@c -*-texinfo-*- @c This is part of the GNU Emacs Lisp Reference Manual. @c Copyright (C) 1990-1995, 1998, 2001-2011 Free Software Foundation, Inc. @c See the file elisp.texi for copying conditions. @setfilename ../../info/macros @node Macros, Customization, Functions, Top @chapter Macros @cindex macros @dfn{Macros} enable you to define new control constructs and other language features. A macro is defined much like a function, but instead of telling how to compute a value, it tells how to compute another Lisp expression which will in turn compute the value. We call this expression the @dfn{expansion} of the macro. Macros can do this because they operate on the unevaluated expressions for the arguments, not on the argument values as functions do. They can therefore construct an expansion containing these argument expressions or parts of them. If you are using a macro to do something an ordinary function could do, just for the sake of speed, consider using an inline function instead. @xref{Inline Functions}. @menu * Simple Macro:: A basic example. * Expansion:: How, when and why macros are expanded. * Compiling Macros:: How macros are expanded by the compiler. * Defining Macros:: How to write a macro definition. * Backquote:: Easier construction of list structure. * Problems with Macros:: Don't evaluate the macro arguments too many times. Don't hide the user's variables. * Indenting Macros:: Specifying how to indent macro calls. @end menu @node Simple Macro @section A Simple Example of a Macro Suppose we would like to define a Lisp construct to increment a variable value, much like the @code{++} operator in C. We would like to write @code{(inc x)} and have the effect of @code{(setq x (1+ x))}. Here's a macro definition that does the job: @findex inc @example @group (defmacro inc (var) (list 'setq var (list '1+ var))) @end group @end example When this is called with @code{(inc x)}, the argument @var{var} is the symbol @code{x}---@emph{not} the @emph{value} of @code{x}, as it would be in a function. The body of the macro uses this to construct the expansion, which is @code{(setq x (1+ x))}. Once the macro definition returns this expansion, Lisp proceeds to evaluate it, thus incrementing @code{x}. @node Expansion @section Expansion of a Macro Call @cindex expansion of macros @cindex macro call A macro call looks just like a function call in that it is a list which starts with the name of the macro. The rest of the elements of the list are the arguments of the macro. Evaluation of the macro call begins like evaluation of a function call except for one crucial difference: the macro arguments are the actual expressions appearing in the macro call. They are not evaluated before they are given to the macro definition. By contrast, the arguments of a function are results of evaluating the elements of the function call list. Having obtained the arguments, Lisp invokes the macro definition just as a function is invoked. The argument variables of the macro are bound to the argument values from the macro call, or to a list of them in the case of a @code{&rest} argument. And the macro body executes and returns its value just as a function body does. The second crucial difference between macros and functions is that the value returned by the macro body is not the value of the macro call. Instead, it is an alternate expression for computing that value, also known as the @dfn{expansion} of the macro. The Lisp interpreter proceeds to evaluate the expansion as soon as it comes back from the macro. Since the expansion is evaluated in the normal manner, it may contain calls to other macros. It may even be a call to the same macro, though this is unusual. You can see the expansion of a given macro call by calling @code{macroexpand}. @defun macroexpand form &optional environment @cindex macro expansion This function expands @var{form}, if it is a macro call. If the result is another macro call, it is expanded in turn, until something which is not a macro call results. That is the value returned by @code{macroexpand}. If @var{form} is not a macro call to begin with, it is returned as given. Note that @code{macroexpand} does not look at the subexpressions of @var{form} (although some macro definitions may do so). Even if they are macro calls themselves, @code{macroexpand} does not expand them. The function @code{macroexpand} does not expand calls to inline functions. Normally there is no need for that, since a call to an inline function is no harder to understand than a call to an ordinary function. If @var{environment} is provided, it specifies an alist of macro definitions that shadow the currently defined macros. Byte compilation uses this feature. @smallexample @group (defmacro inc (var) (list 'setq var (list '1+ var))) @result{} inc @end group @group (macroexpand '(inc r)) @result{} (setq r (1+ r)) @end group @group (defmacro inc2 (var1 var2) (list 'progn (list 'inc var1) (list 'inc var2))) @result{} inc2 @end group @group (macroexpand '(inc2 r s)) @result{} (progn (inc r) (inc s)) ; @r{@code{inc} not expanded here.