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9572c41d09
This is an attempt to work-around a couple of nasty bugs in librdbg's
Makefiles and configuration:
Configure and build RTEMS as below:
configure --enable-networking --enable-rdbg --target=i386-rtems
make RTEMS_BSP=i386ex
After a few minutes you will notice that building aborts in librdbg ....
Analysis:
1) librdbg is tried to be built, though librdbg is not supported and the
required directory hierarchy librdbg/i386/i386ex/ is not existant.
The cause for this is incorrect setting of HAS_RDBG in most
make/custom/*.cfg files (except pc386.cfg). At the moment all
custom/*.cfg files (except pc386.cfg) in general are required to contain
HAS_RDBG=no. However, having HAS_NETWORKING=no in most custom/*.cfg
files and the toplevel configure script suppress building librdbg for
all CPUs except of i386.
=> The i386ex BSP falls though this scheme and librdbg is tried to be
build (CPU=i386 and HAS_NETWORKING=yes).
2) The Makefile.ins below lib/librdbg in general support i386/pc386 only
and are not capable to be used for multiple CPUs or BSPs (RPCGEN
generates it's target and bsp-specific files into librdbg/, therefore no
other CPU or BSP can ever be built afterwards). This problem is hidden
until now, because only a single CPU/BSP pair (i386/pc386) is really
supported.
3) The Makefile.ins below lib/librdbg can delete source files due to
improper handling of source files (make clean removes the *.x files in
the source-tree when configuring inside of the source-tree).
The patch below tries to work-around these problems for the i386ex and
the pc386 BSPs. This work-around is rather fragile (it applies rpcgen
-D, I don't know how portable this is) and incomplete (all custom/*.cfg
except of pc386.cfg should contain HAS_RDBG=no), nevertheless it should
work.
#
# $Id$
#
Building RTEMS
==============
See the file README.configure.
Directory Overview
==================
This is the top level of the RTEMS directory structure. The following
is a description of the files and directories in this directory:
INSTALL
Rudimentary installation instructions. For more detailed
information please see the Release Notes. The Postscript
version of this manual can be found in the file
c_or_ada/doc/relnotes.tgz.
LICENSE
Required legalese.
README
This file.
c
This directory contains the source code for the C
implementation of RTEMS as well as the test suites, sample
applications, Board Support Packages, Device Drivers, and
support libraries.
doc
This directory contains the PDL for the RTEMS executive.
Ada versus C
============
There are two implementations of RTEMS in this source tree --
in Ada and in C. These two implementations are functionally
and structurally equivalent. The C implementation follows
the packaging conventions and hiearchical nature of the Ada
implementation. In addition, a style has been followed which
allows one to easily find the corresponding Ada and C
implementations.
File names in C and code placement was carefully designed to insure
a close mapping to the Ada implementation. The following file name
extensions are used:
.adb - Ada body
.ads - Ada specification
.adp - Ada body requiring preprocessing
.inc - include file for .adp files
.c - C body (non-inlined routines)
.inl - C body (inlined routines)
.h - C specification
In the executive source, XYZ.c and XYZ.inl correspond directly to a
single XYZ.adb or XYZ.adp file. A .h file corresponds directly to
the .ads file. There are only a handful of .inc files in the
Ada source and these are used to insure that the desired simple
inline textual expansion is performed. This avoids scoping and
calling convention side-effects in carefully constructed tests
which usually test context switch behavior.
In addition, in Ada code and data name references are always fully
qualified as PACKAGE.NAME. In C, this convention is followed
by having the package name as part of the name itself and using a
capital letter to indicate the presence of a "." level. So we have
PACKAGE.NAME in Ada and _Package_Name in C. The leading "_" in C
is used to avoid naming conflicts between RTEMS and user variables.
By using these conventions, one can easily compare the C and Ada
implementations.
The most noticeable difference between the C and Ada83 code is
the inability to easily obtain a "typed pointer" in Ada83.
Using the "&" operator in C yields a pointer with a specific type.
The 'Address attribute is the closest feature in Ada83. This
returns a System.Address and this must be coerced via Unchecked_Conversion
into an access type of the desired type. It is easy to view
System.Address as similar to a "void *" in C, but this is not the case.
A "void *" can be assigned to any other pointer type without an
explicit conversion.
The solution adopted to this problem was to provide two routines for
each access type in the Ada implementation -- one to convert from
System.Address to the access type and another to go the opposite
direction. This results in code which accomplishes the same thing
as the corresponding C but it is easier to get lost in the clutter
of the apparent subprogram invocations than the "less bulky"
C equivalent.
A related difference is the types which are only in Ada which are used
for pointers to arrays. These types do not exist and are not needed
in the C implementation.