chore: dont allocate not-small ?Sprite array on stack

use memset like most other allocations in this emu
chore: move FrameBuffer struct to util.zig
2022-09-18 09:20:47 -03:00 · 2022-09-18 09:20:47 -03:00 · 2022-09-18 09:20:47 -03:00 · 2022-09-18 09:20:47 -03:00 · 2022-09-18 09:20:47 -03:00 · 2022-09-18 09:20:47 -03:00
7 changed files with 365 additions and 282 deletions
--- a/src/core/bus/dma.zig
+++ b/src/core/bus/dma.zig
@ -227,7 +227,7 @@ fn DmaController(comptime id: u2) type {
            }
        }
-        pub fn pollBlankingDma(self: *Self, comptime kind: DmaKind) void {
+        pub fn pollBlanking(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
@ -271,11 +271,11 @@ fn DmaController(comptime id: u2) type {
    };
 }
-pub fn pollBlankingDma(bus: *Bus, comptime kind: DmaKind) void {
+pub fn onBlanking(bus: *Bus, comptime kind: DmaKind) void {
-    bus.dma[0].pollBlankingDma(kind);
+    bus.dma[0].pollBlanking(kind);
-    bus.dma[1].pollBlankingDma(kind);
+    bus.dma[1].pollBlanking(kind);
-    bus.dma[2].pollBlankingDma(kind);
+    bus.dma[2].pollBlanking(kind);
-    bus.dma[3].pollBlankingDma(kind);
+    bus.dma[3].pollBlanking(kind);
 }
 const Adjustment = enum(u2) {
--- a/src/core/bus/io.zig
+++ b/src/core/bus/io.zig
@ -302,6 +302,14 @@ pub fn write(bus: *Bus, comptime T: type, address: u32, value: T) void {
            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_0040 => bus.ppu.win.h[0].set(.Lo, value),
            0x0400_0041 => bus.ppu.win.h[0].set(.Hi, value),
            0x0400_0042 => bus.ppu.win.h[1].set(.Lo, value),
            0x0400_0043 => bus.ppu.win.h[1].set(.Hi, value),
            0x0400_0044 => bus.ppu.win.v[0].set(.Lo, value),
            0x0400_0045 => bus.ppu.win.v[0].set(.Hi, value),
            0x0400_0046 => bus.ppu.win.v[1].set(.Lo, value),
            0x0400_0047 => bus.ppu.win.v[1].set(.Hi, value),
            0x0400_0048 => bus.ppu.win.setInL(value),
            0x0400_0049 => bus.ppu.win.setInH(value),
            0x0400_004A => bus.ppu.win.setOutL(value),
@ -459,37 +467,57 @@ pub const BldY = extern union {
    raw: u16,
 };
 const u8WriteKind = enum { Hi, Lo };
 /// Write-only
 pub const WinH = extern union {
    const Self = @This();
    x2: Bitfield(u16, 0, 8),
    x1: Bitfield(u16, 8, 8),
    raw: u16,
    pub fn set(self: *Self, comptime K: u8WriteKind, value: u8) void {
        self.raw = switch (K) {
            .Hi => (@as(u16, value) << 8) | self.raw & 0xFF,
            .Lo => (self.raw & 0xFF00) | value,
        };
    }
 };
 /// Write-only
 pub const WinV = extern union {
    const Self = @This();
    y2: Bitfield(u16, 0, 8),
    y1: Bitfield(u16, 8, 8),
    raw: u16,
    pub fn set(self: *Self, comptime K: u8WriteKind, value: u8) void {
        self.raw = switch (K) {
            .Hi => (@as(u16, value) << 8) | self.raw & 0xFF,
            .Lo => (self.raw & 0xFF00) | value,
        };
    }
 };
 pub const WinIn = extern union {
    w0_bg: Bitfield(u16, 0, 4),
    w0_obj: Bit(u16, 4),
-    w0_colour: Bit(u16, 5),
+    w0_bld: Bit(u16, 5),
    w1_bg: Bitfield(u16, 8, 4),
    w1_obj: Bit(u16, 12),
-    w1_colour: Bit(u16, 13),
+    w1_bld: Bit(u16, 13),
    raw: u16,
 };
 pub const WinOut = extern union {
    out_bg: Bitfield(u16, 0, 4),
    out_obj: Bit(u16, 4),
-    out_colour: Bit(u16, 5),
+    out_bld: Bit(u16, 5),
    obj_bg: Bitfield(u16, 8, 4),
    obj_obj: Bit(u16, 12),
-    obj_colour: Bit(u16, 13),
+    obj_bld: Bit(u16, 13),
    raw: u16,
 };
--- a/src/core/ppu.zig
+++ b/src/core/ppu.zig
@ -1,16 +1,19 @@
 const std = @import("std");
 const io = @import("bus/io.zig");
 const Bit = @import("bitfield").Bit;
 const Bitfield = @import("bitfield").Bitfield;
 const dma = @import("bus/dma.zig");
 const Oam = @import("ppu/Oam.zig");
 const Palette = @import("ppu/Palette.zig");
 const Vram = @import("ppu/Vram.zig");
 const EventKind = @import("scheduler.zig").EventKind;
 const Scheduler = @import("scheduler.zig").Scheduler;
