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authorLinus Torvalds <torvalds@linux-foundation.org>2018-10-25 17:57:35 -0700
committerLinus Torvalds <torvalds@linux-foundation.org>2018-10-25 17:57:35 -0700
commit0d1e8b8d2bcd3150d51754d8d0fdbf44dc88b0d3 (patch)
tree2794cb2347daa76b00160a6ffb68663f4138dcc7 /Documentation
parent83c4087ce468601501ecde4d0ec5b2abd5f57c31 (diff)
parent22a7cdcae6a4a3c8974899e62851d270956f58ce (diff)
downloadlinux-0d1e8b8d2bcd3150d51754d8d0fdbf44dc88b0d3.tar.bz2
Merge tag 'kvm-4.20-1' of git://git.kernel.org/pub/scm/virt/kvm/kvm
Pull KVM updates from Radim Krčmář: "ARM: - Improved guest IPA space support (32 to 52 bits) - RAS event delivery for 32bit - PMU fixes - Guest entry hardening - Various cleanups - Port of dirty_log_test selftest PPC: - Nested HV KVM support for radix guests on POWER9. The performance is much better than with PR KVM. Migration and arbitrary level of nesting is supported. - Disable nested HV-KVM on early POWER9 chips that need a particular hardware bug workaround - One VM per core mode to prevent potential data leaks - PCI pass-through optimization - merge ppc-kvm topic branch and kvm-ppc-fixes to get a better base s390: - Initial version of AP crypto virtualization via vfio-mdev - Improvement for vfio-ap - Set the host program identifier - Optimize page table locking x86: - Enable nested virtualization by default - Implement Hyper-V IPI hypercalls - Improve #PF and #DB handling - Allow guests to use Enlightened VMCS - Add migration selftests for VMCS and Enlightened VMCS - Allow coalesced PIO accesses - Add an option to perform nested VMCS host state consistency check through hardware - Automatic tuning of lapic_timer_advance_ns - Many fixes, minor improvements, and cleanups" * tag 'kvm-4.20-1' of git://git.kernel.org/pub/scm/virt/kvm/kvm: (204 commits) KVM/nVMX: Do not validate that posted_intr_desc_addr is page aligned Revert "kvm: x86: optimize dr6 restore" KVM: PPC: Optimize clearing TCEs for sparse tables x86/kvm/nVMX: tweak shadow fields selftests/kvm: add missing executables to .gitignore KVM: arm64: Safety check PSTATE when entering guest and handle IL KVM: PPC: Book3S HV: Don't use streamlined entry path on early POWER9 chips arm/arm64: KVM: Enable 32 bits kvm vcpu events support arm/arm64: KVM: Rename function kvm_arch_dev_ioctl_check_extension() KVM: arm64: Fix caching of host MDCR_EL2 value KVM: VMX: enable nested virtualization by default KVM/x86: Use 32bit xor to clear registers in svm.c kvm: x86: Introduce KVM_CAP_EXCEPTION_PAYLOAD kvm: vmx: Defer setting of DR6 until #DB delivery kvm: x86: Defer setting of CR2 until #PF delivery kvm: x86: Add payload operands to kvm_multiple_exception kvm: x86: Add exception payload fields to kvm_vcpu_events kvm: x86: Add has_payload and payload to kvm_queued_exception KVM: Documentation: Fix omission in struct kvm_vcpu_events KVM: selftests: add Enlightened VMCS test ...
Diffstat (limited to 'Documentation')
-rw-r--r--Documentation/s390/vfio-ap.txt837
-rw-r--r--Documentation/virtual/kvm/api.txt135
2 files changed, 966 insertions, 6 deletions
diff --git a/Documentation/s390/vfio-ap.txt b/Documentation/s390/vfio-ap.txt
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+Introduction:
+============
+The Adjunct Processor (AP) facility is an IBM Z cryptographic facility comprised
+of three AP instructions and from 1 up to 256 PCIe cryptographic adapter cards.
+The AP devices provide cryptographic functions to all CPUs assigned to a
+linux system running in an IBM Z system LPAR.
+
+The AP adapter cards are exposed via the AP bus. The motivation for vfio-ap
+is to make AP cards available to KVM guests using the VFIO mediated device
+framework. This implementation relies considerably on the s390 virtualization
+facilities which do most of the hard work of providing direct access to AP
+devices.
+
+AP Architectural Overview:
+=========================
+To facilitate the comprehension of the design, let's start with some
+definitions:
+
+* AP adapter
+
+ An AP adapter is an IBM Z adapter card that can perform cryptographic
+ functions. There can be from 0 to 256 adapters assigned to an LPAR. Adapters
+ assigned to the LPAR in which a linux host is running will be available to
+ the linux host. Each adapter is identified by a number from 0 to 255; however,
+ the maximum adapter number is determined by machine model and/or adapter type.
+ When installed, an AP adapter is accessed by AP instructions executed by any
+ CPU.
+
+ The AP adapter cards are assigned to a given LPAR via the system's Activation
+ Profile which can be edited via the HMC. When the linux host system is IPL'd
+ in the LPAR, the AP bus detects the AP adapter cards assigned to the LPAR and
+ creates a sysfs device for each assigned adapter. For example, if AP adapters
+ 4 and 10 (0x0a) are assigned to the LPAR, the AP bus will create the following
+ sysfs device entries:
+
+ /sys/devices/ap/card04
+ /sys/devices/ap/card0a
+
+ Symbolic links to these devices will also be created in the AP bus devices
+ sub-directory:
+
+ /sys/bus/ap/devices/[card04]
+ /sys/bus/ap/devices/[card04]
+
+* AP domain
+
+ An adapter is partitioned into domains. An adapter can hold up to 256 domains
+ depending upon the adapter type and hardware configuration. A domain is
+ identified by a number from 0 to 255; however, the maximum domain number is
+ determined by machine model and/or adapter type.. A domain can be thought of
+ as a set of hardware registers and memory used for processing AP commands. A
+ domain can be configured with a secure private key used for clear key
+ encryption. A domain is classified in one of two ways depending upon how it
+ may be accessed:
+
+ * Usage domains are domains that are targeted by an AP instruction to
+ process an AP command.
