That depends both on the CPU and compiler. Even if the underlying CPU has arbitrary bit shift with a barrel shifter, this will only happen if the compiler takes advantage of that resource.

Keep in mind that shifting anything outside the width in bits of the data is "undefined behavior" in C and C++. Right shift of signed data is also "implementation defined". Rather than too much concern about speed, be concerned that you are getting the same answer on different implementations.

Quoting from ANSI C section 3.3.7:

3.3.7 Bitwise shift operators

Syntax

```
shift-expression:
additive-expression
shift-expression << additive-expression
shift-expression >> additive-expression
```

Constraints

Each of the operands shall have
integral type.

Semantics

The integral promotions are
performed on each of the operands.
The type of the result is that of the
promoted left operand. If the value
of the right operand is negative or is
greater than or equal to the width in
bits of the promoted left operand, the
behavior is undefined.

The result of E1 << E2 is E1
left-shifted E2 bit positions; vacated
bits are filled with zeros. If E1 has
an unsigned type, the value of the
result is E1 multiplied by the
quantity, 2 raised to the power E2,
reduced modulo ULONG_MAX+1 if E1 has
type unsigned long, UINT_MAX+1
otherwise. (The constants ULONG_MAX
and UINT_MAX are defined in the header
.)

The result of E1 >> E2 is E1
right-shifted E2 bit positions. If E1
has an unsigned type or if E1 has a
signed type and a nonnegative value,
the value of the result is the
integral part of the quotient of E1
divided by the quantity, 2 raised to
the power E2 . If E1 has a signed
type and a negative value, the
resulting value is
implementation-defined.

So:

```
x = y << z;
```

"<<": y × 2^{z} (**undefined** if an overflow occurs);

```
x = y >> z;
```

">>": **implementation-defined for signed** (most often the result of the arithmetic shift: y / 2^{z}).