@c -*-texinfo-*- @c This is part of the GNU Emacs Lisp Reference Manual. @c Copyright (C) 1998, 1999, 2001, 2002, 2003, 2004, @c 2005, 2006, 2007 Free Software Foundation, Inc. @c See the file elisp.texi for copying conditions. @setfilename ../info/advising @node Advising Functions, Debugging, Byte Compilation, Top @chapter Advising Emacs Lisp Functions @cindex advising functions The @dfn{advice} feature lets you add to the existing definition of a function, by @dfn{advising the function}. This is a cleaner method for a library to customize functions defined within Emacs---cleaner than redefining the whole function. @cindex piece of advice Each function can have multiple @dfn{pieces of advice}, separately defined. Each defined piece of advice can be @dfn{enabled} or @dfn{disabled} explicitly. All the enabled pieces of advice for any given function actually take effect when you @dfn{activate} advice for that function, or when you define or redefine the function. Note that enabling a piece of advice and activating advice for a function are not the same thing. @strong{Usage Note:} Advice is useful for altering the behavior of existing calls to an existing function. If you want the new behavior for new calls, or for key bindings, you should define a new function (or a new command) which uses the existing function. @strong{Usage note:} Advising a function can cause confusion in debugging, since people who debug calls to the original function may not notice that it has been modified with advice. Therefore, if you have the possibility to change the code of that function (or ask someone to do so) to run a hook, please solve the problem that way. Advice should be reserved for the cases where you cannot get the function changed. In particular, this means that a file in Emacs should not put advice on a function in Emacs. There are currently a few exceptions to this convention, but we aim to correct them. @menu * Simple Advice:: A simple example to explain the basics of advice. * Defining Advice:: Detailed description of @code{defadvice}. * Around-Advice:: Wrapping advice around a function's definition. * Computed Advice:: ...is to @code{defadvice} as @code{fset} is to @code{defun}. * Activation of Advice:: Advice doesn't do anything until you activate it. * Enabling Advice:: You can enable or disable each piece of advice. * Preactivation:: Preactivation is a way of speeding up the loading of compiled advice. * Argument Access in Advice:: How advice can access the function's arguments. * Advising Primitives:: Accessing arguments when advising a primitive. * Combined Definition:: How advice is implemented. @end menu @node Simple Advice @section A Simple Advice Example The command @code{next-line} moves point down vertically one or more lines; it is the standard binding of @kbd{C-n}. When used on the last line of the buffer, this command inserts a newline to create a line to move to if @code{next-line-add-newlines} is non-@code{nil} (its default is @code{nil}.) Suppose you wanted to add a similar feature to @code{previous-line}, which would insert a new line at the beginning of the buffer for the command to move to (when @code{next-line-add-newlines} is non-@code{nil}). How could you do this? You could do it by redefining the whole function, but that is not modular. The advice feature provides a cleaner alternative: you can effectively add your code to the existing function definition, without actually changing or even seeing that definition. Here is how to do this: @example (defadvice previous-line (before next-line-at-end (&optional arg try-vscroll)) "Insert an empty line when moving up from the top line." (if (and next-line-add-newlines (= arg 1) (save-excursion (beginning-of-line) (bobp))) (progn (beginning-of-line) (newline)))) @end example This expression defines a @dfn{piece of advice} for the function @code{previous-line}. This piece of advice is named @code{next-line-at-end}, and the symbol @code{before} says that it is @dfn{before-advice} which should run before the regular definition of @code{previous-line}. @code{(&optional arg try-vscroll)} specifies how the advice code can refer to the function's arguments. When this piece of advice runs, it creates an additional line, in the situation where that is appropriate, but does not move point to that line. This is the correct way to write the advice, because the normal definition will run afterward and will move back to the newly inserted line. Defining the advice doesn't immediately change the function @code{previous-line}. That happens when you @dfn{activate} the advice, like this: @example (ad-activate 'previous-line) @end example @noindent This is what actually begins to use the advice that has been defined so far for the function @code{previous-line}. Henceforth, whenever that function is run, whether invoked by the user with @kbd{C-p} or @kbd{M-x}, or called from Lisp, it runs the advice first, and its regular definition second. This example illustrates before-advice, which is one @dfn{class} of advice: it runs before the function's base definition. There