include/arch/x86/arch.h - third_party/github/zephyrproject-rtos/zephyr - Git at Google

 /*
  * Copyright (c) 2010-2014 Wind River Systems, Inc.
  *
  * SPDX-License-Identifier: Apache-2.0
  */

 /**
  * @file
  * @brief IA-32 specific kernel interface header
  * This header contains the IA-32 specific kernel interface.  It is included
  * by the generic kernel interface header (include/arch/cpu.h)
  */

 #ifndef _ARCH_IFACE_H
 #define _ARCH_IFACE_H

 #include <irq.h>
 #include <arch/x86/irq_controller.h>
 #include <kernel_arch_thread.h>

 #ifndef _ASMLANGUAGE
 #include <arch/x86/asm_inline.h>
 #include <arch/x86/addr_types.h>
 #endif

 #ifdef __cplusplus
 extern "C" {
 #endif

 /* APIs need to support non-byte addressable architectures */

 #define OCTET_TO_SIZEOFUNIT(X) (X)
 #define SIZEOFUNIT_TO_OCTET(X) (X)

 /**
  * Macro used internally by NANO_CPU_INT_REGISTER and NANO_CPU_INT_REGISTER_ASM.
  * Not meant to be used explicitly by platform, driver or application code.
  */
 #define MK_ISR_NAME(x) __isr__##x

 #ifndef _ASMLANGUAGE

 #ifdef CONFIG_INT_LATENCY_BENCHMARK
 void _int_latency_start(void);
 void _int_latency_stop(void);
 #else
 #define _int_latency_start()  do { } while (0)
 #define _int_latency_stop()   do { } while (0)
 #endif

 /* interrupt/exception/error related definitions */

 /*
  * The TCS must be aligned to the same boundary as that used by the floating
  * point register set.  This applies even for threads that don't initially
  * use floating point, since it is possible to enable floating point support
  * later on.
  */

 #define STACK_ALIGN  FP_REG_SET_ALIGN

 typedef struct s_isrList {
 	/** Address of ISR/stub */
 	void		*fnc;
 	/** IRQ associated with the ISR/stub, or -1 if this is not
 	 * associated with a real interrupt; in this case vec must
 	 * not be -1
 	 */
 	unsigned int    irq;
 	/** Priority associated with the IRQ. Ignored if vec is not -1 */
 	unsigned int    priority;
 	/** Vector number associated with ISR/stub, or -1 to assign based
 	 * on priority
 	 */
 	unsigned int    vec;
 	/** Privilege level associated with ISR/stub */
 	unsigned int    dpl;
 } ISR_LIST;


 /**
  * @brief Connect a routine to an interrupt vector
  *
  * This macro "connects" the specified routine, @a r, to the specified interrupt
  * vector, @a v using the descriptor privilege level @a d. On the IA-32
  * architecture, an interrupt vector is a value from 0 to 255. This macro
  * populates the special intList section with the address of the routine, the
  * vector number and the descriptor privilege level. The genIdt tool then picks
  * up this information and generates an actual IDT entry with this information
  * properly encoded.
  *
  * The @a d argument specifies the privilege level for the interrupt-gate
  * descriptor; (hardware) interrupts and exceptions should specify a level of 0,
  * whereas handlers for user-mode software generated interrupts should specify 3.
  * @param r Routine to be connected
  * @param n IRQ number
  * @param p IRQ priority
  * @param v Interrupt Vector
  * @param d Descriptor Privilege Level
  *
  * @return N/A
  *
  */

 #define NANO_CPU_INT_REGISTER(r, n, p, v, d) \
 	 static ISR_LIST __attribute__((section(".intList"))) \
 			 __attribute__((used)) MK_ISR_NAME(r) = \
 			{&r, n, p, v, d}


 /**
  * Code snippets for populating the vector ID and priority into the intList
  *
  * The 'magic' of static interrupts is accomplished by building up an array
  * 'intList' at compile time, and the gen_idt tool uses this to create the
  * actual IDT data structure.
  *
  * For controllers like APIC, the vectors in the IDT are not normally assigned
  * at build time; instead the sentinel value -1 is saved, and gen_idt figures
  * out the right vector to use based on our priority scheme. Groups of 16
  * vectors starting at 32 correspond to each priority level.
  *
  * On MVIC, the mapping is fixed; the vector to use is just the irq line
  * number plus 0x20. The priority argument supplied by the user is discarded.
  *
  * These macros are only intended to be used by IRQ_CONNECT() macro.
  */
 #if CONFIG_X86_FIXED_IRQ_MAPPING
 #define _VECTOR_ARG(irq_p)	_IRQ_CONTROLLER_VECTOR_MAPPING(irq_p)
 #else
 #define _VECTOR_ARG(irq_p)	(-1)
 #endif /* CONFIG_X86_FIXED_IRQ_MAPPING */