+
+ * Control domains are domains that are changed by an AP command sent to a
+ usage domain; for example, to set the secure private key for the control
+ domain.
+
+ The AP usage and control domains are assigned to a given LPAR via the system's
+ Activation Profile which can be edited via the HMC. When a linux host system
+ is IPL'd in the LPAR, the AP bus module detects the AP usage and control
+ domains assigned to the LPAR. The domain number of each usage domain and
+ adapter number of each AP adapter are combined to create AP queue devices
+ (see AP Queue section below). The domain number of each control domain will be
+ represented in a bitmask and stored in a sysfs file
+ /sys/bus/ap/ap_control_domain_mask. The bits in the mask, from most to least
+ significant bit, correspond to domains 0-255.
+
+* AP Queue
+
+ An AP queue is the means by which an AP command is sent to a usage domain
+ inside a specific adapter. An AP queue is identified by a tuple
+ comprised of an AP adapter ID (APID) and an AP queue index (APQI). The
+ APQI corresponds to a given usage domain number within the adapter. This tuple
+ forms an AP Queue Number (APQN) uniquely identifying an AP queue. AP
+ instructions include a field containing the APQN to identify the AP queue to
+ which the AP command is to be sent for processing.
+
+ The AP bus will create a sysfs device for each APQN that can be derived from
+ the cross product of the AP adapter and usage domain numbers detected when the
+ AP bus module is loaded. For example, if adapters 4 and 10 (0x0a) and usage
+ domains 6 and 71 (0x47) are assigned to the LPAR, the AP bus will create the
+ following sysfs entries:
+
+ /sys/devices/ap/card04/04.0006
+ /sys/devices/ap/card04/04.0047
+ /sys/devices/ap/card0a/0a.0006
+ /sys/devices/ap/card0a/0a.0047
+
+ The following symbolic links to these devices will be created in the AP bus
+ devices subdirectory:
+
+ /sys/bus/ap/devices/[04.0006]
+ /sys/bus/ap/devices/[04.0047]
+ /sys/bus/ap/devices/[0a.0006]
+ /sys/bus/ap/devices/[0a.0047]
+
+* AP Instructions:
+
+ There are three AP instructions:
+
+ * NQAP: to enqueue an AP command-request message to a queue
+ * DQAP: to dequeue an AP command-reply message from a queue
+ * PQAP: to administer the queues
+
+ AP instructions identify the domain that is targeted to process the AP
+ command; this must be one of the usage domains. An AP command may modify a
+ domain that is not one of the usage domains, but the modified domain
+ must be one of the control domains.
+
+AP and SIE:
+==========
+Let's now take a look at how AP instructions executed on a guest are interpreted
+by the hardware.
+
+A satellite control block called the Crypto Control Block (CRYCB) is attached to
+our main hardware virtualization control block. The CRYCB contains three fields
+to identify the adapters, usage domains and control domains assigned to the KVM
+guest:
+
+* The AP Mask (APM) field is a bit mask that identifies the AP adapters assigned
+ to the KVM guest. Each bit in the mask, from left to right (i.e. from most
+ significant to least significant bit in big endian order), corresponds to
+ an APID from 0-255. If a bit is set, the corresponding adapter is valid for
+ use by the KVM guest.
+
+* The AP Queue Mask (AQM) field is a bit mask identifying the AP usage domains
+ assigned to the KVM guest. Each bit in the mask, from left to right (i.e. from
+ most significant to least significant bit in big endian order), corresponds to
+ an AP queue index (APQI) from 0-255. If a bit is set, the corresponding queue
+ is valid for use by the KVM guest.
+
+* The AP Domain Mask field is a bit mask that identifies the AP control domains
+ assigned to the KVM guest. The ADM bit mask controls which domains can be
+ changed by an AP command-request message sent to a usage domain from the
+ guest. Each bit in the mask, from left to right (i.e. from most significant to
+ least significant bit in big endian order), corresponds to a domain from
+ 0-255. If a bit is set, the corresponding domain can be modified by an AP
+ command-request message sent to a usage domain.
+
+If you recall from the description of an AP Queue, AP instructions include
+an APQN to identify the AP queue to which an AP command-request message is to be
+sent (NQAP and PQAP instructions), or from which a command-reply message is to
+be received (DQAP instruction). The validity of an APQN is defined by the matrix
+calculated from the APM and AQM; it is the cross product of all assigned adapter
+numbers (APM) with all assigned queue indexes (AQM). For example, if adapters 1
+and 2 and usage domains 5 and 6 are assigned to a guest, the APQNs (1,5), (1,6),
+(2,5) and (2,6) will be valid for the guest.
+
+The APQNs can provide secure key functionality - i.e., a private key is stored
+on the adapter card for each of its domains - so each APQN must be assigned to
+at most one guest or to the linux host.
+
+ Example 1: Valid configuration:
+ ------------------------------
+ Guest1: adapters 1,2 domains 5,6
+ Guest2: adapter 1,2 domain 7
+
+ This is valid because both guests have a unique set of APQNs:
+ Guest1 has APQNs (1,5), (1,6), (2,5), (2,6);
+ Guest2 has APQNs (1,7), (2,7)
+
+ Example 2: Valid configuration:
+ ------------------------------
+ Guest1: adapters 1,2 domains 5,6
+ Guest2: adapters 3,4 domains 5,6
+
+ This is also valid because both guests have a unique set of APQNs:
+ Guest1 has APQNs (1,5), (1,6), (2,5), (2,6);
+ Guest2 has APQNs (3,5), (3,6), (4,5), (4,6)
+
+ Example 3: Invalid configuration:
+ --------------------------------
+ Guest1: adapters 1,2 domains 5,6
+ Guest2: adapter 1 domains 6,7
+
+ This is an invalid configuration because both guests have access to
+ APQN (1,6).
+
+The Design:
+===========
+The design introduces three new objects:
+
+1. AP matrix device
+2. VFIO AP device driver (vfio_ap.ko)
+3. VFIO AP mediated matrix pass-through device
+
+The VFIO AP device driver
+-------------------------
+The VFIO AP (vfio_ap) device driver serves the following purposes:
+
+1. Provides the interfaces to secure APQNs for exclusive use of KVM guests.
+
+2. Sets up the VFIO mediated device interfaces to manage a mediated matrix
+ device and creates the sysfs interfaces for assigning adapters, usage
+ domains, and control domains comprising the matrix for a KVM guest.
+
+3. Configures the APM, AQM and ADM in the CRYCB referenced by a KVM guest's
+ SIE state description to grant the guest access to a matrix of AP devices
+
+Reserve APQNs for exclusive use of KVM guests
+---------------------------------------------
+The following block diagram illustrates the mechanism by which APQNs are
+reserved:
+
+ +------------------+
+ 7 remove | |
+ +--------------------> cex4queue driver |
+ | | |
+ | +------------------+
+ |
+ |
+ | +------------------+ +-----------------+
+ | 5 register driver | | 3 create | |
+ | +----------------> Device core +----------> matrix device |
+ | | | | | |
+ | | +--------^---------+ +-----------------+
+ | | |
+ | | +-------------------+
+ | | +-----------------------------------+ |
+ | | | 4 register AP driver | | 2 register device
+ | | | | |
++--------+---+-v---+ +--------+-------+-+
+| | | |
+| ap_bus +--------------------- > vfio_ap driver |
+| | 8 probe | |
++--------^---------+ +--^--^------------+
+6 edit | | |
+ apmask | +-----------------------------+ | 9 mdev create
+ aqmask | | 1 modprobe |
++--------+-----+---+ +----------------+-+ +------------------+
+| | | |8 create | mediated |
+| admin | | VFIO device core |---------> matrix |
+| + | | | device |
++------+-+---------+ +--------^---------+ +--------^---------+
+ | | | |
+ | | 9 create vfio_ap-passthrough | |
+ | +------------------------------+ |
+ +-------------------------------------------------------------+
+ 10 assign adapter/domain/control domain
+
+The process for reserving an AP queue for use by a KVM guest is:
+
+1. The administrator loads the vfio_ap device driver
+2. The vfio-ap driver during its initialization will register a single 'matrix'
+ device with the device core. This will serve as the parent device for
+ all mediated matrix devices used to configure an AP matrix for a guest.
+3. The /sys/devices/vfio_ap/matrix device is created by the device core
+4 The vfio_ap device driver will register with the AP bus for AP queue devices
+ of type 10 and higher (CEX4 and newer). The driver will provide the vfio_ap
+ driver's probe and remove callback interfaces. Devices older than CEX4 queues
+ are not supported to simplify the implementation by not needlessly
+ complicating the design by supporting older devices that will go out of
+ service in the relatively near future, and for which there are few older
+ systems around on which to test.
+5. The AP bus registers the vfio_ap device driver with the device core
+6. The administrator edits the AP adapter and queue masks to reserve AP queues
+ for use by the vfio_ap device driver.
+7. The AP bus removes the AP queues reserved for the vfio_ap driver from the
+ default zcrypt cex4queue driver.
+8. The AP bus probes the vfio_ap device driver to bind the queues reserved for
+ it.
+9. The administrator creates a passthrough type mediated matrix device to be
+ used by a guest
+10 The administrator assigns the adapters, usage domains and control domains
+ to be exclusively used by a guest.
+
+Set up the VFIO mediated device interfaces
+------------------------------------------
+The VFIO AP device driver utilizes the common interface of the VFIO mediated
+device core driver to:
+* Register an AP mediated bus driver to add a mediated matrix device to and
+ remove it from a VFIO group.
+* Create and destroy a mediated matrix device
+* Add a mediated matrix device to and remove it from the AP mediated bus driver
+* Add a mediated matrix device to and remove it from an IOMMU group
+
+The following high-level block diagram shows the main components and interfaces
+of the VFIO AP mediated matrix device driver:
+
+ +-------------+
+ | |
+ | +---------+ | mdev_register_driver() +--------------+
+ | | Mdev | +<-----------------------+ |
+ | | bus | | | vfio_mdev.ko |
+ | | driver | +----------------------->+ |<-> VFIO user
+ | +---------+ | probe()/remove() +--------------+ APIs
+ | |
+ | MDEV CORE |
+ | MODULE |
+ | mdev.ko |
+ | +---------+ | mdev_register_device() +--------------+
+ | |Physical | +<-----------------------+ |
+ | | device | | | vfio_ap.ko |<-> matrix
+ | |interface| +----------------------->+ | device
+ | +---------+ | callback +--------------+
+ +-------------+
+
+During initialization of the vfio_ap module, the matrix device is registered
+with an 'mdev_parent_ops' structure that provides the sysfs attribute
+structures, mdev functions and callback interfaces for managing the mediated
+matrix device.
+
+* sysfs attribute structures:
+ * supported_type_groups
+ The VFIO mediated device framework supports creation of user-defined
+ mediated device types. These mediated device types are specified
+ via the 'supported_type_groups' structure when a device is registered
+ with the mediated device framework. The registration process creates the
+ sysfs structures for each mediated device type specified in the
+ 'mdev_supported_types' sub-directory of the device being registered. Along
+ with the device type, the sysfs attributes of the mediated device type are
+ provided.
