main_parse.py

# -*- coding: utf-8 -*-
# @Author: Jie
# @Date:   2017-06-15 14:11:08
# @Last Modified by:   Jie Yang,     Contact: jieynlp@gmail.com
# @Last Modified time: 2018-04-26 12:59:38

import time
import sys
import argparse
import random
import copy
import torch
import gc
import cPickle as pickle
import torch.autograd as autograd
import torch.nn as nn
import torch.nn.functional as F
import torch.optim as optim
import numpy as np
from utils.metric import get_ner_fmeasure
from model.seqmodel import SeqModel
from utils.data import Data

seed_num = 42
random.seed(seed_num)
torch.manual_seed(seed_num)
np.random.seed(seed_num)


def data_initialization(data):
    data.initial_feature_alphabets()
    data.build_alphabet(data.train_dir)
    data.build_alphabet(data.dev_dir)
    data.build_alphabet(data.test_dir)
    data.fix_alphabet()


def predict_check(pred_variable, gold_variable, mask_variable):
    """
        input:
            pred_variable (batch_size, sent_len): pred tag result, in numpy format
            gold_variable (batch_size, sent_len): gold result variable
            mask_variable (batch_size, sent_len): mask variable
    """
    pred = pred_variable.cpu().data.numpy()
    gold = gold_variable.cpu().data.numpy()
    mask = mask_variable.cpu().data.numpy()
    overlaped = (pred == gold)
    right_token = np.sum(overlaped * mask)
    total_token = mask.sum()
    # print("right: %s, total: %s"%(right_token, total_token))
    return right_token, total_token


def recover_label(pred_variable, gold_variable, mask_variable, label_alphabet, word_recover):
    """
        input:
            pred_variable (batch_size, sent_len): pred tag result
            gold_variable (batch_size, sent_len): gold result variable
            mask_variable (batch_size, sent_len): mask variable
    """
    
    pred_variable = pred_variable[word_recover]
    gold_variable = gold_variable[word_recover]
    mask_variable = mask_variable[word_recover]
    batch_size = gold_variable.size(0)
    seq_len = gold_variable.size(1)
    mask = mask_variable.cpu().data.numpy()
    pred_tag = pred_variable.cpu().data.numpy()
    gold_tag = gold_variable.cpu().data.numpy()
    batch_size = mask.shape[0]
    pred_label = []
    gold_label = []
    for idx in range(batch_size):
        pred = [label_alphabet.get_instance(pred_tag[idx][idy]) for idy in range(seq_len) if mask[idx][idy] != 0]
        gold = [label_alphabet.get_instance(gold_tag[idx][idy]) for idy in range(seq_len) if mask[idx][idy] != 0]
        # print "p:",pred, pred_tag.tolist()
        # print "g:", gold, gold_tag.tolist()
        assert(len(pred)==len(gold))
        pred_label.append(pred)
        gold_label.append(gold)
    return pred_label, gold_label


def recover_nbest_label(pred_variable, mask_variable, label_alphabet, word_recover):
    """
        input:
            pred_variable (batch_size, sent_len, nbest): pred tag result
            mask_variable (batch_size, sent_len): mask variable
            word_recover (batch_size)
        output:
            nbest_pred_label list: [batch_size, nbest, each_seq_len]
    """
    # print "word recover:", word_recover.size()
    # exit(0)
    pred_variable = pred_variable[word_recover]
    mask_variable = mask_variable[word_recover]
    batch_size = pred_variable.size(0)
    seq_len = pred_variable.size(1)
    print pred_variable.size()
    nbest = pred_variable.size(2)
    mask = mask_variable.cpu().data.numpy()
    pred_tag = pred_variable.cpu().data.numpy()
    batch_size = mask.shape[0]
    pred_label = []
    for idx in range(batch_size):
        pred = []
        for idz in range(nbest):
            each_pred = [label_alphabet.get_instance(pred_tag[idx][idy][idz]) for idy in range(seq_len) if mask[idx][idy] != 0]
            pred.append(each_pred)
        pred_label.append(pred)
    return pred_label



# def save_data_setting(data, save_file):
#     new_data = copy.deepcopy(data)
#     ## remove input instances
#     new_data.train_texts = []
#     new_data.dev_texts = []
#     new_data.test_texts = []
#     new_data.raw_texts = []

