sun2.c revision 1.5.6.1
1 1.5.6.1 skrll /* $NetBSD: sun2.c,v 1.5.6.1 2005/01/24 08:35:03 skrll Exp $ */ 2 1.1 fredette 3 1.1 fredette /*- 4 1.1 fredette * Copyright (c) 1998 The NetBSD Foundation, Inc. 5 1.1 fredette * All rights reserved. 6 1.1 fredette * 7 1.1 fredette * This code is derived from software contributed to The NetBSD Foundation 8 1.1 fredette * by Gordon W. Ross and Matthew Fredette. 9 1.1 fredette * 10 1.1 fredette * Redistribution and use in source and binary forms, with or without 11 1.1 fredette * modification, are permitted provided that the following conditions 12 1.1 fredette * are met: 13 1.1 fredette * 1. Redistributions of source code must retain the above copyright 14 1.1 fredette * notice, this list of conditions and the following disclaimer. 15 1.1 fredette * 2. Redistributions in binary form must reproduce the above copyright 16 1.1 fredette * notice, this list of conditions and the following disclaimer in the 17 1.1 fredette * documentation and/or other materials provided with the distribution. 18 1.1 fredette * 3. All advertising materials mentioning features or use of this software 19 1.1 fredette * must display the following acknowledgement: 20 1.1 fredette * This product includes software developed by the NetBSD 21 1.1 fredette * Foundation, Inc. and its contributors. 22 1.1 fredette * 4. Neither the name of The NetBSD Foundation nor the names of its 23 1.1 fredette * contributors may be used to endorse or promote products derived 24 1.1 fredette * from this software without specific prior written permission. 25 1.1 fredette * 26 1.1 fredette * THIS SOFTWARE IS PROVIDED BY THE NETBSD FOUNDATION, INC. AND CONTRIBUTORS 27 1.1 fredette * ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED 28 1.1 fredette * TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR 29 1.1 fredette * PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE FOUNDATION OR CONTRIBUTORS 30 1.1 fredette * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR 31 1.1 fredette * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF 32 1.1 fredette * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS 33 1.1 fredette * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN 34 1.1 fredette * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) 35 1.1 fredette * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE 36 1.1 fredette * POSSIBILITY OF SUCH DAMAGE. 37 1.1 fredette */ 38 1.1 fredette 39 1.1 fredette /* 40 1.1 fredette * Standalone functions specific to the Sun2. 41 1.1 fredette */ 42 1.1 fredette 43 1.1 fredette /* Need to avoid conflicts on these: */ 44 1.1 fredette #define get_pte sun2_get_pte 45 1.1 fredette #define set_pte sun2_set_pte 46 1.1 fredette #define get_segmap sun2_get_segmap 47 1.1 fredette #define set_segmap sun2_set_segmap 48 1.4 nathanw 49 1.4 nathanw /* 50 1.4 nathanw * We need to get the sun2 NBSG definition, even if we're 51 1.4 nathanw * building this with a different sun68k target. 