#include <algorithm>

#include <vector>

#include "caffe/common_layers.hpp"

#include "caffe/layer.hpp"

#include "caffe/util/math_functions.hpp"

namespace caffe {

template <typename Dtype>

void MVNLayer<Dtype>::Reshape(const vector<Blob<Dtype>*>& bottom,

vector<Blob<Dtype>*>* top) {

(*top)[0]->Reshape(bottom[0]->num(), bottom[0]->channels(),

bottom[0]->height(), bottom[0]->width());

mean_.Reshape(bottom[0]->num(), bottom[0]->channels(),

1, 1);

variance_.Reshape(bottom[0]->num(), bottom[0]->channels(),

1, 1);

temp_.Reshape(bottom[0]->num(), bottom[0]->channels(),

bottom[0]->height(), bottom[0]->width());

sum_multiplier_.Reshape(1, 1,

bottom[0]->height(), bottom[0]->width());

Dtype* multiplier_data = sum_multiplier_.mutable_cpu_data();

caffe_set(sum_multiplier_.count(), Dtype(1), multiplier_data);

}

template <typename Dtype>

void MVNLayer<Dtype>::Forward_cpu(const vector<Blob<Dtype>*>& bottom,

vector<Blob<Dtype>*>* top) {

const Dtype* bottom_data = bottom[0]->cpu_data();

Dtype* top_data = (*top)[0]->mutable_cpu_data();

int num;

if (this->layer_param_.mvn_param().across_channels())

num = bottom[0]->num();

else

num = bottom[0]->num() * bottom[0]->channels();

int dim = bottom[0]->count() / num;

Dtype eps = 1e-10;

if (this->layer_param_.mvn_param().normalize_variance()) {

// put the squares of bottom into temp_

caffe_powx(bottom[0]->count(), bottom_data, Dtype(2),

temp_.mutable_cpu_data());

// computes variance using var(X) = E(X^2) - (EX)^2

caffe_cpu_gemv<Dtype>(CblasNoTrans, num, dim, 1. / dim, bottom_data,

sum_multiplier_.cpu_data(), 0., mean_.mutable_cpu_data()); // EX

caffe_cpu_gemv<Dtype>(CblasNoTrans, num, dim, 1. / dim, temp_.cpu_data(),

sum_multiplier_.cpu_data(), 0.,

variance_.mutable_cpu_data()); // E(X^2)

caffe_powx(mean_.count(), mean_.cpu_data(), Dtype(2),

temp_.mutable_cpu_data()); // (EX)^2

caffe_sub(mean_.count(), variance_.cpu_data(), temp_.cpu_data(),

variance_.mutable_cpu_data()); // variance

// do mean and variance normalization

// subtract mean

caffe_cpu_gemm<Dtype>(CblasNoTrans, CblasNoTrans, num, dim, 1, -1.,

mean_.cpu_data(), sum_multiplier_.cpu_data(), 0.,

temp_.mutable_cpu_data());

caffe_add(temp_.count(), bottom_data, temp_.cpu_data(), top_data);

// normalize variance

caffe_powx(variance_.count(), variance_.cpu_data(), Dtype(0.5),

variance_.mutable_cpu_data());

caffe_add_scalar(variance_.count(), eps, variance_.mutable_cpu_data());

caffe_cpu_gemm<Dtype>(CblasNoTrans, CblasNoTrans, num, dim, 1, 1.,

variance_.cpu_data(), sum_multiplier_.cpu_data(), 0.,

temp_.mutable_cpu_data());

caffe_div(temp_.count(), top_data, temp_.cpu_data(), top_data);

} else {

caffe_cpu_gemv<Dtype>(CblasNoTrans, num, dim, 1. / dim, bottom_data,

sum_multiplier_.cpu_data(), 0., mean_.mutable_cpu_data()); // EX

// subtract mean

caffe_cpu_gemm<Dtype>(CblasNoTrans, CblasNoTrans, num, dim, 1, -1.,

mean_.cpu_data(), sum_multiplier_.cpu_data(), 0.,

temp_.mutable_cpu_data());

caffe_add(temp_.count(), bottom_data, temp_.cpu_data(), top_data);

