drivers/interrupt_controller/intc_ioapic.c - third_party/github/zephyrproject-rtos/zephyr - Git at Google

 /*
  * Copyright (c) 1997-1998, 2000-2002, 2004, 2006-2008, 2011-2015 Wind River
  * Systems, Inc.
  *
  * SPDX-License-Identifier: Apache-2.0
  */

 #define DT_DRV_COMPAT intel_ioapic

 /**
  * @file
  * @brief Intel IO APIC/xAPIC driver
  *
  * This module is a driver for the IO APIC/xAPIC (Advanced Programmable
  * Interrupt Controller) for P6 (PentiumPro, II, III) family processors
  * and P7 (Pentium4) family processors.  The IO APIC/xAPIC is included
  * in the Intel's system chip set, such as ICH2.  Software intervention
  * may be required to enable the IO APIC/xAPIC in some chip sets.
  * The 8259A interrupt controller is intended for use in a uni-processor
  * system, IO APIC can be used in either a uni-processor or multi-processor
  * system.  The IO APIC handles interrupts very differently than the 8259A.
  * Briefly, these differences are:
  *  - Method of Interrupt Transmission. The IO APIC transmits interrupts
  *    through a 3-wire bus and interrupts are handled without the need for
  *    the processor to run an interrupt acknowledge cycle.
  *  - Interrupt Priority. The priority of interrupts in the IO APIC is
  *    independent of the interrupt number.  For example, interrupt 10 can
  *    be given a higher priority than interrupt 3.
  *  - More Interrupts. The IO APIC supports a total of 24 interrupts.
  *
  * The IO APIC unit consists of a set of interrupt input signals, a 24-entry
  * by 64-bit Interrupt Redirection Table, programmable registers, and a message
  * unit for sending and receiving APIC messages over the APIC bus or the
  * Front-Side (system) bus.  IO devices inject interrupts into the system by
  * asserting one of the interrupt lines to the IO APIC.  The IO APIC selects the
  * corresponding entry in the Redirection Table and uses the information in that
  * entry to format an interrupt request message.  Each entry in the Redirection
  * Table can be individually programmed to indicate edge/level sensitive interrupt
  * signals, the interrupt vector and priority, the destination processor, and how
  * the processor is selected (statically and dynamically).  The information in
  * the table is used to transmit a message to other APIC units (via the APIC bus
  * or the Front-Side (system) bus).  IO APIC is used in the Symmetric IO Mode.
  * The base address of IO APIC is determined in loapic_init() and stored in the
  * global variable ioApicBase and ioApicData.
  * The lower 32 bit value of the redirection table entries for IRQ 0
  * to 15 are edge triggered positive high, and for IRQ 16 to 23 are level
  * triggered positive low.
  *
  * This implementation doesn't support multiple IO APICs.
  *
  * INCLUDE FILES: ioapic.h loapic.h
  *
  */

 #include <zephyr/kernel.h>
 #include <zephyr/arch/cpu.h>

 #include <zephyr/toolchain.h>
 #include <zephyr/linker/sections.h>
 #include <zephyr/device.h>
 #include <zephyr/pm/device.h>
 #include <string.h>

 #include <zephyr/drivers/interrupt_controller/ioapic.h> /* public API declarations */
 #include <zephyr/drivers/interrupt_controller/loapic.h> /* public API declarations and registers */
 #include "intc_ioapic_priv.h"

 DEVICE_MMIO_TOPLEVEL_STATIC(ioapic_regs, DT_DRV_INST(0));

 #define IOAPIC_REG DEVICE_MMIO_TOPLEVEL_GET(ioapic_regs)

 /*
  * Destination field (bits[56:63]) defines a set of processors, which is
  * used to be compared with local LDR to determine which local APICs accept
  * the interrupt.
  *
  * XAPIC: in logical destination mode and flat model (determined by DFR).
  * LDR bits[24:31] can accommodate up to 8 logical APIC IDs.
  *
  * X2APIC: in logical destination mode and cluster model.
  * In this case, LDR is read-only to system software and supports up to 16
  * logical IDs. (Cluster ID: don't care to IO APIC).
  *
  * In either case, regardless how many CPUs in the system, 0xff implies that
  * it's intended to deliver to all possible 8 local APICs.
  */
 #define DEFAULT_RTE_DEST	(0xFF << 24)

 static __pinned_bss uint32_t ioapic_rtes;

 #ifdef CONFIG_PM_DEVICE
 #include <zephyr/pm/device.h>

 #define BITS_PER_IRQ  4
 #define IOAPIC_BITFIELD_HI_LO	0
 #define IOAPIC_BITFIELD_LVL_EDGE 1
 #define IOAPIC_BITFIELD_ENBL_DSBL 2
 #define IOAPIC_BITFIELD_DELIV_MODE 3

 #define BIT_POS_FOR_IRQ_OPTION(irq, option) ((irq) * BITS_PER_IRQ + (option))

 /* Allocating up to 256 irq bits bufffer for RTEs, RTEs are dynamically found
  * so let's just assume the maximum, it's only 128 bytes in total.
  */
 #define SUSPEND_BITS_REQD (ROUND_UP((256 * BITS_PER_IRQ), 32))

 __pinned_bss
 uint32_t ioapic_suspend_buf[SUSPEND_BITS_REQD / 32] = {0};
 #endif

 static uint32_t __IoApicGet(int32_t offset);
 static void __IoApicSet(int32_t offset, uint32_t value);
 static void ioApicRedSetHi(unsigned int irq, uint32_t upper32);
 static void ioApicRedSetLo(unsigned int irq, uint32_t lower32);
 static uint32_t ioApicRedGetLo(unsigned int irq);
 static void IoApicRedUpdateLo(unsigned int irq, uint32_t value,
 					uint32_t mask);

 #if defined(CONFIG_INTEL_VTD_ICTL) &&				\
 	!defined(CONFIG_INTEL_VTD_ICTL_XAPIC_PASSTHROUGH)

 #include <zephyr/drivers/interrupt_controller/intel_vtd.h>
 #include <zephyr/arch/x86/acpi.h>

 static const struct device *vtd;
 static uint16_t ioapic_id;


 static bool get_vtd(void)
 {
 	if (vtd != NULL) {
 		return true;
 	}

 #define DRV_COMPAT_BAK DT_DRV_COMPAT
 #undef DT_DRV_COMPAT
 #define DT_DRV_COMPAT intel_vt_d
 	vtd = DEVICE_DT_GET_OR_NULL(DT_DRV_INST(0));
 #undef DT_DRV_COMPAT
 #define DT_DRV_COMPAT DRV_COMPAT_BAK
 #undef DRV_COMPAT_BAK

 	ioapic_id = z_acpi_get_dev_id_from_dmar(ACPI_DRHD_DEV_SCOPE_IOAPIC);

 	return vtd == NULL ? false : true;
 }
 #endif /* CONFIG_INTEL_VTD_ICTL && !INTEL_VTD_ICTL_XAPIC_PASSTHROUGH */

 /*
  * The functions irq_enable() and irq_disable() are implemented in the
  * interrupt controller driver due to the IRQ virtualization imposed by
  * the x86 architecture.
  */

 /**
  * @brief Initialize the IO APIC or xAPIC
  *
  * This routine initializes the IO APIC or xAPIC.
  *
  * @retval 0 on success.
  */
 __boot_func
 int ioapic_init(const struct device *unused)
 {
 	ARG_UNUSED(unused);

 	DEVICE_MMIO_TOPLEVEL_MAP(ioapic_regs, K_MEM_CACHE_NONE);

 	/* Reading MRE: this will give the number of RTEs available */
 	ioapic_rtes = ((__IoApicGet(IOAPIC_VERS) &
 			IOAPIC_MRE_MASK) >> IOAPIC_MRE_POS) + 1;

 #ifdef CONFIG_IOAPIC_MASK_RTE
 	int32_t ix;	/* redirection table index */
 	uint32_t rteValue; /* value to copy into redirection table entry */

 	rteValue = IOAPIC_EDGE | IOAPIC_HIGH | IOAPIC_FIXED | IOAPIC_INT_MASK |
 		   IOAPIC_LOGICAL | 0 /* dummy vector */;

 	for (ix = 0; ix < ioapic_rtes; ix++) {
 		ioApicRedSetHi(ix, DEFAULT_RTE_DEST);
 		ioApicRedSetLo(ix, rteValue);
 	}
 #endif
 	return 0;
 }

 __pinned_func
 uint32_t z_ioapic_num_rtes(void)
 {
 	return ioapic_rtes;
 }

 /**
  * @brief Enable a specified APIC interrupt input line
  *
  * This routine enables a specified APIC interrupt input line.
  *
  * @param irq IRQ number to enable
  */
 __pinned_func
 void z_ioapic_irq_enable(unsigned int irq)
 {
 	IoApicRedUpdateLo(irq, 0, IOAPIC_INT_MASK);
 }

 /**
  * @brief Disable a specified APIC interrupt input line
  *
  * This routine disables a specified APIC interrupt input line.
  * @param irq IRQ number to disable
  */
 __pinned_func
 void z_ioapic_irq_disable(unsigned int irq)
 {
 	IoApicRedUpdateLo(irq, IOAPIC_INT_MASK, IOAPIC_INT_MASK);
 }


 #ifdef CONFIG_PM_DEVICE

 __pinned_func
 void store_flags(unsigned int irq, uint32_t flags)
 {
 	/* Currently only the following four flags are modified */
 	if (flags & IOAPIC_LOW) {
 		sys_bitfield_set_bit((mem_addr_t) ioapic_suspend_buf,
 			BIT_POS_FOR_IRQ_OPTION(irq, IOAPIC_BITFIELD_HI_LO));
 	}

 	if (flags & IOAPIC_LEVEL) {
 		sys_bitfield_set_bit((mem_addr_t) ioapic_suspend_buf,
 			BIT_POS_FOR_IRQ_OPTION(irq, IOAPIC_BITFIELD_LVL_EDGE));
 	}

 	if (flags & IOAPIC_INT_MASK) {
 		sys_bitfield_set_bit((mem_addr_t) ioapic_suspend_buf,
 			BIT_POS_FOR_IRQ_OPTION(irq, IOAPIC_BITFIELD_ENBL_DSBL));
 	}

 	/*
 	 * We support lowest priority and fixed mode only, so only one bit
 	 * needs to be saved.
 	 */
 	if (flags & IOAPIC_LOWEST) {
 		sys_bitfield_set_bit((mem_addr_t) ioapic_suspend_buf,
 			BIT_POS_FOR_IRQ_OPTION(irq, IOAPIC_BITFIELD_DELIV_MODE));
 	}
 }

 __pinned_func
 uint32_t restore_flags(unsigned int irq)
 {
 	uint32_t flags = 0U;

 	if (sys_bitfield_test_bit((mem_addr_t) ioapic_suspend_buf,
 		BIT_POS_FOR_IRQ_OPTION(irq, IOAPIC_BITFIELD_HI_LO))) {
 		flags |= IOAPIC_LOW;
 	}

 	if (sys_bitfield_test_bit((mem_addr_t) ioapic_suspend_buf,
 		BIT_POS_FOR_IRQ_OPTION(irq, IOAPIC_BITFIELD_LVL_EDGE))) {
 		flags |= IOAPIC_LEVEL;
 	}

 	if (sys_bitfield_test_bit((mem_addr_t) ioapic_suspend_buf,
 		BIT_POS_FOR_IRQ_OPTION(irq, IOAPIC_BITFIELD_ENBL_DSBL))) {
 		flags |= IOAPIC_INT_MASK;
 	}

 	if (sys_bitfield_test_bit((mem_addr_t) ioapic_suspend_buf,
 		BIT_POS_FOR_IRQ_OPTION(irq, IOAPIC_BITFIELD_DELIV_MODE))) {
 		flags |= IOAPIC_LOWEST;
 	}

 	return flags;
 }


 __pinned_func
 int ioapic_suspend(const struct device *port)
 {
 	int irq;
 	uint32_t rte_lo;

 	ARG_UNUSED(port);
 	(void)memset(ioapic_suspend_buf, 0, (SUSPEND_BITS_REQD >> 3));
 	for (irq = 0; irq < ioapic_rtes; irq++) {
 		/*
 		 * The following check is to figure out the registered
 		 * IRQ lines, so as to limit ourselves to saving the
 		 *  flags for them only.
 		 */
 		if (_irq_to_interrupt_vector[irq]) {
 			rte_lo = ioApicRedGetLo(irq);
 			store_flags(irq, rte_lo);
 		}
 	}
 	return 0;
 }

 __pinned_func
 int ioapic_resume_from_suspend(const struct device *port)
 {
 	int irq;
 	uint32_t flags;
 	uint32_t rteValue;

 	ARG_UNUSED(port);

 	for (irq = 0; irq < ioapic_rtes; irq++) {
 		if (_irq_to_interrupt_vector[irq]) {
 			/* Get the saved flags */
 			flags = restore_flags(irq);
 			/* Appending the flags that are never modified */
 			flags = flags | IOAPIC_LOGICAL;

 			rteValue = (_irq_to_interrupt_vector[irq] &
 					IOAPIC_VEC_MASK) | flags;
 		} else {
 			/* Initialize the other RTEs to sane values */
 			rteValue = IOAPIC_EDGE | IOAPIC_HIGH |
 				IOAPIC_FIXED | IOAPIC_INT_MASK |
 				IOAPIC_LOGICAL | 0 ; /* dummy vector*/
 		}
 		ioApicRedSetHi(irq, DEFAULT_RTE_DEST);
 		ioApicRedSetLo(irq, rteValue);
 	}
 	return 0;
 }

 /*
 * Implements the driver control management functionality
 * the *context may include IN data or/and OUT data
 */
 __pinned_func
 static int ioapic_pm_action(const struct device *dev,
 			    enum pm_device_action action)
 {
 	int ret = 0;

 	switch (action) {
 	case PM_DEVICE_ACTION_RESUME:
 		ret = ioapic_resume_from_suspend(dev);
 		break;
 	case PM_DEVICE_ACTION_SUSPEND:
 		ret = ioapic_suspend(dev);
 		break;
 	default:
 		ret = -ENOTSUP;
 	}

 	return ret;
 }

 #endif  /*CONFIG_PM_DEVICE*/

 /**
  * @brief Programs the interrupt redirection table
  *
  * This routine sets up the redirection table entry for the specified IRQ
  * @param irq Virtualized IRQ
  * @param vector Vector number
  * @param flags Interrupt flags
  */
 __boot_func
 void z_ioapic_irq_set(unsigned int irq, unsigned int vector, uint32_t flags)
 {
 	uint32_t rteValue;   /* value to copy into redirection table entry */
 #if defined(CONFIG_INTEL_VTD_ICTL) &&				\
 	!defined(CONFIG_INTEL_VTD_ICTL_XAPIC_PASSTHROUGH)
 	int irte_idx;

 	if (!get_vtd()) {
 		goto no_vtd;
 	}

 	irte_idx = vtd_get_irte_by_vector(vtd, vector);
 	if (irte_idx < 0) {
 		irte_idx = vtd_get_irte_by_irq(vtd, irq);
 	}

 	if (irte_idx >= 0 && !vtd_irte_is_msi(vtd, irte_idx)) {
 		/* Enable interrupt remapping format and set the irte index */
 		rteValue = IOAPIC_VTD_REMAP_FORMAT |
 			IOAPIC_VTD_INDEX(irte_idx);
 		ioApicRedSetHi(irq, rteValue);

