final/libomptarget/src/api.cpp - openmp - Git at Google

 //===----------- api.cpp - Target independent OpenMP target RTL -----------===//
 //
 //                     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 OpenMP API interface functions.
 //
 //===----------------------------------------------------------------------===//

 #include <omptarget.h>

 #include "device.h"
 #include "private.h"
 #include "rtl.h"

 #include <climits>
 #include <cstring>
 #include <cstdlib>

 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; 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 *) 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(void *host_ptr, void *device_ptr,
     size_t size, size_t device_offset, int device_num) {
   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) {
     DP("Call to omp_target_associate_ptr with invalid arguments\n");
     return OFFLOAD_FAIL;
   }

   if (device_num == omp_get_initial_device()) {
     DP("omp_target_associate_ptr: no association possible on the host\n");
     return OFFLOAD_FAIL;
   }

   if (!device_is_ready(device_num)) {
     DP("omp_target_associate_ptr returns OFFLOAD_FAIL\n");
     return OFFLOAD_FAIL;
   }

   DeviceTy& Device = Devices[device_num];
   void *device_addr = (void *)((uint64_t)device_ptr + (uint64_t)device_offset);
   int rc = Device.associatePtr(host_ptr, device_addr, size);
   DP("omp_target_associate_ptr returns %d\n", rc);
   return rc;
 }

 EXTERN int omp_target_disassociate_ptr(void *host_ptr, int device_num) {
   DP("Call to omp_target_disassociate_ptr with host_ptr " DPxMOD ", "
       "device_num %d\n", DPxPTR(host_ptr), device_num);

   if (!host_ptr) {
     DP("Call to omp_target_associate_ptr with invalid host_ptr\n");
     return OFFLOAD_FAIL;
   }

   if (device_num == omp_get_initial_device()) {
     DP("omp_target_disassociate_ptr: no association possible on the host\n");
     return OFFLOAD_FAIL;
   }

   if (!device_is_ready(device_num)) {
     DP("omp_target_disassociate_ptr returns OFFLOAD_FAIL\n");
     return OFFLOAD_FAIL;
   }

   DeviceTy& Device = Devices[device_num];
   int rc = Device.disassociatePtr(host_ptr);
   DP("omp_target_disassociate_ptr returns %d\n", rc);
   return rc;
 }
	//===----------- api.cpp - Target independent OpenMP target RTL -----------===//
	//
	// 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 OpenMP API interface functions.
	//
	//===----------------------------------------------------------------------===//

	#include <omptarget.h>

	#include "device.h"
	#include "private.h"
	#include "rtl.h"

	#include <climits>
	#include <cstring>
	#include <cstdlib>

	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; 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 ) 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(void host_ptr, void device_ptr,
	size_t size, size_t device_offset, int device_num) {
	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) {
	DP("Call to omp_target_associate_ptr with invalid arguments\n");
	return OFFLOAD_FAIL;
	}

	if (device_num == omp_get_initial_device()) {
	DP("omp_target_associate_ptr: no association possible on the host\n");
	return OFFLOAD_FAIL;
	}

	if (!device_is_ready(device_num)) {
	DP("omp_target_associate_ptr returns OFFLOAD_FAIL\n");
	return OFFLOAD_FAIL;
	}

	DeviceTy& Device = Devices[device_num];
	void device_addr = (void )((uint64_t)device_ptr + (uint64_t)device_offset);
	int rc = Device.associatePtr(host_ptr, device_addr, size);
	DP("omp_target_associate_ptr returns %d\n", rc);
	return rc;
	}

	EXTERN int omp_target_disassociate_ptr(void *host_ptr, int device_num) {
	DP("Call to omp_target_disassociate_ptr with host_ptr " DPxMOD ", "
	"device_num %d\n", DPxPTR(host_ptr), device_num);

	if (!host_ptr) {
	DP("Call to omp_target_associate_ptr with invalid host_ptr\n");
	return OFFLOAD_FAIL;
	}

	if (device_num == omp_get_initial_device()) {
	DP("omp_target_disassociate_ptr: no association possible on the host\n");
	return OFFLOAD_FAIL;
	}

	if (!device_is_ready(device_num)) {
	DP("omp_target_disassociate_ptr returns OFFLOAD_FAIL\n");
	return OFFLOAD_FAIL;
	}

	DeviceTy& Device = Devices[device_num];
	int rc = Device.disassociatePtr(host_ptr);
	DP("omp_target_disassociate_ptr returns %d\n", rc);
	return rc;
	}