/*
* Jensen is special: the vector is 0x8X0 for EISA interrupt X, and
* 0x9X0 for the local motherboard interrupts..
*
* 0x660 - NMI
*
* 0x800 - IRQ0 interval timer (not used, as we use the RTC timer)
* 0x810 - IRQ1 line printer (duh..)
* 0x860 - IRQ6 floppy disk
* 0x8E0 - IRQ14 SCSI controller
*
* 0x900 - COM1
* 0x920 - COM2
* 0x980 - keyboard
* 0x990 - mouse
*
* PCI-based systems are more sane: they don't have the local
* interrupts at all, and have only normal PCI interrupts from
* devices. Happily it's easy enough to do a sane mapping from the
* Jensen.. Note that this means that we may have to do a hardware
* "ack" to a different interrupt than we report to the rest of the
* world.
*/
static inline void srm_device_interrupt(unsigned long vector, struct pt_regs * regs)
{
int irq, ack;
unsigned long flags;
save_flags(flags);
cli();
ack = irq = (vector - 0x800) >> 4;
#ifdef CONFIG_ALPHA_JENSEN
switch (vector) {
case 0x660: handle_nmi(regs); return;
/* local device interrupts: */
case 0x900: handle_irq(4, regs); return; /* com1 -> irq 4 */
case 0x920: handle_irq(3, regs); return; /* com2 -> irq 3 */
case 0x980: handle_irq(1, regs); return; /* kbd -> irq 1 */
case 0x990: handle_irq(9, regs); return; /* mouse -> irq 9 */
default:
if (vector > 0x900) {
printk("Unknown local interrupt %lx\n", vector);
}
}
/* irq1 is supposed to be the keyboard, silly Jensen (is this really needed??) */
if (irq == 1)
irq = 7;
#endif /* CONFIG_ALPHA_JENSEN */
device_interrupt(irq, ack, regs);
restore_flags(flags) ;
}
asmlinkage void
do_entInt(unsigned long type, unsigned long vector,
unsigned long la_ptr, struct pt_regs *regs)
{
struct pt_regs *old_regs;
switch (type) {
case 0:
#ifdef CONFIG_SMP
handle_ipi(regs);
return;
#else
irq_err_count++;
printk(KERN_CRIT "Interprocessor interrupt? "
"You must be kidding!\n");
#endif
break;
case 1:
old_regs = set_irq_regs(regs);
#ifdef CONFIG_SMP
{
long cpu;
local_irq_disable();
smp_percpu_timer_interrupt(regs);
cpu = smp_processor_id();
if (cpu != boot_cpuid) {
kstat_incr_irqs_this_cpu(RTC_IRQ, irq_to_desc(RTC_IRQ));
} else {
handle_irq(RTC_IRQ);
}
}
#else
handle_irq(RTC_IRQ);
#endif
set_irq_regs(old_regs);
return;
case 2:
old_regs = set_irq_regs(regs);
alpha_mv.machine_check(vector, la_ptr);
set_irq_regs(old_regs);
return;
case 3:
old_regs = set_irq_regs(regs);
alpha_mv.device_interrupt(vector);
set_irq_regs(old_regs);
return;
case 4:
perf_irq(la_ptr, regs);
return;
default:
printk(KERN_CRIT "Hardware intr %ld %lx? Huh?\n",
type, vector);
}
printk(KERN_CRIT "PC = %016lx PS=%04lx\n", regs->pc, regs->ps);
}
static inline void dispatch_multiple_rtc_irq() {
rtc_reg_map *regs = RTC->regs;
uint32 dsr = regs->CRH & regs->CRL;
void (**hs)(void) = RTC->handlers;
uint32 handled = 0;
handle_irq(dsr, RTC_CRL_SECF, hs, RTC_SECONDS_INTERRUPT, handled);
handle_irq(dsr, RTC_CRL_ALRF, hs, RTC_ALARM_GLOBAL_INTERRUPT, handled);
handle_irq(dsr, RTC_CRL_OWF, hs, RTC_OVERFLOW_INTERRUPT, handled);
regs->CRL &= ~handled;
}
static inline void dispatch_adv_cc(timer_dev *dev) {
uint32_t dsr = dev->regs->DIER & dev->regs->SR;
void (**hs)(void) = dev->handlers;
uint32_t handled = 0;
handle_irq(dsr, TIMER_SR_CC4IF, hs, TIMER_CC4_INTERRUPT, handled);
handle_irq(dsr, TIMER_SR_CC3IF, hs, TIMER_CC3_INTERRUPT, handled);
handle_irq(dsr, TIMER_SR_CC2IF, hs, TIMER_CC2_INTERRUPT, handled);
handle_irq(dsr, TIMER_SR_CC1IF, hs, TIMER_CC1_INTERRUPT, handled);
dev->regs->SR &= ~handled;
}
static inline void dispatch_adv_trg_com(timer_dev *dev) {
uint32_t dsr = dev->regs->DIER & dev->regs->SR;
void (**hs)(void) = dev->handlers;
uint32_t handled = 0; /* Logical OR of SR interrupt flags we end up
* handling. We clear these. User handlers
* must clear overcapture flags, to avoid
* wasting time in output mode. */
handle_irq(dsr, TIMER_SR_TIF, hs, TIMER_TRG_INTERRUPT, handled);
handle_irq(dsr, TIMER_SR_COMIF, hs, TIMER_COM_INTERRUPT, handled);
dev->regs->SR &= ~handled;
}
static void
mikasa_device_interrupt(unsigned long vector)
{
unsigned long pld;
unsigned int i;
/* Read the interrupt summary registers */
pld = (((~inw(0x534) & 0x0000ffffUL) << 16)
| (((unsigned long) inb(0xa0)) << 8)
| inb(0x20));
/*
* Now for every possible bit set, work through them and call
* the appropriate interrupt handler.
*/
while (pld) {
i = ffz(~pld);
pld &= pld - 1; /* clear least bit set */
if (i < 16) {
isa_device_interrupt(vector);
} else {
handle_irq(i);
}
}
}
/*
* do_IRQ handles all normal device IRQ's (the special
* SMP cross-CPU interrupts have their own specific
* handlers).
*/
__visible unsigned int __irq_entry do_IRQ(struct pt_regs *regs)
{
struct pt_regs *old_regs = set_irq_regs(regs);
/* high bit used in ret_from_ code */
unsigned vector = ~regs->orig_ax;
unsigned irq;
irq_enter();
exit_idle();
irq = __this_cpu_read(vector_irq[vector]);
if (!handle_irq(irq, regs)) {
ack_APIC_irq();
if (irq != VECTOR_RETRIGGERED) {
pr_emerg_ratelimited("%s: %d.%d No irq handler for vector (irq %d)\n",
__func__, smp_processor_id(),
vector, irq);
} else {
__this_cpu_write(vector_irq[vector], VECTOR_UNDEFINED);
}
}
irq_exit();
set_irq_regs(old_regs);
return 1;
}
/*
* do_IRQ handles all normal device IRQ's (the special
* SMP cross-CPU interrupts have their own specific
* handlers).
*/
unsigned int __irq_entry do_IRQ(struct pt_regs *regs)
{
struct pt_regs *old_regs = set_irq_regs(regs);
/* high bit used in ret_from_ code */
unsigned vector = ~regs->orig_ax;
unsigned irq;
irq_enter();
exit_idle();
irq = __this_cpu_read(vector_irq[vector]);
if (!handle_irq(irq, regs)) {
ack_APIC_irq();
if (printk_ratelimit())
pr_emerg("%s: %d.%d No irq handler for vector (irq %d)\n",
__func__, smp_processor_id(), vector, irq);
}
irq_exit();
set_irq_regs(old_regs);
return 1;
}
static void
miata_srm_device_interrupt(unsigned long vector)
{
int irq;
irq = (vector - 0x800) >> 4;
/*
* I really hate to do this, but the MIATA SRM console ignores the
* low 8 bits in the interrupt summary register, and reports the
* vector 0x80 *lower* than I expected from the bit numbering in
* the documentation.
* This was done because the low 8 summary bits really aren't used
* for reporting any interrupts (the PCI-ISA bridge, bit 7, isn't
* used for this purpose, as PIC interrupts are delivered as the
* vectors 0x800-0x8f0).
* But I really don't want to change the fixup code for allocation
* of IRQs, nor the alpha_irq_mask maintenance stuff, both of which
* look nice and clean now.
