Bering-uClibc 4.x - Developer Guide - Compiling Source Code

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Compiling Source Code
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Introduction

What is buildtool?

Buildtool is a set of Perl scripts and Perl modules to build LRP files (LEAF Packages) from source. Everything in the build process is automated, from extracting the sources and applying patches to configuring and building the source and creating the LRP Package.

Why bother?

In very early LEAF releases it was usual to compile the sources and build the Packages manually. This could be error-prone, and where upstream source upgrades happened regularly it was tedious to have to repeat builds for new versions manually.

The current practice is for every Package to be generated automatically according to simple configuration definitions. This means that no special knowledge is required to re-build a particular Package, because all of the steps are captured in the configuration files. Some effort is required to prepare the initial buildtool configuration but many Packages are fairly "standard" and it is often possible to adapt the configuration from a similar package quite quickly.


Buildtool usage

Options

usage: ./buildtool.pl command [pkgname]|[srcname] [...]

commands:
describe [pkgname]|[srcname]      shows description lines of package
[-f] source [pkgname]|[srcname]   downloads, unpacks and patches
                                  the wanted package/source
[-f] build [pkgname]|[srcname]    the same as source, but builds
                                  and installs sources/packages also
[-f] clean [pkgname]|[srcname]    make a 'make clean' in srcdir
[-f] dlclean [pkgname]|[srcname]  remove everything from dldir
[-f] srcclean [pkgname]|[srcname] make a 'make srcclean' in srcdir
distclean                         remove everything
maketar                           make a tar for distribution

The -f switch allows you to force building sourcing and cleaning
even if it seems the packages/sources are already installed or cleaned.

Getting information about the sources that can be built

Buildtool can only build sources/packages that it has a configuration for (see the next section on how to create such a configuration). To get a listing of the sources that are configured for buildtool type:

 ./buildtool.pl describe

This will give you a list (and a short description) of all sources/packages that can be built. An example output looks like this:

 ./buildtool.pl describe

 The following packages and sources are available:

 Sources:
 ---------------------------------------------------------
 openssh          openssh
 tcp_wrappers     Wietse Venema's TCP wrappers library
 helloworld       classical example
 openssl          Secure Sockets Layer and cryptography
                  libraries and tools
 zlib             zLib shared libraries
 linux            kernel source only package

 Packages:
 ---------------------------------------------------------
 buildenv         this holds everything to build cross build env
 kernel           kernel pseudo package

The difference between sources and packages

You might be a bit confused why in the above output there are Sources and Packages. The main reason for having sources and packages separately is that there are some sources out there that produce programs used in several packages. Or in other words, it sometimes makes sense to just build the sources (like util-linux for example) only once and create several packages out of the resulting binaries.

Downloading the sources for a package

Running

./buildtool.pl source somepackageName

will cause the sources of somepackageName to be "downloaded" (and before that, all its dependencies, if there are any that haven't been downloaded yet). Most of the upstream sources are now copied into the Bering-uClibc 4.x Git repository, since this avoids problems when upstream download sites go off-line and makes it easier to distribute copies of all the source code as required for compliance with some Open Source licenses. As a result, these sources are "downloaded" (from the Internet) when the Sourceforge-hosted Git repository is "cloned", but an important further step is to create symbolic links to the "local repository" (directory repo/) from the source/ directory, so this is what now happens when sources are "downloaded". In a few cases the sources are actually downloaded during this step, taken from the master upstream repository.

After that, the makefile buildtool.mk for this source is executed for target source. This has the effect that the sources will be extracted, and patches (if there are any) are applied.

If all this is completed without error, the sources of somepackageName are ready to be compiled.

Compiling the sources for a package

Running

./buildtool.pl build somepackageName

will cause buildtool to actually compile the source and install it to the build/ directory (and all its dependencies). After this is completed successfully, all binaries required for the lrp package (linked against uClibc) reside in the build/ directory.


