- 24 May, 2016 2 commits
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Dan Carpenter authored
These were supposed to be a bitwise operation but there is a typo. The result is mostly harmless, but sparse correctly complains. Fixes: 44a95dae ('KVM: x86: Detect and Initialize AVIC support') Fixes: 18f40c53 ('svm: Add VMEXIT handlers for AVIC') Signed-off-by:
Dan Carpenter <dan.carpenter@oracle.com> Signed-off-by:
Paolo Bonzini <pbonzini@redhat.com>
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Paolo Bonzini authored
Merge tag 'kvm-arm-for-4-7-take2' of git://git.kernel.org/pub/scm/linux/kernel/git/kvmarm/kvmarm into kvm-next KVM/ARM Changes for v4.7 take 2 "The GIC is dead; Long live the GIC" This set of changes include the new vgic, which is a reimplementation of our horribly broken legacy vgic implementation. The two implementations will live side-by-side (with the new being the configured default) for one kernel release and then we'll remove it. Also fixes a non-critical issue with virtual abort injection to guests.
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- 20 May, 2016 38 commits
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Christoffer Dall authored
When modifying the active state of an interrupt via the MMIO interface, we should ensure that the write has the intended effect. If a guest sets an interrupt to active, but that interrupt is already flushed into a list register on a running VCPU, then that VCPU will write the active state back into the struct vgic_irq upon returning from the guest and syncing its state. This is a non-benign race, because the guest can observe that an interrupt is not active, and it can have a reasonable expectations that other VCPUs will not ack any IRQs, and then set the state to active, and expect it to stay that way. Currently we are not honoring this case. Thefore, change both the SACTIVE and CACTIVE mmio handlers to stop the world, change the irq state, potentially queue the irq if we're setting it to active, and then continue. We take this chance to slightly optimize these functions by not stopping the world when touching private interrupts where there is inherently no possible race. Signed-off-by:Christoffer Dall <christoffer.dall@linaro.org>
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Andre Przywara authored
Now that the new VGIC implementation has reached feature parity with the old one, add the new files to the build system and add a Kconfig option to switch between the two versions. We set the default to the new version to get maximum test coverage, in case people experience problems they can switch back to the old behaviour if needed. Signed-off-by:
Andre Przywara <andre.przywara@arm.com> Acked-by:
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Andre Przywara authored
We now store the mapped hardware IRQ number in our struct, so we don't need the irq_phys_map for the new VGIC. Implement the hardware IRQ mapping on top of the reworked arch timer interface. Signed-off-by:
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Andre Przywara authored
Connect to the new VGIC to the irqfd framework, so that we can inject IRQs. GSI routing and MSI routing is not yet implemented. Signed-off-by:
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Eric Auger authored
Enable the VGIC operation by properly initialising the registers in the hypervisor GIC interface. Signed-off-by:
Eric Auger <eric.auger@linaro.org> Signed-off-by:
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Eric Auger authored
map_resources is the last initialization step. It is executed on first VCPU run. At that stage the code checks that userspace has provided the base addresses for the relevant VGIC regions, which depend on the type of VGIC that is exposed to the guest. Also we check if the two regions overlap. If the checks succeeded, we register the respective register frames with the kvm_io_bus framework. If we emulate a GICv2, the function also forces vgic_init execution if it has not been executed yet. Also we map the virtual GIC CPU interface onto the guest's CPU interface. Signed-off-by:
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Eric Auger authored
This patch allocates and initializes the data structures used to model the vgic distributor and virtual cpu interfaces. At that stage the number of IRQs and number of virtual CPUs is frozen. Signed-off-by:
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Eric Auger authored
This patch implements the vgic_creation function which is called on CREATE_IRQCHIP VM IOCTL (v2 only) or KVM_CREATE_DEVICE Signed-off-by:
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Eric Auger authored
Implements kvm_vgic_hyp_init and vgic_probe function. This uses the new firmware independent VGIC probing to support both ACPI and DT based systems (code from Marc Zyngier). The vgic_global struct is enriched with new fields populated by those functions. Signed-off-by:
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Andre Przywara authored
Using the VMCR accessors we provide access to GIC CPU interface state to userland by wiring it up to the existing userland interface. [Marc: move and make VMCR accessors static, streamline MMIO handlers] Signed-off-by:
