NSF2: Difference between revisions
(Allowing for extra expansion audio enable bits.) |
m (Reverting a change that was discussed only in the "Famitracker Community" Discord server) |
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| Line 19: | Line 19: | ||
| $005 || 1 || BYTE || Version number: $02 (was $01) | | $005 || 1 || BYTE || Version number: $02 (was $01) | ||
|- | |- | ||
| $07C | | $07C || 1 || BYTE || NSF 2.0 feature enables (was $00) | ||
* bit 0: if set, enable IRQ features | * bit 0: if set, enable IRQ features | ||
* bit 1: if set, allow a non-returning init address | * bit 1: if set, allow a non-returning init address | ||
| Line 28: | Line 26: | ||
* bit 7: if set, a metadata block follows the NSF data | * bit 7: if set, a metadata block follows the NSF data | ||
|- | |- | ||
| $ | | $07D || 3 || WORD || Length of NSF data block in bytes, LSB first, up to $100000 (was $000000) | ||
|} | |} | ||
| Line 36: | Line 34: | ||
* [[APU DMC]] IRQ | * [[APU DMC]] IRQ | ||
* [[APU Frame Counter]] IRQ | * [[APU Frame Counter]] IRQ | ||
* A new cycle-counting interval timer at $ | * A new cycle-counting interval timer at $4018-$401A, handled much as a mapper IRQ | ||
A program using IRQ MUST write to $4017 to enable the interval timer IRQ and to reset the frame IRQ. | A program using IRQ MUST write to $4017 to enable the interval timer IRQ and to reset the frame IRQ. | ||
The interval timer has three readable and writable ports: | The interval timer has three readable and writable ports: | ||
* $ | * $4018: Lower 8 bits of the 16-bit timer reload value | ||
* $ | * $4019: Upper 8 bits of the 16-bit timer reload value | ||
* $ | * $401A: Control register. Clearing bit 0 stops the timer and holds it in reset; setting it to 1 starts it. | ||
In NSF 2 files using IRQ, $FFFE and $FFFF (the IRQ vector) are treated as readable and writable. | In NSF 2 files using IRQ, $FFFE and $FFFF (the IRQ vector) are treated as readable and writable. | ||
| Line 56: | Line 54: | ||
The counter is a modulus N counter and has the following behaviour: | The counter is a modulus N counter and has the following behaviour: | ||
When the counter is off (whenever | When the counter is off (whenever 401a bit 0 is clear) it is constantly being reloaded with the values in 4018/4019, and the counter IRQ flag is cleared. | ||
When the counter is on ( | When the counter is on (401a bit 0 is set), it will decrement once per CPU cycle. When it hits 0, it is reloaded from 4018/4019, the IRQ flag is set and an IRQ is asserted. | ||
This means an IRQ will be generated every N+1 clock cycles, where N is the value loaded into the counter. (it is N+1 because 0 is counted too). | This means an IRQ will be generated every N+1 clock cycles, where N is the value loaded into the counter. (it is N+1 because 0 is counted too). | ||
To clear the IRQ flag, you read | To clear the IRQ flag, you read 401a. I should probably put the IRQ flag at bit 7 (read only) to allow easy testing of IRQ source. | ||
Code might look like this: | Code might look like this: | ||
| Line 70: | Line 68: | ||
starttimer: LDA #000h | starttimer: LDA #000h | ||
STA | STA 0401ah ;reset and shut off timer in case it was on | ||
LDA #<irqvector | LDA #<irqvector | ||
| Line 78: | Line 76: | ||
LDA #<timervalue | LDA #<timervalue | ||
STA | STA 04018h ;low byte of timer value | ||
LDA #>timervalue | LDA #>timervalue | ||
STA | STA 04019h ;high byte of timer value | ||
LDA #0c0h | LDA #0c0h | ||
| Line 88: | Line 86: | ||
LDA #01h | LDA #01h | ||
STA | STA 0401ah ;turn the timer on | ||
RTS | RTS | ||
stoptimer: SEI ;turn off IRQs | stoptimer: SEI ;turn off IRQs | ||
LDA #000h | LDA #000h | ||
STA | STA 0401ah ;turn timer off | ||
RTS | RTS | ||
| Line 100: | Line 98: | ||
.... | .... | ||
LDA | LDA 0401ah ;reading 401a resets IRQ flag | ||
RTI ;return from interrupt | RTI ;return from interrupt | ||
| Line 106: | Line 104: | ||
alternatively, if you wish to determine WHAT caused the IRQ (if you're using more than one source) you'd do something like this... | alternatively, if you wish to determine WHAT caused the IRQ (if you're using more than one source) you'd do something like this... | ||
irqvector: BIT | irqvector: BIT 0401ah ;bit 7 indicates we have a timer IRQ waiting | ||
BPL + | BPL + | ||
JSR timer ;if bit 7 was set, call timer subroutine | JSR timer ;if bit 7 was set, call timer subroutine | ||
Revision as of 01:28, 18 June 2017
NSF 2 is a proposed extension to the NSF file format. It is intended to be backward compatible with the original NSF, provide IRQ timer functionality, and allow track times and other metadata to be contained.
