| .. _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>; |
| label = "SUBNODE"; |
| }; |
| }; |
| }; |
| |
| 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``. 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. |
| |
| Node ``a-sub-node`` has an additional property named ``label``, whose value is a |
| string containing the value "SUBNODE". Note that the ``label`` property is |
| distinct from the *node label*. |
| |
| 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"; |
| label = "I2C_0"; |
| reg = <0x40003000 0x1000>; |
| |
| apds9960@39 { |
| compatible = "avago,apds9960"; |
| label = "APDS9960"; |
| reg = <0x39>; |
| }; |
| ti_hdc@43 { |
| compatible = "ti,hdc", "ti,hdc1010"; |
| label = "HDC1010"; |
| reg = <0x43>; |
| }; |
| mma8652fc@1d { |
| compatible = "nxp,fxos8700", "nxp,mma8652fc"; |
| label = "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``. |
| |
| label |
| The device's name according to Zephyr's :ref:`device_model_api`. The value |
| can be passed to :c:func:`device_get_binding()` to retrieve the |
| corresponding driver-level :ref:`struct device* <device_struct>`. This |
| pointer can then be passed to the correct driver API by application code to |
| interact with the device. For example, calling |
| ``device_get_binding("I2C_0")`` would return a pointer to a device |
| structure which could be passed to :ref:`I2C API <i2c_api>` functions like |
| :c:func:`i2c_transfer()`. The generated C header will also contain a macro |
| which expands to this string. |
| |
| Note that the ``label`` property is distinct from the :ref:`node |
| label <dt-node-labels>`. |
| |
| 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 |
| |
| .. _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. |
| |
| Zephyr currently uses :file:`dts_fixup.h` files to rename macros in |
| :file:`devicetree_unfixed.h` to names that are currently in use by C code. The |
| build system looks for fixup files in the :file:`zephyr/boards/` and |
| :file:`zephyr/soc/` directories by default. Fixup files exist for historical |
| reasons. New code should generally avoid them. |
| |
| .. _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_unfixed.h`. |
| |
| :file:`<build>/zephyr/include/generated/devicetree_unfixed.h` |
| The generated macros and additional comments describing the devicetree. |
| Included by ``devicetree.h``. |
| |
| :file:`<build>/zephyr/include/generated/devicetree_fixups.h` |
| The concatenated contents of any :file:`dts_fixup.h` files. |
| 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. |