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Generic bootloader to be used in conjunction with Pelion Device Management Client

Home Page: https://www.pelion.com/iot-device-management/

License: Apache License 2.0

C++ 31.52% C 62.62% Shell 1.67% Python 4.18%

bootloader mbed-os embeded firmware-updates

mbed-bootloader's Introduction

mbed-bootloader

Generic bootloader to be used in conjunction with Pelion Device Management Client.

Build instructions

Install mbed-cli https://github.com/ARMmbed/mbed-cli
Run mbed deploy to pull in dependencies
Compile by running mbed compile -t GCC_ARM -m [target] --profile release --app-config=configs/.json

Installation instructions

An image that contains the bootloader and your application can then be flashed on your device.

If you use Mbed CLI 1.8.x then two images are created when you compile Pelion Device Management Client example application.

A full image mbed-cloud-client-example-internal.bin which combines the application with the bootloader and is used for the initial programming of the device
An update image mbed-cloud-client-example-internal_update.bin which contains only the application and is used for updating the device over the air

In order for Mbed CLI to pick up the bootloader binary you built, set "target.bootloader_img": <path to bootloader binary> in your application's mbed_app.json For more details, see Arm Mbed OS managed bootloader.

Flash mbed-cloud-client-example-internal.bin to your device by drag and drop.

Metadata Header

The metadata header is the bootloader update interface. Each stage of the boot sequence leading up to and including the application (except the root bootloader) is paired with a metadata header (containing version, size, hash etc.). Information contained in the metadata header allows validation and ordering of available firmwares.

The firmware metadata header structure can be found here. There are two header formats, internal and external. The external header format is used for storing firmware on external storage which is assumed to be insecure. Hence the external header format contains extra security information to prevent external tampering of the header data.

Configurations

NOTE: All these configurations must be set the same in the Pelion Device Management Client when compiling the corresponding application for successful update operation.

Active Application and Header

update-client.application-details, Address at which the metadata header of the active firmware is written. Must align to flash erase boundary
mbed-bootloader.application-start-address, Address at which the application starts Must align to vector table size boundary and flash write page boundary.
mbed-bootloader.application-jump-address, Optional address for the application's entry point (vector table) if this is different from mbed-bootloader.application-start-address.

If the application-start-address is set less than one erase sector after the update-client.application-details, the two regions will be erased together. Otherwise the two regions will be erased separately in which case application-start-address must also align to flash erase boundary.

If application-jump-address is not set, the application-start-address will be used as the application's entry point. The entry point MUST be the same as "target.mbed_app_start" in the application.

Firmware Candidate Storage

MBED_CLOUD_CLIENT_UPDATE_STORAGE, This need to be set in the "macros" section of mbed_app.json. Choices are ARM_UCP_FLASHIAP_BLOCKDEVICE and ARM_UCP_FLASHIAP. This determines whether the firmware is stored on a blockdevice or internal flash. If blockdevice is used ARM_UC_USE_PAL_BLOCKDEVICE=1 must also be set.
update-client.storage-address, The address in sd block device or internal flash where the firmware candidates are stored. Must align to flash erase boundary
update-client.storage-size, total size on the block device or internal flash reserved for firmware storage. It will be rounded up to align with flash erase sector size automatically.
update-client.storage-locations, The number of slots in the firmware storage.

NOTE: See the Pelion Device Management Client documentation for more information about storage options available and porting to new platforms.

Device Secret Key

The bootloader uses device secret key to authenticate anything that is stored on external storage. The update client must be able to obtain the same key as the bootloader. The key is derived from a device root of trust using the algorithm here. If the firmware candidate is stored on internal storage, i.e. MBED_CLOUD_CLIENT_UPDATE_STORAGE=ARM_UCP_FLASHIAP then the device secret key is not needed by the bootloader hence any configuration will be ignored.

You may choose to use Mbed OS' KVSTORE feature to store and read the device RoT. During first boot Pelion Device Management Client will generate a random number from an available entropy source and storage it in KVSTORE on internal flash. On subsequent boots, the RoT will be read from KVSTORE. To enable KVSTORE RoT, you must set the following:

Set "mbed-bootloader.use-kvstore-rot": 1 in mbed_app.json to enable the KVStore RoT implementation here.
Set "storage.storage_type": "FILESYSTEM", this configurations will have RoT stored on internal flash.
Set "storage_filesystem.internal_base_address". The addresses Must align to flash erase boundary.
Set "storage_filesystem.rbp_internal_size". It must contain even number of sectors.

Alternatively you can choose to use a custom device specific RoT by implementing the function mbed_cloud_client_get_rot_128bit. An example can be found here.

Bootloader Information

Pelion Cloud Client reports some information about the bootloader to the cloud. The bootloader provides this information in the form of a arm_uc_installer_details_t struct:

const arm_uc_installer_details_t bootloader = {
    .arm_hash = BOOTLOADER_ARM_SOURCE_HASH,
    .oem_hash = BOOTLOADER_OEM_SOURCE_HASH,
    .layout   = BOOTLOADER_STORAGE_LAYOUT
};

For this information to propagate to the cloud, the 3 macros (BOOTLOADER_ARM_SOURCE_HASH, BOOTLOADER_OEM_SOURCE_HASH and BOOTLOADER_STORAGE_LAYOUT) in mbed_bootloader_info.h need to be populated manually before the bootloader binary is built.

