597 lines
27 KiB
TeX
597 lines
27 KiB
TeX
\documentclass[a4paper,twocolumn]{article}
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\usepackage{abstract}
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\usepackage{xspace}
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\usepackage{amssymb}
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\usepackage{latexsym}
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\usepackage{tabularx}
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\usepackage[T1]{fontenc}
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\usepackage{calc}
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\usepackage{listings}
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\usepackage{color}
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\usepackage{url}
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\title{Device trees everywhere}
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\author{David Gibson \texttt{<{dwg}{@}{au1.ibm.com}>}\\
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Benjamin Herrenschmidt \texttt{<{benh}{@}{kernel.crashing.org}>}\\
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\emph{OzLabs, IBM Linux Technology Center}}
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\newcommand{\R}{\textsuperscript{\textregistered}\xspace}
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\newcommand{\tm}{\textsuperscript{\texttrademark}\xspace}
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\newcommand{\tge}{$\geqslant$}
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%\newcommand{\ditto}{\textquotedbl\xspace}
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\newcommand{\fixme}[1]{$\bigstar$\emph{\textbf{\large #1}}$\bigstar$\xspace}
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\newcommand{\ppc}{\mbox{PowerPC}\xspace}
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\newcommand{\of}{Open Firmware\xspace}
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\newcommand{\benh}{Ben Herrenschmidt\xspace}
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\newcommand{\kexec}{\texttt{kexec()}\xspace}
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\newcommand{\dtbeginnode}{\texttt{OF\_DT\_BEGIN\_NODE\xspace}}
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\newcommand{\dtendnode}{\texttt{OF\_DT\_END\_NODE\xspace}}
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\newcommand{\dtprop}{\texttt{OF\_DT\_PROP\xspace}}
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\newcommand{\dtend}{\texttt{OF\_DT\_END\xspace}}
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\newcommand{\dtc}{\texttt{dtc}\xspace}
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\newcommand{\phandle}{\texttt{linux,phandle}\xspace}
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\begin{document}
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\maketitle
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\begin{abstract}
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We present a method for booting a \ppc{}\R Linux\R kernel on an
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embedded machine. To do this, we supply the kernel with a compact
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flattened-tree representation of the system's hardware based on the
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device tree supplied by Open Firmware on IBM\R servers and Apple\R
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Power Macintosh\R machines.
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The ``blob'' representing the device tree can be created using \dtc
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--- the Device Tree Compiler --- that turns a simple text
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representation of the tree into the compact representation used by
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the kernel. The compiler can produce either a binary ``blob'' or an
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assembler file ready to be built into a firmware or bootwrapper
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image.
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This flattened-tree approach is now the only supported method of
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booting a \texttt{ppc64} kernel without Open Firmware, and we plan
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to make it the only supported method for all \texttt{powerpc}
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kernels in the future.
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\end{abstract}
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\section{Introduction}
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\subsection{OF and the device tree}
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Historically, ``everyday'' \ppc machines have booted with the help of
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\of (OF), a firmware environment defined by IEEE1275 \cite{IEEE1275}.
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Among other boot-time services, OF maintains a device tree that
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describes all of the system's hardware devices and how they're
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connected. During boot, before taking control of memory management,
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the Linux kernel uses OF calls to scan the device tree and transfer it
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to an internal representation that is used at run time to look up
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various device information.
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The device tree consists of nodes representing devices or
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buses\footnote{Well, mostly. There are a few special exceptions.}.
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Each node contains \emph{properties}, name--value pairs that give
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information about the device. The values are arbitrary byte strings,
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and for some properties, they contain tables or other structured
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information.
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\subsection{The bad old days}
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Embedded systems, by contrast, usually have a minimal firmware that
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might supply a few vital system parameters (size of RAM and the like),
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but nothing as detailed or complete as the OF device tree. This has
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meant that the various 32-bit \ppc embedded ports have required a
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variety of hacks spread across the kernel to deal with the lack of
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device tree. These vary from specialised boot wrappers to parse
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parameters (which are at least reasonably localised) to
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CONFIG-dependent hacks in drivers to override normal probe logic with
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hardcoded addresses for a particular board. As well as being ugly of
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itself, such CONFIG-dependent hacks make it hard to build a single
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kernel image that supports multiple embedded machines.
