unsupported/Eigen/CXX11/src/Tensor/TensorChipping.h - eigen - Git at Google

 // This file is part of Eigen, a lightweight C++ template library
 // for linear algebra.
 //
 // Copyright (C) 2014 Benoit Steiner <benoit.steiner.goog@gmail.com>
 //
 // This Source Code Form is subject to the terms of the Mozilla
 // Public License v. 2.0. If a copy of the MPL was not distributed
 // with this file, You can obtain one at http://mozilla.org/MPL/2.0/.

 #ifndef EIGEN_CXX11_TENSOR_TENSOR_CHIPPING_H
 #define EIGEN_CXX11_TENSOR_TENSOR_CHIPPING_H

 // IWYU pragma: private
 #include "./InternalHeaderCheck.h"

 namespace Eigen {

 /** \class TensorKChippingReshaping
  * \ingroup CXX11_Tensor_Module
  *
  * \brief A chip is a thin slice, corresponding to a column or a row in a 2-d tensor.
  *
  *
  */

 namespace internal {
 template <DenseIndex DimId, typename XprType>
 struct traits<TensorChippingOp<DimId, XprType> > : public traits<XprType> {
   typedef typename XprType::Scalar Scalar;
   typedef traits<XprType> XprTraits;
   typedef typename XprTraits::StorageKind StorageKind;
   typedef typename XprTraits::Index Index;
   typedef typename XprType::Nested Nested;
   typedef std::remove_reference_t<Nested> Nested_;
   static constexpr int NumDimensions = XprTraits::NumDimensions - 1;
   static constexpr int Layout = XprTraits::Layout;
   typedef typename XprTraits::PointerType PointerType;
 };

 template <DenseIndex DimId, typename XprType>
 struct eval<TensorChippingOp<DimId, XprType>, Eigen::Dense> {
   typedef const TensorChippingOp<DimId, XprType> EIGEN_DEVICE_REF type;
 };

 template <DenseIndex DimId, typename XprType>
 struct nested<TensorChippingOp<DimId, XprType>, 1, typename eval<TensorChippingOp<DimId, XprType> >::type> {
   typedef TensorChippingOp<DimId, XprType> type;
 };

 template <DenseIndex DimId>
 struct DimensionId {
   EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE DimensionId(DenseIndex dim) {
     EIGEN_UNUSED_VARIABLE(dim);
     eigen_assert(dim == DimId);
   }
   EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE DenseIndex actualDim() const { return DimId; }
 };
 template <>
 struct DimensionId<Dynamic> {
   EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE DimensionId(DenseIndex dim) : actual_dim(dim) { eigen_assert(dim >= 0); }
   EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE DenseIndex actualDim() const { return actual_dim; }

  private:
   const DenseIndex actual_dim;
 };

 }  // end namespace internal

 template <DenseIndex DimId, typename XprType>
 class TensorChippingOp : public TensorBase<TensorChippingOp<DimId, XprType> > {
  public:
   typedef TensorBase<TensorChippingOp<DimId, XprType> > Base;
   typedef typename Eigen::internal::traits<TensorChippingOp>::Scalar Scalar;
   typedef typename Eigen::NumTraits<Scalar>::Real RealScalar;
   typedef typename XprType::CoeffReturnType CoeffReturnType;
   typedef typename Eigen::internal::nested<TensorChippingOp>::type Nested;
   typedef typename Eigen::internal::traits<TensorChippingOp>::StorageKind StorageKind;
   typedef typename Eigen::internal::traits<TensorChippingOp>::Index Index;

   EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE TensorChippingOp(const XprType& expr, const Index offset, const Index dim)
       : m_xpr(expr), m_offset(offset), m_dim(dim) {
     eigen_assert(dim < XprType::NumDimensions && dim >= 0 && "Chip_Dim_out_of_range");
   }

   EIGEN_DEVICE_FUNC const Index offset() const { return m_offset; }
   EIGEN_DEVICE_FUNC const Index dim() const { return m_dim.actualDim(); }

   EIGEN_DEVICE_FUNC const internal::remove_all_t<typename XprType::Nested>& expression() const { return m_xpr; }

   EIGEN_TENSOR_INHERIT_ASSIGNMENT_OPERATORS(TensorChippingOp)

  protected:
   typename XprType::Nested m_xpr;
   const Index m_offset;
   const internal::DimensionId<DimId> m_dim;
 };

 // Eval as rvalue
 template <DenseIndex DimId, typename ArgType, typename Device>
 struct TensorEvaluator<const TensorChippingOp<DimId, ArgType>, Device> {
   typedef TensorChippingOp<DimId, ArgType> XprType;
   static constexpr int NumInputDims =
       internal::array_size<typename TensorEvaluator<ArgType, Device>::Dimensions>::value;
   static constexpr int NumDims = NumInputDims - 1;
   typedef typename XprType::Index Index;
   typedef DSizes<Index, NumDims> Dimensions;
   typedef typename XprType::Scalar Scalar;
   typedef typename XprType::CoeffReturnType CoeffReturnType;
   typedef typename PacketType<CoeffReturnType, Device>::type PacketReturnType;
   static constexpr int PacketSize = PacketType<CoeffReturnType, Device>::size;
   typedef StorageMemory<CoeffReturnType, Device> Storage;
   typedef typename Storage::Type EvaluatorPointerType;
   static constexpr int Layout = TensorEvaluator<ArgType, Device>::Layout;

