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// 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_BROADCASTING_H
#define EIGEN_CXX11_TENSOR_TENSOR_BROADCASTING_H
// IWYU pragma: private
#include "./InternalHeaderCheck.h"
namespace Eigen {
/** \class TensorBroadcasting
* \ingroup CXX11_Tensor_Module
*
* \brief Tensor broadcasting class.
*
*
*/
namespace internal {
template <typename Broadcast, typename XprType>
struct traits<TensorBroadcastingOp<Broadcast, 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;
static constexpr int Layout = XprTraits::Layout;
typedef typename XprTraits::PointerType PointerType;
};
template <typename Broadcast, typename XprType>
struct eval<TensorBroadcastingOp<Broadcast, XprType>, Eigen::Dense> {
typedef const TensorBroadcastingOp<Broadcast, XprType> EIGEN_DEVICE_REF type;
};
template <typename Broadcast, typename XprType>
struct nested<TensorBroadcastingOp<Broadcast, XprType>, 1,
typename eval<TensorBroadcastingOp<Broadcast, XprType>>::type> {
typedef TensorBroadcastingOp<Broadcast, XprType> type;
};
template <typename Dims>
struct is_input_scalar {
static const bool value = false;
};
template <>
struct is_input_scalar<Sizes<>> {
static const bool value = true;
};
template <typename std::ptrdiff_t... Indices>
struct is_input_scalar<Sizes<Indices...>> {
static constexpr bool value = (Sizes<Indices...>::total_size == 1);
};
} // end namespace internal
template <typename Broadcast, typename XprType>
class TensorBroadcastingOp : public TensorBase<TensorBroadcastingOp<Broadcast, XprType>, ReadOnlyAccessors> {
public:
typedef typename Eigen::internal::traits<TensorBroadcastingOp>::Scalar Scalar;
typedef typename Eigen::NumTraits<Scalar>::Real RealScalar;
typedef typename XprType::CoeffReturnType CoeffReturnType;
typedef typename Eigen::internal::nested<TensorBroadcastingOp>::type Nested;
typedef typename Eigen::internal::traits<TensorBroadcastingOp>::StorageKind StorageKind;
typedef typename Eigen::internal::traits<TensorBroadcastingOp>::Index Index;
EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE TensorBroadcastingOp(const XprType& expr, const Broadcast& broadcast)
: m_xpr(expr), m_broadcast(broadcast) {}
EIGEN_DEVICE_FUNC const Broadcast& broadcast() const { return m_broadcast; }
EIGEN_DEVICE_FUNC const internal::remove_all_t<typename XprType::Nested>& expression() const { return m_xpr; }
protected:
typename XprType::Nested m_xpr;
const Broadcast m_broadcast;
};
// Eval as rvalue
template <typename Broadcast, typename ArgType, typename Device>
struct TensorEvaluator<const TensorBroadcastingOp<Broadcast, ArgType>, Device> {
typedef TensorBroadcastingOp<Broadcast, ArgType> XprType;
typedef typename XprType::Index Index;
static constexpr int NumDims = internal::array_size<typename TensorEvaluator<ArgType, Device>::Dimensions>::value;
typedef DSizes<Index, NumDims> Dimensions;
typedef typename XprType::Scalar Scalar;
typedef typename TensorEvaluator<ArgType, Device>::Dimensions InputDimensions;
typedef typename XprType::CoeffReturnType CoeffReturnType;
typedef typename PacketType<CoeffReturnType, Device>::type PacketReturnType;
static constexpr int PacketSize = PacketType<CoeffReturnType, Device>::size;
protected: // all the non-static fields must have the same access control, otherwise the TensorEvaluator won't be
// standard layout;
bool isCopy, nByOne, oneByN;
public:
typedef StorageMemory<CoeffReturnType, Device> Storage;
typedef typename Storage::Type EvaluatorPointerType;
enum {
IsAligned = TensorEvaluator<ArgType, Device>::IsAligned,
PacketAccess = TensorEvaluator<ArgType, Device>::PacketAccess,
BlockAccess = TensorEvaluator<ArgType, Device>::BlockAccess,
PreferBlockAccess = true,
RawAccess = false
};
static constexpr int Layout = TensorEvaluator<ArgType, Device>::Layout;
typedef std::remove_const_t<Scalar> ScalarNoConst;
// We do block based broadcasting using a trick with 2x tensor rank and 0
// strides. See block method implementation for details.
typedef DSizes<Index, 2 * NumDims> BroadcastDimensions;
//===- Tensor block evaluation strategy (see TensorBlock.h) -------------===//
typedef internal::TensorBlockDescriptor<NumDims, Index> TensorBlockDesc;
typedef internal::TensorBlockScratchAllocator<Device> TensorBlockScratch;
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)
: isCopy(false),
nByOne(false),
oneByN(false),
m_device(device),
m_broadcast(op.broadcast()),
m_impl(op.expression(), device) {
// The broadcasting op doesn't change the rank of the tensor. One can't broadcast a scalar
// and store the result in a scalar. Instead one should reshape the scalar into a N-D
// tensor with N >= 1 of 1 element first and then broadcast.
EIGEN_STATIC_ASSERT((NumDims > 0), YOU_MADE_A_PROGRAMMING_MISTAKE);
const InputDimensions& input_dims = m_impl.dimensions();
isCopy = true;
for (int i = 0; i < NumDims; ++i) {
eigen_assert(input_dims[i] > 0);
m_dimensions[i] = input_dims[i] * m_broadcast[i];
if (m_broadcast[i] != 1) {
isCopy = false;
}
}
if (static_cast<int>(Layout) == static_cast<int>(ColMajor)) {
m_inputStrides[0] = 1;
m_outputStrides[0] = 1;
for (int i = 1; i < NumDims; ++i) {
m_inputStrides[i] = m_inputStrides[i - 1] * input_dims[i - 1];
m_outputStrides[i] = m_outputStrides[i - 1] * m_dimensions[i - 1];
}
} else {
m_inputStrides[NumDims - 1] = 1;
m_outputStrides[NumDims - 1] = 1;
for (int i = NumDims - 2; i >= 0; --i) {
m_inputStrides[i] = m_inputStrides[i + 1] * input_dims[i + 1];
m_outputStrides[i] = m_outputStrides[i + 1] * m_dimensions[i + 1];
}
}
if (input_dims[0] == 1) {
oneByN = true;
for (int i = 1; i < NumDims; ++i) {
if (m_broadcast[i] != 1) {
oneByN = false;
break;
}
}
} else if (input_dims[NumDims - 1] == 1) {
nByOne = true;
for (int i = 0; i < NumDims - 1; ++i) {
if (m_broadcast[i] != 1) {
nByOne = false;
break;
}
}
}
// Handle special format like NCHW, its input shape is '[1, N..., 1]' and
// broadcast shape is '[N, 1..., N]'
if (!oneByN && !nByOne) {
if (input_dims[0] == 1 && input_dims[NumDims - 1] == 1 && NumDims > 2) {
nByOne = true;
oneByN = true;
for (int i = 1; i < NumDims - 1; ++i) {
if (m_broadcast[i] != 1) {
nByOne = false;
oneByN = false;
break;
}
}
}
}
}
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;
}
#ifdef EIGEN_USE_THREADS
template <typename EvalSubExprsCallback>
EIGEN_STRONG_INLINE void evalSubExprsIfNeededAsync(EvaluatorPointerType, EvalSubExprsCallback done) {
m_impl.evalSubExprsIfNeededAsync(nullptr, [done](bool) { done(true); });
}
#endif // EIGEN_USE_THREADS
EIGEN_STRONG_INLINE void cleanup() { m_impl.cleanup(); }
EIGEN_DEVICE_FUNC EIGEN_ALWAYS_INLINE CoeffReturnType coeff(Index index) const {
if (internal::is_input_scalar<internal::remove_all_t<InputDimensions>>::value) {
return m_impl.coeff(0);
}
if (static_cast<int>(Layout) == static_cast<int>(ColMajor)) {
if (isCopy) {
return m_impl.coeff(index);
} else {
return coeffColMajor(index);
}
} else {
if (isCopy) {
return m_impl.coeff(index);
} else {
return coeffRowMajor(index);
}
}
}
// TODO: attempt to speed this up. The integer divisions and modulo are slow
EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE Index indexColMajor(Index index) const {
Index inputIndex = 0;
EIGEN_UNROLL_LOOP
for (int i = NumDims - 1; i > 0; --i) {
const Index idx = index / m_outputStrides[i];
if (internal::index_statically_eq<Broadcast>(i, 1)) {
eigen_assert(idx < m_impl.dimensions()[i]);
inputIndex += idx * m_inputStrides[i];
} else {
if (internal::index_statically_eq<InputDimensions>(i, 1)) {
eigen_assert(idx % m_impl.dimensions()[i] == 0);
} else {
inputIndex += (idx % m_impl.dimensions()[i]) * m_inputStrides[i];
}
}
index -= idx * m_outputStrides[i];
}
if (internal::index_statically_eq<Broadcast>(0, 1)) {
eigen_assert(index < m_impl.dimensions()[0]);
inputIndex += index;
} else {
if (internal::index_statically_eq<InputDimensions>(0, 1)) {
eigen_assert(index % m_impl.dimensions()[0] == 0);
} else {
inputIndex += (index % m_impl.dimensions()[0]);
}
}
return inputIndex;
}
EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE CoeffReturnType coeffColMajor(Index index) const {
return m_impl.coeff(indexColMajor(index));
}
EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE Index indexRowMajor(Index index) const {
Index inputIndex = 0;
EIGEN_UNROLL_LOOP
for (int i = 0; i < NumDims - 1; ++i) {
const Index idx = index / m_outputStrides[i];
if (internal::index_statically_eq<Broadcast>(i, 1)) {
eigen_assert(idx < m_impl.dimensions()[i]);
inputIndex += idx * m_inputStrides[i];
} else {
if (internal::index_statically_eq<InputDimensions>(i, 1)) {
eigen_assert(idx % m_impl.dimensions()[i] == 0);
} else {
inputIndex += (idx % m_impl.dimensions()[i]) * m_inputStrides[i];
}
}
index -= idx * m_outputStrides[i];
}
if (internal::index_statically_eq<Broadcast>(NumDims - 1, 1)) {
eigen_assert(index < m_impl.dimensions()[NumDims - 1]);
inputIndex += index;
} else {
if (internal::index_statically_eq<InputDimensions>(NumDims - 1, 1)) {
eigen_assert(index % m_impl.dimensions()[NumDims - 1] == 0);
} else {
inputIndex += (index % m_impl.dimensions()[NumDims - 1]);
}
}
return inputIndex;
}
EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE CoeffReturnType coeffRowMajor(Index index) const {
return m_impl.coeff(indexRowMajor(index));
}
template <int LoadMode>
EIGEN_DEVICE_FUNC EIGEN_ALWAYS_INLINE PacketReturnType packet(Index index) const {
if (internal::is_input_scalar<internal::remove_all_t<InputDimensions>>::value) {
return internal::pset1<PacketReturnType>(m_impl.coeff(0));
}
if (static_cast<int>(Layout) == static_cast<int>(ColMajor)) {
if (isCopy) {
#ifdef EIGEN_GPU_COMPILE_PHASE
// See PR 437: on NVIDIA P100 and K20m we observed a x3-4 speed up by enforcing
// unaligned loads here. The reason is unclear though.
return m_impl.template packet<Unaligned>(index);
#else
return m_impl.template packet<LoadMode>(index);
#endif
} else if (oneByN && !nByOne) {
return packetNByOne<LoadMode>(index);
} else if (!oneByN && nByOne) {
return packetOneByN<LoadMode>(index);
} else if (oneByN && nByOne) {
return packetOneByNByOne<LoadMode>(index);
} else {
return packetColMajor<LoadMode>(index);
}
} else {
if (isCopy) {
#ifdef EIGEN_GPU_COMPILE_PHASE
// See above.
return m_impl.template packet<Unaligned>(index);
#else
return m_impl.template packet<LoadMode>(index);
#endif
} else if (oneByN && !nByOne) {
return packetOneByN<LoadMode>(index);
} else if (!oneByN && nByOne) {
return packetNByOne<LoadMode>(index);
} else if (oneByN && nByOne) {
return packetOneByNByOne<LoadMode>(index);
} else {
return packetRowMajor<LoadMode>(index);
}
}
}
template <int LoadMode>
EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE PacketReturnType packetOneByNByOne(Index index) const {
eigen_assert(index + PacketSize - 1 < dimensions().TotalSize());
EIGEN_ALIGN_MAX std::remove_const_t<CoeffReturnType> values[PacketSize];
Index startDim, endDim;
Index inputIndex, outputOffset, batchedIndex;
if (static_cast<int>(Layout) == static_cast<int>(ColMajor)) {
startDim = NumDims - 1;
endDim = 1;
} else {
startDim = 0;
endDim = NumDims - 2;
}
batchedIndex = index % m_outputStrides[startDim];
inputIndex = batchedIndex / m_outputStrides[endDim];
outputOffset = batchedIndex % m_outputStrides[endDim];
if (outputOffset + PacketSize <= m_outputStrides[endDim]) {
values[0] = m_impl.coeff(inputIndex);
return internal::pload1<PacketReturnType>(values);
} else {
EIGEN_UNROLL_LOOP
for (int i = 0, cur = 0; i < PacketSize; ++i, ++cur) {
if (outputOffset + cur < m_outputStrides[endDim]) {
values[i] = m_impl.coeff(inputIndex);
} else {
++inputIndex;
inputIndex = (inputIndex == m_inputStrides[startDim] ? 0 : inputIndex);
values[i] = m_impl.coeff(inputIndex);
outputOffset = 0;
cur = 0;
}
}
return internal::pload<PacketReturnType>(values);
}
}
template <int LoadMode>
EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE PacketReturnType packetOneByN(Index index) const {
// Consider the flattened tensor [v0, ..., vN],
// Concatenates m_broadcast[dim] copies,
// [v0, ..., vN, v0, ..., vN, ... ]
// with dim == NumDims - 1 for col-major, dim == 0 for row-major.
eigen_assert(index + PacketSize - 1 < dimensions().TotalSize());
// Size of flattened tensor.
const Index M =
(static_cast<int>(Layout) == static_cast<int>(ColMajor)) ? m_inputStrides[NumDims - 1] : m_inputStrides[0];
Index inputIndex = index % M;
if (inputIndex + PacketSize <= M) {
return m_impl.template packet<Unaligned>(inputIndex);
} else {
EIGEN_ALIGN_MAX std::remove_const_t<CoeffReturnType> values[PacketSize];
EIGEN_UNROLL_LOOP
for (int i = 0; i < PacketSize; ++i) {
if (inputIndex > M - 1) {
inputIndex = 0;
}
values[i] = m_impl.coeff(inputIndex++);
}
return internal::pload<PacketReturnType>(values);
}
}
template <int LoadMode>
EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE PacketReturnType packetNByOne(Index index) const {
// Consider the flattened tensor [v0, ..., vN],
// Interleaves m_broadcast[dim] copies,
// [v0, v0, ..., v1, v1, ..., vN, vN, ... ]
// with dim == 0 for col-major, dim == NumDims - 1 for row-major.
eigen_assert(index + PacketSize - 1 < dimensions().TotalSize());
const Index M =
(static_cast<int>(Layout) == static_cast<int>(ColMajor)) ? m_broadcast[0] : m_broadcast[NumDims - 1];
Index inputIndex = index / M;
Index outputOffset = index % M;
if (outputOffset + PacketSize <= M) {
return internal::pset1<PacketReturnType>(m_impl.coeff(inputIndex));
} else {
EIGEN_ALIGN_MAX std::remove_const_t<CoeffReturnType> values[PacketSize];
EIGEN_UNROLL_LOOP
for (int i = 0; i < PacketSize; ++i) {
if (outputOffset < M) {
values[i] = m_impl.coeff(inputIndex);
++outputOffset;
} else {
values[i] = m_impl.coeff(++inputIndex);
outputOffset = 1; // Next offset.
}
}
return internal::pload<PacketReturnType>(values);
}
}
// Ignore the LoadMode and always use unaligned loads since we can't guarantee
// the alignment at compile time.
template <int LoadMode>
EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE PacketReturnType packetColMajor(Index index) const {
eigen_assert(index + PacketSize - 1 < dimensions().TotalSize());
const Index originalIndex = index;
Index inputIndex = 0;
EIGEN_UNROLL_LOOP
for (int i = NumDims - 1; i > 0; --i) {
const Index idx = index / m_outputStrides[i];
if (internal::index_statically_eq<Broadcast>(i, 1)) {
eigen_assert(idx < m_impl.dimensions()[i]);
inputIndex += idx * m_inputStrides[i];
} else {
if (internal::index_statically_eq<InputDimensions>(i, 1)) {
eigen_assert(idx % m_impl.dimensions()[i] == 0);
} else {
inputIndex += (idx % m_impl.dimensions()[i]) * m_inputStrides[i];
}
}
index -= idx * m_outputStrides[i];
}
Index innermostLoc;
if (internal::index_statically_eq<Broadcast>(0, 1)) {
eigen_assert(index < m_impl.dimensions()[0]);
innermostLoc = index;
} else {
if (internal::index_statically_eq<InputDimensions>(0, 1)) {
eigen_assert(index % m_impl.dimensions()[0] == 0);
innermostLoc = 0;
} else {
innermostLoc = index % m_impl.dimensions()[0];
}
}
inputIndex += innermostLoc;
// Todo: this could be extended to the second dimension if we're not
// broadcasting alongside the first dimension, and so on.
if (innermostLoc + PacketSize <= m_impl.dimensions()[0]) {
return m_impl.template packet<Unaligned>(inputIndex);
} else {
EIGEN_ALIGN_MAX std::remove_const_t<CoeffReturnType> values[PacketSize];
values[0] = m_impl.coeff(inputIndex);
EIGEN_UNROLL_LOOP
for (int i = 1; i < PacketSize; ++i) {
if (innermostLoc + i < m_impl.dimensions()[0]) {
values[i] = m_impl.coeff(inputIndex + i);
} else {
values[i] = coeffColMajor(originalIndex + i);
}
}
PacketReturnType rslt = internal::pload<PacketReturnType>(values);
return rslt;
}
}
template <int LoadMode>
EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE PacketReturnType packetRowMajor(Index index) const {
eigen_assert(index + PacketSize - 1 < dimensions().TotalSize());
const Index originalIndex = index;
Index inputIndex = 0;
EIGEN_UNROLL_LOOP
for (int i = 0; i < NumDims - 1; ++i) {
const Index idx = index / m_outputStrides[i];
if (internal::index_statically_eq<Broadcast>(i, 1)) {
eigen_assert(idx < m_impl.dimensions()[i]);
inputIndex += idx * m_inputStrides[i];
} else {
if (internal::index_statically_eq<InputDimensions>(i, 1)) {
eigen_assert(idx % m_impl.dimensions()[i] == 0);
} else {
inputIndex += (idx % m_impl.dimensions()[i]) * m_inputStrides[i];
}
}
index -= idx * m_outputStrides[i];
}
Index innermostLoc;
if (internal::index_statically_eq<Broadcast>(NumDims - 1, 1)) {
eigen_assert(index < m_impl.dimensions()[NumDims - 1]);
innermostLoc = index;
} else {
if (internal::index_statically_eq<InputDimensions>(NumDims - 1, 1)) {
eigen_assert(index % m_impl.dimensions()[NumDims - 1] == 0);
innermostLoc = 0;
} else {
innermostLoc = index % m_impl.dimensions()[NumDims - 1];
}
}
inputIndex += innermostLoc;
// Todo: this could be extended to the second dimension if we're not
// broadcasting alongside the first dimension, and so on.
