# Creating own float structure in C++

Yet my lectures in C++ at university began yet i got my first problems. Our task was it to implement a self made structure in C++ for floating points via the IEEE 754 standard:

Create a data structure that allows you to store a float, read its raw byte representation and its internal representation as s, e and m. Use a combination of union and bit-field-struct. Write a program where a float number is assigned to the float part of the structure and the raw and s/e/m representation is printed. Use hexadecimal output for raw and m.

What i had so far is the following:

``````#include <stdio.h>
#include <math.h>

union {
struct KFloat {
//Using bit fields for our self made float. s sign, e exponent, m mantissa
//It should be unsigned because we simply use 0 and 1
unsigned int s : 1, e : 8, m : 23;
};
//One bit will be wasted for our '.'
char internal[33];
};

float calculateRealFloat(KFloat kfloat) {
if(kfloat.s == 0) {
return (1.0+kfloat.m)*pow(2.0, (kfloat.e-127.0));
} else if (kfloat.s == 1) {
return (-1.0)*((1.0+kfloat.m)*pow(2.0, (kfloat.e-127.0)));
}
//Error case when s is bigger 1
return 0.0;
}

int main(void) {
KFloat kf_pos = {0, 128, 1.5707963705062866};//This should be Pi (rounded) aka 3.1415927
KFloat kf_neg = {1, 128, 1.5707963705062866};//Pi negative

float f_pos = calculateRealFloat(kf_pos);
float f_neg = calculateRealFloat(kf_neg);

printf("The positive float is %f or ",f_pos);
printf("%e\n", f_pos);

printf("The negative float is %f or ",f_neg);
printf("%e", f_neg);
return 0;
}
``````

The first error with this code is clearly that the mantissa is absolutely wrong but i have no idea how to fix this.

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Your mantissa should be an integer. Any description of IEEE that has a floating point value for the mantissa is not telling the truth. – john May 2 '13 at 14:26
Your requirement specifically asks for a `union`. – Chad May 2 '13 at 14:39
But how shall i implement the union? I don't know what is meant be raw and internal represantation. – Jack May 2 '13 at 14:40
@Jack: One reason to use C and not C++ is that C partially defines the result of accessing a union member other than the last one stored, and C++ does not. – Eric Postpischil May 2 '13 at 17:08
@John: The IEEE 754 standard does not use the word “mantissa” at all, and it defines the significand as a number represented with digits after a radix point (as well as one before), not as an integer. In subclause 3.3, it refers to “the sigificand m”, and it defines “m” as a number represented by a digit string d[0].d[1]d[2]…d[p-1] (with the original typography not reproduced in this comment). – Eric Postpischil May 2 '13 at 17:12

Create a data structure that allows you to store a float, read its raw byte representation and its internal representation as s, e and m.

this does not mean that you should store a string

I would do this the following way:

``````union MyFloat
{
unsigned char rawByteDataRep[4];
unsigned int  rawDataRep;
float         floatRep;
struct{   // not checked this part just copied from you
unsigned s : 1;
unsigned e : 8;
unsigned m : 23;
}             componentesRep;
}
``````

but be careful! Besides the fact that this union-conversion pattern is widely used, the C-Standard states that the result is undefined behaviour if you read another unionmember than the one that was written.

``````void testMyfloat()
{
MyFloat mf;
mf.floatRep = 3.14;
printf("The float %f is assembled from sign %i magnitude 0x%08x and exponent %i and looks in memory like that 0x%08x.\n",
mf.floatRep,
(int)mf.componentesRep.s,
(unsigned int)mf.componentesRep.m,
(int)mf.componentesRep.e,
mf.componentesRep.rawDataRep);

}
``````
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I think exponent shoul be signed – vlad_tepesch May 2 '13 at 15:29
The behavior is not completely undefined by the C standard. It states that when a union member other than the last one stored is accessed, the bytes are reinterpreted as the new type. Obviously, the representations are somewhat implementation dependent. If one changes `unsigned int` to `uint32_t`, then the union defined in this answer is likely to work in many implementations except for the problems caused by endianness and bit-field order. – Eric Postpischil May 2 '13 at 16:28
The stored exponent of an IEEE-754 binary number is always non-negative. When it is converted to the actual exponent, then it does become a signed value, by subtracting 127 (for a 32-bit `float`) from the stored value. – Eric Postpischil May 2 '13 at 16:31
@Eric ah ok. as you mention it i remember the exponent with the offset. Regarding the c standard: iam quite sure that explicitly looked up this topic, because somebody pointed me onto the undefined behaviour but i cannot find the paragraph now. – vlad_tepesch May 2 '13 at 18:45

Bruce Dawson has an excellent series of blog posts on floating point representation and arithmetic. The latest in the series, which has a bunch of links to previous posts that discusses this subject matter in detail, is here.

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