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Kinetis I2C Driver

This is a tiny driver that allows you to access I2C (IIC, I²C, or I squared C) on Freescale Kinetis microcontrollers. It works asynchronously (interrupt-driven), supports repeated start (restart) and does not depend on any large software framework.

License

MIT. I believe in freedom, which means I believe in letting you do whatever you want with this code.

If you like the code and find it useful, please take a look at PartsBox (https://partsbox.com/), my app that lets you take control of your electronic parts inventory, parts ordering/purchasing, BOM pricing, and production.

Features

  • Small.
  • Works.
  • Reads and writes.
  • Implements repeated start.
  • Uses the Bus Pirate convention.

Limitations

This is not a fully-featured driver. Only master mode is implemented. Only 7-bit addressing is supported. Addressing is fully manual: it is your responsibility to shift the 7-bit I2C address to the left and add the R/W bit (actually, I see this as an advantage).

You have to enable the clock for the I2C peripheral(s) yourself, you also have to supply the clock divider values.

There is almost no error handling.

Rationale

I wanted to use Kinetis microcontrollers to communicate using I2C, but could not find a decent driver. The I2C module is very primitive and needs quite a bit of code. All examples I could find were overly simplistic and only worked in blocking mode. Well, I care about power consumption, so I only write asynchronous interrupt-driven code.

I used to think that once the Kinetis SDK gets written and actually supports all devices, this code would not be necessary. But now that the SDK exists, there are still many reasons to use my code:

  • The KSDK does not support all devices.
  • The driver is fairly large.
  • The driver does not support processing full write/restart/read sequences in an asynchronous way.

There is another reason for publishing the code. I wrote this and then had to put my Kinetis-related projects on hold. After several months I forgot having written this driver and started searching online for one… only to finally find it using Spotlight, on my hard drive. This is what happens if you work on too many projects. To avoid this happening in the future, I now intend to publish most things I write as soon as they are reasonably complete, so that I can find them online when I need them.

Download

Get it directly from the Github repository.

Usage

Here's an example of performing a write and then a read with repeated start (restart) from an MMA8451Q accelerometer with a 7-bit address of 0x1c.

  uint32_t status;
  uint16_t init_sequence[] = {0x3a, 0x0d, I2C_RESTART, 0x3b, I2C_READ};
  uint8_t device_id = 0;		/* Will contain the device id after sequence has been processed. */

  /* These depend on the particular chip being used. */
  SIM->SCGC4 |= SIM_SCGC4_I2C0_MASK;
  SIM->SCGC5 |= SIM_SCGC5_PORTB_MASK;
  PORTB->PCR[0] = PORT_PCR_MUX(2) | PORT_PCR_ODE_MASK;
  PORTB->PCR[1] = PORT_PCR_MUX(2) | PORT_PCR_ODE_MASK;

  status = i2c_init(0, 0x01, 0x20);
  status = i2c_send_sequence(0, init_sequence, 5, &device_id, my_callback, (void*)0x1234);

After successful transmission, device_id should contain the device id of the accelerometer (check with a debugger). The endless loop is there so that you can check the result of the I2C transmission. It is performed asynchronously, so without the loop the program would terminate before the transmission ended.

First, i2c_init() needs to be called. It takes three parameters: device number (devices are numbered starting from 0, most Kinetis microcontrollers have only one I2C device), mult and icr. The last two are raw values that will be written into the F register (see your device reference manual for details).

If you have more than one I2C module, remember to define I2C_NUMBER_OF_DEVICES appropriately in i2c.h.

Note that to successfully use I2C on Kinetis chips, you also have to:

  1. Enable clock gating to the I2C module.
  2. Enable clock gating to the PORT module that has the pins used for I2C.
  3. Configure the PORT PCR registers so that I2C function is selected and the pins are set to open drain (necessary on some devices).

Data transmission (both transmit and receive) is handled by i2c_send_sequence(). It sends a command/data sequence that can include restarts, writes and reads. Every transmission begins with a START, and ends with a STOP so you do not have to specify that.

i2c_send_sequence() takes six parameters:

  • channel_number is the I2C device number,
  • sequence is the I2C operation sequence that should be performed. It can include any number of writes, restarts and reads. Note that the sequence is composed of uint16_t, not uint8_t elements. This is because we have to support out-of-band signalling of I2C_RESTART and I2C_READ operations, while still passing through 8-bit data.
  • sequence_length is the number of sequence elements (not bytes). Sequences of arbitrary (well, 32-bit) length are supported, but there is an upper limit on the number of segments (restarts): no more than 42. This limit is imposed by the Linux ioctl() I2C interface. The minimum sequence length is (rather obviously) 2.
  • received_data should point to a buffer that can hold as many bytes as there are I2C_READ operations in the sequence. If there are no reads, 0 can be passed, as this parameter will not be used,
  • callback_fn is a pointer to a function that will get called upon successful completion of the entire sequence. If 0 is supplied, no function will be called. Note that the function will be called fron an interrupt handler, so it should do the absolute minimum possible (such as enqueue an event to be processed later, set a flag, exit sleep mode, etc).
  • user_data is a pointer that will be passed to the callback_fn.

i2c_send_sequence() uses the Bus Pirate I2C convention, which I found to be very useful and compact. As an example, this Bus Pirate sequence:

 "[0x38 0x0c [ 0x39 r ]"

is specified as:

 {0x38, 0x0c, I2C_RESTART, 0x39, I2C_READ};

in I2C terms, this sequence means:

  1. Write 0x0c to device 0x1c (0x0c is usually the register address).
  2. Do not release the bus.
  3. Issue a repeated start.
  4. Read one byte from device 0x1c (which would normally be the contents of register 0x0c on that device).

The sequence may read multiple bytes:

{0x38, 0x16, I2C_RESTART, 0x39, I2C_READ, I2C_READ, I2C_READ};

This will normally read three bytes from device 0x1c starting at register 0x16. In this case you need to provide a pointer to a buffer than can hold three bytes.

Note that start and stop are added for you automatically, but addressing is fully manual: it is your responsibility to shift the 7-bit I2C address to the left and add the R/W bit. The examples above communicate with a device whose I2C address is 0x1c, which shifted left gives 0x38. For reads we use 0x39, which is (0x1c<<1)|1.

If you wonder why I consider the Bus Pirate convention useful, note that what you specify in the sequence is very close to the actual bytes on the wire. This makes debugging and reproducing other sequences easy. Also, you can use the Bus Pirate to prototype, and then easily convert the tested sequences into actual code.

Devices

This code has been used at least on the following devices:

  • MK02FN128
  • MK20DX128
  • MKL03Z32
  • MKL17Z128
  • MKL25Z128

If you have a Kinetis L device device with the 1N96F mask, make sure the ERRATA_1N96F_WORKAROUND define is enabled. This should happen automatically with newer CMSIS includes. It enables a workaround for issue 6070: I2C: Repeat start cannot be generated if the I2Cx_F[MULT] field is set to a non-zero value.

Building and Packaging

You can build the example by dropping it into a newly created bare metal or KSDK project for your Kinetis chip. Place main.c, i2c.c and i2c.h in sources.

Packaging? Come on. What packaging? Just put those two files in your project. Or put the git repo in as a subproject. Or package it any way you wish — but I'm afraid I won't be able to help.