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321 lines
14 KiB
TeX
321 lines
14 KiB
TeX
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One of the biggest challenges to getting started with embedded devices is that you
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just can't install a copy of Linux and expect to be able to compile a firmware.
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Even if you did remember to install a compiler and every development tool offered,
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you still wouldn't have the basic set of tools needed to produce a firmware image.
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The embedded device represents an entirely new hardware platform, which is
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incompatible with the hardware on your development machine, so in a process called
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cross compiling you need to produce a new compiler capable of generating code for
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your embedded platform, and then use it to compile a basic Linux distribution to
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run on your device.
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The process of creating a cross compiler can be tricky, it's not something that's
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regularly attempted and so the there's a certain amount of mystery and black magic
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associated with it. In many cases when you're dealing with embedded devices you'll
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be provided with a binary copy of a compiler and basic libraries rather than
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instructions for creating your own -- it's a time saving step but at the same time
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often means you'll be using a rather dated set. Likewise, it's also common to be
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provided with a patched copy of the Linux kernel from the board or chip vendor,
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but this is also dated and it can be difficult to spot exactly what has been
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changed to make the kernel run on the embedded platform.
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\subsection{Building an image}
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OpenWrt takes a different approach to building a firmware, downloading, patching
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and compiling everything from scratch, including the cross compiler. Or to put it
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in simpler terms, OpenWrt doesn't contain any executables or even sources, it's an
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automated system for downloading the sources, patching them to work with the given
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platform and compiling them correctly for the platform. What this means is that
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just by changing the template, you can change any step in the process.
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As an example, if a new kernel is released, a simple change to one of the Makefiles
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will download the latest kernel, patch it to run on the embedded platform and produce
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a new firmware image -- there's no work to be done trying to track down an unmodified
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copy of the existing kernel to see what changes had been made, the patches are
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already provided and the process ends up almost completely transparent. This doesn't
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just apply to the kernel, but to anything included with OpenWrt -- It's this one
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simple understated concept which is what allows OpenWrt to stay on the bleeding edge
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with the latest compilers, latest kernels and latest applications.
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So let's take a look at OpenWrt and see how this all works
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\subsubsection{Download openwrt}
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This article refers to the "Kamikaze" branch of OpenWrt, which can be downloaded via
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subversion using the following command:
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\begin{Verbatim}
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svn co https://svn.openwrt.org/openwrt/trunk kamikaze
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\end{Verbatim}
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Additionally, there's a trac interface on \href{https://dev.openwrt.org/}{https://dev.openwrt.org/}
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which can be used to monitor svn commits and browse the sources.
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\subsubsection{The directory structure}
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There are four key directories in the base:
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\begin{itemize}
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\item tools
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\item toolchain
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\item package
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\item target
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\end{itemize}
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\texttt{tools} and \texttt{toolchain} refer to common tools which will be
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used to build the firmware image and the compiler and c library.
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The result of this is three new directories, \texttt{tool\_build}, which is a temporary
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directory for building the target independent tools, \texttt{toolchain\_build\_\textit{<arch>}}
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which is used for building the toolchain for a specific architecture, and
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\texttt{staging\_dir\_\textit{<arch>}} where the resulting toolchain is installed.
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You won't need to do anything with the toolchain directory unless you intend to
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add a new version of one of the components above.
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\texttt{package} is for exactly that -- packages. In an OpenWrt firmware, almost everything
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is an \texttt{.ipk}, a software package which can be added to the firmware to provide new
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features or removed to save space.
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\texttt{target} refers to the embedded platform, this contains items which are specific to
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a specific embedded platform. Of particular interest here is the "\texttt{target/linux}"
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directory which is broken down by platform and contains the kernel config and patches
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to the kernel for a particular platform. There's also the "\texttt{target/image}" directory
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which describes how to package a firmware for a specific platform.
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Both the target and package steps will use the directory "\texttt{build\_\textit{<arch>}}"
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as a temporary directory for compiling. Additionally, anything downloaded by the toolchain,
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target or package steps will be placed in the "\texttt{dl}" directory.
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\subsubsection{Building OpenWrt}
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While the OpenWrt build environment was intended mostly for developers, it also has to be
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simple enough that an inexperienced end user can easily build his or her own customized firmware.
