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iit.py
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import numpy as np
import random
import torch
from utils import randvec
__author__ = "Atticus Geiger"
__version__ = "CS224u, Stanford, Spring 2023"
def get_IIT_equality_dataset_both(embed_dim, size):
train_dataset = IIT_PremackDatasetBoth(
embed_dim=embed_dim,
size=size)
X_base_train, X_sources_train, y_base_train, y_IIT_train, interventions = train_dataset.create()
X_base_train = torch.tensor(X_base_train)
X_sources_train = [torch.tensor(X_source_train) for X_source_train in X_sources_train]
y_base_train = torch.tensor(y_base_train)
y_IIT_train = torch.tensor(y_IIT_train)
interventions = torch.tensor(interventions)
return X_base_train, X_sources_train, y_base_train, y_IIT_train, interventions
def get_IIT_equality_dataset(variable, embed_dim, size):
class_size = size/2
train_dataset = IIT_PremackDataset(
variable,
embed_dim=embed_dim,
n_pos=class_size,
n_neg=class_size)
X_base_train, X_sources_train, y_base_train, y_IIT_train, interventions = train_dataset.create()
X_base_train = torch.tensor(X_base_train)
X_sources_train = [torch.tensor(X_source_train) for X_source_train in X_sources_train]
y_base_train = torch.tensor(y_base_train)
y_IIT_train = torch.tensor(y_IIT_train)
interventions = torch.tensor(interventions)
return X_base_train, X_sources_train, y_base_train, y_IIT_train, interventions
def get_equality_dataset(embed_dim, size):
class_size = size/2
train_dataset = PremackDataset(
embed_dim=embed_dim,
n_pos=class_size,
n_neg=class_size)
X_train, y_train = train_dataset.create()
test_dataset = PremackDataset(
embed_dim=embed_dim,
n_pos=class_size,
n_neg=class_size)
X_test, y_test = test_dataset.create()
train_dataset.test_disjoint(test_dataset)
X_train = torch.tensor(X_train)
X_test = torch.tensor(X_test)
return X_train, X_test, y_train, y_test, test_dataset
class EqualityDataset:
POS_LABEL = 1
NEG_LABEL = 0
def __init__(self, embed_dim=50, n_pos=500, n_neg=500, flatten=True):
"""Creates simple equality datasets, which are basically lists
of `((vec1, vec2), label)` instances, where `label == POS_LABEL`
if `vec1 == vec2`, else `label == NEG_LABEL`. With `flatten=True`,
the instances become `(vec1;vec2, label)`.
Parameters
----------
embed_dim : int
Sets the dimensionality of the individual component vectors.
n_pos : int
n_neg : int
flatten : bool
If False, instances are of the form ((vec1, vec2), label).
If True, vec1 and vec2 are concatenated, creating instances
(x, label) where len(x) == embed_dim*2.
Usage
-----
dataset = EqualityDataset()
X, y = dataset.create()
Attributes
----------
embed_dim : int
n_pos : int
n_neg : int
flatten : bool
"""
self.embed_dim = embed_dim
self.n_pos = n_pos
self.n_neg = n_neg
self.flatten = flatten
def create(self):
"""Main interface
Attributes
----------
data : list
Shuffled version of the raw instances, ignoring `self.flatten`.
Thus, these are all of the form `((vec1, vec2), label)`
X : np.array
The dimensionality depends on `self.flatten`. If it is
False, then `X.shape == (n_pos+n_neg, 2, embed_dim)`. If it
is True, then `X.shape == (n_pos+n_neg, embed_dim*2)`.
y : list
Containing `POS_LABEL` and `NEG_LABEL`. Length: n_pos+n_neg
Returns
-------
self.X, self.y
"""
self.data = []
self.data += self._create_pos()
self.data += self._create_neg()
random.shuffle(self.data)
data = self.data.copy()
if self.flatten:
data = [(np.concatenate(x), label) for x, label in data]
X, y = zip(*data)
self.X = np.array(X)
self.y = y
return self.X, self.y
def test_disjoint(self, other_dataset):
these_vecs = {tuple(x) for pair, label in self.data for x in pair}
other_vecs = {tuple(x) for pair, label in other_dataset.data for x in pair}
shared = these_vecs & other_vecs
assert len(shared) == 0, \
f"This dataset and the other dataset shared {len(shared)} word-level reps."
