I've seen cool C64 demos showing sprites in the border area of the screen. It shouldn't be possible; I think they managed to fool the graphics chip somehow. How exactly did they do it?

  • to get more than the allowed sprites, you have to move the sprite fast enough in relation to the TV refresh rate: the sprite is drawn on the screen in location A, you move it to location B and it gets redrawn again, etc and then when the tv screen is done being drawn, back to location A or where ever A has moved to now.
    – KM.
    Sep 25 '09 at 14:19
  • 4
    I just added c64 to my list of Interesting Tags. +1 from me! Sep 25 '09 at 14:23
  • on it's bigger brother(sister?) the Amiga they added a whole coprocessor (the copper) to define what video hardware changes had to be done at what screenrasterlines. Removing the need to complex assembly interrupt programs
    – Toad
    Sep 25 '09 at 14:24
  • 2
    how can this question be "not constructive"? How do I show stuff in the border and the answer contains the code to do that. How can it be more constructive than that? Jan 15 '13 at 16:26
  • @TylerCrompton Unlike "how do I print text near the edge of the screen", sprites "aren't supposed to" be on the border.
    – wizzwizz4
    Apr 13 '17 at 22:45

Yes, you need assembler. It's an interrupt timing trick. The VIC is able to show sprites in the border, but the frame is just hiding them, so the sprites can slide behind it. It's connected to scan lines displayed by the VIC. For lower/upper borders it's quite simple:

  • Programm an interrupt, synced to start at a certain scan line, 7 pixel or something like that before the lower border.
  • Set the register in VIC to make the border smaller. (There is a register that can do that.)
  • VIC now believes that the border already started and does not start to paint it.
  • -> No border at the bottom.
  • Programm another interrupt after the real border to set it back to original.

For sprites in the left/right borders, it's more complicated because the process has to be repeated for every scan line:

  • Programm an interrupt, synced to start at a certain scan line.
  • Then do some NOPs until you are 7 pixels before the right border.
  • Set the register in VIC to make the border smaller.
  • -> No border at the right side.
  • Do some NOPs until you are after the real border and set the register back to original value.
  • Again do some NOPs until step 2.

The problem is that all these NOPs are busy waits and steal the cycles you have for your stuff.

I was able to find some code for you, from an sprite scroller in the lower border. Here is the code. (It was ripped from some demo.)

C198  78        SEI
C199  20 2E C1  JSR C12E     # clear sprite area
C19C  20 48 C1  JSR C148     # init VIC
C19F  A9 BF     LDA #BF      # set up IRQ in C1BF
C1A1  A2 C1     LDX #C1
C1A3  8D 14 03  STA 0314
C1A6  8E 15 03  STX 0315
C1A9  A9 1B     LDA #1B
C1AB  8D 11 D0  STA D011
C1AE  A9 F7     LDA #F7
C1B0  8D 12 D0  STA D012
C1B3  A9 01     LDA #01
C1B5  8D 1A D0  STA D01A
C1B8  A9 7F     LDA #7F
C1BD  58        CLI
C1BE  60        RTS

# init VIC
C148  A2 00     LDX #00
C14A  BD 88 C1  LDA C188,X
C14D  9D 00 D0  STA D000,X   # set first 16 values from table
C150  E8        INX
C151  E0 10     CPX #10
C153  D0 F5     BNE C14A
C155  A9 FF     LDA #FF
C157  8D 15 D0  STA D015
C15A  A9 00     LDA #00
C15C  8D 1C D0  STA D01C
C15F  A9 FF     LDA #FF
C161  8D 17 D0  STA D017
C164  8D 1D D0  STA D01D
C167  A9 C0     LDA #C0
C169  8D 10 D0  STA D010
C16C  A9 F8     LDA #F8
C16E  A2 00     LDX #00
C170  9D F8 07  STA 07F8,X
C173  18        CLC
C174  69 01     ADC #01
C176  E8        INX
C177  E0 08     CPX #08
C179  D0 F5     BNE C170
C17B  A9 0E     LDA #0E
C17D  A2 00     LDX #00
C17F  9D 27 D0  STA D027,X
C182  E8        INX
C183  E0 08     CPX #08
C185  D0 F8     BNE C17F
C187  60        RTS

# data set into VIC registers
C188  00 F7 30 F7 60 F7 90 F7
C190  C0 F7 F0 F7 20 F7 50 F7

# main IRQ routine
C1BF  A2 08     LDX #08
C1C1  CA        DEX
C1C2  D0 FD     BNE C1C1
C1C4  A2 28     LDX #28      # 40 or so lines
C1C6  EA        NOP          # "timing"
C1C7  EA        NOP
C1C8  EA        NOP
C1C9  EA        NOP
C1CA  CE 16 D0  DEC D016     # fiddle register
C1CD  EE 16 D0  INC D016
C1D0  AC 12 D0  LDY D012
C1D3  88        DEY
C1D4  EA        NOP
C1D5  98        TYA
C1D6  29 07     AND #07
C1D8  09 18     ORA #18
C1DA  8D 11 D0  STA D011
C1DD  24 EA     BIT   EA
C1DF  EA        NOP
C1E0  EA        NOP
C1E1  CA        DEX
C1E2  10 E4     BPL C1C8     # repeat next line
C1E4  A9 1B     LDA #1B
C1E6  8D 11 D0  STA D011
C1E9  A9 01     LDA #01
C1EB  8D 19 D0  STA D019
C1EE  20 00 C0  JSR C000   # call main code
C1F1  4C 31 EA  JMP EA31   # finish IRQ
  • I think the "init VIC" code at 0xC148 mainly sets up sprites in the border for the sprite scroller (It's connected to disabling the border.) But the sprites have to be there otherwise the timing of VIC/raster lines is different and the whole thing does not work. And you want to be sprites there anyway :-) Sep 28 '09 at 9:25