BOOTLOADER_ARM_SOURCE_HASH should be the SHA-1 git commit hash of the published mbed-bootloader source code.
BOOTLOADER_OEM_SOURCE_HASH is used to indicate any modification that OEMs have made on top of the vanilla mbed-bootloader. Hence it should be populated with the OEM modified bootloader SHA-1 git commit hash.
BOOTLOADER_STORAGE_LAYOUT is a proprietary enum to indicate the storage layout supported by this bootloader. The OEM is free to define the meaning of this number.

In order for the cloud client to recognise this struct and obtain the information. The offset of the symbol in the bootloader binary needs to be populated in the cloud client's configuration file. This information can be obtained from the map file of the compiled bootloader.

Example python code for obtaining the location:

with open("BUILD/K64F/GCC_ARM/mbed-bootloader.map", 'r') as fd:
    s = fd.read()

regex = r"\.rodata\..*{}\s+(0x[0-9a-fA-F]+)".format("bootloader")
match = re.search(regex, s, re.MULTILINE)
offset = int(match.groups()[0], 16)
print hex(offset)

In the mbed_app.json of the Pelion Cloud Client Application, change the following:

"update-client.bootloader-details" : "<boot_loader_info_address>"

MISC

User may set in mbed_app.json:

mbed-bootloader.max-copy-retries, The number of retries after a failed copy attempt.
mbed-bootloader.max-boot-retries, The number of retries after a failed forward to application.
mbed-bootloader.show-serial-output, Set to 0 to disable all serial output. Useful for reducing size on headless devices.
mbed-bootloader.show-progress-bar, Set to 1 to print a progress bar for various processes.
mbed-bootloader.max-application-size, Maximum size of the active application. The default value is FLASH_START_ADDRESS + FLASH_SIZE - APPLICATION_START_ADDRESS. Bootloader uses this value to reject candidate image that are too large.

Flash Layout

Default configuration using flash layout with active app and firmware storage on internal flash

    +--------------------------+
    |                          |
    |                          |
    |                          |
    |Firmware Candidate Storage|
    |                          |
    |                          |
    |                          |
    +--------------------------+ <-+ update-client.storage-address
    |                          |
    |        Active App        |
    +--------------------------+ <-+ mbed-bootloader.application-start-address
    |Active App Metadata Header|
    +--------------------------+ <-+ update-client.application-details
    |                          |
    |        Bootloader        |
    |                          |
    +--------------------------+ <-+ 0

Notes on Flash Layout of non PSA tagets with internal flash

This is the default implementation at the default mbed_app.json
The default flash layout is tested with GCC_ARM compiler with newlib-nano and release profile only. If a different compiler is used, the bootloader binary size will be larger and the offsets needs to be adjusted.

The flash layout for non PSA targets with KVStore and firmware storage on internal flash

    +--------------------------+
    |                          |
    |                          |
    |                          |
    |Firmware Candidate Storage|
    |                          |
    |                          |
    |                          |
    +--------------------------+ <-+ update-client.storage-address
    |                          |
    |         KVSTORE          |
    |                          |
    +--------------------------+ <-+ storage_tdb_internal.internal_base_address
    |                          |
    |                          |
    |                          |
    |        Active App        |
    |                          |
    |                          |
    |                          |
    +--------------------------+ <-+ mbed-bootloader.application-start-address
    |Active App Metadata Header|
    +--------------------------+ <-+ update-client.application-details
    |                          |
    |        Bootloader        |
    |                          |
    +--------------------------+ <-+ 0

Notes on Flash Layout of non PSA targets

Internal Flash Only layout can be enabled by compiling the bootloader with the configuration file --app-config configs/internal_flash_no_rot.json. By default the firmware storage region and filesystem is on external sd card.
The default flash layout is tested with GCC_ARM compiler with newlib-nano and release profile only. If a different compiler is used, the bootloader binary size will be larger and the offsets needs to be adjusted.
The KVSTORE regions require even number of flash erase sectors. If the firmware candidate is stored on internal flash, the bootloader does not access the KVStore. But it still needs to be there for the benefit of the Pelion Device Management Client.
Some micro-controller chips are designed with 2 banks of flash that can be read from and written to independently from each other. Hence it is a good idea to put your bootloader and active application on bank 1, your kvstore and firmware candidate storage on bank 2. This way when the application writes data to flash, it doesn't need to halt the processor execution to do it.

