doc/services/settings/index.rst - third_party/github/zephyrproject-rtos/zephyr - Git at Google

 .. _settings_api:

 Settings
 ########

 The settings subsystem gives modules a way to store persistent per-device
 configuration and runtime state.  A variety of storage implementations are
 provided behind a common API using FCB, NVS, or a file system.  These different
 implementations give the application developer flexibility to select an
 appropriate storage medium, and even change it later as needs change.  This
 subsystem is used by various Zephyr components and can be used simultaneously by
 user applications.

 Settings items are stored as key-value pair strings.  By convention,
 the keys can be organized by the package and subtree defining the key,
 for example the key ``id/serial`` would define the ``serial`` configuration
 element for the package ``id``.

 Convenience routines are provided for converting a key value to
 and from a string type.

 For an example of the settings subsystem refer to
 :ref:`the sample <settings_subsys_sample>`.

 .. note::

    As of Zephyr release 2.1 the recommended backend for non-filesystem
    storage is :ref:`NVS <nvs_api>`.

 Handlers
 ********

 Settings handlers for subtree implement a set of handler functions.
 These are registered using a call to ``settings_register()``.

 **h_get**
     This gets called when asking for a settings element value by its name using
     ``settings_runtime_get()`` from the runtime backend.

 **h_set**
     This gets called when the value is loaded from persisted storage with
     ``settings_load()``, or when using ``settings_runtime_set()`` from the
     runtime backend.

 **h_commit**
     This gets called after the settings have been loaded in full.
     Sometimes you don't want an individual setting value to take
     effect right away, for example if there are multiple settings
     which are interdependent.

 **h_export**
     This gets called to write all current settings. This happens
     when ``settings_save()`` tries to save the settings or transfer to any
     user-implemented back-end.

 Backends
 ********

 Backends are meant to load and save data to/from setting handlers, and
 implement a set of handler functions. These are registered using a call to
 ``settings_src_register()`` for backends that can load data, and/or
 ``settings_dst_register()`` for backends that can save data. The current
 implementation allows for multiple source backends but only a single destination
 backend.

 **csi_load**
     This gets called when loading values from persistent storage using
     ``settings_load()``.

 **csi_save**
     This gets called when saving a single setting to persistent storage using
     ``settings_save_one()``.

 **csi_save_start**
     This gets called when starting a save of all current settings using
     ``settings_save()``.

 **csi_save_end**
     This gets called after having saved of all current settings using
     ``settings_save()``.

 Zephyr Storage Backends
 ***********************

 Zephyr has three storage backends: a Flash Circular Buffer
 (:kconfig:option:`CONFIG_SETTINGS_FCB`), a file in the filesystem
 (:kconfig:option:`CONFIG_SETTINGS_FS`), or non-volatile storage
 (:kconfig:option:`CONFIG_SETTINGS_NVS`).

 You can declare multiple sources for settings; settings from
 all of these are restored when ``settings_load()`` is called.

 There can be only one target for writing settings; this is where
 data is stored when you call ``settings_save()``, or ``settings_save_one()``.

 FCB read target is registered using ``settings_fcb_src()``, and write target
 using ``settings_fcb_dst()``. As a side-effect,  ``settings_fcb_src()``
 initializes the FCB area, so it must be called before calling
 ``settings_fcb_dst()``. File read target is registered using
 ``settings_file_src()``, and write target by using ``settings_file_dst()``.
 Non-volatile storage read target is registered using
 ``settings_nvs_src()``, and write target by using
 ``settings_nvs_dst()``.

 Storage Location
 ****************

 The FCB and non-volatile storage (NVS) backends both look for a fixed
 partition with label "storage" by default. A different partition can be
 selected by setting the ``zephyr,settings-partition`` property of the
 chosen node in the devicetree.

 The file path used by the file system backend to store settings
 is selected via the option ``CONFIG_SETTINGS_FS_FILE``.

 Loading data from persisted storage
 ***********************************

 A call to ``settings_load()`` uses an ``h_set`` implementation
 to load settings data from storage to volatile memory.
 After all data is loaded, the ``h_commit`` handler is issued,
 signalling the application that the settings were successfully
 retrieved.

 Technically FCB and filesystem backends may store some history of the entities.
 This means that the newest data entity is stored after any
 older existing data entities.
 Starting with Zephyr 2.1, the back-end must filter out all old entities and
 call the callback with only the newest entity.

 Storing data to persistent storage
 **********************************

 A call to ``settings_save_one()`` uses a backend implementation to store
 settings data to the storage medium. A call to ``settings_save()`` uses an
 ``h_export`` implementation to store different data in one operation using
 ``settings_save_one()``.
 A key need to be covered by a ``h_export`` only if it is supposed to be stored
 by ``settings_save()`` call.

 For both FCB and filesystem back-end only storage requests with data which
 changes most actual key's value are stored, therefore there is no need to check
 whether a value changed by the application. Such a storage mechanism implies
 that storage can contain multiple value assignments for a key , while only the
 last is the current value for the key.

 Garbage collection
 ==================
 When storage becomes full (FCB) or consumes too much space (file system),
 the backend removes non-recent key-value pairs records and unnecessary
 key-delete records.

 Secure domain settings
 **********************
 Currently settings doesn't provide scheme of being secure, and non-secure
 configuration storage simultaneously for the same instance.
 It is recommended that secure domain uses its own settings instance and it might
 provide data for non-secure domain using dedicated interface if needed
 (case dependent).

 Example: Device Configuration
 *****************************

 This is a simple example, where the settings handler only implements ``h_set``
 and ``h_export``. ``h_set`` is called when the value is restored from storage
 (or when set initially), and ``h_export`` is used to write the value to
 storage thanks to ``storage_func()``. The user can also implement some other
 export functionality, for example, writing to the shell console).

 .. code-block:: c

     #define DEFAULT_FOO_VAL_VALUE 1

     static int8 foo_val = DEFAULT_FOO_VAL_VALUE;

     static int foo_settings_set(const char *name, size_t len,
                                 settings_read_cb read_cb, void *cb_arg)
     {
         const char *next;
         int rc;

         if (settings_name_steq(name, "bar", &next) && !next) {
             if (len != sizeof(foo_val)) {
                 return -EINVAL;
             }

             rc = read_cb(cb_arg, &foo_val, sizeof(foo_val));
             if (rc >= 0) {
                 /* key-value pair was properly read.
                  * rc contains value length.
                  */
                 return 0;
             }
             /* read-out error */
             return rc;
         }

         return -ENOENT;
     }

     static int foo_settings_export(int (*storage_func)(const char *name,
                                                        const void *value,
                                                        size_t val_len))
     {
         return storage_func("foo/bar", &foo_val, sizeof(foo_val));
     }

     struct settings_handler my_conf = {
         .name = "foo",
         .h_set = foo_settings_set,
         .h_export = foo_settings_export
     };

 Example: Persist Runtime State
 ******************************

 This is a simple example showing how to persist runtime state. In this example,
 only ``h_set`` is defined, which is used when restoring value from
 persisted storage.

 In this example, the ``main`` function increments ``foo_val``, and then
 persists the latest number. When the system restarts, the application calls
 ``settings_load()`` while initializing, and ``foo_val`` will continue counting
 up from where it was before restart.

