drivers/arm/gic/arm_gic.c - filogic/atf - Gitiles

 /*
  * Copyright (c) 2014-2016, ARM Limited and Contributors. All rights reserved.
  *
  * SPDX-License-Identifier: BSD-3-Clause
  */

 #include <arch.h>
 #include <arch_helpers.h>
 #include <arm_gic.h>
 #include <assert.h>
 #include <bl_common.h>
 #include <debug.h>
 #include <gic_v2.h>
 #include <gic_v3.h>
 #include <interrupt_mgmt.h>
 #include <platform.h>
 #include <stdint.h>

 /* Value used to initialize Non-Secure IRQ priorities four at a time */
 #define GICD_IPRIORITYR_DEF_VAL \
 	(GIC_HIGHEST_NS_PRIORITY | \
 	(GIC_HIGHEST_NS_PRIORITY << 8) | \
 	(GIC_HIGHEST_NS_PRIORITY << 16) | \
 	(GIC_HIGHEST_NS_PRIORITY << 24))

 static uintptr_t g_gicc_base;
 static uintptr_t g_gicd_base;
 static uintptr_t g_gicr_base;
 static const unsigned int *g_irq_sec_ptr;
 static unsigned int g_num_irqs;


 /*******************************************************************************
  * This function does some minimal GICv3 configuration. The Firmware itself does
  * not fully support GICv3 at this time and relies on GICv2 emulation as
  * provided by GICv3. This function allows software (like Linux) in later stages
  * to use full GICv3 features.
  ******************************************************************************/
 static void gicv3_cpuif_setup(void)
 {
 	unsigned int val;
 	uintptr_t base;

 	/*
 	 * When CPUs come out of reset they have their GICR_WAKER.ProcessorSleep
 	 * bit set. In order to allow interrupts to get routed to the CPU we
 	 * need to clear this bit if set and wait for GICR_WAKER.ChildrenAsleep
 	 * to clear (GICv3 Architecture specification 5.4.23).
 	 * GICR_WAKER is NOT banked per CPU, compute the correct base address
 	 * per CPU.
 	 */
 	assert(g_gicr_base);
 	base = gicv3_get_rdist(g_gicr_base, read_mpidr());
 	if (base == (uintptr_t)NULL) {
 		/* No re-distributor base address. This interface cannot be
 		 * configured.
 		 */
 		panic();
 	}

 	val = gicr_read_waker(base);

 	val &= ~WAKER_PS;
 	gicr_write_waker(base, val);
 	dsb();

 	/* We need to wait for ChildrenAsleep to clear. */
 	val = gicr_read_waker(base);
 	while (val & WAKER_CA)
 		val = gicr_read_waker(base);

 	val = read_icc_sre_el3();
 	write_icc_sre_el3(val | ICC_SRE_EN | ICC_SRE_SRE);
 	isb();
 }

 /*******************************************************************************
  * This function does some minimal GICv3 configuration when cores go
  * down.
  ******************************************************************************/
 static void gicv3_cpuif_deactivate(void)
 {
 	unsigned int val;
 	uintptr_t base;

 	/*
 	 * When taking CPUs down we need to set GICR_WAKER.ProcessorSleep and
 	 * wait for GICR_WAKER.ChildrenAsleep to get set.
 	 * (GICv3 Architecture specification 5.4.23).
 	 * GICR_WAKER is NOT banked per CPU, compute the correct base address
 	 * per CPU.
 	 */
 	assert(g_gicr_base);
 	base = gicv3_get_rdist(g_gicr_base, read_mpidr());
 	if (base == (uintptr_t)NULL) {
 		/* No re-distributor base address. This interface cannot be
 		 * configured.
 		 */
 		panic();
 	}

 	val = gicr_read_waker(base);
 	val |= WAKER_PS;
 	gicr_write_waker(base, val);
 	dsb();

 	/* We need to wait for ChildrenAsleep to set. */
 	val = gicr_read_waker(base);
 	while ((val & WAKER_CA) == 0)
 		val = gicr_read_waker(base);
 }


