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DECODA_binary_BOW_AEINIT_TANH_MODELS.py 10.2 KB
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b6d0165d1   Killian   Initial commit 
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  # coding: utf-8
  
  # In[2]:
  
  # Import
  import pandas
  # Alignement
  from alignment.sequence import Sequence
  from alignment.vocabulary import Vocabulary
  from alignment.sequencealigner import *
  import nltk
  import codecs
  import gensim
  from scipy import sparse
  import itertools
  from sklearn.feature_extraction.text import CountVectorizer
  import scipy.sparse
  import scipy.io
  from sklearn import preprocessing
  from keras.models import Sequential
  from keras.layers.core import Dense, Dropout, Activation,AutoEncoder
  from keras.optimizers import SGD,Adam
  from keras.layers import containers
  from mlp import *
  import mlp
  import sklearn.metrics
  import shelve
  import pickle
  from utils import *
  import sys
  # In[4]:
  
  db=shelve.open("{}.shelve".format(sys.argv[1]),writeback=True)
  
  sparse_corp=shelve.open("DECODA_sparse.shelve")
  # In[6]:
  ASR_sparse=sparse_corp["ASR_SPARSE"]
  TRS_sparse=sparse_corp["TRS_SPARSE"]
  
  # In[11]:
  hidden_size=3096
  hidden_size2=2048
  input_activation="tanh"
  out_activation="tanh"
  loss="mse"
  epochs=500
  batch=128
  patience=40
  
  print "gogo autoencoder ASR"
  sgd = SGD(lr=0.0001)#, momentum=0.9, nesterov=True)
  autoencode=Sequential()
  autoencode.add(Dense(ASR_sparse["TRAIN"].shape[1],hidden_size,init='glorot_uniform',activation=input_activation))
  autoencode.add(Dense(hidden_size,hidden_size2,init='glorot_uniform',activation=input_activation))
  autoencode.add(Dense(hidden_size2,hidden_size,init="glorot_uniform",activation=out_activation))
  autoencode.add(Dense(hidden_size,ASR_sparse["DEV"].todense().shape[1],init="glorot_uniform",activation=out_activation))
  
  #autoencode.compile(optimizer=sgd,loss=loss)
  
  autoencode.compile(optimizer=sgd,loss=loss)
  
  
  # In[ ]:
  
  autoencode.fit(ASR_sparse["TRAIN"].todense(),ASR_sparse["TRAIN"].todense(),nb_epoch=epochs,batch_size=batch,
                 callbacks=[keras.callbacks.EarlyStopping(monitor='val_loss',
                                                          patience=patience, verbose=0)],           validation_data=(ASR_sparse["DEV"].todense(),ASR_sparse["DEV"].todense()),verbose=1)
  
  
  # In[ ]:
  
  auto_decoder=Sequential()
  auto_decoder.add(Dense(ASR_sparse["DEV"].todense().shape[1],hidden_size,init='uniform',activation=input_activation,weights=autoencode.get_weights()[:2]))
  auto_decoder.add(Dense(hidden_size,hidden_size2,init='glorot_uniform',activation=input_activation,weights=autoencode.get_weights()[2:4]))
  auto_decoder.add(Dense(hidden_size2,hidden_size,init='glorot_uniform',activation=input_activation,weights=autoencode.get_weights()[4:6]))
  auto_decoder.compile(optimizer=sgd,loss=loss)
  
  
  # In[77]:
  
  #autoencode.predict(ASR_sparse["DEV"].todense())
  
  
  # In[ ]:
  
  print "auto encoder et auto decoder asr okay"
  
  ASR_sparse_AE={}
  for i in ASR_sparse.keys():
      ASR_sparse_AE[i]=auto_decoder.predict(ASR_sparse[i].todense())
      #TRS_sparse[i]=dico.transform(TRS[i][2])
  
  db["ASR_AE_H2_RELU"]=ASR_sparse_AE
  
  
  auto_decoder=Sequential()
  auto_decoder.add(Dense(ASR_sparse["DEV"].todense().shape[1],hidden_size,init='uniform',activation=input_activation,weights=autoencode.get_weights()[:2]))
  auto_decoder.add(Dense(hidden_size,hidden_size2,init='glorot_uniform',activation=input_activation,weights=autoencode.get_weights()[2:4]))
  auto_decoder.compile(optimizer=sgd,loss=loss)
  
  ASR_sparse_AE_H1={}
  for i in ASR_sparse.keys():
      ASR_sparse_AE_H1[i]=auto_decoder.predict(ASR_sparse[i].todense())
      #TRS_sparse[i]=dico.transform(TRS[i][2])
  
  db["ASR_AE_H1_RELU"]=ASR_sparse_AE_H1
  
  
  
  print "auto encoder trs learning"
  # In[68]:/
  sgd_trs = SGD(lr=0.1,momentum=0.9)
  autoencode_trs=Sequential()
  autoencode_trs.add(Dense(TRS_sparse["DEV"].todense().shape[1],hidden_size,init='glorot_uniform',activation=input_activation))
  autoencode_trs.add(Dense(hidden_size,hidden_size2,init='glorot_uniform',activation=input_activation))
  autoencode_trs.add(Dense(hidden_size2,hidden_size,init="glorot_uniform",activation=out_activation))
  autoencode_trs.add(Dense(hidden_size,TRS_sparse["DEV"].todense().shape[1],init="glorot_uniform",activation=out_activation))
  
