/****************************************************************************** * * Copyright(c) 2007 - 2011 Realtek Corporation. All rights reserved. * * This program is free software; you can redistribute it and/or modify it * under the terms of version 2 of the GNU General Public License as * published by the Free Software Foundation. * * 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., * 51 Franklin Street, Fifth Floor, Boston, MA 02110, USA * * ******************************************************************************/ #define _RTW_EFUSE_C_ #include #include #include #include #include #include #define REG_EFUSE_CTRL 0x0030 #define EFUSE_CTRL REG_EFUSE_CTRL /* E-Fuse Control. */ enum{ VOLTAGE_V25 = 0x03, LDOE25_SHIFT = 28 , }; /* * Function: Efuse_PowerSwitch * * Overview: When we want to enable write operation, we should change to * pwr on state. When we stop write, we should switch to 500k mode * and disable LDO 2.5V. */ void Efuse_PowerSwitch( struct adapter *pAdapter, u8 bWrite, u8 PwrState) { u8 tempval; u16 tmpV16; if (PwrState) { usb_write8(pAdapter, REG_EFUSE_ACCESS, EFUSE_ACCESS_ON); /* 1.2V Power: From VDDON with Power Cut(0x0000h[15]), defualt valid */ tmpV16 = usb_read16(pAdapter, REG_SYS_ISO_CTRL); if (!(tmpV16 & PWC_EV12V)) { tmpV16 |= PWC_EV12V; usb_write16(pAdapter, REG_SYS_ISO_CTRL, tmpV16); } /* Reset: 0x0000h[28], default valid */ tmpV16 = usb_read16(pAdapter, REG_SYS_FUNC_EN); if (!(tmpV16 & FEN_ELDR)) { tmpV16 |= FEN_ELDR; usb_write16(pAdapter, REG_SYS_FUNC_EN, tmpV16); } /* Clock: Gated(0x0008h[5]) 8M(0x0008h[1]) clock from ANA, default valid */ tmpV16 = usb_read16(pAdapter, REG_SYS_CLKR); if ((!(tmpV16 & LOADER_CLK_EN)) || (!(tmpV16 & ANA8M))) { tmpV16 |= (LOADER_CLK_EN | ANA8M); usb_write16(pAdapter, REG_SYS_CLKR, tmpV16); } if (bWrite) { /* Enable LDO 2.5V before read/write action */ tempval = usb_read8(pAdapter, EFUSE_TEST+3); tempval &= 0x0F; tempval |= (VOLTAGE_V25 << 4); usb_write8(pAdapter, EFUSE_TEST+3, (tempval | 0x80)); } } else { usb_write8(pAdapter, REG_EFUSE_ACCESS, EFUSE_ACCESS_OFF); if (bWrite) { /* Disable LDO 2.5V after read/write action */ tempval = usb_read8(pAdapter, EFUSE_TEST+3); usb_write8(pAdapter, EFUSE_TEST+3, (tempval & 0x7F)); } } } static void efuse_phymap_to_logical(u8 *phymap, u16 _offset, u16 _size_byte, u8 *pbuf) { u8 *efuseTbl = NULL; u8 rtemp8; u16 eFuse_Addr = 0; u8 offset, wren; u16 i, j; u16 **eFuseWord = NULL; u16 efuse_utilized = 0; u8 u1temp = 0; efuseTbl = kzalloc(EFUSE_MAP_LEN_88E, GFP_KERNEL); if (efuseTbl == NULL) { DBG_88E("%s: alloc efuseTbl fail!\n", __func__); goto exit; } eFuseWord = (u16 **)rtw_malloc2d(EFUSE_MAX_SECTION_88E, EFUSE_MAX_WORD_UNIT, sizeof(u16)); if (eFuseWord == NULL) { DBG_88E("%s: alloc eFuseWord fail!\n", __func__); goto exit; } /* 0. Refresh efuse init map as all oxFF. */ for (i = 0; i < EFUSE_MAX_SECTION_88E; i++) for (j = 0; j < EFUSE_MAX_WORD_UNIT; j++) eFuseWord[i][j] = 0xFFFF; /* */ /* 1. Read the first byte to check if efuse is empty!!! */ /* */ /* */ rtemp8 = *(phymap+eFuse_Addr); if (rtemp8 != 0xFF) { efuse_utilized++; eFuse_Addr++; } else { DBG_88E("EFUSE is empty efuse_Addr-%d efuse_data =%x\n", eFuse_Addr, rtemp8); goto exit; } /* */ /* 2. Read real efuse content. Filter PG header and every section data. */ /* */ while ((rtemp8 != 0xFF) && (eFuse_Addr < EFUSE_REAL_CONTENT_LEN_88E)) { /* Check PG header for section num. */ if ((rtemp8 & 0x1F) == 0x0F) { /* extended header */ u1temp = ((rtemp8 & 0xE0) >> 5); rtemp8 = *(phymap+eFuse_Addr); if ((rtemp8 & 0x0F) == 0x0F) { eFuse_Addr++; rtemp8 = *(phymap+eFuse_Addr); if (rtemp8 != 0xFF && (eFuse_Addr < EFUSE_REAL_CONTENT_LEN_88E)) eFuse_Addr++; continue; } else { offset = ((rtemp8 & 0xF0) >> 1) | u1temp; wren = (rtemp8 & 0x0F); eFuse_Addr++; } } else { offset = ((rtemp8 >> 4) & 0x0f); wren = (rtemp8 & 0x0f); } if (offset < EFUSE_MAX_SECTION_88E) { /* Get word enable value from PG header */ for (i = 0; i < EFUSE_MAX_WORD_UNIT; i++) { /* Check word enable condition in the section */ if (!(wren & 0x01)) { rtemp8 = *(phymap+eFuse_Addr); eFuse_Addr++; efuse_utilized++; eFuseWord[offset][i] = (rtemp8 & 0xff); if (eFuse_Addr >= EFUSE_REAL_CONTENT_LEN_88E) break; rtemp8 = *(phymap+eFuse_Addr); eFuse_Addr++; efuse_utilized++; eFuseWord[offset][i] |= (((u16)rtemp8 << 8) & 0xff00); if (eFuse_Addr >= EFUSE_REAL_CONTENT_LEN_88E) break; } wren >>= 1; } } /* Read next PG header */ rtemp8 = *(phymap+eFuse_Addr); if (rtemp8 != 0xFF && (eFuse_Addr < EFUSE_REAL_CONTENT_LEN_88E)) { efuse_utilized++; eFuse_Addr++; } } /* */ /* 3. Collect 16 sections and 4 word unit into Efuse map. */ /* */ for (i = 0; i < EFUSE_MAX_SECTION_88E; i++) { for (j = 0; j < EFUSE_MAX_WORD_UNIT; j++) { efuseTbl[(i*8)+(j*2)] = (eFuseWord[i][j] & 0xff); efuseTbl[(i*8)+((j*2)+1)] = ((eFuseWord[i][j] >> 8) & 0xff); } } /* */ /* 4. Copy from Efuse map to output pointer memory!!! */ /* */ for (i = 0; i < _size_byte; i++) pbuf[i] = efuseTbl[_offset+i]; /* */ /* 5. Calculate Efuse utilization. */ /* */ exit: kfree(efuseTbl); if (eFuseWord) kfree(eFuseWord); } static void efuse_read_phymap_from_txpktbuf( struct adapter *adapter, int bcnhead, /* beacon head, where FW store len(2-byte) and efuse physical map. */ u8 *content, /* buffer to store efuse physical map */ u16 *size /* for efuse content: the max byte to read. will update to byte read */ ) { u16 dbg_addr = 0; u32 start = 0, passing_time = 0; u8 reg_0x143 = 0; u32 lo32 = 0, hi32 = 0; u16 len = 0, count = 0; int i = 0; u16 limit = *size; u8 *pos = content; if (bcnhead < 0) /* if not valid */ bcnhead = usb_read8(adapter, REG_TDECTRL+1); DBG_88E("%s bcnhead:%d\n", __func__, bcnhead); usb_write8(adapter, REG_PKT_BUFF_ACCESS_CTRL, TXPKT_BUF_SELECT); dbg_addr = bcnhead*128/8; /* 8-bytes addressing */ while (1) { usb_write16(adapter, REG_PKTBUF_DBG_ADDR, dbg_addr+i); usb_write8(adapter, REG_TXPKTBUF_DBG, 0); start = jiffies; while (!(reg_0x143 = usb_read8(adapter, REG_TXPKTBUF_DBG)) && (passing_time = rtw_get_passing_time_ms(start)) < 1000) { DBG_88E("%s polling reg_0x143:0x%02x, reg_0x106:0x%02x\n", __func__, reg_0x143, usb_read8(adapter, 0x106)); msleep(1); } lo32 = le32_to_cpu((__le32)usb_read32(adapter, REG_PKTBUF_DBG_DATA_L)); hi32 = le32_to_cpu((__le32)usb_read32(adapter, REG_PKTBUF_DBG_DATA_H)); if (i == 0) { u8 lenc[2]; u16 lenbak, aaabak; u16 aaa; lenc[0] = usb_read8(adapter, REG_PKTBUF_DBG_DATA_L); lenc[1] = usb_read8(adapter, REG_PKTBUF_DBG_DATA_L+1); aaabak = le16_to_cpup((__le16 *)lenc); lenbak = le16_to_cpu(*((__le16 *)lenc)); aaa = le16_to_cpup((__le16 *)&lo32); len = le16_to_cpu(*((__le16 *)&lo32)); limit = (len-2 < limit) ? len-2 : limit; DBG_88E("%s len:%u, lenbak:%u, aaa:%u, aaabak:%u\n", __func__, len, lenbak, aaa, aaabak); memcpy(pos, ((u8 *)&lo32)+2, (limit >= count+2) ? 2 : limit-count); count += (limit >= count+2) ? 2 : limit-count; pos = content+count; } else { memcpy(pos, ((u8 *)&lo32), (limit >= count+4) ? 4 : limit-count); count += (limit >= count+4) ? 4 : limit-count; pos = content+count; } if (limit > count && len-2 > count) { memcpy(pos, (u8 *)&hi32, (limit >= count+4) ? 4 : limit-count); count += (limit >= count+4) ? 4 : limit-count; pos = content+count; } if (limit <= count || len-2 <= count) break; i++; } usb_write8(adapter, REG_PKT_BUFF_ACCESS_CTRL, DISABLE_TRXPKT_BUF_ACCESS); DBG_88E("%s read count:%u\n", __func__, count); *size = count; } static s32 iol_read_efuse(struct adapter *padapter, u8 txpktbuf_bndy, u16 offset, u16 size_byte, u8 *logical_map) { s32 status = _FAIL; u8 physical_map[512]; u16 size = 512; usb_write8(padapter, REG_TDECTRL+1, txpktbuf_bndy); memset(physical_map, 0xFF, 512); usb_write8(padapter, REG_PKT_BUFF_ACCESS_CTRL, TXPKT_BUF_SELECT); status = iol_execute(padapter, CMD_READ_EFUSE_MAP); if (status == _SUCCESS) efuse_read_phymap_from_txpktbuf(padapter, txpktbuf_bndy, physical_map, &size); efuse_phymap_to_logical(physical_map, offset, size_byte, logical_map); return status; } void efuse_ReadEFuse(struct adapter *Adapter, u8 efuseType, u16 _offset, u16 _size_byte, u8 *pbuf) { if (rtw_IOL_applied(Adapter)) { rtw_hal_power_on(Adapter); iol_mode_enable(Adapter, 1); iol_read_efuse(Adapter, 0, _offset, _size_byte, pbuf); iol_mode_enable(Adapter, 0); } return; } /* Do not support BT */ void EFUSE_GetEfuseDefinition(struct adapter *pAdapter, u8 efuseType, u8 type, void *pOut) { switch (type) { case TYPE_EFUSE_MAX_SECTION: { u8 *pMax_section; pMax_section = (u8 *)pOut; *pMax_section = EFUSE_MAX_SECTION_88E; } break; case TYPE_EFUSE_REAL_CONTENT_LEN: { u16 *pu2Tmp; pu2Tmp = (u16 *)pOut; *pu2Tmp = EFUSE_REAL_CONTENT_LEN_88E; } break; case TYPE_EFUSE_CONTENT_LEN_BANK: { u16 *pu2Tmp; pu2Tmp = (u16 *)pOut; *pu2Tmp = EFUSE_REAL_CONTENT_LEN_88E; } break; case TYPE_AVAILABLE_EFUSE_BYTES_BANK: { u16 *pu2Tmp; pu2Tmp = (u16 *)pOut; *pu2Tmp = (u16)(EFUSE_REAL_CONTENT_LEN_88E-EFUSE_OOB_PROTECT_BYTES_88E); } break; case TYPE_AVAILABLE_EFUSE_BYTES_TOTAL: { u16 *pu2Tmp; pu2Tmp = (u16 *)pOut; *pu2Tmp = (u16)(EFUSE_REAL_CONTENT_LEN_88E-EFUSE_OOB_PROTECT_BYTES_88E); } break; case TYPE_EFUSE_MAP_LEN: { u16 *pu2Tmp; pu2Tmp = (u16 *)pOut; *pu2Tmp = (u16)EFUSE_MAP_LEN_88E; } break; case TYPE_EFUSE_PROTECT_BYTES_BANK: { u8 *pu1Tmp; pu1Tmp = (u8 *)pOut; *pu1Tmp = (u8)(EFUSE_OOB_PROTECT_BYTES_88E); } break; default: { u8 *pu1Tmp; pu1Tmp = (u8 *)pOut; *pu1Tmp = 0; } break; } } u8 Efuse_WordEnableDataWrite(struct adapter *pAdapter, u16 efuse_addr, u8 word_en, u8 *data) { u16 tmpaddr = 0; u16 start_addr = efuse_addr; u8 badworden = 0x0F; u8 tmpdata[8]; memset((void *)tmpdata, 0xff, PGPKT_DATA_SIZE); if (!(word_en&BIT0)) { tmpaddr = start_addr; efuse_OneByteWrite(pAdapter, start_addr++, data[0]); efuse_OneByteWrite(pAdapter, start_addr++, data[1]); efuse_OneByteRead(pAdapter, tmpaddr, &tmpdata[0]); efuse_OneByteRead(pAdapter, tmpaddr+1, &tmpdata[1]); if ((data[0] != tmpdata[0]) || (data[1] != tmpdata[1])) badworden &= (~BIT0); } if (!(word_en&BIT1)) { tmpaddr = start_addr; efuse_OneByteWrite(pAdapter, start_addr++, data[2]); efuse_OneByteWrite(pAdapter, start_addr++, data[3]); efuse_OneByteRead(pAdapter, tmpaddr, &tmpdata[2]); efuse_OneByteRead(pAdapter, tmpaddr+1, &tmpdata[3]); if ((data[2] != tmpdata[2]) || (data[3] != tmpdata[3])) badworden &= (~BIT1); } if (!(word_en&BIT2)) { tmpaddr = start_addr; efuse_OneByteWrite(pAdapter, start_addr++, data[4]); efuse_OneByteWrite(pAdapter, start_addr++, data[5]); efuse_OneByteRead(pAdapter, tmpaddr, &tmpdata[4]); efuse_OneByteRead(pAdapter, tmpaddr+1, &tmpdata[5]); if ((data[4] != tmpdata[4]) || (data[5] != tmpdata[5])) badworden &= (~BIT2); } if (!(word_en&BIT3)) { tmpaddr = start_addr; efuse_OneByteWrite(pAdapter, start_addr++, data[6]); efuse_OneByteWrite(pAdapter, start_addr++, data[7]); efuse_OneByteRead(pAdapter, tmpaddr, &tmpdata[6]); efuse_OneByteRead(pAdapter, tmpaddr+1, &tmpdata[7]); if ((data[6] != tmpdata[6]) || (data[7] != tmpdata[7])) badworden &= (~BIT3); } return badworden; } static u16 Efuse_GetCurrentSize(struct adapter *pAdapter) { int bContinual = true; u16 efuse_addr = 0; u8 hoffset = 0, hworden = 0; u8 efuse_data, word_cnts = 0; rtw_hal_get_hwreg(pAdapter, HW_VAR_EFUSE_BYTES, (u8 *)&efuse_addr); while (bContinual && efuse_OneByteRead(pAdapter, efuse_addr, &efuse_data) && AVAILABLE_EFUSE_ADDR(efuse_addr)) { if (efuse_data != 0xFF) { if ((efuse_data&0x1F) == 0x0F) { /* extended header */ hoffset = efuse_data; efuse_addr++; efuse_OneByteRead(pAdapter, efuse_addr, &efuse_data); if ((efuse_data & 0x0F) == 0x0F) { efuse_addr++; continue; } else { hoffset = ((hoffset & 0xE0) >> 5) | ((efuse_data & 0xF0) >> 1); hworden = efuse_data & 0x0F; } } else { hoffset = (efuse_data>>4) & 0x0F; hworden = efuse_data & 0x0F; } word_cnts = Efuse_CalculateWordCnts(hworden); /* read next header */ efuse_addr = efuse_addr + (word_cnts*2)+1; } else { bContinual = false; } } rtw_hal_set_hwreg(pAdapter, HW_VAR_EFUSE_BYTES, (u8 *)&efuse_addr); return efuse_addr; } int Efuse_PgPacketRead(struct adapter *pAdapter, u8 offset, u8 *data) { u8 ReadState = PG_STATE_HEADER; int bContinual = true; int bDataEmpty = true; u8 efuse_data, word_cnts = 0; u16 efuse_addr = 0; u8 hoffset = 0, hworden = 0; u8 tmpidx = 0; u8 tmpdata[8]; u8 max_section = 0; u8 tmp_header = 0; EFUSE_GetEfuseDefinition(pAdapter, EFUSE_WIFI, TYPE_EFUSE_MAX_SECTION, (void *)&max_section); if (data == NULL) return false; if (offset > max_section) return false; memset((void *)data, 0xff, sizeof(u8)*PGPKT_DATA_SIZE); memset((void *)tmpdata, 0xff, sizeof(u8)*PGPKT_DATA_SIZE); /* Efuse has been pre-programmed dummy 5Bytes at the end of Efuse by CP. */ /* Skip dummy parts to prevent unexpected data read from Efuse. */ /* By pass right now. 2009.02.19. */ while (bContinual && AVAILABLE_EFUSE_ADDR(efuse_addr)) { /* Header Read ------------- */ if (ReadState & PG_STATE_HEADER) { if (efuse_OneByteRead(pAdapter, efuse_addr, &efuse_data) && (efuse_data != 0xFF)) { if (EXT_HEADER(efuse_data)) { tmp_header = efuse_data; efuse_addr++; efuse_OneByteRead(pAdapter, efuse_addr, &efuse_data); if (!ALL_WORDS_DISABLED(efuse_data)) { hoffset = ((tmp_header & 0xE0) >> 5) | ((efuse_data & 0xF0) >> 1); hworden = efuse_data & 0x0F; } else { DBG_88E("Error, All words disabled\n"); efuse_addr++; continue; } } else { hoffset = (efuse_data>>4) & 0x0F; hworden = efuse_data & 0x0F; } word_cnts = Efuse_CalculateWordCnts(hworden); bDataEmpty = true; if (hoffset == offset) { for (tmpidx = 0; tmpidx < word_cnts*2; tmpidx++) { if (efuse_OneByteRead(pAdapter, efuse_addr+1+tmpidx, &efuse_data)) { tmpdata[tmpidx] = efuse_data; if (efuse_data != 0xff) bDataEmpty = false; } } if (bDataEmpty == false) { ReadState = PG_STATE_DATA; } else {/* read next header */ efuse_addr = efuse_addr + (word_cnts*2)+1; ReadState = PG_STATE_HEADER; } } else {/* read next header */ efuse_addr = efuse_addr + (word_cnts*2)+1; ReadState = PG_STATE_HEADER; } } else { bContinual = false; } } else if (ReadState & PG_STATE_DATA) { /* Data section Read ------------- */ efuse_WordEnableDataRead(hworden, tmpdata, data); efuse_addr = efuse_addr + (word_cnts*2)+1; ReadState = PG_STATE_HEADER; } } if ((data[0] == 0xff) && (data[1] == 0xff) && (data[2] == 0xff) && (data[3] == 0xff) && (data[4] == 0xff) && (data[5] == 0xff) && (data[6] == 0xff) && (data[7] == 0xff)) return false; else return true; } static bool hal_EfuseFixHeaderProcess(struct adapter *pAdapter, u8 efuseType, struct pgpkt *pFixPkt, u16 *pAddr) { u8 originaldata[8], badworden = 0; u16 efuse_addr = *pAddr; u32 PgWriteSuccess = 0; memset((void *)originaldata, 0xff, 8); if (Efuse_PgPacketRead(pAdapter, pFixPkt->offset, originaldata)) { /* check if data exist */ badworden = Efuse_WordEnableDataWrite(pAdapter, efuse_addr+1, pFixPkt->word_en, originaldata); if (badworden != 0xf) { /* write fail */ PgWriteSuccess = Efuse_PgPacketWrite(pAdapter, pFixPkt->offset, badworden, originaldata); if (!PgWriteSuccess) return false; else efuse_addr = Efuse_GetCurrentSize(pAdapter); } else { efuse_addr = efuse_addr + (pFixPkt->word_cnts*2) + 1; } } else { efuse_addr = efuse_addr + (pFixPkt->word_cnts*2) + 1; } *pAddr = efuse_addr; return true; } static bool hal_EfusePgPacketWrite2ByteHeader(struct adapter *pAdapter, u8 efuseType, u16 *pAddr, struct pgpkt *pTargetPkt) { bool bRet = false; u16 efuse_addr = *pAddr, efuse_max_available_len = 0; u8 pg_header = 0, tmp_header = 0, pg_header_temp = 0; u8 repeatcnt = 0; EFUSE_GetEfuseDefinition(pAdapter, efuseType, TYPE_AVAILABLE_EFUSE_BYTES_BANK, (void *)&efuse_max_available_len); while (efuse_addr < efuse_max_available_len) { pg_header = ((pTargetPkt->offset & 0x07) << 5) | 0x0F; efuse_OneByteWrite(pAdapter, efuse_addr, pg_header); efuse_OneByteRead(pAdapter, efuse_addr, &tmp_header); while (tmp_header == 0xFF) { if (repeatcnt++ > EFUSE_REPEAT_THRESHOLD_) return false; efuse_OneByteWrite(pAdapter, efuse_addr, pg_header); efuse_OneByteRead(pAdapter, efuse_addr, &tmp_header); } /* to write ext_header */ if (tmp_header == pg_header) { efuse_addr++; pg_header_temp = pg_header; pg_header = ((pTargetPkt->offset & 0x78) << 1) | pTargetPkt->word_en; efuse_OneByteWrite(pAdapter, efuse_addr, pg_header); efuse_OneByteRead(pAdapter, efuse_addr, &tmp_header); while (tmp_header == 0xFF) { if (repeatcnt++ > EFUSE_REPEAT_THRESHOLD_) return false; efuse_OneByteWrite(pAdapter, efuse_addr, pg_header); efuse_OneByteRead(pAdapter, efuse_addr, &tmp_header); } if ((tmp_header & 0x0F) == 0x0F) { /* word_en PG fail */ if (repeatcnt++ > EFUSE_REPEAT_THRESHOLD_) { return false; } else { efuse_addr++; continue; } } else if (pg_header != tmp_header) { /* offset PG fail */ struct pgpkt fixPkt; fixPkt.offset = ((pg_header_temp & 0xE0) >> 5) | ((tmp_header & 0xF0) >> 1); fixPkt.word_en = tmp_header & 0x0F; fixPkt.word_cnts = Efuse_CalculateWordCnts(fixPkt.word_en); if (!hal_EfuseFixHeaderProcess(pAdapter, efuseType, &fixPkt, &efuse_addr)) return false; } else { bRet = true; break; } } else if ((tmp_header & 0x1F) == 0x0F) { /* wrong extended header */ efuse_addr += 2; continue; } } *pAddr = efuse_addr; return bRet; } static bool hal_EfusePgPacketWrite1ByteHeader(struct adapter *pAdapter, u8 efuseType, u16 *pAddr, struct pgpkt *pTargetPkt) { bool bRet = false; u8 pg_header = 0, tmp_header = 0; u16 efuse_addr = *pAddr; u8 repeatcnt = 0; pg_header = ((pTargetPkt->offset << 4) & 0xf0) | pTargetPkt->word_en; efuse_OneByteWrite(pAdapter, efuse_addr, pg_header); efuse_OneByteRead(pAdapter, efuse_addr, &tmp_header); while (tmp_header == 0xFF) { if (repeatcnt++ > EFUSE_REPEAT_THRESHOLD_) return false; efuse_OneByteWrite(pAdapter, efuse_addr, pg_header); efuse_OneByteRead(pAdapter, efuse_addr, &tmp_header); } if (pg_header == tmp_header) { bRet = true; } else { struct pgpkt fixPkt; fixPkt.offset = (tmp_header>>4) & 0x0F; fixPkt.word_en = tmp_header & 0x0F; fixPkt.word_cnts = Efuse_CalculateWordCnts(fixPkt.word_en); if (!hal_EfuseFixHeaderProcess(pAdapter, efuseType, &fixPkt, &efuse_addr)) return false; } *pAddr = efuse_addr; return bRet; } static bool hal_EfusePgPacketWriteData(struct adapter *pAdapter, u8 efuseType, u16 *pAddr, struct pgpkt *pTargetPkt) { u16 efuse_addr = *pAddr; u8 badworden = 0; u32 PgWriteSuccess = 0; badworden = 0x0f; badworden = Efuse_WordEnableDataWrite(pAdapter, efuse_addr+1, pTargetPkt->word_en, pTargetPkt->data); if (badworden == 0x0F) { /* write ok */ return true; } else { /* reorganize other pg packet */ PgWriteSuccess = Efuse_PgPacketWrite(pAdapter, pTargetPkt->offset, badworden, pTargetPkt->data); if (!PgWriteSuccess) return false; else return true; } } static bool hal_EfusePgPacketWriteHeader( struct adapter *pAdapter, u8 efuseType, u16 *pAddr, struct pgpkt *pTargetPkt) { bool bRet = false; if (pTargetPkt->offset >= EFUSE_MAX_SECTION_BASE) bRet = hal_EfusePgPacketWrite2ByteHeader(pAdapter, efuseType, pAddr, pTargetPkt); else bRet = hal_EfusePgPacketWrite1ByteHeader(pAdapter, efuseType, pAddr, pTargetPkt); return bRet; } static bool wordEnMatched(struct pgpkt *pTargetPkt, struct pgpkt *pCurPkt, u8 *pWden) { u8 match_word_en = 0x0F; /* default all words are disabled */ /* check if the same words are enabled both target and current PG packet */ if (((pTargetPkt->word_en & BIT0) == 0) && ((pCurPkt->word_en & BIT0) == 0)) match_word_en &= ~BIT0; /* enable word 0 */ if (((pTargetPkt->word_en & BIT1) == 0) && ((pCurPkt->word_en & BIT1) == 0)) match_word_en &= ~BIT1; /* enable word 1 */ if (((pTargetPkt->word_en & BIT2) == 0) && ((pCurPkt->word_en & BIT2) == 0)) match_word_en &= ~BIT2; /* enable word 2 */ if (((pTargetPkt->word_en & BIT3) == 0) && ((pCurPkt->word_en & BIT3) == 0)) match_word_en &= ~BIT3; /* enable word 3 */ *pWden = match_word_en; if (match_word_en != 0xf) return true; else return false; } static bool hal_EfuseCheckIfDatafollowed(struct adapter *pAdapter, u8 word_cnts, u16 startAddr) { bool bRet = false; u8 i, efuse_data; for (i = 0; i < (word_cnts*2); i++) { if (efuse_OneByteRead(pAdapter, (startAddr+i), &efuse_data) && (efuse_data != 0xFF)) bRet = true; } return bRet; } static bool hal_EfusePartialWriteCheck(struct adapter *pAdapter, u8 efuseType, u16 *pAddr, struct pgpkt *pTargetPkt) { bool bRet = false; u8 i, efuse_data = 0, cur_header = 0; u8 matched_wden = 0, badworden = 0; u16 startAddr = 0, efuse_max_available_len = 0, efuse_max = 0; struct pgpkt curPkt; EFUSE_GetEfuseDefinition(pAdapter, efuseType, TYPE_AVAILABLE_EFUSE_BYTES_BANK, (void *)&efuse_max_available_len); EFUSE_GetEfuseDefinition(pAdapter, efuseType, TYPE_EFUSE_REAL_CONTENT_LEN, (void *)&efuse_max); rtw_hal_get_hwreg(pAdapter, HW_VAR_EFUSE_BYTES, (u8 *)&startAddr); startAddr %= EFUSE_REAL_CONTENT_LEN; while (1) { if (startAddr >= efuse_max_available_len) { bRet = false; break; } if (efuse_OneByteRead(pAdapter, startAddr, &efuse_data) && (efuse_data != 0xFF)) { if (EXT_HEADER(efuse_data)) { cur_header = efuse_data; startAddr++; efuse_OneByteRead(pAdapter, startAddr, &efuse_data); if (ALL_WORDS_DISABLED(efuse_data)) { bRet = false; break; } else { curPkt.offset = ((cur_header & 0xE0) >> 5) | ((efuse_data & 0xF0) >> 1); curPkt.word_en = efuse_data & 0x0F; } } else { cur_header = efuse_data; curPkt.offset = (cur_header>>4) & 0x0F; curPkt.word_en = cur_header & 0x0F; } curPkt.word_cnts = Efuse_CalculateWordCnts(curPkt.word_en); /* if same header is found but no data followed */ /* write some part of data followed by the header. */ if ((curPkt.offset == pTargetPkt->offset) && (!hal_EfuseCheckIfDatafollowed(pAdapter, curPkt.word_cnts, startAddr+1)) && wordEnMatched(pTargetPkt, &curPkt, &matched_wden)) { /* Here to write partial data */ badworden = Efuse_WordEnableDataWrite(pAdapter, startAddr+1, matched_wden, pTargetPkt->data); if (badworden != 0x0F) { u32 PgWriteSuccess = 0; /* if write fail on some words, write these bad words again */ PgWriteSuccess = Efuse_PgPacketWrite(pAdapter, pTargetPkt->offset, badworden, pTargetPkt->data); if (!PgWriteSuccess) { bRet = false; /* write fail, return */ break; } } /* partial write ok, update the target packet for later use */ for (i = 0; i < 4; i++) { if ((matched_wden & (0x1<word_en |= (0x1<word_cnts = Efuse_CalculateWordCnts(pTargetPkt->word_en); } /* read from next header */ startAddr = startAddr + (curPkt.word_cnts*2) + 1; } else { /* not used header, 0xff */ *pAddr = startAddr; bRet = true; break; } } return bRet; } static bool hal_EfusePgCheckAvailableAddr( struct adapter *pAdapter, u8 efuseType ) { u16 efuse_max_available_len = 0; /* Change to check TYPE_EFUSE_MAP_LEN , because 8188E raw 256, logic map over 256. */ EFUSE_GetEfuseDefinition(pAdapter, EFUSE_WIFI, TYPE_EFUSE_MAP_LEN, (void *)&efuse_max_available_len); if (Efuse_GetCurrentSize(pAdapter) >= efuse_max_available_len) return false; return true; } static void hal_EfuseConstructPGPkt(u8 offset, u8 word_en, u8 *pData, struct pgpkt *pTargetPkt) { memset((void *)pTargetPkt->data, 0xFF, sizeof(u8)*8); pTargetPkt->offset = offset; pTargetPkt->word_en = word_en; efuse_WordEnableDataRead(word_en, pData, pTargetPkt->data); pTargetPkt->word_cnts = Efuse_CalculateWordCnts(pTargetPkt->word_en); } bool Efuse_PgPacketWrite(struct adapter *pAdapter, u8 offset, u8 word_en, u8 *pData) { struct pgpkt targetPkt; u16 startAddr = 0; u8 efuseType = EFUSE_WIFI; if (!hal_EfusePgCheckAvailableAddr(pAdapter, efuseType)) return false; hal_EfuseConstructPGPkt(offset, word_en, pData, &targetPkt); if (!hal_EfusePartialWriteCheck(pAdapter, efuseType, &startAddr, &targetPkt)) return false; if (!hal_EfusePgPacketWriteHeader(pAdapter, efuseType, &startAddr, &targetPkt)) return false; if (!hal_EfusePgPacketWriteData(pAdapter, efuseType, &startAddr, &targetPkt)) return false; return true; } u8 Efuse_CalculateWordCnts(u8 word_en) { u8 word_cnts = 0; if (!(word_en & BIT(0))) word_cnts++; /* 0 : write enable */ if (!(word_en & BIT(1))) word_cnts++; if (!(word_en & BIT(2))) word_cnts++; if (!(word_en & BIT(3))) word_cnts++; return word_cnts; } u8 efuse_OneByteRead(struct adapter *pAdapter, u16 addr, u8 *data) { u8 tmpidx = 0; u8 result; usb_write8(pAdapter, EFUSE_CTRL+1, (u8)(addr & 0xff)); usb_write8(pAdapter, EFUSE_CTRL+2, ((u8)((addr>>8) & 0x03)) | (usb_read8(pAdapter, EFUSE_CTRL+2) & 0xFC)); usb_write8(pAdapter, EFUSE_CTRL+3, 0x72);/* read cmd */ while (!(0x80 & usb_read8(pAdapter, EFUSE_CTRL+3)) && (tmpidx < 100)) tmpidx++; if (tmpidx < 100) { *data = usb_read8(pAdapter, EFUSE_CTRL); result = true; } else { *data = 0xff; result = false; } return result; } u8 efuse_OneByteWrite(struct adapter *pAdapter, u16 addr, u8 data) { u8 tmpidx = 0; u8 result; usb_write8(pAdapter, EFUSE_CTRL+1, (u8)(addr&0xff)); usb_write8(pAdapter, EFUSE_CTRL+2, (usb_read8(pAdapter, EFUSE_CTRL+2) & 0xFC) | (u8)((addr>>8) & 0x03)); usb_write8(pAdapter, EFUSE_CTRL, data);/* data */ usb_write8(pAdapter, EFUSE_CTRL+3, 0xF2);/* write cmd */ while ((0x80 & usb_read8(pAdapter, EFUSE_CTRL+3)) && (tmpidx < 100)) tmpidx++; if (tmpidx < 100) result = true; else result = false; return result; } /* * Overview: Read allowed word in current efuse section data. */ void efuse_WordEnableDataRead(u8 word_en, u8 *sourdata, u8 *targetdata) { if (!(word_en&BIT(0))) { targetdata[0] = sourdata[0]; targetdata[1] = sourdata[1]; } if (!(word_en&BIT(1))) { targetdata[2] = sourdata[2]; targetdata[3] = sourdata[3]; } if (!(word_en&BIT(2))) { targetdata[4] = sourdata[4]; targetdata[5] = sourdata[5]; } if (!(word_en&BIT(3))) { targetdata[6] = sourdata[6]; targetdata[7] = sourdata[7]; } } /* * Overview: Read All Efuse content */ static void Efuse_ReadAllMap(struct adapter *pAdapter, u8 efuseType, u8 *Efuse) { u16 mapLen = 0; Efuse_PowerSwitch(pAdapter, false, true); EFUSE_GetEfuseDefinition(pAdapter, efuseType, TYPE_EFUSE_MAP_LEN, (void *)&mapLen); efuse_ReadEFuse(pAdapter, efuseType, 0, mapLen, Efuse); Efuse_PowerSwitch(pAdapter, false, false); } /* * Overview: Transfer current EFUSE content to shadow init and modify map. */ void EFUSE_ShadowMapUpdate( struct adapter *pAdapter, u8 efuseType) { struct eeprom_priv *pEEPROM = GET_EEPROM_EFUSE_PRIV(pAdapter); u16 mapLen = 0; EFUSE_GetEfuseDefinition(pAdapter, efuseType, TYPE_EFUSE_MAP_LEN, (void *)&mapLen); if (pEEPROM->bautoload_fail_flag) memset(pEEPROM->efuse_eeprom_data, 0xFF, mapLen); else Efuse_ReadAllMap(pAdapter, efuseType, pEEPROM->efuse_eeprom_data); }