@page @node Procedures and Macros @chapter Procedures and Macros @menu * Lambda:: Basic procedure creation using lambda. * Primitive Procedures:: Procedures defined in C. * Optional Arguments:: Handling keyword, optional and rest arguments. * Procedure Properties:: Procedure properties and meta-information. * Procedures with Setters:: Procedures with setters. * Macros:: Lisp style macro definitions. * Syntax Rules:: Support for R5RS @code{syntax-rules}. * Syntax Case:: Support for the @code{syntax-case} system. * Internal Macros:: Guile's internal representation. @end menu @node Lambda @section Lambda: Basic Procedure Creation @cindex lambda @c FIXME::martin: Review me! A @code{lambda} expression evaluates to a procedure. The environment which is in effect when a @code{lambda} expression is evaluated is enclosed in the newly created procedure, this is referred to as a @dfn{closure} (@pxref{About Closure}). When a procedure created by @code{lambda} is called with some actual arguments, the environment enclosed in the procedure is extended by binding the variables named in the formal argument list to new locations and storing the actual arguments into these locations. Then the body of the @code{lambda} expression is evaluation sequentially. The result of the last expression in the procedure body is then the result of the procedure invocation. The following examples will show how procedures can be created using @code{lambda}, and what you can do with these procedures. @lisp (lambda (x) (+ x x)) @result{} @r{a procedure} ((lambda (x) (+ x x)) 4) @result{} 8 @end lisp The fact that the environment in effect when creating a procedure is enclosed in the procedure is shown with this example: @lisp (define add4 (let ((x 4)) (lambda (y) (+ x y)))) (add4 6) @result{} 10 @end lisp @deffn syntax lambda formals body @var{formals} should be a formal argument list as described in the following table. @table @code @item (@var{variable1} @dots{}) The procedure takes a fixed number of arguments; when the procedure is called, the arguments will be stored into the newly created location for the formal variables. @item @var{variable} The procedure takes any number of arguments; when the procedure is called, the sequence of actual arguments will converted into a list and stored into the newly created location for the formal variable. @item (@var{variable1} @dots{} @var{variablen} . @var{variablen+1}) If a space-delimited period precedes the last variable, then the procedure takes @var{n} or more variables where @var{n} is the number of formal arguments before the period. There must be at least one argument before the period. The first @var{n} actual arguments will be stored into the newly allocated locations for the first @var{n} formal arguments and the sequence of the remaining actual arguments is converted into a list and the stored into the location for the last formal argument. If there are exactly @var{n} actual arguments, the empty list is stored into the location of the last formal argument. @end table @var{body} is a sequence of Scheme expressions which are evaluated in order when the procedure is invoked. @end deffn @node Primitive Procedures @section Primitive Procedures @cindex primitives @cindex primitive procedures Procedures written in C can be registered for use from Scheme, provided they take only arguments of type @code{SCM} and return @code{SCM} values. @code{scm_c_define_gsubr} is likely to be the most useful mechanism, combining the process of registration (@code{scm_c_make_gsubr}) and definition (@code{scm_define}). @deftypefun SCM scm_c_make_gsubr (const char *name, int req, int opt, int rst, fcn) Register a C procedure @var{FCN} as a ``subr'' --- a primitive subroutine that can be called from Scheme. It will be associated with the given @var{name} but no environment binding will be created. The arguments @var{req}, @var{opt} and @var{rst} specify the number of required, optional and ``rest'' arguments respectively. The total number of these arguments should match the actual number of arguments to @var{fcn}. The number of rest arguments should be 0 or 1. @code{scm_c_make_gsubr} returns a value of type @code{SCM} which is a ``handle'' for the procedure. @end deftypefun @deftypefun SCM scm_c_define_gsubr (const char *name, int req, int opt, int rst, fcn) Register a