Esempio n. 1
0
def main(_):

    model_type=FLAGS.model_type
    # chkpt_path = FLAGS.model_dir+'saved/qgen-maluuba-crop-glove-smart'
    # chkpt_path = FLAGS.model_dir+'qgen-saved/MALUUBA-CROP-LATENT/1533247183'
    disc_path = FLAGS.model_dir+'saved/discriminator-trained-latent'
    chkpt_path = FLAGS.model_dir+'qgen/'+ model_type+'/'+FLAGS.eval_model_id

    # load dataset
    # train_data = loader.load_squad_triples(FLAGS.data_path, False)
    dev_data = loader.load_squad_triples(FLAGS.data_path, dev=FLAGS.eval_on_dev, test=FLAGS.eval_on_test)

    if len(dev_data) < FLAGS.num_eval_samples:
        exit('***ERROR*** Eval dataset is smaller than the num_eval_samples flag!')
    if len(dev_data) > FLAGS.num_eval_samples:
        print('***WARNING*** Eval dataset is larger than the num_eval_samples flag!')

    # train_contexts_unfilt, _,_,train_a_pos_unfilt = zip(*train_data)
    dev_contexts_unfilt, _,_,dev_a_pos_unfilt = zip(*dev_data)

    if FLAGS.filter_window_size_before >-1:
        # train_data = preprocessing.filter_squad(train_data, window_size=FLAGS.filter_window_size, max_tokens=FLAGS.filter_max_tokens)
        dev_data = preprocessing.filter_squad(dev_data, window_size_before=FLAGS.filter_window_size_before, window_size_after=FLAGS.filter_window_size_after, max_tokens=FLAGS.filter_max_tokens)


    # print('Loaded SQuAD with ',len(train_data),' triples')
    print('Loaded SQuAD dev set with ',len(dev_data),' triples')
    # train_contexts, train_qs, train_as,train_a_pos = zip(*train_data)
    dev_contexts, dev_qs, dev_as, dev_a_pos = zip(*dev_data)


    # vocab = loader.get_vocab(train_contexts, tf.app.flags.FLAGS.vocab_size)
    with open(chkpt_path+'/vocab.json') as f:
        vocab = json.load(f)

    with SquadStreamer(vocab, FLAGS.eval_batch_size, 1, shuffle=False) as dev_data_source:

        glove_embeddings = loader.load_glove(FLAGS.data_path)


        # Create model
        if model_type[:7] == "SEQ2SEQ":
            model = Seq2SeqModel(vocab, training_mode=False)
        elif model_type[:2] == "RL":
            # TEMP - no need to spin up the LM or QA model at eval time
            FLAGS.qa_weight = 0
            FLAGS.lm_weight = 0
            model = RLModel(vocab, training_mode=False)
        else:
            exit("Unrecognised model type: "+model_type)

        with model.graph.as_default():
            saver = tf.train.Saver()

        if FLAGS.eval_metrics:
            lm = LstmLmInstance()
            # qa = MpcmQaInstance()
            qa = QANetInstance()

            lm.load_from_chkpt(FLAGS.model_dir+'saved/lmtest')
            # qa.load_from_chkpt(FLAGS.model_dir+'saved/qatest')
            qa.load_from_chkpt(FLAGS.model_dir+'saved/qanet2')

            discriminator = DiscriminatorInstance(trainable=False, path=disc_path)

        gpu_options = tf.GPUOptions(per_process_gpu_memory_fraction=mem_limit)
        with tf.Session(graph=model.graph, config=tf.ConfigProto(gpu_options=gpu_options)) as sess:
            if not os.path.exists(chkpt_path):
                exit('Checkpoint path doesnt exist! '+chkpt_path)
            # summary_writer = tf.summary.FileWriter(FLAGS.log_directory+"eval/"+str(int(time.time())), sess.graph)

            saver.restore(sess, tf.train.latest_checkpoint(chkpt_path))
            # print('Loading not implemented yet')
            # else:
            #     sess.run(tf.global_variables_initializer())
            #     sess.run(model.glove_init_ops)

            num_steps = FLAGS.num_eval_samples//FLAGS.eval_batch_size

            # Initialise the dataset

            # np.random.shuffle(dev_data)
            dev_data_source.initialise(dev_data)

            f1s=[]
            bleus=[]
            qa_scores=[]
            qa_scores_gold=[]
            lm_scores=[]
            nlls=[]
            disc_scores=[]
            sowe_similarities=[]
            copy_probs=[]

            qgolds=[]
            qpreds=[]
            qpred_ids=[]
            qgold_ids=[]
            ctxts=[]
            answers=[]
            ans_positions=[]

            metric_individuals=[]
            res=[]
            for e in range(1):
                for i in tqdm(range(num_steps), desc='Epoch '+str(e)):
                    dev_batch, curr_batch_size = dev_data_source.get_batch()
                    pred_batch,pred_beam,pred_beam_lens,pred_ids,pred_lens,gold_batch, gold_lens,gold_ids,ctxt,ctxt_len,ans,ans_len,nll,copy_prob= sess.run([model.q_hat_beam_string, model.q_hat_full_beam_str, model.q_hat_full_beam_lens,model.q_hat_beam_ids,model.q_hat_beam_lens,model.question_raw, model.question_length, model.question_ids, model.context_raw, model.context_length, model.answer_locs, model.answer_length, model.nll, model.mean_copy_prob], feed_dict={model.input_batch: dev_batch ,model.is_training:False})

                    unfilt_ctxt_batch = [dev_contexts_unfilt[ix] for ix in dev_batch[3]]
                    a_text_batch = ops.byte_token_array_to_str(dev_batch[2][0], dev_batch[2][2], is_array=False)
                    unfilt_apos_batch = [dev_a_pos_unfilt[ix] for ix in dev_batch[3]]

