src/ffa/spmc/interrupts.c

/*
 * Copyright 2024 The Hafnium Authors.
 *
 * Use of this source code is governed by a BSD-style
 * license that can be found in the LICENSE file or at
 * https://opensource.org/licenses/BSD-3-Clause.
 */

#include "hf/plat/interrupts.h"

#include "hf/arch/gicv3.h"
#include "hf/arch/host_timer.h"

#include "hf/api.h"
#include "hf/check.h"
#include "hf/ffa/direct_messaging.h"
#include "hf/ffa/notifications.h"
#include "hf/ffa/vm.h"
#include "hf/hf_ipi.h"
#include "hf/vm.h"

/**
 * This function has been deprecated and it's contents moved into
 * api_interrupt_get in order to align the bitmap and queue for tracking
 * interupts.
 * Returns 0 on success, or -1 otherwise.
 */
int64_t ffa_interrupts_deactivate(uint32_t pint_id, uint32_t vint_id,
				  struct vcpu *current)
{
	(void)pint_id;
	(void)vint_id;
	(void)current;
	return 0;
}

static struct vcpu *ffa_interrupts_find_target_vcpu_secure_interrupt(
	struct vcpu *current, uint32_t interrupt_id)
{
	/*
	 * Find which VM/SP owns this interrupt. We then find the
	 * corresponding vCPU context for this CPU.
	 */
	for (ffa_vm_count_t index = 0; index < vm_get_count(); ++index) {
		struct vm *vm = vm_find_index(index);

		for (uint32_t j = 0; j < VM_MANIFEST_MAX_INTERRUPTS; j++) {
			struct interrupt_descriptor int_desc =
				vm->interrupt_desc[j];

			/*
			 * Interrupt descriptors are populated
			 * contiguously.
			 */
			if (!int_desc.valid) {
				break;
			}
			if (int_desc.interrupt_id == interrupt_id) {
				return api_ffa_get_vm_vcpu(vm, current);
			}
		}
	}

	return NULL;
}

static struct vcpu *ffa_interrupts_find_target_vcpu(struct vcpu *current,
						    uint32_t interrupt_id,
						    uint32_t *v_intid)
{
	struct vcpu *target_vcpu;

	assert(current != NULL);
	assert(v_intid != NULL);

	*v_intid = interrupt_id;

	switch (interrupt_id) {
	case SPURIOUS_INTID_OTHER_WORLD:
		/*
		 * Spurious interrupt ID indicating that there are no pending
		 * interrupts to acknowledge. For such scenarios, resume the
		 * current vCPU.
		 */
		target_vcpu = NULL;
		break;
	case HF_IPI_INTID:
		/*
		 * Get the next vCPU with a pending IPI. If all vCPUs
		 * have had their IPIs handled this will return NULL.
		 */
		target_vcpu = hf_ipi_get_pending_target_vcpu(current);
		break;
	case ARM_SEL2_TIMER_PHYS_INT:
		/* Disable the S-EL2 physical timer */
		host_timer_disable();
		target_vcpu = timer_find_target_vcpu(current);

		if (target_vcpu != NULL) {
			*v_intid = HF_VIRTUAL_TIMER_INTID;
		}
		/*
		 * It is possible for target_vcpu to be NULL in case of spurious
		 * timer interrupt.
		 */
		break;
	case ARM_EL1_VIRT_TIMER_PHYS_INT:
		/* Fall through */
	case ARM_EL1_PHYS_TIMER_PHYS_INT:
		panic("Timer interrupt not expected to fire: %u\n",
		      interrupt_id);
	default:
		target_vcpu = ffa_interrupts_find_target_vcpu_secure_interrupt(
			current, interrupt_id);

		/* The target vCPU for a secure interrupt cannot be NULL. */
		CHECK(target_vcpu != NULL);
	}

	return target_vcpu;
}

/*
 * If the current vCPU is being preempted, record this in the target vCPU
 * and set the current states to VCPU_STATE_PREEMPTED.
 */
static void ffa_interrupts_set_preempted_vcpu(
	struct vcpu_locked target_vcpu_locked,
	struct vcpu_locked current_locked)
{
	struct vcpu *target_vcpu = target_vcpu_locked.vcpu;
	struct vcpu *preempted_vcpu = current_locked.vcpu;

	assert(target_vcpu != NULL);
	assert(preempted_vcpu != NULL);

	target_vcpu->preempted_vcpu = preempted_vcpu;
	preempted_vcpu->state = VCPU_STATE_PREEMPTED;
}

