As this question has multiple major parts, I've dedicated a Q&A to the core challenge: stateful backpropagation. This answer focuses on implementing the variable output step length.

**Description**:

- As validated in Case 5, we can take a bottom-up first approach. First we feed the complete input to
`model_a`

(A) - then, feed its outputs as input to `model_b`

(B), but this time *one step at a time*.
- Note that we must chain B's output steps
*per* A's input step, not *between* A's input steps; i.e., in your diagram, gradient is to flow between `Out[0][1]`

and `Out[0][0]`

, but not between `Out[2][0]`

and `Out[0][1]`

.
- For computing loss it won't matter whether we use a ragged or padded tensor; we must however use a padded tensor for writing to TensorArray.
- Loop logic in code below is general; specific attribute handling and hidden state passing, however, is hard-coded for simplicity, but can be rewritten for generality.

*Code*: at bottom.

**Example**:

- Here we predefine the number of iterations for B per input from A, but we can implement any arbitrary stopping logic. For example, we can take a
`Dense`

layer's output from B as a hidden state and check if its L2-norm exceeds a threshold.
- Per above, if
`longest_step`

is unknown to us, we can simply set it, which is common for NLP & other tasks with a STOP token.
- Alternatively, we may write to separate
`TensorArrays`

at every A's input with `dynamic_size=True`

; see "point of uncertainty" below.

- A valid concern is, how do we know gradients flow correctly? Note that we've validate them for both vertical and horizontal in the linked Q&A, but it didn't cover multiple output steps per an input step, for multiple input steps. See below.

*Point of uncertainty*: I'm not entirely sure whether gradients interact between e.g. `Out[0][1]`

and `Out[2][0]`

. I did, however, verify that gradients *will not* flow horizontally if we write to separate `TensorArray`

s for B's outputs per A's inputs (case 2); reimplementing for cases 4 & 5, grads will differ for *both* models, including lower one with a complete single horizontal pass.

Thus we must write to a unified `TensorArray`

. For such, as there are no ops leading from e.g. `IR[1]`

to `Out[0][1]`

, I can't see how TF would trace it as such - so it seems we're safe. Note, however, that in below example, using `steps_at_t=[1]*6`

*will* make gradient flow in the both model horizontally, as we're writing to a single `TensorArray`

and passing hidden states.

The examined case is confounded, however, with B being stateful at all steps; lifting this requirement, we might *not* need to write to a unified `TensorArray`

for all `Out[0]`

, `Out[1]`

, etc, but we must still test against something we know works, which is no longer as straightforward.

**Example [code]**:

```
import numpy as np
import tensorflow as tf
#%%# Make data & models, then fit ###########################################
x0 = y0 = tf.constant(np.random.randn(2, 3, 4))
msn = MultiStatefulNetwork(batch_shape=(2, 3, 4), steps_at_t=[3, 4, 2])
#%%#############################################
with tf.GradientTape(persistent=True) as tape:
outputs = msn(x0)
# shape: (3, 4, 2, 4), 0-padded
# We can pad labels accordingly.
# Note the (2, 4) model_b's output shape, which is a timestep slice;
# model_b is a *slice model*. Careful in implementing various logics
# which are and aren't intended to be stateful.
```

**Methods**:

Not the cleanest, nor most optimal code, but it works; room for improvement.