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Running the command "\texttt{make menuconfig}" will bring up OpenWrt's configuration menu
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screen, through this menu you can select which platform you're targeting, which versions of
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the toolchain you want to use to build and what packages you want to install into the
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firmware image. Similar to the linux kernel config, almost every option has three choices,
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\texttt{y/m/n} which are represented as follows:
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\begin{itemize}
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\item{\texttt{<*>} (pressing y)} \\
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This will be included in the firmware image
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\item{\texttt{<M>} (pressing m)} \\
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This will be compiled but not included (for later install)
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\item{\texttt{< >} (pressing n)} \\
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This will not be compiled
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\end{itemize}
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After you've finished with the menu configuration, exit and when prompted, save your
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configuration changes. To begin compiling the firmware, type "\texttt{make}". By default
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OpenWrt will only display a high level overview of the compile process and not each individual
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command.
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\subsubsection{Example:}
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\begin{Verbatim}
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make[2] toolchain/install
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make[3] -C toolchain install
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make[2] target/compile
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make[3] -C target compile
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make[4] -C target/utils prepare
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[...]
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\end{Verbatim}
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This makes it easier to monitor which step it's actually compiling and reduces the amount
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of noise caused by the compile output. To see the full output, run the command
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"\texttt{make V=99}".
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During the build process, buildroot will download all sources to the "\texttt{dl}"
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directory and will start patching and compiling them in the "\texttt{build\_\textit{<arch>}}"
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directory. When finished, the resulting firmware will be in the "\texttt{bin}" directory
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and packages will be in the "\texttt{bin/packages}" directory.
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\subsection{Creating packages}
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One of the things that we've attempted to do with OpenWrt's template system is make it
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incredibly easy to port software to OpenWrt. If you look at a typical package directory
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in OpenWrt you'll find two things:
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\begin{itemize}
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\item \texttt{package/\textit{<name>}/Makefile}
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\item \texttt{package/\textit{<name>}/patches}
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\end{itemize}
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The patches directory is optional and typically contains bug fixes or optimizations to
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reduce the size of the executable. The package makefile is the important item, provides
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the steps actually needed to download and compile the package.
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Looking at one of the package makefiles, you'd hardly recognize it as a makefile.
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Through what can only be described as blatant disregard and abuse of the traditional
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make format, the makefile has been transformed into an object oriented template which
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simplifies the entire ordeal.
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Here for example, is \texttt{package/bridge/Makefile}:
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\begin{Verbatim}[frame=single,numbers=left]
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include $(TOPDIR)/rules.mk
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PKG_NAME:=bridge
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PKG_VERSION:=1.0.6
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PKG_RELEASE:=1
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PKG_BUILD_DIR:=$(BUILD_DIR)/bridge-utils-$(PKG_VERSION)
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PKG_SOURCE:=bridge-utils-$(PKG_VERSION).tar.gz
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PKG_SOURCE_URL:=@SF/bridge
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PKG_MD5SUM:=9b7dc52656f5cbec846a7ba3299f73bd
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PKG_CAT:=zcat
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include $(INCLUDE_DIR)/package.mk
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define Package/bridge
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SECTION:=base
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CATEGORY:=Network
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DEFAULT:=y
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TITLE:=Ethernet bridging configuration utility
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URL:=http://bridge.sourceforge.net/
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endef
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define Package/bridge/description
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Ethernet bridging configuration utility
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Manage ethernet bridging; a way to connect networks together
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to form a larger network.
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endef
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define Build/Configure
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$(call Build/Configure/Default, \
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--with-linux-headers=$(LINUX_DIR))
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endef
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define Package/bridge/install
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install -m0755 -d $(1)/usr/sbin
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install -m0755 $(PKG_BUILD_DIR)/brctl/brctl \
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$(1)/usr/sbin/
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endef
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$(eval $(call BuildPackage,bridge))
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\end{Verbatim}
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As you can see, there's not much work to be done; everything is hidden in other makefiles
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and abstracted to the point where you only need to specify a few variables.
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\begin{itemize}
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\item \texttt{PKG\_NAME} \\
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The name of the package, as seen via menuconfig and ipkg
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\item \texttt{PKG\_VERSION} \\
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The upstream version number that we're downloading
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\item \texttt{PKG\_RELEASE} \\
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The version of this package Makefile
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\item \texttt{PKG\_BUILD\_DIR} \\
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Where to compile the package
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\item \texttt{PKG\_SOURCE} \\
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The filename of the original sources
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\item \texttt{PKG\_SOURCE\_URL} \\
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Where to download the sources from
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\item \texttt{PKG\_MD5SUM} \\
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A checksum to validate the download
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\item \texttt{PKG\_CAT} \\
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How to decompress the sources (zcat, bzcat, unzip)
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\end{itemize}
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The \texttt{PKG\_*} variables define where to download the package from;
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\texttt{@SF} is a special keyword for downloading packages from sourceforge.