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Until relatively recently, the only 64-bit \ppc machines without OF
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were legacy (pre-POWER5\R) iSeries\R machines. iSeries machines often
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only have virtual IO devices, which makes it quite simple to work
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around the lack of a device tree. Even so, the lack means the iSeries
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boot sequence must be quite different from the pSeries or Macintosh,
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which is not ideal.
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The device tree also presents a problem for implementing \kexec. When
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the kernel boots, it takes over full control of the system from OF,
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even re-using OF's memory. So, when \kexec comes to boot another
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kernel, OF is no longer around for the second kernel to query.
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\section{The Flattened Tree}
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In May 2005 \benh implemented a new approach to handling the device
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tree that addresses all these problems. When booting on OF systems,
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the first thing the kernel runs is a small piece of code in
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\texttt{prom\_init.c}, which executes in the context of OF. This code
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walks the device tree using OF calls, and transcribes it into a
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compact, flattened format. The resulting device tree ``blob'' is then
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passed to the kernel proper, which eventually unflattens the tree into
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its runtime form. This blob is the only data communicated between the
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\texttt{prom\_init.c} bootstrap and the rest of the kernel.
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When OF isn't available, either because the machine doesn't have it at
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all or because \kexec has been used, the kernel instead starts
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directly from the entry point taking a flattened device tree. The
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device tree blob must be passed in from outside, rather than generated
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by part of the kernel from OF. For \kexec, the userland
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\texttt{kexec} tools build the blob from the runtime device tree
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before invoking the new kernel. For embedded systems the blob can
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come either from the embedded bootloader, or from a specialised
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version of the \texttt{zImage} wrapper for the system in question.
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\subsection{Properties of the flattened tree}
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The flattened tree format should be easy to handle, both for the
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kernel that parses it and the bootloader that generates it. In
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particular, the following properties are desirable:
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\begin{itemize}
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\item \emph{relocatable}: the bootloader or kernel should be able to
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move the blob around as a whole, without needing to parse or adjust
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its internals. In practice that means we must not use pointers
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within the blob.
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\item \emph{insert and delete}: sometimes the bootloader might want to
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make tweaks to the flattened tree, such as deleting or inserting a
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node (or whole subtree). It should be possible to do this without
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having to effectively regenerate the whole flattened tree. In
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practice this means limiting the use of internal offsets in the blob
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that need recalculation if a section is inserted or removed with
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\texttt{memmove()}.
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\item \emph{compact}: embedded systems are frequently short of
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resources, particularly RAM and flash memory space. Thus, the tree
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representation should be kept as small as conveniently possible.
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\end{itemize}
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\subsection{Format of the device tree blob}
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\label{sec:format}
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\begin{figure}[htb!]
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\centering
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\footnotesize
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\begin{tabular}{r|c|l}
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\multicolumn{1}{r}{\textbf{Offset}}& \multicolumn{1}{c}{\textbf{Contents}} \\\cline{2-2}
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\texttt{0x00} & \texttt{0xd00dfeed} & magic number \\\cline{2-2}
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\texttt{0x04} & \emph{totalsize} \\\cline{2-2}
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\texttt{0x08} & \emph{off\_struct} & \\\cline{2-2}
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\texttt{0x0C} & \emph{off\_strs} & \\\cline{2-2}
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\texttt{0x10} & \emph{off\_rsvmap} & \\\cline{2-2}
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\texttt{0x14} & \emph{version} \\\cline{2-2}
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\texttt{0x18} & \emph{last\_comp\_ver} & \\\cline{2-2}
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\texttt{0x1C} & \emph{boot\_cpu\_id} & \tge v2 only\\\cline{2-2}
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\texttt{0x20} & \emph{size\_strs} & \tge v3 only\\\cline{2-2}
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\multicolumn{1}{r}{\vdots} & \multicolumn{1}{c}{\vdots} & \\\cline{2-2}
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\emph{off\_rsvmap} & \emph{address0} & memory reserve \\
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+ \texttt{0x04} & ...& table \\\cline{2-2}
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+ \texttt{0x08} & \emph{len0} & \\
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+ \texttt{0x0C} & ...& \\\cline{2-2}
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\vdots & \multicolumn{1}{c|}{\vdots} & \\\cline{2-2}
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& \texttt{0x00000000}- & end marker\\
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& \texttt{00000000} & \\\cline{2-2}
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& \texttt{0x00000000}- & \\
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& \texttt{00000000} & \\\cline{2-2}
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\multicolumn{1}{r}{\vdots} & \multicolumn{1}{c}{\vdots} & \\\cline{2-2}
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\emph{off\_strs} & \texttt{'n' 'a' 'm' 'e'} & strings block \\
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+ \texttt{0x04} & \texttt{~0~ 'm' 'o' 'd'} & \\
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+ \texttt{0x08} & \texttt{'e' 'l' ~0~ \makebox[\widthof{~~~}]{\textrm{...}}} & \\
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\vdots & \multicolumn{1}{c|}{\vdots} & \\\cline{2-2}
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\multicolumn{1}{r}{+ \emph{size\_strs}} \\
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\multicolumn{1}{r}{\vdots} & \multicolumn{1}{c}{\vdots} & \\\cline{2-2}
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\emph{off\_struct} & \dtbeginnode & structure block \\\cline{2-2}
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+ \texttt{0x04} & \texttt{'/' ~0~ ~0~ ~0~} & root node\\\cline{2-2}
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+ \texttt{0x08} & \dtprop & \\\cline{2-2}
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+ \texttt{0x0C} & \texttt{0x00000005} & ``\texttt{model}''\\\cline{2-2}
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+ \texttt{0x10} & \texttt{0x00000008} & \\\cline{2-2}
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+ \texttt{0x14} & \texttt{'M' 'y' 'B' 'o'} & \\
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+ \texttt{0x18} & \texttt{'a' 'r' 'd' ~0~} & \\\cline{2-2}
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\vdots & \multicolumn{1}{c|}{\vdots} & \\\cline{2-2}
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& \texttt{\dtendnode} \\\cline{2-2}
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& \texttt{\dtend} \\\cline{2-2}
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\multicolumn{1}{r}{\vdots} & \multicolumn{1}{c}{\vdots} & \\\cline{2-2}
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\multicolumn{1}{r}{\emph{totalsize}} \\
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\end{tabular}
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\caption{Device tree blob layout}
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\label{fig:blob-layout}
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\end{figure}
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The format for the blob we devised, was first described on the
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\texttt{linuxppc64-dev} mailing list in \cite{noof1}. The format has
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since evolved through various revisions, and the current version is
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included as part of the \dtc (see \S\ref{sec:dtc}) git tree,
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\cite{dtcgit}.
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Figure \ref{fig:blob-layout} shows the layout of the blob of data
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containing the device tree. It has three sections of variable size:
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the \emph{memory reserve table}, the \emph{structure block} and the
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\emph{strings block}. A small header gives the blob's size and
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version and the locations of the three sections, plus a handful of
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vital parameters used during early boot.
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The memory reserve map section gives a list of regions of memory that
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the kernel must not use\footnote{Usually such ranges contain some data
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structure initialised by the firmware that must be preserved by the
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kernel.}. The list is represented as a simple array of (address,
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size) pairs of 64 bit values, terminated by a zero size entry. The
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strings block is similarly simple, consisting of a number of
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null-terminated strings appended together, which are referenced from
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the structure block as described below.
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The structure block contains the device tree proper. Each node is
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introduced with a 32-bit \dtbeginnode tag, followed by the node's name
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as a null-terminated string, padded to a 32-bit boundary. Then
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follows all of the properties of the node, each introduced with a
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\dtprop tag, then all of the node's subnodes, each introduced with
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their own \dtbeginnode tag. The node ends with an \dtendnode tag, and
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after the \dtendnode for the root node is an \dtend tag, indicating
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the end of the whole tree\footnote{This is redundant, but included for
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ease of parsing.}. The structure block starts with the \dtbeginnode
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introducing the description of the root node (named \texttt{/}).