#     new_data.train_Ids = []
#     new_data.dev_Ids = []
#     new_data.test_Ids = []
#     new_data.raw_Ids = []
#     ## save data settings
#     with open(save_file, 'w') as fp:
#         pickle.dump(new_data, fp)
#     print "Data setting saved to file: ", save_file


# def load_data_setting(save_file):
#     with open(save_file, 'r') as fp:
#         data = pickle.load(fp)
#     print "Data setting loaded from file: ", save_file
#     data.show_data_summary()
#     return data

def lr_decay(optimizer, epoch, decay_rate, init_lr):
    lr = init_lr/(1+decay_rate*epoch)
    print " Learning rate is setted as:", lr
    for param_group in optimizer.param_groups:
        param_group['lr'] = lr
    return optimizer



def evaluate(data, model, name, nbest=None):
    if name == "train":
        instances = data.train_Ids
    elif name == "dev":
        instances = data.dev_Ids
    elif name == 'test':
        instances = data.test_Ids
    elif name == 'raw':
        instances = data.raw_Ids
    else:
        print "Error: wrong evaluate name,", name
    right_token = 0
    whole_token = 0
    nbest_pred_results = []
    pred_scores = []
    pred_results = []
    gold_results = []
    ## set model in eval model
    model.eval()
    batch_size = data.HP_batch_size
    start_time = time.time()
    train_num = len(instances)
    total_batch = train_num//batch_size+1
    for batch_id in range(total_batch):
        start = batch_id*batch_size
        end = (batch_id+1)*batch_size 
        if end > train_num:
            end =  train_num
        instance = instances[start:end]
        if not instance:
            continue
        batch_word, batch_features, batch_wordlen, batch_wordrecover, batch_char, batch_charlen, batch_charrecover, batch_label, mask  = batchify_with_label(instance, data.HP_gpu, True)
        if nbest:
            scores, nbest_tag_seq = model.decode_nbest(batch_word,batch_features, batch_wordlen, batch_char, batch_charlen, batch_charrecover, mask, nbest)
            nbest_pred_result = recover_nbest_label(nbest_tag_seq, mask, data.label_alphabet, batch_wordrecover)
            nbest_pred_results += nbest_pred_result 
            pred_scores += scores[batch_wordrecover].cpu().data.numpy().tolist()
            ## select the best sequence to evalurate
            tag_seq = nbest_tag_seq[:,:,0]
        else:
            tag_seq = model(batch_word, batch_features, batch_wordlen, batch_char, batch_charlen, batch_charrecover, mask)
        # print "tag:",tag_seq
        pred_label, gold_label = recover_label(tag_seq, batch_label, mask, data.label_alphabet, batch_wordrecover)
        pred_results += pred_label
        gold_results += gold_label
    decode_time = time.time() - start_time
    speed = len(instances)/decode_time
    acc, p, r, f = get_ner_fmeasure(gold_results, pred_results, data.tagScheme)
    if nbest:
        return speed, acc, p, r, f, nbest_pred_results, pred_scores
    return speed, acc, p, r, f, pred_results, pred_scores


