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/* ******************************************************************************
*
*
* 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
******************************************************************************/
//
// Created by raver119 on 16.10.2017.
//
#include <array/DataTypeUtils.h>
#include <helpers/ConstantTadHelper.h>
#include <helpers/ShapeUtils.h>
#include <ops/declarable/LegacyReduceFloatOp.h>
#include <ops/declarable/OpRegistrator.h>
#include <legacy/NativeOpExecutioner.h>
namespace sd {
namespace ops {
LegacyReduceFloatOp::LegacyReduceFloatOp() : LegacyOp(1) {
//
}
LegacyReduceFloatOp::LegacyReduceFloatOp(int opNum) : LegacyOp(1, opNum) {
}
LegacyOp* LegacyReduceFloatOp::clone() { return new LegacyReduceFloatOp(this->_opNum); }
Status LegacyReduceFloatOp::validateAndExecute(Context& block) {
auto x = INPUT_VARIABLE(0);
auto z = OUTPUT_VARIABLE(0);
NDArray::prepareSpecialUse({z}, {x});
int opNum = block.opNum() < 0 ? this->_opNum : block.opNum();
sd_debug("Executing LegacyReduceFloatOp: [%i]\n", opNum);
bool allAxes = false;
auto axis = *block.getAxis();
ExtraArguments extras(*block.getTArguments());
PointersManager manager(block.launchContext(), "LegacyReduceFloatOp");
if (block.width() == 1) {
if (axis.size() == static_cast<size_t>(x->rankOf())) allAxes = true;
if (block.getAxis()->empty() || allAxes) {
// scalar
NativeOpExecutioner::execReduceFloatScalar(
block.launchContext(), opNum, x->buffer(), x->shapeInfo(), x->specialBuffer(), x->specialShapeInfo(),
extras.argumentsAsT(z->dataType()), z->buffer(), z->shapeInfo(), z->specialBuffer(), z->specialShapeInfo());
} else {
// TAD
std::vector<LongType> dims(*block.getAxis());
for (size_t e = 0; e < dims.size(); e++)
if (dims[e] < 0) dims[e] += x->rankOf();
REQUIRE_TRUE(dims.size() > 0, 0, "Some dimensions required for reduction!");
const LongType* zShapeInfoH = z->shapeInfo();
const LongType* zShapeInfoD = z->specialShapeInfo();
if (x->rankOf() == z->rankOf()) {
auto zPack = ConstantShapeHelper::getInstance().createShapeInfoWithNoUnitiesForReduce(
z->shapeInfo(), &dims, z->getContext()->getWorkspace());
zShapeInfoH = reinterpret_cast<LongType const*>(zPack->primary());
zShapeInfoD = reinterpret_cast<LongType const*>(zPack->special());
}
std::vector<LongType> *dims2 = ShapeUtils::evalDimsForReduceOp(x->rankOf(), &dims);
NativeOpExecutioner::execReduceFloat(block.launchContext(), opNum, x->buffer(), x->shapeInfo(),
x->specialBuffer(), x->specialShapeInfo(),
extras.argumentsAsT(z->dataType()), z->buffer(), zShapeInfoH,
z->specialBuffer(), zShapeInfoD, dims2->data(), dims2->size());
delete dims2;
}
STORE_RESULT(*z);
} else {
auto indices = INPUT_VARIABLE(1);
if (indices->lengthOf() == x->rankOf()) allAxes = true;
std::vector<LongType> dims(indices->lengthOf());
for (int e = 0; e < indices->lengthOf(); e++) {
// segfault on macOS if not like this
int f = indices->e<int>(e);
dims[e] = f >= 0 ? f : f += x->rankOf();
}
if ((block.getIArguments()->size() == 1 && INT_ARG(0) == DataTypeUtils::max<int>()) || allAxes) {
// scalar
NativeOpExecutioner::execReduceFloatScalar(
block.launchContext(), opNum, x->buffer(), x->shapeInfo(), x->specialBuffer(), x->specialShapeInfo(),
extras.argumentsAsT(x->dataType()), z->buffer(), z->shapeInfo(), z->specialBuffer(), z->specialShapeInfo());
} else {
// TAD
REQUIRE_TRUE(dims.size() > 0, 0, "Some dimensions required for reduction!");
const LongType* zShapeInfoH = z->shapeInfo();
const LongType* zShapeInfoD = z->specialShapeInfo();
if (x->rankOf() == z->rankOf()) {
auto zPack = ConstantShapeHelper::getInstance().createShapeInfoWithNoUnitiesForReduce(
z->shapeInfo(), &dims, z->getContext()->getWorkspace());
zShapeInfoH = reinterpret_cast<LongType const*>(zPack->primary());
zShapeInfoD = reinterpret_cast<LongType const*>(zPack->special());
}
std::vector<LongType> *dims2 = ShapeUtils::evalDimsForReduceOp(x->rankOf(), &dims);
NativeOpExecutioner::execReduceFloat(block.launchContext(), opNum, x->buffer(), x->shapeInfo(),
x->specialBuffer(), x->specialShapeInfo(),
extras.argumentsAsT(z->dataType()), z->buffer(), zShapeInfoH,
z->specialBuffer(), zShapeInfoD, dims2->data(), dims2->size());
delete dims2;
}
}
manager.synchronize();
traceExecIfNeeded(block);
return Status::OK;
}
/**
* For all reductions rules are simple: either you return scalar, or you return reduced NDArray.
* It solely depends on input shape, and requested dimensions
*/
ShapeList* LegacyReduceFloatOp::calculateOutputShape(ShapeList* inputShape, Context& block) {
auto inShape = inputShape->at(0);
auto keepDims = block.numB() > 0 ? B_ARG(0) : false;
auto newFormat = block.numB() > 1 ? B_ARG(1) : true;
auto axis = block.width() > 1 ? INPUT_VARIABLE(1)->asVectorT<LongType>() : *block.getAxis();
// in this case we're building proper shape for reduction
auto newShape =
ShapeUtils::evalReduceShapeInfo(shape::order(inShape), &axis, inShape, keepDims, !newFormat, block.workspace());
return SHAPELIST(newShape);
}
} // namespace ops
} // namespace sd