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

 /*
  * Copyright (c) 2015 Intel corporation
  *
  * SPDX-License-Identifier: Apache-2.0
  */

 /**
  * @file
  * @brief Public interface for configuring interrupts
  */
 #ifndef ZEPHYR_INCLUDE_IRQ_H_
 #define ZEPHYR_INCLUDE_IRQ_H_

 /* Pull in the arch-specific implementations */
 #include <zephyr/arch/cpu.h>

 #ifndef _ASMLANGUAGE
 #include <zephyr/toolchain.h>
 #include <zephyr/types.h>

 #ifdef __cplusplus
 extern "C" {
 #endif

 /**
  * @defgroup isr_apis Interrupt Service Routine APIs
  * @ingroup kernel_apis
  * @{
  */

 /**
  * @brief Initialize an interrupt handler.
  *
  * This routine initializes an interrupt handler for an IRQ. The IRQ must be
  * subsequently enabled before the interrupt handler begins servicing
  * interrupts.
  *
  * @warning
  * Although this routine is invoked at run-time, all of its arguments must be
  * computable by the compiler at build time.
  *
  * @param irq_p IRQ line number.
  * @param priority_p Interrupt priority.
  * @param isr_p Address of interrupt service routine.
  * @param isr_param_p Parameter passed to interrupt service routine.
  * @param flags_p Architecture-specific IRQ configuration flags..
  */
 #define IRQ_CONNECT(irq_p, priority_p, isr_p, isr_param_p, flags_p) \
 	ARCH_IRQ_CONNECT(irq_p, priority_p, isr_p, isr_param_p, flags_p)

 /**
  * Configure a dynamic interrupt.
  *
  * Use this instead of IRQ_CONNECT() if arguments cannot be known at build time.
  *
  * @param irq IRQ line number
  * @param priority Interrupt priority
  * @param routine Interrupt service routine
  * @param parameter ISR parameter
  * @param flags Arch-specific IRQ configuration flags
  *
  * @return The vector assigned to this interrupt
  */
 static inline int
 irq_connect_dynamic(unsigned int irq, unsigned int priority,
 		    void (*routine)(const void *parameter),
 		    const void *parameter, uint32_t flags)
 {
 	return arch_irq_connect_dynamic(irq, priority, routine, parameter,
 					flags);
 }

 /**
  * @brief Initialize a 'direct' interrupt handler.
  *
  * This routine initializes an interrupt handler for an IRQ. The IRQ must be
  * subsequently enabled via irq_enable() before the interrupt handler begins
  * servicing interrupts.
  *
  * These ISRs are designed for performance-critical interrupt handling and do
  * not go through common interrupt handling code. They must be implemented in
  * such a way that it is safe to put them directly in the vector table.  For
  * ISRs written in C, The ISR_DIRECT_DECLARE() macro will do this
  * automatically. For ISRs written in assembly it is entirely up to the
  * developer to ensure that the right steps are taken.
  *
  * This type of interrupt currently has a few limitations compared to normal
  * Zephyr interrupts:
  * - No parameters are passed to the ISR.
  * - No stack switch is done, the ISR will run on the interrupted context's
  *   stack, unless the architecture automatically does the stack switch in HW.
  * - Interrupt locking state is unchanged from how the HW sets it when the ISR
  *   runs. On arches that enter ISRs with interrupts locked, they will remain
  *   locked.
  * - Scheduling decisions are now optional, controlled by the return value of
  *   ISRs implemented with the ISR_DIRECT_DECLARE() macro
  * - The call into the OS to exit power management idle state is now optional.
  *   Normal interrupts always do this before the ISR is run, but when it runs
  *   is now controlled by the placement of a ISR_DIRECT_PM() macro, or omitted
  *   entirely.
  *
  * @warning
  * Although this routine is invoked at run-time, all of its arguments must be
  * computable by the compiler at build time.
  *
  * @param irq_p IRQ line number.
  * @param priority_p Interrupt priority.
  * @param isr_p Address of interrupt service routine.
  * @param flags_p Architecture-specific IRQ configuration flags.
  */
 #define IRQ_DIRECT_CONNECT(irq_p, priority_p, isr_p, flags_p) \
 	ARCH_IRQ_DIRECT_CONNECT(irq_p, priority_p, isr_p, flags_p)

