I want to write a crude Euler simulation of a set of PDEs. I read the PDE tutorial on tensorflow.org and I am a little puzzled about how to do this properly. I have two specific questions but would welcome further feedback if there is anything I have overlooked or misunderstood.

The following code is from the tutorial:

```
# Discretized PDE update rules
U_ = U + eps * Ut
Ut_ = Ut + eps * (laplace(U) - damping * Ut)
# Operation to update the state
step = tf.group(
U.assign(U_),
Ut.assign(Ut_))
```

# Question 1

Isn't there a bug here? Once `U.assign(U_)`

has been evaluated, surely the next evaluation of `Ut_`

will use the updated value of `U`

rather than the value from the same time step? I would have thought that the correct way to do it would be as follows:

```
delta_U = tf.Variable(dU_init)
delta_Ut = tf.Variable(dUt_init)
delta_step = tf.group(
delta_U.assign(Ut)
delta_Ut.assign(laplace(U) - damping * Ut)
)
update_step = tf.group(
U.assign_add(eps * delta_U),
Ut.assign_add(eps * delta_Ut)
)
```

We could then run Euler integration steps by alternating evaluations of `delta_step`

and `update_step`

. If I understand correctly, this could be done via separate invocations of `Session.run()`

:

```
with tf.Session() as sess:
...
for i in range(1000):
sess.run(delta_step)
sess.run(update_step)
```

# Question 2

It seems frustrating that a single operation can't be defined that combines both steps in a fixed order, e.g.

```
combined_update = tf.group(delta_step, update_step)
with tf.Session() as sess:
...
for i in range(1000):
sess.run(combined_update)
```

but according to an answer on this thread, `tf.group()`

does not guarantee any particular evaluation order. The approach described on that thread for controlling evaluation order involves something called "control dependencies"; can they be used in this instance, where we want to ensure that *repeated* evaluations of two tensors are made in a fixed order?

If not, is there another way to control the order of evaluation of these tensors, beyond explicitly using sequential `Session.run()`

calls?

# Update (12/02/2019)

Update: based on jdehesa's answer, I investigated in greater detail. The results support my original intuition that there is a bug in the PDE tutorial which produces incorrect results due to inconsistent evaluation order of `tf.assign()`

calls; this is not resolved by using control dependencies. However, the method from the PDE tutorial usually produces correct results, and I don't understand why.

I checked the results of running the assignment operations in an explicit order, using the following code:

```
import tensorflow as tf
import numpy as np
# define two variables a and b, and the PDEs that govern them
a = tf.Variable(0.0)
b = tf.Variable(1.0)
da_dt_ = b * 2
db_dt_ = 10 - a * b
dt = 0.1 # integration step size
# after one step of Euler integration, we should have
# a = 0.2 [ = 0.0 + (1.0 * 2) * 0.1 ]
# b = 2.0 [ = 1.0 + (10 - 0.0 * 1.0) * 0.1 ]
# using the method from the PDE tutorial, define updated values for a and b
a_ = a + da_dt_ * dt
b_ = b + db_dt_ * dt
# and define the update operations
assignA = a.assign(a_)
assignB = b.assign(b_)
# define a higher-order function that runs a particular simulation n times
# and summarises the results
def summarise(simulation, n=500):
runs = np.array( [ simulation() for i in range(n) ] )
summary = dict( { (tuple(run), 0) for run in np.unique(runs, axis=0) } )
for run in runs:
summary[tuple(run)] += 1
return summary
# check the results of running the assignment operations in an explicit order
def explicitOrder(first, second):
with tf.Session() as sess:
sess.run(tf.global_variables_initializer())
sess.run(first)
sess.run(second)
return (sess.run(a), sess.run(b))
print( summarise(lambda: explicitOrder(assignA, assignB)) )
# prints {(0.2, 1.98): 500}
print( summarise(lambda: explicitOrder(assignB, assignA)) )
# prints {(0.4, 2.0): 500}
```

As expected, if we evaluate `assignA`

first then `a`

gets updated to 0.2, and this updated value is then used to update `b`

to 1.98. If we evaluate `assignB`

first, `b`

is first updated to 2.0, and this updated value is then used to update `a`

to 0.4. These are both the wrong answer to the Euler integration: what we ought to get is `a`

= 0.2, `b`

= 2.0.

I tested what happens when we allow the order of evaluation to be controlled implicitly by `tf.group()`

, without using control dependencies.

```
noCDstep = tf.group(assignA, assignB)
def implicitOrder():
with tf.Session() as sess:
sess.run(tf.global_variables_initializer())
sess.run(noCDstep)
return (sess.run(a), sess.run(b))
print( summarise(lambda: implicitOrder()) )
# prints, e.g. {(0.4, 2.0): 37, (0.2, 1.98): 1, (0.2, 2.0): 462}
```

Occasionally, this produces the same result as evaluating `assignB`

followed by `assignA`

, or (more rarely) evaluating `assignA`

followed by `assignB`

. But most of the time, there is an entirely unexpected result: the correct answer to the Euler integration step. This behaviour is both inconsistent and surprising.

I tried to resolve this inconsistent behaviour by introducing control dependencies as suggested by jdehesa, using the following code:

```
with tf.control_dependencies([a_, b_]):
cdStep = tf.group(assignA, assignB)
def cdOrder():
with tf.Session() as sess:
sess.run(tf.global_variables_initializer())
sess.run(cdStep)
return (sess.run(a), sess.run(b))
print( summarise(lambda: cdOrder()) )
# prints, e.g. {(0.4, 2.0): 3, (0.2, 1.98): 3, (0.2, 2.0): 494}
```

It appears that control dependencies do not resolve this inconsistency, and it is not clear that they make any difference at all. I then tried implementing the approach originally suggested in my question, which uses additional variables to enforce the computation of deltas and updates independently:

```
da_dt = tf.Variable(0.0)
db_dt = tf.Variable(0.0)
assignDeltas = tf.group( da_dt.assign(da_dt_), db_dt.assign(db_dt_) )
assignUpdates = tf.group( a.assign_add(da_dt * dt), b.assign_add(db_dt * dt) )
def explicitDeltas():
with tf.Session() as sess:
sess.run(tf.global_variables_initializer())
sess.run(assignDeltas)
sess.run(assignUpdates)
return (sess.run(a), sess.run(b))
print( summarise(lambda: explicitDeltas()) )
# prints {(0.2, 2.0): 500}
```

As expected, this consistently computes the Euler integration step correctly.

I can understand why sometimes `tf.group(assignA, assignB)`

produces an answer consistent with running `assignA`

followed by `assignB`

, and why it sometimes produces an answer consistent with running `assignB`

followed by `assignA`

, but I don't understand why it usually produces an answer that is magically correct (for the Euler integration case) and consistent with neither of these orders. What is going on?