Integration guide

The purpose of this document is to provide a guide on how to integrate TF-M with other hardware platforms and operating systems.

How to build TF-M

Follow the Build instructions.

How to export files for building non-secure applications

Explained in the Build instructions.

How to add a new platform

Porting TF-M to a New Hardware contains guidance on how to add a new platform.

Supported Platforms

The hardware platforms currently supported are:

  • Soft Macro Model (SMM) Cortex-M33 SSE-200 subsystem for MPS2+ (AN521)

  • Cortex-M23 IoT Kit subsystem for MPS2+ (AN519)

  • Corstone-300 Ethos-U55 FVP (Cortex-M55 plus Ethos-U55 SSE-300 MPS3)

  • Musca-B1 test chip board (Cortex-M33 SSE-200 subsystem)

  • Musca-S1 test chip board (Cortex-M33 SSE-200 subsystem)

  • CoreLink SSE-200 Subsystem for MPS3 (AN524)

  • Corstone SSE-300 with Ethos-U55 Example Subsystem for MPS3 (AN547)

  • STM32L5xx: Cortex-M33 based platform (STM32L562 and STM32L552 socs)

  • nRF9160 DK (Cortex-M33)

  • nRF5340 DK (Cortex-M33 Application MCU)

  • BL5340 DVK (Cortex-M33 Application MCU)

  • Corstone-Polaris Ethos-U55 FVP (Olympus CPU plus Ethos-U55)

The files related to the supported platforms are contained under the platform subfolder. The platform specific files are under platform/ext/target, which is organised by boards (e.g. platform/ext/target/mps2), while the folder platform/ext/common is used to store source and header files which are platform generic.

More information about subsystems supported by the MPS2+ board can be found in: MPS2+ homepage

More information about subsystems supported by the MPS3 board can be found in: MPS3 homepage

More information about the Musca-B1 test chip board can be found in: Musca-B1 homepage

More information about the Musca-S1 test chip board can be found in: Musca-S1 homepage

More information about subsystems supported by the MPS3 board can be found in: MPS3 homepage

More information about the Corstone-300 FVPs can be found in: Arm Ecosystem FVPs homepage

More information about the STM32L5xx platform can be found in: STM32L5 series product page

More information about the nRF5340 DK platform can be found in: nRF5340 DK product page

More information about the nRF9160 DK platform can be found in: nRF9160 DK product page

More information about the BL5340 platform can be found in: BL5340 product page

How to integrate another OS

OS migration to Armv8-M platforms

To work with TF-M on Armv8-M platforms, the OS needs to support the Armv8-M architecture and, in particular, it needs to be able to run in the non-secure world. More information about OS migration to the Armv8-M architecture can be found in the OS requirements. Depending upon the system configuration this may require configuring drivers to use appropriate address ranges.

Interface with TF-M

The files needed for the interface with TF-M are exported at the <install_dir>/interface path. The NS side is only allowed to call TF-M secure functions (veneers) from the NS Thread mode.

TF-M interface header files are exported in <install_dir>/interface/include directory. For example, the Protected Storage (PS) service PSA API is declared in the file <install_dir>/interface/include/psa/protected_storage.h.

TF-M also exports a reference implementation of PSA APIs for NS clients in the <install_dir>/interface/src.

On Armv8-M TrustZone based platforms, NS OS shall implement interface API tfm_ns_interface_dispatch() to integrate with TF-M implementation of PSA APIs. See interface/include/tfm_ns_interface.h for the detailed declaration of tfm_ns_interface_dispatch(). TF-M provides an example of tfm_ns_interface_dispatch() implementation on Armv8-M TrustZone based platforms. In this example, NS OS calls mutex in tfm_ns_interface_dispatch() to synchronize multiple NS client calls to TF-M. See interface/src/tfm_ns_interface.c.example for more details.

TF-M provides a reference implementation of NS mailbox on multi-core platforms, under folder interface/src/multi_core. See Mailbox design for TF-M multi-core mailbox design.

Interface with non-secure world regression tests

A non-secure application that wants to run the non-secure regression tests needs to call the tfm_non_secure_client_run_tests(). This function is exported into the header file test_framework_integ_test.h inside the <build_dir>/install folder structure in the test specific files, i.e. <build_dir>/install/export/tfm/test/inc. The non-secure regression tests are precompiled and delivered as a static library which is available in <build_dir>/install/export/tfm/test/lib, so that the non-secure application needs to link against the library to be able to invoke the tfm_non_secure_client_run_tests() function. The PS non-secure side regression tests rely on some OS functionality e.g. threads, mutexes etc. These functions comply with CMSIS RTOS2 standard and have been exported as thin wrappers defined in os_wrapper.h contained in <build_dir>/install/export/tfm/test/inc. OS needs to provide the implementation of these wrappers to be able to run the tests.

NS client Identification

The NS client identification (NSID) is specified by either SPM or NSPE RTOS. If SPM manages the NSID (default option), then the same NSID (-1) will be used for all connections from NS clients. For the case that NSPE RTOS manages the NSID and/or different NSIDs should be used for different NS clients. See Non-secure Client Extension Integration Guide.

Non-secure interrupts

Non-secure interrupts are allowed to preempt Secure thread mode. With the current implementation, a NSPE task can spoof the identity of another NSPE task. This is an issue only when NSPE has provisions for task isolation. Note, that AIRCR.PRIS is still set to restrict the priority range available to NS interrupts to the lower half of available priorities so that it wouldn’t be possible for any non-secure interrupt to preempt a higher-priority secure interrupt.

Integration with non-Cmake systems

Generated Files

Files that are derived from PSA manifests are generated at build-time by cmake. For integration with systems that do no use cmake, the files must be generated manually.

The tools/tfm_parse_manifest_list.py script can be invoked manually. Some arguments will be needed to be provided. Please refer to tfm_parse_manifest_list.py --help for more details.

Some variables are used in the template files, these will need to be set in the environment before the script will succeed when the script is not run via cmake.


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