198

How can I round a float (such as 37.777779) to two decimal places (37.78) in C?

  • 14
    You cannot properly round the number itself, because float (and double) aren't decimal floating-point - they are binary floating-point - so rounding to decimal positions is meaningless. You can round the output, however. – Pavel Minaev Aug 27 '09 at 21:49
  • 58
    It's not meaningless; it's inexact. There's quite a difference. – Brooks Moses Aug 28 '09 at 3:08
  • 2
    What kind of rounding you're expecting? Half-up or Rounding to nearest even? – Truthseeker Rangwan Aug 3 '14 at 13:21

17 Answers 17

388

If you just want to round the number for output purposes, then the "%.2f" format string is indeed the correct answer. However, if you actually want to round the floating point value for further computation, something like the following works:

#include <math.h>

float val = 37.777779;

float rounded_down = floorf(val * 100) / 100;   /* Result: 37.77 */
float nearest = roundf(val * 100) / 100;  /* Result: 37.78 */
float rounded_up = ceilf(val * 100) / 100;      /* Result: 37.78 */

Notice that there are three different rounding rules you might want to choose: round down (ie, truncate after two decimal places), rounded to nearest, and round up. Usually, you want round to nearest.

As several others have pointed out, due to the quirks of floating point representation, these rounded values may not be exactly the "obvious" decimal values, but they will be very very close.

For much (much!) more information on rounding, and especially on tie-breaking rules for rounding to nearest, see the Wikipedia article on Rounding.

  • 4
    Can it be modified to support rounding to arbitrary precision? – user472308 May 14 '14 at 20:12
  • 1
    @slater When you say 'arbitrary precision', are you asking about rounding to, eg, three instead of two decimal places, or using libraries that implement unbounded precision decimal values? If the former, make what I hope are obvious adjustments to the constant 100; otherwise, do the exact same calculations shown above, just with whatever multi precision library you're using. – Dale Hagglund May 15 '14 at 7:09
  • 2
    @DaleHagglung The former, thank you. Is the adjustment to replace 100 with pow(10, (int)desiredPrecision)? – user472308 May 15 '14 at 15:09
  • 3
    Yep. To round after k decimal places, use a scale factor of 10^k. This should be really easy to see if you write out some decimal values by hand and play around with multiples of 10. Suppose you're working with the value 1.23456789, and want to round it to 3 decimal places. The operation available to you is round to integer. So, how do you move the first three decimal places so that they're left of the decimal point? I hope it's clear that you multiply by 10^3. Now you can round that value to an integer. Next, you put the three low order digits back by dividing by 10^3. – Dale Hagglund May 16 '14 at 3:19
  • 1
    Can I make this work with doubles too somehow? Doesn't seem to do the job I want :( (using floor and ceil). – Ms. Nobody Jun 20 '14 at 12:40
75

Using %.2f in printf. It only print 2 decimal points.

Example:

printf("%.2f", 37.777779);

Output:

37.77
  • This way is better because there is no loss of precision. – albert Feb 1 '14 at 18:45
  • 1
    @albert This also has the advantage of no loss of float range as val * 100 could overflow. – chux - Reinstate Monica Aug 3 '14 at 15:52
  • doesn't give the correct answer which is 37.78. – jpmorr 2 days ago
42

Assuming you're talking about round the value for printing, then Andrew Coleson and AraK's answer are correct:

printf("%.2f", 37.777779);

But note that if you're aiming to round the number to exactly 37.78 for internal use (eg to compare against another value), then this isn't a good idea, due to the way floating point numbers work: you usually don't want to do equality comparisons for floating point, instead use a target value +/- a sigma value. Or encode the number as a string with a known precision, and compare that.

See the link in Greg Hewgill's answer to a related question, which also covers why you shouldn't use floating point for financial calculations.

  • 1
    Upvoted for addressing what may be the question behind the question (or the question that should have been behind the question!). That's a rather important point. – Brooks Moses Aug 28 '09 at 3:13
  • Actually 37.78 can be presented exactly by floating point. Float has 11 to 12 digit for precission. That should be enough to address 3778 377.8 or all kind of 4 decimal digit. – Anonymous White Oct 28 '12 at 9:56
  • @HaryantoCiu yeah fair enough, I've editted my answer a little. – John Carter Nov 8 '12 at 19:00
22

How about this:

float value = 37.777779;
float rounded = ((int)(value * 100 + .5) / 100.0);
  • 4
    -1: a) this won't work for negative numbers (ok, the example is positive but still). b) you don't mention that it's impossible to store the exact decimal value in the float – John Carter Aug 28 '09 at 8:28
  • 28
    @therefromhere: (a) You're right (b) What is this? A high school test? – Daniil Aug 28 '09 at 13:20
  • 1
    why you added 0.5? – muhammad tayyab Jun 3 '16 at 1:48
  • 1
    It's necessary to follow rounding rules. – Daniil Jun 8 '16 at 20:51
  • 1
    rounding rules in the context of @Daniil comment are round to nearest – Shmil The Cat May 15 '17 at 15:43
19
printf("%.2f", 37.777779);