/**
 * If the interrupts were indeed masked by SPMC before an SP's vCPU was resumed,
 * restore the priority mask thereby allowing the interrupts to be delivered.
 */
void ffa_interrupts_unmask(struct vcpu *current)
{
	plat_interrupts_set_priority_mask(current->prev_interrupt_priority);
}

/**
 * Enforce action of an SP in response to non-secure or other-secure interrupt
 * by changing the priority mask. Effectively, physical interrupts shall not
 * trigger which has the same effect as queueing interrupts.
 */
void ffa_interrupts_mask(struct vcpu_locked receiver_vcpu_locked)
{
	struct vcpu *receiver_vcpu = receiver_vcpu_locked.vcpu;
	uint8_t current_priority;

	/* Save current value of priority mask. */
	current_priority = plat_interrupts_get_priority_mask();
	receiver_vcpu->prev_interrupt_priority = current_priority;

	if (receiver_vcpu->vm->other_s_interrupts_action ==
		    OTHER_S_INT_ACTION_QUEUED ||
	    receiver_vcpu->scheduling_mode == SPMC_MODE) {
		/*
		 * If secure interrupts not masked yet, mask them now. We could
		 * enter SPMC scheduled mode when an EL3 SPMD Logical partition
		 * sends a direct request, and we are making the IMPDEF choice
		 * to mask interrupts when such a situation occurs. This keeps
		 * design simple.
		 */
		if (current_priority > SWD_MASK_ALL_INT) {
			plat_interrupts_set_priority_mask(SWD_MASK_ALL_INT);
		}
	} else if (receiver_vcpu->vm->ns_interrupts_action ==
		   NS_ACTION_QUEUED) {
		/* If non secure interrupts not masked yet, mask them now. */
		if (current_priority > SWD_MASK_NS_INT) {
			plat_interrupts_set_priority_mask(SWD_MASK_NS_INT);
		}
	}
}

/**
 * Change the state of both current vCPU and the target vCPU.
 * For S-EL0 partitions it will pop from the queue and write to the vCPU
 * the return FFA_INTERRUPT(virtual interrupt).
 * For S-EL1 partitions, it peeks to the queue to get the next interrupt
 * ID, so it can be included in the return. Partition should still call
 * `hf_interrupt_get()`.
 *
 * If `interrupt_return` is passed as NULL, the function will write to
 * partition context.
 * Otherwise, it will be used to return the ffa_value with the FFA_INTERRUPT
 * ABI.
 *
 * Returns the injected virtual interrupt ID.
 */
static uint32_t interrupt_resume_waiting(struct vcpu_locked current_locked,
					 struct vcpu_locked target_vcpu_locked)
{
	struct vcpu *target_vcpu = target_vcpu_locked.vcpu;
	/*
	 * Since S-EL0 partitions will not receive the interrupt through a vIRQ
	 * signal in addition to the FFA_INTERRUPT ERET, make the interrupt no
	 * longer pending at this point. Otherwise keep it as pending for
	 * when the S-EL1 parition calls hf_interrupt_get.
	 */
	uint32_t pending_intid =
		target_vcpu_locked.vcpu->vm->el0_partition
			? vcpu_virt_interrupt_get_pending_and_enabled(
				  target_vcpu_locked)
			: vcpu_virt_interrupt_peek_pending_and_enabled(
				  target_vcpu_locked);

