ultra_50g / ultra /base_nbfnet.py
mgalkin's picture
modeling script
89650c1
raw
history blame
15.9 kB
import copy
from collections.abc import Sequence
import torch
from torch import nn, autograd
from torch_scatter import scatter_add
from . import tasks, layers
class BaseNBFNet(nn.Module):
def __init__(self, input_dim, hidden_dims, num_relation, message_func="distmult", aggregate_func="sum",
short_cut=False, layer_norm=False, activation="relu", concat_hidden=False, num_mlp_layer=2,
dependent=False, remove_one_hop=False, num_beam=10, path_topk=10, **kwargs):
super(BaseNBFNet, self).__init__()
if not isinstance(hidden_dims, Sequence):
hidden_dims = [hidden_dims]
self.dims = [input_dim] + list(hidden_dims)
self.num_relation = num_relation
self.short_cut = short_cut # whether to use residual connections between GNN layers
self.concat_hidden = concat_hidden # whether to compute final states as a function of all layer outputs or last
self.remove_one_hop = remove_one_hop # whether to dynamically remove one-hop edges from edge_index
self.num_beam = num_beam
self.path_topk = path_topk
self.message_func = message_func
self.aggregate_func = aggregate_func
self.layer_norm = layer_norm
self.activation = activation
self.num_mlp_layers = num_mlp_layer
# self.layers = nn.ModuleList()
# for i in range(len(self.dims) - 1):
# self.layers.append(layers.GeneralizedRelationalConv(self.dims[i], self.dims[i + 1], num_relation,
# self.dims[0], message_func, aggregate_func, layer_norm,
# activation, dependent))
# feature_dim = (sum(hidden_dims) if concat_hidden else hidden_dims[-1]) + input_dim
# # additional relation embedding which serves as an initial 'query' for the NBFNet forward pass
# # each layer has its own learnable relations matrix, so we send the total number of relations, too
# self.query = nn.Embedding(num_relation, input_dim)
# self.mlp = nn.Sequential()
# mlp = []
# for i in range(num_mlp_layer - 1):
# mlp.append(nn.Linear(feature_dim, feature_dim))
# mlp.append(nn.ReLU())
# mlp.append(nn.Linear(feature_dim, 1))
# self.mlp = nn.Sequential(*mlp)
def remove_easy_edges(self, data, h_index, t_index, r_index=None):
# we remove training edges (we need to predict them at training time) from the edge index
# think of it as a dynamic edge dropout
h_index_ext = torch.cat([h_index, t_index], dim=-1)
t_index_ext = torch.cat([t_index, h_index], dim=-1)
r_index_ext = torch.cat([r_index, r_index + data.num_relations // 2], dim=-1)
if self.remove_one_hop:
# we remove all existing immediate edges between heads and tails in the batch
edge_index = data.edge_index
easy_edge = torch.stack([h_index_ext, t_index_ext]).flatten(1)
index = tasks.edge_match(edge_index, easy_edge)[0]
mask = ~index_to_mask(index, data.num_edges)
else:
# we remove existing immediate edges between heads and tails in the batch with the given relation
edge_index = torch.cat([data.edge_index, data.edge_type.unsqueeze(0)])
# note that here we add relation types r_index_ext to the matching query
easy_edge = torch.stack([h_index_ext, t_index_ext, r_index_ext]).flatten(1)
index = tasks.edge_match(edge_index, easy_edge)[0]
mask = ~index_to_mask(index, data.num_edges)
data = copy.copy(data)
data.edge_index = data.edge_index[:, mask]
data.edge_type = data.edge_type[mask]
return data
def negative_sample_to_tail(self, h_index, t_index, r_index, num_direct_rel):
# convert p(h | t, r) to p(t' | h', r')
# h' = t, r' = r^{-1}, t' = h
is_t_neg = (h_index == h_index[:, [0]]).all(dim=-1, keepdim=True)
new_h_index = torch.where(is_t_neg, h_index, t_index)
new_t_index = torch.where(is_t_neg, t_index, h_index)
new_r_index = torch.where(is_t_neg, r_index, r_index + num_direct_rel)
return new_h_index, new_t_index, new_r_index
def bellmanford(self, data, h_index, r_index, separate_grad=False):
batch_size = len(r_index)
# initialize queries (relation types of the given triples)
query = self.query(r_index)
index = h_index.unsqueeze(-1).expand_as(query)
# initial (boundary) condition - initialize all node states as zeros
boundary = torch.zeros(batch_size, data.num_nodes, self.dims[0], device=h_index.device)
# by the scatter operation we put query (relation) embeddings as init features of source (index) nodes
boundary.scatter_add_(1, index.unsqueeze(1), query.unsqueeze(1))
size = (data.num_nodes, data.num_nodes)
edge_weight = torch.ones(data.num_edges, device=h_index.device)
hiddens = []
edge_weights = []
layer_input = boundary
for layer in self.layers:
if separate_grad:
edge_weight = edge_weight.clone().requires_grad_()
# Bellman-Ford iteration, we send the original boundary condition in addition to the updated node states
hidden = layer(layer_input, query, boundary, data.edge_index, data.edge_type, size, edge_weight)
if self.short_cut and hidden.shape == layer_input.shape:
# residual connection here
hidden = hidden + layer_input
hiddens.append(hidden)
edge_weights.append(edge_weight)
layer_input = hidden
# original query (relation type) embeddings
node_query = query.unsqueeze(1).expand(-1, data.num_nodes, -1) # (batch_size, num_nodes, input_dim)
if self.concat_hidden:
output = torch.cat(hiddens + [node_query], dim=-1)
else:
output = torch.cat([hiddens[-1], node_query], dim=-1)
return {
"node_feature": output,
"edge_weights": edge_weights,
}
def forward(self, data, batch):
h_index, t_index, r_index = batch.unbind(-1)
if self.training:
# Edge dropout in the training mode
# here we want to remove immediate edges (head, relation, tail) from the edge_index and edge_types
# to make NBFNet iteration learn non-trivial paths
data = self.remove_easy_edges(data, h_index, t_index, r_index, data.num_relations // 2)
shape = h_index.shape
# turn all triples in a batch into a tail prediction mode
h_index, t_index, r_index = self.negative_sample_to_tail(h_index, t_index, r_index, num_direct_rel=data.num_relations // 2)
assert (h_index[:, [0]] == h_index).all()
assert (r_index[:, [0]] == r_index).all()
# message passing and updated node representations
output = self.bellmanford(data, h_index[:, 0], r_index[:, 0]) # (num_nodes, batch_size, feature_dim)
feature = output["node_feature"]
index = t_index.unsqueeze(-1).expand(-1, -1, feature.shape[-1])
# extract representations of tail entities from the updated node states
feature = feature.gather(1, index) # (batch_size, num_negative + 1, feature_dim)
# probability logit for each tail node in the batch
# (batch_size, num_negative + 1, dim) -> (batch_size, num_negative + 1)
score = self.mlp(feature).squeeze(-1)
return score.view(shape)
def visualize(self, data, batch):
assert batch.shape == (1, 3)
h_index, t_index, r_index = batch.unbind(-1)
output = self.bellmanford(data, h_index, r_index, separate_grad=True)
feature = output["node_feature"]
edge_weights = output["edge_weights"]
index = t_index.unsqueeze(0).unsqueeze(-1).expand(-1, -1, feature.shape[-1])
feature = feature.gather(1, index).squeeze(0)
score = self.mlp(feature).squeeze(-1)
edge_grads = autograd.grad(score, edge_weights)
distances, back_edges = self.beam_search_distance(data, edge_grads, h_index, t_index, self.num_beam)
paths, weights = self.topk_average_length(distances, back_edges, t_index, self.path_topk)
return paths, weights
@torch.no_grad()
def beam_search_distance(self, data, edge_grads, h_index, t_index, num_beam=10):
# beam search the top-k distance from h to t (and to every other node)
num_nodes = data.num_nodes
input = torch.full((num_nodes, num_beam), float("-inf"), device=h_index.device)
input[h_index, 0] = 0
edge_mask = data.edge_index[0, :] != t_index
distances = []
back_edges = []
for edge_grad in edge_grads:
# we don't allow any path goes out of t once it arrives at t
node_in, node_out = data.edge_index[:, edge_mask]
relation = data.edge_type[edge_mask]
edge_grad = edge_grad[edge_mask]
message = input[node_in] + edge_grad.unsqueeze(-1) # (num_edges, num_beam)
# (num_edges, num_beam, 3)
msg_source = torch.stack([node_in, node_out, relation], dim=-1).unsqueeze(1).expand(-1, num_beam, -1)
# (num_edges, num_beam)
is_duplicate = torch.isclose(message.unsqueeze(-1), message.unsqueeze(-2)) & \
(msg_source.unsqueeze(-2) == msg_source.unsqueeze(-3)).all(dim=-1)
# pick the first occurrence as the ranking in the previous node's beam
# this makes deduplication easier later
# and store it in msg_source
is_duplicate = is_duplicate.float() - \
torch.arange(num_beam, dtype=torch.float, device=message.device) / (num_beam + 1)
prev_rank = is_duplicate.argmax(dim=-1, keepdim=True)
msg_source = torch.cat([msg_source, prev_rank], dim=-1) # (num_edges, num_beam, 4)
node_out, order = node_out.sort()
node_out_set = torch.unique(node_out)
# sort messages w.r.t. node_out
message = message[order].flatten() # (num_edges * num_beam)
msg_source = msg_source[order].flatten(0, -2) # (num_edges * num_beam, 4)
size = node_out.bincount(minlength=num_nodes)
msg2out = size_to_index(size[node_out_set] * num_beam)
