Beispiel #1
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def test_device():
    x = tensor([1, 2, 3], dtype="float32")

    y1 = F.eye(x.shape, dtype="float32")
    y2 = F.eye(x.shape, dtype="float32", device=None)
    np.testing.assert_almost_equal(y1.numpy(), y2.numpy())

    y3 = F.eye(x.shape, dtype="float32", device="xpux")
    y4 = F.eye(x.shape, dtype="float32", device=x.device)
    np.testing.assert_almost_equal(y3.numpy(), y4.numpy())

    y5 = F.full((3, 2), 4, device=x.device)
    y6 = F.full((3, 2), 4, device="xpux")
    np.testing.assert_almost_equal(y5.numpy(), y6.numpy())
Beispiel #2
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 def fwd():
     a = F.linspace(3, 10, 3, device=Device("xpux").to_c())
     b = F.eye(3, device=Device("xpux").to_c())
     return a, b
Beispiel #3
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    def forward(self, features, label=None, mask=None):
        """
        if label and mask both None, the loss will degenerate to
        SimSLR unsupervised loss.
        Reference:
            "A Simple Framework for Contrastive Learning of Visual Representations"<https://arxiv.org/pdf/2002.05709.pdf>
            "Supervised Contrastive Learning"<https://arxiv.org/abs/2004.11362>
        Args:
            features(tensor): The embedding feature. shape=[bs, n_views, ...]
            label(tensor): The label of images, shape=[bs]
            mask(tensor): contrastive mask of shape [bsz, bsz], mask_{i,j}=1 if sample j
                has the same class as sample i. Can be asymmetric.
        return:
            loss
        """
        if len(features.shape) < 3:
            raise ValueError("Features need have 3 dimensions at least")
        bs, num_view = features.shape[:2]
        #if dimension > 3, change the shape of the features to [bs, num_view, ...]
        if len(features.shape) > 3:
            features = features.reshape(bs, num_view, -1)

        #label and mask cannot provided at the same time
        if (label is not None) and (mask is not None):
            raise ValueError("label and mask cannot provided at the same time")
        elif (label is None) and (mask is None):
            mask = F.eye(bs, dtype="float32")
        elif label is not None:
            label = label.reshape(-1, 1)
            if label.shape[0] != bs:
                raise RuntimeError(
                    "Num of labels does not match num of features")
            mask = F.equal(label, label.T)
        else:
            mask = mask.astype("float32")

        contrast_count = features.shape[1]
        features = F.split(features, features.shape[1], axis=1)
        contrast_feature = F.squeeze(F.concat(features, axis=0), axis=1)
        if self.contrast_mode == "one":
            anchor_feature = features[:, 0]
            anchor_count = 1
        elif self.contrast_mode == "all":
            anchor_feature = contrast_feature
            anchor_count = contrast_count
        else:
            raise ValueError("Unknown mode:{}".format(self.contrast_mode))
        #compute logits
        anchor_dot_contrast = F.div(
            F.matmul(anchor_feature, contrast_feature.T), self.temperate)

        #for numerical stability
        logits_max = F.max(anchor_dot_contrast, axis=-1, keepdims=True)
        logits = anchor_dot_contrast - logits_max

        #tile mask
        an1, con = mask.shape[:2]
        nums = anchor_count * contrast_count
        # mask-out self-contrast cases
        mask = F.stack([mask] * nums).reshape(an1 * anchor_count,
                                              con * contrast_count)
        logits_mask = F.scatter(
            F.ones_like(mask), 1,
            F.arange(0, int(bs * anchor_count), dtype="int32").reshape(-1, 1),
            F.zeros(int(bs * anchor_count), dtype="int32").reshape(-1, 1))
        mask = mask * logits_mask
        #compute log_prob
        exp_logits = F.exp(logits) * logits_mask
        log_prob = logits - F.log(F.sum(exp_logits, axis=1,
                                        keepdims=True))  #equation 2

        #mean
        mean_log_prob_pos = F.sum(mask * log_prob, axis=1) / F.sum(mask,
                                                                   axis=1)

        #loss
        loss = -(self.temperate / self.base_temperate) * mean_log_prob_pos
        loss = F.mean(loss.reshape(anchor_count, bs))
        return loss