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, .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 is an Uppercase ASCII string which is /// null-padded to 12 bytes /// /// This function returns a slice of the ASCII string without the null terminator(s) /// (essentially, a proper Zig/Rust/Any modern language String) pub fn span(title: *const [12]u8) []const u8 { const end = std.mem.indexOfScalar(u8, title, '\x00'); return title[0 .. end orelse title.len]; } test "span" { var example: *const [12]u8 = "POKEMON_EMER"; try std.testing.expectEqualSlices(u8, "POKEMON_EMER", span(example)); example = "POKEMON_EME\x00"; try std.testing.expectEqualSlices(u8, "POKEMON_EME", span(example)); example = "POKEMON_EM\x00\x00"; try std.testing.expectEqualSlices(u8, "POKEMON_EM", span(example)); example = "POKEMON_E\x00\x00\x00"; try std.testing.expectEqualSlices(u8, "POKEMON_E", span(example)); example = "POKEMON_\x00\x00\x00\x00"; try std.testing.expectEqualSlices(u8, "POKEMON_", span(example)); example = "POKEMON\x00\x00\x00\x00\x00"; try std.testing.expectEqualSlices(u8, "POKEMON", span(example)); example = "POKEMO\x00\x00\x00\x00\x00\x00"; try std.testing.expectEqualSlices(u8, "POKEMO", span(example)); example = "POKEM\x00\x00\x00\x00\x00\x00\x00"; try std.testing.expectEqualSlices(u8, "POKEM", span(example)); example = "POKE\x00\x00\x00\x00\x00\x00\x00\x00"; try std.testing.expectEqualSlices(u8, "POKE", span(example)); example = "POK\x00\x00\x00\x00\x00\x00\x00\x00\x00"; try std.testing.expectEqualSlices(u8, "POK", span(example)); example = "PO\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00"; try std.testing.expectEqualSlices(u8, "PO", span(example)); example = "P\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00"; try std.testing.expectEqualSlices(u8, "P", span(example)); example = "\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00"; try std.testing.expectEqualSlices(u8, "", span(example)); } /// 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]); 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 = std.meta.Tuple(&.{ 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; } } } }; }; }; /// Calculates the correct shift offset for an aligned/unaligned u8 read /// /// TODO: Rename this pub inline fn shift(byte: u8) u4 { return @truncate(u4, byte & 1) << 3; } /// Sets the high bits of an integer to a value pub inline fn setLo(comptime T: type, left: T, right: HalfInt(T)) T { return switch (T) { u32 => (left & 0xFFFF_0000) | right, u16 => (left & 0xFF00) | right, u8 => (left & 0xF0) | right, else => @compileError("unsupported type"), }; } /// sets the low bits of an integer to a value pub inline fn setHi(comptime T: type, left: T, right: HalfInt(T)) T { return switch (T) { u32 => (left & 0x0000_FFFF) | @as(u32, right) << 16, u16 => (left & 0x00FF) | @as(u16, right) << 8, u8 => (left & 0x0F) | @as(u8, right) << 4, 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); }