 /*******************************************************************************
  * Enable secure interrupts and use FIQs to route them. Disable legacy bypass
  * and set the priority mask register to allow all interrupts to trickle in.
  ******************************************************************************/
 void arm_gic_cpuif_setup(void)
 {
 	unsigned int val;

 	assert(g_gicc_base);
 	val = gicc_read_iidr(g_gicc_base);

 	/*
 	 * If GICv3 we need to do a bit of additional setup. We want to
 	 * allow default GICv2 behaviour but allow the next stage to
 	 * enable full gicv3 features.
 	 */
 	if (((val >> GICC_IIDR_ARCH_SHIFT) & GICC_IIDR_ARCH_MASK) >= 3)
 		gicv3_cpuif_setup();

 	val = ENABLE_GRP0 | FIQ_EN | FIQ_BYP_DIS_GRP0;
 	val |= IRQ_BYP_DIS_GRP0 | FIQ_BYP_DIS_GRP1 | IRQ_BYP_DIS_GRP1;

 	gicc_write_pmr(g_gicc_base, GIC_PRI_MASK);
 	gicc_write_ctlr(g_gicc_base, val);
 }

 /*******************************************************************************
  * Place the cpu interface in a state where it can never make a cpu exit wfi as
  * as result of an asserted interrupt. This is critical for powering down a cpu
  ******************************************************************************/
 void arm_gic_cpuif_deactivate(void)
 {
 	unsigned int val;

 	/* Disable secure, non-secure interrupts and disable their bypass */
 	assert(g_gicc_base);
 	val = gicc_read_ctlr(g_gicc_base);
 	val &= ~(ENABLE_GRP0 | ENABLE_GRP1);
 	val |= FIQ_BYP_DIS_GRP1 | FIQ_BYP_DIS_GRP0;
 	val |= IRQ_BYP_DIS_GRP0 | IRQ_BYP_DIS_GRP1;
 	gicc_write_ctlr(g_gicc_base, val);

 	val = gicc_read_iidr(g_gicc_base);

 	/*
 	 * If GICv3 we need to do a bit of additional setup. Make sure the
 	 * RDIST is put to sleep.
 	 */
 	if (((val >> GICC_IIDR_ARCH_SHIFT) & GICC_IIDR_ARCH_MASK) >= 3)
 		gicv3_cpuif_deactivate();
 }

 /*******************************************************************************
  * Per cpu gic distributor setup which will be done by all cpus after a cold
  * boot/hotplug. This marks out the secure interrupts & enables them.
  ******************************************************************************/
 void arm_gic_pcpu_distif_setup(void)
 {
 	unsigned int index, irq_num, sec_ppi_sgi_mask;

 	assert(g_gicd_base);

 	/* Setup PPI priorities doing four at a time */
 	for (index = 0; index < 32; index += 4) {
 		gicd_write_ipriorityr(g_gicd_base, index,
 				GICD_IPRIORITYR_DEF_VAL);
 	}

 	assert(g_irq_sec_ptr);
 	sec_ppi_sgi_mask = 0;

 	/* Ensure all SGIs and PPIs are Group0 to begin with */
 	gicd_write_igroupr(g_gicd_base, 0, 0);

 	for (index = 0; index < g_num_irqs; index++) {
 		irq_num = g_irq_sec_ptr[index];
 		if (irq_num < MIN_SPI_ID) {
 			/* We have an SGI or a PPI */
 			sec_ppi_sgi_mask |= 1U << irq_num;
 			gicd_set_ipriorityr(g_gicd_base, irq_num,
 				GIC_HIGHEST_SEC_PRIORITY);
 			gicd_set_isenabler(g_gicd_base, irq_num);
 		}
 	}

 	/*
 	 * Invert the bitmask to create a mask for non-secure PPIs and
 	 * SGIs. Program the GICD_IGROUPR0 with this bit mask. This write will
 	 * update the GICR_IGROUPR0 as well in case we are running on a GICv3
 	 * system. This is critical if GICD_CTLR.ARE_NS=1.
 	 */
 	gicd_write_igroupr(g_gicd_base, 0, ~sec_ppi_sgi_mask);
 }

