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model.py
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import torch
from torch_geometric.nn import MessagePassing
from torch_geometric.utils import add_self_loops, degree, softmax
from torch_geometric.nn import global_add_pool, global_mean_pool, global_max_pool, GlobalAttention, Set2Set
import torch.nn.functional as F
import torch.nn as nn
from torch_scatter import scatter_add
from torch_geometric.nn.inits import glorot, zeros
num_atom_type = 120 #including the extra mask tokens=119
num_chirality_tag = 3 # original =3. including the extra mask tokens=3
num_bond_type = 6 #including aromatic and self-loop edge, and extra masked tokens
num_bond_direction = 3 # original =3, inlcuding the extra mask tokens=3
class GINConv(MessagePassing):
"""
Extension of GIN aggregation to incorporate edge information by concatenation.
Args:
emb_dim (int): dimensionality of embeddings for nodes and edges.
embed_input (bool): whether to embed input or not.
See https://arxiv.org/abs/1810.00826
"""
def __init__(self, emb_dim, aggr = "add"):
super(GINConv, self).__init__()
#multi-layer perceptron
self.mlp = torch.nn.Sequential(torch.nn.Linear(emb_dim, 2*emb_dim), torch.nn.ReLU(), torch.nn.Linear(2*emb_dim, emb_dim))
self.edge_embedding1 = torch.nn.Embedding(num_bond_type, emb_dim)
self.edge_embedding2 = torch.nn.Embedding(num_bond_direction, emb_dim)
torch.nn.init.xavier_uniform_(self.edge_embedding1.weight.data)
torch.nn.init.xavier_uniform_(self.edge_embedding2.weight.data)
self.aggr = aggr
def forward(self, x, edge_index, edge_attr):
#add self loops in the edge space
edge_index = add_self_loops(edge_index, num_nodes = x.size(0))
#add features corresponding to self-loop edges.
self_loop_attr = torch.zeros(x.size(0), 2)
self_loop_attr[:,0] = 4 #bond type for self-loop edge
self_loop_attr = self_loop_attr.to(edge_attr.device).to(edge_attr.dtype)
edge_attr = torch.cat((edge_attr, self_loop_attr), dim = 0)
edge_embeddings = self.edge_embedding1(edge_attr[:,0]) + self.edge_embedding2(edge_attr[:,1])
# return self.propagate(self.aggr, edge_index, x=x, edge_attr=edge_embeddings)
return self.propagate(edge_index[0], x=x, edge_attr=edge_embeddings) # for latest version
def message(self, x_j, edge_attr):
return x_j + edge_attr
def update(self, aggr_out):
return self.mlp(aggr_out)
class GCNConv(MessagePassing):
def __init__(self, emb_dim, aggr = "add"):
super(GCNConv, self).__init__()
self.emb_dim = emb_dim
self.linear = torch.nn.Linear(emb_dim, emb_dim)
self.edge_embedding1 = torch.nn.Embedding(num_bond_type, emb_dim)
self.edge_embedding2 = torch.nn.Embedding(num_bond_direction, emb_dim)
torch.nn.init.xavier_uniform_(self.edge_embedding1.weight.data)
torch.nn.init.xavier_uniform_(self.edge_embedding2.weight.data)
self.aggr = aggr
def norm(self, edge_index, num_nodes, dtype):
### assuming that self-loops have been already added in edge_index
edge_weight = torch.ones((edge_index.size(1), ), dtype=dtype,
device=edge_index.device)
row, col = edge_index
deg = scatter_add(edge_weight, row, dim=0, dim_size=num_nodes)
deg_inv_sqrt = deg.pow(-0.5)
deg_inv_sqrt[deg_inv_sqrt == float('inf')] = 0
return deg_inv_sqrt[row] * edge_weight * deg_inv_sqrt[col]
def forward(self, x, edge_index, edge_attr):
#add self loops in the edge space
edge_index = add_self_loops(edge_index, num_nodes = x.size(0))
#add features corresponding to self-loop edges.
