Example #1
0
def gae_for_na(name, n_clusters): # 对一个具体的姓名预测其消歧结果  评估值[pre, rec, f1], 文档数, 聚类数
    """
    train and evaluate disambiguation results for a specific name
    :param name:  author name
    :return: evaluation results
    """
    adj, features, pids = load_local_data(name=name) # 邻接矩阵(i,j)=1, 文档特征集(y, aid), 标记集 aid索引编号i; features与labels关于下标 一一对应

    # Store original adjacency matrix (without diagonal entries) for later
    adj_orig = adj
    adj_orig = adj_orig - sp.dia_matrix((adj_orig.diagonal()[np.newaxis, :], [0]), shape=adj_orig.shape)
    adj_orig.eliminate_zeros() # 在原邻接矩阵的基础上 去对角线元素 删除0
    adj_train = gen_train_edges(adj) # 这里搞了半天 感觉就是 把adj的对角元素删了 用的csr_matrix 类型 

    adj = adj_train # 完整的邻接矩阵 

    # Some preprocessing
    adj_norm = preprocess_graph(adj)  # 标准化 矩阵 A^' 返回的是元组tuple 坐标(x,y), 值, 形状
    num_nodes = adj.shape[0] # 节点数
    input_feature_dim = features.shape[1] # 输入 特征 维数 [0]是个数
    if FLAGS.is_sparse:  # TODO to test
        # features = sparse_to_tuple(features.tocoo())
        # features_nonzero = features[1].shape[0]
        features = features.todense()  # TODO
    else: # 条件 进入的是 这边
        features = normalize_vectors(features)# 特征向量 标准化

    # Define placeholders
    # tf.placeholder 此函数可以理解为形参,用于定义过程,在执行的时候再赋具体的值 ?_?
    placeholders = {
        # 'features': tf.sparse_placeholder(tf.float32),
        'features': tf.placeholder(tf.float32, shape=(None, input_feature_dim)),
        'adj': tf.sparse_placeholder(tf.float32),# 为稀疏张量插入占位符,该稀疏张量将始终被提供
        'adj_orig': tf.sparse_placeholder(tf.float32),
        'dropout': tf.placeholder_with_default(0., shape=())# 该函数将返回一个张量。与 input 具有相同的类型。一个占位符张量,默认为 input 的占位符张量 (如果未送入)。
    }

    # Create model
    model = None
    if model_str == 'gcn_ae':
        model = GCNModelAE(placeholders, input_feature_dim)
    elif model_str == 'gcn_vae':# 使用的模型 是 gcn_vae
        model = GCNModelVAE(placeholders, input_feature_dim, num_nodes)
    pos_weight = float(adj.shape[0] * adj.shape[0] - adj.sum()) / adj.sum()  # negative edges/pos edges
    print('positive edge weight', pos_weight)# 负边/正边
    norm = adj.shape[0] * adj.shape[0] / float((adj.shape[0] * adj.shape[0] - adj.nnz) * 2) # 矩阵中非零元素的数量nnz

    # Optimizer
    with tf.name_scope('optimizer'):
        if model_str == 'gcn_ae':
            opt = OptimizerAE(preds=model.reconstructions,
                              labels=tf.reshape(tf.sparse_tensor_to_dense(placeholders['adj_orig'],
                                                                          validate_indices=False), [-1]),
                              pos_weight=pos_weight,
                              norm=norm)
        elif model_str == 'gcn_vae':# 使用的模型 是 gcn_vae
            opt = OptimizerVAE(preds=model.reconstructions,
                               labels=tf.reshape(tf.sparse_tensor_to_dense(placeholders['adj_orig'],
                                                                           validate_indices=False), [-1]),
                               model=model, num_nodes=num_nodes,
                               pos_weight=pos_weight,
                               norm=norm)

    # Initialize session
    sess = tf.Session()
    sess.run(tf.global_variables_initializer())

    adj_label = adj_train + sp.eye(adj_train.shape[0])# sp.eye 单位矩阵 标记, 解码应该得到原矩阵
    adj_label = sparse_to_tuple(adj_label)# 稀疏矩阵 -> 元组 (坐标, 值, 维度形状)

    def get_embs():# 获得内部 嵌入z
        feed_dict.update({placeholders['dropout']: 0})
        emb = sess.run(model.z_mean, feed_dict=feed_dict)  # z_mean is better
        return emb

    # Train model
    for epoch in range(FLAGS.epochs):# 训练批次 epoch

        t = time.time()
        # Construct feed dictionary
        feed_dict = construct_feed_dict(adj_norm, adj_label, features, placeholders)
        feed_dict.update({placeholders['dropout']: FLAGS.dropout})
        # Run single weight update
        outs = sess.run([opt.opt_op, opt.cost, opt.accuracy],
                        feed_dict=feed_dict)

        # Compute average loss
        avg_cost = outs[1]
        avg_accuracy = outs[2]

        print("Epoch:", '%04d' % (epoch + 1), "train_loss=", "{:.5f}".format(avg_cost),
              "train_acc=", "{:.5f}".format(avg_accuracy),
              "time=", "{:.5f}".format(time.time() - t))

    emb = get_embs() # 经过 编码器后 的 嵌入层
    ''' n_clusters = int(name_to_ncluster.get(name, 0))
    n_clusters = len(set(labels))# 直接获得 真实的 聚类大小
    if n_clusters == 1:
        return None, None, None, None '''
    #n_clusters = len(set(labels))# 直接获得 真实的 聚类大小
    emb_norm = normalize_vectors(emb)# 标准化 嵌入层
    clusters_pred = clustering(emb_norm, num_clusters=max(n_clusters,1)) # 聚类, 嵌入集 与 聚类大小

    print('clusters_pred: ', clusters_pred)

    ret = {}
    for i, pred_label in enumerate(clusters_pred):
        pred_label = str(pred_label)
        if pred_label not in ret:
            ret[pred_label] = []
        ret[pred_label].append(pids[i])

    rett = []
    for pred_label in ret:
        tmp = []
        for pid in ret[pred_label]:
            tmp.append(pid)
        rett.append(tmp)
    return rett

    ''' ret = {}
def gae_for_na(name, rawfeature):
    """
    train and evaluate disambiguation results for a specific name
    :param name:  author name
    :return: evaluation results
    """
    adj, features, labels = load_local_data(name=name, rawfeature=rawfeature)

    # Store original adjacency matrix (without diagonal entries) for later
    adj_orig = adj
    adj_orig = adj_orig - sp.dia_matrix((adj_orig.diagonal()[np.newaxis, :], [0]), shape=adj_orig.shape)
    adj_orig.eliminate_zeros()
    adj_train = gen_train_edges(adj)

    adj = adj_train

    # Some preprocessing
    adj_norm = preprocess_graph(adj)
    num_nodes = adj.shape[0]
    input_feature_dim = features.shape[1]
    if FLAGS.is_sparse:  # TODO to test
        # features = sparse_to_tuple(features.tocoo())
        # features_nonzero = features[1].shape[0]
        features = features.todense()  # TODO
    else:
        features = normalize_vectors(features)

    # Define placeholders
    placeholders = {
        # 'features': tf.sparse_placeholder(tf.float32),
        'features': tf.placeholder(tf.float32, shape=(None, input_feature_dim)),
        'adj': tf.sparse_placeholder(tf.float32),
        'adj_orig': tf.sparse_placeholder(tf.float32),
        'dropout': tf.placeholder_with_default(0., shape=())
    }

    # Create model
    model = None
    if model_str == 'gcn_ae':
        model = GCNModelAE(placeholders, input_feature_dim)
    elif model_str == 'gcn_vae':
        model = GCNModelVAE(placeholders, input_feature_dim, num_nodes)
    pos_weight = float(adj.shape[0] * adj.shape[0] - adj.sum()) / adj.sum()  # negative edges/pos edges
    print('positive edge weight', pos_weight)
    norm = adj.shape[0] * adj.shape[0] / float((adj.shape[0] * adj.shape[0] - adj.nnz) * 2)

    # Optimizer
    with tf.name_scope('optimizer'):
        if model_str == 'gcn_ae':
            opt = OptimizerAE(preds=model.reconstructions,
                              labels=tf.reshape(tf.sparse_tensor_to_dense(placeholders['adj_orig'],
                                                                          validate_indices=False), [-1]),
                              pos_weight=pos_weight,
                              norm=norm)
        elif model_str == 'gcn_vae':
            opt = OptimizerVAE(preds=model.reconstructions,
                               labels=tf.reshape(tf.sparse_tensor_to_dense(placeholders['adj_orig'],
                                                                           validate_indices=False), [-1]),
                               model=model, num_nodes=num_nodes,
                               pos_weight=pos_weight,
                               norm=norm)

    # Initialize session
    sess = tf.Session()
    sess.run(tf.global_variables_initializer())

    adj_label = adj_train + sp.eye(adj_train.shape[0])
    adj_label = sparse_to_tuple(adj_label)

    def get_embs():
        feed_dict.update({placeholders['dropout']: 0})
        emb = sess.run(model.z_mean, feed_dict=feed_dict)  # z_mean is better
        return emb

    # Train model
    for epoch in range(FLAGS.epochs):

        t = time.time()
        # Construct feed dictionary
        feed_dict = construct_feed_dict(adj_norm, adj_label, features, placeholders)
        feed_dict.update({placeholders['dropout']: FLAGS.dropout})
        # Run single weight update
        outs = sess.run([opt.opt_op, opt.cost, opt.accuracy],
                        feed_dict=feed_dict)

        # Compute average loss
        avg_cost = outs[1]
        avg_accuracy = outs[2]

        print("Epoch:", '%04d' % (epoch + 1), "train_loss=", "{:.5f}".format(avg_cost),
              "train_acc=", "{:.5f}".format(avg_accuracy),
              "time=", "{:.5f}".format(time.time() - t))

    emb = get_embs()
    n_clusters = len(set(labels))
    emb_norm = normalize_vectors(emb)
    clusters_pred = clustering(emb_norm, num_clusters=n_clusters)
    prec, rec, f1 =  pairwise_precision_recall_f1(clusters_pred, labels)
    print('pairwise precision', '{:.5f}'.format(prec),
          'recall', '{:.5f}'.format(rec),
          'f1', '{:.5f}'.format(f1))

    clusters_pred2 = clustering(features, num_clusters=n_clusters)
    prec2, rec2, f12 =  pairwise_precision_recall_f1(clusters_pred2, labels)
    print('pairwise precision', '{:.5f}'.format(prec2),
          'recall', '{:.5f}'.format(rec2),
          'f1', '{:.5f}'.format(f12))

    from sklearn.manifold import TSNE
    features_new = TSNE(learning_rate=100).fit_transform(features)
    emb_new = TSNE(learning_rate=100).fit_transform(emb_norm)

    labels = np.array(labels) + 2
    clusters_pred = np.array(clusters_pred) + 2
    clusters_pred2 = np.array(clusters_pred2) + 2

    if rawfeature == RAW_INTER_NAME:
        tSNEAnanlyse(emb_norm, labels, join(settings.PIC_DIR, "FINALResult", "rawReature_%s_gae_final_raw.png" % (name)))
        tSNEAnanlyse(features, labels, join(settings.PIC_DIR, "FINALResult", "rawReature_%s_gae_features_raw.png" % (name)))
    elif rawfeature == ATTENTIONFEATURE:
        tSNEAnanlyse(emb_new, labels, join(settings.PIC_DIR, "FINALResult", "rawReature_%s_gae_final.png" % (name)))
        tSNEAnanlyse(features_new, labels, join(settings.PIC_DIR, "FINALResult", "rawReature_%s_gae_features.png" % (name)))
        tSNEAnanlyse(emb_new, clusters_pred, join(settings.PIC_DIR, "FINALResult", "rawReature_%s_gae_final_clusterresult.png" % (name)))
        tSNEAnanlyse(features_new, clusters_pred2, join(settings.PIC_DIR, "FINALResult", "rawReature_%s_gae_features_clusterresult.png" % (name)))
    else:
        tSNEAnanlyse(emb_norm, labels, join(settings.PIC_DIR, "FINALResult", "rawReature_%s_gae_final_triplet.png" % (name)))
        tSNEAnanlyse(features, labels, join(settings.PIC_DIR, "FINALResult", "rawReature_%s_gae_features_triplet.png" % (name)))

    return [prec, rec, f1], num_nodes, n_clusters
Example #3
0
def gae_for_na(name, mode=0):
    """
    train and evaluate disambiguation results for a specific name
    :param name:  author name
    :return: evaluation results
    :mode: 0-train 1-val
    """
    pids, adj, features, labels = load_local_data(name=name)

