unsupported/Eigen/CXX11/src/Tensor/TensorTraits.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_TRAITS_H
 #define EIGEN_CXX11_TENSOR_TENSOR_TRAITS_H

 namespace Eigen {
 namespace internal {


 template<typename Scalar, int Options>
 class compute_tensor_flags
 {
   enum {
     is_dynamic_size_storage = 1,

     aligned_bit =
     (
         ((Options&DontAlign)==0) && (
 #if EIGEN_ALIGN_STATICALLY
             (!is_dynamic_size_storage)
 #else
             0
 #endif
             ||
 #if EIGEN_ALIGN
             is_dynamic_size_storage
 #else
             0
 #endif
       )
     ) ? AlignedBit : 0,
     packet_access_bit = packet_traits<Scalar>::Vectorizable && aligned_bit ? PacketAccessBit : 0
   };

   public:
     enum { ret = packet_access_bit | aligned_bit};
 };


 template<typename Scalar_, int NumIndices_, int Options_, typename IndexType_>
 struct traits<Tensor<Scalar_, NumIndices_, Options_, IndexType_> >
 {
   typedef Scalar_ Scalar;
   typedef Dense StorageKind;
   typedef IndexType_ Index;
   static const int NumDimensions = NumIndices_;
   static const int Layout = Options_ & RowMajor ? RowMajor : ColMajor;
   enum {
     Options = Options_,
     Flags = compute_tensor_flags<Scalar_, Options_>::ret | (is_const<Scalar_>::value ? 0 : LvalueBit),
   };
 };


 template<typename Scalar_, typename Dimensions, int Options_, typename IndexType_>
 struct traits<TensorFixedSize<Scalar_, Dimensions, Options_, IndexType_> >
 {
   typedef Scalar_ Scalar;
   typedef Dense StorageKind;
   typedef IndexType_ Index;
   static const int NumDimensions = array_size<Dimensions>::value;
   static const int Layout = Options_ & RowMajor ? RowMajor : ColMajor;
   enum {
     Options = Options_,
     Flags = compute_tensor_flags<Scalar_, Options_>::ret | (is_const<Scalar_>::value ? 0: LvalueBit),
   };
 };

 template<typename PlainObjectType, int Options_>
 struct traits<TensorMap<PlainObjectType, Options_> >
   : public traits<PlainObjectType>
 {
   typedef traits<PlainObjectType> BaseTraits;
   typedef typename BaseTraits::Scalar Scalar;
   typedef typename BaseTraits::StorageKind StorageKind;
   typedef typename BaseTraits::Index Index;
   static const int NumDimensions = BaseTraits::NumDimensions;
   static const int Layout = BaseTraits::Layout;
   enum {
     Options = Options_,
     Flags = (BaseTraits::Flags & ~AlignedBit) | (Options&Aligned ? AlignedBit : 0),
   };
 };

 template<typename PlainObjectType>
 struct traits<TensorRef<PlainObjectType> >
   : public traits<PlainObjectType>
 {
   typedef traits<PlainObjectType> BaseTraits;
   typedef typename BaseTraits::Scalar Scalar;
   typedef typename BaseTraits::StorageKind StorageKind;
   typedef typename BaseTraits::Index Index;
   static const int NumDimensions = BaseTraits::NumDimensions;
   static const int Layout = BaseTraits::Layout;
   enum {
     Options = BaseTraits::Options,
     Flags = (BaseTraits::Flags & ~AlignedBit) | (Options&Aligned ? AlignedBit : 0),
   };
 };


 template<typename _Scalar, int NumIndices_, int Options, typename IndexType_>
 struct eval<Tensor<_Scalar, NumIndices_, Options, IndexType_>, Eigen::Dense>
 {
   typedef const Tensor<_Scalar, NumIndices_, Options, IndexType_>& type;
 };

 template<typename _Scalar, int NumIndices_, int Options, typename IndexType_>
 struct eval<const Tensor<_Scalar, NumIndices_, Options, IndexType_>, Eigen::Dense>
 {
   typedef const Tensor<_Scalar, NumIndices_, Options, IndexType_>& type;
 };

