drivers/arm/gic/v3/gicv3_helpers.c - tf-a-mtk - Git at Google

 /*
  * Copyright (c) 2015-2018, ARM Limited and Contributors. All rights reserved.
  *
  * SPDX-License-Identifier: BSD-3-Clause
  */

 #include <assert.h>

 #include <arch.h>
 #include <arch_helpers.h>
 #include <common/debug.h>
 #include <common/interrupt_props.h>
 #include <drivers/arm/gic_common.h>

 #include "../common/gic_common_private.h"
 #include "gicv3_private.h"

 /*
  * Accessor to read the GIC Distributor IGRPMODR corresponding to the
  * interrupt `id`, 32 interrupt IDs at a time.
  */
 unsigned int gicd_read_igrpmodr(uintptr_t base, unsigned int id)
 {
 	unsigned int n = id >> IGRPMODR_SHIFT;

 	return mmio_read_32(base + GICD_IGRPMODR + (n << 2));
 }

 /*
  * Accessor to write the GIC Distributor IGRPMODR corresponding to the
  * interrupt `id`, 32 interrupt IDs at a time.
  */
 void gicd_write_igrpmodr(uintptr_t base, unsigned int id, unsigned int val)
 {
 	unsigned int n = id >> IGRPMODR_SHIFT;

 	mmio_write_32(base + GICD_IGRPMODR + (n << 2), val);
 }

 /*
  * Accessor to get the bit corresponding to interrupt ID
  * in GIC Distributor IGRPMODR.
  */
 unsigned int gicd_get_igrpmodr(uintptr_t base, unsigned int id)
 {
 	unsigned int bit_num = id & ((1U << IGRPMODR_SHIFT) - 1U);
 	unsigned int reg_val = gicd_read_igrpmodr(base, id);

 	return (reg_val >> bit_num) & 0x1U;
 }

 /*
  * Accessor to set the bit corresponding to interrupt ID
  * in GIC Distributor IGRPMODR.
  */
 void gicd_set_igrpmodr(uintptr_t base, unsigned int id)
 {
 	unsigned int bit_num = id & ((1U << IGRPMODR_SHIFT) - 1U);
 	unsigned int reg_val = gicd_read_igrpmodr(base, id);

 	gicd_write_igrpmodr(base, id, reg_val | (1U << bit_num));
 }

 /*
  * Accessor to clear the bit corresponding to interrupt ID
  * in GIC Distributor IGRPMODR.
  */
 void gicd_clr_igrpmodr(uintptr_t base, unsigned int id)
 {
 	unsigned int bit_num = id & ((1U << IGRPMODR_SHIFT) - 1U);
 	unsigned int reg_val = gicd_read_igrpmodr(base, id);

 	gicd_write_igrpmodr(base, id, reg_val & ~(1U << bit_num));
 }

 /*
  * Accessor to read the GIC Re-distributor IPRIORITYR corresponding to the
  * interrupt `id`, 4 interrupts IDs at a time.
  */
 unsigned int gicr_read_ipriorityr(uintptr_t base, unsigned int id)
 {
 	unsigned int n = id >> IPRIORITYR_SHIFT;

 	return mmio_read_32(base + GICR_IPRIORITYR + (n << 2));
 }

 /*
  * Accessor to write the GIC Re-distributor IPRIORITYR corresponding to the
  * interrupt `id`, 4 interrupts IDs at a time.
  */
 void gicr_write_ipriorityr(uintptr_t base, unsigned int id, unsigned int val)
 {
 	unsigned int n = id >> IPRIORITYR_SHIFT;

 	mmio_write_32(base + GICR_IPRIORITYR + (n << 2), val);
 }

 /*
  * Accessor to get the bit corresponding to interrupt ID
  * from GIC Re-distributor IGROUPR0.
  */
 unsigned int gicr_get_igroupr0(uintptr_t base, unsigned int id)
 {
 	unsigned int bit_num = id & ((1U << IGROUPR_SHIFT) - 1U);
 	unsigned int reg_val = gicr_read_igroupr0(base);

 	return (reg_val >> bit_num) & 0x1U;
 }

 /*
  * Accessor to set the bit corresponding to interrupt ID
  * in GIC Re-distributor IGROUPR0.
  */
 void gicr_set_igroupr0(uintptr_t base, unsigned int id)
 {
 	unsigned int bit_num = id & ((1U << IGROUPR_SHIFT) - 1U);
 	unsigned int reg_val = gicr_read_igroupr0(base);

 	gicr_write_igroupr0(base, reg_val | (1U << bit_num));
 }

 /*
  * Accessor to clear the bit corresponding to interrupt ID
  * in GIC Re-distributor IGROUPR0.
  */
 void gicr_clr_igroupr0(uintptr_t base, unsigned int id)
 {
 	unsigned int bit_num = id & ((1U << IGROUPR_SHIFT) - 1U);
 	unsigned int reg_val = gicr_read_igroupr0(base);