 /**
  * Configure a static interrupt.
  *
  * All arguments must be computable by the compiler at build time.
  *
  * Internally this function does a few things:
  *
  * 1. There is a declaration of the interrupt parameters in the .intList
  * section, used by gen_idt to create the IDT. This does the same thing
  * as the NANO_CPU_INT_REGISTER() macro, but is done in assembly as we
  * need to populate the .fnc member with the address of the assembly
  * IRQ stub that we generate immediately afterwards.
  *
  * 2. The IRQ stub itself is declared. The code will go in its own named
  * section .text.irqstubs section (which eventually gets linked into 'text')
  * and the stub shall be named (isr_name)_irq(irq_line)_stub
  *
  * 3. The IRQ stub pushes the ISR routine and its argument onto the stack
  * and then jumps to the common interrupt handling code in _interrupt_enter().
  *
  * 4. _irq_controller_irq_config() is called at runtime to set the mapping
  * between the vector and the IRQ line as well as triggering flags
  *
  * @param irq_p IRQ line number
  * @param priority_p Interrupt priority
  * @param isr_p Interrupt service routine
  * @param isr_param_p ISR parameter
  * @param flags_p IRQ triggering options, as defined in irq_controller.h
  *
  * @return The vector assigned to this interrupt
  */
 #define _ARCH_IRQ_CONNECT(irq_p, priority_p, isr_p, isr_param_p, flags_p) \
 ({ \
 	__asm__ __volatile__(							\
 		".pushsection .intList\n\t" \
 		".long %c[isr]_irq%c[irq]_stub\n\t"	/* ISR_LIST.fnc */ \
 		".long %c[irq]\n\t"		/* ISR_LIST.irq */ \
 		".long %c[priority]\n\t"	/* ISR_LIST.priority */ \
 		".long %c[vector]\n\t"		/* ISR_LIST.vec */ \
 		".long 0\n\t"			/* ISR_LIST.dpl */ \
 		".popsection\n\t" \
 		".pushsection .text.irqstubs\n\t" \
 		".global %c[isr]_irq%c[irq]_stub\n\t" \
 		"%c[isr]_irq%c[irq]_stub:\n\t" \
 		"pushl %[isr_param]\n\t" \
 		"pushl %[isr]\n\t" \
 		"jmp _interrupt_enter\n\t" \
 		".popsection\n\t" \
 		: \
 		: [isr] "i" (isr_p), \
 		  [isr_param] "i" (isr_param_p), \
 		  [priority] "i" (priority_p), \
 		  [vector] "i" _VECTOR_ARG(irq_p), \
 		  [irq] "i" (irq_p)); \
 	_irq_controller_irq_config(_IRQ_TO_INTERRUPT_VECTOR(irq_p), (irq_p), \
 				   (flags_p)); \
 	_IRQ_TO_INTERRUPT_VECTOR(irq_p); \
 })

 /** Configure a 'direct' static interrupt
  *
  * All arguments must be computable by the compiler at build time
  *
  */
 #define _ARCH_IRQ_DIRECT_CONNECT(irq_p, priority_p, isr_p, flags_p) \
 ({ \
 	NANO_CPU_INT_REGISTER(isr_p, irq_p, priority_p, -1, 0); \
 	_irq_controller_irq_config(_IRQ_TO_INTERRUPT_VECTOR(irq_p), (irq_p), \
 				   (flags_p)); \
 	_IRQ_TO_INTERRUPT_VECTOR(irq_p); \
 })


 #ifdef CONFIG_X86_FIXED_IRQ_MAPPING
 /* Fixed vector-to-irq association mapping.
  * No need for the table at all.
  */
 #define _IRQ_TO_INTERRUPT_VECTOR(irq) _IRQ_CONTROLLER_VECTOR_MAPPING(irq)
 #else
 /**
  * @brief Convert a statically connected IRQ to its interrupt vector number
  *
  * @param irq IRQ number
  */
 extern unsigned char _irq_to_interrupt_vector[];
 #define _IRQ_TO_INTERRUPT_VECTOR(irq)                       \
 			((unsigned int) _irq_to_interrupt_vector[irq])
 #endif

 #ifdef CONFIG_SYS_POWER_MANAGEMENT
 extern void _arch_irq_direct_pm(void);
 #define _ARCH_ISR_DIRECT_PM() _arch_irq_direct_pm()
 #else
 #define _ARCH_ISR_DIRECT_PM() do { } while (0)
 #endif

 #define _ARCH_ISR_DIRECT_HEADER() _arch_isr_direct_header()
 #define _ARCH_ISR_DIRECT_FOOTER(swap) _arch_isr_direct_footer(swap)

 /* FIXME prefer these inline, but see ZEP-1595 */
 extern void _arch_isr_direct_header(void);
 extern void _arch_isr_direct_footer(int maybe_swap);