 /*******************************************************************************
  * Get the current CPU bit mask from GICD_ITARGETSR0
  ******************************************************************************/
 static unsigned int arm_gic_get_cpuif_id(void)
 {
 	unsigned int val;

 	val = gicd_read_itargetsr(g_gicd_base, 0);
 	return val & GIC_TARGET_CPU_MASK;
 }

 /*******************************************************************************
  * Global gic distributor setup which will be done by the primary cpu after a
  * cold boot. It marks out the secure SPIs, PPIs & SGIs and enables them. It
  * then enables the secure GIC distributor interface.
  ******************************************************************************/
 static void arm_gic_distif_setup(void)
 {
 	unsigned int num_ints, ctlr, index, irq_num;
 	uint8_t target_cpu;

 	/* Disable the distributor before going further */
 	assert(g_gicd_base);
 	ctlr = gicd_read_ctlr(g_gicd_base);
 	ctlr &= ~(ENABLE_GRP0 | ENABLE_GRP1);
 	gicd_write_ctlr(g_gicd_base, ctlr);

 	/*
 	 * Mark out non-secure SPI interrupts. The number of interrupts is
 	 * calculated as 32 * (IT_LINES + 1). We do 32 at a time.
 	 */
 	num_ints = gicd_read_typer(g_gicd_base) & IT_LINES_NO_MASK;
 	num_ints = (num_ints + 1) << 5;
 	for (index = MIN_SPI_ID; index < num_ints; index += 32)
 		gicd_write_igroupr(g_gicd_base, index, ~0);

 	/* Setup SPI priorities doing four at a time */
 	for (index = MIN_SPI_ID; index < num_ints; index += 4) {
 		gicd_write_ipriorityr(g_gicd_base, index,
 				GICD_IPRIORITYR_DEF_VAL);
 	}

 	/* Read the target CPU mask */
 	target_cpu = arm_gic_get_cpuif_id();

 	/* Configure SPI secure interrupts now */
 	assert(g_irq_sec_ptr);
 	for (index = 0; index < g_num_irqs; index++) {
 		irq_num = g_irq_sec_ptr[index];
 		if (irq_num >= MIN_SPI_ID) {
 			/* We have an SPI */
 			gicd_clr_igroupr(g_gicd_base, irq_num);
 			gicd_set_ipriorityr(g_gicd_base, irq_num,
 				GIC_HIGHEST_SEC_PRIORITY);
 			gicd_set_itargetsr(g_gicd_base, irq_num, target_cpu);
 			gicd_set_isenabler(g_gicd_base, irq_num);
 		}
 	}

 	/*
 	 * Configure the SGI and PPI. This is done in a separated function
 	 * because each CPU is responsible for initializing its own private
 	 * interrupts.
 	 */
 	arm_gic_pcpu_distif_setup();

 	gicd_write_ctlr(g_gicd_base, ctlr | ENABLE_GRP0);
 }

 /*******************************************************************************
  * Initialize the ARM GIC driver with the provided platform inputs
 ******************************************************************************/
 void arm_gic_init(uintptr_t gicc_base,
 		  uintptr_t gicd_base,
 		  uintptr_t gicr_base,
 		  const unsigned int *irq_sec_ptr,
 		  unsigned int num_irqs)
 {
 	unsigned int val;

 	assert(gicc_base);
 	assert(gicd_base);
 	assert(irq_sec_ptr);

 	g_gicc_base = gicc_base;
 	g_gicd_base = gicd_base;

 	val = gicc_read_iidr(g_gicc_base);

 	if (((val >> GICC_IIDR_ARCH_SHIFT) & GICC_IIDR_ARCH_MASK) >= 3) {
 		assert(gicr_base);
 		g_gicr_base = gicr_base;
 	}

 	g_irq_sec_ptr = irq_sec_ptr;
 	g_num_irqs = num_irqs;
 }

 /*******************************************************************************
  * Setup the ARM GIC CPU and distributor interfaces.
 ******************************************************************************/
 void arm_gic_setup(void)
 {
 	arm_gic_cpuif_setup();
 	arm_gic_distif_setup();
 }

