Why use only the lower five bits of the shift operand when shifting a 32-bit value? (e.g. (UInt32)1 << 33 == 2)

Consider the following code:

``````UInt32 val = 1;
UInt32 shift31 = val << 31;                    // shift31  == 0x80000000
UInt32 shift32 = val << 32;                    // shift32  == 0x00000001
UInt32 shift33 = val << 33;                    // shift33  == 0x00000002
UInt32 shift33a = (UInt32)((UInt64)val << 33); // shift33a == 0x00000000
``````

It doesn't generate a warning (about using a shift greater than 32) so it must be an expected behavior.

The code that actually gets put out to the generated assembly (or at least Reflector's interpretation of the code) is

`````` uint val = 1;
uint shift31 = val << 0x1f;
uint shift32 = val;
uint shift33 = val << 1;
uint shift33a = val << 0x21;
``````

The IL (again, using Reflector) is

``````L_0000: nop
L_0001: ldc.i4.1
L_0002: stloc.0
L_0003: ldloc.0
L_0004: ldc.i4.s 0x1f
L_0006: shl
L_0007: stloc.1
L_0008: ldloc.0
L_0009: stloc.2
L_000a: ldloc.0
L_000b: ldc.i4.1
L_000c: shl
L_000d: stloc.3
L_000e: ldloc.0
L_000f: conv.u8
L_0010: ldc.i4.s 0x21
L_0012: shl
L_0013: conv.u4
L_0014: stloc.s shift33a
``````

I understand what is going on (it's described in MSDN); when the code is compiled, only the lower 5 bits are being used when shifting a 32-bit value... I'm curious as to why this happens.

(The way `shift33a` comes out also makes me think that something isn't quite right with Reflector, as their c# presentation of the IL will compile to something different)

The question(s):

• Why are only the lower 5 bits of "the value to shift by" used?
• If "it doesn't make sense to shift more than 31 bits", why isn't there a warning?
• Is this a backwards compatilbility thing (i.e. is this what programmers "expect" to happen)?
• Am I correct that the underlying IL can do shifts of more than 31 bits (as in `L_0010: ldc.i4.s 0x21`) but the compiler is trimming the values?
-
Not even the specification gives insight on the "why". You may try asking C# compiler guys like Eric Lippert. –  Joey Mar 13 '09 at 21:52
@Johannes: Yeah, I was just wondering if someone had a use case or something for why it makes sense to behave this way :-/ –  Daniel LeCheminant Mar 13 '09 at 21:57
You should never trust Reflector. I have spent hours chasing bugs, because I trusted the output. The IL is normally the most reliable, but I have had occasions that even didn't go well. Try ILDASM instead. –  leppie Mar 13 '09 at 22:50
@leppie: Yeah, that's why I posted the IL as well :-] –  Daniel LeCheminant Mar 13 '09 at 22:52

It basically boils down to the way the x86 handles the arithmetic shift opcodes: it only uses the bottom 5 bits of the shift count. See the 80386 programming guide, for example. In C/C++, it's technically undefined behavior to do a bit shift by more than 31 bits (for a 32-bit integer), going with the C philosophy of "you don't pay for what you don't need". From section 6.5.7, paragraph 3 of the C99 standard:

The integer 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 of the promoted left operand, the behavior is undefined.

This allows compilers to omit a single shift instruction on x86 for shifts. 64-bit shifts cannot be done in one instruction on x86. They use the SHLD/SHRD instructions plus some additional logic. On x86_64, 64-bit shifts can be done in one instruction.

For example, gcc 3.4.4 emits the following assembly for a 64-bit left-shift by an arbitrary amount (compiled with `-O3 -fomit-frame-pointer`):

``````uint64_t lshift(uint64_t x, int r)
{
return x << r;
}

_lshift:
movl    12(%esp), %ecx
movl    4(%esp), %eax
movl    8(%esp), %edx
shldl   %cl,%eax, %edx
sall    %cl, %eax
testb   \$32, %cl
je      L5
movl    %eax, %edx
xorl    %eax, %eax
L5:
ret
``````

Now, I'm not very familiar with C#, but I'm guessing it has a similar philosophy -- design the language to allow it to be implemented as efficiently as possible. By specifying that shift operations only use the bottom 5/6 bits of the shift count, it permits the JIT compiler to compile the shifts as optimally as possible. 32-bit shifts, as well as 64-bit shifts on 64-bit systems, can get JIT compiled into a single opcode.