 /**
  * @brief Common tasks before executing the body of an ISR
  *
  * This macro must be at the beginning of all direct interrupts and performs
  * minimal architecture-specific tasks before the ISR itself can run. It takes
  * no arguments and has no return value.
  */
 #define ISR_DIRECT_HEADER() ARCH_ISR_DIRECT_HEADER()

 /**
  * @brief Common tasks before exiting the body of an ISR
  *
  * This macro must be at the end of all direct interrupts and performs
  * minimal architecture-specific tasks like EOI. It has no return value.
  *
  * In a normal interrupt, a check is done at end of interrupt to invoke
  * z_swap() logic if the current thread is preemptible and there is another
  * thread ready to run in the kernel's ready queue cache. This is now optional
  * and controlled by the check_reschedule argument. If unsure, set to nonzero.
  * On systems that do stack switching and nested interrupt tracking in software,
  * z_swap() should only be called if this was a non-nested interrupt.
  *
  * @param check_reschedule If nonzero, additionally invoke scheduling logic
  */
 #define ISR_DIRECT_FOOTER(check_reschedule) \
 	ARCH_ISR_DIRECT_FOOTER(check_reschedule)

 /**
  * @brief Perform power management idle exit logic
  *
  * This macro may optionally be invoked somewhere in between IRQ_DIRECT_HEADER()
  * and IRQ_DIRECT_FOOTER() invocations. It performs tasks necessary to
  * exit power management idle state. It takes no parameters and returns no
  * arguments. It may be omitted, but be careful!
  */
 #define ISR_DIRECT_PM() ARCH_ISR_DIRECT_PM()

 /**
  * @brief Helper macro to declare a direct interrupt service routine.
  *
  * This will declare the function in a proper way and automatically include
  * the ISR_DIRECT_FOOTER() and ISR_DIRECT_HEADER() macros. The function should
  * return nonzero status if a scheduling decision should potentially be made.
  * See ISR_DIRECT_FOOTER() for more details on the scheduling decision.
  *
  * For architectures that support 'regular' and 'fast' interrupt types, where
  * these interrupt types require different assembly language handling of
  * registers by the ISR, this will always generate code for the 'fast'
  * interrupt type.
  *
  * Example usage:
  *
  *     ISR_DIRECT_DECLARE(my_isr)
  *     {
  *             bool done = do_stuff();
  *             ISR_DIRECT_PM(); // done after do_stuff() due to latency concerns
  *             if (!done) {
  *                 return 0; // don't bother checking if we have to z_swap()
  *             }
  *
  *             k_sem_give(some_sem);
  *             return 1;
  *      }
  *
  * @param name symbol name of the ISR
  */
 #define ISR_DIRECT_DECLARE(name) ARCH_ISR_DIRECT_DECLARE(name)

 /**
  * @brief Lock interrupts.
  * @def irq_lock()
  *
  * This routine disables all interrupts on the CPU. It returns an unsigned
  * integer "lock-out key", which is an architecture-dependent indicator of
  * whether interrupts were locked prior to the call. The lock-out key must be
  * passed to irq_unlock() to re-enable interrupts.
  *
  * @note
  * This routine must also serve as a memory barrier to ensure the uniprocessor
  * implementation of `k_spinlock_t` is correct.
  *
  * This routine can be called recursively, as long as the caller keeps track
  * of each lock-out key that is generated. Interrupts are re-enabled by
  * passing each of the keys to irq_unlock() in the reverse order they were
  * acquired. (That is, each call to irq_lock() must be balanced by
  * a corresponding call to irq_unlock().)
  *
  * This routine can only be invoked from supervisor mode. Some architectures
  * (for example, ARM) will fail silently if invoked from user mode instead
  * of generating an exception.
  *
  * @note
  * This routine can be called by ISRs or by threads. If it is called by a
  * thread, the interrupt lock is thread-specific; this means that interrupts
  * remain disabled only while the thread is running. If the thread performs an
  * operation that allows another thread to run (for example, giving a semaphore
  * or sleeping for N milliseconds), the interrupt lock no longer applies and
  * interrupts may be re-enabled while other processing occurs. When the thread
  * once again becomes the current thread, the kernel re-establishes its
  * interrupt lock; this ensures the thread won't be interrupted until it has
  * explicitly released the interrupt lock it established.
  *
  * @warning
  * The lock-out key should never be used to manually re-enable interrupts
  * or to inspect or manipulate the contents of the CPU's interrupt bits.
  *
  * @return An architecture-dependent lock-out key representing the
  *         "interrupt disable state" prior to the call.
  */
 #ifdef CONFIG_SMP
 unsigned int z_smp_global_lock(void);
 #define irq_lock() z_smp_global_lock()
 #else
 #define irq_lock() arch_irq_lock()
 #endif

