源码:
// ------------------------------------------------------------------
// Fast R-CNN
// Copyright (c) 2015 Microsoft
// Licensed under The MIT License [see fast-rcnn/LICENSE for details]
// Written by Ross Girshick
// ------------------------------------------------------------------
#include "caffe/fast_rcnn_layers.hpp"
namespace caffe {
template <typename Dtype>
__global__ void SmoothL1Forward(const int n, const Dtype* in, Dtype* out,
Dtype sigma2) {
// f(x) = 0.5 * (sigma * x)^2 if |x| < 1 / sigma / sigma
// |x| - 0.5 / sigma / sigma otherwise
CUDA_KERNEL_LOOP(index, n) {
Dtype val = in[index];
Dtype abs_val = abs(val);
if (abs_val < 1.0 / sigma2) {
out[index] = 0.5 * val * val * sigma2;
} else {
out[index] = abs_val - 0.5 / sigma2;
}
}
}
template <typename Dtype>
void SmoothL1LossLayer<Dtype>::Forward_gpu(const vector<Blob<Dtype>*>& bottom,
const vector<Blob<Dtype>*>& top) {
int count = bottom[0]->count();
caffe_gpu_sub(
count,
bottom[0]->gpu_data(),
bottom[1]->gpu_data(),
diff_.mutable_gpu_data()); // d := b0 - b1
if (has_weights_) {
// apply "inside" weights
caffe_gpu_mul(
count,
bottom[2]->gpu_data(),
diff_.gpu_data(),
diff_.mutable_gpu_data()); // d := w_in * (b0 - b1)
}
SmoothL1Forward<Dtype><<<CAFFE_GET_BLOCKS(count), CAFFE_CUDA_NUM_THREADS>>>(
count, diff_.gpu_data(), errors_.mutable_gpu_data(), sigma2_);
CUDA_POST_KERNEL_CHECK;
if (has_weights_) {
// apply "outside" weights
caffe_gpu_mul(
count,
bottom[3]->gpu_data(),
errors_.gpu_data(),
errors_.mutable_gpu_data()); // d := w_out * SmoothL1(w_in * (b0 - b1))
}
Dtype loss;
caffe_gpu_dot(count, ones_.gpu_data(), errors_.gpu_data(), &loss);
top[0]->mutable_cpu_data()[0] = loss / bottom[0]->num();
}
template <typename Dtype>
__global__ void SmoothL1Backward(const int n, const Dtype* in, Dtype* out,
Dtype sigma2) {
// f'(x) = sigma * sigma * x if |x| < 1 / sigma / sigma
// = sign(x) otherwise
CUDA_KERNEL_LOOP(index, n) {
Dtype val = in[index];
Dtype abs_val = abs(val);
if (abs_val < 1.0 / sigma2) {
out[index] = sigma2 * val;
} else {
out[index] = (Dtype(0) < val) - (val < Dtype(0));
}
}
}
template <typename Dtype>
void SmoothL1LossLayer<Dtype>::Backward_gpu(const vector<Blob<Dtype>*>& top,
const vector<bool>& propagate_down, const vector<Blob<Dtype>*>& bottom) {
// after forwards, diff_ holds w_in * (b0 - b1)
int count = diff_.count();
SmoothL1Backward<Dtype><<<CAFFE_GET_BLOCKS(count), CAFFE_CUDA_NUM_THREADS>>>(
count, diff_.gpu_data(), diff_.mutable_gpu_data(), sigma2_);
CUDA_POST_KERNEL_CHECK;
for (int i = 0; i < 2; ++i) {
if (propagate_down[i]) {
const Dtype sign = (i == 0) ? 1 : -1;
const Dtype alpha = sign * top[0]->cpu_diff()[0] / bottom[i]->num();
caffe_gpu_axpby(
count, // count
alpha, // alpha
diff_.gpu_data(), // x
Dtype(0), // beta
bottom[i]->mutable_gpu_diff()); // y
if (has_weights_) {
// Scale by "inside" weight
caffe_gpu_mul(
count,
bottom[2]->gpu_data(),
bottom[i]->gpu_diff(),
bottom[i]->mutable_gpu_diff());
// Scale by "outside" weight
caffe_gpu_mul(
count,
bottom[3]->gpu_data(),
bottom[i]->gpu_diff(),
bottom[i]->mutable_gpu_diff());
}
}
}
}
INSTANTIATE_LAYER_GPU_FUNCS(SmoothL1LossLayer);
} // namespace caffeSmoothL1LossLayer 计算一张图片的损失函数,对应于下图的加号右边部分
i是mini-batch的anchor的索引。
Pi是目标的预测概率。
有物体时pi*为1,否则为0
ti是一个向量,预测座标
ti*是一个向量,是gt包围盒的座标
bottom[0]预测座标,对应于下图的ti
bottom[1]target座标,对应于下图的ti*
bottom[2]inside,有物体(fg)时为1,否则为0,对应于下图的pi*
bottom[3]outside,没有前景(fg)也没有后景(bg)的为0,其他为1/(bg+fg),对应于加号右边的系数部分(但其实这个地方我本人还是不懂,因为论文上说的系数都是一些固定的值,如入=10。初始代码一直在更新,估计又换了别的方法。不论如何,在现在的代码中outside是乘以了后面的结果)
Lreg的公式就是下图,另x=ti - ti*
Pi*Leg(ti, ti*)表明只有有fg(20个物体类别)的才有回归损失
