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I know, right shifting a negative signed type depends on the implementation, but what if I perform a left shift? For example:

int i = -1;
i << 1;

Is this well-defined?

I think the standard doesn't say about negative value with signed type

if E1 has a signed type and non-negative value, and E1 × 2E2 is representable in the result type, then that is the resulting value; otherwise, the behavior is undefined.

It only clarifies that if the result isn't representable in signed type then the behavior is undefined.

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What part isn't clear? If E1 has a non-negative value and ... otherwise the behavior is undefined. E1 has negative value, therefore the behavior is undefined. It's true that sometimes the standardese could do with some extra brackets to make it entirely clear what an "otherwise" refers to, but here it means "in any situation not already described". It helps when interpreting these things to remember that in any situation where the standard doesn't describe the behavior, then behavior is undefined. So in fact that "otherwise" is formally redundant. – Steve Jessop Dec 7 '11 at 13:21
@SteveJessop: I think the otherwise means if the value is not representable then the behavior is undefined. I'm not sure if this includes E1 with negative value. – Norman Dec 7 '11 at 13:25
@Norman: It does, see R.Marthinho's answer, there is a semicolon, a clear seperator between the condition and the final result. – Xeo Dec 7 '11 at 13:26
Which standard version is that? The wording in C++03 standard ISO/IEC 14882:2003 is different. It says that it must be a bit shift and than only says what is the corresponding numeric value for unsigned type, but does not mention unsigned type at all. Which implies that it's implementation-defined, because the bit pattern is. – Jan Hudec Dec 7 '11 at 13:29
@Jan: the wording is from C++11, which took it from C99. You're right that C89 and C++03 both define the left shift operator as "a bit pattern left-shifted E2 positions", without giving any further definition of what it means to "left-shift" a signed bit pattern. I think the general interpretation of that old text was that if the sign bit gets involved at all, then that's an overflow (UB), rather than that the result must be what you'd expect based on the implementation-defined integer representation. But evidently the old text was considered inadequate, or it wouldn't have been changed. – Steve Jessop Dec 7 '11 at 13:36
up vote 17 down vote accepted

You're not reading that sentence correctly. The standard defines it if: the left operand has a signed type and a non-negative value and the result is representable (and previously in the same paragraph defines it for unsigned types). In all other cases (notice the use of the semicolon in that sentence), i.e, if any of these conditions isn't verified, the behaviour is undefined.

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+1 for better explanation. – Xeo Dec 7 '11 at 13:24
+1 for semicolon – Pubby Dec 7 '11 at 13:26
What if I had a non-negative and I right shift it too many times? int i = 1; i >> 24; is this valid? just confused. – Norman Dec 7 '11 at 15:02
@Norman What do you mean too many times? More bits than an int has? – R. Martinho Fernandes Dec 7 '11 at 15:08
@R.MartinhoFernandes if sizeof(i) > 24, lets say it has 32 bits. If I do i >> 24 then it would be redundant because i has value 1. – Norman Dec 7 '11 at 15:12

otherwise, the behavior is undefined.

This includes the

if E1 has a signed type and non-negative value

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When the C standards were codified, different platforms would do different things when left-shifting negative integers. On some of them, the behavior might trigger implementation-specific traps whose behavior could be outside a program's control, and which could include random code execution. Nonetheless, it was possible that programs written for such platforms might make use of such behavior (a program could e.g. specify that a user would have to do something to configure a system's trap handlers before running it, but the program could then exploit the behavior of the suitably-configured trap handlers).

The authors of the C standard did not want to say that compilers for machines where left-shifting of negative numbers would trap must be modified to prevent such trapping (since programs might potentially be relying upon it), but if left-shifting a negative number is allowed to trigger a trap which could cause any arbitrary behavior (including random code execution) that means that left-shifting a negative number is allowed to do anything whatsoever. Hence Undefined Behavior.

In practice, until about 5 years ago, 99+% of compilers written for a machine that used two's-complement math (meaning 99+% of machines made since 1990) would consistently yield the following behaviors for x<<y and x>>y, to the extent that code reliance upon such behavior was considered no more non-portable than code which assumed char was 8 bits. The C standard didn't mandate such behavior, but any compiler author wanting to be compatible with a wide base of existing code would follow it.

  • if y is a signed type, x << y and x >> y are evaluated as though y was cast to unsigned.
  • if x is type int, x<<y is equivalent to (int)((unsigned)x << y).
  • if x is type int and positive, x>>y equivalent to (unsigned)x >> y. If x is of type int and negative, x>>y is equivalent to `~(~((unsigned)x) >> y).
  • If x is of type long, similar rules apply, but with unsigned long rather than unsigned.
  • if x is an N-bit type and y is greater than N-1, then x >> y and x << y may arbitrarily yield zero, or may act as though the right-hand operand was y % N; they may require extra time proportional to y [note that on a 32-bit machine, if y is negative, that could potentially be a long time, though I only know of one machine which would in practice run more than 256 extra steps]. Compilers were not necessarily consistent in their choice, but would always return one of the indicated values with no other side-effects.

Unfortunately for some reason I can't quite fathom, compiler writers have decided that rather than allowing programmers to indicate what assumptions compilers should use for dead-code removal, compilers should assume that it is impossible to execute any shift whose behavior isn't mandated by the C standard. Thus, given code like the following:

uint32_t shiftleft(uint32_t v, uint8_t n)
  if (n >= 32)
  return v<<n;

a compiler may determine that because the code would engage in Undefined Behavior when n is 32 or larger, the compiler may assume that the if will never return true, and may thus omit the code. Consequently, unless or until someone comes up with a standard for C which restores the classic behaviors and allows programmers to designate what assumptions merit dead code removal, such constructs cannot be recommended for any code that might be fed to a hyper-modern compiler.

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