}

}

template <typename Dtype>

void MVNLayer<Dtype>::Backward_cpu(const vector<Blob<Dtype>*>& top,

const vector<bool>& propagate_down,

vector<Blob<Dtype>*>* bottom) {

const Dtype* top_diff = top[0]->cpu_diff();

const Dtype* top_data = top[0]->cpu_data();

const Dtype* bottom_data = (*bottom)[0]->cpu_data();

Dtype* bottom_diff = (*bottom)[0]->mutable_cpu_diff();

int num;

if (this->layer_param_.mvn_param().across_channels())

num = (*bottom)[0]->num();

else

num = (*bottom)[0]->num() * (*bottom)[0]->channels();

int dim = (*bottom)[0]->count() / num;

Dtype eps = 1e-10;

if (this->layer_param_.mvn_param().normalize_variance()) {

caffe_mul(temp_.count(), top_data, top_diff, bottom_diff);

caffe_cpu_gemv<Dtype>(CblasNoTrans, num, dim, 1., bottom_diff,

sum_multiplier_.cpu_data(), 0., mean_.mutable_cpu_data());

caffe_cpu_gemm<Dtype>(CblasNoTrans, CblasNoTrans, num, dim, 1, 1.,

mean_.cpu_data(), sum_multiplier_.cpu_data(), 0.,

bottom_diff);

caffe_mul(temp_.count(), top_data, bottom_diff, bottom_diff);

caffe_cpu_gemv<Dtype>(CblasNoTrans, num, dim, 1., top_diff,

sum_multiplier_.cpu_data(), 0., mean_.mutable_cpu_data());

caffe_cpu_gemm<Dtype>(CblasNoTrans, CblasNoTrans, num, dim, 1, 1.,

mean_.cpu_data(), sum_multiplier_.cpu_data(), 1.,

bottom_diff);

caffe_cpu_axpby(temp_.count(), Dtype(1), top_diff, Dtype(-1. / dim),

bottom_diff);

// put the squares of bottom into temp_

caffe_powx(temp_.count(), bottom_data, Dtype(2),

temp_.mutable_cpu_data());

// computes variance using var(X) = E(X^2) - (EX)^2

caffe_cpu_gemv<Dtype>(CblasNoTrans, num, dim, 1. / dim, bottom_data,

sum_multiplier_.cpu_data(), 0., mean_.mutable_cpu_data()); // EX

caffe_cpu_gemv<Dtype>(CblasNoTrans, num, dim, 1. / dim, temp_.cpu_data(),

sum_multiplier_.cpu_data(), 0.,

variance_.mutable_cpu_data()); // E(X^2)

caffe_powx(mean_.count(), mean_.cpu_data(), Dtype(2),

temp_.mutable_cpu_data()); // (EX)^2

caffe_sub(mean_.count(), variance_.cpu_data(), temp_.cpu_data(),

variance_.mutable_cpu_data()); // variance

// normalize variance

caffe_powx(variance_.count(), variance_.cpu_data(), Dtype(0.5),

variance_.mutable_cpu_data());

caffe_add_scalar(variance_.count(), eps, variance_.mutable_cpu_data());

caffe_cpu_gemm<Dtype>(CblasNoTrans, CblasNoTrans, num, dim, 1, 1.,

variance_.cpu_data(), sum_multiplier_.cpu_data(), 0.,

temp_.mutable_cpu_data());

caffe_div(temp_.count(), bottom_diff, temp_.cpu_data(), bottom_diff);

} else {

caffe_copy(temp_.count(), top_diff, bottom_diff);

}

}

#ifdef CPU_ONLY

STUB_GPU(MVNLayer);

#endif

INSTANTIATE_CLASS(MVNLayer);

} // namespace caffe