2 @c This is part of the GNU Emacs Lisp Reference Manual.
3 @c Copyright (C) 1990-1994, 1998-1999, 2001-2011 Free Software Foundation, Inc.
4 @c See the file elisp.texi for copying conditions.
5 @setfilename ../../info/streams
6 @node Read and Print, Minibuffers, Debugging, Top
7 @comment node-name, next, previous, up
8 @chapter Reading and Printing Lisp Objects
10 @dfn{Printing} and @dfn{reading} are the operations of converting Lisp
11 objects to textual form and vice versa. They use the printed
12 representations and read syntax described in @ref{Lisp Data Types}.
14 This chapter describes the Lisp functions for reading and printing.
15 It also describes @dfn{streams}, which specify where to get the text (if
16 reading) or where to put it (if printing).
19 * Streams Intro:: Overview of streams, reading and printing.
20 * Input Streams:: Various data types that can be used as input streams.
21 * Input Functions:: Functions to read Lisp objects from text.
22 * Output Streams:: Various data types that can be used as output streams.
23 * Output Functions:: Functions to print Lisp objects as text.
24 * Output Variables:: Variables that control what the printing functions do.
28 @section Introduction to Reading and Printing
33 @dfn{Reading} a Lisp object means parsing a Lisp expression in textual
34 form and producing a corresponding Lisp object. This is how Lisp
35 programs get into Lisp from files of Lisp code. We call the text the
36 @dfn{read syntax} of the object. For example, the text @samp{(a .@: 5)}
37 is the read syntax for a cons cell whose @sc{car} is @code{a} and whose
38 @sc{cdr} is the number 5.
40 @dfn{Printing} a Lisp object means producing text that represents that
41 object---converting the object to its @dfn{printed representation}
42 (@pxref{Printed Representation}). Printing the cons cell described
43 above produces the text @samp{(a .@: 5)}.
45 Reading and printing are more or less inverse operations: printing the
46 object that results from reading a given piece of text often produces
47 the same text, and reading the text that results from printing an object
48 usually produces a similar-looking object. For example, printing the
49 symbol @code{foo} produces the text @samp{foo}, and reading that text
50 returns the symbol @code{foo}. Printing a list whose elements are
51 @code{a} and @code{b} produces the text @samp{(a b)}, and reading that
52 text produces a list (but not the same list) with elements @code{a}
55 However, these two operations are not precisely inverse to each other.
56 There are three kinds of exceptions:
60 Printing can produce text that cannot be read. For example, buffers,
61 windows, frames, subprocesses and markers print as text that starts
62 with @samp{#}; if you try to read this text, you get an error. There is
63 no way to read those data types.
66 One object can have multiple textual representations. For example,
67 @samp{1} and @samp{01} represent the same integer, and @samp{(a b)} and
68 @samp{(a .@: (b))} represent the same list. Reading will accept any of
69 the alternatives, but printing must choose one of them.
72 Comments can appear at certain points in the middle of an object's
73 read sequence without affecting the result of reading it.
77 @section Input Streams
78 @cindex stream (for reading)
81 Most of the Lisp functions for reading text take an @dfn{input stream}
82 as an argument. The input stream specifies where or how to get the
83 characters of the text to be read. Here are the possible types of input
88 @cindex buffer input stream
89 The input characters are read from @var{buffer}, starting with the
90 character directly after point. Point advances as characters are read.
93 @cindex marker input stream
94 The input characters are read from the buffer that @var{marker} is in,
95 starting with the character directly after the marker. The marker
96 position advances as characters are read. The value of point in the
97 buffer has no effect when the stream is a marker.
100 @cindex string input stream
101 The input characters are taken from @var{string}, starting at the first
102 character in the string and using as many characters as required.
105 @cindex function input stream
106 The input characters are generated by @var{function}, which must support
111 When it is called with no arguments, it should return the next character.
114 When it is called with one argument (always a character), @var{function}
115 should save the argument and arrange to return it on the next call.
116 This is called @dfn{unreading} the character; it happens when the Lisp
117 reader reads one character too many and wants to ``put it back where it
118 came from.'' In this case, it makes no difference what value
119 @var{function} returns.
