1 2/*--------------------------------------------------------------------*/ 3/*--- x86- and AMD64-specific definitions. cg-x86-amd64.c ---*/ 4/*--------------------------------------------------------------------*/ 5 6/* 7 This file is part of Cachegrind, a Valgrind tool for cache 8 profiling programs. 9 10 Copyright (C) 2002-2012 Nicholas Nethercote 11 njn@valgrind.org 12 13 This program is free software; you can redistribute it and/or 14 modify it under the terms of the GNU General Public License as 15 published by the Free Software Foundation; either version 2 of the 16 License, or (at your option) any later version. 17 18 This program is distributed in the hope that it will be useful, but 19 WITHOUT ANY WARRANTY; without even the implied warranty of 20 MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU 21 General Public License for more details. 22 23 You should have received a copy of the GNU General Public License 24 along with this program; if not, write to the Free Software 25 Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 26 02111-1307, USA. 27 28 The GNU General Public License is contained in the file COPYING. 29*/ 30 31#if defined(VGA_x86) || defined(VGA_amd64) 32 33#include "pub_tool_basics.h" 34#include "pub_tool_cpuid.h" 35#include "pub_tool_libcbase.h" 36#include "pub_tool_libcassert.h" 37#include "pub_tool_libcprint.h" 38 39#include "cg_arch.h" 40 41// All CPUID info taken from sandpile.org/ia32/cpuid.htm */ 42// Probably only works for Intel and AMD chips, and probably only for some of 43// them. 44 45static void micro_ops_warn(Int actual_size, Int used_size, Int line_size) 46{ 47 VG_(dmsg)("warning: Pentium 4 with %d KB micro-op instruction trace cache\n", 48 actual_size); 49 VG_(dmsg)(" Simulating a %d KB I-cache with %d B lines\n", 50 used_size, line_size); 51} 52 53/* Intel method is truly wretched. We have to do an insane indexing into an 54 * array of pre-defined configurations for various parts of the memory 55 * hierarchy. 56 * According to Intel Processor Identification, App Note 485. 57 * 58 * If a L3 cache is found, then data for it rather than the L2 59 * is returned via *LLc. 60 */ 61static 62Int Intel_cache_info(Int level, cache_t* I1c, cache_t* D1c, cache_t* LLc) 63{ 64 Int cpuid1_eax; 65 Int cpuid1_ignore; 66 Int family; 67 Int model; 68 UChar info[16]; 69 Int i, j, trials; 70 Bool L2_found = False; 71 /* If we see L3 cache info, copy it into L3c. Then, at the end, 72 copy it into *LLc. Hence if a L3 cache is specified, *LLc will 73 eventually contain a description of it rather than the L2 cache. 74 The use of the L3c intermediary makes this process independent 75 of the order in which the cache specifications appear in 76 info[]. */ 77 Bool L3_found = False; 78 cache_t L3c = { 0, 0, 0 }; 79 80 if (level < 2) { 81 VG_(dmsg)("warning: CPUID level < 2 for Intel processor (%d)\n", level); 82 return -1; 83 } 84 85 /* family/model needed to distinguish code reuse (currently 0x49) */ 86 VG_(cpuid)(1, 0, &cpuid1_eax, &cpuid1_ignore, 87 &cpuid1_ignore, &cpuid1_ignore); 88 family = (((cpuid1_eax >> 20) & 0xff) << 4) + ((cpuid1_eax >> 8) & 0xf); 89 model = (((cpuid1_eax >> 16) & 0xf) << 4) + ((cpuid1_eax >> 4) & 0xf); 90 91 VG_(cpuid)(2, 0, (Int*)&info[0], (Int*)&info[4], 92 (Int*)&info[8], (Int*)&info[12]); 93 trials = info[0] - 1; /* AL register - bits 0..7 