 /**
  * @brief Unlock interrupts.
  * @def irq_unlock()
  *
  * This routine reverses the effect of a previous call to irq_lock() using
  * the associated lock-out key. The caller must call the routine once for
  * each time it called irq_lock(), supplying the keys in the reverse order
  * they were acquired, before interrupts are enabled.
  *
  * @note
  * This routine must also serve as a memory barrier to ensure the uniprocessor
  * implementation of `k_spinlock_t` is correct.
  *
  * This routine can only be invoked from supervisor mode. Some architectures
  * (for example, ARM) will fail silently if invoked from user mode instead
  * of generating an exception.
  *
  * @note Can be called by ISRs.
  *
  * @param key Lock-out key generated by irq_lock().
  */
 #ifdef CONFIG_SMP
 void z_smp_global_unlock(unsigned int key);
 #define irq_unlock(key) z_smp_global_unlock(key)
 #else
 #define irq_unlock(key) arch_irq_unlock(key)
 #endif

 /**
  * @brief Return IRQ level
  * This routine returns the interrupt level number of the provided interrupt.
  *
  * @param irq IRQ number in its zephyr format
  *
  * @return 1 if IRQ level 1, 2 if IRQ level 2, 3 if IRQ level 3
  */
 static inline unsigned int irq_get_level(unsigned int irq)
 {
 #if defined(CONFIG_3RD_LEVEL_INTERRUPTS)
 	return ((irq >> 16) & 0xFF) != 0 ? 3 :
 		(((irq >> 8) & 0xFF) == 0 ? 1 : 2);
 #elif defined(CONFIG_2ND_LEVEL_INTERRUPTS)
 	return ((irq >> 8) & 0xFF) == 0 ? 1 : 2;
 #else
 	ARG_UNUSED(irq);

 	return 1;
 #endif
 }

 #ifdef CONFIG_2ND_LEVEL_INTERRUPTS
 /**
  * @brief Return the 2nd level interrupt number
  *
  *
  * This routine returns the second level irq number of the zephyr irq
  * number passed in
  *
  * @param irq IRQ number in its zephyr format
  *
  * @return 2nd level IRQ number
  */
 static inline unsigned int irq_from_level_2(unsigned int irq)
 {
 #ifdef CONFIG_3RD_LEVEL_INTERRUPTS
 	return ((irq >> 8) & 0xFF) - 1;
 #else
 	return (irq >> 8) - 1;
 #endif
 }

 /**
  * @brief Converts irq from level 1 to level 2 format
  *
  *
  * This routine converts the input into the level 2 irq number format
  *
  * @note Values >= 0xFF are invalid
  *
  * @param irq IRQ number in its zephyr format
  *
  * @return 2nd level IRQ number
  */
 static inline unsigned int irq_to_level_2(unsigned int irq)
 {
 	return (irq + 1) << 8;
 }

 /**
  * @brief Returns the parent IRQ of the level 2 raw IRQ number
  *
  *
  * The parent of a 2nd level interrupt is in the 1st byte
  *
  * @param irq IRQ number in its zephyr format
  *
  * @return 2nd level IRQ parent
  */
 static inline unsigned int irq_parent_level_2(unsigned int irq)
 {
 	return irq & 0xFF;
 }
 #endif