+
+ The VFIO AP device driver will register one mediated device type for
+ passthrough devices:
+ /sys/devices/vfio_ap/matrix/mdev_supported_types/vfio_ap-passthrough
+ Only the read-only attributes required by the VFIO mdev framework will
+ be provided:
+ ... name
+ ... device_api
+ ... available_instances
+ ... device_api
+ Where:
+ * name: specifies the name of the mediated device type
+ * device_api: the mediated device type's API
+ * available_instances: the number of mediated matrix passthrough devices
+ that can be created
+ * device_api: specifies the VFIO API
+ * mdev_attr_groups
+ This attribute group identifies the user-defined sysfs attributes of the
+ mediated device. When a device is registered with the VFIO mediated device
+ framework, the sysfs attribute files identified in the 'mdev_attr_groups'
+ structure will be created in the mediated matrix device's directory. The
+ sysfs attributes for a mediated matrix device are:
+ * assign_adapter:
+ * unassign_adapter:
+ Write-only attributes for assigning/unassigning an AP adapter to/from the
+ mediated matrix device. To assign/unassign an adapter, the APID of the
+ adapter is echoed to the respective attribute file.
+ * assign_domain:
+ * unassign_domain:
+ Write-only attributes for assigning/unassigning an AP usage domain to/from
+ the mediated matrix device. To assign/unassign a domain, the domain
+ number of the the usage domain is echoed to the respective attribute
+ file.
+ * matrix:
+ A read-only file for displaying the APQNs derived from the cross product
+ of the adapter and domain numbers assigned to the mediated matrix device.
+ * assign_control_domain:
+ * unassign_control_domain:
+ Write-only attributes for assigning/unassigning an AP control domain
+ to/from the mediated matrix device. To assign/unassign a control domain,
+ the ID of the domain to be assigned/unassigned is echoed to the respective
+ attribute file.
+ * control_domains:
+ A read-only file for displaying the control domain numbers assigned to the
+ mediated matrix device.
+
+* functions:
+ * create:
+ allocates the ap_matrix_mdev structure used by the vfio_ap driver to:
+ * Store the reference to the KVM structure for the guest using the mdev
+ * Store the AP matrix configuration for the adapters, domains, and control
+ domains assigned via the corresponding sysfs attributes files
+ * remove:
+ deallocates the mediated matrix device's ap_matrix_mdev structure. This will
+ be allowed only if a running guest is not using the mdev.
+
+* callback interfaces
+ * open:
+ The vfio_ap driver uses this callback to register a
+ VFIO_GROUP_NOTIFY_SET_KVM notifier callback function for the mdev matrix
+ device. The open is invoked when QEMU connects the VFIO iommu group
+ for the mdev matrix device to the MDEV bus. Access to the KVM structure used
+ to configure the KVM guest is provided via this callback. The KVM structure,
+ is used to configure the guest's access to the AP matrix defined via the
+ mediated matrix device's sysfs attribute files.
+ * release:
+ unregisters the VFIO_GROUP_NOTIFY_SET_KVM notifier callback function for the
+ mdev matrix device and deconfigures the guest's AP matrix.
+
+Configure the APM, AQM and ADM in the CRYCB:
+-------------------------------------------
+Configuring the AP matrix for a KVM guest will be performed when the
+VFIO_GROUP_NOTIFY_SET_KVM notifier callback is invoked. The notifier
+function is called when QEMU connects to KVM. The guest's AP matrix is
+configured via it's CRYCB by:
+* Setting the bits in the APM corresponding to the APIDs assigned to the
+ mediated matrix device via its 'assign_adapter' interface.
+* Setting the bits in the AQM corresponding to the domains assigned to the
+ mediated matrix device via its 'assign_domain' interface.
+* Setting the bits in the ADM corresponding to the domain dIDs assigned to the
+ mediated matrix device via its 'assign_control_domains' interface.
+
+The CPU model features for AP
+-----------------------------
+The AP stack relies on the presence of the AP instructions as well as two
+facilities: The AP Facilities Test (APFT) facility; and the AP Query
+Configuration Information (QCI) facility. These features/facilities are made
+available to a KVM guest via the following CPU model features:
+
+1. ap: Indicates whether the AP instructions are installed on the guest. This
+ feature will be enabled by KVM only if the AP instructions are installed
+ on the host.
+
+2. apft: Indicates the APFT facility is available on the guest. This facility
+ can be made available to the guest only if it is available on the host (i.e.,
+ facility bit 15 is set).
+
+3. apqci: Indicates the AP QCI facility is available on the guest. This facility
+ can be made available to the guest only if it is available on the host (i.e.,
+ facility bit 12 is set).
+
+Note: If the user chooses to specify a CPU model different than the 'host'
+model to QEMU, the CPU model features and facilities need to be turned on
+explicitly; for example:
+
+ /usr/bin/qemu-system-s390x ... -cpu z13,ap=on,apqci=on,apft=on
+
+A guest can be precluded from using AP features/facilities by turning them off
+explicitly; for example:
+
+ /usr/bin/qemu-system-s390x ... -cpu host,ap=off,apqci=off,apft=off
+
+Note: If the APFT facility is turned off (apft=off) for the guest, the guest
+will not see any AP devices. The zcrypt device drivers that register for type 10
+and newer AP devices - i.e., the cex4card and cex4queue device drivers - need
+the APFT facility to ascertain the facilities installed on a given AP device. If
+the APFT facility is not installed on the guest, then the probe of device
+drivers will fail since only type 10 and newer devices can be configured for
+guest use.
