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THCDeviceTensor.cuh
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THCDeviceTensor.cuh
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#ifndef THC_DEVICE_TENSOR_INC
#define THC_DEVICE_TENSOR_INC
#include <cuda.h>
#include <cuda_runtime.h>
// A CUDA 6.5 compatible version of static_assert. Remove once on CUDA 7.0.
template <bool>
struct THCStaticAssert;
template <>
struct THCStaticAssert<true> {
};
#define thc_static_assert(expr) (THCStaticAssert<(expr) != 0>())
/// Our tensor type
template <typename T,
int Dim,
typename IndexT,
template <typename U> class PtrTraits>
class THCDeviceTensor;
/// Type of a subspace of a tensor
namespace detail {
template <typename TensorType,
int SubDim,
template <typename U> class PtrTraits>
class THCDeviceSubTensor;
}
template <typename T>
struct RestrictPtrTraits {
typedef T* __restrict__ PtrType;
};
template <typename T>
struct DefaultPtrTraits {
typedef T* PtrType;
};
/**
Templated multi-dimensional array that supports strided access of
elements. Main access is through `operator[]`; e.g.,
`tensor[x][y][z]`.
- `T` is the contained type (e.g., `float`)
- `Dim` is the tensor rank
- `IndexT` is the integer type used for size/stride arrays, and for
- all indexing math. Default is `int`, but for large tensors, `int64_t`
- can be used instead.
- `PtrTraits` are traits applied to our data pointer (T*). By default,
- this is just T*, but RestrictPtrTraits can be used to apply T*
- __restrict__ for alias-free analysis.
*/
template <typename T,
int Dim,
typename IndexT = int,
template <typename U> class PtrTraits = DefaultPtrTraits>
class THCDeviceTensor {
public:
enum { NumDim = Dim };
typedef T DataType;
typedef IndexT IndexType;
typedef typename PtrTraits<T>::PtrType DataPtrType;
typedef THCDeviceTensor<T, Dim, IndexT, PtrTraits> TensorType;
/// Default constructor
__host__ __device__ THCDeviceTensor();
/// Constructor that calculates strides with no padding
__host__ __device__ THCDeviceTensor(DataPtrType data,
#ifdef _MSC_VER
const IndexT (&sizes)[Dim]);
#else
const IndexT sizes[Dim]);
#endif
/// Constructor that takes arbitrary size/stride arrays
__host__ __device__ THCDeviceTensor(DataPtrType data,
#ifdef _MSC_VER
const IndexT (&sizes)[Dim],
const IndexT (&strides)[Dim]);
#else
const IndexT sizes[Dim],
const IndexT strides[Dim]);
#endif
/// Returns true if the two tensors are of the same dimensionality,
/// size and stride.
template <int OtherDim>
__host__ __device__ bool
isSameSizeAndStride(
const THCDeviceTensor<T, OtherDim, IndexT, PtrTraits>& rhs) const;
/// Cast to a tensor of a different type of the same size and stride
template <typename U>
__host__ __device__ THCDeviceTensor<U, Dim, IndexT, PtrTraits> cast();
/// Const version of `cast`
template <typename U>
__host__ __device__
const THCDeviceTensor<U, Dim, IndexT, PtrTraits> cast() const;
/// Returns a raw pointer to the start of our data.
__host__ __device__ __forceinline__ DataPtrType data() {
return data_;
}
/// Returns a raw pointer to the start of our data (const).
__host__ __device__ __forceinline__
const DataPtrType data() const {
return data_;
}
/// Cast to a different datatype
template <typename U>
__host__ __device__ __forceinline__
typename PtrTraits<U>::PtrType dataAs() {
return reinterpret_cast<typename PtrTraits<U>::PtrType>(data_);
}
/// Cast to a different datatype
template <typename U>
__host__ __device__ __forceinline__
const typename PtrTraits<const U>::PtrType dataAs() const {
return reinterpret_cast<typename PtrTraits<const U>::PtrType>(data_);
}
/// Returns a read/write view of a portion of our tensor.
__host__ __device__ __forceinline__
detail::THCDeviceSubTensor<TensorType, Dim - 1, PtrTraits>
operator[](IndexT);
/// Returns a read/write view of a portion of our tensor (const).
__host__ __device__ __forceinline__
const detail::THCDeviceSubTensor<TensorType, Dim - 1, PtrTraits>
operator[](IndexT) const;
/// Returns the size of a given dimension, `[0, Dim - 1]`. No bounds
/// checking.
__host__ __device__ __forceinline__ int getSize(int i) const {
return size_[i];
}
/// Returns the stride of a given dimension, `[0, Dim - 1]`. No bounds
/// checking.
__host__ __device__ __forceinline__ int getStride(int i) const {
return stride_[i];
}
/// Returns the total number of elements contained within our data
/// (product of `getSize(i)`)
__host__ __device__ ptrdiff_t numElements() const;
/// Returns the size array.
__host__ __device__ __forceinline__ const IndexT* sizes() const {
return size_;
}
/// Returns the stride array.
__host__ __device__ __forceinline__ const IndexT* strides() const {
return stride_;
}
/// Returns true if there is no padding within the tensor and no
/// re-ordering of the dimensions.
/// ~~~
/// (stride(i) == size(i + 1) * stride(i + 1)) && stride(dim - 1) == 0
/// ~~~
__host__ __device__ bool isContiguous() const;
/// Returns whether a given dimension has only increasing stride
/// from the previous dimension. A tensor that was permuted by
/// exchanging size and stride only will fail this check.
/// If `i == 0` just check `size > 0`. Returns `false` if `stride` is `<= 0`.
__host__ __device__ bool isConsistentlySized(int i) const;
// Returns whether at each dimension `stride <= size`.
// If this is not the case then iterating once over the size space will
// touch the same memory locations multiple times.
__host__ __device__ bool isConsistentlySized() const;
/// Returns true if the given dimension range [first, last) has no padding.
__host__ __device__ bool isContiguousRange(int first, int last) const;
/// Returns a tensor of the same dimension after transposing the two
/// dimensions given. Does not actually move elements; transposition
/// is made by permuting the size/stride arrays.
/// If the dimensions are not valid, asserts.
__host__ __device__ THCDeviceTensor<T, Dim, IndexT, PtrTraits>
transpose(int dim1, int dim2) const;
/// Upcast a tensor of dimension `D` to some tensor of dimension
/// D' > D by padding the leading dimensions by 1
/// e.g., upcasting a 2-d tensor `[2][3]` to a 4-d tensor `[1][1][2][3]`
template <int NewDim>
__host__ __device__ THCDeviceTensor<T, NewDim, IndexT, PtrTraits>
upcastOuter();
/// Upcast a tensor of dimension `D` to some tensor of dimension
/// D' > D by padding the lowest/most varying dimensions by 1
/// e.g., upcasting a 2-d tensor `[2][3]` to a 4-d tensor `[2][3][1][1]`
template <int NewDim>
__host__ __device__ THCDeviceTensor<T, NewDim, IndexT, PtrTraits>
upcastInner();
/// Downcast a tensor of dimension `D` to some tensor of dimension
/// D' < D by collapsing the leading dimensions. asserts if there is
/// padding on the leading dimensions.
template <int NewDim>
__host__ __device__
THCDeviceTensor<T, NewDim, IndexT, PtrTraits> downcastOuter();
/// Downcast a tensor of dimension `D` to some tensor of dimension
/// D' < D by collapsing the leading dimensions. asserts if there is
/// padding on the leading dimensions.
template <int NewDim>
__host__ __device__
THCDeviceTensor<T, NewDim, IndexT, PtrTraits> downcastInner();
/// Returns a tensor that is a view of the `SubDim`-dimensional slice
/// of this tensor, starting at `at`.
template <int SubDim>
__host__ __device__ THCDeviceTensor<T, SubDim, IndexT, PtrTraits>
view(DataPtrType at);
/// Returns a tensor that is a view of the `SubDim`-dimensional slice
/// of this tensor, starting where our data begins
template <int SubDim>
__host__ __device__ THCDeviceTensor<T, SubDim, IndexT, PtrTraits>
view();
/// Zeroes out the tensor asynchronously. Asserts if the contents
/// in question are not contiguous.