Creating buildtool sources/packages

Overview

For each package, 3 files control how it's built:

conf/sources.cfg
Defines the servers that the config files for the packages are downloaded from, and the packages/sources themselves as well as the dependencies of a given package. All other files that are part of a package and should be downloaded from somewhere have to be explicitly named in the buildtool.cfg which is specific to the package. The file conf/sources.cfg is the same for all packages/sources, and you can find it in the conf/ subdir in your Buildtool root directory.
New with Bering-uClibc 4.x is conf/sources.local which is "included" at the end of conf/sources.cfg and is used to define local sources/packages, typically those being developed and debugged and not yet ready to be loaded into the master repository.
buildtool.cfg
(package specific - will be downloaded with the information from conf/sources.cfg). Defines where to get the sources/patches and also has the definitions for the package itself (used by buildpacket).
buildtool.mk
(package specific - will be downloaded with the information from buildtool.cfg). Makefile for actually building the sources.

Step by step guide to creating a simple config

This section should give you a quick glance at how the configuration for a specific source is created (but it won't show the hours of fighting with some source because it refuses to build - you will experience that soon enough when you create your own package. I don't want to discourage you, but cross-compiling often is more difficult than building on the target system). For a more complete overview, please see the following sections of this chapter.

For this exercise, we will create a package called hdsupp.lrp, which contains utilities for preparing a harddisk or Compact Flash disk for running under Bering uClibc. This package will contain fdisk, syslinux and mkfs.msdos.

Because there is no combined tarball for syslinux, fdisk and mkfs.msdos, we will have to create 3 different source definitions for buildtool. We will start with syslinux, since that is the easiest one.

By the time you read this, hdsupp will already be part of the buildtool checkout. This means that the settings for syslinux, util-linux and dosfstools in conf/sources.cfg will already be there. You can decide to either just skip that section, or (for the sake of learning something) delete that part of conf/sources.cfg and enter the information again manually. The following sections will assume that buildtool knows nothing about syslinux, util-linux and dosfstools.

Creating the source definition for syslinux, util-linux, dosfstools

First of all we need to edit conf/sources.cfg to contain a source definition for syslinux, util-linux, dosfstools.

<Source syslinux>
  Server = localrepo
  Directory = syslinux
  Description = Syslinux boot-loader plus an MBR
  <Requires>
    Name  = buildenv
  </Requires>
</Source>

<Source util-linux>
  Server = localrepo
  Directory = util-linux
  Description = provides fdisk and mkfs.minix
  <Requires>
    Name  = buildenv
  </Requires>
</Source>

<Source dosfstools>
  Server = localrepo
  Directory = dosfstools
  <Requires>
    Name  = buildenv
  </Requires>  Description = provides mkfs.dos
</Source>

For now, we'll just pretend that the buildtool.cfg file will be in the leaf Git repository. In this section, we will create everything needed for syslinux - the other sources will be taken care of later.

Next, we need to create a directory called syslinux in source. Doing

mkdir repo/syslinux

will do the job. This directory will contain buildtool.cfg, buildtool.mk and the syslinux sources.

Create a new file repo/syslinux/buildtool.cfg and enter the following information.

<File buildtool.mk>
  Server = localrepo
  Directory = syslinux
</File>

<File syslinux-4.03.tar.bz2>
  Server = localrepo
  envname = SOURCE_TGZ
</File>

The two server definitions tell buildtool which server it should download the files from. In almost every case it is "localrepo" which refers to your local copy of the Bering-uClibc 4.x Git repository. Next we define the file definitiones themselves.

Note the envname parameter - with this definition in the cfg-file, buildtool will set an environment variable (named SOURCE_TGZ in this case) containing the filename of the syslinux sources (syslinux-4.03.tar.bz2 in our example). This saves us from having to hardcode any version-specific information into the makefile. Specifying envname is not mandatory, but it keeps things simple for upgrading to a new version of a source.


Creating the makefile for syslinux

Obviously, this guide will not be able to teach you how to write makefiles, or what to do when there are errors during build. We'll simply focus on creating a makefile that produces the binaries and conforms to what buildtool expects.

