/* * Copyright (c) 2014 Wind River Systems, Inc. * * SPDX-License-Identifier: Apache-2.0 */ /** * @file * @brief ARCv2 public interrupt handling * * ARCv2 kernel interrupt handling interface. Included by arc/arch.h. */ #ifndef ZEPHYR_INCLUDE_ARCH_ARC_V2_IRQ_H_ #define ZEPHYR_INCLUDE_ARCH_ARC_V2_IRQ_H_ #include #include #include #include #include #ifdef __cplusplus extern "C" { #endif #define ARC_MP_PRIMARY_CPU_ID 0 #ifndef _ASMLANGUAGE extern void z_arc_firq_stack_set(void); extern void arch_irq_enable(unsigned int irq); extern void arch_irq_disable(unsigned int irq); extern int arch_irq_is_enabled(unsigned int irq); #ifdef CONFIG_TRACING_ISR extern void sys_trace_isr_enter(void); extern void sys_trace_isr_exit(void); #endif extern void z_irq_priority_set(unsigned int irq, unsigned int prio, uint32_t flags); /* Z_ISR_DECLARE will populate the .intList section with the interrupt's * parameters, which will then be used by gen_irq_tables.py to create * the vector table and the software ISR table. This is all done at * build-time. * * We additionally set the priority in the interrupt controller at * runtime. */ #define ARCH_IRQ_CONNECT(irq_p, priority_p, isr_p, isr_param_p, flags_p) \ { \ Z_ISR_DECLARE(irq_p, 0, isr_p, isr_param_p); \ z_irq_priority_set(irq_p, priority_p, flags_p); \ } /** * Configure a 'direct' static interrupt. * * When firq has no separate stack(CONFIG_ARC_FIRQ_STACK=N), it's not safe * to call C ISR handlers because sp will be switched to bank1's sp which * is undefined value. * So for this case, the priority cannot be set to 0 but next level 1 * * When firq has separate stack (CONFIG_ARC_FIRQ_STACK=y) but at the same * time stack checking is enabled (CONFIG_ARC_STACK_CHECKING=y) * the stack checking can raise stack check exception as sp is switched to * firq's stack (bank1's sp). So for this case, the priority cannot be set * to 0 but next level 1. * * Note that for the above cases, if application still wants to use firq by * setting priority to 0. Application can call z_irq_priority_set again. * Then it's left to application to handle the details of firq * * See include/irq.h for details. * All arguments must be computable at build time. */ #define ARCH_IRQ_DIRECT_CONNECT(irq_p, priority_p, isr_p, flags_p) \ { \ Z_ISR_DECLARE(irq_p, ISR_FLAG_DIRECT, isr_p, NULL); \ BUILD_ASSERT(priority_p || !IS_ENABLED(CONFIG_ARC_FIRQ) || \ (IS_ENABLED(CONFIG_ARC_FIRQ_STACK) && \ !IS_ENABLED(CONFIG_ARC_STACK_CHECKING)), \ "irq priority cannot be set to 0 when CONFIG_ARC_FIRQ_STACK" \ "is not configured or CONFIG_ARC_FIRQ_STACK " \ "and CONFIG_ARC_STACK_CHECKING are configured together"); \ z_irq_priority_set(irq_p, priority_p, flags_p); \ } static inline void arch_isr_direct_header(void) { #ifdef CONFIG_TRACING_ISR sys_trace_isr_enter(); #endif } static inline void arch_isr_direct_footer(int maybe_swap) { /* clear SW generated interrupt */ if (z_arc_v2_aux_reg_read(_ARC_V2_ICAUSE) == z_arc_v2_aux_reg_read(_ARC_V2_AUX_IRQ_HINT)) { z_arc_v2_aux_reg_write(_ARC_V2_AUX_IRQ_HINT, 0); } #ifdef CONFIG_TRACING_ISR sys_trace_isr_exit(); #endif } #define ARCH_ISR_DIRECT_HEADER() arch_isr_direct_header() extern void arch_isr_direct_header(void); #define ARCH_ISR_DIRECT_FOOTER(swap) arch_isr_direct_footer(swap) #if defined(__CCAC__) #define _ARC_DIRECT_ISR_FUNC_ATTRIBUTE __interrupt__ #else #define _ARC_DIRECT_ISR_FUNC_ATTRIBUTE interrupt("ilink") #endif /* * Scheduling can not be done in direct isr. If required, please use kernel * aware interrupt handling */ #define ARCH_ISR_DIRECT_DECLARE(name) \ static inline int name##_body(void); \ __attribute__ ((_ARC_DIRECT_ISR_FUNC_ATTRIBUTE))void name(void) \ { \ ISR_DIRECT_HEADER(); \ name##_body(); \ ISR_DIRECT_FOOTER(0); \ } \ static inline int name##_body(void) /** * * @brief Disable all interrupts on the local CPU * * This routine disables interrupts. It can be called from either interrupt or * thread 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 * thread 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; __asm__ volatile("clri %0" : "=r"(key):: "memory"); return key; } static ALWAYS_INLINE void arch_irq_unlock(unsigned int key) { __asm__ volatile("seti %0" : : "ir"(key) : "memory"); } static ALWAYS_INLINE bool arch_irq_unlocked(unsigned int key) { /* ARC irq lock uses instruction "clri r0", * r0 == {26’d0, 1’b1, STATUS32.IE, STATUS32.E[3:0] } * bit4 is used to record IE (Interrupt Enable) bit */ return (key & 0x10) == 0x10; } #endif /* _ASMLANGUAGE */ #ifdef __cplusplus } #endif #endif /* ZEPHYR_INCLUDE_ARCH_ARC_V2_IRQ_H_ */