I became curious if it's possible to implement such kind of triangle oscillator without conditions and enumerations. Well, one option is the following:

```
def oscillator(magnitude):
i = 0
x = y = -1
double_magnitude = magnitude + magnitude
while True:
yield i
x = (x + 1) * (1 - (x // (double_magnitude - 1))) # instead of (x + 1) % double_magnitude
y = (y + 1) * (1 - (y // (magnitude - 1))) # instead of (y + 1) % magnitude
difference = x - y # difference ∈ {0, magnitude}
derivative = (-1 * (difference > 0) + 1 * (difference == 0))
i += derivative
```

The idea behind this is to take 2 sawtooth waves with different periods and subtract one from another. The result will be a square wave with values in {0, magnitude}. Then we just substitute {0, magnitude} with {-1, +1} respectively to get derivative values for our target signal.

Let's look at example with `magnitude = 5`

:

```
o = oscillator(5)
[next(o) for _ in range(21)]
```

This outputs `[0, 1, 2, 3, 4, 5, 4, 3, 2, 1, 0, 1, 2, 3, 4, 5, 4, 3, 2, 1, 0]`

.

If `abs()`

is allowed, it can be used for simplicity. For example, the following code gives the same output as above:

```
[abs(5 - ((x + 5) % 10)) for x in range(21)]
```

`TypeError: unsupported operand type(s) for +: 'range' and 'range'`

. This will only work in Python 2`range(100, 0, -1)`

does not actually produce`range(0, 100, 1)`

in reverse. If you meant to go from`0`

through to`99`

included, then from`99`

back to`0`

, use`range(99, -1, -1)`

.`range(100)`

is the shorter form for`range(0, 100, 1)`

, it is good practice to use that instead. And there is no`range(0, infinity)`

syntax, you'd use`for i in itertools.count():`

perhaps to create an infinite counter, or`while True:`

to create an endless loop.