/* ****************************************************************************** * * * This program and the accompanying materials are made available under the * terms of the Apache License, Version 2.0 which is available at * https://www.apache.org/licenses/LICENSE-2.0. * * See the NOTICE file distributed with this work for additional * information regarding copyright ownership. * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, WITHOUT * WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. See the * License for the specific language governing permissions and limitations * under the License. * * SPDX-License-Identifier: Apache-2.0 ******************************************************************************/ // // @author Yurii Shyrma (iuriish@yahoo.com), created on 14.03.2019 // #ifndef LIBND4J_LOOPS_H #define LIBND4J_LOOPS_H #include #include #include #include #include #include #include #include #include #include #include namespace sd { template class ND4J_EXPORT ReductionLoops { protected: public: template static FORCEINLINE void loopReduce(sd::memory::Workspace* workspace, const X* x, const Nd4jLong *xShapeInfo, Z* z, const Nd4jLong *zShapeInfo, const int* dims, E* extraParams); }; template class ReductionFloatLoops : public ReductionLoops { public: static void wrapper(int opNum, sd::memory::Workspace* workspace, const X* x, const Nd4jLong *xShapeInfo, Z* z, const Nd4jLong *zShapeInfo, const int* dims, Z* extraParams); template static void innerloopReduce(sd::memory::Workspace* workspace, const X* x, const Nd4jLong *xShapeInfo, Z* z, const Nd4jLong *zShapeInfo, const int* dims, Z* extraParams); }; template class ND4J_EXPORT ReductionBoolLoops : public ReductionLoops { public: static void wrapper(int opNum, sd::memory::Workspace* workspace, const X* x, const Nd4jLong *xShapeInfo, Z* z, const Nd4jLong *zShapeInfo, const int* dims, X* extraParams); template static void innerloopReduce(sd::memory::Workspace* workspace, const X* x, const Nd4jLong *xShapeInfo, Z* z, const Nd4jLong *zShapeInfo, const int* dims, X* extraParams); }; template class ND4J_EXPORT ReductionLongLoops : public ReductionLoops { public: static void wrapper(int opNum, sd::memory::Workspace* workspace, const X* x, const Nd4jLong *xShapeInfo, Z* z, const Nd4jLong *zShapeInfo, const int* dims, X* extraParams); template static void innerloopReduce(sd::memory::Workspace* workspace, const X* x, const Nd4jLong *xShapeInfo, Z* z, const Nd4jLong *zShapeInfo, const int* dims, X* extraParams); }; template class ND4J_EXPORT ReductionSameLoops : public ReductionLoops { public: static void wrapper(int opNum, sd::memory::Workspace* workspace, const X* x, const Nd4jLong *xShapeInfo, X* z, const Nd4jLong *zShapeInfo, const int* dims, X* extraParams); template static void innerloopReduce(sd::memory::Workspace* workspace, const X* x, const Nd4jLong *xShapeInfo, X* z, const Nd4jLong *zShapeInfo, const int* dims, X* extraParams); }; template class ND4J_EXPORT IndexReductionLoops { private: public: static void wrapIndexReduce(int opNum, const void* x, const Nd4jLong* xShapeInfo, void* z, const Nd4jLong* zShapeInfo, const Nd4jLong* tadShapeInfo, const Nd4jLong* tadOffsets, void* extraParams); template static void loopIndexReduce(const X* x, const Nd4jLong* xShapeInfo, Z* z, const Nd4jLong* zShapeInfo, const Nd4jLong* tadShapeInfo, const Nd4jLong* tadOffsets, X* extraParams); }; template class ND4J_EXPORT TransformLoops { public: template static FORCEINLINE void loopTransform(const X* x, const Nd4jLong* xShapeInfo, Z* z, const Nd4jLong* zShapeInfo, E* extraParams, uint64_t threadId, uint64_t numThreads); }; template class ND4J_EXPORT Reduction3Loops { public: template static FORCEINLINE void loopReduce3(const X* x, const Nd4jLong* xShapeInfo, const X* y, const Nd4jLong* yShapeInfo, Z* z, const Nd4jLong* zShapeInfo, int* dims, int dimsLen, Z* extraParams, int64_t start, int64_t stop); template static FORCEINLINE void loopReduce3All(const X* x, const Nd4jLong* xShapeInfo, const X* y, const Nd4jLong* yShapeInfo, Z* z, const Nd4jLong* zShapeInfo, const Nd4jLong* xTadShapeInfo, const Nd4jLong* xTadOffsets, const Nd4jLong* yTadShapeInfo, const Nd4jLong* yTadOffsets, Z* extraParams, int64_t start, int64_t stop); static void wrapper(int opNum, const X* x, const Nd4jLong* xShapeInfo, const X* y, const Nd4jLong* yShapeInfo, Z* z, const Nd4jLong* zShapeInfo, int* dims, int dimsLen, Z* extraParams, int64_t start, int64_t stop); static void wrapperAll(int opNum, const X* x, const Nd4jLong* xShapeInfo, const X* y, const Nd4jLong* yShapeInfo, Z* z, const Nd4jLong* zShapeInfo, const Nd4jLong* xTadShapeInfo, const Nd4jLong* xTadOffsets, const Nd4jLong* yTadShapeInfo, const Nd4jLong* yTadOffsets, Z* extraParams, int64_t start, int64_t stop); template static void innerloopReduce3(const X* x, const Nd4jLong* xShapeInfo, const X* y, const Nd4jLong* yShapeInfo, Z* z, const Nd4jLong* zShapeInfo, int* dims, int dimsLen, Z* extraParams, int64_t start, int64_t stop); template static void innerloopReduce3All(const X* x, const Nd4jLong* xShapeInfo, const X* y, const Nd4jLong* yShapeInfo, Z* z, const Nd4jLong* zShapeInfo, const Nd4jLong* xTadShapeInfo, const Nd4jLong* xTadOffsets, const Nd4jLong* yTadShapeInfo, const Nd4jLong* yTadOffsets, Z* extraParams, int64_t start, int64_t stop); }; ////////////////////////////////////////////////////////////////////////// template static void reduceExec21(const X *x, const Nd4jLong *xShapeInfo, Z* z, const Nd4jLong *zShapeInfo, const int *dims, E* extraParams) { const uint xAxis0 = shape::sizeAt(xShapeInfo, dims[0]); const Nd4jLong xStrd0 = shape::strideAt(xShapeInfo, dims[0]); const Nd4jLong zStrd0 = shape::strideAt(zShapeInfo, 0); const uint xAxis1 = shape::sizeAt(xShapeInfo, dims[1]); const Nd4jLong xStrd1 = shape::strideAt(xShapeInfo, dims[1]); auto func = PRAGMA_THREADS_FOR { for (auto i0 = start; i0 < stop; ++i0) { auto x0 = x + i0 * xStrd0; auto z0 = z + i0 * zStrd0; auto s = OpType::startingValue(x0); if(xStrd1 == 1) for (uint i1 = 0; i1 < xAxis1; ++i1) s = OpType::update(s, OpType::op(x0[i1], extraParams), extraParams); else for (uint i1 = 0; i1 < xAxis1; ++i1) s = OpType::update(s, OpType::op(x0[i1 * xStrd1], extraParams), extraParams); *z0 = OpType::postProcess(s, static_cast(xAxis1), extraParams); } }; samediff::Threads::parallel_for(func, 0,xAxis0); } ////////////////////////////////////////////////////////////////////////// template static void reduceExec31(const X *x, const Nd4jLong *xShapeInfo, Z* z, const Nd4jLong *zShapeInfo, const int *dims, E* extraParams) { const uint xAxis0 = shape::sizeAt(xShapeInfo, dims[0]); const Nd4jLong xStrd0 = shape::strideAt(xShapeInfo, dims[0]); const Nd4jLong zStrd0 = shape::strideAt(zShapeInfo, 0); const uint xAxis1 = shape::sizeAt(xShapeInfo, dims[1]); const Nd4jLong xStrd1 = shape::strideAt(xShapeInfo, dims[1]); const uint xAxis2 = shape::sizeAt(xShapeInfo, dims[2]); const Nd4jLong xStrd2 = shape::strideAt(xShapeInfo, dims[2]); const Nd4jLong tadLen = static_cast(xAxis1 * xAxis2); auto func = PRAGMA_THREADS_FOR { for (auto i0 = start; i0 < stop; ++i0) { auto x0 = x + i0 * xStrd0; auto z0 = z + i0 * zStrd0; auto s = OpType::startingValue(x0); if(xStrd1 == 1) for (uint i2 = 0; i2 < xAxis2; ++i2) for (uint i1 = 0; i1 < xAxis1; ++i1) s = OpType::update(s, OpType::op(x0[i1 + i2*xStrd2], extraParams), extraParams); else if(xStrd2 == 1) for (uint i1 = 0; i1 < xAxis1; ++i1) for (uint i2 = 0; i2 < xAxis2; ++i2) s = OpType::update(s, OpType::op(x0[i1*xStrd1 + i2], extraParams), extraParams); else for (uint i1 = 0; i1 < xAxis1; ++i1) for (uint i2 = 0; i2 < xAxis2; ++i2) s = OpType::update(s, OpType::op(x0[i1*xStrd1 + i2*xStrd2], extraParams), extraParams); *z0 = OpType::postProcess(s, tadLen, extraParams); } }; samediff::Threads::parallel_for(func, 0,xAxis0); } ////////////////////////////////////////////////////////////////////////// template void reduceExec32(const X *x, const Nd4jLong *xShapeInfo, Z* z, const Nd4jLong *zShapeInfo, const int *dims, E* extraParams) { const uint xAxis0 = shape::sizeAt(xShapeInfo, shape::order(zShapeInfo) == 'c' ? dims[0] : dims[1]); const Nd4jLong xStrd0 = shape::strideAt(xShapeInfo, shape::order(zShapeInfo) == 'c' ? dims[0] : dims[1]); const Nd4jLong zStrd0 = shape::strideAt(zShapeInfo, shape::order(zShapeInfo) == 'c' ? 0 : 1); const uint xAxis1 = shape::sizeAt(xShapeInfo, shape::order(zShapeInfo) == 'c' ? dims[1] : dims[0]); const Nd4jLong xStrd1 = shape::strideAt(xShapeInfo, shape::order(zShapeInfo) == 'c' ? dims[1] : dims[0]); const Nd4jLong zStrd1 = shape::strideAt(zShapeInfo, shape::order(zShapeInfo) == 'c' ? 1 : 0); const uint xAxis2 = shape::sizeAt(xShapeInfo, dims[2]); const Nd4jLong xStrd2 = shape::strideAt(xShapeInfo, dims[2]); auto func = PRAGMA_THREADS_FOR_2D { for (auto i0 = start_x; i0 < stop_x; ++i0) { for (auto i1 = start_y; i1 < stop_y; ++i1) { auto x1 = x + i0 * xStrd0 + i1 * xStrd1; auto z1 = z + i0 * zStrd0 + i1 * zStrd1; auto s = OpType::startingValue(x1); if(xStrd2 == 1) for (uint i2 = 0; i2 < xAxis2; ++i2) s = OpType::update(s, OpType::op(x1[i2], extraParams), extraParams); else for (uint i2 = 0; i2 < xAxis2; ++i2) s = OpType::update(s, OpType::op(x1[i2 * xStrd2], extraParams), extraParams); *z1 = OpType::postProcess(s, static_cast(xAxis2), extraParams); } } }; samediff::Threads::parallel_for(func, 0,xAxis0,1, 0,xAxis1,1); } ////////////////////////////////////////////////////////////////////////// template void reduceExec41(const X *x, const Nd4jLong *xShapeInfo, Z* z, const Nd4jLong *zShapeInfo, const int *dims, E* extraParams) { const uint xAxis0 = shape::sizeAt(xShapeInfo, dims[0]); const Nd4jLong xStrd0 = shape::strideAt(xShapeInfo, dims[0]); const Nd4jLong zStrd0 = shape::strideAt(zShapeInfo, 0); const uint xAxis1 = shape::sizeAt(xShapeInfo, dims[1]); const Nd4jLong xStrd1 = shape::strideAt(xShapeInfo, dims[1]); const uint xAxis2 = shape::sizeAt(xShapeInfo, dims[2]); const Nd4jLong xStrd2 = shape::strideAt(xShapeInfo, dims[2]); const uint xAxis3 = shape::sizeAt(xShapeInfo, dims[3]); const Nd4jLong xStrd3 = shape::strideAt(xShapeInfo, dims[3]); const Nd4jLong tadLen = static_cast(xAxis1 * xAxis2 * xAxis3); auto func = PRAGMA_THREADS_FOR { for (auto i0 = start; i0 < stop; ++i0) { auto x0 = x + i0 * xStrd0; auto z0 = z + i0 * zStrd0; auto s = OpType::startingValue(x0); if(xStrd1 == 1) for (uint i3 = 0; i3 < xAxis3; ++i3) for (uint i2 = 0; i2 < xAxis2; ++i2) for (uint i1 = 0; i1 < xAxis1; ++i1) s = OpType::update(s, OpType::op(x0[i1 + i2*xStrd2 + i3*xStrd3], extraParams), extraParams); else if(xStrd2 == 1) for (uint i1 = 0; i1 < xAxis1; ++i1) for (uint i3 = 0; i3 < xAxis3; ++i3) for (uint i2 = 0; i2 < xAxis2; ++i2) s = OpType::update(s, OpType::op(x0[i1*xStrd1 + i2 + i3*xStrd3], extraParams), extraParams); else if(xStrd3 == 1) for (uint i1 = 0; i1 < xAxis1; ++i1) for (uint i2 = 0; i2 < xAxis2; ++i2) for (uint i3 = 0; i3 < xAxis3; ++i3) s = OpType::update(s, OpType::op(x0[i1*xStrd1 + i2*xStrd2 + i3], extraParams), extraParams); else for (uint i1 = 0; i1 < xAxis1; ++i1) for (uint i2 = 0; i2 < xAxis2; ++i2) for (uint i3 = 0; i3 < xAxis3; ++i3) s = OpType::update(s, OpType::op(x0[i1*xStrd1 + i2*xStrd2 + i3*xStrd3], extraParams), extraParams); *z0 = OpType::postProcess(s, tadLen, extraParams); } }; samediff::Threads::parallel_for(func, 0,xAxis0); } ////////////////////////////////////////////////////////////////////////// template void reduceExec42(const X *x, const Nd4jLong *xShapeInfo, Z* z, const Nd4jLong *zShapeInfo, const int *dims, E* extraParams) { const uint xAxis0 = shape::sizeAt(xShapeInfo, shape::order(zShapeInfo) == 'c' ? dims[0] : dims[1]); const Nd4jLong xStrd0 = shape::strideAt(xShapeInfo, shape::order(zShapeInfo) == 'c' ? dims[0] : dims[1]); const Nd4jLong zStrd0 = shape::strideAt(zShapeInfo, shape::order(zShapeInfo) == 'c' ? 0 : 1); const uint xAxis1 = shape::sizeAt(xShapeInfo, shape::order(zShapeInfo) == 'c' ? dims[1] : dims[0]); const Nd4jLong xStrd1 = shape::strideAt(xShapeInfo, shape::order(zShapeInfo) == 'c' ? dims[1] : dims[0]); const Nd4jLong zStrd1 = shape::strideAt(zShapeInfo, shape::order(zShapeInfo) == 'c' ? 1 : 0); const uint xAxis2 = shape::sizeAt(xShapeInfo, dims[2]); const Nd4jLong xStrd2 = shape::strideAt(xShapeInfo, dims[2]); const uint xAxis3 = shape::sizeAt(xShapeInfo, dims[3]); const Nd4jLong xStrd3 = shape::strideAt(xShapeInfo, dims[3]); const Nd4jLong tadLen = static_cast(xAxis2 * xAxis3); auto func = PRAGMA_THREADS_FOR_2D { for (auto i0 = start_x; i0 < stop_x; ++i0) { for (auto i1 = start_y; i1 < stop_y; ++i1) { auto x1 = x + i0 * xStrd0 + i1 * xStrd1; auto z1 = z + i0 * zStrd0 + i1 * zStrd1; auto s = OpType::startingValue(x1); if(xStrd2 == 1) for (uint i3 = 0; i3 < xAxis3; ++i3) for (uint i2 = 0; i2 < xAxis2; ++i2) s = OpType::update(s, OpType::op(x1[i2 + i3*xStrd3], extraParams), extraParams); else if(xStrd3 == 1) for (uint i2 = 0; i2 < xAxis2; ++i2) for (uint i3 = 0; i3 < xAxis3; ++i3) s = OpType::update(s, OpType::op(x1[i2*xStrd2 + i3], extraParams), extraParams); else for (uint i2 = 0; i2 < xAxis2; ++i2) for (uint i3 = 0; i3 < xAxis3; ++i3) s = OpType::update(s, OpType::op(x1[i2*xStrd2 + i3*xStrd3], extraParams), extraParams); *z1 = OpType::postProcess(s, tadLen, extraParams); } } }; samediff::Threads::parallel_for(func, 0,xAxis0,1, 0,xAxis1,1); } ////////////////////////////////////////////////////////////////////////// template void reduceExec43(const X *x, const Nd4jLong *xShapeInfo, Z* z, const Nd4jLong *zShapeInfo, const int *dims, E* extraParams) { const uint xAxis0 = shape::sizeAt(xShapeInfo, shape::order(zShapeInfo) == 'c' ? dims[0] : dims[2]); const Nd4jLong xStrd0 = shape::strideAt(xShapeInfo, shape::order(zShapeInfo) == 'c' ? dims[0] : dims[2]); const Nd4jLong zStrd0 = shape::strideAt(zShapeInfo, shape::order(zShapeInfo) == 'c' ? 