If C# were ported to a platform that had different behavior for its native shift opcodes, then this would actually incur an extra performance hit -- the JIT compiler would have to ensure that the standard is respected, so it would have to add extra logic to make sure only the bottom 5/6 bits of the shift count were used.

-
Then what is the explanation for shift33a? Is this a backwards compatibility thing? –  Daniel LeCheminant Mar 13 '09 at 21:46
I doubt C#, being a CLR language, should pay much attention to how x68 behaves. Sure, it's the only platform it was officially supported on, but still, a VM doesn't need much compat to existing processors. –  Joey Mar 13 '09 at 21:49
I see nothing in ISO C99 (draft) about bitshifts >31 being undefined, nor do I see why that would be the case. C is (in)famously wordsize agnostic. –  Ken Mar 13 '09 at 22:06
The IL appears to be able to do shifts of more than 31 bits (this was the case for shift33a, which became `L_0010: ldc.i4.s 0x21`, which had a result of 0) –  Daniel LeCheminant Mar 13 '09 at 22:43

I wrote this simple test in C (gcc, linux), and got similar results. What is interesting though, is that the constant defines for over shifting were turned into zero instead of wrapping around. It did give a warning about those, so at least there was some recognition that it was an "incorrect" thing to do.

``````#include <stdio.h>

unsigned int is0 = 1 << 31;
unsigned int is1 = 1 << 32;
unsigned int is2 = 1 << 33;

int main()
{
unsigned int loopy = 0;
int x = 0;
printf("0x%08X\n", is0);
printf("0x%08X\n", is1);
printf("0x%08X\n", is2);

for (x = 0; x < 35; ++x)
{
loopy = 1 << x;
printf("%02d 0x%08X\n", x,loopy);
}

return 0;
}
``````

Here are the results:

``````0x80000000
0x00000000
0x00000000
00 0x00000001
01 0x00000002
02 0x00000004
03 0x00000008
04 0x00000010
05 0x00000020
06 0x00000040
07 0x00000080
08 0x00000100
09 0x00000200
10 0x00000400
11 0x00000800
12 0x00001000
13 0x00002000
14 0x00004000
15 0x00008000
16 0x00010000
17 0x00020000
18 0x00040000
19 0x00080000
20 0x00100000
21 0x00200000
22 0x00400000
23 0x00800000
24 0x01000000
25 0x02000000
26 0x04000000
27 0x08000000
28 0x10000000
29 0x20000000
30 0x40000000
31 0x80000000
32 0x00000001
33 0x00000002
34 0x00000004
``````
-
This code has undefined meaning. Shifting by >= 32 bits is undefined. For this reason your program does not show anything reliably. –  usr Jul 19 '12 at 16:04

Unit32 overflows at 32 bits, that is defined in the spec. What are you expecting?

The CLR does not define a left shift with overflow detection operator(1). If you need that kind of facility you need to check for yourself.

(1) The C# compiler might cast it to long, but I am not sure.

-
Well, intuitively, I would expect that left shifting 1 32 bits to the left would come out 0 (because of the overflow), and not 1. –  Daniel LeCheminant Mar 13 '09 at 22:38
It's undefined, the CLR can do what it wants. I dont make the rules... :) –  leppie Mar 13 '09 at 22:45
Yeah, looking at download.microsoft.com/download/D/C/1/…: If the “Shift-By” operand is larger than the width of the “To-Be-Shifted” operand, then the results are unspecified." –  Daniel LeCheminant Mar 13 '09 at 22:51
I have been looking through you question again, but I cannot understand what you mean by 5 bits, where do you get that from? –  leppie Mar 13 '09 at 22:55
I mean that only the lower 5 bits of the shift amount are actually used when determining how many bits to shift the value by. So a shift of 33 on a 32-bit value is effectively a shift of 1 (because the lower five bits of 33 == 00001) –  Daniel LeCheminant Mar 13 '09 at 23:09