Source code for sparseml.pytorch.optim.sensitivity_pruning

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Sensitivity analysis implementations for kernel sparsity on Modules against loss funcs.

from typing import Any, Callable, List, Tuple, Union

import torch
from torch import Tensor
from torch.nn import Module
from import DataLoader

from sparseml.optim import (
from sparseml.pytorch.optim.mask_creator_pruning import UnstructuredPruningMaskCreator
from sparseml.pytorch.optim.mask_pruning import ModuleParamPruningMask
from sparseml.pytorch.utils import (

__all__ = [

[docs]def model_prunability_magnitude(module: Module): """ Calculate the approximate sensitivity for an overall model. Range of the values are not scaled to anything, so must be taken in context with other known models. :param module: the model to calculate the sensitivity for :return: the approximated sensitivity """ prunable = get_prunable_layers(module) tensors = [] for (name, layer) in prunable: weight = getattr(layer, "weight") values = weight.view(-1).abs() tensors.append(values) all_weights = avg = all_weights.mean().item() return avg
[docs]def pruning_loss_sens_magnitude( module: Module, sparsity_levels: Union[ List[float], Tuple[float, ...] ] = default_pruning_sparsities_loss(True), ) -> PruningLossSensitivityAnalysis: """ Approximated kernel sparsity (pruning) loss analysis for a given model. Returns the results for each prunable param (conv, linear) in the model. :param module: the model to calculate the sparse sensitivity analysis for :param sparsity_levels: the sparsity levels to calculate the loss for for each param :return: the analysis results for the model """ prunable = get_prunable_layers(module) analysis = PruningLossSensitivityAnalysis() for index, (name, layer) in enumerate(prunable): weight = getattr(layer, "weight") name = "{}.weight".format(name) values, _ = weight.view(-1).abs().sort() prev_index = 0 for sparsity in sparsity_levels: val_index = round(sparsity * len(values)) if val_index >= len(values): val_index = len(values) - 1 if sparsity <= 1e-9: baseline = True sparsity = 0.0 sparse_avg = 0.0 else: baseline = False if val_index > prev_index: sparse_avg = values[prev_index:val_index].mean().item() prev_index = val_index else: sparse_avg = values[val_index].item() prev_index = val_index + 1 analysis.add_result(None, name, index, sparsity, sparse_avg, baseline) return analysis
def _sensitivity_callback( prunable_layers: List[Tuple[str, Module]], sparsity_levels: List[int], steps_per_measurement: int, analysis: PruningLossSensitivityAnalysis, loss_key: str, ) -> Callable: measurement_steps = 0 layer_index = -1 sparsity_index = -1 current_mask = None def complete_measurement(): """ Uses complete_measurement to handle when all of the required steps have been taken for a given layer and sparsity level. This handles incrementing to the next sparsity level. If all sparsity levels are complete, increments to the next layer and starts from the initial sparsity level. Should only be invoked when all measurements have been taken. """ nonlocal measurement_steps nonlocal layer_index nonlocal sparsity_index nonlocal current_mask measurement_steps = 0 sparsity_index += 1 if 0 <= sparsity_index < len(sparsity_levels) and 0 <= layer_index < len( prunable_layers ): # increment sparsity level for current layer current_mask.set_param_masks_from_sparsity(sparsity_levels[sparsity_index]) else: # go to next layer sparsity_index = 0 layer_index += 1 if current_mask: current_mask.enabled = False current_mask.reset() del current_mask current_mask = None if layer_index < len(prunable_layers): current_mask = ModuleParamPruningMask( [prunable_layers[layer_index][1]], store_init=True, mask_creator=UnstructuredPruningMaskCreator(), ) current_mask.enabled = True if sparsity_levels[sparsity_index] > 0.0: current_mask.set_param_masks_from_sparsity( sparsity_levels[sparsity_index] ) complete_measurement() def batch_end( epoch: int, step: int, batch_size: int, data: Any, pred: Any, losses: Any, ): nonlocal measurement_steps measurement_steps += 1 if layer_index < len(prunable_layers): analysis.add_result( None, "{}.weight".format(prunable_layers[layer_index][0]), sparsity_index, sparsity_levels[sparsity_index], losses[loss_key].item(), baseline=sparsity_levels[sparsity_index] < 1e-9, ) if measurement_steps >= steps_per_measurement: complete_measurement() return batch_end
[docs]def pruning_loss_sens_one_shot( module: Module, data: DataLoader, loss: Union[LossWrapper, Callable[[Any, Any], Tensor]], device: str, steps_per_measurement: int, sparsity_levels: List[int] = default_pruning_sparsities_loss(False), loss_key: str = DEFAULT_LOSS_KEY, tester_run_funcs: ModuleRunFuncs = None, tester_loggers: List[BaseLogger] = None, show_progress: bool = True, ) -> PruningLossSensitivityAnalysis: """ Run a one shot sensitivity analysis for kernel sparsity. It does not retrain, and instead puts the model to eval mode. Moves layer by layer to calculate the sensitivity analysis for each and resets the previously run layers. Note, by default it caches the data. This means it is not parallel for data loading and the first run can take longer. Subsequent sparsity checks for layers and levels will be much faster. :param module: the module to run the kernel sparsity sensitivity analysis over will extract all prunable layers out :param data: the data to run through the module for calculating the sensitivity analysis :param loss: the loss function to use for the sensitivity analysis :param device: the device to run the analysis on; ex: cpu, cuda :param steps_per_measurement: the number of samples or items to take for each measurement at each sparsity lev :param sparsity_levels: the sparsity levels to check for each layer to calculate sensitivity :param loss_key: the key for the loss function to track in the returned dict :param tester_run_funcs: override functions to use in the ModuleTester that runs :param tester_loggers: loggers to log data to while running the analysis :param show_progress: track progress of the runs if True :return: the sensitivity results for every layer that is prunable """ analysis = PruningLossSensitivityAnalysis() tester = ModuleTester( module, device, loss, loggers=tester_loggers, log_summary=False, log_steps=max(1, round(steps_per_measurement / 10)), ) layers = get_prunable_layers(module) batch_end = _sensitivity_callback( layers, sparsity_levels, steps_per_measurement, analysis, loss_key ) batch_end_hook = tester.run_hooks.register_batch_end_hook(batch_end) if tester_run_funcs is not None: tester.run_funcs.copy(tester_run_funcs) data_loader = infinite_data_loader( data, early_stop_steps=steps_per_measurement, cache=True ) data_loader, desc="KS Analysis", show_progress=show_progress, track_results=False, max_steps=steps_per_measurement * len(sparsity_levels) * len(layers), ) batch_end_hook.remove() return analysis