtr, void **TgtVarsPtr, ptrdiff_t *TgtOffsets, int32_t TgtVarsSize, int32_t NumTeams, int32_t ThreadLimit, uint64_t LoopTripCount) { return RTL->run_team_region(RTLDeviceID, TgtEntryPtr, TgtVarsPtr, TgtOffsets, TgtVarsSize, NumTeams, ThreadLimit, LoopTripCount); } //////////////////////////////////////////////////////////////////////////////// // Functionality for registering libs static void RegisterImageIntoTranslationTable(TranslationTable &TT, RTLInfoTy &RTL, __tgt_device_image *image) { // same size, as when we increase one, we also increase the other. assert(TT.TargetsTable.size() == TT.TargetsImages.size() && "We should have as many images as we have tables!"); // Resize the Targets Table and Images to accommodate the new targets if // required unsigned TargetsTableMinimumSize = RTL.Idx + RTL.NumberOfDevices; if (TT.TargetsTable.size() < TargetsTableMinimumSize) { TT.TargetsImages.resize(TargetsTableMinimumSize, 0); TT.TargetsTable.resize(TargetsTableMinimumSize, 0); } // Register the image in all devices for this target type. for (int32_t i = 0; i < RTL.NumberOfDevices; ++i) { // If we are changing the image we are also invalidating the target table. if (TT.TargetsImages[RTL.Idx + i] != image) { TT.TargetsImages[RTL.Idx + i] = image; TT.TargetsTable[RTL.Idx + i] = 0; // lazy initialization of target table. } } } //////////////////////////////////////////////////////////////////////////////// // Functionality for registering Ctors/Dtors static void RegisterGlobalCtorsDtorsForImage(__tgt_bin_desc *desc, __tgt_device_image *img, RTLInfoTy *RTL) { for (int32_t i = 0; i < RTL->NumberOfDevices; ++i) { DeviceTy &Device = Devices[RTL->Idx + i]; Device.PendingGlobalsMtx.lock(); Device.HasPendingGlobals = true; for (__tgt_offload_entry *entry = img->EntriesBegin; entry != img->EntriesEnd; ++entry) { if (entry->flags & OMP_DECLARE_TARGET_CTOR) { DP("Adding ctor " DPxMOD " to the pending list.\n", DPxPTR(entry->addr)); Device.PendingCtorsDtors[desc].PendingCtors.push_back(entry->addr); } else if (entry->flags & OMP_DECLARE_TARGET_DTOR) { // Dtors are pushed in reverse order so they are executed from end // to beginning when unregistering the library! DP("Adding dtor " DPxMOD " to the pending list.\n", DPxPTR(entry->addr)); Device.PendingCtorsDtors[desc].PendingDtors.push_front(entry->addr); } if (entry->flags & OMP_DECLARE_TARGET_LINK) { DP("The \"link\" attribute is not yet supported!\n"); } } Device.PendingGlobalsMtx.unlock(); } } //////////////////////////////////////////////////////////////////////////////// /// adds a target shared library to the target execution image EXTERN void __tgt_register_lib(__tgt_bin_desc *desc) { // Attempt to load all plugins available in the system. RTLs.LoadRTLsOnce(); RTLsMtx.lock(); // Register the images with the RTLs that understand them, if any. for (int32_t i = 0; i < desc->NumDeviceImages; ++i) { // Obtain the image. __tgt_device_image *img = &desc->DeviceImages[i]; RTLInfoTy *FoundRTL = NULL; // Scan the RTLs that have associated images until we find one that supports // the current image. for (auto &R : RTLs.AllRTLs) { if (!R.is_valid_binary(img)) { DP("Image " DPxMOD " is NOT compatible with RTL %s!\n", DPxPTR(img->ImageStart), R.RTLName.c_str()); continue; } DP("Image " DPxMOD " is compatible with RTL %s!\n", DPxPTR(img->ImageStart), R.RTLName.c_str()); // If this RTL is not already in use, initialize it. if (!R.isUsed) { // Initialize the device information for the RTL we are about to use. DeviceTy device(&R); size_t start = Devices.size(); Devices.resize(start + R.NumberOfDevices, device); for (int32_t device_id = 0; device_id < R.NumberOfDevices; device_id++) { // global device ID Devices[start + device_id].DeviceID = start + device_id; // RTL local device ID Devices[start + device_id].RTLDeviceID = device_id; // Save pointer to device in RTL in case we want to unregister the RTL R.Devices.push_back(&Devices[start + device_id]); } // Initialize the index of this RTL and save it in the used RTLs. R.Idx = (RTLs.UsedRTLs.empty()) ? 0 : RTLs.UsedRTLs.back()->Idx + RTLs.UsedRTLs.back()->NumberOfDevices; assert((size_t) R.Idx == start && "RTL index should equal the number of devices used so far."); R.isUsed = true; RTLs.UsedRTLs.push_back(&R); DP("RTL " DPxMOD " has index %d!\n", DPxPTR(R.LibraryHandler), R.Idx); } // Initialize (if necessary) translation table for this library. TrlTblMtx.lock(); if(!HostEntriesBeginToTransTable.count(desc->HostEntriesBegin)){ TranslationTable &tt = HostEntriesBeginToTransTable[desc->HostEntriesBegin]; tt.HostTable.EntriesBegin = desc->HostEntriesBegin; tt.HostTable.EntriesEnd = desc->HostEntriesEnd; } // Retrieve translation table for this library. TranslationTable &TransTable = HostEntriesBeginToTransTable[desc->HostEntriesBegin]; DP("Registering image " DPxMOD " with RTL %s!\n", DPxPTR(img->ImageStart), R.RTLName.c_str()); RegisterImageIntoTranslationTable(TransTable, R, img); TrlTblMtx.unlock(); FoundRTL = &R; // Load ctors/dtors for static objects RegisterGlobalCtorsDtorsForImage(desc, img, FoundRTL); // if an RTL was found we are done - proceed to register the next image break; } if (!FoundRTL) { DP("No RTL found for image " DPxMOD "!\n", DPxPTR(img->ImageStart)); } } RTLsMtx.unlock(); DP("Done registering entries!\n"); } //////////////////////////////////////////////////////////////////////////////// /// unloads a target shared library EXTERN void __tgt_unregister_lib(__tgt_bin_desc *desc) { DP("Unloading target library!