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418 lines
14 KiB
Markdown
418 lines
14 KiB
Markdown
# Regular Objects
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As with backgrounds, objects can be used in both an affine and non-affine way.
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For this section we'll focus on the non-affine elements, and then we'll do all
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the affine stuff in a later chapter.
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## Objects vs Sprites
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As [TONC](https://www.coranac.com/tonc/text/regobj.htm) helpfully reminds us
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(and then proceeds to not follow its own advice), we should always try to think
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in terms of _objects_, not _sprites_. A sprite is a logical / software concern,
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perhaps a player concern, whereas an object is a hardware concern.
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What's more, a given sprite that the player sees might need more than one object
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to display. Objects must be either square or rectangular (so sprite bits that
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stick out probably call for a second object), and can only be from 8x8 to 64x64
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(so anything bigger has to be two objects lined up to appear as one).
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## General Object Info
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Unlike with backgrounds, you can enable the object layer in any video mode.
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There's space for 128 object definitions in OAM.
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The display gets a number of cycles per scanline to process objects: 1210 by
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default, but only 954 if you enable the "HBlank interval free" setting in the
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display control register. The [cycle cost per
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object](http://problemkaputt.de/gbatek.htm#lcdobjoverview) depends on the
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object's size and if it's using affine or regular mode, so enabling the HBlank
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interval free setting doesn't cut the number of objects displayable by an exact
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number of objects. The objects are processed in order of their definitions and
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if you run out of cycles then the rest just don't get shown. If there's a
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concern that you might run out of cycles you can place important objects (such
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as the player) at the start of the list and then less important animation
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objects later on.
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## Ready the Palette
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Objects use the palette the same as the background does. The only difference is
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that the palette data for objects starts at `0x500_0200`.
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```rust
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pub const PALRAM_OBJECT_BASE: VolatilePtr<u16> = VolatilePtr(0x500_0200 as *mut u16);
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pub fn object_palette(slot: usize) -> u16 {
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assert!(slot < 256);
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unsafe { PALRAM_OBJECT_BASE.offset(slot as isize).read() }
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}
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pub fn set_object_palette(slot: usize, color: u16) {
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assert!(slot < 256);
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unsafe { PALRAM_OBJECT_BASE.offset(slot as isize).write(color) }
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}
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```
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## Ready the Tiles
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Objects, as with backgrounds, are composed of 8x8 tiles, and if you want
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something bigger than 8x8 you have to use more than one tile put together.
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Object tiles go into the final two charblocks of VRAM (indexes 4 and 5). Because
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there's only two of them, they are sometimes called the lower block
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(`0x601_0000`) and the higher/upper block (`0x601_4000`).
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Tile indexes for sprites always offset from the base of the lower block, and
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they always go 32 bytes at a time, regardless of if the object is set for 4bpp
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or 8bpp. From this we can determine that there's 512 tile slots in each of the
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two object charblocks. However, in video modes 3, 4, and 5 the space for the
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background cuts into the lower charblock, so you can only safely use the upper
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charblock.
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```rust
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pub fn obj_tile_4bpp(tile_index: usize) -> Tile4bpp {
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assert!(tile_index < 512);
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let address = VRAM + size_of::<Charblock4bpp>() * 4 + 32 * tile_index;
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unsafe { VolatilePtr(address as *mut Tile4bpp).read() }
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}
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pub fn set_obj_tile_4bpp(tile_index: usize, tile: Tile4bpp) {
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assert!(tile_index < 512);
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let address = VRAM + size_of::<Charblock4bpp>() * 4 + 32 * tile_index;
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unsafe { VolatilePtr(address as *mut Tile4bpp).write(tile) }
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}
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pub fn obj_tile_8bpp(tile_index: usize) -> Tile8bpp {
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assert!(tile_index < 512);
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let address = VRAM + size_of::<Charblock8bpp>() * 4 + 32 * tile_index;
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unsafe { VolatilePtr(address as *mut Tile8bpp).read() }
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}
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pub fn set_obj_tile_8bpp(tile_index: usize, tile: Tile8bpp) {
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assert!(tile_index < 512);
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let address = VRAM + size_of::<Charblock8bpp>() * 4 + 32 * tile_index;
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unsafe { VolatilePtr(address as *mut Tile8bpp).write(tile) }
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}
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```
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With backgrounds you picked every single tile individually with a bunch of
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screen entry values. Objects don't do that at all. Instead you pick a base tile,
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size, and shape, then it figures out the rest from there. However, you may
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recall back with the display control register something about an "object memory
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1d" bit. This is where that comes into play.