 		/* Remapped: delivery mode is Fixed (000) and
 		 * destination mode is no longer present as it is replaced by
 		 * the 15th bit of irte index, which is always 0 in our case.
 		 */
 		rteValue = IOAPIC_INT_MASK |
 			(vector & IOAPIC_VEC_MASK) |
 			(flags & IOAPIC_TRIGGER_MASK) |
 			(flags & IOAPIC_POLARITY_MASK);
 		ioApicRedSetLo(irq, rteValue);

 		vtd_remap(vtd, irte_idx, vector, flags, ioapic_id);
 	} else {
 no_vtd:
 #else
 	{
 #endif /* CONFIG_INTEL_VTD_ICTL && !CONFIG_INTEL_VTD_ICTL_XAPIC_PASSTHROUGH */
 		/* the delivery mode is determined by the flags
 		 * passed from drivers
 		 */
 		rteValue = IOAPIC_INT_MASK | IOAPIC_LOGICAL |
 			(vector & IOAPIC_VEC_MASK) | flags;
 		ioApicRedSetHi(irq, DEFAULT_RTE_DEST);
 		ioApicRedSetLo(irq, rteValue);
 	}
 }

 /**
  * @brief Program interrupt vector for specified irq
  *
  * The routine writes the interrupt vector in the Interrupt Redirection
  * Table for specified irq number
  *
  * @param irq Interrupt number
  * @param vector Vector number
  */
 __boot_func
 void z_ioapic_int_vec_set(unsigned int irq, unsigned int vector)
 {
 	IoApicRedUpdateLo(irq, vector, IOAPIC_VEC_MASK);
 }

 /**
  * @brief Read a 32 bit IO APIC register
  *
  * This routine reads the specified IO APIC register using indirect addressing.
  * @param offset Register offset (8 bits)
  *
  * @return register value
  */
 __pinned_func
 static uint32_t __IoApicGet(int32_t offset)
 {
 	uint32_t value; /* value */
 	unsigned int key;	/* interrupt lock level */

 	/* lock interrupts to ensure indirect addressing works "atomically" */

 	key = irq_lock();

 	*((volatile uint32_t *) (IOAPIC_REG + IOAPIC_IND)) = (char)offset;
 	value = *((volatile uint32_t *)(IOAPIC_REG + IOAPIC_DATA));

 	irq_unlock(key);

 	return value;
 }

 /**
  * @brief Write a 32 bit IO APIC register
  *
  * This routine writes the specified IO APIC register using indirect addressing.
  *
  * @param offset Register offset (8 bits)
  * @param value Value to set the register
  */
 __pinned_func
 static void __IoApicSet(int32_t offset, uint32_t value)
 {
 	unsigned int key; /* interrupt lock level */

 	/* lock interrupts to ensure indirect addressing works "atomically" */

 	key = irq_lock();

 	*(volatile uint32_t *)(IOAPIC_REG + IOAPIC_IND) = (char)offset;
 	*((volatile uint32_t *)(IOAPIC_REG + IOAPIC_DATA)) = value;

 	irq_unlock(key);
 }

 /**
  * @brief Get low 32 bits of Redirection Table entry
  *
  * This routine reads the low-order 32 bits of a Redirection Table entry.
  *
  * @param irq INTIN number
  * @return 32 low-order bits
  */
 __pinned_func
 static uint32_t ioApicRedGetLo(unsigned int irq)
 {
 	int32_t offset = IOAPIC_REDTBL + (irq << 1); /* register offset */

 	return __IoApicGet(offset);
 }

 /**
  * @brief Set low 32 bits of Redirection Table entry
  *
  * This routine writes the low-order 32 bits of a Redirection Table entry.
  *
  * @param irq INTIN number
  * @param lower32 Value to be written
  */
 __pinned_func
 static void ioApicRedSetLo(unsigned int irq, uint32_t lower32)
 {
 	int32_t offset = IOAPIC_REDTBL + (irq << 1); /* register offset */

 	__IoApicSet(offset, lower32);
 }

 /**
  * @brief Set high 32 bits of Redirection Table entry
  *
  * This routine writes the high-order 32 bits of a Redirection Table entry.
  *
  * @param irq INTIN number
  * @param upper32 Value to be written
  */
 __pinned_func
 static void ioApicRedSetHi(unsigned int irq, uint32_t upper32)
 {
 	int32_t offset = IOAPIC_REDTBL + (irq << 1) + 1; /* register offset */

 	__IoApicSet(offset, upper32);
 }

 /**
  * @brief Modify low 32 bits of Redirection Table entry
  *
  * This routine modifies selected portions of the low-order 32 bits of a
  * Redirection Table entry, as indicated by the associate bit mask.
  *
  * @param irq INTIN number
  * @param value Value to be written
  * @param mask  Mask of bits to be modified
  */
 __pinned_func
 static void IoApicRedUpdateLo(unsigned int irq,
 				uint32_t value,
 				uint32_t mask)
 {
 	ioApicRedSetLo(irq, (ioApicRedGetLo(irq) & ~mask) | (value & mask));
 }

