src/arch/aarch64/hypervisor/handler.c

/*
 * Copyright 2018 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 <stdnoreturn.h>

#include "hf/arch/barriers.h"
#include "hf/arch/init.h"
#include "hf/arch/mmu.h"
#include "hf/arch/other_world.h"
#include "hf/arch/plat/smc.h"

#include "hf/api.h"
#include "hf/check.h"
#include "hf/cpu.h"
#include "hf/dlog.h"
#include "hf/ffa.h"
#include "hf/ffa_internal.h"
#include "hf/panic.h"
#include "hf/vm.h"

#include "vmapi/hf/call.h"

#include "debug_el1.h"
#include "feature_id.h"
#include "msr.h"
#include "perfmon.h"
#include "psci.h"
#include "psci_handler.h"
#include "smc.h"
#include "sysregs.h"

/**
 * Hypervisor Fault Address Register Non-Secure.
 */
#define HPFAR_EL2_NS (UINT64_C(0x1) << 63)

/**
 * Hypervisor Fault Address Register Faulting IPA.
 */
#define HPFAR_EL2_FIPA (UINT64_C(0xFFFFFFFFFF0))

/**
 * Gets the value to increment for the next PC.
 * The ESR encodes whether the instruction is 2 bytes or 4 bytes long.
 */
#define GET_NEXT_PC_INC(esr) (GET_ESR_IL(esr) ? 4 : 2)

/**
 * The Client ID field within X7 for an SMC64 call.
 */
#define CLIENT_ID_MASK UINT64_C(0xffff)

/**
 * Returns a reference to the currently executing vCPU.
 */
static struct vcpu *current(void)
{
	return (struct vcpu *)read_msr(tpidr_el2);
}

/**
 * Saves the state of per-vCPU peripherals, such as the virtual timer, and
 * informs the arch-independent sections that registers have been saved.
 */
void complete_saving_state(struct vcpu *vcpu)
{
	vcpu->regs.peripherals.cntv_cval_el0 = read_msr(cntv_cval_el0);
	vcpu->regs.peripherals.cntv_ctl_el0 = read_msr(cntv_ctl_el0);

	api_regs_state_saved(vcpu);

	/*
	 * If switching away from the primary, copy the current EL0 virtual
	 * timer registers to the corresponding EL2 physical timer registers.
	 * This is used to emulate the virtual timer for the primary in case it
	 * should fire while the secondary is running.
	 */
	if (vcpu->vm->id == HF_PRIMARY_VM_ID) {
		/*
		 * Clear timer control register before copying compare value, to
		 * avoid a spurious timer interrupt. This could be a problem if
		 * the interrupt is configured as edge-triggered, as it would
		 * then be latched in.
		 */
		write_msr(cnthp_ctl_el2, 0);
		write_msr(cnthp_cval_el2, read_msr(cntv_cval_el0));
		write_msr(cnthp_ctl_el2, read_msr(cntv_ctl_el0));
	}
}

/**
 * Restores the state of per-vCPU peripherals, such as the virtual timer.
 */
void begin_restoring_state(struct vcpu *vcpu)
{
	/*
	 * Clear timer control register before restoring compare value, to avoid
	 * a spurious timer interrupt. This could be a problem if the interrupt
	 * is configured as edge-triggered, as it would then be latched in.
	 */
	write_msr(cntv_ctl_el0, 0);
	write_msr(cntv_cval_el0, vcpu->regs.peripherals.cntv_cval_el0);
	write_msr(cntv_ctl_el0, vcpu->regs.peripherals.cntv_ctl_el0);

	/*
	 * If we are switching (back) to the primary, disable the EL2 physical
	 * timer which was being used to emulate the EL0 virtual timer, as the
	 * virtual timer is now running for the primary again.
	 */
	if (vcpu->vm->id == HF_PRIMARY_VM_ID) {
		write_msr(cnthp_ctl_el2, 0);
		write_msr(cnthp_cval_el2, 0);
	}
}

/**
 * Invalidate all stage 1 TLB entries on the current (physical) CPU for the
 * current VMID.
 */
static void invalidate_vm_tlb(void)
{
	/*
	 * Ensure that the last VTTBR write has taken effect so we invalidate
	 * the right set of TLB entries.
	 */
	isb();

	__asm__ volatile("tlbi vmalle1");

	/*
	 * Ensure that no instructions are fetched for the VM until after the
	 * TLB invalidation has taken effect.
	 */
	isb();

	/*
	 * Ensure that no data reads or writes for the VM happen until after the
	 * TLB invalidation has taken effect. Non-shareable is enough because
	 * the TLB is local to the CPU.
	 */
	dsb(nsh);
}

/**
 * Invalidates the TLB if a different vCPU is being run than the last vCPU of
 * the same VM which was run on the current pCPU.
 *
 * This is necessary because VMs may (contrary to the architecture
 * specification) use inconsistent ASIDs across vCPUs. c.f. KVM's similar
 * workaround:
 * https://git.kernel.org/pub/scm/linux/kernel/git/torvalds/linux.git/commit/?id=94d0e5980d6791b9
 */
void maybe_invalidate_tlb(struct vcpu *vcpu)
{
	size_t current_cpu_index = cpu_index(vcpu->cpu);
	ffa_vcpu_index_t new_vcpu_index = vcpu_index(vcpu);

	if (vcpu->vm->arch.last_vcpu_on_cpu[current_cpu_index] !=
	    new_vcpu_index) {
		/*
		 * The vCPU has changed since the last time this VM was run on
		 * this pCPU, so we need to invalidate the TLB.
		 */
		invalidate_vm_tlb();

		/* Record the fact that this vCPU is now running on this CPU. */
		vcpu->vm->arch.last_vcpu_on_cpu[current_cpu_index] =
			new_vcpu_index;
	}
}

noreturn void irq_current_exception_noreturn(uintreg_t elr, uintreg_t spsr)
{
	(void)elr;
	(void)spsr;

	panic("IRQ from current exception level.");
}

noreturn void fiq_current_exception_noreturn(uintreg_t elr, uintreg_t spsr)
{
	(void)elr;
	(void)spsr;

	panic("FIQ from current exception level.");
}

noreturn void serr_current_exception_noreturn(uintreg_t elr, uintreg_t spsr)
{
	(void)elr;
	(void)spsr;

	panic("SError from current exception level.");
}

noreturn void sync_current_exception_noreturn(uintreg_t elr, uintreg_t spsr)
{
	uintreg_t esr = read_msr(esr_el2);
	uintreg_t ec = GET_ESR_EC(esr);

	(void)spsr;

	switch (ec) {
	case EC_DATA_ABORT_SAME_EL:
		if (!(esr & (1U << 10))) { /* Check FnV bit. */
			dlog_error(
				"Data abort: pc=%#x, esr=%#x, ec=%#x, "
				"far=%#x\n",
				elr, esr, ec, read_msr(far_el2));
		} else {
			dlog_error(
				"Data abort: pc=%#x, esr=%#x, ec=%#x, "
				"far=invalid\n",
				elr, esr, ec);
		}

		break;

	default:
		dlog_error(
			"Unknown current sync exception pc=%#x, esr=%#x, "
			"ec=%#x\n",
			elr, esr, ec);
		break;
	}

	panic("EL2 exception");
}

/**
 * Sets or clears the VI bit in the HCR_EL2 register saved in the given
 * arch_regs.
 */
static void set_virtual_interrupt(struct arch_regs *r, bool enable)
{
	if (enable) {
		r->lazy.hcr_el2 |= HCR_EL2_VI;
	} else {
		r->lazy.hcr_el2 &= ~HCR_EL2_VI;
	}
}

/**
 * Sets or clears the VI bit in the HCR_EL2 register.
 */
static void set_virtual_interrupt_current(bool enable)
{
	uintreg_t hcr_el2 = read_msr(hcr_el2);

	if (enable) {
		hcr_el2 |= HCR_EL2_VI;
	} else {
		hcr_el2 &= ~HCR_EL2_VI;
	}
	write_msr(hcr_el2, hcr_el2);
}

#if SECURE_WORLD == 1
static bool sp_boot_next(struct vcpu *current, struct vcpu **next,
			 struct ffa_value *ffa_ret)
{
	struct vm_locked current_vm_locked;
	struct vm *vm_next = NULL;
	bool ret = false;

