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review.coreboot.org / coreboot / d522db048b1e1b6e61f585859d7a95b308cb53de / . / src / northbridge / intel / gm45 / raminit.c
blob: d067dc2ff94e443653d6ad61f1087a556b5986e0 [file] [log] [blame]
Patrick Georgi2efc8802012-11-06 11:03:53 +0100[diff] [blame]1/*
2 * This file is part of the coreboot project.
3 *
4 * Copyright (C) 2012 secunet Security Networks AG
5 *
6 * This program is free software; you can redistribute it and/or
7 * modify it under the terms of the GNU General Public License as
8 * published by the Free Software Foundation; version 2 of
9 * the License.
10 *
11 * This program is distributed in the hope that it will be useful,
12 * but WITHOUT ANY WARRANTY; without even the implied warranty of
13 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
14 * GNU General Public License for more details.
Patrick Georgi2efc8802012-11-06 11:03:53 +0100[diff] [blame]15 */
16
17#include <stdint.h>
Kyösti Mälkki931c1dc2014-06-30 09:40:19 +0300[diff] [blame]18#include <stdlib.h>
Patrick Georgi2efc8802012-11-06 11:03:53 +0100[diff] [blame]19#include <arch/cpu.h>
20#include <arch/io.h>
Patrick Georgi2efc8802012-11-06 11:03:53 +0100[diff] [blame]21#include <device/pci_def.h>
22#include <device/pnp_def.h>
Patrick Rudolph266a1f72016-06-09 18:13:34 +0200[diff] [blame]23#include <device/device.h>
Patrick Georgi2efc8802012-11-06 11:03:53 +0100[diff] [blame]24#include <spd.h>
25#include <console/console.h>
26#include <lib.h>
Arthur Heymans10141c32016-10-27 00:31:41 +0200[diff] [blame]27#include <delay.h>
Arthur Heymans049347f2017-05-12 11:54:08 +0200[diff] [blame]28#include <timestamp.h>
Patrick Georgi2efc8802012-11-06 11:03:53 +0100[diff] [blame]29#include "gm45.h"
Patrick Rudolph266a1f72016-06-09 18:13:34 +0200[diff] [blame]30#include "chip.h"
Patrick Georgi2efc8802012-11-06 11:03:53 +0100[diff] [blame]31
32static const gmch_gfx_t gmch_gfx_types[][5] = {
33/* MAX_667MHz MAX_533MHz MAX_400MHz MAX_333MHz MAX_800MHz */
34 { GMCH_UNKNOWN, GMCH_UNKNOWN, GMCH_UNKNOWN, GMCH_UNKNOWN, GMCH_UNKNOWN },
35 { GMCH_GM47, GMCH_GM45, GMCH_UNKNOWN, GMCH_UNKNOWN, GMCH_GM49 },
36 { GMCH_GE45, GMCH_GE45, GMCH_GE45, GMCH_GE45, GMCH_GE45 },
37 { GMCH_UNKNOWN, GMCH_GL43, GMCH_GL40, GMCH_UNKNOWN, GMCH_UNKNOWN },
38 { GMCH_UNKNOWN, GMCH_GS45, GMCH_GS40, GMCH_UNKNOWN, GMCH_UNKNOWN },
39 { GMCH_UNKNOWN, GMCH_UNKNOWN, GMCH_UNKNOWN, GMCH_UNKNOWN, GMCH_UNKNOWN },
40 { GMCH_UNKNOWN, GMCH_UNKNOWN, GMCH_UNKNOWN, GMCH_UNKNOWN, GMCH_UNKNOWN },
41 { GMCH_PM45, GMCH_PM45, GMCH_PM45, GMCH_PM45, GMCH_PM45 },
42};
43
44void get_gmch_info(sysinfo_t *sysinfo)
45{
46 sysinfo->stepping = pci_read_config8(PCI_DEV(0, 0, 0), PCI_CLASS_REVISION);
47 if ((sysinfo->stepping > STEPPING_B3) &&
48 (sysinfo->stepping != STEPPING_CONVERSION_A1))
49 die("Unknown stepping.\n");
50 if (sysinfo->stepping <= STEPPING_B3)
51 printk(BIOS_DEBUG, "Stepping %c%d\n", 'A' + sysinfo->stepping / 4, sysinfo->stepping % 4);
52 else
53 printk(BIOS_DEBUG, "Conversion stepping A1\n");
54
55 const u32 eax = cpuid_ext(0x04, 0).eax;
56 sysinfo->cores = ((eax >> 26) & 0x3f) + 1;
57 printk(BIOS_SPEW, "%d CPU cores\n", sysinfo->cores);
58
59 u32 capid = pci_read_config16(PCI_DEV(0, 0, 0), D0F0_CAPID0+8);
60 if (!(capid & (1<<(79-64)))) {
61 printk(BIOS_SPEW, "iTPM enabled\n");
62 }
63
64 capid = pci_read_config32(PCI_DEV(0, 0, 0), D0F0_CAPID0+4);
65 if (!(capid & (1<<(57-32)))) {
66 printk(BIOS_SPEW, "ME enabled\n");
67 }
68
69 if (!(capid & (1<<(56-32)))) {
70 printk(BIOS_SPEW, "AMT enabled\n");
71 }
72
73 sysinfo->max_ddr2_mhz = (capid & (1<<(53-32)))?667:800;
74 printk(BIOS_SPEW, "capable of DDR2 of %d MHz or lower\n", sysinfo->max_ddr2_mhz);
75
76 if (!(capid & (1<<(48-32)))) {
77 printk(BIOS_SPEW, "VT-d enabled\n");
78 }
79
80 const u32 gfx_variant = (capid>>(42-32)) & 0x7;
81 const u32 render_freq = ((capid>>(50-32) & 0x1) << 2) | ((capid>>(35-32)) & 0x3);
82 if (render_freq <= 4)
83 sysinfo->gfx_type = gmch_gfx_types[gfx_variant][render_freq];
84 else
85 sysinfo->gfx_type = GMCH_UNKNOWN;
Patrick Georgi2efc8802012-11-06 11:03:53 +0100[diff] [blame]86 switch (sysinfo->gfx_type) {
87 case GMCH_GM45:
88 printk(BIOS_SPEW, "GMCH: GM45\n");
89 break;
90 case GMCH_GM47:
91 printk(BIOS_SPEW, "GMCH: GM47\n");
92 break;
93 case GMCH_GM49:
94 printk(BIOS_SPEW, "GMCH: GM49\n");
95 break;
96 case GMCH_GE45:
97 printk(BIOS_SPEW, "GMCH: GE45\n");
98 break;
99 case GMCH_GL40:
100 printk(BIOS_SPEW, "GMCH: GL40\n");
101 break;
102 case GMCH_GL43:
103 printk(BIOS_SPEW, "GMCH: GL43\n");
104 break;
105 case GMCH_GS40:
106 printk(BIOS_SPEW, "GMCH: GS40\n");
107 break;
108 case GMCH_GS45:
Nico Huber5aaeb272015-12-30 00:17:27 +0100[diff] [blame]109 printk(BIOS_SPEW, "GMCH: GS45, using %s-power mode\n",
110 sysinfo->gs45_low_power_mode ? "low" : "high");
Patrick Georgi2efc8802012-11-06 11:03:53 +0100[diff] [blame]111 break;
112 case GMCH_PM45:
113 printk(BIOS_SPEW, "GMCH: PM45\n");
114 break;
115 case GMCH_UNKNOWN:
116 printk(BIOS_SPEW, "unknown GMCH\n");
117 break;
118 }
119
120 sysinfo->txt_enabled = !(capid & (1 << (37-32)));
121 if (sysinfo->txt_enabled) {
122 printk(BIOS_SPEW, "TXT enabled\n");
123 }
124
125 switch (render_freq) {
126 case 4:
127 sysinfo->max_render_mhz = 800;
128 break;
129 case 0:
130 sysinfo->max_render_mhz = 667;
131 break;
132 case 1:
133 sysinfo->max_render_mhz = 533;
134 break;
135 case 2:
136 sysinfo->max_render_mhz = 400;
137 break;
138 case 3:
139 sysinfo->max_render_mhz = 333;
140 break;
141 default:
142 printk(BIOS_SPEW, "Unknown render frequency\n");
143 sysinfo->max_render_mhz = 0;
144 break;
145 }
146 if (sysinfo->max_render_mhz != 0) {
147 printk(BIOS_SPEW, "Render frequency: %d MHz\n", sysinfo->max_render_mhz);
148 }
149
150 if (!(capid & (1<<(33-32)))) {
151 printk(BIOS_SPEW, "IGD enabled\n");
152 }
153
154 if (!(capid & (1<<(32-32)))) {
155 printk(BIOS_SPEW, "PCIe-to-GMCH enabled\n");
156 }
157
158 capid = pci_read_config32(PCI_DEV(0, 0, 0), D0F0_CAPID0);
159
160 u32 ddr_cap = capid>>30 & 0x3;
161 switch (ddr_cap) {
162 case 0:
163 sysinfo->max_ddr3_mt = 1067;
164 break;
165 case 1:
166 sysinfo->max_ddr3_mt = 800;
167 break;
168 case 2:
169 case 3:
170 printk(BIOS_SPEW, "GMCH not DDR3 capable\n");
171 sysinfo->max_ddr3_mt = 0;
172 break;
173 }
174 if (sysinfo->max_ddr3_mt != 0) {
175 printk(BIOS_SPEW, "GMCH supports DDR3 with %d MT or less\n", sysinfo->max_ddr3_mt);
176 }
177
178 const unsigned max_fsb = (capid >> 28) & 0x3;
179 switch (max_fsb) {
180 case 1:
181 sysinfo->max_fsb_mhz = 1067;
182 break;
183 case 2:
184 sysinfo->max_fsb_mhz = 800;
185 break;
186 case 3:
187 sysinfo->max_fsb_mhz = 667;
188 break;
189 default:
190 die("unknown FSB capability\n");
191 break;
192 }
193 if (sysinfo->max_fsb_mhz != 0) {
194 printk(BIOS_SPEW, "GMCH supports FSB with up to %d MHz\n", sysinfo->max_fsb_mhz);
195 }
196 sysinfo->max_fsb = max_fsb - 1;
197}
198
199/*
200 * Detect if the system went through an interrupted RAM init or is incon-
201 * sistent. If so, initiate a cold reboot. Otherwise mark the system to be
Martin Roth128c1042016-11-18 09:29:03 -0700[diff] [blame]202 * in RAM init, so this function would detect it on an erroneous reboot.
Patrick Georgi2efc8802012-11-06 11:03:53 +0100[diff] [blame]203 */
204void enter_raminit_or_reset(void)
205{
206 /* Interrupted RAM init or inconsistent system? */
207 u8 reg8 = pci_read_config8(PCI_DEV(0, 0x1f, 0), 0xa2);
208
209 if (reg8 & (1 << 2)) { /* S4-assertion-width violation */
210 /* Ignore S4-assertion-width violation like original BIOS. */
211 printk(BIOS_WARNING,
212 "WARNING: Ignoring S4-assertion-width violation.\n");
213 /* Bit2 is R/WC, so it will clear itself below. */
214 }
215
216 if (reg8 & (1 << 7)) { /* interrupted RAM init */
217 /* Don't enable S4-assertion stretch. Makes trouble on roda/rk9.
