54 lines
2.0 KiB
Python
54 lines
2.0 KiB
Python
import numpy as np
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from tqdm import trange
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from tinygrad.tensor import Tensor
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from tinygrad.helpers import CI
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def train(model, X_train, Y_train, optim, steps, BS=128, lossfn=lambda out,y: out.sparse_categorical_crossentropy(y),
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transform=lambda x: x, target_transform=lambda x: x, noloss=False):
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with Tensor.train():
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losses, accuracies = [], []
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for i in (t := trange(steps, disable=CI)):
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samp = np.random.randint(0, X_train.shape[0], size=(BS))
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x = Tensor(transform(X_train[samp]), requires_grad=False)
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y = Tensor(target_transform(Y_train[samp]))
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# network
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out = model.forward(x) if hasattr(model, 'forward') else model(x)
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loss = lossfn(out, y)
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optim.zero_grad()
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loss.backward()
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if noloss: del loss
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optim.step()
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# printing
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if not noloss:
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cat = out.argmax(axis=-1)
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accuracy = (cat == y).mean().numpy()
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loss = loss.detach().numpy()
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losses.append(loss)
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accuracies.append(accuracy)
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t.set_description("loss %.2f accuracy %.2f" % (loss, accuracy))
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return [losses, accuracies]
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def evaluate(model, X_test, Y_test, num_classes=None, BS=128, return_predict=False, transform=lambda x: x,
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target_transform=lambda y: y):
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Tensor.training = False
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def numpy_eval(Y_test, num_classes):
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Y_test_preds_out = np.zeros(list(Y_test.shape)+[num_classes])
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for i in trange((len(Y_test)-1)//BS+1, disable=CI):
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x = Tensor(transform(X_test[i*BS:(i+1)*BS]))
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out = model.forward(x) if hasattr(model, 'forward') else model(x)
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Y_test_preds_out[i*BS:(i+1)*BS] = out.numpy()
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Y_test_preds = np.argmax(Y_test_preds_out, axis=-1)
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Y_test = target_transform(Y_test)
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return (Y_test == Y_test_preds).mean(), Y_test_preds
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if num_classes is None: num_classes = Y_test.max().astype(int)+1
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acc, Y_test_pred = numpy_eval(Y_test, num_classes)
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print("test set accuracy is %f" % acc)
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return (acc, Y_test_pred) if return_predict else acc
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