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.. _devicetree-intro:
Introduction to devicetree
##########################
.. tip::
This is a conceptual overview of devicetree and how Zephyr uses it. For
step-by-step guides and examples, see :ref:`dt-howtos`.
A *devicetree* is a hierarchical data structure that describes hardware. The
`Devicetree specification`_ defines its source and binary representations.
Zephyr uses devicetree to describe the hardware available on its :ref:`boards`,
as well as that hardware's initial configuration.
There are two types of devicetree input files: *devicetree sources* and
*devicetree bindings*. The sources contain the devicetree itself. The bindings
describe its contents, including data types. The :ref:`build system
<build_overview>` uses devicetree sources and bindings to produce a generated C
header. The generated header's contents are abstracted by the ``devicetree.h``
API, which you can use to get information from your devicetree.
Here is a simplified view of the process:
.. figure:: zephyr_dt_build_flow.png
:figclass: align-center
Devicetree build flow
All Zephyr and application source code files can include and use
``devicetree.h``. This includes :ref:`device drivers <device_model_api>`,
:ref:`applications <application>`, :ref:`tests <testing>`, the kernel, etc.
The API itself is based on C macros. The macro names all start with ``DT_``. In
general, if you see a macro that starts with ``DT_`` in a Zephyr source file,
it's probably a ``devicetree.h`` macro. The generated C header contains macros
that start with ``DT_`` as well; you might see those in compiler error
messages. You always can tell a generated- from a non-generated macro:
generated macros have some lowercased letters, while the ``devicetree.h`` macro
names have all capital letters.
Some information defined in devicetree is available via ``CONFIG_`` macros
generated from :ref:`Kconfig <kconfig>`. This is often done for backwards
compatibility, since Zephyr has used Kconfig for longer than devicetree, and is
still in the process of converting some information from Kconfig to devicetree.
It is also done to allow Kconfig overrides of default values taken from
devicetree. Devicetree information is referenced from Kconfig via :ref:`Kconfig
functions <kconfig-functions>`. See :ref:`dt_vs_kconfig` for some additional
comparisons with Kconfig.
.. _dt-syntax:
Syntax and structure
********************
As the name indicates, a devicetree is a tree. The human-readable text format
for this tree is called DTS (for devicetree source), and is defined in the
`Devicetree specification`_.
.. _Devicetree specification: https://www.devicetree.org/
Here is an example DTS file:
.. code-block:: devicetree
/dts-v1/;
/ {
a-node {
subnode_nodelabel: a-sub-node {
foo = <3>;
};
};
};
The ``/dts-v1/;`` line means the file's contents are in version 1 of the DTS
syntax, which has replaced a now-obsolete "version 0".
The tree has three *nodes*:
#. A root node: ``/``
#. A node named ``a-node``, which is a child of the root node
#. A node named ``a-sub-node``, which is a child of ``a-node``
.. _dt-node-labels:
Nodes can be assigned *node labels*, which are unique shorthands that can be
used to refer to the labeled node elsewhere in the devicetree. Above,
``a-sub-node`` has the *node label* ``subnode_nodelabel``, which can be
accessed via ``DT_NODELABEL(subnode_nodelabel)``. A node can have zero, one, or
multiple *node labels*.
Devicetree nodes have *paths* identifying their locations in the tree. Like
Unix file system paths, devicetree paths are strings separated by slashes
(``/``), and the root node's path is a single slash: ``/``. Otherwise, each
node's path is formed by concatenating the node's ancestors' names with the
node's own name, separated by slashes. For example, the full path to
``a-sub-node`` is ``/a-node/a-sub-node``.
Devicetree nodes can also have *properties*. Properties are name/value pairs.
Property values can be any sequence of bytes. In some cases, the values are an
array of what are called *cells*. A cell is just a 32-bit unsigned integer.
Node ``a-sub-node`` has a property named ``foo``, whose value is a cell with
value 3. The size and type of ``foo``\ 's value are implied by the enclosing
angle brackets (``<`` and ``>``) in the DTS.
See :ref:`dt-writing-property-values` below for more example property values.
