title |
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Strings |
The most important thing to know about strings in Common Lisp is probably that they are arrays and thus also sequences. This implies that all concepts that are applicable to arrays and sequences also apply to strings. If you can't find a particular string function, make sure you've also searched for the more general array or sequence functions. We'll only cover a fraction of what can be done with and to strings here.
ASDF3, which is included with almost all Common Lisp implementations,
includes
Utilities for Implementation- and OS- Portability (UIOP),
which defines functions to work on strings (strcat
,
string-prefix-p
, string-enclosed-p
, first-char
, last-char
,
split-string
, stripln
).
Some external libraries available on Quicklisp bring some more functionality or some shorter ways to do.
- str defines
trim
,words
,unwords
,lines
,unlines
,concat
,split
,shorten
,repeat
,replace-all
,starts-with?
,ends-with?
,blankp
,emptyp
, … - Serapeum is a large set of utilities with many string manipulation functions.
- cl-change-case
has functions to convert strings between camelCase, param-case,
snake_case and more. They are also included into
str
. - mk-string-metrics has functions to calculate various string metrics efficiently (Damerau-Levenshtein, Hamming, Jaro, Jaro-Winkler, Levenshtein, etc),
- and
cl-ppcre
can come in handy, for exampleppcre:replace-regexp-all
. See the regexp section.
Last but not least, when you'll need to tackle the format
construct,
don't miss the following resources:
- the official CLHS documentation
- a quick reference
- a CLHS summary on HexstreamSoft
- the list of all format directives at the end of this document.
- plus a Slime tip: type
C-c C-d ~
plus a letter of a format directive to open up its documentation. Use TAB-completion to list them all. Again more useful withivy-mode
orhelm-mode
.
A string is created with double quotes, all right, but we can recall these other ways:
- using
format nil
doesn't print but returns a new string (see more examples offormat
below):
(defparameter *person* "you")
(format nil "hello ~a" *person*) ;; => "hello you"
make-string count
creates a string of the given length. The:initial-element
character is repeatedcount
times:
(make-string 3 :initial-element #\♥) ;; => "♥♥♥"
As a string is a sequence, you can access substrings with the SUBSEQ function. The index into the string is, as always, zero-based. The third, optional, argument is the index of the first character which is not a part of the substring, it is not the length of the substring.
(defparameter *my-string* (string "Groucho Marx"))
*MY-STRING*
(subseq *my-string* 8)
"Marx"
(subseq *my-string* 0 7)
"Groucho"
(subseq *my-string* 1 5)
"rouc"
You can also manipulate the substring if you use SUBSEQ together with SETF.
* (defparameter *my-string* (string "Harpo Marx"))
*MY-STRING*
* (subseq *my-string* 0 5)
"Harpo"
* (setf (subseq *my-string* 0 5) "Chico")
"Chico"
* *my-string*
"Chico Marx"
But note that the string isn't "stretchable". To cite from the HyperSpec: "If the subsequence and the new sequence are not of equal length, the shorter length determines the number of elements that are replaced." For example:
* (defparameter *my-string* (string "Karl Marx"))
*MY-STRING*
* (subseq *my-string* 0 4)
"Karl"
* (setf (subseq *my-string* 0 4) "Harpo")
"Harpo"
* *my-string*
"Harp Marx"
* (subseq *my-string* 4)
" Marx"
* (setf (subseq *my-string* 4) "o Marx")
"o Marx"
* *my-string*
"Harpo Mar"
You can use the function CHAR to access individual characters of a string. CHAR can also be used in conjunction with SETF.
* (defparameter *my-string* (string "Groucho Marx"))
*MY-STRING*
* (char *my-string* 11)
#\x
* (char *my-string* 7)
#\Space
* (char *my-string* 6)
#\o
* (setf (char *my-string* 6) #\y)
#\y
* *my-string*
"Grouchy Marx"
Note that there's also SCHAR. If efficiency is important, SCHAR can be a bit faster where appropriate.
Because strings are arrays and thus sequences, you can also use the more generic functions AREF and ELT (which are more general while CHAR might be implemented more efficiently).
* (defparameter *my-string* (string "Groucho Marx"))
*MY-STRING*
* (aref *my-string* 3)
#\u
* (elt *my-string* 8)
#\M
Each character in a string has an integer code. The range of recognized codes and Lisp's ability to print them is directed related to your implementation's character set support, e.g. ISO-8859-1, or Unicode. Here are some examples in SBCL of UTF-8 which encodes characters as 1 to 4 8 bit bytes. The first example shows a character outside the first 128 chars, or what is considered the normal Latin character set. The second example shows a multibyte encoding (beyond the value 255). Notice the Lisp reader can round-trip characters by name.
* (stream-external-format *standard-output*)
:UTF-8
* (code-char 200)
#\LATIN_CAPITAL_LETTER_E_WITH_GRAVE
* (char-code #\LATIN_CAPITAL_LETTER_E_WITH_GRAVE)
200
* (code-char 2048)
#\SAMARITAN_LETTER_ALAF
* (char-code #\SAMARITAN_LETTER_ALAF)
2048
Check out the UTF-8 Wikipedia article for the range of supported characters and their encodings.
There's a slew of (sequence) functions that can be used to manipulate a string and we'll only provide some examples here. See the sequences dictionary in the HyperSpec for more.
remove
one character from a string:
* (remove #\o "Harpo Marx")
"Harp Marx"
* (remove #\a "Harpo Marx")
"Hrpo Mrx"
* (remove #\a "Harpo Marx" :start 2)
"Harpo Mrx"
* (remove-if #'upper-case-p "Harpo Marx")
"arpo arx"
Replace one character with substitute
(non destructive) or replace
(destructive):
* (substitute #\u #\o "Groucho Marx")
"Gruuchu Marx"
* (substitute-if #\_ #'upper-case-p "Groucho Marx")
"_roucho _arx"
* (defparameter *my-string* (string "Zeppo Marx"))
*MY-STRING*
* (replace *my-string* "Harpo" :end1 5)
"Harpo Marx"
* *my-string*
"Harpo Marx"
The name says it all: CONCATENATE is your friend. Note that this is a generic sequence function and you have to provide the result type as the first argument.
* (concatenate 'string "Karl" " " "Marx")
"Karl Marx"
* (concatenate 'list "Karl" " " "Marx")
(#\K #\a #\r #\l #\Space #\M #\a #\r #\x)
With UIOP, use strcat
:
* (uiop:strcat "karl" " " marx")
or with the library str
, use concat
:
* (str:concat "foo" "bar")
If you have to construct a string out of many parts, all of these calls to CONCATENATE seem wasteful, though. There are at least three other good ways to construct a string piecemeal, depending on what exactly your data is. If you build your string one character at a time, make it an adjustable VECTOR (a one-dimensional ARRAY) of type character with a fill-pointer of zero, then use VECTOR-PUSH-EXTEND on it. That way, you can also give hints to the system if you can estimate how long the string will be. (See the optional third argument to VECTOR-PUSH-EXTEND.)
* (defparameter *my-string* (make-array 0
:element-type 'character
:fill-pointer 0
:adjustable t))
*MY-STRING*
* *my-string*
""
* (dolist (char '(#\Z #\a #\p #\p #\a))
(vector-push-extend char *my-string*))
NIL
* *my-string*
"Zappa"
If the string will be constructed out of (the printed representations of) arbitrary objects, (symbols, numbers, characters, strings, ...), you can use FORMAT with an output stream argument of NIL. This directs FORMAT to return the indicated output as a string.
* (format nil "This is a string with a list ~A in it"
'(1 2 3))
"This is a string with a list (1 2 3) in it"
We can use the looping constructs of the FORMAT mini language to emulate CONCATENATE.
* (format nil "The Marx brothers are:~{ ~A~}."
