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@@ -1,18 +1,21 @@ |
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# an implementation for "Learning Deep Generative Models of Graphs" |
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import os |
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from main import * |
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class Args_DGMG(): |
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def __init__(self): |
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### CUDA |
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self.cuda = 2 |
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self.cuda = 0 |
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### model type |
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self.note = 'Baseline_DGMG' # do GCN after adding each edge |
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self.note = 'Baseline_DGMG' # do GCN after adding each edge |
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# self.note = 'Baseline_DGMG_fast' # do GCN only after adding each node |
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### data config |
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self.graph_type = 'caveman_small' |
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# self.graph_type = 'grid_small' |
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# self.graph_type = 'caveman_small' |
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self.graph_type = 'grid_small' |
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# self.graph_type = 'ladder_small' |
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# self.graph_type = 'enzymes_small' |
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# self.graph_type = 'barabasi_small' |
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@@ -24,14 +27,13 @@ class Args_DGMG(): |
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self.node_embedding_size = 64 |
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self.test_graph_num = 200 |
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### training config |
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self.epochs = 2000 # now one epoch means self.batch_ratio x batch_size |
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self.load_epoch = 2000 |
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self.epochs_test_start = 100 |
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self.epochs_test = 100 |
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self.epochs_log = 100 |
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self.epochs_save = 100 |
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self.epochs = 100 # now one epoch means self.batch_ratio x batch_size |
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self.load_epoch = 100 |
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self.epochs_test_start = 10 |
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self.epochs_test = 10 |
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self.epochs_log = 10 |
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self.epochs_save = 10 |
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if 'fast' in self.note: |
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self.is_fast = True |
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else: |
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@@ -49,7 +51,6 @@ class Args_DGMG(): |
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self.figure_prediction_save_path = 'figures_prediction/' |
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self.nll_save_path = 'nll/' |
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self.fname = self.note + '_' + self.graph_type + '_' + str(self.node_embedding_size) |
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self.fname_pred = self.note + '_' + self.graph_type + '_' + str(self.node_embedding_size) + '_pred_' |
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self.fname_train = self.note + '_' + self.graph_type + '_' + str(self.node_embedding_size) + '_train_' |
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@@ -59,13 +60,12 @@ class Args_DGMG(): |
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self.save = True |
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def train_DGMG_epoch(epoch, args, model, dataset, optimizer, scheduler, is_fast = False): |
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def train_DGMG_epoch(epoch, args, model, dataset, optimizer, scheduler, is_fast=False): |
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model.train() |
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graph_num = len(dataset) |
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order = list(range(graph_num)) |
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shuffle(order) |
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loss_addnode = 0 |
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loss_addedge = 0 |
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loss_node = 0 |
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@@ -79,16 +79,17 @@ def train_DGMG_epoch(epoch, args, model, dataset, optimizer, scheduler, is_fast |
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order_mapping = dict(zip(graph.nodes(), node_order)) |
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graph = nx.relabel_nodes(graph, order_mapping, copy=True) |
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# NOTE: when starting loop, we assume a node has already been generated |
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node_count = 1 |
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node_embedding = [Variable(torch.ones(1,args.node_embedding_size)).cuda()] # list of torch tensors, each size: 1*hidden |
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node_embedding = [ |
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Variable(torch.ones(1, args.node_embedding_size)).cuda()] # list of torch tensors, each size: 1*hidden |
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loss = 0 |
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while node_count<=graph.number_of_nodes(): |
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node_neighbor = graph.subgraph(list(range(node_count))).adjacency_list() # list of lists (first node is zero) |
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node_neighbor_new = graph.subgraph(list(range(node_count+1))).adjacency_list()[-1] # list of new node's neighbors |
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while node_count <= graph.number_of_nodes(): |
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node_neighbor = graph.subgraph( |
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list(range(node_count))).adjacency_list() # list of lists (first node is zero) |
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node_neighbor_new = graph.subgraph(list(range(node_count + 1))).adjacency_list()[ |
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-1] # list of new node's neighbors |
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# 1 message passing |