 /*******************************************************************************
  * An ARM processor signals interrupt exceptions through the IRQ and FIQ pins.
  * The interrupt controller knows which pin/line it uses to signal a type of
  * interrupt. This function provides a common implementation of
  * plat_interrupt_type_to_line() in an ARM GIC environment for optional re-use
  * across platforms. It lets the interrupt management framework determine
  * for a type of interrupt and security state, which line should be used in the
  * SCR_EL3 to control its routing to EL3. The interrupt line is represented as
  * the bit position of the IRQ or FIQ bit in the SCR_EL3.
  ******************************************************************************/
 uint32_t arm_gic_interrupt_type_to_line(uint32_t type,
 				uint32_t security_state)
 {
 	assert(type == INTR_TYPE_S_EL1 ||
 	       type == INTR_TYPE_EL3 ||
 	       type == INTR_TYPE_NS);

 	assert(sec_state_is_valid(security_state));

 	/*
 	 * We ignore the security state parameter under the assumption that
 	 * both normal and secure worlds are using ARM GICv2. This parameter
 	 * will be used when the secure world starts using GICv3.
 	 */
 #if ARM_GIC_ARCH == 2
 	return gicv2_interrupt_type_to_line(g_gicc_base, type);
 #else
 #error "Invalid ARM GIC architecture version specified for platform port"
 #endif /* ARM_GIC_ARCH */
 }

 #if ARM_GIC_ARCH == 2
 /*******************************************************************************
  * This function returns the type of the highest priority pending interrupt at
  * the GIC cpu interface. INTR_TYPE_INVAL is returned when there is no
  * interrupt pending.
  ******************************************************************************/
 uint32_t arm_gic_get_pending_interrupt_type(void)
 {
 	uint32_t id;

 	assert(g_gicc_base);
 	id = gicc_read_hppir(g_gicc_base) & INT_ID_MASK;

 	/* Assume that all secure interrupts are S-EL1 interrupts */
 	if (id < 1022)
 		return INTR_TYPE_S_EL1;

 	if (id == GIC_SPURIOUS_INTERRUPT)
 		return INTR_TYPE_INVAL;

 	return INTR_TYPE_NS;
 }

 /*******************************************************************************
  * This function returns the id of the highest priority pending interrupt at
  * the GIC cpu interface. INTR_ID_UNAVAILABLE is returned when there is no
  * interrupt pending.
  ******************************************************************************/
 uint32_t arm_gic_get_pending_interrupt_id(void)
 {
 	uint32_t id;

 	assert(g_gicc_base);
 	id = gicc_read_hppir(g_gicc_base) & INT_ID_MASK;

 	if (id < 1022)
 		return id;

 	if (id == 1023)
 		return INTR_ID_UNAVAILABLE;

 	/*
 	 * Find out which non-secure interrupt it is under the assumption that
 	 * the GICC_CTLR.AckCtl bit is 0.
 	 */
 	return gicc_read_ahppir(g_gicc_base) & INT_ID_MASK;
 }

 /*******************************************************************************
  * This functions reads the GIC cpu interface Interrupt Acknowledge register
  * to start handling the pending interrupt. It returns the contents of the IAR.
  ******************************************************************************/
 uint32_t arm_gic_acknowledge_interrupt(void)
 {
 	assert(g_gicc_base);
 	return gicc_read_IAR(g_gicc_base);
 }

 /*******************************************************************************
  * This functions writes the GIC cpu interface End Of Interrupt register with
  * the passed value to finish handling the active interrupt
  ******************************************************************************/
 void arm_gic_end_of_interrupt(uint32_t id)
 {
 	assert(g_gicc_base);
 	gicc_write_EOIR(g_gicc_base, id);
 }

 /*******************************************************************************
  * 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.
  ******************************************************************************/
 uint32_t arm_gic_get_interrupt_type(uint32_t id)
 {
 	uint32_t group;

 	assert(g_gicd_base);
 	group = gicd_get_igroupr(g_gicd_base, id);