In practice, devicetree nodes usually correspond to some hardware, and the node
hierarchy reflects the hardware's physical layout. For example, let's consider
a board with three I2C peripherals connected to an I2C bus controller on an SoC,
like this:
.. figure:: zephyr_dt_i2c_high_level.png
:alt: representation of a board with three I2C peripherals
:figclass: align-center
Nodes corresponding to the I2C bus controller and each I2C peripheral would be
present in the devicetree. Reflecting the hardware layout, the
I2C peripheral nodes would be children of the bus controller node.
Similar conventions exist for representing other types of hardware.
The DTS would look something like this:
.. code-block:: devicetree
/dts-v1/;
/ {
soc {
i2c-bus-controller {
i2c-peripheral-1 {
};
i2c-peripheral-2 {
};
i2c-peripheral-3 {
};
};
};
};
Properties are used in practice to describe or configure the hardware the node
represents. For example, an I2C peripheral's node has a property whose value is
the peripheral's address on the bus.
Here's a tree representing the same example, but with real-world node
names and properties you might see when working with I2C devices.
.. figure:: zephyr_dt_i2c_example.png
:figclass: align-center
I2C devicetree example with real-world names and properties.
Node names are at the top of each node with a gray background.
Properties are shown as "name=value" lines.
This is the corresponding DTS:
.. code-block:: devicetree
/dts-v1/;
/ {
soc {
i2c@40003000 {
compatible = "nordic,nrf-twim";
reg = <0x40003000 0x1000>;
apds9960@39 {
compatible = "avago,apds9960";
reg = <0x39>;
};
ti_hdc@43 {
compatible = "ti,hdc", "ti,hdc1010";
reg = <0x43>;
};
mma8652fc@1d {
compatible = "nxp,fxos8700", "nxp,mma8652fc";
reg = <0x1d>;
};
};
};
};
.. _dt-unit-address:
In addition to showing more realistic names and properties, the above example
introduces a new devicetree concept: unit addresses. Unit addresses are the
parts of node names after an "at" sign (``@``), like ``40003000`` in
``i2c@40003000``, or ``39`` in ``apds9960@39``. Unit addresses are optional:
the ``soc`` node does not have one.
Some more details about unit addresses and important properties follow.
Unit address examples
*********************
In devicetree, unit addresses give a node's address in the
address space of its parent node. Here are some example unit addresses for
different types of hardware.
Memory-mapped peripherals
The peripheral's register map base address.
For example, the node named ``i2c@40003000`` represents an I2C controller
whose register map base address is 0x40003000.
I2C peripherals
The peripheral's address on the I2C bus.
For example, the child node ``apds9960@39`` of the I2C controller
in the previous section has I2C address 0x39.
SPI peripherals
An index representing the peripheral's chip select line number.
(If there is no chip select line, 0 is used.)
Memory
The physical start address.
For example, a node named ``memory@2000000`` represents RAM starting at
physical address 0x2000000.
Memory-mapped flash
Like RAM, the physical start address.
For example, a node named ``flash@8000000`` represents a flash device
whose physical start address is 0x8000000.
Fixed flash partitions
This applies when the devicetree is used to store a flash partition table.
The unit address is the partition's start offset within the flash memory.
For example, take this flash device and its partitions:
.. code-block:: devicetree
flash@8000000 {
/* ... */
partitions {
partition@0 { /* ... */ };
partition@20000 { /* ... */ };
/* ... */
};
};
The node named ``partition@0`` has offset 0 from the start of its flash
device, so its base address is 0x8000000. Similarly, the base address of
the node named ``partition@20000`` is 0x8020000.
.. _dt-important-props:
Important properties
********************
.. Documentation maintainers: If you add a property to this list,
make sure it gets linked to from gen_devicetree_rest.py too.
Some important properties are:
compatible
The name of the hardware device the node represents.
The recommended format is ``"vendor,device"``, like ``"avago,apds9960"``,
or a sequence of these, like ``"ti,hdc", "ti,hdc1010"``. The ``vendor``
part is an abbreviated name of the vendor. The file
:zephyr_file:`dts/bindings/vendor-prefixes.txt` contains a list of commonly
accepted ``vendor`` names. The ``device`` part is usually taken from the
datasheet.
It is also sometimes a value like ``gpio-keys``, ``mmio-sram``, or
``fixed-clock`` when the hardware's behavior is generic.