 PM_DEVICE_DEFINE(ioapic, ioapic_pm_action);

 DEVICE_DEFINE(ioapic, "ioapic", ioapic_init, PM_DEVICE_GET(ioapic), NULL, NULL,
 	      PRE_KERNEL_1, CONFIG_INTC_INIT_PRIORITY, NULL);
	/*
	* Copyright (c) 1997-1998, 2000-2002, 2004, 2006-2008, 2011-2015 Wind River
	* Systems, Inc.
	*
	* SPDX-License-Identifier: Apache-2.0
	*/

	#define DT_DRV_COMPAT intel_ioapic

	/**
	* @file
	* @brief Intel IO APIC/xAPIC driver
	*
	* This module is a driver for the IO APIC/xAPIC (Advanced Programmable
	* Interrupt Controller) for P6 (PentiumPro, II, III) family processors
	* and P7 (Pentium4) family processors. The IO APIC/xAPIC is included
	* in the Intel's system chip set, such as ICH2. Software intervention
	* may be required to enable the IO APIC/xAPIC in some chip sets.
	* The 8259A interrupt controller is intended for use in a uni-processor
	* system, IO APIC can be used in either a uni-processor or multi-processor
	* system. The IO APIC handles interrupts very differently than the 8259A.
	* Briefly, these differences are:
	* - Method of Interrupt Transmission. The IO APIC transmits interrupts
	* through a 3-wire bus and interrupts are handled without the need for
	* the processor to run an interrupt acknowledge cycle.
	* - Interrupt Priority. The priority of interrupts in the IO APIC is
	* independent of the interrupt number. For example, interrupt 10 can
	* be given a higher priority than interrupt 3.
	* - More Interrupts. The IO APIC supports a total of 24 interrupts.
	*
	* The IO APIC unit consists of a set of interrupt input signals, a 24-entry
	* by 64-bit Interrupt Redirection Table, programmable registers, and a message
	* unit for sending and receiving APIC messages over the APIC bus or the
	* Front-Side (system) bus. IO devices inject interrupts into the system by
	* asserting one of the interrupt lines to the IO APIC. The IO APIC selects the
	* corresponding entry in the Redirection Table and uses the information in that
	* entry to format an interrupt request message. Each entry in the Redirection
	* Table can be individually programmed to indicate edge/level sensitive interrupt
	* signals, the interrupt vector and priority, the destination processor, and how
	* the processor is selected (statically and dynamically). The information in
	* the table is used to transmit a message to other APIC units (via the APIC bus
	* or the Front-Side (system) bus). IO APIC is used in the Symmetric IO Mode.
	* The base address of IO APIC is determined in loapic_init() and stored in the
	* global variable ioApicBase and ioApicData.
	* The lower 32 bit value of the redirection table entries for IRQ 0
	* to 15 are edge triggered positive high, and for IRQ 16 to 23 are level
	* triggered positive low.
	*
	* This implementation doesn't support multiple IO APICs.
	*
	* INCLUDE FILES: ioapic.h loapic.h
	*
	*/

	#include <zephyr/kernel.h>
	#include <zephyr/arch/cpu.h>

	#include <zephyr/toolchain.h>
	#include <zephyr/linker/sections.h>
	#include <zephyr/device.h>
	#include <zephyr/pm/device.h>
	#include <string.h>

	#include <zephyr/drivers/interrupt_controller/ioapic.h> /* public API declarations */
	#include <zephyr/drivers/interrupt_controller/loapic.h> /* public API declarations and registers */
	#include "intc_ioapic_priv.h"

	DEVICE_MMIO_TOPLEVEL_STATIC(ioapic_regs, DT_DRV_INST(0));

	#define IOAPIC_REG DEVICE_MMIO_TOPLEVEL_GET(ioapic_regs)

	/*
	* Destination field (bits[56:63]) defines a set of processors, which is
	* used to be compared with local LDR to determine which local APICs accept
	* the interrupt.
	*
	* XAPIC: in logical destination mode and flat model (determined by DFR).
	* LDR bits[24:31] can accommodate up to 8 logical APIC IDs.
	*
	* X2APIC: in logical destination mode and cluster model.
	* In this case, LDR is read-only to system software and supports up to 16
	* logical IDs. (Cluster ID: don't care to IO APIC).
	*
	* In either case, regardless how many CPUs in the system, 0xff implies that
	* it's intended to deliver to all possible 8 local APICs.
	*/
	#define DEFAULT_RTE_DEST (0xFF << 24)

	static __pinned_bss uint32_t ioapic_rtes;

	#ifdef CONFIG_PM_DEVICE
	#include <zephyr/pm/device.h>

	#define BITS_PER_IRQ 4
	#define IOAPIC_BITFIELD_HI_LO 0
	#define IOAPIC_BITFIELD_LVL_EDGE 1
	#define IOAPIC_BITFIELD_ENBL_DSBL 2
	#define IOAPIC_BITFIELD_DELIV_MODE 3

	#define BIT_POS_FOR_IRQ_OPTION(irq, option) ((irq) * BITS_PER_IRQ + (option))

	/* Allocating up to 256 irq bits bufffer for RTEs, RTEs are dynamically found
	* so let's just assume the maximum, it's only 128 bytes in total.
	*/
	#define SUSPEND_BITS_REQD (ROUND_UP((256 * BITS_PER_IRQ), 32))

