cpu.c revision 1.119
1 1.119 skrll /* $NetBSD: cpu.c,v 1.119 2018/08/15 06:04:01 skrll Exp $ */ 2 1.1 matt 3 1.1 matt /* 4 1.1 matt * Copyright (c) 1995 Mark Brinicombe. 5 1.1 matt * Copyright (c) 1995 Brini. 6 1.1 matt * All rights reserved. 7 1.1 matt * 8 1.1 matt * Redistribution and use in source and binary forms, with or without 9 1.1 matt * modification, are permitted provided that the following conditions 10 1.1 matt * are met: 11 1.1 matt * 1. Redistributions of source code must retain the above copyright 12 1.1 matt * notice, this list of conditions and the following disclaimer. 13 1.1 matt * 2. Redistributions in binary form must reproduce the above copyright 14 1.1 matt * notice, this list of conditions and the following disclaimer in the 15 1.1 matt * documentation and/or other materials provided with the distribution. 16 1.1 matt * 3. All advertising materials mentioning features or use of this software 17 1.1 matt * must display the following acknowledgement: 18 1.1 matt * This product includes software developed by Brini. 19 1.1 matt * 4. The name of the company nor the name of the author may be used to 20 1.1 matt * endorse or promote products derived from this software without specific 21 1.1 matt * prior written permission. 22 1.1 matt * 23 1.1 matt * THIS SOFTWARE IS PROVIDED BY BRINI ``AS IS'' AND ANY EXPRESS OR IMPLIED 24 1.1 matt * WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF 25 1.1 matt * MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. 26 1.1 matt * IN NO EVENT SHALL BRINI OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, 27 1.1 matt * INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES 28 1.1 matt * (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR 29 1.1 matt * SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) 30 1.1 matt * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT 31 1.1 matt * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY 32 1.1 matt * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF 33 1.1 matt * SUCH DAMAGE. 34 1.1 matt * 35 1.1 matt * RiscBSD kernel project 36 1.1 matt * 37 1.1 matt * cpu.c 38 1.1 matt * 39 1.55 wiz * Probing and configuration for the master CPU 40 1.1 matt * 41 1.1 matt * Created : 10/10/95 42 1.1 matt */ 43 1.1 matt 44 1.1 matt #include "opt_armfpe.h" 45 1.118 skrll #include "opt_cputypes.h" 46 1.51 martin #include "opt_multiprocessor.h" 47 1.1 matt 48 1.119 skrll #include <sys/cdefs.h> 49 1.119 skrll __KERNEL_RCSID(0, "$NetBSD: cpu.c,v 1.119 2018/08/15 06:04:01 skrll Exp $"); 50 1.119 skrll 51 1.1 matt #include <sys/param.h> 52 1.1 matt #include <sys/systm.h> 53 1.85 matt #include <sys/conf.h> 54 1.85 matt #include <sys/cpu.h> 55 1.1 matt #include <sys/device.h> 56 1.85 matt #include <sys/kmem.h> 57 1.1 matt #include <sys/proc.h> 58 1.85 matt 59 1.1 matt #include <uvm/uvm_extern.h> 60 1.33 thorpej 61 1.97 matt #include <arm/locore.h> 62 1.10 thorpej #include <arm/undefined.h> 63 1.10 thorpej 64 1.93 matt extern const char *cpu_arch; 65 1.1 matt 66 1.85 matt #ifdef MULTIPROCESSOR 67 1.85 matt volatile u_int arm_cpu_hatched = 0; 68 1.104 matt volatile uint32_t arm_cpu_mbox __cacheline_aligned = 0; 69 1.104 matt uint32_t arm_cpu_marker[2] __cacheline_aligned = { 0, 0 }; 70 1.104 matt u_int arm_cpu_max = 1; 71 1.85 matt #endif 72 1.85 matt 73 1.1 matt /* Prototypes */ 74 1.104 matt void identify_arm_cpu(device_t, struct cpu_info *); 75 1.104 matt void identify_cortex_caches(device_t); 76 1.104 matt void identify_features(device_t); 77 1.1 matt 78 1.1 matt /* 79 1.25 bjh21 * Identify the master (boot) CPU 80 1.1 matt */ 81 1.1 matt 82 1.1 matt void 83 1.85 matt cpu_attach(device_t dv, cpuid_t id) 84 1.1 matt { 85 1.86 matt const char * const xname = device_xname(dv); 86 1.85 matt struct cpu_info *ci; 87 1.85 matt 88 1.85 matt if (id == 0) { 89 1.85 matt ci = curcpu(); 90 1.27 reinoud 91 1.85 matt /* Get the CPU ID from coprocessor 15 */ 92 1.85 matt 93 1.112 christos ci->ci_arm_cpuid = cpu_idnum(); 94 1.85 matt ci->ci_arm_cputype = ci->ci_arm_cpuid & CPU_ID_CPU_MASK; 95 1.85 matt ci->ci_arm_cpurev = ci->ci_arm_cpuid & CPU_ID_REVISION_MASK; 96 1.85 matt } else { 97 1.85 matt #ifdef MULTIPROCESSOR 98 1.85 matt KASSERT(cpu_info[id] == NULL); 99 1.85 matt ci = kmem_zalloc(sizeof(*ci), KM_SLEEP); 100 1.85 matt ci->ci_cpl = IPL_HIGH; 101 1.85 matt ci->ci_cpuid = id; 102 1.104 matt uint32_t mpidr = armreg_mpidr_read(); 103 1.104 matt if (mpidr & MPIDR_MT) { 104 1.104 matt ci->ci_data.cpu_smt_id = mpidr & MPIDR_AFF0; 105 1.104 matt ci->ci_data.cpu_core_id = mpidr & MPIDR_AFF1; 106 1.104 matt ci->ci_data.cpu_package_id = mpidr & MPIDR_AFF2; 107 1.104 matt } else { 108 1.104 matt ci->ci_data.cpu_core_id = mpidr & MPIDR_AFF0; 109 1.104 matt ci->ci_data.cpu_package_id = mpidr & MPIDR_AFF1; 110 1.104 matt } 111 1.85 matt ci->ci_data.cpu_core_id = id; 112 1.85 matt ci->ci_data.cpu_cc_freq = cpu_info_store.ci_data.cpu_cc_freq; 113 1.85 matt ci->ci_arm_cpuid = cpu_info_store.ci_arm_cpuid; 114 1.85 matt ci->ci_arm_cputype = cpu_info_store.ci_arm_cputype; 115 1.85 matt ci->ci_arm_cpurev = cpu_info_store.ci_arm_cpurev; 116 1.104 matt ci->ci_ctrl = cpu_info_store.ci_ctrl; 117 1.104 matt ci->ci_undefsave[2] = cpu_info_store.ci_undefsave[2]; 118 1.85 matt cpu_info[ci->ci_cpuid] = ci; 119 1.85 matt if ((arm_cpu_hatched & (1 << id)) == 0) { 120 1.85 matt ci->ci_dev = dv; 121 1.85 matt dv->dv_private = ci; 122 1.85 matt aprint_naive(": disabled\n"); 123 1.85 matt aprint_normal(": disabled (unresponsive)\n"); 124 1.85 matt return; 125 1.85 matt } 126 1.85 matt #else 127 1.85 matt aprint_naive(": disabled\n"); 128 1.85 matt aprint_normal(": disabled (uniprocessor kernel)\n"); 129 1.85 matt return; 130 1.85 matt #endif 131 1.85 matt } 132 1.23 bjh21 133 1.85 matt ci->ci_dev = dv; 134 1.85 matt dv->dv_private = ci; 135 1.1 matt 136 1.85 matt evcnt_attach_dynamic(&ci->ci_arm700bugcount, EVCNT_TYPE_MISC, 137 1.86 matt NULL, xname, "arm700swibug"); 138 1.86 matt 139 1.86 matt evcnt_attach_dynamic_nozero(&ci->ci_abt_evs[FAULT_WRTBUF_0], EVCNT_TYPE_TRAP, 140 1.86 matt NULL, xname, "vector abort"); 141 1.86 matt evcnt_attach_dynamic_nozero(&ci->ci_abt_evs[FAULT_WRTBUF_1], EVCNT_TYPE_TRAP, 142 1.86 matt NULL, xname, "terminal abort"); 143 1.86 matt evcnt_attach_dynamic_nozero(&ci->ci_abt_evs[FAULT_BUSERR_0], EVCNT_TYPE_TRAP, 144 1.86 matt NULL, xname, "external linefetch abort (S)"); 145 1.86 matt evcnt_attach_dynamic_nozero(&ci->ci_abt_evs[FAULT_BUSERR_1], EVCNT_TYPE_TRAP, 146 1.86 matt NULL, xname, "external linefetch abort (P)"); 147 1.86 matt evcnt_attach_dynamic_nozero(&ci->ci_abt_evs[FAULT_BUSERR_2], EVCNT_TYPE_TRAP, 148 1.86 matt NULL, xname, "external non-linefetch abort (S)"); 149 1.86 matt evcnt_attach_dynamic_nozero(&ci->ci_abt_evs[FAULT_BUSERR_3], EVCNT_TYPE_TRAP, 150 1.86 matt NULL, xname, "external non-linefetch abort (P)"); 151 1.86 matt evcnt_attach_dynamic_nozero(&ci->ci_abt_evs[FAULT_BUSTRNL1], EVCNT_TYPE_TRAP, 152 1.86 matt NULL, xname, "external translation abort (L1)"); 153 1.86 matt evcnt_attach_dynamic_nozero(&ci->ci_abt_evs[FAULT_BUSTRNL2], EVCNT_TYPE_TRAP, 154 1.86 matt NULL, xname, "external translation abort (L2)"); 155 1.86 matt evcnt_attach_dynamic_nozero(&ci->ci_abt_evs[FAULT_ALIGN_0], EVCNT_TYPE_TRAP, 156 1.86 matt NULL, xname, "alignment abort (0)"); 157 1.86 matt evcnt_attach_dynamic_nozero(&ci->ci_abt_evs[FAULT_ALIGN_1], EVCNT_TYPE_TRAP, 158 1.86 matt NULL, xname, "alignment abort (1)"); 159 1.86 matt evcnt_attach_dynamic_nozero(&ci->ci_abt_evs[FAULT_TRANS_S], EVCNT_TYPE_TRAP, 160 1.86 matt NULL, xname, "translation abort (S)"); 161 1.86 matt evcnt_attach_dynamic_nozero(&ci->ci_abt_evs[FAULT_TRANS_P], EVCNT_TYPE_TRAP, 162 1.86 matt NULL, xname, "translation abort (P)"); 163 1.86 matt evcnt_attach_dynamic_nozero(&ci->ci_abt_evs[FAULT_DOMAIN_S], EVCNT_TYPE_TRAP, 164 1.86 matt NULL, xname, "domain abort (S)"); 165 1.86 matt evcnt_attach_dynamic_nozero(&ci->ci_abt_evs[FAULT_DOMAIN_P], EVCNT_TYPE_TRAP, 166 1.86 matt NULL, xname, "domain abort (P)"); 167 1.86 matt evcnt_attach_dynamic_nozero(&ci->ci_abt_evs[FAULT_PERM_S], EVCNT_TYPE_TRAP, 168 1.86 matt NULL, xname, "permission abort (S)"); 169 1.86 matt evcnt_attach_dynamic_nozero(&ci->ci_abt_evs[FAULT_PERM_P], EVCNT_TYPE_TRAP, 170 1.86 matt NULL, xname, "permission abort (P)"); 171 1.104 matt evcnt_attach_dynamic_nozero(&ci->ci_und_ev, EVCNT_TYPE_TRAP, 172 1.104 matt NULL, xname, "undefined insn traps"); 173 1.104 matt evcnt_attach_dynamic_nozero(&ci->ci_und_cp15_ev, EVCNT_TYPE_TRAP, 174 1.104 matt NULL, xname, "undefined cp15 insn traps"); 175 1.1 matt 176 1.85 matt #ifdef MULTIPROCESSOR 177 1.85 matt /* 178 1.85 matt * and we are done if this is a secondary processor. 179 1.85 matt */ 180 1.104 matt if (id != 0) { 181 1.104 matt #if 1 182 1.104 matt aprint_naive("\n"); 183 1.104 matt aprint_normal("\n"); 184 1.104 matt #else 185 1.103 christos aprint_naive(": %s\n", cpu_getmodel()); 186 1.103 christos aprint_normal(": %s\n", cpu_getmodel()); 187 1.104 matt #endif 188 1.85 matt mi_cpu_attach(ci); 189 1.104 matt #ifdef ARM_MMU_EXTENDED 190 1.104 matt pmap_tlb_info_attach(&pmap_tlb0_info, ci); 191 1.104 matt #endif 192 1.85 matt return; 193 1.85 matt } 194 1.85 matt #endif 195 1.1 matt 196 1.85 matt identify_arm_cpu(dv, ci); 197 1.1 matt 198 1.85 matt #ifdef CPU_STRONGARM 199 1.85 matt if (ci->ci_arm_cputype == CPU_ID_SA110 && 200 1.85 matt ci->ci_arm_cpurev < 3) { 201 1.85 matt aprint_normal_dev(dv, "SA-110 with bugged STM^ instruction\n"); 202 1.1 matt } 203 1.85 matt #endif 204 1.1 matt 205 1.1 matt #ifdef CPU_ARM8 206 1.85 matt if ((ci->ci_arm_cpuid & CPU_ID_CPU_MASK) == CPU_ID_ARM810) { 207 1.1 matt int clock = arm8_clock_config(0, 0); 208 1.1 matt char *fclk; 209 1.85 matt aprint_normal_dev(dv, "ARM810 cp15=%02x", clock); 210 1.49 thorpej aprint_normal(" clock:%s", (clock & 1) ? " dynamic" : ""); 211 1.49 thorpej aprint_normal("%s", (clock & 2) ? " sync" : ""); 212 1.1 matt switch ((clock >> 2) & 3) { 213 1.15 bjh21 case 0: 214 1.1 matt fclk = "bus clock"; 215 1.1 matt break; 216 1.15 bjh21 case 1: 217 1.1 matt fclk = "ref clock"; 218 1.1 matt break; 219 1.15 bjh21 case 3: 220 1.1 matt fclk = "pll"; 221 1.1 matt break; 222 1.15 bjh21 default: 223 1.1 matt fclk = "illegal"; 224 1.1 matt break; 225 1.1 matt } 226 1.49 thorpej aprint_normal(" fclk source=%s\n", fclk); 227 1.1 matt } 228 1.1 matt #endif 229 1.1 matt 230 1.104 matt vfp_attach(ci); /* XXX SMP */ 231 1.1 matt } 232 1.1 matt 233 1.19 bjh21 enum cpu_class { 234 1.19 bjh21 CPU_CLASS_NONE, 235 1.19 bjh21 CPU_CLASS_ARM2, 236 1.19 bjh21 CPU_CLASS_ARM2AS, 237 1.19 bjh21 CPU_CLASS_ARM3, 238 1.19 bjh21 CPU_CLASS_ARM6, 239 1.19 bjh21 CPU_CLASS_ARM7, 240 1.19 bjh21 CPU_CLASS_ARM7TDMI, 241 1.19 bjh21 CPU_CLASS_ARM8, 242 1.19 bjh21 CPU_CLASS_ARM9TDMI, 243 1.19 bjh21 CPU_CLASS_ARM9ES, 244 1.64 christos CPU_CLASS_ARM9EJS, 245 1.53 rearnsha CPU_CLASS_ARM10E, 246 1.57 rearnsha CPU_CLASS_ARM10EJ, 247 1.19 bjh21 CPU_CLASS_SA1, 248 1.58 rearnsha CPU_CLASS_XSCALE, 249 1.70 matt CPU_CLASS_ARM11J, 250 1.70 matt CPU_CLASS_ARMV4, 251 1.74 matt CPU_CLASS_CORTEX, 252 1.94 rkujawa CPU_CLASS_PJ4B, 253 1.19 bjh21 }; 254 1.19 bjh21 255 1.42 bjh21 static const char * const generic_steppings[16] = { 256 1.14 bjh21 "rev 0", "rev 1", "rev 2", "rev 3", 257 1.14 bjh21 "rev 4", "rev 5", "rev 6", "rev 7", 258 1.14 bjh21 "rev 8", "rev 9", "rev 10", "rev 11", 259 1.14 bjh21 "rev 12", "rev 13", "rev 14", "rev 15", 260 1.14 bjh21 }; 261 1.14 bjh21 262 1.68 matt static const char * const pN_steppings[16] = { 263 1.68 matt "*p0", "*p1", "*p2", "*p3", "*p4", "*p5", "*p6", "*p7", 264 1.68 matt "*p8", "*p9", "*p10", "*p11", "*p12", "*p13", "*p14", "*p15", 265 1.68 matt }; 266 1.68 matt 267 1.42 bjh21 static const char * const sa110_steppings[16] = { 268 1.14 bjh21 "rev 0", "step J", "step K", "step S", 269 1.14 bjh21 "step T", "rev 5", "rev 6", "rev 7", 270 1.14 bjh21 "rev 8", "rev 9", "rev 10", "rev 11", 271 1.14 bjh21 "rev 12", "rev 13", "rev 14", "rev 15", 272 1.14 bjh21 }; 273 1.14 bjh21 274 1.42 bjh21 static const char * const sa1100_steppings[16] = { 275 1.14 bjh21 "rev 0", "step B", "step C", "rev 3", 276 1.14 bjh21 "rev 4", "rev 5", "rev 6", "rev 7", 277 1.14 bjh21 "step D", "step E", "rev 10" "step G", 278 1.14 bjh21 "rev 12", "rev 13", "rev 14", "rev 15", 279 1.14 bjh21 }; 280 1.14 bjh21 281 1.42 bjh21 static const char * const sa1110_steppings[16] = { 282 1.14 bjh21 "step A-0", "rev 1", "rev 2", "rev 3", 283 1.14 bjh21 "step B-0", "step B-1", "step B-2", "step B-3", 284 1.14 bjh21 "step B-4", "step B-5", "rev 10", "rev 11", 285 1.14 bjh21 "rev 12", "rev 13", "rev 14", "rev 15", 286 1.13 thorpej }; 287 1.13 thorpej 288 1.42 bjh21 static const char * const ixp12x0_steppings[16] = { 289 1.37 ichiro "(IXP1200 step A)", "(IXP1200 step B)", 290 1.37 ichiro "rev 2", "(IXP1200 step C)", 291 1.37 ichiro "(IXP1200 step D)", "(IXP1240/1250 step A)", 292 1.37 ichiro "(IXP1240 step B)", "(IXP1250 step B)", 293 1.36 thorpej "rev 8", "rev 9", "rev 10", "rev 11", 294 1.36 thorpej "rev 12", "rev 13", "rev 14", "rev 15", 295 1.36 thorpej }; 296 1.36 thorpej 297 1.42 bjh21 static const char * const xscale_steppings[16] = { 298 1.14 bjh21 "step A-0", "step A-1", "step B-0", "step C-0", 299 1.40 briggs "step D-0", "rev 5", "rev 6", "rev 7", 300 1.40 briggs "rev 8", "rev 9", "rev 10", "rev 11", 301 1.40 briggs "rev 12", "rev 13", "rev 14", "rev 15", 302 1.40 briggs }; 303 1.40 briggs 304 1.42 bjh21 static const char * const i80321_steppings[16] = { 305 1.40 briggs "step A-0", "step B-0", "rev 2", "rev 3", 306 1.14 bjh21 "rev 4", "rev 5", "rev 6", "rev 7", 307 1.14 bjh21 "rev 8", "rev 9", "rev 10", "rev 11", 308 1.14 bjh21 "rev 12", "rev 13", "rev 14", "rev 15", 309 1.13 thorpej }; 310 1.13 thorpej 311 1.60 nonaka static const char * const i80219_steppings[16] = { 312 1.60 nonaka "step A-0", "rev 1", "rev 2", "rev 3", 313 1.60 nonaka "rev 4", "rev 5", "rev 6", "rev 7", 314 1.60 nonaka "rev 8", "rev 9", "rev 10", "rev 11", 315 1.60 nonaka "rev 12", "rev 13", "rev 14", "rev 15", 316 1.60 nonaka }; 317 1.60 nonaka 318 1.56 bsh /* Steppings for PXA2[15]0 */ 319 1.42 bjh21 static const char * const pxa2x0_steppings[16] = { 320 1.35 thorpej "step A-0", "step A-1", "step B-0", "step B-1", 321 1.48 rjs "step B-2", "step C-0", "rev 6", "rev 7", 322 1.35 thorpej "rev 8", "rev 9", "rev 10", "rev 11", 323 1.35 thorpej "rev 12", "rev 13", "rev 14", "rev 15", 324 1.35 thorpej }; 325 1.35 thorpej 326 1.56 bsh /* Steppings for PXA255/26x. 327 1.56 bsh * rev 5: PXA26x B0, rev 6: PXA255 A0 328 1.56 bsh */ 329 1.56 bsh static const char * const pxa255_steppings[16] = { 330 1.56 bsh "rev 0", "rev 1", "rev 2", "step A-0", 331 1.56 bsh "rev 4", "step B-0", "step A-0", "rev 7", 332 1.56 bsh "rev 8", "rev 9", "rev 10", "rev 11", 333 1.56 bsh "rev 12", "rev 13", "rev 14", "rev 15", 334 1.56 bsh }; 335 1.56 bsh 336 1.59 bsh /* Stepping for PXA27x */ 337 1.59 bsh static const char * const pxa27x_steppings[16] = { 338 1.59 bsh "step A-0", "step A-1", "step B-0", "step B-1", 339 1.59 bsh "step C-0", "rev 5", "rev 6", "rev 7", 340 1.59 bsh "rev 8", "rev 9", "rev 10", "rev 11", 341 1.59 bsh "rev 12", "rev 13", "rev 14", "rev 15", 342 1.59 bsh }; 343 1.59 bsh 344 1.50 ichiro static const char * const ixp425_steppings[16] = { 345 1.50 ichiro "step 0", "rev 1", "rev 2", "rev 3", 346 1.50 ichiro "rev 4", "rev 5", "rev 6", "rev 7", 347 1.50 ichiro "rev 8", "rev 9", "rev 10", "rev 11", 348 1.50 ichiro "rev 12", "rev 13", "rev 14", "rev 15", 349 1.50 ichiro }; 350 1.50 ichiro 351 1.1 matt struct cpuidtab { 352 1.88 skrll uint32_t cpuid; 353 1.1 matt enum cpu_class cpu_class; 354 1.72 mrg const char *cpu_classname; 355 1.42 bjh21 const char * const *cpu_steppings; 356 1.93 matt char cpu_arch[8]; 357 1.1 matt }; 358 1.1 matt 359 1.1 matt const struct cpuidtab cpuids[] = { 360 1.13 thorpej { CPU_ID_ARM2, CPU_CLASS_ARM2, "ARM2", 361 1.93 matt generic_steppings, "2" }, 362 1.13 thorpej { CPU_ID_ARM250, CPU_CLASS_ARM2AS, "ARM250", 363 1.93 matt generic_steppings, "2" }, 364 1.13 thorpej 365 1.13 thorpej { CPU_ID_ARM3, CPU_CLASS_ARM3, "ARM3", 366 1.93 matt generic_steppings, "2A" }, 367 1.13 thorpej 368 1.13 thorpej { CPU_ID_ARM600, CPU_CLASS_ARM6, "ARM600", 369 1.93 matt generic_steppings, "3" }, 370 1.13 thorpej { CPU_ID_ARM610, CPU_CLASS_ARM6, "ARM610", 371 1.93 matt generic_steppings, "3" }, 372 1.13 thorpej { CPU_ID_ARM620, CPU_CLASS_ARM6, "ARM620", 373 1.93 matt generic_steppings, "3" }, 374 1.13 thorpej 375 1.13 thorpej { CPU_ID_ARM700, CPU_CLASS_ARM7, "ARM700", 376 1.93 matt generic_steppings, "3" }, 377 1.13 thorpej { CPU_ID_ARM710, CPU_CLASS_ARM7, "ARM710", 378 1.93 matt generic_steppings, "3" }, 379 1.13 thorpej { CPU_ID_ARM7500, CPU_CLASS_ARM7, "ARM7500", 380 1.93 matt generic_steppings, "3" }, 381 1.13 thorpej { CPU_ID_ARM710A, CPU_CLASS_ARM7, "ARM710a", 382 1.93 matt generic_steppings, "3" }, 383 1.13 thorpej { CPU_ID_ARM7500FE, CPU_CLASS_ARM7, "ARM7500FE", 384 1.93 matt generic_steppings, "3" }, 385 1.93 matt 386 1.93 matt { CPU_ID_ARM810, CPU_CLASS_ARM8, "ARM810", 387 1.93 matt generic_steppings, "4" }, 388 1.93 matt 389 1.93 matt { CPU_ID_SA110, CPU_CLASS_SA1, "SA-110", 390 1.93 matt sa110_steppings, "4" }, 391 1.93 matt { CPU_ID_SA1100, CPU_CLASS_SA1, "SA-1100", 392 1.93 matt sa1100_steppings, "4" }, 393 1.93 matt { CPU_ID_SA1110, CPU_CLASS_SA1, "SA-1110", 394 1.93 matt sa1110_steppings, "4" }, 395 1.93 matt 396 1.93 matt { CPU_ID_FA526, CPU_CLASS_ARMV4, "FA526", 397 1.93 matt generic_steppings, "4" }, 398 1.93 matt 399 1.93 matt { CPU_ID_IXP1200, CPU_CLASS_SA1, "IXP1200", 400 1.93 matt ixp12x0_steppings, "4" }, 401 1.93 matt 402 1.13 thorpej { CPU_ID_ARM710T, CPU_CLASS_ARM7TDMI, "ARM710T", 403 1.93 matt generic_steppings, "4T" }, 404 1.13 thorpej { CPU_ID_ARM720T, CPU_CLASS_ARM7TDMI, "ARM720T", 405 1.93 matt generic_steppings, "4T" }, 406 1.13 thorpej { CPU_ID_ARM740T8K, CPU_CLASS_ARM7TDMI, "ARM740T (8 KB cache)", 407 1.93 matt generic_steppings, "4T" }, 408 1.13 thorpej { CPU_ID_ARM740T4K, CPU_CLASS_ARM7TDMI, "ARM740T (4 KB cache)", 409 1.93 matt generic_steppings, "4T" }, 410 1.13 thorpej { CPU_ID_ARM920T, CPU_CLASS_ARM9TDMI, "ARM920T", 411 1.93 matt generic_steppings, "4T" }, 412 1.13 thorpej { CPU_ID_ARM922T, CPU_CLASS_ARM9TDMI, "ARM922T", 413 1.93 matt generic_steppings, "4T" }, 414 1.13 thorpej { CPU_ID_ARM940T, CPU_CLASS_ARM9TDMI, "ARM940T", 415 1.93 matt generic_steppings, "4T" }, 416 1.93 matt { CPU_ID_TI925T, CPU_CLASS_ARM9TDMI, "TI ARM925T", 417 1.93 matt generic_steppings, "4T" }, 418 1.93 matt 419 1.13 thorpej { CPU_ID_ARM946ES, CPU_CLASS_ARM9ES, "ARM946E-S", 420 1.93 matt generic_steppings, "5TE" }, 421 1.13 thorpej { CPU_ID_ARM966ES, CPU_CLASS_ARM9ES, "ARM966E-S", 422 1.93 matt generic_steppings, "5TE" }, 423 1.13 thorpej { CPU_ID_ARM966ESR1, CPU_CLASS_ARM9ES, "ARM966E-S", 424 1.93 matt generic_steppings, "5TE" }, 425 1.77 kiyohara { CPU_ID_MV88SV131, CPU_CLASS_ARM9ES, "Sheeva 88SV131", 426 1.93 matt generic_steppings, "5TE" }, 427 1.77 kiyohara { CPU_ID_MV88FR571_VD, CPU_CLASS_ARM9ES, "Sheeva 88FR571-vd", 428 1.93 matt generic_steppings, "5TE" }, 429 1.13 thorpej 430 1.32 thorpej { CPU_ID_80200, CPU_CLASS_XSCALE, "i80200", 431 1.93 matt xscale_steppings, "5TE" }, 432 1.32 thorpej 433 1.38 thorpej { CPU_ID_80321_400, CPU_CLASS_XSCALE, "i80321 400MHz", 434 1.93 matt i80321_steppings, "5TE" }, 435 1.38 thorpej { CPU_ID_80321_600, CPU_CLASS_XSCALE, "i80321 600MHz", 436 1.93 matt i80321_steppings, "5TE" }, 437 1.40 briggs { CPU_ID_80321_400_B0, CPU_CLASS_XSCALE, "i80321 400MHz", 438 1.93 matt i80321_steppings, "5TE" }, 439 1.40 briggs { CPU_ID_80321_600_B0, CPU_CLASS_XSCALE, "i80321 600MHz", 440 1.93 matt i80321_steppings, "5TE" }, 441 1.13 thorpej 442 1.60 nonaka { CPU_ID_80219_400, CPU_CLASS_XSCALE, "i80219 400MHz", 443 1.93 matt i80219_steppings, "5TE" }, 444 1.60 nonaka { CPU_ID_80219_600, CPU_CLASS_XSCALE, "i80219 600MHz", 445 1.93 matt i80219_steppings, "5TE" }, 446 1.60 nonaka 447 1.59 bsh { CPU_ID_PXA27X, CPU_CLASS_XSCALE, "PXA27x", 448 1.93 matt pxa27x_steppings, "5TE" }, 449 1.48 rjs { CPU_ID_PXA250A, CPU_CLASS_XSCALE, "PXA250", 450 1.93 matt pxa2x0_steppings, "5TE" }, 451 1.48 rjs { CPU_ID_PXA210A, CPU_CLASS_XSCALE, "PXA210", 452 1.93 matt pxa2x0_steppings, "5TE" }, 453 1.48 rjs { CPU_ID_PXA250B, CPU_CLASS_XSCALE, "PXA250", 454 1.93 matt pxa2x0_steppings, "5TE" }, 455 1.48 rjs { CPU_ID_PXA210B, CPU_CLASS_XSCALE, "PXA210", 456 1.93 matt pxa2x0_steppings, "5TE" }, 457 1.56 bsh { CPU_ID_PXA250C, CPU_CLASS_XSCALE, "PXA255/26x", 458 1.93 matt pxa255_steppings, "5TE" }, 459 1.48 rjs { CPU_ID_PXA210C, CPU_CLASS_XSCALE, "PXA210", 460 1.93 matt pxa2x0_steppings, "5TE" }, 461 1.35 thorpej 462 1.50 ichiro { CPU_ID_IXP425_533, CPU_CLASS_XSCALE, "IXP425 533MHz", 463 1.93 matt ixp425_steppings, "5TE" }, 464 1.50 ichiro { CPU_ID_IXP425_400, CPU_CLASS_XSCALE, "IXP425 400MHz", 465 1.93 matt ixp425_steppings, "5TE" }, 466 1.50 ichiro { CPU_ID_IXP425_266, CPU_CLASS_XSCALE, "IXP425 266MHz", 467 1.93 matt ixp425_steppings, "5TE" }, 468 1.93 matt 469 1.93 matt { CPU_ID_ARM1020E, CPU_CLASS_ARM10E, "ARM1020E", 470 1.93 matt generic_steppings, "5TE" }, 471 1.93 matt { CPU_ID_ARM1022ES, CPU_CLASS_ARM10E, "ARM1022E-S", 472 1.93 matt generic_steppings, "5TE" }, 473 1.93 matt 474 1.93 matt { CPU_ID_ARM1026EJS, CPU_CLASS_ARM10EJ, "ARM1026EJ-S", 475 1.93 matt generic_steppings, "5TEJ" }, 476 1.93 matt { CPU_ID_ARM926EJS, CPU_CLASS_ARM9EJS, "ARM926EJ-S", 477 1.93 matt generic_steppings, "5TEJ" }, 478 1.50 ichiro 479 1.68 matt { CPU_ID_ARM1136JS, CPU_CLASS_ARM11J, "ARM1136J-S r0", 480 1.93 matt pN_steppings, "6J" }, 481 1.68 matt { CPU_ID_ARM1136JSR1, CPU_CLASS_ARM11J, "ARM1136J-S r1", 482 1.93 matt pN_steppings, "6J" }, 483 1.81 skrll #if 0 484 1.81 skrll /* The ARM1156T2-S only has a memory protection unit */ 485 1.80 skrll { CPU_ID_ARM1156T2S, CPU_CLASS_ARM11J, "ARM1156T2-S r0", 486 1.93 matt pN_steppings, "6T2" }, 487 1.81 skrll #endif 488 1.79 skrll { CPU_ID_ARM1176JZS, CPU_CLASS_ARM11J, "ARM1176JZ-S r0", 489 1.93 matt pN_steppings, "6ZK" }, 490 1.74 matt 491 1.78 bsh { CPU_ID_ARM11MPCORE, CPU_CLASS_ARM11J, "ARM11 MPCore", 492 1.93 matt generic_steppings, "6K" }, 493 1.78 bsh 494 1.82 matt { CPU_ID_CORTEXA5R0, CPU_CLASS_CORTEX, "Cortex-A5 r0", 495 1.93 matt pN_steppings, "7A" }, 496 1.98 matt { CPU_ID_CORTEXA7R0, CPU_CLASS_CORTEX, "Cortex-A7 r0", 497 1.98 matt pN_steppings, "7A" }, 498 1.74 matt { CPU_ID_CORTEXA8R1, CPU_CLASS_CORTEX, "Cortex-A8 r1", 499 1.93 matt pN_steppings, "7A" }, 500 1.74 matt { CPU_ID_CORTEXA8R2, CPU_CLASS_CORTEX, "Cortex-A8 r2", 501 1.93 matt pN_steppings, "7A" }, 502 1.74 matt { CPU_ID_CORTEXA8R3, CPU_CLASS_CORTEX, "Cortex-A8 r3", 503 1.93 matt pN_steppings, "7A" }, 504 1.114 kiyohara { CPU_ID_CORTEXA9R1, CPU_CLASS_CORTEX, "Cortex-A9 r1", 505 1.114 kiyohara pN_steppings, "7A" }, 506 1.82 matt { CPU_ID_CORTEXA9R2, CPU_CLASS_CORTEX, "Cortex-A9 r2", 507 1.93 matt pN_steppings, "7A" }, 508 1.82 matt { CPU_ID_CORTEXA9R3, CPU_CLASS_CORTEX, "Cortex-A9 r3", 509 1.93 matt pN_steppings, "7A" }, 510 1.82 matt { CPU_ID_CORTEXA9R4, CPU_CLASS_CORTEX, "Cortex-A9 r4", 511 1.93 matt pN_steppings, "7A" }, 512 1.82 matt { CPU_ID_CORTEXA15R2, CPU_CLASS_CORTEX, "Cortex-A15 r2", 513 1.93 matt pN_steppings, "7A" }, 514 1.82 matt { CPU_ID_CORTEXA15R3, CPU_CLASS_CORTEX, "Cortex-A15 r3", 515 1.93 matt pN_steppings, "7A" }, 516 1.106 matt { CPU_ID_CORTEXA17R1, CPU_CLASS_CORTEX, "Cortex-A17 r1", 517 1.106 matt pN_steppings, "7A" }, 518 1.116 matt { CPU_ID_CORTEXA35R0, CPU_CLASS_CORTEX, "Cortex-A35 r0", 519 1.116 matt pN_steppings, "8A" }, 520 1.113 skrll { CPU_ID_CORTEXA53R0, CPU_CLASS_CORTEX, "Cortex-A53 r0", 521 1.113 skrll pN_steppings, "8A" }, 522 1.113 skrll { CPU_ID_CORTEXA57R0, CPU_CLASS_CORTEX, "Cortex-A57 r0", 523 1.113 skrll pN_steppings, "8A" }, 524 1.113 skrll { CPU_ID_CORTEXA57R1, CPU_CLASS_CORTEX, "Cortex-A57 r1", 525 1.113 skrll pN_steppings, "8A" }, 526 1.113 skrll { CPU_ID_CORTEXA72R0, CPU_CLASS_CORTEX, "Cortex-A72 r0", 527 1.113 skrll pN_steppings, "8A" }, 528 1.70 matt 529 1.94 rkujawa { CPU_ID_MV88SV581X_V6, CPU_CLASS_PJ4B, "Sheeva 88SV581x", 530 1.94 rkujawa generic_steppings }, 531 1.94 rkujawa { CPU_ID_ARM_88SV581X_V6, CPU_CLASS_PJ4B, "Sheeva 88SV581x", 532 1.94 rkujawa generic_steppings }, 533 1.94 rkujawa { CPU_ID_MV88SV581X_V7, CPU_CLASS_PJ4B, "Sheeva 88SV581x", 534 1.94 rkujawa generic_steppings }, 535 1.94 rkujawa { CPU_ID_ARM_88SV581X_V7, CPU_CLASS_PJ4B, "Sheeva 88SV581x", 536 1.94 rkujawa generic_steppings }, 537 1.94 rkujawa { CPU_ID_MV88SV584X_V6, CPU_CLASS_PJ4B, "Sheeva 88SV584x", 538 1.94 rkujawa generic_steppings }, 539 1.94 rkujawa { CPU_ID_ARM_88SV584X_V6, CPU_CLASS_PJ4B, "Sheeva 88SV584x", 540 1.94 rkujawa generic_steppings }, 541 1.94 rkujawa { CPU_ID_MV88SV584X_V7, CPU_CLASS_PJ4B, "Sheeva 88SV584x", 542 1.94 rkujawa generic_steppings }, 543 1.94 rkujawa 544 1.94 rkujawa 545 1.93 matt { 0, CPU_CLASS_NONE, NULL, NULL, "" } 546 1.1 matt }; 547 1.1 matt 548 1.1 matt struct cpu_classtab { 549 1.9 thorpej const char *class_name; 550 1.9 thorpej const char *class_option; 551 1.1 matt }; 552 1.1 matt 553 1.1 matt const struct cpu_classtab cpu_classes[] = { 554 1.74 matt [CPU_CLASS_NONE] = { "unknown", NULL }, 555 1.74 matt [CPU_CLASS_ARM2] = { "ARM2", "CPU_ARM2" }, 556 1.74 matt [CPU_CLASS_ARM2AS] = { "ARM2as", "CPU_ARM250" }, 557 1.74 matt [CPU_CLASS_ARM3] = { "ARM3", "CPU_ARM3" }, 558 1.74 matt [CPU_CLASS_ARM6] = { "ARM6", "CPU_ARM6" }, 559 1.74 matt [CPU_CLASS_ARM7] = { "ARM7", "CPU_ARM7" }, 560 1.74 matt [CPU_CLASS_ARM7TDMI] = { "ARM7TDMI", "CPU_ARM7TDMI" }, 561 1.74 matt [CPU_CLASS_ARM8] = { "ARM8", "CPU_ARM8" }, 562 1.74 matt [CPU_CLASS_ARM9TDMI] = { "ARM9TDMI", NULL }, 563 1.74 matt [CPU_CLASS_ARM9ES] = { "ARM9E-S", "CPU_ARM9E" }, 564 1.74 matt [CPU_CLASS_ARM9EJS] = { "ARM9EJ-S", "CPU_ARM9E" }, 565 1.74 matt [CPU_CLASS_ARM10E] = { "ARM10E", "CPU_ARM10" }, 566 1.74 matt [CPU_CLASS_ARM10EJ] = { "ARM10EJ", "CPU_ARM10" }, 567 1.74 matt [CPU_CLASS_SA1] = { "SA-1", "CPU_SA110" }, 568 1.74 matt [CPU_CLASS_XSCALE] = { "XScale", "CPU_XSCALE_..." }, 569 1.74 matt [CPU_CLASS_ARM11J] = { "ARM11J", "CPU_ARM11" }, 570 1.74 matt [CPU_CLASS_ARMV4] = { "ARMv4", "CPU_ARMV4" }, 571 1.75 matt [CPU_CLASS_CORTEX] = { "Cortex", "CPU_CORTEX" }, 572 1.94 rkujawa [CPU_CLASS_PJ4B] = { "Marvell", "CPU_PJ4B" }, 573 1.1 matt }; 574 1.1 matt 575 1.1 matt /* 576 1.47 wiz * Report the type of the specified arm processor. This uses the generic and 577 1.55 wiz * arm specific information in the CPU structure to identify the processor. 578 1.55 wiz * The remaining fields in the CPU structure are filled in appropriately. 579 1.1 matt */ 580 1.1 matt 581 1.42 bjh21 static const char * const wtnames[] = { 582 1.12 thorpej "write-through", 583 1.12 thorpej "write-back", 584 1.12 thorpej "write-back", 585 1.12 thorpej "**unknown 3**", 586 1.12 thorpej "**unknown 4**", 587 1.12 thorpej "write-back-locking", /* XXX XScale-specific? */ 588 1.12 thorpej "write-back-locking-A", 589 1.12 thorpej "write-back-locking-B", 590 1.12 thorpej "**unknown 8**", 591 1.12 thorpej "**unknown 9**", 592 1.12 thorpej "**unknown 10**", 593 1.12 thorpej "**unknown 11**", 594 1.107 jmcneill "write-back", 595 1.102 matt "write-back-locking-line", 596 1.57 rearnsha "write-back-locking-C", 597 1.86 matt "write-back-locking-D", 598 1.12 thorpej }; 599 1.12 thorpej 600 1.86 matt static void 601 1.86 matt print_cache_info(device_t dv, struct arm_cache_info *info, u_int level) 602 1.86 matt { 603 1.86 matt if (info->cache_unified) { 604 1.100 matt aprint_normal_dev(dv, "%dKB/%dB %d-way %s L%u %cI%cT Unified cache\n", 605 1.86 matt info->dcache_size / 1024, 606 1.86 matt info->dcache_line_size, info->dcache_ways, 607 1.100 matt wtnames[info->cache_type], level + 1, 608 1.100 matt info->dcache_type & CACHE_TYPE_PIxx ? 'P' : 'V', 609 1.100 matt info->dcache_type & CACHE_TYPE_xxPT ? 'P' : 'V'); 610 1.86 matt } else { 611 1.100 matt aprint_normal_dev(dv, "%dKB/%dB %d-way L%u %cI%cT Instruction cache\n", 612 1.86 matt info->icache_size / 1024, 613 1.100 matt info->icache_line_size, info->icache_ways, level + 1, 614 1.100 matt info->icache_type & CACHE_TYPE_PIxx ? 'P' : 'V', 615 1.100 matt info->icache_type & CACHE_TYPE_xxPT ? 'P' : 'V'); 616 1.100 matt aprint_normal_dev(dv, "%dKB/%dB %d-way %s L%u %cI%cT Data cache\n", 617 1.86 matt info->dcache_size / 1024, 618 1.86 matt info->dcache_line_size, info->dcache_ways, 619 1.100 matt wtnames[info->cache_type], level + 1, 620 1.100 matt info->dcache_type & CACHE_TYPE_PIxx ? 'P' : 'V', 621 1.100 matt info->dcache_type & CACHE_TYPE_xxPT ? 'P' : 'V'); 622 1.86 matt } 623 1.86 matt } 624 1.86 matt 625 1.104 matt static enum cpu_class 626 1.104 matt identify_arm_model(uint32_t cpuid, char *buf, size_t len) 627 1.104 matt { 628 1.104 matt enum cpu_class cpu_class = CPU_CLASS_NONE; 629 1.104 matt for (const struct cpuidtab *id = cpuids; id->cpuid != 0; id++) { 630 1.104 matt if (id->cpuid == (cpuid & CPU_ID_CPU_MASK)) { 631 1.104 matt const char *steppingstr = 632 1.104 matt id->cpu_steppings[cpuid & CPU_ID_REVISION_MASK]; 633 1.104 matt cpu_arch = id->cpu_arch; 634 1.104 matt cpu_class = id->cpu_class; 635 1.104 matt snprintf(buf, len, "%s%s%s (%s V%s core)", 636 1.104 matt id->cpu_classname, 637 1.104 matt steppingstr[0] == '*' ? "" : " ", 638 1.104 matt &steppingstr[steppingstr[0] == '*'], 639 1.104 matt cpu_classes[cpu_class].class_name, 640 1.104 matt cpu_arch); 641 1.104 matt return cpu_class; 642 1.104 matt } 643 1.104 matt } 644 1.104 matt 645 1.104 matt snprintf(buf, len, "unknown CPU (ID = 0x%x)", cpuid); 646 1.104 matt return cpu_class; 647 1.104 matt } 648 1.104 matt 649 1.1 matt void 650 1.84 matt identify_arm_cpu(device_t dv, struct cpu_info *ci) 651 1.1 matt { 652 1.104 matt const uint32_t arm_cpuid = ci->ci_arm_cpuid; 653 1.85 matt const char * const xname = device_xname(dv); 654 1.104 matt char model[128]; 655 1.1 matt 656 1.104 matt if (arm_cpuid == 0) { 657 1.49 thorpej aprint_error("Processor failed probe - no CPU ID\n"); 658 1.1 matt return; 659 1.1 matt } 660 1.1 matt 661 1.104 matt const enum cpu_class cpu_class = identify_arm_model(arm_cpuid, 662 1.104 matt model, sizeof(model)); 663 1.104 matt if (ci->ci_cpuid == 0) { 664 1.104 matt cpu_setmodel("%s", model); 665 1.104 matt } 666 1.1 matt 667 1.85 matt if (ci->ci_data.cpu_cc_freq != 0) { 668 1.105 reinoud char freqbuf[10]; 669 1.85 matt humanize_number(freqbuf, sizeof(freqbuf), ci->ci_data.cpu_cc_freq, 670 1.85 matt "Hz", 1000); 671 1.85 matt 672 1.104 matt aprint_naive(": %s %s\n", freqbuf, model); 673 1.104 matt aprint_normal(": %s %s\n", freqbuf, model); 674 1.85 matt } else { 675 1.104 matt aprint_naive(": %s\n", model); 676 1.104 matt aprint_normal(": %s\n", model); 677 1.85 matt } 678 1.29 bjh21 679 1.85 matt aprint_normal("%s:", xname); 680 1.29 bjh21 681 1.19 bjh21 switch (cpu_class) { 682 1.1 matt case CPU_CLASS_ARM6: 683 1.1 matt case CPU_CLASS_ARM7: 684 1.3 chris case CPU_CLASS_ARM7TDMI: 685 1.1 matt case CPU_CLASS_ARM8: 686 1.18 bjh21 if ((ci->ci_ctrl & CPU_CONTROL_IDC_ENABLE) == 0) 687 1.49 thorpej aprint_normal(" IDC disabled"); 688 1.1 matt else 689 1.49 thorpej aprint_normal(" IDC enabled"); 690 1.1 matt break; 691 1.6 rearnsha case CPU_CLASS_ARM9TDMI: 692 1.64 christos case CPU_CLASS_ARM9ES: 693 1.64 christos case CPU_CLASS_ARM9EJS: 694 1.53 rearnsha case CPU_CLASS_ARM10E: 695 1.57 rearnsha case CPU_CLASS_ARM10EJ: 696 1.1 matt case CPU_CLASS_SA1: 697 1.4 matt case CPU_CLASS_XSCALE: 698 1.58 rearnsha case CPU_CLASS_ARM11J: 699 1.71 matt case CPU_CLASS_ARMV4: 700 1.74 matt case CPU_CLASS_CORTEX: 701 1.94 rkujawa case CPU_CLASS_PJ4B: 702 1.18 bjh21 if ((ci->ci_ctrl & CPU_CONTROL_DC_ENABLE) == 0) 703 1.49 thorpej aprint_normal(" DC disabled"); 704 1.1 matt else 705 1.49 thorpej aprint_normal(" DC enabled"); 706 1.18 bjh21 if ((ci->ci_ctrl & CPU_CONTROL_IC_ENABLE) == 0) 707 1.49 thorpej aprint_normal(" IC disabled"); 708 1.1 matt else 709 1.49 thorpej aprint_normal(" IC enabled"); 710 1.1 matt break; 711 1.19 bjh21 default: 712 1.19 bjh21 break; 713 1.1 matt } 714 1.18 bjh21 if ((ci->ci_ctrl & CPU_CONTROL_WBUF_ENABLE) == 0) 715 1.49 thorpej aprint_normal(" WB disabled"); 716 1.1 matt else 717 1.49 thorpej aprint_normal(" WB enabled"); 718 1.1 matt 719 1.18 bjh21 if (ci->ci_ctrl & CPU_CONTROL_LABT_ENABLE) 720 1.49 thorpej aprint_normal(" LABT"); 721 1.1 matt else 722 1.49 thorpej aprint_normal(" EABT"); 723 1.1 matt 724 1.18 bjh21 if (ci->ci_ctrl & CPU_CONTROL_BPRD_ENABLE) 725 1.49 thorpej aprint_normal(" branch prediction enabled"); 726 1.1 matt 727 1.49 thorpej aprint_normal("\n"); 728 1.1 matt 729 1.104 matt if (CPU_ID_CORTEX_P(arm_cpuid) || CPU_ID_ARM11_P(arm_cpuid) || CPU_ID_MV88SV58XX_P(arm_cpuid)) { 730 1.87 matt identify_features(dv); 731 1.87 matt } 732 1.92 matt 733 1.12 thorpej /* Print cache info. */ 734 1.86 matt if (arm_pcache.icache_line_size != 0 || arm_pcache.dcache_line_size != 0) { 735 1.86 matt print_cache_info(dv, &arm_pcache, 0); 736 1.86 matt } 737 1.86 matt if (arm_scache.icache_line_size != 0 || arm_scache.dcache_line_size != 0) { 738 1.86 matt print_cache_info(dv, &arm_scache, 1); 739 1.12 thorpej } 740 1.12 thorpej 741 1.1 matt 742 1.19 bjh21 switch (cpu_class) { 743 1.1 matt #ifdef CPU_ARM6 744 1.1 matt case CPU_CLASS_ARM6: 745 1.1 matt #endif 746 1.1 matt #ifdef CPU_ARM7 747 1.1 matt case CPU_CLASS_ARM7: 748 1.1 matt #endif 749 1.3 chris #ifdef CPU_ARM7TDMI 750 1.3 chris case CPU_CLASS_ARM7TDMI: 751 1.3 chris #endif 752 1.1 matt #ifdef CPU_ARM8 753 1.1 matt case CPU_CLASS_ARM8: 754 1.6 rearnsha #endif 755 1.6 rearnsha #ifdef CPU_ARM9 756 1.6 rearnsha case CPU_CLASS_ARM9TDMI: 757 1.53 rearnsha #endif 758 1.77 kiyohara #if defined(CPU_ARM9E) || defined(CPU_SHEEVA) 759 1.64 christos case CPU_CLASS_ARM9ES: 760 1.64 christos case CPU_CLASS_ARM9EJS: 761 1.64 christos #endif 762 1.53 rearnsha #ifdef CPU_ARM10 763 1.53 rearnsha case CPU_CLASS_ARM10E: 764 1.57 rearnsha case CPU_CLASS_ARM10EJ: 765 1.1 matt #endif 766 1.37 ichiro #if defined(CPU_SA110) || defined(CPU_SA1100) || \ 767 1.37 ichiro defined(CPU_SA1110) || defined(CPU_IXP12X0) 768 1.1 matt case CPU_CLASS_SA1: 769 1.4 matt #endif 770 1.35 thorpej #if defined(CPU_XSCALE_80200) || defined(CPU_XSCALE_80321) || \ 771 1.59 bsh defined(__CPU_XSCALE_PXA2XX) || defined(CPU_XSCALE_IXP425) 772 1.4 matt case CPU_CLASS_XSCALE: 773 1.1 matt #endif 774 1.68 matt #if defined(CPU_ARM11) 775 1.58 rearnsha case CPU_CLASS_ARM11J: 776 1.76 matt #endif 777 1.76 matt #if defined(CPU_CORTEX) 778 1.74 matt case CPU_CLASS_CORTEX: 779 1.58 rearnsha #endif 780 1.94 rkujawa #if defined(CPU_PJ4B) 781 1.94 rkujawa case CPU_CLASS_PJ4B: 782 1.94 rkujawa #endif 783 1.71 matt #if defined(CPU_FA526) 784 1.71 matt case CPU_CLASS_ARMV4: 785 1.71 matt #endif 786 1.1 matt break; 787 1.1 matt default: 788 1.85 matt if (cpu_classes[cpu_class].class_option == NULL) { 789 1.85 matt aprint_error_dev(dv, "%s does not fully support this CPU.\n", 790 1.85 matt ostype); 791 1.85 matt } else { 792 1.85 matt aprint_error_dev(dv, "This kernel does not fully support " 793 1.85 matt "this CPU.\n"); 794 1.85 matt aprint_normal_dev(dv, "Recompile with \"options %s\" to " 795 1.85 matt "correct this.\n", cpu_classes[cpu_class].class_option); 796 1.1 matt } 797 1.1 matt break; 798 1.1 matt } 799 1.43 bjh21 } 800 1.1 matt 801 1.92 matt extern int cpu_instruction_set_attributes[6]; 802 1.92 matt extern int cpu_memory_model_features[4]; 803 1.92 matt extern int cpu_processor_features[2]; 804 1.92 matt extern int cpu_simd_present; 805 1.92 matt extern int cpu_simdex_present; 806 1.92 matt 807 1.85 matt void 808 1.85 matt identify_features(device_t dv) 809 1.85 matt { 810 1.92 matt cpu_instruction_set_attributes[0] = armreg_isar0_read(); 811 1.92 matt cpu_instruction_set_attributes[1] = armreg_isar1_read(); 812 1.92 matt cpu_instruction_set_attributes[2] = armreg_isar2_read(); 813 1.92 matt cpu_instruction_set_attributes[3] = armreg_isar3_read(); 814 1.92 matt cpu_instruction_set_attributes[4] = armreg_isar4_read(); 815 1.92 matt cpu_instruction_set_attributes[5] = armreg_isar5_read(); 816 1.92 matt 817 1.99 matt cpu_hwdiv_present = 818 1.99 matt ((cpu_instruction_set_attributes[0] >> 24) & 0x0f) >= 2; 819 1.92 matt cpu_simd_present = 820 1.92 matt ((cpu_instruction_set_attributes[3] >> 4) & 0x0f) >= 3; 821 1.92 matt cpu_simdex_present = cpu_simd_present 822 1.92 matt && ((cpu_instruction_set_attributes[1] >> 12) & 0x0f) >= 2; 823 1.101 matt cpu_synchprim_present = 824 1.101 matt ((cpu_instruction_set_attributes[3] >> 8) & 0xf0) 825 1.101 matt | ((cpu_instruction_set_attributes[4] >> 20) & 0x0f); 826 1.92 matt 827 1.92 matt cpu_memory_model_features[0] = armreg_mmfr0_read(); 828 1.92 matt cpu_memory_model_features[1] = armreg_mmfr1_read(); 829 1.92 matt cpu_memory_model_features[2] = armreg_mmfr2_read(); 830 1.92 matt cpu_memory_model_features[3] = armreg_mmfr3_read(); 831 1.85 matt 832 1.104 matt #if 0 833 1.92 matt if (__SHIFTOUT(cpu_memory_model_features[3], __BITS(23,20))) { 834 1.87 matt /* 835 1.87 matt * Updates to the translation tables do not require a clean 836 1.92 matt * to the point of unification to ensure visibility by 837 1.92 matt * subsequent translation table walks. 838 1.87 matt */ 839 1.87 matt pmap_needs_pte_sync = 0; 840 1.87 matt } 841 1.104 matt #endif 842 1.87 matt 843 1.92 matt cpu_processor_features[0] = armreg_pfr0_read(); 844 1.92 matt cpu_processor_features[1] = armreg_pfr1_read(); 845 1.85 matt 846 1.111 jmcneill aprint_debug_dev(dv, "sctlr: %#x\n", armreg_sctlr_read()); 847 1.111 jmcneill aprint_debug_dev(dv, "actlr: %#x\n", armreg_auxctl_read()); 848 1.111 jmcneill aprint_debug_dev(dv, "revidr: %#x\n", armreg_revidr_read()); 849 1.108 matt #ifdef MULTIPROCESSOR 850 1.111 jmcneill aprint_debug_dev(dv, "mpidr: %#x\n", armreg_mpidr_read()); 851 1.108 matt #endif 852 1.111 jmcneill aprint_debug_dev(dv, 853 1.85 matt "isar: [0]=%#x [1]=%#x [2]=%#x [3]=%#x, [4]=%#x, [5]=%#x\n", 854 1.92 matt cpu_instruction_set_attributes[0], 855 1.92 matt cpu_instruction_set_attributes[1], 856 1.92 matt cpu_instruction_set_attributes[2], 857 1.92 matt cpu_instruction_set_attributes[3], 858 1.92 matt cpu_instruction_set_attributes[4], 859 1.92 matt cpu_instruction_set_attributes[5]); 860 1.111 jmcneill aprint_debug_dev(dv, 861 1.85 matt "mmfr: [0]=%#x [1]=%#x [2]=%#x [3]=%#x\n", 862 1.92 matt cpu_memory_model_features[0], cpu_memory_model_features[1], 863 1.92 matt cpu_memory_model_features[2], cpu_memory_model_features[3]); 864 1.111 jmcneill aprint_debug_dev(dv, 865 1.85 matt "pfr: [0]=%#x [1]=%#x\n", 866 1.92 matt cpu_processor_features[0], cpu_processor_features[1]); 867 1.85 matt } 868
Indexes created Thu Sep 25 06:09:39 GMT 2025