source: rtems/c/src/exec/score/cpu/powerpc/old_exception_processing/cpu.c @ bf85b19

4.104.114.84.95
Last change on this file since bf85b19 was acc25ee, checked in by Joel Sherrill <joel.sherrill@…>, on 12/02/99 at 14:31:19

Merged of mcp750 and mvme2307 BSP by Eric Valette <valette@…>.
As part of this effort, the mpc750 libcpu code is now shared with the
ppc6xx.

  • Property mode set to 100644
File size: 20.2 KB
Line 
1/*
2 *  PowerPC CPU Dependent Source
3 *
4 *  Author:     Andrew Bray <andy@i-cubed.co.uk>
5 *
6 *  COPYRIGHT (c) 1995 by i-cubed ltd.
7 *
8 *  To anyone who acknowledges that this file is provided "AS IS"
9 *  without any express or implied warranty:
10 *      permission to use, copy, modify, and distribute this file
11 *      for any purpose is hereby granted without fee, provided that
12 *      the above copyright notice and this notice appears in all
13 *      copies, and that the name of i-cubed limited not be used in
14 *      advertising or publicity pertaining to distribution of the
15 *      software without specific, written prior permission.
16 *      i-cubed limited makes no representations about the suitability
17 *      of this software for any purpose.
18 *
19 *  Derived from c/src/exec/cpu/no_cpu/cpu.c:
20 *
21 *  COPYRIGHT (c) 1989-1997.
22 *  On-Line Applications Research Corporation (OAR).
23 *  Copyright assigned to U.S. Government, 1994.
24 *
25 *  The license and distribution terms for this file may be found in
26 *  the file LICENSE in this distribution or at
27 *  http://www.OARcorp.com/rtems/license.html.
28 *
29 *  $Id$
30 */
31
32#include <rtems/system.h>
33#include <rtems/score/isr.h>
34#include <rtems/score/context.h>
35#include <rtems/score/thread.h>
36#include <rtems/score/interr.h>
37
38/*
39 *  These are for testing purposes.
40 */
41
42/*  _CPU_Initialize
43 *
44 *  This routine performs processor dependent initialization.
45 *
46 *  INPUT PARAMETERS:
47 *    cpu_table       - CPU table to initialize
48 *    thread_dispatch - address of disptaching routine
49 */
50
51static void ppc_spurious(int, CPU_Interrupt_frame *);
52
53void _CPU_Initialize(
54  rtems_cpu_table  *cpu_table,
55  void      (*thread_dispatch)      /* ignored on this CPU */
56)
57{
58  proc_ptr handler = (proc_ptr)ppc_spurious;
59  int i;
60#if (PPC_ABI != PPC_ABI_POWEROPEN)
61  register unsigned32 r2 = 0;
62#if (PPC_ABI != PPC_ABI_GCC27)
63  register unsigned32 r13 = 0;
64
65  asm ("mr %0,13" : "=r" ((r13)) : "0" ((r13)));
66  _CPU_IRQ_info.Default_r13 = r13;
67#endif
68
69  asm ("mr %0,2" : "=r" ((r2)) : "0" ((r2)));
70  _CPU_IRQ_info.Default_r2 = r2;
71#endif
72
73  _CPU_IRQ_info.Nest_level = &_ISR_Nest_level;
74  _CPU_IRQ_info.Disable_level = &_Thread_Dispatch_disable_level;
75  _CPU_IRQ_info.Vector_table = _ISR_Vector_table;
76#if (PPC_ABI == PPC_ABI_POWEROPEN)
77  _CPU_IRQ_info.Dispatch_r2 = ((unsigned32 *)_Thread_Dispatch)[1];
78#endif
79  _CPU_IRQ_info.Switch_necessary = &_Context_Switch_necessary;
80  _CPU_IRQ_info.Signal = &_ISR_Signals_to_thread_executing;
81
82#if (PPC_USE_SPRG)
83  i = (int)&_CPU_IRQ_info;
84  asm volatile("mtspr 0x113, %0" : "=r" (i) : "0" (i)); /* SPRG 3 */
85#endif
86
87  /*
88   * Store Msr Value in the IRQ info structure.
89   */
90   _CPU_MSR_Value(_CPU_IRQ_info.msr_initial);
91 
92#if (PPC_USE_SPRG)
93  i = _CPU_IRQ_info.msr_initial;
94  asm volatile("mtspr 0x112, %0" : "=r" (i) : "0" (i)); /* SPRG 2 */
95#endif
96
97  if ( cpu_table->spurious_handler )
98    handler = (proc_ptr)cpu_table->spurious_handler;
99
100  for (i = 0; i < PPC_INTERRUPT_MAX;  i++)
101    _ISR_Vector_table[i] = handler;
102
103  _CPU_Table = *cpu_table;
104}
105
106/*PAGE
107 *
108 *  _CPU_ISR_Calculate_level
109 *
110 *  The PowerPC puts its interrupt enable status in the MSR register
111 *  which also contains things like endianness control.  To be more
112 *  awkward, the layout varies from processor to processor.  This
113 *  is why it was necessary to adopt a scheme which allowed the user
114 *  to specify specifically which interrupt sources were enabled.
115 */
116 
117unsigned32 _CPU_ISR_Calculate_level(
118  unsigned32 new_level
119)
120{
121  register unsigned32 new_msr = 0;
122
123  /*
124   *  Set the critical interrupt enable bit
125   */
126
127#if (PPC_HAS_RFCI)
128  if ( !(new_level & PPC_INTERRUPT_LEVEL_CE) )
129    new_msr |= PPC_MSR_CE;
130#endif
131
132  if ( !(new_level & PPC_INTERRUPT_LEVEL_ME) )
133    new_msr |= PPC_MSR_ME;
134
135  if ( !(new_level & PPC_INTERRUPT_LEVEL_EE) )
136    new_msr |= PPC_MSR_EE;
137
138  return new_msr;
139}
140
141/*PAGE
142 *
143 *  _CPU_ISR_Set_level
144 *
145 *  This routine sets the requested level in the MSR.
146 */
147
148void _CPU_ISR_Set_level(
149  unsigned32 new_level
150)
151{
152  register unsigned32 tmp = 0;
153  register unsigned32 new_msr;
154
155  new_msr = _CPU_ISR_Calculate_level( new_level );
156
157  asm volatile (
158    "mfmsr %0; andc %0,%0,%1; and %2, %2, %1; or %0, %0, %2; mtmsr %0" :
159    "=&r" ((tmp)) :
160    "r" ((PPC_MSR_DISABLE_MASK)), "r" ((new_msr)), "0" ((tmp))
161  );
162}
163
164/*PAGE
165 *
166 *  _CPU_ISR_Get_level
167 *
168 *  This routine gets the current interrupt level from the MSR and
169 *  converts it to an RTEMS interrupt level.
170 */
171
172unsigned32 _CPU_ISR_Get_level( void )
173{
174  unsigned32 level = 0;
175  unsigned32 msr;
176 
177  asm volatile("mfmsr %0" : "=r" ((msr)));
178 
179  msr &= PPC_MSR_DISABLE_MASK;
180
181  /*
182   *  Set the critical interrupt enable bit
183   */
184
185#if (PPC_HAS_RFCI)
186  if ( !(msr & PPC_MSR_CE) )
187    level |= PPC_INTERRUPT_LEVEL_CE;
188#endif
189
190  if ( !(msr & PPC_MSR_ME) )
191    level |= PPC_INTERRUPT_LEVEL_ME;
192
193  if ( !(msr & PPC_MSR_EE) )
194    level |= PPC_INTERRUPT_LEVEL_EE;
195
196  return level;
197}
198
199/*PAGE
200 *
201 *  _CPU_Context_Initialize
202 */
203
204#if (PPC_ABI == PPC_ABI_POWEROPEN)
205#define CPU_MINIMUM_STACK_FRAME_SIZE 56
206#else /* PPC_ABI_SVR4 or PPC_ABI_EABI */
207#define CPU_MINIMUM_STACK_FRAME_SIZE 8
208#endif
209
210void _CPU_Context_Initialize(
211  Context_Control  *the_context,
212  unsigned32       *stack_base,
213  unsigned32        size,
214  unsigned32        new_level,
215  void             *entry_point,
216  boolean           is_fp
217)
218{
219  unsigned32 msr_value;
220  unsigned32 sp;
221
222  sp = (unsigned32)stack_base + size - CPU_MINIMUM_STACK_FRAME_SIZE;
223  *((unsigned32 *)sp) = 0;
224  the_context->gpr1 = sp;
225   
226  the_context->msr = _CPU_ISR_Calculate_level( new_level );
227
228  /*
229   *  The FP bit of the MSR should only be enabled if this is a floating
230   *  point task.  Unfortunately, the vfprintf_r routine in newlib
231   *  ends up pushing a floating point register regardless of whether or
232   *  not a floating point number is being printed.  Serious restructuring
233   *  of vfprintf.c will be required to avoid this behavior.  At this
234   *  time (7 July 1997), this restructuring is not being done.
235   */
236
237  /*if ( is_fp ) */
238    the_context->msr |= PPC_MSR_FP;
239
240  /*
241   *  Calculate the task's MSR value:
242   *
243   *     + Set the exception prefix bit to point to the exception table
244   *     + Force the RI bit
245   *     + Use the DR and IR bits
246   */
247  _CPU_MSR_Value( msr_value );
248  the_context->msr |= (msr_value & PPC_MSR_EP);
249  the_context->msr |= PPC_MSR_RI;
250  the_context->msr |= msr_value & (PPC_MSR_DR|PPC_MSR_IR);
251
252#if (PPC_ABI == PPC_ABI_POWEROPEN)
253  { unsigned32 *desc = (unsigned32 *)entry_point;
254
255    the_context->pc = desc[0];
256    the_context->gpr2 = desc[1];
257  }
258#endif
259
260#if (PPC_ABI == PPC_ABI_SVR4)
261  { unsigned    r13 = 0;
262    asm volatile ("mr %0, 13" : "=r" ((r13)));
263   
264    the_context->pc = (unsigned32)entry_point;
265    the_context->gpr13 = r13;
266  }
267#endif
268
269#if (PPC_ABI == PPC_ABI_EABI)
270  { unsigned32  r2 = 0;
271    unsigned    r13 = 0;
272    asm volatile ("mr %0,2; mr %1,13" : "=r" ((r2)), "=r" ((r13)));
273 
274    the_context->pc = (unsigned32)entry_point;
275    the_context->gpr2 = r2;
276    the_context->gpr13 = r13;
277  }
278#endif
279}
280
281
282/*  _CPU_ISR_install_vector
283 *
284 *  This kernel routine installs the RTEMS handler for the
285 *  specified vector.
286 *
287 *  Input parameters:
288 *    vector      - interrupt vector number
289 *    old_handler - former ISR for this vector number
290 *    new_handler - replacement ISR for this vector number
291 *
292 *  Output parameters:  NONE
293 *
294 */
295
296void _CPU_ISR_install_vector(
297  unsigned32  vector,
298  proc_ptr    new_handler,
299  proc_ptr   *old_handler
300)
301{
302   proc_ptr   ignored;
303   *old_handler = _ISR_Vector_table[ vector ];
304
305   /*
306    *  If the interrupt vector table is a table of pointer to isr entry
307    *  points, then we need to install the appropriate RTEMS interrupt
308    *  handler for this vector number.
309    */
310
311   /*
312    * Install the wrapper so this ISR can be invoked properly.
313    */
314   if (_CPU_Table.exceptions_in_RAM)
315      _CPU_ISR_install_raw_handler( vector, _ISR_Handler, &ignored );
316
317   /*
318    *  We put the actual user ISR address in '_ISR_vector_table'.  This will
319    *  be used by the _ISR_Handler so the user gets control.
320    */
321
322    _ISR_Vector_table[ vector ] = new_handler ? (ISR_Handler_entry)new_handler :
323       _CPU_Table.spurious_handler ?
324          (ISR_Handler_entry)_CPU_Table.spurious_handler :
325          (ISR_Handler_entry)ppc_spurious;
326}
327
328/*PAGE
329 *
330 *  _CPU_Install_interrupt_stack
331 */
332
333void _CPU_Install_interrupt_stack( void )
334{
335#if (PPC_ABI == PPC_ABI_POWEROPEN || PPC_ABI == PPC_ABI_GCC27)
336  _CPU_IRQ_info.Stack = _CPU_Interrupt_stack_high - 56;
337#else
338  _CPU_IRQ_info.Stack = _CPU_Interrupt_stack_high - 8;
339#endif
340}
341
342/* Handle a spurious interrupt */
343static void ppc_spurious(int v, CPU_Interrupt_frame *i)
344{
345#if 0
346    printf("Spurious interrupt on vector %d from %08.8x\n",
347           v, i->pc);
348#endif
349#ifdef ppc403
350    if (v == PPC_IRQ_EXTERNAL)
351        {
352            register int r = 0;
353
354            asm volatile("mtdcr 0x42, %0" :
355                "=&r" ((r)) : "0" ((r))); /* EXIER */
356        }
357    else if (v == PPC_IRQ_PIT)
358        {
359            register int r = 0x08000000;
360
361            asm volatile("mtspr 0x3d8, %0" :
362                "=&r" ((r)) : "0" ((r))); /* TSR */
363        }
364    else if (v == PPC_IRQ_FIT)
365        {
366            register int r = 0x04000000;
367
368            asm volatile("mtspr 0x3d8, %0" :
369                "=&r" ((r)) : "0" ((r))); /* TSR */
370        }
371#endif
372}
373
374void _CPU_Fatal_error(unsigned32 _error)
375{
376  asm volatile ("mr 3, %0" : : "r" ((_error)));
377  asm volatile ("tweq 5,5");
378  asm volatile ("li 0,0; mtmsr 0");
379  while (1) ;
380}
381
382#define PPC_SYNCHRONOUS_TRAP_BIT_MASK    0x100
383#define PPC_ASYNCHRONOUS_TRAP( _trap ) (_trap)
384#define PPC_SYNCHRONOUS_TRAP ( _trap ) ((_trap)+PPC_SYNCHRONOUS_TRAP_BIT_MASK)
385#define PPC_REAL_TRAP_NUMBER ( _trap ) ((_trap)%PPC_SYNCHRONOUS_TRAP_BIT_MASK)
386
387
388const CPU_Trap_table_entry _CPU_Trap_slot_template = {
389
390#if (PPC_ABI == PPC_ABI_POWEROPEN || PPC_ABI == PPC_ABI_GCC27)
391#error " Vector install not tested."
392#if (PPC_HAS_FPU)
393#error " Vector install not tested."
394  0x9421feb0,           /* stwu r1, -(20*4 + 18*8 + IP_END)(r1) */
395#else
396#error " Vector install not tested."
397  0x9421ff40,           /* stwu    r1, -(20*4 + IP_END)(r1)     */
398#endif
399#else
400  0x9421ff90,           /* stwu    r1, -(IP_END)(r1)            */
401#endif
402
403  0x90010008,           /* stw   %r0, IP_0(%r1)                 */
404  0x38000000,           /* li    %r0, PPC_IRQ                   */
405  0x48000002            /* ba    PROC (_ISR_Handler)            */
406};
407
408#if defined(mpc860) || defined(mpc821)
409const CPU_Trap_table_entry _CPU_Trap_slot_template_m860 = {
410  0x7c0803ac,           /* mtlr  %r0                            */
411  0x81210028,           /* lwz   %r9, IP_9(%r1)                 */
412  0x38000000,           /* li    %r0, PPC_IRQ                   */
413  0x48000002            /* b     PROC (_ISR_Handler)            */
414};
415#endif /* mpc860 */
416
417unsigned32  ppc_exception_vector_addr(
418  unsigned32 vector
419);
420
421
422/*PAGE
423 *
424 *  _CPU_ISR_install_raw_handler
425 *
426 *  This routine installs the specified handler as a "raw" non-executive
427 *  supported trap handler (a.k.a. interrupt service routine).
428 *
429 *  Input Parameters:
430 *    vector      - trap table entry number plus synchronous
431 *                    vs. asynchronous information
432 *    new_handler - address of the handler to be installed
433 *    old_handler - pointer to an address of the handler previously installed
434 *
435 *  Output Parameters: NONE
436 *    *new_handler - address of the handler previously installed
437 *
438 *  NOTE:
439 *
440 *  This routine is based on the SPARC routine _CPU_ISR_install_raw_handler.
441 *  Install a software trap handler as an executive interrupt handler
442 *  (which is desirable since RTEMS takes care of window and register issues),
443 *  then the executive needs to know that the return address is to the trap
444 *  rather than the instruction following the trap.
445 *
446 */
447 
448void _CPU_ISR_install_raw_handler(
449  unsigned32  vector,
450  proc_ptr    new_handler,
451  proc_ptr   *old_handler
452)
453{
454  unsigned32             real_vector;
455  CPU_Trap_table_entry  *slot;
456  unsigned32             u32_handler=0;
457
458  /*
459   *  Get the "real" trap number for this vector ignoring the synchronous
460   *  versus asynchronous indicator included with our vector numbers.
461   */
462
463  real_vector = vector;
464
465  /*
466   *  Get the current base address of the trap table and calculate a pointer
467   *  to the slot we are interested in.
468   */
469  slot = (CPU_Trap_table_entry  *)ppc_exception_vector_addr( real_vector );
470
471  /*
472   *  Get the address of the old_handler from the trap table.
473   *
474   *  NOTE: The old_handler returned will be bogus if it does not follow
475   *        the RTEMS model.
476   */
477
478#define HIGH_BITS_MASK   0xFFFFFC00
479#define HIGH_BITS_SHIFT  10
480#define LOW_BITS_MASK    0x000003FF
481
482  if (slot->stwu_r1 == _CPU_Trap_slot_template.stwu_r1) {
483    /*
484     * Set u32_handler = to target address 
485     */
486    u32_handler = slot->b_Handler & 0x03fffffc;
487
488    /* IMD FIX: sign extend address fragment... */
489    if (u32_handler & 0x02000000) {
490      u32_handler  |= 0xfc000000;
491    }
492
493    *old_handler =  (proc_ptr) u32_handler;
494  } else
495/* There are two kinds of handlers for the MPC860. One is the 'standard'
496 *  one like above. The other is for the cascaded interrupts from the SIU
497 *  and CPM. Therefore we must check for the alternate one if the standard
498 *  one is not present
499 */
500#if defined(mpc860) || defined(mpc821)
501  if (slot->stwu_r1 == _CPU_Trap_slot_template_m860.stwu_r1) {
502    /*
503     * Set u32_handler = to target address 
504     */
505    u32_handler = slot->b_Handler & 0x03fffffc;
506    *old_handler =  (proc_ptr) u32_handler;
507  } else
508#endif /* mpc860 */
509
510    *old_handler = 0;
511
512  /*
513   *  Copy the template to the slot and then fix it.
514   */
515#if defined(mpc860) || defined(mpc821)
516  if (vector >= PPC_IRQ_IRQ0)
517    *slot = _CPU_Trap_slot_template_m860;
518  else
519#endif /* mpc860 */
520  *slot = _CPU_Trap_slot_template;
521
522  u32_handler = (unsigned32) new_handler;
523
524  /*
525   * IMD FIX: insert address fragment only (bits 6..29)
526   *          therefore check for proper address range
527   *          and remove unwanted bits
528   */
529  if ((u32_handler & 0xfc000000) == 0xfc000000) {
530    u32_handler  &= ~0xfc000000;
531  }
532  else if ((u32_handler & 0xfc000000) != 0x00000000) {
533    _Internal_error_Occurred(INTERNAL_ERROR_CORE,
534                             TRUE,
535                             u32_handler);
536  }
537
538  slot->b_Handler |= u32_handler;
539
540  slot->li_r0_IRQ  |= vector;
541
542  _CPU_Data_Cache_Block_Flush( slot );
543}
544
545unsigned32  ppc_exception_vector_addr(
546  unsigned32 vector
547)
548{
549#if (!PPC_HAS_EVPR)
550  unsigned32 Msr;
551#endif
552  unsigned32 Top = 0;
553  unsigned32 Offset = 0x000;
554
555#if (PPC_HAS_EXCEPTION_PREFIX)
556  _CPU_MSR_Value ( Msr );
557  if ( ( Msr & PPC_MSR_EP) != 0 ) /* Vectors at FFFx_xxxx */
558    Top = 0xfff00000;
559#elif (PPC_HAS_EVPR)
560  asm volatile( "mfspr %0,0x3d6" : "=r" (Top)); /* EVPR */
561  Top = Top & 0xffff0000;
562#endif
563
564  switch ( vector ) {
565    case PPC_IRQ_SYSTEM_RESET:   /* on 40x aka PPC_IRQ_CRIT */
566      Offset = 0x00100;
567      break;
568    case PPC_IRQ_MCHECK:
569      Offset = 0x00200;
570      break;
571    case PPC_IRQ_PROTECT:
572      Offset = 0x00300;
573      break;
574    case PPC_IRQ_ISI:
575      Offset = 0x00400;
576      break;
577    case PPC_IRQ_EXTERNAL:
578      Offset = 0x00500;
579      break;
580    case PPC_IRQ_ALIGNMENT:
581      Offset = 0x00600;
582      break;
583    case PPC_IRQ_PROGRAM:
584      Offset = 0x00700;
585      break;
586    case PPC_IRQ_NOFP:
587      Offset = 0x00800;
588      break;
589    case PPC_IRQ_DECREMENTER:
590      Offset = 0x00900;
591      break;
592    case PPC_IRQ_RESERVED_A:
593      Offset = 0x00a00;
594      break;
595    case PPC_IRQ_RESERVED_B:
596      Offset = 0x00b00;
597      break;
598    case PPC_IRQ_SCALL:
599      Offset = 0x00c00;
600      break;
601    case PPC_IRQ_TRACE:
602      Offset = 0x00d00;
603      break;
604    case PPC_IRQ_FP_ASST:
605      Offset = 0x00e00;
606      break;
607
608#if defined(ppc403)
609                                 
610/*  PPC_IRQ_CRIT is the same vector as PPC_IRQ_RESET
611    case PPC_IRQ_CRIT:
612      Offset = 0x00100;
613      break;
614*/
615    case PPC_IRQ_PIT:
616      Offset = 0x01000;
617      break;
618    case PPC_IRQ_FIT:
619      Offset = 0x01010;
620      break;
621    case PPC_IRQ_WATCHDOG:
622      Offset = 0x01020;
623      break;
624    case PPC_IRQ_DEBUG:
625      Offset = 0x02000;
626      break;
627
628#elif defined(ppc601)
629    case PPC_IRQ_TRACE:
630      Offset = 0x02000;
631      break;
632
633#elif defined(ppc603)
634    case PPC_IRQ_TRANS_MISS:
635      Offset = 0x1000;
636      break;
637    case PPC_IRQ_DATA_LOAD:
638      Offset = 0x1100;
639      break;
640    case PPC_IRQ_DATA_STORE:
641      Offset = 0x1200;
642      break;
643    case PPC_IRQ_ADDR_BRK:
644      Offset = 0x1300;
645      break;
646    case PPC_IRQ_SYS_MGT:
647      Offset = 0x1400;
648      break;
649
650#elif defined(ppc603e)
651    case PPC_TLB_INST_MISS:
652      Offset = 0x1000;
653      break;
654    case PPC_TLB_LOAD_MISS:
655      Offset = 0x1100;
656      break;
657    case PPC_TLB_STORE_MISS:
658      Offset = 0x1200;
659      break;
660    case PPC_IRQ_ADDRBRK:
661      Offset = 0x1300;
662      break;
663    case PPC_IRQ_SYS_MGT:
664      Offset = 0x1400;
665      break;
666
667#elif defined(mpc604)
668    case PPC_IRQ_ADDR_BRK:
669      Offset = 0x1300;
670      break;
671    case PPC_IRQ_SYS_MGT:
672      Offset = 0x1400;
673      break;
674
675#elif defined(mpc860) || defined(mpc821)
676    case PPC_IRQ_EMULATE:
677      Offset = 0x1000;
678      break;
679    case PPC_IRQ_INST_MISS:
680      Offset = 0x1100;
681      break;
682    case PPC_IRQ_DATA_MISS:
683      Offset = 0x1200;
684      break;
685    case PPC_IRQ_INST_ERR:
686      Offset = 0x1300;
687      break;
688    case PPC_IRQ_DATA_ERR:
689      Offset = 0x1400;
690      break;
691    case PPC_IRQ_DATA_BPNT:
692      Offset = 0x1c00;
693      break;
694    case PPC_IRQ_INST_BPNT:
695      Offset = 0x1d00;
696      break;
697    case PPC_IRQ_IO_BPNT:
698      Offset = 0x1e00;
699      break;
700    case PPC_IRQ_DEV_PORT:
701      Offset = 0x1f00;
702      break;
703    case PPC_IRQ_IRQ0:
704      Offset = 0x2000;
705      break;
706    case PPC_IRQ_LVL0:
707      Offset = 0x2040;
708      break;
709    case PPC_IRQ_IRQ1:
710      Offset = 0x2080;
711      break;
712    case PPC_IRQ_LVL1:
713      Offset = 0x20c0;
714      break;
715    case PPC_IRQ_IRQ2:
716      Offset = 0x2100;
717      break;
718    case PPC_IRQ_LVL2:
719      Offset = 0x2140;
720      break;
721    case PPC_IRQ_IRQ3:
722      Offset = 0x2180;
723      break;
724    case PPC_IRQ_LVL3:
725      Offset = 0x21c0;
726      break;
727    case PPC_IRQ_IRQ4:
728      Offset = 0x2200;
729      break;
730    case PPC_IRQ_LVL4:
731      Offset = 0x2240;
732      break;
733    case PPC_IRQ_IRQ5:
734      Offset = 0x2280;
735      break;
736    case PPC_IRQ_LVL5:
737      Offset = 0x22c0;
738      break;
739    case PPC_IRQ_IRQ6:
740      Offset = 0x2300;
741      break;
742    case PPC_IRQ_LVL6:
743      Offset = 0x2340;
744      break;
745    case PPC_IRQ_IRQ7:
746      Offset = 0x2380;
747      break;
748    case PPC_IRQ_LVL7:
749      Offset = 0x23c0;
750      break;
751    case PPC_IRQ_CPM_RESERVED_0:
752      Offset = 0x2400;
753      break;
754    case PPC_IRQ_CPM_PC4:
755      Offset = 0x2410;
756      break;
757    case PPC_IRQ_CPM_PC5:
758      Offset = 0x2420;
759      break;
760    case PPC_IRQ_CPM_SMC2:
761      Offset = 0x2430;
762      break;
763    case PPC_IRQ_CPM_SMC1:
764      Offset = 0x2440;
765      break;
766    case PPC_IRQ_CPM_SPI:
767      Offset = 0x2450;
768      break;
769    case PPC_IRQ_CPM_PC6:
770      Offset = 0x2460;
771      break;
772    case PPC_IRQ_CPM_TIMER4:
773      Offset = 0x2470;
774      break;
775    case PPC_IRQ_CPM_RESERVED_8:
776      Offset = 0x2480;
777      break;
778    case PPC_IRQ_CPM_PC7:
779      Offset = 0x2490;
780      break;
781    case PPC_IRQ_CPM_PC8:
782      Offset = 0x24a0;
783      break;
784    case PPC_IRQ_CPM_PC9:
785      Offset = 0x24b0;
786      break;
787    case PPC_IRQ_CPM_TIMER3:
788      Offset = 0x24c0;
789      break;
790    case PPC_IRQ_CPM_RESERVED_D:
791      Offset = 0x24d0;
792      break;
793    case PPC_IRQ_CPM_PC10:
794      Offset = 0x24e0;
795      break;
796    case PPC_IRQ_CPM_PC11:
797      Offset = 0x24f0;
798      break;
799    case PPC_IRQ_CPM_I2C:
800      Offset = 0x2500;
801      break;
802    case PPC_IRQ_CPM_RISC_TIMER:
803      Offset = 0x2510;
804      break;
805    case PPC_IRQ_CPM_TIMER2:
806      Offset = 0x2520;
807      break;
808    case PPC_IRQ_CPM_RESERVED_13:
809      Offset = 0x2530;
810      break;
811    case PPC_IRQ_CPM_IDMA2:
812      Offset = 0x2540;
813      break;
814    case PPC_IRQ_CPM_IDMA1:
815      Offset = 0x2550;
816      break;
817    case PPC_IRQ_CPM_SDMA_ERROR:
818      Offset = 0x2560;
819      break;
820    case PPC_IRQ_CPM_PC12:
821      Offset = 0x2570;
822      break;
823    case PPC_IRQ_CPM_PC13:
824      Offset = 0x2580;
825      break;
826    case PPC_IRQ_CPM_TIMER1:
827      Offset = 0x2590;
828      break;
829    case PPC_IRQ_CPM_PC14:
830      Offset = 0x25a0;
831      break;
832    case PPC_IRQ_CPM_SCC4:
833      Offset = 0x25b0;
834      break;
835    case PPC_IRQ_CPM_SCC3:
836      Offset = 0x25c0;
837      break;
838    case PPC_IRQ_CPM_SCC2:
839      Offset = 0x25d0;
840      break;
841    case PPC_IRQ_CPM_SCC1:
842      Offset = 0x25e0;
843      break;
844    case PPC_IRQ_CPM_PC15:
845      Offset = 0x25f0;
846      break;
847#endif
848
849  }
850  Top += Offset;
851  return Top;
852}
853
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