/****************************************************************************** * * Name: skvpd.c * Project: GEnesis, PCI Gigabit Ethernet Adapter * Purpose: Shared software to read and write VPD data * ******************************************************************************/ /****************************************************************************** * * (C)Copyright 1998-2003 SysKonnect GmbH. * * 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. * * The information in this file is provided "AS IS" without warranty. * ******************************************************************************/ /* Please refer skvpd.txt for infomation how to include this module */ static const char SysKonnectFileId[] = "@(#)$Id: skvpd.c,v 1.37 2003/01/13 10:42:45 rschmidt Exp $ (C) SK"; #include "h/skdrv1st.h" #include "h/sktypes.h" #include "h/skdebug.h" #include "h/skdrv2nd.h" /* * Static functions */ #ifndef SK_KR_PROTO static SK_VPD_PARA *vpd_find_para( SK_AC *pAC, const char *key, SK_VPD_PARA *p); #else /* SK_KR_PROTO */ static SK_VPD_PARA *vpd_find_para(); #endif /* SK_KR_PROTO */ /* * waits for a completion of a VPD transfer * The VPD transfer must complete within SK_TICKS_PER_SEC/16 * * returns 0: success, transfer completes * error exit(9) with a error message */ static int VpdWait( SK_AC *pAC, /* Adapters context */ SK_IOC IoC, /* IO Context */ int event) /* event to wait for (VPD_READ / VPD_write) completion*/ { SK_U64 start_time; SK_U16 state; SK_DBG_MSG(pAC,SK_DBGMOD_VPD, SK_DBGCAT_CTRL, ("VPD wait for %s\n", event?"Write":"Read")); start_time = SkOsGetTime(pAC); do { if (SkOsGetTime(pAC) - start_time > SK_TICKS_PER_SEC) { /* Bug fix AF: Thu Mar 28 2002 * Do not call: VPD_STOP(pAC, IoC); * A pending VPD read cycle can not be aborted by writing * VPD_WRITE to the PCI_VPD_ADR_REG (VPD address register). * Although the write threshold in the OUR-register protects * VPD read only space from being overwritten this does not * protect a VPD read from being `converted` into a VPD write * operation (on the fly). As a consequence the VPD_STOP would * delete VPD read only data. In case of any problems with the * I2C bus we exit the loop here. The I2C read operation can * not be aborted except by a reset (->LR). */ SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_FATAL | SK_DBGCAT_ERR, ("ERROR:VPD wait timeout\n")); return(1); } VPD_IN16(pAC, IoC, PCI_VPD_ADR_REG, &state); SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_CTRL, ("state = %x, event %x\n",state,event)); } while((int)(state & PCI_VPD_FLAG) == event); return(0); } #ifdef SKDIAG /* * Read the dword at address 'addr' from the VPD EEPROM. * * Needed Time: MIN 1,3 ms MAX 2,6 ms * * Note: The DWord is returned in the endianess of the machine the routine * is running on. * * Returns the data read. */ SK_U32 VpdReadDWord( SK_AC *pAC, /* Adapters context */ SK_IOC IoC, /* IO Context */ int addr) /* VPD address */ { SK_U32 Rtv; /* start VPD read */ SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_CTRL, ("VPD read dword at 0x%x\n",addr)); addr &= ~VPD_WRITE; /* ensure the R/W bit is set to read */ VPD_OUT16(pAC, IoC, PCI_VPD_ADR_REG, (SK_U16)addr); /* ignore return code here */ (void)VpdWait(pAC, IoC, VPD_READ); /* Don't swap here, it's a data stream of bytes */ Rtv = 0; VPD_IN32(pAC, IoC, PCI_VPD_DAT_REG, &Rtv); SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_CTRL, ("VPD read dword data = 0x%x\n",Rtv)); return(Rtv); } #endif /* SKDIAG */ #if 0 /* Write the dword 'data' at address 'addr' into the VPD EEPROM, and verify that the data is written. Needed Time: . MIN MAX . ------------------------------------------------------------------- . write 1.8 ms 3.6 ms . internal write cyles 0.7 ms 7.0 ms . ------------------------------------------------------------------- . over all program time 2.5 ms 10.6 ms . read 1.3 ms 2.6 ms . ------------------------------------------------------------------- . over all 3.8 ms 13.2 ms . Returns 0: success 1: error, I2C transfer does not terminate 2: error, data verify error */ static int VpdWriteDWord( SK_AC *pAC, /* pAC pointer */ SK_IOC IoC, /* IO Context */ int addr, /* VPD address */ SK_U32 data) /* VPD data to write */ { /* start VPD write */ /* Don't swap here, it's a data stream of bytes */ SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_CTRL, ("VPD write dword at addr 0x%x, data = 0x%x\n",addr,data)); VPD_OUT32(pAC, IoC, PCI_VPD_DAT_REG, (SK_U32)data); /* But do it here */ addr |= VPD_WRITE; VPD_OUT16(pAC, IoC, PCI_VPD_ADR_REG, (SK_U16)(addr | VPD_WRITE)); /* this may take up to 10,6 ms */ if (VpdWait(pAC, IoC, VPD_WRITE)) { SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_ERR, ("Write Timed Out\n")); return(1); }; /* verify data */ if (VpdReadDWord(pAC, IoC, addr) != data) { SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_ERR | SK_DBGCAT_FATAL, ("Data Verify Error\n")); return(2); } return(0); } /* VpdWriteDWord */ #endif /* 0 */ /* * Read one Stream of 'len' bytes of VPD data, starting at 'addr' from * or to the I2C EEPROM. * * Returns number of bytes read / written. */ static int VpdWriteStream( SK_AC *pAC, /* Adapters context */ SK_IOC IoC, /* IO Context */ char *buf, /* data buffer */ int Addr, /* VPD start address */ int Len) /* number of bytes to read / to write */ { int i; int j; SK_U16 AdrReg; int Rtv; SK_U8 * pComp; /* Compare pointer */ SK_U8 Data; /* Input Data for Compare */ /* Init Compare Pointer */ pComp = (SK_U8 *) buf; for (i = 0; i < Len; i++, buf++) { if ((i%sizeof(SK_U32)) == 0) { /* * At the begin of each cycle read the Data Reg * So it is initialized even if only a few bytes * are written. */ AdrReg = (SK_U16) Addr; AdrReg &= ~VPD_WRITE; /* READ operation */ VPD_OUT16(pAC, IoC, PCI_VPD_ADR_REG, AdrReg); /* Wait for termination */ Rtv = VpdWait(pAC, IoC, VPD_READ); if (Rtv != 0) { return(i); } } /* Write current Byte */ VPD_OUT8(pAC, IoC, PCI_VPD_DAT_REG + (i%sizeof(SK_U32)), *(SK_U8*)buf); if (((i%sizeof(SK_U32)) == 3) || (i == (Len - 1))) { /* New Address needs to be written to VPD_ADDR reg */ AdrReg = (SK_U16) Addr; Addr += sizeof(SK_U32); AdrReg |= VPD_WRITE; /* WRITE operation */ VPD_OUT16(pAC, IoC, PCI_VPD_ADR_REG, AdrReg); /* Wait for termination */ Rtv = VpdWait(pAC, IoC, VPD_WRITE); if (Rtv != 0) { SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_ERR, ("Write Timed Out\n")); return(i - (i%sizeof(SK_U32))); } /* * Now re-read to verify */ AdrReg &= ~VPD_WRITE; /* READ operation */ VPD_OUT16(pAC, IoC, PCI_VPD_ADR_REG, AdrReg); /* Wait for termination */ Rtv = VpdWait(pAC, IoC, VPD_READ); if (Rtv != 0) { SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_ERR, ("Verify Timed Out\n")); return(i - (i%sizeof(SK_U32))); } for (j = 0; j <= (int)(i%sizeof(SK_U32)); j++, pComp++) { VPD_IN8(pAC, IoC, PCI_VPD_DAT_REG + j, &Data); if (Data != *pComp) { /* Verify Error */ SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_ERR, ("WriteStream Verify Error\n")); return(i - (i%sizeof(SK_U32)) + j); } } } } return(Len); } /* * Read one Stream of 'len' bytes of VPD data, starting at 'addr' from * or to the I2C EEPROM. * * Returns number of bytes read / written. */ static int VpdReadStream( SK_AC *pAC, /* Adapters context */ SK_IOC IoC, /* IO Context */ char *buf, /* data buffer */ int Addr, /* VPD start address */ int Len) /* number of bytes to read / to write */ { int i; SK_U16 AdrReg; int Rtv; for (i = 0; i < Len; i++, buf++) { if ((i%sizeof(SK_U32)) == 0) { /* New Address needs to be written to VPD_ADDR reg */ AdrReg = (SK_U16) Addr; Addr += sizeof(SK_U32); AdrReg &= ~VPD_WRITE; /* READ operation */ VPD_OUT16(pAC, IoC, PCI_VPD_ADR_REG, AdrReg); /* Wait for termination */ Rtv = VpdWait(pAC, IoC, VPD_READ); if (Rtv != 0) { return(i); } } VPD_IN8(pAC, IoC, PCI_VPD_DAT_REG + (i%sizeof(SK_U32)), (SK_U8 *)buf); } return(Len); } /* * Read ore writes 'len' bytes of VPD data, starting at 'addr' from * or to the I2C EEPROM. * * Returns number of bytes read / written. */ static int VpdTransferBlock( SK_AC *pAC, /* Adapters context */ SK_IOC IoC, /* IO Context */ char *buf, /* data buffer */ int addr, /* VPD start address */ int len, /* number of bytes to read / to write */ int dir) /* transfer direction may be VPD_READ or VPD_WRITE */ { int Rtv; /* Return value */ int vpd_rom_size; SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_CTRL, ("VPD %s block, addr = 0x%x, len = %d\n", dir ? "write" : "read", addr, len)); if (len == 0) return(0); vpd_rom_size = pAC->vpd.rom_size; if (addr > vpd_rom_size - 4) { SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_ERR | SK_DBGCAT_FATAL, ("Address error: 0x%x, exp. < 0x%x\n", addr, vpd_rom_size - 4)); return(0); } if (addr + len > vpd_rom_size) { len = vpd_rom_size - addr; SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_ERR, ("Warning: len was cut to %d\n", len)); } if (dir == VPD_READ) { Rtv = VpdReadStream(pAC, IoC, buf, addr, len); } else { Rtv = VpdWriteStream(pAC, IoC, buf, addr, len); } return(Rtv); } #ifdef SKDIAG /* * Read 'len' bytes of VPD data, starting at 'addr'. * * Returns number of bytes read. */ int VpdReadBlock( SK_AC *pAC, /* pAC pointer */ SK_IOC IoC, /* IO Context */ char *buf, /* buffer were the data should be stored */ int addr, /* start reading at the VPD address */ int len) /* number of bytes to read */ { return(VpdTransferBlock(pAC, IoC, buf, addr, len, VPD_READ)); } /* * Write 'len' bytes of *but to the VPD EEPROM, starting at 'addr'. * * Returns number of bytes writes. */ int VpdWriteBlock( SK_AC *pAC, /* pAC pointer */ SK_IOC IoC, /* IO Context */ char *buf, /* buffer, holds the data to write */ int addr, /* start writing at the VPD address */ int len) /* number of bytes to write */ { return(VpdTransferBlock(pAC, IoC, buf, addr, len, VPD_WRITE)); } #endif /* SKDIAG */ /* * (re)initialize the VPD buffer * * Reads the VPD data from the EEPROM into the VPD buffer. * Get the remaining read only and read / write space. * * return 0: success * 1: fatal VPD error */ static int VpdInit( SK_AC *pAC, /* Adapters context */ SK_IOC IoC) /* IO Context */ { SK_VPD_PARA *r, rp; /* RW or RV */ int i; unsigned char x; int vpd_size; SK_U16 dev_id; SK_U32 our_reg2; SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_INIT, ("VpdInit .. ")); VPD_IN16(pAC, IoC, PCI_DEVICE_ID, &dev_id); VPD_IN32(pAC, IoC, PCI_OUR_REG_2, &our_reg2); pAC->vpd.rom_size = 256 << ((our_reg2 & PCI_VPD_ROM_SZ) >> 14); /* * this function might get used before the hardware is initialized * therefore we cannot always trust in GIChipId */ if (((pAC->vpd.v.vpd_status & VPD_VALID) == 0 && dev_id != VPD_DEV_ID_GENESIS) || ((pAC->vpd.v.vpd_status & VPD_VALID) != 0 && !pAC->GIni.GIGenesis)) { /* for Yukon the VPD size is always 256 */ vpd_size = VPD_SIZE_YUKON; } else { /* Genesis uses the maximum ROM size up to 512 for VPD */ if (pAC->vpd.rom_size > VPD_SIZE_GENESIS) { vpd_size = VPD_SIZE_GENESIS; } else { vpd_size = pAC->vpd.rom_size; } } /* read the VPD data into the VPD buffer */ if (VpdTransferBlock(pAC, IoC, pAC->vpd.vpd_buf, 0, vpd_size, VPD_READ) != vpd_size) { SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_ERR, ("Block Read Error\n")); return(1); } pAC->vpd.vpd_size = vpd_size; /* Asus K8V Se Deluxe bugfix. Correct VPD content */ /* MBo April 2004 */ if( ((unsigned char)pAC->vpd.vpd_buf[0x3f] == 0x38) && ((unsigned char)pAC->vpd.vpd_buf[0x40] == 0x3c) && ((unsigned char)pAC->vpd.vpd_buf[0x41] == 0x45) ) { printk(KERN_INFO "sk98lin : humm... Asus mainboard with buggy VPD ? correcting data.\n"); pAC->vpd.vpd_buf[0x40] = 0x38; } /* find the end tag of the RO area */ if (!(r = vpd_find_para(pAC, VPD_RV, &rp))) { SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_ERR | SK_DBGCAT_FATAL, ("Encoding Error: RV Tag not found\n")); return(1); } if (r->p_val + r->p_len > pAC->vpd.vpd_buf + vpd_size/2) { SK_DBG_MSG(pAC,SK_DBGMOD_VPD,SK_DBGCAT_ERR | SK_DBGCAT_FATAL, ("Encoding Error: Invalid VPD struct size\n")); return(1); } pAC->vpd.v.vpd_free_ro = r->p_len - 1; /* test the checksum */ for (i = 0, x = 0; (unsigned)i <= (unsigned)vpd_size/2 - r->p_len; i++) { x += pAC->vpd.vpd_buf[i]; } if (x != 0) { /* checksum error */ SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_ERR | SK_DBGCAT_FATAL, ("VPD Checksum Error\n")); return(1); } /* find and check the end tag of the RW area */ if (!(r = vpd_find_para(pAC, VPD_RW, &rp))) { SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_ERR | SK_DBGCAT_FATAL, ("Encoding Error: RV Tag not found\n")); return(1); } if (r->p_val < pAC->vpd.vpd_buf + vpd_size/2) { SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_ERR | SK_DBGCAT_FATAL, ("Encoding Error: Invalid VPD struct size\n")); return(1); } pAC->vpd.v.vpd_free_rw = r->p_len; /* everything seems to be ok */ if (pAC->GIni.GIChipId != 0) { pAC->vpd.v.vpd_status |= VPD_VALID; } SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_INIT, ("done. Free RO = %d, Free RW = %d\n", pAC->vpd.v.vpd_free_ro, pAC->vpd.v.vpd_free_rw)); return(0); } /* * find the Keyword 'key' in the VPD buffer and fills the * parameter struct 'p' with it's values * * returns *p success * 0: parameter was not found or VPD encoding error */ static SK_VPD_PARA *vpd_find_para( SK_AC *pAC, /* common data base */ const char *key, /* keyword to find (e.g. "MN") */ SK_VPD_PARA *p) /* parameter description struct */ { char *v ; /* points to VPD buffer */ int max; /* Maximum Number of Iterations */ v = pAC->vpd.vpd_buf; max = 128; SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_CTRL, ("VPD find para %s .. ",key)); /* check mandatory resource type ID string (Product Name) */ if (*v != (char)RES_ID) { SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_ERR | SK_DBGCAT_FATAL, ("Error: 0x%x missing\n", RES_ID)); return(0); } if (strcmp(key, VPD_NAME) == 0) { p->p_len = VPD_GET_RES_LEN(v); p->p_val = VPD_GET_VAL(v); SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_CTRL, ("found, len = %d\n", p->p_len)); return(p); } v += 3 + VPD_GET_RES_LEN(v) + 3; for (;; ) { if (SK_MEMCMP(key,v,2) == 0) { p->p_len = VPD_GET_VPD_LEN(v); p->p_val = VPD_GET_VAL(v); SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_CTRL, ("found, len = %d\n",p->p_len)); return(p); } /* exit when reaching the "RW" Tag or the maximum of itera. */ max--; if (SK_MEMCMP(VPD_RW,v,2) == 0 || max == 0) { break; } if (SK_MEMCMP(VPD_RV,v,2) == 0) { v += 3 + VPD_GET_VPD_LEN(v) + 3; /* skip VPD-W */ } else { v += 3 + VPD_GET_VPD_LEN(v); } SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_CTRL, ("scanning '%c%c' len = %d\n",v[0],v[1],v[2])); } #ifdef DEBUG SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_CTRL, ("not found\n")); if (max == 0) { SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_ERR | SK_DBGCAT_FATAL, ("Key/Len Encoding error\n")); } #endif /* DEBUG */ return(0); } /* * Move 'n' bytes. Begin with the last byte if 'n' is > 0, * Start with the last byte if n is < 0. * * returns nothing */ static void vpd_move_para( char *start, /* start of memory block */ char *end, /* end of memory block to move */ int n) /* number of bytes the memory block has to be moved */ { char *p; int i; /* number of byte copied */ if (n == 0) return; i = (int) (end - start + 1); if (n < 0) { p = start + n; while (i != 0) { *p++ = *start++; i--; } } else { p = end + n; while (i != 0) { *p-- = *end--; i--; } } } /* * setup the VPD keyword 'key' at 'ip'. * * returns nothing */ static void vpd_insert_key( const char *key, /* keyword to insert */ const char *buf, /* buffer with the keyword value */ int len, /* length of the value string */ char *ip) /* inseration point */ { SK_VPD_KEY *p; p = (SK_VPD_KEY *) ip; p->p_key[0] = key[0]; p->p_key[1] = key[1]; p->p_len = (unsigned char) len; SK_MEMCPY(&p->p_val,buf,len); } /* * Setup the VPD end tag "RV" / "RW". * Also correct the remaining space variables vpd_free_ro / vpd_free_rw. * * returns 0: success * 1: encoding error */ static int vpd_mod_endtag( SK_AC *pAC, /* common data base */ char *etp) /* end pointer input position */ { SK_VPD_KEY *p; unsigned char x; int i; int vpd_size; SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_CTRL, ("VPD modify endtag at 0x%x = '%c%c'\n",etp,etp[0],etp[1])); vpd_size = pAC->vpd.vpd_size; p = (SK_VPD_KEY *) etp; if (p->p_key[0] != 'R' || (p->p_key[1] != 'V' && p->p_key[1] != 'W')) { /* something wrong here, encoding error */ SK_DBG_MSG(pAC,SK_DBGMOD_VPD,SK_DBGCAT_ERR | SK_DBGCAT_FATAL, ("Encoding Error: invalid end tag\n")); return(1); } if (etp > pAC->vpd.vpd_buf + vpd_size/2) { /* create "RW" tag */ p->p_len = (unsigned char)(pAC->vpd.vpd_buf+vpd_size-etp-3-1); pAC->vpd.v.vpd_free_rw = (int) p->p_len; i = pAC->vpd.v.vpd_free_rw; etp += 3; } else { /* create "RV" tag */ p->p_len = (unsigned char)(pAC->vpd.vpd_buf+vpd_size/2-etp-3); pAC->vpd.v.vpd_free_ro = (int) p->p_len - 1; /* setup checksum */ for (i = 0, x = 0; i < vpd_size/2 - p->p_len; i++) { x += pAC->vpd.vpd_buf[i]; } p->p_val = (char) 0 - x; i = pAC->vpd.v.vpd_free_ro; etp += 4; } while (i) { *etp++ = 0x00; i--; } return(0); } /* * Insert a VPD keyword into the VPD buffer. * * The keyword 'key' is inserted at the position 'ip' in the * VPD buffer. * The keywords behind the input position will * be moved. The VPD end tag "RV" or "RW" is generated again. * * returns 0: success * 2: value string was cut * 4: VPD full, keyword was not written * 6: fatal VPD error * */ int VpdSetupPara( SK_AC *pAC, /* common data base */ const char *key, /* keyword to insert */ const char *buf, /* buffer with the keyword value */ int len, /* length of the keyword value */ int type, /* VPD_RO_KEY or VPD_RW_KEY */ int op) /* operation to do: ADD_KEY or OWR_KEY */ { SK_VPD_PARA vp; char *etp; /* end tag position */ int free; /* remaining space in selected area */ char *ip; /* input position inside the VPD buffer */ int rtv; /* return code */ int head; /* additional haeder bytes to move */ int found; /* additinoal bytes if the keyword was found */ int vpd_size; SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_CTRL, ("VPD setup para key = %s, val = %s\n",key,buf)); vpd_size = pAC->vpd.vpd_size; rtv = 0; ip = 0; if (type == VPD_RW_KEY) { /* end tag is "RW" */ free = pAC->vpd.v.vpd_free_rw; etp = pAC->vpd.vpd_buf + (vpd_size - free - 1 - 3); } else { /* end tag is "RV" */ free = pAC->vpd.v.vpd_free_ro; etp = pAC->vpd.vpd_buf + (vpd_size/2 - free - 4); } SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_CTRL, ("Free RO = %d, Free RW = %d\n", pAC->vpd.v.vpd_free_ro, pAC->vpd.v.vpd_free_rw)); head = 0; found = 0; if (op == OWR_KEY) { if (vpd_find_para(pAC, key, &vp)) { found = 3; ip = vp.p_val - 3; free += vp.p_len + 3; SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_CTRL, ("Overwrite Key\n")); } else { op = ADD_KEY; SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_CTRL, ("Add Key\n")); } } if (op == ADD_KEY) { ip = etp; vp.p_len = 0; head = 3; } if (len + 3 > free) { if (free < 7) { SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_ERR, ("VPD Buffer Overflow, keyword not written\n")); return(4); } /* cut it again */ len = free - 3; rtv = 2; SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_ERR, ("VPD Buffer Full, Keyword was cut\n")); } vpd_move_para(ip + vp.p_len + found, etp+2, len-vp.p_len+head); vpd_insert_key(key, buf, len, ip); if (vpd_mod_endtag(pAC, etp + len - vp.p_len + head)) { pAC->vpd.v.vpd_status &= ~VPD_VALID; SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_ERR, ("VPD Encoding Error\n")); return(6); } return(rtv); } /* * Read the contents of the VPD EEPROM and copy it to the * VPD buffer if not already done. * * return: A pointer to the vpd_status structure. The structure contains * this fields. */ SK_VPD_STATUS *VpdStat( SK_AC *pAC, /* Adapters context */ SK_IOC IoC) /* IO Context */ { if ((pAC->vpd.v.vpd_status & VPD_VALID) == 0) { (void)VpdInit(pAC, IoC); } return(&pAC->vpd.v); } /* * Read the contents of the VPD EEPROM and copy it to the VPD * buffer if not already done. * Scan the VPD buffer for VPD keywords and create the VPD * keyword list by copying the keywords to 'buf', all after * each other and terminated with a '\0'. * * Exceptions: o The Resource Type ID String (product name) is called "Name" * o The VPD end tags 'RV' and 'RW' are not listed * * The number of copied keywords is counted in 'elements'. * * returns 0: success * 2: buffer overfull, one or more keywords are missing * 6: fatal VPD error * * example values after returning: * * buf = "Name\0PN\0EC\0MN\0SN\0CP\0VF\0VL\0YA\0" * *len = 30 * *elements = 9 */ int VpdKeys( SK_AC *pAC, /* common data base */ SK_IOC IoC, /* IO Context */ char *buf, /* buffer where to copy the keywords */ int *len, /* buffer length */ int *elements) /* number of keywords returned */ { char *v; int n; SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_RX, ("list VPD keys .. ")); *elements = 0; if ((pAC->vpd.v.vpd_status & VPD_VALID) == 0) { if (VpdInit(pAC, IoC) != 0) { *len = 0; SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_ERR, ("VPD Init Error, terminated\n")); return(6); } } if ((signed)strlen(VPD_NAME) + 1 <= *len) { v = pAC->vpd.vpd_buf; strcpy(buf,VPD_NAME); n = strlen(VPD_NAME) + 1; buf += n; *elements = 1; SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_RX, ("'%c%c' ",v[0],v[1])); } else { *len = 0; SK_DBG_MSG(pAC,SK_DBGMOD_VPD,SK_DBGCAT_ERR, ("buffer overflow\n")); return(2); } v += 3 + VPD_GET_RES_LEN(v) + 3; for (;; ) { /* exit when reaching the "RW" Tag */ if (SK_MEMCMP(VPD_RW,v,2) == 0) { break; } if (SK_MEMCMP(VPD_RV,v,2) == 0) { v += 3 + VPD_GET_VPD_LEN(v) + 3; /* skip VPD-W */ continue; } if (n+3 <= *len) { SK_MEMCPY(buf,v,2); buf += 2; *buf++ = '\0'; n += 3; v += 3 + VPD_GET_VPD_LEN(v); *elements += 1; SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_RX, ("'%c%c' ",v[0],v[1])); } else { *len = n; SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_ERR, ("buffer overflow\n")); return(2); } } SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_RX, ("\n")); *len = n; return(0); } /* * Read the contents of the VPD EEPROM and copy it to the * VPD buffer if not already done. Search for the VPD keyword * 'key' and copy its value to 'buf'. Add a terminating '\0'. * If the value does not fit into the buffer cut it after * 'len' - 1 bytes. * * returns 0: success * 1: keyword not found * 2: value string was cut * 3: VPD transfer timeout * 6: fatal VPD error */ int VpdRead( SK_AC *pAC, /* common data base */ SK_IOC IoC, /* IO Context */ const char *key, /* keyword to read (e.g. "MN") */ char *buf, /* buffer where to copy the keyword value */ int *len) /* buffer length */ { SK_VPD_PARA *p, vp; SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_RX, ("VPD read %s .. ", key)); if ((pAC->vpd.v.vpd_status & VPD_VALID) == 0) { if (VpdInit(pAC, IoC) != 0) { *len = 0; SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_ERR, ("VPD init error\n")); return(6); } } if ((p = vpd_find_para(pAC, key, &vp)) != NULL) { if (p->p_len > (*(unsigned *)len)-1) { p->p_len = *len - 1; } SK_MEMCPY(buf, p->p_val, p->p_len); buf[p->p_len] = '\0'; *len = p->p_len; SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_RX, ("%c%c%c%c.., len = %d\n", buf[0],buf[1],buf[2],buf[3],*len)); } else { *len = 0; SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_ERR, ("not found\n")); return(1); } return(0); } /* * Check whether a given key may be written * * returns * SK_TRUE Yes it may be written * SK_FALSE No it may be written */ SK_BOOL VpdMayWrite( char *key) /* keyword to write (allowed values "Yx", "Vx") */ { if ((*key != 'Y' && *key != 'V') || key[1] < '0' || key[1] > 'Z' || (key[1] > '9' && key[1] < 'A') || strlen(key) != 2) { return(SK_FALSE); } return(SK_TRUE); } /* * Read the contents of the VPD EEPROM and copy it to the VPD * buffer if not already done. Insert/overwrite the keyword 'key' * in the VPD buffer. Cut the keyword value if it does not fit * into the VPD read / write area. * * returns 0: success * 2: value string was cut * 3: VPD transfer timeout * 4: VPD full, keyword was not written * 5: keyword cannot be written * 6: fatal VPD error */ int VpdWrite( SK_AC *pAC, /* common data base */ SK_IOC IoC, /* IO Context */ const char *key, /* keyword to write (allowed values "Yx", "Vx") */ const char *buf) /* buffer where the keyword value can be read from */ { int len; /* length of the keyword to write */ int rtv; /* return code */ int rtv2; SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_TX, ("VPD write %s = %s\n",key,buf)); if ((*key != 'Y' && *key != 'V') || key[1] < '0' || key[1] > 'Z' || (key[1] > '9' && key[1] < 'A') || strlen(key) != 2) { SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_ERR, ("illegal key tag, keyword not written\n")); return(5); } if ((pAC->vpd.v.vpd_status & VPD_VALID) == 0) { if (VpdInit(pAC, IoC) != 0) { SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_ERR, ("VPD init error\n")); return(6); } } rtv = 0; len = strlen(buf); if (len > VPD_MAX_LEN) { /* cut it */ len = VPD_MAX_LEN; rtv = 2; SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_ERR, ("keyword too long, cut after %d bytes\n",VPD_MAX_LEN)); } if ((rtv2 = VpdSetupPara(pAC, key, buf, len, VPD_RW_KEY, OWR_KEY)) != 0) { SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_ERR, ("VPD write error\n")); return(rtv2); } return(rtv); } /* * Read the contents of the VPD EEPROM and copy it to the * VPD buffer if not already done. Remove the VPD keyword * 'key' from the VPD buffer. * Only the keywords in the read/write area can be deleted. * Keywords in the read only area cannot be deleted. * * returns 0: success, keyword was removed * 1: keyword not found * 5: keyword cannot be deleted * 6: fatal VPD error */ int VpdDelete( SK_AC *pAC, /* common data base */ SK_IOC IoC, /* IO Context */ char *key) /* keyword to read (e.g. "MN") */ { SK_VPD_PARA *p, vp; char *etp; int vpd_size; vpd_size = pAC->vpd.vpd_size; SK_DBG_MSG(pAC,SK_DBGMOD_VPD,SK_DBGCAT_TX,("VPD delete key %s\n",key)); if ((pAC->vpd.v.vpd_status & VPD_VALID) == 0) { if (VpdInit(pAC, IoC) != 0) { SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_ERR, ("VPD init error\n")); return(6); } } if ((p = vpd_find_para(pAC, key, &vp)) != NULL) { if (p->p_val < pAC->vpd.vpd_buf + vpd_size/2) { /* try to delete read only keyword */ SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_ERR, ("cannot delete RO keyword\n")); return(5); } etp = pAC->vpd.vpd_buf + (vpd_size-pAC->vpd.v.vpd_free_rw-1-3); vpd_move_para(vp.p_val+vp.p_len, etp+2, - ((int)(vp.p_len + 3))); if (vpd_mod_endtag(pAC, etp - vp.p_len - 3)) { pAC->vpd.v.vpd_status &= ~VPD_VALID; SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_ERR, ("VPD encoding error\n")); return(6); } } else { SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_ERR, ("keyword not found\n")); return(1); } return(0); } /* * If the VPD buffer contains valid data write the VPD * read/write area back to the VPD EEPROM. * * returns 0: success * 3: VPD transfer timeout */ int VpdUpdate( SK_AC *pAC, /* Adapters context */ SK_IOC IoC) /* IO Context */ { int vpd_size; vpd_size = pAC->vpd.vpd_size; SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_TX, ("VPD update .. ")); if ((pAC->vpd.v.vpd_status & VPD_VALID) != 0) { if (VpdTransferBlock(pAC, IoC, pAC->vpd.vpd_buf + vpd_size/2, vpd_size/2, vpd_size/2, VPD_WRITE) != vpd_size/2) { SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_ERR, ("transfer timed out\n")); return(3); } } SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_TX, ("done\n")); return(0); } /* * Read the contents of the VPD EEPROM and copy it to the VPD buffer * if not already done. If the keyword "VF" is not present it will be * created and the error log message will be stored to this keyword. * If "VF" is not present the error log message will be stored to the * keyword "VL". "VL" will created or overwritten if "VF" is present. * The VPD read/write area is saved to the VPD EEPROM. * * returns nothing, errors will be ignored. */ void VpdErrLog( SK_AC *pAC, /* common data base */ SK_IOC IoC, /* IO Context */ char *msg) /* error log message */ { SK_VPD_PARA *v, vf; /* VF */ int len; SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_TX, ("VPD error log msg %s\n", msg)); if ((pAC->vpd.v.vpd_status & VPD_VALID) == 0) { if (VpdInit(pAC, IoC) != 0) { SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_ERR, ("VPD init error\n")); return; } } len = strlen(msg); if (len > VPD_MAX_LEN) { /* cut it */ len = VPD_MAX_LEN; } if ((v = vpd_find_para(pAC, VPD_VF, &vf)) != NULL) { SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_TX, ("overwrite VL\n")); (void)VpdSetupPara(pAC, VPD_VL, msg, len, VPD_RW_KEY, OWR_KEY); } else { SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_TX, ("write VF\n")); (void)VpdSetupPara(pAC, VPD_VF, msg, len, VPD_RW_KEY, ADD_KEY); } (void)VpdUpdate(pAC, IoC); }