self_loop_attr = torch.zeros(x.size(0), 2)
self_loop_attr[:,0] = 4 #bond type for self-loop edge
self_loop_attr = self_loop_attr.to(edge_attr.device).to(edge_attr.dtype)
edge_attr = torch.cat((edge_attr, self_loop_attr), dim = 0)
edge_embeddings = self.edge_embedding1(edge_attr[:,0]) + self.edge_embedding2(edge_attr[:,1])
norm = self.norm(edge_index, x.size(0), x.dtype)
x = self.linear(x)
return self.propagate(edge_index[0], x=x, edge_attr=edge_embeddings, norm = norm)
def message(self, x_j, edge_attr, norm):
return norm.view(-1, 1) * (x_j + edge_attr)
class GATConv(MessagePassing):
def __init__(self, emb_dim, heads=2, negative_slope=0.2, aggr = "add"):
super(GATConv, self).__init__()
self.aggr = aggr
self.emb_dim = emb_dim
self.heads = heads
self.negative_slope = negative_slope
self.weight_linear = torch.nn.Linear(emb_dim, heads * emb_dim)
self.att = torch.nn.Parameter(torch.Tensor(1, heads, 2 * emb_dim))
self.bias = torch.nn.Parameter(torch.Tensor(emb_dim))
self.edge_embedding1 = torch.nn.Embedding(num_bond_type, heads * emb_dim)
self.edge_embedding2 = torch.nn.Embedding(num_bond_direction, heads * emb_dim)
torch.nn.init.xavier_uniform_(self.edge_embedding1.weight.data)
torch.nn.init.xavier_uniform_(self.edge_embedding2.weight.data)
self.reset_parameters()
def reset_parameters(self):
glorot(self.att)
zeros(self.bias)
def forward(self, x, edge_index, edge_attr):
#add self loops in the edge space
edge_index = add_self_loops(edge_index, num_nodes = x.size(0))
#add features corresponding to self-loop edges.
self_loop_attr = torch.zeros(x.size(0), 2)
self_loop_attr[:,0] = 4 #bond type for self-loop edge
self_loop_attr = self_loop_attr.to(edge_attr.device).to(edge_attr.dtype)
edge_attr = torch.cat((edge_attr, self_loop_attr), dim = 0)
edge_embeddings = self.edge_embedding1(edge_attr[:,0]) + self.edge_embedding2(edge_attr[:,1])
x = self.weight_linear(x).view(-1, self.heads, self.emb_dim)
return self.propagate(self.aggr, edge_index, x=x, edge_attr=edge_embeddings)
def message(self, edge_index, x_i, x_j, edge_attr):
edge_attr = edge_attr.view(-1, self.heads, self.emb_dim)
x_j += edge_attr
alpha = (torch.cat([x_i, x_j], dim=-1) * self.att).sum(dim=-1)
alpha = F.leaky_relu(alpha, self.negative_slope)
alpha = softmax(alpha, edge_index[0])
return x_j * alpha.view(-1, self.heads, 1)
def update(self, aggr_out):
aggr_out = aggr_out.mean(dim=1)
aggr_out = aggr_out + self.bias
return aggr_out
class GraphSAGEConv(MessagePassing):
def __init__(self, emb_dim, aggr = "mean"):
super(GraphSAGEConv, self).__init__()
self.emb_dim = emb_dim
self.linear = torch.nn.Linear(emb_dim, emb_dim)
self.edge_embedding1 = torch.nn.Embedding(num_bond_type, emb_dim)
self.edge_embedding2 = torch.nn.Embedding(num_bond_direction, emb_dim)
torch.nn.init.xavier_uniform_(self.edge_embedding1.weight.data)
torch.nn.init.xavier_uniform_(self.edge_embedding2.weight.data)
self.aggr = aggr
def forward(self, x, edge_index, edge_attr):
#add self loops in the edge space
edge_index = add_self_loops(edge_index, num_nodes = x.size(0))
#add features corresponding to self-loop edges.
self_loop_attr = torch.zeros(x.size(0), 2)
self_loop_attr[:,0] = 4 #bond type for self-loop edge
self_loop_attr = self_loop_attr.to(edge_attr.device).to(edge_attr.dtype)
edge_attr = torch.cat((edge_attr, self_loop_attr), dim = 0)
edge_embeddings = self.edge_embedding1(edge_attr[:,0]) + self.edge_embedding2(edge_attr[:,1])
x = self.linear(x)
return self.propagate(self.aggr, edge_index, x=x, edge_attr=edge_embeddings)
def message(self, x_j, edge_attr):
return x_j + edge_attr
def update(self, aggr_out):
return F.normalize(aggr_out, p = 2, dim = -1)
class GNN(torch.nn.Module):
"""
Args:
num_layer (int): the number of GNN layers
emb_dim (int): dimensionality of embeddings
JK (str): last, concat, max or sum.
max_pool_layer (int): the layer from which we use max pool rather than add pool for neighbor aggregation
drop_ratio (float): dropout rate
gnn_type: gin, gcn, graphsage, gat
Output:
node representations
"""
def __init__(self, num_layer, emb_dim, JK = "last", drop_ratio = 0, gnn_type = "gin"):
super(GNN, self).__init__()
self.num_layer = num_layer
self.drop_ratio = drop_ratio
self.JK = JK
if self.num_layer < 2:
raise ValueError("Number of GNN layers must be greater than 1.")
self.x_embedding1 = torch.nn.Embedding(num_atom_type, emb_dim)
self.x_embedding2 = torch.nn.Embedding(num_chirality_tag, emb_dim)
torch.nn.init.xavier_uniform_(self.x_embedding1.weight.data)
torch.nn.init.xavier_uniform_(self.x_embedding2.weight.data)
###List of MLPs
self.gnns = torch.nn.ModuleList()
for layer in range(num_layer):
if gnn_type == "gin":
self.gnns.append(GINConv(emb_dim, aggr = "add"))
elif gnn_type == "gcn":
self.gnns.append(GCNConv(emb_dim))
elif gnn_type == "gat":
self.gnns.append(GATConv(emb_dim))
elif gnn_type == "graphsage":
self.gnns.append(GraphSAGEConv(emb_dim))
###List of batchnorms
self.batch_norms = torch.nn.ModuleList()
for layer in range(num_layer):
self.batch_norms.append(torch.nn.BatchNorm1d(emb_dim))
#def forward(self, x, edge_index, edge_attr):
def forward(self, *argv):
if len(argv) == 3:
x, edge_index, edge_attr = argv[0], argv[1], argv[2]
elif len(argv) == 1:
data = argv[0]
x, edge_index, edge_attr = data.x, data.edge_index, data.edge_attr
else:
raise ValueError("unmatched number of arguments.")
x = self.x_embedding1(x[:,0]) + self.x_embedding2(x[:,1])
h_list = [x]
for layer in range(self.num_layer):
h = self.gnns[layer](h_list[layer], edge_index, edge_attr)
h = self.batch_norms[layer](h)
#h = F.dropout(F.relu(h), self.drop_ratio, training = self.training)
if layer == self.num_layer - 1:
#remove relu for the last layer
h = F.dropout(h, self.drop_ratio, training = self.training)
else:
h = F.dropout(F.relu(h), self.drop_ratio, training = self.training)
h_list.append(h)
### Different implementations of Jk-concat
if self.JK == "concat":
node_representation = torch.cat(h_list, dim = 1)
elif self.JK == "last":
node_representation = h_list[-1]
elif self.JK == "max":
h_list = [h.unsqueeze_(0) for h in h_list]
node_representation = torch.max(torch.cat(h_list, dim = 0), dim = 0)[0]
elif self.JK == "sum":
h_list = [h.unsqueeze_(0) for h in h_list]
node_representation = torch.sum(torch.cat(h_list, dim = 0), dim = 0)[0]
return node_representation
class GNN_graphCL(torch.nn.Module):
"""
Extension of GIN to incorporate edge information by concatenation.
Args:
num_layer (int): the number of GNN layers
emb_dim (int): dimensionality of embeddings
num_tasks (int): number of tasks in multi-task learning scenario
drop_ratio (float): dropout rate
JK (str): last, concat, max or sum.
graph_pooling (str): sum, mean, max, attention, set2set
gnn_type: gin, gcn, graphsage, gat
See https://arxiv.org/abs/1810.00826
JK-net: https://arxiv.org/abs/1806.03536
"""
def __init__(self, num_layer, emb_dim, num_tasks, JK = "last", drop_ratio = 0, graph_pooling = "mean", gnn_type = "gin"):
super(GNN_graphCL, self).__init__()
self.num_layer = num_layer
self.drop_ratio = drop_ratio
self.JK = JK
self.emb_dim = emb_dim
self.num_tasks = num_tasks
if self.num_layer < 2:
raise ValueError("Number of GNN layers must be greater than 1.")
self.gnn = GNN(num_layer, emb_dim, JK, drop_ratio, gnn_type = gnn_type)
self.proj_head = nn.Sequential(nn.Linear(emb_dim, 128), nn.ReLU(inplace=True), nn.Linear(128, 128))
#Different kind of graph pooling
if graph_pooling == "sum":
self.pool = global_add_pool
elif graph_pooling == "mean":
self.pool = global_mean_pool
elif graph_pooling == "max":
self.pool = global_max_pool
elif graph_pooling == "attention":
if self.JK == "concat":
self.pool = GlobalAttention(gate_nn = torch.nn.Linear((self.num_layer + 1) * emb_dim, 1))
else:
self.pool = GlobalAttention(gate_nn = torch.nn.Linear(emb_dim, 1))
elif graph_pooling[:-1] == "set2set":
set2set_iter = int(graph_pooling[-1])
if self.JK == "concat":
self.pool = Set2Set((self.num_layer + 1) * emb_dim, set2set_iter)
else:
self.pool = Set2Set(emb_dim, set2set_iter)
else:
raise ValueError("Invalid graph pooling type.")
#For graph-level binary classification
if graph_pooling[:-1] == "set2set":
self.mult = 2
else:
self.mult = 1
if self.JK == "concat":
self.graph_pred_linear = torch.nn.Linear(self.mult * (self.num_layer + 1) * self.emb_dim, self.num_tasks)
else:
self.graph_pred_linear = torch.nn.Linear(self.mult * self.emb_dim, self.num_tasks)
def from_pretrained(self, model_file):
self.gnn.load_state_dict(torch.load(model_file))
def forward(self, *argv):
if len(argv) == 4:
x, edge_index, edge_attr, batch = argv[0], argv[1], argv[2], argv[3]
elif len(argv) == 1:
data = argv[0]
x, edge_index, edge_attr, batch = data.x, data.edge_index, data.edge_attr, data.batch
else:
raise ValueError("unmatched number of arguments.")
node_representation = self.gnn(x, edge_index, edge_attr)
graph_representation = self.pool(node_representation, batch)
return self.proj_head(graph_representation)
def loss_cl(self, x1, x2):
T = 0.5
batch_size, _ = x1.size()
# similarity matrix
x1_abs = x1.norm(dim=1)
x2_abs = x2.norm(dim=1)
sim_matrix = torch.einsum('ik,jk->ij', x1, x2) / torch.einsum('i,j->ij', x1_abs, x2_abs)
sim_matrix = torch.exp(sim_matrix / T)
pos_sim = sim_matrix[range(batch_size), range(batch_size)] #Nx1
# left view
loss_left = pos_sim / (sim_matrix.sum(dim=1) - pos_sim) #Nx1/Nx1
loss_left = - torch.log(loss_left).mean()
# right view
loss_right = pos_sim / (sim_matrix.sum(dim=0) - pos_sim)
loss_right = - torch.log(loss_right).mean()
# loss
loss = (loss_left + loss_right) / 2.0
return loss
def loss_global_cl(self, x, ids, sim_global_idx):
T = 0.5
batch_size, _ = x.size()
# similarity matrix
x_abs = x.norm(dim=1)
sim_matrix = torch.einsum('ik,jk->ij', x, x) / torch.einsum('i,j->ij', x_abs, x_abs)
sim_matrix = torch.exp(sim_matrix / T)
# print('sim_matrix: ', sim_matrix)
sim_batch_idx = sim_global_idx[ids, :]
sim_batch_idx = sim_batch_idx[:, ids]
# print('sim_batch_idx: ', sim_batch_idx)
pos_sim_matrix = sim_batch_idx * sim_matrix #NxN
# print('pos_sim_matrix: ', pos_sim_matrix)
pos_sim = pos_sim_matrix.sum(dim=1) #Nx1
# print('pos_sim: ', pos_sim)
loss = pos_sim / (sim_matrix.sum(dim=1) - pos_sim)
# print('loss before log: ', loss)
loss = - torch.log(loss).mean()
return loss
def loss_global_sup(self, x1, x2, ids, sim_global):
batch_size, _ = x1.size()
# batch_size *= 2
# x1, x2 = torch.cat((x1, x2), dim=0), torch.cat((x2, x1), dim=0)
x1_abs = x1.norm(dim=1)
x2_abs = x2.norm(dim=1)
'''
sim_matrix = torch.einsum('ik,jk->ij', x1, x2) / torch.einsum('i,j->ij', x1_abs, x2_abs)
sim_matrix = torch.exp(sim_matrix / T)
pos_sim = sim_matrix[range(batch_size), range(batch_size)]
self_sim = sim_matrix[range(batch_size), list(range(int(batch_size/2), batch_size))+list(range(int(batch_size/2)))]
loss = pos_sim / (sim_matrix.sum(dim=1) - pos_sim - self_sim)
loss = - torch.log(loss).mean()
'''
sim_matrix = torch.einsum('ik,jk->ij', x1, x2) / torch.einsum('i,j->ij', x1_abs, x2_abs)
sim_label = sim_global[ids, :]
sim_label = sim_label[:, ids]
# print('sim_label: ', sim_label.size())
# print('sim_matrix: ', sim_matrix.size())
loss = torch.mean((sim_matrix-sim_label)**2)
# print('loss: ', loss)
return loss
class GNN_graphpred(torch.nn.Module):
"""
Extension of GIN to incorporate edge information by concatenation.
Args:
num_layer (int): the number of GNN layers
emb_dim (int): dimensionality of embeddings
num_tasks (int): number of tasks in multi-task learning scenario
drop_ratio (float): dropout rate
JK (str): last, concat, max or sum.
graph_pooling (str): sum, mean, max, attention, set2set
gnn_type: gin, gcn, graphsage, gat
See https://arxiv.org/abs/1810.00826
JK-net: https://arxiv.org/abs/1806.03536
"""
def __init__(self, num_layer, emb_dim, num_tasks, JK = "last", drop_ratio = 0, graph_pooling = "mean", gnn_type = "gin"):
super(GNN_graphpred, self).__init__()
self.num_layer = num_layer
self.drop_ratio = drop_ratio
self.JK = JK
self.emb_dim = emb_dim
self.num_tasks = num_tasks
if self.num_layer < 2:
raise ValueError("Number of GNN layers must be greater than 1.")
self.gnn = GNN(num_layer, emb_dim, JK, drop_ratio, gnn_type = gnn_type)
#Different kind of graph pooling
if graph_pooling == "sum":
self.pool = global_add_pool
elif graph_pooling == "mean":
self.pool = global_mean_pool
elif graph_pooling == "max":
self.pool = global_max_pool
elif graph_pooling == "attention":
if self.JK == "concat":
self.pool = GlobalAttention(gate_nn = torch.nn.Linear((self.num_layer + 1) * emb_dim, 1))
else:
self.pool = GlobalAttention(gate_nn = torch.nn.Linear(emb_dim, 1))
elif graph_pooling[:-1] == "set2set":
set2set_iter = int(graph_pooling[-1])
if self.JK == "concat":
self.pool = Set2Set((self.num_layer + 1) * emb_dim, set2set_iter)
else:
self.pool = Set2Set(emb_dim, set2set_iter)
else:
raise ValueError("Invalid graph pooling type.")
#For graph-level binary classification
if graph_pooling[:-1] == "set2set":
self.mult = 2
else:
self.mult = 1
if self.JK == "concat":
self.graph_pred_linear = torch.nn.Linear(self.mult * (self.num_layer + 1) * self.emb_dim, self.num_tasks)
else:
self.graph_pred_linear = torch.nn.Linear(self.mult * self.emb_dim, self.num_tasks)
def from_pretrained(self, model_file):
#self.gnn = GNN(self.num_layer, self.emb_dim, JK = self.JK, drop_ratio = self.drop_ratio)
self.gnn.load_state_dict(torch.load(model_file))
def forward(self, *argv):
if len(argv) == 4:
x, edge_index, edge_attr, batch = argv[0], argv[1], argv[2], argv[3]
elif len(argv) == 1:
data = argv[0]
x, edge_index, edge_attr, batch = data.x, data.edge_index, data.edge_attr, data.batch
else:
raise ValueError("unmatched number of arguments.")
node_representation = self.gnn(x, edge_index, edge_attr)
return self.graph_pred_linear(self.pool(node_representation, batch))
if __name__ == "__main__":
#pass
def loss_cl(x1, x2):
T = 1.0
batch_size, _ = x1.size()
# similarity matrix
x1_abs = x1.norm(dim=1)
print('x1_abs: ', x1_abs)
x2_abs = x2.norm(dim=1)
print('x2_abs: ', x2_abs)
sim_matrix = torch.einsum('ik,jk->ij', x1, x2) / torch.einsum('i,j->ij', x1_abs, x2_abs)
sim_matrix = torch.exp(sim_matrix / T)
print('sim_matrix: ', sim_matrix)
pos_sim = sim_matrix[range(batch_size), range(batch_size)] #Nx1
print('pos_sim: ', pos_sim)
print('row sum: ', sim_matrix.sum(dim=1))
print('col sum: ', sim_matrix.sum(dim=0))
# left view
loss_left = pos_sim / (sim_matrix.sum(dim=1) - pos_sim) #Nx1/Nx1
print('loss_left: ', loss_left)
loss_left = - torch.log(loss_left).mean()
# right view
loss_right = pos_sim / (sim_matrix.sum(dim=0) - pos_sim)
print('loss_right: ', loss_right)
loss_right = - torch.log(loss_right).mean()
# loss
loss = (loss_left + loss_right) / 2.0
print(loss)
return loss
x1 = torch.tensor([[1,0,1], [1,0,2], [1,1,1]], dtype=torch.float32)
x2 = torch.tensor([[1,2,3], [1,1,2], [1,3,1]], dtype=torch.float32)
loss_cl(x1, x2)
loss_cl(x2, x1)