	/*
	 * If VM hasn't been initialized, initialize it and traverse
	 * booting list following "next_boot" field in the VM structure.
	 * Once all the SPs have been booted (when "next_boot" is NULL),
	 * return execution to the NWd.
	 */
	current_vm_locked = vm_lock(current->vm);
	if (current_vm_locked.vm->initialized == false) {
		current_vm_locked.vm->initialized = true;
		dlog_verbose("Initialized VM: %#x, boot_order: %u\n",
			     current_vm_locked.vm->id,
			     current_vm_locked.vm->boot_order);

		if (current_vm_locked.vm->next_boot != NULL) {
			current->state = VCPU_STATE_BLOCKED_MAILBOX;
			vm_next = current_vm_locked.vm->next_boot;
			CHECK(vm_next->initialized == false);
			*next = vm_get_vcpu(vm_next, vcpu_index(current));
			arch_regs_reset(*next);
			(*next)->cpu = current->cpu;
			(*next)->state = VCPU_STATE_RUNNING;
			(*next)->regs_available = false;

			*ffa_ret = (struct ffa_value){.func = FFA_INTERRUPT_32};
			ret = true;
			goto out;
		}

		dlog_verbose("Finished initializing all VMs.\n");
	}

out:
	vm_unlock(&current_vm_locked);
	return ret;
}
#endif

/**
 * Checks whether to block an SMC being forwarded from a VM.
 */
static bool smc_is_blocked(const struct vm *vm, uint32_t func)
{
	bool block_by_default = !vm->smc_whitelist.permissive;

	for (size_t i = 0; i < vm->smc_whitelist.smc_count; ++i) {
		if (func == vm->smc_whitelist.smcs[i]) {
			return false;
		}
	}

	dlog_notice("SMC %#010x attempted from VM %d, blocked=%d\n", func,
		    vm->id, block_by_default);

	/* Access is still allowed in permissive mode. */
	return block_by_default;
}

/**
 * Applies SMC access control according to manifest and forwards the call if
 * access is granted.
 */
static void smc_forwarder(const struct vm *vm, struct ffa_value *args)
{
	struct ffa_value ret;
	uint32_t client_id = vm->id;
	uintreg_t arg7 = args->arg7;

	if (smc_is_blocked(vm, args->func)) {
		args->func = SMCCC_ERROR_UNKNOWN;
		return;
	}

	/*
	 * Set the Client ID but keep the existing Secure OS ID and anything
	 * else (currently unspecified) that the client may have passed in the
	 * upper bits.
	 */
	args->arg7 = client_id | (arg7 & ~CLIENT_ID_MASK);
	ret = smc_forward(args->func, args->arg1, args->arg2, args->arg3,
			  args->arg4, args->arg5, args->arg6, args->arg7);

	/*
	 * Preserve the value passed by the caller, rather than the generated
	 * client_id. Note that this would also overwrite any return value that
	 * may be in x7, but the SMCs that we are forwarding are legacy calls
	 * from before SMCCC 1.2 so won't have more than 4 return values anyway.
	 */
	ret.arg7 = arg7;

	plat_smc_post_forward(*args, &ret);

	*args = ret;
}

/**
 * In the normal world, ffa_handler is always called from the virtual FF-A
 * instance (from a VM in EL1). In the secure world, ffa_handler may be called
 * from the virtual (a secure partition in S-EL1) or physical FF-A instance
 * (from the normal world via EL3). The function returns true when the call is
 * handled. The *next pointer is updated to the next vCPU to run, which might be
 * the 'other world' vCPU if the call originated from the virtual FF-A instance
 * and has to be forwarded down to EL3, or left as is to resume the current
 * vCPU.
 */
static bool ffa_handler(struct ffa_value *args, struct vcpu *current,
			struct vcpu **next)
{
	uint32_t func = args->func & ~SMCCC_CONVENTION_MASK;

	/*
	 * NOTE: When adding new methods to this handler update
	 * api_ffa_features accordingly.
	 */
	switch (func) {
	case FFA_VERSION_32:
		*args = api_ffa_version(args->arg1);
		return true;
	case FFA_PARTITION_INFO_GET_32: {
		struct ffa_uuid uuid;

		ffa_uuid_init(args->arg1, args->arg2, args->arg3, args->arg4,
			      &uuid);
		*args = api_ffa_partition_info_get(current, &uuid);
		return true;
	}
	case FFA_ID_GET_32:
		*args = api_ffa_id_get(current);
		return true;
	case FFA_FEATURES_32:
		*args = api_ffa_features(args->arg1);
		return true;
	case FFA_RX_RELEASE_32:
		*args = api_ffa_rx_release(current, next);
		return true;
	case FFA_RXTX_MAP_32:
		*args = api_ffa_rxtx_map(ipa_init(args->arg1),
					 ipa_init(args->arg2), args->arg3,
					 current, next);
		return true;
	case FFA_YIELD_32:
		*args = api_yield(current, next);
		return true;
	case FFA_MSG_SEND_32:
		*args = api_ffa_msg_send(
			ffa_msg_send_sender(*args),
			ffa_msg_send_receiver(*args), ffa_msg_send_size(*args),
			ffa_msg_send_attributes(*args), current, next);
		return true;
	case FFA_MSG_WAIT_32:
#if SECURE_WORLD == 1
		if (sp_boot_next(current, next, args)) {
			return true;
		}
#endif
		*args = api_ffa_msg_recv(true, current, next);
		return true;
	case FFA_MSG_POLL_32:
		*args = api_ffa_msg_recv(false, current, next);
		return true;
	case FFA_RUN_32:
		*args = api_ffa_run(ffa_vm_id(*args), ffa_vcpu_index(*args),
				    current, next);
		return true;
	case FFA_MEM_DONATE_32:
	case FFA_MEM_LEND_32:
	case FFA_MEM_SHARE_32:
		*args = api_ffa_mem_send(func, args->arg1, args->arg2,
					 ipa_init(args->arg3), args->arg4,
					 current);
		return true;
	case FFA_MEM_RETRIEVE_REQ_32:
		*args = api_ffa_mem_retrieve_req(args->arg1, args->arg2,
						 ipa_init(args->arg3),
						 args->arg4, current);
		return true;
	case FFA_MEM_RELINQUISH_32:
		*args = api_ffa_mem_relinquish(current);
		return true;
	case FFA_MEM_RECLAIM_32:
		*args = api_ffa_mem_reclaim(
			ffa_assemble_handle(args->arg1, args->arg2), args->arg3,
			current);
		return true;
	case FFA_MEM_FRAG_RX_32:
		*args = api_ffa_mem_frag_rx(ffa_frag_handle(*args), args->arg3,
					    (args->arg4 >> 16) & 0xffff,
					    current);
		return true;
	case FFA_MEM_FRAG_TX_32:
		*args = api_ffa_mem_frag_tx(ffa_frag_handle(*args), args->arg3,
					    (args->arg4 >> 16) & 0xffff,
					    current);
		return true;
	case FFA_MSG_SEND_DIRECT_REQ_32:
		*args = api_ffa_msg_send_direct_req(
			ffa_msg_send_sender(*args),
			ffa_msg_send_receiver(*args), *args, current, next);
		return true;
	case FFA_MSG_SEND_DIRECT_RESP_32:
		*args = api_ffa_msg_send_direct_resp(
			ffa_msg_send_sender(*args),
			ffa_msg_send_receiver(*args), *args, current, next);
		return true;
	}

	return false;
}

#if SECURE_WORLD == 1

/**
 * Called to switch to the other world and handle FF-A calls from it. Returns
 * when it is ready to run a secure partition again.
 *
 * Expects that `other_world_vcpu` points to the vCPU of the 'other world VM'
 * which corresponds to this physical CPU, and that `*next` is `NULL`.
 */
static void other_world_switch_loop(struct vcpu *other_world_vcpu,
				    struct vcpu **next)
{
	struct ffa_value other_world_args =
		arch_regs_get_args(&other_world_vcpu->regs);

	CHECK(!vm_id_is_current_world(other_world_vcpu->vm->id));
	CHECK(*next == NULL);

	while (*next == NULL) {
		/*
		 * Either we just entered the function or the last FF-A call
		 * from the other world was handled and next is still NULL,
		 * which means that the result should be passed back to the
		 * other world.
		 */
		other_world_args = smc_ffa_call(other_world_args);

		/*
		 * The call to EL3 returned, thus other_world_args contains an
		 * FF-A call from the physical FF-A instance. Handle it. At this
		 * point *next is still NULL, which means that we will return
		 * the result of the call back to EL3 unless the API handler
		 * sets *next to something different.
		 */
		if (!ffa_handler(&other_world_args, other_world_vcpu, next)) {
			other_world_args.func = SMCCC_ERROR_UNKNOWN;
		}
	}

	/*
	 * ffa_handler set *next to something, which means it wants to switch
	 * back to an SP in EL1. It must be something in this world though, as
	 * if it wanted to return back to the other world (where the last FF-A
	 * call came from) it wouldn't have set *next at all.
	 */
	CHECK(vm_id_is_current_world((*next)->vm->id));