Create a new file source/syslinux/buildtool.mk and enter the following contents:

 #############################################################
 #
 # buildtool makefile for syslinux
 #
 #############################################################

 include $(MASTERMAKEFILE)
 
 SOURCE_DIR:=$(shell $(BT_TGZ_GETDIRNAME) $(SOURCE_TGZ) 2>/dev/null )
 ifeq ($(SOURCE_DIR),)
 SOURCE_DIR:=$(shell cat DIRNAME)
 endif
 TARGET_DIR:=$(BT_BUILD_DIR)/syslinux
 
 source:
   bzcat $(SOURCE_TGZ) |  tar -xvf -
   echo $(SOURCE_DIR) > DIRNAME
   -mkdir $(TARGET_DIR)

 build:
   export LANG=en_US  # Hack for Redhat 9
   export CC=$(TARGET_CC)
   $(MAKE) -C $(SOURCE_DIR) syslinux
   -$(BT_STRIP) $(BT_STRIP_BINOPTS) $(SOURCE_DIR)/syslinux
   $(MAKE) -C $(SOURCE_DIR) INSTALLROOT=$(TARGET_DIR) install
   cp $(SOURCE_DIR)/mbr.bin $(TARGET_DIR)/usr/bin/mbr.bin
   mkdir -p $(BT_STAGING_DIR)/usr/bin
   -cp $(TARGET_DIR)/usr/bin/syslinux $(BT_STAGING_DIR)/usr/sbin/
   -cp $(TARGET_DIR)/usr/bin/mbr.bin $(BT_STAGING_DIR)/usr/sbin/

 clean:
   rm -rf $(TARGET_DIR)
   $(MAKE) -C $(SOURCE_DIR) clean

As with all makefiles, make sure that the delimiter in front of the commands (like $(MAKE) -C $(SOURCE_DIR) clean above) is a tab and not spaces.

Creating the source definition for fdisk

On Debian, fdisk (and also mkfs.minix, which we will use for the hdsupp package as well) is part of the util-linux package. So, we use the sources that are luckily already provided in the bering uClibc CVS (no need to pretend they're in CVS this time).

Create a directory source/util-linux/ and a new file source/util-linux/buildtool.cfg and enter the following information.

<Server cvs-sourceforge>
  Type = viewcvs
  Name = leaf.cvs.sourceforge.net
  Serverpath = /leaf/src/bering-uclibc/apps
</Server>

<File buildtool.mk>
  Server = cvs-sourceforge
  Revision = HEAD
  Directory = util-linux
</File>

<File util-linux_2.11n.orig.tar.gz>
  Server = cvs-sourceforge
  envname = UTIL_LINUX_SOURCE
</File>

<File util-linux_2.11n-4.diff.gz>So
  Server = cvs-sourceforge
  envname = UTIL_LINUX_PATCH1
</File>

The makefile for util-linux

As with syslinux, we need to create a makefile. This time the source target will also include applying a patch

 #############################################################
 #
 # util-linux
 #
 #############################################################

 include $(MASTERMAKEFILE)
 
 UTIL_LINUX_DIR:=$(shell $(BT_TGZ_GETDIRNAME) $(UTIL_LINUX_SOURCE) 2>/dev/null )
 ifeq ($(UTIL_LINUX_DIR),)
 UTIL_LINUX_DIR:=$(shell cat DIRNAME)
 endif
 
 UTIL_LINUX_TARGET_DIR:=$(BT_BUILD_DIR)/util-linux
 export CC=$(TARGET_CC)
 export CFLAGS=-I$(BT_STAGING_DIR)/include
 export LDFLAGS=-L$(BT_STAGING_DIR)/lib -L$(BT_STAGING_DIR)/usr/lib

 source:
   zcat $(UTIL_LINUX_SOURCE) |  tar -xvf -
   echo $(UTIL_LINUX_DIR) > DIRNAME
   zcat $(UTIL_LINUX_PATCH1) | patch -d $(UTIL_LINUX_DIR) -p1
   cd $(UTIL_LINUX_DIR) && ./configure
   perl -i -p -e 's,HAVE_SLANG=yes,HAVE_SLANG=no,' $(UTIL_LINUX_DIR)/MCONFIG
   perl -i -p -e 's,LIBSLANG=-lslang,LIBSLANG=,' $(UTIL_LINUX_DIR)/MCONFIG
   -mkdir $(UTIL_LINUX_TARGET_DIR)