C procedure @var{FCN}, as for @code{scm_c_make_gsubr} above, and additionally create a top-level Scheme binding for the procedure in the ``current environment'' using @code{scm_define}. @code{scm_c_define_gsubr} returns a handle for the procedure in the same way as @code{scm_c_make_gsubr}, which is usually not further required. @end deftypefun @code{scm_c_make_gsubr} and @code{scm_c_define_gsubr} automatically use @code{scm_c_make_subr} and also @code{scm_makcclo} if necessary. It is advisable to use the gsubr variants since they provide a slightly higher-level abstraction of the Guile implementation. @node Optional Arguments @section Optional Arguments @c FIXME::martin: Review me! Scheme procedures, as defined in R5RS, can either handle a fixed number of actual arguments, or a fixed number of actual arguments followed by arbitrarily many additional arguments. Writing procedures of variable arity can be useful, but unfortunately, the syntactic means for handling argument lists of varying length is a bit inconvenient. It is possible to give names to the fixed number of argument, but the remaining (optional) arguments can be only referenced as a list of values (@pxref{Lambda}). Guile comes with the module @code{(ice-9 optargs)}, which makes using optional arguments much more convenient. In addition, this module provides syntax for handling keywords in argument lists (@pxref{Keywords}). Before using any of the procedures or macros defined in this section, you have to load the module @code{(ice-9 optargs)} with the statement: @cindex @code{optargs} @lisp (use-modules (ice-9 optargs)) @end lisp @menu * let-optional Reference:: Locally binding optional arguments. * let-keywords Reference:: Locally binding keywords arguments. * lambda* Reference:: Creating advanced argument handling procedures. * define* Reference:: Defining procedures and macros. @end menu @node let-optional Reference @subsection let-optional Reference @c FIXME::martin: Review me! The syntax @code{let-optional} and @code{let-optional*} are for destructuring rest argument lists and giving names to the various list elements. @code{let-optional} binds all variables simultaneously, while @code{let-optional*} binds them sequentially, consistent with @code{let} and @code{let*} (@pxref{Local Bindings}). @deffn {library syntax} let-optional rest-arg (binding @dots{}) expr @dots{} @deffnx {library syntax} let-optional* rest-arg (binding @dots{}) expr @dots{} These two macros give you an optional argument interface that is very @dfn{Schemey} and introduces no fancy syntax. They are compatible with the scsh macros of the same name, but are slightly extended. Each of @var{binding} may be of one of the forms @var{var} or @code{(@var{var} @var{default-value})}. @var{rest-arg} should be the rest-argument of the procedures these are used from. The items in @var{rest-arg} are sequentially bound to the variable names are given. When @var{rest-arg} runs out, the remaining vars are bound either to the default values or @code{#f} if no default value was specified. @var{rest-arg} remains bound to whatever may have been left of @var{rest-arg}. After binding the variables, the expressions @var{expr} @dots{} are evaluated in order. @end deffn @node let-keywords Reference @subsection let-keywords Reference @c FIXME::martin: Review me! @code{let-keywords} and @code{let-keywords*} are used for extracting values from argument lists which use keywords instead of argument position for binding local variables to argument values. @code{let-keywords} binds all variables simultaneously, while @code{let-keywords*} binds them sequentially, consistent with @code{let} and @code{let*} (@pxref{Local Bindings}). @deffn {library syntax} let-keywords rest-arg allow-other-keys? (binding @dots{}) expr @dots{} @deffnx {library syntax} let-keywords rest-arg allow-other-keys? (binding @dots{}) expr @dots{} These macros pick out keyword arguments from @var{rest-arg}, but do not modify it. This is consistent at least with Common Lisp, which duplicates keyword arguments in the rest argument. More explanation of what keyword arguments in a lambda list look like can be found below in the documentation for @code{lambda*} (@pxref{lambda* Reference}). @var{binding}s can have the same form as for @code{let-optional}. If @var{allow-other-keys?