are two other advice classes: @dfn{after-advice}, which runs after the base definition, and @dfn{around-advice}, which lets you specify an expression to wrap around the invocation of the base definition. @node Defining Advice @section Defining Advice @cindex defining advice @cindex advice, defining To define a piece of advice, use the macro @code{defadvice}. A call to @code{defadvice} has the following syntax, which is based on the syntax of @code{defun} and @code{defmacro}, but adds more: @findex defadvice @example (defadvice @var{function} (@var{class} @var{name} @r{[}@var{position}@r{]} @r{[}@var{arglist}@r{]} @var{flags}...) @r{[}@var{documentation-string}@r{]} @r{[}@var{interactive-form}@r{]} @var{body-forms}...) @end example @noindent Here, @var{function} is the name of the function (or macro or special form) to be advised. From now on, we will write just ``function'' when describing the entity being advised, but this always includes macros and special forms. In place of the argument list in an ordinary definition, an advice definition calls for several different pieces of information. @cindex class of advice @cindex before-advice @cindex after-advice @cindex around-advice @var{class} specifies the @dfn{class} of the advice---one of @code{before}, @code{after}, or @code{around}. Before-advice runs before the function itself; after-advice runs after the function itself; around-advice is wrapped around the execution of the function itself. After-advice and around-advice can override the return value by setting @code{ad-return-value}. @defvar ad-return-value While advice is executing, after the function's original definition has been executed, this variable holds its return value, which will ultimately be returned to the caller after finishing all the advice. After-advice and around-advice can arrange to return some other value by storing it in this variable. @end defvar The argument @var{name} is the name of the advice, a non-@code{nil} symbol. The advice name uniquely identifies one piece of advice, within all the pieces of advice in a particular class for a particular @var{function}. The name allows you to refer to the piece of advice---to redefine it, or to enable or disable it. The optional @var{position} specifies where, in the current list of advice of the specified @var{class}, this new advice should be placed. It should be either @code{first}, @code{last} or a number that specifies a zero-based position (@code{first} is equivalent to 0). If no position is specified, the default is @code{first}. Position values outside the range of existing positions in this class are mapped to the beginning or the end of the range, whichever is closer. The @var{position} value is ignored when redefining an existing piece of advice. The optional @var{arglist} can be used to define the argument list for the sake of advice. This becomes the argument list of the combined definition that is generated in order to run the advice (@pxref{Combined Definition}). Therefore, the advice expressions can use the argument variables in this list to access argument values. The argument list used in advice need not be the same as the argument list used in the original function, but must be compatible with it, so that it can handle the ways the function is actually called. If two pieces of advice for a function both specify an argument list, they must specify the same argument list. @xref{Argument Access in Advice}, for more information about argument lists and advice, and a more flexible way for advice to access the arguments. The remaining elements, @var{flags}, are symbols that specify further information about how to use this piece of advice. Here are the valid symbols and their meanings: @table @code @item activate Activate the advice for @var{function} now. Changes in a function's advice always take effect the next time you activate advice for the function; this flag says to do so, for @var{function}, immediately after defining this piece of advice. @cindex forward advice This flag has no immediate effect if @var{function} itself is not defined yet (a situation known as @dfn{forward advice}), because it is impossible to activate an undefined function's advice. However, defining @var{function} will automatically activate its advice. @item protect Protect this piece of advice against non-local exits and errors in preceding code and advice. Protecting advice places it as a cleanup in an @code{unwind-protect} form, so that it will execute even if the previous code gets an error or uses @code{throw}. @xref{Cleanups}. @item compile Compile the combined definition that is used to run the advice. This flag is ignored unless @code{activate} is also specified. @xref{Combined Definition}. @item disable Initially disable this piece of advice, so that it will not be used unless subsequently explicitly enabled. @xref{Enabling Advice}. @item preactivate Activate advice for @var{function} when this @code{defadvice} is compiled or macroexpanded. This generates a compiled advised definition according to the current advice state, which will be used during activation if appropriate. @xref{Preactivation}. This is useful only if this @code{defadvice} is byte-compiled. @end table The optional @var{documentation-string} serves to document this piece of advice. When advice is active for @var{function}, the documentation for @var{function} (as returned by @code{documentation}) combines the documentation strings of all the advice for @var{function} with the documentation string of its original function definition. The optional @var{interactive-form} form can be supplied to change the interactive behavior of the original function. If more than one piece of advice has an @var{interactive-form}, then the first one (the one with the smallest position) found among all the advice takes precedence. The possibly empty list of @var{body-forms} specifies the body of the advice. The body of an advice can access or change the arguments, the return value, the binding environment, and perform any other kind of side effect. @strong{Warning:} When you advise a macro, keep in mind that macros are expanded when a program is compiled, not when a compiled program is run. All subroutines used by the advice need to be available when the byte compiler expands the macro. @deffn Command ad-unadvise function This command deletes the advice from @var{function}. @end deffn @deffn Command ad-unadvise-all This command deletes all pieces of advice from all functions. @end deffn @node Around-Advice @section Around-Advice Around-advice lets you ``wrap'' a Lisp expression ``around'' the original function definition. You specify where the original function definition should go by means of the special symbol @code{ad-do-it}. Where this symbol occurs inside the around-advice body, it is replaced with a @code{progn} containing the forms of the surrounded code. Here is an example: @example (defadvice foo (around foo-around) "Ignore case in `foo'." (let ((case-fold-search t)) ad-do-it)) @end example @noindent Its effect is to make sure that case is ignored in searches when the original definition of @code{foo} is run. @defvar ad-do-it This is not really a variable, rather a place-holder that looks like a variable. You use it in around-advice to specify the place to run the function's original definition and other ``earlier'' around-advice. @end defvar If the around-advice does not use @code{ad-do-it}, then it does not run the original function definition. This provides a way to override the original definition completely. (It also overrides lower-positioned pieces of around-advice). If the around-advice uses @code{ad-do-it} more than once, the original definition is run at each place. In this way, around-advice can execute the original definition (and lower-positioned pieces of around-advice) several times. Another way to do that is by using @code{ad-do-it} inside of a loop. @node Computed Advice @section Computed Advice The macro @code{defadvice} resembles @code{defun} in that the code for the advice, and all other information about it, are explicitly stated in the source code. You can also create advice whose details are computed, using the function @code{ad-add-advice}. @defun ad-add-advice function advice class position Calling @code{ad-add-advice} adds @var{advice} as a piece of advice to @var{function} in class @var{class}. The argument @var{advice} has this form: @example (@var{name} @var{protected} @var{enabled} @var{definition}) @end example Here @var{protected} and @var{enabled} are flags, and @var{definition} is the expression that says what the advice should do. If @var{enabled} is @code{nil}, this piece of advice is initially disabled (@pxref{Enabling Advice}). If @var{function} already has one or more pieces of advice in the specified @var{class}, then @var{position} specifies where in the list to put the new piece of advice. The value of @var{position} can either be @code{first}, @code{last}, or a number (counting from 0 at the beginning of the list). Numbers outside the range are mapped to the beginning or the end of the range, whichever is closer. The @var{position} value is ignored when redefining an existing piece of advice. If @var{function} already has a piece of @var{advice} with the same name, then the position argument is ignored and the old advice is replaced with the new one. @end defun @node Activation of Advice @section Activation of Advice @cindex activating advice @cindex advice, activating By default, advice does not take effect when you define it---only when you @dfn{activate} advice for the function that was advised. However, the advice will be activated automatically if you define or redefine the function later. You can request the activation of advice for a function when you define the advice, by specifying the @code{activate} flag in the @code{defadvice}. But normally you activate the advice for a function by calling the function @code{ad-activate} or one of the other activation commands listed below. Separating the activation of advice from the act of defining it permits you to add several pieces of advice to one function efficiently, without redefining