 	gicr_write_igroupr0(base, reg_val & ~(1U << bit_num));
 }

 /*
  * Accessor to get the bit corresponding to interrupt ID
  * from GIC Re-distributor IGRPMODR0.
  */
 unsigned int gicr_get_igrpmodr0(uintptr_t base, unsigned int id)
 {
 	unsigned int bit_num = id & ((1U << IGRPMODR_SHIFT) - 1U);
 	unsigned int reg_val = gicr_read_igrpmodr0(base);

 	return (reg_val >> bit_num) & 0x1U;
 }

 /*
  * Accessor to set the bit corresponding to interrupt ID
  * in GIC Re-distributor IGRPMODR0.
  */
 void gicr_set_igrpmodr0(uintptr_t base, unsigned int id)
 {
 	unsigned int bit_num = id & ((1U << IGRPMODR_SHIFT) - 1U);
 	unsigned int reg_val = gicr_read_igrpmodr0(base);

 	gicr_write_igrpmodr0(base, reg_val | (1U << bit_num));
 }

 /*
  * Accessor to clear the bit corresponding to interrupt ID
  * in GIC Re-distributor IGRPMODR0.
  */
 void gicr_clr_igrpmodr0(uintptr_t base, unsigned int id)
 {
 	unsigned int bit_num = id & ((1U << IGRPMODR_SHIFT) - 1U);
 	unsigned int reg_val = gicr_read_igrpmodr0(base);

 	gicr_write_igrpmodr0(base, reg_val & ~(1U << bit_num));
 }

 /*
  * Accessor to set the bit corresponding to interrupt ID
  * in GIC Re-distributor ISENABLER0.
  */
 void gicr_set_isenabler0(uintptr_t base, unsigned int id)
 {
 	unsigned int bit_num = id & ((1U << ISENABLER_SHIFT) - 1U);

 	gicr_write_isenabler0(base, (1U << bit_num));
 }

 /*
  * Accessor to set the bit corresponding to interrupt ID in GIC Re-distributor
  * ICENABLER0.
  */
 void gicr_set_icenabler0(uintptr_t base, unsigned int id)
 {
 	unsigned int bit_num = id & ((1U << ICENABLER_SHIFT) - 1U);

 	gicr_write_icenabler0(base, (1U << bit_num));
 }

 /*
  * Accessor to set the bit corresponding to interrupt ID in GIC Re-distributor
  * ISACTIVER0.
  */
 unsigned int gicr_get_isactiver0(uintptr_t base, unsigned int id)
 {
 	unsigned int bit_num = id & ((1U << ISACTIVER_SHIFT) - 1U);
 	unsigned int reg_val = gicr_read_isactiver0(base);

 	return (reg_val >> bit_num) & 0x1U;
 }

 /*
  * Accessor to clear the bit corresponding to interrupt ID in GIC Re-distributor
  * ICPENDRR0.
  */
 void gicr_set_icpendr0(uintptr_t base, unsigned int id)
 {
 	unsigned int bit_num = id & ((1U << ICPENDR_SHIFT) - 1U);

 	gicr_write_icpendr0(base, (1U << bit_num));
 }

 /*
  * Accessor to set the bit corresponding to interrupt ID in GIC Re-distributor
  * ISPENDR0.
  */
 void gicr_set_ispendr0(uintptr_t base, unsigned int id)
 {
 	unsigned int bit_num = id & ((1U << ISPENDR_SHIFT) - 1U);

 	gicr_write_ispendr0(base, (1U << bit_num));
 }

 /*
  * Accessor to set the byte corresponding to interrupt ID
  * in GIC Re-distributor IPRIORITYR.
  */
 void gicr_set_ipriorityr(uintptr_t base, unsigned int id, unsigned int pri)
 {
 	uint8_t val = pri & GIC_PRI_MASK;

 	mmio_write_8(base + GICR_IPRIORITYR + id, val);
 }

 /*
  * Accessor to set the bit fields corresponding to interrupt ID
  * in GIC Re-distributor ICFGR0.
  */
 void gicr_set_icfgr0(uintptr_t base, unsigned int id, unsigned int cfg)
 {
 	/* Interrupt configuration is a 2-bit field */
 	unsigned int bit_num = id & ((1U << ICFGR_SHIFT) - 1U);
 	unsigned int bit_shift = bit_num << 1U;

 	uint32_t reg_val = gicr_read_icfgr0(base);

 	/* Clear the field, and insert required configuration */
 	reg_val &= ~(GIC_CFG_MASK << bit_shift);
 	reg_val |= ((cfg & GIC_CFG_MASK) << bit_shift);

 	gicr_write_icfgr0(base, reg_val);
 }

 /*
  * Accessor to set the bit fields corresponding to interrupt ID
  * in GIC Re-distributor ICFGR1.
  */
 void gicr_set_icfgr1(uintptr_t base, unsigned int id, unsigned int cfg)
 {
 	/* Interrupt configuration is a 2-bit field */
 	unsigned int bit_num = id & ((1U << ICFGR_SHIFT) - 1U);
 	unsigned int bit_shift = bit_num << 1U;

 	uint32_t reg_val = gicr_read_icfgr1(base);

 	/* Clear the field, and insert required configuration */
 	reg_val &= ~(GIC_CFG_MASK << bit_shift);
 	reg_val |= ((cfg & GIC_CFG_MASK) << bit_shift);

 	gicr_write_icfgr1(base, reg_val);
 }

 /******************************************************************************
  * This function marks the core as awake in the re-distributor and
  * ensures that the interface is active.
  *****************************************************************************/
 void gicv3_rdistif_mark_core_awake(uintptr_t gicr_base)
 {
 	/*
 	 * The WAKER_PS_BIT should be changed to 0
 	 * only when WAKER_CA_BIT is 1.
 	 */
 	assert((gicr_read_waker(gicr_base) & WAKER_CA_BIT) != 0U);

 	/* Mark the connected core as awake */
 	gicr_write_waker(gicr_base, gicr_read_waker(gicr_base) & ~WAKER_PS_BIT);

 	/* Wait till the WAKER_CA_BIT changes to 0 */
 	while ((gicr_read_waker(gicr_base) & WAKER_CA_BIT) != 0U)
 		;
 }


 /******************************************************************************
  * This function marks the core as asleep in the re-distributor and ensures
  * that the interface is quiescent.
  *****************************************************************************/
 void gicv3_rdistif_mark_core_asleep(uintptr_t gicr_base)
 {
 	/* Mark the connected core as asleep */
 	gicr_write_waker(gicr_base, gicr_read_waker(gicr_base) | WAKER_PS_BIT);

 	/* Wait till the WAKER_CA_BIT changes to 1 */
 	while ((gicr_read_waker(gicr_base) & WAKER_CA_BIT) == 0U)
 		;
 }


 /*******************************************************************************
  * This function probes the Redistributor frames when the driver is initialised
  * and saves their base addresses. These base addresses are used later to
  * initialise each Redistributor interface.
  ******************************************************************************/
 void gicv3_rdistif_base_addrs_probe(uintptr_t *rdistif_base_addrs,
 					unsigned int rdistif_num,
 					uintptr_t gicr_base,
 					mpidr_hash_fn mpidr_to_core_pos)
 {
 	u_register_t mpidr;
 	unsigned int proc_num;
 	uint64_t typer_val;
 	uintptr_t rdistif_base = gicr_base;

 	assert(rdistif_base_addrs != NULL);

 	/*
 	 * Iterate over the Redistributor frames. Store the base address of each
 	 * frame in the platform provided array. Use the "Processor Number"
 	 * field to index into the array if the platform has not provided a hash
 	 * function to convert an MPIDR (obtained from the "Affinity Value"
 	 * field into a linear index.
 	 */
 	do {
 		typer_val = gicr_read_typer(rdistif_base);
 		if (mpidr_to_core_pos != NULL) {
 			mpidr = mpidr_from_gicr_typer(typer_val);
 			proc_num = mpidr_to_core_pos(mpidr);
 		} else {
 			proc_num = (typer_val >> TYPER_PROC_NUM_SHIFT) &
 				TYPER_PROC_NUM_MASK;
 		}

 		if (proc_num < rdistif_num)
 			rdistif_base_addrs[proc_num] = rdistif_base;

 		rdistif_base += (1U << GICR_PCPUBASE_SHIFT);
 	} while ((typer_val & TYPER_LAST_BIT) == 0U);
 }

 /*******************************************************************************
  * Helper function to configure the default attributes of SPIs.
  ******************************************************************************/
 void gicv3_spis_config_defaults(uintptr_t gicd_base)
 {
 	unsigned int index, num_ints;

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

 	/*
 	 * Treat all SPIs as G1NS by default. The number of interrupts is
 	 * calculated as 32 * (IT_LINES + 1). We do 32 at a time.
 	 */
 	for (index = MIN_SPI_ID; index < num_ints; index += 32U)
 		gicd_write_igroupr(gicd_base, index, ~0U);

 	/* Setup the default SPI priorities doing four at a time */
 	for (index = MIN_SPI_ID; index < num_ints; index += 4U)
 		gicd_write_ipriorityr(gicd_base,
 				      index,
 				      GICD_IPRIORITYR_DEF_VAL);

 	/*
 	 * Treat all SPIs as level triggered by default, write 16 at
 	 * a time
 	 */
 	for (index = MIN_SPI_ID; index < num_ints; index += 16U)
 		gicd_write_icfgr(gicd_base, index, 0U);
 }

 /*******************************************************************************
  * Helper function to configure properties of secure SPIs
  ******************************************************************************/
 unsigned int gicv3_secure_spis_config_props(uintptr_t gicd_base,
 		const interrupt_prop_t *interrupt_props,
 		unsigned int interrupt_props_num)
 {
 	unsigned int i;
 	const interrupt_prop_t *current_prop;
 	unsigned long long gic_affinity_val;
 	unsigned int ctlr_enable = 0U;

 	/* Make sure there's a valid property array */
 	if (interrupt_props_num > 0U)
 		assert(interrupt_props != NULL);

 	for (i = 0U; i < interrupt_props_num; i++) {
 		current_prop = &interrupt_props[i];

 		if (current_prop->intr_num < MIN_SPI_ID)
 			continue;

 		/* Configure this interrupt as a secure interrupt */
 		gicd_clr_igroupr(gicd_base, current_prop->intr_num);

 		/* Configure this interrupt as G0 or a G1S interrupt */
 		assert((current_prop->intr_grp == INTR_GROUP0) ||
 				(current_prop->intr_grp == INTR_GROUP1S));
 		if (current_prop->intr_grp == INTR_GROUP1S) {
 			gicd_set_igrpmodr(gicd_base, current_prop->intr_num);
 			ctlr_enable |= CTLR_ENABLE_G1S_BIT;
 		} else {
 			gicd_clr_igrpmodr(gicd_base, current_prop->intr_num);
 			ctlr_enable |= CTLR_ENABLE_G0_BIT;
 		}

 		/* Set interrupt configuration */
 		gicd_set_icfgr(gicd_base, current_prop->intr_num,
 				current_prop->intr_cfg);

 		/* Set the priority of this interrupt */
 		gicd_set_ipriorityr(gicd_base, current_prop->intr_num,
 				current_prop->intr_pri);

 		/* Target SPIs to the primary CPU */
 		gic_affinity_val =
 			gicd_irouter_val_from_mpidr(read_mpidr(), 0U);
 		gicd_write_irouter(gicd_base, current_prop->intr_num,
 				gic_affinity_val);

 		/* Enable this interrupt */
 		gicd_set_isenabler(gicd_base, current_prop->intr_num);
 	}

 	return ctlr_enable;
 }

 /*******************************************************************************
  * Helper function to configure the default attributes of SPIs.
  ******************************************************************************/
 void gicv3_ppi_sgi_config_defaults(uintptr_t gicr_base)
 {
 	unsigned int index;

 	/*
 	 * 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, ~0U);
 	gicr_wait_for_pending_write(gicr_base);

 	/* Treat all SGIs/PPIs as G1NS by default. */
 	gicr_write_igroupr0(gicr_base, ~0U);

 	/* Setup the default PPI/SGI priorities doing four at a time */
 	for (index = 0U; index < MIN_SPI_ID; index += 4U)
 		gicr_write_ipriorityr(gicr_base,
 				      index,
 				      GICD_IPRIORITYR_DEF_VAL);

 	/* Configure all PPIs as level triggered by default */
 	gicr_write_icfgr1(gicr_base, 0U);
 }

 /*******************************************************************************
  * Helper function to configure properties of secure G0 and G1S PPIs and SGIs.
  ******************************************************************************/
 unsigned int gicv3_secure_ppi_sgi_config_props(uintptr_t gicr_base,
 		const interrupt_prop_t *interrupt_props,
 		unsigned int interrupt_props_num)
 {
 	unsigned int i;
 	const interrupt_prop_t *current_prop;
 	unsigned int ctlr_enable = 0U;

 	/* Make sure there's a valid property array */
 	if (interrupt_props_num > 0U)
 		assert(interrupt_props != NULL);

 	for (i = 0U; i < interrupt_props_num; i++) {
 		current_prop = &interrupt_props[i];

 		if (current_prop->intr_num >= MIN_SPI_ID)
 			continue;

 		/* Configure this interrupt as a secure interrupt */
 		gicr_clr_igroupr0(gicr_base, current_prop->intr_num);

 		/* Configure this interrupt as G0 or a G1S interrupt */
 		assert((current_prop->intr_grp == INTR_GROUP0) ||
 				(current_prop->intr_grp == INTR_GROUP1S));
 		if (current_prop->intr_grp == INTR_GROUP1S) {
 			gicr_set_igrpmodr0(gicr_base, current_prop->intr_num);
 			ctlr_enable |= CTLR_ENABLE_G1S_BIT;
 		} else {
 			gicr_clr_igrpmodr0(gicr_base, current_prop->intr_num);
 			ctlr_enable |= CTLR_ENABLE_G0_BIT;
 		}

 		/* Set the priority of this interrupt */
 		gicr_set_ipriorityr(gicr_base, current_prop->intr_num,
 				current_prop->intr_pri);

 		/*
 		 * Set interrupt configuration for PPIs. Configuration for SGIs
 		 * are ignored.
 		 */
 		if ((current_prop->intr_num >= MIN_PPI_ID) &&
 				(current_prop->intr_num < MIN_SPI_ID)) {
 			gicr_set_icfgr1(gicr_base, current_prop->intr_num,
 					current_prop->intr_cfg);
 		}

 		/* Enable this interrupt */
 		gicr_set_isenabler0(gicr_base, current_prop->intr_num);
 	}

 	return ctlr_enable;
 }
	/*
	* Copyright (c) 2015-2018, ARM Limited and Contributors. All rights reserved.
	*
	* SPDX-License-Identifier: BSD-3-Clause
	*/

	#include <assert.h>

	#include <arch.h>
	#include <arch_helpers.h>
	#include <common/debug.h>
	#include <common/interrupt_props.h>
	#include <drivers/arm/gic_common.h>

	#include "../common/gic_common_private.h"
	#include "gicv3_private.h"

	/*
	* Accessor to read the GIC Distributor IGRPMODR corresponding to the
	* interrupt `id`, 32 interrupt IDs at a time.
	*/
	unsigned int gicd_read_igrpmodr(uintptr_t base, unsigned int id)
	{
	unsigned int n = id >> IGRPMODR_SHIFT;

	return mmio_read_32(base + GICD_IGRPMODR + (n << 2));
	}

	/*
	* Accessor to write the GIC Distributor IGRPMODR corresponding to the
	* interrupt `id`, 32 interrupt IDs at a time.
	*/
	void gicd_write_igrpmodr(uintptr_t base, unsigned int id, unsigned int val)
	{
	unsigned int n = id >> IGRPMODR_SHIFT;

	mmio_write_32(base + GICD_IGRPMODR + (n << 2), val);
	}

	/*
	* Accessor to get the bit corresponding to interrupt ID
	* in GIC Distributor IGRPMODR.
	*/
	unsigned int gicd_get_igrpmodr(uintptr_t base, unsigned int id)
	{
	unsigned int bit_num = id & ((1U << IGRPMODR_SHIFT) - 1U);
	unsigned int reg_val = gicd_read_igrpmodr(base, id);

	return (reg_val >> bit_num) & 0x1U;
	}

	/*
	* Accessor to set the bit corresponding to interrupt ID
	* in GIC Distributor IGRPMODR.
	*/
	void gicd_set_igrpmodr(uintptr_t base, unsigned int id)
	{
	unsigned int bit_num = id & ((1U << IGRPMODR_SHIFT) - 1U);
	unsigned int reg_val = gicd_read_igrpmodr(base, id);

	gicd_write_igrpmodr(base, id, reg_val \| (1U << bit_num));
	}

	/*
	* Accessor to clear the bit corresponding to interrupt ID
	* in GIC Distributor IGRPMODR.
	*/
	void gicd_clr_igrpmodr(uintptr_t base, unsigned int id)
	{
	unsigned int bit_num = id & ((1U << IGRPMODR_SHIFT) - 1U);
	unsigned int reg_val = gicd_read_igrpmodr(base, id);

	gicd_write_igrpmodr(base, id, reg_val & ~(1U << bit_num));
	}

	/*
	* Accessor to read the GIC Re-distributor IPRIORITYR corresponding to the
	* interrupt `id`, 4 interrupts IDs at a time.
	*/
	unsigned int gicr_read_ipriorityr(uintptr_t base, unsigned int id)
	{
	unsigned int n = id >> IPRIORITYR_SHIFT;

	return mmio_read_32(base + GICR_IPRIORITYR + (n << 2));
	}

	/*
	* Accessor to write the GIC Re-distributor IPRIORITYR corresponding to the
	* interrupt `id`, 4 interrupts IDs at a time.
	*/
	void gicr_write_ipriorityr(uintptr_t base, unsigned int id, unsigned int val)
	{
	unsigned int n = id >> IPRIORITYR_SHIFT;

	mmio_write_32(base + GICR_IPRIORITYR + (n << 2), val);
	}

	/*
	* Accessor to get the bit corresponding to interrupt ID
	* from GIC Re-distributor IGROUPR0.
	*/
	unsigned int gicr_get_igroupr0(uintptr_t base, unsigned int id)
	{
	unsigned int bit_num = id & ((1U << IGROUPR_SHIFT) - 1U);
	unsigned int reg_val = gicr_read_igroupr0(base);

	return (reg_val >> bit_num) & 0x1U;
	}

	/*
	* Accessor to set the bit corresponding to interrupt ID
	* in GIC Re-distributor IGROUPR0.
	*/
	void gicr_set_igroupr0(uintptr_t base, unsigned int id)
	{
	unsigned int bit_num = id & ((1U << IGROUPR_SHIFT) - 1U);
	unsigned int reg_val = gicr_read_igroupr0(base);

	gicr_write_igroupr0(base, reg_val \| (1U << bit_num));
	}

	/*
	* Accessor to clear the bit corresponding to interrupt ID
	* in GIC Re-distributor IGROUPR0.
	*/
	void gicr_clr_igroupr0(uintptr_t base, unsigned int id)
	{
	unsigned int bit_num = id & ((1U << IGROUPR_SHIFT) - 1U);
	unsigned int reg_val = gicr_read_igroupr0(base);

