8

Trying to generate a series of random numbers on my Commodore 64 (C64) using JSR $E09A and retrieving the number from $63 and $64. (which according to all the documentation I've seen is the same routine when you use RND(0) from BASIC. But can't get it to iterate. The following will work and place a different number in $63 and $64 when executed by itself.

. C000  A5 00    LDA $00
. C002  20 9A E0 JSR $E09A
. C005  00       BRK

Now when I try to iterate say 10 times with the following code, it never returns.

. C000  A0 0A    LDY #$0A
. C002  A9 00    LDA #$00
. C004  20 9A E0 JSR $E09A
. C007  88       DEY
. C008  D0 F8    BNE $C002
. C00A  00       BRK

Am I missing something so obvious I can't see it. I'm not worried about how "random" it is. At this point I just want a series of random numbers.

6
  • I don't have an answer, but I wonder if the new Retro Computing forum here on Stack Exchange might have some folks on it who could help you also.
    – TomServo
    Jul 6, 2017 at 0:01
  • 8
    The function you're calling may be changing the value in the Y register.
    – Ross Ridge
    Jul 6, 2017 at 0:05
  • 1
    That was it, I knew I was missing something obvious
    – Kenny
    Jul 6, 2017 at 0:21
  • 6
    JLH is referring to Retrocomputing, but programming questions are completely on-topic here on Stack Overflow, no matter how old your target machine may be. :-) Jul 6, 2017 at 11:27
  • Thanks @CodyGray I will check out the Retrocomputing section. I recently came across some of my old Commodore floppies and was able to transfer them to USB. I found the VICE commodore emulators and am now happily reliving the mid '80s, by tweaking some of my all BASIC stuff with some assembly routines,
    – Kenny
    Jul 6, 2017 at 12:13

8 Answers 8

11

The SID chip can actually generate numbers that are more random than BASIC's pseudo-random numbers. Start the generator with:

LDA #$FF  ; maximum frequency value
STA $D40E ; voice 3 frequency low byte
STA $D40F ; voice 3 frequency high byte
LDA #$80  ; noise waveform, gate bit off
STA $D412 ; voice 3 control register
RTS

Then you can get random numbers whenever you want with:

LDA $D41B ; get random value from 0-255
7
  • Can you still use this technique if your program is actively using the SID (all three voices simultaneously) to play music?
    – Psychonaut
    Jan 9, 2019 at 8:53
  • 5
    No...and maybe. You can pull random numbers generated in advance from a cache and, when voice 3 is not being used, turn off the output and re-fill the cache before resetting voice 3 ready for the next output. It just involves a change to the music playing routine to use it during the gaps.
    – Mike
    Jan 10, 2019 at 18:38
  • However, the sequence always starts the same: 254, 131, 229, 233, 173, ...
    – Lovro
    Feb 13, 2020 at 7:01
  • 1
    What are you running it on? I can't speak for emulators but the hardware approach was used to generate random numbers for premium bonds. The SID chip actually does generate noise, I think.
    – Mike
    Feb 14, 2020 at 11:46
  • in frequency is better 1 or 2 .. because the noise waveform repeats... and there is no reason to make it change more thance once per cpu cycle.
    – Zibri
    Jun 21, 2020 at 9:34
9

Thanks to Ross Ridge for suggesting that the called function was changing the value in the Y register. I knew it had to be something obvious!

By storing Y before the JSR, and restoring after, it now will iterate properly. Here is the quick fix:

Edit: Updated 7/10/17 - to show full code and incorporate JeremyP suggestion. This is essentially a coin flip iterator (50000 repetitions) for purposes of experimenting with random

