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decagon-pytorch/experiments/triacontagon_run/triacontagon_run.py

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  1. #!/usr/bin/env python3

  2. 

  3. from triacontagon.data import Data

  4. from triacontagon.split import split_data

  5. from triacontagon.model import Model

  6. from triacontagon.loop import TrainLoop

  7. from triacontagon.decode import dedicom_decoder

  8. from triacontagon.util import common_one_hot_encoding

  9. 

  10. import os

  11. import pandas as pd

  12. from bisect import bisect_left

  13. import torch

  14. import sys

  15. 

  16. 

  17. def index(a, x):

  18.     i = bisect_left(a, x)

  19.     if i != len(a) and a[i] == x:

  20.         return i

  21.     raise ValueError

  22. 

  23. 

  24. def load_data(dev):

  25.     path = '/pstore/data/data_science/ref/decagon'

  26. 

  27.     df_combo = pd.read_csv(os.path.join(path, 'bio-decagon-combo.csv'))

  28.     df_effcat = pd.read_csv(os.path.join(path, 'bio-decagon-effectcategories.csv'))

  29.     df_mono = pd.read_csv(os.path.join(path, 'bio-decagon-mono.csv'))

  30.     df_ppi = pd.read_csv(os.path.join(path, 'bio-decagon-ppi.csv'))

  31.     df_tgtall = pd.read_csv(os.path.join(path, 'bio-decagon-targets-all.csv'))

  32.     df_tgt = pd.read_csv(os.path.join(path, 'bio-decagon-targets.csv'))

  33. 

  34.     lst = [ 'df_combo', 'df_effcat', 'df_mono', 'df_ppi', 'df_tgtall', 'df_tgt' ]

  35. 

  36.     for nam in lst:

  37.         print(f'len({nam}): {len(locals()[nam])}')

  38.         print(f'{nam}.columns: {locals()[nam].columns}')

  39. 

  40.     genes = set()

  41.     genes = genes.union(df_ppi['Gene 1']).union(df_ppi['Gene 2']) \

  42.         .union(df_tgtall['Gene']).union(df_tgt['Gene'])

  43.     genes = sorted(genes)

  44.     print('len(genes):', len(genes))

  45. 

  46.     drugs = set()

  47.     drugs = drugs.union(df_combo['STITCH 1']).union(df_combo['STITCH 2']) \

  48.         .union(df_mono['STITCH']).union(df_tgtall['STITCH']).union(df_tgt['STITCH'])

  49.     drugs = sorted(drugs)

  50.     print('len(drugs):', len(drugs))

  51. 

  52.     data = Data()

  53.     data.add_vertex_type('Gene', len(genes))

  54.     data.add_vertex_type('Drug', len(drugs))

  55. 

  56.     print('Preparing PPI...')

  57.     print('Indexing rows...')

  58.     rows = [index(genes, g) for g in df_ppi['Gene 1']]

  59.     print('Indexing cols...')

  60.     cols = [index(genes, g) for g in df_ppi['Gene 2']]

  61.     indices = list(zip(rows, cols))

  62.     indices = torch.tensor(indices).transpose(0, 1)

  63.     values = torch.ones(len(rows))

  64.     print('indices.shape:', indices.shape, 'values.shape:', values.shape)

  65.     adj_mat = torch.sparse_coo_tensor(indices, values, size=(len(genes),) * 2,

  66.         device=dev)

  67.     adj_mat = (adj_mat + adj_mat.transpose(0, 1)) / 2

  68.     print('adj_mat created')

  69.     data.add_edge_type('PPI', 0, 0, [ adj_mat ], dedicom_decoder)

  70.     print('OK')

  71. 

  72.     print('Preparing Drug-Gene (Target) edges...')

  73.     rows = [index(drugs, d) for d in df_tgtall['STITCH']]

  74.     cols = [index(genes, g) for g in df_tgtall['Gene']]

  75.     indices = list(zip(rows, cols))

  76.     indices = torch.tensor(indices).transpose(0, 1)

  77.     values = torch.ones(len(rows))

  78.     adj_mat = torch.sparse_coo_tensor(indices, values, size=(len(drugs), len(genes)),

  79.         device=dev)

  80.     data.add_edge_type('Drug-Gene', 1, 0, [ adj_mat ], dedicom_decoder)

  81.     data.add_edge_type('Gene-Drug', 0, 1, [ adj_mat.transpose(0, 1) ], dedicom_decoder)

  82.     print('OK')

  83. 

  84.     print('Preparing Drug-Drug (Side Effect) edges...')

  85.     fam = data.add_relation_family('Drug-Drug (Side Effect)', 1, 1, True)

  86.     print('# of side effects:', len(df_combo), 'unique:', len(df_combo['Polypharmacy Side Effect'].unique()))

  87.     adjacency_matrices = []

  88.     side_effect_names = []

  89.     for eff, df in df_combo.groupby('Polypharmacy Side Effect'):

  90.         sys.stdout.write('.') # print(eff, '...')

  91.         sys.stdout.flush()

  92.         rows = [index(drugs, d) for d in df['STITCH 1']]

  93.         cols = [index(drugs, d) for d in df['STITCH 2']]

  94.         indices = list(zip(rows, cols))

  95.         indices = torch.tensor(indices).transpose(0, 1)

  96.         values = torch.ones(len(rows))

  97.         adj_mat = torch.sparse_coo_tensor(indices, values, size=(len(drugs), len(drugs)),

  98.             device=dev)

  99.         adj_mat = (adj_mat + adj_mat.transpose(0, 1)) / 2

  100.         adjacency_matrices.append(adj_mat)

  101.         side_effect_names.append(df['Polypharmacy Side Effect'])

  102.     fam.add_edge_type('Drug-Drug', 1, 1, adjacency_matrices, dedicom_decoder)

  103.     print()

  104.     print('OK')

  105. 

  106.     return data

  107. 

  108. 

  109. def _wrap(obj, method_name):

  110.     orig_fn = getattr(obj, method_name)

  111.     def fn(*args, **kwargs):

  112.         print(f'{method_name}() :: ENTER')

  113.         res = orig_fn(*args, **kwargs)

  114.         print(f'{method_name}() :: EXIT')

  115.         return res

  116.     setattr(obj, method_name, fn)

  117. 

  118. 

  119. def main():

  120.     dev = torch.device('cuda:0')

  121.     data = load_data(dev)

  122. 

  123.     train_data, val_data, test_data = split_data(data, (.8, .1, .1))

  124. 

  125.     n = sum(vt.count for vt in data.vertex_types)

  126. 

  127.     model = Model(data, [n, 32, 64], keep_prob=.9,

  128.         conv_activation=torch.sigmoid,

  129.         dec_activation=torch.sigmoid).to(dev)

  130. 

  131.     initial_repr = common_one_hot_encoding([ vt.count \

  132.         for vt in data.vertex_types ], device=dev)

  133. 

  134.     loop = TrainLoop(model, val_data, test_data,

  135.         initial_repr, max_epochs=50, batch_size=512,

  136.         loss=torch.nn.functional.binary_cross_entropy_with_logits,

  137.         lr=0.001)

  138. 

  139.     loop.run()

  140. 

  141.     with open('/pstore/data/data_science/year/2020/adaszews/models/triacontagon/basic_run.pth', 'wb') as f:

  142.         torch.save(model.state_dict(), f)

  143. 

  144. 

  145. if __name__ == '__main__':

  146.     main()