\n"); RTLsMtx.lock(); // Find which RTL understands each image, if any. for (int32_t i = 0; i < desc->NumDeviceImages; ++i) { // Obtain the image. __tgt_device_image *img = &desc->DeviceImages[i]; RTLInfoTy *FoundRTL = NULL; // Scan the RTLs that have associated images until we find one that supports // the current image. We only need to scan RTLs that are already being used. for (auto *R : RTLs.UsedRTLs) { assert(R->isUsed && "Expecting used RTLs."); if (!R->is_valid_binary(img)) { DP("Image " DPxMOD " is NOT compatible with RTL " DPxMOD "!\n", DPxPTR(img->ImageStart), DPxPTR(R->LibraryHandler)); continue; } DP("Image " DPxMOD " is compatible with RTL " DPxMOD "!\n", DPxPTR(img->ImageStart), DPxPTR(R->LibraryHandler)); FoundRTL = R; // Execute dtors for static objects if the device has been used, i.e. // if its PendingCtors list has been emptied. for (int32_t i = 0; i < FoundRTL->NumberOfDevices; ++i) { DeviceTy &Device = Devices[FoundRTL->Idx + i]; Device.PendingGlobalsMtx.lock(); if (Device.PendingCtorsDtors[desc].PendingCtors.empty()) { for (auto &dtor : Device.PendingCtorsDtors[desc].PendingDtors) { int rc = target(Device.DeviceID, dtor, 0, NULL, NULL, NULL, NULL, 1, 1, true /*team*/); if (rc != OFFLOAD_SUCCESS) { DP("Running destructor " DPxMOD " failed.\n", DPxPTR(dtor)); } } // Remove this library's entry from PendingCtorsDtors Device.PendingCtorsDtors.erase(desc); } Device.PendingGlobalsMtx.unlock(); } DP("Unregistered image " DPxMOD " from RTL " DPxMOD "!\n", DPxPTR(img->ImageStart), DPxPTR(R->LibraryHandler)); break; } // if no RTL was found proceed to unregister the next image if (!FoundRTL){ DP("No RTLs in use support the image " DPxMOD "!\n", DPxPTR(img->ImageStart)); } } RTLsMtx.unlock(); DP("Done unregistering images!\n"); // Remove entries from HostPtrToTableMap TblMapMtx.lock(); for (__tgt_offload_entry *cur = desc->HostEntriesBegin; cur < desc->HostEntriesEnd; ++cur) { HostPtrToTableMap.erase(cur->addr); } // Remove translation table for this descriptor. auto tt = HostEntriesBeginToTransTable.find(desc->HostEntriesBegin); if (tt != HostEntriesBeginToTransTable.end()) { DP("Removing translation table for descriptor " DPxMOD "\n", DPxPTR(desc->HostEntriesBegin)); HostEntriesBeginToTransTable.erase(tt); } else { DP("Translation table for descriptor " DPxMOD " cannot be found, probably " "it has been already removed.\n", DPxPTR(desc->HostEntriesBegin)); } TblMapMtx.unlock(); // TODO: Remove RTL and the devices it manages if it's not used anymore? // TODO: Write some RTL->unload_image(...) function? DP("Done unregistering library!\n"); } /// Map global data and execute pending ctors static int InitLibrary(DeviceTy& Device) { /* * Map global data */ int32_t device_id = Device.DeviceID; int rc = OFFLOAD_SUCCESS; Device.PendingGlobalsMtx.lock(); TrlTblMtx.lock(); for (HostEntriesBeginToTransTableTy::iterator ii = HostEntriesBeginToTransTable.begin(); ii != HostEntriesBeginToTransTable.end(); ++ii) { TranslationTable *TransTable = &ii->second; if (TransTable->TargetsTable[device_id] != 0) { // Library entries have already been processed continue; } // 1) get image. assert(TransTable->TargetsImages.size() > (size_t)device_id && "Not expecting a device ID outside the table's bounds!"); __tgt_device_image *img = TransTable->TargetsImages[device_id]; if (!img) { DP("No image loaded for device id %d.\n", device_id); rc = OFFLOAD_FAIL; break; } // 2) load image into the target table. __tgt_target_table *TargetTable = TransTable->TargetsTable[device_id] = Device.load_binary(img); // Unable to get table for this image: invalidate image and fail. if (!TargetTable) { DP("Unable to generate entries table for device id %d.\n", device_id); TransTable->TargetsImages[device_id] = 0; rc = OFFLOAD_FAIL; break; } // Verify whether the two table sizes match. size_t hsize = TransTable->HostTable.EntriesEnd - TransTable->HostTable.EntriesBegin; size_t tsize = TargetTable->EntriesEnd - TargetTable->EntriesBegin; // Invalid image for these host entries! if (hsize != tsize) { DP("Host and Target tables mismatch for device id %d [%zx != %zx].\n", device_id, hsize, tsize); TransTable->TargetsImages[device_id] = 0; TransTable->TargetsTable[device_id] = 0; rc = OFFLOAD_FAIL; break; } // process global data that needs to be mapped. Device.DataMapMtx.lock(); __tgt_target_table *HostTable = &TransTable->HostTable; for (__tgt_offload_entry *CurrDeviceEntry = TargetTable->EntriesBegin, *CurrHostEntry = HostTable->EntriesBegin, *EntryDeviceEnd = TargetTable->EntriesEnd; CurrDeviceEntry != EntryDeviceEnd; CurrDeviceEntry++, CurrHostEntry++) { if (CurrDeviceEntry->size != 0) { // has data. assert(CurrDeviceEntry->size == CurrHostEntry->size && "data size mismatch"); // Fortran may use multiple weak declarations for the same symbol, // therefore we must allow for multiple weak symbols to be loaded from // the fat binary. Treat these mappings as any other "regular" mapping. // Add entry to map. if (Device.getTgtPtrBegin(CurrHostEntry->addr, CurrHostEntry->size)) continue; DP("Add mapping from host " DPxMOD " to device " DPxMOD " with size %zu" "\n", DPxPTR(CurrHostEntry->addr), DPxPTR(CurrDeviceEntry->addr), CurrDeviceEntry->size); Device.HostDataToTargetMap.push_front(HostDataToTargetTy( (uintptr_t)CurrHostEntry->addr /*HstPtrBase*/, (uintptr_t)CurrHostEntry->addr /*HstPtrBegin*/, (uintptr_t)CurrHostEntry->addr + CurrHostEntry->size /*HstPtrEnd*/, (uintptr_t)CurrDeviceEntry->addr /*TgtPtrBegin*/, INF_REF_CNT /*RefCount*/)); } } Device.DataMapMtx.unlock(); } TrlTblMtx.unlock(); if (rc != OFFLOAD_SUCCESS) { Device.PendingGlobalsMtx.unlock(); return rc; } /* * Run ctors for static objects */ if (!Device.PendingCtorsDtors.empty()) { // Call all ctors for all libraries registered so far for (auto &lib : Device.PendingCtorsDtors) { if (!lib.second.PendingCtors.empty()) { DP("Has pending ctors... call now\n"); for (auto &entry : lib.second.PendingCtors) { void *ctor = entry; int rc = target(device_id, ctor, 0, NULL, NULL, NULL, NULL, 1, 1, true /*team*/); if (rc != OFFLOAD_SUCCESS) { DP("Running ctor " DPxMOD " failed.