	gicr_write_igroupr0(base, reg_val & ~(1U << bit_num));
	}

	/*
	* Accessor to get the bit corresponding to interrupt ID
	* from GIC Re-distributor IGRPMODR0.
	*/
	unsigned int gicr_get_igrpmodr0(uintptr_t base, unsigned int id)
	{
	unsigned int bit_num = id & ((1U << IGRPMODR_SHIFT) - 1U);
	unsigned int reg_val = gicr_read_igrpmodr0(base);

	return (reg_val >> bit_num) & 0x1U;
	}

	/*
	* Accessor to set the bit corresponding to interrupt ID
	* in GIC Re-distributor IGRPMODR0.
	*/
	void gicr_set_igrpmodr0(uintptr_t base, unsigned int id)
	{
	unsigned int bit_num = id & ((1U << IGRPMODR_SHIFT) - 1U);
	unsigned int reg_val = gicr_read_igrpmodr0(base);

	gicr_write_igrpmodr0(base, reg_val \| (1U << bit_num));
	}

	/*
	* Accessor to clear the bit corresponding to interrupt ID
	* in GIC Re-distributor IGRPMODR0.
	*/
	void gicr_clr_igrpmodr0(uintptr_t base, unsigned int id)
	{
	unsigned int bit_num = id & ((1U << IGRPMODR_SHIFT) - 1U);
	unsigned int reg_val = gicr_read_igrpmodr0(base);

	gicr_write_igrpmodr0(base, reg_val & ~(1U << bit_num));
	}

	/*
	* Accessor to set the bit corresponding to interrupt ID
	* in GIC Re-distributor ISENABLER0.
	*/
	void gicr_set_isenabler0(uintptr_t base, unsigned int id)
	{
	unsigned int bit_num = id & ((1U << ISENABLER_SHIFT) - 1U);

	gicr_write_isenabler0(base, (1U << bit_num));
	}

	/*
	* Accessor to set the bit corresponding to interrupt ID in GIC Re-distributor
	* ICENABLER0.
	*/
	void gicr_set_icenabler0(uintptr_t base, unsigned int id)
	{
	unsigned int bit_num = id & ((1U << ICENABLER_SHIFT) - 1U);

	gicr_write_icenabler0(base, (1U << bit_num));
	}

	/*
	* Accessor to set the bit corresponding to interrupt ID in GIC Re-distributor
	* ISACTIVER0.
	*/
	unsigned int gicr_get_isactiver0(uintptr_t base, unsigned int id)
	{
	unsigned int bit_num = id & ((1U << ISACTIVER_SHIFT) - 1U);
	unsigned int reg_val = gicr_read_isactiver0(base);

	return (reg_val >> bit_num) & 0x1U;
	}

	/*
	* Accessor to clear the bit corresponding to interrupt ID in GIC Re-distributor
	* ICPENDRR0.
	*/
	void gicr_set_icpendr0(uintptr_t base, unsigned int id)
	{
	unsigned int bit_num = id & ((1U << ICPENDR_SHIFT) - 1U);

	gicr_write_icpendr0(base, (1U << bit_num));
	}

	/*
	* Accessor to set the bit corresponding to interrupt ID in GIC Re-distributor
	* ISPENDR0.
	*/
	void gicr_set_ispendr0(uintptr_t base, unsigned int id)
	{
	unsigned int bit_num = id & ((1U << ISPENDR_SHIFT) - 1U);

	gicr_write_ispendr0(base, (1U << bit_num));
	}

	/*
	* Accessor to set the byte corresponding to interrupt ID
	* in GIC Re-distributor IPRIORITYR.
	*/
	void gicr_set_ipriorityr(uintptr_t base, unsigned int id, unsigned int pri)
	{
	uint8_t val = pri & GIC_PRI_MASK;

	mmio_write_8(base + GICR_IPRIORITYR + id, val);
	}

	/*
	* Accessor to set the bit fields corresponding to interrupt ID
	* in GIC Re-distributor ICFGR0.
	*/
	void gicr_set_icfgr0(uintptr_t base, unsigned int id, unsigned int cfg)
	{
	/* Interrupt configuration is a 2-bit field */
	unsigned int bit_num = id & ((1U << ICFGR_SHIFT) - 1U);
	unsigned int bit_shift = bit_num << 1U;

	uint32_t reg_val = gicr_read_icfgr0(base);

