Hi everyone. Yes a 65C02 computer with hardware that accelerates Forth, including a new addressing mode and a very fast, one-byte NEXT instruction:
https://laughtonelectronics.com/Arcana/ ... mmary.html

Not for sale, unfortunately - it's a homebuilt. But very obviously Forth related; hence the post under this topic.
I'm new to this forum and am pleased to become part of your group!

-- Jeff

Edit: add a photo of the board. Change link to point to the one-page Short Summary
Edit2: add another photo and the register diagram. BTW, to find specific info (also the photo gallery! ) please refer to the Contents and Appendices links here.

_________________
http://WilsonMinesCo.com/ lots of 6502 resources
The "second front page" is http://wilsonminesco.com/links.html .
What's an additional VIA among friends, anyhow?

Thanks for your reply, Garth. I'll try respond to your comments briefly, and hopefully not reveal my ignorance regarding some of the topics if I can help it!

The speed of KK Forth compared with plain FIG Forth would depend on the code mix, of course. @ and ! are somewhat faster. And a higher proportion of short routines would mean NEXT executes comparatively often, so KK's 300+ percent speedup of NEXT would really shine when short definitions prevail. Otherwise the speedup probably isn't all that dramatic [Oops; wrong! See footnote]. It's still a modestly powered, 8-bit micro. It took some inspiration and some perspiration to figure this stuff out and make it work!

I'm sorry not to have much to say about 65816, although I very much admire what seems to be a well-executed upgrade to the family. The truth is I built KK over 20 years ago, and since that time I haven't much kept up with things 65xx. (Do they really have 6502s that'll do 24 MHz now? Caramba!!) KK is so old I could've posted my article in the 6502.org Nostalgia section! The reason I'm writing about it now is to flesh out my new Web site - which I'll take a moment to shamelessly plug, and encourage everyone to visit: https://LaughtonElectronics.com There's also other interesting stuff there, I promise!

(LOL!) Well, maybe it's not so funny. I have quite a few more ideas for "smart" registers -- basically Z-Pg memory that knows when to modify itself. That could take the form of an LSI peripheral or even just some IP for a Design Library. When you think about it, 65xx's off-chip "registers" (Z-Pg) offer unique opportunities to create a stronger programming model without disturbing the CPU core.

In closing I'll explain that the KimKlone never had to rely on any [hmphh! sniff!] store-bought computer or software to assemble its code! I modified Bill Ragsdale's Forth 6502 assembler so it'd generate 'C02 and KK ops, and used that. Similar story for KK's microcode: this was assembled by some clunky Forth code I wrote, executing on KK's predecessor, my heavily modified KIM-1!

-- Jeff

Edit: I retract my remark. Throughput almost doubles, which is pretty dramatic. Details in my next post.
Edit: update web-site link. Add a link to my 2013 post about KK's predecessor, my heavily modified KIM-1.

_________________
http://WilsonMinesCo.com/ lots of 6502 resources
The "second front page" is http://wilsonminesco.com/links.html .
What's an additional VIA among friends, anyhow?

I'm very impressed by this design. You obviously spent a lot of time studying instruction execution on a per cycle basis. To think you did this so long ago, and no one else has done so, or at least published the fact.

I like this even better than the hidden DMA cycles discussed last year, or was it two years ago now...

Well Done!!!

Daryl

Odd but I think I like the 65C02 with your extended addressing better then a 65C816.

Rick

Another nice thing about extending a 6502 externally is that it lends itself to an FPGA implementation: take one of the 6502 cores out there, and add whatever you need. Doesn't disturb the core much, so not so much verification to do.

I'm tempted to think that borrowing the '816 approach of putting the bank byte out on the data bus is also a win: the FPGA can be on a 5v-friendly 40-pin DIP module, at the cost of an external latch. Then the board design stays in familiar 0.1" pitch, through-hole, 5v territory.

(Edit: Or, use a 48-pin DIP module...)

Still digesting some of the excellent replies here.. and I haven't gotten through the links Garth provided yet. (Thanks for that, btw.)