void zero(cudaStream_t stream = 0);
private:
/// Raw pointer to where the tensor data begins
DataPtrType data_;
/// Array of strides (in sizeof(T) terms) per each dimension
IndexT stride_[Dim];
/// Size per each dimension
IndexT size_[Dim];
};
namespace detail {
/// Specialization for a view of a single value (0-dimensional)
template <typename TensorType, template <typename U> class PtrTraits>
class THCDeviceSubTensor<TensorType, 0, PtrTraits> {
public:
__host__ __device__ THCDeviceSubTensor<TensorType, 0, PtrTraits>
operator=(typename TensorType::DataType val) {
*data_ = val;
return *this;
}
// operator T&
__host__ __device__ operator typename TensorType::DataType&() {
return *data_;
}
// const operator T& returning const T&
__host__ __device__ operator const typename TensorType::DataType&() const {
return *data_;
}
// operator& returning T*
__host__ __device__ typename TensorType::DataType* operator&() {
return data_;
}
// const operator& returning const T*
__host__ __device__ const typename TensorType::DataType* operator&() const {
return data_;
}
/// Returns a raw accessor to our slice.
__host__ __device__ __forceinline__ typename TensorType::DataPtrType data() {
return data_;
}
/// Returns a raw accessor to our slice (const).
__host__ __device__ __forceinline__
const typename TensorType::DataPtrType data() const {
return data_;
}
/// Cast to a different datatype.
template <typename T>
__host__ __device__ T& as() {
return *dataAs<T>();
}
/// Cast to a different datatype (const).
template <typename T>
__host__ __device__ const T& as() const {
return *dataAs<T>();
}
/// Cast to a different datatype
template <typename T>
__host__ __device__ __forceinline__
typename PtrTraits<T>::PtrType dataAs() {
return reinterpret_cast<typename PtrTraits<T>::PtrType>(data_);
}
/// Cast to a different datatype (const)
template <typename T>
__host__ __device__ __forceinline__
typename PtrTraits<const T>::PtrType dataAs() const {
return reinterpret_cast<typename PtrTraits<const T>::PtrType>(data_);
}
/// Use the texture cache for reads
__device__ __forceinline__ typename TensorType::DataType ldg() const {
#if __CUDA_ARCH__ >= 350
return __ldg(data_);
#else
return *data_;
#endif
}
/// Use the texture cache for reads; cast as a particular type
template <typename T>
__device__ __forceinline__ T ldgAs() const {
#if __CUDA_ARCH__ >= 350
return __ldg(dataAs<T>());
#else
return as<T>();
#endif
}
private:
/// One dimension greater can create us
friend class THCDeviceSubTensor<TensorType, 1, PtrTraits>;
/// Our parent tensor can create us
friend class THCDeviceTensor<typename TensorType::DataType,
1,
typename TensorType::IndexType,
PtrTraits>;
__host__ __device__ __forceinline__ THCDeviceSubTensor(
TensorType& t,
typename TensorType::DataPtrType data)
: tensor_(t),
data_(data) {
}
/// The tensor we're referencing
TensorType& tensor_;
/// Where our value is located
typename TensorType::DataPtrType const data_;
};
/// A `SubDim`-rank slice of a parent THCDeviceTensor
template <typename TensorType,
int SubDim,
template <typename U> class PtrTraits>
class THCDeviceSubTensor {
public:
/// Returns a view of the data located at our offset (the dimension
/// `SubDim` - 1 tensor).
__host__ __device__ __forceinline__
THCDeviceSubTensor<TensorType, SubDim - 1, PtrTraits>
operator[](typename TensorType::IndexType index) {
return THCDeviceSubTensor<TensorType, SubDim - 1, PtrTraits>(
tensor_,
data_ + index * tensor_.getStride(TensorType::NumDim - SubDim));
}
/// Returns a view of the data located at our offset (the dimension
/// `SubDim` - 1 tensor) (const).
