/* 4-28-2011 Spark Fun Electronics 2011 Nathan Seidle This code is public domain but you buy me a beer if you use this and we meet someday (Beerware license). This example code plays a MP3 from the SD card called 'track001.mp3'. The theory is that you can load a microSD card up with a bunch of MP3s and then play a given 'track' depending on some sort of input such as which pin is pulled low. It relies on the sdfatlib from Bill Greiman: http://code.google.com/p/sdfatlib/ You will need to download and install his library. To compile, you MUST change Sd2PinMap.h of the SDfatlib! The default SS_PIN = 10;. You must change this line under the ATmega328/Arduino area of code to uint8_t const SS_PIN = 9;. This will cause the sdfatlib to use pin 9 as the 'chip select' for the microSD card on pin 9 of the Arduino so that the layout of the shield works. Attach the shield to an Arduino. Load code (after editing Sd2PinMap.h) then open the terminal at 57600bps. This example shows that it takes ~30ms to load up the VS1053 buffer. We can then do whatever we want for ~100ms before we need to return to filling the buffer (for another 30ms). This code is heavily based on the example code I wrote to control the MP3 shield found here: http://www.sparkfun.com/products/9736 This example code extends the previous example by reading the MP3 from an SD card and file rather than from internal memory of the ATmega. Because the current MP3 shield does not have a microSD socket, you will need to add the microSD shield to your Arduino stack. The main gotcha from all of this is that you have to make sure your CS pins for each device on an SPI bus is carefully declared. For the SS pin (aka CS) on the SD FAT libaray, you need to correctly set it within Sd2PinMap.h. The default pin in Sd2PinMap.h is 10. If you're using the SparkFun microSD shield with the SparkFun MP3 shield, the SD CS pin is pin 9. Four pins are needed to control the VS1503: DREQ CS DCS Reset (optional but good to have access to) Plus the SPI bus Only the SPI bus pins and another CS pin are needed to control the microSD card. What surprised me is the fact that with a normal MP3 we can do other things for up to 100ms while the MP3 IC crunches through it's fairly large buffer of 2048 bytes. As long as you keep your sensor checks or serial reporting to under 100ms and leave ~30ms to then replenish the MP3 buffer, you can do quite a lot while the MP3 is playing glitch free. */ #include //Add the SdFat Libraries #include #include //Create the variables to be used by SdFat Library Sd2Card card; SdVolume volume; SdFile root; SdFile track; //This is the name of the file on the microSD card you would like to play //Stick with normal 8.3 nomeclature. All lower-case works well. //Note: you must name the tracks on the SD card with 001, 002, 003, etc. //For example, the code is expecting to play 'track002.mp3', not track2.mp3. char trackName[] = "track002.mp3"; int trackNumber = 0; const int BUTTON = 12; // the input pin where the // pushbutton is connected int val = 0; // val will be used to store the state // of the input pin char errorMsg[100]; //This is a generic array used for sprintf of error messages #define TRUE 0 #define FALSE 1 //MP3 Player Shield pin mapping. See the schematic #define MP3_XCS 6 //Control Chip Select Pin (for accessing SPI Control/Status registers) #define MP3_XDCS 7 //Data Chip Select / BSYNC Pin #define MP3_DREQ 2 //Data Request Pin: Player asks for more data #define MP3_RESET 8 //Reset is active low //Remember you have to edit the Sd2PinMap.h of the sdfatlib library to correct control the SD card. //VS10xx SCI Registers #define SCI_MODE 0x00 #define SCI_STATUS 0x01 #define SCI_BASS 0x02 #define SCI_CLOCKF 0x03 #define SCI_DECODE_TIME 0x04 #define SCI_AUDATA 0x05 #define SCI_WRAM 0x06 #define SCI_WRAMADDR 0x07 #define SCI_HDAT0 0x08 #define SCI_HDAT1 0x09 #define SCI_AIADDR 0x0A #define SCI_VOL 0x0B #define SCI_AICTRL0 0x0C #define SCI_AICTRL1 0x0D #define SCI_AICTRL2 0x0E #define SCI_AICTRL3 0x0F void setup() { pinMode(MP3_DREQ, INPUT); pinMode(MP3_XCS, OUTPUT); pinMode(MP3_XDCS, OUTPUT); pinMode(MP3_RESET, OUTPUT); digitalWrite(MP3_XCS, HIGH); //Deselect Control digitalWrite(MP3_XDCS, HIGH); //Deselect Data digitalWrite(MP3_RESET, LOW); //Put VS1053 into hardware reset pinMode(BUTTON, INPUT); // and BUTTON is an input Serial.begin(57600); //Use serial for debugging Serial.println("MP3 Testing"); //Setup SD card interface pinMode(10, OUTPUT); //Pin 10 must be set as an output for the SD communication to work. if (!card.init(SPI_FULL_SPEED)) Serial.println("Error: Card init"); //Initialize the SD card and configure the I/O pins. if (!volume.init(&card)) Serial.println("Error: Volume ini"); //Initialize a volume on the SD card. if (!root.openRoot(&volume)) Serial.println("Error: Opening root"); //Open the root directory in the volume. //We have no need to setup SPI for VS1053 because this has already been done by the SDfatlib //From page 12 of datasheet, max SCI reads are CLKI/7. Input clock is 12.288MHz. //Internal clock multiplier is 1.0x after power up. //Therefore, max SPI speed is 1.75MHz. We will use 1MHz to be safe. SPI.setClockDivider(SPI_CLOCK_DIV16); //Set SPI bus speed to 1MHz (16MHz / 16 = 1MHz) SPI.transfer(0xFF); //Throw a dummy byte at the bus //Initialize VS1053 chip delay(10); digitalWrite(MP3_RESET, HIGH); //Bring up VS1053 //delay(10); //We don't need this delay because any register changes will check for a high DREQ //Mp3SetVolume(20, 20); //Set initial volume (20 = -10dB) LOUD Mp3SetVolume(0, 0); //Set initial volume (20 = -10dB) Manageable //Mp3SetVolume(80, 80); //Set initial volume (20 = -10dB) More quiet //Let's check the status of the VS1053 int MP3Mode = Mp3ReadRegister(SCI_MODE); int MP3Status = Mp3ReadRegister(SCI_STATUS); int MP3Clock = Mp3ReadRegister(SCI_CLOCKF); Serial.print("SCI_Mode (0x4800) = 0x"); Serial.println(MP3Mode, HEX); Serial.print("SCI_Status (0x48) = 0x"); Serial.println(MP3Status, HEX); int vsVersion = (MP3Status >> 4) & 0x000F; //Mask out only the four version bits Serial.print("VS Version (VS1053 is 4) = "); Serial.println(vsVersion, DEC); //The 1053B should respond with 4. VS1001 = 0, VS1011 = 1, VS1002 = 2, VS1003 = 3 Serial.print("SCI_ClockF = 0x"); Serial.println(MP3Clock, HEX); //Now that we have the VS1053 up and running, increase the internal clock multiplier and up our SPI rate Mp3WriteRegister(SCI_CLOCKF, 0x60, 0x00); //Set multiplier to 3.0x //From page 12 of datasheet, max SCI reads are CLKI/7. Input clock is 12.288MHz. //Internal clock multiplier is now 3x. //Therefore, max SPI speed is 5MHz. 4MHz will be safe. SPI.setClockDivider(SPI_CLOCK_DIV4); //Set SPI bus speed to 4MHz (16MHz / 4 = 4MHz) MP3Clock = Mp3ReadRegister(SCI_CLOCKF); Serial.print("SCI_ClockF = 0x"); Serial.println(MP3Clock, HEX); //MP3 IC setup complete } void loop(){ val = digitalRead(BUTTON); // read input value and store it // check whether the input is HIGH (button pressed) if (val == HIGH) { playMP3(trackName); } else { } } //PlayMP3 pulls 32 byte chunks from the SD card and throws them at the VS1053 //We monitor the DREQ (data request pin). If it goes low then we determine if //we need new data or not. If yes, pull new from SD card. Then throw the data //at the VS1053 until it is full. void playMP3(char* fileName) { if (!track.open(&root, fileName, O_READ)) { //Open the file in read mode. sprintf(errorMsg, "Failed to open %s", fileName); Serial.println(errorMsg); return; } Serial.println("Track open"); uint8_t mp3DataBuffer[32]; //Buffer of 32 bytes. VS1053 can take 32 bytes at a go. //track.read(mp3DataBuffer, sizeof(mp3DataBuffer)); //Read the first 32 bytes of the song int need_data = TRUE; long replenish_time = millis(); Serial.println("Start MP3 decoding"); while(1) { while(!digitalRead(MP3_DREQ)) { //DREQ is low while the receive buffer is full //You can do something else here, the buffer of the MP3 is full and happy. //Maybe set the volume or test to see