Re: your question about KK's performance (compared to a stock 'C02) when running FigForth, it seems I did KK an injustice in describing the speedup as undramatic. Now that I do the math I see that throughput rises 89%, based on a code mix with equal occurences of the following: DOCOL SEMIS DOCON DOVAR SWAP OVER @ ! + 0= BRANCH 0BRANCH (LOOP). Sadly, what this really tells us is how woefully NEXT-bound 6502 FigForth is! The routines I just mentioned average out to about 34 clocks; NEXT is 43 !. For a stock 'C02 the time spent in NEXT exceeds the time spent actually computing. So for KK, trimming NEXT to 9 cycles was hugely more important than the (still significant) speedup in @ and !.
Switching to a WDC chip might allow some speedup. As for WAIt and SToP, these use opcodes I've already defined, so there's a conflict. As is, KK would continue to substitute $CB and $DB opcodes and function as before, but it'd be impossible to access the WAIt and SToP functions. I don't care about that, but if I did then I could make space by reducing and rearranging the KK opcodes in column B and column 3. Then KK could "substitute" WAIt and SToP op-codes with themselves - ie, allow $CB and $DB to reach the CPU unchanged. All it would take is a substitution-PROM update and some NOPs in the microcode to get rid of what I put there. But I think I'd prefer to stick with KK's present instruction set, and do without WAIt and SToP.
Not sure where you're going with this, BigEd. You're proposing a product that's hobbyist-friendly? (Unless I'm mistaken, nobody else prefers through-hole) Would it be a KK product? (a KimKlone clone!?) Probably you mean something else. But hey - you wouldn't need to give it The Full Monty... the Smart Register idea could be done without microcode, for instance... There are a range of tradeffs to select from. It could be simpler than KK... or more exotic, a 65816 version, as Garth suggested!

Speaking of 65816, I really have to do some more boning up on that chip. Hopefully when you hear from me next I'll be a little better informed. But I think I agree with kc5tja's remark (from the "6502 with 3-byte addressing" Topic):
[Edit: WDC paragraph.]

Sorry, yes, I was following my own train of thought there, concerning an upgrade to an 80's micro. I'm not ready to solder surface mount devices, but I want the flexibility of CPLDs and FPGAs, and I've got a 5v system to build on. I've got a couple of these DIL modules, and they should be suitable to experiment with variations on the 6502 theme.

_________________
http://WilsonMinesCo.com/ lots of 6502 resources
The "second front page" is http://wilsonminesco.com/links.html .
What's an additional VIA among friends, anyhow?

Upgrading an 80s micro? Are there posts I can read re: this project?

I too cringe at the thought of building with the tiny SMD packages, but they're available and they have advantages, as Garth mentioned.

I've done well by soldering to these adapter boards by Aries Electronics (see photo) which can THEN plug into a wire-wrap socket. There are SOIC, PLCC, QFP... Still a dicey soldering job, but greatly aided by unimpeded access from all directions. [DigiKey lists them in Product Index -> Prototyping, Fabrication -> Adapters, breakout boards]

-- Jeff

_________________
http://WilsonMinesCo.com/ lots of 6502 resources
The "second front page" is http://wilsonminesco.com/links.html .
What's an additional VIA among friends, anyhow?

Not yet, but I'll see what I can do. Our 3rd effort is in bring-up right now. We're using BBC Model Bs - I've mentioned the TUBE in a few posts, although right now it's a CPU socket upgrade.

On the 65816, a 10 cycle DTC NEXT that plays well with other children (in contrast to the 6 cycle NEXT linked above) is possible:



In this case, X is IP. With TOS in the accumulator, Y or S could be the data stack pointer. In the latter case, the return stack pointer could be stored on the direct page, leaving Y free to be used/overwritten as needed; e.g. XOR would be:



The former case would likely use more space, since abs,Y is 3 bytes vs. 2 bytes for stack relative addressing. It also seems natural that the 65816 stack would then be the return stack. XOR would be:



X, if it were available, would be a more convenient data stack pointer, since INC, DEC, and the shifts are available with direct,X addressing, but not available indexed by Y or S. Keeping the TOS in the accumulator alleviates this considerably, as few words use those operations below the TOS.

Inlining NEXT seems worthwhile, at cost of only 2 bytes.

