125 lines
4.1 KiB
Python
125 lines
4.1 KiB
Python
"""LVQ models that are optimized using non-gradient methods."""
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from ..core.losses import _get_dp_dm
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from ..nn.activations import get_activation
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from ..nn.wrappers import LambdaLayer
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from .abstract import NonGradientMixin
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from .glvq import GLVQ
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class LVQ1(NonGradientMixin, GLVQ):
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"""Learning Vector Quantization 1."""
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def training_step(self, train_batch, batch_idx, optimizer_idx=None):
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protos, plables = self.proto_layer()
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x, y = train_batch
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dis = self.compute_distances(x)
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# TODO Vectorized implementation
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for xi, yi in zip(x, y):
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d = self.compute_distances(xi.view(1, -1))
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preds = self.competition_layer(d, plabels)
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w = d.argmin(1)
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if yi == preds:
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shift = xi - protos[w]
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else:
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shift = protos[w] - xi
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updated_protos = protos + 0.0
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updated_protos[w] = protos[w] + (self.hparams.lr * shift)
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self.proto_layer.load_state_dict({"_components": updated_protos},
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strict=False)
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print(f"dis={dis}")
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print(f"y={y}")
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# Logging
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self.log_acc(dis, y, tag="train_acc")
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return None
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class LVQ21(NonGradientMixin, GLVQ):
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"""Learning Vector Quantization 2.1."""
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def training_step(self, train_batch, batch_idx, optimizer_idx=None):
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protos, plabels = self.proto_layer()
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x, y = train_batch
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dis = self.compute_distances(x)
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# TODO Vectorized implementation
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for xi, yi in zip(x, y):
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xi = xi.view(1, -1)
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yi = yi.view(1, )
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d = self.compute_distances(xi)
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(_, wp), (_, wn) = _get_dp_dm(d, yi, plabels, with_indices=True)
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shiftp = xi - protos[wp]
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shiftn = protos[wn] - xi
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updated_protos = protos + 0.0
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updated_protos[wp] = protos[wp] + (self.hparams.lr * shiftp)
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updated_protos[wn] = protos[wn] + (self.hparams.lr * shiftn)
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self.proto_layer.load_state_dict({"_components": updated_protos},
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strict=False)
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# Logging
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self.log_acc(dis, y, tag="train_acc")
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return None
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class MedianLVQ(NonGradientMixin, GLVQ):
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"""Median LVQ
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# TODO Avoid computing distances over and over
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"""
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def __init__(self, hparams, verbose=True, **kwargs):
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self.verbose = verbose
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super().__init__(hparams, **kwargs)
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self.transfer_layer = LambdaLayer(
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get_activation(self.hparams.transfer_fn))
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def _f(self, x, y, protos, plabels):
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d = self.distance_layer(x, protos)
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dp, dm = _get_dp_dm(d, y, plabels)
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mu = (dp - dm) / (dp + dm)
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invmu = -1.0 * mu
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f = self.transfer_layer(invmu, beta=self.hparams.transfer_beta) + 1.0
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return f
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def expectation(self, x, y, protos, plabels):
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f = self._f(x, y, protos, plabels)
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gamma = f / f.sum()
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return gamma
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def lower_bound(self, x, y, protos, plabels, gamma):
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f = self._f(x, y, protos, plabels)
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lower_bound = (gamma * f.log()).sum()
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return lower_bound
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def training_step(self, train_batch, batch_idx, optimizer_idx=None):
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protos, plabels = self.proto_layer()
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x, y = train_batch
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dis = self.compute_distances(x)
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for i, _ in enumerate(protos):
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# Expectation step
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gamma = self.expectation(x, y, protos, plabels)
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lower_bound = self.lower_bound(x, y, protos, plabels, gamma)
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# Maximization step
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_protos = protos + 0
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for k, xk in enumerate(x):
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_protos[i] = xk
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_lower_bound = self.lower_bound(x, y, _protos, plabels, gamma)
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if _lower_bound > lower_bound:
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if self.verbose:
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print(f"Updating prototype {i} to data {k}...")
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self.proto_layer.load_state_dict({"_components": _protos},
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strict=False)
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break
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# Logging
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self.log_acc(dis, y, tag="train_acc")
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return None
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