The following code demonstrates how to read a register that is 2 bytes (16 bits) long over I2C. It will work with almost all I2C devices like EEPROMs, ADCs and others, provided you have the correct. Note that some devices like the LAN9303 have a slightly different addressing scheme or other peculiarities. In my opinion, it’s most efficient to just try out the standard way of reading a register and start from there.
Note that this code does not implement error handling for the sake of simplicity. Additionally, we wait for data using delay() instead of Wire.available(). This is a minimal example so it creates minimal confusion for the reader. We will provide a full example with error handling in a followup post.
Option 1: Reading the register into an uint16_t (recommended)
const uint8_t SLAVE_I2C_ADDRESS = 0b1010;
const uint16_t SLAVE_I2C_REGISTER_ADDRESS = 0x50;
Wire.beginTransmission(SLAVE_I2C_ADDRESS);
Wire.write(SLAVE_I2C_REGISTER_ADDRESS);
Wire.endTransmission();
Wire.requestFrom(SLAVE_I2C_ADDRESS, 2); // This register is 16 bits = 2 bytes long
delay(5); // Wait for data to be available
// Read directly into an uint32_t
uint16_t buf;
Wire.readBytes((uint8_t*)&buf, 2);
// Print register value
Serial.printf("Register value: %04x\r\n", __builtin_bswap16(buf));For an explanation on why we need __builtin_bswap16(), see How to print 16-bit uint16_t as four hex digits in Arduino
Option 2: Reading the register into an uint8_t array
const uint8_t SLAVE_I2C_ADDRESS = 0b1010;
const uint16_t SLAVE_I2C_REGISTER_ADDRESS = 0x50;
Wire.beginTransmission(SLAVE_I2C_ADDRESS);
Wire.write(SLAVE_I2C_REGISTER_ADDRESS);
Wire.endTransmission();
Wire.requestFrom(SLAVE_I2C_ADDRESS, 2); // This register is 16 bits = 2 bytes long
delay(5); // Wait for data to be available
// Read into a 2-byte buffer
uint8_t buf[2];
Wire.readBytes(buf, 2);
// Print register value
Serial.printf("Register value: %02x%02x\r\n", buf[0], buf[1]);Also see: