forked from Imagelibrary/rtems
eb299afca2
to move RTEMS more to automake/autoconf and GNU compliance.
Finally, here they are: the "big-patch" patches - merged into one big
patch (~1.5MB).
Sorry for the delay, but testing took much more time than I had expected
- esp. reworking the acpolish script triggered many more tiny issues
than I had expected (cf. below).
At least, now you've got something to spend your weekend with :-.
WARNINGS:
* I've gone a little (??) further than I had announced before.
* Several directories have been moved.
* Several files have been added and removed
* I have tested it with many BSPs/CPUs and a variety of permutiations of
configuration flags, but not with all.
* Most parts of the patch are automatically generated, however there are
many tiny manual modifications.
APPLYING THE PATCH:
./autogen -c
mkdir tools
mv c/src/exec/score/tools tools/cpu
mv c/build-tools tools/build
mv c/update-tools tools/update
patch -p1 -E < rtems-rc-19990709-0.diff
./autogen
If the patch doesn't apply to rtems-cvs, I would suggest that you should
try to apply it brute-force and then to run tools/update/rtems-polish.sh
-ac -am afterwards. A recursive diff between rtems-19990709 + patch and
rtems-cvs + patch then should report only a few dozen significant
changes to configuration files which need to be merged manually (IIRC, I
did not change any source files).
*** Attention: There are files to be removed, moved, copied and added
in/to CVS!
NEWS/CHANGES:
1. Configuration takes place in 3 stages: 1. per host (toplevel
configure script), 2. per target (c/configure), 3. per bsp
c/src/configure automatically triggered from ./configure and
c/Makefile.am.
2. Building of subdirectory c/ takes place in c/$(target_alias) for
cross-targets in c/ for native targets
3. Building of subdirectory c/src takes place in c/${target_alias}/<bsp>
for cross-targets, c/<bsp> for native targets
4. c/build-tools moved to tools/build
5. c/src/exec/score/cpu/tools moved to tools/cpu (=cpu-tools split out)
6. c/update-tools moved to tools/update
7. New subdirectory c/src/make, handles files from make/ on a per BSP
basis
8. Maintainer mode support: Ie. if configuring with
--enable-maintainer-mode disabled (the default), then tracking of many
dependencies will be disabled in Makefiles. Esp. many dependencies for
auto* generated files will be switched off in Makefiles. Ie. if not
using "--enable-maintainer-mode" many auto* generated files will not be
updated automatically, i.e. normal users should not be required to have
auto* tools anymore (untested).
9. Independent configuration scripts for / (toplevel), tools/build,
tools/cpu, tools/update, c/, c/src/, c/src/exec, c/src/lib, c/src/tests,
c/src/make
10. Automake support for all directories above and besides c/src
11. "preinstall" now is implemented as depth-first recursive make target
12. host compiled tools (exception bsp-tools) are accessed in location
in the build tree instead of inside the build-tree when building RTEMS.
13. RTEMS_ROOT and PROJECT_ROOT now point to directories inside the
build-tree - many tiny changes as consequence from this.
14. --with-cross-host support removed (offically announced obsolete by
cygnus)
15. Changing the order of building libraries below c/src/lib/
16. Former toplevel configure script broken into aclocal/*.m4 macros
17. Newlib now detected by configure macros, RTEMS_HAS_NEWLIB removed
from *cfg.
18. sptables.h now generated by autoconf
19. Rules for "mkinstalldirs temporary installation tree" moved from
c/Makefile to subdirectories.
20. Cpu-tools do not get installed.
21. FIX: Use ACLOCAL_AMFLAGS instead of ACLOCAL = -I ... in Makefile.ams
which are in directories with own configure scripts.
22. Hardcoding BSP names into libbsp/.../tools to avoid RTEMS_BSP get
overridden from the environment.
22. FIX: Handling of MP_PIECES in various Makefiles
23. FIX: Removing "::" rules from some Makefile.ins
24. FIX: File permission chaos: (-m 444 and -m 555 vs. -m 644 and -m
755) - Now all include files use -m 644.
25. Removed many gnumake-conditionals in Makefile.ins - Partially
replaced with automake-conditional, partially replaced with
conditionalized Makefile variables (... _yes_V)
26. Massively reworked acpolish: acpolish now parses Makefile.ins and
interprets parts of the Makefile.ins.
27. FIX: Some $(wildcard $(srcdir)/*.h) macros removed / replaced with
explicit lists of files in Makefile.ins.
28. FIX: Replacing MKLIB with RANLIB in Makefile.ins
29. HACK: Add preinstallation for pc386 specific
$(PROJECT_RELEASE)/BootImgs directory
... many more details, I can't recall
KNOWN BUGS:
1. make [debug|profile]_install do not do what they are promissing.
"make [debug|profile] install" does what "make [debug|profile]_install"
has been doing. Proposal: remove [debug|profile]_install
2. Dependencies between temporary installation tree and source tree are
not yet handled correctly.
3. Dependencies between temporary installation tree and source tree are
handled ineffencently (Using INSTALL_CHANGE instead of make
dependencies)
4. RTEMS_ROOT, PROJECT_ROOT, top_builddir, RTEMS_TOPdir now are
redundant.
5. The new configure scripts still are in their infancy. They contain
redundant checks and might still contain bugs, too.
6. RTEMS autoconf Makefile.ins use a mixture of configuration
information gathered in c/$(target_alias)/<bsp>/make and of information
collected from their configure scripts.
7. make dist is not fully functional
8. Subdirectory host-/build-/target- configure options (--target,
--host, --build) do not conform to Cygnus/GNU conventions.
9. Some RTEMS autoconf Makefile.in's makefile targets are not supported
in automake Makefile.ams/ins (e.g. get, clobber).
10. Some automake standard targets are not propagated from toplevel and
c/Makefile.am to autoconf subdirectories (eg. make dist).
11. rpcgen generated files are not part of the source-tree (Automake
conventions favor supplying generated files inside the source-tree,
however there is no support for rpcgen generated files in automake, cf.
yacc/lex support in automake).
12. RTEMS_HAS_RDBG handling is flaky. make/*.cfg use RTEMS_HAS_RDBG per
CPU, while librdb's sources can only be built per BSP. Raises the more
general question whether librdbg located correctly in the source-tree.
13. All make/*cfg files are configured per cpu, currently there is no
location to store per-bsp configuration information --> bsp.cfg, per
aconfig.h?
14. "make install" without having run "make all" beforehand does not
work.
15. handling of --enable-multiprocessing seems to be broken in
make/custom/*
16. Makefile.ins still exploit many gmake features.
17. File permisson chaos on libraries (no explict -m for
libraries/rels/etc).
18. mcp750 Makefiles are broken (Note: I *do* mean buggy - I am not
talking about "not-conforming to conventions", here :-).
19. Dependencies between configure scripts are not handled, eg. aborting
"make RTEMS_BSP=<bsp>" can leave the build-tree in an unusable state.
20. "make clean" does not delete <build-tree>/<bsp>. This is intentional
for now, because rerunning "make" after "make clean" requires an
explicit "make preinstall" afterwards now. This should be done
automatically, but doesn't work in this case for now. To work around
this problem <build-tree>/<bsp> is kept during "make clean" for now
(HACK).
TODO:
1. split out host-compiled bsp-tools
2. Use Cygnus/GNU standards for cross-compiling target-subdir
(CC=CC_FOR_TARGET .. configure --host=${target_alias}
--build=`config.guess'}), to be added to toplevel configure script after
splitting out bsp-tools.
3. Exploit per cpu support directory (c/src/<cpu>)- Splitting out
per-cpu libraries - Are there any?
4. Further automake support
5. Converting subdirectories into standalone / self-contained
subdirectories (Esp. moving their headers to the same common root as
their sources, eg. mv lib/include/rtems++
lib/librtems++/include/rtems++) - This is the main obstacle which
prevents moving further towards automake.
6. Propagating values from *.cfg into Makefiles instead of propagating
them at make time via Makefile-fragments (i.e. try to avoid using
*.cfg).
7. Testing on cygwin host (I *do* expect cygwin specific problems).
8. The ARCH in o-$(ARCH)-$(VARIANT) build-subdirectories is not needed
anymore.
GENERAL ISSUES:
1. Temporary installation tree -- Ian and I seem to disagree basically.
Though I think that I understand his argumentation, I do not share it.
IMO, his way of using the buildtree is mis-using the build-tree, relying
on an inofficial feature of RTEMS's current implementation, which
doesn't even work correctly in the current build-tree, though it
attempts hard to do so. From my very POV, it unnecessarily complicates
the structures of the source- and build-trees. It is not supported by
automake (No automatic generation for the necessary rules) and
complicates the transition to automake significantly (Generating the
rules with an enhanced version of acpolish could be possible).
As Ian correctly pointed out, here a management decision is needed -
though I don't see the need to draw this decision in short terms.
2. preinstallation generally is a sure means to spoil the structure of
the source tree, IMHO (No ranting intended, I am completly serious about
this one). eg. through tree dependencies. The worst problem related to
this I have found in the meantime is bsp_specs. bsp_specs is part of
libbsp, ie. there is *no* way to build *any* part of the source tree
*without* having a BSP *preinstalled*.
Note: This issue is related to issue 1., but is not identical - The
difference is the change of the order make rules have to be triggered.
While preinstallation triggers rules spread all over the source tree
before a "make all" can be run, a temporary installation tree could also
be installed by post "make all" hooks (all-local:, to be run after make
all in a directory is completed) if the directories' dependencies would
be a tree,
3. Stuctural dependencies between subdirectories.
4. Depth of the source tree (Prevents multilibbing and introduces many
unnecessary configure scripts).
5. per cpu vs. per bsp configuration (There are no real per-cpu parts
yets :-).
6. automake does not support $makefiles in AC_OUTPUT. Unlike before, we
now should try to avoid RTEMS_CHECK_MAKEFILE and to hard-code as much
paths to Makefiles as possible.
7. General redesign of the source tree
8. Main installation point - Changing it to ${prefix}/${target_alias}. ?
Besides item 8. (which is a must, IMHO), as far as I see most of them
can not be solved soon and will remain issues in the mid- to long-term
:-.
REMARKS:
* You (as the maintainer) should always use --enable-maintainer-mode
when building RTEMS to ensure that maintainer mode generated files (esp.
those in c/src/make) will be updated when make/* files have changed.
* Use @RTEMS_BSP@ in Makefile.ins and Makefile.ams below c/src/,
$(RTEMS_BSP) or ${RTEMS_BSP} will be overridden from environment
variables when using make RTEMS_BSP="....".
* c/src/make is a temporary cludge until configuration issues are
solved. At the moment it is configured per bsp, but contains
per-target/cpu info only. Its main purpose now is to circumvent
modifying make/*.cfg files, because I consider make/* to be frozen for
backward compatibilty.
* This patch should only affect configuration files. At least I do not
remember having touched any source files.
* To build the bare bsp you now need to mention it in --enable-rtemsbsp.
Example: building gensh1 and sh1/bare simultaneously:
../rtems-rc-19990709-1/configure --target=sh-rtems \
--enable-rtemsbsp="bare gensh1" \
--prefix=/tmp/rtems \
--enable-bare-cpu-cflags='-DMHZ=20 -m1
-DCPU_CONSOLE_DEVNAME=\"/dev/null\"' \
--enable-bare-cpu-model=sh7032 \
--enable-maintainer-mode \
--enable-cxx
make
make install
* The next steps in development would be to split out bsp-tools and then
to change to Cygnus/GNU canonicalization conventions for building the c/
subdirectory afterwards (i.e. many standard AC_*.m4 macros could be used
instead of customized versions)
FINAL REMARK:
The issues mentioned in the lists above sound much worser than the
situation actually is. Most of them are not specific to this patch, but
are also valid for the snapshot. I just wrote down what I came across
when working on the patch over the last few weeks.
