xref: /titanic_50/usr/src/uts/intel/kdi/ia32/kdi_asm.s (revision ead1f93ee620d7580f7e53350fe5a884fc4f158a)
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/*
23 * Copyright 2007 Sun Microsystems, Inc.  All rights reserved.
24 * Use is subject to license terms.
25 */
26
27#pragma ident	"%Z%%M%	%I%	%E% SMI"
28
29/*
30 * Debugger entry for both master and slave CPUs
31 */
32
33#if defined(__lint)
34#include <sys/types.h>
35#endif
36
37#include <sys/segments.h>
38#include <sys/asm_linkage.h>
39#include <sys/controlregs.h>
40#include <sys/x86_archext.h>
41#include <sys/privregs.h>
42#include <sys/machprivregs.h>
43#include <sys/kdi_regs.h>
44#include <sys/uadmin.h>
45#include <sys/psw.h>
46
47#ifdef _ASM
48
49#include <kdi_assym.h>
50#include <assym.h>
51
52/* clobbers %edx, %ecx, returns addr in %eax, cpu id in %ebx */
53#define	GET_CPUSAVE_ADDR \
54	movl	%gs:CPU_ID, %ebx;		\
55	movl	%ebx, %eax;			\
56	movl	$KRS_SIZE, %ecx;		\
57	mull	%ecx;				\
58	movl	$kdi_cpusave, %edx;		\
59	/*CSTYLED*/				\
60	addl	(%edx), %eax
61
62/*
63 * Save copies of the IDT and GDT descriptors.  Note that we only save the IDT
64 * and GDT if the IDT isn't ours, as we may be legitimately re-entering the
65 * debugger through the trap handler.  We don't want to clobber the saved IDT
66 * in the process, as we'd end up resuming the world on our IDT.
67 */
68#define	SAVE_IDTGDT				\
69	movl	%gs:CPU_IDT, %edx;		\
70	cmpl	$kdi_idt, %edx;			\
71	je	1f;				\
72	movl	%edx, KRS_IDT(%eax);		\
73	movl	%gs:CPU_GDT, %edx;		\
74	movl	%edx, KRS_GDT(%eax);		\
751:
76
77/*
78 * Given the address of the current CPU's cpusave area in %edi, the following
79 * macro restores the debugging state to said CPU.  Restored state includes
80 * the debug registers from the global %dr variables, and debugging MSRs from
81 * the CPU save area.  This code would be in a separate routine, but for the
82 * fact that some of the MSRs are jump-sensitive.  As such, we need to minimize
83 * the number of jumps taken subsequent to the update of said MSRs.  We can
84 * remove one jump (the ret) by using a macro instead of a function for the
85 * debugging state restoration code.
86 *
87 * Takes the cpusave area in %edi as a parameter, clobbers %eax-%edx
88 */
89#define	KDI_RESTORE_DEBUGGING_STATE \
90	leal	kdi_drreg, %ebx;				\
91								\
92	pushl	DR_CTL(%ebx);					\
93	pushl	$7;						\
94	call	kdi_dreg_set;					\
95	addl	$8, %esp;					\
96								\
97	pushl	$KDIREG_DRSTAT_RESERVED;				\
98	pushl	$6;						\
99	call	kdi_dreg_set;					\
100	addl	$8, %esp;					\
101								\
102	pushl	DRADDR_OFF(0)(%ebx);				\
103	pushl	$0;						\
104	call	kdi_dreg_set;					\
105	addl	$8, %esp;					\
106								\
107	pushl	DRADDR_OFF(1)(%ebx);				\
108	pushl	$1;						\
109	call	kdi_dreg_set;			 		\
110	addl	$8, %esp;					\
111								\
112	pushl	DRADDR_OFF(2)(%ebx);				\
113	pushl	$2;						\
114	call	kdi_dreg_set;					\
115	addl	$8, %esp;					\
116								\
117	pushl	DRADDR_OFF(3)(%ebx);				\
118	pushl	$3;						\
119	call	kdi_dreg_set;					\
120	addl	$8, %esp;					\
121								\
122	/*							\
123	 * Write any requested MSRs.				\
124	 */							\
125	movl	KRS_MSR(%edi), %ebx;				\
126	cmpl	$0, %ebx;					\
127	je	3f;						\
1281:								\
129	movl	MSR_NUM(%ebx), %ecx;				\
130	cmpl	$0, %ecx;					\
131	je	3f;						\
132								\
133	movl	MSR_TYPE(%ebx), %edx;				\
134	cmpl	$KDI_MSR_WRITE, %edx;				\
135	jne	2f;						\
136								\
137	movl	MSR_VALP(%ebx), %edx;				\
138	movl	0(%edx), %eax;					\
139	movl	4(%edx), %edx;					\
140	wrmsr;							\
1412:								\
142	addl	$MSR_SIZE, %ebx;				\
143	jmp	1b;						\
1443:								\
145	/*							\
146	 * We must not branch after re-enabling LBR.  If	\
147	 * kdi_wsr_wrexit_msr is set, it contains the number	\
148	 * of the MSR that controls LBR.  kdi_wsr_wrexit_valp	\
149	 * contains the value that is to be written to enable	\
150	 * LBR.							\
151	 */							\
152	movl	kdi_msr_wrexit_msr, %ecx;			\
153	cmpl	$0, %ecx;					\
154	je	1f;						\
155								\
156	movl	kdi_msr_wrexit_valp, %edx;			\
157	movl	0(%edx), %eax;					\
158	movl	4(%edx), %edx;					\
159								\
160	wrmsr;							\
1611:
162
163#define	KDI_RESTORE_REGS() \
164	/* Discard savfp and savpc */ \
165	addl	$8, %esp; \
166	popl	%ss; \
167	popl	%gs; \
168	popl	%fs; \
169	popl	%es; \
170	popl	%ds; \
171	popal; \
172	/* Discard trapno and err */ \
173	addl	$8, %esp
174
175/*
176 * Each cpusave buffer has an area set aside for a ring buffer of breadcrumbs.
177 * The following macros manage the buffer.
178 */
179
180/* Advance the ring buffer */
181#define	ADVANCE_CRUMB_POINTER(cpusave, tmp1, tmp2) \
182	movl	KRS_CURCRUMBIDX(cpusave), tmp1;	\
183	cmpl	$[KDI_NCRUMBS - 1], tmp1;	\
184	jge	1f;				\
185	/* Advance the pointer and index */	\
186	addl	$1, tmp1;			\
187	movl	tmp1, KRS_CURCRUMBIDX(cpusave);	\
188	movl	KRS_CURCRUMB(cpusave), tmp1;	\
189	addl	$KRM_SIZE, tmp1;		\
190	jmp	2f;				\
1911:	/* Reset the pointer and index */	\
192	movw	$0, KRS_CURCRUMBIDX(cpusave);	\
193	leal	KRS_CRUMBS(cpusave), tmp1;	\
1942:	movl	tmp1, KRS_CURCRUMB(cpusave);	\
195	/* Clear the new crumb */		\
196	movl	$KDI_NCRUMBS, tmp2;		\
1973:	movl	$0, -4(tmp1, tmp2, 4);		\
198	decl	tmp2;				\
199	jnz	3b
200
201/* Set a value in the current breadcrumb buffer */
202#define	ADD_CRUMB(cpusave, offset, value, tmp) \
203	movl	KRS_CURCRUMB(cpusave), tmp;	\
204	movl	value, offset(tmp)
205
206#endif	/* _ASM */
207
208/*
209 * The main entry point for master CPUs.  It also serves as the trap handler
210 * for all traps and interrupts taken during single-step.
211 */
212#if defined(__lint)
213void
214kdi_cmnint(void)
215{
216}
217#else	/* __lint */
218
219 	/* XXX implement me */
220	ENTRY_NP(kdi_nmiint)
221	clr	%ecx
222	movl	(%ecx), %ecx
223	SET_SIZE(kdi_nmiint)
224
225	ENTRY_NP(kdi_cmnint)
226	ALTENTRY(kdi_master_entry)
227
228	/* Save all registers and selectors */
229
230	pushal
231	pushl	%ds
232	pushl	%es
233	pushl	%fs
234	pushl	%gs
235	pushl	%ss
236
237	subl	$8, %esp
238	movl	%ebp, REG_OFF(KDIREG_SAVFP)(%esp)
239	movl	REG_OFF(KDIREG_EIP)(%esp), %eax
240	movl	%eax, REG_OFF(KDIREG_SAVPC)(%esp)
241
242	/*
243	 * If the kernel has started using its own selectors, we should too.
244	 * Update our saved selectors if they haven't been updated already.