+
+Example:
+=======
+Let's now provide an example to illustrate how KVM guests may be given
+access to AP facilities. For this example, we will show how to configure
+three guests such that executing the lszcrypt command on the guests would
+look like this:
+
+Guest1
+------
+CARD.DOMAIN TYPE MODE
+------------------------------
+05 CEX5C CCA-Coproc
+05.0004 CEX5C CCA-Coproc
+05.00ab CEX5C CCA-Coproc
+06 CEX5A Accelerator
+06.0004 CEX5A Accelerator
+06.00ab CEX5C CCA-Coproc
+
+Guest2
+------
+CARD.DOMAIN TYPE MODE
+------------------------------
+05 CEX5A Accelerator
+05.0047 CEX5A Accelerator
+05.00ff CEX5A Accelerator
+
+Guest2
+------
+CARD.DOMAIN TYPE MODE
+------------------------------
+06 CEX5A Accelerator
+06.0047 CEX5A Accelerator
+06.00ff CEX5A Accelerator
+
+These are the steps:
+
+1. Install the vfio_ap module on the linux host. The dependency chain for the
+ vfio_ap module is:
+ * iommu
+ * s390
+ * zcrypt
+ * vfio
+ * vfio_mdev
+ * vfio_mdev_device
+ * KVM
+
+ To build the vfio_ap module, the kernel build must be configured with the
+ following Kconfig elements selected:
+ * IOMMU_SUPPORT
+ * S390
+ * ZCRYPT
+ * S390_AP_IOMMU
+ * VFIO
+ * VFIO_MDEV
+ * VFIO_MDEV_DEVICE
+ * KVM
+
+ If using make menuconfig select the following to build the vfio_ap module:
+ -> Device Drivers
+ -> IOMMU Hardware Support
+ select S390 AP IOMMU Support
+ -> VFIO Non-Privileged userspace driver framework
+ -> Mediated device driver frramework
+ -> VFIO driver for Mediated devices
+ -> I/O subsystem
+ -> VFIO support for AP devices
+
+2. Secure the AP queues to be used by the three guests so that the host can not
+ access them. To secure them, there are two sysfs files that specify
+ bitmasks marking a subset of the APQN range as 'usable by the default AP
+ queue device drivers' or 'not usable by the default device drivers' and thus
+ available for use by the vfio_ap device driver'. The location of the sysfs
+ files containing the masks are:
+
+ /sys/bus/ap/apmask
+ /sys/bus/ap/aqmask
+
+ The 'apmask' is a 256-bit mask that identifies a set of AP adapter IDs
+ (APID). Each bit in the mask, from left to right (i.e., from most significant
+ to least significant bit in big endian order), corresponds to an APID from
+ 0-255. If a bit is set, the APID is marked as usable only by the default AP
+ queue device drivers; otherwise, the APID is usable by the vfio_ap
+ device driver.
+
+ The 'aqmask' is a 256-bit mask that identifies a set of AP queue indexes
+ (APQI). Each bit in the mask, from left to right (i.e., from most significant
+ to least significant bit in big endian order), corresponds to an APQI from
+ 0-255. If a bit is set, the APQI is marked as usable only by the default AP
+ queue device drivers; otherwise, the APQI is usable by the vfio_ap device
+ driver.
+
+ Take, for example, the following mask:
+
+ 0x7dffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffff
+
+ It indicates:
+
+ 1, 2, 3, 4, 5, and 7-255 belong to the default drivers' pool, and 0 and 6
+ belong to the vfio_ap device driver's pool.
+
+ The APQN of each AP queue device assigned to the linux host is checked by the
+ AP bus against the set of APQNs derived from the cross product of APIDs
+ and APQIs marked as usable only by the default AP queue device drivers. If a
+ match is detected, only the default AP queue device drivers will be probed;
+ otherwise, the vfio_ap device driver will be probed.
+
+ By default, the two masks are set to reserve all APQNs for use by the default
+ AP queue device drivers. There are two ways the default masks can be changed:
+
+ 1. The sysfs mask files can be edited by echoing a string into the
+ respective sysfs mask file in one of two formats:
+
+ * An absolute hex string starting with 0x - like "0x12345678" - sets
+ the mask. If the given string is shorter than the mask, it is padded
+ with 0s on the right; for example, specifying a mask value of 0x41 is
+ the same as specifying:
+
+ 0x4100000000000000000000000000000000000000000000000000000000000000
+
+ Keep in mind that the mask reads from left to right (i.e., most
+ significant to least significant bit in big endian order), so the mask
+ above identifies device numbers 1 and 7 (01000001).
+
+ If the string is longer than the mask, the operation is terminated with
+ an error (EINVAL).
+
+ * Individual bits in the mask can be switched on and off by specifying
+ each bit number to be switched in a comma separated list. Each bit
+ number string must be prepended with a ('+') or minus ('-') to indicate
+ the corresponding bit is to be switched on ('+') or off ('-'). Some
+ valid values are:
+
+ "+0" switches bit 0 on
+ "-13" switches bit 13 off
+ "+0x41" switches bit 65 on
+ "-0xff" switches bit 255 off
+
+ The following example:
+ +0,-6,+0x47,-0xf0
+
+ Switches bits 0 and 71 (0x47) on
+ Switches bits 6 and 240 (0xf0) off
+
+ Note that the bits not specified in the list remain as they were before
+ the operation.
+
+ 2. The masks can also be changed at boot time via parameters on the kernel
+ command line like this:
+
+ ap.apmask=0xffff ap.aqmask=0x40
+
+ This would create the following masks:
+
+ apmask:
+ 0xffff000000000000000000000000000000000000000000000000000000000000
+
+ aqmask:
+ 0x4000000000000000000000000000000000000000000000000000000000000000
+
+ Resulting in these two pools:
+
+ default drivers pool: adapter 0-15, domain 1
+ alternate drivers pool: adapter 16-255, domains 0, 2-255
+
+ Securing the APQNs for our example:
+ ----------------------------------
+ To secure the AP queues 05.0004, 05.0047, 05.00ab, 05.00ff, 06.0004, 06.0047,
+ 06.00ab, and 06.00ff for use by the vfio_ap device driver, the corresponding
+ APQNs can either be removed from the default masks:
+
+ echo -5,-6 > /sys/bus/ap/apmask
+
+ echo -4,-0x47,-0xab,-0xff > /sys/bus/ap/aqmask
+
+ Or the masks can be set as follows:
+
+ echo 0xf9ffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffff \
+ > apmask
+
+ echo 0xf7fffffffffffffffeffffffffffffffffffffffffeffffffffffffffffffffe \
+ > aqmask
+
+ This will result in AP queues 05.0004, 05.0047, 05.00ab, 05.00ff, 06.0004,
+ 06.0047, 06.00ab, and 06.00ff getting bound to the vfio_ap device driver. The
+ sysfs directory for the vfio_ap device driver will now contain symbolic links
+ to the AP queue devices bound to it:
+
+ /sys/bus/ap
+ ... [drivers]
+ ...... [vfio_ap]
+ ......... [05.0004]
+ ......... [05.0047]
+ ......... [05.00ab]
+ ......... [05.00ff]
+ ......... [06.0004]
+ ......... [06.0047]
+ ......... [06.00ab]
+ ......... [06.00ff]
+
+ Keep in mind that only type 10 and newer adapters (i.e., CEX4 and later)
+ can be bound to the vfio_ap device driver. The reason for this is to
+ simplify the implementation by not needlessly complicating the design by
+ supporting older devices that will go out of service in the relatively near
+ future and for which there are few older systems on which to test.
