Literals/String
Show literal specification of characters and strings.
You are encouraged to solve this task according to the task description, using any language you may know.
- Task
If supported, show how the following work:
- verbatim strings (quotes where escape sequences are quoted literally)
- here-strings
Also, discuss which quotes expand variables.
- Related tasks
- Metrics
- Counting
- Word frequency
- Letter frequency
- Jewels and stones
- I before E except after C
- Bioinformatics/base count
- Count occurrences of a substring
- Count how many vowels and consonants occur in a string
- Remove/replace
- XXXX redacted
- Conjugate a Latin verb
- Remove vowels from a string
- String interpolation (included)
- Strip block comments
- Strip comments from a string
- Strip a set of characters from a string
- Strip whitespace from a string -- top and tail
- Strip control codes and extended characters from a string
- Anagrams/Derangements/shuffling
- Word wheel
- ABC problem
- Sattolo cycle
- Knuth shuffle
- Ordered words
- Superpermutation minimisation
- Textonyms (using a phone text pad)
- Anagrams
- Anagrams/Deranged anagrams
- Permutations/Derangements
- Find/Search/Determine
- ABC words
- Odd words
- Word ladder
- Semordnilap
- Word search
- Wordiff (game)
- String matching
- Tea cup rim text
- Alternade words
- Changeable words
- State name puzzle
- String comparison
- Unique characters
- Unique characters in each string
- Extract file extension
- Levenshtein distance
- Palindrome detection
- Common list elements
- Longest common suffix
- Longest common prefix
- Compare a list of strings
- Longest common substring
- Find common directory path
- Words from neighbour ones
- Change e letters to i in words
- Non-continuous subsequences
- Longest common subsequence
- Longest palindromic substrings
- Longest increasing subsequence
- Words containing "the" substring
- Sum of the digits of n is substring of n
- Determine if a string is numeric
- Determine if a string is collapsible
- Determine if a string is squeezable
- Determine if a string has all unique characters
- Determine if a string has all the same characters
- Longest substrings without repeating characters
- Find words which contains all the vowels
- Find words which contain the most consonants
- Find words which contains more than 3 vowels
- Find words whose first and last three letters are equal
- Find words with alternating vowels and consonants
- Formatting
- Substring
- Rep-string
- Word wrap
- String case
- Align columns
- Literals/String
- Repeat a string
- Brace expansion
- Brace expansion using ranges
- Reverse a string
- Phrase reversals
- Comma quibbling
- Special characters
- String concatenation
- Substring/Top and tail
- Commatizing numbers
- Reverse words in a string
- Suffixation of decimal numbers
- Long literals, with continuations
- Numerical and alphabetical suffixes
- Abbreviations, easy
- Abbreviations, simple
- Abbreviations, automatic
- Song lyrics/poems/Mad Libs/phrases
- Mad Libs
- Magic 8-ball
- 99 bottles of beer
- The Name Game (a song)
- The Old lady swallowed a fly
- The Twelve Days of Christmas
- Tokenize
- Text between
- Tokenize a string
- Word break problem
- Tokenize a string with escaping
- Split a character string based on change of character
- Sequences
11l
Character literals:
V c = Char(‘a’)
Regular string literals are enclosed in double quotes, and use \ to delimit special characters:
"foo\nbar"
Raw string literals are enclosed in paired single quotation marks:
‘foo
bar’
If raw string literal should contains unpaired single quotation marks, then balancing of raw string should be performed:
'‘‘don’t’ // the same as "don’t"
6502 Assembly
Strings are enclosed in double quotes.
db "Hello World"
Any typed character in double quotes is assembled as the ASCII equivalent of that character. Therefore the following two data blocks are equivalent:
db "Hello World"
db $48,$65,$6c,$6c,$6f,$20,$57,$6f,$72,$6c,$64
When using a single-character literal as an operand for an instruction, it MUST have a # in front, or else the CPU will treat it as a pointer being dereferenced rather than a numeric constant. (We've all made this mistake at least once without realizing it.)
LDA #'A' ;load ascii code of "A" into the accumulator.
LDA 'A' ;load the byte stored at memory address 0x41 into the accumulator.
The assembler typically assumes nothing with regard to special characters. A \n
will be interpreted literally, for example. How special characters are handled depends on the printing routine of the hardware's BIOS, or one created by the programmer. If your printing routine is able to support a null terminator and ASCII control codes, the following represents "Hello World" with the new line command and null terminator:
db "Hello World",13,10,0
Creating your own printing routine is a bit out of the scope of this task but here's a simple demonstration that supports the \n and null termination:
PrintString:
lda (StringPtr),y
beq Terminated
cmp #'\' ; a single ascii character is specified in single quotes.
beq HandleSpecialChars
jsr PrintChar ;unimplemented print routine
iny ;next character
jmp PrintString ;back to top
Terminated:
rts ;exit
HandleSpecialChars:
iny ;next char
lda (StringPtr),y
cmp #'n'
beq NextLine ;unimplemented new line routine, it ends in "JMP DoneSpecialChar."
;Typically this would reset the x cursor and increment the y cursor, which are software variables that
;get converted to a VRAM address in some other routine.
DoneSpecialChar:
iny
jmp PrintString ;jump back to top. Notice that neither the backslash nor the character after it were actually printed.
68000 Assembly
Strings are enclosed in double quotes. C places a null terminator at the end of the string for you; in 68000 Assembly you have to type it manually (unless your assembler has an .ASCIZ
directive or equivalent, and not all do).
DC.B "Hello World",0
EVEN
Any typed character in double quotes is assembled as the ASCII equivalent of that character. Therefore the following two data blocks are equivalent:
DC.B "Hello World",0
EVEN
DC.B $48,$65,$6c,$6c,$6f,$20,$57,$6f,$72,$6c,$64,$00
EVEN
When using a string literal as an operand for an instruction, it must begin with #, otherwise it will be treated as a pointer being dereferenced rather than the numeric constant you intended.
MOVE.L #'SEGA',D0 ;load the string "SEGA" into D0
MOVE.L '0000',D0 ;load the 32-bit value at address 0x00303030 (the most significant byte is always treated as zero,
;because the 68000 only has a 24-bit address space.
The assembler typically assumes nothing with regard to special characters. How special characters are handled depends on the printing routine of the hardware's BIOS, or in the case of embedded hardware with no BIOS or a very limited one like the Sega Genesis, the printing routine created by the programmer. By default, there is no support for any control codes unless you add it in yourself.
Ada
Single character literals require single quotes
ch : character := 'a';
String literals use double quotes
msg : string := "hello world";
empty : string := ""; -- an empty string
The length of a string in Ada is equal to the number of characters in the string. Ada does not employ a terminating null character like C. A string can have zero length, but zero length strings are not often used. Ada's string type is a fixed length string. It cannot be extended after it is created. If you need to extend the length of a string you need to use either a bounded string, which has a pre-determined maximum length, similar to C strings, or an unbounded string which can expand or shrink to match the data it contains.
Aime
Aime has no character representation, but it allows single quoted character constants. Their implied typed is integer.
integer c;
c = 'z';
String literals are double quoted.
text s;
s = "z";
ALGOL 68
In ALGOL 68 a single character (CHAR), character arrays ([]CHAR) and strings (STRING) are contained in double quotes. ALGOL 68 also has FORMAT strings which are contained between dollar ($) symbols.
CHAR charx = "z";
Strings are contained in double quotes.
[]CHAR charxyz = "xyz";
STRING stringxyz = "xyz";
FORMAT twonewlines = $ll$, threenewpages=$ppp$, fourbackspaces=$bbbb$;
Note: When only uppercase characters sets are available (eg on computers with only 6 bits per "byte") the single quote can used to denote a reserved word. eg
.PR QUOTE .PR
[]'CHAR' CHARXYZ = "XYZ";
The STRING type is simply a FLEX array of CHAR.
MODE STRING = FLEX[1:0]CHAR;
ALGOL 68 also has raw strings called BYTES, this type is a fixed width packed array of CHAR.
BYTES bytesabc = bytes pack("abc");
A string quote character is inserted in a string when two quotes are entered, eg:
STRING stringquote = """I'll be back."" - The Terminator";
A string can span lines, but cannot contain newlines. String literals are concatenated when compiled:
STRING linexyz := "line X;" +
"line Y;" +
"line Z;";
ALGOL 68 uses FORMATs for doing more advanced manipulations. For example given:
FILE linef; STRING line;
associate(linef, line);
Instead of using preprocessor macros ALGOL 68 can do FORMAT variable replacement within FORMATs at run time.
FORMAT my_symbol = $"SYMBOL"$;
FORMAT foo = $"prefix_"f(my_symbol)"_suffix"$;
putf(linef ,foo);
In standard ALGOL 68 a "book" is a file. A book is composed of pages and lines and therefore a FORMAT be used for inserting backspaces, space, newlines and newpages into books.
INT pages=100, lines=25, characters=80;
FILE bookf; FLEX[pages]FLEX[lines]FLEX[characters]CHAR book;
associate(bookf, book);
# following putf inserts the string " Line 4 indented 5" on page 3 #
putf(bookf, $3p"Page 3"4l5x"Line 4 indented 5"$)
Note: ALGOL 68G does not implement newpage and backspace.
ALGOL W
begin
% String literals are enclosed in double-quotes in Algol W. %
% There isn't a separate character type but strings of lenghth one can %
% be used instead. %
% There are no escaping conventions used in string literals, except that %
% in order to have a double-quote character in a string, two double %
% quotes must be used. %
% Examples: %
% write a single character %
write( "a" );
% write a double-quote character %
write( """" );
% write a multi-character string - note the "\" is not an escape %
% and a\nb will appear on the output, not a and b on separate lines %
write( "a\nb" );
end.
- Output:
a " a\nb
ARM Assembly
/* ARM assembly Raspberry PI */
/* program stringsEx.s */
/* Constantes */
.equ STDOUT, 1 @ Linux output console
.equ EXIT, 1 @ Linux syscall
.equ WRITE, 4 @ Linux syscall
/* Initialized data */
.data
szMessString: .asciz "String with final zero \n"
szMessString1: .string "Other string with final zero \n"
sString: .ascii "String without final zero"
.byte 0 @ add final zero for display
sLineSpaces: .byte '>'
.fill 10,1,' ' @ 10 spaces
.asciz "<\n" @ add <, CR and final zero for display
sSpaces1: .space 10,' ' @ other 10 spaces
.byte 0 @ add final zero for display
sCharA: .space 10,'A' @ curious !! 10 A with space instruction
.asciz "\n" @ add CR and final zero for display
cChar1: .byte 'A' @ character A
cChar2: .byte 0x41 @ character A
szCarriageReturn: .asciz "\n"
/* UnInitialized data */
.bss
/* code section */
.text
.global main
main:
ldr r0,iAdrszMessString
bl affichageMess @ display message
ldr r0,iAdrszMessString1
bl affichageMess
ldr r0,iAdrsString
bl affichageMess
ldr r0,iAdrszCarriageReturn
bl affichageMess
ldr r0,iAdrsLineSpaces
bl affichageMess
ldr r0,iAdrsCharA
bl affichageMess
100: @ standard end of the program
mov r0, #0 @ return code
mov r7, #EXIT @ request to exit program
svc 0 @ perform system call
iAdrszMessString: .int szMessString
iAdrszMessString1: .int szMessString1
iAdrsString: .int sString
iAdrsLineSpaces: .int sLineSpaces
iAdrszCarriageReturn: .int szCarriageReturn
iAdrsCharA: .int sCharA
/******************************************************************/
/* display text with size calculation */
/******************************************************************/
/* r0 contains the address of the message */
affichageMess:
push {r0,r1,r2,r7,lr} @ save registers
mov r2,#0 @ counter length */
1: @ loop length calculation
ldrb r1,[r0,r2] @ read octet start position + index
cmp r1,#0 @ if 0 its over
addne r2,r2,#1 @ else add 1 in the length
bne 1b @ and loop
@ so here r2 contains the length of the message
mov r1,r0 @ address message in r1
mov r0,#STDOUT @ code to write to the standard output Linux
mov r7, #WRITE @ code call system "write"
svc #0 @ call system
pop {r0,r1,r2,r7,lr} @ restaur registers
bx lr @ return
Arturo
str: "Hello world"
print [str "->" type str]
fullLineStr: « This is a full-line string
print [fullLineStr "->" type fullLineStr]
multiline: {
This
is a multi-line
string
}
print [multiline "->" type multiline]
verbatim: {:
This is
a verbatim
multi-line
string
:}
print [verbatim "->" type verbatim]
- Output:
Hello world -> :string This is a full-line string -> :string This is a multi-line string -> :string This is yet another multi-line string -> :string
AutoHotkey
unicode
"c" ; character
"text" ; string
hereString = ; with interpolation of %variables%
(
"<>"
the time is %A_Now%
\!
)
hereString2 = ; with same line comments allowed, without interpolation of variables
(Comments %
literal %A_Now% ; no interpolation here
)
AWK
In awk, strings are enclosed using doublequotes. Characters are just strings of length 1.
c = "x"
str= "hello"
s1 = "abcd" # simple string
s2 = "ab\"cd" # string containing a double quote, escaped with backslash
print s1
print s2
- Output:
Concatenation
$ awk 'BEGIN{c="x"; s="hello";s1 = "abcd"; s2 = "ab\"cd"; s=s c; print s; print s1; print s2}'
hellox
Axe
Character literal:
'A'
String literal:
"ABC"
Note that string literals are only null-terminated if they are assigned to a variable (e.g. Str1).
BASIC
Traditional BASIC implementations do not use literal character notation within a string or here document notation. However, literal characters can be referenced using their character code and these can be added to strings as required. Here we use the ASCII code for doublequotes to get the characters into a string:
10 LET Q$=CHR$(34): REM DOUBLEQUOTES
20 LET D$=Q$+Q$: REM A PAIR OF DOUBLEQUOTES
30 LET S$=Q$+"THIS IS A QUOTED STRING"+Q$
40 PRINT Q$;"HELLO";Q$:REM ADD QUOTES DURING OUTPUT
Most modern BASIC implementations don't differentiate between characters and strings -- a character is just a string of length 1.
