chore: add test for RingBuffer

tmp: removed audio resampler
feat(util): implement RingBuffer
2022-12-10 01:02:59 -04:00 · 2022-12-09 22:16:51 -04:00 · 2022-12-09 22:16:51 -04:00 · 2022-12-05 11:08:04 -04:00 · 2022-12-01 13:23:09 -04:00 · 2022-11-30 00:42:20 -04:00
62 changed files with 10370 additions and 3561 deletions
--- a/.github/workflows/main.yml
+++ b/.github/workflows/main.yml
@@ -0,0 +1,58 @@
 name: Nightly
 on:
  push:
    paths:
      - "**.zig"
    branches:
      - main
  schedule:
    - cron: '0 0 * * *'
  workflow_dispatch:
 jobs:
  build:
    strategy:
      matrix:
        os: [ubuntu-latest, windows-latest, macos-latest]
    runs-on: ${{matrix.os}}
    steps:
      - uses: goto-bus-stop/setup-zig@v2
        with:
          version: master
      - name: prepare-linux
        if: runner.os == 'Linux'
        run: |
            sudo apt-get update
            sudo apt-get install libsdl2-dev
      - name: prepare-windows
        if: runner.os == 'Windows'
        run: |
            vcpkg integrate install
            vcpkg install sdl2:x64-windows
            git config --global core.autocrlf false
      - name: prepare-macos
        if: runner.os == 'macOS'
        run: |
            brew install sdl2
      - uses: actions/checkout@v3
        with:
          submodules: true
      - name: build 
        run: zig build -Drelease-safe
      - name: upload
        uses: actions/upload-artifact@v3
        with:
          name: zba-${{matrix.os}}
          path: zig-out/bin
  lint:
    runs-on: ubuntu-latest
    steps: 
      - uses: actions/checkout@v3
        with:
          submodules: true
      - uses: goto-bus-stop/setup-zig@v2
        with:
          version: master
      - run: zig fmt src/**/*.zig
--- a/.gitignore
+++ b/.gitignore
@@ -1,7 +1,7 @@
 /.vscode
 /bin
-/zig-cache
+**/zig-cache
-/zig-out
+**/zig-out
 /docs
 **/*.log
 **/*.bin
--- a/.gitmodules
+++ b/.gitmodules
@@ -7,3 +7,9 @@
 [submodule "lib/known-folders"]
 	path = lib/known-folders
 	url = https://github.com/ziglibs/known-folders
 [submodule "lib/zig-datetime"]
 	path = lib/zig-datetime
 	url = https://github.com/frmdstryr/zig-datetime
 [submodule "lib/zig-toml"]
 	path = lib/zig-toml
 	url = https://github.com/aeronavery/zig-toml
--- a/README.md
+++ b/README.md
@@ -1,64 +1,110 @@
 # ZBA (working title)
-An in-progress Gameboy Advance Emulator written in Zig ⚡!
+
 A Game Boy Advance Emulator written in Zig ⚡!
 ## Scope
 I'm hardly the first to write a Game Boy Advance Emulator nor will I be the last. This project isn't going to compete with the GOATs like [mGBA](https://github.com/mgba-emu) or [NanoBoyAdvance](https://github.com/nba-emu/NanoBoyAdvance). There aren't any interesting ideas either like in [DSHBA](https://github.com/DenSinH/DSHBA).
 This is a simple (read: incomplete) for-fun long-term project. I hope to get "mostly there", which to me means that I'm not missing any major hardware features and the set of possible improvements would be in memory timing or in UI/UX. With respect to that goal, here's what's outstanding:
 ### TODO
 - [ ] Affine Sprites
 - [ ] Windowing (see [this branch](https://git.musuka.dev/paoda/zba/src/branch/window))
 - [ ] Audio Resampler (Having issues with SDL2's)
 - [ ] Immediate Mode GUI
 - [ ] Refactoring for easy-ish perf boosts
 ## Usage
 As it currently exists, ZBA is run from the terminal. In your console of choice, type `./zba --help` to see what you can do.
 I typically find myself typing `./zba -b ./bin/bios.bin ./bin/test/suite.gba` to see how badly my "cool new feature" broke everything else.
 Need a BIOS? Why not try using the open-source [Cult-Of-GBA BIOS](https://github.com/Cult-of-GBA/BIOS) written by [fleroviux](https://github.com/fleroviux) and [DenSinH](https://github.com/DenSinH)?
 Finally it's worth noting that ZBA uses a TOML config file it'll store in your OS's data directory. See `example.toml` to learn about the defaults and what exactly you can mess around with.
 ## Tests
- [ ] [jsmolka's GBA Test Collection](https://github.com/jsmolka/gba-tests)
+
-    - [x] `arm.gba` and `thumb.gba`
+GBA Tests | [jsmolka](https://github.com/jsmolka/)
-    - [x] `flash64.gba`, `flash128.gba`, `none.gba`, and `sram.gba`
+--- | ---
-    - [x] `hello.gba`, `shades.gba`, and `stripes.gba`
+`arm.gba`,  `thumb.gba` | PASS
-    - [x] `memory.gba`
+`memory.gba`, `bios.gba` | PASS
-    - [x] `bios.gba`
+`flash64.gba`, `flash128.gba` | PASS
-    - [ ] `nes.gba`
+`sram.gba` | PASS
- [ ] [DenSinH's GBA ROMs](https://github.com/DenSinH/GBARoms)
+`none.gba` | PASS
-    - [x] `eeprom-test`
+`hello.gba`, `shades.gba`, `stripes.gba` | PASS
-    - [x] `flash-test`
+`nes.gba` | PASS
-    - [x] `midikey2freq`
+
-    - [ ] `swi-tests-random`
+GBARoms | [DenSinH](https://github.com/DenSinH/)
- [ ] [destoer's GBA Tests](https://github.com/destoer/gba_tests)
+--- | ---
-    - [x] `cond_invalid.gba`
+`eeprom-test`, `flash-test` | PASS
-    - [x] `dma_priority.gba`
+`midikey2freq` | PASS
-    - [x] `hello_world.gba`
+`swi-tests-random` | FAIL
-    - [x] `if_ack.gba`
+
-    - [ ] `line_timing.gba`
+gba_tests | [destoer](https://github.com/destoer/)
-    - [ ] `lyc_midline.gba`
+--- | ---
-    - [ ] `window_midframe.gba`
+`cond_invalid.gba` | PASS
- [x] [ladystarbreeze's GBA Test Collection](https://github.com/ladystarbreeze/GBA-Test-Collection)
+`dma_priority.gba` | PASS
-    - [x] `retAddr.gba`
+`hello_world.gba` | PASS
-    - [x] `helloWorld.gba`
+`if_ack.gba` | PASS
-    - [x] `helloAudio.gba`
+`line_timing.gba` | FAIL
- [x] [`armwrestler-gba-fixed.gba`](https://github.com/destoer/armwrestler-gba-fixed)
+`lyc_midline.gba` | FAIL
- [x] [FuzzARM](https://github.com/DenSinH/FuzzARM)
+`window_midframe.gba` | FAIL
 GBA Test Collection | [ladystarbreeze](https://github.com/ladystarbreeze)
 --- | ---
 `retAddr.gba` | PASS
 `helloWorld.gba` | PASS
 `helloAudio.gba` | PASS
 FuzzARM | [DenSinH](https://github.com/DenSinH/)
 --- | ---
 `main.gba` | PASS
 arm7wrestler GBA Fixed | [destoer](https://github.com/destoer)
 --- | ---
 `armwrestler-gba-fixed.gba` | PASS
 ## Resources
-* [GBATEK](https://problemkaputt.de/gbatek.htm)
+
-* [TONC](https://coranac.com/tonc/text/toc.htm)
+- [GBATEK](https://problemkaputt.de/gbatek.htm)
-* [ARM Architecture Reference Manual](https://www.intel.com/content/dam/www/programmable/us/en/pdfs/literature/third-party/ddi0100e_arm_arm.pdf)
+- [TONC](https://coranac.com/tonc/text/toc.htm)
-* [ARM7TDMI Data Sheet](https://www.dca.fee.unicamp.br/cursos/EA871/references/ARM/ARM7TDMIDataSheet.pdf)
+- [ARM Architecture Reference Manual](https://www.intel.com/content/dam/www/programmable/us/en/pdfs/literature/third-party/ddi0100e_arm_arm.pdf)
 - [ARM7TDMI Data Sheet](https://www.dca.fee.unicamp.br/cursos/EA871/references/ARM/ARM7TDMIDataSheet.pdf)
 ## Compiling
-Most recently built on Zig [0.10.0-dev.2978+803376708](https://github.com/ziglang/zig/tree/803376708)
+
 Most recently built on Zig [0.11.0-dev.368+1829b6eab](https://github.com/ziglang/zig/tree/1829b6eab)
 ### Dependencies
 * [SDL.zig](https://github.com/MasterQ32/SDL.zig)
    * [SDL2](https://www.libsdl.org/download-2.0.php)
 * [zig-clap](https://github.com/Hejsil/zig-clap)
 * [known-folders](https://github.com/ziglibs/known-folders)
 * [`bitfields.zig`](https://github.com/FlorenceOS/Florence/blob/f6044db788d35d43d66c1d7e58ef1e3c79f10d6f/lib/util/bitfields.zig)
-`bitfields.zig` from [FlorenceOS](https://github.com/FlorenceOS) is included under `lib/util/bitfield.zig`.
+Dependency | Source
 --- | ---
 SDL.zig | <https://github.com/MasterQ32/SDL.zig>
 zig-clap | <https://github.com/Hejsil/zig-clap>
 known-folders | <https://github.com/ziglibs/known-folders>
 zig-toml | <https://github.com/aeronavery/zig-toml>
 zig-datetime | <https://github.com/frmdstryr/zig-datetime>
 `bitfields.zig` | [https://github.com/FlorenceOS/Florence](https://github.com/FlorenceOS/Florence/blob/aaa5a9e568/lib/util/bitfields.zig)
 `gl.zig` | <https://github.com/MasterQ32/zig-opengl>
-Use `git submodule update --init` from the project root to pull the git submodules `SDL.zig`, `zig-clap`, and `known-folders`
+Use `git submodule update --init` from the project root to pull the git submodules `SDL.zig`, `zig-clap`, `known-folders`, `zig-toml` and `zig-datetime`
 Be sure to provide SDL2 using:
-* Linux: Your distro's package manager
+
-* MacOS: ¯\\\_(ツ)_/¯
+- Linux: Your distro's package manager
-* Windows: [`vcpkg`](https://github.com/Microsoft/vcpkg) (install `sdl2:x64-windows`)
+- MacOS: ¯\\\_(ツ)_/¯
 - Windows: [`vcpkg`](https://github.com/Microsoft/vcpkg) (install `sdl2:x64-windows`)
 `SDL.zig` will provide a helpful compile error if the zig compiler is unable to find SDL2.
 Once you've got all the dependencies, execute `zig build -Drelease-fast`. The executable is located at `zig-out/bin/`.
 ## Controls
 Key | Button
 --- | ---
 <kbd>X</kbd> | A
--- a/build.zig
+++ b/build.zig
@@ -1,7 +1,15 @@
 const std = @import("std");
 const builtin = @import("builtin");
 const Sdk = @import("lib/SDL.zig/Sdk.zig");
 pub fn build(b: *std.build.Builder) void {
    // Minimum Zig Version
    const min_ver = std.SemanticVersion.parse("0.11.0-dev.323+30eb2a175") catch return; // https://github.com/ziglang/zig/commit/30eb2a175
    if (builtin.zig_version.order(min_ver).compare(.lt)) {
        std.log.err("{s}", .{b.fmt("Zig v{} does not meet the minimum version requirement. (Zig v{})", .{ builtin.zig_version, min_ver })});
        std.os.exit(1);
    }
    // Standard target options allows the person running `zig build` to choose
    // what target to build for. Here we do not override the defaults, which
    // means any target is allowed, and the default is native. Other options
@@ -13,10 +21,15 @@ pub fn build(b: *std.build.Builder) void {
    const mode = b.standardReleaseOptions();
    const exe = b.addExecutable("zba", "src/main.zig");
    exe.setMainPkgPath("."); // Necessary so that src/main.zig can embed example.toml
    exe.setTarget(target);
    // Known Folders (%APPDATA%, XDG, etc.)
    exe.addPackagePath("known_folders", "lib/known-folders/known-folders.zig");
    // DateTime Library
    exe.addPackagePath("datetime", "lib/zig-datetime/src/main.zig");
    // Bitfield type from FlorenceOS: https://github.com/FlorenceOS/
    // exe.addPackage(.{ .name = "bitfield", .path = .{ .path = "lib/util/bitfield.zig" } });
    exe.addPackagePath("bitfield", "lib/util/bitfield.zig");
@@ -24,13 +37,17 @@ pub fn build(b: *std.build.Builder) void {
    // Argument Parsing Library
    exe.addPackagePath("clap", "lib/zig-clap/clap.zig");
    // TOML Library
    exe.addPackagePath("toml", "lib/zig-toml/src/toml.zig");
    // OpenGL 3.3 Bindings
    exe.addPackagePath("gl", "lib/gl.zig");
    // Zig SDL Bindings: https://github.com/MasterQ32/SDL.zig
    const sdk = Sdk.init(b);
    sdk.link(exe, .dynamic);
    exe.addPackage(sdk.getNativePackage("sdl2"));
    exe.setTarget(target);
    exe.setBuildMode(mode);
    exe.install();
--- a/example.toml
+++ b/example.toml
@@ -0,0 +1,25 @@
 [Host]
 # Using nearest-neighbour scaling, how many times the native resolution 
 # of the game bow should the screen be?
 win_scale = 3
 # Enable VSYNC on the UI thread
 vsync = true
 # Mute ZBA
 mute = false
 [Guest]
 # Sync Emulation to Audio 
 audio_sync = true
 # Sync Emulation to Video
 video_sync = true
 # Force RTC support
 force_rtc = false
 # Skip BIOS
 skip_bios = false
 [Debug]
 # Enable detailed CPU logs
 cpu_trace = false
 # When false and builtin.mode == .Debug, ZBA will panic
 # on unknown I/O reads
 unhandled_io = true
--- a/lib/SDL.zig
+++ b/lib/SDL.zig
--- a/lib/gl.zig
+++ b/lib/gl.zig
--- a/lib/util/bitfield.zig
+++ b/lib/util/bitfield.zig
@@ -14,7 +14,7 @@ fn PtrCastPreserveCV(comptime T: type, comptime PtrToT: type, comptime NewT: typ
 fn BitType(comptime FieldType: type, comptime ValueType: type, comptime shamt: usize) type {
    const self_bit: FieldType = (1 << shamt);
-    return struct {
+    return extern struct {
        bits: Bitfield(FieldType, shamt, 1),
        pub fn set(self: anytype) void {
@@ -63,7 +63,7 @@ pub fn Bitfield(comptime FieldType: type, comptime shamt: usize, comptime num_bi
    const ValueType = std.meta.Int(.unsigned, num_bits);
-    return struct {
+    return extern struct {
        dummy: FieldType,
        fn field(self: anytype) PtrCastPreserveCV(@This(), @TypeOf(self), FieldType) {
--- a/lib/zig-clap
+++ b/lib/zig-clap
--- a/lib/zig-datetime
+++ b/lib/zig-datetime
--- a/lib/zig-toml
+++ b/lib/zig-toml
--- a/src/Gui.zig
+++ b/src/Gui.zig
@@ -1,193 +0,0 @@
 const std = @import("std");
 const SDL = @import("sdl2");
 const Self = @This();
 const Apu = @import("core/apu.zig").Apu;
 const Arm7tdmi = @import("core/cpu.zig").Arm7tdmi;
 const Scheduler = @import("core/scheduler.zig").Scheduler;
 const FpsTracker = @import("core/util.zig").FpsTracker;
 const pitch = @import("core/ppu.zig").framebuf_pitch;
 const scale = @import("core/emu.zig").win_scale;
 const emu = @import("core/emu.zig");
 const asString = @import("core/util.zig").asString;
 const log = std.log.scoped(.GUI);
 const default_title: []const u8 = "ZBA";
 window: *SDL.SDL_Window,
 base_title: [12]u8,
 renderer: *SDL.SDL_Renderer,
 texture: *SDL.SDL_Texture,
 audio: ?Audio,
 pub fn init(title: [12]u8, width: i32, height: i32) Self {
    const ret = SDL.SDL_Init(SDL.SDL_INIT_VIDEO | SDL.SDL_INIT_EVENTS | SDL.SDL_INIT_AUDIO | SDL.SDL_INIT_GAMECONTROLLER);
    if (ret < 0) panic();
    const window = SDL.SDL_CreateWindow(
        default_title.ptr,
        SDL.SDL_WINDOWPOS_CENTERED,
        SDL.SDL_WINDOWPOS_CENTERED,
        @as(c_int, width * scale),
        @as(c_int, height * scale),
        SDL.SDL_WINDOW_SHOWN,
    ) orelse panic();
    const renderer = SDL.SDL_CreateRenderer(window, -1, SDL.SDL_RENDERER_ACCELERATED | SDL.SDL_RENDERER_PRESENTVSYNC) orelse panic();
    const texture = SDL.SDL_CreateTexture(
        renderer,
        SDL.SDL_PIXELFORMAT_RGBA8888,
        SDL.SDL_TEXTUREACCESS_STREAMING,
        @as(c_int, width),
        @as(c_int, height),
    ) orelse panic();
    return Self{
        .window = window,
        .base_title = title,
        .renderer = renderer,
        .texture = texture,
        .audio = null,
    };
 }
 pub fn run(self: *Self, arm7tdmi: *Arm7tdmi, scheduler: *Scheduler) !void {
    var quit = std.atomic.Atomic(bool).init(false);
    var frame_rate = FpsTracker.init();
    const thread = try std.Thread.spawn(.{}, emu.run, .{ &quit, &frame_rate, scheduler, arm7tdmi });
    defer thread.join();
    var title_buf: [0x100]u8 = [_]u8{0} ** 0x100;
    emu_loop: while (true) {
        var event: SDL.SDL_Event = undefined;
        while (SDL.SDL_PollEvent(&event) != 0) {
            switch (event.type) {
                SDL.SDL_QUIT => break :emu_loop,
                SDL.SDL_KEYDOWN => {
                    const io = &arm7tdmi.bus.io;
                    const key_code = event.key.keysym.sym;
                    switch (key_code) {
                        SDL.SDLK_UP => io.keyinput.up.unset(),
                        SDL.SDLK_DOWN => io.keyinput.down.unset(),
                        SDL.SDLK_LEFT => io.keyinput.left.unset(),
                        SDL.SDLK_RIGHT => io.keyinput.right.unset(),
                        SDL.SDLK_x => io.keyinput.a.unset(),
                        SDL.SDLK_z => io.keyinput.b.unset(),
                        SDL.SDLK_a => io.keyinput.shoulder_l.unset(),
                        SDL.SDLK_s => io.keyinput.shoulder_r.unset(),
                        SDL.SDLK_RETURN => io.keyinput.start.unset(),
                        SDL.SDLK_RSHIFT => io.keyinput.select.unset(),
                        else => {},
                    }
                },
                SDL.SDL_KEYUP => {
                    const io = &arm7tdmi.bus.io;
                    const key_code = event.key.keysym.sym;
                    switch (key_code) {
                        SDL.SDLK_UP => io.keyinput.up.set(),
                        SDL.SDLK_DOWN => io.keyinput.down.set(),
                        SDL.SDLK_LEFT => io.keyinput.left.set(),
                        SDL.SDLK_RIGHT => io.keyinput.right.set(),
                        SDL.SDLK_x => io.keyinput.a.set(),
                        SDL.SDLK_z => io.keyinput.b.set(),
                        SDL.SDLK_a => io.keyinput.shoulder_l.set(),
                        SDL.SDLK_s => io.keyinput.shoulder_r.set(),
                        SDL.SDLK_RETURN => io.keyinput.start.set(),
                        SDL.SDLK_RSHIFT => io.keyinput.select.set(),
                        SDL.SDLK_i => log.err("Sample Count: {}", .{@intCast(u32, SDL.SDL_AudioStreamAvailable(arm7tdmi.bus.apu.stream)) / (2 * @sizeOf(u16))}),
                        SDL.SDLK_j => log.err("Scheduler Capacity: {} | Scheduler Event Count: {}", .{ scheduler.queue.capacity(), scheduler.queue.count() }),
                        SDL.SDLK_k => {
                            // Dump IWRAM to file
                            log.info("PC: 0x{X:0>8}", .{arm7tdmi.r[15]});
                            log.info("LR: 0x{X:0>8}", .{arm7tdmi.r[14]});
                            // const iwram_file = try std.fs.cwd().createFile("iwram.bin", .{});
                            // defer iwram_file.close();
                            // try iwram_file.writeAll(cpu.bus.iwram.buf);
                        },
                        else => {},
                    }
                },
                else => {},
            }
        }
        // Emulator has an internal Double Buffer
        const framebuf = arm7tdmi.bus.ppu.framebuf.get(.Renderer);
        _ = SDL.SDL_UpdateTexture(self.texture, null, framebuf.ptr, pitch);
        _ = SDL.SDL_RenderCopy(self.renderer, self.texture, null, null);
        SDL.SDL_RenderPresent(self.renderer);
        const title = std.fmt.bufPrint(&title_buf, "ZBA | {s} [Emu: {}fps] ", .{ self.base_title, frame_rate.value() }) catch unreachable;
        SDL.SDL_SetWindowTitle(self.window, title.ptr);
    }
    quit.store(true, .SeqCst); // Terminate Emulator Thread
 }
 pub fn initAudio(self: *Self, apu: *Apu) void {
    self.audio = Audio.init(apu);
    self.audio.?.play();
 }
 pub fn deinit(self: Self) void {
    if (self.audio) |aud| aud.deinit();
    SDL.SDL_DestroyTexture(self.texture);
    SDL.SDL_DestroyRenderer(self.renderer);
    SDL.SDL_DestroyWindow(self.window);
    SDL.SDL_Quit();
 }
 const Audio = struct {
    const This = @This();
    const sample_rate = @import("core/apu.zig").host_sample_rate;
    device: SDL.SDL_AudioDeviceID,
    fn init(apu: *Apu) This {
        var have: SDL.SDL_AudioSpec = undefined;
        var want: SDL.SDL_AudioSpec = std.mem.zeroes(SDL.SDL_AudioSpec);
        want.freq = sample_rate;
        want.format = SDL.AUDIO_U16;
        want.channels = 2;
        want.samples = 0x100;
        want.callback = This.callback;
        want.userdata = apu;
        const device = SDL.SDL_OpenAudioDevice(null, 0, &want, &have, 0);
        if (device == 0) panic();
        return .{
            .device = device,
        };
    }
    fn deinit(this: This) void {
        SDL.SDL_CloseAudioDevice(this.device);
    }
    pub fn play(this: *This) void {
        SDL.SDL_PauseAudioDevice(this.device, 0);
    }
    export fn callback(userdata: ?*anyopaque, stream: [*c]u8, len: c_int) void {
        const apu = @ptrCast(*Apu, @alignCast(@alignOf(*Apu), userdata));
        const written = SDL.SDL_AudioStreamGet(apu.stream, stream, len);
        // If we don't write anything, play silence otherwise garbage will be played
        // FIXME: I don't think this hack to remove DC Offset is acceptable :thinking:
        if (written == 0) std.mem.set(u8, stream[0..@intCast(usize, len)], 0x40);
    }
 };
 fn panic() noreturn {
    const str = @as(?[*:0]const u8, SDL.SDL_GetError()) orelse "unknown error";
    @panic(std.mem.sliceTo(str, 0));
 }
--- a/src/config.zig
+++ b/src/config.zig
@@ -0,0 +1,86 @@
 const std = @import("std");
 const toml = @import("toml");
 const Allocator = std.mem.Allocator;
 const log = std.log.scoped(.Config);
 var state: Config = .{};
 const Config = struct {
    host: Host = .{},
    guest: Guest = .{},
    debug: Debug = .{},
    /// Settings related to the Computer the Emulator is being run on
    const Host = struct {
        /// Using Nearest-Neighbor, multiply the resolution of the GBA Window
        win_scale: i64 = 3,
        /// Enable Vsync
        ///
        /// Note: This does not affect whether Emulation is synced to 59Hz
        vsync: bool = true,
        /// Mute ZBA
        mute: bool = false,
    };
    // Settings realted to the emulation itself
    const Guest = struct {
        /// Whether Emulation thread to sync to Audio Callbacks
        audio_sync: bool = true,
        /// Whether Emulation thread should sync to 59Hz
        video_sync: bool = true,
        /// Whether RTC I/O should always be enabled
        force_rtc: bool = false,
        /// Skip BIOS
        skip_bios: bool = false,
    };
    /// Settings related to debugging ZBA
    const Debug = struct {
        /// Enable CPU Trace logs
        cpu_trace: bool = false,
        /// If false and ZBA is built in debug mode, ZBA will panic on unhandled I/O
        unhandled_io: bool = true,
    };
 };
 pub fn config() *const Config {
    return &state;
 }
 /// Reads a config file and then loads it into the global state
 pub fn load(allocator: Allocator, file_path: []const u8) !void {
    var config_file = try std.fs.cwd().openFile(file_path, .{});
    defer config_file.close();
    log.info("loaded from {s}", .{file_path});
    const contents = try config_file.readToEndAlloc(allocator, try config_file.getEndPos());
    defer allocator.free(contents);
    var parser = try toml.parseFile(allocator, file_path);
    defer parser.deinit();
    const table = try parser.parse();
    defer table.deinit();
    // TODO: Report unknown config options
    if (table.keys.get("Host")) |host| {
        if (host.Table.keys.get("win_scale")) |scale| state.host.win_scale = scale.Integer;
        if (host.Table.keys.get("vsync")) |vsync| state.host.vsync = vsync.Boolean;
        if (host.Table.keys.get("mute")) |mute| state.host.mute = mute.Boolean;
    }
    if (table.keys.get("Guest")) |guest| {
        if (guest.Table.keys.get("audio_sync")) |sync| state.guest.audio_sync = sync.Boolean;
        if (guest.Table.keys.get("video_sync")) |sync| state.guest.video_sync = sync.Boolean;
        if (guest.Table.keys.get("force_rtc")) |forced| state.guest.force_rtc = forced.Boolean;
        if (guest.Table.keys.get("skip_bios")) |skip| state.guest.skip_bios = skip.Boolean;
    }
    if (table.keys.get("Debug")) |debug| {
        if (debug.Table.keys.get("cpu_trace")) |trace| state.debug.cpu_trace = trace.Boolean;
        if (debug.Table.keys.get("unhandled_io")) |unhandled| state.debug.unhandled_io = unhandled.Boolean;
    }
 }
--- a/src/core/Bus.zig
+++ b/src/core/Bus.zig
@@ -1,6 +1,5 @@
 const std = @import("std");
 const AudioDeviceId = @import("sdl2").SDL_AudioDeviceID;
 const Arm7tdmi = @import("cpu.zig").Arm7tdmi;
 const Bios = @import("bus/Bios.zig");
 const Ewram = @import("bus/Ewram.zig");
@@ -12,7 +11,7 @@ const Apu = @import("apu.zig").Apu;
 const DmaTuple = @import("bus/dma.zig").DmaTuple;
 const TimerTuple = @import("bus/timer.zig").TimerTuple;
 const Scheduler = @import("scheduler.zig").Scheduler;
-const FilePaths = @import("util.zig").FilePaths;
+const FilePaths = @import("../util.zig").FilePaths;
 const io = @import("bus/io.zig");
 const Allocator = std.mem.Allocator;
@@ -20,7 +19,7 @@ const log = std.log.scoped(.Bus);
 const createDmaTuple = @import("bus/dma.zig").create;
 const createTimerTuple = @import("bus/timer.zig").create;
-const rotr = @import("util.zig").rotr;
+const rotr = @import("../util.zig").rotr;
 const timings: [2][0x10]u8 = [_][0x10]u8{
    // BIOS, Unused, EWRAM, IWRAM, I/0, PALRAM, VRAM, OAM, ROM0, ROM0, ROM1, ROM1, ROM2, ROM2, SRAM, Unused
@@ -34,6 +33,11 @@ pub const fetch_timings: [2][0x10]u8 = [_][0x10]u8{
    [_]u8{ 1, 1, 6, 1, 1, 2, 2, 1, 4, 4, 4, 4, 4, 4, 8, 8 }, // 32-bit
 };
 // Fastmem Related
 const page_size = 1 * 0x400; // 1KiB
 const address_space_size = 0x1000_0000;
 const table_len = address_space_size / page_size;
 const Self = @This();
 pak: GamePak,
@@ -46,62 +50,179 @@ iwram: Iwram,
 ewram: Ewram,
 io: Io,
-cpu: ?*Arm7tdmi,
+cpu: *Arm7tdmi,
 sched: *Scheduler,
-pub fn init(alloc: Allocator, sched: *Scheduler, paths: FilePaths) !Self {
+read_table: *const [table_len]?*const anyopaque,
-    return Self{
+write_tables: [2]*const [table_len]?*anyopaque,
-        .pak = try GamePak.init(alloc, paths.rom, paths.save),
+allocator: Allocator,
-        .bios = try Bios.init(alloc, paths.bios),
+
-        .ppu = try Ppu.init(alloc, sched),
+pub fn init(self: *Self, allocator: Allocator, sched: *Scheduler, cpu: *Arm7tdmi, paths: FilePaths) !void {
    const tables = try allocator.alloc(?*anyopaque, 3 * table_len); // Allocate all tables
    const read_table: *[table_len]?*const anyopaque = tables[0..table_len];
    const left_write: *[table_len]?*anyopaque = tables[table_len .. 2 * table_len];
    const right_write: *[table_len]?*anyopaque = tables[2 * table_len .. 3 * table_len];
    self.* = .{
        .pak = try GamePak.init(allocator, cpu, paths.rom, paths.save),
        .bios = try Bios.init(allocator, paths.bios),
        .ppu = try Ppu.init(allocator, sched),
        .apu = Apu.init(sched),
-        .iwram = try Iwram.init(alloc),
+        .iwram = try Iwram.init(allocator),
-        .ewram = try Ewram.init(alloc),
+        .ewram = try Ewram.init(allocator),
        .dma = createDmaTuple(),
        .tim = createTimerTuple(sched),
        .io = Io.init(),
-        .cpu = null,
+        .cpu = cpu,
        .sched = sched,
        .read_table = read_table,
        .write_tables = .{ left_write, right_write },
        .allocator = allocator,
    };
    // read_table, write_tables, and *Self are not restricted to the lifetime
    // of this init function so we can initialize our tables here
    fillReadTable(self, read_table);
    // Internal Display Memory behavious unusually on 8-bit reads
    // so we have two different tables depending on whether there's an 8-bit read or not
    fillWriteTable(u32, self, left_write);
    fillWriteTable(u8, self, right_write);
 }
-pub fn deinit(self: Self) void {
+pub fn deinit(self: *Self) void {
    self.iwram.deinit();
    self.ewram.deinit();
    self.pak.deinit();
    self.bios.deinit();
    self.ppu.deinit();
    // This is so I can deallocate the original `allocator.alloc`. I have to re-make the type
    // since I'm not keeping it around, This is very jank and bad though
    // FIXME: please figure out another way
    self.allocator.free(@ptrCast([*]const ?*anyopaque, self.read_table[0..])[0 .. 3 * table_len]);
    self.* = undefined;
 }
-pub fn attach(self: *Self, cpu: *Arm7tdmi) void {
+fn fillReadTable(bus: *Self, table: *[table_len]?*const anyopaque) void {
-    self.cpu = cpu;
+    const vramMirror = @import("ppu.zig").Vram.mirror;
    for (table) |*ptr, i| {
        const addr = page_size * i;
        ptr.* = switch (addr) {
            // General Internal Memory
            0x0000_0000...0x0000_3FFF => null, // BIOS has it's own checks
            0x0200_0000...0x02FF_FFFF => &bus.ewram.buf[addr & 0x3FFFF],
            0x0300_0000...0x03FF_FFFF => &bus.iwram.buf[addr & 0x7FFF],
            0x0400_0000...0x0400_03FF => null, // I/O
            // Internal Display Memory
            0x0500_0000...0x05FF_FFFF => &bus.ppu.palette.buf[addr & 0x3FF],
            0x0600_0000...0x06FF_FFFF => &bus.ppu.vram.buf[vramMirror(addr)],
            0x0700_0000...0x07FF_FFFF => &bus.ppu.oam.buf[addr & 0x3FF],
            // External Memory (Game Pak)
            0x0800_0000...0x0DFF_FFFF => fillTableExternalMemory(bus, addr),
            0x0E00_0000...0x0FFF_FFFF => null, // SRAM
            else => null,
        };
    }
 }
-pub fn dbgRead(self: *const Self, comptime T: type, address: u32) T {
+fn fillWriteTable(comptime T: type, bus: *Self, table: *[table_len]?*const anyopaque) void {
-    const page = @truncate(u8, address >> 24);
+    comptime std.debug.assert(T == u32 or T == u16 or T == u8);
-    const aligned_addr = forceAlign(T, address);
+    const vramMirror = @import("ppu.zig").Vram.mirror;
    for (table) |*ptr, i| {
        const addr = page_size * i;
        ptr.* = switch (addr) {
            // General Internal Memory
            0x0000_0000...0x0000_3FFF => null, // BIOS has it's own checks
            0x0200_0000...0x02FF_FFFF => &bus.ewram.buf[addr & 0x3FFFF],
            0x0300_0000...0x03FF_FFFF => &bus.iwram.buf[addr & 0x7FFF],
            0x0400_0000...0x0400_03FF => null, // I/O
            // Internal Display Memory
            0x0500_0000...0x05FF_FFFF => if (T != u8) &bus.ppu.palette.buf[addr & 0x3FF] else null,
            0x0600_0000...0x06FF_FFFF => if (T != u8) &bus.ppu.vram.buf[vramMirror(addr)] else null,
            0x0700_0000...0x07FF_FFFF => if (T != u8) &bus.ppu.oam.buf[addr & 0x3FF] else null,
            // External Memory (Game Pak)
            0x0800_0000...0x0DFF_FFFF => null, // ROM
            0x0E00_0000...0x0FFF_FFFF => null, // SRAM
            else => null,
        };
    }
 }
 fn fillTableExternalMemory(bus: *Self, addr: usize) ?*anyopaque {
    // see `GamePak.zig` for more information about what conditions need to be true
    // so that a simple pointer dereference isn't possible
    const start_addr = addr;
    const end_addr = addr + page_size;
    const gpio_data = start_addr <= 0x0800_00C4 and 0x0800_00C4 < end_addr;
    const gpio_direction = start_addr <= 0x0800_00C6 and 0x0800_00C6 < end_addr;
    const gpio_control = start_addr <= 0x0800_00C8 and 0x0800_00C8 < end_addr;
    if (bus.pak.gpio.device.kind != .None and (gpio_data or gpio_direction or gpio_control)) {
        // We found a GPIO device, and this page a GPIO register. We want to handle this in slowmem
        return null;
    }
    if (bus.pak.backup.kind == .Eeprom) {
        if (bus.pak.buf.len > 0x100_000) {
            // We are using a "large" EEPROM which means that if the below check is true
            // this page has an address that's reserved for the EEPROM and therefore must
            // be handled in slowmem
            if (addr & 0x1FF_FFFF > 0x1FF_FEFF) return null;
        } else {
            // We are using a "small" EEPROM which means that if the below check is true
            // (that is, we're in the 0xD address page) then we must handle at least one
            // address in this page in slowmem
            if (@truncate(u4, addr >> 24) == 0xD) return null;
        }
    }
    // Finally, the GamePak has some unique behaviour for reads past the end of the ROM,
    // so those will be handled by slowmem as well
    const masked_addr = addr & 0x1FF_FFFF;
    if (masked_addr >= bus.pak.buf.len) return null;
    return &bus.pak.buf[masked_addr];
 }
 // TODO: Take advantage of fastmem here too?
 pub fn dbgRead(self: *const Self, comptime T: type, unaligned_address: u32) T {
    const page = @truncate(u8, unaligned_address >> 24);
    const address = forceAlign(T, unaligned_address);
    return switch (page) {
        // General Internal Memory
        0x00 => blk: {
            if (address < Bios.size)
-                break :blk self.bios.dbgRead(T, self.cpu.?.r[15], aligned_addr);
+                break :blk self.bios.dbgRead(T, self.cpu.r[15], address);
-            break :blk self.readOpenBus(T, address);
+            break :blk self.openBus(T, address);
        },
-        0x02 => self.ewram.read(T, aligned_addr),
+        0x02 => self.ewram.read(T, address),
-        0x03 => self.iwram.read(T, aligned_addr),
+        0x03 => self.iwram.read(T, address),
-        0x04 => io.read(self, T, aligned_addr),
+        0x04 => self.readIo(T, address),
        // Internal Display Memory
-        0x05 => self.ppu.palette.read(T, aligned_addr),
+        0x05 => self.ppu.palette.read(T, address),
-        0x06 => self.ppu.vram.read(T, aligned_addr),
+        0x06 => self.ppu.vram.read(T, address),
-        0x07 => self.ppu.oam.read(T, aligned_addr),
+        0x07 => self.ppu.oam.read(T, address),
        // External Memory (Game Pak)
-        0x08...0x0D => self.pak.dbgRead(T, aligned_addr),
+        0x08...0x0D => self.pak.dbgRead(T, address),
        0x0E...0x0F => blk: {
-            const value = self.pak.backup.read(address);
+            const value = self.pak.backup.read(unaligned_address);
            const multiplier = switch (T) {
                u32 => 0x01010101,
@@ -112,66 +233,127 @@ pub fn dbgRead(self: *const Self, comptime T: type, address: u32) T {
            break :blk @as(T, value) * multiplier;
        },
-        else => self.readOpenBus(T, address),
+        else => self.openBus(T, address),
    };
 }
-fn readOpenBus(self: *const Self, comptime T: type, address: u32) T {
+fn readIo(self: *const Self, comptime T: type, address: u32) T {
-    const r15 = self.cpu.?.r[15];
+    return io.read(self, T, address) orelse self.openBus(T, address);
 }
 fn openBus(self: *const Self, comptime T: type, address: u32) T {
    @setCold(true);
    const r15 = self.cpu.r[15];
    const word = blk: {
        // If Arm, get the most recently fetched instruction (PC + 8)
        //
        // FIXME: This is most likely a faulty assumption.
        // I think what *actually* happens is that the Bus has a latch for the most
        // recently fetched piece of data, which is then returned during Open Bus (also DMA open bus?)
        // I can "get away" with this because it's very statistically likely that the most recently latched value is
        // the most recently fetched instruction by the pipeline
        if (!self.cpu.cpsr.t.read()) break :blk self.cpu.pipe.stage[1].?;
    const word = if (self.cpu.?.cpsr.t.read()) blk: {
        const page = @truncate(u8, r15 >> 24);
        // PC + 2 = stage[0]
        // PC + 4 = stage[1]
        // PC + 6 = Need a Debug Read for this?
        switch (page) {
            // EWRAM, PALRAM, VRAM, and Game ROM (16-bit)
            0x02, 0x05, 0x06, 0x08...0x0D => {
-                const halfword = self.dbgRead(u16, r15 + 2);
+                const halfword: u32 = @truncate(u16, self.cpu.pipe.stage[1].?);
-                break :blk @as(u32, halfword) << 16 | halfword;
+                break :blk halfword << 16 | halfword;
            },
            // BIOS or OAM (32-bit)
            0x00, 0x07 => {
-                const offset: u32 = if (address & 3 == 0b00) 2 else 0;
+                // Aligned: (PC + 6) | (PC + 4)
-                break :blk @as(u32, self.dbgRead(u16, (r15 + 2) + offset)) << 16 | self.dbgRead(u16, r15 + offset);
+                // Unaligned: (PC + 4) | (PC + 2)
                const aligned = address & 3 == 0b00;
                // TODO: What to do on PC + 6?
