loadfile_machdep.c revision 1.8
1 1.8 he /* $NetBSD: loadfile_machdep.c,v 1.8 2011/05/20 14:49:54 he Exp $ */ 2 1.1 cdi 3 1.1 cdi /*- 4 1.1 cdi * Copyright (c) 2005 The NetBSD Foundation, Inc. 5 1.1 cdi * All rights reserved. 6 1.1 cdi * 7 1.1 cdi * This work is based on the code contributed by Robert Drehmel to the 8 1.1 cdi * FreeBSD project. 9 1.1 cdi * 10 1.1 cdi * Redistribution and use in source and binary forms, with or without 11 1.1 cdi * modification, are permitted provided that the following conditions 12 1.1 cdi * are met: 13 1.1 cdi * 1. Redistributions of source code must retain the above copyright 14 1.1 cdi * notice, this list of conditions and the following disclaimer. 15 1.1 cdi * 2. Redistributions in binary form must reproduce the above copyright 16 1.1 cdi * notice, this list of conditions and the following disclaimer in the 17 1.1 cdi * documentation and/or other materials provided with the distribution. 18 1.1 cdi * 19 1.1 cdi * THIS SOFTWARE IS PROVIDED BY THE NETBSD FOUNDATION, INC. AND CONTRIBUTORS 20 1.1 cdi * ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED 21 1.1 cdi * TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR 22 1.1 cdi * PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE FOUNDATION OR CONTRIBUTORS 23 1.1 cdi * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR 24 1.1 cdi * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF 25 1.1 cdi * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS 26 1.1 cdi * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN 27 1.1 cdi * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) 28 1.1 cdi * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE 29 1.1 cdi * POSSIBILITY OF SUCH DAMAGE. 30 1.1 cdi */ 31 1.1 cdi 32 1.1 cdi #include <lib/libsa/stand.h> 33 1.8 he #include <lib/libkern/libkern.h> 34 1.1 cdi 35 1.1 cdi #include <machine/pte.h> 36 1.1 cdi #include <machine/cpu.h> 37 1.1 cdi #include <machine/ctlreg.h> 38 1.1 cdi #include <machine/vmparam.h> 39 1.1 cdi #include <machine/promlib.h> 40 1.1 cdi 41 1.1 cdi #include "boot.h" 42 1.1 cdi #include "openfirm.h" 43 1.1 cdi 44 1.1 cdi 45 1.1 cdi #define MAXSEGNUM 50 46 1.2 uwe #define hi(val) ((uint32_t)(((val) >> 32) & (uint32_t)-1)) 47 1.2 uwe #define lo(val) ((uint32_t)((val) & (uint32_t)-1)) 48 1.1 cdi 49 1.1 cdi #define roundup2(x, y) (((x)+((y)-1))&(~((y)-1))) 50 1.1 cdi 51 1.1 cdi 52 1.1 cdi typedef int phandle_t; 53 1.1 cdi 54 1.2 uwe extern void itlb_enter(vaddr_t, uint32_t, uint32_t); 55 1.2 uwe extern void dtlb_enter(vaddr_t, uint32_t, uint32_t); 56 1.3 martin extern void dtlb_replace(vaddr_t, uint32_t, uint32_t); 57 1.1 cdi extern vaddr_t itlb_va_to_pa(vaddr_t); 58 1.1 cdi extern vaddr_t dtlb_va_to_pa(vaddr_t); 59 1.1 cdi 60 1.1 cdi static void tlb_init(void); 61 1.1 cdi 62 1.1 cdi static int mmu_mapin(vaddr_t, vsize_t); 63 1.1 cdi static ssize_t mmu_read(int, void *, size_t); 64 1.1 cdi static void* mmu_memcpy(void *, const void *, size_t); 65 1.1 cdi static void* mmu_memset(void *, int, size_t); 66 1.1 cdi static void mmu_freeall(void); 67 1.1 cdi 68 1.1 cdi static int ofw_mapin(vaddr_t, vsize_t); 69 1.1 cdi static ssize_t ofw_read(int, void *, size_t); 70 1.1 cdi static void* ofw_memcpy(void *, const void *, size_t); 71 1.1 cdi static void* ofw_memset(void *, int, size_t); 72 1.1 cdi static void ofw_freeall(void); 73 1.1 cdi 74 1.1 cdi static int nop_mapin(vaddr_t, vsize_t); 75 1.1 cdi static ssize_t nop_read(int, void *, size_t); 76 1.1 cdi static void* nop_memcpy(void *, const void *, size_t); 77 1.1 cdi static void* nop_memset(void *, int, size_t); 78 1.1 cdi static void nop_freeall(void); 79 1.1 cdi 80 1.1 cdi 81 1.1 cdi struct tlb_entry *dtlb_store = 0; 82 1.1 cdi struct tlb_entry *itlb_store = 0; 83 1.1 cdi 84 1.1 cdi int dtlb_slot; 85 1.1 cdi int itlb_slot; 86 1.1 cdi int dtlb_slot_max; 87 1.1 cdi int itlb_slot_max; 88 1.1 cdi 89 1.1 cdi static struct kvamap { 90 1.1 cdi uint64_t start; 91 1.1 cdi uint64_t end; 92 1.1 cdi } kvamap[MAXSEGNUM]; 93 1.1 cdi 94 1.1 cdi static struct memsw { 95 1.1 cdi ssize_t (* read)(int f, void *addr, size_t size); 96 1.1 cdi void* (* memcpy)(void *dst, const void *src, size_t size); 97 1.1 cdi void* (* memset)(void *dst, int c, size_t size); 98 1.1 cdi void (* freeall)(void); 99 1.1 cdi } memswa[] = { 100 1.1 cdi { nop_read, nop_memcpy, nop_memset, nop_freeall }, 101 1.1 cdi { ofw_read, ofw_memcpy, ofw_memset, ofw_freeall }, 102 1.1 cdi { mmu_read, mmu_memcpy, mmu_memset, mmu_freeall } 103 1.1 cdi }; 104 1.1 cdi 105 1.1 cdi static struct memsw *memsw = &memswa[0]; 106 1.1 cdi 107 1.1 cdi 108 1.1 cdi /* 109 1.1 cdi * Check if a memory region is already mapped. Return length and virtual 110 1.1 cdi * address of unmapped sub-region, if any. 111 1.1 cdi */ 112 1.1 cdi static uint64_t 113 1.1 cdi kvamap_extract(vaddr_t va, vsize_t len, vaddr_t *new_va) 114 1.1 cdi { 115 1.1 cdi int i; 116 1.1 cdi 117 1.1 cdi *new_va = va; 118 1.1 cdi for (i = 0; (len > 0) && (i < MAXSEGNUM); i++) { 119 1.1 cdi if (kvamap[i].start == NULL) 120 1.1 cdi break; 121 1.1 cdi if ((kvamap[i].start <= va) && (va < kvamap[i].end)) { 122 1.1 cdi uint64_t va_len = kvamap[i].end - va + kvamap[i].start; 123 1.1 cdi len = (va_len < len) ? len - va_len : 0; 124 1.1 cdi *new_va = kvamap[i].end; 125 1.1 cdi } 126 1.1 cdi } 127 1.1 cdi 128 1.1 cdi return (len); 129 1.1 cdi } 130 1.1 cdi 131 1.1 cdi /* 132 1.1 cdi * Record new kernel mapping. 133 1.1 cdi */ 134 1.1 cdi static void 135 1.1 cdi kvamap_enter(uint64_t va, uint64_t len) 136 1.1 cdi { 137 1.1 cdi int i; 138 1.1 cdi 139 1.1 cdi DPRINTF(("kvamap_enter: %d@%p\n", (int)len, (void*)(u_long)va)); 140 1.1 cdi for (i = 0; (len > 0) && (i < MAXSEGNUM); i++) { 141 1.1 cdi if (kvamap[i].start == NULL) { 142 1.1 cdi kvamap[i].start = va; 143 1.1 cdi kvamap[i].end = va + len; 144 1.1 cdi break; 145 1.1 cdi } 146 1.1 cdi } 147 1.1 cdi 148 1.1 cdi if (i == MAXSEGNUM) { 149 1.1 cdi panic("Too many allocations requested."); 150 1.1 cdi } 151 1.1 cdi } 152 1.1 cdi 153 1.1 cdi /* 154 1.1 cdi * Initialize TLB as required by MMU mapping functions. 155 1.1 cdi */ 156 1.1 cdi static void 157 1.1 cdi tlb_init(void) 158 1.1 cdi { 159 1.1 cdi phandle_t child; 160 1.1 cdi phandle_t root; 161 1.1 cdi char buf[128]; 162 1.1 cdi u_int bootcpu; 163 1.1 cdi u_int cpu; 164 1.1 cdi 165 1.1 cdi if (dtlb_store != NULL) { 166 1.1 cdi return; 167 1.1 cdi } 168 1.1 cdi 169 1.1 cdi bootcpu = get_cpuid(); 170 1.1 cdi 171 1.1 cdi if ( (root = prom_findroot()) == -1) { 172 1.1 cdi panic("tlb_init: prom_findroot()"); 173 1.1 cdi } 174 1.1 cdi 175 1.1 cdi for (child = prom_firstchild(root); child != 0; 176 1.1 cdi child = prom_nextsibling(child)) { 177 1.1 cdi if (child == -1) { 178 1.1 cdi panic("tlb_init: OF_child"); 179 1.1 cdi } 180 1.1 cdi if (_prom_getprop(child, "device_type", buf, sizeof(buf)) > 0 && 181 1.1 cdi strcmp(buf, "cpu") == 0) { 182 1.1 cdi if (_prom_getprop(child, "upa-portid", &cpu, 183 1.1 cdi sizeof(cpu)) == -1 && _prom_getprop(child, "portid", 184 1.1 cdi &cpu, sizeof(cpu)) == -1) 185 1.7 nakayama panic("tlb_init: prom_getprop"); 186 1.1 cdi if (cpu == bootcpu) 187 1.1 cdi break; 188 1.1 cdi } 189 1.1 cdi } 190 1.1 cdi if (cpu != bootcpu) 191 1.7 nakayama panic("tlb_init: no node for bootcpu?!?!"); 192 1.1 cdi if (_prom_getprop(child, "#dtlb-entries", &dtlb_slot_max, 193 1.1 cdi sizeof(dtlb_slot_max)) == -1 || 194 1.1 cdi _prom_getprop(child, "#itlb-entries", &itlb_slot_max, 195 1.1 cdi sizeof(itlb_slot_max)) == -1) 196 1.7 nakayama panic("tlb_init: prom_getprop"); 197 1.1 cdi dtlb_store = alloc(dtlb_slot_max * sizeof(*dtlb_store)); 198 1.1 cdi itlb_store = alloc(itlb_slot_max * sizeof(*itlb_store)); 199 1.1 cdi if (dtlb_store == NULL || itlb_store == NULL) { 200 1.7 nakayama panic("tlb_init: malloc"); 201 1.1 cdi } 202 1.1 cdi 203 1.1 cdi dtlb_slot = itlb_slot = 0; 204 1.1 cdi } 205 1.1 cdi 206 1.1 cdi /* 207 1.1 cdi * Map requested memory region with permanent 4MB pages. 208 1.1 cdi */ 209 1.1 cdi static int 210 1.1 cdi mmu_mapin(vaddr_t rva, vsize_t len) 211 1.1 cdi { 212 1.7 nakayama uint64_t data; 213 1.7 nakayama paddr_t pa; 214 1.7 nakayama vaddr_t va, mva; 215 1.1 cdi 216 1.1 cdi len = roundup2(len + (rva & PAGE_MASK_4M), PAGE_SIZE_4M); 217 1.1 cdi rva &= ~PAGE_MASK_4M; 218 1.1 cdi 219 1.1 cdi tlb_init(); 220 1.7 nakayama for (pa = (paddr_t)-1; len > 0; rva = va) { 221 1.1 cdi if ( (len = kvamap_extract(rva, len, &va)) == 0) { 222 1.1 cdi /* The rest is already mapped */ 223 1.1 cdi break; 224 1.1 cdi } 225 1.1 cdi 226 1.1 cdi if (dtlb_va_to_pa(va) == (u_long)-1 || 227 1.1 cdi itlb_va_to_pa(va) == (u_long)-1) { 228 1.1 cdi /* Allocate a physical page, claim the virtual area */ 229 1.7 nakayama if (pa == (paddr_t)-1) { 230 1.7 nakayama pa = OF_alloc_phys(PAGE_SIZE_4M, PAGE_SIZE_4M); 231 1.7 nakayama if (pa == (paddr_t)-1) 232 1.1 cdi panic("out of memory"); 233 1.7 nakayama mva = OF_claim_virt(va, PAGE_SIZE_4M); 234 1.1 cdi if (mva != va) { 235 1.1 cdi panic("can't claim virtual page " 236 1.1 cdi "(wanted %#lx, got %#lx)", 237 1.1 cdi va, mva); 238 1.1 cdi } 239 1.1 cdi /* The mappings may have changed, be paranoid. */ 240 1.1 cdi continue; 241 1.1 cdi } 242 1.1 cdi 243 1.1 cdi /* 244 1.1 cdi * Actually, we can only allocate two pages less at 245 1.1 cdi * most (depending on the kernel TSB size). 246 1.1 cdi */ 247 1.1 cdi if (dtlb_slot >= dtlb_slot_max) 248 1.1 cdi panic("mmu_mapin: out of dtlb_slots"); 249 1.1 cdi if (itlb_slot >= itlb_slot_max) 250 1.1 cdi panic("mmu_mapin: out of itlb_slots"); 251 1.1 cdi 252 1.7 nakayama DPRINTF(("mmu_mapin: %p:%p.%p\n", va, hi(pa), lo(pa))); 253 1.1 cdi 254 1.1 cdi data = TSB_DATA(0, /* global */ 255 1.1 cdi PGSZ_4M, /* 4mb page */ 256 1.1 cdi pa, /* phys.address */ 257 1.1 cdi 1, /* privileged */ 258 1.1 cdi 1, /* write */ 259 1.1 cdi 1, /* cache */ 260 1.1 cdi 1, /* alias */ 261 1.1 cdi 1, /* valid */ 262 1.1 cdi 0 /* endianness */ 263 1.1 cdi ); 264 1.1 cdi data |= TLB_L | TLB_CV; /* locked, virt.cache */ 265 1.1 cdi 266 1.1 cdi dtlb_store[dtlb_slot].te_pa = pa; 267 1.1 cdi dtlb_store[dtlb_slot].te_va = va; 268 1.1 cdi dtlb_slot++; 269 1.1 cdi dtlb_enter(va, hi(data), lo(data)); 270 1.7 nakayama pa = (paddr_t)-1; 271 1.1 cdi } 272 1.1 cdi 273 1.1 cdi kvamap_enter(va, PAGE_SIZE_4M); 274 1.1 cdi 275 1.1 cdi len -= len > PAGE_SIZE_4M ? PAGE_SIZE_4M : len; 276 1.1 cdi va += PAGE_SIZE_4M; 277 1.1 cdi } 278 1.1 cdi 279 1.7 nakayama if (pa != (paddr_t)-1) { 280 1.1 cdi OF_free_phys(pa, PAGE_SIZE_4M); 281 1.1 cdi } 282 1.1 cdi 283 1.1 cdi return (0); 284 1.1 cdi } 285 1.1 cdi 286 1.1 cdi static ssize_t 287 1.1 cdi mmu_read(int f, void *addr, size_t size) 288 1.1 cdi { 289 1.1 cdi mmu_mapin((vaddr_t)addr, size); 290 1.1 cdi return read(f, addr, size); 291 1.1 cdi } 292 1.1 cdi 293 1.1 cdi static void* 294 1.1 cdi mmu_memcpy(void *dst, const void *src, size_t size) 295 1.1 cdi { 296 1.1 cdi mmu_mapin((vaddr_t)dst, size); 297 1.1 cdi return memcpy(dst, src, size); 298 1.1 cdi } 299 1.1 cdi 300 1.1 cdi static void* 301 1.1 cdi mmu_memset(void *dst, int c, size_t size) 302 1.1 cdi { 303 1.1 cdi mmu_mapin((vaddr_t)dst, size); 304 1.1 cdi return memset(dst, c, size); 305 1.1 cdi } 306 1.1 cdi 307 1.1 cdi static void 308 1.1 cdi mmu_freeall(void) 309 1.1 cdi { 310 1.1 cdi int i; 311 1.1 cdi 312 1.1 cdi dtlb_slot = itlb_slot = 0; 313 1.1 cdi for (i = 0; i < MAXSEGNUM; i++) { 314 1.1 cdi /* XXX return all mappings to PROM and unmap the pages! */ 315 1.1 cdi kvamap[i].start = kvamap[i].end = 0; 316 1.1 cdi } 317 1.1 cdi } 318 1.1 cdi 319 1.1 cdi /* 320 1.1 cdi * Claim requested memory region in OpenFirmware allocation pool. 321 1.1 cdi */ 322 1.1 cdi static int 323 1.1 cdi ofw_mapin(vaddr_t rva, vsize_t len) 324 1.1 cdi { 325 1.1 cdi vaddr_t va; 326 1.1 cdi 327 1.1 cdi len = roundup2(len + (rva & PAGE_MASK_4M), PAGE_SIZE_4M); 328 1.1 cdi rva &= ~PAGE_MASK_4M; 329 1.1 cdi 330 1.1 cdi if ( (len = kvamap_extract(rva, len, &va)) != 0) { 331 1.1 cdi if (OF_claim((void *)(long)va, len, PAGE_SIZE_4M) == (void*)-1){ 332 1.1 cdi panic("ofw_mapin: Cannot claim memory."); 333 1.1 cdi } 334 1.1 cdi kvamap_enter(va, len); 335 1.1 cdi } 336 1.1 cdi 337 1.1 cdi return (0); 338 1.1 cdi } 339 1.1 cdi 340 1.1 cdi static ssize_t 341 1.1 cdi ofw_read(int f, void *addr, size_t size) 342 1.1 cdi { 343 1.1 cdi ofw_mapin((vaddr_t)addr, size); 344 1.1 cdi return read(f, addr, size); 345 1.1 cdi } 346 1.1 cdi 347 1.1 cdi static void* 348 1.1 cdi ofw_memcpy(void *dst, const void *src, size_t size) 349 1.1 cdi { 350 1.1 cdi ofw_mapin((vaddr_t)dst, size); 351 1.1 cdi return memcpy(dst, src, size); 352 1.1 cdi } 353 1.1 cdi 354 1.1 cdi static void* 355 1.1 cdi ofw_memset(void *dst, int c, size_t size) 356 1.1 cdi { 357 1.1 cdi ofw_mapin((vaddr_t)dst, size); 358 1.1 cdi return memset(dst, c, size); 359 1.1 cdi } 360 1.1 cdi 361 1.1 cdi static void 362 1.1 cdi ofw_freeall(void) 363 1.1 cdi { 364 1.1 cdi int i; 365 1.1 cdi 366 1.1 cdi dtlb_slot = itlb_slot = 0; 367 1.1 cdi for (i = 0; i < MAXSEGNUM; i++) { 368 1.1 cdi OF_release((void*)(u_long)kvamap[i].start, 369 1.1 cdi (u_int)(kvamap[i].end - kvamap[i].start)); 370 1.1 cdi kvamap[i].start = kvamap[i].end = 0; 371 1.1 cdi } 372 1.1 cdi } 373 1.1 cdi 374 1.1 cdi /* 375 1.1 cdi * NOP implementation exists solely for kernel header loading sake. Here 376 1.1 cdi * we use alloc() interface to allocate memory and avoid doing some dangerous 377 1.1 cdi * things. 378 1.1 cdi */ 379 1.1 cdi static ssize_t 380 1.1 cdi nop_read(int f, void *addr, size_t size) 381 1.1 cdi { 382 1.1 cdi return read(f, addr, size); 383 1.1 cdi } 384 1.1 cdi 385 1.1 cdi static void* 386 1.1 cdi nop_memcpy(void *dst, const void *src, size_t size) 387 1.1 cdi { 388 1.1 cdi /* 389 1.1 cdi * Real NOP to make LOAD_HDR work: loadfile_elfXX copies ELF headers 390 1.1 cdi * right after the highest kernel address which will not be mapped with 391 1.1 cdi * nop_XXX operations. 392 1.1 cdi */ 393 1.1 cdi return (dst); 394 1.1 cdi } 395 1.1 cdi 396 1.1 cdi static void* 397 1.1 cdi nop_memset(void *dst, int c, size_t size) 398 1.1 cdi { 399 1.1 cdi return memset(dst, c, size); 400 1.1 cdi } 401 1.1 cdi 402 1.1 cdi static void 403 1.1 cdi nop_freeall(void) 404 1.1 cdi { } 405 1.1 cdi 406 1.1 cdi /* 407 1.1 cdi * loadfile() hooks. 408 1.1 cdi */ 409 1.1 cdi ssize_t 410 1.1 cdi sparc64_read(int f, void *addr, size_t size) 411 1.1 cdi { 412 1.1 cdi return (*memsw->read)(f, addr, size); 413 1.1 cdi } 414 1.1 cdi 415 1.1 cdi void* 416 1.1 cdi sparc64_memcpy(void *dst, const void *src, size_t size) 417 1.1 cdi { 418 1.1 cdi return (*memsw->memcpy)(dst, src, size); 419 1.1 cdi } 420 1.1 cdi 421 1.1 cdi void* 422 1.1 cdi sparc64_memset(void *dst, int c, size_t size) 423 1.1 cdi { 424 1.1 cdi return (*memsw->memset)(dst, c, size); 425 1.1 cdi } 426 1.1 cdi 427 1.1 cdi /* 428 1.3 martin * Remove write permissions from text mappings in the dTLB. 429 1.3 martin * Add entries in the iTLB. 430 1.3 martin */ 431 1.3 martin void 432 1.3 martin sparc64_finalize_tlb(u_long data_va) 433 1.3 martin { 434 1.3 martin int i; 435 1.3 martin int64_t data; 436 1.6 martin bool writable_text = false; 437 1.3 martin 438 1.3 martin for (i = 0; i < dtlb_slot; i++) { 439 1.6 martin if (dtlb_store[i].te_va >= data_va) { 440 1.6 martin /* 441 1.6 martin * If (for whatever reason) the start of the 442 1.6 martin * writable section is right at the start of 443 1.6 martin * the kernel, we need to map it into the ITLB 444 1.6 martin * nevertheless (and don't make it readonly). 445 1.6 martin */ 446 1.6 martin if (i == 0 && dtlb_store[i].te_va == data_va) 447 1.6 martin writable_text = true; 448 1.6 martin else 449 1.6 martin continue; 450 1.6 martin } 451 1.3 martin 452 1.3 martin data = TSB_DATA(0, /* global */ 453 1.3 martin PGSZ_4M, /* 4mb page */ 454 1.3 martin dtlb_store[i].te_pa, /* phys.address */ 455 1.3 martin 1, /* privileged */ 456 1.3 martin 0, /* write */ 457 1.3 martin 1, /* cache */ 458 1.3 martin 1, /* alias */ 459 1.3 martin 1, /* valid */ 460 1.3 martin 0 /* endianness */ 461 1.3 martin ); 462 1.3 martin data |= TLB_L | TLB_CV; /* locked, virt.cache */ 463 1.6 martin if (!writable_text) 464 1.6 martin dtlb_replace(dtlb_store[i].te_va, hi(data), lo(data)); 465 1.3 martin itlb_store[itlb_slot] = dtlb_store[i]; 466 1.3 martin itlb_slot++; 467 1.3 martin itlb_enter(dtlb_store[i].te_va, hi(data), lo(data)); 468 1.3 martin } 469 1.6 martin if (writable_text) 470 1.6 martin printf("WARNING: kernel text mapped writable!\n"); 471 1.3 martin } 472 1.3 martin 473 1.3 martin /* 474 1.1 cdi * Record kernel mappings in bootinfo structure. 475 1.1 cdi */ 476 1.1 cdi void 477 1.1 cdi sparc64_bi_add(void) 478 1.1 cdi { 479 1.1 cdi int i; 480 1.1 cdi int itlb_size, dtlb_size; 481 1.1 cdi struct btinfo_count bi_count; 482 1.1 cdi struct btinfo_tlb *bi_itlb, *bi_dtlb; 483 1.1 cdi 484 1.1 cdi bi_count.count = itlb_slot; 485 1.1 cdi bi_add(&bi_count, BTINFO_ITLB_SLOTS, sizeof(bi_count)); 486 1.1 cdi bi_count.count = dtlb_slot; 487 1.1 cdi bi_add(&bi_count, BTINFO_DTLB_SLOTS, sizeof(bi_count)); 488 1.1 cdi 489 1.1 cdi itlb_size = sizeof(*bi_itlb) + sizeof(struct tlb_entry) * itlb_slot; 490 1.1 cdi dtlb_size = sizeof(*bi_dtlb) + sizeof(struct tlb_entry) * dtlb_slot; 491 1.1 cdi 492 1.1 cdi bi_itlb = alloc(itlb_size); 493 1.1 cdi bi_dtlb = alloc(dtlb_size); 494 1.1 cdi 495 1.1 cdi if ((bi_itlb == NULL) || (bi_dtlb == NULL)) { 496 1.1 cdi panic("Out of memory in sparc64_bi_add.\n"); 497 1.1 cdi } 498 1.1 cdi 499 1.1 cdi for (i = 0; i < itlb_slot; i++) { 500 1.1 cdi bi_itlb->tlb[i].te_va = itlb_store[i].te_va; 501 1.1 cdi bi_itlb->tlb[i].te_pa = itlb_store[i].te_pa; 502 1.1 cdi } 503 1.1 cdi bi_add(bi_itlb, BTINFO_ITLB, itlb_size); 504 1.1 cdi 505 1.1 cdi for (i = 0; i < dtlb_slot; i++) { 506 1.1 cdi bi_dtlb->tlb[i].te_va = dtlb_store[i].te_va; 507 1.1 cdi bi_dtlb->tlb[i].te_pa = dtlb_store[i].te_pa; 508 1.1 cdi } 509 1.1 cdi bi_add(bi_dtlb, BTINFO_DTLB, dtlb_size); 510 1.1 cdi } 511 1.1 cdi 512 1.1 cdi /* 513 1.1 cdi * Choose kernel image mapping strategy: 514 1.1 cdi * 515 1.1 cdi * LOADFILE_NOP_ALLOCATOR To load kernel image headers 516 1.1 cdi * LOADFILE_OFW_ALLOCATOR To map the kernel by OpenFirmware means 517 1.1 cdi * LOADFILE_MMU_ALLOCATOR To use permanent 4MB mappings 518 1.1 cdi */ 519 1.1 cdi void 520 1.1 cdi loadfile_set_allocator(int type) 521 1.1 cdi { 522 1.1 cdi if (type >= (sizeof(memswa) / sizeof(struct memsw))) { 523 1.1 cdi panic("Bad allocator request.\n"); 524 1.1 cdi } 525 1.1 cdi 526 1.1 cdi /* 527 1.1 cdi * Release all memory claimed by previous allocator and schedule 528 1.1 cdi * another allocator for succeeding memory allocation calls. 529 1.1 cdi */ 530 1.1 cdi (*memsw->freeall)(); 531 1.1 cdi memsw = &memswa[type]; 532 1.1 cdi } 533
Indexes created Thu Sep 25 16:09:42 GMT 2025