415 lines
22 KiB
Plaintext
415 lines
22 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 sgazeos@gmail.com
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//
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#include <ops/declarable/helpers/image_suppression.h>
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#include <array/NDArrayFactory.h>
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#include <legacy/NativeOps.h>
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#include <exceptions/cuda_exception.h>
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#include <queue>
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namespace sd {
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namespace ops {
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namespace helpers {
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////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
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// needToSuppressWithThreshold - predicate for suppression
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// boxes - boxes tensor buffer
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// boxesShape boxes tensor shape
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// previousIndex - index for current pos value
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// nextIndex - index for neighbor pos value
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// threshold - threashold value to suppress
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//
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// return value: true, if threshold is overcome, false otherwise
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//
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template <typename T>
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static __device__ bool needToSuppressWithThreshold(T* boxes, Nd4jLong* boxesShape, int previousIndex, int nextIndex, T threshold) {
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Nd4jLong previous0[] = {previousIndex, 0};
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Nd4jLong previous1[] = {previousIndex, 1};
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Nd4jLong previous2[] = {previousIndex, 2};
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Nd4jLong previous3[] = {previousIndex, 3};
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Nd4jLong next0[] = {nextIndex, 0};
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Nd4jLong next1[] = {nextIndex, 1};
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Nd4jLong next2[] = {nextIndex, 2};
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Nd4jLong next3[] = {nextIndex, 3};
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// we have rectangle with given max values. Compute vexes of rectangle first
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T minYPrev = sd::math::nd4j_min(boxes[shape::getOffset(boxesShape, previous0)], boxes[shape::getOffset(boxesShape, previous2)]);
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T minXPrev = sd::math::nd4j_min(boxes[shape::getOffset(boxesShape, previous1)], boxes[shape::getOffset(boxesShape, previous3)]);
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T maxYPrev = sd::math::nd4j_max(boxes[shape::getOffset(boxesShape, previous0)], boxes[shape::getOffset(boxesShape, previous2)]);
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T maxXPrev = sd::math::nd4j_max(boxes[shape::getOffset(boxesShape, previous1)], boxes[shape::getOffset(boxesShape, previous3)]);
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T minYNext = sd::math::nd4j_min(boxes[shape::getOffset(boxesShape, next0)], boxes[shape::getOffset(boxesShape, next2)]);
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T minXNext = sd::math::nd4j_min(boxes[shape::getOffset(boxesShape, next1)], boxes[shape::getOffset(boxesShape, next3)]);
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T maxYNext = sd::math::nd4j_max(boxes[shape::getOffset(boxesShape, next0)], boxes[shape::getOffset(boxesShape, next2)]);
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T maxXNext = sd::math::nd4j_max(boxes[shape::getOffset(boxesShape, next1)], boxes[shape::getOffset(boxesShape, next3)]);
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// compute areas for comparation
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T areaPrev = (maxYPrev - minYPrev) * (maxXPrev - minXPrev);
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T areaNext = (maxYNext - minYNext) * (maxXNext - minXNext);
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// of course, areas should be positive
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if (areaNext <= T(0.f) || areaPrev <= T(0.f)) return false;
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// compute intersection of rectangles
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T minIntersectionY = sd::math::nd4j_max(minYPrev, minYNext);
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T minIntersectionX = sd::math::nd4j_max(minXPrev, minXNext);
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T maxIntersectionY = sd::math::nd4j_min(maxYPrev, maxYNext);
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T maxIntersectionX = sd::math::nd4j_min(maxXPrev, maxXNext);
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T intersectionArea =
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sd::math::nd4j_max(T(maxIntersectionY - minIntersectionY), T(0.0f)) *
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sd::math::nd4j_max(T(maxIntersectionX - minIntersectionX), T(0.0f));
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T intersectionValue = intersectionArea / (areaPrev + areaNext - intersectionArea);
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// final check
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return intersectionValue > threshold;
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}
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template <typename T>
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static __device__ T similirityV3(T* boxes, Nd4jLong* boxesShape, int previousIndex, int nextIndex) {
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Nd4jLong previous0[] = {previousIndex, 0};
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Nd4jLong previous1[] = {previousIndex, 1};
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Nd4jLong previous2[] = {previousIndex, 2};
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Nd4jLong previous3[] = {previousIndex, 3};
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Nd4jLong next0[] = {nextIndex, 0};
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Nd4jLong next1[] = {nextIndex, 1};
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Nd4jLong next2[] = {nextIndex, 2};
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Nd4jLong next3[] = {nextIndex, 3};
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// we have rectangle with given max values. Compute vexes of rectangle first
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T minYPrev = sd::math::nd4j_min(boxes[shape::getOffset(boxesShape, previous0)], boxes[shape::getOffset(boxesShape, previous2)]);
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T minXPrev = sd::math::nd4j_min(boxes[shape::getOffset(boxesShape, previous1)], boxes[shape::getOffset(boxesShape, previous3)]);
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T maxYPrev = sd::math::nd4j_max(boxes[shape::getOffset(boxesShape, previous0)], boxes[shape::getOffset(boxesShape, previous2)]);
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T maxXPrev = sd::math::nd4j_max(boxes[shape::getOffset(boxesShape, previous1)], boxes[shape::getOffset(boxesShape, previous3)]);
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T minYNext = sd::math::nd4j_min(boxes[shape::getOffset(boxesShape, next0)], boxes[shape::getOffset(boxesShape, next2)]);
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T minXNext = sd::math::nd4j_min(boxes[shape::getOffset(boxesShape, next1)], boxes[shape::getOffset(boxesShape, next3)]);
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T maxYNext = sd::math::nd4j_max(boxes[shape::getOffset(boxesShape, next0)], boxes[shape::getOffset(boxesShape, next2)]);
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T maxXNext = sd::math::nd4j_max(boxes[shape::getOffset(boxesShape, next1)], boxes[shape::getOffset(boxesShape, next3)]);
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// compute areas for comparation
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T areaPrev = (maxYPrev - minYPrev) * (maxXPrev - minXPrev);
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T areaNext = (maxYNext - minYNext) * (maxXNext - minXNext);
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// of course, areas should be positive
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if (areaNext <= T(0.f) || areaPrev <= T(0.f)) return false;
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// compute intersection of rectangles
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T minIntersectionY = sd::math::nd4j_max(minYPrev, minYNext);
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T minIntersectionX = sd::math::nd4j_max(minXPrev, minXNext);
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T maxIntersectionY = sd::math::nd4j_min(maxYPrev, maxYNext);
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T maxIntersectionX = sd::math::nd4j_min(maxXPrev, maxXNext);
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T intersectionArea =
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sd::math::nd4j_max(T(maxIntersectionY - minIntersectionY), T(0.0f)) *
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sd::math::nd4j_max(T(maxIntersectionX - minIntersectionX), T(0.0f));
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T intersectionValue = intersectionArea / (areaPrev + areaNext - intersectionArea);
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// final check
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return intersectionValue;
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}
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////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
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// shouldSelectKernel - compute status for all selected rectangles (boxes)
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//
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// we compute boolean flag as shared uint32 and return it on final only for the first thread
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//
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template <typename T, typename I>
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static __global__ void shouldSelectKernel(T* boxesBuf, Nd4jLong* boxesShape, I* indexBuf, I* selectedIndicesData, double threshold, int numSelected, int i, bool* shouldSelect) {
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auto tid = blockIdx.x * blockDim.x + threadIdx.x;
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auto step = gridDim.x * blockDim.x;
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__shared__ unsigned int shouldSelectShared;
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if (threadIdx.x == 0) {
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shouldSelectShared = (unsigned int)shouldSelect[0];
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}
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__syncthreads();
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for (int j = numSelected - 1 - tid; j >= 0; j -= step) {
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if (shouldSelectShared) {
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if (needToSuppressWithThreshold(boxesBuf, boxesShape, indexBuf[i],
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indexBuf[selectedIndicesData[j]], T(threshold)))
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atomicCAS(&shouldSelectShared, 1, 0); // exchange only when need to suppress
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}
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}
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__syncthreads();
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// final move: collect result
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if (threadIdx.x == 0) {
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*shouldSelect = shouldSelectShared > 0;
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}
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}
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////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
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// indices - type depended, indicesLong - type defined (only 64bit integers)
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//
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template <typename I>
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static __global__ void copyIndices(void* indices, void* indicesLong, Nd4jLong len) {
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I* indexBuf = reinterpret_cast<I*>(indices);
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Nd4jLong* srcBuf = reinterpret_cast<Nd4jLong*>(indicesLong);;
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auto tid = threadIdx.x + blockIdx.x * blockDim.x;
