diff --git a/main.ino b/main.ino new file mode 100644 index 0000000..90713e0 --- /dev/null +++ b/main.ino @@ -0,0 +1,129 @@ +#include +#include +#include "PN532.h" + +PN532_SPI pn532spi(SPI, 10); +PN532 nfc(pn532spi); + +void setup(void) { + Serial.begin(115200); + Serial.println("Hello!"); + + nfc.begin(); + + uint32_t versiondata = nfc.getFirmwareVersion(); + if (! versiondata) + { + Serial.print("Didn't find PN53x board"); + while (1); + } + //Serial.print("Found chip PN5"); Serial.println((versiondata>>24) & 0xFF, HEX); + Serial.print("Firmware ver. "); Serial.print((versiondata>>16) & 0xFF, DEC); + Serial.print('.'); Serial.println((versiondata>>8) & 0xFF, DEC); + + // configure board to read RFID tags + nfc.SAMConfig(); + + Serial.println("Waiting for an ISO14443A Card ..."); +} + + +void loop(void) +{ + uint8_t success; + uint8_t uid[] = { 0, 0, 0, 0, 0, 0, 0 }; // Buffer to store the returned UID + uint8_t uidLength; // Length of the UID (4 or 7 bytes depending on ISO14443A card type) + + // Wait for an ISO14443A type cards (Mifare, etc.). When one is found + // 'uid' will be populated with the UID, and uidLength will indicate + // if the uid is 4 bytes (Mifare Classic) or 7 bytes (Mifare Ultralight) + success = nfc.readPassiveTargetID(PN532_MIFARE_ISO14443A, uid, &uidLength); + + if(success) + { + // Display some basic information about the card + Serial.println("Found an ISO14443A card"); + Serial.print(" UID Length: ");Serial.print(uidLength, DEC);Serial.println(" bytes"); + Serial.print(" UID Value: "); + nfc.PrintHex(uid, uidLength); + Serial.println(""); + + if(uidLength == 4) + { + // We probably have a Mifare Classic card ... + Serial.println("Seems to be a Mifare Classic card (4 byte UID)"); + + // Now we need to try to authenticate it for read/write access + // Try with the factory default KeyA: 0xFF 0xFF 0xFF 0xFF 0xFF 0xFF + Serial.println("Trying to authenticate block 4 with default KEYA value"); + uint8_t keya[6] = { 0xA0, 0xA1, 0xA2, 0xA3, 0xA4, 0xA5 }; + + // Start with block 4 (the first block of sector 1) since sector 0 + // contains the manufacturer data and it's probably better just + // to leave it alone unless you know what you're doing + success = nfc.mifareclassic_AuthenticateBlock(uid, uidLength, 44, 0, keya); + + if(success) + { + Serial.println("Sector 1 (Blocks 4..7) has been authenticated"); + uint8_t data[16]; + + // If you want to write something to block 4 to test with, uncomment + // the following line and this text should be read back in a minute + // data = { 'a', 'd', 'a', 'f', 'r', 'u', 'i', 't', '.', 'c', 'o', 'm', 0, 0, 0, 0}; + // success = nfc.mifareclassic_WriteDataBlock (4, data); + + // Try to read the contents of block 4 + success = nfc.mifareclassic_ReadDataBlock(44, data); + + if(success) + { + // Data seems to have been read ... spit it out + Serial.println("Reading Block 4:"); + nfc.PrintHexChar(data, 16); + nfc.mifareclassic_ReadDataBlock(45, data); + nfc.PrintHexChar(data, 16); + nfc.mifareclassic_ReadDataBlock(46, data); + nfc.PrintHexChar(data, 16); + Serial.println(""); + + // Wait a bit before reading the card again + delay(1000); + } + else + { + Serial.println("Ooops ... unable to read the requested block. Try another key?"); + } + } + else + { + Serial.println("Ooops ... authentication failed: Try another key?"); + } + } + + if(uidLength == 7) + { + // We probably have a Mifare Ultralight card ... + Serial.println("Seems to be a Mifare Ultralight tag (7 byte UID)"); + + // Try to read the first general-purpose user page (#4) + Serial.println("Reading page 4"); + uint8_t data[32]; + success = nfc.mifareultralight_ReadPage (4, data); + if(success) + { + // Data seems to have been read ... spit it out + nfc.PrintHexChar(data, 4); + Serial.println(""); + + // Wait a bit before reading the card again + delay(1000); + } + else + { + Serial.println("Ooops ... unable to read the requested page!?"); + } + } + } +} + -- libgit2 0.21.2