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Each property, after the \dtprop, has a 32-bit value giving an offset
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from the beginning of the strings block at which the property name is
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stored. Because it's common for many nodes to have properties with
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the same name, this approach can substantially reduce the total size
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of the blob. The name offset is followed by the length of the
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property value (as a 32-bit value) and then the data itself padded to
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a 32-bit boundary.
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\subsection{Contents of the tree}
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\label{sec:treecontents}
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Having seen how to represent the device tree structure as a flattened
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blob, what actually goes into the tree? The short answer is ``the
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same as an OF tree''. On OF systems, the flattened tree is
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transcribed directly from the OF device tree, so for simplicity we
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also use OF conventions for the tree on other systems.
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In many cases a flat tree can be simpler than a typical OF provided
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device tree. The flattened tree need only provide those nodes and
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properties that the kernel actually requires; the flattened tree
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generally need not include devices that the kernel can probe itself.
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For example, an OF device tree would normally include nodes for each
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PCI device on the system. A flattened tree need only include nodes
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for the PCI host bridges; the kernel will scan the buses thus
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described to find the subsidiary devices. The device tree can include
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nodes for devices where the kernel needs extra information, though:
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for example, for ISA devices on a subsidiary PCI/ISA bridge, or for
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devices with unusual interrupt routing.
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Where they exist, we follow the IEEE1275 bindings that specify how to
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describe various buses in the device tree (for example,
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\cite{IEEE1275-pci} describe how to represent PCI devices). The
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standard has not been updated for a long time, however, and lacks
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bindings for many modern buses and devices. In particular, embedded
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specific devices such as the various System-on-Chip buses are not
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covered. We intend to create new bindings for such buses, in keeping
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with the general conventions of IEEE1275 (a simple such binding for a
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System-on-Chip bus was included in \cite{noof5} a revision of
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\cite{noof1}).
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One complication arises for representing ``phandles'' in the flattened
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tree. In OF, each node in the tree has an associated phandle, a
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32-bit integer that uniquely identifies the node\footnote{In practice
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usually implemented as a pointer or offset within OF memory.}. This
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handle is used by the various OF calls to query and traverse the tree.
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Sometimes phandles are also used within the tree to refer to other
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nodes in the tree. For example, devices that produce interrupts
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generally have an \texttt{interrupt-parent} property giving the
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phandle of the interrupt controller that handles interrupts from this
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device. Parsing these and other interrupt related properties allows
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the kernel to build a complete representation of the system's
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interrupt tree, which can be quite different from the tree of bus
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connections.
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In the flattened tree, a node's phandle is represented by a special
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\phandle property. When the kernel generates a flattened tree from
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OF, it adds a \phandle property to each node, containing the phandle
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retrieved from OF. When the tree is generated without OF, however,
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only nodes that are actually referred to by phandle need to have this
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property.
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Another complication arises because nodes in an OF tree have two
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names. First they have the ``unit name'', which is how the node is
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referred to in an OF path. The unit name generally consists of a
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device type followed by an \texttt{@} followed by a \emph{unit
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address}. For example \texttt{/memory@0} is the full path of a memory
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node at address 0, \texttt{/ht@0,f2000000/pci@1} is the path of a PCI
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bus node, which is under a HyperTransport\tm bus node. The form of
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the unit address is bus dependent, but is generally derived from the
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node's \texttt{reg} property. In addition, nodes have a property,
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\texttt{name}, whose value is usually equal to the first path of the
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unit name. For example, the nodes in the previous example would have
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\texttt{name} properties equal to \texttt{memory} and \texttt{pci},
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respectively. To save space in the blob, the current version of the
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flattened tree format only requires the unit names to be present.
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When the kernel unflattens the tree, it automatically generates a
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\texttt{name} property from the node's path name.
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\section{The Device Tree Compiler}
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\label{sec:dtc}
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\begin{figure}[htb!]
