BigEd wrote:
In some systems one might have another clock which rises earlier and gives more time to a memory access. It would of course be necessary to derive that clock in a safe way, such as by using a much higher speed master clock to determine the edges.
I am guessing that someone would do that to, e.g., get more time for a slow memory without having to slow the system clock rate. Fair enough, but not really relevant to the discussion here as far as I can tell, since I'm concerned with systems that don't play such tricks but just do "the usual" and use Φ0/Φ2 for determining when signals from the CPU are safe to use.
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In the more modern faster parts, it all gets more compressed, and the documentation is lacking. I think I've seen it said that the modern datasheet doesn't really give room for 14MHz operation of a system - but we're saved by the practical observation that we don't seem to see worst-case behaviour.
Well, I'm not sure what you mean by "compressed," but if it doesn't involve changing the timing
relationships it shouldn't make a difference, should it?
A W65C02 not being able to run at 14 MHz sounds
very odd to me given that they have a 14 Mhz column on the data sheet, and their "F Max vs Vdd" chart goes up to 20 Mhz, with a little cross marked at about 19.5 MHz and 4.2 V.
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timing-65C02S-WDC-2018.png [ 50.13 KiB | Viewed 525 times ]
Looking at the 14 MHz specs (in ns), clock pulse width high and low tPWH = tPWL = 35 min:
Data setup tMDS = 25 max, meaning that it's available at least 10 ns before Φ2↓, and tDHW = 10 min appears to give that another 10 ns after Φ2↓, so that looks no different from the 6810 case in my previous post and data is fine at 14 MHz. (I see now that all these "hold" times are actually holds from the clock edge, which makes things make a lot more sense and really does lock them to that clock edge.)
For the address, address setup time tADS = 30 max, giving at least 5 ns between the address being settled and Φ2↑. The address hold time tAH = 10 min so again, at least 10 ns after Φ2↑.
I guess I need to thank you for forcing me into the data sheets to this depth; it's really been very educational. :-)
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But to the original discussion, I'm all for a thorough analysis of phi0 vs phi2 and the pitfalls to be avoided.
Ok, so using my newfound skills on the original MOS data sheet...I'm still stuck. I just can't see anything that gives any sort of relationship between Φ0 and Φ2, and all the timings are referenced to Φ2 OUT for the 650x series. (The 651x all reference to Φ2 IN because there is no Φ2 out.)
But I decided to have a look at a 1979 Synertek SY6500 datasheet I happen to have kicking around on paper, and it turns out that it
does give this. (Yay!) Fortunately it's already been scanned and is
up on 6502.org. The timing diagram is a full page, so rather than paste it here perhaps it's easier just for you guys to go look at page 4 of that scan.
It gives "Φ₀ Neg to Φ₂ Neg Delay" TO2- = 65 ns max (at 1 MHz), and "Φ₀ Pos to Φ₂ Pos Delay" TO2+ = 75 ns. So finally we seem to have some numbers that might tell us how tolerances change between the two. But I wonder if these take into account the much slower rise time of Φ2 compared to a good Φ0 signal.
Anyway, let's just go with Φ0 edges up to 65/75 ns earlier than Φ2 edges. The minimum length of Φ2low (ref "A" to ref "B") isn't directly given, but it looks like we can get it by adding TD = 5 min + TPWHΦ1 + TO1- = 5 min + TD = 5 min. We get TPWHΦ1 from TLΦ0O - 20 = 480 - 20 = 460, so a Φ2 high pulse is minimum 475 ns. Phew! Is that even right? Maybe I'll stop here while someone checks that and I gird myself for the next steps. And go off and read Jeff's stuff again, since it's been a while.
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...hold time constraints are very important and often overlooked.
Right. I think we have those covered in the hold times from the clock edge I discovered above, right?
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