machdep.c revision 1.43
1 1.43 cgd /* $NetBSD: machdep.c,v 1.43 1996/10/01 18:41:08 cgd Exp $ */ 2 1.1 cgd 3 1.1 cgd /* 4 1.16 cgd * Copyright (c) 1994, 1995, 1996 Carnegie-Mellon University. 5 1.1 cgd * All rights reserved. 6 1.1 cgd * 7 1.1 cgd * Author: Chris G. Demetriou 8 1.1 cgd * 9 1.1 cgd * Permission to use, copy, modify and distribute this software and 10 1.1 cgd * its documentation is hereby granted, provided that both the copyright 11 1.1 cgd * notice and this permission notice appear in all copies of the 12 1.1 cgd * software, derivative works or modified versions, and any portions 13 1.1 cgd * thereof, and that both notices appear in supporting documentation. 14 1.1 cgd * 15 1.1 cgd * CARNEGIE MELLON ALLOWS FREE USE OF THIS SOFTWARE IN ITS "AS IS" 16 1.1 cgd * CONDITION. CARNEGIE MELLON DISCLAIMS ANY LIABILITY OF ANY KIND 17 1.1 cgd * FOR ANY DAMAGES WHATSOEVER RESULTING FROM THE USE OF THIS SOFTWARE. 18 1.1 cgd * 19 1.1 cgd * Carnegie Mellon requests users of this software to return to 20 1.1 cgd * 21 1.1 cgd * Software Distribution Coordinator or Software.Distribution (at) CS.CMU.EDU 22 1.1 cgd * School of Computer Science 23 1.1 cgd * Carnegie Mellon University 24 1.1 cgd * Pittsburgh PA 15213-3890 25 1.1 cgd * 26 1.1 cgd * any improvements or extensions that they make and grant Carnegie the 27 1.1 cgd * rights to redistribute these changes. 28 1.1 cgd */ 29 1.1 cgd 30 1.1 cgd #include <sys/param.h> 31 1.1 cgd #include <sys/systm.h> 32 1.1 cgd #include <sys/signalvar.h> 33 1.1 cgd #include <sys/kernel.h> 34 1.1 cgd #include <sys/map.h> 35 1.1 cgd #include <sys/proc.h> 36 1.1 cgd #include <sys/buf.h> 37 1.1 cgd #include <sys/reboot.h> 38 1.28 cgd #include <sys/device.h> 39 1.1 cgd #include <sys/conf.h> 40 1.1 cgd #include <sys/file.h> 41 1.1 cgd #ifdef REAL_CLISTS 42 1.1 cgd #include <sys/clist.h> 43 1.1 cgd #endif 44 1.1 cgd #include <sys/callout.h> 45 1.1 cgd #include <sys/malloc.h> 46 1.1 cgd #include <sys/mbuf.h> 47 1.1 cgd #include <sys/msgbuf.h> 48 1.1 cgd #include <sys/ioctl.h> 49 1.1 cgd #include <sys/tty.h> 50 1.1 cgd #include <sys/user.h> 51 1.1 cgd #include <sys/exec.h> 52 1.1 cgd #include <sys/exec_ecoff.h> 53 1.1 cgd #include <sys/sysctl.h> 54 1.43 cgd #include <sys/core.h> 55 1.43 cgd #include <sys/kcore.h> 56 1.43 cgd #include <machine/kcore.h> 57 1.1 cgd #ifdef SYSVMSG 58 1.1 cgd #include <sys/msg.h> 59 1.1 cgd #endif 60 1.1 cgd #ifdef SYSVSEM 61 1.1 cgd #include <sys/sem.h> 62 1.1 cgd #endif 63 1.1 cgd #ifdef SYSVSHM 64 1.1 cgd #include <sys/shm.h> 65 1.1 cgd #endif 66 1.1 cgd 67 1.1 cgd #include <sys/mount.h> 68 1.1 cgd #include <sys/syscallargs.h> 69 1.1 cgd 70 1.1 cgd #include <vm/vm_kern.h> 71 1.1 cgd 72 1.1 cgd #include <dev/cons.h> 73 1.1 cgd 74 1.1 cgd #include <machine/cpu.h> 75 1.1 cgd #include <machine/reg.h> 76 1.1 cgd #include <machine/rpb.h> 77 1.1 cgd #include <machine/prom.h> 78 1.1 cgd 79 1.8 cgd #ifdef DEC_3000_500 80 1.8 cgd #include <alpha/alpha/dec_3000_500.h> 81 1.8 cgd #endif 82 1.8 cgd #ifdef DEC_3000_300 83 1.8 cgd #include <alpha/alpha/dec_3000_300.h> 84 1.8 cgd #endif 85 1.8 cgd #ifdef DEC_2100_A50 86 1.8 cgd #include <alpha/alpha/dec_2100_a50.h> 87 1.8 cgd #endif 88 1.12 cgd #ifdef DEC_KN20AA 89 1.12 cgd #include <alpha/alpha/dec_kn20aa.h> 90 1.12 cgd #endif 91 1.12 cgd #ifdef DEC_AXPPCI_33 92 1.12 cgd #include <alpha/alpha/dec_axppci_33.h> 93 1.12 cgd #endif 94 1.12 cgd #ifdef DEC_21000 95 1.12 cgd #include <alpha/alpha/dec_21000.h> 96 1.12 cgd #endif 97 1.8 cgd 98 1.33 cgd #include <net/if.h> 99 1.1 cgd #include <net/netisr.h> 100 1.33 cgd #include <netinet/in.h> 101 1.33 cgd #include <netinet/ip_var.h> 102 1.33 cgd #include <netinet/if_arp.h> 103 1.1 cgd #include "ether.h" 104 1.1 cgd 105 1.17 cgd #include "le_ioasic.h" /* for le_iomem creation */ 106 1.1 cgd 107 1.1 cgd vm_map_t buffer_map; 108 1.1 cgd 109 1.7 cgd void dumpsys __P((void)); 110 1.7 cgd 111 1.1 cgd /* 112 1.1 cgd * Declare these as initialized data so we can patch them. 113 1.1 cgd */ 114 1.1 cgd int nswbuf = 0; 115 1.1 cgd #ifdef NBUF 116 1.1 cgd int nbuf = NBUF; 117 1.1 cgd #else 118 1.1 cgd int nbuf = 0; 119 1.1 cgd #endif 120 1.1 cgd #ifdef BUFPAGES 121 1.1 cgd int bufpages = BUFPAGES; 122 1.1 cgd #else 123 1.1 cgd int bufpages = 0; 124 1.1 cgd #endif 125 1.1 cgd int msgbufmapped = 0; /* set when safe to use msgbuf */ 126 1.1 cgd int maxmem; /* max memory per process */ 127 1.7 cgd 128 1.7 cgd int totalphysmem; /* total amount of physical memory in system */ 129 1.7 cgd int physmem; /* physical memory used by NetBSD + some rsvd */ 130 1.7 cgd int firstusablepage; /* first usable memory page */ 131 1.7 cgd int lastusablepage; /* last usable memory page */ 132 1.1 cgd int resvmem; /* amount of memory reserved for PROM */ 133 1.7 cgd int unusedmem; /* amount of memory for OS that we don't use */ 134 1.7 cgd int unknownmem; /* amount of memory with an unknown use */ 135 1.1 cgd 136 1.1 cgd int cputype; /* system type, from the RPB */ 137 1.1 cgd 138 1.1 cgd /* 139 1.1 cgd * XXX We need an address to which we can assign things so that they 140 1.1 cgd * won't be optimized away because we didn't use the value. 141 1.1 cgd */ 142 1.1 cgd u_int32_t no_optimize; 143 1.1 cgd 144 1.1 cgd /* the following is used externally (sysctl_hw) */ 145 1.1 cgd char machine[] = "alpha"; 146 1.29 cgd char cpu_model[128]; 147 1.1 cgd char *model_names[] = { 148 1.2 cgd "UNKNOWN (0)", 149 1.2 cgd "Alpha Demonstration Unit", 150 1.2 cgd "DEC 4000 (\"Cobra\")", 151 1.2 cgd "DEC 7000 (\"Ruby\")", 152 1.2 cgd "DEC 3000/500 (\"Flamingo\") family", 153 1.2 cgd "UNKNOWN (5)", 154 1.2 cgd "DEC 2000/300 (\"Jensen\")", 155 1.2 cgd "DEC 3000/300 (\"Pelican\")", 156 1.2 cgd "UNKNOWN (8)", 157 1.2 cgd "DEC 2100/A500 (\"Sable\")", 158 1.2 cgd "AXPvme 64", 159 1.2 cgd "AXPpci 33 (\"NoName\")", 160 1.12 cgd "DEC 21000 (\"TurboLaser\")", 161 1.7 cgd "DEC 2100/A50 (\"Avanti\") family", 162 1.2 cgd "Mustang", 163 1.12 cgd "DEC KN20AA", 164 1.12 cgd "UNKNOWN (16)", 165 1.2 cgd "DEC 1000 (\"Mikasa\")", 166 1.1 cgd }; 167 1.1 cgd int nmodel_names = sizeof model_names/sizeof model_names[0]; 168 1.1 cgd 169 1.1 cgd struct user *proc0paddr; 170 1.1 cgd 171 1.1 cgd /* Number of machine cycles per microsecond */ 172 1.1 cgd u_int64_t cycles_per_usec; 173 1.1 cgd 174 1.1 cgd /* some memory areas for device DMA. "ick." */ 175 1.1 cgd caddr_t le_iomem; /* XXX iomem for LANCE DMA */ 176 1.1 cgd 177 1.1 cgd /* Interrupt vectors (in locore) */ 178 1.1 cgd extern int XentInt(), XentArith(), XentMM(), XentIF(), XentUna(), XentSys(); 179 1.1 cgd 180 1.7 cgd /* number of cpus in the box. really! */ 181 1.7 cgd int ncpus; 182 1.7 cgd 183 1.8 cgd /* various CPU-specific functions. */ 184 1.8 cgd char *(*cpu_modelname) __P((void)); 185 1.24 cgd void (*cpu_consinit) __P((void)); 186 1.28 cgd void (*cpu_device_register) __P((struct device *dev, void *aux)); 187 1.8 cgd char *cpu_iobus; 188 1.8 cgd 189 1.25 cgd char boot_flags[64]; 190 1.8 cgd 191 1.30 cgd /* for cpu_sysctl() */ 192 1.36 cgd char root_device[17]; 193 1.36 cgd int alpha_unaligned_print = 1; /* warn about unaligned accesses */ 194 1.36 cgd int alpha_unaligned_fix = 1; /* fix up unaligned accesses */ 195 1.36 cgd int alpha_unaligned_sigbus = 0; /* don't SIGBUS on fixed-up accesses */ 196 1.30 cgd 197 1.36 cgd void identifycpu(); 198 1.33 cgd 199 1.1 cgd int 200 1.25 cgd alpha_init(pfn, ptb) 201 1.1 cgd u_long pfn; /* first free PFN number */ 202 1.1 cgd u_long ptb; /* PFN of current level 1 page table */ 203 1.1 cgd { 204 1.2 cgd extern char _end[]; 205 1.1 cgd caddr_t start, v; 206 1.1 cgd struct mddt *mddtp; 207 1.7 cgd int i, mddtweird; 208 1.1 cgd char *p; 209 1.1 cgd 210 1.1 cgd /* 211 1.1 cgd * Turn off interrupts and floating point. 