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* If object memory is set to be 2d (the default) then each charblock is treated
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as 32 tiles by 32 tiles square. Each object has a base tile and dimensions,
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and that just extracts directly from the charblock picture as if you were
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selecting an area. This mode probably makes for the easiest image editing.
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* If object memory is set to be 1d then the tiles are loaded sequentially from
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the starting point, enough to fill in the object's dimensions. This most
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probably makes it the easiest to program with about things, since programming
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languages are pretty good at 1d things.
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I'm not sure I explained that well, here's a picture:
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![2d1d-diagram](obj_memory_2d1d.jpg)
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In 2d mode, a new row of tiles starts every 32 tile indexes.
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Of course, the mode that you actually end up using is not particularly
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important, since it should be the job of your image conversion routine to get
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everything all lined up and into place anyway.
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## Set the Object Attributes
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The final step is to assign the correct attributes to an object. Each object has
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three `u16` values that make up its overall attributes.
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Before we go into the details, I want to bring up that the hardware will attempt
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to process every single object every single frame if the object layer is
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enabled, and also that all of the GBA's object memory is cleared to 0 at
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startup. Why do these two things matter right now? As you'll see in a second an
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"all zero" set of object attributes causes an 8x8 object to appear at 0,0 using
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object tile index 0. This is usually _not_ what you want your unused objects to
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do. When your game first starts you should take a moment to mark any objects you
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won't be using as objects to not render.
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### ObjectAttributes.attr0
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* 8 bits for row coordinate (marks the top of the sprite)
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* 2 bits for object rendering: 0 = Normal, 1 = Affine, 2 = Disabled, 3 = Affine with double rendering area
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* 2 bits for object mode: 0 = Normal, 1 = Alpha Blending, 2 = Object Window, 3 = Forbidden
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* 1 bit for mosaic enabled
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* 1 bit 8bpp color enabled
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* 2 bits for shape: 0 = Square, 1 = Horizontal, 2 = Vertical, 3 = Forbidden
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If an object is 128 pixels big at Y > 128 you'll get a strange looking result
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where it acts like Y > -128 and then displays partly off screen to the top.
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### ObjectAttributes.attr1
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* 9 bit for column coordinate (marks the left of the sprite)
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* Either:
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* 3 empty bits, 1 bit for horizontal flip, 1 bit for vertical flip (non-affine)
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* 5 bits for affine index (affine)
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* 2 bits for size.
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| Size | Square | Horizontal | Vertical|
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|:----:|:------:|:----------:|:-------:|
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| 0 | 8x8 | 16x8 | 8x16 |
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| 1 | 16x16 | 32x8 | 8x32 |
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| 2 | 32x32 | 32x16 | 16x32 |
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| 3 | 64x64 | 64x32 | 32x64 |
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### ObjectAttributes.attr2
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* 10 bits for the base tile index
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* 2 bits for priority
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* 4 bits for the palbank index (4bpp mode only, ignored in 8bpp)
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### ObjectAttributes summary
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So I said in the GBA memory mapping section that C people would tell you that
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the object attributes should look like this:
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```rust
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#[repr(C)]
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pub struct ObjectAttributes {
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attr0: u16,
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attr1: u16,
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attr2: u16,
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filler: i16,
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}
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```
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Except that:
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1) It's wasteful when we store object attributes on their own outside of OAM
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(which we definitely might want to do).
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2) In Rust we can't access just one field through a volatile pointer (our
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pointers aren't actually volatile to begin with, just the ops we do with them
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are). We have to read or write the whole pointer's value at a time.
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Similarly, we can't do things like `|=` and `&=` with volatile in Rust. So in
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rust we can't have a volatile pointer to an ObjectAttributes and then write
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to just the three "real" values and not touch the filler field. Having the
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filler value in there just means we have to dance around it more, not less.
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3) We want to newtype this whole thing to prevent accidental invalid states from
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being written into memory.
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So we will not be using that representation. At the same time we want to have no
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overhead, so we will stick to three `u16` values. We could newtype each
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individual field to be its own type (`ObjectAttributesAttr0` or something silly
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like that), since there aren't actual dependencies between two different fields
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such that a change in one can throw another into a forbidden state. The worst
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that can happen is if we disable or enable affine mode (`attr0`) it can change
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the meaning of `attr1`. The changed meaning isn't actually in invalid state
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though, so we _could_ make each field its own type if we wanted.
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However, when you think about it, I can't imagine a common situation where we do
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something like make an `attr0` value that we then want to save on its own and
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apply to several different `ObjectAttributes` that we make during a game. That
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just doesn't sound likely to me. So, we'll go the route where `ObjectAttributes`
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is just a big black box to the outside world and we don't need to think about
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the three fields internally as being separate.
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First we make it so that we can get and set object attributes from memory:
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```rust
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pub const OAM: usize = 0x700_0000;
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pub fn object_attributes(slot: usize) -> ObjectAttributes {
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assert!(slot < 128);
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let ptr = VolatilePtr((OAM + slot * (size_of::<u16>() * 4)) as *mut u16);
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unsafe {
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ObjectAttributes {
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attr0: ptr.read(),
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attr1: ptr.offset(1).read(),
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attr2: ptr.offset(2).read(),
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}
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}
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}
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pub fn set_object_attributes(slot: usize, obj: ObjectAttributes) {
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assert!(slot < 128);
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let ptr = VolatilePtr((OAM + slot * (size_of::<u16>() * 4)) as *mut u16);
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unsafe {
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ptr.write(obj.attr0);
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ptr.offset(1).write(obj.attr1);
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ptr.offset(2).write(obj.attr2);
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}
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}
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#[derive(Debug, Clone, Copy, Default)]
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pub struct ObjectAttributes {
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attr0: u16,
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attr1: u16,
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attr2: u16,
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}
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```
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Then we add a billion methods to the `ObjectAttributes` type so that we can
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actually set all the different values that we want to set.
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This code block is the last thing on this page so if you don't wanna scroll past
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the whole thing you can just go to the next page.
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```rust
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#[derive(Debug, Clone, Copy)]
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pub enum ObjectRenderMode {
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Normal,
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Affine,
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Disabled,
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DoubleAreaAffine,
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}
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#[derive(Debug, Clone, Copy)]
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pub enum ObjectMode {
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Normal,
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AlphaBlending,
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ObjectWindow,
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}
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#[derive(Debug, Clone, Copy)]
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pub enum ObjectShape {
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Square,
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Horizontal,
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Vertical,
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}
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#[derive(Debug, Clone, Copy)]
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pub enum ObjectOrientation {
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Normal,
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HFlip,
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VFlip,
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BothFlip,
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Affine(u8),
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}
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impl ObjectAttributes {
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pub fn row(&self) -> u16 {
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self.attr0 & 0b1111_1111
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}
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pub fn column(&self) -> u16 {
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self.attr1 & 0b1_1111_1111
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}
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pub fn rendering(&self) -> ObjectRenderMode {
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match (self.attr0 >> 8) & 0b11 {
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0 => ObjectRenderMode::Normal,
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1 => ObjectRenderMode::Affine,
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2 => ObjectRenderMode::Disabled,
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3 => ObjectRenderMode::DoubleAreaAffine,
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_ => unimplemented!(),
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}
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}
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pub fn mode(&self) -> ObjectMode {
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match (self.attr0 >> 0xA) & 0b11 {
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0 => ObjectMode::Normal,
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1 => ObjectMode::AlphaBlending,
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2 => ObjectMode::ObjectWindow,
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_ => unimplemented!(),
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}
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}
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pub fn mosaic(&self) -> bool {
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((self.attr0 << 3) as i16) < 0
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}
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pub fn two_fifty_six_colors(&self) -> bool {
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((self.attr0 << 2) as i16) < 0
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}
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pub fn shape(&self) -> ObjectShape {
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match (self.attr0 >> 0xE) & 0b11 {
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0 => ObjectShape::Square,
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1 => ObjectShape::Horizontal,
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2 => ObjectShape::Vertical,
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_ => unimplemented!(),
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}
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}
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pub fn orientation(&self) -> ObjectOrientation {
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if (self.attr0 >> 8) & 1 > 0 {
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ObjectOrientation::Affine((self.attr1 >> 9) as u8 & 0b1_1111)
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} else {
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match (self.attr1 >> 0xC) & 0b11 {
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0 => ObjectOrientation::Normal,
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1 => ObjectOrientation::HFlip,
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2 => ObjectOrientation::VFlip,
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3 => ObjectOrientation::BothFlip,
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_ => unimplemented!(),
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}
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}
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}
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pub fn size(&self) -> u16 {
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self.attr1 >> 0xE
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}
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pub fn tile_index(&self) -> u16 {
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self.attr2 & 0b11_1111_1111
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}
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pub fn priority(&self) -> u16 {
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self.attr2 >> 0xA
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}
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pub fn palbank(&self) -> u16 {
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self.attr2 >> 0xC
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}
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//
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pub fn set_row(&mut self, row: u16) {
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self.attr0 &= !0b1111_1111;
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self.attr0 |= row & 0b1111_1111;
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}
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pub fn set_column(&mut self, col: u16) {
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self.attr1 &= !0b1_1111_1111;
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self.attr2 |= col & 0b1_1111_1111;
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}
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pub fn set_rendering(&mut self, rendering: ObjectRenderMode) {
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const RENDERING_MASK: u16 = 0b11 << 8;
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self.attr0 &= !RENDERING_MASK;
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self.attr0 |= (rendering as u16) << 8;
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}
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pub fn set_mode(&mut self, mode: ObjectMode) {
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const MODE_MASK: u16 = 0b11 << 0xA;
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self.attr0 &= MODE_MASK;
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self.attr0 |= (mode as u16) << 0xA;
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}
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pub fn set_mosaic(&mut self, bit: bool) {
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const MOSAIC_BIT: u16 = 1 << 0xC;
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if bit {
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self.attr0 |= MOSAIC_BIT
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} else {
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self.attr0 &= !MOSAIC_BIT
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}
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}
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pub fn set_two_fifty_six_colors(&mut self, bit: bool) {
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const COLOR_MODE_BIT: u16 = 1 << 0xD;
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if bit {
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self.attr0 |= COLOR_MODE_BIT
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} else {
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self.attr0 &= !COLOR_MODE_BIT
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}
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}
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pub fn set_shape(&mut self, shape: ObjectShape) {
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self.attr0 &= 0b0011_1111_1111_1111;
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self.attr0 |= (shape as u16) << 0xE;
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}
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pub fn set_orientation(&mut self, orientation: ObjectOrientation) {
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const AFFINE_INDEX_MASK: u16 = 0b1_1111 << 9;
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self.attr1 &= !AFFINE_INDEX_MASK;
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let bits = match orientation {
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ObjectOrientation::Affine(index) => (index as u16) << 9,
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ObjectOrientation::Normal => 0,
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ObjectOrientation::HFlip => 1 << 0xC,
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ObjectOrientation::VFlip => 1 << 0xD,
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ObjectOrientation::BothFlip => 0b11 << 0xC,
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};
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self.attr1 |= bits;
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}
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pub fn set_size(&mut self, size: u16) {
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self.attr1 &= 0b0011_1111_1111_1111;
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self.attr1 |= size << 14;
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}
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pub fn set_tile_index(&mut self, index: u16) {
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self.attr2 &= !0b11_1111_1111;
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self.attr2 |= 0b11_1111_1111 & index;
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}
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pub fn set_priority(&mut self, priority: u16) {
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self.attr2 &= !0b0000_1100_0000_0000;
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self.attr2 |= (priority & 0b11) << 0xA;
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}
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pub fn set_palbank(&mut self, palbank: u16) {
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self.attr2 &= !0b1111_0000_0000_0000;
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self.attr2 |= (palbank & 0b1111) << 0xC;
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}
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}
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```
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