@page @node Modules @chapter Modules @cindex modules When programs become large, naming conflicts can occur when a function or global variable defined in one file has the same name as a function or global variable in another file. Even just a @emph{similarity} between function names can cause hard-to-find bugs, since a programmer might type the wrong function name. The approach used to tackle this problem is called @emph{information encapsulation}, which consists of packaging functional units into a given name space that is clearly separated from other name spaces. @cindex encapsulation @cindex information encapsulation @cindex name space The language features that allow this are usually called @emph{the module system} because programs are broken up into modules that are compiled separately (or loaded separately in an interpreter). Older languages, like C, have limited support for name space manipulation and protection. In C a variable or function is public by default, and can be made local to a module with the @code{static} keyword. But you cannot reference public variables and functions from another module with different names. More advanced module systems have become a common feature in recently designed languages: ML, Python, Perl, and Modula 3 all allow the @emph{renaming} of objects from a foreign module, so they will not clutter the global name space. @cindex name space - private @menu * Scheme and modules:: How modules are handled in standard Scheme. * The Guile module system:: How Guile does it. * Dynamic Libraries:: Loading libraries of compiled code at run time. @end menu @node Scheme and modules @section Scheme and modules Scheme, as defined in R5RS, does @emph{not} have a module system at all. Aubrey Jaffer, mostly to support his portable Scheme library SLIB, implemented a provide/require mechanism for many Scheme implementations. Library files in SLIB @emph{provide} a feature, and when user programs @emph{require} that feature, the library file is loaded in. For example, the file @file{random.scm} in the SLIB package contains the line @smalllisp (provide 'random) @end smalllisp so to use its procedures, a user would type @smalllisp (require 'random) @end smalllisp and they would magically become available, @emph{but still have the same names!} So this method is nice, but not as good as a full-featured module system. @node The Guile module system @section The Guile module system In 1996 Tom Lord implemented a full-featured module system for Guile which allows loading Scheme source files into a private name space. This system has been in available since Guile version 1.4. @c fixme: Actually, was it available before? 1.4 seems a bit late... For Guile version 1.5.0 and later, the system has been improved to have better integration from C code, more fine-grained user control over interfaces, and documentation. Although it is anticipated that the module system implementation will change in the future, the Scheme programming interface described in this manual should be considered stable. The C programming interface is considered relatively stable, although at the time of this writing, there is still some flux. @c fixme: Review: Need better C code interface commentary. @menu * General Information about Modules:: Guile module basics. * Using Guile Modules:: How to use existing modules. * Creating Guile Modules:: How to package your code into modules. * More Module Procedures:: Low-level module code. * Module System Quirks:: Strange things to be aware of. * Included Guile Modules:: Which modules come with Guile? @end menu @node General Information about Modules @subsection General Information about Modules A Guile module is a collection of named procedures, variables and macros, altogether called the @dfn{bindings}, since they bind, or associate, a symbol (the name) to a Scheme object (procedure, variable, or macro). Within a module, all bindings are visible. Certain bindings can be declared @dfn{public}, in which case they are added to the module's so-called @dfn{export list}; this set of public bindings is called the module's @dfn{public interface} (@pxref{Creating Guile Modules}). A client module @dfn{uses} a providing module's bindings by either accessing the providing module's public interface, or by building a custom interface (and then accessing that). In a custom interface, the client module can @dfn{select} which bindings to access and can also algorithmically @dfn{rename} bindings. In contrast, when using the providing module's public interface, the entire export list is available without renaming (@pxref{Using Guile Modules}). To use a module, it must be found and loaded. All Guile modules have a unique @dfn{module name}, which is a list of one or more symbols. Examples are @code{(ice-9 popen)} or @code{(srfi srfi-11)}. When Guile searches for the code of a module, it constructs the name of the file to load by concatenating the name elements with slashes between the elements and appending a number of file name extensions from the list @code{%load-extensions} (REFFIXME). The resulting file name is then searched in all directories in the variable @code{%load-path}. For example, the @code{(ice-9 popen)} module would result in the filename @code{ice-9/popen.scm} and searched in the installation directory of Guile and in all other directories in the load path. @c FIXME::martin: Not sure about this, maybe someone knows better? Every module has a so-called syntax transformer associated with it. This is a procedure which performs all syntax transformation for the time the module is read in and evaluated. When working with modules, you can manipulate the current syntax transformer using the @code{use-syntax} syntactic form or the @code{#:use-syntax} module definition option (@pxref{Creating Guile Modules}). Please note that there are some problems with the current module system you should keep in mind (@pxref{Module System Quirks}). We hope to address these eventually. @node Using Guile Modules @subsection Using Guile Modules To use a Guile module is to access either its public interface or a custom interface (@pxref{General Information about Modules}). Both types of access are handled by the syntactic form @code{use-modules}, which accepts one or more interface specifications and, upon evaluation, arranges for those interfaces to be available to the current module. This process may include locating and loading code for a given module if that code has not yet been loaded (REFFIXME %load-path). An @dfn{interface specification} has one of two forms. The first variation is simply to name the module, in which case its public interface is the one accessed. For example: @smalllisp (use-modules (ice-9 popen)) @end smalllisp Here, the interface specification is @code{(ice-9 popen)}, and the result is that the current module now has access to @code{open-pipe}, @code{close-pipe}, @code{open-input-pipe}, and so on (@pxref{Included Guile Modules}). Note in the previous example that if the current module had already defined @code{open-pipe}, that definition would be overwritten by the definition in @code{(ice-9 popen)}. For this reason (and others), there is a second variation of interface specification that not only names a module to be accessed, but also selects bindings from it and renames them to suit the current module's needs. For example: @smalllisp (use-modules ((ice-9 popen) :select ((open-pipe . pipe-open) close-pipe) :rename (symbol-prefix-proc 'unixy:))) @end smalllisp Here, the interface specification is more complex than before, and the result is that a custom interface with only two bindings is created and subsequently accessed by the current module. The mapping of old to new names is as follows: @c Use `smallexample' since `table' is ugly. --ttn @smallexample (ice-9 popen) sees: current module sees: open-pipe unixy:pipe-open close-pipe unixy:close-pipe @end smallexample This example also shows how to use the convenience procedure @code{symbol-prefix-proc}. @c begin (scm-doc-string "boot-9.scm" "symbol-prefix-proc") @deffn procedure symbol-prefix-proc prefix-sym Return a procedure that prefixes its arg (a symbol) with @var{prefix-sym}. @c Insert gratuitous C++ slam here. --ttn @end deffn @c begin (scm-doc-string "boot-9.scm" "use-modules") @deffn syntax use-modules spec @dots{} Resolve each interface specification @var{spec} into an interface and arrange for these to be accessible by the current module. The return value is unspecified. @var{spec} can be a list of symbols, in which case it names a module whose public interface is found and used. @var{spec} can also be of the form: @smalllisp (MODULE-NAME [:select SELECTION] [:rename RENAMER]) @end smalllisp in which case a custom interface is newly created and used. @var{module-name} is a list of symbols, as above; @var{selection} is a list of selection-specs; and @var{renamer} is a procedure that takes a symbol and returns its new name. A selection-spec is either a symbol or a pair of symbols @code{(ORIG . SEEN)}, where @var{orig} is the name in the used module and @var{seen} is the name in the using module. Note that @var{seen} is also passed through @var{renamer}. The @code{:select} and @code{:rename} clauses are optional. If both are omitted, the returned interface has no bindings. If the @code{:select} clause is omitted, @var{renamer} operates on the used module's public interface. Signal error if module name is not resolvable. @end deffn @c FIXME::martin: Is this correct, and is there more to say? @c FIXME::martin: Define term and concept `system transformer' somewhere. @deffn syntax use-syntax module-name Load the module @code{module-name} and use its system transformer as the system transformer for the currently defined module, as well as installing it as the current system transformer. @end deffn @node Creating Guile Modules @subsection Creating Guile Modules When you want to create your own modules, you have to take the following steps: @itemize @bullet @item Create a Scheme source file and add all variables and procedures you wish to export, or which are required by the exported procedures. @item Add a @code{define-module} form at the beginning. @item Export all bindings which should be in the public interface, either by using @code{define-public} or @code{export} (both documented below). @end itemize @c begin (scm-doc-string "boot-9.scm" "define-module") @deffn syntax define-module module-name [options @dots{}] @var{module-name} is of the form @code{(hierarchy file)}. One example of this is @smalllisp (define-module (ice-9 popen)) @end smalllisp @code{define-module} makes this module available to Guile programs under the given @var{module-name}. The @var{options} are keyword/value pairs which specify more about the defined module. The recognized options and their meaning is shown in the following table. @c fixme: Should we use "#:" or ":"? @table @code @item #:use-module @var{interface-specification} Equivalent to a @code{(use-modules @var{interface-specification})} (@pxref{Using Guile Modules}). @item #:use-syntax @var{module} Use @var{module} when loading the currently defined module, and install it as the syntax transformer. @item #:autoload @var{module} @var{symbol} Load @var{module} whenever @var{symbol} is accessed. @item #:export @var{list} Export all identifiers in @var{list}, which must be a list of symbols. This is equivalent to @code{(export @var{list})} in the module body. @item #:no-backtrace Tell Guile not to record information for procedure backtraces when executing the procedures in this module. @item #:pure Create a @dfn{pure} module, that is a module which does not contain any of the standard procedure bindings except for the syntax forms. This is useful if you want to create @dfn{safe} modules, that is modules which do not know anything about dangerous procedures. @end table @end deffn @c end @deffn syntax export variable @dots{} Add all @var{variable}s (which must be symbols) to the list of exported bindings of the current module. @end deffn @c begin (scm-doc-string "boot-9.scm" "define-public") @deffn syntax define-public @dots{} Equivalent to @code{(begin (define foo ...) (export foo))}. @end deffn @c end @node More Module Procedures @subsection More Module Procedures @c FIXME::martin: Review me! @c FIXME::martin: Should this procedure be documented and supported @c at all? The procedures in this section are useful if you want to dig into the innards of Guile's module system. If you don't know precisely what you do, you should probably avoid using any of them. @deffn primitive standard-eval-closure module Return an eval closure for the module @var{module}. @end deffn @node Module System Quirks @subsection Module System Quirks Although the programming interfaces are relatively stable, the Guile module system itself is still evolving. Here are some situations where usage surpasses design. @itemize @bullet @item When using a module which exports a macro definition, the other module must export all bindings the macro expansion uses, too, because the expanded code would otherwise not be able to see these definitions and issue a ``variable unbound'' error, or worse, would use another binding which might be present in the scope of the expansion. @item When two or more used modules export bindings with the same names, the last accessed module wins, and the exported binding of that last module will silently be used. This might lead to hard-to-find errors because wrong procedures or variables are used. To avoid this kind of @dfn{name-clash} situation, use a custom interface specification (@pxref{Using Guile Modules}). (We include this entry for the possible benefit of users of Guile versions previous to 1.5.0, when custom interfaces were added to the module system.) @item [Add other quirks here.] @end itemize @node Included Guile Modules @subsection Included Guile Modules @c FIXME::martin: Review me! Some modules are included in the Guile distribution; here are references to the entries in this manual which describe them in more detail: @table @strong @item boot-9 boot-9 is Guile's initialization module, and it is always loaded when Guile starts up. @item (ice-9 debug) Mikael Djurfeldt's source-level debugging support for Guile (@pxref{Debugger User Interface}). @item (ice-9 threads) Guile's support for multi threaded execution (@pxref{Scheduling}). @item (ice-9 rdelim) Line- and character-delimited input (@pxref{Line/Delimited}). @item (ice-9 rw) Block string input/output (@pxref{Block Reading and Writing}). @item (ice-9 documentation) Online documentation (REFFIXME). @item (srfi srfi-1) A library providing a lot of useful list and pair processing procedures (@pxref{SRFI-1}). @item (srfi srfi-2) Support for @code{and-let*} (@pxref{SRFI-2}). @item (srfi srfi-4) Support for homogeneous numeric vectors (@pxref{SRFI-4}). @item (srfi srfi-6) Support for some additional string port procedures (@pxref{SRFI-6}). @item (srfi srfi-8) Multiple-value handling with @code{receive} (@pxref{SRFI-8}). @item (srfi srfi-9) Record definition with @code{define-record-type} (@pxref{SRFI-9}). @item (srfi srfi-10) Read hash extension @code{#,()} (@pxref{SRFI-10}). @item (srfi srfi-11) Multiple-value handling with @code{let-values} and @code{let-values*} (@pxref{SRFI-11}). @item (srfi srfi-13) String library (@pxref{SRFI-13}). @item (srfi srfi-14) Character-set library (@pxref{SRFI-14}). @item (srfi srfi-17) Getter-with-setter support (@pxref{SRFI-17}). @item (ice-9 slib) This module contains hooks for using Aubrey Jaffer's portable Scheme library SLIB from Guile (@pxref{SLIB}). @c FIXME::martin: This module is not in the distribution. Remove it @c from here? @item (ice-9 jacal) This module contains hooks for using Aubrey Jaffer's symbolic math packge Jacal from Guile (@pxref{JACAL}). @end table @node Dynamic Libraries @section Dynamic Libraries Most modern Unices have something called @dfn{shared libraries}. This ordinarily means that they have the capability to share the executable image of a library between several running programs to save memory and disk space. But generally, shared libraries give a lot of additional flexibility compared to the traditional static libraries. In fact, calling them `dynamic' libraries is as correct as calling them `shared'. Shared libraries really give you a lot of flexibility in addition to the memory and disk space savings. When you link a program against a shared library, that library is not closely incorporated into the final executable. Instead, the executable of your program only contains enough information to find the needed shared libraries when the program is actually run. Only then, when the program is starting, is the final step of the linking process performed. This means that you need not recompile all programs when you install a new, only slightly modified version of a shared library. The programs will pick up the changes automatically the next time they are run. Now, when all the necessary machinery is there to perform part of the linking at run-time, why not take the next step and allow the programmer to explicitly take advantage of it from within his program? Of course, many operating systems that support shared libraries do just that, and chances are that Guile will allow you to access this feature from within your Scheme programs. As you might have guessed already, this feature is called @dfn{dynamic linking}@footnote{Some people also refer to the final linking stage at program startup as `dynamic linking', so if you want to make yourself perfectly clear, it is probably best to use the more technical term @dfn{dlopening}, as suggested by Gordon Matzigkeit in his libtool documentation.} As with many aspects of Guile, there is a low-level way to access the dynamic linking apparatus, and a more high-level interface that integrates dynamically linked libraries into the module system. @menu * Low level dynamic linking:: * Compiled Code Modules:: * Dynamic Linking and Compiled Code Modules:: @end menu @node Low level dynamic linking @subsection Low level dynamic linking When using the low level procedures to do your dynamic linking, you have complete control over which library is loaded when and what get's done with it. @deffn primitive dynamic-link library Find the shared library denoted by @var{library} (a string) and link it into the running Guile application. When everything works out, return a Scheme object suitable for representing the linked object file. Otherwise an error is thrown. How object files are searched is system dependent. Normally, @var{library} is just the name of some shared library file that will be searched for in the places where shared libraries usually reside, such as in @file{/usr/lib} and @file{/usr/local/lib}. @end deffn @deffn primitive dynamic-object? val Determine whether @var{val} represents a dynamically linked object file. @end deffn @deffn primitive dynamic-unlink dynobj Unlink the indicated object file from the application. The argument @var{dynobj} should be one of the values returned by @code{dynamic-link}. When @code{dynamic-unlink} has been called on @var{dynobj}, it is no longer usable as an argument to the functions below and you will get type mismatch errors when you try to. @end deffn @deffn primitive dynamic-func function dynobj Search the C function indicated by @var{function} (a string or symbol) in @var{dynobj} and return some Scheme object that can later be used with @code{dynamic-call} to actually call this function. Right now, these Scheme objects are formed by casting the address of the function to @code{long} and converting this number to its Scheme representation. Regardless whether your C compiler prepends an underscore @samp{_} to the global names in a program, you should @strong{not} include this underscore in @var{function}. Guile knows whether the underscore is needed or not and will add it when necessary. @end deffn @deffn primitive dynamic-call function dynobj Call the C function indicated by @var{function} and @var{dynobj}. The function is passed no arguments and its return value is ignored. When @var{function} is something returned by @code{dynamic-func}, call that function and ignore @var{dynobj}. When @var{function} is a string (or symbol, etc.), look it up in @var{dynobj}; this is equivalent to @smallexample (dynamic-call (dynamic-func @var{function} @var{dynobj} #f)) @end smallexample Interrupts are deferred while the C function is executing (with @code{SCM_DEFER_INTS}/@code{SCM_ALLOW_INTS}). @end deffn @deffn primitive dynamic-args-call function dynobj args Call the C function indicated by @var{function} and @var{dynobj}, just like @code{dynamic-call}, but pass it some arguments and return its return value. The C function is expected to take two arguments and return an @code{int}, just like @code{main}: @smallexample int c_func (int argc, char **argv); @end smallexample The parameter @var{args} must be a list of strings and is converted into an array of @code{char *}. The array is passed in @var{argv} and its size in @var{argc}. The return value is converted to a Scheme number and returned from the call to @code{dynamic-args-call}. @end deffn When dynamic linking is disabled or not supported on your system, the above functions throw errors, but they are still available. Here is a small example that works on GNU/Linux: @smallexample (define libc-obj (dynamic-link "libc.so")) libc-obj @result{} # (dynamic-args-call 'rand libc-obj '()) @result{} 269167349 (dynamic-unlink libc-obj) libc-obj @result{} # @end smallexample As you can see, after calling @code{dynamic-unlink} on a dynamically linked library, it is marked as @samp{(unlinked)} and you are no longer able to use it with @code{dynamic-call}, etc. Whether the library is really removed from you program is system-dependent and will generally not happen when some other parts of your program still use it. In the example above, @code{libc} is almost certainly not removed from your program because it is badly needed by almost everything. The functions to call a function from a dynamically linked library, @code{dynamic-call} and @code{dynamic-args-call}, are not very powerful. They are mostly intended to be used for calling specially written initialization functions that will then add new primitives to Guile. For example, we do not expect that you will dynamically link @file{libX11} with @code{dynamic-link} and then construct a beautiful graphical user interface just by using @code{dynamic-call} and @code{dynamic-args-call}. Instead, the usual way would be to write a special Guile<->X11 glue library that has intimate knowledge about both Guile and X11 and does whatever is necessary to make them inter-operate smoothly. This glue library could then be dynamically linked into a vanilla Guile interpreter and activated by calling its initialization function. That function would add all the new types and primitives to the Guile interpreter that it has to offer. From this setup the next logical step is to integrate these glue libraries into the module system of Guile so that you can load new primitives into a running system just as you can load new Scheme code. There is, however, another possibility to get a more thorough access to the functions contained in a dynamically linked library. Anthony Green has written @file{libffi}, a library that implements a @dfn{foreign function interface} for a number of different platforms. With it, you can extend the Spartan functionality of @code{dynamic-call} and @code{dynamic-args-call} considerably. There is glue code available in the Guile contrib archive to make @file{libffi} accessible from Guile. @node Compiled Code Modules @subsection Putting Compiled Code into Modules @c FIXME::martin: Change all gh_ references to their scm_ equivalents. The new primitives that you add to Guile with @code{gh_new_procedure} or with any of the other mechanisms are normally placed into the same module as all the other builtin procedures (like @code{display}). However, it is also possible to put new primitives into their own module. The mechanism for doing so is not very well thought out and is likely to change when the module system of Guile itself is revised, but it is simple and useful enough to document it as it stands. What @code{gh_new_procedure} and the functions used by the snarfer really do is to add the new primitives to whatever module is the @emph{current module} when they are called. This is analogous to the way Scheme code is put into modules: the @code{define-module} expression at the top of a Scheme source file creates a new module and makes it the current module while the rest of the file is evaluated. The @code{define} expressions in that file then add their new definitions to this current module. Therefore, all we need to do is to make sure that the right module is current when calling @code{gh_new_procedure} for our new primitives. Unfortunately, there is not yet an easy way to access the module system from C, so we are better off with a more indirect approach. Instead of adding our primitives at initialization time we merely register with Guile that we are ready to provide the contents of a certain module, should it ever be needed. @deftypefun void scm_register_module_xxx (char *@var{name}, void (*@var{initfunc})(void)) Register with Guile that @var{initfunc} will provide the contents of the module @var{name}. The function @var{initfunc} should perform the usual initialization actions for your new primitives, like calling @code{gh_new_procedure} or including the file produced by the snarfer. When @var{initfunc} is called, the current module is a newly created module with a name as indicated by @var{name}. Each definition that is added to it will be automatically exported. The string @var{name} indicates the hierachical name of the new module. It should consist of the individual components of the module name separated by single spaces. That is, the Scheme module name @code{(foo bar)}, which is a list, should be written as @code{"foo bar"} for the @var{name} parameter. You can call @code{scm_register_module_xxx} at any time, even before Guile has been initialized. This might be useful when you want to put the call to it in some initialization code that is magically called before main, like constructors for global C++ objects. An example for @code{scm_register_module_xxx} appears in the next section. @end deftypefun Now, instead of calling the initialization function at program startup, you should simply call @code{scm_register_module_xxx} and pass it the initialization function. When the named module is later requested by Scheme code with @code{use-modules} for example, Guile will notice that it knows how to create this module and will call the initialization function at the right time in the right context. @node Dynamic Linking and Compiled Code Modules @subsection Dynamic Linking and Compiled Code Modules The most interesting application of dynamically linked libraries is probably to use them for providing @emph{compiled code modules} to Scheme programs. As much fun as programming in Scheme is, every now and then comes the need to write some low-level C stuff to make Scheme even more fun. Not only can you put these new primitives into their own module (see the previous section), you can even put them into a shared library that is only then linked to your running Guile image when it is actually needed. An example will hopefully make everything clear. Suppose we want to make the Bessel functions of the C library available to Scheme in the module @samp{(math bessel)}. First we need to write the appropriate glue code to convert the arguments and return values of the functions from Scheme to C and back. Additionally, we need a function that will add them to the set of Guile primitives. Because this is just an example, we will only implement this for the @code{j0} function. @c FIXME::martin: Change all gh_ references to their scm_ equivalents. @smallexample #include #include SCM j0_wrapper (SCM x) @{ return gh_double2scm (j0 (gh_scm2double (x))); @} void init_math_bessel () @{ gh_new_procedure1_0 ("j0", j0_wrapper); @} @end smallexample We can already try to bring this into action by manually calling the low level functions for performing dynamic linking. The C source file needs to be compiled into a shared library. Here is how to do it on GNU/Linux, please refer to the @code{libtool} documentation for how to create dynamically linkable libraries portably. @smallexample gcc -shared -o libbessel.so -fPIC bessel.c @end smallexample Now fire up Guile: @smalllisp (define bessel-lib (dynamic-link "./libbessel.so")) (dynamic-call "init_math_bessel" bessel-lib) (j0 2) @result{} 0.223890779141236 @end smalllisp The filename @file{./libbessel.so} should be pointing to the shared library produced with the @code{gcc} command above, of course. The second line of the Guile interaction will call the @code{init_math_bessel} function which in turn will register the C function @code{j0_wrapper} with the Guile interpreter under the name @code{j0}. This function becomes immediately available and we can call it from Scheme. Fun, isn't it? But we are only half way there. This is what @code{apropos} has to say about @code{j0}: @smallexample (apropos 'j0) @print{} the-root-module: j0 # @end smallexample As you can see, @code{j0} is contained in the root module, where all the other Guile primitives like @code{display}, etc live. In general, a primitive is put into whatever module is the @dfn{current module} at the time @code{gh_new_procedure} is called. To put @code{j0} into its own module named @samp{(math bessel)}, we need to make a call to @code{scm_register_module_xxx}. Additionally, to have Guile perform the dynamic linking automatically, we need to put @file{libbessel.so} into a place where Guile can find it. The call to @code{scm_register_module_xxx} should be contained in a specially named @dfn{module init function}. Guile knows about this special name and will call that function automatically after having linked in the shared library. For our example, we add the following code to @file{bessel.c}: @smallexample void scm_init_math_bessel_module () @{ scm_register_module_xxx ("math bessel", init_math_bessel); @} @end smallexample The general pattern for the name of a module init function is: @samp{scm_init_}, followed by the name of the module where the individual hierarchical components are concatenated with underscores, followed by @samp{_module}. It should call @code{scm_register_module_xxx} with the correct module name and the appropriate initialization function. When that initialization function will be called, a newly created module with the right name will be the @emph{current module} so that all definitions that the initialization functions makes will end up in the correct module. After @file{libbessel.so} has been rebuild, we need to place the shared library into the right place. When Guile tries to autoload the @samp{(math bessel)} module, it looks not only for a file called @file{math/bessel.scm} in its @code{%load-path}, but also for @file{math/libbessel.so}. So all we need to do is to create a directory called @file{math} somewhere in Guile's @code{%load-path} and place @file{libbessel.so} there. Normally, the current directory @file{.} is in the @code{%load-path}, so we just use that for this example. @smallexample % mkdir maths % cd maths % ln -s ../libbessel.so . % cd .. % guile guile> (use-modules (math bessel)) guile> (j0 2) 0.223890779141236 guile> (apropos 'j0) @print{} bessel: j0 # @end smallexample That's it! Note that we used a symlink to make @file{libbessel.so} appear in the right spot. This is probably not a bad idea in general. The directories that the @file{%load-path} normally contains are supposed to contain only architecture independent files. They are not really the right place for a shared library. You might want to install the libraries somewhere below @samp{exec_prefix} and then symlink to them from the architecture independent directory. This will at least work on heterogenous systems where the architecture dependent stuff resides in the same place on all machines (which seems like a good idea to me anyway). @c Local Variables: @c TeX-master: "guile.texi" @c End: