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Correct spelling problems for Documentation/s390/ as reported by codespell. Signed-off-by: Randy Dunlap <rdunlap@infradead.org> Acked-by: Heiko Carstens <hca@linux.ibm.com> Link: https://lore.kernel.org/r/20230209071400.31476-16-rdunlap@infradead.org Signed-off-by: Heiko Carstens <hca@linux.ibm.com>
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==================================
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vfio-ccw: the basic infrastructure
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==================================
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Introduction
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------------
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Here we describe the vfio support for I/O subchannel devices for
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Linux/s390. Motivation for vfio-ccw is to passthrough subchannels to a
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virtual machine, while vfio is the means.
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Different than other hardware architectures, s390 has defined a unified
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I/O access method, which is so called Channel I/O. It has its own access
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patterns:
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- Channel programs run asynchronously on a separate (co)processor.
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- The channel subsystem will access any memory designated by the caller
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in the channel program directly, i.e. there is no iommu involved.
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Thus when we introduce vfio support for these devices, we realize it
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with a mediated device (mdev) implementation. The vfio mdev will be
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added to an iommu group, so as to make itself able to be managed by the
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vfio framework. And we add read/write callbacks for special vfio I/O
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regions to pass the channel programs from the mdev to its parent device
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(the real I/O subchannel device) to do further address translation and
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to perform I/O instructions.
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This document does not intend to explain the s390 I/O architecture in
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every detail. More information/reference could be found here:
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- A good start to know Channel I/O in general:
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https://en.wikipedia.org/wiki/Channel_I/O
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- s390 architecture:
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s390 Principles of Operation manual (IBM Form. No. SA22-7832)
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- The existing QEMU code which implements a simple emulated channel
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subsystem could also be a good reference. It makes it easier to follow
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the flow.
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qemu/hw/s390x/css.c
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For vfio mediated device framework:
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- Documentation/driver-api/vfio-mediated-device.rst
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Motivation of vfio-ccw
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----------------------
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Typically, a guest virtualized via QEMU/KVM on s390 only sees
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paravirtualized virtio devices via the "Virtio Over Channel I/O
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(virtio-ccw)" transport. This makes virtio devices discoverable via
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standard operating system algorithms for handling channel devices.
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However this is not enough. On s390 for the majority of devices, which
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use the standard Channel I/O based mechanism, we also need to provide
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the functionality of passing through them to a QEMU virtual machine.
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This includes devices that don't have a virtio counterpart (e.g. tape
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drives) or that have specific characteristics which guests want to
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exploit.
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For passing a device to a guest, we want to use the same interface as
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everybody else, namely vfio. We implement this vfio support for channel
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devices via the vfio mediated device framework and the subchannel device
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driver "vfio_ccw".
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Access patterns of CCW devices
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------------------------------
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s390 architecture has implemented a so called channel subsystem, that
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provides a unified view of the devices physically attached to the
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systems. Though the s390 hardware platform knows about a huge variety of
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different peripheral attachments like disk devices (aka. DASDs), tapes,
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communication controllers, etc. They can all be accessed by a well
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defined access method and they are presenting I/O completion a unified
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way: I/O interruptions.
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All I/O requires the use of channel command words (CCWs). A CCW is an
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instruction to a specialized I/O channel processor. A channel program is
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a sequence of CCWs which are executed by the I/O channel subsystem. To
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issue a channel program to the channel subsystem, it is required to
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build an operation request block (ORB), which can be used to point out
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the format of the CCW and other control information to the system. The
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operating system signals the I/O channel subsystem to begin executing
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the channel program with a SSCH (start sub-channel) instruction. The
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central processor is then free to proceed with non-I/O instructions
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until interrupted. The I/O completion result is received by the
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interrupt handler in the form of interrupt response block (IRB).
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Back to vfio-ccw, in short:
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- ORBs and channel programs are built in guest kernel (with guest
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physical addresses).
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- ORBs and channel programs are passed to the host kernel.
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- Host kernel translates the guest physical addresses to real addresses
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and starts the I/O with issuing a privileged Channel I/O instruction
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(e.g SSCH).
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- channel programs run asynchronously on a separate processor.
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- I/O completion will be signaled to the host with I/O interruptions.
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And it will be copied as IRB to user space to pass it back to the
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guest.
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Physical vfio ccw device and its child mdev
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-------------------------------------------
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As mentioned above, we realize vfio-ccw with a mdev implementation.
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Channel I/O does not have IOMMU hardware support, so the physical
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vfio-ccw device does not have an IOMMU level translation or isolation.
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Subchannel I/O instructions are all privileged instructions. When
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handling the I/O instruction interception, vfio-ccw has the software
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policing and translation how the channel program is programmed before
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it gets sent to hardware.
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Within this implementation, we have two drivers for two types of
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devices:
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- The vfio_ccw driver for the physical subchannel device.
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This is an I/O subchannel driver for the real subchannel device. It
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realizes a group of callbacks and registers to the mdev framework as a
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parent (physical) device. As a consequence, mdev provides vfio_ccw a
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generic interface (sysfs) to create mdev devices. A vfio mdev could be
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created by vfio_ccw then and added to the mediated bus. It is the vfio
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device that added to an IOMMU group and a vfio group.
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vfio_ccw also provides an I/O region to accept channel program
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request from user space and store I/O interrupt result for user
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space to retrieve. To notify user space an I/O completion, it offers
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an interface to setup an eventfd fd for asynchronous signaling.
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- The vfio_mdev driver for the mediated vfio ccw device.
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This is provided by the mdev framework. It is a vfio device driver for
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the mdev that created by vfio_ccw.
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It realizes a group of vfio device driver callbacks, adds itself to a
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vfio group, and registers itself to the mdev framework as a mdev
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driver.
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It uses a vfio iommu backend that uses the existing map and unmap
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ioctls, but rather than programming them into an IOMMU for a device,
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it simply stores the translations for use by later requests. This
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means that a device programmed in a VM with guest physical addresses
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can have the vfio kernel convert that address to process virtual
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address, pin the page and program the hardware with the host physical
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address in one step.
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For a mdev, the vfio iommu backend will not pin the pages during the
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VFIO_IOMMU_MAP_DMA ioctl. Mdev framework will only maintain a database
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of the iova<->vaddr mappings in this operation. And they export a
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vfio_pin_pages and a vfio_unpin_pages interfaces from the vfio iommu
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backend for the physical devices to pin and unpin pages by demand.
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Below is a high Level block diagram::
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+-------------+
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| +---------+ | mdev_register_driver() +--------------+
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| | Mdev | +<-----------------------+ |
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| | bus | | | vfio_mdev.ko |
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| | driver | +----------------------->+ |<-> VFIO user
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| +---------+ | probe()/remove() +--------------+ APIs
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| MDEV CORE |
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| MODULE |
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| mdev.ko |
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| +---------+ | mdev_register_parent() +--------------+
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| |Physical | +<-----------------------+ |
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| | device | | | vfio_ccw.ko |<-> subchannel
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| |interface| +----------------------->+ | device
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| +---------+ | callback +--------------+
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+-------------+
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The process of how these work together.
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1. vfio_ccw.ko drives the physical I/O subchannel, and registers the
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physical device (with callbacks) to mdev framework.
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When vfio_ccw probing the subchannel device, it registers device
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pointer and callbacks to the mdev framework. Mdev related file nodes
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under the device node in sysfs would be created for the subchannel
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device, namely 'mdev_create', 'mdev_destroy' and
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'mdev_supported_types'.
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2. Create a mediated vfio ccw device.
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Use the 'mdev_create' sysfs file, we need to manually create one (and
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only one for our case) mediated device.
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3. vfio_mdev.ko drives the mediated ccw device.
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vfio_mdev is also the vfio device driver. It will probe the mdev and
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add it to an iommu_group and a vfio_group. Then we could pass through
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the mdev to a guest.
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VFIO-CCW Regions
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----------------
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The vfio-ccw driver exposes MMIO regions to accept requests from and return
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results to userspace.