 #define _ARCH_ISR_DIRECT_DECLARE(name) \
 	static inline int name##_body(void); \
 	__attribute__ ((interrupt)) void name(void *stack_frame) \
 	{ \
 		ARG_UNUSED(stack_frame); \
 		int check_reschedule; \
 		ISR_DIRECT_HEADER(); \
 		check_reschedule = name##_body(); \
 		ISR_DIRECT_FOOTER(check_reschedule); \
 	} \
 	static inline int name##_body(void)

 /**
  * @brief Exception Stack Frame
  *
  * A pointer to an "exception stack frame" (ESF) is passed as an argument
  * to exception handlers registered via nanoCpuExcConnect().  As the system
  * always operates at ring 0, only the EIP, CS and EFLAGS registers are pushed
  * onto the stack when an exception occurs.
  *
  * The exception stack frame includes the volatile registers (EAX, ECX, and
  * EDX) as well as the 5 non-volatile registers (EDI, ESI, EBX, EBP and ESP).
  * Those registers are pushed onto the stack by _ExcEnt().
  */

 typedef struct nanoEsf {
 	unsigned int esp;
 	unsigned int ebp;
 	unsigned int ebx;
 	unsigned int esi;
 	unsigned int edi;
 	unsigned int edx;
 	unsigned int eax;
 	unsigned int ecx;
 	unsigned int errorCode;
 	unsigned int eip;
 	unsigned int cs;
 	unsigned int eflags;
 } NANO_ESF;

 /**
  * @brief "interrupt stack frame" (ISF)
  *
  * An "interrupt stack frame" (ISF) as constructed by the processor and the
  * interrupt wrapper function _interrupt_enter().  As the system always
  * operates at ring 0, only the EIP, CS and EFLAGS registers are pushed onto
  * the stack when an interrupt occurs.
  *
  * The interrupt stack frame includes the volatile registers EAX, ECX, and EDX
  * plus nonvolatile EDI pushed on the stack by _interrupt_enter().
  *
  * Only target-based debug tools such as GDB require the other non-volatile
  * registers (ESI, EBX, EBP and ESP) to be preserved during an interrupt.
  */

 typedef struct nanoIsf {
 #ifdef CONFIG_DEBUG_INFO
 	unsigned int esp;
 	unsigned int ebp;
 	unsigned int ebx;
 	unsigned int esi;
 #endif /* CONFIG_DEBUG_INFO */
 	unsigned int edi;
 	unsigned int ecx;
 	unsigned int edx;
 	unsigned int eax;
 	unsigned int eip;
 	unsigned int cs;
 	unsigned int eflags;
 } NANO_ISF;

 #endif /* !_ASMLANGUAGE */

 /*
  * Reason codes passed to both _NanoFatalErrorHandler()
  * and _SysFatalErrorHandler().
  */

 /** Unhandled exception/interrupt */
 #define _NANO_ERR_SPURIOUS_INT		 (0)
 /** Page fault */
 #define _NANO_ERR_PAGE_FAULT		 (1)
 /** General protection fault */
 #define _NANO_ERR_GEN_PROT_FAULT	 (2)
 /** Invalid task exit */
 #define _NANO_ERR_INVALID_TASK_EXIT  (3)
 /** Stack corruption detected */
 #define _NANO_ERR_STACK_CHK_FAIL	 (4)
 /** Kernel Allocation Failure */
 #define _NANO_ERR_ALLOCATION_FAIL    (5)
 /** Unhandled exception */
 #define _NANO_ERR_CPU_EXCEPTION		(6)
 /** Kernel oops (fatal to thread) */
 #define _NANO_ERR_KERNEL_OOPS		(7)
 /** Kernel panic (fatal to system) */
 #define _NANO_ERR_KERNEL_PANIC		(8)

 #ifndef _ASMLANGUAGE

 /**
  * @brief Disable all interrupts on the CPU (inline)
  *
  * This routine disables interrupts.  It can be called from either interrupt,
  * task or fiber level.  This routine returns an architecture-dependent
  * lock-out key representing the "interrupt disable state" prior to the call;
  * this key can be passed to irq_unlock() to re-enable interrupts.
  *
  * The lock-out key should only be used as the argument to the irq_unlock()
  * API.  It should never be used to manually re-enable interrupts or to inspect
  * or manipulate the contents of the source register.
  *
  * This function can be called recursively: it will return a key to return the
  * state of interrupt locking to the previous level.
  *
  * WARNINGS
  * Invoking a kernel routine with interrupts locked may result in
  * interrupts being re-enabled for an unspecified period of time.  If the
  * called routine blocks, interrupts will be re-enabled while another
  * thread executes, or while the system is idle.
  *
  * The "interrupt disable state" is an attribute of a thread.  Thus, if a
  * fiber or task disables interrupts and subsequently invokes a kernel
  * routine that causes the calling thread to block, the interrupt
  * disable state will be restored when the thread is later rescheduled
  * for execution.
  *
  * @return An architecture-dependent lock-out key representing the
  * "interrupt disable state" prior to the call.
  *
  */

 static ALWAYS_INLINE unsigned int _arch_irq_lock(void)
 {
 	unsigned int key = _do_irq_lock();