def _create_pos(self):
data = []
for _ in range(self.n_pos):
vec = randvec(self.embed_dim)
rep = (vec, vec)
data.append((rep, self.POS_LABEL))
return data
def _create_neg(self):
data = []
for _ in range(self.n_neg):
vec1 = randvec(self.embed_dim)
vec2 = vec1.copy()
while np.array_equal(vec1, vec2):
vec2 = randvec(self.embed_dim)
rep = (vec1, vec2)
data.append((rep, self.NEG_LABEL))
return data
class PremackDataset:
POS_LABEL = 1
NEG_LABEL = 0
def __init__(self, embed_dim=50, n_pos=500, n_neg=500,
flatten_root=True, flatten_leaves=True, intermediate=False):
"""Creates Premack datasets. Conceptually, the instances are
(((a, b), (c, d)), label)
where `label == POS_LABEL` if (a == b) == (c == d), else
`label == NEG_LABEL`. With `flatten_leaves=True`, these become
((a;b, c;d), label)
and with `flatten_root=True`, these become
(a;b;c;d, label)
and `flatten_root=True` means that `flatten_leaves=True`, since
we can't flatten the roof without flattening the leaves.
Parameters
----------
embed_dim : int
Sets the dimensionality of the individual component vectors.
n_pos : int
n_neg : int
flatten_root : bool
flatten_leaves : bool
Usage
-----
dataset = EqualityDataset()
X, y = dataset.create()
Attributes
----------
embed_dim : int
n_pos : int
n_neg : int
flatten_root : bool
flatten_leaves : bool
n_same_same : n_pos / 2
n_diff_diff : n_pos / 2
n_same_diff : n_neg / 2
n_diff_same : n_neg / 2
Raises
------
ValueError
If `n_pos` or `n_neg` is not even, since this means we
can't get an even distribtion of the two sub-types of
each of those classes while also staying faithful to
user's expected number of examples for each class.
"""
self.embed_dim = embed_dim
self.n_pos = n_pos
self.n_neg = n_neg
for n, v in ((n_pos, 'n_pos'), (n_neg, 'n_neg')):
if n % 2 != 0:
raise ValueError(
f"The value of {v} must be even to ensure a balanced "
f"split across its two sub-types of the {v} class.")
self.n_same_same = int(n_pos / 2)
self.n_diff_diff = int(n_pos / 2)
self.n_same_diff = int(n_neg / 2)
self.n_diff_same = int(n_neg / 2)
self.flatten_root = flatten_root
self.flatten_leaves = flatten_leaves
self.intermediate = intermediate
def create(self):
"""Main interface
Attributes
----------
data : list
Shuffled version of the raw instances, ignoring
`self.flatten_root` and `self.flatten_leaves`.
Thus, these are all of the form `(((a, b), (c, d)), label)`
X : np.array
The dimensionality depends on `self.flatten_root` and
`self.flatten_leaves`.
If both are False, then
`X.shape == (n_pos+n_neg, 2, 2, embed_dim)`
If `self.flatten_root`, then
`X.shape == (n_pos+n_neg, embed_dim*4)`
If only `self.flatten_leaves`, then
`X.shape == (n_pos+n_neg, 2, embed_dim*2)`
y : list
Containing `POS_LABEL` and `NEG_LABEL`. Length: n_pos+n_neg
Returns
-------
self.X, self.y
"""
self.data = []
self.data += self._create_same_same()
self.data += self._create_diff_diff()
self.data += self._create_same_diff()
self.data += self._create_diff_same()
random.shuffle(self.data)
data = self.data.copy()
if self.flatten_root or self.flatten_leaves:
data = [((np.concatenate(x1), np.concatenate(x2)), label)
for (x1, x2), label in data]
if self.flatten_root:
data = [(np.concatenate(x), label) for x, label in data]
X, y = zip(*data)
self.X = np.array(X)
self.y = y
return self.X, self.y
def test_disjoint(self, other_dataset):
these_vecs = {tuple(x) for root_pair, label in self.data
for pair in root_pair for x in pair}
other_vecs = {tuple(x) for root_pair, label in other_dataset.data
for pair in root_pair for x in pair}
shared = these_vecs & other_vecs
assert len(shared) == 0, \
f"This dataset and the other dataset shared {len(shared)} word-level reps."