                const high: u32 = if (aligned) self.dbgRead(u16, r15 + 4) else @truncate(u16, self.cpu.pipe.stage[1].?);
                const low: u32 = @truncate(u16, self.cpu.pipe.stage[@boolToInt(aligned)].?);
                break :blk high << 16 | low;
            },
            // IWRAM (16-bit but special)
            0x03 => {
-                const offset: u32 = if (address & 3 == 0b00) 2 else 0;
+                // Aligned: (PC + 2) | (PC + 4)
-                break :blk @as(u32, self.dbgRead(u16, (r15 + 2) - offset)) << 16 | self.dbgRead(u16, r15 + offset);
+                // Unaligned: (PC + 4) | (PC + 2)
-            },
+                const aligned = address & 3 == 0b00;
            else => unreachable,
        }
    } else self.dbgRead(u32, r15 + 4);
-    return @truncate(T, rotr(u32, word, 8 * (address & 3)));
+                const high: u32 = @truncate(u16, self.cpu.pipe.stage[1 - @boolToInt(aligned)].?);
                const low: u32 = @truncate(u16, self.cpu.pipe.stage[@boolToInt(aligned)].?);
                break :blk high << 16 | low;
            },
            else => {
                log.err("THUMB open bus read from 0x{X:0>2} page @0x{X:0>8}", .{ page, address });
                @panic("invariant most-likely broken");
            },
        }
    };
    return @truncate(T, word);
 }
-pub fn read(self: *Self, comptime T: type, address: u32) T {
+pub fn read(self: *Self, comptime T: type, unaligned_address: u32) T {
-    const page = @truncate(u8, address >> 24);
+    const bits = @typeInfo(std.math.IntFittingRange(0, page_size - 1)).Int.bits;
-    const aligned_addr = forceAlign(T, address);
+    const page = unaligned_address >> bits;
    const offset = unaligned_address & (page_size - 1);
-    self.sched.tick += timings[@boolToInt(T == u32)][@truncate(u4, page)];
+    // whether or not we do this in slowmem or fastmem, we should advance the scheduler
    self.sched.tick += timings[@boolToInt(T == u32)][@truncate(u4, unaligned_address >> 24)];
    // We're doing some serious out-of-bounds open-bus reads
    if (page >= table_len) return self.openBus(T, unaligned_address);
    if (self.read_table[page]) |some_ptr| {
        // We have a pointer to a page, cast the pointer to it's underlying type
        const Ptr = [*]const T;
        const alignment = @alignOf(std.meta.Child(Ptr));
        const ptr = @ptrCast(Ptr, @alignCast(alignment, some_ptr));
        // Note: We don't check array length, since we force align the
        // lower bits of the address as the GBA would
        return ptr[forceAlign(T, offset) / @sizeOf(T)];
    }
    return self.slowRead(T, unaligned_address);
 }
 fn slowRead(self: *Self, comptime T: type, unaligned_address: u32) T {
    @setCold(true);
    const page = @truncate(u8, unaligned_address >> 24);
    const address = forceAlign(T, unaligned_address);
    return switch (page) {
        // General Internal Memory
        0x00 => blk: {
            if (address < Bios.size)
-                break :blk self.bios.read(T, self.cpu.?.r[15], aligned_addr);
+                break :blk self.bios.read(T, self.cpu.r[15], address);
-            break :blk self.readOpenBus(T, address);
+            break :blk self.openBus(T, address);
        },
-        0x02 => self.ewram.read(T, aligned_addr),
+        0x02 => unreachable, // completely handled by fastmeme
-        0x03 => self.iwram.read(T, aligned_addr),
+        0x03 => unreachable, // completely handled by fastmeme
-        0x04 => io.read(self, T, aligned_addr),
+        0x04 => self.readIo(T, address),
        // Internal Display Memory
-        0x05 => self.ppu.palette.read(T, aligned_addr),
+        0x05 => unreachable, // completely handled by fastmeme
-        0x06 => self.ppu.vram.read(T, aligned_addr),
+        0x06 => unreachable, // completely handled by fastmeme
-        0x07 => self.ppu.oam.read(T, aligned_addr),
+        0x07 => unreachable, // completely handled by fastmeme
        // External Memory (Game Pak)
-        0x08...0x0D => self.pak.read(T, aligned_addr),
+        0x08...0x0D => self.pak.read(T, address),
        0x0E...0x0F => blk: {
-            const value = self.pak.backup.read(address);
+            const value = self.pak.backup.read(unaligned_address);
            const multiplier = switch (T) {
                u32 => 0x01010101,
@@ -182,48 +364,75 @@ pub fn read(self: *Self, comptime T: type, address: u32) T {
            break :blk @as(T, value) * multiplier;
        },
-        else => self.readOpenBus(T, address),
+        else => self.openBus(T, address),
    };
 }
-pub fn write(self: *Self, comptime T: type, address: u32, value: T) void {
+pub fn write(self: *Self, comptime T: type, unaligned_address: u32, value: T) void {
-    const page = @truncate(u8, address >> 24);
+    const bits = @typeInfo(std.math.IntFittingRange(0, page_size - 1)).Int.bits;
-    const aligned_addr = forceAlign(T, address);
+    const page = unaligned_address >> bits;
    const offset = unaligned_address & (page_size - 1);
-    self.sched.tick += timings[@boolToInt(T == u32)][@truncate(u4, page)];
+    // whether or not we do this in slowmem or fastmem, we should advance the scheduler
    self.sched.tick += timings[@boolToInt(T == u32)][@truncate(u4, unaligned_address >> 24)];
    // We're doing some serious out-of-bounds open-bus writes, they do nothing though
    if (page >= table_len) return;
    if (self.write_tables[@boolToInt(T == u8)][page]) |some_ptr| {
        // We have a pointer to a page, cast the pointer to it's underlying type
        const Ptr = [*]T;
        const alignment = @alignOf(std.meta.Child(Ptr));
        const ptr = @ptrCast(Ptr, @alignCast(alignment, some_ptr));
        // Note: We don't check array length, since we force align the
        // lower bits of the address as the GBA would
        ptr[forceAlign(T, offset) / @sizeOf(T)] = value;
    } else {
        // we can return early if this is an 8-bit OAM write
        if (T == u8 and @truncate(u8, unaligned_address >> 24) == 0x07) return;
        self.slowWrite(T, unaligned_address, value);
    }
 }
 pub fn slowWrite(self: *Self, comptime T: type, unaligned_address: u32, value: T) void {
    // @setCold(true);
    const page = @truncate(u8, unaligned_address >> 24);
    const address = forceAlign(T, unaligned_address);
    switch (page) {
        // General Internal Memory
-        0x00 => self.bios.write(T, aligned_addr, value),
+        0x00 => self.bios.write(T, address, value),
-        0x02 => self.ewram.write(T, aligned_addr, value),
+        0x02 => unreachable, // completely handled by fastmem
-        0x03 => self.iwram.write(T, aligned_addr, value),
+        0x03 => unreachable, // completely handled by fastmem
-        0x04 => io.write(self, T, aligned_addr, value),
+        0x04 => io.write(self, T, address, value),
        // Internal Display Memory
-        0x05 => self.ppu.palette.write(T, aligned_addr, value),
+        0x05 => self.ppu.palette.write(T, address, value),
-        0x06 => self.ppu.vram.write(T, self.ppu.dispcnt, aligned_addr, value),
+        0x06 => self.ppu.vram.write(T, self.ppu.dispcnt, address, value),
-        0x07 => self.ppu.oam.write(T, aligned_addr, value),
+        0x07 => unreachable, // completely handled by fastmem
        // External Memory (Game Pak)
-        0x08...0x0D => self.pak.write(T, self.dma[3].word_count, aligned_addr, value),
+        0x08...0x0D => self.pak.write(T, self.dma[3].word_count, address, value),
-        0x0E...0x0F => {
+        0x0E...0x0F => self.pak.backup.write(unaligned_address, @truncate(u8, rotr(T, value, 8 * rotateBy(T, unaligned_address)))),
            const rotate_by = switch (T) {
                u32 => address & 3,
                u16 => address & 1,
                u8 => 0,
                else => @compileError("Backup: Unsupported write width"),
            };
            self.pak.backup.write(address, @truncate(u8, rotr(T, value, 8 * rotate_by)));
        },
        else => {},
    }
 }
-fn forceAlign(comptime T: type, address: u32) u32 {
+inline fn rotateBy(comptime T: type, address: u32) u32 {
    return switch (T) {
-        u32 => address & 0xFFFF_FFFC,
+        u32 => address & 3,
-        u16 => address & 0xFFFF_FFFE,
+        u16 => address & 1,
        u8 => 0,
        else => @compileError("Backup: Unsupported write width"),
    };
 }
 inline fn forceAlign(comptime T: type, address: u32) u32 {
    return switch (T) {
        u32 => address & ~@as(u32, 3),
        u16 => address & ~@as(u32, 1),
        u8 => address,
        else => @compileError("Bus: Invalid read/write type"),
    };
--- a/src/core/apu.zig
+++ b/src/core/apu.zig
--- a/src/core/apu/Noise.zig
+++ b/src/core/apu/Noise.zig
@@ -0,0 +1,145 @@
 const io = @import("../bus/io.zig");
 const util = @import("../../util.zig");
 const Scheduler = @import("../scheduler.zig").Scheduler;
 const FrameSequencer = @import("../apu.zig").FrameSequencer;
 const Tick = @import("../apu.zig").Apu.Tick;
 const Envelope = @import("device/Envelope.zig");
 const Length = @import("device/Length.zig");
 const Lfsr = @import("signal/Lfsr.zig");
 const Self = @This();
 /// Write-only
 /// NR41
 len: u6,
 /// NR42
 envelope: io.Envelope,
 /// NR43
 poly: io.PolyCounter,
 /// NR44
 cnt: io.NoiseControl,
 /// Length Functionarlity
 len_dev: Length,
 /// Envelope Functionality
 env_dev: Envelope,
 // Linear Feedback Shift Register
 lfsr: Lfsr,
 enabled: bool,
 sample: i8,
 pub fn init(sched: *Scheduler) Self {
    return .{
        .len = 0,
        .envelope = .{ .raw = 0 },
        .poly = .{ .raw = 0 },
        .cnt = .{ .raw = 0 },
        .enabled = false,
        .len_dev = Length.create(),
        .env_dev = Envelope.create(),
        .lfsr = Lfsr.create(sched),
        .sample = 0,
    };
 }
 pub fn reset(self: *Self) void {
    self.len = 0; // NR41
    self.envelope.raw = 0; // NR42
    self.poly.raw = 0; // NR43
    self.cnt.raw = 0; // NR44
    self.len_dev.reset();
    self.env_dev.reset();
    self.sample = 0;
    self.enabled = false;
 }
 pub fn tick(self: *Self, comptime kind: Tick) void {
    switch (kind) {
        .Length => self.len_dev.tick(self.cnt.length_enable.read(), &self.enabled),
        .Envelope => self.env_dev.tick(self.envelope),
        .Sweep => @compileError("Channel 4 does not implement Sweep"),
    }
 }
 /// NR41, NR42
 pub fn sound4CntL(self: *const Self) u16 {
    return @as(u16, self.envelope.raw) << 8;
 }
 /// NR41, NR42
 pub fn setSound4CntL(self: *Self, value: u16) void {
    self.setNr41(@truncate(u8, value));
    self.setNr42(@truncate(u8, value >> 8));
 }
 /// NR41
 pub fn setNr41(self: *Self, len: u8) void {
    self.len = @truncate(u6, len);
    self.len_dev.timer = @as(u7, 64) - @truncate(u6, len);
 }
 /// NR42
 pub fn setNr42(self: *Self, value: u8) void {
    self.envelope.raw = value;
    if (!self.isDacEnabled()) self.enabled = false;
 }
 /// NR43, NR44
 pub fn sound4CntH(self: *const Self) u16 {
    return @as(u16, self.poly.raw & 0x40) << 8 | self.cnt.raw;
 }
 /// NR43, NR44
 pub fn setSound4CntH(self: *Self, fs: *const FrameSequencer, value: u16) void {
    self.poly.raw = @truncate(u8, value);
    self.setNr44(fs, @truncate(u8, value >> 8));
 }
 /// NR44
 pub fn setNr44(self: *Self, fs: *const FrameSequencer, byte: u8) void {
    var new: io.NoiseControl = .{ .raw = byte };
    if (new.trigger.read()) {
        self.enabled = true;
        if (self.len_dev.timer == 0) {
            self.len_dev.timer =
                if (!fs.isLengthNext() and new.length_enable.read()) 63 else 64;
        }
        // Update The Frequency Timer
        self.lfsr.reload(self.poly);
        self.lfsr.shift = 0x7FFF;
        // Update Envelope and Volume
        self.env_dev.timer = self.envelope.period.read();
        if (fs.isEnvelopeNext() and self.env_dev.timer != 0b111) self.env_dev.timer += 1;
        self.env_dev.vol = self.envelope.init_vol.read();
        self.enabled = self.isDacEnabled();
    }
    util.audio.length.ch4.update(self, fs, new);
    self.cnt = new;
 }
 pub fn onNoiseEvent(self: *Self, late: u64) void {
    self.lfsr.onLfsrTimerExpire(self.poly, late);
    self.sample = 0;
    if (!self.isDacEnabled()) return;
    self.sample = if (self.enabled) self.lfsr.sample() * @as(i8, self.env_dev.vol) else 0;
 }
 fn isDacEnabled(self: *const Self) bool {
    return self.envelope.raw & 0xF8 != 0x00;
 }
--- a/src/core/apu/Tone.zig
+++ b/src/core/apu/Tone.zig
@@ -0,0 +1,141 @@
 const io = @import("../bus/io.zig");
 const util = @import("../../util.zig");
 const Scheduler = @import("../scheduler.zig").Scheduler;
 const FrameSequencer = @import("../apu.zig").FrameSequencer;
 const Tick = @import("../apu.zig").Apu.Tick;
 const Length = @import("device/Length.zig");
 const Envelope = @import("device/Envelope.zig");
 const Square = @import("signal/Square.zig");
 const Self = @This();
 /// NR21
 duty: io.Duty,
 /// NR22
 envelope: io.Envelope,
 /// NR23, NR24
 freq: io.Frequency,
 /// Length Functionarlity
 len_dev: Length,
 /// Envelope Functionality
 env_dev: Envelope,
 /// FrequencyTimer Functionality
 square: Square,
 enabled: bool,
 sample: i8,
 pub fn init(sched: *Scheduler) Self {
    return .{
        .duty = .{ .raw = 0 },
        .envelope = .{ .raw = 0 },
        .freq = .{ .raw = 0 },
        .enabled = false,
        .square = Square.init(sched),
        .len_dev = Length.create(),
        .env_dev = Envelope.create(),
        .sample = 0,
    };
 }
 pub fn reset(self: *Self) void {
    self.duty.raw = 0; // NR21
    self.envelope.raw = 0; // NR22
    self.freq.raw = 0; // NR32, NR24
    self.len_dev.reset();
    self.env_dev.reset();
    self.sample = 0;
    self.enabled = false;
 }
 pub fn tick(self: *Self, comptime kind: Tick) void {
    switch (kind) {
        .Length => self.len_dev.tick(self.freq.length_enable.read(), &self.enabled),
        .Envelope => self.env_dev.tick(self.envelope),
        .Sweep => @compileError("Channel 2 does not implement Sweep"),
    }
 }
 pub fn onToneEvent(self: *Self, late: u64) void {
    self.square.onSquareTimerExpire(Self, self.freq, late);
    self.sample = 0;
    if (!self.isDacEnabled()) return;
    self.sample = if (self.enabled) self.square.sample(self.duty) * @as(i8, self.env_dev.vol) else 0;
 }
 /// NR21, NR22
 pub fn sound2CntL(self: *const Self) u16 {
    return @as(u16, self.envelope.raw) << 8 | (self.duty.raw & 0xC0);
 }
 /// NR21, NR22
 pub fn setSound2CntL(self: *Self, value: u16) void {
    self.setNr21(@truncate(u8, value));
    self.setNr22(@truncate(u8, value >> 8));
 }
 /// NR21
 pub fn setNr21(self: *Self, value: u8) void {
    self.duty.raw = value;
    self.len_dev.timer = @as(u7, 64) - @truncate(u6, value);
 }
 /// NR22
 pub fn setNr22(self: *Self, value: u8) void {
    self.envelope.raw = value;
    if (!self.isDacEnabled()) self.enabled = false;
 }
 /// NR23, NR24
 pub fn sound2CntH(self: *const Self) u16 {
    return self.freq.raw & 0x4000;
 }
 /// NR23, NR24
 pub fn setSound2CntH(self: *Self, fs: *const FrameSequencer, value: u16) void {
    self.setNr23(@truncate(u8, value));
    self.setNr24(fs, @truncate(u8, value >> 8));
 }
 /// NR23
 pub fn setNr23(self: *Self, byte: u8) void {
    self.freq.raw = (self.freq.raw & 0xFF00) | byte;
 }
 /// NR24
 pub fn setNr24(self: *Self, fs: *const FrameSequencer, byte: u8) void {
    var new: io.Frequency = .{ .raw = (@as(u16, byte) << 8) | (self.freq.raw & 0xFF) };
    if (new.trigger.read()) {
        self.enabled = true;
        if (self.len_dev.timer == 0) {
            self.len_dev.timer =
                if (!fs.isLengthNext() and new.length_enable.read()) 63 else 64;
        }
        self.square.reload(Self, self.freq.frequency.read());
        // Reload Envelope period and timer
        self.env_dev.timer = self.envelope.period.read();
        if (fs.isEnvelopeNext() and self.env_dev.timer != 0b111) self.env_dev.timer += 1;
        self.env_dev.vol = self.envelope.init_vol.read();
        self.enabled = self.isDacEnabled();
    }
    util.audio.length.update(Self, self, fs, new);
    self.freq = new;
 }
 fn isDacEnabled(self: *const Self) bool {
    return self.envelope.raw & 0xF8 != 0;
 }
--- a/src/core/apu/ToneSweep.zig
+++ b/src/core/apu/ToneSweep.zig
@@ -0,0 +1,185 @@
 const io = @import("../bus/io.zig");
 const util = @import("../../util.zig");
 const Scheduler = @import("../scheduler.zig").Scheduler;
 const FrameSequencer = @import("../apu.zig").FrameSequencer;
 const Length = @import("device/Length.zig");
 const Envelope = @import("device/Envelope.zig");
 const Sweep = @import("device/Sweep.zig");
 const Square = @import("signal/Square.zig");
 const Tick = @import("../apu.zig").Apu.Tick;
 const Self = @This();
 /// NR10
 sweep: io.Sweep,
 /// NR11
 duty: io.Duty,
 /// NR12
 envelope: io.Envelope,
 /// NR13, NR14
 freq: io.Frequency,
 /// Length Functionality
 len_dev: Length,
 /// Sweep Functionality
 sweep_dev: Sweep,
 /// Envelope Functionality
 env_dev: Envelope,
 /// Frequency Timer Functionality
 square: Square,
 enabled: bool,
 sample: i8,
 pub fn init(sched: *Scheduler) Self {
    return .{
        .sweep = .{ .raw = 0 },
        .duty = .{ .raw = 0 },
        .envelope = .{ .raw = 0 },
        .freq = .{ .raw = 0 },
        .sample = 0,
        .enabled = false,
        .square = Square.init(sched),
        .len_dev = Length.create(),
        .sweep_dev = Sweep.create(),
        .env_dev = Envelope.create(),
    };
 }
 pub fn reset(self: *Self) void {
    self.sweep.raw = 0; // NR10
    self.duty.raw = 0; // NR11
    self.envelope.raw = 0; // NR12
    self.freq.raw = 0; // NR13, NR14
    self.len_dev.reset();
    self.sweep_dev.reset();
    self.env_dev.reset();
    self.sample = 0;
    self.enabled = false;
 }
 pub fn tick(self: *Self, comptime kind: Tick) void {
    switch (kind) {
        .Length => self.len_dev.tick(self.freq.length_enable.read(), &self.enabled),
        .Envelope => self.env_dev.tick(self.envelope),
        .Sweep => self.sweep_dev.tick(self),
    }
 }
 pub fn onToneSweepEvent(self: *Self, late: u64) void {
    self.square.onSquareTimerExpire(Self, self.freq, late);
    self.sample = 0;
    if (!self.isDacEnabled()) return;
    self.sample = if (self.enabled) self.square.sample(self.duty) * @as(i8, self.env_dev.vol) else 0;
 }
 /// NR10, NR11, NR12
 pub fn setSound1Cnt(self: *Self, value: u32) void {
    self.setSound1CntL(@truncate(u8, value));
    self.setSound1CntH(@truncate(u16, value >> 16));
 }
 /// NR10
 pub fn sound1CntL(self: *const Self) u8 {
    return self.sweep.raw & 0x7F;
 }
 /// NR10
 pub fn setSound1CntL(self: *Self, value: u8) void {
    const new = io.Sweep{ .raw = value };
    if (!new.direction.read()) {
        // If at least one (1) sweep calculation has been made with
        // the negate bit set (since last trigger), disable the channel
        if (self.sweep_dev.calc_performed) self.enabled = false;
    }
    self.sweep.raw = value;
 }
 /// NR11, NR12
 pub fn sound1CntH(self: *const Self) u16 {
    return @as(u16, self.envelope.raw) << 8 | (self.duty.raw & 0xC0);
 }
 /// NR11, NR12
 pub fn setSound1CntH(self: *Self, value: u16) void {
    self.setNr11(@truncate(u8, value));
    self.setNr12(@truncate(u8, value >> 8));
 }
 /// NR11
 pub fn setNr11(self: *Self, value: u8) void {
    self.duty.raw = value;
    self.len_dev.timer = @as(u7, 64) - @truncate(u6, value);
 }
 /// NR12
 pub fn setNr12(self: *Self, value: u8) void {
    self.envelope.raw = value;
    if (!self.isDacEnabled()) self.enabled = false;
 }
 /// NR13, NR14
 pub fn sound1CntX(self: *const Self) u16 {
    return self.freq.raw & 0x4000;
 }
 /// NR13, NR14
 pub fn setSound1CntX(self: *Self, fs: *const FrameSequencer, value: u16) void {
    self.setNr13(@truncate(u8, value));
    self.setNr14(fs, @truncate(u8, value >> 8));
 }
 /// NR13
 pub fn setNr13(self: *Self, byte: u8) void {
    self.freq.raw = (self.freq.raw & 0xFF00) | byte;
 }
 /// NR14
 pub fn setNr14(self: *Self, fs: *const FrameSequencer, byte: u8) void {
    var new: io.Frequency = .{ .raw = (@as(u16, byte) << 8) | (self.freq.raw & 0xFF) };
    if (new.trigger.read()) {
        self.enabled = true;
        if (self.len_dev.timer == 0) {
            self.len_dev.timer =
                if (!fs.isLengthNext() and new.length_enable.read()) 63 else 64;
        }
        self.square.reload(Self, self.freq.frequency.read());
        // Reload Envelope period and timer
        self.env_dev.timer = self.envelope.period.read();
        if (fs.isEnvelopeNext() and self.env_dev.timer != 0b111) self.env_dev.timer += 1;
        self.env_dev.vol = self.envelope.init_vol.read();
        // Sweep Trigger Behaviour
        const sw_period = self.sweep.period.read();
        const sw_shift = self.sweep.shift.read();
        self.sweep_dev.calc_performed = false;
        self.sweep_dev.shadow = self.freq.frequency.read();
        self.sweep_dev.timer = if (sw_period == 0) 8 else sw_period;
        self.sweep_dev.enabled = sw_period != 0 or sw_shift != 0;
        if (sw_shift != 0) _ = self.sweep_dev.calculate(self.sweep, &self.enabled);
        self.enabled = self.isDacEnabled();
    }
    util.audio.length.update(Self, self, fs, new);
    self.freq = new;
 }
 fn isDacEnabled(self: *const Self) bool {
    return self.envelope.raw & 0xF8 != 0;
 }
--- a/src/core/apu/Wave.zig
+++ b/src/core/apu/Wave.zig
@@ -0,0 +1,145 @@
 const io = @import("../bus/io.zig");
 const util = @import("../../util.zig");
 const Scheduler = @import("../scheduler.zig").Scheduler;
 const FrameSequencer = @import("../apu.zig").FrameSequencer;
 const Tick = @import("../apu.zig").Apu.Tick;
 const Length = @import("device/Length.zig");
 const Wave = @import("signal/Wave.zig");
 const Self = @This();
 /// Write-only
 /// NR30
 select: io.WaveSelect,
 /// NR31
 length: u8,
 /// NR32
 vol: io.WaveVolume,
 /// NR33, NR34
 freq: io.Frequency,
 /// Length Functionarlity
 len_dev: Length,
 wave_dev: Wave,
 enabled: bool,
 sample: i8,
 pub fn init(sched: *Scheduler) Self {
    return .{
        .select = .{ .raw = 0 },
        .vol = .{ .raw = 0 },
        .freq = .{ .raw = 0 },
        .length = 0,
        .len_dev = Length.create(),
        .wave_dev = Wave.init(sched),
        .enabled = false,
        .sample = 0,
    };
 }
 pub fn reset(self: *Self) void {
    self.select.raw = 0; // NR30
    self.length = 0; // NR31
    self.vol.raw = 0; // NR32
    self.freq.raw = 0; // NR33, NR34
    self.len_dev.reset();
    self.wave_dev.reset();
    self.sample = 0;
    self.enabled = false;
 }
 pub fn tick(self: *Self, comptime kind: Tick) void {
    switch (kind) {
        .Length => self.len_dev.tick(self.freq.length_enable.read(), &self.enabled),
        .Envelope => @compileError("Channel 3 does not implement Envelope"),
        .Sweep => @compileError("Channel 3 does not implement Sweep"),
    }
 }
 /// NR30, NR31, NR32
 pub fn setSound3Cnt(self: *Self, value: u32) void {
    self.setSound3CntL(@truncate(u8, value));
    self.setSound3CntH(@truncate(u16, value >> 16));
 }
 /// NR30
 pub fn setSound3CntL(self: *Self, value: u8) void {
    self.select.raw = value;
    if (!self.select.enabled.read()) self.enabled = false;
 }
 /// NR30
 pub fn sound3CntL(self: *const Self) u8 {
    return self.select.raw & 0xE0;
 }
 /// NR31, NR32
 pub fn sound3CntH(self: *const Self) u16 {
    return @as(u16, self.length & 0xE0) << 8;
 }
 /// NR31, NR32
 pub fn setSound3CntH(self: *Self, value: u16) void {
    self.setNr31(@truncate(u8, value));
    self.vol.raw = (@truncate(u8, value >> 8));
 }
 /// NR31
 pub fn setNr31(self: *Self, len: u8) void {
    self.length = len;
    self.len_dev.timer = 256 - @as(u9, len);
 }
 /// NR33, NR34
 pub fn setSound3CntX(self: *Self, fs: *const FrameSequencer, value: u16) void {
    self.setNr33(@truncate(u8, value));
    self.setNr34(fs, @truncate(u8, value >> 8));
 }
 /// NR33, NR34
 pub fn sound3CntX(self: *const Self) u16 {
    return self.freq.raw & 0x4000;
 }
 /// NR33
 pub fn setNr33(self: *Self, byte: u8) void {
    self.freq.raw = (self.freq.raw & 0xFF00) | byte;
 }
 /// NR34
 pub fn setNr34(self: *Self, fs: *const FrameSequencer, byte: u8) void {
    var new: io.Frequency = .{ .raw = (@as(u16, byte) << 8) | (self.freq.raw & 0xFF) };
    if (new.trigger.read()) {
        self.enabled = true;
        if (self.len_dev.timer == 0) {
            self.len_dev.timer =
                if (!fs.isLengthNext() and new.length_enable.read()) 255 else 256;
        }
        // Update The Frequency Timer
        self.wave_dev.reload(self.freq.frequency.read());
        self.wave_dev.offset = 0;
        self.enabled = self.select.enabled.read();
    }
    util.audio.length.update(Self, self, fs, new);
    self.freq = new;
 }
 pub fn onWaveEvent(self: *Self, late: u64) void {
    self.wave_dev.onWaveTimerExpire(self.freq, self.select, late);
    self.sample = 0;
    if (!self.select.enabled.read()) return;
    // Convert unsigned 4-bit wave sample to signed 8-bit sample
    self.sample = (2 * @as(i8, self.wave_dev.sample(self.select)) - 15) >> self.wave_dev.shift(self.vol);
 }
--- a/src/core/apu/device/Envelope.zig
+++ b/src/core/apu/device/Envelope.zig
@@ -0,0 +1,33 @@
 const io = @import("../../bus/io.zig");
 const Self = @This();
 /// Period Timer
 timer: u3,
 /// Current Volume
 vol: u4,
 pub fn create() Self {
    return .{ .timer = 0, .vol = 0 };
 }
 pub fn reset(self: *Self) void {
    self.timer = 0;
    self.vol = 0;
 }
 pub fn tick(self: *Self, nrx2: io.Envelope) void {
    if (nrx2.period.read() != 0) {
        if (self.timer != 0) self.timer -= 1;
        if (self.timer == 0) {
            self.timer = nrx2.period.read();
            if (nrx2.direction.read()) {
                if (self.vol < 0xF) self.vol += 1;
            } else {
                if (self.vol > 0x0) self.vol -= 1;
            }
        }
    }
 }
--- a/src/core/apu/device/Length.zig
+++ b/src/core/apu/device/Length.zig
@@ -0,0 +1,22 @@
 const Self = @This();
 timer: u9,
 pub fn create() Self {
    return .{ .timer = 0 };
 }
 pub fn reset(self: *Self) void {
    self.timer = 0;
 }
 pub fn tick(self: *Self, enabled: bool, ch_enable: *bool) void {
    if (enabled) {
        if (self.timer == 0) return;
        self.timer -= 1;
        // By returning early if timer == 0, this is only
        // true if timer == 0 because of the decrement we just did
        if (self.timer == 0) ch_enable.* = false;
    }
 }
--- a/src/core/apu/device/Sweep.zig
+++ b/src/core/apu/device/Sweep.zig
@@ -0,0 +1,61 @@
 const io = @import("../../bus/io.zig");
 const ToneSweep = @import("../ToneSweep.zig");
 const Self = @This();
 timer: u8,
 enabled: bool,
 shadow: u11,
 calc_performed: bool,
 pub fn create() Self {
    return .{
        .timer = 0,
        .enabled = false,
        .shadow = 0,
        .calc_performed = false,
    };
 }
 pub fn reset(self: *Self) void {
    self.timer = 0;
    self.enabled = false;
    self.shadow = 0;
    self.calc_performed = false;
 }
 pub fn tick(self: *Self, ch1: *ToneSweep) void {
    if (self.timer != 0) self.timer -= 1;
    if (self.timer == 0) {
        const period = ch1.sweep.period.read();
        self.timer = if (period == 0) 8 else period;
        if (self.enabled and period != 0) {
            const new_freq = self.calculate(ch1.sweep, &ch1.enabled);
            if (new_freq <= 0x7FF and ch1.sweep.shift.read() != 0) {
                ch1.freq.frequency.write(@truncate(u11, new_freq));
                self.shadow = @truncate(u11, new_freq);
                _ = self.calculate(ch1.sweep, &ch1.enabled);
            }
        }
    }
 }
 /// Calculates the Sweep Frequency
 pub fn calculate(self: *Self, sweep: io.Sweep, ch_enable: *bool) u12 {
    const shadow = @as(u12, self.shadow);
    const shadow_shifted = shadow >> sweep.shift.read();
    const decrease = sweep.direction.read();
    const freq = if (decrease) blk: {
        self.calc_performed = true;
        break :blk shadow - shadow_shifted;
    } else shadow + shadow_shifted;
    if (freq > 0x7FF) ch_enable.* = false;
    return freq;
 }
--- a/src/core/apu/signal/Lfsr.zig
+++ b/src/core/apu/signal/Lfsr.zig
@@ -0,0 +1,62 @@
 //! Linear Feedback Shift Register
 const io = @import("../../bus/io.zig");
 const Scheduler = @import("../../scheduler.zig").Scheduler;
 const Self = @This();
 pub const interval: u64 = (1 << 24) / (1 << 22);
 shift: u15,
 timer: u16,
 sched: *Scheduler,
 pub fn create(sched: *Scheduler) Self {
    return .{
        .shift = 0,
        .timer = 0,
        .sched = sched,
    };
 }
 pub fn reset(self: *Self) void {
    self.shift = 0;
    self.timer = 0;
 }
 pub fn sample(self: *const Self) i8 {
    return if ((~self.shift & 1) == 1) 1 else -1;
 }
 /// Reload LFSR Timer
 pub fn reload(self: *Self, poly: io.PolyCounter) void {
    self.sched.removeScheduledEvent(.{ .ApuChannel = 3 });
    const div = Self.divisor(poly.div_ratio.read());
    const timer = div << poly.shift.read();
    self.sched.push(.{ .ApuChannel = 3 }, @as(u64, timer) * interval);
 }
 /// Scheduler Event Handler for LFSR Timer Expire
 /// FIXME: This gets called a lot, slowing down the scheduler
 pub fn onLfsrTimerExpire(self: *Self, poly: io.PolyCounter, late: u64) void {
    // Obscure: "Using a noise channel clock shift of 14 or 15
    // results in the LFSR receiving no clocks."
    if (poly.shift.read() >= 14) return;
    const div = Self.divisor(poly.div_ratio.read());
    const timer = div << poly.shift.read();
    const tmp = (self.shift & 1) ^ ((self.shift & 2) >> 1);
    self.shift = (self.shift >> 1) | (tmp << 14);
    if (poly.width.read())
        self.shift = (self.shift & ~@as(u15, 0x40)) | tmp << 6;
    self.sched.push(.{ .ApuChannel = 3 }, @as(u64, timer) * interval -| late);
 }
 fn divisor(code: u3) u16 {
    if (code == 0) return 8;
    return @as(u16, code) << 4;
 }
--- a/src/core/apu/signal/Square.zig
+++ b/src/core/apu/signal/Square.zig
@@ -0,0 +1,62 @@
 const std = @import("std");
 const io = @import("../../bus/io.zig");
 const Scheduler = @import("../../scheduler.zig").Scheduler;
 const ToneSweep = @import("../ToneSweep.zig");
 const Tone = @import("../Tone.zig");
 const Self = @This();
 pub const interval: u64 = (1 << 24) / (1 << 22);
 pos: u3,
 sched: *Scheduler,
 timer: u16,
 pub fn init(sched: *Scheduler) Self {
    return .{
        .timer = 0,
        .pos = 0,
        .sched = sched,
    };
 }
 pub fn reset(self: *Self) void {
    self.timer = 0;
    self.pos = 0;
 }
 /// Scheduler Event Handler for Square Synth Timer Expire
 pub fn onSquareTimerExpire(self: *Self, comptime T: type, nrx34: io.Frequency, late: u64) void {
    comptime std.debug.assert(T == ToneSweep or T == Tone);
    self.pos +%= 1;
    self.timer = (@as(u16, 2048) - nrx34.frequency.read()) * 4;
    self.sched.push(.{ .ApuChannel = if (T == ToneSweep) 0 else 1 }, @as(u64, self.timer) * interval -| late);
 }
 /// Reload Square Wave Timer
 pub fn reload(self: *Self, comptime T: type, value: u11) void {
    comptime std.debug.assert(T == ToneSweep or T == Tone);
    const channel = if (T == ToneSweep) 0 else 1;
    self.sched.removeScheduledEvent(.{ .ApuChannel = channel });
    const tmp = (@as(u16, 2048) - value) * 4; // What Freq Timer should be assuming no weird behaviour
    self.timer = (tmp & ~@as(u16, 0x3)) | self.timer & 0x3; // Keep the last two bits from the old timer;
    self.sched.push(.{ .ApuChannel = channel }, @as(u64, self.timer) * interval);
 }
 pub fn sample(self: *const Self, nrx1: io.Duty) i8 {
    const pattern = nrx1.pattern.read();
    const i = self.pos ^ 7; // index of 0 should get highest bit
    const result = switch (pattern) {
        0b00 => @as(u8, 0b00000001) >> i, // 12.5%
        0b01 => @as(u8, 0b00000011) >> i, // 25%
        0b10 => @as(u8, 0b00001111) >> i, // 50%
        0b11 => @as(u8, 0b11111100) >> i, // 75%
    };
    return if (result & 1 == 1) 1 else -1;
 }
--- a/src/core/apu/signal/Wave.zig
+++ b/src/core/apu/signal/Wave.zig
@@ -0,0 +1,84 @@
 const std = @import("std");
 const io = @import("../../bus/io.zig");
 const Scheduler = @import("../../scheduler.zig").Scheduler;
 const buf_len = 0x20;
 pub const interval: u64 = (1 << 24) / (1 << 22);
 const Self = @This();
 buf: [buf_len]u8,
 timer: u16,
 offset: u12,
 sched: *Scheduler,
 pub fn read(self: *const Self, comptime T: type, nr30: io.WaveSelect, addr: u32) T {
    // TODO: Handle reads when Channel 3 is disabled
    const base = if (!nr30.bank.read()) @as(u32, 0x10) else 0; // Read from the Opposite Bank in Use
    const i = base + addr - 0x0400_0090;
    return std.mem.readIntSliceLittle(T, self.buf[i..][0..@sizeOf(T)]);
 }
 pub fn write(self: *Self, comptime T: type, nr30: io.WaveSelect, addr: u32, value: T) void {
    // TODO: Handle writes when Channel 3 is disabled
    const base = if (!nr30.bank.read()) @as(u32, 0x10) else 0; // Write to the Opposite Bank in Use
    const i = base + addr - 0x0400_0090;
    std.mem.writeIntSliceLittle(T, self.buf[i..][0..@sizeOf(T)], value);
 }
 pub fn init(sched: *Scheduler) Self {
    return .{
        .buf = [_]u8{0x00} ** buf_len,
        .timer = 0,
        .offset = 0,
        .sched = sched,
    };
 }
 pub fn reset(self: *Self) void {
    self.timer = 0;
    self.offset = 0;
    // sample buffer isn't reset because it's outside of the range of what NR52{7}'s effects
 }
 /// Reload internal Wave Timer
 pub fn reload(self: *Self, value: u11) void {
    self.sched.removeScheduledEvent(.{ .ApuChannel = 2 });
    self.timer = (@as(u16, 2048) - value) * 2;
    self.sched.push(.{ .ApuChannel = 2 }, @as(u64, self.timer) * interval);
 }
 /// Scheduler Event Handler
 pub fn onWaveTimerExpire(self: *Self, nrx34: io.Frequency, nr30: io.WaveSelect, late: u64) void {
    if (nr30.dimension.read()) {
        self.offset = (self.offset + 1) % 0x40; // 0x20 bytes (both banks), which contain 2 samples each
    } else {
        self.offset = (self.offset + 1) % 0x20; // 0x10 bytes, which contain 2 samples each
    }
    self.timer = (@as(u16, 2048) - nrx34.frequency.read()) * 2;
    self.sched.push(.{ .ApuChannel = 2 }, @as(u64, self.timer) * interval -| late);
 }
 /// Generate Sample from Wave Synth
 pub fn sample(self: *const Self, nr30: io.WaveSelect) u4 {
    const base = if (nr30.bank.read()) @as(u32, 0x10) else 0;
    const value = self.buf[base + self.offset / 2];
    return if (self.offset & 1 == 0) @truncate(u4, value >> 4) else @truncate(u4, value);
 }
 /// TODO: Write comment
 pub fn shift(_: *const Self, nr32: io.WaveVolume) u2 {
    return switch (nr32.kind.read()) {
        0b00 => 3, // Mute / Zero
        0b01 => 0, // 100% Volume
        0b10 => 1, // 50% Volume
        0b11 => 2, // 25% Volume
    };
 }
--- a/src/core/bus/Bios.zig
+++ b/src/core/bus/Bios.zig
@@ -8,56 +8,56 @@ pub const size = 0x4000;
 const Self = @This();
 buf: ?[]u8,
-alloc: Allocator,
+allocator: Allocator,
 addr_latch: u32,
 pub fn init(alloc: Allocator, maybe_path: ?[]const u8) !Self {
    var buf: ?[]u8 = null;
    if (maybe_path) |path| {
        const file = try std.fs.cwd().openFile(path, .{});
        defer file.close();
        buf = try file.readToEndAlloc(alloc, try file.getEndPos());
    }
    return Self{
        .buf = buf,
        .alloc = alloc,
        .addr_latch = 0,
    };
 }
 pub fn deinit(self: Self) void {
    if (self.buf) |buf| self.alloc.free(buf);
 }
 pub fn read(self: *Self, comptime T: type, r15: u32, addr: u32) T {
    if (r15 < Self.size) {
        self.addr_latch = addr;
-        return self.uncheckedRead(T, addr);
+        return self._read(T, addr);
    }
    log.debug("Rejected read since r15=0x{X:0>8}", .{r15});
-    return @truncate(T, self.uncheckedRead(T, self.addr_latch + 8));
+    return @truncate(T, self._read(T, self.addr_latch));
 }
 pub fn dbgRead(self: *const Self, comptime T: type, r15: u32, addr: u32) T {
-    if (r15 < Self.size) return self.uncheckedRead(T, addr);
+    if (r15 < Self.size) return self._read(T, addr);
-    return @truncate(T, self.uncheckedRead(T, self.addr_latch + 8));
+    return @truncate(T, self._read(T, self.addr_latch + 8));
 }
-fn uncheckedRead(self: *const Self, comptime T: type, addr: u32) T {
+/// Read without the GBA safety checks
-    if (self.buf) |buf| {
+fn _read(self: *const Self, comptime T: type, addr: u32) T {
-        return switch (T) {
+    const buf = self.buf orelse std.debug.panic("[BIOS] ZBA tried to read {} from 0x{X:0>8} but not BIOS was present", .{ T, addr });
            u32, u16, u8 => std.mem.readIntSliceLittle(T, buf[addr..][0..@sizeOf(T)]),
            else => @compileError("BIOS: Unsupported read width"),
        };
    }
-    std.debug.panic("[BIOS] ZBA tried to read {} from 0x{X:0>8} but not BIOS was present", .{ T, addr });
+    return switch (T) {
        u32, u16, u8 => std.mem.readIntSliceLittle(T, buf[addr..][0..@sizeOf(T)]),
        else => @compileError("BIOS: Unsupported read width"),
    };
 }
 pub fn write(_: *Self, comptime T: type, addr: u32, value: T) void {
    @setCold(true);
    log.debug("Tried to write {} 0x{X:} to 0x{X:0>8} ", .{ T, value, addr });
 }
 pub fn init(allocator: Allocator, maybe_path: ?[]const u8) !Self {
    const buf: ?[]u8 = if (maybe_path) |path| blk: {
        const file = try std.fs.cwd().openFile(path, .{});
        defer file.close();
        break :blk try file.readToEndAlloc(allocator, try file.getEndPos());
    } else null;
    return Self{
        .buf = buf,
        .allocator = allocator,
        .addr_latch = 0,
    };
 }
 pub fn deinit(self: *Self) void {
    if (self.buf) |buf| self.allocator.free(buf);
    self.* = undefined;
 }
--- a/src/core/bus/Ewram.zig
+++ b/src/core/bus/Ewram.zig
@@ -5,21 +5,7 @@ const ewram_size = 0x40000;
 const Self = @This();
 buf: []u8,
-alloc: Allocator,
+allocator: Allocator,
 pub fn init(alloc: Allocator) !Self {
    const buf = try alloc.alloc(u8, ewram_size);
    std.mem.set(u8, buf, 0);
    return Self{
        .buf = buf,
        .alloc = alloc,
    };
 }
 pub fn deinit(self: Self) void {
    self.alloc.free(self.buf);
 }
 pub fn read(self: *const Self, comptime T: type, address: usize) T {
    const addr = address & 0x3FFFF;
@@ -38,3 +24,18 @@ pub fn write(self: *const Self, comptime T: type, address: usize, value: T) void
        else => @compileError("EWRAM: Unsupported write width"),
    };
 }
 pub fn init(allocator: Allocator) !Self {
    const buf = try allocator.alloc(u8, ewram_size);
    std.mem.set(u8, buf, 0);
    return Self{
        .buf = buf,
        .allocator = allocator,
    };
 }
 pub fn deinit(self: *Self) void {
    self.allocator.free(self.buf);
    self.* = undefined;
 }
--- a/src/core/bus/GamePak.zig
+++ b/src/core/bus/GamePak.zig
@@ -1,73 +1,26 @@
 const std = @import("std");
 const config = @import("../../config.zig");
 const Arm7tdmi = @import("../cpu.zig").Arm7tdmi;
 const Backup = @import("backup.zig").Backup;
 const Gpio = @import("gpio.zig").Gpio;
 const Allocator = std.mem.Allocator;
 const log = std.log.scoped(.GamePak);
 const Self = @This();
 title: [12]u8,
 buf: []u8,
-alloc: Allocator,
+allocator: Allocator,
 backup: Backup,
-
+gpio: *Gpio,
 pub fn init(alloc: Allocator, rom_path: []const u8, save_path: ?[]const u8) !Self {
    const file = try std.fs.cwd().openFile(rom_path, .{});
    defer file.close();
    const file_buf = try file.readToEndAlloc(alloc, try file.getEndPos());
    const title = parseTitle(file_buf);
    const kind = Backup.guessKind(file_buf) orelse .None;
    const pak = Self{
        .buf = file_buf,
        .alloc = alloc,
        .title = title,
        .backup = try Backup.init(alloc, kind, title, save_path),
    };
    pak.parseHeader();
    return pak;
 }
 fn parseHeader(self: *const Self) void {
    const title = parseTitle(self.buf);
    const code = self.buf[0xAC..0xB0];
    const maker = self.buf[0xB0..0xB2];
    const version = self.buf[0xBC];
    log.info("Title: {s}", .{title});
    if (version != 0) log.info("Version: {}", .{version});
    log.info("Game Code: {s}", .{code});
    if (lookupMaker(maker)) |c| log.info("Maker: {s}", .{c}) else log.info("Maker Code: {s}", .{maker});
 }
 fn parseTitle(buf: []u8) [12]u8 {
    return buf[0xA0..0xAC].*;
 }
 fn lookupMaker(slice: *const [2]u8) ?[]const u8 {
    const id = @as(u16, slice[1]) << 8 | @as(u16, slice[0]);
    return switch (id) {
        0x3130 => "Nintendo",
        else => null,
    };
 }
 inline fn isLarge(self: *const Self) bool {
    return self.buf.len > 0x100_0000;
 }
 pub fn deinit(self: Self) void {
    self.alloc.free(self.buf);
    self.backup.deinit();
 }
 pub fn read(self: *Self, comptime T: type, address: u32) T {
    const addr = address & 0x1FF_FFFF;
    if (self.backup.kind == .Eeprom) {
-        if (self.isLarge()) {
+        if (self.buf.len > 0x100_0000) { // Large
            // Addresses 0x1FF_FF00 to 0x1FF_FFFF are reserved from EEPROM accesses if
            // * Backup type is EEPROM
            // * Large ROM (Size is greater than 16MB)
@@ -82,6 +35,35 @@ pub fn read(self: *Self, comptime T: type, address: u32) T {
        }
    }
    if (self.gpio.cnt == 1) {
        // GPIO Can be read from
        // We assume that this will only be true when a ROM actually does want something from GPIO
        switch (T) {
            u32 => switch (address) {
                // TODO: Do I even need to implement these?
                0x0800_00C4 => std.debug.panic("Handle 32-bit GPIO Data/Direction Reads", .{}),
                0x0800_00C6 => std.debug.panic("Handle 32-bit GPIO Direction/Control Reads", .{}),
                0x0800_00C8 => std.debug.panic("Handle 32-bit GPIO Control Reads", .{}),
                else => {},
            },
            u16 => switch (address) {
                // FIXME: What do 16-bit GPIO Reads look like?
                0x0800_00C4 => return self.gpio.read(.Data),
                0x0800_00C6 => return self.gpio.read(.Direction),
                0x0800_00C8 => return self.gpio.read(.Control),
                else => {},
            },
            u8 => switch (address) {
                0x0800_00C4 => return self.gpio.read(.Data),
                0x0800_00C6 => return self.gpio.read(.Direction),
                0x0800_00C8 => return self.gpio.read(.Control),
                else => {},
            },
            else => @compileError("GamePak[GPIO]: Unsupported read width"),
        }
    }
    return switch (T) {
        u32 => (@as(T, self.get(addr + 3)) << 24) | (@as(T, self.get(addr + 2)) << 16) | (@as(T, self.get(addr + 1)) << 8) | (@as(T, self.get(addr))),
        u16 => (@as(T, self.get(addr + 1)) << 8) | @as(T, self.get(addr)),
@@ -90,11 +72,19 @@ pub fn read(self: *Self, comptime T: type, address: u32) T {
    };
 }
 inline fn get(self: *const Self, i: u32) u8 {
    @setRuntimeSafety(false);
    if (i < self.buf.len) return self.buf[i];
    const lhs = i >> 1 & 0xFFFF;
    return @truncate(u8, lhs >> 8 * @truncate(u5, i & 1));
 }
 pub fn dbgRead(self: *const Self, comptime T: type, address: u32) T {
    const addr = address & 0x1FF_FFFF;
    if (self.backup.kind == .Eeprom) {
-        if (self.isLarge()) {
+        if (self.buf.len > 0x100_0000) { // Large
            // Addresses 0x1FF_FF00 to 0x1FF_FFFF are reserved from EEPROM accesses if
            // * Backup type is EEPROM
            // * Large ROM (Size is greater than 16MB)
@@ -109,6 +99,34 @@ pub fn dbgRead(self: *const Self, comptime T: type, address: u32) T {
        }
    }
    if (self.gpio.cnt == 1) {
        // GPIO Can be read from
        // We assume that this will only be true when a ROM actually does want something from GPIO
        switch (T) {
            u32 => switch (address) {
                // FIXME: Do I even need to implement these?
                0x0800_00C4 => std.debug.panic("Handle 32-bit GPIO Data/Direction Reads", .{}),
                0x0800_00C6 => std.debug.panic("Handle 32-bit GPIO Direction/Control Reads", .{}),
                0x0800_00C8 => std.debug.panic("Handle 32-bit GPIO Control Reads", .{}),
                else => {},
            },
            u16 => switch (address) {
                0x0800_00C4 => return self.gpio.read(.Data),
                0x0800_00C6 => return self.gpio.read(.Direction),
                0x0800_00C8 => return self.gpio.read(.Control),
                else => {},
            },
            u8 => switch (address) {
                0x0800_00C4 => return self.gpio.read(.Data),
                0x0800_00C6 => return self.gpio.read(.Direction),
                0x0800_00C8 => return self.gpio.read(.Control),
                else => {},
            },
            else => @compileError("GamePak[GPIO]: Unsupported read width"),
        }
    }
    return switch (T) {
        u32 => (@as(T, self.get(addr + 3)) << 24) | (@as(T, self.get(addr + 2)) << 16) | (@as(T, self.get(addr + 1)) << 8) | (@as(T, self.get(addr))),
        u16 => (@as(T, self.get(addr + 1)) << 8) | @as(T, self.get(addr)),
@@ -123,7 +141,7 @@ pub fn write(self: *Self, comptime T: type, word_count: u16, address: u32, value
    if (self.backup.kind == .Eeprom) {
        const bit = @truncate(u1, value);
-        if (self.isLarge()) {
+        if (self.buf.len > 0x100_0000) { // Large
            // Addresses 0x1FF_FF00 to 0x1FF_FFFF are reserved from EEPROM accesses if
            // * Backup type is EEPROM
            // * Large ROM (Size is greater than 16MB)
@@ -140,27 +158,80 @@ pub fn write(self: *Self, comptime T: type, word_count: u16, address: u32, value
    switch (T) {
        u32 => switch (address) {
-            0x0800_00C4 => log.debug("Wrote {} 0x{X:} to I/O Port Data and Direction", .{ T, value }),
+            0x0800_00C4 => {
-            0x0800_00C6 => log.debug("Wrote {} 0x{X:} to I/O Port Direction and Control", .{ T, value }),
+                self.gpio.write(.Data, @truncate(u4, value));
-            else => {},
+                self.gpio.write(.Direction, @truncate(u4, value >> 16));
            },
            0x0800_00C6 => {
                self.gpio.write(.Direction, @truncate(u4, value));
                self.gpio.write(.Control, @truncate(u1, value >> 16));
            },
            else => log.err("Wrote {} 0x{X:0>8} to 0x{X:0>8}, Unhandled", .{ T, value, address }),
        },
        u16 => switch (address) {
-            0x0800_00C4 => log.debug("Wrote {} 0x{X:} to I/O Port Data", .{ T, value }),
+            0x0800_00C4 => self.gpio.write(.Data, @truncate(u4, value)),
-            0x0800_00C6 => log.debug("Wrote {} 0x{X:} to I/O Port Direction", .{ T, value }),
+            0x0800_00C6 => self.gpio.write(.Direction, @truncate(u4, value)),
-            0x0800_00C8 => log.debug("Wrote {} 0x{X:} to I/O Port Control", .{ T, value }),
+            0x0800_00C8 => self.gpio.write(.Control, @truncate(u1, value)),
-            else => {},
+            else => log.err("Wrote {} 0x{X:0>4} to 0x{X:0>8}, Unhandled", .{ T, value, address }),
        },
-        u8 => log.debug("Wrote {} 0x{X:} to 0x{X:0>8}, Ignored.", .{ T, value, address }),
+        u8 => log.debug("Wrote {} 0x{X:0>2} to 0x{X:0>8}, Ignored.", .{ T, value, address }),
        else => @compileError("GamePak: Unsupported write width"),
    }
 }
-fn get(self: *const Self, i: u32) u8 {
+pub fn init(allocator: Allocator, cpu: *Arm7tdmi, rom_path: []const u8, save_path: ?[]const u8) !Self {
-    @setRuntimeSafety(false);
+    const file = try std.fs.cwd().openFile(rom_path, .{});
-    if (i < self.buf.len) return self.buf[i];
+    defer file.close();
-    const lhs = i >> 1 & 0xFFFF;
+    const file_buf = try file.readToEndAlloc(allocator, try file.getEndPos());
-    return @truncate(u8, lhs >> 8 * @truncate(u5, i & 1));
+    const title = file_buf[0xA0..0xAC].*;
    const kind = Backup.guess(file_buf);
    const device = if (config.config().guest.force_rtc) .Rtc else guessDevice(file_buf);
    logHeader(file_buf, &title);
    return .{
        .buf = file_buf,
        .allocator = allocator,
        .title = title,
        .backup = try Backup.init(allocator, kind, title, save_path),
        .gpio = try Gpio.init(allocator, cpu, device),
    };
 }
 pub fn deinit(self: *Self) void {
    self.backup.deinit();
    self.gpio.deinit(self.allocator);
    self.allocator.destroy(self.gpio);
    self.allocator.free(self.buf);
    self.* = undefined;
 }
 /// Searches the ROM to see if it can determine whether the ROM it's searching uses
 /// any GPIO device, like a RTC for example.
 fn guessDevice(buf: []const u8) Gpio.Device.Kind {
    // Try to Guess if ROM uses RTC
    const needle = "RTC_V"; // I was told SIIRTC_V, though Pokemen Firered (USA) is a false negative
    var i: usize = 0;
    while ((i + needle.len) < buf.len) : (i += 1) {
        if (std.mem.eql(u8, needle, buf[i..(i + needle.len)])) return .Rtc;
    }
    // TODO: Detect other GPIO devices
    return .None;
 }
 fn logHeader(buf: []const u8, title: *const [12]u8) void {
    const code = buf[0xAC..0xB0];
    const maker = buf[0xB0..0xB2];
    const version = buf[0xBC];
    log.info("Title: {s}", .{title});
    if (version != 0) log.info("Version: {}", .{version});
    log.info("Game Code: {s}", .{code});
    log.info("Maker Code: {s}", .{maker});
 }
 test "OOB Access" {
--- a/src/core/bus/Iwram.zig
+++ b/src/core/bus/Iwram.zig
@@ -5,21 +5,7 @@ const iwram_size = 0x8000;
 const Self = @This();
 buf: []u8,
-alloc: Allocator,
+allocator: Allocator,
 pub fn init(alloc: Allocator) !Self {
    const buf = try alloc.alloc(u8, iwram_size);
    std.mem.set(u8, buf, 0);
    return Self{
        .buf = buf,
        .alloc = alloc,
    };
 }
 pub fn deinit(self: Self) void {
    self.alloc.free(self.buf);
 }
 pub fn read(self: *const Self, comptime T: type, address: usize) T {
    const addr = address & 0x7FFF;
@@ -38,3 +24,18 @@ pub fn write(self: *const Self, comptime T: type, address: usize, value: T) void
        else => @compileError("IWRAM: Unsupported write width"),
    };
 }
 pub fn init(allocator: Allocator) !Self {
    const buf = try allocator.alloc(u8, iwram_size);
    std.mem.set(u8, buf, 0);
    return Self{
        .buf = buf,
        .allocator = allocator,
    };
 }
 pub fn deinit(self: *Self) void {
    self.allocator.free(self.buf);
    self.* = undefined;
 }
--- a/src/core/bus/backup.zig
+++ b/src/core/bus/backup.zig
@@ -2,23 +2,29 @@ const std = @import("std");
 const Allocator = std.mem.Allocator;
 const log = std.log.scoped(.Backup);
-const escape = @import("../util.zig").escape;
+const Eeprom = @import("backup/eeprom.zig").Eeprom;
-const asString = @import("../util.zig").asString;
+const Flash = @import("backup/Flash.zig");
-const backup_kinds = [5]Needle{
+const escape = @import("../../util.zig").escape;
 const Needle = struct { str: []const u8, kind: Backup.Kind };
 const backup_kinds = [6]Needle{
    .{ .str = "EEPROM_V", .kind = .Eeprom },
    .{ .str = "SRAM_V", .kind = .Sram },
    .{ .str = "SRAM_F_V", .kind = .Sram },
    .{ .str = "FLASH_V", .kind = .Flash },
    .{ .str = "FLASH512_V", .kind = .Flash },
    .{ .str = "FLASH1M_V", .kind = .Flash1M },
 };
 const SaveError = error{Unsupported};
 pub const Backup = struct {
    const Self = @This();
    buf: []u8,
-    alloc: Allocator,
+    allocator: Allocator,
-    kind: BackupKind,
+    kind: Kind,
    title: [12]u8,
    save_path: ?[]const u8,
@@ -26,120 +32,13 @@ pub const Backup = struct {
    flash: Flash,
    eeprom: Eeprom,
-    pub fn init(alloc: Allocator, kind: BackupKind, title: [12]u8, path: ?[]const u8) !Self {
+    const Kind = enum {
-        log.info("Kind: {}", .{kind});
+        Eeprom,
-
+        Sram,
-        const buf_size: usize = switch (kind) {
+        Flash,
-            .Sram => 0x8000, // 32K
+        Flash1M,
-            .Flash => 0x10000, // 64K
+        None,
-            .Flash1M => 0x20000, // 128K
+    };
            .None, .Eeprom => 0, // EEPROM is handled upon first Read Request to it
        };
        const buf = try alloc.alloc(u8, buf_size);
        std.mem.set(u8, buf, 0xFF);
        var backup = Self{
            .buf = buf,
            .alloc = alloc,
            .kind = kind,
            .title = title,
            .save_path = path,
            .flash = Flash.init(),
            .eeprom = Eeprom.init(alloc),
        };
        if (backup.save_path) |p| backup.loadSaveFromDisk(p) catch |e| log.err("Failed to load save: {}", .{e});
        return backup;
    }
    pub fn guessKind(rom: []const u8) ?BackupKind {
        for (backup_kinds) |needle| {
            const needle_len = needle.str.len;
            var i: usize = 0;
            while ((i + needle_len) < rom.len) : (i += 1) {
                if (std.mem.eql(u8, needle.str, rom[i..][0..needle_len])) return needle.kind;
            }
        }
        return null;
    }
    pub fn deinit(self: Self) void {
        if (self.save_path) |path| self.writeSaveToDisk(path) catch |e| log.err("Failed to write save: {}", .{e});
        self.alloc.free(self.buf);
    }
    fn loadSaveFromDisk(self: *Self, path: []const u8) !void {
        const file_path = try self.getSaveFilePath(path);
        defer self.alloc.free(file_path);
        // FIXME: Don't rely on this lol
        if (std.mem.eql(u8, file_path[file_path.len - 12 .. file_path.len], "untitled.sav")) {
            return log.err("ROM header lacks title, no save loaded", .{});
        }
        const file: std.fs.File = try std.fs.openFileAbsolute(file_path, .{});
        const file_buf = try file.readToEndAlloc(self.alloc, try file.getEndPos());
        defer self.alloc.free(file_buf);
        switch (self.kind) {
            .Sram, .Flash, .Flash1M => {
                if (self.buf.len == file_buf.len) {
                    std.mem.copy(u8, self.buf, file_buf);
                    return log.info("Loaded Save from {s}", .{file_path});
                }
                log.err("{s} is {} bytes, but we expected {} bytes", .{ file_path, file_buf.len, self.buf.len });
            },
            .Eeprom => {
                if (file_buf.len == 0x200 or file_buf.len == 0x2000) {
                    self.eeprom.kind = if (file_buf.len == 0x200) .Small else .Large;
                    self.buf = try self.alloc.alloc(u8, file_buf.len);
                    std.mem.copy(u8, self.buf, file_buf);
                    return log.info("Loaded Save from {s}", .{file_path});
                }
                log.err("EEPROM can either be 0x200 bytes or 0x2000 byes, but {s} was {X:} bytes", .{
                    file_path,
                    file_buf.len,
                });
            },
            .None => return SaveError.UnsupportedBackupKind,
        }
    }
    fn getSaveFilePath(self: *const Self, path: []const u8) ![]const u8 {
        const filename = try self.getSaveFilename();
        defer self.alloc.free(filename);
        return try std.fs.path.join(self.alloc, &[_][]const u8{ path, filename });
    }
    fn getSaveFilename(self: *const Self) ![]const u8 {
        const title = asString(escape(self.title));
        const name = if (title.len != 0) title else "untitled";
        return try std.mem.concat(self.alloc, u8, &[_][]const u8{ name, ".sav" });
    }
    fn writeSaveToDisk(self: Self, path: []const u8) !void {
        const file_path = try self.getSaveFilePath(path);
        defer self.alloc.free(file_path);
        switch (self.kind) {
            .Sram, .Flash, .Flash1M, .Eeprom => {
                const file = try std.fs.createFileAbsolute(file_path, .{});
                defer file.close();
                try file.writeAll(self.buf);
                log.info("Wrote Save to {s}", .{file_path});
            },
            else => return SaveError.UnsupportedBackupKind,
        }
    }
    pub fn read(self: *const Self, address: usize) u8 {
        const addr = address & 0xFFFF;
@@ -174,7 +73,7 @@ pub const Backup = struct {
        switch (self.kind) {
            .Flash, .Flash1M => {
                if (self.flash.prep_write) return self.flash.write(self.buf, addr, byte);
-                if (self.flash.shouldEraseSector(addr, byte)) return self.flash.eraseSector(self.buf, addr);
+                if (self.flash.shouldEraseSector(addr, byte)) return self.flash.erase(self.buf, addr);
                switch (addr) {
                    0x0000 => if (self.kind == .Flash1M and self.flash.set_bank) {
@@ -199,366 +98,121 @@ pub const Backup = struct {
            .None, .Eeprom => {},
        }
    }
 };
-const BackupKind = enum {
+    pub fn init(allocator: Allocator, kind: Kind, title: [12]u8, path: ?[]const u8) !Self {
-    Eeprom,
+        log.info("Kind: {}", .{kind});
    Sram,
    Flash,
    Flash1M,
    None,
 };
-const Needle = struct {
+        const buf_size: usize = switch (kind) {
-    const Self = @This();
+            .Sram => 0x8000, // 32K
            .Flash => 0x10000, // 64K
            .Flash1M => 0x20000, // 128K
            .None, .Eeprom => 0, // EEPROM is handled upon first Read Request to it
        };
-    str: []const u8,
+        const buf = try allocator.alloc(u8, buf_size);
-    kind: BackupKind,
+        std.mem.set(u8, buf, 0xFF);
-    fn init(str: []const u8, kind: BackupKind) Self {
+        var backup = Self{
-        return .{
+            .buf = buf,
-            .str = str,
+            .allocator = allocator,
            .kind = kind,
            .title = title,
            .save_path = path,
            .flash = Flash.create(),
            .eeprom = Eeprom.create(allocator),
        };
    }
 };
-const SaveError = error{
+        if (backup.save_path) |p| backup.readSave(allocator, p) catch |e| log.err("Failed to load save: {}", .{e});
-    UnsupportedBackupKind,
+        return backup;
 };
 const Flash = struct {
    const Self = @This();
    state: FlashState,
    id_mode: bool,
    set_bank: bool,
    prep_erase: bool,
    prep_write: bool,
    bank: u1,
    fn init() Self {
        return .{
            .state = .Ready,
            .id_mode = false,
            .set_bank = false,
            .prep_erase = false,
            .prep_write = false,
            .bank = 0,
        };
    }
-    fn handleCommand(self: *Self, buf: []u8, byte: u8) void {
+    pub fn deinit(self: *Self) void {
-        switch (byte) {
+        if (self.save_path) |path| self.writeSave(self.allocator, path) catch |e| log.err("Failed to write save: {}", .{e});
-            0x90 => self.id_mode = true,
+        self.allocator.free(self.buf);
-            0xF0 => self.id_mode = false,
+        self.* = undefined;
            0xB0 => self.set_bank = true,
            0x80 => self.prep_erase = true,
            0x10 => {
                std.mem.set(u8, buf, 0xFF);
                self.prep_erase = false;
            },
            0xA0 => self.prep_write = true,
            else => std.debug.panic("Unhandled Flash Command: 0x{X:0>2}", .{byte}),
        }
        self.state = .Ready;
    }
-    fn shouldEraseSector(self: *const Self, addr: usize, byte: u8) bool {
+    /// Guesses the Backup Kind of a GBA ROM
-        return self.state == .Command and self.prep_erase and byte == 0x30 and addr & 0xFFF == 0x000;
+    pub fn guess(rom: []const u8) Kind {
-    }
+        for (backup_kinds) |needle| {
            const needle_len = needle.str.len;
-    fn write(self: *Self, buf: []u8, idx: usize, byte: u8) void {
+            var i: usize = 0;
-        buf[self.baseAddress() + idx] = byte;
+            while ((i + needle_len) < rom.len) : (i += 1) {
-        self.prep_write = false;
+                if (std.mem.eql(u8, needle.str, rom[i..][0..needle_len])) return needle.kind;
    }
    fn read(self: *const Self, buf: []u8, idx: usize) u8 {
        return buf[self.baseAddress() + idx];
    }
    fn eraseSector(self: *Self, buf: []u8, idx: usize) void {
        const start = self.baseAddress() + (idx & 0xF000);
        std.mem.set(u8, buf[start..][0..0x1000], 0xFF);
        self.prep_erase = false;
        self.state = .Ready;
    }
    inline fn baseAddress(self: *const Self) usize {
        return if (self.bank == 1) 0x10000 else @as(usize, 0);
    }
 };
 const FlashState = enum {
    Ready,
    Set,
    Command,
 };
 const Eeprom = struct {
    const Self = @This();
    addr: u14,
    kind: Kind,
    state: State,
    writer: Writer,
    reader: Reader,
    alloc: Allocator,
    const Kind = enum {
        Unknown,
        Small, // 512B
        Large, // 8KB
    };
    const State = enum {
        Ready,
        Read,
        Write,
        WriteTransfer,
        RequestEnd,
    };
    fn init(alloc: Allocator) Self {
        return .{
            .kind = .Unknown,
            .state = .Ready,
            .writer = Writer.init(),
            .reader = Reader.init(),
            .addr = 0,
            .alloc = alloc,
        };
    }
    pub fn read(self: *Self) u1 {
        return self.reader.read();
    }
    pub fn dbgRead(self: *const Self) u1 {
        return self.reader.dbgRead();
    }
    pub fn write(self: *Self, word_count: u16, buf: *[]u8, bit: u1) void {
        if (self.guessKind(word_count)) |found| {
            log.info("EEPROM Kind: {}", .{found});
            self.kind = found;
            // buf.len will not equal zero when a save file was found and loaded.
            // Right now, we assume that the save file is of the correct size which
            // isn't necessarily true, since we can't trust anything a user can influence
            // TODO: use ?[]u8 instead of a 0-sized slice?
            if (buf.len == 0) {
                const len: usize = switch (found) {
                    .Small => 0x200,
                    .Large => 0x2000,
                    else => unreachable,
                };
                buf.* = self.alloc.alloc(u8, len) catch |e| {
                    log.err("Failed to resize EEPROM buf to {} bytes", .{len});
                    std.debug.panic("EEPROM entered irrecoverable state {}", .{e});
                };
                std.mem.set(u8, buf.*, 0xFF);
            }
        }
-        if (self.state == .RequestEnd) {
+        return .None;
            if (bit != 0) log.debug("EEPROM Request did not end in 0u1. TODO: is this ok?", .{});
            self.state = .Ready;
            return;
        }
        switch (self.state) {
            .Ready => self.writer.requestWrite(bit),
            .Read, .Write => self.writer.addressWrite(self.kind, bit),
            .WriteTransfer => self.writer.dataWrite(bit),
            .RequestEnd => unreachable, // We return early just above this block
        }
        self.tick(buf.*);
    }
-    fn guessKind(self: *const Self, word_count: u16) ?Kind {
+    fn readSave(self: *Self, allocator: Allocator, path: []const u8) !void {
-        if (self.kind != .Unknown or self.state != .Read) return null;
+        const file_path = try self.savePath(allocator, path);
        defer allocator.free(file_path);
-        return switch (word_count) {
+        const expected = "untitled.sav";
-            17 => .Large,
+        if (std.mem.eql(u8, file_path[file_path.len - expected.len .. file_path.len], expected)) {
-            9 => .Small,
+            return log.err("ROM header lacks title, no save loaded", .{});
-            else => blk: {
+        }
                log.err("Unexpected length of DMA3 Transfer upon initial EEPROM read: {}", .{word_count});
                break :blk null;
            },
        };
    }
-    fn tick(self: *Self, buf: []u8) void {
+        const file: std.fs.File = try std.fs.openFileAbsolute(file_path, .{});
-        switch (self.state) {
+        const file_buf = try file.readToEndAlloc(allocator, try file.getEndPos());
-            .Ready => {
+        defer allocator.free(file_buf);
                if (self.writer.len() == 2) {
                    const req = @intCast(u2, self.writer.finish());
                    switch (req) {
                        0b11 => self.state = .Read,
                        0b10 => self.state = .Write,
                        else => log.err("Unknown EEPROM Request 0b{b:0>2}", .{req}),
                    }
                }
            },
            .Read => {
                switch (self.kind) {
                    .Large => {
                        if (self.writer.len() == 14) {
                            const addr = @intCast(u10, self.writer.finish());
                            const value = std.mem.readIntSliceLittle(u64, buf[@as(u13, addr) * 8 ..][0..8]);
-                            self.reader.configure(value);
+        switch (self.kind) {
-                            self.state = .RequestEnd;
+            .Sram, .Flash, .Flash1M => {
-                        }
+                if (self.buf.len == file_buf.len) {
-                    },
+                    std.mem.copy(u8, self.buf, file_buf);
-                    .Small => {
+                    return log.info("Loaded Save from {s}", .{file_path});
-                        if (self.writer.len() == 6) {
+                }
                            // FIXME: Duplicated code from above
                            const addr = @intCast(u6, self.writer.finish());
                            const value = std.mem.readIntSliceLittle(u64, buf[@as(u13, addr) * 8 ..][0..8]);
-                            self.reader.configure(value);
+                log.err("{s} is {} bytes, but we expected {} bytes", .{ file_path, file_buf.len, self.buf.len });
                            self.state = .RequestEnd;
                        }
                    },
                    else => log.err("Unable to calculate EEPROM read address. EEPROM size UNKNOWN", .{}),
                }
            },
-            .Write => {
+            .Eeprom => {
-                switch (self.kind) {
+                if (file_buf.len == 0x200 or file_buf.len == 0x2000) {
-                    .Large => {
+                    self.eeprom.kind = if (file_buf.len == 0x200) .Small else .Large;
-                        if (self.writer.len() == 14) {
+
-                            self.addr = @intCast(u10, self.writer.finish());
+                    self.buf = try allocator.alloc(u8, file_buf.len);
-                            self.state = .WriteTransfer;
+                    std.mem.copy(u8, self.buf, file_buf);
-                        }
+                    return log.info("Loaded Save from {s}", .{file_path});
                    },
                    .Small => {
                        if (self.writer.len() == 6) {
                            self.addr = @intCast(u6, self.writer.finish());
                            self.state = .WriteTransfer;
                        }
                    },
                    else => log.err("Unable to calculate EEPROM write address. EEPROM size UNKNOWN", .{}),
                }
                log.err("EEPROM can either be 0x200 bytes or 0x2000 byes, but {s} was {X:} bytes", .{
                    file_path,
                    file_buf.len,
                });
            },
-            .WriteTransfer => {
+            .None => return SaveError.Unsupported,
                if (self.writer.len() == 64) {
                    std.mem.writeIntSliceLittle(u64, buf[self.addr * 8 ..][0..8], self.writer.finish());
                    self.state = .RequestEnd;
                }
            },
            .RequestEnd => unreachable, // We return early in write() if state is .RequestEnd
        }
    }
-    const Reader = struct {
+    fn savePath(self: *const Self, allocator: Allocator, path: []const u8) ![]const u8 {
-        const This = @This();
+        const filename = try self.saveName(allocator);
        defer allocator.free(filename);
-        data: u64,
+        return try std.fs.path.join(allocator, &[_][]const u8{ path, filename });
-        i: u8,
+    }
        enabled: bool,
-        fn init() This {
+    fn saveName(self: *const Self, allocator: Allocator) ![]const u8 {
-            return .{
+        const title_str = std.mem.sliceTo(&escape(self.title), 0);
-                .data = 0,
+        const name = if (title_str.len != 0) title_str else "untitled";
-                .i = 0,
+
-                .enabled = false,
+        return try std.mem.concat(allocator, u8, &[_][]const u8{ name, ".sav" });
-            };
+    }
    fn writeSave(self: Self, allocator: Allocator, path: []const u8) !void {
        const file_path = try self.savePath(allocator, path);
        defer allocator.free(file_path);
        switch (self.kind) {
            .Sram, .Flash, .Flash1M, .Eeprom => {
                const file = try std.fs.createFileAbsolute(file_path, .{});
                defer file.close();
                try file.writeAll(self.buf);
                log.info("Wrote Save to {s}", .{file_path});
            },
            else => return SaveError.Unsupported,
        }
-
+    }
        fn configure(self: *This, value: u64) void {
            self.data = value;
            self.i = 0;
            self.enabled = true;
        }
        fn read(self: *This) u1 {
            if (!self.enabled) return 1;
            const bit = if (self.i < 4) blk: {
                break :blk 0;
            } else blk: {
                const idx = @intCast(u6, 63 - (self.i - 4));
                break :blk @truncate(u1, self.data >> idx);
            };
            self.i = (self.i + 1) % (64 + 4);
            if (self.i == 0) self.enabled = false;
            return bit;
        }
        fn dbgRead(self: *const This) u1 {
            if (!self.enabled) return 1;
            const bit = if (self.i < 4) blk: {
                break :blk 0;
            } else blk: {
                const idx = @intCast(u6, 63 - (self.i - 4));
                break :blk @truncate(u1, self.data >> idx);
            };
            return bit;
        }
    };
    const Writer = struct {
        const This = @This();
        data: u64,
        i: u8,
        fn init() This {
            return .{ .data = 0, .i = 0 };
        }
        fn requestWrite(self: *This, bit: u1) void {
            const idx = @intCast(u1, 1 - self.i);
            self.data = (self.data & ~(@as(u64, 1) << idx)) | (@as(u64, bit) << idx);
            self.i += 1;
        }
        fn addressWrite(self: *This, kind: Eeprom.Kind, bit: u1) void {
            if (kind == .Unknown) return;
            const size: u4 = switch (kind) {
                .Large => 13,
                .Small => 5,
                .Unknown => unreachable,
            };
            const idx = @intCast(u4, size - self.i);
            self.data = (self.data & ~(@as(u64, 1) << idx)) | (@as(u64, bit) << idx);
            self.i += 1;
        }
        fn dataWrite(self: *This, bit: u1) void {
            const idx = @intCast(u6, 63 - self.i);
            self.data = (self.data & ~(@as(u64, 1) << idx)) | (@as(u64, bit) << idx);
            self.i += 1;
        }
        fn len(self: *const This) u8 {
            return self.i;
        }
        fn finish(self: *This) u64 {
            defer self.reset();
            return self.data;
        }
        fn reset(self: *This) void {
            self.i = 0;
            self.data = 0;
        }
    };
 };
--- a/src/core/bus/backup/Flash.zig
+++ b/src/core/bus/backup/Flash.zig
@@ -0,0 +1,72 @@
 const std = @import("std");
 const Self = @This();
 state: State,
 id_mode: bool,
 set_bank: bool,
 prep_erase: bool,
 prep_write: bool,
 bank: u1,
 const State = enum {
    Ready,
    Set,
    Command,
 };
 pub fn read(self: *const Self, buf: []u8, idx: usize) u8 {
    return buf[self.address() + idx];
 }
 pub fn write(self: *Self, buf: []u8, idx: usize, byte: u8) void {
    buf[self.address() + idx] = byte;
    self.prep_write = false;
 }
 pub fn create() Self {
    return .{
        .state = .Ready,
        .id_mode = false,
        .set_bank = false,
        .prep_erase = false,
        .prep_write = false,
        .bank = 0,
    };
 }
 pub fn handleCommand(self: *Self, buf: []u8, byte: u8) void {
    switch (byte) {
        0x90 => self.id_mode = true,
        0xF0 => self.id_mode = false,
        0xB0 => self.set_bank = true,
        0x80 => self.prep_erase = true,
        0x10 => {
            std.mem.set(u8, buf, 0xFF);
            self.prep_erase = false;
        },
        0xA0 => self.prep_write = true,
        else => std.debug.panic("Unhandled Flash Command: 0x{X:0>2}", .{byte}),
    }
    self.state = .Ready;
 }
 pub fn shouldEraseSector(self: *const Self, addr: usize, byte: u8) bool {
    return self.state == .Command and self.prep_erase and byte == 0x30 and addr & 0xFFF == 0x000;
 }
 pub fn erase(self: *Self, buf: []u8, sector: usize) void {
    const start = self.address() + (sector & 0xF000);
    std.mem.set(u8, buf[start..][0..0x1000], 0xFF);
    self.prep_erase = false;
    self.state = .Ready;
 }
 /// Base Address
 inline fn address(self: *const Self) usize {
    return if (self.bank == 1) 0x10000 else @as(usize, 0);
 }
--- a/src/core/bus/backup/eeprom.zig
+++ b/src/core/bus/backup/eeprom.zig
@@ -0,0 +1,269 @@
 const std = @import("std");
 const Allocator = std.mem.Allocator;
 const log = std.log.scoped(.Eeprom);
 pub const Eeprom = struct {
    const Self = @This();
    addr: u14,
    kind: Kind,
    state: State,
    writer: Writer,
    reader: Reader,
    allocator: Allocator,
    const Kind = enum {
        Unknown,
        Small, // 512B
        Large, // 8KB
    };
    const State = enum {
        Ready,
        Read,
        Write,
        WriteTransfer,
        RequestEnd,
    };
    pub fn read(self: *Self) u1 {
        return self.reader.read();
    }
    pub fn dbgRead(self: *const Self) u1 {
        return self.reader.dbgRead();
    }
    pub fn write(self: *Self, word_count: u16, buf: *[]u8, bit: u1) void {
        if (self.guessKind(word_count)) |found| {
            log.info("EEPROM Kind: {}", .{found});
            self.kind = found;
            // buf.len will not equal zero when a save file was found and loaded.
            // Right now, we assume that the save file is of the correct size which
            // isn't necessarily true, since we can't trust anything a user can influence
            // TODO: use ?[]u8 instead of a 0-sized slice?
            if (buf.len == 0) {
                const len: usize = switch (found) {
                    .Small => 0x200,
                    .Large => 0x2000,
                    else => unreachable,
                };
                buf.* = self.allocator.alloc(u8, len) catch |e| {
                    log.err("Failed to resize EEPROM buf to {} bytes", .{len});
                    std.debug.panic("EEPROM entered irrecoverable state {}", .{e});
                };
                std.mem.set(u8, buf.*, 0xFF);
            }
        }
        if (self.state == .RequestEnd) {
            // if (bit != 0) log.debug("EEPROM Request did not end in 0u1. TODO: is this ok?", .{});
            self.state = .Ready;
            return;
        }
        switch (self.state) {
            .Ready => self.writer.requestWrite(bit),
            .Read, .Write => self.writer.addressWrite(self.kind, bit),
            .WriteTransfer => self.writer.dataWrite(bit),
            .RequestEnd => unreachable, // We return early just above this block
        }
        self.tick(buf.*);
    }
    pub fn create(allocator: Allocator) Self {
        return .{
            .kind = .Unknown,
            .state = .Ready,
            .writer = Writer.create(),
            .reader = Reader.create(),
            .addr = 0,
            .allocator = allocator,
        };
    }
    fn guessKind(self: *const Self, word_count: u16) ?Kind {
        if (self.kind != .Unknown or self.state != .Read) return null;
        return switch (word_count) {
            17 => .Large,
            9 => .Small,
            else => blk: {
                log.err("Unexpected length of DMA3 Transfer upon initial EEPROM read: {}", .{word_count});
                break :blk null;
            },
        };
    }
    fn tick(self: *Self, buf: []u8) void {
        switch (self.state) {
            .Ready => {
                if (self.writer.len() == 2) {
                    const req = @intCast(u2, self.writer.finish());
                    switch (req) {
                        0b11 => self.state = .Read,
                        0b10 => self.state = .Write,
                        else => log.err("Unknown EEPROM Request 0b{b:0>2}", .{req}),
                    }
                }
            },
            .Read => {
                switch (self.kind) {
                    .Large => {
                        if (self.writer.len() == 14) {
                            const addr = @intCast(u10, self.writer.finish());
                            const value = std.mem.readIntSliceLittle(u64, buf[@as(u13, addr) * 8 ..][0..8]);
                            self.reader.configure(value);
                            self.state = .RequestEnd;
                        }
                    },
                    .Small => {
                        if (self.writer.len() == 6) {
                            // FIXME: Duplicated code from above
                            const addr = @intCast(u6, self.writer.finish());
                            const value = std.mem.readIntSliceLittle(u64, buf[@as(u13, addr) * 8 ..][0..8]);
                            self.reader.configure(value);
                            self.state = .RequestEnd;
                        }
                    },
                    else => log.err("Unable to calculate EEPROM read address. EEPROM size UNKNOWN", .{}),
                }
            },
            .Write => {
                switch (self.kind) {
                    .Large => {
                        if (self.writer.len() == 14) {
                            self.addr = @intCast(u10, self.writer.finish());
                            self.state = .WriteTransfer;
                        }
                    },
                    .Small => {
                        if (self.writer.len() == 6) {
                            self.addr = @intCast(u6, self.writer.finish());
                            self.state = .WriteTransfer;
                        }
                    },
                    else => log.err("Unable to calculate EEPROM write address. EEPROM size UNKNOWN", .{}),
                }
            },
            .WriteTransfer => {
                if (self.writer.len() == 64) {
                    std.mem.writeIntSliceLittle(u64, buf[self.addr * 8 ..][0..8], self.writer.finish());
                    self.state = .RequestEnd;
                }
            },
            .RequestEnd => unreachable, // We return early in write() if state is .RequestEnd
        }
    }
 };
 const Reader = struct {
    const Self = @This();
    data: u64,
    i: u8,
    enabled: bool,
    fn create() Self {
        return .{
            .data = 0,
            .i = 0,
            .enabled = false,
        };
    }
    fn read(self: *Self) u1 {
        if (!self.enabled) return 1;
        const bit = if (self.i < 4) blk: {
            break :blk 0;
        } else blk: {
            const idx = @intCast(u6, 63 - (self.i - 4));
            break :blk @truncate(u1, self.data >> idx);
        };
        self.i = (self.i + 1) % (64 + 4);
        if (self.i == 0) self.enabled = false;
        return bit;
    }
    fn dbgRead(self: *const Self) u1 {
        if (!self.enabled) return 1;
        const bit = if (self.i < 4) blk: {
            break :blk 0;
        } else blk: {
            const idx = @intCast(u6, 63 - (self.i - 4));
            break :blk @truncate(u1, self.data >> idx);
        };
        return bit;
    }
    fn configure(self: *Self, value: u64) void {
        self.data = value;
        self.i = 0;
        self.enabled = true;
    }
 };
 const Writer = struct {
    const Self = @This();
    data: u64,
    i: u8,
    fn create() Self {
        return .{ .data = 0, .i = 0 };
    }
    fn requestWrite(self: *Self, bit: u1) void {
        const idx = @intCast(u1, 1 - self.i);
        self.data = (self.data & ~(@as(u64, 1) << idx)) | (@as(u64, bit) << idx);
        self.i += 1;
    }
    fn addressWrite(self: *Self, kind: Eeprom.Kind, bit: u1) void {
        if (kind == .Unknown) return;
        const size: u4 = switch (kind) {
            .Large => 13,
            .Small => 5,
            .Unknown => unreachable,
        };
        const idx = @intCast(u4, size - self.i);
        self.data = (self.data & ~(@as(u64, 1) << idx)) | (@as(u64, bit) << idx);
        self.i += 1;
    }
    fn dataWrite(self: *Self, bit: u1) void {
        const idx = @intCast(u6, 63 - self.i);
        self.data = (self.data & ~(@as(u64, 1) << idx)) | (@as(u64, bit) << idx);
        self.i += 1;
    }
    fn len(self: *const Self) u8 {
        return self.i;
    }
    fn finish(self: *Self) u64 {
        defer self.reset();
        return self.data;
    }
    fn reset(self: *Self) void {
        self.i = 0;
        self.data = 0;
    }
 };
--- a/src/core/bus/dma.zig
+++ b/src/core/bus/dma.zig
@@ -1,91 +1,144 @@
 const std = @import("std");
 const util = @import("../../util.zig");
 const DmaControl = @import("io.zig").DmaControl;
 const Bus = @import("../Bus.zig");
 const Arm7tdmi = @import("../cpu.zig").Arm7tdmi;
-const readUndefined = @import("../util.zig").readUndefined;
+pub const DmaTuple = struct { DmaController(0), DmaController(1), DmaController(2), DmaController(3) };
 const writeUndefined = @import("../util.zig").writeUndefined;
 pub const DmaTuple = std.meta.Tuple(&[_]type{ DmaController(0), DmaController(1), DmaController(2), DmaController(3) });
 const log = std.log.scoped(.DmaTransfer);
 const getHalf = util.getHalf;
 const setHalf = util.setHalf;
 const setQuart = util.setQuart;
 const rotr = @import("../../util.zig").rotr;
 pub fn create() DmaTuple {
    return .{ DmaController(0).init(), DmaController(1).init(), DmaController(2).init(), DmaController(3).init() };
 }
-pub fn read(comptime T: type, dma: *const DmaTuple, addr: u32) T {
+pub fn read(comptime T: type, dma: *const DmaTuple, addr: u32) ?T {
-    const byte = @truncate(u8, addr);
+    const byte_addr = @truncate(u8, addr);
    return switch (T) {
-        u32 => switch (byte) {
+        u32 => switch (byte_addr) {
-            0xB8 => @as(T, dma.*[0].cnt.raw) << 16,
+            0xB0, 0xB4 => null, // DMA0SAD, DMA0DAD,
-            0xC4 => @as(T, dma.*[1].cnt.raw) << 16,
+            0xB8 => @as(T, dma.*[0].dmacntH()) << 16, // DMA0CNT_L is write-only
-            0xD0 => @as(T, dma.*[2].cnt.raw) << 16,
+            0xBC, 0xC0 => null, // DMA1SAD, DMA1DAD
-            0xDC => @as(T, dma.*[3].cnt.raw) << 16,
+            0xC4 => @as(T, dma.*[1].dmacntH()) << 16, // DMA1CNT_L is write-only
-            else => readUndefined(log, "Tried to perform a {} read to 0x{X:0>8}", .{ T, addr }),
+            0xC8, 0xCC => null, // DMA2SAD, DMA2DAD
            0xD0 => @as(T, dma.*[2].dmacntH()) << 16, // DMA2CNT_L is write-only
            0xD4, 0xD8 => null, // DMA3SAD, DMA3DAD
            0xDC => @as(T, dma.*[3].dmacntH()) << 16, // DMA3CNT_L is write-only
            else => util.io.read.err(T, log, "unaligned {} read from 0x{X:0>8}", .{ T, addr }),
        },
-        u16 => switch (byte) {
+        u16 => switch (byte_addr) {
-            0xBA => dma.*[0].cnt.raw,
+            0xB0, 0xB2, 0xB4, 0xB6 => null, // DMA0SAD, DMA0DAD
-            0xC6 => dma.*[1].cnt.raw,
+            0xB8 => 0x0000, // DMA0CNT_L, suite.gba expects 0x0000 instead of 0xDEAD
-            0xD2 => dma.*[2].cnt.raw,
+            0xBA => dma.*[0].dmacntH(),
-            0xDE => dma.*[3].cnt.raw,
+
-            else => readUndefined(log, "Tried to perform a {} read to 0x{X:0>8}", .{ T, addr }),
+            0xBC, 0xBE, 0xC0, 0xC2 => null, // DMA1SAD, DMA1DAD
            0xC4 => 0x0000, // DMA1CNT_L
            0xC6 => dma.*[1].dmacntH(),
            0xC8, 0xCA, 0xCC, 0xCE => null, // DMA2SAD, DMA2DAD
            0xD0 => 0x0000, // DMA2CNT_L
            0xD2 => dma.*[2].dmacntH(),
            0xD4, 0xD6, 0xD8, 0xDA => null, // DMA3SAD, DMA3DAD
            0xDC => 0x0000, // DMA3CNT_L
            0xDE => dma.*[3].dmacntH(),
            else => util.io.read.err(T, log, "unaligned {} read from 0x{X:0>8}", .{ T, addr }),
        },
        u8 => switch (byte_addr) {
            0xB0...0xB7 => null, // DMA0SAD, DMA0DAD
            0xB8, 0xB9 => 0x00, // DMA0CNT_L
            0xBA, 0xBB => @truncate(T, dma.*[0].dmacntH() >> getHalf(byte_addr)),
            0xBC...0xC3 => null, // DMA1SAD, DMA1DAD
            0xC4, 0xC5 => 0x00, // DMA1CNT_L
            0xC6, 0xC7 => @truncate(T, dma.*[1].dmacntH() >> getHalf(byte_addr)),
            0xC8...0xCF => null, // DMA2SAD, DMA2DAD
            0xD0, 0xD1 => 0x00, // DMA2CNT_L
            0xD2, 0xD3 => @truncate(T, dma.*[2].dmacntH() >> getHalf(byte_addr)),
            0xD4...0xDB => null, // DMA3SAD, DMA3DAD
            0xDC, 0xDD => 0x00, // DMA3CNT_L
            0xDE, 0xDF => @truncate(T, dma.*[3].dmacntH() >> getHalf(byte_addr)),
            else => util.io.read.err(T, log, "unexpected {} read from 0x{X:0>8}", .{ T, addr }),
        },
        u8 => readUndefined(log, "Tried to perform a {} read to 0x{X:0>8}", .{ T, addr }),
        else => @compileError("DMA: Unsupported read width"),
    };
 }
 pub fn write(comptime T: type, dma: *DmaTuple, addr: u32, value: T) void {
-    const byte = @truncate(u8, addr);
+    const byte_addr = @truncate(u8, addr);
    switch (T) {
-        u32 => switch (byte) {
+        u32 => switch (byte_addr) {
-            0xB0 => dma.*[0].setSad(value),
+            0xB0 => dma.*[0].setDmasad(value),
-            0xB4 => dma.*[0].setDad(value),
+            0xB4 => dma.*[0].setDmadad(value),
-            0xB8 => dma.*[0].setCnt(value),
+            0xB8 => dma.*[0].setDmacnt(value),
-            0xBC => dma.*[1].setSad(value),
+
-            0xC0 => dma.*[1].setDad(value),
+            0xBC => dma.*[1].setDmasad(value),
-            0xC4 => dma.*[1].setCnt(value),
+            0xC0 => dma.*[1].setDmadad(value),
-            0xC8 => dma.*[2].setSad(value),
+            0xC4 => dma.*[1].setDmacnt(value),
-            0xCC => dma.*[2].setDad(value),
+
-            0xD0 => dma.*[2].setCnt(value),
+            0xC8 => dma.*[2].setDmasad(value),
-            0xD4 => dma.*[3].setSad(value),
+            0xCC => dma.*[2].setDmadad(value),
-            0xD8 => dma.*[3].setDad(value),
+            0xD0 => dma.*[2].setDmacnt(value),
-            0xDC => dma.*[3].setCnt(value),
+
-            else => writeUndefined(log, "Tried to write 0x{X:0>8}{} to 0x{X:0>8}", .{ value, T, addr }),
+            0xD4 => dma.*[3].setDmasad(value),
            0xD8 => dma.*[3].setDmadad(value),
            0xDC => dma.*[3].setDmacnt(value),
            else => util.io.write.undef(log, "Tried to write 0x{X:0>8}{} to 0x{X:0>8}", .{ value, T, addr }),
        },
-        u16 => switch (byte) {
+        u16 => switch (byte_addr) {
-            0xB0 => dma.*[0].setSad(setU32L(dma.*[0].sad, value)),
+            0xB0, 0xB2 => dma.*[0].setDmasad(setHalf(u32, dma.*[0].sad, byte_addr, value)),
-            0xB2 => dma.*[0].setSad(setU32H(dma.*[0].sad, value)),
+            0xB4, 0xB6 => dma.*[0].setDmadad(setHalf(u32, dma.*[0].dad, byte_addr, value)),
-            0xB4 => dma.*[0].setDad(setU32L(dma.*[0].dad, value)),
+            0xB8 => dma.*[0].setDmacntL(value),
-            0xB6 => dma.*[0].setDad(setU32H(dma.*[0].dad, value)),
+            0xBA => dma.*[0].setDmacntH(value),
            0xB8 => dma.*[0].setCntL(value),
            0xBA => dma.*[0].setCntH(value),
-            0xBC => dma.*[1].setSad(setU32L(dma.*[1].sad, value)),
+            0xBC, 0xBE => dma.*[1].setDmasad(setHalf(u32, dma.*[1].sad, byte_addr, value)),
-            0xBE => dma.*[1].setSad(setU32H(dma.*[1].sad, value)),
+            0xC0, 0xC2 => dma.*[1].setDmadad(setHalf(u32, dma.*[1].dad, byte_addr, value)),
-            0xC0 => dma.*[1].setDad(setU32L(dma.*[1].dad, value)),
+            0xC4 => dma.*[1].setDmacntL(value),
-            0xC2 => dma.*[1].setDad(setU32H(dma.*[1].dad, value)),
+            0xC6 => dma.*[1].setDmacntH(value),
            0xC4 => dma.*[1].setCntL(value),
            0xC6 => dma.*[1].setCntH(value),
-            0xC8 => dma.*[2].setSad(setU32L(dma.*[2].sad, value)),
+            0xC8, 0xCA => dma.*[2].setDmasad(setHalf(u32, dma.*[2].sad, byte_addr, value)),
-            0xCA => dma.*[2].setSad(setU32H(dma.*[2].sad, value)),
+            0xCC, 0xCE => dma.*[2].setDmadad(setHalf(u32, dma.*[2].dad, byte_addr, value)),
-            0xCC => dma.*[2].setDad(setU32L(dma.*[2].dad, value)),
+            0xD0 => dma.*[2].setDmacntL(value),
-            0xCE => dma.*[2].setDad(setU32H(dma.*[2].dad, value)),
+            0xD2 => dma.*[2].setDmacntH(value),
            0xD0 => dma.*[2].setCntL(value),
            0xD2 => dma.*[2].setCntH(value),
-            0xD4 => dma.*[3].setSad(setU32L(dma.*[3].sad, value)),
+            0xD4, 0xD6 => dma.*[3].setDmasad(setHalf(u32, dma.*[3].sad, byte_addr, value)),
-            0xD6 => dma.*[3].setSad(setU32H(dma.*[3].sad, value)),
+            0xD8, 0xDA => dma.*[3].setDmadad(setHalf(u32, dma.*[3].dad, byte_addr, value)),
-            0xD8 => dma.*[3].setDad(setU32L(dma.*[3].dad, value)),
+            0xDC => dma.*[3].setDmacntL(value),
-            0xDA => dma.*[3].setDad(setU32H(dma.*[3].dad, value)),
+            0xDE => dma.*[3].setDmacntH(value),
-            0xDC => dma.*[3].setCntL(value),
+            else => util.io.write.undef(log, "Tried to write 0x{X:0>4}{} to 0x{X:0>8}", .{ value, T, addr }),
-            0xDE => dma.*[3].setCntH(value),
+        },
-            else => writeUndefined(log, "Tried to write 0x{X:0>4}{} to 0x{X:0>8}", .{ value, T, addr }),
+        u8 => switch (byte_addr) {
            0xB0, 0xB1, 0xB2, 0xB3 => dma.*[0].setDmasad(setQuart(dma.*[0].sad, byte_addr, value)),
            0xB4, 0xB5, 0xB6, 0xB7 => dma.*[0].setDmadad(setQuart(dma.*[0].dad, byte_addr, value)),
            0xB8, 0xB9 => dma.*[0].setDmacntL(setHalf(u16, dma.*[0].word_count, byte_addr, value)),
            0xBA, 0xBB => dma.*[0].setDmacntH(setHalf(u16, dma.*[0].cnt.raw, byte_addr, value)),
            0xBC, 0xBD, 0xBE, 0xBF => dma.*[1].setDmasad(setQuart(dma.*[1].sad, byte_addr, value)),
            0xC0, 0xC1, 0xC2, 0xC3 => dma.*[1].setDmadad(setQuart(dma.*[1].dad, byte_addr, value)),
            0xC4, 0xC5 => dma.*[1].setDmacntL(setHalf(u16, dma.*[1].word_count, byte_addr, value)),
            0xC6, 0xC7 => dma.*[1].setDmacntH(setHalf(u16, dma.*[1].cnt.raw, byte_addr, value)),
            0xC8, 0xC9, 0xCA, 0xCB => dma.*[2].setDmasad(setQuart(dma.*[2].sad, byte_addr, value)),
            0xCC, 0xCD, 0xCE, 0xCF => dma.*[2].setDmadad(setQuart(dma.*[2].dad, byte_addr, value)),
            0xD0, 0xD1 => dma.*[2].setDmacntL(setHalf(u16, dma.*[2].word_count, byte_addr, value)),
            0xD2, 0xD3 => dma.*[2].setDmacntH(setHalf(u16, dma.*[2].cnt.raw, byte_addr, value)),
            0xD4, 0xD5, 0xD6, 0xD7 => dma.*[3].setDmasad(setQuart(dma.*[3].sad, byte_addr, value)),
            0xD8, 0xD9, 0xDA, 0xDB => dma.*[3].setDmadad(setQuart(dma.*[3].dad, byte_addr, value)),
            0xDC, 0xDD => dma.*[3].setDmacntL(setHalf(u16, dma.*[3].word_count, byte_addr, value)),
            0xDE, 0xDF => dma.*[3].setDmacntH(setHalf(u16, dma.*[3].cnt.raw, byte_addr, value)),
            else => util.io.write.undef(log, "Tried to write 0x{X:0>2}{} to 0x{X:0>8}", .{ value, T, addr }),
        },
        u8 => writeUndefined(log, "Tried to write 0x{X:0>2}{} to 0x{X:0>8}", .{ value, T, addr }),
        else => @compileError("DMA: Unsupported write width"),
    }
 }
@@ -97,6 +150,7 @@ fn DmaController(comptime id: u2) type {
        const sad_mask: u32 = if (id == 0) 0x07FF_FFFF else 0x0FFF_FFFF;
        const dad_mask: u32 = if (id != 3) 0x07FF_FFFF else 0x0FFF_FFFF;
        const WordCount = if (id == 3) u16 else u14;
        /// Write-only. The first address in a DMA transfer. (DMASAD)
        /// Note: use writeSrc instead of manipulating src_addr directly
@@ -105,20 +159,19 @@ fn DmaController(comptime id: u2) type {
        /// Note: Use writeDst instead of manipulatig dst_addr directly
        dad: u32,
        /// Write-only. The Word Count for the DMA Transfer (DMACNT_L)
-        word_count: if (id == 3) u16 else u14,
+        word_count: WordCount,
        /// Read / Write. DMACNT_H
        /// Note: Use writeControl instead of manipulating cnt directly.
        cnt: DmaControl,
        /// Internal. The last successfully read value
        data_latch: u32,
        /// Internal. Currrent Source Address
-        _sad: u32,
+        sad_latch: u32,
        /// Internal. Current Destination Address
-        _dad: u32,
+        dad_latch: u32,
        /// Internal. Word Count
-        _word_count: if (id == 3) u16 else u14,
+        _word_count: WordCount,
        // Internal. FIFO Word Count
        _fifo_word_count: u8,
        /// Some DMA Transfers are enabled during Hblank / VBlank and / or
        /// have delays. Thefore bit 15 of DMACNT isn't actually something
@@ -133,34 +186,39 @@ fn DmaController(comptime id: u2) type {
                .cnt = .{ .raw = 0x000 },
                // Internals
-                ._sad = 0,
+                .sad_latch = 0,
-                ._dad = 0,
+                .dad_latch = 0,
                .data_latch = 0,
                ._word_count = 0,
                ._fifo_word_count = 4,
                .in_progress = false,
            };
        }
-        pub fn setSad(self: *Self, addr: u32) void {
+        pub fn setDmasad(self: *Self, addr: u32) void {
            self.sad = addr & sad_mask;
        }
-        pub fn setDad(self: *Self, addr: u32) void {
+        pub fn setDmadad(self: *Self, addr: u32) void {
            self.dad = addr & dad_mask;
        }
-        pub fn setCntL(self: *Self, halfword: u16) void {
+        pub fn setDmacntL(self: *Self, halfword: u16) void {
            self.word_count = @truncate(@TypeOf(self.word_count), halfword);
        }
-        pub fn setCntH(self: *Self, halfword: u16) void {
+        pub fn dmacntH(self: *const Self) u16 {
            return self.cnt.raw & if (id == 3) 0xFFE0 else 0xF7E0;
        }
        pub fn setDmacntH(self: *Self, halfword: u16) void {
            const new = DmaControl{ .raw = halfword };
            if (!self.cnt.enabled.read() and new.enabled.read()) {
                // Reload Internals on Rising Edge.
-                self._sad = self.sad;
+                self.sad_latch = self.sad;
-                self._dad = self.dad;
+                self.dad_latch = self.dad;
-                self._word_count = if (self.word_count == 0) std.math.maxInt(@TypeOf(self._word_count)) else self.word_count;
+                self._word_count = if (self.word_count == 0) std.math.maxInt(WordCount) else self.word_count;
                // Only a Start Timing of 00 has a DMA Transfer immediately begin
                self.in_progress = new.start_timing.read() == 0b00;
@@ -169,38 +227,50 @@ fn DmaController(comptime id: u2) type {
            self.cnt.raw = halfword;
        }
-        pub fn setCnt(self: *Self, word: u32) void {
+        pub fn setDmacnt(self: *Self, word: u32) void {
-            self.setCntL(@truncate(u16, word));
+            self.setDmacntL(@truncate(u16, word));
-            self.setCntH(@truncate(u16, word >> 16));
+            self.setDmacntH(@truncate(u16, word >> 16));
        }
        pub fn step(self: *Self, cpu: *Arm7tdmi) void {
            const is_fifo = (id == 1 or id == 2) and self.cnt.start_timing.read() == 0b11;
-            const sad_adj = Self.adjustment(self.cnt.sad_adj.read());
+            const sad_adj = @intToEnum(Adjustment, self.cnt.sad_adj.read());
-            const dad_adj = if (is_fifo) .Fixed else Self.adjustment(self.cnt.dad_adj.read());
+            const dad_adj = if (is_fifo) .Fixed else @intToEnum(Adjustment, self.cnt.dad_adj.read());
            const transfer_type = is_fifo or self.cnt.transfer_type.read();
            const offset: u32 = if (transfer_type) @sizeOf(u32) else @sizeOf(u16);
            const mask = if (transfer_type) ~@as(u32, 3) else ~@as(u32, 1);
            const sad_addr = self.sad_latch & mask;
            const dad_addr = self.dad_latch & mask;
            if (transfer_type) {
-                cpu.bus.write(u32, self._dad & mask, cpu.bus.read(u32, self._sad & mask));
+                if (sad_addr >= 0x0200_0000) self.data_latch = cpu.bus.read(u32, sad_addr);
                cpu.bus.write(u32, dad_addr, self.data_latch);
            } else {
-                cpu.bus.write(u16, self._dad & mask, cpu.bus.read(u16, self._sad & mask));
+                if (sad_addr >= 0x0200_0000) {
                    const value: u32 = cpu.bus.read(u16, sad_addr);
                    self.data_latch = value << 16 | value;
                }
                cpu.bus.write(u16, dad_addr, @truncate(u16, rotr(u32, self.data_latch, 8 * (dad_addr & 3))));
            }
-            switch (sad_adj) {
+            switch (@truncate(u8, sad_addr >> 24)) {
-                .Increment => self._sad +%= offset,
+                // according to fleroviux, DMAs with a source address in ROM misbehave
-                .Decrement => self._sad -%= offset,
+                // the resultant behaviour is that the source address will increment despite what DMAXCNT says
-                // TODO: Is just ignoring this ok?
+                0x08...0x0D => self.sad_latch +%= offset, // obscure behaviour
-                .IncrementReload => log.err("{} is a prohibited adjustment on SAD", .{sad_adj}),
+                else => switch (sad_adj) {
-                .Fixed => {},
+                    .Increment => self.sad_latch +%= offset,
                    .Decrement => self.sad_latch -%= offset,
                    .IncrementReload => log.err("{} is a prohibited adjustment on SAD", .{sad_adj}),
                    .Fixed => {},
                },
            }
            switch (dad_adj) {
-                .Increment, .IncrementReload => self._dad +%= offset,
+                .Increment, .IncrementReload => self.dad_latch +%= offset,
-                .Decrement => self._dad -%= offset,
+                .Decrement => self.dad_latch -%= offset,
                .Fixed => {},
            }
@@ -228,7 +298,7 @@ fn DmaController(comptime id: u2) type {
            }
        }
-        pub fn pollBlankingDma(self: *Self, comptime kind: DmaKind) void {
+        fn poll(self: *Self, comptime kind: DmaKind) void {
            if (self.in_progress) return; // If there's an ongoing DMA Transfer, exit early
            // No ongoing DMA Transfer, We want to check if we should repeat an existing one
@@ -244,11 +314,11 @@ fn DmaController(comptime id: u2) type {
            // Reload internal DAD latch if we are in IncrementRelaod
            if (self.in_progress) {
                self._word_count = if (self.word_count == 0) std.math.maxInt(@TypeOf(self._word_count)) else self.word_count;
-                if (Self.adjustment(self.cnt.dad_adj.read()) == .IncrementReload) self._dad = self.dad;
+                if (@intToEnum(Adjustment, self.cnt.dad_adj.read()) == .IncrementReload) self.dad_latch = self.dad;
            }
        }
-        pub fn requestSoundDma(self: *Self, _: u32) void {
+        pub fn requestAudio(self: *Self, _: u32) void {
            comptime std.debug.assert(id == 1 or id == 2);
            if (self.in_progress) return; // APU must wait their turn
@@ -260,23 +330,19 @@ fn DmaController(comptime id: u2) type {
            // We Assume DMACNT_L is set to 4
            // FIXME: Safe to just assume whatever DAD is set to is the FIFO Address?
-            // self._dad = fifo_addr;
+            // self.dad_latch = fifo_addr;
            self.cnt.repeat.set();
            self._word_count = 4;
            self.in_progress = true;
        }
        fn adjustment(idx: u2) Adjustment {
            return std.meta.intToEnum(Adjustment, idx) catch unreachable;
        }
    };
 }
-pub fn pollBlankingDma(bus: *Bus, comptime kind: DmaKind) void {
+pub fn pollDmaOnBlank(bus: *Bus, comptime kind: DmaKind) void {
-    bus.dma[0].pollBlankingDma(kind);
+    comptime var i: usize = 0;
-    bus.dma[1].pollBlankingDma(kind);
+    inline while (i < 4) : (i += 1) {
-    bus.dma[2].pollBlankingDma(kind);
+        bus.dma[i].poll(kind);
-    bus.dma[3].pollBlankingDma(kind);
+    }
 }
 const Adjustment = enum(u2) {
@@ -292,11 +358,3 @@ const DmaKind = enum(u2) {
    VBlank,
    Special,
 };
 fn setU32L(left: u32, right: u16) u32 {
    return (left & 0xFFFF_0000) | right;
 }
 fn setU32H(left: u32, right: u16) u32 {
    return (left & 0x0000_FFFF) | (@as(u32, right) << 16);
 }
--- a/src/core/bus/gpio.zig
+++ b/src/core/bus/gpio.zig
@@ -0,0 +1,464 @@
 const std = @import("std");
 const Bit = @import("bitfield").Bit;
 const DateTime = @import("datetime").datetime.Datetime;
 const Arm7tdmi = @import("../cpu.zig").Arm7tdmi;
 const Allocator = std.mem.Allocator;
 /// GPIO Register Implementation
 pub const Gpio = struct {
    const Self = @This();
    const log = std.log.scoped(.Gpio);
    data: u4,
    direction: u4,
    cnt: u1,
    device: Device,
    const Register = enum { Data, Direction, Control };
    pub const Device = struct {
        ptr: ?*anyopaque,
        kind: Kind, // TODO: Make comptime known?
        pub const Kind = enum { Rtc, None };
        fn step(self: *Device, value: u4) u4 {
            return switch (self.kind) {
                .Rtc => blk: {
                    const clock = @ptrCast(*Clock, @alignCast(@alignOf(*Clock), self.ptr.?));
                    break :blk clock.step(Clock.Data{ .raw = value });
                },
                .None => value,
            };
        }
        fn init(kind: Kind, ptr: ?*anyopaque) Device {
            return .{ .kind = kind, .ptr = ptr };
        }
    };
    pub fn write(self: *Self, comptime reg: Register, value: if (reg == .Control) u1 else u4) void {
        switch (reg) {
            .Data => {
                const masked_value = value & self.direction;
                // The value which is actually stored in the GPIO register
                // might be modified by the device implementing the GPIO interface e.g. RTC reads
                self.data = self.device.step(masked_value);
            },
            .Direction => self.direction = value,
            .Control => self.cnt = value,
        }
    }
    pub fn read(self: *const Self, comptime reg: Register) if (reg == .Control) u1 else u4 {
        if (self.cnt == 0) return 0;
        return switch (reg) {
            .Data => self.data & ~self.direction,
            .Direction => self.direction,
            .Control => self.cnt,
        };
    }
    pub fn init(allocator: Allocator, cpu: *Arm7tdmi, kind: Device.Kind) !*Self {
        log.info("Device: {}", .{kind});
        const self = try allocator.create(Self);
        errdefer allocator.destroy(self);
        self.* = .{
            .data = 0b0000,
            .direction = 0b1111, // TODO: What is GPIO Direction set to by default?
