xref: /titanic_52/usr/src/uts/i86pc/os/cpuid.c (revision cef70d2c52b5ed31a487790e4584f648812210a9)
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  * Copyright (c) 2009, Intel Corporation.
27  * All rights reserved.
28  */
29 
30 /*
31  * Various routines to handle identification
32  * and classification of x86 processors.
33  */
34 
35 #include <sys/types.h>
36 #include <sys/archsystm.h>
37 #include <sys/x86_archext.h>
38 #include <sys/kmem.h>
39 #include <sys/systm.h>
40 #include <sys/cmn_err.h>
41 #include <sys/sunddi.h>
42 #include <sys/sunndi.h>
43 #include <sys/cpuvar.h>
44 #include <sys/processor.h>
45 #include <sys/sysmacros.h>
46 #include <sys/pg.h>
47 #include <sys/fp.h>
48 #include <sys/controlregs.h>
49 #include <sys/auxv_386.h>
50 #include <sys/bitmap.h>
51 #include <sys/memnode.h>
52 
53 #ifdef __xpv
54 #include <sys/hypervisor.h>
55 #else
56 #include <sys/ontrap.h>
57 #endif
58 
59 /*
60  * Pass 0 of cpuid feature analysis happens in locore. It contains special code
61  * to recognize Cyrix processors that are not cpuid-compliant, and to deal with
62  * them accordingly. For most modern processors, feature detection occurs here
63  * in pass 1.
64  *
65  * Pass 1 of cpuid feature analysis happens just at the beginning of mlsetup()
66  * for the boot CPU and does the basic analysis that the early kernel needs.
67  * x86_feature is set based on the return value of cpuid_pass1() of the boot
68  * CPU.
69  *
70  * Pass 1 includes:
71  *
72  *	o Determining vendor/model/family/stepping and setting x86_type and
73  *	  x86_vendor accordingly.
74  *	o Processing the feature flags returned by the cpuid instruction while
75  *	  applying any workarounds or tricks for the specific processor.
76  *	o Mapping the feature flags into Solaris feature bits (X86_*).
77  *	o Processing extended feature flags if supported by the processor,
78  *	  again while applying specific processor knowledge.
79  *	o Determining the CMT characteristics of the system.
80  *
81  * Pass 1 is done on non-boot CPUs during their initialization and the results
82  * are used only as a meager attempt at ensuring that all processors within the
83  * system support the same features.
84  *
85  * Pass 2 of cpuid feature analysis happens just at the beginning
86  * of startup().  It just copies in and corrects the remainder
87  * of the cpuid data we depend on: standard cpuid functions that we didn't
88  * need for pass1 feature analysis, and extended cpuid functions beyond the
89  * simple feature processing done in pass1.
90  *
91  * Pass 3 of cpuid analysis is invoked after basic kernel services; in
92  * particular kernel memory allocation has been made available. It creates a
93  * readable brand string based on the data collected in the first two passes.
94  *
95  * Pass 4 of cpuid analysis is invoked after post_startup() when all
96  * the support infrastructure for various hardware features has been
97  * initialized. It determines which processor features will be reported
98  * to userland via the aux vector.
99  *
100  * All passes are executed on all CPUs, but only the boot CPU determines what
101  * features the kernel will use.
102  *
103  * Much of the worst junk in this file is for the support of processors
104  * that didn't really implement the cpuid instruction properly.
105  *
106  * NOTE: The accessor functions (cpuid_get*) are aware of, and ASSERT upon,
107  * the pass numbers.  Accordingly, changes to the pass code may require changes
108  * to the accessor code.
109  */
110 
111 uint_t x86_feature = 0;
112 uint_t x86_vendor = X86_VENDOR_IntelClone;
113 uint_t x86_type = X86_TYPE_OTHER;
114 uint_t x86_clflush_size = 0;
115 
116 uint_t pentiumpro_bug4046376;
117 uint_t pentiumpro_bug4064495;
118 
119 uint_t enable486;
120 /*
121  * This is set to platform type Solaris is running on.
122  */
123 static int platform_type = HW_NATIVE;
124 
125 /*
126  * monitor/mwait info.
127  *
128  * size_actual and buf_actual are the real address and size allocated to get
129  * proper mwait_buf alignement.  buf_actual and size_actual should be passed
130  * to kmem_free().  Currently kmem_alloc() and mwait happen to both use
131  * processor cache-line alignment, but this is not guarantied in the furture.
132  */
133 struct mwait_info {
134 	size_t		mon_min;	/* min size to avoid missed wakeups */
135 	size_t		mon_max;	/* size to avoid false wakeups */
136 	size_t		size_actual;	/* size actually allocated */
137 	void		*buf_actual;	/* memory actually allocated */
138 	uint32_t	support;	/* processor support of monitor/mwait */
139 };
140 
141 /*
142  * These constants determine how many of the elements of the
143  * cpuid we cache in the cpuid_info data structure; the
144  * remaining elements are accessible via the cpuid instruction.
145  */
146 
147 #define	NMAX_CPI_STD	6		/* eax = 0 .. 5 */
148 #define	NMAX_CPI_EXTD	9		/* eax = 0x80000000 .. 0x80000008 */
149 
150 struct cpuid_info {
151 	uint_t cpi_pass;		/* last pass completed */
152 	/*
153 	 * standard function information
154 	 */
155 	uint_t cpi_maxeax;		/* fn 0: %eax */
156 	char cpi_vendorstr[13];		/* fn 0: %ebx:%ecx:%edx */
157 	uint_t cpi_vendor;		/* enum of cpi_vendorstr */
158 
159 	uint_t cpi_family;		/* fn 1: extended family */
160 	uint_t cpi_model;		/* fn 1: extended model */
161 	uint_t cpi_step;		/* fn 1: stepping */
162 	chipid_t cpi_chipid;		/* fn 1: %ebx: chip # on ht cpus */
163 	uint_t cpi_brandid;		/* fn 1: %ebx: brand ID */
164 	int cpi_clogid;			/* fn 1: %ebx: thread # */
165 	uint_t cpi_ncpu_per_chip;	/* fn 1: %ebx: logical cpu count */
166 	uint8_t cpi_cacheinfo[16];	/* fn 2: intel-style cache desc */
167 	uint_t cpi_ncache;		/* fn 2: number of elements */
168 	uint_t cpi_ncpu_shr_last_cache;	/* fn 4: %eax: ncpus sharing cache */
169 	id_t cpi_last_lvl_cacheid;	/* fn 4: %eax: derived cache id */
170 	uint_t cpi_std_4_size;		/* fn 4: number of fn 4 elements */
171 	struct cpuid_regs **cpi_std_4;	/* fn 4: %ecx == 0 .. fn4_size */
172 	struct cpuid_regs cpi_std[NMAX_CPI_STD];	/* 0 .. 5 */
173 	/*
174 	 * extended function information
175 	 */
176 	uint_t cpi_xmaxeax;		/* fn 0x80000000: %eax */
177 	char cpi_brandstr[49];		/* fn 0x8000000[234] */
178 	uint8_t cpi_pabits;		/* fn 0x80000006: %eax */
179 	uint8_t cpi_vabits;		/* fn 0x80000006: %eax */
180 	struct cpuid_regs cpi_extd[NMAX_CPI_EXTD]; /* 0x8000000[0-8] */
181 	id_t cpi_coreid;		/* same coreid => strands share core */
182 	int cpi_pkgcoreid;		/* core number within single package */
183 	uint_t cpi_ncore_per_chip;	/* AMD: fn 0x80000008: %ecx[7-0] */
184 					/* Intel: fn 4: %eax[31-26] */
185 	/*
186 	 * supported feature information
187 	 */
188 	uint32_t cpi_support[5];
189 #define	STD_EDX_FEATURES	0
190 #define	AMD_EDX_FEATURES	1
191 #define	TM_EDX_FEATURES		2
192 #define	STD_ECX_FEATURES	3
193 #define	AMD_ECX_FEATURES	4
194 	/*
195 	 * Synthesized information, where known.
196 	 */
197 	uint32_t cpi_chiprev;		/* See X86_CHIPREV_* in x86_archext.h */
198 	const char *cpi_chiprevstr;	/* May be NULL if chiprev unknown */
199 	uint32_t cpi_socket;		/* Chip package/socket type */
200 
201 	struct mwait_info cpi_mwait;	/* fn 5: monitor/mwait info */
202 	uint32_t cpi_apicid;
203 };
204 
205 
206 static struct cpuid_info cpuid_info0;
207 
208 /*
209  * These bit fields are defined by the Intel Application Note AP-485
210  * "Intel Processor Identification and the CPUID Instruction"
211  */
212 #define	CPI_FAMILY_XTD(cpi)	BITX((cpi)->cpi_std[1].cp_eax, 27, 20)
213 #define	CPI_MODEL_XTD(cpi)	BITX((cpi)->cpi_std[1].cp_eax, 19, 16)
214 #define	CPI_TYPE(cpi)		BITX((cpi)->cpi_std[1].cp_eax, 13, 12)
215 #define	CPI_FAMILY(cpi)		BITX((cpi)->cpi_std[1].cp_eax, 11, 8)
216 #define	CPI_STEP(cpi)		BITX((cpi)->cpi_std[1].cp_eax, 3, 0)
217 #define	CPI_MODEL(cpi)		BITX((cpi)->cpi_std[1].cp_eax, 7, 4)
218 
219 #define	CPI_FEATURES_EDX(cpi)		((cpi)->cpi_std[1].cp_edx)
220 #define	CPI_FEATURES_ECX(cpi)		((cpi)->cpi_std[1].cp_ecx)
221 #define	CPI_FEATURES_XTD_EDX(cpi)	((cpi)->cpi_extd[1].cp_edx)
222 #define	CPI_FEATURES_XTD_ECX(cpi)	((cpi)->cpi_extd[1].cp_ecx)
223 
224 #define	CPI_BRANDID(cpi)	BITX((cpi)->cpi_std[1].cp_ebx, 7, 0)
225 #define	CPI_CHUNKS(cpi)		BITX((cpi)->cpi_std[1].cp_ebx, 15, 7)
226 #define	CPI_CPU_COUNT(cpi)	BITX((cpi)->cpi_std[1].cp_ebx, 23, 16)
227 #define	CPI_APIC_ID(cpi)	BITX((cpi)->cpi_std[1].cp_ebx, 31, 24)
228 
229 #define	CPI_MAXEAX_MAX		0x100		/* sanity control */
230 #define	CPI_XMAXEAX_MAX		0x80000100
231 #define	CPI_FN4_ECX_MAX		0x20		/* sanity: max fn 4 levels */
232 #define	CPI_FNB_ECX_MAX		0x20		/* sanity: max fn B levels */
233 
234 /*
235  * Function 4 (Deterministic Cache Parameters) macros
236  * Defined by Intel Application Note AP-485
237  */
238 #define	CPI_NUM_CORES(regs)		BITX((regs)->cp_eax, 31, 26)
239 #define	CPI_NTHR_SHR_CACHE(regs)	BITX((regs)->cp_eax, 25, 14)
240 #define	CPI_FULL_ASSOC_CACHE(regs)	BITX((regs)->cp_eax, 9, 9)
241 #define	CPI_SELF_INIT_CACHE(regs)	BITX((regs)->cp_eax, 8, 8)
242 #define	CPI_CACHE_LVL(regs)		BITX((regs)->cp_eax, 7, 5)
243 #define	CPI_CACHE_TYPE(regs)		BITX((regs)->cp_eax, 4, 0)
244 #define	CPI_CPU_LEVEL_TYPE(regs)	BITX((regs)->cp_ecx, 15, 8)
245 
246 #define	CPI_CACHE_WAYS(regs)		BITX((regs)->cp_ebx, 31, 22)
247 #define	CPI_CACHE_PARTS(regs)		BITX((regs)->cp_ebx, 21, 12)
248 #define	CPI_CACHE_COH_LN_SZ(regs)	BITX((regs)->cp_ebx, 11, 0)
249 
250 #define	CPI_CACHE_SETS(regs)		BITX((regs)->cp_ecx, 31, 0)
251 
252 #define	CPI_PREFCH_STRIDE(regs)		BITX((regs)->cp_edx, 9, 0)
253 
254 
255 /*
256  * A couple of shorthand macros to identify "later" P6-family chips
257  * like the Pentium M and Core.  First, the "older" P6-based stuff
258  * (loosely defined as "pre-Pentium-4"):
259  * P6, PII, Mobile PII, PII Xeon, PIII, Mobile PIII, PIII Xeon
260  */
261 
262 #define	IS_LEGACY_P6(cpi) (			\
263 	cpi->cpi_family == 6 && 		\
264 		(cpi->cpi_model == 1 ||		\
265 		cpi->cpi_model == 3 ||		\
266 		cpi->cpi_model == 5 ||		\
267 		cpi->cpi_model == 6 ||		\
268 		cpi->cpi_model == 7 ||		\
269 		cpi->cpi_model == 8 ||		\
270 		cpi->cpi_model == 0xA ||	\
271 		cpi->cpi_model == 0xB)		\
272 )
273 
274 /* A "new F6" is everything with family 6 that's not the above */
275 #define	IS_NEW_F6(cpi) ((cpi->cpi_family == 6) && !IS_LEGACY_P6(cpi))
276 
277 /* Extended family/model support */
278 #define	IS_EXTENDED_MODEL_INTEL(cpi) (cpi->cpi_family == 0x6 || \
279 	cpi->cpi_family >= 0xf)
280 
281 /*
282  * Info for monitor/mwait idle loop.
283  *
284  * See cpuid section of "Intel 64 and IA-32 Architectures Software Developer's
285  * Manual Volume 2A: Instruction Set Reference, A-M" #25366-022US, November
286  * 2006.
287  * See MONITOR/MWAIT section of "AMD64 Architecture Programmer's Manual
288  * Documentation Updates" #33633, Rev 2.05, December 2006.
289  */
290 #define	MWAIT_SUPPORT		(0x00000001)	/* mwait supported */
291 #define	MWAIT_EXTENSIONS	(0x00000002)	/* extenstion supported */
292 #define	MWAIT_ECX_INT_ENABLE	(0x00000004)	/* ecx 1 extension supported */
293 #define	MWAIT_SUPPORTED(cpi)	((cpi)->cpi_std[1].cp_ecx & CPUID_INTC_ECX_MON)
294 #define	MWAIT_INT_ENABLE(cpi)	((cpi)->cpi_std[5].cp_ecx & 0x2)
295 #define	MWAIT_EXTENSION(cpi)	((cpi)->cpi_std[5].cp_ecx & 0x1)
296 #define	MWAIT_SIZE_MIN(cpi)	BITX((cpi)->cpi_std[5].cp_eax, 15, 0)
297 #define	MWAIT_SIZE_MAX(cpi)	BITX((cpi)->cpi_std[5].cp_ebx, 15, 0)
298 /*
299  * Number of sub-cstates for a given c-state.
300  */
301 #define	MWAIT_NUM_SUBC_STATES(cpi, c_state)			\
302 	BITX((cpi)->cpi_std[5].cp_edx, c_state + 3, c_state)
303 
304 /*
305  * Functions we consune from cpuid_subr.c;  don't publish these in a header
306  * file to try and keep people using the expected cpuid_* interfaces.
307  */
308 extern uint32_t _cpuid_skt(uint_t, uint_t, uint_t, uint_t);
309 extern uint32_t _cpuid_chiprev(uint_t, uint_t, uint_t, uint_t);
310 extern const char *_cpuid_chiprevstr(uint_t, uint_t, uint_t, uint_t);
311 extern uint_t _cpuid_vendorstr_to_vendorcode(char *);
312 
313 /*
314  * Apply up various platform-dependent restrictions where the
315  * underlying platform restrictions mean the CPU can be marked
316  * as less capable than its cpuid instruction would imply.
317  */
318 #if defined(__xpv)
319 static void
320 platform_cpuid_mangle(uint_t vendor, uint32_t eax, struct cpuid_regs *cp)
321 {
322 	switch (eax) {
323 	case 1: {
324 		uint32_t mcamask = DOMAIN_IS_INITDOMAIN(xen_info) ?
325 		    0 : CPUID_INTC_EDX_MCA;
326 		cp->cp_edx &=
327 		    ~(mcamask |
328 		    CPUID_INTC_EDX_PSE |
329 		    CPUID_INTC_EDX_VME | CPUID_INTC_EDX_DE |
330 		    CPUID_INTC_EDX_SEP | CPUID_INTC_EDX_MTRR |
331 		    CPUID_INTC_EDX_PGE | CPUID_INTC_EDX_PAT |
332 		    CPUID_AMD_EDX_SYSC | CPUID_INTC_EDX_SEP |
333 		    CPUID_INTC_EDX_PSE36 | CPUID_INTC_EDX_HTT);
334 		break;
335 	}
336 
337 	case 0x80000001:
338 		cp->cp_edx &=
339 		    ~(CPUID_AMD_EDX_PSE |
340 		    CPUID_INTC_EDX_VME | CPUID_INTC_EDX_DE |
341 		    CPUID_AMD_EDX_MTRR | CPUID_AMD_EDX_PGE |
342 		    CPUID_AMD_EDX_PAT | CPUID_AMD_EDX_PSE36 |
343 		    CPUID_AMD_EDX_SYSC | CPUID_INTC_EDX_SEP |
344 		    CPUID_AMD_EDX_TSCP);
345 		cp->cp_ecx &= ~CPUID_AMD_ECX_CMP_LGCY;
346 		break;
347 	default:
348 		break;
349 	}
350 
351 	switch (vendor) {
352 	case X86_VENDOR_Intel:
353 		switch (eax) {
354 		case 4:
355 			/*
356 			 * Zero out the (ncores-per-chip - 1) field
357 			 */
358 			cp->cp_eax &= 0x03fffffff;
359 			break;
360 		default:
361 			break;
362 		}
363 		break;
364 	case X86_VENDOR_AMD:
365 		switch (eax) {
366 		case 0x80000008:
367 			/*
368 			 * Zero out the (ncores-per-chip - 1) field
369 			 */
370 			cp->cp_ecx &= 0xffffff00;
371 			break;
372 		default:
373 			break;
374 		}
375 		break;
376 	default:
377 		break;
378 	}
379 }
380 #else
381 #define	platform_cpuid_mangle(vendor, eax, cp)	/* nothing */
382 #endif
383 
384 /*
385  *  Some undocumented ways of patching the results of the cpuid
386  *  instruction to permit running Solaris 10 on future cpus that
387  *  we don't currently support.  Could be set to non-zero values
388  *  via settings in eeprom.
389  */
390 
391 uint32_t cpuid_feature_ecx_include;
392 uint32_t cpuid_feature_ecx_exclude;
393 uint32_t cpuid_feature_edx_include;
394 uint32_t cpuid_feature_edx_exclude;
395 
396 void
397 cpuid_alloc_space(cpu_t *cpu)
398 {
399 	/*
400 	 * By convention, cpu0 is the boot cpu, which is set up
401 	 * before memory allocation is available.  All other cpus get
402 	 * their cpuid_info struct allocated here.
403 	 */
404 	ASSERT(cpu->cpu_id != 0);
405 	cpu->cpu_m.mcpu_cpi =
406 	    kmem_zalloc(sizeof (*cpu->cpu_m.mcpu_cpi), KM_SLEEP);
407 }
408 
409 void
410 cpuid_free_space(cpu_t *cpu)
411 {
412 	struct cpuid_info *cpi = cpu->cpu_m.mcpu_cpi;
413 	int i;
414 
415 	ASSERT(cpu->cpu_id != 0);
416 
417 	/*
418 	 * Free up any function 4 related dynamic storage
419 	 */
420 	for (i = 1; i < cpi->cpi_std_4_size; i++)
421 		kmem_free(cpi->cpi_std_4[i], sizeof (struct cpuid_regs));
422 	if (cpi->cpi_std_4_size > 0)
423 		kmem_free(cpi->cpi_std_4,
424 		    cpi->cpi_std_4_size * sizeof (struct cpuid_regs *));
425 
426 	kmem_free(cpu->cpu_m.mcpu_cpi, sizeof (*cpu->cpu_m.mcpu_cpi));
427 }
428 
429 #if !defined(__xpv)
430 
431 static void
432 determine_platform()
433 {
434 	struct cpuid_regs cp;
435 	char *xen_str;
436 	uint32_t xen_signature[4];
437 
438 	/*
439 	 * In a fully virtualized domain, Xen's pseudo-cpuid function
440 	 * 0x40000000 returns a string representing the Xen signature in
441 	 * %ebx, %ecx, and %edx.  %eax contains the maximum supported cpuid
442 	 * function.
