xref: /titanic_51/usr/src/uts/sun4u/ml/mach_locore.s (revision 575a742678105d588b7c8e1653b57a7e3d78440b)
1/*
2 * CDDL HEADER START
3 *
4 * The contents of this file are subject to the terms of the
5 * Common Development and Distribution License (the "License").
6 * You may not use this file except in compliance with the License.
7 *
8 * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE
9 * or http://www.opensolaris.org/os/licensing.
10 * See the License for the specific language governing permissions
11 * and limitations under the License.
12 *
13 * When distributing Covered Code, include this CDDL HEADER in each
14 * file and include the License file at usr/src/OPENSOLARIS.LICENSE.
15 * If applicable, add the following below this CDDL HEADER, with the
16 * fields enclosed by brackets "[]" replaced with your own identifying
17 * information: Portions Copyright [yyyy] [name of copyright owner]
18 *
19 * CDDL HEADER END
20 */
21/*
22 * Copyright 2008 Sun Microsystems, Inc.  All rights reserved.
23 * Use is subject to license terms.
24 */
25
26#pragma ident	"%Z%%M%	%I%	%E% SMI"
27
28#if defined(lint)
29#include <sys/types.h>
30#include <sys/t_lock.h>
31#include <sys/promif.h>
32#include <sys/prom_isa.h>
33#endif	/* lint */
34
35#include <sys/asm_linkage.h>
36#include <sys/intreg.h>
37#include <sys/ivintr.h>
38#include <sys/mmu.h>
39#include <sys/machpcb.h>
40#include <sys/machtrap.h>
41#include <sys/machlock.h>
42#include <sys/fdreg.h>
43#include <sys/vis.h>
44#include <sys/traptrace.h>
45#include <sys/panic.h>
46#include <sys/machasi.h>
47#include <sys/clock.h>
48#include <vm/hat_sfmmu.h>
49#if defined(lint)
50
51#include <sys/thread.h>
52#include <sys/time.h>
53
54#else	/* lint */
55
56#include "assym.h"
57
58
59!
60! REGOFF must add up to allow double word access to r_tstate.
61! PCB_WBUF must also be aligned.
62!
63#if (REGOFF & 7) != 0
64#error "struct regs not aligned"
65#endif
66
67/*
68 * Absolute external symbols.
69 * On the sun4u we put the panic buffer in the third and fourth pages.
70 * We set things up so that the first 2 pages of KERNELBASE is illegal
71 * to act as a redzone during copyin/copyout type operations. One of
72 * the reasons the panic buffer is allocated in low memory to
73 * prevent being overwritten during booting operations (besides
74 * the fact that it is small enough to share pages with others).
75 */
76
77	.seg	".data"
78	.global	panicbuf
79
80PROM	= 0xFFE00000			! address of prom virtual area
81panicbuf = SYSBASE32 + PAGESIZE		! address of panic buffer
82
83	.type	panicbuf, #object
84	.size	panicbuf, PANICBUFSIZE
85
86/*
87 * Absolute external symbol - intr_vec_table.
88 *
89 * With new bus structures supporting a larger number of interrupt
90 * numbers, the interrupt vector table, intr_vec_table[] has been
91 * moved out of kernel nucleus and allocated after panicbuf.
92 */
93	.global intr_vec_table
94
95intr_vec_table = SYSBASE32 + PAGESIZE + PANICBUFSIZE ! address of interrupt table
96
97	.type	intr_vec_table, #object
98	.size	intr_vec_table, MAXIVNUM * CPTRSIZE + MAX_RSVD_IV * IV_SIZE + MAX_RSVD_IVX * (IV_SIZE + CPTRSIZE * (NCPU - 1))
99
100/*
101 * The thread 0 stack. This must be the first thing in the data
102 * segment (other than an sccs string) so that we don't stomp
103 * on anything important if the stack overflows. We get a
104 * red zone below this stack for free when the kernel text is
105 * write protected.
106 */
107
108	.global	t0stack
109	.align	16
110	.type	t0stack, #object
111t0stack:
112	.skip	T0STKSZ			! thread 0 stack
113t0stacktop:
114	.size	t0stack, T0STKSZ
115
116/*
117 * cpu0 and its ptl1_panic stack.  The cpu structure must be allocated
118 * on a single page for ptl1_panic's physical address accesses.
119 */
120	.global	cpu0
121	.align	MMU_PAGESIZE
122cpu0:
123	.type	cpu0, #object
124	.skip	CPU_ALLOC_SIZE
125	.size	cpu0, CPU_ALLOC_SIZE
126
127	.global t0
128	.align	PTR24_ALIGN		! alignment for mutex.
129	.type	t0, #object
130t0:
131	.skip	THREAD_SIZE		! thread 0
132	.size	t0, THREAD_SIZE
133
134#ifdef	TRAPTRACE
135	.global	trap_trace_ctl
136	.global	trap_tr0
137	.global trap_trace_bufsize
138	.global	trap_freeze
139	.global	trap_freeze_pc
140
141	.align	4
142trap_trace_bufsize:
143	.word	TRAP_TSIZE		! default trap buffer size
144trap_freeze:
145	.word	0
146
147	.align	64
148trap_trace_ctl:
149	.skip	NCPU * TRAPTR_SIZE	! NCPU control headers
150
151	.align	16
152trap_tr0:
153	.skip	TRAP_TSIZE		! one buffer for the boot cpu
154
155/*
156 * When an assertion in TRACE_PTR was failed, %pc is saved in trap_freeze_pc to
157 * show in which TRACE_PTR the assertion failure happened.
158 */
159	.align	8
160trap_freeze_pc:
161	.nword	0
162#endif	/* TRAPTRACE */
163
164	.align 4
165	.seg	".text"
166
167#ifdef	NOPROM
168	.global availmem
169availmem:
170	.word	0
171#endif	/* NOPROM */
172
173	.align	8
174_local_p1275cis:
175	.nword	0
176
177#endif	/* lint */
178
179#if defined(lint)
180
181void
182_start(void)
183{}
184
185#else /* lint */
186
187	.seg	".data"
188
189	.global nwindows, nwin_minus_one, winmask
190nwindows:
191	.word   8
192nwin_minus_one:
193	.word   7
194winmask:
195	.word	8
196
197	.global	afsrbuf
198afsrbuf:
199	.word	0,0,0,0
200
201/*
202 * System initialization
203 *
204 * Our contract with the boot prom specifies that the MMU is on and the
205 * first 16 meg of memory is mapped with a level-1 pte.  We are called
206 * with p1275cis ptr in %o0 and kdi_dvec in %o1; we start execution
207 * directly from physical memory, so we need to get up into our proper
208 * addresses quickly: all code before we do this must be position
209 * independent.
210 *
211 * NB: Above is not true for boot/stick kernel, the only thing mapped is
212 * the text+data+bss. The kernel is loaded directly into KERNELBASE.
213 *
214 * 	entry, the romvec pointer (romp) is the first argument;
215 * 	  i.e., %o0.
216 * 	the bootops vector is in the third argument (%o1)
217 *
218 * Our tasks are:
219 * 	save parameters
220 * 	construct mappings for KERNELBASE (not needed for boot/stick kernel)
221 * 	hop up into high memory           (not needed for boot/stick kernel)
222 * 	initialize stack pointer
223 * 	initialize trap base register
224 * 	initialize window invalid mask
225 * 	initialize psr (with traps enabled)
226 * 	figure out all the module type stuff
227 * 	tear down the 1-1 mappings
228 * 	dive into main()
229 */
230	ENTRY_NP(_start)
231	!
232	! Stash away our arguments in memory.
233	!
234	sethi	%hi(_local_p1275cis), %g1
235	stn	%o4, [%g1 + %lo(_local_p1275cis)]
236
237	!
238	! Initialize CPU state registers
239	!
240	wrpr	%g0, PSTATE_KERN, %pstate
241	wr	%g0, %g0, %fprs
242
243	!
244	! call krtld to link the world together
245	!
246	call	kobj_start
247	mov	%o4, %o0
248
249	CLEARTICKNPT			! allow user rdtick
250	!
251	! Get maxwin from %ver
252	!
253	rdpr	%ver, %g1
254	and	%g1, VER_MAXWIN, %g1
255
256	!
257	! Stuff some memory cells related to numbers of windows.
258	!
259	sethi	%hi(nwin_minus_one), %g2
260	st	%g1, [%g2 + %lo(nwin_minus_one)]
261	inc	%g1
262	sethi	%hi(nwindows), %g2
263	st	%g1, [%g2 + %lo(nwindows)]
264	dec	%g1
265	mov	-2, %g2
266	sll	%g2, %g1, %g2
267	sethi	%hi(winmask), %g4
268	st	%g2, [%g4 + %lo(winmask)]
269
270	!
271	! save a pointer to obp's tba for later use by kmdb
272	!
273	rdpr	%tba, %g1
274	set	boot_tba, %g2
275	stx	%g1, [%g2]
276
277	!
278	! copy obp's breakpoint trap entry to obp_bpt
279	!
280	rdpr	%tba, %g1
281	set	T_SOFTWARE_TRAP | ST_MON_BREAKPOINT, %g2
282	sll	%g2, 5, %g2
283	or	%g1, %g2, %g1
284	set	obp_bpt, %g2
285	ldx	[%g1], %g3
286	stx	%g3, [%g2]
287	flush	%g2
288	ldx	[%g1 + 8], %g3
289	stx	%g3, [%g2 + 8]
290	flush	%g2 + 8
291	ldx	[%g1 + 16], %g3
292	stx	%g3, [%g2 + 16]
293	flush	%g2 + 16
294	ldx	[%g1 + 24], %g3
295	stx	%g3, [%g2 + 24]
296	flush	%g2 + 24
297
298	!
299	! Initialize thread 0's stack.
300	!
301	set	t0stacktop, %g1		! setup kernel stack pointer
302	sub	%g1, SA(KFPUSIZE+GSR_SIZE), %g2
303	and	%g2, 0x3f, %g3
304	sub	%g2, %g3, %o1
305	sub	%o1, SA(MPCBSIZE) + STACK_BIAS, %sp
306
307	!
308	! Initialize global thread register.
309	!
310	set	t0, THREAD_REG
311
312	!
313	! Fill in enough of the cpu structure so that
314	! the wbuf management code works. Make sure the
315	! boot cpu is inserted in cpu[] based on cpuid.
316	!
317	CPU_INDEX(%g2, %g1)
318	sll	%g2, CPTRSHIFT, %g2		! convert cpuid to cpu[] offset
319	set	cpu0, %o0			! &cpu0
320	set	cpu, %g1			! &cpu[]
321	stn	%o0, [%g1 + %g2]		! cpu[cpuid] = &cpu0
322
323	stn	%o0, [THREAD_REG + T_CPU]	! threadp()->t_cpu = cpu[cpuid]
324	stn	THREAD_REG, [%o0 + CPU_THREAD]	! cpu[cpuid]->cpu_thread = threadp()
325
326
327	!  We do NOT need to bzero our BSS...boot has already done it for us.
328	!  Just need to reference edata so that we don't break /dev/ksyms
329	set	edata, %g0
330
331	!
332	! Call mlsetup with address of prototype user registers.
333	!
334	call	mlsetup
335	add	%sp, REGOFF + STACK_BIAS, %o0
336
337#if (REGOFF != MPCB_REGS)
338#error "hole in struct machpcb between frame and regs?"
339#endif
340
341	!
342	! Now call main.  We will return as process 1 (init).
343	!
344	call	main
345	nop
346
347	!
348	! Main should never return.
349	!
350	set	.mainretmsg, %o0
351	call	panic
352	nop
353	SET_SIZE(_start)
354
355.mainretmsg:
356	.asciz	"main returned"
357	.align	4
358
359#endif	/* lint */
360
361
362/*
363 * Generic system trap handler.
364 *
365 * Some kernel trap handlers save themselves from buying a window by
366 * borrowing some of sys_trap's unused locals. %l0 thru %l3 may be used
367 * for this purpose, as user_rtt and priv_rtt do not depend on them.
368 * %l4 thru %l7 should NOT be used this way.
369 *
370 * Entry Conditions:
371 * 	%pstate		am:0 priv:1 ie:0
372 * 			globals are either ag or ig (not mg!)
373 *
374 * Register Inputs:
375 * 	%g1		pc of trap handler
376 * 	%g2, %g3	args for handler
377 * 	%g4		desired %pil (-1 means current %pil)
378 * 	%g5, %g6	destroyed
379 * 	%g7		saved
380 *
381 * Register Usage:
382 * 	%l0, %l1	temps
383 * 	%l3		saved %g1
384 * 	%l6		curthread for user traps, %pil for priv traps
385 * 	%l7		regs
386 *
387 * Called function prototype variants:
388 *
389 *	func(struct regs *rp);
390 * 	func(struct regs *rp, uintptr_t arg1 [%g2], uintptr_t arg2 [%g3])
391 *	func(struct regs *rp, uintptr_t arg1 [%g2],
392 *	    uint32_t arg2 [%g3.l], uint32_t arg3 [%g3.h])
393 *	func(struct regs *rp, uint32_t arg1 [%g2.l],
394 *	    uint32_t arg2 [%g3.l], uint32_t arg3 [%g3.h], uint32_t [%g2.h])
395 */
396
397#if defined(lint)
398
399void
400sys_trap(void)
401{}
402
403#else	/* lint */
404
405	ENTRY_NP(sys_trap)
406	!
407	! force tl=1, update %cwp, branch to correct handler
408	!
409	wrpr	%g0, 1, %tl
410	rdpr	%tstate, %g5
411	btst	TSTATE_PRIV, %g5
412	and	%g5, TSTATE_CWP, %g6
413	bnz,pn	%xcc, priv_trap
414	wrpr	%g0, %g6, %cwp
415
416	ALTENTRY(user_trap)
417	!
418	! user trap
419	!
420	! make all windows clean for kernel
421	! buy a window using the current thread's stack
422	!
423	sethi	%hi(nwin_minus_one), %g5
424	ld	[%g5 + %lo(nwin_minus_one)], %g5
425	wrpr	%g0, %g5, %cleanwin
426	CPU_ADDR(%g5, %g6)
427	ldn	[%g5 + CPU_THREAD], %g5
428	ldn	[%g5 + T_STACK], %g6
429	sub	%g6, STACK_BIAS, %g6
430	save	%g6, 0, %sp
431	!
432	! set window registers so that current windows are "other" windows
433	!
434	rdpr	%canrestore, %l0
435	rdpr	%wstate, %l1
436	wrpr	%g0, 0, %canrestore
437	sllx	%l1, WSTATE_SHIFT, %l1
438	wrpr	%l1, WSTATE_K64, %wstate
439	wrpr	%g0, %l0, %otherwin
440	!
441	! set pcontext to run kernel
442	!
443	sethi	%hi(kcontextreg), %l0
444	ldx     [%l0 + %lo(kcontextreg)], %l0
445	mov	MMU_PCONTEXT, %l1	! if kcontextreg==PCONTEXT, do nothing
446	ldxa	[%l1]ASI_MMU_CTX, %l2
447	xor	%l0, %l2, %l2
448	srlx	%l2, CTXREG_NEXT_SHIFT, %l2
449	brz	%l2, 2f			! if N_pgsz0/1 changed, need demap
450	sethi	%hi(FLUSH_ADDR), %l3
451	mov	DEMAP_ALL_TYPE, %l2
452	stxa	%g0, [%l2]ASI_DTLB_DEMAP
453	stxa	%g0, [%l2]ASI_ITLB_DEMAP
4542:
455	stxa	%l0, [%l1]ASI_MMU_CTX
456	flush	%l3			! flush required by immu
4571:
458
459	set	utl0, %g6		! bounce to utl0
460have_win:
461	SYSTRAP_TRACE(%o1, %o2, %o3)
462
463
464	!
465	! at this point we have a new window we can play in,
466	! and %g6 is the label we want done to bounce to
467	!
468	! save needed current globals
469	!
470	mov	%g1, %l3	! pc
471	mov	%g2, %o1	! arg #1
472	mov	%g3, %o2	! arg #2
473	srlx	%g3, 32, %o3	! pseudo arg #3
474	srlx	%g2, 32, %o4	! pseudo arg #4
475	mov	%g5, %l6	! curthread if user trap, %pil if priv trap
476	!
477	! save trap state on stack
478	!
479	add	%sp, REGOFF + STACK_BIAS, %l7
480	rdpr	%tpc, %l0
481	rdpr	%tnpc, %l1
482	rdpr	%tstate, %l2
483	stn	%l0, [%l7 + PC_OFF]
484	stn	%l1, [%l7 + nPC_OFF]
485	stx	%l2, [%l7 + TSTATE_OFF]
486	!
487	! setup pil
488	!
489	brlz,pt		%g4, 1f
490	nop
491#ifdef DEBUG
492	!
493	! ASSERT(%g4 >= %pil).
494	!
495	rdpr	%pil, %l0
496	cmp	%g4, %l0
497	bge,pt	%xcc, 0f
498	nop				! yes, nop; to avoid anull
499	set	bad_g4_called, %l3
500	mov	1, %o1
501	st	%o1, [%l3]
502	set	bad_g4, %l3		! pc
503	set	sys_trap_wrong_pil, %o1	! arg #1
504	mov	%g4, %o2		! arg #2
505	ba	1f			! stay at the current %pil
506	mov	%l0, %o3		! arg #3
5070:
508#endif /* DEBUG */
509	wrpr		%g0, %g4, %pil
5101:
511	!
512	! set trap regs to execute in kernel at %g6
513	! done resumes execution there
514	!
515	wrpr	%g0, %g6, %tnpc
516	rdpr	%cwp, %l0
517	set	TSTATE_KERN, %l1
518	wrpr	%l1, %l0, %tstate
519	done
520	/* NOTREACHED */
521	SET_SIZE(user_trap)
522	SET_SIZE(sys_trap)
523
524
525	ENTRY_NP(prom_trap)
526	!
527	! prom trap switches the stack to 32-bit
528	! if we took a trap from a 64-bit window
529	! Then buys a window on the current stack.
530	!
531	save	%sp, -SA64(REGOFF + REGSIZE), %sp
532					/* 32 bit frame, 64 bit sized */
533	set	ptl0, %g6
534	ba,a,pt	%xcc, have_win
535	SET_SIZE(prom_trap)
536
537	ENTRY_NP(priv_trap)
538	!
539	! kernel trap
540	! buy a window on the current stack
541	!
542	! is the trap PC in the range allocated to Open Firmware?
543	rdpr	%tpc, %g5
544	set	OFW_END_ADDR, %g6
545	cmp	%g5, %g6
546	bgu,a,pn %xcc, 1f
547	  rdpr	%pil, %g5
548	set	OFW_START_ADDR, %g6
549	cmp	%g5, %g6
550	bgeu,pn	%xcc, prom_trap
551	  rdpr	%pil, %g5
5521:
553	!
554	! check if the primary context is of kernel.
555	!
556	mov     MMU_PCONTEXT, %g6
557	ldxa    [%g6]ASI_MMU_CTX, %g5
558	sllx    %g5, CTXREG_CTX_SHIFT, %g5      ! keep just the ctx bits
559	brnz,pn %g5, 2f				! assumes KCONTEXT == 0
560	  rdpr  %pil, %g5
561	!
562	! primary context is of kernel.
563	!
564        set     ktl0, %g6
565        save    %sp, -SA(REGOFF + REGSIZE), %sp
566        ba,a,pt %xcc, have_win
5672:
568	!
569	! primary context is of user. caller of sys_trap()
570	! or priv_trap() did not set kernel context. raise
571	! trap level to MAXTL-1 so that ptl1_panic() prints
572	! out all levels of trap data.
573	!
574	rdpr	%ver, %g5
575	srlx	%g5, VER_MAXTL_SHIFT, %g5
576	and	%g5, VER_MAXTL_MASK, %g5	! %g5 = MAXTL
577	sub	%g5, 1, %g5
578	wrpr	%g0, %g5, %tl
579	mov	PTL1_BAD_CTX, %g1
580	ba,a,pt	%xcc, ptl1_panic
581	SET_SIZE(priv_trap)
582
583	ENTRY_NP(utl0)
584	SAVE_GLOBALS(%l7)
585	SAVE_OUTS(%l7)
586	mov	%l6, THREAD_REG
587	wrpr	%g0, PSTATE_KERN, %pstate	! enable ints
588	jmpl	%l3, %o7			! call trap handler
589	mov	%l7, %o0
590	!
591	ALTENTRY(user_rtt)
592	!
593	! Register inputs
594	!	%l7 - regs
595	!
596	! disable interrupts and check for ASTs and wbuf restores
597	! keep cpu_base_spl in %l4 and THREAD_REG in %l6 (needed
598	! in wbuf.s when globals have already been restored).
599	!
600	wrpr	%g0, PIL_MAX, %pil
601	ldn	[THREAD_REG + T_CPU], %l0
602	ld	[%l0 + CPU_BASE_SPL], %l4
603
604	ldub	[THREAD_REG + T_ASTFLAG], %l2
605	brz,pt	%l2, 1f
606	ld	[%sp + STACK_BIAS + MPCB_WBCNT], %l3
607	!
608	! call trap to do ast processing
609	!
610	wrpr	%g0, %l4, %pil			! pil = cpu_base_spl
611	mov	%l7, %o0
612	call	trap
613	  mov	T_AST, %o2
614	ba,a,pt	%xcc, user_rtt
6151:
616	brz,pt	%l3, 2f
617	mov	THREAD_REG, %l6
618	!
619	! call restore_wbuf to push wbuf windows to stack
620	!
621	wrpr	%g0, %l4, %pil			! pil = cpu_base_spl
622	mov	%l7, %o0
623	call	trap
624	  mov	T_FLUSH_PCB, %o2
625	ba,a,pt	%xcc, user_rtt
6262:
627#ifdef TRAPTRACE
628	TRACE_RTT(TT_SYS_RTT_USER, %l0, %l1, %l2, %l3)
629#endif /* TRAPTRACE */
630	ld	[%sp + STACK_BIAS + MPCB_WSTATE], %l3	! get wstate
631
632	!
633	! restore user globals and outs
634	!
635	rdpr	%pstate, %l1
636	wrpr	%l1, PSTATE_IE, %pstate
637	RESTORE_GLOBALS(%l7)
638	! switch to alternate globals, saving THREAD_REG in %l6
639	wrpr	%l1, PSTATE_IE | PSTATE_AG, %pstate
640	mov	%sp, %g6	! remember the mpcb pointer in %g6
641	RESTORE_OUTS(%l7)
642	!
643	! set %pil from cpu_base_spl
644	!
645	wrpr	%g0, %l4, %pil
646	!
647	! raise tl (now using nucleus context)
648	!
649	wrpr	%g0, 1, %tl
650
651	! switch "other" windows back to "normal" windows.
652	rdpr	%otherwin, %g1
653	wrpr	%g0, 0, %otherwin
654	add	%l3, WSTATE_CLEAN_OFFSET, %l3	! convert to "clean" wstate
655	wrpr	%g0, %l3, %wstate
656	wrpr	%g0, %g1, %canrestore
657
658	! set pcontext to scontext for user execution
659	mov	MMU_SCONTEXT, %g3
660	ldxa	[%g3]ASI_MMU_CTX, %g2
661
662	mov	MMU_PCONTEXT, %g3
663	ldxa    [%g3]ASI_MMU_CTX, %g4		! need N_pgsz0/1 bits
664        srlx    %g4, CTXREG_NEXT_SHIFT, %g4
665        sllx    %g4, CTXREG_NEXT_SHIFT, %g4
666        or      %g4, %g2, %g2                   ! Or in Nuc pgsz bits
667
668	sethi	%hi(FLUSH_ADDR), %g4
669	stxa	%g2, [%g3]ASI_MMU_CTX
670	flush	%g4				! flush required by immu
671	!
672	! Within the code segment [rtt_ctx_start - rtt_ctx_end],
673	! PCONTEXT is set to run user code. If a trap happens in this
674	! window, and the trap needs to be handled at TL=0, the handler
675	! must make sure to set PCONTEXT to run kernel. A convenience
676	! macro, RESET_USER_RTT_REGS(scr1, scr2, label) is available to
677	! TL>1 handlers for this purpose.
678	!
679	! %g1 = %canrestore
680	! %l7 = regs
681	! %g6 = mpcb
682	!
683	.global	rtt_ctx_start
684rtt_ctx_start:
685	!
686	! setup trap regs
687	!
688	ldn	[%l7 + PC_OFF], %g3
689	ldn	[%l7 + nPC_OFF], %g2
690	ldx	[%l7 + TSTATE_OFF], %l0
691	andn	%l0, TSTATE_CWP, %g7
692	wrpr	%g3, %tpc
693	wrpr	%g2, %tnpc
694
695	!
696	! Restore to window we originally trapped in.
697	! First attempt to restore from the watchpoint saved register window
698	!
699	tst	%g1
700	bne,a	1f
701	  clrn	[%g6 + STACK_BIAS + MPCB_RSP0]
702	tst	%fp
703	be,a	1f
704	  clrn	[%g6 + STACK_BIAS + MPCB_RSP0]
705	! test for user return window in pcb
706	ldn	[%g6 + STACK_BIAS + MPCB_RSP0], %g1
707	cmp	%fp, %g1
708	bne	1f
709	  clrn	[%g6 + STACK_BIAS + MPCB_RSP0]
710	restored
711	restore
712	! restore from user return window
713	RESTORE_V9WINDOW(%g6 + STACK_BIAS + MPCB_RWIN0)
714	!
715	! Attempt to restore from the scond watchpoint saved register window
716	tst	%fp
717	be,a	2f
718	  clrn	[%g6 + STACK_BIAS + MPCB_RSP1]
719	ldn	[%g6 + STACK_BIAS + MPCB_RSP1], %g1
720	cmp	%fp, %g1
721	bne	2f
722	  clrn	[%g6 + STACK_BIAS + MPCB_RSP1]
723	restored
724	restore
725	RESTORE_V9WINDOW(%g6 + STACK_BIAS + MPCB_RWIN1)
726	save
727	b,a	2f
7281:
729	restore				! should not trap
7302:
731	!
732	! set %cleanwin to %canrestore
733	! set %tstate to the correct %cwp
734	! retry resumes user execution
735	!
736	rdpr	%canrestore, %g1
737	wrpr	%g0, %g1, %cleanwin
738	rdpr	%cwp, %g1
739	wrpr	%g1, %g7, %tstate
740	retry
741	.global	rtt_ctx_end
742rtt_ctx_end:
743	/* NOTREACHED */
744	SET_SIZE(user_rtt)
745	SET_SIZE(utl0)
746
747	ENTRY_NP(ptl0)
748	SAVE_GLOBALS(%l7)
749	SAVE_OUTS(%l7)
750	CPU_ADDR(%g5, %g6)
751	ldn	[%g5 + CPU_THREAD], THREAD_REG
752	wrpr	%g0, PSTATE_KERN, %pstate	! enable ints
753	jmpl	%l3, %o7			! call trap handler
754	mov	%l7, %o0
755	!
756	ALTENTRY(prom_rtt)
757#ifdef TRAPTRACE
758	TRACE_RTT(TT_SYS_RTT_PROM, %l0, %l1, %l2, %l3)
759#endif /* TRAPTRACE */
760	ba,pt	%xcc, common_rtt
761	mov	THREAD_REG, %l0
762	SET_SIZE(prom_rtt)
763	SET_SIZE(ptl0)
764
765	ENTRY_NP(ktl0)
766	SAVE_GLOBALS(%l7)
767	SAVE_OUTS(%l7)				! for the call bug workaround
768	wrpr	%g0, PSTATE_KERN, %pstate	! enable ints
769	jmpl	%l3, %o7			! call trap handler
770	mov	%l7, %o0
771	!
772	ALTENTRY(priv_rtt)
773#ifdef TRAPTRACE
774	TRACE_RTT(TT_SYS_RTT_PRIV, %l0, %l1, %l2, %l3)
775#endif /* TRAPTRACE */
776	!
777	! Register inputs
778	!	%l7 - regs
779	!	%l6 - trap %pil
780	!
781	! Check for a kernel preemption request
782	!
783	ldn	[THREAD_REG + T_CPU], %l0
784	ldub	[%l0 + CPU_KPRUNRUN], %l0
785	brz,pt	%l0, 1f
786	nop
787
788	!
789	! Attempt to preempt
790	!
791	ldstub	[THREAD_REG + T_PREEMPT_LK], %l0	! load preempt lock
792	brnz,pn	%l0, 1f			! can't call kpreempt if this thread is
793	nop				!   already in it...
794
795	call	kpreempt
796	mov	%l6, %o0		! pass original interrupt level
797
798	stub	%g0, [THREAD_REG + T_PREEMPT_LK]	! nuke the lock
799
800	rdpr	%pil, %o0		! compare old pil level
801	cmp	%l6, %o0		!   with current pil level
802	movg	%xcc, %o0, %l6		! if current is lower, drop old pil
8031:
804	!
805	! If we interrupted the mutex_owner_running() critical region we
806	! must reset the PC and nPC back to the beginning to prevent missed
807	! wakeups. See the comments in mutex_owner_running() for details.
808	!
809	ldn	[%l7 + PC_OFF], %l0
810	set	mutex_owner_running_critical_start, %l1
811	sub	%l0, %l1, %l0
812	cmp	%l0, mutex_owner_running_critical_size
813	bgeu,pt	%xcc, 2f
814	mov	THREAD_REG, %l0
815	stn	%l1, [%l7 + PC_OFF]	! restart mutex_owner_running()
816	add	%l1, 4, %l1
817	ba,pt	%xcc, common_rtt
818	stn	%l1, [%l7 + nPC_OFF]
819
8202:
821	!
822	! If we interrupted the mutex_exit() critical region we must reset
823	! the PC and nPC back to the beginning to prevent missed wakeups.
824	! See the comments in mutex_exit() for details.
825	!
826	ldn	[%l7 + PC_OFF], %l0
827	set	mutex_exit_critical_start, %l1
828	sub	%l0, %l1, %l0
829	cmp	%l0, mutex_exit_critical_size
830	bgeu,pt	%xcc, common_rtt
831	mov	THREAD_REG, %l0
832	stn	%l1, [%l7 + PC_OFF]	! restart mutex_exit()
833	add	%l1, 4, %l1
834	stn	%l1, [%l7 + nPC_OFF]
835
836common_rtt:
837	!
838	! restore globals and outs
839	!
840	rdpr	%pstate, %l1
841	wrpr	%l1, PSTATE_IE, %pstate
842	RESTORE_GLOBALS(%l7)
843	! switch to alternate globals
844	wrpr	%l1, PSTATE_IE | PSTATE_AG, %pstate
845	RESTORE_OUTS(%l7)
846	!
847	! set %pil from max(old pil, cpu_base_spl)
848	!
849	ldn	[%l0 + T_CPU], %l0
850	ld	[%l0 + CPU_BASE_SPL], %l0
851	cmp	%l6, %l0
852	movg	%xcc, %l6, %l0
853	wrpr	%g0, %l0, %pil
854	!
855	! raise tl
856	! setup trap regs
857	! restore to window we originally trapped in
858	!
859	wrpr	%g0, 1, %tl
860	ldn	[%l7 + PC_OFF], %g1
861	ldn	[%l7 + nPC_OFF], %g2
862	ldx	[%l7 + TSTATE_OFF], %l0
863	andn	%l0, TSTATE_CWP, %g7
864	wrpr	%g1, %tpc
865	wrpr	%g2, %tnpc
866	restore
867	!
868	! set %tstate to the correct %cwp
869	! retry resumes prom execution
870	!
871	rdpr	%cwp, %g1
872	wrpr	%g1, %g7, %tstate
873	retry
874	/* NOTREACHED */
875	SET_SIZE(priv_rtt)
876	SET_SIZE(ktl0)
877
878#endif	/* lint */
879
880#ifndef lint
881
882#ifdef DEBUG
883	.seg	".data"
884	.align	4
885
886	.global bad_g4_called
887bad_g4_called:
888	.word	0
889
890sys_trap_wrong_pil:
891	.asciz	"sys_trap: %g4(%d) is lower than %pil(%d)"
892	.align	4
893	.seg	".text"
894
895	ENTRY_NP(bad_g4)
896	mov	%o1, %o0
897	mov	%o2, %o1
898	call	panic
899	mov	%o3, %o2
900	SET_SIZE(bad_g4)
901#endif /* DEBUG */
902#endif /* lint */
903
904/*
905 * sys_tl1_panic can be called by traps at tl1 which
906 * really want to panic, but need the rearrangement of
907 * the args as provided by this wrapper routine.
908 */
909#if defined(lint)
910
911void
912sys_tl1_panic(void)
913{}
914
915#else	/* lint */
916	ENTRY_NP(sys_tl1_panic)
917	mov	%o1, %o0
918	mov	%o2, %o1
919	call	panic
920	mov	%o3, %o2
921	SET_SIZE(sys_tl1_panic)
922#endif /* lint */
923
924/*
925 * Turn on or off bits in the auxiliary i/o register.
926 *
927 * set_auxioreg(bit, flag)
928 *	int bit;		bit mask in aux i/o reg
929 *	int flag;		0 = off, otherwise on
930 *
931 * This is intrinsicly ugly but is used by the floppy driver.  It is also
932 * used to turn on/off the led.
933 */
934
935#if defined(lint)
936
937/* ARGSUSED */
938void
939set_auxioreg(int bit, int flag)
940{}
941
942#else	/* lint */
943
944	.seg	".data"
945	.align	4
946auxio_panic:
947	.asciz	"set_auxioreg: interrupts already disabled on entry"
948	.align	4
949	.seg	".text"
950
951	ENTRY_NP(set_auxioreg)
952	/*
953	 * o0 = bit mask
954	 * o1 = flag: 0 = off, otherwise on
955	 *
956	 * disable interrupts while updating auxioreg
957	 */
958	rdpr	%pstate, %o2
959#ifdef	DEBUG
960	andcc	%o2, PSTATE_IE, %g0	/* if interrupts already */
961	bnz,a,pt %icc, 1f		/* disabled, panic */
962	  nop
963	sethi	%hi(auxio_panic), %o0
964	call	panic
965	  or	%o0, %lo(auxio_panic), %o0
9661:
967#endif /* DEBUG */
968	wrpr	%o2, PSTATE_IE, %pstate		/* disable interrupts */
969	sethi	%hi(v_auxio_addr), %o3
970	ldn	[%o3 + %lo(v_auxio_addr)], %o4
971	ldub	[%o4], %g1			/* read aux i/o register */
972	tst	%o1
973	bnz,a	2f
974	 bset	%o0, %g1		/* on */
975	bclr	%o0, %g1		/* off */
9762:
977	or	%g1, AUX_MBO, %g1	/* Must Be Ones */
978	stb	%g1, [%o4]		/* write aux i/o register */
979	retl
980	 wrpr	%g0, %o2, %pstate	/* enable interrupt */
981	SET_SIZE(set_auxioreg)
982
983#endif /* lint */
984
985/*
986 * Flush all windows to memory, except for the one we entered in.
987 * We do this by doing NWINDOW-2 saves then the same number of restores.
988 * This leaves the WIM immediately before window entered in.
989 * This is used for context switching.
990 */
991
992#if defined(lint)
993
994void
995flush_windows(void)
996{}
997
998#else	/* lint */
999
1000	ENTRY_NP(flush_windows)
1001	retl
1002	flushw
1003	SET_SIZE(flush_windows)
1004
1005#endif	/* lint */
1006
1007#if defined(lint)
1008
1009void
1010debug_flush_windows(void)
1011{}
1012
1013#else	/* lint */
1014
1015	ENTRY_NP(debug_flush_windows)
1016	set	nwindows, %g1
1017	ld	[%g1], %g1
1018	mov	%g1, %g2
1019
10201:
1021	save	%sp, -WINDOWSIZE, %sp
1022	brnz	%g2, 1b
1023	dec	%g2
1024
1025	mov	%g1, %g2
10262:
1027	restore
1028	brnz	%g2, 2b
1029	dec	%g2
1030
1031	retl
1032	nop
1033
1034	SET_SIZE(debug_flush_windows)
1035
1036#endif	/* lint */
1037
1038/*
1039 * flush user windows to memory.
1040 */
1041
1042#if defined(lint)
1043
1044void
1045flush_user_windows(void)
1046{}
1047
1048#else	/* lint */
1049
1050	ENTRY_NP(flush_user_windows)
1051	rdpr	%otherwin, %g1
1052	brz	%g1, 3f
1053	clr	%g2
10541:
1055	save	%sp, -WINDOWSIZE, %sp
1056	rdpr	%otherwin, %g1
1057	brnz	%g1, 1b
1058	add	%g2, 1, %g2
10592:
1060	sub	%g2, 1, %g2		! restore back to orig window
1061	brnz	%g2, 2b
1062	restore
10633:
1064	retl
1065	nop
1066	SET_SIZE(flush_user_windows)
1067
1068#endif	/* lint */
1069
1070/*
1071 * Throw out any user windows in the register file.
1072 * Used by setregs (exec) to clean out old user.
1073 * Used by sigcleanup to remove extraneous windows when returning from a
1074 * signal.
1075 */
1076
1077#if defined(lint)
1078
1079void
1080trash_user_windows(void)
1081{}
1082
1083#else	/* lint */
1084
1085	ENTRY_NP(trash_user_windows)
1086	rdpr	%otherwin, %g1
1087	brz	%g1, 3f			! no user windows?
1088	ldn	[THREAD_REG + T_STACK], %g5
1089
1090	!
1091	! There are old user windows in the register file. We disable ints
1092	! and increment cansave so that we don't overflow on these windows.
1093	! Also, this sets up a nice underflow when first returning to the
1094	! new user.
1095	!
1096	rdpr	%pstate, %g2
1097	wrpr	%g2, PSTATE_IE, %pstate
1098	rdpr	%cansave, %g3
1099	rdpr	%otherwin, %g1		! re-read in case of interrupt
1100	add	%g3, %g1, %g3
1101	wrpr	%g0, 0, %otherwin
1102	wrpr	%g0, %g3, %cansave
1103	wrpr	%g0, %g2, %pstate
11043:
1105	retl
1106 	clr     [%g5 + MPCB_WBCNT]       ! zero window buffer cnt
1107	SET_SIZE(trash_user_windows)
1108
1109
1110#endif	/* lint */
1111
1112/*
1113 * Setup g7 via the CPU data structure.
1114 */
1115#if defined(lint)
1116
1117struct scb *
1118set_tbr(struct scb *s)
1119{ return (s); }
1120
1121#else	/* lint */
1122
1123	ENTRY_NP(set_tbr)
1124	retl
1125	ta	72		! no tbr, stop simulation
1126	SET_SIZE(set_tbr)
1127
1128#endif	/* lint */
1129
1130
1131#if defined(lint)
1132/*
1133 * These need to be defined somewhere to lint and there is no "hicore.s"...
1134 */
1135char etext[1], end[1];
1136#endif	/* lint*/
1137
1138#if defined (lint)
1139
1140/* ARGSUSED */
1141void
1142ptl1_panic(u_int reason)
1143{}
1144
1145#else /* lint */
1146
1147#define	PTL1_SAVE_WINDOW(RP)						\
1148	stxa	%l0, [RP + RW64_LOCAL + (0 * RW64_LOCAL_INCR)] %asi;	\
1149	stxa	%l1, [RP + RW64_LOCAL + (1 * RW64_LOCAL_INCR)] %asi;	\
1150	stxa	%l2, [RP + RW64_LOCAL + (2 * RW64_LOCAL_INCR)] %asi;	\
1151	stxa	%l3, [RP + RW64_LOCAL + (3 * RW64_LOCAL_INCR)] %asi;	\
1152	stxa	%l4, [RP + RW64_LOCAL + (4 * RW64_LOCAL_INCR)] %asi;	\
1153	stxa	%l5, [RP + RW64_LOCAL + (5 * RW64_LOCAL_INCR)] %asi;	\
1154	stxa	%l6, [RP + RW64_LOCAL + (6 * RW64_LOCAL_INCR)] %asi;	\
1155	stxa	%l7, [RP + RW64_LOCAL + (7 * RW64_LOCAL_INCR)] %asi;	\
1156	stxa	%i0, [RP + RW64_IN + (0 * RW64_IN_INCR)] %asi;		\
1157	stxa	%i1, [RP + RW64_IN + (1 * RW64_IN_INCR)] %asi;		\
1158	stxa	%i2, [RP + RW64_IN + (2 * RW64_IN_INCR)] %asi;		\
1159	stxa	%i3, [RP + RW64_IN + (3 * RW64_IN_INCR)] %asi;		\
1160	stxa	%i4, [RP + RW64_IN + (4 * RW64_IN_INCR)] %asi;		\
1161	stxa	%i5, [RP + RW64_IN + (5 * RW64_IN_INCR)] %asi;		\
1162	stxa	%i6, [RP + RW64_IN + (6 * RW64_IN_INCR)] %asi;		\
1163	stxa	%i7, [RP + RW64_IN + (7 * RW64_IN_INCR)] %asi
1164#define	PTL1_NEXT_WINDOW(scr)	\
1165	add	scr, RWIN64SIZE, scr
1166
1167#define	PTL1_RESET_RWINDOWS(scr)			\
1168	sethi	%hi(nwin_minus_one), scr;		\
1169	ld	[scr + %lo(nwin_minus_one)], scr;	\
1170	wrpr	scr, %cleanwin;				\
1171	dec	scr;					\
1172	wrpr	scr, %cansave;				\
1173	wrpr	%g0, %canrestore;			\
1174	wrpr	%g0, %otherwin
1175
1176#define	PTL1_DCACHE_LINE_SIZE	4	/* small enough for all CPUs */
1177
1178/*
1179 * ptl1_panic is called when the kernel detects that it is in an invalid state
1180 * and the trap level is greater than 0.  ptl1_panic is responsible to save the
1181 * current CPU state, to restore the CPU state to normal, and to call panic.
1182 * The CPU state must be saved reliably without causing traps.  ptl1_panic saves
1183 * it in the ptl1_state structure, which is a member of the machcpu structure.
1184 * In order to access the ptl1_state structure without causing traps, physical
1185 * addresses are used so that we can avoid MMU miss traps.  The restriction of
1186 * physical memory accesses is that the ptl1_state structure must be on a single
1187 * physical page.  This is because (1) a single physical address for each
1188 * ptl1_state structure is needed and (2) it simplifies physical address
1189 * calculation for each member of the structure.
1190 * ptl1_panic is a likely spot for stack overflows to wind up; thus, the current
1191 * stack may not be usable.  In order to call panic reliably in such a state,
1192 * each CPU needs a dedicated ptl1 panic stack.
1193 * CPU_ALLOC_SIZE, which is defined to be MMU_PAGESIZE, is used to allocate the
1194 * cpu structure and a ptl1 panic stack.  They are put together on the same page
1195 * for memory space efficiency.  The low address part is used for the cpu
1196 * structure, and the high address part is for a ptl1 panic stack.
1197 * The cpu_pa array holds the physical addresses of the allocated cpu structures,
1198 * as the cpu array holds their virtual addresses.
1199 *
1200 * %g1 reason to be called
1201 * %g2 broken
1202 * %g3 broken
1203 */
1204	ENTRY_NP(ptl1_panic)
1205	!
1206	! flush D$ first, so that stale data will not be accessed later.
1207	! Data written via ASI_MEM bypasses D$.  If D$ contains data at the same
1208	! address, where data was written via ASI_MEM, a load from that address
1209	! using a virtual address and the default ASI still takes the old data.
1210	! Flushing D$ erases old data in D$, so that it will not be loaded.
1211	! Since we can afford only 2 registers (%g2 and %g3) for this job, we
1212	! flush entire D$.
1213	! For FJ OPL processors (IMPL values < SPITFIRE_IMPL), DC flushing
1214	! is not needed.
1215	!
1216	GET_CPU_IMPL(%g2)
1217	cmp	%g2, SPITFIRE_IMPL
1218	blt,pn	%icc, 1f		! Skip flushing for OPL processors
1219	 nop
1220	sethi	%hi(dcache_size), %g2
1221	ld	[%g2 + %lo(dcache_size)], %g2
1222	sethi	%hi(dcache_linesize), %g3
1223	ld	[%g3 + %lo(dcache_linesize)], %g3
1224	sub	%g2, %g3, %g2
12250:	stxa	%g0, [%g2] ASI_DC_TAG
1226	membar	#Sync
1227	brnz,pt	%g2, 0b
1228	  sub	%g2, %g3, %g2
12291:
1230	!
1231	! increment the entry counter.
1232	! save CPU state if this is the first entry.
1233	!
1234	CPU_PADDR(%g2, %g3);
1235	add	%g2, CPU_PTL1, %g2		! pstate = &CPU->mcpu.ptl1_state
1236	wr	%g0, ASI_MEM, %asi		! physical address access
1237	!
1238	! pstate->ptl1_entry_count++
1239	!
1240	lduwa	[%g2 + PTL1_ENTRY_COUNT] %asi, %g3
1241	add	%g3, 1, %g3
1242	stuwa	%g3, [%g2 + PTL1_ENTRY_COUNT] %asi
1243	!
1244	! CPU state saving is skipped from the 2nd entry to ptl1_panic since we
1245	! do not want to clobber the state from the original failure.  panic()
1246	! is responsible for handling multiple or recursive panics.
1247	!
1248	cmp	%g3, 2				! if (ptl1_entry_count >= 2)
1249	bge,pn	%icc, state_saved		!	goto state_saved
1250	  add	%g2, PTL1_REGS, %g3		! %g3 = &pstate->ptl1_regs[0]
1251	!
1252	! save CPU state
1253	!
1254save_cpu_state:
1255	! save current global registers
1256	! so that all them become available for use
1257	!
1258	stxa	%g1, [%g3 + PTL1_G1] %asi
1259	stxa	%g2, [%g3 + PTL1_G2] %asi
1260	stxa	%g3, [%g3 + PTL1_G3] %asi
1261	stxa	%g4, [%g3 + PTL1_G4] %asi
1262	stxa	%g5, [%g3 + PTL1_G5] %asi
1263	stxa	%g6, [%g3 + PTL1_G6] %asi
1264	stxa	%g7, [%g3 + PTL1_G7] %asi
1265	!
1266	! %tl, %tt, %tstate, %tpc, %tnpc for each TL
1267	!
1268	rdpr	%tl, %g1
1269	brz	%g1, 1f				! if(trap_level == 0) -------+
1270	add	%g3, PTL1_TRAP_REGS, %g4	! %g4 = &ptl1_trap_regs[0];  !
12710:						! -----------<----------+    !
1272	stwa	%g1, [%g4 + PTL1_TL] %asi				!    !
1273	rdpr	%tt, %g5						!    !
1274	stwa	%g5, [%g4 + PTL1_TT] %asi				!    !
1275	rdpr	%tstate, %g5						!    !
1276	stxa	%g5, [%g4 + PTL1_TSTATE] %asi				!    !
1277	rdpr	%tpc, %g5						!    !
1278	stxa	%g5, [%g4 + PTL1_TPC] %asi				!    !
1279	rdpr	%tnpc, %g5						!    !
1280	stxa	%g5, [%g4 + PTL1_TNPC] %asi				!    !
1281	add	%g4, PTL1_TRAP_REGS_INCR, %g4				!    !
1282	deccc	%g1							!    !
1283	bnz,a,pt %icc, 0b			! if(trap_level != 0) --+    !
1284	  wrpr	%g1, %tl						     !
12851:						! ----------<----------------+
1286	!
1287	! %pstate, %pil, SOFTINT, (S)TICK
1288	! Pending interrupts is also cleared in order to avoid a recursive call
1289	! to ptl1_panic in case the interrupt handler causes a panic.
1290	!
1291	rdpr	%pil, %g1
1292	stba	%g1, [%g3 + PTL1_PIL] %asi
1293	rdpr	%pstate, %g1
1294	stha	%g1, [%g3 + PTL1_PSTATE] %asi
1295	rd	SOFTINT, %g1
1296	sta	%g1, [%g3 + PTL1_SOFTINT] %asi
1297	wr	%g1, CLEAR_SOFTINT
1298	sethi   %hi(traptrace_use_stick), %g1
1299	ld      [%g1 + %lo(traptrace_use_stick)], %g1
1300	brz,a,pn %g1, 2f
1301	  rdpr	%tick, %g1
1302	rd	STICK, %g1
13032:	stxa	%g1, [%g3 + PTL1_TICK] %asi
1304
1305	!
1306	! MMU registers because ptl1_panic may be called from
1307	! the MMU trap handlers.
1308	!
1309	mov     MMU_SFAR, %g1
1310	ldxa    [%g1]ASI_DMMU, %g4
1311	stxa	%g4, [%g3 + PTL1_DMMU_SFAR]%asi
1312	mov     MMU_SFSR, %g1
1313	ldxa    [%g1]ASI_DMMU, %g4
1314	stxa	%g4, [%g3 + PTL1_DMMU_SFSR]%asi
1315	ldxa    [%g1]ASI_IMMU, %g4
1316	stxa	%g4, [%g3 + PTL1_IMMU_SFSR]%asi
1317	mov     MMU_TAG_ACCESS, %g1
1318	ldxa    [%g1]ASI_DMMU, %g4
1319	stxa	%g4, [%g3 + PTL1_DMMU_TAG_ACCESS]%asi
1320	ldxa    [%g1]ASI_IMMU, %g4
1321	stxa	%g4, [%g3 + PTL1_IMMU_TAG_ACCESS]%asi
1322
1323	!
1324	! Save register window state and register windows.
1325	!
1326	rdpr	%cwp, %g1
1327	stba	%g1, [%g3 + PTL1_CWP] %asi
1328	rdpr	%wstate, %g1
1329	stba	%g1, [%g3 + PTL1_WSTATE] %asi
1330	rdpr	%otherwin, %g1
1331	stba	%g1, [%g3 + PTL1_OTHERWIN] %asi
1332	rdpr	%cleanwin, %g1
1333	stba	%g1, [%g3 + PTL1_CLEANWIN] %asi
1334	rdpr	%cansave, %g1
1335	stba	%g1, [%g3 + PTL1_CANSAVE] %asi
1336	rdpr	%canrestore, %g1
1337	stba	%g1, [%g3 + PTL1_CANRESTORE] %asi
1338
1339	PTL1_RESET_RWINDOWS(%g1)
1340	clr	%g1
1341	wrpr	%g1, %cwp
1342	add	%g3, PTL1_RWINDOW, %g4		! %g4 = &ptl1_rwindow[0];
1343
13443:	PTL1_SAVE_WINDOW(%g4)	! <-------------+
1345	inc	%g1				!
1346	cmp	%g1, MAXWIN			!
1347	bgeu,pn	%icc, 5f			!
1348	wrpr	%g1, %cwp			!
1349	rdpr	%cwp, %g2			!
1350	cmp	%g1, %g2			! saturation check
1351	be,pt	%icc, 3b			!
1352	  PTL1_NEXT_WINDOW(%g4)		! ------+
13535:
1354	!
1355	! most crucial CPU state was saved.
1356	! Proceed to go back to TL = 0.
1357	!
1358state_saved:
1359	wrpr	%g0, 1, %tl
1360	wrpr	%g0, PIL_MAX, %pil
1361	!
1362	PTL1_RESET_RWINDOWS(%g1)
1363	wrpr	%g0, %cwp
1364	wrpr	%g0, %cleanwin
1365	wrpr	%g0, WSTATE_KERN, %wstate
1366	!
1367	! Set pcontext to run kernel.
1368	!
1369	! For OPL, load kcontexreg instead of clearing primary
1370	! context register.  This is to avoid changing nucleus page
1371	! size bits after boot initialization.
1372	!
1373#ifdef _OPL
1374	sethi	%hi(kcontextreg), %g4
1375	ldx	[%g4 + %lo(kcontextreg)], %g4
1376#endif /* _OPL */
1377
1378	set	DEMAP_ALL_TYPE, %g1
1379	sethi	%hi(FLUSH_ADDR), %g3
1380	set	MMU_PCONTEXT, %g2
1381
1382	stxa	%g0, [%g1]ASI_DTLB_DEMAP
1383	stxa	%g0, [%g1]ASI_ITLB_DEMAP
1384
1385#ifdef _OPL
1386	stxa	%g4, [%g2]ASI_MMU_CTX
1387#else /* _OPL */
1388	stxa	%g0, [%g2]ASI_MMU_CTX
1389#endif /* _OPL */
1390
1391	flush	%g3
1392
1393	rdpr	%cwp, %g1
1394	set	TSTATE_KERN, %g3
1395	wrpr	%g3, %g1, %tstate
1396	set	ptl1_panic_tl0, %g3
1397	wrpr	%g0, %g3, %tnpc
1398	done					! go to -->-+	TL:1
1399							    !
1400ptl1_panic_tl0:					! ----<-----+	TL:0
1401	CPU_ADDR(%l0, %l1)			! %l0 = cpu[cpuid]
1402	add	%l0, CPU_PTL1, %l1		! %l1 = &CPU->mcpu.ptl1_state
1403	!
1404	! prepare to call panic()
1405	!
1406	ldn	[%l0 + CPU_THREAD], THREAD_REG	! restore %g7
1407	ldn	[%l1 + PTL1_STKTOP], %l2	! %sp = ptl1_stktop
1408	sub	%l2, SA(MINFRAME) + STACK_BIAS, %sp
1409	clr	%fp				! no frame below this window
1410	clr	%i7
1411	!
1412	! enable limited interrupts
1413	!
1414	wrpr	%g0, CLOCK_LEVEL, %pil
1415	wrpr	%g0, PSTATE_KERN, %pstate
1416	!
1417	ba,pt	%xcc, ptl1_panic_handler
1418	  mov	%l1, %o0
1419	/*NOTREACHED*/
1420	SET_SIZE(ptl1_panic)
1421#endif /* lint */
1422
1423#ifdef	PTL1_PANIC_DEBUG
1424#if defined (lint)
1425/*
1426 * ptl1_recurse() calls itself a number of times to either set up a known
1427 * stack or to cause a kernel stack overflow. It decrements the arguments
1428 * on each recursion.
1429 * It's called by #ifdef PTL1_PANIC_DEBUG code in startup.c to set the
1430 * registers to a known state to facilitate debugging.
1431 */
1432
1433/* ARGSUSED */
1434void
1435ptl1_recurse(int count_threshold, int trap_threshold)
1436{}
1437
1438#else /* lint */
1439
1440	ENTRY_NP(ptl1_recurse)
1441	save    %sp, -SA(MINFRAME), %sp
1442
1443	set 	ptl1_recurse_call, %o7
1444	cmp	%o7, %i7			! if ptl1_recurse is called
1445	be,pt  %icc, 0f				! by itself, then skip
1446	  nop					! register initialization
1447
1448	/*
1449	 * Initialize Out Registers to Known Values
1450	 */
1451	set	0x01000, %l0			! %i0 is the ...
1452						! recursion_depth_count
1453	sub	%i0, 1, %o0;
1454	sub 	%i1, 1, %o1;
1455	add	%l0, %o0, %o2;
1456	add	%l0, %o2, %o3;
1457	add	%l0, %o3, %o4;
1458	add	%l0, %o4, %o5;
1459	ba,a	1f
1460	  nop
1461
14620:	/* Outs = Ins - 1 */
1463	sub	%i0, 1, %o0;
1464	sub	%i1, 1, %o1;
1465	sub	%i2, 1, %o2;
1466	sub	%i3, 1, %o3;
1467	sub	%i4, 1, %o4;
1468	sub	%i5, 1, %o5;
1469
1470	/* Locals = Ins + 1 */
14711:	add	%i0, 1, %l0;
1472	add	%i1, 1, %l1;
1473	add	%i2, 1, %l2;
1474	add	%i3, 1, %l3;
1475	add	%i4, 1, %l4;
1476	add	%i5, 1, %l5;
1477
1478	set     0x0100000, %g5
1479	add	%g5, %g0, %g1
1480	add	%g5, %g1, %g2
1481	add	%g5, %g2, %g3
1482	add	%g5, %g3, %g4
1483	add	%g5, %g4, %g5
1484
1485	brz,pn %i1, ptl1_recurse_trap		! if trpp_count == 0) {
1486	  nop					!    trap to ptl1_panic
1487						!
1488	brz,pn %i0, ptl1_recure_exit		! if(depth_count == 0) {
1489	  nop					!    skip recursive call
1490						! }
1491ptl1_recurse_call:
1492	call	ptl1_recurse
1493	  nop
1494
1495ptl1_recure_exit:
1496	ret
1497	restore
1498
1499ptl1_recurse_trap:
1500	ta	PTL1_DEBUG_TRAP; 		! Trap Always to ptl1_panic()
1501	  nop 					! NOTREACHED
1502        SET_SIZE(ptl1_recurse)
1503
1504#endif /* lint */
1505
1506#if defined (lint)
1507
1508/* ARGSUSED */
1509void
1510ptl1_panic_xt(int arg1, int arg2)
1511{}
1512
1513#else /* lint */
1514	/*
1515	 * Asm function to handle a cross trap to call ptl1_panic()
1516	 */
1517	ENTRY_NP(ptl1_panic_xt)
1518	ba	ptl1_panic
1519	  mov	PTL1_BAD_DEBUG, %g1
1520        SET_SIZE(ptl1_panic_xt)
1521
1522#endif /* lint */
1523
1524#endif	/* PTL1_PANIC_DEBUG */
1525
1526#ifdef	TRAPTRACE
1527#if	defined (lint)
1528
1529void
1530trace_ptr_panic(void)
1531{
1532}
1533
1534#else	/* lint */
1535
1536	ENTRY_NP(trace_ptr_panic)
1537	!
1538	! freeze the trap trace to disable the assertions.  Otherwise,
1539	! ptl1_panic is likely to be repeatedly called from there.
1540	! %g2 and %g3 are used as scratch registers in ptl1_panic.
1541	!
1542	mov	1, %g3
1543	sethi	%hi(trap_freeze), %g2
1544	st	%g3, [%g2 + %lo(trap_freeze)]
1545	!
1546	! %g1 contains the %pc address where an assertion was failed.
1547	! save it in trap_freeze_pc for a debugging hint if there is
1548	! no value saved in it.
1549	!
1550	set	trap_freeze_pc, %g2
1551	casn	[%g2], %g0, %g1
1552
1553	ba	ptl1_panic
1554	mov	PTL1_BAD_TRACE_PTR, %g1
1555	SET_SIZE(trace_ptr_panic)
1556
1557#endif	/* lint */
1558#endif	/* TRAPTRACE */
1559
1560#if	defined (lint)
1561/*
1562 * set_kcontextreg() sets PCONTEXT to kctx
1563 * if PCONTEXT==kctx, do nothing
1564 * if N_pgsz0|N_pgsz1 differ, do demap all first
1565 */
1566
1567/* ARGSUSED */
1568void
1569set_kcontextreg()
1570{
1571}
1572
1573#else	/* lint */
1574
1575        ENTRY_NP(set_kcontextreg)
1576	! SET_KCONTEXTREG(reg0, reg1, reg2, reg3, reg4, label1, label2, label3)
1577	SET_KCONTEXTREG(%o0, %o1, %o2, %o3, %o4, l1, l2, l3)
1578	retl
1579        nop
1580	SET_SIZE(set_kcontextreg)
1581
1582#endif /* lint */
1583
1584
1585/*
1586 * The interface for a 32-bit client program that takes over the TBA
1587 * calling the 64-bit romvec OBP.
1588 */
1589
1590#if defined(lint)
1591
1592/* ARGSUSED */
1593int
1594client_handler(void *cif_handler, void *arg_array)
1595{ return 0; }
1596
1597#else	/* lint */
1598
1599	ENTRY(client_handler)
1600	save	%sp, -SA64(MINFRAME64), %sp	! 32 bit frame, 64 bit sized
1601	sethi	%hi(tba_taken_over), %l2
1602	ld	[%l2+%lo(tba_taken_over)], %l3
1603	brz	%l3, 1f				! is the tba_taken_over = 1 ?
1604	rdpr	%wstate, %l5			! save %wstate
1605	andn	%l5, WSTATE_MASK, %l6
1606	wrpr	%l6, WSTATE_KMIX, %wstate
1607
1608	!
1609	! switch to PCONTEXT=0
1610	!
1611#ifndef _OPL
1612	mov	MMU_PCONTEXT, %o2
1613	ldxa	[%o2]ASI_DMMU, %o2
1614	srlx	%o2, CTXREG_NEXT_SHIFT, %o2
1615	brz,pt	%o2, 1f				! nucleus pgsz is 0, no problem
1616	  nop
1617	rdpr	%pstate, %l4			! disable interrupts
1618	andn	%l4, PSTATE_IE, %o2
1619	wrpr	%g0, %o2, %pstate
1620	mov	DEMAP_ALL_TYPE, %o2		! set PCONTEXT=0
1621	stxa	%g0, [%o2]ASI_DTLB_DEMAP
1622	stxa	%g0, [%o2]ASI_ITLB_DEMAP
1623	mov	MMU_PCONTEXT, %o2
1624	stxa	%g0, [%o2]ASI_DMMU
1625        membar  #Sync
1626	sethi	%hi(FLUSH_ADDR), %o2
1627	flush	%o2				! flush required by immu
1628	wrpr	%g0, %l4, %pstate		! restore interrupt state
1629#endif /* _OPL */
1630
16311:	mov	%i1, %o0
1632	rdpr	%pstate, %l4			! Get the present pstate value
1633	andn	%l4, PSTATE_AM, %l6
1634	wrpr	%l6, 0, %pstate			! Set PSTATE_AM = 0
1635	jmpl	%i0, %o7			! Call cif handler
1636	nop
1637	wrpr	%l4, 0, %pstate			! restore pstate
1638	brz	%l3, 1f				! is the tba_taken_over = 1
1639	  nop
1640	wrpr	%g0, %l5, %wstate		! restore wstate
1641
1642	!
1643	! switch to PCONTEXT=kcontexreg
1644	!
1645#ifndef _OPL
1646	sethi	%hi(kcontextreg), %o3
1647	ldx     [%o3 + %lo(kcontextreg)], %o3
1648	brz	%o3, 1f
1649	  nop
1650	rdpr	%pstate, %l4			! disable interrupts
1651	andn	%l4, PSTATE_IE, %o2
1652	wrpr	%g0, %o2, %pstate
1653	mov	DEMAP_ALL_TYPE, %o2
1654	stxa	%g0, [%o2]ASI_DTLB_DEMAP
1655	stxa	%g0, [%o2]ASI_ITLB_DEMAP
1656	mov	MMU_PCONTEXT, %o2
1657	stxa	%o3, [%o2]ASI_DMMU
1658        membar  #Sync
1659	sethi	%hi(FLUSH_ADDR), %o2
1660	flush	%o2				! flush required by immu
1661	wrpr	%g0, %l4, %pstate		! restore interrupt state
1662#endif /* _OPL */
1663
16641:	ret					! Return result ...
1665	restore	%o0, %g0, %o0			! delay; result in %o0
1666	SET_SIZE(client_handler)
1667
1668#endif	/* lint */
1669
1670