meta-ibm: romulus: fans: switch to non-native

meta-phosphor recently enabled target class config recipes.  Those are
preferable to native class config recipes because native recipes cannot
be overridden based on MACHINE, so switch to target class config

Switching to target class recipes consists of temporarily setting
PHOSPHOR_FAN_CONFIG_USE_NATIVE_SYSROOT to 0, overriding the phosphor
distro default of 1.  After all OpenBMC BSP layers have moved to target
class config recipes PHOSPHOR_FAN_CONFIG_USE_NATIVE_SYSROOT can be
removed from meta-phosphor and any BSP layers.

Any references to -native recipes are replaced with their target class

Any -native bbappends are re-worked to apply to their target class

Finally, use BPN instead of PN when setting FILESEXTRAPATHS, to avoid
unfortunate directory hierarchies if these bbappends are copy/pasted and
then used to bbappend a native recipe.  Since this patch moves to target
class recipes, this is a noop; however, this avoids unfortunate
directory hierarchies with native bbappends such as:



Using "${THISDIR}/${BPN}:" enables a more sensible hierarchy:



This behavior occurs because By default FILESPATH is set in base.bbclass
(in OE-Core) to look for files in ${BP}, ${BPN} and files (and a number
of subdirectories of those based on ${FILESOVERRIDES}).

(From meta-ibm rev: 589ee00a5ec7bc97c7d5c079cf66b3dbd3ac2b4f)

Change-Id: I1a593373f1b4bc82c554a9330cdd75f04f21d1d8
Signed-off-by: Brad Bishop <>
20 files changed
tree: edb6107204d2434554a383512165884bb086dada
  1. .github/
  2. meta-arm/
  3. meta-aspeed/
  4. meta-evb/
  5. meta-facebook/
  6. meta-google/
  7. meta-hxt/
  8. meta-ibm/
  9. meta-ingrasys/
  10. meta-inspur/
  11. meta-intel/
  12. meta-inventec/
  13. meta-mellanox/
  14. meta-nuvoton/
  15. meta-openembedded/
  16. meta-openpower/
  17. meta-phosphor/
  18. meta-portwell/
  19. meta-qualcomm/
  20. meta-quanta/
  21. meta-raspberrypi/
  22. meta-security/
  23. meta-x86/
  24. meta-xilinx/
  25. poky/
  26. .gitignore
  27. .gitreview
  28. .templateconf
  30. openbmc-env
  32. setup


Build Status

The OpenBMC project can be described as a Linux distribution for embedded devices that have a BMC; typically, but not limited to, things like servers, top of rack switches or RAID appliances. The OpenBMC stack uses technologies such as Yocto, OpenEmbedded, systemd, and D-Bus to allow easy customization for your server platform.

Setting up your OpenBMC project

1) Prerequisite

  • Ubuntu 14.04
sudo apt-get install -y git build-essential libsdl1.2-dev texinfo gawk chrpath diffstat
  • Fedora 28
sudo dnf install -y git patch diffstat texinfo chrpath SDL-devel bitbake \
    rpcgen perl-Thread-Queue perl-bignum perl-Crypt-OpenSSL-Bignum
sudo dnf groupinstall "C Development Tools and Libraries"

2) Download the source

git clone
cd openbmc

3) Target your hardware

Any build requires an environment variable known as TEMPLATECONF to be set to a hardware target. You can see all of the known targets with find meta-* -name local.conf.sample. Choose the hardware target and then move to the next step. Additional examples can be found in the OpenBMC Cheatsheet


As an example target Palmetto

export TEMPLATECONF=meta-ibm/meta-palmetto/conf

4) Build

. openbmc-env
bitbake obmc-phosphor-image

Additional details can be found in the docs repository.

Build Validation and Testing

Commits submitted by members of the OpenBMC GitHub community are compiled and tested via our Jenkins server. Commits are run through two levels of testing. At the repository level the makefile make check directive is run. At the system level, the commit is built into a firmware image and run with an arm-softmmu QEMU model against a barrage of CI tests.

Commits submitted by non-members do not automatically proceed through CI testing. After visual inspection of the commit, a CI run can be manually performed by the reviewer.

Automated testing against the QEMU model along with supported systems are performed. The OpenBMC project uses the Robot Framework for all automation. Our complete test repository can be found here.

Submitting Patches

Support of additional hardware and software packages is always welcome. Please follow the contributing guidelines when making a submission. It is expected that contributions contain test cases.

Bug Reporting

Issues are managed on GitHub. It is recommended you search through the issues before opening a new one.

Features of OpenBMC

Feature List

  • Host management: Power, Cooling, LEDs, Inventory, Events, Watchdog
  • Full IPMI 2.0 Compliance with DCMI
  • Code Update Support for multiple BMC/BIOS images
  • Web-based user interface
  • REST interfaces
  • D-Bus based interfaces
  • SSH based SOL
  • Remote KVM
  • Hardware Simulation
  • Automated Testing

Features In Progress

  • OpenCompute Redfish Compliance
  • User management
  • Virtual media
  • Verified Boot

Features Requested but need help

  • OpenBMC performance monitoring

Finding out more

Dive deeper into OpenBMC by opening the docs repository.