	/* Clear the field, and insert required configuration */
	reg_val &= ~(GIC_CFG_MASK << bit_shift);
	reg_val \|= ((cfg & GIC_CFG_MASK) << bit_shift);

	gicr_write_icfgr0(base, reg_val);
	}

	/*
	* Accessor to set the bit fields corresponding to interrupt ID
	* in GIC Re-distributor ICFGR1.
	*/
	void gicr_set_icfgr1(uintptr_t base, unsigned int id, unsigned int cfg)
	{
	/* Interrupt configuration is a 2-bit field */
	unsigned int bit_num = id & ((1U << ICFGR_SHIFT) - 1U);
	unsigned int bit_shift = bit_num << 1U;

	uint32_t reg_val = gicr_read_icfgr1(base);

	/* Clear the field, and insert required configuration */
	reg_val &= ~(GIC_CFG_MASK << bit_shift);
	reg_val \|= ((cfg & GIC_CFG_MASK) << bit_shift);

	gicr_write_icfgr1(base, reg_val);
	}

	/******************************************************************************
	* This function marks the core as awake in the re-distributor and
	* ensures that the interface is active.
	*****************************************************************************/
	void gicv3_rdistif_mark_core_awake(uintptr_t gicr_base)
	{
	/*
	* The WAKER_PS_BIT should be changed to 0
	* only when WAKER_CA_BIT is 1.
	*/
	assert((gicr_read_waker(gicr_base) & WAKER_CA_BIT) != 0U);

	/* Mark the connected core as awake */
	gicr_write_waker(gicr_base, gicr_read_waker(gicr_base) & ~WAKER_PS_BIT);

	/* Wait till the WAKER_CA_BIT changes to 0 */
	while ((gicr_read_waker(gicr_base) & WAKER_CA_BIT) != 0U)
	;
	}


	/******************************************************************************
	* This function marks the core as asleep in the re-distributor and ensures
	* that the interface is quiescent.
	*****************************************************************************/
	void gicv3_rdistif_mark_core_asleep(uintptr_t gicr_base)
	{
	/* Mark the connected core as asleep */
	gicr_write_waker(gicr_base, gicr_read_waker(gicr_base) \| WAKER_PS_BIT);

	/* Wait till the WAKER_CA_BIT changes to 1 */
	while ((gicr_read_waker(gicr_base) & WAKER_CA_BIT) == 0U)
	;
	}


	/*******************************************************************************
	* This function probes the Redistributor frames when the driver is initialised
	* and saves their base addresses. These base addresses are used later to
	* initialise each Redistributor interface.
	******************************************************************************/
	void gicv3_rdistif_base_addrs_probe(uintptr_t *rdistif_base_addrs,
	unsigned int rdistif_num,
	uintptr_t gicr_base,
	mpidr_hash_fn mpidr_to_core_pos)
	{
	u_register_t mpidr;
	unsigned int proc_num;
	uint64_t typer_val;
	uintptr_t rdistif_base = gicr_base;

	assert(rdistif_base_addrs != NULL);

	/*
	* Iterate over the Redistributor frames. Store the base address of each
	* frame in the platform provided array. Use the "Processor Number"
	* field to index into the array if the platform has not provided a hash
	* function to convert an MPIDR (obtained from the "Affinity Value"
	* field into a linear index.
	*/
	do {
	typer_val = gicr_read_typer(rdistif_base);
	if (mpidr_to_core_pos != NULL) {
	mpidr = mpidr_from_gicr_typer(typer_val);
	proc_num = mpidr_to_core_pos(mpidr);
	} else {
	proc_num = (typer_val >> TYPER_PROC_NUM_SHIFT) &
	TYPER_PROC_NUM_MASK;
	}

	if (proc_num < rdistif_num)
	rdistif_base_addrs[proc_num] = rdistif_base;

	rdistif_base += (1U << GICR_PCPUBASE_SHIFT);
	} while ((typer_val & TYPER_LAST_BIT) == 0U);
	}

	/*******************************************************************************
	* Helper function to configure the default attributes of SPIs.
	******************************************************************************/
	void gicv3_spis_config_defaults(uintptr_t gicd_base)
	{
	unsigned int index, num_ints;

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

	/*
	* Treat all SPIs as G1NS by default. The number of interrupts is
	* calculated as 32 * (IT_LINES + 1). We do 32 at a time.
	*/
	for (index = MIN_SPI_ID; index < num_ints; index += 32U)
	gicd_write_igroupr(gicd_base, index, ~0U);

	/* Setup the default SPI priorities doing four at a time */
	for (index = MIN_SPI_ID; index < num_ints; index += 4U)
	gicd_write_ipriorityr(gicd_base,
	index,
	GICD_IPRIORITYR_DEF_VAL);

	/*
	* Treat all SPIs as level triggered by default, write 16 at
	* a time
	*/
	for (index = MIN_SPI_ID; index < num_ints; index += 16U)
	gicd_write_icfgr(gicd_base, index, 0U);
	}

	/*******************************************************************************
	* Helper function to configure properties of secure SPIs
	******************************************************************************/
	unsigned int gicv3_secure_spis_config_props(uintptr_t gicd_base,
	const interrupt_prop_t *interrupt_props,
	unsigned int interrupt_props_num)
	{
	unsigned int i;
	const interrupt_prop_t *current_prop;
	unsigned long long gic_affinity_val;
	unsigned int ctlr_enable = 0U;

