File ffcall/avcall/avcall.3 from the latest check-in


.TH AVCALL 3 "14 January 2001"
.SH NAME
avcall \- build a C argument list incrementally and call a C function on it.
.SH SYNOPSIS
.B #include <avcall.h>
.LP
.BI "av_alist " alist ";"
.LP
.BI av_start_ type "(" alist ", " "&func"
.RI "[["\c
.BI ", "\c
.I return_type\c
.RB "]" ", "\c
.I "&return_value"\c
.RB "]" ");"
.LP
.BI av_ type "(" alist ", "\c
.RI "["\c
.IB arg_type ","\c
.RI "] "\c
.IB value ");"
.LP
.BI "av_call(" alist ");"
.IX  "av_alist"  ""  "\fLav_alist\fP \(em avcall argument list declaration"
.IX  "av_start_type()"  ""  "\fLav_start_type()\fP \(em initialize avcall function"
.IX  "av_type()"  ""  "\fLav_type()\fP \(em push next argument in avcall list"
.IX  "av_call()"  ""  "\fLav_call()\fP \(em finish avcall argument list and call function"
.SH DESCRIPTION
.LP
This set of macros builds an argument list for a C function and calls
the function on it. It significantly reduces the amount of `glue' code
required for parsers, debuggers, imbedded interpreters, C extensions to
application programs and other situations where collections of functions
need to be called on lists of externally-supplied arguments.

Function calling conventions differ considerably on different
machines and
.I avcall
attempts to provide some degree of isolation from such architecture
dependencies.

The interface is like 
.BR stdarg (3)
in reverse. All of the macros return 0 for success, < 0 for failure (e.g., 
argument list overflow or type-not-supported).
.RS 0
.TP
(1)
.B #include <avcall.h>
.nf
and declare the argument list structure
.BI "av_alist " alist ;
.fi
.TP
(2)
Set any special flags. This is architecture and compiler dependent.
Compiler options that affect passing conventions may need to be flagged
by
.BR "#define" s
before the
.B "#include <avcall.h>"
statement. However, the
.I configure
script should have determined which
.BR "#define" s
are needed and put them
at the top of
.BR avcall.h .
.TP
(3)
Initialize the alist with the function address and return value
pointer (if any). There is a separate macro for each simple return type
([u]char, [u]short, [u]int, [u]long, [u]longlong, float, double, where `u'
indicates `unsigned'). The macros for functions returning structures or
pointers require an explicit type argument.
.LP
E.g.,
.LP
.BI "av_start_int (" alist ", " &func ", " &int_return );
.LP
.BI "av_start_double (" alist ", " &func ", " &double_return );
.LP
.BI "av_start_void (" alist ", " &func );
.LP
.nf
.BI "av_start_struct (" alist ", " &func ", " struct_type ", " splittable ", "
.BI "                 " &struct_return );
.fi
.LP
.nf
.BI "av_start_ptr (" alist ", " &func ", " pointer_type ", "
.BI "              " &pointer_return );
.fi
.LP
The
.I splittable
flag specifies whether the
.I struct_type
can be returned in registers such that every struct field fits entirely in
a single register. This needs to be specified for structs of size
2*sizeof(long). For structs of size <= sizeof(long),
.I splittable
is ignored and assumed to be 1. For structs of size > 2*sizeof(long),
.I splittable
is ignored and assumed to be 0. There are some handy macros for this:
.nf
.BI "av_word_splittable_1 (" type1 )
.BI "av_word_splittable_2 (" type1 ", " type2 )
.BI "av_word_splittable_3 (" type1 ", " type2 ", " type3 )
.BI "av_word_splittable_4 (" type1 ", " type2 ", " type3 ", " type4 )
.fi
For a struct with three slots
.nf
.BI "struct { " "type1 id1" "; " "type2 id2" "; " "type3 id3" "; }"
.fi
you can specify
.I splittable
as
.BI "av_word_splittable_3 (" type1 ", " type2 ", " type3 )
.RB .
.TP
(4)
Push the arguments on to the list in order. Again there is a macro
for each simple built-in type, and the macros for structure and pointer
arguments require an extra type argument:
.LP
.BI "av_int (" alist ", " int_value );
.LP
.BI "av_double (" alist ", " double_value );
.LP
.BI "av_struct (" alist ", " struct_or_union_type ", " struct_value );
.LP
.BI "av_ptr (" alist ", " pointer_type ", " pointer_value );
.TP
(5)
Call the function, set the return value, and tidy up:
.LP
.BI "av_call (" alist );
.RE

.SH NOTES

(1) Functions whose first declaration is in Kernighan & Ritchie style (i.e.,
without a typed argument list) MUST use default K&R C expression promotions
(char and short to int, float to double) whether they are compiled by a K&R
or an ANSI compiler, because the true argument types may not be known at the
call point. Such functions typically back-convert their arguments to the 
declared types on function entry. (In fact, the only way to pass a true char,
short or float in K&R C is by an explicit cast: 
.B func((char)c,(float)f)
). 
Similarly, some K&R compilers (such as Sun cc on the sparc) actually
return a float as a double.

Hence, for arguments of functions declared in K&R style you should use
.B av_int(\|)
and
.B av_double(\|)
rather than 
.B av_char(\|),
.B av_short(\|)
or
.B av_float(\|).
If you use a K&R compiler, the avcall header files may be able to
detect this and define 
.B av_float(\|),
etc, appropriately, but with an ANSI compiler there is no way 
.I avcall
can know how a function was declared, so you have to correct the
argument types yourself.

(2) The explicit type arguments of the 
.B av_struct(\|) 
and 
.B av_ptr(\|) 
macros are typically used to calculate size, alignment, and passing
conventions.  This may not be sufficient for some machines with unusual
structure and pointer handling: in this case additional 
.B av_start_\c
.I type\c
.B (\|)
and 
.B av_\c
.I type\c
.B (\|)
macros may be defined.

(3) The macros
.BR av_start_longlong(\|) ,
.BR av_start_ulonglong(\|) ,
.B av_longlong(\|)
and
.B av_ulonglong(\|)
work only if the C compiler has a working
.B long long
64-bit integer type.

(4) The struct types used in
.B av_start_struct(\|)
and
.B av_struct(\|)
must only contain (signed or unsigned) int, long, long long or pointer fields.
Struct types containing (signed or unsigned) char, short, float, double or
other structs are not supported.

.SH SEE ALSO
.BR stdarg (3),
.BR varargs (3).

.SH BUGS

The current implementations have been tested on a selection of common
cases but there are probably still many bugs.

There are typically built-in limits on the size of the argument-list,
which may also include the size of any structure arguments.

The decision whether a struct is to be returned in registers or in memory
considers only the struct's size and alignment. This is inaccurate: for
example, gcc on m68k-next returns
.B "struct { char a,b,c; }"
in registers and
.B "struct { char a[3]; }"
in memory, although both types have the same size and the same alignment.

.SH NON-BUGS

All information is passed in CPU registers and the stack. The
.B avcall
package is therefore multithread-safe.

.SH PORTING AVCALL

Ports, bug-fixes, and suggestions are most welcome. The macros required
for argument pushing are pretty grungy, but it does seem to be possible
to port avcall to a range of machines. Ports to non-standard or
non-32-bit machines are especially welcome so we can sort the interface
out before it's too late.

Knowledge about argument passing conventions can be found in the gcc
source, file
.RI gcc-2.6.3/config/ cpu / cpu .h,
section "Stack layout; function entry, exit and calling."

Some of the grunge is usually handled by a C or assembly level glue
routine that actually pushes the arguments, calls the function and
unpacks any return value.
This is called __builtin_avcall(\|). A precompiled assembler version for
people without gcc is also made available. The routine should ideally
have flags for the passing conventions of other compilers.

Many of the current routines waste a lot of stack space and generally do
hairy things to stack frames - a bit more assembly code would probably
help things along quite a bit here.

.SH AUTHOR

Bill Triggs <Bill.Triggs@inrialpes.fr>. 

.SH ACKNOWLEDGEMENTS

Some initial ideas were stolen from the C interface to the Zelk
extensions to Oliver Laumann's Elk scheme interpreter by J.P.Lewis, NEC
C&C Research, <zilla@ccrl.nj.nec.com> (for Sun4 & SGI), and Roy
Featherstone's <roy@robots.oxford.ac.uk> personal C interface library
for Sun[34] & SGI.  I also looked at the machine-dependent parts of the
GCC and GDB distributions, and put the gcc asm(\|) extensions to good
use. Thanks guys!

This work was partly supported by EC-ESPRIT Basic Research Action SECOND.