443 	 */
444 	cp.cp_eax = 0x40000000;
445 	(void) __cpuid_insn(&cp);
446 	xen_signature[0] = cp.cp_ebx;
447 	xen_signature[1] = cp.cp_ecx;
448 	xen_signature[2] = cp.cp_edx;
449 	xen_signature[3] = 0;
450 	xen_str = (char *)xen_signature;
451 	if (strcmp("XenVMMXenVMM", xen_str) == 0 && cp.cp_eax <= 0x40000002) {
452 		platform_type = HW_XEN_HVM;
453 	} else if (vmware_platform()) { /* running under vmware hypervisor? */
454 		platform_type = HW_VMWARE;
455 	}
456 }
457 
458 int
459 get_hwenv(void)
460 {
461 	return (platform_type);
462 }
463 
464 int
465 is_controldom(void)
466 {
467 	return (0);
468 }
469 
470 #else
471 
472 int
473 get_hwenv(void)
474 {
475 	return (HW_XEN_PV);
476 }
477 
478 int
479 is_controldom(void)
480 {
481 	return (DOMAIN_IS_INITDOMAIN(xen_info));
482 }
483 
484 #endif	/* __xpv */
485 
486 uint_t
487 cpuid_pass1(cpu_t *cpu)
488 {
489 	uint32_t mask_ecx, mask_edx;
490 	uint_t feature = X86_CPUID;
491 	struct cpuid_info *cpi;
492 	struct cpuid_regs *cp;
493 	int xcpuid;
494 #if !defined(__xpv)
495 	extern int idle_cpu_prefer_mwait;
496 #endif
497 
498 	/*
499 	 * Space statically allocated for cpu0, ensure pointer is set
500 	 */
501 	if (cpu->cpu_id == 0)
502 		cpu->cpu_m.mcpu_cpi = &cpuid_info0;
503 	cpi = cpu->cpu_m.mcpu_cpi;
504 	ASSERT(cpi != NULL);
505 	cp = &cpi->cpi_std[0];
506 	cp->cp_eax = 0;
507 	cpi->cpi_maxeax = __cpuid_insn(cp);
508 	{
509 		uint32_t *iptr = (uint32_t *)cpi->cpi_vendorstr;
510 		*iptr++ = cp->cp_ebx;
511 		*iptr++ = cp->cp_edx;
512 		*iptr++ = cp->cp_ecx;
513 		*(char *)&cpi->cpi_vendorstr[12] = '\0';
514 	}
515 
516 	cpi->cpi_vendor = _cpuid_vendorstr_to_vendorcode(cpi->cpi_vendorstr);
517 	x86_vendor = cpi->cpi_vendor; /* for compatibility */
518 
519 	/*
520 	 * Limit the range in case of weird hardware
521 	 */
522 	if (cpi->cpi_maxeax > CPI_MAXEAX_MAX)
523 		cpi->cpi_maxeax = CPI_MAXEAX_MAX;
524 	if (cpi->cpi_maxeax < 1)
525 		goto pass1_done;
526 
527 	cp = &cpi->cpi_std[1];
528 	cp->cp_eax = 1;
529 	(void) __cpuid_insn(cp);
530 
531 	/*
532 	 * Extract identifying constants for easy access.
533 	 */
534 	cpi->cpi_model = CPI_MODEL(cpi);
535 	cpi->cpi_family = CPI_FAMILY(cpi);
536 
537 	if (cpi->cpi_family == 0xf)
538 		cpi->cpi_family += CPI_FAMILY_XTD(cpi);
539 
540 	/*
541 	 * Beware: AMD uses "extended model" iff base *FAMILY* == 0xf.
542 	 * Intel, and presumably everyone else, uses model == 0xf, as
543 	 * one would expect (max value means possible overflow).  Sigh.
544 	 */
545 
546 	switch (cpi->cpi_vendor) {
547 	case X86_VENDOR_Intel:
548 		if (IS_EXTENDED_MODEL_INTEL(cpi))
549 			cpi->cpi_model += CPI_MODEL_XTD(cpi) << 4;
550 		break;
551 	case X86_VENDOR_AMD:
552 		if (CPI_FAMILY(cpi) == 0xf)
553 			cpi->cpi_model += CPI_MODEL_XTD(cpi) << 4;
554 		break;
555 	default:
556 		if (cpi->cpi_model == 0xf)
557 			cpi->cpi_model += CPI_MODEL_XTD(cpi) << 4;
558 		break;
559 	}
560 
561 	cpi->cpi_step = CPI_STEP(cpi);
562 	cpi->cpi_brandid = CPI_BRANDID(cpi);
563 
564 	/*
565 	 * *default* assumptions:
566 	 * - believe %edx feature word
567 	 * - ignore %ecx feature word
568 	 * - 32-bit virtual and physical addressing
569 	 */
570 	mask_edx = 0xffffffff;
571 	mask_ecx = 0;
572 
573 	cpi->cpi_pabits = cpi->cpi_vabits = 32;
574 
575 	switch (cpi->cpi_vendor) {
576 	case X86_VENDOR_Intel:
577 		if (cpi->cpi_family == 5)
578 			x86_type = X86_TYPE_P5;
579 		else if (IS_LEGACY_P6(cpi)) {
580 			x86_type = X86_TYPE_P6;
581 			pentiumpro_bug4046376 = 1;
582 			pentiumpro_bug4064495 = 1;
583 			/*
584 			 * Clear the SEP bit when it was set erroneously
585 			 */
586 			if (cpi->cpi_model < 3 && cpi->cpi_step < 3)
587 				cp->cp_edx &= ~CPUID_INTC_EDX_SEP;
588 		} else if (IS_NEW_F6(cpi) || cpi->cpi_family == 0xf) {
589 			x86_type = X86_TYPE_P4;
590 			/*
591 			 * We don't currently depend on any of the %ecx
592 			 * features until Prescott, so we'll only check
593 			 * this from P4 onwards.  We might want to revisit
594 			 * that idea later.
595 			 */
596 			mask_ecx = 0xffffffff;
597 		} else if (cpi->cpi_family > 0xf)
598 			mask_ecx = 0xffffffff;
599 		/*
600 		 * We don't support MONITOR/MWAIT if leaf 5 is not available
601 		 * to obtain the monitor linesize.
602 		 */
603 		if (cpi->cpi_maxeax < 5)
604 			mask_ecx &= ~CPUID_INTC_ECX_MON;
605 		break;
606 	case X86_VENDOR_IntelClone:
607 	default:
608 		break;
609 	case X86_VENDOR_AMD:
610 #if defined(OPTERON_ERRATUM_108)
611 		if (cpi->cpi_family == 0xf && cpi->cpi_model == 0xe) {
612 			cp->cp_eax = (0xf0f & cp->cp_eax) | 0xc0;
613 			cpi->cpi_model = 0xc;
614 		} else
615 #endif
616 		if (cpi->cpi_family == 5) {
617 			/*
618 			 * AMD K5 and K6
619 			 *
620 			 * These CPUs have an incomplete implementation
621 			 * of MCA/MCE which we mask away.
622 			 */
623 			mask_edx &= ~(CPUID_INTC_EDX_MCE | CPUID_INTC_EDX_MCA);
624 
625 			/*
626 			 * Model 0 uses the wrong (APIC) bit
627 			 * to indicate PGE.  Fix it here.
628 			 */
629 			if (cpi->cpi_model == 0) {
630 				if (cp->cp_edx & 0x200) {
631 					cp->cp_edx &= ~0x200;
632 					cp->cp_edx |= CPUID_INTC_EDX_PGE;
633 				}
634 			}
635 
636 			/*
637 			 * Early models had problems w/ MMX; disable.
638 			 */
639 			if (cpi->cpi_model < 6)
640 				mask_edx &= ~CPUID_INTC_EDX_MMX;
641 		}
642 
643 		/*
644 		 * For newer families, SSE3 and CX16, at least, are valid;
645 		 * enable all
646 		 */
647 		if (cpi->cpi_family >= 0xf)
648 			mask_ecx = 0xffffffff;
649 		/*
650 		 * We don't support MONITOR/MWAIT if leaf 5 is not available
651 		 * to obtain the monitor linesize.
652 		 */
653 		if (cpi->cpi_maxeax < 5)
654 			mask_ecx &= ~CPUID_INTC_ECX_MON;
655 
656 #if !defined(__xpv)
657 		/*
658 		 * Do not use MONITOR/MWAIT to halt in the idle loop on any AMD
659 		 * processors.  AMD does not intend MWAIT to be used in the cpu
660 		 * idle loop on current and future processors.  10h and future
661 		 * AMD processors use more power in MWAIT than HLT.
662 		 * Pre-family-10h Opterons do not have the MWAIT instruction.
663 		 */
664 		idle_cpu_prefer_mwait = 0;
665 #endif
666 
667 		break;
668 	case X86_VENDOR_TM:
669 		/*
670 		 * workaround the NT workaround in CMS 4.1
671 		 */
672 		if (cpi->cpi_family == 5 && cpi->cpi_model == 4 &&
673 		    (cpi->cpi_step == 2 || cpi->cpi_step == 3))
674 			cp->cp_edx |= CPUID_INTC_EDX_CX8;
675 		break;
676 	case X86_VENDOR_Centaur:
677 		/*
678 		 * workaround the NT workarounds again
679 		 */
680 		if (cpi->cpi_family == 6)
681 			cp->cp_edx |= CPUID_INTC_EDX_CX8;
682 		break;
683 	case X86_VENDOR_Cyrix:
684 		/*
685 		 * We rely heavily on the probing in locore
686 		 * to actually figure out what parts, if any,
687 		 * of the Cyrix cpuid instruction to believe.
688 		 */
689 		switch (x86_type) {
690 		case X86_TYPE_CYRIX_486:
691 			mask_edx = 0;
692 			break;
693 		case X86_TYPE_CYRIX_6x86:
694 			mask_edx = 0;
695 			break;
696 		case X86_TYPE_CYRIX_6x86L:
697 			mask_edx =
698 			    CPUID_INTC_EDX_DE |
699 			    CPUID_INTC_EDX_CX8;
700 			break;
701 		case X86_TYPE_CYRIX_6x86MX:
702 			mask_edx =
703 			    CPUID_INTC_EDX_DE |
704 			    CPUID_INTC_EDX_MSR |
705 			    CPUID_INTC_EDX_CX8 |
706 			    CPUID_INTC_EDX_PGE |
707 			    CPUID_INTC_EDX_CMOV |
708 			    CPUID_INTC_EDX_MMX;
709 			break;
710 		case X86_TYPE_CYRIX_GXm:
711 			mask_edx =
712 			    CPUID_INTC_EDX_MSR |
713 			    CPUID_INTC_EDX_CX8 |
714 			    CPUID_INTC_EDX_CMOV |
715 			    CPUID_INTC_EDX_MMX;
716 			break;
717 		case X86_TYPE_CYRIX_MediaGX:
718 			break;
719 		case X86_TYPE_CYRIX_MII:
720 		case X86_TYPE_VIA_CYRIX_III:
721 			mask_edx =
722 			    CPUID_INTC_EDX_DE |
723 			    CPUID_INTC_EDX_TSC |
724 			    CPUID_INTC_EDX_MSR |
725 			    CPUID_INTC_EDX_CX8 |
726 			    CPUID_INTC_EDX_PGE |
727 			    CPUID_INTC_EDX_CMOV |
728 			    CPUID_INTC_EDX_MMX;
729 			break;
730 		default:
731 			break;
732 		}
733 		break;
734 	}
735 
736 #if defined(__xpv)
737 	/*
738 	 * Do not support MONITOR/MWAIT under a hypervisor
739 	 */
740 	mask_ecx &= ~CPUID_INTC_ECX_MON;
741 #endif	/* __xpv */
742 
743 	/*
744 	 * Now we've figured out the masks that determine
745 	 * which bits we choose to believe, apply the masks
746 	 * to the feature words, then map the kernel's view
747 	 * of these feature words into its feature word.
748 	 */
749 	cp->cp_edx &= mask_edx;
750 	cp->cp_ecx &= mask_ecx;
751 
752 	/*
753 	 * apply any platform restrictions (we don't call this
754 	 * immediately after __cpuid_insn here, because we need the
755 	 * workarounds applied above first)
756 	 */
757 	platform_cpuid_mangle(cpi->cpi_vendor, 1, cp);
758 
759 	/*
760 	 * fold in overrides from the "eeprom" mechanism
761 	 */
762 	cp->cp_edx |= cpuid_feature_edx_include;
763 	cp->cp_edx &= ~cpuid_feature_edx_exclude;
764 
765 	cp->cp_ecx |= cpuid_feature_ecx_include;
766 	cp->cp_ecx &= ~cpuid_feature_ecx_exclude;
767 
768 	if (cp->cp_edx & CPUID_INTC_EDX_PSE)
769 		feature |= X86_LARGEPAGE;
770 	if (cp->cp_edx & CPUID_INTC_EDX_TSC)
771 		feature |= X86_TSC;
772 	if (cp->cp_edx & CPUID_INTC_EDX_MSR)
773 		feature |= X86_MSR;
774 	if (cp->cp_edx & CPUID_INTC_EDX_MTRR)
775 		feature |= X86_MTRR;
776 	if (cp->cp_edx & CPUID_INTC_EDX_PGE)
777 		feature |= X86_PGE;
778 	if (cp->cp_edx & CPUID_INTC_EDX_CMOV)
779 		feature |= X86_CMOV;
780 	if (cp->cp_edx & CPUID_INTC_EDX_MMX)
781 		feature |= X86_MMX;
782 	if ((cp->cp_edx & CPUID_INTC_EDX_MCE) != 0 &&
783 	    (cp->cp_edx & CPUID_INTC_EDX_MCA) != 0)
784 		feature |= X86_MCA;
785 	if (cp->cp_edx & CPUID_INTC_EDX_PAE)
786 		feature |= X86_PAE;
787 	if (cp->cp_edx & CPUID_INTC_EDX_CX8)
788 		feature |= X86_CX8;
789 	if (cp->cp_ecx & CPUID_INTC_ECX_CX16)
790 		feature |= X86_CX16;
791 	if (cp->cp_edx & CPUID_INTC_EDX_PAT)
792 		feature |= X86_PAT;
793 	if (cp->cp_edx & CPUID_INTC_EDX_SEP)
794 		feature |= X86_SEP;
795 	if (cp->cp_edx & CPUID_INTC_EDX_FXSR) {
796 		/*
797 		 * In our implementation, fxsave/fxrstor
798 		 * are prerequisites before we'll even
799 		 * try and do SSE things.
800 		 */
801 		if (cp->cp_edx & CPUID_INTC_EDX_SSE)
802 			feature |= X86_SSE;
803 		if (cp->cp_edx & CPUID_INTC_EDX_SSE2)
804 			feature |= X86_SSE2;
805 		if (cp->cp_ecx & CPUID_INTC_ECX_SSE3)
806 			feature |= X86_SSE3;
807 		if (cpi->cpi_vendor == X86_VENDOR_Intel) {
808 			if (cp->cp_ecx & CPUID_INTC_ECX_SSSE3)
809 				feature |= X86_SSSE3;
810 			if (cp->cp_ecx & CPUID_INTC_ECX_SSE4_1)
811 				feature |= X86_SSE4_1;
812 			if (cp->cp_ecx & CPUID_INTC_ECX_SSE4_2)
813 				feature |= X86_SSE4_2;
814 		}
815 	}
816 	if (cp->cp_edx & CPUID_INTC_EDX_DE)
817 		feature |= X86_DE;
818 #if !defined(__xpv)
819 	if (cp->cp_ecx & CPUID_INTC_ECX_MON) {
820 
821 		/*
822 		 * We require the CLFLUSH instruction for erratum workaround
823 		 * to use MONITOR/MWAIT.
824 		 */
825 		if (cp->cp_edx & CPUID_INTC_EDX_CLFSH) {
826 			cpi->cpi_mwait.support |= MWAIT_SUPPORT;
827 			feature |= X86_MWAIT;
828 		} else {
829 			extern int idle_cpu_assert_cflush_monitor;
830 
831 			/*
832 			 * All processors we are aware of which have
833 			 * MONITOR/MWAIT also have CLFLUSH.
834 			 */
835 			if (idle_cpu_assert_cflush_monitor) {
836 				ASSERT((cp->cp_ecx & CPUID_INTC_ECX_MON) &&
837 				    (cp->cp_edx & CPUID_INTC_EDX_CLFSH));
838 			}
839 		}
840 	}
841 #endif	/* __xpv */
842 
843 	/*
844 	 * Only need it first time, rest of the cpus would follow suite.
845 	 * we only capture this for the bootcpu.
846 	 */
847 	if (cp->cp_edx & CPUID_INTC_EDX_CLFSH) {
848 		feature |= X86_CLFSH;
849 		x86_clflush_size = (BITX(cp->cp_ebx, 15, 8) * 8);
850 	}
851 
852 	if (feature & X86_PAE)
853 		cpi->cpi_pabits = 36;
854 
855 	/*
856 	 * Hyperthreading configuration is slightly tricky on Intel
857 	 * and pure clones, and even trickier on AMD.
858 	 *
859 	 * (AMD chose to set the HTT bit on their CMP processors,
860 	 * even though they're not actually hyperthreaded.  Thus it
861 	 * takes a bit more work to figure out what's really going
862 	 * on ... see the handling of the CMP_LGCY bit below)
863 	 */
864 	if (cp->cp_edx & CPUID_INTC_EDX_HTT) {
865 		cpi->cpi_ncpu_per_chip = CPI_CPU_COUNT(cpi);
866 		if (cpi->cpi_ncpu_per_chip > 1)
867 			feature |= X86_HTT;
868 	} else {
869 		cpi->cpi_ncpu_per_chip = 1;
870 	}
871 
872 	/*
873 	 * Work on the "extended" feature information, doing
874 	 * some basic initialization for cpuid_pass2()
875 	 */
876 	xcpuid = 0;
877 	switch (cpi->cpi_vendor) {
878 	case X86_VENDOR_Intel:
879 		if (IS_NEW_F6(cpi) || cpi->cpi_family >= 0xf)
880 			xcpuid++;
881 		break;
882 	case X86_VENDOR_AMD:
883 		if (cpi->cpi_family > 5 ||
884 		    (cpi->cpi_family == 5 && cpi->cpi_model >= 1))
885 			xcpuid++;
886 		break;
887 	case X86_VENDOR_Cyrix:
888 		/*
889 		 * Only these Cyrix CPUs are -known- to support
890 		 * extended cpuid operations.
891 		 */
892 		if (x86_type == X86_TYPE_VIA_CYRIX_III ||
893 		    x86_type == X86_TYPE_CYRIX_GXm)
894 			xcpuid++;
895 		break;
896 	case X86_VENDOR_Centaur:
897 	case X86_VENDOR_TM:
898 	default:
899 		xcpuid++;
900 		break;
901 	}
902 
903 	if (xcpuid) {
904 		cp = &cpi->cpi_extd[0];
905 		cp->cp_eax = 0x80000000;
906 		cpi->cpi_xmaxeax = __cpuid_insn(cp);
907 	}
908 
909 	if (cpi->cpi_xmaxeax & 0x80000000) {
910 
911 		if (cpi->cpi_xmaxeax > CPI_XMAXEAX_MAX)
912 			cpi->cpi_xmaxeax = CPI_XMAXEAX_MAX;
913 
914 		switch (cpi->cpi_vendor) {
915 		case X86_VENDOR_Intel:
916 		case X86_VENDOR_AMD:
917 			if (cpi->cpi_xmaxeax < 0x80000001)
918 				break;
919 			cp = &cpi->cpi_extd[1];
920 			cp->cp_eax = 0x80000001;
921 			(void) __cpuid_insn(cp);
922 
923 			if (cpi->cpi_vendor == X86_VENDOR_AMD &&
924 			    cpi->cpi_family == 5 &&
925 			    cpi->cpi_model == 6 &&
926 			    cpi->cpi_step == 6) {
927 				/*
928 				 * K6 model 6 uses bit 10 to indicate SYSC
929 				 * Later models use bit 11. Fix it here.
930 				 */
931 				if (cp->cp_edx & 0x400) {
932 					cp->cp_edx &= ~0x400;
933 					cp->cp_edx |= CPUID_AMD_EDX_SYSC;
934 				}
935 			}
936 
937 			platform_cpuid_mangle(cpi->cpi_vendor, 0x80000001, cp);
938 
939 			/*
940 			 * Compute the additions to the kernel's feature word.
941 			 */
942 			if (cp->cp_edx & CPUID_AMD_EDX_NX)
943 				feature |= X86_NX;
944 
945 			/*
946 			 * Regardless whether or not we boot 64-bit,
947 			 * we should have a way to identify whether
948 			 * the CPU is capable of running 64-bit.
949 			 */
950 			if (cp->cp_edx & CPUID_AMD_EDX_LM)
951 				feature |= X86_64;
952 
953 #if defined(__amd64)
954 			/* 1 GB large page - enable only for 64 bit kernel */
955 			if (cp->cp_edx & CPUID_AMD_EDX_1GPG)
956 				feature |= X86_1GPG;
957 #endif
958 
959 			if ((cpi->cpi_vendor == X86_VENDOR_AMD) &&
960 			    (cpi->cpi_std[1].cp_edx & CPUID_INTC_EDX_FXSR) &&
961 			    (cp->cp_ecx & CPUID_AMD_ECX_SSE4A))
962 				feature |= X86_SSE4A;
963 
964 			/*
965 			 * If both the HTT and CMP_LGCY bits are set,
966 			 * then we're not actually HyperThreaded.  Read
967 			 * "AMD CPUID Specification" for more details.
968 			 */
969 			if (cpi->cpi_vendor == X86_VENDOR_AMD &&
970 			    (feature & X86_HTT) &&
971 			    (cp->cp_ecx & CPUID_AMD_ECX_CMP_LGCY)) {
972 				feature &= ~X86_HTT;
973 				feature |= X86_CMP;
974 			}
975 #if defined(__amd64)
976 			/*
977 			 * It's really tricky to support syscall/sysret in
978 			 * the i386 kernel; we rely on sysenter/sysexit
979 			 * instead.  In the amd64 kernel, things are -way-
980 			 * better.
981 			 */
982 			if (cp->cp_edx & CPUID_AMD_EDX_SYSC)
983 				feature |= X86_ASYSC;
984 
985 			/*
986 			 * While we're thinking about system calls, note
987 			 * that AMD processors don't support sysenter
988 			 * in long mode at all, so don't try to program them.
989 			 */
990 			if (x86_vendor == X86_VENDOR_AMD)
991 				feature &= ~X86_SEP;
992 #endif
993 			if (cp->cp_edx & CPUID_AMD_EDX_TSCP)
994 				feature |= X86_TSCP;
995 			break;
996 		default:
997 			break;
998 		}
999 
1000 		/*
1001 		 * Get CPUID data about processor cores and hyperthreads.
1002 		 */
1003 		switch (cpi->cpi_vendor) {
1004 		case X86_VENDOR_Intel:
1005 			if (cpi->cpi_maxeax >= 4) {
1006 				cp = &cpi->cpi_std[4];
1007 				cp->cp_eax = 4;
1008 				cp->cp_ecx = 0;
1009 				(void) __cpuid_insn(cp);
1010 				platform_cpuid_mangle(cpi->cpi_vendor, 4, cp);
1011 			}
1012 			/*FALLTHROUGH*/
1013 		case X86_VENDOR_AMD:
1014 			if (cpi->cpi_xmaxeax < 0x80000008)
1015 				break;
1016 			cp = &cpi->cpi_extd[8];
1017 			cp->cp_eax = 0x80000008;
1018 			(void) __cpuid_insn(cp);
1019 			platform_cpuid_mangle(cpi->cpi_vendor, 0x80000008, cp);
1020 
1021 			/*
1022 			 * Virtual and physical address limits from
1023 			 * cpuid override previously guessed values.
1024 			 */
1025 			cpi->cpi_pabits = BITX(cp->cp_eax, 7, 0);
1026 			cpi->cpi_vabits = BITX(cp->cp_eax, 15, 8);
1027 			break;
1028 		default:
1029 			break;
1030 		}
1031 
1032 		/*
1033 		 * Derive the number of cores per chip
1034 		 */
1035 		switch (cpi->cpi_vendor) {
1036 		case X86_VENDOR_Intel:
1037 			if (cpi->cpi_maxeax < 4) {
1038 				cpi->cpi_ncore_per_chip = 1;
1039 				break;
1040 			} else {
1041 				cpi->cpi_ncore_per_chip =
1042 				    BITX((cpi)->cpi_std[4].cp_eax, 31, 26) + 1;
1043 			}
1044 			break;
1045 		case X86_VENDOR_AMD:
1046 			if (cpi->cpi_xmaxeax < 0x80000008) {
1047 				cpi->cpi_ncore_per_chip = 1;
1048 				break;
1049 			} else {
1050 				/*
1051 				 * On family 0xf cpuid fn 2 ECX[7:0] "NC" is
1052 				 * 1 less than the number of physical cores on
1053 				 * the chip.  In family 0x10 this value can
1054 				 * be affected by "downcoring" - it reflects
1055 				 * 1 less than the number of cores actually
1056 				 * enabled on this node.
1057 				 */
1058 				cpi->cpi_ncore_per_chip =
1059 				    BITX((cpi)->cpi_extd[8].cp_ecx, 7, 0) + 1;
1060 			}
1061 			break;
1062 		default:
1063 			cpi->cpi_ncore_per_chip = 1;
1064 			break;
1065 		}
1066 
1067 		/*
1068 		 * Get CPUID data about TSC Invariance in Deep C-State.
1069 		 */
1070 		switch (cpi->cpi_vendor) {
1071 		case X86_VENDOR_Intel:
1072 			if (cpi->cpi_maxeax >= 7) {
1073 				cp = &cpi->cpi_extd[7];
1074 				cp->cp_eax = 0x80000007;
1075 				cp->cp_ecx = 0;
1076 				(void) __cpuid_insn(cp);
1077 			}
1078 			break;
1079 		default:
1080 			break;
1081 		}
1082 	} else {
1083 		cpi->cpi_ncore_per_chip = 1;
1084 	}
1085 
1086 	/*
1087 	 * If more than one core, then this processor is CMP.
1088 	 */
1089 	if (cpi->cpi_ncore_per_chip > 1)
1090 		feature |= X86_CMP;
1091 
1092 	/*
1093 	 * If the number of cores is the same as the number
1094 	 * of CPUs, then we cannot have HyperThreading.
1095 	 */
1096 	if (cpi->cpi_ncpu_per_chip == cpi->cpi_ncore_per_chip)
1097 		feature &= ~X86_HTT;
1098 
1099 	if ((feature & (X86_HTT | X86_CMP)) == 0) {
1100 		/*
1101 		 * Single-core single-threaded processors.
1102 		 */
1103 		cpi->cpi_chipid = -1;
1104 		cpi->cpi_clogid = 0;
1105 		cpi->cpi_coreid = cpu->cpu_id;
1106 		cpi->cpi_pkgcoreid = 0;
1107 	} else if (cpi->cpi_ncpu_per_chip > 1) {
1108 		uint_t i;
1109 		uint_t chipid_shift = 0;
1110 		uint_t coreid_shift = 0;
1111 		uint_t apic_id = CPI_APIC_ID(cpi);
1112 
1113 		for (i = 1; i < cpi->cpi_ncpu_per_chip; i <<= 1)
1114 			chipid_shift++;
1115 		cpi->cpi_chipid = apic_id >> chipid_shift;
1116 		cpi->cpi_clogid = apic_id & ((1 << chipid_shift) - 1);
1117 
1118 		if (cpi->cpi_vendor == X86_VENDOR_Intel) {
1119 			if (feature & X86_CMP) {
1120 				/*
1121 				 * Multi-core (and possibly multi-threaded)
1122 				 * processors.
1123 				 */
1124 				uint_t ncpu_per_core;
1125 				if (cpi->cpi_ncore_per_chip == 1)
1126 					ncpu_per_core = cpi->cpi_ncpu_per_chip;
1127 				else if (cpi->cpi_ncore_per_chip > 1)
1128 					ncpu_per_core = cpi->cpi_ncpu_per_chip /
1129 					    cpi->cpi_ncore_per_chip;
1130 				/*
1131 				 * 8bit APIC IDs on dual core Pentiums
1132 				 * look like this:
1133 				 *
1134 				 * +-----------------------+------+------+
1135 				 * | Physical Package ID   |  MC  |  HT  |
1136 				 * +-----------------------+------+------+
1137 				 * <------- chipid -------->
1138 				 * <------- coreid --------------->
1139 				 *			   <--- clogid -->
1140 				 *			   <------>
1141 				 *			   pkgcoreid
1142 				 *
1143 				 * Where the number of bits necessary to
1144 				 * represent MC and HT fields together equals
1145 				 * to the minimum number of bits necessary to
1146 				 * store the value of cpi->cpi_ncpu_per_chip.
1147 				 * Of those bits, the MC part uses the number
1148 				 * of bits necessary to store the value of
1149 				 * cpi->cpi_ncore_per_chip.
1150 				 */
1151 				for (i = 1; i < ncpu_per_core; i <<= 1)
1152 					coreid_shift++;
1153 				cpi->cpi_coreid = apic_id >> coreid_shift;
1154 				cpi->cpi_pkgcoreid = cpi->cpi_clogid >>
1155 				    coreid_shift;
1156 			} else if (feature & X86_HTT) {
1157 				/*
1158 				 * Single-core multi-threaded processors.
1159 				 */
1160 				cpi->cpi_coreid = cpi->cpi_chipid;
1161 				cpi->cpi_pkgcoreid = 0;
1162 			}
1163 		} else if (cpi->cpi_vendor == X86_VENDOR_AMD) {
1164 			/*
1165 			 * AMD CMP chips currently have a single thread per
1166 			 * core, with 2 cores on family 0xf and 2, 3 or 4
1167 			 * cores on family 0x10.
1168 			 *
1169 			 * Since no two cpus share a core we must assign a
1170 			 * distinct coreid per cpu, and we do this by using
1171 			 * the cpu_id.  This scheme does not, however,
1172 			 * guarantee that sibling cores of a chip will have
1173 			 * sequential coreids starting at a multiple of the
1174 			 * number of cores per chip - that is usually the
1175 			 * case, but if the ACPI MADT table is presented
1176 			 * in a different order then we need to perform a
1177 			 * few more gymnastics for the pkgcoreid.
1178 			 *
1179 			 * In family 0xf CMPs there are 2 cores on all nodes
1180 			 * present - no mixing of single and dual core parts.
1181 			 *
1182 			 * In family 0x10 CMPs cpuid fn 2 ECX[15:12]
1183 			 * "ApicIdCoreIdSize[3:0]" tells us how
1184 			 * many least-significant bits in the ApicId
1185 			 * are used to represent the core number
1186 			 * within the node.  Cores are always
1187 			 * numbered sequentially from 0 regardless
1188 			 * of how many or which are disabled, and
1189 			 * there seems to be no way to discover the
1190 			 * real core id when some are disabled.
1191 			 */
1192 			cpi->cpi_coreid = cpu->cpu_id;
1193 
1194 			if (cpi->cpi_family == 0x10 &&
1195 			    cpi->cpi_xmaxeax >= 0x80000008) {
1196 				int coreidsz =
1197 				    BITX((cpi)->cpi_extd[8].cp_ecx, 15, 12);
1198 
1199 				cpi->cpi_pkgcoreid =
1200 				    apic_id & ((1 << coreidsz) - 1);
1201 			} else {
1202 				cpi->cpi_pkgcoreid = cpi->cpi_clogid;
1203 			}
1204 		} else {
1205 			/*
1206 			 * All other processors are currently
1207 			 * assumed to have single cores.
1208 			 */
1209 			cpi->cpi_coreid = cpi->cpi_chipid;
1210 			cpi->cpi_pkgcoreid = 0;
1211 		}
1212 	}
1213 
1214 	cpi->cpi_apicid = CPI_APIC_ID(cpi);
1215 
1216 	/*
1217 	 * Synthesize chip "revision" and socket type
1218 	 */
1219 	cpi->cpi_chiprev = _cpuid_chiprev(cpi->cpi_vendor, cpi->cpi_family,
1220 	    cpi->cpi_model, cpi->cpi_step);
1221 	cpi->cpi_chiprevstr = _cpuid_chiprevstr(cpi->cpi_vendor,
1222 	    cpi->cpi_family, cpi->cpi_model, cpi->cpi_step);
1223 	cpi->cpi_socket = _cpuid_skt(cpi->cpi_vendor, cpi->cpi_family,
1224 	    cpi->cpi_model, cpi->cpi_step);
1225 
1226 pass1_done:
1227 #if !defined(__xpv)
1228 	determine_platform();
1229 #endif
1230 	cpi->cpi_pass = 1;
1231 	return (feature);
1232 }
1233 
1234 /*
1235  * Make copies of the cpuid table entries we depend on, in
1236  * part for ease of parsing now, in part so that we have only
1237  * one place to correct any of it, in part for ease of
1238  * later export to userland, and in part so we can look at
1239  * this stuff in a crash dump.
1240  */
1241 
1242 /*ARGSUSED*/
1243 void
1244 cpuid_pass2(cpu_t *cpu)
1245 {
1246 	uint_t n, nmax;
1247 	int i;
1248 	struct cpuid_regs *cp;
1249 	uint8_t *dp;
1250 	uint32_t *iptr;
1251 	struct cpuid_info *cpi = cpu->cpu_m.mcpu_cpi;
1252 
1253 	ASSERT(cpi->cpi_pass == 1);
1254 
1255 	if (cpi->cpi_maxeax < 1)
1256 		goto pass2_done;
1257 
1258 	if ((nmax = cpi->cpi_maxeax + 1) > NMAX_CPI_STD)
1259 		nmax = NMAX_CPI_STD;
1260 	/*
1261 	 * (We already handled n == 0 and n == 1 in pass 1)
1262 	 */
1263 	for (n = 2, cp = &cpi->cpi_std[2]; n < nmax; n++, cp++) {
1264 		cp->cp_eax = n;
1265 
1266 		/*
1267 		 * CPUID function 4 expects %ecx to be initialized
1268 		 * with an index which indicates which cache to return
1269 		 * information about. The OS is expected to call function 4
1270 		 * with %ecx set to 0, 1, 2, ... until it returns with
1271 		 * EAX[4:0] set to 0, which indicates there are no more
1272 		 * caches.
1273 		 *
1274 		 * Here, populate cpi_std[4] with the information returned by
1275 		 * function 4 when %ecx == 0, and do the rest in cpuid_pass3()
1276 		 * when dynamic memory allocation becomes available.
1277 		 *
1278 		 * Note: we need to explicitly initialize %ecx here, since
1279 		 * function 4 may have been previously invoked.
1280 		 */
1281 		if (n == 4)
1282 			cp->cp_ecx = 0;
1283 
1284 		(void) __cpuid_insn(cp);
1285 		platform_cpuid_mangle(cpi->cpi_vendor, n, cp);
1286 		switch (n) {
1287 		case 2:
1288 			/*
1289 			 * "the lower 8 bits of the %eax register
1290 			 * contain a value that identifies the number
1291 			 * of times the cpuid [instruction] has to be
1292 			 * executed to obtain a complete image of the
1293 			 * processor's caching systems."
1294 			 *
1295 			 * How *do* they make this stuff up?
1296 			 */
1297 			cpi->cpi_ncache = sizeof (*cp) *
1298 			    BITX(cp->cp_eax, 7, 0);
1299 			if (cpi->cpi_ncache == 0)
1300 				break;
1301 			cpi->cpi_ncache--;	/* skip count byte */
1302 
1303 			/*
1304 			 * Well, for now, rather than attempt to implement
1305 			 * this slightly dubious algorithm, we just look
1306 			 * at the first 15 ..
1307 			 */
1308 			if (cpi->cpi_ncache > (sizeof (*cp) - 1))
1309 				cpi->cpi_ncache = sizeof (*cp) - 1;
1310 
1311 			dp = cpi->cpi_cacheinfo;
1312 			if (BITX(cp->cp_eax, 31, 31) == 0) {
1313 				uint8_t *p = (void *)&cp->cp_eax;
1314 				for (i = 1; i < 4; i++)
1315 					if (p[i] != 0)
1316 						*dp++ = p[i];
1317 			}
1318 			if (BITX(cp->cp_ebx, 31, 31) == 0) {
1319 				uint8_t *p = (void *)&cp->cp_ebx;
1320 				for (i = 0; i < 4; i++)
1321 					if (p[i] != 0)
1322 						*dp++ = p[i];
1323 			}
1324 			if (BITX(cp->cp_ecx, 31, 31) == 0) {
1325 				uint8_t *p = (void *)&cp->cp_ecx;
1326 				for (i = 0; i < 4; i++)
1327 					if (p[i] != 0)
1328 						*dp++ = p[i];
1329 			}
1330 			if (BITX(cp->cp_edx, 31, 31) == 0) {
1331 				uint8_t *p = (void *)&cp->cp_edx;
1332 				for (i = 0; i < 4; i++)
1333 					if (p[i] != 0)
1334 						*dp++ = p[i];
1335 			}
1336 			break;
1337 
1338 		case 3:	/* Processor serial number, if PSN supported */
1339 			break;
1340 
1341 		case 4:	/* Deterministic cache parameters */
1342 			break;
1343 
1344 		case 5:	/* Monitor/Mwait parameters */
1345 		{
1346 			size_t mwait_size;
1347 
1348 			/*
1349 			 * check cpi_mwait.support which was set in cpuid_pass1
1350 			 */
1351 			if (!(cpi->cpi_mwait.support & MWAIT_SUPPORT))
1352 				break;
1353 
1354 			/*
1355 			 * Protect ourself from insane mwait line size.
1356 			 * Workaround for incomplete hardware emulator(s).
1357 			 */
1358 			mwait_size = (size_t)MWAIT_SIZE_MAX(cpi);
1359 			if (mwait_size < sizeof (uint32_t) ||
1360 			    !ISP2(mwait_size)) {
1361 #if DEBUG
1362 				cmn_err(CE_NOTE, "Cannot handle cpu %d mwait "
1363 				    "size %ld", cpu->cpu_id, (long)mwait_size);
1364 #endif
1365 				break;
1366 			}
1367 
1368 			cpi->cpi_mwait.mon_min = (size_t)MWAIT_SIZE_MIN(cpi);
1369 			cpi->cpi_mwait.mon_max = mwait_size;
1370 			if (MWAIT_EXTENSION(cpi)) {
1371 				cpi->cpi_mwait.support |= MWAIT_EXTENSIONS;
1372 				if (MWAIT_INT_ENABLE(cpi))
1373 					cpi->cpi_mwait.support |=
1374 					    MWAIT_ECX_INT_ENABLE;
1375 			}
1376 			break;
1377 		}
1378 		default:
1379 			break;
1380 		}
1381 	}
1382 
1383 	if (cpi->cpi_maxeax >= 0xB && cpi->cpi_vendor == X86_VENDOR_Intel) {
1384 		struct cpuid_regs regs;
1385 
1386 		cp = &regs;
1387 		cp->cp_eax = 0xB;
1388 		cp->cp_edx = cp->cp_ebx = cp->cp_ecx = 0;
1389 
1390 		(void) __cpuid_insn(cp);
1391 
1392 		/*
1393 		 * Check CPUID.EAX=0BH, ECX=0H:EBX is non-zero, which
1394 		 * indicates that the extended topology enumeration leaf is
1395 		 * available.
1396 		 */
1397 		if (cp->cp_ebx) {
1398 			uint32_t x2apic_id;
1399 			uint_t coreid_shift = 0;
1400 			uint_t ncpu_per_core = 1;
1401 			uint_t chipid_shift = 0;
1402 			uint_t ncpu_per_chip = 1;
1403 			uint_t i;
1404 			uint_t level;
1405 
1406 			for (i = 0; i < CPI_FNB_ECX_MAX; i++) {
1407 				cp->cp_eax = 0xB;
1408 				cp->cp_ecx = i;
1409 
1410 				(void) __cpuid_insn(cp);
1411 				level = CPI_CPU_LEVEL_TYPE(cp);
1412 
1413 				if (level == 1) {
1414 					x2apic_id = cp->cp_edx;
1415 					coreid_shift = BITX(cp->cp_eax, 4, 0);
1416 					ncpu_per_core = BITX(cp->cp_ebx, 15, 0);
1417 				} else if (level == 2) {
1418 					x2apic_id = cp->cp_edx;
1419 					chipid_shift = BITX(cp->cp_eax, 4, 0);
1420 					ncpu_per_chip = BITX(cp->cp_ebx, 15, 0);
1421 				}
1422 			}
1423 
1424 			cpi->cpi_apicid = x2apic_id;
1425 			cpi->cpi_ncpu_per_chip = ncpu_per_chip;
1426 			cpi->cpi_ncore_per_chip = ncpu_per_chip /
1427 			    ncpu_per_core;
1428 			cpi->cpi_chipid = x2apic_id >> chipid_shift;
1429 			cpi->cpi_clogid = x2apic_id & ((1 << chipid_shift) - 1);
1430 			cpi->cpi_coreid = x2apic_id >> coreid_shift;
1431 			cpi->cpi_pkgcoreid = cpi->cpi_clogid >> coreid_shift;
1432 		}
1433 
1434 		/* Make cp NULL so that we don't stumble on others */
1435 		cp = NULL;
1436 	}
1437 
1438 	if ((cpi->cpi_xmaxeax & 0x80000000) == 0)
1439 		goto pass2_done;
1440 
1441 	if ((nmax = cpi->cpi_xmaxeax - 0x80000000 + 1) > NMAX_CPI_EXTD)
1442 		nmax = NMAX_CPI_EXTD;
1443 	/*
1444 	 * Copy the extended properties, fixing them as we go.
1445 	 * (We already handled n == 0 and n == 1 in pass 1)
1446 	 */
1447 	iptr = (void *)cpi->cpi_brandstr;
1448 	for (n = 2, cp = &cpi->cpi_extd[2]; n < nmax; cp++, n++) {
1449 		cp->cp_eax = 0x80000000 + n;
1450 		(void) __cpuid_insn(cp);
1451 		platform_cpuid_mangle(cpi->cpi_vendor, 0x80000000 + n, cp);
1452 		switch (n) {
1453 		case 2:
1454 		case 3:
1455 		case 4:
1456 			/*
1457 			 * Extract the brand string
1458 			 */
1459 			*iptr++ = cp->cp_eax;
1460 			*iptr++ = cp->cp_ebx;
1461 			*iptr++ = cp->cp_ecx;
1462 			*iptr++ = cp->cp_edx;
1463 			break;
1464 		case 5:
1465 			switch (cpi->cpi_vendor) {
1466 			case X86_VENDOR_AMD:
1467 				/*
1468 				 * The Athlon and Duron were the first
1469 				 * parts to report the sizes of the
1470 				 * TLB for large pages. Before then,
1471 				 * we don't trust the data.
1472 				 */
1473 				if (cpi->cpi_family < 6 ||
1474 				    (cpi->cpi_family == 6 &&
1475 				    cpi->cpi_model < 1))
1476 					cp->cp_eax = 0;
1477 				break;
1478 			default:
1479 				break;
1480 			}
1481 			break;
1482 		case 6:
1483 			switch (cpi->cpi_vendor) {
1484 			case X86_VENDOR_AMD:
1485 				/*
1486 				 * The Athlon and Duron were the first
1487 				 * AMD parts with L2 TLB's.
1488 				 * Before then, don't trust the data.