 	/* Assume that all secure interrupts are S-EL1 interrupts */
 	if (group == GRP0)
 		return INTR_TYPE_S_EL1;
 	else
 		return INTR_TYPE_NS;
 }

 #else
 #error "Invalid ARM GIC architecture version specified for platform port"
 #endif /* ARM_GIC_ARCH */
	/*
	* Copyright (c) 2014-2016, ARM Limited and Contributors. All rights reserved.
	*
	* SPDX-License-Identifier: BSD-3-Clause
	*/

	#include <arch.h>
	#include <arch_helpers.h>
	#include <arm_gic.h>
	#include <assert.h>
	#include <bl_common.h>
	#include <debug.h>
	#include <gic_v2.h>
	#include <gic_v3.h>
	#include <interrupt_mgmt.h>
	#include <platform.h>
	#include <stdint.h>

	/* Value used to initialize Non-Secure IRQ priorities four at a time */
	#define GICD_IPRIORITYR_DEF_VAL \
	(GIC_HIGHEST_NS_PRIORITY \| \
	(GIC_HIGHEST_NS_PRIORITY << 8) \| \
	(GIC_HIGHEST_NS_PRIORITY << 16) \| \
	(GIC_HIGHEST_NS_PRIORITY << 24))

	static uintptr_t g_gicc_base;
	static uintptr_t g_gicd_base;
	static uintptr_t g_gicr_base;
	static const unsigned int *g_irq_sec_ptr;
	static unsigned int g_num_irqs;


	/*******************************************************************************
	* This function does some minimal GICv3 configuration. The Firmware itself does
	* not fully support GICv3 at this time and relies on GICv2 emulation as
	* provided by GICv3. This function allows software (like Linux) in later stages
	* to use full GICv3 features.
	******************************************************************************/
	static void gicv3_cpuif_setup(void)
	{
	unsigned int val;
	uintptr_t base;

	/*
	* When CPUs come out of reset they have their GICR_WAKER.ProcessorSleep
	* bit set. In order to allow interrupts to get routed to the CPU we
	* need to clear this bit if set and wait for GICR_WAKER.ChildrenAsleep
	* to clear (GICv3 Architecture specification 5.4.23).
	* GICR_WAKER is NOT banked per CPU, compute the correct base address
	* per CPU.
	*/
	assert(g_gicr_base);
	base = gicv3_get_rdist(g_gicr_base, read_mpidr());
	if (base == (uintptr_t)NULL) {
	/* No re-distributor base address. This interface cannot be
	* configured.
	*/
	panic();
	}

	val = gicr_read_waker(base);

	val &= ~WAKER_PS;
	gicr_write_waker(base, val);
	dsb();

	/* We need to wait for ChildrenAsleep to clear. */
	val = gicr_read_waker(base);
	while (val & WAKER_CA)
	val = gicr_read_waker(base);

	val = read_icc_sre_el3();
	write_icc_sre_el3(val \| ICC_SRE_EN \| ICC_SRE_SRE);
	isb();
	}

	/*******************************************************************************
	* This function does some minimal GICv3 configuration when cores go
	* down.
	******************************************************************************/
	static void gicv3_cpuif_deactivate(void)
	{
	unsigned int val;
	uintptr_t base;

	/*
	* When taking CPUs down we need to set GICR_WAKER.ProcessorSleep and
	* wait for GICR_WAKER.ChildrenAsleep to get set.
	* (GICv3 Architecture specification 5.4.23).
	* GICR_WAKER is NOT banked per CPU, compute the correct base address
	* per CPU.
	*/
	assert(g_gicr_base);
	base = gicv3_get_rdist(g_gicr_base, read_mpidr());
	if (base == (uintptr_t)NULL) {
	/* No re-distributor base address. This interface cannot be
	* configured.
	*/
	panic();
	}

	val = gicr_read_waker(base);
	val \|= WAKER_PS;
	gicr_write_waker(base, val);
	dsb();

	/* We need to wait for ChildrenAsleep to set. */
	val = gicr_read_waker(base);
	while ((val & WAKER_CA) == 0)
	val = gicr_read_waker(base);
	}


