//===----------- api.cpp - 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 // //===----------------------------------------------------------------------===// // // Implementation of OpenMP API interface functions. // //===----------------------------------------------------------------------===// #include "device.h" #include "omptarget.h" #include "private.h" #include "rtl.h" #include #include #include EXTERN int omp_get_num_devices(void) { TIMESCOPE(); PM->RTLsMtx.lock(); size_t DevicesSize = PM->Devices.size(); PM->RTLsMtx.unlock(); DP("Call to omp_get_num_devices returning %zd\n", DevicesSize); return DevicesSize; } EXTERN int omp_get_initial_device(void) { TIMESCOPE(); int hostDevice = omp_get_num_devices(); DP("Call to omp_get_initial_device returning %d\n", hostDevice); return hostDevice; } EXTERN void *omp_target_alloc(size_t size, int device_num) { return targetAllocExplicit(size, device_num, TARGET_ALLOC_DEFAULT, __func__); } EXTERN void *llvm_omp_target_alloc_device(size_t size, int device_num) { return targetAllocExplicit(size, device_num, TARGET_ALLOC_DEVICE, __func__); } EXTERN void *llvm_omp_target_alloc_host(size_t size, int device_num) { return targetAllocExplicit(size, device_num, TARGET_ALLOC_HOST, __func__); } EXTERN void *llvm_omp_target_alloc_shared(size_t size, int device_num) { return targetAllocExplicit(size, device_num, TARGET_ALLOC_SHARED, __func__); } EXTERN void *llvm_omp_get_dynamic_shared() { return nullptr; } EXTERN void omp_target_free(void *device_ptr, int device_num) { TIMESCOPE(); 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; } PM->Devices[device_num]->deleteData(device_ptr); DP("omp_target_free deallocated device ptr\n"); } EXTERN int omp_target_is_present(const void *ptr, int device_num) { TIMESCOPE(); 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; } PM->RTLsMtx.lock(); size_t DevicesSize = PM->Devices.size(); PM->RTLsMtx.unlock(); if (DevicesSize <= (size_t)device_num) { DP("Call to omp_target_is_present with invalid device ID, returning " "false\n"); return false; } DeviceTy &Device = *PM->Devices[device_num]; bool IsLast; // not used bool IsHostPtr; void *TgtPtr = Device.getTgtPtrBegin(const_cast(ptr), 0, IsLast, /*UpdateRefCount=*/false, /*UseHoldRefCount=*/false, IsHostPtr); int rc = (TgtPtr != NULL); // Under unified memory the host pointer can be returned by the // getTgtPtrBegin() function which means that there is no device // corresponding point for ptr. This function should return false // in that situation. if (PM->RTLs.RequiresFlags & OMP_REQ_UNIFIED_SHARED_MEMORY) rc = !IsHostPtr; DP("Call to omp_target_is_present returns %d\n", rc); return rc; } EXTERN int omp_target_memcpy(void *dst, const void *src, size_t length, size_t dst_offset, size_t src_offset, int dst_device, int src_device) { TIMESCOPE(); 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) { if (length == 0) { DP("Call to omp_target_memcpy with zero length, nothing to do\n"); return OFFLOAD_SUCCESS; } REPORT("Call to omp_target_memcpy with invalid arguments\n"); return OFFLOAD_FAIL; } if (src_device != omp_get_initial_device() && !device_is_ready(src_device)) { REPORT("omp_target_memcpy returns OFFLOAD_FAIL\n"); return OFFLOAD_FAIL; } if (dst_device != omp_get_initial_device() && !device_is_ready(dst_device)) { REPORT("omp_target_memcpy returns OFFLOAD_FAIL\n"); return OFFLOAD_FAIL; } int rc = OFFLOAD_SUCCESS; void *srcAddr = (char *)const_cast(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 = *PM->Devices[dst_device]; AsyncInfoTy AsyncInfo(DstDev); rc = DstDev.submitData(dstAddr, srcAddr, length, AsyncInfo); } else if (dst_device == omp_get_initial_device()) { DP("copy from device to host\n"); DeviceTy &SrcDev = *PM->Devices[src_device]; AsyncInfoTy AsyncInfo(SrcDev); rc = SrcDev.retrieveData(dstAddr, srcAddr, length, AsyncInfo); } else { DP("copy from device to device\n"); DeviceTy &SrcDev = *PM->Devices[src_device]; DeviceTy &DstDev = *PM->Devices[dst_device]; // First try to use D2D memcpy which is more efficient. If fails, fall back // to unefficient way. if (SrcDev.isDataExchangable(DstDev)) { AsyncInfoTy AsyncInfo(SrcDev); rc = SrcDev.dataExchange(srcAddr, DstDev, dstAddr, length, AsyncInfo); if (rc == OFFLOAD_SUCCESS) return OFFLOAD_SUCCESS; } void *buffer = malloc(length); { AsyncInfoTy AsyncInfo(SrcDev); rc = SrcDev.retrieveData(buffer, srcAddr, length, AsyncInfo); } if (rc == OFFLOAD_SUCCESS) { AsyncInfoTy AsyncInfo(SrcDev); rc = DstDev.submitData(dstAddr, buffer, length, AsyncInfo); } free(buffer); } DP("omp_target_memcpy returns %d\n", rc); return rc; } EXTERN int omp_target_memcpy_rect( void *dst, const 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) { TIMESCOPE(); 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) { REPORT("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; i < num_dims; ++i) { dst_slice_size *= dst_dimensions[i]; src_slice_size *= src_dimensions[i]; } size_t dst_off = dst_offsets[0] * dst_slice_size; size_t src_off = src_offsets[0] * src_slice_size; for (size_t i = 0; i < volume[0]; ++i) { rc = omp_target_memcpy_rect( (char *)dst + dst_off + dst_slice_size * i, (char *)const_cast(src) + src_off + src_slice_size * i, element_size, num_dims - 1, volume + 1, dst_offsets + 1, src_offsets + 1, dst_dimensions + 1, src_dimensions + 1, dst_device, src_device); if (rc) { DP("Recursive call to omp_target_memcpy_rect returns unsuccessfully\n"); return rc; } } } DP("omp_target_memcpy_rect returns %d\n", rc); return rc; } EXTERN int omp_target_associate_ptr(const void *host_ptr, const void *device_ptr, size_t size, size_t device_offset, int device_num) { TIMESCOPE(); DP("Call to omp_target_associate_ptr with host_ptr " DPxMOD ", " "device_ptr " DPxMOD ", size %zu, device_offset %zu, device_num %d\n", DPxPTR(host_ptr), DPxPTR(device_ptr), size, device_offset, device_num); if (!host_ptr || !device_ptr || size <= 0) { REPORT("Call to omp_target_associate_ptr with invalid arguments\n"); return OFFLOAD_FAIL; } if (device_num == omp_get_initial_device()) { REPORT("omp_target_associate_ptr: no association possible on the host\n"); return OFFLOAD_FAIL; } if (!device_is_ready(device_num)) { REPORT("omp_target_associate_ptr returns OFFLOAD_FAIL\n"); return OFFLOAD_FAIL; } DeviceTy &Device = *PM->Devices[device_num]; void *device_addr = (void *)((uint64_t)device_ptr + (uint64_t)device_offset); int rc = Device.associatePtr(const_cast(host_ptr), const_cast(device_addr), size); DP("omp_target_associate_ptr returns %d\n", rc); return rc; } EXTERN int omp_target_disassociate_ptr(const void *host_ptr, int device_num) { TIMESCOPE(); DP("Call to omp_target_disassociate_ptr with host_ptr " DPxMOD ", " "device_num %d\n", DPxPTR(host_ptr), device_num); if (!host_ptr) { REPORT("Call to omp_target_associate_ptr with invalid host_ptr\n"); return OFFLOAD_FAIL; } if (device_num == omp_get_initial_device()) { REPORT( "omp_target_disassociate_ptr: no association possible on the host\n"); return OFFLOAD_FAIL; } if (!device_is_ready(device_num)) { REPORT("omp_target_disassociate_ptr returns OFFLOAD_FAIL\n"); return OFFLOAD_FAIL; } DeviceTy &Device = *PM->Devices[device_num]; int rc = Device.disassociatePtr(const_cast(host_ptr)); DP("omp_target_disassociate_ptr returns %d\n", rc); return rc; }