The correct answer is a simple "because the standard (and the docs) say so". But I'm not gonna be cynical because it's obvious that's not what you are after.
In addition to the other answers here, I'll try to relate the infinities to saturating arithmetic.
Other answers have already stated that the reason the comparisons on NaNs result in
true, so I'm not gonna beat a dead horse.
Let's say I have a saturating integer that represents grayscale colors. Why am I using saturating arithmetic? Because anything brighter than white is still white, and anything darker than black is still black (except orange). That means
BLACK - x == BLACK and
WHITE + x == WHITE. Makes sense?
Now, let's say we want to represent those grayscale colors with a (signed) 1s complement 8-bit integer where
BLACK == -127 and
WHITE == 127. Why 1s complement? Because it gives us a signed zero like IEEE 754 floating point. And, because we are using saturating arithmetic,
-127 - x == -127 and
127 + x == 127.
How does this relate to floating point infinities? Replace the integer with floating point,
POSITIVE_INFINITY and what do you get?
NEGATIVE_INFINITY - x == NEGATIVE_INFINITY and
POSITIVE_INFINITY + x == POSITIVE_INFINITY.
Since you used
POSITIVE_INFINITY, I'll use it also. First we need a class to represent our saturating integer-based color; let's call it
SaturatedColor and assume it works like any other integer in Java. Now, let's take your code and replace
double with our own
SaturatedColor a = SaturatedColor.WHITE;
SaturatedColor b = SaturatedColor.WHITE;
As we established above,
WHITE above) is
127, so let's do that here:
SaturatedColor a = 127;
SaturatedColor b = 127;
Now we take the
System.out.println statements you used and replace
b with their value (values?):
System.out.println(127 == 127);
System.out.println(127 < 127);
System.out.println(127 > 127);
It should be obvious what this will print.