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Devicetree HOWTOs

This page has step-by-step advice for getting things done with devicetree.

Tip

See Troubleshooting devicetree for troubleshooting advice.

Get your devicetree and generated header

A board’s devicetree (BOARD.dts) pulls in common node definitions via #include preprocessor directives. This at least includes the SoC’s .dtsi. One way to figure out the devicetree’s contents is by opening these files, e.g. by looking in dts/<ARCH>/<vendor>/<soc>.dtsi, but this can be time consuming.

If you just want to see the “final” devicetree for your board, build an application and open the zephyr.dts file in the build directory.

Tip

You can build Hello World to see the “base” devicetree for your board without any additional changes from overlay files.

For example, using the QEMU Emulation for ARM Cortex-M3 board to build Hello World:

# --cmake-only here just forces CMake to run, skipping the
# build process to save time.
west build -b qemu_cortex_m3 samples/hello_world --cmake-only

You can change qemu_cortex_m3 to match your board.

CMake prints the input and output file locations like this:

-- Found BOARD.dts: .../zephyr/boards/arm/qemu_cortex_m3/qemu_cortex_m3.dts
-- Generated zephyr.dts: .../zephyr/build/zephyr/zephyr.dts
-- Generated devicetree_generated.h: .../zephyr/build/zephyr/include/generated/zephyr/devicetree_generated.h

The zephyr.dts file is the final devicetree in DTS format.

The devicetree_generated.h file is the corresponding generated header.

See Input and output files for details about these files.

Get a struct device from a devicetree node

When writing Zephyr applications, you’ll often want to get a driver-level struct device corresponding to a devicetree node.

For example, with this devicetree fragment, you might want the struct device for serial@40002000:

/ {
        soc {
                serial0: serial@40002000 {
                        status = "okay";
                        current-speed = <115200>;
                        /* ... */
                };
        };

        aliases {
                my-serial = &serial0;
        };

        chosen {
                zephyr,console = &serial0;
        };
};

Start by making a node identifier for the device you are interested in. There are different ways to do this; pick whichever one works best for your requirements. Here are some examples:

/* Option 1: by node label */
#define MY_SERIAL DT_NODELABEL(serial0)

/* Option 2: by alias */
#define MY_SERIAL DT_ALIAS(my_serial)

/* Option 3: by chosen node */
#define MY_SERIAL DT_CHOSEN(zephyr_console)

/* Option 4: by path */
#define MY_SERIAL DT_PATH(soc, serial_40002000)

Once you have a node identifier there are two ways to proceed. One way to get a device is to use DEVICE_DT_GET:

const struct device *const uart_dev = DEVICE_DT_GET(MY_SERIAL);

if (!device_is_ready(uart_dev)) {
        /* Not ready, do not use */
        return -ENODEV;
}

There are variants of DEVICE_DT_GET such as DEVICE_DT_GET_OR_NULL, DEVICE_DT_GET_ONE or DEVICE_DT_GET_ANY. This idiom fetches the device pointer at build-time, which means there is no runtime penalty. This method is useful if you want to store the device pointer as configuration data. But because the device may not be initialized, or may have failed to initialize, you must verify that the device is ready to be used before passing it to any API functions. (This check is done for you by device_get_binding().)

In some situations the device cannot be known at build-time, e.g., if it depends on user input like in a shell application. In this case you can get the struct device by combining device_get_binding() with the device name:

const char *dev_name = /* TODO: insert device name from user */;
const struct device *uart_dev = device_get_binding(dev_name);

You can then use uart_dev with Universal Asynchronous Receiver-Transmitter (UART) API functions like uart_configure(). Similar code will work for other device types; just make sure you use the correct API for the device.

If you’re having trouble, see Troubleshooting devicetree. The first thing to check is that the node has status = "okay", like this:

#define MY_SERIAL DT_NODELABEL(my_serial)

#if DT_NODE_HAS_STATUS(MY_SERIAL, okay)
const struct device *const uart_dev = DEVICE_DT_GET(MY_SERIAL);
#else
#error "Node is disabled"
#endif

If you see the #error output, make sure to enable the node in your devicetree. In some situations your code will compile but it will fail to link with a message similar to:

...undefined reference to `__device_dts_ord_N'
collect2: error: ld returned 1 exit status

This likely means there’s a Kconfig issue preventing the device driver from being built, resulting in a reference that does not exist. If your code compiles successfully, the last thing to check is if the device is ready, like this:

if (!device_is_ready(uart_dev)) {
     printk("Device not ready\n");
}

If you find that the device is not ready, it likely means that the device’s initialization function failed. Enabling logging or debugging driver code may help in such situations. Note that you can also use device_get_binding() to obtain a reference at runtime. If it returns NULL it can either mean that device’s driver failed to initialize or that it does not exist.

