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Let's say I want to write a function that does the following:

Given a number N,
when N is rounded to D1 digits
does the result include more than D2 decimal places, not counting trailing zeroes?

For example, say N is .01001, D1 is 4, and D2 is 2. The question becomes, does .0100 include more than 2 decimal places, not counting trailing zeroes? And the answer is "no". But if N was .00101, the answer would be "yes".

I'm looking for an efficient way to do this using standard C library functions, taking into account the limitations of floating-point numbers.

An example of my intended usage: show a number using four digits if necessary, but otherwise show it using two digits.

(This is not a homework question -- this is a result of being a professional programmer who didn't do these kinds of homework questions when he was a student.)

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This is actually an interesting and difficult problem. If it were homework, I wonder what kind of answer an instructor would be looking for. The only correct answer I could envision CS students being able to come up with is the one I gave. –  R.. Sep 22 '10 at 0:46

5 Answers 5

up vote 4 down vote accepted

The only easy way to do this with the standard library is to use snprintf (or just sprintf) with the right format, and then count the zeros yourself. Correctly computing the decimal representation of a (binary) floating point number is a very very difficult task that you don't want to try to do yourself, and you have near-zero chance of writing a correct version that's faster than your standard library one.

I hope I got this right; it's untested:

double n; /* the number N */
int d1, d2; /* the parameters d1 and d2 */
char s[MAXLEN], *z;
snprintf(s, sizeof s, "%.*f", d1, n);
for (z=s+strlen(s)-1; *z==0; z--);
if (strlen(++z)<d1-d2) puts("yes");
else puts("no");

Edit: As noted by ssianky, snprintf may have limitations on the precision it prints. Actually the C standard allows pretty much any floating point operation to give the wrong result for no reason whatsoever as long as the implementation documents as such, but IEEE behavior is encouraged, and POSIX additionally requires correctly rounded results up to DECIMAL_DIG places, but allows implementations to print nonsense (for example all zeros) after printing sufficiently many places to uniquely determine the actual floating point value. So to make a long story short, if d1 is reasonably large, or if your platform is pathological, snprintf-based approaches might not give the right answer. (In practice they'll give the right answer on GNU systems and the wrong answer on Microsoft systems.)

If you care about this shortcoming and want correct results for any value of d1, you'll have to implement exact float-to-decimal code yourself. Loops that involve multiplying a floating point value repeatedly by 10 will not suffice for this.

Edit 2: Looking at the OP's "intended usage", using snprintf seems like a no-brainer. If you want to print the value to begin with and are just trying to decide how many decimal places to use, just print it to a string and then chop off the trailing zeros before displaying it. In fact, the %g printf format specifier might even do what the OP wants already...

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Thanks -- I've enjoyed reading the answers and discussion. I was expecting the solution to be a mathematical one, but I think you're right that chopping off the zeros is the best approach. –  JW. Sep 26 '10 at 2:13

You can first multiply your number by 10^D1 and round it to the nearest integer, then check if it's divisible by 10^D2. There are a handful of rounding functions to choose from that will round up/down/away from zero/etc., so be sure to check that you're using the one you want.

The function below is written so that it is small and self-contained, but a production implementation should use a lookup table for the powers of ten as indicated in the comment lines. This will yield faster performance and avoid error accumulating in the floating-point product.

int f (double N, unsigned int D1, unsigned int D2)
{
   int i, n_mult_round, ten_d2;
   /* instead of the loop below, a real implementation should use */
   /* N *= dbl_powers_of_ten[D1]; */
   /* where dbl_powers_of_ten is a double array containing powers of ten */
   for (i = 0; i < D1; ++i) {
      N *= 10.0;
   }
   n_mult_round = (int) round (N);
   /* instead of the loop below, a real implementation should use */
   /* ten_d2 = int_powers_of_ten[D2]; */
   /* where int_powers_of_ten is an int array containing powers of ten */
   ten_d2 = 1;
   for (i = 0; i < D2; ++i) {
      ten_d2 *= 10;
   }
   if ( n_mult_round % ten_d2 == 0 ) {
      return ( 1 );
   }
   else {
      return ( 0 );
   }
}
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Multiplication by powers of 10 is a lossy operation for floating point numbers - multiplication by 10^n destroys 2*n bits of precision. This could very well cause incorrect results. –  R.. Sep 22 '10 at 0:43
2  
@R.. Are you sure? That implies that multiplying a 32-bit float by 10^16 gives complete garbage. –  Philip Starhill Sep 22 '10 at 0:57
    