\n", DPxPTR(ctor)); Device.PendingGlobalsMtx.unlock(); return OFFLOAD_FAIL; } } // Clear the list to indicate that this device has been used lib.second.PendingCtors.clear(); DP("Done with pending ctors for lib " DPxMOD "\n", DPxPTR(lib.first)); } } } Device.HasPendingGlobals = false; Device.PendingGlobalsMtx.unlock(); return OFFLOAD_SUCCESS; } // Check whether a device has been initialized, global ctors have been // executed and global data has been mapped; do so if not already done. static int CheckDevice(int32_t device_id) { // Is device ready? if (!device_is_ready(device_id)) { DP("Device %d is not ready.\n", device_id); return OFFLOAD_FAIL; } // Get device info. DeviceTy &Device = Devices[device_id]; // Check whether global data has been mapped for this device Device.PendingGlobalsMtx.lock(); bool hasPendingGlobals = Device.HasPendingGlobals; Device.PendingGlobalsMtx.unlock(); if (hasPendingGlobals && InitLibrary(Device) != OFFLOAD_SUCCESS) { DP("Failed to init globals on device %d\n", device_id); return OFFLOAD_FAIL; } return OFFLOAD_SUCCESS; } // Following datatypes and functions (tgt_oldmap_type, combined_entry_t, // translate_map, cleanup_map) will be removed once the compiler starts using // the new map types. // Old map types enum tgt_oldmap_type { OMP_TGT_OLDMAPTYPE_TO = 0x001, // copy data from host to device OMP_TGT_OLDMAPTYPE_FROM = 0x002, // copy data from device to host OMP_TGT_OLDMAPTYPE_ALWAYS = 0x004, // copy regardless of the ref. count OMP_TGT_OLDMAPTYPE_DELETE = 0x008, // force unmapping of data OMP_TGT_OLDMAPTYPE_MAP_PTR = 0x010, // map pointer as well as pointee OMP_TGT_OLDMAPTYPE_FIRST_MAP = 0x020, // first occurrence of mapped variable OMP_TGT_OLDMAPTYPE_RETURN_PTR = 0x040, // return TgtBase addr of mapped data OMP_TGT_OLDMAPTYPE_PRIVATE_PTR = 0x080, // private variable - not mapped OMP_TGT_OLDMAPTYPE_PRIVATE_VAL = 0x100 // copy by value - not mapped }; // Temporary functions for map translation and cleanup struct combined_entry_t { int num_members; // number of members in combined entry void *base_addr; // base address of combined entry void *begin_addr; // begin address of combined entry void *end_addr; // size of combined entry }; static void translate_map(int32_t arg_num, void **args_base, void **args, int64_t *arg_sizes, int32_t *arg_types, int32_t &new_arg_num, void **&new_args_base, void **&new_args, int64_t *&new_arg_sizes, int64_t *&new_arg_types, bool is_target_construct) { if (arg_num <= 0) { DP("Nothing to translate\n"); new_arg_num = 0; return; } // array of combined entries combined_entry_t *cmb_entries = (combined_entry_t *) alloca(arg_num * sizeof(combined_entry_t)); // number of combined entries long num_combined = 0; // old entry is MAP_PTR? bool *is_ptr_old = (bool *) alloca(arg_num * sizeof(bool)); // old entry is member of member_of[old] cmb_entry int *member_of = (int *) alloca(arg_num * sizeof(int)); // temporary storage for modifications of the original arg_types int32_t *mod_arg_types = (int32_t *) alloca(arg_num *sizeof(int32_t)); DP("Translating %d map entries\n", arg_num); for (int i = 0; i < arg_num; ++i) { member_of[i] = -1; is_ptr_old[i] = false; mod_arg_types[i] = arg_types[i]; // Scan previous entries to see whether this entry shares the same base for (int j = 0; j < i; ++j) { void *new_begin_addr = NULL; void *new_end_addr = NULL; if (mod_arg_types[i] & OMP_TGT_OLDMAPTYPE_MAP_PTR) { if (args_base[i] == args[j]) { if (!(mod_arg_types[j] & OMP_TGT_OLDMAPTYPE_MAP_PTR)) { DP("Entry %d has the same base as entry %d's begin address\n", i, j); new_begin_addr = args_base[i]; new_end_addr = (char *)args_base[i] + sizeof(void *); assert(arg_sizes[j] == sizeof(void *)); is_ptr_old[j] = true; } else { DP("Entry %d has the same base as entry %d's begin address, but " "%d's base was a MAP_PTR too\n", i, j, j); int32_t to_from_always_delete = OMP_TGT_OLDMAPTYPE_TO | OMP_TGT_OLDMAPTYPE_FROM | OMP_TGT_OLDMAPTYPE_ALWAYS | OMP_TGT_OLDMAPTYPE_DELETE; if (mod_arg_types[j] & to_from_always_delete) { DP("Resetting to/from/always/delete flags for entry %d because " "it is only a pointer to pointer\n", j); mod_arg_types[j] &= ~to_from_always_delete; } } } } else { if (!