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DEVELOP.py
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DEVELOP.py
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#!/usr/bin/env/python
"""
Usage:
DEVELOP.py [options]
Options:
-h --help Show this screen
--dataset NAME Dataset name: zinc, qm9, cep
--config-file FILE Hyperparameter configuration file path (in JSON format)
--config CONFIG Hyperparameter configuration dictionary (in JSON format)
--log_dir NAME log dir name
--data_dir NAME data dir name
--restore FILE File to restore weights from.
--freeze-graph-model Freeze weights of graph model components
--restrict_data INT Limit data
--out_name NAME Name of output
"""
from typing import Sequence, Any
from docopt import docopt
from collections import defaultdict, deque
import numpy as np
import tensorflow as tf
import sys, traceback
import pdb
import json
import os
from GGNN_DEVELOP import ChemModel
import utils
from utils import *
import pickle
import random
from numpy import linalg as LA
from rdkit import Chem
from copy import deepcopy
import os
import time
from data_augmentation import *
import molgrid
'''
Comments provide the expected tensor shapes where helpful.
Key to symbols in comments:
---------------------------
[...]: a tensor
; ; : a list
b: batch size
e: number of edege types (3)
es: maximum number of BFS transitions in this batch
v: number of vertices per graph in this batch
h: GNN hidden size
j: Augmentation vector size
'''
class DenseGGNNChemModel(ChemModel):
def __init__(self, args):
super().__init__(args)
@classmethod
def default_params(cls):
params = dict(super().default_params())
params.update({
'task_sample_ratios': {},
'use_edge_bias': True, # whether use edge bias in gnn
'clamp_gradient_norm': 1.0,
'out_layer_dropout_keep_prob': 1.0,
'tie_fwd_bkwd': True,
'random_seed': 0, # fixed for reproducibility
'batch_size': 16,
'prior_learning_rate': 0.05,
'stop_criterion': 0.01,
'num_epochs': 10,
'epoch_to_generate': 10,
'number_of_generation_per_valid': 10,
'maximum_distance': 50,
"use_argmax_generation": False, # use random sampling or argmax during generation
'residual_connection_on': True, # whether residual connection is on
'residual_connections': { # For iteration i, specify list of layers whose output is added as an input
2: [0],
4: [0, 2],
6: [0, 2, 4],
8: [0, 2, 4, 6],
10: [0, 2, 4, 6, 8],
12: [0, 2, 4, 6, 8, 10],
14: [0, 2, 4, 6, 8, 10, 12],
},
'num_timesteps': 7, # gnn propagation step
'hidden_size': 32,
'encoding_size': 4,
'kl_trade_off_lambda': 0.3, # kl tradeoff
'learning_rate': 0.001,
'graph_state_dropout_keep_prob': 1,
'compensate_num': 0, # how many atoms to be added during generation
'train_file': 'data/molecules_train_zinc.json',
'valid_file': 'data/molecules_valid_zinc.json',
'train_struct_file': 'data/train_structural_info.types',
'valid_struct_file': 'data/valid_structural_info.types',
'struct_data_root': './data/',
'try_different_starting': True,
"num_different_starting": 1,
'generation': False, # only generate
'use_graph': True, # use gnn
"label_one_hot": False, # one hot label or not
"multi_bfs_path": False, # whether sample several BFS paths for each molecule
"bfs_path_count": 30,
"path_random_order": False, # False: canonical order, True: random order
"sample_transition": False, # whether to use transition sampling
'edge_weight_dropout_keep_prob': 1,
'check_overlap_edge': False,
"truncate_distance": 10,
"cnn_ligand_only": False,
"output_name": '',
'struct_data_len': 5, # length of 1D structural/pharmacophoric info
"min_atoms": 0,
"max_atoms": 0,
})
return params
def prepare_specific_graph_model(self) -> None:
h_dim = self.params['hidden_size']
out_dim = self.params['encoding_size']
expanded_h_dim=self.params['hidden_size']+self.params['hidden_size'] + 1 # 1 for focus bit
struct_dim = self.params['struct_data_len'] + 1 # 1 for iteration num
self.placeholders['graph_state_keep_prob'] = tf.placeholder(tf.float32, None, name='graph_state_keep_prob')
self.placeholders['edge_weight_dropout_keep_prob'] = tf.placeholder(tf.float32, None, name='edge_weight_dropout_keep_prob')
# initial graph representation
self.placeholders['initial_node_representation_in'] = tf.placeholder(tf.float32,
[None, None, self.params['hidden_size']],
name='node_features_in') # padded node symbols
self.placeholders['initial_node_representation_out'] = tf.placeholder(tf.float32,
[None, None, self.params['hidden_size']],
name='node_features_out') # padded node symbols
# mask out invalid node
self.placeholders['node_mask_in'] = tf.placeholder(tf.float32, [None, None], name='node_mask_in') # [b, v]
self.placeholders['node_mask_out'] = tf.placeholder(tf.float32, [None, None], name='node_mask_out') # [b, v]
self.placeholders['num_vertices'] = tf.placeholder(tf.int32, ())
# vertices to keep edges between
self.placeholders['vertices_to_keep'] = tf.placeholder(tf.float32, [None, None], name='vertices_to_keep') # [b, v]
# exit vectors
self.placeholders['exit_points'] = tf.placeholder(tf.float32, [None, None], name='exit_points') # [b, 2]
# structural informations - distance and angle between fragments
self.placeholders['abs_dist'] = tf.placeholder(tf.float32, [None, struct_dim-1], name='abs_dist') # [b, struct_info] # -1 to remove iteration num
# iteration number during generation
self.placeholders['it_num'] = tf.placeholder(tf.int32, [None], name='it_num')
# index of structural data for example
self.placeholders['sdf_idx'] = tf.placeholder(tf.int32, [None], name='sdf_idx')
# adj for encoder
self.placeholders['adjacency_matrix_in'] = tf.placeholder(tf.float32,
[None, self.num_edge_types, None, None], name="adjacency_matrix_in") # [b, e, v, v]
self.placeholders['adjacency_matrix_out'] = tf.placeholder(tf.float32,
[None, self.num_edge_types, None, None], name="adjacency_matrix_out") # [b, e, v, v]
# labels for node symbol prediction
self.placeholders['node_symbols_in'] = tf.placeholder(tf.float32, [None, None, self.params['num_symbols']]) # [b, v, edge_type]
self.placeholders['node_symbols_out'] = tf.placeholder(tf.float32, [None, None, self.params['num_symbols']]) # [b, v, edge_type]
# node symbols used to enhance latent representations
self.placeholders['latent_node_symbols_in'] = tf.placeholder(tf.float32,
[None, None, self.params['hidden_size']], name='latent_node_symbol_in') # [b, v, h]
self.placeholders['latent_node_symbols_out'] = tf.placeholder(tf.float32,
[None, None, self.params['hidden_size']], name='latent_node_symbol_out') # [b, v, h]
# mask out cross entropies in decoder
self.placeholders['iteration_mask_out']=tf.placeholder(tf.float32, [None, None]) # [b, es]
# adj matrices used in decoder
self.placeholders['incre_adj_mat_out']=tf.placeholder(tf.float32, [None, None, self.num_edge_types, None, None], name='incre_adj_mat_out') # [b, es, e, v, v]
# distance
self.placeholders['distance_to_others_out']=tf.placeholder(tf.int32, [None, None, None], name='distance_to_others_out') # [b, es, v]
# maximum iteration number of this batch
self.placeholders['max_iteration_num']=tf.placeholder(tf.int32, [], name='max_iteration_num') # number
# node number in focus at each iteration step
self.placeholders['node_sequence_out']=tf.placeholder(tf.float32, [None, None, None], name='node_sequence_out') # [b, es, v]
# mask out invalid edge types at each iteration step
self.placeholders['edge_type_masks_out']=tf.placeholder(tf.float32, [None, None, self.num_edge_types, None], name='edge_type_masks_out') # [b, es, e, v]
# ground truth edge type labels at each iteration step
self.placeholders['edge_type_labels_out']=tf.placeholder(tf.float32, [None, None, self.num_edge_types, None], name='edge_type_labels_out') # [b, es, e, v]
# mask out invalid edge at each iteration step
self.placeholders['edge_masks_out']=tf.placeholder(tf.float32, [None, None, None], name='edge_masks_out') # [b, es, v]
# ground truth edge labels at each iteration step
self.placeholders['edge_labels_out']=tf.placeholder(tf.float32, [None, None, None], name='edge_labels_out') # [b, es, v]
# ground truth labels for whether it stops at each iteration step
self.placeholders['local_stop_out']=tf.placeholder(tf.float32, [None, None], name='local_stop_out') # [b, es]
# z_prior sampled from standard normal distribution
self.placeholders['z_prior']=tf.placeholder(tf.float32, [None, None, self.params['encoding_size']], name='z_prior') # prior z ~ normal distribution - full molecule
self.placeholders['z_prior_in']=tf.placeholder(tf.float32, [None, None, self.params['hidden_size']], name='z_prior_in') # prior z ~ normal distribution - fragments
# put in front of kl latent loss
self.placeholders['kl_trade_off_lambda']=tf.placeholder(tf.float32, [], name='kl_trade_off_lambda') # number
# overlapped edge features
#self.placeholders['overlapped_edge_features_in']=tf.placeholder(tf.int32, [None, None, None], name='overlapped_edge_features_in') # [b, es, v]
self.placeholders['overlapped_edge_features_out']=tf.placeholder(tf.int32, [None, None, None], name='overlapped_edge_features_out') # [b, es, v]
# CNN input
self.placeholders['cnn_input'] = tf.placeholder(tf.float32, [None, None, None, None, None], name="cnn_input") # [b, n_channels, x, y, z]
