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decagon-pytorch/tests/decagon_pytorch/test_convolve.py

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  1. import decagon_pytorch.convolve

  2. import decagon.deep.layers

  3. import torch

  4. import tensorflow as tf

  5. import numpy as np

  6. 

  7. 

  8. def prepare_data():

  9.     np.random.seed(0)

  10.     latent = np.random.random((5, 10)).astype(np.float32)

  11.     latent[latent < .5] = 0

  12.     latent = np.ceil(latent)

  13.     adjacency_matrices = []

  14.     for _ in range(5):

  15.         adj_mat = np.random.random((len(latent),) * 2).astype(np.float32)

  16.         adj_mat[adj_mat < .5] = 0

  17.         adj_mat = np.ceil(adj_mat)

  18.         adjacency_matrices.append(adj_mat)

  19.     return latent, adjacency_matrices

  20. 

  21. 

  22. def dense_to_sparse_tf(x):

  23.     a, b = np.where(x)

  24.     indices = np.array([a, b]).T

  25.     values = x[a, b]

  26.     return tf.sparse.SparseTensor(indices, values, x.shape)

  27. 

  28. 

  29. def dropout_sparse_tf(x, keep_prob, num_nonzero_elems):

  30.     """Dropout for sparse tensors. Currently fails for very large sparse tensors (>1M elements)

  31.     """

  32.     noise_shape = [num_nonzero_elems]

  33.     random_tensor = keep_prob

  34.     random_tensor += tf.convert_to_tensor(torch.rand(noise_shape).detach().numpy())

  35.     # tf.convert_to_tensor(np.random.random(noise_shape))

  36.     # tf.random_uniform(noise_shape)

  37.     dropout_mask = tf.cast(tf.floor(random_tensor), dtype=tf.bool)

  38.     pre_out = tf.sparse_retain(x, dropout_mask)

  39.     return pre_out * (1./keep_prob)

  40. 

  41. 

  42. def sparse_graph_conv_torch():

  43.     torch.random.manual_seed(0)

  44.     latent, adjacency_matrices = prepare_data()

  45.     print('latent.dtype:', latent.dtype)

  46.     latent = torch.tensor(latent).to_sparse()

  47.     adj_mat = adjacency_matrices[0]

  48.     adj_mat = torch.tensor(adj_mat).to_sparse()

  49.     print('adj_mat.dtype:', adj_mat.dtype,

  50.         'latent.dtype:', latent.dtype)

  51.     conv = decagon_pytorch.convolve.SparseGraphConv(10, 10,

  52.         adj_mat)

  53.     latent = conv(latent)

  54.     return latent

  55. 

  56. 

  57. def sparse_graph_conv_tf():

  58.     torch.random.manual_seed(0)

  59.     latent, adjacency_matrices = prepare_data()

  60.     conv_torch = decagon_pytorch.convolve.SparseGraphConv(10, 10,

  61.         torch.tensor(adjacency_matrices[0]).to_sparse())

  62.     weight = tf.constant(conv_torch.weight.detach().numpy())

  63.     latent = dense_to_sparse_tf(latent)

  64.     adj_mat = dense_to_sparse_tf(adjacency_matrices[0])

  65.     latent = tf.sparse_tensor_dense_matmul(latent, weight)

  66.     latent = tf.sparse_tensor_dense_matmul(adj_mat, latent)

  67.     return latent

  68. 

  69. 

  70. def sparse_dropout_graph_conv_activation_torch(keep_prob=1.):

  71.     torch.random.manual_seed(0)

  72.     latent, adjacency_matrices = prepare_data()

  73.     latent = torch.tensor(latent).to_sparse()

  74.     adj_mat = adjacency_matrices[0]

  75.     adj_mat = torch.tensor(adj_mat).to_sparse()

  76.     conv = decagon_pytorch.convolve.SparseDropoutGraphConvActivation(10, 10,

  77.         adj_mat, keep_prob=keep_prob)

  78.     latent = conv(latent)

  79.     return latent

  80. 

  81. 

  82. def sparse_dropout_graph_conv_activation_tf(keep_prob=1.):

  83.     torch.random.manual_seed(0)

  84.     latent, adjacency_matrices = prepare_data()

  85.     conv_torch = decagon_pytorch.convolve.SparseGraphConv(10, 10,

  86.         torch.tensor(adjacency_matrices[0]).to_sparse())

  87. 

  88.     weight = tf.constant(conv_torch.weight.detach().numpy())

  89.     nonzero_feat = np.sum(latent > 0)

  90. 

  91.     latent = dense_to_sparse_tf(latent)

  92.     latent = dropout_sparse_tf(latent, keep_prob,

  93.         nonzero_feat)

  94. 

  95.     adj_mat = dense_to_sparse_tf(adjacency_matrices[0])

  96. 

  97.     latent = tf.sparse_tensor_dense_matmul(latent, weight)

  98.     latent = tf.sparse_tensor_dense_matmul(adj_mat, latent)

  99. 

  100.     latent = tf.nn.relu(latent)

  101. 

  102.     return latent

  103. 

  104. 

  105. def test_sparse_graph_conv():

  106.     latent_torch = sparse_graph_conv_torch()

  107.     latent_tf = sparse_graph_conv_tf()

  108.     assert np.all(latent_torch.detach().numpy() == latent_tf.eval(session = tf.Session()))

  109. 

  110. 

  111. def test_sparse_dropout_grap_conv_activation():

  112.     for i in range(11):

  113.         keep_prob = i/10. + np.finfo(np.float32).eps

  114. 

  115.         latent_torch = sparse_dropout_graph_conv_activation_torch(keep_prob)

  116.         latent_tf = sparse_dropout_graph_conv_activation_tf(keep_prob)

  117. 

  118.         latent_torch = latent_torch.detach().numpy()

  119.         latent_tf = latent_tf.eval(session = tf.Session())

  120.         print('latent_torch:', latent_torch)

  121.         print('latent_tf:', latent_tf)

  122. 

  123.         assert np.all(latent_torch - latent_tf < .000001)

  124. 

  125. 

  126. def test_sparse_multi_dgca():

  127.     pass