} @end group @end smallexample @end defun @defun macroexpand-all form &optional environment @code{macroexpand-all} expands macros like @code{macroexpand}, but will look for and expand all macros in @var{form}, not just at the top-level. If no macros are expanded, the return value is @code{eq} to @var{form}. Repeating the example used for @code{macroexpand} above with @code{macroexpand-all}, we see that @code{macroexpand-all} @emph{does} expand the embedded calls to @code{inc}: @smallexample (macroexpand-all '(inc2 r s)) @result{} (progn (setq r (1+ r)) (setq s (1+ s))) @end smallexample @end defun @node Compiling Macros @section Macros and Byte Compilation @cindex byte-compiling macros You might ask why we take the trouble to compute an expansion for a macro and then evaluate the expansion. Why not have the macro body produce the desired results directly? The reason has to do with compilation. When a macro call appears in a Lisp program being compiled, the Lisp compiler calls the macro definition just as the interpreter would, and receives an expansion. But instead of evaluating this expansion, it compiles the expansion as if it had appeared directly in the program. As a result, the compiled code produces the value and side effects intended for the macro, but executes at full compiled speed. This would not work if the macro body computed the value and side effects itself---they would be computed at compile time, which is not useful. In order for compilation of macro calls to work, the macros must already be defined in Lisp when the calls to them are compiled. The compiler has a special feature to help you do this: if a file being compiled contains a @code{defmacro} form, the macro is defined temporarily for the rest of the compilation of that file. Byte-compiling a file also executes any @code{require} calls at top-level in the file, so you can ensure that necessary macro definitions are available during compilation by requiring the files that define them (@pxref{Named Features}). To avoid loading the macro definition files when someone @emph{runs} the compiled program, write @code{eval-when-compile} around the @code{require} calls (@pxref{Eval During Compile}). @node Defining Macros @section Defining Macros A Lisp macro is a list whose @sc{car} is @code{macro}. Its @sc{cdr} should be a function; expansion of the macro works by applying the function (with @code{apply}) to the list of unevaluated argument-expressions from the macro call. It is possible to use an anonymous Lisp macro just like an anonymous function, but this is never done, because it does not make sense to pass an anonymous macro to functionals such as @code{mapcar}. In practice, all Lisp macros have names, and they are usually defined with the special form @code{defmacro}. @defspec defmacro name argument-list body-forms@dots{} @code{defmacro} defines the symbol @var{name} as a macro that looks like this: @example (macro lambda @var{argument-list} . @var{body-forms}) @end example (Note that the @sc{cdr} of this list is a function---a lambda expression.) This macro object is stored in the function cell of @var{name}. The value returned by evaluating the @code{defmacro} form is @var{name}, but usually we ignore this value. The shape and meaning of @var{argument-list} is the same as in a function, and the keywords @code{&rest} and @code{&optional} may be used (@pxref{Argument List}). Macros may have a documentation string, but any @code{interactive} declaration is ignored since macros cannot be called interactively. @end defspec The body of the macro definition can include a @code{declare} form, which can specify how @key{TAB} should indent macro calls, and how to step through them for Edebug. @defmac declare @var{specs}@dots{} @anchor{Definition of declare} A @code{declare} form is used in a macro definition to specify various additional information about it. Two kinds of specification are currently supported: @table @code @item (debug @var{edebug-form-spec}) Specify how to step through macro calls for Edebug. @xref{Instrumenting Macro Calls}. @item (indent @var{indent-spec}) Specify how to indent calls to this macro. @xref{Indenting Macros}, for more details. @end table A @code{declare} form only has its special effect in the body of a @code{defmacro} form if it immediately follows the documentation string, if present, or the argument list otherwise. (Strictly speaking, @emph{several} @code{declare} forms can follow the documentation string or argument list, but since a @code{declare} form can have several @var{specs}, they can always be combined into a single form.) When used at other places in a @code{defmacro} form, or outside a @code{defmacro} form, @code{declare} just returns @code{nil} without evaluating any @var{specs}. @end defmac No macro absolutely needs a @code{declare} form, because that form has no effect on how the macro expands, on what the macro means in the program. It only affects