qemu-e2k/docs/system/ppc/powernv.rst
Cédric Le Goater a4ee352fe0 docs/system: Extend PPC section
This moves the current documentation in files specific to each
platform family. PowerNV machine is updated, the other machines need
to be done.

Signed-off-by: Cédric Le Goater <clg@kaod.org>
Message-Id: <20210222133956.156001-1-clg@kaod.org>
Reviewed-by: Greg Kurz <groug@kaod.org>
[dwg: Trivial capitalization fix]
Signed-off-by: David Gibson <david@gibson.dropbear.id.au>
2021-03-10 09:07:09 +11:00

194 lines
7.0 KiB
ReStructuredText

PowerNV family boards (``powernv8``, ``powernv9``)
==================================================================
PowerNV (as Non-Virtualized) is the "baremetal" platform using the
OPAL firmware. It runs Linux on IBM and OpenPOWER systems and it can
be used as an hypervisor OS, running KVM guests, or simply as a host
OS.
The PowerNV QEMU machine tries to emulate a PowerNV system at the
level of the skiboot firmware, which loads the OS and provides some
runtime services. Power Systems have a lower firmware (HostBoot) that
does low level system initialization, like DRAM training. This is
beyond the scope of what QEMU addresses today.
Supported devices
-----------------
* Multi processor support for POWER8, POWER8NVL and POWER9.
* XSCOM, serial communication sideband bus to configure chiplets
* Simple LPC Controller
* Processor Service Interface (PSI) Controller
* Interrupt Controller, XICS (POWER8) and XIVE (POWER9)
* POWER8 PHB3 PCIe Host bridge and POWER9 PHB4 PCIe Host bridge
* Simple OCC is an on-chip microcontroller used for power management
tasks
* iBT device to handle BMC communication, with the internal BMC
simulator provided by QEMU or an external BMC such as an Aspeed
QEMU machine.
* PNOR containing the different firmware partitions.
Missing devices
---------------
A lot is missing, among which :
* POWER10 processor
* XIVE2 (POWER10) interrupt controller
* I2C controllers (yet to be merged)
* NPU/NPU2/NPU3 controllers
* EEH support for PCIe Host bridge controllers
* NX controller
* VAS controller
* chipTOD (Time Of Day)
* Self Boot Engine (SBE).
* FSI bus
Firmware
--------
The OPAL firmware (OpenPower Abstraction Layer) for OpenPower systems
includes the runtime services `skiboot` and the bootloader kernel and
initramfs `skiroot`. Source code can be found on GitHub:
https://github.com/open-power.
Prebuilt images of `skiboot` and `skiboot` are made available on the `OpenPOWER <https://openpower.xyz/job/openpower/job/openpower-op-build/>`__ site. To boot a POWER9 machine, use the `witherspoon <https://openpower.xyz/job/openpower/job/openpower-op-build/label=slave,target=witherspoon/lastSuccessfulBuild/>`__ images. For POWER8, use
the `palmetto <https://openpower.xyz/job/openpower/job/openpower-op-build/label=slave,target=palmetto/lastSuccessfulBuild/>`__ images.
QEMU includes a prebuilt image of `skiboot` which is updated when a
more recent version is required by the models.
Boot options
------------
Here is a simple setup with one e1000e NIC :
.. code-block:: bash
$ qemu-system-ppc64 -m 2G -machine powernv9 -smp 2,cores=2,threads=1 \
-accel tcg,thread=single \
-device e1000e,netdev=net0,mac=C0:FF:EE:00:00:02,bus=pcie.0,addr=0x0 \
-netdev user,id=net0,hostfwd=::20022-:22,hostname=pnv \
-kernel ./zImage.epapr \
-initrd ./rootfs.cpio.xz \
-nographic
and a SATA disk :
.. code-block:: bash
-device ich9-ahci,id=sata0,bus=pcie.1,addr=0x0 \
-drive file=./ubuntu-ppc64le.qcow2,if=none,id=drive0,format=qcow2,cache=none \
-device ide-hd,bus=sata0.0,unit=0,drive=drive0,id=ide,bootindex=1 \
Complex PCIe configuration
~~~~~~~~~~~~~~~~~~~~~~~~~~
Six PHBs are defined per chip (POWER9) but no default PCI layout is
provided (to be compatible with libvirt). One PCI device can be added