'("Groucho" "Harpo" "Chico" "Zeppo" "Karl"))
"The Marx brothers are: Groucho Harpo Chico Zeppo Karl."
FORMAT can do a lot more processing but it has a relatively arcane syntax. After this last example, you can find the details in the CLHS section about formatted output.
* (format nil "The Marx brothers are:~{ ~A~^,~}."
'("Groucho" "Harpo" "Chico" "Zeppo" "Karl"))
"The Marx brothers are: Groucho, Harpo, Chico, Zeppo, Karl."
Another way to create a string out of the printed representation of various object is using WITH-OUTPUT-TO-STRING. The value of this handy macro is a string containing everything that was output to the string stream within the body to the macro. This means you also have the full power of FORMAT at your disposal, should you need it.
* (with-output-to-string (stream)
(dolist (char '(#\Z #\a #\p #\p #\a #\, #\Space))
(princ char stream))
(format stream "~S - ~S" 1940 1993))
"Zappa, 1940 - 1993"
Use the MAP function to process a string one character at a time.
* (defparameter *my-string* (string "Groucho Marx"))
*MY-STRING*
* (map 'string (lambda (c) (print c)) *my-string*)
#\G
#\r
#\o
#\u
#\c
#\h
#\o
#\Space
#\M
#\a
#\r
#\x
"Groucho Marx"
Or do it with LOOP.
* (loop for char across "Zeppo"
collect char)
(#\Z #\e #\p #\p #\o)
Reversing a string by character is easy using the built-in REVERSE function (or its destructive counterpart NREVERSE).
*(defparameter *my-string* (string "DSL"))
*MY-STRING*
* (reverse *my-string*)
"LSD"
There's no one-liner in CL to reverse a string by word (like you would do it in Perl with split and join). You either have to use functions from an external library like SPLIT-SEQUENCE or you have to roll your own solution.
Here's an attempt with the str
library:
* (defparameter *singing* "singing in the rain")
*SINGING*
* (str:words *SINGING*)
("singing" "in" "the" "rain")
* (reverse *)
("rain" "the" "in" "singing")
* (str:unwords *)
"rain the in singing"
And here's another one with no external dependencies:
* (defun split-by-one-space (string)
"Returns a list of substrings of string
divided by ONE space each.
Note: Two consecutive spaces will be seen as
if there were an empty string between them."
(loop for i = 0 then (1+ j)
as j = (position #\Space string :start i)
collect (subseq string i j)
while j))
SPLIT-BY-ONE-SPACE
* (split-by-one-space "Singing in the rain")
("Singing" "in" "the" "rain")
* (split-by-one-space "Singing in the rain")
("Singing" "in" "the" "" "rain")
* (split-by-one-space "Cool")
("Cool")
* (split-by-one-space " Cool ")
("" "Cool" "")
* (defun join-string-list (string-list)
"Concatenates a list of strings
and puts spaces between the elements."
(format nil "~{~A~^ ~}" string-list))
JOIN-STRING-LIST
* (join-string-list '("We" "want" "better" "examples"))
"We want better examples"
* (join-string-list '("Really"))
"Really"
* (join-string-list '())
""
* (join-string-list
(nreverse
(split-by-one-space
"Reverse this sentence by word")))
"word by sentence this Reverse"
We'll use here SBCL's string operations. More generally, see SBCL's unicode support.
Sorting unicode strings with string-lessp
as the comparison function
isn't satisfying:
(sort '("Aaa" "Ééé" "Zzz") #'string-lessp)
;; ("Aaa" "Zzz" "Ééé")
With SBCL, use sb-unicode:unicode<
:
(sort '("Aaa" "Ééé" "Zzz") #'sb-unicode:unicode<)
;; ("Aaa" "Ééé" "Zzz")
These functions use SBCL's sb-unicode
: they are SBCL specific.
Use sb-unicode:sentences
to break a string into sentences according
to the default sentence breaking rules.
Use sb-unicode:lines
to break a string into lines that are no wider
than the :margin
keyword argument. Combining marks will always be kept together with their base characters, and spaces (but not other types of whitespace) will be removed from the end of lines. If :margin
is unspecified, it defaults to 80 characters
(sb-unicode:lines "A first sentence. A second somewhat long one." :margin 10)
;; => ("A first"
"sentence."
"A second"
"somewhat"
"long one.")
See also sb-unicode:words
and sb-unicode:graphenes
.
Tip: you can ensure these functions are run only in SBCL with a feature flag:
#+sbcl
(runs on sbcl)
#-sbcl
(runs on other implementations)
Common Lisp has a couple of functions to control the case of a string.
* (string-upcase "cool")
"COOL"
* (string-upcase "Cool")
"COOL"
* (string-downcase "COOL")
"cool"
* (string-downcase "Cool")
"cool"
* (string-capitalize "cool")
"Cool"
* (string-capitalize "cool example")
"Cool Example"
These functions take the :start
and :end
keyword arguments so you can optionally
only manipulate a part of the string. They also have destructive counterparts
whose names starts with "N".
* (string-capitalize "cool example" :start 5)
"cool Example"
* (string-capitalize "cool example" :end 5)
"Cool example"
* (defparameter *my-string* (string "BIG"))
*MY-STRING*
* (defparameter *my-downcase-string* (nstring-downcase *my-string*))
*MY-DOWNCASE-STRING*
* *my-downcase-string*
"big"
* *my-string*
"big"
Note this potential caveat: according to the HyperSpec,
for STRING-UPCASE, STRING-DOWNCASE, and STRING-CAPITALIZE, string is not modified. However, if no characters in string require conversion, the result may be either string or a copy of it, at the implementation's discretion.
This implies that the last result in the following example is implementation-dependent - it may either be "BIG" or "BUG". If you want to be sure, use COPY-SEQ.
* (defparameter *my-string* (string "BIG"))
*MY-STRING*
* (defparameter *my-upcase-string* (string-upcase *my-string*))
*MY-UPCASE-STRING*
* (setf (char *my-string* 1) #\U)
#\U
* *my-string*
"BUG"
* *my-upcase-string*
"BIG"
The format function has directives to change the case of words:
(format t "~(~a~)" "HELLO WORLD")
;; => hello world
(format t "~:(~a~)" "HELLO WORLD")
Hello World
NIL
(format t "~@(~a~)" "hello world")
Hello world
NIL
Where we re-use the colon and the @:
(format t "~@:(~a~)" "hello world")
HELLO WORLD
NIL
Not only can you trim blanks, but you can get rid of arbitrary characters. The functions STRING-TRIM, STRING-LEFT-TRIM and STRING-RIGHT-TRIM return a substring of their second argument where all characters that are in the first argument are removed off the beginning and/or the end. The first argument can be any sequence of characters.
* (string-trim " " " trim me ")
"trim me"
* (string-trim " et" " trim me ")
"rim m"
* (string-left-trim " et" " trim me ")
"rim me "
* (string-right-trim " et" " trim me ")
" trim m"
* (string-right-trim '(#\Space #\e #\t) " trim me ")
" trim m"
* (string-right-trim '(#\Space #\e #\t #\m) " trim me ")
Note: The caveat mentioned in the section about Controlling Case also applies here.
The function INTERN will "convert" a string to a symbol. Actually, it will check whether the symbol denoted by the string (its first argument) is already accessible in the package (its second, optional, argument which defaults to the current package) and enter it, if necessary, into this package. It is beyond the scope of this chapter to explain all the concepts involved and to address the second return value of this function. See the CLHS chapter about packages for details.
Note that the case of the string is relevant.
