Documentation/i2c/i2c-protocol - linux - Git at Google

 This document describes the i2c protocol. Or will, when it is finished :-)

 Key to symbols
 ==============

 S     (1 bit) : Start bit
 P     (1 bit) : Stop bit
 Rd/Wr (1 bit) : Read/Write bit. Rd equals 1, Wr equals 0.
 A, NA (1 bit) : Accept and reverse accept bit.
 Addr  (7 bits): I2C 7 bit address. Note that this can be expanded as usual to
                 get a 10 bit I2C address.
 Comm  (8 bits): Command byte, a data byte which often selects a register on
                 the device.
 Data  (8 bits): A plain data byte. Sometimes, I write DataLow, DataHigh
                 for 16 bit data.
 Count (8 bits): A data byte containing the length of a block operation.

 [..]: Data sent by I2C device, as opposed to data sent by the host adapter.


 Simple send transaction
 ======================

 This corresponds to i2c_master_send.

   S Addr Wr [A] Data [A] Data [A] ... [A] Data [A] P


 Simple receive transaction
 ===========================

 This corresponds to i2c_master_recv

   S Addr Rd [A] [Data] A [Data] A ... A [Data] NA P


 Combined transactions
 ====================

 This corresponds to i2c_transfer

 They are just like the above transactions, but instead of a stop bit P
 a start bit S is sent and the transaction continues. An example of
 a byte read, followed by a byte write:

   S Addr Rd [A] [Data] NA S Addr Wr [A] Data [A] P


 Modified transactions
 =====================

 The following modifications to the I2C protocol can also be generated by
 setting these flags for i2c messages. With the exception of I2C_M_NOSTART, they
 are usually only needed to work around device issues:

 I2C_M_IGNORE_NAK:
     Normally message is interrupted immediately if there is [NA] from the
     client. Setting this flag treats any [NA] as [A], and all of
     message is sent.
     These messages may still fail to SCL lo->hi timeout.

 I2C_M_NO_RD_ACK:
     In a read message, master A/NA bit is skipped.

 I2C_M_NOSTART:
     In a combined transaction, no 'S Addr Wr/Rd [A]' is generated at some
     point. For example, setting I2C_M_NOSTART on the second partial message
     generates something like:
       S Addr Rd [A] [Data] NA Data [A] P
     If you set the I2C_M_NOSTART variable for the first partial message,
     we do not generate Addr, but we do generate the startbit S. This will
     probably confuse all other clients on your bus, so don't try this.

     This is often used to gather transmits from multiple data buffers in
     system memory into something that appears as a single transfer to the
     I2C device but may also be used between direction changes by some
     rare devices.

 I2C_M_REV_DIR_ADDR:
     This toggles the Rd/Wr flag. That is, if you want to do a write, but
     need to emit an Rd instead of a Wr, or vice versa, you set this
     flag. For example:
       S Addr Rd [A] Data [A] Data [A] ... [A] Data [A] P

 I2C_M_STOP:
     Force a stop condition (P) after the message. Some I2C related protocols
     like SCCB require that. Normally, you really don't want to get interrupted
     between the messages of one transfer.
	This document describes the i2c protocol. Or will, when it is finished :-)

	Key to symbols
	==============

	S (1 bit) : Start bit
	P (1 bit) : Stop bit
	Rd/Wr (1 bit) : Read/Write bit. Rd equals 1, Wr equals 0.
	A, NA (1 bit) : Accept and reverse accept bit.
	Addr (7 bits): I2C 7 bit address. Note that this can be expanded as usual to
	get a 10 bit I2C address.
	Comm (8 bits): Command byte, a data byte which often selects a register on
	the device.
	Data (8 bits): A plain data byte. Sometimes, I write DataLow, DataHigh
	for 16 bit data.
	Count (8 bits): A data byte containing the length of a block operation.

	[..]: Data sent by I2C device, as opposed to data sent by the host adapter.


	Simple send transaction
	======================

	This corresponds to i2c_master_send.

	S Addr Wr [A] Data [A] Data [A] ... [A] Data [A] P


	Simple receive transaction
	===========================

	This corresponds to i2c_master_recv

	S Addr Rd [A] [Data] A [Data] A ... A [Data] NA P


	Combined transactions
	====================

	This corresponds to i2c_transfer

	They are just like the above transactions, but instead of a stop bit P
	a start bit S is sent and the transaction continues. An example of
	a byte read, followed by a byte write:

	S Addr Rd [A] [Data] NA S Addr Wr [A] Data [A] P


	Modified transactions
	=====================

	The following modifications to the I2C protocol can also be generated by
	setting these flags for i2c messages. With the exception of I2C_M_NOSTART, they
	are usually only needed to work around device issues:

	I2C_M_IGNORE_NAK:
	Normally message is interrupted immediately if there is [NA] from the
	client. Setting this flag treats any [NA] as [A], and all of
	message is sent.
	These messages may still fail to SCL lo->hi timeout.

	I2C_M_NO_RD_ACK:
	In a read message, master A/NA bit is skipped.

	I2C_M_NOSTART:
	In a combined transaction, no 'S Addr Wr/Rd [A]' is generated at some
	point. For example, setting I2C_M_NOSTART on the second partial message
	generates something like:
	S Addr Rd [A] [Data] NA Data [A] P
	If you set the I2C_M_NOSTART variable for the first partial message,
	we do not generate Addr, but we do generate the startbit S. This will
	probably confuse all other clients on your bus, so don't try this.

	This is often used to gather transmits from multiple data buffers in
	system memory into something that appears as a single transfer to the
	I2C device but may also be used between direction changes by some
	rare devices.

	I2C_M_REV_DIR_ADDR:
	This toggles the Rd/Wr flag. That is, if you want to do a write, but
	need to emit an Rd instead of a Wr, or vice versa, you set this
	flag. For example:
	S Addr Rd [A] Data [A] Data [A] ... [A] Data [A] P

	I2C_M_STOP:
	Force a stop condition (P) after the message. Some I2C related protocols
	like SCCB require that. Normally, you really don't want to get interrupted
	between the messages of one transfer.