Few (if any) BASIC implementations support variables inside strings; instead, they must be handled outside the quotes.
Most BASICs don't support escaping inside the string, with the possible exception of the VB-style ""
for a single quotation mark (not supported by most BASICs).
To insert otherwise-unprintable characters requires the use of CHR$
.
(One notable exception is FreeBASIC, which supports C-style escaping with OPTION ESCAPE
.)
Strings can optionally be declared as being a certain length, much like C strings.
DIM c AS STRING * 1, s AS STRING
c = "char" 'everything after the first character is silently discarded
s = "string"
PRINT CHR$(34); s; " data "; c; CHR$(34)
- Output:
"string data c"
Applesoft BASIC
M$ = CHR$(13) : Q$ = CHR$(34)
A$ = "THERE ARE" + M$
A$ = A$ + "NO " + Q$ + "HERE" + Q$ + " STRINGS."
? A$
IS-BASIC
100 PRINT CHR$(34)
110 PRINT """"
120 PRINT "This is a ""quoted string""."
BASIC256
print "Hello, World."
print chr(34); "Hello, World." & chr(34)
print "Tom said," + "'The fox ran away.'"
ZX Spectrum Basic
The ZX Spectrum supports the use of CHR$(34). Alternatively, it is possible to print the doublequotes, by adding an extra pair of doublequotes:
10 REM Print some quotes
20 PRINT CHR$(34)
30 REM Print some more doublequotes
40 PRINT """"
50 REM Output the word hello enclosed in doublequotes
60 PRINT """Hello"""
uBasic/4tH
uBasic/4tH supports the inclusion of doublequotes by allowing the escape \q
in almost every string literal.
Print "This is a ";Chr(Ord("\q"));"quoted string";Chr(Ord("\q"))
Print "This is a \qquoted string\q"
a := "This is a \qquoted string\q" : Print Show(a)
BBC BASIC
Quoted (literal) strings consist of 8-bit characters and support both ANSI and UTF-8 encodings; they may not contain 'control' characters (0x00 to 0x1F). The only special character is the double-quote " which must be escaped as "". There is no special representation for a single character (it is just a string of length one). 'Here strings' are not supported.
PRINT "This is a ""quoted string"""
- Output:
This is a "quoted string"
bc
The double-quote " starts a literal string which ends at the next double-quote. Thus strings can span multiple lines and cannot contain a double-qoute (there is no escaping mechanism).
Characters are just strings of length one.
Befunge
The double quote character (") enters a string literal mode, where ASCII values of characters encountered in the current instruction pointer direction up to the next quote are pushed onto the stack. Thus, any character may be used in a string except for a quote (ascii 34), which may be pushed using 57*1-. Note: since you are pushing the string onto a stack, you usually want to define the string in reverse order so that the first character is on top.
"gnirts">:#,_@
Bracmat
Strings of any length can always be surrounded by quotes.
They must be surrounded by quotes if the string contains white space characters or one of the characters =.,|&:+*^'$_;{}
or character sequences \D
or \L
.
They must also be surrounded by quotes if they start with one or more characters from the set [~/#<>%@?!-
.
Inside strings the characters "
and \
must be escaped with a backslash \
.
White space characters for carriage return, newline and tabulator can be expressed as \r
, \n
and \t
, respectively.
Escape sequences need not be enclosed in quotes.
A string expression prepended with @
or %
has no escape sequences: all characters except quotes are taken litterally.
These are 10 examples of valid string expressions.
(The last example is a multiline string.)
- Examples:
string "string" stri\t-\tng\r\n "-10" "+10" "{a*b}" ".,|&:+*^'$_" "[~/#<>%@?!-" string[~/#<>%@?!- "str; ing .,|&:+*^'$_ "
C
In C, single characters are contained in single quotes.
char ch = 'z';
Strings are contained in double quotes.
char str[] = "z";
This means that 'z' and "z" are different. The former is a character while the latter is a string, an array of two characters: the letter 'z' and the string-terminator null '\0'.
C has no raw string feature (please define). C also has no built-in mechanism for expanding variables within strings.
A string can span lines. Newlines can be added via backslash escapes, and string literals are concatenated when compiled:
char lines[] = "line 1\n"
"line 2\n"
"line 3\n";
C can use library functions such as sprintf for doing formatted replacement within strings at run time, or preprocessor concatenation to build string literals at compile time:
#define FOO "prefix_"##MY_SYMBOL##"_suffix"
C#
C# uses single quotes for characters and double quotes for strings just like C.
C# supports verbatim strings. These begin with @" and end with ". Verbatim quotes may contain line breaks and so verbatim strings and here-strings overlap.
string path = @"C:\Windows\System32";
string multiline = @"Line 1.
Line 2.
Line 3.";
C++
Quoting is essentially the same in C and C++.
In C++11, it is also possible to use so-called "Raw Strings":
auto strA = R"(this is
a newline-separated
raw string)";
Clojure
Character literals are prefixed by a backslash:
[\h \e \l \l \o] ; a vector of characters
\uXXXX ; where XXXX is some hex Unicode code point
\\ ; the backslash character literal
There are also identifiers for special characters:
\space
\newline
\tab
\formfeed
\return
\backspace
Clojure strings are Java Strings, and literals are written in the same manner:
"hello world\r\n"
COBOL
Strings can be enclosed in either single quotes or double quotes. There is no difference between them.
"This is a valid string."
'As is this.'
Character literals are strings of two-digit hexadecimal numbers preceded by an x.
X"00" *> Null character
X"48656C6C6F21" *> "Hello!"
There are also figurative constants which are equivalent to certain string literals:
HIGH-VALUE HIGH-VALUES *> Equivalent to (a string of) X"FF".
LOW-VALUE LOW-VALUES *> " " X"00".
NULL *> " " X"00".
QUOTE QUOTES *> " " double-quote character.
SPACE SPACES *> " " space.
ZERO ZEROS ZEROES *> " " zero.
Common Lisp
Character literals are referenced using a hash-backslash notation. Strings are arrays or sequences of characters and can be declared using double-quotes or constructed using other sequence commands.
(let ((colon #\:)
(str "http://www.rosettacode.com/"))
(format t "colon found at position ~d~%" (position colon str)))
D
Character literals:
char c = 'a';
Regular strings support C-style escape sequences.
auto str = "hello"; // UTF-8
auto str2 = "hello"c; // UTF-8
auto str3 = "hello"w; // UTF-16
auto str4 = "hello"d; // UTF-32
Literal string (escape sequences are not interpreted):
auto str = `"Hello," he said.`;
auto str2 = r"\n is slash-n";
Specified delimiter string:
// Any character is allowed after the first quote;
// the string ends with that same character followed
// by a quote.
auto str = q"$"Hello?" he enquired.$";
// If you include a newline, you get a heredoc string:
auto otherStr = q"EOS
This is part of the string.
So is this.
EOS";
Token string:
// The contents of a token string must be valid code fragments.
auto str = q{int i = 5;};
// The contents here isn't a legal token in D, so it's an error:
auto illegal = q{@?};
Hex string:
// assigns value 'hello' to str
auto str = x"68 65 6c 6c 6f";
Delphi
var
lChar: Char;
lLine: string;
lMultiLine: string;
begin
lChar := 'a';
lLine := 'some text';
lMultiLine := 'some text' + #13#10 + 'on two lines';
DWScript
Strings are either single or double quote delimited, if you want to include the delimiter in the string, you just double it. Specific character codes (Unicode) can be specified via # (outside of the string).
const s1 := 'quoted "word" in string';
const s2 := "quoted ""word"" in string"; // sames as s1, shows the doubling of the delimiter
const s2 := 'first line'#13#10'second line'; // CR+LF in the middle
Dyalect
Strings in Dyalect are double quote delimited (and characters are single quote delimited). Both support escape codes:
let c = '\u0020' //a character
let str = "A string\non several lines!\sAnd you can incorporate expressions: \(c)!"
Dyalect also supports multiline strings:
let long_str = <[first line
second line
third line]>
Multiline strings do not support escape codes.
Déjà Vu
local :s "String literal"
local :s2 "newline \n carriage return \r tab \t"
!print "backslash \\ quote \q decimal character \{8364}"
- Output:
backslash \ quote " decimal character €
DuckDB
DuckDB conforms to the SQL standard of string literals (see #SQL elsewhere on this page) but adds some conveniences:
1. Consecutive single-quoted string literals separated only by whitespace that contains at least one newline are implicitly concatenated.
2. A string literal with special characters (backspace, formfeed, newline, carriage return, tab) can be specified using the notation: E'....' or e'.....'.
For example, using the CLI:
D .mode line D SELECT E'''Hello duck!''\nDuckDB' as saying; saying = 'Hello duck!' DuckDB D
3. Double-dollar-quoted string literals are also supported, e.g.
D SELECT $$Hello world$$ as greeting; ┌──────────────┐ │ greeting │ │ varchar │ ├──────────────┤ │ Hello\nworld │ └──────────────┘ D
The `format` function can be used to interpolate expressions within string literals.
E
E has three sorts of quotes: strings, characters, and quasiliterals.
'T' # character
"The quick brown fox" # string
`The $kind brown fox` # "simple" quasiliteral
term`the($adjectives*, fox)` # "term" quasiliteral
Strings and characters use syntax similar to Java; double and single quotes, respectively, and common backslash escapes.
Quasiliterals are a user-extensible mechanism for writing any type of object "literally" in source, with "holes" for interpolation or pattern-matching. The fourth example above represents a Term object (terms are a tree language like XML or JSON), with the items from the variable adjectives spliced in.
Quasiliterals can be used for strings as well. The third example above is the built-in simple interpolator, which also supports pattern matching. There is also a regular-expression quasi-pattern:
? if ("<abc,def>" =~ `<@a,@b>`) { [a, b] } else { null }
# value: ["abc", "def"]
? if (" >abc, def< " =~ rx`\W*(@a\w+)\W+(@b\w+)\W*`) { [a, b] } else { null }
# value: ["abc", "def"]
EasyLang
Strings are always enclosed in double quotes ("). Unicode is also supported.
print "EasyLang"
print "简"
Ela
Ela has both characters:
c = 'c'
and strings:
str = "Hello, world!"
Both support C-style escape codes:
c = '\t'
str = "first line\nsecond line\nthird line"
Also Ela supports verbatim strings with the following syntax:
vs = <[This is a
verbatim string]>
Elena
ELENA 4.x :
var c := $65; // character
var s := "some text"; // UTF-8 literal
var w := "some wide text"w; // UTF-16 literal
var s2 := "text with ""quotes"" and
two lines";
Elixir
String
Strings are between double quotes; they're represented internally as utf-8 encoded bytes and support interpolation.
IO.puts "Begin String \n============"
str = "string"
str |> is_binary # true
While internally represented as a sequence of bytes, the String module splits the codepoints into strings.
str |> String.codepoints
The bytes can be accessed by appending a null byte to the string
str <> <<0>>
Strings can be evaluated using ?
before a character in the command line or in a string, then evaluating the string
?a # 97
Code.eval_string("?b") # 98
Code.eval_string("?ł") # 322
Char Lists
Char lists are simply lists of characters. Elixir will attempt to convert number values to characters if a string could be formed from the values. Char lists represent characters as single quotes and still allow for interpolation.
IO.inspect "Begin Char List \n============="
[115, 116, 114, 105, 110, 103]
ch = "hi"
'string #{ch}'
Again, since 0 cannot be rendered as a character, adding it to a char list will return the char list
'string #{ch}'++[0]
- Output:
Begin String
============
"string"
true
["s", "t", "r", "i", "n", "g"]
<<115, 116, 114, 105, 110, 103, 0>>
97
98
322
Begin Char List
===============
'string'
'string hi'
[115, 116, 114, 105, 110, 103, 32, 104, 105, 0]
Emacs Lisp
Strings
The only string literal is a double-quote
"This is a string."
Backslash gives various special characters similar to C, such as
\n
for newline and \"
for a literal
double-quote. \\
is a literal backslash. See "Syntax
for Strings" in the elisp manual.
Characters
A character is an integer in current Emacs. (In the past character
was a separate type.) ?
is the read syntax.
?z ;=> 122
?\n ;=> 10
See "Basic Char Syntax" in the elisp manual.
Erlang
Erlang strings are lists containing integer values within the range of the ASCII or (depending on version and settings) Unicode characters.
"This is a string".
[$T,$h,$i,$s,$ ,$a,$ ,$s,$t,$r,$i,$n,$g,$,,$ ,$t,$o,$o].
Characters are represented either as literals (above) or integer values.
97 == $a. % => true
With the string syntax, characters can be escaped with \.
"\"The quick brown fox jumps over the lazy dog.\"".
F#
let n= 'N'
let i="Name=\"Nigel Galloway\"\n"
let g= @"Name=""Nigel Galloway""\n"
let e="Nigel
Galloway"
let l= """Name="Nigel Galloway"\n"""
printfn "%c\n%s\n%s\n%s\n%s" n i g e l
- Output:
N Name="Nigel Galloway" Name="Nigel Galloway"\n Nigel Galloway Name="Nigel Galloway"\n
Factor
A basic character:
CHAR: a
Characters are Unicode code points (integers in the range [0-2,097,152]).
CHAR:
is a parsing word that takes a literal character, escape code, or Unicode code point name and adds a Unicode code point to the parse tree.
CHAR: x ! 120
CHAR: \u000032 ! 50
CHAR: \u{exclamation-mark} ! 33
CHAR: exclamation-mark ! 33
CHAR: ugaritic-letter-samka ! 66450
Strings are represented as fixed-size mutable sequences of Unicode code points.