.C 033c  A9 00       LDA #$00
.C 033e  85 FB       STA $FB    ; set up register for counter
.C 0340  85 FC       STA $FC
.C 0342  A2 C8       LDX #$C8   ; outer loop= 200
.C 0344  86 FD       STX $FD
.C 0346  A0 FA       LDY #$FA   ; inner loop=250
.C 0348  84 FE       STY $FE
.C 034a  20 94 E0    JSR $E094  ; Get random# Vic20 Address (E09B for C64)
.C 034d  A5 63       LDA $64
.C 034f  C9 80       CMP #$80   ; >128 = HEADS
.C 0351  90 0D       BCC $0360  ; else continue loop
.C 0353  18          CLC        ; increment 2 byte number
.C 0354  A5 FB       LDA $FB
.C 0356  69 01       ADC #$01   ; LSB
.C 0358  85 FB       STA $FB
.C 035a  A5 FC       LDA $FC
.C 035c  69 00       ADC #$00   ; MSB
.C 035e  85 FC       STA $FC
.C 0360  C6 FE       DEC $FE
.C 0362  D0 E6       BNE $034A  ; end inner loop
.C 0364  C6 FD       DEC $FD
.C 0366  D0 DE       BNE $0346  ; end outer loop
.C 0368  60          RTS        ; return to basic

I can get the random number by LDA $63 or LDA $64 inside the loop and use it for my purposes.

This turned out to be a lot slower than expected, taking only half the time it would've taken in BASIC. The RND function takes a lot of cycles, however, I found this Compute! article which uses the SID chip as a random number generator.

LDA #$FF  ; maximum frequency value
STA $D40E ; voice 3 frequency low byte
STA $D40F ; voice 3 frequency high byte
LDA #$80  ; noise waveform, gate bit off
STA $D412 ; voice 3 control register  

Once turned on it generates numbers independently and doesn't have to be executed again. A loop that repeatadly calls LDA $D41B will get you a new random number on each iteration. In my test 50,000 iterations took 1.25 seconds and million took a little over 24 seconds. Pretty impressive for a 1MHz computer!

0
1

You are essentially calling RND(0) which uses the timer to generate a seed. However, that is not directly usuable in assembly. First try switching to a positive number (any number) and see if it starts producing values.

9
  • 2
    And, as Ross said, the function is changing Y register. See also the Fully Commented Commodore 64 ROM Disassembly
    – Jester
    Jul 6, 2017 at 0:16
  • Oh right. So my answer is completely wrong. I'm not sure about SO etiquette, should I delete it?
    – Chet
    Jul 6, 2017 at 0:18
  • It's not completely wrong, he is calling rnd(0) and that is using the timer. Just not sure why you said it wasn't usable.
    – Jester
    Jul 6, 2017 at 0:22
  • I misread something so I thought you had to copy the timer into a specific memory location before you called RND(0). But it is clear from your link that the RND function is performing this copy for you.
    – Chet
    Jul 6, 2017 at 0:29
  • 2
    @Kenny: you want to "seed" the RNG only once, so RND(0) is only for first call, afterwards you should maintain the current seed. Reinitializing the seed all the time is detrimental to the results, actually if you call it fast enough and the timer regs have still the same value, you may receive same random values back. (this is general RNG answer explaining the principle, I didn't study the C64 case, so I have no idea how you should properly treat the seed value after initialization, whether the last random number is also seed for next one, or what).
    – Ped7g
    Jul 6, 2017 at 1:49
0

If you don't have a programm with timed raster-IRQ or something similar, you can just get a "random" number with lda $d012.

3
  • even without timed IRQs, as the CPU cycles are hard-wired to the VIC, you risk to get an ever repeating sequence this way... The SID method shown in the self-answer is better ;)
    – user2371524
    Jul 13, 2017 at 14:26
  • That's right, if your program is running without any user interaction. the Sid method steals one Voice for music.
    – A.vH
    Jul 14, 2017 at 7:33
  • Yes, it's unlikely to happen in an interactive program, you're correct :) Just saying the "SID method" doesn't expose that risk at all. For a game, the quality of the randomness won't matter too much anyways of course.
    – user2371524
    Jul 14, 2017 at 7:34
0

I found this thread searching for more general RND(start, end) routine in C64 assembly. Something implemented as this BASIC example:

