## Doubles, the "Simple" Explanation

The largest "double" number (double precision floating point number) is typically a 64-bit or 8-byte number expressed as:

```
1.79E308
or
1.79 x 10 (to the power of) 308
```

As you can guess, 10 to the power of 308 is a GIGANTIC NUMBER, like 170000000000000000000000000000000000000000000 and even larger!

On the other end of the scale, double precision floating point 64-bit numbers support tiny tiny decimal numbers of fractions using the "dot" notation, the smallest being:

```
4.94E-324
or
4.94 x 10 (to the power of) -324
```

Anything multiplied times 10 to the power of a negative power is a tiny tiny decimal, like 0.0000000000000000000000000000000000494 and even smaller.

But what confuses people is they will hear computer nerds and math people say, "but that number has a range of only 15 numbers values". It turns out that the values described above are the all-time MAXIMUM and MINIMUM values the computer can store and present from memory. But they lose accuracy and the ability to create numbers LONG BEFORE they get that big. So most programmers AVOID the maximum double number possible, and try and stick within a known, much smaller range.

But why? And what is the *best* maximum double number to use? I could not find the answer reading dozens of bad explanations on math sites online. So this SIMPLE explanation may help you below. It helped me!!

DOUBLE NUMBER FACTS and FLAWS

**JavaScript** (which also uses the 64-bit double precision storage system for numbers in computers) uses double precision floating point numbers for storing all known numerical values. It thus uses the same MAX and MIN ranges shown above. But most languages use a typed numerical system with ranges to avoid accuracy problems. The double and float number storage systems, however, seem to all share the same flaw of losing numerical *precision* as they get larger and smaller. I will explain why as it affects the idea of "maximum" values...

To address this, **JavaScript** has what is called a **Number.MAX_SAFE_INTEGER** value, which is `9007199254740991`

. This is the most accurate number it can represent for Integers, but is NOT the largest number that can be stored. It is *accurate* because it guarantees any number equal to or less than that value can be viewed, calculated, stored, etc. Beyond that range, there are "missing" numbers. The reason is because double precision numbers AFTER `9007199254740991`

use an additional number to multiple them to larger and larger values, including the true max number of `1.79E308`

. That new number is called an *exponent*.

THE EVIL EXPONENT

It happens to be the fact that this max value of `9007199254740991`

is also the max number you can store in the 53 bits of computer memory used in the 64-bit storage system. This `9007199254740991`

number stored in the 53-bits in memory is the largest value possible that can be stored directly in the *mantissa* section of memory of a typical double precision floating point number used by JavaScript.

`9007199254740991`

, by-the-way, is in a format we call Base10 or decimal, the number Humans use. But it is also stored in computer memory as 53-bits as this value...

```
11111111111111111111111111111111111111111111111111111
```

This the maximum number of bits computers can actually store the integer part of double precision numbers using the 64-bit number memory system.

To get to the even LARGER max number possible (`1.79E308`

), JavaScript has to use an extra trick called the *exponent* to multiple it to larger and larger values. So there is an `11-bit exponent`

number next to the `53-bit mantissa`

value in computer memory above that allows the number to grow much larger and much smaller, creating the final range of numbers double are expected to represent. (Also, there is a single bit for positive and negative numbers, as well.)

After the computer reaches this limit of max Integer value (around ~9 quadrillion) and filling up the mantissa section of memory with 53 bits, **JavaScript** uses a new 11-bit storage area for the *exponent* which allows much larger integers to grow (up to 10 to the power of 308!) and much smaller decimals to get smaller (10 to the power of -324!). Thus, this *exponent* number allows for a full range of large and small decimals to be created with the floating radix or decimal point to move up and down the number, creating the complex fractional or decimal values you expect to see. Again, this *exponent* is another large number store in 11-bits, and itself has a max value of `2048`

.

You will notice `9007199254740991`

is a max integer, but does not explain the larger MAX value possible in storage or the MINIMUM decimal number, or even how decimal fractions get created and stored. How does this computer bit value create all that?

**The answer is again, through the ***exponent*!

It turns out that the exponent 11-bit value is divided itself into a positive and negative value so that it can create large integers but also small decimal numbers.

To do so, it has its own positive and negative range created by subtracting `1024`

from its `2048`

max value to get a new range of values from `+1023`

to `-1023`

(minus reserved values for 0) to create the positive/negative exponent range. To then get the FINAL DOUBLE NUMBER, the *mantissa* (`9007199254740991`

) is multiplied by the *exponent* (plus the single bit sign added) to get the final value! This allows the *exponent* to multiply the *mantissa* value to even larger integer ranges beyond 9 quadrillion, but also go the opposite way with the decimal to very tiny fractions.

However, the -+1023 number stored in the *exponent* is not multiplied to the *mantissa* to get the double, but used to raise a number `2`

to a power of the exponent. The exponent is a decimal number, but not applied to a decimal exponent like 10 to the power or 1023. It is applied to a Base2 system again and creates a value of `2 to the power of (the exponent number)`

.

