eeprom.c 8.4 KB

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  1. // SPDX-License-Identifier: GPL-2.0-only
  2. /*
  3. * Copyright (C) 2014 Felix Fietkau <nbd@openwrt.org>
  4. * Copyright (C) 2015 Jakub Kicinski <kubakici@wp.pl>
  5. * Copyright (C) 2018 Stanislaw Gruszka <stf_xl@wp.pl>
  6. */
  7. #include <linux/module.h>
  8. #include <linux/of.h>
  9. #include <linux/mtd/mtd.h>
  10. #include <linux/mtd/partitions.h>
  11. #include <linux/etherdevice.h>
  12. #include <linux/unaligned.h>
  13. #include "mt76x0.h"
  14. #include "eeprom.h"
  15. #include "../mt76x02_phy.h"
  16. #define MT_MAP_READS DIV_ROUND_UP(MT_EFUSE_USAGE_MAP_SIZE, 16)
  17. static int
  18. mt76x0_efuse_physical_size_check(struct mt76x02_dev *dev)
  19. {
  20. u8 data[MT_MAP_READS * 16];
  21. int ret, i;
  22. u32 start = 0, end = 0, cnt_free;
  23. ret = mt76x02_get_efuse_data(dev, MT_EE_USAGE_MAP_START, data,
  24. sizeof(data), MT_EE_PHYSICAL_READ);
  25. if (ret)
  26. return ret;
  27. for (i = 0; i < MT_EFUSE_USAGE_MAP_SIZE; i++)
  28. if (!data[i]) {
  29. if (!start)
  30. start = MT_EE_USAGE_MAP_START + i;
  31. end = MT_EE_USAGE_MAP_START + i;
  32. }
  33. cnt_free = end - start + 1;
  34. if (MT_EFUSE_USAGE_MAP_SIZE - cnt_free < 5) {
  35. dev_err(dev->mt76.dev,
  36. "driver does not support default EEPROM\n");
  37. return -EINVAL;
  38. }
  39. return 0;
  40. }
  41. static void mt76x0_set_chip_cap(struct mt76x02_dev *dev)
  42. {
  43. u16 nic_conf0 = mt76x02_eeprom_get(dev, MT_EE_NIC_CONF_0);
  44. u16 nic_conf1 = mt76x02_eeprom_get(dev, MT_EE_NIC_CONF_1);
  45. mt76x02_eeprom_parse_hw_cap(dev);
  46. dev_dbg(dev->mt76.dev, "2GHz %d 5GHz %d\n",
  47. dev->mphy.cap.has_2ghz, dev->mphy.cap.has_5ghz);
  48. if (dev->no_2ghz) {
  49. dev->mphy.cap.has_2ghz = false;
  50. dev_dbg(dev->mt76.dev, "mask out 2GHz support\n");
  51. }
  52. if (is_mt7630(dev)) {
  53. dev->mphy.cap.has_5ghz = false;
  54. dev_dbg(dev->mt76.dev, "mask out 5GHz support\n");
  55. }
  56. if (!mt76x02_field_valid(nic_conf1 & 0xff))
  57. nic_conf1 &= 0xff00;
  58. if (nic_conf1 & MT_EE_NIC_CONF_1_HW_RF_CTRL)
  59. dev_dbg(dev->mt76.dev,
  60. "driver does not support HW RF ctrl\n");
  61. if (!mt76x02_field_valid(nic_conf0 >> 8))
  62. return;
  63. if (FIELD_GET(MT_EE_NIC_CONF_0_RX_PATH, nic_conf0) > 1 ||
  64. FIELD_GET(MT_EE_NIC_CONF_0_TX_PATH, nic_conf0) > 1)
  65. dev_err(dev->mt76.dev, "invalid tx-rx stream\n");
  66. }
  67. static void mt76x0_set_temp_offset(struct mt76x02_dev *dev)
  68. {
  69. u8 val;
  70. val = mt76x02_eeprom_get(dev, MT_EE_2G_TARGET_POWER) >> 8;
  71. if (mt76x02_field_valid(val))
  72. dev->cal.rx.temp_offset = mt76x02_sign_extend(val, 8);
  73. else
  74. dev->cal.rx.temp_offset = -10;
  75. }
  76. static void mt76x0_set_freq_offset(struct mt76x02_dev *dev)
  77. {
  78. struct mt76x02_rx_freq_cal *caldata = &dev->cal.rx;
  79. u8 val;
  80. val = mt76x02_eeprom_get(dev, MT_EE_FREQ_OFFSET);
  81. if (!mt76x02_field_valid(val))
  82. val = 0;
  83. caldata->freq_offset = val;
  84. val = mt76x02_eeprom_get(dev, MT_EE_TSSI_BOUND4) >> 8;
  85. if (!mt76x02_field_valid(val))
  86. val = 0;
  87. caldata->freq_offset -= mt76x02_sign_extend(val, 8);
  88. }
  89. void mt76x0_read_rx_gain(struct mt76x02_dev *dev)
  90. {
  91. struct ieee80211_channel *chan = dev->mphy.chandef.chan;