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The md5sum is used to verify the package was downloaded correctly and
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\texttt{PKG\_BUILD\_DIR} defines where to find the package after the sources are
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uncompressed into \texttt{\$(BUILD\_DIR)}.
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At the bottom of the file is where the real magic happens, "BuildPackage" is a macro
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setup by the earlier include statements. BuildPackage only takes one argument directly --
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the name of the package to be built, in this case "\texttt{bridge}". All other information
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is taken from the define blocks. This is a way of providing a level of verbosity, it's
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inherently clear what the contents of the \texttt{description} template in
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\texttt{Package/bridge} is, which wouldn't be the case if we passed this information
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directly as the Nth argument to \texttt{BuildPackage}.
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\texttt{BuildPackage} uses the following defines:
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\textbf{\texttt{Package/\textit{<name>}}:} \\
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\texttt{\textit{<name>}} matches the argument passed to buildroot, this describes
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the package the menuconfig and ipkg entries. Within \texttt{Package/\textit{<name>}}
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you can define the following variables:
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\begin{itemize}
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\item \texttt{SECTION} \\
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The type of package (currently unused)
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\item \texttt{CATEGORY} \\
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Which menu it appears in menuconfig
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\item \texttt{TITLE} \\
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A short description of the package
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\item \texttt{URL} \\
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Where to find the original software
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\item \texttt{MAINTAINER} (optional) \\
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Who to contact concerning the package
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\item \texttt{DEPENDS} (optional) \\
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Which packages must be built/installed before this package
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\end{itemize}
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\textbf{\texttt{Package/\textit{<name>}/conffiles} (optional):} \\
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A list of config files installed by this package, one file per line.
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\textbf{\texttt{Build/Prepare} (optional):} \\
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A set of commands to unpack and patch the sources. You may safely leave this
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undefined.
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\textbf{\texttt{Build/Configure} (optional):} \\
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You can leave this undefined if the source doesn't use configure or has a
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normal config script, otherwise you can put your own commands here or use
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"\texttt{\$(call Build/Configure/Default,\textit{<args>})}" as above to
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pass in additional arguments for a standard configure script.
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\textbf{\texttt{Build/Compile} (optional):} \\
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How to compile the source; in most cases you should leave this undefined.
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\textbf{\texttt{Package/\textit{<name>}/install}:} \\
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A set of commands to copy files out of the compiled source and into the ipkg
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which is represented by the \texttt{\$(1)} directory.
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The reason that some of the defines are prefixed by "\texttt{Package/\textit{<name>}}"
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and others are simply "\texttt{Build}" is because of the possibility of generating
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multiple packages from a single source. OpenWrt works under the assumption of one
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source per package makefile, but you can split that source into as many packages as
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desired. Since you only need to compile the sources once, there's one global set of
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"\texttt{Build}" defines, but you can add as many "Package/<name>" defines as you want
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by adding extra calls to \texttt{BuildPackage} -- see the dropbear package for an example.
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After you've created your \texttt{package/\textit{<name>}/Makefile}, the new package
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will automatically show in the menu the next time you run "make menuconfig" and if selected
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will be built automatically the next time "\texttt{make}" is run.
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\subsubsection{Troubleshooting}
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If you find your package doesn't show up in menuconfig, try the following command to
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see if you get the correct description:
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\begin{Verbatim}
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TOPDIR=$PWD make -C package/<name> DUMP=1 V=99
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\end{Verbatim}
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If you're just having trouble getting your package to compile, there's a few
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shortcuts you can take. Instead of waiting for make to get to your package, you can
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run one of the following:
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\begin{itemize}
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\item \texttt{make package/\textit{<name>}-clean V=99}
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\item \texttt{make package/\textit{<name>}-install V=99}
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\end{itemize}
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Another nice trick is that if the source directory under \texttt{build\_\textit{<arch>}}
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is newer than the package directory, it won't clobber it by unpacking the sources again.
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If you were working on a patch you could simply edit the sources under the
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\texttt{build\_\textit{<arch>}/\textit{<source>}} directory and run the install command above,
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when satisfied, copy the patched sources elsewhere and diff them with the unpatched
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sources. A warning though - if you go modify anything under \texttt{package/\textit{<name>}}
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it will remove the old sources and unpack a fresh copy.
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