  #autoencode_trs.compile(optimizer=sgd_trs,loss=loss)
  
  autoencode_trs.compile(optimizer=sgd,loss=loss)
  
  
  # In[69]:
  
  autoencode_trs.fit(TRS_sparse["TRAIN"].todense(),TRS_sparse["TRAIN"].todense(),nb_epoch=epochs,batch_size=batch,
                 callbacks=[keras.callbacks.EarlyStopping(monitor='val_loss',
                                                          patience=patience, verbose=0)],
                 validation_data=(TRS_sparse["DEV"].todense(),TRS_sparse["DEV"].todense()),verbose=1)
  
  
  # In[87]:
  
  auto_decoder_trs=Sequential()
  auto_decoder_trs.add(Dense(ASR_sparse["DEV"].todense().shape[1],hidden_size,activation=input_activation,weights=autoencode_trs.get_weights()[:2]))
  auto_decoder_trs.add(Dense(hidden_size,hidden_size2,activation=input_activation,weights=autoencode_trs.get_weights()[2:4]))
  auto_decoder_trs.add(Dense(hidden_size2,hidden_size,activation=input_activation,weights=autoencode_trs.get_weights()[4:6]))
  auto_decoder_trs.compile(optimizer=sgd,loss=loss)
  
  
  # In[88]:
  print "auto encoder trs okay"
  TRS_sparse_AE={}
  
  for i in TRS_sparse.keys():
      TRS_sparse_AE[i]=auto_decoder_trs.predict(TRS_sparse[i].todense())
      #TRS_sparse[i]=dico.transform(TRS[i][2])
  
  db["TRS_AE_H2_RELU"]=TRS_sparse_AE
  
  
  
  auto_decoder_trs=Sequential()
  auto_decoder_trs.add(Dense(ASR_sparse["DEV"].todense().shape[1],hidden_size,activation=input_activation,weights=autoencode_trs.get_weights()[:2]))
  auto_decoder_trs.add(Dense(hidden_size,hidden_size2,activation=input_activation,weights=autoencode_trs.get_weights()[2:4]))
  auto_decoder_trs.compile(optimizer=sgd,loss=loss)
  
  
  # In[88]:
  print "auto encoder trs okay"
  TRS_sparse_AE_H1={}
  
  for i in TRS_sparse.keys():
      TRS_sparse_AE_H1[i]=auto_decoder_trs.predict(TRS_sparse[i].todense())
      #TRS_sparse[i]=dico.transform(TRS[i][2])
  
  db["TRS_AE_H1_RELU"]=TRS_sparse_AE
  
  
  db.sync()
  
  
  
  
  # In[261]:
  
  #pred_dev= model_TRS_AE.predict(TRS_sparse_AE["DEV"],batch_size=1)
  
  TRS_AE={}
  ASR_AE={}
  for i in TRS_sparse.keys():
      TRS_AE[i]=autoencode_trs.predict(TRS_sparse[i].todense())
      ASR_AE[i]=autoencode.predict(ASR_sparse[i].todense())
  
  
  db["TRS_AE_OUT_RELU"]=TRS_AE
  db["ASR_AE_OUT_RELU"]=ASR_AE
  
  db.sync()
  # # Transfert de couche
  # ICI
  spe_finetune=Sequential()
  spe_finetune.add(Dense(TRS_sparse["DEV"].todense().shape[1],hidden_size,init='glorot_uniform',activation=input_activation,weights=autoencode.get_weights()[:2]))
  spe_finetune.add(Dense(hidden_size,hidden_size2,init='glorot_uniform',activation=input_activation,weights=autoencode.get_weights()[2:4]))
  spe_finetune.add(Dense(hidden_size2,hidden_size,init="glorot_uniform",activation=out_activation,weights=autoencode_trs.get_weights()[4:6]))
  spe_finetune.add(Dense(hidden_size,TRS_sparse["DEV"].todense().shape[1],init="glorot_uniform",activation=out_activation,weights=autoencode_trs.get_weights()[6:8]))
  
  #spe_finetune.compile(optimizer=sgd_trs,loss=loss)
  
  spe_finetune.compile(optimizer=sgd,loss=loss)
  
  
  auto_decoder_spe_finetune=Sequential()
  auto_decoder_spe_finetune.add(Dense(ASR_sparse["DEV"].todense().shape[1],hidden_size,activation=input_activation,weights=autoencode.get_weights()[:2]))
  auto_decoder_spe_finetune.add(Dense(hidden_size,hidden_size2,activation=input_activation,weights=autoencode.get_weights()[2:4]))
  auto_decoder_spe_finetune.add(Dense(hidden_size2,hidden_size,init="glorot_uniform",activation=out_activation,weights=autoencode_trs.get_weights()[4:6]))
  auto_decoder_spe_finetune.compile(optimizer=sgd,loss=loss)
  