* (in-package "COMMON-LISP-USER")
#<The COMMON-LISP-USER package, 35/44 internal, 0/9 external>
* (intern "MY-SYMBOL")
MY-SYMBOL
NIL
* (intern "MY-SYMBOL")
MY-SYMBOL
:INTERNAL
* (export 'MY-SYMBOL)
T
* (intern "MY-SYMBOL")
MY-SYMBOL
:EXTERNAL
* (intern "My-Symbol")
|My-Symbol|
NIL
* (intern "MY-SYMBOL" "KEYWORD")
:MY-SYMBOL
NIL
* (intern "MY-SYMBOL" "KEYWORD")
:MY-SYMBOL
:EXTERNAL
To do the opposite, convert from a symbol to a string, use SYMBOL-NAME or STRING.
* (symbol-name 'MY-SYMBOL)
"MY-SYMBOL"
* (symbol-name 'my-symbol)
"MY-SYMBOL"
* (symbol-name '|my-symbol|)
"my-symbol"
* (string 'howdy)
"HOWDY"
You can use COERCE to convert a string of length 1 to a character. You can also use COERCE to convert any sequence of characters into a string. You can not use COERCE to convert a character to a string, though - you'll have to use STRING instead.
* (coerce "a" 'character)
#\a
* (coerce (subseq "cool" 2 3) 'character)
#\o
* (coerce "cool" 'list)
(#\c #\o #\o #\l)
* (coerce '(#\h #\e #\y) 'string)
"hey"
* (coerce (nth 2 '(#\h #\e #\y)) 'character)
#\y
* (defparameter *my-array* (make-array 5 :initial-element #\x))
*MY-ARRAY*
* *my-array*
#(#\x #\x #\x #\x #\x)
* (coerce *my-array* 'string)
"xxxxx"
* (string 'howdy)
"HOWDY"
* (string #\y)
"y"
* (coerce #\y 'string)
#\y can't be converted to type STRING.
[Condition of type SIMPLE-TYPE-ERROR]
Use find
, position
, and their …-if
counterparts to find characters in a string, with the appropriate :test
parameter:
(find #\t "Tea time." :test #'equal)
#\t
* (find #\t "Tea time." :test #'equalp)
#\T
* (find #\z "Tea time." :test #'equalp)
NIL
* (find-if #'digit-char-p "Tea time.")
#\1
* (find-if #'digit-char-p "Tea time." :from-end t)
#\0
(position #\t "Tea time." :test #'equal)
4 ;; <= the first lowercase t
(position #\t "Tea time." :test #'equalp)
0 ;; <= the first capital T
(position-if #'digit-char-p "Tea time is at 5'00.")
15
(position-if #'digit-char-p "Tea time is at 5'00." :from-end t)
18
Or use count
and friends to count characters in a string:
(count #\t "Tea time." :test #'equal)
1 ;; <= equal ignores the capital T
(count #\t "Tea time." :test #'equalp)
2 ;; <= equalp counts the capital T
(count-if #'digit-char-p "Tea time is at 5'00.")
3
(count-if #'digit-char-p "Tea time is at 5'00." :start 18)
1
The function search
can find substrings of a string.
* (search "we" "If we can't be free we can at least be cheap")
3
* (search "we" "If we can't be free we can at least be cheap"
:from-end t)
20
* (search "we" "If we can't be free we can at least be cheap"
:start2 4)
20
* (search "we" "If we can't be free we can at least be cheap"
:end2 5 :from-end t)
3
* (search "FREE" "If we can't be free we can at least be cheap")
NIL
* (search "FREE" "If we can't be free we can at least be cheap"
:test #'char-equal)
15
CL provides the parse-integer
function to convert a string representation of an integer
to the corresponding numeric value. The second return value is the index into
the string where the parsing stopped.
(parse-integer "42")
42
2
(parse-integer "42" :start 1)
2
2
(parse-integer "42" :end 1)
4
1
(parse-integer "42" :radix 8)
34
2
(parse-integer " 42 ")
42
3
(parse-integer " 42 is forty-two" :junk-allowed t)
42
3
(parse-integer " 42 is forty-two")
Error in function PARSE-INTEGER:
There's junk in this string: " 42 is forty-two".
parse-integer
doesn't understand radix specifiers like #X
, nor is there a
built-in function to parse other numeric types. You could use read-from-string
in this case.
