services/std_svc/sdei/sdei_intr_mgmt.c - imx-atf - Git at Google

 /*
  * Copyright (c) 2017-2018, ARM Limited and Contributors. All rights reserved.
  *
  * SPDX-License-Identifier: BSD-3-Clause
  */

 #include <arch_helpers.h>
 #include <assert.h>
 #include <bl_common.h>
 #include <cassert.h>
 #include <debug.h>
 #include <ehf.h>
 #include <interrupt_mgmt.h>
 #include <runtime_svc.h>
 #include <sdei.h>
 #include <string.h>
 #include "sdei_private.h"

 /* x0-x17 GPREGS context */
 #define SDEI_SAVED_GPREGS	18U

 /* Maximum preemption nesting levels: Critical priority and Normal priority */
 #define MAX_EVENT_NESTING	2U

 /* Per-CPU SDEI state access macro */
 #define sdei_get_this_pe_state()	(&cpu_state[plat_my_core_pos()])

 /* Structure to store information about an outstanding dispatch */
 typedef struct sdei_dispatch_context {
 	sdei_ev_map_t *map;
 	uint64_t x[SDEI_SAVED_GPREGS];
 	struct jmpbuf *dispatch_jmp;

 	/* Exception state registers */
 	uint64_t elr_el3;
 	uint64_t spsr_el3;

 #if DYNAMIC_WORKAROUND_CVE_2018_3639
 	/* CVE-2018-3639 mitigation state */
 	uint64_t disable_cve_2018_3639;
 #endif
 } sdei_dispatch_context_t;

 /* Per-CPU SDEI state data */
 typedef struct sdei_cpu_state {
 	sdei_dispatch_context_t dispatch_stack[MAX_EVENT_NESTING];
 	unsigned short stack_top; /* Empty ascending */
 	bool pe_masked;
 	bool pending_enables;
 } sdei_cpu_state_t;

 /* SDEI states for all cores in the system */
 static sdei_cpu_state_t cpu_state[PLATFORM_CORE_COUNT];

 int64_t sdei_pe_mask(void)
 {
 	int64_t ret = 0;
 	sdei_cpu_state_t *state = sdei_get_this_pe_state();

 	/*
 	 * Return value indicates whether this call had any effect in the mask
 	 * status of this PE.
 	 */
 	if (!state->pe_masked) {
 		state->pe_masked = true;
 		ret = 1;
 	}

 	return ret;
 }

 void sdei_pe_unmask(void)
 {
 	unsigned int i;
 	sdei_ev_map_t *map;
 	sdei_entry_t *se;
 	sdei_cpu_state_t *state = sdei_get_this_pe_state();
 	uint64_t my_mpidr = read_mpidr_el1() & MPIDR_AFFINITY_MASK;

 	/*
 	 * If there are pending enables, iterate through the private mappings
 	 * and enable those bound maps that are in enabled state. Also, iterate
 	 * through shared mappings and enable interrupts of events that are
 	 * targeted to this PE.
 	 */
 	if (state->pending_enables) {
 		for_each_private_map(i, map) {
 			se = get_event_entry(map);
 			if (is_map_bound(map) && GET_EV_STATE(se, ENABLED))
 				plat_ic_enable_interrupt(map->intr);
 		}

 		for_each_shared_map(i, map) {
 			se = get_event_entry(map);

 			sdei_map_lock(map);
 			if (is_map_bound(map) && GET_EV_STATE(se, ENABLED) &&
 					(se->reg_flags == SDEI_REGF_RM_PE) &&
 					(se->affinity == my_mpidr)) {
 				plat_ic_enable_interrupt(map->intr);
 			}
 			sdei_map_unlock(map);
 		}
 	}

 	state->pending_enables = false;
 	state->pe_masked = false;
 }

 /* Push a dispatch context to the dispatch stack */
 static sdei_dispatch_context_t *push_dispatch(void)
 {
 	sdei_cpu_state_t *state = sdei_get_this_pe_state();
 	sdei_dispatch_context_t *disp_ctx;

 	/* Cannot have more than max events */
 	assert(state->stack_top < MAX_EVENT_NESTING);

 	disp_ctx = &state->dispatch_stack[state->stack_top];
 	state->stack_top++;

 	return disp_ctx;
 }

 /* Pop a dispatch context to the dispatch stack */
 static sdei_dispatch_context_t *pop_dispatch(void)
 {
 	sdei_cpu_state_t *state = sdei_get_this_pe_state();

 	if (state->stack_top == 0U)
 		return NULL;

 	assert(state->stack_top <= MAX_EVENT_NESTING);

 	state->stack_top--;

 	return &state->dispatch_stack[state->stack_top];
 }

 /* Retrieve the context at the top of dispatch stack */
 static sdei_dispatch_context_t *get_outstanding_dispatch(void)
 {
 	sdei_cpu_state_t *state = sdei_get_this_pe_state();

 	if (state->stack_top == 0U)
 		return NULL;

 	assert(state->stack_top <= MAX_EVENT_NESTING);

 	return &state->dispatch_stack[state->stack_top - 1U];
 }

 static sdei_dispatch_context_t *save_event_ctx(sdei_ev_map_t *map,
 		void *tgt_ctx)
 {
 	sdei_dispatch_context_t *disp_ctx;
 	const gp_regs_t *tgt_gpregs;
 	const el3_state_t *tgt_el3;

 	assert(tgt_ctx != NULL);
 	tgt_gpregs = get_gpregs_ctx(tgt_ctx);
 	tgt_el3 = get_el3state_ctx(tgt_ctx);

 	disp_ctx = push_dispatch();
 	assert(disp_ctx != NULL);
 	disp_ctx->map = map;

 	/* Save general purpose and exception registers */
 	memcpy(disp_ctx->x, tgt_gpregs, sizeof(disp_ctx->x));
 	disp_ctx->spsr_el3 = read_ctx_reg(tgt_el3, CTX_SPSR_EL3);
 	disp_ctx->elr_el3 = read_ctx_reg(tgt_el3, CTX_ELR_EL3);

 	return disp_ctx;
 }

 static void restore_event_ctx(const sdei_dispatch_context_t *disp_ctx, void *tgt_ctx)
 {
 	gp_regs_t *tgt_gpregs;
 	el3_state_t *tgt_el3;

 	assert(tgt_ctx != NULL);
 	tgt_gpregs = get_gpregs_ctx(tgt_ctx);
 	tgt_el3 = get_el3state_ctx(tgt_ctx);

 	CASSERT(sizeof(disp_ctx->x) == (SDEI_SAVED_GPREGS * sizeof(uint64_t)),
 			foo);

 	/* Restore general purpose and exception registers */
 	memcpy(tgt_gpregs, disp_ctx->x, sizeof(disp_ctx->x));
 	write_ctx_reg(tgt_el3, CTX_SPSR_EL3, disp_ctx->spsr_el3);
 	write_ctx_reg(tgt_el3, CTX_ELR_EL3, disp_ctx->elr_el3);

 #if DYNAMIC_WORKAROUND_CVE_2018_3639
 	cve_2018_3639_t *tgt_cve_2018_3639;
 	tgt_cve_2018_3639 = get_cve_2018_3639_ctx(tgt_ctx);

 	/* Restore CVE-2018-3639 mitigation state */
 	write_ctx_reg(tgt_cve_2018_3639, CTX_CVE_2018_3639_DISABLE,
 		disp_ctx->disable_cve_2018_3639);
 #endif
 }

 static void save_secure_context(void)
 {
 	cm_el1_sysregs_context_save(SECURE);
 }

 /* Restore Secure context and arrange to resume it at the next ERET */
 static void restore_and_resume_secure_context(void)
 {
 	cm_el1_sysregs_context_restore(SECURE);
 	cm_set_next_eret_context(SECURE);
 }

 /*
  * Restore Non-secure context and arrange to resume it at the next ERET. Return
  * pointer to the Non-secure context.
  */
 static cpu_context_t *restore_and_resume_ns_context(void)
 {
 	cpu_context_t *ns_ctx;

 	cm_el1_sysregs_context_restore(NON_SECURE);
 	cm_set_next_eret_context(NON_SECURE);

 	ns_ctx = cm_get_context(NON_SECURE);
 	assert(ns_ctx != NULL);

 	return ns_ctx;
 }

 /*
  * Populate the Non-secure context so that the next ERET will dispatch to the
  * SDEI client.
  */
 static void setup_ns_dispatch(sdei_ev_map_t *map, sdei_entry_t *se,
 		cpu_context_t *ctx, struct jmpbuf *dispatch_jmp)
 {
 	sdei_dispatch_context_t *disp_ctx;

 	/* Push the event and context */
 	disp_ctx = save_event_ctx(map, ctx);

 	/*
 	 * Setup handler arguments:
 	 *
 	 * - x0: Event number
 	 * - x1: Handler argument supplied at the time of event registration
 	 * - x2: Interrupted PC
 	 * - x3: Interrupted SPSR
 	 */
 	SMC_SET_GP(ctx, CTX_GPREG_X0, (uint64_t) map->ev_num);
 	SMC_SET_GP(ctx, CTX_GPREG_X1, se->arg);
 	SMC_SET_GP(ctx, CTX_GPREG_X2, disp_ctx->elr_el3);
 	SMC_SET_GP(ctx, CTX_GPREG_X3, disp_ctx->spsr_el3);

 	/*
 	 * Prepare for ERET:
 	 *
 	 * - Set PC to the registered handler address
 	 * - Set SPSR to jump to client EL with exceptions masked
 	 */
 	cm_set_elr_spsr_el3(NON_SECURE, (uintptr_t) se->ep,
 			SPSR_64(sdei_client_el(), MODE_SP_ELX,
 				DISABLE_ALL_EXCEPTIONS));

 #if DYNAMIC_WORKAROUND_CVE_2018_3639
 	cve_2018_3639_t *tgt_cve_2018_3639;
 	tgt_cve_2018_3639 = get_cve_2018_3639_ctx(ctx);

 	/* Save CVE-2018-3639 mitigation state */
 	disp_ctx->disable_cve_2018_3639 = read_ctx_reg(tgt_cve_2018_3639,
 		CTX_CVE_2018_3639_DISABLE);

 	/* Force SDEI handler to execute with mitigation enabled by default */
 	write_ctx_reg(tgt_cve_2018_3639, CTX_CVE_2018_3639_DISABLE, 0);
 #endif

 	disp_ctx->dispatch_jmp = dispatch_jmp;
 }

 /* Handle a triggered SDEI interrupt while events were masked on this PE */
 static void handle_masked_trigger(sdei_ev_map_t *map, sdei_entry_t *se,
 		sdei_cpu_state_t *state, unsigned int intr_raw)
 {
 	uint64_t my_mpidr __unused = (read_mpidr_el1() & MPIDR_AFFINITY_MASK);
 	bool disable = false;

 	/* Nothing to do for event 0 */
 	if (map->ev_num == SDEI_EVENT_0)
 		return;

 	/*
 	 * For a private event, or for a shared event specifically routed to
 	 * this CPU, we disable interrupt, leave the interrupt pending, and do
 	 * EOI.
 	 */
 	if (is_event_private(map) || (se->reg_flags == SDEI_REGF_RM_PE))
 		disable = true;

 	if (se->reg_flags == SDEI_REGF_RM_PE)
 		assert(se->affinity == my_mpidr);

 	if (disable) {
 		plat_ic_disable_interrupt(map->intr);
 		plat_ic_set_interrupt_pending(map->intr);
 		plat_ic_end_of_interrupt(intr_raw);
 		state->pending_enables = true;

 		return;
 	}

 	/*
 	 * We just received a shared event with routing set to ANY PE. The
 	 * interrupt can't be delegated on this PE as SDEI events are masked.
 	 * However, because its routing mode is ANY, it is possible that the
 	 * event can be delegated on any other PE that hasn't masked events.
 	 * Therefore, we set the interrupt back pending so as to give other
 	 * suitable PEs a chance of handling it.
 	 */
 	assert(plat_ic_is_spi(map->intr) != 0);
 	plat_ic_set_interrupt_pending(map->intr);

 	/*
 	 * Leaving the same interrupt pending also means that the same interrupt
 	 * can target this PE again as soon as this PE leaves EL3. Whether and
 	 * how often that happens depends on the implementation of GIC.
 	 *
 	 * We therefore call a platform handler to resolve this situation.
 	 */
 	plat_sdei_handle_masked_trigger(my_mpidr, map->intr);

 	/* This PE is masked. We EOI the interrupt, as it can't be delegated */
 	plat_ic_end_of_interrupt(intr_raw);
 }

 /* SDEI main interrupt handler */
 int sdei_intr_handler(uint32_t intr_raw, uint32_t flags, void *handle,
 		void *cookie)
 {
 	sdei_entry_t *se;
 	cpu_context_t *ctx;
 	sdei_ev_map_t *map;
 	const sdei_dispatch_context_t *disp_ctx;
 	unsigned int sec_state;
 	sdei_cpu_state_t *state;
 	uint32_t intr;
 	struct jmpbuf dispatch_jmp;
 	const uint64_t mpidr = read_mpidr_el1();

 	/*
 	 * To handle an event, the following conditions must be true:
 	 *
 	 * 1. Event must be signalled
 	 * 2. Event must be enabled
 	 * 3. This PE must be a target PE for the event
 	 * 4. PE must be unmasked for SDEI
 	 * 5. If this is a normal event, no event must be running
 	 * 6. If this is a critical event, no critical event must be running
 	 *
 	 * (1) and (2) are true when this function is running
 	 * (3) is enforced in GIC by selecting the appropriate routing option
 	 * (4) is satisfied by client calling PE_UNMASK
 	 * (5) and (6) is enforced using interrupt priority, the RPR, in GIC:
 	 *   - Normal SDEI events belong to Normal SDE priority class
 	 *   - Critical SDEI events belong to Critical CSDE priority class
 	 *
 	 * The interrupt has already been acknowledged, and therefore is active,
 	 * so no other PE can handle this event while we are at it.
 	 *
 	 * Find if this is an SDEI interrupt. There must be an event mapped to
 	 * this interrupt
 	 */
 	intr = plat_ic_get_interrupt_id(intr_raw);
 	map = find_event_map_by_intr(intr, (plat_ic_is_spi(intr) != 0));
 	if (map == NULL) {
 		ERROR("No SDEI map for interrupt %u\n", intr);
 		panic();
 	}

 	/*
 	 * Received interrupt number must either correspond to event 0, or must
 	 * be bound interrupt.
 	 */
 	assert((map->ev_num == SDEI_EVENT_0) || is_map_bound(map));

 	se = get_event_entry(map);
 	state = sdei_get_this_pe_state();

 	if (state->pe_masked) {
 		/*
 		 * Interrupts received while this PE was masked can't be
 		 * dispatched.
 		 */
 		SDEI_LOG("interrupt %u on %llx while PE masked\n", map->intr,
 				mpidr);
 		if (is_event_shared(map))
 			sdei_map_lock(map);

 		handle_masked_trigger(map, se, state, intr_raw);

 		if (is_event_shared(map))
 			sdei_map_unlock(map);

 		return 0;
 	}

 	/* Insert load barrier for signalled SDEI event */
 	if (map->ev_num == SDEI_EVENT_0)
 		dmbld();

 	if (is_event_shared(map))
 		sdei_map_lock(map);

 	/* Assert shared event routed to this PE had been configured so */
 	if (is_event_shared(map) && (se->reg_flags == SDEI_REGF_RM_PE)) {
 		assert(se->affinity == (mpidr & MPIDR_AFFINITY_MASK));
 	}

 	if (!can_sdei_state_trans(se, DO_DISPATCH)) {
 		SDEI_LOG("SDEI event 0x%x can't be dispatched; state=0x%x\n",
 				map->ev_num, se->state);

 		/*
 		 * If the event is registered, leave the interrupt pending so
 		 * that it's delivered when the event is enabled.
 		 */
 		if (GET_EV_STATE(se, REGISTERED))
 			plat_ic_set_interrupt_pending(map->intr);

 		/*
 		 * The interrupt was disabled or unregistered after the handler
 		 * started to execute, which means now the interrupt is already
 		 * disabled and we just need to EOI the interrupt.
 		 */
 		plat_ic_end_of_interrupt(intr_raw);

 		if (is_event_shared(map))
 			sdei_map_unlock(map);

 		return 0;
 	}

 	disp_ctx = get_outstanding_dispatch();
 	if (is_event_critical(map)) {
 		/*
 		 * If this event is Critical, and if there's an outstanding
 		 * dispatch, assert the latter is a Normal dispatch. Critical
 		 * events can preempt an outstanding Normal event dispatch.
 		 */
 		if (disp_ctx != NULL)
 			assert(is_event_normal(disp_ctx->map));
 	} else {
 		/*
 		 * If this event is Normal, assert that there are no outstanding
 		 * dispatches. Normal events can't preempt any outstanding event
 		 * dispatches.
 		 */
 		assert(disp_ctx == NULL);
 	}

 	sec_state = get_interrupt_src_ss(flags);

 	if (is_event_shared(map))
 		sdei_map_unlock(map);

 	SDEI_LOG("ACK %llx, ev:%d ss:%d spsr:%lx ELR:%lx\n", mpidr, map->ev_num,
 			sec_state, read_spsr_el3(), read_elr_el3());

 	ctx = handle;

 	/*
 	 * Check if we interrupted secure state. Perform a context switch so
 	 * that we can delegate to NS.
 	 */
 	if (sec_state == SECURE) {
 		save_secure_context();
 		ctx = restore_and_resume_ns_context();
 	}

 	/* Synchronously dispatch event */
 	setup_ns_dispatch(map, se, ctx, &dispatch_jmp);
 	begin_sdei_synchronous_dispatch(&dispatch_jmp);

 	/*
 	 * We reach here when client completes the event.
 	 *
 	 * If the cause of dispatch originally interrupted the Secure world, and
 	 * if Non-secure world wasn't allowed to preempt Secure execution,
 	 * resume Secure.
 	 *
 	 * No need to save the Non-secure context ahead of a world switch: the
 	 * Non-secure context was fully saved before dispatch, and has been
 	 * returned to its pre-dispatch state.
 	 */
 	if ((sec_state == SECURE) && (ehf_is_ns_preemption_allowed() == 0U))
 		restore_and_resume_secure_context();

 	/*
 	 * The event was dispatched after receiving SDEI interrupt. With
 	 * the event handling completed, EOI the corresponding
 	 * interrupt.
 	 */
 	if ((map->ev_num != SDEI_EVENT_0) && !is_map_bound(map)) {
 		ERROR("Invalid SDEI mapping: ev=%u\n", map->ev_num);
 		panic();
 	}
 	plat_ic_end_of_interrupt(intr_raw);

 	return 0;
 }

 /*
  * Explicitly dispatch the given SDEI event.
  *
  * When calling this API, the caller must be prepared for the SDEI dispatcher to
  * restore and make Non-secure context as active. This call returns only after
  * the client has completed the dispatch. Then, the Non-secure context will be
  * active, and the following ERET will return to Non-secure.
  *
  * Should the caller require re-entry to Secure, it must restore the Secure
  * context and program registers for ERET.
  */
 int sdei_dispatch_event(int ev_num)
 {
 	sdei_entry_t *se;
 	sdei_ev_map_t *map;
 	cpu_context_t *ns_ctx;
 	sdei_dispatch_context_t *disp_ctx;
 	sdei_cpu_state_t *state;
 	struct jmpbuf dispatch_jmp;

 	/* Can't dispatch if events are masked on this PE */
 	state = sdei_get_this_pe_state();
 	if (state->pe_masked)
 		return -1;

 	/* Event 0 can't be dispatched */
 	if (ev_num == SDEI_EVENT_0)
 		return -1;

 	/* Locate mapping corresponding to this event */
 	map = find_event_map(ev_num);
 	if (map == NULL)
 		return -1;

 	/* Only explicit events can be dispatched */
 	if (!is_map_explicit(map))
 		return -1;

 	/* Examine state of dispatch stack */
 	disp_ctx = get_outstanding_dispatch();
 	if (disp_ctx != NULL) {
 		/*
 		 * There's an outstanding dispatch. If the outstanding dispatch
 		 * is critical, no more dispatches are possible.
 		 */
 		if (is_event_critical(disp_ctx->map))
 			return -1;

 		/*
 		 * If the outstanding dispatch is Normal, only critical events
 		 * can be dispatched.
 		 */
 		if (is_event_normal(map))
 			return -1;
 	}

 	se = get_event_entry(map);
 	if (!can_sdei_state_trans(se, DO_DISPATCH))
 		return -1;

 	/* Activate the priority corresponding to the event being dispatched */
 	ehf_activate_priority(sdei_event_priority(map));

 	/*
 	 * Prepare for NS dispatch by restoring the Non-secure context and
 	 * marking that as active.
 	 */
 	ns_ctx = restore_and_resume_ns_context();

 	/* Dispatch event synchronously */
 	setup_ns_dispatch(map, se, ns_ctx, &dispatch_jmp);
 	begin_sdei_synchronous_dispatch(&dispatch_jmp);

 	/*
 	 * We reach here when client completes the event.
 	 *
 	 * Deactivate the priority level that was activated at the time of
 	 * explicit dispatch.
 	 */
 	ehf_deactivate_priority(sdei_event_priority(map));

 	return 0;
 }

 static void end_sdei_synchronous_dispatch(struct jmpbuf *buffer)
 {
 	longjmp(buffer);
 }

 int sdei_event_complete(bool resume, uint64_t pc)
 {
 	sdei_dispatch_context_t *disp_ctx;
 	sdei_entry_t *se;
 	sdei_ev_map_t *map;
 	cpu_context_t *ctx;
 	sdei_action_t act;
 	unsigned int client_el = sdei_client_el();

 	/* Return error if called without an active event */
 	disp_ctx = get_outstanding_dispatch();
 	if (disp_ctx == NULL)
 		return SDEI_EDENY;

 	/* Validate resumption point */
 	if (resume && (plat_sdei_validate_entry_point(pc, client_el) != 0))
 		return SDEI_EDENY;

 	map = disp_ctx->map;
 	assert(map != NULL);
 	se = get_event_entry(map);

 	if (is_event_shared(map))
 		sdei_map_lock(map);

 	act = resume ? DO_COMPLETE_RESUME : DO_COMPLETE;
 	if (!can_sdei_state_trans(se, act)) {
 		if (is_event_shared(map))
 			sdei_map_unlock(map);
 		return SDEI_EDENY;
 	}

 	if (is_event_shared(map))
 		sdei_map_unlock(map);

 	/* Having done sanity checks, pop dispatch */
 	(void) pop_dispatch();

 	SDEI_LOG("EOI:%lx, %d spsr:%lx elr:%lx\n", read_mpidr_el1(),
 			map->ev_num, read_spsr_el3(), read_elr_el3());

 	/*
 	 * Restore Non-secure to how it was originally interrupted. Once done,
 	 * it's up-to-date with the saved copy.
 	 */
 	ctx = cm_get_context(NON_SECURE);
 	restore_event_ctx(disp_ctx, ctx);

 	if (resume) {
 		/*
 		 * Complete-and-resume call. Prepare the Non-secure context
 		 * (currently active) for complete and resume.
 		 */
 		cm_set_elr_spsr_el3(NON_SECURE, pc, SPSR_64(client_el,
 					MODE_SP_ELX, DISABLE_ALL_EXCEPTIONS));

 		/*
 		 * Make it look as if a synchronous exception were taken at the
 		 * supplied Non-secure resumption point. Populate SPSR and
 		 * ELR_ELx so that an ERET from there works as expected.
 		 *
 		 * The assumption is that the client, if necessary, would have
 		 * saved any live content in these registers before making this
 		 * call.
 		 */
 		if (client_el == MODE_EL2) {
 			write_elr_el2(disp_ctx->elr_el3);
 			write_spsr_el2(disp_ctx->spsr_el3);
 		} else {
 			/* EL1 */
 			write_elr_el1(disp_ctx->elr_el3);
 			write_spsr_el1(disp_ctx->spsr_el3);
 		}
 	}

 	/* End the outstanding dispatch */
 	end_sdei_synchronous_dispatch(disp_ctx->dispatch_jmp);

 	return 0;
 }

 int64_t sdei_event_context(void *handle, unsigned int param)
 {
 	sdei_dispatch_context_t *disp_ctx;

 	if (param >= SDEI_SAVED_GPREGS)
 		return SDEI_EINVAL;

 	/* Get outstanding dispatch on this CPU */
 	disp_ctx = get_outstanding_dispatch();
 	if (disp_ctx == NULL)
 		return SDEI_EDENY;

 	assert(disp_ctx->map != NULL);

 	if (!can_sdei_state_trans(get_event_entry(disp_ctx->map), DO_CONTEXT))
 		return SDEI_EDENY;

 	/*
 	 * No locking is required for the Running status as this is the only CPU
 	 * which can complete the event
 	 */

 	return (int64_t) disp_ctx->x[param];
 }
	/*
	* Copyright (c) 2017-2018, ARM Limited and Contributors. All rights reserved.
	*
	* SPDX-License-Identifier: BSD-3-Clause
	*/

	#include <arch_helpers.h>
	#include <assert.h>
	#include <bl_common.h>
	#include <cassert.h>
	#include <debug.h>
	#include <ehf.h>
	#include <interrupt_mgmt.h>
	#include <runtime_svc.h>
	#include <sdei.h>
	#include <string.h>
	#include "sdei_private.h"

	/* x0-x17 GPREGS context */
	#define SDEI_SAVED_GPREGS 18U

	/* Maximum preemption nesting levels: Critical priority and Normal priority */
	#define MAX_EVENT_NESTING 2U

	/* Per-CPU SDEI state access macro */
	#define sdei_get_this_pe_state() (&cpu_state[plat_my_core_pos()])

	/* Structure to store information about an outstanding dispatch */
	typedef struct sdei_dispatch_context {
	sdei_ev_map_t *map;
	uint64_t x[SDEI_SAVED_GPREGS];
	struct jmpbuf *dispatch_jmp;

	/* Exception state registers */
	uint64_t elr_el3;
	uint64_t spsr_el3;

	#if DYNAMIC_WORKAROUND_CVE_2018_3639
	/* CVE-2018-3639 mitigation state */
	uint64_t disable_cve_2018_3639;
	#endif
	} sdei_dispatch_context_t;

	/* Per-CPU SDEI state data */
	typedef struct sdei_cpu_state {
	sdei_dispatch_context_t dispatch_stack[MAX_EVENT_NESTING];
	unsigned short stack_top; /* Empty ascending */
	bool pe_masked;
	bool pending_enables;
	} sdei_cpu_state_t;

	/* SDEI states for all cores in the system */
	static sdei_cpu_state_t cpu_state[PLATFORM_CORE_COUNT];

	int64_t sdei_pe_mask(void)
	{
	int64_t ret = 0;
	sdei_cpu_state_t *state = sdei_get_this_pe_state();

	/*
	* Return value indicates whether this call had any effect in the mask
	* status of this PE.
	*/
	if (!state->pe_masked) {
	state->pe_masked = true;
	ret = 1;
	}

	return ret;
	}

	void sdei_pe_unmask(void)
	{
	unsigned int i;
	sdei_ev_map_t *map;
	sdei_entry_t *se;
	sdei_cpu_state_t *state = sdei_get_this_pe_state();
	uint64_t my_mpidr = read_mpidr_el1() & MPIDR_AFFINITY_MASK;

	/*
	* If there are pending enables, iterate through the private mappings
	* and enable those bound maps that are in enabled state. Also, iterate
	* through shared mappings and enable interrupts of events that are
	* targeted to this PE.
	*/
	if (state->pending_enables) {
	for_each_private_map(i, map) {
	se = get_event_entry(map);
	if (is_map_bound(map) && GET_EV_STATE(se, ENABLED))
	plat_ic_enable_interrupt(map->intr);
	}

	for_each_shared_map(i, map) {
	se = get_event_entry(map);

	sdei_map_lock(map);
	if (is_map_bound(map) && GET_EV_STATE(se, ENABLED) &&
	(se->reg_flags == SDEI_REGF_RM_PE) &&
	(se->affinity == my_mpidr)) {
	plat_ic_enable_interrupt(map->intr);
	}
	sdei_map_unlock(map);
	}
	}

	state->pending_enables = false;
	state->pe_masked = false;
	}

	/* Push a dispatch context to the dispatch stack */
	static sdei_dispatch_context_t *push_dispatch(void)
	{
	sdei_cpu_state_t *state = sdei_get_this_pe_state();
	sdei_dispatch_context_t *disp_ctx;

	/* Cannot have more than max events */
	assert(state->stack_top < MAX_EVENT_NESTING);

	disp_ctx = &state->dispatch_stack[state->stack_top];
	state->stack_top++;

	return disp_ctx;
	}

	/* Pop a dispatch context to the dispatch stack */
	static sdei_dispatch_context_t *pop_dispatch(void)
	{
	sdei_cpu_state_t *state = sdei_get_this_pe_state();

	if (state->stack_top == 0U)
	return NULL;

	assert(state->stack_top <= MAX_EVENT_NESTING);

	state->stack_top--;

	return &state->dispatch_stack[state->stack_top];
	}

	/* Retrieve the context at the top of dispatch stack */
	static sdei_dispatch_context_t *get_outstanding_dispatch(void)
	{
	sdei_cpu_state_t *state = sdei_get_this_pe_state();

	if (state->stack_top == 0U)
	return NULL;

	assert(state->stack_top <= MAX_EVENT_NESTING);

	return &state->dispatch_stack[state->stack_top - 1U];
	}

	static sdei_dispatch_context_t save_event_ctx(sdei_ev_map_t map,
	void *tgt_ctx)
	{
	sdei_dispatch_context_t *disp_ctx;
	const gp_regs_t *tgt_gpregs;
	const el3_state_t *tgt_el3;

	assert(tgt_ctx != NULL);
	tgt_gpregs = get_gpregs_ctx(tgt_ctx);
	tgt_el3 = get_el3state_ctx(tgt_ctx);

	disp_ctx = push_dispatch();
	assert(disp_ctx != NULL);
	disp_ctx->map = map;

	/* Save general purpose and exception registers */
	memcpy(disp_ctx->x, tgt_gpregs, sizeof(disp_ctx->x));
	disp_ctx->spsr_el3 = read_ctx_reg(tgt_el3, CTX_SPSR_EL3);
	disp_ctx->elr_el3 = read_ctx_reg(tgt_el3, CTX_ELR_EL3);

	return disp_ctx;
	}

	static void restore_event_ctx(const sdei_dispatch_context_t disp_ctx, void tgt_ctx)
	{
	gp_regs_t *tgt_gpregs;
	el3_state_t *tgt_el3;

	assert(tgt_ctx != NULL);
	tgt_gpregs = get_gpregs_ctx(tgt_ctx);
	tgt_el3 = get_el3state_ctx(tgt_ctx);

	CASSERT(sizeof(disp_ctx->x) == (SDEI_SAVED_GPREGS * sizeof(uint64_t)),
	foo);

	/* Restore general purpose and exception registers */
	memcpy(tgt_gpregs, disp_ctx->x, sizeof(disp_ctx->x));
	write_ctx_reg(tgt_el3, CTX_SPSR_EL3, disp_ctx->spsr_el3);
	write_ctx_reg(tgt_el3, CTX_ELR_EL3, disp_ctx->elr_el3);

	#if DYNAMIC_WORKAROUND_CVE_2018_3639
	cve_2018_3639_t *tgt_cve_2018_3639;
	tgt_cve_2018_3639 = get_cve_2018_3639_ctx(tgt_ctx);

	/* Restore CVE-2018-3639 mitigation state */
	write_ctx_reg(tgt_cve_2018_3639, CTX_CVE_2018_3639_DISABLE,
	disp_ctx->disable_cve_2018_3639);
	#endif
	}

	static void save_secure_context(void)
	{
	cm_el1_sysregs_context_save(SECURE);
	}

	/* Restore Secure context and arrange to resume it at the next ERET */
	static void restore_and_resume_secure_context(void)
	{
	cm_el1_sysregs_context_restore(SECURE);
	cm_set_next_eret_context(SECURE);
	}

	/*
	* Restore Non-secure context and arrange to resume it at the next ERET. Return
	* pointer to the Non-secure context.
	*/
	static cpu_context_t *restore_and_resume_ns_context(void)
	{
	cpu_context_t *ns_ctx;

	cm_el1_sysregs_context_restore(NON_SECURE);
	cm_set_next_eret_context(NON_SECURE);

	ns_ctx = cm_get_context(NON_SECURE);
	assert(ns_ctx != NULL);

	return ns_ctx;
	}

	/*
	* Populate the Non-secure context so that the next ERET will dispatch to the
	* SDEI client.
	*/
	static void setup_ns_dispatch(sdei_ev_map_t map, sdei_entry_t se,
	cpu_context_t ctx, struct jmpbuf dispatch_jmp)
	{
	sdei_dispatch_context_t *disp_ctx;

	/* Push the event and context */
	disp_ctx = save_event_ctx(map, ctx);

	/*
	* Setup handler arguments:
	*
	* - x0: Event number
	* - x1: Handler argument supplied at the time of event registration
	* - x2: Interrupted PC
	* - x3: Interrupted SPSR
	*/
	SMC_SET_GP(ctx, CTX_GPREG_X0, (uint64_t) map->ev_num);
	SMC_SET_GP(ctx, CTX_GPREG_X1, se->arg);
	SMC_SET_GP(ctx, CTX_GPREG_X2, disp_ctx->elr_el3);
	SMC_SET_GP(ctx, CTX_GPREG_X3, disp_ctx->spsr_el3);

	/*
	* Prepare for ERET:
	*
	* - Set PC to the registered handler address
	* - Set SPSR to jump to client EL with exceptions masked
	*/
	cm_set_elr_spsr_el3(NON_SECURE, (uintptr_t) se->ep,
	SPSR_64(sdei_client_el(), MODE_SP_ELX,
	DISABLE_ALL_EXCEPTIONS));

	#if DYNAMIC_WORKAROUND_CVE_2018_3639
	cve_2018_3639_t *tgt_cve_2018_3639;
	tgt_cve_2018_3639 = get_cve_2018_3639_ctx(ctx);

	/* Save CVE-2018-3639 mitigation state */
	disp_ctx->disable_cve_2018_3639 = read_ctx_reg(tgt_cve_2018_3639,
	CTX_CVE_2018_3639_DISABLE);

	/* Force SDEI handler to execute with mitigation enabled by default */
	write_ctx_reg(tgt_cve_2018_3639, CTX_CVE_2018_3639_DISABLE, 0);
	#endif

	disp_ctx->dispatch_jmp = dispatch_jmp;
	}

	/* Handle a triggered SDEI interrupt while events were masked on this PE */
	static void handle_masked_trigger(sdei_ev_map_t map, sdei_entry_t se,
	sdei_cpu_state_t *state, unsigned int intr_raw)
	{
	uint64_t my_mpidr __unused = (read_mpidr_el1() & MPIDR_AFFINITY_MASK);
	bool disable = false;

	/* Nothing to do for event 0 */
	if (map->ev_num == SDEI_EVENT_0)
	return;

	/*
	* For a private event, or for a shared event specifically routed to
	* this CPU, we disable interrupt, leave the interrupt pending, and do
	* EOI.
	*/
	if (is_event_private(map) \|\| (se->reg_flags == SDEI_REGF_RM_PE))
	disable = true;

	if (se->reg_flags == SDEI_REGF_RM_PE)
	assert(se->affinity == my_mpidr);

	if (disable) {
	plat_ic_disable_interrupt(map->intr);
	plat_ic_set_interrupt_pending(map->intr);
	plat_ic_end_of_interrupt(intr_raw);
	state->pending_enables = true;

	return;
	}

	/*
	* We just received a shared event with routing set to ANY PE. The
	* interrupt can't be delegated on this PE as SDEI events are masked.
	* However, because its routing mode is ANY, it is possible that the
	* event can be delegated on any other PE that hasn't masked events.
	* Therefore, we set the interrupt back pending so as to give other
	* suitable PEs a chance of handling it.
	*/
	assert(plat_ic_is_spi(map->intr) != 0);
	plat_ic_set_interrupt_pending(map->intr);

	/*
	* Leaving the same interrupt pending also means that the same interrupt
	* can target this PE again as soon as this PE leaves EL3. Whether and
	* how often that happens depends on the implementation of GIC.
	*
	* We therefore call a platform handler to resolve this situation.
	*/
	plat_sdei_handle_masked_trigger(my_mpidr, map->intr);

	/* This PE is masked. We EOI the interrupt, as it can't be delegated */
	plat_ic_end_of_interrupt(intr_raw);
	}

	/* SDEI main interrupt handler */
	int sdei_intr_handler(uint32_t intr_raw, uint32_t flags, void *handle,
	void *cookie)
	{
	sdei_entry_t *se;
	cpu_context_t *ctx;
	sdei_ev_map_t *map;
	const sdei_dispatch_context_t *disp_ctx;
	unsigned int sec_state;
	sdei_cpu_state_t *state;
	uint32_t intr;
	struct jmpbuf dispatch_jmp;
	const uint64_t mpidr = read_mpidr_el1();

	/*
	* To handle an event, the following conditions must be true:
	*
	* 1. Event must be signalled
	* 2. Event must be enabled
	* 3. This PE must be a target PE for the event
	* 4. PE must be unmasked for SDEI
	* 5. If this is a normal event, no event must be running
	* 6. If this is a critical event, no critical event must be running
	*
	* (1) and (2) are true when this function is running
	* (3) is enforced in GIC by selecting the appropriate routing option
	* (4) is satisfied by client calling PE_UNMASK
	* (5) and (6) is enforced using interrupt priority, the RPR, in GIC:
	* - Normal SDEI events belong to Normal SDE priority class
	* - Critical SDEI events belong to Critical CSDE priority class
	*
	* The interrupt has already been acknowledged, and therefore is active,
	* so no other PE can handle this event while we are at it.
	*
	* Find if this is an SDEI interrupt. There must be an event mapped to
	* this interrupt
	*/
	intr = plat_ic_get_interrupt_id(intr_raw);
	map = find_event_map_by_intr(intr, (plat_ic_is_spi(intr) != 0));
	if (map == NULL) {
	ERROR("No SDEI map for interrupt %u\n", intr);
	panic();
	}

	/*
	* Received interrupt number must either correspond to event 0, or must
	* be bound interrupt.
	*/
	assert((map->ev_num == SDEI_EVENT_0) \|\| is_map_bound(map));

	se = get_event_entry(map);
	state = sdei_get_this_pe_state();

	if (state->pe_masked) {
	/*
	* Interrupts received while this PE was masked can't be
	* dispatched.
	*/
	SDEI_LOG("interrupt %u on %llx while PE masked\n", map->intr,
	mpidr);
	if (is_event_shared(map))
	sdei_map_lock(map);

	handle_masked_trigger(map, se, state, intr_raw);

	if (is_event_shared(map))
	sdei_map_unlock(map);

	return 0;
	}

	/* Insert load barrier for signalled SDEI event */
	if (map->ev_num == SDEI_EVENT_0)
	dmbld();

	if (is_event_shared(map))
	sdei_map_lock(map);

	/* Assert shared event routed to this PE had been configured so */
	if (is_event_shared(map) && (se->reg_flags == SDEI_REGF_RM_PE)) {
	assert(se->affinity == (mpidr & MPIDR_AFFINITY_MASK));
	}

	if (!can_sdei_state_trans(se, DO_DISPATCH)) {
	SDEI_LOG("SDEI event 0x%x can't be dispatched; state=0x%x\n",
	map->ev_num, se->state);

	/*
	* If the event is registered, leave the interrupt pending so
	* that it's delivered when the event is enabled.
	*/
	if (GET_EV_STATE(se, REGISTERED))
	plat_ic_set_interrupt_pending(map->intr);

	/*
	* The interrupt was disabled or unregistered after the handler
	* started to execute, which means now the interrupt is already
	* disabled and we just need to EOI the interrupt.
	*/
	plat_ic_end_of_interrupt(intr_raw);

	if (is_event_shared(map))
	sdei_map_unlock(map);

	return 0;
	}

	disp_ctx = get_outstanding_dispatch();
	if (is_event_critical(map)) {
	/*
	* If this event is Critical, and if there's an outstanding
	* dispatch, assert the latter is a Normal dispatch. Critical
	* events can preempt an outstanding Normal event dispatch.
	*/
	if (disp_ctx != NULL)
	assert(is_event_normal(disp_ctx->map));
	} else {
	/*
	* If this event is Normal, assert that there are no outstanding
	* dispatches. Normal events can't preempt any outstanding event
	* dispatches.
	*/
	assert(disp_ctx == NULL);
	}

	sec_state = get_interrupt_src_ss(flags);

	if (is_event_shared(map))
	sdei_map_unlock(map);

	SDEI_LOG("ACK %llx, ev:%d ss:%d spsr:%lx ELR:%lx\n", mpidr, map->ev_num,
	sec_state, read_spsr_el3(), read_elr_el3());

	ctx = handle;

	/*
	* Check if we interrupted secure state. Perform a context switch so
	* that we can delegate to NS.
	*/
	if (sec_state == SECURE) {
	save_secure_context();
	ctx = restore_and_resume_ns_context();
	}

	/* Synchronously dispatch event */
	setup_ns_dispatch(map, se, ctx, &dispatch_jmp);
	begin_sdei_synchronous_dispatch(&dispatch_jmp);

	/*
	* We reach here when client completes the event.
	*
	* If the cause of dispatch originally interrupted the Secure world, and
	* if Non-secure world wasn't allowed to preempt Secure execution,
	* resume Secure.
	*
	* No need to save the Non-secure context ahead of a world switch: the
	* Non-secure context was fully saved before dispatch, and has been
	* returned to its pre-dispatch state.
	*/
	if ((sec_state == SECURE) && (ehf_is_ns_preemption_allowed() == 0U))
	restore_and_resume_secure_context();

	/*
	* The event was dispatched after receiving SDEI interrupt. With
	* the event handling completed, EOI the corresponding
	* interrupt.
	*/
	if ((map->ev_num != SDEI_EVENT_0) && !is_map_bound(map)) {
	ERROR("Invalid SDEI mapping: ev=%u\n", map->ev_num);
	panic();
	}
	plat_ic_end_of_interrupt(intr_raw);

	return 0;
	}

	/*
	* Explicitly dispatch the given SDEI event.
	*
	* When calling this API, the caller must be prepared for the SDEI dispatcher to
	* restore and make Non-secure context as active. This call returns only after
	* the client has completed the dispatch. Then, the Non-secure context will be
	* active, and the following ERET will return to Non-secure.
	*
	* Should the caller require re-entry to Secure, it must restore the Secure
	* context and program registers for ERET.
	*/
	int sdei_dispatch_event(int ev_num)
	{
	sdei_entry_t *se;
	sdei_ev_map_t *map;
	cpu_context_t *ns_ctx;
	sdei_dispatch_context_t *disp_ctx;
	sdei_cpu_state_t *state;
	struct jmpbuf dispatch_jmp;

	/* Can't dispatch if events are masked on this PE */
	state = sdei_get_this_pe_state();
	if (state->pe_masked)
	return -1;

	/* Event 0 can't be dispatched */
	if (ev_num == SDEI_EVENT_0)
	return -1;

	/* Locate mapping corresponding to this event */
	map = find_event_map(ev_num);
	if (map == NULL)
	return -1;

	/* Only explicit events can be dispatched */
	if (!is_map_explicit(map))
	return -1;

	/* Examine state of dispatch stack */
	disp_ctx = get_outstanding_dispatch();
	if (disp_ctx != NULL) {
	/*
	* There's an outstanding dispatch. If the outstanding dispatch
	* is critical, no more dispatches are possible.
	*/
	if (is_event_critical(disp_ctx->map))
	return -1;

	/*
	* If the outstanding dispatch is Normal, only critical events
	* can be dispatched.
	*/
	if (is_event_normal(map))
	return -1;
	}

	se = get_event_entry(map);
	if (!can_sdei_state_trans(se, DO_DISPATCH))
	return -1;

	/* Activate the priority corresponding to the event being dispatched */
	ehf_activate_priority(sdei_event_priority(map));

	/*
	* Prepare for NS dispatch by restoring the Non-secure context and
	* marking that as active.
	*/
	ns_ctx = restore_and_resume_ns_context();

	/* Dispatch event synchronously */
	setup_ns_dispatch(map, se, ns_ctx, &dispatch_jmp);
	begin_sdei_synchronous_dispatch(&dispatch_jmp);

	/*
	* We reach here when client completes the event.
	*
	* Deactivate the priority level that was activated at the time of
	* explicit dispatch.
	*/
	ehf_deactivate_priority(sdei_event_priority(map));

	return 0;
	}

	static void end_sdei_synchronous_dispatch(struct jmpbuf *buffer)
	{
	longjmp(buffer);
	}

	int sdei_event_complete(bool resume, uint64_t pc)
	{
	sdei_dispatch_context_t *disp_ctx;
	sdei_entry_t *se;
	sdei_ev_map_t *map;
	cpu_context_t *ctx;
	sdei_action_t act;
	unsigned int client_el = sdei_client_el();

	/* Return error if called without an active event */
	disp_ctx = get_outstanding_dispatch();
	if (disp_ctx == NULL)
	return SDEI_EDENY;

	/* Validate resumption point */
	if (resume && (plat_sdei_validate_entry_point(pc, client_el) != 0))
	return SDEI_EDENY;

	map = disp_ctx->map;
	assert(map != NULL);
	se = get_event_entry(map);

	if (is_event_shared(map))
	sdei_map_lock(map);

	act = resume ? DO_COMPLETE_RESUME : DO_COMPLETE;
	if (!can_sdei_state_trans(se, act)) {
	if (is_event_shared(map))
	sdei_map_unlock(map);
	return SDEI_EDENY;
	}

	if (is_event_shared(map))
	sdei_map_unlock(map);

	/* Having done sanity checks, pop dispatch */
	(void) pop_dispatch();

	SDEI_LOG("EOI:%lx, %d spsr:%lx elr:%lx\n", read_mpidr_el1(),
	map->ev_num, read_spsr_el3(), read_elr_el3());

	/*
	* Restore Non-secure to how it was originally interrupted. Once done,
	* it's up-to-date with the saved copy.
	*/
	ctx = cm_get_context(NON_SECURE);
	restore_event_ctx(disp_ctx, ctx);

	if (resume) {
	/*
	* Complete-and-resume call. Prepare the Non-secure context
	* (currently active) for complete and resume.
	*/
	cm_set_elr_spsr_el3(NON_SECURE, pc, SPSR_64(client_el,
	MODE_SP_ELX, DISABLE_ALL_EXCEPTIONS));

	/*
	* Make it look as if a synchronous exception were taken at the
	* supplied Non-secure resumption point. Populate SPSR and
	* ELR_ELx so that an ERET from there works as expected.
	*
	* The assumption is that the client, if necessary, would have
	* saved any live content in these registers before making this
	* call.
	*/
	if (client_el == MODE_EL2) {
	write_elr_el2(disp_ctx->elr_el3);
	write_spsr_el2(disp_ctx->spsr_el3);
	} else {
	/* EL1 */
	write_elr_el1(disp_ctx->elr_el3);
	write_spsr_el1(disp_ctx->spsr_el3);
	}
	}

	/* End the outstanding dispatch */
	end_sdei_synchronous_dispatch(disp_ctx->dispatch_jmp);

	return 0;
	}

	int64_t sdei_event_context(void *handle, unsigned int param)
	{
	sdei_dispatch_context_t *disp_ctx;

	if (param >= SDEI_SAVED_GPREGS)
	return SDEI_EINVAL;

	/* Get outstanding dispatch on this CPU */
	disp_ctx = get_outstanding_dispatch();
	if (disp_ctx == NULL)
	return SDEI_EDENY;

	assert(disp_ctx->map != NULL);

	if (!can_sdei_state_trans(get_event_entry(disp_ctx->map), DO_CONTEXT))
	return SDEI_EDENY;

	/*
	* No locking is required for the Running status as this is the only CPU
	* which can complete the event
	*/

	return (int64_t) disp_ctx->x[param];
	}