Kernel-4.18.0-80.el8_booting-without-of

       Booting the Linux/ppc kernel without Open Firmware
       --------------------------------------------------

(c) 2005 Benjamin Herrenschmidt ,
IBM Corp.
(c) 2005 Becky Bruce <becky.bruce at freescale.com>,
Freescale Semiconductor, FSL SOC and 32-bit additions
(c) 2006 MontaVista Software, Inc.
Flash chip node definition

Table of Contents

I - Introduction
1) Entry point for arch/arm
2) Entry point for arch/powerpc
3) Entry point for arch/x86
4) Entry point for arch/mips/bmips
5) Entry point for arch/sh

II - The DT block format
1) Header
2) Device tree generalities
3) Device tree “structure” block
4) Device tree “strings” block

III - Required content of the device tree
1) Note about cells and address representation
2) Note about “compatible” properties
3) Note about “name” properties
4) Note about node and property names and character set
5) Required nodes and properties
a) The root node
b) The /cpus node
c) The /cpus/* nodes
d) the /memory node(s)
e) The /chosen node
f) the /soc node

IV - “dtc”, the device tree compiler

V - Recommendations for a bootloader

VI - System-on-a-chip devices and nodes
1) Defining child nodes of an SOC
2) Representing devices without a current OF specification

VII - Specifying interrupt information for devices
1) interrupts property
2) interrupt-parent property
3) OpenPIC Interrupt Controllers
4) ISA Interrupt Controllers

VIII - Specifying device power management information (sleep property)

IX - Specifying dma bus information

Appendix A - Sample SOC node for MPC8540

Revision Information

May 18, 2005: Rev 0.1 - Initial draft, no chapter III yet.

May 19, 2005: Rev 0.2 - Add chapter III and bits & pieces here or
clarifies the fact that a lot of things are
optional, the kernel only requires a very
small device tree, though it is encouraged
to provide an as complete one as possible.

May 24, 2005: Rev 0.3 - Precise that DT block has to be in RAM
- Misc fixes
- Define version 3 and new format version 16
for the DT block (version 16 needs kernel
patches, will be fwd separately).
String block now has a size, and full path
is replaced by unit name for more
compactness.
linux,phandle is made optional, only nodes
that are referenced by other nodes need it.
“name” property is now automatically
deduced from the unit name

June 1, 2005: Rev 0.4 - Correct confusion between OF_DT_END and
OF_DT_END_NODE in structure definition.
- Change version 16 format to always align
property data to 4 bytes. Since tokens are
already aligned, that means no specific
required alignment between property size
and property data. The old style variable
alignment would make it impossible to do
“simple” insertion of properties using
memmove (thanks Milton for
noticing). Updated kernel patch as well
- Correct a few more alignment constraints
- Add a chapter about the device-tree
compiler and the textural representation of
the tree that can be “compiled” by dtc.

November 21, 2005: Rev 0.5
- Additions/generalizations for 32-bit
- Changed to reflect the new arch/powerpc
structure
- Added chapter VI

ToDo:
- Add some definitions of interrupt tree (simple/complex)
- Add some definitions for PCI host bridges
- Add some common address format examples
- Add definitions for standard properties and “compatible”
names for cells that are not already defined by the existing
OF spec.
- Compare FSL SOC use of PCI to standard and make sure no new
node definition required.
- Add more information about node definitions for SOC devices
that currently have no standard, like the FSL CPM.

I - Introduction

During the development of the Linux/ppc64 kernel, and more
specifically, the addition of new platform types outside of the old
IBM pSeries/iSeries pair, it was decided to enforce some strict rules
regarding the kernel entry and bootloader <-> kernel interfaces, in
order to avoid the degeneration that had become the ppc32 kernel entry
point and the way a new platform should be added to the kernel. The
legacy iSeries platform breaks those rules as it predates this scheme,
but no new board support will be accepted in the main tree that
doesn’t follow them properly. In addition, since the advent of the
arch/powerpc merged architecture for ppc32 and ppc64, new 32-bit
platforms and 32-bit platforms which move into arch/powerpc will be
required to use these rules as well.

The main requirement that will be defined in more detail below is
the presence of a device-tree whose format is defined after Open
Firmware specification. However, in order to make life easier
to embedded board vendors, the kernel doesn’t require the device-tree
to represent every device in the system and only requires some nodes
and properties to be present. This will be described in detail in
section III, but, for example, the kernel does not require you to
create a node for every PCI device in the system. It is a requirement
to have a node for PCI host bridges in order to provide interrupt
routing information and memory/IO ranges, among others. It is also
recommended to define nodes for on chip devices and other buses that
don’t specifically fit in an existing OF specification. This creates a
great flexibility in the way the kernel can then probe those and match
drivers to device, without having to hard code all sorts of tables. It
also makes it more flexible for board vendors to do minor hardware
upgrades without significantly impacting the kernel code or cluttering
it with special cases.

  1. Entry point for arch/arm

There is one single entry point to the kernel, at the start
of the kernel image. That entry point supports two calling
conventions. A summary of the interface is described here. A full
description of the boot requirements is documented in
Documentation/arm/Booting

    a) ATAGS interface.  Minimal information is passed from firmware
    to the kernel with a tagged list of predefined parameters.

            r0 : 0

            r1 : Machine type number

            r2 : Physical address of tagged list in system RAM

    b) Entry with a flattened device-tree block.  Firmware loads the
    physical address of the flattened device tree block (dtb) into r2,
    r1 is not used, but it is considered good practice to use a valid
    machine number as described in Documentation/arm/Booting.

            r0 : 0

            r1 : Valid machine type number.  When using a device tree,
            a single machine type number will often be assigned to
            represent a class or family of SoCs.

            r2 : physical pointer to the device-tree block
            (defined in chapter II) in RAM.  Device tree can be located
            anywhere in system RAM, but it should be aligned on a 64 bit
            boundary.

The kernel will differentiate between ATAGS and device tree booting by
reading the memory pointed to by r2 and looking for either the flattened
device tree block magic value (0xd00dfeed) or the ATAG_CORE value at
offset 0x4 from r2 (0x54410001).

