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| import streamlit as st | |
| from keras.layers import LSTM, Dropout, Bidirectional, Dense,Embedding,Flatten,Maximum,Activation,Conv2D,LayerNormalization,add\ | |
| , BatchNormalization, SpatialDropout1D ,Input,Layer,Multiply,Reshape ,Add, GRU,Concatenate,Conv1D,TimeDistributed,ZeroPadding1D,concatenate,MaxPool1D,GlobalMaxPooling1D | |
| import keras.backend as K | |
| from keras import initializers, regularizers, constraints, activations | |
| from keras.initializers import Constant | |
| from keras import Model | |
| import sys | |
| import json | |
| import pandas as pd | |
| import numpy as np | |
| with open('CHAR_TYPES_MAP.json') as json_file: | |
| CHAR_TYPES_MAP = json.load(json_file) | |
| with open('CHARS_MAP.json') as json_file: | |
| CHARS_MAP = json.load(json_file) | |
| with open('CHAR_TYPE_FLATTEN.json') as json_file: | |
| CHAR_TYPE_FLATTEN = json.load(json_file) | |
| class TimestepDropout(Dropout): | |
| def __init__(self, rate, **kwargs): | |
| super(TimestepDropout, self).__init__(rate, **kwargs) | |
| def _get_noise_shape(self, inputs): | |
| input_shape = K.shape(inputs) | |
| noise_shape = (input_shape[0], input_shape[1], 1) | |
| return noise_shape | |
| def model_(n_gram = 21): | |
| input1 = Input(shape=(21,),dtype='float32',name = 'char_input') | |
| input2 = Input(shape=(21,),dtype='float32',name = 'type_input') | |
| a = Embedding(178, 32)(input1) | |
| a = SpatialDropout1D(0.15)(a) | |
| #a = TimestepDropout(0.05)(a) | |
| char_input = BatchNormalization()(a) | |
| a_concat = [] | |
| filters = [[1,200],[2,200],[3,200],[4,200],[5,200],[6,200],[8,200],[11,150],[12,100]] | |
| #filters = [[1,200],[2,200],[3,200],[4,200],[5,200],[6,200],[7,200],[8,200],[9,150],[10,150],[11,150],[12,100]] | |
| for (window_size, filters_size) in filters: | |
| convs = Conv1D(filters=filters_size, kernel_size=window_size, strides=1)(char_input) | |
| convs = Activation('elu')(convs) | |
| convs = TimeDistributed(Dense(5, input_shape=(21, filters_size)))(convs) | |
| convs = ZeroPadding1D(padding=(0, window_size-1))(convs) | |
| a_concat.append(convs) | |
| token_max = Maximum()(a_concat) | |
| lstm_char = Bidirectional(LSTM(128 ,return_sequences=True,kernel_regularizer=regularizers.L2(0.0000001),bias_regularizer=regularizers.L2(0.0000001)))(char_input) | |
| lstm_char = Dense(64, activation='elu')(lstm_char) | |
| #lstm_char = Bidirectional(LSTM(64 ,return_sequences=True))(lstm_char) | |
| #lstm_char = Attention(return_sequences=True)(lstm_char) | |
| b = Embedding(12, 12)(input2) | |
| type_inputs = SpatialDropout1D(0.15)(b) | |
| #type_inputs = TimestepDropout(0.05)(b) | |
| x = Concatenate()([type_inputs, char_input, lstm_char, token_max]) | |
| x = BatchNormalization()(x) | |
| x = Flatten()(x) | |
| x = Dense(100, activation='elu')(x) | |
| x = Dropout(0.2)(x) | |
| out = Dense(1, activation='sigmoid',dtype = 'float32',kernel_regularizer=regularizers.L2(0.01),bias_regularizer=regularizers.L2(0.01))(x) | |
| model = Model(inputs=[input1, input2], outputs=out) | |
| return model | |
| def create_feature_array(text, n_pad=21): | |
| n = len(text) | |
| n_pad_2 = int((n_pad - 1)/2) | |
| text_pad = [' '] * n_pad_2 + [t for t in text] + [' '] * n_pad_2 | |
| x_char, x_type = [], [] | |
| for i in range(n_pad_2, n_pad_2 + n): | |
| char_list = text_pad[i + 1: i + n_pad_2 + 1] + \ | |
| list(reversed(text_pad[i - n_pad_2: i])) + \ | |
| [text_pad[i]] | |
| char_map = [CHARS_MAP.get(c, 179) for c in char_list] | |
| char_type = [CHAR_TYPES_MAP.get(CHAR_TYPE_FLATTEN.get(c, 'o'), 4) | |
| for c in char_list] | |
| x_char.append(char_map) | |
| x_type.append(char_type) | |
| x_char = np.array(x_char).astype(float) | |
| x_type = np.array(x_type).astype(float) | |
| return x_char, x_type | |
| def tokenize(text): | |
| n_pad = 21 | |
| if not text: | |
| return [''] | |
| if isinstance(text, str) and sys.version_info.major == 2: | |
| text = text.decode('utf-8') | |
| x_char, x_type = create_feature_array(text, n_pad=n_pad) | |
| word_end = [] | |
| y_predict = model.predict([x_char, x_type], batch_size = 512) | |
| y_predict = (y_predict.ravel() > 0.46542968749999997).astype(int) | |
| word_end = y_predict[1:].tolist() + [1] | |
| tokens = [] | |
| word = '' | |
| for char, w_e in zip(text, word_end): | |
| word += char | |
| if w_e: | |
| tokens.append(word) | |
| word = '' | |
| return tokens | |
| model = model_() | |
| model.load_weights("cutto_tf2.h5") | |
| st.title("Cutto Thai word seggmentation.") | |
| text = st.text_area("Enter original text!") | |
| if st.button("cut it!!"): | |
| if text: | |
| words = tokenize(text) | |
| st.subheader("Answer:") | |
| st.write('|'.join(words)) | |
| else: | |
| st.warning("Please enter some text to seggmentation") | |
| multi = '''### Score | |
| Evaluate the model performance using the test dataset divided from BEST CORPUS 2009, which comprises 10 percent, with the following scores: | |
| - F1-Score: 98.37 | |
| - Precision: 98.02 | |
| - Recall: 98.67 | |
| ### Resource Funding | |
| NSTDA Supercomputer center (ThaiSC) and the National e-Science Infrastructure Consortium for their support of computer facilities. | |
| ### Citation | |
| If you use cutto in your project or publication, please cite the model as follows: | |
| ''' | |
| st.markdown(multi) | |
| st.code(f""" | |
| ปรีชานนท์ ชาติไทย และ สัจจวัจน์ ส่งเสริม. (2567), | |
| การสรุปข้อความข่าวภาษาไทยด้วยโครงข่ายประสาทเทียม (Thai News Text Summarization Using Neural Network), | |
| วิทยาศาสตรบัณฑิต (วทบ.):ขอนแก่น, มหาวิทยาลัยขอนแก่น) | |
| """) | |