This question is motivated by me implementing cryptographic algorithms (e.g. SHA-1) in C/C++, writing portable platform-agnostic code, and thoroughly avoiding undefined behavior.

Suppose that a standardized crypto algorithm asks you to implement this:

```
b = (a << 31) & 0xFFFFFFFF
```

where `a`

and `b`

are unsigned 32-bit integers. Notice that in the result, we discard any bits above the least significant 32 bits.

As a first naive approximation, we might assume that `int`

is 32 bits wide on most platforms, so we would write:

```
unsigned int a = (...);
unsigned int b = a << 31;
```

We know this code won't work everywhere because `int`

is 16 bits wide on some systems, 64 bits on others, and possibly even 36 bits. But using `stdint.h`

, we can improve this code with the `uint32_t`

type:

```
uint32_t a = (...);
uint32_t b = a << 31;
```

So we are done, right? That's what I thought for years. ... Not quite. Suppose that on a certain platform, we have:

```
// stdint.h
typedef unsigned short uint32_t;
```

The rule for performing arithmetic operations in C/C++ is that if the type (such as `short`

) is narrower than `int`

, then it gets widened to `int`

if all values can fit, or `unsigned int`

otherwise.

Let's say that the compiler defines `short`

as 32 bits (signed) and `int`

as 48 bits (signed). Then these lines of code:

```
uint32_t a = (...);
uint32_t b = a << 31;
```

will effectively mean:

```
unsigned short a = (...);
unsigned short b = (unsigned short)((int)a << 31);
```

Note that `a`

is promoted to `int`

because all of `ushort`

(i.e. `uint32`

) fits into `int`

(i.e. `int48`

).

But now we have a problem: **shifting non-zero bits left into the sign bit of a signed integer type is undefined behavior**. This problem happened because our `uint32`

was promoted to `int48`

- instead of being promoted to `uint48`

(where left-shifting would be okay).

Here are my questions:

Is my reasoning correct, and is this a legitimate problem in theory?

Is this problem safe to ignore because on every platform the next integer type is double the width?

Is a good idea to correctly defend against this pathological situation by pre-masking the input like this?:

`b = (a & 1) << 31;`

. (This will necessarily be correct on every platform. But this could make a speed-critical crypto algorithm slower than necessary.)

Clarifications/edits:

I'll accept answers for C or C++ or both. I want to know the answer for at least one of the languages.

The pre-masking logic may hurt bit rotation. For example, GCC will compile

`b = (a << 31) | (a >> 1);`

to a 32-bit bit-rotation instruction in assembly language. But if we pre-mask the left shift, it is possible that the new logic is not translated into bit rotation, which means now 4 operations are performed instead of 1.

oneof them and never compile C as C++ or vice versa. – too honest for this site Oct 10 '16 at 18:42`(a << 31) & 0xFFFFFFFF`

does not jibe. The code does a maskafterthe shift. – chux Oct 10 '16 at 18:42`31u`

then`a`

will be promoted to`uint48`

. – user3528438 Oct 10 '16 at 18:45`using my_uint_at_least32 = std::conditional_t<(sizeof(std::uint32_t) < sizeof(unsigned)), unsigned, std::uint32_t>;`

. – Jarod42 Oct 10 '16 at 18:51