  1. Entry point for arch/powerpc

There is one single entry point to the kernel, at the start
of the kernel image. That entry point supports two calling
conventions:

    a) Boot from Open Firmware. If your firmware is compatible
    with Open Firmware (IEEE 1275) or provides an OF compatible
    client interface API (support for "interpret" callback of
    forth words isn't required), you can enter the kernel with:

          r5 : OF callback pointer as defined by IEEE 1275
          bindings to powerpc. Only the 32-bit client interface
          is currently supported

          r3, r4 : address & length of an initrd if any or 0

          The MMU is either on or off; the kernel will run the
          trampoline located in arch/powerpc/kernel/prom_init.c to
          extract the device-tree and other information from open
          firmware and build a flattened device-tree as described
          in b). prom_init() will then re-enter the kernel using
          the second method. This trampoline code runs in the
          context of the firmware, which is supposed to handle all
          exceptions during that time.

    b) Direct entry with a flattened device-tree block. This entry
    point is called by a) after the OF trampoline and can also be
    called directly by a bootloader that does not support the Open
    Firmware client interface. It is also used by "kexec" to
    implement "hot" booting of a new kernel from a previous
    running one. This method is what I will describe in more
    details in this document, as method a) is simply standard Open
    Firmware, and thus should be implemented according to the
    various standard documents defining it and its binding to the
    PowerPC platform. The entry point definition then becomes:

            r3 : physical pointer to the device-tree block
            (defined in chapter II) in RAM

            r4 : physical pointer to the kernel itself. This is
            used by the assembly code to properly disable the MMU
            in case you are entering the kernel with MMU enabled
            and a non-1:1 mapping.

            r5 : NULL (as to differentiate with method a)

    Note about SMP entry: Either your firmware puts your other
    CPUs in some sleep loop or spin loop in ROM where you can get
    them out via a soft reset or some other means, in which case
    you don't need to care, or you'll have to enter the kernel
    with all CPUs. The way to do that with method b) will be
    described in a later revision of this document.

Board supports (platforms) are not exclusive config options. An
arbitrary set of board supports can be built in a single kernel
image. The kernel will “know” what set of functions to use for a
given platform based on the content of the device-tree. Thus, you
should:

    a) add your platform support as a _boolean_ option in
    arch/powerpc/Kconfig, following the example of PPC_PSERIES,
    PPC_PMAC and PPC_MAPLE. The later is probably a good
    example of a board support to start from.

    b) create your main platform file as
    "arch/powerpc/platforms/myplatform/myboard_setup.c" and add it
    to the Makefile under the condition of your CONFIG_
    option. This file will define a structure of type "ppc_md"
    containing the various callbacks that the generic code will
    use to get to your platform specific code

A kernel image may support multiple platforms, but only if the
platforms feature the same core architecture. A single kernel build
cannot support both configurations with Book E and configurations
with classic Powerpc architectures.

  1. Entry point for arch/x86

There is one single 32bit entry point to the kernel at code32_start,
the decompressor (the real mode entry point goes to the same 32bit
entry point once it switched into protected mode). That entry point
supports one calling convention which is documented in
Documentation/x86/boot.txt
The physical pointer to the device-tree block (defined in chapter II)
is passed via setup_data which requires at least boot protocol 2.09.
The type filed is defined as

#define SETUP_DTB 2

This device-tree is used as an extension to the “boot page”. As such it
does not parse / consider data which is already covered by the boot
page. This includes memory size, reserved ranges, command line arguments
or initrd address. It simply holds information which can not be retrieved
otherwise like interrupt routing or a list of devices behind an I2C bus.

  1. Entry point for arch/mips/bmips

Some bootloaders only support a single entry point, at the start of the
kernel image. Other bootloaders will jump to the ELF start address.
Both schemes are supported; CONFIG_BOOT_RAW=y and CONFIG_NO_EXCEPT_FILL=y,
so the first instruction immediately jumps to kernel_entry().

Similar to the arch/arm case (b), a DT-aware bootloader is expected to
set up the following registers:

     a0 : 0

     a1 : 0xffffffff

     a2 : Physical pointer to the device tree block (defined in chapter
     II) in RAM.  The device tree can be located anywhere in the first
     512MB of the physical address space (0x00000000 - 0x1fffffff),
     aligned on a 64 bit boundary.

Legacy bootloaders do not use this convention, and they do not pass in a
DT block. In this case, Linux will look for a builtin DTB, selected via
CONFIG_DT_*.

This convention is defined for 32-bit systems only, as there are not
currently any 64-bit BMIPS implementations.

  1. Entry point for arch/sh

Device-tree-compatible SH bootloaders are expected to provide the physical
address of the device tree blob in r4. Since legacy bootloaders did not
guarantee any particular initial register state, kernels built to
inter-operate with old bootloaders must either use a builtin DTB or
select a legacy board option (something other than CONFIG_SH_DEVICE_TREE)
that does not use device tree. Support for the latter is being phased out
in favor of device tree.

II - The DT block format

This chapter defines the actual format of the flattened device-tree
passed to the kernel. The actual content of it and kernel requirements
are described later. You can find example of code manipulating that
format in various places, including arch/powerpc/kernel/prom_init.c
which will generate a flattened device-tree from the Open Firmware
representation, or the fs2dt utility which is part of the kexec tools
which will generate one from a filesystem representation. It is
expected that a bootloader like uboot provides a bit more support,
that will be discussed later as well.

Note: The block has to be in main memory. It has to be accessible in
both real mode and virtual mode with no mapping other than main
memory. If you are writing a simple flash bootloader, it should copy
the block to RAM before passing it to the kernel.

  1. Header

The kernel is passed the physical address pointing to an area of memory
that is roughly described in include/linux/of_fdt.h by the structure
boot_param_header:

struct boot_param_header {
u32 magic; /* magic word OF_DT_HEADER /
u32 totalsize; /
total size of DT block /
u32 off_dt_struct; /
offset to structure /
u32 off_dt_strings; /
offset to strings /
u32 off_mem_rsvmap; /
offset to memory reserve map
/
u32 version; /
format version /
u32 last_comp_version; /
last compatible version */

    /* version 2 fields below */
    u32     boot_cpuid_phys;        /* Which physical CPU id we're
                                       booting on */
    /* version 3 fields below */
    u32     size_dt_strings;        /* size of the strings block */

    /* version 17 fields below */
    u32    size_dt_struct;        /* size of the DT structure block */

};

Along with the constants:

/* Definitions used by the flattened device tree /
#define OF_DT_HEADER 0xd00dfeed /
4: version,
4: total size /
#define OF_DT_BEGIN_NODE 0x1 /
Start node: full name
/
#define OF_DT_END_NODE 0x2 /
End node /
#define OF_DT_PROP 0x3 /
Property: name off,
size, content */
#define OF_DT_END 0x9

All values in this header are in big endian format, the various
fields in this header are defined more precisely below. All
“offset” values are in bytes from the start of the header; that is
from the physical base address of the device tree block.

