PPU palettes: Difference between revisions
(Make description a bit less awkward. (It's still pretty awkward though.)) |
(The background palette "hack" is an intentional feature of the PPU) |
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== The background palette hack == | == The background palette hack == | ||
When rendering is ''completely'' disabled in PPUMASK (both background and sprite rendering disabled) and the current VRAM address points in the range $3F00-$3FFF, the color indicated by this palette location will be shown on screen instead of the backdrop color. This can be used to display colors from the normally unused $3F04/$3F08/$3F0C palette locations. | When rendering is ''completely'' disabled in PPUMASK (both background and sprite rendering disabled) and the current VRAM address points in the range $3F00-$3FFF, the color indicated by this palette location will be shown on screen instead of the backdrop color (looking at the relevant circuitry in [[Visual 2C02]], this is an intentional feature of the PPU and not merely a side effect of how rendering works). This can be used to display colors from the normally unused $3F04/$3F08/$3F0C palette locations. | ||
A loop that fills the palette will cause each color in turn to be shown on the screen, so to avoid horizontal rainbow bar glitches while loading the palette, wait for a real vertical blank first using an [[NMI]] technique. | A loop that fills the palette will cause each color in turn to be shown on the screen, so to avoid horizontal rainbow bar glitches while loading the palette, wait for a real vertical blank first using an [[NMI]] technique. |
Revision as of 14:45, 1 July 2013
The palette for the background runs from VRAM $3F00 to $3F0F; the palette for the sprites runs from $3F10 to $3F1F. Each color takes up one byte.
$3F00 | Universal background color |
$3F01-$3F03 | Background palette 0 |
$3F05-$3F07 | Background palette 1 |
$3F09-$3F0B | Background palette 2 |
$3F0D-$3F0F | Background palette 3 |
$3F11-$3F13 | Sprite palette 0 |
$3F15-$3F17 | Sprite palette 1 |
$3F19-$3F1B | Sprite palette 2 |
$3F1D-$3F1F | Sprite palette 3 |
Each palette has three colors. Each 16x16 pixel area of the background can use the backdrop color and the three colors from one of the four background palettes. The choice of palette for each 16x16 pixel area is controlled by bits in the attribute table at the end of each nametable. Each sprite can use the three colors from one of the sprite palettes. The choice of palette is in attribute 2 of each sprite (see PPU OAM).
Addresses $3F04/$3F08/$3F0C can contain unique data, though these values are not used by the PPU when normally rendering (since the pattern values that would otherwise select those cells select the background color instead). They can still be shown using the background palette hack, explained below.
Addresses $3F10/$3F14/$3F18/$3F1C are mirrors of $3F00/$3F04/$3F08/$3F0C. Note that this goes for writing as well as reading; a symptom of not having implemented this correctly in an emulator is the sky being black in Super Mario Bros (as it writes the background color palette entry through the mirror).
Another way of looking at it:
43210 ||||| |||++- Pixel value from tile data |++--- Palette number from attribute table or OAM +----- Background/Sprite select
Like most early color game consoles, the NES palette is based on Hue/Saturation/Value
76543210 |||||||| ||||++++- Hue (phase) ||++----- Value (voltage) ++------- Unimplemented, reads back as 0
Hue $0 is light gray, $1-$C are blue to red to green to cyan, $D is dark gray, and $E-$F are black. The canonical code for "black" is $0F or $1D. $0D should not be used; it results in a "blacker than black" signal that may cause problems for some TVs. It works this way because of the way colors are represented in an NTSC or PAL signal, with the phase of a color subcarrier controlling the hue. For details, see NTSC video.
Note that most VS Unisystem arcade PPUs have completely different palettes, and Playchoice-10 PPUs render hue $D as black.
Backdrop color (palette index 0) uses
Provided rendering hasn't been completely disabled (i.e., either background or sprite rendering is enabled in PPUMASK ($2001)), the backdrop color will be used when background rendering is disabled, and also for the leftmost 8 pixels of the background when those are hidden via PPUMASK.
Internally, disabling either background or sprite rendering (but not both) causes 0 to be used as the palette index for the corresponding background and sprite pixels, but does not affect the PPU VRAM access pattern.
The background palette hack
When rendering is completely disabled in PPUMASK (both background and sprite rendering disabled) and the current VRAM address points in the range $3F00-$3FFF, the color indicated by this palette location will be shown on screen instead of the backdrop color (looking at the relevant circuitry in Visual 2C02, this is an intentional feature of the PPU and not merely a side effect of how rendering works). This can be used to display colors from the normally unused $3F04/$3F08/$3F0C palette locations. A loop that fills the palette will cause each color in turn to be shown on the screen, so to avoid horizontal rainbow bar glitches while loading the palette, wait for a real vertical blank first using an NMI technique.