/* * This program will format an SD or SDHC card. * Warning all data will be deleted! * * For SD/SDHC cards larger than 64 MB this * program attempts to match the format * generated by SDFormatter available here: * * http://www.sdcard.org/consumers/formatter/ * * For smaller cards this program uses FAT16 * and SDFormatter uses FAT12. */ #error use new Version 2 SdFormatter // Set USE_SDIO to zero for SPI card access. #define USE_SDIO 0 // // Change the value of chipSelect if your hardware does // not use the default value, SS. Common values are: // Arduino Ethernet shield: pin 4 // Sparkfun SD shield: pin 8 // Adafruit SD shields and modules: pin 10 const uint8_t chipSelect = SS; // Initialize at highest supported speed not over 50 MHz. // Reduce max speed if errors occur. #define SPI_SPEED SD_SCK_MHZ(50) // Print extra info for debug if DEBUG_PRINT is nonzero #define DEBUG_PRINT 0 #include #include "SdFat.h" #include "sdios.h" #if DEBUG_PRINT #include "FreeStack.h" #endif // DEBUG_PRINT // Serial output stream ArduinoOutStream cout(Serial); #if USE_SDIO // Use faster SdioCardEX SdioCardEX card; // SdioCard card; #else // USE_SDIO Sd2Card card; #endif // USE_SDIO uint32_t cardSizeBlocks; uint32_t cardCapacityMB; // cache for SD block cache_t cache; // MBR information uint8_t partType; uint32_t relSector; uint32_t partSize; // Fake disk geometry uint8_t numberOfHeads; uint8_t sectorsPerTrack; // FAT parameters uint16_t reservedSectors; uint8_t sectorsPerCluster; uint32_t fatStart; uint32_t fatSize; uint32_t dataStart; // constants for file system structure uint16_t const BU16 = 128; uint16_t const BU32 = 8192; // strings needed in file system structures char noName[] = "NO NAME "; char fat16str[] = "FAT16 "; char fat32str[] = "FAT32 "; //------------------------------------------------------------------------------ #define sdError(msg) {cout << F("error: ") << F(msg) << endl; sdErrorHalt();} //------------------------------------------------------------------------------ void sdErrorHalt() { if (card.errorCode()) { cout << F("SD error: ") << hex << int(card.errorCode()); cout << ',' << int(card.errorData()) << dec << endl; } SysCall::halt(); } //------------------------------------------------------------------------------ #if DEBUG_PRINT void debugPrint() { cout << F("FreeStack: ") << FreeStack() << endl; cout << F("partStart: ") << relSector << endl; cout << F("partSize: ") << partSize << endl; cout << F("reserved: ") << reservedSectors << endl; cout << F("fatStart: ") << fatStart << endl; cout << F("fatSize: ") << fatSize << endl; cout << F("dataStart: ") << dataStart << endl; cout << F("clusterCount: "); cout << ((relSector + partSize - dataStart)/sectorsPerCluster) << endl; cout << endl; cout << F("Heads: ") << int(numberOfHeads) << endl; cout << F("Sectors: ") << int(sectorsPerTrack) << endl; cout << F("Cylinders: "); cout << cardSizeBlocks/(numberOfHeads*sectorsPerTrack) << endl; } #endif // DEBUG_PRINT //------------------------------------------------------------------------------ // write cached block to the card uint8_t writeCache(uint32_t lbn) { return card.writeBlock(lbn, cache.data); } //------------------------------------------------------------------------------ // initialize appropriate sizes for SD capacity void initSizes() { if (cardCapacityMB <= 6) { sdError("Card is too small."); } else if (cardCapacityMB <= 16) { sectorsPerCluster = 2; } else if (cardCapacityMB <= 32) { sectorsPerCluster = 4; } else if (cardCapacityMB <= 64) { sectorsPerCluster = 8; } else if (cardCapacityMB <= 128) { sectorsPerCluster = 16; } else if (cardCapacityMB <= 1024) { sectorsPerCluster = 32; } else if (cardCapacityMB <= 32768) { sectorsPerCluster = 64; } else { // SDXC cards sectorsPerCluster = 128; } cout << F("Blocks/Cluster: ") << int(sectorsPerCluster) << endl; // set fake disk geometry sectorsPerTrack = cardCapacityMB <= 256 ? 32 : 63; if (cardCapacityMB <= 16) { numberOfHeads = 2; } else if (cardCapacityMB <= 32) { numberOfHeads = 4; } else if (cardCapacityMB <= 128) { numberOfHeads = 8; } else if (cardCapacityMB <= 504) { numberOfHeads = 16; } else if (cardCapacityMB <= 1008) { numberOfHeads = 32; } else if (cardCapacityMB <= 2016) { numberOfHeads = 64; } else if (cardCapacityMB <= 4032) { numberOfHeads = 128; } else { numberOfHeads = 255; } } //------------------------------------------------------------------------------ // zero cache and optionally set the sector signature void clearCache(uint8_t addSig) { memset(&cache, 0, sizeof(cache)); if (addSig) { cache.mbr.mbrSig0 = BOOTSIG0; cache.mbr.mbrSig1 = BOOTSIG1; } } //------------------------------------------------------------------------------ // zero FAT and root dir area on SD void clearFatDir(uint32_t bgn, uint32_t count) { clearCache(false); #if USE_SDIO for (uint32_t i = 0; i < count; i++) { if (!card.writeBlock(bgn + i, cache.data)) { sdError("Clear FAT/DIR writeBlock failed"); } if ((i & 0XFF) == 0) { cout << '.'; } } #else // USE_SDIO if (!card.writeStart(bgn, count)) { sdError("Clear FAT/DIR writeStart failed"); } for (uint32_t i = 0; i < count; i++) { if ((i & 0XFF) == 0) { cout << '.'; } if (!card.writeData(cache.data)) { sdError("Clear FAT/DIR writeData failed"); } } if (!card.writeStop()) { sdError("Clear FAT/DIR writeStop failed"); } #endif // USE_SDIO cout << endl; } //------------------------------------------------------------------------------ // return cylinder number for a logical block number uint16_t lbnToCylinder(uint32_t lbn) { return lbn / (numberOfHeads * sectorsPerTrack); } //------------------------------------------------------------------------------ // return head number for a logical block number uint8_t lbnToHead(uint32_t lbn) { return (lbn % (numberOfHeads * sectorsPerTrack)) / sectorsPerTrack; } //------------------------------------------------------------------------------ // return sector number for a logical block number uint8_t lbnToSector(uint32_t lbn) { return (lbn % sectorsPerTrack) + 1; } //------------------------------------------------------------------------------ // format and write the Master Boot Record void writeMbr() { clearCache(true); part_t* p = cache.mbr.part; p->boot = 0; uint16_t c = lbnToCylinder(relSector); if (c > 1023) { sdError("MBR CHS"); } p->beginCylinderHigh = c >> 8; p->beginCylinderLow = c & 0XFF; p->beginHead = lbnToHead(relSector); p->beginSector = lbnToSector(relSector); p->type = partType; uint32_t endLbn = relSector + partSize - 1; c = lbnToCylinder(endLbn); if (c <= 1023) { p->endCylinderHigh = c >> 8; p->endCylinderLow = c & 0XFF; p->endHead = lbnToHead(endLbn); p->endSector = lbnToSector(endLbn); } else { // Too big flag, c = 1023, h = 254, s = 63 p->endCylinderHigh = 3; p->endCylinderLow = 255; p->endHead = 254; p->endSector = 63; } p->firstSector = relSector; p->totalSectors = partSize; if (!writeCache(0)) { sdError("write MBR"); } } //------------------------------------------------------------------------------ // generate serial number from card size and micros since boot uint32_t volSerialNumber() { return (cardSizeBlocks << 8) + micros(); } //------------------------------------------------------------------------------ // format the SD as FAT16 void makeFat16() { uint32_t nc; for (dataStart = 2 * BU16;; dataStart += BU16) { nc = (cardSizeBlocks - dataStart)/sectorsPerCluster; fatSize = (nc + 2 + 255)/256; uint32_t r = BU16 + 1 + 2 * fatSize + 32; if (dataStart < r) { continue; } relSector = dataStart - r + BU16; break; } // check valid cluster count for FAT16 volume if (nc < 4085 || nc >= 65525) { sdError("Bad cluster count"); } reservedSectors = 1; fatStart = relSector + reservedSectors; partSize = nc * sectorsPerCluster + 2 * fatSize + reservedSectors + 32; if (partSize < 32680) { partType = 0X01; } else if (partSize < 65536) { partType = 0X04; } else { partType = 0X06; } // write MBR writeMbr(); clearCache(true); fat_boot_t* pb = &cache.fbs; pb->jump[0] = 0XEB; pb->jump[1] = 0X00; pb->jump[2] = 0X90; for (uint8_t i = 0; i < sizeof(pb->oemId); i++) { pb->oemId[i] = ' '; } pb->bytesPerSector = 512; pb->sectorsPerCluster = sectorsPerCluster; pb->reservedSectorCount = reservedSectors; pb->fatCount = 2; pb->rootDirEntryCount = 512; pb->mediaType = 0XF8; pb->sectorsPerFat16 = fatSize; pb->sectorsPerTrack = sectorsPerTrack; pb->headCount = numberOfHeads; pb->hidddenSectors = relSector; pb->totalSectors32 = partSize; pb->driveNumber = 0X80; pb->bootSignature = EXTENDED_BOOT_SIG; pb->volumeSerialNumber = volSerialNumber(); memcpy(pb->volumeLabel, noName, sizeof(pb->volumeLabel)); memcpy(pb->fileSystemType, fat16str, sizeof(pb->fileSystemType)); // write partition boot sector if (!writeCache(relSector)) { sdError("FAT16 write PBS failed"); } // clear FAT and root directory clearFatDir(fatStart, dataStart - fatStart); clearCache(false); cache.fat16[0] = 0XFFF8; cache.fat16[1] = 0XFFFF; // write first block of FAT and backup for reserved clusters if (!writeCache(fatStart) || !writeCache(fatStart + fatSize)) { sdError("FAT16 reserve failed"); } } //------------------------------------------------------------------------------ // format the SD as FAT32 void makeFat32() { uint32_t nc; relSector = BU32; for (dataStart = 2 * BU32;; dataStart += BU32) { nc = (cardSizeBlocks - dataStart)/sectorsPerCluster; fatSize = (nc + 2 + 127)/128; uint32_t r = relSector + 9 + 2 * fatSize; if (dataStart >= r) { break; } } // error if too few clusters in FAT32 volume if (nc < 65525) { sdError("Bad cluster count"); } reservedSectors = dataStart - relSector - 2 * fatSize; fatStart = relSector + reservedSectors; partSize = nc * sectorsPerCluster + dataStart - relSector; // type depends on address of end sector // max CHS has lbn = 16450560 = 1024*255*63 if ((relSector + partSize) <= 16450560) { // FAT32 partType = 0X0B; } else { // FAT32 with INT 13 partType = 0X0C; } writeMbr(); clearCache(true); fat32_boot_t* pb = &cache.fbs32; pb->jump[0] = 0XEB; pb->jump[1] = 0X00; pb->jump[2] = 0X90; for (uint8_t i = 0; i < sizeof(pb->oemId); i++) { pb->oemId[i] = ' '; } pb->bytesPerSector = 512; pb->sectorsPerCluster = sectorsPerCluster; pb->reservedSectorCount = reservedSectors; pb->fatCount = 2; pb->mediaType = 0XF8; pb->sectorsPerTrack = sectorsPerTrack; pb->headCount = numberOfHeads; pb->hidddenSectors = relSector; pb->totalSectors32 = partSize; pb->sectorsPerFat32 = fatSize; pb->fat32RootCluster = 2; pb->fat32FSInfo = 1; pb->fat32BackBootBlock = 6; pb->driveNumber = 0X80; pb->bootSignature = EXTENDED_BOOT_SIG; pb->volumeSerialNumber = volSerialNumber(); memcpy(pb->volumeLabel, noName, sizeof(pb->volumeLabel)); memcpy(pb->fileSystemType, fat32str, sizeof(pb->fileSystemType)); // write partition boot sector and backup if (!writeCache(relSector) || !writeCache(relSector + 6)) { sdError("FAT32 write PBS failed"); } clearCache(true); // write extra boot area and backup if (!writeCache(relSector + 2) || !writeCache(relSector + 8)) { sdError("FAT32 PBS ext failed"); } fat32_fsinfo_t* pf = &cache.fsinfo; pf->leadSignature = FSINFO_LEAD_SIG; pf->structSignature = FSINFO_STRUCT_SIG; pf->freeCount = 0XFFFFFFFF; pf->nextFree = 0XFFFFFFFF; // write FSINFO sector and backup if (!writeCache(relSector + 1) || !writeCache(relSector + 7)) { sdError("FAT32 FSINFO failed"); } clearFatDir(fatStart, 2 * fatSize + sectorsPerCluster); clearCache(false); cache.fat32[0] = 0x0FFFFFF8; cache.fat32[1] = 0x0FFFFFFF; cache.fat32[2] = 0x0FFFFFFF; // write first block of FAT and backup for reserved clusters if (!writeCache(fatStart) || !writeCache(fatStart + fatSize)) { sdError("FAT32 reserve failed"); } } //------------------------------------------------------------------------------ // flash erase all data uint32_t const ERASE_SIZE = 262144L; void eraseCard() { cout << endl << F("Erasing\n"); uint32_t firstBlock = 0; uint32_t lastBlock; uint16_t n = 0; do { lastBlock = firstBlock + ERASE_SIZE - 1; if (lastBlock >= cardSizeBlocks) { lastBlock = cardSizeBlocks - 1; } if (!card.erase(firstBlock, lastBlock)) { sdError("erase failed"); } cout << '.'; if ((n++)%32 == 31) { cout << endl; } firstBlock += ERASE_SIZE; } while (firstBlock < cardSizeBlocks); cout << endl; if (!card.readBlock(0, cache.data)) { sdError("readBlock"); } cout << hex << showbase << setfill('0') << internal; cout << F("All data set to ") << setw(4) << int(cache.data[0]) << endl; cout << dec << noshowbase << setfill(' ') << right; cout << F("Erase done\n"); } //------------------------------------------------------------------------------ void formatCard() { cout << endl; cout << F("Formatting\n"); initSizes(); if (card.type() != SD_CARD_TYPE_SDHC) { cout << F("FAT16\n"); makeFat16(); } else { cout << F("FAT32\n"); makeFat32(); } #if DEBUG_PRINT debugPrint(); #endif // DEBUG_PRINT cout << F("Format done\n"); } //------------------------------------------------------------------------------ void setup() { char c; Serial.begin(9600); // Wait for USB Serial while (!Serial) { SysCall::yield(); } cout << F("Type any character to start\n"); while (!Serial.available()) { SysCall::yield(); } // Discard any extra characters. do { delay(10); } while (Serial.available() && Serial.read() >= 0); cout << F( "\n" "This program can erase and/or format SD/SDHC cards.\n" "\n" "Erase uses the card's fast flash erase command.\n" "Flash erase sets all data to 0X00 for most cards\n" "and 0XFF for a few vendor's cards.\n" "\n" "Cards larger than 2 GB will be formatted FAT32 and\n" "smaller cards will be formatted FAT16.\n" "\n" "Warning, all data on the card will be erased.\n" "Enter 'Y' to continue: "); while (!Serial.available()) { SysCall::yield(); } c = Serial.read(); cout << c << endl; if (c != 'Y') { cout << F("Quiting, you did not enter 'Y'.\n"); return; } // Read any existing Serial data. do { delay(10); } while (Serial.available() && Serial.read() >= 0); cout << F( "\n" "Options are:\n" "E - erase the card and skip formatting.\n" "F - erase and then format the card. (recommended)\n" "Q - quick format the card without erase.\n" "\n" "Enter option: "); while (!Serial.available()) { SysCall::yield(); } c = Serial.read(); cout << c << endl; if (!strchr("EFQ", c)) { cout << F("Quiting, invalid option entered.") << endl; return; } #if USE_SDIO if (!card.begin()) { sdError("card.begin failed"); } #else // USE_SDIO if (!card.begin(chipSelect, SPI_SPEED)) { cout << F( "\nSD initialization failure!\n" "Is the SD card inserted correctly?\n" "Is chip select correct at the top of this program?\n"); sdError("card.begin failed"); } #endif cardSizeBlocks = card.cardSize(); if (cardSizeBlocks == 0) { sdError("cardSize"); } cardCapacityMB = (cardSizeBlocks + 2047)/2048; cout << F("Card Size: ") << setprecision(0) << 1.048576*cardCapacityMB; cout << F(" MB, (MB = 1,000,000 bytes)") << endl; if (c == 'E' || c == 'F') { eraseCard(); } if (c == 'F' || c == 'Q') { formatCard(); } } //------------------------------------------------------------------------------ void loop() {}