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eval_translation.py
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eval_translation.py
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# Copyright (C) 2016-2018 Mikel Artetxe <[email protected]>
#
# This program is free software: you can redistribute it and/or modify
# it under the terms of the GNU General Public License as published by
# the Free Software Foundation, either version 3 of the License, or
# (at your option) any later version.
#
# This program is distributed in the hope that it will be useful,
# but WITHOUT ANY WARRANTY; without even the implied warranty of
# MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
# GNU General Public License for more details.
#
# You should have received a copy of the GNU General Public License
# along with this program. If not, see <http://www.gnu.org/licenses/>.
import embeddings
from cupy_utils import *
import argparse
import collections
import numpy as np
import sys
BATCH_SIZE = 500
def topk_mean(m, k, inplace=False): # TODO Assuming that axis is 1
xp = get_array_module(m)
n = m.shape[0]
ans = xp.zeros(n, dtype=m.dtype)
if k <= 0:
return ans
if not inplace:
m = xp.array(m)
ind0 = xp.arange(n)
ind1 = xp.empty(n, dtype=int)
minimum = m.min()
for i in range(k):
m.argmax(axis=1, out=ind1)
ans += m[ind0, ind1]
m[ind0, ind1] = minimum
return ans / k
def main():
# Parse command line arguments
parser = argparse.ArgumentParser(description='Evaluate embeddings of two languages in a shared space in word translation induction')
parser.add_argument('src_embeddings', help='the source language embeddings')
parser.add_argument('trg_embeddings', help='the target language embeddings')
parser.add_argument('-d', '--dictionary', default=sys.stdin.fileno(), help='the test dictionary file (defaults to stdin)')
parser.add_argument('--retrieval', default='nn', choices=['nn', 'invnn', 'invsoftmax', 'csls'], help='the retrieval method (nn: standard nearest neighbor; invnn: inverted nearest neighbor; invsoftmax: inverted softmax; csls: cross-domain similarity local scaling)')
parser.add_argument('--inv_temperature', default=1, type=float, help='the inverse temperature (only compatible with inverted softmax)')
parser.add_argument('--inv_sample', default=None, type=int, help='use a random subset of the source vocabulary for the inverse computations (only compatible with inverted softmax)')
parser.add_argument('-k', '--neighborhood', default=10, type=int, help='the neighborhood size (only compatible with csls)')
parser.add_argument('--dot', action='store_true', help='use the dot product in the similarity computations instead of the cosine')
parser.add_argument('--encoding', default='utf-8', help='the character encoding for input/output (defaults to utf-8)')
parser.add_argument('--seed', type=int, default=0, help='the random seed')
parser.add_argument('--precision', choices=['fp16', 'fp32', 'fp64'], default='fp32', help='the floating-point precision (defaults to fp32)')
parser.add_argument('--cuda', action='store_true', help='use cuda (requires cupy)')
args = parser.parse_args()
# Choose the right dtype for the desired precision
if args.precision == 'fp16':
dtype = 'float16'
elif args.precision == 'fp32':
dtype = 'float32'
elif args.precision == 'fp64':
dtype = 'float64'
# Read input embeddings
srcfile = open(args.src_embeddings, encoding=args.encoding, errors='surrogateescape')
trgfile = open(args.trg_embeddings, encoding=args.encoding, errors='surrogateescape')
