Linux KVM Hypercall:
X86:
KVM Hypercalls have a three-byte sequence of either the vmcall or the vmmcall
instruction. The hypervisor can replace it with instructions that are
guaranteed to be supported.
Up to four arguments may be passed in rbx, rcx, rdx, and rsi respectively.
The hypercall number should be placed in rax and the return value will be
placed in rax. No other registers will be clobbered unless explicitly stated
by the particular hypercall.
S390:
R2-R7 are used for parameters 1-6. In addition, R1 is used for hypercall
number. The return value is written to R2.
S390 uses diagnose instruction as hypercall (0x500) along with hypercall
number in R1.
For further information on the S390 diagnose call as supported by KVM,
refer to Documentation/virtual/kvm/s390-diag.txt.
PowerPC:
It uses R3-R10 and hypercall number in R11. R4-R11 are used as output registers.
Return value is placed in R3.
KVM hypercalls uses 4 byte opcode, that are patched with ‘hypercall-instructions’
property inside the device tree’s /hypervisor node.
For more information refer to Documentation/virtual/kvm/ppc-pv.txt
MIPS:
KVM hypercalls use the HYPCALL instruction with code 0 and the hypercall
number in $2 (v0). Up to four arguments may be placed in $4-$7 (a0-a3) and
the return value is placed in $2 (v0).
KVM Hypercalls Documentation
The template for each hypercall is:
Hypercall name.
Architecture(s)
Status (deprecated, obsolete, active)
Purpose
KVM_HC_VAPIC_POLL_IRQ
Architecture: x86
Status: active
Purpose: Trigger guest exit so that the host can check for pending
interrupts on reentry.
- KVM_HC_MMU_OP
Architecture: x86
Status: deprecated.
Purpose: Support MMU operations such as writing to PTE,
flushing TLB, release PT.
- KVM_HC_FEATURES
Architecture: PPC
Status: active
Purpose: Expose hypercall availability to the guest. On x86 platforms, cpuid
used to enumerate which hypercalls are available. On PPC, either device tree
based lookup ( which is also what EPAPR dictates) OR KVM specific enumeration
mechanism (which is this hypercall) can be used.
- KVM_HC_PPC_MAP_MAGIC_PAGE
Architecture: PPC
Status: active
Purpose: To enable communication between the hypervisor and guest there is a
shared page that contains parts of supervisor visible register state.
The guest can map this shared page to access its supervisor register through
memory using this hypercall.
- KVM_HC_KICK_CPU
Architecture: x86
Status: active
Purpose: Hypercall used to wakeup a vcpu from HLT state
Usage example : A vcpu of a paravirtualized guest that is busywaiting in guest
kernel mode for an event to occur (ex: a spinlock to become available) can
execute HLT instruction once it has busy-waited for more than a threshold
time-interval. Execution of HLT instruction would cause the hypervisor to put
the vcpu to sleep until occurrence of an appropriate event. Another vcpu of the
same guest can wakeup the sleeping vcpu by issuing KVM_HC_KICK_CPU hypercall,
specifying APIC ID (a1) of the vcpu to be woken up. An additional argument (a0)
is used in the hypercall for future use.
- KVM_HC_CLOCK_PAIRING
Architecture: x86
Status: active
Purpose: Hypercall used to synchronize host and guest clocks.
Usage:
a0: guest physical address where host copies
“struct kvm_clock_offset” structure.
a1: clock_type, ATM only KVM_CLOCK_PAIRING_WALLCLOCK (0)
is supported (corresponding to the host’s CLOCK_REALTIME clock).
struct kvm_clock_pairing {
__s64 sec;
__s64 nsec;
__u64 tsc;
__u32 flags;
__u32 pad[9];
};
Where:
* sec: seconds from clock_type clock.
* nsec: nanoseconds from clock_type clock.
* tsc: guest TSC value used to calculate sec/nsec pair
* flags: flags, unused (0) at the moment.
The hypercall lets a guest compute a precise timestamp across
host and guest. The guest can use the returned TSC value to
compute the CLOCK_REALTIME for its clock, at the same instant.
Returns KVM_EOPNOTSUPP if the host does not use TSC clocksource,
or if clock type is different than KVM_CLOCK_PAIRING_WALLCLOCK.
- KVM_HC_SEND_IPI
Architecture: x86
Status: active
Purpose: Send IPIs to multiple vCPUs.
a0: lower part of the bitmap of destination APIC IDs
a1: higher part of the bitmap of destination APIC IDs
a2: the lowest APIC ID in bitmap
a3: APIC ICR
The hypercall lets a guest send multicast IPIs, with at most 128
128 destinations per hypercall in 64-bit mode and 64 vCPUs per
hypercall in 32-bit mode. The destinations are represented by a
bitmap contained in the first two arguments (a0 and a1). Bit 0 of
a0 corresponds to the APIC ID in the third argument (a2), bit 1
corresponds to the APIC ID a2+1, and so on.
Returns the number of CPUs to which the IPIs were delivered successfully.