###################### Floating-Point Support ###################### TF-M adds several configuration flags to control Floating point (FP) [1]_ support in TF-M Secure Processing Environment (SPE) and Non Secure Processing Environment (NSPE). * Support FP in SPE or NSPE. * Support FP Application Binary Interface (ABI) [2]_ types: software, hardware. SPE and NSPE shall use the same FP ABI type. * Support lazy stacking enable/disable in SPE only, NSPE is not allowed to enable/disable this feature. * Support GNU Arm Embedded Toolchain [3]_. ``GNU Arm Embedded Toolchain 10.3- 2021.10`` and later version shall be used to mitigate VLLDM instruction security vulnerability [4]_. * Support both IPC [5]_ and SFN [11]_ models in TF-M. * Support Armv8-M mainline. * Support isolation level 1,2,3. * Support Arm Compiler for Embedded [10]_. ``Arm Compiler for Embedded 6.17`` and later version shall be used to mitigate VLLDM instruction security vulnerability [4]_. * Does not support use FPU in First-Level Interrupt Handling (FLIH) [6]_ at current stage. Please refer to Arm AN521 or AN552 platform as a reference implementation when you enable FP support on your platforms. .. Note:: Alternatively, if you intend to use FP in your own NSPE application but the TF-M SPE services that you enable do not require FP, you can set the CMake configuration ``CONFIG_TFM_ENABLE_CP10CP11`` to ``ON`` and **ignore** any configurations described below. .. Note:: CONFIG_TFM_DISABLE_CP10CP11 can be set to ON to disable CP10/CP11 coprocessors in cases when it's expected that FPU must not be used neither by secure nor by non-secure images. .. Note:: ``GNU Arm Embedded Toolchain 10.3-2021.10`` may have issue that reports ``'-mcpu=cortex-m55' conflicts with '-march=armv8.1-m.main'`` warning [8]_. This issue has been fixed in the later version. ============================ FP ABI type for SPE and NSPE ============================ FP design in Armv8.0-M [9]_ architecture requires consistent FP ABI types between SPE and NSPE. Furthermore, both sides shall set up CPACR individually when FPU is used. Otherwise, No Coprocessor (NOCP) usage fault will be asserted during FP context switch between security states. Secure and non-secure libraries are compiled with ``COMPILER_CP_FLAG`` and linked with ``LINKER_CP_OPTION`` for different FP ABI types. All those libraries shall be built with ``COMPLIER_CP_FLAG``. If FP ABI types mismatch error is generated during build, please check whether the library is compiled with ``COMPILER_CP_FLAG``. Example: .. code-block:: cmake target_compile_options(lib PRIVATE ${COMPILER_CP_FLAG} ) =================================== CMake configurations for FP support =================================== The following CMake configurations configure ``COMPILER_CP_FLAG`` in TF-M SPE. * ``CONFIG_TFM_ENABLE_FP`` is used to enable/disable FPU usage. +--------------------------+---------------------------+ | CONFIG_TFM_ENABLE_FP | FP support | +==========================+===========================+ | off (default) | FP disabled | +--------------------------+---------------------------+ | on | FP enabled | +--------------------------+---------------------------+ .. Note:: ``CONFIG_TFM_FLOAT_ABI`` depends on ``CONFIG_TFM_ENABLE_FP``. If ``CONFIG_TFM_ENABLE_FP is set ``CONFIG_TFM_FLOAT_ABI`` is automatically set to ``hard``. .. Note:: If you build TF-M SPE with ``CONFIG_TFM_ENABLE_FP=on`` and provide your own NSPE application, your own NSPE **must** take care of enabling floating point coprocessors CP10 and CP11 on the NS side to avoid aforementioned NOCP usage fault. * ``CONFIG_TFM_LAZY_STACKING`` is used to enable/disable lazy stacking feature. This feature is only valid for FP hardware ABI type. NSPE is not allowed to enable/disable this feature. Let SPE decide the secure/non-secure shared setting of lazy stacking to avoid the possible side-path brought by flexibility. +------------------------------+---------------------------+ | CONFIG_TFM_LAZY_STACKING | Description | +==============================+===========================+ | 0FF | Disable lazy stacking | +------------------------------+---------------------------+ | ON (default) | Enable lazy stacking | +------------------------------+---------------------------+ * ``CONFIG_TFM_FP_ARCH`` specifies which FP architecture is available on the target, valid for FP hardware ABI type. FP architecture is processor dependent. For GNUARM compiler, example value are: auto, fpv5-d16, fpv5-sp-d16, etc. For armclang, example value are: none, softvfp, fpv5-d16, fpv5-sp-d16, etc. This parameter shall be specified by platform in preload.cmake. Please check compiler reference manual and processor hardware manual for more details to set correct FPU configuration for platform. * ``CONFIG_TFM_FP_ARCH_ASM`` specifies the target FPU architecture name shared by Arm Compiler armasm and armlink. It is only used in the ``--fpu=`` argument by Arm Compiler and shall be aligned with ``CONFIG_TFM_FP_ARCH``. FP architecture is processor dependent. For armasm and armlink, example value are: SoftVFP, FPv5_D16, etc. This parameter shall be specified by platform in preload.cmake. Please check compiler reference manual and processor hardware manual for more details to set correct FPU configuration for platform. ********* Reference ********* .. [1] `High-Performance Hardware Support for Floating-Point Operations `_ .. [2] `Float Point ABI `_ .. [3] `GNU Arm Embedded Toolchain `_ .. [4] `VLLDM instruction Security Vulnerability `_ .. [5] `ArmĀ® Platform Security Architecture Firmware Framework 1.0 `_ .. [6] :doc:`Secure Interrupt Integration Guide ` .. [8] `GCC Issue on '-mcpu=cortex-m55' conflicts with '-march=armv8.1-m.main' Warning `_ .. [9] `Armv8-M Architecture Reference Manual `_ .. [10] `Arm Compiler for Embedded `_ .. [11] `FF-M v1.1 Extension `__ -------------- *Copyright (c) 2021-2023, Arm Limited. All rights reserved.*