PSA configuration using flash layout with KVStore and firmware storage on external storage

    +--------------------------+
    |                          |
    |         KVSTORE          |
    |                          |
    +--------------------------+ <-+ storage_tdb_internal.internal_base_address
    |                          |
    |        Free space        |
    |                          |
    +--------------------------+
    |                          |
    |                          |
    |                          |
    |        Active App        |
    |                          |
    |                          |
    |                          |
    +--------------------------+ <-+ mbed-bootloader.application-start-address
    |Active App Metadata Header|
    +--------------------------+ <-+ update-client.application-details
    |                          |
    |        Bootloader        |
    |                          |
    +--------------------------+ <-+ 0

Notes on Flash Layout of PSA targets

This is the PSA default implementation using the default mbed_app.json
The default flash layout is tested with GCC_ARM compiler with newlib-nano and release profile only. If a different compiler is used, the bootloader binary size will be larger and the offsets needs to be adjusted.
The KVSTORE regions require even number of flash erase sectors. For PSA targets the KVStore is located at the ends of the flash.

Alignment

Flash Erase Boundary: Flash can usually only be erased in blocks of specific sizes, this is platform specific and hence many regions need to align to this boundary.

Flash Page Boundary: Flash can usually only be written in blocks of specific sizes, this is platform specific and hence many regions need to align to this boundary.

Vector Table Size Boundary: The ARM architecture dictates that the Vector table of the application must be placed at an address that aligns to the next power of 2 of the size of the vector table.

External Storage

The firmware update candidates is stored on an external sd card if the default configuration is used. The firmware is stored sequentially on the block device. The expected layout is as follows:

    +--------------------------+<-+ End of SD card block device
    |                          |
    +--------------------------+<-+ update-client.storage-size + update-client.storage-address
    |                          |
    +--------------------------+
    |                          |
    |   Firmware Candidate 1   |
    |                          |
    +--------------------------+
    |   Firmware Candidate 1   |
    |     Metadata Header      |
    +--------------------------+
    |                          |
    +--------------------------+
    |                          |
    |   Firmware Candidate 0   |
    |                          |
    +--------------------------+
    |   Firmware Candidate 0   |
    |     Metadata Header      |
    +--------------------------+ <-+ update-client.storage-address
    |                          |
    +--------------------------+ <-+ Start of SD card block device (i.e. 0x0)

Debug

Debug prints can be turned on by enabling the define #define tr_debug(fmt, ...) printf("[DBG ] " fmt "\r\n", ##__VA_ARGS__) in source/bootloader_common.h and setting the ARM_UC_ALL_TRACE_ENABLE=1 macro on command line mbed compile -DARM_UC_ALL_TRACE_ENABLE=1.

Example config case study

Scenario: Your target is NUCLEO_F429ZI. You have added extra functionality to the bootloader such that the size of the bootloader exceeded the default 32KiB. How to configure your bootloader and application so that everything still work together.

STEP 1: Design flash layout

NUCLEO_F429ZI has 2MiB of flash, and its sector sizes are as follows: 4x16KiB, 1x64KiB, 7x128KiB, 4x16KiB, 1x64KiB, 7x128KiB. Because the bootloader is larger than 32KiB, it will take the first 3 sectors. The KVStore area can no longer take 2x16KiB sectors. KVStore require even number of sectors. Hence we will move KVSTORE to the last 2x128KiB sectors in the flash region. So we will end up with the following layout:

0x08000000 - 0x0800C000 Bootloader
0x0800C000 - 0x0800C400 Application Header
0x0800C400 - 0x081C0000 Application
0x081C0000 - 0x08200000 KVSTORE

The update firmware candidate is still stored on sd-card.

STEP 2: Configure the bootloader

Given the above flash layout the following configuration need to change in the mbed_app.json:

"storage_filesystem.internal_base_address": "(0x08000000+(2*1024-2*128)*1024)"
"storage_filesystem.rbp_internal_size": "(2*128*1024)"
"update-client.application-details": "(0x08000000+3*16*1024)"
"mbed-bootloader.application-start-address": "(0x08000000+(3*16+1)*1024)"
"mbed-bootloader.max-application-size" : "((1024*2-128*2-3*16-1)*1024)"

Now compile your bootloader. Flash and run the bootloader, on the serial UART you will see the following printout:

Layout: <layout_no> <boot_loader_info_address>

Keep a note of the boot_loader_info_address which we will use in the next step.

STEP 3: Configure the Pelion Cloud Client Application

In mbed_app.json, change the following:

"update-client.application-details" : "(0x08000000+3*16*1024)"
"update-client.bootloader-details" : "<boot_loader_info_address>"

Change the following in mbed_app.json:

"storage_filesystem.internal_base_address": "(0x08000000+(2*1024-2*128)*1024)"
"storage_filesystem.rbp_internal_size": "(2*128*1024)"
"target.app_offset": "0x800c400",
"target.header_offset": "0x800c000",
"target.bootloader_img": "<path_to_your_newly_built_image>"

Now you can build the application following the Pelion Device Management Platform Documentation.

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mbed-bootloader's Issues

Readme instructions for compile unclear

The readme specifies the following command for compile.

mbed compile -t GCC_ARM -m [target] --profile release --app-config=configs/.json

This doesn't work because you need to explicitly specify the configuration file to use.

It would be of great help to the user to include an intermediate step that asks them to choose the flash layout and other configuration choices.

Update instructions to benefit from `mbed dm` feature

Mbed OS 5.10 (about to be released) supports merging the application with the bootloader automatically.
Requires having Mbed CLI 1.8.x

Instructions on this mbed-bootloader repo should be updated:
https://github.com/ARMmbed/mbed-bootloader#build-instructions

An include references to documentation, for example:

Mbed CLI
https://os.mbed.com/docs/latest/tools/cli-update.html (to be made available asap)
Create an application include a bootloader
https://os.mbed.com/docs/latest/tutorials/bootloader.html (to be made available asap)

@LiyouZhou is this something you could help with?

bootloader readme.md refers to internal repository

The README.md has this about Device Secret Key:

Alternatively you can choose to use a custom device specific RoT by implementing the function mbed_cloud_client_get_rot_128bit. An example can be found here.

The here points to mbed-bootloader-internal repository which is not accessible by the same audience as mbed-bootloader.

Questions for mbed-bootloader

I'm understanding about bootloader and referring below link.
(https://github.com/ARMmbed/mbed-bootloader)
(https://cloud.mbed.com/docs/current/updating-firmware/bootloaders.html)
(https://cloud.mbed.com/docs/current/porting/porting-the-device-management-update-client.html#bootloader)

I'm confused because could not find the answer or understand about below questions.

When a new firmware combined bootloader is initially flashed by drag and drop, is it right that this file is always stored in each active app and bootloader area in internal flash?
When we inject the secure information(ex. Device private key and certificate), where is this information stored, internal flash or external flash(SD-card)??

Could you please answer me??

Thanks.

How do we determine the content of bootloader-details?

Some significant values are not set in the BOOTLOADER_ARM_SOURCE_HASH, BOOTLOADER_OEM_SOURCE_HASH and BOOTLOADER_STORAGE_LAYOUT.

Do you plan to implement them in the future?
Does the user need to set some values?
We understand that these values are bootloader-details, but I could not find a document on this definitions.

https://github.com/ARMmbed/mbed-bootloader/blob/061032fd7604e79785152e00175dcfc15dfe06cb/mbed_bootloader_info.h#L24-L34

Mbed OS PR #12278 breaks compilation

Mbed OS renamed target.default_lib to target.c_lib in PR ARMmbed/mbed-os#12278 which breaks the current configuration files.

@SeppoTakalo I would recommend pinning Mbed OS to a version to your liking.

Need better information on how to configure nvstore

Building for K64F with 5.10 rc, ends up in error:

Building project mbed-bootloader (K64F, GCC_ARM)
Scan: mbed-bootloader
Scan: env
[ERROR] Attempt to override undefined parameter 'nvstore.area_1_address' in 'application[K64F]'

Not able to find documentation on how to actually configure my build correctly.

existsErrorMessageLeadingToReboot function returns always false.

bool existsErrorMessageLeadingToReboot(void) { return false; }

Are you going to implement the contents in the future?
Or does the user need to implement them adapted to the user application?

Getting value of "update-client.bootloader-details"

The mbed os pelion example json file requires us to enter the update-client.bootloader-details address. The value for this address is taken by running the bootloader binary which shows the following line:
[BOOT] Layout: 0 8006F1C
The value 8006F1C in this case is set in to update-client.bootloader-details.

Since latest commit on mbed-bootloader, this information is not displayed any more. One way i can think of is to add a printf myself to get this address but what do you recommend?

Secondly the mbed os pelion example (currently private) is now updated to mbed-os 5.14.0 so do any idea when this repository will be updated to mbed-os 5.14?

Earlier the pelion example test cases were passing mbed-os 5.13.4 and bootloader v4.0.3 but now i am getting failures so just wanted to confirm if there any compatibilty issues with mbed-os 5.14.0 and bootloader version 4.0.3?

@MarceloSalazar

Fail to build with GCC_ARM

I build mbed-bootloader with:

mbed compile -m K64F -t GCC_ARM --profile tiny.json

but fail with error message:

