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I have the code:

float f = -6;
DWORD d = 7;
signed long long ll = -d * f; //should be 42
std::cout << ll;

But when I compile it (Visual Studio 2012, Windows 7 x64), I see the output:

-25769803776

And the debugger says:

    ll  -25769803776    __int64
    d   7               unsigned long
    f   -6.00000000     float

I don't understand why the result (ll) is not 42: float f and DWORD d have right values in debugger, signed long long have much "better" range and can hold both signed and unsigned values.

Where is my mistake?

Also, how to save (which type to use) the result of multiply by two DWORD or DWORD and float (before each of them there can be a - sign), e.g.:

-f * -f
-f * d
-d * d
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3 Answers 3

up vote 2 down vote accepted

d is a 32bit unsigned integer. Meaning that -d is a very large positive number according to the C standard. For same-size integer calculations, this works fine, because the signed and unsigned values have the same form and -d will indeed be the "correct" form for -6 as an integer.

You can, assuming only lower 31 bits are used, cast it to a signed value. If the top bit is set (use assert((d & 0x80000000) == 0) to check that), then you will need to cast it to a 64-bit value first.

Alternatively, you can add parenthesis to negate the final result, which is in float:

 signed long long ll = -(d * f);

Casting to float will also work, and since the calculation is done in float anyway, the resulting value will be equally precise/imprecise whether you cast d to float or not - the compiler will do that either way.

Here's the code produced by clang in LLVM-IR form:

define i32 @main() #0 {
entry:
  %f = alloca float, align 4
  %d = alloca i32, align 4
  %ll = alloca i64, align 8
  store float -6.000000e+00, float* %f, align 4
  store i32 7, i32* %d, align 4
  %0 = load i32* %d, align 4
  %sub = sub i32 0, %0
  %conv = uitofp i32 %sub to float
  %1 = load float* %f, align 4
  %mul = fmul float %conv, %1
  %conv1 = fptosi float %mul to i64
  store i64 %conv1, i64* %ll, align 8
  ret i32 0
}

Note the uitofp i32 %sub to float - this is making d into a float value.

(Side-comment: I personally would choose 14 & 3 for an example giving 42, but good choice of a result anyway).

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You've negated an unsigned number. Try to do -float(d) * f instead. You should be able to see the effect if you do DWORD e = -d; and examine e in the debugger.

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That's the point! But about float(d) - won't I miss precision? I mean for really big values (near the upper range of DWORD)? I checked that for DWORD d = 4294967200; float f = float(d) I miss 100 (float is 4294967300) - I guess it's acceptable, but it's the maximum difference? –  PolGraphic Mar 15 '14 at 12:30
1  
Then you need to use a signed type which gives enough precision, like the signed long long you use for the final result. -signed long long(d) * f for example. –  KayEss Mar 15 '14 at 12:53
    
Note that casting d to signed long long first won't actually help, as the value is still converted to float after cast - it just converts from a 64-bit integer to a float instead of 32-bit unsigned int, but it's still becomes a float. If you want more bits, use double (and cast d to double). –  Mats Petersson Mar 15 '14 at 13:12

C doesn't pay any attention to the type of variable on the left-hand side of an assignment when it's doing a computation on the right-hand side.

That is, in your example, it only looks at "unsigned long" multiplied by "float" negated with a minus sign, and since the rules say that's done as an unsigned multiplication bit-complement, it will be. Later it will put the result into ll, but that's not related! The computation is done before the assignment, so they're totally separate.

An example which bites every C hacker on the ass at some time or another is this one, using the same types you use in your question:

__int64 x = 1 << 60;

That looks like it should put a number in x that has a 1 bit in its 60'th position, right? (Mathematically, that number would be 2 to the 60th power.) But because a bare 1 is considered an int, which is typically 32 bits wide, 1 << 60 is computed to be 0, because there aren't 60 positions in a 32-bit integer!

"But I'm going to store it in __int64 x," you say. C doesn't care.

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1  
"unsigned long multiplied by float, and since the rules say that's done as an unsigned multiplication" - No –  tommyo Mar 15 '14 at 13:13
    
Thanks, tommyo, you're right and I fixed that bit. –  librik Mar 15 '14 at 21:09

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