CelliesProjects/QuickStartSD.ino

## QuickStartSD.ino
// Quick hardware test for SPI card access.
//
#include <SPI.h>
#include "SdFat.h"

#define _dc                   27  // Goes to TFT DC
#define _sclk                 25  // Goes to TFT SCK/CLK
#define _mosi                 32  // Goes to TFT MOSI
#define _miso                 14  // Goes to TFT MISO
#define _cs                    4  // Goes to TFT CS
#define  SD_CS                 0  // Goes to SD CS

//
// Set DISABLE_CHIP_SELECT to disable a second SPI device.
// For example, with the Ethernet shield, set DISABLE_CHIP_SELECT
// to 10 to disable the Ethernet controller.
const int8_t DISABLE_CHIP_SELECT = -1;
//
// Test with reduced SPI speed for breadboards.  SD_SCK_MHZ(4) will select
// the highest speed supported by the board that is not over 4 MHz.
// Change SPI_SPEED to SD_SCK_MHZ(50) for best performance.
#define SPI_SPEED SD_SCK_MHZ(2)
//------------------------------------------------------------------------------
// File system object.
SdFat sd;

// Serial streams
ArduinoOutStream cout(Serial);

// input buffer for line
char cinBuf[40];
ArduinoInStream cin(Serial, cinBuf, sizeof(cinBuf));

// SD card chip select
int chipSelect;

void cardOrSpeed() {
  cout << F("Try another SD card or reduce the SPI bus speed.\n");
  cout << F("Edit SPI_SPEED in this program to change it.\n");
}

void reformatMsg() {
  cout << F("Try reformatting the card.  For best results use\n");
  cout << F("the SdFormatter program in SdFat/examples or download\n");
  cout << F("and use SDFormatter from www.sdcard.org/downloads.\n");
}

void setup() {

  SPI.begin( _sclk, _miso, _mosi );
  SPI.setFrequency( 40000000 );

  Serial.begin(115200);

  // Wait for USB Serial
  while (!Serial) {
    SysCall::yield();
  }
  cout << F("\nSPI pins:\n");
  cout << F("MISO: ") << int(_miso) << endl;
  cout << F("MOSI: ") << int(_mosi) << endl;
  cout << F("SCK:  ") << int(_sclk) << endl;
  cout << F("SS:   ") << int(SD_CS) << endl;

  if (DISABLE_CHIP_SELECT < 0) {
    cout << F(
           "\nBe sure to edit DISABLE_CHIP_SELECT if you have\n"
           "a second SPI device.  For example, with the Ethernet\n"
           "shield, DISABLE_CHIP_SELECT should be set to 10\n"
           "to disable the Ethernet controller.\n");
  }
  cout << F(
         "\nSD chip select is the key hardware option.\n"
         "Common values are:\n"
         "Arduino Ethernet shield, pin 4\n"
         "Sparkfun SD shield, pin 8\n"
         "Adafruit SD shields and modules, pin 10\n");
}

bool firstTry = true;
void loop() {
  // Read any existing Serial data.
  do {
    delay(10);
  } while (Serial.available() && Serial.read() >= 0);

  if (!firstTry) {
    cout << F("\nRestarting\n");
  }
  firstTry = false;

  cout << F("\nEnter the chip select pin number: ");
  while (!Serial.available()) {
    SysCall::yield();
  }
  cin.readline();
  if (cin >> chipSelect) {
    cout << chipSelect << endl;
  } else {
    cout << F("\nInvalid pin number\n");
    return;
  }
  if (DISABLE_CHIP_SELECT < 0) {
    cout << F(
           "\nAssuming the SD is the only SPI device.\n"
           "Edit DISABLE_CHIP_SELECT to disable another device.\n");
  } else {
    cout << F("\nDisabling SPI device on pin ");
    cout << int(DISABLE_CHIP_SELECT) << endl;
    pinMode(DISABLE_CHIP_SELECT, OUTPUT);
    digitalWrite(DISABLE_CHIP_SELECT, HIGH);
  }
  if (!sd.begin(chipSelect, SPI_SPEED)) {
    if (sd.card()->errorCode()) {
      cout << F(
             "\nSD initialization failed.\n"
             "Do not reformat the card!\n"
             "Is the card correctly inserted?\n"
             "Is chipSelect set to the correct value?\n"
             "Does another SPI device need to be disabled?\n"
             "Is there a wiring/soldering problem?\n");
      cout << F("\nerrorCode: ") << hex << showbase;
      cout << int(sd.card()->errorCode());
      cout << F(", errorData: ") << int(sd.card()->errorData());
      cout << dec << noshowbase << endl;
      return;
    }
    cout << F("\nCard successfully initialized.\n");
    if (sd.vol()->fatType() == 0) {
      cout << F("Can't find a valid FAT16/FAT32 partition.\n");
      reformatMsg();
      return;
    }
    if (!sd.vwd()->isOpen()) {
      cout << F("Can't open root directory.\n");
      reformatMsg();
      return;
    }
    cout << F("Can't determine error type\n");
    return;
  }
  cout << F("\nCard successfully initialized.\n");
  cout << endl;

  uint32_t size = sd.card()->cardSize();
  if (size == 0) {
    cout << F("Can't determine the card size.\n");
    cardOrSpeed();
    return;
  }
  uint32_t sizeMB = 0.000512 * size + 0.5;
  cout << F("Card size: ") << sizeMB;
  cout << F(" MB (MB = 1,000,000 bytes)\n");
  cout << endl;
  cout << F("Volume is FAT") << int(sd.vol()->fatType());
  cout << F(", Cluster size (bytes): ") << 512L * sd.vol()->blocksPerCluster();
  cout << endl << endl;

  cout << F("Files found (date time size name):\n");
  sd.ls(LS_R | LS_DATE | LS_SIZE);

  if ((sizeMB > 1100 && sd.vol()->blocksPerCluster() < 64)
      || (sizeMB < 2200 && sd.vol()->fatType() == 32)) {
    cout << F("\nThis card should be reformatted for best performance.\n");
    cout << F("Use a cluster size of 32 KB for cards larger than 1 GB.\n");
    cout << F("Only cards larger than 2 GB should be formatted FAT32.\n");
    reformatMsg();
    return;
  }
  // Read any extra Serial data.
  do {
    delay(10);
  } while (Serial.available() && Serial.read() >= 0);
  cout << F("\nSuccess!  Type any character to restart.\n");
  while (!Serial.available()) {
    SysCall::yield();
  }
}
	// Quick hardware test for SPI card access.
	//
	#include <SPI.h>
	#include "SdFat.h"

	#define _dc 27 // Goes to TFT DC
	#define _sclk 25 // Goes to TFT SCK/CLK
	#define _mosi 32 // Goes to TFT MOSI
	#define _miso 14 // Goes to TFT MISO
	#define _cs 4 // Goes to TFT CS
	#define SD_CS 0 // Goes to SD CS

	//
	// Set DISABLE_CHIP_SELECT to disable a second SPI device.
	// For example, with the Ethernet shield, set DISABLE_CHIP_SELECT
	// to 10 to disable the Ethernet controller.
	const int8_t DISABLE_CHIP_SELECT = -1;
	//
	// Test with reduced SPI speed for breadboards. SD_SCK_MHZ(4) will select
	// the highest speed supported by the board that is not over 4 MHz.
	// Change SPI_SPEED to SD_SCK_MHZ(50) for best performance.
	#define SPI_SPEED SD_SCK_MHZ(2)
	//------------------------------------------------------------------------------
	// File system object.
	SdFat sd;

	// Serial streams
	ArduinoOutStream cout(Serial);

	// input buffer for line
	char cinBuf[40];
	ArduinoInStream cin(Serial, cinBuf, sizeof(cinBuf));

	// SD card chip select
	int chipSelect;

	void cardOrSpeed() {
	cout << F("Try another SD card or reduce the SPI bus speed.\n");
	cout << F("Edit SPI_SPEED in this program to change it.\n");
	}

	void reformatMsg() {
	cout << F("Try reformatting the card. For best results use\n");
	cout << F("the SdFormatter program in SdFat/examples or download\n");
	cout << F("and use SDFormatter from www.sdcard.org/downloads.\n");
	}

	void setup() {

	SPI.begin( _sclk, _miso, _mosi );
	SPI.setFrequency( 40000000 );

	Serial.begin(115200);

	// Wait for USB Serial
	while (!Serial) {
	SysCall::yield();
	}
	cout << F("\nSPI pins:\n");
	cout << F("MISO: ") << int(_miso) << endl;
	cout << F("MOSI: ") << int(_mosi) << endl;
	cout << F("SCK: ") << int(_sclk) << endl;
	cout << F("SS: ") << int(SD_CS) << endl;

	if (DISABLE_CHIP_SELECT < 0) {
	cout << F(
	"\nBe sure to edit DISABLE_CHIP_SELECT if you have\n"
	"a second SPI device. For example, with the Ethernet\n"
	"shield, DISABLE_CHIP_SELECT should be set to 10\n"
	"to disable the Ethernet controller.\n");
	}
	cout << F(
	"\nSD chip select is the key hardware option.\n"
	"Common values are:\n"
	"Arduino Ethernet shield, pin 4\n"
	"Sparkfun SD shield, pin 8\n"
	"Adafruit SD shields and modules, pin 10\n");
	}

	bool firstTry = true;
	void loop() {
	// Read any existing Serial data.
	do {
	delay(10);
	} while (Serial.available() && Serial.read() >= 0);

	if (!firstTry) {
	cout << F("\nRestarting\n");
	}
	firstTry = false;

	cout << F("\nEnter the chip select pin number: ");
	while (!Serial.available()) {
	SysCall::yield();
	}
	cin.readline();
	if (cin >> chipSelect) {
	cout << chipSelect << endl;
	} else {
	cout << F("\nInvalid pin number\n");
	return;
	}
	if (DISABLE_CHIP_SELECT < 0) {
	cout << F(
	"\nAssuming the SD is the only SPI device.\n"
	"Edit DISABLE_CHIP_SELECT to disable another device.\n");
	} else {
	cout << F("\nDisabling SPI device on pin ");
	cout << int(DISABLE_CHIP_SELECT) << endl;
	pinMode(DISABLE_CHIP_SELECT, OUTPUT);
	digitalWrite(DISABLE_CHIP_SELECT, HIGH);
	}
	if (!sd.begin(chipSelect, SPI_SPEED)) {
	if (sd.card()->errorCode()) {
	cout << F(
	"\nSD initialization failed.\n"
	"Do not reformat the card!\n"
	"Is the card correctly inserted?\n"
	"Is chipSelect set to the correct value?\n"
	"Does another SPI device need to be disabled?\n"
	"Is there a wiring/soldering problem?\n");
	cout << F("\nerrorCode: ") << hex << showbase;
	cout << int(sd.card()->errorCode());
	cout << F(", errorData: ") << int(sd.card()->errorData());
	cout << dec << noshowbase << endl;
	return;
	}
	cout << F("\nCard successfully initialized.\n");
	if (sd.vol()->fatType() == 0) {
	cout << F("Can't find a valid FAT16/FAT32 partition.\n");
	reformatMsg();
	return;
	}
	if (!sd.vwd()->isOpen()) {
	cout << F("Can't open root directory.\n");
	reformatMsg();
	return;
	}
	cout << F("Can't determine error type\n");
	return;
	}
	cout << F("\nCard successfully initialized.\n");
	cout << endl;

	uint32_t size = sd.card()->cardSize();
	if (size == 0) {
	cout << F("Can't determine the card size.\n");
	cardOrSpeed();
	return;
	}
	uint32_t sizeMB = 0.000512 * size + 0.5;
	cout << F("Card size: ") << sizeMB;
	cout << F(" MB (MB = 1,000,000 bytes)\n");
	cout << endl;
	cout << F("Volume is FAT") << int(sd.vol()->fatType());
	cout << F(", Cluster size (bytes): ") << 512L * sd.vol()->blocksPerCluster();
	cout << endl << endl;

	cout << F("Files found (date time size name):\n");
	sd.ls(LS_R \| LS_DATE \| LS_SIZE);

	if ((sizeMB > 1100 && sd.vol()->blocksPerCluster() < 64)
	\|\| (sizeMB < 2200 && sd.vol()->fatType() == 32)) {
	cout << F("\nThis card should be reformatted for best performance.\n");
	cout << F("Use a cluster size of 32 KB for cards larger than 1 GB.\n");
	cout << F("Only cards larger than 2 GB should be formatted FAT32.\n");
	reformatMsg();
	return;
	}
	// Read any extra Serial data.
	do {
	delay(10);
	} while (Serial.available() && Serial.read() >= 0);
	cout << F("\nSuccess! Type any character to restart.\n");
	while (!Serial.available()) {
	SysCall::yield();
	}
	}