__host__ __device__ __forceinline__
const THCDeviceSubTensor<TensorType, SubDim - 1, PtrTraits>
operator[](typename TensorType::IndexType index) const {
return THCDeviceSubTensor<TensorType, SubDim - 1, PtrTraits>(
tensor_,
data_ + index * tensor_.getStride(TensorType::NumDim - SubDim));
}
// operator& returning T*
__host__ __device__ typename TensorType::DataType* operator&() {
return data_;
}
// const operator& returning const T*
__host__ __device__ const typename TensorType::DataType* operator&() const {
return data_;
}
/// Returns a raw accessor to our slice.
__host__ __device__ __forceinline__ typename TensorType::DataPtrType data() {
return data_;
}
/// Returns a raw accessor to our slice (const).
__host__ __device__ __forceinline__
const typename TensorType::DataPtrType data() const {
return data_;
}
/// Cast to a different datatype.
template <typename T>
__host__ __device__ T& as() {
return *dataAs<T>();
}
/// Cast to a different datatype (const).
template <typename T>
__host__ __device__ const T& as() const {
return *dataAs<T>();
}
/// Cast to a different datatype
template <typename T>
__host__ __device__ __forceinline__
typename PtrTraits<T>::PtrType dataAs() {
return reinterpret_cast<typename PtrTraits<T>::PtrType>(data_);
}
/// Cast to a different datatype (const)
template <typename T>
__host__ __device__ __forceinline__
typename PtrTraits<const T>::PtrType dataAs() const {
return reinterpret_cast<typename PtrTraits<const T>::PtrType>(data_);
}
/// Use the texture cache for reads
__device__ __forceinline__ typename TensorType::DataType ldg() const {
#if __CUDA_ARCH__ >= 350
return __ldg(data_);
#else
return *data_;
#endif
}
/// Use the texture cache for reads; cast as a particular type
template <typename T>
__device__ __forceinline__ T ldgAs() const {
#if __CUDA_ARCH__ >= 350
return __ldg(dataAs<T>());
#else
return as<T>();
#endif
}
/// Returns a tensor that is a view of the SubDim-dimensional slice
/// of this tensor, starting where our data begins
THCDeviceTensor<typename TensorType::DataType,
SubDim,
typename TensorType::IndexType,
PtrTraits> view() {
return tensor_.template view<SubDim>(data_);
}
private:
/// One dimension greater can create us
friend class THCDeviceSubTensor<TensorType, SubDim + 1, PtrTraits>;
/// Our parent tensor can create us
friend class
THCDeviceTensor<typename TensorType::DataType,
TensorType::NumDim,
typename TensorType::IndexType,
PtrTraits>;
__host__ __device__ __forceinline__ THCDeviceSubTensor(
TensorType& t,
typename TensorType::DataPtrType data)
: tensor_(t),
data_(data) {
}
/// The tensor we're referencing
TensorType& tensor_;
/// The start of our sub-region
typename TensorType::DataPtrType const data_;
};
} // namespace detail
template <typename T, int Dim,
typename IndexT, template <typename U> class PtrTraits>
__host__ __device__ __forceinline__
detail::THCDeviceSubTensor<THCDeviceTensor<T, Dim, IndexT, PtrTraits>,
Dim - 1, PtrTraits>
THCDeviceTensor<T, Dim, IndexT, PtrTraits>::operator[](IndexT index) {
return detail::THCDeviceSubTensor<TensorType, Dim - 1, PtrTraits>(
detail::THCDeviceSubTensor<TensorType, Dim, PtrTraits>(
*this, data_)[index]);
}
template <typename T, int Dim,
typename IndexT, template <typename U> class PtrTraits>
__host__ __device__ __forceinline__
const detail::THCDeviceSubTensor<THCDeviceTensor<T, Dim, IndexT, PtrTraits>,
Dim - 1, PtrTraits>
THCDeviceTensor<T, Dim, IndexT, PtrTraits>::operator[](IndexT index) const {
return detail::THCDeviceSubTensor<TensorType, Dim - 1, PtrTraits>(
detail::THCDeviceSubTensor<TensorType, Dim, PtrTraits>(
const_cast<TensorType&>(*this), data_)[index]);
}
#include <THC/THCDeviceTensor-inl.cuh>
#endif // THC_DEVICE_TENSOR_INC