    # Store original adjacency matrix (without diagonal entries) for later
    adj_orig = adj
    adj_orig = adj_orig - sp.dia_matrix(
        (adj_orig.diagonal()[np.newaxis, :], [0]), shape=adj_orig.shape)
    adj_orig.eliminate_zeros()
    adj_train = gen_train_edges(adj)

    adj = adj_train

    # Some preprocessing
    adj_norm = preprocess_graph(adj)
    num_nodes = adj.shape[0]
    input_feature_dim = features.shape[1]
    if FLAGS.is_sparse:  # TODO to test
        # features = sparse_to_tuple(features.tocoo())
        # features_nonzero = features[1].shape[0]
        features = features.todense()  # TODO
    else:
        features = normalize_vectors(features)

    # Define placeholders
    placeholders = {
        # 'features': tf.sparse_placeholder(tf.float32),
        'features': tf.placeholder(tf.float32,
                                   shape=(None, input_feature_dim)),
        'adj': tf.sparse_placeholder(tf.float32),
        'adj_orig': tf.sparse_placeholder(tf.float32),
        'dropout': tf.placeholder_with_default(0., shape=())
    }

    # Create model
    model = None
    if model_str == 'gcn_ae':
        model = GCNModelAE(placeholders, input_feature_dim)
    elif model_str == 'gcn_vae':
        model = GCNModelVAE(placeholders, input_feature_dim, num_nodes)
    pos_weight = float(adj.shape[0] * adj.shape[0] -
                       adj.sum()) / adj.sum()  # negative edges/pos edges
    print('positive edge weight', pos_weight)
    norm = adj.shape[0] * adj.shape[0] / float(
        (adj.shape[0] * adj.shape[0] - adj.nnz) * 2)

    # Optimizer
    with tf.name_scope('optimizer'):
        if model_str == 'gcn_ae':
            opt = OptimizerAE(preds=model.reconstructions,
                              labels=tf.reshape(
                                  tf.sparse_tensor_to_dense(
                                      placeholders['adj_orig'],
                                      validate_indices=False), [-1]),
                              pos_weight=pos_weight,
                              norm=norm)
        elif model_str == 'gcn_vae':
            opt = OptimizerVAE(preds=model.reconstructions,
                               labels=tf.reshape(
                                   tf.sparse_tensor_to_dense(
                                       placeholders['adj_orig'],
                                       validate_indices=False), [-1]),
                               model=model,
                               num_nodes=num_nodes,
                               pos_weight=pos_weight,
                               norm=norm)

    # Initialize session
    sess = tf.Session()
    sess.run(tf.global_variables_initializer())

    adj_label = adj_train + sp.eye(adj_train.shape[0])
    adj_label = sparse_to_tuple(adj_label)

    def get_embs():
        feed_dict.update({placeholders['dropout']: 0})
        emb = sess.run(model.z_mean, feed_dict=feed_dict)  # z_mean is better
        return emb

    # Train model
    for epoch in range(FLAGS.epochs):

        t = time.time()
        # Construct feed dictionary
        feed_dict = construct_feed_dict(adj_norm, adj_label, features,
                                        placeholders)
        feed_dict.update({placeholders['dropout']: FLAGS.dropout})
        # Run single weight update
        outs = sess.run([opt.opt_op, opt.cost, opt.accuracy],
                        feed_dict=feed_dict)

        # Compute average loss
        avg_cost = outs[1]
        avg_accuracy = outs[2]

        print("Epoch:", '%04d' % (epoch + 1), "train_loss=",
              "{:.5f}".format(avg_cost), "train_acc=",
              "{:.5f}".format(avg_accuracy), "time=",
              "{:.5f}".format(time.time() - t))

    emb = get_embs()

    for idx, pid in enumerate(pids):
        local_output[pid] = emb[idx]

    # Train mode calcul F1
    if not (mode == 2):
        n_clusters = len(set(labels))
        emb_norm = normalize_vectors(emb)
        model = AgglomerativeClustering(n_clusters=n_clusters)
        model.fit(emb_norm)
        prec, rec, f1 = pairwise_precision_recall_f1(model.labels_, labels)
        print('pairwise precision', '{:.5f}'.format(prec), 'recall',
              '{:.5f}'.format(rec), 'f1', '{:.5f}'.format(f1))
        return [prec, rec, f1], num_nodes, n_clusters