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vfio-ccw I/O region
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-------------------
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An I/O region is used to accept channel program request from user
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space and store I/O interrupt result for user space to retrieve. The
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definition of the region is::
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struct ccw_io_region {
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#define ORB_AREA_SIZE 12
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__u8 orb_area[ORB_AREA_SIZE];
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#define SCSW_AREA_SIZE 12
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__u8 scsw_area[SCSW_AREA_SIZE];
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#define IRB_AREA_SIZE 96
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__u8 irb_area[IRB_AREA_SIZE];
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__u32 ret_code;
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} __packed;
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This region is always available.
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While starting an I/O request, orb_area should be filled with the
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guest ORB, and scsw_area should be filled with the SCSW of the Virtual
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Subchannel.
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irb_area stores the I/O result.
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ret_code stores a return code for each access of the region. The following
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values may occur:
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``0``
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The operation was successful.
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``-EOPNOTSUPP``
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The ORB specified transport mode or the
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SCSW specified a function other than the start function.
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``-EIO``
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A request was issued while the device was not in a state ready to accept
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requests, or an internal error occurred.
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``-EBUSY``
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The subchannel was status pending or busy, or a request is already active.
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``-EAGAIN``
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A request was being processed, and the caller should retry.
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``-EACCES``
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The channel path(s) used for the I/O were found to be not operational.
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``-ENODEV``
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The device was found to be not operational.
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``-EINVAL``
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The orb specified a chain longer than 255 ccws, or an internal error
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occurred.
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vfio-ccw cmd region
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-------------------
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The vfio-ccw cmd region is used to accept asynchronous instructions
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from userspace::
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#define VFIO_CCW_ASYNC_CMD_HSCH (1 << 0)
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#define VFIO_CCW_ASYNC_CMD_CSCH (1 << 1)
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struct ccw_cmd_region {
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__u32 command;
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__u32 ret_code;
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} __packed;
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This region is exposed via region type VFIO_REGION_SUBTYPE_CCW_ASYNC_CMD.
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Currently, CLEAR SUBCHANNEL and HALT SUBCHANNEL use this region.
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command specifies the command to be issued; ret_code stores a return code
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for each access of the region. The following values may occur:
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``0``
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The operation was successful.
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``-ENODEV``
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The device was found to be not operational.
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``-EINVAL``
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A command other than halt or clear was specified.
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``-EIO``
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A request was issued while the device was not in a state ready to accept
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requests.
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``-EAGAIN``
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A request was being processed, and the caller should retry.
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``-EBUSY``
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The subchannel was status pending or busy while processing a halt request.
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vfio-ccw schib region
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---------------------
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The vfio-ccw schib region is used to return Subchannel-Information
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Block (SCHIB) data to userspace::
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struct ccw_schib_region {
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#define SCHIB_AREA_SIZE 52
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__u8 schib_area[SCHIB_AREA_SIZE];
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} __packed;
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This region is exposed via region type VFIO_REGION_SUBTYPE_CCW_SCHIB.
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Reading this region triggers a STORE SUBCHANNEL to be issued to the
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associated hardware.
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vfio-ccw crw region
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---------------------
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The vfio-ccw crw region is used to return Channel Report Word (CRW)
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data to userspace::
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struct ccw_crw_region {
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__u32 crw;
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__u32 pad;
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} __packed;
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This region is exposed via region type VFIO_REGION_SUBTYPE_CCW_CRW.
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Reading this region returns a CRW if one that is relevant for this
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subchannel (e.g. one reporting changes in channel path state) is
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pending, or all zeroes if not. If multiple CRWs are pending (including
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possibly chained CRWs), reading this region again will return the next
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one, until no more CRWs are pending and zeroes are returned. This is
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similar to how STORE CHANNEL REPORT WORD works.
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vfio-ccw operation details
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--------------------------
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vfio-ccw follows what vfio-pci did on the s390 platform and uses
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vfio-iommu-type1 as the vfio iommu backend.