def _create_same_same(self):
data = []
for _ in range(self.n_same_same):
left = self._create_same_pair()
right = self._create_same_pair()
rep = (left, right)
data.append((rep, self.POS_LABEL))
return data
def _create_diff_diff(self):
data = []
for _ in range(self.n_diff_diff):
left = self._create_diff_pair()
right = self._create_diff_pair()
rep = (left, right)
data.append((rep, self.POS_LABEL))
return data
def _create_same_diff(self):
data = []
for _ in range(self.n_same_diff):
left = self._create_same_pair()
right = self._create_diff_pair()
rep = (left, right)
data.append((rep, self.NEG_LABEL))
return data
def _create_diff_same(self):
data = []
for _ in range(self.n_diff_same):
left = self._create_diff_pair()
right = self._create_same_pair()
rep = (left, right)
data.append((rep, self.NEG_LABEL))
return data
def _create_same_pair(self):
vec = randvec(self.embed_dim)
return (vec, vec)
def _create_diff_pair(self):
vec1 = randvec(self.embed_dim)
vec2 = randvec(self.embed_dim)
assert not np.array_equal(vec1, vec2)
return (vec1, vec2)
class PremackDatasetLeafFlattened(PremackDataset):
def __init__(self, embed_dim=50, n_pos=500, n_neg=500):
super().__init__(
embed_dim=embed_dim,
n_pos=n_pos,
n_neg=n_neg,
flatten_leaves=True,
flatten_root=False,
intermediate=False)
class IIT_PremackDataset:
V1 = 0
V2 = 1
POS_LABEL = 1
NEG_LABEL = 0
def __init__(self, variable, embed_dim=50, n_pos=500, n_neg=500,
flatten_root=True, flatten_leaves=True, intermediate=False):
self.variable = variable
self.embed_dim = embed_dim
self.n_pos = n_pos
self.n_neg = n_neg
for n, v in ((n_pos, 'n_pos'), (n_neg, 'n_neg')):
if n % 2 != 0:
raise ValueError(
f"The value of {v} must be even to ensure a balanced "
f"split across its two sub-types of the {v} class.")
self.n_same_same_to_same = int(n_pos / 4)
self.n_diff_diff_to_same = int(n_neg / 4)
self.n_same_diff_to_same = int(n_neg / 4)
self.n_diff_same_to_same = int(n_neg / 4)
self.n_same_same_to_diff = int(n_neg / 4)
self.n_diff_diff_to_diff = int(n_neg / 4)
self.n_same_diff_to_diff = int(n_neg / 4)
self.n_diff_same_to_diff = int(n_neg / 4)
self.flatten_root = flatten_root
self.flatten_leaves = flatten_leaves
self.intermediate = intermediate
def create(self):
self.data = []
self.data += self._create_same_same_to_same()
self.data += self._create_diff_diff_to_same()
self.data += self._create_same_diff_to_same()
self.data += self._create_diff_same_to_same()
self.data += self._create_same_same_to_diff()
self.data += self._create_diff_diff_to_diff()
self.data += self._create_same_diff_to_diff()
self.data += self._create_diff_same_to_diff()
random.shuffle(self.data)
data = self.data.copy()
if self.flatten_root or self.flatten_leaves:
data = [((np.concatenate(x1), np.concatenate(x2)),(np.concatenate(x3), np.concatenate(x4)), base_label, IIT_label, intervention)
for (x1, x2,x3,x4), base_label, IIT_label, intervention in data]
if self.flatten_root:
data = [(np.concatenate(base), np.concatenate(source), label, IIT_label, intervention)
for base, source, label, IIT_label, intervention in data]
base, source, y, IIT_y, interventions = zip(*data)
self.base = np.array(base)
self.source = np.array(source)
self.y = np.array(y)
self.IIT_y = np.array(IIT_y)
self.interventions = np.array(interventions)
self.sources = list()
self.sources.append(self.source)
return self.base, self.sources, self.y, self.IIT_y, self.interventions
def _create_same_same_to_same(self):
data = []
for _ in range(self.n_same_same_to_same):
base_left = self._create_same_pair()
base_right = self._create_same_pair()
base_label = self.POS_LABEL
if self.variable == "V1":
