Documentation/virt/kvm/devices/vcpu.rst - linux - Git at Google

 .. SPDX-License-Identifier: GPL-2.0

 ======================
 Generic vcpu interface
 ======================

 The virtual cpu "device" also accepts the ioctls KVM_SET_DEVICE_ATTR,
 KVM_GET_DEVICE_ATTR, and KVM_HAS_DEVICE_ATTR. The interface uses the same struct
 kvm_device_attr as other devices, but targets VCPU-wide settings and controls.

 The groups and attributes per virtual cpu, if any, are architecture specific.

 1. GROUP: KVM_ARM_VCPU_PMU_V3_CTRL
 ==================================

 :Architectures: ARM64

 1.1. ATTRIBUTE: KVM_ARM_VCPU_PMU_V3_IRQ
 ---------------------------------------

 :Parameters: in kvm_device_attr.addr the address for PMU overflow interrupt is a
 	     pointer to an int

 Returns:

 	 =======  ========================================================
 	 -EBUSY   The PMU overflow interrupt is already set
 	 -EFAULT  Error reading interrupt number
 	 -ENXIO   PMUv3 not supported or the overflow interrupt not set
 		  when attempting to get it
 	 -ENODEV  KVM_ARM_VCPU_PMU_V3 feature missing from VCPU
 	 -EINVAL  Invalid PMU overflow interrupt number supplied or
 		  trying to set the IRQ number without using an in-kernel
 		  irqchip.
 	 =======  ========================================================

 A value describing the PMUv3 (Performance Monitor Unit v3) overflow interrupt
 number for this vcpu. This interrupt could be a PPI or SPI, but the interrupt
 type must be same for each vcpu. As a PPI, the interrupt number is the same for
 all vcpus, while as an SPI it must be a separate number per vcpu.

 1.2 ATTRIBUTE: KVM_ARM_VCPU_PMU_V3_INIT
 ---------------------------------------

 :Parameters: no additional parameter in kvm_device_attr.addr

 Returns:

 	 =======  ======================================================
 	 -EEXIST  Interrupt number already used
 	 -ENODEV  PMUv3 not supported or GIC not initialized
 	 -ENXIO   PMUv3 not supported, missing VCPU feature or interrupt
 		  number not set
 	 -EBUSY   PMUv3 already initialized
 	 =======  ======================================================

 Request the initialization of the PMUv3.  If using the PMUv3 with an in-kernel
 virtual GIC implementation, this must be done after initializing the in-kernel
 irqchip.

 1.3 ATTRIBUTE: KVM_ARM_VCPU_PMU_V3_FILTER
 -----------------------------------------

 :Parameters: in kvm_device_attr.addr the address for a PMU event filter is a
              pointer to a struct kvm_pmu_event_filter

 :Returns:

 	 =======  ======================================================
 	 -ENODEV  PMUv3 not supported or GIC not initialized
 	 -ENXIO   PMUv3 not properly configured or in-kernel irqchip not
 	 	  configured as required prior to calling this attribute
 	 -EBUSY   PMUv3 already initialized
 	 -EINVAL  Invalid filter range
 	 =======  ======================================================

 Request the installation of a PMU event filter described as follows::

     struct kvm_pmu_event_filter {
 	    __u16	base_event;
 	    __u16	nevents;

     #define KVM_PMU_EVENT_ALLOW	0
     #define KVM_PMU_EVENT_DENY	1

 	    __u8	action;
 	    __u8	pad[3];
     };

 A filter range is defined as the range [@base_event, @base_event + @nevents),
 together with an @action (KVM_PMU_EVENT_ALLOW or KVM_PMU_EVENT_DENY). The
 first registered range defines the global policy (global ALLOW if the first
 @action is DENY, global DENY if the first @action is ALLOW). Multiple ranges
 can be programmed, and must fit within the event space defined by the PMU
 architecture (10 bits on ARMv8.0, 16 bits from ARMv8.1 onwards).

 Note: "Cancelling" a filter by registering the opposite action for the same
 range doesn't change the default action. For example, installing an ALLOW
 filter for event range [0:10) as the first filter and then applying a DENY
 action for the same range will leave the whole range as disabled.

 Restrictions: Event 0 (SW_INCR) is never filtered, as it doesn't count a
 hardware event. Filtering event 0x1E (CHAIN) has no effect either, as it
 isn't strictly speaking an event. Filtering the cycle counter is possible
 using event 0x11 (CPU_CYCLES).


 2. GROUP: KVM_ARM_VCPU_TIMER_CTRL
 =================================

 :Architectures: ARM, ARM64

 2.1. ATTRIBUTES: KVM_ARM_VCPU_TIMER_IRQ_VTIMER, KVM_ARM_VCPU_TIMER_IRQ_PTIMER
 -----------------------------------------------------------------------------

 :Parameters: in kvm_device_attr.addr the address for the timer interrupt is a
 	     pointer to an int

 Returns:

 	 =======  =================================
 	 -EINVAL  Invalid timer interrupt number
 	 -EBUSY   One or more VCPUs has already run
 	 =======  =================================

 A value describing the architected timer interrupt number when connected to an
 in-kernel virtual GIC.  These must be a PPI (16 <= intid < 32).  Setting the
 attribute overrides the default values (see below).

 =============================  ==========================================
 KVM_ARM_VCPU_TIMER_IRQ_VTIMER  The EL1 virtual timer intid (default: 27)
 KVM_ARM_VCPU_TIMER_IRQ_PTIMER  The EL1 physical timer intid (default: 30)
 =============================  ==========================================

 Setting the same PPI for different timers will prevent the VCPUs from running.
 Setting the interrupt number on a VCPU configures all VCPUs created at that
 time to use the number provided for a given timer, overwriting any previously
 configured values on other VCPUs.  Userspace should configure the interrupt
 numbers on at least one VCPU after creating all VCPUs and before running any
 VCPUs.

 3. GROUP: KVM_ARM_VCPU_PVTIME_CTRL
 ==================================

 :Architectures: ARM64

 3.1 ATTRIBUTE: KVM_ARM_VCPU_PVTIME_IPA
 --------------------------------------

 :Parameters: 64-bit base address

 Returns:

 	 =======  ======================================
 	 -ENXIO   Stolen time not implemented
 	 -EEXIST  Base address already set for this VCPU
 	 -EINVAL  Base address not 64 byte aligned
 	 =======  ======================================

 Specifies the base address of the stolen time structure for this VCPU. The
 base address must be 64 byte aligned and exist within a valid guest memory
 region. See Documentation/virt/kvm/arm/pvtime.rst for more information
 including the layout of the stolen time structure.

 4. GROUP: KVM_VCPU_TSC_CTRL
 ===========================

 :Architectures: x86

 4.1 ATTRIBUTE: KVM_VCPU_TSC_OFFSET

 :Parameters: 64-bit unsigned TSC offset

 Returns:

 	 ======= ======================================
 	 -EFAULT Error reading/writing the provided
 		 parameter address.
 	 -ENXIO  Attribute not supported
 	 ======= ======================================

 Specifies the guest's TSC offset relative to the host's TSC. The guest's
 TSC is then derived by the following equation:

   guest_tsc = host_tsc + KVM_VCPU_TSC_OFFSET

 This attribute is useful to adjust the guest's TSC on live migration,
 so that the TSC counts the time during which the VM was paused. The
 following describes a possible algorithm to use for this purpose.

 From the source VMM process:

 1. Invoke the KVM_GET_CLOCK ioctl to record the host TSC (tsc_src),
    kvmclock nanoseconds (guest_src), and host CLOCK_REALTIME nanoseconds
    (host_src).

 2. Read the KVM_VCPU_TSC_OFFSET attribute for every vCPU to record the
    guest TSC offset (ofs_src[i]).

 3. Invoke the KVM_GET_TSC_KHZ ioctl to record the frequency of the
    guest's TSC (freq).

 From the destination VMM process:

 4. Invoke the KVM_SET_CLOCK ioctl, providing the source nanoseconds from
    kvmclock (guest_src) and CLOCK_REALTIME (host_src) in their respective
    fields.  Ensure that the KVM_CLOCK_REALTIME flag is set in the provided
    structure.

    KVM will advance the VM's kvmclock to account for elapsed time since
    recording the clock values.  Note that this will cause problems in
    the guest (e.g., timeouts) unless CLOCK_REALTIME is synchronized
    between the source and destination, and a reasonably short time passes
    between the source pausing the VMs and the destination executing
    steps 4-7.

 5. Invoke the KVM_GET_CLOCK ioctl to record the host TSC (tsc_dest) and
    kvmclock nanoseconds (guest_dest).

 6. Adjust the guest TSC offsets for every vCPU to account for (1) time
    elapsed since recording state and (2) difference in TSCs between the
    source and destination machine:

    ofs_dst[i] = ofs_src[i] -
      (guest_src - guest_dest) * freq +
      (tsc_src - tsc_dest)

    ("ofs[i] + tsc - guest * freq" is the guest TSC value corresponding to
    a time of 0 in kvmclock.  The above formula ensures that it is the
    same on the destination as it was on the source).

 7. Write the KVM_VCPU_TSC_OFFSET attribute for every vCPU with the
    respective value derived in the previous step.
	.. SPDX-License-Identifier: GPL-2.0

	======================
	Generic vcpu interface
	======================

	The virtual cpu "device" also accepts the ioctls KVM_SET_DEVICE_ATTR,
	KVM_GET_DEVICE_ATTR, and KVM_HAS_DEVICE_ATTR. The interface uses the same struct
	kvm_device_attr as other devices, but targets VCPU-wide settings and controls.

	The groups and attributes per virtual cpu, if any, are architecture specific.

	1. GROUP: KVM_ARM_VCPU_PMU_V3_CTRL
	==================================

	:Architectures: ARM64

	1.1. ATTRIBUTE: KVM_ARM_VCPU_PMU_V3_IRQ
	---------------------------------------

	:Parameters: in kvm_device_attr.addr the address for PMU overflow interrupt is a
	pointer to an int

	Returns:

	======= ========================================================
	-EBUSY The PMU overflow interrupt is already set
	-EFAULT Error reading interrupt number
	-ENXIO PMUv3 not supported or the overflow interrupt not set
	when attempting to get it
	-ENODEV KVM_ARM_VCPU_PMU_V3 feature missing from VCPU
	-EINVAL Invalid PMU overflow interrupt number supplied or
	trying to set the IRQ number without using an in-kernel
	irqchip.
	======= ========================================================

	A value describing the PMUv3 (Performance Monitor Unit v3) overflow interrupt
	number for this vcpu. This interrupt could be a PPI or SPI, but the interrupt
	type must be same for each vcpu. As a PPI, the interrupt number is the same for
	all vcpus, while as an SPI it must be a separate number per vcpu.

	1.2 ATTRIBUTE: KVM_ARM_VCPU_PMU_V3_INIT
	---------------------------------------

	:Parameters: no additional parameter in kvm_device_attr.addr

	Returns:

	======= ======================================================
	-EEXIST Interrupt number already used
	-ENODEV PMUv3 not supported or GIC not initialized
	-ENXIO PMUv3 not supported, missing VCPU feature or interrupt
	number not set
	-EBUSY PMUv3 already initialized
	======= ======================================================

	Request the initialization of the PMUv3. If using the PMUv3 with an in-kernel
	virtual GIC implementation, this must be done after initializing the in-kernel
	irqchip.

	1.3 ATTRIBUTE: KVM_ARM_VCPU_PMU_V3_FILTER
	-----------------------------------------

	:Parameters: in kvm_device_attr.addr the address for a PMU event filter is a
	pointer to a struct kvm_pmu_event_filter

	:Returns:

	======= ======================================================
	-ENODEV PMUv3 not supported or GIC not initialized
	-ENXIO PMUv3 not properly configured or in-kernel irqchip not
	configured as required prior to calling this attribute
	-EBUSY PMUv3 already initialized
	-EINVAL Invalid filter range
	======= ======================================================

	Request the installation of a PMU event filter described as follows::

	struct kvm_pmu_event_filter {
	__u16 base_event;
	__u16 nevents;

	#define KVM_PMU_EVENT_ALLOW 0
	#define KVM_PMU_EVENT_DENY 1

	__u8 action;
	__u8 pad[3];
	};

	A filter range is defined as the range [@base_event, @base_event + @nevents),
	together with an @action (KVM_PMU_EVENT_ALLOW or KVM_PMU_EVENT_DENY). The
	first registered range defines the global policy (global ALLOW if the first
	@action is DENY, global DENY if the first @action is ALLOW). Multiple ranges
	can be programmed, and must fit within the event space defined by the PMU
	architecture (10 bits on ARMv8.0, 16 bits from ARMv8.1 onwards).

	Note: "Cancelling" a filter by registering the opposite action for the same
	range doesn't change the default action. For example, installing an ALLOW
	filter for event range [0:10) as the first filter and then applying a DENY
	action for the same range will leave the whole range as disabled.

	Restrictions: Event 0 (SW_INCR) is never filtered, as it doesn't count a
	hardware event. Filtering event 0x1E (CHAIN) has no effect either, as it
	isn't strictly speaking an event. Filtering the cycle counter is possible
	using event 0x11 (CPU_CYCLES).


