drivers/arm/gic/v3/gicv3_main.c - filogic/atf - Gitiles

 /*
  * Copyright (c) 2015-2017, ARM Limited and Contributors. All rights reserved.
  *
  * SPDX-License-Identifier: BSD-3-Clause
  */

 #include <arch.h>
 #include <arch_helpers.h>
 #include <assert.h>
 #include <debug.h>
 #include <gicv3.h>
 #include "gicv3_private.h"

 const gicv3_driver_data_t *gicv3_driver_data;
 static unsigned int gicv2_compat;

 /*
  * Redistributor power operations are weakly bound so that they can be
  * overridden
  */
 #pragma weak gicv3_rdistif_off
 #pragma weak gicv3_rdistif_on


 /* Helper macros to save and restore GICD registers to and from the context */
 #define RESTORE_GICD_REGS(base, ctx, intr_num, reg, REG)		\
 	do {								\
 		for (unsigned int int_id = MIN_SPI_ID; int_id < intr_num; \
 				int_id += (1 << REG##_SHIFT)) {		\
 			gicd_write_##reg(base, int_id,			\
 				ctx->gicd_##reg[(int_id - MIN_SPI_ID) >> REG##_SHIFT]); \
 		}							\
 	} while (0)

 #define SAVE_GICD_REGS(base, ctx, intr_num, reg, REG)			\
 	do {								\
 		for (unsigned int int_id = MIN_SPI_ID; int_id < intr_num; \
 				int_id += (1 << REG##_SHIFT)) {		\
 			ctx->gicd_##reg[(int_id - MIN_SPI_ID) >> REG##_SHIFT] =\
 					gicd_read_##reg(base, int_id);	\
 		}							\
 	} while (0)


 /*******************************************************************************
  * This function initialises the ARM GICv3 driver in EL3 with provided platform
  * inputs.
  ******************************************************************************/
 void gicv3_driver_init(const gicv3_driver_data_t *plat_driver_data)
 {
 	unsigned int gic_version;

 	assert(plat_driver_data);
 	assert(plat_driver_data->gicd_base);
 	assert(plat_driver_data->gicr_base);
 	assert(plat_driver_data->rdistif_num);
 	assert(plat_driver_data->rdistif_base_addrs);

 	assert(IS_IN_EL3());

 	/*
 	 * The platform should provide a list of at least one type of
 	 * interrupts
 	 */
 	assert(plat_driver_data->g0_interrupt_array ||
 	       plat_driver_data->g1s_interrupt_array);

 	/*
 	 * If there are no interrupts of a particular type, then the number of
 	 * interrupts of that type should be 0 and vice-versa.
 	 */
 	assert(plat_driver_data->g0_interrupt_array ?
 	       plat_driver_data->g0_interrupt_num :
 	       plat_driver_data->g0_interrupt_num == 0);
 	assert(plat_driver_data->g1s_interrupt_array ?
 	       plat_driver_data->g1s_interrupt_num :
 	       plat_driver_data->g1s_interrupt_num == 0);

 	/* Check for system register support */
 #ifdef AARCH32
 	assert(read_id_pfr1() & (ID_PFR1_GIC_MASK << ID_PFR1_GIC_SHIFT));
 #else
 	assert(read_id_aa64pfr0_el1() &
 			(ID_AA64PFR0_GIC_MASK << ID_AA64PFR0_GIC_SHIFT));
 #endif /* AARCH32 */

 	/* The GIC version should be 3.0 */
 	gic_version = gicd_read_pidr2(plat_driver_data->gicd_base);
 	gic_version >>=	PIDR2_ARCH_REV_SHIFT;
 	gic_version &= PIDR2_ARCH_REV_MASK;
 	assert(gic_version == ARCH_REV_GICV3);

 	/*
 	 * Find out whether the GIC supports the GICv2 compatibility mode. The
 	 * ARE_S bit resets to 0 if supported
 	 */
 	gicv2_compat = gicd_read_ctlr(plat_driver_data->gicd_base);
 	gicv2_compat >>= CTLR_ARE_S_SHIFT;
 	gicv2_compat = !(gicv2_compat & CTLR_ARE_S_MASK);

 	/*
 	 * Find the base address of each implemented Redistributor interface.
 	 * The number of interfaces should be equal to the number of CPUs in the
 	 * system. The memory for saving these addresses has to be allocated by
 	 * the platform port
 	 */
 	gicv3_rdistif_base_addrs_probe(plat_driver_data->rdistif_base_addrs,
 					   plat_driver_data->rdistif_num,
 					   plat_driver_data->gicr_base,
 					   plat_driver_data->mpidr_to_core_pos);

 	gicv3_driver_data = plat_driver_data;

 	/*
 	 * The GIC driver data is initialized by the primary CPU with caches
 	 * enabled. When the secondary CPU boots up, it initializes the
 	 * GICC/GICR interface with the caches disabled. Hence flush the
 	 * driver data to ensure coherency. This is not required if the
 	 * platform has HW_ASSISTED_COHERENCY enabled.
 	 */
 #if !HW_ASSISTED_COHERENCY
 	flush_dcache_range((uintptr_t) &gicv3_driver_data,
 			sizeof(gicv3_driver_data));
 	flush_dcache_range((uintptr_t) gicv3_driver_data,
 			sizeof(*gicv3_driver_data));
 #endif

 	INFO("GICv3 %s legacy support detected."
 			" ARM GICV3 driver initialized in EL3\n",
 			gicv2_compat ? "with" : "without");
 }

 /*******************************************************************************
  * This function initialises the GIC distributor interface based upon the data
  * provided by the platform while initialising the driver.
  ******************************************************************************/
 void gicv3_distif_init(void)
 {
 	unsigned int bitmap = 0;

 	assert(gicv3_driver_data);
 	assert(gicv3_driver_data->gicd_base);
 	assert(gicv3_driver_data->g1s_interrupt_array ||
 	       gicv3_driver_data->g0_interrupt_array);

 	assert(IS_IN_EL3());

 	/*
 	 * Clear the "enable" bits for G0/G1S/G1NS interrupts before configuring
 	 * the ARE_S bit. The Distributor might generate a system error
 	 * otherwise.
 	 */
 	gicd_clr_ctlr(gicv3_driver_data->gicd_base,
 		      CTLR_ENABLE_G0_BIT |
 		      CTLR_ENABLE_G1S_BIT |
 		      CTLR_ENABLE_G1NS_BIT,
 		      RWP_TRUE);

 	/* Set the ARE_S and ARE_NS bit now that interrupts have been disabled */
 	gicd_set_ctlr(gicv3_driver_data->gicd_base,
 			CTLR_ARE_S_BIT | CTLR_ARE_NS_BIT, RWP_TRUE);

 	/* Set the default attribute of all SPIs */
 	gicv3_spis_configure_defaults(gicv3_driver_data->gicd_base);

 	/* Configure the G1S SPIs */
 	if (gicv3_driver_data->g1s_interrupt_array) {
 		gicv3_secure_spis_configure(gicv3_driver_data->gicd_base,
 					gicv3_driver_data->g1s_interrupt_num,
 					gicv3_driver_data->g1s_interrupt_array,
 					INTR_GROUP1S);
 		bitmap |= CTLR_ENABLE_G1S_BIT;
 	}

 	/* Configure the G0 SPIs */
 	if (gicv3_driver_data->g0_interrupt_array) {
 		gicv3_secure_spis_configure(gicv3_driver_data->gicd_base,
 					gicv3_driver_data->g0_interrupt_num,
 					gicv3_driver_data->g0_interrupt_array,
 					INTR_GROUP0);
 		bitmap |= CTLR_ENABLE_G0_BIT;
 	}

 	/* Enable the secure SPIs now that they have been configured */
 	gicd_set_ctlr(gicv3_driver_data->gicd_base, bitmap, RWP_TRUE);
 }

 /*******************************************************************************
  * This function initialises the GIC Redistributor interface of the calling CPU
  * (identified by the 'proc_num' parameter) based upon the data provided by the
  * platform while initialising the driver.
  ******************************************************************************/
 void gicv3_rdistif_init(unsigned int proc_num)
 {
 	uintptr_t gicr_base;

 	assert(gicv3_driver_data);
 	assert(proc_num < gicv3_driver_data->rdistif_num);
 	assert(gicv3_driver_data->rdistif_base_addrs);
 	assert(gicv3_driver_data->gicd_base);
 	assert(gicd_read_ctlr(gicv3_driver_data->gicd_base) & CTLR_ARE_S_BIT);
 	assert(gicv3_driver_data->g1s_interrupt_array ||
 	       gicv3_driver_data->g0_interrupt_array);

 	assert(IS_IN_EL3());

 	/* Power on redistributor */
 	gicv3_rdistif_on(proc_num);

 	gicr_base = gicv3_driver_data->rdistif_base_addrs[proc_num];

 	/* Set the default attribute of all SGIs and PPIs */
 	gicv3_ppi_sgi_configure_defaults(gicr_base);

 	/* Configure the G1S SGIs/PPIs */
 	if (gicv3_driver_data->g1s_interrupt_array) {
 		gicv3_secure_ppi_sgi_configure(gicr_base,
 					gicv3_driver_data->g1s_interrupt_num,
 					gicv3_driver_data->g1s_interrupt_array,
 					INTR_GROUP1S);
 	}

 	/* Configure the G0 SGIs/PPIs */
 	if (gicv3_driver_data->g0_interrupt_array) {
 		gicv3_secure_ppi_sgi_configure(gicr_base,
 					gicv3_driver_data->g0_interrupt_num,
 					gicv3_driver_data->g0_interrupt_array,
 					INTR_GROUP0);
 	}
 }

 /*******************************************************************************
  * Functions to perform power operations on GIC Redistributor
  ******************************************************************************/
 void gicv3_rdistif_off(unsigned int proc_num)
 {
 	return;
 }

 void gicv3_rdistif_on(unsigned int proc_num)
 {
 	return;
 }

 /*******************************************************************************
  * This function enables the GIC CPU interface of the calling CPU using only
  * system register accesses.
  ******************************************************************************/
 void gicv3_cpuif_enable(unsigned int proc_num)
 {
 	uintptr_t gicr_base;
 	unsigned int scr_el3;
 	unsigned int icc_sre_el3;

 	assert(gicv3_driver_data);
 	assert(proc_num < gicv3_driver_data->rdistif_num);
 	assert(gicv3_driver_data->rdistif_base_addrs);
 	assert(IS_IN_EL3());

 	/* Mark the connected core as awake */
 	gicr_base = gicv3_driver_data->rdistif_base_addrs[proc_num];
 	gicv3_rdistif_mark_core_awake(gicr_base);

 	/* Disable the legacy interrupt bypass */
 	icc_sre_el3 = ICC_SRE_DIB_BIT | ICC_SRE_DFB_BIT;

 	/*
 	 * Enable system register access for EL3 and allow lower exception
 	 * levels to configure the same for themselves. If the legacy mode is
 	 * not supported, the SRE bit is RAO/WI
 	 */
 	icc_sre_el3 |= (ICC_SRE_EN_BIT | ICC_SRE_SRE_BIT);
 	write_icc_sre_el3(read_icc_sre_el3() | icc_sre_el3);

 	scr_el3 = read_scr_el3();

 	/*
 	 * Switch to NS state to write Non secure ICC_SRE_EL1 and
 	 * ICC_SRE_EL2 registers.
 	 */
 	write_scr_el3(scr_el3 | SCR_NS_BIT);
 	isb();

 	write_icc_sre_el2(read_icc_sre_el2() | icc_sre_el3);
 	write_icc_sre_el1(ICC_SRE_SRE_BIT);
 	isb();

 	/* Switch to secure state. */
 	write_scr_el3(scr_el3 & (~SCR_NS_BIT));
 	isb();

 	/* Program the idle priority in the PMR */
 	write_icc_pmr_el1(GIC_PRI_MASK);

 	/* Enable Group0 interrupts */
 	write_icc_igrpen0_el1(IGRPEN1_EL1_ENABLE_G0_BIT);

 	/* Enable Group1 Secure interrupts */
 	write_icc_igrpen1_el3(read_icc_igrpen1_el3() |
 				IGRPEN1_EL3_ENABLE_G1S_BIT);

 	/* Write the secure ICC_SRE_EL1 register */
 	write_icc_sre_el1(ICC_SRE_SRE_BIT);
 	isb();
 }

 /*******************************************************************************
  * This function disables the GIC CPU interface of the calling CPU using
  * only system register accesses.
  ******************************************************************************/
 void gicv3_cpuif_disable(unsigned int proc_num)
 {
 	uintptr_t gicr_base;

 	assert(gicv3_driver_data);
 	assert(proc_num < gicv3_driver_data->rdistif_num);
 	assert(gicv3_driver_data->rdistif_base_addrs);

 	assert(IS_IN_EL3());

 	/* Disable legacy interrupt bypass */
 	write_icc_sre_el3(read_icc_sre_el3() |
 			  (ICC_SRE_DIB_BIT | ICC_SRE_DFB_BIT));

 	/* Disable Group0 interrupts */
 	write_icc_igrpen0_el1(read_icc_igrpen0_el1() &
 			      ~IGRPEN1_EL1_ENABLE_G0_BIT);

 	/* Disable Group1 Secure and Non-Secure interrupts */
 	write_icc_igrpen1_el3(read_icc_igrpen1_el3() &
 			      ~(IGRPEN1_EL3_ENABLE_G1NS_BIT |
 			      IGRPEN1_EL3_ENABLE_G1S_BIT));

 	/* Synchronise accesses to group enable registers */
 	isb();

 	/* Mark the connected core as asleep */
 	gicr_base = gicv3_driver_data->rdistif_base_addrs[proc_num];
 	gicv3_rdistif_mark_core_asleep(gicr_base);
 }

 /*******************************************************************************
  * This function returns the id of the highest priority pending interrupt at
  * the GIC cpu interface.
  ******************************************************************************/
 unsigned int gicv3_get_pending_interrupt_id(void)
 {
 	unsigned int id;

 	assert(IS_IN_EL3());
 	id = read_icc_hppir0_el1() & HPPIR0_EL1_INTID_MASK;

 	/*
 	 * If the ID is special identifier corresponding to G1S or G1NS
 	 * interrupt, then read the highest pending group 1 interrupt.
 	 */
 	if ((id == PENDING_G1S_INTID) || (id == PENDING_G1NS_INTID))
 		return read_icc_hppir1_el1() & HPPIR1_EL1_INTID_MASK;

 	return id;
 }

 /*******************************************************************************
  * This function returns the type of the highest priority pending interrupt at
  * the GIC cpu interface. The return values can be one of the following :
  *   PENDING_G1S_INTID  : The interrupt type is secure Group 1.
  *   PENDING_G1NS_INTID : The interrupt type is non secure Group 1.
  *   0 - 1019           : The interrupt type is secure Group 0.
  *   GIC_SPURIOUS_INTERRUPT : there is no pending interrupt with
  *                            sufficient priority to be signaled
  ******************************************************************************/
 unsigned int gicv3_get_pending_interrupt_type(void)
 {
 	assert(IS_IN_EL3());
 	return read_icc_hppir0_el1() & HPPIR0_EL1_INTID_MASK;
 }

 /*******************************************************************************
  * This function returns the type of the interrupt id depending upon the group
  * this interrupt has been configured under by the interrupt controller i.e.
  * group0 or group1 Secure / Non Secure. The return value can be one of the
  * following :
  *    INTR_GROUP0  : The interrupt type is a Secure Group 0 interrupt
  *    INTR_GROUP1S : The interrupt type is a Secure Group 1 secure interrupt
  *    INTR_GROUP1NS: The interrupt type is a Secure Group 1 non secure
  *                   interrupt.
  ******************************************************************************/
 unsigned int gicv3_get_interrupt_type(unsigned int id,
 					  unsigned int proc_num)
 {
 	unsigned int igroup, grpmodr;
 	uintptr_t gicr_base;

 	assert(IS_IN_EL3());
 	assert(gicv3_driver_data);

 	/* Ensure the parameters are valid */
 	assert(id < PENDING_G1S_INTID || id >= MIN_LPI_ID);
 	assert(proc_num < gicv3_driver_data->rdistif_num);

 	/* All LPI interrupts are Group 1 non secure */
 	if (id >= MIN_LPI_ID)
 		return INTR_GROUP1NS;

 	if (id < MIN_SPI_ID) {
 		assert(gicv3_driver_data->rdistif_base_addrs);
 		gicr_base = gicv3_driver_data->rdistif_base_addrs[proc_num];
 		igroup = gicr_get_igroupr0(gicr_base, id);
 		grpmodr = gicr_get_igrpmodr0(gicr_base, id);
 	} else {
 		assert(gicv3_driver_data->gicd_base);
 		igroup = gicd_get_igroupr(gicv3_driver_data->gicd_base, id);
 		grpmodr = gicd_get_igrpmodr(gicv3_driver_data->gicd_base, id);
 	}

 	/*
 	 * If the IGROUP bit is set, then it is a Group 1 Non secure
 	 * interrupt
 	 */
 	if (igroup)
 		return INTR_GROUP1NS;

 	/* If the GRPMOD bit is set, then it is a Group 1 Secure interrupt */
 	if (grpmodr)
 		return INTR_GROUP1S;

 	/* Else it is a Group 0 Secure interrupt */
 	return INTR_GROUP0;
 }

 /*****************************************************************************
  * Function to save and disable the GIC ITS register context. The power
  * management of GIC ITS is implementation-defined and this function doesn't
  * save any memory structures required to support ITS. As the sequence to save
  * this state is implementation defined, it should be executed in platform
  * specific code. Calling this function alone and then powering down the GIC and
  * ITS without implementing the aforementioned platform specific code will
  * corrupt the ITS state.
  *
  * This function must be invoked after the GIC CPU interface is disabled.
  *****************************************************************************/
 void gicv3_its_save_disable(uintptr_t gits_base, gicv3_its_ctx_t * const its_ctx)
 {
 	int i;

 	assert(gicv3_driver_data);
 	assert(IS_IN_EL3());
 	assert(its_ctx);
 	assert(gits_base);

 	its_ctx->gits_ctlr = gits_read_ctlr(gits_base);

 	/* Disable the ITS */
 	gits_write_ctlr(gits_base, its_ctx->gits_ctlr &
 					(~GITS_CTLR_ENABLED_BIT));

 	/* Wait for quiescent state */
 	gits_wait_for_quiescent_bit(gits_base);

 	its_ctx->gits_cbaser = gits_read_cbaser(gits_base);
 	its_ctx->gits_cwriter = gits_read_cwriter(gits_base);

 	for (i = 0; i < ARRAY_SIZE(its_ctx->gits_baser); i++)
 		its_ctx->gits_baser[i] = gits_read_baser(gits_base, i);
 }

 /*****************************************************************************
  * Function to restore the GIC ITS register context. The power
  * management of GIC ITS is implementation defined and this function doesn't
  * restore any memory structures required to support ITS. The assumption is
  * that these structures are in memory and are retained during system suspend.
  *
  * This must be invoked before the GIC CPU interface is enabled.
  *****************************************************************************/
 void gicv3_its_restore(uintptr_t gits_base, const gicv3_its_ctx_t * const its_ctx)
 {
 	int i;

 	assert(gicv3_driver_data);
 	assert(IS_IN_EL3());
 	assert(its_ctx);
 	assert(gits_base);

 	/* Assert that the GITS is disabled and quiescent */
 	assert((gits_read_ctlr(gits_base) & GITS_CTLR_ENABLED_BIT) == 0);
 	assert((gits_read_ctlr(gits_base) & GITS_CTLR_QUIESCENT_BIT) == 1);

 	gits_write_cbaser(gits_base, its_ctx->gits_cbaser);
 	gits_write_cwriter(gits_base, its_ctx->gits_cwriter);

 	for (i = 0; i < ARRAY_SIZE(its_ctx->gits_baser); i++)
 		gits_write_baser(gits_base, i, its_ctx->gits_baser[i]);

 	/* Restore the ITS CTLR but leave the ITS disabled */
 	gits_write_ctlr(gits_base, its_ctx->gits_ctlr &
 			(~GITS_CTLR_ENABLED_BIT));
 }

 /*****************************************************************************
  * Function to save the GIC Redistributor register context. This function
  * must be invoked after CPU interface disable and prior to Distributor save.
  *****************************************************************************/
 void gicv3_rdistif_save(unsigned int proc_num, gicv3_redist_ctx_t * const rdist_ctx)
 {
 	uintptr_t gicr_base;
 	unsigned int int_id;

 	assert(gicv3_driver_data);
 	assert(proc_num < gicv3_driver_data->rdistif_num);
 	assert(gicv3_driver_data->rdistif_base_addrs);
 	assert(IS_IN_EL3());
 	assert(rdist_ctx);

 	gicr_base = gicv3_driver_data->rdistif_base_addrs[proc_num];

 	/*
 	 * Wait for any write to GICR_CTLR to complete before trying to save any
 	 * state.
 	 */
 	gicr_wait_for_pending_write(gicr_base);

 	rdist_ctx->gicr_ctlr = gicr_read_ctlr(gicr_base);

 	rdist_ctx->gicr_propbaser = gicr_read_propbaser(gicr_base);
 	rdist_ctx->gicr_pendbaser = gicr_read_pendbaser(gicr_base);

 	rdist_ctx->gicr_igroupr0 = gicr_read_igroupr0(gicr_base);
 	rdist_ctx->gicr_isenabler0 = gicr_read_isenabler0(gicr_base);
 	rdist_ctx->gicr_ispendr0 = gicr_read_ispendr0(gicr_base);
 	rdist_ctx->gicr_isactiver0 = gicr_read_isactiver0(gicr_base);
 	rdist_ctx->gicr_icfgr0 = gicr_read_icfgr0(gicr_base);
 	rdist_ctx->gicr_icfgr1 = gicr_read_icfgr1(gicr_base);
 	rdist_ctx->gicr_igrpmodr0 = gicr_read_igrpmodr0(gicr_base);
 	rdist_ctx->gicr_nsacr = gicr_read_nsacr(gicr_base);
 	for (int_id = MIN_SGI_ID; int_id < TOTAL_PCPU_INTR_NUM;
 			int_id += (1 << IPRIORITYR_SHIFT)) {
 		rdist_ctx->gicr_ipriorityr[(int_id - MIN_SGI_ID) >> IPRIORITYR_SHIFT] =
 				gicr_read_ipriorityr(gicr_base, int_id);
 	}


 	/*
 	 * Call the pre-save hook that implements the IMP DEF sequence that may
 	 * be required on some GIC implementations. As this may need to access
 	 * the Redistributor registers, we pass it proc_num.
 	 */
 	gicv3_distif_pre_save(proc_num);
 }

 /*****************************************************************************
  * Function to restore the GIC Redistributor register context. We disable
  * LPI and per-cpu interrupts before we start restore of the Redistributor.
  * This function must be invoked after Distributor restore but prior to
  * CPU interface enable. The pending and active interrupts are restored
  * after the interrupts are fully configured and enabled.
  *****************************************************************************/
 void gicv3_rdistif_init_restore(unsigned int proc_num,
 				const gicv3_redist_ctx_t * const rdist_ctx)
 {
 	uintptr_t gicr_base;
 	unsigned int int_id;

 	assert(gicv3_driver_data);
 	assert(proc_num < gicv3_driver_data->rdistif_num);
 	assert(gicv3_driver_data->rdistif_base_addrs);
 	assert(IS_IN_EL3());
 	assert(rdist_ctx);

 	gicr_base = gicv3_driver_data->rdistif_base_addrs[proc_num];

 	/* Power on redistributor */
 	gicv3_rdistif_on(proc_num);

 	/*
 	 * Call the post-restore hook that implements the IMP DEF sequence that
 	 * may be required on some GIC implementations. As this may need to
 	 * access the Redistributor registers, we pass it proc_num.
 	 */
 	gicv3_distif_post_restore(proc_num);

 	/*
 	 * Disable all SGIs (imp. def.)/PPIs before configuring them. This is a
 	 * more scalable approach as it avoids clearing the enable bits in the
 	 * GICD_CTLR
 	 */
 	gicr_write_icenabler0(gicr_base, ~0);
 	/* Wait for pending writes to GICR_ICENABLER */
 	gicr_wait_for_pending_write(gicr_base);

 	/*
 	 * Disable the LPIs to avoid unpredictable behavior when writing to
 	 * GICR_PROPBASER and GICR_PENDBASER.
 	 */
 	gicr_write_ctlr(gicr_base,
 			rdist_ctx->gicr_ctlr & ~(GICR_CTLR_EN_LPIS_BIT));

 	/* Restore registers' content */
 	gicr_write_propbaser(gicr_base, rdist_ctx->gicr_propbaser);
 	gicr_write_pendbaser(gicr_base, rdist_ctx->gicr_pendbaser);

 	gicr_write_igroupr0(gicr_base, rdist_ctx->gicr_igroupr0);

 	for (int_id = MIN_SGI_ID; int_id < TOTAL_PCPU_INTR_NUM;
 			int_id += (1 << IPRIORITYR_SHIFT)) {
 		gicr_write_ipriorityr(gicr_base, int_id,
 		rdist_ctx->gicr_ipriorityr[
 				(int_id - MIN_SGI_ID) >> IPRIORITYR_SHIFT]);
 	}

 	gicr_write_icfgr0(gicr_base, rdist_ctx->gicr_icfgr0);
 	gicr_write_icfgr1(gicr_base, rdist_ctx->gicr_icfgr1);
 	gicr_write_igrpmodr0(gicr_base, rdist_ctx->gicr_igrpmodr0);
 	gicr_write_nsacr(gicr_base, rdist_ctx->gicr_nsacr);

 	/* Restore after group and priorities are set */
 	gicr_write_ispendr0(gicr_base, rdist_ctx->gicr_ispendr0);
 	gicr_write_isactiver0(gicr_base, rdist_ctx->gicr_isactiver0);

 	/*
 	 * Wait for all writes to the Distributor to complete before enabling
 	 * the SGI and PPIs.
 	 */
 	gicr_wait_for_upstream_pending_write(gicr_base);
 	gicr_write_isenabler0(gicr_base, rdist_ctx->gicr_isenabler0);

 	/*
 	 * Restore GICR_CTLR.Enable_LPIs bit and wait for pending writes in case
 	 * the first write to GICR_CTLR was still in flight (this write only
 	 * restores GICR_CTLR.Enable_LPIs and no waiting is required for this
 	 * bit).
 	 */
 	gicr_write_ctlr(gicr_base, rdist_ctx->gicr_ctlr);
 	gicr_wait_for_pending_write(gicr_base);
 }

 /*****************************************************************************
  * Function to save the GIC Distributor register context. This function
  * must be invoked after CPU interface disable and Redistributor save.
  *****************************************************************************/
 void gicv3_distif_save(gicv3_dist_ctx_t * const dist_ctx)
 {
 	unsigned int num_ints;

 	assert(gicv3_driver_data);
 	assert(gicv3_driver_data->gicd_base);
 	assert(IS_IN_EL3());
 	assert(dist_ctx);

 	uintptr_t gicd_base = gicv3_driver_data->gicd_base;

 	num_ints = gicd_read_typer(gicd_base);
 	num_ints &= TYPER_IT_LINES_NO_MASK;
 	num_ints = (num_ints + 1) << 5;

 	assert(num_ints <= MAX_SPI_ID + 1);

 	/* Wait for pending write to complete */
 	gicd_wait_for_pending_write(gicd_base);

 	/* Save the GICD_CTLR */
 	dist_ctx->gicd_ctlr = gicd_read_ctlr(gicd_base);

 	/* Save GICD_IGROUPR for INTIDs 32 - 1020 */
 	SAVE_GICD_REGS(gicd_base, dist_ctx, num_ints, igroupr, IGROUPR);

 	/* Save GICD_ISENABLER for INT_IDs 32 - 1020 */
 	SAVE_GICD_REGS(gicd_base, dist_ctx, num_ints, isenabler, ISENABLER);

 	/* Save GICD_ISPENDR for INTIDs 32 - 1020 */
 	SAVE_GICD_REGS(gicd_base, dist_ctx, num_ints, ispendr, ISPENDR);

 	/* Save GICD_ISACTIVER for INTIDs 32 - 1020 */
 	SAVE_GICD_REGS(gicd_base, dist_ctx, num_ints, isactiver, ISACTIVER);

 	/* Save GICD_IPRIORITYR for INTIDs 32 - 1020 */
 	SAVE_GICD_REGS(gicd_base, dist_ctx, num_ints, ipriorityr, IPRIORITYR);

 	/* Save GICD_ICFGR for INTIDs 32 - 1020 */
 	SAVE_GICD_REGS(gicd_base, dist_ctx, num_ints, icfgr, ICFGR);

 	/* Save GICD_IGRPMODR for INTIDs 32 - 1020 */
 	SAVE_GICD_REGS(gicd_base, dist_ctx, num_ints, igrpmodr, IGRPMODR);

 	/* Save GICD_NSACR for INTIDs 32 - 1020 */
 	SAVE_GICD_REGS(gicd_base, dist_ctx, num_ints, nsacr, NSACR);