	__pinned_bss
	uint32_t ioapic_suspend_buf[SUSPEND_BITS_REQD / 32] = {0};
	#endif

	static uint32_t __IoApicGet(int32_t offset);
	static void __IoApicSet(int32_t offset, uint32_t value);
	static void ioApicRedSetHi(unsigned int irq, uint32_t upper32);
	static void ioApicRedSetLo(unsigned int irq, uint32_t lower32);
	static uint32_t ioApicRedGetLo(unsigned int irq);
	static void IoApicRedUpdateLo(unsigned int irq, uint32_t value,
	uint32_t mask);

	#if defined(CONFIG_INTEL_VTD_ICTL) && \
	!defined(CONFIG_INTEL_VTD_ICTL_XAPIC_PASSTHROUGH)

	#include <zephyr/drivers/interrupt_controller/intel_vtd.h>
	#include <zephyr/arch/x86/acpi.h>

	static const struct device *vtd;
	static uint16_t ioapic_id;


	static bool get_vtd(void)
	{
	if (vtd != NULL) {
	return true;
	}

	#define DRV_COMPAT_BAK DT_DRV_COMPAT
	#undef DT_DRV_COMPAT
	#define DT_DRV_COMPAT intel_vt_d
	vtd = DEVICE_DT_GET_OR_NULL(DT_DRV_INST(0));
	#undef DT_DRV_COMPAT
	#define DT_DRV_COMPAT DRV_COMPAT_BAK
	#undef DRV_COMPAT_BAK

	ioapic_id = z_acpi_get_dev_id_from_dmar(ACPI_DRHD_DEV_SCOPE_IOAPIC);

	return vtd == NULL ? false : true;
	}
	#endif /* CONFIG_INTEL_VTD_ICTL && !INTEL_VTD_ICTL_XAPIC_PASSTHROUGH */

	/*
	* The functions irq_enable() and irq_disable() are implemented in the
	* interrupt controller driver due to the IRQ virtualization imposed by
	* the x86 architecture.
	*/

	/**
	* @brief Initialize the IO APIC or xAPIC
	*
	* This routine initializes the IO APIC or xAPIC.
	*
	* @retval 0 on success.
	*/
	__boot_func
	int ioapic_init(const struct device *unused)
	{
	ARG_UNUSED(unused);

	DEVICE_MMIO_TOPLEVEL_MAP(ioapic_regs, K_MEM_CACHE_NONE);

	/* Reading MRE: this will give the number of RTEs available */
	ioapic_rtes = ((__IoApicGet(IOAPIC_VERS) &
	IOAPIC_MRE_MASK) >> IOAPIC_MRE_POS) + 1;

	#ifdef CONFIG_IOAPIC_MASK_RTE
	int32_t ix; /* redirection table index */
	uint32_t rteValue; /* value to copy into redirection table entry */

	rteValue = IOAPIC_EDGE \| IOAPIC_HIGH \| IOAPIC_FIXED \| IOAPIC_INT_MASK \|
	IOAPIC_LOGICAL \| 0 /* dummy vector */;

	for (ix = 0; ix < ioapic_rtes; ix++) {
	ioApicRedSetHi(ix, DEFAULT_RTE_DEST);
	ioApicRedSetLo(ix, rteValue);
	}
	#endif
	return 0;
	}

	__pinned_func
	uint32_t z_ioapic_num_rtes(void)
	{
	return ioapic_rtes;
	}

	/**
	* @brief Enable a specified APIC interrupt input line
	*
	* This routine enables a specified APIC interrupt input line.
	*
	* @param irq IRQ number to enable
	*/
	__pinned_func
	void z_ioapic_irq_enable(unsigned int irq)
	{
	IoApicRedUpdateLo(irq, 0, IOAPIC_INT_MASK);
	}

	/**
	* @brief Disable a specified APIC interrupt input line
	*
	* This routine disables a specified APIC interrupt input line.
	* @param irq IRQ number to disable
	*/
	__pinned_func
	void z_ioapic_irq_disable(unsigned int irq)
	{
	IoApicRedUpdateLo(irq, IOAPIC_INT_MASK, IOAPIC_INT_MASK);
	}


	#ifdef CONFIG_PM_DEVICE

	__pinned_func
	void store_flags(unsigned int irq, uint32_t flags)
	{
	/* Currently only the following four flags are modified */
	if (flags & IOAPIC_LOW) {
	sys_bitfield_set_bit((mem_addr_t) ioapic_suspend_buf,
	BIT_POS_FOR_IRQ_OPTION(irq, IOAPIC_BITFIELD_HI_LO));
	}

	if (flags & IOAPIC_LEVEL) {
	sys_bitfield_set_bit((mem_addr_t) ioapic_suspend_buf,
	BIT_POS_FOR_IRQ_OPTION(irq, IOAPIC_BITFIELD_LVL_EDGE));
	}

	if (flags & IOAPIC_INT_MASK) {
	sys_bitfield_set_bit((mem_addr_t) ioapic_suspend_buf,
	BIT_POS_FOR_IRQ_OPTION(irq, IOAPIC_BITFIELD_ENBL_DSBL));
	}

