Partition Manager

The Partition Manager is a Python script that sets the start address and size of all the flash and RAM partitions in a multi-image build context. When creating an application that requires child images, like a bootloader, you can configure the Partition Manager to control where each image should be placed in memory, and how the RAM should be shared.

See Multi-image builds using child and parent images for more information about multi-image builds.

The Partition Manager is activated for all multi-image builds, regardless of which build strategy is used for the child image.

Note

When you build a multi-image application using the Partition Manager, the devicetree source flash partitions are ignored.

Overview

The Partition Manager script reads the configuration files named pm.yml, which define flash and RAM partitions. A definition of a flash partition includes the name and the constraints on both size and placement in the flash memory. A definition of a RAM partition includes the name and the constraints on its size. The Partition Manager allocates a start address and, when set, a size to each partition in a way that complies with these constraints.

There are different types of flash partitions and RAM partitions, as described in the following section.

Flash partition types

Image partitions

An image partition is the flash memory area reserved for an image to which the image binary is written.

When the Partition Manager is active, there is one root image and one or more child images. The name of the root image is app. It is always implicitly defined. Child images are explicitly defined in pm.yml files. The size of the root image partition is dynamic, while the sizes of all child image partitions are statically defined.

Placeholder partitions

A placeholder partition does not contain an image, but reserves space for other uses. For example, you might want to reserve space in the flash memory to hold an updated application image while it is being downloaded and before it is copied to the application image partition.

Container partitions

A container partition does not reserve space but is used to logically and (or) physically group other partitions.

The start addresses and sizes of image partitions are used in the preprocessing of the linker script for each image.

RAM partition types

Default image RAM partition

The default image RAM partition consists of all the RAM that is not defined as a permanent image RAM partition or placeholder RAM partition. It is the default RAM partition associated with an image and is set as the RAM region when linking the image. If an image must reserve its RAM area permanently (that is, at the same time as other images are running), it must use a permanent image RAM partition, described below.

Permanent image RAM partitions

A permanent image RAM partition reserves RAM for an image permanently. It is typically used for images that will remain active after they have booted the next step in the boot chain. If an image has configured a permanent image RAM partition, it is set as the RAM region when linking the image, instead of the default image RAM partition.

Permanent placeholder RAM partitions

A permanent placeholder RAM partition is used to permanently reserve RAM regions that are not associated with an image.

Configuration

Each child image must define its Partition Manager configuration in a file called pm.yml. This file must be stored in the same folder as the main CMakeLists.txt file of the child image.

Note

pm.yml is only used for child images. The root application does not need to define a pm.yml file, because its partition size and placement is implied by the size and placement of the child image partitions. If a root application defines a pm.yml file, it is silently ignored.

The Partition Manager configuration can be also provided by a subsystem, intended as a software component. For example, the support for a file system. Subsystem Partition Manager configurations cannot define image partitions.

See subsys/partition_manager/CMakeLists.txt for details on how to add the subsystem-specific Partition Manager configuration files. The following code shows how the settings subsystem configuration is added.

if (CONFIG_SETTINGS_FCB OR CONFIG_SETTINGS_NVS)
  ncs_add_partition_manager_config(pm.yml.settings)
endif()

When multiple application images, within the same domain, build the same subsystem code, there are some limitations if the code adds a Partition Manager configuration file using this methodology. In particular, partition definitions are global per domain, and must be identical across all the calls to ncs_add_partition_manager_config(). If the same partition is defined twice with different configurations within a domain, the Partition Manager will fail.

Note

If Partition Manager configurations are only defined by subsystems, so that only one image is included in the build, you must set the option CONFIG_PM_SINGLE_IMAGE to execute the Partition Manager script.

Configuration file format

A pm.yml file contains partition definitions. Each partition is defined as follows:

partition_name:
   partition_property:
      property_value

partition_name is the name of the partition (for example, mcuboot).

The following partition properties and property values are available:

placement: dict

This property specifies the placement of the partition relative to other partitions, to the start or end of the flash, or to the root image app.

A partition with the placement property set is either an image partition or a placeholder partition. If the partition name is the same as the image name (as defined in a CMakeLists.txt; see Defining and enabling a child image for details), this partition is the image partition. All other partitions are placeholder partitions. Each pm.yml file must define exactly one image partition.

The placement is formatted as a YAML dict. The valid keywords are listed below:

before: list

Place the partition before the first existing partition in the list.

after: list

Place the partition after the first existing partition in the list.

Valid values in the lists are app, start, end, or the name of any partition. The value start refers to the start address of the flash device’s memory. The value end refers to its end address. It is not possible to place the partition after end or before start.

align: dict

Ensure the alignment of the start or the end of the partition by specifying a dict with a start or end key respectively, where the value is the number of bytes to align to. If necessary, empty partitions are inserted in front of or behind the partition to ensure that the alignment is correct. Only one key can be specified. Partitions that directly or indirectly (through spans) share size with the app partitions can only be aligned if they are placed directly after the app partition.

align_next: int

Ensure that the _next_ partition is aligned on this number of bytes. This is equivalent to ensuring the alignment of the start of the next partition. If the start of the next partition is already aligned, the largest alignment takes effect. align_next fails if the alignment of the start of the next partition is not a divisor or multiple of the align_next value. align_next also fails if the end of the next partition is aligned.

span: list OR span: string

This property is used to define container partitions. Its value may be a list or string.

Since this property is used to define container partitions, it cannot be used together with the placement property.

If the value is a list, its elements are the names of the partitions that should be placed in the container:

The following example shows a partition that spans, or contains, partition_1 through partition_n, in any order:

container_partition_name:
  span: [partition_1, partition_2, ..., partition_n]

The list elements are interpreted as the set of potential partitions in the container, which the Partition Manager may place in the flash in any order. For example, partition_2 could be placed before partition_1.

If the value is a string, it is interpreted as a list with one item:

The following two examples are equivalent:

container_partition_name:
  span: foo

container_partition_name:
  span: [foo]

Non-existent partitions are removed from the span list before processing. Partitions with empty span lists are removed altogether, unless filled by the inside property.

If the Partition Manager is forced to place a partition that is not declared in the span list between two partitions that are in the list, the configuration is unsatisfiable and therefore invalid. See Span property example 1 for an example of an invalid configuration.

Note

You can specify configurations with an ambiguous ordering. Different versions of the Partition Manager script may produce different partition orders for such configurations, or fail to find a solution even if one is possible. The Partition Manager always detects unsatisfiable configurations (no false positives), but it might fail on some valid inputs (false negatives).

Here are three examples of valid and invalid configurations:

  • In the following example, the mcuboot and tfm configurations result in this partition order: mcuboot, tfm, app. Therefore, the foo partition configuration is invalid, because tfm must be placed between mcuboot and app, but is not in the span list.

    Span property example 1 (invalid)
    mcuboot:
       placement:
          before: [tfm, app]
    
    tfm:
       placement:
          before: [app]
    
    foo:
       span: [mcuboot, app]
    
  • In the following example, these mcuboot, tfm, and app configurations have two possible orders:

    • Order 1: mcuboot, tfm, app

    • Order 2: mcuboot, app, tfm

    In the absence of additional configuration, the Partition Manager may choose either order. However, since a span configuring the foo partition is present, the Partition Manager should choose order 2, since it is the only order that results in a valid configuration for the foo partition.

    Span property example 2 (valid)
    mcuboot:
       placement:
    
    tfm:
       placement:
          after: [mcuboot]
    
    app:
       placement:
          after: [mcuboot]
    
    foo:
       span: [mcuboot, app]
    
  • In the following example, these mcuboot, tfm, and app configurations have two possible orders:

    • Order 1: mcuboot, tfm, app

    • Order 2: mcuboot, app, tfm

    However, the overall configuration is unsatisfiable: foo requires order 2, while bar requires order 1.

    Span property example 3 (invalid)
    mcuboot:
       placement:
    
    tfm:
       placement:
          after: [mcuboot]
    
    app:
       placement:
          after: [mcuboot]
    
    foo:
       span: [mcuboot, app]
    
    bar:
       span: [mcuboot, tfm]
    
inside: list

This property is the inverse of span. The name of the partition that specifies this property is added to the span list of the first existing container partition in the list. This property can be set for image or placeholder partitions.