def batchify_with_label(input_batch_list, gpu, volatile_flag=False):
    """
        input: list of words, chars and labels, various length. [[words,chars, labels],[words,chars,labels],...]
            words: word ids for one sentence. (batch_size, sent_len) 
            chars: char ids for on sentences, various length. (batch_size, sent_len, each_word_length)
        output:
            zero padding for word and char, with their batch length
            word_seq_tensor: (batch_size, max_sent_len) Variable
            word_seq_lengths: (batch_size,1) Tensor
            char_seq_tensor: (batch_size*max_sent_len, max_word_len) Variable
            char_seq_lengths: (batch_size*max_sent_len,1) Tensor
            char_seq_recover: (batch_size*max_sent_len,1)  recover char sequence order 
            label_seq_tensor: (batch_size, max_sent_len)
            mask: (batch_size, max_sent_len) 
    """
    batch_size = len(input_batch_list)
    words = [sent[0] for sent in input_batch_list]
    features = [np.asarray(sent[1]) for sent in input_batch_list]
    feature_num = len(features[0][0])
    chars = [sent[2] for sent in input_batch_list]
    labels = [sent[3] for sent in input_batch_list]
    word_seq_lengths = torch.LongTensor(map(len, words))
    max_seq_len = word_seq_lengths.max()
    word_seq_tensor = autograd.Variable(torch.zeros((batch_size, max_seq_len)), volatile =  volatile_flag).long()
    label_seq_tensor = autograd.Variable(torch.zeros((batch_size, max_seq_len)),volatile =  volatile_flag).long()
    feature_seq_tensors = []
    for idx in range(feature_num):
        feature_seq_tensors.append(autograd.Variable(torch.zeros((batch_size, max_seq_len)),volatile =  volatile_flag).long())
    mask = autograd.Variable(torch.zeros((batch_size, max_seq_len)),volatile =  volatile_flag).byte()
    for idx, (seq, label, seqlen) in enumerate(zip(words, labels, word_seq_lengths)):
        word_seq_tensor[idx, :seqlen] = torch.LongTensor(seq)
        label_seq_tensor[idx, :seqlen] = torch.LongTensor(label)
        mask[idx, :seqlen] = torch.Tensor([1]*seqlen)
        for idy in range(feature_num):
            feature_seq_tensors[idy][idx,:seqlen] = torch.LongTensor(features[idx][:,idy])
    word_seq_lengths, word_perm_idx = word_seq_lengths.sort(0, descending=True)
    word_seq_tensor = word_seq_tensor[word_perm_idx]
    for idx in range(feature_num):
        feature_seq_tensors[idx] = feature_seq_tensors[idx][word_perm_idx]

    label_seq_tensor = label_seq_tensor[word_perm_idx]
    mask = mask[word_perm_idx]
    ### deal with char
    # pad_chars (batch_size, max_seq_len)
    pad_chars = [chars[idx] + [[0]] * (max_seq_len-len(chars[idx])) for idx in range(len(chars))]
    length_list = [map(len, pad_char) for pad_char in pad_chars]
    max_word_len = max(map(max, length_list))
    char_seq_tensor = autograd.Variable(torch.zeros((batch_size, max_seq_len, max_word_len)), volatile =  volatile_flag).long()
    char_seq_lengths = torch.LongTensor(length_list)
    for idx, (seq, seqlen) in enumerate(zip(pad_chars, char_seq_lengths)):
        for idy, (word, wordlen) in enumerate(zip(seq, seqlen)):
            # print len(word), wordlen
            char_seq_tensor[idx, idy, :wordlen] = torch.LongTensor(word)
    
    char_seq_tensor = char_seq_tensor[word_perm_idx].view(batch_size*max_seq_len,-1)
    char_seq_lengths = char_seq_lengths[word_perm_idx].view(batch_size*max_seq_len,)
    char_seq_lengths, char_perm_idx = char_seq_lengths.sort(0, descending=True)
    char_seq_tensor = char_seq_tensor[char_perm_idx]
    _, char_seq_recover = char_perm_idx.sort(0, descending=False)
    _, word_seq_recover = word_perm_idx.sort(0, descending=False)
    if gpu:
        word_seq_tensor = word_seq_tensor.cuda()
        for idx in range(feature_num):
            feature_seq_tensors[idx] = feature_seq_tensors[idx].cuda()
        word_seq_lengths = word_seq_lengths.cuda()
        word_seq_recover = word_seq_recover.cuda()
        label_seq_tensor = label_seq_tensor.cuda()
        char_seq_tensor = char_seq_tensor.cuda()
        char_seq_recover = char_seq_recover.cuda()
        mask = mask.cuda()
    return word_seq_tensor,feature_seq_tensors, word_seq_lengths, word_seq_recover, char_seq_tensor, char_seq_lengths, char_seq_recover, label_seq_tensor, mask