A basic string:
"Hello, world!"
We can take a look under the hood:
"Hello, world!" { } like ! { 72 101 108 108 111 44 32 119 111 114 108 100 33 }
Both CHAR:
and strings support the following escape codes:
Escape code | Meaning |
---|---|
\\ | \ |
\s | a space |
\t | a tab |
\n | a newline |
\r | a carriage return |
\b | a backspace (ASCII 8) |
\v | a vertical tab (ASCII 11) |
\f | a form feed (ASCII 12) |
\0 | a null byte (ASCII 0) |
\e | escape (ASCII 27) |
\" | " |
\xxx | The Unicode code point with hexadecimal number xxx |
\uxxxxxx | The Unicode code point with hexadecimal number xxxxxx |
\u{name} | The Unicode code point named name |
Some examples of strings with escape codes:
"Line one\nLine two" print
- Output:
Line one Line two
Putting quotation marks into a string:
"\"Hello,\" she said." print
- Output:
"Hello," she said.
Strings can span multiple lines. Newlines are inserted where they occur in the literal.
"2\u{superscript-two} = 4
2\u{superscript-three} = 8
2\u{superscript-four} = 16" print
- Output:
2² = 4 2³ = 8 2⁴ = 16
The multiline
vocabulary provides support for verbatim strings and here-strings.
A verbatim string:
USE: multiline
[[ escape codes \t are literal \\ in here
but newlines \u{plus-minus-sign} are still
inserted " for each line the string \" spans.]] print
- Output:
escape codes \t are literal \\ in here but newlines \u{plus-minus-sign} are still inserted " for each line the string \" spans.
Note that the space after [[
is necessary for the Factor parser to recognize it as a word. "
is one of very few special cases where this is not necessary. The space will not be counted as part of the string.
A here-string:
USE: multiline
HEREDOC: END
Everything between the line above
and the final line (a user-defined token)
is parsed into a string where whitespace
is significant.
END
print
- Output:
Everything between the line above and the final line (a user-defined token) is parsed into a string where whitespace is significant.
STRING:
is similar to HEREDOC:
except instead of immediately placing the string on the data stack, it defines a word that places the string on the data stack when called.
USE: multiline
STRING: random-stuff
ABC
123
"x y z
;
random-stuff print
- Output:
ABC 123 "x y z
Finally, the interpolate
vocabulary provides support for interpolating lexical variables, dynamic variables, and data stack values into strings.
USING: interpolate locals namespaces ;
"Sally" "name" set
"bicycle"
"home"
[let
"crying" :> a
[I ${name} crashed her ${1}. Her ${1} broke.
${name} ran ${} ${a}.
I]
]
- Output:
Sally crashed her bicycle. Her bicycle broke. Sally ran home crying.
${}
consumes values from the stack. With a number n inside, you can reference (and re-reference!) the data stack value n places from the top of the data stack.
Forth
In the interpreter:
char c emit
s" string" type
In the compiler:
: main
[char] c emit
s" string" type ;
Strings may contain any printable character except a double quote, and may not span multiple lines. Strings are done via the word S" which parses ahead for a terminal quote. The space directly after S" is thus not included in the string.
GNU Forth has a prefix syntax for character literals, and another string literal word S\" which allows escaped characters, similar to C.
'c emit
s\" hello\nthere!"
Fortran
First Fortran (1958) did not offer any means to manipulate text except via the H (for Hollerith) code in FORMAT statements of the form nH where n was an integer that counted the exact numbers of characters following the H, any characters, that constituted the text literal. Miscounts would cause a syntax error, if you were lucky. This would be used for output to annotate the numbers, but consider the following:
DIMENSION ATWT(12)
PRINT 1
1 FORMAT (12HElement Name,F9.4)
DO 10 I = 1,12
READ 1,ATWT(I)
10 PRINT 1,ATWT(I)
END
Evidently, the syntax highlighter here does not recognise the Hollerith style usage. Nor do some compilers, even if in its original home within FORMAT statements.
The first PRINT statement writes out a heading, here with lower case letters as an anachronism. Then the loop reads a deck of cards containing the name of an element and its atomic weight into an array ATWT, but the special feature is that the first twelve characters of each card replace the text in the FORMAT statement, and thus the following PRINT statement shows the name of the element followed by its atomic weight as just read.
Fortran IV introduced a text literal, specified within apostrophes, with two apostrophes in a row indicating an apostrophe within the text. Later, either an apostrophe or a double quote could be used to start a text string (and the same one must be used to end it) so that if one or the other were desired within a text literal, the other could be used as its delimiters. If both were desired, then there would be no escape from doubling for one. Because spaces are significant within text literals, a long text literal continued on the next line would have the contents of column seven of the continuation line immediately following the contents of column 72 of the continued line - except that (for some compilers reading disc files) if such lines did not extend to column 72 (because trailing spaces were trimmed from the records) rather less text would be defined. So, even though this is in fixed-format (or card image) style, again misinterpreted by the syntax highlighter,
BLAH = "
1Stuff"
might be the equivalent of only BLAH = "Stuff"
instead of defining a text literal with many leading spaces. F90 formalised an opportunity for free-format source files; many compilers had also allowed usage beyond column 72.
Within the text literal, any character whatever may be supplied as text grist, according to the encodement recognised by the card reader as this was a fixed-format file - cards have an actual physical size. This applied also to source text held in disc files, as they were either fixed-size records or, for variable-length records, records had a length specification and the record content was not involved. Variable-length records were good for omitting the storage of the trailing spaces on each line, except that the sequence numbers were at the end of the line! In this case they might be omitted (unlike a card deck, a disc file's records are not going to be dropped) or there may be special provision for them to be at the start of each line with the source text's column one staring in column nine of the record. But, for the likes of paper tape, the question "How long is a record?" has no natural answer, and record endings were marked by a special symbol. Such a symbol (or symbol sequence) could not appear within a record, such as within a text literal and be taken as a part of the text. This style has been followed by the ASCII world, with variously CR, CRLF, LFCR and CR sequences being used to mark end-of-record. Such characters cannot be placed within a text literal, but the CHAR(n) function makes them available in character expressions. Some compilers however corrupt the "literal" nature of text literals by allowing escape sequences to do so, usually in the style popularised by C, thus \n, and consequently, \\ should a single \ be desired.
Some examples, supposing that TEXT is a CHARACTER variable.
TEXT = 'That''s right!' !Only apostrophes as delimiters. Doubling required.
TEXT = "That's right!" !Chose quotes, so that apostrophes may be used freely.
TEXT = "He said ""That's right!""" !Give in, and use quotes for a "quoted string" source style.
TEXT = 'He said "That''s right!"' !Though one may dabble in inconsistency.
TEXT = 23HHe said "That's right!" !Some later compilers allowed Hollerith to escape from FORMAT.
A similar syntax enables the specification of hexadecimal, octal or binary sequences, as in X = Z"01FE"
for hexadecimal (the "H" code already being used for "Hollerith" even if the H-usage is not supported by the compiler) but this is for numerical values, not text strings. While one could mess about with EQUIVALENCE statements, numbers fill up from the right while text strings fill from the left and there would be "endian" issues as well, so it is probably not worth the bother. Just use the CHAR function in an expression, as in
TEXT = "That's"//CHAR(10)//"right!" !For an ASCII linefeed (or newline) character.
Which may or may not be acted upon by the output device. A lineprinter probably would ignore a linefeed character but a teletype would not - it would roll the printing carriage one line up without returning to the column one position, thus the usage LFCR (or CRLF) to add the carriage return action. Some systems regard the LF as also implying a CR and for these the notation \n for "newline" is mnemonic even though there is no "newline" character code in ASCII - though there is in EBCDIC. Display screens do not handle glyph construction via overprinting though teletypes (and lineprinters) do. Similarly, a display screen may or may not start a new screen with a formfeed character and a lineprinter won't start a new page - at least if attached to a mainframe computer.
FreeBASIC
Print "Hello, World."
Print Chr(34); "Hello, World." & Chr(34)
Print "Tom said, ""The fox ran away."""
Print "Tom said," + "'The fox ran away.'"
friendly interactive shell
echo Quotes are optional in most cases.
echo
echo 'But they are when using either of these characters (or whitespace):'
echo '# $ % ^ & * ( ) { } ; \' " \\ < > ?'
echo
echo Single quotes only interpolate \\ and \' sequences.
echo '\In \other \cases, \backslashes \are \preserved \literally.'
echo
set something variable
echo "Double quotes interpolates \\, \" and \$ sequences and $something accesses."
FurryScript
A name literal starts with ` and is one word long; it functions like a string.
A normal string literal uses angle brackets (< and >) around it. You can have additional < > pairs inside (which can nest to any level) in order to represent subroutine calls (they are not called where the string literal appears; they are called only once it is processed).
A story text uses {|| and ||} around it, and can contain any text, with no escapes supported.
All three kinds are string literals.
FutureBasic
@"Hello, world!"
GAP
IsChar('a');
# true
IsString("abc");
# true
IsString('a');
# false
IsChar("a");
# false
gecho
'a outascii
Just one character.
'yo...dawg. print
A string.
Go
See the language specification sections on rune literals and string literals.
In Go, character literals are called "rune literals" and can be any single valid Unicode code point. They are written as an integer value or as text within single quotes.
ch := 'z'
ch = 122 // or 0x7a or 0172 or any other integer literal
ch = '\x7a' // \x{2*hex}
ch = '\u007a' // \u{4*hex}
ch = '\U0000007a' // \U{8*hex}
ch = '\172' // \{3*octal}
A rune literal results in an untyped integer.
When used in a typed constant or stored in a variable, usually the type is either byte
or rune
to distinguish character values from integer values.
These are aliases for uint8
and int32
respectively, but like other integer types in Go, they are distinct and require an explicate cast.
ch := 'z' // ch is type rune (an int32 type)
var r rune = 'z' // r is type rune
var b byte = 'z' // b is type byte (an uint8 type)
b2 := byte('z') // equivalent to b
const z = 'z' // z is untyped, it may be freely assigned or used in any integer expression
b = z
r = z
ch2 := z // equivalent to ch (type rune)
var i int = z
const c byte = 'z' // c is a typed constant
b = c
r = rune(c)
i = int(c)
b3 := c // equivalent to b
Strings literals are are either interpreted or raw.
Interpreted string literals are contained in double quotes. They may not contain newlines but may contain backslash escapes.
str := "z"
str = "\u007a"
str = "two\nlines"
This means that 'z' and "z" are different. The former is a character while the latter is a string.
Unicode may be included in the string literals. They will be encoded in UTF-8.
str := "日本語"
Raw string literals are contained within back quotes. They may contain any character except a back quote. Backslashes have no special meaning.
`\n` == "\\n"
Raw string literals, unlike regular string literals, may also span multiple lines.
The newline is included in the string (but not any '\r'
characters):
`abc
def` == "abc\ndef", // never "abc\r\ndef" even if the source file contains CR+LF line endings
Go raw string literals serve the purpose of here-strings in other languages. There is no variable expansion in either kind of string literal (the Go text/template package provides something like variable expansion).
Groovy
In Groovy, unlike in Java, a String literal is delimited with single quotes (apostrophes(')).
def string = 'Able was I'
There is a double quote (quotation mark(")) delimited syntax in Groovy, but it represents an expression construct called a GString (I know, I know). Inside of a GString, sub-expression substitution of the form ${subexpression} may take place. Thus the following results:
def gString = "${string} ere I saw Elba"
println gString
//Outputs:
//Able was I ere I saw Elba
UNIX Shell command line users should recognize these forms of syntax as strong ('-delimited) and weak ("-delimited) quoting. And like UNIX Shell weak quoting syntax, the evaluated subexpression part of the GString syntax loses its special meaning when preceded by a backslash (\):
def gString2 = "1 + 1 = ${1 + 1}"
assert gString2 == '1 + 1 = 2'
def gString3 = "1 + 1 = \${1 + 1}"
assert gString3 == '1 + 1 = ${1 + 1}'
Groovy also supports multi-line String literals and multi-line GString expressions.
def multiLineString = '''
A man
A plan
A canal
'''
def multiLineGString = """
${multiLineString.trim()}:
Panama!
"""
println multiLineGString
//Outputs:
//
//A man
//A plan
//A canal:
//Panama!
//
UNIX Shell programmers should recognize these forms of syntax as similar in function to the strong and weak forms of Here Document syntax.
Both String literals and GString expressions support a number of special characters (usually non-printable characters) which consist of a single character preceded by a backslash (hence \X), or a 4-hexadecimal-digit UNICODE encoding preceded by a backslash and a lowercase "u" (hence \uXXXX).
One of these special characters is the backslash itself, denoted with in a String or GString as \\. This actually interferes with regular expression syntax in which literal backslashes play various important regular-expression-specific roles. Thus it can become quite onerous to write regular expressions using String or GString quoting syntax, since every regex backslash would have to be written as \\.
However, Groovy has a special GString syntax that uses slash (/) as a GString delimiter rather that quote ("). In this special syntax, most backslash usages that would require a double backslash in a regular String or GString require only a single backslash (\). This does not create a "regular expression object" (there is not such a thing in Groovy); however, it does evaluate to form a "regular expression ready" String, as demonstrated in the following:
def regexString = /(\[[Tt]itle\]|\[[Ss]ubject\])${10 * 5}/
assert regexString == '(\\[[Tt]itle\\]|\\[[Ss]ubject\\])50'
Javascript users (and others) will recognize the roots of this "regex-ready" syntax as a feature in their own language.
Since apostrophe is used to delimit String literals, that delimiter syntax is not available, as it is in Java, to denote single character literals (type char or Character). However, single character string literals can be converted to character literals by casting. Shown in the examples below are casting using the as operator, Java-style parenthetical casting, and forced coercion in the intialization of a variable of type char or Character.
assert 'a' instanceof String
assert ('a' as char) instanceof Character
assert ((char)'a') instanceof Character
char x = 'a'
assert x instanceof Character
Character y = 'b'
assert y instanceof Character && (x+1 == y)
As in Java, backslash is also used to mask a string delimiter. Thus the following two assignments represent strings containing a single quote and a single apostrophe respectively
def quote = "\""
def apostrophe = '\''
Of course, if you are not using GString subexpression evaluation, you can just use apostrophe delimiters to contain a quote, or quote delimiters to contain an apostrophe.
def quote2 = '"'
def apostrophe2 = "'"
assert quote == quote2
assert apostrophe == apostrophe2
Haskell
language support
Characters use single quotes, strings use double quotes. Both allow Unicode. Escape sequences start with a backslash. There are no verbatim strings, no here-strings, and no expansion of variables in strings.
Strings may be split across lines, even indented, using the 'gap' syntax:
"abcdef" == "abc\
\def"
"abc\ndef" == "abc\n\
\def"
You can also use \& which expands into nothing (but can be useful to interrupt another escape sequence).
The Haskell 98 Report section Character and String Literals has more information.
using raw-strings-qq package
using raw-strings-qq package:
{-# LANGUAGE QuasiQuotes #-}
import Text.RawString.QQ
"abc\ndef" == [r|abc
def|]
HicEst
HicEst makes no distinction between single characters and strings. One can use single quotes, or double quotes, or most non-standard characters.
CHARACTER c1='A', c2="B", c3=&C&
CHARACTER str1='single quotes', str2="double quotes", str3*100
str3 = % delimit "Nested 'strings' " if needed %
A null character CHAR(0) is printed as " ", displayed as "." in dialogs, but ends the string in Windows controls such as StatusBar or ClipBoard
str3 = 'a string' // CHAR(0) // "may contain" // $CRLF // ~ any character ~
Named literal constants in HicEst:
$TAB == CHAR(9) ! evaluates to 1 (true)
$LF == CHAR(10)
$CR == CHAR(13)
$CRLF == CHAR(13) // CHAR(10) ! concatenation
Icon and Unicon
Below is a little program to demonstrate string literals.
- Output:
size=2, type=cset, value='ab' size=4, type=string, value="aaab" size=21, type=string, value="\"aaab\b\d\e\f\n\n\n\r\t\v'\"\\\x00\x00\x03"
IDL
The single and double quotes are fairly interchangeable allowing one to use whichever isn't to be quoted (though single-quotes seem more well-behaved around integers in strings). Thus the following are both valid character-constant assignments:
a = " that's a string "
b = ' a "string" is this '
In a pinch, a character constant doesn't absolutely have to be terminated, rendering the following valid:
a = " that's a string
Duplicating either of them quotes them. Thus the following contains three single quotes and no double-quotes:
a = ' that''s a string
print,a
;==> that's a string
Things in quotes are not expanded. To get to the content of a variable, leave it unquoted:
b = 'hello'
a = b+' world
print,a
;==> hello world
Single-quoted strings of valid hex or octal digits will be expanded if followed by "x" or "o":
print,'777'x
;==> 1911
print,'777'o
;==> 511
print,'777'
;==> 777
so will be unterminated double-quoted strings if they represent valid octal numbers:
print,"777
;==> 511
print,"877
;==> 877
Note that this renders the following false (common trip-up for IDL newbies):
a = "0"
;==> Syntax error.
...because the number zero indicates that an octal number follows, but the second double-quote is not a valid octal digit.
Byte-arrays that are converted into strings are converted to the ascii-characters represented by the bytes. E.g.
crlf = string([13b,10b])
Inform 7
String literals are enclosed in double quotes. These may include raw line breaks, or expressions to be substituted enclosed in square brackets.
Home is a room. The description is "This is where you live...
...with your [number of animals in Home] pet[s]."
Single quotes in a string are translated to double quotes when they occur outside of a word: the string literal
"'That's nice,' said the captain."
will print as
"That's nice," said the captain.
Raw linebreak must be double -- single linebreaks will be collapsed unless explicitly marked with `[line break]`. In addition, leading whitespace is stripped from each line. This:
"
\
\
\
\"
will print as:
\\\\
while this:
"
[line break]\
[line break] \
[line break] \
[line break] \"
will insert line breaks and preserve the following whitespace, printing as:
\ \ \ \
There are no character literals: phrases that manipulate characters pass them as single-character strings.
J
Like C, J treats strings as lists of characters. Character literals are enclosed in single quotes, and there is no interpolation. Therefore, the only "escape" character neccessary is the single-quote itself, and within a character literal is represented by a pair of adjacent single quotes (much like in C, where within a character literal, a slash is represented by a pair of adjacent slashes).
Examples:
'x' NB. Scalar character
'string' NB. List of characters, i.e. a string
'can''t get simpler' NB. Embedded single-quote
Like VB, J can include newlines and other special characters in literals with concatentation. Also like VB, J comes with certain constants predefined for some characters:
'Here is line 1',LF,'and line two'
'On a mac, you need',CR,'a carriage return'
'And on windows, ',CRLF,'you need both'
TAB,TAB,TAB,'Everyone loves tabs!'
These constants are simply names assigned to selections from the ASCII alphabet. That is, the standard library executes lines like this:
CR =: 13 { a.
LF =: 10 { a.
CRLF =: CR,LF NB. Or just 10 13 { a.
TAB =: 9 { a.
Since these constants are nothing special, it can be seen that any variable can be similarly included in a literal:
NAME =: 'John Q. Public'
'Hello, ',NAME,' you may have already won $1,000,000'
For multiline literals, you may define an explicit noun, which is terminated by a lone )
template =: noun define
Hello, NAME.
My name is SHYSTER, and I'm here to tell
you that you my have already won $AMOUNT!!
To collect your winnings, please send $PAYMENT
to ADDRESS.
)
Simple substitution is most easily effected by using loading a standard script:
load 'strings'
name =: 'John Q. Public'
shyster =: 'Ed McMahon'
amount =: 1e6
payment =: 2 * amount
address =: 'Publisher''s Clearing House'
targets =: ;: 'NAME SHYSTER AMOUNT PAYMENT ADDRESS'
sources =: ":&.> name;shyster;amount;payment;address
message =: template rplc targets,.sources
While C-like interpolation can be effected with another:
load 'printf'
'This should look %d%% familiar \nto programmers of %s.' sprintf 99;'C'
This should look 99% familiar
to programmers of C.
Java
char a = 'a'; // prints as: a
String b = "abc"; // prints as: abc
char doubleQuote = '"'; // prints as: "
char singleQuote = '\''; // prints as: '
String singleQuotes = "''"; // prints as: ''
String doubleQuotes = "\"\""; // prints as: ""
Null characters ('\0') are printed as spaces in Java. They will not terminate a String as they would in C or C++. So, the String "this \0is \0a \0test" will print like this:
this is a test
JavaScript
A JavaScript string is a sequence of zero or more characters enclosed in either 'single quotes' or "double quotes". Neither form prevents escape sequences: "\n"
and '\n'
are both strings of length 1. There is no variable interpolation.
Unicode characters can be entered as literals or as 4 character hexadecimal escapes. The following expressions are equivalent:
(function () {
return "αβγδ 中间来点中文 🐫 אבגד"
})();
(function() {
return "\u03b1\u03b2\u03b3\u03b4 \u4e2d\u95f4\u6765\u70b9\u4e2d\u6587 \ud83d\udc2b \u05d0\u05d1\u05d2\u05d3";
})();
Note that in the case of the Emoji character above, where more than 4 hexadecimal characters are needed, ES5 requires us to separately write a pair of surrogate halves, and the String.length of such characters is 2.
ES6 introduces Unicode code point escapes such as
'\u{2F804}'
allowing direct escaping of code points up to 0x10FFFF.
ES6 also introduces template literals, which are string literals allowing embedded expressions. You can use multi-line strings and string interpolation features with them. Template literals are enclosed by the backtick (` `
) (grave accent) character instead of double or single quotes.
const multiLine = `string text line 1
string text line 2`
const expression = `expressions are also supported, using \$\{\}: ${multiLine}`
console.log(expression)
- Output:
expressions are also supported, using ${}: string text line 1 string text line 2
jq
jq supports all JSON types, including JSON strings; jq also supports "string interpolation".
The rules for constructing JSON string literals are explained elsewhere (notably at json.org), so here we'll focus on "string interpolation" -- a technique for creating JSON strings programmatically using string literals, much like ruby's "#{...}", for example. The twist is that the string literal for specifying string interpolation is (by design) not itself a valid JSON string.
Suppose that:
- s is (or is a reference to) a JSON entity (e.g. a string or a number), and
- we wish to create a JSON string that is some combination of JSON strings and the string value of s, for example: "The value of s is " + (s|tostring).
jq allows the shorthand: "The value of s is \(s)", and in general, arbitrarily many such interpolations may be made.
JSON
A JSON string literal is a sequence of zero or more Unicode characters, wrapped in double quotes, using backslash escapes. Unicode code points can be represented as a hexadecimal escape sequence, like "\u002F"
which is the same as "/"
. Multi-line strings are not supported.
Julia
Concatenation:
greet = "Hello"
whom = "world"
greet * ", " * whom * "."
Interpolation:
"$greet, $whom."
Both will output:
Hello, world.
Triple-quoted strings
str = """Hello,
world.
"""
print(str)
Will output:
Hello,
world.
Kotlin
Kotlin supports two kinds of string literals (UTF-16 encoded):
- escaped string literals, enclosed in double-quotes, which can contain 'escaped characters'.
- raw string literals, enclosed in triple double-quotes, which ignore escaping but can contain new lines.
The language also supports character literals - a single UTF-16 character (including an escaped character) enclosed in single quotes.
Here are some examples of these :
// version 1.0.6
fun main(args: Array<String>) {
val cl = 'a' // character literal - can contain escaped character
val esl = "abc\ndef" // escaped string literal - can contain escaped character(s)
val rsl = """
This is a raw string literal
which does not treat escaped characters
(\t, \b, \n, \r, \', \", \\, \$ and \u)
specially and can contain new lines.
"Quotes" or doubled ""quotes"" can
be included without problem but not
tripled quotes.
"""
val msl = """
|Leading whitespace can be removed from a raw
|string literal by including
|a margin prefix ('|' is the default)
|in combination with the trimMargin function.
""".trimMargin()
println(cl)
println(esl)
println(rsl)
println(msl)
}
- Output:
a abc def This is a raw string literal which does not treat escaped characters (\t, \b, \n, \r, \', \", \\, \$ and \u) specially and can contain new lines. "Quotes" or doubled ""quotes"" can be included without problem but not tripled quotes. Leading whitepace can be removed from a raw string literal by including a margin ('|' is the default) in combination with the trimMargin function.
LabVIEW
LabVIEW is a graphical language so it uses graphical string delimiters. No escaping is needed.
This image is a VI Snippet, an executable image of LabVIEW code. The LabVIEW version is shown on the top-right hand corner. You can download it, then drag-and-drop it onto the LabVIEW block diagram from a file browser, and it will appear as runnable, editable code.
Lasso
All strings in Lasso are Unicode strings. This means that a string can contain any of the characters available in Unicode. Lasso supports two kinds of string literals: quoted and ticked. Quoted strings can contain escape sequences, while ticked strings cannot. Both quoted and ticked string literals can contain line breaks and they both return same type of string object. [1]
Quoted Strings
'I\'m a 2" string\n'
"I'm a 2\" string\n"
Ticked Strings
In the below example here \n would not be a line feed, it represents a backslash and n.
`I'm also a 2" string\n`
LaTeX
Since LaTeX is a markup language rather than a programming language, quotes are displayed rather than interpreted. However, quotes do deserve special mention in LaTeX. Opening (left) quotes are denoted with backquotes and closing (right) quotes are denoted with quotes. Single quotes use a single symbol and double quotes use double symbols. For example, to typeset 'a' is for "apple" in LaTeX, one would type
\documentclass{minimal}
\begin{document}
`a' is for ``apple"
\end{document}
One common mistake is to use the same symbol for opening and closing quotes, which results in the one of the quotes being backward in the output. Another common mistake is to use a double quote symbol in the input file rather than two single quotes in order to produce a double quote in the output.
Liberty BASIC
'Liberty BASIC does not support escape characters within literal strings.
print "Quotation mark:"
print chr$(34)
print
'Print literal string
print "Hello, World."
'Print literal string displaying quotation marks.
print chr$(34) + "Hello, World." + chr$(34)
Lingo
- Lingo only supports single quotes for string literals. Single quotes inside string literals have to be replaced by ""E&":
str = "Hello ""E&"world!""E
put str
-- "Hello "world!""
- Lingo does not support heredoc syntax, but only multiline string literals by using the line continuation character "\":
str = "This is the first line.\
This is the second line.\
This is the third line."