secondary features: indentation and Edebug. @node Backquote @section Backquote @cindex backquote (list substitution) @cindex ` (list substitution) @findex ` Macros often need to construct large list structures from a mixture of constants and nonconstant parts. To make this easier, use the @samp{`} syntax (usually called @dfn{backquote}). Backquote allows you to quote a list, but selectively evaluate elements of that list. In the simplest case, it is identical to the special form @code{quote} (@pxref{Quoting}). For example, these two forms yield identical results: @example @group `(a list of (+ 2 3) elements) @result{} (a list of (+ 2 3) elements) @end group @group '(a list of (+ 2 3) elements) @result{} (a list of (+ 2 3) elements) @end group @end example @findex , @r{(with backquote)} The special marker @samp{,} inside of the argument to backquote indicates a value that isn't constant. Backquote evaluates the argument of @samp{,} and puts the value in the list structure: @example @group (list 'a 'list 'of (+ 2 3) 'elements) @result{} (a list of 5 elements) @end group @group `(a list of ,(+ 2 3) elements) @result{} (a list of 5 elements) @end group @end example Substitution with @samp{,} is allowed at deeper levels of the list structure also. For example: @example @group (defmacro t-becomes-nil (variable) `(if (eq ,variable t) (setq ,variable nil))) @end group @group (t-becomes-nil foo) @equiv{} (if (eq foo t) (setq foo nil)) @end group @end example @findex ,@@ @r{(with backquote)} @cindex splicing (with backquote) You can also @dfn{splice} an evaluated value into the resulting list, using the special marker @samp{,@@}. The elements of the spliced list become elements at the same level as the other elements of the resulting list. The equivalent code without using @samp{`} is often unreadable. Here are some examples: @example @group (setq some-list '(2 3)) @result{} (2 3) @end group @group (cons 1 (append some-list '(4) some-list)) @result{} (1 2 3 4 2 3) @end group @group `(1 ,@@some-list 4 ,@@some-list) @result{} (1 2 3 4 2 3) @end group @group (setq list '(hack foo bar)) @result{} (hack foo bar) @end group @group (cons 'use (cons 'the (cons 'words (append (cdr list) '(as elements))))) @result{} (use the words foo bar as elements) @end group @group `(use the words ,@@(cdr list) as elements) @result{} (use the words foo bar as elements) @end group @end example @node Problems with Macros @section Common Problems Using Macros The basic facts of macro expansion have counterintuitive consequences. This section describes some important consequences that can lead to trouble, and rules to follow to avoid trouble. @menu * Wrong Time:: Do the work in the expansion, not in the macro. * Argument Evaluation:: The expansion should evaluate each macro arg once. * Surprising Local Vars:: Local variable bindings in the expansion require special care. * Eval During Expansion:: Don't evaluate them; put them in the expansion. * Repeated Expansion:: Avoid depending on how many times expansion is done. @end menu @node Wrong Time @subsection Wrong Time The most common problem in writing macros is doing some of the real work prematurely---while expanding the macro, rather than in the expansion itself. For instance, one real package had this macro definition: @example (defmacro my-set-buffer-multibyte (arg) (if (fboundp 'set-buffer-multibyte) (set-buffer-multibyte arg))) @end example With this erroneous macro definition, the program worked fine when interpreted but failed when compiled. This macro definition called @code{set-buffer-multibyte} during compilation, which was wrong, and then did nothing when the compiled package was run. The definition that the programmer really wanted was this: @example (defmacro my-set-buffer-multibyte (arg) (if (fboundp 'set-buffer-multibyte) `(set-buffer-multibyte ,arg))) @end example @noindent This macro expands, if appropriate, into a call to @code{set-buffer-multibyte} that will be executed when the compiled program is actually run. @node Argument Evaluation @subsection Evaluating Macro Arguments Repeatedly When defining a macro you must pay attention to the number of times the arguments will be evaluated when the expansion is executed. The following macro (used to facilitate iteration) illustrates the problem. This macro allows us to write a simple ``for'' loop such as one might find in Pascal. @findex for @smallexample @group (defmacro for (var from init to final do &rest body) "Execute a simple \"for\" loop. For example, (for i from 1 to 10 do (print i))." (list 'let (list (list var init)) (cons 'while (cons (list '<= var final) (append body (list (list 'inc var))))))) @end group @result{} for @group (for i from 1 to 3 do (setq square (* i i)) (princ (format "\n%d %d" i square))) @expansion{} @end group @group (let ((i 1)) (while (<= i 3) (setq square (* i i)) (princ (format "\n%d %d" i square)) (inc i))) @end group @group @print{}1 1 @print{}2 4 @print{}3 9 @result{} nil @end group @end smallexample @noindent The arguments @code{from}, @code{to}, and @code{do} in this macro are ``syntactic sugar''; they are entirely ignored. The idea is that you will write noise words (such as @code{from}, @code{to}, and @code{do}) in those positions in the macro call. Here's an equivalent definition simplified through use of backquote: @smallexample @group (defmacro for (var from init to final do &rest body) "Execute a simple \"for\" loop. For example, (for i from 1 to 10 do (print i))." `(let ((,var ,init)) (while (<= ,var ,final) ,@@body (inc ,var)))) @end group @end smallexample Both forms of this definition (with backquote and without) suffer from the defect that @var{final} is evaluated on every iteration. If @var{final} is a constant, this is not a problem. If it is a more complex form, say @code{(long-complex-calculation x)}, this can slow down the execution significantly. If @var{final} has side effects, executing it more than once is probably incorrect. @cindex macro argument evaluation A well-designed macro definition takes steps to avoid this problem by producing an expansion that evaluates the argument expressions exactly once unless repeated evaluation is part of the intended purpose of the macro. Here is a correct expansion for the @code{for} macro: @smallexample @group (let ((i 1) (max 3)) (while (<= i max) (setq square (* i i)) (princ (format "%d %d" i square)) (inc i))) @end group @end smallexample Here is a macro definition that creates this expansion: @smallexample @group (defmacro for (var from init to final do &rest body) "Execute a simple for loop: (for i from 1 to 10 do (print i))." `(let ((,var ,init) (max ,final)) (while (<= ,var max) ,@@body (inc ,var)))) @end group @end smallexample Unfortunately, this fix introduces another problem, described in the following section. @node Surprising Local Vars @subsection Local Variables in Macro Expansions @ifnottex In the previous section, the definition of @code{for} was fixed as follows to make the expansion evaluate the macro arguments the proper number of times: @smallexample @group (defmacro for (var from init to final do &rest body) "Execute a simple for loop: (for i from 1 to 10 do (print i))." @end group @group `(let ((,var ,init) (max ,final)) (while (<= ,var max) ,@@body (inc ,var)))) @end group @end smallexample @end ifnottex The new definition of @code{for} has a new problem: it introduces a local variable named @code{max} which the user does not expect. This causes trouble in examples such as the following: @smallexample @group (let ((max 0)) (for x from 0 to 10 do (let ((this (frob x))) (if (< max this) (setq max this))))) @end group @end smallexample @noindent The references to @code{max} inside the body of the @code{for}, which are supposed to refer to the user's binding of @code{max}, really access the binding made by @code{for}. The way to correct this is to use an uninterned symbol instead of @code{max} (@pxref{Creating Symbols}). The uninterned symbol can be bound and referred to just like any other symbol, but since it is created by @code{for}, we know that it cannot already appear in the user's program. Since it is not interned, there is no way the user can put it into the program later. It will never appear anywhere except where put by @code{for}. Here is a definition of @code{for} that works this way: @smallexample @group (defmacro for (var from init to final do &rest body) "Execute a simple for loop: (for i from 1 to 10 do (print i))." (let ((tempvar (make-symbol "max"))) `(let ((,var ,init) (,tempvar ,final)) (while (<= ,var ,tempvar) ,@@body (inc ,var))))) @end group @end smallexample @noindent This creates an uninterned symbol named @code{max} and puts it in the expansion instead of the usual interned symbol @code{max} that appears in expressions ordinarily. @node Eval During Expansion @subsection Evaluating Macro Arguments in Expansion Another problem can happen if the macro definition itself evaluates any of the macro argument expressions, such as by calling @code{eval} (@pxref{Eval}). If the argument is supposed to refer to the user's variables, you may have trouble if the user happens to use a variable with the same name as one of the macro arguments. Inside the macro body, the macro argument binding is the most local binding of this variable, so any references inside the form being evaluated do refer to it. Here is an example: @example @group (defmacro foo (a) (list 'setq (eval a) t)) @result{} foo @end group @group (setq x 'b) (foo x) @expansion{} (setq b t) @result{} t ; @r{and @code{b} has been set.} ;; @r{but} (setq a 'c) (foo a) @expansion{} (setq a t) @result{} t ; @r{but this set @code{a}, not @code{c}.