	/*
	 * Store the return value on the other world vCPU, ready for next time
	 * we switch to it (in case they aren't overwritten at that point by
	 * whatever API function decides to make the switch).
	 */
	arch_regs_set_retval(&other_world_vcpu->regs, other_world_args);
}

#endif

/**
 * Set or clear VI bit according to pending interrupts.
 */
static void update_vi(struct vcpu *next)
{
	if (next == NULL) {
		/*
		 * Not switching vCPUs, set the bit for the current vCPU
		 * directly in the register.
		 */
		struct vcpu *vcpu = current();

		sl_lock(&vcpu->lock);
		set_virtual_interrupt_current(
			vcpu->interrupts.enabled_and_pending_count > 0);
		sl_unlock(&vcpu->lock);
	} else {
		CHECK(vm_id_is_current_world(next->vm->id));

		/*
		 * About to switch vCPUs, set the bit for the vCPU to which we
		 * are switching in the saved copy of the register.
		 */
		sl_lock(&next->lock);
		set_virtual_interrupt(
			&next->regs,
			next->interrupts.enabled_and_pending_count > 0);
		sl_unlock(&next->lock);
	}
}

/**
 * Handles PSCI and FF-A calls and writes the return value back to the registers
 * of the vCPU. This is shared between smc_handler and hvc_handler.
 *
 * Returns true if the call was handled.
 */
static bool hvc_smc_handler(struct ffa_value args, struct vcpu *vcpu,
			    struct vcpu **next)
{
	if (psci_handler(vcpu, args.func, args.arg1, args.arg2, args.arg3,
			 &vcpu->regs.r[0], next)) {
		return true;
	}

	if (ffa_handler(&args, vcpu, next)) {
		arch_regs_set_retval(&vcpu->regs, args);

#if SECURE_WORLD == 1
		struct vcpu *other_world_vcpu =
			vcpu_get_other_world_counterpart(current());

		if (*next == other_world_vcpu) {
			/*
			 * TODO: Save non-volatile registers of current SP vCPU
			 * before switching to normal world.
			 * For now we rely on the SPMD in TF-A to do this at
			 * EL3:
			 * https://git.trustedfirmware.org/TF-A/trusted-firmware-a.git/tree/services/std_svc/spmd/spmd_main.c#n121
			 * This requires that the CTX_INCLUDE_FP_REGS option is
			 * enabled in the TF-A build.
			 */
			api_regs_state_saved(vcpu);

			*next = NULL;
			other_world_switch_loop(other_world_vcpu, next);

			/*
			 * Whatever API function has requested a switch back to
			 * the vCPU of an SP should have set regs_available to
			 * false already. It must also have explicitly set a
			 * next vCPU rather than leaving it NULL, because NULL
			 * would have meant returning to the normal world.
			 */
			CHECK(next != NULL);
			CHECK(!(*next)->regs_available);
		}
#endif

		update_vi(*next);
		return true;
	}

	return false;
}

/**
 * Processes SMC instruction calls.
 */
static struct vcpu *smc_handler(struct vcpu *vcpu)
{
	struct ffa_value args = arch_regs_get_args(&vcpu->regs);
	struct vcpu *next = NULL;

	if (hvc_smc_handler(args, vcpu, &next)) {
		return next;
	}

	switch (args.func & ~SMCCC_CONVENTION_MASK) {
	case HF_DEBUG_LOG:
		vcpu->regs.r[0] = api_debug_log(args.arg1, vcpu);
		return NULL;
	}

	smc_forwarder(vcpu->vm, &args);
	arch_regs_set_retval(&vcpu->regs, args);
	return NULL;
}

/*
 * Exception vector offsets.
 * See Arm Architecture Reference Manual Armv8-A, D1.10.2.
 */

/**
 * Offset for synchronous exceptions at current EL with SPx.
 */
#define OFFSET_CURRENT_SPX UINT64_C(0x200)

/**
 * Offset for synchronous exceptions at lower EL using AArch64.
 */
#define OFFSET_LOWER_EL_64 UINT64_C(0x400)

/**
 * Offset for synchronous exceptions at lower EL using AArch32.
 */
#define OFFSET_LOWER_EL_32 UINT64_C(0x600)

/**
 * Returns the address for the exception handler at EL1.
 */
static uintreg_t get_el1_exception_handler_addr(const struct vcpu *vcpu)
{
	uintreg_t base_addr = read_msr(vbar_el1);
	uintreg_t pe_mode = vcpu->regs.spsr & PSR_PE_MODE_MASK;
	bool is_arch32 = vcpu->regs.spsr & PSR_ARCH_MODE_32;

	if (pe_mode == PSR_PE_MODE_EL0T) {
		if (is_arch32) {
			base_addr += OFFSET_LOWER_EL_32;
		} else {
			base_addr += OFFSET_LOWER_EL_64;
		}
	} else {
		CHECK(!is_arch32);
		base_addr += OFFSET_CURRENT_SPX;
	}

	return base_addr;
}

/**
 * Injects an exception with the specified Exception Syndrom Register value into
 * the EL1.
 *
 * NOTE: This function assumes that the lazy registers haven't been saved, and
 * writes to the lazy registers of the CPU directly instead of the vCPU.
 */
static void inject_el1_exception(struct vcpu *vcpu, uintreg_t esr_el1_value,
				 uintreg_t far_el1_value)
{
	uintreg_t handler_address = get_el1_exception_handler_addr(vcpu);

	/* Update the CPU state to inject the exception. */
	write_msr(esr_el1, esr_el1_value);
	write_msr(far_el1, far_el1_value);
	write_msr(elr_el1, vcpu->regs.pc);
	write_msr(spsr_el1, vcpu->regs.spsr);

	/*
	 * Mask (disable) interrupts and run in EL1h mode.
	 * EL1h mode is used because by default, taking an exception selects the
	 * stack pointer for the target Exception level. The software can change
	 * that later in the handler if needed.
	 */
	vcpu->regs.spsr = PSR_D | PSR_A | PSR_I | PSR_F | PSR_PE_MODE_EL1H;

	/* Transfer control to the exception hander. */
	vcpu->regs.pc = handler_address;
}

/**
 * Injects a Data Abort exception (same exception level).
 */
static void inject_el1_data_abort_exception(struct vcpu *vcpu,
					    uintreg_t esr_el2,
					    uintreg_t far_el2)
{
	/*
	 *  ISS encoding remains the same, but the EC is changed to reflect
	 *  where the exception came from.
	 *  See Arm Architecture Reference Manual Armv8-A, pages D13-2943/2982.
	 */
	uintreg_t esr_el1_value = GET_ESR_ISS(esr_el2) | GET_ESR_IL(esr_el2) |
				  (EC_DATA_ABORT_SAME_EL << ESR_EC_OFFSET);

	dlog_notice("Injecting Data Abort exception into VM%d.\n",
		    vcpu->vm->id);

	inject_el1_exception(vcpu, esr_el1_value, far_el2);
}

/**
 * Injects a Data Abort exception (same exception level).
 */
static void inject_el1_instruction_abort_exception(struct vcpu *vcpu,
						   uintreg_t esr_el2,
						   uintreg_t far_el2)
{
	/*
	 *  ISS encoding remains the same, but the EC is changed to reflect
	 *  where the exception came from.
	 *  See Arm Architecture Reference Manual Armv8-A, pages D13-2941/2980.
	 */
	uintreg_t esr_el1_value =
		GET_ESR_ISS(esr_el2) | GET_ESR_IL(esr_el2) |
		(EC_INSTRUCTION_ABORT_SAME_EL << ESR_EC_OFFSET);

	dlog_notice("Injecting Instruction Abort exception into VM%d.\n",
		    vcpu->vm->id);

	inject_el1_exception(vcpu, esr_el1_value, far_el2);
}

/**
 * Injects an exception with an unknown reason into the EL1.
 */
static void inject_el1_unknown_exception(struct vcpu *vcpu, uintreg_t esr_el2)
{
	uintreg_t esr_el1_value =
		GET_ESR_IL(esr_el2) | (EC_UNKNOWN << ESR_EC_OFFSET);

