1 /* 2 ************************************************************************* 3 * Ralink Tech Inc. 4 * 5F., No.36, Taiyuan St., Jhubei City, 5 * Hsinchu County 302, 6 * Taiwan, R.O.C. 7 * 8 * (c) Copyright 2002-2007, Ralink Technology, Inc. 9 * 10 * This program is free software; you can redistribute it and/or modify * 11 * it under the terms of the GNU General Public License as published by * 12 * the Free Software Foundation; either version 2 of the License, or * 13 * (at your option) any later version. * 14 * * 15 * This program is distributed in the hope that it will be useful, * 16 * but WITHOUT ANY WARRANTY; without even the implied warranty of * 17 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * 18 * GNU General Public License for more details. * 19 * * 20 * You should have received a copy of the GNU General Public License * 21 * along with this program; if not, write to the * 22 * Free Software Foundation, Inc., * 23 * 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA. * 24 * * 25 ************************************************************************* 26 27 Module Name: 28 rtmp_phy.h 29 30 Abstract: 31 Ralink Wireless Chip PHY(BBP/RF) related definition & structures 32 33 Revision History: 34 Who When What 35 -------- ---------- ---------------------------------------------- 36 */ 37 38 #ifndef __RTMP_PHY_H__ 39 #define __RTMP_PHY_H__ 40 41 /* 42 RF sections 43 */ 44 #define RF_R00 0 45 #define RF_R01 1 46 #define RF_R02 2 47 #define RF_R03 3 48 #define RF_R04 4 49 #define RF_R05 5 50 #define RF_R06 6 51 #define RF_R07 7 52 #define RF_R08 8 53 #define RF_R09 9 54 #define RF_R10 10 55 #define RF_R11 11 56 #define RF_R12 12 57 #define RF_R13 13 58 #define RF_R14 14 59 #define RF_R15 15 60 #define RF_R16 16 61 #define RF_R17 17 62 #define RF_R18 18 63 #define RF_R19 19 64 #define RF_R20 20 65 #define RF_R21 21 66 #define RF_R22 22 67 #define RF_R23 23 68 #define RF_R24 24 69 #define RF_R25 25 70 #define RF_R26 26 71 #define RF_R27 27 72 #define RF_R28 28 73 #define RF_R29 29 74 #define RF_R30 30 75 #define RF_R31 31 76 77 /* value domain of pAd->RfIcType */ 78 #define RFIC_2820 1 /* 2.4G 2T3R */ 79 #define RFIC_2850 2 /* 2.4G/5G 2T3R */ 80 #define RFIC_2720 3 /* 2.4G 1T2R */ 81 #define RFIC_2750 4 /* 2.4G/5G 1T2R */ 82 #define RFIC_3020 5 /* 2.4G 1T1R */ 83 #define RFIC_2020 6 /* 2.4G B/G */ 84 #define RFIC_3021 7 /* 2.4G 1T2R */ 85 #define RFIC_3022 8 /* 2.4G 2T2R */ 86 #define RFIC_3052 9 /* 2.4G/5G 2T2R */ 87 88 /* 89 BBP sections 90 */ 91 #define BBP_R0 0 /* version */ 92 #define BBP_R1 1 /* TSSI */ 93 #define BBP_R2 2 /* TX configure */ 94 #define BBP_R3 3 95 #define BBP_R4 4 96 #define BBP_R5 5 97 #define BBP_R6 6 98 #define BBP_R14 14 /* RX configure */ 99 #define BBP_R16 16 100 #define BBP_R17 17 /* RX sensibility */ 101 #define BBP_R18 18 102 #define BBP_R21 21 103 #define