	/*
	* We support lowest priority and fixed mode only, so only one bit
	* needs to be saved.
	*/
	if (flags & IOAPIC_LOWEST) {
	sys_bitfield_set_bit((mem_addr_t) ioapic_suspend_buf,
	BIT_POS_FOR_IRQ_OPTION(irq, IOAPIC_BITFIELD_DELIV_MODE));
	}
	}

	__pinned_func
	uint32_t restore_flags(unsigned int irq)
	{
	uint32_t flags = 0U;

	if (sys_bitfield_test_bit((mem_addr_t) ioapic_suspend_buf,
	BIT_POS_FOR_IRQ_OPTION(irq, IOAPIC_BITFIELD_HI_LO))) {
	flags \|= IOAPIC_LOW;
	}

	if (sys_bitfield_test_bit((mem_addr_t) ioapic_suspend_buf,
	BIT_POS_FOR_IRQ_OPTION(irq, IOAPIC_BITFIELD_LVL_EDGE))) {
	flags \|= IOAPIC_LEVEL;
	}

	if (sys_bitfield_test_bit((mem_addr_t) ioapic_suspend_buf,
	BIT_POS_FOR_IRQ_OPTION(irq, IOAPIC_BITFIELD_ENBL_DSBL))) {
	flags \|= IOAPIC_INT_MASK;
	}

	if (sys_bitfield_test_bit((mem_addr_t) ioapic_suspend_buf,
	BIT_POS_FOR_IRQ_OPTION(irq, IOAPIC_BITFIELD_DELIV_MODE))) {
	flags \|= IOAPIC_LOWEST;
	}

	return flags;
	}


	__pinned_func
	int ioapic_suspend(const struct device *port)
	{
	int irq;
	uint32_t rte_lo;

	ARG_UNUSED(port);
	(void)memset(ioapic_suspend_buf, 0, (SUSPEND_BITS_REQD >> 3));
	for (irq = 0; irq < ioapic_rtes; irq++) {
	/*
	* The following check is to figure out the registered
	* IRQ lines, so as to limit ourselves to saving the
	* flags for them only.
	*/
	if (_irq_to_interrupt_vector[irq]) {
	rte_lo = ioApicRedGetLo(irq);
	store_flags(irq, rte_lo);
	}
	}
	return 0;
	}

	__pinned_func
	int ioapic_resume_from_suspend(const struct device *port)
	{
	int irq;
	uint32_t flags;
	uint32_t rteValue;

	ARG_UNUSED(port);

	for (irq = 0; irq < ioapic_rtes; irq++) {
	if (_irq_to_interrupt_vector[irq]) {
	/* Get the saved flags */
	flags = restore_flags(irq);
	/* Appending the flags that are never modified */
	flags = flags \| IOAPIC_LOGICAL;

	rteValue = (_irq_to_interrupt_vector[irq] &
	IOAPIC_VEC_MASK) \| flags;
	} else {
	/* Initialize the other RTEs to sane values */
	rteValue = IOAPIC_EDGE \| IOAPIC_HIGH \|
	IOAPIC_FIXED \| IOAPIC_INT_MASK \|
	IOAPIC_LOGICAL \| 0 ; /* dummy vector*/
	}
	ioApicRedSetHi(irq, DEFAULT_RTE_DEST);
	ioApicRedSetLo(irq, rteValue);
	}
	return 0;
	}

	/*
	* Implements the driver control management functionality
	* the *context may include IN data or/and OUT data
	*/
	__pinned_func
	static int ioapic_pm_action(const struct device *dev,
	enum pm_device_action action)
	{
	int ret = 0;

	switch (action) {
	case PM_DEVICE_ACTION_RESUME:
	ret = ioapic_resume_from_suspend(dev);
	break;
	case PM_DEVICE_ACTION_SUSPEND:
	ret = ioapic_suspend(dev);
	break;
	default:
	ret = -ENOTSUP;
	}

	return ret;
	}

	#endif /CONFIG_PM_DEVICE/

	/**
	* @brief Programs the interrupt redirection table
	*
	* This routine sets up the redirection table entry for the specified IRQ
	* @param irq Virtualized IRQ
	* @param vector Vector number
	* @param flags Interrupt flags
	*/
	__boot_func
	void z_ioapic_irq_set(unsigned int irq, unsigned int vector, uint32_t flags)
	{
	uint32_t rteValue; /* value to copy into redirection table entry */
	#if defined(CONFIG_INTEL_VTD_ICTL) && \
	!defined(CONFIG_INTEL_VTD_ICTL_XAPIC_PASSTHROUGH)
	int irte_idx;

	if (!get_vtd()) {
	goto no_vtd;
	}

	irte_idx = vtd_get_irte_by_vector(vtd, vector);
	if (irte_idx < 0) {
	irte_idx = vtd_get_irte_by_irq(vtd, irq);
	}

	if (irte_idx >= 0 && !vtd_irte_is_msi(vtd, irte_idx)) {
	/* Enable interrupt remapping format and set the irte index */
	rteValue = IOAPIC_VTD_REMAP_FORMAT \|
	IOAPIC_VTD_INDEX(irte_idx);
	ioApicRedSetHi(irq, rteValue);