@Philip: Try (1.0+DBL_EPSILON)*10.0 - make sure the result gets stored to memory and read back so you don't get excess precision, though. You should get 10.0. Then try multiplying some numbers like 1.0000000123 by large powers of 10 and see what happens. –  R.. Sep 22 '10 at 1:04
    
@R.. He's not disputing whether multiplication causes a loss of precision. However, your claim as to the 'rate' of loss is ludicrous! Multiplying by a power of 10 primarily affects the exponent. The only reason there is any loss at all is because of the imprecise conversion between base-10, and base-2 for the mantissa. –  Craig Young Sep 22 '10 at 5:20
    
+1 Given the intent of the question (to decide on 2 vs 4 decimal representation), this solution should be perfectly acceptable. –  Craig Young Sep 22 '10 at 5:24
  1. Format it as a string to the max precision.
  2. Remove zeros from the right until you reach the min precision.

Here's an unsafe implementation to get you started:

char buff[20]; /* make as big as necessary */
int maxPrecision = 4;
int minPrecision = 2;

sprintf(buff, "%.*f", maxPrecision, myFloat);

char *p = buff + (strlen(buff) - 1);
char *punct = strchr(buff, ".");

/* remove trailing zeros until we reach minPrecision */
while (*p == '0' && p > (punct + minPrecision))
    *p-- = 0; 
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Don't construct a format string at runtime for this. RTFM about the * character in printf format strings. –  R.. Sep 22 '10 at 0:41
1  
@R: no need to use language...after all, the answer wasn't wrong, just sub-optimal. –  egrunin Sep 22 '10 at 1:49
    
Sorry, bad habit. RTFM is just my notation for RTM. :-) –  R.. Sep 22 '10 at 4:30

What about this? fmod should return the decimals after the specified number of decimal places, so we can compare those two numbers to see if they're equal.

int needsD1Decimals(float N, int D1, int D2) {
    float pow1 = pow(0.1f, D1); // 0.0001
    float pow2 = pow(0.1f, D2); // 0.01
    float mod1 = fmod(N, pow1); // 0.00001
    float mod2 = fmod(N, pow2); // 0.00001
    if (fabs(mod1 - mod2) > (pow1 / 2)) { // > 0.00005 to handle errors
        return 1;
    }
    return 0;
}

If you're just wanting to print out the correct answer, it might be faster to just print it with the most decimal places and truncate the zeros at the end:

void printNumber(float N, int D1, int D2) {
    char format[256];
    char result[256];
    sprintf(format, "%%.%df", D1);
    sprintf(result, format, N);
    char *end = result + strlen(result) - 1;
    int zeros = 0;
    while (end > result && end[0] == '0' && zeros < (D1 - D2))
    {
        zeros++;
        end--;
    }
    if (zeros >= (D1 - D2))
    {
        end[1] = '\0';
    }
    puts(result);
}

void doNumber(float N, int D1, int D2) {
    printf("%f, %d, %d: ", N, D1, D2);
    printNumber(N, D1, D2);
    printf("\n");
}

int _tmain(int argc, _TCHAR* argv[])
{
    doNumber(0.01001f, 4, 2);
    doNumber(0.010101f, 4, 2);
    doNumber(0.011001f, 4, 2);
    doNumber(5000.0f, 4, 2);
    return 0;
}
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int foo(float number, int d1, int d2)
{
    assert((number > 0.0f) && (number < 1.0f) && (d1 <= FLT_DIG) && (d2 < d1) && (d2 > 0));

    int count = d1;
    int n = (int)(number * pow(10.0f, d1));

    if (n == 0) return 0;

    while ((n % 10) == 0)
    {
        n /= 10;
        count--;
    }

    return (count > d2) ? 1 : 0;
}
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-1 for hopelessly wrong answer and ignorance of floating point –  R.. Sep 22 '10 at 0:28
    
And another -1 if I could give it for writing code that's not even valid C: int(number)...??? –  R.. Sep 22 '10 at 0:45
    
What output does your program give? (Once you fix the syntax errors...) It gives 25 on my machine. Hint: you've completely ignored the parameter d1 in the statement of the problem. –  R.. Sep 22 '10 at 0:49
    
1) I fink you are who are totally ignorant about floating numbers. Multiplying it with 10 will not change fraction part, but only exponent. And yes, int(n) is not valid C cast, but (int)n is. –  ssianky Sep 22 '10 at 0:52
    
2) snprintf IS NOT eficient –  ssianky Sep 22 '10 at 0:52

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