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splitcross.py
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splitcross.py
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from collections import defaultdict
import torch
import torch.nn as nn
import numpy as np
class SplitCrossEntropyLoss(nn.Module):
r'''SplitCrossEntropyLoss calculates an approximate softmax'''
def __init__(self, hidden_size, splits, verbose=False):
# We assume splits is [0, split1, split2, N] where N >= |V|
# For example, a vocab of 1000 words may have splits [0] + [100, 500] + [inf]
super(SplitCrossEntropyLoss, self).__init__()
self.hidden_size = hidden_size
self.splits = [0] + splits + [100 * 1000000]
self.nsplits = len(self.splits) - 1
self.stats = defaultdict(list)
self.verbose = verbose
# Each of the splits that aren't in the head require a pretend token, we'll call them tombstones
# The probability given to this tombstone is the probability of selecting an item from the represented split
if self.nsplits > 1:
self.tail_vectors = nn.Parameter(torch.zeros(self.nsplits - 1, hidden_size))
self.tail_bias = nn.Parameter(torch.zeros(self.nsplits - 1))
def logprob(self, weight, bias, hiddens, splits=None, softmaxed_head_res=None, verbose=False):
# First we perform the first softmax on the head vocabulary and the tombstones
if softmaxed_head_res is None:
start, end = self.splits[0], self.splits[1]
head_weight = None if end - start == 0 else weight[start:end]
head_bias = None if end - start == 0 else bias[start:end]
# We only add the tombstones if we have more than one split
if self.nsplits > 1:
head_weight = self.tail_vectors if head_weight is None else torch.cat([head_weight, self.tail_vectors])
head_bias = self.tail_bias if head_bias is None else torch.cat([head_bias, self.tail_bias])
# Perform the softmax calculation for the word vectors in the head for all splits
# We need to guard against empty splits as torch.cat does not like random lists
head_res = torch.nn.functional.linear(hiddens, head_weight, bias=head_bias)
softmaxed_head_res = torch.nn.functional.log_softmax(head_res, dim=-1)
if splits is None:
splits = list(range(self.nsplits))
results = []
running_offset = 0
for idx in splits:
# For those targets in the head (idx == 0) we only need to return their loss
if idx == 0:
results.append(softmaxed_head_res[:, :-(self.nsplits - 1)])
# If the target is in one of the splits, the probability is the p(tombstone) * p(word within tombstone)
else:
start, end = self.splits[idx], self.splits[idx + 1]
tail_weight = weight[start:end]
tail_bias = bias[start:end]
# Calculate the softmax for the words in the tombstone
tail_res = torch.nn.functional.linear(hiddens, tail_weight, bias=tail_bias)
# Then we calculate p(tombstone) * p(word in tombstone)
# Adding is equivalent to multiplication in log space
head_entropy = (softmaxed_head_res[:, -idx]).contiguous()
tail_entropy = torch.nn.functional.log_softmax(tail_res, dim=-1)
results.append(head_entropy.view(-1, 1) + tail_entropy)
if len(results) > 1:
return torch.cat(results, dim=1)
return results[0]
def split_on_targets(self, hiddens, targets):
# Split the targets into those in the head and in the tail
split_targets = []
split_hiddens = []
# Determine to which split each element belongs (for each start split value, add 1 if equal or greater)
# This method appears slower at least for WT-103 values for approx softmax
#masks = [(targets >= self.splits[idx]).view(1, -1) for idx in range(1, self.nsplits)]
#mask = torch.sum(torch.cat(masks, dim=0), dim=0)
###
# This is equally fast for smaller splits as method below but scales linearly
mask = None
for idx in range(1, self.nsplits):
partial_mask = targets >= self.splits[idx]
mask = mask + partial_mask if mask is not None else partial_mask
###
#masks = torch.stack([targets] * (self.nsplits - 1))
#mask = torch.sum(masks >= self.split_starts, dim=0)
for idx in range(self.nsplits):
# If there are no splits, avoid costly masked select
if self.nsplits == 1:
split_targets, split_hiddens = [targets], [hiddens]
continue
# If all the words are covered by earlier targets, we have empties so later stages don't freak out
if sum(len(t) for t in split_targets) == len(targets):
split_targets.append([])
split_hiddens.append([])
continue
# Are you in our split?
tmp_mask = mask == idx
split_targets.append(torch.masked_select(targets, tmp_mask))
split_hiddens.append(hiddens.masked_select(tmp_mask.unsqueeze(1).expand_as(hiddens)).view(-1, hiddens.size(1)))
return split_targets, split_hiddens
def forward(self, weight, bias, hiddens, targets, verbose=False):
if self.verbose or verbose:
for idx in sorted(self.stats):
print('{}: {}'.format(idx, int(np.mean(self.stats[idx]))), end=', ')
print()
total_loss = None
if len(hiddens.size()) > 2: hiddens = hiddens.view(-1, hiddens.size(2))
split_targets, split_hiddens = self.split_on_targets(hiddens, targets)
# First we perform the first softmax on the head vocabulary and the tombstones
start, end = self.splits[0], self.splits[1]
head_weight = None if end - start == 0 else weight[start:end]
head_bias = None if end - start == 0 else bias[start:end]
# We only add the tombstones if we have more than one split
if self.nsplits > 1:
head_weight = self.tail_vectors if head_weight is None else torch.cat([head_weight, self.tail_vectors])
head_bias = self.tail_bias if head_bias is None else torch.cat([head_bias, self.tail_bias])
# Perform the softmax calculation for the word vectors in the head for all splits
# We need to guard against empty splits as torch.cat does not like random lists
combo = torch.cat([split_hiddens[i] for i in range(self.nsplits) if len(split_hiddens[i])])
###
all_head_res = torch.nn.functional.linear(combo, head_weight, bias=head_bias)
softmaxed_all_head_res = torch.nn.functional.log_softmax(all_head_res, dim=-1)
if self.verbose or verbose:
self.stats[0].append(combo.size()[0] * head_weight.size()[0])
running_offset = 0
for idx in range(self.nsplits):
# If there are no targets for this split, continue
if len(split_targets[idx]) == 0: continue
# For those targets in the head (idx == 0) we only need to return their loss
if idx == 0:
softmaxed_head_res = softmaxed_all_head_res[running_offset:running_offset + len(split_hiddens[idx])]
entropy = -torch.gather(softmaxed_head_res, dim=1, index=split_targets[idx].view(-1, 1))
# If the target is in one of the splits, the probability is the p(tombstone) * p(word within tombstone)
else:
softmaxed_head_res = softmaxed_all_head_res[running_offset:running_offset + len(split_hiddens[idx])]
if self.verbose or verbose:
start, end = self.splits[idx], self.splits[idx + 1]
tail_weight = weight[start:end]
self.stats[idx].append(split_hiddens[idx].size()[0] * tail_weight.size()[0])
# Calculate the softmax for the words in the tombstone
tail_res = self.logprob(weight, bias, split_hiddens[idx], splits=[idx], softmaxed_head_res=softmaxed_head_res)
# Then we calculate p(tombstone) * p(word in tombstone)
# Adding is equivalent to multiplication in log space
head_entropy = softmaxed_head_res[:, -idx]
# All indices are shifted - if the first split handles [0,...,499] then the 500th in the second split will be 0 indexed
indices = (split_targets[idx] - self.splits[idx]).view(-1, 1)
# Warning: if you don't squeeze, you get an N x 1 return, which acts oddly with broadcasting
tail_entropy = torch.gather(torch.nn.functional.log_softmax(tail_res, dim=-1), dim=1, index=indices).squeeze()
entropy = -(head_entropy + tail_entropy)
###
running_offset += len(split_hiddens[idx])
total_loss = entropy.float().sum() if total_loss is None else total_loss + entropy.float().sum()
return (total_loss / len(targets)).type_as(weight)
if __name__ == '__main__':
np.random.seed(42)
torch.manual_seed(42)
if torch.cuda.is_available():
torch.cuda.manual_seed(42)
V = 8
H = 10
N = 100
E = 10
embed = torch.nn.Embedding(V, H)
crit = SplitCrossEntropyLoss(hidden_size=H, splits=[V // 2])
bias = torch.nn.Parameter(torch.ones(V))
optimizer = torch.optim.SGD(list(embed.parameters()) + list(crit.parameters()), lr=1)
for _ in range(E):
prev = torch.autograd.Variable((torch.rand(N, 1) * 0.999 * V).int().long())
x = torch.autograd.Variable((torch.rand(N, 1) * 0.999 * V).int().long())
y = embed(prev).squeeze()
c = crit(embed.weight, bias, y, x.view(N))
print('Crit', c.exp().data[0])
logprobs = crit.logprob(embed.weight, bias, y[:2]).exp()
print(logprobs)
print(logprobs.sum(dim=1))
optimizer.zero_grad()
c.backward()
optimizer.step()