of %eax */ 94 info[0] = 0x0; /* reset AL */ 95 96 if (0 != trials) { 97 VG_(dmsg)("warning: non-zero CPUID trials for Intel processor (%d)\n", 98 trials); 99 return -1; 100 } 101 102 for (i = 0; i < 16; i++) { 103 104 switch (info[i]) { 105 106 case 0x0: /* ignore zeros */ 107 break; 108 109 /* TLB info, ignore */ 110 case 0x01: case 0x02: case 0x03: case 0x04: case 0x05: 111 case 0x0b: 112 case 0x4f: case 0x50: case 0x51: case 0x52: case 0x55: 113 case 0x56: case 0x57: case 0x59: 114 case 0x5a: case 0x5b: case 0x5c: case 0x5d: 115 case 0x76: 116 case 0xb0: case 0xb1: case 0xb2: 117 case 0xb3: case 0xb4: case 0xba: case 0xc0: 118 case 0xca: 119 break; 120 121 case 0x06: *I1c = (cache_t) { 8, 4, 32 }; break; 122 case 0x08: *I1c = (cache_t) { 16, 4, 32 }; break; 123 case 0x09: *I1c = (cache_t) { 32, 4, 64 }; break; 124 case 0x30: *I1c = (cache_t) { 32, 8, 64 }; break; 125 126 case 0x0a: *D1c = (cache_t) { 8, 2, 32 }; break; 127 case 0x0c: *D1c = (cache_t) { 16, 4, 32 }; break; 128 case 0x0d: *D1c = (cache_t) { 16, 4, 64 }; break; 129 case 0x0e: *D1c = (cache_t) { 24, 6, 64 }; break; 130 case 0x2c: *D1c = (cache_t) { 32, 8, 64 }; break; 131 132 /* IA-64 info -- panic! */ 133 case 0x10: case 0x15: case 0x1a: 134 case 0x88: case 0x89: case 0x8a: case 0x8d: 135 case 0x90: case 0x96: case 0x9b: 136 VG_(tool_panic)("IA-64 cache detected?!"); 137 138 /* L3 cache info. */ 139 case 0x22: L3c = (cache_t) { 512, 4, 64 }; L3_found = True; break; 140 case 0x23: L3c = (cache_t) { 1024, 8, 64 }; L3_found = True; break; 141 case 0x25: L3c = (cache_t) { 2048, 8, 64 }; L3_found = True; break; 142 case 0x29: L3c = (cache_t) { 4096, 8, 64 }; L3_found = True; break; 143 case 0x46: L3c = (cache_t) { 4096, 4, 64 }; L3_found = True; break; 144 case 0x47: L3c = (cache_t) { 8192, 8, 64 }; L3_found = True; break; 145 case 0x4a: L3c = (cache_t) { 6144, 12, 64 }; L3_found = True; break; 146 case 0x4b: L3c = (cache_t) { 8192, 16, 64 }; L3_found = True; break; 147 case 0x4c: L3c = (cache_t) { 12288, 12, 64 }; L3_found = True; break; 148 case 0x4d: L3c = (cache_t) { 16384, 16, 64 }; L3_found = True; break; 149 case 0xd0: L3c = (cache_t) { 512, 4, 64 }; L3_found = True; break; 150 case 0xd1: L3c = (cache_t) { 1024, 4, 64 }; L3_found = True; break; 151 case 0xd2: L3c = (cache_t) { 2048, 4, 64 }; L3_found = True; break; 152 case 0xd6: L3c = (cache_t) { 1024, 8, 64 }; L3_found = True; break; 153 case 0xd7: L3c = (cache_t) { 2048, 8, 64 }; L3_found = True; break; 154 case 0xd8: L3c = (cache_t) { 4096, 8, 64 }; L3_found = True; break; 155 case 0xdc: L3c = (cache_t) { 1536, 12, 64 }; L3_found = True; break; 156 case 0xdd: L3c = (cache_t) { 3072, 12, 64 }; L3_found = True; break; 157 case 0xde: L3c = (cache_t) { 6144, 12, 64 }; L3_found = True; break; 158 case 0xe2: L3c = (cache_t) { 2048, 16, 64 }; L3_found = True; break; 159 case 0xe3: L3c = (cache_t) { 4096, 16, 64 }; L3_found = True; break; 160 case 0xe4: L3c = (cache_t) { 8192, 16, 64 }; L3_found = True; break; 161 case 0xea: L3c = (cache_t) { 12288, 24, 64 }; L3_found = True; break; 162 case 0xeb: L3c = (cache_t) { 18432, 24, 64 }; L3_found = True; break; 163 case 0xec: L3c = (cache_t) { 24576, 24, 64 }; L3_found = True; break; 164 165 /* Described as "MLC" in Intel documentation */ 166 case 0x21: *LLc = (cache_t) { 256, 8, 64 }; L2_found = True; break; 167 168 /* These are sectored, whatever that means */ 169 case 0x39: *LLc = (cache_t) { 128, 4, 64 }; L2_found = True; break; 170 case 0x3c: *LLc = (cache_t) { 256, 4, 64 }; L2_found = True; break; 171 172 /* If a P6 core, this means "no L2 cache". 173 If a P4 core, this means "no L3 cache". 174 We don't know what core it is, so don't issue a warning. To detect 175 a missing L2 cache, we use 'L2_found'. */ 176 case 0x40: 177 break; 178 179 case 0x41: *LLc = (cache_t) { 128, 4, 32 }; L2_found = True; break; 180 case 0x42: *LLc = (cache_t) { 256, 4, 32 }; L2_found = True; break; 181 case 0x43: *LLc = (cache_t) { 512, 4, 32 }; L2_found = True; break; 182 case 0x44: *LLc = (cache_t) { 1024, 4, 32 }; L2_found = True; break; 183 case 0x45: *LLc = (cache_t) { 2048, 4, 32 }; L2_found = True; break; 184 case 0x48: *LLc = (cache_t) { 3072, 12, 64 }; L2_found = True; break; 185 case 0x4e: *LLc = (cache_t) { 6144, 24, 64 }; L2_found = True; break; 186 case 0x49: 187 if (family == 15 && model == 6) { 188 /* On Xeon MP (family F, model 6), this is for L3 */ 189 L3c = (cache_t) { 4096, 16, 64 }; L3_found = True; 190 } else { 191 *LLc = (cache_t) { 4096, 16, 64 }; L2_found = True; 192 } 193 break; 194 195 /* These are sectored, whatever that means */ 196 case 0x60: *D1c = (cache_t) { 16, 8, 64 }; break; /* sectored */ 197 case 0x66: *D1c = (cache_t) { 8, 4, 64 }; break; /* sectored */ 198 case 0x67: *D1c = (cache_t) { 16, 4, 64 }; break; /* sectored */ 199 case 0x68: *D1c = (cache_t) { 32, 4, 64 }; break; /* sectored */ 200 201 /* HACK ALERT: Instruction trace cache -- capacity is micro-ops based. 202 * conversion to byte size is a total guess; treat the 12K and 16K 203 * cases the same since the cache byte size must be a power of two for 204 * everything to work!. Also guessing 32 bytes for the line size... 205 */ 206 case 0x70: /* 12K micro-ops, 8-way */ 207 *I1c = (cache_t) { 16, 8, 32 }; 208 micro_ops_warn(12, 16, 32); 209 break; 210 case 0x71: /* 16K micro-ops, 8-way */ 211 *I1c = (cache_t) { 16, 8, 32 }; 212 micro_ops_warn(16, 16, 32); 213 break; 214 case 0x72: /* 32K micro-ops, 8-way */ 215 *I1c = (cache_t) { 32, 8, 32 }; 216 micro_ops_warn(32, 32, 32); 217 break; 218 219 /* not sectored, whatever that might mean */ 220 case 0x78: *LLc = (cache_t) { 1024, 4, 64 }; L2_found = True; break; 221 222 /* These are sectored, whatever that means */ 223 case 0x79: *LLc = (cache_t) { 128, 8, 64 }; L2_found = True; break; 224 case 0x7a: *LLc = (cache_t) { 256, 8, 64 }; L2_found = True; break; 225 case 0x7b: *LLc = (cache_t) { 512, 8, 64 }; L2_found = True; break; 226 case 0x7c: *LLc = (cache_t) { 1024, 8, 64 }; L2_found = True; break; 227 case 0x7d: *LLc = (cache_t) { 2048, 8, 64 }; L2_found = True; break; 228 case 0x7e: *LLc = (cache_t) { 256, 8, 128 }; L2_found = True; break; 229 case 0x7f: *LLc = (cache_t) { 512, 2, 64 }; L2_found = True; break; 230 case 0x80: *LLc = (cache_t) { 512, 8, 64 }; L2_found = True; break; 231 case 0x81: *LLc = (cache_t) { 128, 8, 32 }; L2_found = True; break; 232 case 0x82: *LLc = (cache_t) { 256, 8, 32 }; L2_found = True; break; 233 case 0x83: *LLc = (cache_t) { 512, 8, 32 }; L2_found = True; break; 234 case 0x84: *LLc = (cache_t) { 1024, 8, 32 }; L2_found = True; break; 235 case 0x85: *LLc = (cache_t) { 2048, 8, 32 }; L2_found = True; break; 236 case 0x86: *LLc = (cache_t) { 512, 4, 64 }; L2_found = True; break; 237 case 0x87: *LLc = (cache_t) { 1024, 8, 64 }; L2_found = True; break; 238 239 /* Ignore prefetch information */ 240 case 0xf0: case 0xf1: 241 break; 242 243 case 0xff: 244 j = 0; 245 VG_(cpuid)(4, j++, (Int*)&info[0], (Int*)&info[4], 246 (Int*)&info[8], (Int*)&info[12]); 247 248 while ((info[0] & 0x1f) != 0) { 249 UInt assoc = ((*(UInt *)&info[4] >> 22) & 0x3ff) + 1; 250 UInt parts = ((*(UInt *)&info[4] >> 12) & 0x3ff) + 1; 251 UInt line_size = (*(UInt *)&info[4] & 0x7ff) + 1; 252 UInt sets = *(UInt *)&info[8] + 1; 253 cache_t c; 254 255 c.size = assoc * parts * line_size * sets / 1024; 256 c.assoc = assoc; 257 c.line_size = line_size; 258 259 switch ((info[0] & 0xe0) >> 5) 260 { 261 case 1: 262 switch (info[0] & 0x1f) 263 { 264 case 1: *D1c = c; break; 265 case 2: *I1c = c; break; 266 case 3: VG_(dmsg)("warning: L1 unified cache ignored\n"); break; 267 default: VG_(dmsg)("warning: L1 cache of unknown type ignored\n"); break; 268 } 269 break; 270 case 2: 271 switch (info[0] & 0x1f) 272 { 273 case 1: VG_(dmsg)("warning: L2 data cache ignored\n"); break; 274 case 2: VG_(dmsg)("warning: L2 instruction cache ignored\n"); break; 275 case 3: *LLc = c; L2_found = True; break; 276 default: VG_(dmsg)("warning: L2 cache of unknown type ignored\n"); break; 277 } 278 break; 279 case 3: 280 switch (info[0] & 0x1f) 281 { 282 case 1: VG_(dmsg)("warning: L3 data cache ignored\n"); break; 283 case 2: VG_(dmsg)("warning: L3 instruction cache ignored\n"); break; 284 case 3: L3c = c; L3_found = True; break; 285 default: VG_(dmsg)("warning: L3 cache of unknown type ignored\n"); break; 286 } 287 break; 288 default: 289 VG_(dmsg)("warning: L%u cache ignored\n", (info[0] & 0xe0) >> 5); 290 break; 291 } 292 293 VG_(cpuid)(4, j++, (Int*)&info[0], (Int*)&info[4], 294 (Int*)&info[8], (Int*)&info[12]); 295 } 296 break; 297 298 default: 299 VG_(dmsg)("warning: Unknown Intel cache config value (0x%x), ignoring\n", 300 info[i]); 301 break; 302 } 303 } 304 305 /* If we found a L3 cache, throw away the L2 data and use the L3's instead. */ 306 if (L3_found) { 307 VG_(dmsg)("warning: L3 cache found, using its data for the LL simulation.\n"); 308 *LLc = L3c; 309 L2_found = True; 310 } 311 312 if (!L2_found) 313 VG_(dmsg)("warning: L2 cache not installed, ignore LL results.\n"); 314 315 return 0; 316} 317 318/* AMD method is straightforward, just extract appropriate bits from the 319 * result registers. 320 * 321 * Bits, for D1 and I1: 322 * 31..24 data L1 cache size in KBs 323 * 23..16 data L1 cache associativity (FFh=full) 324 * 15.. 8 data L1 cache lines per tag 325 * 7.. 0 data L1 cache line size in bytes 326 * 327 * Bits, for L2: 328 * 31..16 unified L2 cache size in KBs 329 * 15..12 unified L2 cache associativity (0=off, FFh=full) 330 * 11.. 8 unified L2 cache lines per tag 331 * 7.. 0 unified L2 cache line size in bytes 332 * 333 * #3 The AMD K7 processor's L2 cache must be configured prior to relying 334 * upon this information. (Whatever that means -- njn) 335 * 336 * Also, according to Cyrille Chepelov, Duron stepping A0 processors (model 337 * 0x630) have a bug and misreport their L2 size as 1KB (it's really 64KB), 338 * so we detect that. 339 * 340 * Returns 0 on success, non-zero on failure. As with the Intel code 341 * above, if a L3 cache is found, then data for it rather than the L2 342 * is returned via *LLc. 343 */ 344 345/* A small helper */ 346static Int decode_AMD_cache_L2_L3_assoc ( Int bits_15_12 ) 347{ 348 /* Decode a L2/L3 associativity indication. It is encoded 349 differently from the I1/D1 associativity. Returns 1 350 (direct-map) as a safe but suboptimal result for unknown 351 encodings. */ 352 switch (bits_15_12 & 0xF) { 353 case 1: return 1; case 2: return 2; 354 case 4: return 4; case 6: return 8; 355 case 8: return 16; case 0xA: return 32; 356 case 0xB: return 48; case 0xC: return 64; 357 case 0xD: return 96; case 0xE: return 128; 358 case 0xF: /* fully associative */ 359 case 0: /* L2/L3 cache or TLB is disabled */ 360 default: 361 return 1; 362 } 363} 364 365static 366Int AMD_cache_info(cache_t* I1c, cache_t* D1c, cache_t* LLc) 367{ 368 UInt ext_level; 369 UInt dummy, model; 370 UInt I1i, D1i, L2i, L3i; 371 372 VG_(cpuid)(0x80000000, 0, &ext_level, &dummy, &dummy, &dummy); 373 374 if (0 == (ext_level & 0x80000000) || ext_level < 0x80000006) { 375 VG_(dmsg)("warning: ext_level < 0x80000006 for AMD processor (0x%x)\n", 376 ext_level); 377 return -1; 378 } 379 380 VG_(cpuid)(0x80000005, 0, &dummy, &dummy, &D1i, &I1i); 381 VG_(cpuid)(0x80000006, 0, &dummy, &dummy, &L2i, &L3i); 382 383 VG_(cpuid)(0x1, 0, &model, &dummy, &dummy, &dummy); 384 385 /* Check for Duron bug */ 386 if (model == 0x630) { 387 VG_(dmsg)("warning: Buggy Duron stepping A0. Assuming L2 size=65536 bytes\n"); 388 L2i = (64 << 16) | (L2i & 0xffff); 389 } 390 391 D1c->size = (D1i >> 24) & 0xff; 392 D1c->assoc = (D1i >> 16) & 0xff; 393 D1c->line_size = (D1i >> 0) & 0xff; 394 395 I1c->size = (I1i >> 24) & 0xff; 396 I1c->assoc = (I1i >> 16) & 0xff; 397 I1c->line_size = (I1i >> 0) & 0xff; 398 399 LLc->size = (L2i >> 16) & 0xffff; /* Nb: different bits used for L2 */ 400 LLc->assoc = decode_AMD_cache_L2_L3_assoc((L2i >> 12) & 0xf); 401 LLc->line_size = (L2i >> 0) & 0xff; 402 403 if (((L3i >> 18) & 0x3fff) > 0) { 404 /* There's an L3 cache. Replace *LLc contents with this info. */ 405 /* NB: the test in the if is "if L3 size > 0 ". I don't know if 406 this is the right way to test presence-vs-absence of L3. I 407 can't see any guidance on this in the AMD documentation. */ 408 LLc->size = ((L3i >> 18) & 0x3fff) * 512; 409 LLc->assoc = decode_AMD_cache_L2_L3_assoc((L3i >> 12) & 0xf); 410 LLc->line_size = (L3i >> 0) & 0xff; 411 VG_(dmsg)("warning: L3 cache found, using its data for the L2 simulation.\n"); 412 } 413 414 return 0; 415} 416 417static 418Int get_caches_from_CPUID(cache_t* I1c, cache_t* D1c, cache_t* LLc) 419{ 420 Int level, ret; 421 Char vendor_id[13]; 422 423 if (!VG_(has_cpuid)()) { 424 VG_(dmsg)("CPUID instruction not supported\n"); 425 return -1; 426 } 427 428 VG_(cpuid)(0, 0, &level, (int*)&vendor_id[0], 429 (int*)&vendor_id[8], (int*)&vendor_id[4]); 430 vendor_id[12] = '\0'; 431 432 if (0 == level) { 433 VG_(dmsg)("CPUID level is 0, early Pentium?\n"); 434 return -1; 435 } 436 437 /* Only handling Intel and AMD chips... no Cyrix, Transmeta, etc */ 438 if (0 == VG_(strcmp)(vendor_id, "GenuineIntel")) { 439 ret = Intel_cache_info(level, I1c, D1c, LLc); 440 441 } else if (0 == VG_(strcmp)(vendor_id, "AuthenticAMD")) { 442 ret = AMD_cache_info(I1c, D1c, LLc); 443 444 } else if (0 == VG_(strcmp)(vendor_id, "CentaurHauls")) { 445 /* Total kludge. Pretend to be a VIA Nehemiah. */ 446 D1c->size = 64; 447 D1c->assoc = 16; 448 D1c->line_size = 16; 449 I1c->size = 64; 450 I1c->assoc = 4; 451 I1c->line_size = 16; 452 LLc->size = 64; 453 LLc->assoc = 16; 454 LLc->line_size = 16; 455 ret = 0; 456 457 } else { 458 VG_(dmsg)("CPU vendor ID not recognised (%s)\n", vendor_id); 459 return -1; 460 } 461 462 /* Successful! Convert sizes from KB to bytes */ 463 I1c->size *= 1024; 464 D1c->size *= 1024; 465 LLc->size *= 1024; 466 467 /* If the LL cache config isn't something the simulation functions 468 can handle, try to adjust it so it is. Caches are characterised 469 by (total size T, line size L, associativity A), and then we 470 have 471 472 number of sets S = T / (L * A) 473 474 The required constraints are: 475 476 * L must be a power of 2, but it always is in practice, so 477 no problem there 478 479 * A can be any value >= 1 480 481 * T can be any value, but .. 482 483 * S must be a power of 2. 484 485 That sometimes gives a problem. For example, some Core iX based 486 Intel CPUs have T = 12MB, A = 16, L = 64, which gives 12288 487 sets. The "fix" in this case is to increase the associativity 488 by 50% to 24, which reduces the number of sets to 8192, making 489 it a power of 2. That's what the following code does (handing 490 the "3/2 rescaling case".) We might need to deal with other 491 ratios later (5/4 ?). 492 493 The "fix" is "justified" (cough, cough) by alleging that 494 increases of associativity above about 4 have very little effect 495 on the actual miss rate. It would be far more inaccurate to 496 fudge this by changing the size of the simulated cache -- 497 changing the associativity is a much better option. 498 */ 499 if (LLc->size > 0 && LLc->assoc > 0 && LLc->line_size > 0) { 500 Long nSets = (Long)LLc->size / (Long)(LLc->line_size * LLc->assoc); 501 if (/* stay sane */ 502 nSets >= 4 503 /* nSets is not a power of 2 */ 504 && VG_(log2_64)( (ULong)nSets ) == -1 505 /* nSets is 50% above a power of 2 */ 506 && VG_(log2_64)( (ULong)((2 * nSets) / (Long)3) ) != -1 507 /* associativity can be increased by exactly 50% */ 508 && (LLc->assoc % 2) == 0 509 ) { 510 /* # sets is 1.5 * a power of two, but the associativity is 511 even, so we can increase that up by 50% and implicitly 512 scale the # sets down accordingly. */ 513 Int new_assoc = LLc->assoc + (LLc->assoc / 2); 514 VG_(dmsg)("warning: pretending that LL cache has associativity" 515 " %d instead of actual %d\n", new_assoc, LLc->assoc); 516 LLc->assoc = new_assoc; 517 } 518 } 519 520 return ret; 521} 522 523 524void VG_(configure_caches)(cache_t* I1c, cache_t* D1c, cache_t* LLc, 525 Bool all_caches_clo_defined) 526{ 527 Int res; 528 529 // Set caches to default. 530 *I1c = (cache_t) { 65536, 2, 64 }; 531 *D1c = (cache_t) { 65536, 2, 64 }; 532 *LLc = (cache_t) { 262144, 8, 64 }; 533 534 // Then replace with any info we can get from CPUID. 535 res = get_caches_from_CPUID(I1c, D1c, LLc); 536 537 // Warn if CPUID failed and config not completely specified from cmd line. 538 if (res != 0 && !all_caches_clo_defined) { 539 VG_(dmsg)("Warning: Couldn't auto-detect cache config, using one " 540 "or more defaults \n"); 541 } 542} 543 544#endif // defined(VGA_x86) || defined(VGA_amd64) 545 546/*--------------------------------------------------------------------*/ 547/*--- end ---*/ 548/*--------------------------------------------------------------------*/ 549