source_left = self._create_same_pair()
source_right = self._create_random_pair()
IIT_label = self.POS_LABEL
intervention = self.V1
if self.variable == "V2":
source_left = self._create_random_pair()
source_right = self._create_same_pair()
intervention = self.V2
IIT_label = self.POS_LABEL
rep = (base_left, base_right, source_left,source_right)
data.append((rep, base_label, IIT_label, intervention))
return data
def _create_diff_diff_to_same(self):
data = []
for _ in range(self.n_diff_diff_to_same):
base_left = self._create_diff_pair()
base_right = self._create_diff_pair()
base_label = self.POS_LABEL
if self.variable == "V1":
source_left = self._create_same_pair()
source_right = self._create_random_pair()
IIT_label = self.NEG_LABEL
intervention = self.V1
if self.variable == "V2":
source_left = self._create_random_pair()
source_right = self._create_same_pair()
IIT_label = self.NEG_LABEL
intervention = self.V2
rep = (base_left, base_right, source_left,source_right)
data.append((rep, base_label, IIT_label, intervention))
return data
def _create_same_diff_to_same(self):
data = []
for _ in range(self.n_same_diff_to_same):
base_left = self._create_same_pair()
base_right = self._create_diff_pair()
base_label = self.NEG_LABEL
if self.variable == "V1":
source_left = self._create_same_pair()
source_right = self._create_random_pair()
IIT_label = self.NEG_LABEL
intervention = self.V1
if self.variable == "V2":
source_left = self._create_random_pair()
source_right = self._create_same_pair()
IIT_label = self.POS_LABEL
intervention = self.V2
rep = (base_left, base_right, source_left,source_right)
data.append((rep, base_label, IIT_label, intervention))
return data
def _create_diff_same_to_same(self):
data = []
for _ in range(self.n_diff_same_to_same):
base_left = self._create_diff_pair()
base_right = self._create_same_pair()
base_label = self.NEG_LABEL
if self.variable == "V1":
source_left = self._create_same_pair()
source_right = self._create_random_pair()
IIT_label = self.POS_LABEL
intervention = self.V1
if self.variable == "V2":
source_left = self._create_random_pair()
source_right = self._create_same_pair()
IIT_label = self.NEG_LABEL
intervention = self.V2
rep = (base_left, base_right, source_left,source_right)
data.append((rep, base_label, IIT_label, intervention))
return data
def _create_same_same_to_diff(self):
data = []
for _ in range(self.n_same_same_to_diff):
base_left = self._create_same_pair()
base_right = self._create_same_pair()
base_label = self.POS_LABEL
if self.variable == "V1":
source_left = self._create_diff_pair()
source_right = self._create_random_pair()
IIT_label = self.NEG_LABEL
intervention = self.V1
if self.variable == "V2":
source_left = self._create_random_pair()
source_right = self._create_diff_pair()
IIT_label = self.NEG_LABEL
intervention = self.V2
rep = (base_left, base_right, source_left,source_right)
data.append((rep, base_label, IIT_label, intervention))
return data
def _create_diff_diff_to_diff(self):
data = []
for _ in range(self.n_diff_diff_to_diff):
base_left = self._create_diff_pair()
base_right = self._create_diff_pair()
base_label = self.POS_LABEL
if self.variable == "V1":
source_left = self._create_diff_pair()
source_right = self._create_random_pair()
IIT_label = self.POS_LABEL
intervention = self.V1
if self.variable == "V2":
source_left = self._create_random_pair()
source_right = self._create_diff_pair()
IIT_label = self.POS_LABEL
intervention = self.V2
rep = (base_left, base_right, source_left,source_right)
data.append((rep, base_label, IIT_label, intervention))
return data
def _create_same_diff_to_diff(self):
