tut12 zwischenspeichern
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@ -225,4 +225,95 @@ Musterlösung 11 - Wiederholung Types - Functions!
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## Funktionale Programmierung - was ist das?
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-
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- Funktionen sind äquivalent zu Datenobjekten
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- anonyme Funktionen aka Lambdas
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- Closures
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- Programmablauf mit Verkettung und Komposition von Funktionen
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---
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## Funktionen sind Datenobjekte
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- Jede Funktion hat den Datentyp `Callable`
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- Wir können Funktionen wie alle anderen Objekte variabeln zuweisen
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```python
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def add(a: int, b: int) -> int:
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return a + b
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add_but_variable = add
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print(add_but_variable(3, 2)) # 5
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```
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---
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## Anonyme Funktionen - `lambda`
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- Mit dem `lambda` Keyword lassen sich anonyme Funktionen definieren ohne `def`
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- Bietet sich vor allem an für kleine Funktionen und Kompositionen von Funktionen
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```python
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print(reduce(lambda x, y: x + y, [1, 2, 3, 4])) # 10
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```
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- hat als Datentyp auch `Callable`
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```python
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add: Callable[[int, int], int] = lambda x, y: x + y
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```
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---
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## Closures
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- Verkettete Funktionen, bei denen die Variabeln aus vorherigen benutzt werden können
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```python
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def poly(x: float) -> Callable[[float, float], Callable[[float], float]]:
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return lambda a, b: lambda c: a * x ** 2 + b * x + c
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print(poly(3)(2, 3)(5)) # 2 * 3 ** 2 + 3 * 3 + 5 = 32
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```
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- kein wirklich schönes Beispiel, ein besseres ist `compose` für Kompositionen
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---
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## Komposition
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- Verketten von Funktionen
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```python
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def compose[T](*funcs: Callable[[T], T]) -> Callable[[T], T]:
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return reduce(lambda f, g: lambda n: f(g(n)), funcs)
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f: Callable[[int], int] = lambda n: n + 42
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g: Callable[[int], int] = lambda n: n ** 2
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h: Callable[[int], int] = lambda n: n - 3
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print(compose(f, g, h)(0))
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```
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---
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## Higher-Order Functions
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- nehmen eine oder mehrere `Callable` als Argument
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- geben ein `Callable` zurück
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### Higher-Order-Functions - `map`
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- Wendet ein `Callable` auf jedes Element in einem `Iterable` an
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```python
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def map[T, R](func: Callable[[T], R], xs: Iterable[T]) -> Iterable[R]:
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return [func(x) for x in xs]
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numeric_list = list(map(lambda e: int(e), ['1', '2', '3']))
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print(numeric_list) # [1, 2, 3]
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```
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---
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### Higher-Order-Functions - `filter`
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- `filter` verarbeitet Datenstrukturen anhand eines Prädikats (`Callable`)
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- behält nur Elemente die das Prädikat erfüllen
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```python
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def filter[T](predicate: Callable[[T], bool], xs: Iterable[T]) -> Iterable[T]:
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return [x for x in xs if predicate(x)]
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```
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BIN
Tutorium/tut12/slides.pdf
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BIN
Tutorium/tut12/slides.pdf
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@ -5,8 +5,8 @@ def map[T, R](func: Callable[[T], R], xs: Iterable[T]) -> Iterable[R]:
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return [func(x) for x in xs]
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def filter[T](func: Callable[[T], bool], xs: Iterable[T]) -> Iterable[T]:
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return [x for x in xs if func(x)]
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def filter[T](predicate: Callable[[T], bool], xs: Iterable[T]) -> Iterable[T]:
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return [x for x in xs if predicate(x)]
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def reduce[T](func: Callable[[T, T], T], xs: Iterable[T]) -> T:
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@ -35,21 +35,49 @@ def compose[T](*funcs: Callable[[T], T]) -> Callable[[T], T]:
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return reduce(lambda f, g: lambda n: f(g(n)), funcs)
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f: Callable[[int], int] = lambda n: n + 42
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g: Callable[[int], int] = lambda n: n ** 2
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h: Callable[[int], int] = lambda n: n - 3
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def poly(x: float) -> Callable[[float, float], Callable[[float], float]]:
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return lambda a, b: lambda c: a * x ** 2 + b * x + c
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print(compose(f, g, h)(0))
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def main():
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f: Callable[[int], int] = lambda n: n + 42
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g: Callable[[int], int] = lambda n: n ** 2
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h: Callable[[int], int] = lambda n: n - 3
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print(list(filter(lambda e: bool(e), [1, 2, 3, None, 5, 6])))
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print(list(filter(lambda e: not bool(e), [1, 2, 3, None, 5, 6])))
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fhg: Callable[[int], int] = compose(f, g, h)
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print(list(map(lambda e: str(e), [1, 2, 3, 4, 5, 6, "hello_functional"])))
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# f(g(h(0))) <=> ((0 - 3) ** 2) + 42 = 52
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print(fhg(0))
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print(compose(f, g, h)(0))
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print(list(
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filter(lambda e: len(e) > 1,
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map(lambda e: str(e),
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[1, 2, 3, 4, "hello_world"]))))
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print(list(filter(lambda e: bool(e), [1, 2, 3, None, 5, 6])))
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print(list(filter(lambda e: not bool(e), [1, 2, 3, None, 5, 6])))
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print(list(filter(lambda e: isinstance(e, int), [1, 2, 3, "hello"])))
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print(list(flatten([[1, 2, 3], 4, [[5, 6], 7, [8, 9]]])))
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print(list(map(lambda e: str(e), [1, 2, 3, 4, 5, 6, "hello_functional"])))
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print(list(
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filter(lambda e: len(e) > 1,
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map(lambda e: str(e),
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[1, 2, 3, 4, "hello_world"]))))
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print(list(filter(lambda e: isinstance(e, int), [1, 2, 3, "hello"])))
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print(list(flatten([[1, 2, 3], 4, [[5, 6], 7, [8, 9]]])))
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def add(a: int, b: int) -> int:
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return a + b
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add_but_variable: Callable[[int, int], int] = add
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print(add_but_variable(3, 2)) # 5
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add2: Callable[[int, int], int] = lambda x, y: x + y
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print(add2(2, 3))
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print((lambda x, y: x + y)(3, 4))
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print(reduce(lambda x, y: x + y, [1, 2, 3, 4])) # 10
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print(poly(3)(2, 3)(5))
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if __name__ == '__main__':
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main()
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