We show this in the Regular Expressions chapter but while we are on this topic, you can find it super useful:
* (ppcre:all-matches-as-strings "-?\\d+" "42 is 41 plus 1")
;; ("42" "41" "1")
* (mapcar #'parse-integer *)
;; (42 41 1)
Be aware that the full reader is in effect if you're using this
function. This can lead to vulnerability issues. You should use a
library like parse-number
or parse-float
instead.
(read-from-string "#X23")
35
4
(read-from-string "4.5")
4.5
3
(read-from-string "6/8")
3/4
3
(read-from-string "#C(6/8 1)")
#C(3/4 1)
9
(read-from-string "1.2e2")
120.00001
5
(read-from-string "symbol")
SYMBOL
6
(defparameter *foo* 42)
*FOO*
(read-from-string "#.(setq *foo* \"gotcha\")")
"gotcha"
23
*foo*
"gotcha"
At the very least, if you are reading data coming from the outside, use this:
(let ((cl:*read-eval* nil))
(read-from-string "…"))
This prevents code to be evaluated at read-time. That way our last example, using the #.
reader macro, would not work. You'll get the error "can't read #. while *READ-EVAL* is NIL".
And better yet, for more protection from a possibly custom readtable that would introduce another reader macro:
(with-standard-io-syntax
(let ((cl:*read-eval* nil))
(read-from-string "…")))
There is no built-in function similar to parse-integer
to parse
other number types. The external library
parse-float does exactly
that. It doesn't use read-from-string
so it is safe to use.
(ql:quickload "parse-float")
(parse-float:parse-float "1.2e2")
;; 120.00001
;; 5
LispWorks also has a parse-float function.
See also parse-number.
The general function WRITE-TO-STRING or one of its simpler variants PRIN1-TO-STRING or PRINC-TO-STRING may be used to convert a number to a string. With WRITE-TO-STRING, the :base keyword argument may be used to change the output base for a single call. To change the output base globally, set print-base which defaults to 10. Remember in Lisp, rational numbers are represented as quotients of two integers even when converted to strings.
(write-to-string 250)
"250"
(write-to-string 250.02)
"250.02"
(write-to-string 250 :base 5)
"2000"
(write-to-string (/ 1 3))
"1/3"
*
The general functions EQUAL and EQUALP can be used to test whether two strings are equal. The strings are compared element-by-element, either in a case-sensitive manner (EQUAL) or not (EQUALP). There's also a bunch of string-specific comparison functions. You'll want to use these if you're deploying implementation-defined attributes of characters. Check your vendor's documentation in this case.
Here are a few examples. Note that all functions that test for inequality return the position of the first mismatch as a generalized boolean. You can also use the generic sequence function MISMATCH if you need more versatility.
(string= "Marx" "Marx")
T
(string= "Marx" "marx")
NIL
(string-equal "Marx" "marx")
T
(string< "Groucho" "Zeppo")
0
(string< "groucho" "Zeppo")
NIL
(string-lessp "groucho" "Zeppo")
0
(mismatch "Harpo Marx" "Zeppo Marx" :from-end t :test #'char=)
3
The format
function has a lot of directives to print strings,
numbers, lists, going recursively, even calling Lisp functions,
etc. We'll focus here on a few things to print and format strings.
The need of our examples arise when we want to print many strings and justify them. Let's work with this list of movies:
(defparameter movies '(
(1 "Matrix" 5)
(10 "Matrix Trilogy swe sub" 3.3)
))
We want an aligned and justified result like this:
1 Matrix 5
10 Matrix Trilogy swe sub 3.3
We'll use mapcar
to iterate over our movies and experiment with the
format constructs.
(mapcar (lambda (it)
(format t "~a ~a ~a~%" (first it) (second it) (third it)))
movies)
which prints:
1 Matrix 5
10 Matrix Trilogy swe sub 3.3
Format directives start with ~
. A final character like A
or a
(they are case insensitive) defines the directive. In between, it can
accept coma-separated options and parameters.
