Rendering logic: Difference between revisions
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On the NeoGeo hardware, the GPU (Graphics Processing Unit) a.k.a. VDP, may refer to a chip or a group of different chips used to generate the video signal. | On the NeoGeo hardware, the GPU (Graphics Processing Unit) a.k.a. VDP, may refer to a chip or a group of different chips used to generate the video signal. | ||
* [[LSPC-A0]], [[PRO-B0]] (early) | * [[LSPC-A0]], [[PRO-B0]] (early) | ||
* [[LSPC2-A2]], [[NEO-B1]] (most common) | * [[LSPC2-A2]], [[NEO-B1]] (most common) | ||
* [[NEO-GRC]], [[NEO-OFC]] (CD systems) | * [[NEO-GRC]], [[NEO-OFC]] (CD systems) | ||
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==Graphics fetch== | ==Graphics fetch== | ||
Tile pixel lines are rendered in halves | Tile pixel lines are rendered in halves. | ||
===Fix tiles=== | |||
32mclk = 8 pixels, 2 pixels per read. | |||
* | * S1 ROM address is ...1**** (PCK2 pulse) | ||
** 2H1 is 0 for 2 pixels (columns 0 & 1) | |||
** | ** Then 1 for 2 pixels (columns 2 & 3) | ||
* | * S1 ROM address is ...0**** (PCK2 pulse) | ||
** | ** 2H1 is 0 for 2 pixels (columns 4 & 5) | ||
** Then 1 for 2 pixels (columns 6 & 7) | |||
* | ===Sprite tiles=== | ||
* | 16mclk = 16 pixels, 8 pixels per read. | ||
* C ROM address is ...1***** (PCK1 pulse) (columns 0~7) | |||
* C ROM address is ...0***** (PCK1 pulse) (columns 8~15) | |||
CA4 is used to select upper/lower tiles (see [[Sprite graphics format]]). | |||
=Video generation= | =Video generation= | ||
See [[Display timing]] for the sync signal's timing. | See [[Display timing]] for the sync signal's timing. | ||
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Inactive during H-blank. | Inactive during H-blank. | ||
==LD signals== | |||
The LD1~2 signals sets the X position in B1. It is /2, since it is set in both even and odd buffers. | |||
Example P bus data for 20 sprites right next to each other (X+=16px): | |||
<pre>0000,0808,1010,1838,2000,2808,3010,3838,40C0,48E8,50F0,58F8,60C0,68E8,70F0,78F8,8000,8808,9010,9838,0,0,0...</pre> | |||
The lower byte might just be garbage ignored by B1. | |||
==WSE signals== | ==WSE signals== | ||
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* If the pixel is skipped for horizontal reduction, there are no pulses at all. | * If the pixel is skipped for horizontal reduction, there are no pulses at all. | ||
During output, the pulses are also synchronized and always present. This is used to clear to the backdrop color for the next rendering cycle. | During output, the pulses are also synchronized to CSK signals and always present. This is used to clear to the backdrop color for the next rendering cycle. | ||
The buffer's /WE signals seems to be (CSK & WSE). | The buffer's /WE signals seems to be (CSK & WSE). | ||
==SS signals== | ==SS signals== | ||
The complementary pair of SS* signals from LSPC tell B1 how the buffers are used: | The complementary pair of SS* signals from LSPC tell B1 how the buffers are used: | ||
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==Notes== | ==Notes== | ||
* What's the use of TMS0 ? Not buffer flip, SS1~2 do that. | |||
* Fix pixel rendering: 4mclk (realtime) | |||
* Sprite pixel rendering: 1mclk | |||
* LSPC runs at 24MHz, but generates signals on rising and falling edges ("48MHz") | |||
A single sprite line (16 pixels) '''always''' takes 16mclk, whatever the zoom value or the amount of transparent pixels. | |||
It can also be observed that there's always 96 pulses on LD* during rendering, since 1536mclk per line / 16mclk per sprite = 96 sprites max per line. | It can also be observed that there's always 96 pulses on LD* during rendering, since 1536mclk per line / 16mclk per sprite = 96 sprites max per line. | ||
* The rising edge of PCK1 and PCK2 | * The rising edge of PCK1 and PCK2 latches fix or sprite pixels from the cart ROMs. | ||
* 1H1 is probably used to split pixels of FIXD between left and right. | * 1H1 is probably used to split pixels of FIXD between left and right. | ||
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To do: Edit waveforms, FP and SP windows of the P BUS start 0.5mclk earlier (1.5,5,1.5,1.5,5,1.5 = 16). | To do: Edit waveforms, FP and SP windows of the P BUS start 0.5mclk earlier (1.5,5,1.5,1.5,5,1.5 = 16). | ||
