Text formatting
Strings
JavaScript's String type is used to represent textual data. It is a set of "elements" of 16-bit unsigned integer values (UTF-16 code units). Each element in the String occupies a position in the String. The first element is at index 0, the next at index 1, and so on. The length of a String is the number of elements in it. You can create strings using string literals or string objects.
String literals
You can declare strings in source code using either single or double quotes:
'foo'
"bar"
More advanced strings can be created using escape sequences:
Hexadecimal escape sequences
The number after \x is interpreted as a hexadecimal number.
"\xA9" // "©"
Unicode escape sequences
The Unicode escape sequences require at least four hexadecimal digits following \u
.
"\u00A9" // "©"
Unicode code point escapes
With Unicode code point escapes, any character can be escaped using hexadecimal numbers so that it is possible to use Unicode code points up to 0x10FFFF
. With the four-digit Unicode escapes it is often necessary to write the surrogate halves separately to achieve the same result.
See also String.fromCodePoint()
or String.prototype.codePointAt()
.
"\u{2F804}"
// the same with simple Unicode escapes
"\uD87E\uDC04"
String objects
The String
object is a wrapper around the string primitive data type.
const foo = new String("foo"); // Creates a String object
console.log(foo); // [String: 'foo']
typeof foo; // 'object'
You can call any of the methods of the String
object on a string literal value—JavaScript automatically converts the string literal to a temporary String
object, calls the method, then discards the temporary String
object. You can also use the length
property with a string literal.
You should use string literals unless you specifically need to use a String
object, because String
objects can have counterintuitive behavior. For example:
const firstString = "2 + 2"; // Creates a string literal value
const secondString = new String("2 + 2"); // Creates a String object
eval(firstString); // Returns the number 4
eval(secondString); // Returns a String object containing "2 + 2"
A String
object has one property, length
, that indicates the number of UTF-16 code units in the string. For example, the following code assigns helloLength
the value 13, because "Hello, World!" has 13 characters, each represented by one UTF-16 code unit. You can access each code unit using an array bracket style. You can't change individual characters because strings are immutable array-like objects:
const hello = "Hello, World!";
const helloLength = hello.length;
hello[0] = "L"; // This has no effect, because strings are immutable
hello[0]; // This returns "H"
Characters whose Unicode scalar values are greater than U+FFFF (such as some rare Chinese/Japanese/Korean/Vietnamese characters and some emoji) are stored in UTF-16 with two surrogate code units each. For example, a string containing the single character U+1F600 "Emoji grinning face" will have length 2. Accessing the individual code units in such a string using square brackets may have undesirable consequences such as the formation of strings with unmatched surrogate code units, in violation of the Unicode standard. (Examples should be added to this page after MDN bug 857438 is fixed.) See also String.fromCodePoint()
or String.prototype.codePointAt()
.
A String
object has a variety of methods: for example those that return a variation on the string itself, such as substring
and toUpperCase
.
The following table summarizes the methods of String
objects.
Method | Description |
---|---|
charAt() , charCodeAt() ,
codePointAt()
|
Return the character or character code at the specified position in string. |
indexOf() ,
lastIndexOf()
|
Return the position of specified substring in the string or last position of specified substring, respectively. |
startsWith() ,
endsWith() ,
includes()
|
Returns whether or not the string starts, ends or contains a specified string. |
concat() |
Combines the text of two strings and returns a new string. |
split() |
Splits a String object into an array of strings by
separating the string into substrings.
|
slice() |
Extracts a section of a string and returns a new string. |
substring() ,
substr()
|
Return the specified subset of the string, either by specifying the start and end indexes or the start index and a length. |
match() , matchAll() ,
replace() , replaceAll() ,
search()
|
Work with regular expressions. |
toLowerCase() ,
toUpperCase()
|
Return the string in all lowercase or all uppercase, respectively. |
normalize() |
Returns the Unicode Normalization Form of the calling string value. |
repeat() |
Returns a string consisting of the elements of the object repeated the given times. |
trim() |
Trims whitespace from the beginning and end of the string. |
Multi-line template literals
Template literals are string literals allowing embedded expressions. You can use multi-line strings and string interpolation features with them.