Marc Zyngier <marc.zyngier@arm.com> Reviewed-by:
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Andre Przywara authored
Since the GIC CPU interface is always virtualized by the hardware, we don't have CPU interface state information readily available in our emulation if userland wants to save or restore it. Fortunately the GIC hypervisor interface provides the VMCR register to access the required virtual CPU interface bits. Provide wrappers for GICv2 and GICv3 hosts to have access to this register. Signed-off-by:
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Andre Przywara authored
Userland may want to save and restore the state of the in-kernel VGIC, so we provide the code which takes a userland request and translate that into calls to our MMIO framework. From Christoffer: When accessing the VGIC state from userspace we really don't want a VCPU to be messing with the state at the same time, and the API specifies that we should return -EBUSY if any VCPUs are running. Check and prevent VCPUs from running by grabbing their mutexes, one by one, and error out if we fail. (Note: This could potentially be simplified to just do a simple check and see if any VCPUs are running, and return -EBUSY then, without enforcing the locking throughout the duration of the uaccess, if we think that taking/releasing all these mutexes for every single GIC register access is too heavyweight.) Signed-off-by:
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Christoffer Dall authored
Userland can access the emulated GIC to save and restore its state for initialization or migration purposes. The kvm_io_bus API requires an absolute gpa, which does not fit the KVM_DEV_ARM_VGIC_GRP_DIST_REGS user API, that only provides relative offsets. So we provide a wrapper to plug into our MMIO framework and find the respective register handler. Signed-off-by:
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Eric Auger authored
This patch implements the switches for KVM_DEV_ARM_VGIC_GRP_DIST_REGS and KVM_DEV_ARM_VGIC_GRP_CPU_REGS API which allows the userspace to access VGIC registers. Signed-off-by:
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Eric Auger authored
This patch implements the KVM_DEV_ARM_VGIC_GRP_ADDR group which enables to set the base address of GIC regions as seen by the guest. Signed-off-by:
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Eric Auger authored
kvm_vgic_addr is used by the userspace to set the base address of the following register regions, as seen by the guest: - distributor(v2 and v3), - re-distributors (v3), - CPU interface (v2). Signed-off-by:
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Eric Auger authored
This patch implements the KVM_DEV_ARM_VGIC_GRP_CTRL group API featuring KVM_DEV_ARM_VGIC_CTRL_INIT attribute. The vgic_init function is not yet implemented though. Signed-off-by:
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Eric Auger authored
This patch implements the KVM_DEV_ARM_VGIC_GRP_NR_IRQS group. This modality is supported by both VGIC V2 and V3 KVM device as will be other groups, hence the introduction of common helpers. Signed-off-by:
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Eric Auger authored
This patch introduces the skeleton for the KVM device operations associated to KVM_DEV_TYPE_ARM_VGIC_V2 and KVM_DEV_TYPE_ARM_VGIC_V3. At that stage kvm_vgic_create is stubbed. Signed-off-by:
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Andre Przywara authored
In contrast to GICv2 SGIs in a GICv3 implementation are not triggered by a MMIO write, but with a system register write. KVM knows about that register already, we just need to implement the handler and wire it up to the core KVM/ARM code. Signed-off-by:
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Andre Przywara authored
Since GICv3 supports much more than the 8 CPUs the GICv2 ITARGETSR register can handle, the new IROUTER register covers the whole range of possible target (V)CPUs by using the same MPIDR that the cores report themselves. In addition to translating this MPIDR into a vcpu pointer we store the originally written value as well. The architecture allows to write any values into the register, which must be read back as written. Since we don't support affinity level 3, we don't need to take care about the upper word of this 64-bit register, which simplifies the handling a bit. Signed-off-by:
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Andre Przywara authored
We implement the only one ID register that is required by the architecture, also this is the one that Linux actually checks. Signed-off-by:
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Andre Przywara authored
The redistributor TYPER tells the OS about the associated MPIDR, also the LAST bit is crucial to determine the number of redistributors. Signed-off-by:
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Andre Przywara authored
As in the GICv2 emulation we handle those three registers in one function. Signed-off-by:
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Andre Przywara authored