52 1.4 nathanw */ 53 1.4 nathanw #include <arch/sun2/include/param.h> 54 1.1 fredette 55 1.1 fredette #include <sys/param.h> 56 1.1 fredette #include <machine/idprom.h> 57 1.1 fredette #include <machine/mon.h> 58 1.1 fredette 59 1.1 fredette #include <arch/sun2/include/pte.h> 60 1.1 fredette #include <arch/sun2/sun2/control.h> 61 1.1 fredette #ifdef notyet 62 1.1 fredette #include <arch/sun3/sun3/vme.h> 63 1.1 fredette #else 64 1.1 fredette #define VME16_BASE MBIO_BASE 65 1.1 fredette #define VME16_MASK MBIO_MASK 66 1.1 fredette #endif 67 1.1 fredette #include <arch/sun2/sun2/mbmem.h> 68 1.1 fredette #include <arch/sun2/sun2/mbio.h> 69 1.1 fredette 70 1.1 fredette #include <stand.h> 71 1.1 fredette 72 1.1 fredette #include "libsa.h" 73 1.1 fredette #include "dvma.h" 74 1.1 fredette #include "saio.h" /* enum MAPTYPES */ 75 1.1 fredette 76 1.1 fredette #define OBIO_MASK 0xFFFFFF 77 1.1 fredette 78 1.5.6.1 skrll u_int get_pte(vaddr_t); 79 1.5.6.1 skrll void set_pte(vaddr_t, u_int); 80 1.5.6.1 skrll char * dvma2_alloc(int); 81 1.5.6.1 skrll void dvma2_free(char *, int); 82 1.5.6.1 skrll char * dvma2_mapin(char *, int); 83 1.5.6.1 skrll void dvma2_mapout(char *, int); 84 1.5.6.1 skrll char * dev2_mapin(int, u_long, int); 85 1.1 fredette 86 1.1 fredette struct mapinfo { 87 1.1 fredette int maptype; 88 1.1 fredette int pgtype; 89 1.1 fredette u_int base; 90 1.1 fredette u_int mask; 91 1.1 fredette }; 92 1.1 fredette 93 1.1 fredette #ifdef notyet 94 1.1 fredette struct mapinfo 95 1.1 fredette sun2_mapinfo[MAP__NTYPES] = { 96 1.1 fredette /* On-board memory, I/O */ 97 1.1 fredette { MAP_MAINMEM, PGT_OBMEM, 0, ~0 }, 98 1.1 fredette { MAP_OBIO, PGT_OBIO, 0, OBIO_MASK }, 99 1.1 fredette /* Multibus memory, I/O */ 100 1.1 fredette { MAP_MBMEM, PGT_MBMEM, MBMEM_BASE, MBMEM_MASK }, 101 1.1 fredette { MAP_MBIO, PGT_MBIO, MBIO_BASE, MBIO_MASK }, 102 1.1 fredette /* VME A16 */ 103 1.1 fredette { MAP_VME16A16D, PGT_VME_D16, VME16_BASE, VME16_MASK }, 104 1.1 fredette { MAP_VME16A32D, 0, 0, 0 }, 105 1.1 fredette /* VME A24 */ 106 1.1 fredette { MAP_VME24A16D, 0, 0, 0 }, 107 1.1 fredette { MAP_VME24A32D, 0, 0, 0 }, 108 1.1 fredette /* VME A32 */ 109 1.1 fredette { MAP_VME32A16D, 0, 0, 0 }, 110 1.1 fredette { MAP_VME32A32D, 0, 0, 0 }, 111 1.1 fredette }; 112 1.1 fredette #endif 113 1.1 fredette 114 1.1 fredette /* The virtual address we will use for PROM device mappings. */ 115 1.1 fredette int sun2_devmap = SUN3_MONSHORTSEG; 116 1.1 fredette 117 1.1 fredette char * 118 1.5.6.1 skrll dev2_mapin(int maptype, u_long physaddr, int length) 119 1.1 fredette { 120 1.1 fredette #ifdef notyet 121 1.1 fredette u_int i, pa, pte, pgva, va; 122 1.1 fredette 123 1.1 fredette if ((sun2_devmap + length) > SUN3_MONSHORTPAGE) 124 1.5 provos panic("dev2_mapin: length=%d", length); 125 1.1 fredette 126 1.1 fredette for (i = 0; i < MAP__NTYPES; i++) 127 1.1 fredette if (sun2_mapinfo[i].maptype == maptype) 128 1.1 fredette goto found; 129 1.1 fredette panic("dev2_mapin: bad maptype"); 130 1.1 fredette found: 131 1.1 fredette 132 1.1 fredette if (physaddr & ~(sun2_mapinfo[i].mask)) 133 1.1 fredette panic("dev2_mapin: bad address"); 134 1.1 fredette pa = sun2_mapinfo[i].base += physaddr; 135 1.1 fredette 136 1.1 fredette pte = PA_PGNUM(pa) | PG_PERM | 137 1.1 fredette sun2_mapinfo[i].pgtype; 138 1.1 fredette 139 1.1 fredette va = pgva = sun2_devmap; 140 1.1 fredette do { 141 1.1 fredette set_pte(pgva, pte); 142 1.1 fredette pgva += NBPG; 143 1.1 fredette pte += 1; 144 1.1 fredette length -= NBPG; 145 1.1 fredette } while (length > 0); 146 1.1 fredette sun2_devmap = pgva; 147 1.1 fredette va += (physaddr & PGOFSET); 148 1.1 fredette 149 1.1 fredette #ifdef DEBUG_PROM 150 1.1 fredette if (debug) 151 1.1 fredette printf("dev2_mapin: va=0x%x pte=0x%x\n", 152 1.1 fredette va, get_pte(va)); 153 1.1 fredette #endif 154 1.1 fredette return ((char*)va); 155 1.1 fredette #else 156 1.1 fredette panic("dev2_mapin"); 157 1.1 fredette return(NULL); 158 1.1 fredette #endif 159 1.1 fredette } 160 1.1 fredette 161 1.1 fredette /***************************************************************** 162 1.1 fredette * DVMA support 163 1.1 fredette */ 164 1.1 fredette 165 1.1 fredette /* 166 1.1 fredette * The easiest way to deal with the need for DVMA mappings is to 167 1.1 fredette * create a DVMA alias mapping of the entire address range used by 168 1.1 fredette * the boot program. That way, dvma_mapin can just compute the 169 1.1 fredette * DVMA alias address, and dvma_mapout does nothing. 170 1.1 fredette * 171 1.1 fredette * Note that this assumes that standalone programs will do I/O 172 1.1 fredette * operations only within range (SA_MIN_VA .. SA_MAX_VA) checked. 173 1.1 fredette */ 174 1.1 fredette 175 1.1 fredette #define DVMA_BASE 0x00f00000 176 1.1 fredette #define DVMA_MAPLEN 0x38000 /* 256K - 32K (save MONSHORTSEG) */ 177 1.1 fredette 178 1.1 fredette #define SA_MIN_VA 0x220000 179 1.1 fredette #define SA_MAX_VA (SA_MIN_VA + DVMA_MAPLEN) 180 1.1 fredette 181 1.1 fredette /* This points to the end of the free DVMA space. */ 182 1.1 fredette u_int dvma2_end = DVMA_BASE + DVMA_MAPLEN; 183 1.1 fredette 184 1.5.6.1 skrll void 185 1.5.6.1 skrll dvma2_init(void) 186 1.1 fredette { 187 1.1 fredette int segva, dmava, sme; 188 1.1 fredette 189 1.1 fredette segva = SA_MIN_VA; 190 1.1 fredette dmava = DVMA_BASE; 191 1.1 fredette 192 1.1 fredette while (segva < SA_MAX_VA) { 193 1.1 fredette sme = get_segmap(segva); 194 1.1 fredette set_segmap(dmava, sme); 195 1.1 fredette segva += NBSG; 196 1.1 fredette dmava += NBSG; 197 1.1 fredette } 198 1.1 fredette } 199 1.1 fredette 200 1.1 fredette /* Convert a local address to a DVMA address. */ 201 1.1 fredette char * 202 1.1 fredette dvma2_mapin(char *addr, int len) 203 1.1 fredette { 204 1.1 fredette int va = (int)addr; 205 1.1 fredette 206 1.1 fredette /* Make sure the address is in the DVMA map. */ 207 1.1 fredette if ((va < SA_MIN_VA) || (va >= SA_MAX_VA)) 208 1.5 provos panic("dvma2_mapin: 0x%x outside 0x%x..0x%x", 209 1.1 fredette va, SA_MIN_VA, SA_MAX_VA); 210 1.1 fredette 211 1.1 fredette va -= SA_MIN_VA; 212 1.1 fredette va += DVMA_BASE; 213 1.1 fredette 214 1.1 fredette return ((char *) va); 215 1.1 fredette } 216 1.1 fredette 217 1.1 fredette /* Destroy a DVMA address alias. */ 218 1.1 fredette void 219 1.1 fredette dvma2_mapout(char *addr, int len) 220 1.1 fredette { 221 1.1 fredette int va = (int)addr; 222 1.1 fredette 223 1.1 fredette /* Make sure the address is in the DVMA map. */ 224 1.1 fredette if ((va < DVMA_BASE) || (va >= (DVMA_BASE + DVMA_MAPLEN))) 225 1.1 fredette panic("dvma2_mapout"); 226 1.1 fredette } 227 1.1 fredette 228 1.1 fredette char * 229 1.1 fredette dvma2_alloc(int len) 230 1.1 fredette { 231 1.1 fredette len = m68k_round_page(len); 232 1.1 fredette dvma2_end -= len; 233 1.1 fredette return((char*)dvma2_end); 234 1.1 fredette } 235 1.1 fredette 236 1.1 fredette void 237 1.1 fredette dvma2_free(char *dvma, int len) 238 1.1 fredette { 239 1.1 fredette /* not worth the trouble */ 240 1.1 fredette } 241 1.1 fredette 242 1.1 fredette /***************************************************************** 243 1.1 fredette * Control space stuff... 244 1.1 fredette */ 245 1.1 fredette 246 1.1 fredette u_int 247 1.5.6.1 skrll get_pte(vaddr_t va) 248 1.1 fredette { 249 1.1 fredette u_int pte; 250 1.1 fredette 251 1.1 fredette pte = get_control_word(CONTROL_ADDR_BUILD(PGMAP_BASE, va)); 252 1.1 fredette if (pte & PG_VALID) { 253 1.1 fredette /* 254 1.1 fredette * This clears bit 30 (the kernel readable bit, which 255 1.1 fredette * should always be set), bit 28 (which should always 256 1.1 fredette * be set) and bit 26 (the user writable bit, which we 257 1.1 fredette * always have tracking the kernel writable bit). In 258 1.1 fredette * the protection, this leaves bit 29 (the kernel 259 1.1 fredette * writable bit) and bit 27 (the user readable bit). 260 1.1 fredette * See pte2.h for more about this hack. 261 1.1 fredette */ 262 1.1 fredette pte &= ~(0x54000000); 263 1.1 fredette /* 264 1.1 fredette * Flip bit 27 (the user readable bit) to become bit 265 1.1 fredette * 27 (the PG_SYSTEM bit). 266 1.1 fredette */ 267 1.1 fredette pte ^= (PG_SYSTEM); 268 1.1 fredette } 269 1.1 fredette return (pte); 270 1.1 fredette } 271 1.1 fredette 272 1.1 fredette void 273 1.5.6.1 skrll set_pte(vaddr_t va, u_int pte) 274 1.1 fredette { 275 1.1 fredette if (pte & PG_VALID) { 276 1.1 fredette /* Clear bit 26 (the user writable bit). */ 277 1.1 fredette pte &= (~0x04000000); 278 1.1 fredette /* 279 1.1 fredette * Flip bit 27 (the PG_SYSTEM bit) to become bit 27 280 1.1 fredette * (the user readable bit). 281 1.1 fredette */ 282 1.1 fredette pte ^= (PG_SYSTEM); 283 1.1 fredette /* 284 1.1 fredette * Always set bits 30 (the kernel readable bit) and 285 1.1 fredette * bit 28, and set bit 26 (the user writable bit) iff 286 1.1 fredette * bit 29 (the kernel writable bit) is set *and* bit 287 1.1 fredette * 27 (the user readable bit) is set. This latter bit 288 1.1 fredette * of logic is expressed in the bizarre second term 289 1.1 fredette * below, chosen because it needs no branches. 290 1.1 fredette */ 291 1.1 fredette #if (PG_WRITE >> 2) != PG_SYSTEM 292 1.1 fredette #error "PG_WRITE and PG_SYSTEM definitions don't match!" 293 1.1 fredette #endif 294 1.1 fredette pte |= 0x50000000 295 1.1 fredette | ((((pte & PG_WRITE) >> 2) & pte) >> 1); 296 1.1 fredette } 297 1.1 fredette set_control_word(CONTROL_ADDR_BUILD(PGMAP_BASE, va), pte); 298 1.1 fredette } 299 1.1 fredette 300 1.1 fredette int 301 1.5.6.1 skrll get_segmap(vaddr_t va) 302 1.1 fredette { 303 1.1 fredette va = CONTROL_ADDR_BUILD(SEGMAP_BASE, va); 304 1.1 fredette return (get_control_byte(va)); 305 1.1 fredette } 306 1.1 fredette 307 1.1 fredette void 308 1.5.6.1 skrll set_segmap(vaddr_t va, int sme) 309 1.1 fredette { 310 1.1 fredette va = CONTROL_ADDR_BUILD(SEGMAP_BASE, va); 311 1.1 fredette set_control_byte(va, sme); 312 1.1 fredette } 313 1.1 fredette 314 1.1 fredette /* 315 1.1 fredette * Copy the IDPROM contents into the passed buffer. 316 1.1 fredette * The caller (idprom.c) will do the checksum. 