I wouldn't be too surprised if you don't like the patch at the current
point in development. I am willing to discuss details and problems, I
also have no problem if you would post-pone applying this patch to times
after 4.1, but rejecting it as a whole for all times would be a false
management decision, IMHO.
Therefore I would suggest that you, if your time constaints allow it,
should at least play a little while with this patch to understand what
is going on and before drawing a decision on how to handle this
proposal. I know this patch is neither perfect nor complete, but I
consider it to be a major breakthrough. Don't be anxious because of the
size of the patch, the core of the patch is rather small, the size is
mainly the side effect of some systematic cleanups inside the Makefiles
(result of acpolish).
Feel free to ask if you encounter problems, if you don't understand
something or if you meet bugs - I am far from being perfect and am
prepared to answer them.
Ralf.
--
Ralf Corsepius
Forschungsinstitut fuer Anwendungsorientierte Wissensverarbeitung (FAW)
Helmholtzstr. 16, 89081 Ulm, Germany Tel: +49/731/501-8690
mailto:corsepiu@faw.uni-ulm.de FAX: +49/731/501-999
http://www.faw.uni-ulm.de
#
# $Id$
#
make/README
This file describes the layout and conventions of the make tree used in
the RTEMS software project and others.
All of these "make" trees are substantially similar; however this
file documents the current state of the rtems Makefile tree.
This make tree was developed originally to simplify porting projects
between various os's. The primary goals are:
. simple *and* customizable individual makefiles
. use widely available GNU make. There is no pre-processing or
automatic generation of Makefiles.
. Same makefiles work on *many* host os's due to portability
of GNU make and the host os config files.
. Support for different compilers and operating systems
on a per-user basis. Using the same sources (including
Makefiles) one developer can develop and test under SVR4,
another under 4.x, another under HPUX.
. Builtin support for compiling "variants" such as debug,
profile, and tcov versions. These variants can be built
recursively.
. Control of system dependencies. "hidden" dependencies on
environment variables (such as PATH)
have been removed whenever possible. No matter what your
PATH variable is set to, you should get the same thing
when you 'make' as everyone else on the project.
This description attempts to cover all aspects of the Makefile tree. Most
of what is described here is maintained automatically by the configuration
files.
The example makefiles in make/Templates should be used as a starting
point for new directories.
There are 2 main types of Makefile:
directory and leaf.
Directory Makefiles
-------------------
A Makefile in a source directory with sub-directories is called a
"directory" Makefile.
Directory Makefile's are simply responsible for acting as "middle-men"
and recursing into their sub-directories and propagating the make.
For example, directory src/bin will contain only a Makefile and
sub-directories. No actual source code will reside in the directory.
The following commands:
$ cd src/bin
$ make all
would descend into all the subdirectories of 'src/bin' and recursively
perform a 'make all'.
A 'make debug' will recurse thru sub-directories as a debug build.
A template directory Makefile which should work in almost all
cases is in make/Templates/Makefile.dir
Leaf Makefiles
--------------
Source directories that contain source code for libraries or
programs use a "leaf" Makefile.
These makefiles contain the rules necessary to build programs
(or libraries).
A template leaf Makefile is in Templates/Makefile.leaf . A template
leaf Makefile for building libraries is in Templates/Makefile.lib .
NOTE: To simplify nested makefile's and source maintenance, we disallow
combining source and directories (that make(1) would be expected to
recurse into) in one source directory. Ie., a directory in the source
tree may contain EITHER source files OR recursive sub directories, but NOT
both.
Variants (where objects go)
---------------------------
All binary targets are placed in a sub-directory whose name is (for
example):
o-force386/ -- binaries (no debug, no profile)
o-force386-debug/ -- debug binaries
o-force386-profile/ -- profiling binaries
Using the template Makefiles, this will all happen automatically.
Within a Makefile, the ${ARCH} variable is set to o-force386,
o-force386-debug, etc., as appropriate.
Typing 'make' will place objects in o-force386.
'make debug' will place objects in o-force386-debug.
'make profile' will place objects in o-force386-profile.
NOTE: For RTEMS work, the word 'force386' is the specified
RTEMS_BSP (specified in the modules file)
The debug and profile targets are equivalent to 'all' except that
CFLAGS and/or LDFLAGS are modified as per the compiler config file for
debug and profile support.
Targets debug_install and profile_install are equivalent to 'make
install' except that debug (or profile) variants are built and
installed.
The targets debug, profile, debug_install, profile_install, etc., can be
invoked recursively at the directory make level. So from the top of a
tree, one could install a debug version of everything under that point
by:
$ cd src/lib
$ gmake debug_install
When building a command that is linked with a generated library, the
appropriate version of the library will be linked in.
For example, the following fragments link the normal, debug, or
profile version of "libmine.a" as appropriate:
LDLIBS += $(LIBMINE)
LIBMINE = ../libmine/${ARCH}/libmine.a
${ARCH}/pgm: $(LIBMINE) ${OBJS}
$(LINK.c) -o $@ ${OBJS} $(LDLIBS)
If we do 'gmake debug', then the library in
../libmine/sparc-debug/libmine.a will be linked in. If $(LIBMINE)
might not exist (or might be out of date) at this point, we could add
${LIBMINE}: FORCEIT
cd ../libmine; ${MAKE} ${VARIANT_VA}
The above would generate the following command to build libmine.a:
cd ../libmine; gmake debug
The macro reference ${VARIANT_VA} converts ${ARCH} to the word 'debug'
(in this example) and thus ensures the proper version of the library
is built.
Targets
-------
All Makefile's support the following targets:
all -- make "everything"
install -- install "everything"
The following targets are provided automatically by
the included config files:
clean -- delete all targets
clobber -- 'clean' plus delete sccs'd files
lint -- run lint or lint-like tool
get -- "sccs get" all sources
depend -- build a make dependency file
"variant targets" -- special variants, see below
All directory Makefiles automatically propagate all these targets. If
you don't wish to support 'all' or 'install' in your source directory,
you must leave the rules section empty, as the parent directory Makefile
will attempt it on recursive make's.
Configuration
-------------
All the real work described here happens in file(s) included
from your Makefile.
All Makefiles include a customization file which is used to select
compiler and host operating system. The environment variable
RTEMS_CUSTOM must point to this file; eg:
/.../make/custom/force386.cfg
All leaf Makefile's also include either 'make/leaf.cfg' (or
'make/lib.cfg' for building libraries). These config files provide
default rules and set up the command macros as appropriate.
All directory Makefiles include 'make/directory.cfg'. directory.cfg
provides all the rules for recursing through sub directories.
The Makefile templates already perform these include's.
'make/leaf.cfg' (or directory.cfg) in turn includes:
a file specifying general purpose rules appropriate for
both leaf and directory makefiles.
( make/main.cfg )
personality modules specified by the customization file for:
compiler ( make/compilers/??.cfg )
private customization files
---------------------------
[ $(RTEMS_CUSTOM) ]
Your own private configuration file. Specifies which of the above
files you want to include.
Example: custom/force386.cfg
CONFIG.$(HOST_ARCH).OS = $(RTEMS_ROOT)/make/os/HPUX-9.0.cfg
# HOST Compiler config file
# You may also want to specify where the compiler resides here.
CC_$(HOST_ARCH)_DIR=/usr/local
CONFIG.$(HOST_ARCH).CC = $(RTEMS_ROOT)/make/compilers/gcc.cfg
## Target compiler config file, if any
CC_$(TARGET_ARCH)_DIR=$(RTEMS_GNUTOOLS)
CONFIG.$(TARGET_ARCH).CC = $(RTEMS_ROOT)/make/compilers/gcc-force386.cfg
generic rules file
------------------
[ make/main.cfg ]
included by leaf.cfg or directory.cfg.
This file contains some standard rules and variable assignments
that all Makefiles need.
It also includes the FORCEIT: pseudo target.
OS config file for host machine
-------------------------------
[ make/os/OS-NAME.cfg ]
included by main.cfg
Figures out the target architecture and specifies command names
for the OS tools including RCS/CVS (but NOT for the compiler tools).
Compiler configuration for the target
-------------------------------------
[ compilers/COMPILER-NAME.cfg ]
included by leaf.cfg
Specifies the names of tools for compiling programs.
Names in here should be fully qualified, and NOT depend on $PATH.
Also specifies compiler flags to be used to generate optimized,
debugging and profile versions, as well as rules to compile
assembly language and make makefile dependencies.
Configuration Variables
-----------------------
Variables you have to set in the environment or in your Makefile.
Note: the rtems module files set RTEMS_ROOT and RTEMS_CUSTOM
for you.
Environment Variables
---------------------
RTEMS_BSP -- name of your 'bsp' eg: force386
RTEMS_ROOT -- The root of your source tree.
All other file names are derived from this.
[ eg: % setenv RTEMS_ROOT $HOME/work/rtems ]
RTEMS_CUSTOM -- name of your config files in make/custom
Example:
$(RTEMS_ROOT)/make/custom/$(RTEMS_BSP).cfg
RTEMS_GNUTOOLS -- root of the gcc tools for the target
The value RTEMS_ROOT is used in the custom
files to generate the make(1) variables:
PROJECT_ROOT
PROJECT_RELEASE
PROJECT_TOOLS
etc., which are used within the make config files themselves.
(The files in make/*.cfg try to avoid use of word RTEMS so
they can be more easily shared by other projects)
Preset variables
----------------
Aside from command names set by the os and compiler config files,
a number of MAKE variables are automatically set and maintained by
the config files.
CONFIG.$(HOST_ARCH).CC
-- full path of C compilation config file, set by custom
config file.
PROJECT_RELEASE
-- release/install directory
[ $(PROJECT_ROOT) ]
PROJECT_BIN
-- directory for installed binaries
[ $(PROJECT_ROOT)/bin ]
PROJECT_TOOLS
-- directory for build environment commands
[ eg: $(PROJECT_ROOT)/build-tools ]
TARCH -- ${TARGET_ARCH}
[ eg: o-forc386 ]
obsolete and should not be referenced
ARCH -- target sub-directory for object code
[ eg: o-force386 or o-force386-debug ]
HOST_ARCH
-- host machine architecture name
[ eg: sun4, sparc on SVR4 ]
VARIANTS -- full list of all possible values for $(ARCH);
used mainly for 'make clean'
[ eg: "o-force386 o-force386-debug o-force386-profile" ]
VARIANT_VA -- Variant name.
Normally "", but for 'make debug' it is "debug",
for 'make profile', "profile, etc.
see make/leaf.cfg for more info.
Preset compilation variables
----------------------------
This is a list of some of the compilation variables.
Refer to the compiler config files for the complete list.
CFLAGS_OPTIMIZE_V -- value of optimize flag for compiler
[ eg: -O ]
CFLAGS_DEBUG_V -- value of debug flag for compiler
[ eg: -g ]
CFLAGS_PROFILE_V -- compiler profile flags
[ eg: -pg ]
CFLAGS_DEBUG_OPTIMIZE_V
-- optimize flag if compiling for debug
[ eg: "" ]
CFLAGS_DEBUG
CFLAGS_PROFILE
CFLAGS_OPTIMIZE -- current values for each depending
on make variant.