Print a tilde with ~~
, or 10 with ~10~
.
Other directives include:
R
: Roman (e.g., prints in English):(format t "~R" 20)
=> "twenty".$
: monetary:(format t "~$" 21982)
=> 21982.00D
,B
,O
,X
: Decimal, Binary, Octal, Hexadecimal.F
: fixed-format Floating point.P
: plural:(format nil "~D famil~:@P/~D famil~:@P" 7 1)
=> "7 families/1 family"
(format t "~a" movies)
is the most basic primitive.
(format nil "~a" movies)
;; => "((1 Matrix 5) (10 Matrix Trilogy swe sub 3.3))"
~%
is the newline character. ~10%
prints 10 newlines.
~&
does not print a newline if the output stream is already at one.
with ~T
. Also ~10T
works.
Also i
for indentation.
Use a number as parameter, like ~2a
:
(format nil "~20a" "yo")
;; "yo "
(mapcar (lambda (it)
(format t "~2a ~a ~a~%" (first it) (second it) (third it)))
movies)
1 Matrix 5
10 Matrix Trilogy swe sub 3.3
So, expanding:
(mapcar (lambda (it)
(format t "~2a ~25a ~2a~%" (first it) (second it) (third it)))
movies)
1 Matrix 5
10 Matrix Trilogy swe sub 3.3
text is justified on the right (this would be with option :
).
Use a @
as in ~2@A
:
(format nil "~20@a" "yo")
;; " yo"
(mapcar (lambda (it)
(format nil "~2@a ~25@a ~2a~%" (first it) (second it) (third it)))
movies)
1 Matrix 5
10 Matrix Trilogy swe sub 3.3
In ~,2F
, 2 is the number of decimals and F the floats directive:
(format t "~,2F" 20.1)
=> "20.10".
With ~2,2f
:
(mapcar (lambda (it)
(format t "~2@a ~25a ~2,2f~%" (first it) (second it) (third it)))
movies)
1 Matrix 5.00
10 Matrix Trilogy swe sub 3.30
And we're happy with this result.
Create a string from a list with iteration construct ~{str~}
:
(format nil "~{~A, ~}" '(a b c))
;; "A, B, C, "
using ~^
to avoid printing the comma and space after the last element:
(format nil "~{~A~^, ~}" '(a b c))
;; "A, B, C"
~:{str~}
is similar but for a list of sublists:
(format nil "~:{~S are ~S. ~}" '((pigeons birds) (dogs mammals)))
;; "PIGEONS are BIRDS. DOGS are MAMMALS. "
~@{str~}
is similar to ~{str~}
, but instead of using one argument that is a list, all the remaining arguments are used as the list of arguments for the iteration:
(format nil "~@{~S are ~S. ~}" 'pigeons 'birds 'dogs 'mammals)
;; "PIGEONS are BIRDS. DOGS are MAMMALS. "
Sometimes you want to justify a string, but the length is a variable
itself. You can't hardcode its value as in (format nil "~30a" "foo")
. Enters the v
directive. We can use it in place of the
comma-separated prefix parameters:
(let ((padding 30))
(format nil "~va" padding "foo"))
;; "foo "
Other times, you would like to insert a complete format directive
at run time. Enters the ?
directive.
(format nil "~?" "~30a" '("foo"))
;; ^ a list
or, using ~@?
:
(format nil "~@?" "~30a" "foo" )
;; ^ not a list
Of course, it is always possible to format a format string beforehand:
(let* ((length 30)
(directive (format nil "~~~aa" length)))
(format nil directive "foo"))
Choose one value out of many options by specifying a number:
(format nil "~[dog~;cat~;bird~:;default~]" 0)
;; "dog"
(format nil "~[dog~;cat~;bird~:;default~]" 1)
;; "cat"
If the number is out of range, the default option (after ~:;
) is returned:
(format nil "~[dog~;cat~;bird~:;default~]" 9)
;; "default"
Combine it with ~:*
to implement irregular plural:
(format nil "I saw ~r el~:*~[ves~;f~:;ves~]." 0)
;; => "I saw zero elves."
