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I2C HWIP Technical Specification

i2c:

Overview

This document specifies I2C hardware IP functionality. This module conforms to the Comportable guideline for peripheral functionality. See that document for integration overview within the broader top level system.

Features

  • Two-pin clock-data parallel bidirectional external interface: SCL (serial clock line) and SDA (serial data line)
  • Support for I2C Controller ("I2C Master"1) and I2C Target ("I2C Slave"1) device modes
  • Support for Standard-mode (100 kbaud), Fast-mode (400 kbaud) and Fast-mode Plus (1 Mbaud)
  • Bandwidth up to 1 Mbaud
  • Support for all "Mandatory" features as specified for I2C Controllers (as listed in Table 2 of the I2C specification (revision 6)):
    • Start condition
    • Stop condition
    • Acknowledge (ACK)
    • 7-bit target address
  • Support for the following optional capabilities:
    • Clock stretching in the controller mode
    • Automatic clock stretching in the target mode2
    • Programmable automatic ACK control in the target mode
  • Support for multi-controller features:
    • Controller-controller clock synchronization
    • Controller bus arbitration
    • Target responses to broadcast transfers (similar to arbitration)
    • Bus idle detection
  • Byte-formatted register interface with four separate queues: two queues in the controller mode, one for holding read data (RX), the other for holding bytes to be transmitted (TX: addresses or write data) and two queues in the target mode, for holding read (RX) and write (TX) data
  • Direct SCL and SDA control in "Override mode" (for debugging)
  • SCL and SDA ports mapped to I/O via the pinmux
  • Interrupts in the controller mode for FMT and RX FIFO overflow, target NACK, SCL/SDA signal interference, timeout, unstable SDA signal levels, and transaction complete
  • Interrupts in the target mode for TX FIFO empty during a read, TX FIFO nonempty at the end of a read, TX overflow and ACQ FIFO full, controller sending STOP after ACK, and controller ceasing to send SCL pulses during an ongoing transaction
  • Loopback support with external controller when in target operation
  • SW may reset I2C block using the Reset Manager

1 lowRISC is avoiding the fraught terms master/slave and defaulting to controller/target where applicable.

2 The target is only compatible with controllers that support clock stretching. For controllers that do not support clock stretching, it is expected that there must be an additional protocol to guarantee there is always sufficient space and data. These protocols are not in scope of this document.

Description

This IP block implements the I2C specification (rev. 6), though with some variation in nomenclature. For the purposes of this document, an "I2C Controller" meets the specifications put forth for a "Master" device. Furthermore, a device which meets the specifications put forward for an "I2C Slave" device is here referred to as an "I2C Target" or "I2C Target Device". Note that there are some places where "host" is used, such as in register and interrupt names. This is equivalent to "controller" and comes from a time before more recent I2C and SMBus specifications settled on "controller" being the replacement. It should not be confused with "SMBus Host," which has a specific meaning in that protocol.

At a high-level, the I2C protocol is a clock-parallel serial protocol, with at least one controller issuing transactions to a number of targets on the same bus. A transaction may consist of multiple transfers, each of which has its own address byte and command bit (R/W). However, it is strongly recommended that all transfers in a transaction are issued to the same target address. Multiple controllers may begin a transaction simultaneously, but bus arbitration will cause only one stream of bits to reach a target. This IP block can detect and report lost bus arbitration, and typically, the next action for software is to retry the transaction.

Every transfer consists of a number of bytes transmitted, either from controller-to-target or target-to-controller. Each byte is typically followed by a single bit acknowledgement (ACK) from the receiving side. Typically each transfer consists of:

  1. A START signal, issued by the controller.
  2. An address, issued by the controller, encoded using 7 bits.
  3. An R/W bit indicating if the transaction is a read-from or a write-to the target device. The R/W bit is encoded along with the address.
  4. An acknowledge signal (ACK) sent by the target device.
  5. Data bytes, where the number of bytes required is indicated by the controller, in a manner which differs between reads and writes.
    • For write transactions, the target device sends an ACK signal after every byte received. The controller indicates the end of a transaction by sending a STOP or repeating the START signal.
    • For read transactions, the target device continues to send data as long as the controller acknowledges the target-issued data by sending an ACK signal. Once the controller has received all the required data it indicates that no more data is needed by explicitly de-asserting the ACK signal (this is called a NACK signal) just before sending a STOP or a repeated START signal.
  6. A STOP signal or a repeated START signal.

All well-behaved transactions end with a STOP signal, which indicates the end of the last transfer and when the bus is free again. However, this IP does support detection of bus timeouts, when there has been no activity for a specified amount of time.

This protocol is generally quite flexible with respect to timing constraints, and slow enough to be managed by a software microcontroller, however such an implementation requires frequent activity on the part of the microcontroller. This IP presents a simple register interface and state-machine to manage the corresponding I/O pins directly using a byte-formatted programming model.

Compatibility

This IP block should be compatible with any target device covered by the I2C specification (rev. 6), operating at speeds up to 1 Mbaud. This IP in the controller mode issues addresses in 7-bit encoding, and in the target mode, receives addresses in 7-bit encoding. (It remains the obligation of system designers to ensure that devices remain in a 7-bit address space.) This IP also supports clock-stretching, should that be required by target devices.