ncut-pytorch / directed_ncut.py
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add directed ncut (test)
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# %%
import torch
import torch.nn.functional as F
def affinity_from_features(
features,
features_B=None,
affinity_focal_gamma=1.0,
distance="cosine",
normalize_features=False,
fill_diagonal=False,
n_features=1,
):
"""Compute affinity matrix from input features.
Args:
features (torch.Tensor): input features, shape (n_samples, n_features)
feature_B (torch.Tensor, optional): optional, if not None, compute affinity between two features
affinity_focal_gamma (float): affinity matrix parameter, lower t reduce the edge weights
on weak connections, default 1.0
distance (str): distance metric, 'cosine' (default) or 'euclidean'.
apply_normalize (bool): normalize input features before computing affinity matrix,
default True
Returns:
(torch.Tensor): affinity matrix, shape (n_samples, n_samples)
"""
# compute affinity matrix from input features
features = features.clone()
if features_B is not None:
features_B = features_B.clone()
# if feature_B is not provided, compute affinity matrix on features x features
# if feature_B is provided, compute affinity matrix on features x feature_B
if features_B is not None:
assert not fill_diagonal, "fill_diagonal should be False when feature_B is None"
features_B = features if features_B is None else features_B
if normalize_features:
features = F.normalize(features, dim=-1)
features_B = F.normalize(features_B, dim=-1)
if distance == "cosine":
# if not check_if_normalized(features):
# TODO: make sure features are normalized within each head
features = F.normalize(features, dim=-1)
# if not check_if_normalized(features_B):
features_B = F.normalize(features_B, dim=-1)
A = 1 - (features @ features_B.T) / n_features
elif distance == "euclidean":
A = torch.cdist(features, features_B, p=2) / n_features
else:
raise ValueError("distance should be 'cosine' or 'euclidean'")
if fill_diagonal:
A[torch.arange(A.shape[0]), torch.arange(A.shape[0])] = 0
# torch.exp make affinity matrix positive definite,
# lower affinity_focal_gamma reduce the weak edge weights
A = torch.exp(-((A / affinity_focal_gamma)))
return A
from ncut_pytorch.ncut_pytorch import run_subgraph_sampling, propagate_knn, gram_schmidt
import logging
import torch
def ncut(
A,
num_eig=20,
eig_solver="svd_lowrank",
make_symmetric=True,
):
"""PyTorch implementation of Normalized cut without Nystrom-like approximation.
Args:
A (torch.Tensor): affinity matrix, shape (n_samples, n_samples)
num_eig (int): number of eigenvectors to return
eig_solver (str): eigen decompose solver, ['svd_lowrank', 'lobpcg', 'svd', 'eigh']
Returns:
(torch.Tensor): eigenvectors corresponding to the eigenvalues, shape (n_samples, num_eig)
(torch.Tensor): eigenvalues of the eigenvectors, sorted in descending order
"""
if make_symmetric:
# make sure A is symmetric
A = (A + A.T) / 2
# symmetrical normalization; A = D^(-1/2) A D^(-1/2)
D_r = A.sum(dim=0).detach().clone()
D_c = A.sum(dim=1).detach().clone()
A /= torch.sqrt(D_r)[:, None]
A /= torch.sqrt(D_c)[None, :]
# compute eigenvectors
if eig_solver == "svd_lowrank": # default
# only top q eigenvectors, fastest
eigen_vector, eigen_value, _ = torch.svd_lowrank(A, q=num_eig)
elif eig_solver == "lobpcg":
# only top k eigenvectors, fast
eigen_value, eigen_vector = torch.lobpcg(A, k=num_eig)
elif eig_solver == "svd":
# all eigenvectors, slow
eigen_vector, eigen_value, _ = torch.svd(A)
elif eig_solver == "eigh":
# all eigenvectors, slow
eigen_value, eigen_vector = torch.linalg.eigh(A)
else:
raise ValueError(
"eigen_solver should be 'lobpcg', 'svd_lowrank', 'svd' or 'eigh'"
)
# sort eigenvectors by eigenvalues, take top (descending order)
eigen_value = eigen_value.real
eigen_vector = eigen_vector.real
sort_order = torch.argsort(eigen_value, descending=True)[:num_eig]
eigen_value = eigen_value[sort_order]
eigen_vector = eigen_vector[:, sort_order]
if eigen_value.min() < 0:
logging.warning(
"negative eigenvalues detected, please make sure the affinity matrix is positive definite"
)
return eigen_vector, eigen_value
def nystrom_ncut(
features,
features_B=None,
num_eig=100,
num_sample=10000,
knn=10,
sample_method="farthest",
distance="cosine",
affinity_focal_gamma=1.0,
indirect_connection=False,
indirect_pca_dim=100,
device=None,
eig_solver="svd_lowrank",
normalize_features=False,
matmul_chunk_size=8096,
make_orthogonal=False,
verbose=False,
no_propagation=False,
make_symmetric=False,
n_features=1,
):
"""PyTorch implementation of Faster Nystrom Normalized cut.
Args:
features (torch.Tensor): feature matrix, shape (n_samples, n_features)
features_2 (torch.Tensor): feature matrix 2, for asymmetric affinity matrix, shape (n_samples2, n_features)
num_eig (int): default 20, number of top eigenvectors to return
num_sample (int): default 30000, number of samples for Nystrom-like approximation
knn (int): default 3, number of KNN for propagating eigenvectors from subgraph to full graph,
smaller knn will result in more sharp eigenvectors,
sample_method (str): sample method, 'farthest' (default) or 'random'
'farthest' is recommended for better approximation
distance (str): distance metric, 'cosine' (default) or 'euclidean'
affinity_focal_gamma (float): affinity matrix parameter, lower t reduce the weak edge weights,
resulting in more sharp eigenvectors, default 1.0
indirect_connection (bool): include indirect connection in the subgraph, default True
indirect_pca_dim (int): default 100, PCA dimension to reduce the node dimension, only applied to
the not sampled nodes, not applied to the sampled nodes
device (str): device to use for computation, if None, will not change device
a good practice is to pass features by CPU since it's usually large,
and move subgraph affinity to GPU to speed up eigenvector computation
eig_solver (str): eigen decompose solver, 'svd_lowrank' (default), 'lobpcg', 'svd', 'eigh'
'svd_lowrank' is recommended for large scale graph, it's the fastest
they correspond to torch.svd_lowrank, torch.lobpcg, torch.svd, torch.linalg.eigh
normalize_features (bool): normalize input features before computing affinity matrix,
default True
matmul_chunk_size (int): chunk size for matrix multiplication
large matrix multiplication is chunked to reduce memory usage,
smaller chunk size will reduce memory usage but slower computation, default 8096
make_orthogonal (bool): make eigenvectors orthogonal after propagation, default True
verbose (bool): show progress bar when propagating eigenvectors from subgraph to full graph
no_propagation (bool): if True, skip the eigenvector propagation step, only return the subgraph eigenvectors
Returns:
(torch.Tensor): eigenvectors, shape (n_samples, num_eig)
(torch.Tensor): eigenvalues, sorted in descending order, shape (num_eig,)
(torch.Tensor): sampled_indices used by Nystrom-like approximation subgraph, shape (num_sample,)
"""
# check if features dimension greater than num_eig
if eig_solver in ["svd_lowrank", "lobpcg"]:
assert features.shape[0] > (
num_eig * 2
), "number of nodes should be greater than 2*num_eig"
if eig_solver in ["svd", "eigh"]:
assert (
features.shape[0] > num_eig
), "number of nodes should be greater than num_eig"
features = features.clone()
if normalize_features:
# features need to be normalized for affinity matrix computation (cosine distance)
features = torch.nn.functional.normalize(features, dim=-1)
sampled_indices = run_subgraph_sampling(
features,
num_sample=num_sample,
sample_method=sample_method,
)
sampled_indices_B = run_subgraph_sampling(
features_B,
num_sample=num_sample,
sample_method=sample_method,
)
sampled_features = features[sampled_indices]
sampled_features_B = features_B[sampled_indices_B]
# move subgraph gpu to speed up
original_device = sampled_features.device
device = original_device if device is None else device
sampled_features = sampled_features.to(device)
sampled_features_B = sampled_features_B.to(device)
# compute affinity matrix on subgraph
A = affinity_from_features(
sampled_features, features_B=sampled_features_B,
affinity_focal_gamma=affinity_focal_gamma, distance=distance,
n_features=n_features,
)
not_sampled = torch.tensor(
list(set(range(features.shape[0])) - set(sampled_indices))
)
if len(not_sampled) == 0:
# if sampled all nodes, no need for nyström approximation
eigen_vector, eigen_value = ncut(A, num_eig, eig_solver=eig_solver)
return eigen_vector, eigen_value, sampled_indices
# 1) PCA to reduce the node dimension for the not sampled nodes
# 2) compute indirect connection on the PC nodes
if len(not_sampled) > 0 and indirect_connection:
raise NotImplementedError("indirect_connection is not implemented yet")
indirect_pca_dim = min(indirect_pca_dim, min(*features.shape))
U, S, V = torch.pca_lowrank(features[not_sampled].T, q=indirect_pca_dim)
feature_B = (features[not_sampled].T @ V).T # project to PCA space
feature_B = feature_B.to(device)
B = affinity_from_features(
sampled_features,
feature_B,
affinity_focal_gamma=affinity_focal_gamma,
distance=distance,
fill_diagonal=False,
)
# P is 1-hop random walk matrix
B_row = B / B.sum(axis=1, keepdim=True)
B_col = B / B.sum(axis=0, keepdim=True)
P = B_row @ B_col.T
P = (P + P.T) / 2
# fill diagonal with 0
P[torch.arange(P.shape[0]), torch.arange(P.shape[0])] = 0
A = A + P
# compute normalized cut on the subgraph
eigen_vector, eigen_value = ncut(A, num_eig, eig_solver=eig_solver, make_symmetric=make_symmetric)
eigen_vector = eigen_vector.to(dtype=features.dtype, device=original_device)
eigen_value = eigen_value.to(dtype=features.dtype, device=original_device)
if no_propagation:
return eigen_vector, eigen_value, sampled_indices
# propagate eigenvectors from subgraph to full graph
eigen_vector = propagate_knn(
eigen_vector,
features,
sampled_features,
knn,
chunk_size=matmul_chunk_size,
device=device,
use_tqdm=verbose,
)
# post-hoc orthogonalization
if make_orthogonal:
eigen_vector = gram_schmidt(eigen_vector)
return eigen_vector, eigen_value, sampled_indices