   enum {
     // Alignment can't be guaranteed at compile time since it depends on the
     // slice offsets.
     IsAligned = false,
     PacketAccess = TensorEvaluator<ArgType, Device>::PacketAccess,
     BlockAccess = TensorEvaluator<ArgType, Device>::BlockAccess,
     // Chipping of outer-most dimension is a trivial operation, because we can
     // read and write directly from the underlying tensor using single offset.
     IsOuterChipping = (Layout == ColMajor && DimId == NumInputDims - 1) || (Layout == RowMajor && DimId == 0),
     // Chipping inner-most dimension.
     IsInnerChipping = (Layout == ColMajor && DimId == 0) || (Layout == RowMajor && DimId == NumInputDims - 1),
     // Prefer block access if the underlying expression prefers it, otherwise
     // only if chipping is not trivial.
     PreferBlockAccess = TensorEvaluator<ArgType, Device>::PreferBlockAccess || !IsOuterChipping,
     CoordAccess = false,  // to be implemented
     RawAccess = false
   };

   typedef std::remove_const_t<Scalar> ScalarNoConst;

   //===- Tensor block evaluation strategy (see TensorBlock.h) -------------===//
   typedef internal::TensorBlockDescriptor<NumDims, Index> TensorBlockDesc;
   typedef internal::TensorBlockScratchAllocator<Device> TensorBlockScratch;

   typedef internal::TensorBlockDescriptor<NumInputDims, Index> ArgTensorBlockDesc;
   typedef typename TensorEvaluator<const ArgType, Device>::TensorBlock ArgTensorBlock;

   typedef typename internal::TensorMaterializedBlock<ScalarNoConst, NumDims, Layout, Index> TensorBlock;
   //===--------------------------------------------------------------------===//

   EIGEN_STRONG_INLINE TensorEvaluator(const XprType& op, const Device& device)
       : m_impl(op.expression(), device), m_dim(op.dim()), m_device(device) {
     EIGEN_STATIC_ASSERT((NumInputDims >= 1), YOU_MADE_A_PROGRAMMING_MISTAKE);
     eigen_assert(NumInputDims > m_dim.actualDim());

     const typename TensorEvaluator<ArgType, Device>::Dimensions& input_dims = m_impl.dimensions();
     eigen_assert(op.offset() < input_dims[m_dim.actualDim()]);

     int j = 0;
     for (int i = 0; i < NumInputDims; ++i) {
       if (i != m_dim.actualDim()) {
         m_dimensions[j] = input_dims[i];
         ++j;
       }
     }

     m_stride = 1;
     m_inputStride = 1;
     if (static_cast<int>(Layout) == static_cast<int>(ColMajor)) {
       for (int i = 0; i < m_dim.actualDim(); ++i) {
         m_stride *= input_dims[i];
         m_inputStride *= input_dims[i];
       }
     } else {
       for (int i = NumInputDims - 1; i > m_dim.actualDim(); --i) {
         m_stride *= input_dims[i];
         m_inputStride *= input_dims[i];
       }
     }
     m_inputStride *= input_dims[m_dim.actualDim()];
     m_inputOffset = m_stride * op.offset();
   }

   EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE const Dimensions& dimensions() const { return m_dimensions; }

   EIGEN_STRONG_INLINE bool evalSubExprsIfNeeded(EvaluatorPointerType) {
     m_impl.evalSubExprsIfNeeded(NULL);
     return true;
   }

   EIGEN_STRONG_INLINE void cleanup() { m_impl.cleanup(); }

   EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE CoeffReturnType coeff(Index index) const {
     return m_impl.coeff(srcCoeff(index));
   }

   template <int LoadMode>
   EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE PacketReturnType packet(Index index) const {
     eigen_assert(index + PacketSize - 1 < dimensions().TotalSize());

     if (isInnerChipping()) {
       // m_stride is equal to 1, so let's avoid the integer division.
       eigen_assert(m_stride == 1);
       Index inputIndex = index * m_inputStride + m_inputOffset;
       EIGEN_ALIGN_MAX std::remove_const_t<CoeffReturnType> values[PacketSize];
       EIGEN_UNROLL_LOOP
       for (int i = 0; i < PacketSize; ++i) {
         values[i] = m_impl.coeff(inputIndex);
         inputIndex += m_inputStride;
       }
       PacketReturnType rslt = internal::pload<PacketReturnType>(values);
       return rslt;
     } else if (isOuterChipping()) {
       // m_stride is always greater than index, so let's avoid the integer division.
       eigen_assert(m_stride > index);
       return m_impl.template packet<LoadMode>(index + m_inputOffset);
     } else {
       const Index idx = index / m_stride;
       const Index rem = index - idx * m_stride;
       if (rem + PacketSize <= m_stride) {
         Index inputIndex = idx * m_inputStride + m_inputOffset + rem;
         return m_impl.template packet<LoadMode>(inputIndex);
       } else {
         // Cross the stride boundary. Fallback to slow path.
         EIGEN_ALIGN_MAX std::remove_const_t<CoeffReturnType> values[PacketSize];
         EIGEN_UNROLL_LOOP
         for (int i = 0; i < PacketSize; ++i) {
           values[i] = coeff(index);
           ++index;
         }
         PacketReturnType rslt = internal::pload<PacketReturnType>(values);
         return rslt;
       }
     }
   }

   EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE TensorOpCost costPerCoeff(bool vectorized) const {
     double cost = 0;
     if ((static_cast<int>(Layout) == static_cast<int>(ColMajor) && m_dim.actualDim() == 0) ||
         (static_cast<int>(Layout) == static_cast<int>(RowMajor) && m_dim.actualDim() == NumInputDims - 1)) {
       cost += TensorOpCost::MulCost<Index>() + TensorOpCost::AddCost<Index>();
     } else if ((static_cast<int>(Layout) == static_cast<int>(ColMajor) && m_dim.actualDim() == NumInputDims - 1) ||
                (static_cast<int>(Layout) == static_cast<int>(RowMajor) && m_dim.actualDim() == 0)) {
       cost += TensorOpCost::AddCost<Index>();
     } else {
       cost += 3 * TensorOpCost::MulCost<Index>() + TensorOpCost::DivCost<Index>() + 3 * TensorOpCost::AddCost<Index>();
     }

     return m_impl.costPerCoeff(vectorized) + TensorOpCost(0, 0, cost, vectorized, PacketSize);
   }

   EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE internal::TensorBlockResourceRequirements getResourceRequirements() const {
     const size_t target_size = m_device.lastLevelCacheSize();
     return internal::TensorBlockResourceRequirements::merge(
         internal::TensorBlockResourceRequirements::skewed<Scalar>(target_size), m_impl.getResourceRequirements());
   }

   EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE TensorBlock block(TensorBlockDesc& desc, TensorBlockScratch& scratch,
                                                           bool root_of_expr_ast = false) const {
     const Index chip_dim = m_dim.actualDim();

     DSizes<Index, NumInputDims> input_block_dims;
     for (int i = 0; i < NumInputDims; ++i) {
       input_block_dims[i] = i < chip_dim ? desc.dimension(i) : i > chip_dim ? desc.dimension(i - 1) : 1;
     }

     ArgTensorBlockDesc arg_desc(srcCoeff(desc.offset()), input_block_dims);

     // Try to reuse destination buffer for materializing argument block.
     if (desc.HasDestinationBuffer()) {
       DSizes<Index, NumInputDims> arg_destination_strides;
       for (int i = 0; i < NumInputDims; ++i) {
         arg_destination_strides[i] = i < chip_dim   ? desc.destination().strides()[i]
                                      : i > chip_dim ? desc.destination().strides()[i - 1]
                                                     : 0;  // for dimensions of size `1` stride should never be used.
       }

       arg_desc.template AddDestinationBuffer<Layout>(desc.destination().template data<ScalarNoConst>(),
                                                      arg_destination_strides);
     }

     ArgTensorBlock arg_block = m_impl.block(arg_desc, scratch, root_of_expr_ast);
     if (!arg_desc.HasDestinationBuffer()) desc.DropDestinationBuffer();

     if (arg_block.data() != NULL) {
       // Forward argument block buffer if possible.
       return TensorBlock(arg_block.kind(), arg_block.data(), desc.dimensions());

     } else {
       // Assign argument block expression to a buffer.

       // Prepare storage for the materialized chipping result.
       const typename TensorBlock::Storage block_storage = TensorBlock::prepareStorage(desc, scratch);

       typedef internal::TensorBlockAssignment<ScalarNoConst, NumInputDims, typename ArgTensorBlock::XprType, Index>
           TensorBlockAssignment;

       TensorBlockAssignment::Run(
           TensorBlockAssignment::target(arg_desc.dimensions(), internal::strides<Layout>(arg_desc.dimensions()),
                                         block_storage.data()),
           arg_block.expr());

       return block_storage.AsTensorMaterializedBlock();
     }
   }

   EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE typename Storage::Type data() const {
     typename Storage::Type result = constCast(m_impl.data());
     if (isOuterChipping() && result) {
       return result + m_inputOffset;
     } else {
       return NULL;
     }
   }

  protected:
   EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE Index srcCoeff(Index index) const {
     Index inputIndex;
     if (isInnerChipping()) {
       // m_stride is equal to 1, so let's avoid the integer division.
       eigen_assert(m_stride == 1);
       inputIndex = index * m_inputStride + m_inputOffset;
     } else if (isOuterChipping()) {
       // m_stride is always greater than index, so let's avoid the integer
       // division.
       eigen_assert(m_stride > index);
       inputIndex = index + m_inputOffset;
     } else {
       const Index idx = index / m_stride;
       inputIndex = idx * m_inputStride + m_inputOffset;
       index -= idx * m_stride;
       inputIndex += index;
     }
     return inputIndex;
   }

   EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE bool isInnerChipping() const {
     return IsInnerChipping || (static_cast<int>(Layout) == ColMajor && m_dim.actualDim() == 0) ||
            (static_cast<int>(Layout) == RowMajor && m_dim.actualDim() == NumInputDims - 1);
   }

   EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE bool isOuterChipping() const {
     return IsOuterChipping || (static_cast<int>(Layout) == ColMajor && m_dim.actualDim() == NumInputDims - 1) ||
            (static_cast<int>(Layout) == RowMajor && m_dim.actualDim() == 0);
   }

   Dimensions m_dimensions;
   Index m_stride;
   Index m_inputOffset;
   Index m_inputStride;
   TensorEvaluator<ArgType, Device> m_impl;
   const internal::DimensionId<DimId> m_dim;
   const Device EIGEN_DEVICE_REF m_device;
 };

 // Eval as lvalue
 template <DenseIndex DimId, typename ArgType, typename Device>
 struct TensorEvaluator<TensorChippingOp<DimId, ArgType>, Device>
     : public TensorEvaluator<const TensorChippingOp<DimId, ArgType>, Device> {
   typedef TensorEvaluator<const TensorChippingOp<DimId, ArgType>, Device> Base;
   typedef TensorChippingOp<DimId, ArgType> XprType;
   static constexpr int NumInputDims =
       internal::array_size<typename TensorEvaluator<ArgType, Device>::Dimensions>::value;
   static constexpr int NumDims = NumInputDims - 1;
   typedef typename XprType::Index Index;
   typedef DSizes<Index, NumDims> Dimensions;
   typedef typename XprType::Scalar Scalar;
   typedef typename XprType::CoeffReturnType CoeffReturnType;
   typedef typename PacketType<CoeffReturnType, Device>::type PacketReturnType;
   static constexpr int PacketSize = PacketType<CoeffReturnType, Device>::size;

   enum {
     IsAligned = false,
     PacketAccess = TensorEvaluator<ArgType, Device>::PacketAccess,
     BlockAccess = TensorEvaluator<ArgType, Device>::RawAccess,
     Layout = TensorEvaluator<ArgType, Device>::Layout,
     RawAccess = false
   };

   //===- Tensor block evaluation strategy (see TensorBlock.h) -------------===//
   typedef internal::TensorBlockDescriptor<NumDims, Index> TensorBlockDesc;
   //===--------------------------------------------------------------------===//

   EIGEN_STRONG_INLINE TensorEvaluator(const XprType& op, const Device& device) : Base(op, device) {}

   EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE CoeffReturnType& coeffRef(Index index) const {
     return this->m_impl.coeffRef(this->srcCoeff(index));
   }

   template <int StoreMode>
   EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE void writePacket(Index index, const PacketReturnType& x) const {
     if (this->isInnerChipping()) {
       // m_stride is equal to 1, so let's avoid the integer division.
       eigen_assert(this->m_stride == 1);
       EIGEN_ALIGN_MAX std::remove_const_t<CoeffReturnType> values[PacketSize];
       internal::pstore<CoeffReturnType, PacketReturnType>(values, x);
       Index inputIndex = index * this->m_inputStride + this->m_inputOffset;
       EIGEN_UNROLL_LOOP
       for (int i = 0; i < PacketSize; ++i) {
         this->m_impl.coeffRef(inputIndex) = values[i];
         inputIndex += this->m_inputStride;
       }
     } else if (this->isOuterChipping()) {
       // m_stride is always greater than index, so let's avoid the integer division.
       eigen_assert(this->m_stride > index);
       this->m_impl.template writePacket<StoreMode>(index + this->m_inputOffset, x);
     } else {
       const Index idx = index / this->m_stride;
       const Index rem = index - idx * this->m_stride;
       if (rem + PacketSize <= this->m_stride) {
         const Index inputIndex = idx * this->m_inputStride + this->m_inputOffset + rem;
         this->m_impl.template writePacket<StoreMode>(inputIndex, x);
       } else {
         // Cross stride boundary. Fallback to slow path.
         EIGEN_ALIGN_MAX std::remove_const_t<CoeffReturnType> values[PacketSize];
         internal::pstore<CoeffReturnType, PacketReturnType>(values, x);
         EIGEN_UNROLL_LOOP
         for (int i = 0; i < PacketSize; ++i) {
           this->coeffRef(index) = values[i];
           ++index;
         }
       }
     }
   }

   template <typename TensorBlock>
   EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE void writeBlock(const TensorBlockDesc& desc, const TensorBlock& block) {
     eigen_assert(this->m_impl.data() != NULL);

     const Index chip_dim = this->m_dim.actualDim();

     DSizes<Index, NumInputDims> input_block_dims;
     for (int i = 0; i < NumInputDims; ++i) {
       input_block_dims[i] = i < chip_dim ? desc.dimension(i) : i > chip_dim ? desc.dimension(i - 1) : 1;
     }

     typedef TensorReshapingOp<const DSizes<Index, NumInputDims>, const typename TensorBlock::XprType> TensorBlockExpr;

     typedef internal::TensorBlockAssignment<Scalar, NumInputDims, TensorBlockExpr, Index> TensorBlockAssign;

     TensorBlockAssign::Run(
         TensorBlockAssign::target(input_block_dims, internal::strides<Layout>(this->m_impl.dimensions()),
                                   this->m_impl.data(), this->srcCoeff(desc.offset())),
         block.expr().reshape(input_block_dims));
   }
 };

 }  // end namespace Eigen

 #endif  // EIGEN_CXX11_TENSOR_TENSOR_CHIPPING_H
	// This file is part of Eigen, a lightweight C++ template library
	// for linear algebra.
	//
	// Copyright (C) 2014 Benoit Steiner <benoit.steiner.goog@gmail.com>
	//
	// This Source Code Form is subject to the terms of the Mozilla
	// Public License v. 2.0. If a copy of the MPL was not distributed
	// with this file, You can obtain one at http://mozilla.org/MPL/2.0/.