If you want to write to C-string:

char number[24]; // dummy size, you should take care of the size!
sprintf(number, "%.2f", 37.777779);
  • @Sinan: Why the edit? @AraK: No, you should take care of the size :). Use snprintf(). – aib Aug 28 '09 at 14:17
  • 1
    @aib: I would guess because /**/ are C style comments and the question is tagged for C – Michael Haren Aug 28 '09 at 14:20
  • @Michael: So are //. – aib Aug 31 '09 at 13:49
  • 5
    C89 only allowed /**/-style, C99 introduced support for //-style. Use a lame/old compiler (or force C89 mode) and you'll be unable to use //-style. Having said that, it's 2009, let's consider them both C and C++ style. – Andrew Coleson Sep 4 '09 at 17:28
11

There isn't a way to round a float to another float because the rounded float may not be representable (a limitation of floating-point numbers). For instance, say you round 37.777779 to 37.78, but the nearest representable number is 37.781.

However, you can "round" a float by using a format string function.

  • 2
    This is no different from saying "there's no way to divide two floats and get a float, because the divided result may not be representable," which may be precisely true but is irrelevant. Floats are always inexact, even for something as basic as addition; the assumption is always that what you actually get is "the float that most closely approximates the exact rounded answer". – Brooks Moses Aug 28 '09 at 3:11
  • What I meant is that you cannot round a float to n decimal places and then expect the result always have n decimal places. You will still get a float, just not the one you expected. – Andrew Keeton Aug 28 '09 at 3:28
7

Also, if you're using C++, you can just create a function like this:

string prd(const double x, const int decDigits) {
    stringstream ss;
    ss << fixed;
    ss.precision(decDigits); // set # places after decimal
    ss << x;
    return ss.str();
}

You can then output any double myDouble with n places after the decimal point with code such as this:

std::cout << prd(myDouble,n);
6

You can still use:

float ceilf(float x); // don't forget #include <math.h> and link with -lm.

example:

float valueToRound = 37.777779;
float roundedValue = ceilf(valueToRound * 100) / 100;
  • This truncates at decimal point (i.e. will produce 37), and he needs to round to two places after the decimal point. – Pavel Minaev Aug 27 '09 at 23:23
  • Rounding to two places after the decimal point is a trivial variation, though (but still should be mentioned in the answer; ZeroCool, want to add an edit?): float roundedValue = ceilf(valueToRound * 100.0) / 100.0; – Brooks Moses Aug 28 '09 at 3:07
  • Into a state of sleep :) – ZeroCool Aug 28 '09 at 8:02
  • How come this solution isn't more popular? This works exactly how it should with minimal code. Is there some caveat with it? – Andy Dec 3 '13 at 5:35
5

In C++ (or in C with C-style casts), you could create the function:

/* Function to control # of decimal places to be output for x */
double showDecimals(const double& x, const int& numDecimals) {
    int y=x;
    double z=x-y;
    double m=pow(10,numDecimals);
    double q=z*m;
    double r=round(q);

    return static_cast<double>(y)+(1.0/m)*r;
}

Then std::cout << showDecimals(37.777779,2); would produce: 37.78.

Obviously you don't really need to create all 5 variables in that function, but I leave them there so you can see the logic. There are probably simpler solutions, but this works well for me--especially since it allows me to adjust the number of digits after the decimal place as I need.

5

Always use the printf family of functions for this. Even if you want to get the value as a float, you're best off using snprintf to get the rounded value as a string and then parsing it back with atof:

#include <math.h>
#include <stdio.h>
#include <stddef.h>
#include <stdlib.h>

double dround(double val, int dp) {
    int charsNeeded = 1 + snprintf(NULL, 0, "%.*f", dp, val);
    char *buffer = malloc(charsNeeded);
    snprintf(buffer, charsNeeded, "%.*f", dp, val);
    double result = atof(buffer);
    free(buffer);
    return result;
}

I say this because the approach shown by the currently top-voted answer and several others here - multiplying by 100, rounding to the nearest integer, and then dividing by 100 again - is flawed in two ways:

  • For some values, it will round in the wrong direction because the multiplication by 100 changes the decimal digit determining the rounding direction from a 4 to a 5 or vice versa, due to the imprecision of floating point numbers
  • For some values, multiplying and then dividing by 100 doesn't round-trip, meaning that even if no rounding takes place the end result will be wrong

To illustrate the first kind of error - the rounding direction sometimes being wrong - try running this program:

int main(void) {
    // This number is EXACTLY representable as a double
    double x = 0.01499999999999999944488848768742172978818416595458984375;

    printf("x: %.50f\n", x);

    double res1 = dround(x, 2);
    double res2 = round(100 * x) / 100;

    printf("Rounded with snprintf: %.50f\n", res1);
    printf("Rounded with round, then divided: %.50f\n", res2);
}

You'll see this output:

x: 0.01499999999999999944488848768742172978818416595459
Rounded with snprintf: 0.01000000000000000020816681711721685132943093776703
Rounded with round, then divided: 0.02000000000000000041633363423443370265886187553406

Note that the value we started with was less than 0.015, and so the mathematically correct answer when rounding it to 2 decimal places is 0.01. Of course, 0.01 is not exactly representable as a double, but we expect our result to be the double nearest to 0.01. Using snprintf gives us that result, but using round(100 * x) / 100 gives us 0.02, which is wrong. Why? Because 100 * x gives us exactly 1.5 as the result. Multiplying by 100 thus changes the correct direction to round in.

To illustrate the second kind of error - the result sometimes being wrong due to * 100 and / 100 not truly being inverses of each other - we can do a similar exercise with a very big number:

int main(void) {
    double x = 8631192423766613.0;

    printf("x: %.1f\n", x);

    double res1 = dround(x, 2);
    double res2 = round(100 * x) / 100;

    printf("Rounded with snprintf: %.1f\n", res1);
    printf("Rounded with round, then divided: %.1f\n", res2);
}

Our number now doesn't even have a fractional part; it's an integer value, just stored with type double. So the result after rounding it should be the same number we started with, right?

If you run the program above, you'll see:

x: 8631192423766613.0
Rounded with snprintf: 8631192423766613.0
Rounded with round, then divided: 8631192423766612.0

Oops. Our snprintf method returns the right result again, but the multiply-then-round-then-divide approach fails. That's because the mathematically correct value of 8631192423766613.0 * 100, 863119242376661300.0, is not exactly representable as a double; the closest value is 863119242376661248.0. When you divide that back by 100, you get 8631192423766612.0 - a different number to the one you started with.

Hopefully that's a sufficient demonstration that using roundf for rounding to a number of decimal places is broken, and that you should use snprintf instead. If that feels like a horrible hack to you, perhaps you'll be reassured by the knowledge that it's basically what CPython does.

  • +1 for a concrete example of what goes wrong with my answer and those similar to it, thanks to the weirdness of IEEE floating point, and providing a straightforward alternative. I was peripherally aware, quite a long time back, of lot of effort put into print and friends to me them safe for round-tripping floating point values. I would guess that the work done then might be showing up here. – Dale Hagglund Aug 27 at 3:26
  • Ahem... Sorry for the word salad near the end there, which it's now too late to edit. What I meant to say was "... a lot of effort put into printf and friends to make them safe ..." – Dale Hagglund Sep 1 at 0:14
4

Use float roundf(float x).

"The round functions round their argument to the nearest integer value in floating-point format, rounding halfway cases away from zero, regardless of the current rounding direction." C11dr §7.12.9.5

#include <math.h>
float y = roundf(x * 100.0f) / 100.0f; 

Depending on your float implementation, numbers that may appear to be half-way are not. as floating-point is typically base-2 oriented. Further, precisely rounding to the nearest 0.01 on all "half-way" cases is most challenging.

void r100(const char *s) {
  float x, y;
  sscanf(s, "%f", &x);
  y = round(x*100.0)/100.0;
  printf("%6s %.12e %.12e\n", s, x, y);
}

int main(void) {
  r100("1.115");
  r100("1.125");
  r100("1.135");
  return 0;
}

 1.115 1.115000009537e+00 1.120000004768e+00  
 1.125 1.125000000000e+00 1.129999995232e+00
 1.135 1.134999990463e+00 1.139999985695e+00

Although "1.115" is "half-way" between 1.11 and 1.12, when converted to float, the value is 1.115000009537... and is no longer "half-way", but closer to 1.12 and rounds to the closest float of 1.120000004768...

"1.125" is "half-way" between 1.12 and 1.13, when converted to float, the value is exactly 1.125 and is "half-way". It rounds toward 1.13 due to ties to even rule and rounds to the closest float of 1.129999995232...

Although "1.135" is "half-way" between 1.13 and 1.14, when converted to float, the value is 1.134999990463... and is no longer "half-way", but closer to 1.13 and rounds to the closest float of 1.129999995232...

If code used

y = roundf(x*100.0f)/100.0f;

Although "1.135" is "half-way" between 1.13 and 1.14, when converted to float, the value is 1.134999990463... and is no longer "half-way", but closer to 1.13 but incorrectly rounds to float of 1.139999985695... due to the more limited precision of float vs. double. This incorrect value may be viewed as correct, depending on coding goals.