245	 */
246	movw	%cs, %ax
247	cmpw	$KCS_SEL, %ax
248	jne	1f			/* The kernel hasn't switched yet */
249
250	movw	$KDS_SEL, %ax
251	movw	%ax, %ds
252	movw	kdi_cs, %ax
253	cmpw	$KCS_SEL, %ax
254	je	1f			/* We already switched */
255
256	/*
257	 * The kernel switched, but we haven't.  Update our saved selectors
258	 * to match the kernel's copies for use below.
259	 */
260	movl	$KCS_SEL, kdi_cs
261	movl	$KDS_SEL, kdi_ds
262	movl	$KFS_SEL, kdi_fs
263	movl	$KGS_SEL, kdi_gs
264
2651:
266	/*
267	 * Set the selectors to a known state.  If we come in from kmdb's IDT,
268	 * we'll be on boot's %cs.  This will cause GET_CPUSAVE_ADDR to return
269	 * CPU 0's cpusave, regardless of which CPU we're on, and chaos will
270	 * ensue.  So, if we've got $KCSSEL in kdi_cs, switch to it.  The other
271	 * selectors are restored normally.
272	 */
273	movw	%cs:kdi_cs, %ax
274	cmpw	$KCS_SEL, %ax
275	jne	1f
276	ljmp	$KCS_SEL, $1f
2771:
278	movw	%cs:kdi_ds, %ds
279	movw	kdi_ds, %es
280	movw	kdi_fs, %fs
281	movw	kdi_gs, %gs
282	movw	kdi_ds, %ss
283
284	/*
285	 * This has to come after we set %gs to the kernel descriptor.  Since
286	 * we've hijacked some IDT entries used in user-space such as the
287	 * breakpoint handler, we can enter kdi_cmnint() with GDT_LWPGS used
288	 * in %gs.  On the hypervisor, CLI() needs GDT_GS to access the machcpu.
289	 */
290	CLI(%eax)
291
292#if defined(__xpv)
293	/*
294	 * Clear saved_upcall_mask in unused byte of cs slot on stack.
295	 * It can only confuse things.
296	 */
297	movb    $0, REG_OFF(KDIREG_CS)+2(%esp)
298
299#endif
300
301	GET_CPUSAVE_ADDR		/* %eax = cpusave, %ebx = CPU ID */
302
303	ADVANCE_CRUMB_POINTER(%eax, %ecx, %edx)
304
305	ADD_CRUMB(%eax, KRM_CPU_STATE, $KDI_CPU_STATE_MASTER, %edx)
306
307	movl	REG_OFF(KDIREG_EIP)(%esp), %ecx
308	ADD_CRUMB(%eax, KRM_PC, %ecx, %edx)
309	ADD_CRUMB(%eax, KRM_SP, %esp, %edx)
310	movl	REG_OFF(KDIREG_TRAPNO)(%esp), %ecx
311	ADD_CRUMB(%eax, KRM_TRAPNO, %ecx, %edx)
312
313	movl	%esp, %ebp
314	pushl	%eax
315
316	/*
317	 * Were we in the debugger when we took the trap (i.e. was %esp in one
318	 * of the debugger's memory ranges)?
319	 */
320	leal	kdi_memranges, %ecx
321	movl	kdi_nmemranges, %edx
3221:	cmpl	MR_BASE(%ecx), %esp
323	jl	2f		/* below this range -- try the next one */
324	cmpl	MR_LIM(%ecx), %esp
325	jg	2f		/* above this range -- try the next one */
326	jmp	3f		/* matched within this range */
327
3282:	decl	%edx
329	jz	kdi_save_common_state	/* %esp not within debugger memory */
330	addl	$MR_SIZE, %ecx
331	jmp	1b
332
3333:	/*
334	 * %esp was within one of the debugger's memory ranges.  This should
335	 * only happen when we take a trap while running in the debugger.
336	 * kmdb_dpi_handle_fault will determine whether or not it was an
337	 * expected trap, and will take the appropriate action.
338	 */
339
340	pushl	%ebx			/* cpuid */
341
342	movl	REG_OFF(KDIREG_ESP)(%ebp), %ecx
343	addl	$REG_OFF(KDIREG_EFLAGS - KDIREG_EAX), %ecx
344	pushl	%ecx
345
346	pushl	REG_OFF(KDIREG_EIP)(%ebp)
347	pushl	REG_OFF(KDIREG_TRAPNO)(%ebp)
348
349	call	kdi_dvec_handle_fault
350	addl	$16, %esp
351
352	/*
353	 * If we're here, we ran into a debugger problem, and the user
354	 * elected to solve it by having the debugger debug itself.  The
355	 * state we're about to save is that of the debugger when it took
356	 * the fault.
357	 */
358
359	jmp	kdi_save_common_state
360
361	SET_SIZE(kdi_master_entry)
362	SET_SIZE(kdi_cmnint)
363
364#endif	/* __lint */
365
366/*
367 * The cross-call handler for slave CPUs.
368 *
369 * The debugger is single-threaded, so only one CPU, called the master, may be
370 * running it at any given time.  The other CPUs, known as slaves, spin in a
371 * busy loop until there's something for them to do.  This is the entry point
372 * for the slaves - they'll be sent here in response to a cross-call sent by the
373 * master.
374 */
375
376#if defined(__lint)
377char kdi_slave_entry_patch;
378
379void
380kdi_slave_entry(void)
381{
382}
383#else /* __lint */
384	.globl	kdi_slave_entry_patch;
385
386	ENTRY_NP(kdi_slave_entry)
387
388	/* kdi_msr_add_clrentry knows where this is */
389kdi_slave_entry_patch:
390	KDI_MSR_PATCH;
391
392	/*
393	 * Cross calls are implemented as function calls, so our stack
394	 * currently looks like one you'd get from a zero-argument function
395	 * call. There's an %eip at %esp, and that's about it.  We want to
396	 * make it look like the master CPU's stack.  By doing this, we can
397	 * use the same resume code for both master and slave.  We need to
398	 * make our stack look like a `struct regs' before we jump into the
399	 * common save routine.
400	 */
401
402	pushl	%cs
403	pushfl
404	pushl	$-1		/* A phony trap error code */
405	pushl	$-1		/* A phony trap number */
406	pushal
407	pushl	%ds
408	pushl	%es
409	pushl	%fs
410	pushl	%gs
411	pushl	%ss
412
413	subl	$8, %esp
414	movl	%ebp, REG_OFF(KDIREG_SAVFP)(%esp)
415	movl	REG_OFF(KDIREG_EIP)(%esp), %eax
416	movl	%eax, REG_OFF(KDIREG_SAVPC)(%esp)
417
418	/*
419	 * Swap our saved EFLAGS and %eip.  Each is where the other
420	 * should be.
421	 */
422	movl	REG_OFF(KDIREG_EFLAGS)(%esp), %eax
423	xchgl	REG_OFF(KDIREG_EIP)(%esp), %eax
424	movl	%eax, REG_OFF(KDIREG_EFLAGS)(%esp)
425
426	/*
427	 * Our stack now matches struct regs, and is irettable.  We don't need
428	 * to do anything special for the hypervisor w.r.t. PS_IE since we
429	 * iret twice anyway; the second iret back to the hypervisor
430	 * will re-enable interrupts.
431	 */
432	CLI(%eax)
433
434	/* Load sanitized segment selectors */
435	movw	kdi_ds, %ds
436	movw	kdi_ds, %es
437	movw	kdi_fs, %fs
438	movw	kdi_gs, %gs
439	movw	kdi_ds, %ss
440
441	GET_CPUSAVE_ADDR	/* %eax = cpusave, %ebx = CPU ID */
442
443	ADVANCE_CRUMB_POINTER(%eax, %ecx, %edx)
444
445	ADD_CRUMB(%eax, KRM_CPU_STATE, $KDI_CPU_STATE_SLAVE, %edx)
446
447	movl	REG_OFF(KDIREG_EIP)(%esp), %ecx
448	ADD_CRUMB(%eax, KRM_PC, %ecx, %edx)
449
450	pushl	%eax
451	jmp	kdi_save_common_state
452
453	SET_SIZE(kdi_slave_entry)
454
455#endif	/* __lint */
456
457/*
458 * The state of the world:
459 *
460 * The stack has a complete set of saved registers and segment
461 * selectors, arranged in `struct regs' order (or vice-versa), up to
462 * and including EFLAGS.  It also has a pointer to our cpusave area.
463 *
464 * We need to save a pointer to these saved registers.  We also want
465 * to adjust the saved %esp - it should point just beyond the saved
466 * registers to the last frame of the thread we interrupted.  Finally,
467 * we want to clear out bits 16-31 of the saved selectors, as the
468 * selector pushls don't automatically clear them.
469 */
470#if !defined(__lint)
471
472	ENTRY_NP(kdi_save_common_state)
473
474	popl	%eax			/* the cpusave area */
475
476	movl	%esp, KRS_GREGS(%eax)	/* save ptr to current saved regs */
477
478	addl	$REG_OFF(KDIREG_EFLAGS - KDIREG_EAX), KDIREG_OFF(KDIREG_ESP)(%esp)
479
480	andl	$0xffff, KDIREG_OFF(KDIREG_SS)(%esp)
481	andl	$0xffff, KDIREG_OFF(KDIREG_GS)(%esp)
482	andl	$0xffff, KDIREG_OFF(KDIREG_FS)(%esp)
483	andl	$0xffff, KDIREG_OFF(KDIREG_ES)(%esp)
484	andl	$0xffff, KDIREG_OFF(KDIREG_DS)(%esp)
485
486	pushl	%eax
487	call	kdi_trap_pass
488	cmpl	$1, %eax
489	je	kdi_pass_to_kernel
490	popl	%eax
491
492	SAVE_IDTGDT
493
494#if !defined(__xpv)
495	/* Save off %cr0, and clear write protect */
496	movl	%cr0, %ecx
497	movl	%ecx, KRS_CR0(%eax)
498	andl	$_BITNOT(CR0_WP), %ecx
499	movl	%ecx, %cr0
500#endif
501	pushl	%edi
502	movl	%eax, %edi
503
504	/* Save the debug registers and disable any active watchpoints */
505	pushl	$7
506	call	kdi_dreg_get
507	addl	$4, %esp
508
509	movl	%eax, KRS_DRCTL(%edi)
510	andl	$_BITNOT(KDIREG_DRCTL_WPALLEN_MASK), %eax
511
512	pushl	%eax
513	pushl	$7
514	call	kdi_dreg_set
515	addl	$8, %esp
516
517	pushl	$6
518	call	kdi_dreg_get
519	addl	$4, %esp
520	movl	%eax, KRS_DRSTAT(%edi)
521
522	pushl	$0
523	call	kdi_dreg_get
524	addl	$4, %esp
525	movl	%eax, KRS_DROFF(0)(%edi)
526
527	pushl	$1
528	call	kdi_dreg_get
529	addl	$4, %esp
530	movl	%eax, KRS_DROFF(1)(%edi)
531
532	pushl	$2
533	call	kdi_dreg_get
534	addl	$4, %esp
535	movl	%eax, KRS_DROFF(2)(%edi)
536
537	pushl	$3
538	call	kdi_dreg_get
539	addl	$4, %esp
540	movl	%eax, KRS_DROFF(3)(%edi)
541
542	movl	%edi, %eax
543	popl	%edi
544
545	/*
546	 * Save any requested MSRs.
547	 */
548	movl	KRS_MSR(%eax), %ecx
549	cmpl	$0, %ecx
550	je	no_msr
551
552	pushl	%eax		/* rdmsr clobbers %eax */
553	movl	%ecx, %ebx
5541:
555	movl	MSR_NUM(%ebx), %ecx
556	cmpl	$0, %ecx
557	je	msr_done
558
559	movl	MSR_TYPE(%ebx), %edx
560	cmpl	$KDI_MSR_READ, %edx
561	jne	msr_next
562
563	rdmsr			/* addr in %ecx, value into %edx:%eax */
564	movl	%eax, MSR_VAL(%ebx)
565	movl	%edx, _CONST(MSR_VAL + 4)(%ebx)
566
567msr_next:
568	addl	$MSR_SIZE, %ebx
569	jmp	1b
570
571msr_done:
572	popl	%eax
573
574no_msr:
575	clr	%ebp		/* stack traces should end here */
576
577	pushl	%eax
578	call	kdi_debugger_entry
579	popl	%eax
580
581	jmp	kdi_resume
582
583	SET_SIZE(kdi_save_common_state)
584
585#endif	/* !__lint */
586
587/*
588 * Resume the world.  The code that calls kdi_resume has already
589 * decided whether or not to restore the IDT.
