What happens in degenerate case of multiple assignment?

I'm teaching myself algorithms. I needed to swap two items in a list. Python makes all things easy:

``````def swap(A, i, j):
A[i], A[j] = A[j], A[i]
``````

This works a treat:

``````>>> A = list(range(5))
>>> A
[0, 1, 2, 3, 4]
>>> swap(A, 0, 1)
>>> A
[1, 0, 2, 3, 4]
``````

Note the function is resilient to the degenerate case `i = j`. As you'd expect, it simply leaves the list unchanged:

``````>>> A = list(range(5))
>>> swap(A, 0, 0)
>>> A
[0, 1, 2, 3, 4]
``````

Later I wanted to permute three items in a list. I wrote a function to permute them in a 3-cycle:

``````def cycle(A, i, j, k):
A[i], A[j], A[k] = A[j], A[k], A[i]
``````

This worked well:

``````>>> A = list("tap")
>>> A
['t', 'a', 'p']
>>> cycle(A, 0, 1, 2)
>>> A
['a', 'p', 't']
``````

However I (eventually) discovered it goes wrong in degenerate cases. I assumed a degenerate 3-cycle would be a swap. So it is when `i = j`, `cycle(i, i, k) ≡ swap(i, k)`:

``````>>> A = list(range(5))
>>> cycle(A, 0, 0, 1)
>>> A
[1, 0, 2, 3, 4]
``````

But when `i = k` something else happens:

``````>>> A = list(range(5))
>>> sum(A)
10
>>> cycle(A, 1, 0, 1)
>>> A
[1, 1, 2, 3, 4]
>>> sum(A)
11
``````

What's going on? `sum` should be invariant under any permutation! Why does this case `i = k` degenerate differently?

How can I achieve what I want? That is a 3-cycle function that degenerates to a swap if only 2 indices are distinct `cycle(i, i, j) ≡ cycle(i, j, i) ≡ cycle(i, j, j) ≡ swap(i, j)`

-
Can you clarify exactly what behavior you're expecting out of the degeneration? Also note there's `itertools.permutations` that would shuffle the values - though you can't specify how it's going to shuffle them, only that it will eventually permute through all possible pairings. e.g. what about `cycle(A, 0, 0, 0)`? – Wayne Werner Jan 19 at 17:47
@WayneWerner "a 3-cycle function that degenerates to a swap if only 2 indices are distinct" eg. `cycle(i, j, i) ≡ swap(i, j)` – Colonel Panic Jan 20 at 10:54
I'm not sure that's well defined. That's enough to write a function for when `i=k`, but what if `j=k`? or `i=j`? Are those cases ignored? – Wayne Werner Jan 20 at 13:04
Precisely: `cycle(i, i, j) ≡ cycle(i, j, i) ≡ cycle(i, j, j) ≡ swap(i, j)`. And of course `cycle(i, i, i)` should be the identity function. – Colonel Panic Jan 20 at 14:26

`cycle` is doing exactly what you ask it to: assigning to the left hand values the right hand values.

``````def cycle(A, i, j, k):
A[i], A[j], A[k] = A[j], A[k], A[i]
``````

is functionally equivalent to

``````def cycle(A, i, j, k):
new_values = A[j], A[k], A[i]
A[i], A[j], A[k] = new_values
``````

So when you do `cycle(A, 1, 0, 1)` what you are saying is that you want

``````A[1] = previous_A[0]
A[0] = previous_A[1]
A[1] = previous_A[1]
``````

If you want cycle to work sequentially then you must write it sequentially, otherwise python evaluates the right hand and then expands that to the arguments on the left hand.

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Great explanation. It would be nice to also add an actual solution to the problem! – Daniel Darabos Jan 19 at 17:11
@DanielDarabos it would, if it was actually a problem. – njzk2 Jan 19 at 18:44

Well it seems you are re-assigning to the same target `A[1]`, to get a visualization of the call:

``````A[1], A[0], A[1] = A[0], A[1], A[1]
``````

Remember, from the documentation on assignment statements:

An assignment statement evaluates the expression list (remember that this can be a single expression or a comma-separated list, the latter yielding a tuple) and assigns the single resulting object to each of the target lists, from left to right.

So your evaluation goes something like dis:

• Create tuple with values `A[0], A[1], A[1]` translating to `(0, 1, 1)`
• Assign these to the target list `A[1], A[0], A[1]` from left to right.

Assignment from left to right takes place:

1. `A[1] = 0`
2. `A[0] = 1`
3. `A[1] = 1`

So the first assignment made is `A[1]` with the first element of the tuple `0`, then the second assignment `A[0]` with the second element `1` and, finally, at the end, `A[1]` is overriden with the third element in the tuple `1`.

You can get a more convoluted view of this with `dis.dis`; notice how all elements in the right hand of the assignment statement are loaded first and then they are assigned to their values:

``````dis.dis(cycle)
6 BINARY_SUBSCR
13 BINARY_SUBSCR
21 ROT_THREE
22 ROT_TWO
23 LOAD_FAST                0 (A)  # Assign first
29 STORE_SUBSCR
30 LOAD_FAST                0 (A)  # Assign second
Because `cycle(A, 1, 0, 1)` becomes `A[1], A[0], A[1] = A[0], A[1], A[1]`, resulting in both `A[0]` and `A[1]` ending up with the old value of `A[1]`. `cycle(0, 0, 1)` works because it becomes `A[0], A[0], A[1] = A[0], A[1], A[0]`, which is equivalent to `swap(A, k, j)`.