DMA examples: Difference between revisions
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== WRAM clear == | |||
== Updating Tilemap Rows == | |||
=== Updating a single tilemap row in a 64 tile-wide background === | |||
Tilemap columns 31 and 32 of a 64 tile-wide background is non-contiguous. Transferring an 64 tile tilemap row requires two separate DMA transfers to the following locations: | |||
* <tt class="nowrap">rowBuffer[ 0 - 63]</tt> to VRAM word address <tt>rowBufferVramWaddr + 0</tt> | |||
* <tt class="nowrap">rowBuffer[ 64 - 128]</tt> to VRAM word address <tt>rowBufferVramWaddr + 0x400</tt> | |||
The DMA A-Bus address will be incremented during the transfer (unless it is in ''fixed address'' mode). This means DMAADDR will be prefilled with the address of the second half of the row buffer after the first DMA transfer. | |||
<pre> | |||
; 8 bit A | |||
; 16 bit Index | |||
; DB access registers | |||
; DP = 0 | |||
; | |||
; rowBuffer u16[64] - buffer containing a 64 tile tilemap row (128 bytes in size) | |||
; rowBufferVramWaddr u16 - the VRAM word address to transfer rowBuffer to | |||
; VRAM word addressing | |||
lda #$80 | |||
sta VMAIN | |||
; | |||
; First DMA transfer. | |||
; Transfer `rowBuffer` bytes 0 - 63 to VRAM word address `rowBufferVramWaddr` | |||
; | |||
; Set VRAM word address | |||
ldx rowBufferVramWaddr | |||
stx VMADD | |||
; Word transfer to VMDATA | |||
ldx #DMA_01 | ((VMDATAL & 0xff) << 8) | |||
stx DMAMODE ; also sets B Bus Address | |||
; Set DMA source address | |||
ldx #rowBuffer & 0xffff | |||
stx DMAADDR | |||
lda #rowBuffer >> 16 | |||
sta DMAADDRBANK | |||
; Length of the DMA transfer (32 words, 64 bytes) | |||
ldx #64 | |||
stx DMALEN | |||
; Start DMA transfer | |||
lda #1 | |||
sta MDMAEN | |||
; | |||
; Second DMA transfer. | |||
; Transfer `rowBuffer` bytes 64 - 127 to VRAM word address `rowBufferVramWaddr + 0x400` | |||
; | |||
; Set VRAM word address to `rowBufferVramWaddr + 0x400` | |||
lda rowBufferVramWaddr | |||
sta VMADDL | |||
lda rowBufferVramWaddr + 1 | |||
clc | |||
adc #$04 | |||
sta VMADDH | |||
; No need to set DMAMODE or DMAPPUREG, it remains unchanged after a DMA transfer. | |||
; After the first transfer, DMAADDR will contain `rowBuffer + 64`. | |||
; There is no need to set DMAADDR or DMAADDRBANK. | |||
; We must write to DMALEN, it will be 0 after a successful DMA transfer. | |||
ldx #64 | |||
stx DMALEN | |||
; Start DMA transfer | |||
lda #1 | |||
sta MDMAEN | |||
</pre> | |||
=== Updating two tilemap rows in a 64 tile-wide background === | |||
Due to the discontiguous nature of the tilemap in a 64 tile-wide background, a transfer of a contiguous 64x2 word grid to VRAM requires 4 DMA transfers: | |||
* <tt class="nowrap">rowBuffer[ 0 - 63]</tt> to VRAM word address <tt>rowBufferVramWaddr + 0</tt> | |||
* <tt class="nowrap">rowBuffer[128 - 191]</tt> to VRAM word address <tt>rowBufferVramWaddr + 0x020</tt> | |||
* <tt class="nowrap">rowBuffer[ 64 - 127]</tt> to VRAM word address <tt>rowBufferVramWaddr + 0x400</tt> | |||
* <tt class="nowrap">rowBuffer[192 - 255]</tt> to VRAM word address <tt>rowBufferVramWaddr + 0x420</tt> | |||
This transfer can be simplified by using two DMA channels to transfer the first and third quarters of the rowBuffer, one after another, in a single DMA transfer. Afterwords, the second and fourth quarters can be transferred to VRAM. | |||
* <tt class="nowrap">rowBuffer[ 0 - 63]</tt> and <tt class="nowrap">rowBuffer[128 - 191]</tt> to VRAM word address <tt>rowBufferVramWaddr + 0</tt> | |||