  • magic

    This is a magic value that “marks” the beginning of the
    device-tree block header. It contains the value 0xd00dfeed and is
    defined by the constant OF_DT_HEADER

  • totalsize

    This is the total size of the DT block including the header. The
    “DT” block should enclose all data structures defined in this
    chapter (who are pointed to by offsets in this header). That is,
    the device-tree structure, strings, and the memory reserve map.

  • off_dt_struct

    This is an offset from the beginning of the header to the start
    of the “structure” part the device tree. (see 2) device tree)

  • off_dt_strings

    This is an offset from the beginning of the header to the start
    of the “strings” part of the device-tree

  • off_mem_rsvmap

    This is an offset from the beginning of the header to the start
    of the reserved memory map. This map is a list of pairs of 64-
    bit integers. Each pair is a physical address and a size. The
    list is terminated by an entry of size 0. This map provides the
    kernel with a list of physical memory areas that are “reserved”
    and thus not to be used for memory allocations, especially during
    early initialization. The kernel needs to allocate memory during
    boot for things like un-flattening the device-tree, allocating an
    MMU hash table, etc… Those allocations must be done in such a
    way to avoid overriding critical things like, on Open Firmware
    capable machines, the RTAS instance, or on some pSeries, the TCE
    tables used for the iommu. Typically, the reserve map should
    contain at least this DT block itself (header,total_size). If
    you are passing an initrd to the kernel, you should reserve it as
    well. You do not need to reserve the kernel image itself. The map
    should be 64-bit aligned.

  • version

    This is the version of this structure. Version 1 stops
    here. Version 2 adds an additional field boot_cpuid_phys.
    Version 3 adds the size of the strings block, allowing the kernel
    to reallocate it easily at boot and free up the unused flattened
    structure after expansion. Version 16 introduces a new more
    “compact” format for the tree itself that is however not backward
    compatible. Version 17 adds an additional field, size_dt_struct,
    allowing it to be reallocated or moved more easily (this is
    particularly useful for bootloaders which need to make
    adjustments to a device tree based on probed information). You
    should always generate a structure of the highest version defined
    at the time of your implementation. Currently that is version 17,
    unless you explicitly aim at being backward compatible.

  • last_comp_version

    Last compatible version. This indicates down to what version of
    the DT block you are backward compatible. For example, version 2
    is backward compatible with version 1 (that is, a kernel build
    for version 1 will be able to boot with a version 2 format). You
    should put a 1 in this field if you generate a device tree of
    version 1 to 3, or 16 if you generate a tree of version 16 or 17
    using the new unit name format.

  • boot_cpuid_phys

    This field only exist on version 2 headers. It indicate which
    physical CPU ID is calling the kernel entry point. This is used,
    among others, by kexec. If you are on an SMP system, this value
    should match the content of the “reg” property of the CPU node in
    the device-tree corresponding to the CPU calling the kernel entry
    point (see further chapters for more information on the required
    device-tree contents)

  • size_dt_strings

    This field only exists on version 3 and later headers. It
    gives the size of the “strings” section of the device tree (which
    starts at the offset given by off_dt_strings).

  • size_dt_struct

    This field only exists on version 17 and later headers. It gives
    the size of the “structure” section of the device tree (which
    starts at the offset given by off_dt_struct).

    So the typical layout of a DT block (though the various parts don’t
    need to be in that order) looks like this (addresses go from top to
    bottom):

         ------------------------------
 base -> |  struct boot_param_header  |
         ------------------------------
         |      (alignment gap) (*)   |
         ------------------------------
         |      memory reserve map    |
         ------------------------------
         |      (alignment gap)       |
         ------------------------------
         |                            |
         |    device-tree structure   |
         |                            |
         ------------------------------
         |      (alignment gap)       |
         ------------------------------
         |                            |
         |     device-tree strings    |
         |                            |
  -----> ------------------------------
  |
  |
  --- (base + totalsize)

(*) The alignment gaps are not necessarily present; their presence
and size are dependent on the various alignment requirements of
the individual data blocks.

  1. Device tree generalities

This device-tree itself is separated in two different blocks, a
structure block and a strings block. Both need to be aligned to a 4
byte boundary.

First, let’s quickly describe the device-tree concept before detailing
the storage format. This chapter does not describe the detail of the
required types of nodes & properties for the kernel, this is done
later in chapter III.

The device-tree layout is strongly inherited from the definition of
the Open Firmware IEEE 1275 device-tree. It’s basically a tree of
nodes, each node having two or more named properties. A property can
have a value or not.

It is a tree, so each node has one and only one parent except for the
root node who has no parent.

A node has 2 names. The actual node name is generally contained in a
property of type “name” in the node property list whose value is a
zero terminated string and is mandatory for version 1 to 3 of the
format definition (as it is in Open Firmware). Version 16 makes it
optional as it can generate it from the unit name defined below.

There is also a “unit name” that is used to differentiate nodes with
the same name at the same level, it is usually made of the node
names, the “@” sign, and a “unit address”, which definition is
specific to the bus type the node sits on.

The unit name doesn’t exist as a property per-se but is included in
the device-tree structure. It is typically used to represent “path” in
the device-tree. More details about the actual format of these will be
below.

The kernel generic code does not make any formal use of the
unit address (though some board support code may do) so the only real
requirement here for the unit address is to ensure uniqueness of
the node unit name at a given level of the tree. Nodes with no notion
of address and no possible sibling of the same name (like /memory or
/cpus) may omit the unit address in the context of this specification,
or use the “@0” default unit address. The unit name is used to define
a node “full path”, which is the concatenation of all parent node
unit names separated with “/“.

The root node doesn’t have a defined name, and isn’t required to have
a name property either if you are using version 3 or earlier of the
format. It also has no unit address (no @ symbol followed by a unit
address). The root node unit name is thus an empty string. The full
path to the root node is “/“.

Every node which actually represents an actual device (that is, a node
which isn’t only a virtual “container” for more nodes, like “/cpus”
is) is also required to have a “compatible” property indicating the
specific hardware and an optional list of devices it is fully
backwards compatible with.

Finally, every node that can be referenced from a property in another
node is required to have either a “phandle” or a “linux,phandle”
property. Real Open Firmware implementations provide a unique
“phandle” value for every node that the “prom_init()” trampoline code
turns into “linux,phandle” properties. However, this is made optional
if the flattened device tree is used directly. An example of a node
referencing another node via “phandle” is when laying out the
interrupt tree which will be described in a further version of this
document.