                    # subtract 1 to remove the "end sent token"
                    pred_q_batch = [q.replace(' </Sent>',"").replace(" <PAD>","") for q in ops.byte_token_array_to_str(pred_batch, pred_lens-1)]

                    ctxts.extend(unfilt_ctxt_batch)
                    answers.extend(a_text_batch)
                    ans_positions.extend([dev_a_pos_unfilt[ix] for ix in dev_batch[3]])
                    copy_probs.extend(copy_prob.tolist())



                    # get QA score

                    # gold_str=[]
                    # pred_str=[]


                    gold_ans = ops.byte_token_array_to_str(dev_batch[2][0], dev_batch[2][2], is_array=False)
                    # pred_str = ops.byte_token_array_to_str([dev_batch[0][0][b][qa_pred[b][0]:qa_pred[b][1]] for b in range(curr_batch_size)], is_array=False)
                    nlls.extend(nll.tolist())

                    if FLAGS.eval_metrics:
                        qa_pred = qa.get_ans(unfilt_ctxt_batch, ops.byte_token_array_to_str(pred_batch, pred_lens))
                        gold_qa_pred = qa.get_ans(unfilt_ctxt_batch, ops.byte_token_array_to_str(dev_batch[1][0], dev_batch[1][3]))

                        qa_score_batch = [metrics.f1(metrics.normalize_answer(gold_ans[b]), metrics.normalize_answer(qa_pred[b])) for b in range(curr_batch_size)]
                        qa_score_gold_batch = [metrics.f1(metrics.normalize_answer(gold_ans[b]), metrics.normalize_answer(gold_qa_pred[b])) for b in range(curr_batch_size)]
                        lm_score_batch = lm.get_seq_perplexity(pred_q_batch).tolist()
                        disc_score_batch = discriminator.get_pred(unfilt_ctxt_batch, pred_q_batch, gold_ans, unfilt_apos_batch).tolist()

                    for b, pred in enumerate(pred_batch):
                        pred_str = pred_q_batch[b].replace(' </Sent>',"").replace(" <PAD>","")
                        gold_str = tokens_to_string(gold_batch[b][:gold_lens[b]-1])
                        f1s.append(metrics.f1(gold_str, pred_str))
                        bleus.append(metrics.bleu(gold_str, pred_str))
                        qgolds.append(gold_str)
                        qpreds.append(pred_str)

                        # calc cosine similarity between sums of word embeddings
                        pred_sowe = np.sum(np.asarray([glove_embeddings[w] if w in glove_embeddings.keys() else np.zeros((FLAGS.embedding_size,)) for w in preprocessing.tokenise(pred_str ,asbytes=False)]) ,axis=0)
                        gold_sowe = np.sum(np.asarray([glove_embeddings[w] if w in glove_embeddings.keys() else np.zeros((FLAGS.embedding_size,)) for w in preprocessing.tokenise(gold_str ,asbytes=False)]) ,axis=0)
                        this_similarity = np.inner(pred_sowe, gold_sowe)/np.linalg.norm(pred_sowe, ord=2)/np.linalg.norm(gold_sowe, ord=2)

                        sowe_similarities.append(this_similarity)



                        this_metric_dict={
                            'f1':f1s[-1],
                            'bleu': bleus[-1],
                            'nll': nlls[-1],
                            'sowe': sowe_similarities[-1]
                            }
                        if FLAGS.eval_metrics:
                            this_metric_dict={
                            **this_metric_dict,
                            'qa': qa_score_batch[b],
                            'lm': lm_score_batch[b],
                            'disc': disc_score_batch[b]}
                            qa_scores.extend(qa_score_batch)
                            lm_scores.extend(lm_score_batch)
                            disc_scores.extend(disc_score_batch)
                        metric_individuals.append(this_metric_dict)

                        res.append({
                            'c':unfilt_ctxt_batch[b],
                            'q_pred': pred_str,
                            'q_gold': gold_str,
                            'a_pos': unfilt_apos_batch[b],
                            'a_text': a_text_batch[b],
                            'metrics': this_metric_dict,

                            'q_pred_ids': pred_ids.tolist()[b],
                            'q_gold_ids': dev_batch[1][1][b].tolist()

                        })

                    # Quick output
                    if i==0:
                        # print(copy_prob.tolist())
                        # print(copy_probs)
                        pred_str = tokens_to_string(pred_batch[0][:pred_lens[0]-1])
                        gold_str = tokens_to_string(gold_batch[0][:gold_lens[0]-1])
                        # print(pred_str)
                        print(qpreds[0])
                        print(gold_str)


                        title=chkpt_path
                        out_str = output_eval(title,pred_batch,  pred_ids, pred_lens, gold_batch, gold_lens, ctxt, ctxt_len, ans, ans_len)
                        with open(FLAGS.log_directory+'out_eval_'+model_type+'.htm', 'w', encoding='utf-8') as fp:
                            fp.write(out_str)

            # res = list(zip(qpreds,qgolds,ctxts,answers,ans_positions,metric_individuals))
            metric_dict={
                'f1':np.mean(f1s),
                'bleu': metrics.bleu_corpus(qgolds, qpreds),
                'nll':np.mean(nlls),
                'sowe': np.mean(sowe_similarities)
                }
            if FLAGS.eval_metrics:
                metric_dict={**metric_dict,
                'qa':np.mean(qa_scores),
                'lm':np.mean(lm_scores),
                'disc': np.mean(disc_scores)}
            # print(res)
            with open(FLAGS.log_directory+'out_eval_'+model_type+("_test" if FLAGS.eval_on_test else "")+("_train" if (not FLAGS.eval_on_dev and not FLAGS.eval_on_test) else "")+'.json', 'w', encoding='utf-8') as fp:
                json.dump({"metrics":metric_dict, "results": res}, fp)


            print("F1: ", np.mean(f1s))
            print("BLEU: ", metrics.bleu_corpus(qgolds, qpreds))
            print("NLL: ", np.mean(nlls))
            print("SOWE: ", np.mean(sowe_similarities))

            print("Copy prob: ", np.mean(copy_probs))
            if FLAGS.eval_metrics:
                print("QA: ", np.mean(qa_scores))
                print("LM: ", np.mean(lm_scores))
                print("Disc: ", np.mean(disc_scores))
Esempio n. 2
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                                       asbytes=False).tolist()
            for cand in candidates
        ]
        max_len = max([len(lmq) for lmq in qs_for_lm])
        qs_for_lm = [
            lmq + [lm_vocab[loader.PAD] for j in range(max_len - len(lmq))]
            for lmq in qs_for_lm
        ]
        ppls = lm.get_seq_perplexity(np.asarray(qs_for_lm))
        best_ix = np.argmin(ppls)
        gen_q = candidates[best_ix]

    gen_q_toks = preprocessing.tokenise(gen_q, asbytes=False)

    f1s.append(metrics.f1(triple[1], gen_q))
    bleus.append(metrics.bleu(triple[1], gen_q))

    qhat_for_lm = preprocessing.lookup_vocab(gen_q_toks,
                                             lm_vocab,
                                             do_tokenise=False,
                                             asbytes=False)
    ctxt_for_lm = preprocessing.lookup_vocab(ctxt_toks,
                                             lm_vocab,
                                             do_tokenise=False,
                                             asbytes=False)
    qhat_for_qa = preprocessing.lookup_vocab(gen_q_toks,
                                             qa_vocab,
                                             do_tokenise=False,
                                             asbytes=False)
    ctxt_for_qa = preprocessing.lookup_vocab(ctxt_toks,
                                             qa_vocab,
Esempio n. 3
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def main(_):
    if FLAGS.testing:
        print('TEST MODE - reducing model size')
        FLAGS.context_encoder_units = 100
        FLAGS.answer_encoder_units = 100
        FLAGS.decoder_units = 100
        FLAGS.batch_size = 8
        FLAGS.eval_batch_size = 8
        # FLAGS.embedding_size=50

    run_id = str(int(time.time()))
    chkpt_path = FLAGS.model_dir + 'qgen/' + FLAGS.model_type + '/' + run_id
    restore_path = FLAGS.model_dir + 'qgen/' + FLAGS.restore_path if FLAGS.restore_path is not None else None  #'MALUUBA-CROP-LATENT'+'/'+'1534123959'
    # restore_path=FLAGS.model_dir+'saved/qgen-maluuba-crop-glove-smart'
    disc_path = FLAGS.model_dir + 'saved/discriminator-trained-latent'

    print("Run ID is ", run_id)
    print("Model type is ", FLAGS.model_type)

    if not os.path.exists(chkpt_path):
        os.makedirs(chkpt_path)

    # load dataset
    train_data = loader.load_squad_triples(FLAGS.data_path, False)
    dev_data = loader.load_squad_triples(FLAGS.data_path, True)

    train_contexts_unfilt, _, ans_text_unfilt, ans_pos_unfilt = zip(
        *train_data)
    dev_contexts_unfilt, _, dev_ans_text_unfilt, dev_ans_pos_unfilt = zip(
        *dev_data)

    if FLAGS.testing:
        train_data = train_data[:1000]
        num_dev_samples = 100
    else:
        num_dev_samples = FLAGS.num_dev_samples

    if FLAGS.filter_window_size_before > -1:
        train_data = preprocessing.filter_squad(
            train_data,
            window_size_before=FLAGS.filter_window_size_before,
            window_size_after=FLAGS.filter_window_size_after,
            max_tokens=FLAGS.filter_max_tokens)
        dev_data = preprocessing.filter_squad(
            dev_data,
            window_size_before=FLAGS.filter_window_size_before,
            window_size_after=FLAGS.filter_window_size_after,
            max_tokens=FLAGS.filter_max_tokens)

    print('Loaded SQuAD with ', len(train_data), ' triples')
    train_contexts, train_qs, train_as, train_a_pos = zip(*train_data)

    if FLAGS.restore:
        if restore_path is None:
            exit('You need to specify a restore path!')
        with open(restore_path + '/vocab.json', encoding="utf-8") as f:
            vocab = json.load(f)
    elif FLAGS.glove_vocab:
        vocab = loader.get_glove_vocab(FLAGS.data_path,
                                       size=FLAGS.vocab_size,
                                       d=FLAGS.embedding_size)
        with open(chkpt_path + '/vocab.json', 'w',
                  encoding="utf-8") as outfile:
            json.dump(vocab, outfile)
    else:
        vocab = loader.get_vocab(train_contexts + train_qs, FLAGS.vocab_size)
        with open(chkpt_path + '/vocab.json', 'w',
                  encoding="utf-8") as outfile:
            json.dump(vocab, outfile)

    # Create model
    if FLAGS.model_type[:7] == "SEQ2SEQ":
        model = Seq2SeqModel(vocab,
                             training_mode=True,
                             use_embedding_loss=FLAGS.embedding_loss)
    elif FLAGS.model_type[:7] == "MALUUBA":
        # TEMP
        if not FLAGS.policy_gradient:
            FLAGS.qa_weight = 0
            FLAGS.lm_weight = 0
        model = MaluubaModel(vocab,
                             training_mode=True,
                             use_embedding_loss=FLAGS.embedding_loss)
        # if FLAGS.model_type[:10] == "MALUUBA_RL":
        #     qa_vocab=model.qa.vocab
        #     lm_vocab=model.lm.vocab
        if FLAGS.policy_gradient:
            discriminator = DiscriminatorInstance(trainable=FLAGS.disc_train,
                                                  path=disc_path)
    else:
        exit("Unrecognised model type: " + FLAGS.model_type)

    # create data streamer
    with SquadStreamer(vocab, FLAGS.batch_size, FLAGS.num_epochs,
                       shuffle=True) as train_data_source, SquadStreamer(
                           vocab, FLAGS.eval_batch_size, 1,
                           shuffle=True) as dev_data_source:

        with model.graph.as_default():
            saver = tf.train.Saver(max_to_keep=1, save_relative_paths=True)

        # change visible devices if using RL models
        gpu_options = tf.GPUOptions(per_process_gpu_memory_fraction=mem_limit,
                                    visible_device_list='0',
                                    allow_growth=True)
        with tf.Session(config=tf.ConfigProto(gpu_options=gpu_options,
                                              allow_soft_placement=False),
                        graph=model.graph) as sess:

            summary_writer = tf.summary.FileWriter(
                FLAGS.log_dir + 'qgen/' + FLAGS.model_type + '/' + run_id,
                sess.graph)

            train_data_source.initialise(train_data)

            num_steps_train = len(train_data) // FLAGS.batch_size
            num_steps_dev = num_dev_samples // FLAGS.eval_batch_size

            if FLAGS.restore:
                saver.restore(sess, tf.train.latest_checkpoint(restore_path))
                start_e = 15  #FLAGS.num_epochs
                print('Loaded model')
            else:
                start_e = 0
                sess.run(tf.global_variables_initializer())
                # sess.run(model.glove_init_ops)

                f1summary = tf.Summary(value=[
                    tf.Summary.Value(tag="dev_perf/f1", simple_value=0.0)
                ])
                bleusummary = tf.Summary(value=[
                    tf.Summary.Value(tag="dev_perf/bleu", simple_value=0.0)
                ])

                summary_writer.add_summary(f1summary, global_step=0)
                summary_writer.add_summary(bleusummary, global_step=0)

            # Initialise the dataset
            # sess.run(model.iterator.initializer, feed_dict={model.context_ph: train_contexts,
            #                                   model.qs_ph: train_qs, model.as_ph: train_as, model.a_pos_ph: train_a_pos})

            best_oos_nll = 1e6

            lm_score_moments = online_moments.OnlineMoment()
            qa_score_moments = online_moments.OnlineMoment()
            disc_score_moments = online_moments.OnlineMoment()

            # for e in range(start_e,start_e+FLAGS.num_epochs):
            # Train for one epoch
            for i in tqdm(range(num_steps_train * FLAGS.num_epochs),
                          desc='Training'):
                # Get a batch
                train_batch, curr_batch_size = train_data_source.get_batch()

                # Are we doing policy gradient? Do a forward pass first, then build the PG batch and do an update step
                if FLAGS.model_type[:
                                    10] == "MALUUBA_RL" and FLAGS.policy_gradient:

                    # do a fwd pass first, get the score, then do another pass and optimize
                    qhat_str, qhat_ids, qhat_lens = sess.run(
                        [
                            model.q_hat_beam_string, model.q_hat_beam_ids,
                            model.q_hat_beam_lens
                        ],
                        feed_dict={
                            model.input_batch: train_batch,
                            model.is_training: FLAGS.pg_dropout,
                            model.hide_answer_in_copy: True
                        })

                    # The output is as long as the max allowed len - remove the pointless extra padding
                    qhat_ids = qhat_ids[:, :np.max(qhat_lens)]
                    qhat_str = qhat_str[:, :np.max(qhat_lens)]

                    pred_str = byte_token_array_to_str(qhat_str, qhat_lens - 1)
                    gold_q_str = byte_token_array_to_str(
                        train_batch[1][0], train_batch[1][3])

