I was reading about floating-point NaN values in the Java Language Specification (I'm boring). A 32-bit
float has this bit format:
seee eeee emmm mmmm mmmm mmmm mmmm mmmm
s is the sign bit,
e are the exponent bits, and
m are the mantissa bits. A NaN value is encoded as an exponent of all 1s, and the mantissa bits are not all 0 (which would be +/- infinity). This means that there are lots of different possible NaN values (having different
m bit values).
On this, JLS §4.2.3 says:
IEEE 754 allows multiple distinct NaN values for each of its single and double floating-point formats. While each hardware architecture returns a particular bit pattern for NaN when a new NaN is generated, a programmer can also create NaNs with different bit patterns to encode, for example, retrospective diagnostic information.
The text in the JLS seems to imply that the result of, for example,
0.0/0.0, has a hardware-dependent bit pattern, and depending on whether that expression was computed as a compile time constant, the hardware it is dependent on might be the hardware the Java program was compiled on or the hardware the program was run on. This all seems very flaky if true.
I ran the following test:
System.out.println(Integer.toHexString(Float.floatToRawIntBits(0.0f/0.0f))); System.out.println(Integer.toHexString(Float.floatToRawIntBits(Float.NaN))); System.out.println(Long.toHexString(Double.doubleToRawLongBits(0.0d/0.0d))); System.out.println(Long.toHexString(Double.doubleToRawLongBits(Double.NaN)));
The output on my machine is:
7fc00000 7fc00000 7ff8000000000000 7ff8000000000000
The output shows nothing out of the expected. The exponent bits are all 1. The upper bit of the mantissa is also 1, which for NaNs apparently indicates a "quiet NaN" as opposed to a "signalling NaN" (https://en.wikipedia.org/wiki/NaN#Floating_point). The sign bit and the rest of the mantissa bits are 0. The output also shows that there was no difference between the NaNs generated on my machine and the constant NaNs from the Float and Double classes.
My question is, is that output guaranteed in Java, regardless of the CPU of the compiler or VM, or is it all genuinely unpredictable? The JLS is mysterious about this.
If that output is guaranteed for
0.0/0.0, are there any arithmetic ways of producing NaNs that do have other (possibly hardware-dependent?) bit patterns? (I know
longBitsToDouble can encode other NaNs, but I'd like to know if other values can occur from normal arithmetic.)
A followup point: I've noticed that Float.NaN and Double.NaN specify their exact bit pattern, but in the source (Float, Double) they are generated by
0.0/0.0. If the result of that division is really dependent on the hardware of the compiler, it seems like there is a flaw there in either the spec or the implementation.