	/* Make sure there's a valid property array */
	if (interrupt_props_num > 0U)
	assert(interrupt_props != NULL);

	for (i = 0U; i < interrupt_props_num; i++) {
	current_prop = &interrupt_props[i];

	if (current_prop->intr_num < MIN_SPI_ID)
	continue;

	/* Configure this interrupt as a secure interrupt */
	gicd_clr_igroupr(gicd_base, current_prop->intr_num);

	/* Configure this interrupt as G0 or a G1S interrupt */
	assert((current_prop->intr_grp == INTR_GROUP0) \|\|
	(current_prop->intr_grp == INTR_GROUP1S));
	if (current_prop->intr_grp == INTR_GROUP1S) {
	gicd_set_igrpmodr(gicd_base, current_prop->intr_num);
	ctlr_enable \|= CTLR_ENABLE_G1S_BIT;
	} else {
	gicd_clr_igrpmodr(gicd_base, current_prop->intr_num);
	ctlr_enable \|= CTLR_ENABLE_G0_BIT;
	}

	/* Set interrupt configuration */
	gicd_set_icfgr(gicd_base, current_prop->intr_num,
	current_prop->intr_cfg);

	/* Set the priority of this interrupt */
	gicd_set_ipriorityr(gicd_base, current_prop->intr_num,
	current_prop->intr_pri);

	/* Target SPIs to the primary CPU */
	gic_affinity_val =
	gicd_irouter_val_from_mpidr(read_mpidr(), 0U);
	gicd_write_irouter(gicd_base, current_prop->intr_num,
	gic_affinity_val);

	/* Enable this interrupt */
	gicd_set_isenabler(gicd_base, current_prop->intr_num);
	}

	return ctlr_enable;
	}

	/*******************************************************************************
	* Helper function to configure the default attributes of SPIs.
	******************************************************************************/
	void gicv3_ppi_sgi_config_defaults(uintptr_t gicr_base)
	{
	unsigned int index;

	/*
	* 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, ~0U);
	gicr_wait_for_pending_write(gicr_base);

	/* Treat all SGIs/PPIs as G1NS by default. */
	gicr_write_igroupr0(gicr_base, ~0U);

	/* Setup the default PPI/SGI priorities doing four at a time */
	for (index = 0U; index < MIN_SPI_ID; index += 4U)
	gicr_write_ipriorityr(gicr_base,
	index,
	GICD_IPRIORITYR_DEF_VAL);

	/* Configure all PPIs as level triggered by default */
	gicr_write_icfgr1(gicr_base, 0U);
	}

	/*******************************************************************************
	* Helper function to configure properties of secure G0 and G1S PPIs and SGIs.
	******************************************************************************/
	unsigned int gicv3_secure_ppi_sgi_config_props(uintptr_t gicr_base,
	const interrupt_prop_t *interrupt_props,
	unsigned int interrupt_props_num)
	{
	unsigned int i;
	const interrupt_prop_t *current_prop;
	unsigned int ctlr_enable = 0U;

	/* Make sure there's a valid property array */
	if (interrupt_props_num > 0U)
	assert(interrupt_props != NULL);

	for (i = 0U; i < interrupt_props_num; i++) {
	current_prop = &interrupt_props[i];

	if (current_prop->intr_num >= MIN_SPI_ID)
	continue;

	/* Configure this interrupt as a secure interrupt */
	gicr_clr_igroupr0(gicr_base, current_prop->intr_num);

	/* Configure this interrupt as G0 or a G1S interrupt */
	assert((current_prop->intr_grp == INTR_GROUP0) \|\|
	(current_prop->intr_grp == INTR_GROUP1S));
	if (current_prop->intr_grp == INTR_GROUP1S) {
	gicr_set_igrpmodr0(gicr_base, current_prop->intr_num);
	ctlr_enable \|= CTLR_ENABLE_G1S_BIT;
	} else {
	gicr_clr_igrpmodr0(gicr_base, current_prop->intr_num);
	ctlr_enable \|= CTLR_ENABLE_G0_BIT;
	}

	/* Set the priority of this interrupt */
	gicr_set_ipriorityr(gicr_base, current_prop->intr_num,
	current_prop->intr_pri);

	/*
	* Set interrupt configuration for PPIs. Configuration for SGIs
	* are ignored.
	*/
	if ((current_prop->intr_num >= MIN_PPI_ID) &&
	(current_prop->intr_num < MIN_SPI_ID)) {
	gicr_set_icfgr1(gicr_base, current_prop->intr_num,
	current_prop->intr_cfg);
	}

	/* Enable this interrupt */
	gicr_set_isenabler0(gicr_base, current_prop->intr_num);
	}

	return ctlr_enable;
	}