src_words, x = embeddings.read(srcfile, dtype=dtype)
trg_words, z = embeddings.read(trgfile, dtype=dtype)
# NumPy/CuPy management
if args.cuda:
if not supports_cupy():
print('ERROR: Install CuPy for CUDA support', file=sys.stderr)
sys.exit(-1)
xp = get_cupy()
x = xp.asarray(x)
z = xp.asarray(z)
else:
xp = np
xp.random.seed(args.seed)
# Length normalize embeddings so their dot product effectively computes the cosine similarity
if not args.dot:
embeddings.length_normalize(x)
embeddings.length_normalize(z)
# Build word to index map
src_word2ind = {word: i for i, word in enumerate(src_words)}
trg_word2ind = {word: i for i, word in enumerate(trg_words)}
# Read dictionary and compute coverage
f = open(args.dictionary, encoding=args.encoding, errors='surrogateescape')
src2trg = collections.defaultdict(set)
oov = set()
vocab = set()
for line in f:
src, trg = line.split()
try:
src_ind = src_word2ind[src]
trg_ind = trg_word2ind[trg]
src2trg[src_ind].add(trg_ind)
vocab.add(src)
except KeyError:
oov.add(src)
src = list(src2trg.keys())
oov -= vocab # If one of the translation options is in the vocabulary, then the entry is not an oov
coverage = len(src2trg) / (len(src2trg) + len(oov))
# Find translations
translation = collections.defaultdict(int)
if args.retrieval == 'nn': # Standard nearest neighbor
for i in range(0, len(src), BATCH_SIZE):
j = min(i + BATCH_SIZE, len(src))
similarities = x[src[i:j]].dot(z.T)
nn = similarities.argmax(axis=1).tolist()
for k in range(j-i):
translation[src[i+k]] = nn[k]
elif args.retrieval == 'invnn': # Inverted nearest neighbor
best_rank = np.full(len(src), x.shape[0], dtype=int)
best_sim = np.full(len(src), -100, dtype=dtype)
for i in range(0, z.shape[0], BATCH_SIZE):
j = min(i + BATCH_SIZE, z.shape[0])
similarities = z[i:j].dot(x.T)
ind = (-similarities).argsort(axis=1)
ranks = asnumpy(ind.argsort(axis=1)[:, src])
sims = asnumpy(similarities[:, src])
for k in range(i, j):
for l in range(len(src)):
rank = ranks[k-i, l]
sim = sims[k-i, l]
if rank < best_rank[l] or (rank == best_rank[l] and sim > best_sim[l]):
best_rank[l] = rank
best_sim[l] = sim
translation[src[l]] = k
elif args.retrieval == 'invsoftmax': # Inverted softmax
sample = xp.arange(x.shape[0]) if args.inv_sample is None else xp.random.randint(0, x.shape[0], args.inv_sample)
partition = xp.zeros(z.shape[0])
for i in range(0, len(sample), BATCH_SIZE):
j = min(i + BATCH_SIZE, len(sample))
partition += xp.exp(args.inv_temperature*z.dot(x[sample[i:j]].T)).sum(axis=1)
for i in range(0, len(src), BATCH_SIZE):
j = min(i + BATCH_SIZE, len(src))
p = xp.exp(args.inv_temperature*x[src[i:j]].dot(z.T)) / partition
nn = p.argmax(axis=1).tolist()
for k in range(j-i):
translation[src[i+k]] = nn[k]
elif args.retrieval == 'csls': # Cross-domain similarity local scaling
knn_sim_bwd = xp.zeros(z.shape[0])
for i in range(0, z.shape[0], BATCH_SIZE):
j = min(i + BATCH_SIZE, z.shape[0])
knn_sim_bwd[i:j] = topk_mean(z[i:j].dot(x.T), k=args.neighborhood, inplace=True)
for i in range(0, len(src), BATCH_SIZE):
j = min(i + BATCH_SIZE, len(src))
similarities = 2*x[src[i:j]].dot(z.T) - knn_sim_bwd # Equivalent to the real CSLS scores for NN
nn = similarities.argmax(axis=1).tolist()
for k in range(j-i):
translation[src[i+k]] = nn[k]
# Compute accuracy
accuracy = np.mean([1 if translation[i] in src2trg[i] else 0 for i in src])
print('Coverage:{0:7.2%} Accuracy:{1:7.2%}'.format(coverage, accuracy))
if __name__ == '__main__':
main()