X-Git-Url: http://repo.macrolet.net/gitweb/?a=blobdiff_plain;f=doc%2Fmanual%2Fffi.texinfo;h=b4fc8cae4a1e668ad1ff604f715be0bb0e98c2cd;hb=a01e7ac2e8a9f3afae8f759381a0829fceb5bfde;hp=68d5ccec44d6ffde80ec874ff21586ecbdaee828;hpb=78867137cd2b9e689fd07640d60e4cf3942bf719;p=sbcl.git

diff --git a/doc/manual/ffi.texinfo b/doc/manual/ffi.texinfo
index 68d5cce..b4fc8ca 100644
--- a/doc/manual/ffi.texinfo
+++ b/doc/manual/ffi.texinfo
@@ -1,9 +1,9 @@
-@node    The Foreign Function Interface, Function Index, Beyond The ANSI Standard, Top
+@node  Foreign Function Interface
 @comment  node-name,  next,  previous,  up
-@chapter The Foreign Function Interface
+@chapter Foreign Function Interface
 
 This chapter describes SBCL's interface to C programs and
-libraries (and, since C interfaces are a sort of @emph{ingua
+libraries (and, since C interfaces are a sort of @emph{lingua
 franca} of the Unix world, to other programs and libraries in
 general.)
 
@@ -24,12 +24,12 @@ notably in the name of the @code{SB-ALIEN} package.
 * Operations On Foreign Values::  
 * Foreign Variables::           
 * Foreign Data Structure Examples::  
-* Loading Unix Object Files::   
+* Loading Shared Object Files::  
 * Foreign Function Calls::      
 * Step-By-Step Example of the Foreign Function Interface::  
 @end menu
 
-@node  Introduction to the Foreign Function Interface, Foreign Types, The Foreign Function Interface, The Foreign Function Interface
+@node  Introduction to the Foreign Function Interface
 @comment  node-name,  next,  previous,  up
 @section Introduction to the Foreign Function Interface
 @c AKA "Introduction to Aliens" in the CMU CL manual
@@ -64,7 +64,7 @@ use of extensions to the Lisp language.
 
 SBCL, like CMUCL before it, relies primarily on the automatic
 conversion and direct manipulation approaches. The @code{SB-ALIEN}
-package provices a facility wherein foreign values of simple scalar
+package provides a facility wherein foreign values of simple scalar
 types are automatically converted and complex types are directly
 manipulated in their foreign representation.  Additionally the
 lower-level System Area Pointers (or @acronym{SAP}s) can be used where
@@ -79,7 +79,7 @@ raw pointer to the foreign data within an @code{alien-value} object.
 The type language and operations on foreign types are
 intentionally similar to those of the C language.
 
-@node  Foreign Types, Operations On Foreign Values, Introduction to the Foreign Function Interface, The Foreign Function Interface
+@node  Foreign Types
 @comment  node-name,  next,  previous,  up
 @section Foreign Types
 @c AKA "Alien Types" in the CMU CL manual
@@ -109,7 +109,7 @@ has the corresponding SBCL @acronym{FFI} type
 * Foreign Type Specifiers::     
 @end menu
 
-@node  Defining Foreign Types, Foreign Types and Lisp Types, Foreign Types, Foreign Types
+@node  Defining Foreign Types
 @comment  node-name,  next,  previous,  up
 @subsection Defining Foreign Types
 
@@ -127,7 +127,7 @@ An anonymous structure or union type is specified by using the name
 inherently named, but can be given named abbreviations using the
 @code{define-alien-type} macro.
 
-@node  Foreign Types and Lisp Types, Foreign Type Specifiers, Defining Foreign Types, Foreign Types
+@node  Foreign Types and Lisp Types
 @comment  node-name,  next,  previous,  up
 @subsection Foreign Types and Lisp Types
 
@@ -153,7 +153,7 @@ to Lisp floats.  When @code{type-of} is called on an alien value that
 is not automatically converted to a Lisp value, then it will return an
 @code{alien} type specifier.
 
-@node  Foreign Type Specifiers,  , Foreign Types and Lisp Types, Foreign Types
+@node  Foreign Type Specifiers
 @comment  node-name,  next,  previous,  up
 @subsection Foreign Type Specifiers
 
@@ -174,7 +174,7 @@ ANSI C. A null alien pointer can be detected with the
 @code{sb-alien:null-alien} function.
 
 @item
-The foreign type specifier @code{(array @var{foo} &optional
+The foreign type specifier @code{(array @var{foo} &rest
 dimensions)} describes array of the specified @code{dimensions},
 holding elements of type @var{foo}. Note that (unlike in C) @code{(*
 @var{foo})} and @code{(array @var{foo})} are considered to be
@@ -196,8 +196,10 @@ variables. Dynamic arrays can only be allocated using
 The foreign type specifier @code{(sb-alien:struct @var{name} &rest
 @var{fields})} describes a structure type with the specified
 @var{name} and @var{fields}. Fields are allocated at the same offsets
-used by the implementation's C compiler. If @var{name} is @code{nil}
-then the structure is anonymous.
+used by the implementation's C compiler, as guessed by the SBCL
+internals. An optional @code{:alignment} keyword argument can be
+specified for each field to explicitly control the alignment of a
+field. If @var{name} is @code{nil} then the structure is anonymous.
 
 If a named foreign @code{struct} specifier is passed to
 @code{define-alien-type} or @code{with-alien}, then this defines,
@@ -216,9 +218,9 @@ determine which field is active from context.
 @item
 The foreign type specifier @code{(sb-alien:enum @var{name} &rest
 @var{specs})} describes an enumeration type that maps between integer
-values and keywords. If @var{name} is @code{nil}, then the type is
+values and symbols. If @var{name} is @code{nil}, then the type is
 anonymous.  Each element of the @var{specs} list is either a Lisp
-keyword, or a list @code{(@var{keyword} @var{value})}.  @var{value} is
+symbol, or a list @code{(@var{symbol} @var{value})}.  @var{value} is
 an integer. If @var{value} is not supplied, then it defaults to one
 greater than the value for the preceding spec (or to zero if it is the
 first spec).
@@ -281,13 +283,37 @@ types to declare that no useful value is returned.  Using
 return zero values.
 
 @item
-The foreign type specifier @code{sb-alien:c-string} is similar to
-@code{(* char)}, but is interpreted as a null-terminated string, and
-is automatically converted into a Lisp string when accessed; or if the
-pointer is C @code{NULL} or @code{0}, then accessing it gives Lisp
-@code{nil}.  Lisp strings are stored with a trailing NUL
-termination, so no copying (either by the user or the implementation)
-is necessary when passing them to foreign code.
+The foreign type specifier @code{(sb-alien:c-string &key external-format
+element-type)} is similar to @code{(* char)}, but is interpreted as a
+null-terminated string, and is automatically converted into a Lisp
+string when accessed; or if the pointer is C @code{NULL} or @code{0},
+then accessing it gives Lisp @code{nil}.
+
+External format conversion is automatically done when Lisp strings are
+passed to foreign code, or when foreign strings are passed to Lisp code.
+If the type specifier has an explicit @code{external-format}, that
+external format will be used. Otherwise a default external format that
+has been determined at SBCL startup time based on the current locale
+settings will be used. For example, when the following alien routine is
+called, the Lisp string given as argument is converted to an
+@code{ebcdic} octet representation.
+
+@lisp
+(define-alien-routine test int (str (c-string :external-format :ebcdic-us)))
+@end lisp
+
+Lisp strings of type @code{base-string} are stored with a trailing NUL
+termination, so no copying (either by the user or the implementation) is
+necessary when passing them to foreign code, assuming that the
+@code{external-format} and @code{element-type} of the @code{c-string}
+type are compatible with the internal representation of the string. For
+an SBCL built with Unicode support that means an @code{external-format}
+of @code{:ascii} and an @code{element-type} of @code{base-char}. Without
+Unicode support the @code{external-format} can also be
+@code{:iso-8859-1}, and the @code{element-type} can also be
+@code{character}. If the @code{external-format} or @code{element-type}
+is not compatible, or the string is a @code{(simple-array character
+(*))}, this data is copied by the implementation as required.
 
 Assigning a Lisp string to a @code{c-string} structure field or
 variable stores the contents of the string to the memory already
@@ -323,7 +349,7 @@ specifiers as foreign type specifiers: @code{sb-alien:char},
 
 @end itemize
 
-@node  Operations On Foreign Values, Foreign Variables, Foreign Types, The Foreign Function Interface
+@node  Operations On Foreign Values
 @comment  node-name,  next,  previous,  up
 @section Operations On Foreign Values
 @c AKA "Alien Operations" in the CMU CL manual
@@ -338,11 +364,12 @@ to dynamically allocate and free foreign variables.
 * Foreign Dynamic Allocation::  
 @end menu
 
-@node  Accessing Foreign Values, Coercing Foreign Values, Operations On Foreign Values, Operations On Foreign Values
+@node  Accessing Foreign Values
 @comment  node-name,  next,  previous,  up
 @subsection Accessing Foreign Values
 
 @defun sb-alien:deref @var{pointer-or-array} &rest @var{indices}
+@findex deref
 
 The @code{sb-alien:deref} function returns the value pointed to by a
 foreign pointer, or the value of a foreign array element. When
@@ -352,11 +379,11 @@ the size of the type pointed to. When dereferencing an array, the
 number of indices must be the same as the number of dimensions in the
 array type. @code{deref} can be set with @code{setf} to assign a new
 value.
-
 @end defun
 
-@defun sb-alien:slot @var{struct-or-union} &rest @var{slot-names}
-  
+@defun sb-alien:slot @var{struct-or-union} @var{slot-name}
+@findex slot
+
 The @code{sb-alien:slot} function extracts the value of the slot named
 @var{slot-name} from a foreign @code{struct} or @code{union}. If
 @var{struct-or-union} is a pointer to a structure or union, then it is
@@ -378,12 +405,14 @@ used with caution; corrupting the Lisp heap or other memory with
 @acronym{SAP}s is trivial.
 
 @defun sb-sys:int-sap @var{machine-address}
+@findex int-sap
 
 Creates a @acronym{SAP} pointing at the virtual address
 @var{machine-address}.
 @end defun
 
 @defun sb-sys:sap-ref-32 @var{sap} @var{offset}
+@findex sap-ref-32
 
 Access the value of the memory location at @var{offset} bytes from
 @var{sap}.  This form may also be used with @code{setf} to alter the
@@ -391,6 +420,7 @@ memory at that location.
 @end defun
 
 @defun sb-sys:sap= @var{sap1} @var{sap2}
+@findex sap=
 
 Compare @var{sap1} and @var{sap2} for equality.
 @end defun
@@ -404,12 +434,13 @@ use @code{apropos} and @code{describe} for more details
 @end lisp
 
 
-@node  Coercing Foreign Values, Foreign Dynamic Allocation, Accessing Foreign Values, Operations On Foreign Values
+@node  Coercing Foreign Values
 @comment  node-name,  next,  previous,  up
 @subsection Coercing Foreign Values
 
 @defun sb-alien:addr @var{alien-expr}
-  
+@findex addr
+
 The @code{sb-alien:addr} macro returns a pointer to the location
 specified by @var{alien-expr}, which must be either a foreign
 variable, a use of @code{sb-alien:deref}, a use of
@@ -417,7 +448,8 @@ variable, a use of @code{sb-alien:deref}, a use of
 @end defun
 
 @defun sb-alien:cast @var{foreign-value} @var{new-type}
-  
+@findex cast
+
 The @code{sb-alien:cast} macro converts @var{foreign-value} to a new
 foreign value with the specified @var{new-type}. Both types, old and
 new, must be foreign pointer, array or function types.  Note that the
@@ -426,15 +458,17 @@ argument, but it does refer to the same foreign data bits.
 @end defun
 
 @defun sb-alien:sap-alien @var{sap} @var{type}
-  
+@findex sap-alien
+
 The @code{sb-alien:sap-alien} function converts @var{sap} (a system
 area pointer) to a foreign value with the specified
-@var{type}. @var{type} is not evaluated.  </para>
+@var{type}. @var{type} is not evaluated.
 
 The @var{type} must be some foreign pointer, array, or record type.
 @end defun
 
 @defun sb-alien:alien-sap @var{foreign-value} @var{type}
+@findex alien-sap
 
 The @code{sb-alien:alien-sap} function returns the @acronym{SAP} which
 points to @var{alien-value}'s data.
@@ -444,7 +478,7 @@ record type.
 @end defun
 
 
-@node  Foreign Dynamic Allocation,  , Coercing Foreign Values, Operations On Foreign Values
+@node  Foreign Dynamic Allocation
 @comment  node-name,  next,  previous,  up
 @subsection Foreign Dynamic Allocation
 
@@ -457,7 +491,8 @@ Lisp @code{sb-alien:make-alien}, or for Lisp code to call
 code.
 
 @defmac sb-alien:make-alien @var{type} @var{size}
-  
+@findex make-alien
+
 The @code{sb-alien:make-alien} macro
 returns a dynamically allocated foreign value of the specified
 @var{type} (which is not evaluated.)  The allocated memory is not
@@ -494,6 +529,7 @@ result pointing to the first one.
 @end defmac
 
 @defun sb-alien:free-alien @var{foreign-value}
+@findex free-alien
 
 The @code{sb-alien:free-alien} function
 frees the storage for @var{foreign-value}, 
@@ -504,7 +540,7 @@ See also the @code{sb-alien:with-alien} macro, which allocates foreign
 values on the stack.
 @end defun
 
-@node  Foreign Variables, Foreign Data Structure Examples, Operations On Foreign Values, The Foreign Function Interface
+@node  Foreign Variables
 @comment  node-name,  next,  previous,  up
 @section Foreign Variables
 @c AKA "Alien Variables" in the CMU CL manual
@@ -517,11 +553,12 @@ are supported.
 * External Foreign Variables::  
 @end menu
 
-@node  Local Foreign Variables, External Foreign Variables, Foreign Variables, Foreign Variables
+@node  Local Foreign Variables
 @comment  node-name,  next,  previous,  up
 @subsection Local Foreign Variables
 
 @defmac sb-alien:with-alien @var{var-definitions} &body @var{body}
+@findex with-alien
 
 The @code{with-alien} macro establishes local foreign variables with
 the specified alien types and names.  This form is analogous to
@@ -549,7 +586,7 @@ defined foreign structure type @var{foo} can be referenced by its name
 using @code{(struct @var{foo})}.
 @end defmac
 
-@node  External Foreign Variables,  , Local Foreign Variables, Foreign Variables
+@node  External Foreign Variables
 @comment  node-name,  next,  previous,  up
 @subsection External Foreign Variables
 
@@ -580,6 +617,7 @@ specified by using a list of the form
 @end itemize
 
 @defmac sb-alien:define-alien-variable @var{name} @var{type}
+@findex define-alien-variable
 
 The @code{define-alien-variable} macro defines @var{name} as an
 external foreign variable of the specified foreign @code{type}.
@@ -606,6 +644,7 @@ For example, to access a C-level counter @var{foo}, one could write
 @end defmac
 
 @defun sb-alien:get-errno
+@findex get-errno
 
 Since in modern C libraries, the @code{errno} ``variable'' is typically
 no longer a variable, but some bizarre artificial construct
@@ -616,6 +655,7 @@ the operator @code{sb-alien:get-errno} to allow Lisp code to read it.
 @end defun
 
 @defmac sb-alien:extern-alien @var{name} @var{type}
+@findex extern-alien
 
 The @code{extern-alien} macro returns an alien with the specified
 @var{type} which points to an externally defined value.  @var{name} is
@@ -623,7 +663,7 @@ not evaluated, and may be either a string or a symbol.  @var{type} is
 an unevaluated alien type specifier.
 @end defmac
 
-@node  Foreign Data Structure Examples, Loading Unix Object Files, Foreign Variables, The Foreign Function Interface
+@node  Foreign Data Structure Examples
 @comment  node-name,  next,  previous,  up
 @section Foreign Data Structure Examples
 @c AKA "Alien Data Structure Example" in the CMU CL manual
@@ -697,42 +737,16 @@ which can be manipulated in Lisp like this:
 (setq my-struct (slot my-struct 'n))
 @end lisp
 
-@node  Loading Unix Object Files, Foreign Function Calls, Foreign Data Structure Examples, The Foreign Function Interface
+@node  Loading Shared Object Files
 @comment  node-name,  next,  previous,  up
-@section Loading Unix Object Files
+@section Loading Shared Object Files
 
 Foreign object files can be loaded into the running Lisp process by
-calling the functions @code{load-foreign} or @code{load-1-foreign}.
-
-The @code{sb-alien:load-1-foreign} function is the more primitive of
-the two operations. It loads a single object file into the currently
-running Lisp. The external symbols defining routines and variables are
-made available for future external references (e.g. by
-@code{extern-alien}). Forward references to foreign symbols aren't
-supported: @code{load-1-foreign} must be run before any of the defined
-symbols are referenced.
-
-@code{sb-alien:load-foreign} is built in terms of
-@code{load-1-foreign} and some other machinery like
-@code{sb-ext:run-program}.  It accepts a list of files and libraries,
-and runs the linker on the files and libraries, creating an absolute
-Unix object file which is then processed by @code{load-1-foreign}.
-
-@quotation
-Note: As of SBCL 0.7.5, all foreign code (code loaded with
-@code{load-1-function} or @code{load-function}) is lost when a Lisp
-core is saved with @code{sb-ext:save-lisp-and-die}, and no attempt is
-made to restore it when the core is loaded. Historically this has been
-an annoyance both for SBCL users and for CMUCL users.  It's hard to
-solve this problem completely cleanly, but some generally-reliable
-partial solution might be useful. Once someone in either camp gets
-sufficiently annoyed to create it, SBCL is likely to adopt some
-mechanism for automatically restoring foreign code when a saved core
-is loaded.
-@end quotation
+calling @code{load-shared-object}.
 