	/*******************************************************************************
	* Enable secure interrupts and use FIQs to route them. Disable legacy bypass
	* and set the priority mask register to allow all interrupts to trickle in.
	******************************************************************************/
	void arm_gic_cpuif_setup(void)
	{
	unsigned int val;

	assert(g_gicc_base);
	val = gicc_read_iidr(g_gicc_base);

	/*
	* If GICv3 we need to do a bit of additional setup. We want to
	* allow default GICv2 behaviour but allow the next stage to
	* enable full gicv3 features.
	*/
	if (((val >> GICC_IIDR_ARCH_SHIFT) & GICC_IIDR_ARCH_MASK) >= 3)
	gicv3_cpuif_setup();

	val = ENABLE_GRP0 \| FIQ_EN \| FIQ_BYP_DIS_GRP0;
	val \|= IRQ_BYP_DIS_GRP0 \| FIQ_BYP_DIS_GRP1 \| IRQ_BYP_DIS_GRP1;

	gicc_write_pmr(g_gicc_base, GIC_PRI_MASK);
	gicc_write_ctlr(g_gicc_base, val);
	}

	/*******************************************************************************
	* Place the cpu interface in a state where it can never make a cpu exit wfi as
	* as result of an asserted interrupt. This is critical for powering down a cpu
	******************************************************************************/
	void arm_gic_cpuif_deactivate(void)
	{
	unsigned int val;

	/* Disable secure, non-secure interrupts and disable their bypass */
	assert(g_gicc_base);
	val = gicc_read_ctlr(g_gicc_base);
	val &= ~(ENABLE_GRP0 \| ENABLE_GRP1);
	val \|= FIQ_BYP_DIS_GRP1 \| FIQ_BYP_DIS_GRP0;
	val \|= IRQ_BYP_DIS_GRP0 \| IRQ_BYP_DIS_GRP1;
	gicc_write_ctlr(g_gicc_base, val);

	val = gicc_read_iidr(g_gicc_base);

	/*
	* If GICv3 we need to do a bit of additional setup. Make sure the
	* RDIST is put to sleep.
	*/
	if (((val >> GICC_IIDR_ARCH_SHIFT) & GICC_IIDR_ARCH_MASK) >= 3)
	gicv3_cpuif_deactivate();
	}

	/*******************************************************************************
	* Per cpu gic distributor setup which will be done by all cpus after a cold
	* boot/hotplug. This marks out the secure interrupts & enables them.
	******************************************************************************/
	void arm_gic_pcpu_distif_setup(void)
	{
	unsigned int index, irq_num, sec_ppi_sgi_mask;

	assert(g_gicd_base);

	/* Setup PPI priorities doing four at a time */
	for (index = 0; index < 32; index += 4) {
	gicd_write_ipriorityr(g_gicd_base, index,
	GICD_IPRIORITYR_DEF_VAL);
	}

	assert(g_irq_sec_ptr);
	sec_ppi_sgi_mask = 0;

	/* Ensure all SGIs and PPIs are Group0 to begin with */
	gicd_write_igroupr(g_gicd_base, 0, 0);

	for (index = 0; index < g_num_irqs; index++) {
	irq_num = g_irq_sec_ptr[index];
	if (irq_num < MIN_SPI_ID) {
	/* We have an SGI or a PPI */
	sec_ppi_sgi_mask \|= 1U << irq_num;
	gicd_set_ipriorityr(g_gicd_base, irq_num,
	GIC_HIGHEST_SEC_PRIORITY);
	gicd_set_isenabler(g_gicd_base, irq_num);
	}
	}

	/*
	* Invert the bitmask to create a mask for non-secure PPIs and
	* SGIs. Program the GICD_IGROUPR0 with this bit mask. This write will
	* update the GICR_IGROUPR0 as well in case we are running on a GICv3
	* system. This is critical if GICD_CTLR.ARE_NS=1.
	*/
	gicd_write_igroupr(g_gicd_base, 0, ~sec_ppi_sgi_mask);
	}