 #ifdef CONFIG_3RD_LEVEL_INTERRUPTS
 /**
  * @brief Return the 3rd level interrupt number
  *
  *
  * This routine returns the third level irq number of the zephyr irq
  * number passed in
  *
  * @param irq IRQ number in its zephyr format
  *
  * @return 3rd level IRQ number
  */
 static inline unsigned int irq_from_level_3(unsigned int irq)
 {
 	return (irq >> 16) - 1;
 }

 /**
  * @brief Converts irq from level 1 to level 3 format
  *
  *
  * This routine converts the input into the level 3 irq number format
  *
  * @note Values >= 0xFF are invalid
  *
  * @param irq IRQ number in its zephyr format
  *
  * @return 3rd level IRQ number
  */
 static inline unsigned int irq_to_level_3(unsigned int irq)
 {
 	return (irq + 1) << 16;
 }

 /**
  * @brief Returns the parent IRQ of the level 3 raw IRQ number
  *
  *
  * The parent of a 3rd level interrupt is in the 2nd byte
  *
  * @param irq IRQ number in its zephyr format
  *
  * @return 3rd level IRQ parent
  */
 static inline unsigned int irq_parent_level_3(unsigned int irq)
 {
 	return (irq >> 8) & 0xFF;
 }
 #endif

 /**
  * @brief Enable an IRQ.
  *
  * This routine enables interrupts from source @a irq.
  *
  * @param irq IRQ line.
  */
 #define irq_enable(irq) arch_irq_enable(irq)

 /**
  * @brief Disable an IRQ.
  *
  * This routine disables interrupts from source @a irq.
  *
  * @param irq IRQ line.
  */
 #define irq_disable(irq) arch_irq_disable(irq)

 /**
  * @brief Get IRQ enable state.
  *
  * This routine indicates if interrupts from source @a irq are enabled.
  *
  * @param irq IRQ line.
  *
  * @return interrupt enable state, true or false
  */
 #define irq_is_enabled(irq) arch_irq_is_enabled(irq)

 /**
  * @}
  */

 #ifdef __cplusplus
 }
 #endif

 #endif /* ASMLANGUAGE */
 #endif /* ZEPHYR_INCLUDE_IRQ_H_ */
	/*
	* Copyright (c) 2015 Intel corporation
	*
	* SPDX-License-Identifier: Apache-2.0
	*/

	/**
	* @file
	* @brief Public interface for configuring interrupts
	*/
	#ifndef ZEPHYR_INCLUDE_IRQ_H_
	#define ZEPHYR_INCLUDE_IRQ_H_

	/* Pull in the arch-specific implementations */
	#include <zephyr/arch/cpu.h>

	#ifndef _ASMLANGUAGE
	#include <zephyr/toolchain.h>
	#include <zephyr/types.h>

	#ifdef __cplusplus
	extern "C" {
	#endif

	/**
	* @defgroup isr_apis Interrupt Service Routine APIs
	* @ingroup kernel_apis
	* @{
	*/

	/**
	* @brief Initialize an interrupt handler.
	*
	* This routine initializes an interrupt handler for an IRQ. The IRQ must be
	* subsequently enabled before the interrupt handler begins servicing
	* interrupts.
	*
	* @warning
	* Although this routine is invoked at run-time, all of its arguments must be
	* computable by the compiler at build time.
	*
	* @param irq_p IRQ line number.
	* @param priority_p Interrupt priority.
	* @param isr_p Address of interrupt service routine.
	* @param isr_param_p Parameter passed to interrupt service routine.
	* @param flags_p Architecture-specific IRQ configuration flags..
	*/
	#define IRQ_CONNECT(irq_p, priority_p, isr_p, isr_param_p, flags_p) \
	ARCH_IRQ_CONNECT(irq_p, priority_p, isr_p, isr_param_p, flags_p)

	/**
	* Configure a dynamic interrupt.
	*
	* Use this instead of IRQ_CONNECT() if arguments cannot be known at build time.
	*
	* @param irq IRQ line number
	* @param priority Interrupt priority
	* @param routine Interrupt service routine
	* @param parameter ISR parameter
	* @param flags Arch-specific IRQ configuration flags
	*
	* @return The vector assigned to this interrupt
	*/
	static inline int
	irq_connect_dynamic(unsigned int irq, unsigned int priority,
	void (routine)(const void parameter),
	const void *parameter, uint32_t flags)
	{
	return arch_irq_connect_dynamic(irq, priority, routine, parameter,
	flags);
	}

