# -*- coding: utf-8 -*- # Owner(s): ["module: unknown"] import itertools import logging import re import torch from torch import nn from torch.ao.sparsity import BaseSparsifier, WeightNormSparsifier, FakeSparsity, NearlyDiagonalSparsifier from torch.nn.utils.parametrize import is_parametrized from torch.testing._internal.common_utils import TestCase logging.basicConfig(format='%(asctime)s - %(name)s - %(levelname)s - %(message)s', level=logging.INFO) class Model(nn.Module): def __init__(self): super().__init__() self.seq = nn.Sequential( nn.Linear(16, 16) ) self.linear = nn.Linear(16, 16) self.head = nn.Linear(16, 4) def forward(self, x): x = self.seq(x) x = self.linear(x) x = self.head(x) return x class ImplementedSparsifier(BaseSparsifier): def __init__(self, **kwargs): super().__init__(defaults=kwargs) def update_mask(self, module, **kwargs): module.parametrizations.weight[0].mask[0] = 0 linear_state = self.state['linear.weight'] linear_state['step_count'] = linear_state.get('step_count', 0) + 1 class TestBaseSparsifier(TestCase): def test_constructor(self): # Cannot instantiate the abstract base self.assertRaises(TypeError, BaseSparsifier) # Can instantiate the model with no configs model = Model() sparsifier = ImplementedSparsifier(test=3) sparsifier.prepare(model, config=None) assert len(sparsifier.groups) == 3 sparsifier.step() # Can instantiate the model with configs sparsifier = ImplementedSparsifier(test=3) sparsifier.prepare(model, [{'tensor_fqn': 'linear.weight'}]) assert len(sparsifier.groups) == 1 assert sparsifier.groups[0]['tensor_fqn'] == 'linear.weight' assert 'test' in sparsifier.groups[0] assert sparsifier.groups[0]['test'] == 3 def test_prepare_config(self): model = Model() sparsifier = ImplementedSparsifier(test=3) # Make sure there are no parametrizations before `prepare` assert not hasattr(model.seq[0], 'parametrizations') assert not hasattr(model.linear, 'parametrizations') assert not hasattr(model.head, 'parametrizations') sparsifier.prepare(model, config=[ {'tensor_fqn': 'seq.0.weight', 'test': 42}, # No 'linear' to make sure it will be skipped in the sparsification {'tensor_fqn': 'head.weight'} ]) assert len(sparsifier.groups) == 2 # Check if default argument is not assigned if explicit assert sparsifier.groups[0]['tensor_fqn'] == 'seq.0.weight' assert sparsifier.groups[0]['test'] == 42 # Check if FQN and module are pointing to the same location assert sparsifier.groups[1]['tensor_fqn'] == 'head.weight' assert sparsifier.groups[1]['module'] == model.head # Check if parameterizations are attached assert hasattr(model.seq[0], 'parametrizations') assert not hasattr(model.linear, 'parametrizations') assert hasattr(model.head, 'parametrizations') def test_step(self): model = Model() sparsifier = ImplementedSparsifier(test=3) sparsifier.enable_mask_update = True sparsifier.prepare(model, [{'tensor_fqn': 'linear.weight'}]) sparsifier.step() assert torch.all(model.linear.parametrizations.weight[0].mask[0] == 0) def test_state_dict(self): step_count = 3 model0 = Model() sparsifier0 = ImplementedSparsifier(test=3) sparsifier0.prepare(model0, [{'tensor_fqn': 'linear.weight'}]) mask = model0.linear.parametrizations['weight'][0].mask mask.data = torch.arange(mask.shape[0] * mask.shape[1]).reshape(mask.shape) for step in range(step_count): sparsifier0.step() state_dict = sparsifier0.state_dict() # Check the expected keys in the state_dict assert 'state' in state_dict assert 'step_count' in state_dict['state']['linear.weight'] assert state_dict['state']['linear.weight']['step_count'] == 3 assert 'groups' in state_dict assert 'test' in state_dict['groups'][0] assert 'tensor_fqn' in state_dict['groups'][0] assert state_dict['groups'][0]['tensor_fqn'] == 'linear.weight' # Check loading static_dict creates an equivalent model model1 = Model() sparsifier1 = ImplementedSparsifier() sparsifier1.prepare(model1, None) assert sparsifier0.state != sparsifier1.state # Make sure the masks are different in the beginning for mg in sparsifier0.groups: if mg['tensor_fqn'] == 'linear.weight': mask0 = mg['module'].parametrizations.weight[0].mask for mg in sparsifier1.groups: if mg['tensor_fqn'] == 'linear.weight': mask1 = mg['module'].parametrizations.weight[0].mask self.assertNotEqual(mask0, mask1) sparsifier1.load_state_dict(state_dict) # Make sure the states are loaded, and are correct assert sparsifier0.state == sparsifier1.state # Make sure the masks (and all dicts) are the same after loading assert len(sparsifier0.groups) == len(sparsifier1.groups) for idx in range(len(sparsifier0.groups)): mg0 = sparsifier0.groups[idx] mg1 = sparsifier1.groups[idx] for key in mg0.keys(): assert key in mg1 if key == 'module': # We cannot compare modules as they are different param0 = mg0[key].parametrizations.weight[0] param1 = mg1[key].parametrizations.weight[0] assert hasattr(param0, 'mask') assert hasattr(param1, 'mask') self.assertEqual(param0.__dict__, param1.__dict__) else: assert mg0[key] == mg1[key] def test_mask_squash(self): model = Model() sparsifier = ImplementedSparsifier(test=3) sparsifier.prepare(model, [{'tensor_fqn': 'linear.weight'}]) assert hasattr(model.linear.parametrizations.weight[0], 'mask') assert is_parametrized(model.linear, 'weight') assert not is_parametrized(model.seq[0], 'weight') sparsifier.squash_mask() assert not is_parametrized(model.seq[0], 'weight') assert not is_parametrized(model.linear, 'weight') def test_mask_squash_with_params1(self): model = Model() sparsifier = ImplementedSparsifier(foo=3, bar=2, baz=1) sparsifier.prepare(model, [{'tensor_fqn': 'linear.weight'}, {'tensor_fqn': 'seq.0.weight'}]) sparsifier.squash_mask( params_to_keep_per_layer={ 'linear': ('foo', 'bar'), 'seq.0': ('baz',) }) assert not is_parametrized(model.seq[0], 'weight') assert not is_parametrized(model.linear, 'weight') assert hasattr(model.seq[0], 'sparse_params') assert hasattr(model.linear, 'sparse_params') assert model.seq[0].sparse_params.get('foo', None) is None assert model.seq[0].sparse_params.get('bar', None) is None assert model.seq[0].sparse_params.get('baz', None) == 1 assert model.linear.sparse_params.get('foo', None) == 3 assert model.linear.sparse_params.get('bar', None) == 2 assert model.linear.sparse_params.get('baz', None) is None def test_mask_squash_with_params2(self): model = Model() sparsifier = ImplementedSparsifier(foo=3, bar=2, baz=1) sparsifier.prepare(model, [{'tensor_fqn': 'linear.weight'}, {'tensor_fqn': 'seq.0.weight'}]) sparsifier.squash_mask(params_to_keep=('foo', 'bar')) assert not is_parametrized(model.seq[0], 'weight') assert not is_parametrized(model.linear, 'weight') assert hasattr(model.seq[0], 'sparse_params') assert hasattr(model.linear, 'sparse_params') assert model.seq[0].sparse_params.get('foo', None) == 3 assert model.seq[0].sparse_params.get('bar', None) == 2 assert model.seq[0].sparse_params.get('baz', None) is None assert model.linear.sparse_params.get('foo', None) == 3 assert model.linear.sparse_params.get('bar', None) == 2 assert model.linear.sparse_params.get('baz', None) is None def test_mask_squash_with_params3(self): model = Model() sparsifier = ImplementedSparsifier(foo=3, bar=2, baz=1) sparsifier.prepare(model, [{'tensor_fqn': 'linear.weight'}, {'tensor_fqn': 'seq.0.weight'}]) sparsifier.squash_mask( params_to_keep=('foo', 'bar'), params_to_keep_per_layer={'seq.0': ('baz',)}) assert not is_parametrized(model.seq[0], 'weight') assert not is_parametrized(model.linear, 'weight') assert hasattr(model.seq[0], 'sparse_params') assert hasattr(model.linear, 'sparse_params') assert model.seq[0].sparse_params.get('foo', None) == 3 assert model.seq[0].sparse_params.get('bar', None) == 2 assert model.seq[0].sparse_params.get('baz', None) == 1 assert model.linear.sparse_params.get('foo', None) == 3 assert model.linear.sparse_params.get('bar', None) == 2 assert model.linear.sparse_params.get('baz', None) is None class TestWeightNormSparsifier(TestCase): def test_constructor(self): model = Model() sparsifier = WeightNormSparsifier() sparsifier.prepare(model, config=None) for g in sparsifier.groups: assert isinstance(g['module'], nn.Linear) # The groups are unordered assert g['module_fqn'] in ('seq.0', 'linear', 'head') def test_step(self): model = Model() sparsifier = WeightNormSparsifier(sparsity_level=0.5) sparsifier.prepare(model, config=[{'tensor_fqn': 'linear.weight'}]) for g in sparsifier.groups: # Before step module = g['module'] assert (1.0 - module.parametrizations['weight'][0].mask.mean()) == 0 # checking sparsity level is 0 sparsifier.enable_mask_update = True sparsifier.step() self.assertAlmostEqual(model.linear.parametrizations['weight'][0].mask.mean().item(), 0.5, places=2) for g in sparsifier.groups: # After step module = g['module'] assert (1.0 - module.parametrizations['weight'][0].mask.mean()) > 0 # checking sparsity level has increased # Test if the mask collapses to all zeros if the weights are randomized iters_before_collapse = 1000 for _ in range(iters_before_collapse): model.linear.weight.data = torch.randn(model.linear.weight.shape) sparsifier.step() for g in sparsifier.groups: # After step module = g['module'] assert (1.0 - module.parametrizations['weight'][0].mask.mean()) > 0 # checking sparsity level did not collapse def test_step_2_of_4(self): model = Model() sparsifier = WeightNormSparsifier(sparsity_level=1.0, sparse_block_shape=(1, 4), zeros_per_block=2) sparsifier.prepare(model, config=[{'tensor_fqn': 'linear.weight'}]) sparsifier.step() # make sure the sparsity level is approximately 50% mask = model.linear.parametrizations['weight'][0].mask.to(torch.float) # mean works on float only self.assertAlmostEqual(mask.mean().item(), 0.5, places=2) # Make sure each block has exactly 50% zeros module = sparsifier.groups[0]['module'] mask = module.parametrizations['weight'][0].mask for row in mask: for idx in range(0, len(row), 4): block = row[idx:idx + 4] block, _ = block.sort() assert (block[:2] == 0).all() assert (block[2:] != 0).all() def test_prepare(self): model = Model() sparsifier = WeightNormSparsifier() sparsifier.prepare(model, config=None) for g in sparsifier.groups: module = g['module'] # Check mask exists assert hasattr(module.parametrizations['weight'][0], 'mask') # Check parametrization exists and is correct assert is_parametrized(module, 'weight') assert type(module.parametrizations.weight[0]) == FakeSparsity def test_mask_squash(self): model = Model() sparsifier = WeightNormSparsifier() sparsifier.prepare(model, config=None) sparsifier.squash_mask() for g in sparsifier.groups: module = g['module'] assert not is_parametrized(module, 'weight') assert not hasattr(module, 'mask') def test_sparsity_levels(self): sparsity_levels = [-1.0, 0.0, 0.5, 1.0, 2.0] sparse_block_shapes = [(1, 1), (1, 4), (2, 2), (4, 1)] zeros_per_blocks = [0, 1, 2, 3, 4] testcases = itertools.tee(itertools.product(sparsity_levels, sparse_block_shapes, zeros_per_blocks)) # Create a config and model with all the testcases model = nn.Sequential() sparsifier = WeightNormSparsifier() sparsity_per_layer_config = [] p = re.compile(r'[-\.\s]') for sl, sbs, zpb in testcases[0]: # Make sure the number of zeros is not > values in a block if zpb > sbs[0] * sbs[1]: continue layer_name = f'{sl}_{sbs}_{zpb}' layer_name = p.sub('_', layer_name) layer = nn.Linear(12, 12, bias=False) layer.weight = nn.Parameter(torch.ones(12, 12)) model.add_module(layer_name, layer) config = { 'tensor_fqn': layer_name + ".weight", 'sparsity_level': sl, 'sparse_block_shape': sbs, 'zeros_per_block': zpb } sparsity_per_layer_config.append(config) sparsifier.prepare(model, sparsity_per_layer_config) sparsifier.step() sparsifier.squash_mask() model.eval() for sl, sbs, zpb in testcases[1]: if zpb > sbs[0] * sbs[1]: continue layer_name = f'{sl}_{sbs}_{zpb}' layer_name = p.sub('_', layer_name) layer = getattr(model, layer_name) # Level