BBP_R22 22 104 #define BBP_R24 24 105 #define BBP_R25 25 106 #define BBP_R26 26 107 #define BBP_R27 27 108 #define BBP_R31 31 109 #define BBP_R49 49 /*TSSI */ 110 #define BBP_R50 50 111 #define BBP_R51 51 112 #define BBP_R52 52 113 #define BBP_R55 55 114 #define BBP_R62 62 /* Rx SQ0 Threshold HIGH */ 115 #define BBP_R63 63 116 #define BBP_R64 64 117 #define BBP_R65 65 118 #define BBP_R66 66 119 #define BBP_R67 67 120 #define BBP_R68 68 121 #define BBP_R69 69 122 #define BBP_R70 70 /* Rx AGC SQ CCK Xcorr threshold */ 123 #define BBP_R73 73 124 #define BBP_R75 75 125 #define BBP_R77 77 126 #define BBP_R78 78 127 #define BBP_R79 79 128 #define BBP_R80 80 129 #define BBP_R81 81 130 #define BBP_R82 82 131 #define BBP_R83 83 132 #define BBP_R84 84 133 #define BBP_R86 86 134 #define BBP_R91 91 135 #define BBP_R92 92 136 #define BBP_R94 94 /* Tx Gain Control */ 137 #define BBP_R103 103 138 #define BBP_R105 105 139 #define BBP_R106 106 140 #define BBP_R113 113 141 #define BBP_R114 114 142 #define BBP_R115 115 143 #define BBP_R116 116 144 #define BBP_R117 117 145 #define BBP_R118 118 146 #define BBP_R119 119 147 #define BBP_R120 120 148 #define BBP_R121 121 149 #define BBP_R122 122 150 #define BBP_R123 123 151 #ifdef RT30xx 152 #define BBP_R138 138 /* add by johnli, RF power sequence setup, ADC dynamic on/off control */ 153 #endif /* RT30xx // */ 154 155 #define BBPR94_DEFAULT 0x06 /* Add 1 value will gain 1db */ 156 157 /* */ 158 /* BBP & RF are using indirect access. Before write any value into it. */ 159 /* We have to make sure there is no outstanding command pending via checking busy bit. */ 160 /* */ 161 #define MAX_BUSY_COUNT 100 /* Number of retry before failing access BBP & RF indirect register */ 162 163 /*#define PHY_TR_SWITCH_TIME 5 // usec */ 164 165 /*#define BBP_R17_LOW_SENSIBILITY 0x50 */ 166 /*#define BBP_R17_MID_SENSIBILITY 0x41 */ 167 /*#define BBP_R17_DYNAMIC_UP_BOUND 0x40 */ 168 169 #define RSSI_FOR_VERY_LOW_SENSIBILITY -35 170 #define RSSI_FOR_LOW_SENSIBILITY -58 171 #define RSSI_FOR_MID_LOW_SENSIBILITY -80 172 #define RSSI_FOR_MID_SENSIBILITY -90 173 174 /***************************************************************************** 175 RF register Read/Write marco definition 176 *****************************************************************************/ 177 #ifdef RTMP_MAC_PCI 178 #define RTMP_RF_IO_WRITE32(_A, _V) \ 179 { \ 180 if ((_A)->bPCIclkOff == FALSE) { \ 181 PHY_CSR4_STRUC _value; \ 182 unsigned long _busyCnt = 0; \ 183 \ 184 do { \ 185 RTMP_IO_READ32((_A), RF_CSR_CFG0, &_value.word); \ 186 if (_value.field.Busy == IDLE) \ 187 break; \ 188 _busyCnt++; \ 189 } while (_busyCnt < MAX_BUSY_COUNT); \ 190 if (_busyCnt < MAX_BUSY_COUNT) { \ 191 RTMP_IO_WRITE32((_A), RF_CSR_CFG0, (_V)); \ 192 } \ 193 } \ 194 } 195 #endif /* RTMP_MAC_PCI // */ 196 #ifdef RTMP_MAC_USB 197 #define RTMP_RF_IO_WRITE32(_A, _V) RTUSBWriteRFRegister(_A, _V) 198 #endif /* RTMP_MAC_USB // */ 199 200 #ifdef RT30xx 201 #define RTMP_RF_IO_READ8_BY_REG_ID(_A, _I, _pV) RT30xxReadRFRegister(_A, _I, _pV) 202 #define RTMP_RF_IO_WRITE8_BY_REG_ID(_A, _I, _V) RT30xxWriteRFRegister(_A, _I, _V) 203 #endif /* RT30xx // */ 204 205 /***************************************************************************** 206 BBP register Read/Write marco definitions. 207 we read/write the bbp value by register's ID. 208 Generate PER to test BA 209 *****************************************************************************/ 210 #ifdef RTMP_MAC_PCI 211 /* 212 basic marco for BBP read operation. 213 _pAd: the data structure pointer of struct rt_rtmp_adapter 214 _bbpID : the bbp register ID 215 _pV: data pointer used to save the value of queried bbp register. 216 _bViaMCU: if we need access the bbp via the MCU. 217 */ 218 #define RTMP_BBP_IO_READ8(_pAd, _bbpID, _pV, _bViaMCU) \ 219 do { \ 220 BBP_CSR_CFG_STRUC BbpCsr; \ 221 int _busyCnt, _secCnt, _regID; \ 222 \ 223 _regID = ((_bViaMCU) == TRUE ? H2M_BBP_AGENT : BBP_CSR_CFG); \ 224 for (_busyCnt = 0; _busyCnt < MAX_BUSY_COUNT; _busyCnt++) { \ 225 RTMP_IO_READ32(_pAd, _regID, &BbpCsr.word); \ 226 if (BbpCsr.field.Busy == BUSY) \ 227 continue; \ 228 BbpCsr.word = 0; \ 229 BbpCsr.field.fRead = 1; \ 230 BbpCsr.field.BBP_RW_MODE = 1; \ 231 BbpCsr.field.Busy = 1; \ 232 BbpCsr.field.RegNum = _bbpID; \ 233 RTMP_IO_WRITE32(_pAd, _regID, BbpCsr.word); \ 234 if ((_bViaMCU) == TRUE) { \ 235 AsicSendCommandToMcu(_pAd, 0x80, 0xff, 0x0, 0x0); \ 236 RTMPusecDelay(1000); \ 237 } \ 238 for (_secCnt = 0; _secCnt < MAX_BUSY_COUNT; _secCnt++) { \ 239 RTMP_IO_READ32(_pAd, _regID, &BbpCsr.word); \ 240 if (BbpCsr.field.Busy == IDLE) \ 241 break; \ 242 } \ 243 if ((BbpCsr.field.Busy == IDLE) && \ 244 (BbpCsr.field.RegNum == _bbpID)) { \ 245 *(_pV) = (u8)BbpCsr.field.Value; \ 246 break; \ 247 } \ 248 } \ 249 if (BbpCsr.field.Busy == BUSY) { \ 250 DBGPRINT_ERR("BBP(viaMCU=%d) read R%d fail\n", (_bViaMCU), _bbpID); \ 251 *(_pV) = (_pAd)->BbpWriteLatch[_bbpID]; \ 252 if ((_bViaMCU) == TRUE) { \ 253 RTMP_IO_READ32(_pAd, _regID, &BbpCsr.word); \ 254 BbpCsr.field.Busy = 0; \ 255 RTMP_IO_WRITE32(_pAd, _regID, BbpCsr.word); \ 256 } \ 257 } \ 258 } while (0) 259 260 /* 261 This marco used for the BBP read operation which didn't need via MCU. 262 */ 263 #define BBP_IO_READ8_BY_REG_ID(_A, _I, _pV) \ 264 RTMP_BBP_IO_READ8((_A), (_I), (_pV), FALSE) 265 266 /* 267 This marco used for the BBP read operation which need via MCU. 268 But for some chipset which didn't have mcu (e.g., RBUS based chipset), we 269 will use this function too and didn't access the bbp register via the MCU. 270 */ 271 /* Read BBP register by register's ID. Generate PER to test BA */ 272 #define RTMP_BBP_IO_READ8_BY_REG_ID(_A, _I, _pV) \ 273 { \ 274 BBP_CSR_CFG_STRUC BbpCsr; \ 275 int i, k; \ 276 BOOLEAN brc; \ 277 BbpCsr.field.Busy = IDLE; \ 278 if ((IS_RT3090((_A)) || IS_RT3572((_A)) || IS_RT3390((_A))) \ 279 && ((_A)->StaCfg.PSControl.field.rt30xxPowerMode == 3) \ 280 && ((_A)->StaCfg.PSControl.field.EnableNewPS == TRUE) \ 281 && ((_A)->bPCIclkOff == FALSE) \ 282 && ((_A)->brt30xxBanMcuCmd == FALSE)) { \ 283 for (i = 0; i < MAX_BUSY_COUNT; i++) { \ 284 RTMP_IO_READ32(_A, H2M_BBP_AGENT, &BbpCsr.word); \ 285 if (BbpCsr.field.Busy == BUSY) { \ 286 continue; \ 287 } \ 288 BbpCsr.word = 0; \ 289 BbpCsr.field.fRead = 1; \ 290 BbpCsr.field.BBP_RW_MODE = 1; \ 291 BbpCsr.field.Busy = 1; \ 292 BbpCsr.field.RegNum = _I; \ 293 RTMP_IO_WRITE32(_A, H2M_BBP_AGENT, BbpCsr.word); \ 294 brc = AsicSendCommandToMcu(_A, 0x80, 0xff, 0x0, 0x0); \ 295 if (brc == TRUE) { \ 296 for (k = 0; k < MAX_BUSY_COUNT; k++) { \ 297 RTMP_IO_READ32(_A, H2M_BBP_AGENT, &BbpCsr.word); \ 298 if (BbpCsr.field.Busy == IDLE) \ 299 break; \ 300 } \ 301 if ((BbpCsr.field.Busy == IDLE) && \ 302 (BbpCsr.field.RegNum == _I)) { \ 303 *(_pV) = (u8)BbpCsr.field.Value; \ 304 break; \ 305 } \ 306 } else { \ 307 BbpCsr.field.Busy = 0; \ 308 RTMP_IO_WRITE32(_A, H2M_BBP_AGENT, BbpCsr.word); \ 309 } \ 310 } \ 311 } \ 312 else if (!((IS_RT3090((_A)) || IS_RT3572((_A)) || IS_RT3390((_A))) && ((_A)->StaCfg.PSControl.field.rt30xxPowerMode == 3) \ 313 && ((_A)->StaCfg.PSControl.field.EnableNewPS == TRUE)) \ 314 && ((_A)->bPCIclkOff == FALSE)) { \ 315 for (i = 0; i < MAX_BUSY_COUNT; i++) { \ 316 RTMP_IO_READ32(_A, H2M_BBP_AGENT, &BbpCsr.word); \ 317 if (BbpCsr.field.Busy == BUSY) { \ 318 continue; \ 319 } \ 320 BbpCsr.word = 0; \ 321 BbpCsr.field.fRead = 1; \ 322 BbpCsr.field.BBP_RW_MODE = 1; \ 323 BbpCsr.field.Busy = 1; \ 324 BbpCsr.field.RegNum = _I; \ 325 RTMP_IO_WRITE32(_A, H2M_BBP_AGENT, BbpCsr.word); \ 326 AsicSendCommandToMcu(_A, 0x80, 0xff, 0x0, 0x0); \ 327 for (k = 0; k < MAX_BUSY_COUNT; k++) { \ 328 RTMP_IO_READ32(_A, H2M_BBP_AGENT, &BbpCsr.word); \ 329 if (BbpCsr.field.Busy == IDLE) \ 330 break; \ 331 } \ 332 if ((BbpCsr.field.Busy == IDLE) && \ 333 (BbpCsr.field.RegNum == _I)) { \ 334 *(_pV) = (u8)BbpCsr.field.Value; \ 335 break; \ 336 } \ 337 } \ 338 } else { \ 339 DBGPRINT_ERR(" , brt30xxBanMcuCmd = %d, Read BBP %d \n", (_A)->brt30xxBanMcuCmd, (_I)); \ 340 *(_pV) = (_A)->BbpWriteLatch[_I]; \ 341 } \ 342 if ((BbpCsr.field.Busy == BUSY) || ((_A)->bPCIclkOff == TRUE)) { \ 343 DBGPRINT_ERR("BBP read R%d=0x%x fail\n", _I, BbpCsr.word); \ 344 *(_pV) = (_A)->BbpWriteLatch[_I]; \ 345 } \ 346 } 347 348 /* 349 basic marco for BBP write operation. 350 _pAd: the data structure pointer of struct rt_rtmp_adapter 351 _bbpID : the bbp register ID 352 _pV: data used to save the value of queried bbp register. 353 _bViaMCU: if we need access the bbp via the MCU. 354 */ 355 #define RTMP_BBP_IO_WRITE8(_pAd, _bbpID, _pV, _bViaMCU) \ 356 do { \ 357 BBP_CSR_CFG_STRUC BbpCsr; \ 358 int _busyCnt, _regID; \ 359 \ 360 _regID = ((_bViaMCU) == TRUE ? H2M_BBP_AGENT : BBP_CSR_CFG); \ 361 for (_busyCnt = 0; _busyCnt < MAX_BUSY_COUNT; _busyCnt++) { \ 362 RTMP_IO_READ32((_pAd), BBP_CSR_CFG, &BbpCsr.word); \ 363 if (BbpCsr.field.Busy == BUSY) \ 364 continue; \ 365 BbpCsr.word = 0; \ 366 BbpCsr.field.fRead = 0; \ 367 BbpCsr.field.BBP_RW_MODE = 1; \ 368 BbpCsr.field.Busy = 1; \ 369 BbpCsr.field.Value = _pV; \ 370 BbpCsr.field.RegNum = _bbpID; \ 371 RTMP_IO_WRITE32((_pAd), BBP_CSR_CFG, BbpCsr.word); \ 372 if ((_bViaMCU) == TRUE) { \ 373 AsicSendCommandToMcu(_pAd, 0x80, 0xff, 0x0, 0x0); \ 374 if ((_pAd)->OpMode == OPMODE_AP) \ 375 RTMPusecDelay(1000); \ 376 } \ 377 (_pAd)->BbpWriteLatch[_bbpID] = _pV; \ 378 break; \ 379 } \ 380 if (_busyCnt == MAX_BUSY_COUNT) { \ 381 DBGPRINT_ERR("BBP write R%d fail\n", _bbpID); \ 382 if ((_bViaMCU) == TRUE) { \ 383 RTMP_IO_READ32(_pAd, H2M_BBP_AGENT, &BbpCsr.word); \ 384 BbpCsr.field.Busy = 0; \ 385 RTMP_IO_WRITE32(_pAd, H2M_BBP_AGENT, BbpCsr.word); \ 386 } \ 387 } \ 388 } while (0) 389 390 /* 391 This marco used for the BBP write operation which didn't need via MCU. 392 */ 393 #define BBP_IO_WRITE8_BY_REG_ID(_A, _I, _pV) \ 394 RTMP_BBP_IO_WRITE8((_A), (_I), (_pV), FALSE) 395 396 /* 397 This marco used for the BBP write operation which need via MCU. 398 But for some chipset which didn't have mcu (e.g., RBUS based chipset), we 399 will use this function too and didn't access the bbp register via the MCU. 400 */ 401 /* Write BBP register by register's ID & value */ 402 #define RTMP_BBP_IO_WRITE8_BY_REG_ID(_A, _I, _V) \ 403 { \ 404 BBP_CSR_CFG_STRUC BbpCsr; \ 405 int BusyCnt = 0; \ 406 BOOLEAN brc; \ 407 if (_I < MAX_NUM_OF_BBP_LATCH) { \ 408 if ((IS_RT3090((_A)) || IS_RT3572((_A)) || IS_RT3390((_A))) \ 409 && ((_A)->StaCfg.PSControl.field.rt30xxPowerMode == 3) \ 410 && ((_A)->StaCfg.PSControl.field.EnableNewPS == TRUE) \ 411 && ((_A)->bPCIclkOff == FALSE) \ 412 && ((_A)->brt30xxBanMcuCmd == FALSE)) { \ 413 if (_A->AccessBBPFailCount > 20) { \ 414 AsicResetBBPAgent(_A); \ 415 _A->AccessBBPFailCount = 0; \ 416 } \ 417 for (BusyCnt = 0; BusyCnt < MAX_BUSY_COUNT; BusyCnt++) { \ 418 RTMP_IO_READ32(_A, H2M_BBP_AGENT, &BbpCsr.word); \ 419 if (BbpCsr.field.Busy == BUSY) \ 420 continue; \ 421 BbpCsr.word = 0; \ 422 BbpCsr.field.fRead = 0; \ 423 BbpCsr.field.BBP_RW_MODE = 1; \ 424 BbpCsr.field.Busy = 1; \ 425 BbpCsr.field.Value = _V; \ 426 BbpCsr.field.RegNum = _I; \ 427 RTMP_IO_WRITE32(_A, H2M_BBP_AGENT, BbpCsr.word); \ 428 brc = AsicSendCommandToMcu(_A, 0x80, 0xff, 0x0, 0x0); \ 429 if (brc == TRUE) { \ 430 (_A)->BbpWriteLatch[_I] = _V; \ 431 } else { \ 432 BbpCsr.field.Busy = 0; \ 433 RTMP_IO_WRITE32(_A, H2M_BBP_AGENT, BbpCsr.word); \ 434 } \ 435 break; \ 436 } \ 437 } \ 438 else if (!((IS_RT3090((_A)) || IS_RT3572((_A)) || IS_RT3390((_A))) \ 439 && ((_A)->StaCfg.PSControl.field.rt30xxPowerMode == 3) \ 440 && ((_A)->StaCfg.PSControl.field.EnableNewPS == TRUE)) \ 441 && ((_A)->bPCIclkOff == FALSE)) { \ 442 if (_A->AccessBBPFailCount > 20) { \ 443 AsicResetBBPAgent(_A); \ 444 _A->AccessBBPFailCount = 0; \ 445 } \ 446 for (BusyCnt = 0; BusyCnt < MAX_BUSY_COUNT; BusyCnt++) { \ 447 RTMP_IO_READ32(_A, H2M_BBP_AGENT, &BbpCsr.word); \ 448 if (BbpCsr.field.Busy == BUSY) \ 449 continue; \ 450 BbpCsr.word = 0; \ 451 BbpCsr.field.fRead = 0; \ 452 BbpCsr.field.BBP_RW_MODE = 1; \ 453 BbpCsr.field.Busy = 1; \ 454 BbpCsr.field.Value = _V; \ 455 BbpCsr.field.RegNum = _I; \ 456 RTMP_IO_WRITE32(_A, H2M_BBP_AGENT, BbpCsr.word); \ 457 AsicSendCommandToMcu(_A, 0x80, 0xff, 0x0, 0x0); \ 458 (_A)->BbpWriteLatch[_I] = _V; \ 459 break; \ 460 } \ 461 } else { \ 462 DBGPRINT_ERR(" brt30xxBanMcuCmd = %d. Write BBP %d \n", (_A)->brt30xxBanMcuCmd, (_I)); \ 463 } \ 464 if ((BusyCnt == MAX_BUSY_COUNT) || ((_A)->bPCIclkOff == TRUE)) { \ 465 if (BusyCnt == MAX_BUSY_COUNT) \ 466 (_A)->AccessBBPFailCount++; \ 467 DBGPRINT_ERR("BBP write R%d=0x%x fail. BusyCnt= %d.bPCIclkOff = %d. \n", _I, BbpCsr.word, BusyCnt, (_A)->bPCIclkOff); \ 468 } \ 469 } else { \ 470 DBGPRINT_ERR("****** BBP_Write_Latch Buffer exceeds max boundary ****** \n"); \ 471 } \ 472 } 473 #endif /* RTMP_MAC_PCI // */ 474 475 #ifdef RTMP_MAC_USB 476 #define RTMP_BBP_IO_READ8_BY_REG_ID(_A, _I, _pV) RTUSBReadBBPRegister(_A, _I, _pV) 477 #define RTMP_BBP_IO_WRITE8_BY_REG_ID(_A, _I, _V) RTUSBWriteBBPRegister(_A, _I, _V) 478 479 #define BBP_IO_WRITE8_BY_REG_ID(_A, _I, _V) RTUSBWriteBBPRegister(_A, _I, _V) 480 #define BBP_IO_READ8_BY_REG_ID(_A, _I, _pV) RTUSBReadBBPRegister(_A, _I, _pV) 481 #endif /* RTMP_MAC_USB // */ 482 483 #ifdef RT30xx 484 #define RTMP_ASIC_MMPS_DISABLE(_pAd) \ 485 do { \ 486 u32 _macData; \ 487 u8 _bbpData = 0; \ 488 /* disable MMPS BBP control register */ \ 489 RTMP_BBP_IO_READ8_BY_REG_ID(_pAd, BBP_R3, &_bbpData); \ 490 _bbpData &= ~(0x04); /*bit 2*/ \ 491 RTMP_BBP_IO_WRITE8_BY_REG_ID(_pAd, BBP_R3, _bbpData); \ 492 \ 493 /* disable MMPS MAC control register */ \ 494 RTMP_IO_READ32(_pAd, 0x1210, &_macData); \ 495 _macData &= ~(0x09); /*bit 0, 3*/ \ 496 RTMP_IO_WRITE32(_pAd, 0x1210, _macData); \ 497 } while (0) 498 499 #define RTMP_ASIC_MMPS_ENABLE(_pAd) \ 500 do { \ 501 u32 _macData; \ 502 u8 _bbpData = 0; \ 503 /* enable MMPS BBP control register */ \ 504 RTMP_BBP_IO_READ8_BY_REG_ID(_pAd, BBP_R3, &_bbpData); \ 505 _bbpData |= (0x04); /*bit 2*/ \ 506 RTMP_BBP_IO_WRITE8_BY_REG_ID(_pAd, BBP_R3, _bbpData); \ 507 \ 508 /* enable MMPS MAC control register */ \ 509 RTMP_IO_READ32(_pAd, 0x1210, &_macData); \ 510 _macData |= (0x09); /*bit 0, 3*/ \ 511 RTMP_IO_WRITE32(_pAd, 0x1210, _macData); \ 512 } while (0) 513 514 #endif /* RT30xx // */ 515 516 #endif /* __RTMP_PHY_H__ // */ 517