INT(RND(1) * (end- start + 1)) + start

While there are many helpful answers here, I was missing this kind of solution, so I had to find my own; and it might be helpful to another person coming to this thread, so here it goes:

            lda #<end   
            sta $FD
            lda #>end
            sta $FE
            lda #<start
            sta $FB
            lda #>start
            sta $FC
rnd:
            //reseed, to avoid repeated sequence; RND(0)
            lda #00
            jsr $E09A
            //++end 
            inc $FD
            bne skip1
            inc $FE
skip1:
            //- start
            lda $FD
            sec
            sbc $FB
            sta $FD
            lda $FE
            sbc $FC
            sta $FE         

            //++end-start to FAC
            ldy $FD
            lda $FE
            jsr $B391 //A(h),Y(L) - FAC 
            ldx #<flt
            ldy #>flt
            jsr $BBD4   //store FAC to flt
            //get actual RND(1)
            lda #$7f
            jsr $E09A
            //multiply by ++end - start
            lda #<flt
            ldy #>flt
            jsr $BA28
            //to integer
            jsr $BCCC
            //FAC to int;
            jsr $B1BF
            lda $65         
            clc
            adc $FB
            sta $14
            lda $64
            adc $FC
            sta $15
            rts     
flt:        .byte 0,0,0,0,0

The routine works with 16 bit numbers in range 0 - 32767. Arguments start in 251,252; end in 253, 254. 16 bit result found in $14.

0

The real problems on a C64 are:

  1. SID generated numbers are also pseudorandom and they repeat in a sequence (I can't find the link discussing that)

  2. Raster position is not random.

The only source of true randomness in a c64 is user input.

So what I do is:

  1. initialize SID noise waveform
  2. get cia timer 1 LSB at startup (which is fine on a normal c64, but is not random on an emulator)
  3. start cia timer 2
  4. wait for the user to press any key (or a joystick direction/button)
  5. get cia timer 2 LSB
  6. get SID amplitude value
  7. optionally get raster position but depending if you are calling this routine from basic or assembler you might not get a totally random value.

Then you have your random seed for your favourite pseudorandom routine. Or just a one shot 16/24/32 bit random number.

In a game, for example you can get the cia timers when the user moves the joystick and get a random byte.

Note: dropping a prg or d64 in an emulator is very different than writing "load..." because every user writes differently every time and timers LSB are "random" in that case.

In some emulator a random delay is added to the computer start for this reason.

3
  • 1
    I'm not sure being only pseudo-random is a problem here. It's unlikely the numbers are being generated for cryptographic purposes.
    – Ross Ridge
    Sep 2, 2020 at 5:29
  • just FYI, a fibonacci based PRNG passes all checks for randomness... check this out: github.com/Zibri/rand2
    – Zibri
    Mar 9, 2021 at 14:47
  • @RossRidge here you go: stackoverflow.com/a/76500260/236062
    – Zibri
    Jun 24, 2023 at 15:18
0
LDA #$FF
STA $D40E ; set maximum frequency
STA $D40F ; set maximum frequency
LDA #$81
STA $D412 ; set NOISE waveform

JSR RND  ; A will contain a random byte
RTS

RND:
   LDA $DC04 ; read Timer A of CIA#1
   STA YY+1
XX:
   EOR #$FF
   STA ($fd),y
   EOR $D41B ; read Waveform Amplitude
YY:
   EOR #$00
   STA XX+1
   RTS
4
  • 1
    What algorithm does this use? It looks like it's only XORing with some values from memory, and updating the immediate in the YY: EOR. So I don't see any mixing of bits horizontally within a seed value. Is it reading memory locations that get modified by interrupts, or I/O ports? Jun 18, 2023 at 17:46
  • No. It's mixing the contents of the white noise random generator of the SID with the Timer A of CIA1.
    – Zibri
    Jun 23, 2023 at 8:48
  • It would be a good idea for your answer to say that, in comments on the code and/or in text. I see you have an earlier answer on this question; you could have edited a new section into it, or if this is separate enough, could just have its own text explanation. Jun 23, 2023 at 13:01
  • @PeterCordes ok.. I commented the code.
    – Zibri
    Jun 24, 2023 at 15:17
-1