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# do 2 times message passing |
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@@ -108,7 +109,7 @@ def train_DGMG_epoch(epoch, args, model, dataset, optimizer, scheduler, is_fast |
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if is_fast: |
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node_embedding_cat = torch.cat(node_embedding, dim=0) |
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# calc loss |
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loss_addnode_step = F.binary_cross_entropy(p_addnode,Variable(torch.ones((1,1))).cuda()) |
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loss_addnode_step = F.binary_cross_entropy(p_addnode, Variable(torch.ones((1, 1))).cuda()) |
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# loss_addnode_step.backward(retain_graph=True) |
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loss += loss_addnode_step |
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loss_addnode += loss_addnode_step.data |
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@@ -120,9 +121,8 @@ def train_DGMG_epoch(epoch, args, model, dataset, optimizer, scheduler, is_fast |
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loss_addnode += loss_addnode_step.data |
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break |
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edge_count = 0 |
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while edge_count<=len(node_neighbor_new): |
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while edge_count <= len(node_neighbor_new): |
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if not is_fast: |
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node_embedding = message_passing(node_neighbor, node_embedding, model) |
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node_embedding_cat = torch.cat(node_embedding, dim=0) |
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@@ -140,19 +140,20 @@ def train_DGMG_epoch(epoch, args, model, dataset, optimizer, scheduler, is_fast |
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# 5 f_nodes |
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# excluding the last node (which is the new node) |
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node_new_embedding_cat = node_embedding_cat[-1,:].expand(node_embedding_cat.size(0)-1,node_embedding_cat.size(1)) |
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s_node = model.f_s(torch.cat((node_embedding_cat[0:-1,:],node_new_embedding_cat),dim=1)) |
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p_node = F.softmax(s_node.permute(1,0)) |
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node_new_embedding_cat = node_embedding_cat[-1, :].expand(node_embedding_cat.size(0) - 1, |
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node_embedding_cat.size(1)) |
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s_node = model.f_s(torch.cat((node_embedding_cat[0:-1, :], node_new_embedding_cat), dim=1)) |
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p_node = F.softmax(s_node.permute(1, 0)) |
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# get ground truth |
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a_node = torch.zeros((1,p_node.size(1))) |
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a_node = torch.zeros((1, p_node.size(1))) |
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# print('node_neighbor_new',node_neighbor_new, edge_count) |
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a_node[0,node_neighbor_new[edge_count]] = 1 |
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a_node[0, node_neighbor_new[edge_count]] = 1 |
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a_node = Variable(a_node).cuda() |
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# add edge |
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node_neighbor[-1].append(node_neighbor_new[edge_count]) |
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node_neighbor[node_neighbor_new[edge_count]].append(len(node_neighbor)-1) |
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node_neighbor[node_neighbor_new[edge_count]].append(len(node_neighbor) - 1) |
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# calc loss |
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loss_node_step = F.binary_cross_entropy(p_node,a_node) |
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loss_node_step = F.binary_cross_entropy(p_node, a_node) |
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# loss_node_step.backward(retain_graph=True) |
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loss += loss_node_step |
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loss_node += loss_node_step.data |
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@@ -175,48 +176,27 @@ def train_DGMG_epoch(epoch, args, model, dataset, optimizer, scheduler, is_fast |
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loss_all = loss_addnode + loss_addedge + loss_node |
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if epoch % args.epochs_log==0: |
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if epoch % args.epochs_log == 0: |
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print('Epoch: {}/{}, train loss: {:.6f}, graph type: {}, hidden: {}'.format( |
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epoch, args.epochs,loss_all[0], args.graph_type, args.node_embedding_size)) |
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epoch, args.epochs, loss_all, args.graph_type, args.node_embedding_size)) |
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# loss_sum += loss.data[0]*x.size(0) |
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# return loss_sum |
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def test_DGMG_epoch(args, model, is_fast=False): |
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model.eval() |
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graph_num = args.test_graph_num |
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def train_DGMG_forward_epoch(args, model, dataset, is_fast = False): |
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model.train() |
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graph_num = len(dataset) |
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order = list(range(graph_num)) |
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shuffle(order) |
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loss_addnode = 0 |
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loss_addedge = 0 |
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loss_node = 0 |
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for i in order: |
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model.zero_grad() |
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graph = dataset[i] |
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# do random ordering: relabel nodes |
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node_order = list(range(graph.number_of_nodes())) |
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shuffle(node_order) |
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order_mapping = dict(zip(graph.nodes(), node_order)) |
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graph = nx.relabel_nodes(graph, order_mapping, copy=True) |
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graphs_generated = [] |
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for i in range(graph_num): |
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# NOTE: when starting loop, we assume a node has already been generated |
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node_count = 1 |
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node_embedding = [Variable(torch.ones(1,args.node_embedding_size)).cuda()] # list of torch tensors, each size: 1*hidden |
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loss = 0 |
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while node_count<=graph.number_of_nodes(): |
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node_neighbor = graph.subgraph(list(range(node_count))).adjacency_list() # list of lists (first node is zero) |
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node_neighbor_new = graph.subgraph(list(range(node_count+1))).adjacency_list()[-1] # list of new node's neighbors |
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node_neighbor = [[]] # list of lists (first node is zero) |
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node_embedding = [ |
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Variable(torch.ones(1, args.node_embedding_size)).cuda()] # list of torch tensors, each size: 1*hidden |
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node_count = 1 |
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while node_count <= args.max_num_node: |
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# 1 message passing |
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# do 2 times message passing |
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node_embedding = message_passing(node_neighbor, node_embedding, model) |
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@@ -228,28 +208,20 @@ def train_DGMG_forward_epoch(args, model, dataset, is_fast = False): |
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# 3 f_addnode |
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p_addnode = model.f_an(graph_embedding) |
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if node_count < graph.number_of_nodes(): |
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a_addnode = sample_tensor(p_addnode) |
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# print(a_addnode.data[0][0]) |
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if a_addnode.data[0][0] == 1: |
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# print('add node') |
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# add node |
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node_neighbor.append([]) |
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node_embedding.append(init_embedding) |
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if is_fast: |
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node_embedding_cat = torch.cat(node_embedding, dim=0) |
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# calc loss |
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loss_addnode_step = F.binary_cross_entropy(p_addnode,Variable(torch.ones((1,1))).cuda()) |
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# loss_addnode_step.backward(retain_graph=True) |
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loss += loss_addnode_step |
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loss_addnode += loss_addnode_step.data |
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else: |
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# calc loss |
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loss_addnode_step = F.binary_cross_entropy(p_addnode, Variable(torch.zeros((1, 1))).cuda()) |
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# loss_addnode_step.backward(retain_graph=True) |
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loss += loss_addnode_step |
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loss_addnode += loss_addnode_step.data |
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break |
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edge_count = 0 |
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while edge_count<=len(node_neighbor_new): |
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while edge_count < args.max_num_node: |
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if not is_fast: |
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node_embedding = message_passing(node_neighbor, node_embedding, model) |
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node_embedding_cat = torch.cat(node_embedding, dim=0) |
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@@ -257,61 +229,37 @@ def train_DGMG_forward_epoch(args, model, dataset, is_fast = False): |
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# 4 f_addedge |
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p_addedge = model.f_ae(graph_embedding) |
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a_addedge = sample_tensor(p_addedge) |
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# print(a_addedge.data[0][0]) |
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if edge_count < len(node_neighbor_new): |
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# calc loss |
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loss_addedge_step = F.binary_cross_entropy(p_addedge, Variable(torch.ones((1, 1))).cuda()) |
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# loss_addedge_step.backward(retain_graph=True) |
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loss += loss_addedge_step |
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loss_addedge += loss_addedge_step.data |
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if a_addedge.data[0][0] == 1: |
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# print('add edge') |
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# 5 f_nodes |
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# excluding the last node (which is the new node) |
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node_new_embedding_cat = node_embedding_cat[-1,:].expand(node_embedding_cat.size(0)-1,node_embedding_cat.size(1)) |
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s_node = model.f_s(torch.cat((node_embedding_cat[0:-1,:],node_new_embedding_cat),dim=1)) |
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p_node = F.softmax(s_node.permute(1,0)) |
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# get ground truth |
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a_node = torch.zeros((1,p_node.size(1))) |
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# print('node_neighbor_new',node_neighbor_new, edge_count) |
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a_node[0,node_neighbor_new[edge_count]] = 1 |
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a_node = Variable(a_node).cuda() |
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node_new_embedding_cat = node_embedding_cat[-1, :].expand(node_embedding_cat.size(0) - 1, |