It all relied on timing. The C64 had a method to query the exact vertical location of the electron beam while it was drawing the screen. When a new line started, you had to wait a few cycles (you could time this using the NOP instruction) and then you had to set a hardware register of the videochip which was responsible for setting the screenmode (and the border width). By timing it exactly right, and doing it every scanline again, the whole sideborder disappeared.

The bottom border went away with a similar trick. On the exact scanline where the vertical border started you too had to set the videomode which disabled the bottom border for that frame.

Indeed this whole thing had to be done in assembly. Otherwise you could never get the timing exactly right.

As a side note, I think the sideborder trick was credited to the 1001 Crew (a Dutch group). I'm not sure who pulled off the first bottom border trick.

  • yes but that was not the register you had to set to change the screenmode
    – Toad
    Feb 4 '13 at 15:26
  • I know, but you wrote it rather "unspecifically". So I just wanted to add some details. I believe $d011 was the one selecting if you were using 25 or 24 lines, which made the border contract or not. en.wikipedia.org/wiki/MOS_Technology_VIC-II Feb 6 '13 at 15:15

For a good tutorial on the topic of opening the borders on the C64, check out Pasi Ojala's excellent article in C=Hacking Issue 6.

Without getting too technical, the trick uses a feature of the VIC chip to let you switch between 25/24 rows and 40/38 columns of text/graphics, and involves making this switch at the exact right moment to fool the VIC into thinking it has already switched the borders on when in fact it hasn't. Check out the above article for a more thorough explanation with code examples.


That is a long time ago.

I know there was a solution that relied on the frequency of the monitor.

With a CRT, the current pixel is known even if it was outside of the normal screen. So you could manipulate the ray.

Somewhere in my junkpile there must be some C64 books.

Offtopic, but graphics with the VIC20 (the predecessor of the C64) was fun. There was no way to manipulate each pixel, but you could change the existing characters. So you filled the screen with all characters from 0 to ... and changed the characters to set pixels to the screen. ;-).

  • 1
    Also on C64 wasn't very simply to change a pixel. The graphical mode essentially emulated a character mode screen filled with 0, 1, ... characters. :-)
    – peterh
    May 23 '17 at 18:20
  • You can manipulate every single pixel using the hi-res bitmap mode. Or pairs of them in the multicolor bitmap mode, but that always uses 8000 Bytes (not 8k) and you don't always have those. Btw, you don't change the existing characters, they're in a ROM so you can't do that, but you can copy them to RAM and then manipulate them.
    – user14699696
    Nov 26 '20 at 13:16

As it was already said, you have to fool the VIC to think that the border already started, but the reason why I write this is because the top answer is a little bit inprecise: I was totally unable to find a register to make the border smaller, so this is the way you do it (at least for top and bottom): You wait until the VIC reached the 25th character row and then you enable 24 rows ($D011, bit 3). You can do the same thing for the left and the right border, just with 38 cols ($D016, bit 3), but to do that you need very precise timing and you also need to eliminate the bad lines by setting the vertical scroll register, so the scanline mod 8 is never equal to the scroll value. Of course, you can't use the normal display anymore because the bad lines actually aren't just bad, they are used to load character data I think, stuff that repeats for every 8th line in the non-border area. I personally was a little bit confused when I read the top answer, I hope that can help. (Also, the top answer has a mistake: You don't make the border smaller, you make it bigger)


Timing was the key. The image was created in the border by changing the overscan (border) colour as the CRT's beam moved from left to right. There are two timing signals required to produce an image - vertical refresh and horizontal refresh. By detecting when the horizontal and vertical refresh occurs you can start a sequence of assembler instructions to change the border colour to produce an image. You need to work out the number of CPU clock ticks per border pixel and use that to create code that changes the border colour at the right point.

It doesn't work very well when it comes to writing games as the CPU overhead is too great for there to be any time lift to process user input and game state.

  • this is not how it was done... The processor was too slow to change the color fast enough so that any pixel alone could be lighted. At best. The way to remove the border was to time the exact moment when the border began/stopped and change the displaymode. (see my answer)
    – Toad
    Sep 26 '09 at 9:46
  • I've just done some calculations: 25 frames at 250 lines a frame is 6250 lines a second or 0.00016 seconds a line. At 1Mhz this is 160 instructions so the most you can get using this method is 160 pixels accross the screen. I have seen images in the border done this way and they were a quite blocky.
    – Skizz
    Sep 28 '09 at 9:20
  • Once you get the timing right and get the vertical border open/disabled, the sprites (if any) placed out there becomes visible. thats how you get graphics out there. Feb 3 '13 at 23:09
  • Not sure your calculations are right there Skizz. For example the instruction to increment a memory location not in zero page is 6 cycles. Or the instruction to store the accumulator to memory is 4 cycles. And one machine cycle is 8 hires pixels (or 4 multicolor pixels) of rastertime.
    – OmarL
    Aug 30 '17 at 14:51

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