	/* FF-A v1.1 EAC0 Table 8.2 case 1 and Table 12.10. */
	vcpu_enter_secure_interrupt_rtm(target_vcpu_locked);
	ffa_interrupts_mask(target_vcpu_locked);
	ffa_interrupts_set_preempted_vcpu(target_vcpu_locked, current_locked);

	if (target_vcpu->cpu != current_locked.vcpu->cpu) {
		/*
		 * The target vcpu could have migrated to a different
		 * physical CPU. SPMC will migrate it to current
		 * physical CPU and resume it.
		 */
		assert(target_vcpu->vm->vcpu_count == 1);
		target_vcpu->cpu = current_locked.vcpu->cpu;
	}

	return pending_intid;
}

/**
 * Handles the secure interrupt according to the target vCPU's state.
 * Returns the next vCPU to resume accordingly.
 * If it returns NULL, the current vCPU shall be resumed.
 * This might be if the target vCPU is the current vCPU, or if the
 * target vCPU is not in a state in which it can be resumed to handle
 * the secure interrupt.
 */
static struct vcpu *ffa_interrupts_signal_secure_interrupt(
	struct vcpu_locked current_locked,
	struct vcpu_locked target_vcpu_locked, uint32_t v_intid)
{
	struct vcpu *target_vcpu = target_vcpu_locked.vcpu;
	struct vcpu *current = current_locked.vcpu;
	struct vcpu *next = NULL;

	/*
	 * The target vcpu has migrated to a different physical
	 * CPU. Hence, it cannot be resumed on this CPU, SPMC
	 * resumes current vCPU.
	 */
	if (target_vcpu->cpu != current_locked.vcpu->cpu) {
		assert(target_vcpu->vm->vcpu_count == 1);
	}

	/* Secure interrupt signaling and queuing for SP. */
	switch (target_vcpu->state) {
	case VCPU_STATE_WAITING:
		if (!target_vcpu->vm->sri_policy.intr_while_waiting) {
			uint32_t inject_int_id = interrupt_resume_waiting(
				current_locked, target_vcpu_locked);
			struct ffa_value int_ret =
				api_ffa_interrupt_return(inject_int_id);

			if (inject_int_id != 0) {
				assert(v_intid == inject_int_id);
			}

			next = target_vcpu;

			vcpu_set_running(target_vcpu_locked, &int_ret);
		} else {
			dlog_verbose(
				"%s: SP is waiting, SRI delayed due to "
				"interrupt. Partition %x, vcpu %x, interrupt "
				"%x\n",
				__func__, target_vcpu->vm->id,
				vcpu_index(target_vcpu), v_intid);
			ffa_notifications_sri_set_delayed(target_vcpu->cpu);
		}
		break;
	case VCPU_STATE_BLOCKED:
		if (!target_vcpu->vm->el0_partition &&
		    target_vcpu->cpu == current_locked.vcpu->cpu &&
		    ffa_direct_msg_precedes_in_call_chain(current_locked,
							  target_vcpu_locked)) {
			struct ffa_value ret_interrupt =
				api_ffa_interrupt_return(0);

			/*
			 * If the target vCPU ran earlier in the same call
			 * chain as the current vCPU, SPMC leaves all
			 * intermediate execution contexts in blocked state and
			 * resumes the target vCPU for handling secure
			 * interrupt.
			 * Under the current design, there is only one possible
			 * scenario in which this could happen: both the
			 * preempted (i.e. current) and target vCPU are in the
			 * same NWd scheduled call chain and is described in the
			 * Scenario 1 of Table 8.4 in EAC0 spec.
			 */
			assert(current_locked.vcpu->scheduling_mode ==
			       NWD_MODE);
			assert(target_vcpu->scheduling_mode == NWD_MODE);

			/*
			 * The execution preempted the call chain that involved
			 * the targeted and the current SPs.
			 * The targetted SP is set running, whilst the
			 * preempted SP is set PREEMPTED.
			 */
			vcpu_set_running(target_vcpu_locked, &ret_interrupt);

			ffa_interrupts_set_preempted_vcpu(target_vcpu_locked,
							  current_locked);
			next = target_vcpu;
			break;
		}

		/*
		 * `next` is NULL.
		 * Either:
		 * - EL0 paritition can't be resumed when in blocked state.
		 * - The target vCPU has migrated to a different
		 * physical CPU. Hence, it cannot be resumed on this
		 * CPU, SPMC resumes current vCPU.
		 * - The target vCPU cannot be resumed now because it is
		 * in BLOCKED state (it yielded CPU cycles using
		 * FFA_YIELD). SPMC queues the virtual interrupt and
		 * resumes the current vCPU which could belong to either
		 * a VM or a SP.
		 */
		break;
	case VCPU_STATE_PREEMPTED:
		/*
		 * We do not resume a target vCPU that has been already
		 * pre-empted by an interrupt. Make the vIRQ pending for
		 * target SP(i.e., queue the interrupt) and continue to
		 * resume current vCPU. Refer to section 8.3.2.1 bullet
		 * 3 in the FF-A v1.1 EAC0 spec.
		 */
		if (!target_vcpu->vm->el0_partition &&
		    target_vcpu->cpu == current_locked.vcpu->cpu &&
		    current->vm->id == HF_OTHER_WORLD_ID) {
			/*
			 * The target vCPU must have been preempted by a
			 * non secure interrupt. It could not have been
			 * preempted by a secure interrupt as current
			 * SPMC implementation does not allow secure
			 * interrupt prioritization. Moreover, the
			 * target vCPU should have been in Normal World
			 * scheduled mode as SPMC scheduled mode call
			 * chain cannot be preempted by a non secure
			 * interrupt.
			 */
			CHECK(target_vcpu->scheduling_mode == NWD_MODE);
		}
		break;
	case VCPU_STATE_RUNNING:
		/*
		 * Interrupt has been injected in the vCPU state.
		 */
		break;
	case VCPU_STATE_BLOCKED_INTERRUPT:
		/* WFI is no-op for SP. Fall through. */
	default:
		/*
		 * vCPU of Target SP cannot be in OFF/ABORTED state if it has
		 * to handle secure interrupt.
		 */
		panic("Secure interrupt cannot be signaled to target SP\n");
		break;
	}

	return next;
}

/**
 * Obtain the physical interrupt that triggered from the interrupt controller,
 * and inject the corresponding virtual interrupt to the target vCPU.
 * When PEs executing in the Normal World, and secure interrupts trigger,
 * execution is trapped into EL3. SPMD then routes the interrupt to SPMC
 * through FFA_INTERRUPT_32 ABI synchronously using eret conduit.
 */
void ffa_interrupts_handle_secure_interrupt(struct vcpu *current,
					    struct vcpu **next)
{
	struct vcpu *target_vcpu;
	struct vcpu_locked target_vcpu_locked =
		(struct vcpu_locked){.vcpu = NULL};
	struct vcpu_locked current_locked;
	uint32_t intid;
	struct vm_locked target_vm_locked;
	uint32_t v_intid;

	/* Find pending interrupt id. This also activates the interrupt. */
	intid = plat_interrupts_get_pending_interrupt_id();
	v_intid = intid;

	/* Get the target vCPU and get the virtual interrupt ID. */
	target_vcpu = ffa_interrupts_find_target_vcpu(current, intid, &v_intid);

	/*
	 * Spurious interrupt ID indicates there is no pending interrupt to
	 * acknowledge so we do not need to call end of interrupt.
	 */
	if (v_intid != SPURIOUS_INTID_OTHER_WORLD) {
		/*
		 * End the interrupt to drop the running priority. It also
		 * deactivates the physical interrupt. If not, the interrupt
		 * could trigger again after resuming current vCPU.
		 */
		plat_interrupts_end_of_interrupt(intid);
	}

	if (target_vcpu == NULL) {
		/* No further handling required. Resume the current vCPU. */
		*next = NULL;
		return;
	}

	target_vm_locked = vm_lock(target_vcpu->vm);

	if (target_vcpu == current) {
		current_locked = vcpu_lock(current);
		target_vcpu_locked = current_locked;
	} else {
		struct two_vcpu_locked vcpus_locked;
		/* Lock both vCPUs at once to avoid deadlock. */
		vcpus_locked = vcpu_lock_both(current, target_vcpu);
		current_locked = vcpus_locked.vcpu1;
		target_vcpu_locked = vcpus_locked.vcpu2;
	}

	/*
	 * A race condition can occur with the execution contexts belonging to
	 * an MP SP. An interrupt targeting the execution context on present
	 * core can trigger while the execution context of this SP on a
	 * different core is being aborted. In such scenario, the physical
	 * interrupts beloning to the aborted SP are disabled and the current
	 * execution context is resumed.
	 */
	if (target_vcpu->state == VCPU_STATE_ABORTED ||
	    atomic_load_explicit(&target_vcpu->vm->aborting,
				 memory_order_relaxed)) {
		/* Clear fields corresponding to secure interrupt handling. */
		vcpu_secure_interrupt_complete(target_vcpu_locked);
		ffa_vm_disable_interrupts(target_vm_locked);

		/* Resume current vCPU. */
		*next = NULL;
	} else {
		/* Set the interrupt pending in the target vCPU. */
		vcpu_virt_interrupt_inject(target_vcpu_locked, v_intid);

		switch (intid) {
		case HF_IPI_INTID:
			if (hf_ipi_handle(target_vcpu_locked)) {
				*next = NULL;
				break;
			}
			/*
			 * Fall through in the case handling has not been fully
			 * completed.
			 */
		default:
			/*
			 * Either invoke the handler related to partitions from
			 * S-EL0 or from S-EL1.
			 */
			*next = ffa_interrupts_signal_secure_interrupt(
				current_locked, target_vcpu_locked, v_intid);
		}
	}

	if (target_vcpu_locked.vcpu != NULL) {
		vcpu_unlock(&target_vcpu_locked);
	}

	vcpu_unlock(&current_locked);
	vm_unlock(&target_vm_locked);
}

bool ffa_interrupts_inject_notification_pending_interrupt(
	struct vcpu_locked target_locked, struct vm_locked receiver_locked)
{
	struct vm *next_vm = target_locked.vcpu->vm;
	bool ret = false;

	/*
	 * Inject the NPI if:
	 * - The targeted VM ID is from this world (i.e. if it is an SP).
	 * - The partition has global pending notifications or there are
	 *   pending per-vCPU notifications in the next vCPU.
	 */
	if (vm_id_is_current_world(next_vm->id) &&
	    (vm_are_per_vcpu_notifications_pending(
		     receiver_locked, vcpu_index(target_locked.vcpu)) ||
	     vm_are_global_notifications_pending(receiver_locked))) {
		vcpu_virt_interrupt_inject(target_locked,
					   HF_NOTIFICATION_PENDING_INTID);
		ret = true;
	}

	return ret;
}

struct vcpu *ffa_interrupts_unwind_nwd_call_chain(struct vcpu *current_vcpu)
{
	struct vcpu *next;
	struct two_vcpu_locked both_vcpu_locked;

	/*
	 * The action specified by SP in its manifest is ``Non-secure interrupt
	 * is signaled``. Refer to section 8.2.4 rules and guidelines bullet 4.
	 * Hence, the call chain starts unwinding. The current vCPU must have
	 * been a part of NWd scheduled call chain. Therefore, it is pre-empted
	 * and execution is either handed back to the normal world or to the
	 * previous SP vCPU in the call chain through the FFA_INTERRUPT ABI.
	 * The api_preempt() call is equivalent to calling
	 * api_switch_to_other_world for current vCPU passing FFA_INTERRUPT. The
	 * SP can be resumed later by FFA_RUN.
	 */
	CHECK(current_vcpu->scheduling_mode == NWD_MODE);
	assert(current_vcpu->call_chain.next_node == NULL);

	if (current_vcpu->call_chain.prev_node == NULL) {
		/* End of NWd scheduled call chain */
		return api_preempt(current_vcpu);
	}

	next = current_vcpu->call_chain.prev_node;
	CHECK(next != NULL);

	/*
	 * Lock both vCPUs. Strictly speaking, it may not be necessary since
	 * next is guaranteed to be in BLOCKED state as it is the predecessor of
	 * the current vCPU in the present call chain.
	 */
	both_vcpu_locked = vcpu_lock_both(current_vcpu, next);

	/* Removing a node from an existing call chain. */
	current_vcpu->call_chain.prev_node = NULL;
	current_vcpu->state = VCPU_STATE_PREEMPTED;