 build:
   $(MAKE) CC=$(TARGET_CC) -C $(UTIL_LINUX_DIR) misc-utils
   $(MAKE) CC=$(TARGET_CC) -C $(UTIL_LINUX_DIR) disk-utils
   $(MAKE) CC=$(TARGET_CC) -C $(UTIL_LINUX_DIR) fdisk fdisk
   -$(BT_STRIP) $(BT_STRIP_BINOPTS) $(UTIL_LINUX_DIR)/fdisk/fdisk
   -$(BT_STRIP) $(BT_STRIP_BINOPTS) $(UTIL_LINUX_DIR)/disk-utils/mkfs.minix
   -cp $(UTIL_LINUX_DIR)/fdisk/fdisk $(UTIL_LINUX_TARGET_DIR)/
   -cp $(UTIL_LINUX_DIR)/disk-utils/mkfs.minix $(UTIL_LINUX_TARGET_DIR)/
   mkdir -p $(BT_STAGING_DIR)/sbin
   -cp $(UTIL_LINUX_DIR)/fdisk/fdisk $(BT_STAGING_DIR)/sbin/
   -cp $(UTIL_LINUX_DIR)/disk-utils/mkfs.minix $(BT_STAGING_DIR)/sbin/

 clean:
   rm -rf $(UTIL_LINUX_TARGET_DIR)
   $(MAKE) -C $(UTIL_LINUX_DIR) clean

This one shows where things get a bit trickier - for some reason, the configure-script that comes with util-linux insisted on building cfdisk (which needs ncurses). So, after running configure, we remove the definitions that cause this from MCONFIG (this is what the two calls to Perl do).

Source definition for dosfstools

Dosfstools provides mkfs.msdos. Again we need to create a directory for the sources/configs first. So, create a directory source/dosfstools and a new file source/dosfstools/buildtool.cfg with the following content:

<Server cvs-sourceforge>
  Type = viewcvs
  Name = leaf.cvs.sourceforge.net
  Serverpath = /leaf/src/bering-uclibc/apps
</Server>

<Server debian>
  Type = http
  Name = ftp.debian.org
  Serverpath = debian/pool/main/d/dosfstools
</Server>

<File buildtool.mk>
  Server = cvs-sourceforge
  Revision = HEAD
  Directory = dosfstools
</File>

<File dosfstools_2.9.orig.tar.gz>
  Server = debian
  envname = DOSFSTOOLS_SOURCE
</File>

<File dosfstools_2.9-1.diff.gz>
  Server = debian
  envname = DOSFSTOOLS_PATCH1
</File>

Pretty much like the definitions before. Don't let yourself be fooled - despite the name ftp.debian.org, we can access this server using the http protocol.

Makefile for dosfstools

As one would expect the makefile for dosfstools looks just like the other ones.

 #############################################################
 #
 # dosfstools
 #
 #############################################################

 include $(MASTERMAKEFILE)
 
 DOSFSTOOLS_DIR:=$(shell $(BT_TGZ_GETDIRNAME) $(DOSFSTOOLS_SOURCE) 2>/dev/null )
 ifeq ($(DOSFSTOOLS_DIR),)
 DOSFSTOOLS_DIR:=$(shell cat DIRNAME)
 endif
 
 DOSFSTOOLS_TARGET_DIR:=$(BT_BUILD_DIR)/dosfstools
 export CC=$(TARGET_CC)

 source:
   zcat $(DOSFSTOOLS_SOURCE) |  tar -xvf -
   echo $(DOSFSTOOLS_DIR) > DIRNAME
   zcat $(DOSFSTOOLS_PATCH1) | patch -d $(DOSFSTOOLS_DIR) -p1
   perl -i -p -e 's,CC\s*=\s*gcc,#CC = gcc,' $(DOSFSTOOLS_DIR)/Makefile
   perl -i -p -e 's,PREFIX\s*=.*,PREFIX=$(DOSFSTOOLS_TARGET_DIR),' \
     $(DOSFSTOOLS_DIR)/Makefile
   -mkdir $(DOSFSTOOLS_TARGET_DIR)

 build:
   export PREFIX=$(DOSFSTOOLS_TARGET_DIR)
   $(MAKE) CC=$(TARGET_CC) -C $(DOSFSTOOLS_DIR)
   $(MAKE) CC=$(TARGET_CC) -C $(DOSFSTOOLS_DIR) install
   -$(BT_STRIP) $(BT_STRIP_BINOPTS) $(DOSFSTOOLS_TARGET_DIR)/sbin/mkdosfs
   mkdir -p $(BT_STAGING_DIR)/sbin
   -cp $(DOSFSTOOLS_TARGET_DIR)/sbin/mkfs.msdos $(BT_STAGING_DIR)/sbin/

 clean:
   rm -rf $(DOSFSTOOLS_TARGET_DIR)
   $(MAKE) -C $(DOSFSTOOLS_DIR) clean

Finishing up hdsupp

Finally - almost there. Hdsupp will be a "wrapper package" - it doesn't really compile anything, it just makes sure that all sources it needs have been compiled, copies the binaries to the staging dir (this part could also be done in the individual .mk files) and creates the lrp package.

In the beginning of this guide, we haven't added a definition for hdsupp to conf/sources.cfg. We'll change that now. Hdsupp is special, since one of its functions is to make sure all of the sources have been compiled already - it has dependencies. In buildtool, we use the required tag to indicate dependencies. This tag lists all sources that must be built before hdsupp can be built. Notice that hdsupp is not specified as a source, but as a package (at this point, it makes no difference to buildtool, but it most likely will in the future - only packages will be able to produce lrp-files).

So, enter the following to conf/sources.cfg:

<Package hdsupp>
  Server = cvs-sourceforge
  Revision = HEAD
  Directory = hdsupp
  Description = Package providing tools for harddrives/CF disks
  <Requires>
    Name = syslinux
    Name = util-linux
    Name = dosfstools
  </Requires>
</Package>
Hdsupp package definition

As before we need to create a directory for hdsupp containing buildtool.cfg and buildtool.mk. Create a new directory source/hdsupp, a file buildtool.cfg and enter the following information to buildtool.cfg:

<Server cvs-sourceforge>
  Type = viewcvs
  Name = leaf.cvs.sourceforge.net
  Serverpath = /leaf/src/bering-uclibc/apps
</Server>

<File buildtool.mk>
  Server = cvs-sourceforge
  Revision = HEAD
  Directory = hdsupp
</File>

As you can see, this one is extremely simple. Since hdsupp doesn't provide any sources, we only need to specify buildtool.mk.

This is not all we need to add here - there's more to get buildpacket to work. But this will be taken care of in the "Step by step" section of the buildpacket chapter. (TODO add link)

Hdsupp makefile

You may be wondering why we need a makefile at all, since hdsupp does not provide any sources. You are right - we don't need a makefile. But to keep buildtool happy (and to make sure that buildpacket can verify that hdsupp has actually been built), we will provide one that simply does nothing.

As before, create a new file called buildtool.mk in sources/hdsupp and enter the following contents:

 #############################################################
 #
 # hdsupp
 #
 #############################################################

 include $(MASTERMAKEFILE)

 source:
   # nothing to be done

 build:
   # nothing to be done

 clean:
   # nothing to be done

That's it. You can now enter ./buildtool.pl build hdsupp and (hopefully) buildtool will download and compile everything needed. If something goes wrong, have a look at the buildtool-logfile (usually the error-messages are pretty clear about what's wrong).

Buildtool reference

conf/sources.cfg

In this file you need to set two definitions - first, the server from which buildtool.cfg gets downloaded.

Sample:

<Server hejl>
  Type = http
  Name = lrp.hejl.de
  Serverpath = /devel
</Server>
<Package openssh>
  Server = hejl
  Directory = openssh
  Description = OpenSSH (ssh, sshd, ssh-key, sftp)
  <Requires>
    Name = openssl
    Name = zlib
    Name = tcp_wrappers
  </Requires>
</Package>

The server section specifies that buildtool will use the url http://lrp.hejl.de/devel as a base to download the config for the package. This url consists of two parts: The Name of the server and the serverpath which will be appended to the servername. Don't use an url here, since the protocol section of the url will be automatically added by buildtool (depending on what is specified as "Type").

