Contrary to some modern dynamically typed programming languages such as JavaScript or Ruby that have a single basic numeric type, the C programming language has many. That is because C reflects the different way to represent different kinds of numbers within a processor register.

To investigate different representations you can use the `union`

construct where the same data can be viewed as different types.

Define

```
union {
float x;
int v;
} u;
```

Assign `u.x = 1.0f`

and `printf("0x%08x\n",u.v)`

to get the 32-bit representation of `1.0f`

as a floating point number. It should return `0x3f800000`

and not `0x00000001`

as one might expect.

As mentioned in earlier answers this reflects the representation of a floating number as a 32-bit value as `

```
1.0f = 0x3F800000 = 0011.1111.1000.0000.0000.0000.0000.0000 =
0 0111.1111 000.0000.0000.0000.0000.0000 = 0 0x7F 0
```

Here the three parts are *sign* s=0, *exponent* e=127, and *mantissa* m=0 and the floating point value is computed as

```
value = s * (1 + m * 2^-23) * 2^(e-127)
```

With this representation any integer number from -16,777,215 to 16,777,215 can be represented exactly. This is the value of (2^24 - 1) since there are only 23 bits in the mantissa. This range is not sufficient for many applications, therefore the `float`

type cannot replace the `int`

type.

The range of exact representation of integers by the `double`

type is wider since the value occupies 64 bits and there are 53 bits reserved for the mantissa. It is exactly from
-9,007,199,254,740,991 to 9,007,199,254,740,991. Yet `double`

requires twice as much memory.

Another source of difficulty is the way fractional numbers are represented. Since decimal fractions cannot be represented exactly (0.1f = 0x3dcccccd = 0.10000000149...) the use of floating point numbers breaks common algebraic identities.

```
0.1f * 10 != 1.0f
```

This can be confusing and lead to errors that are hard to detect. In general **strict equality should not be used with floating point numbers**.

Another example of floating point arithmetic depature from algebraic correctness:

```
float x = 16777217.0f;
float y = 16777215.0f;
x -= 1.0f;
y += 1.0f;
if (y > x) {printf("16777215.0 + 1.0 > 16777217.0 - 1.0\n");}
```

Yet another issue is the behaviour of the system when the limits of exact representation are broken. When in integer arithmetic the result of an arithmetic operation is greater than the range of the type, this can be detected in many ways: a special OVERFLOW bit in the processor flags register is flipped, and the result is significantly different from the expected.

In floating point arithmetic as the example above shows, the loss of precision occurs silently.

Hope this helps to understand why one needs many basic numeric types in C.