Why does Clang optimize away the loop in this code

#include <time.h>
#include <stdio.h>

static size_t const N = 1 << 27;
static double arr[N] = { /* initialize to zero */ };

int main()
    clock_t const start = clock();
    for (int i = 0; i < N; ++i) { arr[i] *= 1.0; }
    printf("%u ms\n", (unsigned)(clock() - start) * 1000 / CLOCKS_PER_SEC);

but not the loop in this code?

#include <time.h>
#include <stdio.h>

static size_t const N = 1 << 27;
static double arr[N] = { /* initialize to zero */ };

int main()
    clock_t const start = clock();
    for (int i = 0; i < N; ++i) { arr[i] += 0.0; }
    printf("%u ms\n", (unsigned)(clock() - start) * 1000 / CLOCKS_PER_SEC);

(Tagging as both C and C++ because I would like to know if the answer is different for each.)

  • 2
    Which optimization flags are currently active? Oct 22, 2015 at 3:40
  • 1
    @IwillnotexistIdonotexist: I just used -O3, I don't know how to check what that activates though.
    – user541686
    Oct 22, 2015 at 3:42
  • 2
    It would be interesting to see what happens if you add -ffast-math to the command line.
    – plugwash
    Oct 22, 2015 at 14:47
  • static double arr[N] is not permitted in C; const variables do not count as constant expressions in that language
    – M.M
    Oct 23, 2015 at 7:08
  • 1
    [Insert snarky comment about how C is not C++, even though you already called it out.] Oct 23, 2015 at 10:40

2 Answers 2


The IEEE 754-2008 Standard for Floating-Point Arithmetic and the ISO/IEC 10967 Language Independent Arithmetic (LIA) Standard, Part 1 answer why this is so.

IEEE 754 § 6.3 The sign bit

When either an input or result is NaN, this standard does not interpret the sign of a NaN. Note, however, that operations on bit strings — copy, negate, abs, copySign — specify the sign bit of a NaN result, sometimes based upon the sign bit of a NaN operand. The logical predicate totalOrder is also affected by the sign bit of a NaN operand. For all other operations, this standard does not specify the sign bit of a NaN result, even when there is only one input NaN, or when the NaN is produced from an invalid operation.

When neither the inputs nor result are NaN, the sign of a product or quotient is the exclusive OR of the operands’ signs; the sign of a sum, or of a difference x − y regarded as a sum x + (−y), differs from at most one of the addends’ signs; and the sign of the result of conversions, the quantize operation, the roundTo-Integral operations, and the roundToIntegralExact (see 5.3.1) is the sign of the first or only operand. These rules shall apply even when operands or results are zero or infinite.

When the sum of two operands with opposite signs (or the difference of two operands with like signs) is exactly zero, the sign of that sum (or difference) shall be +0 in all rounding-direction attributes except roundTowardNegative; under that attribute, the sign of an exact zero sum (or difference) shall be −0. However, x + x = x − (−x) retains the same sign as x even when x is zero.

The Case of Addition

Under the default rounding mode (Round-to-Nearest, Ties-to-Even), we see that x+0.0 produces x, EXCEPT when x is -0.0: In that case we have a sum of two operands with opposite signs whose sum is zero, and §6.3 paragraph 3 rules this addition produces +0.0.

Since +0.0 is not bitwise identical to the original -0.0, and that -0.0 is a legitimate value that may occur as input, the compiler is obliged to put in the code that will transform potential negative zeros to +0.0.

The summary: Under the default rounding mode, in x+0.0, if x

  • is not -0.0, then x itself is an acceptable output value.
  • is -0.0, then the output value must be +0.0, which is not bitwise identical to -0.0.

The Case of Multiplication

Under the default rounding mode, no such problem occurs with x*1.0. If x:

  • is a (sub)normal number, x*1.0 == x always.
  • is +/- infinity, then the result is +/- infinity of the same sign.
  • is NaN, then according to

    IEEE 754 § 6.2.3 NaN Propagation

    An operation that propagates a NaN operand to its result and has a single NaN as an input should produce a NaN with the payload of the input NaN if representable in the destination format.

    which means that the exponent and mantissa (though not the sign) of NaN*1.0 are recommended to be unchanged from the input NaN. The sign is unspecified in accordance with §6.3p1 above, but an implementation may specify it to be identical to the source NaN.

  • is +/- 0.0, then the result is a 0 with its sign bit XORed with the sign bit of 1.0, in agreement with §6.3p2. Since the sign bit of 1.0 is 0, the output value is unchanged from the input. Thus, x*1.0 == x even when x is a (negative) zero.

The Case of Subtraction

Under the default rounding mode, the subtraction x-0.0 is also a no-op, because it is equivalent to x + (-0.0). If x is

  • is NaN, then §6.3p1 and §6.2.3 apply in much the same way as for addition and multiplication.
  • is +/- infinity, then the result is +/- infinity of the same sign.
  • is a (sub)normal number, x-0.0 == x always.
  • is -0.0, then by §6.3p2 we have "[...] the sign of a sum, or of a difference x − y regarded as a sum x + (−y), differs from at most one of the addends’ signs;". This forces us to assign -0.0 as the result of (-0.0) + (-0.0), because -0.0 differs in sign from none of the addends, while +0.0 differs in sign from two of the addends, in violation of this clause.
  • is +0.0, then this reduces to the addition case (+0.0) + (-0.0) considered above in The Case of Addition, which by §6.3p3 is ruled to give +0.0.

