torch_concepts.nn.MixCUC¶

class MixCUC(in_features_endogenous: int, in_features_exogenous: int, out_features: int, in_activation: ~typing.Callable = <built-in method sigmoid of type object>, cardinalities: ~typing.List[int] | None = None)[source]¶

Concept exogenous predictor with mixture of concept activations and exogenous features.

This predictor implements the Concept Embedding Model (CEM) task predictor that combines concept activations with learned exogenous using a mixture operation.

Main reference: “Concept Embedding Models: Beyond the Accuracy-Explainability Trade-Off” (Espinosa Zarlenga et al., NeurIPS 2022).

in_features_endogenous¶

Number of input concept endogenous.

Type:: int

in_features_exogenous¶

Number of exogenous features.

Type:: int

out_features¶

Number of output features.

Type:: int

cardinalities¶

Cardinalities for grouped concepts.

Type:: List[int]

predictor¶

Linear predictor module.

Type:: nn.Module

Parameters:

in_features_endogenous – Number of input concept endogenous.
in_features_exogenous – Number of exogenous features (must be even).
out_features – Number of output task features.
in_activation – Activation function for concept endogenous (default: sigmoid).
cardinalities – List of concept group cardinalities (optional).

Example

>>> import torch
>>> from torch_concepts.nn import MixCUC
>>>
>>> # Create predictor with 10 concepts, 20 exogenous dims, 3 tasks
>>> predictor = MixCUC(
...     in_features_endogenous=10,
...     in_features_exogenous=10,  # Must be half of exogenous latent size when no cardinalities are provided
...     out_features=3,
...     in_activation=torch.sigmoid
... )
>>>
>>> # Generate random inputs
>>> concept_endogenous = torch.randn(4, 10)  # batch_size=4, n_concepts=10
>>> exogenous = torch.randn(4, 10, 20)  # (batch, n_concepts, emb_size)
>>>
>>> # Forward pass
>>> task_endogenous = predictor(endogenous=concept_endogenous, exogenous=exogenous)
>>> print(task_endogenous.shape)  # torch.Size([4, 3])
>>>
>>> # With concept groups (e.g., color has 3 values, shape has 4, etc.)
>>> predictor_grouped = MixCUC(
...     in_features_endogenous=10,
...     in_features_exogenous=20, # Must be equal to exogenous latent size when cardinalities are provided
...     out_features=3,
...     cardinalities=[3, 4, 3]  # 3 groups summing to 10
... )
>>>
>>> # Forward pass with grouped concepts
>>> task_endogenous = predictor_grouped(endogenous=concept_endogenous, exogenous=exogenous)
>>> print(task_endogenous.shape)  # torch.Size([4, 3])

References

Espinosa Zarlenga et al. “Concept Embedding Models: Beyond the Accuracy-Explainability Trade-Off”, NeurIPS 2022. https://arxiv.org/abs/2209.09056

__init__(in_features_endogenous: int, in_features_exogenous: int, out_features: int, in_activation: ~typing.Callable = <built-in method sigmoid of type object>, cardinalities: ~typing.List[int] | None = None)[source]¶

Methods

`__init__`(in_features_endogenous, ...[, ...])
`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.
`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`(endogenous, exogenous)	Forward pass through the predictor.
`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.
`prune`(mask)	Prune the predictor by removing connections based on the given mask.
`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.
`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`
`call_super_init`
`dump_patches`
`training`