how much we can delay before we hear audible glitches //If the MP3 IC is happy, but we need to read new data from the SD, now is a great time to do so if(need_data == TRUE) { if(!track.read(mp3DataBuffer, sizeof(mp3DataBuffer))) { //Try reading 32 new bytes of the song //Oh no! There is no data left to read! //Time to exit break; } need_data = FALSE; } //Serial.println("."); //Print a character to show we are doing nothing //This is here to show how much time is spent transferring new bytes to the VS1053 buffer. Relies on replenish_time below. Serial.print("Time to replenish buffer: "); Serial.print(millis() - replenish_time, DEC); Serial.print("ms"); //Test to see just how much we can do before the audio starts to glitch long start_time = millis(); //delay(150); //Do NOTHING - audible glitches //delay(135); //Do NOTHING - audible glitches //delay(120); //Do NOTHING - barely audible glitches delay(100); //Do NOTHING - sounds fine Serial.print(" Idle time: "); Serial.print(millis() - start_time, DEC); Serial.println("ms"); //Look at that! We can actually do quite a lot without the audio glitching //Now that we've completely emptied the VS1053 buffer (2048 bytes) let's see how much //time the VS1053 keeps the DREQ line high, indicating it needs to be fed replenish_time = millis(); } if(need_data == TRUE){ //This is here in case we haven't had any free time to load new data if(!track.read(mp3DataBuffer, sizeof(mp3DataBuffer))) { //Go out to SD card and try reading 32 new bytes of the song //Oh no! There is no data left to read! //Time to exit break; } need_data = FALSE; } //Once DREQ is released (high) we now feed 32 bytes of data to the VS1053 from our SD read buffer digitalWrite(MP3_XDCS, LOW); //Select Data for(int y = 0 ; y < sizeof(mp3DataBuffer) ; y++) { SPI.transfer(mp3DataBuffer[y]); // Send SPI byte } digitalWrite(MP3_XDCS, HIGH); //Deselect Data need_data = TRUE; //We've just dumped 32 bytes into VS1053 so our SD read buffer is empty. Set flag so we go get more data } while(!digitalRead(MP3_DREQ)) ; //Wait for DREQ to go high indicating transfer is complete digitalWrite(MP3_XDCS, HIGH); //Deselect Data track.close(); //Close out this track sprintf(errorMsg, "Track %s done!", fileName); Serial.println(errorMsg); } //Write to VS10xx register //SCI: Data transfers are always 16bit. When a new SCI operation comes in //DREQ goes low. We then have to wait for DREQ to go high again. //XCS should be low for the full duration of operation. void Mp3WriteRegister(unsigned char addressbyte, unsigned char highbyte, unsigned char lowbyte){ while(!digitalRead(MP3_DREQ)) ; //Wait for DREQ to go high indicating IC is available digitalWrite(MP3_XCS, LOW); //Select control //SCI consists of instruction byte, address byte, and 16-bit data word. SPI.transfer(0x02); //Write instruction SPI.transfer(addressbyte); SPI.transfer(highbyte); SPI.transfer(lowbyte); while(!digitalRead(MP3_DREQ)) ; //Wait for DREQ to go high indicating command is complete digitalWrite(MP3_XCS, HIGH); //Deselect Control } //Read the 16-bit value of a VS10xx register unsigned int Mp3ReadRegister (unsigned char addressbyte){ while(!digitalRead(MP3_DREQ)) ; //Wait for DREQ to go high indicating IC is available digitalWrite(MP3_XCS, LOW); //Select control //SCI consists of instruction byte, address byte, and 16-bit data word. SPI.transfer(0x03); //Read instruction SPI.transfer(addressbyte); char response1 = SPI.transfer(0xFF); //Read the first byte while(!digitalRead(MP3_DREQ)) ; //Wait for DREQ to go high indicating command is complete char response2 = SPI.transfer(0xFF); //Read the second byte while(!digitalRead(MP3_DREQ)) ; //Wait for DREQ to go high indicating command is complete digitalWrite(MP3_XCS, HIGH); //Deselect Control int resultvalue = response1 << 8; resultvalue |= response2; return resultvalue; } //Set VS10xx Volume Register void Mp3SetVolume(unsigned char leftchannel, unsigned char rightchannel){ Mp3WriteRegister(SCI_VOL, leftchannel, rightchannel); }