Strings
Base.length
— Method.length(s::AbstractString)
The number of characters in string s
.
julia> length("jμΛIα")
5
Base.sizeof
— Method.sizeof(s::AbstractString)
The number of bytes in string s
.
julia> sizeof("❤")
3
Base.:*
— Method.*(x, y...)
Multiplication operator. x*y*z*...
calls this function with all arguments, i.e. *(x, y, z, ...)
.
Base.:^
— Method.^(s::AbstractString, n::Integer)
Repeat n
times the string s
. The repeat
function is an alias to this operator.
julia> "Test "^3
"Test Test Test "
Base.string
— Function.string(xs...)
Create a string from any values using the print
function.
julia> string("a", 1, true)
"a1true"
Base.repr
— Function.repr(x)
Create a string from any value using the showall
function.
Core.String
— Method.String(s::AbstractString)
Convert a string to a contiguous byte array representation encoded as UTF-8 bytes. This representation is often appropriate for passing strings to C.
Base.transcode
— Function.transcode(T, src)
Convert string data between Unicode encodings. src
is either a String
or a Vector{UIntXX}
of UTF-XX code units, where XX
is 8, 16, or 32. T
indicates the encoding of the return value: String
to return a (UTF-8 encoded) String
or UIntXX
to return a Vector{UIntXX}
of UTF-XX
data. (The alias Cwchar_t
can also be used as the integer type, for converting wchar_t*
strings used by external C libraries.)
The transcode
function succeeds as long as the input data can be reasonably represented in the target encoding; it always succeeds for conversions between UTF-XX encodings, even for invalid Unicode data.
Only conversion to/from UTF-8 is currently supported.
Base.unsafe_string
— Function.unsafe_string(p::Ptr{UInt8}, [length::Integer])
Copy a string from the address of a C-style (NUL-terminated) string encoded as UTF-8. (The pointer can be safely freed afterwards.) If length
is specified (the length of the data in bytes), the string does not have to be NUL-terminated.
This function is labelled "unsafe" because it will crash if p
is not a valid memory address to data of the requested length.
Base.codeunit
— Method.codeunit(s::AbstractString, i::Integer)
Get the i
th code unit of an encoded string. For example, returns the i
th byte of the representation of a UTF-8 string.
Base.ascii
— Function.ascii(s::AbstractString)
Convert a string to String
type and check that it contains only ASCII data, otherwise throwing an ArgumentError
indicating the position of the first non-ASCII byte.
julia> ascii("abcdeγfgh")
ERROR: ArgumentError: invalid ASCII at index 6 in "abcdeγfgh"
Stacktrace:
[1] ascii(::String) at ./strings/util.jl:479
julia> ascii("abcdefgh")
"abcdefgh"
Base.@r_str
— Macro.@r_str -> Regex
Construct a regex, such as r"^[a-z]*$"
. The regex also accepts one or more flags, listed after the ending quote, to change its behaviour:
i
enables case-insensitive matchingm
treats the^
and$
tokens as matching the start and end of individual lines, as opposed to the whole string.s
allows the.
modifier to match newlines.x
enables "comment mode": whitespace is enabled except when escaped with\
, and#
is treated as starting a comment.
For example, this regex has all three flags enabled:
julia> match(r"a+.*b+.*?d$"ism, "Goodbye,\nOh, angry,\nBad world\n")
RegexMatch("angry,\nBad world")
Base.Docs.@html_str
— Macro.@html_str -> Docs.HTML
Create an HTML
object from a literal string.
Base.Docs.@text_str
— Macro.@text_str -> Docs.Text
Create a Text
object from a literal string.
Base.UTF8proc.normalize_string
— Function.normalize_string(s::AbstractString, normalform::Symbol)
Normalize the string s
according to one of the four "normal forms" of the Unicode standard: normalform
can be :NFC
, :NFD
, :NFKC
, or :NFKD
. Normal forms C (canonical composition) and D (canonical decomposition) convert different visually identical representations of the same abstract string into a single canonical form, with form C being more compact. Normal forms KC and KD additionally canonicalize "compatibility equivalents": they convert characters that are abstractly similar but visually distinct into a single canonical choice (e.g. they expand ligatures into the individual characters), with form KC being more compact.
Alternatively, finer control and additional transformations may be be obtained by calling normalize_string(s; keywords...)
, where any number of the following boolean keywords options (which all default to false
except for compose
) are specified:
compose=false
: do not perform canonical compositiondecompose=true
: do canonical decomposition instead of canonical composition (compose=true
is ignored if present)compat=true
: compatibility equivalents are canonicalizedcasefold=true
: perform Unicode case folding, e.g. for case-insensitive string comparisonnewline2lf=true
,newline2ls=true
, ornewline2ps=true
: convert various newline sequences (LF, CRLF, CR, NEL) into a linefeed (LF), line-separation (LS), or paragraph-separation (PS) character, respectivelystripmark=true
: strip diacritical marks (e.g. accents)stripignore=true
: strip Unicode's "default ignorable" characters (e.g. the soft hyphen or the left-to-right marker)stripcc=true
: strip control characters; horizontal tabs and form feeds are converted to spaces; newlines are also converted to spaces unless a newline-conversion flag was specifiedrejectna=true
: throw an error if unassigned code points are foundstable=true
: enforce Unicode Versioning Stability
For example, NFKC corresponds to the options compose=true, compat=true, stable=true
.
Base.UTF8proc.graphemes
— Function.graphemes(s::AbstractString) -> GraphemeIterator
Returns an iterator over substrings of s
that correspond to the extended graphemes in the string, as defined by Unicode UAX #29. (Roughly, these are what users would perceive as single characters, even though they may contain more than one codepoint; for example a letter combined with an accent mark is a single grapheme.)
Base.isvalid
— Method.isvalid(value) -> Bool
Returns true
if the given value is valid for its type, which currently can be either Char
or String
.
Base.isvalid
— Method.isvalid(T, value) -> Bool
Returns true
if the given value is valid for that type. Types currently can be either Char
or String
. Values for Char
can be of type Char
or UInt32
. Values for String
can be of that type, or Vector{UInt8}
.
Base.isvalid
— Method.isvalid(str::AbstractString, i::Integer)
Tells whether index i
is valid for the given string.
julia> str = "αβγdef";
julia> isvalid(str, 1)
true
julia> str[1]
'α': Unicode U+03b1 (category Ll: Letter, lowercase)
julia> isvalid(str, 2)
false
julia> str[2]
ERROR: UnicodeError: invalid character index
[...]
Base.UTF8proc.is_assigned_char
— Function.is_assigned_char(c) -> Bool
Returns true
if the given char or integer is an assigned Unicode code point.
Base.ismatch
— Function.ismatch(r::Regex, s::AbstractString) -> Bool
Test whether a string contains a match of the given regular expression.
Base.match
— Function.match(r::Regex, s::AbstractString[, idx::Integer[, addopts]])
Search for the first match of the regular expression r
in s
and return a RegexMatch
object containing the match, or nothing if the match failed. The matching substring can be retrieved by accessing m.match
and the captured sequences can be retrieved by accessing m.captures
The optional idx
argument specifies an index at which to start the search.
Base.eachmatch
— Function.eachmatch(r::Regex, s::AbstractString[, overlap::Bool=false])
Search for all matches of a the regular expression r
in s
and return a iterator over the matches. If overlap is true
, the matching sequences are allowed to overlap indices in the original string, otherwise they must be from distinct character ranges.
Base.matchall
— Function.matchall(r::Regex, s::AbstractString[, overlap::Bool=false]) -> Vector{AbstractString}
Return a vector of the matching substrings from eachmatch
.
Base.lpad
— Function.lpad(s, n::Integer, p::AbstractString=" ")
Make a string at least n
columns wide when printed by padding s
on the left with copies of p
.
julia> lpad("March",10)
" March"
Base.rpad
— Function.rpad(s, n::Integer, p::AbstractString=" ")
Make a string at least n
columns wide when printed by padding s
on the right with copies of p
.
julia> rpad("March",20)
"March "
Base.search
— Function.search(string::AbstractString, chars::Chars, [start::Integer])
Search for the first occurrence of the given characters within the given string. The second argument may be a single character, a vector or a set of characters, a string, or a regular expression (though regular expressions are only allowed on contiguous strings, such as ASCII or UTF-8 strings). The third argument optionally specifies a starting index. The return value is a range of indexes where the matching sequence is found, such that s[search(s,x)] == x
:
search(string, "substring")
= start:end
such that string[start:end] == "substring"
, or 0:-1
if unmatched.
search(string, 'c')
= index
such that string[index] == 'c'
, or 0
if unmatched.
julia> search("Hello to the world", "z")
0:-1
julia> search("JuliaLang","Julia")
1:5
Base.rsearch
— Function.rsearch(s::AbstractString, chars::Chars, [start::Integer])
Similar to search
, but returning the last occurrence of the given characters within the given string, searching in reverse from start
.
julia> rsearch("aaabbb","b")
6:6
Base.searchindex
— Function.searchindex(s::AbstractString, substring, [start::Integer])
Similar to search
, but return only the start index at which the substring is found, or 0
if it is not.
julia> searchindex("Hello to the world", "z")
0
julia> searchindex("JuliaLang","Julia")
1
julia> searchindex("JuliaLang","Lang")
6
Base.rsearchindex
— Function.rsearchindex(s::AbstractString, substring, [start::Integer])
Similar to rsearch
, but return only the start index at which the substring is found, or 0
if it is not.
julia> rsearchindex("aaabbb","b")
6
julia> rsearchindex("aaabbb","a")
3
Base.contains
— Method.contains(haystack::AbstractString, needle::AbstractString)
Determine whether the second argument is a substring of the first.
julia> contains("JuliaLang is pretty cool!", "Julia")
true
Base.reverse
— Method.reverse(s::AbstractString) -> AbstractString
Reverses a string.
julia> reverse("JuliaLang")
"gnaLailuJ"
Base.replace
— Function.replace(string::AbstractString, pat, r[, n::Integer=0])
Search for the given pattern pat
, and replace each occurrence with r
. If n
is provided, replace at most n
occurrences. As with search, the second argument may be a single character, a vector or a set of characters, a string, or a regular expression. If r
is a function, each occurrence is replaced with r(s)
where s
is the matched substring. If pat
is a regular expression and r
is a SubstitutionString
, then capture group references in r
are replaced with the corresponding matched text.
Base.split
— Function.split(s::AbstractString, [chars]; limit::Integer=0, keep::Bool=true)
Return an array of substrings by splitting the given string on occurrences of the given character delimiters, which may be specified in any of the formats allowed by search
's second argument (i.e. a single character, collection of characters, string, or regular expression). If chars
is omitted, it defaults to the set of all space characters, and keep
is taken to be false
. The two keyword arguments are optional: they are a maximum size for the result and a flag determining whether empty fields should be kept in the result.
julia> a = "Ma.rch"
"Ma.rch"
julia> split(a,".")
2-element Array{SubString{String},1}:
"Ma"
"rch"
Base.rsplit
— Function.rsplit(s::AbstractString, [chars]; limit::Integer=0, keep::Bool=true)
Similar to split
, but starting from the end of the string.
julia> a = "M.a.r.c.h"
"M.a.r.c.h"
julia> rsplit(a,".")
5-element Array{SubString{String},1}:
"M"
"a"
"r"
"c"
"h"
julia> rsplit(a,".";limit=1)
1-element Array{SubString{String},1}:
"M.a.r.c.h"
julia> rsplit(a,".";limit=2)
2-element Array{SubString{String},1}:
"M.a.r.c"
"h"
Base.strip
— Function.strip(s::AbstractString, [chars::Chars])
Return s
with any leading and trailing whitespace removed. If chars
(a character, or vector or set of characters) is provided, instead remove characters contained in it.
julia> strip("{3, 5}\n", ['{', '}', '\n'])
"3, 5"
Base.lstrip
— Function.lstrip(s::AbstractString[, chars::Chars])
Return s
with any leading whitespace and delimiters removed. The default delimiters to remove are ' '
, \t
, \n
, \v
, \f
, and \r
. If chars
(a character, or vector or set of characters) is provided, instead remove characters contained in it.
julia> a = lpad("March", 20)
" March"
julia> lstrip(a)
"March"
Base.rstrip
— Function.rstrip(s::AbstractString[, chars::Chars])
Return s
with any trailing whitespace and delimiters removed. The default delimiters to remove are ' '
, \t
, \n
, \v
, \f
, and \r
. If chars
(a character, or vector or set of characters) is provided, instead remove characters contained in it.
julia> a = rpad("March", 20)
"March "
julia> rstrip(a)
"March"
Base.startswith
— Function.startswith(s::AbstractString, prefix::AbstractString)
Returns true
if s
starts with prefix
. If prefix
is a vector or set of characters, tests whether the first character of s
belongs to that set.
See also endswith
.
julia> startswith("JuliaLang", "Julia")
true
Base.endswith
— Function.endswith(s::AbstractString, suffix::AbstractString)
Returns true
if s
ends with suffix
. If suffix
is a vector or set of characters, tests whether the last character of s
belongs to that set.
See also startswith
.
julia> endswith("Sunday", "day")
true
Base.uppercase
— Function.uppercase(s::AbstractString)
Returns s
with all characters converted to uppercase.
julia> uppercase("Julia")
"JULIA"
Base.lowercase
— Function.lowercase(s::AbstractString)
Returns s
with all characters converted to lowercase.
julia> lowercase("STRINGS AND THINGS")
"strings and things"
Base.titlecase
— Function.titlecase(s::AbstractString)
Capitalizes the first character of each word in s
.
julia> titlecase("the julia programming language")
"The Julia Programming Language"
Base.ucfirst
— Function.ucfirst(s::AbstractString)
Returns string
with the first character converted to uppercase.
julia> ucfirst("python")
"Python"
Base.lcfirst
— Function.lcfirst(s::AbstractString)
Returns string
with the first character converted to lowercase.
julia> lcfirst("Julia")
"julia"
Base.join
— Function.join(io::IO, strings, delim, [last])
Join an array of strings
into a single string, inserting the given delimiter between adjacent strings. If last
is given, it will be used instead of delim
between the last two strings. For example,
julia> join(["apples", "bananas", "pineapples"], ", ", " and ")
"apples, bananas and pineapples"
strings
can be any iterable over elements x
which are convertible to strings via print(io::IOBuffer, x)
. strings
will be printed to io
.
Base.chop
— Function.chop(s::AbstractString)
Remove the last character from s
.
julia> a = "March"
"March"
julia> chop(a)
"Marc"
Base.chomp
— Function.chomp(s::AbstractString)
Remove a single trailing newline from a string.
julia> chomp("Hello\n")
"Hello"
Base.ind2chr
— Function.ind2chr(s::AbstractString, i::Integer)
Convert a byte index i
to a character index with respect to string s
.
See also chr2ind
.
julia> str = "αβγdef";
julia> ind2chr(str, 3)
2
julia> chr2ind(str, 2)
3
Base.chr2ind
— Function.chr2ind(s::AbstractString, i::Integer)
Convert a character index i
to a byte index.
See also ind2chr
.
julia> str = "αβγdef";
julia> chr2ind(str, 2)
3
julia> ind2chr(str, 3)
2
Base.nextind
— Function.nextind(str::AbstractString, i::Integer)
Get the next valid string index after i
. Returns a value greater than endof(str)
at or after the end of the string.
julia> str = "αβγdef";
julia> nextind(str, 1)
3
julia> endof(str)
9
julia> nextind(str, 9)
10
Base.prevind
— Function.prevind(str::AbstractString, i::Integer)
Get the previous valid string index before i
. Returns a value less than 1
at the beginning of the string.
julia> prevind("αβγdef", 3)
1
julia> prevind("αβγdef", 1)
0
Base.Random.randstring
— Function.randstring([rng,] len=8)
Create a random ASCII string of length len
, consisting of upper- and lower-case letters and the digits 0-9. The optional rng
argument specifies a random number generator, see Random Numbers.
Base.UTF8proc.charwidth
— Function.charwidth(c)
Gives the number of columns needed to print a character.
Base.strwidth
— Function.strwidth(s::AbstractString)
Gives the number of columns needed to print a string.
julia> strwidth("March")
5
Base.UTF8proc.isalnum
— Function.isalnum(c::Char) -> Bool
Tests whether a character is alphanumeric. A character is classified as alphabetic if it belongs to the Unicode general category Letter or Number, i.e. a character whose category code begins with 'L' or 'N'.
Base.UTF8proc.isalpha
— Function.isalpha(c::Char) -> Bool
Tests whether a character is alphabetic. A character is classified as alphabetic if it belongs to the Unicode general category Letter, i.e. a character whose category code begins with 'L'.
Base.isascii
— Function.isascii(c::Union{Char,AbstractString}) -> Bool
Tests whether a character belongs to the ASCII character set, or whether this is true for all elements of a string.
Base.UTF8proc.iscntrl
— Function.iscntrl(c::Char) -> Bool
Tests whether a character is a control character. Control characters are the non-printing characters of the Latin-1 subset of Unicode.
Base.UTF8proc.isdigit
— Function.isdigit(c::Char) -> Bool
Tests whether a character is a numeric digit (0-9).
Base.UTF8proc.isgraph
— Function.isgraph(c::Char) -> Bool
Tests whether a character is printable, and not a space. Any character that would cause a printer to use ink should be classified with isgraph(c)==true
.
Base.UTF8proc.islower
— Function.islower(c::Char) -> Bool
Tests whether a character is a lowercase letter. A character is classified as lowercase if it belongs to Unicode category Ll, Letter: Lowercase.
Base.UTF8proc.isnumber
— Function.isnumber(c::Char) -> Bool
Tests whether a character is numeric. A character is classified as numeric if it belongs to the Unicode general category Number, i.e. a character whose category code begins with 'N'.
Base.UTF8proc.isprint
— Function.isprint(c::Char) -> Bool
Tests whether a character is printable, including spaces, but not a control character.
Base.UTF8proc.ispunct
— Function.ispunct(c::Char) -> Bool
Tests whether a character belongs to the Unicode general category Punctuation, i.e. a character whose category code begins with 'P'.
Base.UTF8proc.isspace
— Function.isspace(c::Char) -> Bool
Tests whether a character is any whitespace character. Includes ASCII characters '\t', '\n', '\v', '\f', '\r', and ' ', Latin-1 character U+0085, and characters in Unicode category Zs.
Base.UTF8proc.isupper
— Function.isupper(c::Char) -> Bool
Tests whether a character is an uppercase letter. A character is classified as uppercase if it belongs to Unicode category Lu, Letter: Uppercase, or Lt, Letter: Titlecase.
Base.isxdigit
— Function.isxdigit(c::Char) -> Bool
Tests whether a character is a valid hexadecimal digit. Note that this does not include x
(as in the standard 0x
prefix).
julia> isxdigit('a')
true
julia> isxdigit('x')
false
Core.Symbol
— Type.Symbol(x...) -> Symbol
Create a Symbol
by concatenating the string representations of the arguments together.
Base.escape_string
— Function.escape_string([io,] str::AbstractString[, esc::AbstractString]) -> AbstractString
General escaping of traditional C and Unicode escape sequences. Any characters in esc
are also escaped (with a backslash). See also unescape_string
.
Base.unescape_string
— Function.unescape_string([io,] s::AbstractString) -> AbstractString
General unescaping of traditional C and Unicode escape sequences. Reverse of escape_string
.