	/**
	* @brief Initialize a 'direct' interrupt handler.
	*
	* This routine initializes an interrupt handler for an IRQ. The IRQ must be
	* subsequently enabled via irq_enable() before the interrupt handler begins
	* servicing interrupts.
	*
	* These ISRs are designed for performance-critical interrupt handling and do
	* not go through common interrupt handling code. They must be implemented in
	* such a way that it is safe to put them directly in the vector table. For
	* ISRs written in C, The ISR_DIRECT_DECLARE() macro will do this
	* automatically. For ISRs written in assembly it is entirely up to the
	* developer to ensure that the right steps are taken.
	*
	* This type of interrupt currently has a few limitations compared to normal
	* Zephyr interrupts:
	* - No parameters are passed to the ISR.
	* - No stack switch is done, the ISR will run on the interrupted context's
	* stack, unless the architecture automatically does the stack switch in HW.
	* - Interrupt locking state is unchanged from how the HW sets it when the ISR
	* runs. On arches that enter ISRs with interrupts locked, they will remain
	* locked.
	* - Scheduling decisions are now optional, controlled by the return value of
	* ISRs implemented with the ISR_DIRECT_DECLARE() macro
	* - The call into the OS to exit power management idle state is now optional.
	* Normal interrupts always do this before the ISR is run, but when it runs
	* is now controlled by the placement of a ISR_DIRECT_PM() macro, or omitted
	* entirely.
	*
	* @warning
	* Although this routine is invoked at run-time, all of its arguments must be
	* computable by the compiler at build time.
	*
	* @param irq_p IRQ line number.
	* @param priority_p Interrupt priority.
	* @param isr_p Address of interrupt service routine.
	* @param flags_p Architecture-specific IRQ configuration flags.
	*/
	#define IRQ_DIRECT_CONNECT(irq_p, priority_p, isr_p, flags_p) \
	ARCH_IRQ_DIRECT_CONNECT(irq_p, priority_p, isr_p, flags_p)

	/**
	* @brief Common tasks before executing the body of an ISR
	*
	* This macro must be at the beginning of all direct interrupts and performs
	* minimal architecture-specific tasks before the ISR itself can run. It takes
	* no arguments and has no return value.
	*/
	#define ISR_DIRECT_HEADER() ARCH_ISR_DIRECT_HEADER()

	/**
	* @brief Common tasks before exiting the body of an ISR
	*
	* This macro must be at the end of all direct interrupts and performs
	* minimal architecture-specific tasks like EOI. It has no return value.
	*
	* In a normal interrupt, a check is done at end of interrupt to invoke
	* z_swap() logic if the current thread is preemptible and there is another
	* thread ready to run in the kernel's ready queue cache. This is now optional
	* and controlled by the check_reschedule argument. If unsure, set to nonzero.
	* On systems that do stack switching and nested interrupt tracking in software,
	* z_swap() should only be called if this was a non-nested interrupt.
	*
	* @param check_reschedule If nonzero, additionally invoke scheduling logic
	*/
	#define ISR_DIRECT_FOOTER(check_reschedule) \
	ARCH_ISR_DIRECT_FOOTER(check_reschedule)

	/**
	* @brief Perform power management idle exit logic
	*
	* This macro may optionally be invoked somewhere in between IRQ_DIRECT_HEADER()
	* and IRQ_DIRECT_FOOTER() invocations. It performs tasks necessary to
	* exit power management idle state. It takes no parameters and returns no
	* arguments. It may be omitted, but be careful!
	*/
	#define ISR_DIRECT_PM() ARCH_ISR_DIRECT_PM()