* <tt class="nowrap">rowBuffer[ 64 - 127]</tt> and <tt class="nowrap">rowBuffer[192 - 255]</tt> to VRAM word address <tt>rowBufferVramWaddr + 0x400</tt> | |||
<pre> | |||
; 8 bit A | |||
; 16 bit Index | |||
; DB access registers | |||
; DP = 0 | |||
; | |||
; rowBuffer u16[128] - buffer containing a 64x2 tilemap grid (256 bytes in size) | |||
; rowBufferVramWaddr u16 - the VRAM word address to transfer rowBuffer to | |||
; VRAM word addressing | |||
lda #$80 | |||
sta VMAIN | |||
; | |||
; First DMA transfer (using DMA channels 0 & 1). | |||
; Transfer `rowBuffer` bytes 0 - 63 and bytes 128 - 191 to VRAM word address `rowBufferVramWaddr` | |||
; | |||
; Set VRAM word address | |||
ldx rowBufferVramWaddr | |||
stx VMADD | |||
; Word transfer to VMDATA | |||
ldx #DMA_01 | ((VMDATAL & 0xff) << 8) | |||
stx DMAMODE + $00 ; also sets B Bus Address | |||
stx DMAMODE + $10 | |||
; Set DMA source addresses | |||
ldx #rowBuffer & 0xffff | |||
stx DMAADDR + $00 | |||
ldx #(rowBuffer + 128) & 0xffff | |||
stx DMAADDR + $10 | |||
lda #rowBuffer >> 16 | |||
sta DMAADDRBANK + $00 | |||
sta DMAADDRBANK + $10 | |||
; Transfer size for each DMA channel (32 words, 64 bytes) | |||
ldx #64 | |||
stx DMALEN + $00 | |||
stx DMALEN + $10 | |||
; Start DMA transfer for channels 0 & 1 | |||
lda #$03 | |||
sta MDMAEN | |||
; | |||
; Second DMA transfer (using DMA channels 0 & 1). | |||
; Transfer `rowBuffer` bytes 64 - 127 and bytes 192 - 255 to VRAM word address `rowBufferVramWaddr + 0x400` | |||
; | |||
; Set VRAM word address to `rowBufferVramWaddr + 0x400` | |||
lda rowBufferVramWaddr | |||
sta VMADDL | |||
lda rowBufferVramWaddr + 1 | |||
clc | |||
adc #$04 | |||
sta VMADDH | |||
; No need to set DMAMODE or DMAPPUREG, it remains unchanged after a DMA transfer. | |||
; After the first transfer, DMAADDR channel 0 will contain `rowBuffer + 64` | |||
; and DMAADDR channel 1 will contain `rowBuffer + 192` | |||
; | |||
; There is no need to set DMAADDR or DMAADDRBANK. | |||
; We must write to DMALEN, it will be 0 after a successful DMA transfer. | |||
ldx #64 | |||
stx DMALEN + $00 | |||
stx DMALEN + $10 | |||
; Start DMA transfer for channels 0 & 1 | |||
lda #$03 | |||
sta MDMAEN | |||
</pre> | |||
== Fixed address DMA transfers == | |||
The ''fixed address'' DMA mode is useful for clearing and filling blocks of memory. | |||
=== WRAM clear === | |||
These are reusable subroutines for clearing out sections of RAM, which a program might want to do at the start of a level, or in [[Init code]]. Both routines take a start address in X, and a size in Y. | These are reusable subroutines for clearing out sections of RAM, which a program might want to do at the start of a level, or in [[Init code]]. Both routines take a start address in X, and a size in Y. | ||
The source address of a DMA transfer to WMDATA cannot be in Work-RAM, because the SNES cannot handle using DMA to copy from one section of Work-RAM to another. If you intend to fill Work-RAM with a non-zero value, use a source address in Cartridge-RAM or ROM. | |||
Note: This routine cannot be used to clear the entire bank $7E of Work-RAM, as it will override the stack and crash the program. | |||
Note: Due to [[Errata#DMA|a hardware bug]] on early SNES consoles it's not recommended to do this while [[HDMA]] is enabled. | Note: Due to [[Errata#DMA|a hardware bug]] on early SNES consoles it's not recommended to do this while [[HDMA]] is enabled. | ||
<pre> | <pre> | ||
