forked from yasharhezaveh/Ensai
-
Notifications
You must be signed in to change notification settings - Fork 0
/
my_txtutils.py
333 lines (285 loc) · 12 KB
/
my_txtutils.py
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
97
98
99
100
101
102
103
104
105
106
107
108
109
110
111
112
113
114
115
116
117
118
119
120
121
122
123
124
125
126
127
128
129
130
131
132
133
134
135
136
137
138
139
140
141
142
143
144
145
146
147
148
149
150
151
152
153
154
155
156
157
158
159
160
161
162
163
164
165
166
167
168
169
170
171
172
173
174
175
176
177
178
179
180
181
182
183
184
185
186
187
188
189
190
191
192
193
194
195
196
197
198
199
200
201
202
203
204
205
206
207
208
209
210
211
212
213
214
215
216
217
218
219
220
221
222
223
224
225
226
227
228
229
230
231
232
233
234
235
236
237
238
239
240
241
242
243
244
245
246
247
248
249
250
251
252
253
254
255
256
257
258
259
260
261
262
263
264
265
266
267
268
269
270
271
272
273
274
275
276
277
278
279
280
281
282
283
284
285
286
287
288
289
290
291
292
293
294
295
296
297
298
299
300
301
302
303
304
305
306
307
308
309
310
311
312
313
314
315
316
317
318
319
320
321
322
323
324
325
326
327
328
329
330
331
332
333
# encoding: UTF-8
# Copyright 2017 Google.com
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
import numpy as np
import glob
import sys
# size of the alphabet that we work with
ALPHASIZE = 98
# Specification of the supported alphabet (subset of ASCII-7)
# 10 line feed LF
# 32-64 numbers and punctuation
# 65-90 upper-case letters
# 91-97 more punctuation
# 97-122 lower-case letters
# 123-126 more punctuation
def convert_from_alphabet(a):
"""Encode a character
:param a: one character
:return: the encoded value
"""
if a == 9:
return 1
if a == 10:
return 127 - 30 # LF
elif 32 <= a <= 126:
return a - 30
else:
return 0 # unknown
# encoded values:
# unknown = 0
# tab = 1
# space = 2
# all chars from 32 to 126 = c-30
# LF mapped to 127-30
def convert_to_alphabet(c, avoid_tab_and_lf=False):
"""Decode a code point
:param c: code point
:param avoid_tab_and_lf: if True, tab and line feed characters are replaced by '\'
:return: decoded character
"""
if c == 1:
return 32 if avoid_tab_and_lf else 9 # space instead of TAB
if c == 127 - 30:
return 92 if avoid_tab_and_lf else 10 # \ instead of LF
if 32 <= c + 30 <= 126:
return c + 30
else:
return 0 # unknown
def encode_text(s):
"""Encode a string.
:param s: a text string
:return: encoded list of code points
"""
return list(map(lambda a: convert_from_alphabet(ord(a)), s))
def decode_to_text(c, avoid_tab_and_lf=False):
"""Decode an encoded string.
:param c: encoded list of code points
:param avoid_tab_and_lf: if True, tab and line feed characters are replaced by '\'
:return:
"""
return "".join(map(lambda a: chr(convert_to_alphabet(a, avoid_tab_and_lf)), c))
def sample_from_probabilities(probabilities, topn=ALPHASIZE):
"""Roll the dice to produce a random integer in the [0..ALPHASIZE] range,
according to the provided probabilities. If topn is specified, only the
topn highest probabilities are taken into account.
:param probabilities: a list of size ALPHASIZE with individual probabilities
:param topn: the number of highest probabilities to consider. Defaults to all of them.
:return: a random integer
"""
p = np.squeeze(probabilities)
p[np.argsort(p)[:-topn]] = 0
p = p / np.sum(p)
return np.random.choice(ALPHASIZE, 1, p=p)[0]
def rnn_minibatch_sequencer(raw_data, batch_size, sequence_size, nb_epochs):
"""
Divides the data into batches of sequences so that all the sequences in one batch
continue in the next batch. This is a generator that will keep returning batches
until the input data has been seen nb_epochs times. Sequences are continued even
between epochs, apart from one, the one corresponding to the end of raw_data.