	/**
	* @brief Helper macro to declare a direct interrupt service routine.
	*
	* This will declare the function in a proper way and automatically include
	* the ISR_DIRECT_FOOTER() and ISR_DIRECT_HEADER() macros. The function should
	* return nonzero status if a scheduling decision should potentially be made.
	* See ISR_DIRECT_FOOTER() for more details on the scheduling decision.
	*
	* For architectures that support 'regular' and 'fast' interrupt types, where
	* these interrupt types require different assembly language handling of
	* registers by the ISR, this will always generate code for the 'fast'
	* interrupt type.
	*
	* Example usage:
	*
	* ISR_DIRECT_DECLARE(my_isr)
	* {
	* bool done = do_stuff();
	* ISR_DIRECT_PM(); // done after do_stuff() due to latency concerns
	* if (!done) {
	* return 0; // don't bother checking if we have to z_swap()
	* }
	*
	* k_sem_give(some_sem);
	* return 1;
	* }
	*
	* @param name symbol name of the ISR
	*/
	#define ISR_DIRECT_DECLARE(name) ARCH_ISR_DIRECT_DECLARE(name)

	/**
	* @brief Lock interrupts.
	* @def irq_lock()
	*
	* This routine disables all interrupts on the CPU. It returns an unsigned
	* integer "lock-out key", which is an architecture-dependent indicator of
	* whether interrupts were locked prior to the call. The lock-out key must be
	* passed to irq_unlock() to re-enable interrupts.
	*
	* @note
	* This routine must also serve as a memory barrier to ensure the uniprocessor
	* implementation of `k_spinlock_t` is correct.
	*
	* This routine can be called recursively, as long as the caller keeps track
	* of each lock-out key that is generated. Interrupts are re-enabled by
	* passing each of the keys to irq_unlock() in the reverse order they were
	* acquired. (That is, each call to irq_lock() must be balanced by
	* a corresponding call to irq_unlock().)
	*
	* This routine can only be invoked from supervisor mode. Some architectures
	* (for example, ARM) will fail silently if invoked from user mode instead
	* of generating an exception.
	*
	* @note
	* This routine can be called by ISRs or by threads. If it is called by a
	* thread, the interrupt lock is thread-specific; this means that interrupts
	* remain disabled only while the thread is running. If the thread performs an
	* operation that allows another thread to run (for example, giving a semaphore
	* or sleeping for N milliseconds), the interrupt lock no longer applies and
	* interrupts may be re-enabled while other processing occurs. When the thread
	* once again becomes the current thread, the kernel re-establishes its
	* interrupt lock; this ensures the thread won't be interrupted until it has
	* explicitly released the interrupt lock it established.
	*
	* @warning
	* The lock-out key should never be used to manually re-enable interrupts
	* or to inspect or manipulate the contents of the CPU's interrupt bits.
	*
	* @return An architecture-dependent lock-out key representing the
	* "interrupt disable state" prior to the call.
	*/
	#ifdef CONFIG_SMP
	unsigned int z_smp_global_lock(void);
	#define irq_lock() z_smp_global_lock()
	#else
	#define irq_lock() arch_irq_lock()
	#endif

	/**
	* @brief Unlock interrupts.
	* @def irq_unlock()
	*
	* This routine reverses the effect of a previous call to irq_lock() using
	* the associated lock-out key. The caller must call the routine once for
	* each time it called irq_lock(), supplying the keys in the reverse order
	* they were acquired, before interrupts are enabled.
	*
	* @note
	* This routine must also serve as a memory barrier to ensure the uniprocessor
	* implementation of `k_spinlock_t` is correct.
	*
	* This routine can only be invoked from supervisor mode. Some architectures
	* (for example, ARM) will fail silently if invoked from user mode instead
	* of generating an exception.
	*
	* @note Can be called by ISRs.
	*
	* @param key Lock-out key generated by irq_lock().
	*/
	#ifdef CONFIG_SMP
	void z_smp_global_unlock(unsigned int key);
	#define irq_unlock(key) z_smp_global_unlock(key)
	#else
	#define irq_unlock(key) arch_irq_unlock(key)
	#endif

