# Round a float to a given precision

I want to round a float number to a given precision, for example :

``````0.051 i want to convert it to
0.1

0.049 i want to convert it to
0.0

0.56 i want to convert it to
0.6

0.54 i want to convert it to
0.5
``````

I cant explain it better, but the reason for this is to translate a point location (like 0.131f, 0.432f) to the location of tile in a grid (like 0.1f, 0.4f).

Is there any way to achieve this?

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possible duplicate of How to round to integer (naturally) in C++? – Martin Beckett Jun 26 '12 at 14:02
Rounding a floating-point number to 1 or more decimal places doesn't make much sense; a number like `0.1` cannot be represented exactly in binary floating-point. Rounding can be done on output (to a string or to a file). – Keith Thompson Feb 18 '14 at 18:17
We are in the IT department ,we are trying to represent the infinite possibilities of the real world in lines of code, everything makes sense here. I am using this for a infinite scrolling background in a game, lost precision doesn't really matter. – SteveL Feb 18 '14 at 20:40
I have tested this, and it seems to not work correctly. If you try to round 127, it returns 128 (I am using double instead of float for f and for the return type). – BlunT Aug 14 '14 at 11:42
@BlunT ,probably you didn't got the point of the function ,what is the precision you are passing? if you put 2 you will get 128 cause you will get the closest number from 0,2,4,6...,128,130...(2 as a increment),if you pass 127.456 and precision 0.01f you will get 127.46 cause 127.46 is the closest to 0,0.01,0.02f.....127.45,127.46,127.47(0.01 as an increment) – SteveL Aug 14 '14 at 12:48

As long as your grid is regular, just find a transformation from integers to this grid. So let's say your grid is

``````0.2  0.4  0.6  ...
``````

Then you round by

``````float round(float f)
{
return floor(f * 5 + 0.5) / 5;
// return std::round(f * 5) / 5; // C++11
}
``````
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thank you , this is simple and it works perfect!!! – SteveL Jun 26 '12 at 14:18

EDIT 1: I was looking for solutions for numpy in python and didn't realize that the OP asked for C++ haha, oh well.

EDIT 2: Lol, looks like I didn't even address your original question. It looks like you're really wanting to round off according to a decimal (operation is independent of the given number), not a precision (operation is dependent on the number), and the others have already addressed that.

I was actually looking around for this too but could not find something, so I threw together an implementation for numpy arrays. It looks like it implements the logic that slashmais stated.

``````def pround(x, precision = 5):
temp = array(x)
ignore = (temp == 0.)
use = logical_not(ignore)
ex = floor(log10(abs(temp[use]))) - precision + 1
div = 10**ex
temp[use] = floor(temp[use] / div + 0.5) * div
return temp
``````

Here's a C++ scalar version as well, and you could probably do something similar to above using Eigen (they have logical indexing): (I also took this as a chance to practice some more boost haha):

``````#include <cmath>
#include <iostream>
#include <vector>
#include <boost/foreach.hpp>
#include <boost/function.hpp>
#include <boost/bind.hpp>

using namespace std;

double pround(double x, int precision)
{
if (x == 0.)
return x;
int ex = floor(log10(abs(x))) - precision + 1;
double div = pow(10, ex);
return floor(x / div + 0.5) * div;
}

template<typename T>
vector<T>& operator<<(vector<T> &x, const T &item)
{
x.push_back(item);
return x;
}

int main()
{
vector<double> list;
list << 0.051 << 0.049 << 0.56 << 0.54;
// What the OP was wanting
BOOST_FOREACH(double x, list)
{
cout << floor(x * 10 + 0.5) / 10 << "\n";
}

cout << "\n";

BOOST_FOREACH(double x, list)
{
cout << pround(x, 0) << "\n";
}

cout << "\n";

boost::function<double(double)> rounder = boost::bind(&pround, _1, 3);
vector<double> newList;
newList << 1.2345 << 1034324.23 << 0.0092320985;
BOOST_FOREACH(double x, newList)
{
cout << rounder(x) << "\n";
}

return 0;
}
``````

Output:

``````0.1
0
0.6
0.5

0.1
0
1
1

1.23
1.03e+06
0.00923
``````
-

The standard `ceil()`, `floor()` functions don't have a precision, I guess could work around that by adding your own precision - but this may introduce errors - e.g.

``````double ceil(double v, int p)
{
v *= pow(10, p);
v = ceil(v);
v /= pow(10, p);
}
``````

I guess you could test to see if this is reliable for you?

-
Isn't it /= pow(10, p) OR *= pow(10, -p)? – Aurélien Ooms Oct 8 '13 at 21:21
@AurélienOoms, thanks, a small typo... – Nim Oct 9 '13 at 8:04

Use `floor()` and `ceil()`. `floor` will convert a float to the next smaller integer, and `ceil` to the next higher:

``````floor( 4.5 ); // returns 4.0
ceil( 4.5 );  // returns 5.0
``````

I think the following would work:

``````float round( float f )
{
return floor((f * 10 ) + 0.5) / 10;
}
``````

`floor( f + 0.5 )` will round to an integer. By first multiplying by 10 and then dividing the result by 10 you are rounding by increments of 0.1.

-

An algorithm you can use:

• get 10-to-the-power(number-of-significant-digits) (=P10)
• multiply your double-value by P10
• add: 0.5 (or subtract if negative - see Ankush Shah's comment)
• divide the integer-portion of this sum by (P10) - the answer will be your rounded number
-
small point: if the number is negative, you will have to subtract 0.5 – Ankush Shah Dec 6 '15 at 1:08

Usually you know the desired precision at compile time. Therefore, using the templated Pow function available here, you can do:

``````template <int PRECISION>
float roundP(float f)
{
const int temp = Pow<10,PRECISION>::result;
return roundf(f*temp)/temp;
}

int main () {
std::cout << std::setprecision(10);
std::cout << roundP<0>(M_PI) << std::endl;
std::cout << roundP<1>(M_PI) << std::endl;
std::cout << roundP<2>(M_PI) << std::endl;
std::cout << roundP<3>(M_PI) << std::endl;
std::cout << roundP<4>(M_PI) << std::endl;
std::cout << roundP<5>(M_PI) << std::endl;
std::cout << roundP<6>(M_PI) << std::endl;
std::cout << roundP<7>(M_PI) << std::endl;
}
``````

Tested here.

The result also shows how imprecise is floating point representation :)

3

3.099999905

3.140000105

3.14199996

3.141599894

3.141590118

3.141592979

3.141592741

You can have better results using double:

``````template <int PRECISION>
double roundP(double f)
{
const int temp = Pow<10,PRECISION>::result;
return round(f*temp)/temp;
}
``````

Printed with precision 20:

3

3.1000000000000000888

3.1400000000000001243

3.1419999999999999041

3.1415999999999999481

3.1415899999999998826

3.1415929999999998579

3.1415926999999999047

-

Since Mooing Duck edited my question and removed the code saying questions shouldn't contain answers (understandable), I will write the solution here:

``````float round(float f,float prec)
{
return (float) (floor(f*(1.0f/prec) + 0.5)/(1.0f/prec));
}
``````
-

Algorithm for rounding float number:

`````` double Rounding(double src, int precision) {
int_64 des;
double tmp;
double result;
tmp = src * pow(10, precision);
if(tmp < 0) {//negative double
des = (int_64)(tmp - 0.5);
}else {
des = (int_64)(tmp + 0.5);
}
result = (double)((double)dst * pow(10, -precision));
return result;
}
``````
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