* So, here's this grotty hack... :-(
*/
if (irq >= 16)
irq = irq + 8;
handle_irq(irq);
}
static void
jensen_device_interrupt(unsigned long vector, struct pt_regs * regs)
{
int irq;
switch (vector) {
case 0x660:
printk("Whee.. NMI received. Probable hardware error\n");
printk("61=%02x, 461=%02x\n", inb(0x61), inb(0x461));
return;
/* local device interrupts: */
case 0x900: irq = 4; break; /* com1 -> irq 4 */
case 0x920: irq = 3; break; /* com2 -> irq 3 */
case 0x980: irq = 1; break; /* kbd -> irq 1 */
case 0x990: irq = 9; break; /* mouse -> irq 9 */
default:
if (vector > 0x900) {
printk("Unknown local interrupt %lx\n", vector);
return;
}
irq = (vector - 0x800) >> 4;
if (irq == 1)
irq = 7;
break;
}
handle_irq(irq, regs);
}
/* Check if the pending bit for an IRQ line is set; if so, call the handler
* function. */
static void check_irq_pending(uchar irq_num)
{
bool handle = FALSE;
/* Check the appropriate hardware register, depending on the IRQ number. */
if (irq_num >= 64)
{
if (regs->IRQ_basic_pending & (1 << (irq_num - 64)))
{
handle = TRUE;
}
}
else if (irq_num >= 32)
{
if (regs->IRQ_pending_2 & (1 << (irq_num - 32)))
{
handle = TRUE;
}
}
else
{
if (regs->IRQ_pending_1 & (1 << irq_num))
{
handle = TRUE;
}
}
if (handle)
{
handle_irq(irq_num);
/* The pending bit should have been cleared in a device-specific way by
* the handler function. As far as we can tell, it cannot be cleared
* directly through the interrupt controller. */
}
}
static void
rx164_device_interrupt(unsigned long vector)
{
unsigned long pld;
volatile unsigned int *dirr;
long i;
/* Read the interrupt summary register. On Polaris, this is
the DIRR register in PCI config space (offset 0x84). */
dirr = (void *)(POLARIS_DENSE_CONFIG_BASE + 0x84);
pld = *dirr;
/*
* Now for every possible bit set, work through them and call
* the appropriate interrupt handler.
*/
while (pld) {
i = ffz(~pld);
pld &= pld - 1; /* clear least bit set */
if (i == 20) {
isa_no_iack_sc_device_interrupt(vector);
} else {
handle_irq(16+i);
}
}
}
static void
dp264_device_interrupt(unsigned long vector, struct pt_regs * regs)
{
#if 1
printk("dp264_device_interrupt: NOT IMPLEMENTED YET!! \n");
#else
unsigned long pld;
unsigned int i;
/* Read the interrupt summary register of TSUNAMI */
pld = TSUNAMI_cchip->dir0.csr;
/*
* Now for every possible bit set, work through them and call
* the appropriate interrupt handler.
*/
while (pld) {
i = ffz(~pld);
pld &= pld - 1; /* clear least bit set */
if (i == 55)
isa_device_interrupt(vector, regs);
else
handle_irq(16 + i, 16 + i, regs);
#if 0
TSUNAMI_cchip->dir0.csr = 1UL << i; mb();
tmp = TSUNAMI_cchip->dir0.csr;
#endif
}
#endif
}
static void
miata_srm_device_interrupt(unsigned long vector)
{
int irq;
irq = (vector - 0x800) >> 4;
/*
*/
if (irq >= 16)
irq = irq + 8;
handle_irq(irq);
}
static void
rawhide_srm_device_interrupt(unsigned long vector)
{
int irq;
irq = (vector - 0x800) >> 4;
/*
* The RAWHIDE SRM console reports PCI interrupts with a vector
* 0x80 *higher* than one might expect, as PCI IRQ 0 (ie bit 0)
* shows up as IRQ 24, etc, etc. We adjust it down by 8 to have
* it line up with the actual bit numbers from the REQ registers,
* which is how we manage the interrupts/mask. Sigh...
*
* Also, PCI #1 interrupts are offset some more... :-(
*/
if (irq == 52) {
/* SCSI on PCI1 is special. */
irq = 72;
}
/* Adjust by which hose it is from. */
irq -= ((irq + 16) >> 2) & 0x38;
handle_irq(irq);
}
/*
* do_IRQ handles all normal device IRQ's (the special
* SMP cross-CPU interrupts have their own specific
* handlers).
