Getting this right in all corner cases is a bit tricky. If I have to solve such a task, I'd usually start with a naive implementation that I can be pretty sure will be correct and only then start implementing an optimized version. While doing so, I can always compare against the naive approach to validate my results.

The naive approach is to start with 1 and multiply / divide it with / by 2 until we have bracketed the absolute value of the input. Then, we'll output the nearer of the boundaries. It's actually a bit more complicated: If the value is a NaN or infinity, it requires special treatment.

Here is the code:

```
public static double getClosestPowerOf2Loop(final double x) {
final double absx = Math.abs(x);
double prev = 1.0;
double next = 1.0;
if (Double.isInfinite(x) || Double.isNaN(x)) {
return x;
} else if (absx < 1.0) {
do {
prev = next;
next /= 2.0;
} while (next > absx);
} else if (absx > 1.0) {
do {
prev = next;
next *= 2.0;
} while (next < absx);
}
if (x < 0.0) {
prev = -prev;
next = -next;
}
return (Math.abs(next - x) < Math.abs(prev - x)) ? next : prev;
}
```

I hope the code will be clear without further explanation. Since Java 8, you can use `!Double.isFinite(x)`

as a replacement for `Double.isInfinite(x) || Double.isNaN(x)`

.

Let's see for an optimized version. As other answers have already suggested, we should probably look at the bit representation. Java requires floating point values to be represented using IEE 754. In that format, numbers in `double`

(64 bit) precision are represented as

- 1 bit sign,
- 11 bits exponent and
- 52 bits mantissa.

We will special-case NaNs and infinities (which are represented by special bit patterns) again. However, there is yet another exception: The most significant bit of the mantissa is *implicitly* 1 and not found in the bit pattern – except for very small numbers where a so-called *subnormal* representation us used where the most significant digit is not the most significant bit of the mantissa. Therefore, for normal numbers we will simply set the mantissa's bits to all 0 but for subnormals, we convert it to a number where none but the most significant 1 bit is preserved. This procedure always rounds towards zero so to get the other bound, we simply multiply by 2.

Let's see how this all works together:

```
public static double getClosestPowerOf2Bits(final double x) {
if (Double.isInfinite(x) || Double.isNaN(x)) {
return x;
} else {
final long bits = Double.doubleToLongBits(x);
final long signexp = bits & 0xfff0000000000000L;
final long mantissa = bits & 0x000fffffffffffffL;
final long mantissaPrev = Math.abs(x) < Double.MIN_NORMAL
? Long.highestOneBit(mantissa)
: 0x0000000000000000L;
final double prev = Double.longBitsToDouble(signexp | mantissaPrev);
final double next = 2.0 * prev;
return (Math.abs(next - x) < Math.abs(prev - x)) ? next : prev;
}
}
```

I'm note entirely sure I have covered all corner cases but the following tests do run:

```
public static void main(final String[] args) {
final double[] values = {
5.0, 4.1, 3.9, 1.0, 0.0, -0.1, -8.0, -8.1, -7.9,
0.9 * Double.MIN_NORMAL, -0.9 * Double.MIN_NORMAL,
Double.NaN, Double.MAX_VALUE, Double.MIN_VALUE,
Double.NEGATIVE_INFINITY, Double.POSITIVE_INFINITY,
};
for (final double value : values) {
final double powerL = getClosestPowerOf2Loop(value);
final double powerB = getClosestPowerOf2Bits(value);
System.out.printf("%17.10g --> %17.10g %17.10g%n",
value, powerL, powerB);
assert Double.doubleToLongBits(powerL) == Double.doubleToLongBits(powerB);
}
}
```

Output:

```
5.000000000 --> 4.000000000 4.000000000
4.100000000 --> 4.000000000 4.000000000
3.900000000 --> 4.000000000 4.000000000
1.000000000 --> 1.000000000 1.000000000
0.000000000 --> 0.000000000 0.000000000
-0.1000000000 --> -0.1250000000 -0.1250000000
-8.000000000 --> -8.000000000 -8.000000000
-8.100000000 --> -8.000000000 -8.000000000
-7.900000000 --> -8.000000000 -8.000000000
2.002566473e-308 --> 2.225073859e-308 2.225073859e-308
-2.002566473e-308 --> -2.225073859e-308 -2.225073859e-308
NaN --> NaN NaN
1.797693135e+308 --> 8.988465674e+307 8.988465674e+307
4.900000000e-324 --> 4.900000000e-324 4.900000000e-324
-Infinity --> -Infinity -Infinity
Infinity --> Infinity Infinity
```

How about performance?

I have run the following benchmark

```
public static void main(final String[] args) {
final Random rand = new Random();
for (int i = 0; i < 1000000; ++i) {
final double value = Double.longBitsToDouble(rand.nextLong());
final double power = getClosestPowerOf2(value);
}
}
```

where `getClosestPowerOf2`

is to be replaced by either `getClosestPowerOf2Loop`

or `getClosestPowerOf2Bits`

. On my laptop, I get the following results:

`getClosestPowerOf2Loop`

: 2.35 s
`getClosestPowerOf2Bits`

: 1.80 s

Was that really worth the effort?

`12345.4375`