- Lingo does not support automatic variable expansion in strings. But the function value() can be used to expand template strings in the current context:
template = QUOTE&"Milliseconds since last reboot: ""E&"&_system.milliseconds"
-- expand template in current context
str = value(template)
put str
-- "Milliseconds since last reboot: 20077664"
Lisaac
Characters:
c1 := 'a';
c2 := '\n'; // newline
c3 := '\''; // quote
c4 := '\101o'; // octal
c5 := '\10\'; // decimal
c6 := '\0Ah\'; // hexadecimal
c7 := '\10010110b\'; // binary
Strings:
s1 := "this is a\nsample"; // newline
s2 := "\""; // double quote
s3 := "abc\
\xyz"; // "abcxyz", cut the gap
LiveCode
LiveCode has only one string representation using quotes. Characters are accessed through chunk expressions, specifically char. Some special characters are built-in constants such as quote, space, comma, cr, return. There is no support for escaping characters or multiline literals.
put "Literal string" -- Literal string
put char 1 of "Literal string" -- L
put char 1 to 7 of "Literal string" -- Literal
put word 1 of "Literal string" -- Literal
put quote & "string" & quote -- "string"
Logo
Logo does not have a string or character type that is separate from its symbol type ("word"). A literal word is specified by prefixing a double-quote character. Reserved and delimiting characters, ()[];~+-*/\=<>| and newline, may be used if preceded by a backslash. Alternatively, the string may be wrapped in vertical bars, in which case only backslash and vertical bar need be escaped.
print "Hello\,\ world
print "|Hello, world|
Lua
Strings can be enclosed using singlequotes or doublequotes. Having two different types of quotation symbols enables either of the symbols to be embedded within a string enclosed with the other symbol.
singlequotestring = 'can contain "double quotes"'
doublequotestring = "can contain 'single quotes'"
longstring = [[can contain
newlines]]
longstring2 = [==[ can contain [[ other ]=] longstring " and ' string [===[ qualifiers]==]
Note that interpolation of variables names within a string does not take place. However, interpolation of literal characters escape sequences does occur, irrespective of whether singlequote or doublequote enclosures are being used.
M2000 Interpreter
Print "Hello {World}"
Print {Hello "World"}
Report {Multiline String
2nd line
}
Print """Hello There"""={"Hello There"}
Print Quote$("Hello There")={"Hello There"}
M4
The quoting characters are ` and ',
but can be changed by the changequote
macro:
`this is quoted string'
changequote(`[',`]')dnl
[this is a quoted string]
Maple
There is no separate character type in Maple; a character is just a string of length equal to 1.
> "foobar";
"foobar"
> "foo\nbar"; # string with a newline
"foo
bar"
> "c"; # a character
"c"
Note that adjacent strings in the input (separated only by white-space) are concatenated automatically by the parser.
> "foo" "bar";
"foobar"
Since variable names are not distinguished lexically from other text (such as by using a "$" prefix, as in some shells), Maple does not do any kind of variable expansion inside strings.
Mathematica /Wolfram Language
There is no character type in Mathematica, only string type.
"c"; // String (result: "c")
"\n"; // String (result: newline character)
MATLAB
Strings start and end with single quotes, the escape sequence for a single quote with in a string, is the use of two consequtive single quotes
s1 = 'abcd' % simple string
s2 = 'ab''cd' % string containing a single quote
- Output:
>> s1 = 'abcd' % simple string s1 = abcd >> s2 = 'ab''cd' % string containing a single quote s2 = ab'cd
Maxima
/* A string */
"The quick brown fox jumps over the lazy dog";
/* A character - just a one character string */
"a"
Metafont
In Metafont there's no difference between a single character string and a single character. Moreover, the double quotes (which delimites a string) cannot be inserted directly into a string; for this reason, the basic Metafont macro set defines
string ditto; ditto = char 34;
i.e. a string which is the single character having ASCII code 34 ("). Macro or variables expansion inside a string block is inhibited.
message "You've said: " & ditto & "Good bye!" & ditto & ".";
ML/I
ML/I treats all input and programs as character streams. Strings do not have to be quoted; they are taken 'as is'. If one wishes to ensure that a string is taken literally (i.e. not evaluated), it is enclosed in literal brackets. There are no predefined literal brackets; the programmer can define anything suitable, usually by setting up a matched text skip, using the MCSKIP operation macro. By convention, the pair <> is used for literal brackets, unless this clashes in the case of a particular processing task.
Input
MCSKIP "WITH" NL
"" Literals/String
MCINS %.
MCSKIP MT,<>
"" Demonstration of literal string
MCDEF Bob AS Alice
"" The following two lines both mention Bob. The first line is
"" evaluated, but the second is surrounded by literal brackets and is not
"" evaluated.
This is the first mention of Bob
<and here we mention Bob again>
Output
This is the first mention of Alice
and here we mention Bob again
MIPS Assembly
Strings are specified using single or double quotes. The assembler will convert each letter of the string into its ASCII equivalent during the assembly process. Therefore, all of the following statements have the same effect:
li a0,'A'
li a0,0x41
li a0,65
li a0,0b01000001
This means that you can do compile-time "character addition/subtraction" and the like, to better communicate why your code is doing what it's doing.
;print 0 if $t0 if even, 1 if $t0 is odd
andi t0,t0,1 ;clear all but bit 1. This tells us if $t0 is odd or even.
addiu t0,"0" ;add ASCII 0 (0x30) to $t0
jal PrintChar ;implementation-defined print routine that prints the ASCII value of $t0 to the screen.
ASCII strings use .byte
for declaration. Control codes are implemented by strategically placing commas and their numeric values outside of quotation marks, like so:
MyString:
.byte "Hello World!",13,10,0 ;carriage return, line feed, null terminator
.align 4 ;pads to the next 4 byte-boundary
As with most RISC CPUs, alignment is a must, especially when working with ASCII strings. ARMIPS doesn't provide alignment automatically, but it does have the .align
directive to provide sufficient padding (if necessary) to ensure everything after your string is properly aligned. If it was already aligned, the directive will do nothing rather than burn the bytes, meaning that you don't have to take the time to count how long your string is. There's no memory wasted by dropping a .align
after every piece of byte-length data, so might as well.
Modula-3
Characters in Modula-3 use single quotes.
VAR char: CHAR := 'a';
Strings in Modula-3 use double quotes.
VAR str: TEXT := "foo";
TEXT
is the string type in Modula-3.
Characters can be stored in an array and then converted to type TEXT using the function Text.FromChars
in the Text
module.
Strings (of type TEXT
) can be converted into an array of characters using the function Text.SetChars
.
VAR str: TEXT := "Foo";
VAR chrarray: ARRAY [1..3] OF CHAR;
Text.SetChars(chrarray, str);
(* chrarray now has the value ['F', 'o', 'o'] *)
MUMPS
All strings are delimited by the double quotes character. But you can escape the double quotes to add a double quotes character to a string.
USER>SET S1="ABC" USER>SET S2="""DEF""" USER>SET S3="""GHI" USER>W S1 ABC USER>W S2 "DEF" USER>W S3 "GHI
Nemerle
Character literals are enclosed in single quotes. Regular strings are enclosed in double quotes, and use \ to delimit special characters, whitespace similar to C. A @ preceding the double quotes indicates a literal string. A $ preceding the double quote indicates string interpolation, identifiers prefixed with $ inside the string literal will be replaced with their value. Nemerle also has a recursive string literal, enclosed within <# #>, that is the same as a literal string, except that it allows nesting of strings.
'a' // character literal
'\n' // also a character literal
"foo\nbar" // string literal
@"x\n" // same as "x\\n"
@"x
y" // same as "x\n y"
@"""Hi!""" // "" replaces \" to escape a literal quote mark
<#This string type can contain any symbols including "
and new lines. It does not support escape codes
like "\n".#> // same as "This string type can contain any symbols including \"\nand new lines. "
// + "It does not\nsupport escape codes\nlike \"\\n\"."
<#Test <# Inner #> end#> // same as "Test <# Inner #> end" (i.e. this string type support recursion.
Nim
var c = 'c'
var s = "foobar"
var l = """foobar
and even
more test here"""
var f = r"C:\texts\text.txt" # Raw string
OASYS Assembler
There are two kinds, strings with quotation marks and strings with braces. Both kinds are treated exactly like numeric tokens for all purposes.
Strings with quotation marks can contain repeated quotation marks to represent a quotation mark, a tilde to represent a line break, or a line break to represent a space (in which case any leading spaces on the following line are ignored).
Strings with braces start with { and end with the next } (they don't nest), and all characters (except a right-brace) are treated as-is.
There are no character literals.
Objeck
Objeck string support is similar to Java except that string elements are 1-byte in length. In addition, string literals may terminated using a NULL character or the string's length calculation.
Objective-C
The same as C, with the addition of the new string literal
@"Hello, world!"
which represents a pointer to a statically allocated string object, of type NSString *, similar to string literals in Java. You can use this literal like other object pointers, e.g. call methods on it [@"Hello, world!" uppercaseString]
.
OCaml
Characters are contained in single quotes:
# 'a';;
- : char = 'a'
Strings are contained in double quotes:
# "Hello world";;
- : string = "Hello world"
Strings may be split across lines and concatenated using the following syntax: (the newline and any blanks at the beginning of the second line is ignored)
# "abc\
def";;
- : string = "abcdef"
If the above syntax is not used then any newlines and whitespace are included in the string:
# "abc
def";;
- : string = "abc\n def"
Another syntax to include verbatim text:
# {id|
Hello World!
|id} ;;
- : string = "\n Hello World!\n"
Octave
Strings can be defined in Octave with single or double quotes. In order to maintain compatible with Matlab, it is recommended to use single quotes for defining strings.
s1 = 'abcd' % simple string
s2 = 'ab''cd' % string containing a single quote using an escaped single quote
s3 = 'ab"cd' % simple string containing a double quote
s4 = "ab'cd" % string containing a single quote
s5 = "ab""cd" % string containing a double quote using an escaped double quote
- Output:
octave:5> s1 = 'abcd' % simple string s1 = abcd octave:6> s2 = 'ab''cd' % string containing a single quote using an escaped single quote s2 = ab'cd octave:7> s3 = 'ab"cd' % simple string containing a double quote s3 = ab"cd octave:8> s4 = "ab'cd" % string containing a single quote s4 = ab'cd octave:9> s5 = "ab""cd" % string containing a double quote using an escaped double quote s5 = ab"cd
Oforth
Oforth uses single quotes for characters and double quotes for strings.
There is no character type : characters are integers representing unicode value of the character.
'a'
'\''
"abcd"
"ab\ncd"
"ab\" and \" cd"
Oz
declare
Digit0 = &0 %% the character '0'
NewLine = &\n %% a character with special representation
NewLine = &\012 %% characters can also be specified with octals
%% Strings are lists of characters, but can also be written in double quotes:
[&H &e &l &l &o] = "Hello"
AnAtom = 'Hello' %% single quotes are used for atoms
Atom2 = hello = 'hello' %% for atoms starting with a lower case letter, they are optional
%% To build strings out of other values, so-called virtual strings are used:
MyName = "Peter"
MyAge = 8
{System.showInfo MyName # " is " # MyAge # " years old."}
PARI/GP
There are just three escapes:
\e escape \n newline \t tab
Any other escaped character simply represents itself; \\
and \"
are the most useful.
There are no characters or character strings as such,
but Vectorsmall("string") is very similar to a character array.
Version 2.4.3 added the functions printf
and Strprintf
which allow interpolation (typically with %Ps).
Pascal
See Delphi
PascalABC.NET
##
var s1 := 'Hello';
var s2 := 'quotes ''in'' string';
var s3 := 'chars with a'#13#10'given code in string';
Perl
Perl makes no distinction between single characters and strings. One can use single or double quotes, but they are different. Double-quotes allows you to interpolate variables and escape sequences, while single-quotes do not.
'c'; # character
'hello'; # these two strings are the same
"hello";
'Hi $name. How are you?'; # result: "Hi $name. How are you?"
"Hi $name. How are you?"; # result: "Hi Bob. How are you?"
'\n'; # 2-character string with a backslash and "n"
"\n"; # newline character
`ls`; # runs a command in the shell and returns the output as a string
q/hello/; # same as 'hello', but allows custom delimiters, eg: q(hi) and q!hi!
qq/hello/; # same as "hello", but allows custom delimiters, eg: qq{$hi} and qq#hi#
qw/one two three/; # same as ('one', 'two', 'three'); constructs a list of the words
qx/ls/; # quoted execution, same as `ls`
qr/regex/; # creates a regular expression
<<END; # Here-Document
Hi, whatever goes here gets put into the string,
including newlines and $variables,
until the label we put above
END
<<'END'; # Here-Document like single-quoted
Same as above, but no interpolation of $variables.
END
Phix
single character literals (incidentally entirely equivalient to their ascii value) require single quotes, eg
constant UPPERCASEJ = 'J' -- equivalent to 74
string literals use double quotes, eg
constant hw = "Hello World!", mt = "" -- empty string
Note that 'z' and "z" are quite different. In Phix there is a strong difference between a character and a string.
All strings are ansi or utf8, depending on the encoding of the source file, eg
s = "日本語"
Utf8 strings are byte-subscripted rather than character-subscripted, so s[3] is not necessarily the third character.
Phix strings have a length field in the (internal) header, /and/ a terminating null, so they can be used directly when interfacing to C-style languages.
Phix strings can also be used to hold "raw binary", ie instead of a sequence of characters, a sequence of any bytes in the range 0 to 255.
Strings are fully mutable: you can append, prepend, replace, substitute, and crop characters and slices (/substrings) any way you like, eg
string s = "food" s[2..3] = 'e' -- s is now "feed" (replace all) s[2..2] = "east" -- s is now "feasted" (replace substring) s[2..5] = "" -- s is now "fed"
Special characters may be entered (between quotes) using a back-slash:
Code Value Meaning \n #10 newline \r #13 carriage return \b #08 backspace \t #09 tab \\ #5C backslash \" #22 double quote (the \ is optional in ', mandatory in ") \' #27 single quote (the \ is optional in ", mandatory in ') \0 #00 null \#HH #HH any hexadecimal byte \xHH #HH any hexadecimal byte \uH4 - any 16-bit unicode point, eg "\u1234", max #FFFF \UH8 - any 32-bit unicode point, eg "\U00105678", max #10FFFF
There are no other automatic substitutions or interpolation, other than through explict function calls such as [s]printf().
Strings can also be entered by using triple quotes or backticks intead of double quotes to include linebreaks and avoid any backslash interpretation. If the literal begins with a newline, it is discarded and any immediately following leading underscores specify a (maximum) trimming that should be applied to all subsequent lines. Examples:
ts = ""` this string\thing`"" ts = ""` _____this string\thing`"" ts = `this string\thing` ts = "this\nstring\\thing"
which are all equivalent.
On a practical note, as long as you have at least 2GB of physical memory, you should experience no problems whatsoever constructing a string with 400 million characters, and you could more than triple that by allocating things up front, however deliberately hogging the biggest block of memory the system will allow is generally considered bad programming practice, and may lead to disk thrashing.
Hex string literals are also supported (mainly for compatibility with OpenEuphoria, x/u/U for 1/2/4 byte codes), eg:
?x"68 65 6c 6c 6f"; -- displays "hello"
PHP
PHP makes no distinction between single characters and strings. One can use single or double quotes, but they are different. Double-quotes allows you to interpolate variables and escape sequences, while single-quotes do not.
'c'; # character
'hello'; # these two strings are the same
"hello";
'Hi $name. How are you?'; # result: "Hi $name. How are you?"
"Hi $name. How are you?"; # result: "Hi Bob. How are you?"
'\n'; # 2-character string with a backslash and "n"
"\n"; # newline character
`ls`; # runs a command in the shell and returns the output as a string
<<END # Here-Document
Hi, whatever goes here gets put into the string,
including newlines and $variables,
until the label we put above
END;
<<'END' # Here-Document like single-quoted
Same as above, but no interpolation of $variables.
END;
Picat
A string is a list of characters. The string literal is in double quotes (a character is in single quote, e.g 's'):
"string"
It can also be constructed as a list of characters:
['s','t','r','i','n','g']
or as a list of (character) atoms (without single quotes):
[s,t,r,i,n,g]
However, upper case characters must be quoted (otherwise they are considered variables):
['S',t,r,i,n,g]
Quoting of certain characters are with an escape character (\c
):
"a string\'s quotes: \"a string\'s quotes\". Spaces: \t\n\l\r"
A string can be written on several lines where the newlines are kept:
X = "string with
newlines and
spaces",
% ...
Using a single \
as the last character on a line makes the line continue without newline.
X = "string with \
newlines \
and \
spaces",
% ...
is the same as
string with newlines and spaces
PicoLisp
PicoLisp doesn't have a string data type. Instead, symbols are used. Certain uninterned symbols, called "transient symbols", however, look and behave like strings on other languages.
Syntactically, transient symbols (called "strings" in the following) are surrounded by double quotes.
: "ab\"cd"
-> "ab\"cd"
Double quotes in strings are escaped with a backslash.
ASCII control characters can be written using the hat ('^') character:
: "ab^Icd^Jef" # Tab, linefeed
There is no special character type or representation. Individual characters are handled as single-character strings:
: (chop "abc")
-> ("a" "b" "c")
: (pack (reverse @))
-> "cba"
A limited handling of here-strings is available with the 'here' function.
Pike
'c'; // Character code (ASCII) (result: 99)
"c"; // String (result: "c")
"\n"; // String (result: newline character)
"hi " + world // String (result: "hi " and the contents of the variable world)
#"multiple line
string using the
preprocessor" // single literal string with newlines in it
PL/I
'H' /* a single character as a literal. */
'this is a string'
'' /* an empty string literal. */
'John''s cat' /* a literal containing an embedded apostrophe. */
/* stored are <<John's cat>> */
'101100'b /* a bit string, stored as one bit per digit. */
Plain English
A string literal is surrounded by double quotes. Plain English does not make a distinction between string and character literals.
To escape a double quote inside a string literal, use two double quotes.
"a ""string"" literal"
Plain TeX
`a' is for ``apple"
\end
The same as LaTeX case, even though one should say the opposite.
The `` and '' in TeX (plainTeX, LaTeX and many more) are just examples of ligatures.
Pop11
In Pop11 charaters literals are written in inverted quotes (backticks)
`a` ;;; charater a
String are written in quotes
'a' ;;; string consisting of single character
Backslash is used to insert special charaters into strings:
'\'\n' ;;; string consisting of quote and newline
PowerShell
PowerShell makes no distinction between characters and strings. Single quoted strings do not interpolate variable contents but double quoted strings do. Also, escape sequences are quoted literally as separate characters within single quotes.
PowerShell here-strings begin with @' (or @") followed immediately by a line break and end with a line break followed by '@ (or "@). Escape sequences and variables are interpolated in @" quotes but not in @' quotes.
Prolog
Standard Prolog has no string types. It has atoms which can be formed in two ways, one of which is wrapping arbitrary text in single quotation marks:
'This is an "atom" and not a string.'
Such atoms can be (and are) treated as immutable strings in Prolog in many cases. Another string-like form wraps text in double quotation marks:
"This 'string' will fool you if you're in a standard Prolog environment."
While this appears as a string to non-Prolog users, it is in reality a linked list of integers with each node containing the integer value of the character (or for Unicode-capable systems, code point) at that location. For example:
?- [97, 98, 99] = "abc".
true.
Individual character constants are special forms of integer (syntax sugar) using a 0' prefix:
?- 97 = 0'a.
true.
SWI-Prolog, beginning with version 7, introduced a new native string type. Unless options are specifically set by the user, character sequences wrapped in double quotes are now a string data type. The older list-based version uses back quotes instead:
?- [97, 98, 99] = "abc".
false.
?- [97, 98, 99] = `abc`.
true.
Also starting with SWI-Prolog version 7, quasiquotation became possible. While not exactly a string type directly, they can be (ab)used to give multi-line strings. More importantly, however, they permit special string handling to be embedded into Prolog code, in effect permitting entire other languages inside of Prolog to be used natively as per this example:
test_qq_odbc :-
myodbc_connect_db(Conn),
odbc_query(Conn, {|odbc||
select
P.image,D.description,D.meta_keywords,C.image,G.description
from
product P, product_description D, category C, category_description G, product_to_category J
where
P.product_id=D.product_id and
P.product_id=J.product_id and C.category_id=J.category_id and
C.category_id=G.category_id
|}, Row),
writeln(Row).
In this example, the test_qq_odbc/0 predicate connects to an ODBC database and performs a query. The query is wrapped into a multi-line quasiquotation (beginning with {| and ending with |}) that checks the syntax and security of the query, so not only is the query a multi-line string, it is a **checked** multiline string in this case.
PureBasic
PureBasic supports char in ASCII and UNICODE as well as both dynamic and fixed length strings.
; Characters (*.c), can be ASCII or UNICODE depending on compiler setting
Define.c AChar='A'
; defines as *.a it will be ASCII and *.u is always UNICODE
Define.a A='b'
Define.u U='水'
; Strings is defined as **.s or ending with '$'
Define.s AStrion ="String #1"
Define BStrion.s ="String #2"
Define CString$ ="String #3"
; Fixed length stings can be defined if needed
Define XString.s{100} ="I am 100 char long!"
; '"' can be included via CHR() or its predefined constant
Define AStringQuotes$=Chr(34)+"Buu"+Chr(34)+" said the ghost!"
Define BStringQuotes$=#DOUBLEQUOTE$+"Buu"+#DOUBLEQUOTE$+" said yet a ghost!"
To dynamically detect the current sizes of a character, e.g. ASCI or UNICODE mode, StringByteLength() can be used.
Select StringByteLength("X")
Case 1
Print("ASCII-mode; Soo, Hello world!")
Case 2
Print("UNICODE-mode; Soo, 您好世界!")
EndSelect
Python
Python makes no distinction between single characters and strings. One can use single or double quotes.
'c' == "c" # character
'text' == "text"
' " '
" ' "
'\x20' == ' '
u'unicode string'
u'\u05d0' # unicode literal
As shown in the last examples, Unicode strings are single or double quoted with a "u" or "U" prepended thereto.
Verbatim (a.k.a. "raw") strings are contained within either single or double quotes, but have an "r" or "R" prepended to indicate that backslash characters should NOT be treated as "escape sequences." This is useful when defining regular expressions as it avoids the need to use sequences like \\\\ (a sequence of four backslashes) in order to get one literal backslash into a regular expression string.
r'\x20' == '\\x20'
The Unicode and raw string modifiers can be combined to prefix a raw Unicode string. This must be done as "ur" or "UR" (not with the letters reversed as it: "ru").
Here-strings are denoted with triple quotes.
''' single triple quote '''
""" double triple quote """
The "u" and "r" prefixes can also be used with triple quoted strings.
Triple quoted strings can contain any mixture of double and single quotes as well as embedded newlines, etc. They are terminated by unescaped triple quotes of the same type that initiated the expression. They are generally used for "doc strings" and other multi-line string expressions --- and are useful for "commenting out" blocks of code.
Quackery
A character literal is denoted by the word char
. The character is the first non-whitespace character following char
.
A string literal is denoted by the word $
. The string is delimited by the first non-whitespace character following $
.
Character and string literals illustrated in the Quackery shell (REPL):
/O> char X emit ... char Y emit ... char Z emit cr ... $ "This is a 'string'." echo$ cr ... $ 'This is a "string" too.' echo$ cr ... $ ~This is one with "quotes" and 'apostrophes'.~ echo$ cr ... $ \Any non-whitespace character can be the delimiter.\ echo$ cr ... XYZ This is a 'string'. This is a "string" too. This is one with "quotes" and 'apostrophes'. Any non-whitespace character can be the delimiter.
R
R makes no distinction between characters and strings, and uses single and double quotes interchangeably, though double quotes are considered to be preferred. Verbatim strings are not supported. See ?Quotes for more information.
str1 <- "the quick brown fox, etc."
str2 <- 'the quick brown fox, etc.'
identical(str1, str2) #returns TRUE
R also supports testing string literals with ==, e.g.,
modestring <- 'row,col'
mode.vec <- unlist(strsplit(modestring, ','))
mode.vec[1] # "row"
mode.vec[2] # "col"
if (mode.vec[2] == 'col') { cat('Col!\n') } # Col! (with no quotes)
if (mode.vec[1] == "row") { cat('Row!\n') } # Row!
R also uses backticks, for creating non-standard variable names (amongst other things).
`a b` <- 4
`a b` # 4
a b # Error: unexpected symbol in "a b"
R will print different styles of single and double quote using sQuote and dQuote
options(useFancyQuotes=FALSE)
cat("plain quotes: ", dQuote("double"), "and", sQuote("single"), "\n")
returns
plain quotes: "double" and 'single'
options(useFancyQuotes=TRUE)
cat("fancy quotes: ", dQuote("double"), "and", sQuote("single"), "\n")
returns
fancy quotes: “double” and ‘single’
options(useFancyQuotes="TeX")
cat("fancy quotes: ", dQuote("double"), "and", sQuote("single"), "\n")
returns
TeX quotes: ``double'' and `single'
Racket
Characters are specified as hash-backslash-character, sometime using a name for the character.
#\a
#\space
#\return
Strings are double-quoted, and have most of the usual C-style escapes. To include a double-quote in strings, escape it with a backslash, and the same goes for doubly-escaped backslashes (leading to the usual regexp fun).
Racket source code is read as UTF-8 text so strings can include Unicode characters -- but the internal representation is UCS-4. This includes "\NNN" for octals and "\xHH" for hex and "\uHHHH" for higher characters. See the docs for a complete specification.
Racket also has here strings, and a more sophisticated facility for text that includes interpolation-like features, which is described in the Here Document entry
Raku
(formerly Perl 6) Unlike most languages that hardwire their quoting mechanisms, the quote mechanism in Raku is extensible, and all normal-looking quotes actually derive from a parent quoting language called Q via grammatical mixins, applied via standard Raku adverbial syntax. The available quote mixins, straight from current spec S02, are:
Short Long Meaning ===== ==== ======= :x :exec Execute as command and return results :w :words Split result on words (no quote protection) :ww :quotewords Split result on words (with quote protection) :v :val Evaluate word or words for value literals :q :single Interpolate \\, \q and \' (or whatever) :qq :double Interpolate with :s, :a, :h, :f, :c, :b :s :scalar Interpolate $ vars :a :array Interpolate @ vars :h :hash Interpolate % vars :f :function Interpolate & calls :c :closure Interpolate {...} expressions :b :backslash Interpolate \n, \t, etc. (implies :q at least) :to :heredoc Parse result as heredoc terminator :regex Parse as regex :subst Parse as substitution :trans Parse as transliteration :code Quasiquoting :p :path Return a Path object (see S16 for more options
In any case, an initial Q, q, or qq may omit the initial colon to form traditional Perl quotes such as qw//. And Q can be used by itself to introduce a quote that has no escapes at all except for the closing delimiter:
my $raw = Q'$@\@#)&!#';
Note that the single quotes there imply no single quoting semantics as they would in Perl 5. They're just the quotes the programmer happened to choose, since they were most like the raw quoting. Single quotes imply :q only when used as normal single quotes are, as discussed below. As in Perl 5, you can use any non-alphanumeric, non-whitespace characters for delimiters with the general forms of quoting, including matching bracket characters, including any Unicode brackets.
Using the definitions above, we can derive the various standard "sugar" quotes from Q, including:
Normal Means ====== ===== q/.../ Q :q /.../ qq/.../ Q :qq /.../ '...' Q :q /.../ "..." Q :qq /.../ <...> Q :q :w :v /.../ «...» Q :qq :ww :v /.../ /.../ Q :regex /.../ quasi {...} Q :code {...}
The :qq-derived languages all give normal Perlish interpolation, but individual interpolations may be chosen or suppressed with extra adverbs.
Unlike in Perl 5, we don't use backticks as shorthand for what is now expressed as qqx// in Raku. (Backticks are now reserved for user-defined syntax.) Heredocs now have no special << syntax, but fall out of the :to adverb:
say qq:to/END/;
Your ad here.
END
Indentation equivalent to the ending tag is automatically removed.
Backslash sequences recognized by :b (and hence :qq) include:
"\a" # BELL
"\b" # BACKSPACE
"\t" # TAB
"\n" # LINE FEED
"\f" # FORM FEED
"\r" # CARRIAGE RETURN
"\e" # ESCAPE
"\x263a" # ☺
"\o40" # SPACE
"\0" # NULL
"\cC" # CTRL-C
"\c8" # BACKSPACE
"\c[13,10]" # CRLF
"\c[LATIN CAPITAL LETTER A, COMBINING RING ABOVE]"
Leading 0 specifically does not mean octal in Perl 6; you must use \o instead.
Retro
Strings begin with a single quote and end on space. Underscores are replaced with spaces.
ASCII characters are prefixed by a single dollar sign.
$c
'hello,_world!
'This_is_'a_string'
REXX
There are two types of quotes used for REXX literals:
- " (sometimes called a double quote or quote)
- ' (sometimes called a single quote or apostrophe)
There is no difference between them as far as specifying a REXX literal.
You can double them (code two of them adjacent) to specify a quote within the string.
char1 = "A"
char2 = 'A'
str = "this is a string"
another = 'this is also a string'
escape1 = "that's it!"
escape2 = 'that''s it!'
Variable expansion is not possible within REXX literals.
Simply concatenate the string with the variable:
amount = 100
result = "You got" amount "points."
say result
- Output:
You got 100 points.
It's also possible to express characters in hexadecimal notation in a string:
lf = '0A'x
cr = '0D'x
mmm = '01 02 03 34 ee'x
ppp = 'dead beaf 11112222 33334444 55556666 77778888 00009999 c0ffee'X
lang = '52455858'x /*which is "REXX" on ASCII-computers.*/
Binary strings are also possible:
jjj = '01011011'B
jjj = '01011011'b
jjj = "0101 1011"b
jjj = '0101 1011 1111'b
longjjj = '11110000 10100001 10110010 11100011 11100100'B
Ring
see 'This is a "quoted string"'
Ruby
Quotes that do not interpolate:
'single quotes with \'embedded quote\' and \\backslash'
%q(not interpolating with (nested) parentheses
and newline)
Quotes that interpolate:
a = 42
"double quotes with \"embedded quote\"\nnewline and variable interpolation: #{a} % 10 = #{a % 10}"
%Q(same as above)
%|same as above|
Heredocs
print <<HERE
With an unquoted delimiter, this interpolates:
a = #{a}
HERE
print <<-INDENTED
This delimiter can have whitespace before it
INDENTED
print <<'NON_INTERPOLATING'
This will not interpolate: #{a}
NON_INTERPOLATING
Rust
A char
in Rust is a Unicode scalar value. A char type in Rust is always four bytes in size and can be denoted by single quotes:
let char01: char = 'a';
let char02: char = '\u{25A0}'; // Black square
let char03: char = '❤'; // Heart
Rust has two common string types: &str
and String
. These different string types are used depending if it's a fixed string literal that is saved into the executable and lives throughout the program execution (usually borrowed as a &str
), a string slice that references a contiguous sequence of elements (borrowed as a &str
), or a String
which allows for a growable heap allocated valid UTF-8 string. Only the String
type is fully owned by its variable, and the other two are only interacted through the reference &str
. The &str
string slice type may point to a string literal or a heap-allocated string.
The String type in Rust is intended to always contain a valid UTF-8 string. UTF-8 is a "variable width" encoding, and therefore Strings are going to be typically smaller than an array of the same Rust char
's. For example, the String "hi" is all within ASCII, and therefore a UTF-8 String of "hi" represents each character as one byte each. On the other hand, a char array ['h', 'i'] would take up 8 bytes in total. A string is denoted by double quotes:
const string_literal_str1: &str = "Hi Rust!";
let string_slice_str1: &str = string_literal_str1; // Creating a string slice from a string literal
let string_slice_str2: &str = "hello str"; // String slice pointing to string literal "hello str"
let string1: String = String::new(); // Empty String
let string2: String = String::from("hello"); // Creating String from string literal "hello"
let string3: String = "hi".to_string();
let string4: String = "bye".to_owned();
let string5: String = "see you soon".into();
// The "to_string()", "to_owned" or "into" are all equivalent in the code above.
// The "to_string()", "to_owned" or "into" methods are needed so that a string slice (&str) or a string literal (&str) is explicitly converted into a heap-allocated fully-owned String type. Otherwise the compiler's type checker will complain "expected struct `String`, found `&str` (string slice)"
let string6: String = string_slice_str2.to_owned(); // Explictly converting the string_slice_str2 into a heap-allocated fully-owned String. This can be done with "to_string()", "to_owned" or "into".
// String slices can also point to heap allocated strings:
let string_slice_str3: &str = &string2; // Creating a string slice to a heap-allocated String.
let string7: String = string_slice_str3.to_string(); // Converting string_slice_str3 into a heap-allocated fully-owned String copy, resulting in a new independent owned string copy of the original String. This can be done with "to_string()", "to_owned" or "into".
Rust supports verbatim strings and here-strings by putting r#
before the first double quotes, and the end is marked by adding a #
after the final double quotes. If there is a "#
inside the contents of your here-string or your verbatim string then you can just add more #
's as required in both the beggining and the end:
let verbatim_here_string01: &str = r#"A \verbatim string\, line breaks in programming use \n and tabs \t"#;
let verbatim_here_string02: &str = r#"
A \multi-line\ string, in programming
line breaks use the characters \n
and for tabs we use the characters \t
"#;
let verbatim_here_string03: &str = r##"
Part number "#001": 1
Part number "#002": 2
Part number "#003": 3
"##;
To expand variables in Rust we have 3 options: we can use the "format!" macro, the "print!" macro or the "println!" macro.
let number: i32 = 42;
let number_string: String = format!("Number: {}", number);
println!("The result in string form is '{}'.", number_string);
print!("The number is {}. ", number); // Print without line break
println!("Again, it's {}", number); // Print with line break
// The above prints:
// The result in string form is 'Number: 42'.
// The number is 42. Again, it's 42
In Rust, there are other string types that are specialized to specific string requirements, such as working with system strings (OsString and OsStr), working with C strings (CString and CStr), and working with system paths (Path and PathBuf).
S-lang
S-Lang supports character literals with single-quote apostrophe. These are normally limited to byte sized 0 thru 255 (ASCII, extended into 8 bits).
Wide (unicode) character literals can be introduced with apostrophe '\x{Hex}'
, for example '\x{1D7BC}'
for math symbol sans-serif bold italic small sigma. Character literals are treated as Integer_Type data.
Double-quotes are used for strings, but these may not include literal newlines or NUL bytes without using backslash escapes. S-Lang 2.2 introduced verbatim strings using backtick. These may include newline literals, but other platform concerns can make NUL byte literals in the source code a tricky business. Both double-quote and back-quote allow a suffix:
- R for no backslash escapes (default for back-quoted strings)
- Q to force backslash escaping (default for double-quoted strings)
- B to produce a binary string, BString_Type
- $ to request dollar prefix variable substitutions within the given string.
% String literals
variable c, ch, s, b, r, v;
c = 'A';
ch = '\x{1d7bc}';
printf("Double quotes\n");
s = "this is a single line string with\t\tbackslash substitutions";
() = fputs(s, stdout);
() = fputs("\n", stdout);
s = "this is a single line string without\t\tbackslash substitutions"R;
() = fputs(s, stdout);
() = fputs("\n", stdout);
s = "string with backslash escaped newline \
takes up two lines in source, but no newline is in the string";
() = fputs(s, stdout);
() = fputs("\n", stdout);
printf("\nBack quotes\n");
r = `this is a multi line string with
backslash substitutions and \t(tabs)\t`Q;
() = fputs(r, stdout);
() = fputs("\n", stdout);
r = `this is a multi line string without
backslash substitutions and \t(tabs)\t`;
() = fputs(r, stdout);
() = fputs("\n", stdout);
printf("\nvariable substitution\n");
v = "variable substitution with $$c as $c"$;
() = fputs(v, stdout);
() = fputs("\n", stdout);
v = "no variable substitutions, $$c as $c";
() = fputs(v, stdout);
() = fputs("\n", stdout);
printf("\nBString_Type\n");
b = "this is a binary string, NUL \0 \0 bytes allowed"B;
print(b);
% display of b will be stopped at the NUL byte using stdio streams
() = fputs(b, stdout);
() = fputs("\n", stdout);
printf("strlen(b) is %d, bstrlen(b) is %d\n", strlen(b), bstrlen(b));
- Output:
prompt$ slsh strlit.sl Double quotes this is a single line string with backslash substitutions this is a single line string without\t\tbackslash substitutions string with backslash escaped newline takes up two lines in source, but no newline is in the string Back quotes this is a multi line string with backslash substitutions and (tabs) this is a multi line string without backslash substitutions and \t(tabs)\t variable substitution variable substitution with $c as 65 no variable substitutions, $$c as $c BString_Type "this is a binary string, NUL \000 \000 bytes allowed" this is a binary string, NUL strlen(b) is 29, bstrlen(b) is 46
With substitutions, if a literal dollar sign or backquote is required, the character needs to be doubled. "$$c" is the literal "$c" when using dollar suffixed strings.
Backslash escapes include:
\"
-- double quote\'
-- single quote\\
-- backslash\0
-- NUL byte\a
-- bell character (ASCII 7)\t
-- tab character (ASCII 9)\n
-- newline character (ASCII 10)\e
-- escape character (ASCII 27)\xhh
-- byte expressed in HEXADECIMAL notation\ooo
-- byte expressed in OCTAL notation\dnnn
-- byte expressed in DECIMAL\u{h..h}
-- the Unicode character U+h..h\x{h..h}
-- the Unicode character U+h..h [modal]
Scala
Character literals use single quotes marks:
val c = 'c'
However, symbols are denoted with a single quote, so care must be taken not to confuse the two:
val sym = 'symbol
Strings can use either double quotes, or three successive double quotes. The first allows special characters, the second doesn't:
scala> "newline and slash: \n and \\"
res5: java.lang.String =
newline and slash:
and \
scala> """newline and slash: \n and \\"""
res6: java.lang.String = newline and slash: \n and \\
However, Unicode characters are expanded wherever they happen, even inside comments. So, for instance:
scala> val uniquote = \u0022normal string"
uniquote: java.lang.String = normal string
scala> val insidequote = """an inside \u0022 quote"""
insidequote: java.lang.String = an inside " quote
Finally, on version 2.7, the triple-double-quoted string ends at the third consecutive quote, on version 2.8 it ends on the last quote of a series of at least three double-quotes.
Scala 2.7
scala> val error = """can't finish with a quote: """"
<console>:1: error: unterminated string
val error = """can't finish with a quote: """"
^
Scala 2.8
scala> val success = """but it can on 2.8: """"
success: java.lang.String = but it can on 2.8: "
Scheme
Characters are specified using the "#\" syntax:
#\a
#\A
#\?
#\space
#\newline
Strings are contained in double quotes:
"Hello world"
Literal symbols, lists, pairs, etc. can be quoted using the quote syntax:
'apple
'(1 2 3) ; same as (list 1 2 3)
'() ; empty list
'(a . b) ; same as (cons 'a 'b)
Seed7
The type char describes Unicode characters encoded with UTF-32. A character literal is written as UTF-8 encoded Unicode character enclosed in single quotes.
var char: ch is 'z';
The type string describes sequences of Unicode characters. The characters in the string use the UTF-32 encoding. A string literal is a sequence of UTF-8 encoded Unicode characters surrounded by double quotes.
var string: stri is "hello";
This means that 'z' and "z" are different. The former is a character while the latter is a string. Seed7 strings are not null terminated (they do not end with \0). They can contain any sequence of UNICODE (UTF-32) characters (including a \0). Empty strings are also allowed. In order to represent non-printable characters and certain printable characters the following escape sequences may be used.
audible alert | BEL | \a | |
backspace | BS | \b | |
escape | ESC | \e | |
formfeed | FF | \f | |
newline | NL (LF) | \n | |
carriage return | CR | \r | |
horizontal tab | HT | \t | |
vertical tab | VT | \v | |
backslash | (\) | \\ | |
apostrophe | (') | \' | |
double quote | (") | \" | |
control-A | \A | ||
... | |||
control-Z | \Z |
A backslash followed by an integer literal and a semicolon is interpreted as character with the specified ordinal number. Note that the integer literal is interpreted decimal unless it is written as based integer.
"Euro sign: \8364;"
There is also a possibility to break a string into several lines.
var string: example is "this is a string\
\ which continues in the next line\n\
\and contains a line break";
There is no built-in mechanism for expanding variables within strings.
Sidef
Quotes that do not interpolate:
'single quotes with \'embedded quote\' and \\backslash';
‚unicode single quoted’;
%q(not interpolating with (nested) parentheses
and newline);
Quotes that interpolate:
var a = 42;
"double \Uquotes\E with \"embedded quote\"\nnewline and variable interpolation: #{a} % 10 = #{a % 10}";
„same as above”;
%Q(same as above);
Heredocs:
print <<EOT
Implicit double-quoted (interpolates):
a = #{a}
EOT
print <<"EOD"
Explicit double-quoted with interpolation:
a = #{a}
EOD
print <<'NON_INTERPOLATING'
This will not interpolate: #{a}
NON_INTERPOLATING
Slate
Characters are specified using the $ syntax:
$a
$D
$8
$,
$\s
$\n
Strings are contained in single quotes, with backslash for escaping:
'Hello\'s the word.'
SQL
String literals in SQL use single-quotation. There are no escapes, but you can double a ' mark to make a single ' in the text.
SELECT 'The boy said ''hello''.';
Standard ML
Characters are contained in the #""
syntax:
- #"a";
val it = #"a" : char
Strings are contained in double quotes:
- "Hello world";
val it = "Hello world" : string
Strings may be split across lines and concatenated by having two backslashes around the newline and whitespace:
- "abc\
\def";
val it = "abcdef" : string
Swift
let you = "You"
let str1 = "\(you) can insert variables into strings."
let str2 = "Swift also supports unicode in strings ı∫ƒ∂ß´™¡à"
let str3 = "Swift also supports control characters \n\tLike this"
let str4 = "'" // '
let str5 = "\"" // "
println(str3)
- Output:
Swift also supports control characters Like this
Swift 4 introduced multi-line string literals called long strings. Long strings are strings delimited by """triple quotes"""
that can contain newlines and individual "
characters without the need to escape them.
let author = "Author"
let xml == """
<?xml version="1.0"?>
<catalog>
<book id="bk101" empty="">
<author>\(author)</author>
<title>XML Developer's Guide</title>
<genre>Computer</genre>
<price>44.95</price>
<publish_date>2000-10-01</publish_date>
<description>An in-depth look at creating applications with XML.</description>
</book>
</catalog>
"""
println(xml)
- Output:
<?xml version="1.0"?> <catalog> <book id="bk101" empty=""> <author>Author</author> <title>XML Developer's Guide</title> <genre>Computer</genre> <price>44.95</price> <publish_date>2000-10-01</publish_date> <description>An in-depth look at creating applications with XML.</description> </book> </catalog>
To allow free formatting of the literal an indentation stripping operation is applied whereby any whitespace characters in front of the closing delimiter are removed from each of the lines in the literal. As part of this process any initial linefeed is also removed. This allows the developer to paste literal content directly into the string without modification.
Tcl
Tcl makes no distinction between single characters and strings.
Double quotes allow command and variable interpolation:
set str "This is Tcl $::tcl_version\tIt is [clock format [clock seconds]]"
puts $str ;# ==> This is Tcl 8.5 It is Mon Apr 06 16:49:46 EDT 2009
Braces prevent interpolation
set str {This is Tcl $::tcl_version\tIt is [clock format [clock seconds]]}
puts $str ;# ==> This is Tcl $::tcl_version\tIt is [clock format [clock seconds]]
TI-89 BASIC
Double quotes enclose strings, e.g. "Hello Rosetta Code"
.
There are no escape characters.
Quotes in strings are doubled: "This > "" < is one double-quote."
TOML
There are four ways to express strings: basic, multi-line basic, literal, and multi-line literal. All strings must contain only valid UTF-8 characters.
Basic strings are surrounded by quotation marks. Any Unicode character may be used except those that must be escaped: quotation mark, backslash, and the control characters other than tab (U+0000 to U+0008, U+000A to U+001F, U+007F).
str = "I'm a string. \"You can quote me\". Name\tJos\u00E9\nLocation\tSF."
Multi-line basic strings are surrounded by three quotation marks on each side and allow newlines. A newline immediately following the opening delimiter will be trimmed. All other whitespace and newline characters remain intact.
str1 = """
Roses are red
Violets are blue"""
When the last non-whitespace character on a line is a \
("line ending backslash"), it will be trimmed along with all whitespace (including newlines) up to the next non-whitespace character or closing delimiter. All of the escape sequences that are valid for basic strings are also valid for multi-line basic strings.
# The following strings are byte-for-byte equivalent:
str1 = "The quick brown fox jumps over the lazy dog."
str2 = """
The quick brown \
fox jumps over \
the lazy dog."""
str3 = """\
The quick brown \
fox jumps over \
the lazy dog.\
"""
Literal strings are surrounded by single quotes and do not support escaping. This means that there is no way to write a single quote in a literal string. Like basic strings, they must appear on a single line.
# What you see is what you get.
winpath = 'C:\Users\nodejs\templates'
winpath2 = '\\ServerX\admin$\system32\'
quoted = 'Tom "Dubs" Preston-Werner'
regex = '<\i\c*\s*>'
Multi-line literal strings are surrounded by three single quotes on each side and allow newlines. Like literal strings, there is no escaping whatsoever. A newline immediately following the opening delimiter will be trimmed. All other content between the delimiters is interpreted as-is without modification. One or two single quotes are allowed anywhere within a multi-line literal string, but sequences of three or more single quotes are not permitted.
regex2 = '''I [dw]on't need \d{2} apples'''
lines = '''
The first newline is
trimmed in raw strings.
All other whitespace
is preserved.
'''
TUSCRIPT
$$ MODE TUSCRIPT,{}
s1=*
DATA "string"
s2=*
DATA + "double" quotes
s3=*
DATA + 'single' quotes
s4=*
DATA + "double" + 'single' quotes
show=JOIN(s1," ",s2,s3,s4)
show=JOIN(show)
PRINT show
- Output:
"string" + "double" quotes + 'single' quotes + "double" + 'single' quotes
UNIX Shell
The Unix shell supports several types of quotation marks:
- singlequotes - for literal string quotation
- doublequotes - for interpolated string quotation
- backticks - Used to capture the output from an external program
Quotation marks within a literal String
It is possible to place singlequote characters within a string enclosed with doublequotes and to put doublequote characters in a string enclosed within singlequotes:
echo "The boy said 'hello'."
echo 'The girl said "hello" too.'
We can also use an escapesequence to put doublequote characters in an interpolated string:
print "The man said \"hello\".";
Here documents
The shell supports the use of here documents for the passing of quoted text as input into a command. Here documents cannot be used to represent literal strings as an expression for variable assignment.
cat << END
1, High Street,
SMALLTOWN,
West Midlands.
WM4 5HD.
END
Ursala
Single characters are denoted with a back quote.
a = `x
Unprintable character constants can be expressed like this.
cr = 13%cOi&
Strings are enclosed in single forward quotes.
b = 'a string'
A single quote in a string is escaped by another single quote.
c = 'Hobson''s choice'
Multi-line strings are enclosed in dash-brackets.
d =
-[this is a list
of strings]-
Dash-bracket enclosed text can have arbitrary nested unquoted expressions, provided they evaluate to lists of character strings.
e = -[the front matter -[ d ]- the rest of it]-
f = -[text -[ d ]- more -[ e ]- text ]-
This notation can also be used for defining functions.
g "x" = -[ Dear -[ "x" ]- bla bla ]-
The double quotes aren't for character strings but dummy variables.
V
A simple quoted string is of the form 'string' e.g
'hello world' puts
Vim Script
A string constant delimited by double quotes " may contain escape sequences like \n, \t, \123 (byte value in octal), \xab (byte value in hexadecimal), \\ (backslash), \" or \u12ff (character code in hexadecimal according to the current encoding).
If a string constant is delimited by single quotes ' all characters are taken as they are. In order to use a single quote inside a literal string it must be escaped with another single quote, i.e. two single quotes stand for one.
Strings must always end at the current line and characters are just strings of length one.
Visual Basic
Debug.Print "Tom said, ""The fox ran away."""
Debug.Print "Tom said, 'The fox ran away.'"
- Output:
Tom said, "The fox ran away." Tom said, 'The fox ran away.'
Visual Basic .NET
Visual Basic only supports single-line strings. The only escape sequence supported is the double double-quote (""), which is translated into a single double-quote.
Dim s = "Tom said, ""The fox ran away."""
Result: Tom said, "The fox ran away."
V (Vlang)
Character literals for Unicode characters, "rune literals", are an alias for u32.
Character literals for UTF-8 characters, "string literals", are an alias for u8.
To denote rune, Unicode characters, ` (backticks) are used :
A rune can be converted to a UTF-8 string by using the .str() method.
rocket := `🚀`
rocket.str() == '🚀' // uses single quotes, not the backtick, after conversion
A string can be converted back to runes by the .runes() method.
hello := 'Hello World'
hello_runes := hello.runes() // [`H`, `e`, `l`, `l`, `o`, ` `, `W`, `o`, `r`, `l`, `d`]
In V, a string is an immutable array of read-only bytes. All Unicode characters are encoded using UTF-8:
mut s := 'hello 🌎'
s[0] = `H` // not allowed as immutable
// convert `string` to `[]u8`
s := 'hello 🌎'
arr := s.bytes()
assert arr.len == 10
// convert `[]u8` to `string`
s2 := arr.bytestr()
assert s2 == s
// indexing gives a byte, u8(66) == `B`
name := 'Bob'
println(name.len == 3) // will print 3
if name[0] == u8(66) {println(name[0].ascii_str())} // will print`B`
String literals are contained in quotes:
str:= "Hello, world!"
WEB
WEB supports single-quoted strings exactly like Pascal strings (duplicate a ' to represent a literal ').
Double-quoted strings are "pool strings"; they are replaced by a numeric literal by the preprocessor, and placed into a string pool file (duplicate a " to represent a literal ").
Pool strings consisting of exactly one character represent numbers 0-255 according to their ASCII character code.
Wren
In Wren a string is an immutable array of bytes. They are usually interpreted as UTF-8 but don't have to be and invalid UTF-8 sequences are permitted. A string can also include the zero byte (\0) which is not interpreted as a string terminator as would be the case in C.
All strings are instances of the built-in String class and there is no separate Character class as such. Characters are simply strings consisting of a single byte or Unicode code point (1 to 4 bytes).
Ordinary string literals must be surrounded in double quotes and support the following escape characters:
Character | Meaning |
---|---|
\0 | The NUL byte: 0 |
\" | A double quote character |
\\ | A backslash |
\% | A percent sign (see below) |
\a | Alarm beep |
\b | Backspace |
\e | ESC character |
\f | Form feed |
\n | Newline |
\r | Carriage return |
\t | Tab |
\v | Vertical tab |
\xhh | A single byte with hex value '0xhh' |
\uhhhh | A Unicode code point within the basic multilingual plane |
\Uhhhhhhhh | Any Unicode code point including emojis |
Ordinary string literals also allow interpolation. If you have a percent sign (%) followed by a parenthesized expression, the expression is evaluated and can be arbitrarily complex. Consequently, if you need to include a normal % character in a string literal, you have to use the escaped form \%.
From v0.4.0 Wren also supports raw string literals. These are any text surrounded by triple double quotes, """, and are interpreted verbatim i.e. any control codes and/or interpolations are not processed as such. They can include single or double double quotes without problem.
var s = "abc123"
var t = "abc\t123\%"
var u = "\U0001F64A\U0001F680"
var v = "%("abc" * 3)"
var w = """a"bc""def\n%(v)"""
System.print([s, t, u, v, w])
- Output:
[abc123, abc 123%, 🙊🚀, abcabcabc, a"bc""def\n%(v)]
Xojo
Xojo only supports single-line strings. The only escape sequence supported is the double double-quote (""), which is translated into a single double-quote.
Dim s As String = "Tom said, ""The fox ran away."""
Result: Tom said, "The fox ran away."
XPL0
The literal value of a character is specified by preceding it with a caret. For example, this assigns the ASCII value of A (hex 41) to Ch: Ch:= ^A; Strings are one-dimensional byte arrays. For example, this assigns the address of the string enclosed in quote marks to Str: Str:= "Hello, world!"; The ASCII code for each character is stored in sequential bytes. By default strings are terminated with the most significant bit set on the last character. The exclamation point would be stored as hex A1. Strings can also be terminated with a zero byte (like in the C language). If the command: string 0; occurs anywhere before a string is set up then it will have an extra zero byte at the end. A quote mark can be included in a string by preceding it with a caret. Carets are also included this way. For example: "^"^^^" is a ^"caret^"" results in: "^" is a "caret" Carets can also be used to specify control characters. For example, this is escape E (hex 1B C5): "^[E" Strings can any length and can span lines, for example: "Hello, world!" A carriage return (hex 0D) and line feed (hex 0A) are in the middle. Strings are output to various devices (such as the console screen or printer) with the Text intrinsic.
XSLT
XSLT is based on XML, and so can use either " or ' to delimit strings. Since XML attribute values are defined using double-quotes, one must use single-quotes for string literals within attributes.
<xsl:if test="starts-with(@name, 'Mr.')">Mister</xsl:if>
Double and single quote characters may also be escaped with XML entities: " and ' respectively.
Z80 Assembly
Strings are enclosed in double quotes.
db "Hello World"
Any typed character in double quotes is assembled as the ASCII equivalent of that character. Therefore the following two data blocks are equivalent:
db "Hello World"
db $48,$65,$6c,$6c,$6f,$20,$57,$6f,$72,$6c,$64
The assembler typically assumes nothing with regard to special characters. A \n
will be interpreted literally, for example. How special characters are handled depends on the printing routine of the hardware's BIOS, or one created by the programmer. If your printing routine is able to support a null terminator and ASCII control codes, the following represents "Hello World" with the new line command and null terminator:
db "Hello World",13,10,0
Creating your own printing routine is a bit out of the scope of this task but here's a simple demonstration that supports the \n and null termination:
PrintString:
; HL contains the pointer to the string literal.
ld a,(hl)
or a ;compares to zero quicker than "CP 0"
ret z ;we're done printing the string, so exit.
cp '\' ; a single ascii character is specified in single quotes. This compares A to the backslash's ASCII value.
jr z,HandleSpecialChars ; if accumulator = '\' then goto "HandleSpecialChars"
call PrintChar ;unimplemented print routine, depending on the system this is either a BIOS call
; or a routine written by the programmer.
inc hl ;next character
jr PrintString ;back to top
HandleSpecialChars:
inc hl ;next char
ld a,(hl)
cp 'n'
call z,NewLine ;unimplemented routine, advances text cursor to next line. Only called if accumulator = 'n'.
inc hl ;advance past the 'n' to the next char.
jr PrintString ;jump back to top. Notice that neither the backslash nor the character after it were actually printed.
zkl
Interpreted string: "hoho". Raw string: 0'|hoho| where | is user choosen. \b, \f, \n, \r, \t, \e escapes are supported. Two adjacent strings are treated as one: "foo" 0'~bar~ --> "foobar". No variable expansion.
here-strings:
text:=
0'|foo|
"bar\n";
- Output:
"foobar\n"
n:=7; text:=String(
"foo = ",3,"\n"
"bar=",n,"\n"
);
- Output:
text = "foo = 3\nbar=7"