/* * This program is a simple binary write/read benchmark. */ #include "SdFat.h" #include "sdios.h" #include "FreeStack.h" // SD_FAT_TYPE = 0 for SdFat/File as defined in SdFatConfig.h, // 1 for FAT16/FAT32, 2 for exFAT, 3 for FAT16/FAT32 and exFAT. #define SD_FAT_TYPE 0 /* Change the value of SD_CS_PIN if you are using SPI and 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 */ // SDCARD_SS_PIN is defined for the built-in SD on some boards. #ifndef SDCARD_SS_PIN const uint8_t SD_CS_PIN = SS; #else // SDCARD_SS_PIN // Assume built-in SD is used. const uint8_t SD_CS_PIN = SDCARD_SS_PIN; #endif // SDCARD_SS_PIN // Try to select the best SD card configuration. #if HAS_SDIO_CLASS #define SD_CONFIG SdioConfig(FIFO_SDIO) #elif ENABLE_DEDICATED_SPI #define SD_CONFIG SdSpiConfig(SD_CS_PIN, DEDICATED_SPI) #else // HAS_SDIO_CLASS #define SD_CONFIG SdSpiConfig(SD_CS_PIN, SHARED_SPI) #endif // HAS_SDIO_CLASS // Set PRE_ALLOCATE true to pre-allocate file clusters. const bool PRE_ALLOCATE = true; // Set SKIP_FIRST_LATENCY true if the first read/write to the SD can // be avoid by writing a file header or reading the first record. const bool SKIP_FIRST_LATENCY = true; // Size of read/write. const size_t BUF_SIZE = 512; // File size in MB where MB = 1,000,000 bytes. const uint32_t FILE_SIZE_MB = 5; // Write pass count. const uint8_t WRITE_COUNT = 2; // Read pass count. const uint8_t READ_COUNT = 2; //============================================================================== // End of configuration constants. //------------------------------------------------------------------------------ // File size in bytes. const uint32_t FILE_SIZE = 1000000UL*FILE_SIZE_MB; // Insure 4-byte alignment. uint32_t buf32[(BUF_SIZE + 3)/4]; uint8_t* buf = (uint8_t*)buf32; #if SD_FAT_TYPE == 0 SdFat sd; File file; #elif SD_FAT_TYPE == 1 SdFat32 sd; File32 file; #elif SD_FAT_TYPE == 2 SdExFat sd; ExFile file; #elif SD_FAT_TYPE == 3 SdFs sd; FsFile file; #else // SD_FAT_TYPE #error Invalid SD_FAT_TYPE #endif // SD_FAT_TYPE // Serial output stream ArduinoOutStream cout(Serial); //------------------------------------------------------------------------------ // Store error strings in flash to save RAM. #define error(s) sd.errorHalt(&Serial, F(s)) //------------------------------------------------------------------------------ void cidDmp() { cid_t cid; if (!sd.card()->readCID(&cid)) { error("readCID failed"); } cout << F("\nManufacturer ID: "); cout << hex << int(cid.mid) << dec << endl; cout << F("OEM ID: ") << cid.oid[0] << cid.oid[1] << endl; cout << F("Product: "); for (uint8_t i = 0; i < 5; i++) { cout << cid.pnm[i]; } cout << F("\nVersion: "); cout << int(cid.prv_n) << '.' << int(cid.prv_m) << endl; cout << F("Serial number: ") << hex << cid.psn << dec << endl; cout << F("Manufacturing date: "); cout << int(cid.mdt_month) << '/'; cout << (2000 + cid.mdt_year_low + 10 * cid.mdt_year_high) << endl; cout << endl; } //------------------------------------------------------------------------------ void setup() { Serial.begin(9600); // Wait for USB Serial while (!Serial) { SysCall::yield(); } delay(1000); cout << F("\nUse a freshly formatted SD for best performance.\n"); if (!ENABLE_DEDICATED_SPI) { cout << F( "\nSet ENABLE_DEDICATED_SPI nonzero in\n" "SdFatConfig.h for best SPI performance.\n"); } // use uppercase in hex and use 0X base prefix cout << uppercase << showbase << endl; } //------------------------------------------------------------------------------ void loop() { float s; uint32_t t; uint32_t maxLatency; uint32_t minLatency; uint32_t totalLatency; bool skipLatency; // Discard any input. do { delay(10); } while (Serial.available() && Serial.read() >= 0); // F() stores strings in flash to save RAM cout << F("Type any character to start\n"); while (!Serial.available()) { SysCall::yield(); } cout << F("FreeStack: ") << FreeStack() << endl; if (!sd.begin(SD_CONFIG)) { sd.initErrorHalt(&Serial); } if (sd.fatType() == FAT_TYPE_EXFAT) { cout << F("Type is exFAT") << endl; } else { cout << F("Type is FAT") << int(sd.fatType()) << endl; } cout << F("Card size: ") << sd.card()->sectorCount()*512E-9; cout << F(" GB (GB = 1E9 bytes)") << endl; cidDmp(); // open or create file - truncate existing file. if (!file.open("bench.dat", O_RDWR | O_CREAT | O_TRUNC)) { error("open failed"); } // fill buf with known data for (uint16_t i = 0; i < (BUF_SIZE-2); i++) { buf[i] = 'A' + (i % 26); } buf[BUF_SIZE-2] = '\r'; buf[BUF_SIZE-1] = '\n'; cout << F("FILE_SIZE_MB = ") << FILE_SIZE_MB << endl; cout << F("BUF_SIZE = ") << BUF_SIZE << F(" bytes\n"); cout << F("Starting write test, please wait.") << endl << endl; // do write test uint32_t n = FILE_SIZE/BUF_SIZE; cout < m) { minLatency = m; } } } file.sync(); t = millis() - t; s = file.fileSize(); cout << s/t <<',' << maxLatency << ',' << minLatency; cout << ',' << totalLatency/n << endl; } cout << endl << F("Starting read test, please wait.") << endl; cout << endl < m) { minLatency = m; } } } s = file.fileSize(); t = millis() - t; cout << s/t <<',' << maxLatency << ',' << minLatency; cout << ',' << totalLatency/n << endl; } cout << endl << F("Done") << endl; file.close(); }