xref: /titanic_50/usr/src/uts/i86pc/ml/cpr_wakecode.s (revision 8fd04b8338ed5093ec2d1e668fa620b7de44c177)
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 2009 Sun Microsystems, Inc.  All rights reserved.
23 * Use is subject to license terms.
24 */
25
26#include <sys/asm_linkage.h>
27#include <sys/asm_misc.h>
28#include <sys/regset.h>
29#include <sys/privregs.h>
30#include <sys/x86_archext.h>
31#include <sys/cpr_wakecode.h>
32
33#if !defined(__lint)
34#include <sys/segments.h>
35#include "assym.h"
36#endif
37
38#ifdef  DEBUG
39#define LED     1
40#define SERIAL  1
41#endif	/*	DEBUG	*/
42
43#ifdef	DEBUG
44#define	COM1	0x3f8
45#define	COM2	0x2f8
46#define	WC_COM	COM2	/* either COM1 or COM2			*/
47#define	WC_LED	0x80    /* diagnostic led port ON motherboard	*/
48
49/*
50 * defined as offsets from the data register
51 */
52#define	DLL	0	/* divisor latch (lsb) */
53#define	DLH	1	/* divisor latch (msb) */
54#define	LCR	3	/* line control register		*/
55#define	MCR	4	/* modem control register		*/
56
57
58#define	DLAB	0x80    /* divisor latch access bit		*/
59#define	B9600L	0X0c	/* lsb bit pattern for 9600 baud	*/
60#define	B9600H	0X0	/* hsb bit pattern for 9600 baud	*/
61#define	DTR	0x01    /* Data Terminal Ready			*/
62#define	RTS	0x02    /* Request To Send			*/
63#define	STOP1	0x00	/* 1 stop bit				*/
64#define	BITS8	0x03    /* 8 bits per char			*/
65
66#endif	/*	DEBUG	*/
67
68/*
69 *	This file contains the low level routines involved in getting
70 *	into and out of ACPI S3, including those needed for restarting
71 *	the non-boot cpus.
72 *
73 *	Our assumptions:
74 *
75 *	Our actions:
76 *
77 */
78
79#if defined(lint) || defined(__lint)
80
81/*ARGSUSED*/
82int
83wc_save_context(wc_cpu_t *pcpu)
84{ return 0; }
85
86#else	/* lint */
87
88#if defined(__GNU_AS__)
89
90	NOTHING AT ALL YET!
91
92#else	/* !defined(__GNU_AS__) */
93
94#if defined(__amd64)
95
96	ENTRY_NP(wc_save_context)
97
98	movq	(%rsp), %rdx		/ return address
99	movq	%rdx, WC_RETADDR(%rdi)
100	pushq	%rbp
101	movq	%rsp,%rbp
102
103	movq    %rdi, WC_VIRTADDR(%rdi)
104	movq    %rdi, WC_RDI(%rdi)
105
106	movq    %rdx, WC_RDX(%rdi)
107
108/ stash everything else we need
109	sgdt	WC_GDT(%rdi)
110	sidt	WC_IDT(%rdi)
111	sldt	WC_LDT(%rdi)
112	str	WC_TR(%rdi)
113
114	movq	%cr0, %rdx
115	movq	%rdx, WC_CR0(%rdi)
116	movq	%cr3, %rdx
117	movq	%rdx, WC_CR3(%rdi)
118	movq	%cr4, %rdx
119	movq	%rdx, WC_CR4(%rdi)
120	movq	%cr8, %rdx
121	movq	%rdx, WC_CR8(%rdi)
122
123	movq    %r8, WC_R8(%rdi)
124	movq    %r9, WC_R9(%rdi)
125	movq    %r10, WC_R10(%rdi)
126	movq    %r11, WC_R11(%rdi)
127	movq    %r12, WC_R12(%rdi)
128	movq    %r13, WC_R13(%rdi)
129	movq    %r14, WC_R14(%rdi)
130	movq    %r15, WC_R15(%rdi)
131	movq    %rax, WC_RAX(%rdi)
132	movq    %rbp, WC_RBP(%rdi)
133	movq    %rbx, WC_RBX(%rdi)
134	movq    %rcx, WC_RCX(%rdi)
135	movq    %rsi, WC_RSI(%rdi)
136	movq    %rsp, WC_RSP(%rdi)
137
138	movw	%ss, WC_SS(%rdi)
139	movw	%cs, WC_CS(%rdi)
140	movw	%ds, WC_DS(%rdi)
141	movw	%es, WC_ES(%rdi)
142
143	movq	$0, %rcx		/ save %fs register
144	movw    %fs, %cx