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auto step = blockDim.x * gridDim.x;
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for (auto i = tid; i < len; i += step)
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indexBuf[i] = (I)srcBuf[i];
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}
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template <typename T, typename I>
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static __global__ void suppressScores(T* scores, I* indices, Nd4jLong length, T scoreThreshold) {
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auto start = blockIdx.x * blockDim.x;
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auto step = gridDim.x * blockDim.x;
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for (auto e = start + threadIdx.x; e < (int)length; e += step) {
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if (scores[e] < scoreThreshold) {
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scores[e] = scoreThreshold;
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indices[e] = -1;
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}
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else {
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indices[e] = I(e);
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}
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}
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}
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////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
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// nonMaxSuppressionV2 algorithm - given from TF NonMaxSuppressionV2 implementation
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//
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template <typename T, typename I>
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static void nonMaxSuppressionV2_(sd::LaunchContext* context, NDArray* boxes, NDArray* scales, int maxSize, double threshold, double scoreThreshold, NDArray* output) {
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auto stream = context->getCudaStream();
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NDArray::prepareSpecialUse({output}, {boxes, scales});
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std::unique_ptr<NDArray> indices(NDArrayFactory::create_<I>('c', {scales->lengthOf()})); // - 1, scales->lengthOf()); //, scales->getContext());
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NDArray scores(*scales);
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Nd4jPointer extras[2] = {nullptr, stream};
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auto indexBuf = indices->dataBuffer()->specialAsT<I>();///reinterpret_cast<I*>(indices->specialBuffer());
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auto scoreBuf = scores.dataBuffer()->specialAsT<T>();
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suppressScores<T,I><<<128, 128, 128, *stream>>>(scoreBuf, indexBuf, scores.lengthOf(), T(scoreThreshold));
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indices->tickWriteDevice();
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sortByValue(extras, indices->buffer(), indices->shapeInfo(), indices->specialBuffer(), indices->specialShapeInfo(), scores.buffer(), scores.shapeInfo(), scores.specialBuffer(), scores.specialShapeInfo(), true);
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indices->tickWriteDevice();
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NDArray selectedIndices = NDArrayFactory::create<I>('c', {output->lengthOf()});
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int numSelected = 0;
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int numBoxes = boxes->sizeAt(0);
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auto boxesBuf = reinterpret_cast<T*>(boxes->specialBuffer());
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auto selectedIndicesData = reinterpret_cast<I*>(selectedIndices.specialBuffer());
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auto outputBuf = reinterpret_cast<I*>(output->specialBuffer());
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bool* shouldSelectD;
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auto err = cudaMalloc(&shouldSelectD, sizeof(bool));
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if (err) {
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throw cuda_exception::build("helpers::nonMaxSuppressionV2: Cannot allocate memory for bool flag", err);
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}
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for (I i = 0; i < boxes->sizeAt(0); ++i) {
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bool shouldSelect = numSelected < output->lengthOf();
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if (shouldSelect) {
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err = cudaMemcpy(shouldSelectD, &shouldSelect, sizeof(bool), cudaMemcpyHostToDevice);
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if (err) {
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throw cuda_exception::build("helpers::nonMaxSuppressionV2: Cannot set up bool flag to device", err);
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}
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shouldSelectKernel<T,I><<<128, 256, 1024, *stream>>>(boxesBuf, boxes->specialShapeInfo(), indexBuf, selectedIndicesData, threshold, numSelected, i, shouldSelectD);
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err = cudaMemcpy(&shouldSelect, shouldSelectD, sizeof(bool), cudaMemcpyDeviceToHost);
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if (err) {
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throw cuda_exception::build("helpers::nonMaxSuppressionV2: Cannot set up bool flag to host", err);
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}
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}
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if (shouldSelect) {
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cudaMemcpy(reinterpret_cast<I*>(output->specialBuffer()) + numSelected, indexBuf + i, sizeof(I), cudaMemcpyDeviceToDevice);
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cudaMemcpy(selectedIndicesData + numSelected, &i, sizeof(I), cudaMemcpyHostToDevice);
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numSelected++;
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}
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}
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err = cudaFree(shouldSelectD);
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if (err) {
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throw cuda_exception::build("helpers::nonMaxSuppressionV2: Cannot deallocate memory for bool flag", err);