	/**
	* @brief Return IRQ level
	* This routine returns the interrupt level number of the provided interrupt.
	*
	* @param irq IRQ number in its zephyr format
	*
	* @return 1 if IRQ level 1, 2 if IRQ level 2, 3 if IRQ level 3
	*/
	static inline unsigned int irq_get_level(unsigned int irq)
	{
	#if defined(CONFIG_3RD_LEVEL_INTERRUPTS)
	return ((irq >> 16) & 0xFF) != 0 ? 3 :
	(((irq >> 8) & 0xFF) == 0 ? 1 : 2);
	#elif defined(CONFIG_2ND_LEVEL_INTERRUPTS)
	return ((irq >> 8) & 0xFF) == 0 ? 1 : 2;
	#else
	ARG_UNUSED(irq);

	return 1;
	#endif
	}

	#ifdef CONFIG_2ND_LEVEL_INTERRUPTS
	/**
	* @brief Return the 2nd level interrupt number
	*
	*
	* This routine returns the second level irq number of the zephyr irq
	* number passed in
	*
	* @param irq IRQ number in its zephyr format
	*
	* @return 2nd level IRQ number
	*/
	static inline unsigned int irq_from_level_2(unsigned int irq)
	{
	#ifdef CONFIG_3RD_LEVEL_INTERRUPTS
	return ((irq >> 8) & 0xFF) - 1;
	#else
	return (irq >> 8) - 1;
	#endif
	}

	/**
	* @brief Converts irq from level 1 to level 2 format
	*
	*
	* This routine converts the input into the level 2 irq number format
	*
	* @note Values >= 0xFF are invalid
	*
	* @param irq IRQ number in its zephyr format
	*
	* @return 2nd level IRQ number
	*/
	static inline unsigned int irq_to_level_2(unsigned int irq)
	{
	return (irq + 1) << 8;
	}

	/**
	* @brief Returns the parent IRQ of the level 2 raw IRQ number
	*
	*
	* The parent of a 2nd level interrupt is in the 1st byte
	*
	* @param irq IRQ number in its zephyr format
	*
	* @return 2nd level IRQ parent
	*/
	static inline unsigned int irq_parent_level_2(unsigned int irq)
	{
	return irq & 0xFF;
	}
	#endif

	#ifdef CONFIG_3RD_LEVEL_INTERRUPTS
	/**
	* @brief Return the 3rd level interrupt number
	*
	*
	* This routine returns the third level irq number of the zephyr irq
	* number passed in
	*
	* @param irq IRQ number in its zephyr format
	*
	* @return 3rd level IRQ number
	*/
	static inline unsigned int irq_from_level_3(unsigned int irq)
	{
	return (irq >> 16) - 1;
	}

	/**
	* @brief Converts irq from level 1 to level 3 format
	*
	*
	* This routine converts the input into the level 3 irq number format
	*
	* @note Values >= 0xFF are invalid
	*
	* @param irq IRQ number in its zephyr format
	*
	* @return 3rd level IRQ number
	*/
	static inline unsigned int irq_to_level_3(unsigned int irq)
	{
	return (irq + 1) << 16;
	}

	/**
	* @brief Returns the parent IRQ of the level 3 raw IRQ number
	*
	*
	* The parent of a 3rd level interrupt is in the 2nd byte
	*
	* @param irq IRQ number in its zephyr format
	*
	* @return 3rd level IRQ parent
	*/
	static inline unsigned int irq_parent_level_3(unsigned int irq)
	{
	return (irq >> 8) & 0xFF;
	}
	#endif

	/**
	* @brief Enable an IRQ.
	*
	* This routine enables interrupts from source @a irq.
	*
	* @param irq IRQ line.
	*/
	#define irq_enable(irq) arch_irq_enable(irq)

	/**
	* @brief Disable an IRQ.
	*
	* This routine disables interrupts from source @a irq.
	*
	* @param irq IRQ line.
	*/
	#define irq_disable(irq) arch_irq_disable(irq)

	/**
	* @brief Get IRQ enable state.
	*
	* This routine indicates if interrupts from source @a irq are enabled.
	*
	* @param irq IRQ line.
	*
	* @return interrupt enable state, true or false
	*/
	#define irq_is_enabled(irq) arch_irq_is_enabled(irq)

	/**
	* @}
	*/

	#ifdef __cplusplus
	}
	#endif

	#endif /* ASMLANGUAGE */
	#endif /* ZEPHYR_INCLUDE_IRQ_H_ */