	/*******************************************************************************
	* Get the current CPU bit mask from GICD_ITARGETSR0
	******************************************************************************/
	static unsigned int arm_gic_get_cpuif_id(void)
	{
	unsigned int val;

	val = gicd_read_itargetsr(g_gicd_base, 0);
	return val & GIC_TARGET_CPU_MASK;
	}

	/*******************************************************************************
	* Global gic distributor setup which will be done by the primary cpu after a
	* cold boot. It marks out the secure SPIs, PPIs & SGIs and enables them. It
	* then enables the secure GIC distributor interface.
	******************************************************************************/
	static void arm_gic_distif_setup(void)
	{
	unsigned int num_ints, ctlr, index, irq_num;
	uint8_t target_cpu;

	/* Disable the distributor before going further */
	assert(g_gicd_base);
	ctlr = gicd_read_ctlr(g_gicd_base);
	ctlr &= ~(ENABLE_GRP0 \| ENABLE_GRP1);
	gicd_write_ctlr(g_gicd_base, ctlr);

	/*
	* Mark out non-secure SPI interrupts. The number of interrupts is
	* calculated as 32 * (IT_LINES + 1). We do 32 at a time.
	*/
	num_ints = gicd_read_typer(g_gicd_base) & IT_LINES_NO_MASK;
	num_ints = (num_ints + 1) << 5;
	for (index = MIN_SPI_ID; index < num_ints; index += 32)
	gicd_write_igroupr(g_gicd_base, index, ~0);

	/* Setup SPI priorities doing four at a time */
	for (index = MIN_SPI_ID; index < num_ints; index += 4) {
	gicd_write_ipriorityr(g_gicd_base, index,
	GICD_IPRIORITYR_DEF_VAL);
	}

	/* Read the target CPU mask */
	target_cpu = arm_gic_get_cpuif_id();

	/* Configure SPI secure interrupts now */
	assert(g_irq_sec_ptr);
	for (index = 0; index < g_num_irqs; index++) {
	irq_num = g_irq_sec_ptr[index];
	if (irq_num >= MIN_SPI_ID) {
	/* We have an SPI */
	gicd_clr_igroupr(g_gicd_base, irq_num);
	gicd_set_ipriorityr(g_gicd_base, irq_num,
	GIC_HIGHEST_SEC_PRIORITY);
	gicd_set_itargetsr(g_gicd_base, irq_num, target_cpu);
	gicd_set_isenabler(g_gicd_base, irq_num);
	}
	}

	/*
	* Configure the SGI and PPI. This is done in a separated function
	* because each CPU is responsible for initializing its own private
	* interrupts.
	*/
	arm_gic_pcpu_distif_setup();

	gicd_write_ctlr(g_gicd_base, ctlr \| ENABLE_GRP0);
	}

	/*******************************************************************************
	* Initialize the ARM GIC driver with the provided platform inputs
	******************************************************************************/
	void arm_gic_init(uintptr_t gicc_base,
	uintptr_t gicd_base,
	uintptr_t gicr_base,
	const unsigned int *irq_sec_ptr,
	unsigned int num_irqs)
	{
	unsigned int val;

	assert(gicc_base);
	assert(gicd_base);
	assert(irq_sec_ptr);

	g_gicc_base = gicc_base;
	g_gicd_base = gicd_base;

	val = gicc_read_iidr(g_gicc_base);

	if (((val >> GICC_IIDR_ARCH_SHIFT) & GICC_IIDR_ARCH_MASK) >= 3) {
	assert(gicr_base);
	g_gicr_base = gicr_base;
	}

	g_irq_sec_ptr = irq_sec_ptr;
	g_num_irqs = num_irqs;
	}

	/*******************************************************************************
	* Setup the ARM GIC CPU and distributor interfaces.
	******************************************************************************/
	void arm_gic_setup(void)
	{
	arm_gic_cpuif_setup();
	arm_gic_distif_setup();
	}