if (innermostLoc + PacketSize <= m_impl.dimensions()[NumDims - 1]) {
return m_impl.template packet<Unaligned>(inputIndex);
} else {
EIGEN_ALIGN_MAX std::remove_const_t<CoeffReturnType> values[PacketSize];
values[0] = m_impl.coeff(inputIndex);
EIGEN_UNROLL_LOOP
for (int i = 1; i < PacketSize; ++i) {
if (innermostLoc + i < m_impl.dimensions()[NumDims - 1]) {
values[i] = m_impl.coeff(inputIndex + i);
} else {
values[i] = coeffRowMajor(originalIndex + i);
}
}
PacketReturnType rslt = internal::pload<PacketReturnType>(values);
return rslt;
}
}
EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE TensorOpCost costPerCoeff(bool vectorized) const {
double compute_cost = TensorOpCost::AddCost<Index>();
if (!isCopy && NumDims > 0) {
EIGEN_UNROLL_LOOP
for (int i = NumDims - 1; i > 0; --i) {
compute_cost += TensorOpCost::DivCost<Index>();
if (internal::index_statically_eq<Broadcast>(i, 1)) {
compute_cost += TensorOpCost::MulCost<Index>() + TensorOpCost::AddCost<Index>();
} else {
if (!internal::index_statically_eq<InputDimensions>(i, 1)) {
compute_cost +=
TensorOpCost::MulCost<Index>() + TensorOpCost::ModCost<Index>() + TensorOpCost::AddCost<Index>();
}
}
compute_cost += TensorOpCost::MulCost<Index>() + TensorOpCost::AddCost<Index>();
}
}
return m_impl.costPerCoeff(vectorized) + TensorOpCost(0, 0, compute_cost, vectorized, PacketSize);
}
EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE internal::TensorBlockResourceRequirements getResourceRequirements() const {
// TODO(wuke): Targeting L1 size is 30% faster than targeting L{-1} on large
// tensors. But this might need further tuning.
const size_t target_size = m_device.firstLevelCacheSize();
return internal::TensorBlockResourceRequirements::merge(
m_impl.getResourceRequirements(), internal::TensorBlockResourceRequirements::skewed<Scalar>(target_size));
}
EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE TensorBlock block(TensorBlockDesc& desc, TensorBlockScratch& scratch,
bool /*root_of_expr_ast*/ = false) const {
BlockBroadcastingParams params = blockBroadcastingParams(desc);
if (params.inner_dim_size == 0 || params.bcast_dim_size == 0) {
return emptyBlock();
}
// Prepare storage for the materialized broadcasting result.
const typename TensorBlock::Storage block_storage = TensorBlock::prepareStorage(desc, scratch);
ScalarNoConst* materialized_output = block_storage.data();
// We potentially will need to materialize input blocks.
size_t materialized_input_size = 0;
ScalarNoConst* materialized_input = NULL;
// Initialize block broadcating iterator state for outer dimensions (outer
// with regard to bcast dimension). Dimension in this array are always in
// inner_most -> outer_most order (col major layout).
array<BlockBroadcastingIteratorState, NumDims> it;
int idx = 0;
for (int i = params.inner_dim_count + 1; i < NumDims; ++i) {
const Index dim = IsColMajor ? i : NumDims - 1 - i;
it[idx].size = params.output_dims[dim];
it[idx].count = 0;
it[idx].output_stride = m_outputStrides[dim];
it[idx].output_span = it[idx].output_stride * (it[idx].size - 1);
idx++;
}
// Write output into the beginning of `materialized_output`.
Index output_offset = 0;
// We will fill output block by broadcasting along the bcast dim, and
// iterating over outer dimension.
const Index output_size = NumDims == 0 ? 1 : params.output_dims.TotalSize();
for (Index num_output_coeffs = 0; num_output_coeffs < output_size;) {
ScalarNoConst* bcast_output = materialized_output + num_output_coeffs;
Index bcast_offset = desc.offset() + output_offset;
// Broadcast along the bcast dimension.
num_output_coeffs += BroadcastBlockAlongBcastDim(params, bcast_offset, scratch, bcast_output, &materialized_input,
&materialized_input_size);
// Switch to the next outer dimension.
for (int j = 0; j < idx; ++j) {
if (++it[j].count < it[j].size) {
output_offset += it[j].output_stride;
break;
}
it[j].count = 0;
output_offset -= it[j].output_span;
}
}
return block_storage.AsTensorMaterializedBlock();
}
EIGEN_DEVICE_FUNC EvaluatorPointerType data() const { return NULL; }
const TensorEvaluator<ArgType, Device>& impl() const { return m_impl; }
Broadcast functor() const { return m_broadcast; }
private:
static constexpr bool IsColMajor = static_cast<int>(Layout) == static_cast<int>(ColMajor);
// We will build a general case block broadcasting on top of broadcasting
// primitive that will do broadcasting only for the inner dimension(s) along
// the first dimension smaller than the input size (it's called `bcast_dim`).
//
// Example:
// dim: 0 1 2 (ColMajor)
// input size: [9, 3, 6]
// block size: [9, 2, 6]
//
// We will compute broadcasted block by iterating over the outer dimensions
// before `bcast_dim` (only dimension `2` in this example) and computing
// broadcasts along the `bcast_dim` (dimension `1` in this example).