123 @cindex @code{t} input stream
124 @code{t} used as a stream means that the input is read from the
125 minibuffer. In fact, the minibuffer is invoked once and the text
126 given by the user is made into a string that is then used as the
127 input stream. If Emacs is running in batch mode, standard input is used
128 instead of the minibuffer. For example,
130 (message "%s" (read t))
132 will read a Lisp expression from standard input and print the result
136 @cindex @code{nil} input stream
137 @code{nil} supplied as an input stream means to use the value of
138 @code{standard-input} instead; that value is the @dfn{default input
139 stream}, and must be a non-@code{nil} input stream.
142 A symbol as input stream is equivalent to the symbol's function
146 Here is an example of reading from a stream that is a buffer, showing
147 where point is located before and after:
151 ---------- Buffer: foo ----------
152 This@point{} is the contents of foo.
153 ---------- Buffer: foo ----------
157 (read (get-buffer "foo"))
161 (read (get-buffer "foo"))
166 ---------- Buffer: foo ----------
167 This is the@point{} contents of foo.
168 ---------- Buffer: foo ----------
173 Note that the first read skips a space. Reading skips any amount of
174 whitespace preceding the significant text.
176 Here is an example of reading from a stream that is a marker,
177 initially positioned at the beginning of the buffer shown. The value
178 read is the symbol @code{This}.
183 ---------- Buffer: foo ----------
184 This is the contents of foo.
185 ---------- Buffer: foo ----------
189 (setq m (set-marker (make-marker) 1 (get-buffer "foo")))
190 @result{} #<marker at 1 in foo>
198 @result{} #<marker at 5 in foo> ;; @r{Before the first space.}
202 Here we read from the contents of a string:
206 (read "(When in) the course")
211 The following example reads from the minibuffer. The
212 prompt is: @w{@samp{Lisp expression: }}. (That is always the prompt
213 used when you read from the stream @code{t}.) The user's input is shown
214 following the prompt.
220 ---------- Buffer: Minibuffer ----------
221 Lisp expression: @kbd{23 @key{RET}}
222 ---------- Buffer: Minibuffer ----------
226 Finally, here is an example of a stream that is a function, named
227 @code{useless-stream}. Before we use the stream, we initialize the
228 variable @code{useless-list} to a list of characters. Then each call to
229 the function @code{useless-stream} obtains the next character in the list
230 or unreads a character by adding it to the front of the list.
234 (setq useless-list (append "XY()" nil))
235 @result{} (88 89 40 41)
239 (defun useless-stream (&optional unread)
241 (setq useless-list (cons unread useless-list))
242 (prog1 (car useless-list)
243 (setq useless-list (cdr useless-list)))))
244 @result{} useless-stream
249 Now we read using the stream thus constructed:
253 (read 'useless-stream)
264 Note that the open and close parentheses remain in the list. The Lisp
265 reader encountered the open parenthesis, decided that it ended the
266 input, and unread it. Another attempt to read from the stream at this
267 point would read @samp{()} and return @code{nil}.
270 This function is used internally as an input stream to read from the
271 input file opened by the function @code{load}. Don't use this function
275 @node Input Functions
276 @section Input Functions
278 This section describes the Lisp functions and variables that pertain
281 In the functions below, @var{stream} stands for an input stream (see
282 the previous section). If @var{stream} is @code{nil} or omitted, it
283 defaults to the value of @code{standard-input}.
286 An @code{end-of-file} error is signaled if reading encounters an
287 unterminated list, vector, or string.
289 @defun read &optional stream
290 This function reads one textual Lisp expression from @var{stream},
291 returning it as a Lisp object. This is the basic Lisp input function.
294 @defun read-from-string string &optional start end
295 @cindex string to object
296 This function reads the first textual Lisp expression from the text in
297 @var{string}. It returns a cons cell whose @sc{car} is that expression,
298 and whose @sc{cdr} is an integer giving the position of the next
299 remaining character in the string (i.e., the first one not read).
301 If @var{start} is supplied, then reading begins at index @var{start} in
302 the string (where the first character is at index 0). If you specify
303 @var{end}, then reading is forced to stop just before that index, as if
304 the rest of the string were not there.
310 (read-from-string "(setq x 55) (setq y 5)")
311 @result{} ((setq x 55) . 11)
314 (read-from-string "\"A short string\"")
315 @result{} ("A short string" . 16)
319 ;; @r{Read starting at the first character.}
320 (read-from-string "(list 112)" 0)
321 @result{} ((list 112) . 10)
324 ;; @r{Read starting at the second character.}
325 (read-from-string "(list 112)" 1)
329 ;; @r{Read starting at the seventh character,}
330 ;; @r{and stopping at the ninth.}
331 (read-from-string "(list 112)" 6 8)
337 @defvar standard-input
338 This variable holds the default input stream---the stream that
339 @code{read} uses when the @var{stream} argument is @code{nil}.
340 The default is @code{t}, meaning use the minibuffer.
344 If non-@code{nil}, this variable enables the reading of circular and
345 shared structures. @xref{Circular Objects}. Its default value is
350 @section Output Streams
351 @cindex stream (for printing)
352 @cindex output stream
354 An output stream specifies what to do with the characters produced
355 by printing. Most print functions accept an output stream as an
356 optional argument. Here are the possible types of output stream:
360 @cindex buffer output stream
361 The output characters are inserted into @var{buffer} at point.
362 Point advances as characters are inserted.
365 @cindex marker output stream
366 The output characters are inserted into the buffer that @var{marker}
367 points into, at the marker position. The marker position advances as
368 characters are inserted. The value of point in the buffer has no effect
369 on printing when the stream is a marker, and this kind of printing
370 does not move point (except that if the marker points at or before the
371 position of point, point advances with the surrounding text, as
375 @cindex function output stream
376 The output characters are passed to @var{function}, which is responsible
377 for storing them away. It is called with a single character as
378 argument, as many times as there are characters to be output, and
379 is responsible for storing the characters wherever you want to put them.
382 @cindex @code{t} output stream
383 The output characters are displayed in the echo area.
386 @cindex @code{nil} output stream
387 @code{nil} specified as an output stream means to use the value of
388 @code{standard-output} instead; that value is the @dfn{default output
389 stream}, and must not be @code{nil}.
392 A symbol as output stream is equivalent to the symbol's function
396 Many of the valid output streams are also valid as input streams. The
397 difference between input and output streams is therefore more a matter
398 of how you use a Lisp object, than of different types of object.
400 Here is an example of a buffer used as an output stream. Point is
401 initially located as shown immediately before the @samp{h} in
402 @samp{the}. At the end, point is located directly before that same
405 @cindex print example
408 ---------- Buffer: foo ----------
409 This is t@point{}he contents of foo.
410 ---------- Buffer: foo ----------
413 (print "This is the output" (get-buffer "foo"))
414 @result{} "This is the output"
417 ---------- Buffer: foo ----------
420 @point{}he contents of foo.
421 ---------- Buffer: foo ----------
425 Now we show a use of a marker as an output stream. Initially, the
426 marker is in buffer @code{foo}, between the @samp{t} and the @samp{h} in
427 the word @samp{the}. At the end, the marker has advanced over the
428 inserted text so that it remains positioned before the same @samp{h}.
429 Note that the location of point, shown in the usual fashion, has no
434 ---------- Buffer: foo ----------
435 This is the @point{}output
436 ---------- Buffer: foo ----------
440 (setq m (copy-marker 10))
441 @result{} #<marker at 10 in foo>
445 (print "More output for foo." m)
446 @result{} "More output for foo."
450 ---------- Buffer: foo ----------
452 "More output for foo."
454 ---------- Buffer: foo ----------
459 @result{} #<marker at 34 in foo>
463 The following example shows output to the echo area:
467 (print "Echo Area output" t)
468 @result{} "Echo Area output"
469 ---------- Echo Area ----------
471 ---------- Echo Area ----------
475 Finally, we show the use of a function as an output stream. The
476 function @code{eat-output} takes each character that it is given and
477 conses it onto the front of the list @code{last-output} (@pxref{Building
478 Lists}). At the end, the list contains all the characters output, but
483 (setq last-output nil)
488 (defun eat-output (c)
489 (setq last-output (cons c last-output)))
494 (print "This is the output" 'eat-output)
495 @result{} "This is the output"
500 @result{} (10 34 116 117 112 116 117 111 32 101 104
501 116 32 115 105 32 115 105 104 84 34 10)
506 Now we can put the output in the proper order by reversing the list:
510 (concat (nreverse last-output))
512 \"This is the output\"
518 Calling @code{concat} converts the list to a string so you can see its
519 contents more clearly.
521 @node Output Functions
522 @section Output Functions
524 This section describes the Lisp functions for printing Lisp
525 objects---converting objects into their printed representation.
527 @cindex @samp{"} in printing
528 @cindex @samp{\} in printing
529 @cindex quoting characters in printing
530 @cindex escape characters in printing
531 Some of the Emacs printing functions add quoting characters to the
532 output when necessary so that it can be read properly. The quoting
533 characters used are @samp{"} and @samp{\}; they distinguish strings from
534 symbols, and prevent punctuation characters in strings and symbols from
535 being taken as delimiters when reading. @xref{Printed Representation},
536 for full details. You specify quoting or no quoting by the choice of
539 If the text is to be read back into Lisp, then you should print with
540 quoting characters to avoid ambiguity. Likewise, if the purpose is to
541 describe a Lisp object clearly for a Lisp programmer. However, if the
542 purpose of the output is to look nice for humans, then it is usually
543 better to print without quoting.
545 Lisp objects can refer to themselves. Printing a self-referential
546 object in the normal way would require an infinite amount of text, and
547 the attempt could cause infinite recursion. Emacs detects such
548 recursion and prints @samp{#@var{level}} instead of recursively printing
549 an object already being printed. For example, here @samp{#0} indicates
550 a recursive reference to the object at level 0 of the current print
554 (setq foo (list nil))
560 In the functions below, @var{stream} stands for an output stream.
561 (See the previous section for a description of output streams.) If
562 @var{stream} is @code{nil} or omitted, it defaults to the value of
563 @code{standard-output}.
565 @defun print object &optional stream
567 The @code{print} function is a convenient way of printing. It outputs
568 the printed representation of @var{object} to @var{stream}, printing in
569 addition one newline before @var{object} and another after it. Quoting
570 characters are used. @code{print} returns @var{object}. For example:
574 (progn (print 'The\ cat\ in)
576 (print " came back"))
578 @print{} The\ cat\ in
582 @print{} " came back"
583 @result{} " came back"
588 @defun prin1 object &optional stream
589 This function outputs the printed representation of @var{object} to
590 @var{stream}. It does not print newlines to separate output as
591 @code{print} does, but it does use quoting characters just like
592 @code{print}. It returns @var{object}.
596 (progn (prin1 'The\ cat\ in)
598 (prin1 " came back"))
599 @print{} The\ cat\ in"the hat"" came back"
600 @result{} " came back"
605 @defun princ object &optional stream
606 This function outputs the printed representation of @var{object} to
607 @var{stream}. It returns @var{object}.
609 This function is intended to produce output that is readable by people,
610 not by @code{read}, so it doesn't insert quoting characters and doesn't
611 put double-quotes around the contents of strings. It does not add any
612 spacing between calls.
618 (princ " in the \"hat\""))
619 @print{} The cat in the "hat"
620 @result{} " in the \"hat\""
625 @defun terpri &optional stream
626 @cindex newline in print
627 This function outputs a newline to @var{stream}. The name stands
628 for ``terminate print.''
631 @defun write-char character &optional stream
632 This function outputs @var{character} to @var{stream}. It returns
636 @defun prin1-to-string object &optional noescape
637 @cindex object to string
638 This function returns a string containing the text that @code{prin1}
639 would have printed for the same argument.
643 (prin1-to-string 'foo)
647 (prin1-to-string (mark-marker))
648 @result{} "#<marker at 2773 in strings.texi>"
652 If @var{noescape} is non-@code{nil}, that inhibits use of quoting
653 characters in the output. (This argument is supported in Emacs versions
658 (prin1-to-string "foo")
662 (prin1-to-string "foo" t)
667 See @code{format}, in @ref{Formatting Strings}, for other ways to obtain
668 the printed representation of a Lisp object as a string.
671 @defmac with-output-to-string body@dots{}
672 This macro executes the @var{body} forms with @code{standard-output} set
673 up to feed output into a string. Then it returns that string.
675 For example, if the current buffer name is @samp{foo},
678 (with-output-to-string
679 (princ "The buffer is ")
680 (princ (buffer-name)))
684 returns @code{"The buffer is foo"}.
687 @node Output Variables
688 @section Variables Affecting Output
689 @cindex output-controlling variables
691 @defvar standard-output
692 The value of this variable is the default output stream---the stream
693 that print functions use when the @var{stream} argument is @code{nil}.
694 The default is @code{t}, meaning display in the echo area.
698 If this is non-@code{nil}, that means to print quoted forms using
699 abbreviated reader syntax. @code{(quote foo)} prints as @code{'foo},
700 @code{(function foo)} as @code{#'foo}, and backquoted forms print
701 using modern backquote syntax.
704 @defvar print-escape-newlines
705 @cindex @samp{\n} in print
706 @cindex escape characters
707 If this variable is non-@code{nil}, then newline characters in strings
708 are printed as @samp{\n} and formfeeds are printed as @samp{\f}.
709 Normally these characters are printed as actual newlines and formfeeds.
711 This variable affects the print functions @code{prin1} and @code{print}
712 that print with quoting. It does not affect @code{princ}. Here is an
713 example using @code{prin1}:
725 (let ((print-escape-newlines t))
734 In the second expression, the local binding of
735 @code{print-escape-newlines} is in effect during the call to
736 @code{prin1}, but not during the printing of the result.
739 @defvar print-escape-nonascii
740 If this variable is non-@code{nil}, then unibyte non-@acronym{ASCII}
741 characters in strings are unconditionally printed as backslash sequences
742 by the print functions @code{prin1} and @code{print} that print with
745 Those functions also use backslash sequences for unibyte non-@acronym{ASCII}
746 characters, regardless of the value of this variable, when the output
747 stream is a multibyte buffer or a marker pointing into one.
750 @defvar print-escape-multibyte
751 If this variable is non-@code{nil}, then multibyte non-@acronym{ASCII}
752 characters in strings are unconditionally printed as backslash sequences
753 by the print functions @code{prin1} and @code{print} that print with
756 Those functions also use backslash sequences for multibyte
757 non-@acronym{ASCII} characters, regardless of the value of this variable,
758 when the output stream is a unibyte buffer or a marker pointing into
763 @cindex printing limits
764 The value of this variable is the maximum number of elements to print in
765 any list, vector or bool-vector. If an object being printed has more
766 than this many elements, it is abbreviated with an ellipsis.
768 If the value is @code{nil} (the default), then there is no limit.
772 (setq print-length 2)
784 The value of this variable is the maximum depth of nesting of
785 parentheses and brackets when printed. Any list or vector at a depth
786 exceeding this limit is abbreviated with an ellipsis. A value of
787 @code{nil} (which is the default) means no limit.
790 @defopt eval-expression-print-length
791 @defoptx eval-expression-print-level
792 These are the values for @code{print-length} and @code{print-level}
793 used by @code{eval-expression}, and thus, indirectly, by many
794 interactive evaluation commands (@pxref{Lisp Eval,, Evaluating
795 Emacs-Lisp Expressions, emacs, The GNU Emacs Manual}).
798 These variables are used for detecting and reporting circular
799 and shared structure:
802 If non-@code{nil}, this variable enables detection of circular and
803 shared structure in printing. @xref{Circular Objects}.
807 If non-@code{nil}, this variable enables detection of uninterned symbols
808 (@pxref{Creating Symbols}) in printing. When this is enabled,
809 uninterned symbols print with the prefix @samp{#:}, which tells the Lisp
810 reader to produce an uninterned symbol.
813 @defvar print-continuous-numbering
814 If non-@code{nil}, that means number continuously across print calls.
815 This affects the numbers printed for @samp{#@var{n}=} labels and
816 @samp{#@var{m}#} references.
818 Don't set this variable with @code{setq}; you should only bind it
819 temporarily to @code{t} with @code{let}. When you do that, you should
820 also bind @code{print-number-table} to @code{nil}.
823 @defvar print-number-table
824 This variable holds a vector used internally by printing to implement
825 the @code{print-circle} feature. You should not use it except
826 to bind it to @code{nil} when you bind @code{print-continuous-numbering}.
829 @defvar float-output-format
830 This variable specifies how to print floating point numbers. Its
831 default value is @code{nil}, meaning use the shortest output
832 that represents the number without losing information.
834 To control output format more precisely, you can put a string in this
835 variable. The string should hold a @samp{%}-specification to be used
836 in the C function @code{sprintf}. For further restrictions on what
837 you can use, see the variable's documentation string.