} is false, an error will be thrown if anything that looks like a keyword argument but does not match a known keyword parameter will result in an error. After binding the variables, the expressions @var{expr} @dots{} are evaluated in order. @end deffn @node lambda* Reference @subsection lambda* Reference @c FIXME::martin: Review me! When using optional and keyword argument lists, using @code{lambda} for creating procedures and using @code{let-optional} or @code{let-keywords} is a bit lengthy. Therefore, @code{lambda*} is provided, which combines the features of those macros into a single convenient syntax. For quick reference, here is the syntax of the formal argument list for @code{lambda*} (brackets are used to indicate grouping only): @example ext-param-list ::= [identifier]* [#:optional [ext-var-decl]+]? [#:key [ext-var-decl]+ [#:allow-other-keys]?]? [[#:rest identifier]|[. identifier]]? ext-var-decl ::= identifier | ( identifier expression ) @end example The characters `*', `+' and `?' are not to be taken literally; they mean respectively, zero or more occurrences, one or more occurrences, and one or zero occurrences. @deffn {library syntax} lambda* formals body @code{lambda*} creates a procedure that takes optional arguments. These are specified by putting them inside brackets at the end of the parameter list, but before any dotted rest argument. For example, @lisp (lambda* (a b #:optional c d . e) '()) @end lisp creates a procedure with fixed arguments @var{a} and @var{b}, optional arguments @var{c} and @var{d}, and rest argument @var{e}. If the optional arguments are omitted in a call, the variables for them are bound to @code{#f}. @code{lambda*} can also take keyword arguments. For example, a procedure defined like this: @lisp (lambda* (#:key xyzzy larch) '()) @end lisp can be called with any of the argument lists @code{(#:xyzzy 11)} @code{(#:larch 13)} @code{(#:larch 42 #:xyzzy 19)} @code{()}. Whichever arguments are given as keywords are bound to values. Optional and keyword arguments can also be given default values which they take on when they are not present in a call, by giving a two-item list in place of an optional argument, for example in: @lisp (lambda* (foo #:optional (bar 42) #:key (baz 73)) (list foo bar baz)) @end lisp @var{foo} is a fixed argument, @var{bar} is an optional argument with default value 42, and baz is a keyword argument with default value 73. Default value expressions are not evaluated unless they are needed and until the procedure is called. @code{lambda*} also supports two more special parameter list keywords. @code{lambda*}-defined procedures now throw an error by default if a keyword other than one of those specified is found in the actual passed arguments. However, specifying @code{#:allow-other-keys} immediately after the keyword argument declarations restores the previous behavior of ignoring unknown keywords. @code{lambda*} also now guarantees that if the same keyword is passed more than once, the last one passed is the one that takes effect. For example, @lisp ((lambda* (#:key (heads 0) (tails 0)) (display (list heads tails))) #:heads 37 #:tails 42 #:heads 99) @end lisp would result in (99 47) being displayed. @code{#:rest} is also now provided as a synonym for the dotted syntax rest argument. The argument lists @code{(a . b)} and @code{(a #:rest b)} are equivalent in all respects to @code{lambda*}. This is provided for more similarity to DSSSL, MIT-Scheme and Kawa among others, as well as for refugees from other Lisp dialects. @end deffn @node define* Reference @subsection define* Reference @c FIXME::martin: Review me! Just like @code{define} has a shorthand notation for defining procedures (@pxref{Lambda Alternatives}), @code{define*} is provided as an abbreviation of the combination of @code{define} and @code{lambda*}. @code{define*-public} is the @code{lambda*} version of @code{define-public}; @code{defmacro*} and @code{defmacro*-public} exist for defining macros with the improved argument list handling possibilities. The @code{-public} versions not only define the procedures/macros, but also export them from the current module. @deffn {library syntax} define* formals body @deffnx {library syntax} define*-public formals body @code{define*} and @code{define*-public} support optional arguments with a similar syntax to @code{lambda*}. They also support arbitrary-depth currying, just like Guile's define. Some examples: @lisp (define* (x y #:optional a (z 3) #:key w . u) (display (list y z u))) @end lisp defines a procedure @code{x} with a fixed argument @var{y}, an optional argument @var{a}, another optional argument @var{z} with default value 3, a keyword argument @var{w}, and a rest argument @var{u}. @lisp (define-public* ((foo #:optional bar) #:optional baz) '()) @end lisp This illustrates currying. A procedure @code{foo} is defined, which, when called with an optional argument @var{bar}, returns a procedure that takes an optional argument @var{baz}. Of course, @code{define*[-public]} also supports @code{#:rest} and @code{#:allow-other-keys} in the same way as @code{lambda*}. @end deffn @deffn {library syntax} defmacro* name formals body @deffnx {library syntax} defmacro*-public name formals body These are just like @code{defmacro} and @code{defmacro-public} except that they take @code{lambda*}-style extended parameter lists, where @code{#:optional}, @code{#:key}, @code{#:allow-other-keys} and @code{#:rest} are allowed with the usual semantics. Here is an example of a macro with an optional argument: @lisp (defmacro* transmorgify (a #:optional b) (a 1)) @end lisp @end deffn @node Procedure Properties @section Procedure Properties and Meta-information @c FIXME::martin: Review me! Procedures always have attached the environment in which they were created and information about how to apply them to actual arguments. In addition to that, properties and meta-information can be stored with procedures. The procedures in this section can be used to test whether a given procedure satisfies a condition; and to access and set a procedure's property. The first group of procedures are predicates to test whether a Scheme object is a procedure, or a special procedure, respectively. @code{procedure?} is the most general predicates, it returns @code{#t} for any kind of procedure. @code{closure?} does not return @code{#t} for primitive procedures, and @code{thunk?} only returns @code{#t} for procedures which do not accept any arguments. @rnindex procedure? @deffn {Scheme Procedure} procedure? obj @deffnx {C Function} scm_procedure_p (obj) Return @code{#t} if @var{obj} is a procedure. @end deffn @deffn {Scheme Procedure} closure? obj @deffnx {C Function} scm_closure_p (obj) Return @code{#t} if @var{obj} is a closure. @end deffn @deffn {Scheme Procedure} thunk? obj @deffnx {C Function} scm_thunk_p (obj) Return @code{#t} if @var{obj} is a thunk. @end deffn @c FIXME::martin: Is that true? @cindex procedure properties Procedure properties are general properties to be attached to procedures. These can be the name of a procedure or other relevant information, such as debug hints. @deffn {Scheme Procedure} procedure-name proc @deffnx {C Function} scm_procedure_name (proc) Return the name of the procedure @var{proc} @end deffn @deffn {Scheme Procedure} procedure-source proc @deffnx {C Function} scm_procedure_source (proc) Return the source of the procedure @var{proc}. @end deffn @deffn {Scheme Procedure} procedure-environment proc @deffnx {C Function} scm_procedure_environment (proc) Return the environment of the procedure @var{proc}. @end deffn @deffn {Scheme Procedure} procedure-properties proc @deffnx {C Function} scm_procedure_properties (proc) Return @var{obj}'s property list. @end deffn @deffn {Scheme Procedure} procedure-property obj key @deffnx {C Function} scm_procedure_property (obj, key) Return the property of @var{obj} with name @var{key}. @end deffn @deffn {Scheme Procedure} set-procedure-properties! proc alist @deffnx {C Function} scm_set_procedure_properties_x (proc, alist) Set @var{obj}'s property list to @var{alist}. @end deffn @deffn {Scheme Procedure} set-procedure-property! obj key value @deffnx {C Function} scm_set_procedure_property_x (obj, key, value) In @var{obj}'s property list, set the property named @var{key} to @var{value}. @end deffn @cindex procedure documentation Documentation for a procedure can be accessed with the procedure @code{procedure-documentation}. @deffn {Scheme Procedure} procedure-documentation proc @deffnx {C Function} scm_procedure_documentation (proc) Return the documentation string associated with @code{proc}. By convention, if a procedure contains more than one expression