Compile [100.0%]: test_env.cpp
Link: mbed-bootloader
BUILD/K64F/GCC_ARM/source/bootloader_common.o: In function `printSHA256':
C:\ccli8\iot\mbed\mbed-os\mbed-bootloader/.\source/bootloader_common.c:60: undefined reference to `__wrap_printf'
BUILD/K64F/GCC_ARM/source/bootloader_common.o: In function `printProgress':
C:\ccli8\iot\mbed\mbed-os\mbed-bootloader/.\source/bootloader_common.c:73: undefined reference to `__wrap_printf'
C:\ccli8\iot\mbed\mbed-os\mbed-bootloader/.\source/bootloader_common.c:84: undefined reference to `__wrap_printf'
C:\ccli8\iot\mbed\mbed-os\mbed-bootloader/.\source/bootloader_common.c:95: undefined reference to `__wrap_printf'
C:\ccli8\iot\mbed\mbed-os\mbed-bootloader/.\source/bootloader_common.c:91: undefined reference to `__wrap_printf'
BUILD/K64F/GCC_ARM/source/main.o:C:\ccli8\iot\mbed\mbed-os\mbed-bootloader/.\source/main.cpp:89: more undefined references to `__wrap_printf' follow
collect2.exe: error: ld returned 1 exit status
[ERROR] BUILD/K64F/GCC_ARM/source/bootloader_common.o: In function `printSHA256':
C:\ccli8\iot\mbed\mbed-os\mbed-bootloader/.\source/bootloader_common.c:60: undefined reference to `__wrap_printf'
BUILD/K64F/GCC_ARM/source/bootloader_common.o: In function `printProgress':
C:\ccli8\iot\mbed\mbed-os\mbed-bootloader/.\source/bootloader_common.c:73: undefined reference to `__wrap_printf'
C:\ccli8\iot\mbed\mbed-os\mbed-bootloader/.\source/bootloader_common.c:84: undefined reference to `__wrap_printf'
C:\ccli8\iot\mbed\mbed-os\mbed-bootloader/.\source/bootloader_common.c:95: undefined reference to `__wrap_printf'
C:\ccli8\iot\mbed\mbed-os\mbed-bootloader/.\source/bootloader_common.c:91: undefined reference to `__wrap_printf'
BUILD/K64F/GCC_ARM/source/main.o:C:\ccli8\iot\mbed\mbed-os\mbed-bootloader/.\source/main.cpp:89: more undefined references to `__wrap_printf' follow
collect2.exe: error: ld returned 1 exit status

[mbed] ERROR: "c:\python27\python.exe" returned error code 1.
[mbed] ERROR: Command "c:\python27\python.exe -u C:\ccli8\iot\mbed\mbed-os\mbed-bootloader\mbed-os\tools\make.py -t GCC_ARM -m K64F --profile tiny.json --source . --build .\BUILD\K64F\GCC_ARM" in "C:\ccli8\iot\mbed\mbed-os\mbed-bootloader"
---

Target
K64F

GCC_ARM Toolchain
GNU Tools for Arm Embedded Processors 7-2017-q4-major

mbed-bootloader
v3.3.0

mbed-os
5.8.4

Update to mbed-os 6.5.0 + CMake

Hi there!

I'm wondering if you are planning on updating the mbed-bootloader to mbed-os 6.5.0+ with CMake support? :)

Fails to compile with LPC55S69_NS

Following these steps

mbed import https://github.com/ARMmbed/mbed-bootloader

cd mbed-bootloader

mbed compile -t ARM -m LPC55S69_NS --profile=tiny.json

Results in this

[Warning] @0,0: L6320W: Ignoring --keep command. Cannot find argument 'os_cb_sections'.
[Error] @0,0: L6218E: Undefined symbol trng_free (referred from BUILD/LPC55S69_NS/ARM-TINY/mbed-os/features/mbedtls/platform/src/mbed_trng.o).
[Error] @0,0: L6218E: Undefined symbol trng_get_bytes (referred from BUILD/LPC55S69_NS/ARM-TINY/mbed-os/features/mbedtls/platform/src/mbed_trng.o).
[Error] @0,0: L6218E: Undefined symbol trng_init (referred from BUILD/LPC55S69_NS/ARM-TINY/mbed-os/features/mbedtls/platform/src/mbed_trng.o).
Warning: L3912W: Option 'legacyalign' is deprecated.
"C:\Users\PELION~1\AppData\Local\Temp\p1120-3", line 38 (column 3): Warning: L6312W: Empty Execution region description for region RW_IRAM1
Warning: L6320W: Ignoring --keep command. Cannot find argument 'os_cb_sections'.
Error: L6218E: Undefined symbol trng_free (referred from BUILD/LPC55S69_NS/ARM-TINY/mbed-os/features/mbedtls/platform/src/mbed_trng.o).
Error: L6218E: Undefined symbol trng_get_bytes (referred from BUILD/LPC55S69_NS/ARM-TINY/mbed-os/features/mbedtls/platform/src/mbed_trng.o).
Error: L6218E: Undefined symbol trng_init (referred from BUILD/LPC55S69_NS/ARM-TINY/mbed-os/features/mbedtls/platform/src/mbed_trng.o).
Finished: 0 information, 3 warning and 3 error messages.
[ERROR] Warning: L3912W: Option 'legacyalign' is deprecated.
"C:\Users\PELION~1\AppData\Local\Temp\p1120-3", line 38 (column 3): Warning: L6312W: Empty Execution region description for region RW_IRAM1
Warning: L6320W: Ignoring --keep command. Cannot find argument 'os_cb_sections'.
Error: L6218E: Undefined symbol trng_free (referred from BUILD/LPC55S69_NS/ARM-TINY/mbed-os/features/mbedtls/platform/src/mbed_trng.o).
Error: L6218E: Undefined symbol trng_get_bytes (referred from BUILD/LPC55S69_NS/ARM-TINY/mbed-os/features/mbedtls/platform/src/mbed_trng.o).
Error: L6218E: Undefined symbol trng_init (referred from BUILD/LPC55S69_NS/ARM-TINY/mbed-os/features/mbedtls/platform/src/mbed_trng.o).
Finished: 0 information, 3 warning and 3 error messages.

RSPIF not supported

I use "internal_kvstore_with_spif.json" as the bootloader configuration file. Then change
"target.components_add": ["SPIF"],
for
"target.components_add": ["RSPIF"],
I found out that SPIFReducedBlockDevice.cpp was not compiled, and there was a link error.

log:

Link: mbed-bootloader-NUCLEO_F412ZG
BUILD/NUCLEO_F412ZG/GCC_ARM-RELEASE/mbed-os/features/storage/system_storage/SystemStorage.o: In function mbed::BlockDevice::get_default_instance()': /home/user/mbed/mbed-bootloader/./mbed-os/features/storage/system_storage/SystemStorage.cpp:111: undefined reference to SPIFReducedBlockDevice::SPIFReducedBlockDevice(PinName, PinName, PinName, PinName, int)'
BUILD/NUCLEO_F412ZG/GCC_ARM-RELEASE/mbed-os/features/storage/system_storage/SystemStorage.o: In function SPIFReducedBlockDevice::~SPIFReducedBlockDevice()': /home/user/mbed/mbed-bootloader/./mbed-os/components/storage/blockdevice/COMPONENT_RSPIF/SPIFReducedBlockDevice.h:59: undefined reference to vtable for SPIFReducedBlockDevice'
collect2: error: ld returned 1 exit status
[ERROR] BUILD/NUCLEO_F412ZG/GCC_ARM-RELEASE/mbed-os/features/storage/system_storage/SystemStorage.o: In function mbed::BlockDevice::get_default_instance()': /home/user/mbed/mbed-bootloader/./mbed-os/features/storage/system_storage/SystemStorage.cpp:111: undefined reference to SPIFReducedBlockDevice::SPIFReducedBlockDevice(PinName, PinName, PinName, PinName, int)'
BUILD/NUCLEO_F412ZG/GCC_ARM-RELEASE/mbed-os/features/storage/system_storage/SystemStorage.o: In function SPIFReducedBlockDevice::~SPIFReducedBlockDevice()': /home/user/mbed/mbed-bootloader/./mbed-os/components/storage/blockdevice/COMPONENT_RSPIF/SPIFReducedBlockDevice.h:59: undefined reference to vtable for SPIFReducedBlockDevice'
collect2: error: ld returned 1 exit status

[mbed] ERROR: "/usr/bin/python3" returned error.
Code: 1
Path: "/home/user/mbed/mbed-bootloader"
Command: "/usr/bin/python3 -u /home/user/mbed/mbed-bootloader/mbed-os/tools/make.py -t GCC_ARM -m NUCLEO_F412ZG --profile release --source . --build ./BUILD/NUCLEO_F412ZG/GCC_ARM-RELEASE -c --artifact-name mbed-bootloader-NUCLEO_F412ZG --app-config configs/internal_kvstore_with_rspif.json"
Tip: You could retry the last command with "-v" flag for verbose output

mbed-bootloader build doesn't find mbed_trace.h and fails

mbed-bootloader when built with mbed-cli with newer mbed-os (commit: 3252530e3a94d4d39e70d67c779577e0e57365f1) fails to build. Build logs and steps to reproduce given below. It's suspsected that .mbedignore list is causing this. An analysis of this is needed.

$ git clone https://github.com/ARMmbed/mbed-bootloader.git
Cloning into 'mbed-bootloader'...
remote: Enumerating objects: 21, done.
remote: Counting objects: 100% (21/21), done.
remote: Compressing objects: 100% (13/13), done.
remote: Total 101 (delta 9), reused 15 (delta 8), pack-reused 80
Receiving objects: 100% (101/101), 61.69 KiB | 0 bytes/s, done.
Resolving deltas: 100% (33/33), done.
Checking connectivity... done.
$ cd mbed-bootloader/
$ ls
bootloader_mbedtls_user_config.h  firmware_update_test  LICENSE        mbed_bootloader_info.h  mbed-os.lib         power_cut_test  sd-driver.lib  tiny.json
configs                           fix-mbed-os-compile   mbed_app.json  mbed-cloud-client.lib   minimal-printf.lib  README.md       source
$ mbed deploy
[mbed] Working path "/home/navkaj01/code/mbed-bootloader" (program)
[mbed] Adding library "mbed-os" from "https://github.com/ARMmbed/mbed-os" at rev #610e35ddc6d5
[mbed] Adding library "mbed-cloud-client" from "https://github.com/ARMmbed/mbed-cloud-client" at rev #62de4b89d235
[mbed] Adding library "sd-driver" from "https://github.com/ARMmbed/sd-driver" at rev #ae7e7440054c
[mbed] Adding library "minimal-printf" from "https://github.com/ARMmbed/minimal-printf" at rev #5cbf9d1dcb58