	#ifndef EIGEN_CXX11_TENSOR_TENSOR_CHIPPING_H
	#define EIGEN_CXX11_TENSOR_TENSOR_CHIPPING_H

	// IWYU pragma: private
	#include "./InternalHeaderCheck.h"

	namespace Eigen {

	/** \class TensorKChippingReshaping
	* \ingroup CXX11_Tensor_Module
	*
	* \brief A chip is a thin slice, corresponding to a column or a row in a 2-d tensor.
	*
	*
	*/

	namespace internal {
	template <DenseIndex DimId, typename XprType>
	struct traits<TensorChippingOp<DimId, XprType> > : public traits<XprType> {
	typedef typename XprType::Scalar Scalar;
	typedef traits<XprType> XprTraits;
	typedef typename XprTraits::StorageKind StorageKind;
	typedef typename XprTraits::Index Index;
	typedef typename XprType::Nested Nested;
	typedef std::remove_reference_t<Nested> Nested_;
	static constexpr int NumDimensions = XprTraits::NumDimensions - 1;
	static constexpr int Layout = XprTraits::Layout;
	typedef typename XprTraits::PointerType PointerType;
	};

	template <DenseIndex DimId, typename XprType>
	struct eval<TensorChippingOp<DimId, XprType>, Eigen::Dense> {
	typedef const TensorChippingOp<DimId, XprType> EIGEN_DEVICE_REF type;
	};

	template <DenseIndex DimId, typename XprType>
	struct nested<TensorChippingOp<DimId, XprType>, 1, typename eval<TensorChippingOp<DimId, XprType> >::type> {
	typedef TensorChippingOp<DimId, XprType> type;
	};

	template <DenseIndex DimId>
	struct DimensionId {
	EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE DimensionId(DenseIndex dim) {
	EIGEN_UNUSED_VARIABLE(dim);
	eigen_assert(dim == DimId);
	}
	EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE DenseIndex actualDim() const { return DimId; }
	};
	template <>
	struct DimensionId<Dynamic> {
	EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE DimensionId(DenseIndex dim) : actual_dim(dim) { eigen_assert(dim >= 0); }
	EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE DenseIndex actualDim() const { return actual_dim; }

	private:
	const DenseIndex actual_dim;
	};

	} // end namespace internal

	template <DenseIndex DimId, typename XprType>
	class TensorChippingOp : public TensorBase<TensorChippingOp<DimId, XprType> > {
	public:
	typedef TensorBase<TensorChippingOp<DimId, XprType> > Base;
	typedef typename Eigen::internal::traits<TensorChippingOp>::Scalar Scalar;
	typedef typename Eigen::NumTraits<Scalar>::Real RealScalar;
	typedef typename XprType::CoeffReturnType CoeffReturnType;
	typedef typename Eigen::internal::nested<TensorChippingOp>::type Nested;
	typedef typename Eigen::internal::traits<TensorChippingOp>::StorageKind StorageKind;
	typedef typename Eigen::internal::traits<TensorChippingOp>::Index Index;

	EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE TensorChippingOp(const XprType& expr, const Index offset, const Index dim)
	: m_xpr(expr), m_offset(offset), m_dim(dim) {
	eigen_assert(dim < XprType::NumDimensions && dim >= 0 && "Chip_Dim_out_of_range");
	}

	EIGEN_DEVICE_FUNC const Index offset() const { return m_offset; }
	EIGEN_DEVICE_FUNC const Index dim() const { return m_dim.actualDim(); }

	EIGEN_DEVICE_FUNC const internal::remove_all_t<typename XprType::Nested>& expression() const { return m_xpr; }

	EIGEN_TENSOR_INHERIT_ASSIGNMENT_OPERATORS(TensorChippingOp)

	protected:
	typename XprType::Nested m_xpr;
	const Index m_offset;
	const internal::DimensionId<DimId> m_dim;
	};

	// Eval as rvalue
	template <DenseIndex DimId, typename ArgType, typename Device>
	struct TensorEvaluator<const TensorChippingOp<DimId, ArgType>, Device> {
	typedef TensorChippingOp<DimId, ArgType> XprType;
	static constexpr int NumInputDims =
	internal::array_size<typename TensorEvaluator<ArgType, Device>::Dimensions>::value;
	static constexpr int NumDims = NumInputDims - 1;
	typedef typename XprType::Index Index;
	typedef DSizes<Index, NumDims> Dimensions;
	typedef typename XprType::Scalar Scalar;
	typedef typename XprType::CoeffReturnType CoeffReturnType;
	typedef typename PacketType<CoeffReturnType, Device>::type PacketReturnType;
	static constexpr int PacketSize = PacketType<CoeffReturnType, Device>::size;
	typedef StorageMemory<CoeffReturnType, Device> Storage;
	typedef typename Storage::Type EvaluatorPointerType;
	static constexpr int Layout = TensorEvaluator<ArgType, Device>::Layout;