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* CCW translation APIs
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A group of APIs (start with `cp_`) to do CCW translation. The CCWs
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passed in by a user space program are organized with their guest
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physical memory addresses. These APIs will copy the CCWs into kernel
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space, and assemble a runnable kernel channel program by updating the
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guest physical addresses with their corresponding host physical addresses.
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Note that we have to use IDALs even for direct-access CCWs, as the
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referenced memory can be located anywhere, including above 2G.
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* vfio_ccw device driver
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This driver utilizes the CCW translation APIs and introduces
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vfio_ccw, which is the driver for the I/O subchannel devices you want
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to pass through.
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vfio_ccw implements the following vfio ioctls::
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VFIO_DEVICE_GET_INFO
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VFIO_DEVICE_GET_IRQ_INFO
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VFIO_DEVICE_GET_REGION_INFO
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VFIO_DEVICE_RESET
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VFIO_DEVICE_SET_IRQS
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This provides an I/O region, so that the user space program can pass a
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channel program to the kernel, to do further CCW translation before
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issuing them to a real device.
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This also provides the SET_IRQ ioctl to setup an event notifier to
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notify the user space program the I/O completion in an asynchronous
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way.
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The use of vfio-ccw is not limited to QEMU, while QEMU is definitely a
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good example to get understand how these patches work. Here is a little
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bit more detail how an I/O request triggered by the QEMU guest will be
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handled (without error handling).
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Explanation:
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- Q1-Q7: QEMU side process.
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- K1-K5: Kernel side process.
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Q1.
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Get I/O region info during initialization.
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Q2.
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Setup event notifier and handler to handle I/O completion.
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... ...
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Q3.
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Intercept a ssch instruction.
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Q4.
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Write the guest channel program and ORB to the I/O region.
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K1.
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Copy from guest to kernel.
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K2.
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Translate the guest channel program to a host kernel space
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channel program, which becomes runnable for a real device.
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K3.
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With the necessary information contained in the orb passed in
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by QEMU, issue the ccwchain to the device.
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K4.
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Return the ssch CC code.
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Q5.
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Return the CC code to the guest.
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... ...
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K5.
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Interrupt handler gets the I/O result and write the result to
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the I/O region.
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K6.
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Signal QEMU to retrieve the result.
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Q6.
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Get the signal and event handler reads out the result from the I/O
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region.
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Q7.
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Update the irb for the guest.
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Limitations
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-----------
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The current vfio-ccw implementation focuses on supporting basic commands
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needed to implement block device functionality (read/write) of DASD/ECKD
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device only. Some commands may need special handling in the future, for
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example, anything related to path grouping.
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DASD is a kind of storage device. While ECKD is a data recording format.
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More information for DASD and ECKD could be found here:
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https://en.wikipedia.org/wiki/Direct-access_storage_device
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https://en.wikipedia.org/wiki/Count_key_data
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Together with the corresponding work in QEMU, we can bring the passed
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through DASD/ECKD device online in a guest now and use it as a block
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device.
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The current code allows the guest to start channel programs via
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START SUBCHANNEL, and to issue HALT SUBCHANNEL, CLEAR SUBCHANNEL,
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and STORE SUBCHANNEL.
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Currently all channel programs are prefetched, regardless of the
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p-bit setting in the ORB. As a result, self modifying channel
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programs are not supported. For this reason, IPL has to be handled as
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a special case by a userspace/guest program; this has been implemented
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in QEMU's s390-ccw bios as of QEMU 4.1.
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vfio-ccw supports classic (command mode) channel I/O only. Transport
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mode (HPF) is not supported.
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QDIO subchannels are currently not supported. Classic devices other than
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DASD/ECKD might work, but have not been tested.
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Reference
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---------
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1. ESA/s390 Principles of Operation manual (IBM Form. No. SA22-7832)
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2. ESA/390 Common I/O Device Commands manual (IBM Form. No. SA22-7204)
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3. https://en.wikipedia.org/wiki/Channel_I/O
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4. Documentation/s390/cds.rst
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5. Documentation/driver-api/vfio.rst
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6. Documentation/driver-api/vfio-mediated-device.rst
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