char _Tamil.py

from tensorflow import keras
import numpy
from keras.models import Sequential
from keras.layers import Dense
from keras.layers import Dropout
from keras.layers import LSTM
from keras.callbacks import ModelCheckpoint
from keras.utils import np_utils
import sys
import codecs
import os
import math
import operator
import json
from functools import reduce
'''
# load ascii text and covert to lowercase
#filename = "wonderland.txt"
filename = "dataset.txt"
raw_text = open(filename).read()
raw_text = raw_text.lower()

# create mapping of unique chars to integers
chars = sorted(list(set(raw_text)))
char_to_int = dict((c, i) for i, c in enumerate(chars))

n_chars = len(raw_text)
n_vocab = len(chars)
print ("Total Characters: ", n_chars)
print ("Total Vocab: ", n_vocab)

# prepare the dataset of input to output pairs encoded as integers
seq_length = 100
dataX = []
dataY = []
for i in range(0, n_chars - seq_length, 1):
	seq_in = raw_text[i:i + seq_length]
	seq_out = raw_text[i + seq_length]
	dataX.append([char_to_int[char] for char in seq_in])
	dataY.append(char_to_int[seq_out])
n_patterns = len(dataX)
print ("Total Patterns: ", n_patterns)

# reshape X to be [samples, time steps, features]
X = numpy.reshape(dataX, (n_patterns, seq_length, 1))
# normalize
X = X / float(n_vocab)
# one hot encode the output variable
y = np_utils.to_categorical(dataY)

# define the LSTM model

model = Sequential()
model.add(LSTM(256, input_shape=(X.shape[1], X.shape[2]), return_sequences=True))
model.add(Dropout(0.2))
model.add(LSTM(256))
model.add(Dropout(0.2))
model.add(Dense(y.shape[1], activation='softmax'))
model.compile(loss='categorical_crossentropy', optimizer='adam')
'''
'''
# define the checkpoint
#filepath="weights-improvement-{epoch:02d}-{loss:.4f}.hdf5"
filepath="Tamilweights-improvement-{epoch:02d}-{loss:.4f}-big.hdf5"
checkpoint = ModelCheckpoint(filepath, monitor='loss', verbose=1, save_best_only=True, mode='min')
callbacks_list = [checkpoint]

model.fit(X, y, epochs=15, batch_size=128, callbacks=callbacks_list)
'''
'''
# load the network weights
filename = "weights-improvement-15-0.5110-big.hdf5"
model.load_weights(filename)
model.compile(loss='categorical_crossentropy', optimizer='adam')

int_to_char = dict((i, c) for i, c in enumerate(chars))

import sys
import numpy
out = open('output.txt', 'w')
# pick a random seed
for j in range(100):
  start = numpy.random.randint(0, len(dataX)-1)
  pattern = dataX[start]
  print ("\n")
  print ("\nSeed:")
  print ("\"", ''.join([int_to_char[value] for value in pattern]), "\"")
  # generate characters
  
  
  print("\nGenerated:")
  for i in range(160):
    x = numpy.reshape(pattern, (1, len(pattern), 1))
    x = x / float(n_vocab)
    prediction = model.predict(x, verbose=0)
    index = numpy.argmax(prediction)
    result = int_to_char[index]
    
    seq_in = [int_to_char[value] for value in pattern]
    
    out.write(str(result))
    
    sys.stdout.write(result)
    
    pattern.append(index)
    pattern = pattern[1:len(pattern)]

    
  
  #output_filename = 'output.txt'
  #save_doc(result, output_filename)
out.close()  
print( "\nDone.")

'''
def fetch_data(cand, ref):
    """ Store each reference and candidate sentences as a list """
    references = []
    if '.txt' in ref:
        reference_file = codecs.open(ref, 'r', 'utf-8')
        references.append(reference_file.readlines())
    else:
        for root, dirs, files in os.walk(ref):
            for f in files:
                reference_file = codecs.open(os.path.join(root, f), 'r', 'utf-8')
                references.append(reference_file.readlines())
    candidate_file = codecs.open(cand, 'r', 'utf-8')
    candidate = candidate_file.readlines()
    return candidate, references


def count_ngram(candidate, references, n):
    clipped_count = 0
    count = 0
    r = 0
    c = 0
    for si in range(len(candidate)):
        # Calculate precision for each sentence
        ref_counts = []
        ref_lengths = []
        # Build dictionary of ngram counts
        for reference in references:
            ref_sentence = reference[si]
            ngram_d = {}
            words = ref_sentence.strip().split()
            ref_lengths.append(len(words))
            limits = len(words) - n + 1
            # loop through the sentance consider the ngram length
            for i in range(limits):
                ngram = ' '.join(words[i:i+n]).lower()
                if ngram in ngram_d.keys():
                    ngram_d[ngram] += 1
                else:
                    ngram_d[ngram] = 1
            ref_counts.append(ngram_d)
        # candidate
        cand_sentence = candidate[si]
        cand_dict = {}
        words = cand_sentence.strip().split()
        limits = len(words) - n + 1
        for i in range(0, limits):
            ngram = ' '.join(words[i:i + n]).lower()
            if ngram in cand_dict:
                cand_dict[ngram] += 1
            else:
                cand_dict[ngram] = 1
        clipped_count += clip_count(cand_dict, ref_counts)
        count += limits
        r += best_length_match(ref_lengths, len(words))
        c += len(words)
    if clipped_count == 0:
        pr = 0
    else:
        pr = float(clipped_count) / count
    bp = brevity_penalty(c, r)
    return pr, bp


def clip_count(cand_d, ref_ds):
    """Count the clip count for each ngram considering all references"""
    count = 0
    for m in cand_d.keys():
        m_w = cand_d[m]
        m_max = 0
        for ref in ref_ds:
            if m in ref:
                m_max = max(m_max, ref[m])
        m_w = min(m_w, m_max)
        count += m_w
    return count


def best_length_match(ref_l, cand_l):
    """Find the closest length of reference to that of candidate"""
    least_diff = abs(cand_l-ref_l[0])
    best = ref_l[0]
    for ref in ref_l:
        if abs(cand_l-ref) < least_diff:
            least_diff = abs(cand_l-ref)
            best = ref
    return best


def brevity_penalty(c, r):
    if c > r:
        bp = 1
    else:
        bp = math.exp(1-(float(r)/c))
    return bp


def geometric_mean(precisions):
    return (reduce(operator.mul, precisions)) ** (1.0 / len(precisions))


def BLEU(candidate, references):
    precisions = []
    for i in range(1):
        pr, bp = count_ngram(candidate, references, i+1)
        precisions.append(pr)
    bleu = geometric_mean(precisions) * bp
    return bleu


#candidate, references = fetch_data(sys.argv[1], sys.argv[2])
candidate, references = fetch_data('generated.txt','dataset.txt')
bleu = BLEU(candidate, references)
print(bleu)
out = open('bleu_out.txt', 'w')
out.write(str(bleu))
out.close()