LDFLAGS_STATIC_LIBRARIES_V
-- ld option for static libraries
-Bstatic or -dy (svr4)
LDFLAGS_SHARED_LIBRARIES_V
-- ld option for dynamic libraries
-Bdynamic or -dn (svr4)
LIB_SOCKET
-- ld(1) -l option(s) to provide
socket support.
LIB_MATH -- ld(1) -l option(s) to provide
math library.
Makefile Variables
------------------
The following variables may be set in a typical Makefile.
C_PIECES -- File names of your .c files without '.c' suffix.
[ eg: C_PIECES=main funcs stuff ]
CC_PIECES -- ditto, except for .cc files
S_PIECES -- ditto, except for .S files.
LIB -- target library name in leaf library makefiles.
[ eg: LIB=${ARCH}/libmine.a ]
H_FILES -- your .h files in this directory.
[ eg: H_FILES=stuff.h extra.h ]
DEFINES -- cc -D items. Included in CPPFLAGS.
leaf Makefiles.
[ eg: DEFINES += -DUNIX ]
CPPFLAGS -- -I include directories.
leaf Makefiles.
[ eg: CPPFLAGS += -I../include ]
YFLAGS -- Yacc flags.
leaf Makefiles.
[ eg: YFLAGS += -v ]
LD_PATHS -- arguments to -L for ld.
Will be prefixed with '-L' or '-L ' as appropriate
and included in LDFLAGS.
LDFLAGS -- -L arguments to ld; more may be ADDed.
LD_LIBS -- libraries to be linked in.
[ eg: LDLIBS += ../libfoo/${ARCH}/libfoo.a ]
XCFLAGS -- "extra" CFLAGS for special needs. Pre-pended
to CFLAGS.
Not set or used by Makefiles.
Can be set on command line to pass extra flags
to the compiler.
XCPPFLAGS -- ditto for CPPFLAGS
Can be set on command line to pass extra flags
to the preprocessor.
XCCPPFLAGS -- same as XCPPFLAGS for C++.
XCCFLAGS -- same as XCFLAGS for C++.
SUB_DIRS -- list of sub directories for make recursion.
directory Makefiles only.
[ eg: SUB_DIRS=cpu bsp ]
CLEAN_ADDITIONS
-- list of files or directories that should
be deleted by 'make clean'
[ eg: CLEAN_ADDITIONS += y.tab.c ]
See 'leaf.cfg' for the 'clean:' rule and its
default deletions.
CLOBBER_ADDITIONS
-- list of files or directories that should
be deleted by 'make clobber'
Since 'make clobber' includes 'make clean',
you don't need to duplicate items in both.
TARGET_ARCH -- target architecture (eg: o-force386)
leaf makefiles only.
Should be specified before 'include leaf.cfg'.
Only needs to be specified if your target is
different from output of `arch`.
Command names
-------------
The following commands should only be called
as make variables:
MAKE,INSTALL,SHELL
ECHO,CAT,RM,CP,MV,LN,MKDIR,CHMOD
ED,SED
CC,CPP,AS,AR,LD,NM,SIZE,RANLIB,MKLIB,
YACC,LEX,LINT,CTAGS,ETAGS
Special Directory Makefile Targets
----------------------------------
all_WRAPUP
clean_WRAPUP
install_WRAPUP
clean_WRAPUP
clobber_WRAPUP
depend_WRAPUP
-- Specify additional commands for recursive
(directory level) targets.
This is handy in certain cases where you need
to do bit of work *after* a recursive make.
make/Templates
--------------
This directory contains Makefile and source file templates that
should help in creating or converting makefiles.
Makefile.leaf
Template leaf Makefiles.
Makefile.lib
Template leaf library Makefiles.
Makefile.dir
Template "directory" makefile.