core/pldm: Add PLDM responder support

PLDM defines data representations and commands that abstract the platform
management hardware.

A PLDM Terminus (or responder) is defined as the point of communication
termination for PLDM messages and the PLDM functions associated with those
messages.
A PLDM terminus is not required to process more than one request at a time
(that is, it can be "single threaded" and does not have to accept and act
on new requests until it has finished responding to any previous request).

Some PLDM control and discovery requests (PLDM_TYPE = PLDM_BASE) are
mandatory a PLDM terminus has to answer.

These following mandatory PLDM command codes for PLDM messaging control
and discovery will be defined in next patches.
    GetTID          0x02
    GetPLDMVersion  0x03
    GetPLDMTypes    0x04
    GetPLDMCommands 0x05

Reviewed-by: Abhishek Singh Tomar <abhishek@linux.ibm.com>
Signed-off-by: Christophe Lombard <clombard@linux.ibm.com>
Signed-off-by: Reza Arbab <arbab@linux.ibm.com>
4 files changed
tree: 51fce7eec73ab205036dd37fcf890a031edf6686
  1. .github/
  2. asm/
  3. ccan/
  4. core/
  5. doc/
  6. external/
  7. hdata/
  8. hw/
  9. include/
  10. libc/
  11. libfdt/
  12. libflash/
  13. libmctp/
  14. libpore/
  15. libstb/
  16. libxz/
  17. opal-ci/
  18. platforms/
  19. pldm/
  20. test/
  21. .gitignore
  22. CONTRIBUTING.md
  23. coverity-model.c
  24. extract-gcov.c
  25. LICENCE
  26. make_offsets.sh
  27. make_version.sh
  28. Makefile
  29. Makefile.main
  30. Makefile.rules
  31. README.md
  32. skiboot.lds.S
  33. skiboot.spec
README.md

skiboot

Firmware for OpenPower systems.

Source: https://github.com/open-power/skiboot

Mailing list: skiboot@lists.ozlabs.org

Info/subscribe: https://lists.ozlabs.org/listinfo/skiboot

Archives: https://lists.ozlabs.org/pipermail/skiboot/

Patchwork: http://patchwork.ozlabs.org/project/skiboot/list/

Documentation: http://open-power.github.io/skiboot/doc/index.html

Overview

OPAL firmware (OpenPower Abstraction Layer) comes in several parts.

A simplified flow of what happens when the power button is pressed is:

  1. The baseboard management controller (BMC) powers the system on.
  2. The BMC selects the master chip and releases the self-boot engines (SBEs) on the POWER8 chips, master last.
  3. The BMC relinquishes control of the flexible service interface (FSI) SCAN/SCOM engines.
  4. The hostboot firmware IPLs the system. It initiates a secondary power-on sequence through a digital power systems sweep (DPSS).
  5. The hostboot firmware loads the OPAL image and moves all processors to their execution starting points.

Here, the OPAL image is three parts:

  1. skiboot (includes OPAL runtime services)
  2. skiroot - the bootloader environment
    • kernel
    • initramfs (containing petitboot bootloader)

They may be all part of one payload or three separate images (depending on platform).

The bootloader will kexec a host kernel (probably linux). The host OS can make OPAL calls. The OPAL API is documented in doc/opal-api/ (there are missing parts, patches are welcome!)

See doc/overview.rst for a more in depth overview of skiboot.

Building

Any host OS can build and test skiboot provided it has a C cross compiler for big endian powerpc64. All good Linux distributions (and several bad ones) provide a packaged compiler that can be installed through the usual package management tools.

To build on Ubuntu:

apt-get install gcc-powerpc64le-linux-gnu gcc valgrind \
	expect libssl-dev device-tree-compiler make \
	xz-utils libmbedtls-dev
CROSS=powerpc64le-linux-gnu- make -j`nproc`

To build on Fedora:

dnf install gcc-powerpc64le-linux-gnu binutils-powerpc64-linux-gnu gcc make \
    diffutils findutils expect valgrind-devel dtc openssl-devel xz \
    mbedtls-devel
CROSS=powerpc64le-linux-gnu- make -j`nproc`

(The little-endian powerpc64le compilers in Ubuntu and Fedora are actually bi-endian and can compile skiboot even though it's big-endian. We recommend installing a little-endian toolchain if you plan on building other projects.)

On any POWER system with a bi-endian system compiler:

CROSS="" make -j`nproc`

Alternatively, pre-built cross compilers for x86 systems can be downloaded from here: https://www.kernel.org/pub/tools/crosstool/ When using these compilers add /opt/cross/gcc-4.8.0-nolibc/powerpc64-linux/bin/ to your PATH. Once this is done skiboot can be compiler by just running make

Building Documentation

We use Sphinx to produce various documentation from reStructuredText (preferred) and Markdown. The Sphinx documentation has a useful primer for reStructuredText here. And the docutils website has a nice quick reference for the basic constructes.

Building on Fedora

dnf install python3-sphinx python3-recommonmark.noarch
pip install -r doc/requirements.txt
make -C doc/ html SPHINXBUILD=sphinx-build-3

On Ubuntu:

Patches welcome!

View the output using doc/_build/html/index.html

Testing

Skiboot comes with a set of unit tests that can be run on your desktop. They can can be run with:

make check

To test in a simulator, install the IBM POWER8 Functional Simulator from: http://www-304.ibm.com/support/customercare/sas/f/pwrfs/home.html Also see external/mambo/README.md

Qemu as of version 2.8 implements the ‘powernv’ machine model and is sufficient to run skiboot:

qemu-system-ppc64 -M powernv -m 3G -nographic -L /path/to/skiboot/

To run a boot-to-bootloader test you need a Linux kernel image ‘zImage.epapr’. Build one using the opal_defconfig config for op-build. See https://github.com/open-power/op-build/ on how to build, or download one from https://github.com/open-power/op-build/releases/ .

Drop zImage.epapr in the skiboot directory and the skiboot test suite will automatically pick it up. You can also run a combined skiboot and Linux test in Qemu (version 3.0+):

qemu-system-ppc64 -M powernv -m 3G -nographic -kernel zImage.epapr -L /path/to/skiboot/

See opal-ci/README for further testing instructions.

To test on real hardware, you will need to understand how to flash new skiboot onto your system. This will vary from platform to platform.

You may want to start with external/boot-tests/boot_test.sh as it can (provided the correct usernames/passwords) automatically flash a new skiboot onto ASTBMC based OpenPower machines.

Hacking

All patches should be sent to the mailing list with linux-kernel style ‘Signed-Off-By’. The following git commands are your friends:

git commit -s
git format-patch

You probably want to read the linux https://kernel.org/doc/html/latest/process/submitting-patches.html as much of it applies to skiboot.

Output files

The Skiboot build process produces a bunch of different outputs. This is what they are, and where you should use them:

skiboot.elf: The output of the linker. Don't flash to a system, but useful when debugging

skiboot.lid: The raw binary object, named .lid because IBM. Flash this on really old P8 systems, the POWER Functional Simulator (mambo), or FSP systems

skiboot.lid.stb: Lid wrapped with secure boot header. Use on FSP systems

skiboot.lid.xz: Compressed raw binary. Use this on a OpenPower P8

skiboot.lid.xz.stb: Compressed raw binary wrapped with a secure boot header. Use this on OpenPower P9 systems

License

See LICENSE