	enum {
	// Alignment can't be guaranteed at compile time since it depends on the
	// slice offsets.
	IsAligned = false,
	PacketAccess = TensorEvaluator<ArgType, Device>::PacketAccess,
	BlockAccess = TensorEvaluator<ArgType, Device>::BlockAccess,
	// Chipping of outer-most dimension is a trivial operation, because we can
	// read and write directly from the underlying tensor using single offset.
	IsOuterChipping = (Layout == ColMajor && DimId == NumInputDims - 1) \|\| (Layout == RowMajor && DimId == 0),
	// Chipping inner-most dimension.
	IsInnerChipping = (Layout == ColMajor && DimId == 0) \|\| (Layout == RowMajor && DimId == NumInputDims - 1),
	// Prefer block access if the underlying expression prefers it, otherwise
	// only if chipping is not trivial.
	PreferBlockAccess = TensorEvaluator<ArgType, Device>::PreferBlockAccess \|\| !IsOuterChipping,
	CoordAccess = false, // to be implemented
	RawAccess = false
	};

	typedef std::remove_const_t<Scalar> ScalarNoConst;

	//===- Tensor block evaluation strategy (see TensorBlock.h) -------------===//
	typedef internal::TensorBlockDescriptor<NumDims, Index> TensorBlockDesc;
	typedef internal::TensorBlockScratchAllocator<Device> TensorBlockScratch;

	typedef internal::TensorBlockDescriptor<NumInputDims, Index> ArgTensorBlockDesc;
	typedef typename TensorEvaluator<const ArgType, Device>::TensorBlock ArgTensorBlock;

	typedef typename internal::TensorMaterializedBlock<ScalarNoConst, NumDims, Layout, Index> TensorBlock;
	//===--------------------------------------------------------------------===//

	EIGEN_STRONG_INLINE TensorEvaluator(const XprType& op, const Device& device)
	: m_impl(op.expression(), device), m_dim(op.dim()), m_device(device) {
	EIGEN_STATIC_ASSERT((NumInputDims >= 1), YOU_MADE_A_PROGRAMMING_MISTAKE);
	eigen_assert(NumInputDims > m_dim.actualDim());

	const typename TensorEvaluator<ArgType, Device>::Dimensions& input_dims = m_impl.dimensions();
	eigen_assert(op.offset() < input_dims[m_dim.actualDim()]);

	int j = 0;
	for (int i = 0; i < NumInputDims; ++i) {
	if (i != m_dim.actualDim()) {
	m_dimensions[j] = input_dims[i];
	++j;
	}
	}

	m_stride = 1;
	m_inputStride = 1;
	if (static_cast<int>(Layout) == static_cast<int>(ColMajor)) {
	for (int i = 0; i < m_dim.actualDim(); ++i) {
	m_stride *= input_dims[i];
	m_inputStride *= input_dims[i];
	}
	} else {
	for (int i = NumInputDims - 1; i > m_dim.actualDim(); --i) {
	m_stride *= input_dims[i];
	m_inputStride *= input_dims[i];
	}
	}
	m_inputStride *= input_dims[m_dim.actualDim()];
	m_inputOffset = m_stride * op.offset();
	}

	EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE const Dimensions& dimensions() const { return m_dimensions; }

	EIGEN_STRONG_INLINE bool evalSubExprsIfNeeded(EvaluatorPointerType) {
	m_impl.evalSubExprsIfNeeded(NULL);
	return true;
	}

	EIGEN_STRONG_INLINE void cleanup() { m_impl.cleanup(); }

	EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE CoeffReturnType coeff(Index index) const {
	return m_impl.coeff(srcCoeff(index));
	}

	template <int LoadMode>
	EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE PacketReturnType packet(Index index) const {
	eigen_assert(index + PacketSize - 1 < dimensions().TotalSize());

	if (isInnerChipping()) {
	// m_stride is equal to 1, so let's avoid the integer division.
	eigen_assert(m_stride == 1);
	Index inputIndex = index * m_inputStride + m_inputOffset;
	EIGEN_ALIGN_MAX std::remove_const_t<CoeffReturnType> values[PacketSize];
	EIGEN_UNROLL_LOOP
	for (int i = 0; i < PacketSize; ++i) {
	values[i] = m_impl.coeff(inputIndex);
	inputIndex += m_inputStride;
	}
	PacketReturnType rslt = internal::pload<PacketReturnType>(values);
	return rslt;
	} else if (isOuterChipping()) {
	// m_stride is always greater than index, so let's avoid the integer division.
	eigen_assert(m_stride > index);
	return m_impl.template packet<LoadMode>(index + m_inputOffset);
	} else {
	const Index idx = index / m_stride;
	const Index rem = index - idx * m_stride;
	if (rem + PacketSize <= m_stride) {
	Index inputIndex = idx * m_inputStride + m_inputOffset + rem;
	return m_impl.template packet<LoadMode>(inputIndex);
	} else {
	// Cross the stride boundary. Fallback to slow path.
	EIGEN_ALIGN_MAX std::remove_const_t<CoeffReturnType> values[PacketSize];
	EIGEN_UNROLL_LOOP
	for (int i = 0; i < PacketSize; ++i) {
	values[i] = coeff(index);
	++index;
	}
	PacketReturnType rslt = internal::pload<PacketReturnType>(values);
	return rslt;
	}
	}
	}

	EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE TensorOpCost costPerCoeff(bool vectorized) const {
	double cost = 0;
	if ((static_cast<int>(Layout) == static_cast<int>(ColMajor) && m_dim.actualDim() == 0) \|\|
	(static_cast<int>(Layout) == static_cast<int>(RowMajor) && m_dim.actualDim() == NumInputDims - 1)) {
	cost += TensorOpCost::MulCost<Index>() + TensorOpCost::AddCost<Index>();
	} else if ((static_cast<int>(Layout) == static_cast<int>(ColMajor) && m_dim.actualDim() == NumInputDims - 1) \|\|
	(static_cast<int>(Layout) == static_cast<int>(RowMajor) && m_dim.actualDim() == 0)) {
	cost += TensorOpCost::AddCost<Index>();
	} else {
	cost += 3 * TensorOpCost::MulCost<Index>() + TensorOpCost::DivCost<Index>() + 3 * TensorOpCost::AddCost<Index>();
	}

	return m_impl.costPerCoeff(vectorized) + TensorOpCost(0, 0, cost, vectorized, PacketSize);
	}

	EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE internal::TensorBlockResourceRequirements getResourceRequirements() const {
	const size_t target_size = m_device.lastLevelCacheSize();
	return internal::TensorBlockResourceRequirements::merge(
	internal::TensorBlockResourceRequirements::skewed<Scalar>(target_size), m_impl.getResourceRequirements());
	}

	EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE TensorBlock block(TensorBlockDesc& desc, TensorBlockScratch& scratch,
	bool root_of_expr_ast = false) const {
	const Index chip_dim = m_dim.actualDim();

	DSizes<Index, NumInputDims> input_block_dims;
	for (int i = 0; i < NumInputDims; ++i) {
	input_block_dims[i] = i < chip_dim ? desc.dimension(i) : i > chip_dim ? desc.dimension(i - 1) : 1;
	}

	ArgTensorBlockDesc arg_desc(srcCoeff(desc.offset()), input_block_dims);

	// Try to reuse destination buffer for materializing argument block.
	if (desc.HasDestinationBuffer()) {
	DSizes<Index, NumInputDims> arg_destination_strides;
	for (int i = 0; i < NumInputDims; ++i) {
	arg_destination_strides[i] = i < chip_dim ? desc.destination().strides()[i]
	: i > chip_dim ? desc.destination().strides()[i - 1]
	: 0; // for dimensions of size `1` stride should never be used.
	}

	arg_desc.template AddDestinationBuffer<Layout>(desc.destination().template data<ScalarNoConst>(),
	arg_destination_strides);
	}

	ArgTensorBlock arg_block = m_impl.block(arg_desc, scratch, root_of_expr_ast);
	if (!arg_desc.HasDestinationBuffer()) desc.DropDestinationBuffer();

	if (arg_block.data() != NULL) {
	// Forward argument block buffer if possible.
	return TensorBlock(arg_block.kind(), arg_block.data(), desc.dimensions());

	} else {
	// Assign argument block expression to a buffer.

	// Prepare storage for the materialized chipping result.
	const typename TensorBlock::Storage block_storage = TensorBlock::prepareStorage(desc, scratch);

	typedef internal::TensorBlockAssignment<ScalarNoConst, NumInputDims, typename ArgTensorBlock::XprType, Index>
	TensorBlockAssignment;

	TensorBlockAssignment::Run(
	TensorBlockAssignment::target(arg_desc.dimensions(), internal::strides<Layout>(arg_desc.dimensions()),
	block_storage.data()),
	arg_block.expr());

	return block_storage.AsTensorMaterializedBlock();
	}
	}

	EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE typename Storage::Type data() const {
	typename Storage::Type result = constCast(m_impl.data());
	if (isOuterChipping() && result) {
	return result + m_inputOffset;
	} else {
	return NULL;
	}
	}

	protected:
	EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE Index srcCoeff(Index index) const {
	Index inputIndex;
	if (isInnerChipping()) {
	// m_stride is equal to 1, so let's avoid the integer division.
	eigen_assert(m_stride == 1);
	inputIndex = index * m_inputStride + m_inputOffset;
	} else if (isOuterChipping()) {
	// m_stride is always greater than index, so let's avoid the integer
	// division.
	eigen_assert(m_stride > index);
	inputIndex = index + m_inputOffset;
	} else {
	const Index idx = index / m_stride;
	inputIndex = idx * m_inputStride + m_inputOffset;
	index -= idx * m_stride;
	inputIndex += index;
	}
	return inputIndex;
	}

	EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE bool isInnerChipping() const {
	return IsInnerChipping \|\| (static_cast<int>(Layout) == ColMajor && m_dim.actualDim() == 0) \|\|
	(static_cast<int>(Layout) == RowMajor && m_dim.actualDim() == NumInputDims - 1);
	}

	EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE bool isOuterChipping() const {
	return IsOuterChipping \|\| (static_cast<int>(Layout) == ColMajor && m_dim.actualDim() == NumInputDims - 1) \|\|
	(static_cast<int>(Layout) == RowMajor && m_dim.actualDim() == 0);
	}

	Dimensions m_dimensions;
	Index m_stride;
	Index m_inputOffset;
	Index m_inputStride;
	TensorEvaluator<ArgType, Device> m_impl;
	const internal::DimensionId<DimId> m_dim;
	const Device EIGEN_DEVICE_REF m_device;
	};

	// Eval as lvalue
	template <DenseIndex DimId, typename ArgType, typename Device>
	struct TensorEvaluator<TensorChippingOp<DimId, ArgType>, Device>
	: public TensorEvaluator<const TensorChippingOp<DimId, ArgType>, Device> {
	typedef TensorEvaluator<const TensorChippingOp<DimId, ArgType>, Device> Base;
	typedef TensorChippingOp<DimId, ArgType> XprType;
	static constexpr int NumInputDims =
	internal::array_size<typename TensorEvaluator<ArgType, Device>::Dimensions>::value;
	static constexpr int NumDims = NumInputDims - 1;
	typedef typename XprType::Index Index;
	typedef DSizes<Index, NumDims> Dimensions;
	typedef typename XprType::Scalar Scalar;
	typedef typename XprType::CoeffReturnType CoeffReturnType;
	typedef typename PacketType<CoeffReturnType, Device>::type PacketReturnType;
	static constexpr int PacketSize = PacketType<CoeffReturnType, Device>::size;

	enum {
	IsAligned = false,
	PacketAccess = TensorEvaluator<ArgType, Device>::PacketAccess,
	BlockAccess = TensorEvaluator<ArgType, Device>::RawAccess,
	Layout = TensorEvaluator<ArgType, Device>::Layout,
	RawAccess = false
	};

	//===- Tensor block evaluation strategy (see TensorBlock.h) -------------===//
	typedef internal::TensorBlockDescriptor<NumDims, Index> TensorBlockDesc;
	//===--------------------------------------------------------------------===//

	EIGEN_STRONG_INLINE TensorEvaluator(const XprType& op, const Device& device) : Base(op, device) {}

	EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE CoeffReturnType& coeffRef(Index index) const {
	return this->m_impl.coeffRef(this->srcCoeff(index));
	}

	template <int StoreMode>
	EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE void writePacket(Index index, const PacketReturnType& x) const {
	if (this->isInnerChipping()) {
	// m_stride is equal to 1, so let's avoid the integer division.
	eigen_assert(this->m_stride == 1);
	EIGEN_ALIGN_MAX std::remove_const_t<CoeffReturnType> values[PacketSize];
	internal::pstore<CoeffReturnType, PacketReturnType>(values, x);
	Index inputIndex = index * this->m_inputStride + this->m_inputOffset;
	EIGEN_UNROLL_LOOP
	for (int i = 0; i < PacketSize; ++i) {
	this->m_impl.coeffRef(inputIndex) = values[i];
	inputIndex += this->m_inputStride;
	}
	} else if (this->isOuterChipping()) {
	// m_stride is always greater than index, so let's avoid the integer division.
	eigen_assert(this->m_stride > index);
	this->m_impl.template writePacket<StoreMode>(index + this->m_inputOffset, x);
	} else {
	const Index idx = index / this->m_stride;
	const Index rem = index - idx * this->m_stride;
	if (rem + PacketSize <= this->m_stride) {
	const Index inputIndex = idx * this->m_inputStride + this->m_inputOffset + rem;
	this->m_impl.template writePacket<StoreMode>(inputIndex, x);
	} else {
	// Cross stride boundary. Fallback to slow path.
	EIGEN_ALIGN_MAX std::remove_const_t<CoeffReturnType> values[PacketSize];
	internal::pstore<CoeffReturnType, PacketReturnType>(values, x);
	EIGEN_UNROLL_LOOP
	for (int i = 0; i < PacketSize; ++i) {
	this->coeffRef(index) = values[i];
	++index;
	}
	}
	}
	}

	template <typename TensorBlock>
	EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE void writeBlock(const TensorBlockDesc& desc, const TensorBlock& block) {
	eigen_assert(this->m_impl.data() != NULL);

	const Index chip_dim = this->m_dim.actualDim();

	DSizes<Index, NumInputDims> input_block_dims;
	for (int i = 0; i < NumInputDims; ++i) {
	input_block_dims[i] = i < chip_dim ? desc.dimension(i) : i > chip_dim ? desc.dimension(i - 1) : 1;
	}

	typedef TensorReshapingOp<const DSizes<Index, NumInputDims>, const typename TensorBlock::XprType> TensorBlockExpr;

	typedef internal::TensorBlockAssignment<Scalar, NumInputDims, TensorBlockExpr, Index> TensorBlockAssign;

	TensorBlockAssign::Run(
	TensorBlockAssign::target(input_block_dims, internal::strides<Layout>(this->m_impl.dimensions()),
	this->m_impl.data(), this->srcCoeff(desc.offset())),
	block.expr().reshape(input_block_dims));
	}
	};

	} // end namespace Eigen

	#endif // EIGEN_CXX11_TENSOR_TENSOR_CHIPPING_H