* Fast VRAM is 35ns (<1mclk), slow VRAM is 100ns (<2.5mclk) | |||
*Fast VRAM is 35ns (<1mclk), slow VRAM is 100ns (<2.5mclk | * The fast VRAM reads always occur 1mclk (41.6ns) after the address is set. Smallest access window is 1.5mclk. | ||
*The fast VRAM reads always occur 1mclk (41.6ns) after address is set. Smallest access window is 1.5mclk. | |||
[[file:timing_gpu1.png]] | [[file:timing_gpu1.png]] | ||
*FIXT: P23~16 is 0, P15~0 is S ROM address (+ external 2H1) | * FIXT: P23~16 is 0, P15~0 is S ROM address (+ external 2H1) | ||
*SPRT: P23~0 is C ROM address (+ external CA4) | * SPRT: P23~0 is C ROM address (+ external CA4) | ||
*LO: P23~16 is [[LO]] ROM data, P15~0 is LO address | * LO: P23~16 is [[LO]] ROM data, P15~0 is LO address | ||
*FP: P19~16 is the fix tile palette, rest is 0 | * FP: P19~16 is the fix tile palette, rest is 0 | ||
*SP: P23~16 is the sprite tile palette, P15~8 is X position, P7~0 is ? | * SP: P23~16 is the sprite tile palette, P15~8 is X position, P7~0 is ? | ||
*LSPC always starts filling up active sprite list A ($8600) each new frame | * LSPC always starts filling up the active sprite list A ($8600) each new frame. | ||
Read sequence: | Read sequence: | ||
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10 states in 16 cycles (or 5 in 8 cycles: 4-3-3-3-3). | 10 states in 16 cycles (or 5 in 8 cycles: 4-3-3-3-3). | ||
One scanline | One scanline lasts 1536mclk cycles = 96 sequences of 16mclk cycles. | ||
Half of the mclk cycles are reserved for sprite Y parsing, the other half is for sprite rendering and CPU access. | |||
==Parsing== | |||
SCB3 (Y) is read (from fast VRAM $8200 to $8380). Each time there is a scanline match, a write state to the active sprite list is inserted (apparently 2 states after the corresponding SCB3 read). | |||
SCB3 is read (from $ | |||
Once SCB3 address $ | Once SCB3 address $8380 is reached, only $0000 writes to the sprite list are done (in order to fill the rest of the sprite list with zeros). | ||
No matter how many sprites are matched in the scanline, | No matter how many sprites are matched in the scanline, there will always be 384 SCB3 read states and 96 sprite list write states. | ||
This explains why sprite #0 cannot be used: this is the value used to pad the sprite list. If the list isn't filled (like most of the time), the sprite #0 i rendered over and over again until the end is reached. | |||
==Rendering== | |||
The state order is : | The state order is : | ||
*1: Read sprite list ($ | *1: Read sprite list ($8600+/$8680+) to get sprite # | ||
*2: Read SCB2 zoom values ($ | *2: Read SCB2 zoom values ($8000+) | ||
*3: Read SCB3 Y pos/size/sticky ($ | *3: Read SCB3 Y pos/size/sticky ($8200+), Y pos ignored in this state ? | ||
*4: Read SCB4 X pos ($ | *4: Read SCB4 X pos ($8400+) | ||
*5: Read/write from CPU | *5: Read/write from CPU if needed | ||
CPU access to | ==CPU access to fast VRAM== | ||
SNK says min. 12 68kclk between writes (so 24mclk). 1 write every 24mclk = 64 per scanline. | SNK says min. 12 68kclk between writes (so 24mclk). 1 write every 24mclk = 64 per scanline. | ||
Why 12 and not 8 ? | Why 12 and not 8 ? | ||
CPU access during state #5 occurs asynchronously with the 68000 bus -> storage in LSPC. | |||
My guess on the HW implementation is that during state #5, the GPU always reads the memory content pointed by REG_VRAMADDR and updates the read latch of REG_VRAMRW. | My guess on the HW implementation is that during state #5, the GPU always reads the memory content pointed by REG_VRAMADDR and updates the read latch of REG_VRAMRW. | ||
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*Available CPU R/W slots depending on parsing progress, safest is ? cycles | *Available CPU R/W slots depending on parsing progress, safest is ? cycles | ||
== | ==CPU access to slow VRAM== | ||
*Slow VRAM is 100ns | * Slow VRAM is 100ns | ||
*4 slots per render cycle, 1 slot for CPU R/W (1 each 16 68k cycles) | * 4 slots per render cycle, 1 slot for CPU R/W (1 each 16 68k cycles) | ||
[[Category:Video system]] | [[Category:Video system]] |
Revision as of 21:28, 10 May 2017
On the NeoGeo hardware, the GPU (Graphics Processing Unit) a.k.a. VDP, may refer to a chip or a group of different chips used to generate the video signal.
- LSPC-A0, PRO-B0 (early)
- LSPC2-A2, NEO-B1 (most common)
- NEO-GRC, NEO-OFC (CD systems)
- NEO-GRZ (CDZ, MV-1C ?)
See graphics pipeline for an overview of the interconnections between chips and cartridges.
Graphics fetch
Tile pixel lines are rendered in halves.
Fix tiles
32mclk = 8 pixels, 2 pixels per read.
- S1 ROM address is ...1**** (PCK2 pulse)
- 2H1 is 0 for 2 pixels (columns 0 & 1)
- Then 1 for 2 pixels (columns 2 & 3)
- S1 ROM address is ...0**** (PCK2 pulse)
- 2H1 is 0 for 2 pixels (columns 4 & 5)
- Then 1 for 2 pixels (columns 6 & 7)
Sprite tiles
16mclk = 16 pixels, 8 pixels per read.
- C ROM address is ...1***** (PCK1 pulse) (columns 0~7)
- C ROM address is ...0***** (PCK1 pulse) (columns 8~15)
CA4 is used to select upper/lower tiles (see Sprite graphics format).
Video generation
See Display timing for the sync signal's timing.
NEO-B1 is used for double-buffering scanlines. While a buffer is output to the screen, the other one is filled up. They're swapped each new scanline. Each of the two line buffers are actually 2 buffers of even/odd pixels. They will be named (1 & 2), and (3 & 4).
CSK signals
CSK1~4 signals are used to clock each buffer (on rising edge ?).
During rendering, the pulses usually go by pairs (1+2 and 3+4) to render pixels 2 by 2. Horizontal scaling cause CSK pulses to be skipped.
During output, the pulses are synchronized and alternative (1+2 then 3+4 then 1+2...) to output even/odd pixels in sequence.
- If the corresponding LD* signal is high, then the buffer pointer is incremented (rendering is always done left to right ?).
- If the corresponding LD* signal is low, then the buffer pointer is loaded from the P bus (X position of sprite, or 0 to start line output).
Inactive during H-blank.
LD signals
The LD1~2 signals sets the X position in B1. It is /2, since it is set in both even and odd buffers.
Example P bus data for 20 sprites right next to each other (X+=16px):
0000,0808,1010,1838,2000,2808,3010,3838,40C0,48E8,50F0,58F8,60C0,68E8,70F0,78F8,8000,8808,9010,9838,0,0,0...
The lower byte might just be garbage ignored by B1.
WSE signals
WSE1~4 signals are used to indicate if the pixel color index on GAD/GBD needs to be written to the buffer.
During rendering, the pulses are synchronized to CSK signals.
- If the pixel is transparent, there is a CSK pulse but no WSE pulse.
- If the pixel is opaque, there are both pulses at the same time.
- If the pixel is skipped for horizontal reduction, there are no pulses at all.
During output, the pulses are also synchronized to CSK signals and always present. This is used to clear to the backdrop color for the next rendering cycle.
The buffer's /WE signals seems to be (CSK & WSE).
SS signals
The complementary pair of SS* signals from LSPC tell B1 how the buffers are used:
- SS1 low & SS2 high: Buffers 1&2 are written to. Buffers 3&4 are output to the TV.
- SS1 high & SS2 low: Buffers 1&2 are output to the TV. Buffers 3&4 are written to.
Notes
- What's the use of TMS0 ? Not buffer flip, SS1~2 do that.
- Fix pixel rendering: 4mclk (realtime)
- Sprite pixel rendering: 1mclk
- LSPC runs at 24MHz, but generates signals on rising and falling edges ("48MHz")
A single sprite line (16 pixels) always takes 16mclk, whatever the zoom value or the amount of transparent pixels.
It can also be observed that there's always 96 pulses on LD* during rendering, since 1536mclk per line / 16mclk per sprite = 96 sprites max per line.
- The rising edge of PCK1 and PCK2 latches fix or sprite pixels from the cart ROMs.
- 1H1 is probably used to split pixels of FIXD between left and right.
Fix data is read 8 pixels in advance (confirms what Charles wrote in mvstech.txt). This seems to be inherited from the Alpha68k as 3 successive 8bit registers forming a waiting "pipeline".
Sprite parsing
This is a draft. The following information shouldn't be considered as exact.
To do: Edit waveforms, FP and SP windows of the P BUS start 0.5mclk earlier (1.5,5,1.5,1.5,5,1.5 = 16).
- Fast VRAM is 35ns (<1mclk), slow VRAM is 100ns (<2.5mclk)
- The fast VRAM reads always occur 1mclk (41.6ns) after the address is set. Smallest access window is 1.5mclk.
- FIXT: P23~16 is 0, P15~0 is S ROM address (+ external 2H1)
- SPRT: P23~0 is C ROM address (+ external CA4)
- LO: P23~16 is LO ROM data, P15~0 is LO address
- FP: P19~16 is the fix tile palette, rest is 0
- SP: P23~16 is the sprite tile palette, P15~8 is X position, P7~0 is ?
- LSPC always starts filling up the active sprite list A ($8600) each new frame.
Read sequence:
Timing diagram when no sprites fall in the next scanline (no writes to sprite list):
Parse ################################ ################################ Render ########################## ########################## 24M |'|_|'|_|'|_|'|_|'|_|'|_|'|_|'|_|'|_|'|_|'|_|'|_|'|_|'|_|'|_|'|_|'|_|'|_|'|_|'|_|'|_|'|_|'|_|'|_|'|_|'|_|'|_|'|_|'|_|'|_|'|_|'|_ Addr | 600 | 200 | 201 | 202 | 203 | 204 | 681 | 00E | 20E | 40E | 600 | 205 | 206 | 207 | 208 | 209 | 682 | 00F | 20F | 40F PCK1 ______|'''|___________________________________________________________|'''|_____________________________________________________ PCK1B '''''''|____|''''''''''''''''''''''''''''''''''''''''''''''''''''''''''|___|'''''''''''''''''''''''''''''''''''''''''''''''''''' LOAD |'''''''|_______________________|'''''''|_______________________|'''''''|_______________________|'''''''|_______________________ 12M __|'''|___|'''|___|'''|___|'''|___|'''|___|'''|___|'''|___|'''|___|'''|___|'''|___|'''|___|'''|___|'''|___|'''|___|'''|___|'''|_ 2Pixel | | | | | | | | | | | | | | | | Read ? ! ! ! ! ! ! ! ! ! ? ! ! ! ! ! ! ! ! ! What 1 2 2 2 2 2 3 4 5 6 1 2 2 2 2 2 3 4 5 6...
- 1: Probably CPU acces slot with last address latched ($600)
- 2: Read sprite Y position from SCB3 ($200+) to see if it's in next scanline
- 3: Read sprite list ($600+) to get sprite #
- 4: Read SCB2 zoom values ($000+)
- 5: Read SCB3 Y/size/chain ($200+)
- 6: Read SCB4 X ($400+)
10 states in 16 cycles (or 5 in 8 cycles: 4-3-3-3-3).
One scanline lasts 1536mclk cycles = 96 sequences of 16mclk cycles.
Half of the mclk cycles are reserved for sprite Y parsing, the other half is for sprite rendering and CPU access.
Parsing
SCB3 (Y) is read (from fast VRAM $8200 to $8380). Each time there is a scanline match, a write state to the active sprite list is inserted (apparently 2 states after the corresponding SCB3 read).
Once SCB3 address $8380 is reached, only $0000 writes to the sprite list are done (in order to fill the rest of the sprite list with zeros).
No matter how many sprites are matched in the scanline, there will always be 384 SCB3 read states and 96 sprite list write states.
This explains why sprite #0 cannot be used: this is the value used to pad the sprite list. If the list isn't filled (like most of the time), the sprite #0 i rendered over and over again until the end is reached.
Rendering
The state order is :
- 1: Read sprite list ($8600+/$8680+) to get sprite #
- 2: Read SCB2 zoom values ($8000+)
- 3: Read SCB3 Y pos/size/sticky ($8200+), Y pos ignored in this state ?
- 4: Read SCB4 X pos ($8400+)
- 5: Read/write from CPU if needed
CPU access to fast VRAM
SNK says min. 12 68kclk between writes (so 24mclk). 1 write every 24mclk = 64 per scanline.
Why 12 and not 8 ?
CPU access during state #5 occurs asynchronously with the 68000 bus -> storage in LSPC.
My guess on the HW implementation is that during state #5, the GPU always reads the memory content pointed by REG_VRAMADDR and updates the read latch of REG_VRAMRW.
If write latch REG_VRAMRW is written by the 68000, the next state #5 becomes a write access and REG_VRAMADDR is incremented by REG_VRAMMOD value.
Even if a theoretical limit of 16mclk or 8 68kclk is possible, some additionnal cycles are needed for the address and data to propagate through the chip.
Or maybe SNK has given the worst case scenario between slow Low VRAM and fast High VRAM ?
Timing diagram when the sprite list is being filled:
+5/8: 0 5 2 7 4 1 6 3 | | | | | 5 2 7 4 1 6 3 0 | | | | | 0 1 2 3 4 5 6 7 8 9 A B C D E F | | | | | LLLLLLLLHHHHHHHHLLLLHHHHHHHHLLLL HHHHHHLLLLLLLLHHHHLLLLLLLLHHHLLL 0 1 2 3 4 5 6 7 8 9 A B C D E F | | | | | Parse ################################ ################################ Render ########################## ########################## 24M |'|_|'|_|'|_|'|_|'|_|'|_|'|_|'|_|'|_|'|_|'|_|'|_|'|_|'|_|'|_|'|_|'|_|'|_|'|_|'|_|'|_|'|_|'|_|'|_|'|_|'|_|'|_|'|_|'|_|'|_|'|_|'|_ Addr | 600 | 20F | 210 | 211 | 600 | 601 | 684 | 005 | 205 | 405 | 600 | 212 | 213 | 602 | 603 | 214 | 685 | 006 | 206 | 406 PCK1 ______|'''|___________________________________________________________|'''|_____________________________________________________ PCK1B '''''''|___|'''''''''''''''''''''''''''''''''''''''''''''''''''''''''''|___|'''''''''''''''''''''''''''''''''''''''''''''''''''' LOAD |'''''''|_______________________|'''''''|_______________________|'''''''|_______________________|'''''''|_______________________ 12M __|'''|___|'''|___|'''|___|'''|___|'''|___|'''|___|'''|___|'''|___|'''|___|'''|___|'''|___|'''|___|'''|___|'''|___|'''|___|'''|_ 2Pixel | | | | | | | | | | | | | | | | /WE ''''''''''''''''''''''''''|___|'|___|'''''''''''''''''''''''''''''''''''''''''''''''|___|'|___|''''''''''''''''''''''''''''''''' Read ? ! ! ! ! ! ! ! ? ! ! ! ! ! ! !
- R/W sequences: (2 write buffers ?)
- 600 RRRWW... 600 RRWWR...
- 600 WWRRW... 600 WRRWW... 600 RRWWR ... 600 RWWRR
- Even lines: Write to list A, Read from list B (Start of display)
- Odd lines: Write to list B, Read from list A
- In 16clk, 2 sprites SCB3 max. are checked to fill up sprite list , and 1 sprite's attributes are read for output
- 384px * 4clk/px = 1536clk/line
- 1536clk / 16clk = 96 sprites max/line
- Available CPU R/W slots depending on parsing progress, safest is ? cycles
CPU access to slow VRAM
- Slow VRAM is 100ns
- 4 slots per render cycle, 1 slot for CPU R/W (1 each 16 68k cycles)