// BlockBroadcastingParams holds precomputed parameters for broadcasting a
// single block along the broadcasting dimension. Sizes and strides along the
// `bcast_dim` might be invalid, they will be adjusted later in
// `BroadcastBlockAlongBcastDim`.
struct BlockBroadcastingParams {
Dimensions input_dims; // input expression dimensions
Dimensions output_dims; // output block sizes
Dimensions output_strides; // output block strides
int inner_dim_count; // count inner dimensions matching in size
int bcast_dim; // broadcasting dimension index
Index bcast_dim_size; // broadcasting dimension size
Index inner_dim_size; // inner dimensions size
// Block sizes and strides for the input block where all dimensions before
// `bcast_dim` are equal to `1`.
Dimensions input_block_sizes;
Dimensions input_block_strides;
// Block sizes and strides for blocks with extra dimensions and strides `0`.
BroadcastDimensions bcast_block_sizes;
BroadcastDimensions bcast_block_strides;
BroadcastDimensions bcast_input_strides;
};
struct BlockBroadcastingIteratorState {
Index size;
Index count;
Index output_stride;
Index output_span;
};
EIGEN_DEVICE_FUNC EIGEN_ALWAYS_INLINE BlockBroadcastingParams blockBroadcastingParams(TensorBlockDesc& desc) const {
BlockBroadcastingParams params;
params.input_dims = Dimensions(m_impl.dimensions());
// Output block sizes and strides.
params.output_dims = desc.dimensions();
params.output_strides = internal::strides<Layout>(params.output_dims);
// Find the broadcasting dimension (first dimension with output size smaller
// that the input size).
params.bcast_dim = 0;
params.bcast_dim_size = 1;
params.inner_dim_size = 1;
// Count the number of inner dimensions that have the same size in the block
// and in the broadcast expression.
params.inner_dim_count = 0;
for (int i = 0; i < NumDims; ++i) {
const int dim = IsColMajor ? i : NumDims - i - 1;
if (params.output_dims[dim] == m_dimensions[dim]) {
params.inner_dim_size *= params.output_dims[dim];
++params.inner_dim_count;
continue;
}
// First non-matching dimension is the broadcasting dimension.
eigen_assert(params.output_dims[dim] < m_dimensions[dim]);
params.bcast_dim = dim;
params.bcast_dim_size = params.output_dims[dim];
break;
}
// Calculate the input block size for looking into the input.
for (int i = 0; i < params.inner_dim_count; ++i) {
const int dim = IsColMajor ? i : NumDims - i - 1;
params.input_block_sizes[dim] = params.input_dims[dim];
}
for (int i = params.inner_dim_count; i < NumDims; ++i) {
const int dim = IsColMajor ? i : NumDims - i - 1;
params.input_block_sizes[dim] = 1;
}
params.input_block_strides = internal::strides<Layout>(params.input_block_sizes);
// Broadcast with the 0-stride trick: Create 1 extra dim for each
// broadcast, set the input stride to 0.
//
// When ColMajor:
//
// - bcast_block_sizes:
// [d_0, b_0, d_1, b_1, ...]
//
// - bcast_block_strides:
// [output_block_strides[0], output_block_strides[0] * d_0,
// output_block_strides[1], output_block_strides[1] * d_1,
// ...]
//
// - bcast_input_strides:
// [input_block_strides[0], 0,
// input_block_strides[1], 0,
// ...].
//
for (int i = 0; i < params.inner_dim_count; ++i) {
const int dim = IsColMajor ? i : NumDims - i - 1;
const int copy_dim = IsColMajor ? 2 * i : 2 * NumDims - 2 * i - 1;
const int broadcast_dim = IsColMajor ? copy_dim + 1 : copy_dim - 1;
params.bcast_block_sizes[copy_dim] = params.input_dims[dim];
params.bcast_block_sizes[broadcast_dim] = m_broadcast[dim];
params.bcast_block_strides[copy_dim] = params.output_strides[dim];
params.bcast_block_strides[broadcast_dim] = params.output_strides[dim] * params.input_dims[dim];
params.bcast_input_strides[copy_dim] = params.input_block_strides[dim];
params.bcast_input_strides[broadcast_dim] = 0;
}
for (int i = 2 * params.inner_dim_count; i < 2 * NumDims; ++i) {
const int dim = IsColMajor ? i : 2 * NumDims - i - 1;
params.bcast_block_sizes[dim] = 1;
params.bcast_block_strides[dim] = 0;
params.bcast_input_strides[dim] = 0;
}
return params;
}
EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE TensorBlock emptyBlock() const {
DSizes<Index, NumDims> dimensions;
for (int i = 0; i < NumDims; ++i) dimensions[i] = 0;
return TensorBlock(internal::TensorBlockKind::kView, NULL, dimensions);
}
EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE Index BroadcastBlockAlongBcastDim(
BlockBroadcastingParams params, Index bcast_offset, TensorBlockScratch& scratch,
ScalarNoConst* materialized_output, ScalarNoConst** materialized_input, size_t* materialized_input_size) const {
if (params.bcast_dim_size == 1) {
// We just need one block read using the ready-set values above.