Find a devicetree binding

Devicetree bindings are YAML files which declare what you can do with the nodes they describe, so it’s critical to be able to find them for the nodes you are using.

If you don’t have them already, Get your devicetree and generated header. To find a node’s binding, open the generated header file, which starts with a list of nodes in a block comment:

/*
 * [...]
 * Nodes in dependency order (ordinal and path):
 *   0   /
 *   1   /aliases
 *   2   /chosen
 *   3   /flash@0
 *   4   /memory@20000000
 *          (etc.)
 * [...]
 */

Make note of the path to the node you want to find, like /flash@0. Search for the node’s output in the file, which starts with something like this if the node has a matching binding:

/*
 * Devicetree node:
 *   /flash@0
 *
 * Binding (compatible = soc-nv-flash):
 *   $ZEPHYR_BASE/dts/bindings/mtd/soc-nv-flash.yaml
 * [...]
 */

See Check for missing bindings for troubleshooting.

Set devicetree overlays

Devicetree overlays are explained in Introduction to devicetree. The CMake variable DTC_OVERLAY_FILE contains a space- or semicolon-separated list of overlay files to use. If DTC_OVERLAY_FILE specifies multiple files, they are included in that order by the C preprocessor. A file in a Zephyr module can be referred to by escaping the Zephyr module dir variable like \${ZEPHYR_<module>_MODULE_DIR}/<path-to>/dts.overlay when setting the DTC_OVERLAY_FILE variable.

You can set DTC_OVERLAY_FILE to contain exactly the files you want to use. Here is an example using west build.

If you don’t set DTC_OVERLAY_FILE, the build system will follow these steps, looking for files in your application configuration directory to use as devicetree overlays:

  1. If the file socs/<SOC>_<BOARD_QUALIFIERS>.overlay exists, it will be used.

  2. If the file boards/<BOARD>.overlay exists, it will be used in addition to the above.

  3. If the current board has multiple revisions and boards/<BOARD>_<revision>.overlay exists, it will be used in addition to the above.

  4. If one or more files have been found in the previous steps, the build system stops looking and just uses those files.

  5. Otherwise, if <BOARD>.overlay exists, it will be used, and the build system will stop looking for more files.

  6. Otherwise, if app.overlay exists, it will be used.

Extra devicetree overlays may be provided using EXTRA_DTC_OVERLAY_FILE which will still allow the build system to automatically use devicetree overlays described in the above steps.

The build system appends overlays specified in EXTRA_DTC_OVERLAY_FILE to the overlays in DTC_OVERLAY_FILE when processing devicetree overlays. This means that changes made via EXTRA_DTC_OVERLAY_FILE have higher precedence than those made via DTC_OVERLAY_FILE.

All configuration files will be taken from the application’s configuration directory except for files with an absolute path that are given with the DTC_OVERLAY_FILE or EXTRA_DTC_OVERLAY_FILE argument.

See Application Configuration Directory on how the application configuration directory is defined.

Using Shields will also add devicetree overlay files.

The DTC_OVERLAY_FILE value is stored in the CMake cache and used in successive builds.

The build system prints all the devicetree overlays it finds in the configuration phase, like this:

-- Found devicetree overlay: .../some/file.overlay

Use devicetree overlays

See Set devicetree overlays for how to add an overlay to the build.

Overlays can override node property values in multiple ways. For example, if your BOARD.dts contains this node:

/ {
        soc {
                serial0: serial@40002000 {
                        status = "okay";
                        current-speed = <115200>;
                        /* ... */
                };
        };
};

These are equivalent ways to override the current-speed value in an overlay:

/* Option 1 */
&serial0 {
     current-speed = <9600>;
};

/* Option 2 */
&{/soc/serial@40002000} {
     current-speed = <9600>;
};

We’ll use the &serial0 style for the rest of these examples.