 	_int_latency_start();

 	return key;
 }


 /**
  *
  * @brief Enable all interrupts on the CPU (inline)
  *
  * This routine re-enables interrupts on the CPU.  The @a key parameter
  * is an architecture-dependent lock-out key that is returned by a previous
  * invocation of irq_lock().
  *
  * This routine can be called from either interrupt, task or fiber level.
  *
  * @return N/A
  *
  */

 static ALWAYS_INLINE void _arch_irq_unlock(unsigned int key)
 {
 	if (!(key & 0x200)) {
 		return;
 	}

 	_int_latency_stop();

 	_do_irq_unlock();
 }

 /**
  * The NANO_SOFT_IRQ macro must be used as the value for the @a irq parameter
  * to NANO_CPU_INT_REGISTER when connecting to an interrupt that does not
  * correspond to any IRQ line (such as spurious vector or SW IRQ)
  */
 #define NANO_SOFT_IRQ	((unsigned int) (-1))

 /**
  * @brief Enable a specific IRQ
  * @param irq IRQ
  */
 extern void	_arch_irq_enable(unsigned int irq);
 /**
  * @brief Disable a specific IRQ
  * @param irq IRQ
  */
 extern void	_arch_irq_disable(unsigned int irq);

 /**
  * @defgroup float_apis Floating Point APIs
  * @ingroup kernel_apis
  * @{
  */

 /**
  * @brief Enable preservation of floating point context information.
  *
  * This routine informs the kernel that the specified thread (which may be
  * the current thread) will be using the floating point registers.
  * The @a options parameter indicates which floating point register sets
  * will be used by the specified thread:
  *
  *  a) K_FP_REGS  indicates x87 FPU and MMX registers only
  *  b) K_SSE_REGS indicates SSE registers (and also x87 FPU and MMX registers)
  *
  * Invoking this routine initializes the thread's floating point context info
  * to that of an FPU that has been reset. The next time the thread is scheduled
  * by _Swap() it will either inherit an FPU that is guaranteed to be in a "sane"
  * state (if the most recent user of the FPU was cooperatively swapped out)
  * or the thread's own floating point context will be loaded (if the most
  * recent user of the FPU was preempted, or if this thread is the first user
  * of the FPU). Thereafter, the kernel will protect the thread's FP context
  * so that it is not altered during a preemptive context switch.
  *
  * @warning
  * This routine should only be used to enable floating point support for a
  * thread that does not currently have such support enabled already.
  *
  * @param thread ID of thread.
  * @param options Registers to be preserved (K_FP_REGS or K_SSE_REGS).
  *
  * @return N/A
  */
 extern void k_float_enable(k_tid_t thread, unsigned int options);

 /**
  * @brief Disable preservation of floating point context information.
  *
  * This routine informs the kernel that the specified thread (which may be
  * the current thread) will no longer be using the floating point registers.
  *
  * @warning
  * This routine should only be used to disable floating point support for
  * a thread that currently has such support enabled.
  *
  * @param thread ID of thread.
  *
  * @return N/A
  */
 extern void k_float_disable(k_tid_t thread);

 /**
  * @}
  */

 #include <stddef.h>	/* for size_t */

 extern void	k_cpu_idle(void);

 extern u32_t _timer_cycle_get_32(void);
 #define _arch_k_cycle_get_32()	_timer_cycle_get_32()

 /** kernel provided routine to report any detected fatal error. */
 extern FUNC_NORETURN void _NanoFatalErrorHandler(unsigned int reason,
 						 const NANO_ESF * pEsf);

 /** User provided routine to handle any detected fatal error post reporting. */
 extern FUNC_NORETURN void _SysFatalErrorHandler(unsigned int reason,
 						const NANO_ESF * pEsf);

 #if CONFIG_X86_KERNEL_OOPS
 #define _ARCH_EXCEPT(reason_p) do { \
 	__asm__ volatile( \
 		"push %[reason]\n\t" \
 		"int %[vector]\n\t" \
 		: \
 		: [vector] "i" (CONFIG_X86_KERNEL_OOPS_VECTOR), \
 		  [reason] "i" (reason_p)); \
 	CODE_UNREACHABLE; \
 } while (0)
 #else
 /** Dummy ESF for fatal errors that would otherwise not have an ESF */
 extern const NANO_ESF _default_esf;
 #endif /* CONFIG_X86_KERNEL_OOPS */

 #endif /* !_ASMLANGUAGE */

 /* reboot through Reset Control Register (I/O port 0xcf9) */

 #define SYS_X86_RST_CNT_REG 0xcf9
 #define SYS_X86_RST_CNT_SYS_RST 0x02
 #define SYS_X86_RST_CNT_CPU_RST 0x4
 #define SYS_X86_RST_CNT_FULL_RST 0x08