                    # Get reward values
                    lm_score = (-1 * model.lm.get_seq_perplexity(pred_str)
                                ).tolist()  # lower perplexity is better

                    # retrieve the uncropped context for QA evaluation
                    unfilt_ctxt_batch = [
                        train_contexts_unfilt[ix] for ix in train_batch[3]
                    ]
                    ans_text_batch = [
                        ans_text_unfilt[ix] for ix in train_batch[3]
                    ]
                    ans_pos_batch = [
                        ans_pos_unfilt[ix] for ix in train_batch[3]
                    ]

                    qa_pred = model.qa.get_ans(unfilt_ctxt_batch, pred_str)
                    qa_pred_gold = model.qa.get_ans(unfilt_ctxt_batch,
                                                    gold_q_str)

                    # gold_str=[]
                    # pred_str=[]
                    qa_f1s = []
                    gold_ans_str = byte_token_array_to_str(train_batch[2][0],
                                                           train_batch[2][2],
                                                           is_array=False)

                    qa_f1s.extend([
                        metrics.f1(metrics.normalize_answer(gold_ans_str[b]),
                                   metrics.normalize_answer(qa_pred[b]))
                        for b in range(curr_batch_size)
                    ])

                    disc_scores = discriminator.get_pred(
                        unfilt_ctxt_batch, pred_str, ans_text_batch,
                        ans_pos_batch)

                    if i > FLAGS.pg_burnin // 2:
                        lm_score_moments.push(lm_score)
                        qa_score_moments.push(qa_f1s)
                        disc_score_moments.push(disc_scores)

                    # print(disc_scores)
                    # print((e-start_e)*num_steps_train+i, flags.pg_burnin)

                    if i > FLAGS.pg_burnin:
                        # A variant of popart
                        qa_score_whitened = (
                            qa_f1s - qa_score_moments.mean
                        ) / np.sqrt(qa_score_moments.variance + 1e-6)
                        lm_score_whitened = (
                            lm_score - lm_score_moments.mean
                        ) / np.sqrt(lm_score_moments.variance + 1e-6)
                        disc_score_whitened = (
                            disc_scores - disc_score_moments.mean
                        ) / np.sqrt(disc_score_moments.variance + 1e-6)

                        lm_summary = tf.Summary(value=[
                            tf.Summary.Value(tag="rl_rewards/lm",
                                             simple_value=np.mean(lm_score))
                        ])
                        summary_writer.add_summary(lm_summary, global_step=(i))
                        qa_summary = tf.Summary(value=[
                            tf.Summary.Value(tag="rl_rewards/qa",
                                             simple_value=np.mean(qa_f1s))
                        ])
                        summary_writer.add_summary(qa_summary, global_step=(i))
                        disc_summary = tf.Summary(value=[
                            tf.Summary.Value(tag="rl_rewards/disc",
                                             simple_value=np.mean(disc_scores))
                        ])
                        summary_writer.add_summary(disc_summary,
                                                   global_step=(i))

                        lm_white_summary = tf.Summary(value=[
                            tf.Summary.Value(tag="rl_rewards/lm_white",
                                             simple_value=np.mean(
                                                 lm_score_whitened))
                        ])
                        summary_writer.add_summary(lm_white_summary,
                                                   global_step=(i))
                        qa_white_summary = tf.Summary(value=[
                            tf.Summary.Value(tag="rl_rewards/qa_white",
                                             simple_value=np.mean(
                                                 qa_score_whitened))
                        ])
                        summary_writer.add_summary(qa_white_summary,
                                                   global_step=(i))
                        disc_white_summary = tf.Summary(value=[
                            tf.Summary.Value(tag="rl_rewards/disc_white",
                                             simple_value=np.mean(
                                                 disc_score_whitened))
                        ])
                        summary_writer.add_summary(disc_white_summary,
                                                   global_step=(i))

                        # Build a combined batch - half ground truth for MLE, half generated for PG
                        train_batch_ext = duplicate_batch_and_inject(
                            train_batch, qhat_ids, qhat_str, qhat_lens)

                        # print(qhat_ids)
                        # print(qhat_lens)
                        # print(train_batch_ext[2][2])

                        rl_dict = {
                            model.lm_score:
                            np.asarray((lm_score_whitened *
                                        FLAGS.lm_weight).tolist() + [
                                            FLAGS.pg_ml_weight
                                            for b in range(curr_batch_size)
                                        ]),
                            model.qa_score:
                            np.asarray((qa_score_whitened *
                                        FLAGS.qa_weight).tolist() +
                                       [0 for b in range(curr_batch_size)]),
                            model.disc_score:
                            np.asarray((disc_score_whitened *
                                        FLAGS.disc_weight).tolist() +
                                       [0 for b in range(curr_batch_size)]),
                            model.rl_lm_enabled:
                            True,
                            model.rl_qa_enabled:
                            True,
                            model.rl_disc_enabled:
                            FLAGS.disc_weight > 0,
                            model.step:
                            i - FLAGS.pg_burnin,
                            model.hide_answer_in_copy:
                            True
                        }

                        # perform a policy gradient step, but combine with a XE step by using appropriate rewards
                        ops = [
                            model.pg_optimizer, model.train_summary,
                            model.q_hat_string
                        ]
                        if i % FLAGS.eval_freq == 0:
                            ops.extend([
                                model.q_hat_ids, model.question_ids,
                                model.copy_prob, model.question_raw,
                                model.question_length
                            ])
                            res_offset = 5
                        else:
                            res_offset = 0
                        ops.extend([model.lm_loss, model.qa_loss])
                        res = sess.run(ops,
                                       feed_dict={
                                           model.input_batch: train_batch_ext,
                                           model.is_training: False,
                                           **rl_dict
                                       })
                        summary_writer.add_summary(res[1], global_step=(i))

                        # Log only the first half of the PG related losses
                        lm_loss_summary = tf.Summary(value=[
                            tf.Summary.Value(
                                tag="train_loss/lm",
                                simple_value=np.mean(res[3 + res_offset]
                                                     [:curr_batch_size]))
                        ])
                        summary_writer.add_summary(lm_loss_summary,
                                                   global_step=(i))
                        qa_loss_summary = tf.Summary(value=[
                            tf.Summary.Value(
                                tag="train_loss/qa",
                                simple_value=np.mean(res[4 + res_offset]
                                                     [:curr_batch_size]))
                        ])
                        summary_writer.add_summary(qa_loss_summary,
                                                   global_step=(i))

                    # TODO: more principled scheduling here than alternating steps
                    if FLAGS.disc_train:
                        ixs = np.round(
                            np.random.binomial(1, 0.5, curr_batch_size))
                        qbatch = [
                            pred_str[ix].replace(" </Sent>", "").replace(
                                " <PAD>", "")
                            if ixs[ix] < 0.5 else gold_q_str[ix].replace(
                                " </Sent>", "").replace(" <PAD>", "")
                            for ix in range(curr_batch_size)
                        ]

                        loss = discriminator.train_step(unfilt_ctxt_batch,
                                                        qbatch,
                                                        ans_text_batch,
                                                        ans_pos_batch,
                                                        ixs,
                                                        step=(i))

                else:
                    # Normal single pass update step. If model has PG capability, fill in the placeholders with empty values
                    if FLAGS.model_type[:
                                        7] == "MALUUBA" and not FLAGS.policy_gradient:
                        rl_dict = {
                            model.lm_score:
                            [0 for b in range(curr_batch_size)],
                            model.qa_score:
                            [0 for b in range(curr_batch_size)],
                            model.disc_score:
                            [0 for b in range(curr_batch_size)],
                            model.rl_lm_enabled: False,
                            model.rl_qa_enabled: False,
                            model.rl_disc_enabled: False,
                            model.hide_answer_in_copy: False
                        }
                    else:
                        rl_dict = {}

                    # Perform a normal optimizer step
                    ops = [
                        model.optimizer, model.train_summary,
                        model.q_hat_string
                    ]
                    if i % FLAGS.eval_freq == 0:
                        ops.extend([
                            model.q_hat_ids, model.question_ids,
                            model.copy_prob, model.question_raw,
                            model.question_length
                        ])
                    res = sess.run(ops,
                                   feed_dict={
                                       model.input_batch: train_batch,
                                       model.is_training: True,
                                       **rl_dict
                                   })
                    summary_writer.add_summary(res[1], global_step=(i))

                # Dump some output periodically
                if i > 0 and i % FLAGS.eval_freq == 0 and (
                        i > FLAGS.pg_burnin or not FLAGS.policy_gradient):
                    with open(FLAGS.log_dir + 'out.htm', 'w',
                              encoding='utf-8') as fp:
                        fp.write(
                            output_pretty(res[2].tolist(), res[3], res[4],
                                          res[5], 0, i))
                    gold_batch = res[6]
                    gold_lens = res[7]
                    f1s = []
                    bleus = []
                    for b, pred in enumerate(res[2]):
                        pred_str = tokens_to_string(pred[:gold_lens[b] - 1])
                        gold_str = tokens_to_string(
                            gold_batch[b][:gold_lens[b] - 1])
                        f1s.append(metrics.f1(gold_str, pred_str))
                        bleus.append(metrics.bleu(gold_str, pred_str))

                    f1summary = tf.Summary(value=[
                        tf.Summary.Value(tag="train_perf/f1",
                                         simple_value=sum(f1s) / len(f1s))
                    ])
                    bleusummary = tf.Summary(value=[
                        tf.Summary.Value(tag="train_perf/bleu",
                                         simple_value=sum(bleus) / len(bleus))
                    ])

                    summary_writer.add_summary(f1summary, global_step=(i))
                    summary_writer.add_summary(bleusummary, global_step=(i))

                    # Evaluate against dev set
                    f1s = []
                    bleus = []
                    nlls = []

                    np.random.shuffle(dev_data)
                    dev_subset = dev_data[:num_dev_samples]
                    dev_data_source.initialise(dev_subset)
                    for j in tqdm(range(num_steps_dev), desc='Eval ' + str(i)):
                        dev_batch, curr_batch_size = dev_data_source.get_batch(
                        )
                        pred_batch, pred_ids, pred_lens, gold_batch, gold_lens, ctxt, ctxt_len, ans, ans_len, nll = sess.run(
                            [
                                model.q_hat_beam_string, model.q_hat_beam_ids,
                                model.q_hat_beam_lens, model.question_raw,
                                model.question_length, model.context_raw,
                                model.context_length, model.answer_locs,
                                model.answer_length, model.nll
                            ],
                            feed_dict={
                                model.input_batch: dev_batch,
                                model.is_training: False
                            })