1489 				 */
1490 				if (cpi->cpi_family < 6 ||
1491 				    cpi->cpi_family == 6 &&
1492 				    cpi->cpi_model < 1)
1493 					cp->cp_eax = cp->cp_ebx = 0;
1494 				/*
1495 				 * AMD Duron rev A0 reports L2
1496 				 * cache size incorrectly as 1K
1497 				 * when it is really 64K
1498 				 */
1499 				if (cpi->cpi_family == 6 &&
1500 				    cpi->cpi_model == 3 &&
1501 				    cpi->cpi_step == 0) {
1502 					cp->cp_ecx &= 0xffff;
1503 					cp->cp_ecx |= 0x400000;
1504 				}
1505 				break;
1506 			case X86_VENDOR_Cyrix:	/* VIA C3 */
1507 				/*
1508 				 * VIA C3 processors are a bit messed
1509 				 * up w.r.t. encoding cache sizes in %ecx
1510 				 */
1511 				if (cpi->cpi_family != 6)
1512 					break;
1513 				/*
1514 				 * model 7 and 8 were incorrectly encoded
1515 				 *
1516 				 * xxx is model 8 really broken?
1517 				 */
1518 				if (cpi->cpi_model == 7 ||
1519 				    cpi->cpi_model == 8)
1520 					cp->cp_ecx =
1521 					    BITX(cp->cp_ecx, 31, 24) << 16 |
1522 					    BITX(cp->cp_ecx, 23, 16) << 12 |
1523 					    BITX(cp->cp_ecx, 15, 8) << 8 |
1524 					    BITX(cp->cp_ecx, 7, 0);
1525 				/*
1526 				 * model 9 stepping 1 has wrong associativity
1527 				 */
1528 				if (cpi->cpi_model == 9 && cpi->cpi_step == 1)
1529 					cp->cp_ecx |= 8 << 12;
1530 				break;
1531 			case X86_VENDOR_Intel:
1532 				/*
1533 				 * Extended L2 Cache features function.
1534 				 * First appeared on Prescott.
1535 				 */
1536 			default:
1537 				break;
1538 			}
1539 			break;
1540 		default:
1541 			break;
1542 		}
1543 	}
1544 
1545 pass2_done:
1546 	cpi->cpi_pass = 2;
1547 }
1548 
1549 static const char *
1550 intel_cpubrand(const struct cpuid_info *cpi)
1551 {
1552 	int i;
1553 
1554 	if ((x86_feature & X86_CPUID) == 0 ||
1555 	    cpi->cpi_maxeax < 1 || cpi->cpi_family < 5)
1556 		return ("i486");
1557 
1558 	switch (cpi->cpi_family) {
1559 	case 5:
1560 		return ("Intel Pentium(r)");
1561 	case 6:
1562 		switch (cpi->cpi_model) {
1563 			uint_t celeron, xeon;
1564 			const struct cpuid_regs *cp;
1565 		case 0:
1566 		case 1:
1567 		case 2:
1568 			return ("Intel Pentium(r) Pro");
1569 		case 3:
1570 		case 4:
1571 			return ("Intel Pentium(r) II");
1572 		case 6:
1573 			return ("Intel Celeron(r)");
1574 		case 5:
1575 		case 7:
1576 			celeron = xeon = 0;
1577 			cp = &cpi->cpi_std[2];	/* cache info */
1578 
1579 			for (i = 1; i < 4; i++) {
1580 				uint_t tmp;
1581 
1582 				tmp = (cp->cp_eax >> (8 * i)) & 0xff;
1583 				if (tmp == 0x40)
1584 					celeron++;
1585 				if (tmp >= 0x44 && tmp <= 0x45)
1586 					xeon++;
1587 			}
1588 
1589 			for (i = 0; i < 2; i++) {
1590 				uint_t tmp;
1591 
1592 				tmp = (cp->cp_ebx >> (8 * i)) & 0xff;
1593 				if (tmp == 0x40)
1594 					celeron++;
1595 				else if (tmp >= 0x44 && tmp <= 0x45)
1596 					xeon++;
1597 			}
1598 
1599 			for (i = 0; i < 4; i++) {
1600 				uint_t tmp;
1601 
1602 				tmp = (cp->cp_ecx >> (8 * i)) & 0xff;
1603 				if (tmp == 0x40)
1604 					celeron++;
1605 				else if (tmp >= 0x44 && tmp <= 0x45)
1606 					xeon++;
1607 			}
1608 
1609 			for (i = 0; i < 4; i++) {
1610 				uint_t tmp;
1611 
1612 				tmp = (cp->cp_edx >> (8 * i)) & 0xff;
1613 				if (tmp == 0x40)
1614 					celeron++;
1615 				else if (tmp >= 0x44 && tmp <= 0x45)
1616 					xeon++;
1617 			}
1618 
1619 			if (celeron)
1620 				return ("Intel Celeron(r)");
1621 			if (xeon)
1622 				return (cpi->cpi_model == 5 ?
1623 				    "Intel Pentium(r) II Xeon(tm)" :
1624 				    "Intel Pentium(r) III Xeon(tm)");
1625 			return (cpi->cpi_model == 5 ?
1626 			    "Intel Pentium(r) II or Pentium(r) II Xeon(tm)" :
1627 			    "Intel Pentium(r) III or Pentium(r) III Xeon(tm)");
1628 		default:
1629 			break;
1630 		}
1631 	default:
1632 		break;
1633 	}
1634 
1635 	/* BrandID is present if the field is nonzero */
1636 	if (cpi->cpi_brandid != 0) {
1637 		static const struct {
1638 			uint_t bt_bid;
1639 			const char *bt_str;
1640 		} brand_tbl[] = {
1641 			{ 0x1,	"Intel(r) Celeron(r)" },
1642 			{ 0x2,	"Intel(r) Pentium(r) III" },
1643 			{ 0x3,	"Intel(r) Pentium(r) III Xeon(tm)" },
1644 			{ 0x4,	"Intel(r) Pentium(r) III" },
1645 			{ 0x6,	"Mobile Intel(r) Pentium(r) III" },
1646 			{ 0x7,	"Mobile Intel(r) Celeron(r)" },
1647 			{ 0x8,	"Intel(r) Pentium(r) 4" },
1648 			{ 0x9,	"Intel(r) Pentium(r) 4" },
1649 			{ 0xa,	"Intel(r) Celeron(r)" },
1650 			{ 0xb,	"Intel(r) Xeon(tm)" },
1651 			{ 0xc,	"Intel(r) Xeon(tm) MP" },
1652 			{ 0xe,	"Mobile Intel(r) Pentium(r) 4" },
1653 			{ 0xf,	"Mobile Intel(r) Celeron(r)" },
1654 			{ 0x11, "Mobile Genuine Intel(r)" },
1655 			{ 0x12, "Intel(r) Celeron(r) M" },
1656 			{ 0x13, "Mobile Intel(r) Celeron(r)" },
1657 			{ 0x14, "Intel(r) Celeron(r)" },
1658 			{ 0x15, "Mobile Genuine Intel(r)" },
1659 			{ 0x16,	"Intel(r) Pentium(r) M" },
1660 			{ 0x17, "Mobile Intel(r) Celeron(r)" }
1661 		};
1662 		uint_t btblmax = sizeof (brand_tbl) / sizeof (brand_tbl[0]);
1663 		uint_t sgn;
1664 
1665 		sgn = (cpi->cpi_family << 8) |
1666 		    (cpi->cpi_model << 4) | cpi->cpi_step;
1667 
1668 		for (i = 0; i < btblmax; i++)
1669 			if (brand_tbl[i].bt_bid == cpi->cpi_brandid)
1670 				break;
1671 		if (i < btblmax) {
1672 			if (sgn == 0x6b1 && cpi->cpi_brandid == 3)
1673 				return ("Intel(r) Celeron(r)");
1674 			if (sgn < 0xf13 && cpi->cpi_brandid == 0xb)
1675 				return ("Intel(r) Xeon(tm) MP");
1676 			if (sgn < 0xf13 && cpi->cpi_brandid == 0xe)
1677 				return ("Intel(r) Xeon(tm)");
1678 			return (brand_tbl[i].bt_str);
1679 		}
1680 	}
1681 
1682 	return (NULL);
1683 }
1684 
1685 static const char *
1686 amd_cpubrand(const struct cpuid_info *cpi)
1687 {
1688 	if ((x86_feature & X86_CPUID) == 0 ||
1689 	    cpi->cpi_maxeax < 1 || cpi->cpi_family < 5)
1690 		return ("i486 compatible");
1691 
1692 	switch (cpi->cpi_family) {
1693 	case 5:
1694 		switch (cpi->cpi_model) {
1695 		case 0:
1696 		case 1:
1697 		case 2:
1698 		case 3:
1699 		case 4:
1700 		case 5:
1701 			return ("AMD-K5(r)");
1702 		case 6:
1703 		case 7:
1704 			return ("AMD-K6(r)");
1705 		case 8:
1706 			return ("AMD-K6(r)-2");
1707 		case 9:
1708 			return ("AMD-K6(r)-III");
1709 		default:
1710 			return ("AMD (family 5)");
1711 		}
1712 	case 6:
1713 		switch (cpi->cpi_model) {
1714 		case 1:
1715 			return ("AMD-K7(tm)");
1716 		case 0:
1717 		case 2:
1718 		case 4:
1719 			return ("AMD Athlon(tm)");
1720 		case 3:
1721 		case 7:
1722 			return ("AMD Duron(tm)");
1723 		case 6:
1724 		case 8:
1725 		case 10:
1726 			/*
1727 			 * Use the L2 cache size to distinguish
1728 			 */
1729 			return ((cpi->cpi_extd[6].cp_ecx >> 16) >= 256 ?
1730 			    "AMD Athlon(tm)" : "AMD Duron(tm)");
1731 		default:
1732 			return ("AMD (family 6)");
1733 		}
1734 	default:
1735 		break;
1736 	}
1737 
1738 	if (cpi->cpi_family == 0xf && cpi->cpi_model == 5 &&
1739 	    cpi->cpi_brandid != 0) {
1740 		switch (BITX(cpi->cpi_brandid, 7, 5)) {
1741 		case 3:
1742 			return ("AMD Opteron(tm) UP 1xx");
1743 		case 4:
1744 			return ("AMD Opteron(tm) DP 2xx");
1745 		case 5:
1746 			return ("AMD Opteron(tm) MP 8xx");
1747 		default:
1748 			return ("AMD Opteron(tm)");
1749 		}
1750 	}
1751 
1752 	return (NULL);
1753 }
1754 
1755 static const char *
1756 cyrix_cpubrand(struct cpuid_info *cpi, uint_t type)
1757 {
1758 	if ((x86_feature & X86_CPUID) == 0 ||
1759 	    cpi->cpi_maxeax < 1 || cpi->cpi_family < 5 ||
1760 	    type == X86_TYPE_CYRIX_486)
1761 		return ("i486 compatible");
1762 
1763 	switch (type) {
1764 	case X86_TYPE_CYRIX_6x86:
1765 		return ("Cyrix 6x86");
1766 	case X86_TYPE_CYRIX_6x86L:
1767 		return ("Cyrix 6x86L");
1768 	case X86_TYPE_CYRIX_6x86MX:
1769 		return ("Cyrix 6x86MX");
1770 	case X86_TYPE_CYRIX_GXm:
1771 		return ("Cyrix GXm");
1772 	case X86_TYPE_CYRIX_MediaGX:
1773 		return ("Cyrix MediaGX");
1774 	case X86_TYPE_CYRIX_MII:
1775 		return ("Cyrix M2");
1776 	case X86_TYPE_VIA_CYRIX_III:
1777 		return ("VIA Cyrix M3");
1778 	default:
1779 		/*
1780 		 * Have another wild guess ..
1781 		 */
1782 		if (cpi->cpi_family == 4 && cpi->cpi_model == 9)
1783 			return ("Cyrix 5x86");
1784 		else if (cpi->cpi_family == 5) {
1785 			switch (cpi->cpi_model) {
1786 			case 2:
1787 				return ("Cyrix 6x86");	/* Cyrix M1 */
1788 			case 4:
1789 				return ("Cyrix MediaGX");
1790 			default:
1791 				break;
1792 			}
1793 		} else if (cpi->cpi_family == 6) {
1794 			switch (cpi->cpi_model) {
1795 			case 0:
1796 				return ("Cyrix 6x86MX"); /* Cyrix M2? */
1797 			case 5:
1798 			case 6:
1799 			case 7:
1800 			case 8:
1801 			case 9:
1802 				return ("VIA C3");
1803 			default:
1804 				break;
1805 			}
1806 		}
1807 		break;
1808 	}
1809 	return (NULL);
1810 }
1811 
1812 /*
1813  * This only gets called in the case that the CPU extended
1814  * feature brand string (0x80000002, 0x80000003, 0x80000004)
1815  * aren't available, or contain null bytes for some reason.
1816  */
1817 static void
1818 fabricate_brandstr(struct cpuid_info *cpi)
1819 {
1820 	const char *brand = NULL;
1821 
1822 	switch (cpi->cpi_vendor) {
1823 	case X86_VENDOR_Intel:
1824 		brand = intel_cpubrand(cpi);
1825 		break;
1826 	case X86_VENDOR_AMD:
1827 		brand = amd_cpubrand(cpi);
1828 		break;
1829 	case X86_VENDOR_Cyrix:
1830 		brand = cyrix_cpubrand(cpi, x86_type);
1831 		break;
1832 	case X86_VENDOR_NexGen:
1833 		if (cpi->cpi_family == 5 && cpi->cpi_model == 0)
1834 			brand = "NexGen Nx586";
1835 		break;
1836 	case X86_VENDOR_Centaur:
1837 		if (cpi->cpi_family == 5)
1838 			switch (cpi->cpi_model) {
1839 			case 4:
1840 				brand = "Centaur C6";
1841 				break;
1842 			case 8:
1843 				brand = "Centaur C2";
1844 				break;
1845 			case 9:
1846 				brand = "Centaur C3";
1847 				break;
1848 			default:
1849 				break;
1850 			}
1851 		break;
1852 	case X86_VENDOR_Rise:
1853 		if (cpi->cpi_family == 5 &&
1854 		    (cpi->cpi_model == 0 || cpi->cpi_model == 2))
1855 			brand = "Rise mP6";
1856 		break;
1857 	case X86_VENDOR_SiS:
1858 		if (cpi->cpi_family == 5 && cpi->cpi_model == 0)
1859 			brand = "SiS 55x";
1860 		break;
1861 	case X86_VENDOR_TM:
1862 		if (cpi->cpi_family == 5 && cpi->cpi_model == 4)
1863 			brand = "Transmeta Crusoe TM3x00 or TM5x00";
1864 		break;
1865 	case X86_VENDOR_NSC:
1866 	case X86_VENDOR_UMC:
1867 	default:
1868 		break;
1869 	}
1870 	if (brand) {
1871 		(void) strcpy((char *)cpi->cpi_brandstr, brand);
1872 		return;
1873 	}
1874 
1875 	/*
1876 	 * If all else fails ...
1877 	 */
1878 	(void) snprintf(cpi->cpi_brandstr, sizeof (cpi->cpi_brandstr),
1879 	    "%s %d.%d.%d", cpi->cpi_vendorstr, cpi->cpi_family,
1880 	    cpi->cpi_model, cpi->cpi_step);
1881 }
1882 
1883 /*
1884  * This routine is called just after kernel memory allocation
1885  * becomes available on cpu0, and as part of mp_startup() on
1886  * the other cpus.
1887  *
1888  * Fixup the brand string, and collect any information from cpuid
1889  * that requires dynamicically allocated storage to represent.
1890  */
1891 /*ARGSUSED*/
1892 void
1893 cpuid_pass3(cpu_t *cpu)
1894 {
1895 	int	i, max, shft, level, size;
1896 	struct cpuid_regs regs;
1897 	struct cpuid_regs *cp;
1898 	struct cpuid_info *cpi = cpu->cpu_m.mcpu_cpi;
1899 
1900 	ASSERT(cpi->cpi_pass == 2);
1901 
1902 	/*
1903 	 * Function 4: Deterministic cache parameters
1904 	 *
1905 	 * Take this opportunity to detect the number of threads
1906 	 * sharing the last level cache, and construct a corresponding
1907 	 * cache id. The respective cpuid_info members are initialized
1908 	 * to the default case of "no last level cache sharing".
1909 	 */
1910 	cpi->cpi_ncpu_shr_last_cache = 1;
1911 	cpi->cpi_last_lvl_cacheid = cpu->cpu_id;
1912 
1913 	if (cpi->cpi_maxeax >= 4 && cpi->cpi_vendor == X86_VENDOR_Intel) {
1914 
1915 		/*
1916 		 * Find the # of elements (size) returned by fn 4, and along
1917 		 * the way detect last level cache sharing details.
1918 		 */
1919 		bzero(&regs, sizeof (regs));
1920 		cp = &regs;
1921 		for (i = 0, max = 0; i < CPI_FN4_ECX_MAX; i++) {
1922 			cp->cp_eax = 4;
1923 			cp->cp_ecx = i;
1924 
1925 			(void) __cpuid_insn(cp);
1926 
1927 			if (CPI_CACHE_TYPE(cp) == 0)
1928 				break;
1929 			level = CPI_CACHE_LVL(cp);
1930 			if (level > max) {
1931 				max = level;
1932 				cpi->cpi_ncpu_shr_last_cache =
1933 				    CPI_NTHR_SHR_CACHE(cp) + 1;
1934 			}
1935 		}
1936 		cpi->cpi_std_4_size = size = i;
1937 
1938 		/*
1939 		 * Allocate the cpi_std_4 array. The first element
1940 		 * references the regs for fn 4, %ecx == 0, which
1941 		 * cpuid_pass2() stashed in cpi->cpi_std[4].
1942 		 */
1943 		if (size > 0) {
1944 			cpi->cpi_std_4 =
1945 			    kmem_alloc(size * sizeof (cp), KM_SLEEP);
1946 			cpi->cpi_std_4[0] = &cpi->cpi_std[4];
1947 
1948 			/*
1949 			 * Allocate storage to hold the additional regs
1950 			 * for function 4, %ecx == 1 .. cpi_std_4_size.
1951 			 *
1952 			 * The regs for fn 4, %ecx == 0 has already
1953 			 * been allocated as indicated above.
1954 			 */
1955 			for (i = 1; i < size; i++) {
1956 				cp = cpi->cpi_std_4[i] =
1957 				    kmem_zalloc(sizeof (regs), KM_SLEEP);
1958 				cp->cp_eax = 4;
1959 				cp->cp_ecx = i;
1960 
1961 				(void) __cpuid_insn(cp);
1962 			}
1963 		}
1964 		/*
1965 		 * Determine the number of bits needed to represent
1966 		 * the number of CPUs sharing the last level cache.
1967 		 *
1968 		 * Shift off that number of bits from the APIC id to
1969 		 * derive the cache id.
1970 		 */
1971 		shft = 0;
1972 		for (i = 1; i < cpi->cpi_ncpu_shr_last_cache; i <<= 1)
1973 			shft++;
1974 		cpi->cpi_last_lvl_cacheid = cpi->cpi_apicid >> shft;
1975 	}
1976 
1977 	/*
1978 	 * Now fixup the brand string
1979 	 */
1980 	if ((cpi->cpi_xmaxeax & 0x80000000) == 0) {
1981 		fabricate_brandstr(cpi);
1982 	} else {
1983 
1984 		/*
1985 		 * If we successfully extracted a brand string from the cpuid
1986 		 * instruction, clean it up by removing leading spaces and
1987 		 * similar junk.
1988 		 */
1989 		if (cpi->cpi_brandstr[0]) {
1990 			size_t maxlen = sizeof (cpi->cpi_brandstr);
1991 			char *src, *dst;
1992 
1993 			dst = src = (char *)cpi->cpi_brandstr;
1994 			src[maxlen - 1] = '\0';
1995 			/*
1996 			 * strip leading spaces
1997 			 */
1998 			while (*src == ' ')
1999 				src++;
2000 			/*
2001 			 * Remove any 'Genuine' or "Authentic" prefixes
2002 			 */
2003 			if (strncmp(src, "Genuine ", 8) == 0)
2004 				src += 8;
2005 			if (strncmp(src, "Authentic ", 10) == 0)
2006 				src += 10;
2007 
2008 			/*
2009 			 * Now do an in-place copy.
2010 			 * Map (R) to (r) and (TM) to (tm).
2011 			 * The era of teletypes is long gone, and there's
2012 			 * -really- no need to shout.
2013 			 */
2014 			while (*src != '\0') {
2015 				if (src[0] == '(') {
2016 					if (strncmp(src + 1, "R)", 2) == 0) {
2017 						(void) strncpy(dst, "(r)", 3);
2018 						src += 3;
2019 						dst += 3;
2020 						continue;
2021 					}
2022 					if (strncmp(src + 1, "TM)", 3) == 0) {
2023 						(void) strncpy(dst, "(tm)", 4);
2024 						src += 4;
2025 						dst += 4;
2026 						continue;
2027 					}
2028 				}
2029 				*dst++ = *src++;
2030 			}
2031 			*dst = '\0';
2032 
2033 			/*
2034 			 * Finally, remove any trailing spaces
2035 			 */
2036 			while (--dst > cpi->cpi_brandstr)
2037 				if (*dst == ' ')
2038 					*dst = '\0';
2039 				else
2040 					break;
2041 		} else
2042 			fabricate_brandstr(cpi);
2043 	}
2044 	cpi->cpi_pass = 3;
2045 }
2046 
2047 /*
2048  * This routine is called out of bind_hwcap() much later in the life
2049  * of the kernel (post_startup()).  The job of this routine is to resolve
2050  * the hardware feature support and kernel support for those features into
2051  * what we're actually going to tell applications via the aux vector.
2052  */
2053 uint_t
2054 cpuid_pass4(cpu_t *cpu)
2055 {
2056 	struct cpuid_info *cpi;
2057 	uint_t hwcap_flags = 0;
2058 
2059 	if (cpu == NULL)
2060 		cpu = CPU;
2061 	cpi = cpu->cpu_m.mcpu_cpi;
2062 
2063 	ASSERT(cpi->cpi_pass == 3);
2064 
2065 	if (cpi->cpi_maxeax >= 1) {
2066 		uint32_t *edx = &cpi->cpi_support[STD_EDX_FEATURES];
2067 		uint32_t *ecx = &cpi->cpi_support[STD_ECX_FEATURES];
2068 
2069 		*edx = CPI_FEATURES_EDX(cpi);
2070 		*ecx = CPI_FEATURES_ECX(cpi);
2071 
2072 		/*
2073 		 * [these require explicit kernel support]
2074 		 */
2075 		if ((x86_feature & X86_SEP) == 0)
2076 			*edx &= ~CPUID_INTC_EDX_SEP;
2077 
2078 		if ((x86_feature & X86_SSE) == 0)
2079 			*edx &= ~(CPUID_INTC_EDX_FXSR|CPUID_INTC_EDX_SSE);
2080 		if ((x86_feature & X86_SSE2) == 0)
2081 			*edx &= ~CPUID_INTC_EDX_SSE2;
2082 
2083 		if ((x86_feature & X86_HTT) == 0)
2084 			*edx &= ~CPUID_INTC_EDX_HTT;
2085 
2086 		if ((x86_feature & X86_SSE3) == 0)
2087 			*ecx &= ~CPUID_INTC_ECX_SSE3;
2088 
2089 		if (cpi->cpi_vendor == X86_VENDOR_Intel) {
2090 			if ((x86_feature & X86_SSSE3) == 0)
2091 				*ecx &= ~CPUID_INTC_ECX_SSSE3;
2092 			if ((x86_feature & X86_SSE4_1) == 0)
2093 				*ecx &= ~CPUID_INTC_ECX_SSE4_1;
2094 			if ((x86_feature & X86_SSE4_2) == 0)
2095 				*ecx &= ~CPUID_INTC_ECX_SSE4_2;
2096 		}
2097 
2098 		/*
2099 		 * [no explicit support required beyond x87 fp context]
2100 		 */
2101 		if (!fpu_exists)
2102 			*edx &= ~(CPUID_INTC_EDX_FPU | CPUID_INTC_EDX_MMX);
2103 
2104 		/*
2105 		 * Now map the supported feature vector to things that we
2106 		 * think userland will care about.
2107 		 */
2108 		if (*edx & CPUID_INTC_EDX_SEP)
2109 			hwcap_flags |= AV_386_SEP;
2110 		if (*edx & CPUID_INTC_EDX_SSE)
2111 			hwcap_flags |= AV_386_FXSR | AV_386_SSE;
2112 		if (*edx & CPUID_INTC_EDX_SSE2)
2113 			hwcap_flags |= AV_386_SSE2;
2114 		if (*ecx & CPUID_INTC_ECX_SSE3)
2115 			hwcap_flags |= AV_386_SSE3;
2116 		if (cpi->cpi_vendor == X86_VENDOR_Intel) {
2117 			if (*ecx & CPUID_INTC_ECX_SSSE3)
2118 				hwcap_flags |= AV_386_SSSE3;
2119 			if (*ecx & CPUID_INTC_ECX_SSE4_1)
2120 				hwcap_flags |= AV_386_SSE4_1;
2121 			if (*ecx & CPUID_INTC_ECX_SSE4_2)
2122 				hwcap_flags |= AV_386_SSE4_2;
2123 			if (*ecx & CPUID_INTC_ECX_MOVBE)
2124 				hwcap_flags |= AV_386_MOVBE;
2125 		}
2126 		if (*ecx & CPUID_INTC_ECX_POPCNT)
2127 			hwcap_flags |= AV_386_POPCNT;
2128 		if (*edx & CPUID_INTC_EDX_FPU)
2129 			hwcap_flags |= AV_386_FPU;
2130 		if (*edx & CPUID_INTC_EDX_MMX)
2131 			hwcap_flags |= AV_386_MMX;
2132 
2133 		if (*edx & CPUID_INTC_EDX_TSC)
2134 			hwcap_flags |= AV_386_TSC;
2135 		if (*edx & CPUID_INTC_EDX_CX8)
2136 			hwcap_flags |= AV_386_CX8;
2137 		if (*edx & CPUID_INTC_EDX_CMOV)
2138 			hwcap_flags |= AV_386_CMOV;
2139 		if (*ecx & CPUID_INTC_ECX_MON)
2140 			hwcap_flags |= AV_386_MON;
2141 		if (*ecx & CPUID_INTC_ECX_CX16)
2142 			hwcap_flags |= AV_386_CX16;
2143 	}
2144 
2145 	if (x86_feature & X86_HTT)
2146 		hwcap_flags |= AV_386_PAUSE;
2147 
2148 	if (cpi->cpi_xmaxeax < 0x80000001)
2149 		goto pass4_done;
2150 
2151 	switch (cpi->cpi_vendor) {
2152 		struct cpuid_regs cp;
2153 		uint32_t *edx, *ecx;
2154 
2155 	case X86_VENDOR_Intel:
2156 		/*
2157 		 * Seems like Intel duplicated what we necessary
2158 		 * here to make the initial crop of 64-bit OS's work.
2159 		 * Hopefully, those are the only "extended" bits
2160 		 * they'll add.
2161 		 */
2162 		/*FALLTHROUGH*/
2163 
2164 	case X86_VENDOR_AMD:
2165 		edx = &cpi->cpi_support[AMD_EDX_FEATURES];
2166 		ecx = &cpi->cpi_support[AMD_ECX_FEATURES];
2167 
2168 		*edx = CPI_FEATURES_XTD_EDX(cpi);
2169 		*ecx = CPI_FEATURES_XTD_ECX(cpi);
2170 
2171 		/*
2172 		 * [these features require explicit kernel support]
2173 		 */
2174 		switch (cpi->cpi_vendor) {
2175 		case X86_VENDOR_Intel:
2176 			if ((x86_feature & X86_TSCP) == 0)
2177 				*edx &= ~CPUID_AMD_EDX_TSCP;
2178 			break;
2179 
2180 		case X86_VENDOR_AMD:
2181 			if ((x86_feature & X86_TSCP) == 0)
2182 				*edx &= ~CPUID_AMD_EDX_TSCP;
2183 			if ((x86_feature & X86_SSE4A) == 0)
2184 				*ecx &= ~CPUID_AMD_ECX_SSE4A;
2185 			break;
2186 
2187 		default:
2188 			break;
2189 		}
2190 
2191 		/*
2192 		 * [no explicit support required beyond
2193 		 * x87 fp context and exception handlers]
2194 		 */
2195 		if (!fpu_exists)
2196 			*edx &= ~(CPUID_AMD_EDX_MMXamd |
2197 			    CPUID_AMD_EDX_3DNow | CPUID_AMD_EDX_3DNowx);
2198 
2199 		if ((x86_feature & X86_NX) == 0)
2200 			*edx &= ~CPUID_AMD_EDX_NX;
2201 #if !defined(__amd64)
2202 		*edx &= ~CPUID_AMD_EDX_LM;
2203 #endif
2204 		/*
2205 		 * Now map the supported feature vector to
2206 		 * things that we think userland will care about.
2207 		 */
2208 #if defined(__amd64)
2209 		if (*edx & CPUID_AMD_EDX_SYSC)
2210 			hwcap_flags |= AV_386_AMD_SYSC;
2211 #endif
2212 		if (*edx & CPUID_AMD_EDX_MMXamd)
2213 			hwcap_flags |= AV_386_AMD_MMX;
2214 		if (*edx & CPUID_AMD_EDX_3DNow)
2215 			hwcap_flags |= AV_386_AMD_3DNow;
2216 		if (*edx & CPUID_AMD_EDX_3DNowx)
2217 			hwcap_flags |= AV_386_AMD_3DNowx;
2218 
2219 		switch (cpi->cpi_vendor) {
2220 		case X86_VENDOR_AMD:
2221 			if (*edx & CPUID_AMD_EDX_TSCP)
2222 				hwcap_flags |= AV_386_TSCP;
2223 			if (*ecx & CPUID_AMD_ECX_AHF64)
2224 				hwcap_flags |= AV_386_AHF;
2225 			if (*ecx & CPUID_AMD_ECX_SSE4A)
2226 				hwcap_flags |= AV_386_AMD_SSE4A;
2227 			if (*ecx & CPUID_AMD_ECX_LZCNT)
2228 				hwcap_flags |= AV_386_AMD_LZCNT;
2229 			break;
2230 
2231 		case X86_VENDOR_Intel:
2232 			if (*edx & CPUID_AMD_EDX_TSCP)
2233 				hwcap_flags |= AV_386_TSCP;
2234 			/*
2235 			 * Aarrgh.
2236 			 * Intel uses a different bit in the same word.
2237 			 */
2238 			if (*ecx & CPUID_INTC_ECX_AHF64)
2239 				hwcap_flags |= AV_386_AHF;
2240 			break;
2241 
2242 		default:
2243 			break;
2244 		}
2245 		break;
2246 
2247 	case X86_VENDOR_TM:
2248 		cp.cp_eax = 0x80860001;
2249 		(void) __cpuid_insn(&cp);
2250 		cpi->cpi_support[TM_EDX_FEATURES] = cp.cp_edx;
2251 		break;
2252 
2253 	default:
2254 		break;
2255 	}
2256 
2257 pass4_done:
2258 	cpi->cpi_pass = 4;
2259 	return (hwcap_flags);
2260 }
2261 
2262 
2263 /*
2264  * Simulate the cpuid instruction using the data we previously
2265  * captured about this CPU.  We try our best to return the truth
2266  * about the hardware, independently of kernel support.
2267  */
2268 uint32_t
2269 cpuid_insn(cpu_t *cpu, struct cpuid_regs *cp)
2270 {
2271 	struct cpuid_info *cpi;
2272 	struct cpuid_regs *xcp;
2273 
2274 	if (cpu == NULL)
2275 		cpu = CPU;
2276 	cpi = cpu->cpu_m.mcpu_cpi;
2277 
2278 	ASSERT(cpuid_checkpass(cpu, 3));
2279 
2280 	/*
2281 	 * CPUID data is cached in two separate places: cpi_std for standard
2282 	 * CPUID functions, and cpi_extd for extended CPUID functions.
2283 	 */
2284 	if (cp->cp_eax <= cpi->cpi_maxeax && cp->cp_eax < NMAX_CPI_STD)
2285 		xcp = &cpi->cpi_std[cp->cp_eax];
2286 	else if (cp->cp_eax >= 0x80000000 && cp->cp_eax <= cpi->cpi_xmaxeax &&
2287 	    cp->cp_eax < 0x80000000 + NMAX_CPI_EXTD)
2288 		xcp = &cpi->cpi_extd[cp->cp_eax - 0x80000000];
2289 	else
2290 		/*
2291 		 * The caller is asking for data from an input parameter which
2292 		 * the kernel has not cached.  In this case we go fetch from
2293 		 * the hardware and return the data directly to the user.
2294 		 */
2295 		return (__cpuid_insn(cp));
2296 
2297 	cp->cp_eax = xcp->cp_eax;
2298 	cp->cp_ebx = xcp->cp_ebx;
2299 	cp->cp_ecx = xcp->cp_ecx;
2300 	cp->cp_edx = xcp->cp_edx;
2301 	return (cp->cp_eax);
2302 }
2303 
2304 int
2305 cpuid_checkpass(cpu_t *cpu, int pass)
2306 {
2307 	return (cpu != NULL && cpu->cpu_m.mcpu_cpi != NULL &&
2308 	    cpu->cpu_m.mcpu_cpi->cpi_pass >= pass);
2309 }
2310 
2311 int
2312 cpuid_getbrandstr(cpu_t *cpu, char *s, size_t n)
2313 {
2314 	ASSERT(cpuid_checkpass(cpu, 3));
2315 
2316 	return (snprintf(s, n, "%s", cpu->cpu_m.mcpu_cpi->cpi_brandstr));
2317 }
2318 
2319 int
2320 cpuid_is_cmt(cpu_t *cpu)
2321 {
2322 	if (cpu == NULL)
2323 		cpu = CPU;
2324 
2325 	ASSERT(cpuid_checkpass(cpu, 1));
2326 
2327 	return (cpu->cpu_m.mcpu_cpi->cpi_chipid >= 0);
2328 }
2329 
2330 /*
2331  * AMD and Intel both implement the 64-bit variant of the syscall
2332  * instruction (syscallq), so if there's -any- support for syscall,
2333  * cpuid currently says "yes, we support this".
2334  *
2335  * However, Intel decided to -not- implement the 32-bit variant of the
2336  * syscall instruction, so we provide a predicate to allow our caller
2337  * to test that subtlety here.
2338  *
2339  * XXPV	Currently, 32-bit syscall instructions don't work via the hypervisor,
2340  *	even in the case where the hardware would in fact support it.
2341  */
2342 /*ARGSUSED*/
2343 int
2344 cpuid_syscall32_insn(cpu_t *cpu)
2345 {
2346 	ASSERT(cpuid_checkpass((cpu == NULL ? CPU : cpu), 1));
2347 
2348 #if !defined(__xpv)
2349 	if (cpu == NULL)
2350 		cpu = CPU;
2351 
2352 	/*CSTYLED*/
2353 	{
2354 		struct cpuid_info *cpi = cpu->cpu_m.mcpu_cpi;
2355 
2356 		if (cpi->cpi_vendor == X86_VENDOR_AMD &&
2357 		    cpi->cpi_xmaxeax >= 0x80000001 &&
2358 		    (CPI_FEATURES_XTD_EDX(cpi) & CPUID_AMD_EDX_SYSC))
2359 			return (1);
2360 	}
2361 #endif
2362 	return (0);
2363 }
2364 
2365 int
2366 cpuid_getidstr(cpu_t *cpu, char *s, size_t n)
2367 {
2368 	struct cpuid_info *cpi = cpu->cpu_m.mcpu_cpi;
2369 
2370 	static const char fmt[] =
2371 	    "x86 (%s %X family %d model %d step %d clock %d MHz)";
2372 	static const char fmt_ht[] =
2373 	    "x86 (chipid 0x%x %s %X family %d model %d step %d clock %d MHz)";
2374 
2375 	ASSERT(cpuid_checkpass(cpu, 1));
2376 
2377 	if (cpuid_is_cmt(cpu))
2378 		return (snprintf(s, n, fmt_ht, cpi->cpi_chipid,
2379 		    cpi->cpi_vendorstr, cpi->cpi_std[1].cp_eax,
2380 		    cpi->cpi_family, cpi->cpi_model,
2381 		    cpi->cpi_step, cpu->cpu_type_info.pi_clock));
2382 	return (snprintf(s, n, fmt,
2383 	    cpi->cpi_vendorstr, cpi->cpi_std[1].cp_eax,
2384 	    cpi->cpi_family, cpi->cpi_model,
2385 	    cpi->cpi_step, cpu->cpu_type_info.pi_clock));
2386 }
2387 
2388 const char *
2389 cpuid_getvendorstr(cpu_t *cpu)
2390 {
2391 	ASSERT(cpuid_checkpass(cpu, 1));
2392 	return ((const char *)cpu->cpu_m.mcpu_cpi->cpi_vendorstr);
2393 }
2394 
2395 uint_t
2396 cpuid_getvendor(cpu_t *cpu)
2397 {
2398 	ASSERT(cpuid_checkpass(cpu, 1));
2399 	return (cpu->cpu_m.mcpu_cpi->cpi_vendor);
2400 }
2401 
2402 uint_t
2403 cpuid_getfamily(cpu_t *cpu)
2404 {
2405 	ASSERT(cpuid_checkpass(cpu, 1));
2406 	return (cpu->cpu_m.mcpu_cpi->cpi_family);
2407 }
2408 
2409 uint_t
2410 cpuid_getmodel(cpu_t *cpu)
2411 {
2412 	ASSERT(cpuid_checkpass(cpu, 1));
2413 	return (cpu->cpu_m.mcpu_cpi->cpi_model);
2414 }
2415 
2416 uint_t
2417 cpuid_get_ncpu_per_chip(cpu_t *cpu)
2418 {
2419 	ASSERT(cpuid_checkpass(cpu, 1));
2420 	return (cpu->cpu_m.mcpu_cpi->cpi_ncpu_per_chip);
2421 }
2422 
2423 uint_t
2424 cpuid_get_ncore_per_chip(cpu_t *cpu)
2425 {
2426 	ASSERT(cpuid_checkpass(cpu, 1));
2427 	return (cpu->cpu_m.mcpu_cpi->cpi_ncore_per_chip);
2428 }
2429 
2430 uint_t
2431 cpuid_get_ncpu_sharing_last_cache(cpu_t *cpu)
2432 {
2433 	ASSERT(cpuid_checkpass(cpu, 2));
2434 	return (cpu->cpu_m.mcpu_cpi->cpi_ncpu_shr_last_cache);
2435 }
2436 
2437 id_t
2438 cpuid_get_last_lvl_cacheid(cpu_t *cpu)
2439 {
2440 	ASSERT(cpuid_checkpass(cpu, 2));
2441 	return (cpu->cpu_m.mcpu_cpi->cpi_last_lvl_cacheid);
2442 }
2443 
2444 uint_t
2445 cpuid_getstep(cpu_t *cpu)
2446 {
2447 	ASSERT(cpuid_checkpass(cpu, 1));
2448 	return (cpu->cpu_m.mcpu_cpi->cpi_step);
2449 }
2450 
2451 uint_t
2452 cpuid_getsig(struct cpu *cpu)
2453 {
2454 	ASSERT(cpuid_checkpass(cpu, 1));
2455 	return (cpu->cpu_m.mcpu_cpi->cpi_std[1].cp_eax);
2456 }
2457 
2458 uint32_t
2459 cpuid_getchiprev(struct cpu *cpu)
2460 {
2461 	ASSERT(cpuid_checkpass(cpu, 1));
2462 	return (cpu->cpu_m.mcpu_cpi->cpi_chiprev);
2463 }
2464 
2465 const char *
2466 cpuid_getchiprevstr(struct cpu *cpu)
2467 {
2468 	ASSERT(cpuid_checkpass(cpu, 1));
2469 	return (cpu->cpu_m.mcpu_cpi->cpi_chiprevstr);
2470 }
2471 
2472 uint32_t
2473 cpuid_getsockettype(struct cpu *cpu)
2474 {
2475 	ASSERT(cpuid_checkpass(cpu, 1));
2476 	return (cpu->cpu_m.mcpu_cpi->cpi_socket);
2477 }
2478 
2479 int
2480 cpuid_get_chipid(cpu_t *cpu)
2481 {
2482 	ASSERT(cpuid_checkpass(cpu, 1));
2483 
2484 	if (cpuid_is_cmt(cpu))
2485 		return (cpu->cpu_m.mcpu_cpi->cpi_chipid);
2486 	return (cpu->cpu_id);
2487 }
2488 
2489 id_t
2490 cpuid_get_coreid(cpu_t *cpu)
2491 {
2492 	ASSERT(cpuid_checkpass(cpu, 1));
2493 	return (cpu->cpu_m.mcpu_cpi->cpi_coreid);
2494 }
2495 
2496 int
2497 cpuid_get_pkgcoreid(cpu_t *cpu)
2498 {
2499 	ASSERT(cpuid_checkpass(cpu, 1));
2500 	return (cpu->cpu_m.mcpu_cpi->cpi_pkgcoreid);
2501 }
2502 
2503 int
2504 cpuid_get_clogid(cpu_t *cpu)
2505 {
2506 	ASSERT(cpuid_checkpass(cpu, 1));
2507 	return (cpu->cpu_m.mcpu_cpi->cpi_clogid);
2508 }
2509 
2510 void
2511 cpuid_get_addrsize(cpu_t *cpu, uint_t *pabits, uint_t *vabits)
2512 {
2513 	struct cpuid_info *cpi;
2514 
2515 	if (cpu == NULL)
2516 		cpu = CPU;
2517 	cpi = cpu->cpu_m.mcpu_cpi;
2518 
2519 	ASSERT(cpuid_checkpass(cpu, 1));
2520 
2521 	if (pabits)
2522 		*pabits = cpi->cpi_pabits;
2523 	if (vabits)
2524 		*vabits = cpi->cpi_vabits;
2525 }
2526 
2527 /*
2528  * Returns the number of data TLB entries for a corresponding
2529  * pagesize.  If it can't be computed, or isn't known, the
2530  * routine returns zero.  If you ask about an architecturally
2531  * impossible pagesize, the routine will panic (so that the
2532  * hat implementor knows that things are inconsistent.)
2533  */
2534 uint_t
2535 cpuid_get_dtlb_nent(cpu_t *cpu, size_t pagesize)
2536 {
2537 	struct cpuid_info *cpi;
2538 	uint_t dtlb_nent = 0;
2539 
2540 	if (cpu == NULL)
2541 		cpu = CPU;
2542 	cpi = cpu->cpu_m.mcpu_cpi;
2543 
2544 	ASSERT(cpuid_checkpass(cpu, 1));
2545 
2546 	/*
2547 	 * Check the L2 TLB info
2548 	 */
2549 	if (cpi->cpi_xmaxeax >= 0x80000006) {
2550 		struct cpuid_regs *cp = &cpi->cpi_extd[6];
2551 
2552 		switch (pagesize) {
2553 
2554 		case 4 * 1024:
2555 			/*
2556 			 * All zero in the top 16 bits of the register
2557 			 * indicates a unified TLB. Size is in low 16 bits.
2558 			 */
2559 			if ((cp->cp_ebx & 0xffff0000) == 0)
2560 				dtlb_nent = cp->cp_ebx & 0x0000ffff;
2561 			else
2562 				dtlb_nent = BITX(cp->cp_ebx, 27, 16);
2563 			break;
2564 
2565 		case 2 * 1024 * 1024:
2566 			if ((cp->cp_eax & 0xffff0000) == 0)
2567 				dtlb_nent = cp->cp_eax & 0x0000ffff;
2568 			else
2569 				dtlb_nent = BITX(cp->cp_eax, 27, 16);
2570 			break;
2571 
2572 		default:
2573 			panic("unknown L2 pagesize");
2574 			/*NOTREACHED*/
2575 		}
2576 	}
2577 
2578 	if (dtlb_nent != 0)
2579 		return (dtlb_nent);
2580 
2581 	/*
2582 	 * No L2 TLB support for this size, try L1.
2583 	 */
2584 	if (cpi->cpi_xmaxeax >= 0x80000005) {
2585 		struct cpuid_regs *cp = &cpi->cpi_extd[5];
2586 
2587 		switch (pagesize) {
2588 		case 4 * 1024:
2589 			dtlb_nent = BITX(cp->cp_ebx, 23, 16);
2590 			break;
2591 		case 2 * 1024 * 1024:
2592 			dtlb_nent = BITX(cp->cp_eax, 23, 16);
2593 			break;
2594 		default:
2595 			panic("unknown L1 d-TLB pagesize");
2596 			/*NOTREACHED*/
2597 		}
2598 	}
2599 
2600 	return (dtlb_nent);
2601 }
2602 
2603 /*
2604  * Return 0 if the erratum is not present or not applicable, positive
2605  * if it is, and negative if the status of the erratum is unknown.
2606  *
2607  * See "Revision Guide for AMD Athlon(tm) 64 and AMD Opteron(tm)
2608  * Processors" #25759, Rev 3.57, August 2005
2609  */
2610 int
2611 cpuid_opteron_erratum(cpu_t *cpu, uint_t erratum)
2612 {
2613 	struct cpuid_info *cpi = cpu->cpu_m.mcpu_cpi;
2614 	uint_t eax;
2615 
2616 	/*
2617 	 * Bail out if this CPU isn't an AMD CPU, or if it's
2618 	 * a legacy (32-bit) AMD CPU.
2619 	 */
2620 	if (cpi->cpi_vendor != X86_VENDOR_AMD ||
2621 	    cpi->cpi_family == 4 || cpi->cpi_family == 5 ||
2622 	    cpi->cpi_family == 6)
2623 
2624 		return (0);
2625 
2626 	eax = cpi->cpi_std[1].cp_eax;
2627 
2628 #define	SH_B0(eax)	(eax == 0xf40 || eax == 0xf50)
2629 #define	SH_B3(eax) 	(eax == 0xf51)
2630 #define	B(eax)		(SH_B0(eax) || SH_B3(eax))
2631 
2632 #define	SH_C0(eax)	(eax == 0xf48 || eax == 0xf58)
2633 
2634 #define	SH_CG(eax)	(eax == 0xf4a || eax == 0xf5a || eax == 0xf7a)
2635 #define	DH_CG(eax)	(eax == 0xfc0 || eax == 0xfe0 || eax == 0xff0)
2636 #define	CH_CG(eax)	(eax == 0xf82 || eax == 0xfb2)
2637 #define	CG(eax)		(SH_CG(eax) || DH_CG(eax) || CH_CG(eax))
2638 
2639 #define	SH_D0(eax)	(eax == 0x10f40 || eax == 0x10f50 || eax == 0x10f70)
2640 #define	DH_D0(eax)	(eax == 0x10fc0 || eax == 0x10ff0)
2641 #define	CH_D0(eax)	(eax == 0x10f80 || eax == 0x10fb0)
2642 #define	D0(eax)		(SH_D0(eax) || DH_D0(eax) || CH_D0(eax))
2643 
2644 #define	SH_E0(eax)	(eax == 0x20f50 || eax == 0x20f40 || eax == 0x20f70)
2645 #define	JH_E1(eax)	(eax == 0x20f10)	/* JH8_E0 had 0x20f30 */
2646 #define	DH_E3(eax)	(eax == 0x20fc0 || eax == 0x20ff0)
2647 #define	SH_E4(eax)	(eax == 0x20f51 || eax == 0x20f71)
2648 #define	BH_E4(eax)	(eax == 0x20fb1)
2649 #define	SH_E5(eax)	(eax == 0x20f42)
2650 #define	DH_E6(eax)	(eax == 0x20ff2 || eax == 0x20fc2)
2651 #define	JH_E6(eax)	(eax == 0x20f12 || eax == 0x20f32)
2652 #define	EX(eax)		(SH_E0(eax) || JH_E1(eax) || DH_E3(eax) || \
2653 			    SH_E4(eax) || BH_E4(eax) || SH_E5(eax) || \
2654 			    DH_E6(eax) || JH_E6(eax))
2655 
2656 #define	DR_AX(eax)	(eax == 0x100f00 || eax == 0x100f01 || eax == 0x100f02)
2657 #define	DR_B0(eax)	(eax == 0x100f20)
2658 #define	DR_B1(eax)	(eax == 0x100f21)
2659 #define	DR_BA(eax)	(eax == 0x100f2a)
2660 #define	DR_B2(eax)	(eax == 0x100f22)
2661 #define	DR_B3(eax)	(eax == 0x100f23)
2662 #define	RB_C0(eax)	(eax == 0x100f40)
2663 
2664 	switch (erratum) {
2665 	case 1:
2666 		return (cpi->cpi_family < 0x10);
2667 	case 51:	/* what does the asterisk mean? */
2668 		return (B(eax) || SH_C0(eax) || CG(eax));
2669 	case 52:
2670 		return (B(eax));
2671 	case 57:
2672 		return (cpi->cpi_family <= 0x11);
2673 	case 58:
2674 		return (B(eax));
2675 	case 60:
2676 		return (cpi->cpi_family <= 0x11);
2677 	case 61:
2678 	case 62:
2679 	case 63:
2680 	case 64:
2681 	case 65:
2682 	case 66:
2683 	case 68:
2684 	case 69:
2685 	case 70:
2686 	case 71:
2687 		return (B(eax));
2688 	case 72:
2689 		return (SH_B0(eax));
2690 	case 74:
2691 		return (B(eax));
2692 	case 75:
2693 		return (cpi->cpi_family < 0x10);
2694 	case 76:
2695 		return (B(eax));
2696 	case 77:
2697 		return (cpi->cpi_family <= 0x11);
2698 	case 78:
2699 		return (B(eax) || SH_C0(eax));
2700 	case 79:
2701 		return (B(eax) || SH_C0(eax) || CG(eax) || D0(eax) || EX(eax));
2702 	case 80:
2703 	case 81:
2704 	case 82:
2705 		return (B(eax));
2706 	case 83:
2707 		return (B(eax) || SH_C0(eax) || CG(eax));
2708 	case 85:
2709 		return (cpi->cpi_family < 0x10);
2710 	case 86:
2711 		return (SH_C0(eax) || CG(eax));
2712 	case 88:
2713 #if !defined(__amd64)
2714 		return (0);
2715 #else
2716 		return (B(eax) || SH_C0(eax));
2717 #endif
2718 	case 89:
2719 		return (cpi->cpi_family < 0x10);
2720 	case 90:
2721 		return (B(eax) || SH_C0(eax) || CG(eax));
2722 	case 91:
2723 	case 92:
2724 		return (B(eax) || SH_C0(eax));
2725 	case 93:
2726 		return (SH_C0(eax));
2727 	case 94:
2728 		return (B(eax) || SH_C0(eax) || CG(eax));
2729 	case 95:
2730 #if !defined(__amd64)
2731 		return (0);
2732 #else
2733 		return (B(eax) || SH_C0(eax));
2734 #endif
2735 	case 96:
2736 		return (B(eax) || SH_C0(eax) || CG(eax));
2737 	case 97:
2738 	case 98:
2739 		return (SH_C0(eax) || CG(eax));
2740 	case 99:
2741 		return (B(eax) || SH_C0(eax) || CG(eax) || D0(eax));
2742 	case 100:
2743 		return (B(eax) || SH_C0(eax));
2744 	case 101:
2745 	case 103:
2746 		return (B(eax) || SH_C0(eax) || CG(eax) || D0(eax));
2747 	case 104:
2748 		return (SH_C0(eax) || CG(eax) || D0(eax));
2749 	case 105:
2750 	case 106:
2751 	case 107:
2752 		return (B(eax) || SH_C0(eax) || CG(eax) || D0(eax));
2753 	case 108:
2754 		return (DH_CG(eax));
2755 	case 109:
2756 		return (SH_C0(eax) || CG(eax) || D0(eax));
2757 	case 110:
2758 		return (D0(eax) || EX(eax));
2759 	case 111:
2760 		return (CG(eax));
2761 	case 112:
2762 		return (B(eax) || SH_C0(eax) || CG(eax) || D0(eax) || EX(eax));
2763 	case 113:
2764 		return (eax == 0x20fc0);
2765 	case 114:
2766 		return (SH_E0(eax) || JH_E1(eax) || DH_E3(eax));
2767 	case 115:
2768 		return (SH_E0(eax) || JH_E1(eax));
2769 	case 116:
2770 		return (SH_E0(eax) || JH_E1(eax) || DH_E3(eax));
2771 	case 117:
2772 		return (B(eax) || SH_C0(eax) || CG(eax) || D0(eax));
2773 	case 118:
2774 		return (SH_E0(eax) || JH_E1(eax) || SH_E4(eax) || BH_E4(eax) ||
2775 		    JH_E6(eax));
2776 	case 121:
2777 		return (B(eax) || SH_C0(eax) || CG(eax) || D0(eax) || EX(eax));
2778 	case 122:
2779 		return (cpi->cpi_family < 0x10 || cpi->cpi_family == 0x11);
2780 	case 123:
2781 		return (JH_E1(eax) || BH_E4(eax) || JH_E6(eax));
2782 	case 131:
2783 		return (cpi->cpi_family < 0x10);
2784 	case 6336786:
2785 		/*
2786 		 * Test for AdvPowerMgmtInfo.TscPStateInvariant
2787 		 * if this is a K8 family or newer processor
2788 		 */
2789 		if (CPI_FAMILY(cpi) == 0xf) {
2790 			struct cpuid_regs regs;
2791 			regs.cp_eax = 0x80000007;
2792 			(void) __cpuid_insn(&regs);
2793 			return (!(regs.cp_edx & 0x100));
2794 		}
2795 		return (0);
2796 	case 6323525:
2797 		return (((((eax >> 12) & 0xff00) + (eax & 0xf00)) |
2798 		    (((eax >> 4) & 0xf) | ((eax >> 12) & 0xf0))) < 0xf40);
2799 
2800 	case 6671130:
2801 		/*
2802 		 * check for processors (pre-Shanghai) that do not provide
2803 		 * optimal management of 1gb ptes in its tlb.
2804 		 */
2805 		return (cpi->cpi_family == 0x10 && cpi->cpi_model < 4);
2806 
2807 	case 298:
2808 		return (DR_AX(eax) || DR_B0(eax) || DR_B1(eax) || DR_BA(eax) ||
2809 		    DR_B2(eax) || RB_C0(eax));
2810 
2811 	default:
2812 		return (-1);
2813 
2814 	}
2815 }
2816 
2817 /*
2818  * Determine if specified erratum is present via OSVW (OS Visible Workaround).
2819  * Return 1 if erratum is present, 0 if not present and -1 if indeterminate.
2820  */
2821 int
2822 osvw_opteron_erratum(cpu_t *cpu, uint_t erratum)
2823 {
2824 	struct cpuid_info	*cpi;
2825 	uint_t			osvwid;
2826 	static int		osvwfeature = -1;
2827 	uint64_t		osvwlength;
2828 
2829 
2830 	cpi = cpu->cpu_m.mcpu_cpi;
2831 
2832 	/* confirm OSVW supported */
2833 	if (osvwfeature == -1) {
2834 		osvwfeature = cpi->cpi_extd[1].cp_ecx & CPUID_AMD_ECX_OSVW;
2835 	} else {
2836 		/* assert that osvw feature setting is consistent on all cpus */
2837 		ASSERT(osvwfeature ==
2838 		    (cpi->cpi_extd[1].cp_ecx & CPUID_AMD_ECX_OSVW));
2839 	}
2840 	if (!osvwfeature)
2841 		return (-1);
2842 
2843 	osvwlength = rdmsr(MSR_AMD_OSVW_ID_LEN) & OSVW_ID_LEN_MASK;
2844 
2845 	switch (erratum) {
2846 	case 298:	/* osvwid is 0 */
2847 		osvwid = 0;
2848 		if (osvwlength <= (uint64_t)osvwid) {
2849 			/* osvwid 0 is unknown */
2850 			return (-1);
2851 		}
2852 
2853 		/*
2854 		 * Check the OSVW STATUS MSR to determine the state
2855 		 * of the erratum where:
2856 		 *   0 - fixed by HW
2857 		 *   1 - BIOS has applied the workaround when BIOS
2858 		 *   workaround is available. (Or for other errata,
2859 		 *   OS workaround is required.)
2860 		 * For a value of 1, caller will confirm that the
2861 		 * erratum 298 workaround has indeed been applied by BIOS.
2862 		 *
2863 		 * A 1 may be set in cpus that have a HW fix
2864 		 * in a mixed cpu system. Regarding erratum 298:
2865 		 *   In a multiprocessor platform, the workaround above
2866 		 *   should be applied to all processors regardless of
2867 		 *   silicon revision when an affected processor is
2868 		 *   present.
2869 		 */
2870 
2871 		return (rdmsr(MSR_AMD_OSVW_STATUS +
2872 		    (osvwid / OSVW_ID_CNT_PER_MSR)) &
2873 		    (1ULL << (osvwid % OSVW_ID_CNT_PER_MSR)));
2874 
2875 	default:
2876 		return (-1);
2877 	}
2878 }
2879 
2880 static const char assoc_str[] = "associativity";
2881 static const char line_str[] = "line-size";
2882 static const char size_str[] = "size";
2883 
2884 static void
2885 add_cache_prop(dev_info_t *devi, const char *label, const char *type,
2886     uint32_t val)
2887 {
2888 	char buf[128];
2889 
2890 	/*
2891 	 * ndi_prop_update_int() is used because it is desirable for
2892 	 * DDI_PROP_HW_DEF and DDI_PROP_DONTSLEEP to be set.
2893 	 */
2894 	if (snprintf(buf, sizeof (buf), "%s-%s", label, type) < sizeof (buf))
2895 		(void) ndi_prop_update_int(DDI_DEV_T_NONE, devi, buf, val);
2896 }
2897 
2898 /*
2899  * Intel-style cache/tlb description
2900  *
2901  * Standard cpuid level 2 gives a randomly ordered
2902  * selection of tags that index into a table that describes
2903  * cache and tlb properties.
2904  */
2905 
2906 static const char l1_icache_str[] = "l1-icache";
2907 static const char l1_dcache_str[] = "l1-dcache";
2908 static const char l2_cache_str[] = "l2-cache";
2909 static const char l3_cache_str[] = "l3-cache";
2910 static const char itlb4k_str[] = "itlb-4K";
2911 static const char dtlb4k_str[] = "dtlb-4K";
2912 static const char itlb2M_str[] = "itlb-2M";
2913 static const char itlb4M_str[] = "itlb-4M";
2914 static const char dtlb4M_str[] = "dtlb-4M";
2915 static const char dtlb24_str[] = "dtlb0-2M-4M";
2916 static const char itlb424_str[] = "itlb-4K-2M-4M";
2917 static const char itlb24_str[] = "itlb-2M-4M";
2918 static const char dtlb44_str[] = "dtlb-4K-4M";
2919 static const char sl1_dcache_str[] = "sectored-l1-dcache";
2920 static const char sl2_cache_str[] = "sectored-l2-cache";
2921 static const char itrace_str[] = "itrace-cache";
2922 static const char sl3_cache_str[] = "sectored-l3-cache";
2923 static const char sh_l2_tlb4k_str[] = "shared-l2-tlb-4k";
2924 
2925 static const struct cachetab {
2926 	uint8_t 	ct_code;
2927 	uint8_t		ct_assoc;
2928 	uint16_t 	ct_line_size;
2929 	size_t		ct_size;
2930 	const char	*ct_label;
2931 } intel_ctab[] = {
2932 	/*
2933 	 * maintain descending order!
2934 	 *
2935 	 * Codes ignored - Reason
2936 	 * ----------------------
2937 	 * 40H - intel_cpuid_4_cache_info() disambiguates l2/l3 cache
2938 	 * f0H/f1H - Currently we do not interpret prefetch size by design
2939 	 */
2940 	{ 0xe4, 16, 64, 8*1024*1024, l3_cache_str},
2941 	{ 0xe3, 16, 64, 4*1024*1024, l3_cache_str},
2942 	{ 0xe2, 16, 64, 2*1024*1024, l3_cache_str},
2943 	{ 0xde, 12, 64, 6*1024*1024, l3_cache_str},
2944 	{ 0xdd, 12, 64, 3*1024*1024, l3_cache_str},
2945 	{ 0xdc, 12, 64, ((1*1024*1024)+(512*1024)), l3_cache_str},
2946 	{ 0xd8, 8, 64, 4*1024*1024, l3_cache_str},
2947 	{ 0xd7, 8, 64, 2*1024*1024, l3_cache_str},
2948 	{ 0xd6, 8, 64, 1*1024*1024, l3_cache_str},
2949 	{ 0xd2, 4, 64, 2*1024*1024, l3_cache_str},
2950 	{ 0xd1, 4, 64, 1*1024*1024, l3_cache_str},
2951 	{ 0xd0, 4, 64, 512*1024, l3_cache_str},
2952 	{ 0xca, 4, 0, 512, sh_l2_tlb4k_str},
2953 	{ 0xc0, 4, 0, 8, dtlb44_str },
2954 	{ 0xba, 4, 0, 64, dtlb4k_str },
2955 	{ 0xb4, 4, 0, 256, dtlb4k_str },
2956 	{ 0xb3, 4, 0, 128, dtlb4k_str },
2957 	{ 0xb2, 4, 0, 64, itlb4k_str },
2958 	{ 0xb0, 4, 0, 128, itlb4k_str },
2959 	{ 0x87, 8, 64, 1024*1024, l2_cache_str},
2960 	{ 0x86, 4, 64, 512*1024, l2_cache_str},
2961 	{ 0x85, 8, 32, 2*1024*1024, l2_cache_str},
2962 	{ 0x84, 8, 32, 1024*1024, l2_cache_str},
2963 	{ 0x83, 8, 32, 512*1024, l2_cache_str},
2964 	{ 0x82, 8, 32, 256*1024, l2_cache_str},
2965 	{ 0x80, 8, 64, 512*1024, l2_cache_str},
2966 	{ 0x7f, 2, 64, 512*1024, l2_cache_str},
2967 	{ 0x7d, 8, 64, 2*1024*1024, sl2_cache_str},
2968 	{ 0x7c, 8, 64, 1024*1024, sl2_cache_str},
2969 	{ 0x7b, 8, 64, 512*1024, sl2_cache_str},
2970 	{ 0x7a, 8, 64, 256*1024, sl2_cache_str},
2971 	{ 0x79, 8, 64, 128*1024, sl2_cache_str},
2972 	{ 0x78, 8, 64, 1024*1024, l2_cache_str},
2973 	{ 0x73, 8, 0, 64*1024, itrace_str},
2974 	{ 0x72, 8, 0, 32*1024, itrace_str},
2975 	{ 0x71, 8, 0, 16*1024, itrace_str},
2976 	{ 0x70, 8, 0, 12*1024, itrace_str},
2977 	{ 0x68, 4, 64, 32*1024, sl1_dcache_str},
2978 	{ 0x67, 4, 64, 16*1024, sl1_dcache_str},
2979 	{ 0x66, 4, 64, 8*1024, sl1_dcache_str},
2980 	{ 0x60, 8, 64, 16*1024, sl1_dcache_str},
2981 	{ 0x5d, 0, 0, 256, dtlb44_str},
2982 	{ 0x5c, 0, 0, 128, dtlb44_str},
2983 	{ 0x5b, 0, 0, 64, dtlb44_str},
2984 	{ 0x5a, 4, 0, 32, dtlb24_str},
2985 	{ 0x59, 0, 0, 16, dtlb4k_str},
2986 	{ 0x57, 4, 0, 16, dtlb4k_str},
2987 	{ 0x56, 4, 0, 16, dtlb4M_str},
2988 	{ 0x55, 0, 0, 7, itlb24_str},
2989 	{ 0x52, 0, 0, 256, itlb424_str},
2990 	{ 0x51, 0, 0, 128, itlb424_str},
2991 	{ 0x50, 0, 0, 64, itlb424_str},
2992 	{ 0x4f, 0, 0, 32, itlb4k_str},
2993 	{ 0x4e, 24, 64, 6*1024*1024, l2_cache_str},
2994 	{ 0x4d, 16, 64, 16*1024*1024, l3_cache_str},
2995 	{ 0x4c, 12, 64, 12*1024*1024, l3_cache_str},
2996 	{ 0x4b, 16, 64, 8*1024*1024, l3_cache_str},
2997 	{ 0x4a, 12, 64, 6*1024*1024, l3_cache_str},
2998 	{ 0x49, 16, 64, 4*1024*1024, l3_cache_str},
2999 	{ 0x48, 12, 64, 3*1024*1024, l2_cache_str},
3000 	{ 0x47, 8, 64, 8*1024*1024, l3_cache_str},
3001 	{ 0x46, 4, 64, 4*1024*1024, l3_cache_str},
3002 	{ 0x45, 4, 32, 2*1024*1024, l2_cache_str},
3003 	{ 0x44, 4, 32, 1024*1024, l2_cache_str},
3004 	{ 0x43, 4, 32, 512*1024, l2_cache_str},
3005 	{ 0x42, 4, 32, 256*1024, l2_cache_str},
3006 	{ 0x41, 4, 32, 128*1024, l2_cache_str},
3007 	{ 0x3e, 4, 64, 512*1024, sl2_cache_str},
3008 	{ 0x3d, 6, 64, 384*1024, sl2_cache_str},
3009 	{ 0x3c, 4, 64, 256*1024, sl2_cache_str},
3010 	{ 0x3b, 2, 64, 128*1024, sl2_cache_str},
3011 	{ 0x3a, 6, 64, 192*1024, sl2_cache_str},
3012 	{ 0x39, 4, 64, 128*1024, sl2_cache_str},
3013 	{ 0x30, 8, 64, 32*1024, l1_icache_str},
3014 	{ 0x2c, 8, 64, 32*1024, l1_dcache_str},
3015 	{ 0x29, 8, 64, 4096*1024, sl3_cache_str},
3016 	{ 0x25, 8, 64, 2048*1024, sl3_cache_str},
3017 	{ 0x23, 8, 64, 1024*1024, sl3_cache_str},
3018 	{ 0x22, 4, 64, 512*1024, sl3_cache_str},
3019 	{ 0x0e, 6, 64, 24*1024, l1_dcache_str},
3020 	{ 0x0d, 4, 32, 16*1024, l1_dcache_str},
3021 	{ 0x0c, 4, 32, 16*1024, l1_dcache_str},
3022 	{ 0x0b, 4, 0, 4, itlb4M_str},
3023 	{ 0x0a, 2, 32, 8*1024, l1_dcache_str},
3024 	{ 0x08, 4, 32, 16*1024, l1_icache_str},
3025 	{ 0x06, 4, 32, 8*1024, l1_icache_str},
3026 	{ 0x05, 4, 0, 32, dtlb4M_str},
3027 	{ 0x04, 4, 0, 8, dtlb4M_str},
3028 	{ 0x03, 4, 0, 64, dtlb4k_str},
3029 	{ 0x02, 4, 0, 2, itlb4M_str},
3030 	{ 0x01, 4, 0, 32, itlb4k_str},
3031 	{ 0 }
3032 };
3033 
3034 static const struct cachetab cyrix_ctab[] = {
3035 	{ 0x70, 4, 0, 32, "tlb-4K" },
3036 	{ 0x80, 4, 16, 16*1024, "l1-cache" },
3037 	{ 0 }
3038 };
3039 
3040 /*
3041  * Search a cache table for a matching entry
3042  */
3043 static const struct cachetab *
3044 find_cacheent(const struct cachetab *ct, uint_t code)
3045 {
3046 	if (code != 0) {
3047 		for (; ct->ct_code != 0; ct++)
3048 			if (ct->ct_code <= code)
3049 				break;
3050 		if (ct->ct_code == code)
3051 			return (ct);
3052 	}
3053 	return (NULL);
3054 }
3055 
3056 /*
3057  * Populate cachetab entry with L2 or L3 cache-information using
3058  * cpuid function 4. This function is called from intel_walk_cacheinfo()
3059  * when descriptor 0x49 is encountered. It returns 0 if no such cache
3060  * information is found.
