Printing and reading are the operations of converting Lisp objects to textual form and vice versa. They use the printed representations and read syntax described in section Lisp Data Types.
This chapter describes the Lisp functions for reading and printing. It also describes streams, which specify where to get the text (if reading) or where to put it (if printing).
Reading a Lisp object means parsing a Lisp expression in textual
form and producing a corresponding Lisp object. This is how Lisp
programs get into Lisp from files of Lisp code. We call the text the
read syntax of the object. For example, the text `(a . 5)'
is the read syntax for a cons cell whose CAR is a
and whose
CDR is the number 5.
Printing a Lisp object means producing text that represents that object--converting the object to its printed representation. Printing the cons cell described above produces the text `(a . 5)'.
Reading and printing are more or less inverse operations: printing the
object that results from reading a given piece of text often produces
the same text, and reading the text that results from printing an object
usually produces a similar-looking object. For example, printing the
symbol foo
produces the text `foo', and reading that text
returns the symbol foo
. Printing a list whose elements are
a
and b
produces the text `(a b)', and reading that
text produces a list (but not the same list) with elements a
and b
.
However, these two operations are not precisely inverses. There are two kinds of exceptions:
Most of the Lisp functions for reading text take an input stream as an argument. The input stream specifies where or how to get the characters of the text to be read. Here are the possible types of input stream:
t
t
used as a stream means that the input is read from the
minibuffer. In fact, the minibuffer is invoked once and the text
given by the user is made into a string that is then used as the
input stream.
nil
nil
supplied as an input stream means to use the value of
standard-input
instead; that value is the default input
stream, and must be a non-nil
input stream.
Here is an example of reading from a stream that is a buffer, showing where point is located before and after:
---------- Buffer: foo ---------- This-!- is the contents of foo. ---------- Buffer: foo ---------- (read (get-buffer "foo")) => is (read (get-buffer "foo")) => the ---------- Buffer: foo ---------- This is the-!- contents of foo. ---------- Buffer: foo ----------
Note that the first read skips a space. Reading skips any amount of whitespace preceding the significant text.
In Emacs 18, reading a symbol discarded the delimiter terminating the symbol. Thus, point would end up at the beginning of `contents' rather than after `the'. The Emacs 19 behavior is superior because it correctly handles input such as `bar(foo)', where the delimiter that ends one object is needed as the beginning of another object.
Here is an example of reading from a stream that is a marker,
initially positioned at the beginning of the buffer shown. The value
read is the symbol This
.
---------- Buffer: foo ---------- This is the contents of foo. ---------- Buffer: foo ---------- (setq m (set-marker (make-marker) 1 (get-buffer "foo"))) => #<marker at 1 in foo> (read m) => This m => #<marker at 5 in foo> ;; Before the first space.
Here we read from the contents of a string:
(read "(When in) the course") => (When in)
The following example reads from the minibuffer. The
prompt is: `Lisp expression: '. (That is always the prompt
used when you read from the stream t
.) The user's input is shown
following the prompt.
(read t) => 23 ---------- Buffer: Minibuffer ---------- Lisp expression: 23 RET ---------- Buffer: Minibuffer ----------
Finally, here is an example of a stream that is a function, named
useless-stream
. Before we use the stream, we initialize the
variable useless-list
to a list of characters. Then each call to
the function useless-stream
obtains the next character in the list
or unreads a character by adding it to the front of the list.
(setq useless-list (append "XY()" nil)) => (88 89 40 41) (defun useless-stream (&optional unread) (if unread (setq useless-list (cons unread useless-list)) (prog1 (car useless-list) (setq useless-list (cdr useless-list))))) => useless-stream
Now we read using the stream thus constructed:
(read 'useless-stream) => XY useless-list => (40 41)
Note that the open and close parentheses remains in the list. The Lisp
reader encountered the open parenthesis, decided that it ended the
input, and unread it. Another attempt to read from the stream at this
point would read `()' and return nil
.
load
. Don't use this function
yourself.
This section describes the Lisp functions and variables that pertain to reading.
In the functions below, stream stands for an input stream (see
the previous section). If stream is nil
or omitted, it
defaults to the value of standard-input
.
An end-of-file
error is signaled if reading encounters an
unterminated list, vector, or string.
If start is supplied, then reading begins at index start in the string (where the first character is at index 0). If end is also supplied, then reading stops just before that index, as if the rest of the string were not there.
For example:
(read-from-string "(setq x 55) (setq y 5)") => ((setq x 55) . 11) (read-from-string "\"A short string\"") => ("A short string" . 16) ;; Read starting at the first character. (read-from-string "(list 112)" 0) => ((list 112) . 10) ;; Read starting at the second character. (read-from-string "(list 112)" 1) => (list . 5) ;; Read starting at the seventh character, ;; and stopping at the ninth. (read-from-string "(list 112)" 6 8) => (11 . 8)
read
uses when the stream argument is nil
.
An output stream specifies what to do with the characters produced by printing. Most print functions accept an output stream as an optional argument. Here are the possible types of output stream:
t
nil
nil
specified as an output stream means to the value of
standard-output
instead; that value is the default output
stream, and must be a non-nil
output stream.
Many of the valid output streams are also valid as input streams. The difference between input and output streams is therefore mostly one of how you use a Lisp object, not a distinction of types of object.