 #ifdef __cplusplus
 }
 #endif

 #endif /* _ARCH_IFACE_H */
	/*
	* Copyright (c) 2010-2014 Wind River Systems, Inc.
	*
	* SPDX-License-Identifier: Apache-2.0
	*/

	/**
	* @file
	* @brief IA-32 specific kernel interface header
	* This header contains the IA-32 specific kernel interface. It is included
	* by the generic kernel interface header (include/arch/cpu.h)
	*/

	#ifndef _ARCH_IFACE_H
	#define _ARCH_IFACE_H

	#include <irq.h>
	#include <arch/x86/irq_controller.h>
	#include <kernel_arch_thread.h>

	#ifndef _ASMLANGUAGE
	#include <arch/x86/asm_inline.h>
	#include <arch/x86/addr_types.h>
	#endif

	#ifdef __cplusplus
	extern "C" {
	#endif

	/* APIs need to support non-byte addressable architectures */

	#define OCTET_TO_SIZEOFUNIT(X) (X)
	#define SIZEOFUNIT_TO_OCTET(X) (X)

	/**
	* Macro used internally by NANO_CPU_INT_REGISTER and NANO_CPU_INT_REGISTER_ASM.
	* Not meant to be used explicitly by platform, driver or application code.
	*/
	#define MK_ISR_NAME(x) __isr__##x

	#ifndef _ASMLANGUAGE

	#ifdef CONFIG_INT_LATENCY_BENCHMARK
	void _int_latency_start(void);
	void _int_latency_stop(void);
	#else
	#define _int_latency_start() do { } while (0)
	#define _int_latency_stop() do { } while (0)
	#endif

	/* interrupt/exception/error related definitions */

	/*
	* The TCS must be aligned to the same boundary as that used by the floating
	* point register set. This applies even for threads that don't initially
	* use floating point, since it is possible to enable floating point support
	* later on.
	*/

	#define STACK_ALIGN FP_REG_SET_ALIGN

	typedef struct s_isrList {
	/** Address of ISR/stub */
	void *fnc;
	/** IRQ associated with the ISR/stub, or -1 if this is not
	* associated with a real interrupt; in this case vec must
	* not be -1
	*/
	unsigned int irq;
	/** Priority associated with the IRQ. Ignored if vec is not -1 */
	unsigned int priority;
	/** Vector number associated with ISR/stub, or -1 to assign based
	* on priority
	*/
	unsigned int vec;
	/** Privilege level associated with ISR/stub */
	unsigned int dpl;
	} ISR_LIST;


	/**
	* @brief Connect a routine to an interrupt vector
	*
	* This macro "connects" the specified routine, @a r, to the specified interrupt
	* vector, @a v using the descriptor privilege level @a d. On the IA-32
	* architecture, an interrupt vector is a value from 0 to 255. This macro
	* populates the special intList section with the address of the routine, the
	* vector number and the descriptor privilege level. The genIdt tool then picks
	* up this information and generates an actual IDT entry with this information
	* properly encoded.
	*
	* The @a d argument specifies the privilege level for the interrupt-gate
	* descriptor; (hardware) interrupts and exceptions should specify a level of 0,
	* whereas handlers for user-mode software generated interrupts should specify 3.
	* @param r Routine to be connected
	* @param n IRQ number
	* @param p IRQ priority
	* @param v Interrupt Vector
	* @param d Descriptor Privilege Level
	*
	* @return N/A
	*
	*/

	#define NANO_CPU_INT_REGISTER(r, n, p, v, d) \
	static ISR_LIST __attribute__((section(".intList"))) \
	__attribute__((used)) MK_ISR_NAME(r) = \
	{&r, n, p, v, d}


	/**
	* Code snippets for populating the vector ID and priority into the intList
	*
	* The 'magic' of static interrupts is accomplished by building up an array
	* 'intList' at compile time, and the gen_idt tool uses this to create the
	* actual IDT data structure.
	*
	* For controllers like APIC, the vectors in the IDT are not normally assigned
	* at build time; instead the sentinel value -1 is saved, and gen_idt figures
	* out the right vector to use based on our priority scheme. Groups of 16
	* vectors starting at 32 correspond to each priority level.
	*
	* On MVIC, the mapping is fixed; the vector to use is just the irq line
	* number plus 0x20. The priority argument supplied by the user is discarded.
	*
	* These macros are only intended to be used by IRQ_CONNECT() macro.
	*/
	#if CONFIG_X86_FIXED_IRQ_MAPPING
	#define _VECTOR_ARG(irq_p) _IRQ_CONTROLLER_VECTOR_MAPPING(irq_p)
	#else
	#define _VECTOR_ARG(irq_p) (-1)
	#endif /* CONFIG_X86_FIXED_IRQ_MAPPING */