 const Arm7tdmi = @import("cpu.zig").Arm7tdmi;
-
+const FrameBuffer = @import("util.zig").FrameBuffer;
 const Bit = @import("bitfield").Bit;
 const Bitfield = @import("bitfield").Bitfield;
 const Allocator = std.mem.Allocator;
-const log = std.log.scoped(.PPU);
+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 COLOUR_LUT = genColourLut();
@ -51,14 +54,14 @@ pub const Ppu = struct {
        sched.push(.Draw, 240 * 4);
        const sprites = try allocator.create([128]?Sprite);
-        sprites.* = [_]?Sprite{null} ** 128;
+        std.mem.set(?Sprite, sprites, null);
        return Self{
            .vram = try Vram.init(allocator),
            .palette = try Palette.init(allocator),
            .oam = try Oam.init(allocator),
            .sched = sched,
-            .framebuf = try FrameBuffer.init(allocator),
+            .framebuf = try FrameBuffer.init(allocator, framebuf_pitch * height),
            .allocator = allocator,
            // Registers
@ -277,16 +280,17 @@ 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;
+            const x = @bitCast(u32, ix);
            const y = @bitCast(u32, iy);
            const win_bounds = self.windowBounds(@truncate(u9, x), @truncate(u8, y));
            if (!shouldDrawBackground(self, n, win_bounds, 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;
                iy = if (iy > px_height) @rem(iy, px_height) else if (iy < 0) px_height + @rem(iy, px_height) else iy;
            } else if (ix > px_width or iy > px_height or ix < 0 or iy < 0) continue;
            const x = @bitCast(u32, ix);
            const y = @bitCast(u32, iy);
            const tile_id: u32 = self.vram.read(u8, screen_base + ((y / 8) * @bitCast(u32, tile_width) + (x / 8)));
            const row = y & 7;
            const col = x & 7;
@ -296,7 +300,7 @@ 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);
+                self.copyToBackgroundBuffer(n, win_bounds, i, bgr555);
            }
        }
@ -305,7 +309,7 @@ pub const Ppu = struct {
        self.aff_bg[n - 2].y_latch.? += self.aff_bg[n - 2].pd; // PD is added to BGxY
    }
-    fn drawBackround(self: *Self, comptime n: u2) void {
+    fn drawBackground(self: *Self, comptime n: u2) void {
        // A Tile in a charblock is a byte, while a Screen Entry is a halfword
        const char_base = 0x4000 * @as(u32, self.bg[n].cnt.char_base.read());
@ -325,10 +329,11 @@ pub const Ppu = struct {
        var i: u32 = 0;
        while (i < width) : (i += 1) {
            if (!shouldDrawBackground(n, self.bldcnt, &self.scanline, i)) continue;
            const x = hofs + i;
            const win_bounds = self.windowBounds(@truncate(u9, x), @truncate(u8, y));
            if (!shouldDrawBackground(self, n, win_bounds, i)) continue;
            // Grab the Screen Entry from VRAM
            const entry_addr = screen_base + tilemapOffset(size, x, y);
            const entry = @bitCast(ScreenEntry, self.vram.read(u16, entry_addr));
@ -353,7 +358,7 @@ 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);
+                self.copyToBackgroundBuffer(n, win_bounds, i, bgr555);
            }
        }
    }
@ -379,10 +384,10 @@ pub const Ppu = struct {
                var layer: usize = 0;
                while (layer < 4) : (layer += 1) {
                    self.drawSprites(@truncate(u2, layer));
-                    if (layer == self.bg[0].cnt.priority.read() and bg_enable & 1 == 1) self.drawBackround(0);
+                    if (layer == self.bg[0].cnt.priority.read() and bg_enable & 1 == 1) self.drawBackground(0);
-                    if (layer == self.bg[1].cnt.priority.read() and bg_enable >> 1 & 1 == 1) self.drawBackround(1);
+                    if (layer == self.bg[1].cnt.priority.read() and bg_enable >> 1 & 1 == 1) self.drawBackground(1);
-                    if (layer == self.bg[2].cnt.priority.read() and bg_enable >> 2 & 1 == 1) self.drawBackround(2);
