RAMBO-1: Difference between revisions
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:''For the mapper used in the game "Rambo", see [[UxROM]].'' | {{Infobox_iNES_mapper | ||
[[Category:MMC3-like mappers]] | |name=RAMBO-1 | ||
The '''Tengen RAMBO-1''' is an [[:Category:ASIC mappers|ASIC]] [[MMC|mapper]], canonically designated as '''mapper 64'''. This mapper is basically Tengen's version of the [[MMC3]], but with some extra features. The RAMBO-1 came as a [[Tengen RAMBO-1 pinout|40-pin PDIP]]. A variant with different mirroring control is [[iNES Mapper 158|mapper 158]]. | |company=Tengen | ||
|mapper=64 | |||
|othermappers=[[iNES Mapper 158|158]] | |||
|nescartdbgames=5 | |||
|complexity=ASIC | |||
|boards=800032 | |||
|pinout=Tengen RAMBO-1 pinout | |||
|prgmax=256K | |||
|prgpage=3×8K + 8K fixed | |||
|chrmax=256K | |||
|chrpage=1Kx8 or 2Kx2 + 1Kx4 | |||
|mirroring=H or V, switchable | |||
|busconflicts=No | |||
|irq=Yes | |||
}} | |||
{{nesdbbox | |||
|ines|64|iNES 064 | |||
|unif|TENGEN-800032|800032 | |||
}}:''For the mapper used in the game "Rambo", see [[UxROM]].'' | |||
[[Category:MMC3-like mappers]][[Category:Mappers with scanline IRQs]][[Category:Mappers with cycle IRQs]] | |||
The '''Tengen RAMBO-1''' is an [[:Category:ASIC mappers|ASIC]] [[MMC|mapper]], canonically designated as '''mapper 64'''. This mapper is basically Tengen's version of the [[MMC3]], but with some extra features. The RAMBO-1 came as a [[Tengen RAMBO-1 pinout|40-pin PDIP]]. A variant with different mirroring control is [[iNES Mapper 158|mapper 158]]. | |||
Example games: | |||
* ''Klax'' | |||
* | * ''Skull and Crossbones'' | ||
* | * ''Shinobi'' | ||
* ''Rolling Thunder'' | |||
* | * ''Hard Drivin' (prototype)'' | ||
* | |||
* | |||
== Banks == | == Banks == | ||
Line 32: | Line 50: | ||
||| |||| | ||| |||| | ||
||| ++++- Specify which bank register to update on next write to Bank Data register | ||| ++++- Specify which bank register to update on next write to Bank Data register | ||
||| | ||| 0000: R0: Select 2 (K=0) or 1 (K=1) KiB CHR bank at PPU $0000 (or $1000) | ||
||| | ||| 0001: R1: Select 2 (K=0) or 1 (K=1) KiB CHR bank at PPU $0800 (or $1800) | ||
||| | ||| 0010: R2: Select 1 KiB CHR bank at PPU $1000-$13FF (or $0000-$03FF) | ||
||| | ||| 0011: R3: Select 1 KiB CHR bank at PPU $1400-$17FF (or $0400-$07FF) | ||
||| | ||| 0100: R4: Select 1 KiB CHR bank at PPU $1800-$1BFF (or $0800-$0BFF) | ||
||| | ||| 0101: R5: Select 1 KiB CHR bank at PPU $1C00-$1FFF (or $0C00-$0FFF) | ||
||| | ||| 0110: R6: Select 8 KiB PRG ROM bank at $8000-$9FFF (or $C000-$DFFF) | ||
||| | ||| 0111: R7: Select 8 KiB PRG ROM bank at $A000-$BFFF | ||
||| | ||| 1000: R8: If K=1, Select 1 KiB CHR bank at PPU $0400 (or $1400) | ||
||| | ||| 1001: R9: If K=1, Select 1 KiB CHR bank at PPU $0C00 (or $1C00) | ||
||| | ||| 1111: RF: Select 8 KiB PRG ROM bank at $C000-$DFFF (or $8000-$9FFF) | ||
||+------- Full 1 KiB CHR bank mode | ||+------- Full 1 KiB CHR bank mode 0: two 2 KiB banks at $0000-$0FFF (or $1000-$1FFF) | ||
|| | || 1: four 1 KiB banks at $0000-$0FFF (or $1000-$1FFF) | ||