the function over and over as each advice is added. More importantly, it permits defining advice for a function before that function is actually defined. When a function's advice is first activated, the function's original definition is saved, and all enabled pieces of advice for that function are combined with the original definition to make a new definition. (Pieces of advice that are currently disabled are not used; see @ref{Enabling Advice}.) This definition is installed, and optionally byte-compiled as well, depending on conditions described below. In all of the commands to activate advice, if @var{compile} is @code{t} (or anything but @code{nil} or a negative number), the command also compiles the combined definition which implements the advice. If it is @code{nil} or a negative number, what happens depends on @code{ad-default-compilation-action} as described below. @deffn Command ad-activate function &optional compile This command activates all the advice defined for @var{function}. @end deffn Activating advice does nothing if @var{function}'s advice is already active. But if there is new advice, added since the previous time you activated advice for @var{function}, it activates the new advice. @deffn Command ad-deactivate function This command deactivates the advice for @var{function}. @cindex deactivating advice @c @cindex advice, deactivating "advice, activating" is just above @end deffn @deffn Command ad-update function &optional compile This command activates the advice for @var{function} if its advice is already activated. This is useful if you change the advice. @end deffn @deffn Command ad-activate-all &optional compile This command activates the advice for all functions. @end deffn @deffn Command ad-deactivate-all This command deactivates the advice for all functions. @end deffn @deffn Command ad-update-all &optional compile This command activates the advice for all functions whose advice is already activated. This is useful if you change the advice of some functions. @end deffn @deffn Command ad-activate-regexp regexp &optional compile This command activates all pieces of advice whose names match @var{regexp}. More precisely, it activates all advice for any function which has at least one piece of advice that matches @var{regexp}. @end deffn @deffn Command ad-deactivate-regexp regexp This command deactivates all pieces of advice whose names match @var{regexp}. More precisely, it deactivates all advice for any function which has at least one piece of advice that matches @var{regexp}. @end deffn @deffn Command ad-update-regexp regexp &optional compile This command activates pieces of advice whose names match @var{regexp}, but only those for functions whose advice is already activated. @cindex reactivating advice Reactivating a function's advice is useful for putting into effect all the changes that have been made in its advice (including enabling and disabling specific pieces of advice; @pxref{Enabling Advice}) since the last time it was activated. @end deffn @deffn Command ad-start-advice Turn on automatic advice activation when a function is defined or redefined. This is the default mode. @end deffn @deffn Command ad-stop-advice Turn off automatic advice activation when a function is defined or redefined. @end deffn @defopt ad-default-compilation-action This variable controls whether to compile the combined definition that results from activating advice for a function. A value of @code{always} specifies to compile unconditionally. A value of @code{never} specifies never compile the advice. A value of @code{maybe} specifies to compile if the byte-compiler is already loaded. A value of @code{like-original} specifies to compile the advice if the original definition of the advised function is compiled or a built-in function. This variable takes effect only if the @var{compile} argument of @code{ad-activate} (or any of the above functions) did not force compilation. @end defopt If the advised definition was constructed during ``preactivation'' (@pxref{Preactivation}), then that definition must already be compiled, because it was constructed during byte-compilation of the file that contained the @code{defadvice} with the @code{preactivate} flag. @node Enabling Advice @section Enabling and Disabling Advice @cindex enabling advice @cindex advice, enabling and disabling @cindex disabling advice Each piece of advice has a flag that says whether it is enabled or not. By enabling or disabling a piece of advice, you can turn it on and off without having to undefine and redefine it. For example, here is how to disable a particular piece of advice named @code{my-advice} for the function @code{foo}: @example (ad-disable-advice 'foo 'before 'my-advice) @end example This function by itself only changes the enable flag for a piece of advice. To make the change take effect in the advised definition, you must activate the advice for @code{foo} again: @example (ad-activate 'foo) @end example @deffn Command ad-disable-advice function class name This command disables the piece of advice named @var{name} in class @var{class} on @var{function}. @end deffn @deffn Command ad-enable-advice function class name This command enables the piece of advice named @var{name} in class @var{class} on @var{function}. @end deffn You can also disable many pieces of advice at once, for various functions, using a regular expression. As always, the changes take real effect only when you next reactivate advice for the functions in question. @deffn Command ad-disable-regexp regexp This command disables all pieces of advice whose names match @var{regexp}, in all classes, on all functions. @end deffn @deffn Command ad-enable-regexp regexp This command enables all pieces of advice whose names match @var{regexp}, in all classes, on all functions. @end deffn @node Preactivation @section Preactivation @cindex preactivating advice @cindex advice, preactivating Constructing a combined definition to execute advice is moderately expensive. When a library advises many functions, this can make loading the library slow. In that case, you can use @dfn{preactivation} to construct suitable combined definitions in advance. To use preactivation, specify the @code{preactivate} flag when you define the advice with @code{defadvice}. This @code{defadvice} call creates a combined definition which embodies this piece of advice (whether enabled or not) plus any other currently enabled advice for the same function, and the function's own definition. If the @code{defadvice} is compiled, that compiles the combined definition also. When the function's advice is subsequently activated, if the enabled advice for the function matches what was used to make this combined definition, then the existing combined definition is used, thus avoiding the need to construct one. Thus, preactivation never causes wrong results---but it may fail to do any good, if the enabled advice at the time of activation doesn't match what was used for preactivation. Here are some symptoms that can indicate that a preactivation did not work properly, because of a mismatch. @itemize @bullet @item Activation of the advised function takes longer than usual. @item The byte-compiler gets loaded while an advised function gets activated. @item @code{byte-compile} is included in the value of @code{features} even though you did not ever explicitly use the byte-compiler. @end itemize Compiled preactivated advice works properly even if the function itself is not defined until later; however, the function needs to be defined when you @emph{compile} the preactivated advice. There is no elegant way to find out why preactivated advice is not being used. What you can do is to trace the function @code{ad-cache-id-verification-code} (with the function @code{trace-function-background}) before the advised function's advice is activated. After activation, check the value returned by @code{ad-cache-id-verification-code} for that function: @code{verified} means that the preactivated advice was used, while other values give some information about why they were considered inappropriate. @strong{Warning:} There is one known case that can make preactivation fail, in that a preconstructed combined definition is used even though it fails to match the current state of advice. This can happen when two packages define different pieces of advice with the same name, in the same class, for the same function. But you should avoid that anyway. @node Argument Access in Advice @section Argument Access in Advice The simplest way to access the arguments of an advised function in the body of a piece of advice is to use the same names that the function definition uses. To do this, you need to know the names of the argument variables of the original function. While this simple method is sufficient in many cases, it has a disadvantage: it is not robust, because it hard-codes the argument names into the advice. If the definition of the original function changes, the advice might break. Another method is to specify an argument list in the advice itself. This avoids the need to know the original function definition's argument names, but it has a limitation: all the advice on any particular function must use the same argument list, because the argument list actually used for all the advice comes from the first piece of advice for that function. A more robust method is to use macros that are translated into the proper access forms at activation time, i.e., when constructing the advised definition. Access macros access actual arguments by position regardless of how these actual arguments get distributed onto the argument variables of a function. This is robust because in Emacs Lisp the meaning of an argument is strictly determined by its position in the argument list. @defmac ad-get-arg position This returns the actual argument that was supplied at @var{position}. @end defmac @defmac ad-get-args position This returns the list of actual arguments supplied starting at @var{position}. @end defmac @defmac ad-set-arg position value This sets the value of the actual argument at @var{position} to @var{value} @end defmac @defmac ad-set-args position