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+.. SPDX-License-Identifier: GPL-2.0
+
+Clocks and Timers
+=================
+
+arm64
+-----
+On arm64, Hyper-V virtualizes the ARMv8 architectural system counter
+and timer. Guest VMs use this virtualized hardware as the Linux
+clocksource and clockevents via the standard arm_arch_timer.c
+driver, just as they would on bare metal. Linux vDSO support for the
+architectural system counter is functional in guest VMs on Hyper-V.
+While Hyper-V also provides a synthetic system clock and four synthetic
+per-CPU timers as described in the TLFS, they are not used by the
+Linux kernel in a Hyper-V guest on arm64.  However, older versions
+of Hyper-V for arm64 only partially virtualize the ARMv8
+architectural timer, such that the timer does not generate
+interrupts in the VM. Because of this limitation, running current
+Linux kernel versions on these older Hyper-V versions requires an
+out-of-tree patch to use the Hyper-V synthetic clocks/timers instead.
+
+x86/x64
+-------
+On x86/x64, Hyper-V provides guest VMs with a synthetic system clock
+and four synthetic per-CPU timers as described in the TLFS. Hyper-V
+also provides access to the virtualized TSC via the RDTSC and
+related instructions. These TSC instructions do not trap to
+the hypervisor and so provide excellent performance in a VM.
+Hyper-V performs TSC calibration, and provides the TSC frequency
+to the guest VM via a synthetic MSR.  Hyper-V initialization code
+in Linux reads this MSR to get the frequency, so it skips TSC
+calibration and sets tsc_reliable. Hyper-V provides virtualized
+versions of the PIT (in Hyper-V  Generation 1 VMs only), local
+APIC timer, and RTC. Hyper-V does not provide a virtualized HPET in
+guest VMs.
+
+The Hyper-V synthetic system clock can be read via a synthetic MSR,
+but this access traps to the hypervisor. As a faster alternative,
+the guest can configure a memory page to be shared between the guest
+and the hypervisor.  Hyper-V populates this memory page with a
+64-bit scale value and offset value. To read the synthetic clock
+value, the guest reads the TSC and then applies the scale and offset
+as described in the Hyper-V TLFS. The resulting value advances
+at a constant 10 MHz frequency. In the case of a live migration
+to a host with a different TSC frequency, Hyper-V adjusts the
+scale and offset values in the shared page so that the 10 MHz
+frequency is maintained.
+
+Starting with Windows Server 2022 Hyper-V, Hyper-V uses hardware
+support for TSC frequency scaling to enable live migration of VMs
+across Hyper-V hosts where the TSC frequency may be different.
+When a Linux guest detects that this Hyper-V functionality is
+available, it prefers to use Linux's standard TSC-based clocksource.
+Otherwise, it uses the clocksource for the Hyper-V synthetic system
+clock implemented via the shared page (identified as
+"hyperv_clocksource_tsc_page").
+
+The Hyper-V synthetic system clock is available to user space via
+vDSO, and gettimeofday() and related system calls can execute
+entirely in user space.  The vDSO is implemented by mapping the
+shared page with scale and offset values into user space.  User
+space code performs the same algorithm of reading the TSC and
+appying the scale and offset to get the constant 10 MHz clock.
+
+Linux clockevents are based on Hyper-V synthetic timer 0. While
+Hyper-V offers 4 synthetic timers for each CPU, Linux only uses
+timer 0. Interrupts from stimer0 are recorded on the "HVS" line in
+/proc/interrupts.  Clockevents based on the virtualized PIT and
+local APIC timer also work, but the Hyper-V synthetic timer is
+preferred.
+
+The driver for the Hyper-V synthetic system clock and timers is
+drivers/clocksource/hyperv_timer.c.