Given 32-bit signed integer `num`

, the following expression returns zero if it is negative, or the original unchanged value otherwise:

`(~num >> 31) & num`

This operation is sometimes called *clamping*; values less than zero are **clamped** to zero. To effect clamping on `num`

itself, use the following statement:

`num &= ~num >> 31;`

**Explanation**
Only positive integers (and zero) have `0`

for their **sign bit**, which is the leftmost, or "most-significant bit" (a.ka., "MSB"). Let's consider the 32-bit case. Since bit positions are numbered from left-to-right starting with 0, the sign bit is "bit 31". By flipping this bit and then propagating it to each of the 31 other bit positions, you get a result where either:

- for positive values and zero, all bits are set (
`0xFFFFFFFF`

, `-1`

), or
- for negative values, all bits are cleared (
`0x00000000`

, `0`

).

By masking the original value with this result, you have zeroed out the value, but only if it was negative originally.

**Remarks**

Since `&`

(bitwise-`AND`

) has very low precedence in **C#**, you will usually have to surround these expressions with outer parentheses:

```
((~num >> 31) & num)
```

If `num`

is *unsigned* (e.g., `uint ui`

), you must use a cast to make sure the shift is signed. This is called a **right-arithmetic shift**, and it ensures that the MSB is duplicated into each rightwards shifted position:

```
((int)~ui >> 31) & ui
```

For 64-bit values, shift by 63 bits instead of 31:

```
/* signed */ long v; (~v >> 63) & v
/* unsigned */ ulong ul; ((long)~ul >> 63) & ul
```

As shown, you must use the `~`

(bitwise-`NOT`

) operator to flip the sign bit. If you attempt to use "unary minus" `-`

instead, you will get the wrong answer for value `0x80000000`

because this is one of exactly two integer values that is *not affected by applying the minus sign to it*. Bitwise-`NOT`

, on the other hand, is guaranteed to flip every bit of any/every value. (The other value that can't be negated is zero, which for this particular problem happens to work out correctly either way)

If you're in a rush, here are some tested extension methods, ready to copy/paste.

```
public static int Clamp0(this int v) => v & ~v >> 31;
public static long Clamp0(this long v) => v & ~v >> 63;
```

One hazard with using the methods shown in (5.) is that there's no error or warning if the caller forgets to assign the return value to anything. In **C#7** you can define *by-reference extension methods* which allow for *in-situ* mutation of value-types. Such methods help avoid the aforementioned problem since they can (and accordingly always should) be declared as returning `void`

:

```
public static void RefClamp0(this ref int v) => v &= ~v >> 31;
public static void RefClamp0(this ref long v) => v &= ~v >> 63;
// 'void' ──^ 'ref' ──^ ^── result assigned by callee
```

Call-site examples for the preceding *by-ref* extension method on `int`

:

```
int x = -999;
x.RefClamp0(); // CORRECT, clamps the value of 'x' in-situ; now x == 0
// x = x.RefClamp0(); // NO -- 'void' return enforces correct by-ref usage
// CS0029: Cannot implicitly convert type 'void' to 'int'
// -999.RefClamp0(); // NO -- compiler errors:
// CS1510: A ref or out value must be an assignable variable
// CS0201: Only [expressions] can be used as a statement
```

**Learn more about non-branching code!**

This code example provided above is one of the simplest bit-twiddling examples which demonstrates branchless code. If you're not familiar with it, the term generally refers to a wide variety of micro-optimization techniques which try to minimize conditional branches in user code, in order to reduce misprediction stalls in the CPU pipeline.