+
+ The administrator, therefore, must take care to secure only AP queues that
+ can be bound to the vfio_ap device driver. The device type for a given AP
+ queue device can be read from the parent card's sysfs directory. For example,
+ to see the hardware type of the queue 05.0004:
+
+ cat /sys/bus/ap/devices/card05/hwtype
+
+ The hwtype must be 10 or higher (CEX4 or newer) in order to be bound to the
+ vfio_ap device driver.
+
+3. Create the mediated devices needed to configure the AP matrixes for the
+ three guests and to provide an interface to the vfio_ap driver for
+ use by the guests:
+
+ /sys/devices/vfio_ap/matrix/
+ --- [mdev_supported_types]
+ ------ [vfio_ap-passthrough] (passthrough mediated matrix device type)
+ --------- create
+ --------- [devices]
+
+ To create the mediated devices for the three guests:
+
+ uuidgen > create
+ uuidgen > create
+ uuidgen > create
+
+ or
+
+ echo $uuid1 > create
+ echo $uuid2 > create
+ echo $uuid3 > create
+
+ This will create three mediated devices in the [devices] subdirectory named
+ after the UUID written to the create attribute file. We call them $uuid1,
+ $uuid2 and $uuid3 and this is the sysfs directory structure after creation:
+
+ /sys/devices/vfio_ap/matrix/
+ --- [mdev_supported_types]
+ ------ [vfio_ap-passthrough]
+ --------- [devices]
+ ------------ [$uuid1]
+ --------------- assign_adapter
+ --------------- assign_control_domain
+ --------------- assign_domain
+ --------------- matrix
+ --------------- unassign_adapter
+ --------------- unassign_control_domain
+ --------------- unassign_domain
+
+ ------------ [$uuid2]
+ --------------- assign_adapter
+ --------------- assign_control_domain
+ --------------- assign_domain
+ --------------- matrix
+ --------------- unassign_adapter
+ ----------------unassign_control_domain
+ ----------------unassign_domain
+
+ ------------ [$uuid3]
+ --------------- assign_adapter
+ --------------- assign_control_domain
+ --------------- assign_domain
+ --------------- matrix
+ --------------- unassign_adapter
+ ----------------unassign_control_domain
+ ----------------unassign_domain
+
+4. The administrator now needs to configure the matrixes for the mediated
+ devices $uuid1 (for Guest1), $uuid2 (for Guest2) and $uuid3 (for Guest3).
+
+ This is how the matrix is configured for Guest1:
+
+ echo 5 > assign_adapter
+ echo 6 > assign_adapter
+ echo 4 > assign_domain
+ echo 0xab > assign_domain
+
+ Control domains can similarly be assigned using the assign_control_domain
+ sysfs file.
+
+ If a mistake is made configuring an adapter, domain or control domain,
+ you can use the unassign_xxx files to unassign the adapter, domain or
+ control domain.
+
+ To display the matrix configuration for Guest1:
+
+ cat matrix
+
+ This is how the matrix is configured for Guest2:
+
+ echo 5 > assign_adapter
+ echo 0x47 > assign_domain
+ echo 0xff > assign_domain
+
+ This is how the matrix is configured for Guest3:
+
+ echo 6 > assign_adapter
+ echo 0x47 > assign_domain
+ echo 0xff > assign_domain
+
+ In order to successfully assign an adapter:
+
+ * The adapter number specified must represent a value from 0 up to the
+ maximum adapter number configured for the system. If an adapter number
+ higher than the maximum is specified, the operation will terminate with
+ an error (ENODEV).
+
+ * All APQNs that can be derived from the adapter ID and the IDs of
+ the previously assigned domains must be bound to the vfio_ap device
+ driver. If no domains have yet been assigned, then there must be at least
+ one APQN with the specified APID bound to the vfio_ap driver. If no such
+ APQNs are bound to the driver, the operation will terminate with an
+ error (EADDRNOTAVAIL).
+
+ No APQN that can be derived from the adapter ID and the IDs of the
+ previously assigned domains can be assigned to another mediated matrix
+ device. If an APQN is assigned to another mediated matrix device, the
+ operation will terminate with an error (EADDRINUSE).
+
+ In order to successfully assign a domain:
+
+ * The domain number specified must represent a value from 0 up to the
+ maximum domain number configured for the system. If a domain number
+ higher than the maximum is specified, the operation will terminate with
+ an error (ENODEV).
+
+ * All APQNs that can be derived from the domain ID and the IDs of
+ the previously assigned adapters must be bound to the vfio_ap device
+ driver. If no domains have yet been assigned, then there must be at least
+ one APQN with the specified APQI bound to the vfio_ap driver. If no such
+ APQNs are bound to the driver, the operation will terminate with an
+ error (EADDRNOTAVAIL).
+
+ No APQN that can be derived from the domain ID and the IDs of the
+ previously assigned adapters can be assigned to another mediated matrix
+ device. If an APQN is assigned to another mediated matrix device, the
+ operation will terminate with an error (EADDRINUSE).
