loss.py

#coding:utf8
import torch
import torch.nn as nn
import torch.nn.functional as F
from torch.autograd import Variable

def get_alpha(root,datatxt):
    count = {}
    json_address = os.path.join(root, datatxt)
    with open(json_address, 'r') as load_f:
        img_label = json.load(load_f)
    for i in range(len(img_label)):
        label = img_label[i]['disease_class']
        if label in count:
            count[label]+=1
        else:
            count[label] = 1
    print(sorted(count.items(),key = lambda d:d[1] ))

class FocalLoss(nn.Module):
    """
        This criterion is a implemenation of Focal Loss, which is proposed in 
        Focal Loss for Dense Object Detection.

            Loss(x, class) = - \alpha (1-softmax(x)[class])^gamma \log(softmax(x)[class])

        The losses are averaged across observations for each minibatch.

        Args:
            alpha(1D Tensor, Variable) : the scalar factor for this criterion
            gamma(float, double) : gamma > 0; reduces the relative loss for well-classified examples (p > .5), 
                                   putting more focus on hard, misclassified examples
            size_average(bool): By default, the losses are averaged over observations for each minibatch.
                                However, if the field size_average is set to False, the losses are
                                instead summed for each minibatch.


    """
    def __init__(self, class_num, alpha=None, gamma=2, size_average=True):
        super(FocalLoss, self).__init__()
        if alpha is None:
            self.alpha = Variable(torch.ones(class_num, 1))
        else:
            if isinstance(alpha, Variable):
                self.alpha = alpha
            else:
                self.alpha = Variable(alpha)
        self.gamma = gamma
        self.class_num = class_num
        self.size_average = size_average

    def forward(self, inputs, targets):
        N = inputs.size(0)
        C = inputs.size(1)
        P = F.softmax(inputs,dim= 1)

        class_mask = inputs.data.new(N, C).fill_(0)
        class_mask = Variable(class_mask)
        ids = targets.view(-1, 1)
        class_mask.scatter_(1, ids.data, 1.)
        #print(class_mask)


        if inputs.is_cuda and not self.alpha.is_cuda:
            self.alpha = self.alpha.cuda()
        alpha = self.alpha[ids.data.view(-1)]

        probs = (P*class_mask).sum(1).view(-1,1)

        log_p = probs.log()
        #print('probs size= {}'.format(probs.size()))
        #print(probs)

        batch_loss = -alpha*(torch.pow((1-probs), self.gamma))*log_p 
        #print('-----bacth_loss------')
        #print(batch_loss)


        if self.size_average:
            loss = batch_loss.mean()
        else:
            loss = batch_loss.sum()
        return loss

if __name__=='__main__':
    #coding:utf8
    from config import opt
    import os
    import json
    get_alpha(root = opt.train_root,
            datatxt='AgriculturalDisease_train_annotations.json',)
    get_alpha(root = opt.val_root,
            datatxt = 'AgriculturalDisease_validation_annotations.json')