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@wiseodd
Last active March 31, 2022 19:59
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import numpy as np
from sklearn.datasets import make_moons
from sklearn.cross_validation import train_test_split
n_feature = 2
n_class = 2
def make_network(n_hidden=100):
model = dict(
W1=np.random.randn(n_feature, n_hidden),
W2=np.random.randn(n_hidden, n_class)
)
return model
def softmax(x):
e_x = np.exp(x - np.max(x))
return e_x / e_x.sum()
def forward(x, model):
# Input to hidden
h = x @ model['W1']
h[h < 0] = 0
# Hidden to output
prob = softmax(h @ model['W2'])
return h, prob
def backward(model, xs, hs, errs):
dW2 = hs.T @ errs
dh = errs @ model['W2'].T
dh[hs < 0] = 0
dW1 = xs.T @ dh
return dict(W1=dW1, W2=dW2)
def get_minibatch_grad(model, X_train, y_train):
xs, hs, errs = [], [], []
for x, cls_idx in zip(X_train, y_train):
h, y_pred = forward(x, model)
y_true = np.zeros(n_class)
y_true[int(cls_idx)] = 1.
err = y_true - y_pred
xs.append(x)
hs.append(h)
errs.append(err)
return backward(model, np.array(xs), np.array(hs), np.array(errs))
def get_minibatch(X, y, minibatch_size):
minibatches = []
X, y = shuffle(X, y)
for i in range(0, X.shape[0], minibatch_size):
X_mini = X[i:i + minibatch_size]
y_mini = y[i:i + minibatch_size]
minibatches.append((X_mini, y_mini))
return minibatches
def sgd(model, X_train, y_train, minibatch_size):
minibatches = get_minibatch(X_train, y_train, minibatch_size)
for iter in range(1, n_iter + 1):
idx = np.random.randint(0, len(minibatches))
X_mini, y_mini = minibatches[idx]
grad = get_minibatch_grad(model, X_mini, y_mini)
for layer in grad:
model[layer] += alpha * grad[layer]
return model
def momentum(model, X_train, y_train, minibatch_size):
velocity = {k: np.zeros_like(v) for k, v in model.items()}
gamma = .9
minibatches = get_minibatch(X_train, y_train, minibatch_size)
for iter in range(1, n_iter + 1):
idx = np.random.randint(0, len(minibatches))
X_mini, y_mini = minibatches[idx]
grad = get_minibatch_grad(model, X_mini, y_mini)
for layer in grad:
velocity[layer] = gamma * velocity[layer] + alpha * grad[layer]
model[layer] += velocity[layer]
return model
def nesterov(model, X_train, y_train, minibatch_size):
velocity = {k: np.zeros_like(v) for k, v in model.items()}
gamma = .9
minibatches = get_minibatch(X_train, y_train, minibatch_size)
for iter in range(1, n_iter + 1):
idx = np.random.randint(0, len(minibatches))
X_mini, y_mini = minibatches[idx]
model_ahead = {k: v + gamma * velocity[k] for k, v in model.items()}
grad = get_minibatch_grad(model, X_mini, y_mini)
for layer in grad:
velocity[layer] = gamma * velocity[layer] + alpha * grad[layer]
model[layer] += velocity[layer]
return model
def adagrad(model, X_train, y_train, minibatch_size):
cache = {k: np.zeros_like(v) for k, v in model.items()}
minibatches = get_minibatch(X_train, y_train, minibatch_size)
for iter in range(1, n_iter + 1):
idx = np.random.randint(0, len(minibatches))
X_mini, y_mini = minibatches[idx]
grad = get_minibatch_grad(model, X_mini, y_mini)
for k in grad:
cache[k] += grad[k]**2
model[k] += alpha * grad[k] / (np.sqrt(cache[k]) + eps)
return model
def rmsprop(model, X_train, y_train, minibatch_size):
cache = {k: np.zeros_like(v) for k, v in model.items()}
gamma = .9
minibatches = get_minibatch(X_train, y_train, minibatch_size)
for iter in range(1, n_iter + 1):
idx = np.random.randint(0, len(minibatches))
X_mini, y_mini = minibatches[idx]
grad = get_minibatch_grad(model, X_mini, y_mini)
for k in grad:
cache[k] = gamma * cache[k] + (1 - gamma) * (grad[k]**2)
model[k] += alpha * grad[k] / (np.sqrt(cache[k]) + eps)
return model
def adam(model, X_train, y_train, minibatch_size):
M = {k: np.zeros_like(v) for k, v in model.items()}
R = {k: np.zeros_like(v) for k, v in model.items()}
beta1 = .9
beta2 = .999
minibatches = get_minibatch(X_train, y_train, minibatch_size)
for iter in range(1, n_iter + 1):
t = iter
idx = np.random.randint(0, len(minibatches))
X_mini, y_mini = minibatches[idx]
grad = get_minibatch_grad(model, X_mini, y_mini)
for k in grad:
M[k] = beta1 * M[k] + (1. - beta1) * grad[k]
R[k] = beta2 * R[k] + (1. - beta2) * grad[k]**2
m_k_hat = M[k] / (1. - beta1**(t))
r_k_hat = R[k] / (1. - beta2**(t))
model[k] += alpha * m_k_hat / (np.sqrt(r_k_hat) + eps)
return model
def shuffle(X, y):
Z = np.column_stack((X, y))
np.random.shuffle(Z)
return Z[:, :-1], Z[:, -1]
if __name__ == '__main__':
X, y = make_moons(n_samples=5000, random_state=42, noise=0.1)
X_train, X_test, y_train, y_test = train_test_split(X, y, random_state=42)
n_iter = 100
eps = 1e-8 # Smoothing to avoid division by zero
alpha = 1e-2
minibatch_size = 100
n_experiment = 3
algos = dict(
sgd=sgd,
momentum=momentum,
nesterov=nesterov,
adagrad=adagrad,
rmsprop=rmsprop,
adam=adam
)
algo_accs = {k: np.zeros(n_experiment) for k in algos}
for algo_name, algo in algos.items():
print('Experimenting on {}'.format(algo_name))
for k in range(n_experiment):
# print('Experiment-{}'.format(k))
# Reset model
model = make_network()
model = algo(model, X_train, y_train, minibatch_size)
y_pred = np.zeros_like(y_test)
for i, x in enumerate(X_test):
_, prob = forward(x, model)
y = np.argmax(prob)
y_pred[i] = y
algo_accs[algo_name][k] = np.mean(y_pred == y_test)
print()
for k, v in algo_accs.items():
print('{} => mean accuracy: {}, std: {}'.format(k, v.mean(), v.std()))
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