irqchip/gic-v4: Add some basic documentation

Do a braindump of the way things are supposed to work.

Reviewed-by: Thomas Gleixner <tglx@linutronix.de>
Reviewed-by: Eric Auger <eric.auger@redhat.com>
Signed-off-by: Marc Zyngier <marc.zyngier@arm.com>
This commit is contained in:
Marc Zyngier 2016-12-21 17:40:16 +00:00
parent f2eac75de4
commit 7954907bed

View File

@ -23,6 +23,77 @@
#include <linux/irqchip/arm-gic-v4.h>
/*
* WARNING: The blurb below assumes that you understand the
* intricacies of GICv3, GICv4, and how a guest's view of a GICv3 gets
* translated into GICv4 commands. So it effectively targets at most
* two individuals. You know who you are.
*
* The core GICv4 code is designed to *avoid* exposing too much of the
* core GIC code (that would in turn leak into the hypervisor code),
* and instead provide a hypervisor agnostic interface to the HW (of
* course, the astute reader will quickly realize that hypervisor
* agnostic actually means KVM-specific - what were you thinking?).
*
* In order to achieve a modicum of isolation, we try to hide most of
* the GICv4 "stuff" behind normal irqchip operations:
*
* - Any guest-visible VLPI is backed by a Linux interrupt (and a
* physical LPI which gets unmapped when the guest maps the
* VLPI). This allows the same DevID/EventID pair to be either
* mapped to the LPI (host) or the VLPI (guest). Note that this is
* exclusive, and you cannot have both.
*
* - Enabling/disabling a VLPI is done by issuing mask/unmask calls.
*
* - Guest INT/CLEAR commands are implemented through
* irq_set_irqchip_state().
*
* - The *bizarre* stuff (mapping/unmapping an interrupt to a VLPI, or
* issuing an INV after changing a priority) gets shoved into the
* irq_set_vcpu_affinity() method. While this is quite horrible
* (let's face it, this is the irqchip version of an ioctl), it
* confines the crap to a single location. And map/unmap really is
* about setting the affinity of a VLPI to a vcpu, so only INV is
* majorly out of place. So there.
*
* A number of commands are simply not provided by this interface, as
* they do not make direct sense. For example, MAPD is purely local to
* the virtual ITS (because it references a virtual device, and the
* physical ITS is still very much in charge of the physical
* device). Same goes for things like MAPC (the physical ITS deals
* with the actual vPE affinity, and not the braindead concept of
* collection). SYNC is not provided either, as each and every command
* is followed by a VSYNC. This could be relaxed in the future, should
* this be seen as a bottleneck (yes, this means *never*).
*
* But handling VLPIs is only one side of the job of the GICv4
* code. The other (darker) side is to take care of the doorbell
* interrupts which are delivered when a VLPI targeting a non-running
* vcpu is being made pending.
*
* The choice made here is that each vcpu (VPE in old northern GICv4
* dialect) gets a single doorbell LPI, no matter how many interrupts
* are targeting it. This has a nice property, which is that the
* interrupt becomes a handle for the VPE, and that the hypervisor
* code can manipulate it through the normal interrupt API:
*
* - VMs (or rather the VM abstraction that matters to the GIC)
* contain an irq domain where each interrupt maps to a VPE. In
* turn, this domain sits on top of the normal LPI allocator, and a
* specially crafted irq_chip implementation.
*
* - mask/unmask do what is expected on the doorbell interrupt.
*
* - irq_set_affinity is used to move a VPE from one redistributor to
* another.
*
* - irq_set_vcpu_affinity once again gets hijacked for the purpose of
* creating a new sub-API, namely scheduling/descheduling a VPE
* (which involves programming GICR_V{PROP,PEND}BASER) and
* performing INVALL operations.
*/
static struct irq_domain *gic_domain;
static const struct irq_domain_ops *vpe_domain_ops;