aboutsummaryrefslogtreecommitdiffstats
path: root/drivers/staging/rt3070/common/rtmp_init.c
diff options
context:
space:
mode:
Diffstat (limited to 'drivers/staging/rt3070/common/rtmp_init.c')
-rw-r--r--drivers/staging/rt3070/common/rtmp_init.c4197
1 files changed, 4197 insertions, 0 deletions
diff --git a/drivers/staging/rt3070/common/rtmp_init.c b/drivers/staging/rt3070/common/rtmp_init.c
new file mode 100644
index 000000000000..4503f6c6d954
--- /dev/null
+++ b/drivers/staging/rt3070/common/rtmp_init.c
@@ -0,0 +1,4197 @@
+/*
+ *************************************************************************
+ * Ralink Tech Inc.
+ * 5F., No.36, Taiyuan St., Jhubei City,
+ * Hsinchu County 302,
+ * Taiwan, R.O.C.
+ *
+ * (c) Copyright 2002-2007, Ralink Technology, Inc.
+ *
+ * This program is free software; you can redistribute it and/or modify *
+ * it under the terms of the GNU General Public License as published by *
+ * the Free Software Foundation; either version 2 of the License, or *
+ * (at your option) any later version. *
+ * *
+ * This program is distributed in the hope that it will be useful, *
+ * but WITHOUT ANY WARRANTY; without even the implied warranty of *
+ * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the *
+ * GNU General Public License for more details. *
+ * *
+ * You should have received a copy of the GNU General Public License *
+ * along with this program; if not, write to the *
+ * Free Software Foundation, Inc., *
+ * 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA. *
+ * *
+ *************************************************************************
+
+ Module Name:
+ rtmp_init.c
+
+ Abstract:
+ Miniport generic portion header file
+
+ Revision History:
+ Who When What
+ -------- ---------- ----------------------------------------------
+ Paul Lin 2002-08-01 created
+ John Chang 2004-08-20 RT2561/2661 use scatter-gather scheme
+ Jan Lee 2006-09-15 RT2860. Change for 802.11n , EEPROM, Led, BA, HT.
+*/
+#include "../rt_config.h"
+#include "../firmware.h"
+
+//#define BIN_IN_FILE /* use *.bin firmware */
+
+UCHAR BIT8[] = {0x01, 0x02, 0x04, 0x08, 0x10, 0x20, 0x40, 0x80};
+ULONG BIT32[] = {0x00000001, 0x00000002, 0x00000004, 0x00000008,
+ 0x00000010, 0x00000020, 0x00000040, 0x00000080,
+ 0x00000100, 0x00000200, 0x00000400, 0x00000800,
+ 0x00001000, 0x00002000, 0x00004000, 0x00008000,
+ 0x00010000, 0x00020000, 0x00040000, 0x00080000,
+ 0x00100000, 0x00200000, 0x00400000, 0x00800000,
+ 0x01000000, 0x02000000, 0x04000000, 0x08000000,
+ 0x10000000, 0x20000000, 0x40000000, 0x80000000};
+
+char* CipherName[] = {"none","wep64","wep128","TKIP","AES","CKIP64","CKIP128"};
+
+const unsigned short ccitt_16Table[] = {
+ 0x0000, 0x1021, 0x2042, 0x3063, 0x4084, 0x50A5, 0x60C6, 0x70E7,
+ 0x8108, 0x9129, 0xA14A, 0xB16B, 0xC18C, 0xD1AD, 0xE1CE, 0xF1EF,
+ 0x1231, 0x0210, 0x3273, 0x2252, 0x52B5, 0x4294, 0x72F7, 0x62D6,
+ 0x9339, 0x8318, 0xB37B, 0xA35A, 0xD3BD, 0xC39C, 0xF3FF, 0xE3DE,
+ 0x2462, 0x3443, 0x0420, 0x1401, 0x64E6, 0x74C7, 0x44A4, 0x5485,
+ 0xA56A, 0xB54B, 0x8528, 0x9509, 0xE5EE, 0xF5CF, 0xC5AC, 0xD58D,
+ 0x3653, 0x2672, 0x1611, 0x0630, 0x76D7, 0x66F6, 0x5695, 0x46B4,
+ 0xB75B, 0xA77A, 0x9719, 0x8738, 0xF7DF, 0xE7FE, 0xD79D, 0xC7BC,
+ 0x48C4, 0x58E5, 0x6886, 0x78A7, 0x0840, 0x1861, 0x2802, 0x3823,
+ 0xC9CC, 0xD9ED, 0xE98E, 0xF9AF, 0x8948, 0x9969, 0xA90A, 0xB92B,
+ 0x5AF5, 0x4AD4, 0x7AB7, 0x6A96, 0x1A71, 0x0A50, 0x3A33, 0x2A12,
+ 0xDBFD, 0xCBDC, 0xFBBF, 0xEB9E, 0x9B79, 0x8B58, 0xBB3B, 0xAB1A,
+ 0x6CA6, 0x7C87, 0x4CE4, 0x5CC5, 0x2C22, 0x3C03, 0x0C60, 0x1C41,
+ 0xEDAE, 0xFD8F, 0xCDEC, 0xDDCD, 0xAD2A, 0xBD0B, 0x8D68, 0x9D49,
+ 0x7E97, 0x6EB6, 0x5ED5, 0x4EF4, 0x3E13, 0x2E32, 0x1E51, 0x0E70,
+ 0xFF9F, 0xEFBE, 0xDFDD, 0xCFFC, 0xBF1B, 0xAF3A, 0x9F59, 0x8F78,
+ 0x9188, 0x81A9, 0xB1CA, 0xA1EB, 0xD10C, 0xC12D, 0xF14E, 0xE16F,
+ 0x1080, 0x00A1, 0x30C2, 0x20E3, 0x5004, 0x4025, 0x7046, 0x6067,
+ 0x83B9, 0x9398, 0xA3FB, 0xB3DA, 0xC33D, 0xD31C, 0xE37F, 0xF35E,
+ 0x02B1, 0x1290, 0x22F3, 0x32D2, 0x4235, 0x5214, 0x6277, 0x7256,
+ 0xB5EA, 0xA5CB, 0x95A8, 0x8589, 0xF56E, 0xE54F, 0xD52C, 0xC50D,
+ 0x34E2, 0x24C3, 0x14A0, 0x0481, 0x7466, 0x6447, 0x5424, 0x4405,
+ 0xA7DB, 0xB7FA, 0x8799, 0x97B8, 0xE75F, 0xF77E, 0xC71D, 0xD73C,
+ 0x26D3, 0x36F2, 0x0691, 0x16B0, 0x6657, 0x7676, 0x4615, 0x5634,
+ 0xD94C, 0xC96D, 0xF90E, 0xE92F, 0x99C8, 0x89E9, 0xB98A, 0xA9AB,
+ 0x5844, 0x4865, 0x7806, 0x6827, 0x18C0, 0x08E1, 0x3882, 0x28A3,
+ 0xCB7D, 0xDB5C, 0xEB3F, 0xFB1E, 0x8BF9, 0x9BD8, 0xABBB, 0xBB9A,
+ 0x4A75, 0x5A54, 0x6A37, 0x7A16, 0x0AF1, 0x1AD0, 0x2AB3, 0x3A92,
+ 0xFD2E, 0xED0F, 0xDD6C, 0xCD4D, 0xBDAA, 0xAD8B, 0x9DE8, 0x8DC9,
+ 0x7C26, 0x6C07, 0x5C64, 0x4C45, 0x3CA2, 0x2C83, 0x1CE0, 0x0CC1,
+ 0xEF1F, 0xFF3E, 0xCF5D, 0xDF7C, 0xAF9B, 0xBFBA, 0x8FD9, 0x9FF8,
+ 0x6E17, 0x7E36, 0x4E55, 0x5E74, 0x2E93, 0x3EB2, 0x0ED1, 0x1EF0
+};
+#define ByteCRC16(v, crc) \
+ (unsigned short)((crc << 8) ^ ccitt_16Table[((crc >> 8) ^ (v)) & 255])
+
+unsigned char BitReverse(unsigned char x)
+{
+ int i;
+ unsigned char Temp=0;
+ for(i=0; ; i++)
+ {
+ if(x & 0x80) Temp |= 0x80;
+ if(i==7) break;
+ x <<= 1;
+ Temp >>= 1;
+ }
+ return Temp;
+}
+
+//
+// BBP register initialization set
+//
+REG_PAIR BBPRegTable[] = {
+ {BBP_R65, 0x2C}, // fix rssi issue
+ {BBP_R66, 0x38}, // Also set this default value to pAd->BbpTuning.R66CurrentValue at initial
+ {BBP_R69, 0x12},
+ {BBP_R70, 0xa}, // BBP_R70 will change to 0x8 in ApStartUp and LinkUp for rt2860C, otherwise value is 0xa
+ {BBP_R73, 0x10},
+ {BBP_R81, 0x37},
+ {BBP_R82, 0x62},
+ {BBP_R83, 0x6A},
+ {BBP_R84, 0x99}, // 0x19 is for rt2860E and after. This is for extension channel overlapping IOT. 0x99 is for rt2860D and before
+ {BBP_R86, 0x00}, // middle range issue, Rory @2008-01-28
+ {BBP_R91, 0x04}, // middle range issue, Rory @2008-01-28
+ {BBP_R92, 0x00}, // middle range issue, Rory @2008-01-28
+ {BBP_R103, 0x00}, // near range high-power issue, requested from Gary @2008-0528
+ {BBP_R105, 0x05}, // 0x05 is for rt2860E to turn on FEQ control. It is safe for rt2860D and before, because Bit 7:2 are reserved in rt2860D and before.
+};
+#define NUM_BBP_REG_PARMS (sizeof(BBPRegTable) / sizeof(REG_PAIR))
+
+//
+// RF register initialization set
+//
+#ifdef RT30xx
+REG_PAIR RT30xx_RFRegTable[] = {
+ {RF_R04, 0x40},
+ {RF_R05, 0x03},
+ {RF_R06, 0x02},
+ {RF_R07, 0x70},
+ {RF_R09, 0x0F},
+ {RF_R10, 0x41},
+ {RF_R11, 0x21},
+ {RF_R12, 0x7B},
+ {RF_R14, 0x90},
+ {RF_R15, 0x58},
+ {RF_R16, 0xB3},
+ {RF_R17, 0x92},
+ {RF_R18, 0x2C},
+ {RF_R19, 0x02},
+ {RF_R20, 0xBA},
+ {RF_R21, 0xDB},
+ {RF_R24, 0x16},
+ {RF_R25, 0x01},
+ {RF_R29, 0x1F},
+};
+#define NUM_RF_REG_PARMS (sizeof(RT30xx_RFRegTable) / sizeof(REG_PAIR))
+#endif // RT30xx //
+
+//
+// ASIC register initialization sets
+//
+
+RTMP_REG_PAIR MACRegTable[] = {
+#if defined(HW_BEACON_OFFSET) && (HW_BEACON_OFFSET == 0x200)
+ {BCN_OFFSET0, 0xf8f0e8e0}, /* 0x3800(e0), 0x3A00(e8), 0x3C00(f0), 0x3E00(f8), 512B for each beacon */
+ {BCN_OFFSET1, 0x6f77d0c8}, /* 0x3200(c8), 0x3400(d0), 0x1DC0(77), 0x1BC0(6f), 512B for each beacon */
+#elif defined(HW_BEACON_OFFSET) && (HW_BEACON_OFFSET == 0x100)
+ {BCN_OFFSET0, 0xece8e4e0}, /* 0x3800, 0x3A00, 0x3C00, 0x3E00, 512B for each beacon */
+ {BCN_OFFSET1, 0xfcf8f4f0}, /* 0x3800, 0x3A00, 0x3C00, 0x3E00, 512B for each beacon */
+#else
+ #error You must re-calculate new value for BCN_OFFSET0 & BCN_OFFSET1 in MACRegTable[]!!!
+#endif // HW_BEACON_OFFSET //
+
+ {LEGACY_BASIC_RATE, 0x0000013f}, // Basic rate set bitmap
+ {HT_BASIC_RATE, 0x00008003}, // Basic HT rate set , 20M, MCS=3, MM. Format is the same as in TXWI.
+ {MAC_SYS_CTRL, 0x00}, // 0x1004, , default Disable RX
+ {RX_FILTR_CFG, 0x17f97}, //0x1400 , RX filter control,
+ {BKOFF_SLOT_CFG, 0x209}, // default set short slot time, CC_DELAY_TIME should be 2
+ //{TX_SW_CFG0, 0x40a06}, // Gary,2006-08-23
+ {TX_SW_CFG0, 0x0}, // Gary,2008-05-21 for CWC test
+ {TX_SW_CFG1, 0x80606}, // Gary,2006-08-23
+ {TX_LINK_CFG, 0x1020}, // Gary,2006-08-23
+ {TX_TIMEOUT_CFG, 0x000a2090},
+ {MAX_LEN_CFG, MAX_AGGREGATION_SIZE | 0x00001000}, // 0x3018, MAX frame length. Max PSDU = 16kbytes.
+ {LED_CFG, 0x7f031e46}, // Gary, 2006-08-23
+
+//#ifdef CONFIG_STA_SUPPORT
+// {WMM_AIFSN_CFG, 0x00002273},
+// {WMM_CWMIN_CFG, 0x00002344},
+// {WMM_CWMAX_CFG, 0x000034aa},
+//#endif // CONFIG_STA_SUPPORT //
+#ifdef INF_AMAZON_SE
+ {PBF_MAX_PCNT, 0x1F3F6F6F}, //iverson modify for usb issue, 2008/09/19
+ // 6F + 6F < total page count FE
+ // so that RX doesn't occupy TX's buffer space when WMM congestion.
+#else
+ {PBF_MAX_PCNT, 0x1F3FBF9F}, //0x1F3f7f9f}, //Jan, 2006/04/20
+#endif // INF_AMAZON_SE //
+ //{TX_RTY_CFG, 0x6bb80408}, // Jan, 2006/11/16
+ {TX_RTY_CFG, 0x47d01f0f}, // Jan, 2006/11/16, Set TxWI->ACK =0 in Probe Rsp Modify for 2860E ,2007-08-03
+ {AUTO_RSP_CFG, 0x00000013}, // Initial Auto_Responder, because QA will turn off Auto-Responder
+ {CCK_PROT_CFG, 0x05740003 /*0x01740003*/}, // Initial Auto_Responder, because QA will turn off Auto-Responder. And RTS threshold is enabled.
+ {OFDM_PROT_CFG, 0x05740003 /*0x01740003*/}, // Initial Auto_Responder, because QA will turn off Auto-Responder. And RTS threshold is enabled.
+//PS packets use Tx1Q (for HCCA) when dequeue from PS unicast queue (WiFi WPA2 MA9_DT1 for Marvell B STA)
+#ifdef RT2870
+#ifdef CONFIG_STA_SUPPORT
+ {PBF_CFG, 0xf40006}, // Only enable Queue 2
+#endif // CONFIG_STA_SUPPORT //
+ {MM40_PROT_CFG, 0x3F44084}, // Initial Auto_Responder, because QA will turn off Auto-Responder
+ {WPDMA_GLO_CFG, 0x00000030},
+#endif // RT2870 //
+ {GF20_PROT_CFG, 0x01744004}, // set 19:18 --> Short NAV for MIMO PS
+ {GF40_PROT_CFG, 0x03F44084},
+ {MM20_PROT_CFG, 0x01744004},
+ {TXOP_CTRL_CFG, 0x0000583f, /*0x0000243f*/ /*0x000024bf*/}, //Extension channel backoff.
+ {TX_RTS_CFG, 0x00092b20},
+//#ifdef WIFI_TEST
+ {EXP_ACK_TIME, 0x002400ca}, // default value
+//#else
+// {EXP_ACK_TIME, 0x005400ca}, // suggested by Gray @ 20070323 for 11n intel-sta throughput
+//#endif // end - WIFI_TEST //
+ {TXOP_HLDR_ET, 0x00000002},
+
+ /* Jerry comments 2008/01/16: we use SIFS = 10us in CCK defaultly, but it seems that 10us
+ is too small for INTEL 2200bg card, so in MBSS mode, the delta time between beacon0
+ and beacon1 is SIFS (10us), so if INTEL 2200bg card connects to BSS0, the ping
+ will always lost. So we change the SIFS of CCK from 10us to 16us. */
+ {XIFS_TIME_CFG, 0x33a41010},
+ {PWR_PIN_CFG, 0x00000003}, // patch for 2880-E
+};
+
+
+#ifdef CONFIG_STA_SUPPORT
+RTMP_REG_PAIR STAMACRegTable[] = {
+ {WMM_AIFSN_CFG, 0x00002273},
+ {WMM_CWMIN_CFG, 0x00002344},
+ {WMM_CWMAX_CFG, 0x000034aa},
+};
+#endif // CONFIG_STA_SUPPORT //
+
+#define NUM_MAC_REG_PARMS (sizeof(MACRegTable) / sizeof(RTMP_REG_PAIR))
+#ifdef CONFIG_STA_SUPPORT
+#define NUM_STA_MAC_REG_PARMS (sizeof(STAMACRegTable) / sizeof(RTMP_REG_PAIR))
+#endif // CONFIG_STA_SUPPORT //
+
+#ifdef RT2870
+//
+// RT2870 Firmware Spec only used 1 oct for version expression
+//
+#define FIRMWARE_MINOR_VERSION 7
+
+#endif // RT2870 //
+
+// New 8k byte firmware size for RT3071/RT3072
+#define FIRMWAREIMAGE_MAX_LENGTH 0x2000
+#define FIRMWAREIMAGE_LENGTH (sizeof (FirmwareImage) / sizeof(UCHAR))
+#define FIRMWARE_MAJOR_VERSION 0
+
+#define FIRMWAREIMAGEV1_LENGTH 0x1000
+#define FIRMWAREIMAGEV2_LENGTH 0x1000
+
+
+
+/*
+ ========================================================================
+
+ Routine Description:
+ Allocate RTMP_ADAPTER data block and do some initialization
+
+ Arguments:
+ Adapter Pointer to our adapter
+
+ Return Value:
+ NDIS_STATUS_SUCCESS
+ NDIS_STATUS_FAILURE
+
+ IRQL = PASSIVE_LEVEL
+
+ Note:
+
+ ========================================================================
+*/
+NDIS_STATUS RTMPAllocAdapterBlock(
+ IN PVOID handle,
+ OUT PRTMP_ADAPTER *ppAdapter)
+{
+ PRTMP_ADAPTER pAd;
+ NDIS_STATUS Status;
+ INT index;
+ UCHAR *pBeaconBuf = NULL;
+
+ DBGPRINT(RT_DEBUG_TRACE, ("--> RTMPAllocAdapterBlock\n"));
+
+ *ppAdapter = NULL;
+
+ do
+ {
+ // Allocate RTMP_ADAPTER memory block
+ pBeaconBuf = kmalloc(MAX_BEACON_SIZE, MEM_ALLOC_FLAG);
+ if (pBeaconBuf == NULL)
+ {
+ Status = NDIS_STATUS_FAILURE;
+ DBGPRINT_ERR(("Failed to allocate memory - BeaconBuf!\n"));
+ break;
+ }
+
+ Status = AdapterBlockAllocateMemory(handle, (PVOID *)&pAd);
+ if (Status != NDIS_STATUS_SUCCESS)
+ {
+ DBGPRINT_ERR(("Failed to allocate memory - ADAPTER\n"));
+ break;
+ }
+ pAd->BeaconBuf = pBeaconBuf;
+ printk("\n\n=== pAd = %p, size = %d ===\n\n", pAd, (UINT32)sizeof(RTMP_ADAPTER));
+
+
+ // Init spin locks
+ NdisAllocateSpinLock(&pAd->MgmtRingLock);
+
+ for (index =0 ; index < NUM_OF_TX_RING; index++)
+ {
+ NdisAllocateSpinLock(&pAd->TxSwQueueLock[index]);
+ NdisAllocateSpinLock(&pAd->DeQueueLock[index]);
+ pAd->DeQueueRunning[index] = FALSE;
+ }
+
+ NdisAllocateSpinLock(&pAd->irq_lock);
+
+ } while (FALSE);
+
+ if ((Status != NDIS_STATUS_SUCCESS) && (pBeaconBuf))
+ kfree(pBeaconBuf);
+
+ *ppAdapter = pAd;
+
+ DBGPRINT_S(Status, ("<-- RTMPAllocAdapterBlock, Status=%x\n", Status));
+ return Status;
+}
+
+/*
+ ========================================================================
+
+ Routine Description:
+ Read initial Tx power per MCS and BW from EEPROM
+
+ Arguments:
+ Adapter Pointer to our adapter
+
+ Return Value:
+ None
+
+ IRQL = PASSIVE_LEVEL
+
+ Note:
+
+ ========================================================================
+*/
+VOID RTMPReadTxPwrPerRate(
+ IN PRTMP_ADAPTER pAd)
+{
+ ULONG data, Adata, Gdata;
+ USHORT i, value, value2;
+ INT Apwrdelta, Gpwrdelta;
+ UCHAR t1,t2,t3,t4;
+ BOOLEAN bValid, bApwrdeltaMinus = TRUE, bGpwrdeltaMinus = TRUE;
+
+ //
+ // Get power delta for 20MHz and 40MHz.
+ //
+ DBGPRINT(RT_DEBUG_TRACE, ("Txpower per Rate\n"));
+ RT28xx_EEPROM_READ16(pAd, EEPROM_TXPOWER_DELTA, value2);
+ Apwrdelta = 0;
+ Gpwrdelta = 0;
+
+ if ((value2 & 0xff) != 0xff)
+ {
+ if ((value2 & 0x80))
+ Gpwrdelta = (value2&0xf);
+
+ if ((value2 & 0x40))
+ bGpwrdeltaMinus = FALSE;
+ else
+ bGpwrdeltaMinus = TRUE;
+ }
+ if ((value2 & 0xff00) != 0xff00)
+ {
+ if ((value2 & 0x8000))
+ Apwrdelta = ((value2&0xf00)>>8);
+
+ if ((value2 & 0x4000))
+ bApwrdeltaMinus = FALSE;
+ else
+ bApwrdeltaMinus = TRUE;
+ }
+ DBGPRINT(RT_DEBUG_TRACE, ("Gpwrdelta = %x, Apwrdelta = %x .\n", Gpwrdelta, Apwrdelta));
+
+ //
+ // Get Txpower per MCS for 20MHz in 2.4G.
+ //
+ for (i=0; i<5; i++)
+ {
+ RT28xx_EEPROM_READ16(pAd, EEPROM_TXPOWER_BYRATE_20MHZ_2_4G + i*4, value);
+ data = value;
+ if (bApwrdeltaMinus == FALSE)
+ {
+ t1 = (value&0xf)+(Apwrdelta);
+ if (t1 > 0xf)
+ t1 = 0xf;
+ t2 = ((value&0xf0)>>4)+(Apwrdelta);
+ if (t2 > 0xf)
+ t2 = 0xf;
+ t3 = ((value&0xf00)>>8)+(Apwrdelta);
+ if (t3 > 0xf)
+ t3 = 0xf;
+ t4 = ((value&0xf000)>>12)+(Apwrdelta);
+ if (t4 > 0xf)
+ t4 = 0xf;
+ }
+ else
+ {
+ if ((value&0xf) > Apwrdelta)
+ t1 = (value&0xf)-(Apwrdelta);
+ else
+ t1 = 0;
+ if (((value&0xf0)>>4) > Apwrdelta)
+ t2 = ((value&0xf0)>>4)-(Apwrdelta);
+ else
+ t2 = 0;
+ if (((value&0xf00)>>8) > Apwrdelta)
+ t3 = ((value&0xf00)>>8)-(Apwrdelta);
+ else
+ t3 = 0;
+ if (((value&0xf000)>>12) > Apwrdelta)
+ t4 = ((value&0xf000)>>12)-(Apwrdelta);
+ else
+ t4 = 0;
+ }
+ Adata = t1 + (t2<<4) + (t3<<8) + (t4<<12);
+ if (bGpwrdeltaMinus == FALSE)
+ {
+ t1 = (value&0xf)+(Gpwrdelta);
+ if (t1 > 0xf)
+ t1 = 0xf;
+ t2 = ((value&0xf0)>>4)+(Gpwrdelta);
+ if (t2 > 0xf)
+ t2 = 0xf;
+ t3 = ((value&0xf00)>>8)+(Gpwrdelta);
+ if (t3 > 0xf)
+ t3 = 0xf;
+ t4 = ((value&0xf000)>>12)+(Gpwrdelta);
+ if (t4 > 0xf)
+ t4 = 0xf;
+ }
+ else
+ {
+ if ((value&0xf) > Gpwrdelta)
+ t1 = (value&0xf)-(Gpwrdelta);
+ else
+ t1 = 0;
+ if (((value&0xf0)>>4) > Gpwrdelta)
+ t2 = ((value&0xf0)>>4)-(Gpwrdelta);
+ else
+ t2 = 0;
+ if (((value&0xf00)>>8) > Gpwrdelta)
+ t3 = ((value&0xf00)>>8)-(Gpwrdelta);
+ else
+ t3 = 0;
+ if (((value&0xf000)>>12) > Gpwrdelta)
+ t4 = ((value&0xf000)>>12)-(Gpwrdelta);
+ else
+ t4 = 0;
+ }
+ Gdata = t1 + (t2<<4) + (t3<<8) + (t4<<12);
+
+ RT28xx_EEPROM_READ16(pAd, EEPROM_TXPOWER_BYRATE_20MHZ_2_4G + i*4 + 2, value);
+ if (bApwrdeltaMinus == FALSE)
+ {
+ t1 = (value&0xf)+(Apwrdelta);
+ if (t1 > 0xf)
+ t1 = 0xf;
+ t2 = ((value&0xf0)>>4)+(Apwrdelta);
+ if (t2 > 0xf)
+ t2 = 0xf;
+ t3 = ((value&0xf00)>>8)+(Apwrdelta);
+ if (t3 > 0xf)
+ t3 = 0xf;
+ t4 = ((value&0xf000)>>12)+(Apwrdelta);
+ if (t4 > 0xf)
+ t4 = 0xf;
+ }
+ else
+ {
+ if ((value&0xf) > Apwrdelta)
+ t1 = (value&0xf)-(Apwrdelta);
+ else
+ t1 = 0;
+ if (((value&0xf0)>>4) > Apwrdelta)
+ t2 = ((value&0xf0)>>4)-(Apwrdelta);
+ else
+ t2 = 0;
+ if (((value&0xf00)>>8) > Apwrdelta)
+ t3 = ((value&0xf00)>>8)-(Apwrdelta);
+ else
+ t3 = 0;
+ if (((value&0xf000)>>12) > Apwrdelta)
+ t4 = ((value&0xf000)>>12)-(Apwrdelta);
+ else
+ t4 = 0;
+ }
+ Adata |= ((t1<<16) + (t2<<20) + (t3<<24) + (t4<<28));
+ if (bGpwrdeltaMinus == FALSE)
+ {
+ t1 = (value&0xf)+(Gpwrdelta);
+ if (t1 > 0xf)
+ t1 = 0xf;
+ t2 = ((value&0xf0)>>4)+(Gpwrdelta);
+ if (t2 > 0xf)
+ t2 = 0xf;
+ t3 = ((value&0xf00)>>8)+(Gpwrdelta);
+ if (t3 > 0xf)
+ t3 = 0xf;
+ t4 = ((value&0xf000)>>12)+(Gpwrdelta);
+ if (t4 > 0xf)
+ t4 = 0xf;
+ }
+ else
+ {
+ if ((value&0xf) > Gpwrdelta)
+ t1 = (value&0xf)-(Gpwrdelta);
+ else
+ t1 = 0;
+ if (((value&0xf0)>>4) > Gpwrdelta)
+ t2 = ((value&0xf0)>>4)-(Gpwrdelta);
+ else
+ t2 = 0;
+ if (((value&0xf00)>>8) > Gpwrdelta)
+ t3 = ((value&0xf00)>>8)-(Gpwrdelta);
+ else
+ t3 = 0;
+ if (((value&0xf000)>>12) > Gpwrdelta)
+ t4 = ((value&0xf000)>>12)-(Gpwrdelta);
+ else
+ t4 = 0;
+ }
+ Gdata |= ((t1<<16) + (t2<<20) + (t3<<24) + (t4<<28));
+ data |= (value<<16);
+
+ pAd->Tx20MPwrCfgABand[i] = pAd->Tx40MPwrCfgABand[i] = Adata;
+ pAd->Tx20MPwrCfgGBand[i] = pAd->Tx40MPwrCfgGBand[i] = Gdata;
+
+ if (data != 0xffffffff)
+ RTMP_IO_WRITE32(pAd, TX_PWR_CFG_0 + i*4, data);
+ DBGPRINT_RAW(RT_DEBUG_TRACE, ("20MHz BW, 2.4G band-%lx, Adata = %lx, Gdata = %lx \n", data, Adata, Gdata));
+ }
+
+ //
+ // Check this block is valid for 40MHz in 2.4G. If invalid, use parameter for 20MHz in 2.4G
+ //
+ bValid = TRUE;
+ for (i=0; i<6; i++)
+ {
+ RT28xx_EEPROM_READ16(pAd, EEPROM_TXPOWER_BYRATE_40MHZ_2_4G + 2 + i*2, value);
+ if (((value & 0x00FF) == 0x00FF) || ((value & 0xFF00) == 0xFF00))
+ {
+ bValid = FALSE;
+ break;
+ }
+ }
+
+ //
+ // Get Txpower per MCS for 40MHz in 2.4G.
+ //
+ if (bValid)
+ {
+ for (i=0; i<4; i++)
+ {
+ RT28xx_EEPROM_READ16(pAd, EEPROM_TXPOWER_BYRATE_40MHZ_2_4G + i*4, value);
+ if (bGpwrdeltaMinus == FALSE)
+ {
+ t1 = (value&0xf)+(Gpwrdelta);
+ if (t1 > 0xf)
+ t1 = 0xf;
+ t2 = ((value&0xf0)>>4)+(Gpwrdelta);
+ if (t2 > 0xf)
+ t2 = 0xf;
+ t3 = ((value&0xf00)>>8)+(Gpwrdelta);
+ if (t3 > 0xf)
+ t3 = 0xf;
+ t4 = ((value&0xf000)>>12)+(Gpwrdelta);
+ if (t4 > 0xf)
+ t4 = 0xf;
+ }
+ else
+ {
+ if ((value&0xf) > Gpwrdelta)
+ t1 = (value&0xf)-(Gpwrdelta);
+ else
+ t1 = 0;
+ if (((value&0xf0)>>4) > Gpwrdelta)
+ t2 = ((value&0xf0)>>4)-(Gpwrdelta);
+ else
+ t2 = 0;
+ if (((value&0xf00)>>8) > Gpwrdelta)
+ t3 = ((value&0xf00)>>8)-(Gpwrdelta);
+ else
+ t3 = 0;
+ if (((value&0xf000)>>12) > Gpwrdelta)
+ t4 = ((value&0xf000)>>12)-(Gpwrdelta);
+ else
+ t4 = 0;
+ }
+ Gdata = t1 + (t2<<4) + (t3<<8) + (t4<<12);
+
+ RT28xx_EEPROM_READ16(pAd, EEPROM_TXPOWER_BYRATE_40MHZ_2_4G + i*4 + 2, value);
+ if (bGpwrdeltaMinus == FALSE)
+ {
+ t1 = (value&0xf)+(Gpwrdelta);
+ if (t1 > 0xf)
+ t1 = 0xf;
+ t2 = ((value&0xf0)>>4)+(Gpwrdelta);
+ if (t2 > 0xf)
+ t2 = 0xf;
+ t3 = ((value&0xf00)>>8)+(Gpwrdelta);
+ if (t3 > 0xf)
+ t3 = 0xf;
+ t4 = ((value&0xf000)>>12)+(Gpwrdelta);
+ if (t4 > 0xf)
+ t4 = 0xf;
+ }
+ else
+ {
+ if ((value&0xf) > Gpwrdelta)
+ t1 = (value&0xf)-(Gpwrdelta);
+ else
+ t1 = 0;
+ if (((value&0xf0)>>4) > Gpwrdelta)
+ t2 = ((value&0xf0)>>4)-(Gpwrdelta);
+ else
+ t2 = 0;
+ if (((value&0xf00)>>8) > Gpwrdelta)
+ t3 = ((value&0xf00)>>8)-(Gpwrdelta);
+ else
+ t3 = 0;
+ if (((value&0xf000)>>12) > Gpwrdelta)
+ t4 = ((value&0xf000)>>12)-(Gpwrdelta);
+ else
+ t4 = 0;
+ }
+ Gdata |= ((t1<<16) + (t2<<20) + (t3<<24) + (t4<<28));
+
+ if (i == 0)
+ pAd->Tx40MPwrCfgGBand[i+1] = (pAd->Tx40MPwrCfgGBand[i+1] & 0x0000FFFF) | (Gdata & 0xFFFF0000);
+ else
+ pAd->Tx40MPwrCfgGBand[i+1] = Gdata;
+
+ DBGPRINT_RAW(RT_DEBUG_TRACE, ("40MHz BW, 2.4G band, Gdata = %lx \n", Gdata));
+ }
+ }
+
+ //
+ // Check this block is valid for 20MHz in 5G. If invalid, use parameter for 20MHz in 2.4G
+ //
+ bValid = TRUE;
+ for (i=0; i<8; i++)
+ {
+ RT28xx_EEPROM_READ16(pAd, EEPROM_TXPOWER_BYRATE_20MHZ_5G + 2 + i*2, value);
+ if (((value & 0x00FF) == 0x00FF) || ((value & 0xFF00) == 0xFF00))
+ {
+ bValid = FALSE;
+ break;
+ }
+ }
+
+ //
+ // Get Txpower per MCS for 20MHz in 5G.
+ //
+ if (bValid)
+ {
+ for (i=0; i<5; i++)
+ {
+ RT28xx_EEPROM_READ16(pAd, EEPROM_TXPOWER_BYRATE_20MHZ_5G + i*4, value);
+ if (bApwrdeltaMinus == FALSE)
+ {
+ t1 = (value&0xf)+(Apwrdelta);
+ if (t1 > 0xf)
+ t1 = 0xf;
+ t2 = ((value&0xf0)>>4)+(Apwrdelta);
+ if (t2 > 0xf)
+ t2 = 0xf;
+ t3 = ((value&0xf00)>>8)+(Apwrdelta);
+ if (t3 > 0xf)
+ t3 = 0xf;
+ t4 = ((value&0xf000)>>12)+(Apwrdelta);
+ if (t4 > 0xf)
+ t4 = 0xf;
+ }
+ else
+ {
+ if ((value&0xf) > Apwrdelta)
+ t1 = (value&0xf)-(Apwrdelta);
+ else
+ t1 = 0;
+ if (((value&0xf0)>>4) > Apwrdelta)
+ t2 = ((value&0xf0)>>4)-(Apwrdelta);
+ else
+ t2 = 0;
+ if (((value&0xf00)>>8) > Apwrdelta)
+ t3 = ((value&0xf00)>>8)-(Apwrdelta);
+ else
+ t3 = 0;
+ if (((value&0xf000)>>12) > Apwrdelta)
+ t4 = ((value&0xf000)>>12)-(Apwrdelta);
+ else
+ t4 = 0;
+ }
+ Adata = t1 + (t2<<4) + (t3<<8) + (t4<<12);
+
+ RT28xx_EEPROM_READ16(pAd, EEPROM_TXPOWER_BYRATE_20MHZ_5G + i*4 + 2, value);
+ if (bApwrdeltaMinus == FALSE)
+ {
+ t1 = (value&0xf)+(Apwrdelta);
+ if (t1 > 0xf)
+ t1 = 0xf;
+ t2 = ((value&0xf0)>>4)+(Apwrdelta);
+ if (t2 > 0xf)
+ t2 = 0xf;
+ t3 = ((value&0xf00)>>8)+(Apwrdelta);
+ if (t3 > 0xf)
+ t3 = 0xf;
+ t4 = ((value&0xf000)>>12)+(Apwrdelta);
+ if (t4 > 0xf)
+ t4 = 0xf;
+ }
+ else
+ {
+ if ((value&0xf) > Apwrdelta)
+ t1 = (value&0xf)-(Apwrdelta);
+ else
+ t1 = 0;
+ if (((value&0xf0)>>4) > Apwrdelta)
+ t2 = ((value&0xf0)>>4)-(Apwrdelta);
+ else
+ t2 = 0;
+ if (((value&0xf00)>>8) > Apwrdelta)
+ t3 = ((value&0xf00)>>8)-(Apwrdelta);
+ else
+ t3 = 0;
+ if (((value&0xf000)>>12) > Apwrdelta)
+ t4 = ((value&0xf000)>>12)-(Apwrdelta);
+ else
+ t4 = 0;
+ }
+ Adata |= ((t1<<16) + (t2<<20) + (t3<<24) + (t4<<28));
+
+ if (i == 0)
+ pAd->Tx20MPwrCfgABand[i] = (pAd->Tx20MPwrCfgABand[i] & 0x0000FFFF) | (Adata & 0xFFFF0000);
+ else
+ pAd->Tx20MPwrCfgABand[i] = Adata;
+
+ DBGPRINT_RAW(RT_DEBUG_TRACE, ("20MHz BW, 5GHz band, Adata = %lx \n", Adata));
+ }
+ }
+
+ //
+ // Check this block is valid for 40MHz in 5G. If invalid, use parameter for 20MHz in 2.4G
+ //
+ bValid = TRUE;
+ for (i=0; i<6; i++)
+ {
+ RT28xx_EEPROM_READ16(pAd, EEPROM_TXPOWER_BYRATE_40MHZ_5G + 2 + i*2, value);
+ if (((value & 0x00FF) == 0x00FF) || ((value & 0xFF00) == 0xFF00))
+ {
+ bValid = FALSE;
+ break;
+ }
+ }
+
+ //
+ // Get Txpower per MCS for 40MHz in 5G.
+ //
+ if (bValid)
+ {
+ for (i=0; i<4; i++)
+ {
+ RT28xx_EEPROM_READ16(pAd, EEPROM_TXPOWER_BYRATE_40MHZ_5G + i*4, value);
+ if (bApwrdeltaMinus == FALSE)
+ {
+ t1 = (value&0xf)+(Apwrdelta);
+ if (t1 > 0xf)
+ t1 = 0xf;
+ t2 = ((value&0xf0)>>4)+(Apwrdelta);
+ if (t2 > 0xf)
+ t2 = 0xf;
+ t3 = ((value&0xf00)>>8)+(Apwrdelta);
+ if (t3 > 0xf)
+ t3 = 0xf;
+ t4 = ((value&0xf000)>>12)+(Apwrdelta);
+ if (t4 > 0xf)
+ t4 = 0xf;
+ }
+ else
+ {
+ if ((value&0xf) > Apwrdelta)
+ t1 = (value&0xf)-(Apwrdelta);
+ else
+ t1 = 0;
+ if (((value&0xf0)>>4) > Apwrdelta)
+ t2 = ((value&0xf0)>>4)-(Apwrdelta);
+ else
+ t2 = 0;
+ if (((value&0xf00)>>8) > Apwrdelta)
+ t3 = ((value&0xf00)>>8)-(Apwrdelta);
+ else
+ t3 = 0;
+ if (((value&0xf000)>>12) > Apwrdelta)
+ t4 = ((value&0xf000)>>12)-(Apwrdelta);
+ else
+ t4 = 0;
+ }
+ Adata = t1 + (t2<<4) + (t3<<8) + (t4<<12);
+
+ RT28xx_EEPROM_READ16(pAd, EEPROM_TXPOWER_BYRATE_40MHZ_5G + i*4 + 2, value);
+ if (bApwrdeltaMinus == FALSE)
+ {
+ t1 = (value&0xf)+(Apwrdelta);
+ if (t1 > 0xf)
+ t1 = 0xf;
+ t2 = ((value&0xf0)>>4)+(Apwrdelta);
+ if (t2 > 0xf)
+ t2 = 0xf;
+ t3 = ((value&0xf00)>>8)+(Apwrdelta);
+ if (t3 > 0xf)
+ t3 = 0xf;
+ t4 = ((value&0xf000)>>12)+(Apwrdelta);
+ if (t4 > 0xf)
+ t4 = 0xf;
+ }
+ else
+ {
+ if ((value&0xf) > Apwrdelta)
+ t1 = (value&0xf)-(Apwrdelta);
+ else
+ t1 = 0;
+ if (((value&0xf0)>>4) > Apwrdelta)
+ t2 = ((value&0xf0)>>4)-(Apwrdelta);
+ else
+ t2 = 0;
+ if (((value&0xf00)>>8) > Apwrdelta)
+ t3 = ((value&0xf00)>>8)-(Apwrdelta);
+ else
+ t3 = 0;
+ if (((value&0xf000)>>12) > Apwrdelta)
+ t4 = ((value&0xf000)>>12)-(Apwrdelta);
+ else
+ t4 = 0;
+ }
+ Adata |= ((t1<<16) + (t2<<20) + (t3<<24) + (t4<<28));
+
+ if (i == 0)
+ pAd->Tx40MPwrCfgABand[i+1] = (pAd->Tx40MPwrCfgABand[i+1] & 0x0000FFFF) | (Adata & 0xFFFF0000);
+ else
+ pAd->Tx40MPwrCfgABand[i+1] = Adata;
+
+ DBGPRINT_RAW(RT_DEBUG_TRACE, ("40MHz BW, 5GHz band, Adata = %lx \n", Adata));
+ }
+ }
+}
+
+
+/*
+ ========================================================================
+
+ Routine Description:
+ Read initial channel power parameters from EEPROM
+
+ Arguments:
+ Adapter Pointer to our adapter
+
+ Return Value:
+ None
+
+ IRQL = PASSIVE_LEVEL
+
+ Note:
+
+ ========================================================================
+*/
+VOID RTMPReadChannelPwr(
+ IN PRTMP_ADAPTER pAd)
+{
+ UCHAR i, choffset;
+ EEPROM_TX_PWR_STRUC Power;
+ EEPROM_TX_PWR_STRUC Power2;
+
+ // Read Tx power value for all channels
+ // Value from 1 - 0x7f. Default value is 24.
+ // Power value : 2.4G 0x00 (0) ~ 0x1F (31)
+ // : 5.5G 0xF9 (-7) ~ 0x0F (15)
+
+ // 0. 11b/g, ch1 - ch 14
+ for (i = 0; i < 7; i++)
+ {
+// Power.word = RTMP_EEPROM_READ16(pAd, EEPROM_G_TX_PWR_OFFSET + i * 2);
+// Power2.word = RTMP_EEPROM_READ16(pAd, EEPROM_G_TX2_PWR_OFFSET + i * 2);
+ RT28xx_EEPROM_READ16(pAd, EEPROM_G_TX_PWR_OFFSET + i * 2, Power.word);
+ RT28xx_EEPROM_READ16(pAd, EEPROM_G_TX2_PWR_OFFSET + i * 2, Power2.word);
+ pAd->TxPower[i * 2].Channel = i * 2 + 1;
+ pAd->TxPower[i * 2 + 1].Channel = i * 2 + 2;
+
+ if ((Power.field.Byte0 > 31) || (Power.field.Byte0 < 0))
+ pAd->TxPower[i * 2].Power = DEFAULT_RF_TX_POWER;
+ else
+ pAd->TxPower[i * 2].Power = Power.field.Byte0;
+
+ if ((Power.field.Byte1 > 31) || (Power.field.Byte1 < 0))
+ pAd->TxPower[i * 2 + 1].Power = DEFAULT_RF_TX_POWER;
+ else
+ pAd->TxPower[i * 2 + 1].Power = Power.field.Byte1;
+
+ if ((Power2.field.Byte0 > 31) || (Power2.field.Byte0 < 0))
+ pAd->TxPower[i * 2].Power2 = DEFAULT_RF_TX_POWER;
+ else
+ pAd->TxPower[i * 2].Power2 = Power2.field.Byte0;
+
+ if ((Power2.field.Byte1 > 31) || (Power2.field.Byte1 < 0))
+ pAd->TxPower[i * 2 + 1].Power2 = DEFAULT_RF_TX_POWER;
+ else
+ pAd->TxPower[i * 2 + 1].Power2 = Power2.field.Byte1;
+ }
+
+ // 1. U-NII lower/middle band: 36, 38, 40; 44, 46, 48; 52, 54, 56; 60, 62, 64 (including central frequency in BW 40MHz)
+ // 1.1 Fill up channel
+ choffset = 14;
+ for (i = 0; i < 4; i++)
+ {
+ pAd->TxPower[3 * i + choffset + 0].Channel = 36 + i * 8 + 0;
+ pAd->TxPower[3 * i + choffset + 0].Power = DEFAULT_RF_TX_POWER;
+ pAd->TxPower[3 * i + choffset + 0].Power2 = DEFAULT_RF_TX_POWER;
+
+ pAd->TxPower[3 * i + choffset + 1].Channel = 36 + i * 8 + 2;
+ pAd->TxPower[3 * i + choffset + 1].Power = DEFAULT_RF_TX_POWER;
+ pAd->TxPower[3 * i + choffset + 1].Power2 = DEFAULT_RF_TX_POWER;
+
+ pAd->TxPower[3 * i + choffset + 2].Channel = 36 + i * 8 + 4;
+ pAd->TxPower[3 * i + choffset + 2].Power = DEFAULT_RF_TX_POWER;
+ pAd->TxPower[3 * i + choffset + 2].Power2 = DEFAULT_RF_TX_POWER;
+ }
+
+ // 1.2 Fill up power
+ for (i = 0; i < 6; i++)
+ {
+// Power.word = RTMP_EEPROM_READ16(pAd, EEPROM_A_TX_PWR_OFFSET + i * 2);
+// Power2.word = RTMP_EEPROM_READ16(pAd, EEPROM_A_TX2_PWR_OFFSET + i * 2);
+ RT28xx_EEPROM_READ16(pAd, EEPROM_A_TX_PWR_OFFSET + i * 2, Power.word);
+ RT28xx_EEPROM_READ16(pAd, EEPROM_A_TX2_PWR_OFFSET + i * 2, Power2.word);
+
+ if ((Power.field.Byte0 < 16) && (Power.field.Byte0 >= -7))
+ pAd->TxPower[i * 2 + choffset + 0].Power = Power.field.Byte0;
+
+ if ((Power.field.Byte1 < 16) && (Power.field.Byte1 >= -7))
+ pAd->TxPower[i * 2 + choffset + 1].Power = Power.field.Byte1;
+
+ if ((Power2.field.Byte0 < 16) && (Power2.field.Byte0 >= -7))
+ pAd->TxPower[i * 2 + choffset + 0].Power2 = Power2.field.Byte0;
+
+ if ((Power2.field.Byte1 < 16) && (Power2.field.Byte1 >= -7))
+ pAd->TxPower[i * 2 + choffset + 1].Power2 = Power2.field.Byte1;
+ }
+
+ // 2. HipperLAN 2 100, 102 ,104; 108, 110, 112; 116, 118, 120; 124, 126, 128; 132, 134, 136; 140 (including central frequency in BW 40MHz)
+ // 2.1 Fill up channel
+ choffset = 14 + 12;
+ for (i = 0; i < 5; i++)
+ {
+ pAd->TxPower[3 * i + choffset + 0].Channel = 100 + i * 8 + 0;
+ pAd->TxPower[3 * i + choffset + 0].Power = DEFAULT_RF_TX_POWER;
+ pAd->TxPower[3 * i + choffset + 0].Power2 = DEFAULT_RF_TX_POWER;
+
+ pAd->TxPower[3 * i + choffset + 1].Channel = 100 + i * 8 + 2;
+ pAd->TxPower[3 * i + choffset + 1].Power = DEFAULT_RF_TX_POWER;
+ pAd->TxPower[3 * i + choffset + 1].Power2 = DEFAULT_RF_TX_POWER;
+
+ pAd->TxPower[3 * i + choffset + 2].Channel = 100 + i * 8 + 4;
+ pAd->TxPower[3 * i + choffset + 2].Power = DEFAULT_RF_TX_POWER;
+ pAd->TxPower[3 * i + choffset + 2].Power2 = DEFAULT_RF_TX_POWER;
+ }
+ pAd->TxPower[3 * 5 + choffset + 0].Channel = 140;
+ pAd->TxPower[3 * 5 + choffset + 0].Power = DEFAULT_RF_TX_POWER;
+ pAd->TxPower[3 * 5 + choffset + 0].Power2 = DEFAULT_RF_TX_POWER;
+
+ // 2.2 Fill up power
+ for (i = 0; i < 8; i++)
+ {
+// Power.word = RTMP_EEPROM_READ16(pAd, EEPROM_A_TX_PWR_OFFSET + (choffset - 14) + i * 2);
+// Power2.word = RTMP_EEPROM_READ16(pAd, EEPROM_A_TX2_PWR_OFFSET + (choffset - 14) + i * 2);
+ RT28xx_EEPROM_READ16(pAd, EEPROM_A_TX_PWR_OFFSET + (choffset - 14) + i * 2, Power.word);
+ RT28xx_EEPROM_READ16(pAd, EEPROM_A_TX2_PWR_OFFSET + (choffset - 14) + i * 2, Power2.word);
+
+ if ((Power.field.Byte0 < 16) && (Power.field.Byte0 >= -7))
+ pAd->TxPower[i * 2 + choffset + 0].Power = Power.field.Byte0;
+
+ if ((Power.field.Byte1 < 16) && (Power.field.Byte1 >= -7))
+ pAd->TxPower[i * 2 + choffset + 1].Power = Power.field.Byte1;
+
+ if ((Power2.field.Byte0 < 16) && (Power2.field.Byte0 >= -7))
+ pAd->TxPower[i * 2 + choffset + 0].Power2 = Power2.field.Byte0;
+
+ if ((Power2.field.Byte1 < 16) && (Power2.field.Byte1 >= -7))
+ pAd->TxPower[i * 2 + choffset + 1].Power2 = Power2.field.Byte1;
+ }
+
+ // 3. U-NII upper band: 149, 151, 153; 157, 159, 161; 165 (including central frequency in BW 40MHz)
+ // 3.1 Fill up channel
+ choffset = 14 + 12 + 16;
+ for (i = 0; i < 2; i++)
+ {
+ pAd->TxPower[3 * i + choffset + 0].Channel = 149 + i * 8 + 0;
+ pAd->TxPower[3 * i + choffset + 0].Power = DEFAULT_RF_TX_POWER;
+ pAd->TxPower[3 * i + choffset + 0].Power2 = DEFAULT_RF_TX_POWER;
+
+ pAd->TxPower[3 * i + choffset + 1].Channel = 149 + i * 8 + 2;
+ pAd->TxPower[3 * i + choffset + 1].Power = DEFAULT_RF_TX_POWER;
+ pAd->TxPower[3 * i + choffset + 1].Power2 = DEFAULT_RF_TX_POWER;
+
+ pAd->TxPower[3 * i + choffset + 2].Channel = 149 + i * 8 + 4;
+ pAd->TxPower[3 * i + choffset + 2].Power = DEFAULT_RF_TX_POWER;
+ pAd->TxPower[3 * i + choffset + 2].Power2 = DEFAULT_RF_TX_POWER;
+ }
+ pAd->TxPower[3 * 2 + choffset + 0].Channel = 165;
+ pAd->TxPower[3 * 2 + choffset + 0].Power = DEFAULT_RF_TX_POWER;
+ pAd->TxPower[3 * 2 + choffset + 0].Power2 = DEFAULT_RF_TX_POWER;
+
+ // 3.2 Fill up power
+ for (i = 0; i < 4; i++)
+ {
+// Power.word = RTMP_EEPROM_READ16(pAd, EEPROM_A_TX_PWR_OFFSET + (choffset - 14) + i * 2);
+// Power2.word = RTMP_EEPROM_READ16(pAd, EEPROM_A_TX2_PWR_OFFSET + (choffset - 14) + i * 2);
+ RT28xx_EEPROM_READ16(pAd, EEPROM_A_TX_PWR_OFFSET + (choffset - 14) + i * 2, Power.word);
+ RT28xx_EEPROM_READ16(pAd, EEPROM_A_TX2_PWR_OFFSET + (choffset - 14) + i * 2, Power2.word);
+
+ if ((Power.field.Byte0 < 16) && (Power.field.Byte0 >= -7))
+ pAd->TxPower[i * 2 + choffset + 0].Power = Power.field.Byte0;
+
+ if ((Power.field.Byte1 < 16) && (Power.field.Byte1 >= -7))
+ pAd->TxPower[i * 2 + choffset + 1].Power = Power.field.Byte1;
+
+ if ((Power2.field.Byte0 < 16) && (Power2.field.Byte0 >= -7))
+ pAd->TxPower[i * 2 + choffset + 0].Power2 = Power2.field.Byte0;
+
+ if ((Power2.field.Byte1 < 16) && (Power2.field.Byte1 >= -7))
+ pAd->TxPower[i * 2 + choffset + 1].Power2 = Power2.field.Byte1;
+ }
+
+ // 4. Print and Debug
+ choffset = 14 + 12 + 16 + 7;
+
+}
+
+/*
+ ========================================================================
+
+ Routine Description:
+ Read the following from the registry
+ 1. All the parameters
+ 2. NetworkAddres
+
+ Arguments:
+ Adapter Pointer to our adapter
+ WrapperConfigurationContext For use by NdisOpenConfiguration
+
+ Return Value:
+ NDIS_STATUS_SUCCESS
+ NDIS_STATUS_FAILURE
+ NDIS_STATUS_RESOURCES
+
+ IRQL = PASSIVE_LEVEL
+
+ Note:
+
+ ========================================================================
+*/
+NDIS_STATUS NICReadRegParameters(
+ IN PRTMP_ADAPTER pAd,
+ IN NDIS_HANDLE WrapperConfigurationContext
+ )
+{
+ NDIS_STATUS Status = NDIS_STATUS_SUCCESS;
+ DBGPRINT_S(Status, ("<-- NICReadRegParameters, Status=%x\n", Status));
+ return Status;
+}
+
+
+#ifdef RT30xx
+/*
+ ========================================================================
+
+ Routine Description:
+ For RF filter calibration purpose
+
+ Arguments:
+ pAd Pointer to our adapter
+
+ Return Value:
+ None
+
+ IRQL = PASSIVE_LEVEL
+
+ ========================================================================
+*/
+VOID RTMPFilterCalibration(
+ IN PRTMP_ADAPTER pAd)
+{
+ UCHAR R55x = 0, value, FilterTarget = 0x1E, BBPValue=0;
+ UINT loop = 0, count = 0, loopcnt = 0, ReTry = 0;
+ UCHAR RF_R24_Value = 0;
+
+ // Give bbp filter initial value
+ pAd->Mlme.CaliBW20RfR24 = 0x1F;
+ pAd->Mlme.CaliBW40RfR24 = 0x2F; //Bit[5] must be 1 for BW 40
+
+ do
+ {
+ if (loop == 1) //BandWidth = 40 MHz
+ {
+ // Write 0x27 to RF_R24 to program filter
+ RF_R24_Value = 0x27;
+ RT30xxWriteRFRegister(pAd, RF_R24, RF_R24_Value);
+ if (IS_RT3090(pAd))
+ FilterTarget = 0x15;
+ else
+ FilterTarget = 0x19;
+
+ // when calibrate BW40, BBP mask must set to BW40.
+ RTMP_BBP_IO_READ8_BY_REG_ID(pAd, BBP_R4, &BBPValue);
+ BBPValue&= (~0x18);
+ BBPValue|= (0x10);
+ RTMP_BBP_IO_WRITE8_BY_REG_ID(pAd, BBP_R4, BBPValue);
+
+ // set to BW40
+ RT30xxReadRFRegister(pAd, RF_R31, &value);
+ value |= 0x20;
+ RT30xxWriteRFRegister(pAd, RF_R31, value);
+ }
+ else //BandWidth = 20 MHz
+ {
+ // Write 0x07 to RF_R24 to program filter
+ RF_R24_Value = 0x07;
+ RT30xxWriteRFRegister(pAd, RF_R24, RF_R24_Value);
+ if (IS_RT3090(pAd))
+ FilterTarget = 0x13;
+ else
+ FilterTarget = 0x16;
+
+ // set to BW20
+ RT30xxReadRFRegister(pAd, RF_R31, &value);
+ value &= (~0x20);
+ RT30xxWriteRFRegister(pAd, RF_R31, value);
+ }
+
+ // Write 0x01 to RF_R22 to enable baseband loopback mode
+ RT30xxReadRFRegister(pAd, RF_R22, &value);
+ value |= 0x01;
+ RT30xxWriteRFRegister(pAd, RF_R22, value);
+
+ // Write 0x00 to BBP_R24 to set power & frequency of passband test tone
+ RTMP_BBP_IO_WRITE8_BY_REG_ID(pAd, BBP_R24, 0);
+
+ do
+ {
+ // Write 0x90 to BBP_R25 to transmit test tone
+ RTMP_BBP_IO_WRITE8_BY_REG_ID(pAd, BBP_R25, 0x90);
+
+ RTMPusecDelay(1000);
+ // Read BBP_R55[6:0] for received power, set R55x = BBP_R55[6:0]
+ RTMP_BBP_IO_READ8_BY_REG_ID(pAd, BBP_R55, &value);
+ R55x = value & 0xFF;
+
+ } while ((ReTry++ < 100) && (R55x == 0));
+
+ // Write 0x06 to BBP_R24 to set power & frequency of stopband test tone
+ RTMP_BBP_IO_WRITE8_BY_REG_ID(pAd, BBP_R24, 0x06);
+
+ while(TRUE)
+ {
+ // Write 0x90 to BBP_R25 to transmit test tone
+ RTMP_BBP_IO_WRITE8_BY_REG_ID(pAd, BBP_R25, 0x90);
+
+ //We need to wait for calibration
+ RTMPusecDelay(1000);
+ RTMP_BBP_IO_READ8_BY_REG_ID(pAd, BBP_R55, &value);
+ value &= 0xFF;
+ if ((R55x - value) < FilterTarget)
+ {
+ RF_R24_Value ++;
+ }
+ else if ((R55x - value) == FilterTarget)
+ {
+ RF_R24_Value ++;
+ count ++;
+ }
+ else
+ {
+ break;
+ }
+
+ // prevent infinite loop cause driver hang.
+ if (loopcnt++ > 100)
+ {
+ DBGPRINT(RT_DEBUG_ERROR, ("RTMPFilterCalibration - can't find a valid value, loopcnt=%d stop calibrating", loopcnt));
+ break;
+ }
+
+ // Write RF_R24 to program filter
+ RT30xxWriteRFRegister(pAd, RF_R24, RF_R24_Value);
+ }
+
+ if (count > 0)
+ {
+ RF_R24_Value = RF_R24_Value - ((count) ? (1) : (0));
+ }
+
+ // Store for future usage
+ if (loopcnt < 100)
+ {
+ if (loop++ == 0)
+ {
+ //BandWidth = 20 MHz
+ pAd->Mlme.CaliBW20RfR24 = (UCHAR)RF_R24_Value;
+ }
+ else
+ {
+ //BandWidth = 40 MHz
+ pAd->Mlme.CaliBW40RfR24 = (UCHAR)RF_R24_Value;
+ break;
+ }
+ }
+ else
+ break;
+
+ RT30xxWriteRFRegister(pAd, RF_R24, RF_R24_Value);
+
+ // reset count
+ count = 0;
+ } while(TRUE);
+
+ //
+ // Set back to initial state
+ //
+ RTMP_BBP_IO_WRITE8_BY_REG_ID(pAd, BBP_R24, 0);
+
+ RT30xxReadRFRegister(pAd, RF_R22, &value);
+ value &= ~(0x01);
+ RT30xxWriteRFRegister(pAd, RF_R22, value);
+
+ // set BBP back to BW20
+ RTMP_BBP_IO_READ8_BY_REG_ID(pAd, BBP_R4, &BBPValue);
+ BBPValue&= (~0x18);
+ RTMP_BBP_IO_WRITE8_BY_REG_ID(pAd, BBP_R4, BBPValue);
+
+ DBGPRINT(RT_DEBUG_TRACE, ("RTMPFilterCalibration - CaliBW20RfR24=0x%x, CaliBW40RfR24=0x%x\n", pAd->Mlme.CaliBW20RfR24, pAd->Mlme.CaliBW40RfR24));
+}
+#endif // RT30xx //
+
+
+#ifdef RT3070
+VOID NICInitRT30xxRFRegisters(IN PRTMP_ADAPTER pAd)
+{
+ INT i;
+ // Driver must read EEPROM to get RfIcType before initial RF registers
+ // Initialize RF register to default value
+ if (IS_RT3070(pAd) || IS_RT3071(pAd))
+ {
+ // Init RF calibration
+ // Driver should toggle RF R30 bit7 before init RF registers
+ UINT32 RfReg = 0;
+ UINT32 data;
+
+ RT30xxReadRFRegister(pAd, RF_R30, (PUCHAR)&RfReg);
+ RfReg |= 0x80;
+ RT30xxWriteRFRegister(pAd, RF_R30, (UCHAR)RfReg);
+ RTMPusecDelay(1000);
+ RfReg &= 0x7F;
+ RT30xxWriteRFRegister(pAd, RF_R30, (UCHAR)RfReg);
+
+ // Initialize RF register to default value
+ for (i = 0; i < NUM_RF_REG_PARMS; i++)
+ {
+ RT30xxWriteRFRegister(pAd, RT30xx_RFRegTable[i].Register, RT30xx_RFRegTable[i].Value);
+ }
+
+ // add by johnli
+ if (IS_RT3070(pAd))
+ {
+ // Update MAC 0x05D4 from 01xxxxxx to 0Dxxxxxx (voltage 1.2V to 1.35V) for RT3070 to improve yield rate
+ RTUSBReadMACRegister(pAd, LDO_CFG0, &data);
+ data = ((data & 0xF0FFFFFF) | 0x0D000000);
+ RTUSBWriteMACRegister(pAd, LDO_CFG0, data);
+ }
+ else if (IS_RT3071(pAd))
+ {
+ // Driver should set RF R6 bit6 on before init RF registers
+ RT30xxReadRFRegister(pAd, RF_R06, (PUCHAR)&RfReg);
+ RfReg |= 0x40;
+ RT30xxWriteRFRegister(pAd, RF_R06, (UCHAR)RfReg);
+
+ // init R31
+ RT30xxWriteRFRegister(pAd, RF_R31, 0x14);
+
+ // RT3071 version E has fixed this issue
+ if ((pAd->NicConfig2.field.DACTestBit == 1) && ((pAd->MACVersion & 0xffff) < 0x0211))
+ {
+ // patch tx EVM issue temporarily
+ RTUSBReadMACRegister(pAd, LDO_CFG0, &data);
+ data = ((data & 0xE0FFFFFF) | 0x0D000000);
+ RTUSBWriteMACRegister(pAd, LDO_CFG0, data);
+ }
+ else
+ {
+ RTMP_IO_READ32(pAd, LDO_CFG0, &data);
+ data = ((data & 0xE0FFFFFF) | 0x01000000);
+ RTMP_IO_WRITE32(pAd, LDO_CFG0, data);
+ }
+
+ // patch LNA_PE_G1 failed issue
+ RTUSBReadMACRegister(pAd, GPIO_SWITCH, &data);
+ data &= ~(0x20);
+ RTUSBWriteMACRegister(pAd, GPIO_SWITCH, data);
+ }
+
+ //For RF filter Calibration
+ RTMPFilterCalibration(pAd);
+
+ // Initialize RF R27 register, set RF R27 must be behind RTMPFilterCalibration()
+ if ((pAd->MACVersion & 0xffff) < 0x0211)
+ RT30xxWriteRFRegister(pAd, RF_R27, 0x3);
+
+ // set led open drain enable
+ RTUSBReadMACRegister(pAd, OPT_14, &data);
+ data |= 0x01;
+ RTUSBWriteMACRegister(pAd, OPT_14, data);
+
+ if (IS_RT3071(pAd))
+ {
+ // add by johnli, RF power sequence setup, load RF normal operation-mode setup
+ RT30xxLoadRFNormalModeSetup(pAd);
+ }
+ }
+
+}
+#endif // RT3070 //
+
+
+/*
+ ========================================================================
+
+ Routine Description:
+ Read initial parameters from EEPROM
+
+ Arguments:
+ Adapter Pointer to our adapter
+
+ Return Value:
+ None
+
+ IRQL = PASSIVE_LEVEL
+
+ Note:
+
+ ========================================================================
+*/
+VOID NICReadEEPROMParameters(
+ IN PRTMP_ADAPTER pAd,
+ IN PUCHAR mac_addr)
+{
+ UINT32 data = 0;
+ USHORT i, value, value2;
+ UCHAR TmpPhy;
+ EEPROM_TX_PWR_STRUC Power;
+ EEPROM_VERSION_STRUC Version;
+ EEPROM_ANTENNA_STRUC Antenna;
+ EEPROM_NIC_CONFIG2_STRUC NicConfig2;
+
+ DBGPRINT(RT_DEBUG_TRACE, ("--> NICReadEEPROMParameters\n"));
+
+ // Init EEPROM Address Number, before access EEPROM; if 93c46, EEPROMAddressNum=6, else if 93c66, EEPROMAddressNum=8
+ RTMP_IO_READ32(pAd, E2PROM_CSR, &data);
+ DBGPRINT(RT_DEBUG_TRACE, ("--> E2PROM_CSR = 0x%x\n", data));
+
+ if((data & 0x30) == 0)
+ pAd->EEPROMAddressNum = 6; // 93C46
+ else if((data & 0x30) == 0x10)
+ pAd->EEPROMAddressNum = 8; // 93C66
+ else
+ pAd->EEPROMAddressNum = 8; // 93C86
+ DBGPRINT(RT_DEBUG_TRACE, ("--> EEPROMAddressNum = %d\n", pAd->EEPROMAddressNum ));
+
+ // RT2860 MAC no longer auto load MAC address from E2PROM. Driver has to intialize
+ // MAC address registers according to E2PROM setting
+ if (mac_addr == NULL ||
+ strlen(mac_addr) != 17 ||
+ mac_addr[2] != ':' || mac_addr[5] != ':' || mac_addr[8] != ':' ||
+ mac_addr[11] != ':' || mac_addr[14] != ':')
+ {
+ USHORT Addr01,Addr23,Addr45 ;
+
+ RT28xx_EEPROM_READ16(pAd, 0x04, Addr01);
+ RT28xx_EEPROM_READ16(pAd, 0x06, Addr23);
+ RT28xx_EEPROM_READ16(pAd, 0x08, Addr45);
+
+ pAd->PermanentAddress[0] = (UCHAR)(Addr01 & 0xff);
+ pAd->PermanentAddress[1] = (UCHAR)(Addr01 >> 8);
+ pAd->PermanentAddress[2] = (UCHAR)(Addr23 & 0xff);
+ pAd->PermanentAddress[3] = (UCHAR)(Addr23 >> 8);
+ pAd->PermanentAddress[4] = (UCHAR)(Addr45 & 0xff);
+ pAd->PermanentAddress[5] = (UCHAR)(Addr45 >> 8);
+
+ DBGPRINT(RT_DEBUG_TRACE, ("Initialize MAC Address from E2PROM \n"));
+ }
+ else
+ {
+ INT j;
+ PUCHAR macptr;
+
+ macptr = mac_addr;
+
+ for (j=0; j<MAC_ADDR_LEN; j++)
+ {
+ AtoH(macptr, &pAd->PermanentAddress[j], 1);
+ macptr=macptr+3;
+ }
+
+ DBGPRINT(RT_DEBUG_TRACE, ("Initialize MAC Address from module parameter \n"));
+ }
+
+
+ {
+ //more conveninet to test mbssid, so ap's bssid &0xf1
+ if (pAd->PermanentAddress[0] == 0xff)
+ pAd->PermanentAddress[0] = RandomByte(pAd)&0xf8;
+
+ //if (pAd->PermanentAddress[5] == 0xff)
+ // pAd->PermanentAddress[5] = RandomByte(pAd)&0xf8;
+
+ DBGPRINT_RAW(RT_DEBUG_TRACE,("E2PROM MAC: =%02x:%02x:%02x:%02x:%02x:%02x\n",
+ pAd->PermanentAddress[0], pAd->PermanentAddress[1],
+ pAd->PermanentAddress[2], pAd->PermanentAddress[3],
+ pAd->PermanentAddress[4], pAd->PermanentAddress[5]));
+ if (pAd->bLocalAdminMAC == FALSE)
+ {
+ MAC_DW0_STRUC csr2;
+ MAC_DW1_STRUC csr3;
+ COPY_MAC_ADDR(pAd->CurrentAddress, pAd->PermanentAddress);
+ csr2.field.Byte0 = pAd->CurrentAddress[0];
+ csr2.field.Byte1 = pAd->CurrentAddress[1];
+ csr2.field.Byte2 = pAd->CurrentAddress[2];
+ csr2.field.Byte3 = pAd->CurrentAddress[3];
+ RTMP_IO_WRITE32(pAd, MAC_ADDR_DW0, csr2.word);
+ csr3.word = 0;
+ csr3.field.Byte4 = pAd->CurrentAddress[4];
+ csr3.field.Byte5 = pAd->CurrentAddress[5];
+ csr3.field.U2MeMask = 0xff;
+ RTMP_IO_WRITE32(pAd, MAC_ADDR_DW1, csr3.word);
+ DBGPRINT_RAW(RT_DEBUG_TRACE,("E2PROM MAC: =%02x:%02x:%02x:%02x:%02x:%02x\n",
+ pAd->PermanentAddress[0], pAd->PermanentAddress[1],
+ pAd->PermanentAddress[2], pAd->PermanentAddress[3],
+ pAd->PermanentAddress[4], pAd->PermanentAddress[5]));
+ }
+ }
+
+ // if not return early. cause fail at emulation.
+ // Init the channel number for TX channel power
+ RTMPReadChannelPwr(pAd);
+
+ // if E2PROM version mismatch with driver's expectation, then skip
+ // all subsequent E2RPOM retieval and set a system error bit to notify GUI
+ RT28xx_EEPROM_READ16(pAd, EEPROM_VERSION_OFFSET, Version.word);
+ pAd->EepromVersion = Version.field.Version + Version.field.FaeReleaseNumber * 256;
+ DBGPRINT(RT_DEBUG_TRACE, ("E2PROM: Version = %d, FAE release #%d\n", Version.field.Version, Version.field.FaeReleaseNumber));
+
+ if (Version.field.Version > VALID_EEPROM_VERSION)
+ {
+ DBGPRINT_ERR(("E2PROM: WRONG VERSION 0x%x, should be %d\n",Version.field.Version, VALID_EEPROM_VERSION));
+ /*pAd->SystemErrorBitmap |= 0x00000001;
+
+ // hard-code default value when no proper E2PROM installed
+ pAd->bAutoTxAgcA = FALSE;
+ pAd->bAutoTxAgcG = FALSE;
+
+ // Default the channel power
+ for (i = 0; i < MAX_NUM_OF_CHANNELS; i++)
+ pAd->TxPower[i].Power = DEFAULT_RF_TX_POWER;
+
+ // Default the channel power
+ for (i = 0; i < MAX_NUM_OF_11JCHANNELS; i++)
+ pAd->TxPower11J[i].Power = DEFAULT_RF_TX_POWER;
+
+ for(i = 0; i < NUM_EEPROM_BBP_PARMS; i++)
+ pAd->EEPROMDefaultValue[i] = 0xffff;
+ return; */
+ }
+
+ // Read BBP default value from EEPROM and store to array(EEPROMDefaultValue) in pAd
+ RT28xx_EEPROM_READ16(pAd, EEPROM_NIC1_OFFSET, value);
+ pAd->EEPROMDefaultValue[0] = value;
+
+ RT28xx_EEPROM_READ16(pAd, EEPROM_NIC2_OFFSET, value);
+ pAd->EEPROMDefaultValue[1] = value;
+
+ RT28xx_EEPROM_READ16(pAd, 0x38, value); // Country Region
+ pAd->EEPROMDefaultValue[2] = value;
+
+ for(i = 0; i < 8; i++)
+ {
+ RT28xx_EEPROM_READ16(pAd, EEPROM_BBP_BASE_OFFSET + i*2, value);
+ pAd->EEPROMDefaultValue[i+3] = value;
+ }
+
+ // We have to parse NIC configuration 0 at here.
+ // If TSSI did not have preloaded value, it should reset the TxAutoAgc to false
+ // Therefore, we have to read TxAutoAgc control beforehand.
+ // Read Tx AGC control bit
+ Antenna.word = pAd->EEPROMDefaultValue[0];
+ if (Antenna.word == 0xFFFF)
+ {
+#ifdef RT30xx
+ if(IS_RT3090(pAd))
+ {
+ Antenna.word = 0;
+ Antenna.field.RfIcType = RFIC_3020;
+ Antenna.field.TxPath = 1;
+ Antenna.field.RxPath = 1;
+ }
+ else
+ {
+#endif // RT30xx //
+ Antenna.word = 0;
+ Antenna.field.RfIcType = RFIC_2820;
+ Antenna.field.TxPath = 1;
+ Antenna.field.RxPath = 2;
+ DBGPRINT(RT_DEBUG_WARN, ("E2PROM error, hard code as 0x%04x\n", Antenna.word));
+#ifdef RT30xx
+ }
+#endif // RT30xx //
+ }
+
+ // Choose the desired Tx&Rx stream.
+ if ((pAd->CommonCfg.TxStream == 0) || (pAd->CommonCfg.TxStream > Antenna.field.TxPath))
+ pAd->CommonCfg.TxStream = Antenna.field.TxPath;
+
+ if ((pAd->CommonCfg.RxStream == 0) || (pAd->CommonCfg.RxStream > Antenna.field.RxPath))
+ {
+ pAd->CommonCfg.RxStream = Antenna.field.RxPath;
+
+ if ((pAd->MACVersion < RALINK_2883_VERSION) &&
+ (pAd->CommonCfg.RxStream > 2))
+ {
+ // only 2 Rx streams for RT2860 series
+ pAd->CommonCfg.RxStream = 2;
+ }
+ }
+
+ // 3*3
+ // read value from EEPROM and set them to CSR174 ~ 177 in chain0 ~ chain2
+ // yet implement
+ for(i=0; i<3; i++)
+ {
+ }
+
+ NicConfig2.word = pAd->EEPROMDefaultValue[1];
+
+
+
+#ifdef CONFIG_STA_SUPPORT
+ IF_DEV_CONFIG_OPMODE_ON_STA(pAd)
+ {
+ if ((NicConfig2.word & 0x00ff) == 0xff)
+ {
+ NicConfig2.word &= 0xff00;
+ }
+
+ if ((NicConfig2.word >> 8) == 0xff)
+ {
+ NicConfig2.word &= 0x00ff;
+ }
+ }
+#endif // CONFIG_STA_SUPPORT //
+
+ if (NicConfig2.field.DynamicTxAgcControl == 1)
+ pAd->bAutoTxAgcA = pAd->bAutoTxAgcG = TRUE;
+ else
+ pAd->bAutoTxAgcA = pAd->bAutoTxAgcG = FALSE;
+
+ DBGPRINT_RAW(RT_DEBUG_TRACE, ("NICReadEEPROMParameters: RxPath = %d, TxPath = %d\n", Antenna.field.RxPath, Antenna.field.TxPath));
+
+ // Save the antenna for future use
+ pAd->Antenna.word = Antenna.word;
+
+ //
+ // Reset PhyMode if we don't support 802.11a
+ // Only RFIC_2850 & RFIC_2750 support 802.11a
+ //
+ if ((Antenna.field.RfIcType != RFIC_2850) && (Antenna.field.RfIcType != RFIC_2750))
+ {
+ if ((pAd->CommonCfg.PhyMode == PHY_11ABG_MIXED) ||
+ (pAd->CommonCfg.PhyMode == PHY_11A))
+ pAd->CommonCfg.PhyMode = PHY_11BG_MIXED;
+#ifdef DOT11_N_SUPPORT
+ else if ((pAd->CommonCfg.PhyMode == PHY_11ABGN_MIXED) ||
+ (pAd->CommonCfg.PhyMode == PHY_11AN_MIXED) ||
+ (pAd->CommonCfg.PhyMode == PHY_11AGN_MIXED) ||
+ (pAd->CommonCfg.PhyMode == PHY_11N_5G))
+ pAd->CommonCfg.PhyMode = PHY_11BGN_MIXED;
+#endif // DOT11_N_SUPPORT //
+ }
+
+ // Read TSSI reference and TSSI boundary for temperature compensation. This is ugly
+ // 0. 11b/g
+ {
+ /* these are tempature reference value (0x00 ~ 0xFE)
+ ex: 0x00 0x15 0x25 0x45 0x88 0xA0 0xB5 0xD0 0xF0
+ TssiPlusBoundaryG [4] [3] [2] [1] [0] (smaller) +
+ TssiMinusBoundaryG[0] [1] [2] [3] [4] (larger) */
+ RT28xx_EEPROM_READ16(pAd, 0x6E, Power.word);
+ pAd->TssiMinusBoundaryG[4] = Power.field.Byte0;
+ pAd->TssiMinusBoundaryG[3] = Power.field.Byte1;
+ RT28xx_EEPROM_READ16(pAd, 0x70, Power.word);
+ pAd->TssiMinusBoundaryG[2] = Power.field.Byte0;
+ pAd->TssiMinusBoundaryG[1] = Power.field.Byte1;
+ RT28xx_EEPROM_READ16(pAd, 0x72, Power.word);
+ pAd->TssiRefG = Power.field.Byte0; /* reference value [0] */
+ pAd->TssiPlusBoundaryG[1] = Power.field.Byte1;
+ RT28xx_EEPROM_READ16(pAd, 0x74, Power.word);
+ pAd->TssiPlusBoundaryG[2] = Power.field.Byte0;
+ pAd->TssiPlusBoundaryG[3] = Power.field.Byte1;
+ RT28xx_EEPROM_READ16(pAd, 0x76, Power.word);
+ pAd->TssiPlusBoundaryG[4] = Power.field.Byte0;
+ pAd->TxAgcStepG = Power.field.Byte1;
+ pAd->TxAgcCompensateG = 0;
+ pAd->TssiMinusBoundaryG[0] = pAd->TssiRefG;
+ pAd->TssiPlusBoundaryG[0] = pAd->TssiRefG;
+
+ // Disable TxAgc if the based value is not right
+ if (pAd->TssiRefG == 0xff)
+ pAd->bAutoTxAgcG = FALSE;
+
+ DBGPRINT(RT_DEBUG_TRACE,("E2PROM: G Tssi[-4 .. +4] = %d %d %d %d - %d -%d %d %d %d, step=%d, tuning=%d\n",
+ pAd->TssiMinusBoundaryG[4], pAd->TssiMinusBoundaryG[3], pAd->TssiMinusBoundaryG[2], pAd->TssiMinusBoundaryG[1],
+ pAd->TssiRefG,
+ pAd->TssiPlusBoundaryG[1], pAd->TssiPlusBoundaryG[2], pAd->TssiPlusBoundaryG[3], pAd->TssiPlusBoundaryG[4],
+ pAd->TxAgcStepG, pAd->bAutoTxAgcG));
+ }
+ // 1. 11a
+ {
+ RT28xx_EEPROM_READ16(pAd, 0xD4, Power.word);
+ pAd->TssiMinusBoundaryA[4] = Power.field.Byte0;
+ pAd->TssiMinusBoundaryA[3] = Power.field.Byte1;
+ RT28xx_EEPROM_READ16(pAd, 0xD6, Power.word);
+ pAd->TssiMinusBoundaryA[2] = Power.field.Byte0;
+ pAd->TssiMinusBoundaryA[1] = Power.field.Byte1;
+ RT28xx_EEPROM_READ16(pAd, 0xD8, Power.word);
+ pAd->TssiRefA = Power.field.Byte0;
+ pAd->TssiPlusBoundaryA[1] = Power.field.Byte1;
+ RT28xx_EEPROM_READ16(pAd, 0xDA, Power.word);
+ pAd->TssiPlusBoundaryA[2] = Power.field.Byte0;
+ pAd->TssiPlusBoundaryA[3] = Power.field.Byte1;
+ RT28xx_EEPROM_READ16(pAd, 0xDC, Power.word);
+ pAd->TssiPlusBoundaryA[4] = Power.field.Byte0;
+ pAd->TxAgcStepA = Power.field.Byte1;
+ pAd->TxAgcCompensateA = 0;
+ pAd->TssiMinusBoundaryA[0] = pAd->TssiRefA;
+ pAd->TssiPlusBoundaryA[0] = pAd->TssiRefA;
+
+ // Disable TxAgc if the based value is not right
+ if (pAd->TssiRefA == 0xff)
+ pAd->bAutoTxAgcA = FALSE;
+
+ DBGPRINT(RT_DEBUG_TRACE,("E2PROM: A Tssi[-4 .. +4] = %d %d %d %d - %d -%d %d %d %d, step=%d, tuning=%d\n",
+ pAd->TssiMinusBoundaryA[4], pAd->TssiMinusBoundaryA[3], pAd->TssiMinusBoundaryA[2], pAd->TssiMinusBoundaryA[1],
+ pAd->TssiRefA,
+ pAd->TssiPlusBoundaryA[1], pAd->TssiPlusBoundaryA[2], pAd->TssiPlusBoundaryA[3], pAd->TssiPlusBoundaryA[4],
+ pAd->TxAgcStepA, pAd->bAutoTxAgcA));
+ }
+ pAd->BbpRssiToDbmDelta = 0x0;
+
+ // Read frequency offset setting for RF
+ RT28xx_EEPROM_READ16(pAd, EEPROM_FREQ_OFFSET, value);
+ if ((value & 0x00FF) != 0x00FF)
+ pAd->RfFreqOffset = (ULONG) (value & 0x00FF);
+ else
+ pAd->RfFreqOffset = 0;
+ DBGPRINT(RT_DEBUG_TRACE, ("E2PROM: RF FreqOffset=0x%lx \n", pAd->RfFreqOffset));
+
+ //CountryRegion byte offset (38h)
+ value = pAd->EEPROMDefaultValue[2] >> 8; // 2.4G band
+ value2 = pAd->EEPROMDefaultValue[2] & 0x00FF; // 5G band
+
+ if ((value <= REGION_MAXIMUM_BG_BAND) && (value2 <= REGION_MAXIMUM_A_BAND))
+ {
+ pAd->CommonCfg.CountryRegion = ((UCHAR) value) | 0x80;
+ pAd->CommonCfg.CountryRegionForABand = ((UCHAR) value2) | 0x80;
+ TmpPhy = pAd->CommonCfg.PhyMode;
+ pAd->CommonCfg.PhyMode = 0xff;
+ RTMPSetPhyMode(pAd, TmpPhy);
+#ifdef DOT11_N_SUPPORT
+ SetCommonHT(pAd);
+#endif // DOT11_N_SUPPORT //
+ }
+
+ //
+ // Get RSSI Offset on EEPROM 0x9Ah & 0x9Ch.
+ // The valid value are (-10 ~ 10)
+ //
+ RT28xx_EEPROM_READ16(pAd, EEPROM_RSSI_BG_OFFSET, value);
+ pAd->BGRssiOffset0 = value & 0x00ff;
+ pAd->BGRssiOffset1 = (value >> 8);
+ RT28xx_EEPROM_READ16(pAd, EEPROM_RSSI_BG_OFFSET+2, value);
+ pAd->BGRssiOffset2 = value & 0x00ff;
+ pAd->ALNAGain1 = (value >> 8);
+ RT28xx_EEPROM_READ16(pAd, EEPROM_LNA_OFFSET, value);
+ pAd->BLNAGain = value & 0x00ff;
+ pAd->ALNAGain0 = (value >> 8);
+
+ // Validate 11b/g RSSI_0 offset.
+ if ((pAd->BGRssiOffset0 < -10) || (pAd->BGRssiOffset0 > 10))
+ pAd->BGRssiOffset0 = 0;
+
+ // Validate 11b/g RSSI_1 offset.
+ if ((pAd->BGRssiOffset1 < -10) || (pAd->BGRssiOffset1 > 10))
+ pAd->BGRssiOffset1 = 0;
+
+ // Validate 11b/g RSSI_2 offset.
+ if ((pAd->BGRssiOffset2 < -10) || (pAd->BGRssiOffset2 > 10))
+ pAd->BGRssiOffset2 = 0;
+
+ RT28xx_EEPROM_READ16(pAd, EEPROM_RSSI_A_OFFSET, value);
+ pAd->ARssiOffset0 = value & 0x00ff;
+ pAd->ARssiOffset1 = (value >> 8);
+ RT28xx_EEPROM_READ16(pAd, (EEPROM_RSSI_A_OFFSET+2), value);
+ pAd->ARssiOffset2 = value & 0x00ff;
+ pAd->ALNAGain2 = (value >> 8);
+
+ if (((UCHAR)pAd->ALNAGain1 == 0xFF) || (pAd->ALNAGain1 == 0x00))
+ pAd->ALNAGain1 = pAd->ALNAGain0;
+ if (((UCHAR)pAd->ALNAGain2 == 0xFF) || (pAd->ALNAGain2 == 0x00))
+ pAd->ALNAGain2 = pAd->ALNAGain0;
+
+ // Validate 11a RSSI_0 offset.
+ if ((pAd->ARssiOffset0 < -10) || (pAd->ARssiOffset0 > 10))
+ pAd->ARssiOffset0 = 0;
+
+ // Validate 11a RSSI_1 offset.
+ if ((pAd->ARssiOffset1 < -10) || (pAd->ARssiOffset1 > 10))
+ pAd->ARssiOffset1 = 0;
+
+ //Validate 11a RSSI_2 offset.
+ if ((pAd->ARssiOffset2 < -10) || (pAd->ARssiOffset2 > 10))
+ pAd->ARssiOffset2 = 0;
+
+ //
+ // Get LED Setting.
+ //
+ RT28xx_EEPROM_READ16(pAd, 0x3a, value);
+ pAd->LedCntl.word = (value&0xff00) >> 8;
+ RT28xx_EEPROM_READ16(pAd, EEPROM_LED1_OFFSET, value);
+ pAd->Led1 = value;
+ RT28xx_EEPROM_READ16(pAd, EEPROM_LED2_OFFSET, value);
+ pAd->Led2 = value;
+ RT28xx_EEPROM_READ16(pAd, EEPROM_LED3_OFFSET, value);
+ pAd->Led3 = value;
+
+ RTMPReadTxPwrPerRate(pAd);
+
+#ifdef SINGLE_SKU
+ //pAd->CommonCfg.DefineMaxTxPwr = RTMP_EEPROM_READ16(pAd, EEPROM_DEFINE_MAX_TXPWR);
+ RT28xx_EEPROM_READ16(pAd, EEPROM_DEFINE_MAX_TXPWR, pAd->CommonCfg.DefineMaxTxPwr);
+#endif // SINGLE_SKU //
+#ifdef RT30xx
+ if (IS_RT30xx(pAd))
+ {
+ eFusePhysicalReadRegisters(pAd, EFUSE_TAG, 2, &value);
+ pAd->EFuseTag = (value & 0xff);
+ }
+#endif // RT30xx //
+
+ DBGPRINT(RT_DEBUG_TRACE, ("<-- NICReadEEPROMParameters\n"));
+}
+
+/*
+ ========================================================================
+
+ Routine Description:
+ Set default value from EEPROM
+
+ Arguments:
+ Adapter Pointer to our adapter
+
+ Return Value:
+ None
+
+ IRQL = PASSIVE_LEVEL
+
+ Note:
+
+ ========================================================================
+*/
+VOID NICInitAsicFromEEPROM(
+ IN PRTMP_ADAPTER pAd)
+{
+#ifdef CONFIG_STA_SUPPORT
+ UINT32 data = 0;
+ UCHAR BBPR1 = 0;
+#endif // CONFIG_STA_SUPPORT //
+ USHORT i;
+ EEPROM_ANTENNA_STRUC Antenna;
+ EEPROM_NIC_CONFIG2_STRUC NicConfig2;
+ UCHAR BBPR3 = 0;
+
+ DBGPRINT(RT_DEBUG_TRACE, ("--> NICInitAsicFromEEPROM\n"));
+ for(i = 3; i < NUM_EEPROM_BBP_PARMS; i++)
+ {
+ UCHAR BbpRegIdx, BbpValue;
+
+ if ((pAd->EEPROMDefaultValue[i] != 0xFFFF) && (pAd->EEPROMDefaultValue[i] != 0))
+ {
+ BbpRegIdx = (UCHAR)(pAd->EEPROMDefaultValue[i] >> 8);
+ BbpValue = (UCHAR)(pAd->EEPROMDefaultValue[i] & 0xff);
+ RTMP_BBP_IO_WRITE8_BY_REG_ID(pAd, BbpRegIdx, BbpValue);
+ }
+ }
+
+ Antenna.word = pAd->EEPROMDefaultValue[0];
+ if (Antenna.word == 0xFFFF)
+ {
+ DBGPRINT(RT_DEBUG_ERROR, ("E2PROM error, hard code as 0x%04x\n", Antenna.word));
+ BUG_ON(Antenna.word == 0xFFFF);
+ }
+ pAd->Mlme.RealRxPath = (UCHAR) Antenna.field.RxPath;
+ pAd->RfIcType = (UCHAR) Antenna.field.RfIcType;
+
+ DBGPRINT(RT_DEBUG_WARN, ("pAd->RfIcType = %d, RealRxPath=%d, TxPath = %d\n", pAd->RfIcType, pAd->Mlme.RealRxPath,Antenna.field.TxPath));
+
+ // Save the antenna for future use
+ pAd->Antenna.word = Antenna.word;
+
+ NicConfig2.word = pAd->EEPROMDefaultValue[1];
+
+
+#ifdef CONFIG_STA_SUPPORT
+ IF_DEV_CONFIG_OPMODE_ON_STA(pAd)
+ {
+ if ((NicConfig2.word & 0x00ff) == 0xff)
+ {
+ NicConfig2.word &= 0xff00;
+ }
+
+ if ((NicConfig2.word >> 8) == 0xff)
+ {
+ NicConfig2.word &= 0x00ff;
+ }
+ }
+#endif // CONFIG_STA_SUPPORT //
+
+ // Save the antenna for future use
+ pAd->NicConfig2.word = NicConfig2.word;
+
+ // set default antenna as main
+ if (pAd->RfIcType == RFIC_3020)
+ AsicSetRxAnt(pAd, pAd->RxAnt.Pair1PrimaryRxAnt);
+
+ //
+ // Send LED Setting to MCU.
+ //
+ if (pAd->LedCntl.word == 0xFF)
+ {
+ pAd->LedCntl.word = 0x01;
+ pAd->Led1 = 0x5555;
+ pAd->Led2 = 0x2221;
+
+#ifdef RT2870
+ pAd->Led3 = 0x5627;
+#endif // RT2870 //
+ }
+
+ AsicSendCommandToMcu(pAd, 0x52, 0xff, (UCHAR)pAd->Led1, (UCHAR)(pAd->Led1 >> 8));
+ AsicSendCommandToMcu(pAd, 0x53, 0xff, (UCHAR)pAd->Led2, (UCHAR)(pAd->Led2 >> 8));
+ AsicSendCommandToMcu(pAd, 0x54, 0xff, (UCHAR)pAd->Led3, (UCHAR)(pAd->Led3 >> 8));
+ pAd->LedIndicatorStregth = 0xFF;
+ RTMPSetSignalLED(pAd, -100); // Force signal strength Led to be turned off, before link up
+
+#ifdef CONFIG_STA_SUPPORT
+ IF_DEV_CONFIG_OPMODE_ON_STA(pAd)
+ {
+ // Read Hardware controlled Radio state enable bit
+ if (NicConfig2.field.HardwareRadioControl == 1)
+ {
+ pAd->StaCfg.bHardwareRadio = TRUE;
+
+ // Read GPIO pin2 as Hardware controlled radio state
+ RTMP_IO_READ32(pAd, GPIO_CTRL_CFG, &data);
+ if ((data & 0x04) == 0)
+ {
+ pAd->StaCfg.bHwRadio = FALSE;
+ pAd->StaCfg.bRadio = FALSE;
+// RTMP_IO_WRITE32(pAd, PWR_PIN_CFG, 0x00001818);
+ RTMP_SET_FLAG(pAd, fRTMP_ADAPTER_RADIO_OFF);
+ }
+ }
+ else
+ pAd->StaCfg.bHardwareRadio = FALSE;
+
+ if (pAd->StaCfg.bRadio == FALSE)
+ {
+ RTMPSetLED(pAd, LED_RADIO_OFF);
+ }
+ else
+ {
+ RTMPSetLED(pAd, LED_RADIO_ON);
+ }
+ }
+#endif // CONFIG_STA_SUPPORT //
+
+ // Turn off patching for cardbus controller
+ if (NicConfig2.field.CardbusAcceleration == 1)
+ {
+// pAd->bTest1 = TRUE;
+ }
+
+ if (NicConfig2.field.DynamicTxAgcControl == 1)
+ pAd->bAutoTxAgcA = pAd->bAutoTxAgcG = TRUE;
+ else
+ pAd->bAutoTxAgcA = pAd->bAutoTxAgcG = FALSE;
+ //
+ // Since BBP has been progamed, to make sure BBP setting will be
+ // upate inside of AsicAntennaSelect, so reset to UNKNOWN_BAND!!
+ //
+ pAd->CommonCfg.BandState = UNKNOWN_BAND;
+
+ RTMP_BBP_IO_READ8_BY_REG_ID(pAd, BBP_R3, &BBPR3);
+ BBPR3 &= (~0x18);
+ if(pAd->Antenna.field.RxPath == 3)
+ {
+ BBPR3 |= (0x10);
+ }
+ else if(pAd->Antenna.field.RxPath == 2)
+ {
+ BBPR3 |= (0x8);
+ }
+ else if(pAd->Antenna.field.RxPath == 1)
+ {
+ BBPR3 |= (0x0);
+ }
+ RTMP_BBP_IO_WRITE8_BY_REG_ID(pAd, BBP_R3, BBPR3);
+
+#ifdef CONFIG_STA_SUPPORT
+ IF_DEV_CONFIG_OPMODE_ON_STA(pAd)
+ {
+ // Handle the difference when 1T
+ RTMP_BBP_IO_READ8_BY_REG_ID(pAd, BBP_R1, &BBPR1);
+ if(pAd->Antenna.field.TxPath == 1)
+ {
+ BBPR1 &= (~0x18);
+ }
+ RTMP_BBP_IO_WRITE8_BY_REG_ID(pAd, BBP_R1, BBPR1);
+
+ DBGPRINT(RT_DEBUG_TRACE, ("Use Hw Radio Control Pin=%d; if used Pin=%d;\n", pAd->CommonCfg.bHardwareRadio, pAd->CommonCfg.bHardwareRadio));
+ }
+#endif // CONFIG_STA_SUPPORT //
+ DBGPRINT(RT_DEBUG_TRACE, ("TxPath = %d, RxPath = %d, RFIC=%d, Polar+LED mode=%x\n", pAd->Antenna.field.TxPath, pAd->Antenna.field.RxPath, pAd->RfIcType, pAd->LedCntl.word));
+ DBGPRINT(RT_DEBUG_TRACE, ("<-- NICInitAsicFromEEPROM\n"));
+}
+
+/*
+ ========================================================================
+
+ Routine Description:
+ Initialize NIC hardware
+
+ Arguments:
+ Adapter Pointer to our adapter
+
+ Return Value:
+ None
+
+ IRQL = PASSIVE_LEVEL
+
+ Note:
+
+ ========================================================================
+*/
+NDIS_STATUS NICInitializeAdapter(
+ IN PRTMP_ADAPTER pAd,
+ IN BOOLEAN bHardReset)
+{
+ NDIS_STATUS Status = NDIS_STATUS_SUCCESS;
+ WPDMA_GLO_CFG_STRUC GloCfg;
+// INT_MASK_CSR_STRUC IntMask;
+ ULONG i =0, j=0;
+ AC_TXOP_CSR0_STRUC csr0;
+
+ DBGPRINT(RT_DEBUG_TRACE, ("--> NICInitializeAdapter\n"));
+
+ // 3. Set DMA global configuration except TX_DMA_EN and RX_DMA_EN bits:
+retry:
+ i = 0;
+ do
+ {
+ RTMP_IO_READ32(pAd, WPDMA_GLO_CFG, &GloCfg.word);
+ if ((GloCfg.field.TxDMABusy == 0) && (GloCfg.field.RxDMABusy == 0))
+ break;
+
+ RTMPusecDelay(1000);
+ i++;
+ }while ( i<100);
+ DBGPRINT(RT_DEBUG_TRACE, ("<== DMA offset 0x208 = 0x%x\n", GloCfg.word));
+ GloCfg.word &= 0xff0;
+ GloCfg.field.EnTXWriteBackDDONE =1;
+ RTMP_IO_WRITE32(pAd, WPDMA_GLO_CFG, GloCfg.word);
+
+ // Record HW Beacon offset
+ pAd->BeaconOffset[0] = HW_BEACON_BASE0;
+ pAd->BeaconOffset[1] = HW_BEACON_BASE1;
+ pAd->BeaconOffset[2] = HW_BEACON_BASE2;
+ pAd->BeaconOffset[3] = HW_BEACON_BASE3;
+ pAd->BeaconOffset[4] = HW_BEACON_BASE4;
+ pAd->BeaconOffset[5] = HW_BEACON_BASE5;
+ pAd->BeaconOffset[6] = HW_BEACON_BASE6;
+ pAd->BeaconOffset[7] = HW_BEACON_BASE7;
+
+ //
+ // write all shared Ring's base address into ASIC
+ //
+
+ // asic simulation sequence put this ahead before loading firmware.
+ // pbf hardware reset
+
+ // Initialze ASIC for TX & Rx operation
+ if (NICInitializeAsic(pAd , bHardReset) != NDIS_STATUS_SUCCESS)
+ {
+ if (j++ == 0)
+ {
+ NICLoadFirmware(pAd);
+ goto retry;
+ }
+ return NDIS_STATUS_FAILURE;
+ }
+
+
+
+
+ // WMM parameter
+ csr0.word = 0;
+ RTMP_IO_WRITE32(pAd, WMM_TXOP0_CFG, csr0.word);
+ if (pAd->CommonCfg.PhyMode == PHY_11B)
+ {
+ csr0.field.Ac0Txop = 192; // AC_VI: 192*32us ~= 6ms
+ csr0.field.Ac1Txop = 96; // AC_VO: 96*32us ~= 3ms
+ }
+ else
+ {
+ csr0.field.Ac0Txop = 96; // AC_VI: 96*32us ~= 3ms
+ csr0.field.Ac1Txop = 48; // AC_VO: 48*32us ~= 1.5ms
+ }
+ RTMP_IO_WRITE32(pAd, WMM_TXOP1_CFG, csr0.word);
+
+
+
+
+ // reset action
+ // Load firmware
+ // Status = NICLoadFirmware(pAd);
+
+ DBGPRINT(RT_DEBUG_TRACE, ("<-- NICInitializeAdapter\n"));
+ return Status;
+}
+
+/*
+ ========================================================================
+
+ Routine Description:
+ Initialize ASIC
+
+ Arguments:
+ Adapter Pointer to our adapter
+
+ Return Value:
+ None
+
+ IRQL = PASSIVE_LEVEL
+
+ Note:
+
+ ========================================================================
+*/
+NDIS_STATUS NICInitializeAsic(
+ IN PRTMP_ADAPTER pAd,
+ IN BOOLEAN bHardReset)
+{
+ ULONG Index = 0;
+ UCHAR R0 = 0xff;
+ UINT32 MacCsr12 = 0, Counter = 0;
+#ifdef RT2870
+ UINT32 MacCsr0 = 0;
+ NTSTATUS Status;
+ UCHAR Value = 0xff;
+#endif // RT2870 //
+#ifdef RT30xx
+ UINT32 eFuseCtrl;
+#endif // RT30xx //
+ USHORT KeyIdx;
+ INT i,apidx;
+
+ DBGPRINT(RT_DEBUG_TRACE, ("--> NICInitializeAsic\n"));
+
+
+#ifdef RT2870
+ //
+ // Make sure MAC gets ready after NICLoadFirmware().
+ //
+ Index = 0;
+
+ //To avoid hang-on issue when interface up in kernel 2.4,
+ //we use a local variable "MacCsr0" instead of using "pAd->MACVersion" directly.
+ do
+ {
+ RTMP_IO_READ32(pAd, MAC_CSR0, &MacCsr0);
+
+ if ((MacCsr0 != 0x00) && (MacCsr0 != 0xFFFFFFFF))
+ break;
+
+ RTMPusecDelay(10);
+ } while (Index++ < 100);
+
+ pAd->MACVersion = MacCsr0;
+ DBGPRINT(RT_DEBUG_TRACE, ("MAC_CSR0 [ Ver:Rev=0x%08x]\n", pAd->MACVersion));
+ // turn on bit13 (set to zero) after rt2860D. This is to solve high-current issue.
+ RTMP_IO_READ32(pAd, PBF_SYS_CTRL, &MacCsr12);
+ MacCsr12 &= (~0x2000);
+ RTMP_IO_WRITE32(pAd, PBF_SYS_CTRL, MacCsr12);
+
+ RTMP_IO_WRITE32(pAd, MAC_SYS_CTRL, 0x3);
+ RTMP_IO_WRITE32(pAd, USB_DMA_CFG, 0x0);
+ Status = RTUSBVenderReset(pAd);
+
+ RTMP_IO_WRITE32(pAd, MAC_SYS_CTRL, 0x0);
+
+ // Initialize MAC register to default value
+ for(Index=0; Index<NUM_MAC_REG_PARMS; Index++)
+ {
+#ifdef RT3070
+ if ((MACRegTable[Index].Register == TX_SW_CFG0) && (IS_RT3070(pAd) || IS_RT3071(pAd)))
+ {
+ MACRegTable[Index].Value = 0x00000400;
+ }
+#endif // RT3070 //
+ RTMP_IO_WRITE32(pAd, (USHORT)MACRegTable[Index].Register, MACRegTable[Index].Value);
+ }
+
+
+#ifdef CONFIG_STA_SUPPORT
+ IF_DEV_CONFIG_OPMODE_ON_STA(pAd)
+ {
+ for (Index = 0; Index < NUM_STA_MAC_REG_PARMS; Index++)
+ {
+ RTMP_IO_WRITE32(pAd, (USHORT)STAMACRegTable[Index].Register, STAMACRegTable[Index].Value);
+ }
+ }
+#endif // CONFIG_STA_SUPPORT //
+#endif // RT2870 //
+
+#ifdef RT30xx
+ // Initialize RT3070 serial MAc registers which is different from RT2870 serial
+ if (IS_RT3090(pAd))
+ {
+ RTMP_IO_WRITE32(pAd, TX_SW_CFG1, 0);
+
+ // RT3071 version E has fixed this issue
+ if ((pAd->MACVersion & 0xffff) < 0x0211)
+ {
+ if (pAd->NicConfig2.field.DACTestBit == 1)
+ {
+ RTMP_IO_WRITE32(pAd, TX_SW_CFG2, 0x1F); // To fix throughput drop drastically
+ }
+ else
+ {
+ RTMP_IO_WRITE32(pAd, TX_SW_CFG2, 0x0F); // To fix throughput drop drastically
+ }
+ }
+ else
+ {
+ RTMP_IO_WRITE32(pAd, TX_SW_CFG2, 0x0);
+ }
+ }
+ else if (IS_RT3070(pAd))
+ {
+ RTMP_IO_WRITE32(pAd, TX_SW_CFG1, 0);
+ RTMP_IO_WRITE32(pAd, TX_SW_CFG2, 0x1F); // To fix throughput drop drastically
+ }
+#endif // RT30xx //
+
+ //
+ // Before program BBP, we need to wait BBP/RF get wake up.
+ //
+ Index = 0;
+ do
+ {
+ RTMP_IO_READ32(pAd, MAC_STATUS_CFG, &MacCsr12);
+
+ if ((MacCsr12 & 0x03) == 0) // if BB.RF is stable
+ break;
+
+ DBGPRINT(RT_DEBUG_TRACE, ("Check MAC_STATUS_CFG = Busy = %x\n", MacCsr12));
+ RTMPusecDelay(1000);
+ } while (Index++ < 100);
+
+ // The commands to firmware should be after these commands, these commands will init firmware
+ // PCI and USB are not the same because PCI driver needs to wait for PCI bus ready
+ RTMP_IO_WRITE32(pAd, H2M_BBP_AGENT, 0); // initialize BBP R/W access agent
+ RTMP_IO_WRITE32(pAd, H2M_MAILBOX_CSR, 0);
+ RTMPusecDelay(1000);
+
+ // Read BBP register, make sure BBP is up and running before write new data
+ Index = 0;
+ do
+ {
+ RTMP_BBP_IO_READ8_BY_REG_ID(pAd, BBP_R0, &R0);
+ DBGPRINT(RT_DEBUG_TRACE, ("BBP version = %x\n", R0));
+ } while ((++Index < 20) && ((R0 == 0xff) || (R0 == 0x00)));
+ //ASSERT(Index < 20); //this will cause BSOD on Check-build driver
+
+ if ((R0 == 0xff) || (R0 == 0x00))
+ return NDIS_STATUS_FAILURE;
+
+ // Initialize BBP register to default value
+ for (Index = 0; Index < NUM_BBP_REG_PARMS; Index++)
+ {
+ RTMP_BBP_IO_WRITE8_BY_REG_ID(pAd, BBPRegTable[Index].Register, BBPRegTable[Index].Value);
+ }
+
+ // for rt2860E and after, init BBP_R84 with 0x19. This is for extension channel overlapping IOT.
+ // RT3090 should not program BBP R84 to 0x19, otherwise TX will block.
+ if (((pAd->MACVersion&0xffff) != 0x0101) && (!IS_RT30xx(pAd)))
+ RTMP_BBP_IO_WRITE8_BY_REG_ID(pAd, BBP_R84, 0x19);
+
+// add by johnli, RF power sequence setup
+#ifdef RT30xx
+ if (IS_RT30xx(pAd))
+ { //update for RT3070/71/72/90/91/92.
+ RTMP_BBP_IO_WRITE8_BY_REG_ID(pAd, BBP_R79, 0x13);
+ RTMP_BBP_IO_WRITE8_BY_REG_ID(pAd, BBP_R80, 0x05);
+ RTMP_BBP_IO_WRITE8_BY_REG_ID(pAd, BBP_R81, 0x33);
+ }
+
+ if (IS_RT3090(pAd))
+ {
+ UCHAR bbpreg=0;
+
+ // enable DC filter
+ if ((pAd->MACVersion & 0xffff) >= 0x0211)
+ {
+ RTMP_BBP_IO_WRITE8_BY_REG_ID(pAd, BBP_R103, 0xc0);
+ }
+
+ // improve power consumption
+ RTMP_BBP_IO_READ8_BY_REG_ID(pAd, BBP_R138, &bbpreg);
+ if (pAd->Antenna.field.TxPath == 1)
+ {
+ // turn off tx DAC_1
+ bbpreg = (bbpreg | 0x20);
+ }
+
+ if (pAd->Antenna.field.RxPath == 1)
+ {
+ // turn off tx ADC_1
+ bbpreg &= (~0x2);
+ }
+ RTMP_BBP_IO_WRITE8_BY_REG_ID(pAd, BBP_R138, bbpreg);
+
+ // improve power consumption in RT3071 Ver.E
+ if ((pAd->MACVersion & 0xffff) >= 0x0211)
+ {
+ RTMP_BBP_IO_READ8_BY_REG_ID(pAd, BBP_R31, &bbpreg);
+ bbpreg &= (~0x3);
+ RTMP_BBP_IO_WRITE8_BY_REG_ID(pAd, BBP_R31, bbpreg);
+ }
+ }
+#endif // RT30xx //
+// end johnli
+
+ if (pAd->MACVersion == 0x28600100)
+ {
+ RTMP_BBP_IO_WRITE8_BY_REG_ID(pAd, BBP_R69, 0x16);
+ RTMP_BBP_IO_WRITE8_BY_REG_ID(pAd, BBP_R73, 0x12);
+ }
+
+ if (pAd->MACVersion >= RALINK_2880E_VERSION && pAd->MACVersion < RALINK_3070_VERSION) // 3*3
+ {
+ // enlarge MAX_LEN_CFG
+ UINT32 csr;
+ RTMP_IO_READ32(pAd, MAX_LEN_CFG, &csr);
+ csr &= 0xFFF;
+ csr |= 0x2000;
+ RTMP_IO_WRITE32(pAd, MAX_LEN_CFG, csr);
+ }
+
+#ifdef RT2870
+{
+ UCHAR MAC_Value[]={0xff,0xff,0xff,0xff,0xff,0xff,0xff,0,0};
+
+ //Initialize WCID table
+ Value = 0xff;
+ for(Index =0 ;Index < 254;Index++)
+ {
+ RTUSBMultiWrite(pAd, (USHORT)(MAC_WCID_BASE + Index * 8), MAC_Value, 8);
+ }
+}
+#endif // RT2870 //
+
+ // Add radio off control
+#ifdef CONFIG_STA_SUPPORT
+ IF_DEV_CONFIG_OPMODE_ON_STA(pAd)
+ {
+ if (pAd->StaCfg.bRadio == FALSE)
+ {
+// RTMP_IO_WRITE32(pAd, PWR_PIN_CFG, 0x00001818);
+ RTMP_SET_FLAG(pAd, fRTMP_ADAPTER_RADIO_OFF);
+ DBGPRINT(RT_DEBUG_TRACE, ("Set Radio Off\n"));
+ }
+ }
+#endif // CONFIG_STA_SUPPORT //
+
+ // Clear raw counters
+ RTMP_IO_READ32(pAd, RX_STA_CNT0, &Counter);
+ RTMP_IO_READ32(pAd, RX_STA_CNT1, &Counter);
+ RTMP_IO_READ32(pAd, RX_STA_CNT2, &Counter);
+ RTMP_IO_READ32(pAd, TX_STA_CNT0, &Counter);
+ RTMP_IO_READ32(pAd, TX_STA_CNT1, &Counter);
+ RTMP_IO_READ32(pAd, TX_STA_CNT2, &Counter);
+
+ // ASIC will keep garbage value after boot
+ // Clear all seared key table when initial
+ // This routine can be ignored in radio-ON/OFF operation.
+ if (bHardReset)
+ {
+ for (KeyIdx = 0; KeyIdx < 4; KeyIdx++)
+ {
+ RTMP_IO_WRITE32(pAd, SHARED_KEY_MODE_BASE + 4*KeyIdx, 0);
+ }
+
+ // Clear all pairwise key table when initial
+ for (KeyIdx = 0; KeyIdx < 256; KeyIdx++)
+ {
+ RTMP_IO_WRITE32(pAd, MAC_WCID_ATTRIBUTE_BASE + (KeyIdx * HW_WCID_ATTRI_SIZE), 1);
+ }
+ }
+
+ // assert HOST ready bit
+// RTMP_IO_WRITE32(pAd, MAC_CSR1, 0x0); // 2004-09-14 asked by Mark
+// RTMP_IO_WRITE32(pAd, MAC_CSR1, 0x4);
+
+ // It isn't necessary to clear this space when not hard reset.
+ if (bHardReset == TRUE)
+ {
+ // clear all on-chip BEACON frame space
+ for (apidx = 0; apidx < HW_BEACON_MAX_COUNT; apidx++)
+ {
+ for (i = 0; i < HW_BEACON_OFFSET>>2; i+=4)
+ RTMP_IO_WRITE32(pAd, pAd->BeaconOffset[apidx] + i, 0x00);
+ }
+ }
+#ifdef RT2870
+ AsicDisableSync(pAd);
+ // Clear raw counters
+ RTMP_IO_READ32(pAd, RX_STA_CNT0, &Counter);
+ RTMP_IO_READ32(pAd, RX_STA_CNT1, &Counter);
+ RTMP_IO_READ32(pAd, RX_STA_CNT2, &Counter);
+ RTMP_IO_READ32(pAd, TX_STA_CNT0, &Counter);
+ RTMP_IO_READ32(pAd, TX_STA_CNT1, &Counter);
+ RTMP_IO_READ32(pAd, TX_STA_CNT2, &Counter);
+ // Default PCI clock cycle per ms is different as default setting, which is based on PCI.
+ RTMP_IO_READ32(pAd, USB_CYC_CFG, &Counter);
+ Counter&=0xffffff00;
+ Counter|=0x000001e;
+ RTMP_IO_WRITE32(pAd, USB_CYC_CFG, Counter);
+#endif // RT2870 //
+#ifdef RT30xx
+ pAd->bUseEfuse=FALSE;
+ RTMP_IO_READ32(pAd, EFUSE_CTRL, &eFuseCtrl);
+ pAd->bUseEfuse = ( (eFuseCtrl & 0x80000000) == 0x80000000) ? 1 : 0;
+ if(pAd->bUseEfuse)
+ {
+ DBGPRINT(RT_DEBUG_TRACE, ("NVM is Efuse\n"));
+ }
+ else
+ {
+ DBGPRINT(RT_DEBUG_TRACE, ("NVM is EEPROM\n"));
+
+ }
+#endif // RT30xx //
+
+#ifdef CONFIG_STA_SUPPORT
+ IF_DEV_CONFIG_OPMODE_ON_STA(pAd)
+ {
+ // for rt2860E and after, init TXOP_CTRL_CFG with 0x583f. This is for extension channel overlapping IOT.
+ if ((pAd->MACVersion&0xffff) != 0x0101)
+ RTMP_IO_WRITE32(pAd, TXOP_CTRL_CFG, 0x583f);
+ }
+#endif // CONFIG_STA_SUPPORT //
+
+ DBGPRINT(RT_DEBUG_TRACE, ("<-- NICInitializeAsic\n"));
+ return NDIS_STATUS_SUCCESS;
+}
+
+/*
+ ========================================================================
+
+ Routine Description:
+ Reset NIC Asics
+
+ Arguments:
+ Adapter Pointer to our adapter
+
+ Return Value:
+ None
+
+ IRQL = PASSIVE_LEVEL
+
+ Note:
+ Reset NIC to initial state AS IS system boot up time.
+
+ ========================================================================
+*/
+VOID NICIssueReset(
+ IN PRTMP_ADAPTER pAd)
+{
+ UINT32 Value = 0;
+ DBGPRINT(RT_DEBUG_TRACE, ("--> NICIssueReset\n"));
+
+ // Abort Tx, prevent ASIC from writing to Host memory
+ //RTMP_IO_WRITE32(pAd, TX_CNTL_CSR, 0x001f0000);
+
+ // Disable Rx, register value supposed will remain after reset
+ RTMP_IO_READ32(pAd, MAC_SYS_CTRL, &Value);
+ Value &= (0xfffffff3);
+ RTMP_IO_WRITE32(pAd, MAC_SYS_CTRL, Value);
+
+ // Issue reset and clear from reset state
+ RTMP_IO_WRITE32(pAd, MAC_SYS_CTRL, 0x03); // 2004-09-17 change from 0x01
+ RTMP_IO_WRITE32(pAd, MAC_SYS_CTRL, 0x00);
+
+ DBGPRINT(RT_DEBUG_TRACE, ("<-- NICIssueReset\n"));
+}
+
+/*
+ ========================================================================
+
+ Routine Description:
+ Check ASIC registers and find any reason the system might hang
+
+ Arguments:
+ Adapter Pointer to our adapter
+
+ Return Value:
+ None
+
+ IRQL = DISPATCH_LEVEL
+
+ ========================================================================
+*/
+BOOLEAN NICCheckForHang(
+ IN PRTMP_ADAPTER pAd)
+{
+ return (FALSE);
+}
+
+VOID NICUpdateFifoStaCounters(
+ IN PRTMP_ADAPTER pAd)
+{
+ TX_STA_FIFO_STRUC StaFifo;
+ MAC_TABLE_ENTRY *pEntry;
+ UCHAR i = 0;
+ UCHAR pid = 0, wcid = 0;
+ CHAR reTry;
+ UCHAR succMCS;
+
+#ifdef RALINK_ATE
+ /* Nothing to do in ATE mode */
+ if (ATE_ON(pAd))
+ return;
+#endif // RALINK_ATE //
+
+ do
+ {
+ RTMP_IO_READ32(pAd, TX_STA_FIFO, &StaFifo.word);
+
+ if (StaFifo.field.bValid == 0)
+ break;
+
+ wcid = (UCHAR)StaFifo.field.wcid;
+
+
+ /* ignore NoACK and MGMT frame use 0xFF as WCID */
+ if ((StaFifo.field.TxAckRequired == 0) || (wcid >= MAX_LEN_OF_MAC_TABLE))
+ {
+ i++;
+ continue;
+ }
+
+ /* PID store Tx MCS Rate */
+ pid = (UCHAR)StaFifo.field.PidType;
+
+ pEntry = &pAd->MacTab.Content[wcid];
+
+ pEntry->DebugFIFOCount++;
+
+#ifdef DOT11_N_SUPPORT
+ if (StaFifo.field.TxBF) // 3*3
+ pEntry->TxBFCount++;
+#endif // DOT11_N_SUPPORT //
+
+#ifdef UAPSD_AP_SUPPORT
+ UAPSD_SP_AUE_Handle(pAd, pEntry, StaFifo.field.TxSuccess);
+#endif // UAPSD_AP_SUPPORT //
+
+ if (!StaFifo.field.TxSuccess)
+ {
+ pEntry->FIFOCount++;
+ pEntry->OneSecTxFailCount++;
+
+ if (pEntry->FIFOCount >= 1)
+ {
+ DBGPRINT(RT_DEBUG_TRACE, ("#"));
+#ifdef DOT11_N_SUPPORT
+ pEntry->NoBADataCountDown = 64;
+#endif // DOT11_N_SUPPORT //
+
+ if(pEntry->PsMode == PWR_ACTIVE)
+ {
+#ifdef DOT11_N_SUPPORT
+ int tid;
+ for (tid=0; tid<NUM_OF_TID; tid++)
+ {
+ BAOriSessionTearDown(pAd, pEntry->Aid, tid, FALSE, FALSE);
+ }
+#endif // DOT11_N_SUPPORT //
+
+ // Update the continuous transmission counter except PS mode
+ pEntry->ContinueTxFailCnt++;
+ }
+ else
+ {
+ // Clear the FIFOCount when sta in Power Save mode. Basically we assume
+ // this tx error happened due to sta just go to sleep.
+ pEntry->FIFOCount = 0;
+ pEntry->ContinueTxFailCnt = 0;
+ }
+ //pEntry->FIFOCount = 0;
+ }
+ //pEntry->bSendBAR = TRUE;
+ }
+ else
+ {
+#ifdef DOT11_N_SUPPORT
+ if ((pEntry->PsMode != PWR_SAVE) && (pEntry->NoBADataCountDown > 0))
+ {
+ pEntry->NoBADataCountDown--;
+ if (pEntry->NoBADataCountDown==0)
+ {
+ DBGPRINT(RT_DEBUG_TRACE, ("@\n"));
+ }
+ }
+#endif // DOT11_N_SUPPORT //
+ pEntry->FIFOCount = 0;
+ pEntry->OneSecTxNoRetryOkCount++;
+ // update NoDataIdleCount when sucessful send packet to STA.
+ pEntry->NoDataIdleCount = 0;
+ pEntry->ContinueTxFailCnt = 0;
+ }
+
+ succMCS = StaFifo.field.SuccessRate & 0x7F;
+
+ reTry = pid - succMCS;
+
+ if (StaFifo.field.TxSuccess)
+ {
+ pEntry->TXMCSExpected[pid]++;
+ if (pid == succMCS)
+ {
+ pEntry->TXMCSSuccessful[pid]++;
+ }
+ else
+ {
+ pEntry->TXMCSAutoFallBack[pid][succMCS]++;
+ }
+ }
+ else
+ {
+ pEntry->TXMCSFailed[pid]++;
+ }
+
+ if (reTry > 0)
+ {
+ if ((pid >= 12) && succMCS <=7)
+ {
+ reTry -= 4;
+ }
+ pEntry->OneSecTxRetryOkCount += reTry;
+ }
+
+ i++;
+ // ASIC store 16 stack
+ } while ( i < (2*TX_RING_SIZE) );
+
+}
+
+/*
+ ========================================================================
+
+ Routine Description:
+ Read statistical counters from hardware registers and record them
+ in software variables for later on query
+
+ Arguments:
+ pAd Pointer to our adapter
+
+ Return Value:
+ None
+
+ IRQL = DISPATCH_LEVEL
+
+ ========================================================================
+*/
+VOID NICUpdateRawCounters(
+ IN PRTMP_ADAPTER pAd)
+{
+ UINT32 OldValue;//, Value2;
+ //ULONG PageSum, OneSecTransmitCount;
+ //ULONG TxErrorRatio, Retry, Fail;
+ RX_STA_CNT0_STRUC RxStaCnt0;
+ RX_STA_CNT1_STRUC RxStaCnt1;
+ RX_STA_CNT2_STRUC RxStaCnt2;
+ TX_STA_CNT0_STRUC TxStaCnt0;
+ TX_STA_CNT1_STRUC StaTx1;
+ TX_STA_CNT2_STRUC StaTx2;
+ TX_AGG_CNT_STRUC TxAggCnt;
+ TX_AGG_CNT0_STRUC TxAggCnt0;
+ TX_AGG_CNT1_STRUC TxAggCnt1;
+ TX_AGG_CNT2_STRUC TxAggCnt2;
+ TX_AGG_CNT3_STRUC TxAggCnt3;
+ TX_AGG_CNT4_STRUC TxAggCnt4;
+ TX_AGG_CNT5_STRUC TxAggCnt5;
+ TX_AGG_CNT6_STRUC TxAggCnt6;
+ TX_AGG_CNT7_STRUC TxAggCnt7;
+
+ RTMP_IO_READ32(pAd, RX_STA_CNT0, &RxStaCnt0.word);
+ RTMP_IO_READ32(pAd, RX_STA_CNT2, &RxStaCnt2.word);
+
+ {
+ RTMP_IO_READ32(pAd, RX_STA_CNT1, &RxStaCnt1.word);
+ // Update RX PLCP error counter
+ pAd->PrivateInfo.PhyRxErrCnt += RxStaCnt1.field.PlcpErr;
+ // Update False CCA counter
+ pAd->RalinkCounters.OneSecFalseCCACnt += RxStaCnt1.field.FalseCca;
+ }
+
+ // Update FCS counters
+ OldValue= pAd->WlanCounters.FCSErrorCount.u.LowPart;
+ pAd->WlanCounters.FCSErrorCount.u.LowPart += (RxStaCnt0.field.CrcErr); // >> 7);
+ if (pAd->WlanCounters.FCSErrorCount.u.LowPart < OldValue)
+ pAd->WlanCounters.FCSErrorCount.u.HighPart++;
+
+ // Add FCS error count to private counters
+ pAd->RalinkCounters.OneSecRxFcsErrCnt += RxStaCnt0.field.CrcErr;
+ OldValue = pAd->RalinkCounters.RealFcsErrCount.u.LowPart;
+ pAd->RalinkCounters.RealFcsErrCount.u.LowPart += RxStaCnt0.field.CrcErr;
+ if (pAd->RalinkCounters.RealFcsErrCount.u.LowPart < OldValue)
+ pAd->RalinkCounters.RealFcsErrCount.u.HighPart++;
+
+ // Update Duplicate Rcv check
+ pAd->RalinkCounters.DuplicateRcv += RxStaCnt2.field.RxDupliCount;
+ pAd->WlanCounters.FrameDuplicateCount.u.LowPart += RxStaCnt2.field.RxDupliCount;
+ // Update RX Overflow counter
+ pAd->Counters8023.RxNoBuffer += (RxStaCnt2.field.RxFifoOverflowCount);
+
+ //pAd->RalinkCounters.RxCount = 0;
+#ifdef RT2870
+ if (pAd->RalinkCounters.RxCount != pAd->watchDogRxCnt)
+ {
+ pAd->watchDogRxCnt = pAd->RalinkCounters.RxCount;
+ pAd->watchDogRxOverFlowCnt = 0;
+ }
+ else
+ {
+ if (RxStaCnt2.field.RxFifoOverflowCount)
+ pAd->watchDogRxOverFlowCnt++;
+ else
+ pAd->watchDogRxOverFlowCnt = 0;
+ }
+#endif // RT2870 //
+
+
+ //if (!OPSTATUS_TEST_FLAG(pAd, fOP_STATUS_TX_RATE_SWITCH_ENABLED) ||
+ // (OPSTATUS_TEST_FLAG(pAd, fOP_STATUS_TX_RATE_SWITCH_ENABLED) && (pAd->MacTab.Size != 1)))
+ if (!pAd->bUpdateBcnCntDone)
+ {
+ // Update BEACON sent count
+ RTMP_IO_READ32(pAd, TX_STA_CNT0, &TxStaCnt0.word);
+ RTMP_IO_READ32(pAd, TX_STA_CNT1, &StaTx1.word);
+ RTMP_IO_READ32(pAd, TX_STA_CNT2, &StaTx2.word);
+ pAd->RalinkCounters.OneSecBeaconSentCnt += TxStaCnt0.field.TxBeaconCount;
+ pAd->RalinkCounters.OneSecTxRetryOkCount += StaTx1.field.TxRetransmit;
+ pAd->RalinkCounters.OneSecTxNoRetryOkCount += StaTx1.field.TxSuccess;
+ pAd->RalinkCounters.OneSecTxFailCount += TxStaCnt0.field.TxFailCount;
+ pAd->WlanCounters.TransmittedFragmentCount.u.LowPart += StaTx1.field.TxSuccess;
+ pAd->WlanCounters.RetryCount.u.LowPart += StaTx1.field.TxRetransmit;
+ pAd->WlanCounters.FailedCount.u.LowPart += TxStaCnt0.field.TxFailCount;
+ }
+
+ //if (pAd->bStaFifoTest == TRUE)
+ {
+ RTMP_IO_READ32(pAd, TX_AGG_CNT, &TxAggCnt.word);
+ RTMP_IO_READ32(pAd, TX_AGG_CNT0, &TxAggCnt0.word);
+ RTMP_IO_READ32(pAd, TX_AGG_CNT1, &TxAggCnt1.word);
+ RTMP_IO_READ32(pAd, TX_AGG_CNT2, &TxAggCnt2.word);
+ RTMP_IO_READ32(pAd, TX_AGG_CNT3, &TxAggCnt3.word);
+ RTMP_IO_READ32(pAd, TX_AGG_CNT4, &TxAggCnt4.word);
+ RTMP_IO_READ32(pAd, TX_AGG_CNT5, &TxAggCnt5.word);
+ RTMP_IO_READ32(pAd, TX_AGG_CNT6, &TxAggCnt6.word);
+ RTMP_IO_READ32(pAd, TX_AGG_CNT7, &TxAggCnt7.word);
+ pAd->RalinkCounters.TxAggCount += TxAggCnt.field.AggTxCount;
+ pAd->RalinkCounters.TxNonAggCount += TxAggCnt.field.NonAggTxCount;
+ pAd->RalinkCounters.TxAgg1MPDUCount += TxAggCnt0.field.AggSize1Count;
+ pAd->RalinkCounters.TxAgg2MPDUCount += TxAggCnt0.field.AggSize2Count;
+
+ pAd->RalinkCounters.TxAgg3MPDUCount += TxAggCnt1.field.AggSize3Count;
+ pAd->RalinkCounters.TxAgg4MPDUCount += TxAggCnt1.field.AggSize4Count;
+ pAd->RalinkCounters.TxAgg5MPDUCount += TxAggCnt2.field.AggSize5Count;
+ pAd->RalinkCounters.TxAgg6MPDUCount += TxAggCnt2.field.AggSize6Count;
+
+ pAd->RalinkCounters.TxAgg7MPDUCount += TxAggCnt3.field.AggSize7Count;
+ pAd->RalinkCounters.TxAgg8MPDUCount += TxAggCnt3.field.AggSize8Count;
+ pAd->RalinkCounters.TxAgg9MPDUCount += TxAggCnt4.field.AggSize9Count;
+ pAd->RalinkCounters.TxAgg10MPDUCount += TxAggCnt4.field.AggSize10Count;
+
+ pAd->RalinkCounters.TxAgg11MPDUCount += TxAggCnt5.field.AggSize11Count;
+ pAd->RalinkCounters.TxAgg12MPDUCount += TxAggCnt5.field.AggSize12Count;
+ pAd->RalinkCounters.TxAgg13MPDUCount += TxAggCnt6.field.AggSize13Count;
+ pAd->RalinkCounters.TxAgg14MPDUCount += TxAggCnt6.field.AggSize14Count;
+
+ pAd->RalinkCounters.TxAgg15MPDUCount += TxAggCnt7.field.AggSize15Count;
+ pAd->RalinkCounters.TxAgg16MPDUCount += TxAggCnt7.field.AggSize16Count;
+
+ // Calculate the transmitted A-MPDU count
+ pAd->RalinkCounters.TransmittedAMPDUCount.u.LowPart += TxAggCnt0.field.AggSize1Count;
+ pAd->RalinkCounters.TransmittedAMPDUCount.u.LowPart += (TxAggCnt0.field.AggSize2Count / 2);
+
+ pAd->RalinkCounters.TransmittedAMPDUCount.u.LowPart += (TxAggCnt1.field.AggSize3Count / 3);
+ pAd->RalinkCounters.TransmittedAMPDUCount.u.LowPart += (TxAggCnt1.field.AggSize4Count / 4);
+
+ pAd->RalinkCounters.TransmittedAMPDUCount.u.LowPart += (TxAggCnt2.field.AggSize5Count / 5);
+ pAd->RalinkCounters.TransmittedAMPDUCount.u.LowPart += (TxAggCnt2.field.AggSize6Count / 6);
+
+ pAd->RalinkCounters.TransmittedAMPDUCount.u.LowPart += (TxAggCnt3.field.AggSize7Count / 7);
+ pAd->RalinkCounters.TransmittedAMPDUCount.u.LowPart += (TxAggCnt3.field.AggSize8Count / 8);
+
+ pAd->RalinkCounters.TransmittedAMPDUCount.u.LowPart += (TxAggCnt4.field.AggSize9Count / 9);
+ pAd->RalinkCounters.TransmittedAMPDUCount.u.LowPart += (TxAggCnt4.field.AggSize10Count / 10);
+
+ pAd->RalinkCounters.TransmittedAMPDUCount.u.LowPart += (TxAggCnt5.field.AggSize11Count / 11);
+ pAd->RalinkCounters.TransmittedAMPDUCount.u.LowPart += (TxAggCnt5.field.AggSize12Count / 12);
+
+ pAd->RalinkCounters.TransmittedAMPDUCount.u.LowPart += (TxAggCnt6.field.AggSize13Count / 13);
+ pAd->RalinkCounters.TransmittedAMPDUCount.u.LowPart += (TxAggCnt6.field.AggSize14Count / 14);
+
+ pAd->RalinkCounters.TransmittedAMPDUCount.u.LowPart += (TxAggCnt7.field.AggSize15Count / 15);
+ pAd->RalinkCounters.TransmittedAMPDUCount.u.LowPart += (TxAggCnt7.field.AggSize16Count / 16);
+ }
+
+#ifdef DBG_DIAGNOSE
+ {
+ RtmpDiagStruct *pDiag;
+ COUNTER_RALINK *pRalinkCounters;
+ UCHAR ArrayCurIdx, i;
+
+ pDiag = &pAd->DiagStruct;
+ pRalinkCounters = &pAd->RalinkCounters;
+ ArrayCurIdx = pDiag->ArrayCurIdx;
+
+ if (pDiag->inited == 0)
+ {
+ NdisZeroMemory(pDiag, sizeof(struct _RtmpDiagStrcut_));
+ pDiag->ArrayStartIdx = pDiag->ArrayCurIdx = 0;
+ pDiag->inited = 1;
+ }
+ else
+ {
+ // Tx
+ pDiag->TxFailCnt[ArrayCurIdx] = TxStaCnt0.field.TxFailCount;
+ pDiag->TxAggCnt[ArrayCurIdx] = TxAggCnt.field.AggTxCount;
+ pDiag->TxNonAggCnt[ArrayCurIdx] = TxAggCnt.field.NonAggTxCount;
+ pDiag->TxAMPDUCnt[ArrayCurIdx][0] = TxAggCnt0.field.AggSize1Count;
+ pDiag->TxAMPDUCnt[ArrayCurIdx][1] = TxAggCnt0.field.AggSize2Count;
+ pDiag->TxAMPDUCnt[ArrayCurIdx][2] = TxAggCnt1.field.AggSize3Count;
+ pDiag->TxAMPDUCnt[ArrayCurIdx][3] = TxAggCnt1.field.AggSize4Count;
+ pDiag->TxAMPDUCnt[ArrayCurIdx][4] = TxAggCnt2.field.AggSize5Count;
+ pDiag->TxAMPDUCnt[ArrayCurIdx][5] = TxAggCnt2.field.AggSize6Count;
+ pDiag->TxAMPDUCnt[ArrayCurIdx][6] = TxAggCnt3.field.AggSize7Count;
+ pDiag->TxAMPDUCnt[ArrayCurIdx][7] = TxAggCnt3.field.AggSize8Count;
+ pDiag->TxAMPDUCnt[ArrayCurIdx][8] = TxAggCnt4.field.AggSize9Count;
+ pDiag->TxAMPDUCnt[ArrayCurIdx][9] = TxAggCnt4.field.AggSize10Count;
+ pDiag->TxAMPDUCnt[ArrayCurIdx][10] = TxAggCnt5.field.AggSize11Count;
+ pDiag->TxAMPDUCnt[ArrayCurIdx][11] = TxAggCnt5.field.AggSize12Count;
+ pDiag->TxAMPDUCnt[ArrayCurIdx][12] = TxAggCnt6.field.AggSize13Count;
+ pDiag->TxAMPDUCnt[ArrayCurIdx][13] = TxAggCnt6.field.AggSize14Count;
+ pDiag->TxAMPDUCnt[ArrayCurIdx][14] = TxAggCnt7.field.AggSize15Count;
+ pDiag->TxAMPDUCnt[ArrayCurIdx][15] = TxAggCnt7.field.AggSize16Count;
+
+ pDiag->RxCrcErrCnt[ArrayCurIdx] = RxStaCnt0.field.CrcErr;
+
+ INC_RING_INDEX(pDiag->ArrayCurIdx, DIAGNOSE_TIME);
+ ArrayCurIdx = pDiag->ArrayCurIdx;
+ for (i =0; i < 9; i++)
+ {
+ pDiag->TxDescCnt[ArrayCurIdx][i]= 0;
+ pDiag->TxSWQueCnt[ArrayCurIdx][i] =0;
+ pDiag->TxMcsCnt[ArrayCurIdx][i] = 0;
+ pDiag->RxMcsCnt[ArrayCurIdx][i] = 0;
+ }
+ pDiag->TxDataCnt[ArrayCurIdx] = 0;
+ pDiag->TxFailCnt[ArrayCurIdx] = 0;
+ pDiag->RxDataCnt[ArrayCurIdx] = 0;
+ pDiag->RxCrcErrCnt[ArrayCurIdx] = 0;
+// for (i = 9; i < 16; i++)
+ for (i = 9; i < 24; i++) // 3*3
+ {
+ pDiag->TxDescCnt[ArrayCurIdx][i] = 0;
+ pDiag->TxMcsCnt[ArrayCurIdx][i] = 0;
+ pDiag->RxMcsCnt[ArrayCurIdx][i] = 0;
+}
+
+ if (pDiag->ArrayCurIdx == pDiag->ArrayStartIdx)
+ INC_RING_INDEX(pDiag->ArrayStartIdx, DIAGNOSE_TIME);
+ }
+
+ }
+#endif // DBG_DIAGNOSE //
+
+
+}
+
+
+/*
+ ========================================================================
+
+ Routine Description:
+ Reset NIC from error
+
+ Arguments:
+ Adapter Pointer to our adapter
+
+ Return Value:
+ None
+
+ IRQL = PASSIVE_LEVEL
+
+ Note:
+ Reset NIC from error state
+
+ ========================================================================
+*/
+VOID NICResetFromError(
+ IN PRTMP_ADAPTER pAd)
+{
+ // Reset BBP (according to alex, reset ASIC will force reset BBP
+ // Therefore, skip the reset BBP
+ // RTMP_IO_WRITE32(pAd, MAC_CSR1, 0x2);
+
+ RTMP_IO_WRITE32(pAd, MAC_SYS_CTRL, 0x1);
+ // Remove ASIC from reset state
+ RTMP_IO_WRITE32(pAd, MAC_SYS_CTRL, 0x0);
+
+ NICInitializeAdapter(pAd, FALSE);
+ NICInitAsicFromEEPROM(pAd);
+
+ // Switch to current channel, since during reset process, the connection should remains on.
+ AsicSwitchChannel(pAd, pAd->CommonCfg.CentralChannel, FALSE);
+ AsicLockChannel(pAd, pAd->CommonCfg.CentralChannel);
+}
+
+/*
+ ========================================================================
+
+ Routine Description:
+ erase 8051 firmware image in MAC ASIC
+
+ Arguments:
+ Adapter Pointer to our adapter
+
+ IRQL = PASSIVE_LEVEL
+
+ ========================================================================
+*/
+VOID NICEraseFirmware(
+ IN PRTMP_ADAPTER pAd)
+{
+ ULONG i;
+
+ for(i=0; i<MAX_FIRMWARE_IMAGE_SIZE; i+=4)
+ RTMP_IO_WRITE32(pAd, FIRMWARE_IMAGE_BASE + i, 0);
+
+}/* End of NICEraseFirmware */
+
+/*
+ ========================================================================
+
+ Routine Description:
+ Load 8051 firmware RT2561.BIN file into MAC ASIC
+
+ Arguments:
+ Adapter Pointer to our adapter
+
+ Return Value:
+ NDIS_STATUS_SUCCESS firmware image load ok
+ NDIS_STATUS_FAILURE image not found
+
+ IRQL = PASSIVE_LEVEL
+
+ ========================================================================
+*/
+NDIS_STATUS NICLoadFirmware(
+ IN PRTMP_ADAPTER pAd)
+{
+#ifdef BIN_IN_FILE
+#define NICLF_DEFAULT_USE() \
+ flg_default_firm_use = TRUE; \
+ printk("%s - Use default firmware!\n", __FUNCTION__);
+
+ NDIS_STATUS Status = NDIS_STATUS_SUCCESS;
+ PUCHAR src;
+ struct file *srcf;
+ INT retval, orgfsuid, orgfsgid, i;
+ mm_segment_t orgfs;
+ PUCHAR pFirmwareImage;
+ UINT FileLength = 0;
+ UINT32 MacReg;
+ ULONG Index;
+ ULONG firm;
+ BOOLEAN flg_default_firm_use = FALSE;
+
+
+ DBGPRINT(RT_DEBUG_TRACE, ("===> %s\n", __FUNCTION__));
+
+ /* init */
+ pFirmwareImage = NULL;
+ src = RTMP_FIRMWARE_FILE_NAME;
+
+ /* save uid and gid used for filesystem access.
+ set user and group to 0 (root) */
+ orgfsuid = current->fsuid;
+ orgfsgid = current->fsgid;
+ current->fsuid = current->fsgid = 0;
+ orgfs = get_fs();
+ set_fs(KERNEL_DS);
+
+ pAd->FirmwareVersion = (FIRMWARE_MAJOR_VERSION << 8) + \
+ FIRMWARE_MINOR_VERSION;
+
+
+ /* allocate firmware buffer */
+ pFirmwareImage = kmalloc(MAX_FIRMWARE_IMAGE_SIZE, MEM_ALLOC_FLAG);
+ if (pFirmwareImage == NULL)
+ {
+ /* allocate fail, use default firmware array in firmware.h */
+ printk("%s - Allocate memory fail!\n", __FUNCTION__);
+ NICLF_DEFAULT_USE();
+ }
+ else
+ {
+ /* allocate ok! zero the firmware buffer */
+ memset(pFirmwareImage, 0x00, MAX_FIRMWARE_IMAGE_SIZE);
+ } /* End of if */
+
+
+ /* if ok, read firmware file from *.bin file */
+ if (flg_default_firm_use == FALSE)
+ {
+ do
+ {
+ /* open the bin file */
+ srcf = filp_open(src, O_RDONLY, 0);
+
+ if (IS_ERR(srcf))
+ {
+ printk("%s - Error %ld opening %s\n",
+ __FUNCTION__, -PTR_ERR(srcf), src);
+ NICLF_DEFAULT_USE();
+ break;
+ } /* End of if */
+
+ /* the object must have a read method */
+ if ((srcf->f_op == NULL) || (srcf->f_op->read == NULL))
+ {
+ printk("%s - %s does not have a write method\n", __FUNCTION__, src);
+ NICLF_DEFAULT_USE();
+ break;
+ } /* End of if */
+
+ /* read the firmware from the file *.bin */
+ FileLength = srcf->f_op->read(srcf,
+ pFirmwareImage,
+ MAX_FIRMWARE_IMAGE_SIZE,
+ &srcf->f_pos);
+
+ if (FileLength != MAX_FIRMWARE_IMAGE_SIZE)
+ {
+ printk("%s: error file length (=%d) in RT2860AP.BIN\n",
+ __FUNCTION__, FileLength);
+ NICLF_DEFAULT_USE();
+ break;
+ }
+ else
+ {
+ PUCHAR ptr = pFirmwareImage;
+ USHORT crc = 0xffff;
+
+
+ /* calculate firmware CRC */
+ for(i=0; i<(MAX_FIRMWARE_IMAGE_SIZE-2); i++, ptr++)
+ crc = ByteCRC16(BitReverse(*ptr), crc);
+ /* End of for */
+
+ if ((pFirmwareImage[MAX_FIRMWARE_IMAGE_SIZE-2] != \
+ (UCHAR)BitReverse((UCHAR)(crc>>8))) ||
+ (pFirmwareImage[MAX_FIRMWARE_IMAGE_SIZE-1] != \
+ (UCHAR)BitReverse((UCHAR)crc)))
+ {
+ /* CRC fail */
+ printk("%s: CRC = 0x%02x 0x%02x "
+ "error, should be 0x%02x 0x%02x\n",
+ __FUNCTION__,
+ pFirmwareImage[MAX_FIRMWARE_IMAGE_SIZE-2],
+ pFirmwareImage[MAX_FIRMWARE_IMAGE_SIZE-1],
+ (UCHAR)(crc>>8), (UCHAR)(crc));
+ NICLF_DEFAULT_USE();
+ break;
+ }
+ else
+ {
+ /* firmware is ok */
+ pAd->FirmwareVersion = \
+ (pFirmwareImage[MAX_FIRMWARE_IMAGE_SIZE-4] << 8) +
+ pFirmwareImage[MAX_FIRMWARE_IMAGE_SIZE-3];
+
+ /* check if firmware version of the file is too old */
+ if ((pAd->FirmwareVersion) < \
+ ((FIRMWARE_MAJOR_VERSION << 8) +
+ FIRMWARE_MINOR_VERSION))
+ {
+ printk("%s: firmware version too old!\n", __FUNCTION__);
+ NICLF_DEFAULT_USE();
+ break;
+ } /* End of if */
+ } /* End of if */
+
+ DBGPRINT(RT_DEBUG_TRACE,
+ ("NICLoadFirmware: CRC ok, ver=%d.%d\n",
+ pFirmwareImage[MAX_FIRMWARE_IMAGE_SIZE-4],
+ pFirmwareImage[MAX_FIRMWARE_IMAGE_SIZE-3]));
+ } /* End of if (FileLength == MAX_FIRMWARE_IMAGE_SIZE) */
+ break;
+ } while(TRUE);
+
+ /* close firmware file */
+ if (IS_ERR(srcf))
+ ;
+ else
+ {
+ retval = filp_close(srcf, NULL);
+ if (retval)
+ {
+ DBGPRINT(RT_DEBUG_ERROR,
+ ("--> Error %d closing %s\n", -retval, src));
+ } /* End of if */
+ } /* End of if */
+ } /* End of if */
+
+
+ /* write firmware to ASIC */
+ if (flg_default_firm_use == TRUE)
+ {
+ /* use default fimeware, free allocated buffer */
+ if (pFirmwareImage != NULL)
+ kfree(pFirmwareImage);
+ /* End of if */
+
+ /* use default *.bin array */
+ pFirmwareImage = FirmwareImage;
+ FileLength = sizeof(FirmwareImage);
+ } /* End of if */
+
+ /* enable Host program ram write selection */
+ RTMP_IO_WRITE32(pAd, PBF_SYS_CTRL, 0x10000);
+
+ for(i=0; i<FileLength; i+=4)
+ {
+ firm = pFirmwareImage[i] +
+ (pFirmwareImage[i+3] << 24) +
+ (pFirmwareImage[i+2] << 16) +
+ (pFirmwareImage[i+1] << 8);
+
+ RTMP_IO_WRITE32(pAd, FIRMWARE_IMAGE_BASE + i, firm);
+ } /* End of for */
+
+ RTMP_IO_WRITE32(pAd, PBF_SYS_CTRL, 0x00000);
+ RTMP_IO_WRITE32(pAd, PBF_SYS_CTRL, 0x00001);
+
+ /* initialize BBP R/W access agent */
+ RTMP_IO_WRITE32(pAd, H2M_BBP_AGENT, 0);
+ RTMP_IO_WRITE32(pAd, H2M_MAILBOX_CSR, 0);
+
+ if (flg_default_firm_use == FALSE)
+ {
+ /* use file firmware, free allocated buffer */
+ if (pFirmwareImage != NULL)
+ kfree(pFirmwareImage);
+ /* End of if */
+ } /* End of if */
+
+ set_fs(orgfs);
+ current->fsuid = orgfsuid;
+ current->fsgid = orgfsgid;
+#else
+
+ NDIS_STATUS Status = NDIS_STATUS_SUCCESS;
+ PUCHAR pFirmwareImage;
+ ULONG FileLength, Index;
+ //ULONG firm;
+ UINT32 MacReg = 0;
+ UINT32 Version = (pAd->MACVersion >> 16);
+
+ pFirmwareImage = FirmwareImage;
+ FileLength = sizeof(FirmwareImage);
+
+ // New 8k byte firmware size for RT3071/RT3072
+ //printk("Usb Chip\n");
+ if (FIRMWAREIMAGE_LENGTH == FIRMWAREIMAGE_MAX_LENGTH)
+ //The firmware image consists of two parts. One is the origianl and the other is the new.
+ //Use Second Part
+ {
+#ifdef RT2870
+ if ((Version != 0x2860) && (Version != 0x2872) && (Version != 0x3070))
+ { // Use Firmware V2.
+ //printk("KH:Use New Version,part2\n");
+ pFirmwareImage = (PUCHAR)&FirmwareImage[FIRMWAREIMAGEV1_LENGTH];
+ FileLength = FIRMWAREIMAGEV2_LENGTH;
+ }
+ else
+ {
+ //printk("KH:Use New Version,part1\n");
+ pFirmwareImage = FirmwareImage;
+ FileLength = FIRMWAREIMAGEV1_LENGTH;
+ }
+#endif // RT2870 //
+ }
+ else
+ {
+ DBGPRINT(RT_DEBUG_ERROR, ("KH: bin file should be 8KB.\n"));
+ Status = NDIS_STATUS_FAILURE;
+ }
+
+ RT28XX_WRITE_FIRMWARE(pAd, pFirmwareImage, FileLength);
+
+#endif
+
+ /* check if MCU is ready */
+ Index = 0;
+ do
+ {
+ RTMP_IO_READ32(pAd, PBF_SYS_CTRL, &MacReg);
+
+ if (MacReg & 0x80)
+ break;
+
+ RTMPusecDelay(1000);
+ } while (Index++ < 1000);
+
+ if (Index >= 1000)
+ {
+ Status = NDIS_STATUS_FAILURE;
+ DBGPRINT(RT_DEBUG_ERROR, ("NICLoadFirmware: MCU is not ready\n\n\n"));
+ } /* End of if */
+
+ DBGPRINT(RT_DEBUG_TRACE,
+ ("<=== %s (status=%d)\n", __FUNCTION__, Status));
+ return Status;
+} /* End of NICLoadFirmware */
+
+
+/*
+ ========================================================================
+
+ Routine Description:
+ Load Tx rate switching parameters
+
+ Arguments:
+ Adapter Pointer to our adapter
+
+ Return Value:
+ NDIS_STATUS_SUCCESS firmware image load ok
+ NDIS_STATUS_FAILURE image not found
+
+ IRQL = PASSIVE_LEVEL
+
+ Rate Table Format:
+ 1. (B0: Valid Item number) (B1:Initial item from zero)
+ 2. Item Number(Dec) Mode(Hex) Current MCS(Dec) TrainUp(Dec) TrainDown(Dec)
+
+ ========================================================================
+*/
+NDIS_STATUS NICLoadRateSwitchingParams(
+ IN PRTMP_ADAPTER pAd)
+{
+ return NDIS_STATUS_SUCCESS;
+}
+
+/*
+ ========================================================================
+
+ Routine Description:
+ if pSrc1 all zero with length Length, return 0.
+ If not all zero, return 1
+
+ Arguments:
+ pSrc1
+
+ Return Value:
+ 1: not all zero
+ 0: all zero
+
+ IRQL = DISPATCH_LEVEL
+
+ Note:
+
+ ========================================================================
+*/
+ULONG RTMPNotAllZero(
+ IN PVOID pSrc1,
+ IN ULONG Length)
+{
+ PUCHAR pMem1;
+ ULONG Index = 0;
+
+ pMem1 = (PUCHAR) pSrc1;
+
+ for (Index = 0; Index < Length; Index++)
+ {
+ if (pMem1[Index] != 0x0)
+ {
+ break;
+ }
+ }
+
+ if (Index == Length)
+ {
+ return (0);
+ }
+ else
+ {
+ return (1);
+ }
+}
+
+/*
+ ========================================================================
+
+ Routine Description:
+ Compare two memory block
+
+ Arguments:
+ pSrc1 Pointer to first memory address
+ pSrc2 Pointer to second memory address
+
+ Return Value:
+ 0: memory is equal
+ 1: pSrc1 memory is larger
+ 2: pSrc2 memory is larger
+
+ IRQL = DISPATCH_LEVEL
+
+ Note:
+
+ ========================================================================
+*/
+ULONG RTMPCompareMemory(
+ IN PVOID pSrc1,
+ IN PVOID pSrc2,
+ IN ULONG Length)
+{
+ PUCHAR pMem1;
+ PUCHAR pMem2;
+ ULONG Index = 0;
+
+ pMem1 = (PUCHAR) pSrc1;
+ pMem2 = (PUCHAR) pSrc2;
+
+ for (Index = 0; Index < Length; Index++)
+ {
+ if (pMem1[Index] > pMem2[Index])
+ return (1);
+ else if (pMem1[Index] < pMem2[Index])
+ return (2);
+ }
+
+ // Equal
+ return (0);
+}
+
+/*
+ ========================================================================
+
+ Routine Description:
+ Zero out memory block
+
+ Arguments:
+ pSrc1 Pointer to memory address
+ Length Size
+
+ Return Value:
+ None
+
+ IRQL = PASSIVE_LEVEL
+ IRQL = DISPATCH_LEVEL
+
+ Note:
+
+ ========================================================================
+*/
+VOID RTMPZeroMemory(
+ IN PVOID pSrc,
+ IN ULONG Length)
+{
+ PUCHAR pMem;
+ ULONG Index = 0;
+
+ pMem = (PUCHAR) pSrc;
+
+ for (Index = 0; Index < Length; Index++)
+ {
+ pMem[Index] = 0x00;
+ }
+}
+
+VOID RTMPFillMemory(
+ IN PVOID pSrc,
+ IN ULONG Length,
+ IN UCHAR Fill)
+{
+ PUCHAR pMem;
+ ULONG Index = 0;
+
+ pMem = (PUCHAR) pSrc;
+
+ for (Index = 0; Index < Length; Index++)
+ {
+ pMem[Index] = Fill;
+ }
+}
+
+/*
+ ========================================================================
+
+ Routine Description:
+ Copy data from memory block 1 to memory block 2
+
+ Arguments:
+ pDest Pointer to destination memory address
+ pSrc Pointer to source memory address
+ Length Copy size
+
+ Return Value:
+ None
+
+ IRQL = PASSIVE_LEVEL
+ IRQL = DISPATCH_LEVEL
+
+ Note:
+
+ ========================================================================
+*/
+VOID RTMPMoveMemory(
+ OUT PVOID pDest,
+ IN PVOID pSrc,
+ IN ULONG Length)
+{
+ PUCHAR pMem1;
+ PUCHAR pMem2;
+ UINT Index;
+
+ ASSERT((Length==0) || (pDest && pSrc));
+
+ pMem1 = (PUCHAR) pDest;
+ pMem2 = (PUCHAR) pSrc;
+
+ for (Index = 0; Index < Length; Index++)
+ {
+ pMem1[Index] = pMem2[Index];
+ }
+}
+
+/*
+ ========================================================================
+
+ Routine Description:
+ Initialize port configuration structure
+
+ Arguments:
+ Adapter Pointer to our adapter
+
+ Return Value:
+ None
+
+ IRQL = PASSIVE_LEVEL
+
+ Note:
+
+ ========================================================================
+*/
+VOID UserCfgInit(
+ IN PRTMP_ADAPTER pAd)
+{
+// EDCA_PARM DefaultEdcaParm;
+ UINT key_index, bss_index;
+
+ DBGPRINT(RT_DEBUG_TRACE, ("--> UserCfgInit\n"));
+
+ //
+ // part I. intialize common configuration
+ //
+#ifdef RT2870
+ pAd->BulkOutReq = 0;
+
+ pAd->BulkOutComplete = 0;
+ pAd->BulkOutCompleteOther = 0;
+ pAd->BulkOutCompleteCancel = 0;
+ pAd->BulkInReq = 0;
+ pAd->BulkInComplete = 0;
+ pAd->BulkInCompleteFail = 0;
+
+ //pAd->QuickTimerP = 100;
+ //pAd->TurnAggrBulkInCount = 0;
+ pAd->bUsbTxBulkAggre = 0;
+
+ // init as unsed value to ensure driver will set to MCU once.
+ pAd->LedIndicatorStregth = 0xFF;
+
+ pAd->CommonCfg.MaxPktOneTxBulk = 2;
+ pAd->CommonCfg.TxBulkFactor = 1;
+ pAd->CommonCfg.RxBulkFactor =1;
+
+ pAd->CommonCfg.TxPower = 100; //mW
+
+ NdisZeroMemory(&pAd->CommonCfg.IOTestParm, sizeof(pAd->CommonCfg.IOTestParm));
+#endif // RT2870 //
+
+ for(key_index=0; key_index<SHARE_KEY_NUM; key_index++)
+ {
+ for(bss_index = 0; bss_index < MAX_MBSSID_NUM; bss_index++)
+ {
+ pAd->SharedKey[bss_index][key_index].KeyLen = 0;
+ pAd->SharedKey[bss_index][key_index].CipherAlg = CIPHER_NONE;
+ } /* End of for */
+ } /* End of for */
+
+ pAd->EepromAccess = FALSE;
+
+ pAd->Antenna.word = 0;
+ pAd->CommonCfg.BBPCurrentBW = BW_20;
+
+ pAd->LedCntl.word = 0;
+
+ pAd->bAutoTxAgcA = FALSE; // Default is OFF
+ pAd->bAutoTxAgcG = FALSE; // Default is OFF
+ pAd->RfIcType = RFIC_2820;
+
+ // Init timer for reset complete event
+ pAd->CommonCfg.CentralChannel = 1;
+ pAd->bForcePrintTX = FALSE;
+ pAd->bForcePrintRX = FALSE;
+ pAd->bStaFifoTest = FALSE;
+ pAd->bProtectionTest = FALSE;
+ pAd->bHCCATest = FALSE;
+ pAd->bGenOneHCCA = FALSE;
+ pAd->CommonCfg.Dsifs = 10; // in units of usec
+ pAd->CommonCfg.TxPower = 100; //mW
+ pAd->CommonCfg.TxPowerPercentage = 0xffffffff; // AUTO
+ pAd->CommonCfg.TxPowerDefault = 0xffffffff; // AUTO
+ pAd->CommonCfg.TxPreamble = Rt802_11PreambleAuto; // use Long preamble on TX by defaut
+ pAd->CommonCfg.bUseZeroToDisableFragment = FALSE;
+ pAd->CommonCfg.RtsThreshold = 2347;
+ pAd->CommonCfg.FragmentThreshold = 2346;
+ pAd->CommonCfg.UseBGProtection = 0; // 0: AUTO
+ pAd->CommonCfg.bEnableTxBurst = TRUE; //0;
+ pAd->CommonCfg.PhyMode = 0xff; // unknown
+ pAd->CommonCfg.BandState = UNKNOWN_BAND;
+ pAd->CommonCfg.RadarDetect.CSPeriod = 10;
+ pAd->CommonCfg.RadarDetect.CSCount = 0;
+ pAd->CommonCfg.RadarDetect.RDMode = RD_NORMAL_MODE;
+ pAd->CommonCfg.RadarDetect.ChMovingTime = 65;
+ pAd->CommonCfg.RadarDetect.LongPulseRadarTh = 3;
+ pAd->CommonCfg.bAPSDCapable = FALSE;
+ pAd->CommonCfg.bNeedSendTriggerFrame = FALSE;
+ pAd->CommonCfg.TriggerTimerCount = 0;
+ pAd->CommonCfg.bAPSDForcePowerSave = FALSE;
+ pAd->CommonCfg.bCountryFlag = FALSE;
+ pAd->CommonCfg.TxStream = 0;
+ pAd->CommonCfg.RxStream = 0;
+
+ NdisZeroMemory(&pAd->BeaconTxWI, sizeof(pAd->BeaconTxWI));
+
+#ifdef DOT11_N_SUPPORT
+ NdisZeroMemory(&pAd->CommonCfg.HtCapability, sizeof(pAd->CommonCfg.HtCapability));
+ pAd->HTCEnable = FALSE;
+ pAd->bBroadComHT = FALSE;
+ pAd->CommonCfg.bRdg = FALSE;
+
+#ifdef DOT11N_DRAFT3
+ pAd->CommonCfg.Dot11OBssScanPassiveDwell = dot11OBSSScanPassiveDwell; // Unit : TU. 5~1000
+ pAd->CommonCfg.Dot11OBssScanActiveDwell = dot11OBSSScanActiveDwell; // Unit : TU. 10~1000
+ pAd->CommonCfg.Dot11BssWidthTriggerScanInt = dot11BSSWidthTriggerScanInterval; // Unit : Second
+ pAd->CommonCfg.Dot11OBssScanPassiveTotalPerChannel = dot11OBSSScanPassiveTotalPerChannel; // Unit : TU. 200~10000
+ pAd->CommonCfg.Dot11OBssScanActiveTotalPerChannel = dot11OBSSScanActiveTotalPerChannel; // Unit : TU. 20~10000
+ pAd->CommonCfg.Dot11BssWidthChanTranDelayFactor = dot11BSSWidthChannelTransactionDelayFactor;
+ pAd->CommonCfg.Dot11OBssScanActivityThre = dot11BSSScanActivityThreshold; // Unit : percentage
+ pAd->CommonCfg.Dot11BssWidthChanTranDelay = (pAd->CommonCfg.Dot11BssWidthTriggerScanInt * pAd->CommonCfg.Dot11BssWidthChanTranDelayFactor);
+#endif // DOT11N_DRAFT3 //
+
+ NdisZeroMemory(&pAd->CommonCfg.AddHTInfo, sizeof(pAd->CommonCfg.AddHTInfo));
+ pAd->CommonCfg.BACapability.field.MMPSmode = MMPS_ENABLE;
+ pAd->CommonCfg.BACapability.field.MpduDensity = 0;
+ pAd->CommonCfg.BACapability.field.Policy = IMMED_BA;
+ pAd->CommonCfg.BACapability.field.RxBAWinLimit = 64; //32;
+ pAd->CommonCfg.BACapability.field.TxBAWinLimit = 64; //32;
+ DBGPRINT(RT_DEBUG_TRACE, ("--> UserCfgInit. BACapability = 0x%x\n", pAd->CommonCfg.BACapability.word));
+
+ pAd->CommonCfg.BACapability.field.AutoBA = FALSE;
+ BATableInit(pAd, &pAd->BATable);
+
+ pAd->CommonCfg.bExtChannelSwitchAnnouncement = 1;
+ pAd->CommonCfg.bHTProtect = 1;
+ pAd->CommonCfg.bMIMOPSEnable = TRUE;
+ pAd->CommonCfg.bBADecline = FALSE;
+ pAd->CommonCfg.bDisableReordering = FALSE;
+
+ pAd->CommonCfg.TxBASize = 7;
+
+ pAd->CommonCfg.REGBACapability.word = pAd->CommonCfg.BACapability.word;
+#endif // DOT11_N_SUPPORT //
+
+ //pAd->CommonCfg.HTPhyMode.field.BW = BW_20;
+ //pAd->CommonCfg.HTPhyMode.field.MCS = MCS_AUTO;
+ //pAd->CommonCfg.HTPhyMode.field.ShortGI = GI_800;
+ //pAd->CommonCfg.HTPhyMode.field.STBC = STBC_NONE;
+ pAd->CommonCfg.TxRate = RATE_6;
+
+ pAd->CommonCfg.MlmeTransmit.field.MCS = MCS_RATE_6;
+ pAd->CommonCfg.MlmeTransmit.field.BW = BW_20;
+ pAd->CommonCfg.MlmeTransmit.field.MODE = MODE_OFDM;
+
+ pAd->CommonCfg.BeaconPeriod = 100; // in mSec
+
+ //
+ // part II. intialize STA specific configuration
+ //
+#ifdef CONFIG_STA_SUPPORT
+ IF_DEV_CONFIG_OPMODE_ON_STA(pAd)
+ {
+ RX_FILTER_SET_FLAG(pAd, fRX_FILTER_ACCEPT_DIRECT);
+ RX_FILTER_CLEAR_FLAG(pAd, fRX_FILTER_ACCEPT_MULTICAST);
+ RX_FILTER_SET_FLAG(pAd, fRX_FILTER_ACCEPT_BROADCAST);
+ RX_FILTER_SET_FLAG(pAd, fRX_FILTER_ACCEPT_ALL_MULTICAST);
+
+ pAd->StaCfg.Psm = PWR_ACTIVE;
+
+ pAd->StaCfg.OrigWepStatus = Ndis802_11EncryptionDisabled;
+ pAd->StaCfg.PairCipher = Ndis802_11EncryptionDisabled;
+ pAd->StaCfg.GroupCipher = Ndis802_11EncryptionDisabled;
+ pAd->StaCfg.bMixCipher = FALSE;
+ pAd->StaCfg.DefaultKeyId = 0;
+
+ // 802.1x port control
+ pAd->StaCfg.PrivacyFilter = Ndis802_11PrivFilter8021xWEP;
+ pAd->StaCfg.PortSecured = WPA_802_1X_PORT_NOT_SECURED;
+ pAd->StaCfg.LastMicErrorTime = 0;
+ pAd->StaCfg.MicErrCnt = 0;
+ pAd->StaCfg.bBlockAssoc = FALSE;
+ pAd->StaCfg.WpaState = SS_NOTUSE;
+
+ pAd->CommonCfg.NdisRadioStateOff = FALSE; // New to support microsoft disable radio with OID command
+
+ pAd->StaCfg.RssiTrigger = 0;
+ NdisZeroMemory(&pAd->StaCfg.RssiSample, sizeof(RSSI_SAMPLE));
+ pAd->StaCfg.RssiTriggerMode = RSSI_TRIGGERED_UPON_BELOW_THRESHOLD;
+ pAd->StaCfg.AtimWin = 0;
+ pAd->StaCfg.DefaultListenCount = 3;//default listen count;
+ pAd->StaCfg.BssType = BSS_INFRA; // BSS_INFRA or BSS_ADHOC or BSS_MONITOR
+ pAd->StaCfg.bScanReqIsFromWebUI = FALSE;
+ OPSTATUS_CLEAR_FLAG(pAd, fOP_STATUS_DOZE);
+ OPSTATUS_CLEAR_FLAG(pAd, fOP_STATUS_WAKEUP_NOW);
+
+ pAd->StaCfg.bAutoTxRateSwitch = TRUE;
+ pAd->StaCfg.DesiredTransmitSetting.field.MCS = MCS_AUTO;
+ }
+
+#ifdef EXT_BUILD_CHANNEL_LIST
+ pAd->StaCfg.IEEE80211dClientMode = Rt802_11_D_None;
+#endif // EXT_BUILD_CHANNEL_LIST //
+#endif // CONFIG_STA_SUPPORT //
+
+ // global variables mXXXX used in MAC protocol state machines
+ OPSTATUS_SET_FLAG(pAd, fOP_STATUS_RECEIVE_DTIM);
+ OPSTATUS_CLEAR_FLAG(pAd, fOP_STATUS_ADHOC_ON);
+ OPSTATUS_CLEAR_FLAG(pAd, fOP_STATUS_INFRA_ON);
+
+ // PHY specification
+ pAd->CommonCfg.PhyMode = PHY_11BG_MIXED; // default PHY mode
+ OPSTATUS_CLEAR_FLAG(pAd, fOP_STATUS_SHORT_PREAMBLE_INUSED); // CCK use LONG preamble
+
+#ifdef CONFIG_STA_SUPPORT
+ IF_DEV_CONFIG_OPMODE_ON_STA(pAd)
+ {
+ // user desired power mode
+ pAd->StaCfg.WindowsPowerMode = Ndis802_11PowerModeCAM;
+ pAd->StaCfg.WindowsBatteryPowerMode = Ndis802_11PowerModeCAM;
+ pAd->StaCfg.bWindowsACCAMEnable = FALSE;
+
+#ifdef LEAP_SUPPORT
+ // CCX v1.0 releated init value
+ RTMPInitTimer(pAd, &pAd->StaCfg.LeapAuthTimer, GET_TIMER_FUNCTION(LeapAuthTimeout), pAd, FALSE);
+ pAd->StaCfg.LeapAuthMode = CISCO_AuthModeLEAPNone;
+ pAd->StaCfg.bCkipOn = FALSE;
+#endif // LEAP_SUPPORT //
+
+ RTMPInitTimer(pAd, &pAd->StaCfg.StaQuickResponeForRateUpTimer, GET_TIMER_FUNCTION(StaQuickResponeForRateUpExec), pAd, FALSE);
+ pAd->StaCfg.StaQuickResponeForRateUpTimerRunning = FALSE;
+
+ // Patch for Ndtest
+ pAd->StaCfg.ScanCnt = 0;
+
+ // CCX 2.0 control flag init
+ pAd->StaCfg.CCXEnable = FALSE;
+ pAd->StaCfg.CCXReqType = MSRN_TYPE_UNUSED;
+ pAd->StaCfg.CCXQosECWMin = 4;
+ pAd->StaCfg.CCXQosECWMax = 10;
+
+ pAd->StaCfg.bHwRadio = TRUE; // Default Hardware Radio status is On
+ pAd->StaCfg.bSwRadio = TRUE; // Default Software Radio status is On
+ pAd->StaCfg.bRadio = TRUE; // bHwRadio && bSwRadio
+ pAd->StaCfg.bHardwareRadio = FALSE; // Default is OFF
+ pAd->StaCfg.bShowHiddenSSID = FALSE; // Default no show
+
+ // Nitro mode control
+ pAd->StaCfg.bAutoReconnect = TRUE;
+
+ // Save the init time as last scan time, the system should do scan after 2 seconds.
+ // This patch is for driver wake up from standby mode, system will do scan right away.
+ pAd->StaCfg.LastScanTime = 0;
+ NdisZeroMemory(pAd->nickname, IW_ESSID_MAX_SIZE+1);
+ sprintf(pAd->nickname, "%s", STA_NIC_DEVICE_NAME);
+ RTMPInitTimer(pAd, &pAd->StaCfg.WpaDisassocAndBlockAssocTimer, GET_TIMER_FUNCTION(WpaDisassocApAndBlockAssoc), pAd, FALSE);
+#ifdef WPA_SUPPLICANT_SUPPORT
+ pAd->StaCfg.IEEE8021X = FALSE;
+ pAd->StaCfg.IEEE8021x_required_keys = FALSE;
+ pAd->StaCfg.WpaSupplicantUP = WPA_SUPPLICANT_DISABLE;
+#ifdef NATIVE_WPA_SUPPLICANT_SUPPORT
+ pAd->StaCfg.WpaSupplicantUP = WPA_SUPPLICANT_ENABLE;
+#endif // NATIVE_WPA_SUPPLICANT_SUPPORT //
+#endif // WPA_SUPPLICANT_SUPPORT //
+
+ }
+#endif // CONFIG_STA_SUPPORT //
+
+ // Default for extra information is not valid
+ pAd->ExtraInfo = EXTRA_INFO_CLEAR;
+
+ // Default Config change flag
+ pAd->bConfigChanged = FALSE;
+
+ //
+ // part III. AP configurations
+ //
+
+
+ //
+ // part IV. others
+ //
+ // dynamic BBP R66:sensibity tuning to overcome background noise
+ pAd->BbpTuning.bEnable = TRUE;
+ pAd->BbpTuning.FalseCcaLowerThreshold = 100;
+ pAd->BbpTuning.FalseCcaUpperThreshold = 512;
+ pAd->BbpTuning.R66Delta = 4;
+ pAd->Mlme.bEnableAutoAntennaCheck = TRUE;
+
+ //
+ // Also initial R66CurrentValue, RTUSBResumeMsduTransmission might use this value.
+ // if not initial this value, the default value will be 0.
+ //
+ pAd->BbpTuning.R66CurrentValue = 0x38;
+
+ pAd->Bbp94 = BBPR94_DEFAULT;
+ pAd->BbpForCCK = FALSE;
+
+ // Default is FALSE for test bit 1
+ //pAd->bTest1 = FALSE;
+
+ // initialize MAC table and allocate spin lock
+ NdisZeroMemory(&pAd->MacTab, sizeof(MAC_TABLE));
+ InitializeQueueHeader(&pAd->MacTab.McastPsQueue);
+ NdisAllocateSpinLock(&pAd->MacTabLock);
+
+ //RTMPInitTimer(pAd, &pAd->RECBATimer, RECBATimerTimeout, pAd, TRUE);
+ //RTMPSetTimer(&pAd->RECBATimer, REORDER_EXEC_INTV);
+
+#ifdef RALINK_ATE
+ NdisZeroMemory(&pAd->ate, sizeof(ATE_INFO));
+ pAd->ate.Mode = ATE_STOP;
+ pAd->ate.TxCount = 200;/* to exceed TX_RING_SIZE ... */
+ pAd->ate.TxLength = 1024;
+ pAd->ate.TxWI.ShortGI = 0;// LONG GI : 800 ns
+ pAd->ate.TxWI.PHYMODE = MODE_CCK;
+ pAd->ate.TxWI.MCS = 3;
+ pAd->ate.TxWI.BW = BW_20;
+ pAd->ate.Channel = 1;
+ pAd->ate.QID = QID_AC_BE;
+ pAd->ate.Addr1[0] = 0x00;
+ pAd->ate.Addr1[1] = 0x11;
+ pAd->ate.Addr1[2] = 0x22;
+ pAd->ate.Addr1[3] = 0xAA;
+ pAd->ate.Addr1[4] = 0xBB;
+ pAd->ate.Addr1[5] = 0xCC;
+ NdisMoveMemory(pAd->ate.Addr2, pAd->ate.Addr1, ETH_LENGTH_OF_ADDRESS);
+ NdisMoveMemory(pAd->ate.Addr3, pAd->ate.Addr1, ETH_LENGTH_OF_ADDRESS);
+ pAd->ate.bRxFer = 0;
+ pAd->ate.bQATxStart = FALSE;
+ pAd->ate.bQARxStart = FALSE;
+#ifdef RALINK_28xx_QA
+ //pAd->ate.Repeat = 0;
+ pAd->ate.TxStatus = 0;
+ pAd->ate.AtePid = 0;
+#endif // RALINK_28xx_QA //
+#endif // RALINK_ATE //
+
+
+ pAd->CommonCfg.bWiFiTest = FALSE;
+
+
+ DBGPRINT(RT_DEBUG_TRACE, ("<-- UserCfgInit\n"));
+}
+
+// IRQL = PASSIVE_LEVEL
+UCHAR BtoH(char ch)
+{
+ if (ch >= '0' && ch <= '9') return (ch - '0'); // Handle numerals
+ if (ch >= 'A' && ch <= 'F') return (ch - 'A' + 0xA); // Handle capitol hex digits
+ if (ch >= 'a' && ch <= 'f') return (ch - 'a' + 0xA); // Handle small hex digits
+ return(255);
+}
+
+//
+// FUNCTION: AtoH(char *, UCHAR *, int)
+//
+// PURPOSE: Converts ascii string to network order hex
+//
+// PARAMETERS:
+// src - pointer to input ascii string
+// dest - pointer to output hex
+// destlen - size of dest
+//
+// COMMENTS:
+//
+// 2 ascii bytes make a hex byte so must put 1st ascii byte of pair
+// into upper nibble and 2nd ascii byte of pair into lower nibble.
+//
+// IRQL = PASSIVE_LEVEL
+
+void AtoH(char * src, UCHAR * dest, int destlen)
+{
+ char * srcptr;
+ PUCHAR destTemp;
+
+ srcptr = src;
+ destTemp = (PUCHAR) dest;
+
+ while(destlen--)
+ {
+ *destTemp = BtoH(*srcptr++) << 4; // Put 1st ascii byte in upper nibble.
+ *destTemp += BtoH(*srcptr++); // Add 2nd ascii byte to above.
+ destTemp++;
+ }
+}
+
+VOID RTMPPatchMacBbpBug(
+ IN PRTMP_ADAPTER pAd)
+{
+ ULONG Index;
+
+ // Initialize BBP register to default value
+ for (Index = 0; Index < NUM_BBP_REG_PARMS; Index++)
+ {
+ RTMP_BBP_IO_WRITE8_BY_REG_ID(pAd, BBPRegTable[Index].Register, (UCHAR)BBPRegTable[Index].Value);
+ }
+
+ // Initialize RF register to default value
+ AsicSwitchChannel(pAd, pAd->CommonCfg.Channel, FALSE);
+ AsicLockChannel(pAd, pAd->CommonCfg.Channel);
+
+ // Re-init BBP register from EEPROM value
+ NICInitAsicFromEEPROM(pAd);
+}
+
+/*
+ ========================================================================
+
+ Routine Description:
+ Init timer objects
+
+ Arguments:
+ pAd Pointer to our adapter
+ pTimer Timer structure
+ pTimerFunc Function to execute when timer expired
+ Repeat Ture for period timer
+
+ Return Value:
+ None
+
+ Note:
+
+ ========================================================================
+*/
+VOID RTMPInitTimer(
+ IN PRTMP_ADAPTER pAd,
+ IN PRALINK_TIMER_STRUCT pTimer,
+ IN PVOID pTimerFunc,
+ IN PVOID pData,
+ IN BOOLEAN Repeat)
+{
+ //
+ // Set Valid to TRUE for later used.
+ // It will crash if we cancel a timer or set a timer
+ // that we haven't initialize before.
+ //
+ pTimer->Valid = TRUE;
+
+ pTimer->PeriodicType = Repeat;
+ pTimer->State = FALSE;
+ pTimer->cookie = (ULONG) pData;
+
+#ifdef RT2870
+ pTimer->pAd = pAd;
+#endif // RT2870 //
+
+ RTMP_OS_Init_Timer(pAd, &pTimer->TimerObj, pTimerFunc, (PVOID) pTimer);
+}
+
+/*
+ ========================================================================
+
+ Routine Description:
+ Init timer objects
+
+ Arguments:
+ pTimer Timer structure
+ Value Timer value in milliseconds
+
+ Return Value:
+ None
+
+ Note:
+ To use this routine, must call RTMPInitTimer before.
+
+ ========================================================================
+*/
+VOID RTMPSetTimer(
+ IN PRALINK_TIMER_STRUCT pTimer,
+ IN ULONG Value)
+{
+ if (pTimer->Valid)
+ {
+ pTimer->TimerValue = Value;
+ pTimer->State = FALSE;
+ if (pTimer->PeriodicType == TRUE)
+ {
+ pTimer->Repeat = TRUE;
+ RTMP_SetPeriodicTimer(&pTimer->TimerObj, Value);
+ }
+ else
+ {
+ pTimer->Repeat = FALSE;
+ RTMP_OS_Add_Timer(&pTimer->TimerObj, Value);
+ }
+ }
+ else
+ {
+ DBGPRINT_ERR(("RTMPSetTimer failed, Timer hasn't been initialize!\n"));
+ }
+}
+
+
+/*
+ ========================================================================
+
+ Routine Description:
+ Init timer objects
+
+ Arguments:
+ pTimer Timer structure
+ Value Timer value in milliseconds
+
+ Return Value:
+ None
+
+ Note:
+ To use this routine, must call RTMPInitTimer before.
+
+ ========================================================================
+*/
+VOID RTMPModTimer(
+ IN PRALINK_TIMER_STRUCT pTimer,
+ IN ULONG Value)
+{
+ BOOLEAN Cancel;
+
+ if (pTimer->Valid)
+ {
+ pTimer->TimerValue = Value;
+ pTimer->State = FALSE;
+ if (pTimer->PeriodicType == TRUE)
+ {
+ RTMPCancelTimer(pTimer, &Cancel);
+ RTMPSetTimer(pTimer, Value);
+ }
+ else
+ {
+ RTMP_OS_Mod_Timer(&pTimer->TimerObj, Value);
+ }
+ }
+ else
+ {
+ DBGPRINT_ERR(("RTMPModTimer failed, Timer hasn't been initialize!\n"));
+ }
+}
+
+/*
+ ========================================================================
+
+ Routine Description:
+ Cancel timer objects
+
+ Arguments:
+ Adapter Pointer to our adapter
+
+ Return Value:
+ None
+
+ IRQL = PASSIVE_LEVEL
+ IRQL = DISPATCH_LEVEL
+
+ Note:
+ 1.) To use this routine, must call RTMPInitTimer before.
+ 2.) Reset NIC to initial state AS IS system boot up time.
+
+ ========================================================================
+*/
+VOID RTMPCancelTimer(
+ IN PRALINK_TIMER_STRUCT pTimer,
+ OUT BOOLEAN *pCancelled)
+{
+ if (pTimer->Valid)
+ {
+ if (pTimer->State == FALSE)
+ pTimer->Repeat = FALSE;
+ RTMP_OS_Del_Timer(&pTimer->TimerObj, pCancelled);
+
+ if (*pCancelled == TRUE)
+ pTimer->State = TRUE;
+
+#ifdef RT2870
+ // We need to go-through the TimerQ to findout this timer handler and remove it if
+ // it's still waiting for execution.
+
+ RT2870_TimerQ_Remove(pTimer->pAd, pTimer);
+#endif // RT2870 //
+ }
+ else
+ {
+ //
+ // NdisMCancelTimer just canced the timer and not mean release the timer.
+ // And don't set the "Valid" to False. So that we can use this timer again.
+ //
+ DBGPRINT_ERR(("RTMPCancelTimer failed, Timer hasn't been initialize!\n"));
+ }
+}
+
+/*
+ ========================================================================
+
+ Routine Description:
+ Set LED Status
+
+ Arguments:
+ pAd Pointer to our adapter
+ Status LED Status
+
+ Return Value:
+ None
+
+ IRQL = PASSIVE_LEVEL
+ IRQL = DISPATCH_LEVEL
+
+ Note:
+
+ ========================================================================
+*/
+VOID RTMPSetLED(
+ IN PRTMP_ADAPTER pAd,
+ IN UCHAR Status)
+{
+ //ULONG data;
+ UCHAR HighByte = 0;
+ UCHAR LowByte;
+
+// In ATE mode of RT2860 AP/STA, we have erased 8051 firmware.
+// So LED mode is not supported when ATE is running.
+#ifdef RALINK_ATE
+ if (ATE_ON(pAd))
+ return;
+#endif // RALINK_ATE //
+
+ LowByte = pAd->LedCntl.field.LedMode&0x7f;
+ switch (Status)
+ {
+ case LED_LINK_DOWN:
+ HighByte = 0x20;
+ AsicSendCommandToMcu(pAd, 0x50, 0xff, LowByte, HighByte);
+ pAd->LedIndicatorStregth = 0;
+ break;
+ case LED_LINK_UP:
+ if (pAd->CommonCfg.Channel > 14)
+ HighByte = 0xa0;
+ else
+ HighByte = 0x60;
+ AsicSendCommandToMcu(pAd, 0x50, 0xff, LowByte, HighByte);
+ break;
+ case LED_RADIO_ON:
+ HighByte = 0x20;
+ AsicSendCommandToMcu(pAd, 0x50, 0xff, LowByte, HighByte);
+ break;
+ case LED_HALT:
+ LowByte = 0; // Driver sets MAC register and MAC controls LED
+ case LED_RADIO_OFF:
+ HighByte = 0;
+ AsicSendCommandToMcu(pAd, 0x50, 0xff, LowByte, HighByte);
+ break;
+ case LED_WPS:
+ HighByte = 0x10;
+ AsicSendCommandToMcu(pAd, 0x50, 0xff, LowByte, HighByte);
+ break;
+ case LED_ON_SITE_SURVEY:
+ HighByte = 0x08;
+ AsicSendCommandToMcu(pAd, 0x50, 0xff, LowByte, HighByte);
+ break;
+ case LED_POWER_UP:
+ HighByte = 0x04;
+ AsicSendCommandToMcu(pAd, 0x50, 0xff, LowByte, HighByte);
+ break;
+ default:
+ DBGPRINT(RT_DEBUG_WARN, ("RTMPSetLED::Unknown Status %d\n", Status));
+ break;
+ }
+
+ //
+ // Keep LED status for LED SiteSurvey mode.
+ // After SiteSurvey, we will set the LED mode to previous status.
+ //
+ if ((Status != LED_ON_SITE_SURVEY) && (Status != LED_POWER_UP))
+ pAd->LedStatus = Status;
+
+ DBGPRINT(RT_DEBUG_TRACE, ("RTMPSetLED::Mode=%d,HighByte=0x%02x,LowByte=0x%02x\n", pAd->LedCntl.field.LedMode, HighByte, LowByte));
+}
+
+/*
+ ========================================================================
+
+ Routine Description:
+ Set LED Signal Stregth
+
+ Arguments:
+ pAd Pointer to our adapter
+ Dbm Signal Stregth
+
+ Return Value:
+ None
+
+ IRQL = PASSIVE_LEVEL
+
+ Note:
+ Can be run on any IRQL level.
+
+ According to Microsoft Zero Config Wireless Signal Stregth definition as belows.
+ <= -90 No Signal
+ <= -81 Very Low
+ <= -71 Low
+ <= -67 Good
+ <= -57 Very Good
+ > -57 Excellent
+ ========================================================================
+*/
+VOID RTMPSetSignalLED(
+ IN PRTMP_ADAPTER pAd,
+ IN NDIS_802_11_RSSI Dbm)
+{
+ UCHAR nLed = 0;
+
+ //
+ // if not Signal Stregth, then do nothing.
+ //
+ if (pAd->LedCntl.field.LedMode != LED_MODE_SIGNAL_STREGTH)
+ {
+ return;
+ }
+
+ if (Dbm <= -90)
+ nLed = 0;
+ else if (Dbm <= -81)
+ nLed = 1;
+ else if (Dbm <= -71)
+ nLed = 3;
+ else if (Dbm <= -67)
+ nLed = 7;
+ else if (Dbm <= -57)
+ nLed = 15;
+ else
+ nLed = 31;
+
+ //
+ // Update Signal Stregth to firmware if changed.
+ //
+ if (pAd->LedIndicatorStregth != nLed)
+ {
+ AsicSendCommandToMcu(pAd, 0x51, 0xff, nLed, pAd->LedCntl.field.Polarity);
+ pAd->LedIndicatorStregth = nLed;
+ }
+}
+
+/*
+ ========================================================================
+
+ Routine Description:
+ Enable RX
+
+ Arguments:
+ pAd Pointer to our adapter
+
+ Return Value:
+ None
+
+ IRQL <= DISPATCH_LEVEL
+
+ Note:
+ Before Enable RX, make sure you have enabled Interrupt.
+ ========================================================================
+*/
+VOID RTMPEnableRxTx(
+ IN PRTMP_ADAPTER pAd)
+{
+// WPDMA_GLO_CFG_STRUC GloCfg;
+// ULONG i = 0;
+
+ DBGPRINT(RT_DEBUG_TRACE, ("==> RTMPEnableRxTx\n"));
+
+ // Enable Rx DMA.
+ RT28XXDMAEnable(pAd);
+
+ // enable RX of MAC block
+ if (pAd->OpMode == OPMODE_AP)
+ {
+ UINT32 rx_filter_flag = APNORMAL;
+
+
+ RTMP_IO_WRITE32(pAd, RX_FILTR_CFG, rx_filter_flag); // enable RX of DMA block
+ }
+ else
+ {
+ RTMP_IO_WRITE32(pAd, RX_FILTR_CFG, STANORMAL); // Staion not drop control frame will fail WiFi Certification.
+ }
+
+ RTMP_IO_WRITE32(pAd, MAC_SYS_CTRL, 0xc);
+ DBGPRINT(RT_DEBUG_TRACE, ("<== RTMPEnableRxTx\n"));
+}
+
+
Copyright © 1996 – 2023 Jason A. Donenfeld. All Rights Reverse Engineered.