+                    if (layer == self.bg[2].cnt.priority.read() and bg_enable >> 2 & 1 == 1) self.drawBackground(2);
-                    if (layer == self.bg[3].cnt.priority.read() and bg_enable >> 3 & 1 == 1) self.drawBackround(3);
+                    if (layer == self.bg[3].cnt.priority.read() and bg_enable >> 3 & 1 == 1) self.drawBackground(3);
                }
                // Copy Drawn Scanline to Frame Buffer
@ -407,8 +412,8 @@ pub const Ppu = struct {
                var layer: usize = 0;
                while (layer < 4) : (layer += 1) {
                    self.drawSprites(@truncate(u2, layer));
-                    if (layer == self.bg[0].cnt.priority.read() and bg_enable & 1 == 1) self.drawBackround(0);
+                    if (layer == self.bg[0].cnt.priority.read() and bg_enable & 1 == 1) self.drawBackground(0);
-                    if (layer == self.bg[1].cnt.priority.read() and bg_enable >> 1 & 1 == 1) self.drawBackround(1);
+                    if (layer == self.bg[1].cnt.priority.read() and bg_enable >> 1 & 1 == 1) self.drawBackground(1);
                    if (layer == self.bg[2].cnt.priority.read() and bg_enable >> 2 & 1 == 1) self.drawAffineBackground(2);
                }
@ -486,7 +491,7 @@ pub const Ppu = struct {
                while (i < width) : (i += 1) {
                    // If we're outside of the bounds of mode 5, draw the background colour
                    const bgr555 =
-                        if (scanline < m5_height and i < m5_width) self.vram.read(u16, vram_base + i * @sizeOf(u16)) else self.palette.getBackdrop();
+                        if (scanline < m5_height and i < m5_width) self.vram.read(u16, vram_base + i * @sizeOf(u16)) else self.palette.backdrop();
                    std.mem.writeIntNative(u32, self.framebuf.get(.Emulator)[fb_base + i * @sizeOf(u32) ..][0..@sizeOf(u32)], COLOUR_LUT[bgr555 & 0x7FFF]);
                }
@ -530,7 +535,94 @@ pub const Ppu = struct {
        }
        if (maybe_top) |top| return top;
-        return self.palette.getBackdrop();
+        return self.palette.backdrop();
    }
    fn copyToBackgroundBuffer(self: *Self, comptime n: u2, bounds: ?WindowBounds, i: usize, bgr555: u16) void {
        if (self.bldcnt.mode.read() != 0b00) {
            // Standard Alpha Blending
            const a_layers = self.bldcnt.layer_a.read();
            const is_blend_enabled = (a_layers >> n) & 1 == 1;
            // If Alpha Blending is enabled and we've found an eligible layer for
            // Pixel A, store the pixel in the bottom pixel buffer
            const win_part = if (bounds) |win| blk: {
                // Window Enabled
                break :blk switch (win) {
                    .win0 => self.win.in.w0_bld.read(),
                    .win1 => self.win.in.w1_bld.read(),
                    .out => self.win.out.out_bld.read(),
                };
            } else true;
            if (win_part and is_blend_enabled) {
                self.scanline.btm()[i] = bgr555;
                return;
            }
        }
        self.scanline.top()[i] = bgr555;
    }
    const WindowBounds = enum { win0, win1, out };
    fn windowBounds(self: *Self, x: u9, y: u8) ?WindowBounds {
        const win0 = self.dispcnt.win_enable.read() & 1 == 1;
        const win1 = (self.dispcnt.win_enable.read() >> 1) & 1 == 1;
        const winObj = self.dispcnt.obj_win_enable.read();
        if (!(win0 or win1 or winObj)) return null;
        if (win0 and self.win.inRange(0, x, y)) return .win0;
        if (win1 and self.win.inRange(1, x, y)) return .win1;
        return .out;
    }
    fn shouldDrawBackground(self: *Self, comptime n: u2, bounds: ?WindowBounds, i: usize) bool {
        // If a pixel has been drawn on the top layer, it's because:
        // 1. The pixel is to be blended with a pixel on the bottom layer
        // 2. The pixel is not to be blended at all
        // Also, if we find a pixel on the top layer we don't need to bother with this I think?
        if (self.scanline.top()[i] != null) return false;
        if (bounds) |win| {
            switch (win) {
                .win0 => if ((self.win.in.w0_bg.read() >> n) & 1 == 0) return false,
                .win1 => if ((self.win.in.w1_bg.read() >> n) & 1 == 0) return false,
                .out => if ((self.win.out.out_bg.read() >> n) & 1 == 0) return false,
            }
        }
        if (self.scanline.btm()[i] != null) {
            // The pixel found in the bottom layer is:
            // 1. From a higher priority background
            // 2. From a background that is marked for blending (Pixel A)
            // If Alpha Blending isn't enabled, then we've already found a higher prio
            // pixel, we can return early
            if (self.bldcnt.mode.read() != 0b01) return false;
            const b_layers = self.bldcnt.layer_b.read();
            const win_part = if (bounds) |win| blk: {
                // Window Enabled
                break :blk switch (win) {
                    .win0 => self.win.in.w0_bld.read(),
                    .win1 => self.win.in.w1_bld.read(),
                    .out => self.win.out.out_bld.read(),
                };
            } else true;
            // If the Background is not marked for blending, we've already found
            // a higher priority pixel, move on.
            const is_blend_enabled = win_part and ((b_layers >> n) & 1 == 1);
            if (!is_blend_enabled) return false;
        }
        return true;
    }
    // TODO: Comment this + get a better understanding
@ -572,7 +664,7 @@ pub const Ppu = struct {
        // See if HBlank DMA is present and not enabled
        if (!self.dispstat.vblank.read())
-            pollBlankingDma(cpu.bus, .HBlank);
+            dma.onBlanking(cpu.bus, .HBlank);
        self.dispstat.hblank.set();
        self.sched.push(.HBlank, 68 * 4 -| late);
@ -614,7 +706,7 @@ pub const Ppu = struct {
                self.aff_bg[1].latchRefPoints();
                // See if Vblank DMA is present and not enabled
-                pollBlankingDma(cpu.bus, .VBlank);
+                dma.onBlanking(cpu.bus, .VBlank);
            }
            if (scanline == 227) self.dispstat.vblank.unset();
@ -623,158 +715,6 @@ pub const Ppu = struct {
    }
 };
 const Palette = struct {
    const palram_size = 0x400;
    const Self = @This();
    buf: []u8,
    allocator: Allocator,
    fn init(allocator: Allocator) !Self {
        const buf = try allocator.alloc(u8, palram_size);
        std.mem.set(u8, buf, 0);
        return Self{
            .buf = buf,
            .allocator = allocator,
        };
    }
    fn deinit(self: *Self) void {
        self.allocator.free(self.buf);
        self.* = undefined;
    }
    pub fn read(self: *const Self, comptime T: type, address: usize) T {
        const addr = address & 0x3FF;
        return switch (T) {
            u32, u16, u8 => std.mem.readIntSliceLittle(T, self.buf[addr..][0..@sizeOf(T)]),
            else => @compileError("PALRAM: Unsupported read width"),
        };
    }
    pub fn write(self: *Self, comptime T: type, address: usize, value: T) void {
        const addr = address & 0x3FF;
        switch (T) {
            u32, u16 => std.mem.writeIntSliceLittle(T, self.buf[addr..][0..@sizeOf(T)], value),
            u8 => {
                const align_addr = addr & ~@as(u32, 1); // Aligned to Halfword boundary
                std.mem.writeIntSliceLittle(u16, self.buf[align_addr..][0..@sizeOf(u16)], @as(u16, value) * 0x101);
            },
            else => @compileError("PALRAM: Unsupported write width"),
        }
    }
    fn getBackdrop(self: *const Self) u16 {
        return self.read(u16, 0);
    }
 };
 const Vram = struct {
    const vram_size = 0x18000;
    const Self = @This();
    buf: []u8,
    allocator: Allocator,
    fn init(allocator: Allocator) !Self {
        const buf = try allocator.alloc(u8, vram_size);
        std.mem.set(u8, buf, 0);
        return Self{
            .buf = buf,
            .allocator = allocator,
        };
    }
    fn deinit(self: *Self) void {
        self.allocator.free(self.buf);