# deduplicate messages that are from the same source and the same beam
is_duplicate = (msg_source[1:] == msg_source[:-1]).all(dim=-1)
is_duplicate = torch.cat([torch.zeros(1, dtype=torch.bool, device=message.device), is_duplicate])
message = message[~is_duplicate]
msg_source = msg_source[~is_duplicate]
msg2out = msg2out[~is_duplicate]
size = msg2out.bincount(minlength=len(node_out_set))
if not torch.isinf(message).all():
# take the topk messages from the neighborhood
# distance: (len(node_out_set) * num_beam)
distance, rel_index = scatter_topk(message, size, k=num_beam)
abs_index = rel_index + (size.cumsum(0) - size).unsqueeze(-1)
# store msg_source for backtracking
back_edge = msg_source[abs_index] # (len(node_out_set) * num_beam, 4)
distance = distance.view(len(node_out_set), num_beam)
back_edge = back_edge.view(len(node_out_set), num_beam, 4)
# scatter distance / back_edge back to all nodes
distance = scatter_add(distance, node_out_set, dim=0, dim_size=num_nodes) # (num_nodes, num_beam)
back_edge = scatter_add(back_edge, node_out_set, dim=0, dim_size=num_nodes) # (num_nodes, num_beam, 4)
else:
distance = torch.full((num_nodes, num_beam), float("-inf"), device=message.device)
back_edge = torch.zeros(num_nodes, num_beam, 4, dtype=torch.long, device=message.device)
distances.append(distance)
back_edges.append(back_edge)
input = distance
return distances, back_edges
def topk_average_length(self, distances, back_edges, t_index, k=10):
# backtrack distances and back_edges to generate the paths
paths = []
average_lengths = []
for i in range(len(distances)):
distance, order = distances[i][t_index].flatten(0, -1).sort(descending=True)
back_edge = back_edges[i][t_index].flatten(0, -2)[order]
for d, (h, t, r, prev_rank) in zip(distance[:k].tolist(), back_edge[:k].tolist()):
if d == float("-inf"):
break
path = [(h, t, r)]
for j in range(i - 1, -1, -1):
h, t, r, prev_rank = back_edges[j][h, prev_rank].tolist()
path.append((h, t, r))
paths.append(path[::-1])
average_lengths.append(d / len(path))
if paths:
average_lengths, paths = zip(*sorted(zip(average_lengths, paths), reverse=True)[:k])
return paths, average_lengths
def index_to_mask(index, size):
index = index.view(-1)
size = int(index.max()) + 1 if size is None else size
mask = index.new_zeros(size, dtype=torch.bool)
mask[index] = True
return mask
def size_to_index(size):
range = torch.arange(len(size), device=size.device)
index2sample = range.repeat_interleave(size)
return index2sample
def multi_slice_mask(starts, ends, length):
values = torch.cat([torch.ones_like(starts), -torch.ones_like(ends)])
slices = torch.cat([starts, ends])
mask = scatter_add(values, slices, dim=0, dim_size=length + 1)[:-1]
mask = mask.cumsum(0).bool()
return mask
def scatter_extend(data, size, input, input_size):
new_size = size + input_size
new_cum_size = new_size.cumsum(0)
new_data = torch.zeros(new_cum_size[-1], *data.shape[1:], dtype=data.dtype, device=data.device)
starts = new_cum_size - new_size
ends = starts + size
index = multi_slice_mask(starts, ends, new_cum_size[-1])
new_data[index] = data
new_data[~index] = input
return new_data, new_size
def scatter_topk(input, size, k, largest=True):
index2graph = size_to_index(size)
index2graph = index2graph.view([-1] + [1] * (input.ndim - 1))
mask = ~torch.isinf(input)
max = input[mask].max().item()
min = input[mask].min().item()
safe_input = input.clamp(2 * min - max, 2 * max - min)
offset = (max - min) * 4
if largest:
offset = -offset
input_ext = safe_input + offset * index2graph
index_ext = input_ext.argsort(dim=0, descending=largest)
num_actual = size.clamp(max=k)
num_padding = k - num_actual
starts = size.cumsum(0) - size
ends = starts + num_actual
mask = multi_slice_mask(starts, ends, len(index_ext)).nonzero().flatten()
if (num_padding > 0).any():
# special case: size < k, pad with the last valid index
padding = ends - 1
padding2graph = size_to_index(num_padding)
mask = scatter_extend(mask, num_actual, padding[padding2graph], num_padding)[0]
index = index_ext[mask] # (N * k, ...)
value = input.gather(0, index)
if isinstance(k, torch.Tensor) and k.shape == size.shape:
value = value.view(-1, *input.shape[1:])
index = index.view(-1, *input.shape[1:])
index = index - (size.cumsum(0) - size).repeat_interleave(k).view([-1] + [1] * (index.ndim - 1))
else:
value = value.view(-1, k, *input.shape[1:])
index = index.view(-1, k, *input.shape[1:])
index = index - (size.cumsum(0) - size).view([-1] + [1] * (index.ndim - 1))
return value, index