Here is an example of a buffer used as an output stream. Point is initially located as shown immediately before the `h' in `the'. At the end, point is located directly before that same `h'.
---------- Buffer: foo ---------- This is t-!-he contents of foo. ---------- Buffer: foo ---------- (print "This is the output" (get-buffer "foo")) => "This is the output" ---------- Buffer: foo ---------- This is t "This is the output" -!-he contents of foo. ---------- Buffer: foo ----------
Now we show a use of a marker as an output stream. Initially, the
marker is in buffer foo
, between the `t' and the `h' in
the word `the'. At the end, the marker has advanced over the
inserted text so that it remains positioned before the same `h'.
Note that the location of point, shown in the usual fashion, has no
effect.
---------- Buffer: foo ---------- "This is the -!-output" ---------- Buffer: foo ---------- m => #<marker at 11 in foo> (print "More output for foo." m) => "More output for foo." ---------- Buffer: foo ---------- "This is t "More output for foo." he -!-output" ---------- Buffer: foo ---------- m => #<marker at 35 in foo>
The following example shows output to the echo area:
(print "Echo Area output" t) => "Echo Area output" ---------- Echo Area ---------- "Echo Area output" ---------- Echo Area ----------
Finally, we show the use of a function as an output stream. The
function eat-output
takes each character that it is given and
conses it onto the front of the list last-output
(see section Building Cons Cells and Lists). At the end, the list contains all the characters output, but
in reverse order.
(setq last-output nil) => nil (defun eat-output (c) (setq last-output (cons c last-output))) => eat-output (print "This is the output" 'eat-output) => "This is the output" last-output => (10 34 116 117 112 116 117 111 32 101 104 116 32 115 105 32 115 105 104 84 34 10)
Now we can put the output in the proper order by reversing the list:
(concat (nreverse last-output)) => " \"This is the output\" "
Calling concat
converts the list to a string so you can see its
contents more clearly.
This section describes the Lisp functions for printing Lisp objects.
Some of the Emacs printing functions add quoting characters to the output when necessary so that it can be read properly. The quoting characters used are `"' and `\'; they distinguish strings from symbols, and prevent punctuation characters in strings and symbols from being taken as delimiters when reading. See section Printed Representation and Read Syntax, for full details. You specify quoting or no quoting by the choice of printing function.
If the text is to be read back into Lisp, then it is best to print with quoting characters to avoid ambiguity. Likewise, if the purpose is to describe a Lisp object clearly for a Lisp programmer. However, if the purpose of the output is to look nice for humans, then it is better to print without quoting.
Printing a self-referent Lisp object requires an infinite amount of text. In certain cases, trying to produce this text leads to a stack overflow. Emacs detects such recursion and prints `#level' instead of recursively printing an object already being printed. For example, here `#0' indicates a recursive reference to the object at level 0 of the current print operation:
(setq foo (list nil)) => (nil) (setcar foo foo) => (#0)
In the functions below, stream stands for an output stream.
(See the previous section for a description of output streams.) If
stream is nil
or omitted, it defaults to the value of
standard-output
.
print
function is a convenient way of printing. It outputs
the printed representation of object to stream, printing in
addition one newline before object and another after it. Quoting
characters are used. print
returns object. For example:
(progn (print 'The\ cat\ in) (print "the hat") (print " came back")) -| -| The\ cat\ in -| -| "the hat" -| -| " came back" -| => " came back"
print
does, but it does use quoting characters just like
print
. It returns object.
(progn (prin1 'The\ cat\ in) (prin1 "the hat") (prin1 " came back")) -| The\ cat\ in"the hat"" came back" => " came back"
This function is intended to produce output that is readable by people,
not by read
, so it doesn't insert quoting characters and doesn't
put double-quotes around the contents of strings. It does not add any
spacing between calls.
(progn (princ 'The\ cat) (princ " in the \"hat\"")) -| The cat in the "hat" => " in the \"hat\""
prin1
would have printed for the same argument.
(prin1-to-string 'foo) => "foo" (prin1-to-string (mark-marker)) => "#<marker at 2773 in strings.texi>"
If noescape is non-nil
, that inhibits use of quoting
characters in the output. (This argument is supported in Emacs versions
19 and later.)
(prin1-to-string "foo") => "\"foo\"" (prin1-to-string "foo" t) => "foo"
See format
, in section Conversion of Characters and Strings, for other ways to obtain
the printed representation of a Lisp object as a string.
nil
.
nil
, then newline characters in strings
are printed as `\n' and formfeeds are printed as `\f'.
Normally these characters are printed as actual newlines and formfeeds.
This variable affects the print functions prin1
and print
,
as well as everything that uses them. It does not affect princ
.
Here is an example using prin1
:
(prin1 "a\nb") -| "a -| b" => "a b" (let ((print-escape-newlines t)) (prin1 "a\nb")) -| "a\nb" => "a b"
In the second expression, the local binding of
print-escape-newlines
is in effect during the call to
prin1
, but not during the printing of the result.
If the value is nil
(the default), then there is no limit.
(setq print-length 2) => 2 (print '(1 2 3 4 5)) -| (1 2 ...) => (1 2 ...)
nil
(which is the default) means no limit.
This variable exists in version 19 and later versions.