        self.* = undefined;
    }
    pub fn read(self: *const Self, comptime T: type, address: usize) T {
        const addr = Self.mirror(address);
        return switch (T) {
            u32, u16, u8 => std.mem.readIntSliceLittle(T, self.buf[addr..][0..@sizeOf(T)]),
            else => @compileError("VRAM: Unsupported read width"),
        };
    }
    pub fn write(self: *Self, comptime T: type, dispcnt: io.DisplayControl, address: usize, value: T) void {
        const mode: u3 = dispcnt.bg_mode.read();
        const idx = Self.mirror(address);
        switch (T) {
            u32, u16 => std.mem.writeIntSliceLittle(T, self.buf[idx..][0..@sizeOf(T)], value),
            u8 => {
                // Ignore write if it falls within the boundaries of OBJ VRAM
                switch (mode) {
                    0, 1, 2 => if (0x0001_0000 <= idx) return,
                    else => if (0x0001_4000 <= idx) return,
                }
                const align_idx = idx & ~@as(u32, 1); // Aligned to a halfword boundary
                std.mem.writeIntSliceLittle(u16, self.buf[align_idx..][0..@sizeOf(u16)], @as(u16, value) * 0x101);
            },
            else => @compileError("VRAM: Unsupported write width"),
        }
    }
    fn mirror(address: usize) usize {
        // Mirrored in steps of 128K (64K + 32K + 32K) (abcc)
        const addr = address & 0x1FFFF;
        // If the address is within 96K we don't do anything,
        // otherwise we want to mirror the last 32K (addresses between 64K and 96K)
        return if (addr < vram_size) addr else 0x10000 + (addr & 0x7FFF);
    }
 };
 const Oam = struct {
    const oam_size = 0x400;
    const Self = @This();
    buf: []u8,
    allocator: Allocator,
    fn init(allocator: Allocator) !Self {
        const buf = try allocator.alloc(u8, oam_size);
        std.mem.set(u8, buf, 0);
        return Self{
            .buf = buf,
            .allocator = allocator,
        };
    }
    fn deinit(self: *Self) void {
        self.allocator.free(self.buf);
        self.* = undefined;
    }
    pub fn read(self: *const Self, comptime T: type, address: usize) T {
        const addr = address & 0x3FF;
        return switch (T) {
            u32, u16, u8 => std.mem.readIntSliceLittle(T, self.buf[addr..][0..@sizeOf(T)]),
            else => @compileError("OAM: Unsupported read width"),
        };
    }
    pub fn write(self: *Self, comptime T: type, address: usize, value: T) void {
        const addr = address & 0x3FF;
        switch (T) {
            u32, u16 => std.mem.writeIntSliceLittle(T, self.buf[addr..][0..@sizeOf(T)], value),
            u8 => return, // 8-bit writes are explicitly ignored
            else => @compileError("OAM: Unsupported write width"),
        }
    }
 };
 const Window = struct {
    const Self = @This();
@ -794,6 +734,25 @@ const Window = struct {
        };
    }
    fn inRange(self: *const Self, comptime id: u1, x: u9, y: u8) bool {
        const h = self.h[id];
        const v = self.v[id];
        const y1 = v.y1.read();
        const y2 = if (y1 > v.y2.read()) 160 else std.math.min(160, v.y2.read());
        if (y1 <= y and y < y2) {
            // Within Y bounds
            const x1 = h.x1.read();
            const x2 = if (x1 > h.x2.read()) 240 else std.math.min(240, h.x2.read());
            // Within X Bounds
            return x1 <= x and x < x2;
        }
        return false;
    }
    pub fn setH(self: *Self, value: u32) void {
        self.h[0].raw = @truncate(u16, value);
        self.h[1].raw = @truncate(u16, value >> 16);
@ -1135,37 +1094,6 @@ fn alphaBlend(top: u16, btm: u16, bldalpha: io.BldAlpha) u16 {
    return (bld_b << 10) | (bld_g << 5) | bld_r;
 }
 fn shouldDrawBackground(comptime n: u2, bldcnt: io.BldCnt, scanline: *Scanline, i: usize) bool {
    // If a pixel has been drawn on the top layer, it's because
    // Either the pixel is to be blended with a pixel on the bottom layer
    // or the pixel is not to be blended at all
    // Consequentially, if we find a pixel on the top layer, there's no need
    // to render anything I think?
    if (scanline.top()[i] != null) return false;
    if (scanline.btm()[i] != null) {
        // The Pixel found in the Bottom layer is
        // 1. From a higher priority
        // 2. From a Backround that is marked for Blending (Pixel A)
        //
        // We now have to confirm whether this current Background can be used
        // as Pixel B or not.
        // If Alpha Blending isn't enabled, we've aready found a higher
        // priority pixel to render. Move on
        if (bldcnt.mode.read() != 0b01) return false;
        const b_layers = bldcnt.layer_b.read();
        const is_blend_enabled = (b_layers >> n) & 1 == 1;
        // If the Background is not marked for blending, we've already found
        // a higher priority pixel, move on.
        if (!is_blend_enabled) return false;
    }
    return true;
 }
 fn shouldDrawSprite(bldcnt: io.BldCnt, scanline: *Scanline, x: u9) bool {
    if (scanline.top()[x] != null) return false;
@ -1180,23 +1108,6 @@ fn shouldDrawSprite(bldcnt: io.BldCnt, scanline: *Scanline, x: u9) bool {
    return true;
 }
 fn copyToBackgroundBuffer(comptime n: u2, bldcnt: io.BldCnt, scanline: *Scanline, i: usize, bgr555: u16) void {
    if (bldcnt.mode.read() != 0b00) {
        // Standard Alpha Blending
        const a_layers = bldcnt.layer_a.read();
        const is_blend_enabled = (a_layers >> n) & 1 == 1;
        // If Alpha Blending is enabled and we've found an eligible layer for
        // Pixel A, store the pixel in the bottom pixel buffer
        if (is_blend_enabled) {
            scanline.btm()[i] = bgr555;
            return;
        }
    }
    scanline.top()[i] = bgr555;
 }
 fn copyToSpriteBuffer(bldcnt: io.BldCnt, scanline: *Scanline, x: u9, bgr555: u16) void {
    if (bldcnt.mode.read() != 0b00) {
        // Alpha Blending
@ -1249,48 +1160,3 @@ const Scanline = struct {
        return self.layers[1];
    }
 };
 // Double Buffering Implementation
 const FrameBuffer = struct {
    const Self = @This();
    layers: [2][]u8,
    buf: []u8,
    current: u1,
    allocator: Allocator,
    // TODO: Rename
    const Device = enum {
        Emulator,
        Renderer,
    };
    pub fn init(allocator: Allocator) !Self {
        const framebuf_len = framebuf_pitch * height;
        const buf = try allocator.alloc(u8, framebuf_len * 2);
        std.mem.set(u8, buf, 0);
        return .{
            // Front and Back Framebuffers
            .layers = [_][]u8{ buf[0..][0..framebuf_len], buf[framebuf_len..][0..framebuf_len] },
            .buf = buf,
            .current = 0,
            .allocator = allocator,
        };
    }
    fn deinit(self: *Self) void {
        self.allocator.free(self.buf);
        self.* = undefined;
    }
    pub fn swap(self: *Self) void {
        self.current = ~self.current;
    }
    pub fn get(self: *Self, comptime dev: Device) []u8 {
        return self.layers[if (dev == .Emulator) self.current else ~self.current];
    }
 };
--- a/src/core/ppu/Oam.zig
+++ b/src/core/ppu/Oam.zig
@ -0,0 +1,40 @@
 const std = @import("std");
 const Allocator = std.mem.Allocator;
 const buf_len = 0x400;
 const Self = @This();
 buf: []u8,
 allocator: Allocator,
 pub fn read(self: *const Self, comptime T: type, address: usize) T {
    const addr = address & 0x3FF;
    return switch (T) {
        u32, u16, u8 => std.mem.readIntSliceLittle(T, self.buf[addr..][0..@sizeOf(T)]),
        else => @compileError("OAM: Unsupported read width"),
    };
 }
 pub fn write(self: *Self, comptime T: type, address: usize, value: T) void {
    const addr = address & 0x3FF;
    switch (T) {
        u32, u16 => std.mem.writeIntSliceLittle(T, self.buf[addr..][0..@sizeOf(T)], value),
        u8 => return, // 8-bit writes are explicitly ignored
        else => @compileError("OAM: Unsupported write width"),
    }
 }
 pub fn init(allocator: Allocator) !Self {
    const buf = try allocator.alloc(u8, buf_len);
    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/ppu/Palette.zig
+++ b/src/core/ppu/Palette.zig
@ -0,0 +1,47 @@
 const std = @import("std");
 const Allocator = std.mem.Allocator;
 const buf_len = 0x400;
 const Self = @This();
 buf: []u8,
 allocator: Allocator,
 pub fn read(self: *const Self, comptime T: type, address: usize) T {
    const addr = address & 0x3FF;
    return switch (T) {
        u32, u16, u8 => std.mem.readIntSliceLittle(T, self.buf[addr..][0..@sizeOf(T)]),
        else => @compileError("PALRAM: Unsupported read width"),
    };
 }
 pub fn write(self: *Self, comptime T: type, address: usize, value: T) void {
    const addr = address & 0x3FF;
    switch (T) {
        u32, u16 => std.mem.writeIntSliceLittle(T, self.buf[addr..][0..@sizeOf(T)], value),
        u8 => {
            const align_addr = addr & ~@as(u32, 1); // Aligned to Halfword boundary
            std.mem.writeIntSliceLittle(u16, self.buf[align_addr..][0..@sizeOf(u16)], @as(u16, value) * 0x101);
        },
        else => @compileError("PALRAM: Unsupported write width"),
    }
 }
 pub fn init(allocator: Allocator) !Self {
    const buf = try allocator.alloc(u8, buf_len);
    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;
 }
 pub fn backdrop(self: *const Self) u16 {
    return self.read(u16, 0);
 }
--- a/src/core/ppu/Vram.zig
+++ b/src/core/ppu/Vram.zig
@ -0,0 +1,60 @@
 const std = @import("std");
 const io = @import("../bus/io.zig");
 const Allocator = std.mem.Allocator;
 const buf_len = 0x18000;
 const Self = @This();
 buf: []u8,
 allocator: Allocator,
 pub fn read(self: *const Self, comptime T: type, address: usize) T {
    const addr = Self.mirror(address);
    return switch (T) {
        u32, u16, u8 => std.mem.readIntSliceLittle(T, self.buf[addr..][0..@sizeOf(T)]),
        else => @compileError("VRAM: Unsupported read width"),
    };
 }
 pub fn write(self: *Self, comptime T: type, dispcnt: io.DisplayControl, address: usize, value: T) void {
    const mode: u3 = dispcnt.bg_mode.read();
    const idx = Self.mirror(address);
    switch (T) {
        u32, u16 => std.mem.writeIntSliceLittle(T, self.buf[idx..][0..@sizeOf(T)], value),
        u8 => {
            // Ignore write if it falls within the boundaries of OBJ VRAM
            switch (mode) {
                0, 1, 2 => if (0x0001_0000 <= idx) return,
                else => if (0x0001_4000 <= idx) return,
            }
            const align_idx = idx & ~@as(u32, 1); // Aligned to a halfword boundary
            std.mem.writeIntSliceLittle(u16, self.buf[align_idx..][0..@sizeOf(u16)], @as(u16, value) * 0x101);
        },
        else => @compileError("VRAM: Unsupported write width"),
    }