and the first expression is a string constant, that string is assumed to contain documentation for that procedure. @end deffn @cindex source properties @c FIXME::martin: Is the following true? Source properties are properties which are related to the source code of a procedure, such as the line and column numbers, the file name etc. @deffn {Scheme Procedure} set-source-properties! obj plist @deffnx {C Function} scm_set_source_properties_x (obj, plist) Install the association list @var{plist} as the source property list for @var{obj}. @end deffn @deffn {Scheme Procedure} set-source-property! obj key datum @deffnx {C Function} scm_set_source_property_x (obj, key, datum) Set the source property of object @var{obj}, which is specified by @var{key} to @var{datum}. Normally, the key will be a symbol. @end deffn @deffn {Scheme Procedure} source-properties obj @deffnx {C Function} scm_source_properties (obj) Return the source property association list of @var{obj}. @end deffn @deffn {Scheme Procedure} source-property obj key @deffnx {C Function} scm_source_property (obj, key) Return the source property specified by @var{key} from @var{obj}'s source property list. @end deffn @node Procedures with Setters @section Procedures with Setters @c FIXME::martin: Review me! @c FIXME::martin: Document `operator struct'. @cindex procedure with setter @cindex setter A @dfn{procedure with setter} is a special kind of procedure which normally behaves like any accessor procedure, that is a procedure which accesses a data structure. The difference is that this kind of procedure has a so-called @dfn{setter} attached, which is a procedure for storing something into a data structure. Procedures with setters are treated specially when the procedure appears in the special form @code{set!} (REFFIXME). How it works is best shown by example. Suppose we have a procedure called @code{foo-ref}, which accepts two arguments, a value of type @code{foo} and an integer. The procedure returns the value stored at the given index in the @code{foo} object. Let @code{f} be a variable containing such a @code{foo} data structure.@footnote{Working definitions would be: @lisp (define foo-ref vector-ref) (define foo-set! vector-set!) (define f (make-vector 2 #f)) @end lisp } @lisp (foo-ref f 0) @result{} bar (foo-ref f 1) @result{} braz @end lisp Also suppose that a corresponding setter procedure called @code{foo-set!} does exist. @lisp (foo-set! f 0 'bla) (foo-ref f 0) @result{} bla @end lisp Now we could create a new procedure called @code{foo}, which is a procedure with setter, by calling @code{make-procedure-with-setter} with the accessor and setter procedures @code{foo-ref} and @code{foo-set!}. Let us call this new procedure @code{foo}. @lisp (define foo (make-procedure-with-setter foo-ref foo-set!)) @end lisp @code{foo} can from now an be used to either read from the data structure stored in @code{f}, or to write into the structure. @lisp (set! (foo f 0) 'dum) (foo f 0) @result{} dum @end lisp @deffn {Scheme Procedure} make-procedure-with-setter procedure setter @deffnx {C Function} scm_make_procedure_with_setter (procedure, setter) Create a new procedure which behaves like @var{procedure}, but with the associated setter @var{setter}. @end deffn @deffn {Scheme Procedure} procedure-with-setter? obj @deffnx {C Function} scm_procedure_with_setter_p (obj) Return @code{#t} if @var{obj} is a procedure with an associated setter procedure. @end deffn @deffn {Scheme Procedure} procedure proc @deffnx {C Function} scm_procedure (proc) Return the procedure of @var{proc}, which must be either a procedure with setter, or an operator struct. @end deffn @deffn {Scheme Procedure} setter proc Return the setter of @var{proc}, which must be either a procedure with setter or an operator struct. @end deffn @node Macros @section Lisp Style Macro Definitions @cindex macros @cindex transformation Macros are objects which cause the expression that they appear in to be transformed in some way @emph{before} being evaluated. In expressions that are intended for macro transformation, the identifier that names the relevant macro must appear as the first element, like this: @lisp (@var{macro-name} @var{macro-args} @dots{}) @end lisp In Lisp-like languages, the traditional way to define macros is very similar to procedure definitions. The key differences are that the macro definition body should return a list that describes the transformed expression, and that the definition is marked as a macro definition (rather than a procedure definition) by the use of a different definition keyword: in Lisp, @code{defmacro} rather than @code{defun}, and in Scheme, @code{define-macro} rather than @code{define}. @fnindex defmacro @fnindex define-macro Guile supports this style of macro definition using both @code{defmacro} and @code{define-macro}. The only difference between them is how the macro name and arguments are grouped together in the definition: @lisp (defmacro @var{name} (@var{args} @dots{}) @var{body} @dots{}) @end lisp @noindent is the same as @lisp (define-macro (@var{name} @var{args} @dots{}) @var{body} @dots{}) @end lisp @noindent The difference is analogous to the corresponding difference between Lisp's @code{defun} and Scheme's @code{define}. @code{false-if-exception}, from the @file{boot-9.scm} file in the Guile distribution, is a good example of macro definition using @code{defmacro}: @lisp (defmacro false-if-exception (expr) `(catch #t (lambda () ,expr) (lambda args #f))) @end lisp @noindent The effect of this definition is that expressions beginning with the identifier @code{false-if-exception} are automatically transformed into a @code{catch} expression following the macro definition specification. For example: @lisp (false-if-exception (open-input-file "may-not-exist")) @equiv{} (catch #t (lambda () (open-input-file "may-not-exist")) (lambda args #f)) @end lisp @node Syntax Rules @section The R5RS @code{syntax-rules} System @cindex R5RS syntax-rules system R5RS defines an alternative system for macro and syntax transformations using the keywords @code{define-syntax}, @code{let-syntax}, @code{letrec-syntax} and @code{syntax-rules}. The main difference between the R5RS system and the traditional macros of the previous section is how the transformation is specified. In R5RS, rather than permitting a macro definition to return an arbitrary expression, the transformation is specified in a pattern language that @itemize @bullet @item does not require complicated quoting and extraction of components of the source expression using @code{caddr} etc. @item is designed such that the bindings associated with identifiers in the transformed expression are well defined, and such that it is impossible for the transformed expression to construct new identifiers. @end itemize @noindent The last point is commonly referred to as being @dfn{hygienic}: the R5RS @code{syntax-case} system provides @dfn{hygienic macros}. For example, the R5RS pattern language for the @code{false-if-exception} example of the previous section looks like this: @lisp (syntax-rules () ((_ expr) (catch #t (lambda () expr) (lambda args #f)))) @end lisp @cindex @code{syncase} In Guile, the @code{syntax-rules} system is provided by the @code{(ice-9 syncase)} module. To make these facilities available in your code, include the expression @code{(use-syntax (ice-9 syncase))} (@pxref{Using Guile Modules}) before the first usage of @code{define-syntax} etc. If you are writing a Scheme module, you can alternatively include the form @code{#:use-syntax (ice-9 syncase)} in your @code{define-module} declaration (@pxref{Creating Guile Modules}). @menu * Pattern Language:: The @code{syntax-rules} pattern language. * Define-Syntax:: Top level syntax definitions. * Let-Syntax:: Local syntax definitions. @end menu @node Pattern Language @subsection The @code{syntax-rules} Pattern Language @node Define-Syntax @subsection Top Level Syntax Definitions define-syntax: The gist is (define-syntax ) makes the into a macro so that ( ...) expands at _compile_ or _read_ time (i.e. before any evaluation begins) into some expression that is given by the . @node Let-Syntax @subsection Local Syntax Definitions @node Syntax Case @section Support for the @code{syntax-case} System @node Internal Macros @section Internal Representation of Macros and Syntax Internally, Guile uses three different flavors of macros. The three flavors are called @dfn{acro} (or @dfn{syntax}), @dfn{macro} and @dfn{mmacro}. Given the expression @lisp (foo @dots{}) @end lisp @noindent with @code{foo} being some flavor of macro, one of the following things will happen when the expression is