                        nlls.extend(nll.tolist())
                        # out_str="<h1>"+str(e)+' - '+str(datetime.datetime.now())+'</h1>'
                        for b, pred in enumerate(pred_batch):
                            pred_str = tokens_to_string(
                                pred[:pred_lens[b] - 1]).replace(
                                    ' </Sent>', "").replace(" <PAD>", "")
                            gold_str = tokens_to_string(
                                gold_batch[b][:gold_lens[b] - 1])
                            f1s.append(metrics.f1(gold_str, pred_str))
                            bleus.append(metrics.bleu(gold_str, pred_str))
                            # out_str+=pred_str.replace('>','&gt;').replace('<','&lt;')+"<br/>"+gold_str.replace('>','&gt;').replace('<','&lt;')+"<hr/>"
                        if j == 0:
                            title = chkpt_path
                            out_str = output_eval(title, pred_batch, pred_ids,
                                                  pred_lens, gold_batch,
                                                  gold_lens, ctxt, ctxt_len,
                                                  ans, ans_len)
                            with open(FLAGS.log_dir + 'out_eval_' +
                                      FLAGS.model_type + '.htm',
                                      'w',
                                      encoding='utf-8') as fp:
                                fp.write(out_str)

                    f1summary = tf.Summary(value=[
                        tf.Summary.Value(tag="dev_perf/f1",
                                         simple_value=sum(f1s) / len(f1s))
                    ])
                    bleusummary = tf.Summary(value=[
                        tf.Summary.Value(tag="dev_perf/bleu",
                                         simple_value=sum(bleus) / len(bleus))
                    ])
                    nllsummary = tf.Summary(value=[
                        tf.Summary.Value(tag="dev_perf/nll",
                                         simple_value=sum(nlls) / len(nlls))
                    ])

                    summary_writer.add_summary(f1summary, global_step=i)
                    summary_writer.add_summary(bleusummary, global_step=i)
                    summary_writer.add_summary(nllsummary, global_step=i)

                    mean_nll = sum(nlls) / len(nlls)
                    if mean_nll < best_oos_nll:
                        print("New best NLL! ", mean_nll, " Saving...")
                        best_oos_nll = mean_nll
                        saver.save(sess,
                                   chkpt_path + '/model.checkpoint',
                                   global_step=i)
                    else:
                        print("NLL not improved ", mean_nll)
                        if FLAGS.policy_gradient:
                            print("Saving anyway")
                            saver.save(sess,
                                       chkpt_path + '/model.checkpoint',
                                       global_step=i)
                        if FLAGS.disc_train:
                            print("Saving disc")
                            discriminator.save_to_chkpt(FLAGS.model_dir, i)
# q_words=["who","when","what","why","how many","which","where","other"]
q_words = ["who", "when", "what", "how", "which", "where", "why", "other"]
scores = {k: [] for k in q_words}
counts = {k: 0 for k in q_words}

word_gold = ["other" for i in range(len(results))]
word_pred = ["other" for i in range(len(results))]

gold_pred_bleu = []
gold_pred_f1 = []
nlls = []
x = []
for i, res in enumerate(results):
    qpred, qgold, ctxt, answer, a_pos = res['q_pred'], res['q_gold'], res[
        'c'], res['a_text'], res['a_pos']
    gold_pred_bleu.append(metrics.bleu(qgold, qpred))
    nlls.append(res['metrics']['nll'])
    # x.append(metrics.f1(ctxt, qpred))
    x.append(len(preprocessing.tokenise(qgold, asbytes=False)))
    gold_pred_f1.append(metrics.f1(qgold, qpred))

    triggered = False
    for q in q_words:
        if q != "other" and q in qpred.lower():
            # scores[q].append(metrics.bleu(qgold, qpred))
            # scores[q].append(res['metrics']['qa'])
            # counts[q] += 1
            word_pred[i] = q

        if q != "other" and q in qgold.lower():
            counts[q] += 1
def main(_):
    model = FileLoaderModel('./models/BASELINE')
    squad = loader.load_squad_triples(FLAGS.data_path, True, as_dict=True)

    disc_path = FLAGS.model_dir + 'saved/discriminator-trained-latent'

    glove_embeddings = loader.load_glove(FLAGS.data_path)

    if FLAGS.eval_metrics:
        lm = LstmLmInstance()
        # qa = MpcmQaInstance()
        qa = QANetInstance()

        lm.load_from_chkpt(FLAGS.model_dir + 'saved/lmtest')
        # qa.load_from_chkpt(FLAGS.model_dir+'saved/qatest')
        qa.load_from_chkpt(FLAGS.model_dir + 'saved/qanet')

        discriminator = DiscriminatorInstance(trainable=False, path=disc_path)

    f1s = []
    bleus = []
    qa_scores = []
    qa_scores_gold = []
    lm_scores = []
    nlls = []
    disc_scores = []
    sowe_similarities = []

