//============================================================================ // MTO.C - // // Description: // MAC Throughput Optimization for W89C33 802.11g WLAN STA. // // The following MIB attributes or internal variables will be affected // while the MTO is being executed: // dot11FragmentationThreshold, // dot11RTSThreshold, // transmission rate and PLCP preamble type, // CCA mode, // antenna diversity. // // Revision history: // -------------------------------------------------------------------------- // 20031227 UN20 Pete Chao // First draft // 20031229 Turbo copy from PD43 // 20040210 Kevin revised // Copyright (c) 2003 Winbond Electronics Corp. All rights reserved. //============================================================================ // LA20040210_DTO kevin #include "os_common.h" // Declare SQ3 to rate and fragmentation threshold table // Declare fragmentation thresholds table #define MTO_MAX_SQ3_LEVELS 14 #define MTO_MAX_FRAG_TH_LEVELS 5 #define MTO_MAX_DATA_RATE_LEVELS 12 u16 MTO_Frag_Th_Tbl[MTO_MAX_FRAG_TH_LEVELS] = { 256, 384, 512, 768, 1536 }; u8 MTO_SQ3_Level[MTO_MAX_SQ3_LEVELS] = { 0, 26, 30, 32, 34, 35, 37, 42, 44, 46, 54, 62, 78, 81 }; u8 MTO_SQ3toRate[MTO_MAX_SQ3_LEVELS] = { 0, 1, 1, 2, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11 }; u8 MTO_SQ3toFrag[MTO_MAX_SQ3_LEVELS] = { 0, 2, 2, 3, 3, 4, 4, 4, 4, 4, 4, 4, 4, 4 }; // One Exchange Time table // u16 MTO_One_Exchange_Time_Tbl_l[MTO_MAX_FRAG_TH_LEVELS][MTO_MAX_DATA_RATE_LEVELS] = { { 2554, 1474, 822, 0, 0, 636, 0, 0, 0, 0, 0, 0}, { 3578, 1986, 1009, 0, 0, 729, 0, 0, 0, 0, 0, 0}, { 4602, 2498, 1195, 0, 0, 822, 0, 0, 0, 0, 0, 0}, { 6650, 3522, 1567, 0, 0, 1009, 0, 0, 0, 0, 0, 0}, {12794, 6594, 2684, 0, 0, 1567, 0, 0, 0, 0, 0, 0} }; u16 MTO_One_Exchange_Time_Tbl_s[MTO_MAX_FRAG_TH_LEVELS][MTO_MAX_DATA_RATE_LEVELS] = { { 0, 1282, 630, 404, 288, 444, 232, 172, 144, 116, 100, 96}, { 0, 1794, 817, 572, 400, 537, 316, 228, 188, 144, 124, 116}, { 0, 2306, 1003, 744, 516, 630, 400, 288, 228, 172, 144, 136}, { 0, 3330, 1375, 1084, 744, 817, 572, 400, 316, 228, 188, 172}, { 0, 6402, 2492, 2108, 1424, 1375, 1084, 740, 572, 400, 316, 284} }; #define MTO_ONE_EXCHANGE_TIME(preamble_type, frag_th_lvl, data_rate_lvl) \ (preamble_type) ? MTO_One_Exchange_Time_Tbl_s[frag_th_lvl][data_rate_lvl] : \ MTO_One_Exchange_Time_Tbl_l[frag_th_lvl][data_rate_lvl] // Declare data rate table //The following table will be changed at anytime if the opration rate supported by AP don't //match the table u8 MTO_Data_Rate_Tbl[MTO_MAX_DATA_RATE_LEVELS] = { 2, 4, 11, 22, 12, 18, 24, 36, 48, 72, 96, 108 }; //The Stardard_Data_Rate_Tbl and Level2PerTbl table is used to indirectly retreive PER //information from Rate_PER_TBL //The default settings is AP can support full rate set. static u8 Stardard_Data_Rate_Tbl[MTO_MAX_DATA_RATE_LEVELS] = { 2, 4, 11, 22, 12, 18, 24, 36, 48, 72, 96, 108 }; static u8 Level2PerTbl[MTO_MAX_DATA_RATE_LEVELS] = { 0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11 }; //How many kind of tx rate can be supported by AP //DTO will change Rate between MTO_Data_Rate_Tbl[0] and MTO_Data_Rate_Tbl[MTO_DataRateAvailableLevel-1] static u8 MTO_DataRateAvailableLevel = MTO_MAX_DATA_RATE_LEVELS; //Smoothed PER table for each different RATE based on packet length of 1514 static int Rate_PER_TBL[91][MTO_MAX_DATA_RATE_LEVELS] = { // 1M 2M 5.5M 11M 6M 9M 12M 18M 24M 36M 48M 54M /* 0% */{ 93, 177, 420, 538, 690, 774, 1001, 1401, 1768, 2358, 2838, 3039}, /* 1% */{ 92, 176, 416, 533, 683, 767, 992, 1389, 1752, 2336, 2811, 3010}, /* 2% */{ 91, 174, 412, 528, 675, 760, 983, 1376, 1735, 2313, 2783, 2979}, /* 3% */{ 90, 172, 407, 523, 667, 753, 973, 1363, 1719, 2290, 2755, 2948}, /* 4% */{ 90, 170, 403, 518, 659, 746, 964, 1350, 1701, 2266, 2726, 2916}, /* 5% */{ 89, 169, 398, 512, 651, 738, 954, 1336, 1684, 2242, 2696, 2884}, /* 6% */{ 88, 167, 394, 507, 643, 731, 944, 1322, 1666, 2217, 2665, 2851}, /* 7% */{ 87, 165, 389, 502, 635, 723, 935, 1308, 1648, 2192, 2634, 2817}, /* 8% */{ 86, 163, 384, 497, 626, 716, 924, 1294, 1629, 2166, 2602, 2782}, /* 9% */{ 85, 161, 380, 491, 618, 708, 914, 1279, 1611, 2140, 2570, 2747}, /* 10% */{ 84, 160, 375, 486, 609, 700, 904, 1265, 1591, 2113, 2537, 2711}, /* 11% */{ 83, 158, 370, 480, 600, 692, 894, 1250, 1572, 2086, 2503, 2675}, /* 12% */{ 82, 156, 365, 475, 592, 684, 883, 1234, 1552, 2059, 2469, 2638}, /* 13% */{ 81, 154, 360, 469, 583, 676, 872, 1219, 1532, 2031, 2435, 2600}, /* 14% */{ 80, 152, 355, 464, 574, 668, 862, 1204, 1512, 2003, 2400, 2562}, /* 15% */{ 79, 150, 350, 458, 565, 660, 851, 1188, 1492, 1974, 2365, 2524}, /* 16% */{ 78, 148, 345, 453, 556, 652, 840, 1172, 1471, 1945, 2329, 2485}, /* 17% */{ 77, 146, 340, 447, 547, 643, 829, 1156, 1450, 1916, 2293, 2446}, /* 18% */{ 76, 144, 335, 441, 538, 635, 818, 1140, 1429, 1887, 2256, 2406}, /* 19% */{ 75, 143, 330, 436, 529, 627, 807, 1124, 1408, 1857, 2219, 2366}, /* 20% */{ 74, 141, 325, 430, 520, 618, 795, 1107, 1386, 1827, 2182, 2326}, /* 21% */{ 73, 139, 320, 424, 510, 610, 784, 1091, 1365, 1797, 2145, 2285}, /* 22% */{ 72, 137, 314, 418, 501, 601, 772, 1074, 1343, 1766, 2107, 2244}, /* 23% */{ 71, 135, 309, 412, 492, 592, 761, 1057, 1321, 1736, 2069, 2203}, /* 24% */{ 70, 133, 304, 407, 482, 584, 749, 1040, 1299, 1705, 2031, 2161}, /* 25% */{ 69, 131, 299, 401, 473, 575, 738, 1023, 1277, 1674, 1992, 2120}, /* 26% */{ 68, 129, 293, 395, 464, 566, 726, 1006, 1254, 1642, 1953, 2078}, /* 27% */{ 67, 127, 288, 389, 454, 557, 714, 989, 1232, 1611, 1915, 2035}, /* 28% */{ 66, 125, 283, 383, 445, 549, 703, 972, 1209, 1579, 1876, 1993}, /* 29% */{ 65, 123, 278, 377, 436, 540, 691, 955, 1187, 1548, 1836, 1951}, /* 30% */{ 64, 121, 272, 371, 426, 531, 679, 937, 1164, 1516, 1797, 1908}, /* 31% */{ 63, 119, 267, 365, 417, 522, 667, 920, 1141, 1484, 1758, 1866}, /* 32% */{ 62, 117, 262, 359, 407, 513, 655, 902, 1118, 1453, 1719, 1823}, /* 33% */{ 61, 115, 256, 353, 398, 504, 643, 885, 1095, 1421, 1679, 1781}, /* 34% */{ 60, 113, 251, 347, 389, 495, 631, 867, 1072, 1389, 1640, 1738}, /* 35% */{ 59, 111, 246, 341, 379, 486, 619, 850, 1049, 1357, 1600, 1695}, /* 36% */{ 58, 108, 240, 335, 370, 477, 607, 832, 1027, 1325, 1561, 1653}, /* 37% */{ 57, 106, 235, 329, 361, 468, 595, 815, 1004, 1293, 1522, 1610}, /* 38% */{ 56, 104, 230, 323, 351, 459, 584, 797, 981, 1261, 1483, 1568}, /* 39% */{ 55, 102, 224, 317, 342, 450, 572, 780, 958, 1230, 1443, 1526}, /* 40% */{ 54, 100, 219, 311, 333, 441, 560, 762, 935, 1198, 1404, 1484}, /* 41% */{ 53, 98, 214, 305, 324, 432, 548, 744, 912, 1166, 1366, 1442}, /* 42% */{ 52, 96, 209, 299, 315, 423, 536, 727, 889, 1135, 1327, 1400}, /* 43% */{ 51, 94, 203, 293, 306, 414, 524, 709, 866, 1104, 1289, 1358}, /* 44% */{ 50, 92, 198, 287, 297, 405, 512, 692, 844, 1072, 1250, 1317}, /* 45% */{ 49, 90, 193, 281, 288, 396, 500, 675, 821, 1041, 1212, 1276}, /* 46% */{ 48, 88, 188, 275, 279, 387, 488, 657, 799, 1011, 1174, 1236}, /* 47% */{ 47, 86, 183, 269, 271, 378, 476, 640, 777, 980, 1137, 1195}, /* 48% */{ 46, 84, 178, 262, 262, 369, 464, 623, 754, 949, 1100, 1155}, /* 49% */{ 45, 82, 173, 256, 254, 360, 452, 606, 732, 919, 1063, 1116}, /* 50% */{ 44, 80, 168, 251, 245, 351, 441, 589, 710, 889, 1026, 1076}, /* 51% */{ 43, 78, 163, 245, 237, 342, 429, 572, 689, 860, 990, 1038}, /* 52% */{ 42, 76, 158, 239, 228, 333, 417, 555, 667, 830, 955, 999}, /* 53% */{ 41, 74, 153, 233, 220, 324, 406, 538, 645, 801, 919, 961}, /* 54% */{ 40, 72, 148, 227, 212, 315, 394, 522, 624, 773, 884, 924}, /* 55% */{ 39, 70, 143, 221, 204, 307, 383, 505, 603, 744, 850, 887}, /* 56% */{ 38, 68, 138, 215, 196, 298, 371, 489, 582, 716, 816, 851}, /* 57% */{ 37, 67, 134, 209, 189, 289, 360, 473, 562, 688, 783, 815}, /* 58% */{ 36, 65, 129, 203, 181, 281, 349, 457, 541, 661, 750, 780}, /* 59% */{ 35, 63, 124, 197, 174, 272, 338, 441, 521, 634, 717, 745}, /* 60% */{ 34, 61, 120, 192, 166, 264, 327, 425, 501, 608, 686, 712}, /* 61% */{ 33, 59, 115, 186, 159, 255, 316, 409, 482, 582, 655, 678}, /* 62% */{ 32, 57, 111, 180, 152, 247, 305, 394, 462, 556, 624, 646}, /* 63% */{ 31, 55, 107, 174, 145, 238, 294, 379, 443, 531, 594, 614}, /* 64% */{ 30, 53, 102, 169, 138, 230, 283, 364, 425, 506, 565, 583}, /* 65% */{ 29, 52, 98, 163, 132, 222, 273, 349, 406, 482, 536, 553}, /* 66% */{ 28, 50, 94, 158, 125, 214, 262, 334, 388, 459, 508, 523}, /* 67% */{ 27, 48, 90, 152, 119, 206, 252, 320, 370, 436, 481, 495}, /* 68% */{ 26, 46, 86, 147, 113, 198, 242, 306, 353, 413, 455, 467}, /* 69% */{ 26, 44, 82, 141, 107, 190, 231, 292, 336, 391, 429, 440}, /* 70% */{ 25, 43, 78, 136, 101, 182, 221, 278, 319, 370, 405, 414}, /* 71% */{ 24, 41, 74, 130, 95, 174, 212, 265, 303, 350, 381, 389}, /* 72% */{ 23, 39, 71, 125, 90, 167, 202, 252, 287, 329, 358, 365}, /* 73% */{ 22, 37, 67, 119, 85, 159, 192, 239, 271, 310, 335, 342}, /* 74% */{ 21, 36, 63, 114, 80, 151, 183, 226, 256, 291, 314, 320}, /* 75% */{ 20, 34, 60, 109, 75, 144, 174, 214, 241, 273, 294, 298}, /* 76% */{ 19, 32, 57, 104, 70, 137, 164, 202, 227, 256, 274, 278}, /* 77% */{ 18, 31, 53, 99, 66, 130, 155, 190, 213, 239, 256, 259}, /* 78% */{ 17, 29, 50, 94, 62, 122, 146, 178, 200, 223, 238, 241}, /* 79% */{ 16, 28, 47, 89, 58, 115, 138, 167, 187, 208, 222, 225}, /* 80% */{ 16, 26, 44, 84, 54, 109, 129, 156, 175, 194, 206, 209}, /* 81% */{ 15, 24, 41, 79, 50, 102, 121, 146, 163, 180, 192, 194}, /* 82% */{ 14, 23, 39, 74, 47, 95, 113, 136, 151, 167, 178, 181}, /* 83% */{ 13, 21, 36, 69, 44, 89, 105, 126, 140, 155, 166, 169}, /* 84% */{ 12, 20, 33, 64, 41, 82, 97, 116, 130, 144, 155, 158}, /* 85% */{ 11, 19, 31, 60, 39, 76, 89, 107, 120, 134, 145, 149}, /* 86% */{ 11, 17, 29, 55, 36, 70, 82, 98, 110, 125, 136, 140}, /* 87% */{ 10, 16, 26, 51, 34, 64, 75, 90, 102, 116, 128, 133}, /* 88% */{ 9, 14, 24, 46, 32, 58, 68, 81, 93, 108, 121, 128}, /* 89% */{ 8, 13, 22, 42, 31, 52, 61, 74, 86, 102, 116, 124}, /* 90% */{ 7, 12, 21, 37, 29, 46, 54, 66, 79, 96, 112, 121} }; #define RSSIBUF_NUM 10 #define RSSI2RATE_SIZE 9 static TXRETRY_REC TxRateRec={MTO_MAX_DATA_RATE_LEVELS - 1, 0}; //new record=>TxRateRec static int TxRetryRate; //static int SQ3, BSS_PK_CNT, NIDLESLOT, SLOT_CNT, INTERF_CNT, GAP_CNT, DS_EVM; static s32 RSSIBuf[RSSIBUF_NUM]={-70, -70, -70, -70, -70, -70, -70, -70, -70, -70}; static s32 RSSISmoothed=-700; static int RSSIBufIndex=0; static u8 max_rssi_rate; static int rate_tbl[13] = {0,1,2,5,11,6,9,12,18,24,36,48,54}; //[WKCHEN]static core_data_t *pMTOcore_data=NULL; static int TotalTxPkt = 0; static int TotalTxPktRetry = 0; static int TxPktPerAnt[3] = {0,0,0}; static int RXRSSIANT[3] ={-70,-70,-70}; static int TxPktRetryPerAnt[3] = {0,0,0}; //static int TxDominateFlag=FALSE; static u8 old_antenna[4]={1 ,0 ,1 ,0}; static int retryrate_rec[MTO_MAX_DATA_RATE_LEVELS];//this record the retry rate at different data rate static int PeriodTotalTxPkt = 0; static int PeriodTotalTxPktRetry = 0; typedef struct { s32 RSSI; u8 TxRate; }RSSI2RATE; static RSSI2RATE RSSI2RateTbl[RSSI2RATE_SIZE] = { {-740, 108}, // 54M {-760, 96}, // 48M {-820, 72}, // 36M {-850, 48}, // 24M {-870, 36}, // 18M {-890, 24}, // 12M {-900, 12}, // 6M {-920, 11}, // 5.5M {-950, 4}, // 2M }; static u8 untogglecount; static u8 last_rate_ant; //this is used for antenna backoff-hh u8 boSparseTxTraffic = FALSE; void MTO_Init(MTO_FUNC_INPUT); void AntennaToggleInitiator(MTO_FUNC_INPUT); void AntennaToggleState(MTO_FUNC_INPUT); void TxPwrControl(MTO_FUNC_INPUT); void GetFreshAntennaData(MTO_FUNC_INPUT); void TxRateReductionCtrl(MTO_FUNC_INPUT); /** 1.1.31.1000 Turbo modify */ //void MTO_SetDTORateRange(int type); void MTO_SetDTORateRange(MTO_FUNC_INPUT, u8 *pRateArray, u8 ArraySize); void MTO_SetTxCount(MTO_FUNC_INPUT, u8 t0, u8 index); void MTO_TxFailed(MTO_FUNC_INPUT); void SmoothRSSI(s32 new_rssi); void hal_get_dto_para(MTO_FUNC_INPUT, char *buffer); u8 CalcNewRate(MTO_FUNC_INPUT, u8 old_rate, u32 retry_cnt, u32 tx_frag_cnt); u8 GetMaxRateLevelFromRSSI(void); u8 MTO_GetTxFallbackRate(MTO_FUNC_INPUT); int Divide(int a, int b); void multiagc(MTO_FUNC_INPUT, u8 high_gain_mode); //=========================================================================== // MTO_Init -- // // Description: // Set DTO Tx Rate Scope because different AP could have different Rate set. // After our staion join with AP, LM core will call this function to initialize // Tx Rate table. // // Arguments: // pRateArray - The pointer to the Tx Rate Array by the following order // - 2, 4, 11, 22, 12, 18, 24, 36, 48, 72, 96, 108 // - DTO won't check whether rate order is invalid or not // ArraySize - The array size to indicate how many tx rate we can choose // // sample code: // { // u8 RateArray[4] = {2, 4, 11, 22}; // MTO_SetDTORateRange(RateArray, 4); // } // // Return Value: // None //============================================================================ void MTO_SetDTORateRange(MTO_FUNC_INPUT,u8 *pRateArray, u8 ArraySize) { u8 i, j=0; for(i=0;i0;i--) { if(pRateArray[i-1] <= 11) break; pRateArray[i] = pRateArray[i-1]; } pRateArray[i] = 22; MTO_OFDM_RATE_LEVEL() = i; } else { for(i=0; i= 12) break; } MTO_OFDM_RATE_LEVEL() = i; } for(i=0;i MTO_Init()\n")); //[WKCHEN]pMTOcore_data = pcore_data; // 20040510 Turbo add for global variable MTO_TMR_CNT() = 0; MTO_TOGGLE_STATE() = TOGGLE_STATE_IDLE; MTO_TX_RATE_REDUCTION_STATE() = RATE_CHGSTATE_IDLE; MTO_BACKOFF_TMR() = 0; MTO_LAST_RATE() = 11; MTO_CO_EFFICENT() = 0; //MTO_TH_FIXANT() = MTO_DEFAULT_TH_FIXANT; MTO_TH_CNT() = MTO_DEFAULT_TH_CNT; MTO_TH_SQ3() = MTO_DEFAULT_TH_SQ3; MTO_TH_IDLE_SLOT() = MTO_DEFAULT_TH_IDLE_SLOT; MTO_TH_PR_INTERF() = MTO_DEFAULT_TH_PR_INTERF; MTO_TMR_AGING() = MTO_DEFAULT_TMR_AGING; MTO_TMR_PERIODIC() = MTO_DEFAULT_TMR_PERIODIC; //[WKCHEN]MTO_CCA_MODE_SETUP()= (u8) hal_get_cca_mode(MTO_HAL()); //[WKCHEN]MTO_CCA_MODE() = MTO_CCA_MODE_SETUP(); //MTO_PREAMBLE_TYPE() = MTO_PREAMBLE_LONG; MTO_PREAMBLE_TYPE() = MTO_PREAMBLE_SHORT; // for test MTO_ANT_SEL() = hal_get_antenna_number(MTO_HAL()); MTO_ANT_MAC() = MTO_ANT_SEL(); MTO_CNT_ANT(0) = 0; MTO_CNT_ANT(1) = 0; MTO_SQ_ANT(0) = 0; MTO_SQ_ANT(1) = 0; MTO_ANT_DIVERSITY() = MTO_ANTENNA_DIVERSITY_ON; //CardSet_AntennaDiversity(Adapter, MTO_ANT_DIVERSITY()); //PLMESetAntennaDiversity( Adapter, MTO_ANT_DIVERSITY()); MTO_AGING_TIMEOUT() = 0;//MTO_TMR_AGING() / MTO_TMR_PERIODIC(); // The following parameters should be initialized to the values set by user // //MTO_RATE_LEVEL() = 10; MTO_RATE_LEVEL() = 0; MTO_FALLBACK_RATE_LEVEL() = MTO_RATE_LEVEL(); MTO_FRAG_TH_LEVEL() = 4; /** 1.1.23.1000 Turbo modify from -1 to +1 MTO_RTS_THRESHOLD() = MTO_FRAG_TH() - 1; MTO_RTS_THRESHOLD_SETUP() = MTO_FRAG_TH() - 1; */ MTO_RTS_THRESHOLD() = MTO_FRAG_TH() + 1; MTO_RTS_THRESHOLD_SETUP() = MTO_FRAG_TH() + 1; // 1.1.23.1000 Turbo add for mto change preamble from 0 to 1 MTO_RATE_CHANGE_ENABLE() = 1; MTO_FRAG_CHANGE_ENABLE() = 0; // 1.1.29.1000 Turbo add don't support frag //The default valud of ANTDIV_DEFAULT_ON will be decided by EEPROM //#ifdef ANTDIV_DEFAULT_ON //MTO_ANT_DIVERSITY_ENABLE() = 1; //#else //MTO_ANT_DIVERSITY_ENABLE() = 0; //#endif MTO_POWER_CHANGE_ENABLE() = 1; MTO_PREAMBLE_CHANGE_ENABLE()= 1; MTO_RTS_CHANGE_ENABLE() = 0; // 1.1.29.1000 Turbo add don't support frag // 20040512 Turbo add //old_antenna[0] = 1; //old_antenna[1] = 0; //old_antenna[2] = 1; //old_antenna[3] = 0; for (i=0;iphy_type) { case RF_AIROHA_2230: case RF_AIROHA_2230S: // 20060420 Add this MTOPARA_TXPOWER_INDEX() = 46; // MAX-8 // @@ Only for AL 2230 break; case RF_AIROHA_7230: MTOPARA_TXPOWER_INDEX() = 49; break; case RF_WB_242: MTOPARA_TXPOWER_INDEX() = 10; break; case RF_WB_242_1: MTOPARA_TXPOWER_INDEX() = 24; // ->10 20060316.1 modify break; } } else //follow the setting from EEPROM MTOPARA_TXPOWER_INDEX() = MTO_TXPOWER_FROM_EEPROM; hal_set_rf_power(MTO_HAL(), (u8)MTOPARA_TXPOWER_INDEX()); //------------------------------------------------ // For RSSI turning 20060808.4 Cancel load from EEPROM MTO_DATA().RSSI_high = -41; MTO_DATA().RSSI_low = -60; } //---------------------------------------------------------------------------// static u32 DTO_Rx_Info[13][3]; static u32 DTO_RxCRCFail_Info[13][3]; static u32 AntennaToggleBkoffTimer=5; typedef struct{ int RxRate; int RxRatePkts; int index; }RXRATE_ANT; RXRATE_ANT RxRatePeakAnt[3]; #define ANT0 0 #define ANT1 1 #define OLD_ANT 2 void SearchPeakRxRate(int index) { int i; RxRatePeakAnt[index].RxRatePkts=0; //Find out the best rx rate which is used on different antenna for(i=1;i<13;i++) { if(DTO_Rx_Info[i][index] > (u32) RxRatePeakAnt[index].RxRatePkts) { RxRatePeakAnt[index].RxRatePkts = DTO_Rx_Info[i][index]; RxRatePeakAnt[index].RxRate = rate_tbl[i]; RxRatePeakAnt[index].index = i; } } } void ResetDTO_RxInfo(int index, MTO_FUNC_INPUT) { int i; #ifdef _PE_DTO_DUMP_ WBDEBUG(("ResetDTOrx\n")); #endif for(i=0;i<13;i++) DTO_Rx_Info[i][index] = MTO_HAL()->rx_ok_count[i]; for(i=0;i<13;i++) DTO_RxCRCFail_Info[i][index] = MTO_HAL()->rx_err_count[i]; TotalTxPkt = 0; TotalTxPktRetry = 0; } void GetDTO_RxInfo(int index, MTO_FUNC_INPUT) { int i; #ifdef _PE_DTO_DUMP_ WBDEBUG(("GetDTOrx\n")); #endif //PDEBUG(("[MTO]:DTO_Rx_Info[%d]=%d, rx_ok_count=%d\n", index, DTO_Rx_Info[0][index], phw_data->rx_ok_count[0])); for(i=0;i<13;i++) DTO_Rx_Info[i][index] = abs(MTO_HAL()->rx_ok_count[i] - DTO_Rx_Info[i][index]); if(DTO_Rx_Info[0][index]==0) DTO_Rx_Info[0][index] = 1; for(i=0;i<13;i++) DTO_RxCRCFail_Info[i][index] = MTO_HAL()->rx_err_count[i] - DTO_RxCRCFail_Info[i][index]; TxPktPerAnt[index] = TotalTxPkt; TxPktRetryPerAnt[index] = TotalTxPktRetry; TotalTxPkt = 0; TotalTxPktRetry = 0; } void OutputDebugInfo(int index1, int index2) { #ifdef _PE_DTO_DUMP_ WBDEBUG(("[HHDTO]:Total Rx (%d)\t\t(%d) \n ", DTO_Rx_Info[0][index1], DTO_Rx_Info[0][index2])); WBDEBUG(("[HHDTO]:RECEIVE RSSI: (%d)\t\t(%d) \n ", RXRSSIANT[index1], RXRSSIANT[index2])); WBDEBUG(("[HHDTO]:TX packet correct rate: (%d)%%\t\t(%d)%% \n ",Divide(TxPktPerAnt[index1]*100,TxPktRetryPerAnt[index1]), Divide(TxPktPerAnt[index2]*100,TxPktRetryPerAnt[index2]))); #endif { int tmp1, tmp2; #ifdef _PE_DTO_DUMP_ WBDEBUG(("[HHDTO]:Total Tx (%d)\t\t(%d) \n ", TxPktPerAnt[index1], TxPktPerAnt[index2])); WBDEBUG(("[HHDTO]:Total Tx retry (%d)\t\t(%d) \n ", TxPktRetryPerAnt[index1], TxPktRetryPerAnt[index2])); #endif tmp1 = TxPktPerAnt[index1] + DTO_Rx_Info[0][index1]; tmp2 = TxPktPerAnt[index2] + DTO_Rx_Info[0][index2]; #ifdef _PE_DTO_DUMP_ WBDEBUG(("[HHDTO]:Total Tx+RX (%d)\t\t(%d) \n ", tmp1, tmp2)); #endif } } unsigned char TxDominate(int index) { int tmp; tmp = TxPktPerAnt[index] + DTO_Rx_Info[0][index]; if(Divide(TxPktPerAnt[index]*100, tmp) > 40) return TRUE; else return FALSE; } unsigned char CmpTxRetryRate(int index1, int index2) { int tx_retry_rate1, tx_retry_rate2; tx_retry_rate1 = Divide((TxPktRetryPerAnt[index1] - TxPktPerAnt[index1])*100, TxPktRetryPerAnt[index1]); tx_retry_rate2 = Divide((TxPktRetryPerAnt[index2] - TxPktPerAnt[index2])*100, TxPktRetryPerAnt[index2]); #ifdef _PE_DTO_DUMP_ WBDEBUG(("[MTO]:TxRetry Ant0: (%d%%) Ant1: (%d%%) \n ", tx_retry_rate1, tx_retry_rate2)); #endif if(tx_retry_rate1 > tx_retry_rate2) return TRUE; else return FALSE; } void GetFreshAntennaData(MTO_FUNC_INPUT) { u8 x; x = hal_get_antenna_number(MTO_HAL()); //hal_get_bss_pk_cnt(MTO_HAL()); //hal_get_est_sq3(MTO_HAL(), 1); old_antenna[0] = x; //if this is the function for timer ResetDTO_RxInfo(x, MTO_FUNC_INPUT_DATA); if(AntennaToggleBkoffTimer) AntennaToggleBkoffTimer--; if (abs(last_rate_ant-MTO_RATE_LEVEL())>1) //backoff timer reset AntennaToggleBkoffTimer=0; if (MTO_ANT_DIVERSITY() != MTO_ANTENNA_DIVERSITY_ON || MTO_ANT_DIVERSITY_ENABLE() != 1) AntennaToggleBkoffTimer=1; #ifdef _PE_DTO_DUMP_ WBDEBUG(("[HHDTO]:**last data rate=%d,now data rate=%d**antenna toggle timer=%d",last_rate_ant,MTO_RATE_LEVEL(),AntennaToggleBkoffTimer)); #endif last_rate_ant=MTO_RATE_LEVEL(); if(AntennaToggleBkoffTimer==0) { MTO_TOGGLE_STATE() = TOGGLE_STATE_WAIT0; #ifdef _PE_DTO_DUMP_ WBDEBUG(("[HHDTO]:===state is starting==for antenna toggle===")); #endif } else MTO_TOGGLE_STATE() = TOGGLE_STATE_IDLE; if ((MTO_BACKOFF_TMR()!=0)&&(MTO_RATE_LEVEL()>MTO_DataRateAvailableLevel - 3)) { MTO_TOGGLE_STATE() = TOGGLE_STATE_IDLE; #ifdef _PE_DTO_DUMP_ WBDEBUG(("[HHDTO]:===the data rate is %d (good)and will not toogle ===",MTO_DATA_RATE()>>1)); #endif } } int WB_PCR[2]; //packet correct rate void AntennaToggleState(MTO_FUNC_INPUT) { int decideantflag = 0; u8 x; s32 rssi; if(MTO_ANT_DIVERSITY_ENABLE() != 1) return; x = hal_get_antenna_number(MTO_HAL()); switch(MTO_TOGGLE_STATE()) { //Missing..... case TOGGLE_STATE_IDLE: case TOGGLE_STATE_BKOFF: break;; case TOGGLE_STATE_WAIT0://======== GetDTO_RxInfo(x, MTO_FUNC_INPUT_DATA); sme_get_rssi(MTO_FUNC_INPUT_DATA, &rssi); RXRSSIANT[x] = rssi; #ifdef _PE_DTO_DUMP_ WBDEBUG(("[HHDTO] **wait0==== Collecting Ant%d--rssi=%d\n", x,RXRSSIANT[x])); #endif //change antenna and reset the data at changed antenna x = (~x) & 0x01; MTO_ANT_SEL() = x; hal_set_antenna_number(MTO_HAL(), MTO_ANT_SEL()); LOCAL_ANTENNA_NO() = x; MTO_TOGGLE_STATE() = TOGGLE_STATE_WAIT1;//go to wait1 ResetDTO_RxInfo(x, MTO_FUNC_INPUT_DATA); break; case TOGGLE_STATE_WAIT1://=====wait1 //MTO_CNT_ANT(x) = hal_get_bss_pk_cnt(MTO_HAL()); //RXRSSIANT[x] = hal_get_rssi(MTO_HAL()); sme_get_rssi(MTO_FUNC_INPUT_DATA, &rssi); RXRSSIANT[x] = rssi; GetDTO_RxInfo(x, MTO_FUNC_INPUT_DATA); #ifdef _PE_DTO_DUMP_ WBDEBUG(("[HHDTO] **wait1==== Collecting Ant%d--rssi=%d\n", x,RXRSSIANT[x])); #endif MTO_TOGGLE_STATE() = TOGGLE_STATE_MAKEDESISION; break; case TOGGLE_STATE_MAKEDESISION: #ifdef _PE_DTO_DUMP_ WBDEBUG(("[HHDTO]:Ant--0-----------------1---\n")); OutputDebugInfo(ANT0,ANT1); #endif //PDEBUG(("[HHDTO] **decision====\n ")); //=====following is the decision produrce // // first: compare the rssi if difference >10 // select the larger one // ,others go to second // second: comapre the tx+rx packet count if difference >100 // use larger total packets antenna // third::compare the tx PER if packets>20 // if difference >5% using the bigger one // // fourth:compare the RX PER if packets>20 // if PER difference <5% // using old antenna // // if (abs(RXRSSIANT[ANT0]-RXRSSIANT[ANT1]) > MTOPARA_RSSI_TH_FOR_ANTDIV())//====rssi_th { if (RXRSSIANT[ANT0]>RXRSSIANT[ANT1]) { decideantflag=1; MTO_ANT_MAC() = ANT0; } else { decideantflag=1; MTO_ANT_MAC() = ANT1; } #ifdef _PE_DTO_DUMP_ WBDEBUG(("Select antenna by RSSI\n")); #endif } else if (abs(TxPktPerAnt[ANT0] + DTO_Rx_Info[0][ANT0]-TxPktPerAnt[ANT1]-DTO_Rx_Info[0][ANT1])<50)//=====total packet_th { #ifdef _PE_DTO_DUMP_ WBDEBUG(("Total tx/rx is close\n")); #endif if (TxDominate(ANT0) && TxDominate(ANT1)) { if ((TxPktPerAnt[ANT0]>10) && (TxPktPerAnt[ANT1]>10))//====tx packet_th { WB_PCR[ANT0]=Divide(TxPktPerAnt[ANT0]*100,TxPktRetryPerAnt[ANT0]); WB_PCR[ANT1]=Divide(TxPktPerAnt[ANT1]*100,TxPktRetryPerAnt[ANT1]); if (abs(WB_PCR[ANT0]-WB_PCR[ANT1])>5)// tx PER_th { #ifdef _PE_DTO_DUMP_ WBDEBUG(("Decide by Tx correct rate\n")); #endif if (WB_PCR[ANT0]>WB_PCR[ANT1]) { decideantflag=1; MTO_ANT_MAC() = ANT0; } else { decideantflag=1; MTO_ANT_MAC() = ANT1; } } else { decideantflag=0; untogglecount++; MTO_ANT_MAC() = old_antenna[0]; } } else { decideantflag=0; MTO_ANT_MAC() = old_antenna[0]; } } else if ((DTO_Rx_Info[0][ANT0]>10)&&(DTO_Rx_Info[0][ANT1]>10))//rx packet th { #ifdef _PE_DTO_DUMP_ WBDEBUG(("Decide by Rx\n")); #endif if (abs(DTO_Rx_Info[0][ANT0] - DTO_Rx_Info[0][ANT1])>50) { if (DTO_Rx_Info[0][ANT0] > DTO_Rx_Info[0][ANT1]) { decideantflag=1; MTO_ANT_MAC() = ANT0; } else { decideantflag=1; MTO_ANT_MAC() = ANT1; } } else { decideantflag=0; untogglecount++; MTO_ANT_MAC() = old_antenna[0]; } } else { decideantflag=0; MTO_ANT_MAC() = old_antenna[0]; } } else if ((TxPktPerAnt[ANT0]+DTO_Rx_Info[0][ANT0])>(TxPktPerAnt[ANT1]+DTO_Rx_Info[0][ANT1]))//use more packekts { #ifdef _PE_DTO_DUMP_ WBDEBUG(("decide by total tx/rx : ANT 0\n")); #endif decideantflag=1; MTO_ANT_MAC() = ANT0; } else { #ifdef _PE_DTO_DUMP_ WBDEBUG(("decide by total tx/rx : ANT 1\n")); #endif decideantflag=1; MTO_ANT_MAC() = ANT1; } //this is force ant toggle if (decideantflag==1) untogglecount=0; untogglecount=untogglecount%4; if (untogglecount==3) //change antenna MTO_ANT_MAC() = ((~old_antenna[0]) & 0x1); #ifdef _PE_DTO_DUMP_ WBDEBUG(("[HHDTO]:==================untoggle-count=%d",untogglecount)); #endif //PDEBUG(("[HHDTO] **********************************DTO ENABLE=%d",MTO_ANT_DIVERSITY_ENABLE())); if(MTO_ANT_DIVERSITY_ENABLE() == 1) { MTO_ANT_SEL() = MTO_ANT_MAC(); hal_set_antenna_number(MTO_HAL(), MTO_ANT_SEL()); LOCAL_ANTENNA_NO() = MTO_ANT_SEL(); #ifdef _PE_DTO_DUMP_ WBDEBUG(("[HHDTO] ==decision==*******antflag=%d******************selected antenna=%d\n",decideantflag,MTO_ANT_SEL())); #endif } if (decideantflag) { old_antenna[3]=old_antenna[2];//store antenna info old_antenna[2]=old_antenna[1]; old_antenna[1]=old_antenna[0]; old_antenna[0]= MTO_ANT_MAC(); } #ifdef _PE_DTO_DUMP_ WBDEBUG(("[HHDTO]:**old antenna=[%d][%d][%d][%d]\n",old_antenna[0],old_antenna[1],old_antenna[2],old_antenna[3])); #endif if (old_antenna[0]!=old_antenna[1]) AntennaToggleBkoffTimer=0; else if (old_antenna[1]!=old_antenna[2]) AntennaToggleBkoffTimer=1; else if (old_antenna[2]!=old_antenna[3]) AntennaToggleBkoffTimer=2; else AntennaToggleBkoffTimer=4; #ifdef _PE_DTO_DUMP_ WBDEBUG(("[HHDTO]:**back off timer=%d",AntennaToggleBkoffTimer)); #endif ResetDTO_RxInfo(MTO_ANT_MAC(), MTO_FUNC_INPUT_DATA); if (AntennaToggleBkoffTimer==0 && decideantflag) MTO_TOGGLE_STATE() = TOGGLE_STATE_WAIT0; else MTO_TOGGLE_STATE() = TOGGLE_STATE_IDLE; break; } } void multiagc(MTO_FUNC_INPUT, u8 high_gain_mode ) { s32 rssi; hw_data_t *pHwData = MTO_HAL(); sme_get_rssi(MTO_FUNC_INPUT_DATA, &rssi); if( (RF_WB_242 == pHwData->phy_type) || (RF_WB_242_1 == pHwData->phy_type) ) // 20060619.5 Add { if (high_gain_mode==1) { //hw_set_dxx_reg(phw_data, 0x0C, 0xf8f52230); //hw_set_dxx_reg(phw_data, 0x20, 0x06C43440); Wb35Reg_Write( pHwData, 0x100C, 0xF2F32232 ); // 940916 0xf8f52230 ); Wb35Reg_Write( pHwData, 0x1020, 0x04cb3440 ); // 940915 0x06C43440 } else if (high_gain_mode==0) { //hw_set_dxx_reg(phw_data, 0x0C, 0xEEEE000D); //hw_set_dxx_reg(phw_data, 0x20, 0x06c41440); Wb35Reg_Write( pHwData, 0x100C, 0xEEEE000D ); Wb35Reg_Write( pHwData, 0x1020, 0x04cb1440 ); // 940915 0x06c41440 } #ifdef _PE_DTO_DUMP_ WBDEBUG(("[HHDTOAGC] **rssi=%d, high gain mode=%d", rssi, high_gain_mode)); #endif } } void TxPwrControl(MTO_FUNC_INPUT) { s32 rssi; hw_data_t *pHwData = MTO_HAL(); sme_get_rssi(MTO_FUNC_INPUT_DATA, &rssi); if( (RF_WB_242 == pHwData->phy_type) || (RF_WB_242_1 == pHwData->phy_type) ) // 20060619.5 Add { static u8 high_gain_mode; //this is for winbond RF switch LNA //using different register setting if (high_gain_mode==1) { if( rssi > MTO_DATA().RSSI_high ) { //hw_set_dxx_reg(phw_data, 0x0C, 0xf8f52230); //hw_set_dxx_reg(phw_data, 0x20, 0x05541640); high_gain_mode=0; } else { //hw_set_dxx_reg(phw_data, 0x0C, 0xf8f51830); //hw_set_dxx_reg(phw_data, 0x20, 0x05543E40); high_gain_mode=1; } } else //if (high_gain_mode==0) { if( rssi < MTO_DATA().RSSI_low ) { //hw_set_dxx_reg(phw_data, 0x0C, 0xf8f51830); //hw_set_dxx_reg(phw_data, 0x20, 0x05543E40); high_gain_mode=1; } else { //hw_set_dxx_reg(phw_data, 0x0C, 0xf8f52230); //hw_set_dxx_reg(phw_data, 0x20, 0x05541640); high_gain_mode=0; } } // Always high gain 20051014. Using the initial value only. multiagc(MTO_FUNC_INPUT_DATA, high_gain_mode); } } u8 CalcNewRate(MTO_FUNC_INPUT, u8 old_rate, u32 retry_cnt, u32 tx_frag_cnt) { int i; u8 new_rate; u32 retry_rate; int TxThrouput1, TxThrouput2, TxThrouput3, BestThroupht; if(tx_frag_cnt < MTOPARA_TXCOUNT_TH_FOR_CALC_RATE()) //too few packets transmit { return 0xff; } retry_rate = Divide(retry_cnt * 100, tx_frag_cnt); if(retry_rate > 90) retry_rate = 90; //always truncate to 90% due to lookup table size #ifdef _PE_DTO_DUMP_ WBDEBUG(("##### Current level =%d, Retry count =%d, Frag count =%d\n", old_rate, retry_cnt, tx_frag_cnt)); WBDEBUG(("*##* Retry rate =%d, throughput =%d\n", retry_rate, Rate_PER_TBL[retry_rate][old_rate])); WBDEBUG(("TxRateRec.tx_rate =%d, Retry rate = %d, throughput = %d\n", TxRateRec.tx_rate, TxRateRec.tx_retry_rate, Rate_PER_TBL[TxRateRec.tx_retry_rate][Level2PerTbl[TxRateRec.tx_rate]])); WBDEBUG(("old_rate-1 =%d, Retry rate = %d, throughput = %d\n", old_rate-1, retryrate_rec[old_rate-1], Rate_PER_TBL[retryrate_rec[old_rate-1]][old_rate-1])); WBDEBUG(("old_rate+1 =%d, Retry rate = %d, throughput = %d\n", old_rate+1, retryrate_rec[old_rate+1], Rate_PER_TBL[retryrate_rec[old_rate+1]][old_rate+1])); #endif //following is for record the retry rate at the different data rate if (abs(retry_rate-retryrate_rec[old_rate])<50)//---the per TH retryrate_rec[old_rate] = retry_rate; //update retry rate else { for (i=0;i old_rate) //Decrease Tx Rate { TxThrouput1 = Rate_PER_TBL[TxRateRec.tx_retry_rate][Level2PerTbl[TxRateRec.tx_rate]]; TxThrouput2 = Rate_PER_TBL[retry_rate][Level2PerTbl[old_rate]]; if(TxThrouput1 > TxThrouput2) { new_rate = TxRateRec.tx_rate; BestThroupht = TxThrouput1; } else { new_rate = old_rate; BestThroupht = TxThrouput2; } if((old_rate > 0) &&(retry_rate>MTOPARA_TXRATE_DEC_TH())) //Min Rate { TxThrouput3 = Rate_PER_TBL[retryrate_rec[old_rate-1]][Level2PerTbl[old_rate-1]]; if(BestThroupht < TxThrouput3) { new_rate = old_rate - 1; #ifdef _PE_DTO_DUMP_ WBDEBUG(("--------\n")); #endif BestThroupht = TxThrouput3; } } } else if(TxRateRec.tx_rate < old_rate) //Increase Tx Rate { TxThrouput1 = Rate_PER_TBL[TxRateRec.tx_retry_rate][Level2PerTbl[TxRateRec.tx_rate]]; TxThrouput2 = Rate_PER_TBL[retry_rate][Level2PerTbl[old_rate]]; if(TxThrouput1 > TxThrouput2) { new_rate = TxRateRec.tx_rate; BestThroupht = TxThrouput1; } else { new_rate = old_rate; BestThroupht = TxThrouput2; } if ((old_rate < MTO_DataRateAvailableLevel - 1)&&(retry_rate MTOPARA_TXRETRYRATE_REDUCE()) TxThrouput3 = Rate_PER_TBL[retryrate_rec[old_rate+1]-MTOPARA_TXRETRYRATE_REDUCE()][Level2PerTbl[old_rate+1]]; else TxThrouput3 = Rate_PER_TBL[retryrate_rec[old_rate+1]][Level2PerTbl[old_rate+1]]; if(BestThroupht < TxThrouput3) { new_rate = old_rate + 1; #ifdef _PE_DTO_DUMP_ WBDEBUG(("++++++++++\n")); #endif BestThroupht = TxThrouput3; } } } else //Tx Rate no change { TxThrouput2 = Rate_PER_TBL[retry_rate][Level2PerTbl[old_rate]]; new_rate = old_rate; BestThroupht = TxThrouput2; if (retry_rate MTOPARA_TXRETRYRATE_REDUCE()) TxThrouput3 = Rate_PER_TBL[retryrate_rec[old_rate+1]-MTOPARA_TXRETRYRATE_REDUCE()][Level2PerTbl[old_rate+1]]; else TxThrouput3 = Rate_PER_TBL[retryrate_rec[old_rate+1]][Level2PerTbl[old_rate+1]]; if(BestThroupht < TxThrouput3) { new_rate = old_rate + 1; BestThroupht = TxThrouput3; #ifdef _PE_DTO_DUMP_ WBDEBUG(("=++++++++++\n")); #endif } } } else if(old_rate > 0) //Min Rate { TxThrouput3 = Rate_PER_TBL[retryrate_rec[old_rate-1]][Level2PerTbl[old_rate-1]]; if(BestThroupht < TxThrouput3) { new_rate = old_rate - 1; #ifdef _PE_DTO_DUMP_ WBDEBUG(("=--------\n")); #endif BestThroupht = TxThrouput3; } } } if (!LOCAL_IS_IBSS_MODE()) { max_rssi_rate = GetMaxRateLevelFromRSSI(); #ifdef _PE_DTO_DUMP_ WBDEBUG(("[MTO]:RSSI2Rate=%d\n", MTO_Data_Rate_Tbl[max_rssi_rate])); #endif if(new_rate > max_rssi_rate) new_rate = max_rssi_rate; } //save new rate; TxRateRec.tx_rate = old_rate; TxRateRec.tx_retry_rate = (u8) retry_rate; TxRetryRate = retry_rate; return new_rate; } void SmoothRSSI(s32 new_rssi) { RSSISmoothed = RSSISmoothed + new_rssi - RSSIBuf[RSSIBufIndex]; RSSIBuf[RSSIBufIndex] = new_rssi; RSSIBufIndex = (RSSIBufIndex + 1) % 10; } u8 GetMaxRateLevelFromRSSI(void) { u8 i; u8 TxRate; for(i=0;i RSSI2RateTbl[i].RSSI) break; } #ifdef _PE_DTO_DUMP_ WBDEBUG(("[MTO]:RSSI=%d\n", Divide(RSSISmoothed, 10))); #endif if(i < RSSI2RATE_SIZE) TxRate = RSSI2RateTbl[i].TxRate; else TxRate = 2; //divided by 2 = 1Mbps for(i=MTO_DataRateAvailableLevel-1;i>0;i--) { if(TxRate >=MTO_Data_Rate_Tbl[i]) break; } return i; } //=========================================================================== // Description: // If we enable DTO, we will ignore the tx count with different tx rate from // DTO rate. This is because when we adjust DTO tx rate, there could be some // packets in the tx queue with previous tx rate void MTO_SetTxCount(MTO_FUNC_INPUT, u8 tx_rate, u8 index) { MTO_TXFLOWCOUNT()++; if ((MTO_ENABLE==1) && (MTO_RATE_CHANGE_ENABLE()==1)) { if(tx_rate == MTO_DATA_RATE()) { if (index == 0) { if (boSparseTxTraffic) MTO_HAL()->dto_tx_frag_count += MTOPARA_PERIODIC_CHECK_CYCLE(); else MTO_HAL()->dto_tx_frag_count += 1; } else { if (index<8) { MTO_HAL()->dto_tx_retry_count += index; MTO_HAL()->dto_tx_frag_count += (index+1); } else { MTO_HAL()->dto_tx_retry_count += 7; MTO_HAL()->dto_tx_frag_count += 7; } } } else if(MTO_DATA_RATE()>48 && tx_rate ==48) {//ALFRED if (index<3) //for reduciing data rate scheme , //do not calcu different data rate //3 is the reducing data rate at retry { MTO_HAL()->dto_tx_retry_count += index; MTO_HAL()->dto_tx_frag_count += (index+1); } else { MTO_HAL()->dto_tx_retry_count += 3; MTO_HAL()->dto_tx_frag_count += 3; } } } else { MTO_HAL()->dto_tx_retry_count += index; MTO_HAL()->dto_tx_frag_count += (index+1); } TotalTxPkt ++; TotalTxPktRetry += (index+1); PeriodTotalTxPkt ++; PeriodTotalTxPktRetry += (index+1); } u8 MTO_GetTxFallbackRate(MTO_FUNC_INPUT) { return MTO_DATA_FALLBACK_RATE(); } //=========================================================================== // MTO_TxFailed -- // // Description: // Failure of transmitting a packet indicates that certain MTO parmeters // may need to be adjusted. This function is called when NIC just failed // to transmit a packet or when MSDULifeTime expired. // // Arguments: // Adapter - The pointer to the Miniport Adapter Context // // Return Value: // None //============================================================================ void MTO_TxFailed(MTO_FUNC_INPUT) { return; } int Divide(int a, int b) { if (b==0) b=1; return a/b; }