 }
 pub fn init(allocator: Allocator) !Self {
    const buf = try allocator.alloc(u8, buf_len);
    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;
 }
 fn mirror(address: usize) usize {
    // Mirrored in steps of 128K (64K + 32K + 32K) (abcc)
    const addr = address & 0x1FFFF;
    // If the address is within 96K we don't do anything,
    // otherwise we want to mirror the last 32K (addresses between 64K and 96K)
    return if (addr < buf_len) addr else 0x10000 + (addr & 0x7FFF);
 }
--- a/src/core/util.zig
+++ b/src/core/util.zig
@ -3,6 +3,8 @@ const builtin = @import("builtin");
 const Log2Int = std.math.Log2Int;
 const Arm7tdmi = @import("cpu.zig").Arm7tdmi;
 const Allocator = std.mem.Allocator;
 const allow_unhandled_io = @import("emu.zig").allow_unhandled_io;
 // Sign-Extend value of type `T` to type `U`
@ -172,6 +174,7 @@ pub fn writeUndefined(log: anytype, comptime format: []const u8, args: anytype)
 pub const Logger = struct {
    const Self = @This();
    const FmtArgTuple = std.meta.Tuple(&.{ u32, u32, u32, u32, u32, u32, u32, u32, u32, u32, u32, u32, u32, u32, u32, u32, u32, u32 });
    buf: std.io.BufferedWriter(4096 << 2, std.fs.File.Writer),
@ -229,4 +232,43 @@ pub const Logger = struct {
    }
 };
-const FmtArgTuple = std.meta.Tuple(&.{ u32, u32, u32, u32, u32, u32, u32, u32, u32, u32, u32, u32, u32, u32, u32, u32, u32, u32 });
+// Double Buffering Implementation
 pub const FrameBuffer = struct {
    const Self = @This();
    layers: [2][]u8,
    buf: []u8,
    current: u1,
    allocator: Allocator,
    // TODO: Rename
    const Device = enum { Emulator, Renderer };
    pub fn init(allocator: Allocator, comptime len: comptime_int) !Self {
        const buf = try allocator.alloc(u8, len * 2);
        std.mem.set(u8, buf, 0);
        return .{
            // Front and Back Framebuffers
            .layers = [_][]u8{ buf[0..][0..len], buf[len..][0..len] },
            .buf = buf,
            .current = 0,
            .allocator = allocator,
        };
    }
    pub fn deinit(self: *Self) void {
        self.allocator.free(self.buf);
        self.* = undefined;
    }
    pub fn swap(self: *Self) void {
        self.current = ~self.current;
    }
    pub fn get(self: *Self, comptime dev: Device) []u8 {
        return self.layers[if (dev == .Emulator) self.current else ~self.current];
    }
 };
Author	SHA1	Message	Date
Rekai Nyangadzayi Musuka	d645827a19	chore: dont allocate not-small ?Sprite array on stack use memset like most other allocations in this emu	2022-09-18 09:20:47 -03:00
Rekai Nyangadzayi Musuka	8f9dc9d33c	chore: move FrameBuffer struct to util.zig	2022-09-18 09:20:47 -03:00
Rekai Nyangadzayi Musuka	cd985eec94	chore: move OAM, PALRAM and VRAM structs to separate files	2022-09-18 09:20:47 -03:00
Rekai Nyangadzayi Musuka	19498f157a	fix: 8-bit writes to WIN PPU registers Advance Wars depends on these registers similar to Mario Kart's 8-bit writes to Affine Background registers:	2022-09-18 09:20:47 -03:00
Rekai Nyangadzayi Musuka	9a48d1aa94	chore: refactor window	2022-09-18 09:20:47 -03:00
Rekai Nyangadzayi Musuka	cc6c8f1552	chore: crude background window impl (no affine)	2022-09-18 09:20:47 -03:00
Rekai Nyangadzayi Musuka	5a1f81093b	chore: rename function (misspelt until now somehow)	2022-09-18 09:20:47 -03:00