# How can I make TensorFlow 2.0 handle piecewise gradients (e.g. across `tf.gather`)?

I'm attempting to leverage TensorFlow 2.0's automatic differentiation to automate the calculation of certain gradients on financial instruments. Generally this involves a piecewise interpolation scheme between various "benchmark points". The simplest example is below:

``````    import tensorflow as tf

MATURITIES = tf.constant([1.0, 2.0, 3.0, 5.0, 7.0, 10.0, 12.0, 15.0, 20.0, 25.0])
CASH_FLOW_TIMES = tf.constant([n * 0.5 for n in range(1, 51)])
YIELDS = tf.Variable([0.04153733, 0.0425888, 0.04662959, 0.05406879, 0.05728735, 0.0606996, 0.06182699, 0.05854381, 0.05376556, 0.0531946])

@tf.function
def linear(knot_y, knot_x, x):
"""Linear interpolation"""
i = tf.maximum(tf.minimum(tf.searchsorted(knot_x, x, side="right") - 1, knot_x.shape[0] - 2), 0)
y_i = tf.gather(knot_y, i)
x_i = tf.gather(knot_x, i)
return y_i + y_i / x_i * (x - x_i)

tape.watch(YIELDS)
y = linear(YIELDS, MATURITIES, CASH_FLOW_TIMES)
y, dydx
``````

Which outputs the following:

``````    (<tf.Tensor: id=1249, shape=(50,), dtype=float32, numpy=
array([0.02076866, 0.04153733, 0.06230599, 0.0425888 , 0.053236  ,
0.04662959, 0.05440119, 0.06217279, 0.06994438, 0.05406879,
0.05947567, 0.06488255, 0.07028943, 0.05728735, 0.0613793 ,
0.06547125, 0.06956321, 0.07365517, 0.07774712, 0.0606996 ,
0.06373458, 0.06676956, 0.06980454, 0.06182699, 0.06440312,
0.06697924, 0.06955536, 0.07213148, 0.07470761, 0.05854381,
0.06049527, 0.06244673, 0.06439819, 0.06634965, 0.06830111,
0.07025257, 0.07220403, 0.07415549, 0.07610695, 0.05376556,
0.0551097 , 0.05645384, 0.05779798, 0.05914212, 0.06048626,
0.06183039, 0.06317453, 0.06451868, 0.06586281, 0.06720695],
dtype=float32)>,
<tensorflow.python.framework.indexed_slices.IndexedSlices at 0x203027345c0>)
``````

The issue is that, due (I suspect) to the `tf.searchsorted` or `tf.gather` calls, the gradient is an `IndexedSlice`, not a Tensor. This causes an issue when I need to chain multiple `tf.function` together to value a security. For example, say I want to use a transformation of the `YIELDS` variable within my `linear` function:

``````    import tensorflow as tf

MATURITIES = tf.constant([1.0, 2.0, 3.0, 5.0, 7.0, 10.0, 12.0, 15.0, 20.0, 25.0])
CASH_FLOW_TIMES = tf.constant([n * 0.5 for n in range(1, 51)])
YIELDS = tf.Variable([0.04153733, 0.0425888, 0.04662959, 0.05406879, 0.05728735, 0.0606996, 0.06182699, 0.05854381, 0.05376556, 0.0531946])

@tf.function
def logdf_from_yields(yields, times):
return tf.math.multiply(yields, times) * -1.0

@tf.function
def linear(knot_y, knot_x, x):
"""Linear interpolation"""
i = tf.maximum(tf.minimum(tf.searchsorted(knot_x, x, side="right") - 1, knot_x.shape[0] - 2), 0)
y_i = tf.gather(knot_y, i)
x_i = tf.gather(knot_x, i)
return y_i + y_i / x_i * (x - x_i)

tape.watch(YIELDS)
y = linear(logdf_from_yields(YIELDS, MATURITIES), MATURITIES, CASH_FLOW_TIMES)
y, dydx
``````

This code raises the following exception:

``````    ---------------------------------------------------------------------------
AssertionError                            Traceback (most recent call last)
<ipython-input-9-2bc3457894ea> in <module>
20     tape.watch(YIELDS)
21     y = linear(logdf_from_yields(YIELDS, MATURITIES), MATURITIES, CASH_FLOW_TIMES)
---> 22 dydx = tape.gradient(y, YIELDS)
23 y, dydx

1001         sources_raw=flat_sources_raw,
1003
1004     if not self._persistent:

75       sources_raw,

~\Anaconda3\lib\site-packages\tensorflow\python\eager\function.py in backward_function(*args)
904               if a is not None and i not in skip_positions]
905       return self._backward_graph_function._call_flat(  # pylint: disable=protected-access
--> 906           list(args) + side_outputs)
907
908     tape.record_operation(self._forward_function.signature.name, real_outputs,

~\Anaconda3\lib\site-packages\tensorflow\python\eager\function.py in _call_flat(self, args)
610     if any(isinstance(a, composite_tensor.CompositeTensor) for a in args):
611       raise AssertionError("Expected all args to be Tensors or Variables; "
--> 612                            "but got CompositeTensor: %r" % args)
613
614     if (tape.could_possibly_record() or

AssertionError: Expected all args to be Tensors or Variables; but got CompositeTensor: [<tensorflow.python.framework.indexed_slices.IndexedSlices object at 0x00000203013C2128>, <tf.Tensor: id=1024, shape=(), dtype=float32, numpy=-1.0>, <tf.Tensor: id=1025, shape=(10,), dtype=float32, numpy=
array([0.04153733, 0.0851776 , 0.13988876, 0.27034396, 0.40101147,
0.606996  , 0.74192387, 0.87815714, 1.0753112 , 1.329865  ],
dtype=float32)>, <tf.Tensor: id=1026, shape=(10,), dtype=float32, numpy=array([ 1.,  2.,  3.,  5.,  7., 10., 12., 15., 20., 25.], dtype=float32)>, <tf.Tensor: id=1027, shape=(10,), dtype=float32, numpy=
array([0.04153733, 0.0425888 , 0.04662959, 0.05406879, 0.05728735,
0.0606996 , 0.06182699, 0.05854381, 0.05376556, 0.0531946 ],
dtype=float32)>]
``````

Inspecting the traceback, I see that the only item that is not a Tensor or Variable is the IndexedSlice, which I believe, again, comes from the `linear` function.

Is there a way for me to rewrite the piecewise `linear` function (e.g. using different functions) so that it will work with the gradient tape?

What have I tried?

I took a look at this question, but it seemed like the writer was trying to make the index a variable. Here I should know all of my indices ahead of time (i.e. because `MATURITIES` and `CASH_FLOW_TIMES` are fixed for any given instance of the problem ... only `YIELDS` is a `tf.Variable`). So I wasn't so sure how it applied.

This question was also interesting in that it recommended the usage of `tf.convert_to_tensor`, but I'm not sure how to apply it in my case.

Your gradient seems to be fine. TensorFlow uses `tf.IndexedSlices` to represent sparse gradients in some cases like `tf.gather`, but you can easily convert it to a regular tensor like this (the example is in graph mode but the function would be the same in eager mode):

``````import tensorflow as tf

def convert_indexed_slices_to_tensor(idx_slices):
return tf.scatter_nd(tf.expand_dims(idx_slices.indices, 1),
idx_slices.values, idx_slices.dense_shape)

# Test
with tf.Graph().as_default(), tf.Session() as sess:
a = tf.constant([1., 2., 3., 4.])
b = tf.gather(a, [0, 2])
print(g)
# IndexedSlices(indices=..., values=..., dense_shape=...)
g_dense = convert_indexed_slices_to_tensor(g)
# Tensor(...)
print(sess.run(g_dense))
# [1. 0. 1. 0.]
``````

If you want to force `tf.gather` to produce regular tensors, you can wrap it with `tf.custom_gradient` like this:

``````import tensorflow as tf

return tf.scatter_nd(tf.expand_dims(indices, 1), ys, tf.shape(params)), None
return tf.gather(params, indices, validate_indices, name), grad

# Test
with tf.Graph().as_default(), tf.Session() as sess:
a = tf.constant([1., 2., 3., 4.])
Note this assumes `axis=0` and one-dimensional `indices`, otherwise it would still be possible to do the same but it would require a bit more of work.
• Ok, so it seems like `convert_to_tensor` is the way to go. Is there a way to force `tf.gather` to use `tf.Tensor` instead of `tf.IndexedSlices` to represent gradients? I'd rather not move too far away from the current functional decomposition or program flow. – MikeRand Aug 13 '19 at 13:59
• @MikeRand Ah, you're right, actually `tf.convert_to_tensor` does already implement conversion from `tf.IndexedSlices`. I have updated the answer with a possible workaround using `tf.custom_gradient`. – jdehesa Aug 13 '19 at 14:32