*/
unsigned int __irq_entry do_IRQ(struct pt_regs *regs)
{
// 取得原来的寄存器
struct pt_regs *old_regs = set_irq_regs(regs);
// 取得中断向量号
/* high bit used in ret_from_ code */
unsigned vector = ~regs->orig_ax;
unsigned irq;
// 退出idle进程
exit_idle();
// 进入中断。使表示中断处理程序嵌套数量的计数器递增。
// 计数器是指当前进程thread_info结构的preempt_count字段
irq_enter();
// 中断线号与设备的中断号之间对应关系,有系统分配
// 分配表是一个per-cpu变量的vector_irq
irq = __get_cpu_var(vector_irq)[vector];
if (!handle_irq(irq, regs)) {
ack_APIC_irq();
if (printk_ratelimit())
pr_emerg("%s: %d.%d No irq handler for vector (irq %d)\n",
__func__, smp_processor_id(), vector, irq);
}
// 结束中断
irq_exit();
set_irq_regs(old_regs);
return 1;
}
static void
titan_srm_device_interrupt(unsigned long vector)
{
int irq;
irq = (vector - 0x800) >> 4;
handle_irq(irq);
}
void irq_entry(regs *r)
{
ASSERT(!are_interrupts_enabled());
DEBUG_VALIDATE_STACK_PTR();
ASSERT(get_curr_task() != NULL);
DEBUG_check_not_same_interrupt_nested(regs_intnum(r));
handle_irq(r);
}
static void
wildfire_device_interrupt(unsigned long vector, struct pt_regs * regs)
{
int irq;
irq = (vector - 0x800) >> 4;
/*
* bits 10-8: source QBB ID
* bits 7-6: PCA
* bits 5-0: irq in PCA
*/
handle_irq(irq, regs);
return;
}
asmregparm unsigned int do_IRQ(struct pt_regs *regs)
{
/* high bit used in ret_from_ code */
unsigned vector = ~regs->orig_ax;
unsigned irq;
irq_enter();
irq = vector_irq[vector];
if (!handle_irq(irq, regs)) {
ack_APIC_irq();
}
irq_exit();
/* Give scheduler a chance to run */
if (irq == 0) kt_sched_tick();
return 1;
}
/*
* do_IRQ handles all normal device IRQ's (the special
* SMP cross-CPU interrupts have their own specific
* handlers).
*/
__visible unsigned int __irq_entry do_IRQ(struct pt_regs *regs)
{
struct pt_regs *old_regs = set_irq_regs(regs);
struct irq_desc * desc;
/* high bit used in ret_from_ code */
unsigned vector = ~regs->orig_ax;
/*
* NB: Unlike exception entries, IRQ entries do not reliably
* handle context tracking in the low-level entry code. This is
* because syscall entries execute briefly with IRQs on before
* updating context tracking state, so we can take an IRQ from
* kernel mode with CONTEXT_USER. The low-level entry code only
* updates the context if we came from user mode, so we won't
* switch to CONTEXT_KERNEL. We'll fix that once the syscall
* code is cleaned up enough that we can cleanly defer enabling
* IRQs.
*/
entering_irq();
/* entering_irq() tells RCU that we're not quiescent. Check it. */
RCU_LOCKDEP_WARN(!rcu_is_watching(), "IRQ failed to wake up RCU");
desc = __this_cpu_read(vector_irq[vector]);
if (!handle_irq(desc, regs)) {
ack_APIC_irq();
if (desc != VECTOR_RETRIGGERED) {
pr_emerg_ratelimited("%s: %d.%d No irq handler for vector\n",
__func__, smp_processor_id(),
vector);
} else {
__this_cpu_write(vector_irq[vector], VECTOR_UNUSED);
}
}
exiting_irq();
set_irq_regs(old_regs);
return 1;
}
void irq_handler (unsigned int port_number)
{
system_call_thread_name_set ("IRQ handler");
if (system_call_irq_register (serial_port[port_number].irq, "Serial (UART)")
!= STORM_RETURN_SUCCESS)
{
log_print_formatted (&log_structure, LOG_URGENCY_EMERGENCY,
"Could not allocate IRQ %d.", serial_port[port_number].irq);
return;
}
while (TRUE)
{
system_call_irq_wait (serial_port[port_number].irq);
handle_irq (port_number);
system_call_irq_acknowledge (serial_port[port_number].irq);
}
}
/*
* do_IRQ handles all normal device IRQ's (the special
* SMP cross-CPU interrupts have their own specific
* handlers).
*/
__visible unsigned int __irq_entry do_IRQ(struct pt_regs *regs)
{
/* 将栈顶地址保存到全局变量__irq_regs中,old_regs用于保存现在的__irq_regs值 */
struct pt_regs *old_regs = set_irq_regs(regs);
/* 获取中断向量号,因为中断向量号是以取反方式保存的,这里再次取反 */
unsigned vector = ~regs->orig_ax;
/* 中断向量号 */
unsigned irq;
/* 硬中断计数器增加,硬中断计数器保存在preempt_count */
irq_enter();
/* 这里开始禁止调度,因为preempt_count不为0 */
/* 退出idle进程(如果当前进程是idle进程的情况下) */
exit_idle();
/* 根据中断向量号获取中断号 */
irq = __this_cpu_read(vector_irq[vector]);
/* 主要函数是handle_irq,进行中断服务例程的处理 */
if (!handle_irq(irq, regs)) {
/* EIO模式的应答 */
ack_APIC_irq();
/* 该中断号并没有发生过多次触发 */
if (irq != VECTOR_RETRIGGERED) {
pr_emerg_ratelimited("%s: %d.%d No irq handler for vector (irq %d)\n",
__func__, smp_processor_id(),
vector, irq);
} else {
/* 将此中断向量号对应的vector_irq设置为未定义 */
__this_cpu_write(vector_irq[vector], VECTOR_UNDEFINED);
}
}
/* 硬中断计数器减少,并检查是否有软中断需要执行,如果有,会设置CPU在开中断的状态下执行软中断处理 */
irq_exit();
/* 这里开始允许调度 */
/* 恢复原来的__irq_regs值 */
set_irq_regs(old_regs);
return 1;
}
static void
clipper_srm_device_interrupt(unsigned long vector, struct pt_regs * regs)
{
int irq;
irq = (vector - 0x800) >> 4;
/*
* The SRM console reports PCI interrupts with a vector calculated by:
*
* 0x900 + (0x10 * DRIR-bit)
*
* So bit 16 shows up as IRQ 32, etc.
*
* CLIPPER uses bits 8-47 for PCI interrupts, so we do not need
* to scale down the vector reported, we just use it.
*
* Eg IRQ 24 is DRIR bit 8, etc, etc
*/
handle_irq(irq, regs);
}
static void
dp264_device_interrupt(unsigned long vector)
{
unsigned long pld;
unsigned int i;
/* Read the interrupt summary register of TSUNAMI */
pld = TSUNAMI_cchip->dir0.csr;
/*
* Now for every possible bit set, work through them and call
* the appropriate interrupt handler.
*/
while (pld) {
i = ffz(~pld);
pld &= pld - 1; /* clear least bit set */
if (i == 55)
isa_device_interrupt(vector);
else
handle_irq(16 + i);
}
}
static void
alcor_device_interrupt(unsigned long vector)
{
unsigned long pld;
unsigned int i;
/* Read the interrupt summary register of the GRU */
pld = (*(vuip)GRU_INT_REQ) & GRU_INT_REQ_BITS;
/*
* Now for every possible bit set, work through them and call
* the appropriate interrupt handler.
*/
while (pld) {
i = ffz(~pld);
pld &= pld - 1; /* clear least bit set */
if (i == 31) {
isa_device_interrupt(vector);
} else {
handle_irq(16 + i);
}
}
}
static void
alcor_device_interrupt(unsigned long vector)
{
unsigned long pld;
unsigned int i;
/* */
pld = (*(vuip)GRU_INT_REQ) & GRU_INT_REQ_BITS;
/*
*/
while (pld) {
i = ffz(~pld);
pld &= pld - 1; /* */
if (i == 31) {
isa_device_interrupt(vector);
} else {
handle_irq(16 + i);
}
}
}
static void
cabriolet_device_interrupt(unsigned long v)
{
unsigned long pld;
unsigned int i;
/* */
pld = inb(0x804) | (inb(0x805) << 8) | (inb(0x806) << 16);
/*
*/
while (pld) {
i = ffz(~pld);
pld &= pld - 1; /* */
if (i == 4) {
isa_device_interrupt(v);
} else {
handle_irq(16 + i);
}
}
}
static void
cabriolet_device_interrupt(unsigned long v, struct pt_regs *r)
{
unsigned long pld;
unsigned int i;
/* Read the interrupt summary registers */
pld = inb(0x804) | (inb(0x805) << 8) | (inb(0x806) << 16);
/*
* Now for every possible bit set, work through them and call
* the appropriate interrupt handler.
*/
while (pld) {
i = ffz(~pld);
pld &= pld - 1; /* clear least bit set */
if (i == 4) {
isa_device_interrupt(v, r);
} else {
handle_irq(16 + i, r);
}
}
}
static void
dp264_srm_device_interrupt(unsigned long vector, struct pt_regs * regs)
{
int irq;
irq = (vector - 0x800) >> 4;
/*
* The SRM console reports PCI interrupts with a vector calculated by:
*
* 0x900 + (0x10 * DRIR-bit)
*
* So bit 16 shows up as IRQ 32, etc.
*
* On DP264/BRICK/MONET, we adjust it down by 16 because at least
* that many of the low order bits of the DRIR are not used, and
* so we don't count them.
*/
if (irq >= 32)
irq -= 16;
handle_irq(irq, regs);
}