The “phandle” property is a 32-bit value that uniquely
identifies a node. You are free to use whatever values or system of
values, internal pointers, or whatever to generate these, the only
requirement is that every node for which you provide that property has
a unique value for it.

Here is an example of a simple device-tree. In this example, an “o”
designates a node followed by the node unit name. Properties are
presented with their name followed by their content. “content”
represents an ASCII string (zero terminated) value, while
represents a 32-bit value, specified in decimal or hexadecimal (the
latter prefixed 0x). The various nodes in this example will be
discussed in a later chapter. At this point, it is only meant to give
you a idea of what a device-tree looks like. I have purposefully kept
the “name” and “linux,phandle” properties which aren’t necessary in
order to give you a better idea of what the tree looks like in
practice.

/ o device-tree
|- name = “device-tree”
|- model = “MyBoardName”
|- compatible = “MyBoardFamilyName”
|- #address-cells = <2>
|- #size-cells = <2>
|- linux,phandle = <0>
|
o cpus
| | - name = “cpus”
| | - linux,phandle = <1>
| | - #address-cells = <1>
| | - #size-cells = <0>
| |
| o PowerPC,970@0
| |- name = “PowerPC,970”
| |- device_type = “cpu”
| |- reg = <0>
| |- clock-frequency = <0x5f5e1000>
| |- 64-bit
| |- linux,phandle = <2>
|
o memory@0
| |- name = “memory”
| |- device_type = “memory”
| |- reg = <0x00000000 0x00000000 0x00000000 0x20000000>
| |- linux,phandle = <3>
|
o chosen
|- name = “chosen”
|- bootargs = “root=/dev/sda2”
|- linux,phandle = <4>

This tree is almost a minimal tree. It pretty much contains the
minimal set of required nodes and properties to boot a linux kernel;
that is, some basic model information at the root, the CPUs, and the
physical memory layout. It also includes misc information passed
through /chosen, like in this example, the platform type (mandatory)
and the kernel command line arguments (optional).

The /cpus/PowerPC,970@0/64-bit property is an example of a
property without a value. All other properties have a value. The
significance of the #address-cells and #size-cells properties will be
explained in chapter IV which defines precisely the required nodes and
properties and their content.

  1. Device tree “structure” block

The structure of the device tree is a linearized tree structure. The
“OF_DT_BEGIN_NODE” token starts a new node, and the “OF_DT_END_NODE”
ends that node definition. Child nodes are simply defined before
“OF_DT_END_NODE” (that is nodes within the node). A ‘token’ is a 32
bit value. The tree has to be “finished” with a OF_DT_END token

Here’s the basic structure of a single node:

 * token OF_DT_BEGIN_NODE (that is 0x00000001)
 * for version 1 to 3, this is the node full path as a zero
   terminated string, starting with "/". For version 16 and later,
   this is the node unit name only (or an empty string for the
   root node)
 * [align gap to next 4 bytes boundary]
 * for each property:
    * token OF_DT_PROP (that is 0x00000003)
    * 32-bit value of property value size in bytes (or 0 if no
      value)
    * 32-bit value of offset in string block of property name
    * property value data if any
    * [align gap to next 4 bytes boundary]
 * [child nodes if any]
 * token OF_DT_END_NODE (that is 0x00000002)

So the node content can be summarized as a start token, a full path,
a list of properties, a list of child nodes, and an end token. Every
child node is a full node structure itself as defined above.

NOTE: The above definition requires that all property definitions for
a particular node MUST precede any subnode definitions for that node.
Although the structure would not be ambiguous if properties and
subnodes were intermingled, the kernel parser requires that the
properties come first (up until at least 2.6.22). Any tools
manipulating a flattened tree must take care to preserve this
constraint.

  1. Device tree “strings” block

In order to save space, property names, which are generally redundant,
are stored separately in the “strings” block. This block is simply the
whole bunch of zero terminated strings for all property names
concatenated together. The device-tree property definitions in the
structure block will contain offset values from the beginning of the
strings block.

III - Required content of the device tree

WARNING: All “linux,*” properties defined in this document apply only
to a flattened device-tree. If your platform uses a real
implementation of Open Firmware or an implementation compatible with
the Open Firmware client interface, those properties will be created
by the trampoline code in the kernel’s prom_init() file. For example,
that’s where you’ll have to add code to detect your board model and
set the platform number. However, when using the flattened device-tree
entry point, there is no prom_init() pass, and thus you have to
provide those properties yourself.

  1. Note about cells and address representation

The general rule is documented in the various Open Firmware
documentations. If you choose to describe a bus with the device-tree
and there exist an OF bus binding, then you should follow the
specification. However, the kernel does not require every single
device or bus to be described by the device tree.

In general, the format of an address for a device is defined by the
parent bus type, based on the #address-cells and #size-cells
properties. Note that the parent’s parent definitions of #address-cells
and #size-cells are not inherited so every node with children must specify
them. The kernel requires the root node to have those properties defining
addresses format for devices directly mapped on the processor bus.

Those 2 properties define ‘cells’ for representing an address and a
size. A “cell” is a 32-bit number. For example, if both contain 2
like the example tree given above, then an address and a size are both
composed of 2 cells, and each is a 64-bit number (cells are
concatenated and expected to be in big endian format). Another example
is the way Apple firmware defines them, with 2 cells for an address
and one cell for a size. Most 32-bit implementations should define
#address-cells and #size-cells to 1, which represents a 32-bit value.
Some 32-bit processors allow for physical addresses greater than 32
bits; these processors should define #address-cells as 2.

“reg” properties are always a tuple of the type “address size” where
the number of cells of address and size is specified by the bus
#address-cells and #size-cells. When a bus supports various address
spaces and other flags relative to a given address allocation (like
prefetchable, etc…) those flags are usually added to the top level
bits of the physical address. For example, a PCI physical address is
made of 3 cells, the bottom two containing the actual address itself
while the top cell contains address space indication, flags, and pci
bus & device numbers.

For buses that support dynamic allocation, it’s the accepted practice
to then not provide the address in “reg” (keep it 0) though while
providing a flag indicating the address is dynamically allocated, and
then, to provide a separate “assigned-addresses” property that
contains the fully allocated addresses. See the PCI OF bindings for
details.

In general, a simple bus with no address space bits and no dynamic
allocation is preferred if it reflects your hardware, as the existing
kernel address parsing functions will work out of the box. If you
define a bus type with a more complex address format, including things
like address space bits, you’ll have to add a bus translator to the
prom_parse.c file of the recent kernels for your bus type.

The “reg” property only defines addresses and sizes (if #size-cells is
non-0) within a given bus. In order to translate addresses upward
(that is into parent bus addresses, and possibly into CPU physical
addresses), all buses must contain a “ranges” property. If the
“ranges” property is missing at a given level, it’s assumed that
translation isn’t possible, i.e., the registers are not visible on the
parent bus. The format of the “ranges” property for a bus is a list
of:

bus address, parent bus address, size

“bus address” is in the format of the bus this bus node is defining,
that is, for a PCI bridge, it would be a PCI address. Thus, (bus
address, size) defines a range of addresses for child devices. “parent
bus address” is in the format of the parent bus of this bus. For
example, for a PCI host controller, that would be a CPU address. For a
PCI<->ISA bridge, that would be a PCI address. It defines the base
address in the parent bus where the beginning of that range is mapped.

For new 64-bit board support, I recommend either the 2/2 format or
Apple’s 2/1 format which is slightly more compact since sizes usually
fit in a single 32-bit word. New 32-bit board support should use a
1/1 format, unless the processor supports physical addresses greater
than 32-bits, in which case a 2/1 format is recommended.

Alternatively, the “ranges” property may be empty, indicating that the
registers are visible on the parent bus using an identity mapping
translation. In other words, the parent bus address space is the same
as the child bus address space.

  1. Note about “compatible” properties

These properties are optional, but recommended in devices and the root
node. The format of a “compatible” property is a list of concatenated
zero terminated strings. They allow a device to express its
compatibility with a family of similar devices, in some cases,
allowing a single driver to match against several devices regardless
of their actual names.

  1. Note about “name” properties

While earlier users of Open Firmware like OldWorld macintoshes tended
to use the actual device name for the “name” property, it’s nowadays
considered a good practice to use a name that is closer to the device
class (often equal to device_type). For example, nowadays, Ethernet
controllers are named “ethernet”, an additional “model” property
defining precisely the chip type/model, and “compatible” property
defining the family in case a single driver can driver more than one
of these chips. However, the kernel doesn’t generally put any
restriction on the “name” property; it is simply considered good
practice to follow the standard and its evolutions as closely as
possible.

Note also that the new format version 16 makes the “name” property
optional. If it’s absent for a node, then the node’s unit name is then
used to reconstruct the name. That is, the part of the unit name
before the “@” sign is used (or the entire unit name if no “@” sign
is present).

  1. Note about node and property names and character set

While Open Firmware provides more flexible usage of 8859-1, this
specification enforces more strict rules. Nodes and properties should
be comprised only of ASCII characters ‘a’ to ‘z’, ‘0’ to
‘9’, ‘,’, ‘.’, ‘_’, ‘+’, ‘#’, ‘?’, and ‘-‘. Node names additionally
allow uppercase characters ‘A’ to ‘Z’ (property names should be
lowercase. The fact that vendors like Apple don’t respect this rule is
irrelevant here). Additionally, node and property names should always
begin with a character in the range ‘a’ to ‘z’ (or ‘A’ to ‘Z’ for node
names).

The maximum number of characters for both nodes and property names
is 31. In the case of node names, this is only the leftmost part of
a unit name (the pure “name” property), it doesn’t include the unit
address which can extend beyond that limit.

  1. Required nodes and properties

These are all that are currently required. However, it is strongly
recommended that you expose PCI host bridges as documented in the
PCI binding to Open Firmware, and your interrupt tree as documented
in OF interrupt tree specification.

a) The root node

The root node requires some properties to be present:

- model : this is your board name/model
- #address-cells : address representation for "root" devices
- #size-cells: the size representation for "root" devices
- compatible : the board "family" generally finds its way here,
  for example, if you have 2 board models with a similar layout,
  that typically get driven by the same platform code in the
  kernel, you would specify the exact board model in the
  compatible property followed by an entry that represents the SoC
  model.

The root node is also generally where you add additional properties
specific to your board like the serial number if any, that sort of
thing. It is recommended that if you add any “custom” property whose
name may clash with standard defined ones, you prefix them with your
vendor name and a comma.

Additional properties for the root node:

- serial-number : a string representing the device's serial number

b) The /cpus node

This node is the parent of all individual CPU nodes. It doesn’t
have any specific requirements, though it’s generally good practice
to have at least:

           #address-cells = <00000001>
           #size-cells    = <00000000>

This defines that the “address” for a CPU is a single cell, and has
no meaningful size. This is not necessary but the kernel will assume
that format when reading the “reg” properties of a CPU node, see
below

c) The /cpus/* nodes

So under /cpus, you are supposed to create a node for every CPU on
the machine. There is no specific restriction on the name of the
CPU, though it’s common to call it ,. For
example, Apple uses PowerPC,G5 while IBM uses PowerPC,970FX.
However, the Generic Names convention suggests that it would be
better to simply use ‘cpu’ for each cpu node and use the compatible
property to identify the specific cpu core.

Required properties:

- device_type : has to be "cpu"
- reg : This is the physical CPU number, it's a single 32-bit cell
  and is also used as-is as the unit number for constructing the
  unit name in the full path. For example, with 2 CPUs, you would
  have the full path:
    /cpus/PowerPC,970FX@0
    /cpus/PowerPC,970FX@1
  (unit addresses do not require leading zeroes)
- d-cache-block-size : one cell, L1 data cache block size in bytes (*)
- i-cache-block-size : one cell, L1 instruction cache block size in
  bytes
- d-cache-size : one cell, size of L1 data cache in bytes
- i-cache-size : one cell, size of L1 instruction cache in bytes

(*) The cache “block” size is the size on which the cache management
instructions operate. Historically, this document used the cache
“line” size here which is incorrect. The kernel will prefer the cache
block size and will fallback to cache line size for backward
compatibility.

Recommended properties:

- timebase-frequency : a cell indicating the frequency of the
  timebase in Hz. This is not directly used by the generic code,
  but you are welcome to copy/paste the pSeries code for setting
  the kernel timebase/decrementer calibration based on this
  value.
- clock-frequency : a cell indicating the CPU core clock frequency
  in Hz. A new property will be defined for 64-bit values, but if
  your frequency is < 4Ghz, one cell is enough. Here as well as
  for the above, the common code doesn't use that property, but
  you are welcome to re-use the pSeries or Maple one. A future
  kernel version might provide a common function for this.
- d-cache-line-size : one cell, L1 data cache line size in bytes
  if different from the block size
- i-cache-line-size : one cell, L1 instruction cache line size in
  bytes if different from the block size

You are welcome to add any property you find relevant to your board,
like some information about the mechanism used to soft-reset the
CPUs. For example, Apple puts the GPIO number for CPU soft reset
lines in there as a “soft-reset” property since they start secondary
CPUs by soft-resetting them.

d) the /memory node(s)

To define the physical memory layout of your board, you should
create one or more memory node(s). You can either create a single
node with all memory ranges in its reg property, or you can create
several nodes, as you wish. The unit address (@ part) used for the
full path is the address of the first range of memory defined by a
given node. If you use a single memory node, this will typically be
@0.

Required properties:

- device_type : has to be "memory"
- reg : This property contains all the physical memory ranges of
  your board. It's a list of addresses/sizes concatenated
  together, with the number of cells of each defined by the
  #address-cells and #size-cells of the root node. For example,
  with both of these properties being 2 like in the example given
  earlier, a 970 based machine with 6Gb of RAM could typically
  have a "reg" property here that looks like:

  00000000 00000000 00000000 80000000
  00000001 00000000 00000001 00000000

  That is a range starting at 0 of 0x80000000 bytes and a range
  starting at 0x100000000 and of 0x100000000 bytes. You can see
  that there is no memory covering the IO hole between 2Gb and
  4Gb. Some vendors prefer splitting those ranges into smaller
  segments, but the kernel doesn't care.

Additional properties:

- hotpluggable : The presence of this property provides an explicit
  hint to the operating system that this memory may potentially be
  removed later. The kernel can take this into consideration when
  doing nonmovable allocations and when laying out memory zones.

e) The /chosen node

This node is a bit “special”. Normally, that’s where Open Firmware
puts some variable environment information, like the arguments, or
the default input/output devices.

This specification makes a few of these mandatory, but also defines
some linux-specific properties that would be normally constructed by
the prom_init() trampoline when booting with an OF client interface,
but that you have to provide yourself when using the flattened format.

Recommended properties:

- bootargs : This zero-terminated string is passed as the kernel
  command line
- linux,stdout-path : This is the full path to your standard
  console device if any. Typically, if you have serial devices on
  your board, you may want to put the full path to the one set as
  the default console in the firmware here, for the kernel to pick
  it up as its own default console.

Note that u-boot creates and fills in the chosen node for platforms
that use it.

(Note: a practice that is now obsolete was to include a property
under /chosen called interrupt-controller which had a phandle value
that pointed to the main interrupt controller)

f) the /soc node

This node is used to represent a system-on-a-chip (SoC) and must be
present if the processor is a SoC. The top-level soc node contains
information that is global to all devices on the SoC. The node name
should contain a unit address for the SoC, which is the base address
of the memory-mapped register set for the SoC. The name of an SoC
node should start with “soc”, and the remainder of the name should
represent the part number for the soc. For example, the MPC8540’s
soc node would be called “soc8540”.

Required properties:

- ranges : Should be defined as specified in 1) to describe the
  translation of SoC addresses for memory mapped SoC registers.
- bus-frequency: Contains the bus frequency for the SoC node.
  Typically, the value of this field is filled in by the boot
  loader.
- compatible : Exact model of the SoC

Recommended properties:

- reg : This property defines the address and size of the
  memory-mapped registers that are used for the SOC node itself.
  It does not include the child device registers - these will be
  defined inside each child node.  The address specified in the
  "reg" property should match the unit address of the SOC node.
- #address-cells : Address representation for "soc" devices.  The
  format of this field may vary depending on whether or not the
  device registers are memory mapped.  For memory mapped
  registers, this field represents the number of cells needed to
  represent the address of the registers.  For SOCs that do not
  use MMIO, a special address format should be defined that
  contains enough cells to represent the required information.
  See 1) above for more details on defining #address-cells.
- #size-cells : Size representation for "soc" devices
- #interrupt-cells : Defines the width of cells used to represent
   interrupts.  Typically this value is <2>, which includes a
   32-bit number that represents the interrupt number, and a
   32-bit number that represents the interrupt sense and level.
   This field is only needed if the SOC contains an interrupt
   controller.

The SOC node may contain child nodes for each SOC device that the
platform uses. Nodes should not be created for devices which exist
on the SOC but are not used by a particular platform. See chapter VI
for more information on how to specify devices that are part of a SOC.

Example SOC node for the MPC8540:

soc8540@e0000000 {
    #address-cells = <1>;
    #size-cells = <1>;
    #interrupt-cells = <2>;
    device_type = "soc";
    ranges = <0x00000000 0xe0000000 0x00100000>
    reg = <0xe0000000 0x00003000>;
    bus-frequency = <0>;
}

IV - “dtc”, the device tree compiler

dtc source code can be found at
http://git.jdl.com/gitweb/?p=dtc.git

WARNING: This version is still in early development stage; the
resulting device-tree “blobs” have not yet been validated with the
kernel. The current generated block lacks a useful reserve map (it will
be fixed to generate an empty one, it’s up to the bootloader to fill
it up) among others. The error handling needs work, bugs are lurking,
etc…

dtc basically takes a device-tree in a given format and outputs a
device-tree in another format. The currently supported formats are:

Input formats:

 - "dtb": "blob" format, that is a flattened device-tree block
   with
    header all in a binary blob.
 - "dts": "source" format. This is a text file containing a
   "source" for a device-tree. The format is defined later in this
    chapter.
 - "fs" format. This is a representation equivalent to the
    output of /proc/device-tree, that is nodes are directories and
properties are files

Output formats:

 - "dtb": "blob" format
 - "dts": "source" format
 - "asm": assembly language file. This is a file that can be
   sourced by gas to generate a device-tree "blob". That file can
   then simply be added to your Makefile. Additionally, the
   assembly file exports some symbols that can be used.

The syntax of the dtc tool is

dtc [-I <input-format>] [-O <output-format>]
    [-o output-filename] [-V output_version] input_filename

The “output_version” defines what version of the “blob” format will be
generated. Supported versions are 1,2,3 and 16. The default is
currently version 3 but that may change in the future to version 16.

Additionally, dtc performs various sanity checks on the tree, like the
uniqueness of linux, phandle properties, validity of strings, etc…

The format of the .dts “source” file is “C” like, supports C and C++
style comments.

/ {
}

The above is the “device-tree” definition. It’s the only statement
supported currently at the toplevel.

/ {
property1 = “string_value”; /* define a property containing a 0
* terminated string
*/

property2 = <0x1234abcd>; /* define a property containing a
* numerical 32-bit value (hexadecimal)
*/

property3 = <0x12345678 0x12345678 0xdeadbeef>;
/* define a property containing 3
* numerical 32-bit values (cells) in
* hexadecimal
/
property4 = [0x0a 0x0b 0x0c 0x0d 0xde 0xea 0xad 0xbe 0xef];
/
define a property whose content is
* an arbitrary array of bytes
*/

childnode@address { /* define a child node named “childnode”
* whose unit name is “childnode at
* address”
*/

childprop = "hello\n";      /* define a property "childprop" of
                             * childnode (in this case, a string)
                             */

};
};

Nodes can contain other nodes etc… thus defining the hierarchical
structure of the tree.

Strings support common escape sequences from C: “\n”, “\t”, “\r”,
“(octal value)”, “\x(hex value)”.

It is also suggested that you pipe your source file through cpp (gcc
preprocessor) so you can use #include’s, #define for constants, etc…

Finally, various options are planned but not yet implemented, like
automatic generation of phandles, labels (exported to the asm file so
you can point to a property content and change it easily from whatever
you link the device-tree with), label or path instead of numeric value
in some cells to “point” to a node (replaced by a phandle at compile
time), export of reserve map address to the asm file, ability to
specify reserve map content at compile time, etc…

We may provide a .h include file with common definitions of that
proves useful for some properties (like building PCI properties or
interrupt maps) though it may be better to add a notion of struct
definitions to the compiler…

V - Recommendations for a bootloader

Here are some various ideas/recommendations that have been proposed
while all this has been defined and implemented.

  • The bootloader may want to be able to use the device-tree itself
    and may want to manipulate it (to add/edit some properties,
    like physical memory size or kernel arguments). At this point, 2
    choices can be made. Either the bootloader works directly on the
    flattened format, or the bootloader has its own internal tree
    representation with pointers (similar to the kernel one) and
    re-flattens the tree when booting the kernel. The former is a bit
    more difficult to edit/modify, the later requires probably a bit
    more code to handle the tree structure. Note that the structure
    format has been designed so it’s relatively easy to “insert”
    properties or nodes or delete them by just memmoving things
    around. It contains no internal offsets or pointers for this
    purpose.

  • An example of code for iterating nodes & retrieving properties
    directly from the flattened tree format can be found in the kernel
    file drivers/of/fdt.c. Look at the of_scan_flat_dt() function,
    its usage in early_init_devtree(), and the corresponding various
    early_init_dt_scan_*() callbacks. That code can be re-used in a
    GPL bootloader, and as the author of that code, I would be happy
    to discuss possible free licensing to any vendor who wishes to
    integrate all or part of this code into a non-GPL bootloader.
    (reference needed; who is ‘I’ here? —gcl Jan 31, 2011)

VI - System-on-a-chip devices and nodes

Many companies are now starting to develop system-on-a-chip
processors, where the processor core (CPU) and many peripheral devices
exist on a single piece of silicon. For these SOCs, an SOC node
should be used that defines child nodes for the devices that make
up the SOC. While platforms are not required to use this model in
order to boot the kernel, it is highly encouraged that all SOC
implementations define as complete a flat-device-tree as possible to
describe the devices on the SOC. This will allow for the
genericization of much of the kernel code.

  1. Defining child nodes of an SOC

Each device that is part of an SOC may have its own node entry inside
the SOC node. For each device that is included in the SOC, the unit
address property represents the address offset for this device’s
memory-mapped registers in the parent’s address space. The parent’s
address space is defined by the “ranges” property in the top-level soc
node. The “reg” property for each node that exists directly under the
SOC node should contain the address mapping from the child address space
to the parent SOC address space and the size of the device’s
memory-mapped register file.

For many devices that may exist inside an SOC, there are predefined
specifications for the format of the device tree node. All SOC child
nodes should follow these specifications, except where noted in this
document.

See appendix A for an example partial SOC node definition for the
MPC8540.

  1. Representing devices without a current OF specification

Currently, there are many devices on SoCs that do not have a standard
representation defined as part of the Open Firmware specifications,
mainly because the boards that contain these SoCs are not currently
booted using Open Firmware. Binding documentation for new devices
should be added to the Documentation/devicetree/bindings directory.
That directory will expand as device tree support is added to more and
more SoCs.

VII - Specifying interrupt information for devices

The device tree represents the buses and devices of a hardware
system in a form similar to the physical bus topology of the
hardware.

In addition, a logical ‘interrupt tree’ exists which represents the
hierarchy and routing of interrupts in the hardware.

The interrupt tree model is fully described in the
document “Open Firmware Recommended Practice: Interrupt
Mapping Version 0.9”. The document is available at:
http://www.devicetree.org/open-firmware/practice/

  1. interrupts property

Devices that generate interrupts to a single interrupt controller
should use the conventional OF representation described in the
OF interrupt mapping documentation.

Each device which generates interrupts must have an ‘interrupt’
property. The interrupt property value is an arbitrary number of
of ‘interrupt specifier’ values which describe the interrupt or
interrupts for the device.

The encoding of an interrupt specifier is determined by the
interrupt domain in which the device is located in the
interrupt tree. The root of an interrupt domain specifies in
its #interrupt-cells property the number of 32-bit cells
required to encode an interrupt specifier. See the OF interrupt
mapping documentation for a detailed description of domains.

For example, the binding for the OpenPIC interrupt controller
specifies an #interrupt-cells value of 2 to encode the interrupt
number and level/sense information. All interrupt children in an
OpenPIC interrupt domain use 2 cells per interrupt in their interrupts
property.

The PCI bus binding specifies a #interrupt-cells value of 1 to encode
which interrupt pin (INTA,INTB,INTC,INTD) is used.

  1. interrupt-parent property

The interrupt-parent property is specified to define an explicit
link between a device node and its interrupt parent in
the interrupt tree. The value of interrupt-parent is the
phandle of the parent node.

If the interrupt-parent property is not defined for a node, its
interrupt parent is assumed to be an ancestor in the node’s
device tree hierarchy.

  1. OpenPIC Interrupt Controllers

OpenPIC interrupt controllers require 2 cells to encode
interrupt information. The first cell defines the interrupt
number. The second cell defines the sense and level
information.

Sense and level information should be encoded as follows:

0 = low to high edge sensitive type enabled
1 = active low level sensitive type enabled
2 = active high level sensitive type enabled
3 = high to low edge sensitive type enabled
  1. ISA Interrupt Controllers

ISA PIC interrupt controllers require 2 cells to encode
interrupt information. The first cell defines the interrupt
number. The second cell defines the sense and level
information.

ISA PIC interrupt controllers should adhere to the ISA PIC
encodings listed below:

0 =  active low level sensitive type enabled
1 =  active high level sensitive type enabled
2 =  high to low edge sensitive type enabled
3 =  low to high edge sensitive type enabled

VIII - Specifying Device Power Management Information (sleep property)

Devices on SOCs often have mechanisms for placing devices into low-power
states that are decoupled from the devices’ own register blocks. Sometimes,
this information is more complicated than a cell-index property can
reasonably describe. Thus, each device controlled in such a manner
may contain a “sleep” property which describes these connections.

The sleep property consists of one or more sleep resources, each of
which consists of a phandle to a sleep controller, followed by a
controller-specific sleep specifier of zero or more cells.

The semantics of what type of low power modes are possible are defined
by the sleep controller. Some examples of the types of low power modes
that may be supported are:

  • Dynamic: The device may be disabled or enabled at any time.
  • System Suspend: The device may request to be disabled or remain
    awake during system suspend, but will not be disabled until then.
  • Permanent: The device is disabled permanently (until the next hard
    reset).

Some devices may share a clock domain with each other, such that they should
only be suspended when none of the devices are in use. Where reasonable,
such nodes should be placed on a virtual bus, where the bus has the sleep
property. If the clock domain is shared among devices that cannot be
reasonably grouped in this manner, then create a virtual sleep controller
(similar to an interrupt nexus, except that defining a standardized
sleep-map should wait until its necessity is demonstrated).

IX - Specifying dma bus information

Some devices may have DMA memory range shifted relatively to the beginning of
RAM, or even placed outside of kernel RAM. For example, the Keystone 2 SoC
worked in LPAE mode with 4G memory has:

  • RAM range: [0x8 0000 0000, 0x8 FFFF FFFF]
  • DMA range: [ 0x8000 0000, 0xFFFF FFFF]
    and DMA range is aliased into first 2G of RAM in HW.

In such cases, DMA addresses translation should be performed between CPU phys
and DMA addresses. The “dma-ranges” property is intended to be used
for describing the configuration of such system in DT.

In addition, each DMA master device on the DMA bus may or may not support
coherent DMA operations. The “dma-coherent” property is intended to be used
for identifying devices supported coherent DMA operations in DT.

  • DMA Bus master
    Optional property:
  • dma-ranges: encoded as arbitrary number of triplets of
    (child-bus-address, parent-bus-address, length). Each triplet specified
    describes a contiguous DMA address range.
    The dma-ranges property is used to describe the direct memory access (DMA)
    structure of a memory-mapped bus whose device tree parent can be accessed
    from DMA operations originating from the bus. It provides a means of
    defining a mapping or translation between the physical address space of
    the bus and the physical address space of the parent of the bus.
    (for more information see the Devicetree Specification)
  • DMA Bus child
    Optional property:
  • dma-ranges: value. if present - It means that DMA addresses
    translation has to be enabled for this device.
  • dma-coherent: Present if dma operations are coherent

Example:
soc {
compatible = “ti,keystone”,”simple-bus”;
ranges = <0x0 0x0 0x0 0xc0000000>;
dma-ranges = <0x80000000 0x8 0x00000000 0x80000000>;

    [...]

    usb: usb@2680000 {
        compatible = "ti,keystone-dwc3";

        [...]
        dma-coherent;
    };

};

Appendix A - Sample SOC node for MPC8540

soc@e0000000 {
    #address-cells = <1>;
    #size-cells = <1>;
    compatible = "fsl,mpc8540-ccsr", "simple-bus";
    device_type = "soc";
    ranges = <0x00000000 0xe0000000 0x00100000>
    bus-frequency = <0>;
    interrupt-parent = <&pic>;

    ethernet@24000 {
        #address-cells = <1>;
        #size-cells = <1>;
        device_type = "network";
        model = "TSEC";
        compatible = "gianfar", "simple-bus";
        reg = <0x24000 0x1000>;
        local-mac-address = [ 0x00 0xE0 0x0C 0x00 0x73 0x00 ];
        interrupts = <0x29 2 0x30 2 0x34 2>;
        phy-handle = <&phy0>;
        sleep = <&pmc 0x00000080>;
        ranges;

        mdio@24520 {
            reg = <0x24520 0x20>;
            compatible = "fsl,gianfar-mdio";

            phy0: ethernet-phy@0 {
                interrupts = <5 1>;
                reg = <0>;
            };

            phy1: ethernet-phy@1 {
                interrupts = <5 1>;
                reg = <1>;
            };

            phy3: ethernet-phy@3 {
                interrupts = <7 1>;
                reg = <3>;
            };
        };
    };

    ethernet@25000 {
        device_type = "network";
        model = "TSEC";
        compatible = "gianfar";
        reg = <0x25000 0x1000>;
        local-mac-address = [ 0x00 0xE0 0x0C 0x00 0x73 0x01 ];
        interrupts = <0x13 2 0x14 2 0x18 2>;
        phy-handle = <&phy1>;
        sleep = <&pmc 0x00000040>;
    };

    ethernet@26000 {
        device_type = "network";
        model = "FEC";
        compatible = "gianfar";
        reg = <0x26000 0x1000>;
        local-mac-address = [ 0x00 0xE0 0x0C 0x00 0x73 0x02 ];
        interrupts = <0x41 2>;
        phy-handle = <&phy3>;
        sleep = <&pmc 0x00000020>;
    };

    serial@4500 {
        #address-cells = <1>;
        #size-cells = <1>;
        compatible = "fsl,mpc8540-duart", "simple-bus";
        sleep = <&pmc 0x00000002>;
        ranges;

        serial@4500 {
            device_type = "serial";
            compatible = "ns16550";
            reg = <0x4500 0x100>;
            clock-frequency = <0>;
            interrupts = <0x42 2>;
        };

        serial@4600 {
            device_type = "serial";
            compatible = "ns16550";
            reg = <0x4600 0x100>;
            clock-frequency = <0>;
            interrupts = <0x42 2>;
        };
    };

    pic: pic@40000 {
        interrupt-controller;
        #address-cells = <0>;
        #interrupt-cells = <2>;
        reg = <0x40000 0x40000>;
        compatible = "chrp,open-pic";
        device_type = "open-pic";
    };

    i2c@3000 {
        interrupts = <0x43 2>;
        reg = <0x3000 0x100>;
        compatible  = "fsl-i2c";
        dfsrr;
        sleep = <&pmc 0x00000004>;
    };

    pmc: power@e0070 {
        compatible = "fsl,mpc8540-pmc", "fsl,mpc8548-pmc";
        reg = <0xe0070 0x20>;
    };
};