// // ShapePriorbox.cpp // MNN // // Created by MNN on 2019/01/10. // Copyright © 2018, Alibaba Group Holding Limited // #include "shape/SizeComputer.hpp" #include "core/Macro.h" #include "core/TensorUtils.hpp" namespace MNN { class PriorBoxComputer : public SizeComputer { public: virtual bool onComputeSize(const MNN::Op* op, const std::vector& inputs, const std::vector& outputs) const override { MNN_ASSERT(2 == inputs.size()); MNN_ASSERT(1 == outputs.size()); auto layer = op->main_as_PriorBox(); auto inputTensor = inputs[0]; auto inputTensor1 = inputs[1]; int w = inputTensor->width(); int h = inputTensor->height(); auto minSizes = layer->minSizes(); auto maxSizes = layer->maxSizes(); auto aspectRatios = layer->aspectRatios(); int flip = layer->flip(); int imageWidth = layer->imageWidth(); int imageHeight = layer->imageHeight(); float stepWidth = layer->stepWidth(); float stepHeight = layer->stepHeight(); int imageW = imageWidth; int imageH = imageHeight; if (imageW <= 0) { imageW = inputTensor1->width(); } if (imageH <= 0) { imageH = inputTensor1->height(); } float stepW = stepWidth; float stepH = stepHeight; if (stepW <= 0) { stepW = (float)imageW / w; } if (stepH <= 0) { stepH = (float)imageH / h; } int minSizeCount = minSizes ? (int)minSizes->size() : 0; int maxSizeCount = maxSizes ? (int)maxSizes->size() : 0; std::vector aspectRatiosValue{1.0f}; if (aspectRatios != nullptr) { for (int i = 0; i < aspectRatios->size(); ++i) { auto ratio = aspectRatios->data()[i]; bool exist = false; for (auto v : aspectRatiosValue) { auto diff = v - ratio; if (diff < 0) { diff = -diff; } if (diff < 1e-6) { exist = true; break; } } if (!exist) { aspectRatiosValue.emplace_back(ratio); if (flip) { aspectRatiosValue.emplace_back(1.0f / ratio); } } } } int priorCount = minSizeCount * aspectRatiosValue.size() + maxSizeCount; auto& outputTensorBuffer = outputs[0]->buffer(); outputTensorBuffer.dim[0].extent = 1; outputTensorBuffer.dim[1].extent = 2; outputTensorBuffer.dim[2].extent = 4 * w * h * priorCount; outputTensorBuffer.dim[3].extent = 1; outputTensorBuffer.type = halide_type_of(); TensorUtils::getDescribe(outputs[0])->dimensionFormat = MNN_DATA_FORMAT_NC4HW4; return true; } }; REGISTER_SHAPE(PriorBoxComputer, OpType_PriorBox); } // namespace MNN