} @end group @end example It makes a difference whether the user's variable is named @code{a} or @code{x}, because @code{a} conflicts with the macro argument variable @code{a}. Another problem with calling @code{eval} in a macro definition is that it probably won't do what you intend in a compiled program. The byte compiler runs macro definitions while compiling the program, when the program's own computations (which you might have wished to access with @code{eval}) don't occur and its local variable bindings don't exist. To avoid these problems, @strong{don't evaluate an argument expression while computing the macro expansion}. Instead, substitute the expression into the macro expansion, so that its value will be computed as part of executing the expansion. This is how the other examples in this chapter work. @node Repeated Expansion @subsection How Many Times is the Macro Expanded? Occasionally problems result from the fact that a macro call is expanded each time it is evaluated in an interpreted function, but is expanded only once (during compilation) for a compiled function. If the macro definition has side effects, they will work differently depending on how many times the macro is expanded. Therefore, you should avoid side effects in computation of the macro expansion, unless you really know what you are doing. One special kind of side effect can't be avoided: constructing Lisp objects. Almost all macro expansions include constructed lists; that is the whole point of most macros. This is usually safe; there is just one case where you must be careful: when the object you construct is part of a quoted constant in the macro expansion. If the macro is expanded just once, in compilation, then the object is constructed just once, during compilation. But in interpreted execution, the macro is expanded each time the macro call runs, and this means a new object is constructed each time. In most clean Lisp code, this difference won't matter. It can matter only if you perform side-effects on the objects constructed by the macro definition. Thus, to avoid trouble, @strong{avoid side effects on objects constructed by macro definitions}. Here is an example of how such side effects can get you into trouble: @lisp @group (defmacro empty-object () (list 'quote (cons nil nil))) @end group @group (defun initialize (condition) (let ((object (empty-object))) (if condition (setcar object condition)) object)) @end group @end lisp @noindent If @code{initialize} is interpreted, a new list @code{(nil)} is constructed each time @code{initialize} is called. Thus, no side effect survives between calls. If @code{initialize} is compiled, then the macro @code{empty-object} is expanded during compilation, producing a single ``constant'' @code{(nil)} that is reused and altered each time @code{initialize} is called. One way to avoid pathological cases like this is to think of @code{empty-object} as a funny kind of constant, not as a memory allocation construct. You wouldn't use @code{setcar} on a constant such as @code{'(nil)}, so naturally you won't use it on @code{(empty-object)} either. @node Indenting Macros @section Indenting Macros You can use the @code{declare} form in the macro definition to specify how to @key{TAB} should indent calls to the macro. You write it like this: @example (declare (indent @var{indent-spec})) @end example @noindent Here are the possibilities for @var{indent-spec}: @table @asis @item @code{nil} This is the same as no property---use the standard indentation pattern. @item @code{defun} Handle this function like a @samp{def} construct: treat the second line as the start of a @dfn{body}. @item an integer, @var{number} The first @var{number} arguments of the function are @dfn{distinguished} arguments; the rest are considered the body of the expression. A line in the expression is indented according to whether the first argument on it is distinguished or not. If the argument is part of the body, the line is indented @code{lisp-body-indent} more columns than the open-parenthesis starting the containing expression. If the argument is distinguished and is either the first or second argument, it is indented @emph{twice} that many extra columns. If the argument is distinguished and not the first or second argument, the line uses the standard pattern. @item a symbol, @var{symbol} @var{symbol} should be a function name; that function is called to calculate the indentation of a line within this expression. The function receives two arguments: @table @asis @item @var{state} The value returned by @code{parse-partial-sexp} (a Lisp primitive for indentation and nesting computation) when it parses up to the beginning of this line. @item @var{pos} The position at which the line being indented begins. @end table @noindent It should return either a number, which is the number of columns of indentation for that line, or a list whose car is such a number. The difference between returning a number and returning a list is that a number says that all following lines at the same nesting level should be indented just like this one; a list says that following lines might call for different indentations. This makes a difference when the indentation is being computed by @kbd{C-M-q}; if the value is a number, @kbd{C-M-q} need not recalculate indentation for the following lines until the end of the list. @end table