	/**
	* Configure a static interrupt.
	*
	* All arguments must be computable by the compiler at build time.
	*
	* Internally this function does a few things:
	*
	* 1. There is a declaration of the interrupt parameters in the .intList
	* section, used by gen_idt to create the IDT. This does the same thing
	* as the NANO_CPU_INT_REGISTER() macro, but is done in assembly as we
	* need to populate the .fnc member with the address of the assembly
	* IRQ stub that we generate immediately afterwards.
	*
	* 2. The IRQ stub itself is declared. The code will go in its own named
	* section .text.irqstubs section (which eventually gets linked into 'text')
	* and the stub shall be named (isr_name)_irq(irq_line)_stub
	*
	* 3. The IRQ stub pushes the ISR routine and its argument onto the stack
	* and then jumps to the common interrupt handling code in _interrupt_enter().
	*
	* 4. _irq_controller_irq_config() is called at runtime to set the mapping
	* between the vector and the IRQ line as well as triggering flags
	*
	* @param irq_p IRQ line number
	* @param priority_p Interrupt priority
	* @param isr_p Interrupt service routine
	* @param isr_param_p ISR parameter
	* @param flags_p IRQ triggering options, as defined in irq_controller.h
	*
	* @return The vector assigned to this interrupt
	*/
	#define _ARCH_IRQ_CONNECT(irq_p, priority_p, isr_p, isr_param_p, flags_p) \
	({ \
	__asm__ __volatile__( \
	".pushsection .intList\n\t" \
	".long %c[isr]_irq%c[irq]_stub\n\t" /* ISR_LIST.fnc */ \
	".long %c[irq]\n\t" /* ISR_LIST.irq */ \
	".long %c[priority]\n\t" /* ISR_LIST.priority */ \
	".long %c[vector]\n\t" /* ISR_LIST.vec */ \
	".long 0\n\t" /* ISR_LIST.dpl */ \
	".popsection\n\t" \
	".pushsection .text.irqstubs\n\t" \
	".global %c[isr]_irq%c[irq]_stub\n\t" \
	"%c[isr]_irq%c[irq]_stub:\n\t" \
	"pushl %[isr_param]\n\t" \
	"pushl %[isr]\n\t" \
	"jmp _interrupt_enter\n\t" \
	".popsection\n\t" \
	: \
	: [isr] "i" (isr_p), \
	[isr_param] "i" (isr_param_p), \
	[priority] "i" (priority_p), \
	[vector] "i" _VECTOR_ARG(irq_p), \
	[irq] "i" (irq_p)); \
	_irq_controller_irq_config(_IRQ_TO_INTERRUPT_VECTOR(irq_p), (irq_p), \
	(flags_p)); \
	_IRQ_TO_INTERRUPT_VECTOR(irq_p); \
	})

	/** Configure a 'direct' static interrupt
	*
	* All arguments must be computable by the compiler at build time
	*
	*/
	#define _ARCH_IRQ_DIRECT_CONNECT(irq_p, priority_p, isr_p, flags_p) \
	({ \
	NANO_CPU_INT_REGISTER(isr_p, irq_p, priority_p, -1, 0); \
	_irq_controller_irq_config(_IRQ_TO_INTERRUPT_VECTOR(irq_p), (irq_p), \
	(flags_p)); \
	_IRQ_TO_INTERRUPT_VECTOR(irq_p); \
	})


	#ifdef CONFIG_X86_FIXED_IRQ_MAPPING
	/* Fixed vector-to-irq association mapping.
	* No need for the table at all.
	*/
	#define _IRQ_TO_INTERRUPT_VECTOR(irq) _IRQ_CONTROLLER_VECTOR_MAPPING(irq)
	#else
	/**
	* @brief Convert a statically connected IRQ to its interrupt vector number
	*
	* @param irq IRQ number
	*/
	extern unsigned char _irq_to_interrupt_vector[];
	#define _IRQ_TO_INTERRUPT_VECTOR(irq) \
	((unsigned int) _irq_to_interrupt_vector[irq])
	#endif

	#ifdef CONFIG_SYS_POWER_MANAGEMENT
	extern void _arch_irq_direct_pm(void);
	#define _ARCH_ISR_DIRECT_PM() _arch_irq_direct_pm()
	#else
	#define _ARCH_ISR_DIRECT_PM() do { } while (0)
	#endif

	#define _ARCH_ISR_DIRECT_HEADER() _arch_isr_direct_header()
	#define _ARCH_ISR_DIRECT_FOOTER(swap) _arch_isr_direct_footer(swap)

	/* FIXME prefer these inline, but see ZEP-1595 */
	extern void _arch_isr_direct_header(void);
	extern void _arch_isr_direct_footer(int maybe_swap);

