# Javascript - What is the maximum number in scientific notation restricted by?

In JavaScript, I was curious to find out what was the maximum possible number representable in scientific notation without getting "Infinity" as a result, so I wrote a little program and found out it's this one:

``````17976931348623158079372897140530341507993413271003782693617377898044496829276475094664901797758720709633028641669288791094655554785194040263065748867150582068190890200070838367627385484581771153176447573027006985557136695962284291481986083493647529271907416844436551070434271155969950809304288017790417449779
``````

which can be abbreviated to 1.7976931348623157e+308.

My question is, what makes this specific number the maximum possible in JavaScript? Is it hardware-dependent (maybe maximum one on 64 bit?) or language-specific? Why exactly is 308 the maximum usable power of 10?

And also, how different is it in other languages?

• tc39.github.io/ecma262/2017/… BTW you could simply use `Number.MAX_VALUE` to get this value May 31, 2017 at 8:23
• What other languages are you thinking about? May 31, 2017 at 8:26
• @YuryTarabanko Bummer. Well, it was fun doing it anyway :) May 31, 2017 at 8:29
• @Hankrecords Think about intermediate values. How they were represented in memory? So you have 308 digits as string but when you convert it to number engine uses 53 bits to store 308 "correct" digits, right? May 31, 2017 at 9:48
• @Hankrecords, did I misunderstand your question? May 31, 2017 at 9:54

Double precision float. Due to how the double data-type is defined.

All floating point numbers (double is a double-precision float) are written as a product of two values, the mantissa and the exponent. In principle, this works similar to how numbers are written in scientific notation: for the number 1.34 * 10^24, the mantissa is 1.34 and the exponent is 24.

https://en.wikipedia.org/wiki/Double-precision_floating-point_format

`Number.MAX_VALUE`

The value of Number.MAX_VALUE is the largest positive finite value of the Number type, which is approximately 1.7976931348623157e+308.

This property has the attributes `{ [[Writable]]: false, [[Enumerable]]: fafalselse, [[Configurable]]: false }`.

http://ecma262-5.com/ELS5_HTML.htm#Section_8.5

What differs for floats (and doubles) is that you split the total bytes that hold the number into two parts, one for the mantissa and one for the exponent. That gives you an exponent of 10 bits, and one sign bit for the exponent, so that would give you a number from -1023 to +1024.

However, the base of the exponent is not 10, but 2. The way the floating point number exponent is stored uses 8 bits (for floats) or 11 bits (for doubles), meaning you get exponent values of -127 to +128 (float) or -1023 to +1024 (double).

And 2^1024 gives us a value of 1.797693134862315907729305190789 * 10^308, which is the largest exponent of a double precision float.