#ifndef THC_GENERIC_FILE #define THC_GENERIC_FILE "generic/THCTensor.c" #else /**** access methods ****/ THCStorage *THCTensor_(storage)(THCState *state, const THCTensor *self) { return self->storage; } long THCTensor_(storageOffset)(THCState *state, const THCTensor *self) { return self->storageOffset; } int THCTensor_(nDimension)(THCState *state, const THCTensor *self) { return self->nDimension; } long THCTensor_(size)(THCState *state, const THCTensor *self, int dim) { THArgCheck((dim >= 0) && (dim < self->nDimension), 2, "out of range"); return self->size[dim]; } long THCTensor_(stride)(THCState *state, const THCTensor *self, int dim) { THArgCheck((dim >= 0) && (dim < self->nDimension), 2, "out of range"); return self->stride[dim]; } THLongStorage *THCTensor_(newSizeOf)(THCState *state, THCTensor *self) { THLongStorage *size = THLongStorage_newWithSize(self->nDimension); THLongStorage_rawCopy(size, self->size); return size; } THLongStorage *THCTensor_(newStrideOf)(THCState *state, THCTensor *self) { THLongStorage *stride = THLongStorage_newWithSize(self->nDimension); THLongStorage_rawCopy(stride, self->stride); return stride; } real *THCTensor_(data)(THCState *state, const THCTensor *self) { if(self->storage) return (self->storage->data+self->storageOffset); else return NULL; } void THCTensor_(setFlag)(THCState *state, THCTensor *self, const char flag) { self->flag |= flag; } void THCTensor_(clearFlag)(THCState *state, THCTensor *self, const char flag) { self->flag &= ~flag; } /**** creation methods ****/ static void THCTensor_(rawInit)(THCState *state, THCTensor *self); static void THCTensor_(rawSet)(THCState *state, THCTensor *self, THCStorage *storage, long storageOffset, int nDimension, long *size, long *stride); /* Empty init */ THCTensor *THCTensor_(new)(THCState *state) { THCTensor *self = (THCTensor*)THAlloc(sizeof(THCTensor)); THCTensor_(rawInit)(state, self); return self; } /* Pointer-copy init */ THCTensor *THCTensor_(newWithTensor)(THCState *state, THCTensor *tensor) { THCTensor *self = (THCTensor*)THAlloc(sizeof(THCTensor)); THCTensor_(rawInit)(state, self); THCTensor_(rawSet)(state, self, tensor->storage, tensor->storageOffset, tensor->nDimension, tensor->size, tensor->stride); return self; } /* Storage init */ THCTensor *THCTensor_(newWithStorage)(THCState *state, THCStorage *storage, long storageOffset, THLongStorage *size, THLongStorage *stride) { THCTensor *self = (THCTensor*)THAlloc(sizeof(THCTensor)); if(size && stride) THArgCheck(size->size == stride->size, 4, "inconsistent size"); THCTensor_(rawInit)(state, self); THCTensor_(rawSet)(state, self, storage, storageOffset, (size ? size->size : (stride ? stride->size : 0)), (size ? size->data : NULL), (stride ? stride->data : NULL)); return self; } THCTensor *THCTensor_(newWithStorage1d)(THCState *state, THCStorage *storage, long storageOffset, long size0, long stride0) { return THCTensor_(newWithStorage4d)(state, storage, storageOffset, size0, stride0, -1, -1, -1, -1, -1, -1); } THCTensor *THCTensor_(newWithStorage2d)(THCState *state, THCStorage *storage, long storageOffset, long size0, long stride0, long size1, long stride1) { return THCTensor_(newWithStorage4d)(state, storage, storageOffset, size0, stride0, size1, stride1, -1, -1, -1, -1); } THCTensor *THCTensor_(newWithStorage3d)(THCState *state, THCStorage *storage, long storageOffset, long size0, long stride0, long size1, long stride1, long size2, long stride2) { return THCTensor_(newWithStorage4d)(state, storage, storageOffset, size0, stride0, size1, stride1, size2, stride2, -1, -1); } THCTensor *THCTensor_(newWithStorage4d)(THCState *state, THCStorage *storage, long storageOffset, long size0, long stride0, long size1, long stride1, long size2, long stride2, long size3, long stride3) { long size[4] = {size0, size1, size2, size3}; long stride[4] = {stride0, stride1, stride2, stride3}; THCTensor *self = (THCTensor*)THAlloc(sizeof(THCTensor)); THCTensor_(rawInit)(state, self); THCTensor_(rawSet)(state, self, storage, storageOffset, 4, size, stride); return self; } THCTensor *THCTensor_(newWithSize)(THCState *state, THLongStorage *size, THLongStorage *stride) { return THCTensor_(newWithStorage)(state, NULL, 0, size, stride); } THCTensor *THCTensor_(newWithSize1d)(THCState *state, long size0) { return THCTensor_(newWithSize4d)(state, size0, -1, -1, -1); } THCTensor *THCTensor_(newWithSize2d)(THCState *state, long size0, long size1) { return THCTensor_(newWithSize4d)(state, size0, size1, -1, -1); } THCTensor *THCTensor_(newWithSize3d)(THCState *state, long size0, long size1, long size2) { return THCTensor_(newWithSize4d)(state, size0, size1, size2, -1); } THCTensor *THCTensor_(newWithSize4d)(THCState *state, long size0, long size1, long size2, long size3) { long size[4] = {size0, size1, size2, size3}; THCTensor *self = (THCTensor*)THAlloc(sizeof(THCTensor)); THCTensor_(rawInit)(state, self); THCTensor_(rawResize)(state, self, 4, size, NULL); return self; } THCTensor *THCTensor_(newClone)(THCState *state, THCTensor *self) { THCTensor *tensor = THCTensor_(new)(state); THCTensor_(resizeAs)(state, tensor, self); THCTensor_(copy)(state, tensor, self); return tensor; } THCTensor *THCTensor_(newContiguous)(THCState *state, THCTensor *self) { if(!THCTensor_(isContiguous)(state, self)) return THCTensor_(newClone)(state, self); else { THCTensor_(retain)(state, self); return self; } } THCTensor *THCTensor_(newSelect)(THCState *state, THCTensor *tensor, int dimension_, long sliceIndex_) { THCTensor *self = THCTensor_(newWithTensor)(state, tensor); THCTensor_(select)(state, self, NULL, dimension_, sliceIndex_); return self; } THCTensor *THCTensor_(newNarrow)(THCState *state, THCTensor *tensor, int dimension_, long firstIndex_, long size_) { THCTensor *self = THCTensor_(newWithTensor)(state, tensor); THCTensor_(narrow)(state, self, NULL, dimension_, firstIndex_, size_); return self; } THCTensor *THCTensor_(newTranspose)(THCState *state, THCTensor *tensor, int dimension1_, int dimension2_) { THCTensor *self = THCTensor_(newWithTensor)(state, tensor); THCTensor_(transpose)(state, self, NULL, dimension1_, dimension2_); return self; } THCTensor *THCTensor_(newUnfold)(THCState *state, THCTensor *tensor, int dimension_, long size_, long step_) { THCTensor *self = THCTensor_(newWithTensor)(state, tensor); THCTensor_(unfold)(state, self, NULL, dimension_, size_, step_); return self; } /* Resize */ void THCTensor_(resize)(THCState *state, THCTensor *self, THLongStorage *size, THLongStorage *stride) { THArgCheck(size != NULL, 2, "invalid size"); if(stride) THArgCheck(stride->size == size->size, 3, "invalid stride"); THCTensor_(rawResize)(state, self, size->size, size->data, (stride ? stride->data : NULL)); } void THCTensor_(resizeAs)(THCState *state, THCTensor *self, THCTensor *src) { int isSame = 0; int d; if(self->nDimension == src->nDimension) { isSame = 1; for(d = 0; d < self->nDimension; d++) { if(self->size[d] != src->size[d]) { isSame = 0; break; } } } if(!isSame) THCTensor_(rawResize)(state, self, src->nDimension, src->size, NULL); } void THCTensor_(resize1d)(THCState *state, THCTensor *tensor, long size0) { THCTensor_(resize4d)(state, tensor, size0, -1, -1, -1); } void THCTensor_(resize2d)(THCState *state, THCTensor *tensor, long size0, long size1) { THCTensor_(resize4d)(state, tensor, size0, size1, -1, -1); } void THCTensor_(resize3d)(THCState *state, THCTensor *tensor, long size0, long size1, long size2) { THCTensor_(resize4d)(state, tensor, size0, size1, size2, -1); } void THCTensor_(resize4d)(THCState *state, THCTensor *self, long size0, long size1, long size2, long size3) { long size[4] = {size0, size1, size2, size3}; THCTensor_(rawResize)(state, self, 4, size, NULL); } void THCTensor_(resize5d)(THCState *state, THCTensor *self, long size0, long size1, long size2, long size3, long size4) { long size[5] = {size0, size1, size2, size3, size4}; THCTensor_(rawResize)(state, self, 5, size, NULL); } void THCTensor_(set)(THCState *state, THCTensor *self, THCTensor *src) { if(self != src) THCTensor_(rawSet)(state, self, src->storage, src->storageOffset, src->nDimension, src->size, src->stride); } void THCTensor_(setStorage)(THCState *state, THCTensor *self, THCStorage *storage_, long storageOffset_, THLongStorage *size_, THLongStorage *stride_) { if(size_ && stride_) THArgCheck(size_->size == stride_->size, 5, "inconsistent size/stride sizes"); THCTensor_(rawSet)(state, self, storage_, storageOffset_, (size_ ? size_->size : (stride_ ? stride_->size : 0)), (size_ ? size_->data : NULL), (stride_ ? stride_->data : NULL)); } void THCTensor_(setStorage1d)(THCState *state, THCTensor *self, THCStorage *storage_, long storageOffset_, long size0_, long stride0_) { THCTensor_(setStorage4d)(state, self, storage_, storageOffset_, size0_, stride0_, -1, -1, -1, -1, -1, -1); } void THCTensor_(setStorage2d)(THCState *state, THCTensor *self, THCStorage *storage_, long storageOffset_, long size0_, long stride0_, long size1_, long stride1_) { THCTensor_(setStorage4d)(state, self, storage_, storageOffset_, size0_, stride0_, size1_, stride1_, -1, -1, -1, -1); } void THCTensor_(setStorage3d)(THCState *state, THCTensor *self, THCStorage *storage_, long storageOffset_, long size0_, long stride0_, long size1_, long stride1_, long size2_, long stride2_) { THCTensor_(setStorage4d)(state, self, storage_, storageOffset_, size0_, stride0_, size1_, stride1_, size2_, stride2_, -1, -1); } void THCTensor_(setStorage4d)(THCState *state, THCTensor *self, THCStorage *storage_, long storageOffset_, long size0_, long stride0_, long size1_, long stride1_, long size2_, long stride2_, long size3_, long stride3_) { long size[4] = {size0_, size1_, size2_, size3_}; long stride[4] = {stride0_, stride1_, stride2_, stride3_}; THCTensor_(rawSet)(state, self, storage_, storageOffset_, 4, size, stride); } void THCTensor_(narrow)(THCState *state, THCTensor *self, THCTensor *src, int dimension, long firstIndex, long size) { if(!src) src = self; THArgCheck( (dimension >= 0) && (dimension < src->nDimension), 3, "out of range"); THArgCheck( (firstIndex >= 0) && (firstIndex < src->size[dimension]), 4, "out of range"); THArgCheck( (size > 0) && (firstIndex+size <= src->size[dimension]), 5, "out of range"); THCTensor_(set)(state, self, src); if(firstIndex > 0) self->storageOffset += firstIndex*self->stride[dimension]; self->size[dimension] = size; } void THCTensor_(select)(THCState *state, THCTensor *self, THCTensor *src, int dimension, long sliceIndex) { int d; if(!src) src = self; THArgCheck(src->nDimension > 1, 1, "cannot select on a vector"); THArgCheck((dimension >= 0) && (dimension < src->nDimension), 3, "out of range"); THArgCheck((sliceIndex >= 0) && (sliceIndex < src->size[dimension]), 4, "out of range"); THCTensor_(set)(state, self, src); THCTensor_(narrow)(state, self, NULL, dimension, sliceIndex, 1); for(d = dimension; d < self->nDimension-1; d++) { self->size[d] = self->size[d+1]; self->stride[d] = self->stride[d+1]; } self->nDimension--; } void THCTensor_(transpose)(THCState *state, THCTensor *self, THCTensor *src, int dimension1, int dimension2) { long z; if(!src) src = self; THArgCheck( (dimension1 >= 0) && (dimension1 < src->nDimension), 1, "out of range"); THArgCheck( (dimension2 >= 0) && (dimension2 < src->nDimension), 2, "out of range"); THCTensor_(set)(state, self, src); if(dimension1 == dimension2) return; z = self->stride[dimension1]; self->stride[dimension1] = self->stride[dimension2]; self->stride[dimension2] = z; z = self->size[dimension1]; self->size[dimension1] = self->size[dimension2]; self->size[dimension2] = z; } void THCTensor_(unfold)(THCState *state, THCTensor *self, THCTensor *src, int dimension, long size, long step) { long *newSize; long *newStride; int d; if(!src) src = self; THArgCheck( (src->nDimension > 0), 1, "cannot unfold an empty tensor"); THArgCheck(dimension < src->nDimension, 2, "out of range"); THArgCheck(size <= src->size[dimension], 3, "out of range"); THArgCheck(step > 0, 4, "invalid step"); THCTensor_(set)(state, self, src); newSize = (long*)THAlloc(sizeof(long)*(self->nDimension+1)); newStride = (long*)THAlloc(sizeof(long)*(self->nDimension+1)); newSize[self->nDimension] = size; newStride[self->nDimension] = self->stride[dimension]; for(d = 0; d < self->nDimension; d++) { if(d == dimension) { newSize[d] = (self->size[d] - size) / step + 1; newStride[d] = step*self->stride[d]; } else { newSize[d] = self->size[d]; newStride[d] = self->stride[d]; } } THFree(self->size); THFree(self->stride); self->size = newSize; self->stride = newStride; self->nDimension++; } /* we have to handle the case where the result is a number */ void THCTensor_(squeeze)(THCState *state, THCTensor *self, THCTensor *src) { int ndim = 0; int d; if(!src) src = self; THCTensor_(set)(state, self, src); for(d = 0; d < src->nDimension; d++) { if(src->size[d] != 1) { if(d != ndim) { self->size[ndim] = src->size[d]; self->stride[ndim] = src->stride[d]; } ndim++; } } /* right now, we do not handle 0-dimension tensors */ if(ndim == 0 && src->nDimension > 0) { self->size[0] = 1; self->stride[0] = 1; ndim = 1; } self->nDimension = ndim; } void THCTensor_(squeeze1d)(THCState *state, THCTensor *self, THCTensor *src, int dimension) { int d; if(!src) src = self; THArgCheck(dimension < src->nDimension, 3, "dimension out of range"); THCTensor_(set)(state, self, src); if(src->size[dimension] == 1 && src->nDimension > 1) { for(d = dimension; d < self->nDimension-1; d++) { self->size[d] = self->size[d+1]; self->stride[d] = self->stride[d+1]; } self->nDimension--; } } int THCTensor_(isContiguous)(THCState *state, const THCTensor *self) { long z = 1; int d; for(d = self->nDimension-1; d >= 0; d--) { if(self->size[d] != 1) { if(self->stride[d] == z) z *= self->size[d]; else return 0; } } return 1; } int THCTensor_(isSize)(THCState *state, const THCTensor *self, const THLongStorage *dims) { int d; if (self->nDimension != dims->size) return 0; for (d = 0; d < self->nDimension; ++d) { if (self->size[d] != dims->data[d]) return 0; } return 1; } int THCTensor_(isSetTo)(THCState *state, const THCTensor *self, const THCTensor *src) { if (self->storage == src->storage && self->storageOffset == src->storageOffset && self->nDimension == src->nDimension) { int d; for (d = 0; d < self->nDimension; ++d) { if (self->size[d] != src->size[d] || self->stride[d] != src->stride[d]) return 0; } return 1; } return 0; } int THCTensor_(isSameSizeAs)(THCState *state, const THCTensor *self, const THCTensor* src) { int d; if (self->nDimension != src->nDimension) return 0; for(d = 0; d < self->nDimension; ++d) { if(self->size[d] != src->size[d]) return 0; } return 1; } long THCTensor_(nElement)(THCState *state, const THCTensor *self) { if(self->nDimension == 0) return 0; else { long nElement = 1; int d; for(d = 0; d < self->nDimension; d++) nElement *= self->size[d]; return nElement; } } void THCTensor_(retain)(THCState *state, THCTensor *self) { if(self->flag & TH_TENSOR_REFCOUNTED) THAtomicIncrementRef(&self->refcount); } void THCTensor_(free)(THCState *state, THCTensor *self) { if(!self) return; if(self->flag & TH_TENSOR_REFCOUNTED) { if(THAtomicDecrementRef(&self->refcount)) { THFree(self->size); THFree(self->stride); if(self->storage) THCStorage_(free)(state, self->storage); THFree(self); } } } void THCTensor_(freeCopyTo)(THCState *state, THCTensor *self, THCTensor *dst) { if(self != dst) THCTensor_(copy)(state, dst, self); THCTensor_(free)(state, self); } /*******************************************************************************/ static void THCTensor_(rawInit)(THCState *state, THCTensor *self) { self->refcount = 1; self->storage = NULL; self->storageOffset = 0; self->size = NULL; self->stride = NULL; self->nDimension = 0; self->flag = TH_TENSOR_REFCOUNTED; } static void THCTensor_(rawSet)(THCState *state, THCTensor *self, THCStorage *storage, long storageOffset, int nDimension, long *size, long *stride) { /* storage */ if(self->storage != storage) { if(self->storage) THCStorage_(free)(state, self->storage); if(storage) { self->storage = storage; THCStorage_(retain)(state, self->storage); } else self->storage = NULL; } /* storageOffset */ if(storageOffset < 0) THError("Tensor: invalid storage offset"); self->storageOffset = storageOffset; /* size and stride */ THCTensor_(rawResize)(state, self, nDimension, size, stride); } void THCTensor_(rawResize)(THCState *state, THCTensor *self, int nDimension, long *size, long *stride) { int d; int nDimension_; long totalSize; int hascorrectsize = 1; nDimension_ = 0; for(d = 0; d < nDimension; d++) { if(size[d] > 0) { nDimension_++; if((self->nDimension > d) && (size[d] != self->size[d])) hascorrectsize = 0; if((self->nDimension > d) && stride && (stride[d] >= 0) && (stride[d] != self->stride[d])) hascorrectsize = 0; } else break; } nDimension = nDimension_; if(nDimension != self->nDimension) hascorrectsize = 0; if(hascorrectsize) return; if(nDimension > 0) { if(nDimension != self->nDimension) { self->size = (long*)THRealloc(self->size, sizeof(long)*nDimension); self->stride = (long*)THRealloc(self->stride, sizeof(long)*nDimension); self->nDimension = nDimension; } totalSize = 1; for(d = self->nDimension-1; d >= 0; d--) { self->size[d] = size[d]; if(stride && (stride[d] >= 0) ) self->stride[d] = stride[d]; else { if(d == self->nDimension-1) self->stride[d] = 1; else self->stride[d] = self->size[d+1]*self->stride[d+1]; } totalSize += (self->size[d]-1)*self->stride[d]; } if(totalSize+self->storageOffset > 0) { if(!self->storage) self->storage = THCStorage_(new)(state); if(totalSize+self->storageOffset > self->storage->size) THCStorage_(resize)(state, self->storage, totalSize+self->storageOffset); } } else self->nDimension = 0; } void THCTensor_(set1d)(THCState *state, THCTensor *tensor, long x0, real value) { THArgCheck(tensor->nDimension == 1, 1, "tensor must have one dimension"); THArgCheck( (x0 >= 0) && (x0 < tensor->size[0]), 2, "out of range"); THCStorage_(set)(state, tensor->storage, tensor->storageOffset+x0*tensor->stride[0], value); } real THCTensor_(get1d)(THCState *state, const THCTensor *tensor, long x0) { THArgCheck(tensor->nDimension == 1, 1, "tensor must have one dimension"); THArgCheck( (x0 >= 0) && (x0 < tensor->size[0]), 2, "out of range"); return THCStorage_(get)(state, tensor->storage, tensor->storageOffset+x0*tensor->stride[0]); } void THCTensor_(set2d)(THCState *state, THCTensor *tensor, long x0, long x1, real value) { THArgCheck(tensor->nDimension == 2, 1, "tensor must have two dimensions"); THArgCheck((x0 >= 0) && (x0 < tensor->size[0]) && (x1 >= 0) && (x1 < tensor->size[1]), 2, "out of range"); THCStorage_(set)(state, tensor->storage, tensor->storageOffset+x0*tensor->stride[0]+x1*tensor->stride[1], value); } real THCTensor_(get2d)(THCState *state, const THCTensor *tensor, long x0, long x1) { THArgCheck(tensor->nDimension == 2, 1, "tensor must have two dimensions"); THArgCheck((x0 >= 0) && (x0 < tensor->size[0]) && (x1 >= 0) && (x1 < tensor->size[1]), 2, "out of range"); return THCStorage_(get)(state, tensor->storage, tensor->storageOffset+x0*tensor->stride[0]+x1*tensor->stride[1]); } void THCTensor_(set3d)(THCState *state, THCTensor *tensor, long x0, long x1, long x2, real value) { THArgCheck(tensor->nDimension == 3, 1, "tensor must have three dimensions"); THArgCheck( (x0 >= 0) && (x0 < tensor->size[0]) && (x1 >= 0) && (x1 < tensor->size[1]) && (x2 >= 0) && (x2 < tensor->size[2]), 2, "out of range"); THCStorage_(set)(state, tensor->storage, tensor->storageOffset+x0*tensor->stride[0]+x1*tensor->stride[1]+x2*tensor->stride[2], value); } real THCTensor_(get3d)(THCState *state, const THCTensor *tensor, long x0, long x1, long x2) { THArgCheck(tensor->nDimension == 3, 1, "tensor must have three dimensions"); THArgCheck( (x0 >= 0) && (x0 < tensor->size[0]) && (x1 >= 0) && (x1 < tensor->size[1]) && (x2 >= 0) && (x2 < tensor->size[2]), 2, "out of range"); return THCStorage_(get)(state, tensor->storage, tensor->storageOffset+x0*tensor->stride[0]+x1*tensor->stride[1]+x2*tensor->stride[2]); } void THCTensor_(set4d)(THCState *state, THCTensor *tensor, long x0, long x1, long x2, long x3, real value) { THArgCheck(tensor->nDimension == 4, 1, "tensor must have four dimensions"); THArgCheck((x0 >= 0) && (x0 < tensor->size[0]) && (x1 >= 0) && (x1 < tensor->size[1]) && (x2 >= 0) && (x2 < tensor->size[2]) && (x3 >= 0) && (x3 < tensor->size[3]), 2, "out of range"); THCStorage_(set)(state, tensor->storage, tensor->storageOffset+x0*tensor->stride[0]+x1*tensor->stride[1]+x2*tensor->stride[2]+x3*tensor->stride[3], value); } real THCTensor_(get4d)(THCState *state, const THCTensor *tensor, long x0, long x1, long x2, long x3) { THArgCheck(tensor->nDimension == 4, 1, "tensor must have four dimensions"); THArgCheck((x0 >= 0) && (x0 < tensor->size[0]) && (x1 >= 0) && (x1 < tensor->size[1]) && (x2 >= 0) && (x2 < tensor->size[2]) && (x3 >= 0) && (x3 < tensor->size[3]), 2, "out of range"); return THCStorage_(get)(state, tensor->storage, tensor->storageOffset+x0*tensor->stride[0]+x1*tensor->stride[1]+x2*tensor->stride[2]+x3*tensor->stride[3]); } int THCTensor_(checkGPU)(THCState *state, unsigned int nTensors, ...) { /* FIXME: remove this flag after any users stop using it since it is now superseded by the runtime option */ #ifdef DISABLE_CHECK_GPU return 1; #else int kernelP2PEnabled = THCState_getKernelPeerToPeerAccessEnabled(state); int curDev = -1; THCudaCheck(cudaGetDevice(&curDev)); va_list(args); va_start(args, nTensors); int valid = 1; for (unsigned int i = 0; i < nTensors; i++) { THCTensor* tensor = va_arg(args, THCTensor*); if (tensor == NULL) { continue; } int tensorDev = THCTensor_(getDevice)(state, tensor); if (tensorDev == -1) { /* This tensor does not have GPU memory (empty) */ continue; } if (tensorDev != curDev) { if (kernelP2PEnabled) { /* Kernel p2p access is allowed */ /* Can `curDev` access `tensorDev` directly? */ if (!THCState_getPeerToPeerAccess(state, curDev, tensorDev)) { valid = 0; break; } } else { /* No kernel p2p access allowed */ valid = 0; break; } } } va_end(args); return valid; #endif // DISABLE_CHECK_GPU } #endif