Since many words take only a few instructions, a 65816 Forth could spend a significant percentage of its time executing next. An extreme case is 2* which is simply an ASL. It takes 2 cycles for the asl, 10 cycles for next. Likewise for 1+ and 1-.

So, for a performance oriented Forth, STC with inlining may well be the way to go. At zero cycles, STC has the fastest possible NEXT. Inlining
means more space in many cases, though there are optimizations possible, especially with branches (which in most cases will be within the -128/+127 range). Assuming TOS in the accumulator, here are some (untested and sorta contrived) examples of sequences that can be optimized (off the top of my head):



Anyway, the point is that it's at least possible to have a 65816 Forth that really flies.

A few loose ends and some additional remarks on this topic...


Well, it's enjoyable to contemplate, Garth... Assuming the KimKlone's memory chips were also updated, things could be speeded up a LOT! Timing margins are maximal, as there's a pipeline register at the output of the Control Store; access to the Control Store overlaps with execution of the previous micro-word. One minor issue is that the bipolar PROM that aliases 011 op-codes arriving from memory isn't pipelined, so in pursuit of overall higher clock speeds it'd make sense to allow a Wait State (for PROM access) in the minority case of an op-code fetch which returns a 011 code.


Thanks, Rick. I have mixed feelings on this point, myself. Since my last post I've spent some time mulling over the '816 data sheet, and have become sufficiently familiar with the chip to comment.

It's safe to say that KK memory addressing is immensely better than run-of-the-mill MMU arrangements which force code and data spaces to coexist within 64K. The KK is also superior to the MOS 6509, even though both feature what an MMU lacks: the all-important ability to switch between full, undivided 64K banks on a bus-cycle by bus-cycle basis. Naturally the '816 also has this ability, but for various reasons the '816 seems a more capable device, overall, than the KimKlone.

65xx coding revolves around indirect pointers in Zero/Direct Page, and of course for 16 MByte addressing the pointers use an extra byte. The '816 features a couple of address modes (Long Indirect and Long Indirect Post-Indexed-Y) which employ three-byte pointers very efficiently (ie: directly from Zero-page), whereas KK suffers a handicap: somewhere upstream of a Long memory access there needs to be a separate instruction, albeit a speedy one, to fetch the most-significant byte of the pointer and place it in a register.

On the other hand, it's the '816 which is at a disadvantage if you happen to need a Long address mode other than those provided. Consider, for example, a Forth implementation which uses the X register to maintain the Parameter Stack. Presumably you want to be able to accept Long addresses on the stack, but when it comes time to code the Long @ and ! words it becomes uncomfortably apparent that the '816 lacks the Long Pre-Indexed-X Indirect mode you require. The workaround is a two-step operation that begins by updating the Data Bank Register -- more or less as KK does! The difference is that KK has a good selection of instructions for doing this, whereas the only way to update the 816's DBR is with a Pull instruction -- a very clumsy maneuver in this case.

(Because of this issue, if I were writing an '816 Forth I would lean heavily toward using SP, not X, as the P-Stack pointer. Another advantage of using SP would be the applicability of Stack Relative Indirect Indexed mode, a boon directly analogous to KimKlone's "X-Indirect-Y" mode. This is a mode that features pre-indexing, indirection and post-indexing.)

On another point, I admire the '816's ability to manage indexed address calculations that result in Bank crossings -- in other words, actual 24-bit addition, built right into the address mode. (KK must explicitly compute such addresses up front, either in Forth or m/c code.) However, I find the '816 data sheet somewhat ambiguous as to which address modes accommodate Bank crossings and which merely wrap around in the low-order 16 bits. (Is there a better reference document available online? What about a simulator? I don't have an '816 to run tests on!)

That sums up KK versus the '816. Briefly I'll mention a third point of comparison, one that I learned about right here on 6502.org. In the Hardware -> 6502 with 3-byte addressing topic, BigEd mentions a design which "... uses page 03 as extra indirection bytes, so that indirect and indirect,Y opcodes take an extra cycle to fetch a byte from &0301 + zp_offset to yield a 24-bit address..." I like this idea, and would probably take a similar tack if I ever had to design KK over again. As BigEd points out,