It would result in the same only if the function has no side-effects and returns a singleton in a deterministic manner (given its inputs).
x = y = is_computer_on()
Note that the result would be the same, but the process to achieve the result would not:
The content of x and y variables would be the same, but the instruction
x = y = slow_is_computer_on() would last 10 seconds, and its counterpart
x = slow_is_computer_on() ; y = slow_is_computer_on() would last 20 seconds.
It would be almost the same if the function has no side-effects and returns an immutable in a deterministic manner (given its inputs).
return (i+1, i+2, i+3)
x = y = count_three(42)
Note that the same catches explained in previous section applies.
Why I say almost? Because of this:
x = y = count_three(42)
x is y # <- is True
x = count_three(42)
y = count_three(42)
x is y # <- is False
is is something strange, but this illustrates that the return is not the same. This is important for the mutable case:
It is dangerous and may lead to bugs if the function returns a mutable
This has also been answered in this question. For the sake of completeness, I replay the argument:
return [i+1, i+2, i+3]
x = y = mutable_count_three(i)
Because in that scenario
y are the same object, doing an operation like
x.append(42) whould mean that both
y hold a reference to a list which now has 4 elements.
It would not be the same if the function has side-effects
Considering a print a side-effect (which I find valid, but other examples may be used instead):
print "Hello world, I have been called!"
x = y = is_computer_on_with_side_effect() # One print
# The following are *two* prints:
x = is_computer_on_with_side_effect()
y = is_computer_on_with_side_effect()
Instead of a print, it may be a more complex or more subtle side-effect, but the fact remains: the method is called once or twice and that may lead to different behaviour.
It would not be the same if the function is non-deterministic given its inputs
Maybe a simple random method:
# This is a 2d6 throw:
return random.randint(1,6) + random.randint(1,6)
x = y = throw_dice() # x and y will have the same value
# The following may lead to different values:
x = throw_dice()
y = throw_dice()
But, things related to clock, global counters, system stuff, etc. is sensible to being non-deterministic given the input, and in those cases the value of
y may diverge.