 	/* Save GICD_IROUTER for INTIDs 32 - 1024 */
 	SAVE_GICD_REGS(gicd_base, dist_ctx, num_ints, irouter, IROUTER);

 	/*
 	 * GICD_ITARGETSR<n> and GICD_SPENDSGIR<n> are RAZ/WI when
 	 * GICD_CTLR.ARE_(S|NS) bits are set which is the case for our GICv3
 	 * driver.
 	 */
 }

 /*****************************************************************************
  * Function to restore the GIC Distributor register context. We disable G0, G1S
  * and G1NS interrupt groups before we start restore of the Distributor. This
  * function must be invoked prior to Redistributor restore and CPU interface
  * enable. The pending and active interrupts are restored after the interrupts
  * are fully configured and enabled.
  *****************************************************************************/
 void gicv3_distif_init_restore(const gicv3_dist_ctx_t * const dist_ctx)
 {
 	unsigned int num_ints = 0;

 	assert(gicv3_driver_data);
 	assert(gicv3_driver_data->gicd_base);
 	assert(IS_IN_EL3());
 	assert(dist_ctx);

 	uintptr_t gicd_base = gicv3_driver_data->gicd_base;

 	/*
 	 * Clear the "enable" bits for G0/G1S/G1NS interrupts before configuring
 	 * the ARE_S bit. The Distributor might generate a system error
 	 * otherwise.
 	 */
 	gicd_clr_ctlr(gicd_base,
 		      CTLR_ENABLE_G0_BIT |
 		      CTLR_ENABLE_G1S_BIT |
 		      CTLR_ENABLE_G1NS_BIT,
 		      RWP_TRUE);

 	/* Set the ARE_S and ARE_NS bit now that interrupts have been disabled */
 	gicd_set_ctlr(gicd_base, CTLR_ARE_S_BIT | CTLR_ARE_NS_BIT, RWP_TRUE);

 	num_ints = gicd_read_typer(gicd_base);
 	num_ints &= TYPER_IT_LINES_NO_MASK;
 	num_ints = (num_ints + 1) << 5;

 	assert(num_ints <= MAX_SPI_ID + 1);

 	/* Restore GICD_IGROUPR for INTIDs 32 - 1020 */
 	RESTORE_GICD_REGS(gicd_base, dist_ctx, num_ints, igroupr, IGROUPR);

 	/* Restore GICD_IPRIORITYR for INTIDs 32 - 1020 */
 	RESTORE_GICD_REGS(gicd_base, dist_ctx, num_ints, ipriorityr, IPRIORITYR);

 	/* Restore GICD_ICFGR for INTIDs 32 - 1020 */
 	RESTORE_GICD_REGS(gicd_base, dist_ctx, num_ints, icfgr, ICFGR);

 	/* Restore GICD_IGRPMODR for INTIDs 32 - 1020 */
 	RESTORE_GICD_REGS(gicd_base, dist_ctx, num_ints, igrpmodr, IGRPMODR);

 	/* Restore GICD_NSACR for INTIDs 32 - 1020 */
 	RESTORE_GICD_REGS(gicd_base, dist_ctx, num_ints, nsacr, NSACR);

 	/* Restore GICD_IROUTER for INTIDs 32 - 1020 */
 	RESTORE_GICD_REGS(gicd_base, dist_ctx, num_ints, irouter, IROUTER);

 	/*
 	 * Restore ISENABLER, ISPENDR and ISACTIVER after the interrupts are
 	 * configured.
 	 */

 	/* Restore GICD_ISENABLER for INT_IDs 32 - 1020 */
 	RESTORE_GICD_REGS(gicd_base, dist_ctx, num_ints, isenabler, ISENABLER);

 	/* Restore GICD_ISPENDR for INTIDs 32 - 1020 */
 	RESTORE_GICD_REGS(gicd_base, dist_ctx, num_ints, ispendr, ISPENDR);

 	/* Restore GICD_ISACTIVER for INTIDs 32 - 1020 */
 	RESTORE_GICD_REGS(gicd_base, dist_ctx, num_ints, isactiver, ISACTIVER);

 	/* Restore the GICD_CTLR */
 	gicd_write_ctlr(gicd_base, dist_ctx->gicd_ctlr);
 	gicd_wait_for_pending_write(gicd_base);

 }