	/*******************************************************************************
	* An ARM processor signals interrupt exceptions through the IRQ and FIQ pins.
	* The interrupt controller knows which pin/line it uses to signal a type of
	* interrupt. This function provides a common implementation of
	* plat_interrupt_type_to_line() in an ARM GIC environment for optional re-use
	* across platforms. It lets the interrupt management framework determine
	* for a type of interrupt and security state, which line should be used in the
	* SCR_EL3 to control its routing to EL3. The interrupt line is represented as
	* the bit position of the IRQ or FIQ bit in the SCR_EL3.
	******************************************************************************/
	uint32_t arm_gic_interrupt_type_to_line(uint32_t type,
	uint32_t security_state)
	{
	assert(type == INTR_TYPE_S_EL1 \|\|
	type == INTR_TYPE_EL3 \|\|
	type == INTR_TYPE_NS);

	assert(sec_state_is_valid(security_state));

	/*
	* We ignore the security state parameter under the assumption that
	* both normal and secure worlds are using ARM GICv2. This parameter
	* will be used when the secure world starts using GICv3.
	*/
	#if ARM_GIC_ARCH == 2
	return gicv2_interrupt_type_to_line(g_gicc_base, type);
	#else
	#error "Invalid ARM GIC architecture version specified for platform port"
	#endif /* ARM_GIC_ARCH */
	}

	#if ARM_GIC_ARCH == 2
	/*******************************************************************************
	* This function returns the type of the highest priority pending interrupt at
	* the GIC cpu interface. INTR_TYPE_INVAL is returned when there is no
	* interrupt pending.
	******************************************************************************/
	uint32_t arm_gic_get_pending_interrupt_type(void)
	{
	uint32_t id;

	assert(g_gicc_base);
	id = gicc_read_hppir(g_gicc_base) & INT_ID_MASK;

	/* Assume that all secure interrupts are S-EL1 interrupts */
	if (id < 1022)
	return INTR_TYPE_S_EL1;

	if (id == GIC_SPURIOUS_INTERRUPT)
	return INTR_TYPE_INVAL;

	return INTR_TYPE_NS;
	}

	/*******************************************************************************
	* This function returns the id of the highest priority pending interrupt at
	* the GIC cpu interface. INTR_ID_UNAVAILABLE is returned when there is no
	* interrupt pending.
	******************************************************************************/
	uint32_t arm_gic_get_pending_interrupt_id(void)
	{
	uint32_t id;

	assert(g_gicc_base);
	id = gicc_read_hppir(g_gicc_base) & INT_ID_MASK;

	if (id < 1022)
	return id;

	if (id == 1023)
	return INTR_ID_UNAVAILABLE;

	/*
	* Find out which non-secure interrupt it is under the assumption that
	* the GICC_CTLR.AckCtl bit is 0.
	*/
	return gicc_read_ahppir(g_gicc_base) & INT_ID_MASK;
	}

	/*******************************************************************************
	* This functions reads the GIC cpu interface Interrupt Acknowledge register
	* to start handling the pending interrupt. It returns the contents of the IAR.
	******************************************************************************/
	uint32_t arm_gic_acknowledge_interrupt(void)
	{
	assert(g_gicc_base);
	return gicc_read_IAR(g_gicc_base);
	}

	/*******************************************************************************
	* This functions writes the GIC cpu interface End Of Interrupt register with
	* the passed value to finish handling the active interrupt
	******************************************************************************/
	void arm_gic_end_of_interrupt(uint32_t id)
	{
	assert(g_gicc_base);
	gicc_write_EOIR(g_gicc_base, id);
	}

	/*******************************************************************************
	* 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.
	******************************************************************************/
	uint32_t arm_gic_get_interrupt_type(uint32_t id)
	{
	uint32_t group;

	assert(g_gicd_base);
	group = gicd_get_igroupr(g_gicd_base, id);

	/* Assume that all secure interrupts are S-EL1 interrupts */
	if (group == GRP0)
	return INTR_TYPE_S_EL1;
	else
	return INTR_TYPE_NS;
	}

	#else
	#error "Invalid ARM GIC architecture version specified for platform port"
	#endif /* ARM_GIC_ARCH */