pyagc.clusters.DinkClusterHead

class DinkClusterHead(n_clusters: int, n_features: int)[source]

Bases: BaseClusterHead

Neural Clustering Layer proposed in the “Dink-Net: Neural Clustering on Large Graphs” paper (Liu et al., ICML 2023).

This layer models cluster centers as learnable parameters and optimizes clustering assignments via cluster dilation and shrink losses:

\[\mathcal{L}_\text{dilation} = \frac{-1}{(K-1)K} \sum_{i=1}^{K} \sum_{j=1, j\neq i}^{K} \| \mathbf{C}_i - \mathbf{C}_j \|_2^2\]

\[\mathcal{L}_\text{shrink} = \frac{1}{BK} \sum_{i=1}^{B} \sum_{j=1}^{K} \| \mathbf{Z}_i - \mathbf{C}_j \|_2^2\]

where \(\mathbf{C}_i\) is the i-th cluster center, \(\mathbf{Z}_i\) is the i-th embedding in a batch, \(B\) is the batch size, and \(K\) is the number of clusters. The cluster dilation loss pushes cluster centers away from each other to expand the clustering space, while the cluster shrink loss pulls node embeddings toward all cluster centers to avoid confirmation bias.

Parameters:

n_clusters (int) – Number of clusters.
n_features (int) – Feature dimension of the input.

__init__(n_clusters: int, n_features: int)[source]: Initialize internal Module state, shared by both nn.Module and ScriptModule.

Methods

`__init__`(n_clusters, n_features)	Initialize internal Module state, shared by both nn.Module and ScriptModule.
`add_module`(name, module)	Add a child module to the current module.
`apply`(fn)	Apply `fn` recursively to every submodule (as returned by `.children()`) as well as self.
`bfloat16`()	Casts all floating point parameters and buffers to `bfloat16` datatype.
`buffers`([recurse])	Return an iterator over module buffers.
`children`()	Return an iterator over immediate children modules.
`cluster`(z[, soft])	Predicts cluster assignments.
`compile`(args, *kwargs)	Compile this Module's forward using `torch.compile()`.
`cpu`()	Move all model parameters and buffers to the CPU.
`cuda`([device])	Move all model parameters and buffers to the GPU.
`double`()	Casts all floating point parameters and buffers to `double` datatype.
`eval`()	Set the module in evaluation mode.
`extra_repr`()	Return the extra representation of the module.
`float`()	Casts all floating point parameters and buffers to `float` datatype.
`forward`(z)	Compute the clustering loss.
`get_buffer`(target)	Return the buffer given by `target` if it exists, otherwise throw an error.
`get_extra_state`()	Return any extra state to include in the module's state_dict.
`get_parameter`(target)	Return the parameter given by `target` if it exists, otherwise throw an error.
`get_submodule`(target)	Return the submodule given by `target` if it exists, otherwise throw an error.
`half`()	Casts all floating point parameters and buffers to `half` datatype.
`ipu`([device])	Move all model parameters and buffers to the IPU.
`load_state_dict`(state_dict[, strict, assign])	Copy parameters and buffers from `state_dict` into this module and its descendants.
`modules`()	Return an iterator over all modules in the network.
`mtia`([device])	Move all model parameters and buffers to the MTIA.
`named_buffers`([prefix, recurse, ...])	Return an iterator over module buffers, yielding both the name of the buffer as well as the buffer itself.
`named_children`()	Return an iterator over immediate children modules, yielding both the name of the module as well as the module itself.
`named_modules`([memo, prefix, remove_duplicate])	Return an iterator over all modules in the network, yielding both the name of the module as well as the module itself.
`named_parameters`([prefix, recurse, ...])	Return an iterator over module parameters, yielding both the name of the parameter as well as the parameter itself.
`parameters`([recurse])	Return an iterator over module parameters.
`register_backward_hook`(hook)	Register a backward hook on the module.
`register_buffer`(name, tensor[, persistent])	Add a buffer to the module.
`register_forward_hook`(hook, *[, prepend, ...])	Register a forward hook on the module.
`register_forward_pre_hook`(hook, *[, ...])	Register a forward pre-hook on the module.
`register_full_backward_hook`(hook[, prepend])	Register a backward hook on the module.
`register_full_backward_pre_hook`(hook[, prepend])	Register a backward pre-hook on the module.
`register_load_state_dict_post_hook`(hook)	Register a post-hook to be run after module's `load_state_dict()` is called.
`register_load_state_dict_pre_hook`(hook)	Register a pre-hook to be run before module's `load_state_dict()` is called.
`register_module`(name, module)	Alias for `add_module()`.
`register_parameter`(name, param)	Add a parameter to the module.
`register_state_dict_post_hook`(hook)	Register a post-hook for the `state_dict()` method.
`register_state_dict_pre_hook`(hook)	Register a pre-hook for the `state_dict()` method.
`requires_grad_`([requires_grad])	Change if autograd should record operations on parameters in this module.
`reset_cluster_centers`([cluster_centers])	Manually sets the cluster centers.
`set_extra_state`(state)	Set extra state contained in the loaded state_dict.
`set_submodule`(target, module[, strict])	Set the submodule given by `target` if it exists, otherwise throw an error.
`share_memory`()	See `torch.Tensor.share_memory_()`.
`state_dict`(*args[, destination, prefix, ...])	Return a dictionary containing references to the whole state of the module.
`to`(args, *kwargs)	Move and/or cast the parameters and buffers.
`to_empty`(*, device[, recurse])	Move the parameters and buffers to the specified device without copying storage.
`train`([mode])	Set the module in training mode.
`type`(dst_type)	Casts all parameters and buffers to `dst_type`.
`xpu`([device])	Move all model parameters and buffers to the XPU.
`zero_grad`([set_to_none])	Reset gradients of all model parameters.

Attributes

`T_destination`	alias of TypeVar('T_destination', bound=`dict`[`str`, `Any`])
`call_super_init`
`dump_patches`
`predict`	Alias for `cluster()`.

reset_cluster_centers(cluster_centers: Optional[Tensor] = None) → None[source]

Manually sets the cluster centers.

Parameters:: cluster_centers (torch.Tensor, optional) – Tensor of shape (n_clusters, n_features) to initialize the cluster centers. If None, use Xavier uniform initialization.
Return type:: None

forward(z: Tensor) → Tuple[Tensor, Tensor][source]

Compute the clustering loss.

Parameters:: z (torch.Tensor) – Input tensor of shape (n_samples, n_features).
Returns:: dilation_loss and shrink_loss
Return type:: Tuple[torch.Tensor, torch.Tensor]

cluster(z: Tensor, soft: bool = False) → Tensor[source]

Predicts cluster assignments.

Parameters:

z (torch.Tensor) – Input tensor of shape (n_samples, n_features).
soft (bool, optional) – If True, returns the soft assignment matrix; if False, returns hard cluster assignments. (default: False)

Returns:

Tensor –:

If soft is False, (n_samples,) tensor of cluster indices.
If soft is True, (n_samples, n_clusters) tensor of probabilities.