            .cnt = 0b0,
            .device = switch (kind) {
                .Rtc => blk: {
                    const clock = try allocator.create(Clock);
                    clock.init(cpu, self);
                    break :blk Device{ .kind = kind, .ptr = clock };
                },
                .None => Device{ .kind = kind, .ptr = null },
            },
        };
        return self;
    }
    pub fn deinit(self: *Self, allocator: Allocator) void {
        switch (self.device.kind) {
            .Rtc => allocator.destroy(@ptrCast(*Clock, @alignCast(@alignOf(*Clock), self.device.ptr.?))),
            .None => {},
        }
        self.* = undefined;
    }
 };
 /// GBA Real Time Clock
 pub const Clock = struct {
    const Self = @This();
    const log = std.log.scoped(.Rtc);
    writer: Writer,
    reader: Reader,
    state: State,
    cnt: Control,
    year: u8,
    month: u5,
    day: u6,
    weekday: u3,
    hour: u6,
    minute: u7,
    second: u7,
    cpu: *Arm7tdmi,
    gpio: *const Gpio,
    const Register = enum {
        Control,
        DateTime,
        Time,
    };
    const State = union(enum) {
        Idle,
        Command,
        Write: Register,
        Read: Register,
    };
    const Reader = struct {
        i: u4,
        count: u8,
        /// Reads a bit from RTC registers. Which bit it reads is dependent on
        ///
        /// 1. The RTC State Machine, whitch tells us which register we're accessing
        /// 2. A `count`, which keeps track of which byte is currently being read
        /// 3. An index, which keeps track of which bit of the byte determined by `count` is being read
        fn read(self: *Reader, clock: *const Clock, register: Register) u1 {
            const idx = @intCast(u3, self.i);
            defer self.i += 1;
            // FIXME: What do I do about the unused bits?
            return switch (register) {
                .Control => @truncate(u1, switch (self.count) {
                    0 => clock.cnt.raw >> idx,
                    else => std.debug.panic("Tried to read from byte #{} of {} (hint: there's only 1 byte)", .{ self.count, register }),
                }),
                .DateTime => @truncate(u1, switch (self.count) {
                    // Date
                    0 => clock.year >> idx,
                    1 => @as(u8, clock.month) >> idx,
                    2 => @as(u8, clock.day) >> idx,
                    3 => @as(u8, clock.weekday) >> idx,
                    // Time
                    4 => @as(u8, clock.hour) >> idx,
                    5 => @as(u8, clock.minute) >> idx,
                    6 => @as(u8, clock.second) >> idx,
                    else => std.debug.panic("Tried to read from byte #{} of {} (hint: there's only 7 bytes)", .{ self.count, register }),
                }),
                .Time => @truncate(u1, switch (self.count) {
                    0 => @as(u8, clock.hour) >> idx,
                    1 => @as(u8, clock.minute) >> idx,
                    2 => @as(u8, clock.second) >> idx,
                    else => std.debug.panic("Tried to read from byte #{} of {} (hint: there's only 3 bytes)", .{ self.count, register }),
                }),
            };
        }
        /// Is true when a Reader has read a u8's worth of bits
        fn finished(self: *const Reader) bool {
            return self.i >= 8;
        }
        /// Resets the index used to shift bits out of RTC registers
        /// and `count`, which is used to keep track of which byte we're reading
        /// is incremeneted
        fn lap(self: *Reader) void {
            self.i = 0;
            self.count += 1;
        }
        /// Resets the state of a `Reader` in preparation for a future
        /// read command
        fn reset(self: *Reader) void {
            self.i = 0;
            self.count = 0;
        }
    };
    const Writer = struct {
        buf: u8,
        i: u4,
        /// The Number of bytes written since last reset
        count: u8,
        /// Append a bit to the internal bit buffer (aka an integer)
        fn push(self: *Writer, value: u1) void {
            const idx = @intCast(u3, self.i);
            self.buf = (self.buf & ~(@as(u8, 1) << idx)) | @as(u8, value) << idx;
            self.i += 1;
        }
        /// Takes the contents of the internal buffer and writes it to an RTC register
        /// Where it writes to is dependent on:
        ///
        /// 1. The RTC State Machine, whitch tells us which register we're accessing
        /// 2. A `count`, which keeps track of which byte is currently being read
        fn write(self: *const Writer, clock: *Clock, register: Register) void {
            // FIXME: What do do about unused bits?
            switch (register) {
                .Control => switch (self.count) {
                    0 => clock.cnt.raw = (clock.cnt.raw & 0x80) | (self.buf & 0x7F), // Bit 7 read-only
                    else => std.debug.panic("Tried to write to byte #{} of {} (hint: there's only 1 byte)", .{ self.count, register }),
                },
                .DateTime, .Time => log.debug("Ignoring {} write", .{register}),
            }
        }
        /// Is true when 8 bits have been shifted into the internal buffer
        fn finished(self: *const Writer) bool {
            return self.i >= 8;
        }
        /// Resets the internal buffer
        /// resets the index used to shift bits into the internal buffer
        /// increments `count` (which keeps track of byte offsets) by one
        fn lap(self: *Writer) void {
            self.buf = 0;
            self.i = 0;
            self.count += 1;
        }
        /// Resets `Writer` to a clean state in preparation for a future write command
        fn reset(self: *Writer) void {
            self.buf = 0;
            self.i = 0;
            self.count = 0;
        }
    };
    const Data = extern union {
        sck: Bit(u8, 0),
        sio: Bit(u8, 1),
        cs: Bit(u8, 2),
        raw: u8,
    };
    const Control = extern union {
        /// Unknown, value should be preserved though
        unk: Bit(u8, 1),
        /// Per-minute IRQ
        /// If set, fire a Gamepak IRQ every 30s,
        irq: Bit(u8, 3),
        /// 12/24 Hour Bit
        /// If set, 12h mode
        /// If cleared, 24h mode
        mode: Bit(u8, 6),
        /// Read-Only, bit cleared on read
        /// If is set, means that there has been a failure / time has been lost
        off: Bit(u8, 7),
        raw: u8,
    };
    fn init(ptr: *Self, cpu: *Arm7tdmi, gpio: *const Gpio) void {
        ptr.* = .{
            .writer = .{ .buf = 0, .i = 0, .count = 0 },
            .reader = .{ .i = 0, .count = 0 },
            .state = .Idle,
            .cnt = .{ .raw = 0 },
            .year = 0x01,
            .month = 0x6,
            .day = 0x13,
            .weekday = 0x3,
            .hour = 0x23,
            .minute = 0x59,
            .second = 0x59,
            .cpu = cpu,
            .gpio = gpio, // Can't use Arm7tdmi ptr b/c not initialized yet
        };
        cpu.sched.push(.RealTimeClock, 1 << 24); // Every Second
    }
    pub fn onClockUpdate(self: *Self, late: u64) void {
        self.cpu.sched.push(.RealTimeClock, (1 << 24) -| late); // Reschedule
        const now = DateTime.now();
        self.year = bcd(u8, @intCast(u8, now.date.year - 2000));
        self.month = bcd(u5, now.date.month);
        self.day = bcd(u6, now.date.day);
        self.weekday = bcd(u3, (now.date.weekday() + 1) % 7); // API is Monday = 0, Sunday = 6. We want Sunday = 0, Saturday = 6
        self.hour = bcd(u6, now.time.hour);
        self.minute = bcd(u7, now.time.minute);
        self.second = bcd(u7, now.time.second);
    }
    fn step(self: *Self, value: Data) u4 {
        const cache: Data = .{ .raw = self.gpio.data };
        return switch (self.state) {
            .Idle => blk: {
                // FIXME: Maybe check incoming value to see if SCK is also high?
                if (cache.sck.read()) {
                    if (!cache.cs.read() and value.cs.read()) {
                        log.debug("Entering Command Mode", .{});
                        self.state = .Command;
                    }
                }
                break :blk @truncate(u4, value.raw);
            },
            .Command => blk: {
                if (!value.cs.read()) log.err("Expected CS to be set during {}, however CS was cleared", .{self.state});
                // If SCK rises, sample SIO
                if (!cache.sck.read() and value.sck.read()) {
                    self.writer.push(@boolToInt(value.sio.read()));
                    if (self.writer.finished()) {
                        self.state = self.processCommand(self.writer.buf);
                        self.writer.reset();
                        log.debug("Switching to {}", .{self.state});
                    }
                }
                break :blk @truncate(u4, value.raw);
            },
            .Write => |register| blk: {
                if (!value.cs.read()) log.err("Expected CS to be set during {}, however CS was cleared", .{self.state});
                // If SCK rises, sample SIO
                if (!cache.sck.read() and value.sck.read()) {
                    self.writer.push(@boolToInt(value.sio.read()));
                    const register_width: u32 = switch (register) {
                        .Control => 1,
                        .DateTime => 7,
                        .Time => 3,
                    };
                    if (self.writer.finished()) {
                        self.writer.write(self, register); // write inner buffer to RTC register
                        self.writer.lap();
                        if (self.writer.count == register_width) {
                            self.writer.reset();
                            self.state = .Idle;
                        }
                    }
                }
                break :blk @truncate(u4, value.raw);
            },
            .Read => |register| blk: {
                if (!value.cs.read()) log.err("Expected CS to be set during {}, however CS was cleared", .{self.state});
                var ret = value;
                // if SCK rises, sample SIO
                if (!cache.sck.read() and value.sck.read()) {
                    ret.sio.write(self.reader.read(self, register) == 0b1);
                    const register_width: u32 = switch (register) {
                        .Control => 1,
                        .DateTime => 7,
                        .Time => 3,
                    };
                    if (self.reader.finished()) {
                        self.reader.lap();
                        if (self.reader.count == register_width) {
                            self.reader.reset();
                            self.state = .Idle;
                        }
                    }
                }
                break :blk @truncate(u4, ret.raw);
            },
        };
    }
    fn reset(self: *Self) void {
        // mGBA and NBA only zero the control register. We will do the same
        log.debug("Reset (control register was zeroed)", .{});
        self.cnt.raw = 0;
    }
    fn irq(self: *Self) void {
        // TODO: Confirm that this is the right behaviour
        log.debug("Force GamePak IRQ", .{});
        self.cpu.bus.io.irq.game_pak.set();
        self.cpu.handleInterrupt();
    }
    fn processCommand(self: *Self, raw_command: u8) State {
        const command = blk: {
            // If High Nybble is 0x6, no need to switch the endianness
            if (raw_command >> 4 & 0xF == 0x6) break :blk raw_command;
            // Turns out reversing the order of bits isn't trivial at all
            // https://stackoverflow.com/questions/2602823/in-c-c-whats-the-simplest-way-to-reverse-the-order-of-bits-in-a-byte
            var ret = raw_command;
            ret = (ret & 0xF0) >> 4 | (ret & 0x0F) << 4;
            ret = (ret & 0xCC) >> 2 | (ret & 0x33) << 2;
            ret = (ret & 0xAA) >> 1 | (ret & 0x55) << 1;
            break :blk ret;
        };
        log.debug("Handling Command 0x{X:0>2} [0b{b:0>8}]", .{ command, command });
        const is_write = command & 1 == 0;
        const rtc_register = @truncate(u3, command >> 1 & 0x7);
        if (is_write) {
            return switch (rtc_register) {
                0 => blk: {
                    self.reset();
                    break :blk .Idle;
                },
                1 => .{ .Write = .Control },
                2 => .{ .Write = .DateTime },
                3 => .{ .Write = .Time },
                6 => blk: {
                    self.irq();
                    break :blk .Idle;
                },
                4, 5, 7 => .Idle,
            };
        } else {
            return switch (rtc_register) {
                1 => .{ .Read = .Control },
                2 => .{ .Read = .DateTime },
                3 => .{ .Read = .Time },
                0, 4, 5, 6, 7 => .Idle, // Do Nothing
            };
        }
    }
 };
 fn bcd(comptime T: type, value: u8) T {
    var input = value;
    var ret: u8 = 0;
    var shift: u3 = 0;
    while (input > 0) {
        ret |= (input % 10) << (shift << 2);
        shift += 1;
        input /= 10;
    }
    return @truncate(T, ret);
 }
--- a/src/core/bus/io.zig
+++ b/src/core/bus/io.zig
@@ -1,18 +1,17 @@
 const std = @import("std");
-const builtin = @import("builtin");
+const timer = @import("timer.zig");
 const dma = @import("dma.zig");
 const apu = @import("../apu.zig");
 const ppu = @import("../ppu.zig");
 const util = @import("../../util.zig");
 const Bit = @import("bitfield").Bit;
 const Bitfield = @import("bitfield").Bitfield;
 const Bus = @import("../Bus.zig");
 const DmaController = @import("dma.zig").DmaController;
 const Scheduler = @import("../scheduler.zig").Scheduler;
-const timer = @import("timer.zig");
+const getHalf = util.getHalf;
-const dma = @import("dma.zig");
+const setHalf = util.setHalf;
 const apu = @import("../apu.zig");
 const readUndefined = @import("../util.zig").readUndefined;
 const writeUndefined = @import("../util.zig").writeUndefined;
 const log = std.log.scoped(.@"I/O");
 pub const Io = struct {
@@ -23,15 +22,17 @@ pub const Io = struct {
    ie: InterruptEnable,
    irq: InterruptRequest,
    postflg: PostFlag,
    waitcnt: WaitControl,
    haltcnt: HaltControl,
-    keyinput: KeyInput,
+    keyinput: AtomicKeyInput,
    pub fn init() Self {
        return .{
            .ime = false,
            .ie = .{ .raw = 0x0000 },
            .irq = .{ .raw = 0x0000 },
-            .keyinput = .{ .raw = 0x03FF },
+            .keyinput = AtomicKeyInput.init(.{ .raw = 0x03FF }),
            .waitcnt = .{ .raw = 0x0000_0000 }, // Bit 15 == 0 for GBA
            .postflg = .FirstBoot,
            .haltcnt = .Execute,
        };
@@ -43,13 +44,14 @@ pub const Io = struct {
    }
 };
-pub fn read(bus: *const Bus, comptime T: type, address: u32) T {
+pub fn read(bus: *const Bus, comptime T: type, address: u32) ?T {
    return switch (T) {
        u32 => switch (address) {
            // Display
-            0x0400_0000 => bus.ppu.dispcnt.raw,
+            0x0400_0000...0x0400_0054 => ppu.read(T, &bus.ppu, address),
-            0x0400_0004 => @as(T, bus.ppu.vcount.raw) << 16 | bus.ppu.dispstat.raw,
+
-            0x0400_0006 => @as(T, bus.ppu.bg[0].cnt.raw) << 16 | bus.ppu.vcount.raw,
+            // Sound
            0x0400_0060...0x0400_00A4 => apu.read(T, &bus.apu, address),
            // DMA Transfers
            0x0400_00B0...0x0400_00DC => dma.read(T, &bus.dma, address),
@@ -58,33 +60,27 @@ pub fn read(bus: *const Bus, comptime T: type, address: u32) T {
            0x0400_0100...0x0400_010C => timer.read(T, &bus.tim, address),
            // Serial Communication 1
-            0x0400_0128 => readTodo("Read {} from SIOCNT and SIOMLT_SEND", .{T}),
+            0x0400_0128 => util.io.read.todo(log, "Read {} from SIOCNT and SIOMLT_SEND", .{T}),
            // Keypad Input
-            0x0400_0130 => readTodo("Read {} from KEYINPUT", .{T}),
+            0x0400_0130 => util.io.read.todo(log, "Read {} from KEYINPUT", .{T}),
            // Serial Communication 2
-            0x0400_0150 => readTodo("Read {} from JOY_RECV", .{T}),
+            0x0400_0150 => util.io.read.todo(log, "Read {} from JOY_RECV", .{T}),
            // Interrupts
-            0x0400_0200 => @as(T, bus.io.irq.raw) << 16 | bus.io.ie.raw,
+            0x0400_0200 => @as(u32, bus.io.irq.raw) << 16 | bus.io.ie.raw,
            0x0400_0204 => bus.io.waitcnt.raw,
            0x0400_0208 => @boolToInt(bus.io.ime),
-            else => readUndefined(log, "Tried to perform a {} read to 0x{X:0>8}", .{ T, address }),
+            0x0400_0300 => @enumToInt(bus.io.postflg),
            else => util.io.read.undef(T, log, "Tried to perform a {} read to 0x{X:0>8}", .{ T, address }),
        },
        u16 => switch (address) {
            // Display
-            0x0400_0000 => bus.ppu.dispcnt.raw,
+            0x0400_0000...0x0400_0054 => ppu.read(T, &bus.ppu, address),
            0x0400_0004 => bus.ppu.dispstat.raw,
            0x0400_0006 => bus.ppu.vcount.raw,
            0x0400_0008 => bus.ppu.bg[0].cnt.raw,
            0x0400_000A => bus.ppu.bg[1].cnt.raw,
            0x0400_000C => bus.ppu.bg[2].cnt.raw,
            0x0400_000E => bus.ppu.bg[3].cnt.raw,
            0x0400_004C => readTodo("Read {} from MOSAIC", .{T}),
            0x0400_0050 => bus.ppu.bldcnt.raw,
            // Sound
-            0x0400_0060...0x0400_009E => apu.read(T, &bus.apu, address),
+            0x0400_0060...0x0400_00A6 => apu.read(T, &bus.apu, address),
            // DMA Transfers
            0x0400_00B0...0x0400_00DE => dma.read(T, &bus.dma, address),
@@ -93,48 +89,64 @@ pub fn read(bus: *const Bus, comptime T: type, address: u32) T {
            0x0400_0100...0x0400_010E => timer.read(T, &bus.tim, address),
            // Serial Communication 1
-            0x0400_0128 => readTodo("Read {} from SIOCNT", .{T}),
+            0x0400_0128 => util.io.read.todo(log, "Read {} from SIOCNT", .{T}),
            // Keypad Input
-            0x0400_0130 => bus.io.keyinput.raw,
+            0x0400_0130 => bus.io.keyinput.load(.Monotonic).raw,
            // Serial Communication 2
-            0x0400_0134 => readTodo("Read {} from RCNT", .{T}),
+            0x0400_0134 => util.io.read.todo(log, "Read {} from RCNT", .{T}),
            0x0400_0136 => 0x0000,
            0x0400_0142 => 0x0000,
            0x0400_015A => 0x0000,
            // Interrupts
            0x0400_0200 => bus.io.ie.raw,
            0x0400_0202 => bus.io.irq.raw,
-            0x0400_0204 => readTodo("Read {} from WAITCNT", .{T}),
+            0x0400_0204 => bus.io.waitcnt.raw,
            0x0400_0206 => 0x0000,
            0x0400_0208 => @boolToInt(bus.io.ime),
-            else => readUndefined(log, "Tried to perform a {} read to 0x{X:0>8}", .{ T, address }),
+            0x0400_020A => 0x0000,
            0x0400_0300 => @enumToInt(bus.io.postflg),
            0x0400_0302 => 0x0000,
            else => util.io.read.undef(T, log, "Tried to perform a {} read to 0x{X:0>8}", .{ T, address }),
        },
        u8 => return switch (address) {
            // Display
-            0x0400_0000 => @truncate(T, bus.ppu.dispcnt.raw),
+            0x0400_0000...0x0400_0055 => ppu.read(T, &bus.ppu, address),
            0x0400_0004 => @truncate(T, bus.ppu.dispstat.raw),
            0x0400_0005 => @truncate(T, bus.ppu.dispcnt.raw >> 8),
            0x0400_0006 => @truncate(T, bus.ppu.vcount.raw),
            0x0400_0008 => @truncate(T, bus.ppu.bg[0].cnt.raw),
            0x0400_0009 => @truncate(T, bus.ppu.bg[0].cnt.raw >> 8),
            0x0400_000A => @truncate(T, bus.ppu.bg[1].cnt.raw),
            0x0400_000B => @truncate(T, bus.ppu.bg[1].cnt.raw >> 8),
            // Sound
            0x0400_0060...0x0400_00A7 => apu.read(T, &bus.apu, address),
            // DMA Transfers
            0x0400_00B0...0x0400_00DF => dma.read(T, &bus.dma, address),
            // Timers
            0x0400_0100...0x0400_010F => timer.read(T, &bus.tim, address),
            // Serial Communication 1
-            0x0400_0128 => readTodo("Read {} from SIOCNT_L", .{T}),
+            0x0400_0128 => util.io.read.todo(log, "Read {} from SIOCNT_L", .{T}),
            // Keypad Input
-            0x0400_0130 => readTodo("read {} from KEYINPUT_L", .{T}),
+            0x0400_0130 => util.io.read.todo(log, "read {} from KEYINPUT_L", .{T}),
            // Serial Communication 2
-            0x0400_0135 => readTodo("Read {} from RCNT_H", .{T}),
+            0x0400_0135 => util.io.read.todo(log, "Read {} from RCNT_H", .{T}),
            0x0400_0136, 0x0400_0137 => 0x00,
            0x0400_0142, 0x0400_0143 => 0x00,
            0x0400_015A, 0x0400_015B => 0x00,
            // Interrupts
-            0x0400_0200 => @truncate(T, bus.io.ie.raw),
+            0x0400_0200, 0x0400_0201 => @truncate(T, bus.io.ie.raw >> getHalf(@truncate(u8, address))),
            0x0400_0202, 0x0400_0203 => @truncate(T, bus.io.irq.raw >> getHalf(@truncate(u8, address))),
            0x0400_0204, 0x0400_0205 => @truncate(T, bus.io.waitcnt.raw >> getHalf(@truncate(u8, address))),
            0x0400_0206, 0x0400_0207 => 0x00,
            0x0400_0208, 0x0400_0209 => @truncate(T, @as(u16, @boolToInt(bus.io.ime)) >> getHalf(@truncate(u8, address))),
            0x0400_020A, 0x0400_020B => 0x00,
            0x0400_0300 => @enumToInt(bus.io.postflg),
-            else => readUndefined(log, "Tried to perform a {} read to 0x{X:0>8}", .{ T, address }),
+            0x0400_0301 => null,
            0x0400_0302, 0x0400_0303 => 0x00,
            else => util.io.read.undef(T, log, "Tried to perform a {} read to 0x{X:0>8}", .{ T, address }),
        },
        else => @compileError("I/O: Unsupported read width"),
    };
@@ -144,34 +156,7 @@ pub fn write(bus: *Bus, comptime T: type, address: u32, value: T) void {
    return switch (T) {
        u32 => switch (address) {
            // Display
-            0x0400_0000 => bus.ppu.dispcnt.raw = @truncate(u16, value),
+            0x0400_0000...0x0400_0054 => ppu.write(T, &bus.ppu, address, value),
            0x0400_0004 => {
                bus.ppu.dispstat.raw = @truncate(u16, value);
                bus.ppu.vcount.raw = @truncate(u16, value >> 16);
            },
            0x0400_0008 => bus.ppu.setAdjCnts(0, value),
            0x0400_000C => bus.ppu.setAdjCnts(2, value),
            0x0400_0010 => bus.ppu.setBgOffsets(0, value),
            0x0400_0014 => bus.ppu.setBgOffsets(1, value),
            0x0400_0018 => bus.ppu.setBgOffsets(2, value),
            0x0400_001C => bus.ppu.setBgOffsets(3, value),
            0x0400_0020 => bus.ppu.aff_bg[0].writePaPb(value),
            0x0400_0024 => bus.ppu.aff_bg[0].writePcPd(value),
            0x0400_0028 => bus.ppu.aff_bg[0].setX(bus.ppu.dispstat.vblank.read(), value),
            0x0400_002C => bus.ppu.aff_bg[0].setY(bus.ppu.dispstat.vblank.read(), value),
            0x0400_0030 => bus.ppu.aff_bg[1].writePaPb(value),
            0x0400_0034 => bus.ppu.aff_bg[1].writePcPd(value),
            0x0400_0038 => bus.ppu.aff_bg[1].setX(bus.ppu.dispstat.vblank.read(), value),
            0x0400_003C => bus.ppu.aff_bg[1].setY(bus.ppu.dispstat.vblank.read(), value),
            0x0400_0040 => bus.ppu.win.setH(value),
            0x0400_0044 => bus.ppu.win.setV(value),
            0x0400_0048 => bus.ppu.win.setIo(value),
            0x0400_004C => log.debug("Wrote 0x{X:0>8} to MOSAIC", .{value}),
            0x0400_0050 => {
                bus.ppu.bldcnt.raw = @truncate(u16, value);
                bus.ppu.bldalpha.raw = @truncate(u16, value >> 16);
            },
            0x0400_0054 => bus.ppu.bldy.raw = @truncate(u16, value),
            0x0400_0058...0x0400_005C => {}, // Unused
            // Sound
@@ -207,65 +192,28 @@ pub fn write(bus: *Bus, comptime T: type, address: u32, value: T) void {
            // Interrupts
            0x0400_0200 => bus.io.setIrqs(value),
-            0x0400_0204 => log.debug("Wrote 0x{X:0>8} to WAITCNT", .{value}),
+            0x0400_0204 => bus.io.waitcnt.set(@truncate(u16, value)),
            0x0400_0208 => bus.io.ime = value & 1 == 1,
-            0x0400_020C...0x0400_021C => {}, // Unused
+            0x0400_0300 => {
-            else => writeUndefined(log, "Tried to write 0x{X:0>8}{} to 0x{X:0>8}", .{ value, T, address }),
+                bus.io.postflg = @intToEnum(PostFlag, value & 1);
                bus.io.haltcnt = if (value >> 15 & 1 == 0) .Halt else @panic("TODO: Implement STOP");
            },
            else => util.io.write.undef(log, "Tried to write 0x{X:0>8}{} to 0x{X:0>8}", .{ value, T, address }),
        },
        u16 => switch (address) {
            // Display
-            0x0400_0000 => bus.ppu.dispcnt.raw = value,
+            0x0400_0000...0x0400_0054 => ppu.write(T, &bus.ppu, address, value),
-            0x0400_0004 => bus.ppu.dispstat.raw = value,
+            0x0400_0056 => {}, // Not used
            0x0400_0006 => {}, // vcount is read-only
            0x0400_0008 => bus.ppu.bg[0].cnt.raw = value,
            0x0400_000A => bus.ppu.bg[1].cnt.raw = value,
            0x0400_000C => bus.ppu.bg[2].cnt.raw = value,
            0x0400_000E => bus.ppu.bg[3].cnt.raw = value,
            0x0400_0010 => bus.ppu.bg[0].hofs.raw = value, // TODO: Don't write out every HOFS / VOFS?
            0x0400_0012 => bus.ppu.bg[0].vofs.raw = value,
            0x0400_0014 => bus.ppu.bg[1].hofs.raw = value,
            0x0400_0016 => bus.ppu.bg[1].vofs.raw = value,
            0x0400_0018 => bus.ppu.bg[2].hofs.raw = value,
            0x0400_001A => bus.ppu.bg[2].vofs.raw = value,
            0x0400_001C => bus.ppu.bg[3].hofs.raw = value,
            0x0400_001E => bus.ppu.bg[3].vofs.raw = value,
            0x0400_0020 => bus.ppu.aff_bg[0].pa = @bitCast(i16, value),
            0x0400_0022 => bus.ppu.aff_bg[0].pb = @bitCast(i16, value),
            0x0400_0024 => bus.ppu.aff_bg[0].pc = @bitCast(i16, value),
            0x0400_0026 => bus.ppu.aff_bg[0].pd = @bitCast(i16, value),
            0x0400_0028 => bus.ppu.aff_bg[0].x = @bitCast(i32, @bitCast(u32, bus.ppu.aff_bg[0].x) & 0xFFFF_0000 | value),
            0x0400_002A => bus.ppu.aff_bg[0].x = @bitCast(i32, @bitCast(u32, bus.ppu.aff_bg[0].x) & 0x0000_FFFF | (@as(u32, value) << 16)),
            0x0400_002C => bus.ppu.aff_bg[0].y = @bitCast(i32, @bitCast(u32, bus.ppu.aff_bg[0].y) & 0xFFFF_0000 | value),
            0x0400_002E => bus.ppu.aff_bg[0].y = @bitCast(i32, @bitCast(u32, bus.ppu.aff_bg[0].y) & 0x0000_FFFF | (@as(u32, value) << 16)),
            0x0400_0030 => bus.ppu.aff_bg[1].pa = @bitCast(i16, value),
            0x0400_0032 => bus.ppu.aff_bg[1].pb = @bitCast(i16, value),
            0x0400_0034 => bus.ppu.aff_bg[1].pc = @bitCast(i16, value),
            0x0400_0036 => bus.ppu.aff_bg[1].pd = @bitCast(i16, value),
            0x0400_0038 => bus.ppu.aff_bg[1].x = @bitCast(i32, @bitCast(u32, bus.ppu.aff_bg[1].x) & 0xFFFF_0000 | value),
            0x0400_003A => bus.ppu.aff_bg[1].x = @bitCast(i32, @bitCast(u32, bus.ppu.aff_bg[1].x) & 0x0000_FFFF | (@as(u32, value) << 16)),
            0x0400_003C => bus.ppu.aff_bg[1].y = @bitCast(i32, @bitCast(u32, bus.ppu.aff_bg[1].y) & 0xFFFF_0000 | value),
            0x0400_003E => bus.ppu.aff_bg[1].y = @bitCast(i32, @bitCast(u32, bus.ppu.aff_bg[1].y) & 0x0000_FFFF | (@as(u32, value) << 16)),
            0x0400_0040 => bus.ppu.win.h[0].raw = value,
            0x0400_0042 => bus.ppu.win.h[1].raw = value,
            0x0400_0044 => bus.ppu.win.v[0].raw = value,
            0x0400_0046 => bus.ppu.win.v[1].raw = value,
            0x0400_0048 => bus.ppu.win.in.raw = value,
            0x0400_004A => bus.ppu.win.out.raw = value,
            0x0400_004C => log.debug("Wrote 0x{X:0>4} to MOSAIC", .{value}),
            0x0400_0050 => bus.ppu.bldcnt.raw = value,
            0x0400_0052 => bus.ppu.bldalpha.raw = value,
            0x0400_0054 => bus.ppu.bldy.raw = value,
            0x0400_004E, 0x0400_0056 => {}, // Not used
            // Sound
-            0x0400_0060...0x0400_009E => apu.write(T, &bus.apu, address, value),
+            0x0400_0060...0x0400_00A6 => apu.write(T, &bus.apu, address, value),
            // Dma Transfers
            0x0400_00B0...0x0400_00DE => dma.write(T, &bus.dma, address, value),
            // Timers
            0x0400_0100...0x0400_010E => timer.write(T, &bus.tim, address, value),
-            0x0400_0114 => {}, // TODO: Gyakuten Saiban writes 0x8000 to 0x0400_0114
+            0x0400_0114 => {},
            0x0400_0110 => {}, // Not Used,
            // Serial Communication 1
@@ -289,27 +237,29 @@ pub fn write(bus: *Bus, comptime T: type, address: u32, value: T) void {
            // Interrupts
            0x0400_0200 => bus.io.ie.raw = value,
            0x0400_0202 => bus.io.irq.raw &= ~value,
-            0x0400_0204 => log.debug("Wrote 0x{X:0>4} to WAITCNT", .{value}),
+            0x0400_0204 => bus.io.waitcnt.set(value),
            0x0400_0206 => {},
            0x0400_0208 => bus.io.ime = value & 1 == 1,
-            0x0400_0206, 0x0400_020A => {}, // Not Used
+            0x0400_020A => {},
-            else => writeUndefined(log, "Tried to write 0x{X:0>4}{} to 0x{X:0>8}", .{ value, T, address }),
+            0x0400_0300 => {
                bus.io.postflg = @intToEnum(PostFlag, value & 1);
                bus.io.haltcnt = if (value >> 15 & 1 == 0) .Halt else @panic("TODO: Implement STOP");
            },
            else => util.io.write.undef(log, "Tried to write 0x{X:0>4}{} to 0x{X:0>8}", .{ value, T, address }),
        },
        u8 => switch (address) {
            // Display
-            0x0400_0004 => bus.ppu.dispstat.raw = (bus.ppu.dispstat.raw & 0xFF00) | value,
+            0x0400_0000...0x0400_0055 => ppu.write(T, &bus.ppu, address, value),
            0x0400_0005 => bus.ppu.dispstat.raw = (@as(u16, value) << 8) | (bus.ppu.dispstat.raw & 0xFF),
            0x0400_0008 => bus.ppu.bg[0].cnt.raw = (bus.ppu.bg[0].cnt.raw & 0xFF00) | value,
            0x0400_0009 => bus.ppu.bg[0].cnt.raw = (@as(u16, value) << 8) | (bus.ppu.bg[0].cnt.raw & 0xFF),
            0x0400_000A => bus.ppu.bg[1].cnt.raw = (bus.ppu.bg[1].cnt.raw & 0xFF00) | value,
            0x0400_000B => bus.ppu.bg[1].cnt.raw = (@as(u16, value) << 8) | (bus.ppu.bg[1].cnt.raw & 0xFF),
            0x0400_0048 => bus.ppu.win.setInL(value),
            0x0400_0049 => bus.ppu.win.setInH(value),
            0x0400_004A => bus.ppu.win.setOutL(value),
            0x0400_0054 => bus.ppu.bldy.raw = (bus.ppu.bldy.raw & 0xFF00) | value,
            // Sound
            0x0400_0060...0x0400_00A7 => apu.write(T, &bus.apu, address, value),
            // Dma Transfers
            0x0400_00B0...0x0400_00DF => dma.write(T, &bus.dma, address, value),
            // Timers
            0x0400_0100...0x0400_010F => timer.write(T, &bus.tim, address, value),
            // Serial Communication 1
            0x0400_0120 => log.debug("Wrote 0x{X:0>2} to SIODATA32_L_L", .{value}),
            0x0400_0128 => log.debug("Wrote 0x{X:0>2} to SIOCNT_L", .{value}),
@@ -319,23 +269,25 @@ pub fn write(bus: *Bus, comptime T: type, address: u32, value: T) void {
            0x0400_0140 => log.debug("Wrote 0x{X:0>2} to JOYCNT_L", .{value}),
            // Interrupts
            0x0400_0200, 0x0400_0201 => bus.io.ie.raw = setHalf(u16, bus.io.ie.raw, @truncate(u8, address), value),
            0x0400_0202 => bus.io.irq.raw &= ~@as(u16, value),
            0x0400_0203 => bus.io.irq.raw &= ~@as(u16, value) << 8, // TODO: Is this good?
            0x0400_0204, 0x0400_0205 => bus.io.waitcnt.set(setHalf(u16, @truncate(u16, bus.io.waitcnt.raw), @truncate(u8, address), value)),
            0x0400_0206, 0x0400_0207 => {},
            0x0400_0208 => bus.io.ime = value & 1 == 1,
-            0x0400_0300 => bus.io.postflg = std.meta.intToEnum(PostFlag, value & 1) catch unreachable,
+            0x0400_0209 => {},
            0x0400_020A, 0x0400_020B => {},
            0x0400_0300 => bus.io.postflg = @intToEnum(PostFlag, value & 1),
            0x0400_0301 => bus.io.haltcnt = if (value >> 7 & 1 == 0) .Halt else std.debug.panic("TODO: Implement STOP", .{}),
            0x0400_0410 => log.debug("Wrote 0x{X:0>2} to the common yet undocumented 0x{X:0>8}", .{ value, address }),
-            else => writeUndefined(log, "Tried to write 0x{X:0>2}{} to 0x{X:0>8}", .{ value, T, address }),
+            else => util.io.write.undef(log, "Tried to write 0x{X:0>2}{} to 0x{X:0>8}", .{ value, T, address }),
        },
        else => @compileError("I/O: Unsupported write width"),
    };
 }
 fn readTodo(comptime format: []const u8, args: anytype) u8 {
    log.debug(format, args);
    return 0;
 }
 /// Read / Write
 pub const PostFlag = enum(u1) {
    FirstBoot = 0,
@@ -365,14 +317,22 @@ pub const DisplayControl = extern union {
 /// Read / Write
 pub const DisplayStatus = extern union {
    /// read-only
    vblank: Bit(u16, 0),
    /// read-only
    hblank: Bit(u16, 1),
    // read-only
    coincidence: Bit(u16, 2),
    vblank_irq: Bit(u16, 3),
    hblank_irq: Bit(u16, 4),
    vcount_irq: Bit(u16, 5),
    vcount_trigger: Bitfield(u16, 8, 8),
    raw: u16,
    pub fn set(self: *DisplayStatus, value: u16) void {
        const mask: u16 = 0x00C7; // set bits are read-only
        self.raw = (self.raw & mask) | (value & ~mask);
    }
 };
 /// Read Only
@@ -416,6 +376,31 @@ const KeyInput = extern union {
    raw: u16,
 };
 const AtomicKeyInput = struct {
    const Self = @This();
    const Ordering = std.atomic.Ordering;
    inner: KeyInput,
    pub fn init(value: KeyInput) Self {
        return .{ .inner = value };
    }
    pub inline fn load(self: *const Self, comptime ordering: Ordering) KeyInput {
        return .{ .raw = switch (ordering) {
            .AcqRel, .Release => @compileError("not supported for atomic loads"),
            else => @atomicLoad(u16, &self.inner.raw, ordering),
        } };
    }
    pub inline fn store(self: *Self, value: u16, comptime ordering: Ordering) void {
        switch (ordering) {
            .AcqRel, .Acquire => @compileError("not supported for atomic stores"),
            else => @atomicStore(u16, &self.inner.raw, value, ordering),
        }
    }
 };
 // Read / Write
 pub const BackgroundControl = extern union {
    priority: Bitfield(u16, 0, 2),
@@ -663,3 +648,24 @@ pub const SoundBias = extern union {
    sampling_cycle: Bitfield(u16, 14, 2),
    raw: u16,
 };
 /// Read / Write
 pub const WaitControl = extern union {
    sram_cnt: Bitfield(u16, 0, 2),
    s0_first: Bitfield(u16, 2, 2),
    s0_second: Bit(u16, 4),
    s1_first: Bitfield(u16, 5, 2),
    s1_second: Bit(u16, 7),
    s2_first: Bitfield(u16, 8, 2),
    s2_second: Bit(u16, 10),
    phi_out: Bitfield(u16, 11, 2),
    prefetch_enable: Bit(u16, 14),
    pak_kind: Bit(u16, 15),
    raw: u16,
    pub fn set(self: *WaitControl, value: u16) void {
        const mask: u16 = 0x8000; // set bits are read-only
        self.raw = (self.raw & mask) | (value & ~mask);
    }
 };
--- a/src/core/bus/timer.zig
+++ b/src/core/bus/timer.zig
@@ -1,70 +1,100 @@
 const std = @import("std");
 const util = @import("../../util.zig");
 const TimerControl = @import("io.zig").TimerControl;
 const Io = @import("io.zig").Io;
 const Scheduler = @import("../scheduler.zig").Scheduler;
 const Event = @import("../scheduler.zig").Event;
 const Arm7tdmi = @import("../cpu.zig").Arm7tdmi;
-const readUndefined = @import("../util.zig").readUndefined;
+pub const TimerTuple = struct { Timer(0), Timer(1), Timer(2), Timer(3) };
 const writeUndefined = @import("../util.zig").writeUndefined;
 pub const TimerTuple = std.meta.Tuple(&[_]type{ Timer(0), Timer(1), Timer(2), Timer(3) });
 const log = std.log.scoped(.Timer);
 const getHalf = util.getHalf;
 const setHalf = util.setHalf;
 pub fn create(sched: *Scheduler) TimerTuple {
    return .{ Timer(0).init(sched), Timer(1).init(sched), Timer(2).init(sched), Timer(3).init(sched) };
 }
-pub fn read(comptime T: type, tim: *const TimerTuple, addr: u32) T {
+pub fn read(comptime T: type, tim: *const TimerTuple, addr: u32) ?T {
-    const nybble = @truncate(u4, addr);
+    const nybble_addr = @truncate(u4, addr);
    return switch (T) {
-        u32 => switch (nybble) {
+        u32 => switch (nybble_addr) {
-            0x0 => @as(T, tim.*[0].cnt.raw) << 16 | tim.*[0].getCntL(),
+            0x0 => @as(T, tim.*[0].cnt.raw) << 16 | tim.*[0].timcntL(),
-            0x4 => @as(T, tim.*[1].cnt.raw) << 16 | tim.*[1].getCntL(),
+            0x4 => @as(T, tim.*[1].cnt.raw) << 16 | tim.*[1].timcntL(),
-            0x8 => @as(T, tim.*[2].cnt.raw) << 16 | tim.*[2].getCntL(),
+            0x8 => @as(T, tim.*[2].cnt.raw) << 16 | tim.*[2].timcntL(),
-            0xC => @as(T, tim.*[3].cnt.raw) << 16 | tim.*[3].getCntL(),
+            0xC => @as(T, tim.*[3].cnt.raw) << 16 | tim.*[3].timcntL(),
-            else => readUndefined(log, "Tried to perform a {} read to 0x{X:0>8}", .{ T, addr }),
+            else => util.io.read.err(T, log, "unaligned {} read from 0x{X:0>8}", .{ T, addr }),
        },
-        u16 => switch (nybble) {
+        u16 => switch (nybble_addr) {
-            0x0 => tim.*[0].getCntL(),
+            0x0 => tim.*[0].timcntL(),
            0x2 => tim.*[0].cnt.raw,
-            0x4 => tim.*[1].getCntL(),
+
            0x4 => tim.*[1].timcntL(),
            0x6 => tim.*[1].cnt.raw,
-            0x8 => tim.*[2].getCntL(),
+
            0x8 => tim.*[2].timcntL(),
            0xA => tim.*[2].cnt.raw,
-            0xC => tim.*[3].getCntL(),
+
            0xC => tim.*[3].timcntL(),
            0xE => tim.*[3].cnt.raw,
-            else => readUndefined(log, "Tried to perform a {} read to 0x{X:0>8}", .{ T, addr }),
+            else => util.io.read.err(T, log, "unaligned {} read from 0x{X:0>8}", .{ T, addr }),
        },
        u8 => switch (nybble_addr) {
            0x0, 0x1 => @truncate(T, tim.*[0].timcntL() >> getHalf(nybble_addr)),
            0x2, 0x3 => @truncate(T, tim.*[0].cnt.raw >> getHalf(nybble_addr)),
            0x4, 0x5 => @truncate(T, tim.*[1].timcntL() >> getHalf(nybble_addr)),
            0x6, 0x7 => @truncate(T, tim.*[1].cnt.raw >> getHalf(nybble_addr)),
            0x8, 0x9 => @truncate(T, tim.*[2].timcntL() >> getHalf(nybble_addr)),
            0xA, 0xB => @truncate(T, tim.*[2].cnt.raw >> getHalf(nybble_addr)),
            0xC, 0xD => @truncate(T, tim.*[3].timcntL() >> getHalf(nybble_addr)),
            0xE, 0xF => @truncate(T, tim.*[3].cnt.raw >> getHalf(nybble_addr)),
        },
        u8 => readUndefined(log, "Tried to perform a {} read to 0x{X:0>8}", .{ T, addr }),
        else => @compileError("TIM: Unsupported read width"),
    };
 }
 pub fn write(comptime T: type, tim: *TimerTuple, addr: u32, value: T) void {
-    const nybble = @truncate(u4, addr);
+    const nybble_addr = @truncate(u4, addr);
    return switch (T) {
-        u32 => switch (nybble) {
+        u32 => switch (nybble_addr) {
-            0x0 => tim.*[0].setCnt(value),
+            0x0 => tim.*[0].setTimcnt(value),
-            0x4 => tim.*[1].setCnt(value),
+            0x4 => tim.*[1].setTimcnt(value),
-            0x8 => tim.*[2].setCnt(value),
+            0x8 => tim.*[2].setTimcnt(value),
-            0xC => tim.*[3].setCnt(value),
+            0xC => tim.*[3].setTimcnt(value),
-            else => writeUndefined(log, "Tried to write 0x{X:0>8}{} to 0x{X:0>8}", .{ value, T, addr }),
+            else => util.io.write.undef(log, "Tried to write 0x{X:0>8}{} to 0x{X:0>8}", .{ value, T, addr }),
        },
-        u16 => switch (nybble) {
+        u16 => switch (nybble_addr) {
-            0x0 => tim.*[0].setCntL(value),
+            0x0 => tim.*[0].setTimcntL(value),
-            0x2 => tim.*[0].setCntH(value),
+            0x2 => tim.*[0].setTimcntH(value),
-            0x4 => tim.*[1].setCntL(value),
+
-            0x6 => tim.*[1].setCntH(value),
+            0x4 => tim.*[1].setTimcntL(value),
-            0x8 => tim.*[2].setCntL(value),
+            0x6 => tim.*[1].setTimcntH(value),
-            0xA => tim.*[2].setCntH(value),
+
-            0xC => tim.*[3].setCntL(value),
+            0x8 => tim.*[2].setTimcntL(value),
-            0xE => tim.*[3].setCntH(value),
+            0xA => tim.*[2].setTimcntH(value),
-            else => writeUndefined(log, "Tried to write 0x{X:0>4}{} to 0x{X:0>8}", .{ value, T, addr }),
+
            0xC => tim.*[3].setTimcntL(value),
            0xE => tim.*[3].setTimcntH(value),
            else => util.io.write.undef(log, "Tried to write 0x{X:0>4}{} to 0x{X:0>8}", .{ value, T, addr }),
        },
        u8 => switch (nybble_addr) {
            0x0, 0x1 => tim.*[0].setTimcntL(setHalf(u16, tim.*[0]._reload, nybble_addr, value)),
            0x2, 0x3 => tim.*[0].setTimcntH(setHalf(u16, tim.*[0].cnt.raw, nybble_addr, value)),
            0x4, 0x5 => tim.*[1].setTimcntL(setHalf(u16, tim.*[1]._reload, nybble_addr, value)),
            0x6, 0x7 => tim.*[1].setTimcntH(setHalf(u16, tim.*[1].cnt.raw, nybble_addr, value)),
            0x8, 0x9 => tim.*[2].setTimcntL(setHalf(u16, tim.*[2]._reload, nybble_addr, value)),
            0xA, 0xB => tim.*[2].setTimcntH(setHalf(u16, tim.*[2].cnt.raw, nybble_addr, value)),
            0xC, 0xD => tim.*[3].setTimcntL(setHalf(u16, tim.*[3]._reload, nybble_addr, value)),
            0xE, 0xF => tim.*[3].setTimcntH(setHalf(u16, tim.*[3].cnt.raw, nybble_addr, value)),
        },
        u8 => writeUndefined(log, "Tried to write 0x{X:0>2}{} to 0x{X:0>8}", .{ value, T, addr }),
        else => @compileError("TIM: Unsupported write width"),
    };
 }
@@ -73,13 +103,13 @@ fn Timer(comptime id: u2) type {
    return struct {
        const Self = @This();
-        /// Read Only, Internal. Please use self.getCntL()
+        /// Read Only, Internal. Please use self.timcntL()
        _counter: u16,
-        /// Write Only, Internal. Please use self.setCntL()
+        /// Write Only, Internal. Please use self.setTimcntL()
        _reload: u16,
-        /// Write Only, Internal. Please use self.setCntH()
+        /// Write Only, Internal. Please use self.setTimcntH()
        cnt: TimerControl,
        /// Internal.
@@ -98,47 +128,62 @@ fn Timer(comptime id: u2) type {
            };
        }
-        /// TIMCNT_L
+        /// TIMCNT_L Getter
-        pub fn getCntL(self: *const Self) u16 {
+        pub fn timcntL(self: *const Self) u16 {
            if (self.cnt.cascade.read() or !self.cnt.enabled.read()) return self._counter;
            return self._counter +% @truncate(u16, (self.sched.now() - self._start_timestamp) / self.frequency());
        }
-        /// TIMCNT_L
+        /// TIMCNT_L Setter
-        pub fn setCntL(self: *Self, halfword: u16) void {
+        pub fn setTimcntL(self: *Self, halfword: u16) void {
            self._reload = halfword;
        }
        /// TIMCNT_L & TIMCNT_H
-        pub fn setCnt(self: *Self, word: u32) void {
+        pub fn setTimcnt(self: *Self, word: u32) void {
-            self.setCntL(@truncate(u16, word));
+            self.setTimcntL(@truncate(u16, word));
-            self.setCntH(@truncate(u16, word >> 16));
+            self.setTimcntH(@truncate(u16, word >> 16));
        }
        /// TIMCNT_H
-        pub fn setCntH(self: *Self, halfword: u16) void {
+        pub fn setTimcntH(self: *Self, halfword: u16) void {
            const new = TimerControl{ .raw = halfword };
-            // If Timer happens to be enabled, It will either be resheduled or disabled
+            if (self.cnt.enabled.read()) {
-            self.sched.removeScheduledEvent(.{ .TimerOverflow = id });
+                // timer was already enabled
-            if (self.cnt.enabled.read() and (new.cascade.read() or !new.enabled.read())) {
+                // If enabled falling edge or cascade falling edge, timer is paused
-                // Either through the cascade bit or the enable bit, the timer has effectively been disabled
+                if (!new.enabled.read() or (!self.cnt.cascade.read() and new.cascade.read())) {
-                // The Counter should hold whatever value it should have been at when it was disabled
+                    self.sched.removeScheduledEvent(.{ .TimerOverflow = id });
-                self._counter +%= @truncate(u16, (self.sched.now() - self._start_timestamp) / self.frequency());
+
                    // Counter should hold the value it stopped at meaning we have to calculate it now
                    self._counter +%= @truncate(u16, (self.sched.now() - self._start_timestamp) / self.frequency());
                }
                // the timer has always been enabled, but the cascade bit which was blocking the timer has been unset
                if (new.enabled.read() and (self.cnt.cascade.read() and !new.cascade.read())) {
                    // we want to reschedule the timer event, however we won't reload the counter.
                    // the invariant here is that self._counter holds the already calculated paused value
                    self.rescheduleTimerExpire(0);
                }
            } else {
                // the timer was previously disabeld
                if (new.enabled.read()) {
                    // timer should start counting (with a reloaded counter value)
                    self._counter = self._reload;
                    // if cascade happens to be set, the timer doesn't actually do anything though
                    if (!new.cascade.read()) self.rescheduleTimerExpire(0);
                }
            }
            // The counter is only reloaded on the rising edge of the enable bit
            if (!self.cnt.enabled.read() and new.enabled.read()) self._counter = self._reload;
            // If Timer is enabled and we're not cascading, we need to schedule an overflow event
            if (new.enabled.read() and !new.cascade.read()) self.scheduleOverflow(0);
            self.cnt.raw = halfword;
        }
-        pub fn handleOverflow(self: *Self, cpu: *Arm7tdmi, late: u64) void {
+        pub fn onTimerExpire(self: *Self, cpu: *Arm7tdmi, late: u64) void {
            // Fire IRQ if enabled
            const io = &cpu.bus.io;
@@ -155,34 +200,31 @@ fn Timer(comptime id: u2) type {
            // DMA Sound Things
            if (id == 0 or id == 1) {
-                cpu.bus.apu.handleTimerOverflow(cpu, id);
+                cpu.bus.apu.onDmaAudioSampleRequest(cpu, id);
            }
            // Perform Cascade Behaviour
            switch (id) {
-                0 => if (cpu.bus.tim[1].cnt.cascade.read()) {
+                inline 0, 1, 2 => |idx| {
-                    cpu.bus.tim[1]._counter +%= 1;
+                    const next = idx + 1;
-                    if (cpu.bus.tim[1]._counter == 0) cpu.bus.tim[1].handleOverflow(cpu, late);
+
                    if (cpu.bus.tim[next].cnt.cascade.read()) {
                        cpu.bus.tim[next]._counter +%= 1;
                        if (cpu.bus.tim[next]._counter == 0) cpu.bus.tim[next].onTimerExpire(cpu, late);
                    }
                },
-                1 => if (cpu.bus.tim[2].cnt.cascade.read()) {
+                3 => {}, // THere is no timer for TIM3 to cascade to
                    cpu.bus.tim[2]._counter +%= 1;
                    if (cpu.bus.tim[2]._counter == 0) cpu.bus.tim[2].handleOverflow(cpu, late);
                },
                2 => if (cpu.bus.tim[3].cnt.cascade.read()) {
                    cpu.bus.tim[3]._counter +%= 1;
                    if (cpu.bus.tim[3]._counter == 0) cpu.bus.tim[3].handleOverflow(cpu, late);
                },
                3 => {}, // There is no Timer for TIM3 to "cascade" to,
            }
            // Reschedule Timer if we're not cascading
-            if (!self.cnt.cascade.read()) {
+            // TIM0 cascade value is N/A
            if (id == 0 or !self.cnt.cascade.read()) {
                self._counter = self._reload;
-                self.scheduleOverflow(late);
+                self.rescheduleTimerExpire(late);
            }
        }
-        fn scheduleOverflow(self: *Self, late: u64) void {
+        fn rescheduleTimerExpire(self: *Self, late: u64) void {
            const when = (@as(u64, 0x10000) - self._counter) * self.frequency();
            self._start_timestamp = self.sched.now();
--- a/src/core/cpu.zig
+++ b/src/core/cpu.zig
@@ -1,18 +1,17 @@
 const std = @import("std");
 const util = @import("util.zig");
 const Bus = @import("Bus.zig");
 const Bit = @import("bitfield").Bit;
 const Bitfield = @import("bitfield").Bitfield;
 const Scheduler = @import("scheduler.zig").Scheduler;
-const FilePaths = @import("util.zig").FilePaths;
+const Logger = @import("../util.zig").Logger;
 const Logger = @import("util.zig").Logger;
 const File = std.fs.File;
 const log = std.log.scoped(.Arm7Tdmi);
 // ARM Instructions
 pub const arm = struct {
-    pub const InstrFn = fn (*Arm7tdmi, *Bus, u32) void;
+    pub const InstrFn = *const fn (*Arm7tdmi, *Bus, u32) void;
    const lut: [0x1000]InstrFn = populate();
    const processing = @import("cpu/arm/data_processing.zig").dataProcessing;
@@ -28,9 +27,14 @@ pub const arm = struct {
    const multiply = @import("cpu/arm/multiply.zig").multiply;
    const multiplyLong = @import("cpu/arm/multiply.zig").multiplyLong;
    /// Determine index into ARM InstrFn LUT
    fn idx(opcode: u32) u12 {
        return @truncate(u12, opcode >> 20 & 0xFF) << 4 | @truncate(u12, opcode >> 4 & 0xF);
    }
    // Undefined ARM Instruction handler
    fn und(cpu: *Arm7tdmi, _: *Bus, opcode: u32) void {
-        const id = armIdx(opcode);
+        const id = idx(opcode);
        cpu.panic("[CPU/Decode] ID: 0x{X:0>3} 0x{X:0>8} is an illegal opcode", .{ id, opcode });
    }
@@ -110,7 +114,7 @@ pub const arm = struct {
 // THUMB Instructions
 pub const thumb = struct {
-    pub const InstrFn = fn (*Arm7tdmi, *Bus, u16) void;
+    pub const InstrFn = *const fn (*Arm7tdmi, *Bus, u16) void;
    const lut: [0x400]InstrFn = populate();
    const processing = @import("cpu/thumb/data_processing.zig");
@@ -120,9 +124,14 @@ pub const thumb = struct {
    const swi = @import("cpu/thumb/software_interrupt.zig").fmt17;
    const branch = @import("cpu/thumb/branch.zig");
    /// Determine index into THUMB InstrFn LUT
    fn idx(opcode: u16) u10 {
        return @truncate(u10, opcode >> 6);
    }
    /// Undefined THUMB Instruction Handler
    fn und(cpu: *Arm7tdmi, _: *Bus, opcode: u16) void {
-        const id = thumbIdx(opcode);
+        const id = idx(opcode);
        cpu.panic("[CPU/Decode] ID: 0b{b:0>10} 0x{X:0>2} is an illegal opcode", .{ id, opcode });
    }
@@ -226,76 +235,87 @@ pub const thumb = struct {
    }
 };
 const cpu_logging = @import("emu.zig").cpu_logging;
 const log = std.log.scoped(.Arm7Tdmi);
 pub const Arm7tdmi = struct {
    const Self = @This();
    r: [16]u32,
    pipe: Pipeline,
    sched: *Scheduler,
    bus: *Bus,
    cpsr: PSR,
    spsr: PSR,
-    /// Storage  for R8_fiq -> R12_fiq and their normal counterparts
+    bank: Bank,
    /// e.g [r[0 + 8], fiq_r[0 + 8], r[1 + 8], fiq_r[1 + 8]...]
    banked_fiq: [2 * 5]u32,
    /// Storage for r13_<mode>, r14_<mode>
    /// e.g. [r13, r14, r13_svc, r14_svc]
    banked_r: [2 * 6]u32,
    banked_spsr: [5]PSR,
    logger: ?Logger,
-    pub fn init(sched: *Scheduler, bus: *Bus) Self {
+    /// Bank of Registers from other CPU Modes
    const Bank = struct {
        /// Storage for r13_<mode>, r14_<mode>
        /// e.g. [r13, r14, r13_svc, r14_svc]
        r: [2 * 6]u32,
        /// Storage  for R8_fiq -> R12_fiq and their normal counterparts
        /// e.g [r[0 + 8], fiq_r[0 + 8], r[1 + 8], fiq_r[1 + 8]...]
        fiq: [2 * 5]u32,
        spsr: [5]PSR,
        const Kind = enum(u1) {
            R13 = 0,
            R14,
        };
        pub fn create() Bank {
            return .{
                .r = [_]u32{0x00} ** 12,
                .fiq = [_]u32{0x00} ** 10,
                .spsr = [_]PSR{.{ .raw = 0x0000_0000 }} ** 5,
            };
        }
        inline fn regIdx(mode: Mode, kind: Kind) usize {
            const idx: usize = switch (mode) {
                .User, .System => 0,
                .Supervisor => 1,
                .Abort => 2,
                .Undefined => 3,
                .Irq => 4,
                .Fiq => 5,
            };
            return (idx * 2) + if (kind == .R14) @as(usize, 1) else 0;
        }
        inline fn spsrIdx(mode: Mode) usize {
            return switch (mode) {
                .Supervisor => 0,
                .Abort => 1,
                .Undefined => 2,
                .Irq => 3,
                .Fiq => 4,
                else => std.debug.panic("[CPU/Mode] {} does not have a SPSR Register", .{mode}),
            };
        }
        inline fn fiqIdx(i: usize, mode: Mode) usize {
            return (i * 2) + if (mode == .Fiq) @as(usize, 1) else 0;
        }
    };
    pub fn init(sched: *Scheduler, bus: *Bus, log_file: ?std.fs.File) Self {
        return Self{
            .r = [_]u32{0x00} ** 16,
            .pipe = Pipeline.init(),
            .sched = sched,
            .bus = bus,
            .cpsr = .{ .raw = 0x0000_001F },
            .spsr = .{ .raw = 0x0000_0000 },
-            .banked_fiq = [_]u32{0x00} ** 10,
+            .bank = Bank.create(),
-            .banked_r = [_]u32{0x00} ** 12,
+            .logger = if (log_file) |file| Logger.init(file) else null,
            .banked_spsr = [_]PSR{.{ .raw = 0x0000_0000 }} ** 5,
            .logger = null,
        };
    }
    pub fn attach(self: *Self, log_file: std.fs.File) void {
        self.logger = Logger.init(log_file);
    }
    inline fn bankedIdx(mode: Mode, kind: BankedKind) usize {
        const idx: usize = switch (mode) {
            .User, .System => 0,
            .Supervisor => 1,
            .Abort => 2,
            .Undefined => 3,
            .Irq => 4,
            .Fiq => 5,
        };
        return (idx * 2) + if (kind == .R14) @as(usize, 1) else 0;
    }
    inline fn bankedSpsrIndex(mode: Mode) usize {
        return switch (mode) {
            .Supervisor => 0,
            .Abort => 1,
            .Undefined => 2,
            .Irq => 3,
            .Fiq => 4,
            else => std.debug.panic("[CPU/Mode] {} does not have a SPSR Register", .{mode}),
        };
    }
    inline fn bankedFiqIdx(i: usize, mode: Mode) usize {
        return (i * 2) + if (mode == .Fiq) @as(usize, 1) else 0;
    }
    pub inline fn hasSPSR(self: *const Self) bool {
        const mode = getModeChecked(self, self.cpsr.mode.read());
        return switch (mode) {
@@ -331,14 +351,14 @@ pub const Arm7tdmi = struct {
        switch (idx) {
            8...12 => {
                if (current == .Fiq) {
-                    self.banked_fiq[bankedFiqIdx(idx - 8, .User)] = value;
+                    self.bank.fiq[Bank.fiqIdx(idx - 8, .User)] = value;
                } else self.r[idx] = value;
            },
            13, 14 => switch (current) {
                .User, .System => self.r[idx] = value,
                else => {
-                    const kind = std.meta.intToEnum(BankedKind, idx - 13) catch unreachable;
+                    const kind = std.meta.intToEnum(Bank.Kind, idx - 13) catch unreachable;
-                    self.banked_r[bankedIdx(.User, kind)] = value;
+                    self.bank.r[Bank.regIdx(.User, kind)] = value;
                },
            },
            else => self.r[idx] = value, // R0 -> R7  and R15
@@ -349,12 +369,12 @@ pub const Arm7tdmi = struct {
        const current = getModeChecked(self, self.cpsr.mode.read());
        return switch (idx) {
-            8...12 => if (current == .Fiq) self.banked_fiq[bankedFiqIdx(idx - 8, .User)] else self.r[idx],
+            8...12 => if (current == .Fiq) self.bank.fiq[Bank.fiqIdx(idx - 8, .User)] else self.r[idx],
            13, 14 => switch (current) {
                .User, .System => self.r[idx],
                else => blk: {
-                    const kind = std.meta.intToEnum(BankedKind, idx - 13) catch unreachable;
+                    const kind = std.meta.intToEnum(Bank.Kind, idx - 13) catch unreachable;
-                    break :blk self.banked_r[bankedIdx(.User, kind)];
+                    break :blk self.bank.r[Bank.regIdx(.User, kind)];
                },
            },
            else => self.r[idx], // R0 -> R7  and R15
@@ -367,98 +387,95 @@ pub const Arm7tdmi = struct {
        // Bank R8 -> r12
        var i: usize = 0;
        while (i < 5) : (i += 1) {
-            self.banked_fiq[bankedFiqIdx(i, now)] = self.r[8 + i];
+            self.bank.fiq[Bank.fiqIdx(i, now)] = self.r[8 + i];
        }
        // Bank r13, r14, SPSR
        switch (now) {
            .User, .System => {
-                self.banked_r[bankedIdx(now, .R13)] = self.r[13];
+                self.bank.r[Bank.regIdx(now, .R13)] = self.r[13];
-                self.banked_r[bankedIdx(now, .R14)] = self.r[14];
+                self.bank.r[Bank.regIdx(now, .R14)] = self.r[14];
            },
            else => {
-                self.banked_r[bankedIdx(now, .R13)] = self.r[13];
+                self.bank.r[Bank.regIdx(now, .R13)] = self.r[13];
-                self.banked_r[bankedIdx(now, .R14)] = self.r[14];
+                self.bank.r[Bank.regIdx(now, .R14)] = self.r[14];
-                self.banked_spsr[bankedSpsrIndex(now)] = self.spsr;
+                self.bank.spsr[Bank.spsrIdx(now)] = self.spsr;
            },
        }
        // Grab R8 -> R12
        i = 0;
        while (i < 5) : (i += 1) {
-            self.r[8 + i] = self.banked_fiq[bankedFiqIdx(i, next)];
+            self.r[8 + i] = self.bank.fiq[Bank.fiqIdx(i, next)];
        }
        // Grab r13, r14, SPSR
        switch (next) {
            .User, .System => {
-                self.r[13] = self.banked_r[bankedIdx(next, .R13)];
+                self.r[13] = self.bank.r[Bank.regIdx(next, .R13)];
-                self.r[14] = self.banked_r[bankedIdx(next, .R14)];
+                self.r[14] = self.bank.r[Bank.regIdx(next, .R14)];
            },
            else => {
-                self.r[13] = self.banked_r[bankedIdx(next, .R13)];
+                self.r[13] = self.bank.r[Bank.regIdx(next, .R13)];
-                self.r[14] = self.banked_r[bankedIdx(next, .R14)];
+                self.r[14] = self.bank.r[Bank.regIdx(next, .R14)];
-                self.spsr = self.banked_spsr[bankedSpsrIndex(next)];
+                self.spsr = self.bank.spsr[Bank.spsrIdx(next)];
            },
        }
        self.cpsr.mode.write(@enumToInt(next));
    }
    /// Advances state so that the BIOS is skipped
    ///
    /// Note: This accesses the CPU's bus ptr so it only may be called
    /// once the Bus has been properly initialized
    ///
    /// TODO: Make above notice impossible to do in code
    pub fn fastBoot(self: *Self) void {
        self.r = std.mem.zeroes([16]u32);
-        self.r[0] = 0x08000000;
+        // self.r[0] = 0x08000000;
-        self.r[1] = 0x000000EA;
+        // self.r[1] = 0x000000EA;
        self.r[13] = 0x0300_7F00;
        self.r[15] = 0x0800_0000;
-        self.banked_r[bankedIdx(.Irq, .R13)] = 0x0300_7FA0;
+        self.bank.r[Bank.regIdx(.Irq, .R13)] = 0x0300_7FA0;
-        self.banked_r[bankedIdx(.Supervisor, .R13)] = 0x0300_7FE0;
+        self.bank.r[Bank.regIdx(.Supervisor, .R13)] = 0x0300_7FE0;
-        self.cpsr.raw = 0x6000001F;
+        // self.cpsr.raw = 0x6000001F;
        self.cpsr.raw = 0x0000_001F;
        self.bus.bios.addr_latch = 0x0000_00DC + 8;
    }
    pub fn step(self: *Self) void {
-        if (self.cpsr.t.read()) {
+        defer {
-            const opcode = self.fetch(u16);
+            if (!self.pipe.flushed) self.r[15] += if (self.cpsr.t.read()) 2 else @as(u32, 4);
-            if (cpu_logging) self.logger.?.mgbaLog(self, opcode);
+            self.pipe.flushed = false;
        }
-            thumb.lut[thumbIdx(opcode)](self, self.bus, opcode);
+        if (self.cpsr.t.read()) {
            const opcode = @truncate(u16, self.pipe.step(self, u16) orelse return);
            if (self.logger) |*trace| trace.mgbaLog(self, opcode);
            thumb.lut[thumb.idx(opcode)](self, self.bus, opcode);
        } else {
-            const opcode = self.fetch(u32);
+            const opcode = self.pipe.step(self, u32) orelse return;
-            if (cpu_logging) self.logger.?.mgbaLog(self, opcode);
+            if (self.logger) |*trace| trace.mgbaLog(self, opcode);
            if (checkCond(self.cpsr, @truncate(u4, opcode >> 28))) {
-                arm.lut[armIdx(opcode)](self, self.bus, opcode);
+                arm.lut[arm.idx(opcode)](self, self.bus, opcode);
            }
        }
    }
    pub fn stepDmaTransfer(self: *Self) bool {
-        const dma0 = &self.bus.dma[0];
+        comptime var i: usize = 0;
-        const dma1 = &self.bus.dma[1];
+        inline while (i < 4) : (i += 1) {
-        const dma2 = &self.bus.dma[2];
+            if (self.bus.dma[i].in_progress) {
-        const dma3 = &self.bus.dma[3];
+                self.bus.dma[i].step(self);
-
+                return true;
-        if (dma0.in_progress) {
+            }
            dma0.step(self);
            return true;
        }
        if (dma1.in_progress) {
            dma1.step(self);
            return true;
        }
        if (dma2.in_progress) {
            dma2.step(self);
            return true;
        }
        if (dma3.in_progress) {
            dma3.step(self);
            return true;
        }
        return false;
@@ -467,42 +484,41 @@ pub const Arm7tdmi = struct {
    pub fn handleInterrupt(self: *Self) void {
        const should_handle = self.bus.io.ie.raw & self.bus.io.irq.raw;
-        if (should_handle != 0) {
+        // Return if IME is disabled, CPSR I is set or there is nothing to handle
-            self.bus.io.haltcnt = .Execute;
+        if (!self.bus.io.ime or self.cpsr.i.read() or should_handle == 0) return;
            // log.debug("An Interrupt was Fired!", .{});
-            // Either IME is not true or I in CPSR is true
+        // If Pipeline isn't full, we have a bug
-            // Don't handle interrupts
+        std.debug.assert(self.pipe.isFull());
            if (!self.bus.io.ime or self.cpsr.i.read()) return;
            // log.debug("An interrupt was Handled!", .{});
-            // retAddr.gba says r15 on it's own is off by -04h in both ARM and THUMB mode
+        // log.debug("Handling Interrupt!", .{});
-            const r15 = self.r[15] + 4;
+        self.bus.io.haltcnt = .Execute;
            const cpsr = self.cpsr.raw;
-            self.changeMode(.Irq);
+        // FIXME: This seems weird, but retAddr.gba suggests I need to make these changes
-            self.cpsr.t.write(false);
+        const ret_addr = self.r[15] - if (self.cpsr.t.read()) 0 else @as(u32, 4);
-            self.cpsr.i.write(true);
+        const new_spsr = self.cpsr.raw;
-            self.r[14] = r15;
+        self.changeMode(.Irq);
-            self.spsr.raw = cpsr;
+        self.cpsr.t.write(false);
-            self.r[15] = 0x000_0018;
+        self.cpsr.i.write(true);
-        }
+
        self.r[14] = ret_addr;
        self.spsr.raw = new_spsr;
        self.r[15] = 0x0000_0018;
        self.pipe.reload(self);
    }
-    inline fn fetch(self: *Self, comptime T: type) T {
+    inline fn fetch(self: *Self, comptime T: type, address: u32) T {
        comptime std.debug.assert(T == u32 or T == u16); // Opcode may be 32-bit (ARM) or 16-bit (THUMB)
        defer self.r[15] += if (T == u32) 4 else 2;
-        // FIXME: You better hope this is optimized out
+        // Bus.read will advance the scheduler. There are different timings for CPU fetches,
        // so we want to undo what Bus.read will apply. We can do this by caching the current tick
        // This is very dumb.
        //
        // FIXME: Please rework this
        const tick_cache = self.sched.tick;
-        defer self.sched.tick = tick_cache + Bus.fetch_timings[@boolToInt(T == u32)][@truncate(u4, self.r[15] >> 24)];
+        defer self.sched.tick = tick_cache + Bus.fetch_timings[@boolToInt(T == u32)][@truncate(u4, address >> 24)];
-        return self.bus.read(T, self.r[15]);
+        return self.bus.read(T, address);
    }
    pub fn fakePC(self: *const Self) u32 {
        return self.r[15] + 4;
    }
    pub fn panic(self: *const Self, comptime format: []const u8, args: anytype) noreturn {
@@ -514,18 +530,20 @@ pub const Arm7tdmi = struct {
            std.debug.print("R{}: 0x{X:0>8}\tR{}: 0x{X:0>8}\tR{}: 0x{X:0>8}\tR{}: 0x{X:0>8}\n", .{ i, self.r[i], i_1, self.r[i_1], i_2, self.r[i_2], i_3, self.r[i_3] });
        }
        std.debug.print("cpsr: 0x{X:0>8} ", .{self.cpsr.raw});
-        prettyPrintPsr(&self.cpsr);
+        self.cpsr.toString();
        std.debug.print("spsr: 0x{X:0>8} ", .{self.spsr.raw});
-        prettyPrintPsr(&self.spsr);
+        self.spsr.toString();
        std.debug.print("pipeline: {??X:0>8}\n", .{self.pipe.stage});
        if (self.cpsr.t.read()) {
            const opcode = self.bus.dbgRead(u16, self.r[15] - 4);
-            const id = thumbIdx(opcode);
+            const id = thumb.idx(opcode);
            std.debug.print("opcode: ID: 0x{b:0>10} 0x{X:0>4}\n", .{ id, opcode });
        } else {
            const opcode = self.bus.dbgRead(u32, self.r[15] - 4);
-            const id = armIdx(opcode);
+            const id = arm.idx(opcode);
            std.debug.print("opcode: ID: 0x{X:0>3} 0x{X:0>8}\n", .{ id, opcode });
        }
@@ -533,107 +551,74 @@ pub const Arm7tdmi = struct {
        std.debug.panic(format, args);
    }
 };
-    fn prettyPrintPsr(psr: *const PSR) void {
+const condition_lut = [_]u16{
-        std.debug.print("[", .{});
+    0xF0F0, // EQ - Equal
    0x0F0F, // NE - Not Equal
    0xCCCC, // CS - Unsigned higher or same
    0x3333, // CC - Unsigned lower
    0xFF00, // MI - Negative
    0x00FF, // PL - Positive or Zero
    0xAAAA, // VS - Overflow
    0x5555, // VC - No Overflow
    0x0C0C, // HI - unsigned hierh
    0xF3F3, // LS - unsigned lower or same
    0xAA55, // GE - greater or equal
    0x55AA, // LT - less than
    0x0A05, // GT - greater than
    0xF5FA, // LE - less than or equal
    0xFFFF, // AL - always
    0x0000, // NV - never
 };
-        if (psr.n.read()) std.debug.print("N", .{}) else std.debug.print("-", .{});
+pub inline fn checkCond(cpsr: PSR, cond: u4) bool {
-        if (psr.z.read()) std.debug.print("Z", .{}) else std.debug.print("-", .{});
+    const flags = @truncate(u4, cpsr.raw >> 28);
        if (psr.c.read()) std.debug.print("C", .{}) else std.debug.print("-", .{});
        if (psr.v.read()) std.debug.print("V", .{}) else std.debug.print("-", .{});
        if (psr.i.read()) std.debug.print("I", .{}) else std.debug.print("-", .{});
        if (psr.f.read()) std.debug.print("F", .{}) else std.debug.print("-", .{});
        if (psr.t.read()) std.debug.print("T", .{}) else std.debug.print("-", .{});
        std.debug.print("|", .{});
        if (getMode(psr.mode.read())) |mode| std.debug.print("{s}", .{modeString(mode)}) else std.debug.print("---", .{});
-        std.debug.print("]\n", .{});
+    return condition_lut[cond] & (@as(u16, 1) << flags) != 0;
-    }
+}
-    fn modeString(mode: Mode) []const u8 {
+const Pipeline = struct {
-        return switch (mode) {
+    const Self = @This();
-            .User => "usr",
+    stage: [2]?u32,
-            .Fiq => "fiq",
+    flushed: bool,
-            .Irq => "irq",
+
-            .Supervisor => "svc",
+    fn init() Self {
-            .Abort => "abt",
+        return .{
-            .Undefined => "und",
+            .stage = [_]?u32{null} ** 2,
-            .System => "sys",
+            .flushed = false,
        };
    }
-    fn mgbaLog(self: *const Self, file: *const File, opcode: u32) !void {
+    pub fn isFull(self: *const Self) bool {
-        const thumb_fmt = "{X:0>8} {X:0>8} {X:0>8} {X:0>8} {X:0>8} {X:0>8} {X:0>8} {X:0>8} {X:0>8} {X:0>8} {X:0>8} {X:0>8} {X:0>8} {X:0>8} {X:0>8} {X:0>8} cpsr: {X:0>8} | {X:0>4}:\n";
+        return self.stage[0] != null and self.stage[1] != null;
-        const arm_fmt = "{X:0>8} {X:0>8} {X:0>8} {X:0>8} {X:0>8} {X:0>8} {X:0>8} {X:0>8} {X:0>8} {X:0>8} {X:0>8} {X:0>8} {X:0>8} {X:0>8} {X:0>8} {X:0>8} cpsr: {X:0>8} | {X:0>8}:\n";
+    }
        var buf: [0x100]u8 = [_]u8{0x00} ** 0x100; // this is larger than it needs to be
-        const r0 = self.r[0];
+    pub fn step(self: *Self, cpu: *Arm7tdmi, comptime T: type) ?u32 {
-        const r1 = self.r[1];
+        comptime std.debug.assert(T == u32 or T == u16);
        const r2 = self.r[2];
        const r3 = self.r[3];
        const r4 = self.r[4];
        const r5 = self.r[5];
        const r6 = self.r[6];
        const r7 = self.r[7];
        const r8 = self.r[8];
        const r9 = self.r[9];
        const r10 = self.r[10];
        const r11 = self.r[11];
        const r12 = self.r[12];
        const r13 = self.r[13];
        const r14 = self.r[14];
        const r15 = self.r[15];
-        const c_psr = self.cpsr.raw;
+        const opcode = self.stage[0];
        self.stage[0] = self.stage[1];
        self.stage[1] = cpu.fetch(T, cpu.r[15]);
-        var log_str: []u8 = undefined;
+        return opcode;
-        if (self.cpsr.t.read()) {
+    }
            if (opcode >> 11 == 0x1E) {
                // Instruction 1 of a BL Opcode, print in ARM mode
                const other_half = self.bus.dbgRead(u16, self.r[15]);
                const bl_opcode = @as(u32, opcode) << 16 | other_half;
-                log_str = try std.fmt.bufPrint(&buf, arm_fmt, .{ r0, r1, r2, r3, r4, r5, r6, r7, r8, r9, r10, r11, r12, r13, r14, r15, c_psr, bl_opcode });
+    pub fn reload(self: *Self, cpu: *Arm7tdmi) void {
-            } else {
+        if (cpu.cpsr.t.read()) {
-                log_str = try std.fmt.bufPrint(&buf, thumb_fmt, .{ r0, r1, r2, r3, r4, r5, r6, r7, r8, r9, r10, r11, r12, r13, r14, r15, c_psr, opcode });
+            self.stage[0] = cpu.fetch(u16, cpu.r[15]);
-            }
+            self.stage[1] = cpu.fetch(u16, cpu.r[15] + 2);
            cpu.r[15] += 4;
        } else {
-            log_str = try std.fmt.bufPrint(&buf, arm_fmt, .{ r0, r1, r2, r3, r4, r5, r6, r7, r8, r9, r10, r11, r12, r13, r14, r15, c_psr, opcode });
+            self.stage[0] = cpu.fetch(u32, cpu.r[15]);
            self.stage[1] = cpu.fetch(u32, cpu.r[15] + 4);
            cpu.r[15] += 8;
        }
-        _ = try file.writeAll(log_str);
+        self.flushed = true;
    }
 };
 inline fn armIdx(opcode: u32) u12 {
    return @truncate(u12, opcode >> 20 & 0xFF) << 4 | @truncate(u12, opcode >> 4 & 0xF);
 }
 inline fn thumbIdx(opcode: u16) u10 {
    return @truncate(u10, opcode >> 6);
 }
 pub fn checkCond(cpsr: PSR, cond: u4) bool {
    return switch (cond) {
        0x0 => cpsr.z.read(), // EQ - Equal
        0x1 => !cpsr.z.read(), // NE - Not equal
        0x2 => cpsr.c.read(), // CS - Unsigned higher or same
        0x3 => !cpsr.c.read(), // CC - Unsigned lower
        0x4 => cpsr.n.read(), // MI - Negative
        0x5 => !cpsr.n.read(), // PL - Positive or zero
        0x6 => cpsr.v.read(), // VS - Overflow
        0x7 => !cpsr.v.read(), // VC - No overflow
        0x8 => cpsr.c.read() and !cpsr.z.read(), // HI - unsigned higher
        0x9 => !cpsr.c.read() or cpsr.z.read(), // LS - unsigned lower or same
        0xA => cpsr.n.read() == cpsr.v.read(), // GE - Greater or equal
        0xB => cpsr.n.read() != cpsr.v.read(), // LT - Less than
        0xC => !cpsr.z.read() and (cpsr.n.read() == cpsr.v.read()), // GT - Greater than
        0xD => cpsr.z.read() or (cpsr.n.read() != cpsr.v.read()), // LE - Less than or equal
        0xE => true, // AL - Always
        0xF => false, // NV - Never (reserved in ARMv3 and up, but seems to have not changed?)
    };
 }
 pub const PSR = extern union {
    mode: Bitfield(u32, 0, 5),
    t: Bit(u32, 5),
@@ -644,6 +629,22 @@ pub const PSR = extern union {
    z: Bit(u32, 30),
    n: Bit(u32, 31),
    raw: u32,
    fn toString(self: PSR) void {
        std.debug.print("[", .{});
        if (self.n.read()) std.debug.print("N", .{}) else std.debug.print("-", .{});
        if (self.z.read()) std.debug.print("Z", .{}) else std.debug.print("-", .{});
        if (self.c.read()) std.debug.print("C", .{}) else std.debug.print("-", .{});
        if (self.v.read()) std.debug.print("V", .{}) else std.debug.print("-", .{});
        if (self.i.read()) std.debug.print("I", .{}) else std.debug.print("-", .{});
        if (self.f.read()) std.debug.print("F", .{}) else std.debug.print("-", .{});
        if (self.t.read()) std.debug.print("T", .{}) else std.debug.print("-", .{});
        std.debug.print("|", .{});
        if (getMode(self.mode.read())) |m| std.debug.print("{s}", .{m.toString()}) else std.debug.print("---", .{});
        std.debug.print("]\n", .{});
    }
 };
 const Mode = enum(u5) {
@@ -654,11 +655,18 @@ const Mode = enum(u5) {
    Abort = 0b10111,
    Undefined = 0b11011,
    System = 0b11111,
 };
-const BankedKind = enum(u1) {
+    fn toString(self: Mode) []const u8 {
-    R13 = 0,
+        return switch (self) {
-    R14,
+            .User => "usr",
            .Fiq => "fiq",
            .Irq => "irq",
            .Supervisor => "svc",
            .Abort => "abt",
            .Undefined => "und",
            .System => "sys",
        };
    }
 };
 fn getMode(bits: u5) ?Mode {
--- a/src/core/cpu/arm/block_data_transfer.zig
+++ b/src/core/cpu/arm/block_data_transfer.zig
@@ -55,8 +55,9 @@ pub fn blockDataTransfer(comptime P: bool, comptime U: bool, comptime S: bool, c
                if (L) {
                    cpu.r[15] = bus.read(u32, und_addr);
                    cpu.pipe.reload(cpu);
                } else {
-                    bus.write(u32, und_addr, cpu.r[15] + 8);
+                    bus.write(u32, und_addr, cpu.r[15] + 4);
                }
                cpu.r[rn] = if (U) cpu.r[rn] + 0x40 else cpu.r[rn] - 0x40;
@@ -86,17 +87,23 @@ pub fn blockDataTransfer(comptime P: bool, comptime U: bool, comptime S: bool, c
                    cpu.setUserModeRegister(i, bus.read(u32, address));
                } else {
                    const value = bus.read(u32, address);
-                    cpu.r[i] = if (i == 0xF) value & 0xFFFF_FFFC else value;
+
-                    if (S and i == 0xF) cpu.setCpsr(cpu.spsr.raw);
+                    cpu.r[i] = value;
                    if (i == 0xF) {
                        cpu.r[i] &= ~@as(u32, 3); // Align r15
                        cpu.pipe.reload(cpu);
                        if (S) cpu.setCpsr(cpu.spsr.raw);
                    }
                }
            } else {
                if (S) {
                    // Always Transfer User mode Registers
                    // This happens regardless if r15 is in the list
                    const value = cpu.getUserModeRegister(i);
-                    bus.write(u32, address, value + if (i == 0xF) 8 else @as(u32, 0)); // PC is already 4 ahead to make 12
+                    bus.write(u32, address, value + if (i == 0xF) 4 else @as(u32, 0)); // PC is already 8 ahead to make 12
                } else {
-                    bus.write(u32, address, cpu.r[i] + if (i == 0xF) 8 else @as(u32, 0));
+                    bus.write(u32, address, cpu.r[i] + if (i == 0xF) 4 else @as(u32, 0));
                }
            }
        }
--- a/src/core/cpu/arm/branch.zig
+++ b/src/core/cpu/arm/branch.zig
@@ -1,22 +1,26 @@
 const std = @import("std");
 const Bus = @import("../../Bus.zig");
 const Arm7tdmi = @import("../../cpu.zig").Arm7tdmi;
 const InstrFn = @import("../../cpu.zig").arm.InstrFn;
-const sext = @import("../../util.zig").sext;
+const sext = @import("../../../util.zig").sext;
 pub fn branch(comptime L: bool) InstrFn {
    return struct {
        fn inner(cpu: *Arm7tdmi, _: *Bus, opcode: u32) void {
-            if (L) cpu.r[14] = cpu.r[15];
+            if (L) cpu.r[14] = cpu.r[15] - 4;
-            cpu.r[15] = cpu.fakePC() +% (sext(u32, u24, opcode) << 2);
+
            cpu.r[15] +%= sext(u32, u24, opcode) << 2;
            cpu.pipe.reload(cpu);
        }
    }.inner;
 }
 pub fn branchAndExchange(cpu: *Arm7tdmi, _: *Bus, opcode: u32) void {
    const rn = opcode & 0xF;
-    cpu.cpsr.t.write(cpu.r[rn] & 1 == 1);
+
-    cpu.r[15] = cpu.r[rn] & 0xFFFF_FFFE;
+    const thumb = cpu.r[rn] & 1 == 1;
    cpu.r[15] = cpu.r[rn] & if (thumb) ~@as(u32, 1) else ~@as(u32, 3);
    cpu.cpsr.t.write(thumb);
    cpu.pipe.reload(cpu);
 }
--- a/src/core/cpu/arm/data_processing.zig
+++ b/src/core/cpu/arm/data_processing.zig
@@ -2,10 +2,10 @@ const Bus = @import("../../Bus.zig");
 const Arm7tdmi = @import("../../cpu.zig").Arm7tdmi;
 const InstrFn = @import("../../cpu.zig").arm.InstrFn;
-const rotateRight = @import("../barrel_shifter.zig").rotateRight;
+const exec = @import("../barrel_shifter.zig").exec;
-const execute = @import("../barrel_shifter.zig").execute;
+const ror = @import("../barrel_shifter.zig").ror;
-pub fn dataProcessing(comptime I: bool, comptime S: bool, comptime instrKind: u4) InstrFn {
+pub fn dataProcessing(comptime I: bool, comptime S: bool, comptime kind: u4) InstrFn {
    return struct {
        fn inner(cpu: *Arm7tdmi, _: *Bus, opcode: u32) void {
            const rd = @truncate(u4, opcode >> 12 & 0xF);
@@ -13,269 +13,168 @@ pub fn dataProcessing(comptime I: bool, comptime S: bool, comptime instrKind: u4
            const old_carry = @boolToInt(cpu.cpsr.c.read());
            // If certain conditions are met, PC is 12 ahead instead of 8
            // TODO: Why these conditions?
            if (!I and opcode >> 4 & 1 == 1) cpu.r[15] += 4;
            const op1 = cpu.r[rn];
-            const op1 = if (rn == 0xF) cpu.fakePC() else cpu.r[rn];
+            const amount = @truncate(u8, (opcode >> 8 & 0xF) << 1);
-
+            const op2 = if (I) ror(S, &cpu.cpsr, opcode & 0xFF, amount) else exec(S, cpu, opcode);
            var op2: u32 = undefined;
            if (I) {
                const amount = @truncate(u8, (opcode >> 8 & 0xF) << 1);
                op2 = rotateRight(S, &cpu.cpsr, opcode & 0xFF, amount);
            } else {
                op2 = execute(S, cpu, opcode);
            }
            // Undo special condition from above
            if (!I and opcode >> 4 & 1 == 1) cpu.r[15] -= 4;
-            switch (instrKind) {
+            var result: u32 = undefined;
-                0x0 => {
+            var overflow: bool = undefined;
-                    // AND
+
-                    const result = op1 & op2;
+            // Perform Data Processing Logic
-                    cpu.r[rd] = result;
+            switch (kind) {
-                    setArmLogicOpFlags(S, cpu, rd, result);
+                0x0 => result = op1 & op2, // AND
-                },
+                0x1 => result = op1 ^ op2, // EOR
-                0x1 => {
+                0x2 => result = op1 -% op2, // SUB
-                    // EOR
+                0x3 => result = op2 -% op1, // RSB
-                    const result = op1 ^ op2;
+                0x4 => result = add(&overflow, op1, op2), // ADD
-                    cpu.r[rd] = result;
+                0x5 => result = adc(&overflow, op1, op2, old_carry), // ADC
-                    setArmLogicOpFlags(S, cpu, rd, result);
+                0x6 => result = sbc(op1, op2, old_carry), // SBC
-                },
+                0x7 => result = sbc(op2, op1, old_carry), // RSC
                0x2 => {
                    // SUB
                    cpu.r[rd] = armSub(S, cpu, rd, op1, op2);
                },
                0x3 => {
                    // RSB
                    cpu.r[rd] = armSub(S, cpu, rd, op2, op1);
                },
                0x4 => {
                    // ADD
                    cpu.r[rd] = armAdd(S, cpu, rd, op1, op2);
                },
                0x5 => {
                    // ADC
                    cpu.r[rd] = armAdc(S, cpu, rd, op1, op2, old_carry);
                },
                0x6 => {
                    // SBC
                    cpu.r[rd] = armSbc(S, cpu, rd, op1, op2, old_carry);
                },
                0x7 => {
                    // RSC
                    cpu.r[rd] = armSbc(S, cpu, rd, op2, op1, old_carry);
                },
                0x8 => {
                    // TST
-                    if (rd == 0xF) {
+                    if (rd == 0xF)
-                        undefinedTestBehaviour(cpu);
+                        return undefinedTestBehaviour(cpu);
                        return;
                    }
-                    const result = op1 & op2;
+                    result = op1 & op2;
                    setTestOpFlags(S, cpu, opcode, result);
                },
                0x9 => {
                    // TEQ
-                    if (rd == 0xF) {
+                    if (rd == 0xF)
-                        undefinedTestBehaviour(cpu);
+                        return undefinedTestBehaviour(cpu);
                        return;
                    }
-                    const result = op1 ^ op2;
+                    result = op1 ^ op2;
                    setTestOpFlags(S, cpu, opcode, result);
                },
                0xA => {
                    // CMP
-                    if (rd == 0xF) {
+                    if (rd == 0xF)
-                        undefinedTestBehaviour(cpu);
+                        return undefinedTestBehaviour(cpu);
                        return;
                    }
-                    cmp(cpu, op1, op2);
+                    result = op1 -% op2;
                },
                0xB => {
                    // CMN
-                    if (rd == 0xF) {
+                    if (rd == 0xF)
-                        undefinedTestBehaviour(cpu);
+                        return undefinedTestBehaviour(cpu);
                        return;
                    }
-                    cmn(cpu, op1, op2);
+                    overflow = @addWithOverflow(u32, op1, op2, &result);
                },
-                0xC => {
+                0xC => result = op1 | op2, // ORR
-                    // ORR
+                0xD => result = op2, // MOV
-                    const result = op1 | op2;
+                0xE => result = op1 & ~op2, // BIC
                0xF => result = ~op2, // MVN
            }
            // Write to Destination Register
            switch (kind) {
                0x8, 0x9, 0xA, 0xB => {}, // Test Operations
                else => {
                    cpu.r[rd] = result;
-                    setArmLogicOpFlags(S, cpu, rd, result);
+                    if (rd == 0xF) {
                        if (S) cpu.setCpsr(cpu.spsr.raw);
                        cpu.pipe.reload(cpu);
                    }
                },
-                0xD => {
+            }
-                    // MOV
+
-                    cpu.r[rd] = op2;
+            // Write Flags
-                    setArmLogicOpFlags(S, cpu, rd, op2);
+            switch (kind) {
                0x0, 0x1, 0xC, 0xD, 0xE, 0xF => if (S and rd != 0xF) {
                    // Logic Operation Flags
                    cpu.cpsr.n.write(result >> 31 & 1 == 1);
                    cpu.cpsr.z.write(result == 0);
                    // C set by Barrel Shifter, V is unaffected
                },
-                0xE => {
+                0x2, 0x3 => if (S and rd != 0xF) {
-                    // BIC
+                    // SUB, RSB Flags
-                    const result = op1 & ~op2;
+                    cpu.cpsr.n.write(result >> 31 & 1 == 1);
-                    cpu.r[rd] = result;
+                    cpu.cpsr.z.write(result == 0);
-                    setArmLogicOpFlags(S, cpu, rd, result);
+
                    if (kind == 0x2) {
                        // SUB specific
                        cpu.cpsr.c.write(op2 <= op1);
                        cpu.cpsr.v.write(((op1 ^ result) & (~op2 ^ result)) >> 31 & 1 == 1);
                    } else {
                        // RSB Specific
                        cpu.cpsr.c.write(op1 <= op2);
                        cpu.cpsr.v.write(((op2 ^ result) & (~op1 ^ result)) >> 31 & 1 == 1);
                    }
                },
-                0xF => {
+                0x4, 0x5 => if (S and rd != 0xF) {
-                    // MVN
+                    // ADD, ADC Flags
-                    const result = ~op2;
+                    cpu.cpsr.n.write(result >> 31 & 1 == 1);
-                    cpu.r[rd] = result;
+                    cpu.cpsr.z.write(result == 0);
-                    setArmLogicOpFlags(S, cpu, rd, result);
+                    cpu.cpsr.c.write(overflow);
                    cpu.cpsr.v.write(((op1 ^ result) & (op2 ^ result)) >> 31 & 1 == 1);
                },
                0x6, 0x7 => if (S and rd != 0xF) {
                    // SBC, RSC Flags
                    cpu.cpsr.n.write(result >> 31 & 1 == 1);
                    cpu.cpsr.z.write(result == 0);
                    if (kind == 0x6) {
                        // SBC specific
                        const subtrahend = @as(u64, op2) -% old_carry +% 1;
                        cpu.cpsr.c.write(subtrahend <= op1);
                        cpu.cpsr.v.write(((op1 ^ result) & (~op2 ^ result)) >> 31 & 1 == 1);
                    } else {
                        // RSC Specific
                        const subtrahend = @as(u64, op1) -% old_carry +% 1;
                        cpu.cpsr.c.write(subtrahend <= op2);
                        cpu.cpsr.v.write(((op2 ^ result) & (~op1 ^ result)) >> 31 & 1 == 1);
                    }
                },
                0x8, 0x9, 0xA, 0xB => {
                    // Test Operation Flags
                    cpu.cpsr.n.write(result >> 31 & 1 == 1);
                    cpu.cpsr.z.write(result == 0);
                    if (kind == 0xA) {
                        // CMP specific
                        cpu.cpsr.c.write(op2 <= op1);
                        cpu.cpsr.v.write(((op1 ^ result) & (~op2 ^ result)) >> 31 & 1 == 1);
                    } else if (kind == 0xB) {
                        // CMN specific
                        cpu.cpsr.c.write(overflow);
                        cpu.cpsr.v.write(((op1 ^ result) & (op2 ^ result)) >> 31 & 1 == 1);
                    } else {
                        // TST, TEQ specific
                        // Barrel Shifter should always calc CPSR C in TST
                        if (!S) _ = exec(true, cpu, opcode);
                    }
                },
            }
        }
    }.inner;
 }
-fn armSbc(comptime S: bool, cpu: *Arm7tdmi, rd: u4, left: u32, right: u32, old_carry: u1) u32 {
+pub fn sbc(left: u32, right: u32, old_carry: u1) u32 {
    var result: u32 = undefined;
    if (S and rd == 0xF) {
        result = sbc(false, cpu, left, right, old_carry);
        cpu.setCpsr(cpu.spsr.raw);
    } else {
        result = sbc(S, cpu, left, right, old_carry);
    }
    return result;
 }
 pub fn sbc(comptime S: bool, cpu: *Arm7tdmi, left: u32, right: u32, old_carry: u1) u32 {
    // TODO: Make your own version (thanks peach.bot)
    const subtrahend = @as(u64, right) -% old_carry +% 1;
-    const result = @truncate(u32, left -% subtrahend);
+    const ret = @truncate(u32, left -% subtrahend);
-    if (S) {
+    return ret;
        cpu.cpsr.n.write(result >> 31 & 1 == 1);
        cpu.cpsr.z.write(result == 0);
        cpu.cpsr.c.write(subtrahend <= left);
        cpu.cpsr.v.write(((left ^ result) & (~right ^ result)) >> 31 & 1 == 1);
    }
    return result;
 }
-fn armSub(comptime S: bool, cpu: *Arm7tdmi, rd: u4, left: u32, right: u32) u32 {
+pub fn add(overflow: *bool, left: u32, right: u32) u32 {
-    var result: u32 = undefined;
+    var ret: u32 = undefined;
-    if (S and rd == 0xF) {
+    overflow.* = @addWithOverflow(u32, left, right, &ret);
-        result = sub(false, cpu, left, right);
+    return ret;
        cpu.setCpsr(cpu.spsr.raw);
    } else {
        result = sub(S, cpu, left, right);
    }
    return result;
 }
-pub fn sub(comptime S: bool, cpu: *Arm7tdmi, left: u32, right: u32) u32 {
+pub fn adc(overflow: *bool, left: u32, right: u32, old_carry: u1) u32 {
-    const result = left -% right;
+    var ret: u32 = undefined;
    const first = @addWithOverflow(u32, left, right, &ret);
    const second = @addWithOverflow(u32, ret, old_carry, &ret);
-    if (S) {
+    overflow.* = first or second;
-        cpu.cpsr.n.write(result >> 31 & 1 == 1);
+    return ret;
        cpu.cpsr.z.write(result == 0);
        cpu.cpsr.c.write(right <= left);
        cpu.cpsr.v.write(((left ^ result) & (~right ^ result)) >> 31 & 1 == 1);
    }
    return result;
 }
 fn armAdd(comptime S: bool, cpu: *Arm7tdmi, rd: u4, left: u32, right: u32) u32 {
    var result: u32 = undefined;
    if (S and rd == 0xF) {
        result = add(false, cpu, left, right);
        cpu.setCpsr(cpu.spsr.raw);
    } else {
        result = add(S, cpu, left, right);
    }
    return result;
 }
 pub fn add(comptime S: bool, cpu: *Arm7tdmi, left: u32, right: u32) u32 {
    var result: u32 = undefined;
    const didOverflow = @addWithOverflow(u32, left, right, &result);
    if (S) {
        cpu.cpsr.n.write(result >> 31 & 1 == 1);
        cpu.cpsr.z.write(result == 0);
        cpu.cpsr.c.write(didOverflow);
        cpu.cpsr.v.write(((left ^ result) & (right ^ result)) >> 31 & 1 == 1);
    }
    return result;
 }
 fn armAdc(comptime S: bool, cpu: *Arm7tdmi, rd: u4, left: u32, right: u32, old_carry: u1) u32 {
    var result: u32 = undefined;
    if (S and rd == 0xF) {
        result = adc(false, cpu, left, right, old_carry);
        cpu.setCpsr(cpu.spsr.raw);
    } else {
        result = adc(S, cpu, left, right, old_carry);
    }
    return result;
 }
 pub fn adc(comptime S: bool, cpu: *Arm7tdmi, left: u32, right: u32, old_carry: u1) u32 {
    var result: u32 = undefined;
    const did = @addWithOverflow(u32, left, right, &result);
    const overflow = @addWithOverflow(u32, result, old_carry, &result);
    if (S) {
        cpu.cpsr.n.write(result >> 31 & 1 == 1);
        cpu.cpsr.z.write(result == 0);
        cpu.cpsr.c.write(did or overflow);
        cpu.cpsr.v.write(((left ^ result) & (right ^ result)) >> 31 & 1 == 1);
    }
    return result;
 }
 pub fn cmp(cpu: *Arm7tdmi, left: u32, right: u32) void {
    const result = left -% right;
    cpu.cpsr.n.write(result >> 31 & 1 == 1);
    cpu.cpsr.z.write(result == 0);
    cpu.cpsr.c.write(right <= left);
    cpu.cpsr.v.write(((left ^ result) & (~right ^ result)) >> 31 & 1 == 1);
 }
 pub fn cmn(cpu: *Arm7tdmi, left: u32, right: u32) void {
    var result: u32 = undefined;
    const didOverflow = @addWithOverflow(u32, left, right, &result);
    cpu.cpsr.n.write(result >> 31 & 1 == 1);
    cpu.cpsr.z.write(result == 0);
    cpu.cpsr.c.write(didOverflow);
    cpu.cpsr.v.write(((left ^ result) & (right ^ result)) >> 31 & 1 == 1);
 }
 fn setArmLogicOpFlags(comptime S: bool, cpu: *Arm7tdmi, rd: u4, result: u32) void {
    if (S and rd == 0xF) {
        cpu.setCpsr(cpu.spsr.raw);
    } else {
        setLogicOpFlags(S, cpu, result);
    }
 }
 pub fn setLogicOpFlags(comptime S: bool, cpu: *Arm7tdmi, result: u32) void {
    if (S) {
        cpu.cpsr.n.write(result >> 31 & 1 == 1);
        cpu.cpsr.z.write(result == 0);
        // C set by Barrel Shifter, V is unaffected
    }
 }
 fn setTestOpFlags(comptime S: bool, cpu: *Arm7tdmi, opcode: u32, result: u32) void {
    cpu.cpsr.n.write(result >> 31 & 1 == 1);
    cpu.cpsr.z.write(result == 0);
    // Barrel Shifter should always calc CPSR C in TST
    if (!S) _ = execute(true, cpu, opcode);
 }
 fn undefinedTestBehaviour(cpu: *Arm7tdmi) void {
--- a/src/core/cpu/arm/half_signed_data_transfer.zig
+++ b/src/core/cpu/arm/half_signed_data_transfer.zig
@@ -1,11 +1,9 @@
 const std = @import("std");
 const Bus = @import("../../Bus.zig");
 const Arm7tdmi = @import("../../cpu.zig").Arm7tdmi;
 const InstrFn = @import("../../cpu.zig").arm.InstrFn;
-const sext = @import("../../util.zig").sext;
+const sext = @import("../../../util.zig").sext;
-const rotr = @import("../../util.zig").rotr;
+const rotr = @import("../../../util.zig").rotr;
 pub fn halfAndSignedDataTransfer(comptime P: bool, comptime U: bool, comptime I: bool, comptime W: bool, comptime L: bool) InstrFn {
    return struct {
@@ -15,20 +13,8 @@ pub fn halfAndSignedDataTransfer(comptime P: bool, comptime U: bool, comptime I:
            const rm = opcode & 0xF;
            const imm_offset_high = opcode >> 8 & 0xF;
-            var base: u32 = undefined;
+            const base = cpu.r[rn] + if (!L and rn == 0xF) 4 else @as(u32, 0);
-            if (rn == 0xF) {
+            const offset = if (I) imm_offset_high << 4 | rm else cpu.r[rm];
                base = cpu.fakePC();
                if (!L) base += 4;
            } else {
                base = cpu.r[rn];
            }
            var offset: u32 = undefined;
            if (I) {
                offset = imm_offset_high << 4 | rm;
            } else {
                offset = cpu.r[rm];
            }
            const modified_base = if (U) base +% offset else base -% offset;
            var address = if (P) modified_base else base;
@@ -47,11 +33,8 @@ pub fn halfAndSignedDataTransfer(comptime P: bool, comptime U: bool, comptime I:
                    },
                    0b11 => {
                        // LDRSH
-                        result = if (address & 1 == 1) blk: {