The remainder at the end of raw_data that does not fit in an full batch is ignored.
:param raw_data: the training text
:param batch_size: the size of a training minibatch
:param sequence_size: the unroll size of the RNN
:param nb_epochs: number of epochs to train on
:return:
x: one batch of training sequences
y: on batch of target sequences, i.e. training sequences shifted by 1
epoch: the current epoch number (starting at 0)
"""
data = np.array(raw_data)
data_len = data.shape[0]
# using (data_len-1) because we must provide for the sequence shifted by 1 too
nb_batches = (data_len - 1) // (batch_size * sequence_size)
assert nb_batches > 0, "Not enough data, even for a single batch. Try using a smaller batch_size."
rounded_data_len = nb_batches * batch_size * sequence_size
xdata = np.reshape(data[0:rounded_data_len], [batch_size, nb_batches * sequence_size])
ydata = np.reshape(data[1:rounded_data_len + 1], [batch_size, nb_batches * sequence_size])
for epoch in range(nb_epochs):
for batch in range(nb_batches):
x = xdata[:, batch * sequence_size:(batch + 1) * sequence_size]
y = ydata[:, batch * sequence_size:(batch + 1) * sequence_size]
x = np.roll(x, -epoch, axis=0) # to continue the text from epoch to epoch (do not reset rnn state!)
y = np.roll(y, -epoch, axis=0)
yield x, y, epoch
def find_book(index, bookranges):
return next(
book["name"] for book in bookranges if (book["start"] <= index < book["end"]))
def find_book_index(index, bookranges):
return next(
i for i, book in enumerate(bookranges) if (book["start"] <= index < book["end"]))
def print_learning_learned_comparison(X, Y, losses, bookranges, batch_loss, batch_accuracy, epoch_size, index, epoch):
"""Display utility for printing learning statistics"""
print()
# epoch_size in number of batches
batch_size = X.shape[0] # batch_size in number of sequences
sequence_len = X.shape[1] # sequence_len in number of characters
start_index_in_epoch = index % (epoch_size * batch_size * sequence_len)
for k in range(batch_size):
index_in_epoch = index % (epoch_size * batch_size * sequence_len)
decx = decode_to_text(X[k], avoid_tab_and_lf=True)
decy = decode_to_text(Y[k], avoid_tab_and_lf=True)
bookname = find_book(index_in_epoch, bookranges)
formatted_bookname = "{: <10.40}".format(bookname) # min 10 and max 40 chars
epoch_string = "{:4d}".format(index) + " (epoch {}) ".format(epoch)
loss_string = "loss: {:.5f}".format(losses[k])
print_string = epoch_string + formatted_bookname + " │ {} │ {} │ {}"
print(print_string.format(decx, decy, loss_string))
index += sequence_len
# box formatting characters:
# │ \u2502
# ─ \u2500
# └ \u2514
# ┘ \u2518
# ┴ \u2534
# ┌ \u250C
# ┐ \u2510
format_string = "└{:─^" + str(len(epoch_string)) + "}"
format_string += "{:─^" + str(len(formatted_bookname)) + "}"
format_string += "┴{:─^" + str(len(decx) + 2) + "}"
format_string += "┴{:─^" + str(len(decy) + 2) + "}"
format_string += "┴{:─^" + str(len(loss_string)) + "}┘"
footer = format_string.format('INDEX', 'BOOK NAME', 'TRAINING SEQUENCE', 'PREDICTED SEQUENCE', 'LOSS')
print(footer)
# print statistics
batch_index = start_index_in_epoch // (batch_size * sequence_len)
batch_string = "batch {}/{} in epoch {},".format(batch_index, epoch_size, epoch)
stats = "{: <28} batch loss: {:.5f}, batch accuracy: {:.5f}".format(batch_string, batch_loss, batch_accuracy)
print()
print("TRAINING STATS: {}".format(stats))
class Progress:
"""Text mode progress bar.
Usage:
p = Progress(30)
p.step()
p.step()
p.step(start=True) # to restart form 0%
The progress bar displays a new header at each restart."""
def __init__(self, maxi, size=100, msg=""):
"""
:param maxi: the number of steps required to reach 100%
:param size: the number of characters taken on the screen by the progress bar
:param msg: the message displayed in the header of the progress bat
"""
self.maxi = maxi
self.p = self.__start_progress(maxi)() # () to get the iterator from the generator
self.header_printed = False
self.msg = msg
self.size = size
def step(self, reset=False):
if reset:
self.__init__(self.maxi, self.size, self.msg)
if not self.header_printed:
self.__print_header()
next(self.p)
def __print_header(self):
print()
format_string = "0%{: ^" + str(self.size - 6) + "}100%"
print(format_string.format(self.msg))
self.header_printed = True
def __start_progress(self, maxi):
def print_progress():
# Bresenham's algorithm. Yields the number of dots printed.
# This will always print 100 dots in max invocations.
dx = maxi
dy = self.size
d = dy - dx
for x in range(maxi):
k = 0
while d >= 0:
print('=', end="", flush=True)
k += 1
d -= dx
d += dy
yield k
return print_progress
def read_data_files(directory, validation=True):
"""Read data files according to the specified glob pattern
Optionnaly set aside the last file as validation data.
No validation data is returned if there are 5 files or less.
:param directory: for example "data/*.txt"
:param validation: if True (default), sets the last file aside as validation data
:return: training data, validation data, list of loaded file names with ranges
If validation is
"""
codetext = []
bookranges = []
shakelist = glob.glob(directory, recursive=True)
for shakefile in shakelist:
shaketext = open(shakefile, "r")
print("Loading file " + shakefile)
start = len(codetext)
codetext.extend(encode_text(shaketext.read()))
end = len(codetext)
bookranges.append({"start": start, "end": end, "name": shakefile.rsplit("/", 1)[-1]})
shaketext.close()
if len(bookranges) == 0:
sys.exit("No training data has been found. Aborting.")
# For validation, use roughly 90K of text,
# but no more than 10% of the entire text
# and no more than 1 book in 5 => no validation at all for 5 files or fewer.
# 10% of the text is how many files ?
total_len = len(codetext)
validation_len = 0
nb_books1 = 0
for book in reversed(bookranges):
validation_len += book["end"]-book["start"]
nb_books1 += 1
if validation_len > total_len // 10:
break
# 90K of text is how many books ?
validation_len = 0
nb_books2 = 0
for book in reversed(bookranges):
validation_len += book["end"]-book["start"]
nb_books2 += 1
if validation_len > 90*1024:
break
# 20% of the books is how many books ?
nb_books3 = len(bookranges) // 5
# pick the smallest
nb_books = min(nb_books1, nb_books2, nb_books3)
if nb_books == 0 or not validation:
cutoff = len(codetext)
else:
cutoff = bookranges[-nb_books]["start"]
valitext = codetext[cutoff:]
codetext = codetext[:cutoff]
return codetext, valitext, bookranges
def print_data_stats(datalen, valilen, epoch_size):
datalen_mb = datalen/1024.0/1024.0
valilen_kb = valilen/1024.0
print("Training text size is {:.2f}MB with {:.2f}KB set aside for validation.".format(datalen_mb, valilen_kb)
+ " There will be {} batches per epoch".format(epoch_size))
def print_validation_header(validation_start, bookranges):
bookindex = find_book_index(validation_start, bookranges)
books = ''
for i in range(bookindex, len(bookranges)):
books += bookranges[i]["name"]
if i < len(bookranges)-1:
books += ", "
print("{: <60}".format("Validating on " + books), flush=True)
def print_validation_stats(loss, accuracy):
print("VALIDATION STATS: loss: {:.5f}, accuracy: {:.5f}".format(loss,
accuracy))
def print_text_generation_header():
print()
print("┌{:─^111}┐".format('Generating random text from learned state'))
def print_text_generation_footer():
print()
print("└{:─^111}┘".format('End of generation'))
def frequency_limiter(n, multiple=1, modulo=0):
def limit(i):
return i % (multiple * n) == modulo*multiple
return limit