Thesis/data_loader.py

import torch
import numpy as np

from torch.utils.data import Dataset


class TrainDataset(Dataset):
    """
    Training Dataset class.
    Parameters
    ----------
    triples:	The triples used for training the model
    params:		Parameters for the experiments

    Returns
    -------
    A training Dataset class instance used by DataLoader
    """

    def __init__(self, triples, params):
        self.triples = triples
        self.p = params
        self.strategy = self.p.train_strategy
        self.entities = np.arange(self.p.num_ent, dtype=np.int32)

    def __len__(self):
        return len(self.triples)

    def __getitem__(self, idx):
        ele = self.triples[idx]
        triple, label, sub_samp = torch.LongTensor(ele['triple']), np.int32(
            ele['label']), np.float32(ele['sub_samp'])
        trp_label = self.get_label(label)

        if self.p.lbl_smooth != 0.0:
            trp_label = (1.0 - self.p.lbl_smooth) * \
                trp_label + (1.0/self.p.num_ent)

        if self.strategy == 'one_to_n':
            return triple, trp_label, None, None

        elif self.strategy == 'one_to_x':
            sub_samp = torch.FloatTensor([sub_samp])
            neg_ent = torch.LongTensor(self.get_neg_ent(triple, label))
            return triple, trp_label, neg_ent, sub_samp
        else:
            raise NotImplementedError

    @staticmethod
    def collate_fn(data):
        triple = torch.stack([_[0] for _ in data], dim=0)
        trp_label = torch.stack([_[1] for _ in data], dim=0)

        if not data[0][2] is None:							# one_to_x
            neg_ent = torch.stack([_[2] for _ in data], dim=0)
            sub_samp = torch.cat([_[3] for _ in data], dim=0)
            return triple, trp_label, neg_ent, sub_samp
        else:
            return triple, trp_label

    def get_neg_ent(self, triple, label):
        def get(triple, label):
            if self.strategy == 'one_to_x':
                pos_obj = triple[2]
                mask = np.ones([self.p.num_ent], dtype=np.bool)
                mask[label] = 0
                neg_ent = np.int32(np.random.choice(
                    self.entities[mask], self.p.neg_num, replace=False)).reshape([-1])
                neg_ent = np.concatenate((pos_obj.reshape([-1]), neg_ent))
            else:
                pos_obj = label
                mask = np.ones([self.p.num_ent], dtype=np.bool)
                mask[label] = 0
                neg_ent = np.int32(np.random.choice(
                    self.entities[mask], self.p.neg_num - len(label), replace=False)).reshape([-1])
                neg_ent = np.concatenate((pos_obj.reshape([-1]), neg_ent))

                if len(neg_ent) > self.p.neg_num:
                    import pdb
                    pdb.set_trace()

            return neg_ent

        neg_ent = get(triple, label)
        return neg_ent

    def get_label(self, label):
        if self.strategy == 'one_to_n':
            y = np.zeros([self.p.num_ent], dtype=np.float32)
            for e2 in label:
                y[e2] = 1.0
        elif self.strategy == 'one_to_x':
            y = [1] + [0] * self.p.neg_num
        else:
            raise NotImplementedError
        return torch.FloatTensor(y)


class TestDataset(Dataset):
    """
    Evaluation Dataset class.
    Parameters
    ----------
    triples:	The triples used for evaluating the model
    params:		Parameters for the experiments

    Returns
    -------
    An evaluation Dataset class instance used by DataLoader for model evaluation
    """

    def __init__(self, triples, params):
        self.triples = triples
        self.p = params

    def __len__(self):
        return len(self.triples)

    def __getitem__(self, idx):
        ele = self.triples[idx]
        triple, label = torch.LongTensor(ele['triple']), np.int32(ele['label'])
        label = self.get_label(label)

        return triple, label

    @staticmethod
    def collate_fn(data):
        triple = torch.stack([_[0] for _ in data], dim=0)
        label = torch.stack([_[1] for _ in data], dim=0)
        return triple, label

    def get_label(self, label):
        y = np.zeros([self.p.num_ent], dtype=np.float32)
        for e2 in label:
            y[e2] = 1.0
        return torch.FloatTensor(y)
upload 2023-05-04 08:49:41 +00:00			`import torch`
			`import numpy as np`

			`from torch.utils.data import Dataset`


			`class TrainDataset(Dataset):`
			`"""`
			`Training Dataset class.`
			`Parameters`
			`----------`
			`triples: The triples used for training the model`
			`params: Parameters for the experiments`