# weights for encoder and decoder GNN.
if self.params["residual_connection_on"]:
# weights for encoder and decoder GNN. Different weights for each iteration
for scope in ['_encoder', '_decoder']:
if scope == '_encoder':
new_h_dim=h_dim
else:
new_h_dim=expanded_h_dim
for iter_idx in range(self.params['num_timesteps']):
with tf.variable_scope("gru_scope"+scope+str(iter_idx), reuse=False):
self.weights['edge_weights'+scope+str(iter_idx)] = tf.Variable(glorot_init([self.num_edge_types, new_h_dim, new_h_dim]))
if self.params['use_edge_bias']:
self.weights['edge_biases'+scope+str(iter_idx)] = tf.Variable(np.zeros([self.num_edge_types, 1, new_h_dim]).astype(np.float32))
cell = tf.contrib.rnn.GRUCell(new_h_dim)
cell = tf.nn.rnn_cell.DropoutWrapper(cell,
state_keep_prob=self.placeholders['graph_state_keep_prob'])
self.weights['node_gru'+scope+str(iter_idx)] = cell
else:
for scope in ['_encoder', '_decoder']:
if scope == '_encoder':
new_h_dim=h_dim
else:
new_h_dim=expanded_h_dim
self.weights['edge_weights'+scope] = tf.Variable(glorot_init([self.num_edge_types, new_h_dim, new_h_dim]))
if self.params['use_edge_bias']:
self.weights['edge_biases'+scope] = tf.Variable(np.zeros([self.num_edge_types, 1, new_h_dim]).astype(np.float32))
with tf.variable_scope("gru_scope"+scope):
cell = tf.contrib.rnn.GRUCell(new_h_dim)
cell = tf.nn.rnn_cell.DropoutWrapper(cell,
state_keep_prob=self.placeholders['graph_state_keep_prob'])
self.weights['node_gru'+scope] = cell
# weights for calculating mean and variance
self.weights['mean_weights'] = tf.Variable(glorot_init([h_dim, h_dim]))
self.weights['mean_biases'] = tf.Variable(np.zeros([1, h_dim]).astype(np.float32))
self.weights['variance_weights'] = tf.Variable(glorot_init([h_dim, h_dim]))
self.weights['variance_biases'] = tf.Variable(np.zeros([1, h_dim]).astype(np.float32))
self.weights['mean_weights_out'] = tf.Variable(glorot_init([h_dim, out_dim]))
self.weights['mean_biases_out'] = tf.Variable(np.zeros([1, out_dim]).astype(np.float32))
self.weights['variance_weights_out'] = tf.Variable(glorot_init([h_dim, out_dim]))
self.weights['variance_biases_out'] = tf.Variable(np.zeros([1, out_dim]).astype(np.float32))
# The weights for combining means and variances
self.weights['mean_combine_weights_in'] = tf.Variable(glorot_init([out_dim, h_dim]))
self.weights['atten_weights_c_in'] = tf.Variable(glorot_init([h_dim, h_dim]))
self.weights['atten_weights_y_in'] = tf.Variable(glorot_init([h_dim, h_dim]))
# The attention weights for node symbols
self.weights['node_combine_weights_in'] = tf.Variable(glorot_init([h_dim+struct_dim+16, h_dim+struct_dim+16]))
self.weights['node_atten_weights_c_in'] = tf.Variable(glorot_init([h_dim+struct_dim+16, h_dim+struct_dim+16]))
self.weights['node_atten_weights_y_in'] = tf.Variable(glorot_init([h_dim+struct_dim+16, h_dim+struct_dim+16]))
# The weights for generating node symbol logits
self.weights['node_symbol_weights_in'] = tf.Variable(glorot_init([h_dim+struct_dim+16, self.params['num_symbols']]))
self.weights['node_symbol_biases_in'] = tf.Variable(np.zeros([1, self.params['num_symbols']]).astype(np.float32))
feature_dimension=6*expanded_h_dim
# record the total number of features
self.params["feature_dimension"] = 6
# weights for generating edge type logits
direc = "in"
for i in range(self.num_edge_types):
self.weights['edge_type_%d_%s' % (i, direc)] = tf.Variable(glorot_init([feature_dimension+struct_dim+16, feature_dimension+struct_dim+16]))
self.weights['edge_type_biases_%d_%s' % (i, direc)] = tf.Variable(np.zeros([1, feature_dimension+struct_dim+16]).astype(np.float32))
self.weights['edge_type_output_%d_%s' % (i, direc)] = tf.Variable(glorot_init([feature_dimension+struct_dim+16, 1]))
# weights for generating edge logits
self.weights['edge_iteration_'+direc] = tf.Variable(glorot_init([feature_dimension+struct_dim+16, feature_dimension+struct_dim+16]))
self.weights['edge_iteration_biases_'+direc] = tf.Variable(np.zeros([1, feature_dimension+struct_dim+16]).astype(np.float32))
self.weights['edge_iteration_output_'+direc] = tf.Variable(glorot_init([feature_dimension+struct_dim+16, 1]))
# Weights for the stop node
self.weights["stop_node_"+direc] = tf.Variable(glorot_init([1, expanded_h_dim]))
# Weight for distance embedding
self.weights['distance_embedding_'+direc] = tf.Variable(glorot_init([self.params['maximum_distance'], expanded_h_dim]))
# Weight for overlapped edge feature
self.weights["overlapped_edge_weight_"+direc] = tf.Variable(glorot_init([2, expanded_h_dim]))
# use node embeddings
self.weights["node_embedding"]= tf.Variable(glorot_init([self.params["num_symbols"], h_dim]))
# graph state mask
self.ops['graph_state_mask_in']= tf.expand_dims(self.placeholders['node_mask_in'], 2)
self.ops['graph_state_mask_out']= tf.expand_dims(self.placeholders['node_mask_out'], 2)
# weights for the CNN
if self.params['cnn_ligand_only']:
self.params['cnn_input_channels'] = 14
else:
self.params['cnn_input_channels'] = 28
self.weights['cnn_0'] = tf.Variable(glorot_init([3, 3, 3, self.params['cnn_input_channels'], 32]))
self.weights['cnn_biases_0'] = tf.Variable(np.zeros([32]).astype(np.float32))
self.weights['cnn_1'] = tf.Variable(glorot_init([3, 3, 3, 32, 64]))
self.weights['cnn_biases_1'] = tf.Variable(np.zeros([64]).astype(np.float32))
self.weights['cnn_2'] = tf.Variable(glorot_init([3, 3, 3, 64, 128]))
self.weights['cnn_biases_2'] = tf.Variable(np.zeros([128]).astype(np.float32))
self.weights['cnn_linear'] = tf.Variable(glorot_init([128, 16]))
# transform one hot vector to dense embedding vectors
def get_node_embedding_state(self, one_hot_state, source=False):
node_nums=tf.argmax(one_hot_state, axis=2)
if source:
return tf.nn.embedding_lookup(self.weights["node_embedding"], node_nums) * self.ops['graph_state_mask_in']
else:
return tf.nn.embedding_lookup(self.weights["node_embedding"], node_nums) * self.ops['graph_state_mask_out']
def compute_final_node_representations_with_residual(self, h, adj, scope_name): # scope_name: _encoder or _decoder
# h: initial representation, adj: adjacency matrix, different GNN parameters for encoder and decoder
v = self.placeholders['num_vertices']
# _decoder uses a larger latent space because concat of symbol and latent representation
if scope_name=="_decoder":
h_dim = self.params['hidden_size'] + self.params['hidden_size'] + 1
else:
h_dim = self.params['hidden_size']
h = tf.reshape(h, [-1, h_dim]) # [b*v, h]
# record all hidden states at each iteration
all_hidden_states=[h]
for iter_idx in range(self.params['num_timesteps']):
with tf.variable_scope("gru_scope"+scope_name+str(iter_idx), reuse=None) as g_scope:
for edge_type in range(self.num_edge_types):
# the message passed from this vertice to other vertices
m = tf.matmul(h, self.weights['edge_weights'+scope_name+str(iter_idx)][edge_type]) # [b*v, h]
if self.params['use_edge_bias']:
m += self.weights['edge_biases'+scope_name+str(iter_idx)][edge_type] # [b, v, h]
m = tf.reshape(m, [-1, v, h_dim]) # [b, v, h]
# collect the messages from other vertices to each vertice
if edge_type == 0:
acts = tf.matmul(adj[edge_type], m)
else:
acts += tf.matmul(adj[edge_type], m)
# all messages collected for each node
acts = tf.reshape(acts, [-1, h_dim]) # [b*v, h]
# add residual connection here
layer_residual_connections = self.params['residual_connections'].get(iter_idx)
if layer_residual_connections is None:
layer_residual_states = []
else:
layer_residual_states = [all_hidden_states[residual_layer_idx]
for residual_layer_idx in layer_residual_connections]
# concat current hidden states with residual states
acts= tf.concat([acts] + layer_residual_states, axis=1) # [b, (1+num residual connection)* h]
# feed msg inputs and hidden states to GRU
h = self.weights['node_gru'+scope_name+str(iter_idx)](acts, h)[1] # [b*v, h]
# record the new hidden states
all_hidden_states.append(h)
last_h = tf.reshape(all_hidden_states[-1], [-1, v, h_dim])
return last_h
def compute_final_node_representations_without_residual(self, h, adj, edge_weights, edge_biases, node_gru, gru_scope_name):
# h: initial representation, adj: adjacency matrix, different GNN parameters for encoder and decoder
v = self.placeholders['num_vertices']
if gru_scope_name=="gru_scope_decoder":
h_dim = self.params['hidden_size'] + self.params['hidden_size']
else:
h_dim = self.params['hidden_size']
h = tf.reshape(h, [-1, h_dim])
with tf.variable_scope(gru_scope_name) as scope:
for i in range(self.params['num_timesteps']):
if i > 0:
tf.get_variable_scope().reuse_variables()
for edge_type in range(self.num_edge_types):
m = tf.matmul(h, tf.nn.dropout(edge_weights[edge_type],
keep_prob=self.placeholders['edge_weight_dropout_keep_prob'])) # [b*v, h]
if self.params['use_edge_bias']:
m += edge_biases[edge_type] # [b, v, h]
m = tf.reshape(m, [-1, v, h_dim]) # [b, v, h]
if edge_type == 0:
acts = tf.matmul(adj[edge_type], m)
else:
acts += tf.matmul(adj[edge_type], m)
acts = tf.reshape(acts, [-1, h_dim]) # [b*v, h]
h = node_gru(acts, h)[1] # [b*v, h]
last_h = tf.reshape(h, [-1, v, h_dim])
return last_h
def setup_cnn(self, weights, cnn_input, cnn_scope_name):
with tf.variable_scope(cnn_scope_name) as scope:
conv0 = tf.nn.relu(tf.nn.bias_add(tf.nn.conv3d(cnn_input, weights['cnn_0'], strides=[1, 1, 1, 1, 1], padding='SAME', data_format='NCDHW'),
weights['cnn_biases_0'], data_format='NCDHW'))
pool0 = tf.nn.max_pool3d(conv0, ksize=[1, 1, 2, 2, 2], strides=[1, 1, 2, 2, 2], padding='SAME', data_format='NCDHW')
conv1 = tf.nn.relu(tf.nn.bias_add(tf.nn.conv3d(pool0, weights['cnn_1'], strides=[1, 1, 1, 1, 1], padding='SAME', data_format='NCDHW'),
weights['cnn_biases_1'], data_format='NCDHW'))
pool1 = tf.nn.max_pool3d(conv1, ksize=[1, 1, 2, 2, 2], strides=[1, 1, 2, 2, 2], padding='SAME', data_format='NCDHW')
conv2 = tf.nn.relu(tf.nn.bias_add(tf.nn.conv3d(pool1, weights['cnn_2'], strides=[1, 1, 1, 1, 1], padding='SAME', data_format='NCDHW'),
weights['cnn_biases_2'], data_format='NCDHW'))
pool2 = tf.reduce_max(conv2, axis=[2, 3, 4])
flat = tf.layers.flatten(pool2, data_format='channels_first')
flat = tf.nn.dropout(flat, rate=0.2)
dense = tf.matmul(flat, weights['cnn_linear'])
return dense
def compute_mean_and_logvariance(self):
v = self.placeholders['num_vertices']
h_dim = self.params['hidden_size']
out_dim = self.params['encoding_size']
# AVERAGE ENCODING - full molecule
avg_last_h_out = tf.reduce_sum(self.ops['final_node_representations_out'] * self.ops['graph_state_mask_out'], 1) / \
tf.reduce_sum(self.ops['graph_state_mask_out'], 1) # [b, 1, h] - mask out unused nodes
mean_out = tf.matmul(avg_last_h_out, self.weights['mean_weights_out']) + self.weights['mean_biases_out']
logvariance_out = tf.matmul(avg_last_h_out, self.weights['variance_weights_out']) + self.weights['variance_biases_out']
mean_out_ex = tf.reshape(tf.tile(tf.expand_dims(mean_out, 1), [1, v, 1]), [-1, out_dim])
logvariance_out_ex = tf.reshape(tf.tile(tf.expand_dims(logvariance_out,1), [1, v, 1]), [-1, out_dim])
# PER VERTEX ENCODING - unlinked fragments
reshaped_last_h = tf.reshape(self.ops['final_node_representations_in'], [-1, h_dim])
mean = tf.matmul(reshaped_last_h, self.weights['mean_weights']) + self.weights['mean_biases']
logvariance = tf.matmul(reshaped_last_h, self.weights['variance_weights']) + self.weights['variance_biases']
return mean, logvariance, mean_out_ex, logvariance_out_ex
def sample_with_mean_and_logvariance(self):
v = self.placeholders['num_vertices']
h_dim = self.params['hidden_size']
out_dim = self.params['encoding_size']
# Sample from normal distribution
z_prior = tf.reshape(self.placeholders['z_prior'], [-1, out_dim]) # Encoding of full molecule
z_prior_in = tf.reshape(self.placeholders['z_prior_in'], [-1, h_dim]) # Hidden node vectors
# Train: sample from N(u, Sigma). Generation: sample from N(0,1)
z_sampled = tf.cond(self.placeholders['is_generative'], lambda: z_prior, # standard normal
lambda: tf.add(self.ops['mean_out'], tf.multiply(tf.sqrt(tf.exp(self.ops['logvariance_out'])), z_prior))) # non-standard normal
z_frags_sampled = tf.add(self.ops['mean'], tf.multiply(tf.sqrt(tf.exp(self.ops['logvariance'])), z_prior_in))
# Update node representations
# Prepare fragments node embeddings
mean = tf.reshape(self.ops['mean'], [-1, v, h_dim])
mean = mean * self.ops['graph_state_mask_in'] # Mask out nodes not in graph
inverted_mask = tf.ones(tf.shape(self.ops['graph_state_mask_in'])) - self.ops['graph_state_mask_in']
update_vals = self.placeholders['z_prior_in'] * inverted_mask # Add extra nodes sampled from N(0,1)
mean = tf.reshape(tf.add(mean, update_vals), [-1, h_dim]) # Fill in extra vertices with random noise from N(0,1)
# Combine fragments node embeddings with full molecule embedding
# Attention mechanism over in_mol encodings to determine combination with z_sampled
atten_masks_c = tf.tile(tf.expand_dims(self.ops['graph_state_mask_out'], 2), [1, 1, v, 1]) * LARGE_NUMBER - LARGE_NUMBER
atten_masks_yi = tf.tile(tf.expand_dims(self.ops['graph_state_mask_out'], 1), [1, v, 1, 1]) * LARGE_NUMBER - LARGE_NUMBER
atten_masks = atten_masks_c + atten_masks_yi
atten_c = tf.tile(tf.expand_dims(tf.reshape(mean, [-1, v, h_dim]), 2), [1, 1, v, 1]) # [b, v, v, h]
atten_yi = tf.tile(tf.expand_dims(tf.reshape(mean, [-1, v, h_dim]), 1), [1, v, 1, 1]) # [b, v, v, h]
atten_c = tf.reshape(tf.matmul(tf.reshape(atten_c, [-1, h_dim]), self.weights['atten_weights_c_in']), [-1, v, v, h_dim])
atten_yi = tf.reshape(tf.matmul(tf.reshape(atten_yi, [-1, h_dim]), self.weights['atten_weights_y_in']), [-1, v, v, h_dim])
atten_mi = tf.nn.sigmoid(tf.add(atten_c, atten_yi) + atten_masks)
atten_mi = tf.reduce_sum(atten_mi, 2) / tf.tile(tf.expand_dims(tf.reduce_sum(self.ops['graph_state_mask_out'], 1), 1), [1, v, 1])
z_sampled = tf.reshape(tf.matmul(z_sampled, self.weights['mean_combine_weights_in']), [-1, v, h_dim])
mean_sampled = tf.reshape(mean, [-1, v, h_dim]) * self.ops['graph_state_mask_out'] + atten_mi * z_sampled
return mean_sampled
def fully_connected(self, input, hidden_weight, hidden_bias, output_weight):
output=tf.nn.relu(tf.matmul(input, hidden_weight) + hidden_bias)
output=tf.matmul(output, output_weight)
return output
def generate_cross_entropy(self, idx, cross_entropy_losses, edge_predictions, edge_type_predictions):
direc = "out"
direc_r = "in"
v = self.placeholders['num_vertices']
h_dim = self.params['hidden_size']
num_symbols = self.params['num_symbols']
batch_size = tf.shape(self.placeholders['initial_node_representation_'+direc])[0]
# Use latent representation as decoder GNN'input
filtered_z_sampled = self.ops["initial_repre_for_decoder_"+direc_r] # [b, v, h+h]
# data needed in this iteration
incre_adj_mat = self.placeholders['incre_adj_mat_'+direc][:,idx,:,:, :] # [b, e, v, v]
distance_to_others = self.placeholders['distance_to_others_'+direc][:, idx, :] # [b, v]
overlapped_edge_features = self.placeholders['overlapped_edge_features_'+direc][:, idx, :] # [b, v]
node_sequence = self.placeholders['node_sequence_'+direc][:, idx, :] # [b, v]
node_sequence = tf.expand_dims(node_sequence, axis=2) # [b,v, 1]
edge_type_masks = self.placeholders['edge_type_masks_'+direc][:, idx, :, :] # [b, e, v]
# make invalid locations to be very small before using softmax function
edge_type_masks = edge_type_masks * LARGE_NUMBER - LARGE_NUMBER
edge_type_labels = self.placeholders['edge_type_labels_'+direc][:, idx, :, :] # [b, e, v]
edge_masks=self.placeholders['edge_masks_'+direc][:, idx, :] # [b, v]
# make invalid locations to be very small before using softmax function
edge_masks = edge_masks * LARGE_NUMBER - LARGE_NUMBER
edge_labels = self.placeholders['edge_labels_'+direc][:, idx, :] # [b, v]
local_stop = self.placeholders['local_stop_'+direc][:, idx] # [b]
# concat the hidden states with the node in focus
filtered_z_sampled = tf.concat([filtered_z_sampled, node_sequence], axis=2) # [b, v, h + h + 1]
# Decoder GNN
if self.params["use_graph"]:
if self.params["residual_connection_on"]:
new_filtered_z_sampled = self.compute_final_node_representations_with_residual(filtered_z_sampled,
tf.transpose(incre_adj_mat, [1, 0, 2, 3]),
"_decoder") # [b, v, h + h]
else:
new_filtered_z_sampled = self.compute_final_node_representations_without_residual(filtered_z_sampled,
tf.transpose(incre_adj_mat, [1, 0, 2, 3]),
self.weights['edge_weights_decoder'],
self.weights['edge_biases_decoder'],
self.weights['node_gru_decoder'], "gru_scope_decoder") # [b, v, h + h]
else:
new_filtered_z_sampled = filtered_z_sampled
# Filter nonexist nodes
new_filtered_z_sampled=new_filtered_z_sampled * self.ops['graph_state_mask_'+direc]
# Take out the node in focus
node_in_focus = tf.reduce_sum(node_sequence * new_filtered_z_sampled, axis=1)# [b, h + h]
# edge pair representation
edge_repr=tf.concat(\
[tf.tile(tf.expand_dims(node_in_focus, 1), [1,v,1]), new_filtered_z_sampled], axis=2) # [b, v, 2*(h+h)]
#combine edge repre with local and global repr
local_graph_repr_before_expansion = tf.reduce_sum(new_filtered_z_sampled, axis=1) / \
tf.reduce_sum(self.placeholders['node_mask_'+direc], axis=1, keep_dims=True) # [b, h + h]
local_graph_repr = tf.expand_dims(local_graph_repr_before_expansion, 1)
local_graph_repr = tf.tile(local_graph_repr, [1,v,1]) # [b, v, h+h]
global_graph_repr_before_expansion = tf.reduce_sum(filtered_z_sampled, axis=1) / \
tf.reduce_sum(self.placeholders['node_mask_'+direc], axis=1, keep_dims=True)
global_graph_repr = tf.expand_dims(global_graph_repr_before_expansion, 1)
global_graph_repr = tf.tile(global_graph_repr, [1,v,1]) # [b, v, h+h]
# distance representation
distance_repr = tf.nn.embedding_lookup(self.weights['distance_embedding_'+direc_r], distance_to_others) # [b, v, h+h]
# overlapped edge feature representation
overlapped_edge_repr = tf.nn.embedding_lookup(self.weights['overlapped_edge_weight_'+direc_r], overlapped_edge_features) # [b, v, h+h]
