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models.py
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models.py
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import torch.nn as nn
import torch.nn.functional as F
import torch
import math
from torch.nn.parameter import Parameter
from layers import GraphConvolution
from dgl.nn.pytorch.conv import GraphConv,GATConv,SAGEConv
import dgl
def reset_parameters(self):
stdv = 1. / math.sqrt(self.weight.size(1))
self.weight.data.uniform_(-stdv, stdv)
class RNNGCN(nn.Module):
def __init__(self, nfeat, nhid, nclass, dropout):
super(RNNGCN, self).__init__()
self.gc1 = GraphConvolution(nfeat, nhid)
self.gc2 = GraphConvolution(nhid, nclass)
self.dropout = dropout
self.Lambda = Parameter(torch.FloatTensor(1))
self.Lambda.data.uniform_(0.2, 0.2)
def forward(self, x, adj):
#out=[]
now_adj=adj[:,0,:].clone()
for i in range(1,adj.shape[1]): #time_steps
now_adj=(1-self.Lambda)*now_adj+self.Lambda*adj[:,i,:] #weight decay
one_out=self.gc1(x[:,-1,:],now_adj)
one_out=F.relu(one_out)
one_out = F.dropout(one_out, self.dropout, training=self.training)
one_out = self.gc2(one_out,now_adj)
return F.log_softmax(one_out, dim=1)
class TRNNGCN(nn.Module):
def __init__(self, nfeat, nhid, nclass, dropout,nnode,use_cuda=False):
super(TRNNGCN, self).__init__()
self.gc1 = GraphConvolution(nfeat, nhid)
self.gc2 = GraphConvolution(nhid, nclass)
self.dropout = dropout
self.Lambda = Parameter(torch.FloatTensor(nclass,nclass))
self.Lambda.data.uniform_(0.5, 0.5)
self.use_cuda=use_cuda
y=torch.randint(0,nclass,(nnode,1)).flatten()
if self.use_cuda:
self.H = torch.zeros(nnode, nclass).cuda()
else:
self.H = torch.zeros(nnode, nclass)
self.H[range(self.H.shape[0]), y]=1
def forward(self, x, adj):
w=self.Lambda.data
w=w.clamp(0,1)
self.Lambda.data=w
if self.use_cuda:
decay_adj=torch.mm(torch.mm(self.H,self.Lambda),self.H.T).cuda()
else:
decay_adj=torch.mm(torch.mm(self.H,self.Lambda),self.H.T)
now_adj=adj[:,0,:].clone()#torch.zeros(adj.shape[0], adj.shape[2])
for i in range(1,adj.shape[1]): #time_steps
now_adj=(1-decay_adj)*now_adj+decay_adj*adj[:,i,:]
del decay_adj
one_out=F.relu(self.gc1(x[:,-1,:],now_adj))
one_out = F.dropout(one_out, self.dropout, training=self.training)
one_out = self.gc2(one_out,now_adj)
output=F.log_softmax(one_out, dim=1)
y=torch.argmax(output,dim=1)
H_shape=self.H.shape
del self.H
del now_adj
if self.use_cuda:
self.H = torch.zeros(H_shape).cuda()
else:
self.H = torch.zeros(H_shape)
self.H[range(H_shape[0]), y]=1
return output
class LSTMGCN(nn.Module):
def __init__(self, nfeat, nhid, nclass, dropout):
super(LSTMGCN, self).__init__()
self.gc1 = GraphConvolution(nfeat, nhid)
self.gc2 = GraphConvolution(nhid, nclass)
self.dropout = dropout
self.LS_begin=nn.LSTM(input_size=nfeat, hidden_size=nhid, num_layers=1, dropout=0.5,batch_first=True)
self.nhid=nhid
def forward(self, x, adj):
adj=self.LS_begin(adj)
x = F.relu(self.gc1(x[:,-1,:], adj[0][:,-1,:]))
x = F.dropout(x, self.dropout, training=self.training)
x = self.gc2(x, adj[0][:,-1,:])
return F.log_softmax(x, dim=1)
class GCNLSTM(nn.Module):
def __init__(self, nfeat, nhid, nclass, dropout):
super(GCNLSTM, self).__init__()
self.gc1 = GraphConvolution(nfeat, nhid)
self.gc2 = GraphConvolution(nhid, nhid)
self.dropout = dropout
self.LS_end=nn.LSTM(input_size=nhid, hidden_size=nclass, num_layers=2, dropout=0.5,
batch_first=True)
self.nhid=nhid
self.nclass=nclass
self.linear=nn.Linear(nclass, nclass)
def forward(self, x, adj):
out=[]
for i in range(adj.shape[1]):
one_out=F.relu(self.gc1(x[:,i,:],adj[:,i,:]))
one_out = F.dropout(one_out, self.dropout, training=self.training)
one_out = self.gc2(one_out, adj[:,i,:])
out+=[one_out]
out = torch.stack(out, 1)
out=self.LS_end(out)[0][:,-1,:]
return F.log_softmax(out, dim=1)
class GCN(nn.Module):
def __init__(self, nfeat, nhid, nclass, dropout):
super(GCN, self).__init__()
self.gc1 = GraphConvolution(nfeat, nhid)
self.gc2 = GraphConvolution(nhid, nclass)
self.dropout = dropout
def forward(self, x, adj):
x = F.relu(self.gc1(x, adj))
x = F.dropout(x, self.dropout, training=self.training)
x = self.gc2(x, adj)
return F.log_softmax(x, dim=1)
class GAT(nn.Module):
def __init__(self, nfeat, nhid, nclass, dropout):
super(GAT, self).__init__()
self.dropout = dropout
self.conv1 = GATConv(nfeat, nhid, num_heads=1)
self.conv2 = GATConv(nhid, nclass, num_heads=1)
def forward(self, x, adj):
# Use node degree as the initial node feature. For undirected graphs, the in-degree
# is the same as the out_degree.
# Perform graph convolution and activation function.
x = F.relu(self.conv1(adj, x)) #different from self-defined gcn
x=x.reshape(x.shape[0],x.shape[2])
x = F.dropout(x, self.dropout, training=self.training)
x = self.conv2(adj, x)
x=x.reshape(x.shape[0],x.shape[2])
return F.log_softmax(x, dim=1)
class GraphSage(nn.Module):
def __init__(self, nfeat, nhid, nclass, dropout):
super(GraphSage, self).__init__()
self.dropout = dropout
self.conv1 = SAGEConv(nfeat, nhid,aggregator_type='mean')
self.conv2 = SAGEConv(nhid, nclass,aggregator_type='mean')
def forward(self, x, adj):
# Use node degree as the initial node feature. For undirected graphs, the in-degree
# is the same as the out_degree.
# Perform graph convolution and activation function.
x = F.relu(self.conv1(adj, x)) #different from self-defined gcn
x = F.dropout(x, self.dropout, training=self.training)
x = self.conv2(adj, x)
return F.log_softmax(x, dim=1)
#egcn
class Namespace(object):
'''
helps referencing object in a dictionary as dict.key instead of dict['key']
'''
def __init__(self, adict):
self.__dict__.update(adict)
def pad_with_last_val(vect,k):
device = 'cuda' if vect.is_cuda else 'cpu'
pad = torch.ones(k - vect.size(0),
dtype=torch.long,
device = device) * vect[-1]
vect = torch.cat([vect,pad])
return vect
#only use EGCN
class EGCN(torch.nn.Module): #egcn_o
def __init__(self, nfeat, nhid, nclass, device='cpu', skipfeats=False):
super().__init__()
GRCU_args = Namespace({})
feats = [nfeat,
nhid,
nhid]
self.device = device
self.skipfeats = skipfeats
self.GRCU_layers = []
self._parameters = nn.ParameterList()
self.mlp = torch.nn.Sequential(torch.nn.Linear(in_features = nhid,out_features = nhid),
torch.nn.ReLU(),
torch.nn.Linear(in_features = nhid,out_features = nclass))
for i in range(1,len(feats)):
GRCU_args = Namespace({'in_feats' : feats[i-1],
'out_feats': feats[i],
'activation': torch.nn.RReLU()})
grcu_i = GRCU(GRCU_args)
#print (i,'grcu_i', grcu_i)
self.GRCU_layers.append(grcu_i.to(self.device))
self._parameters.extend(list(self.GRCU_layers[-1].parameters()))
def parameters(self):
return self._parameters
def forward(self,Nodes_list, A_list):#,nodes_mask_list):
node_feats= Nodes_list[-1]
for unit in self.GRCU_layers:
Nodes_list = unit(A_list,Nodes_list)#,nodes_mask_list)
out = Nodes_list[-1]
if self.skipfeats:
out = torch.cat((out,node_feats), dim=1) # use node_feats.to_dense() if 2hot encoded input
return F.log_softmax(self.mlp(out), dim=1)
class GRCU(torch.nn.Module):
def __init__(self,args):
super().__init__()
self.args = args
cell_args = Namespace({})
cell_args.rows = args.in_feats
cell_args.cols = args.out_feats
self.evolve_weights = mat_GRU_cell(cell_args)
self.activation = self.args.activation
self.GCN_init_weights = Parameter(torch.Tensor(self.args.in_feats,self.args.out_feats))
self.reset_param(self.GCN_init_weights)
def reset_param(self,t):
#Initialize based on the number of columns
stdv = 1. / math.sqrt(t.size(1))
t.data.uniform_(-stdv,stdv)
def forward(self,A_list,node_embs_list):#,mask_list):
GCN_weights = self.GCN_init_weights
out_seq = []
for t,Ahat in enumerate(A_list):
node_embs = node_embs_list[t]
#first evolve the weights from the initial and use the new weights with the node_embs
GCN_weights = self.evolve_weights(GCN_weights)#,node_embs,mask_list[t])
node_embs = self.activation(Ahat.matmul(node_embs.matmul(GCN_weights)))
out_seq.append(node_embs)
return out_seq
class mat_GRU_cell(torch.nn.Module):
def __init__(self,args):
super().__init__()
self.args = args
self.update = mat_GRU_gate(args.rows,
args.cols,
torch.nn.Sigmoid())
self.reset = mat_GRU_gate(args.rows,
args.cols,
torch.nn.Sigmoid())
self.htilda = mat_GRU_gate(args.rows,
args.cols,
torch.nn.Tanh())
self.choose_topk = TopK(feats = args.rows,
k = args.cols)
def forward(self,prev_Q):#,prev_Z,mask): ###Same as GCNH
# z_topk = self.choose_topk(prev_Z,mask)
z_topk = prev_Q
update = self.update(z_topk,prev_Q)
reset = self.reset(z_topk,prev_Q)
h_cap = reset * prev_Q
h_cap = self.htilda(z_topk, h_cap)
new_Q = (1 - update) * prev_Q + update * h_cap
return new_Q
class mat_GRU_gate(torch.nn.Module):
def __init__(self,rows,cols,activation):
super().__init__()
self.activation = activation
#the k here should be in_feats which is actually the rows
self.W = Parameter(torch.Tensor(rows,rows))
self.reset_param(self.W)
self.U = Parameter(torch.Tensor(rows,rows))
self.reset_param(self.U)
self.bias = Parameter(torch.zeros(rows,cols))
def reset_param(self,t):
#Initialize based on the number of columns
stdv = 1. / math.sqrt(t.size(1))
t.data.uniform_(-stdv,stdv)
def forward(self,x,hidden):
out = self.activation(self.W.matmul(x) + \
self.U.matmul(hidden) + \
self.bias)
return out
class TopK(torch.nn.Module):
def __init__(self,feats,k):
super().__init__()
self.scorer = Parameter(torch.Tensor(feats,1))
self.reset_param(self.scorer)
self.k = k
def reset_param(self,t):
#Initialize based on the number of rows
stdv = 1. / math.sqrt(t.size(0))
t.data.uniform_(-stdv,stdv)
def forward(self,node_embs,mask):
scores = node_embs.matmul(self.scorer) / self.scorer.norm()
scores = scores + mask
vals, topk_indices = scores.view(-1).topk(self.k)
topk_indices = topk_indices[vals > -float("Inf")]
if topk_indices.size(0) < self.k:
topk_indices = u.pad_with_last_val(topk_indices,self.k)
tanh = torch.nn.Tanh()
if isinstance(node_embs, torch.sparse.FloatTensor) or \
isinstance(node_embs, torch.cuda.sparse.FloatTensor):
node_embs = node_embs.to_dense()
out = node_embs[topk_indices] * tanh(scores[topk_indices].view(-1,1))
#we need to transpose the output
return out.t()