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node_embedding_cat.size(1)) |
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s_node = model.f_s(torch.cat((node_embedding_cat[0:-1, :], node_new_embedding_cat), dim=1)) |
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p_node = F.softmax(s_node.permute(1, 0)) |
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a_node = gumbel_softmax(p_node, temperature=0.01) |
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_, a_node_id = a_node.topk(1) |
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a_node_id = int(a_node_id.data[0][0]) |
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# add edge |
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node_neighbor[-1].append(node_neighbor_new[edge_count]) |
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node_neighbor[node_neighbor_new[edge_count]].append(len(node_neighbor)-1) |
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# calc loss |
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loss_node_step = F.binary_cross_entropy(p_node,a_node) |
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# loss_node_step.backward(retain_graph=True) |
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loss += loss_node_step |
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loss_node += loss_node_step.data*p_node.size(1) |
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node_neighbor[-1].append(a_node_id) |
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node_neighbor[a_node_id].append(len(node_neighbor) - 1) |
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else: |
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# calc loss |
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loss_addedge_step = F.binary_cross_entropy(p_addedge, Variable(torch.zeros((1, 1))).cuda()) |
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# loss_addedge_step.backward(retain_graph=True) |
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loss += loss_addedge_step |
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loss_addedge += loss_addedge_step.data |
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break |
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edge_count += 1 |
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node_count += 1 |
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# save graph |
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node_neighbor_dict = dict(zip(list(range(len(node_neighbor))), node_neighbor)) |
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graph = nx.from_dict_of_lists(node_neighbor_dict) |
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graphs_generated.append(graph) |
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loss_all = loss_addnode + loss_addedge + loss_node |
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# if epoch % args.epochs_log==0: |
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# print('Epoch: {}/{}, train loss: {:.6f}, graph type: {}, hidden: {}'.format( |
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# epoch, args.epochs,loss_all[0], args.graph_type, args.node_embedding_size)) |
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return loss_all[0]/len(dataset) |
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return graphs_generated |
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def test_DGMG_epoch(args, model, is_fast=False): |
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def test_DGMG_2(args, model, test_graph, is_fast=False): |
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model.eval() |
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graph_num = args.test_graph_num |
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@@ -319,10 +267,12 @@ def test_DGMG_epoch(args, model, is_fast=False): |
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for i in range(graph_num): |
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# NOTE: when starting loop, we assume a node has already been generated |
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node_neighbor = [[]] # list of lists (first node is zero) |
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node_embedding = [Variable(torch.ones(1,args.node_embedding_size)).cuda()] # list of torch tensors, each size: 1*hidden |
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node_embedding = [ |
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Variable(torch.ones(1, args.node_embedding_size)).cuda()] # list of torch tensors, each size: 1*hidden |
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node_max = len(test_graph.nodes()) |
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node_count = 1 |
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while node_count<=args.max_num_node: |
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while node_count <= node_max: |
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# 1 message passing |
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# do 2 times message passing |
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node_embedding = message_passing(node_neighbor, node_embedding, model) |
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@@ -335,9 +285,8 @@ def test_DGMG_epoch(args, model, is_fast=False): |
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# 3 f_addnode |
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p_addnode = model.f_an(graph_embedding) |
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a_addnode = sample_tensor(p_addnode) |
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# print(a_addnode.data[0][0]) |
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if a_addnode.data[0][0]==1: |
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# print('add node') |
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if a_addnode.data[0][0] == 1: |
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# add node |
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node_neighbor.append([]) |
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node_embedding.append(init_embedding) |
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@@ -347,7 +296,7 @@ def test_DGMG_epoch(args, model, is_fast=False): |
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break |
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edge_count = 0 |
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while edge_count<args.max_num_node: |
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while edge_count < args.max_num_node: |
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if not is_fast: |
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node_embedding = message_passing(node_neighbor, node_embedding, model) |
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node_embedding_cat = torch.cat(node_embedding, dim=0) |
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@@ -356,42 +305,93 @@ def test_DGMG_epoch(args, model, is_fast=False): |
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# 4 f_addedge |
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p_addedge = model.f_ae(graph_embedding) |
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a_addedge = sample_tensor(p_addedge) |
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# print(a_addedge.data[0][0]) |
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if a_addedge.data[0][0]==1: |
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# print('add edge') |
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if a_addedge.data[0][0] == 1: |
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# 5 f_nodes |
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# excluding the last node (which is the new node) |
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node_new_embedding_cat = node_embedding_cat[-1,:].expand(node_embedding_cat.size(0)-1,node_embedding_cat.size(1)) |
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s_node = model.f_s(torch.cat((node_embedding_cat[0:-1,:],node_new_embedding_cat),dim=1)) |
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p_node = F.softmax(s_node.permute(1,0)) |
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node_new_embedding_cat = node_embedding_cat[-1, :].expand(node_embedding_cat.size(0) - 1, |
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node_embedding_cat.size(1)) |
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s_node = model.f_s(torch.cat((node_embedding_cat[0:-1, :], node_new_embedding_cat), dim=1)) |
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p_node = F.softmax(s_node.permute(1, 0)) |
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a_node = gumbel_softmax(p_node, temperature=0.01) |
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_, a_node_id = a_node.topk(1) |
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a_node_id = int(a_node_id.data[0][0]) |
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# add edge |
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node_neighbor[-1].append(a_node_id) |
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node_neighbor[a_node_id].append(len(node_neighbor)-1) |
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node_neighbor[a_node_id].append(len(node_neighbor) - 1) |
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else: |
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break |
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edge_count += 1 |
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node_count += 1 |
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# save graph |
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node_neighbor_dict = dict(zip(list(range(len(node_neighbor))), node_neighbor)) |
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graph = nx.from_dict_of_lists(node_neighbor_dict) |
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graphs_generated.append(graph) |
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return graphs_generated |
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# clear node_neighbor and build it again |
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node_neighbor = [] |
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for n in range(node_max): |
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temp_neighbor = [k for k in test_graph.edge[n]] |
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node_neighbor.append(temp_neighbor) |
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# now add the last node for real |
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# 1 message passing |
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# do 2 times message passing |
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try: |
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node_embedding = message_passing(node_neighbor, node_embedding, model) |
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# 2 graph embedding and new node embedding |
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node_embedding_cat = torch.cat(node_embedding, dim=0) |
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graph_embedding = calc_graph_embedding(node_embedding_cat, model) |
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init_embedding = calc_init_embedding(node_embedding_cat, model) |
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# 3 f_addnode |
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p_addnode = model.f_an(graph_embedding) |
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a_addnode = sample_tensor(p_addnode) |
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if a_addnode.data[0][0] == 1: |
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# add node |
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node_neighbor.append([]) |
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node_embedding.append(init_embedding) |
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if is_fast: |
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node_embedding_cat = torch.cat(node_embedding, dim=0) |
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edge_count = 0 |
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while edge_count < args.max_num_node: |
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if not is_fast: |
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node_embedding = message_passing(node_neighbor, node_embedding, model) |
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node_embedding_cat = torch.cat(node_embedding, dim=0) |
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graph_embedding = calc_graph_embedding(node_embedding_cat, model) |
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# 4 f_addedge |
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p_addedge = model.f_ae(graph_embedding) |
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a_addedge = sample_tensor(p_addedge) |
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if a_addedge.data[0][0] == 1: |
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# 5 f_nodes |
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# excluding the last node (which is the new node) |
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node_new_embedding_cat = node_embedding_cat[-1, :].expand(node_embedding_cat.size(0) - 1, |
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node_embedding_cat.size(1)) |
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s_node = model.f_s(torch.cat((node_embedding_cat[0:-1, :], node_new_embedding_cat), dim=1)) |
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p_node = F.softmax(s_node.permute(1, 0)) |
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a_node = gumbel_softmax(p_node, temperature=0.01) |
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_, a_node_id = a_node.topk(1) |
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a_node_id = int(a_node_id.data[0][0]) |
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# add edge |
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node_neighbor[-1].append(a_node_id) |
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node_neighbor[a_node_id].append(len(node_neighbor) - 1) |
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else: |
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break |
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edge_count += 1 |
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node_count += 1 |
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except: |
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print('error') |
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# save graph |
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node_neighbor_dict = dict(zip(list(range(len(node_neighbor))), node_neighbor)) |
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graph = nx.from_dict_of_lists(node_neighbor_dict) |
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graphs_generated.append(graph) |
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return graphs_generated |
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########### train function for LSTM + VAE |
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@@ -420,10 +420,10 @@ def train_DGMG(args, dataset_train, model): |
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train_DGMG_epoch(epoch, args, model, dataset_train, optimizer, scheduler, is_fast=args.is_fast) |
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time_end = tm.time() |
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time_all[epoch - 1] = time_end - time_start |
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# print('time used',time_all[epoch - 1]) |
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print('time used', time_all[epoch - 1]) |
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# test |
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if epoch % args.epochs_test == 0 and epoch >= args.epochs_test_start: |
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graphs = test_DGMG_epoch(args,model, is_fast=args.is_fast) |
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graphs = test_DGMG_epoch(args, model, is_fast=args.is_fast) |
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fname = args.graph_save_path + args.fname_pred + str(epoch) + '.dat' |
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save_graph_list(graphs, fname) |
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# print('test done, graphs saved') |
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@@ -437,96 +437,23 @@ def train_DGMG(args, dataset_train, model): |
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np.save(args.timing_save_path + args.fname, time_all) |
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########### train function for LSTM + VAE |
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def train_DGMG_nll(args, dataset_train,dataset_test, model,max_iter=1000): |
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# check if load existing model |
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fname = args.model_save_path + args.fname + 'model_' + str(args.load_epoch) + '.dat' |
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model.load_state_dict(torch.load(fname)) |
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fname_output = args.nll_save_path + args.note + '_' + args.graph_type + '.csv' |
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with open(fname_output, 'w+') as f: |
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f.write('train,test\n') |
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# start main loop |
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for iter in range(max_iter): |
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nll_train = train_DGMG_forward_epoch(args, model, dataset_train, is_fast=args.is_fast) |
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nll_test = train_DGMG_forward_epoch(args, model, dataset_test, is_fast=args.is_fast) |
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print('train', nll_train, 'test', nll_test) |
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f.write(str(nll_train) + ',' + str(nll_test) + '\n') |
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if __name__ == '__main__': |
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args = Args_DGMG() |
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os.environ['CUDA_VISIBLE_DEVICES'] = str(args.cuda) |
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print('CUDA', args.cuda) |
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print('File name prefix',args.fname) |
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print('File name prefix', args.fname) |
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graphs = [] |
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for i in range(4, 10): |
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graphs.append(nx.ladder_graph(i)) |
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model = DGM_graphs(h_size = args.node_embedding_size).cuda() |
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model = DGM_graphs(h_size=args.node_embedding_size).cuda() |
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if args.graph_type == 'ladder_small': |
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graphs = [] |
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for i in range(2, 11): |
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graphs.append(nx.ladder_graph(i)) |
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args.max_prev_node = 10 |
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# if args.graph_type == 'caveman_small': |
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# graphs = [] |
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# for i in range(2, 5): |
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# for j in range(2, 6): |
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# for k in range(10): |
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# graphs.append(nx.relaxed_caveman_graph(i, j, p=0.1)) |
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# args.max_prev_node = 20 |
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if args.graph_type=='caveman_small': |
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graphs = [] |
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for i in range(2, 3): |
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for j in range(6, 11): |
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for k in range(20): |
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graphs.append(caveman_special(i, j, p_edge=0.8)) |
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args.max_prev_node = 20 |
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if args.graph_type == 'grid_small': |
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graphs = [] |
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for i in range(2, 5): |
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for j in range(2, 6): |
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for i in range(2, 3): |
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for j in range(2, 4): |
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graphs.append(nx.grid_2d_graph(i, j)) |
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args.max_prev_node = 15 |
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if args.graph_type == 'barabasi_small': |
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graphs = [] |
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for i in range(4, 21): |
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for j in range(3, 4): |
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for k in range(10): |
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graphs.append(nx.barabasi_albert_graph(i, j)) |
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args.max_prev_node = 20 |
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if args.graph_type == 'enzymes_small': |
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graphs_raw = Graph_load_batch(min_num_nodes=10, name='ENZYMES') |
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graphs = [] |
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for G in graphs_raw: |
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if G.number_of_nodes()<=20: |
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graphs.append(G) |
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args.max_prev_node = 15 |
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if args.graph_type == 'citeseer_small': |
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_, _, G = Graph_load(dataset='citeseer') |
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G = max(nx.connected_component_subgraphs(G), key=len) |
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G = nx.convert_node_labels_to_integers(G) |
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graphs = [] |
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for i in range(G.number_of_nodes()): |
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G_ego = nx.ego_graph(G, i, radius=1) |
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if (G_ego.number_of_nodes() >= 4) and (G_ego.number_of_nodes() <= 20): |
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graphs.append(G_ego) |
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shuffle(graphs) |
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graphs = graphs[0:200] |
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args.max_prev_node = 15 |
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args.max_prev_node = 6 |
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# remove self loops |
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for graph in graphs: |
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@@ -537,58 +464,18 @@ if __name__ == '__main__': |
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# split datasets |
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random.seed(123) |
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shuffle(graphs) |
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graphs_len = len(graphs) |
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graphs_test = graphs[int(0.8 * graphs_len):] |
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graphs_train = graphs[0:int(0.8 * graphs_len)] |
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# graphs_len = len(graphs) |
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# graphs_test = graphs[int(0.8 * graphs_len):] |
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# graphs_validate = graphs[int(0.7 * graphs_len):int(0.8 * graphs_len)] |
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# graphs_train = graphs[0:int(0.7 * graphs_len)] |
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args.max_num_node = max([graphs[i].number_of_nodes() for i in range(len(graphs))]) |
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# args.max_num_node = 2000 |
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# show graphs statistics |
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print('total graph num: {}, training set: {}'.format(len(graphs), len(graphs_train))) |
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print('max number node: {}'.format(args.max_num_node)) |
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print('max previous node: {}'.format(args.max_prev_node)) |
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test_graph = nx.grid_2d_graph(2, 3) |
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test_graph.remove_node(test_graph.nodes()[5]) |
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train_DGMG(args, graphs, model) |
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# save ground truth graphs |
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# save_graph_list(graphs, args.graph_save_path + args.fname_train + '0.dat') |
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# save_graph_list(graphs, args.graph_save_path + args.fname_test + '0.dat') |
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# print('train and test graphs saved') |
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## if use pre-saved graphs |
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# dir_input = "graphs/" |
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# fname_test = args.graph_save_path + args.fname_test + '0.dat' |
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# graphs = load_graph_list(fname_test, is_real=True) |
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# graphs_test = graphs[int(0.8 * graphs_len):] |
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# graphs_train = graphs[0:int(0.8 * graphs_len)] |
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# graphs_validate = graphs[0:int(0.2 * graphs_len)] |
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# print('train') |
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# for graph in graphs_validate: |
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# print(graph.number_of_nodes()) |
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# print('test') |
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# for graph in graphs_test: |
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# print(graph.number_of_nodes()) |
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### train |
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train_DGMG(args,graphs,model) |
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### calc nll |
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# train_DGMG_nll(args, graphs_validate,graphs_test, model,max_iter=1000) |
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# for j in range(1000): |
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# graph = graphs[0] |
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# # do random ordering: relabel nodes |
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# node_order = list(range(graph.number_of_nodes())) |
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# shuffle(node_order) |
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# order_mapping = dict(zip(graph.nodes(), node_order)) |
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# graph = nx.relabel_nodes(graph, order_mapping, copy=True) |
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# print(graph.nodes()) |
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test_graph = nx.convert_node_labels_to_integers(test_graph) |
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test_DGMG_2(args, model, test_graph) |