Example for the inside property
mcuboot:
   inside: [b0]

b0:
   span: [] # During processing, this span will contain mcuboot.
size: hexadecimal value

This property defines the size of the partition. You can provide a Kconfig option as the value, which allows the user to easily modify the size (see Configuration file preprocessing for an example).

share_size: list

This property defines the size of the current partition to be the same as the size of the first existing partition in the list. This property can be set for image or placeholder partitions. It cannot be used by container partitions. The list can contain any kind of partition. share_size takes precedence over size if one or more partitions in share_size exists.

If the target partition is the app or a partition that spans over the app, the size is effectively split between them, because the size of the app is dynamically decided.

If none of the partitions in the share_size list exists, and the partition does not define a size property, then the partition is removed. If none of the partitions in the share_size list exists, and the partition does define a size property, then the size property is used to set the size.

region: string

Specify the region where a partition should be placed. See Regions.

affiliation: string or list

This property groups the partition with other partitions with the specified affiliation. Affiliations are used to generate PM_FOREACH_AFFILIATED_TO_<affliation>(fn) macros, which let you invoke the macro fn on all definitions of the partitions with the specified affiliation. The macro passes the partition name from the YAML file to the fn macro, using the upper-case formatting. Currently, the disk affiliation is reserved by the flash disk driver in Zephyr to generate disk objects from partitions defined by the Partition Manager.

extra_params: dict

This is a dictionary of extra <param_name> parameters for the partition. The Partition Manager only uses them for generating PM_<uppercase_partition_name>_EXTRA_PARAM_<param_name> definitions, with the value taken from the YAML file, as assigned to the extra parameter. The Partition Manager does not use or process these parameters in any other way. Extra parameters can be used by other subsystems to add additional information to partitions. Currently, this feature is only used by the flash disk driver in Zephyr to generate disk objects for use with the Disk Access API, with the following extra parameters: disk_sector_size, disk_cache_size, disk_name, and disk_read_only. The following code snippet shows an example of the disk partition configuration using the extra_params dictionary:

Example of disk partition
fatfs_storage:
    affiliation: disk
    extra_params: {
        disk_name: "SD",
        disk_cache_size: 4096,
        disk_sector_size: 512,
        disk_read_only: 0
    }
    placement:
        before: [end]
        align: {start: 4096}
    inside: [nonsecure_storage]
    size: 65536
RAM partition configuration

RAM partitions are partitions located in the sram_primary region. A RAM partition is specified by having the partition name end with _sram. If a partition name is composed of an image name plus the _sram ending, it is used as a permanent image RAM partition for the image.

The following two examples are equivalent:

RAM partition configuration, without the _sram ending
some_permament_sram_block_used_for_logging:
   size: 0x1000
   region: sram_primary
RAM partition configuration, using the _sram ending
some_permament_sram_block_used_for_logging_sram:
   size: 0x1000

The following example specifies a permanent image RAM partition for MCUboot, that will be used by the MCUboot linker script.

mcuboot_sram:
    size: 0xa000

All occurrences of a partition name can be replaced by a dict with the key one_of. This dict is resolved to the first existing partition in the one_of value. The value of the one_of key must be a list of placeholder or image partitions, and it cannot be a span.

See the following two examples, they are equivalent:

Example of using a one_of dict
some_span:
   span: [something, {one_of: [does_not_exist_0, does_not_exist_1, exists1, exists2]}]
Example of not using a one_of dict
some_span:
   span: [something, exists1]

An error is triggered if none of the partitions listed inside the one_of dict exists.

To use this functionality, the properties that must explicitly define the one_of keyword are the following:

  • span

  • share_size

The placement property contains the functionality of one_of by default. As such, you must not use one_of with the placement property. Doing so will trigger a build error.

The keywords before and after already check for the first existing partition in their list. Therefore, you can pass a list of partitions into these keywords.

Configuration file preprocessing

Each pm.yml file is preprocessed to resolve symbols from Kconfig and devicetree.

The following example is taken from the pm.yml file for the Immutable bootloader provided with the nRF Connect SDK. It includes autoconf.h and devicetree_legacy_unfixed.h (generated by Kconfig and devicetree respectively) to read application configurations and hardware properties. In this example the application configuration is used to configure the size of the image and placeholder partitions. The application configuration is also used to decide in which region the otp partition should be stored. The information extracted from devicetree is the alignment value for some partitions.