4

I made this macro for rounding float numbers. Add it in your header / being of file

#define ROUNDF(f, c) (((float)((int)((f) * (c))) / (c)))

Here is an example:

float x = ROUNDF(3.141592, 100)

x equals 3.14 :)

  • 2
    Edited, thats right – mou Jun 26 '16 at 7:30
  • This truncates, but the question requests rounding. Additionally, it is subject to rounding errors in floating-point operations. – Eric Postpischil Dec 1 '18 at 21:07
3
double f_round(double dval, int n)
{
    char l_fmtp[32], l_buf[64];
    char *p_str;
    sprintf (l_fmtp, "%%.%df", n);
    if (dval>=0)
            sprintf (l_buf, l_fmtp, dval);
    else
            sprintf (l_buf, l_fmtp, dval);
    return ((double)strtod(l_buf, &p_str));

}

Here n is the number of decimals

example:

double d = 100.23456;

printf("%f", f_round(d, 4));// result: 100.2346

printf("%f", f_round(d, 2));// result: 100.23
  • -1 for four reasons: 1) the lack of explanation, 2) the vulnerability to buffer overflow - this will overflow, and therefore quite possibly crash, if dval is huge 3) the weird if / else block where you do exactly the same thing in each branch, and 4) the overcomplicated use of sprintf to build the format specifier for a second sprintf call; it's simpler to just use .* and pass the double value and number of decimal places as arguments to the same sprintf call. – Mark Amery Aug 25 at 15:55
2

Code definition :

#define roundz(x,d) ((floor(((x)*pow(10,d))+.5))/pow(10,d))

Results :

a = 8.000000
sqrt(a) = r = 2.828427
roundz(r,2) = 2.830000
roundz(r,3) = 2.828000
roundz(r,5) = 2.828430
0

Let me first attempt to justify my reason for adding yet another answer to this question. In an ideal world, rounding is not really a big deal. However, in real systems, you may need to contend with several issues that can result in rounding that may not be what you expect. For example, you may be performing financial calculations where final results are rounded and displayed to users as 2 decimal places; these same values are stored with fixed precision in a database that may include more than 2 decimal places (for various reasons; there is no optimal number of places to keep...depends on specific situations each system must support, e.g. tiny items whose prices are fractions of a penny per unit); and, floating point computations performed on values where the results are plus/minus epsilon. I have been confronting these issues and evolving my own strategy over the years. I won't claim that I have faced every scenario or have the best answer, but below is an example of my approach so far that overcomes these issues:

Suppose 6 decimal places is regarded as sufficient precision for calculations on floats/doubles (an arbitrary decision for the specific application), using the following rounding function/method:

double Round(double x, int p)
{
    if (x != 0.0) {
        return ((floor((fabs(x)*pow(double(10.0),p))+0.5))/pow(double(10.0),p))*(x/fabs(x));
    } else {
        return 0.0;
    }
}

Rounding to 2 decimal places for presentation of a result can be performed as:

double val;
// ...perform calculations on val
String(Round(Round(Round(val,8),6),2));

For val = 6.825, result is 6.83 as expected.

For val = 6.824999, result is 6.82. Here the assumption is that the calculation resulted in exactly 6.824999 and the 7th decimal place is zero.

For val = 6.8249999, result is 6.83. The 7th decimal place being 9 in this case causes the Round(val,6) function to give the expected result. For this case, there could be any number of trailing 9s.

For val = 6.824999499999, result is 6.83. Rounding to the 8th decimal place as a first step, i.e. Round(val,8), takes care of the one nasty case whereby a calculated floating point result calculates to 6.8249995, but is internally represented as 6.824999499999....

Finally, the example from the question...val = 37.777779 results in 37.78.

This approach could be further generalized as:

double val;
// ...perform calculations on val
String(Round(Round(Round(val,N+2),N),2));

where N is precision to be maintained for all intermediate calculations on floats/doubles. This works on negative values as well. I do not know if this approach is mathematically correct for all possibilities.

-1

...or you can do it the old-fashioned way without any libraries:

float a = 37.777779;

int b = a; // b = 37    
float c = a - b; // c = 0.777779   
c *= 100; // c = 77.777863   
int d = c; // d = 77;    
a = b + d / (float)100; // a = 37.770000;

That of course if you want to remove the extra information from the number.

-2

this function takes the number and precision and returns the rounded off number

float roundoff(float num,int precision)
{
      int temp=(int )(num*pow(10,precision));
      int num1=num*pow(10,precision+1);
      temp*=10;
      temp+=5;
      if(num1>=temp)
              num1+=10;
      num1/=10;
      num1*=10;
      num=num1/pow(10,precision+1);
      return num;
}

it converts the floating point number into int by left shifting the point and checking for the greater than five condition.