	/*
	 * The value of the far_el2 register is UNKNOWN in this case,
	 * therefore, don't propagate it to avoid leaking sensitive information.
	 */
	uintreg_t far_el1_value = 0;
	char *direction_str;

	direction_str = ISS_IS_READ(esr_el2) ? "read" : "write";
	dlog_notice(
		"Trapped access to system register %s: op0=%d, op1=%d, crn=%d, "
		"crm=%d, op2=%d, rt=%d.\n",
		direction_str, GET_ISS_OP0(esr_el2), GET_ISS_OP1(esr_el2),
		GET_ISS_CRN(esr_el2), GET_ISS_CRM(esr_el2),
		GET_ISS_OP2(esr_el2), GET_ISS_RT(esr_el2));

	dlog_notice("Injecting Unknown Reason exception into VM%d.\n",
		    vcpu->vm->id);

	inject_el1_exception(vcpu, esr_el1_value, far_el1_value);
}

static struct vcpu *hvc_handler(struct vcpu *vcpu)
{
	struct ffa_value args = arch_regs_get_args(&vcpu->regs);
	struct vcpu *next = NULL;

	if (hvc_smc_handler(args, vcpu, &next)) {
		return next;
	}

	switch (args.func) {
	case HF_MAILBOX_WRITABLE_GET:
		vcpu->regs.r[0] = api_mailbox_writable_get(vcpu);
		break;

	case HF_MAILBOX_WAITER_GET:
		vcpu->regs.r[0] = api_mailbox_waiter_get(args.arg1, vcpu);
		break;

	case HF_INTERRUPT_ENABLE:
		vcpu->regs.r[0] =
			api_interrupt_enable(args.arg1, args.arg2, vcpu);
		break;

	case HF_INTERRUPT_GET:
		vcpu->regs.r[0] = api_interrupt_get(vcpu);
		break;

	case HF_INTERRUPT_INJECT:
		vcpu->regs.r[0] = api_interrupt_inject(args.arg1, args.arg2,
						       args.arg3, vcpu, &next);
		break;

	case HF_DEBUG_LOG:
		vcpu->regs.r[0] = api_debug_log(args.arg1, vcpu);
		break;

	default:
		vcpu->regs.r[0] = SMCCC_ERROR_UNKNOWN;
	}

	update_vi(next);

	return next;
}

struct vcpu *irq_lower(void)
{
	/*
	 * Switch back to primary VM, interrupts will be handled there.
	 *
	 * If the VM has aborted, this vCPU will be aborted when the scheduler
	 * tries to run it again. This means the interrupt will not be delayed
	 * by the aborted VM.
	 *
	 * TODO: Only switch when the interrupt isn't for the current VM.
	 */
	return api_preempt(current());
}

struct vcpu *fiq_lower(void)
{
	return irq_lower();
}

noreturn struct vcpu *serr_lower(void)
{
	/*
	 * SError exceptions should be isolated and handled by the responsible
	 * VM/exception level. Getting here indicates a bug, that isolation is
	 * not working, or a processor that does not support ARMv8.2-IESB, in
	 * which case Hafnium routes SError exceptions to EL2 (here).
	 */
	panic("SError from a lower exception level.");
}

/**
 * Initialises a fault info structure. It assumes that an FnV bit exists at
 * bit offset 10 of the ESR, and that it is only valid when the bottom 6 bits of
 * the ESR (the fault status code) are 010000; this is the case for both
 * instruction and data aborts, but not necessarily for other exception reasons.
 */
static struct vcpu_fault_info fault_info_init(uintreg_t esr,
					      const struct vcpu *vcpu,
					      uint32_t mode)
{
	uint32_t fsc = esr & 0x3f;
	struct vcpu_fault_info r;
	uint64_t hpfar_el2_val;
	uint64_t hpfar_el2_fipa;

	r.mode = mode;
	r.pc = va_init(vcpu->regs.pc);

	/* Get Hypervisor IPA Fault Address value. */
	hpfar_el2_val = read_msr(hpfar_el2);

	/* Extract Faulting IPA. */
	hpfar_el2_fipa = (hpfar_el2_val & HPFAR_EL2_FIPA) << 8;

#if SECURE_WORLD == 1

	/**
	 * Determine if faulting IPA targets NS space.
	 * At NS-EL2 hpfar_el2 bit 63 is RES0. At S-EL2, this bit determines if
	 * the faulting Stage-1 address output is a secure or non-secure IPA.
	 */
	if ((hpfar_el2_val & HPFAR_EL2_NS) != 0) {
		r.mode |= MM_MODE_NS;
	}