(mod_arg_types[i] & OMP_TGT_OLDMAPTYPE_FIRST_MAP) && args_base[i] == args_base[j]) { DP("Entry %d has the same base address as entry %d\n", i, j); new_begin_addr = args[i]; new_end_addr = (char *)args[i] + arg_sizes[i]; } } // If we have combined the entry with a previous one if (new_begin_addr) { int id; if(member_of[j] == -1) { // We have a new entry id = num_combined++; DP("Creating new combined entry %d for old entry %d\n", id, j); // Initialize new entry cmb_entries[id].num_members = 1; cmb_entries[id].base_addr = args_base[j]; if (mod_arg_types[j] & OMP_TGT_OLDMAPTYPE_MAP_PTR) { cmb_entries[id].begin_addr = args_base[j]; cmb_entries[id].end_addr = (char *)args_base[j] + arg_sizes[j]; } else { cmb_entries[id].begin_addr = args[j]; cmb_entries[id].end_addr = (char *)args[j] + arg_sizes[j]; } member_of[j] = id; } else { // Reuse existing combined entry DP("Reusing existing combined entry %d\n", member_of[j]); id = member_of[j]; } // Update combined entry DP("Adding entry %d to combined entry %d\n", i, id); cmb_entries[id].num_members++; // base_addr stays the same cmb_entries[id].begin_addr = std::min(cmb_entries[id].begin_addr, new_begin_addr); cmb_entries[id].end_addr = std::max(cmb_entries[id].end_addr, new_end_addr); member_of[i] = id; break; } } } DP("New entries: %ld combined + %d original\n", num_combined, arg_num); new_arg_num = arg_num + num_combined; new_args_base = (void **) malloc(new_arg_num * sizeof(void *)); new_args = (void **) malloc(new_arg_num * sizeof(void *)); new_arg_sizes = (int64_t *) malloc(new_arg_num * sizeof(int64_t)); new_arg_types = (int64_t *) malloc(new_arg_num * sizeof(int64_t)); const int64_t alignment = 8; int next_id = 0; // next ID int next_cid = 0; // next combined ID int *combined_to_new_id = (int *) alloca(num_combined * sizeof(int)); for (int i = 0; i < arg_num; ++i) { // It is member_of if (member_of[i] == next_cid) { int cid = next_cid++; // ID of this combined entry int nid = next_id++; // ID of the new (global) entry combined_to_new_id[cid] = nid; DP("Combined entry %3d will become new entry %3d\n", cid, nid); int64_t padding = (int64_t)cmb_entries[cid].begin_addr % alignment; if (padding) { DP("Using a padding of %" PRId64 " for begin address " DPxMOD "\n", padding, DPxPTR(cmb_entries[cid].begin_addr)); cmb_entries[cid].begin_addr = (char *)cmb_entries[cid].begin_addr - padding; } new_args_base[nid] = cmb_entries[cid].base_addr; new_args[nid] = cmb_entries[cid].begin_addr; new_arg_sizes[nid] = (int64_t) ((char *)cmb_entries[cid].end_addr - (char *)cmb_entries[cid].begin_addr); new_arg_types[nid] = OMP_TGT_MAPTYPE_TARGET_PARAM; DP("Entry %3d: base_addr " DPxMOD ", begin_addr " DPxMOD ", " "size %" PRId64 ", type 0x%" PRIx64 "\n", nid, DPxPTR(new_args_base[nid]), DPxPTR(new_args[nid]), new_arg_sizes[nid], new_arg_types[nid]); } else if (member_of[i] != -1) { DP("Combined entry %3d has been encountered before, do nothing\n", member_of[i]); } // Now that the combined entry (the one the old entry was a member of) has // been inserted into the new arguments list, proceed with the old entry. int nid = next_id++; DP("Old entry %3d will become new entry %3d\n", i, nid); new_args_base[nid] = args_base[i]; new_args[nid] = args[i]; new_arg_sizes[nid] = arg_sizes[i]; int64_t old_type = mod_arg_types[i]; if (is_ptr_old[i]) { // Reset TO and FROM flags old_type &= ~(OMP_TGT_OLDMAPTYPE_TO | OMP_TGT_OLDMAPTYPE_FROM); } if (member_of[i] == -1) { if (!is_target_construct) old_type &= ~OMP_TGT_MAPTYPE_TARGET_PARAM; new_arg_types[nid] = old_type; DP("Entry %3d: base_addr " DPxMOD ", begin_addr " DPxMOD ", size %" PRId64 ", type 0x%" PRIx64 " (old entry %d not MEMBER_OF)\n", nid, DPxPTR(new_args_base[nid]), DPxPTR(new_args[nid]), new_arg_sizes[nid], new_arg_types[nid], i); } else { // Old entry is not FIRST_MAP old_type &= ~OMP_TGT_OLDMAPTYPE_FIRST_MAP; // Add MEMBER_OF int new_member_of = combined_to_new_id[member_of[i]]; old_type |= ((int64_t)new_member_of + 1) << 48; new_arg_types[nid] = old_type; DP("Entry %3d: base_addr " DPxMOD ", begin_addr " DPxMOD ", size %" PRId64 ", type 0x%" PRIx64 " (old entry %d MEMBER_OF %d)\n", nid, DPxPTR(new_args_base[nid]), DPxPTR(new_args[nid]), new_arg_sizes[nid], new_arg_types[nid], i, new_member_of); } } } static void cleanup_map(int32_t new_arg_num, void **new_args_base, void **new_args, int64_t *new_arg_sizes, int64_t *new_arg_types, int32_t arg_num, void **args_base) { if (new_arg_num > 0) { int offset = new_arg_num - arg_num; for (int32_t i = 0; i < arg_num; ++i) { // Restore old base address args_base[i] = new_args_base[i+offset]; } free(new_args_base); free(new_args); free(new_arg_sizes); free(new_arg_types); } } static short member_of(int64_t type) { return ((type & OMP_TGT_MAPTYPE_MEMBER_OF) >> 48) - 1; } /// Internal function to do the mapping and transfer the data to the device static int target_data_begin(DeviceTy &Device, int32_t arg_num, void **args_base, void **args, int64_t *arg_sizes, int64_t *arg_types) { // process each input. int rc = OFFLOAD_SUCCESS; for (int32_t i = 0; i < arg_num; ++i) { // Ignore private variables and arrays - there is no mapping for them. if ((arg_types[i] & OMP_TGT_MAPTYPE_LITERAL) || (arg_types[i] & OMP_TGT_MAPTYPE_PRIVATE)) continue; void *HstPtrBegin = args[i]; void *HstPtrBase = args_base[i]; // Address of pointer on the host and device, respectively. void *Pointer_HstPtrBegin, *Pointer_TgtPtrBegin; bool IsNew, Pointer_IsNew; bool IsImplicit = arg_types[i] & OMP_TGT_MAPTYPE_IMPLICIT; bool UpdateRef = !(arg_types[i] & OMP_TGT_MAPTYPE_MEMBER_OF); if (arg_types[i] & OMP_TGT_MAPTYPE_PTR_AND_OBJ) { DP("Has a pointer entry: \n"); // base is address of pointer. Pointer_TgtPtrBegin = Device.getOrAllocTgtPtr(HstPtrBase, HstPtrBase, sizeof(void *), Pointer_IsNew, IsImplicit, UpdateRef); if (!Pointer_TgtPtrBegin) { DP("Call to getOrAllocTgtPtr returned null pointer (device failure or " "illegal mapping).\n"); } DP("There are %zu bytes allocated at target address " DPxMOD " - is%s new" "\n", sizeof(void *), DPxPTR(Pointer_TgtPtrBegin), (Pointer_IsNew ? "" : " not")); Pointer_HstPtrBegin = HstPtrBase; // modify current entry. HstPtrBase = *(void **)HstPtrBase; UpdateRef = true; // subsequently update ref count of pointee } void *TgtPtrBegin = Device.getOrAllocTgtPtr(HstPtrBegin, HstPtrBase, arg_sizes[i], IsNew, IsImplicit, UpdateRef); if (!TgtPtrBegin && arg_sizes[i]) { // If arg_sizes[i]==0, then the argument is a pointer to NULL, so // getOrAlloc() returning NULL is not an error. DP("Call to getOrAllocTgtPtr returned null pointer (device failure or " "illegal mapping).