+                        const value = bus.read(u16, address);
-                            break :blk sext(u32, u8, bus.read(u8, address));
+                        result = if (address & 1 == 1) sext(u32, u8, @truncate(u8, value >> 8)) else sext(u32, u16, value);
                        } else blk: {
                            break :blk sext(u32, u16, bus.read(u16, address));
                        };
                    },
                    0b00 => unreachable, // SWP
                }
--- a/src/core/cpu/arm/psr_transfer.zig
+++ b/src/core/cpu/arm/psr_transfer.zig
@@ -7,7 +7,7 @@ const PSR = @import("../../cpu.zig").PSR;
 const log = std.log.scoped(.PsrTransfer);
-const rotr = @import("../../util.zig").rotr;
+const rotr = @import("../../../util.zig").rotr;
 pub fn psrTransfer(comptime I: bool, comptime R: bool, comptime kind: u2) InstrFn {
    return struct {
--- a/src/core/cpu/arm/single_data_swap.zig
+++ b/src/core/cpu/arm/single_data_swap.zig
@@ -1,10 +1,8 @@
 const std = @import("std");
 const Bus = @import("../../Bus.zig");
 const Arm7tdmi = @import("../../cpu.zig").Arm7tdmi;
 const InstrFn = @import("../../cpu.zig").arm.InstrFn;
-const rotr = @import("../../util.zig").rotr;
+const rotr = @import("../../../util.zig").rotr;
 pub fn singleDataSwap(comptime B: bool) InstrFn {
    return struct {
--- a/src/core/cpu/arm/single_data_transfer.zig
+++ b/src/core/cpu/arm/single_data_transfer.zig
@@ -1,12 +1,9 @@
 const std = @import("std");
 const util = @import("../../util.zig");
 const shifter = @import("../barrel_shifter.zig");
 const Bus = @import("../../Bus.zig");
 const Arm7tdmi = @import("../../cpu.zig").Arm7tdmi;
 const InstrFn = @import("../../cpu.zig").arm.InstrFn;
-const rotr = @import("../../util.zig").rotr;
+const rotr = @import("../../../util.zig").rotr;
 pub fn singleDataTransfer(comptime I: bool, comptime P: bool, comptime U: bool, comptime B: bool, comptime W: bool, comptime L: bool) InstrFn {
    return struct {
@@ -14,15 +11,10 @@ pub fn singleDataTransfer(comptime I: bool, comptime P: bool, comptime U: bool,
            const rn = opcode >> 16 & 0xF;
            const rd = opcode >> 12 & 0xF;
-            var base: u32 = undefined;
+            // rn is r15 and L is not set, the PC is 12 ahead
-            if (rn == 0xF) {
+            const base = cpu.r[rn] + if (!L and rn == 0xF) 4 else @as(u32, 0);
                base = cpu.fakePC();
                if (!L) base += 4; // Offset of 12
            } else {
                base = cpu.r[rn];
            }
-            const offset = if (I) shifter.immShift(false, cpu, opcode) else opcode & 0xFFF;
+            const offset = if (I) shifter.immediate(false, cpu, opcode) else opcode & 0xFFF;
            const modified_base = if (U) base +% offset else base -% offset;
            var address = if (P) modified_base else base;
@@ -40,18 +32,26 @@ pub fn singleDataTransfer(comptime I: bool, comptime P: bool, comptime U: bool,
            } else {
                if (B) {
                    // STRB
-                    const value = if (rd == 0xF) cpu.r[rd] + 8 else cpu.r[rd];
+                    const value = cpu.r[rd] + if (rd == 0xF) 4 else @as(u32, 0); // PC is 12 ahead
                    bus.write(u8, address, @truncate(u8, value));
                } else {
                    // STR
-                    const value = if (rd == 0xF) cpu.r[rd] + 8 else cpu.r[rd];
+                    const value = cpu.r[rd] + if (rd == 0xF) 4 else @as(u32, 0);
                    bus.write(u32, address, value);
                }
            }
            address = modified_base;
-            if (W and P or !P) cpu.r[rn] = address;
+            if (W and P or !P) {
-            if (L) cpu.r[rd] = result; // This emulates the LDR rd == rn behaviour
+                cpu.r[rn] = address;
                if (rn == 0xF) cpu.pipe.reload(cpu);
            }
            if (L) {
                // This emulates the LDR rd == rn behaviour
                cpu.r[rd] = result;
                if (rd == 0xF) cpu.pipe.reload(cpu);
            }
        }
    }.inner;
 }
--- a/src/core/cpu/arm/software_interrupt.zig
+++ b/src/core/cpu/arm/software_interrupt.zig
@@ -6,7 +6,7 @@ pub fn armSoftwareInterrupt() InstrFn {
    return struct {
        fn inner(cpu: *Arm7tdmi, _: *Bus, _: u32) void {
            // Copy Values from Current Mode
-            const r15 = cpu.r[15];
+            const ret_addr = cpu.r[15] - 4;
            const cpsr = cpu.cpsr.raw;
            // Switch Mode
@@ -14,9 +14,10 @@ pub fn armSoftwareInterrupt() InstrFn {
            cpu.cpsr.t.write(false); // Force ARM Mode
            cpu.cpsr.i.write(true); // Disable normal interrupts
-            cpu.r[14] = r15; // Resume Execution
+            cpu.r[14] = ret_addr; // Resume Execution
            cpu.spsr.raw = cpsr; // Previous mode CPSR
            cpu.r[15] = 0x0000_0008;
            cpu.pipe.reload(cpu);
        }
    }.inner;
 }
--- a/src/core/cpu/barrel_shifter.zig
+++ b/src/core/cpu/barrel_shifter.zig
@@ -1,41 +1,35 @@
 const std = @import("std");
 const Arm7tdmi = @import("../cpu.zig").Arm7tdmi;
 const CPSR = @import("../cpu.zig").PSR;
-const rotr = @import("../util.zig").rotr;
+const rotr = @import("../../util.zig").rotr;
-pub fn execute(comptime S: bool, cpu: *Arm7tdmi, opcode: u32) u32 {
+pub fn exec(comptime S: bool, cpu: *Arm7tdmi, opcode: u32) u32 {
    var result: u32 = undefined;
    if (opcode >> 4 & 1 == 1) {
-        result = registerShift(S, cpu, opcode);
+        result = register(S, cpu, opcode);
    } else {
-        result = immShift(S, cpu, opcode);
+        result = immediate(S, cpu, opcode);
    }
    return result;
 }
-fn registerShift(comptime S: bool, cpu: *Arm7tdmi, opcode: u32) u32 {
+fn register(comptime S: bool, cpu: *Arm7tdmi, opcode: u32) u32 {
    const rs_idx = opcode >> 8 & 0xF;
    const rm = cpu.r[opcode & 0xF];
    const rs = @truncate(u8, cpu.r[rs_idx]);
    const rm_idx = opcode & 0xF;
    const rm = if (rm_idx == 0xF) cpu.fakePC() else cpu.r[rm_idx];
    return switch (@truncate(u2, opcode >> 5)) {
-        0b00 => logicalLeft(S, &cpu.cpsr, rm, rs),
+        0b00 => lsl(S, &cpu.cpsr, rm, rs),
-        0b01 => logicalRight(S, &cpu.cpsr, rm, rs),
+        0b01 => lsr(S, &cpu.cpsr, rm, rs),
-        0b10 => arithmeticRight(S, &cpu.cpsr, rm, rs),
+        0b10 => asr(S, &cpu.cpsr, rm, rs),
-        0b11 => rotateRight(S, &cpu.cpsr, rm, rs),
+        0b11 => ror(S, &cpu.cpsr, rm, rs),
    };
 }
-pub fn immShift(comptime S: bool, cpu: *Arm7tdmi, opcode: u32) u32 {
+pub fn immediate(comptime S: bool, cpu: *Arm7tdmi, opcode: u32) u32 {
    const amount = @truncate(u8, opcode >> 7 & 0x1F);
-
+    const rm = cpu.r[opcode & 0xF];
    const rm_idx = opcode & 0xF;
    const rm = if (rm_idx == 0xF) cpu.fakePC() else cpu.r[rm_idx];
    var result: u32 = undefined;
    if (amount == 0) {
@@ -64,17 +58,17 @@ pub fn immShift(comptime S: bool, cpu: *Arm7tdmi, opcode: u32) u32 {
        }
    } else {
        switch (@truncate(u2, opcode >> 5)) {
-            0b00 => result = logicalLeft(S, &cpu.cpsr, rm, amount),
+            0b00 => result = lsl(S, &cpu.cpsr, rm, amount),
-            0b01 => result = logicalRight(S, &cpu.cpsr, rm, amount),
+            0b01 => result = lsr(S, &cpu.cpsr, rm, amount),
-            0b10 => result = arithmeticRight(S, &cpu.cpsr, rm, amount),
+            0b10 => result = asr(S, &cpu.cpsr, rm, amount),
-            0b11 => result = rotateRight(S, &cpu.cpsr, rm, amount),
+            0b11 => result = ror(S, &cpu.cpsr, rm, amount),
        }
    }
    return result;
 }
-pub fn logicalLeft(comptime S: bool, cpsr: *CPSR, rm: u32, total_amount: u8) u32 {
+pub fn lsl(comptime S: bool, cpsr: *CPSR, rm: u32, total_amount: u8) u32 {
    const amount = @truncate(u5, total_amount);
    const bit_count: u8 = @typeInfo(u32).Int.bits;
@@ -101,7 +95,7 @@ pub fn logicalLeft(comptime S: bool, cpsr: *CPSR, rm: u32, total_amount: u8) u32
    return result;
 }
-pub fn logicalRight(comptime S: bool, cpsr: *CPSR, rm: u32, total_amount: u32) u32 {
+pub fn lsr(comptime S: bool, cpsr: *CPSR, rm: u32, total_amount: u32) u32 {
    const amount = @truncate(u5, total_amount);
    const bit_count: u8 = @typeInfo(u32).Int.bits;
@@ -125,7 +119,7 @@ pub fn logicalRight(comptime S: bool, cpsr: *CPSR, rm: u32, total_amount: u32) u
    return result;
 }
-pub fn arithmeticRight(comptime S: bool, cpsr: *CPSR, rm: u32, total_amount: u8) u32 {
+pub fn asr(comptime S: bool, cpsr: *CPSR, rm: u32, total_amount: u8) u32 {
    const amount = @truncate(u5, total_amount);
    const bit_count: u8 = @typeInfo(u32).Int.bits;
@@ -142,7 +136,7 @@ pub fn arithmeticRight(comptime S: bool, cpsr: *CPSR, rm: u32, total_amount: u8)
    return result;
 }
-pub fn rotateRight(comptime S: bool, cpsr: *CPSR, rm: u32, total_amount: u8) u32 {
+pub fn ror(comptime S: bool, cpsr: *CPSR, rm: u32, total_amount: u8) u32 {
    const result = rotr(u32, rm, total_amount);
    if (S and total_amount != 0) {
--- a/src/core/cpu/thumb/alu.zig
+++ b/src/core/cpu/thumb/alu.zig
@@ -4,16 +4,11 @@ const InstrFn = @import("../../cpu.zig").thumb.InstrFn;
 const adc = @import("../arm/data_processing.zig").adc;
 const sbc = @import("../arm/data_processing.zig").sbc;
 const sub = @import("../arm/data_processing.zig").sub;
 const cmp = @import("../arm/data_processing.zig").cmp;
 const cmn = @import("../arm/data_processing.zig").cmn;
 const setTestOpFlags = @import("../arm/data_processing.zig").setTestOpFlags;
 const setLogicOpFlags = @import("../arm/data_processing.zig").setLogicOpFlags;
-const logicalLeft = @import("../barrel_shifter.zig").logicalLeft;
+const lsl = @import("../barrel_shifter.zig").lsl;
-const logicalRight = @import("../barrel_shifter.zig").logicalRight;
+const lsr = @import("../barrel_shifter.zig").lsr;
-const arithmeticRight = @import("../barrel_shifter.zig").arithmeticRight;
+const asr = @import("../barrel_shifter.zig").asr;
-const rotateRight = @import("../barrel_shifter.zig").rotateRight;
+const ror = @import("../barrel_shifter.zig").ror;
 pub fn fmt4(comptime op: u4) InstrFn {
    return struct {
@@ -22,96 +17,85 @@ pub fn fmt4(comptime op: u4) InstrFn {
            const rd = opcode & 0x7;
            const carry = @boolToInt(cpu.cpsr.c.read());
            const op1 = cpu.r[rd];
            const op2 = cpu.r[rs];
            var result: u32 = undefined;
            var overflow: bool = undefined;
            switch (op) {
-                0x0 => {
+                0x0 => result = op1 & op2, // AND
-                    // AND
+                0x1 => result = op1 ^ op2, // EOR
-                    const result = cpu.r[rd] & cpu.r[rs];
+                0x2 => result = lsl(true, &cpu.cpsr, op1, @truncate(u8, op2)), // LSL
-                    cpu.r[rd] = result;
+                0x3 => result = lsr(true, &cpu.cpsr, op1, @truncate(u8, op2)), // LSR
-                    setLogicOpFlags(true, cpu, result);
+                0x4 => result = asr(true, &cpu.cpsr, op1, @truncate(u8, op2)), // ASR
                0x5 => result = adc(&overflow, op1, op2, carry), // ADC
                0x6 => result = sbc(op1, op2, carry), // SBC
                0x7 => result = ror(true, &cpu.cpsr, op1, @truncate(u8, op2)), // ROR
                0x8 => result = op1 & op2, // TST
                0x9 => result = 0 -% op2, // NEG
                0xA => result = op1 -% op2, // CMP
                0xB => overflow = @addWithOverflow(u32, op1, op2, &result), // CMN
                0xC => result = op1 | op2, // ORR
                0xD => result = @truncate(u32, @as(u64, op2) * @as(u64, op1)),
                0xE => result = op1 & ~op2,
                0xF => result = ~op2,
            }
            // Write to Destination Register
            switch (op) {
                0x8, 0xA, 0xB => {},
                else => cpu.r[rd] = result,
            }
            // Write Flags
            switch (op) {
                0x0, 0x1, 0x2, 0x3, 0x4, 0x7, 0xC, 0xE, 0xF => {
                    // Logic Operations
                    cpu.cpsr.n.write(result >> 31 & 1 == 1);
                    cpu.cpsr.z.write(result == 0);
                    // C set by Barrel Shifter, V is unaffected
                },
-                0x1 => {
+                0x8, 0xA => {
-                    // EOR
+                    // Test Flags
-                    const result = cpu.r[rd] ^ cpu.r[rs];
+                    // CMN (0xB) is handled with ADC
-                    cpu.r[rd] = result;
+                    cpu.cpsr.n.write(result >> 31 & 1 == 1);
-                    setLogicOpFlags(true, cpu, result);
+                    cpu.cpsr.z.write(result == 0);
                    if (op == 0xA) {
                        // CMP specific
                        cpu.cpsr.c.write(op2 <= op1);
                        cpu.cpsr.v.write(((op1 ^ result) & (~op2 ^ result)) >> 31 & 1 == 1);
                    }
                },
-                0x2 => {
+                0x5, 0xB => {
-                    // LSL
+                    // ADC, CMN
-                    const result = logicalLeft(true, &cpu.cpsr, cpu.r[rd], @truncate(u8, cpu.r[rs]));
+                    cpu.cpsr.n.write(result >> 31 & 1 == 1);
-                    cpu.r[rd] = result;
+                    cpu.cpsr.z.write(result == 0);
-                    setLogicOpFlags(true, cpu, result);
+                    cpu.cpsr.c.write(overflow);
-                },
+                    cpu.cpsr.v.write(((op1 ^ result) & (op2 ^ result)) >> 31 & 1 == 1);
                0x3 => {
                    // LSR
                    const result = logicalRight(true, &cpu.cpsr, cpu.r[rd], @truncate(u8, cpu.r[rs]));
                    cpu.r[rd] = result;
                    setLogicOpFlags(true, cpu, result);
                },
                0x4 => {
                    // ASR
                    const result = arithmeticRight(true, &cpu.cpsr, cpu.r[rd], @truncate(u8, cpu.r[rs]));
                    cpu.r[rd] = result;
                    setLogicOpFlags(true, cpu, result);
                },
                0x5 => {
                    // ADC
                    cpu.r[rd] = adc(true, cpu, cpu.r[rd], cpu.r[rs], carry);
                },
                0x6 => {
                    // SBC
-                    cpu.r[rd] = sbc(true, cpu, cpu.r[rd], cpu.r[rs], carry);
+                    cpu.cpsr.n.write(result >> 31 & 1 == 1);
-                },
+                    cpu.cpsr.z.write(result == 0);
-                0x7 => {
+
-                    // ROR
+                    const subtrahend = @as(u64, op2) -% carry +% 1;
-                    const result = rotateRight(true, &cpu.cpsr, cpu.r[rd], @truncate(u8, cpu.r[rs]));
+                    cpu.cpsr.c.write(subtrahend <= op1);
-                    cpu.r[rd] = result;
+                    cpu.cpsr.v.write(((op1 ^ result) & (~op2 ^ result)) >> 31 & 1 == 1);
                    setLogicOpFlags(true, cpu, result);
                },
                0x8 => {
                    // TST
                    const result = cpu.r[rd] & cpu.r[rs];
                    setLogicOpFlags(true, cpu, result);
                },
                0x9 => {
                    // NEG
-                    cpu.r[rd] = sub(true, cpu, 0, cpu.r[rs]);
+                    cpu.cpsr.n.write(result >> 31 & 1 == 1);
-                },
+                    cpu.cpsr.z.write(result == 0);
-                0xA => {
+                    cpu.cpsr.c.write(op2 <= 0);
-                    // CMP
+                    cpu.cpsr.v.write(((0 ^ result) & (~op2 ^ result)) >> 31 & 1 == 1);
                    cmp(cpu, cpu.r[rd], cpu.r[rs]);
                },
                0xB => {
                    // CMN
                    cmn(cpu, cpu.r[rd], cpu.r[rs]);
                },
                0xC => {
                    // ORR
                    const result = cpu.r[rd] | cpu.r[rs];
                    cpu.r[rd] = result;
                    setLogicOpFlags(true, cpu, result);
                },
                0xD => {
-                    // MUL
+                    // Multiplication
                    const temp = @as(u64, cpu.r[rs]) * @as(u64, cpu.r[rd]);
                    const result = @truncate(u32, temp);
                    cpu.r[rd] = result;
                    cpu.cpsr.n.write(result >> 31 & 1 == 1);
                    cpu.cpsr.z.write(result == 0);
                    // V is unaffected, assuming similar behaviour to ARMv4 MUL C is undefined
                },
                0xE => {
                    // BIC
                    const result = cpu.r[rd] & ~cpu.r[rs];
                    cpu.r[rd] = result;
                    setLogicOpFlags(true, cpu, result);
                },
                0xF => {
                    // MVN
                    const result = ~cpu.r[rs];
                    cpu.r[rd] = result;
                    setLogicOpFlags(true, cpu, result);
                },
            }
        }
    }.inner;
--- a/src/core/cpu/thumb/block_data_transfer.zig
+++ b/src/core/cpu/thumb/block_data_transfer.zig
@@ -33,7 +33,8 @@ pub fn fmt14(comptime L: bool, comptime R: bool) InstrFn {
            if (R) {
                if (L) {
                    const value = bus.read(u32, address);
-                    cpu.r[15] = value & 0xFFFF_FFFE;
+                    cpu.r[15] = value & ~@as(u32, 1);
                    cpu.pipe.reload(cpu);
                } else {
                    bus.write(u32, address, cpu.r[14]);
                }
@@ -52,7 +53,13 @@ pub fn fmt15(comptime L: bool, comptime rb: u3) InstrFn {
            const end_address = cpu.r[rb] + 4 * countRlist(opcode);
            if (opcode & 0xFF == 0) {
-                if (L) cpu.r[15] = bus.read(u32, address) else bus.write(u32, address, cpu.r[15] + 4);
+                if (L) {
                    cpu.r[15] = bus.read(u32, address);
                    cpu.pipe.reload(cpu);
                } else {
                    bus.write(u32, address, cpu.r[15] + 2);
                }
                cpu.r[rb] += 0x40;
                return;
            }
--- a/src/core/cpu/thumb/branch.zig
+++ b/src/core/cpu/thumb/branch.zig
@@ -3,22 +3,19 @@ const Arm7tdmi = @import("../../cpu.zig").Arm7tdmi;
 const InstrFn = @import("../../cpu.zig").thumb.InstrFn;
 const checkCond = @import("../../cpu.zig").checkCond;
-const sext = @import("../../util.zig").sext;
+const sext = @import("../../../util.zig").sext;
 pub fn fmt16(comptime cond: u4) InstrFn {
    return struct {
        fn inner(cpu: *Arm7tdmi, _: *Bus, opcode: u16) void {
            // B
-            const offset = sext(u32, u8, opcode & 0xFF) << 1;
+            if (cond == 0xE or cond == 0xF)
                cpu.panic("[CPU/THUMB.16] Undefined conditional branch with condition {}", .{cond});
-            const should_execute = switch (cond) {
+            if (!checkCond(cpu.cpsr, cond)) return;
                0xE, 0xF => cpu.panic("[CPU/THUMB.16] Undefined conditional branch with condition {}", .{cond}),
                else => checkCond(cpu.cpsr, cond),
            };
-            if (should_execute) {
+            cpu.r[15] +%= sext(u32, u8, opcode & 0xFF) << 1;
-                cpu.r[15] = (cpu.r[15] + 2) +% offset;
+            cpu.pipe.reload(cpu);
            }
        }
    }.inner;
 }
@@ -27,8 +24,8 @@ pub fn fmt18() InstrFn {
    return struct {
        // B but conditional
        fn inner(cpu: *Arm7tdmi, _: *Bus, opcode: u16) void {
-            const offset = sext(u32, u11, opcode & 0x7FF) << 1;
+            cpu.r[15] +%= sext(u32, u11, opcode & 0x7FF) << 1;
-            cpu.r[15] = (cpu.r[15] + 2) +% offset;
+            cpu.pipe.reload(cpu);
        }
    }.inner;
 }
@@ -41,13 +38,16 @@ pub fn fmt19(comptime is_low: bool) InstrFn {
            if (is_low) {
                // Instruction 2
-                const old_pc = cpu.r[15];
+                const next_opcode = cpu.r[15] - 2;
                cpu.r[15] = cpu.r[14] +% (offset << 1);
-                cpu.r[14] = old_pc | 1;
+                cpu.r[14] = next_opcode | 1;
                cpu.pipe.reload(cpu);
            } else {
                // Instruction 1
-                cpu.r[14] = (cpu.r[15] + 2) +% (sext(u32, u11, offset) << 12);
+                const lr_offset = sext(u32, u11, offset) << 12;
                cpu.r[14] = (cpu.r[15] +% lr_offset) & ~@as(u32, 1);
            }
        }
    }.inner;
--- a/src/core/cpu/thumb/data_processing.zig
+++ b/src/core/cpu/thumb/data_processing.zig
@@ -1,16 +1,12 @@
 const std = @import("std");
 const Bus = @import("../../Bus.zig");
 const Arm7tdmi = @import("../../cpu.zig").Arm7tdmi;
 const InstrFn = @import("../../cpu.zig").thumb.InstrFn;
 const shifter = @import("../barrel_shifter.zig");
 const add = @import("../arm/data_processing.zig").add;
 const sub = @import("../arm/data_processing.zig").sub;
 const cmp = @import("../arm/data_processing.zig").cmp;
 const setLogicOpFlags = @import("../arm/data_processing.zig").setLogicOpFlags;
-const log = std.log.scoped(.Thumb1);
+const lsl = @import("../barrel_shifter.zig").lsl;
 const lsr = @import("../barrel_shifter.zig").lsr;
 const asr = @import("../barrel_shifter.zig").asr;
 pub fn fmt1(comptime op: u2, comptime offset: u5) InstrFn {
    return struct {
@@ -24,7 +20,7 @@ pub fn fmt1(comptime op: u2, comptime offset: u5) InstrFn {
                    if (offset == 0) {
                        break :blk cpu.r[rs];
                    } else {
-                        break :blk shifter.logicalLeft(true, &cpu.cpsr, cpu.r[rs], offset);
+                        break :blk lsl(true, &cpu.cpsr, cpu.r[rs], offset);
                    }
                },
                0b01 => blk: {
@@ -33,7 +29,7 @@ pub fn fmt1(comptime op: u2, comptime offset: u5) InstrFn {
                        cpu.cpsr.c.write(cpu.r[rs] >> 31 & 1 == 1);
                        break :blk @as(u32, 0);
                    } else {
-                        break :blk shifter.logicalRight(true, &cpu.cpsr, cpu.r[rs], offset);
+                        break :blk lsr(true, &cpu.cpsr, cpu.r[rs], offset);
                    }
                },
                0b10 => blk: {
@@ -42,7 +38,7 @@ pub fn fmt1(comptime op: u2, comptime offset: u5) InstrFn {
                        cpu.cpsr.c.write(cpu.r[rs] >> 31 & 1 == 1);
                        break :blk @bitCast(u32, @bitCast(i32, cpu.r[rs]) >> 31);
                    } else {
-                        break :blk shifter.arithmeticRight(true, &cpu.cpsr, cpu.r[rs], offset);
+                        break :blk asr(true, &cpu.cpsr, cpu.r[rs], offset);
                    }
                },
                else => cpu.panic("[CPU/THUMB.1] 0b{b:0>2} is not a valid op", .{op}),
@@ -50,7 +46,10 @@ pub fn fmt1(comptime op: u2, comptime offset: u5) InstrFn {
            // Equivalent to an ARM MOVS
            cpu.r[rd] = result;
-            setLogicOpFlags(true, cpu, result);
+
            // Write Flags
            cpu.cpsr.n.write(result >> 31 & 1 == 1);
            cpu.cpsr.z.write(result == 0);
        }
    }.inner;
 }
@@ -58,28 +57,51 @@ pub fn fmt1(comptime op: u2, comptime offset: u5) InstrFn {
 pub fn fmt5(comptime op: u2, comptime h1: u1, comptime h2: u1) InstrFn {
    return struct {
        fn inner(cpu: *Arm7tdmi, _: *Bus, opcode: u16) void {
-            const src_idx = @as(u4, h2) << 3 | (opcode >> 3 & 0x7);
+            const rs = @as(u4, h2) << 3 | (opcode >> 3 & 0x7);
-            const dst_idx = @as(u4, h1) << 3 | (opcode & 0x7);
+            const rd = @as(u4, h1) << 3 | (opcode & 0x7);
-            const src = if (src_idx == 0xF) (cpu.r[src_idx] + 2) & 0xFFFF_FFFE else cpu.r[src_idx];
+            const op1 = cpu.r[rd];
-            const dst = if (dst_idx == 0xF) (cpu.r[dst_idx] + 2) & 0xFFFF_FFFE else cpu.r[dst_idx];
+            const op2 = cpu.r[rs];
            var result: u32 = undefined;
            var overflow: bool = undefined;
            switch (op) {
-                0b00 => {
+                0b00 => result = add(&overflow, op1, op2), // ADD
-                    // ADD
+                0b01 => result = op1 -% op2, // CMP
-                    const sum = add(false, cpu, dst, src);
+                0b10 => result = op2, // MOV
-                    cpu.r[dst_idx] = if (dst_idx == 0xF) sum & 0xFFFF_FFFE else sum;
+                0b11 => {},
-                },
+            }
-                0b01 => cmp(cpu, dst, src), // CMP
+
-                0b10 => {
+            // Write to Destination Register
-                    // MOV
+            switch (op) {
-                    cpu.r[dst_idx] = if (dst_idx == 0xF) src & 0xFFFF_FFFE else src;
+                0b01 => {}, // Test Instruction
                },
                0b11 => {
                    // BX
-                    cpu.cpsr.t.write(src & 1 == 1);
+                    const is_thumb = op2 & 1 == 1;
-                    cpu.r[15] = src & 0xFFFF_FFFE;
+                    cpu.r[15] = op2 & ~@as(u32, 1);
                    cpu.cpsr.t.write(is_thumb);
                    cpu.pipe.reload(cpu);
                },
                else => {
                    cpu.r[rd] = result;
                    if (rd == 0xF) {
                        cpu.r[15] &= ~@as(u32, 1);
                        cpu.pipe.reload(cpu);
                    }
                },
            }
            // Write Flags
            switch (op) {
                0b01 => {
                    // CMP
                    cpu.cpsr.n.write(result >> 31 & 1 == 1);
                    cpu.cpsr.z.write(result == 0);
                    cpu.cpsr.c.write(op2 <= op1);
                    cpu.cpsr.v.write(((op1 ^ result) & (~op2 ^ result)) >> 31 & 1 == 1);
                },
                0b00, 0b10, 0b11 => {}, // MOV and Branch Instruction
            }
        }
    }.inner;
@@ -90,21 +112,28 @@ pub fn fmt2(comptime I: bool, is_sub: bool, rn: u3) InstrFn {
        fn inner(cpu: *Arm7tdmi, _: *Bus, opcode: u16) void {
            const rs = opcode >> 3 & 0x7;
            const rd = @truncate(u3, opcode);
            const op1 = cpu.r[rs];
            const op2: u32 = if (I) rn else cpu.r[rn];
            if (is_sub) {
                // SUB
-                cpu.r[rd] = if (I) blk: {
+                const result = op1 -% op2;
-                    break :blk sub(true, cpu, cpu.r[rs], rn);
+                cpu.r[rd] = result;
-                } else blk: {
+
-                    break :blk sub(true, cpu, cpu.r[rs], cpu.r[rn]);
+                cpu.cpsr.n.write(result >> 31 & 1 == 1);
-                };
+                cpu.cpsr.z.write(result == 0);
                cpu.cpsr.c.write(op2 <= op1);
                cpu.cpsr.v.write(((op1 ^ result) & (~op2 ^ result)) >> 31 & 1 == 1);
            } else {
                // ADD
-                cpu.r[rd] = if (I) blk: {
+                var overflow: bool = undefined;
-                    break :blk add(true, cpu, cpu.r[rs], rn);
+                const result = add(&overflow, op1, op2);
-                } else blk: {
+                cpu.r[rd] = result;
-                    break :blk add(true, cpu, cpu.r[rs], cpu.r[rn]);
+
-                };
+                cpu.cpsr.n.write(result >> 31 & 1 == 1);
                cpu.cpsr.z.write(result == 0);
                cpu.cpsr.c.write(overflow);
                cpu.cpsr.v.write(((op1 ^ result) & (op2 ^ result)) >> 31 & 1 == 1);
            }
        }
    }.inner;
@@ -113,17 +142,36 @@ pub fn fmt2(comptime I: bool, is_sub: bool, rn: u3) InstrFn {
 pub fn fmt3(comptime op: u2, comptime rd: u3) InstrFn {
    return struct {
        fn inner(cpu: *Arm7tdmi, _: *Bus, opcode: u16) void {
-            const offset = @truncate(u8, opcode);
+            const op1 = cpu.r[rd];
            const op2: u32 = opcode & 0xFF; // Offset
            var overflow: bool = undefined;
            const result: u32 = switch (op) {
                0b00 => op2, // MOV
                0b01 => op1 -% op2, // CMP
                0b10 => add(&overflow, op1, op2), // ADD
                0b11 => op1 -% op2, // SUB
            };
            // Write to Register
            if (op != 0b01) cpu.r[rd] = result;
            // Write Flags
            cpu.cpsr.n.write(result >> 31 & 1 == 1);
            cpu.cpsr.z.write(result == 0);
            switch (op) {
-                0b00 => {
+                0b00 => {}, // MOV | C set by Barrel Shifter, V is unaffected
-                    // MOV
+                0b01, 0b11 => {
-                    cpu.r[rd] = offset;
+                    // SUB, CMP
-                    setLogicOpFlags(true, cpu, offset);
+                    cpu.cpsr.c.write(op2 <= op1);
                    cpu.cpsr.v.write(((op1 ^ result) & (~op2 ^ result)) >> 31 & 1 == 1);
                },
                0b10 => {
                    // ADD
                    cpu.cpsr.c.write(overflow);
                    cpu.cpsr.v.write(((op1 ^ result) & (op2 ^ result)) >> 31 & 1 == 1);
                },
                0b01 => cmp(cpu, cpu.r[rd], offset), // CMP
                0b10 => cpu.r[rd] = add(true, cpu, cpu.r[rd], offset), // ADD
                0b11 => cpu.r[rd] = sub(true, cpu, cpu.r[rd], offset), // SUB
            }
        }
    }.inner;
@@ -133,10 +181,9 @@ pub fn fmt12(comptime isSP: bool, comptime rd: u3) InstrFn {
    return struct {
        fn inner(cpu: *Arm7tdmi, _: *Bus, opcode: u16) void {
            // ADD
-            const left = if (isSP) cpu.r[13] else (cpu.r[15] + 2) & 0xFFFF_FFFD;
+            const left = if (isSP) cpu.r[13] else cpu.r[15] & ~@as(u32, 2);
            const right = (opcode & 0xFF) << 2;
-            const result = left + right;
+            cpu.r[rd] = left + right;
            cpu.r[rd] = result;
        }
    }.inner;
 }
--- a/src/core/cpu/thumb/data_transfer.zig
+++ b/src/core/cpu/thumb/data_transfer.zig
@@ -1,23 +1,22 @@
 const std = @import("std");
 const Bus = @import("../../Bus.zig");
 const Arm7tdmi = @import("../../cpu.zig").Arm7tdmi;
 const InstrFn = @import("../../cpu.zig").thumb.InstrFn;
-const rotr = @import("../../util.zig").rotr;
+const rotr = @import("../../../util.zig").rotr;
 const sext = @import("../../../util.zig").sext;
 pub fn fmt6(comptime rd: u3) InstrFn {
    return struct {
        fn inner(cpu: *Arm7tdmi, bus: *Bus, opcode: u16) void {
            // LDR
            const offset = (opcode & 0xFF) << 2;
-            cpu.r[rd] = bus.read(u32, (cpu.r[15] + 2 & 0xFFFF_FFFD) + offset);
+
            // Bit 1 of the PC intentionally ignored
            cpu.r[rd] = bus.read(u32, (cpu.r[15] & ~@as(u32, 2)) + offset);
        }
    }.inner;
 }
 const sext = @import("../../util.zig").sext;
 pub fn fmt78(comptime op: u2, comptime T: bool) InstrFn {
    return struct {
        fn inner(cpu: *Arm7tdmi, bus: *Bus, opcode: u16) void {
@@ -45,11 +44,8 @@ pub fn fmt78(comptime op: u2, comptime T: bool) InstrFn {
                    },
                    0b11 => {
                        // LDRSH
-                        cpu.r[rd] = if (address & 1 == 1) blk: {
+                        const value = bus.read(u16, address);
-                            break :blk sext(u32, u8, bus.read(u8, address));
+                        cpu.r[rd] = if (address & 1 == 1) sext(u32, u8, @truncate(u8, value >> 8)) else sext(u32, u16, value);
                        } else blk: {
                            break :blk sext(u32, u16, bus.read(u16, address));
                        };
                    },
                }
            } else {
--- a/src/core/cpu/thumb/software_interrupt.zig
+++ b/src/core/cpu/thumb/software_interrupt.zig
@@ -6,7 +6,7 @@ pub fn fmt17() InstrFn {
    return struct {
        fn inner(cpu: *Arm7tdmi, _: *Bus, _: u16) void {
            // Copy Values from Current Mode
-            const r15 = cpu.r[15];
+            const ret_addr = cpu.r[15] - 2;
            const cpsr = cpu.cpsr.raw;
            // Switch Mode
@@ -14,9 +14,10 @@ pub fn fmt17() InstrFn {
            cpu.cpsr.t.write(false); // Force ARM Mode
            cpu.cpsr.i.write(true); // Disable normal interrupts
-            cpu.r[14] = r15; // Resume Execution
+            cpu.r[14] = ret_addr; // Resume Execution
            cpu.spsr.raw = cpsr; // Previous mode CPSR
            cpu.r[15] = 0x0000_0008;
            cpu.pipe.reload(cpu);
        }
    }.inner;
 }
--- a/src/core/emu.zig
+++ b/src/core/emu.zig
@@ -1,35 +1,31 @@
 const std = @import("std");
 const SDL = @import("sdl2");
 const config = @import("../config.zig");
 const Bus = @import("Bus.zig");
 const Scheduler = @import("scheduler.zig").Scheduler;
 const Arm7tdmi = @import("cpu.zig").Arm7tdmi;
-const FpsTracker = @import("util.zig").FpsTracker;
+const FpsTracker = @import("../util.zig").FpsTracker;
-const FilePaths = @import("util.zig").FilePaths;
+const RingBuffer = @import("../util.zig").RingBuffer;
 const Timer = std.time.Timer;
 const Thread = std.Thread;
 const Atomic = std.atomic.Atomic;
 const Allocator = std.mem.Allocator;
-// TODO: Move these to a TOML File
+/// 4 Cycles in 1 dot
-const sync_audio = true; // Enable Audio Sync
+const cycles_per_dot = 4;
 const sync_video: RunKind = .LimitedFPS; // Configure Video Sync
 pub const win_scale = 3; // 1x, 2x, 3x, etc. Window Scaling
 pub const cpu_logging = false; // Enable detailed CPU logging
-// 228 Lines which consist of 308 dots (which are 4 cycles long)
+/// The GBA draws 228 Horizontal which each consist 308 dots
-const cycles_per_frame: u64 = 228 * (308 * 4); //280896
+/// (note: not all lines are visible)
-const clock_rate: u64 = 1 << 24; // 16.78MHz
+const cycles_per_frame = 228 * (308 * cycles_per_dot); //280896
-// TODO: Don't truncate this, be more accurate w/ timing
+/// The GBA ARM7TDMI runs at 2^24 Hz
-// 59.6046447754ns (truncated to just 59ns)
+const clock_rate = 1 << 24; // 16.78MHz
 const clock_period: u64 = std.time.ns_per_s / clock_rate;
 const frame_period = (clock_period * cycles_per_frame);
-// 59.7275005696Hz
+/// The # of nanoseconds a frame should take
-pub const frame_rate = @intToFloat(f64, std.time.ns_per_s) /
+const frame_period = (std.time.ns_per_s * cycles_per_frame) / clock_rate;
-    ((@intToFloat(f64, std.time.ns_per_s) / @intToFloat(f64, clock_rate)) * @intToFloat(f64, cycles_per_frame));
+
 /// Exact Value:  59.7275005696Hz
 /// The inverse of the frame period
 pub const frame_rate: f64 = @intToFloat(f64, clock_rate) / cycles_per_frame;
 const log = std.log.scoped(.Emulation);
@@ -38,18 +34,57 @@ const RunKind = enum {
    UnlimitedFPS,
    Limited,
    LimitedFPS,
    LimitedBusy,
 };
-pub fn run(quit: *Atomic(bool), fps: *FpsTracker, sched: *Scheduler, cpu: *Arm7tdmi) void {
+pub fn run(quit: *Atomic(bool), scheduler: *Scheduler, cpu: *Arm7tdmi, tracker: *FpsTracker) void {
-    if (sync_audio) log.info("Audio sync enabled", .{});
+    const audio_sync = config.config().guest.audio_sync and !config.config().host.mute;
    if (audio_sync) log.info("Audio sync enabled", .{});
-    switch (sync_video) {
+    if (config.config().guest.video_sync) {
-        .Unlimited => runUnsynchronized(quit, sched, cpu, null),
+        inner(.LimitedFPS, audio_sync, quit, scheduler, cpu, tracker);
-        .Limited => runSynchronized(quit, sched, cpu, null),
+    } else {
-        .UnlimitedFPS => runUnsynchronized(quit, sched, cpu, fps),
+        inner(.UnlimitedFPS, audio_sync, quit, scheduler, cpu, tracker);
-        .LimitedFPS => runSynchronized(quit, sched, cpu, fps),
+    }
-        .LimitedBusy => runBusyLoop(quit, sched, cpu),
+}
 fn inner(comptime kind: RunKind, audio_sync: bool, quit: *Atomic(bool), scheduler: *Scheduler, cpu: *Arm7tdmi, tracker: ?*FpsTracker) void {
    if (kind == .UnlimitedFPS or kind == .LimitedFPS) {
        std.debug.assert(tracker != null);
        log.info("FPS tracking enabled", .{});
    }
    switch (kind) {
        .Unlimited, .UnlimitedFPS => {
            log.info("Emulation w/out video sync", .{});
            while (!quit.load(.Monotonic)) {
                runFrame(scheduler, cpu);
                audioSync(audio_sync, &cpu.bus.apu.sample_queue);
                if (kind == .UnlimitedFPS) tracker.?.tick();
            }
        },
        .Limited, .LimitedFPS => {
            log.info("Emulation w/ video sync", .{});
            var timer = Timer.start() catch @panic("failed to initalize std.timer.Timer");
            var wake_time: u64 = frame_period;
            while (!quit.load(.Monotonic)) {
                runFrame(scheduler, cpu);
                const new_wake_time = videoSync(&timer, wake_time);
                // Spin to make up the difference of OS scheduler innacuracies
                // If we happen to also be syncing to audio, we choose to spin on
                // the amount of time needed for audio to catch up rather than
                // our expected wake-up time
                audioSync(audio_sync, &cpu.bus.apu.sample_queue);
                if (!audio_sync) spinLoop(&timer, wake_time);
                wake_time = new_wake_time;
                if (kind == .LimitedFPS) tracker.?.tick();
            }
        },
    }
 }
@@ -70,96 +105,30 @@ pub fn runFrame(sched: *Scheduler, cpu: *Arm7tdmi) void {
    }
 }
-fn syncToAudio(cpu: *const Arm7tdmi) void {
+fn audioSync(audio_sync: bool, sample_queue: *RingBuffer(u16)) void {
-    const stream = cpu.bus.apu.stream;
+    comptime std.debug.assert(@import("../platform.zig").sample_format == SDL.AUDIO_U16);
-    const min_sample_count = 0x800;
+    // const sample_size = 2 * @sizeOf(u16);
    // const max_buf_size: c_int = 0x400;
-    // Busy Loop while we wait for the Audio system to catch up
+    _ = audio_sync;
-    while (SDL.SDL_AudioStreamAvailable(stream) > (@sizeOf(u16) * 2) * min_sample_count) {}
+    _ = sample_queue;
 }
-pub fn runUnsynchronized(quit: *Atomic(bool), sched: *Scheduler, cpu: *Arm7tdmi, fps: ?*FpsTracker) void {
+fn videoSync(timer: *Timer, wake_time: u64) u64 {
    log.info("Emulation thread w/out video sync", .{});
    if (fps) |tracker| {
        log.info("FPS Tracking Enabled", .{});
        while (!quit.load(.SeqCst)) {
            runFrame(sched, cpu);
            if (sync_audio) syncToAudio(cpu);
            tracker.tick();
        }
    } else {
        while (!quit.load(.SeqCst)) {
            runFrame(sched, cpu);
            if (sync_audio) syncToAudio(cpu);
        }
    }
 }
 pub fn runSynchronized(quit: *Atomic(bool), sched: *Scheduler, cpu: *Arm7tdmi, fps: ?*FpsTracker) void {
    log.info("Emulation thread w/ video sync", .{});
    var timer = Timer.start() catch unreachable;
    var wake_time: u64 = frame_period;
    if (fps) |tracker| {
        log.info("FPS Tracking Enabled", .{});
        while (!quit.load(.SeqCst)) {
            runFrame(sched, cpu);
            const new_wake_time = syncToVideo(&timer, wake_time);
            // Spin to make up the difference of OS scheduler innacuracies
            // If we happen to also be syncing to audio, we choose to spin on
            // the amount of time needed for audio to catch up rather than
            // our expected wake-up time
            if (sync_audio) syncToAudio(cpu) else spinLoop(&timer, wake_time);
            wake_time = new_wake_time;
            tracker.tick();
        }
    } else {
        while (!quit.load(.SeqCst)) {
            runFrame(sched, cpu);
            const new_wake_time = syncToVideo(&timer, wake_time);
            // see above comment
            if (sync_audio) syncToAudio(cpu) else spinLoop(&timer, wake_time);
            wake_time = new_wake_time;
        }
    }
 }
 inline fn syncToVideo(timer: *Timer, wake_time: u64) u64 {
    // Use the OS scheduler to put the emulation thread to sleep
-    const maybe_recalc_wake_time = sleep(timer, wake_time);
+    const recalculated = sleep(timer, wake_time);
    // If sleep() determined we need to adjust our wake up time, do so
    // otherwise predict our next wake up time according to the frame period
-    return if (maybe_recalc_wake_time) |recalc| recalc else wake_time + frame_period;
+    return recalculated orelse wake_time + frame_period;
 }
 pub fn runBusyLoop(quit: *Atomic(bool), sched: *Scheduler, cpu: *Arm7tdmi) void {
    log.info("Emulation thread with video sync using busy loop", .{});
    var timer = Timer.start() catch unreachable;
    var wake_time: u64 = frame_period;
    while (!quit.load(.SeqCst)) {
        runFrame(sched, cpu);
        spinLoop(&timer, wake_time);
        // Update to the new wake time
        wake_time += frame_period;
    }
 }
 // TODO: Better sleep impl?
 fn sleep(timer: *Timer, wake_time: u64) ?u64 {
    // const step = std.time.ns_per_ms * 10; // 10ms
    const timestamp = timer.read();
    // ns_late is non zero if we are late.
-    const ns_late = timestamp -| wake_time;
+    var ns_late = timestamp -| wake_time;
    // If we're more than a frame late, skip the rest of this loop
    // Recalculate what our new wake time should be so that we can
@@ -167,15 +136,18 @@ fn sleep(timer: *Timer, wake_time: u64) ?u64 {
    if (ns_late > frame_period) return timestamp + frame_period;
    const sleep_for = frame_period - ns_late;
-    // // Employ several sleep calls in periods of 10ms
+    const step = 2 * std.time.ns_per_ms; // Granularity of 2ms
-    // // By doing this the behaviour should average out to be
+    const times = sleep_for / step;
-    // // more consistent
+    var i: usize = 0;
    // const loop_count = sleep_for / step; // How many groups of 10ms
-    // var i: usize = 0;
+    while (i < times) : (i += 1) {
-    // while (i < loop_count) : (i += 1) std.time.sleep(step);
+        std.time.sleep(step);
-    std.time.sleep(sleep_for);
+        // Upon wakeup, check to see if this particular sleep was longer than expected
        // if so we should exit early, but probably not skip a whole frame period
        ns_late = timer.read() -| wake_time;
        if (ns_late > frame_period) return null;
    }
    return null;
 }
--- a/src/core/ppu.zig
+++ b/src/core/ppu.zig
@@ -1,7 +1,7 @@
 const std = @import("std");
 const io = @import("bus/io.zig");
 const util = @import("../util.zig");
 const EventKind = @import("scheduler.zig").EventKind;
 const Scheduler = @import("scheduler.zig").Scheduler;
 const Arm7tdmi = @import("cpu.zig").Arm7tdmi;
@@ -10,15 +10,229 @@ const Bitfield = @import("bitfield").Bitfield;
 const Allocator = std.mem.Allocator;
 const log = std.log.scoped(.PPU);
 const pollBlankingDma = @import("bus/dma.zig").pollBlankingDma;
-/// This is used to generate byuu / Talurabi's Color Correction algorithm
+const getHalf = util.getHalf;
-const COLOUR_LUT = genColourLut();
+const setHalf = util.setHalf;
 const setQuart = util.setQuart;
 const pollDmaOnBlank = @import("bus/dma.zig").pollDmaOnBlank;
 pub const width = 240;
 pub const height = 160;
 pub const framebuf_pitch = width * @sizeOf(u32);
 pub fn read(comptime T: type, ppu: *const Ppu, addr: u32) ?T {
    const byte_addr = @truncate(u8, addr);
    return switch (T) {
        u32 => switch (byte_addr) {
            0x00 => ppu.dispcnt.raw, // Green Swap is in high half-word
            0x04 => @as(T, ppu.vcount.raw) << 16 | ppu.dispstat.raw,
            0x08 => @as(T, ppu.bg[1].bg1Cnt()) << 16 | ppu.bg[0].bg0Cnt(),
            0x0C => @as(T, ppu.bg[3].cnt.raw) << 16 | ppu.bg[2].cnt.raw,
            0x10, 0x14, 0x18, 0x1C => null, // BGXHOFS/VOFS
            0x20, 0x24, 0x28, 0x2C => null, // BG2 Rot/Scaling
            0x30, 0x34, 0x38, 0x3C => null, // BG3 Rot/Scaling
            0x40, 0x44 => null, // WINXH/V Registers
            0x48 => @as(T, ppu.win.getOut()) << 16 | ppu.win.getIn(),
            0x4C => null, // MOSAIC, undefined in high byte
            0x50 => @as(T, ppu.bld.getAlpha()) << 16 | ppu.bld.getCnt(),
            0x54 => null, // BLDY, undefined in high half-wrd
            else => util.io.read.err(T, log, "unaligned {} read from 0x{X:0>8}", .{ T, addr }),
        },
        u16 => switch (byte_addr) {
            0x00 => ppu.dispcnt.raw,
            0x02 => null, // Green Swap
            0x04 => ppu.dispstat.raw,
            0x06 => ppu.vcount.raw,
            0x08 => ppu.bg[0].bg0Cnt(),
            0x0A => ppu.bg[1].bg1Cnt(),
            0x0C => ppu.bg[2].cnt.raw,
            0x0E => ppu.bg[3].cnt.raw,
            0x10, 0x12, 0x14, 0x16, 0x18, 0x1A, 0x1C, 0x1E => null, // BGXHOFS/VOFS
            0x20, 0x22, 0x24, 0x26, 0x28, 0x2A, 0x2C, 0x2E => null, // BG2 Rot/Scaling
            0x30, 0x32, 0x34, 0x36, 0x38, 0x3A, 0x3C, 0x3E => null, // BG3 Rot/Scaling
            0x40, 0x42, 0x44, 0x46 => null, // WINXH/V Registers
            0x48 => ppu.win.getIn(),
            0x4A => ppu.win.getOut(),
            0x4C => null, // MOSAIC
            0x4E => null,
            0x50 => ppu.bld.getCnt(),
            0x52 => ppu.bld.getAlpha(),
            0x54 => null, // BLDY
            else => util.io.read.err(T, log, "unaligned {} read from 0x{X:0>8}", .{ T, addr }),
        },
        u8 => switch (byte_addr) {
            0x00, 0x01 => @truncate(T, ppu.dispcnt.raw >> getHalf(byte_addr)),
            0x02, 0x03 => null,
            0x04, 0x05 => @truncate(T, ppu.dispstat.raw >> getHalf(byte_addr)),
            0x06, 0x07 => @truncate(T, ppu.vcount.raw >> getHalf(byte_addr)),
            0x08, 0x09 => @truncate(T, ppu.bg[0].bg0Cnt() >> getHalf(byte_addr)),
            0x0A, 0x0B => @truncate(T, ppu.bg[1].bg1Cnt() >> getHalf(byte_addr)),
            0x0C, 0x0D => @truncate(T, ppu.bg[2].cnt.raw >> getHalf(byte_addr)),
            0x0E, 0x0F => @truncate(T, ppu.bg[3].cnt.raw >> getHalf(byte_addr)),
            0x10...0x1F => null, // BGXHOFS/VOFS
            0x20...0x2F => null, // BG2 Rot/Scaling
            0x30...0x3F => null, // BG3 Rot/Scaling
            0x40...0x47 => null, // WINXH/V Registers
            0x48, 0x49 => @truncate(T, ppu.win.getIn() >> getHalf(byte_addr)),
            0x4A, 0x4B => @truncate(T, ppu.win.getOut() >> getHalf(byte_addr)),
            0x4C, 0x4D => null, // MOSAIC
            0x4E, 0x4F => null,
            0x50, 0x51 => @truncate(T, ppu.bld.getCnt() >> getHalf(byte_addr)),
            0x52, 0x53 => @truncate(T, ppu.bld.getAlpha() >> getHalf(byte_addr)),
            0x54, 0x55 => null, // BLDY
            else => util.io.read.err(T, log, "unexpected {} read from 0x{X:0>8}", .{ T, addr }),
        },
        else => @compileError("PPU: Unsupported read width"),
    };
 }
 pub fn write(comptime T: type, ppu: *Ppu, addr: u32, value: T) void {
    const byte_addr = @truncate(u8, addr); // prefixed with 0x0400_00
    switch (T) {
        u32 => switch (byte_addr) {
            0x00 => ppu.dispcnt.raw = @truncate(u16, value),
            0x04 => {
                ppu.dispstat.set(@truncate(u16, value));
                ppu.vcount.raw = @truncate(u16, value >> 16);
            },
            0x08 => ppu.setAdjCnts(0, value),
            0x0C => ppu.setAdjCnts(2, value),
            0x10 => ppu.setBgOffsets(0, value),
            0x14 => ppu.setBgOffsets(1, value),
            0x18 => ppu.setBgOffsets(2, value),
            0x1C => ppu.setBgOffsets(3, value),
            0x20 => ppu.aff_bg[0].writePaPb(value),
            0x24 => ppu.aff_bg[0].writePcPd(value),
            0x28 => ppu.aff_bg[0].setX(ppu.dispstat.vblank.read(), value),
            0x2C => ppu.aff_bg[0].setY(ppu.dispstat.vblank.read(), value),
            0x30 => ppu.aff_bg[1].writePaPb(value),
            0x34 => ppu.aff_bg[1].writePcPd(value),
            0x38 => ppu.aff_bg[1].setX(ppu.dispstat.vblank.read(), value),
            0x3C => ppu.aff_bg[1].setY(ppu.dispstat.vblank.read(), value),
            0x40 => ppu.win.setH(value),
            0x44 => ppu.win.setV(value),
            0x48 => ppu.win.setIo(value),
            0x4C => log.debug("Wrote 0x{X:0>8} to MOSAIC", .{value}),
            0x50 => {
                ppu.bld.cnt.raw = @truncate(u16, value);
                ppu.bld.alpha.raw = @truncate(u16, value >> 16);
            },
            0x54 => ppu.bld.y.raw = @truncate(u16, value),
            else => util.io.write.undef(log, "Tried to write 0x{X:0>8}{} to 0x{X:0>8}", .{ value, T, addr }),
        },
        u16 => switch (byte_addr) {
            0x00 => ppu.dispcnt.raw = value,
            0x02 => {}, // Green Swap
            0x04 => ppu.dispstat.set(value),
            0x06 => {}, // VCOUNT
            0x08 => ppu.bg[0].cnt.raw = value,
            0x0A => ppu.bg[1].cnt.raw = value,
            0x0C => ppu.bg[2].cnt.raw = value,
            0x0E => ppu.bg[3].cnt.raw = value,
            0x10 => ppu.bg[0].hofs.raw = value, // TODO: Don't write out every HOFS / VOFS?