Possible entries in the Server section are:

Type
The type of the server (Currently, the supported download types are: http, ftp, viewcvs and file).
Name
The name of the server (only for http, ftp and viewcvs.) without any leading protocol (like http://). Note if you use viewvcs.cgi you have to add here the pathname of the cgi script (leaf.cvs.sourceforge.net for example)
Serverpath
The directory/pathname that comes after the servername (will be added there by buildtool). In case of a viewcvs server it will be added after the *checkout* that will be appended to the server's Name (*checkout* is needed to tell viewcvs to really download a file). You should not use http for files that are downloaded via viewcvs - even though this is possible, buildtool tries to fetch the correct version, even if there already is a newer version of the file in the repository (in that case, the download via http would fail). For type "File" this should contain a relative path to the file. This really only makes sense for files that are part of the CVS checkout.

Possible entries in the package/source section are:

Server
The name of the server to use (has to be defined as server in the server section, see above).
Directory
This is an additional directory name that will be appended to the serverpath. This makes it possible to define just one server for downloads from multiple directories.
Description
The string that is shown when entering ./buildtool.pl describe
Requires
The Requires section should contain a list of package names that must be built before building this package. The entries in here are put in line by line starting with the keyword Name.

The package section specifies which server to use (there has to be a corresponding server section) and which directory to download the config files from. So, in this example, buildtool.cfg for the package openssh will be downloaded from http://lrp.hejl.de/devel/openssh (this is defined by the url from the server section plus the directory defined by the package definition.

The requires section in this example defines that, before trying to build openssh, buildtool must build openssl, zlib and tcp_wrappers (and whatever packages they require).

buildtool.cfg

Contains two main sections. First of all the server and file specifications used for downloading the sources, and the package specification (which will be used by buildpacket). See the documentation on buildpacket for the package specification.

Example:

<Server hejl>
  Type = http
  Name = lrp.hejl.de
  Serverpath = /devel
</Server>
<Server debian>
  Type = http
  Name = ftp.debian.org
  Serverpath = /debian/openssh
</Server>
<File buildtool.mk>
  Server = hejl
  Directory = openssh
</File>
<File openssh_3.6.1p1.orig.tar.gz>
  Server = debian
  envname = OPENSSH_SOURCE
</File>

<File openssh_3.6.1p2-2.diff.gz>
  Server = debian
  envname = OPENSSH_PATCH2
</File>

The server section follows the same rules as in conf/sources.cfg. At this point, all servers that are referenced by a file section, need to be defined in this file (even if they have already been defined in conf/sources.cfg). This may change in the future, so that servers need to be defined only once.

Each file section defines a file to download. These usually are source archives and patches. The url to download the file is serverURL/Directory/File-section-name. In our example, the three files that will be downloaded are: http://lrp.hejl.de/devel/openssh/buildtool.mk http://ftp.debian.org/debian/openssh/openssh_3.6.1p1.orig.tar.gz and http://ftp.debian.org/debian/openssh/openssh_3.6.1p2-2.diff.gz

For patches, you can use the envname option. The effect of this option is that the value given with this option will be used as an environment variable, containing the name of the patch-file (this way, if a new patch comes out, replacing an old one, the -mk file doesn't need to be changed).

buildtool.mk

buildtool.mk is the makefile that will be used to extract the source archive, apply the patches and compile the source. It must include the "mastermakefile" make/MasterInclude.mk. Luckily, the environment variable MASTERMAKEFILE contains the file name of this file (including the full path). In short, every buildtool.mk file should start with:

include $(MASTERMAKEFILE)
targets

The following targets need to be defined in each mk-file (these are the ones that are called by buildtool - of course you are free to define additional ones you need for building the source).

source

Should extract the source tarball, apply patches and run configure (if applicable).