return BroadcastBlock(params.input_block_sizes, params.input_block_strides, params.bcast_block_sizes,
params.bcast_block_strides, params.bcast_input_strides, bcast_offset, 0, scratch,
materialized_output, materialized_input, materialized_input_size);
} else if (params.input_dims[params.bcast_dim] == 1) {
// Broadcast bcast dimension (< NumDims) by bcast_dim_size.
const int broadcast_bcast_dim =
IsColMajor ? 2 * params.inner_dim_count + 1 : 2 * NumDims - 2 * params.inner_dim_count - 2;
params.bcast_block_sizes[broadcast_bcast_dim] = params.bcast_dim_size;
params.bcast_input_strides[broadcast_bcast_dim] = 0;
params.bcast_block_strides[broadcast_bcast_dim] = params.output_strides[params.bcast_dim];
return BroadcastBlock(params.input_block_sizes, params.input_block_strides, params.bcast_block_sizes,
params.bcast_block_strides, params.bcast_input_strides, bcast_offset, 0, scratch,
materialized_output, materialized_input, materialized_input_size);
} else {
// Keep track of the total number of the coefficients written to the
// output block.
Index num_output_coeffs = 0;
// The general case. Let's denote the output block as
//
// x[..., a:a+bcast_dim_size, :, ..., :]
//
// where a:a+bcast_dim_size is a slice on the bcast_dim dimension
// (< NumDims). We need to split the a:a+bcast_dim_size into possibly 3
// sub-blocks:
//
// (1) a:b, where b is the smallest multiple of
// input_dims[bcast_dim_start] in [a, a+bcast_dim_size].
//
// (2) b:c, where c is the largest multiple of input_dims[bcast_dim_start]
// in [a, a+bcast_dim_size].
//
// (3) c:a+bcast_dim_size .
//
// Or, when b and c do not exist, we just need to process the whole block
// together.
// Find a.
const Index bcast_dim_left_index = bcast_offset / m_outputStrides[params.bcast_dim];
// Find b and c.
const Index input_bcast_dim_size = params.input_dims[params.bcast_dim];
// First multiple after a. This is b when <= bcast_dim_left_index +
// bcast_dim_size.
const Index first_multiple =
numext::div_ceil<Index>(bcast_dim_left_index, input_bcast_dim_size) * input_bcast_dim_size;
if (first_multiple <= bcast_dim_left_index + params.bcast_dim_size) {
// b exists, so does c. Find it.
const Index last_multiple =
(bcast_dim_left_index + params.bcast_dim_size) / input_bcast_dim_size * input_bcast_dim_size;
const int copy_bcast_dim =
IsColMajor ? 2 * params.inner_dim_count : 2 * NumDims - 2 * params.inner_dim_count - 1;
const int broadcast_bcast_dim =
IsColMajor ? 2 * params.inner_dim_count + 1 : 2 * NumDims - 2 * params.inner_dim_count - 2;
if (first_multiple > bcast_dim_left_index) {
const Index head_size = first_multiple - bcast_dim_left_index;
params.input_block_sizes[params.bcast_dim] = head_size;
params.bcast_block_sizes[copy_bcast_dim] = head_size;
params.bcast_input_strides[copy_bcast_dim] = params.input_block_strides[params.bcast_dim];
params.bcast_block_strides[copy_bcast_dim] = params.output_strides[params.bcast_dim];
params.bcast_block_sizes[broadcast_bcast_dim] = 1;
params.bcast_input_strides[broadcast_bcast_dim] = 0;
params.bcast_block_strides[broadcast_bcast_dim] =
params.output_strides[params.bcast_dim] * params.input_dims[params.bcast_dim];
num_output_coeffs +=
BroadcastBlock(params.input_block_sizes, params.input_block_strides, params.bcast_block_sizes,
params.bcast_block_strides, params.bcast_input_strides, bcast_offset, 0, scratch,
materialized_output, materialized_input, materialized_input_size);
}
if (first_multiple < last_multiple) {
params.input_block_sizes[params.bcast_dim] = input_bcast_dim_size;
params.bcast_block_sizes[copy_bcast_dim] = input_bcast_dim_size;
params.bcast_input_strides[copy_bcast_dim] = params.input_block_strides[params.bcast_dim];
params.bcast_block_strides[copy_bcast_dim] = params.output_strides[params.bcast_dim];
params.bcast_block_sizes[broadcast_bcast_dim] = (last_multiple - first_multiple) / input_bcast_dim_size;
params.bcast_input_strides[broadcast_bcast_dim] = 0;
params.bcast_block_strides[broadcast_bcast_dim] =
params.output_strides[params.bcast_dim] * params.input_dims[params.bcast_dim];
const Index offset = (first_multiple - bcast_dim_left_index) * m_outputStrides[params.bcast_dim];
num_output_coeffs +=
BroadcastBlock(params.input_block_sizes, params.input_block_strides, params.bcast_block_sizes,
params.bcast_block_strides, params.bcast_input_strides, bcast_offset, offset, scratch,
materialized_output, materialized_input, materialized_input_size);
}
if (last_multiple < bcast_dim_left_index + params.bcast_dim_size) {
const Index tail_size = bcast_dim_left_index + params.bcast_dim_size - last_multiple;
params.input_block_sizes[params.bcast_dim] = tail_size;
params.bcast_block_sizes[copy_bcast_dim] = tail_size;
params.bcast_input_strides[copy_bcast_dim] = params.input_block_strides[params.bcast_dim];
params.bcast_block_strides[copy_bcast_dim] = params.output_strides[params.bcast_dim];
params.bcast_block_sizes[broadcast_bcast_dim] = 1;
params.bcast_input_strides[broadcast_bcast_dim] = 0;
params.bcast_block_strides[broadcast_bcast_dim] =
params.output_strides[params.bcast_dim] * params.input_dims[params.bcast_dim];
const Index offset = (last_multiple - bcast_dim_left_index) * m_outputStrides[params.bcast_dim];
num_output_coeffs +=
BroadcastBlock(params.input_block_sizes, params.input_block_strides, params.bcast_block_sizes,
params.bcast_block_strides, params.bcast_input_strides, bcast_offset, offset, scratch,
materialized_output, materialized_input, materialized_input_size);
}
} else {
// b and c do not exist.