212 1.1 cgd * Make sure the instruction and data streams are consistent. 213 1.1 cgd */ 214 1.1 cgd (void)splhigh(); 215 1.32 cgd alpha_pal_wrfen(0); 216 1.37 cgd ALPHA_TBIA(); 217 1.32 cgd alpha_pal_imb(); 218 1.1 cgd 219 1.1 cgd /* 220 1.1 cgd * get address of the restart block, while we the bootstrap 221 1.1 cgd * mapping is still around. 222 1.1 cgd */ 223 1.32 cgd hwrpb = (struct rpb *)ALPHA_PHYS_TO_K0SEG( 224 1.32 cgd (vm_offset_t)(*(struct rpb **)HWRPB_ADDR)); 225 1.1 cgd 226 1.1 cgd /* 227 1.1 cgd * Remember how many cycles there are per microsecond, 228 1.7 cgd * so that we can use delay(). Round up, for safety. 229 1.1 cgd */ 230 1.7 cgd cycles_per_usec = (hwrpb->rpb_cc_freq + 999999) / 1000000; 231 1.1 cgd 232 1.1 cgd /* 233 1.1 cgd * Init the PROM interface, so we can use printf 234 1.1 cgd * until PROM mappings go away in consinit. 235 1.1 cgd */ 236 1.1 cgd init_prom_interface(); 237 1.1 cgd 238 1.1 cgd /* 239 1.1 cgd * Point interrupt/exception vectors to our own. 240 1.1 cgd */ 241 1.36 cgd alpha_pal_wrent(XentInt, ALPHA_KENTRY_INT); 242 1.36 cgd alpha_pal_wrent(XentArith, ALPHA_KENTRY_ARITH); 243 1.36 cgd alpha_pal_wrent(XentMM, ALPHA_KENTRY_MM); 244 1.36 cgd alpha_pal_wrent(XentIF, ALPHA_KENTRY_IF); 245 1.36 cgd alpha_pal_wrent(XentUna, ALPHA_KENTRY_UNA); 246 1.36 cgd alpha_pal_wrent(XentSys, ALPHA_KENTRY_SYS); 247 1.36 cgd 248 1.36 cgd /* 249 1.36 cgd * Disable System and Processor Correctable Error reporting. 250 1.36 cgd * Clear pending machine checks and error reports, etc. 251 1.36 cgd */ 252 1.40 cgd alpha_pal_wrmces(alpha_pal_rdmces() | ALPHA_MCES_DSC | ALPHA_MCES_DPC); 253 1.1 cgd 254 1.1 cgd /* 255 1.1 cgd * Find out how much memory is available, by looking at 256 1.7 cgd * the memory cluster descriptors. This also tries to do 257 1.7 cgd * its best to detect things things that have never been seen 258 1.7 cgd * before... 259 1.7 cgd * 260 1.1 cgd * XXX Assumes that the first "system" cluster is the 261 1.7 cgd * only one we can use. Is the second (etc.) system cluster 262 1.7 cgd * (if one happens to exist) guaranteed to be contiguous? or...? 263 1.1 cgd */ 264 1.1 cgd mddtp = (struct mddt *)(((caddr_t)hwrpb) + hwrpb->rpb_memdat_off); 265 1.7 cgd 266 1.7 cgd /* 267 1.7 cgd * BEGIN MDDT WEIRDNESS CHECKING 268 1.7 cgd */ 269 1.7 cgd mddtweird = 0; 270 1.7 cgd 271 1.7 cgd #define cnt mddtp->mddt_cluster_cnt 272 1.7 cgd #define usage(n) mddtp->mddt_clusters[(n)].mddt_usage 273 1.7 cgd if (cnt != 2 && cnt != 3) { 274 1.33 cgd printf("WARNING: weird number (%ld) of mem clusters\n", cnt); 275 1.7 cgd mddtweird = 1; 276 1.7 cgd } else if (usage(0) != MDDT_PALCODE || 277 1.7 cgd usage(1) != MDDT_SYSTEM || 278 1.7 cgd (cnt == 3 && usage(2) != MDDT_PALCODE)) { 279 1.7 cgd mddtweird = 1; 280 1.33 cgd printf("WARNING: %ld mem clusters, but weird config\n", cnt); 281 1.7 cgd } 282 1.7 cgd 283 1.7 cgd for (i = 0; i < cnt; i++) { 284 1.7 cgd if ((usage(i) & MDDT_mbz) != 0) { 285 1.7 cgd printf("WARNING: mem cluster %d has weird usage %lx\n", 286 1.7 cgd i, usage(i)); 287 1.7 cgd mddtweird = 1; 288 1.7 cgd } 289 1.7 cgd if (mddtp->mddt_clusters[i].mddt_pg_cnt == 0) { 290 1.7 cgd printf("WARNING: mem cluster %d has pg cnt == 0\n", i); 291 1.7 cgd mddtweird = 1; 292 1.7 cgd } 293 1.7 cgd /* XXX other things to check? */ 294 1.7 cgd } 295 1.7 cgd #undef cnt 296 1.7 cgd #undef usage 297 1.7 cgd 298 1.7 cgd if (mddtweird) { 299 1.7 cgd printf("\n"); 300 1.7 cgd printf("complete memory cluster information:\n"); 301 1.2 cgd for (i = 0; i < mddtp->mddt_cluster_cnt; i++) { 302 1.2 cgd printf("mddt %d:\n", i); 303 1.2 cgd printf("\tpfn %lx\n", 304 1.2 cgd mddtp->mddt_clusters[i].mddt_pfn); 305 1.2 cgd printf("\tcnt %lx\n", 306 1.2 cgd mddtp->mddt_clusters[i].mddt_pg_cnt); 307 1.2 cgd printf("\ttest %lx\n", 308 1.2 cgd mddtp->mddt_clusters[i].mddt_pg_test); 309 1.2 cgd printf("\tbva %lx\n", 310 1.2 cgd mddtp->mddt_clusters[i].mddt_v_bitaddr); 311 1.2 cgd printf("\tbpa %lx\n", 312 1.2 cgd mddtp->mddt_clusters[i].mddt_p_bitaddr); 313 1.2 cgd printf("\tbcksum %lx\n", 314 1.2 cgd mddtp->mddt_clusters[i].mddt_bit_cksum); 315 1.2 cgd printf("\tusage %lx\n", 316 1.2 cgd mddtp->mddt_clusters[i].mddt_usage); 317 1.2 cgd } 318 1.7 cgd printf("\n"); 319 1.2 cgd } 320 1.7 cgd /* 321 1.7 cgd * END MDDT WEIRDNESS CHECKING 322 1.7 cgd */ 323 1.2 cgd 324 1.1 cgd for (i = 0; i < mddtp->mddt_cluster_cnt; i++) { 325 1.7 cgd totalphysmem += mddtp->mddt_clusters[i].mddt_pg_cnt; 326 1.7 cgd #define usage(n) mddtp->mddt_clusters[(n)].mddt_usage 327 1.7 cgd #define pgcnt(n) mddtp->mddt_clusters[(n)].mddt_pg_cnt 328 1.7 cgd if ((usage(i) & MDDT_mbz) != 0) 329 1.7 cgd unknownmem += pgcnt(i); 330 1.7 cgd else if ((usage(i) & ~MDDT_mbz) == MDDT_PALCODE) 331 1.7 cgd resvmem += pgcnt(i); 332 1.7 cgd else if ((usage(i) & ~MDDT_mbz) == MDDT_SYSTEM) { 333 1.7 cgd /* 334 1.7 cgd * assumes that the system cluster listed is 335 1.7 cgd * one we're in... 336 1.7 cgd */ 337 1.7 cgd if (physmem != resvmem) { 338 1.7 cgd physmem += pgcnt(i); 339 1.7 cgd firstusablepage = 340 1.7 cgd mddtp->mddt_clusters[i].mddt_pfn; 341 1.7 cgd lastusablepage = firstusablepage + pgcnt(i) - 1; 342 1.7 cgd } else 343 1.7 cgd unusedmem += pgcnt(i); 344 1.7 cgd } 345 1.7 cgd #undef usage 346 1.7 cgd #undef pgcnt 347 1.1 cgd } 348 1.7 cgd if (totalphysmem == 0) 349 1.1 cgd panic("can't happen: system seems to have no memory!"); 350 1.1 cgd maxmem = physmem; 351 1.1 cgd 352 1.7 cgd #if 0 353 1.7 cgd printf("totalphysmem = %d\n", totalphysmem); 354 1.7 cgd printf("physmem = %d\n", physmem); 355 1.7 cgd printf("firstusablepage = %d\n", firstusablepage); 356 1.7 cgd printf("lastusablepage = %d\n", lastusablepage); 357 1.7 cgd printf("resvmem = %d\n", resvmem); 358 1.7 cgd printf("unusedmem = %d\n", unusedmem); 359 1.7 cgd printf("unknownmem = %d\n", unknownmem); 360 1.7 cgd #endif 361 1.7 cgd 362 1.1 cgd /* 363 1.1 cgd * find out this CPU's page size 364 1.1 cgd */ 365 1.1 cgd PAGE_SIZE = hwrpb->rpb_page_size; 366 1.12 cgd if (PAGE_SIZE != 8192) 367 1.12 cgd panic("page size %d != 8192?!", PAGE_SIZE); 368 1.1 cgd 369 1.2 cgd v = (caddr_t)alpha_round_page(_end); 370 1.1 cgd /* 371 1.1 cgd * Init mapping for u page(s) for proc 0 372 1.1 cgd */ 373 1.1 cgd start = v; 374 1.1 cgd curproc->p_addr = proc0paddr = (struct user *)v; 375 1.1 cgd v += UPAGES * NBPG; 376 1.1 cgd 377 1.1 cgd /* 378 1.1 cgd * Find out what hardware we're on, and remember its type name. 379 1.1 cgd */ 380 1.1 cgd cputype = hwrpb->rpb_type; 381 1.1 cgd switch (cputype) { 382 1.2 cgd #ifdef DEC_3000_500 /* and 400, [6-9]00 */ 383 1.1 cgd case ST_DEC_3000_500: 384 1.8 cgd cpu_modelname = dec_3000_500_modelname; 385 1.8 cgd cpu_consinit = dec_3000_500_consinit; 386 1.28 cgd cpu_device_register = dec_3000_500_device_register; 387 1.13 cgd cpu_iobus = "tcasic"; 388 1.2 cgd break; 389 1.2 cgd #endif 390 1.2 cgd 391 1.2 cgd #ifdef DEC_3000_300 392 1.2 cgd case ST_DEC_3000_300: 393 1.8 cgd cpu_modelname = dec_3000_300_modelname; 394 1.8 cgd cpu_consinit = dec_3000_300_consinit; 395 1.28 cgd cpu_device_register = dec_3000_300_device_register; 396 1.13 cgd cpu_iobus = "tcasic"; 397 1.2 cgd break; 398 1.2 cgd #endif 399 1.2 cgd 400 1.2 cgd #ifdef DEC_2100_A50 401 1.2 cgd case ST_DEC_2100_A50: 402 1.8 cgd cpu_modelname = dec_2100_a50_modelname; 403 1.8 cgd cpu_consinit = dec_2100_a50_consinit; 404 1.28 cgd cpu_device_register = dec_2100_a50_device_register; 405 1.8 cgd cpu_iobus = "apecs"; 406 1.2 cgd break; 407 1.2 cgd #endif 408 1.2 cgd 409 1.12 cgd #ifdef DEC_KN20AA 410 1.12 cgd case ST_DEC_KN20AA: 411 1.12 cgd cpu_modelname = dec_kn20aa_modelname; 412 1.12 cgd cpu_consinit = dec_kn20aa_consinit; 413 1.28 cgd cpu_device_register = dec_kn20aa_device_register; 414 1.12 cgd cpu_iobus = "cia"; 415 1.12 cgd break; 416 1.12 cgd #endif 417 1.12 cgd 418 1.12 cgd #ifdef DEC_AXPPCI_33 419 1.12 cgd case ST_DEC_AXPPCI_33: 420 1.12 cgd cpu_modelname = dec_axppci_33_modelname; 421 1.12 cgd cpu_consinit = dec_axppci_33_consinit; 422 1.28 cgd cpu_device_register = dec_axppci_33_device_register; 423 1.12 cgd cpu_iobus = "lca"; 424 1.12 cgd break; 425 1.12 cgd #endif 426 1.12 cgd 427 1.8 cgd #ifdef DEC_2000_300 428 1.8 cgd case ST_DEC_2000_300: 429 1.8 cgd cpu_modelname = dec_2000_300_modelname; 430 1.8 cgd cpu_consinit = dec_2000_300_consinit; 431 1.28 cgd cpu_device_register = dec_2000_300_device_register; 432 1.8 cgd cpu_iobus = "ibus"; 433 1.8 cgd XXX DEC 2000/300 NOT SUPPORTED 434 1.12 cgd break; 435 1.2 cgd #endif 436 1.2 cgd 437 1.12 cgd #ifdef DEC_21000 438 1.12 cgd case ST_DEC_21000: 439 1.12 cgd cpu_modelname = dec_21000_modelname; 440 1.12 cgd cpu_consinit = dec_21000_consinit; 441 1.28 cgd cpu_device_register = dec_21000_device_register; 442 1.12 cgd cpu_iobus = "tlsb"; 443 1.27 cgd XXX DEC 21000 NOT SUPPORTED 444 1.12 cgd break; 445 1.2 cgd #endif 446 1.2 cgd 447 1.1 cgd default: 448 1.1 cgd if (cputype > nmodel_names) 449 1.1 cgd panic("Unknown system type %d", cputype); 450 1.1 cgd else 451 1.1 cgd panic("Support for %s system type not in kernel.", 452 1.1 cgd model_names[cputype]); 453 1.1 cgd } 454 1.8 cgd 455 1.29 cgd if ((*cpu_modelname)() != NULL) 456 1.29 cgd strncpy(cpu_model, (*cpu_modelname)(), sizeof cpu_model - 1); 457 1.29 cgd else 458 1.29 cgd strncpy(cpu_model, model_names[cputype], sizeof cpu_model - 1); 459 1.29 cgd cpu_model[sizeof cpu_model - 1] = '\0'; 460 1.1 cgd 461 1.17 cgd #if NLE_IOASIC > 0 462 1.1 cgd /* 463 1.1 cgd * Grab 128K at the top of physical memory for the lance chip 464 1.1 cgd * on machines where it does dma through the I/O ASIC. 465 1.1 cgd * It must be physically contiguous and aligned on a 128K boundary. 466 1.17 cgd * 467 1.17 cgd * Note that since this is conditional on the presence of 468 1.17 cgd * IOASIC-attached 'le' units in the kernel config, the 469 1.17 cgd * message buffer may move on these systems. This shouldn't 470 1.17 cgd * be a problem, because once people have a kernel config that 471 1.17 cgd * they use, they're going to stick with it. 472 1.1 cgd */ 473 1.1 cgd if (cputype == ST_DEC_3000_500 || 474 1.1 cgd cputype == ST_DEC_3000_300) { /* XXX possibly others? */ 475 1.7 cgd lastusablepage -= btoc(128 * 1024); 476 1.32 cgd le_iomem = 477 1.32 cgd (caddr_t)ALPHA_PHYS_TO_K0SEG(ctob(lastusablepage + 1)); 478 1.1 cgd } 479 1.17 cgd #endif /* NLE_IOASIC */ 480 1.1 cgd 481 1.1 cgd /* 482 1.1 cgd * Initialize error message buffer (at end of core). 483 1.1 cgd */ 484 1.7 cgd lastusablepage -= btoc(sizeof (struct msgbuf)); 485 1.32 cgd msgbufp = 486 1.32 cgd (struct msgbuf *)ALPHA_PHYS_TO_K0SEG(ctob(lastusablepage + 1)); 487 1.1 cgd msgbufmapped = 1; 488 1.1 cgd 489 1.1 cgd /* 490 1.1 cgd * Allocate space for system data structures. 491 1.1 cgd * The first available kernel virtual address is in "v". 492 1.1 cgd * As pages of kernel virtual memory are allocated, "v" is incremented. 493 1.1 cgd * 494 1.1 cgd * These data structures are allocated here instead of cpu_startup() 495 1.1 cgd * because physical memory is directly addressable. We don't have 496 1.1 cgd * to map these into virtual address space. 497 1.1 cgd */ 498 1.1 cgd #define valloc(name, type, num) \ 499 1.12 cgd (name) = (type *)v; v = (caddr_t)ALIGN((name)+(num)) 500 1.1 cgd #define valloclim(name, type, num, lim) \ 501 1.12 cgd (name) = (type *)v; v = (caddr_t)ALIGN((lim) = ((name)+(num))) 502 1.1 cgd #ifdef REAL_CLISTS 503 1.1 cgd valloc(cfree, struct cblock, nclist); 504 1.1 cgd #endif 505 1.1 cgd valloc(callout, struct callout, ncallout); 506 1.1 cgd valloc(swapmap, struct map, nswapmap = maxproc * 2); 507 1.1 cgd #ifdef SYSVSHM 508 1.1 cgd valloc(shmsegs, struct shmid_ds, shminfo.shmmni); 509 1.1 cgd #endif 510 1.1 cgd #ifdef SYSVSEM 511 1.1 cgd valloc(sema, struct semid_ds, seminfo.semmni); 512 1.1 cgd valloc(sem, struct sem, seminfo.semmns); 513 1.1 cgd /* This is pretty disgusting! */ 514 1.1 cgd valloc(semu, int, (seminfo.semmnu * seminfo.semusz) / sizeof(int)); 515 1.1 cgd #endif 516 1.1 cgd #ifdef SYSVMSG 517 1.1 cgd valloc(msgpool, char, msginfo.msgmax); 518 1.1 cgd valloc(msgmaps, struct msgmap, msginfo.msgseg); 519 1.1 cgd valloc(msghdrs, struct msg, msginfo.msgtql); 520 1.1 cgd valloc(msqids, struct msqid_ds, msginfo.msgmni); 521 1.1 cgd #endif 522 1.1 cgd 523 1.1 cgd /* 524 1.1 cgd * Determine how many buffers to allocate. 525 1.31 cgd * We allocate 10% of memory for buffer space. Insure a 526 1.1 cgd * minimum of 16 buffers. We allocate 1/2 as many swap buffer 527 1.1 cgd * headers as file i/o buffers. 528 1.1 cgd */ 529 1.1 cgd if (bufpages == 0) 530 1.31 cgd bufpages = (physmem * 10) / (CLSIZE * 100); 531 1.1 cgd if (nbuf == 0) { 532 1.1 cgd nbuf = bufpages; 533 1.1 cgd if (nbuf < 16) 534 1.1 cgd nbuf = 16; 535 1.1 cgd } 536 1.1 cgd if (nswbuf == 0) { 537 1.1 cgd nswbuf = (nbuf / 2) &~ 1; /* force even */ 538 1.1 cgd if (nswbuf > 256) 539 1.1 cgd nswbuf = 256; /* sanity */ 540 1.1 cgd } 541 1.1 cgd valloc(swbuf, struct buf, nswbuf); 542 1.1 cgd valloc(buf, struct buf, nbuf); 543 1.1 cgd 544 1.1 cgd /* 545 1.1 cgd * Clear allocated memory. 546 1.1 cgd */ 547 1.1 cgd bzero(start, v - start); 548 1.1 cgd 549 1.1 cgd /* 550 1.1 cgd * Initialize the virtual memory system, and set the 551 1.1 cgd * page table base register in proc 0's PCB. 552 1.1 cgd */ 553 1.40 cgd #ifndef NEW_PMAP 554 1.32 cgd pmap_bootstrap((vm_offset_t)v, ALPHA_PHYS_TO_K0SEG(ptb << PGSHIFT)); 555 1.40 cgd #else 556 1.40 cgd pmap_bootstrap((vm_offset_t)v, ALPHA_PHYS_TO_K0SEG(ptb << PGSHIFT), 557 1.40 cgd hwrpb->rpb_max_asn); 558 1.40 cgd #endif 559 1.1 cgd 560 1.1 cgd /* 561 1.3 cgd * Initialize the rest of proc 0's PCB, and cache its physical 562 1.3 cgd * address. 563 1.3 cgd */ 564 1.3 cgd proc0.p_md.md_pcbpaddr = 565 1.32 cgd (struct pcb *)ALPHA_K0SEG_TO_PHYS((vm_offset_t)&proc0paddr->u_pcb); 566 1.3 cgd 567 1.3 cgd /* 568 1.3 cgd * Set the kernel sp, reserving space for an (empty) trapframe, 569 1.3 cgd * and make proc0's trapframe pointer point to it for sanity. 570 1.3 cgd */ 571 1.33 cgd proc0paddr->u_pcb.pcb_hw.apcb_ksp = 572 1.3 cgd (u_int64_t)proc0paddr + USPACE - sizeof(struct trapframe); 573 1.33 cgd proc0.p_md.md_tf = (struct trapframe *)proc0paddr->u_pcb.pcb_hw.apcb_ksp; 574 1.38 cgd 575 1.40 cgd #ifdef NEW_PMAP 576 1.40 cgd pmap_activate(kernel_pmap, &proc0paddr->u_pcb.pcb_hw, 0); 577 1.38 cgd #endif 578 1.1 cgd 579 1.1 cgd /* 580 1.25 cgd * Look at arguments passed to us and compute boothowto. 581 1.8 cgd */ 582 1.25 cgd prom_getenv(PROM_E_BOOTED_OSFLAGS, boot_flags, sizeof(boot_flags)); 583 1.25 cgd #if 0 584 1.25 cgd printf("boot flags = \"%s\"\n", boot_flags); 585 1.25 cgd #endif 586 1.1 cgd 587 1.8 cgd boothowto = RB_SINGLE; 588 1.1 cgd #ifdef KADB 589 1.1 cgd boothowto |= RB_KDB; 590 1.1 cgd #endif 591 1.8 cgd for (p = boot_flags; p && *p != '\0'; p++) { 592 1.26 cgd /* 593 1.26 cgd * Note that we'd really like to differentiate case here, 594 1.26 cgd * but the Alpha AXP Architecture Reference Manual 595 1.26 cgd * says that we shouldn't. 596 1.26 cgd */ 597 1.8 cgd switch (*p) { 598 1.26 cgd case 'a': /* autoboot */ 599 1.26 cgd case 'A': 600 1.26 cgd boothowto &= ~RB_SINGLE; 601 1.21 cgd break; 602 1.21 cgd 603 1.43 cgd #ifdef DEBUG 604 1.43 cgd case 'c': /* crash dump immediately after autoconfig */ 605 1.43 cgd case 'C': 606 1.43 cgd boothowto |= RB_DUMP; 607 1.43 cgd break; 608 1.43 cgd #endif 609 1.43 cgd 610 1.36 cgd case 'h': /* always halt, never reboot */ 611 1.36 cgd case 'H': 612 1.36 cgd boothowto |= RB_HALT; 613 1.8 cgd break; 614 1.8 cgd 615 1.21 cgd #if 0 616 1.8 cgd case 'm': /* mini root present in memory */ 617 1.26 cgd case 'M': 618 1.8 cgd boothowto |= RB_MINIROOT; 619 1.8 cgd break; 620 1.21 cgd #endif 621 1.36 cgd 622 1.36 cgd case 'n': /* askname */ 623 1.36 cgd case 'N': 624 1.36 cgd boothowto |= RB_ASKNAME; 625 1.36 cgd break; 626 1.1 cgd } 627 1.1 cgd } 628 1.1 cgd 629 1.7 cgd /* 630 1.7 cgd * Figure out the number of cpus in the box, from RPB fields. 631 1.7 cgd * Really. We mean it. 632 1.7 cgd */ 633 1.7 cgd for (i = 0; i < hwrpb->rpb_pcs_cnt; i++) { 634 1.7 cgd struct pcs *pcsp; 635 1.7 cgd 636 1.7 cgd pcsp = (struct pcs *)((char *)hwrpb + hwrpb->rpb_pcs_off + 637 1.7 cgd (i * hwrpb->rpb_pcs_size)); 638 1.7 cgd if ((pcsp->pcs_flags & PCS_PP) != 0) 639 1.7 cgd ncpus++; 640 1.7 cgd } 641 1.7 cgd 642 1.1 cgd return (0); 643 1.1 cgd } 644 1.1 cgd 645 1.18 cgd void 646 1.1 cgd consinit() 647 1.1 cgd { 648 1.1 cgd 649 1.24 cgd (*cpu_consinit)(); 650 1.1 cgd pmap_unmap_prom(); 651 1.1 cgd } 652 1.1 cgd 653 1.18 cgd void 654 1.1 cgd cpu_startup() 655 1.1 cgd { 656 1.1 cgd register unsigned i; 657 1.1 cgd int base, residual; 658 1.1 cgd vm_offset_t minaddr, maxaddr; 659 1.1 cgd vm_size_t size; 660 1.40 cgd #if defined(DEBUG) 661 1.1 cgd extern int pmapdebug; 662 1.1 cgd int opmapdebug = pmapdebug; 663 1.1 cgd 664 1.1 cgd pmapdebug = 0; 665 1.1 cgd #endif 666 1.1 cgd 667 1.1 cgd /* 668 1.1 cgd * Good {morning,afternoon,evening,night}. 669 1.1 cgd */ 670 1.1 cgd printf(version); 671 1.1 cgd identifycpu(); 672 1.7 cgd printf("real mem = %d (%d reserved for PROM, %d used by NetBSD)\n", 673 1.7 cgd ctob(totalphysmem), ctob(resvmem), ctob(physmem)); 674 1.7 cgd if (unusedmem) 675 1.7 cgd printf("WARNING: unused memory = %d bytes\n", ctob(unusedmem)); 676 1.7 cgd if (unknownmem) 677 1.7 cgd printf("WARNING: %d bytes of memory with unknown purpose\n", 678 1.7 cgd ctob(unknownmem)); 679 1.1 cgd 680 1.1 cgd /* 681 1.1 cgd * Allocate virtual address space for file I/O buffers. 682 1.1 cgd * Note they are different than the array of headers, 'buf', 683 1.1 cgd * and usually occupy more virtual memory than physical. 684 1.1 cgd */ 685 1.1 cgd size = MAXBSIZE * nbuf; 686 1.1 cgd buffer_map = kmem_suballoc(kernel_map, (vm_offset_t *)&buffers, 687 1.1 cgd &maxaddr, size, TRUE); 688 1.1 cgd minaddr = (vm_offset_t)buffers; 689 1.1 cgd if (vm_map_find(buffer_map, vm_object_allocate(size), (vm_offset_t)0, 690 1.1 cgd &minaddr, size, FALSE) != KERN_SUCCESS) 691 1.1 cgd panic("startup: cannot allocate buffers"); 692 1.1 cgd base = bufpages / nbuf; 693 1.1 cgd residual = bufpages % nbuf; 694 1.1 cgd for (i = 0; i < nbuf; i++) { 695 1.1 cgd vm_size_t curbufsize; 696 1.1 cgd vm_offset_t curbuf; 697 1.1 cgd 698 1.1 cgd /* 699 1.1 cgd * First <residual> buffers get (base+1) physical pages 700 1.1 cgd * allocated for them. The rest get (base) physical pages. 701 1.1 cgd * 702 1.1 cgd * The rest of each buffer occupies virtual space, 703 1.1 cgd * but has no physical memory allocated for it. 704 1.1 cgd */ 705 1.1 cgd curbuf = (vm_offset_t)buffers + i * MAXBSIZE; 706 1.1 cgd curbufsize = CLBYTES * (i < residual ? base+1 : base); 707 1.1 cgd vm_map_pageable(buffer_map, curbuf, curbuf+curbufsize, FALSE); 708 1.1 cgd vm_map_simplify(buffer_map, curbuf); 709 1.1 cgd } 710 1.1 cgd /* 711 1.1 cgd * Allocate a submap for exec arguments. This map effectively 712 1.1 cgd * limits the number of processes exec'ing at any time. 713 1.1 cgd */ 714 1.1 cgd exec_map = kmem_suballoc(kernel_map, &minaddr, &maxaddr, 715 1.1 cgd 16 * NCARGS, TRUE); 716 1.1 cgd 717 1.1 cgd /* 718 1.1 cgd * Allocate a submap for physio 719 1.1 cgd */ 720 1.1 cgd phys_map = kmem_suballoc(kernel_map, &minaddr, &maxaddr, 721 1.1 cgd VM_PHYS_SIZE, TRUE); 722 1.1 cgd 723 1.1 cgd /* 724 1.1 cgd * Finally, allocate mbuf pool. Since mclrefcnt is an off-size 725 1.1 cgd * we use the more space efficient malloc in place of kmem_alloc. 726 1.1 cgd */ 727 1.1 cgd mclrefcnt = (char *)malloc(NMBCLUSTERS+CLBYTES/MCLBYTES, 728 1.1 cgd M_MBUF, M_NOWAIT); 729 1.1 cgd bzero(mclrefcnt, NMBCLUSTERS+CLBYTES/MCLBYTES); 730 1.1 cgd mb_map = kmem_suballoc(kernel_map, (vm_offset_t *)&mbutl, &maxaddr, 731 1.1 cgd VM_MBUF_SIZE, FALSE); 732 1.1 cgd /* 733 1.1 cgd * Initialize callouts 734 1.1 cgd */ 735 1.1 cgd callfree = callout; 736 1.1 cgd for (i = 1; i < ncallout; i++) 737 1.1 cgd callout[i-1].c_next = &callout[i]; 738 1.1 cgd callout[i-1].c_next = NULL; 739 1.1 cgd 740 1.40 cgd #if defined(DEBUG) 741 1.1 cgd pmapdebug = opmapdebug; 742 1.1 cgd #endif 743 1.1 cgd printf("avail mem = %ld\n", (long)ptoa(cnt.v_free_count)); 744 1.1 cgd printf("using %ld buffers containing %ld bytes of memory\n", 745 1.1 cgd (long)nbuf, (long)(bufpages * CLBYTES)); 746 1.1 cgd 747 1.1 cgd /* 748 1.1 cgd * Set up buffers, so they can be used to read disk labels. 749 1.1 cgd */ 750 1.1 cgd bufinit(); 751 1.1 cgd 752 1.1 cgd /* 753 1.1 cgd * Configure the system. 754 1.1 cgd */ 755 1.1 cgd configure(); 756 1.1 cgd } 757 1.1 cgd 758 1.33 cgd void 759 1.1 cgd identifycpu() 760 1.1 cgd { 761 1.1 cgd 762 1.7 cgd /* 763 1.7 cgd * print out CPU identification information. 764 1.7 cgd */ 765 1.33 cgd printf("%s, %ldMHz\n", cpu_model, 766 1.7 cgd hwrpb->rpb_cc_freq / 1000000); /* XXX true for 21164? */ 767 1.33 cgd printf("%ld byte page size, %d processor%s.\n", 768 1.7 cgd hwrpb->rpb_page_size, ncpus, ncpus == 1 ? "" : "s"); 769 1.7 cgd #if 0 770 1.7 cgd /* this isn't defined for any systems that we run on? */ 771 1.7 cgd printf("serial number 0x%lx 0x%lx\n", 772 1.1 cgd ((long *)hwrpb->rpb_ssn)[0], ((long *)hwrpb->rpb_ssn)[1]); 773 1.7 cgd 774 1.7 cgd /* and these aren't particularly useful! */ 775 1.1 cgd printf("variation: 0x%lx, revision 0x%lx\n", 776 1.1 cgd hwrpb->rpb_variation, *(long *)hwrpb->rpb_revision); 777 1.7 cgd #endif 778 1.1 cgd } 779 1.1 cgd 780 1.1 cgd int waittime = -1; 781 1.7 cgd struct pcb dumppcb; 782 1.1 cgd 783 1.18 cgd void 784 1.39 mrg boot(howto, bootstr) 785 1.1 cgd int howto; 786 1.39 mrg char *bootstr; 787 1.1 cgd { 788 1.1 cgd extern int cold; 789 1.1 cgd 790 1.1 cgd /* If system is cold, just halt. */ 791 1.1 cgd if (cold) { 792 1.1 cgd howto |= RB_HALT; 793 1.1 cgd goto haltsys; 794 1.1 cgd } 795 1.1 cgd 796 1.36 cgd /* If "always halt" was specified as a boot flag, obey. */ 797 1.36 cgd if ((boothowto & RB_HALT) != 0) 798 1.36 cgd howto |= RB_HALT; 799 1.36 cgd 800 1.7 cgd boothowto = howto; 801 1.7 cgd if ((howto & RB_NOSYNC) == 0 && waittime < 0) { 802 1.1 cgd waittime = 0; 803 1.7 cgd vfs_shutdown(); 804 1.1 cgd /* 805 1.1 cgd * If we've been adjusting the clock, the todr 806 1.1 cgd * will be out of synch; adjust it now. 807 1.1 cgd */ 808 1.1 cgd resettodr(); 809 1.1 cgd } 810 1.1 cgd 811 1.1 cgd /* Disable interrupts. */ 812 1.1 cgd splhigh(); 813 1.1 cgd 814 1.7 cgd /* If rebooting and a dump is requested do it. */ 815 1.42 cgd #if 0 816 1.42 cgd if ((howto & (RB_DUMP | RB_HALT)) == RB_DUMP) 817 1.42 cgd #else 818 1.42 cgd if (howto & RB_DUMP) 819 1.42 cgd #endif 820 1.1 cgd dumpsys(); 821 1.6 cgd 822 1.12 cgd haltsys: 823 1.12 cgd 824 1.6 cgd /* run any shutdown hooks */ 825 1.6 cgd doshutdownhooks(); 826 1.1 cgd 827 1.7 cgd #ifdef BOOTKEY 828 1.7 cgd printf("hit any key to %s...\n", howto & RB_HALT ? "halt" : "reboot"); 829 1.7 cgd cngetc(); 830 1.7 cgd printf("\n"); 831 1.7 cgd #endif 832 1.7 cgd 833 1.1 cgd /* Finally, halt/reboot the system. */ 834 1.1 cgd printf("%s\n\n", howto & RB_HALT ? "halted." : "rebooting..."); 835 1.1 cgd prom_halt(howto & RB_HALT); 836 1.1 cgd /*NOTREACHED*/ 837 1.1 cgd } 838 1.1 cgd 839 1.7 cgd /* 840 1.7 cgd * These variables are needed by /sbin/savecore 841 1.7 cgd */ 842 1.7 cgd u_long dumpmag = 0x8fca0101; /* magic number */ 843 1.7 cgd int dumpsize = 0; /* pages */ 844 1.7 cgd long dumplo = 0; /* blocks */ 845 1.7 cgd 846 1.7 cgd /* 847 1.43 cgd * cpu_dumpsize: calculate size of machine-dependent kernel core dump headers. 848 1.43 cgd */ 849 1.43 cgd int 850 1.43 cgd cpu_dumpsize() 851 1.43 cgd { 852 1.43 cgd int size; 853 1.43 cgd 854 1.43 cgd size = ALIGN(sizeof(kcore_seg_t)) + ALIGN(sizeof(cpu_kcore_hdr_t)); 855 1.43 cgd if (roundup(size, dbtob(1)) != dbtob(1)) 856 1.43 cgd return -1; 857 1.43 cgd 858 1.43 cgd return (1); 859 1.43 cgd } 860 1.43 cgd 861 1.43 cgd /* 862 1.43 cgd * cpu_dump: dump machine-dependent kernel core dump headers. 863 1.43 cgd */ 864 1.43 cgd int 865 1.43 cgd cpu_dump() 866 1.43 cgd { 867 1.43 cgd int (*dump) __P((dev_t, daddr_t, caddr_t, size_t)); 868 1.43 cgd long buf[dbtob(1) / sizeof (long)]; 869 1.43 cgd kcore_seg_t *segp; 870 1.43 cgd cpu_kcore_hdr_t *cpuhdrp; 871 1.43 cgd 872 1.43 cgd dump = bdevsw[major(dumpdev)].d_dump; 873 1.43 cgd 874 1.43 cgd segp = (kcore_seg_t *)buf; 875 1.43 cgd cpuhdrp = 876 1.43 cgd (cpu_kcore_hdr_t *)&buf[ALIGN(sizeof(*segp)) / sizeof (long)]; 877 1.43 cgd 878 1.43 cgd /* 879 1.43 cgd * Generate a segment header. 880 1.43 cgd */ 881 1.43 cgd CORE_SETMAGIC(*segp, KCORE_MAGIC, MID_MACHINE, CORE_CPU); 882 1.43 cgd segp->c_size = dbtob(1) - ALIGN(sizeof(*segp)); 883 1.43 cgd 884 1.43 cgd /* 885 1.43 cgd * Add the machine-dependent header info 886 1.43 cgd */ 887 1.43 cgd cpuhdrp->lev1map_pa = (u_int64_t)Lev1map; 888 1.43 cgd cpuhdrp->page_size = PAGE_SIZE; 889 1.43 cgd cpuhdrp->core_seg.start = ctob(firstusablepage); 890 1.43 cgd cpuhdrp->core_seg.size = ctob(physmem); 891 1.43 cgd 892 1.43 cgd return (dump(dumpdev, dumplo, (caddr_t)buf, dbtob(1))); 893 1.43 cgd } 894 1.43 cgd 895 1.43 cgd /* 896 1.7 cgd * This is called by configure to set dumplo and dumpsize. 897 1.7 cgd * Dumps always skip the first CLBYTES of disk space 898 1.7 cgd * in case there might be a disk label stored there. 899 1.7 cgd * If there is extra space, put dump at the end to 900 1.7 cgd * reduce the chance that swapping trashes it. 901 1.7 cgd */ 902 1.7 cgd void 903 1.7 cgd dumpconf() 904 1.7 cgd { 905 1.43 cgd int nblks, dumpblks; /* size of dump area */ 906 1.7 cgd int maj; 907 1.7 cgd 908 1.7 cgd if (dumpdev == NODEV) 909 1.43 cgd goto bad; 910 1.7 cgd maj = major(dumpdev); 911 1.7 cgd if (maj < 0 || maj >= nblkdev) 912 1.7 cgd panic("dumpconf: bad dumpdev=0x%x", dumpdev); 913 1.7 cgd if (bdevsw[maj].d_psize == NULL) 914 1.43 cgd goto bad; 915 1.7 cgd nblks = (*bdevsw[maj].d_psize)(dumpdev); 916 1.7 cgd if (nblks <= ctod(1)) 917 1.43 cgd goto bad; 918 1.43 cgd 919 1.43 cgd dumpblks = cpu_dumpsize(); 920 1.43 cgd if (dumpblks < 0) 921 1.43 cgd goto bad; 922 1.43 cgd dumpblks += ctod(physmem); 923 1.43 cgd 924 1.43 cgd /* If dump won't fit (incl. room for possible label), punt. */ 925 1.43 cgd if (dumpblks > (nblks - ctod(1))) 926 1.43 cgd goto bad; 927 1.43 cgd 928 1.43 cgd /* Put dump at end of partition */ 929 1.43 cgd dumplo = nblks - dumpblks; 930 1.7 cgd 931 1.43 cgd /* dumpsize is in page units, and doesn't include headers. */ 932 1.7 cgd dumpsize = physmem; 933 1.43 cgd return; 934 1.7 cgd 935 1.43 cgd bad: 936 1.43 cgd dumpsize = 0; 937 1.43 cgd dumplo = -1; 938 1.43 cgd return; 939 1.7 cgd } 940 1.7 cgd 941 1.7 cgd /* 942 1.42 cgd * Dump the kernel's image to the swap partition. 943 1.7 cgd */ 944 1.42 cgd #define BYTES_PER_DUMP NBPG 945 1.42 cgd 946 1.7 cgd void 947 1.7 cgd dumpsys() 948 1.7 cgd { 949 1.42 cgd unsigned bytes, i, n; 950 1.42 cgd int maddr, psize; 951 1.42 cgd daddr_t blkno; 952 1.42 cgd int (*dump) __P((dev_t, daddr_t, caddr_t, size_t)); 953 1.42 cgd int error; 954 1.42 cgd 955 1.42 cgd /* Save registers. */ 956 1.42 cgd savectx(&dumppcb); 957 1.7 cgd 958 1.42 cgd msgbufmapped = 0; /* don't record dump msgs in msgbuf */ 959 1.7 cgd if (dumpdev == NODEV) 960 1.7 cgd return; 961 1.42 cgd 962 1.42 cgd /* 963 1.42 cgd * For dumps during autoconfiguration, 964 1.42 cgd * if dump device has already configured... 965 1.42 cgd */ 966 1.42 cgd if (dumpsize == 0) 967 1.7 cgd dumpconf(); 968 1.43 cgd if (dumplo < 0) { 969 1.43 cgd printf("\ndump to dev %x not possible\n", dumpdev); 970 1.42 cgd return; 971 1.43 cgd } 972 1.33 cgd printf("\ndumping to dev %x, offset %ld\n", dumpdev, dumplo); 973 1.7 cgd 974 1.42 cgd psize = (*bdevsw[major(dumpdev)].d_psize)(dumpdev); 975 1.7 cgd printf("dump "); 976 1.42 cgd if (psize == -1) { 977 1.42 cgd printf("area unavailable\n"); 978 1.42 cgd return; 979 1.42 cgd } 980 1.42 cgd 981 1.42 cgd /* XXX should purge all outstanding keystrokes. */ 982 1.42 cgd 983 1.43 cgd if ((error = cpu_dump()) != 0) 984 1.43 cgd goto err; 985 1.43 cgd 986 1.43 cgd bytes = ctob(physmem); 987 1.42 cgd maddr = ctob(firstusablepage); 988 1.43 cgd blkno = dumplo + cpu_dumpsize(); 989 1.42 cgd dump = bdevsw[major(dumpdev)].d_dump; 990 1.42 cgd error = 0; 991 1.42 cgd for (i = 0; i < bytes; i += n) { 992 1.42 cgd 993 1.42 cgd /* Print out how many MBs we to go. */ 994 1.42 cgd n = bytes - i; 995 1.42 cgd if (n && (n % (1024*1024)) == 0) 996 1.42 cgd printf("%d ", n / (1024 * 1024)); 997 1.42 cgd 998 1.42 cgd /* Limit size for next transfer. */ 999 1.42 cgd if (n > BYTES_PER_DUMP) 1000 1.42 cgd n = BYTES_PER_DUMP; 1001 1.42 cgd 1002 1.42 cgd error = (*dump)(dumpdev, blkno, 1003 1.42 cgd (caddr_t)ALPHA_PHYS_TO_K0SEG(maddr), n); 1004 1.42 cgd if (error) 1005 1.42 cgd break; 1006 1.42 cgd maddr += n; 1007 1.42 cgd blkno += btodb(n); /* XXX? */ 1008 1.42 cgd 1009 1.42 cgd /* XXX should look for keystrokes, to cancel. */ 1010 1.42 cgd } 1011 1.42 cgd 1012 1.43 cgd err: 1013 1.42 cgd switch (error) { 1014 1.7 cgd 1015 1.7 cgd case ENXIO: 1016 1.7 cgd printf("device bad\n"); 1017 1.7 cgd break; 1018 1.7 cgd 1019 1.7 cgd case EFAULT: 1020 1.7 cgd printf("device not ready\n"); 1021 1.7 cgd break; 1022 1.7 cgd 1023 1.7 cgd case EINVAL: 1024 1.7 cgd printf("area improper\n"); 1025 1.7 cgd break; 1026 1.7 cgd 1027 1.7 cgd case EIO: 1028 1.7 cgd printf("i/o error\n"); 1029 1.7 cgd break; 1030 1.7 cgd 1031 1.7 cgd case EINTR: 1032 1.7 cgd printf("aborted from console\n"); 1033 1.7 cgd break; 1034 1.7 cgd 1035 1.42 cgd case 0: 1036 1.42 cgd printf("succeeded\n"); 1037 1.42 cgd break; 1038 1.42 cgd 1039 1.7 cgd default: 1040 1.42 cgd printf("error %d\n", error); 1041 1.7 cgd break; 1042 1.7 cgd } 1043 1.7 cgd printf("\n\n"); 1044 1.7 cgd delay(1000); 1045 1.7 cgd } 1046 1.7 cgd 1047 1.1 cgd void 1048 1.1 cgd frametoreg(framep, regp) 1049 1.1 cgd struct trapframe *framep; 1050 1.1 cgd struct reg *regp; 1051 1.1 cgd { 1052 1.1 cgd 1053 1.1 cgd regp->r_regs[R_V0] = framep->tf_regs[FRAME_V0]; 1054 1.1 cgd regp->r_regs[R_T0] = framep->tf_regs[FRAME_T0]; 1055 1.1 cgd regp->r_regs[R_T1] = framep->tf_regs[FRAME_T1]; 1056 1.1 cgd regp->r_regs[R_T2] = framep->tf_regs[FRAME_T2]; 1057 1.1 cgd regp->r_regs[R_T3] = framep->tf_regs[FRAME_T3]; 1058 1.1 cgd regp->r_regs[R_T4] = framep->tf_regs[FRAME_T4]; 1059 1.1 cgd regp->r_regs[R_T5] = framep->tf_regs[FRAME_T5]; 1060 1.1 cgd regp->r_regs[R_T6] = framep->tf_regs[FRAME_T6]; 1061 1.1 cgd regp->r_regs[R_T7] = framep->tf_regs[FRAME_T7]; 1062 1.1 cgd regp->r_regs[R_S0] = framep->tf_regs[FRAME_S0]; 1063 1.1 cgd regp->r_regs[R_S1] = framep->tf_regs[FRAME_S1]; 1064 1.1 cgd regp->r_regs[R_S2] = framep->tf_regs[FRAME_S2]; 1065 1.1 cgd regp->r_regs[R_S3] = framep->tf_regs[FRAME_S3]; 1066 1.1 cgd regp->r_regs[R_S4] = framep->tf_regs[FRAME_S4]; 1067 1.1 cgd regp->r_regs[R_S5] = framep->tf_regs[FRAME_S5]; 1068 1.1 cgd regp->r_regs[R_S6] = framep->tf_regs[FRAME_S6]; 1069 1.34 cgd regp->r_regs[R_A0] = framep->tf_regs[FRAME_A0]; 1070 1.34 cgd regp->r_regs[R_A1] = framep->tf_regs[FRAME_A1]; 1071 1.34 cgd regp->r_regs[R_A2] = framep->tf_regs[FRAME_A2]; 1072 1.1 cgd regp->r_regs[R_A3] = framep->tf_regs[FRAME_A3]; 1073 1.1 cgd regp->r_regs[R_A4] = framep->tf_regs[FRAME_A4]; 1074 1.1 cgd regp->r_regs[R_A5] = framep->tf_regs[FRAME_A5]; 1075 1.1 cgd regp->r_regs[R_T8] = framep->tf_regs[FRAME_T8]; 1076 1.1 cgd regp->r_regs[R_T9] = framep->tf_regs[FRAME_T9]; 1077 1.1 cgd regp->r_regs[R_T10] = framep->tf_regs[FRAME_T10]; 1078 1.1 cgd regp->r_regs[R_T11] = framep->tf_regs[FRAME_T11]; 1079 1.1 cgd regp->r_regs[R_RA] = framep->tf_regs[FRAME_RA]; 1080 1.1 cgd regp->r_regs[R_T12] = framep->tf_regs[FRAME_T12]; 1081 1.1 cgd regp->r_regs[R_AT] = framep->tf_regs[FRAME_AT]; 1082 1.34 cgd regp->r_regs[R_GP] = framep->tf_regs[FRAME_GP]; 1083 1.35 cgd /* regp->r_regs[R_SP] = framep->tf_regs[FRAME_SP]; XXX */ 1084 1.1 cgd regp->r_regs[R_ZERO] = 0; 1085 1.1 cgd } 1086 1.1 cgd 1087 1.1 cgd void 1088 1.1 cgd regtoframe(regp, framep) 1089 1.1 cgd struct reg *regp; 1090 1.1 cgd struct trapframe *framep; 1091 1.1 cgd { 1092 1.1 cgd 1093 1.1 cgd framep->tf_regs[FRAME_V0] = regp->r_regs[R_V0]; 1094 1.1 cgd framep->tf_regs[FRAME_T0] = regp->r_regs[R_T0]; 1095 1.1 cgd framep->tf_regs[FRAME_T1] = regp->r_regs[R_T1]; 1096 1.1 cgd framep->tf_regs[FRAME_T2] = regp->r_regs[R_T2]; 1097 1.1 cgd framep->tf_regs[FRAME_T3] = regp->r_regs[R_T3]; 1098 1.1 cgd framep->tf_regs[FRAME_T4] = regp->r_regs[R_T4]; 1099 1.1 cgd framep->tf_regs[FRAME_T5] = regp->r_regs[R_T5]; 1100 1.1 cgd framep->tf_regs[FRAME_T6] = regp->r_regs[R_T6]; 1101 1.1 cgd framep->tf_regs[FRAME_T7] = regp->r_regs[R_T7]; 1102 1.1 cgd framep->tf_regs[FRAME_S0] = regp->r_regs[R_S0]; 1103 1.1 cgd framep->tf_regs[FRAME_S1] = regp->r_regs[R_S1]; 1104 1.1 cgd framep->tf_regs[FRAME_S2] = regp->r_regs[R_S2]; 1105 1.1 cgd framep->tf_regs[FRAME_S3] = regp->r_regs[R_S3]; 1106 1.1 cgd framep->tf_regs[FRAME_S4] = regp->r_regs[R_S4]; 1107 1.1 cgd framep->tf_regs[FRAME_S5] = regp->r_regs[R_S5]; 1108 1.1 cgd framep->tf_regs[FRAME_S6] = regp->r_regs[R_S6]; 1109 1.34 cgd framep->tf_regs[FRAME_A0] = regp->r_regs[R_A0]; 1110 1.34 cgd framep->tf_regs[FRAME_A1] = regp->r_regs[R_A1]; 1111 1.34 cgd framep->tf_regs[FRAME_A2] = regp->r_regs[R_A2]; 1112 1.1 cgd framep->tf_regs[FRAME_A3] = regp->r_regs[R_A3]; 1113 1.1 cgd framep->tf_regs[FRAME_A4] = regp->r_regs[R_A4]; 1114 1.1 cgd framep->tf_regs[FRAME_A5] = regp->r_regs[R_A5]; 1115 1.1 cgd framep->tf_regs[FRAME_T8] = regp->r_regs[R_T8]; 1116 1.1 cgd framep->tf_regs[FRAME_T9] = regp->r_regs[R_T9]; 1117 1.1 cgd framep->tf_regs[FRAME_T10] = regp->r_regs[R_T10]; 1118 1.1 cgd framep->tf_regs[FRAME_T11] = regp->r_regs[R_T11]; 1119 1.1 cgd framep->tf_regs[FRAME_RA] = regp->r_regs[R_RA]; 1120 1.1 cgd framep->tf_regs[FRAME_T12] = regp->r_regs[R_T12]; 1121 1.1 cgd framep->tf_regs[FRAME_AT] = regp->r_regs[R_AT]; 1122 1.34 cgd framep->tf_regs[FRAME_GP] = regp->r_regs[R_GP]; 1123 1.35 cgd /* framep->tf_regs[FRAME_SP] = regp->r_regs[R_SP]; XXX */ 1124 1.1 cgd /* ??? = regp->r_regs[R_ZERO]; */ 1125 1.1 cgd } 1126 1.1 cgd 1127 1.1 cgd void 1128 1.1 cgd printregs(regp) 1129 1.1 cgd struct reg *regp; 1130 1.1 cgd { 1131 1.1 cgd int i; 1132 1.1 cgd 1133 1.1 cgd for (i = 0; i < 32; i++) 1134 1.1 cgd printf("R%d:\t0x%016lx%s", i, regp->r_regs[i], 1135 1.1 cgd i & 1 ? "\n" : "\t"); 1136 1.1 cgd } 1137 1.1 cgd 1138 1.1 cgd void 1139 1.1 cgd regdump(framep) 1140 1.1 cgd struct trapframe *framep; 1141 1.1 cgd { 1142 1.1 cgd struct reg reg; 1143 1.1 cgd 1144 1.1 cgd frametoreg(framep, ®); 1145 1.35 cgd reg.r_regs[R_SP] = alpha_pal_rdusp(); 1146 1.35 cgd 1147 1.1 cgd printf("REGISTERS:\n"); 1148 1.1 cgd printregs(®); 1149 1.1 cgd } 1150 1.1 cgd 1151 1.1 cgd #ifdef DEBUG 1152 1.1 cgd int sigdebug = 0; 1153 1.1 cgd int sigpid = 0; 1154 1.1 cgd #define SDB_FOLLOW 0x01 1155 1.1 cgd #define SDB_KSTACK 0x02 1156 1.1 cgd #endif 1157 1.1 cgd 1158 1.1 cgd /* 1159 1.1 cgd * Send an interrupt to process. 1160 1.1 cgd */ 1161 1.1 cgd void 1162 1.1 cgd sendsig(catcher, sig, mask, code) 1163 1.1 cgd sig_t catcher; 1164 1.1 cgd int sig, mask; 1165 1.1 cgd u_long code; 1166 1.1 cgd { 1167 1.1 cgd struct proc *p = curproc; 1168 1.1 cgd struct sigcontext *scp, ksc; 1169 1.1 cgd struct trapframe *frame; 1170 1.1 cgd struct sigacts *psp = p->p_sigacts; 1171 1.1 cgd int oonstack, fsize, rndfsize; 1172 1.1 cgd extern char sigcode[], esigcode[]; 1173 1.1 cgd extern struct proc *fpcurproc; 1174 1.1 cgd 1175 1.1 cgd frame = p->p_md.md_tf; 1176 1.9 mycroft oonstack = psp->ps_sigstk.ss_flags & SS_ONSTACK; 1177 1.1 cgd fsize = sizeof ksc; 1178 1.1 cgd rndfsize = ((fsize + 15) / 16) * 16; 1179 1.1 cgd /* 1180 1.1 cgd * Allocate and validate space for the signal handler 1181 1.1 cgd * context. Note that if the stack is in P0 space, the 1182 1.1 cgd * call to grow() is a nop, and the useracc() check 1183 1.1 cgd * will fail if the process has not already allocated 1184 1.1 cgd * the space with a `brk'. 1185 1.1 cgd */ 1186 1.1 cgd if ((psp->ps_flags & SAS_ALTSTACK) && !oonstack && 1187 1.1 cgd (psp->ps_sigonstack & sigmask(sig))) { 1188 1.14 jtc scp = (struct sigcontext *)(psp->ps_sigstk.ss_sp + 1189 1.1 cgd psp->ps_sigstk.ss_size - rndfsize); 1190 1.9 mycroft psp->ps_sigstk.ss_flags |= SS_ONSTACK; 1191 1.1 cgd } else 1192 1.35 cgd scp = (struct sigcontext *)(alpha_pal_rdusp() - rndfsize); 1193 1.1 cgd if ((u_long)scp <= USRSTACK - ctob(p->p_vmspace->vm_ssize)) 1194 1.1 cgd (void)grow(p, (u_long)scp); 1195 1.1 cgd #ifdef DEBUG 1196 1.1 cgd if ((sigdebug & SDB_KSTACK) && p->p_pid == sigpid) 1197 1.33 cgd printf("sendsig(%d): sig %d ssp %p usp %p\n", p->p_pid, 1198 1.1 cgd sig, &oonstack, scp); 1199 1.1 cgd #endif 1200 1.1 cgd if (useracc((caddr_t)scp, fsize, B_WRITE) == 0) { 1201 1.1 cgd #ifdef DEBUG 1202 1.1 cgd if ((sigdebug & SDB_KSTACK) && p->p_pid == sigpid) 1203 1.1 cgd printf("sendsig(%d): useracc failed on sig %d\n", 1204 1.1 cgd p->p_pid, sig); 1205 1.1 cgd #endif 1206 1.1 cgd /* 1207 1.1 cgd * Process has trashed its stack; give it an illegal 1208 1.1 cgd * instruction to halt it in its tracks. 1209 1.1 cgd */ 1210 1.1 cgd SIGACTION(p, SIGILL) = SIG_DFL; 1211 1.1 cgd sig = sigmask(SIGILL); 1212 1.1 cgd p->p_sigignore &= ~sig; 1213 1.1 cgd p->p_sigcatch &= ~sig; 1214 1.1 cgd p->p_sigmask &= ~sig; 1215 1.1 cgd psignal(p, SIGILL); 1216 1.1 cgd return; 1217 1.1 cgd } 1218 1.1 cgd 1219 1.1 cgd /* 1220 1.1 cgd * Build the signal context to be used by sigreturn. 1221 1.1 cgd */ 1222 1.1 cgd ksc.sc_onstack = oonstack; 1223 1.1 cgd ksc.sc_mask = mask; 1224 1.34 cgd ksc.sc_pc = frame->tf_regs[FRAME_PC]; 1225 1.34 cgd ksc.sc_ps = frame->tf_regs[FRAME_PS]; 1226 1.1 cgd 1227 1.1 cgd /* copy the registers. */ 1228 1.1 cgd frametoreg(frame, (struct reg *)ksc.sc_regs); 1229 1.1 cgd ksc.sc_regs[R_ZERO] = 0xACEDBADE; /* magic number */ 1230 1.35 cgd ksc.sc_regs[R_SP] = alpha_pal_rdusp(); 1231 1.1 cgd 1232 1.1 cgd /* save the floating-point state, if necessary, then copy it. */ 1233 1.1 cgd if (p == fpcurproc) { 1234 1.32 cgd alpha_pal_wrfen(1); 1235 1.1 cgd savefpstate(&p->p_addr->u_pcb.pcb_fp); 1236 1.32 cgd alpha_pal_wrfen(0); 1237 1.1 cgd fpcurproc = NULL; 1238 1.1 cgd } 1239 1.1 cgd ksc.sc_ownedfp = p->p_md.md_flags & MDP_FPUSED; 1240 1.1 cgd bcopy(&p->p_addr->u_pcb.pcb_fp, (struct fpreg *)ksc.sc_fpregs, 1241 1.1 cgd sizeof(struct fpreg)); 1242 1.1 cgd ksc.sc_fp_control = 0; /* XXX ? */ 1243 1.1 cgd bzero(ksc.sc_reserved, sizeof ksc.sc_reserved); /* XXX */ 1244 1.1 cgd bzero(ksc.sc_xxx, sizeof ksc.sc_xxx); /* XXX */ 1245 1.1 cgd 1246 1.1 cgd 1247 1.1 cgd #ifdef COMPAT_OSF1 1248 1.1 cgd /* 1249 1.1 cgd * XXX Create an OSF/1-style sigcontext and associated goo. 1250 1.1 cgd */ 1251 1.1 cgd #endif 1252 1.1 cgd 1253 1.1 cgd /* 1254 1.1 cgd * copy the frame out to userland. 1255 1.1 cgd */ 1256 1.1 cgd (void) copyout((caddr_t)&ksc, (caddr_t)scp, fsize); 1257 1.1 cgd #ifdef DEBUG 1258 1.1 cgd if (sigdebug & SDB_FOLLOW) 1259 1.33 cgd printf("sendsig(%d): sig %d scp %p code %lx\n", p->p_pid, sig, 1260 1.1 cgd scp, code); 1261 1.1 cgd #endif 1262 1.1 cgd 1263 1.1 cgd /* 1264 1.1 cgd * Set up the registers to return to sigcode. 1265 1.1 cgd */ 1266 1.34 cgd frame->tf_regs[FRAME_PC] = 1267 1.34 cgd (u_int64_t)PS_STRINGS - (esigcode - sigcode); 1268 1.34 cgd frame->tf_regs[FRAME_A0] = sig; 1269 1.34 cgd frame->tf_regs[FRAME_A1] = code; 1270 1.34 cgd frame->tf_regs[FRAME_A2] = (u_int64_t)scp; 1271 1.1 cgd frame->tf_regs[FRAME_T12] = (u_int64_t)catcher; /* t12 is pv */ 1272 1.35 cgd alpha_pal_wrusp((unsigned long)scp); 1273 1.1 cgd 1274 1.1 cgd #ifdef DEBUG 1275 1.1 cgd if (sigdebug & SDB_FOLLOW) 1276 1.1 cgd printf("sendsig(%d): pc %lx, catcher %lx\n", p->p_pid, 1277 1.34 cgd frame->tf_regs[FRAME_PC], frame->tf_regs[FRAME_A3]); 1278 1.1 cgd if ((sigdebug & SDB_KSTACK) && p->p_pid == sigpid) 1279 1.1 cgd printf("sendsig(%d): sig %d returns\n", 1280 1.1 cgd p->p_pid, sig); 1281 1.1 cgd #endif 1282 1.1 cgd } 1283 1.1 cgd 1284 1.1 cgd /* 1285 1.1 cgd * System call to cleanup state after a signal 1286 1.1 cgd * has been taken. Reset signal mask and 1287 1.1 cgd * stack state from context left by sendsig (above). 1288 1.1 cgd * Return to previous pc and psl as specified by 1289 1.1 cgd * context left by sendsig. Check carefully to 1290 1.1 cgd * make sure that the user has not modified the 1291 1.1 cgd * psl to gain improper priviledges or to cause 1292 1.1 cgd * a machine fault. 1293 1.1 cgd */ 1294 1.1 cgd /* ARGSUSED */ 1295 1.11 mycroft int 1296 1.11 mycroft sys_sigreturn(p, v, retval) 1297 1.1 cgd struct proc *p; 1298 1.10 thorpej void *v; 1299 1.10 thorpej register_t *retval; 1300 1.10 thorpej { 1301 1.11 mycroft struct sys_sigreturn_args /* { 1302 1.1 cgd syscallarg(struct sigcontext *) sigcntxp; 1303 1.10 thorpej } */ *uap = v; 1304 1.1 cgd struct sigcontext *scp, ksc; 1305 1.1 cgd extern struct proc *fpcurproc; 1306 1.1 cgd 1307 1.1 cgd scp = SCARG(uap, sigcntxp); 1308 1.1 cgd #ifdef DEBUG 1309 1.1 cgd if (sigdebug & SDB_FOLLOW) 1310 1.33 cgd printf("sigreturn: pid %d, scp %p\n", p->p_pid, scp); 1311 1.1 cgd #endif 1312 1.1 cgd 1313 1.1 cgd if (ALIGN(scp) != (u_int64_t)scp) 1314 1.1 cgd return (EINVAL); 1315 1.1 cgd 1316 1.1 cgd /* 1317 1.1 cgd * Test and fetch the context structure. 1318 1.1 cgd * We grab it all at once for speed. 1319 1.1 cgd */ 1320 1.1 cgd if (useracc((caddr_t)scp, sizeof (*scp), B_WRITE) == 0 || 1321 1.1 cgd copyin((caddr_t)scp, (caddr_t)&ksc, sizeof ksc)) 1322 1.1 cgd return (EINVAL); 1323 1.1 cgd 1324 1.1 cgd if (ksc.sc_regs[R_ZERO] != 0xACEDBADE) /* magic number */ 1325 1.1 cgd return (EINVAL); 1326 1.1 cgd /* 1327 1.1 cgd * Restore the user-supplied information 1328 1.1 cgd */ 1329 1.1 cgd if (ksc.sc_onstack) 1330 1.9 mycroft p->p_sigacts->ps_sigstk.ss_flags |= SS_ONSTACK; 1331 1.1 cgd else 1332 1.9 mycroft p->p_sigacts->ps_sigstk.ss_flags &= ~SS_ONSTACK; 1333 1.1 cgd p->p_sigmask = ksc.sc_mask &~ sigcantmask; 1334 1.1 cgd 1335 1.34 cgd p->p_md.md_tf->tf_regs[FRAME_PC] = ksc.sc_pc; 1336 1.34 cgd p->p_md.md_tf->tf_regs[FRAME_PS] = 1337 1.32 cgd (ksc.sc_ps | ALPHA_PSL_USERSET) & ~ALPHA_PSL_USERCLR; 1338 1.1 cgd 1339 1.1 cgd regtoframe((struct reg *)ksc.sc_regs, p->p_md.md_tf); 1340 1.35 cgd alpha_pal_wrusp(ksc.sc_regs[R_SP]); 1341 1.1 cgd 1342 1.1 cgd /* XXX ksc.sc_ownedfp ? */ 1343 1.1 cgd if (p == fpcurproc) 1344 1.1 cgd fpcurproc = NULL; 1345 1.1 cgd bcopy((struct fpreg *)ksc.sc_fpregs, &p->p_addr->u_pcb.pcb_fp, 1346 1.1 cgd sizeof(struct fpreg)); 1347 1.1 cgd /* XXX ksc.sc_fp_control ? */ 1348 1.1 cgd 1349 1.1 cgd #ifdef DEBUG 1350 1.1 cgd if (sigdebug & SDB_FOLLOW) 1351 1.1 cgd printf("sigreturn(%d): returns\n", p->p_pid); 1352 1.1 cgd #endif 1353 1.1 cgd return (EJUSTRETURN); 1354 1.1 cgd } 1355 1.1 cgd 1356 1.1 cgd /* 1357 1.1 cgd * machine dependent system variables. 1358 1.1 cgd */ 1359 1.33 cgd int 1360 1.1 cgd cpu_sysctl(name, namelen, oldp, oldlenp, newp, newlen, p) 1361 1.1 cgd int *name; 1362 1.1 cgd u_int namelen; 1363 1.1 cgd void *oldp; 1364 1.1 cgd size_t *oldlenp; 1365 1.1 cgd void *newp; 1366 1.1 cgd size_t newlen; 1367 1.1 cgd struct proc *p; 1368 1.1 cgd { 1369 1.1 cgd dev_t consdev; 1370 1.1 cgd 1371 1.1 cgd /* all sysctl names at this level are terminal */ 1372 1.1 cgd if (namelen != 1) 1373 1.1 cgd return (ENOTDIR); /* overloaded */ 1374 1.1 cgd 1375 1.1 cgd switch (name[0]) { 1376 1.1 cgd case CPU_CONSDEV: 1377 1.1 cgd if (cn_tab != NULL) 1378 1.1 cgd consdev = cn_tab->cn_dev; 1379 1.1 cgd else 1380 1.1 cgd consdev = NODEV; 1381 1.1 cgd return (sysctl_rdstruct(oldp, oldlenp, newp, &consdev, 1382 1.1 cgd sizeof consdev)); 1383 1.30 cgd 1384 1.30 cgd case CPU_ROOT_DEVICE: 1385 1.30 cgd return (sysctl_rdstring(oldp, oldlenp, newp, root_device)); 1386 1.36 cgd 1387 1.36 cgd case CPU_UNALIGNED_PRINT: 1388 1.36 cgd return (sysctl_int(oldp, oldlenp, newp, newlen, 1389 1.36 cgd &alpha_unaligned_print)); 1390 1.36 cgd 1391 1.36 cgd case CPU_UNALIGNED_FIX: 1392 1.36 cgd return (sysctl_int(oldp, oldlenp, newp, newlen, 1393 1.36 cgd &alpha_unaligned_fix)); 1394 1.36 cgd 1395 1.36 cgd case CPU_UNALIGNED_SIGBUS: 1396 1.36 cgd return (sysctl_int(oldp, oldlenp, newp, newlen, 1397 1.36 cgd &alpha_unaligned_sigbus)); 1398 1.30 cgd 1399 1.1 cgd default: 1400 1.1 cgd return (EOPNOTSUPP); 1401 1.1 cgd } 1402 1.1 cgd /* NOTREACHED */ 1403 1.1 cgd } 1404 1.1 cgd 1405 1.1 cgd /* 1406 1.1 cgd * Set registers on exec. 1407 1.1 cgd */ 1408 1.1 cgd void 1409 1.5 christos setregs(p, pack, stack, retval) 1410 1.1 cgd register struct proc *p; 1411 1.5 christos struct exec_package *pack; 1412 1.1 cgd u_long stack; 1413 1.1 cgd register_t *retval; 1414 1.1 cgd { 1415 1.1 cgd struct trapframe *tfp = p->p_md.md_tf; 1416 1.1 cgd int i; 1417 1.1 cgd extern struct proc *fpcurproc; 1418 1.43 cgd 1419 1.43 cgd #ifdef DEBUG 1420 1.43 cgd /* 1421 1.43 cgd * Crash and dump, if the user requested it. 1422 1.43 cgd */ 1423 1.43 cgd if (boothowto & RB_DUMP) 1424 1.43 cgd panic("crash requested by boot flags"); 1425 1.43 cgd #endif 1426 1.1 cgd 1427 1.1 cgd #ifdef DEBUG 1428 1.34 cgd for (i = 0; i < FRAME_SIZE; i++) 1429 1.1 cgd tfp->tf_regs[i] = 0xbabefacedeadbeef; 1430 1.1 cgd #else 1431 1.34 cgd bzero(tfp->tf_regs, FRAME_SIZE * sizeof tfp->tf_regs[0]); 1432 1.1 cgd #endif 1433 1.1 cgd bzero(&p->p_addr->u_pcb.pcb_fp, sizeof p->p_addr->u_pcb.pcb_fp); 1434 1.7 cgd #define FP_RN 2 /* XXX */ 1435 1.7 cgd p->p_addr->u_pcb.pcb_fp.fpr_cr = (long)FP_RN << 58; 1436 1.35 cgd alpha_pal_wrusp(stack); 1437 1.34 cgd tfp->tf_regs[FRAME_PS] = ALPHA_PSL_USERSET; 1438 1.34 cgd tfp->tf_regs[FRAME_PC] = pack->ep_entry & ~3; 1439 1.41 cgd 1440 1.41 cgd tfp->tf_regs[FRAME_A0] = stack; 1441 1.41 cgd /* a1 and a2 already zeroed */ 1442 1.41 cgd tfp->tf_regs[FRAME_T12] = tfp->tf_regs[FRAME_PC]; /* a.k.a. PV */ 1443 1.1 cgd 1444 1.33 cgd p->p_md.md_flags &= ~MDP_FPUSED; 1445 1.1 cgd if (fpcurproc == p) 1446 1.1 cgd fpcurproc = NULL; 1447 1.1 cgd 1448 1.1 cgd retval[0] = retval[1] = 0; 1449 1.1 cgd } 1450 1.1 cgd 1451 1.1 cgd void 1452 1.1 cgd netintr() 1453 1.1 cgd { 1454 1.1 cgd #ifdef INET 1455 1.1 cgd #if NETHER > 0 1456 1.1 cgd if (netisr & (1 << NETISR_ARP)) { 1457 1.1 cgd netisr &= ~(1 << NETISR_ARP); 1458 1.1 cgd arpintr(); 1459 1.1 cgd } 1460 1.1 cgd #endif 1461 1.1 cgd if (netisr & (1 << NETISR_IP)) { 1462 1.1 cgd netisr &= ~(1 << NETISR_IP); 1463 1.1 cgd ipintr(); 1464 1.1 cgd } 1465 1.1 cgd #endif 1466 1.1 cgd #ifdef NS 1467 1.1 cgd if (netisr & (1 << NETISR_NS)) { 1468 1.1 cgd netisr &= ~(1 << NETISR_NS); 1469 1.1 cgd nsintr(); 1470 1.1 cgd } 1471 1.1 cgd #endif 1472 1.1 cgd #ifdef ISO 1473 1.1 cgd if (netisr & (1 << NETISR_ISO)) { 1474 1.1 cgd netisr &= ~(1 << NETISR_ISO); 1475 1.1 cgd clnlintr(); 1476 1.1 cgd } 1477 1.1 cgd #endif 1478 1.1 cgd #ifdef CCITT 1479 1.1 cgd if (netisr & (1 << NETISR_CCITT)) { 1480 1.1 cgd netisr &= ~(1 << NETISR_CCITT); 1481 1.1 cgd ccittintr(); 1482 1.1 cgd } 1483 1.1 cgd #endif 1484 1.8 cgd #ifdef PPP 1485 1.8 cgd if (netisr & (1 << NETISR_PPP)) { 1486 1.20 cgd netisr &= ~(1 << NETISR_PPP); 1487 1.8 cgd pppintr(); 1488 1.8 cgd } 1489 1.8 cgd #endif 1490 1.1 cgd } 1491 1.1 cgd 1492 1.1 cgd void 1493 1.1 cgd do_sir() 1494 1.1 cgd { 1495 1.1 cgd 1496 1.1 cgd if (ssir & SIR_NET) { 1497 1.1 cgd siroff(SIR_NET); 1498 1.1 cgd cnt.v_soft++; 1499 1.1 cgd netintr(); 1500 1.1 cgd } 1501 1.1 cgd if (ssir & SIR_CLOCK) { 1502 1.1 cgd siroff(SIR_CLOCK); 1503 1.1 cgd cnt.v_soft++; 1504 1.1 cgd softclock(); 1505 1.1 cgd } 1506 1.1 cgd } 1507 1.1 cgd 1508 1.1 cgd int 1509 1.1 cgd spl0() 1510 1.1 cgd { 1511 1.1 cgd 1512 1.1 cgd if (ssir) { 1513 1.1 cgd splsoft(); 1514 1.1 cgd do_sir(); 1515 1.1 cgd } 1516 1.1 cgd 1517 1.32 cgd return (alpha_pal_swpipl(ALPHA_PSL_IPL_0)); 1518 1.1 cgd } 1519 1.1 cgd 1520 1.1 cgd /* 1521 1.1 cgd * The following primitives manipulate the run queues. _whichqs tells which 1522 1.1 cgd * of the 32 queues _qs have processes in them. Setrunqueue puts processes 1523 1.1 cgd * into queues, Remrq removes them from queues. The running process is on 1524 1.1 cgd * no queue, other processes are on a queue related to p->p_priority, divided 1525 1.1 cgd * by 4 actually to shrink the 0-127 range of priorities into the 32 available 1526 1.1 cgd * queues. 1527 1.1 cgd */ 1528 1.1 cgd /* 1529 1.1 cgd * setrunqueue(p) 1530 1.1 cgd * proc *p; 1531 1.1 cgd * 1532 1.1 cgd * Call should be made at splclock(), and p->p_stat should be SRUN. 1533 1.1 cgd */ 1534 1.1 cgd 1535 1.1 cgd void 1536 1.1 cgd setrunqueue(p) 1537 1.1 cgd struct proc *p; 1538 1.1 cgd { 1539 1.1 cgd int bit; 1540 1.1 cgd 1541 1.1 cgd /* firewall: p->p_back must be NULL */ 1542 1.1 cgd if (p->p_back != NULL) 1543 1.1 cgd panic("setrunqueue"); 1544 1.1 cgd 1545 1.1 cgd bit = p->p_priority >> 2; 1546 1.1 cgd whichqs |= (1 << bit); 1547 1.1 cgd p->p_forw = (struct proc *)&qs[bit]; 1548 1.1 cgd p->p_back = qs[bit].ph_rlink; 1549 1.1 cgd p->p_back->p_forw = p; 1550 1.1 cgd qs[bit].ph_rlink = p; 1551 1.1 cgd } 1552 1.1 cgd 1553 1.1 cgd /* 1554 1.1 cgd * Remrq(p) 1555 1.1 cgd * 1556 1.1 cgd * Call should be made at splclock(). 1557 1.1 cgd */ 1558 1.1 cgd void 1559 1.1 cgd remrq(p) 1560 1.1 cgd struct proc *p; 1561 1.1 cgd { 1562 1.1 cgd int bit; 1563 1.1 cgd 1564 1.1 cgd bit = p->p_priority >> 2; 1565 1.1 cgd if ((whichqs & (1 << bit)) == 0) 1566 1.1 cgd panic("remrq"); 1567 1.1 cgd 1568 1.1 cgd p->p_back->p_forw = p->p_forw; 1569 1.1 cgd p->p_forw->p_back = p->p_back; 1570 1.1 cgd p->p_back = NULL; /* for firewall checking. */ 1571 1.1 cgd 1572 1.1 cgd if ((struct proc *)&qs[bit] == qs[bit].ph_link) 1573 1.1 cgd whichqs &= ~(1 << bit); 1574 1.1 cgd } 1575 1.1 cgd 1576 1.1 cgd /* 1577 1.1 cgd * Return the best possible estimate of the time in the timeval 1578 1.1 cgd * to which tvp points. Unfortunately, we can't read the hardware registers. 1579 1.1 cgd * We guarantee that the time will be greater than the value obtained by a 1580 1.1 cgd * previous call. 1581 1.1 cgd */ 1582 1.1 cgd void 1583 1.1 cgd microtime(tvp) 1584 1.1 cgd register struct timeval *tvp; 1585 1.1 cgd { 1586 1.1 cgd int s = splclock(); 1587 1.1 cgd static struct timeval lasttime; 1588 1.1 cgd 1589 1.1 cgd *tvp = time; 1590 1.1 cgd #ifdef notdef 1591 1.1 cgd tvp->tv_usec += clkread(); 1592 1.1 cgd while (tvp->tv_usec > 1000000) { 1593 1.1 cgd tvp->tv_sec++; 1594 1.1 cgd tvp->tv_usec -= 1000000; 1595 1.1 cgd } 1596 1.1 cgd #endif 1597 1.1 cgd if (tvp->tv_sec == lasttime.tv_sec && 1598 1.1 cgd tvp->tv_usec <= lasttime.tv_usec && 1599 1.1 cgd (tvp->tv_usec = lasttime.tv_usec + 1) > 1000000) { 1600 1.1 cgd tvp->tv_sec++; 1601 1.1 cgd tvp->tv_usec -= 1000000; 1602 1.1 cgd } 1603 1.1 cgd lasttime = *tvp; 1604 1.1 cgd splx(s); 1605 1.15 cgd } 1606 1.15 cgd 1607 1.15 cgd /* 1608 1.15 cgd * Wait "n" microseconds. 1609 1.15 cgd */ 1610 1.32 cgd void 1611 1.15 cgd delay(n) 1612 1.32 cgd unsigned long n; 1613 1.15 cgd { 1614 1.15 cgd long N = cycles_per_usec * (n); 1615 1.15 cgd 1616 1.15 cgd while (N > 0) /* XXX */ 1617 1.15 cgd N -= 3; /* XXX */ 1618 1.1 cgd } 1619 1.1 cgd 1620 1.8 cgd #if defined(COMPAT_OSF1) || 1 /* XXX */ 1621 1.1 cgd void 1622 1.19 cgd cpu_exec_ecoff_setregs(p, epp, stack, retval) 1623 1.1 cgd struct proc *p; 1624 1.19 cgd struct exec_package *epp; 1625 1.5 christos u_long stack; 1626 1.5 christos register_t *retval; 1627 1.1 cgd { 1628 1.19 cgd struct ecoff_exechdr *execp = (struct ecoff_exechdr *)epp->ep_hdr; 1629 1.1 cgd 1630 1.19 cgd setregs(p, epp, stack, retval); 1631 1.34 cgd p->p_md.md_tf->tf_regs[FRAME_GP] = execp->a.gp_value; 1632 1.1 cgd } 1633 1.1 cgd 1634 1.1 cgd /* 1635 1.1 cgd * cpu_exec_ecoff_hook(): 1636 1.1 cgd * cpu-dependent ECOFF format hook for execve(). 1637 1.1 cgd * 1638 1.1 cgd * Do any machine-dependent diddling of the exec package when doing ECOFF. 1639 1.1 cgd * 1640 1.1 cgd */ 1641 1.1 cgd int 1642 1.19 cgd cpu_exec_ecoff_hook(p, epp) 1643 1.1 cgd struct proc *p; 1644 1.1 cgd struct exec_package *epp; 1645 1.1 cgd { 1646 1.19 cgd struct ecoff_exechdr *execp = (struct ecoff_exechdr *)epp->ep_hdr; 1647 1.5 christos extern struct emul emul_netbsd; 1648 1.5 christos #ifdef COMPAT_OSF1 1649 1.5 christos extern struct emul emul_osf1; 1650 1.5 christos #endif 1651 1.1 cgd 1652 1.19 cgd switch (execp->f.f_magic) { 1653 1.5 christos #ifdef COMPAT_OSF1 1654 1.1 cgd case ECOFF_MAGIC_ALPHA: 1655 1.5 christos epp->ep_emul = &emul_osf1; 1656 1.1 cgd break; 1657 1.5 christos #endif 1658 1.1 cgd 1659 1.1 cgd case ECOFF_MAGIC_NETBSD_ALPHA: 1660 1.5 christos epp->ep_emul = &emul_netbsd; 1661 1.1 cgd break; 1662 1.1 cgd 1663 1.1 cgd default: 1664 1.12 cgd return ENOEXEC; 1665 1.1 cgd } 1666 1.1 cgd return 0; 1667 1.1 cgd } 1668 1.1 cgd #endif 1669
Indexes created Thu Oct 02 10:09:58 GMT 2025