This article shows how you can write a Y combinator in Java:

```
package com.google.functional;
import com.google.common.base.Function;
import junit.framework.TestCase;
public class YCFun extends TestCase {
public static interface BranchType<F, T> extends
Function<BranchType<F, T>, Function<F, T>> {
}
public static <F, T> Function<Function<Function<F, T>,
Function<F, T>>, Function<F, T>> y() {
return new Function<Function<Function<F, T>, Function<F, T>>,
Function<F, T>>() {
public Function<F, T> apply(
final Function<Function<F, T>, Function<F, T>> f) {
return new BranchType<F, T>() {
public Function<F, T> apply(final BranchType<F, T> x) {
return f.apply(new Function<F, T>() {
public T apply(F y) {
return x.apply(x).apply(y);
}
});
}
}.apply(new BranchType<F, T>() {
public Function<F, T> apply(final BranchType<F, T> x) {
return f.apply(new Function<F, T>() {
public T apply(F y) {
return x.apply(x).apply(y);
}
});
}
});
}
};
}
// To get proper type inference
public static <F, T> Function<F, T> yapply(
final Function<Function<F, T>, Function<F, T>> f) {
return YCFun.<F, T> y().apply(f);
}
public void testFactorial() {
Function<Integer, Integer> factorial =
yapply(new Function<Function<Integer, Integer>,
Function<Integer, Integer>>() {
public Function<Integer, Integer> apply(
final Function<Integer, Integer> f) {
return new Function<Integer, Integer>() {
public Integer apply(Integer i) {
if (i <= 0) {
return 1;
} else {
return f.apply(i - 1) * i;
}
}
};
}
});
assertEquals(720, factorial.apply(6).intValue());
}
}
```

`Y`

function is supposed to be completely standalone, being able to function (pun intended) without referring to any external symbols, including the symbol`Y`

. It'd be cool to see a version in F# that does just that. :-D – Chris Jester-Young Jan 5 '10 at 13:01`let rec...`

: stackoverflow.com/questions/1998407/… . It turns out you can't write`Y`

in a statically typed language without jumping through a lot of hoops. – Juliet Jan 6 '10 at 18:58