-- set mbed-os tip to latest (as of 2/8) --

$ mbed compile  -c -t GCC_ARM -m K64F --profile=tiny.json
<snip>
Compile [ 51.5%]: HeapBlockDevice.cpp
Compile [ 51.8%]: ssl_cli.c
Compile [ 52.2%]: ProfilingBlockDevice.cpp
Compile [ 52.5%]: ObservingBlockDevice.cpp
Compile [ 52.8%]: SlicingBlockDevice.cpp
Compile [ 53.2%]: ReadOnlyBlockDevice.cpp
Compile [ 53.5%]: ssl_srv.c
Compile [ 53.8%]: MBRBlockDevice.cpp
Compile [ 54.2%]: ffunicode.cpp
Compile [ 54.5%]: x509_crt.c
Compile [ 54.8%]: Dir.cpp
Compile [ 55.1%]: lfs_util.c
Compile [ 55.5%]: File.cpp
Compile [ 55.8%]: FileSystem.cpp
Compile [ 56.1%]: kv_config.cpp
[Fatal Error] kv_config.cpp@30,10: mbed_trace.h: No such file or directory
[ERROR] ./mbed-os/features/storage/kvstore/conf/kv_config.cpp:30:10: fatal error: mbed_trace.h: No such file or directory
 #include "mbed_trace.h"
          ^~~~~~~~~~~~~~
compilation terminated.

[mbed] ERROR: "/usr/bin/python" returned error.
       Code: 1
       Path: "~/code/mbed-bootloader"
       Command: "/usr/bin/python -u ~/code/mbed-bootloader/mbed-os/tools/make.py -t GCC_ARM -m K64F --profile tiny.json --source . --build ./BUILD/K64F/GCC_ARM-TINY -c"
       Tip: You could retry the last command with "-v" flag for verbose output
---
<snip>

Library name 'sd' is not unique

The upcoming 5.10 has new SD block device and the existing sd-driver conflicts with it.
Ref: ARMmbed/mbed-os#7774

Enabling BOOT messages

Older versions of Mbed Bootloader used to display BOOT messages as below:

[BOOT] Mbed Bootloader
[BOOT] ARM: 00000000000000000000
[BOOT] OEM: 00000000000000000000
[BOOT] Layout: 0 1006F44
[BOOT] Active firmware integrity check:
[BOOT] [++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++]
[BOOT] SHA256: ABAF3AC1F2D7B8173BC5540DA50E7093C8A479E4C0148090348BD1EA68A0958F
[BOOT] Version: 1539890967
[BOOT] Slot 0 is empty
[BOOT] Active firmware up-to-date
[BOOT] Application's start address: 0x1008400
[BOOT] Application's jump address: 0x1046081
[BOOT] Application's stack address: 0x20040000
[BOOT] Forwarding to application...

Now, these messages seem gone, and it only shows like this:

Mbed Bootloader
booting...

How can I enable the rich BOOT messages? I need those for debugging purposes.

Thanks a lot.

sotp configuration in mbed_app.json for UBLOX_EVK_ODIN_W2 seems too small for default bootloader image size

The SOTP configuration in mbed_app.json for UBLOX_EVK_ODIN_W2 places sotp-section-1 at 32k bytes past the start of flash. However, the default bootloader image size is larger than that, at 59k bytes. Assuming the bootloader is written to start of flash, this means that the bootloader image overlaps the sotp section which will result in a corrupted system.

Please either correct my understanding of the flash layout for bootloader+SOTP+App, or suggest corrected offsets for the 2 sotp sections as well as any additional changes that should be applied to the App image. For example, I assume that if the sotp offset is changed in the bootloader's mbed_app.json, then the same change should be made in the app's mbed_app.json; are there any other changes?

Here are the steps to build:

$ git clone [email protected]:armmbed/mbed-bootloader
$ git checkout v3.3.0
$ mbed config ROOT .
$ mbed target UBLOX_EVK_ODIN_W2
$ mbed toolchain GCC_ARM
$ arm-none-eabi-gcc --version
arm-none-eabi-gcc (GNU Tools for Arm Embedded Processors 7-2017-q4-major) 7.2.1 20170904 (release) [ARM/embedded-7-branch revision 255204]
$ mbed compile

This results in the following output:

...
Elf2Bin: mbed-bootloader
+-----------------------------------------------+-------+-------+-------+
| Module                                        | .text | .data |  .bss |
+-----------------------------------------------+-------+-------+-------+
| [fill]                                        |   137 |     4 |    27 |
| [lib]/c.a                                     | 24925 |  2472 |    89 |
| [lib]/gcc.a                                   |  3112 |     0 |     0 |
| [lib]/misc                                    |   208 |    12 |    28 |
| fix-mbed-os-compile/pal_polyfill.o            |     4 |     0 |     0 |
| mbed-cloud-client/factory-configurator-client |  1676 |     0 |    92 |
| mbed-cloud-client/mbed-client-pal             |   708 |     4 |     4 |
| mbed-cloud-client/update-client-hub           |  2275 |     4 |    16 |
| mbed-os/drivers                               |  1476 |     0 |    20 |
| mbed-os/features                              |  2032 |     0 |     0 |
| mbed-os/hal                                   |  1182 |     4 |    64 |
| mbed-os/platform                              |  1504 |     4 |   270 |
| mbed-os/targets                               | 11515 |     4 |   804 |
| sd-driver/SDBlockDevice.o                     |  4469 |     0 |     0 |
| source/active_application.o                   |   842 |     4 |     4 |
| source/bootloader_common.o                    |   246 |     4 | 16385 |
| source/bootloader_platform.o                  |    46 |     0 |     0 |
| source/main.o                                 |   779 |     8 |   328 |
| source/sotp_rot.o                             |    92 |     0 |     1 |
| source/upgrade.o                              |  1367 |     0 |     8 |
| Subtotals                                     | 58595 |  2524 | 18140 |
+-----------------------------------------------+-------+-------+-------+
Total Static RAM memory (data + bss): 20664 bytes
Total Flash memory (text + data): 61119 bytes

Here is the relevant section of mbed_app.json for UBLOX_EVK_ODIN_W2:

            "flash-start-address"              : "0x08000000",
            "flash-size"                       : "(2048*1024)",
            "sotp-section-1-address"           : "(MBED_CONF_APP_FLASH_START_ADDRESS+32*1024)",
            "sotp-section-1-size"              : "(16*1024)",
            "sotp-section-2-address"           : "(MBED_CONF_APP_FLASH_START_ADDRESS+48*1024)",
            "sotp-section-2-size"              : "(16*1024)",

Smoke test doesn't work

I followed the instruction here, and got result below:

10:57:02 smoke $ ./test.sh K64F https://ruka.mbedcloudtesting.com:443
HOST: Inspecting './test/host_tests' for local host tests...
[1591063026.39][HTST][INF] host test executor ver. 0.0.13
[1591063026.39][HTST][INF] copy image onto target... SKIPPED!
[1591063026.40][HTST][INF] starting host test process...
[1591063026.40][CONN][INF] starting connection process...
[1591063026.40][CONN][INF] notify event queue about extra 240 sec timeout for serial port pooling
[1591063026.40][CONN][INF] initializing global resource mgr listener... 
[1591063026.40][GLRM][ERR] unable to load global resource manager 'raas_client' module!
[1591063026.40][GLRM][ERR] No module named 'raas_client'
[1591063026.40][HTST][INF] setting timeout to: 240 sec
[1591063026.40][CONN][ERR] Failed to connect to resource
[1591063026.41][HTST][ERR] None
[1591063026.41][HTST][WRN] stopped to consume events due to __notify_conn_lost event
[1591063026.41][HTST][INF] __exit_event_queue received
[1591063026.41][HTST][INF] test suite run finished after 0.00 sec...
[1591063026.41][HTST][INF] CONN exited with code: 0
[1591063026.41][HTST][INF] No events in queue
[1591063026.41][HTST][INF] host test result() call skipped, received: ioerr_serial
[1591063026.41][HTST][WRN] missing __exit event from DUT
[1591063026.41][HTST][INF] calling blocking teardown()
[1591063026.41][HTST][INF] teardown() finished
[1591063026.41][HTST][INF] {{result;ioerr_serial}}
10:57:06 smoke $

How can I run the smoke test for the mbed-bootloader?

Fail to reboot with ARM/IAR

I build mbed-bootloader by:
mbed compile -m K64F -t ARM --profile tiny.json
Or:
mbed compile -m K64F -t IAR --profile tiny.json
At first boot, I can see log meessage:

[BOOT] mbed Bootloader
[BOOT] ARM: 0000000000000000000000000000000000000000
[BOOT] OEM: 0000000000000000000000000000000000000000
[BOOT] Layout: 0 9420
[BOOT] Active firmware integrity check:
[ERR ] Active firmware integrity check failed

But I see none after reboot.

If I flash attached K64F bootloader tools/mbed-bootloader-k64f-block_device-sotp-v3_3_0.bin in mbed-cloud-client-example (1.3.1.1), reboot is OK:

[BOOT] mbed Bootloader
[BOOT] ARM: 74CE36607E38CD63ECDD72CE2F1262D58BF55448
[BOOT] OEM: 0000000000000000000000000000000000000000
[BOOT] Layout: 0 7188
[BOOT] Active firmware integrity check:
[ERR ] Active firmware integrity check failed
[BOOT] Slot 0 is empty
[ERR ] Active firmware invalid
[ERR ] Failed to jump to application!
[BOOT] mbed Bootloader
[BOOT] ARM: 74CE36607E38CD63ECDD72CE2F1262D58BF55448
[BOOT] OEM: 0000000000000000000000000000000000000000
[BOOT] Layout: 0 7188
[BOOT] Active firmware integrity check:
[ERR ] Active firmware integrity check failed
[BOOT] Slot 0 is empty
[ERR ] Active firmware invalid
[ERR ] Failed to jump to application!