239 lines
11 KiB
Plaintext
239 lines
11 KiB
Plaintext
/*******************************************************************************
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* Copyright (c) 2015-2018 Skymind, Inc.
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*
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* This program and the accompanying materials are made available under the
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* terms of the Apache License, Version 2.0 which is available at
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* https://www.apache.org/licenses/LICENSE-2.0.
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*
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* Unless required by applicable law or agreed to in writing, software
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* distributed under the License is distributed on an "AS IS" BASIS, WITHOUT
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* WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. See the
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* License for the specific language governing permissions and limitations
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* under the License.
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*
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* SPDX-License-Identifier: Apache-2.0
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******************************************************************************/
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//
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// @author Yurii Shyrma, created on 16.04.2018
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//
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#include <ops/declarable/helpers/reverse.h>
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#include <helpers/ShapeUtils.h>
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#include <array/ResultSet.h>
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#include <helpers/TAD.h>
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#include <helpers/PointersManager.h>
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#include <helpers/ConstantTadHelper.h>
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namespace sd {
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namespace ops {
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namespace helpers {
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template <typename T>
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static __global__ void reverseTadKernel(void* vinput, Nd4jLong *inputShape, void* voutput, Nd4jLong *outputShape, Nd4jLong *inputTadShape, Nd4jLong *inputTadOffsets, Nd4jLong *outputTadShape, Nd4jLong *outputTadOffsets, uint64_t limit, uint64_t numOfElemsToReverse, uint64_t numTads) {
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auto input = reinterpret_cast<T*>(vinput);
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auto output = reinterpret_cast<T*>(voutput);
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const auto tid = blockIdx.x * blockDim.x + threadIdx.x;
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const auto step = gridDim.x * blockDim.x;
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// this means that we'll have additional cycle, to move middle element
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auto div = numOfElemsToReverse / 2;
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auto odd = numOfElemsToReverse % 2 != 0;
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auto rlimit = odd ? limit / 2 + 1 : limit / 2;
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// all threads operate in the same input/output space
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for (uint64_t e = tid; e < rlimit; e += step) {
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// finding out the TAD we're going to process
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auto tadId = e / div;
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if (tadId >= numTads)
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continue;
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// now finding out element within tad
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auto idx = e % div;
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//printf("TID: %i; numTads: %lld; tadLength: %lld; tadId: %i, idx: %lld\n", tid, numTads, numOfElemsToReverse, tadId, idx);
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auto tadInput = input + inputTadOffsets[tadId];
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auto tadOutput = output + outputTadOffsets[tadId];
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// we're calculating offsets within input TAD
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auto fOffset = shape::getIndexOffset(idx, inputTadShape);
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auto lOffset = shape::getIndexOffset(numOfElemsToReverse - idx - 1, inputTadShape);
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// now we're storing input values
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auto v1 = tadInput[fOffset];
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auto v2 = tadInput[lOffset];
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// now we're calculating offsets within output TAD
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auto zfOffset = shape::getIndexOffset(idx, outputTadShape);
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auto zlOffset = shape::getIndexOffset(numOfElemsToReverse - idx - 1, outputTadShape);
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// and saving values to output arrays
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tadOutput[zfOffset] = v2;
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tadOutput[zlOffset] = v1;
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}
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// moving odd element in blocks
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if (odd && threadIdx.x == 0) {
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for (uint64_t e = blockIdx.x; e < numTads; e += gridDim.x) {
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auto tadInput = input + inputTadOffsets[e];
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auto tadOutput = output + outputTadOffsets[e];
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auto xOffset = shape::getIndexOffset(numOfElemsToReverse / 2, inputTadShape);
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auto zOffset = shape::getIndexOffset(numOfElemsToReverse / 2, outputTadShape);
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tadOutput[zOffset] = tadInput[xOffset];
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}
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}
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}
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template <typename T>
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static __global__ void reverseArrayKernel(void* input, Nd4jLong *inputShape, void* output, Nd4jLong *outputShape, Nd4jLong numOfElemsToReverse) {
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const auto tid = blockIdx.x * blockDim.x + threadIdx.x;
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const auto step = gridDim.x * blockDim.x;
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__shared__ int linearStatus;
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__shared__ T* inputArr;
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__shared__ T* outputArr;
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__shared__ char inputOrder, outputOrder;
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if (threadIdx.x == 0) {
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linearStatus = (shape::elementWiseStride(inputShape) == shape::elementWiseStride(outputShape)) && (inputOrder == outputOrder)? shape::elementWiseStride(inputShape):0;
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char inputOrder = shape::order(inputShape);
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char outputOrder = shape::order(outputShape);
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inputArr = reinterpret_cast<T*>(input);
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outputArr = reinterpret_cast<T*>(output);
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}
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__syncthreads();
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auto odd = numOfElemsToReverse % 2 != 0;
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auto limit = numOfElemsToReverse / 2;
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for (uint64_t e = tid; e < limit; e += step) {
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// we're calculating offsets within input array
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auto fOffset = shape::getIndexOffset(e, inputShape);
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auto lOffset = shape::getIndexOffset(numOfElemsToReverse - e - 1, inputShape);
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// now we're storing input values
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auto v1 = inputArr[fOffset];
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auto v2 = inputArr[lOffset];
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// now we're calculating offsets within output array
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auto zfOffset = shape::getIndexOffset(e, outputShape);
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auto zlOffset = shape::getIndexOffset(numOfElemsToReverse - e - 1, outputShape);
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// and saving values to output arrays
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outputArr[zfOffset] = v2;
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outputArr[zlOffset] = v1;
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}
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// in case of odd array we'll have to move middle value
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if (odd && tid == 0) {
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auto xOffset = shape::getIndexOffset(limit, inputShape);
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auto zOffset = shape::getIndexOffset(limit, outputShape);
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outputArr[zOffset] = inputArr[xOffset];
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}
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}
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template<typename T>
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static void reverseTad(sd::LaunchContext * context, const NDArray* input, NDArray* output, Nd4jLong *inputTadShape, Nd4jLong *inputTadOffsets, Nd4jLong *outputTadShape, Nd4jLong *outputTadOffsets, uint64_t tadLength) {
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auto stream = context->getCudaStream();
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reverseTadKernel<T><<<256, 512, 8192, *stream>>>(input->getSpecialBuffer(), input->getSpecialShapeInfo(), output->specialBuffer(), output->specialShapeInfo(), inputTadShape, inputTadOffsets, outputTadShape, outputTadOffsets, input->lengthOf(), tadLength, input->lengthOf() / tadLength);
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}
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template<typename T>
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static void reverseArray(sd::LaunchContext * context, const NDArray* input, NDArray* output, Nd4jLong numOfElemsToReverse) {
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auto stream = context->getCudaStream();
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Nd4jLong numOfReverse = numOfElemsToReverse;
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if (numOfElemsToReverse == 0)
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numOfReverse = input->lengthOf();
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reverseArrayKernel<T><<<256, 512, 8192, *stream>>>(input->getSpecialBuffer(), input->getSpecialShapeInfo(), output->specialBuffer(), output->specialShapeInfo(), numOfReverse);
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}
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///////////////////////////////////////////////////////////////////
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template <typename T>
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static void reverseSequence_(sd::LaunchContext * context, const NDArray* input, const NDArray* seqLengths, NDArray* output, int seqDim, const int batchDim){
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int posOfNonUnityDim = -1;
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seqLengths->syncToHost();
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auto stream = context->getCudaStream();
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if(input->isVector() || shape::isLikeVector(input->getShapeInfo(), posOfNonUnityDim) || seqLengths->lengthOf() == 1) {
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int numOfElemsToReverse = seqLengths->e<int>(0);
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if((seqDim == 0 && input->sizeAt(0) == 1) || (batchDim == posOfNonUnityDim))
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output->assign(input);
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else
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reverseArrayKernel<T><<<256, 512, 8192, *stream>>>(input->getSpecialBuffer(), input->getSpecialShapeInfo(), output->specialBuffer(), output->specialShapeInfo(), numOfElemsToReverse);//helpers::reverseArray<T>(context, const_cast<NDArray*>(input), output, numOfElemsToReverse);
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}
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else {
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if(seqDim > batchDim)
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--seqDim;
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std::vector<int> dimensions = ShapeUtils::evalDimsToExclude(input->rankOf(), {batchDim});
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auto inSubArrsSet = input->allTensorsAlongDimension(dimensions);
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auto outSubArrsSet = output->allTensorsAlongDimension(dimensions);
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for(int i = 0; i < inSubArrsSet.size(); ++i) {
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int numOfElemsToReverse = seqLengths->e<int>(i);
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if(numOfElemsToReverse == 0 || numOfElemsToReverse == 1) {
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outSubArrsSet.at(i)->assign(inSubArrsSet.at(i));
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}
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else {
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auto inInnerSet = inSubArrsSet.at(i)->allTensorsAlongDimension({seqDim});
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auto outInnerSet = outSubArrsSet.at(i)->allTensorsAlongDimension({seqDim});
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for(int j = 0; j < inInnerSet.size(); ++j)
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reverseArray<T>(context, inInnerSet.at(j), outInnerSet.at(j), numOfElemsToReverse);
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}
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}
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}
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}
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void reverseSequence(sd::LaunchContext * context, const NDArray* input, const NDArray* seqLengths, NDArray* output, int seqDim, const int batchDim) {
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NDArray::prepareSpecialUse({output}, {input, seqLengths});
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// if op isn't inplace - copy original data into output array
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if (output->getSpecialBuffer() != input->getSpecialBuffer())
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output->assign(input);
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BUILD_SINGLE_SELECTOR(input->dataType(), reverseSequence_, (context, input, seqLengths, output, seqDim, batchDim), LIBND4J_TYPES);
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NDArray::registerSpecialUse({output}, {input, seqLengths});
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}
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//////////////////////////////////////////////////////////////////////////
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void reverse(sd::LaunchContext * context, const NDArray* input, NDArray* output, const std::vector<int>* intArgs, bool isBackProp) {
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// we need to reverse axis only if that's new op
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std::vector<int> dimensions = isBackProp ? ShapeUtils::evalDimsToExclude(input->rankOf(), *intArgs) : *intArgs;
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std::vector<int> axis = ShapeUtils::evalDimsToExclude(input->rankOf(), dimensions);
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auto packX = sd::ConstantTadHelper::getInstance()->tadForDimensions(input->getShapeInfo(), dimensions);
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auto packZ = sd::ConstantTadHelper::getInstance()->tadForDimensions(output->getShapeInfo(), dimensions);
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NDArray::prepareSpecialUse({output}, {input});
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if (packX.numberOfTads() == 1) {
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BUILD_SINGLE_SELECTOR(input->dataType(), reverseArray, (context, input, output, 0), LIBND4J_TYPES);
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} else {
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BUILD_SINGLE_SELECTOR(input->dataType(), reverseTad, (context, input, output, packX.platformShapeInfo(), packX.platformOffsets(), packZ.platformShapeInfo(), packZ.platformOffsets(), (uint64_t) (input->lengthOf() / packX.numberOfTads())), LIBND4J_TYPES);
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}
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NDArray::registerSpecialUse({output}, {input});
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}
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BUILD_SINGLE_TEMPLATE(template void reverseArray, (sd::LaunchContext * context, const NDArray *inArr, NDArray *outArr, Nd4jLong numOfElemsToReverse), LIBND4J_TYPES);
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}
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}
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}
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