\n"); } DP("There are %" PRId64 " bytes allocated at target address " DPxMOD " - is%s new\n", arg_sizes[i], DPxPTR(TgtPtrBegin), (IsNew ? "" : " not")); if (arg_types[i] & OMP_TGT_MAPTYPE_RETURN_PARAM) { void *ret_ptr; if (arg_types[i] & OMP_TGT_MAPTYPE_PTR_AND_OBJ) ret_ptr = Pointer_TgtPtrBegin; else { bool IsLast; // not used ret_ptr = Device.getTgtPtrBegin(HstPtrBegin, 0, IsLast, false); } DP("Returning device pointer " DPxMOD "\n", DPxPTR(ret_ptr)); args_base[i] = ret_ptr; } if (arg_types[i] & OMP_TGT_MAPTYPE_TO) { bool copy = false; if (IsNew || (arg_types[i] & OMP_TGT_MAPTYPE_ALWAYS)) { copy = true; } else if (arg_types[i] & OMP_TGT_MAPTYPE_MEMBER_OF) { // Copy data only if the "parent" struct has RefCount==1. short parent_idx = member_of(arg_types[i]); long parent_rc = Device.getMapEntryRefCnt(args[parent_idx]); assert(parent_rc > 0 && "parent struct not found"); if (parent_rc == 1) { copy = true; } } if (copy) { DP("Moving %" PRId64 " bytes (hst:" DPxMOD ") -> (tgt:" DPxMOD ")\n", arg_sizes[i], DPxPTR(HstPtrBegin), DPxPTR(TgtPtrBegin)); int rt = Device.data_submit(TgtPtrBegin, HstPtrBegin, arg_sizes[i]); if (rt != OFFLOAD_SUCCESS) { DP("Copying data to device failed.\n"); rc = OFFLOAD_FAIL; } } } if (arg_types[i] & OMP_TGT_MAPTYPE_PTR_AND_OBJ) { DP("Update pointer (" DPxMOD ") -> [" DPxMOD "]\n", DPxPTR(Pointer_TgtPtrBegin), DPxPTR(TgtPtrBegin)); uint64_t Delta = (uint64_t)HstPtrBegin - (uint64_t)HstPtrBase; void *TgtPtrBase = (void *)((uint64_t)TgtPtrBegin - Delta); int rt = Device.data_submit(Pointer_TgtPtrBegin, &TgtPtrBase, sizeof(void *)); if (rt != OFFLOAD_SUCCESS) { DP("Copying data to device failed.\n"); rc = OFFLOAD_FAIL; } // create shadow pointers for this entry Device.ShadowMtx.lock(); Device.ShadowPtrMap[Pointer_HstPtrBegin] = {HstPtrBase, Pointer_TgtPtrBegin, TgtPtrBase}; Device.ShadowMtx.unlock(); } } return rc; } EXTERN void __tgt_target_data_begin_nowait(int32_t device_id, int32_t arg_num, void **args_base, void **args, int64_t *arg_sizes, int32_t *arg_types, int32_t depNum, void *depList, int32_t noAliasDepNum, void *noAliasDepList) { if (depNum + noAliasDepNum > 0) __kmpc_omp_taskwait(NULL, 0); __tgt_target_data_begin(device_id, arg_num, args_base, args, arg_sizes, arg_types); } /// creates host-to-target data mapping, stores it in the /// libomptarget.so internal structure (an entry in a stack of data maps) /// and passes the data to the device. EXTERN void __tgt_target_data_begin(int32_t device_id, int32_t arg_num, void **args_base, void **args, int64_t *arg_sizes, int32_t *arg_types) { DP("Entering data begin region for device %d with %d mappings\n", device_id, arg_num); // No devices available? if (device_id == OFFLOAD_DEVICE_DEFAULT) { device_id = omp_get_default_device(); DP("Use default device id %d\n", device_id); } if (CheckDevice(device_id) != OFFLOAD_SUCCESS) { DP("Failed to get device %d ready\n", device_id); return; } DeviceTy& Device = Devices[device_id]; // Translate maps int32_t new_arg_num; void **new_args_base; void **new_args; int64_t *new_arg_sizes; int64_t *new_arg_types; translate_map(arg_num, args_base, args, arg_sizes, arg_types, new_arg_num, new_args_base, new_args, new_arg_sizes, new_arg_types, false); //target_data_begin(Device, arg_num, args_base, args, arg_sizes, arg_types); target_data_begin(Device, new_arg_num, new_args_base, new_args, new_arg_sizes, new_arg_types); // Cleanup translation memory cleanup_map(new_arg_num, new_args_base, new_args, new_arg_sizes, new_arg_types, arg_num, args_base); } /// Internal function to undo the mapping and retrieve the data from the device. static int target_data_end(DeviceTy &Device, int32_t arg_num, void **args_base, void **args, int64_t *arg_sizes, int64_t *arg_types) { int rc = OFFLOAD_SUCCESS; // process each input. for (int32_t i = arg_num - 1; i >= 0; --i) { // Ignore private variables and arrays - there is no mapping for them. // Also, ignore the use_device_ptr directive, it has no effect here. if ((arg_types[i] & OMP_TGT_MAPTYPE_LITERAL) || (arg_types[i] & OMP_TGT_MAPTYPE_PRIVATE)) continue; void *HstPtrBegin = args[i]; bool IsLast; bool UpdateRef = !(arg_types[i] & OMP_TGT_MAPTYPE_MEMBER_OF) || (arg_types[i] & OMP_TGT_MAPTYPE_PTR_AND_OBJ); bool ForceDelete = arg_types[i] & OMP_TGT_MAPTYPE_DELETE; // If PTR_AND_OBJ, HstPtrBegin is address of pointee void *TgtPtrBegin = Device.getTgtPtrBegin(HstPtrBegin, arg_sizes[i], IsLast, UpdateRef); DP("There are %" PRId64 " bytes allocated at target address " DPxMOD " - is%s last\n", arg_sizes[i], DPxPTR(TgtPtrBegin), (IsLast ? "" : " not")); bool DelEntry = IsLast || ForceDelete; if ((arg_types[i] & OMP_TGT_MAPTYPE_MEMBER_OF) && !(arg_types[i] & OMP_TGT_MAPTYPE_PTR_AND_OBJ)) { DelEntry = false; // protect parent struct from being deallocated } if ((arg_types[i] & OMP_TGT_MAPTYPE_FROM) || DelEntry) { // Move data back to the host if (arg_types[i] & OMP_TGT_MAPTYPE_FROM) { bool Always = arg_types[i] & OMP_TGT_MAPTYPE_ALWAYS; bool CopyMember = false; if ((arg_types[i] & OMP_TGT_MAPTYPE_MEMBER_OF) && !