	/* Remapped: delivery mode is Fixed (000) and
	* destination mode is no longer present as it is replaced by
	* the 15th bit of irte index, which is always 0 in our case.
	*/
	rteValue = IOAPIC_INT_MASK \|
	(vector & IOAPIC_VEC_MASK) \|
	(flags & IOAPIC_TRIGGER_MASK) \|
	(flags & IOAPIC_POLARITY_MASK);
	ioApicRedSetLo(irq, rteValue);

	vtd_remap(vtd, irte_idx, vector, flags, ioapic_id);
	} else {
	no_vtd:
	#else
	{
	#endif /* CONFIG_INTEL_VTD_ICTL && !CONFIG_INTEL_VTD_ICTL_XAPIC_PASSTHROUGH */
	/* the delivery mode is determined by the flags
	* passed from drivers
	*/
	rteValue = IOAPIC_INT_MASK \| IOAPIC_LOGICAL \|
	(vector & IOAPIC_VEC_MASK) \| flags;
	ioApicRedSetHi(irq, DEFAULT_RTE_DEST);
	ioApicRedSetLo(irq, rteValue);
	}
	}

	/**
	* @brief Program interrupt vector for specified irq
	*
	* The routine writes the interrupt vector in the Interrupt Redirection
	* Table for specified irq number
	*
	* @param irq Interrupt number
	* @param vector Vector number
	*/
	__boot_func
	void z_ioapic_int_vec_set(unsigned int irq, unsigned int vector)
	{
	IoApicRedUpdateLo(irq, vector, IOAPIC_VEC_MASK);
	}

	/**
	* @brief Read a 32 bit IO APIC register
	*
	* This routine reads the specified IO APIC register using indirect addressing.
	* @param offset Register offset (8 bits)
	*
	* @return register value
	*/
	__pinned_func
	static uint32_t __IoApicGet(int32_t offset)
	{
	uint32_t value; /* value */
	unsigned int key; /* interrupt lock level */

	/* lock interrupts to ensure indirect addressing works "atomically" */

	key = irq_lock();

	((volatile uint32_t ) (IOAPIC_REG + IOAPIC_IND)) = (char)offset;
	value = ((volatile uint32_t )(IOAPIC_REG + IOAPIC_DATA));

	irq_unlock(key);

	return value;
	}

	/**
	* @brief Write a 32 bit IO APIC register
	*
	* This routine writes the specified IO APIC register using indirect addressing.
	*
	* @param offset Register offset (8 bits)
	* @param value Value to set the register
	*/
	__pinned_func
	static void __IoApicSet(int32_t offset, uint32_t value)
	{
	unsigned int key; /* interrupt lock level */

	/* lock interrupts to ensure indirect addressing works "atomically" */

	key = irq_lock();

	(volatile uint32_t )(IOAPIC_REG + IOAPIC_IND) = (char)offset;
	((volatile uint32_t )(IOAPIC_REG + IOAPIC_DATA)) = value;

	irq_unlock(key);
	}

	/**
	* @brief Get low 32 bits of Redirection Table entry
	*
	* This routine reads the low-order 32 bits of a Redirection Table entry.
	*
	* @param irq INTIN number
	* @return 32 low-order bits
	*/
	__pinned_func
	static uint32_t ioApicRedGetLo(unsigned int irq)
	{
	int32_t offset = IOAPIC_REDTBL + (irq << 1); /* register offset */

	return __IoApicGet(offset);
	}

	/**
	* @brief Set low 32 bits of Redirection Table entry
	*
	* This routine writes the low-order 32 bits of a Redirection Table entry.
	*
	* @param irq INTIN number
	* @param lower32 Value to be written
	*/
	__pinned_func
	static void ioApicRedSetLo(unsigned int irq, uint32_t lower32)
	{
	int32_t offset = IOAPIC_REDTBL + (irq << 1); /* register offset */

	__IoApicSet(offset, lower32);
	}

	/**
	* @brief Set high 32 bits of Redirection Table entry
	*
	* This routine writes the high-order 32 bits of a Redirection Table entry.
	*
	* @param irq INTIN number
	* @param upper32 Value to be written
	*/
	__pinned_func
	static void ioApicRedSetHi(unsigned int irq, uint32_t upper32)
	{
	int32_t offset = IOAPIC_REDTBL + (irq << 1) + 1; /* register offset */

	__IoApicSet(offset, upper32);
	}

	/**
	* @brief Modify low 32 bits of Redirection Table entry
	*
	* This routine modifies selected portions of the low-order 32 bits of a
	* Redirection Table entry, as indicated by the associate bit mask.
	*
	* @param irq INTIN number
	* @param value Value to be written
	* @param mask Mask of bits to be modified
	*/
	__pinned_func
	static void IoApicRedUpdateLo(unsigned int irq,
	uint32_t value,
	uint32_t mask)
	{
	ioApicRedSetLo(irq, (ioApicRedGetLo(irq) & ~mask) \| (value & mask));
	}

	PM_DEVICE_DEFINE(ioapic, ioapic_pm_action);

	DEVICE_DEFINE(ioapic, "ioapic", ioapic_init, PM_DEVICE_GET(ioapic), NULL, NULL,
	PRE_KERNEL_1, CONFIG_INTC_INIT_PRIORITY, NULL);