def train(data):
    print "Training model..."
    data.show_data_summary()
    save_data_name = data.model_dir +".dset"
    data.save(save_data_name)
    model = SeqModel(data)
    loss_function = nn.NLLLoss()
    if data.optimizer.lower() == "sgd":
        optimizer = optim.SGD(model.parameters(), lr=data.HP_lr, momentum=data.HP_momentum,weight_decay=data.HP_l2)
    elif data.optimizer.lower() == "adagrad":
        optimizer = optim.Adagrad(model.parameters(), lr=data.HP_lr, weight_decay=data.HP_l2)
    elif data.optimizer.lower() == "adadelta":
        optimizer = optim.Adadelta(model.parameters(), lr=data.HP_lr, weight_decay=data.HP_l2)
    elif data.optimizer.lower() == "rmsprop":
        optimizer = optim.RMSprop(model.parameters(), lr=data.HP_lr, weight_decay=data.HP_l2)
    elif data.optimizer.lower() == "adam":
        optimizer = optim.Adam(model.parameters(), lr=data.HP_lr, weight_decay=data.HP_l2)
    else:
        print("Optimizer illegal: %s"%(data.optimizer))
        exit(0)
    best_dev = -10
    # data.HP_iteration = 1
    ## start training
    for idx in range(data.HP_iteration):
        epoch_start = time.time()
        temp_start = epoch_start
        print("Epoch: %s/%s" %(idx,data.HP_iteration))
        if data.optimizer == "SGD":
            optimizer = lr_decay(optimizer, idx, data.HP_lr_decay, data.HP_lr)
        instance_count = 0
        sample_id = 0
        sample_loss = 0
        total_loss = 0
        right_token = 0
        whole_token = 0
        random.shuffle(data.train_Ids)
        ## set model in train model
        model.train()
        model.zero_grad()
        batch_size = data.HP_batch_size
        batch_id = 0
        train_num = len(data.train_Ids)
        total_batch = train_num//batch_size+1
        for batch_id in range(total_batch):
            start = batch_id*batch_size
            end = (batch_id+1)*batch_size 
            if end >train_num:
                end = train_num
            instance = data.train_Ids[start:end]
            if not instance:
                continue
            batch_word, batch_features, batch_wordlen, batch_wordrecover, batch_char, batch_charlen, batch_charrecover, batch_label, mask  = batchify_with_label(instance, data.HP_gpu)
            instance_count += 1
            loss, tag_seq = model.neg_log_likelihood_loss(batch_word,batch_features, batch_wordlen, batch_char, batch_charlen, batch_charrecover, batch_label, mask)
            right, whole = predict_check(tag_seq, batch_label, mask)
            right_token += right
            whole_token += whole
            sample_loss += loss.data[0]
            total_loss += loss.data[0]
            if end%500 == 0:
                temp_time = time.time()
                temp_cost = temp_time - temp_start
                temp_start = temp_time
                print("     Instance: %s; Time: %.2fs; loss: %.4f; acc: %s/%s=%.4f"%(end, temp_cost, sample_loss, right_token, whole_token,(right_token+0.)/whole_token))
                sys.stdout.flush()
                sample_loss = 0
            loss.backward()
            optimizer.step()
            model.zero_grad()
        temp_time = time.time()
        temp_cost = temp_time - temp_start
        print("     Instance: %s; Time: %.2fs; loss: %.4f; acc: %s/%s=%.4f"%(end, temp_cost, sample_loss, right_token, whole_token,(right_token+0.)/whole_token))       
        epoch_finish = time.time()
        epoch_cost = epoch_finish - epoch_start
        print("Epoch: %s training finished. Time: %.2fs, speed: %.2fst/s,  total loss: %s"%(idx, epoch_cost, train_num/epoch_cost, total_loss))
        # continue
        speed, acc, p, r, f, _,_ = evaluate(data, model, "dev")
        dev_finish = time.time()
        dev_cost = dev_finish - epoch_finish

        if data.seg:
            current_score = f
            print("Dev: time: %.2fs, speed: %.2fst/s; acc: %.4f, p: %.4f, r: %.4f, f: %.4f"%(dev_cost, speed, acc, p, r, f))
        else:
            current_score = acc
            print("Dev: time: %.2fs speed: %.2fst/s; acc: %.4f"%(dev_cost, speed, acc))