evaluated. @itemize @bullet @item When @code{foo} has been defined to be an @dfn{acro}, the procedure used in the acro definition of @code{foo} is passed the whole expression and the current lexical environment, and whatever that procedure returns is the value of evaluating the expression. You can think of this a procedure that receives its argument as an unevaluated expression. @item When @code{foo} has been defined to be a @dfn{macro}, the procedure used in the macro definition of @code{foo} is passed the whole expression and the current lexical environment, and whatever that procedure returns is evaluated again. That is, the procedure should return a valid Scheme expression. @item When @code{foo} has been defined to be a @dfn{mmacro}, the procedure used in the mmacro definition of `foo' is passed the whole expression and the current lexical environment, and whatever that procedure returns replaces the original expression. Evaluation then starts over from the new expression that has just been returned. @end itemize The key difference between a @dfn{macro} and a @dfn{mmacro} is that the expression returned by a @dfn{mmacro} procedure is remembered (or @dfn{memoized}) so that the expansion does not need to be done again next time the containing code is evaluated. The primitives @code{procedure->syntax}, @code{procedure->macro} and @code{procedure->memoizing-macro} are used to construct acros, macros and mmacros respectively. However, if you do not have a very special reason to use one of these primitives, you should avoid them: they are very specific to Guile's current implementation and therefore likely to change. Use @code{defmacro}, @code{define-macro} (@pxref{Macros}) or @code{define-syntax} (@pxref{Syntax Rules}) instead. (In low level terms, @code{defmacro}, @code{define-macro} and @code{define-syntax} are all implemented as mmacros.) @deffn {Scheme Procedure} procedure->syntax code @deffnx {C Function} scm_makacro (code) Return a macro which, when a symbol defined to this value appears as the first symbol in an expression, returns the result of applying @var{code} to the expression and the environment. @end deffn @deffn {Scheme Procedure} procedure->macro code @deffnx {C Function} scm_makmacro (code) Return a macro which, when a symbol defined to this value appears as the first symbol in an expression, evaluates the result of applying @var{code} to the expression and the environment. For example: @lisp (define trace (procedure->macro (lambda (x env) `(set! ,(cadr x) (tracef ,(cadr x) ',(cadr x)))))) (trace @i{foo}) @equiv{} (set! @i{foo} (tracef @i{foo} '@i{foo})). @end lisp @end deffn @deffn {Scheme Procedure} procedure->memoizing-macro code @deffnx {C Function} scm_makmmacro (code) Return a macro which, when a symbol defined to this value appears as the first symbol in an expression, evaluates the result of applying @var{code} to the expression and the environment. @code{procedure->memoizing-macro} is the same as @code{procedure->macro}, except that the expression returned by @var{code} replaces the original macro expression in the memoized form of the containing code. @end deffn In the following primitives, @dfn{acro} flavor macros are referred to as @dfn{syntax transformers}. @deffn {Scheme Procedure} macro? obj @deffnx {C Function} scm_macro_p (obj) Return @code{#t} if @var{obj} is a regular macro, a memoizing macro or a syntax transformer. @end deffn @deffn {Scheme Procedure} macro-type m @deffnx {C Function} scm_macro_type (m) Return one of the symbols @code{syntax}, @code{macro} or @code{macro!}, depending on whether @var{m} is a syntax transformer, a regular macro, or a memoizing macro, respectively. If @var{m} is not a macro, @code{#f} is returned. @end deffn @deffn {Scheme Procedure} macro-name m @deffnx {C Function} scm_macro_name (m) Return the name of the macro @var{m}. @end deffn @deffn {Scheme Procedure} macro-transformer m @deffnx {C Function} scm_macro_transformer (m) Return the transformer of the macro @var{m}. @end deffn @deffn {Scheme Procedure} cons-source xorig x y @deffnx {C Function} scm_cons_source (xorig, x, y) Create and return a new pair whose car and cdr are @var{x} and @var{y}. Any source properties associated with @var{xorig} are also associated with the new pair. @end deffn @c Local Variables: @c TeX-master: "guile.texi" @c End: