some instruction sets are limited to one bit shift per instruction. And some instruction sets allow any number of bits to shift in one instruction, you specify the number of bits. And these are usually one clock cycle on modern processors (modern being an intentionally vague word). See dan04's answer about a barrel shifter, that is the name for one that does more than one bit in one operation. It all boils down to the logic algorithm, each bit in the result is a logic algorithm based on the input. For a single shift right the bit0 logic would be something like if instruction is [shift right] and bit 1 of the input is a 1 then the result is a one else the result is a 0 kind of thing. bit1 is if instruction is [shift right] then bit 1 = bit 2, etc. But the logic equation could just as easily be if the instruction is [shift right] and the amount operand is a 1 and then result bit 0 = shifted input bit 1 if the operand is a 2 then bit 0 = bit 2, and so on. Being asynchronous gates you can do all of this in one clock cycle. Yes it is true the single shift allows for a faster clock cycle, less gates to settle, if all you are comparing is these two flavors of an instruction. Or the alternative is you know that it takes longer to settle so you declare the instruction is 2 or 3 clocks or whatever and the logic counts to 3 then latches the result.

The msp430 for example only has single bit rotate right instructions (because you can perform a single bit shift or a rotate left with another instruction, which I will leave to the reader to figure out).

The arm instruction set allows multi bit both immediate and register based rotates and shifts, arithmetic and logical. I think there is only one actual rotate instruction and the other is an alias. A rotate left 1 is the same as a rotate right 32, you only need a one direction barrel shifter to implement a multi bit rotate.

shl in the x86 allows more than one bit per instruction. but used to take more than one clock.

and so on, you can easily examine any of the instruction sets out there.

The answer to your question is it is not fixed, sometimes it is one operation, one cycle, one instruction. Sometimes it is one instruction multiple clock cycles. Sometimes it is multiple instructions, multiple clock cycles. The compilers often optimize for these sorts of things, say you have a 16 bit register instruction set and there is a swap byte instruction and an and with immediate but only a single bit shift, to shift 8 bits would be 8 shift instruction cycles lets say, or you could swap bytes (one instruction) and then and the lower half to zeros, which might take two instructions or might be a variable word length instruction of two words or it might encode into a single instruction so 8 instruction/clock cycles vs 2 or 3. A shift of nine you do the same thing and add a shift making it 9 clocks vs 3 or 4, that kind of thing. On some it is faster to multiply by 256 than to shift by 8, etc, etc. Each instruction set has its own limitations and tricks.

It is not even a case that most provide multi bit or most limit to single bit. The processors that fall into the "computer" category are probably your x86, arm, powerpc, mips so that would lean toward one operation to shift. Expand to all processors but not necessarily "computers" commonly used today and it shifts the other way, I would say more of them are single bit than multi bit. Multiple operations needed to perform a multi-bit shift.

`int test(int i) { return i << 30; }`

becomes`sall $30, %eax`

– Flexo♦ Jan 31 '12 at 17:12`shl`

and`shr`

allow arbitrary shift counts, but the actual required cpu cycles depends on what you're doing and the CPU itself. For 286's, it's O(n), for 386+, it's O(1). – Marc B Jan 31 '12 at 17:14