Since for all cases the input value is legal as the output, it is permissible to consider x-0.0 a no-op, and x == x-0.0 a tautology.

Value-Changing Optimizations

The IEEE 754-2008 Standard has the following interesting quote:

IEEE 754 § 10.4 Literal meaning and value-changing optimizations


The following value-changing transformations, among others, preserve the literal meaning of the source code:

  • Applying the identity property 0 + x when x is not zero and is not a signaling NaN and the result has the same exponent as x.
  • Applying the identity property 1 × x when x is not a signaling NaN and the result has the same exponent as x.
  • Changing the payload or sign bit of a quiet NaN.
  • [...]

Since all NaNs and all infinities share the same exponent, and the correctly rounded result of x+0.0 and x*1.0 for finite x has exactly the same magnitude as x, their exponent is the same.


Signaling NaNs are floating-point trap values; They are special NaN values whose use as a floating-point operand results in an invalid operation exception (SIGFPE). If a loop that triggers an exception were optimized out, the software would no longer behave the same.

However, as user2357112 points out in the comments, the C11 Standard explicitly leaves undefined the behaviour of signaling NaNs (sNaN), so the compiler is allowed to assume they do not occur, and thus that the exceptions that they raise also do not occur. The C++11 standard omits describing a behaviour for signaling NaNs, and thus also leaves it undefined.

Rounding Modes

In alternate rounding modes, the permissible optimizations may change. For instance, under Round-to-Negative-Infinity mode, the optimization x+0.0 -> x becomes permissible, but x-0.0 -> x becomes forbidden.

To prevent GCC from assuming default rounding modes and behaviours, the experimental flag -frounding-math can be passed to GCC.


Clang and GCC, even at -O3, remains IEEE-754 compliant. This means it must keep to the above rules of the IEEE-754 standard. x+0.0 is not bit-identical to x for all x under those rules, but x*1.0 may be chosen to be so: Namely, when we

  1. Obey the recommendation to pass unchanged the payload of x when it is a NaN.
  2. Leave the sign bit of a NaN result unchanged by * 1.0.
  3. Obey the order to XOR the sign bit during a quotient/product, when x is not a NaN.

To enable the IEEE-754-unsafe optimization (x+0.0) -> x, the flag -ffast-math needs to be passed to Clang or GCC.

  • 2
    Caveat: what if it is a signaling NaN? (I actually thought that might have been the reason somehow, but I didn't really know how, so I asked.)
    – user541686
    Oct 22, 2015 at 4:39
  • 6
    @Mehrdad: Annex F, the (optional) part of the C standard that specifies C adherence to IEEE 754, explicitly does not cover signaling NaNs. (C11 F.2.1., first line: "This specification does not define the behavior of signaling NaNs.") Implementations that declare conformance to Annex F remain free to do what they want with signaling NaNs. The C++ standard has its own handling of IEEE 754, but whatever it is (I'm not familiar), I doubt it specifies signaling NaN behavior either. Oct 22, 2015 at 6:06
  • 2
    @Mehrdad: sNaN invokes undefined behavior according to the standard (but it's probably well defined by the platform) so the compiler squashing here is allowed.
    – Joshua
    Oct 22, 2015 at 15:33
  • 2
    Oh look, a question that legitimately applies to both C and C++ that is accurately answered for both languages by a reference to a single standard. Will this make people less likely to complain about questions tagged with both C and C++, even when the question deals with a language commonality? Sadly, I think not. Oct 28, 2015 at 19:05
  • 2
    When you say that x-0. is the same as x, it would be worth specifying very clearly that this is not true when rounding round, since 0.-0. is -0. in that case (and indeed gcc refuses to simplify if you use -frounding-math). May 14, 2017 at 6:31

x += 0.0 isn't a NOOP if x is -0.0. The optimizer could strip out the whole loop anyway since the results aren't used, though. In general, it's hard to tell why an optimizer makes the decisions it does.

  • 2
    I actually posted this after I had just read why x += 0.0 is not a no-op, yet I thought that probably isn't the reason because the entire loop should be optimized out either way. I can buy it, it's just not as entirely convincing as I was hoping...
    – user541686
    Oct 22, 2015 at 3:47
  • Given the propensity for object-oriented languages to produce side-effects, I would imagine that it would be difficult to be sure the optimizer isn't changing actual behavior. Oct 22, 2015 at 3:50
  • Could be the reason, since with long long the optimization is in effect (did it with gcc, which behaves the same for double at least)
    – Déjà vu
    Oct 22, 2015 at 3:57
  • 2
    @ringø: long long is an integral type, not an IEEE754 type.
    – MSalters
    Oct 22, 2015 at 15:41
  • 1
    What about x -= 0, is it the same? Oct 23, 2015 at 8:56

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