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}
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}
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////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
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template <typename T, typename I>
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static __device__ bool checkOverlapBoxes(T* boxes, Nd4jLong* shape, T* scores, I* indices, I* selectedIndices, I* startIndices, I selectedSize, I nextCandidateIndex, T overlapThreshold, T scoreThreshold, bool simple) {
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bool shouldHardSuppress = false;
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T& nextCandidateScore = scores[nextCandidateIndex];
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I selectedIndex = indices[nextCandidateIndex];
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I finish = startIndices[nextCandidateIndex];
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for (int j = selectedSize; j > finish; --j) {
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T boxVal;
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if (simple) {
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Nd4jLong xPos[] = {selectedIndex, selectedIndices[j - 1]};
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auto xShift = shape::getOffset(shape, xPos, 0);
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boxVal = boxes[xShift];
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}
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else {
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boxVal = similirityV3(boxes, shape, selectedIndex, selectedIndices[j - 1]);
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}
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if (boxVal > static_cast<T>(overlapThreshold))
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nextCandidateScore = static_cast<T>(0.f);
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// First decide whether to perform hard suppression
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if (boxVal >= overlapThreshold) {
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shouldHardSuppress = true;
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break;
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}
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// If nextCandidate survives hard suppression, apply soft suppression
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if (nextCandidateScore <= static_cast<T>(scoreThreshold)) break;
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}
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return shouldHardSuppress;
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}
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////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
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template <typename T, typename I>
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static __global__ void
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suppressNonMaxOverlapKernel(T* boxes, Nd4jLong* boxesShape, T* scoresData, I* indices, I* startIndices, Nd4jLong length, I maxOutputLen,
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T overlapThreshold, T scoreThreshold, I* output, Nd4jLong* outputShape, I* outputLength, bool simple) {
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__shared__ I selectedSize;
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__shared__ I* tempOutput;
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if (threadIdx.x == 0) {
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selectedSize = outputLength?*outputLength:maxOutputLen;
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extern __shared__ unsigned char shmem[];
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tempOutput = (I*)shmem;
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}
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__syncthreads();
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auto start = blockIdx.x * blockDim.x;
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auto step = blockDim.x * gridDim.x;
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for (I nextCandidateIndex = start + threadIdx.x; selectedSize < maxOutputLen && nextCandidateIndex < (I)length; ) {
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auto originalScore = scoresData[nextCandidateIndex];//nextCandidate._score;
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I nextCandidateBoxIndex = indices[nextCandidateIndex];
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auto selectedSizeMark = selectedSize;
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// skip for cases when index is less than 0 (under score threshold)
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if (nextCandidateBoxIndex < 0) {
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nextCandidateIndex += step;
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continue;
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}
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// check for overlaps
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bool shouldHardSuppress = checkOverlapBoxes(boxes, boxesShape, scoresData, indices, tempOutput, startIndices, selectedSize,
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nextCandidateIndex, overlapThreshold, scoreThreshold, simple);//false;
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T nextCandidateScore = scoresData[nextCandidateIndex];
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startIndices[nextCandidateIndex] = selectedSize;
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if (!shouldHardSuppress) {
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if (nextCandidateScore == originalScore) {
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// Suppression has not occurred, so select nextCandidate
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if (output)
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output[selectedSize] = nextCandidateBoxIndex;
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tempOutput[selectedSize] = nextCandidateBoxIndex;
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math::atomics::nd4j_atomicAdd(&selectedSize, (I)1);
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}
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if (nextCandidateScore > scoreThreshold) {
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// Soft suppression has occurred and current score is still greater than
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// scoreThreshold; add nextCandidate back onto priority queue.
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continue; // in some cases, this index not 0
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}
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}
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nextCandidateIndex += step;
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}
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if (threadIdx.x == 0) {
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if (outputLength)
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*outputLength = selectedSize;
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}
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}
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////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
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template <typename T, typename I>
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static Nd4jLong
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nonMaxSuppressionGeneric_(sd::LaunchContext* context, NDArray* boxes, NDArray* scores, int outputSize,
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double overlapThreshold, double scoreThreshold, NDArray* output, bool simple) {
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auto stream = context->getCudaStream();
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if (output)
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NDArray::prepareSpecialUse({output}, {boxes, scores});
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else {
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if (!boxes->isActualOnDeviceSide())
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boxes->syncToDevice();
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if (!scores->isActualOnDeviceSide())
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scores->syncToDevice();
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}
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NDArray indices = NDArrayFactory::create<I>('c', {scores->lengthOf()}); // - 1, scales->lengthOf()); //, scales->getContext());
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NDArray startPositions = NDArrayFactory::create<I>('c', {scores->lengthOf()});
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NDArray selectedScores(*scores);
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Nd4jPointer extras[2] = {nullptr, stream};
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auto indexBuf = indices.dataBuffer()->specialAsT<I>();///reinterpret_cast<I*>(indices->specialBuffer());
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suppressScores<<<128, 128, 128, *stream>>>(selectedScores.dataBuffer()->specialAsT<T>(), indexBuf, selectedScores.lengthOf(), T(scoreThreshold));
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sortByValue(extras, indices.buffer(), indices.shapeInfo(), indices.specialBuffer(), indices.specialShapeInfo(), selectedScores.buffer(), selectedScores.shapeInfo(), selectedScores.specialBuffer(), selectedScores.specialShapeInfo(), true);
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indices.tickWriteDevice();
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selectedScores.tickWriteDevice();
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auto scoresData = selectedScores.dataBuffer()->specialAsT<T>();//, numBoxes, scoresData.begin());
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auto startIndices = startPositions.dataBuffer()->specialAsT<I>();
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I selectedSize = 0;
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Nd4jLong res = 0;
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if (output) { // this part used when output shape already calculated to fill up values on output
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DataBuffer selectedSizeBuf(&selectedSize, sizeof(I), DataTypeUtils::fromT<I>());
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suppressNonMaxOverlapKernel<<<1, 1, 1024, *stream >>> (boxes->dataBuffer()->specialAsT<T>(),
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boxes->specialShapeInfo(), scoresData, indexBuf, startIndices, scores->lengthOf(), (I) outputSize,
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T(overlapThreshold), T(scoreThreshold), output->dataBuffer()->specialAsT<I>(), output->specialShapeInfo(),
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selectedSizeBuf.specialAsT<I>(), simple);
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}
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else { // this case used on calculation of output shape. Output and output shape shoulde be nullptr.
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DataBuffer selectedSizeBuf(&selectedSize, sizeof(I), DataTypeUtils::fromT<I>());
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suppressNonMaxOverlapKernel<<<1, 1, 1024, *stream >>> (boxes->dataBuffer()->specialAsT<T>(),
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boxes->specialShapeInfo(), scoresData, indexBuf, startIndices, scores->lengthOf(), (I)outputSize,
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T(overlapThreshold), T(scoreThreshold), (I*)nullptr, (Nd4jLong*) nullptr, selectedSizeBuf.specialAsT<I>(), simple);
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selectedSizeBuf.syncToPrimary(context, true);
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res = *selectedSizeBuf.primaryAsT<I>();
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}
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if (output)
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NDArray::registerSpecialUse({output}, {boxes, scores});
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return res;
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}
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////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
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void nonMaxSuppression(sd::LaunchContext * context, NDArray* boxes, NDArray* scales, int maxSize, double threshold, double scoreThreshold, NDArray* output) {
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BUILD_DOUBLE_SELECTOR(boxes->dataType(), output->dataType(), nonMaxSuppressionV2_,
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(context, boxes, scales, maxSize, threshold, scoreThreshold, output),
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FLOAT_TYPES, INDEXING_TYPES);
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}
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////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
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Nd4jLong nonMaxSuppressionGeneric(sd::LaunchContext * context, NDArray* boxes, NDArray* scales, int maxSize, double threshold, double scoreThreshold, NDArray* output) {
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BUILD_DOUBLE_SELECTOR(boxes->dataType(), output ? output->dataType():DataType::INT32, return nonMaxSuppressionGeneric_,
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(context, boxes, scales, maxSize, threshold, scoreThreshold, output, true),
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FLOAT_TYPES, INDEXING_TYPES);
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return boxes->sizeAt(0);
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}
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Nd4jLong
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nonMaxSuppressionV3(sd::LaunchContext* context, NDArray* boxes, NDArray* scores, int maxSize,
|
|
double overlapThreshold, double scoreThreshold, NDArray* output) {
|
|
BUILD_DOUBLE_SELECTOR(boxes->dataType(), output ? output->dataType():DataType::INT32, return nonMaxSuppressionGeneric_,
|
|
(context, boxes, scores, maxSize, overlapThreshold, scoreThreshold, output, false),
|
|
FLOAT_TYPES, INDEXING_TYPES);
|
|
return boxes->sizeAt(0);
|
|
}
|
|
|
|
}
|
|
}
|
|
}
|