145	movq    %rcx, WC_FS(%rdi)
146
147	movl    $MSR_AMD_FSBASE, %ecx
148	rdmsr
149	movl    %eax, WC_FSBASE(%rdi)
150	movl    %edx, WC_FSBASE+4(%rdi)
151
152	movq	$0, %rcx		/ save %gs register
153	movw    %gs, %cx
154	movq    %rcx, WC_GS(%rdi)
155
156	movl    $MSR_AMD_GSBASE, %ecx	/ save gsbase msr
157	rdmsr
158	movl    %eax, WC_GSBASE(%rdi)
159	movl    %edx, WC_GSBASE+4(%rdi)
160
161	movl    $MSR_AMD_KGSBASE, %ecx	/ save kgsbase msr
162	rdmsr
163	movl    %eax, WC_KGSBASE(%rdi)
164	movl    %edx, WC_KGSBASE+4(%rdi)
165
166	movq	%gs:CPU_ID, %rax	/ save current cpu id
167	movq	%rax, WC_CPU_ID(%rdi)
168
169	pushfq
170	popq	WC_EFLAGS(%rdi)
171
172	wbinvd				/ flush the cache
173	mfence
174
175	movq	$1, %rax		/ at suspend return 1
176
177	leave
178
179	ret
180
181	SET_SIZE(wc_save_context)
182
183#elif defined(__i386)
184
185	ENTRY_NP(wc_save_context)
186
187	movl	4(%esp), %eax		/ wc_cpu_t *
188	movl	%eax, WC_VIRTADDR(%eax)
189
190	movl	(%esp), %edx		/ return address
191	movl	%edx, WC_RETADDR(%eax)
192
193	str	WC_TR(%eax)		/ stash everything else we need
194	sgdt	WC_GDT(%eax)
195	sldt	WC_LDT(%eax)
196	sidt	WC_IDT(%eax)
197
198	movl	%cr0, %edx
199	movl	%edx, WC_CR0(%eax)
200	movl	%cr3, %edx
201	movl	%edx, WC_CR3(%eax)
202	movl	%cr4, %edx
203	movl	%edx, WC_CR4(%eax)
204
205	movl	%ebx, WC_EBX(%eax)
206	movl	%edi, WC_EDI(%eax)
207	movl	%esi, WC_ESI(%eax)
208	movl	%ebp, WC_EBP(%eax)
209	movl	%esp, WC_ESP(%eax)
210
211	movw	%ss, WC_SS(%eax)
212	movw	%cs, WC_CS(%eax)
213	movw	%ds, WC_DS(%eax)
214	movw	%es, WC_ES(%eax)
215	movw	%fs, WC_FS(%eax)
216	movw	%gs, WC_GS(%eax)
217
218	pushfl
219	popl	WC_EFLAGS(%eax)
220
221	pushl	%gs:CPU_ID		/ save current cpu id
222	popl	WC_CPU_ID(%eax)
223
224	wbinvd				/ flush the cache
225	mfence
226
227	movl	$1, %eax		/ at suspend return 1
228	ret
229
230	SET_SIZE(wc_save_context)
231
232#endif	/* __amd64 */
233
234#endif	/* __GNU_AS__ */
235
236#endif /* lint */
237
238
239/*
240 *	Our assumptions:
241 *		- We are running in real mode.
242 *		- Interrupts are disabled.
243 *
244 *	Our actions:
245 *		- We start using our GDT by loading correct values in the
246 *		  selector registers (cs=KCS_SEL, ds=es=ss=KDS_SEL, fs=KFS_SEL,
247 *		  gs=KGS_SEL).
248 *		- We change over to using our IDT.
249 *		- We load the default LDT into the hardware LDT register.
250 *		- We load the default TSS into the hardware task register.
251 *		- We restore registers
252 *		- We return to original caller (a la setjmp)
253 */
254
255#if defined(lint) || defined(__lint)
256
257void
258wc_rm_start(void)
259{}
260
261void
262wc_rm_end(void)
263{}
264
265#else	/* lint */
266
267#if defined(__GNU_AS__)
268
269	NOTHING AT ALL YET!
270
271#else	/* __GNU_AS__ */
272
273#if defined(__amd64)
274
275	ENTRY_NP(wc_rm_start)
276
277	/*
278	 * For vulcan as we need to do a .code32 and mentally invert the
279	 * meaning of the addr16 and data16 prefixes to get 32-bit access when
280	 * generating code to be executed in 16-bit mode (sigh...)
281	 */
282
283	.code32
284
285	cli
286	movw		%cs, %ax
287	movw		%ax, %ds		/ establish ds ...
288	movw		%ax, %ss		/ ... and ss:esp
289	D16 movl	$WC_STKSTART, %esp
290/ using the following value blows up machines! - DO NOT USE
291/	D16 movl	0xffc, %esp
292
293
294#if     LED
295	D16 movl        $WC_LED, %edx
296	D16 movb        $0xd1, %al
297	outb    (%dx)
298#endif
299
300#if     SERIAL
301	D16 movl        $WC_COM, %edx
302	D16 movb        $0x61, %al
303	outb    (%dx)
304#endif
305
306	D16 call	cominit
307
308	/*
309	 * Enable protected-mode, write protect, and alignment mask
310	 * %cr0 has already been initialsed to zero
311	 */
312	movl		%cr0, %eax
313	D16 orl		$[CR0_PE|CR0_WP|CR0_AM], %eax
314	movl		%eax, %cr0
315
316	/*
317	 * Do a jmp immediately after writing to cr0 when enabling protected
318	 * mode to clear the real mode prefetch queue (per Intel's docs)
319	 */
320	jmp		pestart
321pestart:
322
323#if     LED
324	D16 movl        $WC_LED, %edx
325	D16 movb        $0xd2, %al
326	outb    (%dx)
327#endif
328
329#if     SERIAL
330	D16 movl        $WC_COM, %edx
331	D16 movb        $0x62, %al
332	outb    (%dx)
333#endif
334
335	/*
336	 * 16-bit protected mode is now active, so prepare to turn on long
337	 * mode
338	 */
339
340#if     LED
341	D16 movl        $WC_LED, %edx
342	D16 movb        $0xd3, %al
343	outb    (%dx)
344#endif
345
346#if     SERIAL
347	D16 movl        $WC_COM, %edx
348	D16 movb        $0x63, %al
349	outb    (%dx)
350#endif
351
352	/*
353 	 * Add any initial cr4 bits
354	 */
355	movl		%cr4, %eax
356	A16 D16 orl	CR4OFF, %eax
357
358	/*
359	 * Enable PAE mode (CR4.PAE)
360	 */
361	D16 orl		$CR4_PAE, %eax
362	movl		%eax, %cr4
363
364#if     LED
365	D16 movl        $WC_LED, %edx
366	D16 movb        $0xd4, %al
367	outb    (%dx)
368#endif
369
370#if     SERIAL
371	D16 movl        $WC_COM, %edx
372	D16 movb        $0x64, %al
373	outb    (%dx)
374#endif
375
376	/*
377	 * Point cr3 to the 64-bit long mode page tables.
378	 *
379	 * Note that these MUST exist in 32-bit space, as we don't have
380	 * a way to load %cr3 with a 64-bit base address for the page tables
381	 * until the CPU is actually executing in 64-bit long mode.
382	 */
383	A16 D16 movl	CR3OFF, %eax
384	movl		%eax, %cr3
385
386	/*
387	 * Set long mode enable in EFER (EFER.LME = 1)
388	 */
389	D16 movl	$MSR_AMD_EFER, %ecx
390	rdmsr
391
392	D16 orl		$AMD_EFER_LME, %eax
393	wrmsr
394
395#if     LED
396	D16 movl        $WC_LED, %edx
397	D16 movb        $0xd5, %al
398	outb    (%dx)
399#endif
400
401#if     SERIAL
402	D16 movl        $WC_COM, %edx
403	D16 movb        $0x65, %al
404	outb    (%dx)
405#endif
406
407	/*
408	 * Finally, turn on paging (CR0.PG = 1) to activate long mode.
409	 */
410	movl		%cr0, %eax
411	D16 orl		$CR0_PG, %eax
412	movl		%eax, %cr0
413
414	/*
415	 * The instruction after enabling paging in CR0 MUST be a branch.
416	 */
417	jmp		long_mode_active
418
419long_mode_active:
420
421#if     LED
422	D16 movl        $WC_LED, %edx
423	D16 movb        $0xd6, %al
424	outb    (%dx)
425#endif
426
427#if     SERIAL
428	D16 movl        $WC_COM, %edx
429	D16 movb        $0x66, %al
430	outb    (%dx)
431#endif
432
433	/*
434	 * Long mode is now active but since we're still running with the
435	 * original 16-bit CS we're actually in 16-bit compatability mode.
436	 *
437	 * We have to load an intermediate GDT and IDT here that we know are
438	 * in 32-bit space before we can use the kernel's GDT and IDT, which
439	 * may be in the 64-bit address space, and since we're in compatability
440	 * mode, we only have access to 16 and 32-bit instructions at the
441	 * moment.
442	 */
443	A16 D16 lgdt	TEMPGDTOFF	/* load temporary GDT */
444	A16 D16 lidt	TEMPIDTOFF	/* load temporary IDT */
445
446
447	/*
448 	 * Do a far transfer to 64-bit mode.  Set the CS selector to a 64-bit
449	 * long mode selector (CS.L=1) in the temporary 32-bit GDT and jump
450	 * to the real mode platter address of wc_long_mode_64 as until the
451	 * 64-bit CS is in place we don't have access to 64-bit instructions
452	 * and thus can't reference a 64-bit %rip.
453	 */
454
455#if     LED
456	D16 movl        $WC_LED, %edx
457	D16 movb        $0xd7, %al
458	outb    (%dx)
459#endif
460
461#if     SERIAL
462	D16 movl        $WC_COM, %edx
463	D16 movb        $0x67, %al
464	outb    (%dx)
465#endif
466
467	D16 	pushl 	$TEMP_CS64_SEL
468	A16 D16 pushl	LM64OFF
469
470	D16 lret
471
472
473/*
474 * Support routine to re-initialize VGA subsystem
475 */
476vgainit:
477	D16 ret
478
479/*
480 * Support routine to re-initialize keyboard (which is USB - help!)
481 */
482kbdinit:
483	D16 ret
484
485/*
486 * Support routine to re-initialize COM ports to something sane
487 */
488cominit:
489	/ init COM1 & COM2
490
491#if     DEBUG
492/*
493 * on debug kernels we need to initialize COM1 & COM2 here, so that
494 * we can get debug output before the asy driver has resumed
495 */
496
497/ select COM1
498	D16 movl	$[COM1+LCR], %edx
499	D16 movb	$DLAB, %al		/ divisor latch
500	outb	(%dx)
501
502	D16 movl	$[COM1+DLL], %edx	/ divisor latch lsb
503	D16 movb	$B9600L, %al		/ divisor latch
504	outb	(%dx)
505
506	D16 movl	$[COM1+DLH], %edx	/ divisor latch hsb
507	D16 movb	$B9600H, %al		/ divisor latch
508	outb	(%dx)
509
510	D16 movl	$[COM1+LCR], %edx	/ select COM1
511	D16 movb	$[STOP1|BITS8], %al	/ 1 stop bit, 8bit word len
512	outb	(%dx)
513
514	D16 movl	$[COM1+MCR], %edx	/ select COM1
515	D16 movb	$[RTS|DTR], %al		/ data term ready & req to send
516	outb	(%dx)
517
518/ select COM2
519	D16 movl	$[COM2+LCR], %edx
520	D16 movb	$DLAB, %al		/ divisor latch
521	outb	(%dx)
522
523	D16 movl	$[COM2+DLL], %edx	/ divisor latch lsb
524	D16 movb	$B9600L, %al		/ divisor latch
525	outb	(%dx)
526
527	D16 movl	$[COM2+DLH], %edx	/ divisor latch hsb
528	D16 movb	$B9600H, %al		/ divisor latch
529	outb	(%dx)
530
531	D16 movl	$[COM2+LCR], %edx	/ select COM1
532	D16 movb	$[STOP1|BITS8], %al	/ 1 stop bit, 8bit word len
533	outb	(%dx)
534
535	D16 movl	$[COM2+MCR], %edx	/ select COM1
536	D16 movb	$[RTS|DTR], %al		/ data term ready & req to send
537	outb	(%dx)
538#endif	/*	DEBUG	*/
539
540	D16 ret
541
542	.code64
543
544	.globl wc_long_mode_64
545wc_long_mode_64:
546
547#if     LED
548	movw        $WC_LED, %dx
549	movb        $0xd8, %al
550	outb    (%dx)
551#endif
552
553#if     SERIAL
554	movw        $WC_COM, %dx
555	movb        $0x68, %al
556	outb    (%dx)
557#endif
558
559	/*
560	 * We are now running in long mode with a 64-bit CS (EFER.LMA=1,
561	 * CS.L=1) so we now have access to 64-bit instructions.
562	 *
563	 * First, set the 64-bit GDT base.
564	 */
565	.globl	rm_platter_pa
566	movl	rm_platter_pa, %eax
567
568	lgdtq	GDTROFF(%rax)		/* load 64-bit GDT */
569
570	/*
571	 * Save the CPU number in %r11; get the value here since it's saved in
572	 * the real mode platter.
573	 */
574/ JAN
575/ the following is wrong! need to figure out MP systems
576/	movl	CPUNOFF(%rax), %r11d
577
578	/*
579	 * Add rm_platter_pa to %rsp to point it to the same location as seen
580	 * from 64-bit mode.
581	 */
582	addq	%rax, %rsp
583
584	/*
585	 * Now do an lretq to load CS with the appropriate selector for the
586	 * kernel's 64-bit GDT and to start executing 64-bit setup code at the
587	 * virtual address where boot originally loaded this code rather than
588	 * the copy in the real mode platter's rm_code array as we've been
589	 * doing so far.
590	 */
591
592#if     LED
593	movw        $WC_LED, %dx
594	movb        $0xd9, %al
595	outb    (%dx)
596#endif
597
598/ JAN this should produce 'i' but we get 'g' instead ???
599#if     SERIAL
600	movw        $WC_COM, %dx
601	movb        $0x69, %al
602	outb    (%dx)
603#endif
604
605	pushq	$KCS_SEL
606	pushq	$kernel_wc_code
607	lretq
608
609	.globl kernel_wc_code
610kernel_wc_code:
611
612#if     LED
613	movw        $WC_LED, %dx
614	movb        $0xda, %al
615	outb    (%dx)
616#endif
617
618/ JAN this should produce 'j' but we get 'g' instead ???
619#if     SERIAL
620	movw        $WC_COM, %dx
621	movb        $0x6a, %al
622	outb    (%dx)
623#endif
624
625	/*
626	 * Complete the balance of the setup we need to before executing
627	 * 64-bit kernel code (namely init rsp, TSS, LGDT, FS and GS).
628	 */
629	.globl  rm_platter_va
630	movq    rm_platter_va, %rbx
631	addq	$WC_CPU, %rbx
632
633#if     LED
634	movw        $WC_LED, %dx
635	movb        $0xdb, %al
636	outb    (%dx)
637#endif
638
639#if     SERIAL
640	movw        $WC_COM, %dx
641	movw        $0x6b, %ax
642	outb    (%dx)
643#endif
644
645	/*
646	 * restore the rest of the registers
647	 */
648
649	lidtq	WC_IDT(%rbx)
650
651#if     LED
652	movw        $WC_LED, %dx
653	movb        $0xdc, %al
654	outb    (%dx)
655#endif
656
657#if     SERIAL
658	movw        $WC_COM, %dx
659	movw        $0x6c, %ax
660	outb    (%dx)
661#endif
662
663	/*
664	 * restore the rest of the registers
665	 */
666
667	movw    $KDS_SEL, %ax
668	movw    %ax, %ds
669	movw    %ax, %es
670	movw    %ax, %ss
671
672	/*
673	 * Before proceeding, enable usage of the page table NX bit if
674	 * that's how the page tables are set up.
675	 */
676	movl    x86_feature, %ecx
677	andl   	 $X86_NX, %ecx
678	jz      1f
679	movl    $MSR_AMD_EFER, %ecx
680	rdmsr
681	orl     $AMD_EFER_NXE, %eax
682	wrmsr
6831:
684
685	movq	WC_CR4(%rbx), %rax	/ restore full cr4 (with Global Enable)
686	movq	%rax, %cr4
687
688	lldt	WC_LDT(%rbx)
689	movzwq	WC_TR(%rbx), %rax	/ clear TSS busy bit
690	addq	WC_GDT+2(%rbx), %rax
691	andl	$0xfffffdff, 4(%rax)
692	movq	4(%rax), %rcx
693	ltr	WC_TR(%rbx)
694
695#if     LED
696	movw        $WC_LED, %dx
697	movb        $0xdd, %al
698	outb    (%dx)
699#endif
700
701#if     SERIAL
702	movw        $WC_COM, %dx
703	movw        $0x6d, %ax
704	outb    (%dx)
705#endif
706
707/ restore %fsbase %gsbase %kgbase registers using wrmsr instruction
708
709	movq    WC_FS(%rbx), %rcx	/ restore fs register
710	movw    %cx, %fs
711
712	movl    $MSR_AMD_FSBASE, %ecx
713	movl    WC_FSBASE(%rbx), %eax
714	movl    WC_FSBASE+4(%rbx), %edx
715	wrmsr
716
717	movq    WC_GS(%rbx), %rcx	/ restore gs register
718	movw    %cx, %gs
719
720	movl    $MSR_AMD_GSBASE, %ecx	/ restore gsbase msr
721	movl    WC_GSBASE(%rbx), %eax
722	movl    WC_GSBASE+4(%rbx), %edx
723	wrmsr
724
725	movl    $MSR_AMD_KGSBASE, %ecx	/ restore kgsbase msr
726	movl    WC_KGSBASE(%rbx), %eax
727	movl    WC_KGSBASE+4(%rbx), %edx
728	wrmsr
729
730	movq	WC_CR0(%rbx), %rdx
731	movq	%rdx, %cr0
732	movq	WC_CR3(%rbx), %rdx
733	movq	%rdx, %cr3
734	movq	WC_CR8(%rbx), %rdx
735	movq	%rdx, %cr8
736
737#if     LED
738	movw        $WC_LED, %dx
739	movb        $0xde, %al
740	outb    (%dx)
741#endif
742
743#if     SERIAL
744	movw        $WC_COM, %dx
745	movb        $0x6e, %al
746	outb    (%dx)
747#endif
748
749	/*
750	 * if we are not running on the boot CPU restore stack contents by
751	 * calling i_cpr_restore_stack(curthread, save_stack);
752	 */
753	movq    %rsp, %rbp
754	call	i_cpr_bootcpuid
755	cmpl	%eax, WC_CPU_ID(%rbx)
756	je	2f
757
758	movq	%gs:CPU_THREAD, %rdi
759	movq	WC_SAVED_STACK(%rbx), %rsi
760	call	i_cpr_restore_stack
7612:
762
763	movq    WC_RSP(%rbx), %rsp	/ restore stack pointer
764
765	/*
766	 * APIC initialization
767	 */
768	movq    %rsp, %rbp
769
770	/*
771	 * skip iff function pointer is NULL
772	 */
773	cmpq	$0, ap_mlsetup
774	je	3f
775	call	*ap_mlsetup
7763:
777
778	call    *cpr_start_cpu_func
779
780/ restore %rbx to the value it ahd before we called the functions above
781	movq    rm_platter_va, %rbx
782	addq	$WC_CPU, %rbx
783
784	movq    WC_R8(%rbx), %r8
785	movq    WC_R9(%rbx), %r9
786	movq    WC_R10(%rbx), %r10
787	movq    WC_R11(%rbx), %r11
788	movq    WC_R12(%rbx), %r12
789	movq    WC_R13(%rbx), %r13
790	movq    WC_R14(%rbx), %r14
791	movq    WC_R15(%rbx), %r15
792/	movq    WC_RAX(%rbx), %rax
793	movq    WC_RBP(%rbx), %rbp
794	movq    WC_RCX(%rbx), %rcx
795/	movq    WC_RDX(%rbx), %rdx
796	movq    WC_RDI(%rbx), %rdi
797	movq    WC_RSI(%rbx), %rsi
798
799
800/ assume that %cs does not need to be restored
801/ %ds, %es & %ss are ignored in 64bit mode
802	movw	WC_SS(%rbx), %ss
803	movw	WC_DS(%rbx), %ds
804	movw	WC_ES(%rbx), %es
805
806#if     LED
807	movw        $WC_LED, %dx
808	movb        $0xdf, %al
809	outb    (%dx)
810#endif
811
812#if     SERIAL
813	movw        $WC_COM, %dx
814	movb        $0x6f, %al
815	outb    (%dx)
816#endif
817
818
819	movq    WC_RBP(%rbx), %rbp
820	movq    WC_RSP(%rbx), %rsp
821
822#if     LED
823	movw        $WC_LED, %dx
824	movb        $0xe0, %al
825	outb    (%dx)
826#endif
827
828#if     SERIAL
829	movw        $WC_COM, %dx
830	movb        $0x70, %al
831	outb    (%dx)
832#endif
833
834
835	movq    WC_RCX(%rbx), %rcx
836
837	pushq	WC_EFLAGS(%rbx)			/ restore flags
838	popfq
839
840#if     LED
841	movw        $WC_LED, %dx
842	movb        $0xe1, %al
843	outb    (%dx)
844#endif
845
846#if     SERIAL
847	movw        $WC_COM, %dx
848	movb        $0x71, %al
849	outb    (%dx)
850#endif
851
852/*
853 * can not use outb after this point, because doing so would mean using
854 * %dx which would modify %rdx which is restored here
855 */
856
857	movq	%rbx, %rax
858	movq    WC_RDX(%rax), %rdx
859	movq    WC_RBX(%rax), %rbx
860
861	leave
862
863	movq	WC_RETADDR(%rax), %rax
864	movq	%rax, (%rsp)		/ return to caller of wc_save_context
865
866	xorl	%eax, %eax			/ at wakeup return 0
867	ret
868
869
870	SET_SIZE(wc_rm_start)
871
872	ENTRY_NP(asmspin)
873
874	movl	%edi, %ecx
875A1:
876	loop	A1
877
878	SET_SIZE(asmspin)
879
880	.globl wc_rm_end
881wc_rm_end:
882	nop
883
884#elif defined(__i386)
885
886	ENTRY_NP(wc_rm_start)
887
888/entry:	jmp		entry			/ stop here for HDT
889
890	cli
891	movw		%cs, %ax
892	movw		%ax, %ds		/ establish ds ...
893	movw		%ax, %ss		/ ... and ss:esp
894	D16 movl	$WC_STKSTART, %esp
895
896#if     LED
897	D16 movl        $WC_LED, %edx
898	D16 movb        $0xd1, %al
899	outb    (%dx)
900#endif
901
902#if     SERIAL
903	D16 movl        $WC_COM, %edx
904	D16 movb        $0x61, %al
905	outb    (%dx)
906#endif
907
908
909	D16 call	vgainit
910	D16 call	kbdinit
911	D16 call	cominit
912
913#if     LED
914	D16 movl        $WC_LED, %edx
915	D16 movb        $0xd2, %al
916	outb    (%dx)
917#endif
918
919#if     SERIAL
920	D16 movl        $WC_COM, %edx
921	D16 movb        $0x62, %al
922	outb    (%dx)
923#endif
924
925	D16 A16 movl	$WC_CPU, %ebx		/ base add of wc_cpu_t
926
927#if     LED
928	D16 movb        $0xd3, %al
929	outb    $WC_LED
930#endif
931
932#if     SERIAL
933	D16 movl        $WC_COM, %edx
934	D16 movb        $0x63, %al
935	outb    (%dx)
936#endif
937
938	D16 A16 movl	%cs:WC_DS(%ebx), %edx	/ %ds post prot/paging transit
939
940#if     LED
941	D16 movb        $0xd4, %al
942	outb    $WC_LED
943#endif
944
945	D16 A16 lgdt	%cs:WC_GDT(%ebx)	/ restore gdt and idtr
946	D16 A16 lidt	%cs:WC_IDT(%ebx)
947
948#if     LED
949	D16 movb        $0xd5, %al
950	outb    $WC_LED
951#endif
952
953	D16 A16 movl	%cs:WC_CR4(%ebx), %eax	/ restore cr4
954	D16 andl	$-1!CR4_PGE, %eax	/ don't set Global Enable yet
955	movl		%eax, %cr4
956
957#if     LED
958	D16 movb        $0xd6, %al
959	outb    $WC_LED
960#endif
961
962	D16 A16 movl	%cs:WC_CR3(%ebx), %eax	/ set PDPT
963	movl		%eax, %cr3
964
965#if     LED
966	D16 movb        $0xd7, %al
967	outb    $WC_LED
968#endif
969
970	D16 A16 movl	%cs:WC_CR0(%ebx), %eax	/ enable prot/paging, etc.
971	movl		%eax, %cr0
972
973#if     LED
974	D16 movb        $0xd8, %al
975	outb    $WC_LED
976#endif
977
978	D16 A16 movl	%cs:WC_VIRTADDR(%ebx), %ebx	/ virtaddr of wc_cpu_t
979
980#if     LED
981	D16 movb        $0xd9, %al
982	outb    $WC_LED
983#endif
984
985#if     LED
986	D16 movb        $0xda, %al
987	outb    $WC_LED
988#endif
989
990	jmp		flush			/ flush prefetch queue
991flush:
992	D16 pushl	$KCS_SEL
993	D16 pushl	$kernel_wc_code
994	D16 lret				/ re-appear at kernel_wc_code
995
996
997/*
998 * Support routine to re-initialize VGA subsystem
999 */
1000vgainit:
1001	D16 ret
1002
1003/*
1004 * Support routine to re-initialize keyboard (which is USB - help!)
1005 */
1006kbdinit:
1007	D16 ret
1008
1009/*
1010 * Support routine to re-initialize COM ports to something sane for debug output
1011 */
1012cominit:
1013#if     DEBUG
1014/*
1015 * on debug kernels we need to initialize COM1 & COM2 here, so that
1016 * we can get debug output before the asy driver has resumed
1017 */
1018
1019/ select COM1
1020	D16 movl	$[COM1+LCR], %edx
1021	D16 movb	$DLAB, %al		/ divisor latch
1022	outb	(%dx)
1023
1024	D16 movl	$[COM1+DLL], %edx	/ divisor latch lsb
1025	D16 movb	$B9600L, %al		/ divisor latch
1026	outb	(%dx)
1027
1028	D16 movl	$[COM1+DLH], %edx	/ divisor latch hsb
1029	D16 movb	$B9600H, %al		/ divisor latch
1030	outb	(%dx)
1031
1032	D16 movl	$[COM1+LCR], %edx	/ select COM1
1033	D16 movb	$[STOP1|BITS8], %al	/ 1 stop bit, 8bit word len
1034	outb	(%dx)
1035
1036	D16 movl	$[COM1+MCR], %edx	/ select COM1
1037	D16 movb	$[RTS|DTR], %al		/ 1 stop bit, 8bit word len
1038	outb	(%dx)
1039
1040/ select COM2
1041	D16 movl	$[COM2+LCR], %edx
1042	D16 movb	$DLAB, %al		/ divisor latch
1043	outb	(%dx)
1044
1045	D16 movl	$[COM2+DLL], %edx	/ divisor latch lsb
1046	D16 movb	$B9600L, %al		/ divisor latch
1047	outb	(%dx)
1048
1049	D16 movl	$[COM2+DLH], %edx	/ divisor latch hsb
1050	D16 movb	$B9600H, %al		/ divisor latch
1051	outb	(%dx)
1052
1053	D16 movl	$[COM2+LCR], %edx	/ select COM1
1054	D16 movb	$[STOP1|BITS8], %al	/ 1 stop bit, 8bit word len
1055	outb	(%dx)
1056
1057	D16 movl	$[COM2+MCR], %edx	/ select COM1
1058	D16 movb	$[RTS|DTR], %al		/ 1 stop bit, 8bit word len
1059	outb	(%dx)
1060#endif	/*	DEBUG	*/
1061
1062	D16 ret
1063
1064	.globl wc_rm_end
1065wc_rm_end:
1066	nop
1067
1068	.globl	kernel_wc_code
1069kernel_wc_code:
1070	/ At this point we are with kernel's cs and proper eip.
1071	/ We will be executing not from the copy in real mode platter,
1072	/ but from the original code where boot loaded us.
1073	/ By this time GDT and IDT are loaded as is cr0, cr3 and cr4.
1074	/ %ebx is wc_cpu
1075	/ %dx is our ds
1076
1077#if     LED
1078	D16 movb        $0xdb, %al
1079	outb	$WC_LED
1080#endif
1081
1082/ got here OK
1083
1084	movw	%dx, %ds		/ $KDS_SEL
1085
1086#if     LED
1087	movb	$0xdc, %al
1088	outb	$WC_LED
1089#endif
1090
1091	/*
1092	 * Before proceeding, enable usage of the page table NX bit if
1093	 * that's how the page tables are set up.
1094	 */
1095	movl    x86_feature, %ecx
1096	andl   	 $X86_NX, %ecx
1097	jz      1f
1098	movl    $MSR_AMD_EFER, %ecx
1099	rdmsr
1100	orl     $AMD_EFER_NXE, %eax
1101	wrmsr
11021:
1103
1104	movl	WC_CR4(%ebx), %eax	/ restore full cr4 (with Global Enable)
1105	movl	%eax, %cr4
1106
1107
1108	lldt	WC_LDT(%ebx)		/ $LDT_SEL
1109
1110	movzwl	WC_TR(%ebx), %eax	/ clear TSS busy bit
1111	addl	WC_GDT+2(%ebx), %eax
1112	andl	$-1!0x200, 4(%eax)
1113	ltr	WC_TR(%ebx)		/ $UTSS_SEL
1114
1115	movw	WC_SS(%ebx), %ss	/ restore segment registers
1116	movw	WC_ES(%ebx), %es
1117	movw	WC_FS(%ebx), %fs
1118	movw	WC_GS(%ebx), %gs
1119
1120	/*
1121	 * set the stack pointer to point into the identity mapped page
1122	 * temporarily, so we can make function calls
1123	 */
1124	.globl  rm_platter_va
1125	movl    rm_platter_va, %eax
1126	movl	$WC_STKSTART, %esp
1127	addl	%eax, %esp
1128	movl	%esp, %ebp
1129
1130	/*
1131	 * if we are not running on the boot CPU restore stack contents by
1132	 * calling i_cpr_restore_stack(curthread, save_stack);
1133	 */
1134	call	i_cpr_bootcpuid
1135	cmpl	%eax, WC_CPU_ID(%ebx)
1136	je	2f
1137
1138	pushl	WC_SAVED_STACK(%ebx)
1139	pushl	%gs:CPU_THREAD
1140	call	i_cpr_restore_stack
1141	addl	$0x10, %esp
11422:
1143
1144	movl	WC_ESP(%ebx), %esp
1145	movl	%esp, %ebp
1146
1147	movl	WC_RETADDR(%ebx), %eax	/ return to caller of wc_save_context
1148	movl	%eax, (%esp)
1149
1150	/*
1151	 * APIC initialization, skip iff function pointer is NULL
1152	 */
1153	cmpl	$0, ap_mlsetup
1154	je	3f
1155	call	*ap_mlsetup
11563:
1157
1158	call    *cpr_start_cpu_func
1159
1160	pushl	WC_EFLAGS(%ebx)		/ restore flags
1161	popfl
1162
1163	movl	WC_EDI(%ebx), %edi	/ restore general registers
1164	movl	WC_ESI(%ebx), %esi
1165	movl	WC_EBP(%ebx), %ebp
1166	movl	WC_EBX(%ebx), %ebx
1167
1168/exit:	jmp	exit			/ stop here for HDT
1169
1170	xorl	%eax, %eax		/ at wakeup return 0
1171	ret
1172
1173	SET_SIZE(wc_rm_start)
1174
1175
1176#endif	/* defined(__amd64) */
1177
1178#endif	/* !defined(__GNU_AS__) */
1179
1180#endif /* lint */
1181
1182