(format nil "I saw ~r el~:*~[ves~;f~:;ves~]." 1)
;; => "I saw one elf."
(format nil "I saw ~r el~:*~[ves~;f~:;ves~]." 2)
;; => "I saw two elves."
Inside (with-output-to-string (mystream) …)
, everything that is
printed into the stream mystream
is captured and returned as a
string:
(defun greet (name &key (stream t))
;; by default, print to standard output.
(format stream "hello ~a" name))
(let ((output (with-output-to-string (stream)
(greet "you" :stream stream))))
(format t "Output is: '~a'. It is indeed a ~a, aka a string.~&" output (type-of output)))
;; Output is: 'hello you'. It is indeed a (SIMPLE-ARRAY CHARACTER (9)), aka a string.
;; NIL
The following examples use the
cl-slug library which,
internally, iterates over the characters of the string and uses
ppcre:regex-replace-all
.
(ql:quickload "cl-slug")
Then it can be used with the slug
prefix.
Its main function is to transform a string to a slug, suitable for a website's url:
(slug:slugify "My new cool article, for the blog (V. 2).")
;; "my-new-cool-article-for-the-blog-v-2"
Use slug:asciify
to replace accentuated letters by their ascii equivalent:
(slug:asciify "ñ é ß ğ ö")
;; => "n e ss g o"
This function supports many (western) languages:
slug:*available-languages*
((:TR . "Türkçe (Turkish)") (:SV . "Svenska (Swedish)") (:FI . "Suomi (Finnish)")
(:UK . "українська (Ukrainian)") (:RU . "Ру́сский (Russian)") (:RO . "Română (Romanian)")
(:RM . "Rumàntsch (Romansh)") (:PT . "Português (Portuguese)") (:PL . "Polski (Polish)")
(:NO . "Norsk (Norwegian)") (:LT . "Lietuvių (Lithuanian)") (:LV . "Latviešu (Latvian)")
(:LA . "Lingua Latīna (Latin)") (:IT . "Italiano (Italian)") (:EL . "ελληνικά (Greek)")
(:FR . "Français (French)") (:EO . "Esperanto") (:ES . "Español (Spanish)") (:EN . "English")
(:DE . "Deutsch (German)") (:DA . "Dansk (Danish)") (:CS . "Čeština (Czech)")
(:CURRENCY . "Currency"))
Use (str:remove-punctuation s)
or (str:no-case s)
(same as
(cl-change-case:no-case s)
):
(str:remove-punctuation "HEY! What's up ??")
;; "HEY What s up"
(str:no-case "HEY! What's up ??")
;; "hey what s up"
They strip the punctuation with one ppcre unicode regexp
((ppcre:regex-replace-all "[^\\p{L}\\p{N}]+"
where p{L}
is the
"letter" category and p{N}
any kind of numeric character).
All directives are case-insensivite: ~A
is the same as ~a
.
$ - Monetary Floating-Point
% - Newline
& - Fresh-line
( - Case Conversion
) - End of Case Conversion
* - Go-To
/ - Call Function
; - Clause Separator
< - Justification
< - Logical Block
> - End of Justification
? - Recursive Processing
A - Aesthetic
B - Binary
C - Character
D - Decimal
E - Exponential Floating-Point
F - Fixed-Format Floating-Point
G - General Floating-Point
I - Indent
Missing and Additional FORMAT Arguments
Nesting of FORMAT Operations
Newline: Ignored Newline
O - Octal
P - Plural
R - Radix
S - Standard
T - Tabulate
W - Write
X - Hexadecimal
[ - Conditional Expression
] - End of Conditional Expression
^ - Escape Upward
_ - Conditional Newline
{ - Iteration
| - Page
} - End of Iteration
~ - Tilde
- Pretty printing table data, in ASCII art, a tutorial as a Jupyter notebook.