 .. code-block:: c

     #include <zephyr/kernel.h>
     #include <zephyr/sys/reboot.h>
     #include <zephyr/settings/settings.h>
     #include <zephyr/sys/printk.h>
     #include <inttypes.h>

     #define DEFAULT_FOO_VAL_VALUE 0

     static uint8_t foo_val = DEFAULT_FOO_VAL_VALUE;

     static int foo_settings_set(const char *name, size_t len,
                                 settings_read_cb read_cb, void *cb_arg)
     {
         const char *next;
         int rc;

         if (settings_name_steq(name, "bar", &next) && !next) {
             if (len != sizeof(foo_val)) {
                 return -EINVAL;
             }

             rc = read_cb(cb_arg, &foo_val, sizeof(foo_val));
             if (rc >= 0) {
                 return 0;
             }

             return rc;
         }


         return -ENOENT;
     }

     struct settings_handler my_conf = {
         .name = "foo",
         .h_set = foo_settings_set
     };

     void main(void)
     {
         settings_subsys_init();
         settings_register(&my_conf);
         settings_load();

         foo_val++;
         settings_save_one("foo/bar", &foo_val, sizeof(foo_val));

         printk("foo: %d\n", foo_val);

         k_msleep(1000);
         sys_reboot(SYS_REBOOT_COLD);
     }

 Example: Custom Backend Implementation
 **************************************

 This is a simple example showing how to register a simple custom backend
 handler (:kconfig:option:`CONFIG_SETTINGS_CUSTOM`).

 .. code-block:: c

     static int settings_custom_load(struct settings_store *cs)
     {
         //...
     }

     static int settings_custom_save(struct settings_store *cs, const char *name,
                                     const char *value, size_t val_len)
     {
         //...
     }

     /* custom backend interface */
     static struct settings_store_itf settings_custom_itf = {
         .csi_load = settings_custom_load,
         .csi_save = settings_custom_save,
     };

     /* custom backend node */
     static struct settings_store settings_custom_store = {
         .cs_itf = &settings_custom_itf
     }

     int settings_backend_init(void)
     {
         /* register custom backend */
         settings_dst_register(&settings_custom_store);
         settings_src_register(&settings_custom_store);
         return 0;
     }

 API Reference
 *************

 The Settings subsystem APIs are provided by ``settings.h``:

 API for general settings usage
 ==============================
 .. doxygengroup:: settings

 API for key-name processing
 ===========================
 .. doxygengroup:: settings_name_proc

 API for runtime settings manipulation
 =====================================
 .. doxygengroup:: settings_rt

 API of backend interface
 ========================
 ..  doxygengroup:: settings_backend
	.. _settings_api:

	Settings
	########

	The settings subsystem gives modules a way to store persistent per-device
	configuration and runtime state. A variety of storage implementations are
	provided behind a common API using FCB, NVS, or a file system. These different
	implementations give the application developer flexibility to select an
	appropriate storage medium, and even change it later as needs change. This
	subsystem is used by various Zephyr components and can be used simultaneously by
	user applications.

	Settings items are stored as key-value pair strings. By convention,
	the keys can be organized by the package and subtree defining the key,
	for example the key ``id/serial`` would define the ``serial`` configuration
	element for the package ``id``.

	Convenience routines are provided for converting a key value to
	and from a string type.

	For an example of the settings subsystem refer to
	:ref:`the sample <settings_subsys_sample>`.

	.. note::

	As of Zephyr release 2.1 the recommended backend for non-filesystem
	storage is :ref:`NVS <nvs_api>`.

	Handlers
	********

	Settings handlers for subtree implement a set of handler functions.
	These are registered using a call to ``settings_register()``.

	h_get
	This gets called when asking for a settings element value by its name using
	``settings_runtime_get()`` from the runtime backend.

	h_set
	This gets called when the value is loaded from persisted storage with
	``settings_load()``, or when using ``settings_runtime_set()`` from the
	runtime backend.

	h_commit
	This gets called after the settings have been loaded in full.
	Sometimes you don't want an individual setting value to take
	effect right away, for example if there are multiple settings
	which are interdependent.

	h_export
	This gets called to write all current settings. This happens
	when ``settings_save()`` tries to save the settings or transfer to any
	user-implemented back-end.

	Backends
	********

	Backends are meant to load and save data to/from setting handlers, and
	implement a set of handler functions. These are registered using a call to
	``settings_src_register()`` for backends that can load data, and/or
	``settings_dst_register()`` for backends that can save data. The current
	implementation allows for multiple source backends but only a single destination
	backend.

	csi_load
	This gets called when loading values from persistent storage using
	``settings_load()``.

	csi_save
	This gets called when saving a single setting to persistent storage using
	``settings_save_one()``.

	csi_save_start
	This gets called when starting a save of all current settings using
	``settings_save()``.

	csi_save_end
	This gets called after having saved of all current settings using
	``settings_save()``.

	Zephyr Storage Backends
	***********************

	Zephyr has three storage backends: a Flash Circular Buffer
	(:kconfig:option:`CONFIG_SETTINGS_FCB`), a file in the filesystem
	(:kconfig:option:`CONFIG_SETTINGS_FS`), or non-volatile storage
	(:kconfig:option:`CONFIG_SETTINGS_NVS`).

	You can declare multiple sources for settings; settings from
	all of these are restored when ``settings_load()`` is called.

	There can be only one target for writing settings; this is where
	data is stored when you call ``settings_save()``, or ``settings_save_one()``.

	FCB read target is registered using ``settings_fcb_src()``, and write target
	using ``settings_fcb_dst()``. As a side-effect, ``settings_fcb_src()``
	initializes the FCB area, so it must be called before calling
	``settings_fcb_dst()``. File read target is registered using
	``settings_file_src()``, and write target by using ``settings_file_dst()``.
	Non-volatile storage read target is registered using
	``settings_nvs_src()``, and write target by using
	``settings_nvs_dst()``.

	Storage Location
	****************

	The FCB and non-volatile storage (NVS) backends both look for a fixed
	partition with label "storage" by default. A different partition can be
	selected by setting the ``zephyr,settings-partition`` property of the
	chosen node in the devicetree.

	The file path used by the file system backend to store settings
	is selected via the option ``CONFIG_SETTINGS_FS_FILE``.

	Loading data from persisted storage
	***********************************

	A call to ``settings_load()`` uses an ``h_set`` implementation
	to load settings data from storage to volatile memory.
	After all data is loaded, the ``h_commit`` handler is issued,
	signalling the application that the settings were successfully
	retrieved.

	Technically FCB and filesystem backends may store some history of the entities.
	This means that the newest data entity is stored after any
	older existing data entities.
	Starting with Zephyr 2.1, the back-end must filter out all old entities and
	call the callback with only the newest entity.

	Storing data to persistent storage
	**********************************

	A call to ``settings_save_one()`` uses a backend implementation to store
	settings data to the storage medium. A call to ``settings_save()`` uses an
	``h_export`` implementation to store different data in one operation using
	``settings_save_one()``.
	A key need to be covered by a ``h_export`` only if it is supposed to be stored
	by ``settings_save()`` call.

	For both FCB and filesystem back-end only storage requests with data which
	changes most actual key's value are stored, therefore there is no need to check
	whether a value changed by the application. Such a storage mechanism implies
	that storage can contain multiple value assignments for a key , while only the
	last is the current value for the key.

	Garbage collection
	==================
	When storage becomes full (FCB) or consumes too much space (file system),
	the backend removes non-recent key-value pairs records and unnecessary
	key-delete records.

	Secure domain settings
	**********************
	Currently settings doesn't provide scheme of being secure, and non-secure
	configuration storage simultaneously for the same instance.
	It is recommended that secure domain uses its own settings instance and it might
	provide data for non-secure domain using dedicated interface if needed
	(case dependent).

	Example: Device Configuration
	*****************************

	This is a simple example, where the settings handler only implements ``h_set``
	and ``h_export``. ``h_set`` is called when the value is restored from storage
	(or when set initially), and ``h_export`` is used to write the value to
	storage thanks to ``storage_func()``. The user can also implement some other
	export functionality, for example, writing to the shell console).

	.. code-block:: c

	#define DEFAULT_FOO_VAL_VALUE 1

	static int8 foo_val = DEFAULT_FOO_VAL_VALUE;

	static int foo_settings_set(const char *name, size_t len,
	settings_read_cb read_cb, void *cb_arg)
	{
	const char *next;
	int rc;

	if (settings_name_steq(name, "bar", &next) && !next) {
	if (len != sizeof(foo_val)) {
	return -EINVAL;
	}

	rc = read_cb(cb_arg, &foo_val, sizeof(foo_val));
	if (rc >= 0) {
	/* key-value pair was properly read.
	* rc contains value length.
	*/
	return 0;
	}
	/* read-out error */
	return rc;
	}

	return -ENOENT;
	}

	static int foo_settings_export(int (storage_func)(const char name,
	const void *value,
	size_t val_len))
	{
	return storage_func("foo/bar", &foo_val, sizeof(foo_val));
	}

	struct settings_handler my_conf = {
	.name = "foo",
	.h_set = foo_settings_set,
	.h_export = foo_settings_export
	};

	Example: Persist Runtime State
	******************************

	This is a simple example showing how to persist runtime state. In this example,
	only ``h_set`` is defined, which is used when restoring value from
	persisted storage.

	In this example, the ``main`` function increments ``foo_val``, and then
	persists the latest number. When the system restarts, the application calls
	``settings_load()`` while initializing, and ``foo_val`` will continue counting
	up from where it was before restart.

	.. code-block:: c

	#include <zephyr/kernel.h>
	#include <zephyr/sys/reboot.h>
	#include <zephyr/settings/settings.h>
	#include <zephyr/sys/printk.h>
	#include <inttypes.h>

	#define DEFAULT_FOO_VAL_VALUE 0

	static uint8_t foo_val = DEFAULT_FOO_VAL_VALUE;

	static int foo_settings_set(const char *name, size_t len,
	settings_read_cb read_cb, void *cb_arg)
	{
	const char *next;
	int rc;

	if (settings_name_steq(name, "bar", &next) && !next) {
	if (len != sizeof(foo_val)) {
	return -EINVAL;
	}

	rc = read_cb(cb_arg, &foo_val, sizeof(foo_val));
	if (rc >= 0) {
	return 0;
	}

	return rc;
	}


	return -ENOENT;
	}

	struct settings_handler my_conf = {
	.name = "foo",
	.h_set = foo_settings_set
	};

	void main(void)
	{
	settings_subsys_init();
	settings_register(&my_conf);
	settings_load();

	foo_val++;
	settings_save_one("foo/bar", &foo_val, sizeof(foo_val));

	printk("foo: %d\n", foo_val);

	k_msleep(1000);
	sys_reboot(SYS_REBOOT_COLD);
	}

	Example: Custom Backend Implementation
	**************************************

	This is a simple example showing how to register a simple custom backend
	handler (:kconfig:option:`CONFIG_SETTINGS_CUSTOM`).

	.. code-block:: c

	static int settings_custom_load(struct settings_store *cs)
	{
	//...
	}

	static int settings_custom_save(struct settings_store cs, const char name,
	const char *value, size_t val_len)
	{
	//...
	}

	/* custom backend interface */
	static struct settings_store_itf settings_custom_itf = {
	.csi_load = settings_custom_load,
	.csi_save = settings_custom_save,
	};

	/* custom backend node */
	static struct settings_store settings_custom_store = {
	.cs_itf = &settings_custom_itf
	}

	int settings_backend_init(void)
	{
	/* register custom backend */
	settings_dst_register(&settings_custom_store);
	settings_src_register(&settings_custom_store);
	return 0;
	}

	API Reference
	*************

	The Settings subsystem APIs are provided by ``settings.h``:

	API for general settings usage
	==============================
	.. doxygengroup:: settings

	API for key-name processing
	===========================
	.. doxygengroup:: settings_name_proc

	API for runtime settings manipulation
	=====================================
	.. doxygengroup:: settings_rt

	API of backend interface
	========================
	.. doxygengroup:: settings_backend