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I have to multiply an integer value by 2^31. I have googled it, and it looks like doubles have a range among 2.23e-308 <= |X| <= 1.79e308 when using 64 bits, and a float among 1.18e-38 <= |X| <= 3.40e38.

That's a lot more than what I need. But it doesn't work.

I have this constant value in my header file:

static const float SCALE_FACTOR = 2^-31;

and if then I just do:

float dummy = SCALE_FACTOR;

Then, dummy's value is 11.

I don't know if the problem is assigning a constant value like that, but I don't know how else to write it without losing precision.

Any help?

EDIT:Sorry, stupid question. My MatLab background betrayed me and forgot that ^ is not for exponentiation in C++. I have voted to close.

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closed as too localized by Roman Rdgz, casperOne Nov 14 '12 at 21:49

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^ is the operator for bit-wise exclusive OR. Use 2e-31 to assign a value of 2x10^-31, or pow(2,-31) for 2^-31. –  jarmond Nov 14 '12 at 12:37
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^ is the bitwise exclusive or operator, not the exponentiation operator. –  hvd Nov 14 '12 at 12:37
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Do you want the integer value 2^(31), as the question title and text say, or the fractional value 2^(-31), as the code implies? –  Mike Seymour Nov 14 '12 at 12:57
    
I am rather surprised you got 11 and not -29. –  CashCow Nov 14 '12 at 13:41
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4 Answers

up vote 3 down vote accepted

^ is a bitwise xor operator in C++, not a mathematical exponentiation operator. You have a few alternatives.

  1. Because you're storing the constant in an intrinsically lossy format, a float, you could just work out the base-10 e form literal and use that: perhaps something like 4.6566128730773926e-010 for 2^-31. This is prone to error (I've made one, for example), and isn't necessarily portable between floating point formats.
  2. You can set the constant using a constant expression that can be evaluated at compile time, and use an integer literal: either 0x80000000 or 1UL << 31 for 2^31, or 1.0f / 0x80000000 for 2^-31 for example.

You could use a pow function of some kind to calculate the value at runtime, of course.

Incidentally, if you're using integers, why not just use a long long or other 64bit integral type, instead of a floating point which may well present you with rounding errors? It isn't totally clear from your question whether you are looking at floating point values because you need floating point value ranges, or because you are merely worried about overflowing a 32-bit integer value.

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The e form is for specifying a decimal number; you'd need 31 decimal places to specify 2^(-31) exactly, and even then I wouldn't trust the compiler to give exactly the required value. Hex literals only work for integers. –  Mike Seymour Nov 14 '12 at 12:50
    
(My comment was based on the code implying that the value should be 2^(-31). If it's actually 2^31, as the question title says, then your answer is fine, although you wouldn't use the e form for that value). –  Mike Seymour Nov 14 '12 at 12:59
    
@MikeSeymour if you're dropping the value into a float anyway, why do you need to care about specifying the value precisely? And given the number the OP wants, there's nothing to stop you using a hex literal like this: const float a = 1.0f / 0x80000000;, for example. –  Rook Nov 14 '12 at 13:03
    
@MikeSeymour yeah, I noticed that the original question talks about both 2^31 and 2^-31. Who knows what is actually needed, though! –  Rook Nov 14 '12 at 13:04
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I still don't know why C++ doesn't provide a hexadecimal point for literals like 2 to the power of -31. There is a way to do it in C so why not C++. Also could allow mantissa-exponential form of hexadecimal literals like it does with decimal ones eg 2.X-8 –  CashCow Nov 14 '12 at 13:38
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In your code

static const float SCALE_FACTOR = 2^-31;

the static is superfluous (constants have internal linkage by default), the ^ denotes bitwise XOR, the - is meaningless (at least if you want to "multiply by 2^31" as stated), and float is needlessly a special choice, as opposed to the default floating point type double (which e.g. is the type of a floating point literal such as 3.14).

Also, in C++ reserve shouting ALL UPPERCASE identifiers for macros (the common convention). Using them for constants is a Java-ism. Ironically the Java convention originated with C, where in times past constants had to be expressed as macros.

Instead, therefore write

double const scale_factor = 1uL << 31;

where

  • not explicitly specifying internal linkage (keyword static),

  • using default floating point type double instead of float,

  • not using ALL UPPERCASE identifier (which should be reserved for macros),

  • using left bitshift << to compute power of two, instead of incorrect ^,

  • not adding any meaningless minus sign,

  • using type unsigned long (specified by uL) to be sure to have sufficient range.

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1  
The - isn't meaningless -- it's incorrect and quite meaningful. –  Lightness Races in Orbit Nov 14 '12 at 13:18
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Using them for constants is a Java-ism./which should be reserved for macros That's totally subjective. Plenty of us use caps for compile-time consts. Especially as we don't use macros at all. –  Lightness Races in Orbit Nov 14 '12 at 13:19
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@Alf The static may be redundant, but I can see a coding guidelines requiring it, for reasons of coherence and readability. –  James Kanze Nov 14 '12 at 13:25
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@LightnessRacesinOrbit: you can find a little more information about the rationale for the all caps naming convention for macros in Bjarne Stroustrups FAQ, (stroustrup.com/bs_faq2.html#macro). –  Cheers and hth. - Alf Nov 14 '12 at 13:35
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@James: even in this short single line there are a host of potential conflicts with various coding guidelines. you just happened to notice a single such possibility. for example, a coding guideline may require use of float rather than my recommended double, or using camel case scaleFactor rather than underscore based scale_factor (or indeed, all caps), or writing the const before the type name, or [endless]... there is not necessarily any good rationale for a coding guideline. however, i recommend sutter and alexandrescu's guidelines book, which says: don't fret the small stuff –  Cheers and hth. - Alf Nov 14 '12 at 13:39
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^ is an operator for bitwise XOR, not for raising to power. You need std::pow().

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pow is fine if either the mantissa or exponent is unknown at compile time, but for constants there's no particular reason not to use a suitable floating point literal. –  Rook Nov 14 '12 at 12:40
    
@Rook Only that you cannot specify binary floating point literals (or can you?). –  Christian Rau Nov 14 '12 at 12:44
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You can in C as of C99, but that has not made it into C++. FWIW, gcc accepts it even in C++ mode: 0x1p-31 –  hvd Nov 14 '12 at 12:45
    
@ChristianRau that's a good point, and I stand corrected. There are of course integer literals which can do the job fine in this case! –  Rook Nov 14 '12 at 12:49
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Multiplying by a power of 2 is equivalent to shifting left by that power. To multiply an integer by two to the 31, just shift it:

unsigned long value = whatever;
unsigned long value_times_2_to_the_31 = value << 31;

There's no need for floating-point math here. But just for completeness, to produce a double value of 2 to the 31:

double two_to_the_31 = std::ldexp(1.0, 31);

Note that while the result of the shift expression with a signed type would be formally undefined in some situations, that results from overflowing the integer type; using floating-point math instead doesn't eliminate the overflow, it just puts it into a different part of the code.

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the expression long value_times_2_to_the_31 = value << 31; has formally UB, but in practice, for a conventional 32-bit two's complement long the value 1 produces -2147483648 (due to two's complement). you want an unsigned long there, as in my answer. also, no need for the runtime expression, and the header inclusion for that. –  Cheers and hth. - Alf Nov 14 '12 at 13:50
    
Changed long to unsigned long. –  Pete Becker Nov 14 '12 at 13:52
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