Template literals are enclosed by backtick (grave accent) characters (`
) instead of double or single quotes. Template literals can contain placeholders. These are indicated by the dollar sign and curly braces (${expression}
).
Multi-lines
Any new line characters inserted in the source are part of the template literal. Using normal strings, you would have to use the following syntax in order to get multi-line strings:
console.log(
"string text line 1\n\
string text line 2",
);
// "string text line 1
// string text line 2"
To get the same effect with multi-line strings, you can now write:
console.log(`string text line 1
string text line 2`);
// "string text line 1
// string text line 2"
Embedded expressions
In order to embed expressions within normal strings, you would use the following syntax:
const five = 5;
const ten = 10;
console.log(
"Fifteen is " + (five + ten) + " and not " + (2 * five + ten) + ".",
);
// "Fifteen is 15 and not 20."
Now, with template literals, you are able to make use of the syntactic sugar making substitutions like this more readable:
const five = 5;
const ten = 10;
console.log(`Fifteen is ${five + ten} and not ${2 * five + ten}.`);
// "Fifteen is 15 and not 20."
For more information, read about Template literals in the JavaScript reference.
Internationalization
The Intl
object is the namespace for the ECMAScript Internationalization API, which provides language sensitive string comparison, number formatting, and date and time formatting. The constructors for Intl.Collator
, Intl.NumberFormat
, and Intl.DateTimeFormat
objects are properties of the Intl
object.
Date and time formatting
The Intl.DateTimeFormat
object is useful for formatting date and time. The following formats a date for English as used in the United States. (The result is different in another time zone.)
// July 17, 2014 00:00:00 UTC:
const july172014 = new Date("2014-07-17");
const options = {
year: "2-digit",
month: "2-digit",
day: "2-digit",
hour: "2-digit",
minute: "2-digit",
timeZoneName: "short",
};
const americanDateTime = new Intl.DateTimeFormat("en-US", options).format;
// Local timezone vary depending on your settings
// In CEST, logs: 07/17/14, 02:00 AM GMT+2
// In PDT, logs: 07/16/14, 05:00 PM GMT-7
console.log(americanDateTime(july172014));
Number formatting
The Intl.NumberFormat
object is useful for formatting numbers, for example currencies.
const gasPrice = new Intl.NumberFormat("en-US", {
style: "currency",
currency: "USD",
minimumFractionDigits: 3,
});
console.log(gasPrice.format(5.259)); // $5.259
const hanDecimalRMBInChina = new Intl.NumberFormat("zh-CN-u-nu-hanidec", {
style: "currency",
currency: "CNY",
});
console.log(hanDecimalRMBInChina.format(1314.25)); // ¥ 一,三一四.二五
Collation
The Intl.Collator
object is useful for comparing and sorting strings.
For example, there are actually two different sort orders in German, phonebook and dictionary. Phonebook sort emphasizes sound, and it's as if "ä", "ö", and so on were expanded to "ae", "oe", and so on prior to sorting.
const names = ["Hochberg", "Hönigswald", "Holzman"];
const germanPhonebook = new Intl.Collator("de-DE-u-co-phonebk");
// as if sorting ["Hochberg", "Hoenigswald", "Holzman"]:
console.log(names.sort(germanPhonebook.compare).join(", "));
// "Hochberg, Hönigswald, Holzman"
Some German words conjugate with extra umlauts, so in dictionaries it's sensible to order ignoring umlauts (except when ordering words differing only by umlauts: schon before schön).
const germanDictionary = new Intl.Collator("de-DE-u-co-dict");
// as if sorting ["Hochberg", "Honigswald", "Holzman"]:
console.log(names.sort(germanDictionary.compare).join(", "));
// "Hochberg, Holzman, Hönigswald"
For more information about the Intl
API, see also Introducing the JavaScript Internationalization API.