Exemplo n.º 1
0
    def test_foldr(self):
        # This test aims to make sure that we walk the array from right to left
        # and checks it in the following way: multiplying left to right 1e-40
        # cannot be held into a float32 so it causes an underflow while from
        # right to left we have no such problem and the result is larger
        x = np.array([1e-20, 1e-20, 10, 10, 10], dtype=np.float32)
        for K in [KTF, KTH]:
            p1 = K.eval(K.foldl(lambda a, b: a * b, x))
            p2 = K.eval(K.foldr(lambda a, b: a * b, x))

            assert p1 < p2
            assert 9e-38 < p2 <= 1e-37
Exemplo n.º 2
0
    def test_foldr(self):
        # This test aims to make sure that we walk the array from right to left
        # and checks it in the following way: multiplying left to right 1e-40
        # cannot be held into a float32 so it causes an underflow while from
        # right to left we have no such problem and the result is larger
        x = np.array([1e-20, 1e-20, 10, 10, 10], dtype=np.float32)
        for K in [KTF, KTH]:
            p1 = K.eval(K.foldl(lambda a, b: a * b, x))
            p2 = K.eval(K.foldr(lambda a, b: a * b, x))

            assert p1 < p2
            assert 9e-38 < p2 <= 1e-37
Exemplo n.º 3
0
def integral(y_true, y_pred):
    dx = K.constant(0.05 / 100, dtype='float32')
    Acc_L2R_t = K.foldl(lambda acc, x: x * 0, K.transpose(y_true))
    Acc_L2R_p = K.foldl(lambda acc, x: x * 0, K.transpose(y_pred))
    Acc_R2L_t = K.foldr(lambda acc, x: x * 0, K.transpose(y_true))
    Acc_R2L_p = K.foldr(lambda acc, x: x * 0, K.transpose(y_pred))
    for i in range(2, 50):
        Acc_L2R_t += K.foldl(lambda acc, x: acc + x,
                             K.transpose(y_true)[0:int(i - 1)])
        Acc_L2R_t += K.foldl(lambda acc, x: acc + x, K.transpose(y_true)[1:i])
        Acc_L2R_p += K.foldl(lambda acc, x: acc + x,
                             K.transpose(y_pred)[0:int(i - 1)])
        Acc_L2R_p += K.foldl(lambda acc, x: acc + x, K.transpose(y_pred)[1:i])
        Acc_R2L_t += K.foldr(lambda acc, x: acc + x,
                             K.transpose(y_true)[0:int(i - 1)])
        Acc_R2L_t += K.foldr(lambda acc, x: acc + x, K.transpose(y_true)[1:i])
        Acc_R2L_p += K.foldr(lambda acc, x: acc + x,
                             K.transpose(y_pred)[0:int(i - 1)])
        Acc_R2L_p += K.foldr(lambda acc, x: acc + x, K.transpose(y_pred)[1:i])
    return K.mean(K.square(y_pred - y_true), axis=-1) + K.mean(
        K.square(Acc_L2R_t * dx - Acc_L2R_p * dx) +
        K.mean(K.square(Acc_R2L_t * dx - Acc_R2L_p * dx)),
        axis=-1)