3061  */
3062 static int
3063 intel_cpuid_4_cache_info(struct cachetab *ct, struct cpuid_info *cpi)
3064 {
3065 	uint32_t level, i;
3066 	int ret = 0;
3067 
3068 	for (i = 0; i < cpi->cpi_std_4_size; i++) {
3069 		level = CPI_CACHE_LVL(cpi->cpi_std_4[i]);
3070 
3071 		if (level == 2 || level == 3) {
3072 			ct->ct_assoc = CPI_CACHE_WAYS(cpi->cpi_std_4[i]) + 1;
3073 			ct->ct_line_size =
3074 			    CPI_CACHE_COH_LN_SZ(cpi->cpi_std_4[i]) + 1;
3075 			ct->ct_size = ct->ct_assoc *
3076 			    (CPI_CACHE_PARTS(cpi->cpi_std_4[i]) + 1) *
3077 			    ct->ct_line_size *
3078 			    (cpi->cpi_std_4[i]->cp_ecx + 1);
3079 
3080 			if (level == 2) {
3081 				ct->ct_label = l2_cache_str;
3082 			} else if (level == 3) {
3083 				ct->ct_label = l3_cache_str;
3084 			}
3085 			ret = 1;
3086 		}
3087 	}
3088 
3089 	return (ret);
3090 }
3091 
3092 /*
3093  * Walk the cacheinfo descriptor, applying 'func' to every valid element
3094  * The walk is terminated if the walker returns non-zero.
3095  */
3096 static void
3097 intel_walk_cacheinfo(struct cpuid_info *cpi,
3098     void *arg, int (*func)(void *, const struct cachetab *))
3099 {
3100 	const struct cachetab *ct;
3101 	struct cachetab des_49_ct, des_b1_ct;
3102 	uint8_t *dp;
3103 	int i;
3104 
3105 	if ((dp = cpi->cpi_cacheinfo) == NULL)
3106 		return;
3107 	for (i = 0; i < cpi->cpi_ncache; i++, dp++) {
3108 		/*
3109 		 * For overloaded descriptor 0x49 we use cpuid function 4
3110 		 * if supported by the current processor, to create
3111 		 * cache information.
3112 		 * For overloaded descriptor 0xb1 we use X86_PAE flag
3113 		 * to disambiguate the cache information.
3114 		 */
3115 		if (*dp == 0x49 && cpi->cpi_maxeax >= 0x4 &&
3116 		    intel_cpuid_4_cache_info(&des_49_ct, cpi) == 1) {
3117 				ct = &des_49_ct;
3118 		} else if (*dp == 0xb1) {
3119 			des_b1_ct.ct_code = 0xb1;
3120 			des_b1_ct.ct_assoc = 4;
3121 			des_b1_ct.ct_line_size = 0;
3122 			if (x86_feature & X86_PAE) {
3123 				des_b1_ct.ct_size = 8;
3124 				des_b1_ct.ct_label = itlb2M_str;
3125 			} else {
3126 				des_b1_ct.ct_size = 4;
3127 				des_b1_ct.ct_label = itlb4M_str;
3128 			}
3129 			ct = &des_b1_ct;
3130 		} else {
3131 			if ((ct = find_cacheent(intel_ctab, *dp)) == NULL) {
3132 				continue;
3133 			}
3134 		}
3135 
3136 		if (func(arg, ct) != 0) {
3137 			break;
3138 		}
3139 	}
3140 }
3141 
3142 /*
3143  * (Like the Intel one, except for Cyrix CPUs)
3144  */
3145 static void
3146 cyrix_walk_cacheinfo(struct cpuid_info *cpi,
3147     void *arg, int (*func)(void *, const struct cachetab *))
3148 {
3149 	const struct cachetab *ct;
3150 	uint8_t *dp;
3151 	int i;
3152 
3153 	if ((dp = cpi->cpi_cacheinfo) == NULL)
3154 		return;
3155 	for (i = 0; i < cpi->cpi_ncache; i++, dp++) {
3156 		/*
3157 		 * Search Cyrix-specific descriptor table first ..
3158 		 */
3159 		if ((ct = find_cacheent(cyrix_ctab, *dp)) != NULL) {
3160 			if (func(arg, ct) != 0)
3161 				break;
3162 			continue;
3163 		}
3164 		/*
3165 		 * .. else fall back to the Intel one
3166 		 */
3167 		if ((ct = find_cacheent(intel_ctab, *dp)) != NULL) {
3168 			if (func(arg, ct) != 0)
3169 				break;
3170 			continue;
3171 		}
3172 	}
3173 }
3174 
3175 /*
3176  * A cacheinfo walker that adds associativity, line-size, and size properties
3177  * to the devinfo node it is passed as an argument.
3178  */
3179 static int
3180 add_cacheent_props(void *arg, const struct cachetab *ct)
3181 {
3182 	dev_info_t *devi = arg;
3183 
3184 	add_cache_prop(devi, ct->ct_label, assoc_str, ct->ct_assoc);
3185 	if (ct->ct_line_size != 0)
3186 		add_cache_prop(devi, ct->ct_label, line_str,
3187 		    ct->ct_line_size);
3188 	add_cache_prop(devi, ct->ct_label, size_str, ct->ct_size);
3189 	return (0);
3190 }
3191 
3192 
3193 static const char fully_assoc[] = "fully-associative?";
3194 
3195 /*
3196  * AMD style cache/tlb description
3197  *
3198  * Extended functions 5 and 6 directly describe properties of
3199  * tlbs and various cache levels.
3200  */
3201 static void
3202 add_amd_assoc(dev_info_t *devi, const char *label, uint_t assoc)
3203 {
3204 	switch (assoc) {
3205 	case 0:	/* reserved; ignore */
3206 		break;
3207 	default:
3208 		add_cache_prop(devi, label, assoc_str, assoc);
3209 		break;
3210 	case 0xff:
3211 		add_cache_prop(devi, label, fully_assoc, 1);
3212 		break;
3213 	}
3214 }
3215 
3216 static void
3217 add_amd_tlb(dev_info_t *devi, const char *label, uint_t assoc, uint_t size)
3218 {
3219 	if (size == 0)
3220 		return;
3221 	add_cache_prop(devi, label, size_str, size);
3222 	add_amd_assoc(devi, label, assoc);
3223 }
3224 
3225 static void
3226 add_amd_cache(dev_info_t *devi, const char *label,
3227     uint_t size, uint_t assoc, uint_t lines_per_tag, uint_t line_size)
3228 {
3229 	if (size == 0 || line_size == 0)
3230 		return;
3231 	add_amd_assoc(devi, label, assoc);
3232 	/*
3233 	 * Most AMD parts have a sectored cache. Multiple cache lines are
3234 	 * associated with each tag. A sector consists of all cache lines
3235 	 * associated with a tag. For example, the AMD K6-III has a sector
3236 	 * size of 2 cache lines per tag.
3237 	 */
3238 	if (lines_per_tag != 0)
3239 		add_cache_prop(devi, label, "lines-per-tag", lines_per_tag);
3240 	add_cache_prop(devi, label, line_str, line_size);
3241 	add_cache_prop(devi, label, size_str, size * 1024);
3242 }
3243 
3244 static void
3245 add_amd_l2_assoc(dev_info_t *devi, const char *label, uint_t assoc)
3246 {
3247 	switch (assoc) {
3248 	case 0:	/* off */
3249 		break;
3250 	case 1:
3251 	case 2:
3252 	case 4:
3253 		add_cache_prop(devi, label, assoc_str, assoc);
3254 		break;
3255 	case 6:
3256 		add_cache_prop(devi, label, assoc_str, 8);
3257 		break;
3258 	case 8:
3259 		add_cache_prop(devi, label, assoc_str, 16);
3260 		break;
3261 	case 0xf:
3262 		add_cache_prop(devi, label, fully_assoc, 1);
3263 		break;
3264 	default: /* reserved; ignore */
3265 		break;
3266 	}
3267 }
3268 
3269 static void
3270 add_amd_l2_tlb(dev_info_t *devi, const char *label, uint_t assoc, uint_t size)
3271 {
3272 	if (size == 0 || assoc == 0)
3273 		return;
3274 	add_amd_l2_assoc(devi, label, assoc);
3275 	add_cache_prop(devi, label, size_str, size);
3276 }
3277 
3278 static void
3279 add_amd_l2_cache(dev_info_t *devi, const char *label,
3280     uint_t size, uint_t assoc, uint_t lines_per_tag, uint_t line_size)
3281 {
3282 	if (size == 0 || assoc == 0 || line_size == 0)
3283 		return;
3284 	add_amd_l2_assoc(devi, label, assoc);
3285 	if (lines_per_tag != 0)
3286 		add_cache_prop(devi, label, "lines-per-tag", lines_per_tag);
3287 	add_cache_prop(devi, label, line_str, line_size);
3288 	add_cache_prop(devi, label, size_str, size * 1024);
3289 }
3290 
3291 static void
3292 amd_cache_info(struct cpuid_info *cpi, dev_info_t *devi)
3293 {
3294 	struct cpuid_regs *cp;
3295 
3296 	if (cpi->cpi_xmaxeax < 0x80000005)
3297 		return;
3298 	cp = &cpi->cpi_extd[5];
3299 
3300 	/*
3301 	 * 4M/2M L1 TLB configuration
3302 	 *
3303 	 * We report the size for 2M pages because AMD uses two
3304 	 * TLB entries for one 4M page.
3305 	 */
3306 	add_amd_tlb(devi, "dtlb-2M",
3307 	    BITX(cp->cp_eax, 31, 24), BITX(cp->cp_eax, 23, 16));
3308 	add_amd_tlb(devi, "itlb-2M",
3309 	    BITX(cp->cp_eax, 15, 8), BITX(cp->cp_eax, 7, 0));
3310 
3311 	/*
3312 	 * 4K L1 TLB configuration
3313 	 */
3314 
3315 	switch (cpi->cpi_vendor) {
3316 		uint_t nentries;
3317 	case X86_VENDOR_TM:
3318 		if (cpi->cpi_family >= 5) {
3319 			/*
3320 			 * Crusoe processors have 256 TLB entries, but
3321 			 * cpuid data format constrains them to only
3322 			 * reporting 255 of them.
3323 			 */
3324 			if ((nentries = BITX(cp->cp_ebx, 23, 16)) == 255)
3325 				nentries = 256;
3326 			/*
3327 			 * Crusoe processors also have a unified TLB
3328 			 */
3329 			add_amd_tlb(devi, "tlb-4K", BITX(cp->cp_ebx, 31, 24),
3330 			    nentries);
3331 			break;
3332 		}
3333 		/*FALLTHROUGH*/
3334 	default:
3335 		add_amd_tlb(devi, itlb4k_str,
3336 		    BITX(cp->cp_ebx, 31, 24), BITX(cp->cp_ebx, 23, 16));
3337 		add_amd_tlb(devi, dtlb4k_str,
3338 		    BITX(cp->cp_ebx, 15, 8), BITX(cp->cp_ebx, 7, 0));
3339 		break;
3340 	}
3341 
3342 	/*
3343 	 * data L1 cache configuration
3344 	 */
3345 
3346 	add_amd_cache(devi, l1_dcache_str,
3347 	    BITX(cp->cp_ecx, 31, 24), BITX(cp->cp_ecx, 23, 16),
3348 	    BITX(cp->cp_ecx, 15, 8), BITX(cp->cp_ecx, 7, 0));
3349 
3350 	/*
3351 	 * code L1 cache configuration
3352 	 */
3353 
3354 	add_amd_cache(devi, l1_icache_str,
3355 	    BITX(cp->cp_edx, 31, 24), BITX(cp->cp_edx, 23, 16),
3356 	    BITX(cp->cp_edx, 15, 8), BITX(cp->cp_edx, 7, 0));
3357 
3358 	if (cpi->cpi_xmaxeax < 0x80000006)
3359 		return;
3360 	cp = &cpi->cpi_extd[6];
3361 
3362 	/* Check for a unified L2 TLB for large pages */
3363 
3364 	if (BITX(cp->cp_eax, 31, 16) == 0)
3365 		add_amd_l2_tlb(devi, "l2-tlb-2M",
3366 		    BITX(cp->cp_eax, 15, 12), BITX(cp->cp_eax, 11, 0));
3367 	else {
3368 		add_amd_l2_tlb(devi, "l2-dtlb-2M",
3369 		    BITX(cp->cp_eax, 31, 28), BITX(cp->cp_eax, 27, 16));
3370 		add_amd_l2_tlb(devi, "l2-itlb-2M",
3371 		    BITX(cp->cp_eax, 15, 12), BITX(cp->cp_eax, 11, 0));
3372 	}
3373 
3374 	/* Check for a unified L2 TLB for 4K pages */
3375 
3376 	if (BITX(cp->cp_ebx, 31, 16) == 0) {
3377 		add_amd_l2_tlb(devi, "l2-tlb-4K",
3378 		    BITX(cp->cp_eax, 15, 12), BITX(cp->cp_eax, 11, 0));
3379 	} else {
3380 		add_amd_l2_tlb(devi, "l2-dtlb-4K",
3381 		    BITX(cp->cp_eax, 31, 28), BITX(cp->cp_eax, 27, 16));
3382 		add_amd_l2_tlb(devi, "l2-itlb-4K",
3383 		    BITX(cp->cp_eax, 15, 12), BITX(cp->cp_eax, 11, 0));
3384 	}
3385 
3386 	add_amd_l2_cache(devi, l2_cache_str,
3387 	    BITX(cp->cp_ecx, 31, 16), BITX(cp->cp_ecx, 15, 12),
3388 	    BITX(cp->cp_ecx, 11, 8), BITX(cp->cp_ecx, 7, 0));
3389 }
3390 
3391 /*
3392  * There are two basic ways that the x86 world describes it cache
3393  * and tlb architecture - Intel's way and AMD's way.
3394  *
3395  * Return which flavor of cache architecture we should use
3396  */
3397 static int
3398 x86_which_cacheinfo(struct cpuid_info *cpi)
3399 {
3400 	switch (cpi->cpi_vendor) {
3401 	case X86_VENDOR_Intel:
3402 		if (cpi->cpi_maxeax >= 2)
3403 			return (X86_VENDOR_Intel);
3404 		break;
3405 	case X86_VENDOR_AMD:
3406 		/*
3407 		 * The K5 model 1 was the first part from AMD that reported
3408 		 * cache sizes via extended cpuid functions.
3409 		 */
3410 		if (cpi->cpi_family > 5 ||
3411 		    (cpi->cpi_family == 5 && cpi->cpi_model >= 1))
3412 			return (X86_VENDOR_AMD);
3413 		break;
3414 	case X86_VENDOR_TM:
3415 		if (cpi->cpi_family >= 5)
3416 			return (X86_VENDOR_AMD);
3417 		/*FALLTHROUGH*/
3418 	default:
3419 		/*
3420 		 * If they have extended CPU data for 0x80000005
3421 		 * then we assume they have AMD-format cache
3422 		 * information.
3423 		 *
3424 		 * If not, and the vendor happens to be Cyrix,
3425 		 * then try our-Cyrix specific handler.
3426 		 *
3427 		 * If we're not Cyrix, then assume we're using Intel's
3428 		 * table-driven format instead.
3429 		 */
3430 		if (cpi->cpi_xmaxeax >= 0x80000005)
3431 			return (X86_VENDOR_AMD);
3432 		else if (cpi->cpi_vendor == X86_VENDOR_Cyrix)
3433 			return (X86_VENDOR_Cyrix);
3434 		else if (cpi->cpi_maxeax >= 2)
3435 			return (X86_VENDOR_Intel);
3436 		break;
3437 	}
3438 	return (-1);
3439 }
3440 
3441 /*
3442  * create a node for the given cpu under the prom root node.
3443  * Also, create a cpu node in the device tree.
3444  */
3445 static dev_info_t *cpu_nex_devi = NULL;
3446 static kmutex_t cpu_node_lock;
3447 
3448 /*
3449  * Called from post_startup() and mp_startup()
3450  */
3451 void
3452 add_cpunode2devtree(processorid_t cpu_id, struct cpuid_info *cpi)
3453 {
3454 	dev_info_t *cpu_devi;
3455 	int create;
3456 
3457 	mutex_enter(&cpu_node_lock);
3458 
3459 	/*
3460 	 * create a nexus node for all cpus identified as 'cpu_id' under
3461 	 * the root node.
3462 	 */
3463 	if (cpu_nex_devi == NULL) {
3464 		if (ndi_devi_alloc(ddi_root_node(), "cpus",
3465 		    (pnode_t)DEVI_SID_NODEID, &cpu_nex_devi) != NDI_SUCCESS) {
3466 			mutex_exit(&cpu_node_lock);
3467 			return;
3468 		}
3469 		(void) ndi_devi_online(cpu_nex_devi, 0);
3470 	}
3471 
3472 	/*
3473 	 * create a child node for cpu identified as 'cpu_id'
3474 	 */
3475 	cpu_devi = ddi_add_child(cpu_nex_devi, "cpu", DEVI_SID_NODEID,
3476 	    cpu_id);
3477 	if (cpu_devi == NULL) {
3478 		mutex_exit(&cpu_node_lock);
3479 		return;
3480 	}
3481 
3482 	/* device_type */
3483 
3484 	(void) ndi_prop_update_string(DDI_DEV_T_NONE, cpu_devi,
3485 	    "device_type", "cpu");
3486 
3487 	/* reg */
3488 
3489 	(void) ndi_prop_update_int(DDI_DEV_T_NONE, cpu_devi,
3490 	    "reg", cpu_id);
3491 
3492 	/* cpu-mhz, and clock-frequency */
3493 
3494 	if (cpu_freq > 0) {
3495 		long long mul;
3496 
3497 		(void) ndi_prop_update_int(DDI_DEV_T_NONE, cpu_devi,
3498 		    "cpu-mhz", cpu_freq);
3499 
3500 		if ((mul = cpu_freq * 1000000LL) <= INT_MAX)
3501 			(void) ndi_prop_update_int(DDI_DEV_T_NONE, cpu_devi,
3502 			    "clock-frequency", (int)mul);
3503 	}
3504 
3505 	(void) ndi_devi_online(cpu_devi, 0);
3506 
3507 	if ((x86_feature & X86_CPUID) == 0) {
3508 		mutex_exit(&cpu_node_lock);
3509 		return;
3510 	}
3511 
3512 	/* vendor-id */
3513 
3514 	(void) ndi_prop_update_string(DDI_DEV_T_NONE, cpu_devi,
3515 	    "vendor-id", cpi->cpi_vendorstr);
3516 
3517 	if (cpi->cpi_maxeax == 0) {
3518 		mutex_exit(&cpu_node_lock);
3519 		return;
3520 	}
3521 
3522 	/*
3523 	 * family, model, and step
3524 	 */
3525 	(void) ndi_prop_update_int(DDI_DEV_T_NONE, cpu_devi,
3526 	    "family", CPI_FAMILY(cpi));
3527 	(void) ndi_prop_update_int(DDI_DEV_T_NONE, cpu_devi,
3528 	    "cpu-model", CPI_MODEL(cpi));
3529 	(void) ndi_prop_update_int(DDI_DEV_T_NONE, cpu_devi,
3530 	    "stepping-id", CPI_STEP(cpi));
3531 
3532 	/* type */
3533 
3534 	switch (cpi->cpi_vendor) {
3535 	case X86_VENDOR_Intel:
3536 		create = 1;
3537 		break;
3538 	default:
3539 		create = 0;
3540 		break;
3541 	}
3542 	if (create)
3543 		(void) ndi_prop_update_int(DDI_DEV_T_NONE, cpu_devi,
3544 		    "type", CPI_TYPE(cpi));
3545 
3546 	/* ext-family */
3547 
3548 	switch (cpi->cpi_vendor) {
3549 	case X86_VENDOR_Intel:
3550 	case X86_VENDOR_AMD:
3551 		create = cpi->cpi_family >= 0xf;
3552 		break;
3553 	default:
3554 		create = 0;
3555 		break;
3556 	}
3557 	if (create)
3558 		(void) ndi_prop_update_int(DDI_DEV_T_NONE, cpu_devi,
3559 		    "ext-family", CPI_FAMILY_XTD(cpi));
3560 
3561 	/* ext-model */
3562 
3563 	switch (cpi->cpi_vendor) {
3564 	case X86_VENDOR_Intel:
3565 		create = IS_EXTENDED_MODEL_INTEL(cpi);
3566 		break;
3567 	case X86_VENDOR_AMD:
3568 		create = CPI_FAMILY(cpi) == 0xf;
3569 		break;
3570 	default:
3571 		create = 0;
3572 		break;
3573 	}
3574 	if (create)
3575 		(void) ndi_prop_update_int(DDI_DEV_T_NONE, cpu_devi,
3576 		    "ext-model", CPI_MODEL_XTD(cpi));
3577 
3578 	/* generation */
3579 
3580 	switch (cpi->cpi_vendor) {
3581 	case X86_VENDOR_AMD:
3582 		/*
3583 		 * AMD K5 model 1 was the first part to support this
3584 		 */
3585 		create = cpi->cpi_xmaxeax >= 0x80000001;
3586 		break;
3587 	default:
3588 		create = 0;
3589 		break;
3590 	}
3591 	if (create)
3592 		(void) ndi_prop_update_int(DDI_DEV_T_NONE, cpu_devi,
3593 		    "generation", BITX((cpi)->cpi_extd[1].cp_eax, 11, 8));
3594 
3595 	/* brand-id */
3596 
3597 	switch (cpi->cpi_vendor) {
3598 	case X86_VENDOR_Intel:
3599 		/*
3600 		 * brand id first appeared on Pentium III Xeon model 8,
3601 		 * and Celeron model 8 processors and Opteron
3602 		 */
3603 		create = cpi->cpi_family > 6 ||
3604 		    (cpi->cpi_family == 6 && cpi->cpi_model >= 8);
3605 		break;
3606 	case X86_VENDOR_AMD:
3607 		create = cpi->cpi_family >= 0xf;
3608 		break;
3609 	default:
3610 		create = 0;
3611 		break;
3612 	}
3613 	if (create && cpi->cpi_brandid != 0) {
3614 		(void) ndi_prop_update_int(DDI_DEV_T_NONE, cpu_devi,
3615 		    "brand-id", cpi->cpi_brandid);
3616 	}
3617 
3618 	/* chunks, and apic-id */
3619 
3620 	switch (cpi->cpi_vendor) {
3621 		/*
3622 		 * first available on Pentium IV and Opteron (K8)
3623 		 */
3624 	case X86_VENDOR_Intel:
3625 		create = IS_NEW_F6(cpi) || cpi->cpi_family >= 0xf;
3626 		break;
3627 	case X86_VENDOR_AMD:
3628 		create = cpi->cpi_family >= 0xf;
3629 		break;
3630 	default:
3631 		create = 0;
3632 		break;
3633 	}
3634 	if (create) {
3635 		(void) ndi_prop_update_int(DDI_DEV_T_NONE, cpu_devi,
3636 		    "chunks", CPI_CHUNKS(cpi));
3637 		(void) ndi_prop_update_int(DDI_DEV_T_NONE, cpu_devi,
3638 		    "apic-id", cpi->cpi_apicid);
3639 		if (cpi->cpi_chipid >= 0) {
3640 			(void) ndi_prop_update_int(DDI_DEV_T_NONE, cpu_devi,
3641 			    "chip#", cpi->cpi_chipid);
3642 			(void) ndi_prop_update_int(DDI_DEV_T_NONE, cpu_devi,
3643 			    "clog#", cpi->cpi_clogid);
3644 		}
3645 	}
3646 
3647 	/* cpuid-features */
3648 
3649 	(void) ndi_prop_update_int(DDI_DEV_T_NONE, cpu_devi,
3650 	    "cpuid-features", CPI_FEATURES_EDX(cpi));
3651 
3652 
3653 	/* cpuid-features-ecx */
3654 
3655 	switch (cpi->cpi_vendor) {
3656 	case X86_VENDOR_Intel:
3657 		create = IS_NEW_F6(cpi) || cpi->cpi_family >= 0xf;
3658 		break;
3659 	default:
3660 		create = 0;
3661 		break;
3662 	}
3663 	if (create)
3664 		(void) ndi_prop_update_int(DDI_DEV_T_NONE, cpu_devi,
3665 		    "cpuid-features-ecx", CPI_FEATURES_ECX(cpi));
3666 
3667 	/* ext-cpuid-features */
3668 
3669 	switch (cpi->cpi_vendor) {
3670 	case X86_VENDOR_Intel:
3671 	case X86_VENDOR_AMD:
3672 	case X86_VENDOR_Cyrix:
3673 	case X86_VENDOR_TM:
3674 	case X86_VENDOR_Centaur:
3675 		create = cpi->cpi_xmaxeax >= 0x80000001;
3676 		break;
3677 	default:
3678 		create = 0;
3679 		break;
3680 	}
3681 	if (create) {
3682 		(void) ndi_prop_update_int(DDI_DEV_T_NONE, cpu_devi,
3683 		    "ext-cpuid-features", CPI_FEATURES_XTD_EDX(cpi));
3684 		(void) ndi_prop_update_int(DDI_DEV_T_NONE, cpu_devi,
3685 		    "ext-cpuid-features-ecx", CPI_FEATURES_XTD_ECX(cpi));
3686 	}
3687 
3688 	/*
3689 	 * Brand String first appeared in Intel Pentium IV, AMD K5
3690 	 * model 1, and Cyrix GXm.  On earlier models we try and
3691 	 * simulate something similar .. so this string should always
3692 	 * same -something- about the processor, however lame.
3693 	 */
3694 	(void) ndi_prop_update_string(DDI_DEV_T_NONE, cpu_devi,
3695 	    "brand-string", cpi->cpi_brandstr);
3696 
3697 	/*
3698 	 * Finally, cache and tlb information
3699 	 */
3700 	switch (x86_which_cacheinfo(cpi)) {
3701 	case X86_VENDOR_Intel:
3702 		intel_walk_cacheinfo(cpi, cpu_devi, add_cacheent_props);
3703 		break;
3704 	case X86_VENDOR_Cyrix:
3705 		cyrix_walk_cacheinfo(cpi, cpu_devi, add_cacheent_props);
3706 		break;
3707 	case X86_VENDOR_AMD:
3708 		amd_cache_info(cpi, cpu_devi);
3709 		break;
3710 	default:
3711 		break;
3712 	}
3713 
3714 	mutex_exit(&cpu_node_lock);
3715 }
3716 
3717 struct l2info {
3718 	int *l2i_csz;
3719 	int *l2i_lsz;
3720 	int *l2i_assoc;
3721 	int l2i_ret;
3722 };
3723 
3724 /*
3725  * A cacheinfo walker that fetches the size, line-size and associativity
3726  * of the L2 cache
3727  */
3728 static int
3729 intel_l2cinfo(void *arg, const struct cachetab *ct)
3730 {
3731 	struct l2info *l2i = arg;
3732 	int *ip;
3733 
3734 	if (ct->ct_label != l2_cache_str &&
3735 	    ct->ct_label != sl2_cache_str)
3736 		return (0);	/* not an L2 -- keep walking */
3737 
3738 	if ((ip = l2i->l2i_csz) != NULL)
3739 		*ip = ct->ct_size;
3740 	if ((ip = l2i->l2i_lsz) != NULL)
3741 		*ip = ct->ct_line_size;
3742 	if ((ip = l2i->l2i_assoc) != NULL)
3743 		*ip = ct->ct_assoc;
3744 	l2i->l2i_ret = ct->ct_size;
3745 	return (1);		/* was an L2 -- terminate walk */
3746 }
3747 
3748 /*
3749  * AMD L2/L3 Cache and TLB Associativity Field Definition:
3750  *
3751  *	Unlike the associativity for the L1 cache and tlb where the 8 bit
3752  *	value is the associativity, the associativity for the L2 cache and
3753  *	tlb is encoded in the following table. The 4 bit L2 value serves as
3754  *	an index into the amd_afd[] array to determine the associativity.
3755  *	-1 is undefined. 0 is fully associative.
3756  */
3757 
3758 static int amd_afd[] =
3759 	{-1, 1, 2, -1, 4, -1, 8, -1, 16, -1, 32, 48, 64, 96, 128, 0};
3760 
3761 static void
3762 amd_l2cacheinfo(struct cpuid_info *cpi, struct l2info *l2i)
3763 {
3764 	struct cpuid_regs *cp;
3765 	uint_t size, assoc;
3766 	int i;
3767 	int *ip;
3768 
3769 	if (cpi->cpi_xmaxeax < 0x80000006)
3770 		return;
3771 	cp = &cpi->cpi_extd[6];
3772 
3773 	if ((i = BITX(cp->cp_ecx, 15, 12)) != 0 &&
3774 	    (size = BITX(cp->cp_ecx, 31, 16)) != 0) {
3775 		uint_t cachesz = size * 1024;
3776 		assoc = amd_afd[i];
3777 
3778 		ASSERT(assoc != -1);
3779 
3780 		if ((ip = l2i->l2i_csz) != NULL)
3781 			*ip = cachesz;
3782 		if ((ip = l2i->l2i_lsz) != NULL)
3783 			*ip = BITX(cp->cp_ecx, 7, 0);
3784 		if ((ip = l2i->l2i_assoc) != NULL)
3785 			*ip = assoc;
3786 		l2i->l2i_ret = cachesz;
3787 	}
3788 }
3789 
3790 int
3791 getl2cacheinfo(cpu_t *cpu, int *csz, int *lsz, int *assoc)
3792 {
3793 	struct cpuid_info *cpi = cpu->cpu_m.mcpu_cpi;
3794 	struct l2info __l2info, *l2i = &__l2info;
3795 
3796 	l2i->l2i_csz = csz;
3797 	l2i->l2i_lsz = lsz;
3798 	l2i->l2i_assoc = assoc;
3799 	l2i->l2i_ret = -1;
3800 
3801 	switch (x86_which_cacheinfo(cpi)) {
3802 	case X86_VENDOR_Intel:
3803 		intel_walk_cacheinfo(cpi, l2i, intel_l2cinfo);
3804 		break;
3805 	case X86_VENDOR_Cyrix:
3806 		cyrix_walk_cacheinfo(cpi, l2i, intel_l2cinfo);
3807 		break;
3808 	case X86_VENDOR_AMD:
3809 		amd_l2cacheinfo(cpi, l2i);
3810 		break;
3811 	default:
3812 		break;
3813 	}
3814 	return (l2i->l2i_ret);
3815 }
3816 
3817 #if !defined(__xpv)
3818 
3819 uint32_t *
3820 cpuid_mwait_alloc(cpu_t *cpu)
3821 {
3822 	uint32_t	*ret;
3823 	size_t		mwait_size;
3824 
3825 	ASSERT(cpuid_checkpass(cpu, 2));
3826 
3827 	mwait_size = cpu->cpu_m.mcpu_cpi->cpi_mwait.mon_max;
3828 	if (mwait_size == 0)
3829 		return (NULL);
3830 
3831 	/*
3832 	 * kmem_alloc() returns cache line size aligned data for mwait_size
3833 	 * allocations.  mwait_size is currently cache line sized.  Neither
3834 	 * of these implementation details are guarantied to be true in the
3835 	 * future.
3836 	 *
3837 	 * First try allocating mwait_size as kmem_alloc() currently returns
3838 	 * correctly aligned memory.  If kmem_alloc() does not return
3839 	 * mwait_size aligned memory, then use mwait_size ROUNDUP.
3840 	 *
3841 	 * Set cpi_mwait.buf_actual and cpi_mwait.size_actual in case we
3842 	 * decide to free this memory.
3843 	 */
3844 	ret = kmem_zalloc(mwait_size, KM_SLEEP);
3845 	if (ret == (uint32_t *)P2ROUNDUP((uintptr_t)ret, mwait_size)) {
3846 		cpu->cpu_m.mcpu_cpi->cpi_mwait.buf_actual = ret;
3847 		cpu->cpu_m.mcpu_cpi->cpi_mwait.size_actual = mwait_size;
3848 		*ret = MWAIT_RUNNING;
3849 		return (ret);
3850 	} else {
3851 		kmem_free(ret, mwait_size);
3852 		ret = kmem_zalloc(mwait_size * 2, KM_SLEEP);
3853 		cpu->cpu_m.mcpu_cpi->cpi_mwait.buf_actual = ret;
3854 		cpu->cpu_m.mcpu_cpi->cpi_mwait.size_actual = mwait_size * 2;
3855 		ret = (uint32_t *)P2ROUNDUP((uintptr_t)ret, mwait_size);
3856 		*ret = MWAIT_RUNNING;
3857 		return (ret);
3858 	}
3859 }
3860 
3861 void
3862 cpuid_mwait_free(cpu_t *cpu)
3863 {
3864 	ASSERT(cpuid_checkpass(cpu, 2));
3865 
3866 	if (cpu->cpu_m.mcpu_cpi->cpi_mwait.buf_actual != NULL &&
3867 	    cpu->cpu_m.mcpu_cpi->cpi_mwait.size_actual > 0) {
3868 		kmem_free(cpu->cpu_m.mcpu_cpi->cpi_mwait.buf_actual,
3869 		    cpu->cpu_m.mcpu_cpi->cpi_mwait.size_actual);
3870 	}
3871 
3872 	cpu->cpu_m.mcpu_cpi->cpi_mwait.buf_actual = NULL;
3873 	cpu->cpu_m.mcpu_cpi->cpi_mwait.size_actual = 0;
3874 }
3875 
3876 void
3877 patch_tsc_read(int flag)
3878 {
3879 	size_t cnt;
3880 
3881 	switch (flag) {
3882 	case X86_NO_TSC:
3883 		cnt = &_no_rdtsc_end - &_no_rdtsc_start;
3884 		(void) memcpy((void *)tsc_read, (void *)&_no_rdtsc_start, cnt);
3885 		break;
3886 	case X86_HAVE_TSCP:
3887 		cnt = &_tscp_end - &_tscp_start;
3888 		(void) memcpy((void *)tsc_read, (void *)&_tscp_start, cnt);
3889 		break;
3890 	case X86_TSC_MFENCE:
3891 		cnt = &_tsc_mfence_end - &_tsc_mfence_start;
3892 		(void) memcpy((void *)tsc_read,
3893 		    (void *)&_tsc_mfence_start, cnt);
3894 		break;
3895 	case X86_TSC_LFENCE:
3896 		cnt = &_tsc_lfence_end - &_tsc_lfence_start;
3897 		(void) memcpy((void *)tsc_read,
3898 		    (void *)&_tsc_lfence_start, cnt);
3899 		break;
3900 	default:
3901 		break;
3902 	}
3903 }
3904 
3905 int
3906 cpuid_deep_cstates_supported(void)
3907 {
3908 	struct cpuid_info *cpi;
3909 	struct cpuid_regs regs;
3910 
3911 	ASSERT(cpuid_checkpass(CPU, 1));
3912 
3913 	cpi = CPU->cpu_m.mcpu_cpi;
3914 
3915 	if (!(x86_feature & X86_CPUID))
3916 		return (0);
3917 
3918 	switch (cpi->cpi_vendor) {
3919 	case X86_VENDOR_Intel:
3920 		if (cpi->cpi_xmaxeax < 0x80000007)
3921 			return (0);
3922 
3923 		/*
3924 		 * TSC run at a constant rate in all ACPI C-states?
3925 		 */
3926 		regs.cp_eax = 0x80000007;
3927 		(void) __cpuid_insn(&regs);
3928 		return (regs.cp_edx & CPUID_TSC_CSTATE_INVARIANCE);
3929 
3930 	default:
3931 		return (0);
3932 	}
3933 }
3934 
3935 #endif	/* !__xpv */
3936 
3937 void
3938 post_startup_cpu_fixups(void)
3939 {
3940 #ifndef __xpv
3941 	/*
3942 	 * Some AMD processors support C1E state. Entering this state will
3943 	 * cause the local APIC timer to stop, which we can't deal with at
3944 	 * this time.
3945 	 */
3946 	if (cpuid_getvendor(CPU) == X86_VENDOR_AMD) {
3947 		on_trap_data_t otd;
3948 		uint64_t reg;
3949 
3950 		if (!on_trap(&otd, OT_DATA_ACCESS)) {
3951 			reg = rdmsr(MSR_AMD_INT_PENDING_CMP_HALT);
3952 			/* Disable C1E state if it is enabled by BIOS */
3953 			if ((reg >> AMD_ACTONCMPHALT_SHIFT) &
3954 			    AMD_ACTONCMPHALT_MASK) {
3955 				reg &= ~(AMD_ACTONCMPHALT_MASK <<
3956 				    AMD_ACTONCMPHALT_SHIFT);
3957 				wrmsr(MSR_AMD_INT_PENDING_CMP_HALT, reg);
3958 			}
3959 		}
3960 		no_trap();
3961 	}
3962 #endif	/* !__xpv */
3963 }
3964 
3965 /*
3966  * Starting with the Westmere processor the local
3967  * APIC timer will continue running in all C-states,
3968  * including the deepest C-states.
3969  */
3970 int
3971 cpuid_arat_supported(void)
3972 {
3973 	struct cpuid_info *cpi;
3974 	struct cpuid_regs regs;
3975 
3976 	ASSERT(cpuid_checkpass(CPU, 1));
3977 	ASSERT(x86_feature & X86_CPUID);
3978 
3979 	cpi = CPU->cpu_m.mcpu_cpi;
3980 
3981 	switch (cpi->cpi_vendor) {
3982 	case X86_VENDOR_Intel:
3983 		/*
3984 		 * Always-running Local APIC Timer is
3985 		 * indicated by CPUID.6.EAX[2].
3986 		 */
3987 		if (cpi->cpi_maxeax >= 6) {
3988 			regs.cp_eax = 6;
3989 			(void) cpuid_insn(NULL, &regs);
3990 			return (regs.cp_eax & CPUID_CSTATE_ARAT);
3991 		} else {
3992 			return (0);
3993 		}
3994 	default:
3995 		return (0);
3996 	}
3997 }
3998 
3999 #if defined(__amd64) && !defined(__xpv)
4000 /*
4001  * Patch in versions of bcopy for high performance Intel Nhm processors
4002  * and later...
4003  */
4004 void
4005 patch_memops(uint_t vendor)
4006 {
4007 	size_t cnt, i;
4008 	caddr_t to, from;
4009 
4010 	if ((vendor == X86_VENDOR_Intel) && ((x86_feature & X86_SSE4_2) != 0)) {
4011 		cnt = &bcopy_patch_end - &bcopy_patch_start;
4012 		to = &bcopy_ck_size;
4013 		from = &bcopy_patch_start;
4014 		for (i = 0; i < cnt; i++) {
4015 			*to++ = *from++;
4016 		}
4017 	}
4018 }
4019 #endif  /* __amd64 && !__xpv */
4020