 template<typename Scalar_, typename Dimensions, int Options, typename IndexType_>
 struct eval<TensorFixedSize<Scalar_, Dimensions, Options, IndexType_>, Eigen::Dense>
 {
   typedef const TensorFixedSize<Scalar_, Dimensions, Options, IndexType_>& type;
 };

 template<typename Scalar_, typename Dimensions, int Options, typename IndexType_>
 struct eval<const TensorFixedSize<Scalar_, Dimensions, Options, IndexType_>, Eigen::Dense>
 {
   typedef const TensorFixedSize<Scalar_, Dimensions, Options, IndexType_>& type;
 };

 template<typename PlainObjectType, int Options>
 struct eval<TensorMap<PlainObjectType, Options>, Eigen::Dense>
 {
   typedef const TensorMap<PlainObjectType, Options>& type;
 };

 template<typename PlainObjectType, int Options>
 struct eval<const TensorMap<PlainObjectType, Options>, Eigen::Dense>
 {
   typedef const TensorMap<PlainObjectType, Options>& type;
 };

 template<typename PlainObjectType>
 struct eval<TensorRef<PlainObjectType>, Eigen::Dense>
 {
   typedef const TensorRef<PlainObjectType>& type;
 };

 template<typename PlainObjectType>
 struct eval<const TensorRef<PlainObjectType>, Eigen::Dense>
 {
   typedef const TensorRef<PlainObjectType>& type;
 };


 template <typename Scalar_, int NumIndices_, int Options_, typename IndexType_>
 struct nested<Tensor<Scalar_, NumIndices_, Options_, IndexType_>, 1, typename eval<Tensor<Scalar_, NumIndices_, Options_, IndexType_> >::type>
 {
   typedef const Tensor<Scalar_, NumIndices_, Options_, IndexType_>& type;
 };

 template <typename Scalar_, int NumIndices_, int Options_, typename IndexType_>
 struct nested<const Tensor<Scalar_, NumIndices_, Options_, IndexType_>, 1, typename eval<const Tensor<Scalar_, NumIndices_, Options_, IndexType_> >::type>
 {
   typedef const Tensor<Scalar_, NumIndices_, Options_, IndexType_>& type;
 };

 template <typename Scalar_, typename Dimensions, int Options, typename IndexType_>
 struct nested<TensorFixedSize<Scalar_, Dimensions, Options, IndexType_>, 1, typename eval<TensorFixedSize<Scalar_, Dimensions, Options, IndexType_> >::type>
 {
   typedef const TensorFixedSize<Scalar_, Dimensions, Options, IndexType_>& type;
 };

 template <typename Scalar_, typename Dimensions, int Options, typename IndexType_>
 struct nested<const TensorFixedSize<Scalar_, Dimensions, Options, IndexType_>, 1, typename eval<const TensorFixedSize<Scalar_, Dimensions, Options, IndexType_> >::type>
 {
   typedef const TensorFixedSize<Scalar_, Dimensions, Options, IndexType_>& type;
 };


 template <typename PlainObjectType, int Options>
 struct nested<TensorMap<PlainObjectType, Options>, 1, typename eval<TensorMap<PlainObjectType, Options> >::type>
 {
   typedef const TensorMap<PlainObjectType, Options>& type;
 };

 template <typename PlainObjectType, int Options>
 struct nested<const TensorMap<PlainObjectType, Options>, 1, typename eval<TensorMap<PlainObjectType, Options> >::type>
 {
   typedef const TensorMap<PlainObjectType, Options>& type;
 };

 template <typename PlainObjectType>
 struct nested<TensorRef<PlainObjectType>, 1, typename eval<TensorRef<PlainObjectType> >::type>
 {
   typedef const TensorRef<PlainObjectType>& type;
 };

 template <typename PlainObjectType>
 struct nested<const TensorRef<PlainObjectType>, 1, typename eval<TensorRef<PlainObjectType> >::type>
 {
   typedef const TensorRef<PlainObjectType>& type;
 };

 }  // end namespace internal

 // Convolutional layers take in an input tensor of shape (D, R, C, B), or (D, C,
 // R, B), and convolve it with a set of filters, which can also be presented as
 // a tensor (D, K, K, M), where M is the number of filters, K is the filter
 // size, and each 3-dimensional tensor of size (D, K, K) is a filter. For
 // simplicity we assume that we always use square filters (which is usually the
 // case in images), hence the two Ks in the tensor dimension.  It also takes in
 // a few additional parameters:
 // Stride (S): The convolution stride is the offset between locations where we
 //             apply the filters.  A larger stride means that the output will be
 //             spatially smaller.
 // Padding (P): The padding we apply to the input tensor along the R and C
 //              dimensions.  This is usually used to make sure that the spatial
 //              dimensions of the output matches our intention.
 //
 // Two types of padding are often used:
 //   SAME: The pad value is computed so that the output will have size
 //         R/S and C/S.
 //   VALID: no padding is carried out.
 // When we do padding, the padded values at the padded locations are usually
 // zero.
 //
 // The output dimensions for convolution, when given all the parameters above,
 // are as follows:
 // When Padding = SAME: the output size is (B, R', C', M), where
 //   R' = ceil(float(R) / float(S))
 //   C' = ceil(float(C) / float(S))
 // where ceil is the ceiling function.  The input tensor is padded with 0 as
 // needed.  The number of padded rows and columns are computed as:
 //   Pr = ((R' - 1) * S + K - R) / 2
 //   Pc = ((C' - 1) * S + K - C) / 2
 // when the stride is 1, we have the simplified case R'=R, C'=C, Pr=Pc=(K-1)/2.
 // This is where SAME comes from - the output has the same size as the input has.
 // When Padding = VALID: the output size is computed as
 //   R' = ceil(float(R - K + 1) / float(S))
 //   C' = ceil(float(C - K + 1) / float(S))
 // and the number of padded rows and columns are computed in the same way as in
 // the SAME case.
 // When the stride is 1, we have the simplified case R'=R-K+1, C'=C-K+1, Pr=0,
 // Pc=0.
 typedef enum {
   PADDING_VALID = 1,
   PADDING_SAME = 2,
 } PaddingType;

 }  // end namespace Eigen

 #endif // EIGEN_CXX11_TENSOR_TENSOR_TRAITS_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_TRAITS_H
	#define EIGEN_CXX11_TENSOR_TENSOR_TRAITS_H

	namespace Eigen {
	namespace internal {


	template<typename Scalar, int Options>
	class compute_tensor_flags
	{
	enum {
	is_dynamic_size_storage = 1,

	aligned_bit =
	(
	((Options&DontAlign)==0) && (
	#if EIGEN_ALIGN_STATICALLY
	(!is_dynamic_size_storage)
	#else
	0
	#endif
	\|\|
	#if EIGEN_ALIGN
	is_dynamic_size_storage
	#else
	0
	#endif
	)
	) ? AlignedBit : 0,
	packet_access_bit = packet_traits<Scalar>::Vectorizable && aligned_bit ? PacketAccessBit : 0
	};

	public:
	enum { ret = packet_access_bit \| aligned_bit};
	};


	template<typename Scalar_, int NumIndices_, int Options_, typename IndexType_>
	struct traits<Tensor<Scalar_, NumIndices_, Options_, IndexType_> >
	{
	typedef Scalar_ Scalar;
	typedef Dense StorageKind;
	typedef IndexType_ Index;
	static const int NumDimensions = NumIndices_;
	static const int Layout = Options_ & RowMajor ? RowMajor : ColMajor;
	enum {
	Options = Options_,
	Flags = compute_tensor_flags<Scalar_, Options_>::ret \| (is_const<Scalar_>::value ? 0 : LvalueBit),
	};
	};


	template<typename Scalar_, typename Dimensions, int Options_, typename IndexType_>
	struct traits<TensorFixedSize<Scalar_, Dimensions, Options_, IndexType_> >
	{
	typedef Scalar_ Scalar;
	typedef Dense StorageKind;
	typedef IndexType_ Index;
	static const int NumDimensions = array_size<Dimensions>::value;
	static const int Layout = Options_ & RowMajor ? RowMajor : ColMajor;
	enum {
	Options = Options_,
	Flags = compute_tensor_flags<Scalar_, Options_>::ret \| (is_const<Scalar_>::value ? 0: LvalueBit),
	};
	};

	template<typename PlainObjectType, int Options_>
	struct traits<TensorMap<PlainObjectType, Options_> >
	: public traits<PlainObjectType>
	{
	typedef traits<PlainObjectType> BaseTraits;
	typedef typename BaseTraits::Scalar Scalar;
	typedef typename BaseTraits::StorageKind StorageKind;
	typedef typename BaseTraits::Index Index;
	static const int NumDimensions = BaseTraits::NumDimensions;
	static const int Layout = BaseTraits::Layout;
	enum {
	Options = Options_,
	Flags = (BaseTraits::Flags & ~AlignedBit) \| (Options&Aligned ? AlignedBit : 0),
	};
	};

	template<typename PlainObjectType>
	struct traits<TensorRef<PlainObjectType> >
	: public traits<PlainObjectType>
	{
	typedef traits<PlainObjectType> BaseTraits;
	typedef typename BaseTraits::Scalar Scalar;
	typedef typename BaseTraits::StorageKind StorageKind;
	typedef typename BaseTraits::Index Index;
	static const int NumDimensions = BaseTraits::NumDimensions;
	static const int Layout = BaseTraits::Layout;
	enum {
	Options = BaseTraits::Options,
	Flags = (BaseTraits::Flags & ~AlignedBit) \| (Options&Aligned ? AlignedBit : 0),
	};
	};


	template<typename _Scalar, int NumIndices_, int Options, typename IndexType_>
	struct eval<Tensor<_Scalar, NumIndices_, Options, IndexType_>, Eigen::Dense>
	{
	typedef const Tensor<_Scalar, NumIndices_, Options, IndexType_>& type;
	};

	template<typename _Scalar, int NumIndices_, int Options, typename IndexType_>
	struct eval<const Tensor<_Scalar, NumIndices_, Options, IndexType_>, Eigen::Dense>
	{
	typedef const Tensor<_Scalar, NumIndices_, Options, IndexType_>& type;
	};

	template<typename Scalar_, typename Dimensions, int Options, typename IndexType_>
	struct eval<TensorFixedSize<Scalar_, Dimensions, Options, IndexType_>, Eigen::Dense>
	{
	typedef const TensorFixedSize<Scalar_, Dimensions, Options, IndexType_>& type;
	};

	template<typename Scalar_, typename Dimensions, int Options, typename IndexType_>
	struct eval<const TensorFixedSize<Scalar_, Dimensions, Options, IndexType_>, Eigen::Dense>
	{
	typedef const TensorFixedSize<Scalar_, Dimensions, Options, IndexType_>& type;
	};

	template<typename PlainObjectType, int Options>
	struct eval<TensorMap<PlainObjectType, Options>, Eigen::Dense>
	{
	typedef const TensorMap<PlainObjectType, Options>& type;
	};

	template<typename PlainObjectType, int Options>
	struct eval<const TensorMap<PlainObjectType, Options>, Eigen::Dense>
	{
	typedef const TensorMap<PlainObjectType, Options>& type;
	};

	template<typename PlainObjectType>
	struct eval<TensorRef<PlainObjectType>, Eigen::Dense>
	{
	typedef const TensorRef<PlainObjectType>& type;
	};

	template<typename PlainObjectType>
	struct eval<const TensorRef<PlainObjectType>, Eigen::Dense>
	{
	typedef const TensorRef<PlainObjectType>& type;
	};


	template <typename Scalar_, int NumIndices_, int Options_, typename IndexType_>
	struct nested<Tensor<Scalar_, NumIndices_, Options_, IndexType_>, 1, typename eval<Tensor<Scalar_, NumIndices_, Options_, IndexType_> >::type>
	{
	typedef const Tensor<Scalar_, NumIndices_, Options_, IndexType_>& type;
	};

	template <typename Scalar_, int NumIndices_, int Options_, typename IndexType_>
	struct nested<const Tensor<Scalar_, NumIndices_, Options_, IndexType_>, 1, typename eval<const Tensor<Scalar_, NumIndices_, Options_, IndexType_> >::type>
	{
	typedef const Tensor<Scalar_, NumIndices_, Options_, IndexType_>& type;
	};

	template <typename Scalar_, typename Dimensions, int Options, typename IndexType_>
	struct nested<TensorFixedSize<Scalar_, Dimensions, Options, IndexType_>, 1, typename eval<TensorFixedSize<Scalar_, Dimensions, Options, IndexType_> >::type>
	{
	typedef const TensorFixedSize<Scalar_, Dimensions, Options, IndexType_>& type;
	};

	template <typename Scalar_, typename Dimensions, int Options, typename IndexType_>
	struct nested<const TensorFixedSize<Scalar_, Dimensions, Options, IndexType_>, 1, typename eval<const TensorFixedSize<Scalar_, Dimensions, Options, IndexType_> >::type>
	{
	typedef const TensorFixedSize<Scalar_, Dimensions, Options, IndexType_>& type;
	};


	template <typename PlainObjectType, int Options>
	struct nested<TensorMap<PlainObjectType, Options>, 1, typename eval<TensorMap<PlainObjectType, Options> >::type>
	{
	typedef const TensorMap<PlainObjectType, Options>& type;
	};

	template <typename PlainObjectType, int Options>
	struct nested<const TensorMap<PlainObjectType, Options>, 1, typename eval<TensorMap<PlainObjectType, Options> >::type>
	{
	typedef const TensorMap<PlainObjectType, Options>& type;
	};

	template <typename PlainObjectType>
	struct nested<TensorRef<PlainObjectType>, 1, typename eval<TensorRef<PlainObjectType> >::type>
	{
	typedef const TensorRef<PlainObjectType>& type;
	};

	template <typename PlainObjectType>
	struct nested<const TensorRef<PlainObjectType>, 1, typename eval<TensorRef<PlainObjectType> >::type>
	{
	typedef const TensorRef<PlainObjectType>& type;
	};

	} // end namespace internal

	// Convolutional layers take in an input tensor of shape (D, R, C, B), or (D, C,
	// R, B), and convolve it with a set of filters, which can also be presented as
	// a tensor (D, K, K, M), where M is the number of filters, K is the filter
	// size, and each 3-dimensional tensor of size (D, K, K) is a filter. For
	// simplicity we assume that we always use square filters (which is usually the
	// case in images), hence the two Ks in the tensor dimension. It also takes in
	// a few additional parameters:
	// Stride (S): The convolution stride is the offset between locations where we
	// apply the filters. A larger stride means that the output will be
	// spatially smaller.
	// Padding (P): The padding we apply to the input tensor along the R and C
	// dimensions. This is usually used to make sure that the spatial
	// dimensions of the output matches our intention.
	//
	// Two types of padding are often used:
	// SAME: The pad value is computed so that the output will have size
	// R/S and C/S.
	// VALID: no padding is carried out.
	// When we do padding, the padded values at the padded locations are usually
	// zero.
	//
	// The output dimensions for convolution, when given all the parameters above,
	// are as follows:
	// When Padding = SAME: the output size is (B, R', C', M), where
	// R' = ceil(float(R) / float(S))
	// C' = ceil(float(C) / float(S))
	// where ceil is the ceiling function. The input tensor is padded with 0 as
	// needed. The number of padded rows and columns are computed as:
	// Pr = ((R' - 1) * S + K - R) / 2
	// Pc = ((C' - 1) * S + K - C) / 2
	// when the stride is 1, we have the simplified case R'=R, C'=C, Pr=Pc=(K-1)/2.
	// This is where SAME comes from - the output has the same size as the input has.
	// When Padding = VALID: the output size is computed as
	// R' = ceil(float(R - K + 1) / float(S))
	// C' = ceil(float(C - K + 1) / float(S))
	// and the number of padded rows and columns are computed in the same way as in
	// the SAME case.
	// When the stride is 1, we have the simplified case R'=R-K+1, C'=C-K+1, Pr=0,
	// Pc=0.
	typedef enum {
	PADDING_VALID = 1,
	PADDING_SAME = 2,
	} PaddingType;

	} // end namespace Eigen

	#endif // EIGEN_CXX11_TENSOR_TENSOR_TRAITS_H