0 : 2); const uint xAxis1 = shape::sizeAt(xShapeInfo, dims[1]); const Nd4jLong xStrd1 = shape::strideAt(xShapeInfo, dims[1]); const Nd4jLong zStrd1 = shape::strideAt(zShapeInfo, 1); const uint xAxis2 = shape::sizeAt(xShapeInfo, shape::order(zShapeInfo) == 'c' ? dims[2] : dims[0]); const Nd4jLong xStrd2 = shape::strideAt(xShapeInfo, shape::order(zShapeInfo) == 'c' ? dims[2] : dims[0]); const Nd4jLong zStrd2 = shape::strideAt(zShapeInfo, shape::order(zShapeInfo) == 'c' ? 2 : 0); const uint xAxis3 = shape::sizeAt(xShapeInfo, dims[3]); const Nd4jLong xStrd3 = shape::strideAt(xShapeInfo, dims[3]); auto func = PRAGMA_THREADS_FOR_3D { for (auto i0 = start_x; i0 < stop_x; ++i0) { for (auto i1 = start_y; i1 < stop_y; ++i1) { for (auto i2 = start_z; i2 < stop_z; ++i2) { auto x2 = x + i0 * xStrd0 + i1 * xStrd1 + i2 * xStrd2; auto z2 = z + i0 * zStrd0 + i1 * zStrd1 + i2 * zStrd2; auto s = OpType::startingValue(x2); if(xStrd3 == 1) for (uint i3 = 0; i3 < xAxis3; ++i3) s = OpType::update(s, OpType::op(x2[i3], extraParams), extraParams); else for (uint i3 = 0; i3 < xAxis3; ++i3) s = OpType::update(s, OpType::op(x2[i3*xStrd3], extraParams), extraParams); *z2 = OpType::postProcess(s, static_cast(xAxis3), extraParams); } } } }; samediff::Threads::parallel_for(func, 0,xAxis0,1, 0,xAxis1,1, 0,xAxis2,1); } ////////////////////////////////////////////////////////////////////////// template void reduceExec51(const X *x, const Nd4jLong *xShapeInfo, Z* z, const Nd4jLong *zShapeInfo, const int *dims, E* extraParams) { const uint xAxis0 = shape::sizeAt(xShapeInfo, dims[0]); const Nd4jLong xStrd0 = shape::strideAt(xShapeInfo, dims[0]); const Nd4jLong zStrd0 = shape::strideAt(zShapeInfo, 0); const uint xAxis1 = shape::sizeAt(xShapeInfo, dims[1]); const Nd4jLong xStrd1 = shape::strideAt(xShapeInfo, dims[1]); const uint xAxis2 = shape::sizeAt(xShapeInfo, dims[2]); const Nd4jLong xStrd2 = shape::strideAt(xShapeInfo, dims[2]); const uint xAxis3 = shape::sizeAt(xShapeInfo, dims[3]); const Nd4jLong xStrd3 = shape::strideAt(xShapeInfo, dims[3]); const uint xAxis4 = shape::sizeAt(xShapeInfo, dims[4]); const Nd4jLong xStrd4 = shape::strideAt(xShapeInfo, dims[4]); const Nd4jLong tadLen = static_cast(xAxis1 * xAxis2 * xAxis3 * xAxis4); auto func = PRAGMA_THREADS_FOR { for (auto i0 = start; i0 < stop; ++i0) { auto x0 = x + i0 * xStrd0; auto z0 = z + i0 * zStrd0; auto s = OpType::startingValue(x0); if(xStrd1 == 1) for (uint i4 = 0; i4 < xAxis4; ++i4) for (uint i3 = 0; i3 < xAxis3; ++i3) for (uint i2 = 0; i2 < xAxis2; ++i2) for (uint i1 = 0; i1 < xAxis1; ++i1) s = OpType::update(s, OpType::op(x0[i1 + i2*xStrd2 + i3*xStrd3 + i4*xStrd4], extraParams), extraParams); else if(xStrd2 == 1) for (uint i4 = 0; i4 < xAxis4; ++i4) for (uint i3 = 0; i3 < xAxis3; ++i3) for (uint i1 = 0; i1 < xAxis1; ++i1) for (uint i2 = 0; i2 < xAxis2; ++i2) s = OpType::update(s, OpType::op(x0[i1*xStrd1 + i2 + i3*xStrd3 + i4*xStrd4], extraParams), extraParams); else if(xStrd3 == 1) for (uint i1 = 0; i1 < xAxis1; ++i1) for (uint i2 = 0; i2 < xAxis2; ++i2) for (uint i4 = 0; i4 < xAxis4; ++i4) for (uint i3 = 0; i3 < xAxis3; ++i3) s = OpType::update(s, OpType::op(x0[i1*xStrd1 + i2*xStrd2 + i3 + i4*xStrd4], extraParams), extraParams); else if(xStrd4 == 1) for (uint i1 = 0; i1 < xAxis1; ++i1) for (uint i2 = 0; i2 < xAxis2; ++i2) for (uint i3 = 0; i3 < xAxis3; ++i3) for (uint i4 = 0; i4 < xAxis4; ++i4) s = OpType::update(s, OpType::op(x0[i1*xStrd1 + i2*xStrd2 + i3*xStrd3 + i4], extraParams), extraParams); else for (uint i1 = 0; i1 < xAxis1; ++i1) for (uint i2 = 0; i2 < xAxis2; ++i2) for (uint i3 = 0; i3 < xAxis3; ++i3) for (uint i4 = 0; i4 < xAxis4; ++i4) s = OpType::update(s, OpType::op(x0[i1*xStrd1 + i2*xStrd2 + i3*xStrd3 + i4*xStrd4], extraParams), extraParams); *z0 = OpType::postProcess(s, tadLen, extraParams); } }; samediff::Threads::parallel_for(func, 0,xAxis0); } ////////////////////////////////////////////////////////////////////////// template void reduceExec52(const X *x, const Nd4jLong *xShapeInfo, Z* z, const Nd4jLong *zShapeInfo, const int *dims, E* extraParams) { const uint xAxis0 = shape::sizeAt(xShapeInfo, shape::order(zShapeInfo) == 'c' ? dims[0] : dims[1]); const Nd4jLong xStrd0 = shape::strideAt(xShapeInfo, shape::order(zShapeInfo) == 'c' ? dims[0] : dims[1]); const Nd4jLong zStrd0 = shape::strideAt(zShapeInfo, shape::order(zShapeInfo) == 'c' ? 0 : 1); const uint xAxis1 = shape::sizeAt(xShapeInfo, shape::order(zShapeInfo) == 'c' ? dims[1] : dims[0]); const Nd4jLong xStrd1 = shape::strideAt(xShapeInfo, shape::order(zShapeInfo) == 'c' ? dims[1] : dims[0]); const Nd4jLong zStrd1 = shape::strideAt(zShapeInfo, shape::order(zShapeInfo) == 'c' ? 1 : 0); const uint xAxis2 = shape::sizeAt(xShapeInfo, dims[2]); const Nd4jLong xStrd2 = shape::strideAt(xShapeInfo, dims[2]); const uint xAxis3 = shape::sizeAt(xShapeInfo, dims[3]); const Nd4jLong xStrd3 = shape::strideAt(xShapeInfo, dims[3]); const uint xAxis4 = shape::sizeAt(xShapeInfo, dims[4]); const Nd4jLong xStrd4 = shape::strideAt(xShapeInfo, dims[4]); const Nd4jLong tadLen = static_cast(xAxis2 * xAxis3 * xAxis4); auto func = PRAGMA_THREADS_FOR_2D { for (auto i0 = start_x; i0 < stop_x; ++i0) { for (auto i1 = start_y; i1 < stop_y; ++i1) { auto x1 = x + i0 * xStrd0 + i1 * xStrd1; auto z1 = z + i0 * zStrd0 + i1 * zStrd1; auto s = OpType::startingValue(x1); if(xStrd2 == 1) for (uint i4 = 0; i4 < xAxis4; ++i4) for (uint i3 = 0; i3 < xAxis3; ++i3) for (uint i2 = 0; i2 < xAxis2; ++i2) s = OpType::update(s, OpType::op(x1[i2 + i3*xStrd3 + i4*xStrd4], extraParams), extraParams); else if(xStrd3 == 1) for (uint i2 = 0; i2 < xAxis2; ++i2) for (uint i4 = 0; i4 < xAxis4; ++i4) for (uint i3 = 0; i3 < xAxis3; ++i3) s = OpType::update(s, OpType::op(x1[i2*xStrd2 + i3 + i4*xStrd4], extraParams), extraParams); else if(xStrd4 == 1) for (uint i2 = 0; i2 < xAxis2; ++i2) for (uint i3 = 0; i3 < xAxis3; ++i3) for (uint i4 = 0; i4 < xAxis4; ++i4) s = OpType::update(s, OpType::op(x1[i2*xStrd2 + i3*xStrd3 + i4], extraParams), extraParams); else for (uint i2 = 0; i2 < xAxis2; ++i2) for (uint i3 = 0; i3 < xAxis3; ++i3) for (uint i4 = 0; i4 < xAxis4; ++i4) s = OpType::update(s, OpType::op(x1[i2*xStrd2 + i3*xStrd3 + i4*xStrd4], extraParams), extraParams); *z1 = OpType::postProcess(s, tadLen, extraParams); } } }; samediff::Threads::parallel_for(func, 0,xAxis0,1, 0,xAxis1,1); } ////////////////////////////////////////////////////////////////////////// template void reduceExec53(const X *x, const Nd4jLong *xShapeInfo, Z* z, const Nd4jLong *zShapeInfo, const int *dims, E* extraParams) { const uint xAxis0 = shape::sizeAt(xShapeInfo, shape::order(zShapeInfo) == 'c' ? dims[0] : dims[2]); const Nd4jLong xStrd0 = shape::strideAt(xShapeInfo, shape::order(zShapeInfo) == 'c' ? dims[0] : dims[2]); const Nd4jLong zStrd0 = shape::strideAt(zShapeInfo, shape::order(zShapeInfo) == 'c' ? 0 : 2); const uint xAxis1 = shape::sizeAt(xShapeInfo, dims[1]); const Nd4jLong xStrd1 = shape::strideAt(xShapeInfo, dims[1]); const Nd4jLong zStrd1 = shape::strideAt(zShapeInfo, 1); const uint xAxis2 = shape::sizeAt(xShapeInfo, shape::order(zShapeInfo) == 'c' ? dims[2] : dims[0]); const Nd4jLong xStrd2 = shape::strideAt(xShapeInfo, shape::order(zShapeInfo) == 'c' ? dims[2] : dims[0]); const Nd4jLong zStrd2 = shape::strideAt(zShapeInfo, shape::order(zShapeInfo) == 'c' ? 2 : 0); const uint xAxis3 = shape::sizeAt(xShapeInfo, dims[3]); const Nd4jLong xStrd3 = shape::strideAt(xShapeInfo, dims[3]); const uint xAxis4 = shape::sizeAt(xShapeInfo, dims[4]); const Nd4jLong xStrd4 = shape::strideAt(xShapeInfo, dims[4]); const Nd4jLong tadLen = static_cast(xAxis3 * xAxis4); auto func = PRAGMA_THREADS_FOR_3D { for (auto i0 = start_x; i0 < stop_x; ++i0) { for (auto i1 = start_y; i1 < stop_y; ++i1) { for (auto i2 = start_z; i2 < stop_z; ++i2) { auto x2 = x + i0 * xStrd0 + i1 * xStrd1 + i2 * xStrd2; auto z2 = z + i0 * zStrd0 + i1 * zStrd1 + i2 * zStrd2; auto s = OpType::startingValue(x2); if(xStrd3 == 1) for (uint i4 = 0; i4 < xAxis4; ++i4) for (uint i3 = 0; i3 < xAxis3; ++i3) s = OpType::update(s, OpType::op(x2[i3 + i4*xStrd4], extraParams), extraParams); else if(xStrd4 == 1) for (uint i3 = 0; i3 < xAxis3; ++i3) for (uint i4 = 0; i4 < xAxis4; ++i4) s = OpType::update(s, OpType::op(x2[i3*xStrd3 + i4], extraParams), extraParams); else for (uint i3 = 0; i3 < xAxis3; ++i3) for (uint i4 = 0; i4 < xAxis4; ++i4) s = OpType::update(s, OpType::op(x2[i3*xStrd3 + i4*xStrd4], extraParams), extraParams); *z2 = OpType::postProcess(s, tadLen, extraParams); } } } }; samediff::Threads::parallel_for(func, 0,xAxis0,1, 0,xAxis1,1, 0,xAxis2,1); } ////////////////////////////////////////////////////////////////////////// template void reduceExec54(const X *x, const Nd4jLong *xShapeInfo, Z* z, const Nd4jLong *zShapeInfo, const int *dims, E* extraParams) { const uint xAxis0 = shape::sizeAt(xShapeInfo, shape::order(zShapeInfo) == 'c' ? dims[0] : dims[3]); const Nd4jLong xStrd0 = shape::strideAt(xShapeInfo, shape::order(zShapeInfo) == 'c' ? dims[0] : dims[3]); const Nd4jLong zStrd0 = shape::strideAt(zShapeInfo, shape::order(zShapeInfo) == 'c' ? 0 : 3); const uint xAxis1 = shape::sizeAt(xShapeInfo, shape::order(zShapeInfo) == 'c' ? dims[1] : dims[2]); const Nd4jLong xStrd1 = shape::strideAt(xShapeInfo, shape::order(zShapeInfo) == 'c' ? dims[1] : dims[2]); const Nd4jLong zStrd1 = shape::strideAt(zShapeInfo, shape::order(zShapeInfo) == 'c' ? 1 : 2); const uint xAxis2 = shape::sizeAt(xShapeInfo, shape::order(zShapeInfo) == 'c' ? dims[2] : dims[1]); const Nd4jLong xStrd2 = shape::strideAt(xShapeInfo, shape::order(zShapeInfo) == 'c' ? dims[2] : dims[1]); const Nd4jLong zStrd2 = shape::strideAt(zShapeInfo, shape::order(zShapeInfo) == 'c' ? 2 : 1); const uint xAxis3 = shape::sizeAt(xShapeInfo, shape::order(zShapeInfo) == 'c' ? dims[3] : dims[0]); const Nd4jLong xStrd3 = shape::strideAt(xShapeInfo, shape::order(zShapeInfo) == 'c' ? dims[3] : dims[0]); const Nd4jLong zStrd3 = shape::strideAt(zShapeInfo, shape::order(zShapeInfo) == 'c' ? 3 : 0); const uint xAxis4 = shape::sizeAt(xShapeInfo, dims[4]); const Nd4jLong xStrd4 = shape::strideAt(xShapeInfo, dims[4]); auto func = PRAGMA_THREADS_FOR_3D { for (auto i0 = start_x; i0 < stop_x; ++i0) { for (auto i1 = start_y; i1 < stop_y; ++i1) { for (auto i2 = start_z; i2 < stop_z; ++i2) { for (auto i3 = 0; i3 < xAxis3; ++i3) { auto x3 = x + i0 * xStrd0 + i1 * xStrd1 + i2 * xStrd2 + i3 * xStrd3; auto z3 = z + i0 * zStrd0 + i1 * zStrd1 + i2 * zStrd2 + i3 * zStrd3; auto s = OpType::startingValue(x3); if(xStrd4 == 1) for (uint i4 = 0; i4 < xAxis4; ++i4) s = OpType::update(s, OpType::op(x3[i4], extraParams), extraParams); else for (uint i4 = 0; i4 < xAxis4; ++i4) s = OpType::update(s, OpType::op(x3[i4*xStrd4], extraParams), extraParams); *z3 = OpType::postProcess(s, static_cast(xAxis4), extraParams); } } } } }; samediff::Threads::parallel_for(func, 0,xAxis0,1, 0,xAxis1,1, 0,xAxis2,1); } //////////////////////////////////////////////////////////////////////// template void reduceDefault(sd::memory::Workspace* workspace, const X *x, const Nd4jLong *xShapeInfo, Z* z, const Nd4jLong *zShapeInfo, const int *dims, E* extraParams) { const int zRank = shape::rank(zShapeInfo); const int tadRank = shape::rank(xShapeInfo) - zRank; Nd4jLong* outerXTadShapeInfo = sd::ShapeBuilders::createSubArrShapeInfo(xShapeInfo, dims, zRank); Nd4jLong* innerXTadShapeInfo = sd::ShapeBuilders::createSubArrShapeInfo(xShapeInfo, dims+zRank, tadRank); const bool sameOffsets1 = shape::haveSameShapeAndStrides(zShapeInfo, outerXTadShapeInfo); const bool sameOffsets2 = shape::haveSameShapeAndStrides(zShapeInfo, innerXTadShapeInfo); const Nd4jLong zLen = shape::length(zShapeInfo); const Nd4jLong tadLen = shape::length(innerXTadShapeInfo); Nd4jLong* zOffsets = nullptr; ALLOCATE(zOffsets, workspace, zLen, Nd4jLong); shape::calcOffsets(zShapeInfo, zOffsets); Nd4jLong* outerXTadOffsets = zOffsets; if(!sameOffsets1) { ALLOCATE(outerXTadOffsets, workspace, zLen, Nd4jLong); shape::calcOffsets(outerXTadShapeInfo, outerXTadOffsets); } Nd4jLong* innerXTadOffsets = zOffsets; if(!sameOffsets2) { ALLOCATE(innerXTadOffsets, workspace, tadLen, Nd4jLong); shape::calcOffsets(innerXTadShapeInfo, innerXTadOffsets); } auto func = PRAGMA_THREADS_FOR{ for (auto i = start; i < stop; ++i) { const auto tad = x + outerXTadOffsets[i]; auto s = OpType::startingValue(tad); for (Nd4jLong j = 0; j < tadLen; j++) s = OpType::update(s, OpType::op(tad[innerXTadOffsets[j]], extraParams), extraParams); z[zOffsets[i]] = OpType::postProcess(s, tadLen, extraParams); } }; samediff::Threads::parallel_for(func, 0, shape::length(zShapeInfo)); RELEASE(outerXTadShapeInfo, workspace); RELEASE(innerXTadShapeInfo, workspace); RELEASE(zOffsets, workspace); if(!sameOffsets1) RELEASE(outerXTadOffsets, workspace); if(!sameOffsets2) RELEASE(innerXTadOffsets, workspace); } ////////////////////////////////////////////////////////////////////////////// template template void sd::ReductionLoops::loopReduce(sd::memory::Workspace* workspace, const X* x, const Nd4jLong *xShapeInfo, Z* z, const Nd4jLong *zShapeInfo, const int* dims, E* extraParams) { const int xRank = shape::rank(xShapeInfo); const int zRank = shape::rank(zShapeInfo); // shape::printShapeInfoLinear(xShapeInfo); // shape::printShapeInfoLinear(zShapeInfo); // shape::printIntArray(dims, shape::rank(xShapeInfo)); if(xRank == 2 && zRank == 1) reduceExec21(x, xShapeInfo, z, zShapeInfo, dims, extraParams); else if(xRank == 3 && zRank == 1) reduceExec31(x, xShapeInfo, z, zShapeInfo, dims, extraParams); else if(xRank == 3 && zRank == 2) reduceExec32(x, xShapeInfo, z, zShapeInfo, dims, extraParams); else if(xRank == 4 && zRank == 1) reduceExec41(x, xShapeInfo, z, zShapeInfo, dims, extraParams); else if(xRank == 4 && zRank == 2) reduceExec42(x, xShapeInfo, z, zShapeInfo, dims, extraParams); else if(xRank == 4 && zRank == 3) reduceExec43(x, xShapeInfo, z, zShapeInfo, dims, extraParams); else if(xRank == 5 && zRank == 1) reduceExec51(x, xShapeInfo, z, zShapeInfo, dims, extraParams); else if(xRank == 5 && zRank == 2) reduceExec52(x, xShapeInfo, z, zShapeInfo, dims, extraParams); else if(xRank == 5 && zRank == 3) reduceExec53(x, xShapeInfo, z, zShapeInfo, dims, extraParams); else if(xRank == 5 && zRank == 4) reduceExec54(x, xShapeInfo, z, zShapeInfo, dims, extraParams); else reduceDefault(workspace, x, xShapeInfo, z, zShapeInfo, dims, extraParams); } ////////////////////////////////////////////////////////////////////////////// template template void sd::TransformLoops::loopTransform(const X* x, const Nd4jLong* xShapeInfo, Z* z, const Nd4jLong* zShapeInfo, E* extraParams, uint64_t threadId, uint64_t numThreads) { const LoopKind::Kind kindOfLoop = LoopKind::deduceKindOfLoopXZ(xShapeInfo, zShapeInfo); const Nd4jLong* xShape = shape::shapeOf(const_cast(xShapeInfo)); const Nd4jLong* xStride = shape::stride(const_cast(xShapeInfo)); const Nd4jLong* zStride = shape::stride(const_cast(zShapeInfo)); const Nd4jLong len = shape::length(xShapeInfo); if (len == 0) return; switch (kindOfLoop) { //*********************************************// case LoopKind::EWS1: { auto span = samediff::Span::build(threadId, numThreads, 0, len, 1); int64_t start = span.startX(), stop = span.stopX(); for (auto i = start; i < stop; i++) z[i] = OpType::op(x[i], extraParams); } break; //*********************************************// case LoopKind::EWSNONZERO: { const uint xEws = shape::elementWiseStride(xShapeInfo); const uint zEws = shape::elementWiseStride(zShapeInfo); auto span = samediff::Span::build(threadId, numThreads, 0, len, 1); int64_t start = span.startX(), stop = span.stopX(); for (auto i = start; i < stop; i++) z[i * zEws] = OpType::op(x[i * xEws], extraParams); } break; //*********************************************// case LoopKind::Z_EWSNONZERO: { const uint zEws = shape::elementWiseStride(zShapeInfo); uint castXShapeInfo[MAX_RANK]; const bool canCastX = sd::DataTypeUtils::castShapeInfo(xShapeInfo, castXShapeInfo); auto span = samediff::Span::build(threadId, numThreads, 0, len, 1); int64_t start = span.startX(), stop = span.stopX(); if (zEws > 1) { for (auto i = start; i < stop; i++) { const auto xOffset = shape::indexOffset(i, xShapeInfo, castXShapeInfo, canCastX); z[i * zEws] = OpType::op(x[xOffset], extraParams); } } else { for (auto i = start; i < stop; i++) { const auto xOffset = shape::indexOffset(i, xShapeInfo, castXShapeInfo, canCastX); z[i] = OpType::op(x[xOffset], extraParams); } } } break; //*********************************************// case LoopKind::RANK1: { auto span = samediff::Span::build(threadId, numThreads, 0, len, 1); for (auto i0 = span.startX(); i0 < span.stopX(); i0++) z[i0 * zStride[0]] = OpType::op(x[i0 * xStride[0]], extraParams); } break; //*********************************************// case LoopKind::RANK2: { auto uXShape0 = static_cast(xShape[0]); auto uXShape1 = static_cast(xShape[1]); auto loop = samediff::ThreadsHelper::pickLoop2d(numThreads, uXShape0, uXShape1); auto span = samediff::Span2::build(loop, threadId, numThreads, 0, uXShape0, 1, 0, uXShape1, 1); for (auto i0 = span.startX(); i0 < span.stopX(); i0++) { auto z0 = i0 * zStride[0]; auto x0 = i0 * xStride[0]; for (auto i1 = span.startY(); i1 < span.stopY(); ++i1) z[z0 + i1 * zStride[1]] = OpType::op(x[x0 + i1 * xStride[1]], extraParams); } } break; //*********************************************// case LoopKind::RANK3: { auto uXShape0 = xShape[0]; auto uXShape1 = xShape[1]; auto uXShape2 = xShape[2]; auto loop = samediff::ThreadsHelper::pickLoop2d(numThreads, uXShape0, uXShape1); auto span = samediff::Span2::build(loop, threadId, numThreads, 0, uXShape0, 1, 0, uXShape1, 1); for (auto i0 = span.startX(); i0 < span.stopX(); i0++) for (auto i1 = span.startY(); i1 < span.stopY(); i1++) { auto z0 = i0 * zStride[0] + i1 * zStride[1]; auto x0 = i0 * xStride[0] + i1 * xStride[1]; for (Nd4jLong i2 = 0; i2 < uXShape2; ++i2) z[z0 + i2 * zStride[2]] = OpType::op(x[x0 + i2 * xStride[2]], extraParams); } } break; //*********************************************// case LoopKind::RANK4: { auto uXShape0 = xShape[0]; auto uXShape1 = xShape[1]; auto uXShape2 = xShape[2]; auto uXShape3 = xShape[3]; auto loop = samediff::ThreadsHelper::pickLoop3d(numThreads, uXShape0, uXShape1, uXShape2); auto span = samediff::Span3::build(loop, threadId, numThreads, 0, uXShape0, 1, 0, uXShape1, 1, 0, uXShape2, 1); for (auto i0 = span.startX(); i0 < span.stopX(); i0++) for (auto i1 = span.startY(); i1 < span.stopY(); i1++) for (auto i2 = span.startZ(); i2 < span.stopZ(); i2++) { auto x0 = i0 * xStride[0] + i1 * xStride[1] + i2 * xStride[2]; auto z0 = i0 * zStride[0] + i1 * zStride[1] + i2 * zStride[2]; for (Nd4jLong i3 = 0; i3 < uXShape3; ++i3) z[z0 + i3 * zStride[3]] = OpType::op(x[x0 + i3 * xStride[3]], extraParams); } } break; //*********************************************// case LoopKind::RANK5: { auto uXShape0 = xShape[0]; auto uXShape1 = xShape[1]; auto uXShape2 = xShape[2]; auto uXShape3 = xShape[3]; auto uXShape4 = xShape[4]; auto loop = samediff::ThreadsHelper::pickLoop3d(numThreads, uXShape0, uXShape1, uXShape2); auto span = samediff::Span3::build(loop, threadId, numThreads, 0, uXShape0, 1, 0, uXShape1, 1, 0, uXShape2, 1); for (auto i0 = span.startX(); i0 < span.stopX(); i0++) for (auto i1 = span.startY(); i1 < span.stopY(); i1++) for (auto i2 = span.startZ(); i2 < span.stopZ(); i2++) { auto z0 = i0 * zStride[0] + i1 * zStride[1] + i2 * zStride[2]; auto x0 = i0 * xStride[0] + i1 * xStride[1] + i2 * xStride[2]; for (Nd4jLong i3 = 0; i3 < uXShape3; ++i3) { auto z1 = z0 + i3 * zStride[3]; auto x1 = x0 + i3 * xStride[3]; for (Nd4jLong i4 = 0; i4 < uXShape4; ++i4) z[z1 + i4 * zStride[4]] = OpType::op(x[x1 + i4 * xStride[4]], extraParams); } } } break; //*********************************************// default: { uint xShapeInfoCast[MAX_RANK]; uint zShapeInfoCast[MAX_RANK]; bool canCastX = DataTypeUtils::castShapeInfo(xShapeInfo, xShapeInfoCast); bool canCastZ = DataTypeUtils::castShapeInfo(zShapeInfo, zShapeInfoCast); auto span = samediff::Span::build(threadId, numThreads, 0, len, 1); for (auto i = span.startX(); i < span.stopX(); i++) { auto xOffset = shape::indexOffset(i, xShapeInfo, xShapeInfoCast, canCastX); auto zOffset = shape::indexOffset(i, zShapeInfo, zShapeInfoCast, canCastZ); z[zOffset] = OpType::op(x[xOffset], extraParams); } } } } ////////////////////////////////////////////////////////////////////////////// template template void sd::Reduction3Loops::loopReduce3(const X* x, const Nd4jLong* xShapeInfo, const X* y, const Nd4jLong* yShapeInfo, Z* z, const Nd4jLong* zShapeInfo, int* dims, int dimsLen, Z* extraParameters, int64_t start, int64_t stop) { // both tads have same shape, however strides and ews may differ Z param0(OpType::startingValue(x)), param1(OpType::startingValue(x)), param2(extraParameters ? extraParameters[0] : OpType::startingValue(x)); const Nd4jLong xLen = shape::length(xShapeInfo); const Nd4jLong yLen = shape::length(yShapeInfo); const Nd4jLong* xTadShapeInfo = nullptr, * yTadShapeInfo = nullptr, * xTadOffsets = nullptr, * yTadOffsets = nullptr; TadPack tadPackX, tadPackY; std::vector zeroOffsets; if (xLen == yLen) { tadPackX = sd::ConstantTadHelper::getInstance().tadForDimensions(xShapeInfo, dims, dimsLen); tadPackY = sd::ConstantTadHelper::getInstance().tadForDimensions(yShapeInfo, dims, dimsLen); xTadShapeInfo = tadPackX.primaryShapeInfo(); yTadShapeInfo = tadPackY.primaryShapeInfo(); xTadOffsets = tadPackX.primaryOffsets(); yTadOffsets = tadPackY.primaryOffsets(); } else if (yLen > xLen) { tadPackY = sd::ConstantTadHelper::getInstance().tadForDimensions(yShapeInfo, dims, dimsLen); xTadShapeInfo = xShapeInfo; yTadShapeInfo = tadPackY.primaryShapeInfo(); yTadOffsets = tadPackY.primaryOffsets(); } else { tadPackX = sd::ConstantTadHelper::getInstance().tadForDimensions(xShapeInfo, dims, dimsLen); yTadShapeInfo = yShapeInfo; xTadShapeInfo = tadPackX.primaryShapeInfo(); xTadOffsets = tadPackX.primaryOffsets(); } const LoopKind::Kind kindOfLoop = LoopKind::deduceKindOfLoopTadXYZ(xTadShapeInfo, yTadShapeInfo, zShapeInfo); const auto xTadEws = shape::elementWiseStride(xTadShapeInfo); const auto yTadEws = shape::elementWiseStride(yTadShapeInfo); const auto zEws = shape::elementWiseStride(zShapeInfo); const auto zLen = shape::length(zShapeInfo); const auto tadLen = shape::length(xTadShapeInfo); const auto tadShape = shape::shapeOf(xTadShapeInfo); const auto xTadStride = shape::stride(xTadShapeInfo); const auto yTadStride = shape::stride(xTadShapeInfo); int numThreads = OmpLaunchHelper::tadThreads(tadLen, zLen); switch (kindOfLoop) { //*********************************************// case LoopKind::EWS1: { Z extraParams[3]; for (auto i = start; i < stop; i++) { extraParams[0] = param0; extraParams[1] = param1; extraParams[2] = param2; const auto xTad = xTadOffsets ? x + xTadOffsets[i] : x; const auto yTad = yTadOffsets ? y + yTadOffsets[i] : y; auto s = OpType::startingValue(xTad); for (Nd4jLong j = 0; j < tadLen; ++j) s = OpType::update(s, OpType::op(xTad[j], yTad[j], extraParams), extraParams); z[i] = OpType::postProcess(s, tadLen, extraParams); }; } break; //*********************************************// case LoopKind::EWSNONZERO: { Z extraParams[3]; for (auto i = start; i < stop; i++) { extraParams[0] = param0; extraParams[1] = param1; extraParams[2] = param2; const auto xTad = xTadOffsets ? x + xTadOffsets[i] : x; const auto yTad = yTadOffsets ? y + yTadOffsets[i] : y; auto s = OpType::startingValue(xTad); for (Nd4jLong j = 0; j < tadLen; ++j) s = OpType::update(s, OpType::op(xTad[j * xTadEws], yTad[j * yTadEws], extraParams), extraParams); z[i * zEws] = OpType::postProcess(s, tadLen, extraParams); }; } break; //*********************************************// case LoopKind::RANK1: { Z extraParams[3]; for (auto i = start; i < stop; i++) { extraParams[0] = param0; extraParams[1] = param1; extraParams[2] = param2; const auto xTad = xTadOffsets ? x + xTadOffsets[i] : x; const auto yTad = yTadOffsets ? y + yTadOffsets[i] : y; auto s = OpType::startingValue(xTad); for (Nd4jLong i0 = 0; i0 < tadLen; ++i0) { const auto xTadOffset = i0 * xTadStride[0]; const auto yTadOffset = i0 * yTadStride[0]; s = OpType::update(s, OpType::op(xTad[xTadOffset], yTad[yTadOffset], extraParams), extraParams); } z[i * zEws] = OpType::postProcess(s, tadLen, extraParams); }; } break; //*********************************************// case LoopKind::RANK2: { Z extraParams[3]; for (auto i = start; i < stop; i++) { extraParams[0] = param0; extraParams[1] = param1; extraParams[2] = param2; const auto xTad = xTadOffsets ? x + xTadOffsets[i] : x; const auto yTad = yTadOffsets ? y + yTadOffsets[i] : y; auto s = OpType::startingValue(xTad); for (Nd4jLong i0 = 0; i0 < tadShape[0]; ++i0) { for (Nd4jLong i1 = 0; i1 < tadShape[1]; ++i1) { const auto xTadOffset = i0 * xTadStride[0] + i1 * xTadStride[1]; const auto yTadOffset = i0 * yTadStride[0] + i1 * yTadStride[1]; s = OpType::update(s, OpType::op(xTad[xTadOffset], yTad[yTadOffset], extraParams), extraParams); } } z[i * zEws] = OpType::postProcess(s, tadLen, extraParams); }; } break; //*********************************************// case LoopKind::RANK3: { Z extraParams[3]; for (auto i = start; i < stop; i++) { extraParams[0] = param0; extraParams[1] = param1; extraParams[2] = param2; const auto xTad = xTadOffsets ? x + xTadOffsets[i] : x; const auto yTad = yTadOffsets ? y + yTadOffsets[i] : y; auto s = OpType::startingValue(xTad); for (Nd4jLong i0 = 0; i0 < tadShape[0]; ++i0) { for (Nd4jLong i1 = 0; i1 < tadShape[1]; ++i1) { for (Nd4jLong i2 = 0; i2 < tadShape[2]; ++i2) { const auto xTadOffset = i0 * xTadStride[0] + i1 * xTadStride[1] + i2 * xTadStride[2]; const auto yTadOffset = i0 * yTadStride[0] + i1 * yTadStride[1] + i2 * yTadStride[2]; s = OpType::update(s, OpType::op(xTad[xTadOffset], yTad[yTadOffset], extraParams), extraParams); } } } z[i * zEws] = OpType::postProcess(s, tadLen, extraParams); }; } break; //*********************************************// case LoopKind::RANK4: { Z extraParams[3]; for (auto i = start; i < stop; i++) { extraParams[0] = param0; extraParams[1] = param1; extraParams[2] = param2; const auto xTad = xTadOffsets ? x + xTadOffsets[i] : x; const auto yTad = yTadOffsets ? y + yTadOffsets[i] : y; auto s = OpType::startingValue(xTad); for (Nd4jLong i0 = 0; i0 < tadShape[0]; ++i0) { for (Nd4jLong i1 = 0; i1 < tadShape[1]; ++i1) { for (Nd4jLong i2 = 0; i2 < tadShape[2]; ++i2) { for (Nd4jLong i3 = 0; i3 < tadShape[3]; ++i3) { const auto xTadOffset = i0 * xTadStride[0] + i1 * xTadStride[1] + i2 * xTadStride[2] + i3 * xTadStride[3]; const auto yTadOffset = i0 * yTadStride[0] + i1 * yTadStride[1] + i2 * yTadStride[2] + i3 * yTadStride[3]; s = OpType::update(s, OpType::op(xTad[xTadOffset], yTad[yTadOffset], extraParams), extraParams); } } } } z[i * zEws] = OpType::postProcess(s, tadLen, extraParams); }; } break; //*********************************************// case LoopKind::RANK5: { Z extraParams[3]; for (auto i = start; i < stop; i++) { extraParams[0] = param0; extraParams[1] = param1; extraParams[2] = param2; const auto xTad = xTadOffsets ? x + xTadOffsets[i] : x; const auto yTad = yTadOffsets ? y + yTadOffsets[i] : y; auto s = OpType::startingValue(xTad); for (Nd4jLong i0 = 0; i0 < tadShape[0]; ++i0) { for (Nd4jLong i1 = 0; i1 < tadShape[1]; ++i1) { for (Nd4jLong i2 = 0; i2 < tadShape[2]; ++i2) { for (Nd4jLong i3 = 0; i3 < tadShape[3]; ++i3) { for (Nd4jLong i4 = 0; i4 < tadShape[4]; ++i4) { const auto xTadOffset = i0 * xTadStride[0] + i1 * xTadStride[1] + i2 * xTadStride[2] + i3 * xTadStride[3] + i4 * xTadStride[4]; const auto yTadOffset = i0 * yTadStride[0] + i1 * yTadStride[1] + i2 * yTadStride[2] + i3 * yTadStride[3] + i4 * yTadStride[4]; s = OpType::update(s, OpType::op(xTad[xTadOffset], yTad[yTadOffset], extraParams), extraParams); } } } } } z[i * zEws] = OpType::postProcess(s, tadLen, extraParams); }; } break; //*********************************************// default: { uint castXTadShapeInfo[MAX_RANK]; const bool canCastXTad = sd::DataTypeUtils::castShapeInfo(xTadShapeInfo, castXTadShapeInfo); if (shape::haveSameShapeAndStrides(xTadShapeInfo, yTadShapeInfo)) { Z extraParams[3]; for (auto i = start; i < stop; i++) { extraParams[0] = param0; extraParams[1] = param1; extraParams[2] = param2; const auto xTad = xTadOffsets ? x + xTadOffsets[i] : x; const auto yTad = yTadOffsets ? y + yTadOffsets[i] : y; auto s = OpType::startingValue(xTad); for (Nd4jLong j = 0; j < tadLen; ++j) { const auto tadOffset = shape::indexOffset(j, xTadShapeInfo, castXTadShapeInfo, canCastXTad); s = OpType::update(s, OpType::op(xTad[tadOffset], yTad[tadOffset], extraParams), extraParams); } z[i * zEws] = OpType::postProcess(s, tadLen, extraParams); }; } else { uint castYTadShapeInfo[MAX_RANK]; const bool canCastYTad = sd::DataTypeUtils::castShapeInfo(yTadShapeInfo, castYTadShapeInfo); Z extraParams[3]; for (auto i = start; i < stop; i++) { extraParams[0] = param0; extraParams[1] = param1; extraParams[2] = param2; const auto xTad = xTadOffsets ? x + xTadOffsets[i] : x; const auto yTad = yTadOffsets ? y + yTadOffsets[i] : y; auto s = OpType::startingValue(xTad); for (Nd4jLong j = 0; j < tadLen; ++j) { const auto xTadOffset = shape::indexOffset(j, xTadShapeInfo, castXTadShapeInfo, canCastXTad); const auto yTadOffset = shape::indexOffset(j, yTadShapeInfo, castYTadShapeInfo, canCastYTad); s = OpType::update(s, OpType::op(xTad[xTadOffset], yTad[yTadOffset], extraParams), extraParams); } z[i * zEws] = OpType::postProcess(s, tadLen, extraParams); }; } } } } ////////////////////////////////////////////////////////////////////////////// template template void sd::Reduction3Loops::loopReduce3All(const X* x, const Nd4jLong* xShapeInfo, const X* y, const Nd4jLong* yShapeInfo, Z* z, const Nd4jLong* zShapeInfo, const Nd4jLong* xTadShapeInfo, const Nd4jLong* xTadOffsets, const Nd4jLong* yTadShapeInfo, const Nd4jLong* yTadOffsets, Z* extraParameters, int64_t start, int64_t stop) { // both tads have same shape, however strides and ews may differ Z param0(OpType::startingValue(x)), param1(OpType::startingValue(x)), param2(extraParameters ? extraParameters[0] : OpType::startingValue(x)); const LoopKind::Kind kindOfLoop = LoopKind::deduceKindOfLoopTadXYZ(xTadShapeInfo, yTadShapeInfo, zShapeInfo); const auto xTadEws = shape::elementWiseStride(xTadShapeInfo); const auto yTadEws = shape::elementWiseStride(yTadShapeInfo); const auto zEws = shape::elementWiseStride(zShapeInfo); const auto zLen = shape::length(zShapeInfo); const auto tadLen = shape::length(xTadShapeInfo); const auto numXTads = shape::length(xShapeInfo) / tadLen; const auto numYTads = shape::length(yShapeInfo) / tadLen; const auto tadShape = shape::shapeOf(xTadShapeInfo); const auto xTadStride = shape::stride(xTadShapeInfo); const auto yTadStride = shape::stride(yTadShapeInfo); const auto startVal = OpType::startingValue(x); int numThreads = OmpLaunchHelper::tadThreads(tadLen, numXTads * numYTads); switch (kindOfLoop) { //*********************************************// case LoopKind::EWS1: { Z extraParams[3]; for (Nd4jLong ix = 0; ix < numXTads; ix++) { for (Nd4jLong iy = 0; iy < numYTads; iy++) { extraParams[0] = param0; extraParams[1] = param1; extraParams[2] = param2; const auto xTad = x + xTadOffsets[ix]; const auto yTad = y + yTadOffsets[iy]; const auto zInd = ix * numYTads + iy; auto s = startVal; for (Nd4jLong j = 0; j < tadLen; ++j) s = OpType::update(s, OpType::op(xTad[j], yTad[j], extraParams), extraParams); z[zInd] = OpType::postProcess(s, tadLen, extraParams); } }; } break; //*********************************************// case LoopKind::EWSNONZERO: { Z extraParams[3]; for (Nd4jLong ix = 0; ix < numXTads; ix++) { for (Nd4jLong iy = 0; iy < numYTads; iy++) { extraParams[0] = param0; extraParams[1] = param1; extraParams[2] = param2; const auto xTad = x + xTadOffsets[ix]; const auto yTad = y + yTadOffsets[iy]; const auto zInd = ix * numYTads + iy; auto s = startVal; for (Nd4jLong j = 0; j < tadLen; ++j) s = OpType::update(s, OpType::op(xTad[j * xTadEws], yTad[j * yTadEws], extraParams), extraParams); z[zInd * zEws] = OpType::postProcess(s, tadLen, extraParams); } }; } break; //*********************************************// case LoopKind::RANK1: { Z extraParams[3]; for (Nd4jLong ix = 0; ix < numXTads; ix++) { for (Nd4jLong iy = 0; iy < numYTads; iy++) { extraParams[0] = param0; extraParams[1] = param1; extraParams[2] = param2; const auto xTad = x + xTadOffsets[ix]; const auto yTad = y + yTadOffsets[iy]; const auto zInd = ix * numYTads + iy; auto s = startVal; for (Nd4jLong i0 = 0; i0 < tadLen; ++i0) { const auto xTadOffset = i0 * xTadStride[0]; const auto yTadOffset = i0 * yTadStride[0]; s = OpType::update(s, OpType::op(xTad[xTadOffset], yTad[yTadOffset], extraParams), extraParams); } z[zInd * zEws] = OpType::postProcess(s, tadLen, extraParams); } }; } break; //*********************************************// case LoopKind::RANK2: { Z extraParams[3]; for (Nd4jLong ix = 0; ix < numXTads; ix++) { for (Nd4jLong iy = 0; iy < numYTads; iy++) { extraParams[0] = param0; extraParams[1] = param1; extraParams[2] = param2; const auto xTad = x + xTadOffsets[ix]; const auto yTad = y + yTadOffsets[iy]; const auto zInd = ix * numYTads + iy; auto s = startVal; for (Nd4jLong i0 = 0; i0 < tadShape[0]; ++i0) { for (Nd4jLong i1 = 0; i1 < tadShape[1]; ++i1) { const auto xTadOffset = i0 * xTadStride[0] + i1 * xTadStride[1]; const auto yTadOffset = i0 * yTadStride[0] + i1 * yTadStride[1]; s = OpType::update(s, OpType::op(xTad[xTadOffset], yTad[yTadOffset], extraParams), extraParams); } } z[zInd * zEws] = OpType::postProcess(s, tadLen, extraParams); } }; } break; //*********************************************// case LoopKind::RANK3: { Z extraParams[3]; for (Nd4jLong ix = 0; ix < numXTads; ix++) { for (Nd4jLong iy = 0; iy < numYTads; iy++) { extraParams[0] = param0; extraParams[1] = param1; extraParams[2] = param2; const auto xTad = x + xTadOffsets[ix]; const auto yTad = y + yTadOffsets[iy]; const auto zInd = ix * numYTads + iy; auto s = startVal; for (Nd4jLong i0 = 0; i0 < tadShape[0]; ++i0) { for (Nd4jLong i1 = 0; i1 < tadShape[1]; ++i1) { for (Nd4jLong i2 = 0; i2 < tadShape[2]; ++i2) { const auto xTadOffset = i0 * xTadStride[0] + i1 * xTadStride[1] + i2 * xTadStride[2]; const auto yTadOffset = i0 * yTadStride[0] + i1 * yTadStride[1] + i2 * yTadStride[2]; s = OpType::update(s, OpType::op(xTad[xTadOffset], yTad[yTadOffset], extraParams), extraParams); } } } z[zInd * zEws] = OpType::postProcess(s, tadLen, extraParams); } }; } break; //*********************************************// case LoopKind::RANK4: { Z extraParams[3]; for (Nd4jLong ix = 0; ix < numXTads; ix++) { for (Nd4jLong iy = 0; iy < numYTads; iy++) { extraParams[0] = param0; extraParams[1] = param1; extraParams[2] = param2; const auto xTad = x + xTadOffsets[ix]; const auto yTad = y + yTadOffsets[iy]; const auto zInd = ix * numYTads + iy; auto s = startVal; for (Nd4jLong i0 = 0; i0 < tadShape[0]; ++i0) { for (Nd4jLong i1 = 0; i1 < tadShape[1]; ++i1) { for (Nd4jLong i2 = 0; i2 < tadShape[2]; ++i2) { for (Nd4jLong i3 = 0; i3 < tadShape[3]; ++i3) { const auto xTadOffset = i0 * xTadStride[0] + i1 * xTadStride[1] + i2 * xTadStride[2] + i3 * xTadStride[3]; const auto yTadOffset = i0 * yTadStride[0] + i1 * yTadStride[1] + i2 * yTadStride[2] + i3 * yTadStride[3]; s = OpType::update(s, OpType::op(xTad[xTadOffset], yTad[yTadOffset], extraParams), extraParams); } } } } z[zInd * zEws] = OpType::postProcess(s, tadLen, extraParams); } }; } break; //*********************************************// case LoopKind::RANK5: { Z extraParams[3]; for (Nd4jLong ix = 0; ix < numXTads; ix++) { for (Nd4jLong iy = 0; iy < numYTads; iy++) { extraParams[0] = param0; extraParams[1] = param1; extraParams[2] = param2; const auto xTad = x + xTadOffsets[ix]; const auto yTad = y + yTadOffsets[iy]; const auto zInd = ix * numYTads + iy; auto s = startVal; for (Nd4jLong i0 = 0; i0 < tadShape[0]; ++i0) { for (Nd4jLong i1 = 0; i1 < tadShape[1]; ++i1) { for (Nd4jLong i2 = 0; i2 < tadShape[2]; ++i2) { for (Nd4jLong i3 = 0; i3 < tadShape[3]; ++i3) { for (Nd4jLong i4 = 0; i4 < tadShape[4]; ++i4) { const auto xTadOffset = i0 * xTadStride[0] + i1 * xTadStride[1] + i2 * xTadStride[2] + i3 * xTadStride[3] + i4 * xTadStride[4]; const auto yTadOffset = i0 * yTadStride[0] + i1 * yTadStride[1] + i2 * yTadStride[2] + i3 * yTadStride[3] + i4 * yTadStride[4]; s = OpType::update(s, OpType::op(xTad[xTadOffset], yTad[yTadOffset], extraParams), extraParams); } } } } } z[zInd * zEws] = OpType::postProcess(start, tadLen, extraParams); } }; } break; //*********************************************// default: { uint castXTadShapeInfo[MAX_RANK]; const bool canCastXTad = sd::DataTypeUtils::castShapeInfo(xTadShapeInfo, castXTadShapeInfo); if (shape::haveSameShapeAndStrides(xTadShapeInfo, yTadShapeInfo)) { Z extraParams[3]; for (Nd4jLong ix = 0; ix < numXTads; ix++) { for (Nd4jLong iy = 0; iy < numYTads; iy++) { extraParams[0] = param0; extraParams[1] = param1; extraParams[2] = param2; const auto xTad = x + xTadOffsets[ix]; const auto yTad = y + yTadOffsets[iy]; const auto zInd = ix * numYTads + iy; auto s = startVal; for (Nd4jLong j = 0; j < tadLen; ++j) { const auto tadOffset = shape::indexOffset(j, xTadShapeInfo, castXTadShapeInfo, canCastXTad); s = OpType::update(s, OpType::op(xTad[tadOffset], yTad[tadOffset], extraParams), extraParams); } z[zInd * zEws] = OpType::postProcess(s, tadLen, extraParams); } }; } else { uint castYTadShapeInfo[MAX_RANK]; const bool canCastYTad = sd::DataTypeUtils::castShapeInfo(yTadShapeInfo, castYTadShapeInfo); Z extraParams[3]; for (Nd4jLong ix = 0; ix < numXTads; ix++) { for (Nd4jLong iy = 0; iy < numYTads; iy++) { extraParams[0] = param0; extraParams[1] = param1; extraParams[2] = param2; const auto xTad = x + xTadOffsets[ix]; const auto yTad = y + yTadOffsets[iy]; const auto zInd = ix * numYTads + iy; auto s = startVal; for (Nd4jLong j = 0; j < tadLen; ++j) { const auto xTadOffset = shape::indexOffset(j, xTadShapeInfo, castXTadShapeInfo, canCastXTad); const auto yTadOffset = shape::indexOffset(j, yTadShapeInfo, castYTadShapeInfo, canCastYTad); s = OpType::update(s, OpType::op(xTad[xTadOffset], yTad[yTadOffset], extraParams), extraParams); } z[zInd * zEws] = OpType::postProcess(s, tadLen, extraParams); } }; } } } } } #endif //LIBND4J_LOOPS_H