#include <autoconf.h>
#include <devicetree_legacy_unfixed.h>

b0:
  size: CONFIG_PM_PARTITION_SIZE_B0_IMAGE
  placement:
    after: start

b0_container:
  span: [b0, provision]

s0_pad:
  share_size: mcuboot_pad
  placement:
    after: b0
    align: {start: CONFIG_FPROTECT_BLOCK_SIZE}

app_image:
  span: [tfm, app]

s0_image:
  # S0 spans over the image booted by B0
  span: {one_of: [mcuboot, app_image]}

s0:
  # Phony container to allow hex overriding
  span: [s0_pad, s0_image]

s1_pad:
  # This partition will only exist if mcuboot_pad exists.
  share_size: mcuboot_pad
  placement:
    after: s0
    align: {start: DT_FLASH_ERASE_BLOCK_SIZE}

s1_image:
  share_size: {one_of: [mcuboot, s0_image]}
  placement:
    after: [s1_pad, s0]
    align: {end: CONFIG_FPROTECT_BLOCK_SIZE}

s1:
  # Partition which contains the whole S1 partition.
  span: [s1_pad, s1_image]

provision:
  size: CONFIG_PM_PARTITION_SIZE_PROVISION
#if defined(CONFIG_SOC_SERIES_NRF91X) || defined(CONFIG_SOC_NRF5340_CPUAPP)
  region: otp
#else
  placement:
    after: b0
    align: {start: DT_FLASH_ERASE_BLOCK_SIZE}
#endif

Regions

The Partition Manager places partitions in different regions. For example, you can use regions for internal flash memory and external flash memory.

To define in which region a partition should be placed, use the region property in the configuration of the partition. If no region is specified, the predefined internal flash region is used.

Defining a region

Each region is defined by a name, a start address, a size, a placement strategy, and, if applicable, a device name. A region only specifies a device name if there is a device driver associated with the region, for example, a driver for an external SPI flash.

There are three types of placement strategies, which affect how partitions are placed in regions:

start_to_end

Place partitions sequentially from start to end. Partitions stored in a region with this placement strategy cannot affect their placement through the placement property. The unused part of the region is assigned to a partition with the same name as the region.

end_to_start

Place partitions sequentially from end to start. Partitions stored in a region with this placement strategy cannot affect their placement through the placement property. The unused part of the region is exposed through a partition with the same name as the region.

complex

Place partitions according to their placement configuration. The unused part of the region is exposed through a partition named app.

Regions are defined in partition_manager.cmake. For example, see the following definitions for default regions:

add_region(                           # Define region without device name
  NAME otp                            # Name
  SIZE 756                            # Size
  BASE 0xff8108                       # Base address
  PLACEMENT start_to_end              # Placement strategy
  )

add_region(                           # Define region with device name
  NAME flash_primary                  # Name
  SIZE ${flash_size}                  # Size
  BASE ${CONFIG_FLASH_BASE_ADDRESS}   # Base address
  PLACEMENT complex                   # Placement strategy
  DEVICE flash_controller             # DTS node label of flash controller
  DEFAULT_DRIVER_KCONFIG              # Kconfig option that should be set for
                                      # the driver to be compiled in
  )

External flash memory partitions

The Partition Manager supports partitions in the external flash memory through the use of Regions. Any placeholder partition can specify that it should be stored in the external flash memory region. External flash memory regions always use the start_to_end placement strategy.

To store partitions in the external flash memory, you can either choose a value for the nordic,pm-ext-flash property in the devicetree, or directly use an external flash DTS node label as DEVICE. See the following example of an overlay file that sets this value:

nrf52840dk_nrf52840.overlay
/ {
	chosen {
		nordic,pm-ext-flash = &mx25r64;
	};
};

After the nordic,pm-ext-flash value is set, you can place partitions in the external flash memory as follows:

# Name of partition
external_plz:
  region: external_flash
  size: CONFIG_EXTERNAL_PLZ_SIZE

Note

See Using external flash memory partitions for more details on using external flash memory with MCUboot.

A partition can be accessible at runtime only if the flash device where it resides has its driver enabled at compile time. Partition manager ignores partitions that are located in a region without its driver enabled. To let partition manager know which Kconfig option ensures the existence of the driver, the option DEFAULT_DRIVER_KCONFIG is used.

