spdmem.c revision 1.15
1 1.15 msaitoh /* $NetBSD: spdmem.c,v 1.15 2015/12/05 06:36:12 msaitoh Exp $ */ 2 1.1 pgoyette 3 1.1 pgoyette /* 4 1.1 pgoyette * Copyright (c) 2007 Nicolas Joly 5 1.1 pgoyette * Copyright (c) 2007 Paul Goyette 6 1.1 pgoyette * Copyright (c) 2007 Tobias Nygren 7 1.1 pgoyette * All rights reserved. 8 1.1 pgoyette * 9 1.1 pgoyette * Redistribution and use in source and binary forms, with or without 10 1.1 pgoyette * modification, are permitted provided that the following conditions 11 1.1 pgoyette * are met: 12 1.1 pgoyette * 1. Redistributions of source code must retain the above copyright 13 1.1 pgoyette * notice, this list of conditions and the following disclaimer. 14 1.1 pgoyette * 2. Redistributions in binary form must reproduce the above copyright 15 1.1 pgoyette * notice, this list of conditions and the following disclaimer in the 16 1.1 pgoyette * documentation and/or other materials provided with the distribution. 17 1.1 pgoyette * 3. The name of the author may not be used to endorse or promote products 18 1.1 pgoyette * derived from this software without specific prior written permission. 19 1.1 pgoyette * 20 1.1 pgoyette * THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS 21 1.1 pgoyette * ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED 22 1.1 pgoyette * TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR 23 1.1 pgoyette * PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE FOUNDATION OR CONTRIBUTORS 24 1.1 pgoyette * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR 25 1.1 pgoyette * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF 26 1.1 pgoyette * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS 27 1.1 pgoyette * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN 28 1.1 pgoyette * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) 29 1.1 pgoyette * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE 30 1.1 pgoyette * POSSIBILITY OF SUCH DAMAGE. 31 1.1 pgoyette */ 32 1.1 pgoyette 33 1.1 pgoyette /* 34 1.1 pgoyette * Serial Presence Detect (SPD) memory identification 35 1.1 pgoyette */ 36 1.1 pgoyette 37 1.1 pgoyette #include <sys/cdefs.h> 38 1.15 msaitoh __KERNEL_RCSID(0, "$NetBSD: spdmem.c,v 1.15 2015/12/05 06:36:12 msaitoh Exp $"); 39 1.1 pgoyette 40 1.1 pgoyette #include <sys/param.h> 41 1.1 pgoyette #include <sys/device.h> 42 1.1 pgoyette #include <sys/endian.h> 43 1.1 pgoyette #include <sys/sysctl.h> 44 1.1 pgoyette #include <machine/bswap.h> 45 1.1 pgoyette 46 1.1 pgoyette #include <dev/i2c/i2cvar.h> 47 1.1 pgoyette #include <dev/ic/spdmemreg.h> 48 1.1 pgoyette #include <dev/ic/spdmemvar.h> 49 1.1 pgoyette 50 1.1 pgoyette /* Routines for decoding spd data */ 51 1.1 pgoyette static void decode_edofpm(const struct sysctlnode *, device_t, struct spdmem *); 52 1.1 pgoyette static void decode_rom(const struct sysctlnode *, device_t, struct spdmem *); 53 1.1 pgoyette static void decode_sdram(const struct sysctlnode *, device_t, struct spdmem *, 54 1.1 pgoyette int); 55 1.1 pgoyette static void decode_ddr(const struct sysctlnode *, device_t, struct spdmem *); 56 1.1 pgoyette static void decode_ddr2(const struct sysctlnode *, device_t, struct spdmem *); 57 1.1 pgoyette static void decode_ddr3(const struct sysctlnode *, device_t, struct spdmem *); 58 1.13 pgoyette static void decode_ddr4(const struct sysctlnode *, device_t, struct spdmem *); 59 1.1 pgoyette static void decode_fbdimm(const struct sysctlnode *, device_t, struct spdmem *); 60 1.1 pgoyette 61 1.3 pgoyette static void decode_size_speed(device_t, const struct sysctlnode *, 62 1.3 pgoyette int, int, int, int, bool, const char *, int); 63 1.1 pgoyette static void decode_voltage_refresh(device_t, struct spdmem *); 64 1.1 pgoyette 65 1.1 pgoyette #define IS_RAMBUS_TYPE (s->sm_len < 4) 66 1.1 pgoyette 67 1.12 matt static const char* const spdmem_basic_types[] = { 68 1.1 pgoyette "unknown", 69 1.1 pgoyette "FPM", 70 1.1 pgoyette "EDO", 71 1.1 pgoyette "Pipelined Nibble", 72 1.1 pgoyette "SDRAM", 73 1.1 pgoyette "ROM", 74 1.1 pgoyette "DDR SGRAM", 75 1.1 pgoyette "DDR SDRAM", 76 1.1 pgoyette "DDR2 SDRAM", 77 1.1 pgoyette "DDR2 SDRAM FB", 78 1.1 pgoyette "DDR2 SDRAM FB Probe", 79 1.12 matt "DDR3 SDRAM", 80 1.11 msaitoh "DDR4 SDRAM" 81 1.1 pgoyette }; 82 1.1 pgoyette 83 1.13 pgoyette static const char* const spdmem_ddr4_module_types[] = { 84 1.13 pgoyette "DDR4 Extended", 85 1.13 pgoyette "DDR4 RDIMM", 86 1.13 pgoyette "DDR4 UDIMM", 87 1.13 pgoyette "DDR4 SO-DIMM", 88 1.13 pgoyette "DDR4 Load-Reduced DIMM", 89 1.13 pgoyette "DDR4 Mini-RDIMM", 90 1.13 pgoyette "DDR4 Mini-UDIMM", 91 1.13 pgoyette "DDR4 Reserved", 92 1.13 pgoyette "DDR4 72Bit SO-RDIMM", 93 1.13 pgoyette "DDR4 72Bit SO-UDIMM", 94 1.13 pgoyette "DDR4 Undefined", 95 1.13 pgoyette "DDR4 Reserved", 96 1.13 pgoyette "DDR4 16Bit SO-DIMM", 97 1.13 pgoyette "DDR4 32Bit SO-DIMM", 98 1.13 pgoyette "DDR4 Reserved", 99 1.13 pgoyette "DDR4 Undefined" 100 1.13 pgoyette }; 101 1.13 pgoyette 102 1.12 matt static const char* const spdmem_superset_types[] = { 103 1.1 pgoyette "unknown", 104 1.1 pgoyette "ESDRAM", 105 1.1 pgoyette "DDR ESDRAM", 106 1.1 pgoyette "PEM EDO", 107 1.1 pgoyette "PEM SDRAM" 108 1.1 pgoyette }; 109 1.1 pgoyette 110 1.12 matt static const char* const spdmem_voltage_types[] = { 111 1.1 pgoyette "TTL (5V tolerant)", 112 1.1 pgoyette "LvTTL (not 5V tolerant)", 113 1.1 pgoyette "HSTL 1.5V", 114 1.1 pgoyette "SSTL 3.3V", 115 1.1 pgoyette "SSTL 2.5V", 116 1.1 pgoyette "SSTL 1.8V" 117 1.1 pgoyette }; 118 1.1 pgoyette 119 1.12 matt static const char* const spdmem_refresh_types[] = { 120 1.1 pgoyette "15.625us", 121 1.1 pgoyette "3.9us", 122 1.1 pgoyette "7.8us", 123 1.1 pgoyette "31.3us", 124 1.1 pgoyette "62.5us", 125 1.1 pgoyette "125us" 126 1.1 pgoyette }; 127 1.1 pgoyette 128 1.12 matt static const char* const spdmem_parity_types[] = { 129 1.1 pgoyette "no parity or ECC", 130 1.1 pgoyette "data parity", 131 1.1 pgoyette "data ECC", 132 1.1 pgoyette "data parity and ECC", 133 1.1 pgoyette "cmd/addr parity", 134 1.1 pgoyette "cmd/addr/data parity", 135 1.1 pgoyette "cmd/addr parity, data ECC", 136 1.1 pgoyette "cmd/addr/data parity, data ECC" 137 1.1 pgoyette }; 138 1.1 pgoyette 139 1.13 pgoyette int spd_rom_sizes[] = { 0, 128, 256, 384, 512 }; 140 1.13 pgoyette 141 1.13 pgoyette 142 1.1 pgoyette /* Cycle time fractional values (units of .001 ns) for DDR2 SDRAM */ 143 1.1 pgoyette static const uint16_t spdmem_cycle_frac[] = { 144 1.1 pgoyette 0, 100, 200, 300, 400, 500, 600, 700, 800, 900, 145 1.1 pgoyette 250, 333, 667, 750, 999, 999 146 1.1 pgoyette }; 147 1.1 pgoyette 148 1.1 pgoyette /* Format string for timing info */ 149 1.5 wiz #define LATENCY "tAA-tRCD-tRP-tRAS: %d-%d-%d-%d\n" 150 1.1 pgoyette 151 1.1 pgoyette /* CRC functions used for certain memory types */ 152 1.1 pgoyette 153 1.1 pgoyette static uint16_t spdcrc16 (struct spdmem_softc *sc, int count) 154 1.1 pgoyette { 155 1.1 pgoyette uint16_t crc; 156 1.1 pgoyette int i, j; 157 1.1 pgoyette uint8_t val; 158 1.1 pgoyette crc = 0; 159 1.1 pgoyette for (j = 0; j <= count; j++) { 160 1.1 pgoyette val = (sc->sc_read)(sc, j); 161 1.1 pgoyette crc = crc ^ val << 8; 162 1.1 pgoyette for (i = 0; i < 8; ++i) 163 1.1 pgoyette if (crc & 0x8000) 164 1.1 pgoyette crc = crc << 1 ^ 0x1021; 165 1.1 pgoyette else 166 1.1 pgoyette crc = crc << 1; 167 1.1 pgoyette } 168 1.1 pgoyette return (crc & 0xFFFF); 169 1.1 pgoyette } 170 1.1 pgoyette 171 1.1 pgoyette int 172 1.1 pgoyette spdmem_common_probe(struct spdmem_softc *sc) 173 1.1 pgoyette { 174 1.1 pgoyette int cksum = 0; 175 1.1 pgoyette uint8_t i, val, spd_type; 176 1.1 pgoyette int spd_len, spd_crc_cover; 177 1.1 pgoyette uint16_t crc_calc, crc_spd; 178 1.1 pgoyette 179 1.1 pgoyette spd_type = (sc->sc_read)(sc, 2); 180 1.1 pgoyette 181 1.1 pgoyette /* For older memory types, validate the checksum over 1st 63 bytes */ 182 1.1 pgoyette if (spd_type <= SPDMEM_MEMTYPE_DDR2SDRAM) { 183 1.1 pgoyette for (i = 0; i < 63; i++) 184 1.1 pgoyette cksum += (sc->sc_read)(sc, i); 185 1.1 pgoyette 186 1.1 pgoyette val = (sc->sc_read)(sc, 63); 187 1.1 pgoyette 188 1.1 pgoyette if (cksum == 0 || (cksum & 0xff) != val) { 189 1.1 pgoyette aprint_debug("spd checksum failed, calc = 0x%02x, " 190 1.1 pgoyette "spd = 0x%02x\n", cksum, val); 191 1.1 pgoyette return 0; 192 1.1 pgoyette } else 193 1.1 pgoyette return 1; 194 1.1 pgoyette } 195 1.1 pgoyette 196 1.1 pgoyette /* For DDR3 and FBDIMM, verify the CRC */ 197 1.1 pgoyette else if (spd_type <= SPDMEM_MEMTYPE_DDR3SDRAM) { 198 1.1 pgoyette spd_len = (sc->sc_read)(sc, 0); 199 1.2 pgoyette if (spd_len & SPDMEM_SPDCRC_116) 200 1.1 pgoyette spd_crc_cover = 116; 201 1.1 pgoyette else 202 1.1 pgoyette spd_crc_cover = 125; 203 1.1 pgoyette switch (spd_len & SPDMEM_SPDLEN_MASK) { 204 1.1 pgoyette case SPDMEM_SPDLEN_128: 205 1.1 pgoyette spd_len = 128; 206 1.1 pgoyette break; 207 1.1 pgoyette case SPDMEM_SPDLEN_176: 208 1.1 pgoyette spd_len = 176; 209 1.1 pgoyette break; 210 1.1 pgoyette case SPDMEM_SPDLEN_256: 211 1.1 pgoyette spd_len = 256; 212 1.1 pgoyette break; 213 1.1 pgoyette default: 214 1.1 pgoyette return 0; 215 1.1 pgoyette } 216 1.1 pgoyette if (spd_crc_cover > spd_len) 217 1.1 pgoyette return 0; 218 1.1 pgoyette crc_calc = spdcrc16(sc, spd_crc_cover); 219 1.1 pgoyette crc_spd = (sc->sc_read)(sc, 127) << 8; 220 1.1 pgoyette crc_spd |= (sc->sc_read)(sc, 126); 221 1.1 pgoyette if (crc_calc != crc_spd) { 222 1.1 pgoyette aprint_debug("crc16 failed, covers %d bytes, " 223 1.1 pgoyette "calc = 0x%04x, spd = 0x%04x\n", 224 1.1 pgoyette spd_crc_cover, crc_calc, crc_spd); 225 1.1 pgoyette return 0; 226 1.1 pgoyette } 227 1.1 pgoyette return 1; 228 1.13 pgoyette } else if (spd_type == SPDMEM_MEMTYPE_DDR4SDRAM) { 229 1.13 pgoyette spd_len = (sc->sc_read)(sc, 0) & 0x0f; 230 1.13 pgoyette if ((unsigned int)spd_len > __arraycount(spd_rom_sizes)) 231 1.13 pgoyette return 0; 232 1.13 pgoyette spd_len = spd_rom_sizes[spd_len]; 233 1.15 msaitoh spd_crc_cover=125; /* For byte 0 to 125 */ 234 1.13 pgoyette if (spd_crc_cover > spd_len) 235 1.13 pgoyette return 0; 236 1.13 pgoyette crc_calc = spdcrc16(sc, spd_crc_cover); 237 1.13 pgoyette crc_spd = (sc->sc_read)(sc, 127) << 8; 238 1.13 pgoyette crc_spd |= (sc->sc_read)(sc, 126); 239 1.13 pgoyette if (crc_calc != crc_spd) { 240 1.13 pgoyette aprint_debug("crc16 failed, covers %d bytes, " 241 1.13 pgoyette "calc = 0x%04x, spd = 0x%04x\n", 242 1.13 pgoyette spd_crc_cover, crc_calc, crc_spd); 243 1.13 pgoyette return 0; 244 1.13 pgoyette } 245 1.13 pgoyette /* 246 1.13 pgoyette * We probably could also verify the CRC for the other 247 1.13 pgoyette * "pages" of SPD data in blocks 1 and 2, but we'll do 248 1.13 pgoyette * it some other time. 249 1.13 pgoyette */ 250 1.13 pgoyette return 1; 251 1.13 pgoyette } else 252 1.13 pgoyette return 0; 253 1.1 pgoyette 254 1.1 pgoyette /* For unrecognized memory types, don't match at all */ 255 1.1 pgoyette return 0; 256 1.1 pgoyette } 257 1.1 pgoyette 258 1.1 pgoyette void 259 1.1 pgoyette spdmem_common_attach(struct spdmem_softc *sc, device_t self) 260 1.1 pgoyette { 261 1.1 pgoyette struct spdmem *s = &(sc->sc_spd_data); 262 1.1 pgoyette const char *type; 263 1.1 pgoyette const char *rambus_rev = "Reserved"; 264 1.1 pgoyette int dimm_size; 265 1.3 pgoyette unsigned int i, spd_len, spd_size; 266 1.1 pgoyette const struct sysctlnode *node = NULL; 267 1.1 pgoyette 268 1.1 pgoyette s->sm_len = (sc->sc_read)(sc, 0); 269 1.1 pgoyette s->sm_size = (sc->sc_read)(sc, 1); 270 1.1 pgoyette s->sm_type = (sc->sc_read)(sc, 2); 271 1.1 pgoyette 272 1.13 pgoyette if (s->sm_type == SPDMEM_MEMTYPE_DDR4SDRAM) { 273 1.13 pgoyette /* 274 1.13 pgoyette * An even newer encoding with one byte holding both 275 1.13 pgoyette * the used-size and capacity values 276 1.13 pgoyette */ 277 1.13 pgoyette spd_len = s->sm_len & 0x0f; 278 1.13 pgoyette spd_size = (s->sm_len >> 4) & 0x07; 279 1.13 pgoyette 280 1.13 pgoyette spd_len = spd_rom_sizes[spd_len]; 281 1.13 pgoyette spd_size *= 512; 282 1.13 pgoyette 283 1.13 pgoyette } else if (s->sm_type >= SPDMEM_MEMTYPE_FBDIMM) { 284 1.13 pgoyette /* 285 1.13 pgoyette * FBDIMM and DDR3 (and probably all newer) have a different 286 1.13 pgoyette * encoding of the SPD EEPROM used/total sizes 287 1.13 pgoyette */ 288 1.1 pgoyette spd_size = 64 << (s->sm_len & SPDMEM_SPDSIZE_MASK); 289 1.1 pgoyette switch (s->sm_len & SPDMEM_SPDLEN_MASK) { 290 1.1 pgoyette case SPDMEM_SPDLEN_128: 291 1.1 pgoyette spd_len = 128; 292 1.1 pgoyette break; 293 1.1 pgoyette case SPDMEM_SPDLEN_176: 294 1.1 pgoyette spd_len = 176; 295 1.1 pgoyette break; 296 1.1 pgoyette case SPDMEM_SPDLEN_256: 297 1.1 pgoyette spd_len = 256; 298 1.1 pgoyette break; 299 1.1 pgoyette default: 300 1.1 pgoyette spd_len = 64; 301 1.1 pgoyette break; 302 1.1 pgoyette } 303 1.1 pgoyette } else { 304 1.1 pgoyette spd_size = 1 << s->sm_size; 305 1.1 pgoyette spd_len = s->sm_len; 306 1.1 pgoyette if (spd_len < 64) 307 1.1 pgoyette spd_len = 64; 308 1.1 pgoyette } 309 1.1 pgoyette if (spd_len > spd_size) 310 1.1 pgoyette spd_len = spd_size; 311 1.1 pgoyette if (spd_len > sizeof(struct spdmem)) 312 1.1 pgoyette spd_len = sizeof(struct spdmem); 313 1.1 pgoyette for (i = 3; i < spd_len; i++) 314 1.1 pgoyette ((uint8_t *)s)[i] = (sc->sc_read)(sc, i); 315 1.1 pgoyette 316 1.1 pgoyette /* 317 1.1 pgoyette * Setup our sysctl subtree, hw.spdmemN 318 1.1 pgoyette */ 319 1.3 pgoyette sc->sc_sysctl_log = NULL; 320 1.9 pooka sysctl_createv(&sc->sc_sysctl_log, 0, NULL, &node, 321 1.9 pooka 0, CTLTYPE_NODE, 322 1.9 pooka device_xname(self), NULL, NULL, 0, NULL, 0, 323 1.9 pooka CTL_HW, CTL_CREATE, CTL_EOL); 324 1.1 pgoyette if (node != NULL && spd_len != 0) 325 1.3 pgoyette sysctl_createv(&sc->sc_sysctl_log, 0, NULL, NULL, 326 1.1 pgoyette 0, 327 1.1 pgoyette CTLTYPE_STRUCT, "spd_data", 328 1.1 pgoyette SYSCTL_DESCR("raw spd data"), NULL, 329 1.1 pgoyette 0, s, spd_len, 330 1.1 pgoyette CTL_HW, node->sysctl_num, CTL_CREATE, CTL_EOL); 331 1.1 pgoyette 332 1.1 pgoyette /* 333 1.1 pgoyette * Decode and print key SPD contents 334 1.1 pgoyette */ 335 1.1 pgoyette if (IS_RAMBUS_TYPE) { 336 1.1 pgoyette if (s->sm_type == SPDMEM_MEMTYPE_RAMBUS) 337 1.1 pgoyette type = "Rambus"; 338 1.1 pgoyette else if (s->sm_type == SPDMEM_MEMTYPE_DIRECTRAMBUS) 339 1.1 pgoyette type = "Direct Rambus"; 340 1.1 pgoyette else 341 1.1 pgoyette type = "Rambus (unknown)"; 342 1.1 pgoyette 343 1.1 pgoyette switch (s->sm_len) { 344 1.1 pgoyette case 0: 345 1.1 pgoyette rambus_rev = "Invalid"; 346 1.1 pgoyette break; 347 1.1 pgoyette case 1: 348 1.1 pgoyette rambus_rev = "0.7"; 349 1.1 pgoyette break; 350 1.1 pgoyette case 2: 351 1.1 pgoyette rambus_rev = "1.0"; 352 1.1 pgoyette break; 353 1.1 pgoyette default: 354 1.1 pgoyette rambus_rev = "Reserved"; 355 1.1 pgoyette break; 356 1.1 pgoyette } 357 1.1 pgoyette } else { 358 1.1 pgoyette if (s->sm_type < __arraycount(spdmem_basic_types)) 359 1.1 pgoyette type = spdmem_basic_types[s->sm_type]; 360 1.1 pgoyette else 361 1.1 pgoyette type = "unknown memory type"; 362 1.1 pgoyette 363 1.1 pgoyette if (s->sm_type == SPDMEM_MEMTYPE_EDO && 364 1.1 pgoyette s->sm_fpm.fpm_superset == SPDMEM_SUPERSET_EDO_PEM) 365 1.1 pgoyette type = spdmem_superset_types[SPDMEM_SUPERSET_EDO_PEM]; 366 1.1 pgoyette if (s->sm_type == SPDMEM_MEMTYPE_SDRAM && 367 1.1 pgoyette s->sm_sdr.sdr_superset == SPDMEM_SUPERSET_SDRAM_PEM) 368 1.1 pgoyette type = spdmem_superset_types[SPDMEM_SUPERSET_SDRAM_PEM]; 369 1.1 pgoyette if (s->sm_type == SPDMEM_MEMTYPE_DDRSDRAM && 370 1.1 pgoyette s->sm_ddr.ddr_superset == SPDMEM_SUPERSET_DDR_ESDRAM) 371 1.1 pgoyette type = 372 1.1 pgoyette spdmem_superset_types[SPDMEM_SUPERSET_DDR_ESDRAM]; 373 1.1 pgoyette if (s->sm_type == SPDMEM_MEMTYPE_SDRAM && 374 1.1 pgoyette s->sm_sdr.sdr_superset == SPDMEM_SUPERSET_ESDRAM) { 375 1.1 pgoyette type = spdmem_superset_types[SPDMEM_SUPERSET_ESDRAM]; 376 1.1 pgoyette } 377 1.13 pgoyette if (s->sm_type == SPDMEM_MEMTYPE_DDR4SDRAM && 378 1.13 pgoyette s->sm_ddr4.ddr4_mod_type < 379 1.13 pgoyette __arraycount(spdmem_ddr4_module_types)) { 380 1.13 pgoyette type = spdmem_ddr4_module_types[s->sm_ddr4.ddr4_mod_type]; 381 1.13 pgoyette } 382 1.1 pgoyette } 383 1.1 pgoyette 384 1.1 pgoyette strlcpy(sc->sc_type, type, SPDMEM_TYPE_MAXLEN); 385 1.1 pgoyette if (node != NULL) 386 1.3 pgoyette sysctl_createv(&sc->sc_sysctl_log, 0, NULL, NULL, 387 1.1 pgoyette 0, 388 1.1 pgoyette CTLTYPE_STRING, "mem_type", 389 1.1 pgoyette SYSCTL_DESCR("memory module type"), NULL, 390 1.1 pgoyette 0, sc->sc_type, 0, 391 1.1 pgoyette CTL_HW, node->sysctl_num, CTL_CREATE, CTL_EOL); 392 1.1 pgoyette 393 1.1 pgoyette if (IS_RAMBUS_TYPE) { 394 1.8 soren aprint_naive("\n"); 395 1.8 soren aprint_normal("\n"); 396 1.8 soren aprint_normal_dev(self, "%s, SPD Revision %s", type, rambus_rev); 397 1.1 pgoyette dimm_size = 1 << (s->sm_rdr.rdr_rows + s->sm_rdr.rdr_cols - 13); 398 1.1 pgoyette if (dimm_size >= 1024) 399 1.1 pgoyette aprint_normal(", %dGB\n", dimm_size / 1024); 400 1.1 pgoyette else 401 1.1 pgoyette aprint_normal(", %dMB\n", dimm_size); 402 1.1 pgoyette 403 1.1 pgoyette /* No further decode for RAMBUS memory */ 404 1.1 pgoyette return; 405 1.1 pgoyette } 406 1.1 pgoyette switch (s->sm_type) { 407 1.1 pgoyette case SPDMEM_MEMTYPE_EDO: 408 1.1 pgoyette case SPDMEM_MEMTYPE_FPM: 409 1.1 pgoyette decode_edofpm(node, self, s); 410 1.1 pgoyette break; 411 1.1 pgoyette case SPDMEM_MEMTYPE_ROM: 412 1.1 pgoyette decode_rom(node, self, s); 413 1.1 pgoyette break; 414 1.1 pgoyette case SPDMEM_MEMTYPE_SDRAM: 415 1.1 pgoyette decode_sdram(node, self, s, spd_len); 416 1.1 pgoyette break; 417 1.1 pgoyette case SPDMEM_MEMTYPE_DDRSDRAM: 418 1.1 pgoyette decode_ddr(node, self, s); 419 1.1 pgoyette break; 420 1.1 pgoyette case SPDMEM_MEMTYPE_DDR2SDRAM: 421 1.1 pgoyette decode_ddr2(node, self, s); 422 1.1 pgoyette break; 423 1.1 pgoyette case SPDMEM_MEMTYPE_DDR3SDRAM: 424 1.1 pgoyette decode_ddr3(node, self, s); 425 1.1 pgoyette break; 426 1.1 pgoyette case SPDMEM_MEMTYPE_FBDIMM: 427 1.1 pgoyette case SPDMEM_MEMTYPE_FBDIMM_PROBE: 428 1.1 pgoyette decode_fbdimm(node, self, s); 429 1.1 pgoyette break; 430 1.13 pgoyette case SPDMEM_MEMTYPE_DDR4SDRAM: 431 1.13 pgoyette decode_ddr4(node, self, s); 432 1.13 pgoyette break; 433 1.1 pgoyette } 434 1.8 soren 435 1.8 soren /* Dump SPD */ 436 1.8 soren for (i = 0; i < spd_len; i += 16) { 437 1.8 soren unsigned int j, k; 438 1.8 soren aprint_debug_dev(self, "0x%02x:", i); 439 1.8 soren k = (spd_len > (i + 16)) ? i + 16 : spd_len; 440 1.8 soren for (j = i; j < k; j++) 441 1.8 soren aprint_debug(" %02x", ((uint8_t *)s)[j]); 442 1.8 soren aprint_debug("\n"); 443 1.8 soren } 444 1.1 pgoyette } 445 1.1 pgoyette 446 1.3 pgoyette int 447 1.3 pgoyette spdmem_common_detach(struct spdmem_softc *sc, device_t self) 448 1.3 pgoyette { 449 1.3 pgoyette sysctl_teardown(&sc->sc_sysctl_log); 450 1.3 pgoyette 451 1.3 pgoyette return 0; 452 1.3 pgoyette } 453 1.3 pgoyette 454 1.1 pgoyette static void 455 1.3 pgoyette decode_size_speed(device_t self, const struct sysctlnode *node, 456 1.3 pgoyette int dimm_size, int cycle_time, int d_clk, int bits, 457 1.3 pgoyette bool round, const char *ddr_type_string, int speed) 458 1.1 pgoyette { 459 1.1 pgoyette int p_clk; 460 1.7 chs struct spdmem_softc *sc = device_private(self); 461 1.1 pgoyette 462 1.1 pgoyette if (dimm_size < 1024) 463 1.1 pgoyette aprint_normal("%dMB", dimm_size); 464 1.1 pgoyette else 465 1.1 pgoyette aprint_normal("%dGB", dimm_size / 1024); 466 1.1 pgoyette if (node != NULL) 467 1.3 pgoyette sysctl_createv(&sc->sc_sysctl_log, 0, NULL, NULL, 468 1.1 pgoyette CTLFLAG_IMMEDIATE, 469 1.1 pgoyette CTLTYPE_INT, "size", 470 1.1 pgoyette SYSCTL_DESCR("module size in MB"), NULL, 471 1.1 pgoyette dimm_size, NULL, 0, 472 1.1 pgoyette CTL_HW, node->sysctl_num, CTL_CREATE, CTL_EOL); 473 1.1 pgoyette 474 1.1 pgoyette if (cycle_time == 0) { 475 1.1 pgoyette aprint_normal("\n"); 476 1.1 pgoyette return; 477 1.1 pgoyette } 478 1.1 pgoyette 479 1.1 pgoyette /* 480 1.1 pgoyette * Calculate p_clk first, since for DDR3 we need maximum significance. 481 1.1 pgoyette * DDR3 rating is not rounded to a multiple of 100. This results in 482 1.1 pgoyette * cycle_time of 1.5ns displayed as PC3-10666. 483 1.1 pgoyette * 484 1.1 pgoyette * For SDRAM, the speed is provided by the caller so we use it. 485 1.1 pgoyette */ 486 1.1 pgoyette d_clk *= 1000 * 1000; 487 1.1 pgoyette if (speed) 488 1.1 pgoyette p_clk = speed; 489 1.1 pgoyette else 490 1.1 pgoyette p_clk = (d_clk * bits) / 8 / cycle_time; 491 1.1 pgoyette d_clk = ((d_clk + cycle_time / 2) ) / cycle_time; 492 1.1 pgoyette if (round) { 493 1.1 pgoyette if ((p_clk % 100) >= 50) 494 1.1 pgoyette p_clk += 50; 495 1.1 pgoyette p_clk -= p_clk % 100; 496 1.1 pgoyette } 497 1.1 pgoyette aprint_normal(", %dMHz (%s-%d)\n", 498 1.1 pgoyette d_clk, ddr_type_string, p_clk); 499 1.1 pgoyette if (node != NULL) 500 1.3 pgoyette sysctl_createv(&sc->sc_sysctl_log, 0, NULL, NULL, 501 1.1 pgoyette CTLFLAG_IMMEDIATE, 502 1.1 pgoyette CTLTYPE_INT, "speed", 503 1.1 pgoyette SYSCTL_DESCR("memory speed in MHz"), 504 1.1 pgoyette NULL, d_clk, NULL, 0, 505 1.1 pgoyette CTL_HW, node->sysctl_num, CTL_CREATE, CTL_EOL); 506 1.1 pgoyette } 507 1.1 pgoyette 508 1.1 pgoyette static void 509 1.1 pgoyette decode_voltage_refresh(device_t self, struct spdmem *s) 510 1.1 pgoyette { 511 1.1 pgoyette const char *voltage, *refresh; 512 1.1 pgoyette 513 1.1 pgoyette if (s->sm_voltage < __arraycount(spdmem_voltage_types)) 514 1.1 pgoyette voltage = spdmem_voltage_types[s->sm_voltage]; 515 1.1 pgoyette else 516 1.1 pgoyette voltage = "unknown"; 517 1.1 pgoyette 518 1.1 pgoyette if (s->sm_refresh < __arraycount(spdmem_refresh_types)) 519 1.1 pgoyette refresh = spdmem_refresh_types[s->sm_refresh]; 520 1.1 pgoyette else 521 1.1 pgoyette refresh = "unknown"; 522 1.1 pgoyette 523 1.1 pgoyette aprint_verbose_dev(self, "voltage %s, refresh time %s%s\n", 524 1.1 pgoyette voltage, refresh, 525 1.1 pgoyette s->sm_selfrefresh?" (self-refreshing)":""); 526 1.1 pgoyette } 527 1.1 pgoyette 528 1.1 pgoyette static void 529 1.1 pgoyette decode_edofpm(const struct sysctlnode *node, device_t self, struct spdmem *s) { 530 1.8 soren aprint_naive("\n"); 531 1.8 soren aprint_normal("\n"); 532 1.8 soren aprint_normal_dev(self, "%s", spdmem_basic_types[s->sm_type]); 533 1.8 soren 534 1.1 pgoyette aprint_normal("\n"); 535 1.1 pgoyette aprint_verbose_dev(self, 536 1.1 pgoyette "%d rows, %d cols, %d banks, %dns tRAC, %dns tCAC\n", 537 1.1 pgoyette s->sm_fpm.fpm_rows, s->sm_fpm.fpm_cols, s->sm_fpm.fpm_banks, 538 1.1 pgoyette s->sm_fpm.fpm_tRAC, s->sm_fpm.fpm_tCAC); 539 1.1 pgoyette } 540 1.1 pgoyette 541 1.1 pgoyette static void 542 1.1 pgoyette decode_rom(const struct sysctlnode *node, device_t self, struct spdmem *s) { 543 1.8 soren aprint_naive("\n"); 544 1.8 soren aprint_normal("\n"); 545 1.8 soren aprint_normal_dev(self, "%s", spdmem_basic_types[s->sm_type]); 546 1.8 soren 547 1.1 pgoyette aprint_normal("\n"); 548 1.1 pgoyette aprint_verbose_dev(self, "%d rows, %d cols, %d banks\n", 549 1.1 pgoyette s->sm_rom.rom_rows, s->sm_rom.rom_cols, s->sm_rom.rom_banks); 550 1.1 pgoyette } 551 1.1 pgoyette 552 1.1 pgoyette static void 553 1.1 pgoyette decode_sdram(const struct sysctlnode *node, device_t self, struct spdmem *s, 554 1.1 pgoyette int spd_len) { 555 1.1 pgoyette int dimm_size, cycle_time, bits, tAA, i, speed, freq; 556 1.1 pgoyette 557 1.8 soren aprint_naive("\n"); 558 1.8 soren aprint_normal("\n"); 559 1.8 soren aprint_normal_dev(self, "%s", spdmem_basic_types[s->sm_type]); 560 1.8 soren 561 1.1 pgoyette aprint_normal("%s, %s, ", 562 1.1 pgoyette (s->sm_sdr.sdr_mod_attrs & SPDMEM_SDR_MASK_REG)? 563 1.1 pgoyette " (registered)":"", 564 1.1 pgoyette (s->sm_config < __arraycount(spdmem_parity_types))? 565 1.1 pgoyette spdmem_parity_types[s->sm_config]:"invalid parity"); 566 1.1 pgoyette 567 1.1 pgoyette dimm_size = 1 << (s->sm_sdr.sdr_rows + s->sm_sdr.sdr_cols - 17); 568 1.1 pgoyette dimm_size *= s->sm_sdr.sdr_banks * s->sm_sdr.sdr_banks_per_chip; 569 1.1 pgoyette 570 1.1 pgoyette cycle_time = s->sm_sdr.sdr_cycle_whole * 1000 + 571 1.1 pgoyette s->sm_sdr.sdr_cycle_tenths * 100; 572 1.1 pgoyette bits = le16toh(s->sm_sdr.sdr_datawidth); 573 1.1 pgoyette if (s->sm_config == 1 || s->sm_config == 2) 574 1.1 pgoyette bits -= 8; 575 1.1 pgoyette 576 1.1 pgoyette /* Calculate speed here - from OpenBSD */ 577 1.1 pgoyette if (spd_len >= 128) 578 1.1 pgoyette freq = ((uint8_t *)s)[126]; 579 1.1 pgoyette else 580 1.1 pgoyette freq = 0; 581 1.1 pgoyette switch (freq) { 582 1.1 pgoyette /* 583 1.1 pgoyette * Must check cycle time since some PC-133 DIMMs 584 1.1 pgoyette * actually report PC-100 585 1.1 pgoyette */ 586 1.1 pgoyette case 100: 587 1.1 pgoyette case 133: 588 1.1 pgoyette if (cycle_time < 8000) 589 1.1 pgoyette speed = 133; 590 1.1 pgoyette else 591 1.1 pgoyette speed = 100; 592 1.1 pgoyette break; 593 1.1 pgoyette case 0x66: /* Legacy DIMMs use _hex_ 66! */ 594 1.1 pgoyette default: 595 1.1 pgoyette speed = 66; 596 1.1 pgoyette } 597 1.3 pgoyette decode_size_speed(self, node, dimm_size, cycle_time, 1, bits, FALSE, 598 1.3 pgoyette "PC", speed); 599 1.1 pgoyette 600 1.1 pgoyette aprint_verbose_dev(self, 601 1.1 pgoyette "%d rows, %d cols, %d banks, %d banks/chip, %d.%dns cycle time\n", 602 1.1 pgoyette s->sm_sdr.sdr_rows, s->sm_sdr.sdr_cols, s->sm_sdr.sdr_banks, 603 1.1 pgoyette s->sm_sdr.sdr_banks_per_chip, cycle_time/1000, 604 1.1 pgoyette (cycle_time % 1000) / 100); 605 1.1 pgoyette 606 1.1 pgoyette tAA = 0; 607 1.1 pgoyette for (i = 0; i < 8; i++) 608 1.1 pgoyette if (s->sm_sdr.sdr_tCAS & (1 << i)) 609 1.1 pgoyette tAA = i; 610 1.1 pgoyette tAA++; 611 1.4 christos aprint_verbose_dev(self, LATENCY, tAA, s->sm_sdr.sdr_tRCD, 612 1.1 pgoyette s->sm_sdr.sdr_tRP, s->sm_sdr.sdr_tRAS); 613 1.1 pgoyette 614 1.1 pgoyette decode_voltage_refresh(self, s); 615 1.1 pgoyette } 616 1.1 pgoyette 617 1.1 pgoyette static void 618 1.1 pgoyette decode_ddr(const struct sysctlnode *node, device_t self, struct spdmem *s) { 619 1.1 pgoyette int dimm_size, cycle_time, bits, tAA, i; 620 1.1 pgoyette 621 1.8 soren aprint_naive("\n"); 622 1.8 soren aprint_normal("\n"); 623 1.8 soren aprint_normal_dev(self, "%s", spdmem_basic_types[s->sm_type]); 624 1.8 soren 625 1.1 pgoyette aprint_normal("%s, %s, ", 626 1.1 pgoyette (s->sm_ddr.ddr_mod_attrs & SPDMEM_DDR_MASK_REG)? 627 1.1 pgoyette " (registered)":"", 628 1.1 pgoyette (s->sm_config < __arraycount(spdmem_parity_types))? 629 1.1 pgoyette spdmem_parity_types[s->sm_config]:"invalid parity"); 630 1.1 pgoyette 631 1.1 pgoyette dimm_size = 1 << (s->sm_ddr.ddr_rows + s->sm_ddr.ddr_cols - 17); 632 1.1 pgoyette dimm_size *= s->sm_ddr.ddr_ranks * s->sm_ddr.ddr_banks_per_chip; 633 1.1 pgoyette 634 1.1 pgoyette cycle_time = s->sm_ddr.ddr_cycle_whole * 1000 + 635 1.1 pgoyette spdmem_cycle_frac[s->sm_ddr.ddr_cycle_tenths]; 636 1.1 pgoyette bits = le16toh(s->sm_ddr.ddr_datawidth); 637 1.1 pgoyette if (s->sm_config == 1 || s->sm_config == 2) 638 1.1 pgoyette bits -= 8; 639 1.3 pgoyette decode_size_speed(self, node, dimm_size, cycle_time, 2, bits, TRUE, 640 1.3 pgoyette "PC", 0); 641 1.1 pgoyette 642 1.1 pgoyette aprint_verbose_dev(self, 643 1.1 pgoyette "%d rows, %d cols, %d ranks, %d banks/chip, %d.%dns cycle time\n", 644 1.1 pgoyette s->sm_ddr.ddr_rows, s->sm_ddr.ddr_cols, s->sm_ddr.ddr_ranks, 645 1.1 pgoyette s->sm_ddr.ddr_banks_per_chip, cycle_time/1000, 646 1.1 pgoyette (cycle_time % 1000 + 50) / 100); 647 1.1 pgoyette 648 1.1 pgoyette tAA = 0; 649 1.1 pgoyette for (i = 2; i < 8; i++) 650 1.1 pgoyette if (s->sm_ddr.ddr_tCAS & (1 << i)) 651 1.1 pgoyette tAA = i; 652 1.1 pgoyette tAA /= 2; 653 1.1 pgoyette 654 1.1 pgoyette #define __DDR_ROUND(scale, field) \ 655 1.1 pgoyette ((scale * s->sm_ddr.field + cycle_time - 1) / cycle_time) 656 1.1 pgoyette 657 1.4 christos aprint_verbose_dev(self, LATENCY, tAA, __DDR_ROUND(250, ddr_tRCD), 658 1.1 pgoyette __DDR_ROUND(250, ddr_tRP), __DDR_ROUND(1000, ddr_tRAS)); 659 1.1 pgoyette 660 1.1 pgoyette #undef __DDR_ROUND 661 1.1 pgoyette 662 1.1 pgoyette decode_voltage_refresh(self, s); 663 1.1 pgoyette } 664 1.1 pgoyette 665 1.1 pgoyette static void 666 1.1 pgoyette decode_ddr2(const struct sysctlnode *node, device_t self, struct spdmem *s) { 667 1.1 pgoyette int dimm_size, cycle_time, bits, tAA, i; 668 1.1 pgoyette 669 1.8 soren aprint_naive("\n"); 670 1.8 soren aprint_normal("\n"); 671 1.8 soren aprint_normal_dev(self, "%s", spdmem_basic_types[s->sm_type]); 672 1.8 soren 673 1.1 pgoyette aprint_normal("%s, %s, ", 674 1.1 pgoyette (s->sm_ddr2.ddr2_mod_attrs & SPDMEM_DDR2_MASK_REG)? 675 1.1 pgoyette " (registered)":"", 676 1.1 pgoyette (s->sm_config < __arraycount(spdmem_parity_types))? 677 1.1 pgoyette spdmem_parity_types[s->sm_config]:"invalid parity"); 678 1.1 pgoyette 679 1.1 pgoyette dimm_size = 1 << (s->sm_ddr2.ddr2_rows + s->sm_ddr2.ddr2_cols - 17); 680 1.1 pgoyette dimm_size *= (s->sm_ddr2.ddr2_ranks + 1) * 681 1.1 pgoyette s->sm_ddr2.ddr2_banks_per_chip; 682 1.1 pgoyette 683 1.1 pgoyette cycle_time = s->sm_ddr2.ddr2_cycle_whole * 1000 + 684 1.1 pgoyette spdmem_cycle_frac[s->sm_ddr2.ddr2_cycle_frac]; 685 1.1 pgoyette bits = s->sm_ddr2.ddr2_datawidth; 686 1.1 pgoyette if ((s->sm_config & 0x03) != 0) 687 1.1 pgoyette bits -= 8; 688 1.3 pgoyette decode_size_speed(self, node, dimm_size, cycle_time, 2, bits, TRUE, 689 1.3 pgoyette "PC2", 0); 690 1.1 pgoyette 691 1.1 pgoyette aprint_verbose_dev(self, 692 1.1 pgoyette "%d rows, %d cols, %d ranks, %d banks/chip, %d.%02dns cycle time\n", 693 1.1 pgoyette s->sm_ddr2.ddr2_rows, s->sm_ddr2.ddr2_cols, 694 1.1 pgoyette s->sm_ddr2.ddr2_ranks + 1, s->sm_ddr2.ddr2_banks_per_chip, 695 1.1 pgoyette cycle_time / 1000, (cycle_time % 1000 + 5) /10 ); 696 1.1 pgoyette 697 1.1 pgoyette tAA = 0; 698 1.1 pgoyette for (i = 2; i < 8; i++) 699 1.1 pgoyette if (s->sm_ddr2.ddr2_tCAS & (1 << i)) 700 1.1 pgoyette tAA = i; 701 1.1 pgoyette 702 1.1 pgoyette #define __DDR2_ROUND(scale, field) \ 703 1.1 pgoyette ((scale * s->sm_ddr2.field + cycle_time - 1) / cycle_time) 704 1.1 pgoyette 705 1.4 christos aprint_verbose_dev(self, LATENCY, tAA, __DDR2_ROUND(250, ddr2_tRCD), 706 1.1 pgoyette __DDR2_ROUND(250, ddr2_tRP), __DDR2_ROUND(1000, ddr2_tRAS)); 707 1.1 pgoyette 708 1.1 pgoyette #undef __DDR_ROUND 709 1.1 pgoyette 710 1.1 pgoyette decode_voltage_refresh(self, s); 711 1.1 pgoyette } 712 1.1 pgoyette 713 1.1 pgoyette static void 714 1.1 pgoyette decode_ddr3(const struct sysctlnode *node, device_t self, struct spdmem *s) { 715 1.1 pgoyette int dimm_size, cycle_time, bits; 716 1.1 pgoyette 717 1.8 soren aprint_naive("\n"); 718 1.8 soren aprint_normal(": %18s\n", s->sm_ddr3.ddr3_part); 719 1.8 soren aprint_normal_dev(self, "%s", spdmem_basic_types[s->sm_type]); 720 1.8 soren 721 1.1 pgoyette if (s->sm_ddr3.ddr3_mod_type == 722 1.1 pgoyette SPDMEM_DDR3_TYPE_MINI_RDIMM || 723 1.1 pgoyette s->sm_ddr3.ddr3_mod_type == SPDMEM_DDR3_TYPE_RDIMM) 724 1.1 pgoyette aprint_normal(" (registered)"); 725 1.1 pgoyette aprint_normal(", %sECC, %stemp-sensor, ", 726 1.1 pgoyette (s->sm_ddr3.ddr3_hasECC)?"":"no ", 727 1.1 pgoyette (s->sm_ddr3.ddr3_has_therm_sensor)?"":"no "); 728 1.1 pgoyette 729 1.1 pgoyette /* 730 1.1 pgoyette * DDR3 size specification is quite different from others 731 1.1 pgoyette * 732 1.1 pgoyette * Module capacity is defined as 733 1.1 pgoyette * Chip_Capacity_in_bits / 8bits-per-byte * 734 1.1 pgoyette * external_bus_width / internal_bus_width 735 1.1 pgoyette * We further divide by 2**20 to get our answer in MB 736 1.1 pgoyette */ 737 1.1 pgoyette dimm_size = (s->sm_ddr3.ddr3_chipsize + 28 - 20) - 3 + 738 1.1 pgoyette (s->sm_ddr3.ddr3_datawidth + 3) - 739 1.1 pgoyette (s->sm_ddr3.ddr3_chipwidth + 2); 740 1.1 pgoyette dimm_size = (1 << dimm_size) * (s->sm_ddr3.ddr3_physbanks + 1); 741 1.1 pgoyette 742 1.1 pgoyette cycle_time = (1000 * s->sm_ddr3.ddr3_mtb_dividend + 743 1.1 pgoyette (s->sm_ddr3.ddr3_mtb_divisor / 2)) / 744 1.1 pgoyette s->sm_ddr3.ddr3_mtb_divisor; 745 1.1 pgoyette cycle_time *= s->sm_ddr3.ddr3_tCKmin; 746 1.1 pgoyette bits = 1 << (s->sm_ddr3.ddr3_datawidth + 3); 747 1.3 pgoyette decode_size_speed(self, node, dimm_size, cycle_time, 2, bits, FALSE, 748 1.3 pgoyette "PC3", 0); 749 1.1 pgoyette 750 1.1 pgoyette aprint_verbose_dev(self, 751 1.1 pgoyette "%d rows, %d cols, %d log. banks, %d phys. banks, " 752 1.1 pgoyette "%d.%03dns cycle time\n", 753 1.1 pgoyette s->sm_ddr3.ddr3_rows + 9, s->sm_ddr3.ddr3_cols + 12, 754 1.1 pgoyette 1 << (s->sm_ddr3.ddr3_logbanks + 3), 755 1.1 pgoyette s->sm_ddr3.ddr3_physbanks + 1, 756 1.1 pgoyette cycle_time/1000, cycle_time % 1000); 757 1.1 pgoyette 758 1.1 pgoyette #define __DDR3_CYCLES(field) (s->sm_ddr3.field / s->sm_ddr3.ddr3_tCKmin) 759 1.1 pgoyette 760 1.4 christos aprint_verbose_dev(self, LATENCY, __DDR3_CYCLES(ddr3_tAAmin), 761 1.1 pgoyette __DDR3_CYCLES(ddr3_tRCDmin), __DDR3_CYCLES(ddr3_tRPmin), 762 1.1 pgoyette (s->sm_ddr3.ddr3_tRAS_msb * 256 + s->sm_ddr3.ddr3_tRAS_lsb) / 763 1.1 pgoyette s->sm_ddr3.ddr3_tCKmin); 764 1.1 pgoyette 765 1.1 pgoyette #undef __DDR3_CYCLES 766 1.14 msaitoh 767 1.14 msaitoh /* For DDR3, Voltage is written in another area */ 768 1.14 msaitoh if (!s->sm_ddr3.ddr3_NOT15V || s->sm_ddr3.ddr3_135V 769 1.14 msaitoh || s->sm_ddr3.ddr3_125V) { 770 1.14 msaitoh aprint_verbose("%s:", device_xname(self)); 771 1.14 msaitoh if (!s->sm_ddr3.ddr3_NOT15V) 772 1.14 msaitoh aprint_verbose(" 1.5V"); 773 1.14 msaitoh if (s->sm_ddr3.ddr3_135V) 774 1.14 msaitoh aprint_verbose(" 1.35V"); 775 1.14 msaitoh if (s->sm_ddr3.ddr3_125V) 776 1.14 msaitoh aprint_verbose(" 1.25V"); 777 1.14 msaitoh aprint_verbose(" operable\n"); 778 1.14 msaitoh } 779 1.1 pgoyette } 780 1.1 pgoyette 781 1.1 pgoyette static void 782 1.1 pgoyette decode_fbdimm(const struct sysctlnode *node, device_t self, struct spdmem *s) { 783 1.1 pgoyette int dimm_size, cycle_time, bits; 784 1.1 pgoyette 785 1.8 soren aprint_naive("\n"); 786 1.8 soren aprint_normal("\n"); 787 1.8 soren aprint_normal_dev(self, "%s", spdmem_basic_types[s->sm_type]); 788 1.8 soren 789 1.1 pgoyette /* 790 1.1 pgoyette * FB-DIMM module size calculation is very much like DDR3 791 1.1 pgoyette */ 792 1.1 pgoyette dimm_size = s->sm_fbd.fbdimm_rows + 12 + 793 1.1 pgoyette s->sm_fbd.fbdimm_cols + 9 - 20 - 3; 794 1.1 pgoyette dimm_size = (1 << dimm_size) * (1 << (s->sm_fbd.fbdimm_banks + 2)); 795 1.1 pgoyette 796 1.1 pgoyette cycle_time = (1000 * s->sm_fbd.fbdimm_mtb_dividend + 797 1.1 pgoyette (s->sm_fbd.fbdimm_mtb_divisor / 2)) / 798 1.1 pgoyette s->sm_fbd.fbdimm_mtb_divisor; 799 1.1 pgoyette bits = 1 << (s->sm_fbd.fbdimm_dev_width + 2); 800 1.3 pgoyette decode_size_speed(self, node, dimm_size, cycle_time, 2, bits, TRUE, 801 1.3 pgoyette "PC2", 0); 802 1.1 pgoyette 803 1.1 pgoyette aprint_verbose_dev(self, 804 1.1 pgoyette "%d rows, %d cols, %d banks, %d.%02dns cycle time\n", 805 1.1 pgoyette s->sm_fbd.fbdimm_rows, s->sm_fbd.fbdimm_cols, 806 1.1 pgoyette 1 << (s->sm_fbd.fbdimm_banks + 2), 807 1.1 pgoyette cycle_time / 1000, (cycle_time % 1000 + 5) /10 ); 808 1.1 pgoyette 809 1.1 pgoyette #define __FBDIMM_CYCLES(field) (s->sm_fbd.field / s->sm_fbd.fbdimm_tCKmin) 810 1.1 pgoyette 811 1.4 christos aprint_verbose_dev(self, LATENCY, __FBDIMM_CYCLES(fbdimm_tAAmin), 812 1.1 pgoyette __FBDIMM_CYCLES(fbdimm_tRCDmin), __FBDIMM_CYCLES(fbdimm_tRPmin), 813 1.1 pgoyette (s->sm_fbd.fbdimm_tRAS_msb * 256 + 814 1.1 pgoyette s->sm_fbd.fbdimm_tRAS_lsb) / 815 1.1 pgoyette s->sm_fbd.fbdimm_tCKmin); 816 1.1 pgoyette 817 1.1 pgoyette #undef __FBDIMM_CYCLES 818 1.1 pgoyette 819 1.1 pgoyette decode_voltage_refresh(self, s); 820 1.1 pgoyette } 821 1.13 pgoyette 822 1.13 pgoyette static void 823 1.13 pgoyette decode_ddr4(const struct sysctlnode *node, device_t self, struct spdmem *s) { 824 1.13 pgoyette int dimm_size, cycle_time; 825 1.13 pgoyette int tAA_clocks, tRCD_clocks,tRP_clocks, tRAS_clocks; 826 1.13 pgoyette 827 1.13 pgoyette aprint_naive("\n"); 828 1.13 pgoyette aprint_normal(": %20s\n", s->sm_ddr4.ddr4_part_number); 829 1.13 pgoyette aprint_normal_dev(self, "%s", spdmem_basic_types[s->sm_type]); 830 1.13 pgoyette if (s->sm_ddr4.ddr4_mod_type < __arraycount(spdmem_ddr4_module_types)) 831 1.13 pgoyette aprint_normal(" (%s)", 832 1.13 pgoyette spdmem_ddr4_module_types[s->sm_ddr4.ddr4_mod_type]); 833 1.13 pgoyette aprint_normal(", %stemp-sensor, ", 834 1.13 pgoyette (s->sm_ddr4.ddr4_has_therm_sensor)?"":"no "); 835 1.13 pgoyette 836 1.13 pgoyette /* 837 1.13 pgoyette * DDR4 size calculation from JEDEC spec 838 1.13 pgoyette * 839 1.13 pgoyette * Module capacity in bytes is defined as 840 1.13 pgoyette * Chip_Capacity_in_bits / 8bits-per-byte * 841 1.13 pgoyette * primary_bus_width / DRAM_width * 842 1.13 pgoyette * logical_ranks_per_DIMM 843 1.13 pgoyette * 844 1.13 pgoyette * logical_ranks_per DIMM equals package_ranks, but multiply 845 1.13 pgoyette * by diecount for 3DS packages 846 1.13 pgoyette * 847 1.13 pgoyette * We further divide by 2**20 to get our answer in MB 848 1.13 pgoyette */ 849 1.13 pgoyette dimm_size = (s->sm_ddr4.ddr4_capacity + 28) /* chip_capacity */ 850 1.13 pgoyette - 20 /* convert to MB */ 851 1.13 pgoyette - 3 /* bits --> bytes */ 852 1.13 pgoyette + (s->sm_ddr4.ddr4_primary_bus_width + 3); /* bus width */ 853 1.13 pgoyette switch (s->sm_ddr4.ddr4_device_width) { /* DRAM width */ 854 1.13 pgoyette case 0: dimm_size -= 2; 855 1.13 pgoyette break; 856 1.13 pgoyette case 1: dimm_size -= 3; 857 1.13 pgoyette break; 858 1.13 pgoyette case 2: dimm_size -= 4; 859 1.13 pgoyette break; 860 1.13 pgoyette case 4: dimm_size -= 5; 861 1.13 pgoyette break; 862 1.13 pgoyette default: 863 1.13 pgoyette dimm_size = -1; /* flag invalid value */ 864 1.13 pgoyette } 865 1.13 pgoyette if (dimm_size >=0) { 866 1.13 pgoyette dimm_size = (1 << dimm_size) * 867 1.13 pgoyette (s->sm_ddr4.ddr4_package_ranks + 1); /* log.ranks/DIMM */ 868 1.13 pgoyette if (s->sm_ddr4.ddr4_signal_loading == 2) { 869 1.13 pgoyette dimm_size *= s->sm_ddr4.ddr4_diecount; 870 1.13 pgoyette } 871 1.13 pgoyette } 872 1.13 pgoyette 873 1.13 pgoyette /* 874 1.13 pgoyette * For now, the only value for mtb is 1 = 125ps, and ftp = 1ps 875 1.13 pgoyette * so we don't need to figure out the time-base units - just 876 1.13 pgoyette * hard-code them for now. 877 1.13 pgoyette */ 878 1.13 pgoyette cycle_time = 125 * s->sm_ddr4.ddr4_tCKAVGmin_mtb + 879 1.13 pgoyette s->sm_ddr4.ddr4_tCKAVGmin_ftb; 880 1.13 pgoyette aprint_normal("%d MB, %d.%03dns cycle time (%dMHz)\n", dimm_size, 881 1.13 pgoyette cycle_time/1000, cycle_time % 1000, 1000000 / cycle_time); 882 1.13 pgoyette 883 1.13 pgoyette decode_size_speed(self, node, dimm_size, cycle_time, 2, 884 1.13 pgoyette 1 << (s->sm_ddr4.ddr4_device_width + 3), 885 1.13 pgoyette TRUE, "PC4", 0); 886 1.13 pgoyette 887 1.13 pgoyette aprint_verbose_dev(self, 888 1.13 pgoyette "%d rows, %d cols, %d banks, %d bank groups\n", 889 1.13 pgoyette s->sm_ddr3.ddr3_rows + 9, s->sm_ddr3.ddr3_cols + 12, 890 1.13 pgoyette 1 << (2 + s->sm_ddr4.ddr4_logbanks), 891 1.13 pgoyette 1 << s->sm_ddr4.ddr4_bankgroups); 892 1.13 pgoyette 893 1.13 pgoyette /* 894 1.13 pgoyette * Note that the ddr4_xxx_ftb fields are actually signed offsets from 895 1.13 pgoyette * the corresponding mtb value, so we might have to subtract 256! 896 1.13 pgoyette */ 897 1.13 pgoyette #define __DDR4_VALUE(field) (s->sm_ddr4.ddr4_##field##_mtb * 256 + \ 898 1.13 pgoyette s->sm_ddr4.ddr4_##field##_ftb) - \ 899 1.13 pgoyette ((s->sm_ddr4.ddr4_##field##_ftb > 127)?256:0) 900 1.13 pgoyette 901 1.13 pgoyette tAA_clocks = (__DDR4_VALUE(tAAmin) * 1000 ) / cycle_time; 902 1.13 pgoyette tRP_clocks = (__DDR4_VALUE(tRPmin) * 1000 ) / cycle_time; 903 1.13 pgoyette tRCD_clocks = (__DDR4_VALUE(tRCDmin) * 1000 ) / cycle_time; 904 1.13 pgoyette tRAS_clocks = (s->sm_ddr4.ddr4_tRASmin_msb * 256 + 905 1.13 pgoyette s->sm_ddr4.ddr4_tRASmin_lsb) * 125 * 1000 / cycle_time; 906 1.13 pgoyette 907 1.13 pgoyette /* 908 1.13 pgoyette * Per JEDEC spec, rounding is done by taking the time value, dividing 909 1.13 pgoyette * by the cycle time, subtracting .010 from the result, and then 910 1.13 pgoyette * rounded up to the nearest integer. Unfortunately, none of their 911 1.13 pgoyette * examples say what to do when the result of the subtraction is already 912 1.13 pgoyette * an integer. For now, assume that we still round up (so an interval 913 1.13 pgoyette * of exactly 12.010 clock cycles will be printed as 13). 914 1.13 pgoyette */ 915 1.13 pgoyette #define __DDR4_ROUND(value) ((value - 10) / 1000 + 1) 916 1.13 pgoyette 917 1.13 pgoyette aprint_verbose_dev(self, LATENCY, __DDR4_ROUND(tAA_clocks), 918 1.13 pgoyette __DDR4_ROUND(tRP_clocks), 919 1.13 pgoyette __DDR4_ROUND(tRCD_clocks), 920 1.13 pgoyette __DDR4_ROUND(tRAS_clocks)); 921 1.13 pgoyette 922 1.13 pgoyette #undef __DDR4_VALUE 923 1.13 pgoyette #undef __DDR4_ROUND 924 1.13 pgoyette } 925
Indexes created Wed Oct 01 18:09:54 GMT 2025