More importantly: I implemented this in Eager, and have no idea how it'll work in Graph, and making it work for both can be quite tricky. If needed, just run in Graph and compare all values as done in the "cases".

```
# ideally we won't `import tensorflow` at all; kept for code simplicity
import tensorflow as tf
from tensorflow.python.util import nest
from tensorflow.python.ops import array_ops, tensor_array_ops
from tensorflow.python.framework import ops
from tensorflow.keras.layers import Input, SimpleRNN, SimpleRNNCell
from tensorflow.keras.models import Model
#######################################################################
class MultiStatefulNetwork():
def __init__(self, batch_shape=(2, 6, 4), steps_at_t=[]):
self.batch_shape=batch_shape
self.steps_at_t=steps_at_t
self.batch_size = batch_shape[0]
self.units = batch_shape[-1]
self._build_models()
def __call__(self, inputs):
outputs = self._forward_pass_a(inputs)
outputs = self._forward_pass_b(outputs)
return outputs
def _forward_pass_a(self, inputs):
return self.model_a(inputs, training=True)
def _forward_pass_b(self, inputs):
return model_rnn_outer(self.model_b, inputs, self.steps_at_t)
def _build_models(self):
ipt = Input(batch_shape=self.batch_shape)
out = SimpleRNN(self.units, return_sequences=True)(ipt)
self.model_a = Model(ipt, out)
ipt = Input(batch_shape=(self.batch_size, self.units))
sipt = Input(batch_shape=(self.batch_size, self.units))
out, state = SimpleRNNCell(4)(ipt, sipt)
self.model_b = Model([ipt, sipt], [out, state])
self.model_a.compile('sgd', 'mse')
self.model_b.compile('sgd', 'mse')
def inner_pass(model, inputs, states):
return model_rnn(model, inputs, states)
def model_rnn_outer(model, inputs, steps_at_t=[2, 2, 4, 3]):
def outer_step_function(inputs, states):
x, steps = inputs
x = array_ops.expand_dims(x, 0)
x = array_ops.tile(x, [steps, *[1] * (x.ndim - 1)]) # repeat steps times
output, new_states = inner_pass(model, x, states)
return output, new_states
(outer_steps, steps_at_t, longest_step, outer_t, initial_states,
output_ta, input_ta) = _process_args_outer(model, inputs, steps_at_t)
def _outer_step(outer_t, output_ta_t, *states):
current_input = [input_ta.read(outer_t), steps_at_t.read(outer_t)]
output, new_states = outer_step_function(current_input, tuple(states))
# pad if shorter than longest_step.
# model_b may output twice, but longest in `steps_at_t` is 4; then we need
# output.shape == (2, *model_b.output_shape) -> (4, *...)
# checking directly on `output` is more reliable than from `steps_at_t`
output = tf.cond(
tf.math.less(output.shape[0], longest_step),
lambda: tf.pad(output, [[0, longest_step - output.shape[0]],
*[[0, 0]] * (output.ndim - 1)]),
lambda: output)
output_ta_t = output_ta_t.write(outer_t, output)
return (outer_t + 1, output_ta_t) + tuple(new_states)
final_outputs = tf.while_loop(
body=_outer_step,
loop_vars=(outer_t, output_ta) + initial_states,
cond=lambda outer_t, *_: tf.math.less(outer_t, outer_steps))
output_ta = final_outputs[1]
outputs = output_ta.stack()
return outputs
def _process_args_outer(model, inputs, steps_at_t):
def swap_batch_timestep(input_t):
# Swap the batch and timestep dim for the incoming tensor.
# (samples, timesteps, channels) -> (timesteps, samples, channels)
# iterating dim0 to feed (samples, channels) slices expected by RNN
axes = list(range(len(input_t.shape)))
axes[0], axes[1] = 1, 0
return array_ops.transpose(input_t, axes)
inputs = nest.map_structure(swap_batch_timestep, inputs)
assert inputs.shape[0] == len(steps_at_t)
outer_steps = array_ops.shape(inputs)[0] # model_a_steps
longest_step = max(steps_at_t)
steps_at_t = tensor_array_ops.TensorArray(
dtype=tf.int32, size=len(steps_at_t)).unstack(steps_at_t)
# assume single-input network, excluding states which are handled separately
input_ta = tensor_array_ops.TensorArray(
dtype=inputs.dtype,
size=outer_steps,
element_shape=tf.TensorShape(model.input_shape[0]),
tensor_array_name='outer_input_ta_0').unstack(inputs)
# TensorArray is used to write outputs at every timestep, but does not
# support RaggedTensor; thus we must make TensorArray such that column length
# is that of the longest outer step, # and pad model_b's outputs accordingly
element_shape = tf.TensorShape((longest_step, *model.output_shape[0]))
# overall shape: (outer_steps, longest_step, *model_b.output_shape)
# for every input / at each step we write in dim0 (outer_steps)
output_ta = tensor_array_ops.TensorArray(
dtype=model.output[0].dtype,
size=outer_steps,
element_shape=element_shape,
tensor_array_name='outer_output_ta_0')
outer_t = tf.constant(0, dtype='int32')
initial_states = (tf.zeros(model.input_shape[0], dtype='float32'),)
return (outer_steps, steps_at_t, longest_step, outer_t, initial_states,
output_ta, input_ta)
def model_rnn(model, inputs, states):
def step_function(inputs, states):
output, new_states = model([inputs, *states], training=True)
return output, new_states
initial_states = states
input_ta, output_ta, time, time_steps_t = _process_args(model, inputs)
def _step(time, output_ta_t, *states):
current_input = input_ta.read(time)
output, new_states = step_function(current_input, tuple(states))
flat_state = nest.flatten(states)
flat_new_state = nest.flatten(new_states)
for state, new_state in zip(flat_state, flat_new_state):
if isinstance(new_state, ops.Tensor):
new_state.set_shape(state.shape)
output_ta_t = output_ta_t.write(time, output)
new_states = nest.pack_sequence_as(initial_states, flat_new_state)
return (time + 1, output_ta_t) + tuple(new_states)
final_outputs = tf.while_loop(
body=_step,
loop_vars=(time, output_ta) + tuple(initial_states),
cond=lambda time, *_: tf.math.less(time, time_steps_t))
new_states = final_outputs[2:]
output_ta = final_outputs[1]
outputs = output_ta.stack()
return outputs, new_states
def _process_args(model, inputs):
time_steps_t = tf.constant(inputs.shape[0], dtype='int32')
# assume single-input network (excluding states)
input_ta = tensor_array_ops.TensorArray(
dtype=inputs.dtype,
size=time_steps_t,
tensor_array_name='input_ta_0').unstack(inputs)
# assume single-output network (excluding states)
output_ta = tensor_array_ops.TensorArray(
dtype=model.output[0].dtype,
size=time_steps_t,
element_shape=tf.TensorShape(model.output_shape[0]),
tensor_array_name='output_ta_0')
time = tf.constant(0, dtype='int32', name='time')
return input_ta, output_ta, time, time_steps_t
```