	#define _ARCH_ISR_DIRECT_DECLARE(name) \
	static inline int name##_body(void); \
	__attribute__ ((interrupt)) void name(void *stack_frame) \
	{ \
	ARG_UNUSED(stack_frame); \
	int check_reschedule; \
	ISR_DIRECT_HEADER(); \
	check_reschedule = name##_body(); \
	ISR_DIRECT_FOOTER(check_reschedule); \
	} \
	static inline int name##_body(void)

	/**
	* @brief Exception Stack Frame
	*
	* A pointer to an "exception stack frame" (ESF) is passed as an argument
	* to exception handlers registered via nanoCpuExcConnect(). As the system
	* always operates at ring 0, only the EIP, CS and EFLAGS registers are pushed
	* onto the stack when an exception occurs.
	*
	* The exception stack frame includes the volatile registers (EAX, ECX, and
	* EDX) as well as the 5 non-volatile registers (EDI, ESI, EBX, EBP and ESP).
	* Those registers are pushed onto the stack by _ExcEnt().
	*/

	typedef struct nanoEsf {
	unsigned int esp;
	unsigned int ebp;
	unsigned int ebx;
	unsigned int esi;
	unsigned int edi;
	unsigned int edx;
	unsigned int eax;
	unsigned int ecx;
	unsigned int errorCode;
	unsigned int eip;
	unsigned int cs;
	unsigned int eflags;
	} NANO_ESF;

	/**
	* @brief "interrupt stack frame" (ISF)
	*
	* An "interrupt stack frame" (ISF) as constructed by the processor and the
	* interrupt wrapper function _interrupt_enter(). As the system always
	* operates at ring 0, only the EIP, CS and EFLAGS registers are pushed onto
	* the stack when an interrupt occurs.
	*
	* The interrupt stack frame includes the volatile registers EAX, ECX, and EDX
	* plus nonvolatile EDI pushed on the stack by _interrupt_enter().
	*
	* Only target-based debug tools such as GDB require the other non-volatile
	* registers (ESI, EBX, EBP and ESP) to be preserved during an interrupt.
	*/

	typedef struct nanoIsf {
	#ifdef CONFIG_DEBUG_INFO
	unsigned int esp;
	unsigned int ebp;
	unsigned int ebx;
	unsigned int esi;
	#endif /* CONFIG_DEBUG_INFO */
	unsigned int edi;
	unsigned int ecx;
	unsigned int edx;
	unsigned int eax;
	unsigned int eip;
	unsigned int cs;
	unsigned int eflags;
	} NANO_ISF;

	#endif /* !_ASMLANGUAGE */

	/*
	* Reason codes passed to both _NanoFatalErrorHandler()
	* and _SysFatalErrorHandler().
	*/

	/** Unhandled exception/interrupt */
	#define _NANO_ERR_SPURIOUS_INT (0)
	/** Page fault */
	#define _NANO_ERR_PAGE_FAULT (1)
	/** General protection fault */
	#define _NANO_ERR_GEN_PROT_FAULT (2)
	/** Invalid task exit */
	#define _NANO_ERR_INVALID_TASK_EXIT (3)
	/** Stack corruption detected */
	#define _NANO_ERR_STACK_CHK_FAIL (4)
	/** Kernel Allocation Failure */
	#define _NANO_ERR_ALLOCATION_FAIL (5)
	/** Unhandled exception */
	#define _NANO_ERR_CPU_EXCEPTION (6)
	/** Kernel oops (fatal to thread) */
	#define _NANO_ERR_KERNEL_OOPS (7)
	/** Kernel panic (fatal to system) */
	#define _NANO_ERR_KERNEL_PANIC (8)

	#ifndef _ASMLANGUAGE

	/**
	* @brief Disable all interrupts on the CPU (inline)
	*
	* This routine disables interrupts. It can be called from either interrupt,
	* task or fiber level. This routine returns an architecture-dependent
	* lock-out key representing the "interrupt disable state" prior to the call;
	* this key can be passed to irq_unlock() to re-enable interrupts.
	*
	* The lock-out key should only be used as the argument to the irq_unlock()
	* API. It should never be used to manually re-enable interrupts or to inspect
	* or manipulate the contents of the source register.
	*
	* This function can be called recursively: it will return a key to return the
	* state of interrupt locking to the previous level.
	*
	* WARNINGS
	* Invoking a kernel routine with interrupts locked may result in
	* interrupts being re-enabled for an unspecified period of time. If the
	* called routine blocks, interrupts will be re-enabled while another
	* thread executes, or while the system is idle.
	*
	* The "interrupt disable state" is an attribute of a thread. Thus, if a
	* fiber or task disables interrupts and subsequently invokes a kernel
	* routine that causes the calling thread to block, the interrupt
	* disable state will be restored when the thread is later rescheduled
	* for execution.
	*
	* @return An architecture-dependent lock-out key representing the
	* "interrupt disable state" prior to the call.
	*
	*/

	static ALWAYS_INLINE unsigned int _arch_irq_lock(void)
	{
	unsigned int key = _do_irq_lock();

