The CEC framework provides a unified kernel interface for use with HDMI CEC hardware. It is designed to handle a multiple types of hardware (receivers, transmitters, USB dongles). The framework also gives the option to decide what to do in the kernel driver and what should be handled by userspace applications. In addition it integrates the remote control passthrough feature into the kernel’s remote control framework.
The CEC protocol enables consumer electronic devices to communicate with each other through the HDMI connection. The protocol uses logical addresses in the communication. The logical address is strictly connected with the functionality provided by the device. The TV acting as the communication hub is always assigned address 0. The physical address is determined by the physical connection between devices.
The CEC framework described here is up to date with the CEC 2.0 specification. It is documented in the HDMI 1.4 specification with the new 2.0 bits documented in the HDMI 2.0 specification. But for most of the features the freely available HDMI 1.3a specification is sufficient:
The struct cec_adapter represents the CEC adapter hardware. It is created by calling cec_allocate_adapter() and deleted by calling cec_delete_adapter():
To create an adapter you need to pass the following information:
To register the /dev/cecX device node and the remote control device (if CEC_CAP_RC is set) you call:
where parent is the parent device.
To unregister the devices call:
Note: if cec_register_adapter() fails, then call cec_delete_adapter() to clean up. But if cec_register_adapter() succeeded, then only call cec_unregister_adapter() to clean up, never cec_delete_adapter(). The unregister function will delete the adapter automatically once the last user of that /dev/cecX device has closed its file handle.
The following low-level adapter operations have to be implemented in your driver:
struct cec_adap_ops
{
/* Low-level callbacks */
int (*adap_enable)(struct cec_adapter *adap, bool enable);
int (*adap_monitor_all_enable)(struct cec_adapter *adap, bool enable);
int (*adap_log_addr)(struct cec_adapter *adap, u8 logical_addr);
int (*adap_transmit)(struct cec_adapter *adap, u8 attempts,
u32 signal_free_time, struct cec_msg *msg);
void (*adap_status)(struct cec_adapter *adap, struct seq_file *file);
/* High-level callbacks */
...
};
The five low-level ops deal with various aspects of controlling the CEC adapter hardware:
To enable/disable the hardware:
This callback enables or disables the CEC hardware. Enabling the CEC hardware means powering it up in a state where no logical addresses are claimed. This op assumes that the physical address (adap->phys_addr) is valid when enable is true and will not change while the CEC adapter remains enabled. The initial state of the CEC adapter after calling cec_allocate_adapter() is disabled.
Note that adap_enable must return 0 if enable is false.
To enable/disable the ‘monitor all’ mode:
If enabled, then the adapter should be put in a mode to also monitor messages that not for us. Not all hardware supports this and this function is only called if the CEC_CAP_MONITOR_ALL capability is set. This callback is optional (some hardware may always be in ‘monitor all’ mode).
Note that adap_monitor_all_enable must return 0 if enable is false.
To program a new logical address:
If logical_addr == CEC_LOG_ADDR_INVALID then all programmed logical addresses are to be erased. Otherwise the given logical address should be programmed. If the maximum number of available logical addresses is exceeded, then it should return -ENXIO. Once a logical address is programmed the CEC hardware can receive directed messages to that address.
Note that adap_log_addr must return 0 if logical_addr is CEC_LOG_ADDR_INVALID.
To transmit a new message:
This transmits a new message. The attempts argument is the suggested number of attempts for the transmit.
The signal_free_time is the number of data bit periods that the adapter should wait when the line is free before attempting to send a message. This value depends on whether this transmit is a retry, a message from a new initiator or a new message for the same initiator. Most hardware will handle this automatically, but in some cases this information is needed.
The CEC_FREE_TIME_TO_USEC macro can be used to convert signal_free_time to microseconds (one data bit period is 2.4 ms).
To log the current CEC hardware status:
This optional callback can be used to show the status of the CEC hardware. The status is available through debugfs: cat /sys/kernel/debug/cec/cecX/status
Your adapter driver will also have to react to events (typically interrupt driven) by calling into the framework in the following situations:
When a transmit finished (successfully or otherwise):
The status can be one of:
The *_cnt arguments are the number of error conditions that were seen. This may be 0 if no information is available. Drivers that do not support hardware retry can just set the counter corresponding to the transmit error to 1, if the hardware does support retry then either set these counters to 0 if the hardware provides no feedback of which errors occurred and how many times, or fill in the correct values as reported by the hardware.
When a CEC message was received:
Speaks for itself.
Typically the CEC hardware provides interrupts that signal when a transmit finished and whether it was successful or not, and it provides and interrupt when a CEC message was received.
The CEC driver should always process the transmit interrupts first before handling the receive interrupt. The framework expects to see the cec_transmit_done call before the cec_received_msg call, otherwise it can get confused if the received message was in reply to the transmitted message.
The low-level operations drive the hardware, the high-level operations are CEC protocol driven. The following high-level callbacks are available:
struct cec_adap_ops {
/* Low-level callbacks */
...
/* High-level CEC message callback */
int (*received)(struct cec_adapter *adap, struct cec_msg *msg);
};
The received() callback allows the driver to optionally handle a newly received CEC message
If the driver wants to process a CEC message, then it can implement this callback. If it doesn’t want to handle this message, then it should return -ENOMSG, otherwise the CEC framework assumes it processed this message and it will not do anything with it.
CEC Adapter drivers can call the following CEC framework functions:
Transmit a CEC message. If block is true, then wait until the message has been transmitted, otherwise just queue it and return.
Change the physical address. This function will set adap->phys_addr and send an event if it has changed. If cec_s_log_addrs() has been called and the physical address has become valid, then the CEC framework will start claiming the logical addresses. If block is true, then this function won’t return until this process has finished.
When the physical address is set to a valid value the CEC adapter will be enabled (see the adap_enable op). When it is set to CEC_PHYS_ADDR_INVALID, then the CEC adapter will be disabled. If you change a valid physical address to another valid physical address, then this function will first set the address to CEC_PHYS_ADDR_INVALID before enabling the new physical address.
Claim the CEC logical addresses. Should never be called if CEC_CAP_LOG_ADDRS is set. If block is true, then wait until the logical addresses have been claimed, otherwise just queue it and return. To unconfigure all logical addresses call this function with log_addrs set to NULL or with log_addrs->num_log_addrs set to 0. The block argument is ignored when unconfiguring. This function will just return if the physical address is invalid. Once the physical address becomes valid, then the framework will attempt to claim these logical addresses.