data = []
for _ in range(self.n_same_diff_to_diff):
base_left = self._create_same_pair()
base_right = self._create_diff_pair()
base_label = self.NEG_LABEL
if self.variable == "V1":
source_left = self._create_diff_pair()
source_right = self._create_random_pair()
IIT_label = self.POS_LABEL
intervention = self.V1
if self.variable == "V2":
source_left = self._create_random_pair()
source_right = self._create_diff_pair()
IIT_label = self.NEG_LABEL
intervention = self.V2
rep = (base_left, base_right, source_left,source_right)
data.append((rep, base_label, IIT_label, intervention))
return data
def _create_diff_same_to_diff(self):
data = []
for _ in range(self.n_diff_same_to_diff):
base_left = self._create_diff_pair()
base_right = self._create_same_pair()
base_label = self.NEG_LABEL
if self.variable == "V1":
source_left = self._create_diff_pair()
source_right = self._create_random_pair()
IIT_label = self.NEG_LABEL
intervention = self.V1
if self.variable == "V2":
source_left = self._create_random_pair()
source_right = self._create_diff_pair()
IIT_label = self.POS_LABEL
intervention = self.V2
rep = (base_left, base_right, source_left,source_right)
data.append((rep, base_label, IIT_label, intervention))
return data
def _create_random_pair(self):
if random.choice([True,False]):
return self._create_same_pair()
else:
return self._create_diff_pair()
def _create_same_pair(self):
vec = randvec(self.embed_dim)
return (vec, vec)
def _create_diff_pair(self):
vec1 = randvec(self.embed_dim)
vec2 = randvec(self.embed_dim)
assert not np.array_equal(vec1, vec2)
return (vec1, vec2)
class IIT_PremackDatasetBoth:
V1 = 0
V2 = 1
POS_LABEL = 1
NEG_LABEL = 0
both_coord_id = 2
def __init__(self, size= 1000, embed_dim=50, flatten_root=True, flatten_leaves=True, intermediate=False):
self.embed_dim = embed_dim
self.size= size
self.flatten_root = flatten_root
self.flatten_leaves = flatten_leaves
self.intermediate = intermediate
def create(self):
data = []
for _ in range(self.size):
rep = [self._create_random_pair() for _ in range(6)]
if (rep[0][0] == rep[0][1]).all() == (rep[1][0] == rep[1][1]).all():
base_label = self.POS_LABEL
else:
base_label = self.NEG_LABEL
if (rep[2][0] == rep[2][1]).all() == (rep[5][0] == rep[5][1]).all():
IIT_label = self.POS_LABEL
else:
IIT_label = self.NEG_LABEL
data.append((rep,base_label, IIT_label, self.both_coord_id))
random.shuffle(data)
data = data.copy()
if self.flatten_root or self.flatten_leaves:
data = [
(
(
(np.concatenate(x1), np.concatenate(x2)),
(np.concatenate(x3), np.concatenate(x4)),
(np.concatenate(x5), np.concatenate(x6))
),
base_label, IIT_label, intervention
)
for (x1, x2,x3,x4,x5,x6), base_label, IIT_label, intervention in data
]
if self.flatten_root:
data = [(np.concatenate(base), np.concatenate(source),np.concatenate(source2), label, IIT_label, intervention)
for (base, source, source2), label, IIT_label, intervention in data]
base, source, source2, y, IIT_y, interventions = zip(*data)
self.base = np.array(base)
self.source = np.array(source)
self.source2 = np.array(source2)
self.y = np.array(y)
self.IIT_y = np.array(IIT_y)
self.interventions = np.array(interventions)
return self.base, [self.source, self.source2], self.y, self.IIT_y, self.interventions
def _create_random_pair(self):
if random.choice([True,False]):
return self._create_same_pair()
else:
return self._create_diff_pair()
def _create_same_pair(self):
vec = randvec(self.embed_dim)
return (vec, vec)
def _create_diff_pair(self):
vec1 = randvec(self.embed_dim)
vec2 = randvec(self.embed_dim)
assert not np.array_equal(vec1, vec2)
return (vec1, vec2)