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</pre> | </pre> | ||
=== Filling VRAM === | |||
== Filling VRAM == | |||
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== Filling VRAM with a word value == | === Filling VRAM with a word value === | ||
Filling VRAM with a word value is a bit more complicated. The ''fixed address'' DMA mode only allows for byte fills. Fortunately the VMAIN register provides a method of writing to the low and high bytes of VRAM separately, allowing for a VRAM word fill to be preformed in two DMA transfers. | Filling VRAM with a word value is a bit more complicated. The ''fixed address'' DMA mode only allows for byte fills. Fortunately the VMAIN register provides a method of writing to the low and high bytes of VRAM separately, allowing for a VRAM word fill to be preformed in two DMA transfers. | ||
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.endproc | .endproc | ||
</pre> | </pre> | ||
== See Also == | |||
* [[DMA registers]] | |||
* [[HDMA examples]] | |||
== Links == | |||
* [https://nesdoug.com/2020/05/16/dma-palette/ DMA Palette] - by nesdoug | |||
* [https://wiki.superfamicom.org/grog%27s-guide-to-dma-and-hdma-on-the-snes Grog's Guide to DMA and HDMA on the SNES] - superfamicom.org wiki | |||
* [https://en.wikibooks.org/wiki/Super_NES_Programming/DMA_tutorial DMA tutorial] - Super NES Programming Wikibooks |
Latest revision as of 21:07, 7 October 2022
This page provides examples on how to use DMA registers to do fast copies on the SNES.
These examples use the following defines to make the code clearer:
; Registers Also known as... DMAMODE = $4300 ; DMAPn DMAPPUREG = $4301 ; BBADn DMAADDR = $4302 ; A1TnL DMAADDRHI = $4303 ; A1TnH DMAADDRBANK = $4304 ; A1Bn DMALEN = $4305 ; DASnL DMALENHI = $4306 ; DASnH ; Configuration for $43n0 ; OR these together to get the desired effect DMA_LINEAR = $00 DMA_01 = $01 DMA_00 = $02 DMA_0011 = $03 DMA_0123 = $04 DMA_0101 = $05 DMA_FORWARD = $00 DMA_CONST = $08 DMA_BACKWARD = $10 DMA_INDIRECT = $40 DMA_READPPU = $80 ; These defines are meant for a 16-bit write to $43n0 and $43n1 ; and they set up the channel for several common cases. DMAMODE_PPULOFILL = (<VMDATAL << 8) | DMA_LINEAR | DMA_CONST DMAMODE_PPUHIFILL = (<VMDATAH << 8) | DMA_LINEAR | DMA_CONST DMAMODE_PPUFILL = (<VMDATAL << 8) | DMA_01 | DMA_CONST DMAMODE_RAMFILL = (<WMDATA << 8) | DMA_LINEAR | DMA_CONST DMAMODE_PPULODATA = (<VMDATAL << 8) | DMA_LINEAR | DMA_FORWARD DMAMODE_PPUHIDATA = (<VMDATAH << 8) | DMA_LINEAR | DMA_FORWARD DMAMODE_PPUDATA = (<VMDATAL << 8) | DMA_01 | DMA_FORWARD DMAMODE_CGDATA = (<CGDATA << 8) | DMA_00 | DMA_FORWARD DMAMODE_OAMDATA = (<OAMDATA << 8) | DMA_00 | DMA_FORWARD
Copying OAM
This is a simple DMA example that sends an OAM buffer to the PPU.
.proc CopyOAM php rep #$20 ; Set A to 16-bit lda #DMAMODE_OAMDATA sta DMAMODE lda #OAM ; Copy from OAM buffer in RAM sta DMAADDR lda #544 ; 512 bytes + 32 bytes = 544 sta DMALEN sep #$20 ; Set A to 8-bit lda #^OAM ; Set the bank byte of the source address sta DMAADDRBANK ; Start the DMA lda #1 sta MDMAEN plp rtl .endproc
DMA as part of a scrolling update
This example demonstrates using DMA to write to video RAM while scrolling a large map, and it might make sense to put something like it in a game's vblank handler. Notice the writes to PPU registers - the DMA unit only handles writing the actual data, so anything else (such as setting the destination address) has to be done normally. This also demonstrates using VMAIN to write downwards through a tilemap.
.a16 ; Does a column need to be updated? lda ColumnUpdateAddress beq :+ stz ColumnUpdateAddress sta VMADDL ; Write to VMDATAL and VMDATAH lda #DMAMODE_PPUDATA sta DMAMODE ; Copy from the buffer lda #.loword(ColumnUpdateBuffer) sta DMAADDR ; A tilemap column is 32 tiles long, and each tile is 2 bytes lda #32*2 sta DMALEN sep #$20 ; 8-bit accumulator lda #^ColumnUpdateBuffer sta <DMAADDRBANK lda #$81 ; Increment on VMDATAH write, increment by 32 sta VMAIN lda #1 ; Start the DMA sta MDMAEN lda #$80 ; Increment on VMDATAH write, increment by 1 sta VMAIN rep #$20 ; 16-bit accumulator :
Updating Tilemap Rows
Updating a single tilemap row in a 64 tile-wide background
Tilemap columns 31 and 32 of a 64 tile-wide background is non-contiguous. Transferring an 64 tile tilemap row requires two separate DMA transfers to the following locations:
- rowBuffer[ 0 - 63] to VRAM word address rowBufferVramWaddr + 0
- rowBuffer[ 64 - 128] to VRAM word address rowBufferVramWaddr + 0x400
The DMA A-Bus address will be incremented during the transfer (unless it is in fixed address mode). This means DMAADDR will be prefilled with the address of the second half of the row buffer after the first DMA transfer.
; 8 bit A ; 16 bit Index ; DB access registers ; DP = 0 ; ; rowBuffer u16[64] - buffer containing a 64 tile tilemap row (128 bytes in size) ; rowBufferVramWaddr u16 - the VRAM word address to transfer rowBuffer to ; VRAM word addressing lda #$80 sta VMAIN ; ; First DMA transfer. ; Transfer `rowBuffer` bytes 0 - 63 to VRAM word address `rowBufferVramWaddr` ; ; Set VRAM word address ldx rowBufferVramWaddr stx VMADD ; Word transfer to VMDATA ldx #DMA_01 | ((VMDATAL & 0xff) << 8) stx DMAMODE ; also sets B Bus Address ; Set DMA source address ldx #rowBuffer & 0xffff stx DMAADDR lda #rowBuffer >> 16 sta DMAADDRBANK ; Length of the DMA transfer (32 words, 64 bytes) ldx #64 stx DMALEN ; Start DMA transfer lda #1 sta MDMAEN ; ; Second DMA transfer. ; Transfer `rowBuffer` bytes 64 - 127 to VRAM word address `rowBufferVramWaddr + 0x400` ; ; Set VRAM word address to `rowBufferVramWaddr + 0x400` lda rowBufferVramWaddr sta VMADDL lda rowBufferVramWaddr + 1 clc adc #$04 sta VMADDH ; No need to set DMAMODE or DMAPPUREG, it remains unchanged after a DMA transfer. ; After the first transfer, DMAADDR will contain `rowBuffer + 64`. ; There is no need to set DMAADDR or DMAADDRBANK. ; We must write to DMALEN, it will be 0 after a successful DMA transfer. ldx #64 stx DMALEN ; Start DMA transfer lda #1 sta MDMAEN
Updating two tilemap rows in a 64 tile-wide background
Due to the discontiguous nature of the tilemap in a 64 tile-wide background, a transfer of a contiguous 64x2 word grid to VRAM requires 4 DMA transfers:
- rowBuffer[ 0 - 63] to VRAM word address rowBufferVramWaddr + 0
- rowBuffer[128 - 191] to VRAM word address rowBufferVramWaddr + 0x020
- rowBuffer[ 64 - 127] to VRAM word address rowBufferVramWaddr + 0x400
- rowBuffer[192 - 255] to VRAM word address rowBufferVramWaddr + 0x420
This transfer can be simplified by using two DMA channels to transfer the first and third quarters of the rowBuffer, one after another, in a single DMA transfer. Afterwords, the second and fourth quarters can be transferred to VRAM.
- rowBuffer[ 0 - 63] and rowBuffer[128 - 191] to VRAM word address rowBufferVramWaddr + 0
- rowBuffer[ 64 - 127] and rowBuffer[192 - 255] to VRAM word address rowBufferVramWaddr + 0x400
; 8 bit A ; 16 bit Index ; DB access registers ; DP = 0 ; ; rowBuffer u16[128] - buffer containing a 64x2 tilemap grid (256 bytes in size) ; rowBufferVramWaddr u16 - the VRAM word address to transfer rowBuffer to ; VRAM word addressing lda #$80 sta VMAIN ; ; First DMA transfer (using DMA channels 0 & 1). ; Transfer `rowBuffer` bytes 0 - 63 and bytes 128 - 191 to VRAM word address `rowBufferVramWaddr` ; ; Set VRAM word address ldx rowBufferVramWaddr stx VMADD ; Word transfer to VMDATA ldx #DMA_01 | ((VMDATAL & 0xff) << 8) stx DMAMODE + $00 ; also sets B Bus Address stx DMAMODE + $10 ; Set DMA source addresses ldx #rowBuffer & 0xffff stx DMAADDR + $00 ldx #(rowBuffer + 128) & 0xffff stx DMAADDR + $10 lda #rowBuffer >> 16 sta DMAADDRBANK + $00 sta DMAADDRBANK + $10 ; Transfer size for each DMA channel (32 words, 64 bytes) ldx #64 stx DMALEN + $00 stx DMALEN + $10 ; Start DMA transfer for channels 0 & 1 lda #$03 sta MDMAEN ; ; Second DMA transfer (using DMA channels 0 & 1). ; Transfer `rowBuffer` bytes 64 - 127 and bytes 192 - 255 to VRAM word address `rowBufferVramWaddr + 0x400` ; ; Set VRAM word address to `rowBufferVramWaddr + 0x400` lda rowBufferVramWaddr sta VMADDL lda rowBufferVramWaddr + 1 clc adc #$04 sta VMADDH ; No need to set DMAMODE or DMAPPUREG, it remains unchanged after a DMA transfer. ; After the first transfer, DMAADDR channel 0 will contain `rowBuffer + 64` ; and DMAADDR channel 1 will contain `rowBuffer + 192` ; ; There is no need to set DMAADDR or DMAADDRBANK. ; We must write to DMALEN, it will be 0 after a successful DMA transfer. ldx #64 stx DMALEN + $00 stx DMALEN + $10 ; Start DMA transfer for channels 0 & 1 lda #$03 sta MDMAEN
Fixed address DMA transfers
The fixed address DMA mode is useful for clearing and filling blocks of memory.
WRAM clear
These are reusable subroutines for clearing out sections of RAM, which a program might want to do at the start of a level, or in Init code. Both routines take a start address in X, and a size in Y.
The source address of a DMA transfer to WMDATA cannot be in Work-RAM, because the SNES cannot handle using DMA to copy from one section of Work-RAM to another. If you intend to fill Work-RAM with a non-zero value, use a source address in Cartridge-RAM or ROM.
Note: This routine cannot be used to clear the entire bank $7E of Work-RAM, as it will override the stack and crash the program.
Note: Due to a hardware bug on early SNES consoles it's not recommended to do this while HDMA is enabled.
.i16 ; 16-bit index registers assumed .proc MemClear php sep #$20 ; 8-bit accumulator stz WMADDH ; Set high bit of WRAM address to zero - meaning the first 64KB of RAM UseHighHalf: stx WMADDL ; WRAM address, bottom 16 bits sty DMALEN ; Configure DMA to write to WMDATA, and keep the source address constant ldx #DMAMODE_RAMFILL ZeroSource: stx DMAMODE ; The zero byte used as the source needs to come from somewhere in ROM ; here it's taken from the second byte of a "STX $4300" ldx #.loword(ZeroSource+1) stx DMAADDR ; Set the bank byte of the source address too lda #^MemClear sta DMAADDRBANK ; Start the DMA lda #1 sta MDMAEN plp rtl .endproc ; Clear a section of bank 7F instead .proc MemClear7F php sep #$20 lda #1 ; Use the second 64KB of RAM sta WMADDH bra MemClear::UseHighHalf .endproc
Filling VRAM
A fixed byte DMA transfer can be used to clear a block of VRAM. Unlike the clear Work-RAM routine above, the source of the DMA can be a Work-RAM memory address. This allows us to fill VRAM with a byte value of our choosing.
; 8 bit A ; 16 bit Index ; DB access registers ; DP = 0 ; ; Uses a single zeropage byte variable (zpTmpByte) ; Clears all of VRAM (using DMA) .proc ResetVram ldx #0 ldy #0 ; fallthrough .endproc ; Clear a block of VRAM (using DMA) ; ; IN: X - VRAM word address ; IN: Y - size (in bytes) .proc ClearVram lda #0 ; fallthrough .endproc ; Fill a block of VRAM with a byte value (using DMA) ; ; IN: X - VRAM word address ; IN: Y - size in bytes (if 0 then 64KiB of VRAM is filled) ; IN: A - byte value .proc FillVRAM ; Store value to fill in zeropage sta zpTmpByte ; VRAM word addressing lda #$80 sta VMAIN ; Set VRAM word address stx VMADD ; Length of the DMA transfer sty DMALEN ; Fixed byte transfer to word register VMDATA ldx #DMA_01 | DMA_CONST | ((VMDATA & 0xff) << 8) stx DMAMODE ; also sets B Bus Address ; Set DMA source address ldx #zpTmpByte stx DMAADDR stz DMAADDRBANK ; zeropage bank is always 0 ; Disable HDMA (prevents the model-1 HDMA/DMA crash) stz HDMAEN ; Start DMA transfer lda #1 sta MDMAEN rts .endproc
Filling VRAM with a word value
Filling VRAM with a word value is a bit more complicated. The fixed address DMA mode only allows for byte fills. Fortunately the VMAIN register provides a method of writing to the low and high bytes of VRAM separately, allowing for a VRAM word fill to be preformed in two DMA transfers.
; 8 bit A ; 16 bit Index ; DB access registers ; DP = 0 ; ; Uses a single zeropage word variable (zpTmpWord) ; Fills a 32x32 tilemap in VRAM with a given word value (using DMA) ; IN: X = VRAM word address ; IN: Y = word value .proc FillVramTilemap ; Store value to fill in zeropage sty zpTmpWord ; Must not modify X, it is still required after the first DMA transfer ; Disable HDMA (prevents the model-1 HDMA/DMA crash) stz HDMAEN ; ; Transfer the low byte of zpTmpWord to VMDATAL `32*32` times ; ; VRAM byte addressing to VMDATAL stz VMAIN ; Set VRAM word address stx VMADD ; Fixed byte transfer to byte register VMDATAL ldy #DMA_LINEAR | DMA_CONST | ((VMDATAL & 0xff) << 8) sty DMAMODE ; also sets B Bus Address ; Set DMA source address to the low byte of zpTmpWord ldy #zpTmpWord sty DMAADDR stz DMAADDRBANK ; zeropage bank is always 0 ; Length of the DMA transfer ldy #32 * 32 sty DMALEN ; Start DMA transfer lda #1 sta MDMAEN ; ; Transfer the high byte of zpTmpWord to VMDATAH `32*32` times ; ; VRAM byte addressing to VMDATAH lda #$80 sta VMAIN ; Set VRAM word address stx VMADD ; Change DMA B-Bus address to VMDATAH lda #VMDATAH & 0xff sta DMAPPUREG ; DMAMODE is already set ; Set DMA source address to the high byte of zpTmpWord lda #zpTmpWord + 1 sta DMAADDR ; DMAADDRHI and DMAADDRBANK is already set ; Length of the DMA transfer ldy #32 * 32 sty DMALEN ; Start DMA transfer lda #1 sta MDMAEN rts .endproc
See Also
Links
- DMA Palette - by nesdoug
- Grog's Guide to DMA and HDMA on the SNES - superfamicom.org wiki
- DMA tutorial - Super NES Programming Wikibooks