For partitions in the internal flash memory, DEFAULT_DRIVER_KCONFIG within partition_manager.cmake is set automatically to CONFIG_SOC_FLASH_NRF, so that all the partitions placed in the internal flash are always available at runtime. For external regions, DEFAULT_DRIVER_KCONFIG within partition_manager.cmake must be set to CONFIG_PM_EXTERNAL_FLASH_HAS_DRIVER. Out-of-tree drivers can select this value to attest that they provide support for the external flash. This is a hidden option and can be selected only by an external driver or a Kconfig option.

This option is automatically set when CONFIG_NRF_QSPI_NOR or CONFIG_SPI_NOR is enabled. If the application provides the driver in an unusual way, this option can be overridden by setting CONFIG_PM_OVERRIDE_EXTERNAL_DRIVER_CHECK in the application configuration.

As partition manager does not know if partitions are used at runtime, consider the following:

  • Enabling Kconfig options that affect DEFAULT_DRIVER_KCONFIG will add a partition map entry for the partition depending on it, whether it is used at runtime or not.

  • Not enabling the Kconfig options that affect DEFAULT_DRIVER_KCONFIG will not add partition map entry for partition depending on it, whether it is used at runtime or not.

  • Enabling Kconfig options that affect DEFAULT_DRIVER_KCONFIG can cause linker errors when the option has no effect on including a driver into compilation. In this case, partition manager adds a partition map entry that has a pointer to the flash device it is supposed to be placed on, but due to misconfiguration the driver is actually not compiled in. This situation can also be caused by setting the CONFIG_PM_OVERRIDE_EXTERNAL_DRIVER_CHECK, as partition manager will just assume that the driver is provided by the application.

Note

When using an application configured with an MCUboot child image, both images use the same partition manager configuration, which means that the app and MCUboot have exactly the same partition maps. The accessibility at runtime of flash partitions depends on the configurations of both the application and MCUboot and the values they give to the DEFAULT_DRIVER_KCONFIG option of the partition manager region specification.

Build system

The build system finds the child images that have been enabled and their configurations.

For each image, the Partition Manager’s CMake code infers the paths to the following files and folders from the name and from other global properties:

  • The pm.yml file

  • The compiled HEX file

  • The generated include folder

After CMake finishes configuring the child images, the Partition Manager script is executed in configure time (execute_process) with the lists of names and paths as arguments. The configurations generated by the Partition Manager script are imported as CMake variables (see CMake).

The Partition Manager script outputs a partitions.yml file. This file contains the internal state of the Partition Manager at the end of processing. This means it contains the merged contents of all pm.yml files, the sizes and addresses of all partitions, and other information generated by the Partition Manager.

Generated output

After the main Partition Manager script has finished, another script runs. This script takes the partitions.yml file as input and creates the following output files:

  • A C header file pm_config.h for each child image and for the root application

  • A key-value file pm.config

The header files are used in the C code, while the key-value file is imported into the CMake namespace. Both kinds of files contain, among other information, the start address and size of all partitions.

Usage

The output that the Partition Manager generates can be used in various areas of your code.

C code

When the Partition Manager is enabled, all source files are compiled with the define USE_PARTITION_MANAGER set to 1. If you use this define in your code, the preprocessor can choose what code to include depending on whether the Partition Manager is being used.

#if USE_PARTITION_MANAGER
#include <pm_config.h>
#define NON_SECURE_APP_ADDRESS PM_APP_ADDRESS
#else
...

HEX files

The Partition Manager may implicitly or explicitly assign a HEX file to a partition.

Image partitions are implicitly assigned the compiled HEX file, that is, the HEX file that is generated when building the corresponding image. Container partitions are implicitly assigned the result of merging the HEX files that are assigned to the underlying partitions. Placeholder partitions are not implicitly assigned a HEX file.

To explicitly assign a HEX file to a partition, set the global properties partition_name_PM_HEX_FILE and partition_name_PM_TARGET in CMake, where partition_name is the name of the partition. partition_name_PM_TARGET specifies the build target that generates the HEX file specified in partition_name_PM_HEX_FILE.

