def __call__(self, x: jnp.ndarray, *, is_training: bool) -> jnp.ndarray:
n_upsamples = max(self._n_time_upsamples, self._n_space_upsamples)
time_stride = 2
space_stride = 2
for i in range(n_upsamples):
if i >= self._n_time_upsamples:
time_stride = 1
if i >= self._n_space_upsamples:
space_stride = 1
channels = self._n_outputs * pow(2, n_upsamples - 1 - i)
x = hk.Conv3DTranspose(
output_channels=channels,
stride=[time_stride, space_stride, space_stride],
kernel_shape=[4, 4, 4],
name=f'conv3d_transpose_{i}')(x)
if i != n_upsamples - 1:
x = jax.nn.relu(x)
return x
shape=(BATCH_SIZE, 2, 2)),
ModuleDescriptor(
name="Conv2D",
create=lambda: hk.Conv2D(3, 3),
shape=(BATCH_SIZE, 2, 2, 2)),
ModuleDescriptor(
name="Conv2DTranspose",
create=lambda: hk.Conv2DTranspose(3, 3),
shape=(BATCH_SIZE, 2, 2, 2)),
ModuleDescriptor(
name="Conv3D",
create=lambda: hk.Conv3D(3, 3),
shape=(BATCH_SIZE, 2, 2, 2, 2)),
ModuleDescriptor(
name="Conv3DTranspose",
create=lambda: hk.Conv3DTranspose(3, 3),
shape=(BATCH_SIZE, 2, 2, 2, 2)),
ModuleDescriptor(
name="DepthwiseConv2D",
create=lambda: hk.DepthwiseConv2D(1, 3),
shape=(BATCH_SIZE, 2, 2, 2)),
)
class DummyCore(hk.RNNCore):
def initial_state(self, batch_size):
return jnp.ones([batch_size, 128, 1])
def __call__(self, inputs, state):
return inputs, state