  92. struct mt76x02_rx_freq_cal *caldata = &dev->cal.rx;
  93. s8 val, lna_5g[3], lna_2g;
  94. u16 rssi_offset;
  95. int i;
  96. mt76x02_get_rx_gain(dev, chan->band, &rssi_offset, &lna_2g, lna_5g);
  97. caldata->lna_gain = mt76x02_get_lna_gain(dev, &lna_2g, lna_5g, chan);
  98. for (i = 0; i < ARRAY_SIZE(caldata->rssi_offset); i++) {
  99. val = rssi_offset >> (8 * i);
  100. if (val < -10 || val > 10)
  101. val = 0;
  102. caldata->rssi_offset[i] = val;
  103. }
  104. }
  105. static s8 mt76x0_get_delta(struct mt76x02_dev *dev)
  106. {
  107. struct cfg80211_chan_def *chandef = &dev->mphy.chandef;
  108. u8 val;
  109. if (chandef->width == NL80211_CHAN_WIDTH_80) {
  110. val = mt76x02_eeprom_get(dev, MT_EE_5G_TARGET_POWER) >> 8;
  111. } else if (chandef->width == NL80211_CHAN_WIDTH_40) {
  112. u16 data;
  113. data = mt76x02_eeprom_get(dev, MT_EE_TX_POWER_DELTA_BW40);
  114. if (chandef->chan->band == NL80211_BAND_5GHZ)
  115. val = data >> 8;
  116. else
  117. val = data;
  118. } else {
  119. return 0;
  120. }
  121. return mt76x02_rate_power_val(val);
  122. }
  123. void mt76x0_get_tx_power_per_rate(struct mt76x02_dev *dev,
  124. struct ieee80211_channel *chan,
  125. struct mt76x02_rate_power *t)
  126. {
  127. bool is_2ghz = chan->band == NL80211_BAND_2GHZ;
  128. u16 val, addr;
  129. s8 delta;
  130. memset(t, 0, sizeof(*t));
  131. /* cck 1M, 2M, 5.5M, 11M */
  132. val = mt76x02_eeprom_get(dev, MT_EE_TX_POWER_BYRATE_BASE);
  133. t->cck[0] = t->cck[1] = s6_to_s8(val);
  134. t->cck[2] = t->cck[3] = s6_to_s8(val >> 8);
  135. /* ofdm 6M, 9M, 12M, 18M */
  136. addr = is_2ghz ? MT_EE_TX_POWER_BYRATE_BASE + 2 : 0x120;
  137. val = mt76x02_eeprom_get(dev, addr);
  138. t->ofdm[0] = t->ofdm[1] = s6_to_s8(val);
  139. t->ofdm[2] = t->ofdm[3] = s6_to_s8(val >> 8);
  140. /* ofdm 24M, 36M, 48M, 54M */
  141. addr = is_2ghz ? MT_EE_TX_POWER_BYRATE_BASE + 4 : 0x122;
  142. val = mt76x02_eeprom_get(dev, addr);
  143. t->ofdm[4] = t->ofdm[5] = s6_to_s8(val);
  144. t->ofdm[6] = t->ofdm[7] = s6_to_s8(val >> 8);
  145. /* ht-vht mcs 1ss 0, 1, 2, 3 */
  146. addr = is_2ghz ? MT_EE_TX_POWER_BYRATE_BASE + 6 : 0x124;
  147. val = mt76x02_eeprom_get(dev, addr);
  148. t->ht[0] = t->ht[1] = s6_to_s8(val);
  149. t->ht[2] = t->ht[3] = s6_to_s8(val >> 8);
  150. /* ht-vht mcs 1ss 4, 5, 6 */
  151. addr = is_2ghz ? MT_EE_TX_POWER_BYRATE_BASE + 8 : 0x126;
  152. val = mt76x02_eeprom_get(dev, addr);
  153. t->ht[4] = t->ht[5] = s6_to_s8(val);
  154. t->ht[6] = t->ht[7] = s6_to_s8(val >> 8);
  155. /* vht mcs 8, 9 5GHz */
  156. val = mt76x02_eeprom_get(dev, 0x12c);
  157. t->vht[0] = s6_to_s8(val);
  158. t->vht[1] = s6_to_s8(val >> 8);
  159. delta = mt76x0_tssi_enabled(dev) ? 0 : mt76x0_get_delta(dev);
  160. mt76x02_add_rate_power_offset(t, delta);
  161. }
  162. void mt76x0_get_power_info(struct mt76x02_dev *dev,
  163. struct ieee80211_channel *chan, s8 *tp)
  164. {
  165. static const struct mt76x0_chan_map {
  166. u8 chan;
  167. u8 offset;
  168. } chan_map[] = {
  169. { 2, 0 }, { 4, 2 }, { 6, 4 }, { 8, 6 },
  170. { 10, 8 }, { 12, 10 }, { 14, 12 }, { 38, 0 },
  171. { 44, 2 }, { 48, 4 }, { 54, 6 }, { 60, 8 },
  172. { 64, 10 }, { 102, 12 }, { 108, 14 }, { 112, 16 },
  173. { 118, 18 }, { 124, 20 }, { 128, 22 }, { 134, 24 },
  174. { 140, 26 }, { 151, 28 }, { 157, 30 }, { 161, 32 },
  175. { 167, 34 }, { 171, 36 }, { 175, 38 },
  176. };
  177. u8 offset, addr;
  178. int i, idx = 0;
  179. u16 data;
  180. if (mt76x0_tssi_enabled(dev)) {
  181. s8 target_power;
  182. if (chan->band == NL80211_BAND_5GHZ)
  183. data = mt76x02_eeprom_get(dev, MT_EE_5G_TARGET_POWER);
  184. else
  185. data = mt76x02_eeprom_get(dev, MT_EE_2G_TARGET_POWER);
  186. target_power = (data & 0xff) - dev->rate_power.ofdm[7];
  187. *tp = target_power + mt76x0_get_delta(dev);
  188. return;
  189. }
  190. for (i = 0; i < ARRAY_SIZE(chan_map); i++) {
  191. if (chan->hw_value <= chan_map[i].chan) {
  192. idx = (chan->hw_value == chan_map[i].chan);
  193. offset = chan_map[i].offset;
  194. break;
  195. }
  196. }
  197. if (i == ARRAY_SIZE(chan_map))
  198. offset = chan_map[0].offset;
  199. if (chan->band == NL80211_BAND_2GHZ) {
  200. addr = MT_EE_TX_POWER_DELTA_BW80 + offset;
  201. } else {
  202. switch (chan->hw_value) {
  203. case 42:
  204. offset = 2;
  205. break;
  206. case 58:
  207. offset = 8;
  208. break;
  209. case 106:
  210. offset = 14;
  211. break;
  212. case 122:
  213. offset = 20;
  214. break;
  215. case 155:
  216. offset = 30;
  217. break;
  218. default:
  219. break;
  220. }
  221. addr = MT_EE_TX_POWER_0_GRP4_TSSI_SLOPE + 2 + offset;
  222. }
  223. data = mt76x02_eeprom_get(dev, addr);
  224. *tp = data >> (8 * idx);
  225. if (*tp < 0 || *tp > 0x3f)
  226. *tp = 5;
  227. }
  228. static int mt76x0_check_eeprom(struct mt76x02_dev *dev)
  229. {
  230. u16 val;
  231. val = get_unaligned_le16(dev->mt76.eeprom.data);
  232. if (!val)
  233. val = get_unaligned_le16(dev->mt76.eeprom.data +
  234. MT_EE_PCI_ID);
  235. switch (val) {
  236. case 0x7650:
  237. case 0x7610:
  238. return 0;
  239. default:
  240. dev_err(dev->mt76.dev, "EEPROM data check failed: %04x\n",
  241. val);
  242. return -EINVAL;
  243. }
  244. }
  245. static int mt76x0_load_eeprom(struct mt76x02_dev *dev)
  246. {
  247. int found;
  248. found = mt76_eeprom_init(&dev->mt76, MT76X0_EEPROM_SIZE);
  249. if (found < 0)
  250. return found;
  251. if (found && !mt76x0_check_eeprom(dev))
  252. return 0;
  253. found = mt76x0_efuse_physical_size_check(dev);
  254. if (found < 0)
  255. return found;
  256. return mt76x02_get_efuse_data(dev, 0, dev->mt76.eeprom.data,
  257. MT76X0_EEPROM_SIZE, MT_EE_READ);
  258. }
  259. int mt76x0_eeprom_init(struct mt76x02_dev *dev)
  260. {
  261. u8 version, fae;
  262. u16 data;
  263. int err;
  264. err = mt76x0_load_eeprom(dev);
  265. if (err < 0)
  266. return err;
  267. data = mt76x02_eeprom_get(dev, MT_EE_VERSION);
  268. version = data >> 8;
  269. fae = data;
  270. if (version > MT76X0U_EE_MAX_VER)
  271. dev_warn(dev->mt76.dev,
  272. "Warning: unsupported EEPROM version %02hhx\n",
  273. version);
  274. dev_info(dev->mt76.dev, "EEPROM ver:%02hhx fae:%02hhx\n",
  275. version, fae);
  276. memcpy(dev->mphy.macaddr, (u8 *)dev->mt76.eeprom.data + MT_EE_MAC_ADDR,
  277. ETH_ALEN);
  278. err = mt76_eeprom_override(&dev->mphy);
  279. if (err)
  280. return err;
  281. mt76x02_mac_setaddr(dev, dev->mphy.macaddr);
  282. mt76x0_set_chip_cap(dev);
  283. mt76x0_set_freq_offset(dev);
  284. mt76x0_set_temp_offset(dev);
  285. return 0;
  286. }
  287. MODULE_DESCRIPTION("MediaTek MT76x EEPROM helpers");
  288. MODULE_LICENSE("Dual BSD/GPL");