    qgolds = []
    qpreds = []
    ctxts = []
    answers = []
    ans_positions = []

    metric_individuals = []
    res = []

    missing = 0

    for id, el in tqdm(squad.items()):

        unfilt_ctxt_batch = [el[0]]
        a_text_batch = [el[2]]
        a_pos_batch = [el[3]]

        ctxts.extend(unfilt_ctxt_batch)
        answers.extend(a_text_batch)
        ans_positions.extend(a_pos_batch)

        pred_str = model.get_q(id)

        if pred_str is None:
            missing += 1
            continue
        gold_str = el[1]

        if FLAGS.eval_metrics:
            qa_pred = qa.get_ans(unfilt_ctxt_batch, [pred_str])
            gold_qa_pred = qa.get_ans(unfilt_ctxt_batch, [gold_str])

            qa_score = metrics.f1(el[2].lower(), qa_pred[0].lower())
            qa_score_gold = metrics.f1(el[2].lower(), gold_qa_pred[0].lower())
            lm_score = lm.get_seq_perplexity([pred_str]).tolist()
            disc_score = discriminator.get_pred(unfilt_ctxt_batch, [pred_str],
                                                a_text_batch,
                                                a_pos_batch).tolist()[0]

        f1s.append(metrics.f1(gold_str, pred_str))
        bleus.append(metrics.bleu(gold_str, pred_str))
        qgolds.append(gold_str)
        qpreds.append(pred_str)

        # calc cosine similarity between sums of word embeddings
        pred_sowe = np.sum(np.asarray([
            glove_embeddings[w] if w in glove_embeddings.keys() else np.zeros(
                (FLAGS.embedding_size, ))
            for w in preprocessing.tokenise(pred_str, asbytes=False)
        ]),
                           axis=0)
        gold_sowe = np.sum(np.asarray([
            glove_embeddings[w] if w in glove_embeddings.keys() else np.zeros(
                (FLAGS.embedding_size, ))
            for w in preprocessing.tokenise(gold_str, asbytes=False)
        ]),
                           axis=0)
        this_similarity = np.inner(pred_sowe, gold_sowe) / np.linalg.norm(
            pred_sowe, ord=2) / np.linalg.norm(gold_sowe, ord=2)

        sowe_similarities.append(this_similarity)

        this_metric_dict = {
            'f1': f1s[-1],
            'bleu': bleus[-1],
            'nll': 0,
            'sowe': sowe_similarities[-1]
        }
        if FLAGS.eval_metrics:
            this_metric_dict = {
                **this_metric_dict, 'qa': qa_score,
                'lm': lm_score,
                'disc': disc_score
            }
            qa_scores.append(qa_score)
            lm_scores.append(lm_score)
            disc_scores.append(disc_score)
        metric_individuals.append(this_metric_dict)

        res.append({
            'c': el[0],
            'q_pred': pred_str,
            'q_gold': gold_str,
            'a_pos': el[3],
            'a_text': el[2],
            'metrics': this_metric_dict
        })

    metric_dict = {
        'f1': np.mean(f1s),
        'bleu': np.mean(bleus),
        'nll': 0,
        'sowe': np.mean(sowe_similarities)
    }
    if FLAGS.eval_metrics:
        metric_dict = {
            **metric_dict, 'qa': np.mean(qa_scores),
            'lm': np.mean(lm_scores),
            'disc': np.mean(disc_scores)
        }
    # print(res)
    with open(FLAGS.log_dir + 'out_eval_BASELINE' +
              ("_train" if not FLAGS.eval_on_dev else "") + '.json',
              'w',
              encoding='utf-8') as fp:
        json.dump({"metrics": metric_dict, "results": res}, fp)

    print("F1: ", np.mean(f1s))
    print("BLEU: ", np.mean(bleus))
    print("NLL: ", 0)
    print("SOWE: ", np.mean(sowe_similarities))
    if FLAGS.eval_metrics:
        print("QA: ", np.mean(qa_scores))
        print("LM: ", np.mean(lm_scores))
        print("Disc: ", np.mean(disc_scores))

    print(missing, " ids were missing")
Esempio n. 6
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# q_words=["who","when","what","why","how many","which","where","other"]
q_words = ["who", "when", "what", "how", "which", "where", "why", "other"]
scores = {k: [] for k in q_words}
counts = {k: 0 for k in q_words}

word_gold = ["other" for i in range(len(results))]
word_pred = ["other" for i in range(len(results))]

gold_pred_bleu = []
gold_pred_f1 = []
x = []
for i, res in enumerate(results):
    qpred, qgold, ctxt, answer, a_pos = res['q_pred'], res['q_gold'], res[
        'c'], res['a_text'], res['a_pos']
    gold_pred_bleu.append(metrics.bleu(qgold, qpred))
    # x.append(metrics.f1(ctxt, qpred))
    x.append(len(preprocessing.tokenise(qgold, asbytes=False)))
    gold_pred_f1.append(metrics.f1(qgold, qpred))

    triggered = False
    for q in q_words:
        if q != "other" and q in qpred.lower():
            scores[q].append(metrics.bleu(qgold, qpred))
            counts[q] += 1
            word_pred[i] = q

        if q != "other" and q in qgold.lower():
            counts[q] += 1
            word_gold[i] = q
            triggered = True