unsupported/Eigen/CXX11/src/Tensor/TensorConcatenation.h - eigen/fuchsia - 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_CONCATENATION_H
 #define EIGEN_CXX11_TENSOR_TENSOR_CONCATENATION_H

 namespace Eigen {

 /** \class TensorConcatenationOp
   * \ingroup CXX11_Tensor_Module
   *
   * \brief Tensor concatenation class.
   *
   *
   */
 namespace internal {
 template<typename Axis, typename LhsXprType, typename RhsXprType>
 struct traits<TensorConcatenationOp<Axis, LhsXprType, RhsXprType> >
 {
   // Type promotion to handle the case where the types of the lhs and the rhs are different.
   typedef typename promote_storage_type<typename LhsXprType::Scalar,
                                         typename RhsXprType::Scalar>::ret Scalar;
   typedef typename promote_storage_type<typename traits<LhsXprType>::StorageKind,
                                         typename traits<RhsXprType>::StorageKind>::ret StorageKind;
   typedef typename promote_index_type<typename traits<LhsXprType>::Index,
                                       typename traits<RhsXprType>::Index>::type Index;
   typedef typename LhsXprType::Nested LhsNested;
   typedef typename RhsXprType::Nested RhsNested;
   typedef typename remove_reference<LhsNested>::type _LhsNested;
   typedef typename remove_reference<RhsNested>::type _RhsNested;
   static const int NumDimensions = traits<LhsXprType>::NumDimensions;
   static const int Layout = traits<LhsXprType>::Layout;
   enum { Flags = 0 };
 };

 template<typename Axis, typename LhsXprType, typename RhsXprType>
 struct eval<TensorConcatenationOp<Axis, LhsXprType, RhsXprType>, Eigen::Dense>
 {
   typedef const TensorConcatenationOp<Axis, LhsXprType, RhsXprType>& type;
 };

 template<typename Axis, typename LhsXprType, typename RhsXprType>
 struct nested<TensorConcatenationOp<Axis, LhsXprType, RhsXprType>, 1, typename eval<TensorConcatenationOp<Axis, LhsXprType, RhsXprType> >::type>
 {
   typedef TensorConcatenationOp<Axis, LhsXprType, RhsXprType> type;
 };

 }  // end namespace internal


 template<typename Axis, typename LhsXprType, typename RhsXprType>
 class TensorConcatenationOp : public TensorBase<TensorConcatenationOp<Axis, LhsXprType, RhsXprType>, WriteAccessors>
 {
   public:
     typedef typename internal::traits<TensorConcatenationOp>::Scalar Scalar;
     typedef typename internal::traits<TensorConcatenationOp>::StorageKind StorageKind;
     typedef typename internal::traits<TensorConcatenationOp>::Index Index;
     typedef typename internal::nested<TensorConcatenationOp>::type Nested;
     typedef typename internal::promote_storage_type<typename LhsXprType::CoeffReturnType,
                                                     typename RhsXprType::CoeffReturnType>::ret CoeffReturnType;
     typedef typename NumTraits<Scalar>::Real RealScalar;

     EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE TensorConcatenationOp(const LhsXprType& lhs, const RhsXprType& rhs, Axis axis)
         : m_lhs_xpr(lhs), m_rhs_xpr(rhs), m_axis(axis) {}

     EIGEN_DEVICE_FUNC
     const typename internal::remove_all<typename LhsXprType::Nested>::type&
     lhsExpression() const { return m_lhs_xpr; }

     EIGEN_DEVICE_FUNC
     const typename internal::remove_all<typename RhsXprType::Nested>::type&
     rhsExpression() const { return m_rhs_xpr; }

     EIGEN_DEVICE_FUNC const Axis& axis() const { return m_axis; }

     EIGEN_DEVICE_FUNC
     EIGEN_STRONG_INLINE TensorConcatenationOp& operator = (const TensorConcatenationOp& other)
     {
       typedef TensorAssignOp<TensorConcatenationOp, const TensorConcatenationOp> Assign;
       Assign assign(*this, other);
       internal::TensorExecutor<const Assign, DefaultDevice>::run(assign, DefaultDevice());
       return *this;
     }

     template<typename OtherDerived>
     EIGEN_DEVICE_FUNC
     EIGEN_STRONG_INLINE TensorConcatenationOp& operator = (const OtherDerived& other)
     {
       typedef TensorAssignOp<TensorConcatenationOp, const OtherDerived> Assign;
       Assign assign(*this, other);
       internal::TensorExecutor<const Assign, DefaultDevice>::run(assign, DefaultDevice());
       return *this;
     }

   protected:
     typename LhsXprType::Nested m_lhs_xpr;
     typename RhsXprType::Nested m_rhs_xpr;
     const Axis m_axis;
 };


 // Eval as rvalue
 template<typename Axis, typename LeftArgType, typename RightArgType, typename Device>
 struct TensorEvaluator<const TensorConcatenationOp<Axis, LeftArgType, RightArgType>, Device>
 {
   typedef TensorConcatenationOp<Axis, LeftArgType, RightArgType> XprType;
   typedef typename XprType::Index Index;
   static const int NumDims = internal::array_size<typename TensorEvaluator<LeftArgType, Device>::Dimensions>::value;
   static const int RightNumDims = internal::array_size<typename TensorEvaluator<RightArgType, Device>::Dimensions>::value;
   typedef DSizes<Index, NumDims> Dimensions;
   typedef typename XprType::Scalar Scalar;
   typedef typename XprType::CoeffReturnType CoeffReturnType;
   typedef typename PacketType<CoeffReturnType, Device>::type PacketReturnType;
   enum {
     IsAligned = false,
     PacketAccess = TensorEvaluator<LeftArgType, Device>::PacketAccess & TensorEvaluator<RightArgType, Device>::PacketAccess,
     Layout = TensorEvaluator<LeftArgType, Device>::Layout,
     RawAccess = false
   };

   EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE TensorEvaluator(const XprType& op, const Device& device)
     : m_leftImpl(op.lhsExpression(), device), m_rightImpl(op.rhsExpression(), device), m_axis(op.axis())
   {
     EIGEN_STATIC_ASSERT((static_cast<int>(TensorEvaluator<LeftArgType, Device>::Layout) == static_cast<int>(TensorEvaluator<RightArgType, Device>::Layout) || NumDims == 1), YOU_MADE_A_PROGRAMMING_MISTAKE);
     EIGEN_STATIC_ASSERT((NumDims == RightNumDims), YOU_MADE_A_PROGRAMMING_MISTAKE);
     EIGEN_STATIC_ASSERT((NumDims > 0), YOU_MADE_A_PROGRAMMING_MISTAKE);

     eigen_assert(0 <= m_axis && m_axis < NumDims);
     const Dimensions& lhs_dims = m_leftImpl.dimensions();
     const Dimensions& rhs_dims = m_rightImpl.dimensions();
     {
       int i = 0;
       for (; i < m_axis; ++i) {
         eigen_assert(lhs_dims[i] > 0);
         eigen_assert(lhs_dims[i] == rhs_dims[i]);
         m_dimensions[i] = lhs_dims[i];
       }
       eigen_assert(lhs_dims[i] > 0);  // Now i == m_axis.
       eigen_assert(rhs_dims[i] > 0);
       m_dimensions[i] = lhs_dims[i] + rhs_dims[i];
       for (++i; i < NumDims; ++i) {
         eigen_assert(lhs_dims[i] > 0);
         eigen_assert(lhs_dims[i] == rhs_dims[i]);
         m_dimensions[i] = lhs_dims[i];
       }
     }

     if (static_cast<int>(Layout) == static_cast<int>(ColMajor)) {
       m_leftStrides[0] = 1;
       m_rightStrides[0] = 1;
       m_outputStrides[0] = 1;

       for (int j = 1; j < NumDims; ++j) {
         m_leftStrides[j] = m_leftStrides[j-1] * lhs_dims[j-1];
         m_rightStrides[j] = m_rightStrides[j-1] * rhs_dims[j-1];
         m_outputStrides[j] = m_outputStrides[j-1] * m_dimensions[j-1];
       }
     } else {
       m_leftStrides[NumDims - 1] = 1;
       m_rightStrides[NumDims - 1] = 1;
       m_outputStrides[NumDims - 1] = 1;

       for (int j = NumDims - 2; j >= 0; --j) {
         m_leftStrides[j] = m_leftStrides[j+1] * lhs_dims[j+1];
         m_rightStrides[j] = m_rightStrides[j+1] * rhs_dims[j+1];
         m_outputStrides[j] = m_outputStrides[j+1] * m_dimensions[j+1];
       }
     }
   }

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

   // TODO(phli): Add short-circuit memcpy evaluation if underlying data are linear?
   EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE bool evalSubExprsIfNeeded(Scalar* /*data*/)
   {
     m_leftImpl.evalSubExprsIfNeeded(NULL);
     m_rightImpl.evalSubExprsIfNeeded(NULL);
     return true;
   }

   EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE void cleanup()
   {
     m_leftImpl.cleanup();
     m_rightImpl.cleanup();
   }

   // TODO(phli): attempt to speed this up. The integer divisions and modulo are slow.
   // See CL/76180724 comments for more ideas.
   EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE CoeffReturnType coeff(Index index) const
   {
     // Collect dimension-wise indices (subs).
     array<Index, NumDims> subs;
     if (static_cast<int>(Layout) == static_cast<int>(ColMajor)) {
       for (int i = NumDims - 1; i > 0; --i) {
         subs[i] = index / m_outputStrides[i];
         index -= subs[i] * m_outputStrides[i];
       }
       subs[0] = index;
     } else {
       for (int i = 0; i < NumDims - 1; ++i) {
         subs[i] = index / m_outputStrides[i];
         index -= subs[i] * m_outputStrides[i];
       }
       subs[NumDims - 1] = index;
     }

     const Dimensions& left_dims = m_leftImpl.dimensions();
     if (subs[m_axis] < left_dims[m_axis]) {
       Index left_index;
       if (static_cast<int>(Layout) == static_cast<int>(ColMajor)) {
         left_index = subs[0];
         for (int i = 1; i < NumDims; ++i) {
           left_index += (subs[i] % left_dims[i]) * m_leftStrides[i];
         }
       } else {
         left_index = subs[NumDims - 1];
         for (int i = NumDims - 2; i >= 0; --i) {
           left_index += (subs[i] % left_dims[i]) * m_leftStrides[i];
         }
       }
       return m_leftImpl.coeff(left_index);
     } else {
       subs[m_axis] -= left_dims[m_axis];
       const Dimensions& right_dims = m_rightImpl.dimensions();
       Index right_index;
       if (static_cast<int>(Layout) == static_cast<int>(ColMajor)) {
         right_index = subs[0];
         for (int i = 1; i < NumDims; ++i) {
           right_index += (subs[i] % right_dims[i]) * m_rightStrides[i];
         }
       } else {
         right_index = subs[NumDims - 1];
         for (int i = NumDims - 2; i >= 0; --i) {
           right_index += (subs[i] % right_dims[i]) * m_rightStrides[i];
         }
       }
       return m_rightImpl.coeff(right_index);
     }
   }

   // TODO(phli): Add a real vectorization.
   template<int LoadMode>
   EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE PacketReturnType packet(Index index) const
   {
     const int packetSize = internal::unpacket_traits<PacketReturnType>::size;
     EIGEN_STATIC_ASSERT((packetSize > 1), YOU_MADE_A_PROGRAMMING_MISTAKE)
     eigen_assert(index + packetSize - 1 < dimensions().TotalSize());

     EIGEN_ALIGN_MAX CoeffReturnType values[packetSize];
     for (int i = 0; i < packetSize; ++i) {
       values[i] = coeff(index+i);
     }
     PacketReturnType rslt = internal::pload<PacketReturnType>(values);
     return rslt;
   }

   EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE TensorOpCost
   costPerCoeff(bool vectorized) const {
     const double compute_cost = NumDims * (2 * TensorOpCost::AddCost<Index>() +
                                            2 * TensorOpCost::MulCost<Index>() +
                                            TensorOpCost::DivCost<Index>() +
                                            TensorOpCost::ModCost<Index>());
     const double lhs_size = m_leftImpl.dimensions().TotalSize();
     const double rhs_size = m_rightImpl.dimensions().TotalSize();
     return (lhs_size / (lhs_size + rhs_size)) *
                m_leftImpl.costPerCoeff(vectorized) +
            (rhs_size / (lhs_size + rhs_size)) *
                m_rightImpl.costPerCoeff(vectorized) +
            TensorOpCost(0, 0, compute_cost);
   }

   EIGEN_DEVICE_FUNC Scalar* data() const { return NULL; }

   protected:
     Dimensions m_dimensions;
     array<Index, NumDims> m_outputStrides;
     array<Index, NumDims> m_leftStrides;
     array<Index, NumDims> m_rightStrides;
     TensorEvaluator<LeftArgType, Device> m_leftImpl;
     TensorEvaluator<RightArgType, Device> m_rightImpl;
     const Axis m_axis;
 };

 // Eval as lvalue
 template<typename Axis, typename LeftArgType, typename RightArgType, typename Device>
   struct TensorEvaluator<TensorConcatenationOp<Axis, LeftArgType, RightArgType>, Device>
   : public TensorEvaluator<const TensorConcatenationOp<Axis, LeftArgType, RightArgType>, Device>
 {
   typedef TensorEvaluator<const TensorConcatenationOp<Axis, LeftArgType, RightArgType>, Device> Base;
   typedef TensorConcatenationOp<Axis, LeftArgType, RightArgType> XprType;
   typedef typename Base::Dimensions Dimensions;
   enum {
     IsAligned = false,
     PacketAccess = TensorEvaluator<LeftArgType, Device>::PacketAccess & TensorEvaluator<RightArgType, Device>::PacketAccess,
     Layout = TensorEvaluator<LeftArgType, Device>::Layout,
     RawAccess = false
   };

   EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE TensorEvaluator(XprType& op, const Device& device)
     : Base(op, device)
   {
     EIGEN_STATIC_ASSERT((static_cast<int>(Layout) == static_cast<int>(ColMajor)), YOU_MADE_A_PROGRAMMING_MISTAKE);
   }

   typedef typename XprType::Index Index;
   typedef typename XprType::Scalar Scalar;
   typedef typename XprType::CoeffReturnType CoeffReturnType;
   typedef typename PacketType<CoeffReturnType, Device>::type PacketReturnType;

   EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE CoeffReturnType& coeffRef(Index index)
   {
     // Collect dimension-wise indices (subs).
     array<Index, Base::NumDims> subs;
     for (int i = Base::NumDims - 1; i > 0; --i) {
       subs[i] = index / this->m_outputStrides[i];
       index -= subs[i] * this->m_outputStrides[i];
     }
     subs[0] = index;

     const Dimensions& left_dims = this->m_leftImpl.dimensions();
     if (subs[this->m_axis] < left_dims[this->m_axis]) {
       Index left_index = subs[0];
       for (int i = 1; i < Base::NumDims; ++i) {
         left_index += (subs[i] % left_dims[i]) * this->m_leftStrides[i];
       }
       return this->m_leftImpl.coeffRef(left_index);
     } else {
       subs[this->m_axis] -= left_dims[this->m_axis];
       const Dimensions& right_dims = this->m_rightImpl.dimensions();
       Index right_index = subs[0];
       for (int i = 1; i < Base::NumDims; ++i) {
         right_index += (subs[i] % right_dims[i]) * this->m_rightStrides[i];
       }
       return this->m_rightImpl.coeffRef(right_index);
     }
   }

   template <int StoreMode> EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE
   void writePacket(Index index, const PacketReturnType& x)
   {
     const int packetSize = internal::unpacket_traits<PacketReturnType>::size;
     EIGEN_STATIC_ASSERT((packetSize > 1), YOU_MADE_A_PROGRAMMING_MISTAKE)
     eigen_assert(index + packetSize - 1 < this->dimensions().TotalSize());

     EIGEN_ALIGN_MAX CoeffReturnType values[packetSize];
     internal::pstore<CoeffReturnType, PacketReturnType>(values, x);
     for (int i = 0; i < packetSize; ++i) {
       coeffRef(index+i) = values[i];
     }
   }
 };

 } // end namespace Eigen

 #endif // EIGEN_CXX11_TENSOR_TENSOR_CONCATENATION_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_CONCATENATION_H
	#define EIGEN_CXX11_TENSOR_TENSOR_CONCATENATION_H

	namespace Eigen {

	/** \class TensorConcatenationOp
	* \ingroup CXX11_Tensor_Module
	*
	* \brief Tensor concatenation class.
	*
	*
	*/
	namespace internal {
	template<typename Axis, typename LhsXprType, typename RhsXprType>
	struct traits<TensorConcatenationOp<Axis, LhsXprType, RhsXprType> >
	{
	// Type promotion to handle the case where the types of the lhs and the rhs are different.
	typedef typename promote_storage_type<typename LhsXprType::Scalar,
	typename RhsXprType::Scalar>::ret Scalar;
	typedef typename promote_storage_type<typename traits<LhsXprType>::StorageKind,
	typename traits<RhsXprType>::StorageKind>::ret StorageKind;
	typedef typename promote_index_type<typename traits<LhsXprType>::Index,
	typename traits<RhsXprType>::Index>::type Index;
	typedef typename LhsXprType::Nested LhsNested;
	typedef typename RhsXprType::Nested RhsNested;
	typedef typename remove_reference<LhsNested>::type _LhsNested;
	typedef typename remove_reference<RhsNested>::type _RhsNested;
	static const int NumDimensions = traits<LhsXprType>::NumDimensions;
	static const int Layout = traits<LhsXprType>::Layout;
	enum { Flags = 0 };
	};

	template<typename Axis, typename LhsXprType, typename RhsXprType>
	struct eval<TensorConcatenationOp<Axis, LhsXprType, RhsXprType>, Eigen::Dense>
	{
	typedef const TensorConcatenationOp<Axis, LhsXprType, RhsXprType>& type;
	};

	template<typename Axis, typename LhsXprType, typename RhsXprType>
	struct nested<TensorConcatenationOp<Axis, LhsXprType, RhsXprType>, 1, typename eval<TensorConcatenationOp<Axis, LhsXprType, RhsXprType> >::type>
	{
	typedef TensorConcatenationOp<Axis, LhsXprType, RhsXprType> type;
	};

	} // end namespace internal


	template<typename Axis, typename LhsXprType, typename RhsXprType>
	class TensorConcatenationOp : public TensorBase<TensorConcatenationOp<Axis, LhsXprType, RhsXprType>, WriteAccessors>
	{
	public:
	typedef typename internal::traits<TensorConcatenationOp>::Scalar Scalar;
	typedef typename internal::traits<TensorConcatenationOp>::StorageKind StorageKind;
	typedef typename internal::traits<TensorConcatenationOp>::Index Index;
	typedef typename internal::nested<TensorConcatenationOp>::type Nested;
	typedef typename internal::promote_storage_type<typename LhsXprType::CoeffReturnType,
	typename RhsXprType::CoeffReturnType>::ret CoeffReturnType;
	typedef typename NumTraits<Scalar>::Real RealScalar;

	EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE TensorConcatenationOp(const LhsXprType& lhs, const RhsXprType& rhs, Axis axis)
	: m_lhs_xpr(lhs), m_rhs_xpr(rhs), m_axis(axis) {}

	EIGEN_DEVICE_FUNC
	const typename internal::remove_all<typename LhsXprType::Nested>::type&
	lhsExpression() const { return m_lhs_xpr; }

	EIGEN_DEVICE_FUNC
	const typename internal::remove_all<typename RhsXprType::Nested>::type&
	rhsExpression() const { return m_rhs_xpr; }

	EIGEN_DEVICE_FUNC const Axis& axis() const { return m_axis; }

	EIGEN_DEVICE_FUNC
	EIGEN_STRONG_INLINE TensorConcatenationOp& operator = (const TensorConcatenationOp& other)
	{
	typedef TensorAssignOp<TensorConcatenationOp, const TensorConcatenationOp> Assign;
	Assign assign(*this, other);
	internal::TensorExecutor<const Assign, DefaultDevice>::run(assign, DefaultDevice());
	return *this;
	}

	template<typename OtherDerived>
	EIGEN_DEVICE_FUNC
	EIGEN_STRONG_INLINE TensorConcatenationOp& operator = (const OtherDerived& other)
	{
	typedef TensorAssignOp<TensorConcatenationOp, const OtherDerived> Assign;
	Assign assign(*this, other);
	internal::TensorExecutor<const Assign, DefaultDevice>::run(assign, DefaultDevice());
	return *this;
	}

	protected:
	typename LhsXprType::Nested m_lhs_xpr;
	typename RhsXprType::Nested m_rhs_xpr;
	const Axis m_axis;
	};


	// Eval as rvalue
	template<typename Axis, typename LeftArgType, typename RightArgType, typename Device>
	struct TensorEvaluator<const TensorConcatenationOp<Axis, LeftArgType, RightArgType>, Device>
	{
	typedef TensorConcatenationOp<Axis, LeftArgType, RightArgType> XprType;
	typedef typename XprType::Index Index;
	static const int NumDims = internal::array_size<typename TensorEvaluator<LeftArgType, Device>::Dimensions>::value;
	static const int RightNumDims = internal::array_size<typename TensorEvaluator<RightArgType, Device>::Dimensions>::value;
	typedef DSizes<Index, NumDims> Dimensions;
	typedef typename XprType::Scalar Scalar;
	typedef typename XprType::CoeffReturnType CoeffReturnType;
	typedef typename PacketType<CoeffReturnType, Device>::type PacketReturnType;
	enum {
	IsAligned = false,
	PacketAccess = TensorEvaluator<LeftArgType, Device>::PacketAccess & TensorEvaluator<RightArgType, Device>::PacketAccess,
	Layout = TensorEvaluator<LeftArgType, Device>::Layout,
	RawAccess = false
	};

	EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE TensorEvaluator(const XprType& op, const Device& device)
	: m_leftImpl(op.lhsExpression(), device), m_rightImpl(op.rhsExpression(), device), m_axis(op.axis())
	{
	EIGEN_STATIC_ASSERT((static_cast<int>(TensorEvaluator<LeftArgType, Device>::Layout) == static_cast<int>(TensorEvaluator<RightArgType, Device>::Layout) \|\| NumDims == 1), YOU_MADE_A_PROGRAMMING_MISTAKE);
	EIGEN_STATIC_ASSERT((NumDims == RightNumDims), YOU_MADE_A_PROGRAMMING_MISTAKE);
	EIGEN_STATIC_ASSERT((NumDims > 0), YOU_MADE_A_PROGRAMMING_MISTAKE);

	eigen_assert(0 <= m_axis && m_axis < NumDims);
	const Dimensions& lhs_dims = m_leftImpl.dimensions();
	const Dimensions& rhs_dims = m_rightImpl.dimensions();
	{
	int i = 0;
	for (; i < m_axis; ++i) {
	eigen_assert(lhs_dims[i] > 0);
	eigen_assert(lhs_dims[i] == rhs_dims[i]);
	m_dimensions[i] = lhs_dims[i];
	}
	eigen_assert(lhs_dims[i] > 0); // Now i == m_axis.
	eigen_assert(rhs_dims[i] > 0);
	m_dimensions[i] = lhs_dims[i] + rhs_dims[i];
	for (++i; i < NumDims; ++i) {
	eigen_assert(lhs_dims[i] > 0);
	eigen_assert(lhs_dims[i] == rhs_dims[i]);
	m_dimensions[i] = lhs_dims[i];
	}
	}

	if (static_cast<int>(Layout) == static_cast<int>(ColMajor)) {
	m_leftStrides[0] = 1;
	m_rightStrides[0] = 1;
	m_outputStrides[0] = 1;

	for (int j = 1; j < NumDims; ++j) {
	m_leftStrides[j] = m_leftStrides[j-1] * lhs_dims[j-1];
	m_rightStrides[j] = m_rightStrides[j-1] * rhs_dims[j-1];
	m_outputStrides[j] = m_outputStrides[j-1] * m_dimensions[j-1];
	}
	} else {
	m_leftStrides[NumDims - 1] = 1;
	m_rightStrides[NumDims - 1] = 1;
	m_outputStrides[NumDims - 1] = 1;

	for (int j = NumDims - 2; j >= 0; --j) {
	m_leftStrides[j] = m_leftStrides[j+1] * lhs_dims[j+1];
	m_rightStrides[j] = m_rightStrides[j+1] * rhs_dims[j+1];
	m_outputStrides[j] = m_outputStrides[j+1] * m_dimensions[j+1];
	}
	}
	}

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

	// TODO(phli): Add short-circuit memcpy evaluation if underlying data are linear?
	EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE bool evalSubExprsIfNeeded(Scalar* /data/)
	{
	m_leftImpl.evalSubExprsIfNeeded(NULL);
	m_rightImpl.evalSubExprsIfNeeded(NULL);
	return true;
	}

	EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE void cleanup()
	{
	m_leftImpl.cleanup();
	m_rightImpl.cleanup();
	}

	// TODO(phli): attempt to speed this up. The integer divisions and modulo are slow.
	// See CL/76180724 comments for more ideas.
	EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE CoeffReturnType coeff(Index index) const
	{
	// Collect dimension-wise indices (subs).
	array<Index, NumDims> subs;
	if (static_cast<int>(Layout) == static_cast<int>(ColMajor)) {
	for (int i = NumDims - 1; i > 0; --i) {
	subs[i] = index / m_outputStrides[i];
	index -= subs[i] * m_outputStrides[i];
	}
	subs[0] = index;
	} else {
	for (int i = 0; i < NumDims - 1; ++i) {
	subs[i] = index / m_outputStrides[i];
	index -= subs[i] * m_outputStrides[i];
	}
	subs[NumDims - 1] = index;
	}

	const Dimensions& left_dims = m_leftImpl.dimensions();
	if (subs[m_axis] < left_dims[m_axis]) {
	Index left_index;
	if (static_cast<int>(Layout) == static_cast<int>(ColMajor)) {
	left_index = subs[0];
	for (int i = 1; i < NumDims; ++i) {
	left_index += (subs[i] % left_dims[i]) * m_leftStrides[i];
	}
	} else {
	left_index = subs[NumDims - 1];
	for (int i = NumDims - 2; i >= 0; --i) {
	left_index += (subs[i] % left_dims[i]) * m_leftStrides[i];
	}
	}
	return m_leftImpl.coeff(left_index);
	} else {
	subs[m_axis] -= left_dims[m_axis];
	const Dimensions& right_dims = m_rightImpl.dimensions();
	Index right_index;
	if (static_cast<int>(Layout) == static_cast<int>(ColMajor)) {
	right_index = subs[0];
	for (int i = 1; i < NumDims; ++i) {
	right_index += (subs[i] % right_dims[i]) * m_rightStrides[i];
	}
	} else {
	right_index = subs[NumDims - 1];
	for (int i = NumDims - 2; i >= 0; --i) {
	right_index += (subs[i] % right_dims[i]) * m_rightStrides[i];
	}
	}
	return m_rightImpl.coeff(right_index);
	}
	}

	// TODO(phli): Add a real vectorization.
	template<int LoadMode>
	EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE PacketReturnType packet(Index index) const
	{
	const int packetSize = internal::unpacket_traits<PacketReturnType>::size;
	EIGEN_STATIC_ASSERT((packetSize > 1), YOU_MADE_A_PROGRAMMING_MISTAKE)
	eigen_assert(index + packetSize - 1 < dimensions().TotalSize());

	EIGEN_ALIGN_MAX CoeffReturnType values[packetSize];
	for (int i = 0; i < packetSize; ++i) {
	values[i] = coeff(index+i);
	}
	PacketReturnType rslt = internal::pload<PacketReturnType>(values);
	return rslt;
	}

	EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE TensorOpCost
	costPerCoeff(bool vectorized) const {
	const double compute_cost = NumDims * (2 * TensorOpCost::AddCost<Index>() +
	2 * TensorOpCost::MulCost<Index>() +
	TensorOpCost::DivCost<Index>() +
	TensorOpCost::ModCost<Index>());
	const double lhs_size = m_leftImpl.dimensions().TotalSize();
	const double rhs_size = m_rightImpl.dimensions().TotalSize();
	return (lhs_size / (lhs_size + rhs_size)) *
	m_leftImpl.costPerCoeff(vectorized) +
	(rhs_size / (lhs_size + rhs_size)) *
	m_rightImpl.costPerCoeff(vectorized) +
	TensorOpCost(0, 0, compute_cost);
	}

	EIGEN_DEVICE_FUNC Scalar* data() const { return NULL; }

	protected:
	Dimensions m_dimensions;
	array<Index, NumDims> m_outputStrides;
	array<Index, NumDims> m_leftStrides;
	array<Index, NumDims> m_rightStrides;
	TensorEvaluator<LeftArgType, Device> m_leftImpl;
	TensorEvaluator<RightArgType, Device> m_rightImpl;
	const Axis m_axis;
	};

	// Eval as lvalue
	template<typename Axis, typename LeftArgType, typename RightArgType, typename Device>
	struct TensorEvaluator<TensorConcatenationOp<Axis, LeftArgType, RightArgType>, Device>
	: public TensorEvaluator<const TensorConcatenationOp<Axis, LeftArgType, RightArgType>, Device>
	{
	typedef TensorEvaluator<const TensorConcatenationOp<Axis, LeftArgType, RightArgType>, Device> Base;
	typedef TensorConcatenationOp<Axis, LeftArgType, RightArgType> XprType;
	typedef typename Base::Dimensions Dimensions;
	enum {
	IsAligned = false,
	PacketAccess = TensorEvaluator<LeftArgType, Device>::PacketAccess & TensorEvaluator<RightArgType, Device>::PacketAccess,
	Layout = TensorEvaluator<LeftArgType, Device>::Layout,
	RawAccess = false
	};

	EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE TensorEvaluator(XprType& op, const Device& device)
	: Base(op, device)
	{
	EIGEN_STATIC_ASSERT((static_cast<int>(Layout) == static_cast<int>(ColMajor)), YOU_MADE_A_PROGRAMMING_MISTAKE);
	}

	typedef typename XprType::Index Index;
	typedef typename XprType::Scalar Scalar;
	typedef typename XprType::CoeffReturnType CoeffReturnType;
	typedef typename PacketType<CoeffReturnType, Device>::type PacketReturnType;

	EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE CoeffReturnType& coeffRef(Index index)
	{
	// Collect dimension-wise indices (subs).
	array<Index, Base::NumDims> subs;
	for (int i = Base::NumDims - 1; i > 0; --i) {
	subs[i] = index / this->m_outputStrides[i];
	index -= subs[i] * this->m_outputStrides[i];
	}
	subs[0] = index;

	const Dimensions& left_dims = this->m_leftImpl.dimensions();
	if (subs[this->m_axis] < left_dims[this->m_axis]) {
	Index left_index = subs[0];
	for (int i = 1; i < Base::NumDims; ++i) {
	left_index += (subs[i] % left_dims[i]) * this->m_leftStrides[i];
	}
	return this->m_leftImpl.coeffRef(left_index);
	} else {
	subs[this->m_axis] -= left_dims[this->m_axis];
	const Dimensions& right_dims = this->m_rightImpl.dimensions();
	Index right_index = subs[0];
	for (int i = 1; i < Base::NumDims; ++i) {
	right_index += (subs[i] % right_dims[i]) * this->m_rightStrides[i];
	}
	return this->m_rightImpl.coeffRef(right_index);
	}
	}

	template <int StoreMode> EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE
	void writePacket(Index index, const PacketReturnType& x)
	{
	const int packetSize = internal::unpacket_traits<PacketReturnType>::size;
	EIGEN_STATIC_ASSERT((packetSize > 1), YOU_MADE_A_PROGRAMMING_MISTAKE)
	eigen_assert(index + packetSize - 1 < this->dimensions().TotalSize());

	EIGEN_ALIGN_MAX CoeffReturnType values[packetSize];
	internal::pstore<CoeffReturnType, PacketReturnType>(values, x);
	for (int i = 0; i < packetSize; ++i) {
	coeffRef(index+i) = values[i];
	}
	}
	};

	} // end namespace Eigen

	#endif // EIGEN_CXX11_TENSOR_TENSOR_CONCATENATION_H