            0x12 => ppu.bg[0].vofs.raw = value,
            0x14 => ppu.bg[1].hofs.raw = value,
            0x16 => ppu.bg[1].vofs.raw = value,
            0x18 => ppu.bg[2].hofs.raw = value,
            0x1A => ppu.bg[2].vofs.raw = value,
            0x1C => ppu.bg[3].hofs.raw = value,
            0x1E => ppu.bg[3].vofs.raw = value,
            0x20 => ppu.aff_bg[0].pa = @bitCast(i16, value),
            0x22 => ppu.aff_bg[0].pb = @bitCast(i16, value),
            0x24 => ppu.aff_bg[0].pc = @bitCast(i16, value),
            0x26 => ppu.aff_bg[0].pd = @bitCast(i16, value),
            0x28, 0x2A => ppu.aff_bg[0].x = @bitCast(i32, setHalf(u32, @bitCast(u32, ppu.aff_bg[0].x), byte_addr, value)),
            0x2C, 0x2E => ppu.aff_bg[0].y = @bitCast(i32, setHalf(u32, @bitCast(u32, ppu.aff_bg[0].y), byte_addr, value)),
            0x30 => ppu.aff_bg[1].pa = @bitCast(i16, value),
            0x32 => ppu.aff_bg[1].pb = @bitCast(i16, value),
            0x34 => ppu.aff_bg[1].pc = @bitCast(i16, value),
            0x36 => ppu.aff_bg[1].pd = @bitCast(i16, value),
            0x38, 0x3A => ppu.aff_bg[1].x = @bitCast(i32, setHalf(u32, @bitCast(u32, ppu.aff_bg[1].x), byte_addr, value)),
            0x3C, 0x3E => ppu.aff_bg[1].y = @bitCast(i32, setHalf(u32, @bitCast(u32, ppu.aff_bg[1].y), byte_addr, value)),
            0x40 => ppu.win.h[0].raw = value,
            0x42 => ppu.win.h[1].raw = value,
            0x44 => ppu.win.v[0].raw = value,
            0x46 => ppu.win.v[1].raw = value,
            0x48 => ppu.win.in.raw = value,
            0x4A => ppu.win.out.raw = value,
            0x4C => log.debug("Wrote 0x{X:0>4} to MOSAIC", .{value}),
            0x4E => {},
            0x50 => ppu.bld.cnt.raw = value,
            0x52 => ppu.bld.alpha.raw = value,
            0x54 => ppu.bld.y.raw = value,
            else => util.io.write.undef(log, "Tried to write 0x{X:0>4}{} to 0x{X:0>8}", .{ value, T, addr }),
        },
        u8 => switch (byte_addr) {
            0x00, 0x01 => ppu.dispcnt.raw = setHalf(u16, ppu.dispcnt.raw, byte_addr, value),
            0x02, 0x03 => {}, // Green Swap
            0x04, 0x05 => ppu.dispstat.set(setHalf(u16, ppu.dispstat.raw, byte_addr, value)),
            0x06, 0x07 => {}, // VCOUNT
            // BGXCNT
            0x08, 0x09 => ppu.bg[0].cnt.raw = setHalf(u16, ppu.bg[0].cnt.raw, byte_addr, value),
            0x0A, 0x0B => ppu.bg[1].cnt.raw = setHalf(u16, ppu.bg[1].cnt.raw, byte_addr, value),
            0x0C, 0x0D => ppu.bg[2].cnt.raw = setHalf(u16, ppu.bg[2].cnt.raw, byte_addr, value),
            0x0E, 0x0F => ppu.bg[3].cnt.raw = setHalf(u16, ppu.bg[3].cnt.raw, byte_addr, value),
            // BGX HOFS/VOFS
            0x10, 0x11 => ppu.bg[0].hofs.raw = setHalf(u16, ppu.bg[0].hofs.raw, byte_addr, value),
            0x12, 0x13 => ppu.bg[0].vofs.raw = setHalf(u16, ppu.bg[0].vofs.raw, byte_addr, value),
            0x14, 0x15 => ppu.bg[1].hofs.raw = setHalf(u16, ppu.bg[1].hofs.raw, byte_addr, value),
            0x16, 0x17 => ppu.bg[1].vofs.raw = setHalf(u16, ppu.bg[1].vofs.raw, byte_addr, value),
            0x18, 0x19 => ppu.bg[2].hofs.raw = setHalf(u16, ppu.bg[2].hofs.raw, byte_addr, value),
            0x1A, 0x1B => ppu.bg[2].vofs.raw = setHalf(u16, ppu.bg[2].vofs.raw, byte_addr, value),
            0x1C, 0x1D => ppu.bg[3].hofs.raw = setHalf(u16, ppu.bg[3].hofs.raw, byte_addr, value),
            0x1E, 0x1F => ppu.bg[3].vofs.raw = setHalf(u16, ppu.bg[3].vofs.raw, byte_addr, value),
            // BG2 Rot/Scaling
            0x20, 0x21 => ppu.aff_bg[0].pa = @bitCast(i16, setHalf(u16, @bitCast(u16, ppu.aff_bg[0].pa), byte_addr, value)),
            0x22, 0x23 => ppu.aff_bg[0].pb = @bitCast(i16, setHalf(u16, @bitCast(u16, ppu.aff_bg[0].pb), byte_addr, value)),
            0x24, 0x25 => ppu.aff_bg[0].pc = @bitCast(i16, setHalf(u16, @bitCast(u16, ppu.aff_bg[0].pc), byte_addr, value)),
            0x26, 0x27 => ppu.aff_bg[0].pd = @bitCast(i16, setHalf(u16, @bitCast(u16, ppu.aff_bg[0].pd), byte_addr, value)),
            0x28, 0x29, 0x2A, 0x2B => ppu.aff_bg[0].x = @bitCast(i32, setQuart(@bitCast(u32, ppu.aff_bg[0].x), byte_addr, value)),
            0x2C, 0x2D, 0x2E, 0x2F => ppu.aff_bg[0].y = @bitCast(i32, setQuart(@bitCast(u32, ppu.aff_bg[0].y), byte_addr, value)),
            // BG3 Rot/Scaling
            0x30, 0x31 => ppu.aff_bg[1].pa = @bitCast(i16, setHalf(u16, @bitCast(u16, ppu.aff_bg[1].pa), byte_addr, value)),
            0x32, 0x33 => ppu.aff_bg[1].pb = @bitCast(i16, setHalf(u16, @bitCast(u16, ppu.aff_bg[1].pb), byte_addr, value)),
            0x34, 0x35 => ppu.aff_bg[1].pc = @bitCast(i16, setHalf(u16, @bitCast(u16, ppu.aff_bg[1].pc), byte_addr, value)),
            0x36, 0x37 => ppu.aff_bg[1].pd = @bitCast(i16, setHalf(u16, @bitCast(u16, ppu.aff_bg[1].pd), byte_addr, value)),
            0x38, 0x39, 0x3A, 0x3B => ppu.aff_bg[1].x = @bitCast(i32, setQuart(@bitCast(u32, ppu.aff_bg[1].x), byte_addr, value)),
            0x3C, 0x3D, 0x3E, 0x3F => ppu.aff_bg[1].y = @bitCast(i32, setQuart(@bitCast(u32, ppu.aff_bg[1].y), byte_addr, value)),
            // Window
            0x40, 0x41 => ppu.win.h[0].raw = setHalf(u16, ppu.win.h[0].raw, byte_addr, value),
            0x42, 0x43 => ppu.win.h[1].raw = setHalf(u16, ppu.win.h[1].raw, byte_addr, value),
            0x44, 0x45 => ppu.win.v[0].raw = setHalf(u16, ppu.win.v[0].raw, byte_addr, value),
            0x46, 0x47 => ppu.win.v[1].raw = setHalf(u16, ppu.win.v[1].raw, byte_addr, value),
            0x48, 0x49 => ppu.win.in.raw = setHalf(u16, ppu.win.in.raw, byte_addr, value),
            0x4A, 0x4B => ppu.win.out.raw = setHalf(u16, ppu.win.out.raw, byte_addr, value),
            0x4C, 0x4D => log.debug("Wrote 0x{X:0>2} to MOSAIC", .{value}),
            0x4E, 0x4F => {},
            // Blending
            0x50, 0x51 => ppu.bld.cnt.raw = setHalf(u16, ppu.bld.cnt.raw, byte_addr, value),
            0x52, 0x53 => ppu.bld.alpha.raw = setHalf(u16, ppu.bld.alpha.raw, byte_addr, value),
            0x54, 0x55 => ppu.bld.y.raw = setHalf(u16, ppu.bld.y.raw, byte_addr, value),
            else => util.io.write.undef(log, "Tried to write 0x{X:0>2}{} to 0x{X:0>8}", .{ value, T, addr }),
        },
        else => @compileError("PPU: Unsupported write width"),
    }
 }
 pub const Ppu = struct {
    const Self = @This();
@@ -32,60 +246,55 @@ pub const Ppu = struct {
    dispstat: io.DisplayStatus,
    vcount: io.VCount,
-    bldcnt: io.BldCnt,
+    bld: Blend,
    bldalpha: io.BldAlpha,
    bldy: io.BldY,
    vram: Vram,
    palette: Palette,
    oam: Oam,
    sched: *Scheduler,
    framebuf: FrameBuffer,
-    alloc: Allocator,
+    allocator: Allocator,
-    scanline_sprites: [128]?Sprite,
+    scanline_sprites: *[128]?Sprite,
    scanline: Scanline,
-    pub fn init(alloc: Allocator, sched: *Scheduler) !Self {
+    pub fn init(allocator: Allocator, sched: *Scheduler) !Self {
        // Queue first Hblank
        sched.push(.Draw, 240 * 4);
-        const framebufs = try alloc.alloc(u8, (framebuf_pitch * height) * 2);
+        const sprites = try allocator.create([128]?Sprite);
-        std.mem.set(u8, framebufs, 0);
+        sprites.* = [_]?Sprite{null} ** 128;
        const scanline_buf = try alloc.alloc(?u16, width * 2);
        std.mem.set(?u16, scanline_buf, null);
        return Self{
-            .vram = try Vram.init(alloc),
+            .vram = try Vram.init(allocator),
-            .palette = try Palette.init(alloc),
+            .palette = try Palette.init(allocator),
-            .oam = try Oam.init(alloc),
+            .oam = try Oam.init(allocator),
            .sched = sched,
-            .framebuf = FrameBuffer.init(framebufs),
+            .framebuf = try FrameBuffer.init(allocator),
-            .alloc = alloc,
+            .allocator = allocator,
            // Registers
            .win = Window.init(),
            .bg = [_]Background{Background.init()} ** 4,
            .aff_bg = [_]AffineBackground{AffineBackground.init()} ** 2,
            .bld = Blend.create(),
            .dispcnt = .{ .raw = 0x0000 },
            .dispstat = .{ .raw = 0x0000 },
            .vcount = .{ .raw = 0x0000 },
            .bldcnt = .{ .raw = 0x0000 },
            .bldalpha = .{ .raw = 0x0000 },
            .bldy = .{ .raw = 0x0000 },
-            .scanline = Scanline.init(scanline_buf),
+            .scanline = try Scanline.init(allocator),
-            .scanline_sprites = [_]?Sprite{null} ** 128,
+            .scanline_sprites = sprites,
        };
    }
-    pub fn deinit(self: Self) void {
+    pub fn deinit(self: *Self) void {
-        self.framebuf.deinit(self.alloc);
+        self.allocator.destroy(self.scanline_sprites);
-        self.scanline.deinit(self.alloc);
+        self.framebuf.deinit();
        self.scanline.deinit();
        self.vram.deinit();
        self.palette.deinit();
        self.oam.deinit();
        self.* = undefined;
    }
    pub fn setBgOffsets(self: *Self, comptime n: u2, word: u32) void {
@@ -166,7 +375,7 @@ pub const Ppu = struct {
            const x = (sprite.x() +% i) % width;
            const ix = @bitCast(i9, x);
-            if (!shouldDrawSprite(self.bldcnt, &self.scanline, x)) continue;
+            if (!shouldDrawSprite(self.bld.cnt, &self.scanline, x)) continue;
            const sprite_start = sprite.x();
            const isprite_start = @bitCast(i9, sprite_start);
@@ -195,7 +404,7 @@ pub const Ppu = struct {
            // Sprite Palette starts at 0x0500_0200
            if (pal_id != 0) {
                const bgr555 = self.palette.read(u16, 0x200 + pal_id * 2);
-                copyToSpriteBuffer(self.bldcnt, &self.scanline, x, bgr555);
+                copyToSpriteBuffer(self.bld.cnt, &self.scanline, x, bgr555);
            }
        }
    }
@@ -216,7 +425,7 @@ pub const Ppu = struct {
            const x = (sprite.x() +% i) % width;
            const ix = @bitCast(i9, x);
-            if (!shouldDrawSprite(self.bldcnt, &self.scanline, x)) continue;
+            if (!shouldDrawSprite(self.bld.cnt, &self.scanline, x)) continue;
            const sprite_start = sprite.x();
            const isprite_start = @bitCast(i9, sprite_start);
@@ -251,7 +460,7 @@ pub const Ppu = struct {
            // Sprite Palette starts at 0x0500_0200
            if (pal_id != 0) {
                const bgr555 = self.palette.read(u16, 0x200 + pal_id * 2);
-                copyToSpriteBuffer(self.bldcnt, &self.scanline, x, bgr555);
+                copyToSpriteBuffer(self.bld.cnt, &self.scanline, x, bgr555);
            }
        }
    }
@@ -278,7 +487,7 @@ pub const Ppu = struct {
            aff_x += self.aff_bg[n - 2].pa;
            aff_y += self.aff_bg[n - 2].pc;
-            if (!shouldDrawBackground(n, self.bldcnt, &self.scanline, i)) continue;
+            if (!shouldDrawBackground(n, self.bld.cnt, &self.scanline, i)) continue;
            if (self.bg[n].cnt.display_overflow.read()) {
                ix = if (ix > px_width) @rem(ix, px_width) else if (ix < 0) px_width + @rem(ix, px_width) else ix;
@@ -297,7 +506,7 @@ pub const Ppu = struct {
            if (pal_id != 0) {
                const bgr555 = self.palette.read(u16, pal_id * 2);
-                copyToBackgroundBuffer(n, self.bldcnt, &self.scanline, i, bgr555);
+                copyToBackgroundBuffer(n, self.bld.cnt, &self.scanline, i, bgr555);
            }
        }
@@ -326,7 +535,7 @@ pub const Ppu = struct {
        var i: u32 = 0;
        while (i < width) : (i += 1) {
-            if (!shouldDrawBackground(n, self.bldcnt, &self.scanline, i)) continue;
+            if (!shouldDrawBackground(n, self.bld.cnt, &self.scanline, i)) continue;
            const x = hofs + i;
@@ -354,7 +563,7 @@ pub const Ppu = struct {
            if (pal_id != 0) {
                const bgr555 = self.palette.read(u16, pal_id * 2);
-                copyToBackgroundBuffer(n, self.bldcnt, &self.scanline, i, bgr555);
+                copyToBackgroundBuffer(n, self.bld.cnt, &self.scanline, i, bgr555);
            }
        }
    }
@@ -393,13 +602,13 @@ pub const Ppu = struct {
                    const maybe_btm = self.scanline.btm()[i];
                    const bgr555 = self.getBgr555(maybe_top, maybe_btm);
-                    std.mem.writeIntNative(u32, self.framebuf.get(.Emulator)[fb_base + i * @sizeOf(u32) ..][0..@sizeOf(u32)], COLOUR_LUT[bgr555 & 0x7FFF]);
+                    std.mem.writeIntNative(u32, self.framebuf.get(.Emulator)[fb_base + i * @sizeOf(u32) ..][0..@sizeOf(u32)], rgba888(bgr555));
                }
                // Reset Current Scanline Pixel Buffer and list of fetched sprites
                // in prep for next scanline
                self.scanline.reset();
-                std.mem.set(?Sprite, &self.scanline_sprites, null);
+                std.mem.set(?Sprite, self.scanline_sprites, null);
            },
            0x1 => {
                const fb_base = framebuf_pitch * @as(usize, scanline);
@@ -420,13 +629,13 @@ pub const Ppu = struct {
                    const maybe_btm = self.scanline.btm()[i];
                    const bgr555 = self.getBgr555(maybe_top, maybe_btm);
-                    std.mem.writeIntNative(u32, self.framebuf.get(.Emulator)[fb_base + i * @sizeOf(u32) ..][0..@sizeOf(u32)], COLOUR_LUT[bgr555 & 0x7FFF]);
+                    std.mem.writeIntNative(u32, self.framebuf.get(.Emulator)[fb_base + i * @sizeOf(u32) ..][0..@sizeOf(u32)], rgba888(bgr555));
                }
                // Reset Current Scanline Pixel Buffer and list of fetched sprites
                // in prep for next scanline
                self.scanline.reset();
-                std.mem.set(?Sprite, &self.scanline_sprites, null);
+                std.mem.set(?Sprite, self.scanline_sprites, null);
            },
            0x2 => {
                const fb_base = framebuf_pitch * @as(usize, scanline);
@@ -446,13 +655,13 @@ pub const Ppu = struct {
                    const maybe_btm = self.scanline.btm()[i];
                    const bgr555 = self.getBgr555(maybe_top, maybe_btm);
-                    std.mem.writeIntNative(u32, self.framebuf.get(.Emulator)[fb_base + i * @sizeOf(u32) ..][0..@sizeOf(u32)], COLOUR_LUT[bgr555 & 0x7FFF]);
+                    std.mem.writeIntNative(u32, self.framebuf.get(.Emulator)[fb_base + i * @sizeOf(u32) ..][0..@sizeOf(u32)], rgba888(bgr555));
                }
                // Reset Current Scanline Pixel Buffer and list of fetched sprites
                // in prep for next scanline
                self.scanline.reset();
-                std.mem.set(?Sprite, &self.scanline_sprites, null);
+                std.mem.set(?Sprite, self.scanline_sprites, null);
            },
            0x3 => {
                const vram_base = width * @sizeOf(u16) * @as(usize, scanline);
@@ -461,7 +670,7 @@ pub const Ppu = struct {
                var i: usize = 0;
                while (i < width) : (i += 1) {
                    const bgr555 = self.vram.read(u16, vram_base + i * @sizeOf(u16));
-                    std.mem.writeIntNative(u32, self.framebuf.get(.Emulator)[fb_base + i * @sizeOf(u32) ..][0..@sizeOf(u32)], COLOUR_LUT[bgr555 & 0x7FFF]);
+                    std.mem.writeIntNative(u32, self.framebuf.get(.Emulator)[fb_base + i * @sizeOf(u32) ..][0..@sizeOf(u32)], rgba888(bgr555));
                }
            },
            0x4 => {
@@ -472,7 +681,7 @@ pub const Ppu = struct {
                // Render Current Scanline
                for (self.vram.buf[vram_base .. vram_base + width]) |byte, i| {
                    const bgr555 = self.palette.read(u16, @as(u16, byte) * @sizeOf(u16));
-                    std.mem.writeIntNative(u32, self.framebuf.get(.Emulator)[fb_base + i * @sizeOf(u32) ..][0..@sizeOf(u32)], COLOUR_LUT[bgr555 & 0x7FFF]);
+                    std.mem.writeIntNative(u32, self.framebuf.get(.Emulator)[fb_base + i * @sizeOf(u32) ..][0..@sizeOf(u32)], rgba888(bgr555));
                }
            },
            0x5 => {
@@ -489,7 +698,7 @@ pub const Ppu = struct {
                    const bgr555 =
                        if (scanline < m5_height and i < m5_width) self.vram.read(u16, vram_base + i * @sizeOf(u16)) else self.palette.getBackdrop();
-                    std.mem.writeIntNative(u32, self.framebuf.get(.Emulator)[fb_base + i * @sizeOf(u32) ..][0..@sizeOf(u32)], COLOUR_LUT[bgr555 & 0x7FFF]);
+                    std.mem.writeIntNative(u32, self.framebuf.get(.Emulator)[fb_base + i * @sizeOf(u32) ..][0..@sizeOf(u32)], rgba888(bgr555));
                }
            },
            else => std.debug.panic("[PPU] TODO: Implement BG Mode {}", .{bg_mode}),
@@ -498,11 +707,11 @@ pub const Ppu = struct {
    fn getBgr555(self: *Self, maybe_top: ?u16, maybe_btm: ?u16) u16 {
        if (maybe_btm) |btm| {
-            return switch (self.bldcnt.mode.read()) {
+            return switch (self.bld.cnt.mode.read()) {
                0b00 => if (maybe_top) |top| top else btm,
-                0b01 => if (maybe_top) |top| alphaBlend(btm, top, self.bldalpha) else btm,
+                0b01 => if (maybe_top) |top| alphaBlend(btm, top, self.bld.alpha) else btm,
                0b10 => blk: {
-                    const evy: u16 = self.bldy.evy.read();
+                    const evy: u16 = self.bld.y.evy.read();
                    const r = btm & 0x1F;
                    const g = (btm >> 5) & 0x1F;
@@ -515,7 +724,7 @@ pub const Ppu = struct {
                    break :blk (bld_b << 10) | (bld_g << 5) | bld_r;
                },
                0b11 => blk: {
-                    const evy: u16 = self.bldy.evy.read();
+                    const evy: u16 = self.bld.y.evy.read();
                    const btm_r = btm & 0x1F;
                    const btm_g = (btm >> 5) & 0x1F;
@@ -563,7 +772,7 @@ pub const Ppu = struct {
        };
    }
-    pub fn handleHDrawEnd(self: *Self, cpu: *Arm7tdmi, late: u64) void {
+    pub fn onHdrawEnd(self: *Self, cpu: *Arm7tdmi, late: u64) void {
        // Transitioning to a Hblank
        if (self.dispstat.hblank_irq.read()) {
            cpu.bus.io.irq.hblank.set();
@@ -573,13 +782,13 @@ pub const Ppu = struct {
        // See if HBlank DMA is present and not enabled
        if (!self.dispstat.vblank.read())
-            pollBlankingDma(cpu.bus, .HBlank);
+            pollDmaOnBlank(cpu.bus, .HBlank);
        self.dispstat.hblank.set();
        self.sched.push(.HBlank, 68 * 4 -| late);
    }
-    pub fn handleHBlankEnd(self: *Self, cpu: *Arm7tdmi, late: u64) void {
+    pub fn onHblankEnd(self: *Self, cpu: *Arm7tdmi, late: u64) void {
        // The End of a Hblank (During Draw or Vblank)
        const old_scanline = self.vcount.scanline.read();
        const scanline = (old_scanline + 1) % 228;
@@ -615,7 +824,7 @@ pub const Ppu = struct {
                self.aff_bg[1].latchRefPoints();
                // See if Vblank DMA is present and not enabled
-                pollBlankingDma(cpu.bus, .VBlank);
+                pollDmaOnBlank(cpu.bus, .VBlank);
            }
            if (scanline == 227) self.dispstat.vblank.unset();
@@ -629,20 +838,21 @@ const Palette = struct {
    const Self = @This();
    buf: []u8,
-    alloc: Allocator,
+    allocator: Allocator,
-    fn init(alloc: Allocator) !Self {
+    fn init(allocator: Allocator) !Self {
-        const buf = try alloc.alloc(u8, palram_size);
+        const buf = try allocator.alloc(u8, palram_size);
        std.mem.set(u8, buf, 0);
        return Self{
            .buf = buf,
-            .alloc = alloc,
+            .allocator = allocator,
        };
    }
-    fn deinit(self: Self) void {
+    fn deinit(self: *Self) void {
-        self.alloc.free(self.buf);
+        self.allocator.free(self.buf);
        self.* = undefined;
    }
    pub fn read(self: *const Self, comptime T: type, address: usize) T {
@@ -672,25 +882,26 @@ const Palette = struct {
    }
 };
-const Vram = struct {
+pub const Vram = struct {
    const vram_size = 0x18000;
    const Self = @This();
    buf: []u8,
-    alloc: Allocator,
+    allocator: Allocator,
-    fn init(alloc: Allocator) !Self {
+    fn init(allocator: Allocator) !Self {
-        const buf = try alloc.alloc(u8, vram_size);
+        const buf = try allocator.alloc(u8, vram_size);
        std.mem.set(u8, buf, 0);
        return Self{
            .buf = buf,
-            .alloc = alloc,
+            .allocator = allocator,
        };
    }
-    fn deinit(self: Self) void {
+    fn deinit(self: *Self) void {
-        self.alloc.free(self.buf);
+        self.allocator.free(self.buf);
        self.* = undefined;
    }
    pub fn read(self: *const Self, comptime T: type, address: usize) T {
@@ -722,7 +933,7 @@ const Vram = struct {
        }
    }
-    fn mirror(address: usize) usize {
+    pub fn mirror(address: usize) usize {
        // Mirrored in steps of 128K (64K + 32K + 32K) (abcc)
        const addr = address & 0x1FFFF;
@@ -737,20 +948,21 @@ const Oam = struct {
    const Self = @This();
    buf: []u8,
-    alloc: Allocator,
+    allocator: Allocator,
-    fn init(alloc: Allocator) !Self {
+    fn init(allocator: Allocator) !Self {
-        const buf = try alloc.alloc(u8, oam_size);
+        const buf = try allocator.alloc(u8, oam_size);
        std.mem.set(u8, buf, 0);
        return Self{
            .buf = buf,
-            .alloc = alloc,
+            .allocator = allocator,
        };
    }
-    fn deinit(self: Self) void {
+    fn deinit(self: *Self) void {
-        self.alloc.free(self.buf);
+        self.allocator.free(self.buf);
        self.* = undefined;
    }
    pub fn read(self: *const Self, comptime T: type, address: usize) T {
@@ -773,6 +985,30 @@ const Oam = struct {
    }
 };
 const Blend = struct {
    const Self = @This();
    cnt: io.BldCnt,
    alpha: io.BldAlpha,
    y: io.BldY,
    pub fn create() Self {
        return .{
            .cnt = .{ .raw = 0x000 },
            .alpha = .{ .raw = 0x000 },
            .y = .{ .raw = 0x000 },
        };
    }
    pub fn getCnt(self: *const Self) u16 {
        return self.cnt.raw & 0x3FFF;
    }
    pub fn getAlpha(self: *const Self) u16 {
        return self.alpha.raw & 0x1F1F;
    }
 };
 const Window = struct {
    const Self = @This();
@@ -792,6 +1028,14 @@ const Window = struct {
        };
    }
    pub fn getIn(self: *const Self) u16 {
        return self.in.raw & 0x3F3F;
    }
    pub fn getOut(self: *const Self) u16 {
        return self.out.raw & 0x3F3F;
    }
    pub fn setH(self: *Self, value: u32) void {
        self.h[0].raw = @truncate(u16, value);
        self.h[1].raw = @truncate(u16, value >> 16);
@@ -806,18 +1050,6 @@ const Window = struct {
        self.in.raw = @truncate(u16, value);
        self.out.raw = @truncate(u16, value >> 16);
    }
    pub fn setInL(self: *Self, value: u8) void {
        self.in.raw = (self.in.raw & 0xFF00) | value;
    }
    pub fn setInH(self: *Self, value: u8) void {
        self.in.raw = (self.in.raw & 0x00FF) | (@as(u16, value) << 8);
    }
    pub fn setOutL(self: *Self, value: u8) void {
        self.out.raw = (self.out.raw & 0xFF00) | value;
    }
 };
 const Background = struct {
@@ -837,6 +1069,17 @@ const Background = struct {
            .vofs = .{ .raw = 0x0000 },
        };
    }
    /// For whatever reason, some higher bits of BG0CNT
    /// are masked out
    pub inline fn bg0Cnt(self: *const Self) u16 {
        return self.cnt.raw & 0xDFFF;
    }
    /// BG1CNT inherits the same mask as BG0CNTs
    pub inline fn bg1Cnt(self: *const Self) u16 {
        return self.bg0Cnt();
    }
 };
 const AffineBackground = struct {
@@ -1073,7 +1316,7 @@ fn spriteDimensions(shape: u2, size: u2) [2]u8 {
    };
 }
-fn toRgba8888(bgr555: u16) u32 {
+inline fn rgba888(bgr555: u16) u32 {
    const b = @as(u32, bgr555 >> 10 & 0x1F);
    const g = @as(u32, bgr555 >> 5 & 0x1F);
    const r = @as(u32, bgr555 & 0x1F);
@@ -1081,39 +1324,6 @@ fn toRgba8888(bgr555: u16) u32 {
    return (r << 3 | r >> 2) << 24 | (g << 3 | g >> 2) << 16 | (b << 3 | b >> 2) << 8 | 0xFF;
 }
 fn genColourLut() [0x8000]u32 {
    return comptime {
        @setEvalBranchQuota(0x10001);
        var lut: [0x8000]u32 = undefined;
        for (lut) |*px, i| px.* = toRgba8888(i);
        return lut;
    };
 }
 // FIXME: The implementation is incorrect and using it in the LUT crashes the compiler (OOM)
 /// Implementation courtesy of byuu and Talarubi at https://near.sh/articles/video/color-emulation
 fn toRgba8888Talarubi(bgr555: u16) u32 {
    @setRuntimeSafety(false);
    const lcd_gamma: f64 = 4;
    const out_gamma: f64 = 2.2;
    const b = @as(u32, bgr555 >> 10 & 0x1F);
    const g = @as(u32, bgr555 >> 5 & 0x1F);
    const r = @as(u32, bgr555 & 0x1F);
    const lb = std.math.pow(f64, @intToFloat(f64, b << 3 | b >> 2) / 31, lcd_gamma);
    const lg = std.math.pow(f64, @intToFloat(f64, g << 3 | g >> 2) / 31, lcd_gamma);
    const lr = std.math.pow(f64, @intToFloat(f64, r << 3 | r >> 2) / 31, lcd_gamma);
    const out_b = std.math.pow(f64, (220 * lb + 10 * lg + 50 * lr) / 255, 1 / out_gamma);
    const out_g = std.math.pow(f64, (30 * lb + 230 * lg + 10 * lr) / 255, 1 / out_gamma);
    const out_r = std.math.pow(f64, (0 * lb + 50 * lg + 255 * lr) / 255, 1 / out_gamma);
    return @floatToInt(u32, out_r) << 24 | @floatToInt(u32, out_g) << 16 | @floatToInt(u32, out_b) << 8 | 0xFF;
 }
 fn alphaBlend(top: u16, btm: u16, bldalpha: io.BldAlpha) u16 {
    const eva: u16 = bldalpha.eva.read();
    const evb: u16 = bldalpha.evb.read();
@@ -1213,35 +1423,38 @@ fn copyToSpriteBuffer(bldcnt: io.BldCnt, scanline: *Scanline, x: u9, bgr555: u16
 const Scanline = struct {
    const Self = @This();
-    buf: [2][]?u16,
+    layers: [2][]?u16,
-    original: []?u16,
+    buf: []?u16,
-    fn init(buf: []?u16) Self {
+    allocator: Allocator,
        std.debug.assert(buf.len == width * 2);
-        const top_slice = buf[0..][0..width];
+    fn init(allocator: Allocator) !Self {
-        const btm_slice = buf[width..][0..width];
+        const buf = try allocator.alloc(?u16, width * 2); // Top & Bottom Scanline
        std.mem.set(?u16, buf, null);
        return .{
-            .buf = [_][]?u16{ top_slice, btm_slice },
+            // Top & Bototm Layers
-            .original = buf,
+            .layers = [_][]?u16{ buf[0..][0..width], buf[width..][0..width] },
            .buf = buf,
            .allocator = allocator,
        };
    }
    fn reset(self: *Self) void {
-        std.mem.set(?u16, self.original, null);
+        std.mem.set(?u16, self.buf, null);
    }
-    fn deinit(self: Self, alloc: Allocator) void {
+    fn deinit(self: *Self) void {
-        alloc.free(self.original);
+        self.allocator.free(self.buf);
        self.* = undefined;
    }
    fn top(self: *Self) []?u16 {
-        return self.buf[0];
+        return self.layers[0];
    }
    fn btm(self: *Self) []?u16 {
-        return self.buf[1];
+        return self.layers[1];
    }
 };
@@ -1249,9 +1462,11 @@ const Scanline = struct {
 const FrameBuffer = struct {
    const Self = @This();
-    buf: [2][]u8,
+    layers: [2][]u8,
-    original: []u8,
+    buf: []u8,
-    current: u1,
+    current: std.atomic.Atomic(u8),
    allocator: Allocator,
    // TODO: Rename
    const Device = enum {
@@ -1259,28 +1474,33 @@ const FrameBuffer = struct {
        Renderer,
    };
-    pub fn init(bufs: []u8) Self {
+    pub fn init(allocator: Allocator) !Self {
-        std.debug.assert(bufs.len == framebuf_pitch * height * 2);
+        const framebuf_len = framebuf_pitch * height;
-
+        const buf = try allocator.alloc(u8, framebuf_len * 2);
-        const front = bufs[0 .. framebuf_pitch * height];
+        std.mem.set(u8, buf, 0);
        const back = bufs[framebuf_pitch * height ..];
        return .{
-            .buf = [2][]u8{ front, back },
+            // Front and Back Framebuffers
-            .original = bufs,
+            .layers = [_][]u8{ buf[0..][0..framebuf_len], buf[framebuf_len..][0..framebuf_len] },
-            .current = 0,
+            .buf = buf,
            .current = std.atomic.Atomic(u8).init(0),
            .allocator = allocator,
        };
    }
-    fn deinit(self: Self, alloc: Allocator) void {
+    fn deinit(self: *Self) void {
-        alloc.free(self.original);
+        self.allocator.free(self.buf);
        self.* = undefined;
    }
    pub fn swap(self: *Self) void {
-        self.current = ~self.current;
+        _ = self.current.fetchXor(1, .Release); // fetchNot(.Release)
    }
    pub fn get(self: *Self, comptime dev: Device) []u8 {
-        return self.buf[if (dev == .Emulator) self.current else ~self.current];
+        const current = @intCast(u1, self.current.load(.Acquire));
        return self.layers[if (dev == .Emulator) current else ~current];
    }
 };
--- a/src/core/scheduler.zig
+++ b/src/core/scheduler.zig
@@ -1,7 +1,7 @@
 const std = @import("std");
 const Bus = @import("Bus.zig");
 const Arm7tdmi = @import("cpu.zig").Arm7tdmi;
 const Clock = @import("bus/gpio.zig").Clock;
 const Order = std.math.Order;
 const PriorityQueue = std.PriorityQueue;
@@ -14,15 +14,16 @@ pub const Scheduler = struct {
    tick: u64,
    queue: PriorityQueue(Event, void, lessThan),
-    pub fn init(alloc: Allocator) Self {
+    pub fn init(allocator: Allocator) Self {
-        var sched = Self{ .tick = 0, .queue = PriorityQueue(Event, void, lessThan).init(alloc, {}) };
+        var sched = Self{ .tick = 0, .queue = PriorityQueue(Event, void, lessThan).init(allocator, {}) };
        sched.queue.add(.{ .kind = .HeatDeath, .tick = std.math.maxInt(u64) }) catch unreachable;
        return sched;
    }
-    pub fn deinit(self: Self) void {
+    pub fn deinit(self: *Self) void {
        self.queue.deinit();
        self.* = undefined;
    }
    pub inline fn now(self: *const Self) u64 {
@@ -41,28 +42,32 @@ pub const Scheduler = struct {
                .Draw => {
                    // The end of a VDraw
                    cpu.bus.ppu.drawScanline();
-                    cpu.bus.ppu.handleHDrawEnd(cpu, late);
+                    cpu.bus.ppu.onHdrawEnd(cpu, late);
                },
                .TimerOverflow => |id| {
                    switch (id) {
-                        0 => cpu.bus.tim[0].handleOverflow(cpu, late),
+                        inline 0...3 => |idx| cpu.bus.tim[idx].onTimerExpire(cpu, late),
                        1 => cpu.bus.tim[1].handleOverflow(cpu, late),
                        2 => cpu.bus.tim[2].handleOverflow(cpu, late),
                        3 => cpu.bus.tim[3].handleOverflow(cpu, late),
                    }
                },
                .ApuChannel => |id| {
                    switch (id) {
-                        0 => cpu.bus.apu.ch1.channelTimerOverflow(late),
+                        0 => cpu.bus.apu.ch1.onToneSweepEvent(late),
-                        1 => cpu.bus.apu.ch2.channelTimerOverflow(late),
+                        1 => cpu.bus.apu.ch2.onToneEvent(late),
-                        2 => cpu.bus.apu.ch3.channelTimerOverflow(late),
+                        2 => cpu.bus.apu.ch3.onWaveEvent(late),
-                        3 => cpu.bus.apu.ch4.channelTimerOverflow(late),
+                        3 => cpu.bus.apu.ch4.onNoiseEvent(late),
                    }
                },
-                .FrameSequencer => cpu.bus.apu.tickFrameSequencer(late),
+                .RealTimeClock => {
                    const device = &cpu.bus.pak.gpio.device;
                    if (device.kind != .Rtc or device.ptr == null) return;
                    const clock = @ptrCast(*Clock, @alignCast(@alignOf(*Clock), device.ptr.?));
                    clock.onClockUpdate(late);
                },
                .FrameSequencer => cpu.bus.apu.onSequencerTick(late),
                .SampleAudio => cpu.bus.apu.sampleAudio(late),
-                .HBlank => cpu.bus.ppu.handleHBlankEnd(cpu, late), // The end of a HBlank
+                .HBlank => cpu.bus.ppu.onHblankEnd(cpu, late), // The end of a HBlank
-                .VBlank => cpu.bus.ppu.handleHDrawEnd(cpu, late), // The end of a VBlank
+                .VBlank => cpu.bus.ppu.onHdrawEnd(cpu, late), // The end of a VBlank
            }
        }
    }
@@ -117,4 +122,5 @@ pub const EventKind = union(enum) {
    SampleAudio,
    FrameSequencer,
    ApuChannel: u2,
    RealTimeClock,
 };
--- a/src/core/util.zig
+++ b/src/core/util.zig
@@ -1,176 +0,0 @@
 const std = @import("std");
 const builtin = @import("builtin");
 const Log2Int = std.math.Log2Int;
 const Arm7tdmi = @import("cpu.zig").Arm7tdmi;
 // Sign-Extend value of type `T` to type `U`
 pub fn sext(comptime T: type, comptime U: type, value: T) T {
    // U must have less bits than T
    comptime std.debug.assert(@typeInfo(U).Int.bits <= @typeInfo(T).Int.bits);
    const iT = std.meta.Int(.signed, @typeInfo(T).Int.bits);
    const ExtU = if (@typeInfo(U).Int.signedness == .unsigned) T else iT;
    const shift = @intCast(Log2Int(T), @typeInfo(T).Int.bits - @typeInfo(U).Int.bits);
    return @bitCast(T, @bitCast(iT, @as(ExtU, @truncate(U, value)) << shift) >> shift);
 }
 /// See https://godbolt.org/z/W3en9Eche
 pub inline fn rotr(comptime T: type, x: T, r: anytype) T {
    if (@typeInfo(T).Int.signedness == .signed)
        @compileError("cannot rotate signed integer");
    const ar = @intCast(Log2Int(T), @mod(r, @typeInfo(T).Int.bits));
    return x >> ar | x << (1 +% ~ar);
 }
 pub const FpsTracker = struct {
    const Self = @This();
    fps: u32,
    count: std.atomic.Atomic(u32),
    timer: std.time.Timer,
    pub fn init() Self {
        return .{
            .fps = 0,
            .count = std.atomic.Atomic(u32).init(0),
            .timer = std.time.Timer.start() catch unreachable,
        };
    }
    pub fn tick(self: *Self) void {
        _ = self.count.fetchAdd(1, .Monotonic);
    }
    pub fn value(self: *Self) u32 {
        if (self.timer.read() >= std.time.ns_per_s) {
            self.fps = self.count.swap(0, .SeqCst);
            self.timer.reset();
        }
        return self.fps;
    }
 };
 pub fn intToBytes(comptime T: type, value: anytype) [@sizeOf(T)]u8 {
    comptime std.debug.assert(@typeInfo(T) == .Int);
    var result: [@sizeOf(T)]u8 = undefined;
    var i: Log2Int(T) = 0;
    while (i < result.len) : (i += 1) result[i] = @truncate(u8, value >> i * @bitSizeOf(u8));
    return result;
 }
 /// The Title from the GBA Cartridge may be null padded to a maximum
 /// length of 12 bytes.
 ///
 /// This function returns a slice of everything just before the first
 /// `\0`
 pub fn asString(title: [12]u8) []const u8 {
    var len = title.len;
    for (title) |char, i| {
        if (char == 0) {
            len = i;
            break;
        }
    }
    return title[0..len];
 }
 /// Copies a Title and returns either an identical or similar
 /// array consisting of ASCII that won't make any file system angry
 ///
 /// e.g. POKEPIN R/S to POKEPIN R_S
 pub fn escape(title: [12]u8) [12]u8 {
    var result: [12]u8 = title;
    for (result) |*char| {
        if (char.* == '/' or char.* == '\\') char.* = '_';
        if (char.* == 0) break;
    }
    return result;
 }
 pub const FilePaths = struct {
    rom: []const u8,
    bios: ?[]const u8,
    save: ?[]const u8,
 };
 pub fn readUndefined(log: anytype, comptime format: []const u8, args: anytype) u8 {
    log.warn(format, args);
    if (builtin.mode == .Debug) std.debug.panic("TODO: Implement I/O Register", .{});
    return 0;
 }
 pub fn writeUndefined(log: anytype, comptime format: []const u8, args: anytype) void {
    log.warn(format, args);
    if (builtin.mode == .Debug) std.debug.panic("TODO: Implement I/O Register", .{});
 }
 pub const Logger = struct {
    const Self = @This();
    buf: std.io.BufferedWriter(4096 << 2, std.fs.File.Writer),
    pub fn init(file: std.fs.File) Self {
        return .{
            .buf = .{ .unbuffered_writer = file.writer() },
        };
    }
    pub fn print(self: *Self, comptime format: []const u8, args: anytype) !void {
        try self.buf.writer().print(format, args);
    }
    pub fn mgbaLog(self: *Self, arm7tdmi: *const Arm7tdmi, opcode: u32) void {
        const fmt_base = "{X:0>8} {X:0>8} {X:0>8} {X:0>8} {X:0>8} {X:0>8} {X:0>8} {X:0>8} {X:0>8} {X:0>8} {X:0>8} {X:0>8} {X:0>8} {X:0>8} {X:0>8} {X:0>8} cpsr: {X:0>8} | ";
        const thumb_fmt = fmt_base ++ "{X:0>4}:\n";
        const arm_fmt = fmt_base ++ "{X:0>8}:\n";
        if (arm7tdmi.cpsr.t.read()) {
            if (opcode >> 11 == 0x1E) {
                // Instruction 1 of a BL Opcode, print in ARM mode
                const low = arm7tdmi.bus.dbgRead(u16, arm7tdmi.r[15]);
                const bl_opcode = @as(u32, opcode) << 16 | low;
                self.print(arm_fmt, Self.fmtArgs(arm7tdmi, bl_opcode)) catch @panic("failed to write to log file");
            } else {
                self.print(thumb_fmt, Self.fmtArgs(arm7tdmi, opcode)) catch @panic("failed to write to log file");
            }
        } else {
            self.print(arm_fmt, Self.fmtArgs(arm7tdmi, opcode)) catch @panic("failed to write to log file");
        }
    }
    fn fmtArgs(arm7tdmi: *const Arm7tdmi, opcode: u32) FmtArgTuple {
        return .{
            arm7tdmi.r[0],
            arm7tdmi.r[1],
            arm7tdmi.r[2],
            arm7tdmi.r[3],
            arm7tdmi.r[4],
            arm7tdmi.r[5],
            arm7tdmi.r[6],
            arm7tdmi.r[7],
            arm7tdmi.r[8],
            arm7tdmi.r[9],
            arm7tdmi.r[10],
            arm7tdmi.r[11],
            arm7tdmi.r[12],
            arm7tdmi.r[13],
            arm7tdmi.r[14],
            arm7tdmi.r[15],
            arm7tdmi.cpsr.raw,
            opcode,
        };
    }
 };
 const FmtArgTuple = std.meta.Tuple(&.{ u32, u32, u32, u32, u32, u32, u32, u32, u32, u32, u32, u32, u32, u32, u32, u32, u32, u32 });
--- a/src/main.zig
+++ b/src/main.zig
@@ -1,105 +1,160 @@
 const std = @import("std");
 const builtin = @import("builtin");
 const known_folders = @import("known_folders");
 const clap = @import("clap");
-const Gui = @import("Gui.zig");
+const config = @import("config.zig");
 const Gui = @import("platform.zig").Gui;
 const Bus = @import("core/Bus.zig");
 const Arm7tdmi = @import("core/cpu.zig").Arm7tdmi;
 const Scheduler = @import("core/scheduler.zig").Scheduler;
-const FilePaths = @import("core/util.zig").FilePaths;
+const FilePaths = @import("util.zig").FilePaths;
 const Allocator = std.mem.Allocator;
-const log = std.log.scoped(.CLI);
+const log = std.log.scoped(.Cli);
 const width = @import("core/ppu.zig").width;
 const height = @import("core/ppu.zig").height;
 const arm7tdmi_logging = @import("core/emu.zig").cpu_logging;
 pub const log_level = if (builtin.mode != .Debug) .info else std.log.default_level;
 // TODO: Reimpl Logging
 // CLI Arguments + Help Text
 const params = clap.parseParamsComptime(
    \\-h, --help            Display this help and exit.
    \\-s, --skip            Skip BIOS.
    \\-b, --bios <str>      Optional path to a GBA BIOS ROM.
-    \\<str>                 Path to the GBA GamePak ROM
+    \\<str>                 Path to the GBA GamePak ROM.
    \\
 );
-pub fn main() anyerror!void {
+pub fn main() void {
    // Main Allocator for ZBA
    var gpa = std.heap.GeneralPurposeAllocator(.{}){};
    defer std.debug.assert(!gpa.deinit());
    const allocator = gpa.allocator();
-    // Handle CLI Input
+    // Determine the Data Directory (stores saves)
-    const result = try clap.parse(clap.Help, &params, clap.parsers.default, .{});
+    const data_path = blk: {
        const result = known_folders.getPath(allocator, .data);
        const option = result catch |e| exitln("interrupted while determining the data folder: {}", .{e});
        const path = option orelse exitln("no valid data folder found", .{});
        ensureDataDirsExist(path) catch |e| exitln("failed to create folders under \"{s}\": {}", .{ path, e });
        break :blk path;
    };
    defer allocator.free(data_path);
    // Determine the Config Directory
    const config_path = blk: {
        const result = known_folders.getPath(allocator, .roaming_configuration);
        const option = result catch |e| exitln("interreupted while determining the config folder: {}", .{e});
        const path = option orelse exitln("no valid config folder found", .{});
        ensureConfigDirExists(path) catch |e| exitln("failed to create required folder \"{s}\": {}", .{ path, e });
        break :blk path;
    };
    defer allocator.free(config_path);
    // Parse CLI
    const result = clap.parse(clap.Help, &params, clap.parsers.default, .{}) catch |e| exitln("failed to parse cli: {}", .{e});
    defer result.deinit();
-    const paths = try handleArguments(allocator, &result);
+    // TODO: Move config file to XDG Config directory?
    const cfg_file_path = configFilePath(allocator, config_path) catch |e| exitln("failed to ready config file for access: {}", .{e});
    defer allocator.free(cfg_file_path);
    config.load(allocator, cfg_file_path) catch |e| exitln("failed to load config file: {}", .{e});
    const paths = handleArguments(allocator, data_path, &result) catch |e| exitln("failed to handle cli arguments: {}", .{e});
    defer if (paths.save) |path| allocator.free(path);
    const log_file = if (config.config().debug.cpu_trace) blk: {
        break :blk std.fs.cwd().createFile("zba.log", .{}) catch |e| exitln("failed to create trace log file: {}", .{e});
    } else null;
    defer if (log_file) |file| file.close();
    // TODO: Take Emulator Init Code out of main.zig
    var scheduler = Scheduler.init(allocator);
    defer scheduler.deinit();
-    var bus = try Bus.init(allocator, &scheduler, paths);
+    var bus: Bus = undefined;
    var cpu = Arm7tdmi.init(&scheduler, &bus, log_file);
    bus.init(allocator, &scheduler, &cpu, paths) catch |e| exitln("failed to init zba bus: {}", .{e});
    defer bus.deinit();
-    var arm7tdmi = Arm7tdmi.init(&scheduler, &bus);
+    if (config.config().guest.skip_bios or result.args.skip or paths.bios == null) {
-
+        cpu.fastBoot();
    const log_file: ?std.fs.File = if (arm7tdmi_logging) try std.fs.cwd().createFile("zba.log", .{}) else null;
    defer if (log_file) |file| file.close();
    if (log_file) |file| arm7tdmi.attach(file);
    bus.attach(&arm7tdmi); // TODO: Shrink Surface (only CPSR and  r15?)
    if (paths.bios == null) arm7tdmi.fastBoot();
    var gui = Gui.init(bus.pak.title, width, height);
    gui.initAudio(&bus.apu);
    defer gui.deinit();
    try gui.run(&arm7tdmi, &scheduler);
 }
 fn getSavePath(allocator: Allocator) !?[]const u8 {
    const save_subpath = "zba" ++ [_]u8{std.fs.path.sep} ++ "save";
    const maybe_data_path = try known_folders.getPath(allocator, .data);
    defer if (maybe_data_path) |path| allocator.free(path);
    const save_path = if (maybe_data_path) |base| try std.fs.path.join(allocator, &[_][]const u8{ base, "zba", "save" }) else null;
    if (save_path) |_| {
        // If we've determined what our save path should be, ensure the prereq directories
        // are present so that we can successfully write to the path when necessary
        const maybe_data_dir = try known_folders.open(allocator, .data, .{});
        if (maybe_data_dir) |data_dir| try data_dir.makePath(save_subpath);
    }
-    return save_path;
+    var gui = Gui.init(&bus.pak.title, &bus.apu, width, height) catch |e| exitln("failed to init gui: {}", .{e});
    defer gui.deinit();
    gui.run(&cpu, &scheduler) catch |e| exitln("failed to run gui thread: {}", .{e});
 }
-fn getRomPath(result: *const clap.Result(clap.Help, &params, clap.parsers.default)) ![]const u8 {
+pub fn handleArguments(allocator: Allocator, data_path: []const u8, result: *const clap.Result(clap.Help, &params, clap.parsers.default)) !FilePaths {
-    return switch (result.positionals.len) {
+    const rom_path = romPath(result);
        1 => result.positionals[0],
        0 => std.debug.panic("ZBA requires a positional path to a GamePak ROM.\n", .{}),
        else => std.debug.panic("ZBA received too many arguments.\n", .{}),
    };
 }
 pub fn handleArguments(allocator: Allocator, result: *const clap.Result(clap.Help, &params, clap.parsers.default)) !FilePaths {
    const rom_path = try getRomPath(result);
    log.info("ROM path: {s}", .{rom_path});
    const bios_path = result.args.bios;
    if (bios_path) |path| log.info("BIOS path: {s}", .{path}) else log.info("No BIOS provided", .{});
    const save_path = try getSavePath(allocator);
    if (save_path) |path| log.info("Save path: {s}", .{path});
-    return FilePaths{
+    const bios_path = result.args.bios;
    if (bios_path) |path| log.info("BIOS path: {s}", .{path}) else log.warn("No BIOS provided", .{});
    const save_path = try std.fs.path.join(allocator, &[_][]const u8{ data_path, "zba", "save" });
    log.info("Save path: {s}", .{save_path});
    return .{
        .rom = rom_path,
        .bios = bios_path,
        .save = save_path,
    };
 }
 fn configFilePath(allocator: Allocator, config_path: []const u8) ![]const u8 {
    const path = try std.fs.path.join(allocator, &[_][]const u8{ config_path, "zba", "config.toml" });
    errdefer allocator.free(path);
    // We try to create the file exclusively, meaning that we err out if the file already exists.