See the following example, which assigns a cryptographically signed HEX file built by the sign_target build target to the root application:

set_property(
  GLOBAL PROPERTY
  app_PM_HEX_FILE # Must match "*_PM_HEX_FILE"
  ${PROJECT_BINARY_DIR}/signed.hex
)

set_property(
  GLOBAL PROPERTY
  app_PM_TARGET # Must match "*_PM_TARGET"
  sign_target
)

As output, the Partition Manager creates a HEX file called merged.hex, which is programmed to the development kit when calling ninja flash. When creating merged.hex, all assigned HEX files are included in the merge operation. If the HEX files overlap, the conflict is resolved as follows:

  • HEX files assigned to container partitions overwrite HEX files assigned to their underlying partitions.

  • HEX files assigned to larger partitions overwrite HEX files assigned to smaller partitions.

  • Explicitly assigned HEX files overwrite implicitly assigned HEX files.

This means that you can overwrite a partition’s HEX file by wrapping that partition in another partition and assigning a HEX file to the new partition.

Partition Manager report

When using the Partition Manager, run ninja partition_manager_report to see the addresses and sizes of all the configured partitions.

CMake

The CMake variables from the Partition Manager are typically used through generator expressions, because these variables are only made available late in the CMake configure stage. To read a Partition Manager variable through a generator expression, the variable must be assigned as a target property. The Partition Manager stores all variables as target properties on the partition_manager target, which means they can be used in generator expressions in the following way:

Reading Partition Manager variables in generator expressions
--slot-size $<TARGET_PROPERTY:partition_manager,PM_MCUBOOT_PARTITIONS_PRIMARY_SIZE>

Partition placement reports

You can generate an ASCII-art map report to get an overview of how the partition manager creates flash memory partitions. This is especially useful when using multiple bootloaders.

To generate the report, use the ninja partition_manager_report or west build -t partition_manager_report commands.

For example, if you generate a partition placement report on the build of zephyr/samples/hello_world with the nRF52840 development kit using nRF Secure Immutable Bootloader and MCUboot, you would get as an output an ASCII partition map that looks like the following:

 (0x100000 - 1024.0kB):
+------------------------------------------+
+---0x0: b0 (0x9000)-----------------------+
| 0x0: b0_image (0x8000)                   |
| 0x8000: provision (0x1000)               |
+---0x9000: s0 (0xc200)--------------------+
| 0x9000: s0_pad (0x200)                   |
+---0x9200: s0_image (0xc000)--------------+
| 0x9200: mcuboot (0xc000)                 |
| 0x15200: EMPTY_0 (0xe00)                 |
+---0x16000: s1 (0xc200)-------------------+
| 0x16000: s1_pad (0x200)                  |
| 0x16200: EMPTY_1 (0xe00)                 |
| 0x17000: s1_image (0xc000)               |
+---0x23000: mcuboot_primary (0x6e000)-----+
| 0x23000: mcuboot_pad (0x200)             |
+---0x23200: mcuboot_primary_app (0x6de00)-+
+---0x23200: app_image (0x6de00)-----------+
| 0x23200: app (0x6de00)                   |
| 0x91000: mcuboot_secondary (0x6e000)     |
| 0xff000: EMPTY_2 (0x1000)                |
+------------------------------------------+

The sizes of each partition are determined by the associated pm.yml file, such as nrf/samples/bootloader/pm.yml for nRF Secure Immutable Bootloader and bootloader/mcuboot/boot/zephyr/pm.yml for MCUboot.

Static and dynamic configuration

By default, the Partition Manager dynamically places the partitions in memory. However, there are cases where a deployed product can consist of multiple images, and only a subset of these images can be upgraded through a firmware update mechanism. In such cases, the upgradable images must have partitions that are static and are matching the partition map used by the bootloader programmed onto the device. For example, if a device includes a non-upgradable first-stage bootloader and an upgradable application, the application image to be upgraded must be linked to the same address as the one that is deployed. For this purpose, the Partition Manager provides the static configuration to define static partitions.

The area used by the static partitions is called the static area. The static area comes in addition to the dynamic area, which consists of the app partition and all memory adjacent to the app partition that is not occupied by a static partition. Note that there is only one dynamic area. When the Partition Manager is executed, it operates only on the dynamic area, assuming that all other memory is reserved.

Within the dynamic area, you can define new partitions or configure existing partitions even if you are using static partitions. The dynamic area is resized as required when updating the static configuration.

Configuring static partitions

Static partitions are defined through a YAML-formatted configuration file in the root application’s source directory. This file is similar to the regular pm.yml configuration files, except that it also defines the start address for all partitions.

You can set PM_STATIC_YML_FILE to contain exactly the static configuration you want to use.

If you do not set PM_STATIC_YML_FILE, the build system will use the following order to look for files in your application source directory to use as a static configuration layout:

  • If a file suffix is used, the following order applies:

    1. If the file pm_static_<board>_<revision>_<suffix>.yml exists, it will be used.

    2. Otherwise, if the file pm_static_<board>_<revision>.yml exists, it will be used.

    3. Otherwise, if the file pm_static_<board>_<suffix>.yml exists, it will be used.

    4. Otherwise, if the file pm_static_<board>.yml exists, it will be used.

    5. Otherwise, if the file pm_static_<suffix>.yml exists, it will be used.

    6. Otherwise, if the file pm_static.yml exists, it will be used.

  • If a suffixed configuration is not used, then the same order as above applies, except that <suffix> is not part of the file name:

    1. If the file pm_static_<board>_<revision>.yml exists, it will be used.

    2. Otherwise, if the file pm_static_<board>.yml exists, it will be used.

    3. Otherwise, if the file pm_static.yml exists, it will be used.

For Multi-image builds using child and parent images where the image targets a different domain, Updating the build scripts uses the same search algorithm, but a domain specific configuration file is also searched. For example, pm_static_<board>_<suffix>_<domain>.yml or pm_static_<board>_<domain>.yml.

Use a static partition layout to ensure consistency between builds, as the settings storage will be at the same location after the DFU.

The current partition configuration for a build can be found in $BUILD_DIR/partitions.yml. To apply the current configuration as a static configuration, copy this file to $APPLICATION_CONFIG_DIR/pm_static.yml.

It is also possible to build a pm_static.yml from scratch by following the description in Adding a static partition

When modifying static configurations, keep in mind the following:

  • There can only be one unoccupied gap per region.

  • All statically defined partitions in regions with end_to_start or start_to_end placement strategy must be packed at the end or the start of the region, respectively.

The default flash_primary region uses the complex placement strategy, so these limitations do not apply there.

You can add or remove partitions as described in the following sections.

Note

If the static configuration contains an entry for the app partition, this entry is ignored.

Configuring dynamic partitions

For child images that use dynamic partition sizing, the Partition Manager allows you to use the CONFIG_PM_PARTITION_SIZE_<CHILD_IMAGE> Kconfig option to adjust the partition size. This is particularly useful when you want to optimize the memory usage of MCUboot to the smallest possible size by enabling cryptographic functionalities.

Note

To match the reduced size, you need to set the CONFIG_PM_PARTITION_SIZE_<CHILD_IMAGE> Kconfig option in the child image’s configuration. For example, CONFIG_PM_PARTITION_SIZE_MCUBOOT must be set for the MCUboot child image.

The CONFIG_PM_PARTITION_SIZE_<CHILD_IMAGE> Kconfig option allows you to specify the memory size for each child image’s partition directly in the Kconfig file. This allows for precise control over memory allocation which is crucial for system performance optimization.

Common variants of this Kconfig’s option include the following:

You must adjust each variant according to the specific requirements and memory constraints of the project, ensuring optimal usage of available flash memory. For a full list of the CONFIG_PM_PARTITION_SIZE variants, see the related Kconfig search results.

Adding a dynamic partition

New dynamic partitions that are listed in a pm.yml file are automatically added. However, if a partition is defined both as a static partition and as a dynamic partition, the dynamic definition is ignored.

Note

When resolving the relative placement of dynamic partitions, any placement properties referencing static partitions are ignored.

Adding a static partition

To add a static partition, add an entry for it in pm_static.yml. This entry must define the properties address, size, and - if applicable - span. The region defaults to flash_primary if no region property is specified.

Example of static configuration of a partition with span
partition_name:
   address: 0xab00
   size: 0x1000
   span: [example]  # Only if this partition had the span property set originally.

Note

Child images that are built with the build strategy partition_name_BUILD_STRATEGY_SKIP_BUILD or partition_name_BUILD_STRATEGY_USE_HEX_FILE must define a static partition to ensure correct placement of the dynamic partitions.

Removing a static partition

To remove a static partition, delete its entry in pm_static.yml.

Only partitions adjacent to the app partition or other removed partitions can be removed.