  
  
  spe_finetune_fixed=Sequential()
  spe_finetune_fixed.add(Dense(hidden_size2,hidden_size,init="glorot_uniform",activation=out_activation,weights=autoencode_trs.get_weights()[4:6]))
  spe_finetune_fixed.add(Dense(hidden_size,TRS_sparse["DEV"].todense().shape[1],init="glorot_uniform",activation=out_activation,weights=autoencode_trs.get_weights()[6:8]))
  spe_finetune_fixed.compile(optimizer=sgd,loss=loss)
  
  
  # In[88]:
  print "auto encoder SPE RAW OKAY"
  ASR_AE_SPE_FINETUNE_RAW_OUT={}
  ASR_AE_SPE_FINETUNE_RAW_H2={}
  ASR_AE_SPE_FINETUNE_RAW_FIXED_OUT={}
  for i in TRS_sparse.keys():
      ASR_AE_SPE_FINETUNE_RAW_OUT[i]=spe_finetune.predict(ASR_sparse[i].todense())
      #TRS_sparse[i]=dico.transform(TRS[i][2])
      ASR_AE_SPE_FINETUNE_RAW_H2[i]=auto_decoder_spe_finetune.predict(ASR_sparse[i].todense())
      ASR_AE_SPE_FINETUNE_RAW_FIXED_OUT[i]=spe_finetune_fixed.predict(ASR_sparse_AE_H1[i])
  
  db["ASR_AE_SPE_FINETUNE_RAW_OUT"]=ASR_AE_SPE_FINETUNE_RAW_OUT
  db["ASR_AE_SPE_FINETUNE_RAW_H2"]=ASR_AE_SPE_FINETUNE_RAW_H2
  db["ASR_AE_SPE_FINETUNE_RAW_FIXED_OUT"]=ASR_AE_SPE_FINETUNE_RAW_FIXED_OUT
  db.sync()
  
  
  spe_finetune.fit(ASR_sparse["TRAIN"].todense(),TRS_sparse["TRAIN"].todense(),nb_epoch=epochs,batch_size=batch,
                 callbacks=[keras.callbacks.EarlyStopping(monitor='val_loss',
                                                          patience=patience, verbose=0)],           validation_data=(ASR_sparse["DEV"].todense(),TRS_sparse["DEV"].todense()),verbose=1)
  
  
  
  auto_decoder_spe_finetune=Sequential()
  auto_decoder_spe_finetune.add(Dense(ASR_sparse["DEV"].todense().shape[1],hidden_size,activation=input_activation,weights=spe_finetune.get_weights()[:2]))
  auto_decoder_spe_finetune.add(Dense(hidden_size,hidden_size2,activation=input_activation,weights=spe_finetune.get_weights()[2:4]))
  auto_decoder_spe_finetune.add(Dense(hidden_size2,hidden_size,init="glorot_uniform",activation=out_activation,weights=spe_finetune.get_weights()[4:6]))
  auto_decoder_spe_finetune.compile(optimizer=sgd,loss=loss)
  
  
  ASR_sparse_AE_H1[i]
  
  
  spe_finetune_fixed.fit(ASR_sparse_AE_H1["TRAIN"],TRS_sparse["TRAIN"].todense(),nb_epoch=epochs,batch_size=batch,callbacks=[keras.callbacks.EarlyStopping(monitor='val_loss',
      patience=patience, verbose=0)],
      validation_data=(ASR_sparse_AE_H1["DEV"],TRS_sparse["DEV"].todense()),verbose=1)
  
  
  ASR_AE_SPE_FINETUNE_TUNED_OUT={}
  ASR_AE_SPE_FINETUNE_TUNED_H2={}
  ASR_AE_SPE_FINETUNE_TUNED_FIXED_OUT={}
  
  for i in TRS_sparse.keys():
      ASR_AE_SPE_FINETUNE_TUNED_OUT[i]=spe_finetune.predict(ASR_sparse[i].todense())
      #TRS_sparse[i]=dico.transform(TRS[i][2])
      ASR_AE_SPE_FINETUNE_TUNED_H2[i]=auto_decoder_spe_finetune.predict(ASR_sparse[i].todense())
      ASR_AE_SPE_FINETUNE_TUNED_FIXED_OUT[i]=spe_finetune_fixed.predict(ASR_sparse_AE_H1[i])
  db["ASR_AE_SPE_FINETUNE_TUNED_OUT"]=ASR_AE_SPE_FINETUNE_RAW_OUT
  db["ASR_AE_SPE_FINETUNE_TUNED_H2"]=ASR_AE_SPE_FINETUNE_RAW_H2
  db["ASR_AE_SPE_FINETUNE_TUNED_FIXED_OUT"]=ASR_AE_SPE_FINETUNE_RAW_FIXED_OUT
  
  db.sync()
  db.close()