    // All we care about is a file being there so we can just ignore that error in particular and
    // continue down the happy pathj
    std.fs.accessAbsolute(path, .{}) catch |e| {
        if (e != error.FileNotFound) return e;
        const config_file = std.fs.createFileAbsolute(path, .{}) catch |err| exitln("failed to create \"{s}\": {}", .{ path, err });
        defer config_file.close();
        try config_file.writeAll(@embedFile("../example.toml"));
    };
    return path;
 }
 fn ensureDataDirsExist(data_path: []const u8) !void {
    var dir = try std.fs.openDirAbsolute(data_path, .{});
    defer dir.close();
    // Will recursively create directories
    try dir.makePath("zba" ++ std.fs.path.sep_str ++ "save");
 }
 fn ensureConfigDirExists(config_path: []const u8) !void {
    var dir = try std.fs.openDirAbsolute(config_path, .{});
    defer dir.close();
    try dir.makePath("zba");
 }
 fn romPath(result: *const clap.Result(clap.Help, &params, clap.parsers.default)) []const u8 {
    return switch (result.positionals.len) {
        1 => result.positionals[0],
        0 => exitln("ZBA requires a path to a GamePak ROM", .{}),
        else => exitln("ZBA received too many positional arguments.", .{}),
    };
 }
 fn exitln(comptime format: []const u8, args: anytype) noreturn {
    const stderr = std.io.getStdErr().writer();
    stderr.print(format, args) catch {}; // Just exit already...
    stderr.writeByte('\n') catch {};
    std.os.exit(1);
 }
--- a/src/platform.zig
+++ b/src/platform.zig
@@ -0,0 +1,339 @@
 const std = @import("std");
 const SDL = @import("sdl2");
 const gl = @import("gl");
 const emu = @import("core/emu.zig");
 const config = @import("config.zig");
 const Apu = @import("core/apu.zig").Apu;
 const Arm7tdmi = @import("core/cpu.zig").Arm7tdmi;
 const Scheduler = @import("core/scheduler.zig").Scheduler;
 const FpsTracker = @import("util.zig").FpsTracker;
 const gba_width = @import("core/ppu.zig").width;
 const gba_height = @import("core/ppu.zig").height;
 pub const sample_rate = 1 << 16;
 pub const sample_format = SDL.AUDIO_U16;
 const default_title = "ZBA";
 pub const Gui = struct {
    const Self = @This();
    const SDL_GLContext = *anyopaque; // SDL.SDL_GLContext is a ?*anyopaque
    const log = std.log.scoped(.Gui);
    // zig fmt: off
    const vertices: [32]f32 = [_]f32{
        // Positions        // Colours      // Texture Coords
         1.0, -1.0, 0.0,    1.0, 0.0, 0.0,  1.0, 1.0, // Top Right
         1.0,  1.0, 0.0,    0.0, 1.0, 0.0,  1.0, 0.0, // Bottom Right
        -1.0,  1.0, 0.0,    0.0, 0.0, 1.0,  0.0, 0.0, // Bottom Left
        -1.0, -1.0, 0.0,    1.0, 1.0, 0.0,  0.0, 1.0, // Top Left
    };
    const indices: [6]u32 = [_]u32{
        0, 1, 3, // First Triangle
        1, 2, 3, // Second Triangle
    };
    // zig fmt: on
    window: *SDL.SDL_Window,
    ctx: SDL_GLContext,
    title: []const u8,
    audio: Audio,
    program_id: gl.GLuint,
    pub fn init(title: *const [12]u8, apu: *Apu, width: i32, height: i32) !Self {
        if (SDL.SDL_Init(SDL.SDL_INIT_VIDEO | SDL.SDL_INIT_EVENTS | SDL.SDL_INIT_AUDIO) < 0) panic();
        if (SDL.SDL_GL_SetAttribute(SDL.SDL_GL_CONTEXT_PROFILE_MASK, SDL.SDL_GL_CONTEXT_PROFILE_CORE) < 0) panic();
        if (SDL.SDL_GL_SetAttribute(SDL.SDL_GL_CONTEXT_MAJOR_VERSION, 3) < 0) panic();
        if (SDL.SDL_GL_SetAttribute(SDL.SDL_GL_CONTEXT_MAJOR_VERSION, 3) < 0) panic();
        const win_scale = @intCast(c_int, config.config().host.win_scale);
        const window = SDL.SDL_CreateWindow(
            default_title,
            SDL.SDL_WINDOWPOS_CENTERED,
            SDL.SDL_WINDOWPOS_CENTERED,
            @as(c_int, width * win_scale),
            @as(c_int, height * win_scale),
            SDL.SDL_WINDOW_OPENGL | SDL.SDL_WINDOW_SHOWN,
        ) orelse panic();
        const ctx = SDL.SDL_GL_CreateContext(window) orelse panic();
        if (SDL.SDL_GL_MakeCurrent(window, ctx) < 0) panic();
        try gl.load(ctx, Self.glGetProcAddress);
        if (SDL.SDL_GL_SetSwapInterval(@boolToInt(config.config().host.vsync)) < 0) panic();
        const program_id = try compileShaders();
        return Self{
            .window = window,
            .title = std.mem.sliceTo(title, 0),
            .ctx = ctx,
            .program_id = program_id,
            .audio = Audio.init(apu),
        };
    }
    fn compileShaders() !gl.GLuint {
        // TODO: Panic on Shader Compiler Failure + Error Message
        const vert_shader = @embedFile("shader/pixelbuf.vert");
        const frag_shader = @embedFile("shader/pixelbuf.frag");
        const vs = gl.createShader(gl.VERTEX_SHADER);
        defer gl.deleteShader(vs);
        gl.shaderSource(vs, 1, &[_][*c]const u8{vert_shader}, 0);
        gl.compileShader(vs);
        if (!shader.didCompile(vs)) return error.VertexCompileError;
        const fs = gl.createShader(gl.FRAGMENT_SHADER);
        defer gl.deleteShader(fs);
        gl.shaderSource(fs, 1, &[_][*c]const u8{frag_shader}, 0);
        gl.compileShader(fs);
        if (!shader.didCompile(fs)) return error.FragmentCompileError;
        const program = gl.createProgram();
        gl.attachShader(program, vs);
        gl.attachShader(program, fs);
        gl.linkProgram(program);
        return program;
    }
    // Returns the VAO ID since it's used in run()
    fn generateBuffers() struct { c_uint, c_uint, c_uint } {
        var vao_id: c_uint = undefined;
        var vbo_id: c_uint = undefined;
        var ebo_id: c_uint = undefined;
        gl.genVertexArrays(1, &vao_id);
        gl.genBuffers(1, &vbo_id);
        gl.genBuffers(1, &ebo_id);
        gl.bindVertexArray(vao_id);
        gl.bindBuffer(gl.ARRAY_BUFFER, vbo_id);
        gl.bufferData(gl.ARRAY_BUFFER, @sizeOf(@TypeOf(vertices)), &vertices, gl.STATIC_DRAW);
        gl.bindBuffer(gl.ELEMENT_ARRAY_BUFFER, ebo_id);
        gl.bufferData(gl.ELEMENT_ARRAY_BUFFER, @sizeOf(@TypeOf(indices)), &indices, gl.STATIC_DRAW);
        // Position
        gl.vertexAttribPointer(0, 3, gl.FLOAT, gl.FALSE, 8 * @sizeOf(f32), @intToPtr(?*anyopaque, 0)); // lmao
        gl.enableVertexAttribArray(0);
        // Colour
        gl.vertexAttribPointer(1, 3, gl.FLOAT, gl.FALSE, 8 * @sizeOf(f32), @intToPtr(?*anyopaque, (3 * @sizeOf(f32))));
        gl.enableVertexAttribArray(1);
        // Texture Coord
        gl.vertexAttribPointer(2, 2, gl.FLOAT, gl.FALSE, 8 * @sizeOf(f32), @intToPtr(?*anyopaque, (6 * @sizeOf(f32))));
        gl.enableVertexAttribArray(2);
        return .{ vao_id, vbo_id, ebo_id };
    }
    fn generateTexture(buf: []const u8) c_uint {
        var tex_id: c_uint = undefined;
        gl.genTextures(1, &tex_id);
        gl.bindTexture(gl.TEXTURE_2D, tex_id);
        // gl.texParameteri(gl.TEXTURE_2D, gl.TEXTURE_WRAP_S, gl.CLAMP_TO_EDGE);
        // gl.texParameteri(gl.TEXTURE_2D, gl.TEXTURE_WRAP_T, gl.CLAMP_TO_EDGE);
        gl.texParameteri(gl.TEXTURE_2D, gl.TEXTURE_MIN_FILTER, gl.NEAREST);
        gl.texParameteri(gl.TEXTURE_2D, gl.TEXTURE_MAG_FILTER, gl.NEAREST);
        gl.texImage2D(gl.TEXTURE_2D, 0, gl.RGBA, gba_width, gba_height, 0, gl.RGBA, gl.UNSIGNED_INT_8_8_8_8, buf.ptr);
        // gl.generateMipmap(gl.TEXTURE_2D); // TODO: Remove?
        return tex_id;
    }
    pub fn run(self: *Self, cpu: *Arm7tdmi, scheduler: *Scheduler) !void {
        var quit = std.atomic.Atomic(bool).init(false);
        var tracker = FpsTracker.init();
        var buffer_ids = Self.generateBuffers();
        defer {
            gl.deleteBuffers(1, &buffer_ids[2]); // EBO
            gl.deleteBuffers(1, &buffer_ids[1]); // VBO
            gl.deleteVertexArrays(1, &buffer_ids[0]); // VAO
        }
        const vao_id = buffer_ids[0];
        const tex_id = Self.generateTexture(cpu.bus.ppu.framebuf.get(.Renderer));
        defer gl.deleteTextures(1, &tex_id);
        const thread = try std.Thread.spawn(.{}, emu.run, .{ &quit, scheduler, cpu, &tracker });
        defer thread.join();
        var title_buf: [0x100]u8 = undefined;
        emu_loop: while (true) {
            var event: SDL.SDL_Event = undefined;
            while (SDL.SDL_PollEvent(&event) != 0) {
                switch (event.type) {
                    SDL.SDL_QUIT => break :emu_loop,
                    SDL.SDL_KEYDOWN => {
                        const key_code = event.key.keysym.sym;
                        var keyinput = cpu.bus.io.keyinput.load(.Monotonic);
                        switch (key_code) {
                            SDL.SDLK_UP => keyinput.up.unset(),
                            SDL.SDLK_DOWN => keyinput.down.unset(),
                            SDL.SDLK_LEFT => keyinput.left.unset(),
                            SDL.SDLK_RIGHT => keyinput.right.unset(),
                            SDL.SDLK_x => keyinput.a.unset(),
                            SDL.SDLK_z => keyinput.b.unset(),
                            SDL.SDLK_a => keyinput.shoulder_l.unset(),
                            SDL.SDLK_s => keyinput.shoulder_r.unset(),
                            SDL.SDLK_RETURN => keyinput.start.unset(),
                            SDL.SDLK_RSHIFT => keyinput.select.unset(),
                            else => {},
                        }
                        cpu.bus.io.keyinput.store(keyinput.raw, .Monotonic);
                    },
                    SDL.SDL_KEYUP => {
                        const key_code = event.key.keysym.sym;
                        var keyinput = cpu.bus.io.keyinput.load(.Monotonic);
                        switch (key_code) {
                            SDL.SDLK_UP => keyinput.up.set(),
                            SDL.SDLK_DOWN => keyinput.down.set(),
                            SDL.SDLK_LEFT => keyinput.left.set(),
                            SDL.SDLK_RIGHT => keyinput.right.set(),
                            SDL.SDLK_x => keyinput.a.set(),
                            SDL.SDLK_z => keyinput.b.set(),
                            SDL.SDLK_a => keyinput.shoulder_l.set(),
                            SDL.SDLK_s => keyinput.shoulder_r.set(),
                            SDL.SDLK_RETURN => keyinput.start.set(),
                            SDL.SDLK_RSHIFT => keyinput.select.set(),
                            SDL.SDLK_i => {
                                comptime std.debug.assert(sample_format == SDL.AUDIO_U16);
                                log.err("Sample Count: {}", .{cpu.bus.apu.sample_queue.len() / 2});
                            },
                            // SDL.SDLK_j => log.err("Scheduler Capacity: {} | Scheduler Event Count: {}", .{ scheduler.queue.capacity(), scheduler.queue.count() }),
                            SDL.SDLK_k => {},
                            else => {},
                        }
                        cpu.bus.io.keyinput.store(keyinput.raw, .Monotonic);
                    },
                    else => {},
                }
            }
            // Emulator has an internal Double Buffer
            const framebuf = cpu.bus.ppu.framebuf.get(.Renderer);
            gl.texSubImage2D(gl.TEXTURE_2D, 0, 0, 0, gba_width, gba_height, gl.RGBA, gl.UNSIGNED_INT_8_8_8_8, framebuf.ptr);
            gl.useProgram(self.program_id);
            gl.bindVertexArray(vao_id);
            gl.drawElements(gl.TRIANGLES, 6, gl.UNSIGNED_INT, null);
            SDL.SDL_GL_SwapWindow(self.window);
            const dyn_title = std.fmt.bufPrintZ(&title_buf, "ZBA | {s} [Emu: {}fps] ", .{ self.title, tracker.value() }) catch unreachable;
            SDL.SDL_SetWindowTitle(self.window, dyn_title.ptr);
        }
        quit.store(true, .Monotonic); // Terminate Emulator Thread
    }
    pub fn deinit(self: *Self) void {
        self.audio.deinit();
        gl.deleteProgram(self.program_id);
        SDL.SDL_GL_DeleteContext(self.ctx);
        SDL.SDL_DestroyWindow(self.window);
        SDL.SDL_Quit();
        self.* = undefined;
    }
    fn glGetProcAddress(ctx: SDL.SDL_GLContext, proc: [:0]const u8) ?*anyopaque {
        _ = ctx;
        return SDL.SDL_GL_GetProcAddress(proc.ptr);
    }
 };
 const Audio = struct {
    const Self = @This();
    const log = std.log.scoped(.PlatformAudio);
    device: SDL.SDL_AudioDeviceID,
    fn init(apu: *Apu) Self {
        var have: SDL.SDL_AudioSpec = undefined;
        var want: SDL.SDL_AudioSpec = std.mem.zeroes(SDL.SDL_AudioSpec);
        want.freq = sample_rate;
        want.format = sample_format;
        want.channels = 2;
        want.samples = 0x100;
        want.callback = Self.callback;
        want.userdata = apu;
        std.debug.assert(sample_format == SDL.AUDIO_U16);
        log.info("Host Sample Rate: {}Hz, Host Format: SDL.AUDIO_U16", .{sample_rate});
        const device = SDL.SDL_OpenAudioDevice(null, 0, &want, &have, 0);
        if (device == 0) panic();
        if (!config.config().host.mute) {
            SDL.SDL_PauseAudioDevice(device, 0); // Unpause Audio
            log.info("Unpaused Device", .{});
        }
        return .{ .device = device };
    }
    fn deinit(self: *Self) void {
        SDL.SDL_CloseAudioDevice(self.device);
        self.* = undefined;
    }
    export fn callback(userdata: ?*anyopaque, stream: [*c]u8, len: c_int) void {
        const T = *Apu;
        const apu = @ptrCast(T, @alignCast(@alignOf(T), userdata));
        comptime std.debug.assert(sample_format == SDL.AUDIO_U16);
        const sample_buf = @ptrCast([*]u16, @alignCast(@alignOf(u16), stream))[0 .. @intCast(u32, len) / @sizeOf(u16)];
        var previous: u16 = 0x8000;
        for (sample_buf) |*sample| {
            if (apu.sample_queue.pop()) |value| previous = value;
            sample.* = previous;
        }
    }
 };
 const shader = struct {
    const Kind = enum { vertex, fragment };
    const log = std.log.scoped(.Shader);
    fn didCompile(id: gl.GLuint) bool {
        var success: gl.GLint = undefined;
        gl.getShaderiv(id, gl.COMPILE_STATUS, &success);
        if (success == 0) err(id);
        return success == 1;
    }
    fn err(id: gl.GLuint) void {
        const buf_len = 512;
        var error_msg: [buf_len]u8 = undefined;
        gl.getShaderInfoLog(id, buf_len, 0, &error_msg);
        log.err("{s}", .{std.mem.sliceTo(&error_msg, 0)});
    }
 };
 fn panic() noreturn {
    const str = @as(?[*:0]const u8, SDL.SDL_GetError()) orelse "unknown error";
    @panic(std.mem.sliceTo(str, 0));
 }
--- a/src/shader/pixelbuf.frag
+++ b/src/shader/pixelbuf.frag
@@ -0,0 +1,25 @@
 #version 330 core
 out vec4 frag_color;
 in vec3 color;
 in vec2 uv;
 uniform sampler2D screen;
 void main() {
 	// https://near.sh/video/color-emulation
 	// Thanks to Talarubi + Near for the Colour Correction
 	// Thanks to fleur + mattrb for the Shader Impl
 	vec4 color = texture(screen, uv);
 	color.rgb = pow(color.rgb, vec3(4.0)); // LCD Gamma
 	frag_color = vec4(
 		pow(vec3(
 		  	  0 * color.b +  50 * color.g + 255 * color.r,
 	     	 30 * color.b + 230 * color.g +  10 * color.r,
 			220 * color.b +  10 * color.g +  50 * color.r
 		) / 255, vec3(1.0 / 2.2)), // Out Gamma
 	1.0); 
 }
--- a/src/shader/pixelbuf.vert
+++ b/src/shader/pixelbuf.vert
@@ -0,0 +1,13 @@
 #version 330 core
 layout (location = 0) in vec3 pos;
 layout (location = 1) in vec3 in_color;
 layout (location = 2) in vec2 in_uv;
 out vec3 color;
 out vec2 uv;
 void main() {
 	color = in_color;
 	uv = in_uv;
 	gl_Position = vec4(pos, 1.0);
 }
--- a/src/util.zig
+++ b/src/util.zig
@@ -0,0 +1,384 @@
 const std = @import("std");
 const builtin = @import("builtin");
 const config = @import("config.zig");
 const Log2Int = std.math.Log2Int;
 const Arm7tdmi = @import("core/cpu.zig").Arm7tdmi;
 // Sign-Extend value of type `T` to type `U`
 pub fn sext(comptime T: type, comptime U: type, value: T) T {
    // U must have less bits than T
    comptime std.debug.assert(@typeInfo(U).Int.bits <= @typeInfo(T).Int.bits);
    const iT = std.meta.Int(.signed, @typeInfo(T).Int.bits);
    const ExtU = if (@typeInfo(U).Int.signedness == .unsigned) T else iT;
    const shift_amt = @intCast(Log2Int(T), @typeInfo(T).Int.bits - @typeInfo(U).Int.bits);
    return @bitCast(T, @bitCast(iT, @as(ExtU, @truncate(U, value)) << shift_amt) >> shift_amt);
 }
 /// See https://godbolt.org/z/W3en9Eche
 pub inline fn rotr(comptime T: type, x: T, r: anytype) T {
    if (@typeInfo(T).Int.signedness == .signed)
        @compileError("cannot rotate signed integer");
    const ar = @intCast(Log2Int(T), @mod(r, @typeInfo(T).Int.bits));
    return x >> ar | x << (1 +% ~ar);
 }
 pub const FpsTracker = struct {
    const Self = @This();
    fps: u32,
    count: std.atomic.Atomic(u32),
    timer: std.time.Timer,
    pub fn init() Self {
        return .{
            .fps = 0,
            .count = std.atomic.Atomic(u32).init(0),
            .timer = std.time.Timer.start() catch unreachable,
        };
    }
    pub fn tick(self: *Self) void {
        _ = self.count.fetchAdd(1, .Monotonic);
    }
    pub fn value(self: *Self) u32 {
        if (self.timer.read() >= std.time.ns_per_s) {
            self.fps = self.count.swap(0, .Monotonic);
            self.timer.reset();
        }
        return self.fps;
    }
 };
 pub fn intToBytes(comptime T: type, value: anytype) [@sizeOf(T)]u8 {
    comptime std.debug.assert(@typeInfo(T) == .Int);
    var result: [@sizeOf(T)]u8 = undefined;
    var i: Log2Int(T) = 0;
    while (i < result.len) : (i += 1) result[i] = @truncate(u8, value >> i * @bitSizeOf(u8));
    return result;
 }
 /// Creates a copy of a title with all Filesystem-invalid characters replaced
 ///
 /// e.g. POKEPIN R/S to POKEPIN R_S
 pub fn escape(title: [12]u8) [12]u8 {
    var ret: [12]u8 = title;
    //TODO: Add more replacements
    std.mem.replaceScalar(u8, &ret, '/', '_');
    std.mem.replaceScalar(u8, &ret, '\\', '_');
    return ret;
 }
 pub const FilePaths = struct {
    rom: []const u8,
    bios: ?[]const u8,
    save: ?[]const u8,
 };
 pub const io = struct {
    pub const read = struct {
        pub fn todo(comptime log: anytype, comptime format: []const u8, args: anytype) u8 {
            log.debug(format, args);
            return 0;
        }
        pub fn undef(comptime T: type, comptime log: anytype, comptime format: []const u8, args: anytype) ?T {
            @setCold(true);
            const unhandled_io = config.config().debug.unhandled_io;
            log.warn(format, args);
            if (builtin.mode == .Debug and !unhandled_io) std.debug.panic("TODO: Implement I/O Register", .{});
            return null;
        }
        pub fn err(comptime T: type, comptime log: anytype, comptime format: []const u8, args: anytype) ?T {
            @setCold(true);
            log.err(format, args);
            return null;
        }
    };
    pub const write = struct {
        pub fn undef(log: anytype, comptime format: []const u8, args: anytype) void {
            const unhandled_io = config.config().debug.unhandled_io;
            log.warn(format, args);
            if (builtin.mode == .Debug and !unhandled_io) std.debug.panic("TODO: Implement I/O Register", .{});
        }
    };
 };
 pub const Logger = struct {
    const Self = @This();
    buf: std.io.BufferedWriter(4096 << 2, std.fs.File.Writer),
    pub fn init(file: std.fs.File) Self {
        return .{
            .buf = .{ .unbuffered_writer = file.writer() },
        };
    }
    pub fn print(self: *Self, comptime format: []const u8, args: anytype) !void {
        try self.buf.writer().print(format, args);
        try self.buf.flush(); // FIXME: On panics, whatever is in the buffer isn't written to file
    }
    pub fn mgbaLog(self: *Self, cpu: *const Arm7tdmi, opcode: u32) void {
        const fmt_base = "{X:0>8} {X:0>8} {X:0>8} {X:0>8} {X:0>8} {X:0>8} {X:0>8} {X:0>8} {X:0>8} {X:0>8} {X:0>8} {X:0>8} {X:0>8} {X:0>8} {X:0>8} {X:0>8} cpsr: {X:0>8} | ";
        const thumb_fmt = fmt_base ++ "{X:0>4}:\n";
        const arm_fmt = fmt_base ++ "{X:0>8}:\n";
        if (cpu.cpsr.t.read()) {
            if (opcode >> 11 == 0x1E) {
                // Instruction 1 of a BL Opcode, print in ARM mode
                const low = cpu.bus.dbgRead(u16, cpu.r[15] - 2);
                const bl_opcode = @as(u32, opcode) << 16 | low;
                self.print(arm_fmt, Self.fmtArgs(cpu, bl_opcode)) catch @panic("failed to write to log file");
            } else {
                self.print(thumb_fmt, Self.fmtArgs(cpu, opcode)) catch @panic("failed to write to log file");
            }
        } else {
            self.print(arm_fmt, Self.fmtArgs(cpu, opcode)) catch @panic("failed to write to log file");
        }
    }
    fn fmtArgs(cpu: *const Arm7tdmi, opcode: u32) FmtArgTuple {
        return .{
            cpu.r[0],
            cpu.r[1],
            cpu.r[2],
            cpu.r[3],
            cpu.r[4],
            cpu.r[5],
            cpu.r[6],
            cpu.r[7],
            cpu.r[8],
            cpu.r[9],
            cpu.r[10],
            cpu.r[11],
            cpu.r[12],
            cpu.r[13],
            cpu.r[14],
            cpu.r[15] - if (cpu.cpsr.t.read()) 2 else @as(u32, 4),
            cpu.cpsr.raw,
            opcode,
        };
    }
 };
 const FmtArgTuple = struct { u32, u32, u32, u32, u32, u32, u32, u32, u32, u32, u32, u32, u32, u32, u32, u32, u32, u32 };
 pub const audio = struct {
    const _io = @import("core/bus/io.zig");
    const ToneSweep = @import("core/apu/ToneSweep.zig");
    const Tone = @import("core/apu/Tone.zig");
    const Wave = @import("core/apu/Wave.zig");
    const Noise = @import("core/apu/Noise.zig");
    pub const length = struct {
        const FrameSequencer = @import("core/apu.zig").FrameSequencer;
        /// Update State of Ch1, Ch2 and Ch3 length timer
        pub fn update(comptime T: type, self: *T, fs: *const FrameSequencer, nrx34: _io.Frequency) void {
            comptime std.debug.assert(T == ToneSweep or T == Tone or T == Wave);
            // Write to NRx4 when FS's next step is not one that clocks the length counter
            if (!fs.isLengthNext()) {
                // If length_enable was disabled but is now enabled and length timer is not 0 already,
                // decrement the length timer
                if (!self.freq.length_enable.read() and nrx34.length_enable.read() and self.len_dev.timer != 0) {
                    self.len_dev.timer -= 1;
                    // If Length Timer is now 0 and trigger is clear, disable the channel
                    if (self.len_dev.timer == 0 and !nrx34.trigger.read()) self.enabled = false;
                }
            }
        }
        pub const ch4 = struct {
            /// update state of ch4 length timer
            pub fn update(self: *Noise, fs: *const FrameSequencer, nr44: _io.NoiseControl) void {
                // Write to NRx4 when FS's next step is not one that clocks the length counter
                if (!fs.isLengthNext()) {
                    // If length_enable was disabled but is now enabled and length timer is not 0 already,
                    // decrement the length timer
                    if (!self.cnt.length_enable.read() and nr44.length_enable.read() and self.len_dev.timer != 0) {
                        self.len_dev.timer -= 1;
                        // If Length Timer is now 0 and trigger is clear, disable the channel
                        if (self.len_dev.timer == 0 and !nr44.trigger.read()) self.enabled = false;
                    }
                }
            }
        };
    };
 };
 /// Sets a quarter (8) of the bits of the u32 `left` to the value of u8 `right`
 pub inline fn setQuart(left: u32, addr: u8, right: u8) u32 {
    const offset = @truncate(u2, addr);
    return switch (offset) {
        0b00 => (left & 0xFFFF_FF00) | right,
        0b01 => (left & 0xFFFF_00FF) | @as(u32, right) << 8,
        0b10 => (left & 0xFF00_FFFF) | @as(u32, right) << 16,
        0b11 => (left & 0x00FF_FFFF) | @as(u32, right) << 24,
    };
 }
 /// Calculates the correct shift offset for an aligned/unaligned u8 read
 ///
 /// TODO: Support u16 reads of u32 values?
 pub inline fn getHalf(byte: u8) u4 {
    return @truncate(u4, byte & 1) << 3;
 }
 pub inline fn setHalf(comptime T: type, left: T, addr: u8, right: HalfInt(T)) T {
    const offset = @truncate(u1, addr >> if (T == u32) 1 else 0);
    return switch (T) {
        u32 => switch (offset) {
            0b0 => (left & 0xFFFF_0000) | right,
            0b1 => (left & 0x0000_FFFF) | @as(u32, right) << 16,
        },
        u16 => switch (offset) {
            0b0 => (left & 0xFF00) | right,
            0b1 => (left & 0x00FF) | @as(u16, right) << 8,
        },
        else => @compileError("unsupported type"),
    };
 }
 /// The Integer type which corresponds to T with exactly half the amount of bits
 fn HalfInt(comptime T: type) type {
    const type_info = @typeInfo(T);
    comptime std.debug.assert(type_info == .Int); // Type must be an integer
    comptime std.debug.assert(type_info.Int.bits % 2 == 0); // Type must have an even amount of bits
    return std.meta.Int(type_info.Int.signedness, type_info.Int.bits >> 1);
 }
 const Mutex = std.Thread.Mutex;
 pub fn RingBuffer(comptime T: type) type {
    return struct {
        const Self = @This();
        const Index = usize;
        const max_capacity = (@as(Index, 1) << @typeInfo(Index).Int.bits - 1) - 1; // half the range of index type
        const log = std.log.scoped(.RingBuffer);
        read: Index,
        write: Index,
        buf: []T,
        mutex: Mutex,
        const Error = error{buffer_full};
        pub fn init(buf: []T) Self {
            std.mem.set(T, buf, 0);
            std.debug.assert(std.math.isPowerOfTwo(buf.len)); // capacity must be a power of two
            std.debug.assert(buf.len <= max_capacity);
            return .{ .read = 0, .write = 0, .buf = buf, .mutex = .{} };
        }
        pub fn push(self: *Self, left: T, right: T) Error!void {
            self.mutex.lock();
            defer self.mutex.unlock();
            try self._push(left);
            self._push(right) catch |e| {
                self.write -= 1; // undo the previous write;
                return e;
            };
        }
        pub fn pop(self: *Self) ?T {
            self.mutex.lock();
            defer self.mutex.unlock();
            return self._pop();
        }
        pub fn len(self: *Self) Index {
            self.mutex.lock();
            defer self.mutex.unlock();
            return self._len();
        }
        fn _push(self: *Self, value: T) Error!void {
            if (self.isFull()) return error.buffer_full;
            defer self.write += 1;
            self.buf[self.mask(self.write)] = value;
        }
        fn _pop(self: *Self) ?T {
            if (self.isEmpty()) return null;
            defer self.read += 1;
            return self.buf[self.mask(self.read)];
        }
        fn _len(self: *const Self) Index {
            return self.write - self.read;
        }
        fn isFull(self: *const Self) bool {
            return self._len() == self.buf.len;
        }
        fn isEmpty(self: *const Self) bool {
            return self.read == self.write;
        }
        fn mask(self: *const Self, idx: Index) Index {
            return idx & (self.buf.len - 1);
        }
    };
 }
 test "RingBuffer" {
    const Queue = RingBuffer(u8);
    var buf: [4]u8 = undefined;
    var queue = Queue.init(&buf);
    try queue.push(1, 2);
    try std.testing.expectEqual(@as(?u8, 1), queue.pop());
    try queue.push(3, 4);
    try std.testing.expectError(Queue.Error.buffer_full, queue.push(5, 6));
    try std.testing.expectEqual(@as(?u8, 2), queue.pop());
    try queue.push(7, 8);
    try std.testing.expectEqual(@as(?u8, 3), queue.pop());
    try std.testing.expectEqual(@as(?u8, 4), queue.pop());
    try std.testing.expectEqual(@as(?u8, 7), queue.pop());
    try std.testing.expectEqual(@as(?u8, 8), queue.pop());
    try std.testing.expectEqual(@as(?u8, null), queue.pop());
 }
Author	SHA1	Message	Date
Rekai Musuka	2f2c03b96d	chore: add test for RingBuffer	2022-12-10 01:02:59 -04:00
Rekai Musuka	9a2b7a48c0	tmp: removed audio resampler	2022-12-09 22:16:51 -04:00
Rekai Musuka	fe908a6ea9	feat(util): implement RingBuffer	2022-12-09 22:16:51 -04:00
Rekai Musuka	bf95eee3f1	fix(apu): resolve bug in NR10 obscure behaviour	2022-12-05 11:08:04 -04:00
Rekai Musuka	240fbcb1df	chore: update dependencies	2022-12-01 13:23:09 -04:00
Rekai Musuka	26db340077	fix(input): implement atomic for KeyInput	2022-11-30 00:42:20 -04:00
Rekai Musuka	20f611b7b5	chore: be more intentional in atomic ordering use	2022-11-30 00:21:02 -04:00
Rekai Musuka	f9aefedf60	chore: cal glDeleteTextures on program exit	2022-11-29 23:35:13 -04:00
Rekai Musuka	d7e3d34726	fix(platform): ensure that title char* is null terminated	2022-11-29 23:21:57 -04:00
Rekai Musuka	2294dc8832	chore: add minimum zig version	2022-11-29 23:10:29 -04:00
Rekai Musuka	4af86e1cb3	style: replace meta.Tuple calls with new tuple syntax	2022-11-29 23:01:06 -04:00
Rekai Musuka	9fcbbe7d57	chore: cleanup OpenGL vertex array + buffers	2022-11-29 22:53:37 -04:00
Rekai Musuka	c3f67e38a1	chore: exit early on shader compile failure	2022-11-29 22:25:04 -04:00
Rekai Musuka	46e29245b7	fix(apu): disable APU writes when APU is disabled	2022-11-26 12:20:42 -04:00
Rekai Musuka	002e33b48b	fix: properly render table in README	2022-11-24 08:22:58 -04:00
Rekai Musuka	5bb25fe214	chore: update dependencies	2022-11-23 21:57:53 -04:00
Rekai Musuka	66db2e6049	Revert "chore: refactor flash impl" This reverts commit `96a9ae2ca5`.	2022-11-20 21:46:40 -04:00
Rekai Musuka	c5cf471912	fix(timer): removing cascade when TIM aleady enabled shouldn't reset counter	2022-11-20 19:13:49 -04:00
Rekai Musuka	4ed4f8e143	fix(dma): implement obscure behaviour for DMAs from ROM	2022-11-20 17:49:26 -04:00
Rekai Musuka	f31699d921	fix(log): logged improper second opcode for THUMB BL	2022-11-20 15:36:40 -04:00
Rekai Musuka	96a9ae2ca5	chore: refactor flash impl	2022-11-17 10:47:19 -04:00
Rekai Musuka	ee1c0bb313	chore: update README	2022-11-16 10:55:33 -04:00
Rekai Musuka	558c03b12b	style: changes to cpu.zig	2022-11-16 10:21:40 -04:00
Rekai Musuka	7d8fbbb086	fix(bus): resolve off-by-one error	2022-11-14 01:59:43 -04:00
Rekai Musuka	9fd405a896	chore(ci): update CI dependency	2022-11-11 13:25:56 -04:00
Rekai Musuka	5d7cf3a8a2	chore: remove util fn for stdlib equivalent	2022-11-11 13:02:51 -04:00
Rekai Musuka	1230aa1e91	fix(cpu): remove miscompilation workaround	2022-11-11 03:56:49 -04:00
Rekai Musuka	accecb3350	chore(ci): rename CI workflow	2022-11-10 11:58:47 -04:00
Rekai Musuka	1e0ade8f55	chore: update depdendencies	2022-11-07 00:54:35 -04:00
Rekai Musuka	429676ad43	feat(config): write config.toml to config dir, not data dir	2022-11-03 09:45:57 -03:00
Rekai Musuka	ef39d9a7b8	chore(ci): only run for .zig files, name workflow Also enabled workflow dispatch	2022-11-03 08:56:14 -03:00
Rekai Musuka	986bc9448e	fix(bus): account for read_table being the first table when freeing	2022-11-03 07:50:12 -03:00
Rekai Musuka	d34893ba72	fix(bus): fix confusion about which fastmem write table is for which write type	2022-11-02 08:21:59 -03:00
Rekai Musuka	b8a5fb95c1	fix(io): account for read-only bit in WAITCNT	2022-11-02 08:06:19 -03:00
Rekai Musuka	102b2c946b	fix(io): respect read-only bits in DISPSTAT Superstar Saga now renders correctly	2022-11-02 07:54:06 -03:00
Rekai Musuka	505b1b9608	fix(bus): resolve simple oversights	2022-11-01 09:00:25 -03:00
Rekai Musuka	2851c140ea	fix(cpu): use LUT for ARM condition codes	2022-11-01 08:29:42 -03:00
Rekai Musuka	637d81ce44	chore(bus): only perform one allocation for fastmem tables	2022-11-01 07:04:42 -03:00
Rekai Musuka	bc52461f0f	fix(bus): replace write table with two tables for u32/u8 and u8 writes	2022-11-01 07:00:07 -03:00
Rekai Musuka	c395c04a6e	feat(bus): implement fastmem +100 fps in Pokemon Emerald lol	2022-11-01 06:18:12 -03:00
Rekai Musuka	9eb4f8f191	chore: reccomend stable Zig v0.10.0	2022-11-01 01:01:48 -03:00
Rekai Musuka	f774256c42	chore: update README.md	2022-10-31 09:14:42 -03:00
Rekai Musuka	5c15d039e1	chore(ci): update actions/checkout to v3 supresses deprecation warning for node12	2022-10-31 08:16:45 -03:00
Rekai Musuka	28e9342c25	ci: add github actions config file	2022-10-31 08:04:21 -03:00
Rekai Musuka	af8ec4db5b	chore: go through TODOs and FIXMEs mainly deleting / rewording those that no longer apply	2022-10-31 06:17:09 -03:00
Rekai Musuka	5d47e5d167	fix(io): force-align all i/o reads Of course, backups being the exception due to flash or sram quirks, I don't remember lol	2022-10-31 05:50:27 -03:00
Rekai Musuka	5101fbd809	feat(io): pass all suite.gba i/o read tests	2022-10-31 05:22:11 -03:00
Rekai Musuka	472457b9f3	chore: make use of comptime control flow when working with tuples	2022-10-31 05:14:20 -03:00
Rekai Musuka	2ef4bb7dcc	revert(apu): switch from f32 44.1kHz to u16 32.768kHz	2022-10-31 05:14:20 -03:00
Rekai Musuka	9a732ea6f8	chore(i/o): ensure interrupt i/o exists	2022-10-31 05:14:20 -03:00
Rekai Musuka	f80799a593	fix(util): resolve bug in setHalf function introduced in `472215b4c2`	2022-10-30 04:12:58 -03:00
Rekai Musuka	ca67ca3183	fix(apu): only enable dma sound fifo after manual write	2022-10-30 03:48:12 -03:00
Rekai Musuka	47fc49deb6	fix(audio): add asserts where I assume audio format	2022-10-30 03:25:49 -03:00
Rekai Musuka	472215b4c2	feat(ppu): implement all i/o writes	2022-10-30 03:11:04 -03:00
Rekai Musuka	c9a423d094	fix(ppu): resolve mistakes in ppu i/o reads	2022-10-30 02:15:26 -03:00
Rekai Musuka	1d163fa56f	feat(apu): implement all apu i/o writes	2022-10-30 02:02:23 -03:00
Rekai Musuka	13710a3236	feat(timer): implement all timer i/o writes	2022-10-30 01:18:46 -03:00
Rekai Musuka	6154585e77	feat(dma): implement all dma i/o writes	2022-10-30 01:04:22 -03:00
Rekai Musuka	7debdc490d	fix(io): resovle off-by-one errors in i/o register ranges	2022-10-29 05:23:05 -03:00
Rekai Musuka	58375795bf	fix(ppu): apply proper masks to ppu i/o Refactor Window, and bldcnt, bldalpha, bldy	2022-10-29 05:18:53 -03:00
Rekai Musuka	f0dca29836	fix(dma): apply proper masks to dma i/o	2022-10-29 04:53:21 -03:00
Rekai Musuka	c75682dbd4	fix(apu): some invalid i/o registers should read 0x0000	2022-10-29 04:29:44 -03:00
Rekai Musuka	36832ba1fb	feat(apu): impelement all apu i/o reads	2022-10-29 04:24:06 -03:00
Rekai Musuka	647bd83224	chore(io): rewrite certain error messages We can do this now that we know that it won't be because of any unimplemented feature in some circumstances	2022-10-29 02:37:54 -03:00
Rekai Musuka	c831f67d1a	feat(timer): implemeant all timer i/o reads	2022-10-29 01:37:28 -03:00
Rekai Musuka	268961262d	feat(dma): implement all dma i/o reads	2022-10-29 01:30:12 -03:00
Rekai Musuka	3e62feacba	feat(ppu): implement all ppu i/o reads	2022-10-29 01:29:27 -03:00
Rekai Musuka	d859cee365	style: get rid of unnecessary type coersion	2022-10-29 00:06:08 -03:00
Rekai Musuka	371cf4cc12	style(i/o, ppu): refactor ppu i/o	2022-10-28 23:45:54 -03:00
Rekai Musuka	10aec67ee0	emu: implement thread sleep in granular steps	2022-10-28 21:58:55 -03:00
Rekai Musuka	4eb715a138	doc(emu): properly document + simply constants	2022-10-28 21:57:30 -03:00
Rekai Musuka	14b24787ab	style: remove unnecessary imports	2022-10-28 21:56:55 -03:00
Rekai Musuka	eb7ffa29f4	fix(apu): pause device on mute instead of writing silence	2022-10-27 09:11:08 -03:00
Rekai Musuka	4b8ed3cebb	fix(io): resolve embarrasingly simple regression introduced in `21eddac31e`	2022-10-23 04:39:31 -03:00
Rekai Musuka	928ce674d9	fix(cpu): fix obscure LDRSH behaviour	2022-10-22 22:12:41 -03:00
Rekai Musuka	945dbec013	fix(open-bus): don't rotate result Rotating misaligned reads is the responsibility of the CPU	2022-10-22 21:32:36 -03:00
Rekai Nyangadzayi Musuka	dd98066a34	Merge pull request 'feat(dma): Implement DMA Latch' (#5 ) from dma-latch into main Reviewed-on: #5	2022-10-22 23:53:21 +00:00
Rekai Musuka	a2868dfe9e	feat(dma): Implement DMA Latch	2022-10-22 20:52:02 -03:00
Rekai Musuka	22979d9450	fix(bios): fix regression was reading addr_latch + 8, which is a remnant from when I was faking the pipeline	2022-10-22 15:33:36 -03:00
Rekai Musuka	712c58391d	chore(config): change defaults in config.toml	2022-10-21 06:01:22 -03:00
paoda	407774d798	chore(gitignore): update .gitignore	2022-10-21 04:40:55 -03:00
paoda	16f8f4c953	feat: write default config.toml if it doesn't exist also resolves panic on missing /zba or /zba/save directory by ensuring those directories exist as soon as we know the data directory	2022-10-21 04:39:16 -03:00
paoda	143ffd95f7	chore: update README	2022-10-21 02:59:43 -03:00
Rekai Nyangadzayi Musuka	250ff25ed7	Merge pull request 'Configure SDL2 to use OpenGL' (#4 ) from opengl into main Reviewed-on: #4	2022-10-20 01:41:50 +00:00
Rekai Musuka	eff52ac1bb	fix(opengl): properly control whether vsync is enabled	2022-10-17 20:31:42 -03:00
Rekai Musuka	e60b556f72	chore(ppu): remove BGR555 -> RGBA888 LUT LUT probably couldn't fit in CPU cache anyways. TODO: Consider whether LUTs for separate channels (size 32 * 3 * 3 instead of std.math.maxInt(u15))	2022-10-17 20:31:42 -03:00
Rekai Musuka	3a3e6acc6a	chore: replace OpenGL 4.5 bindings with OpenGL 3.3	2022-10-17 20:31:42 -03:00
Rekai Musuka	4b4bc7f894	chore: remove unnecessary ptr cast	2022-10-17 20:31:42 -03:00
Rekai Musuka	325208d460	feat: implement better Colour Emulation	2022-10-17 20:31:42 -03:00
Rekai Musuka	f44a1a49fd	fix: lower required OpenGL version + resolve offset bug	2022-10-17 20:31:42 -03:00
Rekai Musuka	1575f517a9	feat: use opengl TODO: - Texture isn't scaling properly - I need to reverse the colours in the frag shader	2022-10-17 20:31:42 -03:00
Rekai Musuka	26dba16789	chore(gpio): add missing errdefer	2022-10-17 20:01:50 -03:00
Rekai Musuka	b133880064	chore(main): report errors slightly better	2022-10-17 18:30:40 -03:00
Rekai Musuka	2474daa3ae	chore(config): add log message	2022-10-17 17:39:02 -03:00
Rekai Musuka	fc53a40b3c	feat(config): add option to skip BIOS	2022-10-17 17:31:07 -03:00
Rekai Musuka	7097e21361	feat(cli): Add option to skip BIOS	2022-10-17 17:25:04 -03:00
Rekai Musuka	a9fe24b1b4	chore: Update README.md	2022-10-17 17:00:54 -03:00
Rekai Nyangadzayi Musuka	f38c840d32	Merge pull request 'Draft: Implement Instruction Pipeline' (#3 ) from pipeline into main Reviewed-on: #3	2022-10-17 19:42:42 +00:00
Rekai Musuka	19e70c39d1	feat(config): add config option to mute ZBA	2022-10-13 00:54:15 -03:00
Rekai Musuka	5a72a8e7f3	chore(config): add example config file	2022-10-13 00:46:18 -03:00
Rekai Musuka	7b146ad7ca	fix(bios): set addr_latch even if bios is skipped	2022-10-13 00:35:22 -03:00
Rekai Musuka	822eed1f3a	fix(bus): make open bus impl aware of CPU pipeline	2022-10-13 00:35:22 -03:00
Rekai Musuka	b37a14900c	style(bus): cpu ptr doesn't need to be optional	2022-10-13 00:35:22 -03:00
Rekai Musuka	f5bd20bc2a	style: code cleanup	2022-10-13 00:35:22 -03:00
Rekai Musuka	d3514b14f3	fix: resolve timing regressions make sure to use fetch timings when fetching instructions	2022-10-13 00:35:20 -03:00
Rekai Musuka	06c60dad74	fix: rename Pipline to Pipeline	2022-10-13 00:34:18 -03:00
Rekai Musuka	870e991862	feat: working pipeline implementation	2022-10-13 00:34:18 -03:00
Rekai Musuka	5bb5bdf389	chore: refactor ARM/THUMB data processing instructions	2022-10-13 00:34:18 -03:00
Rekai Musuka	a3996cbc58	fix: don't flush pipeline when reloading CPSR in ARM Data Processing	2022-10-13 00:34:18 -03:00
Rekai Musuka	a948c6f900	chore: don't write to CPSR + swap with SPSR at the same time	2022-10-13 00:34:18 -03:00
Rekai Musuka	014180cbd0	chore: update README.md	2022-10-13 00:33:13 -03:00
Rekai Musuka	e4451738b5	fix: advance r15, even when the pipeline is reloaded from the scheduler The PC would fall behind whenever an IRQ was called because the pipeline was reloaded (+8 to PC), however that was never actually done by any code Now, the PC is always incremented when the pipeline is reloaded	2022-10-13 00:33:13 -03:00
Rekai Musuka	48b81c8e7a	chore: dump pipeline state on cpu panic	2022-10-13 00:33:13 -03:00
Rekai Musuka	3cf1bf54e9	fix: reimpl THUMB.5 instructions pipeline branch now passes arm.gba and thumb.gba again (TODO: Stop rewriting my commits away)	2022-10-13 00:33:13 -03:00
Rekai Musuka	1f9eeedfe8	fix: impl workaround for stage2 miscompilation	2022-10-13 00:33:13 -03:00
Rekai Musuka	72a63eeb98	chore: instantly refill the pipeline on flush I believe this to be necessary in order to get hardware interrupts working. thumb.gba test 108 fails but I'm committing anyways (despite the regression) because this is kind of rebase/merge hell and I have something that at least sort of works rn	2022-10-13 00:33:13 -03:00
Rekai Musuka	2799c3f202	fix: reimpl handleInterrupt code	2022-10-13 00:33:13 -03:00
Rekai Musuka	b3ada64e64	feat: implement basic pipeline passes arm.gba, thumb.gb and armwrestler, fails in actual games TODO: run FuzzARM debug specific titles	2022-10-13 00:33:11 -03:00
Rekai Musuka	62162ba492	feat: resolve off-by-{word, halfword} errors when printing debug info	2022-10-13 00:31:47 -03:00
Rekai Musuka	aa100de581	feat: reimplement cpu logging	2022-10-13 00:31:47 -03:00
Rekai Nyangadzayi Musuka	7142831284	Merge pull request 'Add TOML Support' (#2 ) from toml into main Reviewed-on: #2	2022-10-13 03:30:26 +00:00
Rekai Musuka	97f48c730e	chore(emu): refactor code	2022-10-13 00:29:51 -03:00
Rekai Musuka	293fbd9f55	feat(config): add support for (and read from) TOML config file	2022-10-13 00:29:48 -03:00
Rekai Musuka	622f479e07	feat: parse config.toml in data folder Also took the chance to rework parts of the logic that determines ZBA's save path	2022-10-13 00:27:18 -03:00
Rekai Musuka	0204eb6f94	chore: add zig-toml dependency	2022-10-13 00:27:18 -03:00
Rekai Musuka	86d2224cfc	chore: update dependencies	2022-10-13 00:23:58 -03:00
Rekai Musuka	21eddac31e	style: improve code quality	2022-10-13 00:23:58 -03:00
Rekai Musuka	785135a074	feat: rewrite device ticks	2022-10-13 00:23:58 -03:00
Rekai Musuka	fd38fd6506	style(scheduler): rename scheduler event handlers	2022-10-13 00:23:58 -03:00
Rekai Musuka	bcacac64df	style: code refactoring	2022-10-13 00:23:58 -03:00
Rekai Musuka	dc7cad9691	style(apu): split apu.zig into multiple files + refactor	2022-10-13 00:23:58 -03:00
Rekai Musuka	b5d8a65e69	style(backup): refactor code	2022-10-10 12:01:49 -03:00
Rekai Musuka	8028394105	style(flash): move flash code into it's own file	2022-10-10 12:01:49 -03:00
Rekai Musuka	cb0eb67e4b	style(eeprom): move eeprom code to it's own file	2022-10-10 12:00:45 -03:00
Rekai Musuka	13f6ee8ec4	style(bus): refactor several hardware abstractions	2022-10-10 11:57:57 -03:00
Rekai Musuka	c71e954748	chore: SDL2.zig expects target to be set before link() is called	2022-09-25 18:59:55 -03:00
Rekai Musuka	c697dec716	chore: update dependencies	2022-09-23 07:21:46 -03:00
Rekai Musuka	92cfc763c0	chore: move util.zig	2022-09-19 16:07:19 -03:00
Rekai Musuka	e192c6712f	chore: disable audio sync by default forgot SDL2 AudioStream doesn't work well for my use-case	2022-09-18 09:20:01 -03:00
Rekai Musuka	3466bf6c0a	chore: change default settings	2022-09-18 06:30:39 -03:00
Rekai Musuka	fbe3de0eb3	chore: reimpl util.escape should make use of stdlib when I can	2022-09-18 06:23:30 -03:00
Rekai Musuka	4af144fca2	fix: Detect FRAM ROMs	2022-09-18 06:19:05 -03:00
Rekai Musuka	9a8aaba1ab	chore: improve util and Gui API	2022-09-18 05:55:15 -03:00
Rekai Musuka	fa3b9c21b9	chore: move Gpio and Clock structs to separate file	2022-09-18 00:37:45 -03:00
Rekai Nyangadzayi Musuka	d3efa432fa	Merge pull request 'Implement RTC' (#1 ) from rtc into main Reviewed-on: #1	2022-09-17 23:36:34 +00:00
Rekai Musuka	50adb5fbac	feat: add option to force-enable RTC	2022-09-17 20:27:17 -03:00
Rekai Musuka	19d78b9292	feat: auto-detect RTC in commercial ROMS	2022-09-17 20:23:49 -03:00
Rekai Musuka	a2e702c366	fix: account for lateness in RTC scheduler event	2022-09-17 09:07:31 -03:00
Rekai Musuka	12c138364d	fix: RTC day is 6 bits wide, not 3	2022-09-16 10:59:41 -03:00
Rekai Musuka	7783c11fac	feat: put RTC Sync on Scheduler TODO: Database to see what games have what GPIO devices	2022-09-16 10:39:02 -03:00
Rekai Musuka	3fc3366c8a	chore: import datetime library + default time for RTC	2022-09-16 10:39:02 -03:00
Rekai Musuka	d6b182f245	fix: ignore RTC Time/DateTime writes this falls in-line with better emulators	2022-09-16 10:39:02 -03:00
Rekai Musuka	3857c44e68	chore: use Clock.Writer for Command parsing, delete Clock.Command	2022-09-16 10:39:02 -03:00
Rekai Musuka	089c5fa025	feat: implement RTC Read/Writes	2022-09-16 10:39:02 -03:00
Rekai Musuka	c977f3f965	feat: implement force irqs for GPIO/RTC	2022-09-16 10:38:51 -03:00
Rekai Musuka	92417025e9	fix: properly resovle stack UAF	2022-09-16 02:10:41 -03:00
Rekai Musuka	1c52c0bf91	chore: shorten `orelse @panic` to `.?`	2022-09-16 02:10:41 -03:00
Rekai Musuka	617f7f4690	fix: update GpioData extern union u4's are no longer supported in extern unions :\	2022-09-16 02:10:41 -03:00
paoda	434a0dfac9	tmp: incomplete impl of GPIO + RTC	2022-09-16 02:10:41 -03:00
Rekai Musuka	4ec8dab460	chore: Guilty Gear X expects these I/O Registers	2022-09-14 11:38:26 -03:00
Rekai Musuka	59c9ff910e	feat: implement open bus for unmapped i/o	2022-09-12 23:18:29 -03:00
Rekai Musuka	0027d3f8a3	chore: comment open bus impl	2022-09-11 07:38:55 -03:00
Rekai Musuka	9f45888910	chore: update dependencies	2022-09-11 06:59:10 -03:00
Rekai Musuka	bf442d5a40	chore: Update README.md	2022-09-10 07:34:52 -03:00
Rekai Musuka	65cfc97f28	feat: reimplement audio sync APU will now drop samples if the Audio Queue is already full, therefore creating a "sped-up" effect when the emulator runs faster than 100%	2022-09-08 20:38:42 -03:00
Rekai Musuka	fa862f095a	chore: move arm/thumb lut idx functions	2022-09-06 23:58:24 -03:00
Rekai Musuka	f3c05b6fe6	chore: update dependencies	2022-09-05 22:52:07 -03:00
Rekai Musuka	3fb7f2f814	chore: better conform to zig idioms	2022-09-03 18:30:48 -03:00
Rekai Musuka	59669ba3a5	chore: rename arm7tdmi variables to just cpu Less verbose, specifying arm7tdmi doesn't really do much when there's no other CPU in the system	2022-09-03 17:56:37 -03:00
Rekai Musuka	6a798d2c9d	chore: allocate sprite array on heap Each Sprite optional is 10 bytes meaning I'm allocating 1.28Kb on the stack which isn't necessary.	2022-08-29 01:07:25 -05:00
Rekai Musuka	5f8c6833f4	chore: improve init/deinit methods	2022-08-29 01:07:25 -05:00
Rekai Musuka	aa52bb5917	chore: reorganize some code	2022-08-26 14:13:49 -05:00
Rekai Musuka	e57f918856	chore: pass the allocator as an argument more often As of right now, I think the only cases where I shouldn't explicitly pass an allocator are in read/write functions and deinits	2022-08-26 13:54:38 -05:00
Rekai Musuka	e5b7441740	fix: resolve use-afer-free in backup.zig This worked fine on stage1, and works fine in debug in stage3. However, stage3 ReleaseSafe would panic due to what I assume must have been an undefined behaviour optimization. While I'm happy that I was quickly made aware of the issue thanks to the safety checks in ReleaseSafe I do wish that this issue showed itself in Debug, since I am using the GPA	2022-08-26 13:04:09 -05:00
Rekai Musuka	2ab8769b7a	feat: Get ZBA working on Zig's new stage2/stage3 compiler	2022-08-21 12:28:31 -05:00