			`Returns`
			`-------`
			`A training Dataset class instance used by DataLoader`
			`"""`

			`def __init__(self, triples, params):`
			`self.triples = triples`
			`self.p = params`
			`self.strategy = self.p.train_strategy`
			`self.entities = np.arange(self.p.num_ent, dtype=np.int32)`

			`def __len__(self):`
			`return len(self.triples)`

			`def __getitem__(self, idx):`
			`ele = self.triples[idx]`
			`triple, label, sub_samp = torch.LongTensor(ele['triple']), np.int32(`
			`ele['label']), np.float32(ele['sub_samp'])`
			`trp_label = self.get_label(label)`

			`if self.p.lbl_smooth != 0.0:`
			`trp_label = (1.0 - self.p.lbl_smooth) * \`
			`trp_label + (1.0/self.p.num_ent)`

			`if self.strategy == 'one_to_n':`
			`return triple, trp_label, None, None`

			`elif self.strategy == 'one_to_x':`
			`sub_samp = torch.FloatTensor([sub_samp])`
			`neg_ent = torch.LongTensor(self.get_neg_ent(triple, label))`
			`return triple, trp_label, neg_ent, sub_samp`
			`else:`
			`raise NotImplementedError`

			`@staticmethod`
			`def collate_fn(data):`
			`triple = torch.stack([_[0] for _ in data], dim=0)`
			`trp_label = torch.stack([_[1] for _ in data], dim=0)`

			`if not data[0][2] is None: # one_to_x`
			`neg_ent = torch.stack([_[2] for _ in data], dim=0)`
			`sub_samp = torch.cat([_[3] for _ in data], dim=0)`
			`return triple, trp_label, neg_ent, sub_samp`
			`else:`
			`return triple, trp_label`

			`def get_neg_ent(self, triple, label):`
			`def get(triple, label):`
			`if self.strategy == 'one_to_x':`
			`pos_obj = triple[2]`
			`mask = np.ones([self.p.num_ent], dtype=np.bool)`
			`mask[label] = 0`
			`neg_ent = np.int32(np.random.choice(`
			`self.entities[mask], self.p.neg_num, replace=False)).reshape([-1])`
			`neg_ent = np.concatenate((pos_obj.reshape([-1]), neg_ent))`
			`else:`
			`pos_obj = label`
			`mask = np.ones([self.p.num_ent], dtype=np.bool)`
			`mask[label] = 0`
			`neg_ent = np.int32(np.random.choice(`
			`self.entities[mask], self.p.neg_num - len(label), replace=False)).reshape([-1])`
			`neg_ent = np.concatenate((pos_obj.reshape([-1]), neg_ent))`

			`if len(neg_ent) > self.p.neg_num:`
			`import pdb`
			`pdb.set_trace()`

			`return neg_ent`

			`neg_ent = get(triple, label)`
			`return neg_ent`

			`def get_label(self, label):`
			`if self.strategy == 'one_to_n':`
			`y = np.zeros([self.p.num_ent], dtype=np.float32)`
			`for e2 in label:`
			`y[e2] = 1.0`
			`elif self.strategy == 'one_to_x':`
			`y = [1] + [0] * self.p.neg_num`
			`else:`
			`raise NotImplementedError`
			`return torch.FloatTensor(y)`


			`class TestDataset(Dataset):`
			`"""`
			`Evaluation Dataset class.`
			`Parameters`
			`----------`
			`triples: The triples used for evaluating the model`
			`params: Parameters for the experiments`

			`Returns`
			`-------`
			`An evaluation Dataset class instance used by DataLoader for model evaluation`
			`"""`

			`def __init__(self, triples, params):`
			`self.triples = triples`
			`self.p = params`

			`def __len__(self):`
			`return len(self.triples)`

			`def __getitem__(self, idx):`
			`ele = self.triples[idx]`
			`triple, label = torch.LongTensor(ele['triple']), np.int32(ele['label'])`
			`label = self.get_label(label)`

			`return triple, label`

			`@staticmethod`
			`def collate_fn(data):`
			`triple = torch.stack([_[0] for _ in data], dim=0)`
			`label = torch.stack([_[1] for _ in data], dim=0)`
			`return triple, label`

			`def get_label(self, label):`
			`y = np.zeros([self.p.num_ent], dtype=np.float32)`
			`for e2 in label:`
			`y[e2] = 1.0`
			`return torch.FloatTensor(y)`