317 1.1 fredette */ 318 1.1 fredette void 319 1.1 fredette sun2_getidprom(u_char *dst) 320 1.1 fredette { 321 1.2 fredette vaddr_t src; /* control space address */ 322 1.1 fredette int len, x; 323 1.1 fredette 324 1.1 fredette src = IDPROM_BASE; 325 1.1 fredette len = sizeof(struct idprom); 326 1.1 fredette do { 327 1.1 fredette x = get_control_byte(src); 328 1.1 fredette src += NBPG; 329 1.1 fredette *dst++ = x; 330 1.1 fredette } while (--len > 0); 331 1.1 fredette } 332 1.1 fredette 333 1.1 fredette /***************************************************************** 334 1.1 fredette * Init our function pointers, etc. 335 1.1 fredette */ 336 1.1 fredette 337 1.3 fredette /* 338 1.3 fredette * For booting, the PROM in fredette's Sun 2/120 doesn't map 339 1.3 fredette * much main memory, and what is mapped is mapped strangely. 340 1.3 fredette * Low virtual memory is mapped like: 341 1.3 fredette * 342 1.3 fredette * 0x000000 - 0x0bffff virtual -> 0x000000 - 0x0bffff physical 343 1.3 fredette * 0x0c0000 - 0x0fffff virtual -> invalid 344 1.3 fredette * 0x100000 - 0x13ffff virtual -> 0x0c0000 - 0x0fffff physical 345 1.3 fredette * 0x200800 - 0x3fffff virtual -> 0x200800 - 0x3fffff physical 346 1.3 fredette * 347 1.3 fredette * I think the SunOS authors wanted to load kernels starting at 348 1.3 fredette * physical zero, and assumed that kernels would be less 349 1.3 fredette * than 768K (0x0c0000) long. Also, the PROM maps physical 350 1.3 fredette * 0x0c0000 - 0x0fffff into DVMA space, so we can't take the 351 1.3 fredette * easy road and just add more mappings to use that physical 352 1.3 fredette * memory while loading (the PROM might do DMA there). 353 1.3 fredette * 354 1.3 fredette * What we do, then, is assume a 4MB machine (you'll really 355 1.3 fredette * need that to run NetBSD at all anyways), and we map two 356 1.3 fredette * chunks of physical and virtual space: 357 1.3 fredette * 358 1.3 fredette * 0x400000 - 0x4bffff virtual -> 0x000000 - 0x0bffff physical 359 1.3 fredette * 0x4c0000 - 0x600000 virtual -> 0x2c0000 - 0x3fffff physical 360 1.3 fredette * 361 1.3 fredette * And then we load starting at virtual 0x400000. We will do 362 1.3 fredette * all of this mapping just by copying PMEGs. 363 1.3 fredette * 364 1.3 fredette * After the load is done, but before we enter the kernel, we're 365 1.3 fredette * done with the PROM, so we copy the part of the kernel that 366 1.3 fredette * got loaded at physical 0x2c0000 down to physical 0x0c0000. 367 1.3 fredette * This can't just be a PMEG copy; we've actually got to move 368 1.3 fredette * bytes in physical memory. 369 1.3 fredette * 370 1.3 fredette * These two chunks of physical and virtual space are defined 371 1.3 fredette * in macros below. Some of the macros are only for completeness: 372 1.3 fredette */ 373 1.3 fredette #define MEM_CHUNK0_SIZE (0x0c0000) 374 1.3 fredette #define MEM_CHUNK0_LOAD_PHYS (0x000000) 375 1.3 fredette #define MEM_CHUNK0_LOAD_VIRT (0x400000) 376 1.3 fredette #define MEM_CHUNK0_LOAD_VIRT_PROM MEM_CHUNK0_LOAD_PHYS 377 1.3 fredette #define MEM_CHUNK0_COPY_PHYS MEM_CHUNK0_LOAD_PHYS 378 1.3 fredette #define MEM_CHUNK0_COPY_VIRT MEM_CHUNK0_COPY_PHYS 379 1.3 fredette 380 1.3 fredette #define MEM_CHUNK1_SIZE (0x140000) 381 1.3 fredette #define MEM_CHUNK1_LOAD_PHYS (0x2c0000) 382 1.3 fredette #define MEM_CHUNK1_LOAD_VIRT (MEM_CHUNK0_LOAD_VIRT + MEM_CHUNK0_SIZE) 383 1.3 fredette #define MEM_CHUNK1_LOAD_VIRT_PROM MEM_CHUNK1_LOAD_PHYS 384 1.3 fredette #define MEM_CHUNK1_COPY_PHYS (MEM_CHUNK0_LOAD_PHYS + MEM_CHUNK0_SIZE) 385 1.3 fredette #define MEM_CHUNK1_COPY_VIRT MEM_CHUNK1_COPY_PHYS 386 1.3 fredette 387 1.3 fredette /* Maps memory for loading. */ 388 1.5.6.1 skrll u_long 389 1.5.6.1 skrll sun2_map_mem_load(void) 390 1.3 fredette { 391 1.3 fredette vaddr_t off; 392 1.3 fredette 393 1.3 fredette /* Map chunk zero for loading. */ 394 1.3 fredette for(off = 0; off < MEM_CHUNK0_SIZE; off += NBSG) 395 1.3 fredette set_segmap(MEM_CHUNK0_LOAD_VIRT + off, 396 1.3 fredette get_segmap(MEM_CHUNK0_LOAD_VIRT_PROM + off)); 397 1.3 fredette 398 1.3 fredette /* Map chunk one for loading. */ 399 1.3 fredette for(off = 0; off < MEM_CHUNK1_SIZE; off += NBSG) 400 1.3 fredette set_segmap(MEM_CHUNK1_LOAD_VIRT + off, 401 1.3 fredette get_segmap(MEM_CHUNK1_LOAD_VIRT_PROM + off)); 402 1.3 fredette 403 1.3 fredette /* Tell our caller where in virtual space to load. */ 404 1.3 fredette return MEM_CHUNK0_LOAD_VIRT; 405 1.3 fredette } 406 1.3 fredette 407 1.3 fredette /* Remaps memory for running. */ 408 1.3 fredette void * 409 1.5.6.1 skrll sun2_map_mem_run(void *entry) 410 1.3 fredette { 411 1.3 fredette vaddr_t off, off_end; 412 1.3 fredette int sme; 413 1.3 fredette u_int pte; 414 1.3 fredette 415 1.3 fredette /* Chunk zero is already mapped and copied. */ 416 1.3 fredette 417 1.3 fredette /* Chunk one needs to be mapped and copied. */ 418 1.3 fredette pte = (get_pte(0) & ~PG_FRAME); 419 1.3 fredette for(off = 0; off < MEM_CHUNK1_SIZE; ) { 420 1.3 fredette 421 1.3 fredette /* 422 1.3 fredette * We use the PMEG immediately before the 423 1.3 fredette * segment we're copying in the PROM virtual 424 1.3 fredette * mapping of the chunk. If this is the first 425 1.3 fredette * segment, this is the PMEG the PROM used to 426 1.3 fredette * map 0x2b8000 virtual to 0x2b8000 physical, 427 1.3 fredette * which I'll assume is unused. For the second 428 1.3 fredette * and subsequent segments, this will be the 429 1.3 fredette * PMEG used to map the previous segment, which 430 1.3 fredette * is now (since we already copied it) unused. 431 1.3 fredette */ 432 1.3 fredette sme = get_segmap((MEM_CHUNK1_LOAD_VIRT_PROM + off) - NBSG); 433 1.3 fredette set_segmap(MEM_CHUNK1_COPY_VIRT + off, sme); 434 1.3 fredette 435 1.3 fredette /* Set the PTEs in this new PMEG. */ 436 1.3 fredette for(off_end = off + NBSG; off < off_end; off += NBPG) 437 1.3 fredette set_pte(MEM_CHUNK1_COPY_VIRT + off, 438 1.3 fredette pte | PA_PGNUM(MEM_CHUNK1_COPY_PHYS + off)); 439 1.3 fredette 440 1.3 fredette /* Copy this segment. */ 441 1.5.6.1 skrll memcpy((caddr_t)(MEM_CHUNK1_COPY_VIRT + (off - NBSG)), 442 1.5.6.1 skrll (caddr_t)(MEM_CHUNK1_LOAD_VIRT + (off - NBSG)), 443 1.5.6.1 skrll NBSG); 444 1.3 fredette } 445 1.3 fredette 446 1.3 fredette /* Tell our caller where in virtual space to enter. */ 447 1.3 fredette return ((caddr_t)entry) - MEM_CHUNK0_LOAD_VIRT; 448 1.3 fredette } 449 1.3 fredette 450 1.5.6.1 skrll void 451 1.5.6.1 skrll sun2_init(void) 452 1.1 fredette { 453 1.1 fredette /* Set the function pointers. */ 454 1.1 fredette dev_mapin_p = dev2_mapin; 455 1.1 fredette dvma_alloc_p = dvma2_alloc; 456 1.1 fredette dvma_free_p = dvma2_free; 457 1.1 fredette dvma_mapin_p = dvma2_mapin; 458 1.1 fredette dvma_mapout_p = dvma2_mapout; 459 1.1 fredette 460 1.1 fredette /* Prepare DVMA segment. */ 461 1.1 fredette dvma2_init(); 462 1.1 fredette } 463
Indexes created Mon Oct 20 11:09:49 GMT 2025