value-list This sets the list of actual arguments starting at @var{position} to @var{value-list}. @end defmac Now an example. Suppose the function @code{foo} is defined as @example (defun foo (x y &optional z &rest r) ...) @end example @noindent and is then called with @example (foo 0 1 2 3 4 5 6) @end example @noindent which means that @var{x} is 0, @var{y} is 1, @var{z} is 2 and @var{r} is @code{(3 4 5 6)} within the body of @code{foo}. Here is what @code{ad-get-arg} and @code{ad-get-args} return in this case: @example (ad-get-arg 0) @result{} 0 (ad-get-arg 1) @result{} 1 (ad-get-arg 2) @result{} 2 (ad-get-arg 3) @result{} 3 (ad-get-args 2) @result{} (2 3 4 5 6) (ad-get-args 4) @result{} (4 5 6) @end example Setting arguments also makes sense in this example: @example (ad-set-arg 5 "five") @end example @noindent has the effect of changing the sixth argument to @code{"five"}. If this happens in advice executed before the body of @code{foo} is run, then @var{r} will be @code{(3 4 "five" 6)} within that body. Here is an example of setting a tail of the argument list: @example (ad-set-args 0 '(5 4 3 2 1 0)) @end example @noindent If this happens in advice executed before the body of @code{foo} is run, then within that body, @var{x} will be 5, @var{y} will be 4, @var{z} will be 3, and @var{r} will be @code{(2 1 0)} inside the body of @code{foo}. These argument constructs are not really implemented as Lisp macros. Instead they are implemented specially by the advice mechanism. @node Advising Primitives @section Advising Primitives @cindex advising primitives Advising a primitive function (also called a ``subr'') is risky. Some primitive functions are used by the advice mechanism; advising them could cause an infinite recursion. Also, many primitive functions are called directly from C code. Calls to the primitive from Lisp code will take note of the advice, but calls from C code will ignore the advice. When the advice facility constructs the combined definition, it needs to know the argument list of the original function. This is not always possible for primitive functions. When advice cannot determine the argument list, it uses @code{(&rest ad-subr-args)}, which always works but is inefficient because it constructs a list of the argument values. You can use @code{ad-define-subr-args} to declare the proper argument names for a primitive function: @defun ad-define-subr-args function arglist This function specifies that @var{arglist} should be used as the argument list for function @var{function}. @end defun For example, @example (ad-define-subr-args 'fset '(sym newdef)) @end example @noindent specifies the argument list for the function @code{fset}. @node Combined Definition @section The Combined Definition Suppose that a function has @var{n} pieces of before-advice (numbered from 0 through @var{n}@minus{}1), @var{m} pieces of around-advice and @var{k} pieces of after-advice. Assuming no piece of advice is protected, the combined definition produced to implement the advice for a function looks like this: @example (lambda @var{arglist} @r{[} @r{[}@var{advised-docstring}@r{]} @r{[}(interactive ...)@r{]} @r{]} (let (ad-return-value) @r{before-0-body-form}... .... @r{before-@var{n}@minus{}1-body-form}... @r{around-0-body-form}... @r{around-1-body-form}... .... @r{around-@var{m}@minus{}1-body-form}... (setq ad-return-value @r{apply original definition to @var{arglist}}) @r{end-of-around-@var{m}@minus{}1-body-form}... .... @r{end-of-around-1-body-form}... @r{end-of-around-0-body-form}... @r{after-0-body-form}... .... @r{after-@var{k}@minus{}1-body-form}... ad-return-value)) @end example Macros are redefined as macros, which means adding @code{macro} to the beginning of the combined definition. The interactive form is present if the original function or some piece of advice specifies one. When an interactive primitive function is advised, advice uses a special method: it calls the primitive with @code{call-interactively} so that it will read its own arguments. In this case, the advice cannot access the arguments. The body forms of the various advice in each class are assembled according to their specified order. The forms of around-advice @var{l} are included in one of the forms of around-advice @var{l} @minus{} 1. The innermost part of the around advice onion is @display apply original definition to @var{arglist} @end display @noindent whose form depends on the type of the original function. The variable @code{ad-return-value} is set to whatever this returns. The variable is visible to all pieces of advice, which can access and modify it before it is actually returned from the advised function. The semantic structure of advised functions that contain protected pieces of advice is the same. The only difference is that @code{unwind-protect} forms ensure that the protected advice gets executed even if some previous piece of advice had an error or a non-local exit. If any around-advice is protected, then the whole around-advice onion is protected as a result. @ignore arch-tag: 80c135c2-f1c3-4f8d-aa85-f8d8770d307f @end ignore