#include <algorithm>

#include <cfloat>

#include <vector>

#include "caffe/layers/softmax_loss_layer.hpp"

#include "caffe/util/math_functions.hpp"

namespace caffe {

template <typename Dtype>

void SoftmaxWithLossLayer<Dtype>::LayerSetUp(

const vector<Blob<Dtype>*>& bottom, const vector<Blob<Dtype>*>& top) {

LossLayer<Dtype>::LayerSetUp(bottom, top);

LayerParameter softmax_param(this->layer_param_);

softmax_param.set_type("Softmax");

softmax_layer_ = LayerRegistry<Dtype>::CreateLayer(softmax_param);

softmax_bottom_vec_.clear();

softmax_bottom_vec_.push_back(bottom[0]);

softmax_top_vec_.clear();

softmax_top_vec_.push_back(&prob_);

softmax_layer_->SetUp(softmax_bottom_vec_, softmax_top_vec_);

has_ignore_label_ =

this->layer_param_.loss_param().has_ignore_label();

if (has_ignore_label_) {

ignore_label_ = this->layer_param_.loss_param().ignore_label();

}

if (!this->layer_param_.loss_param().has_normalization() &&

this->layer_param_.loss_param().has_normalize()) {

normalization_ = this->layer_param_.loss_param().normalize() ?

LossParameter_NormalizationMode_VALID :

LossParameter_NormalizationMode_BATCH_SIZE;

} else {

normalization_ = this->layer_param_.loss_param().normalization();

}

}

template <typename Dtype>

void SoftmaxWithLossLayer<Dtype>::Reshape(

const vector<Blob<Dtype>*>& bottom, const vector<Blob<Dtype>*>& top) {

LossLayer<Dtype>::Reshape(bottom, top);

softmax_layer_->Reshape(softmax_bottom_vec_, softmax_top_vec_);

softmax_axis_ =

bottom[0]->CanonicalAxisIndex(this->layer_param_.softmax_param().axis());

outer_num_ = bottom[0]->count(0, softmax_axis_);

inner_num_ = bottom[0]->count(softmax_axis_ + 1);

CHECK_EQ(outer_num_ * inner_num_, bottom[1]->count())

<< "Number of labels must match number of predictions; "

<< "e.g., if softmax axis == 1 and prediction shape is (N, C, H, W), "

<< "label count (number of labels) must be N*H*W, "

<< "with integer values in {0, 1, ..., C-1}.";

if (top.size() >= 2) {

// softmax output

top[1]->ReshapeLike(*bottom[0]);

}

}

template <typename Dtype>

Dtype SoftmaxWithLossLayer<Dtype>::get_normalizer(

LossParameter_NormalizationMode normalization_mode, int valid_count) {

Dtype normalizer;

switch (normalization_mode) {

case LossParameter_NormalizationMode_FULL:

normalizer = Dtype(outer_num_ * inner_num_);

break;

case LossParameter_NormalizationMode_VALID:

if (valid_count == -1) {

normalizer = Dtype(outer_num_ * inner_num_);

} else {

normalizer = Dtype(valid_count);

}

break;

case LossParameter_NormalizationMode_BATCH_SIZE:

normalizer = Dtype(outer_num_);

break;

case LossParameter_NormalizationMode_NONE:

normalizer = Dtype(1);

break;

default:

LOG(FATAL) << "Unknown normalization mode: "

<< LossParameter_NormalizationMode_Name(normalization_mode);

}

// Some users will have no labels for some examples in order to 'turn off' a

// particular loss in a multi-task setup. The max prevents NaNs in that case.

return std::max(Dtype(1.0), normalizer);

}

template <typename Dtype>

void SoftmaxWithLossLayer<Dtype>::Forward_cpu(

const vector<Blob<Dtype>*>& bottom, const vector<Blob<Dtype>*>& top) {

// The forward pass computes the softmax prob values.

softmax_layer_->Forward(softmax_bottom_vec_, softmax_top_vec_);

const Dtype* prob_data = prob_.cpu_data();

const Dtype* label = bottom[1]->cpu_data();

int dim = prob_.count() / outer_num_;

int count = 0;

Dtype loss = 0;

for (int i = 0; i < outer_num_; ++i) {

for (int j = 0; j < inner_num_; j++) {

const int label_value = static_cast<int>(label[i * inner_num_ + j]);

if (has_ignore_label_ && label_value == ignore_label_) {

continue;

}

DCHECK_GE(label_value, 0);

DCHECK_LT(label_value, prob_.shape(softmax_axis_));

loss -= log(std::max(prob_data[i * dim + label_value * inner_num_ + j],

Dtype(FLT_MIN)));

++count;

}

}

top[0]->mutable_cpu_data()[0] = loss / get_normalizer(normalization_, count);

if (top.size() == 2) {

top[1]->ShareData(prob_);

}

}

template <typename Dtype>

void SoftmaxWithLossLayer<Dtype>::Backward_cpu(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_cpu_diff();

const Dtype* prob_data = prob_.cpu_data();

caffe_copy(prob_.count(), prob_data, bottom_diff);

const Dtype* label = bottom[1]->cpu_data();

int dim = prob_.count() / outer_num_;

int count = 0;

for (int i = 0; i < outer_num_; ++i) {

for (int j = 0; j < inner_num_; ++j) {

const int label_value = static_cast<int>(label[i * inner_num_ + j]);

if (has_ignore_label_ && label_value == ignore_label_) {

for (int c = 0; c < bottom[0]->shape(softmax_axis_); ++c) {

bottom_diff[i * dim + c * inner_num_ + j] = 0;

}

} else {

bottom_diff[i * dim + label_value * inner_num_ + j] -= 1;

++count;

}

}

}

// Scale gradient

Dtype loss_weight = top[0]->cpu_diff()[0] /

get_normalizer(normalization_, count);

caffe_scal(prob_.count(), loss_weight, bottom_diff);

}

}

#ifdef CPU_ONLY

STUB_GPU(SoftmaxWithLossLayer);

#endif

INSTANTIATE_CLASS(SoftmaxWithLossLayer);

REGISTER_LAYER_CLASS(SoftmaxWithLoss);

} // namespace caffe