(arg_types[i] & OMP_TGT_MAPTYPE_PTR_AND_OBJ)) { // Copy data only if the "parent" struct has RefCount==1. short parent_idx = member_of(arg_types[i]); long parent_rc = Device.getMapEntryRefCnt(args[parent_idx]); assert(parent_rc > 0 && "parent struct not found"); if (parent_rc == 1) { CopyMember = true; } } if (DelEntry || Always || CopyMember) { DP("Moving %" PRId64 " bytes (tgt:" DPxMOD ") -> (hst:" DPxMOD ")\n", arg_sizes[i], DPxPTR(TgtPtrBegin), DPxPTR(HstPtrBegin)); int rt = Device.data_retrieve(HstPtrBegin, TgtPtrBegin, arg_sizes[i]); if (rt != OFFLOAD_SUCCESS) { DP("Copying data from device failed.\n"); rc = OFFLOAD_FAIL; } } } // If we copied back to the host a struct/array containing pointers, we // need to restore the original host pointer values from their shadow // copies. If the struct is going to be deallocated, remove any remaining // shadow pointer entries for this struct. uintptr_t lb = (uintptr_t) HstPtrBegin; uintptr_t ub = (uintptr_t) HstPtrBegin + arg_sizes[i]; Device.ShadowMtx.lock(); for (ShadowPtrListTy::iterator it = Device.ShadowPtrMap.begin(); it != Device.ShadowPtrMap.end(); ++it) { void **ShadowHstPtrAddr = (void**) it->first; // An STL map is sorted on its keys; use this property // to quickly determine when to break out of the loop. if ((uintptr_t) ShadowHstPtrAddr < lb) continue; if ((uintptr_t) ShadowHstPtrAddr >= ub) break; // If we copied the struct to the host, we need to restore the pointer. if (arg_types[i] & OMP_TGT_MAPTYPE_FROM) { DP("Restoring original host pointer value " DPxMOD " for host " "pointer " DPxMOD "\n", DPxPTR(it->second.HstPtrVal), DPxPTR(ShadowHstPtrAddr)); *ShadowHstPtrAddr = it->second.HstPtrVal; } // If the struct is to be deallocated, remove the shadow entry. if (DelEntry) { DP("Removing shadow pointer " DPxMOD "\n", DPxPTR(ShadowHstPtrAddr)); Device.ShadowPtrMap.erase(it); } } Device.ShadowMtx.unlock(); // Deallocate map if (DelEntry) { int rt = Device.deallocTgtPtr(HstPtrBegin, arg_sizes[i], ForceDelete); if (rt != OFFLOAD_SUCCESS) { DP("Deallocating data from device failed.\n"); rc = OFFLOAD_FAIL; } } } } return rc; } /// passes data from the target, releases target memory and destroys /// the host-target mapping (top entry from the stack of data maps) /// created by the last __tgt_target_data_begin. EXTERN void __tgt_target_data_end(int32_t device_id, int32_t arg_num, void **args_base, void **args, int64_t *arg_sizes, int32_t *arg_types) { DP("Entering data end region with %d mappings\n", arg_num); // No devices available? if (device_id == OFFLOAD_DEVICE_DEFAULT) { device_id = omp_get_default_device(); } RTLsMtx.lock(); size_t Devices_size = Devices.size(); RTLsMtx.unlock(); if (Devices_size <= (size_t)device_id) { DP("Device ID %d does not have a matching RTL.\n", device_id); return; } DeviceTy &Device = Devices[device_id]; if (!Device.IsInit) { DP("uninit device: ignore"); return; } // Translate maps int32_t new_arg_num; void **new_args_base; void **new_args; int64_t *new_arg_sizes; int64_t *new_arg_types; translate_map(arg_num, args_base, args, arg_sizes, arg_types, new_arg_num, new_args_base, new_args, new_arg_sizes, new_arg_types, false); //target_data_end(Device, arg_num, args_base, args, arg_sizes, arg_types); target_data_end(Device, new_arg_num, new_args_base, new_args, new_arg_sizes, new_arg_types); // Cleanup translation memory cleanup_map(new_arg_num, new_args_base, new_args, new_arg_sizes, new_arg_types, arg_num, args_base); } EXTERN void __tgt_target_data_end_nowait(int32_t device_id, int32_t arg_num, void **args_base, void **args, int64_t *arg_sizes, int32_t *arg_types, int32_t depNum, void *depList, int32_t noAliasDepNum, void *noAliasDepList) { if (depNum + noAliasDepNum > 0) __kmpc_omp_taskwait(NULL, 0); __tgt_target_data_end(device_id, arg_num, args_base, args, arg_sizes, arg_types); } /// passes data to/from the target. EXTERN void __tgt_target_data_update(int32_t device_id, int32_t arg_num, void **args_base, void **args, int64_t *arg_sizes, int32_t *arg_types) { DP("Entering data update with %d mappings\n", arg_num); // No devices available? if (device_id == OFFLOAD_DEVICE_DEFAULT) { device_id = omp_get_default_device(); } if (CheckDevice(device_id) != OFFLOAD_SUCCESS) { DP("Failed to get device %d ready\n", device_id); return; } DeviceTy& Device = Devices[device_id]; // process each input. for (int32_t i = 0; i < arg_num; ++i) { if ((arg_types[i] & OMP_TGT_MAPTYPE_LITERAL) || (arg_types[i] & OMP_TGT_MAPTYPE_PRIVATE)) continue; void *HstPtrBegin = args[i]; int64_t MapSize = arg_sizes[i]; bool IsLast; void *TgtPtrBegin = Device.getTgtPtrBegin(HstPtrBegin, MapSize, IsLast, false); if (arg_types[i] & OMP_TGT_MAPTYPE_FROM) { DP("Moving %" PRId64 " bytes (tgt:" DPxMOD ") -> (hst:" DPxMOD ")\n", arg_sizes[i], DPxPTR(TgtPtrBegin), DPxPTR(HstPtrBegin)); Device.data_retrieve(HstPtrBegin, TgtPtrBegin, MapSize); uintptr_t lb = (uintptr_t) HstPtrBegin; uintptr_t ub = (uintptr_t) HstPtrBegin + MapSize; Device.ShadowMtx.lock(); for (ShadowPtrListTy::iterator it = Device.ShadowPtrMap.begin(); it != Device.ShadowPtrMap.end(); ++it) { void **ShadowHstPtrAddr = (void**) it->first; if ((uintptr_t) ShadowHstPtrAddr < lb) continue; if ((uintptr_t) ShadowHstPtrAddr >= ub) break; DP("Restoring original host pointer value " DPxMOD " for host pointer " DPxMOD "\n", DPxPTR(it->second.HstPtrVal), DPxPTR(ShadowHstPtrAddr)); *ShadowHstPtrAddr = it->second.HstPtrVal; } Device.ShadowMtx.unlock(); } if (arg_types[i] & OMP_TGT_MAPTYPE_TO) { DP("Moving %" PRId64 " bytes (hst:" DPxMOD ") -> (tgt:" DPxMOD ")\n", arg_sizes[i], DPxPTR(HstPtrBegin), DPxPTR(TgtPtrBegin)); Device.data_submit(TgtPtrBegin, HstPtrBegin, MapSize); uintptr_t lb = (uintptr_t) HstPtrBegin; uintptr_t ub = (uintptr_t) HstPtrBegin + MapSize; Device.ShadowMtx.lock(); for (ShadowPtrListTy::iterator it = Device.ShadowPtrMap.begin(); it != Device.ShadowPtrMap.end(); ++it) { void **ShadowHstPtrAddr = (void**) it->first; if ((uintptr_t) ShadowHstPtrAddr < lb) continue; if ((uintptr_t) ShadowHstPtrAddr >= ub) break; DP("Restoring original target pointer value " DPxMOD " for target " "pointer " DPxMOD "\n", DPxPTR(it->second.TgtPtrVal), DPxPTR(it->second.TgtPtrAddr)); Device.data_submit(it->second.TgtPtrAddr, &it->second.TgtPtrVal, sizeof(void *)); } Device.ShadowMtx.unlock(); } } } EXTERN void __tgt_target_data_update_nowait( int32_t device_id, int32_t arg_num, void **args_base, void **args, int64_t *arg_sizes, int32_t *arg_types, int32_t depNum, void *depList, int32_t noAliasDepNum, void *noAliasDepList) { if (depNum + noAliasDepNum > 0) __kmpc_omp_taskwait(NULL, 0); __tgt_target_data_update(device_id, arg_num, args_base, args, arg_sizes, arg_types); } /// performs the same actions as data_begin in case arg_num is /// non-zero and initiates run of the offloaded region on the target platform; /// if arg_num is non-zero after the region execution is done it also /// performs the same action as data_update and data_end above. This function /// returns 0 if it was able to transfer the execution to a target and an /// integer different from zero otherwise. static int target(int32_t device_id, void *host_ptr, int32_t arg_num, void **args_base, void **args, int64_t *arg_sizes, int64_t *arg_types, int32_t team_num, int32_t thread_limit, int IsTeamConstruct) { DeviceTy &Device = Devices[device_id]; // Find the table information in the map or look it up in the translation // tables. TableMap *TM = 0; TblMapMtx.lock(); HostPtrToTableMapTy::iterator TableMapIt = HostPtrToTableMap.find(host_ptr); if (TableMapIt == HostPtrToTableMap.end()) { // We don't have a map. So search all the registered libraries. TrlTblMtx.lock(); for (HostEntriesBeginToTransTableTy::iterator ii = HostEntriesBeginToTransTable.begin(), ie = HostEntriesBeginToTransTable.end(); !TM && ii != ie; ++ii) { // get the translation table (which contains all the good info). TranslationTable *TransTable = &ii->second; // iterate over all the host table entries to see if we can locate the // host_ptr. __tgt_offload_entry *begin = TransTable->HostTable.EntriesBegin; __tgt_offload_entry *end = TransTable->HostTable.EntriesEnd; __tgt_offload_entry *cur = begin; for (uint32_t i = 0; cur < end; ++cur, ++i) { if (cur->addr != host_ptr) continue; // we got a match, now fill the HostPtrToTableMap so that we // may avoid this search next time. TM = &HostPtrToTableMap[host_ptr]; TM->Table = TransTable; TM->Index = i; break; } } TrlTblMtx.unlock(); } else { TM = &TableMapIt->second; } TblMapMtx.unlock(); // No map for this host pointer found! if (!TM) { DP("Host ptr " DPxMOD " does not have a matching target pointer.\n", DPxPTR(host_ptr)); return OFFLOAD_FAIL; } // get target table. TrlTblMtx.lock(); assert(TM->Table->TargetsTable.size() > (size_t)device_id && "Not expecting a device ID outside the table's bounds!"); __tgt_target_table *TargetTable = TM->Table->TargetsTable[device_id]; TrlTblMtx.unlock(); assert(TargetTable && "Global data has not been mapped\n"); // Move data to device. int rc = target_data_begin(Device, arg_num, args_base, args, arg_sizes, arg_types); if (rc != OFFLOAD_SUCCESS) { DP("Call to target_data_begin failed, skipping target execution.\n"); // Call target_data_end to dealloc whatever target_data_begin allocated // and return OFFLOAD_FAIL. target_data_end(Device, arg_num, args_base, args, arg_sizes, arg_types); return OFFLOAD_FAIL; } std::vector tgt_args; std::vector tgt_offsets; // List of (first-)private arrays allocated for this target region std::vector fpArrays; for (int32_t i = 0; i < arg_num; ++i) { if (!(arg_types[i] & OMP_TGT_MAPTYPE_TARGET_PARAM)) { // This is not a target parameter, do not push it into tgt_args. continue; } void *HstPtrBegin = args[i]; void *HstPtrBase = args_base[i]; void *TgtPtrBegin; ptrdiff_t TgtBaseOffset; bool IsLast; // unused. if (arg_types[i] & OMP_TGT_MAPTYPE_LITERAL) { DP("Forwarding first-private value " DPxMOD " to the target construct\n", DPxPTR(HstPtrBase)); TgtPtrBegin = HstPtrBase; TgtBaseOffset = 0; } else if (arg_types[i] & OMP_TGT_MAPTYPE_PRIVATE) { // Allocate memory for (first-)private array TgtPtrBegin = Device.RTL->data_alloc(Device.RTLDeviceID, arg_sizes[i], HstPtrBegin); if (!TgtPtrBegin) { DP ("Data allocation for %sprivate array " DPxMOD " failed\n", (arg_types[i] & OMP_TGT_MAPTYPE_TO ? "first-" : ""), DPxPTR(HstPtrBegin)); rc = OFFLOAD_FAIL; break; } else { fpArrays.push_back(TgtPtrBegin); TgtBaseOffset = (intptr_t)HstPtrBase - (intptr_t)HstPtrBegin; #ifdef OMPTARGET_DEBUG void *TgtPtrBase = (void *)((intptr_t)TgtPtrBegin + TgtBaseOffset); DP("Allocated %" PRId64 " bytes of target memory at " DPxMOD " for " "%sprivate array " DPxMOD " - pushing target argument " DPxMOD "\n", arg_sizes[i], DPxPTR(TgtPtrBegin), (arg_types[i] & OMP_TGT_MAPTYPE_TO ? "first-" : ""), DPxPTR(HstPtrBegin), DPxPTR(TgtPtrBase)); #endif // If first-private, copy data from host if (arg_types[i] & OMP_TGT_MAPTYPE_TO) { int rt = Device.data_submit(TgtPtrBegin, HstPtrBegin, arg_sizes[i]); if (rt != OFFLOAD_SUCCESS) { DP ("Copying data to device failed.