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\centering
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\begin{lstlisting}[frame=single,basicstyle=\footnotesize\ttfamily,
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tabsize=3,numbers=left,xleftmargin=2em]
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/memreserve/ 0x20000000-0x21FFFFFF;
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/ {
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model = "MyBoard";
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compatible = "MyBoardFamily";
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#address-cells = <2>;
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#size-cells = <2>;
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cpus {
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#address-cells = <1>;
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#size-cells = <0>;
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PowerPC,970@0 {
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device_type = "cpu";
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reg = <0>;
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clock-frequency = <5f5e1000>;
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timebase-frequency = <1FCA055>;
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linux,boot-cpu;
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i-cache-size = <10000>;
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d-cache-size = <8000>;
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};
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};
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memory@0 {
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device_type = "memory";
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memreg: reg = <00000000 00000000
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00000000 20000000>;
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};
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mpic@0x3fffdd08400 {
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/* Interrupt controller */
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/* ... */
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};
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pci@40000000000000 {
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/* PCI host bridge */
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/* ... */
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};
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chosen {
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bootargs = "root=/dev/sda2";
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linux,platform = <00000600>;
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interrupt-controller =
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< &/mpic@0x3fffdd08400 >;
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};
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};
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\end{lstlisting}
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\caption{Example \dtc source}
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\label{fig:dts}
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\end{figure}
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As we've seen, the flattened device tree format provides a convenient
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way of communicating device tree information to the kernel. It's
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simple for the kernel to parse, and simple for bootloaders to
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manipulate. On OF systems, it's easy to generate the flattened tree
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by walking the OF maintained tree. However, for embedded systems, the
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flattened tree must be generated from scratch.
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Embedded bootloaders are generally built for a particular board. So,
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it's usually possible to build the device tree blob at compile time
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and include it in the bootloader image. For minor revisions of the
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board, the bootloader can contain code to make the necessary tweaks to
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the tree before passing it to the booted kernel.
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The device trees for embedded boards are usually quite simple, and
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it's possible to hand construct the necessary blob by hand, but doing
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so is tedious. The ``device tree compiler'', \dtc{}\footnote{\dtc can
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be obtained from \cite{dtcgit}.}, is designed to make creating device
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tree blobs easier by converting a text representation of the tree
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into the necessary blob.
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\subsection{Input and output formats}
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As well as the normal mode of compiling a device tree blob from text
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source, \dtc can convert a device tree between a number of
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representations. It can take its input in one of three different
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formats:
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\begin{itemize}
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\item source, the normal case. The device tree is described in a text
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form, described in \S\ref{sec:dts}.
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\item blob (\texttt{dtb}), the flattened tree format described in
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\S\ref{sec:format}. This mode is useful for checking a pre-existing
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device tree blob.
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\item filesystem (\texttt{fs}), input is a directory tree in the
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layout of \texttt{/proc/device-tree} (roughly, a directory for each
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node in the device tree, a file for each property). This is useful
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for building a blob for the device tree in use by the currently
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running kernel.
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\end{itemize}
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In addition, \dtc can output the tree in one of three different
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formats:
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\begin{itemize}
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\item blob (\texttt{dtb}), as in \S\ref{sec:format}. The most
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straightforward use of \dtc is to compile from ``source'' to
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``blob'' format.
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\item source (\texttt{dts}), as in \S\ref{sec:dts}. If used with blob
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input, this allows \dtc to act as a ``decompiler''.
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\item assembler source (\texttt{asm}). \dtc can produce an assembler
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file, which will assemble into a \texttt{.o} file containing the
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device tree blob, with symbols giving the beginning of the blob and
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its various subsections. This can then be linked directly into a
|
|
bootloader or firmware image.
|
|
\end{itemize}
|
|
|
|
For maximum applicability, \dtc can both read and write any of the
|
|
existing revisions of the blob format. When reading, \dtc takes the
|
|
version from the blob header, and when writing it takes a command line
|
|
option specifying the desired version. It automatically makes any
|
|
necessary adjustments to the tree that are necessary for the specified
|
|
version. For example, formats before 0x10 require each node to have
|
|
an explicit \texttt{name} property. When \dtc creates such a blob, it
|
|
will automatically generate \texttt{name} properties from the unit
|
|
names.
|
|
|
|
\subsection{Source format}
|
|
\label{sec:dts}
|
|
|
|
The ``source'' format for \dtc is a text description of the device
|
|
tree in a vaguely C-like form. Figure \ref{fig:dts} shows an
|
|
example. The file starts with \texttt{/memreserve/} directives, which
|
|
gives address ranges to add to the output blob's memory reserve table,
|
|
then the device tree proper is described.