#endif

	/*
	 * Check the FnV bit, which is only valid if dfsc/ifsc is 010000. It
	 * indicates that we cannot rely on far_el2.
	 */
	if (fsc == 0x10 && esr & (1U << 10)) {
		r.vaddr = va_init(0);
		r.ipaddr = ipa_init(hpfar_el2_fipa);
	} else {
		r.vaddr = va_init(read_msr(far_el2));
		r.ipaddr = ipa_init(hpfar_el2_fipa |
				    (read_msr(far_el2) & (PAGE_SIZE - 1)));
	}

	return r;
}

struct vcpu *sync_lower_exception(uintreg_t esr, uintreg_t far)
{
	struct vcpu *vcpu = current();
	struct vcpu_fault_info info;
	struct vcpu *new_vcpu;
	uintreg_t ec = GET_ESR_EC(esr);

	switch (ec) {
	case EC_WFI_WFE:
		/* Skip the instruction. */
		vcpu->regs.pc += GET_NEXT_PC_INC(esr);
		/* Check TI bit of ISS, 0 = WFI, 1 = WFE. */
		if (esr & 1) {
			/* WFE */
			/*
			 * TODO: consider giving the scheduler more context,
			 * somehow.
			 */
			api_yield(vcpu, &new_vcpu);
			return new_vcpu;
		}
		/* WFI */
		return api_wait_for_interrupt(vcpu);

	case EC_DATA_ABORT_LOWER_EL:
		info = fault_info_init(
			esr, vcpu, (esr & (1U << 6)) ? MM_MODE_W : MM_MODE_R);
		if (vcpu_handle_page_fault(vcpu, &info)) {
			return NULL;
		}
		/* Inform the EL1 of the data abort. */
		inject_el1_data_abort_exception(vcpu, esr, far);

		/* Schedule the same VM to continue running. */
		return NULL;

	case EC_INSTRUCTION_ABORT_LOWER_EL:
		info = fault_info_init(esr, vcpu, MM_MODE_X);
		if (vcpu_handle_page_fault(vcpu, &info)) {
			return NULL;
		}
		/* Inform the EL1 of the instruction abort. */
		inject_el1_instruction_abort_exception(vcpu, esr, far);

		/* Schedule the same VM to continue running. */
		return NULL;

	case EC_HVC:
		return hvc_handler(vcpu);

	case EC_SMC: {
		uintreg_t smc_pc = vcpu->regs.pc;
		struct vcpu *next = smc_handler(vcpu);

		/* Skip the SMC instruction. */
		vcpu->regs.pc = smc_pc + GET_NEXT_PC_INC(esr);

		return next;
	}

	case EC_MSR:
		/*
		 * NOTE: This should never be reached because it goes through a
		 * separate path handled by handle_system_register_access().
		 */
		panic("Handled by handle_system_register_access().");

	default:
		dlog_notice(
			"Unknown lower sync exception pc=%#x, esr=%#x, "
			"ec=%#x\n",
			vcpu->regs.pc, esr, ec);
		break;
	}

	/*
	 * The exception wasn't handled. Inject to the VM to give it chance to
	 * handle as an unknown exception.
	 */
	inject_el1_unknown_exception(vcpu, esr);

	/* Schedule the same VM to continue running. */
	return NULL;
}

/**
 * Handles EC = 011000, MSR, MRS instruction traps.
 * Returns non-null ONLY if the access failed and the vCPU is changing.
 */
void handle_system_register_access(uintreg_t esr_el2)
{
	struct vcpu *vcpu = current();
	ffa_vm_id_t vm_id = vcpu->vm->id;
	uintreg_t ec = GET_ESR_EC(esr_el2);

	CHECK(ec == EC_MSR);
	/*
	 * Handle accesses to debug and performance monitor registers.
	 * Inject an exception for unhandled/unsupported registers.
	 */
	if (debug_el1_is_register_access(esr_el2)) {
		if (!debug_el1_process_access(vcpu, vm_id, esr_el2)) {
			inject_el1_unknown_exception(vcpu, esr_el2);
			return;
		}
	} else if (perfmon_is_register_access(esr_el2)) {
		if (!perfmon_process_access(vcpu, vm_id, esr_el2)) {
			inject_el1_unknown_exception(vcpu, esr_el2);
			return;
		}
	} else if (feature_id_is_register_access(esr_el2)) {
		if (!feature_id_process_access(vcpu, esr_el2)) {
			inject_el1_unknown_exception(vcpu, esr_el2);
			return;
		}
	} else {
		inject_el1_unknown_exception(vcpu, esr_el2);
		return;
	}

	/* Instruction was fulfilled. Skip it and run the next one. */
	vcpu->regs.pc += GET_NEXT_PC_INC(esr_el2);
}