	/*
	 * SPMC applies the runtime model till when the vCPU transitions from
	 * running to waiting state. Moreover, the SP continues to remain in
	 * its CPU cycle allocation mode. Hence, rt_model and scheduling_mode
	 * are not changed here.
	 */
	assert(next->state == VCPU_STATE_BLOCKED);
	assert(next->call_chain.next_node == current_vcpu);

	next->call_chain.next_node = NULL;

	vcpu_set_running(both_vcpu_locked.vcpu2,
			 &(struct ffa_value){
				 .func = FFA_INTERRUPT_32,
				 .arg1 = ffa_vm_vcpu(current_vcpu->vm->id,
						     vcpu_index(current_vcpu)),
			 });

	sl_unlock(&next->lock);
	sl_unlock(&current_vcpu->lock);

	return next;
}

static void ffa_interrupts_enable_virtual_maintenance_interrupts(
	struct vcpu_locked current_locked)
{
	struct vcpu *current;
	struct interrupts *interrupts;
	struct vm *vm;

	current = current_locked.vcpu;
	interrupts = &current->interrupts;
	vm = current->vm;

	if (ffa_vm_managed_exit_supported(vm)) {
		vcpu_virt_interrupt_enable(current_locked,
					   HF_MANAGED_EXIT_INTID, true);
		/*
		 * SPMC decides the interrupt type for Managed exit signal based
		 * on the partition manifest.
		 */
		if (vm->me_signal_virq) {
			vcpu_virt_interrupt_set_type(interrupts,
						     HF_MANAGED_EXIT_INTID,
						     INTERRUPT_TYPE_IRQ);
		} else {
			vcpu_virt_interrupt_set_type(interrupts,
						     HF_MANAGED_EXIT_INTID,
						     INTERRUPT_TYPE_FIQ);
		}
	}

	if (vm->notifications.enabled) {
		vcpu_virt_interrupt_enable(current_locked,
					   HF_NOTIFICATION_PENDING_INTID, true);
	}
}

/**
 * Enable relevant virtual interrupts for Secure Partitions.
 * For all SPs, any applicable virtual maintenance interrupts are enabled.
 * Additionally, for S-EL0 partitions, all the interrupts declared in the
 * partition manifest are enabled at the virtual interrupt controller
 * interface early during the boot stage as an S-EL0 SP need not call
 * HF_INTERRUPT_ENABLE hypervisor ABI explicitly.
 */
void ffa_interrupts_enable_virtual_interrupts(struct vcpu_locked current_locked,
					      struct vm_locked vm_locked)
{
	struct vcpu *current;
	struct vm *vm;

	current = current_locked.vcpu;
	vm = current->vm;
	assert(vm == vm_locked.vm);

	if (vm->el0_partition) {
		for (uint32_t k = 0; k < VM_MANIFEST_MAX_INTERRUPTS; k++) {
			struct interrupt_descriptor int_desc;

			int_desc = vm_locked.vm->interrupt_desc[k];

			/* Interrupt descriptors are populated contiguously. */
			if (!int_desc.valid) {
				break;
			}
			vcpu_virt_interrupt_enable(current_locked,
						   int_desc.interrupt_id, true);
		}
	}

	ffa_interrupts_enable_virtual_maintenance_interrupts(current_locked);
}

/**
 * Reconfigure the interrupt belonging to the current partition at runtime.
 * At present, this paravirtualized interface only allows the following
 * commands which signify what change is being requested by the current
 * partition:
 * - Change the target CPU of the interrupt.
 * - Change the security state of the interrupt.
 * - Enable or disable the physical interrupt.
 */
int64_t ffa_interrupts_reconfigure(uint32_t int_id, uint32_t command,
				   uint32_t value, struct vcpu *current)
{
	struct vm *vm = current->vm;
	struct vm_locked vm_locked;
	int64_t ret = -1;
	struct interrupt_descriptor *int_desc = NULL;