Create a new file called vgic-mmio-v3.c and describe the GICv3 distributor and redistributor registers there. This adds a special macro to deal with the split of SGI/PPI in the redistributor and SPIs in the distributor, which allows us to reuse the existing GICv2 handlers for those registers which are compatible. Also we provide a function to deal with the registration of the two separate redistributor frames per VCPU. Signed-off-by:
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Andre Przywara authored
As this register is v2 specific, its implementation lives entirely in vgic-mmio-v2.c. This register allows setting the source mask of an IPI. Signed-off-by:
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Andre Przywara authored
Triggering an IPI via this register is v2 specific, so the implementation lives entirely in vgic-mmio-v2.c. Signed-off-by:
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Andre Przywara authored
The target register handlers are v2 emulation specific, so their implementation lives entirely in vgic-mmio-v2.c. We copy the old VGIC behaviour of assigning an IRQ to the first VCPU set in the target mask instead of making it possibly pending on multiple VCPUs. Signed-off-by:
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Andre Przywara authored
The config register handlers are shared between the v2 and v3 emulation, so their implementation goes into vgic-mmio.c, to be easily referenced from the v3 emulation as well later. Signed-off-by: -
Andre Przywara authored
The priority register handlers are shared between the v2 and v3 emulation, so their implementation goes into vgic-mmio.c, to be easily referenced from the v3 emulation as well later. There is a corner case when we change the priority of a pending interrupt which we don't handle at the moment. Signed-off-by:
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Andre Przywara authored
The active register handlers are shared between the v2 and v3 emulation, so their implementation goes into vgic-mmio.c, to be easily referenced from the v3 emulation as well later. Since activation/deactivation of an interrupt may happen entirely in the guest without it ever exiting, we need some extra logic to properly track the active state. For clearing the active state, we basically have to halt the guest to make sure this is properly propagated into the respective VCPUs. Signed-off-by: -
Andre Przywara authored
The pending register handlers are shared between the v2 and v3 emulation, so their implementation goes into vgic-mmio.c, to be easily referenced from the v3 emulation as well later. For level triggered interrupts the real line level is unaffected by this write, so we keep this state separate and combine it with the device's level to get the actual pending state. Signed-off-by:
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Andre Przywara authored
As the enable register handlers are shared between the v2 and v3 emulation, their implementation goes into vgic-mmio.c, to be easily referenced from the v3 emulation as well later. Signed-off-by:
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Marc Zyngier authored
Those three registers are v2 emulation specific, so their implementation lives entirely in vgic-mmio-v2.c. Also they are handled in one function, as their implementation is pretty simple. When the guest enables the distributor, we kick all VCPUs to get potentially pending interrupts serviced. Signed-off-by:
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Andre Przywara authored
Create vgic-mmio-v2.c to describe GICv2 emulation specific handlers using the initializer macros provided by the VGIC MMIO framework. Provide a function to register the GICv2 distributor registers to the kvm_io_bus framework. The actual handler functions are still stubs in this patch. Signed-off-by:
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Marc Zyngier authored
Add an MMIO handling framework to the VGIC emulation: Each register is described by its offset, size (or number of bits per IRQ, if applicable) and the read/write handler functions. We provide initialization macros to describe each GIC register later easily. Separate dispatch functions for read and write accesses are connected to the kvm_io_bus framework and binary-search for the responsible register handler based on the offset address within the region. We convert the incoming data (referenced by a pointer) to the host's endianess and use pass-by-value to hand the data over to the actual handler functions. The register handler prototype and the endianess conversion are courtesy of Christoffer Dall. Signed-off-by:
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Eric Auger authored
Tell KVM whether a particular VCPU has an IRQ that needs handling in the guest. This is used to decide whether a VCPU is runnable. Signed-off-by:
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Marc Zyngier authored
As the GICv3 virtual interface registers differ from their GICv2 siblings, we need different handlers for processing maintenance interrupts and reading/writing to the LRs. Implement the respective handler functions and connect them to existing code to be called if the host is using a GICv3. Signed-off-by:
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