That value generated is then multiplied to the *mantissa* to get the MAX and MIN number allowed to be stored in JavaScript, as well as all the larger and smaller values within the range. It uses "2" rather than 10 for precision purposes, so with each increase in the exponent value, it only doubles the mantissa value. This reduces the loss of numbers. But this exponent multiplier also means it will *lose* an increasing range of numbers in doubles as it grows, to the point where as you reach the MAX stored exponent and mantissa possible, very large swaths of numbers disappear from the final calculated number, and so certain numbers are now not possible in math calculations!

That is why most use the **SAFE** max integer ranges (`9007199254740991`

or less), as most know very large and small numbers in JavaScript are highly inaccurate! Also note that 2 to the power of -1023 gets the MIN number or small decimal fractions you associate with a typical "float". The exponent is thus used to translate the mantissa integer to very large and small numbers up to the Maximum and Minimum ranges it can store.

Notice that the `2 to power of 1023`

translates to a decimal exponent using `10 to the power of 308`

for max values. That allows you to see the number in Human values, or Base10 numerical format of the binary calculation. Often math experts do not explain that all these values are the same number just in different bases or formats.

THE TRUE MAX FOR DOUBLES IS INFINITY

Finally, what happens when integers reach the MAX number possible, or the smallest decimal fraction possible?

It turns out, double precision floating point numbers have reserved a set of bit values for the 64-bit exponent and mantissa values to store four other possible numbers:

- +Infinity
- -Infinity
- +0
- -0

For example, +0 in double numbers stored in 64-bit memory is a large row of empty bits in computer memory. Below is what happens after you go beyond the smallest decimal possible (`4.94E-324`

) in using a Double precision floating point number. It becomes `+0`

after it runs out of memory! The computer will return `+0`

, but stores 0 bits in memory. Below is the FULL 64-bit storage design in bits for a double in computer memory. The first bit controls `+`

(0) or `-`

(1) for *positive* or *negative* numbers, the 11-bit *exponent* is next (all zeros is 0, so becomes `2 to the power of 0 = 1`

), and the large block of 53 bits for the *mantissa* or *significand*, which represents 0. So `+0`

is represented by all zeroes!

```
0 00000000000 0000000000000000000000000000000000000000000000000000
```

If the double reaches its positive max or min, or its negative max or min, many languages will always return one of those values in some form. However, some return NaN, or overflow, exceptions, etc. How that is handled is a different discussion. But often these four values are your TRUE min and max values for double. By returning irrational values, you at least have have a representation of the max and min in doubles that explain the last forms of the double type that cannot be stored or explained rationally.

SUMMARY

So the MAXIMUM and MINIMUM ranges for positive and negative Doubles are as follows:

```
MAXIMUM TO MINIMUM POSITIVE VALUE RANGE
1.79E308 to 4.94E-324 (+Infinity to +0 for out of range)
MAXIMUM TO MINIMUM NEGATIVE VALUE RANGE
-4.94E-324 to -1.79E308 (-0 to -Infinity for out of range)
But the SAFE and ACCURATE MAX and MIN range is really:
9007199254740991 (max) to -9007199254740991 (min)
```

So you can see with +-Infinity and +-0 added, Doubles have extra max and min ranges to help you when you exceed the max and mins.

As mentioned above, when you go from the largest positive value to smallest decimal positive value or fraction, the bits zero out and you get 0 Past `4.94E-324`

the double cannot store any decimal fraction value smaller so it collapses to +0 in the bit registry. The same event happens for tiny negative decimals which collapse past their value to -0. As you know -0 = +0 so though not the same values stored in memory, in applications they often are coerced to 0. But be aware many applications do deliver signed zeros!

The opposite happens to the large values...past `1.79E308`

they turn into +Infinity and -Infinity for the negative version. This is what creates all the weird number ranges in languages like JavaScript. Double precision numbers have weird returns!

Note that he MINIMUM SAFE RANGE for decimals/fractions is not shown above as it varies based on the precision needed in the fraction. When you combine the integer with the fractional part, the decimal place accuracy drops away quickly as it goes smaller. There are many discussions and debates about this online. No one ever has an answer. The list below might help. You might need to change these ranges listed to much smaller values if you want guaranteed precision. As you can see, if you want to support up to 9-decimal place accuracy in floats, you will need to limit MAX values in the mantissa to these values. Precision means how many decimal places you need with accuracy. Unsafe means past these values, the number will lose precision and have missing numbers:

```
Precision Unsafe
1 5,629,499,534,21,312
2 703,687,441,770,664
3 87,960,930,220,208
4 5,497,558,130,888
5 68,719,476,736
6 8,589,934,592
7 536,870,912
8 67,108,864
9 8,388,608
```

It took me awhile to understand the TRUE limits of Double precision floating point numbers and computers. I created this simple explanation above after reading so much MASS CONFUSION from math experts online who are great at creating numbers but terrible at explaining anything! I hope I helped you on your coding journey - Peace :)

What is the biggest "no-floating" integer", All numbers are represented using a floating point except +0, -0, the really really tiny subnormals (which use a fixed point), the infinities and the NaNs. This is obviously not what you meant to ask. You seem to be asking what's the largest integer where it and every integer smaller than it can be exactly represented by a double.