|
|
|
|
Nodes of the tree are introduced with the node name, followed by a
|
|
\texttt{\{} ... \texttt{\};} block containing the node's properties
|
|
and subnodes. Properties are given as just {\emph{name} \texttt{=}
|
|
\emph{value}\texttt{;}}. The property values can be given in any
|
|
of three forms:
|
|
\begin{itemize}
|
|
\item \emph{string} (for example, \texttt{"MyBoard"}). The property
|
|
value is the given string, including terminating NULL. C-style
|
|
escapes (\verb+\t+, \verb+\n+, \verb+\0+ and so forth) are allowed.
|
|
\item \emph{cells} (for example, \texttt{<0 8000 f0000000>}). The
|
|
property value is made up of a list of 32-bit ``cells'', each given
|
|
as a hex value.
|
|
\item \emph{bytestring} (for example, \texttt{[1234abcdef]}). The
|
|
property value is given as a hex bytestring.
|
|
\end{itemize}
|
|
|
|
Cell properties can also contain \emph{references}. Instead of a hex
|
|
number, the source can give an ampersand (\texttt{\&}) followed by the
|
|
full path to some node in the tree. For example, in Figure
|
|
\ref{fig:dts}, the \texttt{/chosen} node has an
|
|
\texttt{interrupt-controller} property referring to the interrupt
|
|
controller described by the node \texttt{/mpic@0x3fffdd08400}. In the
|
|
output tree, the value of the referenced node's phandle is included in
|
|
the property. If that node doesn't have an explicit phandle property,
|
|
\dtc will automatically create a unique phandle for it. This approach
|
|
makes it easy to create interrupt trees without having to explicitly
|
|
assign and remember phandles for the various interrupt controller
|
|
nodes.
|
|
|
|
The \dtc source can also include ``labels'', which are placed on a
|
|
particular node or property. For example, Figure \ref{fig:dts} has a
|
|
label ``\texttt{memreg}'' on the \texttt{reg} property of the node
|
|
\texttt{/memory@0}. When using assembler output, corresponding labels
|
|
in the output are generated, which will assemble into symbols
|
|
addressing the part of the blob with the node or property in question.
|
|
This is useful for the common case where an embedded board has an
|
|
essentially fixed device tree with a few variable properties, such as
|
|
the size of memory. The bootloader for such a board can have a device
|
|
tree linked in, including a symbol referring to the right place in the
|
|
blob to update the parameter with the correct value determined at
|
|
runtime.
|
|
|
|
\subsection{Tree checking}
|
|
|
|
Between reading in the device tree and writing it out in the new
|
|
format, \dtc performs a number of checks on the tree:
|
|
\begin{itemize}
|
|
\item \emph{syntactic structure}: \dtc checks that node and property
|
|
names contain only allowed characters and meet length restrictions.
|
|
It checks that a node does not have multiple properties or subnodes
|
|
with the same name.
|
|
\item \emph{semantic structure}: In some cases, \dtc checks that
|
|
properties whose contents are defined by convention have appropriate
|
|
values. For example, it checks that \texttt{reg} properties have a
|
|
length that makes sense given the address forms specified by the
|
|
\texttt{\#address-cells} and \texttt{\#size-cells} properties. It
|
|
checks that properties such as \texttt{interrupt-parent} contain a
|
|
valid phandle.
|
|
\item \emph{Linux requirements}: \dtc checks that the device tree
|
|
contains those nodes and properties that are required by the Linux
|
|
kernel to boot correctly.
|
|
\end{itemize}
|
|
|
|
These checks are useful to catch simple problems with the device tree,
|
|
rather than having to debug the results on an embedded kernel. With
|
|
the blob input mode, it can also be used for diagnosing problems with
|
|
an existing blob.
|
|
|
|
\section{Future Work}
|
|
|
|
\subsection{Board ports}
|
|
|
|
The flattened device tree has always been the only supported way to
|
|
boot a \texttt{ppc64} kernel on an embedded system. With the merge of
|
|
\texttt{ppc32} and \texttt{ppc64} code it has also become the only
|
|
supported way to boot any merged \texttt{powerpc} kernel, 32-bit or
|
|
64-bit. In fact, the old \texttt{ppc} architecture exists mainly just
|
|
to support the old ppc32 embedded ports that have not been migrated
|
|
to the flattened device tree approach. We plan to remove the
|
|
\texttt{ppc} architecture eventually, which will mean porting all the
|
|
various embedded boards to use the flattened device tree.
|
|
|
|
\subsection{\dtc features}
|
|
|
|
While it is already quite usable, there are a number of extra features
|
|
that \dtc could include to make creating device trees more convenient:
|
|
\begin{itemize}
|
|
\item \emph{better tree checking}: Although \dtc already performs a
|
|
number of checks on the device tree, they are rather haphazard. In
|
|
many cases \dtc will give up after detecting a minor error early and
|
|
won't pick up more interesting errors later on. There is a
|
|
\texttt{-f} parameter that forces \dtc to generate an output tree
|
|
even if there are errors. At present, this needs to be used more
|
|
often than one might hope, because \dtc is bad at deciding which
|
|
errors should really be fatal, and which rate mere warnings.
|
|
\item \emph{binary include}: Occasionally, it is useful for the device
|
|
tree to incorporate as a property a block of binary data for some
|
|
board-specific purpose. For example, many of Apple's device trees
|
|
incorporate bytecode drivers for certain platform devices. \dtc's
|
|
source format ought to allow this by letting a property's value be
|
|
read directly from a binary file.
|
|
\item \emph{macros}: it might be useful for \dtc to implement some
|
|
sort of macros so that a tree containing a number of similar devices
|
|
(for example, multiple identical ethernet controllers or PCI buses)
|
|
can be written more quickly. At present, this can be accomplished
|
|
in part by running the source file through CPP before compiling with
|
|
\dtc. It's not clear whether ``native'' support for macros would be
|
|
more useful.
|
|
\end{itemize}
|
|
|
|
\bibliographystyle{amsplain}
|
|
\bibliography{dtc-paper}
|
|
|
|
\section*{About the authors}
|
|
|
|
David Gibson has been a member of the IBM Linux Technology Center,
|
|
working from Canberra, Australia, since 2001. Recently he has worked
|
|
on Linux hugepage support and performance counter support for ppc64,
|
|
as well as the device tree compiler. In the past, he has worked on
|
|
bringup for various ppc and ppc64 embedded systems, the orinoco
|
|
wireless driver, ramfs, and a userspace checkpointing system
|
|
(\texttt{esky}).
|
|
|
|
Benjamin Herrenschmidt was a MacOS developer for about 10 years, but
|
|
ultimately saw the light and installed Linux on his Apple PowerPC
|
|
machine. After writing a bootloader, BootX, for it in 1998, he
|
|
started contributing to the PowerPC Linux port in various areas,
|
|
mostly around the support for Apple machines. He became official
|
|
PowerMac maintainer in 2001. In 2003, he joined the IBM Linux
|
|
Technology Center in Canberra, Australia, where he ported the 64 bit
|
|
PowerPC kernel to Apple G5 machines and the Maple embedded board,
|
|
among others things. He's a member of the ppc64 development ``team''
|
|
and one of his current goals is to make the integration of embedded
|
|
platforms smoother and more maintainable than in the 32-bit PowerPC
|
|
kernel.
|
|
|
|
\section*{Legal Statement}
|
|
|
|
This work represents the view of the author and does not necessarily
|
|
represent the view of IBM.
|
|
|
|
IBM, \ppc, \ppc Architecture, POWER5, pSeries and iSeries are
|
|
trademarks or registered trademarks of International Business Machines
|
|
Corporation in the United States and/or other countries.
|
|
|
|
Apple and Power Macintosh are a registered trademarks of Apple
|
|
Computer Inc. in the United States, other countries, or both.
|
|
|
|
Linux is a registered trademark of Linus Torvalds.
|
|
|
|
Other company, product, and service names may be trademarks or service
|
|
marks of others.
|
|
|
|
\end{document}
|