PEFT documentation

Polytropon

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Polytropon

Polytropon is a multitask model with a number of different LoRA adapters in it’s “inventory”. The model learns the correct combination of adapters from the inventory with a routing function to choose the best subset of modules for a specific task. PEFT also supports Multi-Head Adapter Routing (MHR) for Polytropon which builds on and improves the routing function by combining the adapter heads more granularly. The adapter heads are separated into disjoint blocks and a different routing function is learned for each one, allowing for more expressivity.

Combining Modular Skills in Multitask Learning
Multi-Head Adapter Routing for Cross-Task Generalization

The abstract from the paper is:

A modular design encourages neural models to disentangle and recombine different facets of knowledge to generalise more systematically to new tasks. In this work, we assume that each task is associated with a subset of latent discrete skills from a (potentially small) inventory. In turn, skills correspond to parameter-efficient (sparse / low-rank) model parameterisations. By jointly learning these and a task-skill allocation matrix, the network for each task is instantiated as the average of the parameters of active skills. To favour non-trivial soft partitions of skills across tasks, we experiment with a series of inductive biases, such as an Indian Buffet Process prior and a two-speed learning rate. We evaluate our latent-skill model on two main settings: 1) multitask reinforcement learning for grounded instruction following on 8 levels of the BabyAI platform; and 2) few-shot adaptation of pre-trained text-to-text generative models on CrossFit, a benchmark comprising 160 NLP tasks. We find that the modular design of a network significantly increases sample efficiency in reinforcement learning and few-shot generalisation in supervised learning, compared to baselines with fully shared, task-specific, or conditionally generated parameters where knowledge is entangled across tasks. In addition, we show how discrete skills help interpretability, as they yield an explicit hierarchy of tasks.

PolyConfig

class peft.PolyConfig

< >

( peft_type: Union = None auto_mapping: Optional = None base_model_name_or_path: Optional = None revision: Optional = None task_type: Union = None inference_mode: bool = False r: int = 8 target_modules: Union = None modules_to_save: Optional = None init_weights: bool = True poly_type: Literal = 'poly' n_tasks: int = 1 n_skills: int = 4 n_splits: int = 1 )

Parameters

  • r (int) — Attention dimension of each Lora in Poly.
  • target_modules (Union[List[str],str]) — The names of the modules to apply Poly to.
  • modules_to_save (List[str]) — List of modules apart from Poly layers to be set as trainable and saved in the final checkpoint.
  • init_weights (bool) — Whether to perform initialization of Poly weights.
  • poly_type (Literal["poly"]) — The variant of the Poly module to use. Currently, only “poly” is supported.
  • n_tasks (int) — The number of tasks in a multitasking scenario.
  • n_skills (int) — The number of skills (LoRA) in each Poly layer.
  • n_splits (int) — The number of splits within each LoRA of a Poly layer. A value greater than 1 indicates the use of Multi-Head Routing (MHR).

This is the configuration class to store the configuration of a PolyModel.

PolyModel

class peft.PolyModel

< >

( model config adapter_name )