\n"); rc = OFFLOAD_FAIL; break; } } } } else if (arg_types[i] & OMP_TGT_MAPTYPE_PTR_AND_OBJ) { TgtPtrBegin = Device.getTgtPtrBegin(HstPtrBase, sizeof(void *), IsLast, false); TgtBaseOffset = 0; // no offset for ptrs. DP("Obtained target argument " DPxMOD " from host pointer " DPxMOD " to " "object " DPxMOD "\n", DPxPTR(TgtPtrBegin), DPxPTR(HstPtrBase), DPxPTR(HstPtrBase)); } else { TgtPtrBegin = Device.getTgtPtrBegin(HstPtrBegin, arg_sizes[i], IsLast, false); TgtBaseOffset = (intptr_t)HstPtrBase - (intptr_t)HstPtrBegin; #ifdef OMPTARGET_DEBUG void *TgtPtrBase = (void *)((intptr_t)TgtPtrBegin + TgtBaseOffset); DP("Obtained target argument " DPxMOD " from host pointer " DPxMOD "\n", DPxPTR(TgtPtrBase), DPxPTR(HstPtrBegin)); #endif } tgt_args.push_back(TgtPtrBegin); tgt_offsets.push_back(TgtBaseOffset); } // Push omp handle. tgt_args.push_back((void *)0); tgt_offsets.push_back(0); assert(tgt_args.size() == tgt_offsets.size() && "Size mismatch in arguments and offsets"); // Pop loop trip count uint64_t ltc = Device.loopTripCnt; Device.loopTripCnt = 0; // Launch device execution. if (rc == OFFLOAD_SUCCESS) { DP("Launching target execution %s with pointer " DPxMOD " (index=%d).\n", TargetTable->EntriesBegin[TM->Index].name, DPxPTR(TargetTable->EntriesBegin[TM->Index].addr), TM->Index); if (IsTeamConstruct) { rc = Device.run_team_region(TargetTable->EntriesBegin[TM->Index].addr, &tgt_args[0], &tgt_offsets[0], tgt_args.size(), team_num, thread_limit, ltc); } else { rc = Device.run_region(TargetTable->EntriesBegin[TM->Index].addr, &tgt_args[0], &tgt_offsets[0], tgt_args.size()); } } else { DP("Errors occurred while obtaining target arguments, skipping kernel " "execution\n"); } // Deallocate (first-)private arrays for (auto it : fpArrays) { int rt = Device.RTL->data_delete(Device.RTLDeviceID, it); if (rt != OFFLOAD_SUCCESS) { DP("Deallocation of (first-)private arrays failed.\n"); rc = OFFLOAD_FAIL; } } // Move data from device. int rt = target_data_end(Device, arg_num, args_base, args, arg_sizes, arg_types); if (rt != OFFLOAD_SUCCESS) { DP("Call to target_data_end failed.\n"); rc = OFFLOAD_FAIL; } return rc; } EXTERN int __tgt_target(int32_t device_id, void *host_ptr, int32_t arg_num, void **args_base, void **args, int64_t *arg_sizes, int32_t *arg_types) { DP("Entering target region with entry point " DPxMOD " and device Id %d\n", DPxPTR(host_ptr), device_id); if (device_id == OFFLOAD_DEVICE_DEFAULT) { device_id = omp_get_default_device(); } if (CheckDevice(device_id) != OFFLOAD_SUCCESS) { DP("Failed to get device %d ready\n", device_id); return OFFLOAD_FAIL; } // Translate maps int32_t new_arg_num; void **new_args_base; void **new_args; int64_t *new_arg_sizes; int64_t *new_arg_types; translate_map(arg_num, args_base, args, arg_sizes, arg_types, new_arg_num, new_args_base, new_args, new_arg_sizes, new_arg_types, true); //return target(device_id, host_ptr, arg_num, args_base, args, arg_sizes, // arg_types, 0, 0, false /*team*/, false /*recursive*/); int rc = target(device_id, host_ptr, new_arg_num, new_args_base, new_args, new_arg_sizes, new_arg_types, 0, 0, false /*team*/); // Cleanup translation memory cleanup_map(new_arg_num, new_args_base, new_args, new_arg_sizes, new_arg_types, arg_num, args_base); return rc; } EXTERN int __tgt_target_nowait(int32_t device_id, void *host_ptr, int32_t arg_num, void **args_base, void **args, int64_t *arg_sizes, int32_t *arg_types, int32_t depNum, void *depList, int32_t noAliasDepNum, void *noAliasDepList) { if (depNum + noAliasDepNum > 0) __kmpc_omp_taskwait(NULL, 0); return __tgt_target(device_id, host_ptr, arg_num, args_base, args, arg_sizes, arg_types); } EXTERN int __tgt_target_teams(int32_t device_id, void *host_ptr, int32_t arg_num, void **args_base, void **args, int64_t *arg_sizes, int32_t *arg_types, int32_t team_num, int32_t thread_limit) { DP("Entering target region with entry point " DPxMOD " and device Id %d\n", DPxPTR(host_ptr), device_id); if (device_id == OFFLOAD_DEVICE_DEFAULT) { device_id = omp_get_default_device(); } if (CheckDevice(device_id) != OFFLOAD_SUCCESS) { DP("Failed to get device %d ready\n", device_id); return OFFLOAD_FAIL; } // Translate maps int32_t new_arg_num; void **new_args_base; void **new_args; int64_t *new_arg_sizes; int64_t *new_arg_types; translate_map(arg_num, args_base, args, arg_sizes, arg_types, new_arg_num, new_args_base, new_args, new_arg_sizes, new_arg_types, true); //return target(device_id, host_ptr, arg_num, args_base, args, arg_sizes, // arg_types, team_num, thread_limit, true /*team*/, // false /*recursive*/); int rc = target(device_id, host_ptr, new_arg_num, new_args_base, new_args, new_arg_sizes, new_arg_types, team_num, thread_limit, true /*team*/); // Cleanup translation memory cleanup_map(new_arg_num, new_args_base, new_args, new_arg_sizes, new_arg_types, arg_num, args_base); return rc; } EXTERN int __tgt_target_teams_nowait(int32_t device_id, void *host_ptr, int32_t arg_num, void **args_base, void **args, int64_t *arg_sizes, int32_t *arg_types, int32_t team_num, int32_t thread_limit, int32_t depNum, void *depList, int32_t noAliasDepNum, void *noAliasDepList) { if (depNum + noAliasDepNum > 0) __kmpc_omp_taskwait(NULL, 0); return __tgt_target_teams(device_id, host_ptr, arg_num, args_base, args, arg_sizes, arg_types, team_num, thread_limit); } // The trip count mechanism will be revised - this scheme is not thread-safe. EXTERN void __kmpc_push_target_tripcount(int32_t device_id, uint64_t loop_tripcount) { if (device_id == OFFLOAD_DEVICE_DEFAULT) { device_id = omp_get_default_device(); } if (CheckDevice(device_id) != OFFLOAD_SUCCESS) { DP("Failed to get device %d ready\n", device_id); return; } DP("__kmpc_push_target_tripcount(%d, %" PRIu64 ")\n", device_id, loop_tripcount); Devices[device_id].loopTripCnt = loop_tripcount; }