|+-------- PRG ROM bank mode | |+-------- PRG ROM bank mode 0: $8000-$9FFF uses bank selected with R6 | ||
| $A000-$BFFF uses bank selected with | | $A000-$BFFF uses bank selected with R7 | ||
| $C000-$DFFF uses bank selected with | | $C000-$DFFF uses bank selected with RF | ||
| 1: $8000-$9FFF uses bank selected with | | 1: $8000-$9FFF uses bank selected with RF | ||
| $A000-$BFFF uses bank selected with | | $A000-$BFFF uses bank selected with R7 | ||
| $C000-$DFFF uses bank selected with | | $C000-$DFFF uses bank selected with R6 | ||
+--------- CHR A12 inversion | +--------- CHR A12 inversion 0: two 2 KiB banks (or four 1 KiB banks) at $0000-$0FFF | ||
four 1 KiB banks at $1000-$1FFF | four 1 KiB banks at $1000-$1FFF | ||
1: two 2 KiB banks (or four 1 KiB banks) at $1000-$1FFF | 1: two 2 KiB banks (or four 1 KiB banks) at $1000-$1FFF | ||
four 1 KiB banks at $0000-$0FFF | four 1 KiB banks at $0000-$0FFF | ||
==== CHR Banks ==== | |||
{| class="wikitable" | |||
! When $8000 & $80 !! is $00 !! is $80 | |||
|- | |||
! PPU Bank !! colspan=2|Value of RAMBO-1 register | |||
|- | |||
| $0000-$03FF || R0 || R2 | |||
|- | |||
| $0400-$07FF || K=0: R0<br/>K=1: R8 || R3 | |||
|- | |||
| $0800-$0BFF || R1 || R4 | |||
|- | |||
| $0C00-$0FFF || K=0: R1<br/>K=1: R9 || R5 | |||
|- | |||
| $1000-$13FF || R2 || R0 | |||
|- | |||
| $1400-$17FF || R3 || K=0: R0<br/>K=1: R8 | |||
|- | |||
| $1800-$1BFF || R4 || R1 | |||
|- | |||
| $1C00-$1FFF || R5 || K=0: R1<br/>K=1: R9 | |||
|} | |||
With 2KiB banks (where K=0), only even-numbered CHR banks can be selected. The lowest bit in the register is ignored and instead passes PPU A10 directly through to CHR A10. | |||
==== PRG Banks ==== | |||
Because the values in R6, R7, RF, and $8000 are unspecified at power on, the reset vector must point into $E000-$FFFF, and code must initialize these before jumping out of $E000-$FFFF. | |||
{| class="wikitable" | |||
! When $8000 & $40 !! is $00 !! is $40 | |||
|- | |||
! CPU Bank !! colspan=2|Value of RAMBO-1 register | |||
|- | |||
| $8000-$9FFF || R6 || RF | |||
|- | |||
| $A000-$BFFF || R7 || R7 | |||
|- | |||
| $C000-$DFFF || RF || R6 | |||
|- | |||
| $E000-$FFFF || (-1) || (-1) | |||
|} | |||
* (-1) : the last bank | |||
=== Bank data ($8001-$9FFF, odd) === | === Bank data ($8001-$9FFF, odd) === | ||
All eight bits are used for a new value for the bank based on last value written to Bank select register (as mentioned above) | |||
=== Mirroring ($A000-$BFFE, even) === | === Mirroring ($A000-$BFFE, even) === | ||
Line 73: | Line 127: | ||
This applies to '''mapper 64''' only (see [[#Variants|Variants]] below). | This applies to '''mapper 64''' only (see [[#Variants|Variants]] below). | ||
=== Unknown ($A001-$BFFF, odd) === | |||
This register is either not implemented or has undiscovered functionality on RAMBO-1. The MMC3/MMC6 equivalent of this register controls external and internal PRG-RAM access. There is not presently any reason to believe that RAMBO-1 has any support for PRG-RAM. | |||
== IRQ registers == | |||
=== IRQ latch ($C000-$DFFE, even) === | === IRQ latch ($C000-$DFFE, even) === | ||
All eight bits of this register specifies the IRQ counter reload value. When the IRQ counter is zero (or a reload is requested through $C001), this value will be copied into the IRQ counter at the end of the current scanline. | |||
=== IRQ mode select / reload ($C001-$DFFF, odd) === | === IRQ mode select / reload ($C001-$DFFF, odd) === | ||
Line 93: | Line 146: | ||
=== IRQ acknowledge / disable ($E000-$FFFE, even) === | === IRQ acknowledge / disable ($E000-$FFFE, even) === | ||
Writing any value to this register will disable counter interrupts AND acknowledge any pending interrupts. | Writing any value to this register will disable counter interrupts AND acknowledge any pending interrupts. | ||
=== IRQ enable ($E001-$FFFF, odd) === | === IRQ enable ($E001-$FFFF, odd) === | ||
Writing any value to this register will enable counter interrupts. Note that writing to this register does not acknowledge the IRQ if already set. | |||
Writing any value to this register will enable counter interrupts. | |||
== IRQ counter operation == | == IRQ counter operation == | ||
There are two IRQ modes: PPU A12 mode (also known as ''scanline mode'') and CPU cycle mode. | |||
In scanline mode, the counter is clocked using a very similar method to that used by the [[MMC3]] | In ''scanline mode'', the counter is clocked using a very similar method to that used by the [[MMC3]] and follows the same restrictions. In comparison to the [[MMC3]], the actual interrupt triggers slightly later. Specifically, it is delayed until [http://forums.nesdev.org/viewtopic.php?p=117323#p117323 M2 falls twice after the PPU A12 rise] that would have triggered the MMC3 interrupt. | ||
In CPU cycle mode, the counter is clocked every 4 CPU cycles. The actual interrupt triggers [http://forums.nesdev.org/viewtopic.php?p=117461#p117461 one M2 cycle later] than one would naively expect. | In ''CPU cycle mode'', the counter is clocked every 4 CPU cycles. The actual interrupt triggers [http://forums.nesdev.org/viewtopic.php?p=117461#p117461 one M2 cycle later] than one would naively expect. | ||
Whichever | Whichever IRQ mode is being used, the counter behaves the following way: | ||
* '''IF''' $C001 was written to after previous clock | '''When the IRQ is clocked by ''scanline'' or ''CPU cycle'' modes:''' | ||
** reload IRQ counter with IRQ | * '''IF''' $C001 was written to after previous clock: | ||
* '''ELSE IF''' IRQ counter is 0 | ** reload IRQ counter with IRQ reload value; if non zero, this value is '''ORed with 1''' (see notes). | ||
** reload IRQ counter with IRQ | * '''ELSE IF''' IRQ counter is 0: | ||
** reload IRQ counter with IRQ reload value. | |||
* '''ELSE''' | * '''ELSE''' | ||
** Decrement IRQ counter by 1 | ** Decrement IRQ counter by 1. | ||
* | * If IRQ counter is now 0 '''AND''' IRQs are enabled: | ||
*** | ** trigger IRQ after 4 CPU cycles. | ||
'''Notes:''' | |||
* It's still unknown how the extra kick works. ''Klax'' still requires '''+1''' to run perfectly. | |||
* Most emulators run ''Skull & Crossbones'' with a glitched scanline on the "Continue" screen OR during the game (score bar). | |||
Following these rules in scanline counter mode has demonstrated accurate behavior, but this needs to be refined and merged with the description above: | |||
