On Tue, 7 Sep 2021 15:47:05 +0000 Machnikowski, Maciej wrote:
It can be either in FW or in Linux - depending on the deployment. We try to define the API that would enable Linux to manage that.
We should implement the API for Linux to manage things from the get go.
Yep! Yet let's go one step at a time. I believe once we have the basics (EEC monitoring and recovered clock configuration) we'll be able to implement a basic functionality - and add bells and whistles later on, as there are more capabilities that we could support in SW.
The set API may shape how the get API looks. We need a minimal viable API where the whole control part of it is not "firmware or proprietary tools take care of that".
Do you have public docs on how the whole solution works?
The DPLL will operate on pins, so it will have a pin connected from the MAC/PHY that will have the recovered clock, but the recovered clock can be enabled from any port/lane. That information is kept in the MAC/PHY and the DPLL side will not be aware who it belongs to.
So the clock outputs are muxed to a single pin at the Ethernet IP level, in your design. I wonder if this is the common implementation and therefore if it's safe to bake that into the API. Input from other vendors would be great...
I believe this is the state-of-art: here's the Broadcom public one https://docs.broadcom.com/doc/1211168567832, I believe Marvel has similar solution. But would also be happy to hear others.
Interesting. That reveals the need for also marking the backup (/secondary) clock.
Have you seen any docs on how systems with discreet PHY ASICs mux the clocks?
Also do I understand correctly that the output of the Ethernet IP is just the raw Rx clock once receiver is locked and the DPLL which enum if_synce_state refers to is in the time IP, that DPLL could be driven by GNSS etc?
Ethernet IP/PHY usually outputs a divided clock signal (since it's easier to route) derived from the RX clock. The DPLL connectivity is vendor-specific, as you can use it to connect some external signals, but you can as well just care about relying the SyncE clock and only allow recovering it and passing along the QL info when your EEC is locked. That's why I backed up from a full DPLL implementation in favor of a more generic EEC clock.
What is an ECC clock? To me the PLL state in the Ethernet port is the state of the recovered clock. enum if_eec_state has values like holdover which seem to be more applicable to the "system wide" PLL.
Let me ask this - if one port is training the link and the other one has the lock and is the source - what state will be reported for each port?
The Time IP is again relative and vendor-specific. If SyncE is deployed alongside PTP it will most likely be tightly coupled, but if you only care about having a frequency source - it's not mandatory and it can be as well in the PHY IP.
I would not think having just the freq is very useful.
Also I think I will strip the reported states to the bare minimum defined in the ITU-T G.781 instead of reusing the states that were already defined for a specific DPLL.
This is the right thinking. The DPLL can also have different external sources, like the GNSS, and can also drive different output clocks. But for the most basic SyncE implementation, which only runs on a recovered clock, we won't need the DPLL subsystem.
The GNSS pulse would come in over an external pin, tho, right? Your earlier version of the patchset had GNSS as an enum value, how would the driver / FW know that a given pin means GNSS?
The GNSS 1PPS will more likely go directly to the "full" DPLL. The pin topology can be derived from FW or any vendor-specific way of mapping pins to their sources. And, in "worst" case can just be hardcoded for a specific device.