It is currently an unfinished proposal. Currently Nintendulator partially supports it. See link below for reference.
The goals are:
- IRQ support
- "no return" init addresses
- information block
New header fields
| offset | length | type | description |
|---|---|---|---|
| $005 | 1 | BYTE | Version number: $02 (was $01) |
| $07C | 1 | BYTE | NSF 2.0 feature enables (was $00)
|
| $07D | 3 | WORD | Length of NSF data block in bytes, LSB first, up to $100000 (was $000000) |
IRQ support
NSF 2 files are allowed to use three IRQ sources:
- APU DMC IRQ
- APU Frame Counter IRQ
- A new cycle-counting interval timer at $4018-$401A, handled much as a mapper IRQ
A program using IRQ MUST write to $4017 to enable the interval timer IRQ and to reset the frame IRQ.
The interval timer has three readable and writable ports:
- $4018: Lower 8 bits of the 16-bit timer reload value
- $4019: Upper 8 bits of the 16-bit timer reload value
- $401A: Control register. Clearing bit 0 stops the timer and holds it in reset; setting it to 1 starts it.
In NSF 2 files using IRQ, $FFFE and $FFFF (the IRQ vector) are treated as readable and writable. A program using IRQ MUST write to these locations before enabling IRQ. Writes to $FFFE and $FFFF do not affect the NSF data; they are separate bytes of RAM.
For IRQ support, I figured allowing the use of frame IRQs and DPCM IRQs just like on the NES, and then a 16 bit IRQ timer which would be connected to the CPU in the usual way (via its IRQ input).
This would allow a real NES to play 2.0 NSFs using say a PowerPak or similar.
The timer would decrement at the CPU clock rate, whether it be NTSC or PAL rate (so 1.79MHz or 1.66MHz or so).
The counter is a modulus N counter and has the following behaviour:
When the counter is off (whenever 401a bit 0 is clear) it is constantly being reloaded with the values in 4018/4019, and the counter IRQ flag is cleared.
When the counter is on (401a bit 0 is set), it will decrement once per CPU cycle. When it hits 0, it is reloaded from 4018/4019, the IRQ flag is set and an IRQ is asserted.
This means an IRQ will be generated every N+1 clock cycles, where N is the value loaded into the counter. (it is N+1 because 0 is counted too).
To clear the IRQ flag, you read 401a. I should probably put the IRQ flag at bit 7 (read only) to allow easy testing of IRQ source.
Code might look like this:
timervalue: .equ 01fffh ;desired # of cpu cycles minus 1
starttimer: LDA #000h
STA 0401ah ;reset and shut off timer in case it was on
LDA #<irqvector
STA 0fffeh ;store interrupt vector low of our handler
LDA #>irqvector
STA 0ffffh ;store interrupt vector high
LDA #<timervalue
STA 04018h ;low byte of timer value
LDA #>timervalue
STA 04019h ;high byte of timer value
LDA #0c0h
STA 04017h ;turn off frame IRQs
LDA 04015h ;ack any pending DPCM IRQ if, it exists
CLI ;enable IRQs
LDA #01h
STA 0401ah ;turn the timer on
RTS
stoptimer: SEI ;turn off IRQs
LDA #000h
STA 0401ah ;turn timer off
RTS
irqvector: <perform our interrupt code here>
....
....
LDA 0401ah ;reading 401a resets IRQ flag
RTI ;return from interrupt
alternatively, if you wish to determine WHAT caused the IRQ (if you're using more than one source) you'd do something like this...
irqvector: BIT 0401ah ;bit 7 indicates we have a timer IRQ waiting
BPL +
JSR timer ;if bit 7 was set, call timer subroutine
+ BIT 04015h
BPL +
PHP ;save flags if we have DPCM int.
JSR dpcm ;if bit 7 was set, call DPCM sub
PLP
+ BVC +
JSR frame ;bit 6 of 4015 = frame IRQ
+ RTI ;exit interrupt
timer: <do stuff here>
RTS
dpcm: <do stuff here>
RTS
frame: <do stuff here>
RTS
There's a lot of ways to skin this cat, but this is one particular method. The idea is to read the status regs to figure out which source caused the interrupt, then run code to service it, then go back and check the other sources just in case one of them also needs servicing.
Like the APU period timers and the MMC3 scanline timer, the NSF2 cycle timer includes both the 0 and the reload value in its sequence of states. When it hits 0, the NEXT clock performs a reload.
For example, when the reload value is $0010, the counter would have a period of 17 CPU cycles:
10, 10, 10, [Enable now] 0F, 0E, 0D, 0C, ..., 02, 01, 00, 10*, 0F, 0E, 0D, 0C, ...
where * denotes the IRQ flag becoming true.
Non-returning INIT
An NSF with a non-returning INIT takes more or less complete control of the CPU. In effect, the INIT address becomes the reset vector, and the PLAY address becomes the NMI vector. If the IRQ feature is also in use, IRQ has its vector at $FFFE-$FFFF as above.
Metadata
The optional metadata block allows an NSF to carry the following additional metadata:
- Longer title, author, and copyright fields
- UTF-8 encoding for wider language support
- Separate field for ripper
- Lengths of tracks
- Possibility of separate track, author, and copyright fields
The metadata is placed at the end so that pre-NSF 2 players will correctly ignore it by placing it at the end of the NSF data. Files MUST also contain data in the original title, author, and copyright fields for compatibility with pre-NSF 2 tools.
Kev's proposal uses a somewhat TIFF-like chunked format for metadata
| offset | length | type | description |
|---|---|---|---|
| 0 | 1 | BYTE | record type |
| 1 | 2 | WORD | record length |
| 3 | 1 | BYTE | track number to which this record applies, or $FF for all tracks |
| 4 | N | variant | record data |
| N + 4 | 1 | BYTE | next record type... |
Records would be one after another, and a record of 4 $00 bytes would signify the end of the data.
- $00: last record (length 0)
- $01: title (1 line)
- $02: composer (1 line)
- $03: copyright (1 line)
- $04: ripper (1 line)
- $05: Length (in units to be determined)
- $06: Type (background music, jingle, or sound effect; values to be determined)
- $07: Additional description (UTF-8, for example: "Entry 7, cover of 'Breaking the Law' by Judas Priest")
All strings are UTF-8; players should indicate an error for characters that they cannot display. For example, a hardware player supporting only ASCII might replace any run of bytes with the high bit set with �.
To reduce duplication of data, track $FF is a wildcard indicator, which populates fields that don't have a more specific value for a particular track:
- composer, track $FF, jimbob
- title, track 0, my first song
- title, track 1, my second song
- title, track 2, a song by someone else
- composer, track 2, billy
- title, track 3, another song
This would set the composer of tracks 0, 1, and 3 to jimbob.
This format should be easy for a hardware player to parse. If you prefer to enter metadata as JSON, XML, or the like, create a tool that parses your metadata and stuffs it at the end of the NSF.
