def measure_accuracy(activation, data, use_gpu=False):
X_val, y_val = data
executor = ad.Executor([activation], use_gpu=use_gpu)
prob_val, = executor.run(feed_shapes={X: X_val})
if use_gpu:
prob_val = prob_val.asnumpy()
correct = np.sum(np.equal(y_val, np.argmax(prob_val, axis=1)))
percentage = (correct / (y_val.shape[0])) * 100.00
return percentage
def __init__(self, cost, params, lr=0.1, use_gpu=False):
self.cost = cost
self.params = self._copy_to_gpu(params) if use_gpu else params
self.lr = lr
grads = ad.gradients(cost, params)
grads.insert(0, cost)
self.use_gpu = use_gpu
self.executor = ad.Executor(grads, use_gpu=use_gpu)
def test_reducesum():
x2 = ad.Variable(name='x2')
y = ad.reduce_sum(x2)
grad_x2, = ad.gradients(y, [x2])
executor = ad.Executor([y, grad_x2])
x2_val = np.array([[1, 2, 3], [4, 5, 6]])
y_val, grad_x2_val = executor.run(feed_shapes={x2: x2_val})
assert isinstance(y, ad.Node)
assert np.array_equal(y_val, np.array([5, 7, 9]))
assert np.array_equal(grad_x2_val, np.array([1, 1, 1]))
def test_identity():
x = ad.Variable(name='x')
y = ad.Variable(name='y')
z = x / y + x / 2. + 4
z_grad_x, z_grad_y = ad.gradients(z, [x, y])
executor = ad.Executor([z, z_grad_x, z_grad_y])
x_val = 2 * np.ones(1)
y_val = 3 * np.ones(1)
z_val, z_grad_x, z_grad_y = executor.run(feed_shapes={x: x_val, y: y_val})
print(z_val, z_grad_x, z_grad_y)
def test_sigmoid():
x = ad.Variable(name='x')
y = th.nn.sigmoid(x)
grad_x, = ad.gradients(y, [x])
executor = ad.Executor([y, grad_x])
x_val = np.array([-100, 0, 100])
y_val, grad_x_val = executor.run(feed_shapes={x: x_val})
print(y_val, grad_x_val)
def test_relu():
x = ad.Variable(name='x')
y = th.nn.relu(x)
grad_x2, = ad.gradients(y, [x])
executor = ad.Executor([y, grad_x2])
x_val = np.array([[-1, 2, 3], [1, -2, 0]])
y_val, grad_x2_val = executor.run(feed_shapes={x: x_val})
expected_y_val = np.array([[0, 2, 3], [1, 0, 0]])
expected_x2_grad = np.array([[0, 1, 1], [1, 0, 0]])
assert np.array_equal(y_val, expected_y_val)
assert np.array_equal(grad_x2_val, expected_x2_grad)
def test_softmax():
x2_pred = ad.Variable(name='x2_pred')
x2_actu = ad.Variable(name='x2_actu')
y = th.nn.softmax_cross_entropy_with_logits(x2_pred, x2_actu)
x2_pred_grad, x2_actu_grad = ad.gradients(y, [x2_pred, x2_actu])
x2_pred_val = np.array([[0.8, 0.01, 0.5], [0.8, 0.01, 0.5]])
x2_actu_val = np.array([[1.0, 1.0, 0], [1.0, 1.0, 0]])
executor = ad.Executor([y, x2_pred_grad, x2_actu_grad])
y_val, x2_pred_grad_val, x2_actu_grad_val = executor.run(
feed_shapes={
x2_pred: x2_pred_val,
x2_actu: x2_actu_val
})
def test_broadcast_to():
x2 = ad.Variable(name='x2')
x3 = ad.Variable(name='x3')
y = ad.broadcast_to(x2, x3)
grad_x2, grad_x3 = ad.gradients(y, [x2, x3])
executor = ad.Executor([y, grad_x2, grad_x3])
x2_val = np.array([[1, 2, 3]])
x3_val = np.zeros((3, 3))
y_val, grad_x2_val, grad_x3_val = executor.run(feed_shapes={
x2: x2_val,
x3: x3_val
})
# asserts
assert isinstance(y, ad.Node)
assert np.array_equal(y_val, np.array([[1, 2, 3], [1, 2, 3], [1, 2, 3]]))
assert np.array_equal(grad_x2_val, np.array([3, 3, 3]))
def test_matmul():
x = ad.Variable(name='x')
y = ad.Variable(name='y')
z = ad.matmul(x, y)
z_grad_x, z_grad_y = ad.gradients(z, [x, y])
executor = ad.Executor([z, z_grad_x, z_grad_y])
x_val = np.array([[1, 2], [3, 4], [5, 6]]) # 3x2
y_val = np.array([[7, 8, 9], [10, 11, 12]]) # 2x3
z_val, z_grad_x, z_grad_y = executor.run(feed_shapes={x: x_val, y: y_val})
expected_yval = np.matmul(x_val, y_val)
expected_grad_x_val = np.matmul(np.ones_like(expected_yval),
np.transpose(y_val))
expected_grad_y_val = np.matmul(x_val.T, np.ones_like(expected_yval))
assert np.array_equal(expected_yval, z_val)
assert np.array_equal(expected_grad_x_val, z_grad_x)
assert np.array_equal(expected_grad_y_val, z_grad_y)
