2 * arch/mips/dec/int-handler.S
4 * Copyright (C) 1995, 1996, 1997 Paul M. Antoine and Harald Koerfgen
5 * Copyright (C) 2000, 2001, 2002, 2003, 2005 Maciej W. Rozycki
7 * Written by Ralf Baechle and Andreas Busse, modified for DECstation
8 * support by Paul Antoine and Harald Koerfgen.
10 * completly rewritten:
11 * Copyright (C) 1998 Harald Koerfgen
13 * Rewritten extensively for controller-driven IRQ support
14 * by Maciej W. Rozycki.
16 #include <linux/config.h>
18 #include <asm/addrspace.h>
20 #include <asm/mipsregs.h>
21 #include <asm/regdef.h>
22 #include <asm/stackframe.h>
24 #include <asm/dec/interrupts.h>
25 #include <asm/dec/ioasic_addrs.h>
26 #include <asm/dec/ioasic_ints.h>
27 #include <asm/dec/kn01.h>
28 #include <asm/dec/kn02.h>
29 #include <asm/dec/kn02xa.h>
30 #include <asm/dec/kn03.h>
32 #define KN02_CSR_BASE CKSEG1ADDR(KN02_SLOT_BASE + KN02_CSR)
33 #define KN02XA_IOASIC_BASE CKSEG1ADDR(KN02XA_SLOT_BASE + IOASIC_IOCTL)
34 #define KN03_IOASIC_BASE CKSEG1ADDR(KN03_SLOT_BASE + IOASIC_IOCTL)
39 * decstation_handle_int: Interrupt handler for DECstations
41 * We follow the model in the Indy interrupt code by David Miller, where he
42 * says: a lot of complication here is taken away because:
44 * 1) We handle one interrupt and return, sitting in a loop
45 * and moving across all the pending IRQ bits in the cause
46 * register is _NOT_ the answer, the common case is one
47 * pending IRQ so optimize in that direction.
49 * 2) We need not check against bits in the status register
50 * IRQ mask, that would make this routine slow as hell.
52 * 3) Linux only thinks in terms of all IRQs on or all IRQs
53 * off, nothing in between like BSD spl() brain-damage.
55 * Furthermore, the IRQs on the DECstations look basically (barring
56 * software IRQs which we don't use at all) like...
58 * DS2100/3100's, aka kn01, aka Pmax:
62 * 0 Software (ignored)
63 * 1 Software (ignored)
68 * 6 Memory Controller & Video
71 * DS5000/200, aka kn02, aka 3max:
75 * 0 Software (ignored)
76 * 1 Software (ignored)
84 * DS5000/1xx's, aka kn02ba, aka 3min:
88 * 0 Software (ignored)
89 * 1 Software (ignored)
90 * 2 TurboChannel Slot 0
91 * 3 TurboChannel Slot 1
92 * 4 TurboChannel Slot 2
93 * 5 TurboChannel Slot 3 (ASIC)
97 * DS5000/2x's, aka kn02ca, aka maxine:
101 * 0 Software (ignored)
102 * 1 Software (ignored)
103 * 2 Periodic Interrupt (100usec)
105 * 4 I/O write timeout
106 * 5 TurboChannel (ASIC)
107 * 6 Halt Keycode from Access.Bus keyboard (CTRL-ALT-ENTER)
110 * DS5000/2xx's, aka kn03, aka 3maxplus:
114 * 0 Software (ignored)
115 * 1 Software (ignored)
116 * 2 System Board (ASIC)
123 * We handle the IRQ according to _our_ priority (see setup.c),
124 * then we just return. If multiple IRQs are pending then we will
125 * just take another exception, big deal.
128 NESTED(decstation_handle_int, PT_SIZE, ra)
131 CLI # TEST: interrupts should be off
136 * Get pending Interrupts
138 mfc0 t0,CP0_CAUSE # get pending interrupts
143 andi t0,ST0_IM # CAUSE.CE may be non-zero!
144 and t0,t1 # isolate allowed ones
150 bnez t2,fpu # handle FPU immediately
154 * Find irq with highest priority
156 PTR_LA t1,cpu_mask_nr_tbl
161 addu t1,2*PTRSIZE # delay slot
164 * Do the low-level stuff
168 bgez a0,handle_it # irq_nr >= 0?
169 # irq_nr < 0: it is an address
172 # a trick to save a branch:
173 lui t2,(KN03_IOASIC_BASE>>16)&0xffff
174 # upper part of IOASIC Address
177 * Handle "IRQ Controller" Interrupts
178 * Masked Interrupts are still visible and have to be masked "by hand".
180 FEXPORT(kn02_io_int) # 3max
181 lui t0,(KN02_CSR_BASE>>16)&0xffff
182 # get interrupt status and mask
185 andi t1,t0,KN02_IRQ_ALL
187 srl t0,16 # shift interrupt mask
189 FEXPORT(kn02xa_io_int) # 3min/maxine
190 lui t2,(KN02XA_IOASIC_BASE>>16)&0xffff
191 # upper part of IOASIC Address
193 FEXPORT(kn03_io_int) # 3max+ (t2 loaded earlier)
194 lw t0,IO_REG_SIR(t2) # get status: IOASIC sir
195 lw t1,IO_REG_SIMR(t2) # get mask: IOASIC simr
198 1: and t0,t1 # mask out allowed ones
203 * Find irq with highest priority
205 PTR_LA t1,asic_mask_nr_tbl
210 addu t1,2*PTRSIZE # delay slot
213 * Do the low-level stuff
215 lw a0,%lo(-PTRSIZE)(t1)
217 bgez a0,handle_it # irq_nr >= 0?
218 # irq_nr < 0: it is an address
224 * Dispatch low-priority interrupts. We reconsider all status
225 * bits again, which looks like a lose, but it makes the code
226 * simple and O(log n), so it gets compensated.
228 FEXPORT(cpu_all_int) # HALT, timers, software junk
229 li a0,DEC_CPU_IRQ_BASE
231 li t1,CAUSEF_IP>>CAUSEB_IP # mask
233 li t2,4 # nr of bits / 2
235 FEXPORT(kn02_all_int) # impossible ?
237 li t1,KN02_IRQ_ALL # mask
239 li t2,4 # nr of bits / 2
241 FEXPORT(asic_all_int) # various I/O ASIC junk
243 li t1,IO_IRQ_ALL # mask
245 li t2,8 # nr of bits / 2
248 * Dispatch DMA interrupts -- O(log n).
250 FEXPORT(asic_dma_int) # I/O ASIC DMA events
251 li a0,IO_IRQ_BASE+IO_INR_DMA
253 li t1,IO_IRQ_DMA>>IO_INR_DMA # mask
254 li t2,8 # nr of bits / 2
257 * Find irq with highest priority.
258 * Highest irq number takes precedence.
287 END(decstation_handle_int)
290 * Generic unimplemented interrupt routines -- cpu_mask_nr_tbl
291 * and asic_mask_nr_tbl are initialized to point all interrupts here.
292 * The tables are then filled in by machine-specific initialisation
295 FEXPORT(dec_intr_unimplemented)
296 move a1,t0 # cheats way of printing an arg!
297 PANIC("Unimplemented cpu interrupt! CP0_CAUSE: 0x%08x");
299 FEXPORT(asic_intr_unimplemented)
300 move a1,t0 # cheats way of printing an arg!
301 PANIC("Unimplemented asic interrupt! ASIC ISR: 0x%08x");