218 reg8 = pci_read_config8(PCI_DEV(0, 0x1f, 0), 0xa4);
219 pci_write_config8(PCI_DEV(0, 0x1f, 0), 0xa4, reg8 | 0x08);
220 */
221
222 /* Clear bit7. */
223 pci_write_config8(PCI_DEV(0, 0x1f, 0), 0xa2, reg8 & ~(1 << 7));
224
225 printk(BIOS_INFO, "Interrupted RAM init, reset required.\n");
226 gm45_early_reset();
227 }
228 /* Mark system to be in RAM init. */
229 pci_write_config8(PCI_DEV(0, 0x1f, 0), 0xa2, reg8 | (1 << 7));
230}
231
232
233/* For a detected DIMM, test the value of an SPD byte to
234 match the expected value after masking some bits. */
Vladimir Serbinenkoc4d89482014-06-05 09:14:48 +0200[diff] [blame]235static int test_dimm(sysinfo_t *const sysinfo,
236 int dimm, int addr, int bitmask, int expected)
Patrick Georgi2efc8802012-11-06 11:03:53 +0100[diff] [blame]237{
Vladimir Serbinenkoc4d89482014-06-05 09:14:48 +0200[diff] [blame]238 return (smbus_read_byte(sysinfo->spd_map[dimm], addr) & bitmask) == expected;
Patrick Georgi2efc8802012-11-06 11:03:53 +0100[diff] [blame]239}
240
241/* This function dies if dimm is unsuitable for the chipset. */
Vladimir Serbinenkoc4d89482014-06-05 09:14:48 +0200[diff] [blame]242static void verify_ddr3_dimm(sysinfo_t *const sysinfo, int dimm)
Patrick Georgi2efc8802012-11-06 11:03:53 +0100[diff] [blame]243{
Vladimir Serbinenkoc4d89482014-06-05 09:14:48 +0200[diff] [blame]244 if (!test_dimm(sysinfo, dimm, 3, 15, 3))
Patrick Georgi2efc8802012-11-06 11:03:53 +0100[diff] [blame]245 die("Chipset only supports SO-DIMM\n");
246
Vladimir Serbinenkoc4d89482014-06-05 09:14:48 +0200[diff] [blame]247 if (!test_dimm(sysinfo, dimm, 8, 0x18, 0))
Patrick Georgi2efc8802012-11-06 11:03:53 +0100[diff] [blame]248 die("Chipset doesn't support ECC RAM\n");
249
Vladimir Serbinenkoc4d89482014-06-05 09:14:48 +0200[diff] [blame]250 if (!test_dimm(sysinfo, dimm, 7, 0x38, 0) &&
251 !test_dimm(sysinfo, dimm, 7, 0x38, 8))
Patrick Georgi2efc8802012-11-06 11:03:53 +0100[diff] [blame]252 die("Chipset wants single or double sided DIMMs\n");
253
Vladimir Serbinenkoc4d89482014-06-05 09:14:48 +0200[diff] [blame]254 if (!test_dimm(sysinfo, dimm, 7, 7, 1) &&
255 !test_dimm(sysinfo, dimm, 7, 7, 2))
Patrick Georgi2efc8802012-11-06 11:03:53 +0100[diff] [blame]256 die("Chipset requires x8 or x16 width\n");
257
Vladimir Serbinenkoc4d89482014-06-05 09:14:48 +0200[diff] [blame]258 if (!test_dimm(sysinfo, dimm, 4, 0x0f, 0) &&
259 !test_dimm(sysinfo, dimm, 4, 0x0f, 1) &&
260 !test_dimm(sysinfo, dimm, 4, 0x0f, 2) &&
261 !test_dimm(sysinfo, dimm, 4, 0x0f, 3))
Patrick Georgi2efc8802012-11-06 11:03:53 +0100[diff] [blame]262 die("Chipset requires 256Mb, 512Mb, 1Gb or 2Gb chips.");
263
Vladimir Serbinenkoc4d89482014-06-05 09:14:48 +0200[diff] [blame]264 if (!test_dimm(sysinfo, dimm, 4, 0x70, 0))
Patrick Georgi2efc8802012-11-06 11:03:53 +0100[diff] [blame]265 die("Chipset requires 8 banks on DDR3\n");
266
267 /* How to check if burst length is 8?
268 Other values are not supported, are they even possible? */
269
Vladimir Serbinenkoc4d89482014-06-05 09:14:48 +0200[diff] [blame]270 if (!test_dimm(sysinfo, dimm, 10, 0xff, 1))
Patrick Georgi2efc8802012-11-06 11:03:53 +0100[diff] [blame]271 die("Code assumes 1/8ns MTB\n");
272
Vladimir Serbinenkoc4d89482014-06-05 09:14:48 +0200[diff] [blame]273 if (!test_dimm(sysinfo, dimm, 11, 0xff, 8))
Patrick Georgi2efc8802012-11-06 11:03:53 +0100[diff] [blame]274 die("Code assumes 1/8ns MTB\n");
275
Vladimir Serbinenkoc4d89482014-06-05 09:14:48 +0200[diff] [blame]276 if (!test_dimm(sysinfo, dimm, 62, 0x9f, 0) &&
277 !test_dimm(sysinfo, dimm, 62, 0x9f, 1) &&
278 !test_dimm(sysinfo, dimm, 62, 0x9f, 2) &&
279 !test_dimm(sysinfo, dimm, 62, 0x9f, 3) &&
280 !test_dimm(sysinfo, dimm, 62, 0x9f, 5))
Patrick Georgi2efc8802012-11-06 11:03:53 +0100[diff] [blame]281 die("Only raw card types A, B, C, D and F are supported.\n");
282}
283
284/* For every detected DIMM, test if it's suitable for the chipset. */
Vladimir Serbinenkoc4d89482014-06-05 09:14:48 +0200[diff] [blame]285static void verify_ddr3(sysinfo_t *const sysinfo, int mask)
Patrick Georgi2efc8802012-11-06 11:03:53 +0100[diff] [blame]286{
287 int cur = 0;
288 while (mask) {
289 if (mask & 1) {
Vladimir Serbinenkoc4d89482014-06-05 09:14:48 +0200[diff] [blame]290 verify_ddr3_dimm(sysinfo, cur);
Patrick Georgi2efc8802012-11-06 11:03:53 +0100[diff] [blame]291 }
292 mask >>= 1;
293 cur++;
294 }
295}
296
297
298typedef struct {
299 int dimm_mask;
300 struct {
301 unsigned int rows;
302 unsigned int cols;
303 unsigned int chip_capacity;
304 unsigned int banks;
305 unsigned int ranks;
306 unsigned int cas_latencies;
307 unsigned int tAAmin;
308 unsigned int tCKmin;
309 unsigned int width;
310 unsigned int tRAS;
311 unsigned int tRP;
312 unsigned int tRCD;
313 unsigned int tWR;
314 unsigned int page_size;
315 unsigned int raw_card;
316 } channel[2];
317} spdinfo_t;
318/*
319 * This function collects RAM characteristics from SPD, assuming that RAM
320 * is generally within chipset's requirements, since verify_ddr3() passed.
321 */
Vladimir Serbinenkoc4d89482014-06-05 09:14:48 +0200[diff] [blame]322static void collect_ddr3(sysinfo_t *const sysinfo, spdinfo_t *const config)
Patrick Georgi2efc8802012-11-06 11:03:53 +0100[diff] [blame]323{
324 int mask = config->dimm_mask;
325 int cur = 0;
326 while (mask != 0) {
Vladimir Serbinenkoc4d89482014-06-05 09:14:48 +0200[diff] [blame]327 /* FIXME: support several dimms on same channel. */
328 if ((mask & 1) && sysinfo->spd_map[2 * cur]) {
Patrick Georgi2efc8802012-11-06 11:03:53 +0100[diff] [blame]329 int tmp;
Vladimir Serbinenkoc4d89482014-06-05 09:14:48 +0200[diff] [blame]330 const int smb_addr = sysinfo->spd_map[2 * cur];
Patrick Georgi2efc8802012-11-06 11:03:53 +0100[diff] [blame]331
332 config->channel[cur].rows = ((smbus_read_byte(smb_addr, 5) >> 3) & 7) + 12;
333 config->channel[cur].cols = (smbus_read_byte(smb_addr, 5) & 7) + 9;
334
335 config->channel[cur].chip_capacity = smbus_read_byte(smb_addr, 4) & 0xf;
336
337 config->channel[cur].banks = 8; /* GM45 only accepts this for DDR3.
338 verify_ddr3() fails for other values. */
339 config->channel[cur].ranks = ((smbus_read_byte(smb_addr, 7) >> 3) & 7) + 1;
340
341 config->channel[cur].cas_latencies =
342 ((smbus_read_byte(smb_addr, 15) << 8) | smbus_read_byte(smb_addr, 14))
343 << 4; /* so bit x is CAS x */
344 config->channel[cur].tAAmin = smbus_read_byte(smb_addr, 16); /* in MTB */
345 config->channel[cur].tCKmin = smbus_read_byte(smb_addr, 12); /* in MTB */
346
347 config->channel[cur].width = smbus_read_byte(smb_addr, 7) & 7;
348 config->channel[cur].page_size = config->channel[cur].width *
349 (1 << config->channel[cur].cols); /* in Bytes */
350
351 tmp = smbus_read_byte(smb_addr, 21);
352 config->channel[cur].tRAS = smbus_read_byte(smb_addr, 22) | ((tmp & 0xf) << 8);
353 config->channel[cur].tRP = smbus_read_byte(smb_addr, 20);
354 config->channel[cur].tRCD = smbus_read_byte(smb_addr, 18);
355 config->channel[cur].tWR = smbus_read_byte(smb_addr, 17);
356
357 config->channel[cur].raw_card = smbus_read_byte(smb_addr, 62) & 0x1f;
358 }
359 cur++;
Vladimir Serbinenkoc4d89482014-06-05 09:14:48 +0200[diff] [blame]360 mask >>= 2;
Patrick Georgi2efc8802012-11-06 11:03:53 +0100[diff] [blame]361 }
362}
363
Edward O'Callaghan7116ac82014-07-08 01:53:24 +1000[diff] [blame]364#define ROUNDUP_DIV(val, by) CEIL_DIV(val, by)
Patrick Georgi2efc8802012-11-06 11:03:53 +0100[diff] [blame]365#define ROUNDUP_DIV_THIS(val, by) val = ROUNDUP_DIV(val, by)
366static fsb_clock_t read_fsb_clock(void)
367{
368 switch (MCHBAR32(CLKCFG_MCHBAR) & CLKCFG_FSBCLK_MASK) {
369 case 6:
370 return FSB_CLOCK_1067MHz;
371 case 2:
372 return FSB_CLOCK_800MHz;
373 case 3:
374 return FSB_CLOCK_667MHz;
375 default:
376 die("Unsupported FSB clock.\n");
377 }
378}
379static mem_clock_t clock_index(const unsigned int clock)
380{
381 switch (clock) {
382 case 533: return MEM_CLOCK_533MHz;
383 case 400: return MEM_CLOCK_400MHz;
384 case 333: return MEM_CLOCK_333MHz;
385 default: die("Unknown clock value.\n");
386 }
387 return -1; /* Won't be reached. */
388}
389static void normalize_clock(unsigned int *const clock)
390{
391 if (*clock >= 533)
392 *clock = 533;
393 else if (*clock >= 400)
394 *clock = 400;
395 else if (*clock >= 333)
396 *clock = 333;
397 else
398 *clock = 0;
399}
400static void lower_clock(unsigned int *const clock)
401{
402 --*clock;
403 normalize_clock(clock);
404}
405static unsigned int find_common_clock_cas(sysinfo_t *const sysinfo,
406 const spdinfo_t *const spdinfo)
407{
408 /* various constraints must be fulfilled:
409 CAS * tCK < 20ns == 160MTB
410 tCK_max >= tCK >= tCK_min
411 CAS >= roundup(tAA_min/tCK)
412 CAS supported
413 Clock(MHz) = 1000 / tCK(ns)
414 Clock(MHz) = 8000 / tCK(MTB)
415 AND BTW: Clock(MT) = 2000 / tCK(ns) - intel uses MTs but calls them MHz
416 */
417 int i;
418
419 /* Calculate common cas_latencies mask, tCKmin and tAAmin. */
420 unsigned int cas_latencies = (unsigned int)-1;
421 unsigned int tCKmin = 0, tAAmin = 0;
422 FOR_EACH_POPULATED_CHANNEL(sysinfo->dimms, i) {
423 cas_latencies &= spdinfo->channel[i].cas_latencies;
424 if (spdinfo->channel[i].tCKmin > tCKmin)
425 tCKmin = spdinfo->channel[i].tCKmin;
426 if (spdinfo->channel[i].tAAmin > tAAmin)
427 tAAmin = spdinfo->channel[i].tAAmin;
428 }
429
430 /* Get actual value of fsb clock. */
431 sysinfo->selected_timings.fsb_clock = read_fsb_clock();
432 unsigned int fsb_mhz = 0;
433 switch (sysinfo->selected_timings.fsb_clock) {
434 case FSB_CLOCK_1067MHz: fsb_mhz = 1067; break;
435 case FSB_CLOCK_800MHz: fsb_mhz = 800; break;
436 case FSB_CLOCK_667MHz: fsb_mhz = 667; break;
437 }
438
439 unsigned int clock = 8000 / tCKmin;
440 if ((clock > sysinfo->max_ddr3_mt / 2) || (clock > fsb_mhz / 2)) {
441 int new_clock = min(sysinfo->max_ddr3_mt / 2, fsb_mhz / 2);
442 printk(BIOS_SPEW, "DIMMs support %d MHz, but chipset only runs at up to %d. Limiting...\n",
443 clock, new_clock);
444 clock = new_clock;
445 }
446 normalize_clock(&clock);
447
448 /* Find compatible clock / CAS pair. */
449 unsigned int tCKproposed;
450 unsigned int CAS;
451 while (1) {
452 if (!clock)
453 die("Couldn't find compatible clock / CAS settings.\n");
454 tCKproposed = 8000 / clock;
455 CAS = ROUNDUP_DIV(tAAmin, tCKproposed);
456 printk(BIOS_SPEW, "Trying CAS %u, tCK %u.\n", CAS, tCKproposed);
457 for (; CAS <= DDR3_MAX_CAS; ++CAS)
458 if (cas_latencies & (1 << CAS))
459 break;
460 if ((CAS <= DDR3_MAX_CAS) && (CAS * tCKproposed < 160)) {
461 /* Found good CAS. */
462 printk(BIOS_SPEW, "Found compatible clock / CAS pair: %u / %u.\n", clock, CAS);
463 break;
464 }
465 lower_clock(&clock);
466 }
467 sysinfo->selected_timings.CAS = CAS;
468 sysinfo->selected_timings.mem_clock = clock_index(clock);
469
470 return tCKproposed;
471}
472
473static void calculate_derived_timings(sysinfo_t *const sysinfo,
474 const unsigned int tCLK,
475 const spdinfo_t *const spdinfo)
476{
477 int i;
478
479 /* Calculate common tRASmin, tRPmin, tRCDmin and tWRmin. */
480 unsigned int tRASmin = 0, tRPmin = 0, tRCDmin = 0, tWRmin = 0;
481 FOR_EACH_POPULATED_CHANNEL(sysinfo->dimms, i) {
482 if (spdinfo->channel[i].tRAS > tRASmin)
483 tRASmin = spdinfo->channel[i].tRAS;
484 if (spdinfo->channel[i].tRP > tRPmin)
485 tRPmin = spdinfo->channel[i].tRP;
486 if (spdinfo->channel[i].tRCD > tRCDmin)
487 tRCDmin = spdinfo->channel[i].tRCD;
488 if (spdinfo->channel[i].tWR > tWRmin)
489 tWRmin = spdinfo->channel[i].tWR;
490 }
491 ROUNDUP_DIV_THIS(tRASmin, tCLK);
492 ROUNDUP_DIV_THIS(tRPmin, tCLK);
493 ROUNDUP_DIV_THIS(tRCDmin, tCLK);
494 ROUNDUP_DIV_THIS(tWRmin, tCLK);
495
496 /* Lookup tRFC and calculate common tRFCmin. */
497 const unsigned int tRFC_from_clock_and_cap[][4] = {
498 /* CAP_256M CAP_512M CAP_1G CAP_2G */
499 /* 533MHz */ { 40, 56, 68, 104 },
500 /* 400MHz */ { 30, 42, 51, 78 },
501 /* 333MHz */ { 25, 35, 43, 65 },
502 };
503 unsigned int tRFCmin = 0;
504 FOR_EACH_POPULATED_CHANNEL(sysinfo->dimms, i) {
505 const unsigned int tRFC = tRFC_from_clock_and_cap
506 [sysinfo->selected_timings.mem_clock][spdinfo->channel[i].chip_capacity];
507 if (tRFC > tRFCmin)
508 tRFCmin = tRFC;
509 }
510
511 /* Calculate common tRD from CAS and FSB and DRAM clocks. */
512 unsigned int tRDmin = sysinfo->selected_timings.CAS;
513 switch (sysinfo->selected_timings.fsb_clock) {
514 case FSB_CLOCK_667MHz:
515 tRDmin += 1;
516 break;
517 case FSB_CLOCK_800MHz:
518 tRDmin += 2;
519 break;
520 case FSB_CLOCK_1067MHz:
521 tRDmin += 3;
522 if (sysinfo->selected_timings.mem_clock == MEM_CLOCK_1067MT)
523 tRDmin += 1;
524 break;
525 }
526
527 /* Calculate common tRRDmin. */
528 unsigned int tRRDmin = 0;
529 FOR_EACH_POPULATED_CHANNEL(sysinfo->dimms, i) {
530 unsigned int tRRD = 2 + (spdinfo->channel[i].page_size / 1024);
531 if (sysinfo->selected_timings.mem_clock == MEM_CLOCK_1067MT)
532 tRRD += (spdinfo->channel[i].page_size / 1024);
533 if (tRRD > tRRDmin)
534 tRRDmin = tRRD;
535 }
536
537 /* Lookup and calculate common tFAWmin. */
538 unsigned int tFAW_from_pagesize_and_clock[][3] = {
539 /* 533MHz 400MHz 333MHz */
540 /* 1K */ { 20, 15, 13 },
541 /* 2K */ { 27, 20, 17 },
542 };
543 unsigned int tFAWmin = 0;
544 FOR_EACH_POPULATED_CHANNEL(sysinfo->dimms, i) {
545 const unsigned int tFAW = tFAW_from_pagesize_and_clock
546 [spdinfo->channel[i].page_size / 1024 - 1]
547 [sysinfo->selected_timings.mem_clock];
548 if (tFAW > tFAWmin)
549 tFAWmin = tFAW;
550 }
551
552 /* Refresh rate is fixed. */
553 unsigned int tWL;
554 if (sysinfo->selected_timings.mem_clock == MEM_CLOCK_1067MT) {
555 tWL = 6;
556 } else {
557 tWL = 5;
558 }
559
560 printk(BIOS_SPEW, "Timing values:\n"
561 " tCLK: %3u\n"
562 " tRAS: %3u\n"
563 " tRP: %3u\n"
564 " tRCD: %3u\n"
565 " tRFC: %3u\n"
566 " tWR: %3u\n"
567 " tRD: %3u\n"
568 " tRRD: %3u\n"
569 " tFAW: %3u\n"
570 " tWL: %3u\n",
571 tCLK, tRASmin, tRPmin, tRCDmin, tRFCmin, tWRmin, tRDmin, tRRDmin, tFAWmin, tWL);
572
573 sysinfo->selected_timings.tRAS = tRASmin;
574 sysinfo->selected_timings.tRP = tRPmin;
575 sysinfo->selected_timings.tRCD = tRCDmin;
576 sysinfo->selected_timings.tRFC = tRFCmin;
577 sysinfo->selected_timings.tWR = tWRmin;
578 sysinfo->selected_timings.tRD = tRDmin;
579 sysinfo->selected_timings.tRRD = tRRDmin;
580 sysinfo->selected_timings.tFAW = tFAWmin;
581 sysinfo->selected_timings.tWL = tWL;
582}
583
584static void collect_dimm_config(sysinfo_t *const sysinfo)
585{
586 int i;
587 spdinfo_t spdinfo;
588
589 spdinfo.dimm_mask = 0;
590 sysinfo->spd_type = 0;
591
Vladimir Serbinenkoc4d89482014-06-05 09:14:48 +0200[diff] [blame]592 for (i = 0; i < 4; i++)
593 if (sysinfo->spd_map[i]) {
594 const u8 spd = smbus_read_byte(sysinfo->spd_map[i], 2);
595 printk (BIOS_DEBUG, "%x:%x:%x\n",
596 i, sysinfo->spd_map[i],
597 spd);
598 if ((spd == 7) || (spd == 8) || (spd == 0xb)) {
599 spdinfo.dimm_mask |= 1 << i;
600 if (sysinfo->spd_type && sysinfo->spd_type != spd) {
601 die("Multiple types of DIMM installed in the system, don't do that!\n");
602 }
603 sysinfo->spd_type = spd;
Patrick Georgi2efc8802012-11-06 11:03:53 +0100[diff] [blame]604 }
Patrick Georgi2efc8802012-11-06 11:03:53 +0100[diff] [blame]605 }
Patrick Georgi2efc8802012-11-06 11:03:53 +0100[diff] [blame]606 if (spdinfo.dimm_mask == 0) {
607 die("Could not find any DIMM.\n");
608 }
609
610 /* Normalize spd_type to 1, 2, 3. */
611 sysinfo->spd_type = (sysinfo->spd_type & 1) | ((sysinfo->spd_type & 8) >> 2);
612 printk(BIOS_SPEW, "DDR mask %x, DDR %d\n", spdinfo.dimm_mask, sysinfo->spd_type);
613
614 if (sysinfo->spd_type == DDR2) {
615 die("DDR2 not supported at this time.\n");
616 } else if (sysinfo->spd_type == DDR3) {
Vladimir Serbinenkoc4d89482014-06-05 09:14:48 +0200[diff] [blame]617 verify_ddr3(sysinfo, spdinfo.dimm_mask);
618 collect_ddr3(sysinfo, &spdinfo);
Patrick Georgi2efc8802012-11-06 11:03:53 +0100[diff] [blame]619 } else {
620 die("Will never support DDR1.\n");
621 }
622
623 for (i = 0; i < 2; i++) {
624 if ((spdinfo.dimm_mask >> (i*2)) & 1) {
625 printk(BIOS_SPEW, "Bank %d populated:\n"
626 " Raw card type: %4c\n"
627 " Row addr bits: %4u\n"
628 " Col addr bits: %4u\n"
629 " byte width: %4u\n"
630 " page size: %4u\n"
631 " banks: %4u\n"
632 " ranks: %4u\n"
633 " tAAmin: %3u\n"
634 " tCKmin: %3u\n"
635 " Max clock: %3u MHz\n"
636 " CAS: 0x%04x\n",
637 i, spdinfo.channel[i].raw_card + 'A',
638 spdinfo.channel[i].rows, spdinfo.channel[i].cols,
639 spdinfo.channel[i].width, spdinfo.channel[i].page_size,
640 spdinfo.channel[i].banks, spdinfo.channel[i].ranks,
641 spdinfo.channel[i].tAAmin, spdinfo.channel[i].tCKmin,
642 8000 / spdinfo.channel[i].tCKmin, spdinfo.channel[i].cas_latencies);
643 }
644 }
645
646 FOR_EACH_CHANNEL(i) {
647 sysinfo->dimms[i].card_type =
648 (spdinfo.dimm_mask & (1 << (i * 2))) ? spdinfo.channel[i].raw_card + 0xa : 0;
649 }
650
651 /* Find common memory clock and CAS. */
652 const unsigned int tCLK = find_common_clock_cas(sysinfo, &spdinfo);
653
654 /* Calculate other timings from clock and CAS. */
655 calculate_derived_timings(sysinfo, tCLK, &spdinfo);
656
657 /* Initialize DIMM infos. */
658 /* Always prefer interleaved over async channel mode. */
659 FOR_EACH_CHANNEL(i) {
660 IF_CHANNEL_POPULATED(sysinfo->dimms, i) {
661 sysinfo->dimms[i].banks = spdinfo.channel[i].banks;
662 sysinfo->dimms[i].ranks = spdinfo.channel[i].ranks;
663
664 /* .width is 1 for x8 or 2 for x16, bus width is 8 bytes. */
665 const unsigned int chips_per_rank = 8 / spdinfo.channel[i].width;
666
667 sysinfo->dimms[i].chip_width = spdinfo.channel[i].width;
668 sysinfo->dimms[i].chip_capacity = spdinfo.channel[i].chip_capacity;
669 sysinfo->dimms[i].page_size = spdinfo.channel[i].page_size * chips_per_rank;
670 sysinfo->dimms[i].rank_capacity_mb =
671 /* offset of chip_capacity is 8 (256M), therefore, add 8
672 chip_capacity is in Mbit, we want MByte, therefore, subtract 3 */
673 (1 << (spdinfo.channel[i].chip_capacity + 8 - 3)) * chips_per_rank;
674 }
675 }
676 if (CHANNEL_IS_POPULATED(sysinfo->dimms, 0) &&
677 CHANNEL_IS_POPULATED(sysinfo->dimms, 1))
678 sysinfo->selected_timings.channel_mode = CHANNEL_MODE_DUAL_INTERLEAVED;
679 else
680 sysinfo->selected_timings.channel_mode = CHANNEL_MODE_SINGLE;
681}
682
683static void reset_on_bad_warmboot(void)
684{
685 /* Check self refresh channel status. */
686 const u32 reg = MCHBAR32(PMSTS_MCHBAR);
687 /* Clear status bits. R/WC */
688 MCHBAR32(PMSTS_MCHBAR) = reg;
689 if ((reg & PMSTS_WARM_RESET) && !(reg & PMSTS_BOTH_SELFREFRESH)) {
690 printk(BIOS_INFO, "DRAM was not in self refresh "
691 "during warm boot, reset required.\n");
692 gm45_early_reset();
693 }
694}
695
696static void set_system_memory_frequency(const timings_t *const timings)
697{
698 MCHBAR16(CLKCFG_MCHBAR + 0x60) &= ~(1 << 15);
699 MCHBAR16(CLKCFG_MCHBAR + 0x48) &= ~(1 << 15);
700
701 /* Calculate wanted frequency setting. */
702 const int want_freq = 6 - timings->mem_clock;
703
704 /* Read current memory frequency. */
705 const u32 clkcfg = MCHBAR32(CLKCFG_MCHBAR);
706 int cur_freq = (clkcfg & CLKCFG_MEMCLK_MASK) >> CLKCFG_MEMCLK_SHIFT;
707 if (0 == cur_freq) {
708 /* Try memory frequency from scratchpad. */
709 printk(BIOS_DEBUG, "Reading current memory frequency from scratchpad.\n");
710 cur_freq = (MCHBAR16(SSKPD_MCHBAR) & SSKPD_CLK_MASK) >> SSKPD_CLK_SHIFT;
711 }
712
713 if (cur_freq != want_freq) {
714 printk(BIOS_DEBUG, "Changing memory frequency: old %x, new %x.\n", cur_freq, want_freq);
715 /* When writing new frequency setting, reset, then set update bit. */
716 MCHBAR32(CLKCFG_MCHBAR) = (MCHBAR32(CLKCFG_MCHBAR) & ~(CLKCFG_UPDATE | CLKCFG_MEMCLK_MASK)) |
717 (want_freq << CLKCFG_MEMCLK_SHIFT);
718 MCHBAR32(CLKCFG_MCHBAR) = (MCHBAR32(CLKCFG_MCHBAR) & ~CLKCFG_MEMCLK_MASK) |
719 (want_freq << CLKCFG_MEMCLK_SHIFT) | CLKCFG_UPDATE;
720 /* Reset update bit. */
721 MCHBAR32(CLKCFG_MCHBAR) &= ~CLKCFG_UPDATE;
722 }
723
724 if ((timings->fsb_clock == FSB_CLOCK_1067MHz) && (timings->mem_clock == MEM_CLOCK_667MT)) {
725 MCHBAR32(CLKCFG_MCHBAR + 0x16) = 0x000030f0;
726 MCHBAR32(CLKCFG_MCHBAR + 0x64) = 0x000050c1;
727
728 MCHBAR32(CLKCFG_MCHBAR) = (MCHBAR32(CLKCFG_MCHBAR) & ~(1 << 12)) | (1 << 17);
729 MCHBAR32(CLKCFG_MCHBAR) |= (1 << 17) | (1 << 12);
730 MCHBAR32(CLKCFG_MCHBAR) &= ~(1 << 12);
731
732 MCHBAR32(CLKCFG_MCHBAR + 0x04) = 0x9bad1f1f;
733 MCHBAR8(CLKCFG_MCHBAR + 0x08) = 0xf4;
734 MCHBAR8(CLKCFG_MCHBAR + 0x0a) = 0x43;
735 MCHBAR8(CLKCFG_MCHBAR + 0x0c) = 0x10;
736 MCHBAR8(CLKCFG_MCHBAR + 0x0d) = 0x80;
737 MCHBAR32(CLKCFG_MCHBAR + 0x50) = 0x0b0e151b;
738 MCHBAR8(CLKCFG_MCHBAR + 0x54) = 0xb4;
739 MCHBAR8(CLKCFG_MCHBAR + 0x55) = 0x10;
740 MCHBAR8(CLKCFG_MCHBAR + 0x56) = 0x08;
741
742 MCHBAR32(CLKCFG_MCHBAR) |= (1 << 10);
743 MCHBAR32(CLKCFG_MCHBAR) |= (1 << 11);
744 MCHBAR32(CLKCFG_MCHBAR) &= ~(1 << 10);
745 MCHBAR32(CLKCFG_MCHBAR) &= ~(1 << 11);
746 }
747
748 MCHBAR32(CLKCFG_MCHBAR + 0x48) |= 0x3f << 24;
749}
750
751int raminit_read_vco_index(void)
752{
Nico Huberd85a71a2016-11-27 14:43:12 +0100[diff] [blame]753 switch (MCHBAR8(HPLLVCO_MCHBAR) & 0x7) {
Patrick Georgi2efc8802012-11-06 11:03:53 +0100[diff] [blame]754 case VCO_2666:
755 return 0;
756 case VCO_3200:
757 return 1;
758 case VCO_4000:
759 return 2;
760 case VCO_5333:
761 return 3;
762 default:
763 die("Unknown VCO frequency.\n");
764 return 0;
765 }
766}
767static void set_igd_memory_frequencies(const sysinfo_t *const sysinfo)
768{
769 const int gfx_idx = ((sysinfo->gfx_type == GMCH_GS45) &&
770 !sysinfo->gs45_low_power_mode)
771 ? (GMCH_GS45 + 1) : sysinfo->gfx_type;
772
773 /* Render and sampler frequency values seem to be some kind of factor. */
774 const u16 render_freq_from_vco_and_gfxtype[][10] = {
775 /* GM45 GM47 GM49 GE45 GL40 GL43 GS40 GS45 (perf) */
776 /* VCO 2666 */ { 0xd, 0xd, 0xe, 0xd, 0xb, 0xd, 0xb, 0xa, 0xd },
777 /* VCO 3200 */ { 0xd, 0xe, 0xf, 0xd, 0xb, 0xd, 0xb, 0x9, 0xd },
778 /* VCO 4000 */ { 0xc, 0xd, 0xf, 0xc, 0xa, 0xc, 0xa, 0x9, 0xc },
779 /* VCO 5333 */ { 0xb, 0xc, 0xe, 0xb, 0x9, 0xb, 0x9, 0x8, 0xb },
780 };
781 const u16 sampler_freq_from_vco_and_gfxtype[][10] = {
782 /* GM45 GM47 GM49 GE45 GL40 GL43 GS40 GS45 (perf) */
783 /* VCO 2666 */ { 0xc, 0xc, 0xd, 0xc, 0x9, 0xc, 0x9, 0x8, 0xc },
784 /* VCO 3200 */ { 0xc, 0xd, 0xe, 0xc, 0x9, 0xc, 0x9, 0x8, 0xc },
785 /* VCO 4000 */ { 0xa, 0xc, 0xd, 0xa, 0x8, 0xa, 0x8, 0x8, 0xa },
786 /* VCO 5333 */ { 0xa, 0xa, 0xc, 0xa, 0x7, 0xa, 0x7, 0x6, 0xa },
787 };
788 const u16 display_clock_select_from_gfxtype[] = {
789 /* GM45 GM47 GM49 GE45 GL40 GL43 GS40 GS45 (perf) */
790 1, 1, 1, 1, 1, 1, 1, 0, 1
791 };
792
793 if (pci_read_config16(GCFGC_PCIDEV, 0) != 0x8086) {
794 printk(BIOS_DEBUG, "Skipping IGD memory frequency setting.\n");
795 return;
796 }
797
798 MCHBAR16(0x119e) = 0xa800;
799 MCHBAR16(0x11c0) = (MCHBAR16(0x11c0) & ~0xff00) | (0x01 << 8);
800 MCHBAR16(0x119e) = 0xb800;
801 MCHBAR8(0x0f10) |= 1 << 7;
802
803 /* Read VCO. */
804 const int vco_idx = raminit_read_vco_index();
805 printk(BIOS_DEBUG, "Setting IGD memory frequencies for VCO #%d.\n", vco_idx);
806
807 const u32 freqcfg =
808 ((render_freq_from_vco_and_gfxtype[vco_idx][gfx_idx]
809 << GCFGC_CR_SHIFT) & GCFGC_CR_MASK) |
810 ((sampler_freq_from_vco_and_gfxtype[vco_idx][gfx_idx]
811 << GCFGC_CS_SHIFT) & GCFGC_CS_MASK);
812
813 /* Set frequencies, clear update bit. */
814 u32 gcfgc = pci_read_config16(GCFGC_PCIDEV, GCFGC_OFFSET);
815 gcfgc &= ~(GCFGC_CS_MASK | GCFGC_UPDATE | GCFGC_CR_MASK);
816 gcfgc |= freqcfg;
817 pci_write_config16(GCFGC_PCIDEV, GCFGC_OFFSET, gcfgc);
818
819 /* Set frequencies, set update bit. */
820 gcfgc = pci_read_config16(GCFGC_PCIDEV, GCFGC_OFFSET);
821 gcfgc &= ~(GCFGC_CS_MASK | GCFGC_CR_MASK);
822 gcfgc |= freqcfg | GCFGC_UPDATE;
823 pci_write_config16(GCFGC_PCIDEV, GCFGC_OFFSET, gcfgc);
824
825 /* Clear update bit. */
826 pci_write_config16(GCFGC_PCIDEV, GCFGC_OFFSET,
827 pci_read_config16(GCFGC_PCIDEV, GCFGC_OFFSET) & ~GCFGC_UPDATE);
828
829 /* Set display clock select bit. */
830 pci_write_config16(GCFGC_PCIDEV, GCFGC_OFFSET,
831 (pci_read_config16(GCFGC_PCIDEV, GCFGC_OFFSET) & ~GCFGC_CD_MASK) |
832 (display_clock_select_from_gfxtype[gfx_idx] << GCFGC_CD_SHIFT));
833}
834
835static void configure_dram_control_mode(const timings_t *const timings, const dimminfo_t *const dimms)
836{
837 int ch, r;
838
839 FOR_EACH_CHANNEL(ch) {
840 unsigned int mchbar = CxDRC0_MCHBAR(ch);
841 u32 cxdrc = MCHBAR32(mchbar);
842 cxdrc &= ~CxDRC0_RANKEN_MASK;
843 FOR_EACH_POPULATED_RANK_IN_CHANNEL(dimms, ch, r)
844 cxdrc |= CxDRC0_RANKEN(r);
845 cxdrc = (cxdrc & ~CxDRC0_RMS_MASK) |
846 /* Always 7.8us for DDR3: */
847 CxDRC0_RMS_78US;
848 MCHBAR32(mchbar) = cxdrc;
849
850 mchbar = CxDRC1_MCHBAR(ch);
851 cxdrc = MCHBAR32(mchbar);
852 cxdrc |= CxDRC1_NOTPOP_MASK;
853 FOR_EACH_POPULATED_RANK_IN_CHANNEL(dimms, ch, r)
854 cxdrc &= ~CxDRC1_NOTPOP(r);
855 cxdrc |= CxDRC1_MUSTWR;
856 MCHBAR32(mchbar) = cxdrc;
857
858 mchbar = CxDRC2_MCHBAR(ch);
859 cxdrc = MCHBAR32(mchbar);
860 cxdrc |= CxDRC2_NOTPOP_MASK;
861 FOR_EACH_POPULATED_RANK_IN_CHANNEL(dimms, ch, r)
862 cxdrc &= ~CxDRC2_NOTPOP(r);
863 cxdrc |= CxDRC2_MUSTWR;
864 if (timings->mem_clock == MEM_CLOCK_1067MT)
865 cxdrc |= CxDRC2_CLK1067MT;
866 MCHBAR32(mchbar) = cxdrc;
867 }
868}
869
870static void rcomp_initialization(const stepping_t stepping, const int sff)
871{
Elyes HAOUAS3d450002018-08-09 18:55:58 +0200[diff] [blame]872 /* Program RCOMP codes. */
Patrick Georgi2efc8802012-11-06 11:03:53 +0100[diff] [blame]873 if (sff)
874 die("SFF platform unsupported in RCOMP initialization.\n");
875 /* Values are for DDR3. */
876 MCHBAR8(0x6ac) &= ~0x0f;
877 MCHBAR8(0x6b0) = 0x55;
878 MCHBAR8(0x6ec) &= ~0x0f;
879 MCHBAR8(0x6f0) = 0x66;
880 MCHBAR8(0x72c) &= ~0x0f;
881 MCHBAR8(0x730) = 0x66;
882 MCHBAR8(0x76c) &= ~0x0f;
883 MCHBAR8(0x770) = 0x66;
884 MCHBAR8(0x7ac) &= ~0x0f;
885 MCHBAR8(0x7b0) = 0x66;
886 MCHBAR8(0x7ec) &= ~0x0f;
887 MCHBAR8(0x7f0) = 0x66;
888 MCHBAR8(0x86c) &= ~0x0f;
889 MCHBAR8(0x870) = 0x55;
890 MCHBAR8(0x8ac) &= ~0x0f;
891 MCHBAR8(0x8b0) = 0x66;
892 /* ODT multiplier bits. */
893 MCHBAR32(0x04d0) = (MCHBAR32(0x04d0) & ~((7 << 3) | (7 << 0))) | (2 << 3) | (2 << 0);
894
895 /* Perform RCOMP calibration for DDR3. */
896 raminit_rcomp_calibration(stepping);
897
898 /* Run initial RCOMP. */
899 MCHBAR32(0x418) |= 1 << 17;
900 MCHBAR32(0x40c) &= ~(1 << 23);
901 MCHBAR32(0x41c) &= ~((1 << 7) | (1 << 3));
902 MCHBAR32(0x400) |= 1;
903 while (MCHBAR32(0x400) & 1) {}
904
905 /* Run second RCOMP. */
906 MCHBAR32(0x40c) |= 1 << 19;
907 MCHBAR32(0x400) |= 1;
908 while (MCHBAR32(0x400) & 1) {}
909
910 /* Cleanup and start periodic RCOMP. */
911 MCHBAR32(0x40c) &= ~(1 << 19);
912 MCHBAR32(0x40c) |= 1 << 23;
913 MCHBAR32(0x418) &= ~(1 << 17);
914 MCHBAR32(0x41c) |= (1 << 7) | (1 << 3);
915 MCHBAR32(0x400) |= (1 << 1);
916}
917
918static void dram_powerup(const int resume)
919{
Arthur Heymans10141c32016-10-27 00:31:41 +0200[diff] [blame]920 udelay(200);
Patrick Georgi2efc8802012-11-06 11:03:53 +0100[diff] [blame]921 MCHBAR32(CLKCFG_MCHBAR) = (MCHBAR32(CLKCFG_MCHBAR) & ~(1 << 3)) | (3 << 21);
922 if (!resume) {
923 MCHBAR32(0x1434) |= (1 << 10);
Arthur Heymans10141c32016-10-27 00:31:41 +0200[diff] [blame]924 udelay(1);
Patrick Georgi2efc8802012-11-06 11:03:53 +0100[diff] [blame]925 }
926 MCHBAR32(0x1434) |= (1 << 6);
927 if (!resume) {
Arthur Heymans10141c32016-10-27 00:31:41 +0200[diff] [blame]928 udelay(1);
Patrick Georgi2efc8802012-11-06 11:03:53 +0100[diff] [blame]929 MCHBAR32(0x1434) |= (1 << 9);
930 MCHBAR32(0x1434) &= ~(1 << 10);
931 udelay(500);
932 }
933}
934static void dram_program_timings(const timings_t *const timings)
935{
936 /* Values are for DDR3. */
937 const int burst_length = 8;
938 const int tWTR = 4, tRTP = 1;
939 int i;
940
941 FOR_EACH_CHANNEL(i) {
942 u32 reg = MCHBAR32(CxDRT0_MCHBAR(i));
943 const int btb_wtp = timings->tWL + burst_length/2 + timings->tWR;
944 const int btb_wtr = timings->tWL + burst_length/2 + tWTR;
945 reg = (reg & ~(CxDRT0_BtB_WtP_MASK | CxDRT0_BtB_WtR_MASK)) |
946 ((btb_wtp << CxDRT0_BtB_WtP_SHIFT) & CxDRT0_BtB_WtP_MASK) |
947 ((btb_wtr << CxDRT0_BtB_WtR_SHIFT) & CxDRT0_BtB_WtR_MASK);
948 if (timings->mem_clock != MEM_CLOCK_1067MT) {
949 reg = (reg & ~(0x7 << 15)) | ((9 - timings->CAS) << 15);
950 reg = (reg & ~(0xf << 10)) | ((timings->CAS - 3) << 10);
951 } else {
952 reg = (reg & ~(0x7 << 15)) | ((10 - timings->CAS) << 15);
953 reg = (reg & ~(0xf << 10)) | ((timings->CAS - 4) << 10);
954 }
955 reg = (reg & ~(0x7 << 5)) | (3 << 5);
956 reg = (reg & ~(0x7 << 0)) | (1 << 0);
957 MCHBAR32(CxDRT0_MCHBAR(i)) = reg;
958
959 reg = MCHBAR32(CxDRT1_MCHBAR(i));
960 reg = (reg & ~(0x03 << 28)) | ((tRTP & 0x03) << 28);
961 reg = (reg & ~(0x1f << 21)) | ((timings->tRAS & 0x1f) << 21);
962 reg = (reg & ~(0x07 << 10)) | (((timings->tRRD - 2) & 0x07) << 10);
963 reg = (reg & ~(0x07 << 5)) | (((timings->tRCD - 2) & 0x07) << 5);
964 reg = (reg & ~(0x07 << 0)) | (((timings->tRP - 2) & 0x07) << 0);
965 MCHBAR32(CxDRT1_MCHBAR(i)) = reg;
966
967 reg = MCHBAR32(CxDRT2_MCHBAR(i));
968 reg = (reg & ~(0x1f << 17)) | ((timings->tFAW & 0x1f) << 17);
969 if (timings->mem_clock != MEM_CLOCK_1067MT) {
970 reg = (reg & ~(0x7 << 12)) | (0x2 << 12);
971 reg = (reg & ~(0xf << 6)) | (0x9 << 6);
972 } else {
973 reg = (reg & ~(0x7 << 12)) | (0x3 << 12);
974 reg = (reg & ~(0xf << 6)) | (0xc << 6);
975 }
976 reg = (reg & ~(0x1f << 0)) | (0x13 << 0);
977 MCHBAR32(CxDRT2_MCHBAR(i)) = reg;
978
979 reg = MCHBAR32(CxDRT3_MCHBAR(i));
980 reg |= 0x3 << 28;
981 reg = (reg & ~(0x03 << 26));
982 reg = (reg & ~(0x07 << 23)) | (((timings->CAS - 3) & 0x07) << 23);
983 reg = (reg & ~(0xff << 13)) | ((timings->tRFC & 0xff) << 13);
984 reg = (reg & ~(0x07 << 0)) | (((timings->tWL - 2) & 0x07) << 0);
985 MCHBAR32(CxDRT3_MCHBAR(i)) = reg;
986
987 reg = MCHBAR32(CxDRT4_MCHBAR(i));
988 static const u8 timings_by_clock[4][3] = {
989 /* 333MHz 400MHz 533MHz
990 667MT 800MT 1067MT */
991 { 0x07, 0x0a, 0x0d },
992 { 0x3a, 0x46, 0x5d },
993 { 0x0c, 0x0e, 0x18 },
994 { 0x21, 0x28, 0x35 },
995 };
996 const int clk_idx = 2 - timings->mem_clock;
997 reg = (reg & ~(0x01f << 27)) | (timings_by_clock[0][clk_idx] << 27);
998 reg = (reg & ~(0x3ff << 17)) | (timings_by_clock[1][clk_idx] << 17);
999 reg = (reg & ~(0x03f << 10)) | (timings_by_clock[2][clk_idx] << 10);
1000 reg = (reg & ~(0x1ff << 0)) | (timings_by_clock[3][clk_idx] << 0);
1001 MCHBAR32(CxDRT4_MCHBAR(i)) = reg;
1002
1003 reg = MCHBAR32(CxDRT5_MCHBAR(i));
1004 if (timings->mem_clock == MEM_CLOCK_1067MT)
1005 reg = (reg & ~(0xf << 28)) | (0x8 << 28);
1006 reg = (reg & ~(0x00f << 22)) | ((burst_length/2 + timings->CAS + 2) << 22);
1007 reg = (reg & ~(0x3ff << 12)) | (0x190 << 12);
1008 reg = (reg & ~(0x00f << 4)) | ((timings->CAS - 2) << 4);
1009 reg = (reg & ~(0x003 << 2)) | (0x001 << 2);
1010 reg = (reg & ~(0x003 << 0));
1011 MCHBAR32(CxDRT5_MCHBAR(i)) = reg;
1012
1013 reg = MCHBAR32(CxDRT6_MCHBAR(i));
1014 reg = (reg & ~(0xffff << 16)) | (0x066a << 16); /* always 7.8us refresh rate for DDR3 */
1015 reg |= (1 << 2);
1016 MCHBAR32(CxDRT6_MCHBAR(i)) = reg;
1017 }
1018}
1019
1020static void dram_program_banks(const dimminfo_t *const dimms)
1021{
1022 int ch, r;
1023
1024 FOR_EACH_CHANNEL(ch) {
1025 const int tRPALL = dimms[ch].banks == 8;
1026
1027 u32 reg = MCHBAR32(CxDRT1_MCHBAR(ch)) & ~(0x01 << 15);
1028 IF_CHANNEL_POPULATED(dimms, ch)
1029 reg |= tRPALL << 15;
1030 MCHBAR32(CxDRT1_MCHBAR(ch)) = reg;
1031
1032 reg = MCHBAR32(CxDRA_MCHBAR(ch)) & ~CxDRA_BANKS_MASK;
1033 FOR_EACH_POPULATED_RANK_IN_CHANNEL(dimms, ch, r) {
1034 reg |= CxDRA_BANKS(r, dimms[ch].banks);
1035 }
1036 MCHBAR32(CxDRA_MCHBAR(ch)) = reg;
1037 }
1038}
1039
1040static void odt_setup(const timings_t *const timings, const int sff)
1041{
1042 /* Values are for DDR3. */
1043 int ch;
1044
1045 FOR_EACH_CHANNEL(ch) {
1046 u32 reg = MCHBAR32(CxODT_HIGH(ch));
1047 if (sff && (timings->mem_clock != MEM_CLOCK_1067MT))
1048 reg &= ~(0x3 << (61 - 32));
1049 else
1050 reg |= 0x3 << (61 - 32);
1051 reg = (reg & ~(0x3 << (52 - 32))) | (0x2 << (52 - 32));
1052 reg = (reg & ~(0x7 << (48 - 32))) | ((timings->CAS - 3) << (48 - 32));
1053 reg = (reg & ~(0xf << (44 - 32))) | (0x7 << (44 - 32));
1054 if (timings->mem_clock != MEM_CLOCK_1067MT) {
1055 reg = (reg & ~(0xf << (40 - 32))) | ((12 - timings->CAS) << (40 - 32));
1056 reg = (reg & ~(0xf << (36 - 32))) | (( 2 + timings->CAS) << (36 - 32));
1057 } else {
1058 reg = (reg & ~(0xf << (40 - 32))) | ((13 - timings->CAS) << (40 - 32));
1059 reg = (reg & ~(0xf << (36 - 32))) | (( 1 + timings->CAS) << (36 - 32));
1060 }
1061 reg = (reg & ~(0xf << (32 - 32))) | (0x7 << (32 - 32));
1062 MCHBAR32(CxODT_HIGH(ch)) = reg;
1063
1064 reg = MCHBAR32(CxODT_LOW(ch));
1065 reg = (reg & ~(0x7 << 28)) | (0x2 << 28);
1066 reg = (reg & ~(0x3 << 22)) | (0x2 << 22);
1067 reg = (reg & ~(0x7 << 12)) | (0x2 << 12);
1068 reg = (reg & ~(0x7 << 4)) | (0x2 << 4);
1069 switch (timings->mem_clock) {
1070 case MEM_CLOCK_667MT:
1071 reg = (reg & ~0x7);
1072 break;
1073 case MEM_CLOCK_800MT:
1074 reg = (reg & ~0x7) | 0x2;
1075 break;
1076 case MEM_CLOCK_1067MT:
1077 reg = (reg & ~0x7) | 0x5;
1078 break;
1079 }
1080 MCHBAR32(CxODT_LOW(ch)) = reg;
1081 }
1082}
1083
1084static void misc_settings(const timings_t *const timings,
1085 const stepping_t stepping)
1086{
1087 MCHBAR32(0x1260) = (MCHBAR32(0x1260) & ~((1 << 24) | 0x1f)) | timings->tRD;
1088 MCHBAR32(0x1360) = (MCHBAR32(0x1360) & ~((1 << 24) | 0x1f)) | timings->tRD;
1089
1090 MCHBAR8(0x1268) = (MCHBAR8(0x1268) & ~(0xf)) | timings->tWL;
1091 MCHBAR8(0x1368) = (MCHBAR8(0x1368) & ~(0xf)) | timings->tWL;
1092 MCHBAR8(0x12a0) = (MCHBAR8(0x12a0) & ~(0xf)) | 0xa;
1093 MCHBAR8(0x13a0) = (MCHBAR8(0x13a0) & ~(0xf)) | 0xa;
1094
1095 MCHBAR32(0x218) = (MCHBAR32(0x218) & ~((7 << 29) | (7 << 25) | (3 << 22) | (3 << 10))) |
1096 (4 << 29) | (3 << 25) | (0 << 22) | (1 << 10);
1097 MCHBAR32(0x220) = (MCHBAR32(0x220) & ~(7 << 16)) | (1 << 21) | (1 << 16);
1098 MCHBAR32(0x224) = (MCHBAR32(0x224) & ~(7 << 8)) | (3 << 8);
1099 if (stepping >= STEPPING_B1)
1100 MCHBAR8(0x234) |= (1 << 3);
1101}
1102
1103static void clock_crossing_setup(const fsb_clock_t fsb,
1104 const mem_clock_t ddr3clock,
1105 const dimminfo_t *const dimms)
1106{
1107 int ch;
1108
1109 static const u32 values_from_fsb_and_mem[][3][4] = {
1110 /* FSB 1067MHz */{
1111 /* DDR3-1067 */ { 0x00000000, 0x00000000, 0x00180006, 0x00810060 },
1112 /* DDR3-800 */ { 0x00000000, 0x00000000, 0x0000001c, 0x000300e0 },
1113 /* DDR3-667 */ { 0x00000000, 0x00001c00, 0x03c00038, 0x0007e000 },
1114 },
1115 /* FSB 800MHz */{
1116 /* DDR3-1067 */ { 0, 0, 0, 0 },
1117 /* DDR3-800 */ { 0x00000000, 0x00000000, 0x0030000c, 0x000300c0 },
1118 /* DDR3-667 */ { 0x00000000, 0x00000380, 0x0060001c, 0x00030c00 },
1119 },
1120 /* FSB 667MHz */{
1121 /* DDR3-1067 */ { 0, 0, 0, 0 },
1122 /* DDR3-800 */ { 0, 0, 0, 0 },
1123 /* DDR3-667 */ { 0x00000000, 0x00000000, 0x0030000c, 0x000300c0 },
1124 },
1125 };
1126
1127 const u32 *data = values_from_fsb_and_mem[fsb][ddr3clock];
1128 MCHBAR32(0x0208) = data[3];
1129 MCHBAR32(0x020c) = data[2];
1130 if (((fsb == FSB_CLOCK_1067MHz) || (fsb == FSB_CLOCK_800MHz)) && (ddr3clock == MEM_CLOCK_667MT))
1131 MCHBAR32(0x0210) = data[1];
1132
1133 static const u32 from_fsb_and_mem[][3] = {
1134 /* DDR3-1067 DDR3-800 DDR3-667 */
1135 /* FSB 1067MHz */{ 0x40100401, 0x10040220, 0x08040110, },
1136 /* FSB 800MHz */{ 0x00000000, 0x40100401, 0x00080201, },
1137 /* FSB 667MHz */{ 0x00000000, 0x00000000, 0x40100401, },
1138 };
1139 FOR_EACH_CHANNEL(ch) {
1140 const unsigned int mchbar = 0x1258 + (ch * 0x0100);
1141 if ((fsb == FSB_CLOCK_1067MHz) && (ddr3clock == MEM_CLOCK_800MT) && CHANNEL_IS_CARDF(dimms, ch))
1142 MCHBAR32(mchbar) = 0x08040120;
1143 else
1144 MCHBAR32(mchbar) = from_fsb_and_mem[fsb][ddr3clock];
1145 MCHBAR32(mchbar + 4) = 0x00000000;
1146 }
1147}
1148
1149/* Program egress VC1 timings. */
1150static void vc1_program_timings(const fsb_clock_t fsb)
1151{
1152 const u32 timings_by_fsb[][2] = {
1153 /* FSB 1067MHz */ { 0x1a, 0x01380138 },
1154 /* FSB 800MHz */ { 0x14, 0x00f000f0 },
1155 /* FSB 667MHz */ { 0x10, 0x00c000c0 },
1156 };
1157 EPBAR8(0x2c) = timings_by_fsb[fsb][0];
1158 EPBAR32(0x38) = timings_by_fsb[fsb][1];
1159 EPBAR32(0x3c) = timings_by_fsb[fsb][1];
1160}
1161
Patrick Rudolph266a1f72016-06-09 18:13:34 +0200[diff] [blame]1162#define DEFAULT_PCI_MMIO_SIZE 2048
1163#define HOST_BRIDGE PCI_DEVFN(0, 0)
1164
1165static unsigned int get_mmio_size(void)
1166{
1167 const struct device *dev;
1168 const struct northbridge_intel_gm45_config *cfg = NULL;
1169
1170 dev = dev_find_slot(0, HOST_BRIDGE);
1171 if (dev)
1172 cfg = dev->chip_info;
1173
1174 /* If this is zero, it just means devicetree.cb didn't set it */
1175 if (!cfg || cfg->pci_mmio_size == 0)
1176 return DEFAULT_PCI_MMIO_SIZE;
1177 else
1178 return cfg->pci_mmio_size;
1179}
1180
Patrick Georgi2efc8802012-11-06 11:03:53 +0100[diff] [blame]1181/* @prejedec if not zero, set rank size to 128MB and page size to 4KB. */
Vladimir Serbinenko56ae8a02014-08-16 10:59:02 +0200[diff] [blame]1182static void program_memory_map(const dimminfo_t *const dimms, const channel_mode_t mode, const int prejedec, u16 ggc)
Patrick Georgi2efc8802012-11-06 11:03:53 +0100[diff] [blame]1183{
1184 int ch, r;
1185
1186 /* Program rank boundaries (CxDRBy). */
1187 unsigned int base = 0; /* start of next rank in MB */
1188 unsigned int total_mb[2] = { 0, 0 }; /* total memory per channel in MB */
1189 FOR_EACH_CHANNEL(ch) {
1190 if (mode == CHANNEL_MODE_DUAL_INTERLEAVED)
1191 /* In interleaved mode, start every channel from 0. */
1192 base = 0;
1193 for (r = 0; r < RANKS_PER_CHANNEL; r += 2) {
1194 /* Fixed capacity for pre-jedec config. */
1195 const unsigned int rank_capacity_mb =
1196 prejedec ? 128 : dimms[ch].rank_capacity_mb;
1197 u32 reg = 0;
1198
1199 /* Program bounds in CxDRBy. */
1200 IF_RANK_POPULATED(dimms, ch, r) {
1201 base += rank_capacity_mb;
1202 total_mb[ch] += rank_capacity_mb;
1203 }
1204 reg |= CxDRBy_BOUND_MB(r, base);
1205 IF_RANK_POPULATED(dimms, ch, r+1) {
1206 base += rank_capacity_mb;
1207 total_mb[ch] += rank_capacity_mb;
1208 }
1209 reg |= CxDRBy_BOUND_MB(r+1, base);
1210
1211 MCHBAR32(CxDRBy_MCHBAR(ch, r)) = reg;
1212 }
1213 }
1214
1215 /* Program page size (CxDRA). */
1216 FOR_EACH_CHANNEL(ch) {
1217 u32 reg = MCHBAR32(CxDRA_MCHBAR(ch)) & ~CxDRA_PAGESIZE_MASK;
1218 FOR_EACH_POPULATED_RANK_IN_CHANNEL(dimms, ch, r) {
1219 /* Fixed page size for pre-jedec config. */
1220 const unsigned int page_size = /* dimm page size in bytes */
1221 prejedec ? 4096 : dimms[ch].page_size;
1222 reg |= CxDRA_PAGESIZE(r, log2(page_size));
1223 /* deferred to f5_27: reg |= CxDRA_BANKS(r, dimms[ch].banks); */
1224 }
1225 MCHBAR32(CxDRA_MCHBAR(ch)) = reg;
1226 }
1227
1228 /* Calculate memory mapping, all values in MB. */
Vladimir Serbinenko56ae8a02014-08-16 10:59:02 +0200[diff] [blame]1229
1230 u32 uma_sizem = 0;
1231 if (!prejedec) {
1232 if (!(ggc & 2)) {
1233 printk(BIOS_DEBUG, "IGD decoded, subtracting ");
1234
1235 /* Graphics memory */
1236 const u32 gms_sizek = decode_igd_memory_size((ggc >> 4) & 0xf);
1237 printk(BIOS_DEBUG, "%uM UMA", gms_sizek >> 10);
1238
1239 /* GTT Graphics Stolen Memory Size (GGMS) */
1240 const u32 gsm_sizek = decode_igd_gtt_size((ggc >> 8) & 0xf);
1241 printk(BIOS_DEBUG, " and %uM GTT\n", gsm_sizek >> 10);
1242
1243 uma_sizem = (gms_sizek + gsm_sizek) >> 10;
Vladimir Serbinenko56ae8a02014-08-16 10:59:02 +0200[diff] [blame]1244 }
Arthur Heymansd522db02018-08-06 15:50:54 +0200[diff] [blame^]1245 /* TSEG 2M, This amount can easily be covered by SMRR MTRR's,
1246 which requires to have TSEG_BASE aligned to TSEG_SIZE. */
Arthur Heymans8b766052018-01-24 23:25:13 +0100[diff] [blame]1247 u8 reg8 = pci_read_config8(PCI_DEV(0, 0, 0), D0F0_ESMRAMC);
1248 reg8 &= ~0x7;
Arthur Heymansd522db02018-08-06 15:50:54 +0200[diff] [blame^]1249 reg8 |= (1 << 1) | (1 << 0); /* 2M and TSEG_Enable */
Arthur Heymans8b766052018-01-24 23:25:13 +0100[diff] [blame]1250 pci_write_config8(PCI_DEV(0, 0, 0), D0F0_ESMRAMC, reg8);
Arthur Heymansd522db02018-08-06 15:50:54 +0200[diff] [blame^]1251 uma_sizem += 2;
Vladimir Serbinenko56ae8a02014-08-16 10:59:02 +0200[diff] [blame]1252 }
1253
Patrick Rudolph266a1f72016-06-09 18:13:34 +0200[diff] [blame]1254 const unsigned int mmio_size = get_mmio_size();
1255 const unsigned int MMIOstart = 4096 - mmio_size + uma_sizem;
Vladimir Serbinenko9907be42014-08-12 21:51:28 +0200[diff] [blame]1256 const int me_active = pci_read_config8(PCI_DEV(0, 3, 0), PCI_CLASS_REVISION) != 0xff;
1257 const unsigned int ME_SIZE = prejedec || !me_active ? 0 : 32;
Patrick Georgi2efc8802012-11-06 11:03:53 +0100[diff] [blame]1258 const unsigned int usedMEsize = (total_mb[0] != total_mb[1]) ? ME_SIZE : 2 * ME_SIZE;
1259 const unsigned int claimCapable =
1260 !(pci_read_config32(PCI_DEV(0, 0, 0), D0F0_CAPID0 + 4) & (1 << (47 - 32)));
1261
1262 const unsigned int TOM = total_mb[0] + total_mb[1];
1263 unsigned int TOMminusME = TOM - usedMEsize;
1264 unsigned int TOLUD = (TOMminusME < MMIOstart) ? TOMminusME : MMIOstart;
1265 unsigned int TOUUD = TOMminusME;
1266 unsigned int REMAPbase = 0xffff, REMAPlimit = 0;
1267
1268 if (claimCapable && (TOMminusME >= (MMIOstart + 64))) {
1269 /* 64MB alignment: We'll lose some MBs here, if ME is on. */
1270 TOMminusME &= ~(64 - 1);
1271 /* 64MB alignment: Loss will be reclaimed. */
1272 TOLUD &= ~(64 - 1);
1273 if (TOMminusME > 4096) {
1274 REMAPbase = TOMminusME;
1275 REMAPlimit = REMAPbase + (4096 - TOLUD);
1276 } else {
1277 REMAPbase = 4096;
1278 REMAPlimit = REMAPbase + (TOMminusME - TOLUD);
1279 }
1280 TOUUD = REMAPlimit;
1281 /* REMAPlimit is an inclusive bound, all others exclusive. */
1282 REMAPlimit -= 64;
1283 }
1284
1285 pci_write_config16(PCI_DEV(0, 0, 0), D0F0_TOM, (TOM >> 7) & 0x1ff);
1286 pci_write_config16(PCI_DEV(0, 0, 0), D0F0_TOLUD, TOLUD << 4);
1287 pci_write_config16(PCI_DEV(0, 0, 0), D0F0_TOUUD, TOUUD);
1288 pci_write_config16(PCI_DEV(0, 0, 0), D0F0_REMAPBASE, (REMAPbase >> 6) & 0x03ff);
1289 pci_write_config16(PCI_DEV(0, 0, 0), D0F0_REMAPLIMIT, (REMAPlimit >> 6) & 0x03ff);
1290
1291 /* Program channel mode. */
1292 switch (mode) {
1293 case CHANNEL_MODE_SINGLE:
1294 printk(BIOS_DEBUG, "Memory configured in single-channel mode.\n");
1295 MCHBAR32(DCC_MCHBAR) &= ~DCC_INTERLEAVED;
1296 break;
1297 case CHANNEL_MODE_DUAL_ASYNC:
1298 printk(BIOS_DEBUG, "Memory configured in dual-channel assymetric mode.\n");
1299 MCHBAR32(DCC_MCHBAR) &= ~DCC_INTERLEAVED;
1300 break;
1301 case CHANNEL_MODE_DUAL_INTERLEAVED:
1302 printk(BIOS_DEBUG, "Memory configured in dual-channel interleaved mode.\n");
1303 MCHBAR32(DCC_MCHBAR) &= ~(DCC_NO_CHANXOR | (1 << 9));
1304 MCHBAR32(DCC_MCHBAR) |= DCC_INTERLEAVED;
1305 break;
1306 }
1307
1308 printk(BIOS_SPEW, "Memory map:\n"
1309 "TOM = %5uMB\n"
1310 "TOLUD = %5uMB\n"
1311 "TOUUD = %5uMB\n"
1312 "REMAP:\t base = %5uMB\n"
Vladimir Serbinenko9907be42014-08-12 21:51:28 +0200[diff] [blame]1313 "\t limit = %5uMB\n"
1314 "usedMEsize: %dMB\n",
1315 TOM, TOLUD, TOUUD, REMAPbase, REMAPlimit, usedMEsize);
Patrick Georgi2efc8802012-11-06 11:03:53 +0100[diff] [blame]1316}
1317static void prejedec_memory_map(const dimminfo_t *const dimms, channel_mode_t mode)
1318{
1319 /* Never use dual-interleaved mode in pre-jedec config. */
1320 if (CHANNEL_MODE_DUAL_INTERLEAVED == mode)
1321 mode = CHANNEL_MODE_DUAL_ASYNC;
1322
Vladimir Serbinenko56ae8a02014-08-16 10:59:02 +0200[diff] [blame]1323 program_memory_map(dimms, mode, 1, 0);
Patrick Georgi2efc8802012-11-06 11:03:53 +0100[diff] [blame]1324 MCHBAR32(DCC_MCHBAR) |= DCC_NO_CHANXOR;
1325}
1326
1327static void ddr3_select_clock_mux(const mem_clock_t ddr3clock,
1328 const dimminfo_t *const dimms,
1329 const stepping_t stepping)
1330{
1331 const int clk1067 = (ddr3clock == MEM_CLOCK_1067MT);
1332 const int cardF[] = { CHANNEL_IS_CARDF(dimms, 0), CHANNEL_IS_CARDF(dimms, 1) };
1333
1334 int ch;
1335
1336 if (stepping < STEPPING_B1)
1337 die("Stepping <B1 unsupported in clock-multiplexer selection.\n");
1338
1339 FOR_EACH_POPULATED_CHANNEL(dimms, ch) {
1340 int mixed = 0;
1341 if ((1 == ch) && (!CHANNEL_IS_POPULATED(dimms, 0) || (cardF[0] != cardF[1])))
1342 mixed = 4 << 11;
1343 const unsigned int b = 0x14b0 + (ch * 0x0100);
1344 MCHBAR32(b+0x1c) = (MCHBAR32(b+0x1c) & ~(7 << 11)) |
1345 ((( cardF[ch])?1:0) << 11) | mixed;
1346 MCHBAR32(b+0x18) = (MCHBAR32(b+0x18) & ~(7 << 11)) | mixed;
1347 MCHBAR32(b+0x14) = (MCHBAR32(b+0x14) & ~(7 << 11)) |
1348 (((!clk1067 && !cardF[ch])?0:1) << 11) | mixed;
1349 MCHBAR32(b+0x10) = (MCHBAR32(b+0x10) & ~(7 << 11)) |
1350 ((( clk1067 && !cardF[ch])?1:0) << 11) | mixed;
1351 MCHBAR32(b+0x0c) = (MCHBAR32(b+0x0c) & ~(7 << 11)) |
1352 ((( cardF[ch])?3:2) << 11) | mixed;
1353 MCHBAR32(b+0x08) = (MCHBAR32(b+0x08) & ~(7 << 11)) |
1354 (2 << 11) | mixed;
1355 MCHBAR32(b+0x04) = (MCHBAR32(b+0x04) & ~(7 << 11)) |
1356 (((!clk1067 && !cardF[ch])?2:3) << 11) | mixed;
1357 MCHBAR32(b+0x00) = (MCHBAR32(b+0x00) & ~(7 << 11)) |
1358 ((( clk1067 && !cardF[ch])?3:2) << 11) | mixed;
1359 }
1360}
1361static void ddr3_write_io_init(const mem_clock_t ddr3clock,
1362 const dimminfo_t *const dimms,
1363 const stepping_t stepping,
1364 const int sff)
1365{
1366 const int a1step = stepping >= STEPPING_CONVERSION_A1;
1367 const int cardF[] = { CHANNEL_IS_CARDF(dimms, 0), CHANNEL_IS_CARDF(dimms, 1) };
1368
1369 int ch;
1370
1371 if (stepping < STEPPING_B1)
1372 die("Stepping <B1 unsupported in write i/o initialization.\n");
1373 if (sff)
1374 die("SFF platform unsupported in write i/o initialization.\n");
1375
1376 static const u32 ddr3_667_800_by_stepping_ddr3_and_card[][2][2][4] = {
1377 { /* Stepping B3 and below */
1378 { /* 667 MHz */
1379 { 0xa3255008, 0x26888209, 0x26288208, 0x6188040f },
1380 { 0x7524240b, 0xa5255608, 0x232b8508, 0x5528040f },
1381 },
1382 { /* 800 MHz */
1383 { 0xa6255308, 0x26888209, 0x212b7508, 0x6188040f },
1384 { 0x7524240b, 0xa6255708, 0x132b7508, 0x5528040f },
1385 },
1386 },
1387 { /* Conversion stepping A1 and above */
1388 { /* 667 MHz */
1389 { 0xc5257208, 0x26888209, 0x26288208, 0x6188040f },
1390 { 0x7524240b, 0xc5257608, 0x232b8508, 0x5528040f },
1391 },
1392 { /* 800 MHz */
1393 { 0xb6256308, 0x26888209, 0x212b7508, 0x6188040f },
1394 { 0x7524240b, 0xb6256708, 0x132b7508, 0x5528040f },
1395 }
1396 }};
1397
1398 static const u32 ddr3_1067_by_channel_and_card[][2][4] = {
1399 { /* Channel A */
1400 { 0xb2254708, 0x002b7408, 0x132b8008, 0x7228060f },
1401 { 0xb0255008, 0xa4254108, 0x4528b409, 0x9428230f },
1402 },
1403 { /* Channel B */
1404 { 0xa4254208, 0x022b6108, 0x132b8208, 0x9228210f },
1405 { 0x6024140b, 0x92244408, 0x252ba409, 0x9328360c },
1406 },
1407 };
1408
1409 FOR_EACH_POPULATED_CHANNEL(dimms, ch) {
1410 if ((1 == ch) && CHANNEL_IS_POPULATED(dimms, 0) && (cardF[0] == cardF[1]))
1411 /* Only write if second channel population differs. */
1412 continue;
1413 const u32 *const data = (ddr3clock != MEM_CLOCK_1067MT)
1414 ? ddr3_667_800_by_stepping_ddr3_and_card[a1step][2 - ddr3clock][cardF[ch]]
1415 : ddr3_1067_by_channel_and_card[ch][cardF[ch]];
1416 MCHBAR32(CxWRTy_MCHBAR(ch, 0)) = data[0];
1417 MCHBAR32(CxWRTy_MCHBAR(ch, 1)) = data[1];
1418 MCHBAR32(CxWRTy_MCHBAR(ch, 2)) = data[2];
1419 MCHBAR32(CxWRTy_MCHBAR(ch, 3)) = data[3];
1420 }
1421
1422 MCHBAR32(0x1490) = 0x00e70067;
1423 MCHBAR32(0x1494) = 0x000d8000;
1424 MCHBAR32(0x1590) = 0x00e70067;
1425 MCHBAR32(0x1594) = 0x000d8000;
1426}
1427static void ddr3_read_io_init(const mem_clock_t ddr3clock,
1428 const dimminfo_t *const dimms,
1429 const int sff)
1430{
1431 int ch;
1432
1433 FOR_EACH_POPULATED_CHANNEL(dimms, ch) {
1434 u32 addr, tmp;
1435 const unsigned int base = 0x14b0 + (ch * 0x0100);
1436 for (addr = base + 0x1c; addr >= base; addr -= 4) {
1437 tmp = MCHBAR32(addr);
1438 tmp &= ~((3 << 25) | (1 << 8) | (7 << 16) | (0xf << 20) | (1 << 27));
1439 tmp |= (1 << 27);
1440 switch (ddr3clock) {
1441 case MEM_CLOCK_667MT:
1442 tmp |= (1 << 16) | (4 << 20);
1443 break;
1444 case MEM_CLOCK_800MT:
1445 tmp |= (2 << 16) | (3 << 20);
1446 break;
1447 case MEM_CLOCK_1067MT:
1448 if (!sff)
1449 tmp |= (2 << 16) | (1 << 20);
1450 else
1451 tmp |= (2 << 16) | (2 << 20);
1452 break;
1453 default:
1454 die("Wrong clock");
1455 }
1456 MCHBAR32(addr) = tmp;
1457 }
1458 }
1459}
1460
1461static void memory_io_init(const mem_clock_t ddr3clock,
1462 const dimminfo_t *const dimms,
1463 const stepping_t stepping,
1464 const int sff)
1465{
1466 u32 tmp;
1467
1468 if (stepping < STEPPING_B1)
1469 die("Stepping <B1 unsupported in "
1470 "system-memory i/o initialization.\n");
1471
1472 tmp = MCHBAR32(0x1400);
1473 tmp &= ~(3<<13);
1474 tmp |= (1<<9) | (1<<13);
1475 MCHBAR32(0x1400) = tmp;
1476
1477 tmp = MCHBAR32(0x140c);
1478 tmp &= ~(0xff | (1<<11) | (1<<12) |
1479 (1<<16) | (1<<18) | (1<<27) | (0xf<<28));
1480 tmp |= (1<<7) | (1<<11) | (1<<16);
1481 switch (ddr3clock) {
1482 case MEM_CLOCK_667MT:
1483 tmp |= 9 << 28;
1484 break;
1485 case MEM_CLOCK_800MT:
1486 tmp |= 7 << 28;
1487 break;
1488 case MEM_CLOCK_1067MT:
1489 tmp |= 8 << 28;
1490 break;
1491 }
1492 MCHBAR32(0x140c) = tmp;
1493
1494 MCHBAR32(0x1440) &= ~1;
1495
1496 tmp = MCHBAR32(0x1414);
1497 tmp &= ~((1<<20) | (7<<11) | (0xf << 24) | (0xf << 16));
1498 tmp |= (3<<11);
1499 switch (ddr3clock) {
1500 case MEM_CLOCK_667MT:
1501 tmp |= (2 << 24) | (10 << 16);
1502 break;
1503 case MEM_CLOCK_800MT:
1504 tmp |= (3 << 24) | (7 << 16);
1505 break;
1506 case MEM_CLOCK_1067MT:
1507 tmp |= (4 << 24) | (4 << 16);
1508 break;
1509 }
1510 MCHBAR32(0x1414) = tmp;
1511
1512 MCHBAR32(0x1418) &= ~((1<<3) | (1<<11) | (1<<19) | (1<<27));
1513
1514 MCHBAR32(0x141c) &= ~((1<<3) | (1<<11) | (1<<19) | (1<<27));
1515
1516 MCHBAR32(0x1428) |= 1<<14;
1517
1518 tmp = MCHBAR32(0x142c);
1519 tmp &= ~((0xf << 8) | (0x7 << 20) | 0xf | (0xf << 24));
1520 tmp |= (0x3 << 20) | (5 << 24);
1521 switch (ddr3clock) {
1522 case MEM_CLOCK_667MT:
1523 tmp |= (2 << 8) | 0xc;
1524 break;
1525 case MEM_CLOCK_800MT:
1526 tmp |= (3 << 8) | 0xa;
1527 break;
1528 case MEM_CLOCK_1067MT:
1529 tmp |= (4 << 8) | 0x7;
1530 break;
1531 }
1532 MCHBAR32(0x142c) = tmp;
1533
1534 tmp = MCHBAR32(0x400);
1535 tmp &= ~((3 << 4) | (3 << 16) | (3 << 30));
1536 tmp |= (2 << 4) | (2 << 16);
1537 MCHBAR32(0x400) = tmp;
1538
1539 MCHBAR32(0x404) &= ~(0xf << 20);
1540
1541 MCHBAR32(0x40c) &= ~(1 << 6);
1542
1543 tmp = MCHBAR32(0x410);
1544 tmp &= ~(7 << 28);
1545 tmp |= 2 << 28;
1546 MCHBAR32(0x410) = tmp;
1547
1548 tmp = MCHBAR32(0x41c);
1549 tmp &= ~0x77;
1550 tmp |= 0x11;
1551 MCHBAR32(0x41c) = tmp;
1552
1553 ddr3_select_clock_mux(ddr3clock, dimms, stepping);
1554
1555 ddr3_write_io_init(ddr3clock, dimms, stepping, sff);
1556
1557 ddr3_read_io_init(ddr3clock, dimms, sff);
1558}
1559
1560static void jedec_init(const timings_t *const timings,
1561 const dimminfo_t *const dimms)
1562{
1563 if ((timings->tWR < 5) || (timings->tWR > 12))
1564 die("tWR value unsupported in Jedec initialization.\n");
1565
1566 /* Pre-jedec settings */
1567 MCHBAR32(0x40) |= (1 << 1);
1568 MCHBAR32(0x230) |= (3 << 1);
1569 MCHBAR32(0x238) |= (3 << 24);
1570 MCHBAR32(0x23c) |= (3 << 24);
1571
1572 /* Normal write pointer operation */
1573 MCHBAR32(0x14f0) |= (1 << 9);
1574 MCHBAR32(0x15f0) |= (1 << 9);
1575
1576 MCHBAR32(DCC_MCHBAR) = (MCHBAR32(DCC_MCHBAR) & ~DCC_CMD_MASK) | DCC_CMD_NOP;
1577
1578 u8 reg8 = pci_read_config8(PCI_DEV(0, 0, 0), 0xf0);
1579 pci_write_config8(PCI_DEV(0, 0, 0), 0xf0, reg8 & ~(1 << 2));
1580 reg8 = pci_read_config8(PCI_DEV(0, 0, 0), 0xf0);
1581 pci_write_config8(PCI_DEV(0, 0, 0), 0xf0, reg8 | (1 << 2));
1582 udelay(2);
1583
1584 /* 5 6 7 8 9 10 11 12 */
1585 static const u8 wr_lut[] = { 1, 2, 3, 4, 5, 5, 6, 6 };
1586
1587 const int WL = ((timings->tWL - 5) & 7) << 6;
1588 const int ODT_120OHMS = (1 << 9);
1589 const int ODS_34OHMS = (1 << 4);
1590 const int WR = (wr_lut[timings->tWR - 5] & 7) << 12;
1591 const int DLL1 = 1 << 11;
1592 const int CAS = ((timings->CAS - 4) & 7) << 7;
1593 const int INTERLEAVED = 1 << 6;/* This is READ Burst Type == interleaved. */
1594
1595 int ch, r;
1596 FOR_EACH_POPULATED_RANK(dimms, ch, r) {
1597 /* We won't do this in dual-interleaved mode,
1598 so don't care about the offset. */
1599 const u32 rankaddr = raminit_get_rank_addr(ch, r);
Nico Huber0624f922017-04-15 15:57:28 +0200[diff] [blame]1600 printk(BIOS_DEBUG, "JEDEC init @0x%08x\n", rankaddr);
Patrick Georgi2efc8802012-11-06 11:03:53 +0100[diff] [blame]1601 MCHBAR32(DCC_MCHBAR) = (MCHBAR32(DCC_MCHBAR) & ~DCC_SET_EREG_MASK) | DCC_SET_EREGx(2);
Kevin Paul Herbertbde6d302014-12-24 18:43:20 -0800[diff] [blame]1602 read32((u32 *)(rankaddr | WL));
Patrick Georgi2efc8802012-11-06 11:03:53 +0100[diff] [blame]1603 MCHBAR32(DCC_MCHBAR) = (MCHBAR32(DCC_MCHBAR) & ~DCC_SET_EREG_MASK) | DCC_SET_EREGx(3);
Kevin Paul Herbertbde6d302014-12-24 18:43:20 -0800[diff] [blame]1604 read32((u32 *)rankaddr);
Patrick Georgi2efc8802012-11-06 11:03:53 +0100[diff] [blame]1605 MCHBAR32(DCC_MCHBAR) = (MCHBAR32(DCC_MCHBAR) & ~DCC_SET_EREG_MASK) | DCC_SET_EREGx(1);
Kevin Paul Herbertbde6d302014-12-24 18:43:20 -0800[diff] [blame]1606 read32((u32 *)(rankaddr | ODT_120OHMS | ODS_34OHMS));
Patrick Georgi2efc8802012-11-06 11:03:53 +0100[diff] [blame]1607 MCHBAR32(DCC_MCHBAR) = (MCHBAR32(DCC_MCHBAR) & ~DCC_CMD_MASK) | DCC_SET_MREG;
Kevin Paul Herbertbde6d302014-12-24 18:43:20 -0800[diff] [blame]1608 read32((u32 *)(rankaddr | WR | DLL1 | CAS | INTERLEAVED));
Patrick Georgi2efc8802012-11-06 11:03:53 +0100[diff] [blame]1609 MCHBAR32(DCC_MCHBAR) = (MCHBAR32(DCC_MCHBAR) & ~DCC_CMD_MASK) | DCC_SET_MREG;
Kevin Paul Herbertbde6d302014-12-24 18:43:20 -0800[diff] [blame]1610 read32((u32 *)(rankaddr | WR | CAS | INTERLEAVED));
Patrick Georgi2efc8802012-11-06 11:03:53 +0100[diff] [blame]1611 }
1612}
1613
1614static void ddr3_calibrate_zq(void) {
1615 udelay(2);
1616
1617 u32 tmp = MCHBAR32(DCC_MCHBAR);
1618 tmp &= ~(7 << 16);
1619 tmp |= (5 << 16); /* ZQ calibration mode */
1620 MCHBAR32(DCC_MCHBAR) = tmp;
1621
1622 MCHBAR32(CxDRT6_MCHBAR(0)) |= (1 << 3);
1623 MCHBAR32(CxDRT6_MCHBAR(1)) |= (1 << 3);
1624
1625 udelay(1);
1626
1627 MCHBAR32(CxDRT6_MCHBAR(0)) &= ~(1 << 3);
1628 MCHBAR32(CxDRT6_MCHBAR(1)) &= ~(1 << 3);
1629
1630 MCHBAR32(DCC_MCHBAR) |= (7 << 16); /* Normal operation */
1631}
1632
1633static void post_jedec_sequence(const int cores) {
1634 const int quadcore = cores == 4;
1635
1636 MCHBAR32(0x0040) &= ~(1 << 1);
1637 MCHBAR32(0x0230) &= ~(3 << 1);
1638 MCHBAR32(0x0230) |= 1 << 15;
1639 MCHBAR32(0x0230) &= ~(1 << 19);
1640 MCHBAR32(0x1250) = 0x6c4;
1641 MCHBAR32(0x1350) = 0x6c4;
1642 MCHBAR32(0x1254) = 0x871a066d;
1643 MCHBAR32(0x1354) = 0x871a066d;
1644 MCHBAR32(0x0238) |= 1 << 26;
1645 MCHBAR32(0x0238) &= ~(3 << 24);
1646 MCHBAR32(0x0238) |= 1 << 23;
1647 MCHBAR32(0x0238) = (MCHBAR32(0x238) & ~(7 << 20)) | (3 << 20);
1648 MCHBAR32(0x0238) = (MCHBAR32(0x238) & ~(7 << 17)) | (6 << 17);
1649 MCHBAR32(0x0238) = (MCHBAR32(0x238) & ~(7 << 14)) | (6 << 14);
1650 MCHBAR32(0x0238) = (MCHBAR32(0x238) & ~(7 << 11)) | (6 << 11);
1651 MCHBAR32(0x0238) = (MCHBAR32(0x238) & ~(7 << 8)) | (6 << 8);
1652 MCHBAR32(0x023c) &= ~(3 << 24);
1653 MCHBAR32(0x023c) &= ~(1 << 23);
1654 MCHBAR32(0x023c) = (MCHBAR32(0x23c) & ~(7 << 20)) | (3 << 20);
1655 MCHBAR32(0x023c) = (MCHBAR32(0x23c) & ~(7 << 17)) | (6 << 17);
1656 MCHBAR32(0x023c) = (MCHBAR32(0x23c) & ~(7 << 14)) | (6 << 14);
1657 MCHBAR32(0x023c) = (MCHBAR32(0x23c) & ~(7 << 11)) | (6 << 11);
1658 MCHBAR32(0x023c) = (MCHBAR32(0x23c) & ~(7 << 8)) | (6 << 8);
1659
1660 if (quadcore) {
1661 MCHBAR32(0xb14) |= (0xbfbf << 16);
1662 }
1663}
1664
1665static void dram_optimizations(const timings_t *const timings,
1666 const dimminfo_t *const dimms)
1667{
1668 int ch;
1669
1670 FOR_EACH_POPULATED_CHANNEL(dimms, ch) {
1671 const unsigned int mchbar = CxDRC1_MCHBAR(ch);
1672 u32 cxdrc1 = MCHBAR32(mchbar);
1673 cxdrc1 &= ~CxDRC1_SSDS_MASK;
1674 if (dimms[ch].ranks == 1)
1675 cxdrc1 |= CxDRC1_SS;
1676 else
1677 cxdrc1 |= CxDRC1_DS;
1678 MCHBAR32(mchbar) = cxdrc1;
1679 }
1680}
1681
1682u32 raminit_get_rank_addr(unsigned int channel, unsigned int rank)
1683{
1684 if (!channel && !rank)
1685 return 0; /* Address of first rank */
1686
1687 /* Read the bound of the previous rank. */
1688 if (rank > 0) {
1689 rank--;
1690 } else {
1691 rank = 3; /* Highest rank per channel */
1692 channel--;
1693 }
1694 const u32 reg = MCHBAR32(CxDRBy_MCHBAR(channel, rank));
1695 /* Bound is in 32MB. */
1696 return ((reg & CxDRBy_BOUND_MASK(rank)) >> CxDRBy_BOUND_SHIFT(rank)) << 25;
1697}
1698
1699void raminit_reset_readwrite_pointers(void) {
1700 MCHBAR32(0x1234) |= (1 << 6);
1701 MCHBAR32(0x1234) &= ~(1 << 6);
1702 MCHBAR32(0x1334) |= (1 << 6);
1703 MCHBAR32(0x1334) &= ~(1 << 6);
1704 MCHBAR32(0x14f0) &= ~(1 << 9);
1705 MCHBAR32(0x14f0) |= (1 << 9);
1706 MCHBAR32(0x14f0) |= (1 << 10);
1707 MCHBAR32(0x15f0) &= ~(1 << 9);
1708 MCHBAR32(0x15f0) |= (1 << 9);
1709 MCHBAR32(0x15f0) |= (1 << 10);
1710}
1711
1712void raminit(sysinfo_t *const sysinfo, const int s3resume)
1713{
1714 const dimminfo_t *const dimms = sysinfo->dimms;
1715 const timings_t *const timings = &sysinfo->selected_timings;
Patrick Georgi2efc8802012-11-06 11:03:53 +0100[diff] [blame]1716
1717 int ch;
1718 u8 reg8;
1719
Arthur Heymans049347f2017-05-12 11:54:08 +0200[diff] [blame]1720 timestamp_add_now(TS_BEFORE_INITRAM);
Patrick Georgi2efc8802012-11-06 11:03:53 +0100[diff] [blame]1721
1722 /* Wait for some bit, maybe TXT clear. */
1723 if (sysinfo->txt_enabled) {
Kevin Paul Herbertbde6d302014-12-24 18:43:20 -0800[diff] [blame]1724 while (!(read8((u8 *)0xfed40000) & (1 << 7))) {}
Patrick Georgi2efc8802012-11-06 11:03:53 +0100[diff] [blame]1725 }
1726
1727 /* Enable SMBUS. */
1728 enable_smbus();
1729
1730 /* Collect information about DIMMs and find common settings. */
1731 collect_dimm_config(sysinfo);
1732
1733 /* Check for bad warm boot. */
1734 reset_on_bad_warmboot();
1735
1736
1737 /***** From now on, program according to collected infos: *****/
1738
1739 /* Program DRAM type. */
1740 switch (sysinfo->spd_type) {
1741 case DDR2:
1742 MCHBAR8(0x1434) |= (1 << 7);
1743 break;
1744 case DDR3:
1745 MCHBAR8(0x1434) |= (3 << 0);
1746 break;
1747 }
1748
1749 /* Program system memory frequency. */
1750 set_system_memory_frequency(timings);
1751 /* Program IGD memory frequency. */
1752 set_igd_memory_frequencies(sysinfo);
1753
1754 /* Configure DRAM control mode for populated channels. */
1755 configure_dram_control_mode(timings, dimms);
1756
1757 /* Initialize RCOMP. */
Nico Huber5aaeb272015-12-30 00:17:27 +0100[diff] [blame]1758 rcomp_initialization(sysinfo->stepping, sysinfo->sff);
Patrick Georgi2efc8802012-11-06 11:03:53 +0100[diff] [blame]1759
1760 /* Power-up DRAM. */
1761 dram_powerup(s3resume);
1762 /* Program DRAM timings. */
1763 dram_program_timings(timings);
1764 /* Program number of banks. */
1765 dram_program_banks(dimms);
1766 /* Enable DRAM clock pairs for populated DIMMs. */
1767 FOR_EACH_POPULATED_CHANNEL(dimms, ch)
1768 MCHBAR32(CxDCLKDIS_MCHBAR(ch)) |= CxDCLKDIS_ENABLE;
1769
1770 /* Enable On-Die Termination. */
Nico Huber5aaeb272015-12-30 00:17:27 +0100[diff] [blame]1771 odt_setup(timings, sysinfo->sff);
Patrick Georgi2efc8802012-11-06 11:03:53 +0100[diff] [blame]1772 /* Miscellaneous settings. */
1773 misc_settings(timings, sysinfo->stepping);
1774 /* Program clock crossing registers. */
1775 clock_crossing_setup(timings->fsb_clock, timings->mem_clock, dimms);
1776 /* Program egress VC1 timings. */
1777 vc1_program_timings(timings->fsb_clock);
1778 /* Perform system-memory i/o initialization. */
Nico Huber5aaeb272015-12-30 00:17:27 +0100[diff] [blame]1779 memory_io_init(timings->mem_clock, dimms,
1780 sysinfo->stepping, sysinfo->sff);
Patrick Georgi2efc8802012-11-06 11:03:53 +0100[diff] [blame]1781
1782 /* Initialize memory map with dummy values of 128MB per rank with a
1783 page size of 4KB. This makes the JEDEC initialization code easier. */
1784 prejedec_memory_map(dimms, timings->channel_mode);
1785 if (!s3resume)
1786 /* Perform JEDEC initialization of DIMMS. */
1787 jedec_init(timings, dimms);
1788 /* Some programming steps after JEDEC initialization. */
1789 post_jedec_sequence(sysinfo->cores);
1790
1791 /* Announce normal operation, initialization completed. */
1792 MCHBAR32(DCC_MCHBAR) |= (0x7 << 16) | (0x1 << 19);
1793 reg8 = pci_read_config8(PCI_DEV(0, 0, 0), 0xf0);
1794 pci_write_config8(PCI_DEV(0, 0, 0), 0xf0, reg8 | (1 << 2));
1795 reg8 = pci_read_config8(PCI_DEV(0, 0, 0), 0xf0);
1796 pci_write_config8(PCI_DEV(0, 0, 0), 0xf0, reg8 & ~(1 << 2));
1797
1798
1799 /* Take a breath (the reader). */
1800
1801
1802 /* Perform ZQ calibration for DDR3. */
1803 ddr3_calibrate_zq();
1804
1805 /* Perform receive-enable calibration. */
1806 raminit_receive_enable_calibration(timings, dimms);
1807 /* Lend clock values from receive-enable calibration. */
Jonathan Neuschäfer2f828eb2018-02-12 12:00:44 +0100[diff] [blame]1808 MCHBAR32(CxDRT5_MCHBAR(0)) =
1809 (MCHBAR32(CxDRT5_MCHBAR(0)) & ~(0xf0)) |
1810 ((((MCHBAR32(CxDRT3_MCHBAR(0)) >> 7) - 1) & 0xf) << 4);
1811 MCHBAR32(CxDRT5_MCHBAR(1)) =
1812 (MCHBAR32(CxDRT5_MCHBAR(1)) & ~(0xf0)) |
1813 ((((MCHBAR32(CxDRT3_MCHBAR(1)) >> 7) - 1) & 0xf) << 4);
Patrick Georgi2efc8802012-11-06 11:03:53 +0100[diff] [blame]1814
1815 /* Perform read/write training for high clock rate. */
1816 if (timings->mem_clock == MEM_CLOCK_1067MT) {
1817 raminit_read_training(dimms, s3resume);
1818 raminit_write_training(timings->mem_clock, dimms, s3resume);
1819 }
1820
Vladimir Serbinenko56ae8a02014-08-16 10:59:02 +0200[diff] [blame]1821 igd_compute_ggc(sysinfo);
1822
Patrick Georgi2efc8802012-11-06 11:03:53 +0100[diff] [blame]1823 /* Program final memory map (with real values). */
Vladimir Serbinenko56ae8a02014-08-16 10:59:02 +0200[diff] [blame]1824 program_memory_map(dimms, timings->channel_mode, 0, sysinfo->ggc);
Patrick Georgi2efc8802012-11-06 11:03:53 +0100[diff] [blame]1825
1826 /* Some last optimizations. */
1827 dram_optimizations(timings, dimms);
1828
Elyes HAOUAS3d450002018-08-09 18:55:58 +0200[diff] [blame]1829 /* Mark raminit being finished. :-) */
Patrick Georgi2efc8802012-11-06 11:03:53 +0100[diff] [blame]1830 u8 tmp8 = pci_read_config8(PCI_DEV(0, 0x1f, 0), 0xa2) & ~(1 << 7);
1831 pci_write_config8(PCI_DEV(0, 0x1f, 0), 0xa2, tmp8);
Vladimir Serbinenko56ae8a02014-08-16 10:59:02 +0200[diff] [blame]1832
1833 raminit_thermal(sysinfo);
1834 init_igd(sysinfo);
Arthur Heymans049347f2017-05-12 11:54:08 +0200[diff] [blame]1835
1836 timestamp_add_now(TS_AFTER_INITRAM);
Patrick Georgi2efc8802012-11-06 11:03:53 +0100[diff] [blame]1837}