590 */
591#if defined(__lint)
592void
593kdi_resume(void)
594{
595}
596#else	/* __lint */
597
598	/* cpusave in %eax */
599	ENTRY_NP(kdi_resume)
600
601	/*
602	 * Send this CPU back into the world
603	 */
604
605#if !defined(__xpv)
606	movl	KRS_CR0(%eax), %edx
607	movl	%edx, %cr0
608#endif
609
610	pushl	%edi
611	movl	%eax, %edi
612
613	KDI_RESTORE_DEBUGGING_STATE
614
615	popl	%edi
616
617#if defined(__xpv)
618	/*
619	 * kmdb might have set PS_T in the saved eflags, so we can't use
620	 * intr_restore, since that restores all of eflags; instead, just
621	 * pick up PS_IE from the saved eflags.
622	 */
623	movl	REG_OFF(KDIREG_EFLAGS)(%esp), %eax
624	testl	$PS_IE, %eax
625	jz	2f
626	STI
6272:
628#endif
629
630	addl	$8, %esp	/* Discard savfp and savpc */
631
632	popl	%ss
633	popl	%gs
634	popl	%fs
635	popl	%es
636	popl	%ds
637	popal
638
639	addl	$8, %esp	/* Discard TRAPNO and ERROR */
640
641	IRET
642
643	SET_SIZE(kdi_resume)
644#endif	/* __lint */
645
646#if !defined(__lint)
647
648	ENTRY_NP(kdi_pass_to_kernel)
649
650	/* pop cpusave, leaving %esp pointing to saved regs */
651	popl	%eax
652
653	movl	$KDI_CPU_STATE_NONE, KRS_CPU_STATE(%eax)
654
655	/*
656	 * Find the trap and vector off the right kernel handler.  The trap
657	 * handler will expect the stack to be in trap order, with %eip being
658	 * the last entry, so we'll need to restore all our regs.
659	 *
660	 * We're hard-coding the three cases where KMDB has installed permanent
661	 * handlers, since after we restore, we don't have registers to work
662	 * with; we can't use a global since other CPUs can easily pass through
663	 * here at the same time.
664	 *
665	 * Note that we handle T_DBGENTR since userspace might have tried it.
666	 */
667	movl	REG_OFF(KDIREG_TRAPNO)(%esp), %eax
668	cmpl	$T_SGLSTP, %eax
669	je	kpass_dbgtrap
670	cmpl	$T_BPTFLT, %eax
671	je	kpass_brktrap
672	cmpl	$T_DBGENTR, %eax
673	je	kpass_invaltrap
674	/*
675	 * Hmm, unknown handler.  Somebody forgot to update this when they
676	 * added a new trap interposition... try to drop back into kmdb.
677	 */
678	int	$T_DBGENTR
679
680kpass_dbgtrap:
681	KDI_RESTORE_REGS()
682	ljmp	$KCS_SEL, $1f
6831:	jmp	%cs:dbgtrap
684	/*NOTREACHED*/
685
686kpass_brktrap:
687	KDI_RESTORE_REGS()
688	ljmp	$KCS_SEL, $2f
6892:	jmp	%cs:brktrap
690	/*NOTREACHED*/
691
692kpass_invaltrap:
693	KDI_RESTORE_REGS()
694	ljmp	$KCS_SEL, $3f
6953:	jmp	%cs:invaltrap
696	/*NOTREACHED*/
697
698	SET_SIZE(kdi_pass_to_kernel)
699
700	/*
701	 * A minimal version of mdboot(), to be used by the master CPU only.
702	 */
703	ENTRY_NP(kdi_reboot)
704
705	pushl	$AD_BOOT
706	pushl	$A_SHUTDOWN
707	call	*psm_shutdownf
708	addl	$8, %esp
709
710#if defined(__xpv)
711	pushl	$SHUTDOWN_reboot
712	call	HYPERVISOR_shutdown
713#else
714	call	reset
715#endif
716	/*NOTREACHED*/
717
718	SET_SIZE(kdi_reboot)
719
720#endif	/* !__lint */
721
722#if defined(__lint)
723/*ARGSUSED*/
724void
725kdi_cpu_debug_init(kdi_cpusave_t *save)
726{
727}
728#else	/* __lint */
729
730	ENTRY_NP(kdi_cpu_debug_init)
731	pushl	%ebp
732	movl	%esp, %ebp
733
734	pushl	%edi
735	pushl	%ebx
736
737	movl	8(%ebp), %edi
738
739	KDI_RESTORE_DEBUGGING_STATE
740
741	popl	%ebx
742	popl	%edi
743	leave
744	ret
745
746	SET_SIZE(kdi_cpu_debug_init)
747#endif	/* !__lint */
748
749