gradientbehavior? i.e., do horizontal arrows denote a stateful gradient? If so, then you must backpropagate through several full forward passes, which is way beyond the scope of one question.`Out[n][i]`

depends on`IR[n]`

and the hidden state from the previous iteration of`Model[1]`

. And so on, like a normal RNN.`IR[n]`

in turn depends on`Input[n]`

and`H[n]`

like a normal RNN. So the total gradients contributing to any particular output is essentially everything to the (logical) left and (logically) underneath the output. That being said, while`Model[0]`

is stateful, for my particular use case it is not necessary to backpropagate beyond the beginning of a particular time batch to achieve good results. (`H[0]`

can be treated as an immutable input)`H[4]`

, would you backpropagate through`H[3], H[2], H[1], H[0]`

? And for`Out[2][2]`

, through`Out[2][1], Out[2][0]`

? Then you seek batch-to-batch backprop, which isn't natively implemented in tf.keras; RNN's`stateful`

doesn't backpropagate between batches, and learns to work with various initializations rather than truly longer sequences. If this RNN behavior is what you seek, the task is simple - else, fairly complex, but doable within tf.keras by invoking TF ops.`Out[1][1]`

(ie. the stop) depends on both`IR[1]`

and the hidden state from the previous iteration of the upper RNN (which depends on`IR[1]`

), in turn`IR[1]`

depends on`H[1]`

,`H[0]`

,`Input[1]`

and`Input[0]`

. I'm looking to back propagate from`Out[1][1]`

all of the way to the inputs, if this is possible. Otherwise, I cannot see a way to train both networks (as I have no constraints on what`IR`

can be).`Input`

is asingle train step, correct? I.e. weights aren't updated until`Input[-1]`

is consumed.3more comments