# concat and reshape.
combined_edge_repr = tf.concat([edge_repr, local_graph_repr,
global_graph_repr, distance_repr, overlapped_edge_repr], axis=2)
combined_edge_repr = tf.reshape(combined_edge_repr, [-1, self.params["feature_dimension"]*(h_dim + h_dim + 1)])
# Add 1D structural/pharmacophoric info and iteration number
dist = tf.reshape(tf.tile(tf.reshape(self.placeholders['abs_dist'], [-1,1,self.params['struct_data_len']]), [1, v, 1]), [-1, self.params['struct_data_len']])
it_num = tf.tile(tf.reshape([tf.cast(idx+self.placeholders['it_num'], tf.float32)], [1, 1]), [tf.shape(combined_edge_repr)[0], 1])
# Add cnn featurisation
cnn_features = tf.reshape(tf.tile(tf.reshape(self.ops['cnn_features'], [-1, 1, 16]), [1, v, 1]), [-1, 16])
# Concatenate
pos_info = tf.concat([dist, it_num, cnn_features], axis=1)
combined_edge_repr = tf.concat([combined_edge_repr, pos_info], axis=1)
# Calculate edge logits
edge_logits=self.fully_connected(combined_edge_repr, self.weights['edge_iteration_'+direc_r],
self.weights['edge_iteration_biases_'+direc_r], self.weights['edge_iteration_output_'+direc_r])
edge_logits=tf.reshape(edge_logits, [-1, v]) # [b, v]
# filter invalid terms
edge_logits=edge_logits + edge_masks
# Calculate whether it will stop at this step
# prepare the data
expanded_stop_node = tf.tile(self.weights['stop_node_'+direc_r], [batch_size, 1]) # [b, h + h]
distance_to_stop_node = tf.nn.embedding_lookup(self.weights['distance_embedding_'+direc_r], tf.tile([0], [batch_size])) # [b, h + h]
overlap_edge_stop_node = tf.nn.embedding_lookup(self.weights['overlapped_edge_weight_'+direc_r], tf.tile([0], [batch_size])) # [b, h + h]
combined_stop_node_repr = tf.concat([node_in_focus, expanded_stop_node, local_graph_repr_before_expansion,
global_graph_repr_before_expansion, distance_to_stop_node, overlap_edge_stop_node], axis=1) # [b, 6 * (h + h)]
# Add 1D structural/pharmacophoric info and iteration number
dist = self.placeholders['abs_dist']
it_num = tf.tile(tf.reshape([tf.cast(idx+self.placeholders['it_num'], tf.float32)], [1, 1]), [tf.shape(combined_stop_node_repr)[0], 1])
# Add cnn featurisation
cnn_features = self.ops['cnn_features']
# Concatenate
pos_info = tf.concat([dist, it_num, cnn_features], axis=1)
combined_stop_node_repr = tf.concat([combined_stop_node_repr, pos_info], axis=1)
# logits for stop node
stop_logits = self.fully_connected(combined_stop_node_repr,
self.weights['edge_iteration_'+direc_r], self.weights['edge_iteration_biases_'+direc_r],
self.weights['edge_iteration_output_'+direc_r]) # [b, 1]
edge_logits = tf.concat([edge_logits, stop_logits], axis=1) # [b, v + 1]
# Calculate edge type logits
edge_type_logits = []
for i in range(self.num_edge_types):
edge_type_logit = self.fully_connected(combined_edge_repr,
self.weights['edge_type_%d_%s' % (i, direc_r)], self.weights['edge_type_biases_%d_%s' % (i, direc_r)],
self.weights['edge_type_output_%d_%s' % (i, direc_r)]) #[b * v, 1]
edge_type_logits.append(tf.reshape(edge_type_logit, [-1, 1, v])) # [b, 1, v]
edge_type_logits = tf.concat(edge_type_logits, axis=1) # [b, e, v]
# filter invalid items
edge_type_logits = edge_type_logits + edge_type_masks # [b, e, v]
# softmax over edge type axis
edge_type_probs = tf.nn.softmax(edge_type_logits, 1) # [b, e, v]
# edge labels
edge_labels = tf.concat([edge_labels,tf.expand_dims(local_stop, 1)], axis=1) # [b, v + 1]
# softmax for edge
edge_loss =- tf.reduce_sum(tf.log(tf.nn.softmax(edge_logits) + SMALL_NUMBER) * edge_labels, axis=1)
# softmax for edge type
edge_type_loss =- edge_type_labels * tf.log(edge_type_probs + SMALL_NUMBER) # [b, e, v]
edge_type_loss = tf.reduce_sum(edge_type_loss, axis=[1, 2]) # [b]
# total loss
iteration_loss = edge_loss + edge_type_loss
cross_entropy_losses = cross_entropy_losses.write(idx, iteration_loss)
edge_predictions = edge_predictions.write(idx, tf.nn.softmax(edge_logits))
edge_type_predictions = edge_type_predictions.write(idx, edge_type_probs)
return (idx+1, cross_entropy_losses, edge_predictions, edge_type_predictions)
def construct_logit_matrices(self):
v = self.placeholders['num_vertices']
batch_size=tf.shape(self.placeholders['initial_node_representation_out'])[0]
h_dim = self.params['hidden_size']
struct_dim = self.params['struct_data_len'] + 1 # 1 for iteration num
in_direc = "in"
out_direc = "out"
# Initial state: embedding
latent_node_state= self.get_node_embedding_state(self.placeholders["latent_node_symbols_"+out_direc], source=False)
# Concat z_sampled with node symbols
filtered_z_sampled = tf.concat([self.ops['z_sampled_'+in_direc],
latent_node_state], axis=2) # [b, v, h + h]
self.ops["initial_repre_for_decoder_"+in_direc] = filtered_z_sampled
# The tensor array used to collect the cross entropy losses at each step
cross_entropy_losses = tf.TensorArray(dtype=tf.float32, size=self.placeholders['max_iteration_num'])
edge_predictions= tf.TensorArray(dtype=tf.float32, size=self.placeholders['max_iteration_num'])
edge_type_predictions = tf.TensorArray(dtype=tf.float32, size=self.placeholders['max_iteration_num'])
idx_final, cross_entropy_losses_final, edge_predictions_final,edge_type_predictions_final=\
tf.while_loop(lambda idx, cross_entropy_losses,edge_predictions,edge_type_predictions: idx < self.placeholders['max_iteration_num'],
self.generate_cross_entropy,
(tf.constant(0), cross_entropy_losses,edge_predictions,edge_type_predictions,))
# Record the predictions for generation
self.ops['edge_predictions_'+in_direc] = edge_predictions_final.read(0)
self.ops['edge_type_predictions_'+in_direc] = edge_type_predictions_final.read(0)
# Final cross entropy losses
cross_entropy_losses_final = cross_entropy_losses_final.stack()
self.ops['cross_entropy_losses_'+in_direc] = tf.transpose(cross_entropy_losses_final, [1,0]) # [b, es]
# Attention mechanism for node symbols
dist = tf.tile(tf.reshape(self.placeholders['abs_dist'], [-1,1,self.params['struct_data_len']]), [1, v, 1]) # [b, v, 2]
num_atoms = tf.expand_dims(tf.tile(tf.reduce_sum(self.placeholders['node_mask_'+out_direc]-self.placeholders['node_mask_'+in_direc], axis=1, keepdims=True), [1, v]), 2) # [b, v, 1]
cnn_features = tf.tile(tf.reshape(self.ops['cnn_features'], [-1, 1, 16]), [1, v, 1]) # [b, v, 16]
pos_info = tf.concat([dist, num_atoms, cnn_features], axis=2) # [b, v, 3+16]
z_sampled = tf.concat([self.ops['z_sampled_'+in_direc], pos_info], axis=2) # [b, v, h+3+16]
atten_masks_c = tf.tile(tf.expand_dims(self.ops['graph_state_mask_'+out_direc]-self.ops['graph_state_mask_'+in_direc], 2), [1, 1, v, 1]) * LARGE_NUMBER - LARGE_NUMBER # Mask using out_mol not in_mol
atten_masks_yi = tf.tile(tf.expand_dims(self.ops['graph_state_mask_'+out_direc]-self.ops['graph_state_mask_'+in_direc], 1), [1, v, 1, 1]) * LARGE_NUMBER - LARGE_NUMBER
atten_masks = atten_masks_c + atten_masks_yi
atten_c = tf.tile(tf.expand_dims(z_sampled, 2), [1, 1, v, 1]) # [b, v, v, h+3+16]
atten_yi = tf.tile(tf.expand_dims(z_sampled, 1), [1, v, 1, 1]) # [b, v, v, h+3+16]
atten_c = tf.reshape(tf.matmul(tf.reshape(atten_c, [-1, h_dim+struct_dim+16]), self.weights['node_atten_weights_c_'+in_direc]), [-1, v, v, h_dim+struct_dim+16])
atten_yi = tf.reshape(tf.matmul(tf.reshape(atten_yi, [-1, h_dim+struct_dim+16]), self.weights['node_atten_weights_y_'+in_direc]), [-1, v, v, h_dim+struct_dim+16])
atten_mi = tf.nn.sigmoid(tf.add(atten_c, atten_yi) + atten_masks)
atten_mi = tf.reduce_sum(atten_mi, 2) / tf.tile(tf.expand_dims(tf.reduce_sum(self.ops['graph_state_mask_'+out_direc], 1), 1), [1, v, 1]) # Mask using out_mol not in_mol
z_sampled = z_sampled * self.ops['graph_state_mask_'+in_direc] +\
atten_mi * tf.reshape(tf.matmul(tf.reshape(z_sampled, [-1, h_dim+struct_dim+16]), self.weights['node_combine_weights_'+in_direc]), [-1, v, h_dim+struct_dim+16])
# Logits for node symbols
self.ops['node_symbol_logits_'+in_direc]=tf.reshape(tf.matmul(tf.reshape(z_sampled,[-1, h_dim+struct_dim+16]), self.weights['node_symbol_weights_'+in_direc]) +
self.weights['node_symbol_biases_'+in_direc], [-1, v, self.params['num_symbols']])
def construct_loss(self):
v = self.placeholders['num_vertices']
h_dim = self.params['hidden_size']
out_dim = self.params['encoding_size']
kl_trade_off_lambda =self.placeholders['kl_trade_off_lambda']
in_direc = "in"
out_direc = "out"
# Edge loss
self.ops["edge_loss_"+in_direc] = tf.reduce_sum(self.ops['cross_entropy_losses_'+in_direc] * self.placeholders['iteration_mask_'+out_direc], axis=1)
# KL loss
# Node embeddings in fragments
kl_loss_in = 1 + self.ops['logvariance'] - tf.square(self.ops['mean']) - tf.exp(self.ops['logvariance'])
kl_loss_in = tf.reshape(kl_loss_in, [-1, v, h_dim]) * self.ops['graph_state_mask_'+in_direc] # Only penalise for nodes in graph
# Full molecule embedding
kl_loss_noise = 1 + self.ops['logvariance_out'] - tf.square(self.ops['mean_out']) - tf.exp(self.ops['logvariance_out'])
kl_loss_noise = tf.reshape(kl_loss_noise, [-1, v, out_dim]) * self.ops['graph_state_mask_'+out_direc] # Only penalise for nodes in graph
self.ops['kl_loss_'+in_direc] = -0.5 * tf.reduce_sum(kl_loss_in, [1,2]) - 0.5 * tf.reduce_sum(kl_loss_noise, [1,2])
# Node symbol loss
self.ops['node_symbol_prob_'+in_direc] = tf.nn.softmax(self.ops['node_symbol_logits_'+in_direc])
self.ops['node_symbol_loss_'+in_direc] = -tf.reduce_sum(tf.log(self.ops['node_symbol_prob_'+in_direc] + SMALL_NUMBER) *
self.placeholders['node_symbols_'+out_direc], axis=[1,2])
# Overall losses
self.ops['mean_edge_loss_'+in_direc] = tf.reduce_mean(self.ops["edge_loss_"+in_direc])
self.ops['mean_node_symbol_loss_'+in_direc] = tf.reduce_mean(self.ops["node_symbol_loss_"+in_direc])
self.ops['mean_kl_loss_'+in_direc] = tf.reduce_mean(kl_trade_off_lambda *self.ops['kl_loss_'+in_direc])
return tf.reduce_mean(self.ops["edge_loss_in"] + self.ops['node_symbol_loss_in'] +\
kl_trade_off_lambda *self.ops['kl_loss_in'])
def gated_regression(self, last_h, regression_gate, regression_transform, hidden_size, projection_weight, projection_bias, v, mask):
# last_h: [b x v x h]
last_h = tf.reshape(last_h, [-1, hidden_size]) # [b*v, h]
# linear projection on last_h
last_h = tf.nn.relu(tf.matmul(last_h, projection_weight)+projection_bias) # [b*v, h]
# same as last_h
gate_input = last_h
# linear projection and combine
gated_outputs = tf.nn.sigmoid(regression_gate(gate_input)) * tf.nn.tanh(regression_transform(last_h)) # [b*v, 1]
gated_outputs = tf.reshape(gated_outputs, [-1, v]) # [b, v]
masked_gated_outputs = gated_outputs * mask # [b x v]
output = tf.reduce_sum(masked_gated_outputs, axis = 1) # [b]
output=tf.sigmoid(output)
return output
def calculate_incremental_results(self, raw_data, bucket_sizes, file_name, is_training_data):
incremental_results=[[], []]
# Copy the raw_data if more than 1 BFS path is added
new_raw_data=[]
for idx, d in enumerate(raw_data):
out_direc = "out"
res_idx = 1
# Use canonical order or random order here. canonical order starts from index 0. random order starts from random nodes
if not self.params["path_random_order"]:
# Use several different starting index if using multi BFS path
if self.params["multi_bfs_path"]:
list_of_starting_idx= list(range(self.params["bfs_path_count"]))
else:
list_of_starting_idx=[0] # the index 0
else:
# Get the node length for this output molecule
node_length=len(d["node_features_"+out_direc])
if self.params["multi_bfs_path"]:
list_of_starting_idx= np.random.choice(node_length, self.params["bfs_path_count"], replace=True) # randomly choose several
else:
list_of_starting_idx= [random.choice(list(range(node_length)))] # randomly choose one
for list_idx, starting_idx in enumerate(list_of_starting_idx):
# Choose a bucket
chosen_bucket_idx = np.argmax(bucket_sizes > max(max([v for e in d['graph_out']
for v in [e[0], e[2]]]),
max([v for e in d['graph_in']
for v in [e[0], e[2]]])))
chosen_bucket_size = bucket_sizes[chosen_bucket_idx]
nodes_no_master = d['node_features_'+out_direc]
edges_no_master = d['graph_'+out_direc]
incremental_adj_mat,distance_to_others,node_sequence,edge_type_masks,edge_type_labels,local_stop, edge_masks, edge_labels, overlapped_edge_features=\
construct_incremental_graph_preselected(self.params['dataset'], edges_no_master, chosen_bucket_size,
len(nodes_no_master), d['v_to_keep'], d['exit_points'], nodes_no_master, self.params, is_training_data, initial_idx=starting_idx)
if self.params["sample_transition"] and list_idx > 0:
incremental_results[res_idx][-1]=[x+y for x, y in zip(incremental_results[res_idx][-1], [incremental_adj_mat,distance_to_others,
node_sequence,edge_type_masks,edge_type_labels,local_stop, edge_masks, edge_labels, overlapped_edge_features])]
else:
incremental_results[res_idx].append([incremental_adj_mat, distance_to_others, node_sequence, edge_type_masks,
edge_type_labels, local_stop, edge_masks, edge_labels, overlapped_edge_features])
# Copy the raw_data here
new_raw_data.append(d)
# Progress
if idx % 50 == 0:
print('finish calculating %d incremental matrices' % idx, end="\r")
return incremental_results, new_raw_data
# ----- Data preprocessing and chunking into minibatches:
def process_raw_graphs(self, raw_data, is_training_data, file_name, bucket_sizes=None):
if bucket_sizes is None:
bucket_sizes = dataset_info(self.params["dataset"])["bucket_sizes"]
incremental_results, raw_data=self.calculate_incremental_results(raw_data, bucket_sizes, file_name, is_training_data)
bucketed = defaultdict(list)
x_dim = len(raw_data[0]["node_features_out"][0])
for d, incremental_result_1 in zip(raw_data, incremental_results[1]):
# choose a bucket
chosen_bucket_idx = np.argmax(bucket_sizes > max(max([v for e in d['graph_in'] for v in [e[0], e[2]]]),
max([v for e in d['graph_out'] for v in [e[0], e[2]]])))
chosen_bucket_size = bucket_sizes[chosen_bucket_idx]
# total number of nodes in this data point out
n_active_nodes_in = len(d["node_features_in"])
n_active_nodes_out = len(d["node_features_out"])
for n_atoms in range(self.params["min_atoms"], self.params["max_atoms"]+1):
bucketed[chosen_bucket_idx].append({
'adj_mat_in': graph_to_adj_mat(d['graph_in'], chosen_bucket_size, self.num_edge_types, self.params['tie_fwd_bkwd']),
'adj_mat_out': graph_to_adj_mat(d['graph_out'], chosen_bucket_size, self.num_edge_types, self.params['tie_fwd_bkwd']),
'v_to_keep': node_keep_to_dense(d['v_to_keep'], chosen_bucket_size), # FI
'exit_points': d['exit_points'],
'abs_dist': d['abs_dist'],
'it_num': 0,
'sdf_idx': d['sdf_idx'],
'incre_adj_mat_out': incremental_result_1[0],
'distance_to_others_out': incremental_result_1[1],
'overlapped_edge_features_out': incremental_result_1[8],
'node_sequence_out': incremental_result_1[2],
'edge_type_masks_out': incremental_result_1[3],
'edge_type_labels_out': incremental_result_1[4],
'edge_masks_out': incremental_result_1[6],
'edge_labels_out': incremental_result_1[7],
'local_stop_out': incremental_result_1[5],
'number_iteration_out': len(incremental_result_1[5]),
'init_in': d["node_features_in"] + [[0 for _ in range(x_dim)] for __ in
range(chosen_bucket_size - n_active_nodes_in)],
'init_out': d["node_features_out"] + [[0 for _ in range(x_dim)] for __ in
range(chosen_bucket_size - n_active_nodes_out)],
'mask_in': [1. for _ in range(n_active_nodes_in) ] + [0. for _ in range(chosen_bucket_size - n_active_nodes_in)],
'mask_out': [1. for _ in range(n_active_nodes_out) ] + [0. for _ in range(chosen_bucket_size - n_active_nodes_out)],
'smiles_in': d['smiles_in'],
'smiles_out': d['smiles_out'],
'dists': [n_atoms],
})
if is_training_data:
for (bucket_idx, bucket) in bucketed.items():
np.random.shuffle(bucket)
bucket_at_step = [[bucket_idx for _ in range(len(bucket_data) // self.params['batch_size'])]
for bucket_idx, bucket_data in bucketed.items()]
bucket_at_step = [x for y in bucket_at_step for x in y]
return (bucketed, bucket_sizes, bucket_at_step)
def pad_annotations(self, annotations):
return np.pad(annotations,
pad_width=[[0, 0], [0, 0], [0, self.params['hidden_size'] - self.params["num_symbols"]]],
mode='constant')
def make_batch(self, elements, maximum_vertice_num):
# get maximum number of iterations in this batch. used to control while_loop
max_iteration_num=-1
for d in elements:
max_iteration_num=max(d['number_iteration_out'], max_iteration_num)
batch_data = {'adj_mat_in': [], 'adj_mat_out': [], 'v_to_keep': [], 'exit_points': [], 'abs_dist': [], 'it_num': [], 'sdf_idx': [], 'init_in': [], 'init_out': [],
'edge_type_masks_out':[], 'edge_type_labels_out':[], 'edge_masks_out':[], 'edge_labels_out':[],
'node_mask_in': [], 'node_mask_out': [], 'task_masks': [], 'node_sequence_out':[], 'iteration_mask_out': [], 'local_stop_out': [], 'incre_adj_mat_out': [],
'distance_to_others_out': [], 'max_iteration_num': max_iteration_num, 'overlapped_edge_features_out': []}
for d in elements:
batch_data['adj_mat_in'].append(d['adj_mat_in'])
batch_data['adj_mat_out'].append(d['adj_mat_out'])
batch_data['v_to_keep'].append(node_keep_to_dense(d['v_to_keep'], maximum_vertice_num))
batch_data['exit_points'].append(d['exit_points'])
batch_data['abs_dist'].append(d['abs_dist'])
batch_data['it_num'] = [0]
batch_data['sdf_idx'].append(d['sdf_idx'])
batch_data['init_in'].append(d['init_in'])
batch_data['init_out'].append(d['init_out'])
batch_data['node_mask_in'].append(d['mask_in'])
batch_data['node_mask_out'].append(d['mask_out'])
for direc in ['_out']:
# sparse to dense for saving memory
incre_adj_mat = incre_adj_mat_to_dense(d['incre_adj_mat'+direc], self.num_edge_types, maximum_vertice_num)
distance_to_others = distance_to_others_dense(d['distance_to_others'+direc], maximum_vertice_num)
overlapped_edge_features = overlapped_edge_features_to_dense(d['overlapped_edge_features'+direc], maximum_vertice_num)
node_sequence = node_sequence_to_dense(d['node_sequence'+direc],maximum_vertice_num)
edge_type_masks = edge_type_masks_to_dense(d['edge_type_masks'+direc], maximum_vertice_num,self.num_edge_types)
edge_type_labels = edge_type_labels_to_dense(d['edge_type_labels'+direc], maximum_vertice_num,self.num_edge_types)
edge_masks = edge_masks_to_dense(d['edge_masks'+direc], maximum_vertice_num)
edge_labels = edge_labels_to_dense(d['edge_labels'+direc], maximum_vertice_num)
batch_data['incre_adj_mat'+direc].append(incre_adj_mat +
[np.zeros((self.num_edge_types, maximum_vertice_num,maximum_vertice_num))
for _ in range(max_iteration_num-d['number_iteration'+direc])])
batch_data['distance_to_others'+direc].append(distance_to_others +
[np.zeros((maximum_vertice_num))
for _ in range(max_iteration_num-d['number_iteration'+direc])])
batch_data['overlapped_edge_features'+direc].append(overlapped_edge_features +
[np.zeros((maximum_vertice_num))
for _ in range(max_iteration_num-d['number_iteration'+direc])])
batch_data['node_sequence'+direc].append(node_sequence +
[np.zeros((maximum_vertice_num))
for _ in range(max_iteration_num-d['number_iteration'+direc])])
batch_data['edge_type_masks'+direc].append(edge_type_masks +
[np.zeros((self.num_edge_types, maximum_vertice_num))
for _ in range(max_iteration_num-d['number_iteration'+direc])])
batch_data['edge_masks'+direc].append(edge_masks +
[np.zeros((maximum_vertice_num))
for _ in range(max_iteration_num-d['number_iteration'+direc])])
batch_data['edge_type_labels'+direc].append(edge_type_labels +
[np.zeros((self.num_edge_types, maximum_vertice_num))
for _ in range(max_iteration_num-d['number_iteration'+direc])])