	2. GROUP: KVM_ARM_VCPU_TIMER_CTRL
	=================================

	:Architectures: ARM, ARM64

	2.1. ATTRIBUTES: KVM_ARM_VCPU_TIMER_IRQ_VTIMER, KVM_ARM_VCPU_TIMER_IRQ_PTIMER
	-----------------------------------------------------------------------------

	:Parameters: in kvm_device_attr.addr the address for the timer interrupt is a
	pointer to an int

	Returns:

	======= =================================
	-EINVAL Invalid timer interrupt number
	-EBUSY One or more VCPUs has already run
	======= =================================

	A value describing the architected timer interrupt number when connected to an
	in-kernel virtual GIC. These must be a PPI (16 <= intid < 32). Setting the
	attribute overrides the default values (see below).

	============================= ==========================================
	KVM_ARM_VCPU_TIMER_IRQ_VTIMER The EL1 virtual timer intid (default: 27)
	KVM_ARM_VCPU_TIMER_IRQ_PTIMER The EL1 physical timer intid (default: 30)
	============================= ==========================================

	Setting the same PPI for different timers will prevent the VCPUs from running.
	Setting the interrupt number on a VCPU configures all VCPUs created at that
	time to use the number provided for a given timer, overwriting any previously
	configured values on other VCPUs. Userspace should configure the interrupt
	numbers on at least one VCPU after creating all VCPUs and before running any
	VCPUs.

	3. GROUP: KVM_ARM_VCPU_PVTIME_CTRL
	==================================

	:Architectures: ARM64

	3.1 ATTRIBUTE: KVM_ARM_VCPU_PVTIME_IPA
	--------------------------------------

	:Parameters: 64-bit base address

	Returns:

	======= ======================================
	-ENXIO Stolen time not implemented
	-EEXIST Base address already set for this VCPU
	-EINVAL Base address not 64 byte aligned
	======= ======================================

	Specifies the base address of the stolen time structure for this VCPU. The
	base address must be 64 byte aligned and exist within a valid guest memory
	region. See Documentation/virt/kvm/arm/pvtime.rst for more information
	including the layout of the stolen time structure.

	4. GROUP: KVM_VCPU_TSC_CTRL
	===========================

	:Architectures: x86

	4.1 ATTRIBUTE: KVM_VCPU_TSC_OFFSET

	:Parameters: 64-bit unsigned TSC offset

	Returns:

	======= ======================================
	-EFAULT Error reading/writing the provided
	parameter address.
	-ENXIO Attribute not supported
	======= ======================================

	Specifies the guest's TSC offset relative to the host's TSC. The guest's
	TSC is then derived by the following equation:

	guest_tsc = host_tsc + KVM_VCPU_TSC_OFFSET

	This attribute is useful to adjust the guest's TSC on live migration,
	so that the TSC counts the time during which the VM was paused. The
	following describes a possible algorithm to use for this purpose.

	From the source VMM process:

	1. Invoke the KVM_GET_CLOCK ioctl to record the host TSC (tsc_src),
	kvmclock nanoseconds (guest_src), and host CLOCK_REALTIME nanoseconds
	(host_src).

	2. Read the KVM_VCPU_TSC_OFFSET attribute for every vCPU to record the
	guest TSC offset (ofs_src[i]).

	3. Invoke the KVM_GET_TSC_KHZ ioctl to record the frequency of the
	guest's TSC (freq).

	From the destination VMM process:

	4. Invoke the KVM_SET_CLOCK ioctl, providing the source nanoseconds from
	kvmclock (guest_src) and CLOCK_REALTIME (host_src) in their respective
	fields. Ensure that the KVM_CLOCK_REALTIME flag is set in the provided
	structure.

	KVM will advance the VM's kvmclock to account for elapsed time since
	recording the clock values. Note that this will cause problems in
	the guest (e.g., timeouts) unless CLOCK_REALTIME is synchronized
	between the source and destination, and a reasonably short time passes
	between the source pausing the VMs and the destination executing
	steps 4-7.

	5. Invoke the KVM_GET_CLOCK ioctl to record the host TSC (tsc_dest) and
	kvmclock nanoseconds (guest_dest).

	6. Adjust the guest TSC offsets for every vCPU to account for (1) time
	elapsed since recording state and (2) difference in TSCs between the
	source and destination machine:

	ofs_dst[i] = ofs_src[i] -
	(guest_src - guest_dest) * freq +
	(tsc_src - tsc_dest)

	("ofs[i] + tsc - guest * freq" is the guest TSC value corresponding to
	a time of 0 in kvmclock. The above formula ensures that it is the
	same on the destination as it was on the source).

	7. Write the KVM_VCPU_TSC_OFFSET attribute for every vCPU with the
	respective value derived in the previous step.