        if current_score > best_dev:
            if data.seg:
                print "Exceed previous best f score:", best_dev
            else:
                print "Exceed previous best acc score:", best_dev
            model_name = data.model_dir +'.'+ str(idx) + ".model"
            print "Save current best model in file:", model_name
            torch.save(model.state_dict(), model_name)
            best_dev = current_score 
        # ## decode test
        speed, acc, p, r, f, _,_ = evaluate(data, model, "test")
        test_finish = time.time()
        test_cost = test_finish - dev_finish
        if data.seg:
            print("Test: time: %.2fs, speed: %.2fst/s; acc: %.4f, p: %.4f, r: %.4f, f: %.4f"%(test_cost, speed, acc, p, r, f))
        else:
            print("Test: time: %.2fs, speed: %.2fst/s; acc: %.4f"%(test_cost, speed, acc))
        gc.collect() 


def load_model_decode(data, name):
    print "Load Model from file: ", data.model_dir
    model = SeqModel(data)
    ## load model need consider if the model trained in GPU and load in CPU, or vice versa
    # if not gpu:
    #     model.load_state_dict(torch.load(model_dir))
    #     # model.load_state_dict(torch.load(model_dir), map_location=lambda storage, loc: storage)
    #     # model = torch.load(model_dir, map_location=lambda storage, loc: storage)
    # else:
    #     model.load_state_dict(torch.load(model_dir))
    #     # model = torch.load(model_dir)
    model.load_state_dict(torch.load(data.load_model_dir))

    print("Decode %s data, nbest: %s ..."%(name, data.nbest))
    start_time = time.time()
    speed, acc, p, r, f, pred_results, pred_scores = evaluate(data, model, name, data.nbest)
    end_time = time.time()
    time_cost = end_time - start_time
    if data.seg:
        print("%s: time:%.2fs, speed:%.2fst/s; acc: %.4f, p: %.4f, r: %.4f, f: %.4f"%(name, time_cost, speed, acc, p, r, f))
    else:
        print("%s: time:%.2fs, speed:%.2fst/s; acc: %.4f"%(name, time_cost, speed, acc))
    return pred_results, pred_scores




if __name__ == '__main__':
    parser = argparse.ArgumentParser(description='Tuning with NCRF++')
    parser.add_argument('--wordemb',  help='Embedding for words', default='None')
    parser.add_argument('--charemb',  help='Embedding for chars', default='None')
    parser.add_argument('--status', choices=['train', 'decode'], help='update algorithm', default='train')
    parser.add_argument('--savemodel', default="data/model/saved_model.lstmcrf.")
    parser.add_argument('--savedset', help='Dir of saved data setting')
    parser.add_argument('--train', default="data/conll03/train.bmes") 
    parser.add_argument('--dev', default="data/conll03/dev.bmes" )  
    parser.add_argument('--test', default="data/conll03/test.bmes") 
    parser.add_argument('--seg', default="True") 
    parser.add_argument('--raw') 
    parser.add_argument('--loadmodel')
    parser.add_argument('--output') 
    args = parser.parse_args()
    data = Data()
    
    data.train_dir = args.train 
    data.dev_dir = args.dev 
    data.test_dir = args.test
    data.model_dir = args.savemodel
    data.dset_dir = args.savedset
    print "aaa",data.dset_dir
    status = args.status.lower()
    save_model_dir = args.savemodel
    data.HP_gpu = torch.cuda.is_available()
    print "Seed num:",seed_num
    data.number_normalized = True
    data.word_emb_dir = "../data/glove.6B.100d.txt"
    
    if status == 'train':
        print("MODEL: train")
        data_initialization(data)
        data.use_char = True
        data.HP_batch_size = 10
        data.HP_lr = 0.015
        data.char_seq_feature = "CNN"
        data.generate_instance('train')
        data.generate_instance('dev')
        data.generate_instance('test')
        data.build_pretrain_emb()
        train(data)
    elif status == 'decode':   
        print("MODEL: decode")
        data.load(data.dset_dir)    
        data.raw_dir = args.raw
        data.decode_dir = args.output
        data.load_model_dir = args.loadmodel
        data.show_data_summary()
        data.generate_instance('raw')
        print("nbest: %s"%(data.nbest))
        decode_results, pred_scores = load_model_decode(data, 'raw')
        if data.nbest:
            data.write_nbest_decoded_results(decode_results, pred_scores, 'raw')
        else:
            data.write_decoded_results(decode_results, 'raw')
    else:
        print "Invalid argument! Please use valid arguments! (train/test/decode)"