of sparsity is achieved sparse_mask = (layer.weight == 0).float() if zpb == 0: assert sparse_mask.mean() == 0 else: # Ratio of individual zeros in the tensor true_sl = min(max(sl, 0.0), 1.0) true_sl = true_sl * zpb / sbs[0] / sbs[1] assert sparse_mask.mean() == true_sl class TestNearlyDiagonalSparsifier(TestCase): def test_constructor(self): model = Model() sparsifier = NearlyDiagonalSparsifier(nearliness=1) sparsifier.prepare(model, config=None) for g in sparsifier.groups: assert isinstance(g['module'], nn.Linear) # The groups are unordered assert g['module_fqn'] in ('seq.0', 'linear', 'head') def test_step(self): model = Model() sparsifier = NearlyDiagonalSparsifier(nearliness=1) sparsifier.prepare(model, config=[{'tensor_fqn': 'linear.weight'}]) for g in sparsifier.groups: # Before step module = g['module'] assert (1.0 - module.parametrizations['weight'][0].mask.mean()) == 0 # checking sparsity level is 0 sparsifier.enable_mask_update = True sparsifier.step() mask = module.parametrizations['weight'][0].mask height, width = mask.shape assert torch.all(mask == torch.eye(height, width)) for g in sparsifier.groups: # After step module = g['module'] assert (1.0 - module.parametrizations['weight'][0].mask.mean()) > 0 # checking sparsity level has increased # Test if the mask collapses to all zeros if the weights are randomized iters_before_collapse = 1000 for _ in range(iters_before_collapse): model.linear.weight.data = torch.randn(model.linear.weight.shape) sparsifier.step() for g in sparsifier.groups: # After step module = g['module'] assert (1.0 - module.parametrizations['weight'][0].mask.mean()) > 0 # checking sparsity level did not collapse def test_prepare(self): model = Model() sparsifier = NearlyDiagonalSparsifier(nearliness=1) sparsifier.prepare(model, config=None) for g in sparsifier.groups: module = g['module'] # Check mask exists assert hasattr(module.parametrizations['weight'][0], 'mask') # Check parametrization exists and is correct assert is_parametrized(module, 'weight') assert type(module.parametrizations.weight[0]) == FakeSparsity def test_mask_squash(self): model = Model() sparsifier = NearlyDiagonalSparsifier(nearliness=1) sparsifier.prepare(model, config=None) sparsifier.step() sparsifier.squash_mask() for g in sparsifier.groups: module = g['module'] assert not is_parametrized(module, 'weight') assert not hasattr(module, 'mask') weights = module.weight height, width = weights.shape assert torch.all(weights == torch.eye(height, width) * weights) # only diagonal to be present def test_sparsity_levels(self): nearliness_levels = list(nearliness for nearliness in range(-1, 100)) model = nn.Sequential() p = re.compile(r'[-\.\s]') for nearliness in nearliness_levels: sparsifier = NearlyDiagonalSparsifier(nearliness=1) layer_name = f'{nearliness}' layer_name = p.sub('_', layer_name) layer = nn.Linear(32, 32, bias=False) layer.weight = nn.Parameter(torch.ones(32, 32)) width, height = layer.weight.shape model.add_module(layer_name, layer) config = { 'tensor_fqn': layer_name + ".weight", 'nearliness': nearliness } sparsifier.prepare(model, [config]) # should raise a ValueError when nearliness arg is illegal if (nearliness > 0 and nearliness % 2 == 0) or (nearliness // 2 >= min(width, height)): with self.assertRaises(ValueError): sparsifier.step() else: sparsifier.step() sparsifier.squash_mask() model.eval() layer = getattr(model, layer_name) # verify that mask created corresponds to the nearliness self._verify_nearliness(layer.weight, nearliness) # helper function to verify nearliness of a mask def _verify_nearliness(self, mask: torch.Tensor, nearliness: int): if nearliness <= 0: assert torch.all(mask == torch.zeros(mask.shape[0], mask.shape[1])) else: height, width = mask.shape dist_to_diagonal = nearliness // 2 for row in range(0, height): for col in range(0, width): if abs(row - col) <= dist_to_diagonal: assert mask[row, col] == 1 else: assert mask[row, col] == 0