	_int_latency_start();

	return key;
	}


	/**
	*
	* @brief Enable all interrupts on the CPU (inline)
	*
	* This routine re-enables interrupts on the CPU. The @a key parameter
	* is an architecture-dependent lock-out key that is returned by a previous
	* invocation of irq_lock().
	*
	* This routine can be called from either interrupt, task or fiber level.
	*
	* @return N/A
	*
	*/

	static ALWAYS_INLINE void _arch_irq_unlock(unsigned int key)
	{
	if (!(key & 0x200)) {
	return;
	}

	_int_latency_stop();

	_do_irq_unlock();
	}

	/**
	* The NANO_SOFT_IRQ macro must be used as the value for the @a irq parameter
	* to NANO_CPU_INT_REGISTER when connecting to an interrupt that does not
	* correspond to any IRQ line (such as spurious vector or SW IRQ)
	*/
	#define NANO_SOFT_IRQ ((unsigned int) (-1))

	/**
	* @brief Enable a specific IRQ
	* @param irq IRQ
	*/
	extern void _arch_irq_enable(unsigned int irq);
	/**
	* @brief Disable a specific IRQ
	* @param irq IRQ
	*/
	extern void _arch_irq_disable(unsigned int irq);

	/**
	* @defgroup float_apis Floating Point APIs
	* @ingroup kernel_apis
	* @{
	*/

	/**
	* @brief Enable preservation of floating point context information.
	*
	* This routine informs the kernel that the specified thread (which may be
	* the current thread) will be using the floating point registers.
	* The @a options parameter indicates which floating point register sets
	* will be used by the specified thread:
	*
	* a) K_FP_REGS indicates x87 FPU and MMX registers only
	* b) K_SSE_REGS indicates SSE registers (and also x87 FPU and MMX registers)
	*
	* Invoking this routine initializes the thread's floating point context info
	* to that of an FPU that has been reset. The next time the thread is scheduled
	* by _Swap() it will either inherit an FPU that is guaranteed to be in a "sane"
	* state (if the most recent user of the FPU was cooperatively swapped out)
	* or the thread's own floating point context will be loaded (if the most
	* recent user of the FPU was preempted, or if this thread is the first user
	* of the FPU). Thereafter, the kernel will protect the thread's FP context
	* so that it is not altered during a preemptive context switch.
	*
	* @warning
	* This routine should only be used to enable floating point support for a
	* thread that does not currently have such support enabled already.
	*
	* @param thread ID of thread.
	* @param options Registers to be preserved (K_FP_REGS or K_SSE_REGS).
	*
	* @return N/A
	*/
	extern void k_float_enable(k_tid_t thread, unsigned int options);

	/**
	* @brief Disable preservation of floating point context information.
	*
	* This routine informs the kernel that the specified thread (which may be
	* the current thread) will no longer be using the floating point registers.
	*
	* @warning
	* This routine should only be used to disable floating point support for
	* a thread that currently has such support enabled.
	*
	* @param thread ID of thread.
	*
	* @return N/A
	*/
	extern void k_float_disable(k_tid_t thread);

	/**
	* @}
	*/

	#include <stddef.h> /* for size_t */

	extern void k_cpu_idle(void);

	extern u32_t _timer_cycle_get_32(void);
	#define _arch_k_cycle_get_32() _timer_cycle_get_32()

	/** kernel provided routine to report any detected fatal error. */
	extern FUNC_NORETURN void _NanoFatalErrorHandler(unsigned int reason,
	const NANO_ESF * pEsf);

	/** User provided routine to handle any detected fatal error post reporting. */
	extern FUNC_NORETURN void _SysFatalErrorHandler(unsigned int reason,
	const NANO_ESF * pEsf);

	#if CONFIG_X86_KERNEL_OOPS
	#define _ARCH_EXCEPT(reason_p) do { \
	__asm__ volatile( \
	"push %[reason]\n\t" \
	"int %[vector]\n\t" \
	: \
	: [vector] "i" (CONFIG_X86_KERNEL_OOPS_VECTOR), \
	[reason] "i" (reason_p)); \
	CODE_UNREACHABLE; \
	} while (0)
	#else
	/** Dummy ESF for fatal errors that would otherwise not have an ESF */
	extern const NANO_ESF _default_esf;
	#endif /* CONFIG_X86_KERNEL_OOPS */

	#endif /* !_ASMLANGUAGE */

	/* reboot through Reset Control Register (I/O port 0xcf9) */

	#define SYS_X86_RST_CNT_REG 0xcf9
	#define SYS_X86_RST_CNT_SYS_RST 0x02
	#define SYS_X86_RST_CNT_CPU_RST 0x4
	#define SYS_X86_RST_CNT_FULL_RST 0x08

	#ifdef __cplusplus
	}
	#endif

	#endif /* _ARCH_IFACE_H */