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[/] [or1k_soc_on_altera_embedded_dev_kit/] [trunk/] [linux-2.6/] [linux-2.6.24/] [include/] [asm-cris/] [arch-v32/] [irq.h] - Rev 3
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#ifndef _ASM_ARCH_IRQ_H #define _ASM_ARCH_IRQ_H #include "hwregs/intr_vect.h" /* Number of non-cpu interrupts. */ #define NR_IRQS 0x50 /* Exceptions + IRQs */ #define NR_REAL_IRQS 0x20 /* IRQs */ #define FIRST_IRQ 0x31 /* Exception number for first IRQ */ #ifndef __ASSEMBLY__ /* Global IRQ vector. */ typedef void (*irqvectptr)(void); struct etrax_interrupt_vector { irqvectptr v[256]; }; extern struct etrax_interrupt_vector *etrax_irv; /* head.S */ void mask_irq(int irq); void unmask_irq(int irq); void set_exception_vector(int n, irqvectptr addr); /* Save registers so that they match pt_regs. */ #define SAVE_ALL \ "subq 12,$sp\n\t" \ "move $erp,[$sp]\n\t" \ "subq 4,$sp\n\t" \ "move $srp,[$sp]\n\t" \ "subq 4,$sp\n\t" \ "move $ccs,[$sp]\n\t" \ "subq 4,$sp\n\t" \ "move $spc,[$sp]\n\t" \ "subq 4,$sp\n\t" \ "move $mof,[$sp]\n\t" \ "subq 4,$sp\n\t" \ "move $srs,[$sp]\n\t" \ "subq 4,$sp\n\t" \ "move.d $acr,[$sp]\n\t" \ "subq 14*4,$sp\n\t" \ "movem $r13,[$sp]\n\t" \ "subq 4,$sp\n\t" \ "move.d $r10,[$sp]\n" #define STR2(x) #x #define STR(x) STR2(x) #define IRQ_NAME2(nr) nr##_interrupt(void) #define IRQ_NAME(nr) IRQ_NAME2(IRQ##nr) /* * The reason for setting the S-bit when debugging the kernel is that we want * hardware breakpoints to remain active while we are in an exception handler. * Note that we cannot simply copy S1, since we may come here from user-space, * or any context where the S-bit wasn't set. */ #ifdef CONFIG_ETRAX_KGDB #define KGDB_FIXUP \ "move $ccs, $r10\n\t" \ "or.d (1<<9), $r10\n\t" \ "move $r10, $ccs\n\t" #else #define KGDB_FIXUP "" #endif /* * Make sure the causing IRQ is blocked, then call do_IRQ. After that, unblock * and jump to ret_from_intr which is found in entry.S. * * The reason for blocking the IRQ is to allow an sti() before the handler, * which will acknowledge the interrupt, is run. The actual blocking is made * by crisv32_do_IRQ. */ #define BUILD_IRQ(nr, mask) \ void IRQ_NAME(nr); \ __asm__ ( \ ".text\n\t" \ "IRQ" #nr "_interrupt:\n\t" \ SAVE_ALL \ KGDB_FIXUP \ "move.d "#nr",$r10\n\t" \ "move.d $sp,$r12\n\t" \ "jsr crisv32_do_IRQ\n\t" \ "moveq 1, $r11\n\t" \ "jump ret_from_intr\n\t" \ "nop\n\t"); /* * This is subtle. The timer interrupt is crucial and it should not be disabled * for too long. However, if it had been a normal interrupt as per BUILD_IRQ, it * would have been BLOCK'ed, and then softirq's are run before we return here to * UNBLOCK. If the softirq's take too much time to run, the timer irq won't run * and the watchdog will kill us. * * Furthermore, if a lot of other irq's occur before we return here, the * multiple_irq handler is run and it prioritizes the timer interrupt. However * if we had BLOCK'edit here, we would not get the multiple_irq at all. * * The non-blocking here is based on the knowledge that the timer interrupt is * registred as a fast interrupt (IRQF_DISABLED) so that we _know_ there will not * be an sti() before the timer irq handler is run to acknowledge the interrupt. */ #define BUILD_TIMER_IRQ(nr, mask) \ void IRQ_NAME(nr); \ __asm__ ( \ ".text\n\t" \ "IRQ" #nr "_interrupt:\n\t" \ SAVE_ALL \ KGDB_FIXUP \ "move.d "#nr",$r10\n\t" \ "move.d $sp,$r12\n\t" \ "jsr crisv32_do_IRQ\n\t" \ "moveq 0,$r11\n\t" \ "jump ret_from_intr\n\t" \ "nop\n\t"); #endif /* __ASSEMBLY__ */ #endif /* _ASM_ARCH_IRQ_H */