The build system uses the compatible property to find the right
:ref:`bindings <dt-bindings>` for the node. Device drivers use
``devicetree.h`` to find nodes with relevant compatibles, in order to
determine the available hardware to manage.
The ``compatible`` property can have multiple values. Additional values are
useful when the device is a specific instance of a more general family, to
allow the system to match from most- to least-specific device drivers.
Within Zephyr's bindings syntax, this property has type ``string-array``.
reg
Information used to address the device. The value is specific to the device
(i.e. is different depending on the compatible property).
The ``reg`` property is a sequence of ``(address, length)`` pairs. Each
pair is called a "register block". Here are some common patterns:
- Devices accessed via memory-mapped I/O registers (like ``i2c@40003000``):
``address`` is usually the base address of the I/O register space, and
``length`` is the number of bytes occupied by the registers.
- I2C devices (like ``apds9960@39`` and its siblings):
``address`` is a slave address on the I2C bus. There is no ``length``
value.
- SPI devices: ``address`` is a chip select line number; there is no
``length``.
You may notice some similarities between the ``reg`` property and common
unit addresses described above. This is not a coincidence. The ``reg``
property can be seen as a more detailed view of the addressable resources
within a device than its unit address.
status
A string which describes whether the node is enabled.
The devicetree specification allows this property to have values
``"okay"``, ``"disabled"``, ``"reserved"``, ``"fail"``, and ``"fail-sss"``.
Only the values ``"okay"`` and ``"disabled"`` are currently relevant to
Zephyr; use of other values currently results in undefined behavior.
A node is considered enabled if its status property is either ``"okay"`` or
not defined (i.e. does not exist in the devicetree source). Nodes with
status ``"disabled"`` are explicitly disabled. (For backwards
compatibility, the value ``"ok"`` is treated the same as ``"okay"``, but
this usage is deprecated.) Devicetree nodes which correspond to physical
devices must be enabled for the corresponding ``struct device`` in the
Zephyr driver model to be allocated and initialized.
interrupts
Information about interrupts generated by the device, encoded as an array
of one or more *interrupt specifiers*. Each interrupt specifier has some
number of cells. See section 2.4, *Interrupts and Interrupt Mapping*, in the
`Devicetree Specification release v0.3`_ for more details.
Zephyr's devicetree bindings language lets you give a name to each cell in
an interrupt specifier.
.. _Devicetree Specification release v0.3:
https://www.devicetree.org/specifications/
.. highlight:: none
.. note::
Earlier versions of Zephyr made frequent use of the ``label`` property,
which is distinct from the standard :ref:`node label <dt-node-labels>`.
Use of the label *property* in new devicetree bindings, as well as use of
the :c:macro:`DT_LABEL` macro in new code, are actively discouraged. Label
properties continue to persist for historical reasons in some existing
bindings and overlays, but should not be used in new bindings or device
implementations.
.. _dt-writing-property-values:
Writing property values
***********************
This section describes how to write property values in DTS format. The property
types in the table below are described in detail in :ref:`dt-bindings`.
Some specifics are skipped in the interest of keeping things simple; if you're
curious about details, see the devicetree specification.
.. list-table::
:header-rows: 1
:widths: 1 4 4
* - Property type
- How to write
- Example
* - string
- Double quoted
- ``a-string = "hello, world!";``
* - int
- between angle brackets (``<`` and ``>``)
- ``an-int = <1>;``
* - boolean
- for ``true``, with no value (for ``false``, use ``/delete-property/``)
- ``my-true-boolean;``
* - array
- between angle brackets (``<`` and ``>``), separated by spaces
- ``foo = <0xdeadbeef 1234 0>;``
* - uint8-array
- in hexadecimal *without* leading ``0x``, between square brackets (``[`` and ``]``).
- ``a-byte-array = [00 01 ab];``
* - string-array
- separated by commas
- ``a-string-array = "string one", "string two", "string three";``
* - phandle
- between angle brackets (``<`` and ``>``)
- ``a-phandle = <&mynode>;``
* - phandles
- between angle brackets (``<`` and ``>``), separated by spaces
- ``some-phandles = <&mynode0 &mynode1 &mynode2>;``
* - phandle-array
- between angle brackets (``<`` and ``>``), separated by spaces
- ``a-phandle-array = <&mynode0 1 2 &mynode1 3 4>;``
Additional notes on the above:
- Boolean properties are true if present. They should not have a value.
