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focal_loss_layer.cu
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focal_loss_layer.cu
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#include <algorithm>
#include <cfloat>
#include <vector>
#include "caffe/layers/focal_loss_layer.hpp"
#include "caffe/util/math_functions.hpp"
namespace caffe {
template <typename Dtype>
__global__ void FocalLossForwardGPU(const int nthreads,
const Dtype* prob_data, const Dtype* label, Dtype* loss,
const int num, const int dim, const int spatial_dim,
const bool has_ignore_label_, const int ignore_label_,
Dtype* counts, float alpha_, float gamma_) {
CUDA_KERNEL_LOOP(index, nthreads) {
const int n = index / spatial_dim;
const int s = index % spatial_dim;
const int label_value = static_cast<int>(label[n * spatial_dim + s]);
if (has_ignore_label_ && label_value == ignore_label_) {
loss[index] = 0;
counts[index] = 0;
} else {
//loss[index] = -log(max(prob_data[n * dim + label_value * spatial_dim + s],
// Dtype(FLT_MIN)));
Dtype pt = prob_data[n * dim + label_value * spatial_dim + s];
loss[index] = -alpha_ * powf(1 - pt, gamma_) * log(max(pt, Dtype(FLT_MIN)));
counts[index] = 1;
}
}
}
template <typename Dtype>
void FocalLossLayer<Dtype>::Forward_gpu(
const vector<Blob<Dtype>*>& bottom, const vector<Blob<Dtype>*>& top) {
softmax_layer_->Forward(softmax_bottom_vec_, softmax_top_vec_);
const Dtype* prob_data = prob_.gpu_data();
const Dtype* label = bottom[1]->gpu_data();
const int dim = prob_.count() / outer_num_;
const int nthreads = outer_num_ * inner_num_;
// Since this memory is not used for anything until it is overwritten
// on the backward pass, we use it here to avoid having to allocate new GPU
// memory to accumulate intermediate results in the kernel.
Dtype* loss_data = bottom[0]->mutable_gpu_diff();
// Similarly, this memory is never used elsewhere, and thus we can use it
// to avoid having to allocate additional GPU memory.
Dtype* counts = prob_.mutable_gpu_diff();
// NOLINT_NEXT_LINE(whitespace/operators)
FocalLossForwardGPU<Dtype><<<CAFFE_GET_BLOCKS(nthreads),
CAFFE_CUDA_NUM_THREADS>>>(nthreads, prob_data, label, loss_data,
outer_num_, dim, inner_num_, has_ignore_label_, ignore_label_, counts,
alpha_, gamma_);
Dtype loss;
caffe_gpu_asum(nthreads, loss_data, &loss);
Dtype valid_count = -1;
// Only launch another CUDA kernel if we actually need the count of valid
// outputs.
if (normalization_ == LossParameter_NormalizationMode_VALID &&
has_ignore_label_) {
caffe_gpu_asum(nthreads, counts, &valid_count);
}
Dtype normalizer = LossLayer<Dtype>::GetNormalizer(
normalization_, outer_num_, inner_num_, valid_count);
top[0]->mutable_cpu_data()[0] = loss / normalizer;
if (top.size() == 2) {
top[1]->ShareData(prob_);
}
}
template <typename Dtype>
__global__ void FocalLossBackwardGPU(const int nthreads, const Dtype* top,
const Dtype* label, Dtype* bottom_diff, const int num, const int dim,
const int spatial_dim, const bool has_ignore_label_,
const int ignore_label_, Dtype* counts, float alpha_, float gamma_) {
const int channels = dim / spatial_dim;
CUDA_KERNEL_LOOP(index, nthreads) {
const int n = index / spatial_dim;
const int s = index % spatial_dim;
const int label_value = static_cast<int>(label[n * spatial_dim + s]);
if (has_ignore_label_ && label_value == ignore_label_) {
for (int c = 0; c < channels; ++c) {
bottom_diff[n * dim + c * spatial_dim + s] = 0;
}
counts[index] = 0;
} else {
Dtype pt = bottom_diff[n * dim + label_value * spatial_dim + s];
for (int c = 0; c < channels; ++c) {
if(c == label_value){
bottom_diff[n * dim + c * spatial_dim + s] = alpha_ *
powf(1 - pt, gamma_) * (gamma_ * pt * log(max(pt, Dtype(FLT_MIN))) + pt - 1);
}
else{
Dtype pc = bottom_diff[n * dim + c * spatial_dim + s];
bottom_diff[n * dim + c * spatial_dim + s] = alpha_ *
(powf(1 - pt, gamma_ - 1) * (-gamma_ * log(max(pt, Dtype(FLT_MIN))) * pt * pc) +
powf(1 - pt, gamma_) * pc);
}
}
counts[index] = 1;
}
}
}
template <typename Dtype>
void FocalLossLayer<Dtype>::Backward_gpu(const vector<Blob<Dtype>*>& top,
const vector<bool>& propagate_down, const vector<Blob<Dtype>*>& bottom) {
if (propagate_down[1]) {
LOG(FATAL) << this->type()
<< " Layer cannot backpropagate to label inputs.";
}
if (propagate_down[0]) {
Dtype* bottom_diff = bottom[0]->mutable_gpu_diff();
const Dtype* prob_data = prob_.gpu_data();
const Dtype* top_data = top[0]->gpu_data();
caffe_gpu_memcpy(prob_.count() * sizeof(Dtype), prob_data, bottom_diff);
const Dtype* label = bottom[1]->gpu_data();
const int dim = prob_.count() / outer_num_;
const int nthreads = outer_num_ * inner_num_;
// Since this memory is never used for anything else,
// we use to to avoid allocating new GPU memory.
Dtype* counts = prob_.mutable_gpu_diff();
// NOLINT_NEXT_LINE(whitespace/operators)
FocalLossBackwardGPU<Dtype><<<CAFFE_GET_BLOCKS(nthreads),
CAFFE_CUDA_NUM_THREADS>>>(nthreads, top_data, label, bottom_diff,
outer_num_, dim, inner_num_, has_ignore_label_, ignore_label_, counts,
alpha_, gamma_);
Dtype valid_count = -1;
// Only launch another CUDA kernel if we actually need the count of valid
// outputs.
if (normalization_ == LossParameter_NormalizationMode_VALID &&
has_ignore_label_) {
caffe_gpu_asum(nthreads, counts, &valid_count);
}
Dtype normalizer = LossLayer<Dtype>::GetNormalizer(
normalization_, outer_num_, inner_num_, valid_count);
const Dtype loss_weight = top[0]->cpu_diff()[0] / normalizer;
caffe_gpu_scal(prob_.count(), loss_weight , bottom_diff);
}
}
INSTANTIATE_LAYER_GPU_FUNCS(FocalLossLayer);
} // namespace caffe