Esempio n. 1
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def compute_losses(output, minibatch, lambda_factor=1):
    def compute_kernel(x, y):
        x_size = x.size(0)
        y_size = y.size(0)
        dim = x.size(1)
        x = x.unsqueeze(1) # (x_size, 1, dim)
        y = y.unsqueeze(0) # (1, y_size, dim)
        tiled_x = x.expand(x_size, y_size, dim)
        tiled_y = y.expand(x_size, y_size, dim)
        kernel_input = (tiled_x - tiled_y).pow(2).mean(2)/float(dim)
        return torch.exp(-kernel_input) # (x_size, y_size)

    def compute_mmd(x, y):
        x_kernel = compute_kernel(x, x)
        y_kernel = compute_kernel(y, y)
        xy_kernel = compute_kernel(x, y)
        mmd = x_kernel.mean() + y_kernel.mean() - 2*xy_kernel.mean()
        return mmd

    def W_loss(z):
      return compute_mmd(z,torch.randn_like(z))

    rec_loss = F.binary_cross_entropy(output,minibatch.unsqueeze(1))
    prior_loss = lambda_factor*W_loss(z)
    return (rec_loss, prior_loss)
Esempio n. 2
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def loss_vae(recon_x, x, mu, logvar, type="BCE", h1=0.1, h2=0.1):
    """
    see Appendix B from VAE paper:
    Kingma and Welling. Auto-Encoding Variational Bayes. ICLR, 2014
    # https://arxiv.org/abs/1312.6114
    # 0.5 * sum(1 + log(sigma^2) - mu^2 - sigma^2)
    :param recon_x:
    :param x:
    :param mu,logvar: VAE parameters
    :param type: choices BCE,L1,L2
    :param h1: reconsrtruction hyperparam
    :param h2: KL div hyperparam
    :return: total loss of VAE
    """
    batch = recon_x.shape[0]
    assert recon_x.size() == x.size()
    assert recon_x.shape[0] == x.shape[0]
    rec_flat = recon_x.view(batch, -1)
    x_flat = x.view(batch, -1)
    if type == "BCE":
        loss_rec = F.binary_cross_entropy(rec_flat, x_flat, reduction='sum')
    elif type == "L1":
        loss_rec = torch.sum(torch.abs(rec_flat - x_flat))
    elif type == "L2":
        loss_rec = torch.sum(torch.sqrt(rec_flat * rec_flat - x_flat * x_flat))
    KLD = -0.5 * torch.sum(1 + logvar - mu.pow(2) - logvar.exp())
    return loss_rec * h1 + KLD * h2
Esempio n. 3
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 def forward(self, input, target):
     # _assert_no_grad(target)
     target = target.float()
     # input = input[0][0]
     beta = 1 - torch.mean(target)
     # input = F.softmax(input, dim=1)
     input = input[:, 0, :, :]
     # target pixel = 1 -> weight beta
     # target pixel = 0 -> weight 1-beta
     weights = 1 - beta + (2 * beta - 1) * target
     return F.binary_cross_entropy(input, target, weights, reduction='mean')
Esempio n. 4
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    def forward(self, inputs, targets):
        if self.logits:
            BCE_loss = F.binary_cross_entropy_with_logits(inputs, targets, reduce=False)
        else:
            BCE_loss = F.binary_cross_entropy(inputs, targets, reduce=False)
        pt = torch.exp(-BCE_loss)
        F_loss = self.alpha * (1-pt)**self.gamma * BCE_loss

        if self.reduce:
            return torch.mean(F_loss)
        else:
            return F_loss
Esempio n. 5
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def train_model(model, epochs, train_loader, optimizer):
    model.train()
    for epoch in range(epochs):
        total_loss = 0
        total_correct = 0
        total = 0
        with tqdm(train_loader, desc='Train Epoch #{}'.format(epoch)) as t:
            for data, target in t:
                data, target = data.to(DEVICE), target.to(DEVICE)
                optimizer.zero_grad()
                output = model(data)
                optimizer.zero_grad()
                loss = F.binary_cross_entropy(output, target)
                loss.backward()
                optimizer.step()
                total += len(data)
                total_correct += output.round().eq(target).sum().item()
                total_loss += loss.item() * len(data)
                t.set_postfix(loss='{:.4f}'.format(total_loss / total), accuracy='{:.4f}'.format(total_correct / total))
Esempio n. 6
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File: train.py Progetto: LFetty/gaga
 def gan_loss(self, y_hat, y):
     return F.binary_cross_entropy(y_hat, y)
Esempio n. 7
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def compute_loss(minibatch, output, mu, logvar):
    rec_loss = F.binary_cross_entropy(output,minibatch.unsqueeze(1),\
                                   reduction="sum")
    kl_loss  = 0.25 * torch.sum(torch.exp(logvar) + mu**2 - 1. - logvar)
    loss     = rec_loss + kl_loss
    return loss