+@include fun-sb-alien-load-shared-object.texinfo
 
-@node  Foreign Function Calls, Step-By-Step Example of the Foreign Function Interface, Loading Unix Object Files, The Foreign Function Interface
+@node  Foreign Function Calls
 @comment  node-name,  next,  previous,  up
 @section Foreign Function Calls
 
@@ -759,11 +773,12 @@ the only documentation.  Users of a Lisp built with the
 * Calling Lisp From C::         
 @end menu
 
-@node  The alien-funcall Primitive, The define-alien-routine Macro, Foreign Function Calls, Foreign Function Calls
+@node  The alien-funcall Primitive
 @comment  node-name,  next,  previous,  up
 @subsection The @code{alien-funcall} Primitive
 
 @defun sb-alien:alien-funcall @var{alien-function} &rest @var{arguments}
+@findex alien-funcall
 
 The @code{alien-funcall} function is the foreign function call
 primitive: @var{alien-function} is called with the supplied
@@ -812,11 +827,12 @@ the @code{(* (struct foo))} objects filled in by the foreign call:
       result)))
 @end lisp
 
-@node  The define-alien-routine Macro, define-alien-routine Example, The alien-funcall Primitive, Foreign Function Calls
+@node  The define-alien-routine Macro
 @comment  node-name,  next,  previous,  up
 @subsection The @code{define-alien-routine} Macro
 
 @defmac sb-alien:define-alien-routine @var{name} @var{result-type} &rest @var{arg-specifiers}
+@findex define-alien-routine
 
 The @code{define-alien-routine} macro is a convenience for
 automatically generating Lisp interfaces to simple foreign functions.
@@ -890,7 +906,7 @@ representations, avoiding consing.)
 
 @end defmac
 
-@node  define-alien-routine Example, Calling Lisp From C, The define-alien-routine Macro, Foreign Function Calls
+@node  define-alien-routine Example
 @comment  node-name,  next,  previous,  up
 @subsection @code{define-alien-routine} Example
 
@@ -921,7 +937,7 @@ This can be described by the following call to
 The Lisp function @code{cfoo} will have two arguments (@var{str} and
 @var{a}) and two return values (@var{a} and @var{i}).
 
-@node  Calling Lisp From C,  , define-alien-routine Example, Foreign Function Calls
+@node  Calling Lisp From C
 @comment  node-name,  next,  previous,  up
 @subsection Calling Lisp From C
 
@@ -1099,7 +1115,7 @@ call.
 @c -->
 
 
-@node  Step-By-Step Example of the Foreign Function Interface,  , Foreign Function Calls, The Foreign Function Interface
+@node  Step-By-Step Example of the Foreign Function Interface
 @comment  node-name,  next,  previous,  up
 @section Step-By-Step Example of the Foreign Function Interface
 
@@ -1129,7 +1145,7 @@ struct c_struct *c_function (i, s, r, a)
   printf("s = %s\n", s);
   printf("r->x = %d\n", r->x);
   printf("r->s = %s\n", r->s);
-  for (j = 0; j &lt; 10; j++) printf("a[%d] = %d.\n", j, a[j]);
+  for (j = 0; j < 10; j++) printf("a[%d] = %d.\n", j, a[j]);
   r2 = (struct c_struct *) malloc (sizeof(struct c_struct));
   r2->x = i + 5;
   r2->s = "a C string";
@@ -1188,20 +1204,19 @@ It is possible to call this C function from Lisp using the file
 @end lisp
 
 To execute the above example, it is necessary to compile the C
-routine, e.g.: @samp{cc -c test.c} (In order to enable incremental
-loading with some linkers, you may need to say @samp{cc -G 0 -c
-test.c})
+routine, e.g.: @samp{cc -c test.c && ld -shared -o test.so test.o} (In
+order to enable incremental loading with some linkers, you may need to
+say @samp{cc -G 0 -c test.c})
 
-Once the C code has been compiled, you can start up Lisp and load it
-in: @samp{sbcl} Lisp should start up with its normal prompt.
+Once the C code has been compiled, you can start up Lisp and load it in:
+@samp{sbcl}.  Lisp should start up with its normal prompt.
 
 Within Lisp, compile the Lisp file. (This step can be done
 separately. You don't have to recompile every time.)
 @samp{(compile-file "test.lisp")}
 
 Within Lisp, load the foreign object file to define the necessary
-symbols: @samp{(load-foreign "test.o")}.  This must be done before
-loading any code that refers to these symbols.
+symbols: @samp{(load-shared-object "test.so")}. 
 
 Now you can load the compiled Lisp (``fasl'') file into Lisp:
 @samp{(load "test.fasl")}