/* * $Log: P:/user/amir/lite/vcs/i28f016.c_v $ * * Rev 1.10 06 Oct 1997 9:45:48 danig * VPP functions under #ifdef * * Rev 1.9 10 Sep 1997 16:48:24 danig * Debug messages & got rid of generic names * * Rev 1.8 31 Aug 1997 15:09:20 danig * Registration routine return status * * Rev 1.7 24 Jul 1997 17:52:58 amirban * FAR to FAR0 * * Rev 1.6 20 Jul 1997 17:17:06 amirban * No watchDogTimer * * Rev 1.5 07 Jul 1997 15:22:08 amirban * Ver 2.0 * * Rev 1.4 04 Mar 1997 16:44:22 amirban * Page buffer bug fix * * Rev 1.3 18 Aug 1996 13:48:24 amirban * Comments * * Rev 1.2 12 Aug 1996 15:49:04 amirban * Added suspend/resume * * Rev 1.1 31 Jul 1996 14:30:50 amirban * Background stuff * * Rev 1.0 18 Jun 1996 16:34:30 amirban * Initial revision. */ /************************************************************************/ /* */ /* FAT-FTL Lite Software Development Kit */ /* Copyright (C) M-Systems Ltd. 1995-1996 */ /* */ /************************************************************************/ /*----------------------------------------------------------------------*/ /* */ /* This MTD supports the following Flash technologies: */ /* */ /* - Intel 28F016SA/28016SV/Cobra 16-mbit devices */ /* */ /* And (among else), the following Flash media and cards: */ /* */ /* - Intel Series-2+ PCMCIA cards */ /* */ /*----------------------------------------------------------------------*/ #include "flflash.h" #ifdef FL_BACKGROUND #include "backgrnd.h" #endif /* JEDEC ids for this MTD */ #define I28F016_FLASH 0x89a0 #define LH28F016SU_FLASH 0xB088 #define SETUP_ERASE 0x2020 #define SETUP_WRITE 0x4040 #define CLEAR_STATUS 0x5050 #define READ_STATUS 0x7070 #define READ_ID 0x9090 #define SUSPEND_ERASE 0xb0b0 #define CONFIRM_ERASE 0xd0d0 #define RESUME_ERASE 0xd0d0 #define READ_ARRAY 0xffff #define LOAD_PAGE_BUFFER 0xe0e0 #define WRITE_PAGE_BUFFER 0x0c0c #define READ_EXTENDED_REGS 0x7171 #define WSM_VPP_ERROR 0x08 #define WSM_ERROR 0x38 #define WSM_SUSPENDED 0x40 #define WSM_READY 0x80 #define GSR_ERROR 0x20 #define both(word) (vol.interleaving == 1 ? tffsReadWordFlash(word) : tffsReadWordFlash(word) & (tffsReadWordFlash(word) >> 8)) #define any(word) (tffsReadWordFlash(word) | (tffsReadWordFlash(word) >> 8)) /*----------------------------------------------------------------------*/ /* i 2 8 f 0 1 6 W o r d S i z e */ /* */ /* Identify the card size for an Intel 28F016 word-mode Flash array. */ /* Sets the value of vol.noOfChips. */ /* */ /* Parameters: */ /* vol : Pointer identifying drive */ /* */ /* Returns: */ /* FLStatus : 0 = OK, otherwise failed (invalid Flash array)*/ /*----------------------------------------------------------------------*/ FLStatus i28f016WordSize(FLFlash vol) { FlashWPTR flashPtr = (FlashWPTR) flMap(vol.socket,0); unsigned short id0, id1; tffsWriteWordFlash(flashPtr, CLEAR_STATUS); tffsWriteWordFlash(flashPtr, READ_ID); /* We leave the first chip in Read ID mode, so that we can */ /* discover an address wraparound. */ if( vol.type == I28F016_FLASH ) { id0 = 0x0089; id1 = 0x66a0; } else if( vol.type == LH28F016SU_FLASH ) { id0 = 0x00B0; id1 = 0x6688; } for (vol.noOfChips = 1; /* Scan the chips */ vol.noOfChips < 2000; /* Big enough ? */ vol.noOfChips++) { flashPtr = (FlashWPTR) flMap(vol.socket,vol.noOfChips * vol.chipSize); if (tffsReadWordFlash(flashPtr) == id0 && tffsReadWordFlash(flashPtr + 1) == id1) break; /* We've wrapped around to the first chip ! */ tffsWriteWordFlash(flashPtr, READ_ID); if (!(tffsReadWordFlash(flashPtr) == id0 && tffsReadWordFlash(flashPtr + 1) == id1)) break; tffsWriteWordFlash(flashPtr, CLEAR_STATUS); tffsWriteWordFlash(flashPtr, READ_ARRAY); } flashPtr = (FlashWPTR) flMap(vol.socket,0); tffsWriteWordFlash(flashPtr, READ_ARRAY); return flOK; } /*----------------------------------------------------------------------*/ /* i 2 8 f 0 1 6 W r i t e */ /* */ /* Write a block of bytes to Flash */ /* */ /* This routine will be registered as the MTD flash.write routine */ /* */ /* Parameters: */ /* vol : Pointer identifying drive */ /* address : Card address to write to */ /* buffer : Address of data to write */ /* length : Number of bytes to write */ /* overwrite : TRUE if overwriting old Flash contents */ /* FALSE if old contents are known to be erased */ /* */ /* Returns: */ /* FLStatus : 0 on success, failed otherwise */ /*----------------------------------------------------------------------*/ FLStatus i28f016Write(FLFlash vol, CardAddress address, const VOID FAR1 *buffer, dword length, word overwrite) { /* Set timeout of 5 seconds from now */ ULONG writeTimeout = flMsecCounter + 5000; FLStatus status = flOK; FlashWPTR flashPtr; ULONG maxLength, i, from; UCHAR * bBuffer = (UCHAR *) buffer; FlashPTR bFlashPtr; ULONG * dBuffer = (ULONG *) buffer; FlashDPTR dFlashPtr; if (flWriteProtected(vol.socket)) return flWriteProtect; if ((length & 1) || (address & 1)) /* Only write words on word-boundary */ return flBadParameter; #ifdef SOCKET_12_VOLTS checkStatus(flNeedVpp(vol.socket)); #endif maxLength = 256 * vol.interleaving; for (from = 0; from < length && status == flOK; from += maxLength) { FlashWPTR currPtr; ULONG lengthWord; ULONG tailBytes; ULONG thisLength = length - from; if (thisLength > maxLength) thisLength = maxLength; lengthWord = (thisLength + vol.interleaving - 1) / (vol.interleaving == 1 ? 2 : vol.interleaving) - 1; if (vol.interleaving != 1) lengthWord |= (lengthWord << 8); flashPtr = (FlashWPTR) flMap(vol.socket,address + from); tailBytes = ((thisLength - 1) & (vol.interleaving - 1)) + 1; for (i = 0, currPtr = flashPtr; i < (ULONG)vol.interleaving && i < thisLength; i += 2, currPtr++) { tffsWriteWordFlash(currPtr, LOAD_PAGE_BUFFER); if (i < tailBytes) { tffsWriteWordFlash(currPtr, (USHORT) lengthWord); } else { tffsWriteWordFlash(currPtr, (USHORT) (lengthWord - 1)); } tffsWriteWordFlash(currPtr, 0); } dFlashPtr = (FlashDPTR) flashPtr; bFlashPtr = (FlashPTR) flashPtr; for (i = 0; i < thisLength - 4; i += 4) { tffsWriteDwordFlash(dFlashPtr + i, *(dBuffer + from + i)); } for(; i < thisLength; i++) { tffsWriteByteFlash(bFlashPtr + i, *(bBuffer + from + i)); } for (i = 0, currPtr = flashPtr; i < (ULONG)vol.interleaving && i < thisLength; i += 2, currPtr++) { tffsWriteWordFlash(currPtr, WRITE_PAGE_BUFFER); if (!((address + from + i) & vol.interleaving)) { /* Even address */ tffsWriteWordFlash(currPtr, (USHORT) lengthWord); tffsWriteWordFlash(currPtr, 0); } else { /* Odd address */ tffsWriteWordFlash(currPtr, 0); tffsWriteWordFlash(currPtr, (USHORT) lengthWord); } } /* map to the GSR & BSR */ flashPtr = (FlashWPTR) flMap(vol.socket, (CardAddress)( (address + from & -(int)vol.erasableBlockSize) + 4 * vol.interleaving)); for (i = 0, currPtr = flashPtr; i < (ULONG)vol.interleaving && i < thisLength; i += 2, currPtr++) { tffsWriteWordFlash(currPtr, READ_EXTENDED_REGS); while (!(both(currPtr) & WSM_READY) && flMsecCounter < writeTimeout) ; if ((any(currPtr) & GSR_ERROR) || !(both(currPtr) & WSM_READY)) { DEBUG_PRINT(("Debug: write failed for 16-bit Intel media.\n")); status = flWriteFault; tffsWriteWordFlash(currPtr, CLEAR_STATUS); } tffsWriteWordFlash(currPtr, READ_ARRAY); } } #ifdef SOCKET_12_VOLTS flDontNeedVpp(vol.socket); #endif /* verify the data */ dFlashPtr = (FlashDPTR) flMap(vol.socket, address); dBuffer = (ULONG *) buffer; if (status == flOK) { /* compare double words */ for (;length >= 4; length -= 4, dFlashPtr++, dBuffer++) { if (tffsReadDwordFlash(dFlashPtr) != *dBuffer) { DEBUG_PRINT(("Debug: write failed for 16-bit Intel media in verification.\n")); return flWriteFault; } } /* compare the last bytes */ bFlashPtr = (FlashPTR) dFlashPtr; bBuffer = (UCHAR *)dBuffer; for (; length; length--, bFlashPtr++, bBuffer++) { if (tffsReadByteFlash(bFlashPtr) != *bBuffer) { DEBUG_PRINT(("Debug: write failed for 16-bit Intel media in verification.\n")); return flWriteFault; } } } return status; } /*----------------------------------------------------------------------*/ /* i 2 8 f 0 1 6 E r a s e */ /* */ /* Erase one or more contiguous Flash erasable blocks */ /* */ /* This routine will be registered as the MTD vol.erase routine */ /* */ /* Parameters: */ /* vol : Pointer identifying drive */ /* firstErasableBlock : Number of first block to erase */ /* numOfErasableBlocks: Number of blocks to erase */ /* */ /* Returns: */ /* FLStatus : 0 on success, failed otherwise */ /*----------------------------------------------------------------------*/ FLStatus i28f016Erase(FLFlash vol, word firstErasableBlock, word numOfErasableBlocks) { FLStatus status = flOK; /* unless proven otherwise */ LONG iBlock; if (flWriteProtected(vol.socket)) return flWriteProtect; #ifdef SOCKET_12_VOLTS checkStatus(flNeedVpp(vol.socket)); #endif for (iBlock = 0; iBlock < numOfErasableBlocks && status == flOK; iBlock++) { FlashWPTR currPtr; LONG i; FLBoolean finished; FlashWPTR flashPtr = (FlashWPTR) flMap(vol.socket,(firstErasableBlock + iBlock) * vol.erasableBlockSize); for (i = 0, currPtr = flashPtr; i < vol.interleaving; i += 2, currPtr++) { tffsWriteWordFlash(currPtr, SETUP_ERASE); tffsWriteWordFlash(currPtr, CONFIRM_ERASE); } do { #ifdef FL_BACKGROUND while (flForeground(1) == BG_SUSPEND) { /* suspend */ for (i = 0, currPtr = flashPtr; i < vol.interleaving; i += 2, currPtr++) { tffsWriteWordFlash(currPtr, READ_STATUS); if (!(both(currPtr) & WSM_READY)) { tffsWriteWordFlash(currPtr, SUSPEND_ERASE); tffsWriteWordFlash(currPtr, READ_STATUS); while (!(both(currPtr) & WSM_READY)) ; } tffsWriteWordFlash(currPtr, READ_ARRAY); } } #endif finished = TRUE; for (i = 0, currPtr = flashPtr; i < vol.interleaving; i += 2, currPtr++) { tffsWriteWordFlash(currPtr, READ_STATUS); if (any(currPtr) & WSM_SUSPENDED) { tffsWriteWordFlash(currPtr, RESUME_ERASE); finished = FALSE; } else if (!(both(currPtr) & WSM_READY)) finished = FALSE; else { if (any(currPtr) & WSM_ERROR) { DEBUG_PRINT(("Debug: erase failed for 16-bit Intel media.\n")); status = (any(currPtr) & WSM_VPP_ERROR) ? flVppFailure : flWriteFault; tffsWriteWordFlash(currPtr, CLEAR_STATUS); } tffsWriteWordFlash(currPtr, READ_ARRAY); } } flDelayMsecs(10); } while (!finished); } #ifdef SOCKET_12_VOLTS flDontNeedVpp(vol.socket); #endif return status; } /*----------------------------------------------------------------------*/ /* i 2 8 f 0 1 6 M a p */ /* */ /* Map through buffer. This routine will be registered as the map */ /* routine for this MTD. */ /* */ /* Parameters: */ /* vol : Pointer identifying drive */ /* address : Flash address to be mapped. */ /* length : number of bytes to map. */ /* */ /* Returns: */ /* Pointer to the buffer data was mapped to. */ /* */ /*----------------------------------------------------------------------*/ VOID FAR0 *i28f016Map (FLFlash vol, CardAddress address, int length) { vol.socket->remapped = TRUE; return mapThroughBuffer(&vol,address,length); } /*----------------------------------------------------------------------*/ /* i 2 8 f 0 1 6 R e a d */ /* */ /* Read some data from the flash. This routine will be registered as */ /* the read routine for this MTD. */ /* */ /* Parameters: */ /* vol : Pointer identifying drive */ /* address : Address to read from. */ /* buffer : buffer to read to. */ /* length : number of bytes to read (up to sector size). */ /* modes : EDC flag etc. */ /* */ /* Returns: */ /* FLStatus : 0 on success, otherwise failed. */ /* */ /*----------------------------------------------------------------------*/ FLStatus i28f016Read(FLFlash vol, CardAddress address, VOID FAR1 *buffer, dword length, word modes) { ULONG i; UCHAR * bBuffer; FlashPTR bFlashPtr; ULONG * dBuffer = (ULONG *)buffer; FlashDPTR dFlashPtr = (FlashDPTR)flMap(vol.socket, address); for (i = 0; i < length - 4; i += 4, dBuffer++, dFlashPtr++) { *dBuffer = tffsReadDwordFlash(dFlashPtr); } bBuffer = (UCHAR *)dBuffer; bFlashPtr = (FlashPTR)dFlashPtr; for(; i < length; i++, bBuffer++, bFlashPtr++) { *bBuffer = tffsReadByteFlash(bFlashPtr); } return flOK ; } /*----------------------------------------------------------------------*/ /* i 2 8 f 0 1 6 I d e n t i f y */ /* */ /* Identifies media based on Intel 28F016 and registers as an MTD for */ /* such. */ /* */ /* This routine will be placed on the MTD list in custom.h. It must be */ /* an extern routine. */ /* */ /* On successful identification, the Flash structure is filled out and */ /* the write and erase routines registered. */ /* */ /* Parameters: */ /* vol : Pointer identifying drive */ /* */ /* Returns: */ /* FLStatus : 0 on positive identificaion, failed otherwise */ /*----------------------------------------------------------------------*/ FLStatus i28f016Identify(FLFlash vol) { FlashWPTR flashPtr; DEBUG_PRINT(("Debug: entering 16-bit Intel media identification routine.\n")); flSetWindowBusWidth(vol.socket,16);/* use 16-bits */ flSetWindowSpeed(vol.socket,150); /* 120 nsec. */ flSetWindowSize(vol.socket,2); /* 8 KBytes */ flashPtr = (FlashWPTR) flMap(vol.socket,0); vol.noOfChips = 0; tffsWriteWordFlash(flashPtr, READ_ID); if (tffsReadWordFlash(flashPtr) == 0x0089 && tffsReadWordFlash(flashPtr + 1) == 0x66a0) { /* Word mode */ vol.type = I28F016_FLASH; vol.interleaving = 1; tffsWriteWordFlash(flashPtr, READ_ARRAY); } else if (tffsReadWordFlash(flashPtr) == 0x00B0 && tffsReadWordFlash(flashPtr + 1) == 0x6688) { /* Word mode */ vol.type = LH28F016SU_FLASH; vol.interleaving = 1; tffsWriteWordFlash(flashPtr, READ_ARRAY); } else { /* Use standard identification routine to detect byte-mode */ flIntelIdentify(&vol, NULL,0); if (vol.interleaving == 1) vol.type = NOT_FLASH; /* We cannot handle byte-mode interleaving-1 */ } if( (vol.type == I28F016_FLASH) || (vol.type == LH28F016SU_FLASH) ) { vol.chipSize = 0x200000L; vol.erasableBlockSize = 0x10000L * vol.interleaving; checkStatus(vol.interleaving == 1 ? i28f016WordSize(&vol) : flIntelSize(&vol, NULL,0)); /* Register our flash handlers */ vol.write = i28f016Write; vol.erase = i28f016Erase; vol.read = i28f016Read; vol.map = i28f016Map; DEBUG_PRINT(("Debug: identified 16-bit Intel media.\n")); return flOK; } else { DEBUG_PRINT(("Debug: failed to identify 16-bit Intel media.\n")); return flUnknownMedia; /* not ours */ } } /*----------------------------------------------------------------------*/ /* f l R e g i s t e r I 2 8 F 0 1 6 */ /* */ /* Registers this MTD for use */ /* */ /* Parameters: */ /* None */ /* */ /* Returns: */ /* FLStatus : 0 on success, otherwise failure */ /*----------------------------------------------------------------------*/ FLStatus flRegisterI28F016(VOID) { if (noOfMTDs >= MTDS) return flTooManyComponents; mtdTable[noOfMTDs++] = i28f016Identify; return flOK; }