This is very late now, but depending on the requirements, you can also roll your own PRNG. Some algorithms are simple enough to implement, as an example, I'll show a 32bit xorshift implementation here using the parameters [3,25,24] (because this makes two of the shifts use very little code). The returned random number has 16 bits:

rnd_seed:
                sta     $22             ; store pointer to PRNG state
                stx     $23
                lda     #$00            ; initialize with 0
                ldy     #$03
rs_clrloop:     sta     ($22),y
                dey
                bne     rs_clrloop
                lda     $d012           ; except for LSB, use current raster
                bne     seed_ok
                lda     #$7f            ; or a fixed value if 0
seed_ok:        sta     ($22),y
                rts

rnd:
                sta     $22             ; store pointer to PRNG state
                stx     $23
                ldy     #$03
r_cpyloop:      lda     ($22),y         ; copy to ZP $fb - $fe
                sta     $fb,y
                dey
                bpl     r_cpyloop
                ldy     #$03            ; and shift left 3 bits
r_shiftloop:    asl     $fb
                rol     $fc
                rol     $fd
                rol     $fe
                dey
                bpl     r_shiftloop
                ldy     #$03
r_xorloop:      lda     ($22),y         ; xor with original state
                eor     $fb,y
                sta     ($22),y
                dey
                bpl     r_xorloop
                ldy     #$03
                lda     ($22),y
                lsr     a               ; MSB >> 1 gives ">> 25"
                ldy     #$00
                eor     ($22),y         ; xor with original state
                sta     ($22),y
                ldy     #$03            ; this is also value for "<< 24"
                eor     ($22),y         ; so xor with MSB
                sta     ($22),y
                tax                     ; use the two "higher" bytes as result ...
                dey
                lda     ($22),y         ; ... in A/X
                rts

Usage example:

main:
                lda     init
                bne     noinit
                lda     #<prng
                ldx     #>prng
                inc     init
                jsr     rnd_seed
noinit:         lda     #<prng
                ldx     #>prng
                jsr     rnd
                jmp     $bdcd        ; C64 BASIC routine output 16bit int in A/X

init:           .byte   $00
prng:           .res    4            ; 32bit PRNG state
14
  • I tried this code but it doesn't seem to generate a very uniform distribution in lower bits (e.g., some bit patterns don't get generated at all, some get generated often). See: gist.github.com/nurpax/d0fee60a74633ae3027d41a7d1d02c19
    – Nurpax
    Apr 27, 2018 at 12:48
  • @Nurpax Me too, I found only one byte has a good distribution with it a while ago ... I completely forgot I posted it here. Not sure what's the reason, the implementation is correct according to the paper linked, but maybe I misunderstood this listing of possible parameters -- it might not be an ideal choice. Using other parameters would greatly increase runtime (doing a lo0t more shifting), so in the end, I replaced it with an extremely simple 32bit LFSR implementation using a fixed XOR 0x04c11db7 on shifting out a bit to the left. Gives much better values.
    – user2371524
    Apr 27, 2018 at 12:54
  • @Nurpax and it's naturally faster as well ... I could rewrite this answer if you're interested.
    – user2371524
    Apr 27, 2018 at 12:56
  • I’d be interested in your simpler solution. I’m looking for for an easy to implement PRNG. Trying to not roll my own as it will easily lead to hard to notice bugs. Thanks in advance for your code. :)
    – Nurpax
    Apr 27, 2018 at 18:12
  • @Nurpax well I would never roll my own idea, but even rolling my own implementation went not-so well in this case, so, yes :D I'll update this answer with the code I'm currently using, it's only a slight variation of code you also find on codebase64. A simple LFSR, so probably some properties for "good randomness" aren't ideal (don't use this for encryption), but distribution seems quite nice, I use it in a demo for "random" water movement and stars. I'll leave a comment once I edited this answer!
    – user2371524
    Apr 27, 2018 at 18:39

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