+
+ In order to successfully assign a control domain, the domain number
+ specified must represent a value from 0 up to the maximum domain number
+ configured for the system. If a control domain number higher than the maximum
+ is specified, the operation will terminate with an error (ENODEV).
+
+5. Start Guest1:
+
+ /usr/bin/qemu-system-s390x ... -cpu host,ap=on,apqci=on,apft=on \
+ -device vfio-ap,sysfsdev=/sys/devices/vfio_ap/matrix/$uuid1 ...
+
+7. Start Guest2:
+
+ /usr/bin/qemu-system-s390x ... -cpu host,ap=on,apqci=on,apft=on \
+ -device vfio-ap,sysfsdev=/sys/devices/vfio_ap/matrix/$uuid2 ...
+
+7. Start Guest3:
+
+ /usr/bin/qemu-system-s390x ... -cpu host,ap=on,apqci=on,apft=on \
+ -device vfio-ap,sysfsdev=/sys/devices/vfio_ap/matrix/$uuid3 ...
+
+When the guest is shut down, the mediated matrix devices may be removed.
+
+Using our example again, to remove the mediated matrix device $uuid1:
+
+ /sys/devices/vfio_ap/matrix/
+ --- [mdev_supported_types]
+ ------ [vfio_ap-passthrough]
+ --------- [devices]
+ ------------ [$uuid1]
+ --------------- remove
+
+
+ echo 1 > remove
+
+ This will remove all of the mdev matrix device's sysfs structures including
+ the mdev device itself. To recreate and reconfigure the mdev matrix device,
+ all of the steps starting with step 3 will have to be performed again. Note
+ that the remove will fail if a guest using the mdev is still running.
+
+ It is not necessary to remove an mdev matrix device, but one may want to
+ remove it if no guest will use it during the remaining lifetime of the linux
+ host. If the mdev matrix device is removed, one may want to also reconfigure
+ the pool of adapters and queues reserved for use by the default drivers.
+
+Limitations
+===========
+* The KVM/kernel interfaces do not provide a way to prevent restoring an APQN
+ to the default drivers pool of a queue that is still assigned to a mediated
+ device in use by a guest. It is incumbent upon the administrator to
+ ensure there is no mediated device in use by a guest to which the APQN is
+ assigned lest the host be given access to the private data of the AP queue
+ device such as a private key configured specifically for the guest.
+
+* Dynamically modifying the AP matrix for a running guest (which would amount to
+ hot(un)plug of AP devices for the guest) is currently not supported
+
+* Live guest migration is not supported for guests using AP devices.
diff --git a/Documentation/virtual/kvm/api.txt b/Documentation/virtual/kvm/api.txt
index 647f94128a85..cd209f7730af 100644
--- a/Documentation/virtual/kvm/api.txt
+++ b/Documentation/virtual/kvm/api.txt
@@ -123,6 +123,37 @@ memory layout to fit in user mode), check KVM_CAP_MIPS_VZ and use the
flag KVM_VM_MIPS_VZ.
+On arm64, the physical address size for a VM (IPA Size limit) is limited
+to 40bits by default. The limit can be configured if the host supports the
+extension KVM_CAP_ARM_VM_IPA_SIZE. When supported, use
+KVM_VM_TYPE_ARM_IPA_SIZE(IPA_Bits) to set the size in the machine type
+identifier, where IPA_Bits is the maximum width of any physical
+address used by the VM. The IPA_Bits is encoded in bits[7-0] of the
+machine type identifier.
+
+e.g, to configure a guest to use 48bit physical address size :
+
+ vm_fd = ioctl(dev_fd, KVM_CREATE_VM, KVM_VM_TYPE_ARM_IPA_SIZE(48));
+
+The requested size (IPA_Bits) must be :
+ 0 - Implies default size, 40bits (for backward compatibility)
+
+ or
+
+ N - Implies N bits, where N is a positive integer such that,
+ 32 <= N <= Host_IPA_Limit
+
+Host_IPA_Limit is the maximum possible value for IPA_Bits on the host and
+is dependent on the CPU capability and the kernel configuration. The limit can
+be retrieved using KVM_CAP_ARM_VM_IPA_SIZE of the KVM_CHECK_EXTENSION
+ioctl() at run-time.
+
+Please note that configuring the IPA size does not affect the capability
+exposed by the guest CPUs in ID_AA64MMFR0_EL1[PARange]. It only affects
+size of the address translated by the stage2 level (guest physical to
+host physical address translations).
+
+
4.3 KVM_GET_MSR_INDEX_LIST, KVM_GET_MSR_FEATURE_INDEX_LIST
Capability: basic, KVM_CAP_GET_MSR_FEATURES for KVM_GET_MSR_FEATURE_INDEX_LIST
@@ -850,7 +881,7 @@ struct kvm_vcpu_events {
__u8 injected;
__u8 nr;
__u8 has_error_code;
- __u8 pad;
+ __u8 pending;
__u32 error_code;
} exception;
struct {
@@ -873,15 +904,23 @@ struct kvm_vcpu_events {
__u8 smm_inside_nmi;
__u8 latched_init;
} smi;
+ __u8 reserved[27];
+ __u8 exception_has_payload;
+ __u64 exception_payload;
};
-Only two fields are defined in the flags field:
+The following bits are defined in the flags field:
-- KVM_VCPUEVENT_VALID_SHADOW may be set in the flags field to signal that
+- KVM_VCPUEVENT_VALID_SHADOW may be set to signal that
interrupt.shadow contains a valid state.
-- KVM_VCPUEVENT_VALID_SMM may be set in the flags field to signal that
- smi contains a valid state.
+- KVM_VCPUEVENT_VALID_SMM may be set to signal that smi contains a
+ valid state.
+
+- KVM_VCPUEVENT_VALID_PAYLOAD may be set to signal that the
+ exception_has_payload, exception_payload, and exception.pending
+ fields contain a valid state. This bit will be set whenever
+ KVM_CAP_EXCEPTION_PAYLOAD is enabled.
ARM/ARM64:
@@ -961,6 +1000,11 @@ shall be written into the VCPU.
KVM_VCPUEVENT_VALID_SMM can only be set if KVM_CAP_X86_SMM is available.
+If KVM_CAP_EXCEPTION_PAYLOAD is enabled, KVM_VCPUEVENT_VALID_PAYLOAD
+can be set in the flags field to signal that the
+exception_has_payload, exception_payload, and exception.pending fields
+contain a valid state and shall be written into the VCPU.
+
ARM/ARM64:
Set the pending SError exception state for this VCPU. It is not possible to
@@ -1922,6 +1966,7 @@ registers, find a list below:
PPC | KVM_REG_PPC_TIDR | 64
PPC | KVM_REG_PPC_PSSCR | 64
PPC | KVM_REG_PPC_DEC_EXPIRY | 64
+ PPC | KVM_REG_PPC_PTCR | 64
PPC | KVM_REG_PPC_TM_GPR0 | 64
...
PPC | KVM_REG_PPC_TM_GPR31 | 64
@@ -2269,6 +2314,10 @@ The supported flags are:
The emulated MMU supports 1T segments in addition to the
standard 256M ones.
+ - KVM_PPC_NO_HASH
+ This flag indicates that HPT guests are not supported by KVM,
+ thus all guests must use radix MMU mode.
+
The "slb_size" field indicates how many SLB entries are supported
The "sps" array contains 8 entries indicating the supported base
@@ -3676,6 +3725,34 @@ Returns: 0 on success, -1 on error
This copies the vcpu's kvm_nested_state struct from userspace to the kernel. For
the definition of struct kvm_nested_state, see KVM_GET_NESTED_STATE.
+4.116 KVM_(UN)REGISTER_COALESCED_MMIO
+
+Capability: KVM_CAP_COALESCED_MMIO (for coalesced mmio)
+ KVM_CAP_COALESCED_PIO (for coalesced pio)
+Architectures: all
+Type: vm ioctl
+Parameters: struct kvm_coalesced_mmio_zone
+Returns: 0 on success, < 0 on error
+
+Coalesced I/O is a performance optimization that defers hardware
+register write emulation so that userspace exits are avoided. It is
+typically used to reduce the overhead of emulating frequently accessed
+hardware registers.
+
+When a hardware register is configured for coalesced I/O, write accesses
+do not exit to userspace and their value is recorded in a ring buffer
+that is shared between kernel and userspace.
+
+Coalesced I/O is used if one or more write accesses to a hardware
+register can be deferred until a read or a write to another hardware
+register on the same device. This last access will cause a vmexit and
+userspace will process accesses from the ring buffer before emulating
+it. That will avoid exiting to userspace on repeated writes.
+
+Coalesced pio is based on coalesced mmio. There is little difference
+between coalesced mmio and pio except that coalesced pio records accesses
+to I/O ports.
+
5. The kvm_run structure
------------------------
@@ -4522,7 +4599,7 @@ hpage module parameter is not set to 1, -EINVAL is returned.
While it is generally possible to create a huge page backed VM without
this capability, the VM will not be able to run.
-7.14 KVM_CAP_MSR_PLATFORM_INFO
+7.15 KVM_CAP_MSR_PLATFORM_INFO
Architectures: x86
Parameters: args[0] whether feature should be enabled or not
@@ -4531,6 +4608,45 @@ With this capability, a guest may read the MSR_PLATFORM_INFO MSR. Otherwise,
a #GP would be raised when the guest tries to access. Currently, this
capability does not enable write permissions of this MSR for the guest.
+7.16 KVM_CAP_PPC_NESTED_HV
+
+Architectures: ppc
+Parameters: none
+Returns: 0 on success, -EINVAL when the implementation doesn't support
+ nested-HV virtualization.
+
+HV-KVM on POWER9 and later systems allows for "nested-HV"
+virtualization, which provides a way for a guest VM to run guests that
+can run using the CPU's supervisor mode (privileged non-hypervisor
+state). Enabling this capability on a VM depends on the CPU having
+the necessary functionality and on the facility being enabled with a
+kvm-hv module parameter.
+
+7.17 KVM_CAP_EXCEPTION_PAYLOAD
+
+Architectures: x86
+Parameters: args[0] whether feature should be enabled or not
+
+With this capability enabled, CR2 will not be modified prior to the
+emulated VM-exit when L1 intercepts a #PF exception that occurs in
+L2. Similarly, for kvm-intel only, DR6 will not be modified prior to
+the emulated VM-exit when L1 intercepts a #DB exception that occurs in
+L2. As a result, when KVM_GET_VCPU_EVENTS reports a pending #PF (or
+#DB) exception for L2, exception.has_payload will be set and the
+faulting address (or the new DR6 bits*) will be reported in the
+exception_payload field. Similarly, when userspace injects a #PF (or
+#DB) into L2 using KVM_SET_VCPU_EVENTS, it is expected to set
+exception.has_payload and to put the faulting address (or the new DR6
+bits*) in the exception_payload field.
+
+This capability also enables exception.pending in struct
+kvm_vcpu_events, which allows userspace to distinguish between pending
+and injected exceptions.
+
+
+* For the new DR6 bits, note that bit 16 is set iff the #DB exception
+ will clear DR6.RTM.
+
8. Other capabilities.
----------------------
@@ -4772,3 +4888,10 @@ CPU when the exception is taken. If this virtual SError is taken to EL1 using
AArch64, this value will be reported in the ISS field of ESR_ELx.
See KVM_CAP_VCPU_EVENTS for more details.
+8.20 KVM_CAP_HYPERV_SEND_IPI
+
+Architectures: x86
+
+This capability indicates that KVM supports paravirtualized Hyper-V IPI send
+hypercalls:
+HvCallSendSyntheticClusterIpi, HvCallSendSyntheticClusterIpiEx.