diff options
Diffstat (limited to 'drivers/staging/rt3070/common/eeprom.c')
-rw-r--r-- | drivers/staging/rt3070/common/eeprom.c | 1498 |
1 files changed, 1498 insertions, 0 deletions
diff --git a/drivers/staging/rt3070/common/eeprom.c b/drivers/staging/rt3070/common/eeprom.c new file mode 100644 index 000000000000..63e1dc14d151 --- /dev/null +++ b/drivers/staging/rt3070/common/eeprom.c @@ -0,0 +1,1498 @@ +/* + ************************************************************************* + * 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: + eeprom.c + + Abstract: + + Revision History: + Who When What + -------- ---------- ---------------------------------------------- + Name Date Modification logs +*/ +#include "../rt_config.h" + +// IRQL = PASSIVE_LEVEL +VOID RaiseClock( + IN PRTMP_ADAPTER pAd, + IN UINT32 *x) +{ + *x = *x | EESK; + RTMP_IO_WRITE32(pAd, E2PROM_CSR, *x); + RTMPusecDelay(1); // Max frequency = 1MHz in Spec. definition +} + +// IRQL = PASSIVE_LEVEL +VOID LowerClock( + IN PRTMP_ADAPTER pAd, + IN UINT32 *x) +{ + *x = *x & ~EESK; + RTMP_IO_WRITE32(pAd, E2PROM_CSR, *x); + RTMPusecDelay(1); +} + +// IRQL = PASSIVE_LEVEL +USHORT ShiftInBits( + IN PRTMP_ADAPTER pAd) +{ + UINT32 x,i; + USHORT data=0; + + RTMP_IO_READ32(pAd, E2PROM_CSR, &x); + + x &= ~( EEDO | EEDI); + + for(i=0; i<16; i++) + { + data = data << 1; + RaiseClock(pAd, &x); + + RTMP_IO_READ32(pAd, E2PROM_CSR, &x); + LowerClock(pAd, &x); //prevent read failed + + x &= ~(EEDI); + if(x & EEDO) + data |= 1; + } + + return data; +} + +// IRQL = PASSIVE_LEVEL +VOID ShiftOutBits( + IN PRTMP_ADAPTER pAd, + IN USHORT data, + IN USHORT count) +{ + UINT32 x,mask; + + mask = 0x01 << (count - 1); + RTMP_IO_READ32(pAd, E2PROM_CSR, &x); + + x &= ~(EEDO | EEDI); + + do + { + x &= ~EEDI; + if(data & mask) x |= EEDI; + + RTMP_IO_WRITE32(pAd, E2PROM_CSR, x); + + RaiseClock(pAd, &x); + LowerClock(pAd, &x); + + mask = mask >> 1; + } while(mask); + + x &= ~EEDI; + RTMP_IO_WRITE32(pAd, E2PROM_CSR, x); +} + +// IRQL = PASSIVE_LEVEL +VOID EEpromCleanup( + IN PRTMP_ADAPTER pAd) +{ + UINT32 x; + + RTMP_IO_READ32(pAd, E2PROM_CSR, &x); + + x &= ~(EECS | EEDI); + RTMP_IO_WRITE32(pAd, E2PROM_CSR, x); + + RaiseClock(pAd, &x); + LowerClock(pAd, &x); +} + +VOID EWEN( + IN PRTMP_ADAPTER pAd) +{ + UINT32 x; + + // reset bits and set EECS + RTMP_IO_READ32(pAd, E2PROM_CSR, &x); + x &= ~(EEDI | EEDO | EESK); + x |= EECS; + RTMP_IO_WRITE32(pAd, E2PROM_CSR, x); + + // kick a pulse + RaiseClock(pAd, &x); + LowerClock(pAd, &x); + + // output the read_opcode and six pulse in that order + ShiftOutBits(pAd, EEPROM_EWEN_OPCODE, 5); + ShiftOutBits(pAd, 0, 6); + + EEpromCleanup(pAd); +} + +VOID EWDS( + IN PRTMP_ADAPTER pAd) +{ + UINT32 x; + + // reset bits and set EECS + RTMP_IO_READ32(pAd, E2PROM_CSR, &x); + x &= ~(EEDI | EEDO | EESK); + x |= EECS; + RTMP_IO_WRITE32(pAd, E2PROM_CSR, x); + + // kick a pulse + RaiseClock(pAd, &x); + LowerClock(pAd, &x); + + // output the read_opcode and six pulse in that order + ShiftOutBits(pAd, EEPROM_EWDS_OPCODE, 5); + ShiftOutBits(pAd, 0, 6); + + EEpromCleanup(pAd); +} + +// IRQL = PASSIVE_LEVEL +USHORT RTMP_EEPROM_READ16( + IN PRTMP_ADAPTER pAd, + IN USHORT Offset) +{ + UINT32 x; + USHORT data; + + if (pAd->NicConfig2.field.AntDiversity) + { + pAd->EepromAccess = TRUE; + } +//2008/09/11:KH add to support efuse<-- +//2008/09/11:KH add to support efuse--> +{ + Offset /= 2; + // reset bits and set EECS + RTMP_IO_READ32(pAd, E2PROM_CSR, &x); + x &= ~(EEDI | EEDO | EESK); + x |= EECS; + RTMP_IO_WRITE32(pAd, E2PROM_CSR, x); + + // patch can not access e-Fuse issue + if (!IS_RT3090(pAd)) + { + // kick a pulse + RaiseClock(pAd, &x); + LowerClock(pAd, &x); + } + + // output the read_opcode and register number in that order + ShiftOutBits(pAd, EEPROM_READ_OPCODE, 3); + ShiftOutBits(pAd, Offset, pAd->EEPROMAddressNum); + + // Now read the data (16 bits) in from the selected EEPROM word + data = ShiftInBits(pAd); + + EEpromCleanup(pAd); + + // Antenna and EEPROM access are both using EESK pin, + // Therefor we should avoid accessing EESK at the same time + // Then restore antenna after EEPROM access + if ((pAd->NicConfig2.field.AntDiversity) || (pAd->RfIcType == RFIC_3020)) + { + pAd->EepromAccess = FALSE; + AsicSetRxAnt(pAd, pAd->RxAnt.Pair1PrimaryRxAnt); + } +} + return data; +} //ReadEEprom + +VOID RTMP_EEPROM_WRITE16( + IN PRTMP_ADAPTER pAd, + IN USHORT Offset, + IN USHORT Data) +{ + UINT32 x; + + if (pAd->NicConfig2.field.AntDiversity) + { + pAd->EepromAccess = TRUE; + } + //2008/09/11:KH add to support efuse<-- +//2008/09/11:KH add to support efuse--> + { + Offset /= 2; + + EWEN(pAd); + + // reset bits and set EECS + RTMP_IO_READ32(pAd, E2PROM_CSR, &x); + x &= ~(EEDI | EEDO | EESK); + x |= EECS; + RTMP_IO_WRITE32(pAd, E2PROM_CSR, x); + + // patch can not access e-Fuse issue + if (!IS_RT3090(pAd)) + { + // kick a pulse + RaiseClock(pAd, &x); + LowerClock(pAd, &x); + } + + // output the read_opcode ,register number and data in that order + ShiftOutBits(pAd, EEPROM_WRITE_OPCODE, 3); + ShiftOutBits(pAd, Offset, pAd->EEPROMAddressNum); + ShiftOutBits(pAd, Data, 16); // 16-bit access + + // read DO status + RTMP_IO_READ32(pAd, E2PROM_CSR, &x); + + EEpromCleanup(pAd); + + RTMPusecDelay(10000); //delay for twp(MAX)=10ms + + EWDS(pAd); + + EEpromCleanup(pAd); + + // Antenna and EEPROM access are both using EESK pin, + // Therefor we should avoid accessing EESK at the same time + // Then restore antenna after EEPROM access + if ((pAd->NicConfig2.field.AntDiversity) || (pAd->RfIcType == RFIC_3020)) + { + pAd->EepromAccess = FALSE; + AsicSetRxAnt(pAd, pAd->RxAnt.Pair1PrimaryRxAnt); + } +} +} + +//2008/09/11:KH add to support efuse<-- +#ifdef RT30xx +/* + ======================================================================== + + Routine Description: + + Arguments: + + Return Value: + + IRQL = + + Note: + + ======================================================================== +*/ +UCHAR eFuseReadRegisters( + IN PRTMP_ADAPTER pAd, + IN USHORT Offset, + IN USHORT Length, + OUT USHORT* pData) +{ + EFUSE_CTRL_STRUC eFuseCtrlStruc; + int i; + USHORT efuseDataOffset; + UINT32 data; + + RTMP_IO_READ32(pAd, EFUSE_CTRL, (PUINT32) &eFuseCtrlStruc); + + //Step0. Write 10-bit of address to EFSROM_AIN (0x580, bit25:bit16). The address must be 16-byte alignment. + //Use the eeprom logical address and covert to address to block number + eFuseCtrlStruc.field.EFSROM_AIN = Offset & 0xfff0; + + //Step1. Write EFSROM_MODE (0x580, bit7:bit6) to 0. + eFuseCtrlStruc.field.EFSROM_MODE = 0; + + //Step2. Write EFSROM_KICK (0x580, bit30) to 1 to kick-off physical read procedure. + eFuseCtrlStruc.field.EFSROM_KICK = 1; + + NdisMoveMemory(&data, &eFuseCtrlStruc, 4); + RTMP_IO_WRITE32(pAd, EFUSE_CTRL, data); + + //Step3. Polling EFSROM_KICK(0x580, bit30) until it become 0 again. + i = 0; + while(i < 100) + { + //rtmp.HwMemoryReadDword(EFUSE_CTRL, (DWORD *) &eFuseCtrlStruc, 4); + RTMP_IO_READ32(pAd, EFUSE_CTRL, (PUINT32) &eFuseCtrlStruc); + if(eFuseCtrlStruc.field.EFSROM_KICK == 0) + { + break; + } + RTMPusecDelay(2); + i++; + } + + //if EFSROM_AOUT is not found in physical address, write 0xffff + if (eFuseCtrlStruc.field.EFSROM_AOUT == 0x3f) + { + for(i=0; i<Length/2; i++) + *(pData+2*i) = 0xffff; + } + else + { + //Step4. Read 16-byte of data from EFUSE_DATA0-3 (0x590-0x59C) + efuseDataOffset = EFUSE_DATA3 - (Offset & 0xC) ; + //data hold 4 bytes data. + //In RTMP_IO_READ32 will automatically execute 32-bytes swapping + RTMP_IO_READ32(pAd, efuseDataOffset, &data); + //Decide the upper 2 bytes or the bottom 2 bytes. + // Little-endian S | S Big-endian + // addr 3 2 1 0 | 0 1 2 3 + // Ori-V D C B A | A B C D + //After swapping + // D C B A | D C B A + //Return 2-bytes + //The return byte statrs from S. Therefore, the little-endian will return BA, the Big-endian will return DC. + //For returning the bottom 2 bytes, the Big-endian should shift right 2-bytes. +#ifdef RT_BIG_ENDIAN + data = data << (8*((Offset & 0x3)^0x2)); +#else + data = data >> (8*(Offset & 0x3)); +#endif + + NdisMoveMemory(pData, &data, Length); + } + + return (UCHAR) eFuseCtrlStruc.field.EFSROM_AOUT; + +} + +/* + ======================================================================== + + Routine Description: + + Arguments: + + Return Value: + + IRQL = + + Note: + + ======================================================================== +*/ +VOID eFusePhysicalReadRegisters( + IN PRTMP_ADAPTER pAd, + IN USHORT Offset, + IN USHORT Length, + OUT USHORT* pData) +{ + EFUSE_CTRL_STRUC eFuseCtrlStruc; + int i; + USHORT efuseDataOffset; + UINT32 data; + + RTMP_IO_READ32(pAd, EFUSE_CTRL, (PUINT32) &eFuseCtrlStruc); + + //Step0. Write 10-bit of address to EFSROM_AIN (0x580, bit25:bit16). The address must be 16-byte alignment. + eFuseCtrlStruc.field.EFSROM_AIN = Offset & 0xfff0; + + //Step1. Write EFSROM_MODE (0x580, bit7:bit6) to 1. + //Read in physical view + eFuseCtrlStruc.field.EFSROM_MODE = 1; + + //Step2. Write EFSROM_KICK (0x580, bit30) to 1 to kick-off physical read procedure. + eFuseCtrlStruc.field.EFSROM_KICK = 1; + + NdisMoveMemory(&data, &eFuseCtrlStruc, 4); + RTMP_IO_WRITE32(pAd, EFUSE_CTRL, data); + + //Step3. Polling EFSROM_KICK(0x580, bit30) until it become 0 again. + i = 0; + while(i < 100) + { + RTMP_IO_READ32(pAd, EFUSE_CTRL, (PUINT32) &eFuseCtrlStruc); + if(eFuseCtrlStruc.field.EFSROM_KICK == 0) + break; + RTMPusecDelay(2); + i++; + } + + //Step4. Read 16-byte of data from EFUSE_DATA0-3 (0x59C-0x590) + //Because the size of each EFUSE_DATA is 4 Bytes, the size of address of each is 2 bits. + //The previous 2 bits is the EFUSE_DATA number, the last 2 bits is used to decide which bytes + //Decide which EFUSE_DATA to read + //590:F E D C + //594:B A 9 8 + //598:7 6 5 4 + //59C:3 2 1 0 + efuseDataOffset = EFUSE_DATA3 - (Offset & 0xC) ; + + RTMP_IO_READ32(pAd, efuseDataOffset, &data); + +#ifdef RT_BIG_ENDIAN + data = data << (8*((Offset & 0x3)^0x2)); +#else + data = data >> (8*(Offset & 0x3)); +#endif + + NdisMoveMemory(pData, &data, Length); + +} + +/* + ======================================================================== + + Routine Description: + + Arguments: + + Return Value: + + IRQL = + + Note: + + ======================================================================== +*/ +VOID eFuseReadPhysical( + IN PRTMP_ADAPTER pAd, + IN PUSHORT lpInBuffer, + IN ULONG nInBufferSize, + OUT PUSHORT lpOutBuffer, + IN ULONG nOutBufferSize +) +{ + USHORT* pInBuf = (USHORT*)lpInBuffer; + USHORT* pOutBuf = (USHORT*)lpOutBuffer; + + USHORT Offset = pInBuf[0]; //addr + USHORT Length = pInBuf[1]; //length + int i; + + for(i=0; i<Length; i+=2) + { + eFusePhysicalReadRegisters(pAd,Offset+i, 2, &pOutBuf[i/2]); + } +} + +/* + ======================================================================== + + Routine Description: + + Arguments: + + Return Value: + + IRQL = + + Note: + + ======================================================================== +*/ +NTSTATUS eFuseRead( + IN PRTMP_ADAPTER pAd, + IN USHORT Offset, + OUT PUCHAR pData, + IN USHORT Length) +{ + USHORT* pOutBuf = (USHORT*)pData; + NTSTATUS Status = STATUS_SUCCESS; + UCHAR EFSROM_AOUT; + int i; + + for(i=0; i<Length; i+=2) + { + EFSROM_AOUT = eFuseReadRegisters(pAd, Offset+i, 2, &pOutBuf[i/2]); + } + return Status; +} + +/* + ======================================================================== + + Routine Description: + + Arguments: + + Return Value: + + IRQL = + + Note: + + ======================================================================== +*/ +VOID eFusePhysicalWriteRegisters( + IN PRTMP_ADAPTER pAd, + IN USHORT Offset, + IN USHORT Length, + OUT USHORT* pData) +{ + EFUSE_CTRL_STRUC eFuseCtrlStruc; + int i; + USHORT efuseDataOffset; + UINT32 data, eFuseDataBuffer[4]; + + //Step0. Write 16-byte of data to EFUSE_DATA0-3 (0x590-0x59C), where EFUSE_DATA0 is the LSB DW, EFUSE_DATA3 is the MSB DW. + + ///////////////////////////////////////////////////////////////// + //read current values of 16-byte block + RTMP_IO_READ32(pAd, EFUSE_CTRL, (PUINT32) &eFuseCtrlStruc); + + //Step0. Write 10-bit of address to EFSROM_AIN (0x580, bit25:bit16). The address must be 16-byte alignment. + eFuseCtrlStruc.field.EFSROM_AIN = Offset & 0xfff0; + + //Step1. Write EFSROM_MODE (0x580, bit7:bit6) to 1. + eFuseCtrlStruc.field.EFSROM_MODE = 1; + + //Step2. Write EFSROM_KICK (0x580, bit30) to 1 to kick-off physical read procedure. + eFuseCtrlStruc.field.EFSROM_KICK = 1; + + NdisMoveMemory(&data, &eFuseCtrlStruc, 4); + RTMP_IO_WRITE32(pAd, EFUSE_CTRL, data); + + //Step3. Polling EFSROM_KICK(0x580, bit30) until it become 0 again. + i = 0; + while(i < 100) + { + RTMP_IO_READ32(pAd, EFUSE_CTRL, (PUINT32) &eFuseCtrlStruc); + + if(eFuseCtrlStruc.field.EFSROM_KICK == 0) + break; + RTMPusecDelay(2); + i++; + } + + //Step4. Read 16-byte of data from EFUSE_DATA0-3 (0x59C-0x590) + efuseDataOffset = EFUSE_DATA3; + for(i=0; i< 4; i++) + { + RTMP_IO_READ32(pAd, efuseDataOffset, (PUINT32) &eFuseDataBuffer[i]); + efuseDataOffset -= 4; + } + + //Update the value, the offset is multiple of 2, length is 2 + efuseDataOffset = (Offset & 0xc) >> 2; + data = pData[0] & 0xffff; + //The offset should be 0x***10 or 0x***00 + if((Offset % 4) != 0) + { + eFuseDataBuffer[efuseDataOffset] = (eFuseDataBuffer[efuseDataOffset] & 0xffff) | (data << 16); + } + else + { + eFuseDataBuffer[efuseDataOffset] = (eFuseDataBuffer[efuseDataOffset] & 0xffff0000) | data; + } + + efuseDataOffset = EFUSE_DATA3; + for(i=0; i< 4; i++) + { + RTMP_IO_WRITE32(pAd, efuseDataOffset, eFuseDataBuffer[i]); + efuseDataOffset -= 4; + } + ///////////////////////////////////////////////////////////////// + + //Step1. Write 10-bit of address to EFSROM_AIN (0x580, bit25:bit16). The address must be 16-byte alignment. + eFuseCtrlStruc.field.EFSROM_AIN = Offset & 0xfff0; + + //Step2. Write EFSROM_MODE (0x580, bit7:bit6) to 3. + eFuseCtrlStruc.field.EFSROM_MODE = 3; + + //Step3. Write EFSROM_KICK (0x580, bit30) to 1 to kick-off physical write procedure. + eFuseCtrlStruc.field.EFSROM_KICK = 1; + + NdisMoveMemory(&data, &eFuseCtrlStruc, 4); + RTMP_IO_WRITE32(pAd, EFUSE_CTRL, data); + + //Step4. Polling EFSROM_KICK(0x580, bit30) until it become 0 again. It¡¦s done. + i = 0; + while(i < 100) + { + RTMP_IO_READ32(pAd, EFUSE_CTRL, (PUINT32) &eFuseCtrlStruc); + + if(eFuseCtrlStruc.field.EFSROM_KICK == 0) + break; + + RTMPusecDelay(2); + i++; + } +} + +/* + ======================================================================== + + Routine Description: + + Arguments: + + Return Value: + + IRQL = + + Note: + + ======================================================================== +*/ +NTSTATUS eFuseWriteRegisters( + IN PRTMP_ADAPTER pAd, + IN USHORT Offset, + IN USHORT Length, + IN USHORT* pData) +{ + USHORT i; + USHORT eFuseData; + USHORT LogicalAddress, BlkNum = 0xffff; + UCHAR EFSROM_AOUT; + + USHORT addr,tmpaddr, InBuf[3], tmpOffset; + USHORT buffer[8]; + BOOLEAN bWriteSuccess = TRUE; + + DBGPRINT(RT_DEBUG_TRACE, ("eFuseWriteRegisters Offset=%x, pData=%x\n", Offset, *pData)); + + //Step 0. find the entry in the mapping table + //The address of EEPROM is 2-bytes alignment. + //The last bit is used for alignment, so it must be 0. + tmpOffset = Offset & 0xfffe; + EFSROM_AOUT = eFuseReadRegisters(pAd, tmpOffset, 2, &eFuseData); + + if( EFSROM_AOUT == 0x3f) + { //find available logical address pointer + //the logical address does not exist, find an empty one + //from the first address of block 45=16*45=0x2d0 to the last address of block 47 + //==>48*16-3(reserved)=2FC + for (i=EFUSE_USAGE_MAP_START; i<=EFUSE_USAGE_MAP_END; i+=2) + { + //Retrive the logical block nubmer form each logical address pointer + //It will access two logical address pointer each time. + eFusePhysicalReadRegisters(pAd, i, 2, &LogicalAddress); + if( (LogicalAddress & 0xff) == 0) + {//Not used logical address pointer + BlkNum = i-EFUSE_USAGE_MAP_START; + break; + } + else if(( (LogicalAddress >> 8) & 0xff) == 0) + {//Not used logical address pointer + if (i != EFUSE_USAGE_MAP_END) + { + BlkNum = i-EFUSE_USAGE_MAP_START+1; + } + break; + } + } + } + else + { + BlkNum = EFSROM_AOUT; + } + + DBGPRINT(RT_DEBUG_TRACE, ("eFuseWriteRegisters BlkNum = %d \n", BlkNum)); + + if(BlkNum == 0xffff) + { + DBGPRINT(RT_DEBUG_TRACE, ("eFuseWriteRegisters: out of free E-fuse space!!!\n")); + return FALSE; + } + + //Step 1. Save data of this block which is pointed by the avaible logical address pointer + // read and save the original block data + for(i =0; i<8; i++) + { + addr = BlkNum * 0x10 ; + + InBuf[0] = addr+2*i; + InBuf[1] = 2; + InBuf[2] = 0x0; + + eFuseReadPhysical(pAd, &InBuf[0], 4, &InBuf[2], 2); + + buffer[i] = InBuf[2]; + } + + //Step 2. Update the data in buffer, and write the data to Efuse + buffer[ (Offset >> 1) % 8] = pData[0]; + + do + { + //Step 3. Write the data to Efuse + if(!bWriteSuccess) + { + for(i =0; i<8; i++) + { + addr = BlkNum * 0x10 ; + + InBuf[0] = addr+2*i; + InBuf[1] = 2; + InBuf[2] = buffer[i]; + + eFuseWritePhysical(pAd, &InBuf[0], 6, NULL, 2); + } + } + else + { + addr = BlkNum * 0x10 ; + + InBuf[0] = addr+(Offset % 16); + InBuf[1] = 2; + InBuf[2] = pData[0]; + + eFuseWritePhysical(pAd, &InBuf[0], 6, NULL, 2); + } + + //Step 4. Write mapping table + addr = EFUSE_USAGE_MAP_START+BlkNum; + + tmpaddr = addr; + + if(addr % 2 != 0) + addr = addr -1; + InBuf[0] = addr; + InBuf[1] = 2; + + //convert the address from 10 to 8 bit ( bit7, 6 = parity and bit5 ~ 0 = bit9~4), and write to logical map entry + tmpOffset = Offset; + tmpOffset >>= 4; + tmpOffset |= ((~((tmpOffset & 0x01) ^ ( tmpOffset >> 1 & 0x01) ^ (tmpOffset >> 2 & 0x01) ^ (tmpOffset >> 3 & 0x01))) << 6) & 0x40; + tmpOffset |= ((~( (tmpOffset >> 2 & 0x01) ^ (tmpOffset >> 3 & 0x01) ^ (tmpOffset >> 4 & 0x01) ^ ( tmpOffset >> 5 & 0x01))) << 7) & 0x80; + + // write the logical address + if(tmpaddr%2 != 0) + InBuf[2] = tmpOffset<<8; + else + InBuf[2] = tmpOffset; + + eFuseWritePhysical(pAd,&InBuf[0], 6, NULL, 0); + + //Step 5. Compare data if not the same, invalidate the mapping entry, then re-write the data until E-fuse is exhausted + bWriteSuccess = TRUE; + for(i =0; i<8; i++) + { + addr = BlkNum * 0x10 ; + + InBuf[0] = addr+2*i; + InBuf[1] = 2; + InBuf[2] = 0x0; + + eFuseReadPhysical(pAd, &InBuf[0], 4, &InBuf[2], 2); + + if(buffer[i] != InBuf[2]) + { + bWriteSuccess = FALSE; + break; + } + } + + //Step 6. invlidate mapping entry and find a free mapping entry if not succeed + if (!bWriteSuccess) + { + DBGPRINT(RT_DEBUG_TRACE, ("Not bWriteSuccess BlkNum = %d\n", BlkNum)); + + // the offset of current mapping entry + addr = EFUSE_USAGE_MAP_START+BlkNum; + + //find a new mapping entry + BlkNum = 0xffff; + for (i=EFUSE_USAGE_MAP_START; i<=EFUSE_USAGE_MAP_END; i+=2) + { + eFusePhysicalReadRegisters(pAd, i, 2, &LogicalAddress); + if( (LogicalAddress & 0xff) == 0) + { + BlkNum = i-EFUSE_USAGE_MAP_START; + break; + } + else if(( (LogicalAddress >> 8) & 0xff) == 0) + { + if (i != EFUSE_USAGE_MAP_END) + { + BlkNum = i+1-EFUSE_USAGE_MAP_START; + } + break; + } + } + DBGPRINT(RT_DEBUG_TRACE, ("Not bWriteSuccess new BlkNum = %d\n", BlkNum)); + if(BlkNum == 0xffff) + { + DBGPRINT(RT_DEBUG_TRACE, ("eFuseWriteRegisters: out of free E-fuse space!!!\n")); + return FALSE; + } + + //invalidate the original mapping entry if new entry is not found + tmpaddr = addr; + + if(addr % 2 != 0) + addr = addr -1; + InBuf[0] = addr; + InBuf[1] = 2; + + eFuseReadPhysical(pAd, &InBuf[0], 4, &InBuf[2], 2); + + // write the logical address + if(tmpaddr%2 != 0) + { + // Invalidate the high byte + for (i=8; i<15; i++) + { + if( ( (InBuf[2] >> i) & 0x01) == 0) + { + InBuf[2] |= (0x1 <<i); + break; + } + } + } + else + { + // invalidate the low byte + for (i=0; i<8; i++) + { + if( ( (InBuf[2] >> i) & 0x01) == 0) + { + InBuf[2] |= (0x1 <<i); + break; + } + } + } + eFuseWritePhysical(pAd, &InBuf[0], 6, NULL, 0); + } + } + while(!bWriteSuccess); + + return TRUE; +} + +/* + ======================================================================== + + Routine Description: + + Arguments: + + Return Value: + + IRQL = + + Note: + + ======================================================================== +*/ +VOID eFuseWritePhysical( + IN PRTMP_ADAPTER pAd, + PUSHORT lpInBuffer, + ULONG nInBufferSize, + PUCHAR lpOutBuffer, + ULONG nOutBufferSize +) +{ + USHORT* pInBuf = (USHORT*)lpInBuffer; + int i; + //USHORT* pOutBuf = (USHORT*)ioBuffer; + + USHORT Offset = pInBuf[0]; //addr + USHORT Length = pInBuf[1]; //length + USHORT* pValueX = &pInBuf[2]; //value ... + // Little-endian S | S Big-endian + // addr 3 2 1 0 | 0 1 2 3 + // Ori-V D C B A | A B C D + //After swapping + // D C B A | D C B A + //Both the little and big-endian use the same sequence to write data. + //Therefore, we only need swap data when read the data. + for(i=0; i<Length; i+=2) + { + eFusePhysicalWriteRegisters(pAd, Offset+i, 2, &pValueX[i/2]); + } +} + + +/* + ======================================================================== + + Routine Description: + + Arguments: + + Return Value: + + IRQL = + + Note: + + ======================================================================== +*/ +NTSTATUS eFuseWrite( + IN PRTMP_ADAPTER pAd, + IN USHORT Offset, + IN PUCHAR pData, + IN USHORT length) +{ + int i; + + USHORT* pValueX = (PUSHORT) pData; //value ... + //The input value=3070 will be stored as following + // Little-endian S | S Big-endian + // addr 1 0 | 0 1 + // Ori-V 30 70 | 30 70 + //After swapping + // 30 70 | 70 30 + //Casting + // 3070 | 7030 (x) + //The swapping should be removed for big-endian + for(i=0; i<length; i+=2) + { + eFuseWriteRegisters(pAd, Offset+i, 2, &pValueX[i/2]); + } + + return TRUE; +} + +/* + ======================================================================== + + Routine Description: + + Arguments: + + Return Value: + + IRQL = + + Note: + + ======================================================================== +*/ +INT set_eFuseGetFreeBlockCount_Proc( + IN PRTMP_ADAPTER pAd, + IN PUCHAR arg) +{ + USHORT i; + USHORT LogicalAddress; + USHORT efusefreenum=0; + if(!pAd->bUseEfuse) + return FALSE; + for (i = EFUSE_USAGE_MAP_START; i <= EFUSE_USAGE_MAP_END; i+=2) + { + eFusePhysicalReadRegisters(pAd, i, 2, &LogicalAddress); + if( (LogicalAddress & 0xff) == 0) + { + efusefreenum= (UCHAR) (EFUSE_USAGE_MAP_END-i+1); + break; + } + else if(( (LogicalAddress >> 8) & 0xff) == 0) + { + efusefreenum = (UCHAR) (EFUSE_USAGE_MAP_END-i); + break; + } + + if(i == EFUSE_USAGE_MAP_END) + efusefreenum = 0; + } + printk("efuseFreeNumber is %d\n",efusefreenum); + return TRUE; +} +INT set_eFusedump_Proc( + IN PRTMP_ADAPTER pAd, + IN PUCHAR arg) +{ +USHORT InBuf[3]; + INT i=0; + if(!pAd->bUseEfuse) + return FALSE; + for(i =0; i<EFUSE_USAGE_MAP_END/2; i++) + { + InBuf[0] = 2*i; + InBuf[1] = 2; + InBuf[2] = 0x0; + + eFuseReadPhysical(pAd, &InBuf[0], 4, &InBuf[2], 2); + if(i%4==0) + printk("\nBlock %x:",i/8); + printk("%04x ",InBuf[2]); + } + return TRUE; +} +INT set_eFuseLoadFromBin_Proc( + IN PRTMP_ADAPTER pAd, + IN PUCHAR arg) +{ + CHAR *src; + struct file *srcf; + INT retval, orgfsuid, orgfsgid; + mm_segment_t orgfs; + UCHAR *buffer; + UCHAR BinFileSize=0; + INT i = 0,j=0,k=1; + USHORT *PDATA; + USHORT DATA; + BinFileSize=strlen("RT30xxEEPROM.bin"); + src = kmalloc(128, MEM_ALLOC_FLAG); + NdisZeroMemory(src, 128); + + if(strlen(arg)>0) + { + + NdisMoveMemory(src, arg, strlen(arg)); + } + + else + { + + NdisMoveMemory(src, "RT30xxEEPROM.bin", BinFileSize); + } + + DBGPRINT(RT_DEBUG_TRACE, ("FileName=%s\n",src)); + buffer = kmalloc(MAX_EEPROM_BIN_FILE_SIZE, MEM_ALLOC_FLAG); + + if(buffer == NULL) + { + kfree(src); + return FALSE; +} + PDATA=kmalloc(sizeof(USHORT)*8,MEM_ALLOC_FLAG); + + if(PDATA==NULL) + { + kfree(src); + + kfree(buffer); + return FALSE; + } + /* Don't change to uid 0, let the file be opened as the "normal" user */ +#if 0 + orgfsuid = current->fsuid; + orgfsgid = current->fsgid; + current->fsuid=current->fsgid = 0; +#endif + orgfs = get_fs(); + set_fs(KERNEL_DS); + + if (src && *src) + { + srcf = filp_open(src, O_RDONLY, 0); + if (IS_ERR(srcf)) + { + DBGPRINT(RT_DEBUG_ERROR, ("--> Error %ld opening %s\n", -PTR_ERR(srcf),src)); + return FALSE; + } + else + { + // The object must have a read method + if (srcf->f_op && srcf->f_op->read) + { + memset(buffer, 0x00, MAX_EEPROM_BIN_FILE_SIZE); + while(srcf->f_op->read(srcf, &buffer[i], 1, &srcf->f_pos)==1) + { + DBGPRINT(RT_DEBUG_TRACE, ("%02X ",buffer[i])); + if((i+1)%8==0) + DBGPRINT(RT_DEBUG_TRACE, ("\n")); + i++; + if(i>=MAX_EEPROM_BIN_FILE_SIZE) + { + DBGPRINT(RT_DEBUG_ERROR, ("--> Error %ld reading %s, The file is too large[1024]\n", -PTR_ERR(srcf),src)); + kfree(PDATA); + kfree(buffer); + kfree(src); + return FALSE; + } + } + } + else + { + DBGPRINT(RT_DEBUG_ERROR, ("--> Error!! System doest not support read function\n")); + kfree(PDATA); + kfree(buffer); + kfree(src); + return FALSE; + } + } + + + } + else + { + DBGPRINT(RT_DEBUG_ERROR, ("--> Error src or srcf is null\n")); + kfree(PDATA); + kfree(buffer); + return FALSE; + + } + + + retval=filp_close(srcf,NULL); + + if (retval) + { + DBGPRINT(RT_DEBUG_TRACE, ("--> Error %d closing %s\n", -retval, src)); + } + set_fs(orgfs); +#if 0 + current->fsuid = orgfsuid; + current->fsgid = orgfsgid; +#endif + for(j=0;j<i;j++) + { + DBGPRINT(RT_DEBUG_TRACE, ("%02X ",buffer[j])); + if((j+1)%2==0) + PDATA[j/2%8]=((buffer[j]<<8)&0xff00)|(buffer[j-1]&0xff); + if(j%16==0) + { + k=buffer[j]; + } + else + { + k&=buffer[j]; + if((j+1)%16==0) + { + + DBGPRINT(RT_DEBUG_TRACE, (" result=%02X,blk=%02x\n",k,j/16)); + + if(k!=0xff) + eFuseWriteRegistersFromBin(pAd,(USHORT)j-15, 16, PDATA); + else + { + if(eFuseReadRegisters(pAd,j, 2,(PUSHORT)&DATA)!=0x3f) + eFuseWriteRegistersFromBin(pAd,(USHORT)j-15, 16, PDATA); + } + /* + for(l=0;l<8;l++) + printk("%04x ",PDATA[l]); + printk("\n"); + */ + NdisZeroMemory(PDATA,16); + + + } + } + + + } + + + kfree(PDATA); + kfree(buffer); + kfree(src); + return TRUE; +} +NTSTATUS eFuseWriteRegistersFromBin( + IN PRTMP_ADAPTER pAd, + IN USHORT Offset, + IN USHORT Length, + IN USHORT* pData) +{ + USHORT i; + USHORT eFuseData; + USHORT LogicalAddress, BlkNum = 0xffff; + UCHAR EFSROM_AOUT,Loop=0; + EFUSE_CTRL_STRUC eFuseCtrlStruc; + USHORT efuseDataOffset; + UINT32 data,tempbuffer; + USHORT addr,tmpaddr, InBuf[3], tmpOffset; + UINT32 buffer[4]; + BOOLEAN bWriteSuccess = TRUE; + BOOLEAN bNotWrite=TRUE; + BOOLEAN bAllocateNewBlk=TRUE; + + DBGPRINT(RT_DEBUG_TRACE, ("eFuseWriteRegistersFromBin Offset=%x, pData=%04x:%04x:%04x:%04x\n", Offset, *pData,*(pData+1),*(pData+2),*(pData+3))); + + do + { + //Step 0. find the entry in the mapping table + //The address of EEPROM is 2-bytes alignment. + //The last bit is used for alignment, so it must be 0. + Loop++; + tmpOffset = Offset & 0xfffe; + EFSROM_AOUT = eFuseReadRegisters(pAd, tmpOffset, 2, &eFuseData); + + if( EFSROM_AOUT == 0x3f) + { //find available logical address pointer + //the logical address does not exist, find an empty one + //from the first address of block 45=16*45=0x2d0 to the last address of block 47 + //==>48*16-3(reserved)=2FC + bAllocateNewBlk=TRUE; + for (i=EFUSE_USAGE_MAP_START; i<=EFUSE_USAGE_MAP_END; i+=2) + { + //Retrive the logical block nubmer form each logical address pointer + //It will access two logical address pointer each time. + eFusePhysicalReadRegisters(pAd, i, 2, &LogicalAddress); + if( (LogicalAddress & 0xff) == 0) + {//Not used logical address pointer + BlkNum = i-EFUSE_USAGE_MAP_START; + break; + } + else if(( (LogicalAddress >> 8) & 0xff) == 0) + {//Not used logical address pointer + if (i != EFUSE_USAGE_MAP_END) + { + BlkNum = i-EFUSE_USAGE_MAP_START+1; + } + break; + } + } + } + else + { + bAllocateNewBlk=FALSE; + BlkNum = EFSROM_AOUT; + } + + DBGPRINT(RT_DEBUG_TRACE, ("eFuseWriteRegisters BlkNum = %d \n", BlkNum)); + + if(BlkNum == 0xffff) + { + DBGPRINT(RT_DEBUG_TRACE, ("eFuseWriteRegisters: out of free E-fuse space!!!\n")); + return FALSE; + } + //Step 1.1.0 + //If the block is not existing in mapping table, create one + //and write down the 16-bytes data to the new block + if(bAllocateNewBlk) + { + DBGPRINT(RT_DEBUG_TRACE, ("Allocate New Blk\n")); + efuseDataOffset = EFUSE_DATA3; + for(i=0; i< 4; i++) + { + DBGPRINT(RT_DEBUG_TRACE, ("Allocate New Blk, Data%d=%04x%04x\n",3-i,pData[2*i+1],pData[2*i])); + tempbuffer=((pData[2*i+1]<<16)&0xffff0000)|pData[2*i]; + + + RTMP_IO_WRITE32(pAd, efuseDataOffset,tempbuffer); + efuseDataOffset -= 4; + + } + ///////////////////////////////////////////////////////////////// + + //Step1.1.1. Write 10-bit of address to EFSROM_AIN (0x580, bit25:bit16). The address must be 16-byte alignment. + eFuseCtrlStruc.field.EFSROM_AIN = BlkNum* 0x10 ; + + //Step1.1.2. Write EFSROM_MODE (0x580, bit7:bit6) to 3. + eFuseCtrlStruc.field.EFSROM_MODE = 3; + + //Step1.1.3. Write EFSROM_KICK (0x580, bit30) to 1 to kick-off physical write procedure. + eFuseCtrlStruc.field.EFSROM_KICK = 1; + + NdisMoveMemory(&data, &eFuseCtrlStruc, 4); + + RTMP_IO_WRITE32(pAd, EFUSE_CTRL, data); + + //Step1.1.4. Polling EFSROM_KICK(0x580, bit30) until it become 0 again. It¡¦s done. + i = 0; + while(i < 100) + { + RTMP_IO_READ32(pAd, EFUSE_CTRL, (PUINT32) &eFuseCtrlStruc); + + if(eFuseCtrlStruc.field.EFSROM_KICK == 0) + break; + + RTMPusecDelay(2); + i++; + } + + } + else + { //Step1.2. + //If the same logical number is existing, check if the writting data and the data + //saving in this block are the same. + ///////////////////////////////////////////////////////////////// + //read current values of 16-byte block + RTMP_IO_READ32(pAd, EFUSE_CTRL, (PUINT32) &eFuseCtrlStruc); + + //Step1.2.0. Write 10-bit of address to EFSROM_AIN (0x580, bit25:bit16). The address must be 16-byte alignment. + eFuseCtrlStruc.field.EFSROM_AIN = Offset & 0xfff0; + + //Step1.2.1. Write EFSROM_MODE (0x580, bit7:bit6) to 1. + eFuseCtrlStruc.field.EFSROM_MODE = 0; + + //Step1.2.2. Write EFSROM_KICK (0x580, bit30) to 1 to kick-off physical read procedure. + eFuseCtrlStruc.field.EFSROM_KICK = 1; + + NdisMoveMemory(&data, &eFuseCtrlStruc, 4); + RTMP_IO_WRITE32(pAd, EFUSE_CTRL, data); + + //Step1.2.3. Polling EFSROM_KICK(0x580, bit30) until it become 0 again. + i = 0; + while(i < 100) + { + RTMP_IO_READ32(pAd, EFUSE_CTRL, (PUINT32) &eFuseCtrlStruc); + + if(eFuseCtrlStruc.field.EFSROM_KICK == 0) + break; + RTMPusecDelay(2); + i++; + } + + //Step1.2.4. Read 16-byte of data from EFUSE_DATA0-3 (0x59C-0x590) + efuseDataOffset = EFUSE_DATA3; + for(i=0; i< 4; i++) + { + RTMP_IO_READ32(pAd, efuseDataOffset, (PUINT32) &buffer[i]); + efuseDataOffset -= 4; + } + //Step1.2.5. Check if the data of efuse and the writing data are the same. + for(i =0; i<4; i++) + { + tempbuffer=((pData[2*i+1]<<16)&0xffff0000)|pData[2*i]; + DBGPRINT(RT_DEBUG_TRACE, ("buffer[%d]=%x,pData[%d]=%x,pData[%d]=%x,tempbuffer=%x\n",i,buffer[i],2*i,pData[2*i],2*i+1,pData[2*i+1],tempbuffer)); + + if(((buffer[i]&0xffff0000)==(pData[2*i+1]<<16))&&((buffer[i]&0xffff)==pData[2*i])) + bNotWrite&=TRUE; + else + { + bNotWrite&=FALSE; + break; + } + } + if(!bNotWrite) + { + printk("The data is not the same\n"); + + for(i =0; i<8; i++) + { + addr = BlkNum * 0x10 ; + + InBuf[0] = addr+2*i; + InBuf[1] = 2; + InBuf[2] = pData[i]; + + eFuseWritePhysical(pAd, &InBuf[0], 6, NULL, 2); + } + + } + else + return TRUE; + } + + + + //Step 2. Write mapping table + addr = EFUSE_USAGE_MAP_START+BlkNum; + + tmpaddr = addr; + + if(addr % 2 != 0) + addr = addr -1; + InBuf[0] = addr; + InBuf[1] = 2; + + //convert the address from 10 to 8 bit ( bit7, 6 = parity and bit5 ~ 0 = bit9~4), and write to logical map entry + tmpOffset = Offset; + tmpOffset >>= 4; + tmpOffset |= ((~((tmpOffset & 0x01) ^ ( tmpOffset >> 1 & 0x01) ^ (tmpOffset >> 2 & 0x01) ^ (tmpOffset >> 3 & 0x01))) << 6) & 0x40; + tmpOffset |= ((~( (tmpOffset >> 2 & 0x01) ^ (tmpOffset >> 3 & 0x01) ^ (tmpOffset >> 4 & 0x01) ^ ( tmpOffset >> 5 & 0x01))) << 7) & 0x80; + + // write the logical address + if(tmpaddr%2 != 0) + InBuf[2] = tmpOffset<<8; + else + InBuf[2] = tmpOffset; + + eFuseWritePhysical(pAd,&InBuf[0], 6, NULL, 0); + + //Step 3. Compare data if not the same, invalidate the mapping entry, then re-write the data until E-fuse is exhausted + bWriteSuccess = TRUE; + for(i =0; i<8; i++) + { + addr = BlkNum * 0x10 ; + + InBuf[0] = addr+2*i; + InBuf[1] = 2; + InBuf[2] = 0x0; + + eFuseReadPhysical(pAd, &InBuf[0], 4, &InBuf[2], 2); + DBGPRINT(RT_DEBUG_TRACE, ("addr=%x, buffer[i]=%x,InBuf[2]=%x\n",InBuf[0],pData[i],InBuf[2])); + if(pData[i] != InBuf[2]) + { + bWriteSuccess = FALSE; + break; + } + } + + //Step 4. invlidate mapping entry and find a free mapping entry if not succeed + + if (!bWriteSuccess&&Loop<2) + { + DBGPRINT(RT_DEBUG_TRACE, ("eFuseWriteRegistersFromBin::Not bWriteSuccess BlkNum = %d\n", BlkNum)); + + // the offset of current mapping entry + addr = EFUSE_USAGE_MAP_START+BlkNum; + + //find a new mapping entry + BlkNum = 0xffff; + for (i=EFUSE_USAGE_MAP_START; i<=EFUSE_USAGE_MAP_END; i+=2) + { + eFusePhysicalReadRegisters(pAd, i, 2, &LogicalAddress); + if( (LogicalAddress & 0xff) == 0) + { + BlkNum = i-EFUSE_USAGE_MAP_START; + break; + } + else if(( (LogicalAddress >> 8) & 0xff) == 0) + { + if (i != EFUSE_USAGE_MAP_END) + { + BlkNum = i+1-EFUSE_USAGE_MAP_START; + } + break; + } + } + DBGPRINT(RT_DEBUG_TRACE, ("eFuseWriteRegistersFromBin::Not bWriteSuccess new BlkNum = %d\n", BlkNum)); + if(BlkNum == 0xffff) + { + DBGPRINT(RT_DEBUG_TRACE, ("eFuseWriteRegistersFromBin: out of free E-fuse space!!!\n")); + return FALSE; + } + + //invalidate the original mapping entry if new entry is not found + tmpaddr = addr; + + if(addr % 2 != 0) + addr = addr -1; + InBuf[0] = addr; + InBuf[1] = 2; + + eFuseReadPhysical(pAd, &InBuf[0], 4, &InBuf[2], 2); + + // write the logical address + if(tmpaddr%2 != 0) + { + // Invalidate the high byte + for (i=8; i<15; i++) + { + if( ( (InBuf[2] >> i) & 0x01) == 0) + { + InBuf[2] |= (0x1 <<i); + break; + } + } + } + else + { + // invalidate the low byte + for (i=0; i<8; i++) + { + if( ( (InBuf[2] >> i) & 0x01) == 0) + { + InBuf[2] |= (0x1 <<i); + break; + } + } + } + eFuseWritePhysical(pAd, &InBuf[0], 6, NULL, 0); + } + + } + while(!bWriteSuccess&&Loop<2); + + return TRUE; +} + +#endif // RT30xx // +//2008/09/11:KH add to support efuse--> + |