On M2 falling edge: | |||
If PA12 = 0: | |||
If 4-bit counter < 16: 4-bit counter++. | |||
else keep the same value. | |||
If PA12 = 1: | |||
If 4-bit counter = 16: Clock the 8-bit counter. | |||
Always reset 4-bit counter to 0. | |||
On 8-bit counter clock: | |||
If value = 0: | |||
If IRQ is enabled, trigger IRQ (wait 1 more cycle before doing that though, regardless of PA12 next cycle...) | |||
Always reload counter with value in $C000. | |||
Else value--. | |||
On Write to $C001 (reset): | |||
Reload 8-bit counter with value in $C000 | |||
Set 4-bit counter to 17. | |||
== Variants == | == Variants == | ||
[[iNES Mapper 158|Mapper 158]], used for ''Alien Syndrome'', has mirroring like [[iNES Mapper 118|mapper 118]] ([[TLSROM]]), where CIRAM A10 is connected to CHR A17, and bit 7 of each CHR bank mapped into PPU $0000-$0FFF controls which page of CIRAM is used for the corresponding nametable in $2000-$2FFF. | [[iNES Mapper 158|Mapper 158]], used for ''Alien Syndrome'', has mirroring like [[iNES Mapper 118|mapper 118]] ([[TLSROM]]), where CIRAM A10 is connected to CHR A17, and bit 7 of each CHR bank mapped into PPU $0000-$0FFF controls which page of CIRAM is used for the corresponding nametable in $2000-$2FFF. | ||
== | == See also == | ||
*[http://www.romhacking.net/documents/362/ NES Mapper List] by Disch | |||
*[http://nesdev.org/mappers.zip Comprehensive NES Mapper Document] by \Firebug\, information about mapper's initial state is inaccurate. | |||
Latest revision as of 13:48, 7 March 2021
Company | Tengen |
Games | 5 in NesCartDB |
Complexity | ASIC |
Boards | 800032 |
Pinout | Tengen RAMBO-1 pinout |
PRG ROM capacity | 256K |
PRG ROM window | 3×8K + 8K fixed |
PRG RAM capacity | None |
CHR capacity | 256K |
CHR window | 1Kx8 or 2Kx2 + 1Kx4 |
Nametable mirroring | H or V, switchable |
Bus conflicts | No |
IRQ | Yes |
Audio | No |
iNES mappers | 064, 158 |
- For the mapper used in the game "Rambo", see UxROM.
The Tengen RAMBO-1 is an ASIC mapper, canonically designated as mapper 64. This mapper is basically Tengen's version of the MMC3, but with some extra features. The RAMBO-1 came as a 40-pin PDIP. A variant with different mirroring control is mapper 158.
Example games:
- Klax
- Skull and Crossbones
- Shinobi
- Rolling Thunder
- Hard Drivin' (prototype)
Banks
- CPU $8000-$9FFF: 8 KiB switchable PRG ROM bank
- CPU $A000-$BFFF: 8 KiB switchable PRG ROM bank
- CPU $C000-$DFFF: 8 KiB switchable PRG ROM bank
- CPU $E000-$FFFF: 8 KiB PRG ROM bank, fixed to the last bank
- PPU -- Three selectable configurations:
- 1 KiB switchable CHR banks at $0000, $0400, $0800, $0C00, $1000, $1400, $1800, $1C00
- 2 KiB switchable CHR banks at $0000, $0800; 1 KiB switchable CHR banks at $1000, $1400, $1800, $1C00
- 2 KiB switchable CHR banks at $1000, $1800; 1 KiB switchable CHR banks at $0000, $0400, $0800, $0C00
Registers
The RAMBO-1 has four pairs of registers at $8000-$9FFF, $A000-$BFFF, $C000-$DFFF, and $E000-$FFFF - even addresses ($8000, $8002, etc.) select the low register and odd addresses ($8001, $8003, etc.) select the high register in each pair.
Bank select ($8000-$9FFE, even)
7 bit 0 ---- ---- CPKx RRRR ||| |||| ||| ++++- Specify which bank register to update on next write to Bank Data register ||| 0000: R0: Select 2 (K=0) or 1 (K=1) KiB CHR bank at PPU $0000 (or $1000) ||| 0001: R1: Select 2 (K=0) or 1 (K=1) KiB CHR bank at PPU $0800 (or $1800) ||| 0010: R2: Select 1 KiB CHR bank at PPU $1000-$13FF (or $0000-$03FF) ||| 0011: R3: Select 1 KiB CHR bank at PPU $1400-$17FF (or $0400-$07FF) ||| 0100: R4: Select 1 KiB CHR bank at PPU $1800-$1BFF (or $0800-$0BFF) ||| 0101: R5: Select 1 KiB CHR bank at PPU $1C00-$1FFF (or $0C00-$0FFF) ||| 0110: R6: Select 8 KiB PRG ROM bank at $8000-$9FFF (or $C000-$DFFF) ||| 0111: R7: Select 8 KiB PRG ROM bank at $A000-$BFFF ||| 1000: R8: If K=1, Select 1 KiB CHR bank at PPU $0400 (or $1400) ||| 1001: R9: If K=1, Select 1 KiB CHR bank at PPU $0C00 (or $1C00) ||| 1111: RF: Select 8 KiB PRG ROM bank at $C000-$DFFF (or $8000-$9FFF) ||+------- Full 1 KiB CHR bank mode 0: two 2 KiB banks at $0000-$0FFF (or $1000-$1FFF) || 1: four 1 KiB banks at $0000-$0FFF (or $1000-$1FFF) |+-------- PRG ROM bank mode 0: $8000-$9FFF uses bank selected with R6 | $A000-$BFFF uses bank selected with R7 | $C000-$DFFF uses bank selected with RF | 1: $8000-$9FFF uses bank selected with RF | $A000-$BFFF uses bank selected with R7 | $C000-$DFFF uses bank selected with R6 +--------- CHR A12 inversion 0: two 2 KiB banks (or four 1 KiB banks) at $0000-$0FFF four 1 KiB banks at $1000-$1FFF 1: two 2 KiB banks (or four 1 KiB banks) at $1000-$1FFF four 1 KiB banks at $0000-$0FFF
CHR Banks
When $8000 & $80 | is $00 | is $80 |
---|---|---|
PPU Bank | Value of RAMBO-1 register | |
$0000-$03FF | R0 | R2 |
$0400-$07FF | K=0: R0 K=1: R8 |
R3 |
$0800-$0BFF | R1 | R4 |
$0C00-$0FFF | K=0: R1 K=1: R9 |
R5 |
$1000-$13FF | R2 | R0 |
$1400-$17FF | R3 | K=0: R0 K=1: R8 |
$1800-$1BFF | R4 | R1 |
$1C00-$1FFF | R5 | K=0: R1 K=1: R9 |
With 2KiB banks (where K=0), only even-numbered CHR banks can be selected. The lowest bit in the register is ignored and instead passes PPU A10 directly through to CHR A10.
PRG Banks
Because the values in R6, R7, RF, and $8000 are unspecified at power on, the reset vector must point into $E000-$FFFF, and code must initialize these before jumping out of $E000-$FFFF.
When $8000 & $40 | is $00 | is $40 |
---|---|---|
CPU Bank | Value of RAMBO-1 register | |
$8000-$9FFF | R6 | RF |
$A000-$BFFF | R7 | R7 |
$C000-$DFFF | RF | R6 |
$E000-$FFFF | (-1) | (-1) |
- (-1) : the last bank
Bank data ($8001-$9FFF, odd)
All eight bits are used for a new value for the bank based on last value written to Bank select register (as mentioned above)
Mirroring ($A000-$BFFE, even)
7 bit 0 ---- ---- xxxx xxxM | +- Mirroring (0: vertical; 1: horizontal)
This applies to mapper 64 only (see Variants below).
Unknown ($A001-$BFFF, odd)
This register is either not implemented or has undiscovered functionality on RAMBO-1. The MMC3/MMC6 equivalent of this register controls external and internal PRG-RAM access. There is not presently any reason to believe that RAMBO-1 has any support for PRG-RAM.
IRQ registers
IRQ latch ($C000-$DFFE, even)
All eight bits of this register specifies the IRQ counter reload value. When the IRQ counter is zero (or a reload is requested through $C001), this value will be copied into the IRQ counter at the end of the current scanline.
IRQ mode select / reload ($C001-$DFFF, odd)
7 bit 0 ---- ---- xxxx xxxM | +- IRQ mode select (0: Scanline Mode, 1: CPU Cycle Mode)
Writing to this register also clears the IRQ counter so that it will be reloaded at next clock, or the next scanline, depending on the selected mode. This also resets the prescaler in cycle mode, so the next clock will occur 4 cycles later.
IRQ acknowledge / disable ($E000-$FFFE, even)
Writing any value to this register will disable counter interrupts AND acknowledge any pending interrupts.
IRQ enable ($E001-$FFFF, odd)
Writing any value to this register will enable counter interrupts. Note that writing to this register does not acknowledge the IRQ if already set.
IRQ counter operation
There are two IRQ modes: PPU A12 mode (also known as scanline mode) and CPU cycle mode.
In scanline mode, the counter is clocked using a very similar method to that used by the MMC3 and follows the same restrictions. In comparison to the MMC3, the actual interrupt triggers slightly later. Specifically, it is delayed until M2 falls twice after the PPU A12 rise that would have triggered the MMC3 interrupt.
In CPU cycle mode, the counter is clocked every 4 CPU cycles. The actual interrupt triggers one M2 cycle later than one would naively expect.
Whichever IRQ mode is being used, the counter behaves the following way:
When the IRQ is clocked by scanline or CPU cycle modes:
- IF $C001 was written to after previous clock:
- reload IRQ counter with IRQ reload value; if non zero, this value is ORed with 1 (see notes).
- ELSE IF IRQ counter is 0:
- reload IRQ counter with IRQ reload value.
- ELSE
- Decrement IRQ counter by 1.
- If IRQ counter is now 0 AND IRQs are enabled:
- trigger IRQ after 4 CPU cycles.
Notes:
- It's still unknown how the extra kick works. Klax still requires +1 to run perfectly.
- Most emulators run Skull & Crossbones with a glitched scanline on the "Continue" screen OR during the game (score bar).
Following these rules in scanline counter mode has demonstrated accurate behavior, but this needs to be refined and merged with the description above:
On M2 falling edge: If PA12 = 0: If 4-bit counter < 16: 4-bit counter++. else keep the same value. If PA12 = 1: If 4-bit counter = 16: Clock the 8-bit counter. Always reset 4-bit counter to 0. On 8-bit counter clock: If value = 0: If IRQ is enabled, trigger IRQ (wait 1 more cycle before doing that though, regardless of PA12 next cycle...) Always reload counter with value in $C000. Else value--. On Write to $C001 (reset): Reload 8-bit counter with value in $C000 Set 4-bit counter to 17.
Variants
Mapper 158, used for Alien Syndrome, has mirroring like mapper 118 (TLSROM), where CIRAM A10 is connected to CHR A17, and bit 7 of each CHR bank mapped into PPU $0000-$0FFF controls which page of CIRAM is used for the corresponding nametable in $2000-$2FFF.
See also
- NES Mapper List by Disch
- Comprehensive NES Mapper Document by \Firebug\, information about mapper's initial state is inaccurate.