batch_data['edge_labels'+direc].append(edge_labels +
[np.zeros((maximum_vertice_num))
for _ in range(max_iteration_num-d['number_iteration'+direc])])
batch_data['iteration_mask'+direc].append([1 for _ in range(d['number_iteration'+direc])]+
[0 for _ in range(max_iteration_num-d['number_iteration'+direc])])
batch_data['local_stop'+direc].append([int(s) for s in d['local_stop'+direc]]+
[0 for _ in range(max_iteration_num-d['number_iteration'+direc])])
return batch_data
def get_dynamic_feed_dict(self, elements, latent_node_symbol, incre_adj_mat, num_vertices,
distance_to_others, overlapped_edge_dense, node_sequence, edge_type_masks, edge_masks,
random_normal_states, random_normal_states_in, iteration_num, cnn_input):
if incre_adj_mat is None:
incre_adj_mat=np.zeros((1, 1, self.num_edge_types, 1, 1))
distance_to_others=np.zeros((1,1,1))
overlapped_edge_dense=np.zeros((1,1,1))
node_sequence=np.zeros((1,1,1))
edge_type_masks=np.zeros((1,1,self.num_edge_types,1))
edge_masks=np.zeros((1,1,1))
latent_node_symbol=np.zeros((1,1,self.params["num_symbols"]))
return {
self.placeholders['z_prior']: random_normal_states, # [1, v, j]
self.placeholders['z_prior_in']: random_normal_states_in, # [1, v, h]
self.placeholders['incre_adj_mat_out']: incre_adj_mat, # [1, 1, e, v, v]
self.placeholders['num_vertices']: num_vertices, # v
self.placeholders['initial_node_representation_in']: self.pad_annotations([elements['init_in']]),
self.placeholders['initial_node_representation_out']: self.pad_annotations([elements['init_out']]),
self.placeholders['node_symbols_out']: [elements['init_out']],
self.placeholders['node_symbols_in']: [elements['init_in']],
self.placeholders['latent_node_symbols_in']: self.pad_annotations(latent_node_symbol),
self.placeholders['latent_node_symbols_out']: self.pad_annotations(latent_node_symbol),
self.placeholders['adjacency_matrix_in']: [elements['adj_mat_in']],
self.placeholders['adjacency_matrix_out']: [elements['adj_mat_out']],
self.placeholders['vertices_to_keep']: [elements['v_to_keep']],
self.placeholders['exit_points']: [elements['exit_points']],
self.placeholders['abs_dist']: [elements['abs_dist']],
self.placeholders['it_num']: [iteration_num],
self.placeholders['sdf_idx']: [elements['sdf_idx']],
self.placeholders['node_mask_in']: [elements['mask_in']],
self.placeholders['node_mask_out']: [elements['mask_out']],
self.placeholders['graph_state_keep_prob']: 1,
self.placeholders['edge_weight_dropout_keep_prob']: 1,
self.placeholders['iteration_mask_out']: [[1]],
self.placeholders['is_generative']: True,
self.placeholders['out_layer_dropout_keep_prob'] : 1.0,
self.placeholders['distance_to_others_out'] : distance_to_others, # [1, 1,v]
self.placeholders['overlapped_edge_features_out']: overlapped_edge_dense,
self.placeholders['max_iteration_num']: 1,
self.placeholders['node_sequence_out']: node_sequence, # [1, 1, v]
self.placeholders['edge_type_masks_out']: edge_type_masks, # [1, 1, e, v]
self.placeholders['edge_masks_out']: edge_masks, # [1, 1, v]
self.placeholders['cnn_input']: cnn_input, # [1, n_channels, x, y, z]
}
def get_node_symbol(self, batch_feed_dict):
fetch_list = [self.ops['node_symbol_prob_in']]
result = self.sess.run(fetch_list, feed_dict=batch_feed_dict)
return (result[0])
def node_symbol_one_hot(self, sampled_node_symbol, real_n_vertices, max_n_vertices):
one_hot_representations=[]
for idx in range(max_n_vertices):
representation = [0] * self.params["num_symbols"]
if idx < real_n_vertices:
atom_type=sampled_node_symbol[idx]
representation[atom_type]=1
one_hot_representations.append(representation)
return one_hot_representations
def search_and_generate_molecule(self, initial_idx, valences,
sampled_node_symbol, sampled_node_keep, real_n_vertices,
random_normal_states, random_normal_states_in,
elements, max_n_vertices, cnn_input):
# New molecule
new_mol = Chem.MolFromSmiles('')
new_mol = Chem.rdchem.RWMol(new_mol)
# Add atoms
add_atoms(new_mol, sampled_node_symbol, self.params["dataset"])
# Initalise queue
queue=deque([])
# color 0: have not found 1: in the queue 2: searched already
color = [0] * max_n_vertices
# Empty adj list at the beginning
incre_adj_list=defaultdict(list)
count_bonds = 0
# Add edges between vertices to keep
for node, keep in enumerate(sampled_node_keep[0:real_n_vertices]):
if keep == 1:
for neighbor, keep_n in enumerate(sampled_node_keep[0:real_n_vertices]):
if keep_n == 1 and neighbor > node:
for bond in range(self.num_edge_types):
if elements['adj_mat_in'][bond][node][neighbor] == 1:
incre_adj_list[node].append((neighbor, bond))
incre_adj_list[neighbor].append((node, bond))
valences[node] -= (bond+1)
valences[neighbor] -= (bond+1)
# Add the bond
new_mol.AddBond(int(node), int(neighbor), number_to_bond[bond])
count_bonds += 1
# Add exit nodes to queue and update colours of fragment nodes
for v, keep in enumerate(sampled_node_keep[0:real_n_vertices]):
if keep == 1:
if v in elements['exit_points']:
queue.append(v)
color[v]=1
else:
# Mask out nodes that aren't exit vectors
valences[v] = 0
color[v] = 2
# Record the log probabilities at each step
total_log_prob=0
# Add initial_idx to queue if no nodes kept
if len(queue) == 0:
queue.append(initial_idx)
color[initial_idx] = 1
iteration_num = 0
while len(queue) > 0:
node_in_focus = queue.popleft()
# iterate until the stop node is selected
while True:
# Prepare data for one iteration based on the graph state
edge_type_mask_sparse, edge_mask_sparse = generate_mask(valences, incre_adj_list, color, real_n_vertices, node_in_focus, self.params["check_overlap_edge"], new_mol)
#edge_type_mask_sparse, edge_mask_sparse = generate_mask(valences, incre_adj_list, color, max_n_vertices, node_in_focus, self.params["check_overlap_edge"], new_mol)
edge_type_mask = edge_type_masks_to_dense([edge_type_mask_sparse], max_n_vertices, self.num_edge_types) # [1, e, v]
edge_mask = edge_masks_to_dense([edge_mask_sparse],max_n_vertices) # [1, v]
node_sequence = node_sequence_to_dense([node_in_focus], max_n_vertices) # [1, v]
distance_to_others_sparse = bfs_distance(node_in_focus, incre_adj_list)
distance_to_others = distance_to_others_dense([distance_to_others_sparse],max_n_vertices) # [1, v]
overlapped_edge_sparse = get_overlapped_edge_feature(edge_mask_sparse, color, new_mol)
overlapped_edge_dense = overlapped_edge_features_to_dense([overlapped_edge_sparse],max_n_vertices) # [1, v]
incre_adj_mat = incre_adj_mat_to_dense([incre_adj_list],