A boolean property is only false if it is completely missing in the DTS.
- The ``foo`` property value above has three *cells* with values 0xdeadbeef, 1234,
and 0, in that order. Note that hexadecimal and decimal numbers are allowed and
can be intermixed. Since Zephyr transforms DTS to C sources, it is not
necessary to specify the endianness of an individual cell here.
- 64-bit integers are written as two 32-bit cells in big-endian order. The value
0xaaaa0000bbbb1111 would be written ``<0xaaaa0000 0xbbbb1111>``.
- The ``a-byte-array`` property value is the three bytes 0x00, 0x01, and 0xab, in
that order.
- Parentheses, arithmetic operators, and bitwise operators are allowed. The
``bar`` property contains a single cell with value 64::
bar = <(2 * (1 << 5))>;
Note that the entire expression must be parenthesized.
- Property values refer to other nodes in the devicetree by their *phandles*.
You can write a phandle using ``&foo``, where ``foo`` is a :ref:`node label
<dt-node-labels>`. Here is an example devicetree fragment:
.. code-block:: devicetree
foo: device@0 { };
device@1 {
sibling = <&foo 1 2>;
};
The ``sibling`` property of node ``device@1`` contains three cells, in this order:
#. The ``device@0`` node's phandle, which is written here as ``&foo`` since
the ``device@0`` node has a node label ``foo``
#. The value 1
#. The value 2
In the devicetree, a phandle value is a cell -- which again is just a 32-bit
unsigned int. However, the Zephyr devicetree API generally exposes these
values as *node identifiers*. Node identifiers are covered in more detail in
:ref:`dt-from-c`.
- Array and similar type property values can be split into several ``<>``
blocks, like this:
.. code-block:: none
foo = <1 2>, <3 4>; // Okay for 'type: array'
foo = <&label1 &label2>, <&label3 &label4>; // Okay for 'type: phandles'
foo = <&label1 1 2>, <&label2 3 4>; // Okay for 'type: phandle-array'
This is recommended for readability when possible if the value can be
logically grouped into blocks of sub-values.
.. _dt-alias-chosen:
Aliases and chosen nodes
************************
There are two additional ways beyond :ref:`node labels <dt-node-labels>` to
refer to a particular node without specifying its entire path: by alias, or by
chosen node.
Here is an example devicetree which uses both:
.. code-block:: devicetree
/dts-v1/;
/ {
chosen {
zephyr,console = &uart0;
};
aliases {
my-uart = &uart0;
};
soc {
uart0: serial@12340000 {
...
};
};
};
The ``/aliases`` and ``/chosen`` nodes do not refer to an actual hardware
device. Their purpose is to specify other nodes in the devicetree.
Above, ``my-uart`` is an alias for the node with path ``/soc/serial@12340000``.
Using its node label ``uart0``, the same node is set as the value of the chosen
``zephyr,console`` node.
Zephyr sample applications sometimes use aliases to allow overriding the
particular hardware device used by the application in a generic way. For
example, :ref:`blinky-sample` uses this to abstract the LED to blink via the
``led0`` alias.
The ``/chosen`` node's properties are used to configure system- or
subsystem-wide values. See :ref:`devicetree-chosen-nodes` for more information.
.. _devicetree-in-out-files:
Input and output files
**********************
This section describes the input and output files shown in the figure at the
:ref:`top of this introduction <devicetree-intro>` in more detail.
.. figure:: zephyr_dt_inputs_outputs.svg
:figclass: align-center
Devicetree input (green) and output (yellow) files
.. _dt-input-files:
Input files
===========
There are four types of devicetree input files:
- sources (``.dts``)
- includes (``.dtsi``)
- overlays (``.overlay``)
- bindings (``.yaml``)
The devicetree files inside the :file:`zephyr` directory look like this::
boards/<ARCH>/<BOARD>/<BOARD>.dts
dts/common/skeleton.dtsi
dts/<ARCH>/.../<SOC>.dtsi
dts/bindings/.../binding.yaml
Generally speaking, every supported board has a :file:`BOARD.dts` file
describing its hardware. For example, the ``reel_board`` has
:zephyr_file:`boards/arm/reel_board/reel_board.dts`.
:file:`BOARD.dts` includes one or more ``.dtsi`` files. These ``.dtsi`` files
describe the CPU or system-on-chip Zephyr runs on, perhaps by including other
``.dtsi`` files. They can also describe other common hardware features shared by
multiple boards. In addition to these includes, :file:`BOARD.dts` also describes
the board's specific hardware.
The :file:`dts/common` directory contains :file:`skeleton.dtsi`, a minimal
include file for defining a complete devicetree. Architecture-specific
subdirectories (:file:`dts/<ARCH>`) contain ``.dtsi`` files for CPUs or SoCs
which extend :file:`skeleton.dtsi`.
The C preprocessor is run on all devicetree files to expand macro references,
and includes are generally done with ``#include <filename>`` directives, even
though DTS has a ``/include/ "<filename>"`` syntax.
:file:`BOARD.dts` can be extended or modified using *overlays*. Overlays are
also DTS files; the :file:`.overlay` extension is just a convention which makes
their purpose clear. Overlays adapt the base devicetree for different purposes:
- Zephyr applications can use overlays to enable a peripheral that is disabled
by default, select a sensor on the board for an application specific purpose,
etc. Along with :ref:`kconfig`, this makes it possible to reconfigure the
kernel and device drivers without modifying source code.
- Overlays are also used when defining :ref:`shields`.
The build system automatically picks up :file:`.overlay` files stored in
certain locations. It is also possible to explicitly list the overlays to
include, via the :makevar:`DTC_OVERLAY_FILE` CMake variable. See
:ref:`set-devicetree-overlays` for details.
The build system combines :file:`BOARD.dts` and any :file:`.overlay` files by
concatenating them, with the overlays put last. This relies on DTS syntax which
allows merging overlapping definitions of nodes in the devicetree. See
:ref:`dt_k6x_example` for an example of how this works (in the context of
``.dtsi`` files, but the principle is the same for overlays). Putting the
contents of the :file:`.overlay` files last allows them to override
:file:`BOARD.dts`.
:ref:`dt-bindings` (which are YAML files) are essentially glue. They describe
the contents of devicetree sources, includes, and overlays in a way that allows
the build system to generate C macros usable by device drivers and
applications. The :file:`dts/bindings` directory contains bindings.
.. _dt-scripts:
Scripts and tools
=================
The following libraries and scripts, located in :zephyr_file:`scripts/dts/`,
create output files from input files. Their sources have extensive
documentation.
:zephyr_file:`dtlib.py <scripts/dts/dtlib.py>`
A low-level DTS parsing library.
:zephyr_file:`edtlib.py <scripts/dts/edtlib.py>`
A library layered on top of dtlib that uses bindings to interpret
properties and give a higher-level view of the devicetree. Uses dtlib to do
the DTS parsing.
:zephyr_file:`gen_defines.py <scripts/dts/gen_defines.py>`
A script that uses edtlib to generate C preprocessor macros from the
devicetree and bindings.
In addition to these, the standard ``dtc`` (devicetree compiler) tool is run on
the final devicetree if it is installed on your system. This is just to catch
errors or warnings. The output is unused. Boards may need to pass ``dtc``
additional flags, e.g. for warning suppression. Board directories can contain a
file named :file:`pre_dt_board.cmake` which configures these extra flags, like
this:
.. code-block:: cmake
list(APPEND EXTRA_DTC_FLAGS "-Wno-simple_bus_reg")
.. _dt-outputs:
Output files
============
These are created in your application's build directory.
.. warning::
Don't include the header files directly. :ref:`dt-from-c` explains
what to do instead.
:file:`<build>/zephyr/zephyr.dts.pre`
The preprocessed DTS source. This is an intermediate output file, which is
input to :file:`gen_defines.py` and used to create :file:`zephyr.dts` and
:file:`devicetree_generated.h`.
:file:`<build>/zephyr/include/generated/devicetree_generated.h`
The generated macros and additional comments describing the devicetree.
Included by ``devicetree.h``.
:file:`<build>/zephyr/zephyr.dts`
The final merged devicetree. This file is output by :file:`gen_defines.py`.
It is useful for debugging any issues. If the devicetree compiler ``dtc`` is
installed, it is also run on this file, to catch any additional warnings or
errors.