on any of the available PCIe slots using command line options such as:
.. code-block:: bash
-device e1000e,netdev=net0,mac=C0:FF:EE:00:00:02,bus=pcie.0,addr=0x0
-netdev bridge,id=net0,helper=/usr/libexec/qemu-bridge-helper,br=virbr0,id=hostnet0
-device megasas,id=scsi0,bus=pcie.0,addr=0x0
-drive file=./ubuntu-ppc64le.qcow2,if=none,id=drive-scsi0-0-0-0,format=qcow2,cache=none
-device scsi-hd,bus=scsi0.0,channel=0,scsi-id=0,lun=0,drive=drive-scsi0-0-0-0,id=scsi0-0-0-0,bootindex=2
Here is a full example with two different storage controllers on
different PHBs, each with a disk, the second PHB is empty :
.. code-block:: bash
$ qemu-system-ppc64 -m 2G -machine powernv9 -smp 2,cores=2,threads=1 -accel tcg,thread=single \
-kernel ./zImage.epapr -initrd ./rootfs.cpio.xz -bios ./skiboot.lid \
\
-device megasas,id=scsi0,bus=pcie.0,addr=0x0 \
-drive file=./rhel7-ppc64le.qcow2,if=none,id=drive-scsi0-0-0-0,format=qcow2,cache=none \
-device scsi-hd,bus=scsi0.0,channel=0,scsi-id=0,lun=0,drive=drive-scsi0-0-0-0,id=scsi0-0-0-0,bootindex=2 \
\
-device pcie-pci-bridge,id=bridge1,bus=pcie.1,addr=0x0 \
\
-device ich9-ahci,id=sata0,bus=bridge1,addr=0x1 \
-drive file=./ubuntu-ppc64le.qcow2,if=none,id=drive0,format=qcow2,cache=none \
-device ide-hd,bus=sata0.0,unit=0,drive=drive0,id=ide,bootindex=1 \
-device e1000e,netdev=net0,mac=C0:FF:EE:00:00:02,bus=bridge1,addr=0x2 \
-netdev bridge,helper=/usr/libexec/qemu-bridge-helper,br=virbr0,id=net0 \
-device nec-usb-xhci,bus=bridge1,addr=0x7 \
\
-serial mon:stdio -nographic
You can also use VIRTIO devices :
.. code-block:: bash
-drive file=./fedora-ppc64le.qcow2,if=none,snapshot=on,id=drive0 \
-device virtio-blk-pci,drive=drive0,id=blk0,bus=pcie.0 \
\
-netdev tap,helper=/usr/lib/qemu/qemu-bridge-helper,br=virbr0,id=netdev0 \
-device virtio-net-pci,netdev=netdev0,id=net0,bus=pcie.1 \
\
-fsdev local,id=fsdev0,path=$HOME,security_model=passthrough \
-device virtio-9p-pci,fsdev=fsdev0,mount_tag=host,bus=pcie.2
Multi sockets
~~~~~~~~~~~~~
The number of sockets is deduced from the number of CPUs and the
number of cores. ``-smp 2,cores=1`` will define a machine with 2
sockets of 1 core, whereas ``-smp 2,cores=2`` will define a machine
with 1 socket of 2 cores. ``-smp 8,cores=2``, 4 sockets of 2 cores.
BMC configuration
~~~~~~~~~~~~~~~~~
OpenPOWER systems negotiate the shutdown and reboot with their
BMC. The QEMU PowerNV machine embeds an IPMI BMC simulator using the
iBT interface and should offer the same power features.
If you want to define your own BMC, use ``-nodefaults`` and specify
one on the command line :
.. code-block:: bash
-device ipmi-bmc-sim,id=bmc0 -device isa-ipmi-bt,bmc=bmc0,irq=10
The files `palmetto-SDR.bin <http://www.kaod.org/qemu/powernv/palmetto-SDR.bin>`__
and `palmetto-FRU.bin <http://www.kaod.org/qemu/powernv/palmetto-FRU.bin>`__
define a Sensor Data Record repository and a Field Replaceable Unit
inventory for a palmetto BMC. They can be used to extend the QEMU BMC
simulator.
.. code-block:: bash
-device ipmi-bmc-sim,sdrfile=./palmetto-SDR.bin,fruareasize=256,frudatafile=./palmetto-FRU.bin,id=bmc0 \
-device isa-ipmi-bt,bmc=bmc0,irq=10
The PowerNV machine can also be run with an external IPMI BMC device
connected to a remote QEMU machine acting as BMC, using these options
:
.. code-block:: bash
-chardev socket,id=ipmi0,host=localhost,port=9002,reconnect=10 \
-device ipmi-bmc-extern,id=bmc0,chardev=ipmi0 \
-device isa-ipmi-bt,bmc=bmc0,irq=10 \
-nodefaults
NVRAM
~~~~~
Use a MTD drive to add a PNOR to the machine, and get a NVRAM :
.. code-block:: bash
-drive file=./witherspoon.pnor,format=raw,if=mtd
CAVEATS
-------
* No support for multiple HW threads (SMT=1). Same as pseries.
* CPU can hang when doing intensive I/Os. Use ``-append powersave=off`` in that case.