	/*
	 * Lock VM to protect interrupt descriptor from being modified
	 * concurrently.
	 */
	vm_locked = vm_lock(vm);

	switch (command) {
	case INT_RECONFIGURE_TARGET_PE:
		/* Here, value represents the target PE index. */
		if (value >= MAX_CPUS) {
			dlog_verbose(
				"Illegal target PE index specified while "
				"reconfiguring interrupt %x\n",
				int_id);
			goto out_unlock;
		}

		/*
		 * An UP SP cannot reconfigure an interrupt to be targetted to
		 * any other physical CPU except the one it is currently
		 * running on.
		 */
		if (vm_is_up(vm) && value != cpu_index(current->cpu)) {
			dlog_verbose(
				"Illegal target PE index specified by current "
				"UP SP\n");
			goto out_unlock;
		}

		/* Configure the interrupt to be routed to a specific CPU. */
		int_desc = vm_interrupt_set_target_mpidr(
			vm_locked, int_id, cpu_find_index(value)->id);
		break;
	case INT_RECONFIGURE_SEC_STATE:
		/* Specify the new security state of the interrupt. */
		if (value != INT_DESC_SEC_STATE_NS &&
		    value != INT_DESC_SEC_STATE_S) {
			dlog_verbose(
				"Illegal value %x specified while "
				"reconfiguring interrupt %x\n",
				value, int_id);
			goto out_unlock;
		}
		int_desc = vm_interrupt_set_sec_state(vm_locked, int_id, value);
		break;
	case INT_RECONFIGURE_ENABLE:
		/* Enable or disable the interrupt. */
		if (value != INT_DISABLE && value != INT_ENABLE) {
			dlog_verbose(
				"Illegal value %x specified while "
				"reconfiguring interrupt %x\n",
				value, int_id);
			goto out_unlock;
		} else {
			int_desc = vm_interrupt_set_enable(vm_locked, int_id,
							   value == INT_ENABLE);
		}
		break;
	default:
		dlog_verbose("Interrupt reconfigure: Unsupported command %x\n",
			     command);
		goto out_unlock;
	}

	/* Check if the interrupt belongs to the current SP. */
	if (int_desc == NULL) {
		dlog_verbose("Interrupt %x does not belong to current SP\n",
			     int_id);
		goto out_unlock;
	}

	ret = 0;
	plat_interrupts_reconfigure_interrupt(*int_desc);

out_unlock:
	vm_unlock(&vm_locked);

	return ret;
}

bool ffa_interrupts_intercept_call(struct vcpu_locked current_locked,
				   struct vcpu_locked next_locked,
				   struct ffa_value *interrupt_ret)
{
	uint32_t intid;
	struct vm *current_vm = current_locked.vcpu->vm;

	/* No pending interrupts, no need to intercept or trigger SRI. */
	if (vcpu_virt_interrupt_count_get(current_locked) == 0U) {
		return false;
	}

	/*
	 * Do not intercept the call.
	 * Let the partition go into waiting state as planned.
	 * Pend the SRI on the next world switch to the NWd.
	 */
	if (current_vm->sri_policy.intr_pending_entry_wait) {
		dlog_verbose(
			"Partition entry to wait. Interrupts pending. Send "
			"SRI.\n");
		ffa_notifications_sri_set_delayed(current_locked.vcpu->cpu);
		return false;
	}

	/**
	 * At this point the handling of ABIs which can be intercepted by
	 * 'ffa_interrupts_intercept_call' did all the partition/vCPU state
	 * changes assuming there were no interrupts pending, and the call
	 * wouldn't be preempted.
	 * So it helps to think the current partition/vCPU have changed.
	 * If the call is intercepted, the current partition is left in
	 * preempted state, and execution is given to the target of the
	 * interrupt. In the arguments to interrupt_resume_waiting, pass
	 * "next_locked" and "current_locked" in the arguments for current and
	 * next vCPU, respectively. This is according to the description
	 * above.
	 */
	intid = interrupt_resume_waiting(next_locked, current_locked);

	assert(interrupt_ret != NULL);

	dlog_verbose("%s: Pending interrupt %d, intercepting FF-A call.\n",
		     __func__, intid);

	*interrupt_ret = api_ffa_interrupt_return(intid);

	vcpu_set_running(current_locked, NULL);

	return true;
}