Generally we say that a float has precision of 6 digits after the decimal point. But if we store a large number of the order of 10^30 we won't get 6 digits after the decimal point. So is it correct to say that floats have a precision of 6 digits after the decimal point?
"6 digits after the decimal point" is nonesnse, and your example is a good demonstration of this.
This is an exact specification of the
The precision of the
Hence in decimal digits this is approximately:
24 * log(2) / log(10) = 7.22
It sounds like you're asking about precision to decimal places (digits after the decimal point), whereas significant figures (total number of digits excluding leading and traling zeroes) is a better way to describe accuracy of numbers.
You're correct in that the number of digits after the decimal point will change when the number is larger - but if we're talking precision, the number of significant figures will not change when the number is larger. However, the answer isn't simple for decimal numbers:
Most systems these days use IEE floating point format to represent numbers in C. However, if you're on something unusual, it's worth checking. Single precision IEE
As we'd expect, this is all stored in binary.
How many significant figures?
If you are using IEE-754 numbers, "how many significant figures" probably isn't an easy way to think about it, because the precision is measured in binary significant figures rather than decimal.
This means there are 24 significant binary digits, which does not translate to an exact number of decimal significant figures. You can use the formula 24 * log(2) / log(10) to determine that there are 7.225 digits of decimal precision, which isn't a very good answer to your question, since there are numbers of 24 significant binary digits which only have 6 significant decimal digits.
So, single precision floating point numbers have 6-9 significant decimal digits of precision, depending on the number.
Interestingly, you can also use this precision to work out the largest consecutive integer (counting from zero) that you can successfully represent in a single precision float. It is 2^24, or 16,777,216. You can exactly store larger integers, but only if they can be represented in 24 significant binary digits.
The precision of floating point numbers should be measured in binary digits, not decimal digits. This is because computers operate on binary numbers, and a binary fraction can only approximate a decimal fraction.
Language lawyers will say that the exact width of a
IEEE754 specifies that a floating point number is in scientific notation: (-1)s×2e×m
So, the maximum number of decimal digits that can be approximated with this representation is: log10(224) = 7.22 . That approximates seven significant decimal digits, and an exponent ranging from 2-126 to 2127.
Notice that the exponent is measured separately. This is exactly like if you were using ordinary scientific notation, like "A person weighs 72.3 kilograms = 7.23×104 grams". Notice that there are three significant digits here, representing that the number is only accurate to within 100 grams. But there is also an exponent which is a different number entirely. You can have a very big exponent with very few significant digits, like "the sun weighs 1.99×1033 grams." Big number, few digits.
In a nutshell, a float can store about 7-8 significant decimal digits. Let me illustrate this with an example:
Basically, the float stores two values:
Now, this is a simplified example. Floats store binary values instead of decimal values. A 32-bit IEEE 745 float has space for 23 "significant bits" (plus the first one which is always assumed to be 1), which corresponds to roughly 7-8 decimal digits.
And this is exactly what C produces: