// parsing: parseInt("20px"); // 20 parseInt("10100", 2); // 20 parseInt("2e1"); // 2 // type conversion Number("20px"); // NaN Number("2e1"); // 20, exponential notation
parseInt will ignore trailing characters that don't correspond with any digit of the currently used base.
Number constructor doesn't detect implicit octals, but can detect the explicit octal notation:
Number("010"); // 10 Number("0o10") // 8, explicit octal parseInt("010"); // 8, implicit octal parseInt("010", 10); // 10, decimal radix used
And it can handle numbers in hexadecimal notation, just like
Number("0xF"); // 15 parseInt("0xF"); //15
In addition, a widely used construct to perform Numeric type conversion, is the Unary
+ Operator (p. 72), it is equivalent to using the
Number constructor as a function:
+"2e1"; // 20 +"0xF"; // 15 +"010"; // 10
- Takes a string as a first argument, the radix (An integer which is the base of a numeral system e.g. decimal 10 or binary 2) as a second argument
- The function returns a integer number, if the first character cannot be converted to a number
NaNwill be returned.
- If the
parseInt()function encounters a non numerical value, it will cut off the rest of input string and only parse the part until the non numerical value.
- If the radix is
undefinedor 0, JS will assume the following:
- If the input string begins with "0x" or "0X", the radix is 16 (hexadecimal), the remainder of the string is parsed into a number.
- If the input value begins with a 0 the radix can be either 8 (octal) or 10 (decimal). Which radix is chosen is depending on JS engine implementation.
ES5specifies that 10 should be used then. However, this is not supported by all browsers, therefore always specify radix if your numbers can begin with a 0.
- If the input value begins with any number, the radix will be 10
Number()constructor can convert any argument input into a number. If the
Number()constructor cannot convert the input into a number,
NaNwill be returned.
Number()constructor can also handle hexadecimal number, they have to start with
console.log(parseInt('0xF', 16)); // 15 // z is no number, it will only evaluate 0xF, therefore 15 is logged console.log(parseInt('0xFz123', 16)); // because the radix is 10, A is considered a letter not a number (like in Hexadecimal) // Therefore, A will be cut off the string and 10 is logged console.log(parseInt('10A', 10)); // 10 // first character isnot a number, therefore parseInt will return NaN console.log(parseInt('a1213', 10)); console.log('\n'); // start with 0X, therefore Number will interpret it as a hexadecimal value console.log(Number('0x11')); // Cannot be converted to a number, NaN will be returned, notice that // the number constructor will not cut off a non number part like parseInt does console.log(Number('123A')); // scientific notation is allowed console.log(Number('152e-1')); // 15.21
If you are looking for performance then probably best results you'll get with bitwise right shift
"10">>0. Also multiply (
"10" * 1) or not not (
~~"10"). All of them are much faster of
They even have "feature" returning 0 for not number argument.
Here are Performance tests.
parseInt() -> Parses a number to specified redix.
Number()-> Converts the specified value to its numeric equivalent or NaN if it fails to do so.
Hence for converting some non-numeric value to number we should always use Number() function.
Number("")//0 parseInt("")//NaN Number("123")//123 parseInt("123")//123 Number("123ac") //NaN,as it is a non numeric string parsInt("123ac") //123,it parse decimal number outof string Number(true)//1 parseInt(true) //NaN
There are various corner case to
parseInt() functions as it does redix conversion, hence we should avoid using parseInt() function for coersion purposes.
Now, to check weather the provided value is Numeric or not,we should use native
It's a good idea to stay away from parseInt and use Number and Math.round unless you need hex or octal. Both can use strings. Why stay away from it?
parseInt(0.001, 10) 0 parseInt(-0.0000000001, 10) -1 parseInt(0.0000000001, 10) 1 parseInt(4000000000000000000000, 10) 4
It completely butchers really large or really small numbers. Oddly enough it works normally if these inputs are a string.
parseInt("-0.0000000001", 10) 0 parseInt("0.0000000001", 10) 0 parseInt("4000000000000000000000", 10) 4e+21
Instead of risking hard to find bugs with this and the other gotchas people mentioned, I would just avoid
parseInt unless you need to parse something other than base 10.
.toFixed(0) can all do the same things
parseInt can be used for without having these types of bugs.
If you really want or need to use parseInt for some of it's other qualities, never use it to convert floats to ints.
Another way to get the result is to use the ~ operator
For most circumstances
~~someThing === parseInt(something)
but ~~ will return zero for strings that parseInt will accept with trailing other characters or with the number base spec (eg hex) and will also return zero when parseInt returns NaN. Another difference is that ~~ if given a bigint returns a bigint to which you can add another bigint whereas parseInt returns an ordinary floating point number (yes really - it gives exactly the same value as parseFloat) if the bigint is large
However for most circumstances ~~ is 30% faster than parseInt. It is only slower by 10% when something is a floating point represented as a string.
So if the more restricted scope of ~~ fits your need then save the computer time and give yourself less to type