You can add aliases to your devicetree using overlays: an alias is just a property of the /aliases node. For example:

/ {
     aliases {
             my-serial = &serial0;
     };
};

Chosen nodes work the same way. For example:

/ {
     chosen {
             zephyr,console = &serial0;
     };
};

To delete a property (in addition to deleting properties in general, this is how to set a boolean property to false if it’s true in BOARD.dts):

&serial0 {
     /delete-property/ some-unwanted-property;
};

You can add subnodes using overlays. For example, to configure a SPI or I2C child device on an existing bus node, do something like this:

/* SPI device example */
&spi1 {
     my_spi_device: temp-sensor@0 {
             compatible = "...";
             label = "TEMP_SENSOR_0";
             /* reg is the chip select number, if needed;
              * If present, it must match the node's unit address. */
             reg = <0>;

             /* Configure other SPI device properties as needed.
              * Find your device's DT binding for details. */
             spi-max-frequency = <4000000>;
     };
};

/* I2C device example */
&i2c2 {
     my_i2c_device: touchscreen@76 {
             compatible = "...";
             label = "TOUCHSCREEN";
             /* reg is the I2C device address.
              * It must match the node's unit address. */
             reg = <76>;

             /* Configure other I2C device properties as needed.
              * Find your device's DT binding for details. */
     };
};

Other bus devices can be configured similarly:

  • create the device as a subnode of the parent bus

  • set its properties according to its binding

Assuming you have a suitable device driver associated with the my_spi_device and my_i2c_device compatibles, you should now be able to enable the driver via Kconfig and get the struct device for your newly added bus node, then use it with that driver API.

Write device drivers using devicetree APIs

“Devicetree-aware” device drivers should create a struct device for each status = "okay" devicetree node with a particular compatible (or related set of compatibles) supported by the driver.

Writing a devicetree-aware driver begins by defining a devicetree binding for the devices supported by the driver. Use existing bindings from similar drivers as a starting point. A skeletal binding to get started needs nothing more than this:

description: <Human-readable description of your binding>
compatible: "foo-company,bar-device"
include: base.yaml

See Find a devicetree binding for more advice on locating existing bindings.

After writing your binding, your driver C file can then use the devicetree API to find status = "okay" nodes with the desired compatible, and instantiate a struct device for each one. There are two options for instantiating each struct device: using instance numbers, and using node labels.

In either case:

  • Each struct device‘s name should be set to its devicetree node’s label property. This allows the driver’s users to Get a struct device from a devicetree node in the usual way.

  • Each device’s initial configuration should use values from devicetree properties whenever practical. This allows users to configure the driver using devicetree overlays.

Examples for how to do this follow. They assume you’ve already implemented the device-specific configuration and data structures and API functions, like this:

/* my_driver.c */
#include <zephyr/drivers/some_api.h>

/* Define data (RAM) and configuration (ROM) structures: */
struct my_dev_data {
     /* per-device values to store in RAM */
};
struct my_dev_cfg {
     uint32_t freq; /* Just an example: initial clock frequency in Hz */
     /* other configuration to store in ROM */
};

/* Implement driver API functions (drivers/some_api.h callbacks): */
static int my_driver_api_func1(const struct device *dev, uint32_t *foo) { /* ... */ }
static int my_driver_api_func2(const struct device *dev, uint64_t bar) { /* ... */ }
static struct some_api my_api_funcs = {
     .func1 = my_driver_api_func1,
     .func2 = my_driver_api_func2,
};

Option 1: create devices using instance numbers

Use this option, which uses Instance-based APIs, if possible. However, they only work when devicetree nodes for your driver’s compatible are all equivalent, and you do not need to be able to distinguish between them.

To use instance-based APIs, begin by defining DT_DRV_COMPAT to the lowercase-and-underscores version of the compatible that the device driver supports. For example, if your driver’s compatible is "vnd,my-device" in devicetree, you would define DT_DRV_COMPAT to vnd_my_device in your driver C file:

/*
 * Put this near the top of the file. After the includes is a good place.
 * (Note that you can therefore run "git grep DT_DRV_COMPAT drivers" in
 * the zephyr Git repository to look for example drivers using this style).
 */
#define DT_DRV_COMPAT vnd_my_device

Important

As shown, the DT_DRV_COMPAT macro should have neither quotes nor special characters. Remove quotes and convert special characters to underscores when creating DT_DRV_COMPAT from the compatible property.

Finally, define an instantiation macro, which creates each struct device using instance numbers. Do this after defining my_api_funcs.

