Exemple #1
0
 def __init__(self, indices, path, rotations=True):
     self.hdf5file = path
     self.rot = Rotations()
     self.rotations = rotations
     if self.rotations:
         self.indices = np.tile(indices, 24)
     else:
         self.indices = indices
     self.length = len(indices)
Exemple #2
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    def testing(self, epoch, test_dataloader, dataset, ensemble=False, remember=10, rotation=True):
        self.model.eval()
        mse_list = []
        rmse_list = []
        batchnum = 0
        batch_losses = []
        criterion = torch.nn.MSELoss()
        if rotation:
            rot = Rotations()

        for batch_id, (data, target) in enumerate(test_dataloader):
            target = target.view(-1, 1)
            data = data.float().cuda()
            target = target.float()
            if rotation:
                outs = []
                datatemp = data.cpu().numpy()[0]
                for j in range(24):
                    newdat = rot.rotation(datatemp, j).copy()
                    newdat = torch.from_numpy(newdat).float().cuda().view((1, 16, 24, 24, 24))
                    outs.append(self.model(newdat))
                out = torch.tensor([[torch.mean(torch.tensor(outs))]])
            else:
                out = self.model(data)
            if ensemble:
                pred = out
                if epoch == 0:
                    prediction = pred
                else:
                    prediction = self.calcPred(pred, remember=remember, batchnum=batchnum)
                batch_losses.append(out)
                prediction = out
            batchnum += 1

            loss = criterion(prediction, target)
            mse_list.append(loss.data.item())
            rmse_list.append(np.sqrt(loss.data.item()))

            # Print is adapted from https://github.com/pytorch/examples/blob/master/mnist_hogwild/train.py
            print('Test Epoch: {} [{}/{} ({:.0f}%)]\tLoss: {:.6f} MSE-Mean: {:.6f} RMSE-Mean:  {:.6f}'.format(
                epoch, batch_id * len(data), dataset.__len__(),
                       100. * (batch_id * len(data)) / dataset.__len__(), loss.data.item(), np.mean(mse_list),
                np.mean(rmse_list)))

        if ensemble:
            self.epochLosses.append(batch_losses)
        print('Test Epoch: {} MSE (loss): {:.4f}, RMSE: {:.4f} Dataset length {}'.format(epoch, np.mean(mse_list),
                                                                                         np.mean(rmse_list),
                                                                                         dataset.__len__()))
        return np.mean(mse_list), np.mean(rmse_list)
Exemple #3
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class OwnDataset(Dataset):
    def __init__(self, indices, path, rotations=True):
        self.hdf5file = path
        self.rot = Rotations()
        self.rotations = rotations
        if self.rotations:
            self.indices = np.tile(indices, 24)
        else:
            self.indices = indices
        self.length = len(indices)

    def __getitem__(self, index):
        data_idx = self.indices[index]
        with h5py.File(self.hdf5file, 'r') as file:
            if self.rotations:
                data = self.rot.rotation(
                    data=file[str(data_idx) + '/data'][()][0],
                    k=np.floor_divide(index, self.length)).copy()
            else:
                data = file[str(data_idx) + '/data'][()][0]
            label = file[str(data_idx) + '/label'][()]
            #label = -np.log10(np.exp(-label))

        return data, label

    def __len__(self):
        if self.rotations:
            return self.length * 24
        else:
            return self.length
Exemple #4
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class OwnDataset(Dataset):
    def __init__(self, indices, path, rotations=True, version=2):
        self.hdf5file = path
        self.rot = Rotations()
        self.rotations = rotations
        if self.rotations:
            self.indices = np.tile(indices, 24)
        else:
            self.indices = indices
        self.length = len(indices)
        self.version = version

    def __getitem__(self, index):
        data_idx = self.indices[index]
        with h5py.File(self.hdf5file, 'r') as file:
            if self.rotations:
                data = self.rot.rotation(
                    data=file[str(data_idx) + '/data'][()][0],
                    k=np.floor_divide(index, self.length)).copy()
            else:
                data = file[str(data_idx) + '/data'][()][0]
            label = file[str(data_idx) + '/label'][()]

            # In the old version of the code, the labels were calculated with the natural logarithm instead with the log10. So this is the recalc
            if self.version == 1:
                label = -np.log10(np.exp(-label))

        return data, label

    def __len__(self):
        if self.rotations:
            return self.length * 24
        else:
            return self.length
Exemple #5
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    def benchmark(self, n_datapoints, datapath, rotations=True, model=None, ensemble=False, version = 2):
        if ensemble:
            best_models = []
            for i in os.listdir(model):
                if 'bestModel' in i:
                    self.model = torch.load(model+i)
                    self.model.eval()
                    best_models.append(self.model)

        if rotations:
            rot = Rotations()
            datafile = datapath
            labels = []
            outs = []

            if model is not None and not ensemble:
                self.bestModel.load_state_dict(torch.load(model + 'bestModel.pt'))
                self.bestModel.eval()

            for i in range(n_datapoints):
                outs1 = []
                target1 = []

                for j in range(24):
                    with h5py.File(datafile, 'r') as file:
                        data = rot.rotation(data=file[str(i) + '/data'][()][0], k=j)
                        # In the old version, wrong log was used -> recalc
                        if version == 1:
                            label = -np.log10(np.exp(-(file[str(i) + '/label'][()])))
                        else:
                            label = file[str(i) + '/label'][()]
                    data = torch.from_numpy(data.reshape(1, 16, 24, 24, 24).copy()).float().cuda()
                    if ensemble:
                        outall = []
                        for m in best_models:
                            outall.append(m(data))
                        out = torch.mean(torch.tensor(outall))
                    else:
                        out = self.bestModel(data)
                    outs1.append(out.cpu().data.numpy())
                    target1.append(label)

                labels.append(np.mean(target1))
                outs.append(np.mean(outs1))

            error = []
            for i in range(290):
                error.append((outs[i] - labels[i]) ** 2)
            print("testmean: ", np.mean(error))

            return error, labels, outs
        else:
            kwargs = {'num_workers': 4}
            indices = np.arange(n_datapoints)
            test_set = OwnDataset(indices, datapath, rotations=False)
            test_dataloader = DataLoader(dataset=test_set, batch_size=1, shuffle=False, **kwargs)

            if model is not None and not ensemble:
                self.bestModel.load_state_dict(torch.load(model + 'bestModel.pt'))
            self.bestModel.eval()

            outs1 = []
            target1 = []

            for batch_id, (data, target) in enumerate(test_dataloader):
                target = target.view(-1, 1)
                target1.append(target.cpu().data.numpy())
                data = data.float().cuda()
                if ensemble:
                    outall = []
                    for m in best_models:
                        out = m(data)
                        outall.append(out)
                    out = torch.mean(torch.tensor(outall))
                else:
                    out = self.bestModel(data)
                outs1.append(out.cpu().data.numpy())

            error = []
            for i in range(290):
                error.append((outs1[i] - target1[i]) ** 2)
            print(outs1, target1)
            print("testmean: ", np.mean(error))

            return error, target1, outs1