An example mk file follows here:

# example makefile for buildroot
 # include the master settings (like BUILD_DIR, ARCH...).
 include $(MASTERMAKEFILE)

 MYSRC_DIR=example-1.1.1
 MYINSTALL_DIR=$(BT_BUILD_DIR)/example

 # MYEXAMPLE_PATCH2 is set via the buildtool.cfg entry

 .source:
         tar xvzf example.src.tgz
         (cd $(MYSRC_DIR) ; patch -p1 < ../example-1.patch ;\
         patch -p1 < $(MYEXAMPLE_PATCH2)
         touch .source
 source: .source

 .configure:
         (cd $(MYSRC_DIR) ; ./configure --PREFIX=/usr \
         --SYSCONFDIR=/etc \
         --enable-example )
         touch .configure

 .build: .configure
         (cd $(MYSRC_DIR) ; make all CC=$(TARGET_CC) LD=$(TARGET_LD) )
         (cd $(MYSRC_DIR) ; make install INSTALL_PREFIX=$(MYINSTALL_DIR))
         touch .build
 build: .build

 clean:
         make -C $(MYSRC_DIR) clean
         rm .build
         rm .configure

 srcclean: clean
         rm -rf $(MYSRC_DIR)
         rm .source

The reason for the dot-entries in this file is: you might have problems if you try to apply a patch a second time to an already patched source. Although this should normally not happen, if you are working on a package to include into buildtool, it often does. The trick with the dot-files prevents this (as long as the .source file is there, the source won't be unpacked again. If you want the source to be upacked/patched , make a ./buildtool.pl srcclean PACKAGENAME).

build

Should build the sources and install the binaries (to the directory defined by the BT_BUILD_DIR environment variable).

clean

This should clean up all files created during the compile

Environment variables

The following environment variables are defined when the mk file is run

BT_BUILDROOT
root dir of buildtool (where buildtool.pl resides)
BT_SOURCE_DIR
where the sources are
BT_BUILD_DIR/BT_BUILDDIR
the directory where the binaries (from sources or packages) get installed to
BT_STAGING_DIR
the directory where the binaries for the toolchaing get installed to
BT_LINUX_DIR
directory of the linux kernel
BT_PACKAGE_DIR
where to put finished packages
BT_PATCHTOOL
path to patchtool
BT_DPATCH
path to dpatch
BT_KERNEL_RELEASE
contains the kernel release if the file (BT_SOURCE_DIR)/linux/linux/include/linux/version.h exists, otherwise this variable is empty.
GNU_TARGET_NAME
something like i386-linux
GNU_HOST_NAME
something like i386-linux
TARGET_CC
compiler to use for compiling the binaries
TARGET_LD
linker to use for linking against uClibc
BT_STRIP
strip program to use for stripping binaries
BT_STRIP_LIBOPTS
strip options to use for stripping library files
BT_STRIP_BINOPTS
strip options to use for stripping executables
HOSTCC
host compiler to use to compile the first stage of the toolchain. If your default host gcc is version 4.x, you'll need to adjust that setting. See below for more info.

Directory structure

A short overview of the subdirectories you find when you checked out buildtool and have the buildenv finished:

build
This is the place where sources can install their files (something you normally do with a make install DESTDIR=someDir. From here you can take the files to build the packages. Use a subdir for every package.
buildtool
Internal directory , contains the perl modules/classes.
conf
Global Config files are in here (sources.cfg, buildtools.cfg, installed)
doc
you can find some documentation in here.
log
should contain at least one file: buildtoollog, which has all the messages in it you don't want to see on your terminal. Useful for debugging.
make
The place for the MasterMakefile which should be included by every other makefile.
package
In here the actual packages are built. Every package has its own subdir (openssl for example) in which the unpacked package can be found. The packed packages are stored in the package dir as archives (like openssl.lrp).
source
all sources are here. Sources means downloaded files as well as the unpacked and compiled source (which should install its files to the build directory described above, and maybe to the staging directory from there. One subdir for every source.
staging
This directory is primarily for internal use. The uclibc toolchain , the cross-compiler and all libraries are installed here.
tools
you will find some tools in here , like upx for compressing the kernel and (maybe) additional scripts.


Buildtool Tips and FAQ

What you find here

In this chapter you can find a collection of common problems you may run into if you are trying to compile applications with buildtool.

undefined reference to '__libc_start_main'

The Problem

This may occur if you use a Makefile that uses a $(CC) variable to compile stuff and you have not defined CC. It seems that in this case make uses the wrong compiler or libraries. I ran into the problem while trying to compile an application via compileShell.

Solution

add a CC=gcc when calling make , e.g.

  make all CC=gcc

and everything should work fine



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