Hello Michael, On Tue, Jul 14, 2020 at 11:09:28PM +0200, Michael Walle wrote: > > My wishlist (just as it comes to my mind, so no guarantee of > > completeness): > > > > - can do 0% duty cycle for all supported period lengths > > - can do 100% duty cycle for all supported period lengths > > - supports both polarities > > - supports immediate change of configuration and after completion of > > the currently running period > > - atomic update (i.e. if you go from configuration A to configuration B > > the hardware guarantees to only emit periods of type A and then type > > B. (Depending on the item above, the last A period might be cut off.) > > We actually discussed this, because the implementation would be easier. But > if the change takes place immediately you might end up with a longer duty > cycle. Assume the PWM runs at 80% duty cycle and starts with the on-period. > If you now change that to 50% you might end up with one successive duty > cycle of "130%". Eg. the 80% of the old and right after that you switch to > the new 50% and then you'd have a high output which corresponds to a 130% > cycle. I don't know if that is acceptable for all applications. I thought this is a "change takes place immediately" implementation?! So these problems are actually real here. (And this not happening is exactly my wish here. Is there a mis-understanding?) > > - emits an irq when configuration changes > > Why would you need the interrupt? To know that the new setting is active. Currently Thierry's ideal PWM implementation blocks in pwm_apply_state() until the new setting is active. So some signaling is nice. > > > > If you change only cycle but not mode, does the hardware complete the > > > > currently running period? > > > > > > No it does not. > > > > Please document this as a Limitation. > > I've discussed this internally, for now its a limitation. In the worst > case you'd do one 100% duty cycle. Maybe we can fix the hardware. I > acknowledge that this is a severe limitation, esp. if you use the PWM > for controlling stuff (for now its only LCD backlight.. so thats ok). That happens if you reduce the duty cycle from A to B and the counter is already bigger than B but smaller than A, right? The fix would be to compare for counter >= match instead of counter = match. (Which then would result in a period with a duty cycle bigger than B but smaller than A. Also not ideal, but probably better.) > > > > What about disable()? > > > > > > Mhh well, it would do one 100% cycle.. mhh ;) Lets see if there we can > > > fix that (in hardware), not much we can do in the driver here. We are > > > _very_ constraint in size, therefore all that little edge cases fall > > > off > > > the table. > > > > You're saying that on disable the hardware emits a constant high level > > for one cycle? I hope not ... > > Mh, I was mistaken, disabling the PWM will turn it off immediately, but And does turn off mean, the output gets inactive? If so you might also disable the hardware if a 0% duty cycle is configured assuming this saves some energy without modifying the resulting wave form. > one 100% duty cycle may happen if you change from a higher to a lower > duty cycle setting. See above. > > > I never programmed a CPLD to emulate a hardware PWM, but I wonder if > > these are really edge cases that increase the size of the binary?! > > At the moment there is only one 8bit register which stores the value > which is used for matching. If you want to change that setting after > a whole cycle, you'd use another 8bit register to cache the new value. > So this would at least needs 8 additional flip-flops. This doesn't > sound much, but we are already near 100% usage of the CPLD. So its > hard to convince people why this is really necessary. OK. (Maybe there is enough space to allow implementing 100% for mode 0?) Best regards Uwe -- Pengutronix e.K. | Uwe Kleine-König | Industrial Linux Solutions | https://www.pengutronix.de/ |
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