const int copy_bcast_dim =
IsColMajor ? 2 * params.inner_dim_count : 2 * NumDims - 2 * params.inner_dim_count - 1;
params.input_block_sizes[params.bcast_dim] = params.bcast_dim_size;
params.bcast_block_sizes[copy_bcast_dim] = params.bcast_dim_size;
params.bcast_input_strides[copy_bcast_dim] = params.input_block_strides[params.bcast_dim];
params.bcast_block_strides[copy_bcast_dim] = params.output_strides[params.bcast_dim];
num_output_coeffs +=
BroadcastBlock(params.input_block_sizes, params.input_block_strides, params.bcast_block_sizes,
params.bcast_block_strides, params.bcast_input_strides, bcast_offset, 0, scratch,
materialized_output, materialized_input, materialized_input_size);
}
return num_output_coeffs;
}
}
EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE Index BroadcastBlock(
const Dimensions& input_block_sizes, const Dimensions& input_block_strides,
const BroadcastDimensions& bcast_block_sizes, const BroadcastDimensions& bcast_block_strides,
const BroadcastDimensions& bcast_input_strides, Index bcast_offset, Index offset, TensorBlockScratch& scratch,
ScalarNoConst* materialized_output, ScalarNoConst** materialized_input, size_t* materialized_input_size) const {
// ---------------------------------------------------------------------- //
// Tensor block descriptor for reading block from the input.
const Index input_offset = bcast_offset + offset;
TensorBlockDesc input_desc(IsColMajor ? indexColMajor(input_offset) : indexRowMajor(input_offset),
input_block_sizes);
ArgTensorBlock input_block = m_impl.block(input_desc, scratch);
// ---------------------------------------------------------------------- //
// Materialize input block into a temporary memory buffer only if it's not
// already available in the arg block.
const ScalarNoConst* input_buffer = NULL;
if (input_block.data() != NULL) {
// Input block already has raw data, there is no need to materialize it.
input_buffer = input_block.data();
} else {
// Otherwise we have to do block assignment into a temporary buffer.
// Maybe reuse previously allocated buffer, or allocate a new one with a
// scratch allocator.
const size_t input_total_size = input_block_sizes.TotalSize();
if (*materialized_input == NULL || *materialized_input_size < input_total_size) {
*materialized_input_size = input_total_size;
void* mem = scratch.allocate(*materialized_input_size * sizeof(Scalar));
*materialized_input = static_cast<ScalarNoConst*>(mem);
}
typedef internal::TensorBlockAssignment<ScalarNoConst, NumDims, typename ArgTensorBlock::XprType, Index>
TensorBlockAssignment;
TensorBlockAssignment::Run(
TensorBlockAssignment::target(input_block_sizes, input_block_strides, *materialized_input),
input_block.expr());
input_buffer = *materialized_input;
}
// ---------------------------------------------------------------------- //
// Copy data from materialized input block to the materialized output, using
// given broadcast strides (strides with zeroes).
typedef internal::TensorBlockIO<ScalarNoConst, Index, 2 * NumDims, Layout> TensorBlockIO;
typename TensorBlockIO::Src src(bcast_input_strides, input_buffer);
typename TensorBlockIO::Dst dst(bcast_block_sizes, bcast_block_strides, materialized_output + offset);
return TensorBlockIO::Copy(dst, src);
}
protected:
const Device EIGEN_DEVICE_REF m_device;
const std::remove_reference_t<Broadcast> m_broadcast;
Dimensions m_dimensions;
array<Index, NumDims> m_outputStrides;
array<Index, NumDims> m_inputStrides;
TensorEvaluator<ArgType, Device> m_impl;
};
} // end namespace Eigen
#endif // EIGEN_CXX11_TENSOR_TENSOR_BROADCASTING_H