/*
 * This instantiation macro is named "CREATE_MY_DEVICE".
 * Its "inst" argument is an arbitrary instance number.
 *
 * Put this near the end of the file, e.g. after defining "my_api_funcs".
 */
#define CREATE_MY_DEVICE(inst)                                       \
     static struct my_dev_data my_data_##inst = {                    \
             /* initialize RAM values as needed, e.g.: */            \
             .freq = DT_INST_PROP(inst, clock_frequency),            \
     };                                                              \
     static const struct my_dev_cfg my_cfg_##inst = {                \
             /* initialize ROM values as needed. */                  \
     };                                                              \
     DEVICE_DT_INST_DEFINE(inst,                                     \
                           my_dev_init_function,                     \
                           NULL,                                     \
                           &my_data_##inst,                          \
                           &my_cfg_##inst,                           \
                           MY_DEV_INIT_LEVEL, MY_DEV_INIT_PRIORITY,  \
                           &my_api_funcs);

Notice the use of APIs like DT_INST_PROP and DEVICE_DT_INST_DEFINE to access devicetree node data. These APIs retrieve data from the devicetree for instance number inst of the node with compatible determined by DT_DRV_COMPAT.

Finally, pass the instantiation macro to DT_INST_FOREACH_STATUS_OKAY:

/* Call the device creation macro for each instance: */
DT_INST_FOREACH_STATUS_OKAY(CREATE_MY_DEVICE)

DT_INST_FOREACH_STATUS_OKAY expands to code which calls CREATE_MY_DEVICE once for each enabled node with the compatible determined by DT_DRV_COMPAT. It does not append a semicolon to the end of the expansion of CREATE_MY_DEVICE, so the macro’s expansion must end in a semicolon or function definition to support multiple devices.

Option 2: create devices using node labels

Some device drivers cannot use instance numbers. One example is an SoC peripheral driver which relies on vendor HAL APIs specialized for individual IP blocks to implement Zephyr driver callbacks. Cases like this should use DT_NODELABEL to refer to individual nodes in the devicetree representing the supported peripherals on the SoC. The devicetree.h Generic APIs can then be used to access node data.

For this to work, your SoC’s dtsi file must define node labels like mydevice0, mydevice1, etc. appropriately for the IP blocks your driver supports. The resulting devicetree usually looks something like this:

/ {
        soc {
                mydevice0: dev@0 {
                        compatible = "vnd,my-device";
                };
                mydevice1: dev@1 {
                        compatible = "vnd,my-device";
                };
        };
};

The driver can use the mydevice0 and mydevice1 node labels in the devicetree to operate on specific device nodes:

/*
 * This is a convenience macro for creating a node identifier for
 * the relevant devices. An example use is MYDEV(0) to refer to
 * the node with label "mydevice0".
 */
#define MYDEV(idx) DT_NODELABEL(mydevice ## idx)

/*
 * Define your instantiation macro; "idx" is a number like 0 for mydevice0
 * or 1 for mydevice1. It uses MYDEV() to create the node label from the
 * index.
 */
#define CREATE_MY_DEVICE(idx)                                        \
     static struct my_dev_data my_data_##idx = {                     \
             /* initialize RAM values as needed, e.g.: */            \
             .freq = DT_PROP(MYDEV(idx), clock_frequency),           \
     };                                                              \
     static const struct my_dev_cfg my_cfg_##idx = { /* ... */ };    \
     DEVICE_DT_DEFINE(MYDEV(idx),                                    \
                     my_dev_init_function,                           \
                     NULL,                                           \
                     &my_data_##idx,                                 \
                     &my_cfg_##idx,                                  \
                     MY_DEV_INIT_LEVEL, MY_DEV_INIT_PRIORITY,        \
                     &my_api_funcs)

Notice the use of APIs like DT_PROP and DEVICE_DT_DEFINE to access devicetree node data.

Finally, manually detect each enabled devicetree node and use CREATE_MY_DEVICE to instantiate each struct device:

#if DT_NODE_HAS_STATUS(DT_NODELABEL(mydevice0), okay)
CREATE_MY_DEVICE(0)
#endif

#if DT_NODE_HAS_STATUS(DT_NODELABEL(mydevice1), okay)
CREATE_MY_DEVICE(1)
#endif

Since this style does not use DT_INST_FOREACH_STATUS_OKAY(), the driver author is responsible for calling CREATE_MY_DEVICE() for every possible node, e.g. using knowledge about the peripherals available on supported SoCs.

Device drivers that depend on other devices

At times, one struct device depends on another struct device and requires a pointer to it. For example, a sensor device might need a pointer to its SPI bus controller device. Some advice:

Search existing bindings and device drivers for examples.

Applications that depend on board-specific devices

One way to allow application code to run unmodified on multiple boards is by supporting a devicetree alias to specify the hardware specific portions, as is done in the Blinky sample. The application can then be configured in BOARD.dts files or via devicetree overlays.