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paoda:april-fools
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paoda:apu-things
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11 Commits
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Author SHA1 Message Date
Rekai Nyangadzayi Musuka 7233be1ca1 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
 2022-09-09 05:20:24 -03:00
Rekai Nyangadzayi Musuka b4fcaddf80 chore: dump pipeline state on cpu panic 2022-09-09 05:20:24 -03:00
Rekai Nyangadzayi Musuka e496f830f6 fix: reimpl THUMB.5 instructions 
pipeline branch now passes arm.gba and thumb.gba again

(TODO: Stop rewriting my commits away)
 2022-09-09 05:20:24 -03:00
Rekai Nyangadzayi Musuka 5211f0ca70 fix: impl workaround for stage2 miscompilation 2022-09-09 05:20:24 -03:00
Rekai Nyangadzayi Musuka b6e91cbca1 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
 2022-09-09 05:20:24 -03:00
Rekai Nyangadzayi Musuka 323753e77a fix: reimpl handleInterrupt code 2022-09-09 05:20:24 -03:00
Rekai Nyangadzayi Musuka 4aa63e318b feat: implement basic pipeline 
passes arm.gba, thumb.gb and armwrestler, fails in actual games
TODO: run FuzzARM debug specific titles
 2022-09-09 05:20:20 -03:00
Rekai Nyangadzayi Musuka 5b75844d88 feat: resolve off-by-{word, halfword} errors when printing debug info 2022-09-09 05:17:30 -03:00
Rekai Nyangadzayi Musuka c97abea94a feat: reimplement cpu logging 2022-09-09 05:17:30 -03:00
Rekai Nyangadzayi 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 Nyangadzayi Musuka fa862f095a chore: move arm/thumb lut idx functions 2022-09-06 23:58:24 -03:00
17 changed files with 537 additions and 239 deletions
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4
src/Gui.zig
View File

@ -180,11 +180,11 @@ const Audio = struct {
export fn callback(userdata: ?*anyopaque, stream: [*c]u8, len: c_int) void { export fn callback(userdata: ?*anyopaque, stream: [*c]u8, len: c_int) void {
const apu = @ptrCast(*Apu, @alignCast(@alignOf(*Apu), userdata)); const apu = @ptrCast(*Apu, @alignCast(@alignOf(*Apu), userdata));
const written = SDL.SDL_AudioStreamGet(apu.stream, stream, len); _ = SDL.SDL_AudioStreamGet(apu.stream, stream, len);
// If we don't write anything, play silence otherwise garbage will be played // 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: // 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); // if (written == 0) std.mem.set(u8, stream[0..@intCast(usize, len)], 0x40);
} }
}; };

46
src/core/apu.zig
View File

@ -163,6 +163,8 @@ pub const Apu = struct {
fs: FrameSequencer, fs: FrameSequencer,
capacitor: f32, capacitor: f32,
is_buffer_full: bool,
pub fn init(sched: *Scheduler) Self { pub fn init(sched: *Scheduler) Self {
const apu: Self = .{ const apu: Self = .{
.ch1 = ToneSweep.init(sched), .ch1 = ToneSweep.init(sched),
@ -178,11 +180,12 @@ pub const Apu = struct {
.bias = .{ .raw = 0x0200 }, .bias = .{ .raw = 0x0200 },
.sampling_cycle = 0b00, .sampling_cycle = 0b00,
.stream = SDL.SDL_NewAudioStream(SDL.AUDIO_U16, 2, 1 << 15, SDL.AUDIO_U16, 2, host_sample_rate) orelse unreachable, .stream = SDL.SDL_NewAudioStream(SDL.AUDIO_U16, 2, 1 << 15, SDL.AUDIO_U16, 2, host_sample_rate).?,
.sched = sched, .sched = sched,
.capacitor = 0, .capacitor = 0,
.fs = FrameSequencer.init(), .fs = FrameSequencer.init(),
.is_buffer_full = false,
}; };
sched.push(.SampleAudio, apu.sampleTicks()); sched.push(.SampleAudio, apu.sampleTicks());
@ -277,6 +280,13 @@ pub const Apu = struct {
} }
pub fn sampleAudio(self: *Self, late: u64) void { pub fn sampleAudio(self: *Self, late: u64) void {
self.sched.push(.SampleAudio, self.sampleTicks() -| late);
// Whether the APU is busy or not is determined by the main loop in emu.zig
// This should only ever be true (because this side of the emu is single threaded)
// When audio sync is disaabled
if (self.is_buffer_full) return;
var left: i16 = 0; var left: i16 = 0;
var right: i16 = 0; var right: i16 = 0;
@ -325,28 +335,30 @@ pub const Apu = struct {
left += bias; left += bias;
right += bias; right += bias;
const tmp_left = std.math.clamp(@bitCast(u16, left), std.math.minInt(u11), std.math.maxInt(u11)); const clamped_left = std.math.clamp(@bitCast(u16, left), std.math.minInt(u11), std.math.maxInt(u11));
const tmp_right = std.math.clamp(@bitCast(u16, right), std.math.minInt(u11), std.math.maxInt(u11)); const clamped_right = std.math.clamp(@bitCast(u16, right), std.math.minInt(u11), std.math.maxInt(u11));
// Extend to 16-bit signed audio samples // Extend to 16-bit signed audio samples
const final_left = (tmp_left << 5) | (tmp_left >> 6); const ext_left = (clamped_left << 5) | (clamped_left >> 6);
const final_right = (tmp_right << 5) | (tmp_right >> 6); const ext_right = (clamped_right << 5) | (clamped_right >> 6);
if (self.sampling_cycle != self.bias.sampling_cycle.read()) { // FIXME: This rarely happens
const new_sample_rate = Self.sampleRate(self.bias.sampling_cycle.read()); if (self.sampling_cycle != self.bias.sampling_cycle.read()) self.replaceSDLResampler();
log.info("Sample Rate changed from {}Hz to {}Hz", .{ Self.sampleRate(self.sampling_cycle), new_sample_rate });
// Sample Rate Changed, Create a new Resampler since i can't figure out how to change _ = SDL.SDL_AudioStreamPut(self.stream, &[2]u16{ ext_left, ext_right }, 2 * @sizeOf(u16));
// the parameters of the old one
const old = self.stream;
defer SDL.SDL_FreeAudioStream(old);
self.sampling_cycle = self.bias.sampling_cycle.read();
self.stream = SDL.SDL_NewAudioStream(SDL.AUDIO_U16, 2, @intCast(c_int, new_sample_rate), SDL.AUDIO_U16, 2, host_sample_rate) orelse unreachable;
} }
_ = SDL.SDL_AudioStreamPut(self.stream, &[2]u16{ final_left, final_right }, 2 * @sizeOf(u16)); fn replaceSDLResampler(self: *Self) void {
self.sched.push(.SampleAudio, self.sampleTicks() -| late); const sample_rate = Self.sampleRate(self.bias.sampling_cycle.read());
log.info("Sample Rate changed from {}Hz to {}Hz", .{ Self.sampleRate(self.sampling_cycle), sample_rate });
// Sampling Cycle (Sample Rate) changed, Craete a new SDL Audio Resampler
// FIXME: Replace SDL's Audio Resampler with either a custom or more reliable one
const old_stream = self.stream;
defer SDL.SDL_FreeAudioStream(old_stream);
self.sampling_cycle = self.bias.sampling_cycle.read();
self.stream = SDL.SDL_NewAudioStream(SDL.AUDIO_U16, 2, @intCast(c_int, sample_rate), SDL.AUDIO_U16, 2, host_sample_rate).?;
} }
fn sampleTicks(self: *const Self) u64 { fn sampleTicks(self: *const Self) u64 {

157
src/core/cpu.zig
View File

@ -28,9 +28,14 @@ pub const arm = struct {
const multiply = @import("cpu/arm/multiply.zig").multiply; const multiply = @import("cpu/arm/multiply.zig").multiply;
const multiplyLong = @import("cpu/arm/multiply.zig").multiplyLong; 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 // Undefined ARM Instruction handler
fn und(cpu: *Arm7tdmi, _: *Bus, opcode: u32) void { 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 }); cpu.panic("[CPU/Decode] ID: 0x{X:0>3} 0x{X:0>8} is an illegal opcode", .{ id, opcode });
} }
@ -120,9 +125,14 @@ pub const thumb = struct {
const swi = @import("cpu/thumb/software_interrupt.zig").fmt17; const swi = @import("cpu/thumb/software_interrupt.zig").fmt17;
const branch = @import("cpu/thumb/branch.zig"); 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 /// Undefined THUMB Instruction Handler
fn und(cpu: *Arm7tdmi, _: *Bus, opcode: u16) void { 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 }); cpu.panic("[CPU/Decode] ID: 0b{b:0>10} 0x{X:0>2} is an illegal opcode", .{ id, opcode });
} }
@ -233,6 +243,7 @@ pub const Arm7tdmi = struct {
const Self = @This(); const Self = @This();
r: [16]u32, r: [16]u32,
pipe: Pipline,
sched: *Scheduler, sched: *Scheduler,
bus: *Bus, bus: *Bus,
cpsr: PSR, cpsr: PSR,
@ -253,6 +264,7 @@ pub const Arm7tdmi = struct {
pub fn init(sched: *Scheduler, bus: *Bus, log_file: ?std.fs.File) Self { pub fn init(sched: *Scheduler, bus: *Bus, log_file: ?std.fs.File) Self {
return Self{ return Self{
.r = [_]u32{0x00} ** 16, .r = [_]u32{0x00} ** 16,
.pipe = Pipline.init(),
.sched = sched, .sched = sched,
.bus = bus, .bus = bus,
.cpsr = .{ .raw = 0x0000_001F }, .cpsr = .{ .raw = 0x0000_001F },
@ -312,8 +324,21 @@ pub const Arm7tdmi = struct {
return self.bus.io.haltcnt == .Halt; return self.bus.io.haltcnt == .Halt;
} }
pub fn setCpsrNoFlush(self: *Self, value: u32) void {
if (value & 0x1F != self.cpsr.raw & 0x1F) self.changeModeFromIdx(@truncate(u5, value & 0x1F));
self.cpsr.raw = value;
}
pub fn setCpsr(self: *Self, value: u32) void { pub fn setCpsr(self: *Self, value: u32) void {
if (value & 0x1F != self.cpsr.raw & 0x1F) self.changeModeFromIdx(@truncate(u5, value & 0x1F)); if (value & 0x1F != self.cpsr.raw & 0x1F) self.changeModeFromIdx(@truncate(u5, value & 0x1F));
const new: PSR = .{ .raw = value };
if (self.cpsr.t.read() != new.t.read()) {
// If THUMB to ARM or ARM to THUMB, flush pipeline
self.r[15] &= if (new.t.read()) ~@as(u32, 1) else ~@as(u32, 3);
if (new.t.read()) self.pipe.reload(u16, self) else self.pipe.reload(u32, self);
}
self.cpsr.raw = value; self.cpsr.raw = value;
} }
@ -404,31 +429,35 @@ pub const Arm7tdmi = struct {
pub fn fastBoot(self: *Self) void { pub fn fastBoot(self: *Self) void {
self.r = std.mem.zeroes([16]u32); 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[13] = 0x0300_7F00;
self.r[15] = 0x0800_0000; self.r[15] = 0x0800_0000;
self.banked_r[bankedIdx(.Irq, .R13)] = 0x0300_7FA0; self.banked_r[bankedIdx(.Irq, .R13)] = 0x0300_7FA0;
self.banked_r[bankedIdx(.Supervisor, .R13)] = 0x0300_7FE0; self.banked_r[bankedIdx(.Supervisor, .R13)] = 0x0300_7FE0;
self.cpsr.raw = 0x6000001F; // self.cpsr.raw = 0x6000001F;
self.cpsr.raw = 0x0000_001F;
} }
pub fn step(self: *Self) void { pub fn step(self: *Self) void {
if (self.cpsr.t.read()) { if (self.cpsr.t.read()) blk: {
const opcode = self.fetch(u16); const opcode = @truncate(u16, self.pipe.step(self, u16) orelse break :blk);
if (cpu_logging) self.logger.?.mgbaLog(self, opcode); if (cpu_logging) self.logger.?.mgbaLog(self, opcode);
thumb.lut[thumbIdx(opcode)](self, self.bus, opcode); thumb.lut[thumb.idx(opcode)](self, self.bus, opcode);
} else { } else blk: {
const opcode = self.fetch(u32); const opcode = self.pipe.step(self, u32) orelse break :blk;
if (cpu_logging) self.logger.?.mgbaLog(self, opcode); if (cpu_logging) self.logger.?.mgbaLog(self, opcode);
if (checkCond(self.cpsr, @truncate(u4, opcode >> 28))) { 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);
} }
} }
if (!self.pipe.flushed) self.r[15] += if (self.cpsr.t.read()) 2 else @as(u32, 4);
self.pipe.flushed = false;
} }
pub fn stepDmaTransfer(self: *Self) bool { pub fn stepDmaTransfer(self: *Self) bool {
@ -463,27 +492,26 @@ pub const Arm7tdmi = struct {
pub fn handleInterrupt(self: *Self) void { pub fn handleInterrupt(self: *Self) void {
const should_handle = self.bus.io.ie.raw & self.bus.io.irq.raw; 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
if (!self.bus.io.ime or self.cpsr.i.read() or should_handle == 0) return;
// If pipeline isn't full, return but reschedule the handling of the event
if (!self.pipe.isFull()) return;
// log.debug("Handling Interrupt!", .{});
self.bus.io.haltcnt = .Execute; self.bus.io.haltcnt = .Execute;
// log.debug("An Interrupt was Fired!", .{});
// Either IME is not true or I in CPSR is true const ret_addr = self.r[15] - if (self.cpsr.t.read()) 2 else @as(u32, 4);
// Don't handle interrupts const new_spsr = self.cpsr.raw;
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
const r15 = self.r[15] + 4;
const cpsr = self.cpsr.raw;
self.changeMode(.Irq); self.changeMode(.Irq);
self.cpsr.t.write(false); self.cpsr.t.write(false);
self.cpsr.i.write(true); self.cpsr.i.write(true);
self.r[14] = r15; self.r[14] = ret_addr;
self.spsr.raw = cpsr; self.spsr.raw = new_spsr;
self.r[15] = 0x000_0018; self.r[15] = 0x0000_0018;
} self.pipe.reload(u32, self);
} }
inline fn fetch(self: *Self, comptime T: type) T { inline fn fetch(self: *Self, comptime T: type) T {
@ -497,8 +525,12 @@ pub const Arm7tdmi = struct {
return self.bus.read(T, self.r[15]); return self.bus.read(T, self.r[15]);
} }
pub fn fakePC(self: *const Self) u32 { fn debug_log(self: *const Self, file: *const File, opcode: u32) void {
return self.r[15] + 4; if (self.binary_log) {
self.skyLog(file) catch unreachable;
} else {
self.mgbaLog(file, opcode) catch unreachable;
}
} }
pub fn panic(self: *const Self, comptime format: []const u8, args: anytype) noreturn { pub fn panic(self: *const Self, comptime format: []const u8, args: anytype) noreturn {
@ -515,13 +547,15 @@ pub const Arm7tdmi = struct {
std.debug.print("spsr: 0x{X:0>8} ", .{self.spsr.raw}); std.debug.print("spsr: 0x{X:0>8} ", .{self.spsr.raw});
prettyPrintPsr(&self.spsr); prettyPrintPsr(&self.spsr);
std.debug.print("pipeline: {??X:0>8}\n", .{self.pipe.stage});
if (self.cpsr.t.read()) { if (self.cpsr.t.read()) {
const opcode = self.bus.dbgRead(u16, self.r[15] - 4); 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 }); std.debug.print("opcode: ID: 0x{b:0>10} 0x{X:0>4}\n", .{ id, opcode });
} else { } else {
const opcode = self.bus.dbgRead(u32, self.r[15] - 4); 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 }); std.debug.print("opcode: ID: 0x{X:0>3} 0x{X:0>8}\n", .{ id, opcode });
} }
@ -578,7 +612,7 @@ pub const Arm7tdmi = struct {
const r12 = self.r[12]; const r12 = self.r[12];
const r13 = self.r[13]; const r13 = self.r[13];
const r14 = self.r[14]; const r14 = self.r[14];
const r15 = self.r[15]; const r15 = self.r[15] -| if (self.cpsr.t.read()) 2 else @as(u32, 4);
const c_psr = self.cpsr.raw; const c_psr = self.cpsr.raw;
@ -586,7 +620,7 @@ pub const Arm7tdmi = struct {
if (self.cpsr.t.read()) { if (self.cpsr.t.read()) {
if (opcode >> 11 == 0x1E) { if (opcode >> 11 == 0x1E) {
// Instruction 1 of a BL Opcode, print in ARM mode // Instruction 1 of a BL Opcode, print in ARM mode
const other_half = self.bus.dbgRead(u16, self.r[15]); const other_half = self.bus.debugRead(u16, self.r[15] - 2);
const bl_opcode = @as(u32, opcode) << 16 | other_half; 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 }); 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 });
@ -601,14 +635,6 @@ pub const Arm7tdmi = struct {
} }
}; };
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 { pub fn checkCond(cpsr: PSR, cond: u4) bool {
return switch (cond) { return switch (cond) {
0x0 => cpsr.z.read(), // EQ - Equal 0x0 => cpsr.z.read(), // EQ - Equal
@ -630,6 +656,59 @@ pub fn checkCond(cpsr: PSR, cond: u4) bool {
}; };
} }
const Pipline = struct {
const Self = @This();
stage: [2]?u32,
flushed: bool,
fn init() Self {
return .{
.stage = [_]?u32{null} ** 2,
.flushed = false,
};
}
pub fn flush(self: *Self) void {
for (self.stage) |*opcode| opcode.* = null;
self.flushed = true;
// Note: If using this, add
// if (!self.pipe.flushed) self.r[15] += if (self.cpsr.t.read()) 2 else @as(u32, 4);
// to the end of Arm7tdmi.step
}
pub fn isFull(self: *const Self) bool {
return self.stage[0] != null and self.stage[1] != null;
}
pub fn step(self: *Self, cpu: *Arm7tdmi, comptime T: type) ?u32 {
comptime std.debug.assert(T == u32 or T == u16);
// FIXME: https://github.com/ziglang/zig/issues/12642
const opcode = self.stage[0..1][0];
self.stage[0] = self.stage[1];
self.stage[1] = cpu.bus.read(T, cpu.r[15]);
return opcode;
}
pub fn reload(self: *Self, comptime T: type, cpu: *Arm7tdmi) void {
comptime std.debug.assert(T == u32 or T == u16);
// Sometimes, the pipeline can be reloaded twice in the same instruction
// This can happen if:
// 1. R15 is written to
// 2. The CPSR is written to (and T changes), so R15 is written to again
self.stage[0] = cpu.bus.read(T, cpu.r[15]);
self.stage[1] = cpu.bus.read(T, cpu.r[15] + if (T == u32) 4 else @as(u32, 2));
cpu.r[15] += if (T == u32) 8 else @as(u32, 4);
self.flushed = true;
}
};
pub const PSR = extern union { pub const PSR = extern union {
mode: Bitfield(u32, 0, 5), mode: Bitfield(u32, 0, 5),
t: Bit(u32, 5), t: Bit(u32, 5),

18
src/core/cpu/arm/block_data_transfer.zig
View File

@ -55,8 +55,10 @@ pub fn blockDataTransfer(comptime P: bool, comptime U: bool, comptime S: bool, c
if (L) { if (L) {
cpu.r[15] = bus.read(u32, und_addr); cpu.r[15] = bus.read(u32, und_addr);
cpu.pipe.reload(u32, cpu);
} else { } else {
bus.write(u32, und_addr, cpu.r[15] + 8); // FIXME: Should r15 on write be +12 ahead?
bus.write(u32, und_addr, cpu.r[15] + 4);
} }
cpu.r[rn] = if (U) cpu.r[rn] + 0x40 else cpu.r[rn] - 0x40; cpu.r[rn] = if (U) cpu.r[rn] + 0x40 else cpu.r[rn] - 0x40;
@ -86,17 +88,23 @@ pub fn blockDataTransfer(comptime P: bool, comptime U: bool, comptime S: bool, c
cpu.setUserModeRegister(i, bus.read(u32, address)); cpu.setUserModeRegister(i, bus.read(u32, address));
} else { } else {
const value = bus.read(u32, address); 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(u32, cpu);
if (S) cpu.setCpsr(cpu.spsr.raw);
}
} }
} else { } else {
if (S) { if (S) {
// Always Transfer User mode Registers // Always Transfer User mode Registers
// This happens regardless if r15 is in the list // This happens regardless if r15 is in the list
const value = cpu.getUserModeRegister(i); 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 { } 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));
} }
} }
} }

14
src/core/cpu/arm/branch.zig
View File

@ -9,14 +9,20 @@ const sext = @import("../../util.zig").sext;
pub fn branch(comptime L: bool) InstrFn { pub fn branch(comptime L: bool) InstrFn {
return struct { return struct {
fn inner(cpu: *Arm7tdmi, _: *Bus, opcode: u32) void { 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(u32, cpu);
} }
}.inner; }.inner;
} }
pub fn branchAndExchange(cpu: *Arm7tdmi, _: *Bus, opcode: u32) void { pub fn branchAndExchange(cpu: *Arm7tdmi, _: *Bus, opcode: u32) void {
const rn = opcode & 0xF; 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);
if (thumb) cpu.pipe.reload(u16, cpu) else cpu.pipe.reload(u32, cpu);
} }

349
src/core/cpu/arm/data_processing.zig
View File

@ -5,7 +5,7 @@ const InstrFn = @import("../../cpu.zig").arm.InstrFn;
const rotateRight = @import("../barrel_shifter.zig").rotateRight; const rotateRight = @import("../barrel_shifter.zig").rotateRight;
const execute = @import("../barrel_shifter.zig").execute; const execute = @import("../barrel_shifter.zig").execute;
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 { return struct {
fn inner(cpu: *Arm7tdmi, _: *Bus, opcode: u32) void { fn inner(cpu: *Arm7tdmi, _: *Bus, opcode: u32) void {
const rd = @truncate(u4, opcode >> 12 & 0xF); const rd = @truncate(u4, opcode >> 12 & 0xF);
@ -13,124 +13,276 @@ pub fn dataProcessing(comptime I: bool, comptime S: bool, comptime instrKind: u4
const old_carry = @boolToInt(cpu.cpsr.c.read()); const old_carry = @boolToInt(cpu.cpsr.c.read());
// If certain conditions are met, PC is 12 ahead instead of 8 // 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; 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];
var op2: u32 = undefined;
if (I) {
const amount = @truncate(u8, (opcode >> 8 & 0xF) << 1); const amount = @truncate(u8, (opcode >> 8 & 0xF) << 1);
op2 = rotateRight(S, &cpu.cpsr, opcode & 0xFF, amount); const op2 = if (I) rotateRight(S, &cpu.cpsr, opcode & 0xFF, amount) else execute(S, cpu, opcode);
} else {
op2 = execute(S, cpu, opcode);
}
// Undo special condition from above // Undo special condition from above
if (!I and opcode >> 4 & 1 == 1) cpu.r[15] -= 4; if (!I and opcode >> 4 & 1 == 1) cpu.r[15] -= 4;
switch (instrKind) { var result: u32 = undefined;
0x0 => { var didOverflow: 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 = newAdd(&didOverflow, op1, op2), // ADD
cpu.r[rd] = result; 0x5 => result = newAdc(&didOverflow, op1, op2, old_carry), // ADC
setArmLogicOpFlags(S, cpu, rd, result); 0x6 => result = newSbc(op1, op2, old_carry), // SBC
}, 0x7 => result = newSbc(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 => { 0x8 => {
// TST // 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 => { 0x9 => {
// TEQ // 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 => { 0xA => {
// CMP // CMP
if (rd == 0xF) { if (rd == 0xF)
undefinedTestBehaviour(cpu); return undefinedTestBehaviour(cpu);
return;
}
cmp(cpu, op1, op2); result = op1 -% op2;
}, },
0xB => { 0xB => {
// CMN // CMN
if (rd == 0xF) { if (rd == 0xF)
undefinedTestBehaviour(cpu); return undefinedTestBehaviour(cpu);
return;
didOverflow = @addWithOverflow(u32, op1, op2, &result);
},
0xC => result = op1 | op2, // ORR
0xD => result = op2, // MOV
0xE => result = op1 & ~op2, // BIC
0xF => result = ~op2, // MVN
} }
cmn(cpu, op1, op2); // Write to Destination Register
}, switch (kind) {
0xC => { 0x8, 0x9, 0xA, 0xB => {}, // Test Operations
// ORR else => {
const result = op1 | op2;
cpu.r[rd] = result; cpu.r[rd] = result;
setArmLogicOpFlags(S, cpu, rd, result); if (rd == 0xF) cpu.pipe.reload(u32, cpu);
}, },
0xD => { }
// MOV
cpu.r[rd] = op2; // Write Flags
setArmLogicOpFlags(S, cpu, rd, op2); switch (kind) {
0x0, 0x1, 0xC, 0xD, 0xE, 0xF => {
// Logic Operation Flags
if (S) {
if (rd == 0xF) {
cpu.setCpsr(cpu.spsr.raw);
} else {
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 => {
// BIC // SUB, RSB Flags
const result = op1 & ~op2; if (S) {
cpu.r[rd] = result; cpu.cpsr.n.write(result >> 31 & 1 == 1);
setArmLogicOpFlags(S, cpu, rd, result); cpu.cpsr.z.write(result == 0);
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);
}
if (rd == 0xF) cpu.setCpsr(cpu.spsr.raw);
}
}, },
0xF => { 0x4, 0x5 => {
// MVN // ADD, ADC Flags
const result = ~op2; if (S) {
cpu.r[rd] = result; cpu.cpsr.n.write(result >> 31 & 1 == 1);
setArmLogicOpFlags(S, cpu, rd, result); cpu.cpsr.z.write(result == 0);
cpu.cpsr.c.write(didOverflow);
cpu.cpsr.v.write(((op1 ^ result) & (op2 ^ result)) >> 31 & 1 == 1);
if (rd == 0xF) cpu.setCpsr(cpu.spsr.raw);
}
},
0x6, 0x7 => {
// SBC, RSC Flags
if (S) {
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);
}
if (rd == 0xF) cpu.setCpsr(cpu.spsr.raw);
}
},
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(didOverflow);
cpu.cpsr.v.write(((op1 ^ result) & (op2 ^ result)) >> 31 & 1 == 1);
} else {
// TEST, TEQ specific
// Barrel Shifter should always calc CPSR C in TST
if (!S) _ = execute(true, cpu, opcode);
}
}, },
} }
} }
}.inner; }.inner;
} }
// pub fn dataProcessing(comptime I: bool, comptime S: bool, comptime instrKind: u4) InstrFn {
// return struct {
// fn inner(cpu: *Arm7tdmi, _: *Bus, opcode: u32) void {
// const rd = @truncate(u4, opcode >> 12 & 0xF);
// const rn = opcode >> 16 & 0xF;
// const old_carry = @boolToInt(cpu.cpsr.c.read());
// // If certain conditions are met, PC is 12 ahead instead of 8
// // TODO: What are these conditions? I can't remember
// if (!I and opcode >> 4 & 1 == 1) cpu.r[15] += 4;
// const op1 = cpu.r[rn];
// const amount = @truncate(u8, (opcode >> 8 & 0xF) << 1);
// const op2 = if (I) rotateRight(S, &cpu.cpsr, opcode & 0xFF, amount) else execute(S, cpu, opcode);
// // Undo special condition from above
// if (!I and opcode >> 4 & 1 == 1) cpu.r[15] -= 4;
// switch (instrKind) {
// 0x0 => {
// // AND
// const result = op1 & op2;
// cpu.r[rd] = result;
// setArmLogicOpFlags(S, cpu, rd, result);
// },
// 0x1 => {
// // EOR
// const result = op1 ^ op2;
// cpu.r[rd] = result;
// setArmLogicOpFlags(S, cpu, rd, result);
// },
// 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)
// return undefinedTestBehaviour(cpu);
// const result = op1 & op2;
// setTestOpFlags(S, cpu, opcode, result);
// },
// 0x9 => {
// // TEQ
// if (rd == 0xF)
// return undefinedTestBehaviour(cpu);
// const result = op1 ^ op2;
// setTestOpFlags(S, cpu, opcode, result);
// },
// 0xA => {
// // CMP
// if (rd == 0xF)
// return undefinedTestBehaviour(cpu);
// cmp(cpu, op1, op2);
// },
// 0xB => {
// // CMN
// if (rd == 0xF)
// return undefinedTestBehaviour(cpu);
// cmn(cpu, op1, op2);
// },
// 0xC => {
// // ORR
// const result = op1 | op2;
// cpu.r[rd] = result;
// setArmLogicOpFlags(S, cpu, rd, result);
// },
// 0xD => {
// // MOV
// cpu.r[rd] = op2;
// setArmLogicOpFlags(S, cpu, rd, op2);
// },
// 0xE => {
// // BIC
// const result = op1 & ~op2;
// cpu.r[rd] = result;
// setArmLogicOpFlags(S, cpu, rd, result);
// },
// 0xF => {
// // MVN
// const result = ~op2;
// cpu.r[rd] = result;
// setArmLogicOpFlags(S, cpu, rd, result);
// },
// }
// if (rd == 0xF) cpu.pipe.reload(u32, cpu);
// }
// }.inner;
// }
fn armSbc(comptime S: bool, cpu: *Arm7tdmi, rd: u4, left: u32, right: u32, old_carry: u1) u32 { fn armSbc(comptime S: bool, cpu: *Arm7tdmi, rd: u4, left: u32, right: u32, old_carry: u1) u32 {
var result: u32 = undefined; var result: u32 = undefined;
if (S and rd == 0xF) { if (S and rd == 0xF) {
@ -143,6 +295,14 @@ fn armSbc(comptime S: bool, cpu: *Arm7tdmi, rd: u4, left: u32, right: u32, old_c
return result; return result;
} }
fn newSbc(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 ret = @truncate(u32, left -% subtrahend);
return ret;
}
pub fn sbc(comptime S: bool, cpu: *Arm7tdmi, left: u32, right: u32, old_carry: u1) u32 { pub fn sbc(comptime S: bool, cpu: *Arm7tdmi, left: u32, right: u32, old_carry: u1) u32 {
// TODO: Make your own version (thanks peach.bot) // TODO: Make your own version (thanks peach.bot)
const subtrahend = @as(u64, right) -% old_carry +% 1; const subtrahend = @as(u64, right) -% old_carry +% 1;
@ -195,6 +355,12 @@ fn armAdd(comptime S: bool, cpu: *Arm7tdmi, rd: u4, left: u32, right: u32) u32 {
return result; return result;
} }
fn newAdd(didOverflow: *bool, left: u32, right: u32) u32 {
var ret: u32 = undefined;
didOverflow.* = @addWithOverflow(u32, left, right, &ret);
return ret;
}
pub fn add(comptime S: bool, cpu: *Arm7tdmi, left: u32, right: u32) u32 { pub fn add(comptime S: bool, cpu: *Arm7tdmi, left: u32, right: u32) u32 {
var result: u32 = undefined; var result: u32 = undefined;
const didOverflow = @addWithOverflow(u32, left, right, &result); const didOverflow = @addWithOverflow(u32, left, right, &result);
@ -221,6 +387,15 @@ fn armAdc(comptime S: bool, cpu: *Arm7tdmi, rd: u4, left: u32, right: u32, old_c
return result; return result;
} }
fn newAdc(didOverflow: *bool, left: u32, right: u32, old_carry: u1) u32 {
var ret: u32 = undefined;
const did = @addWithOverflow(u32, left, right, &ret);
const overflow = @addWithOverflow(u32, ret, old_carry, &ret);
didOverflow.* = did or overflow;
return ret;
}
pub fn adc(comptime S: bool, cpu: *Arm7tdmi, left: u32, right: u32, old_carry: u1) u32 { pub fn adc(comptime S: bool, cpu: *Arm7tdmi, left: u32, right: u32, old_carry: u1) u32 {
var result: u32 = undefined; var result: u32 = undefined;
const did = @addWithOverflow(u32, left, right, &result); const did = @addWithOverflow(u32, left, right, &result);
@ -280,5 +455,5 @@ fn setTestOpFlags(comptime S: bool, cpu: *Arm7tdmi, opcode: u32, result: u32) vo
fn undefinedTestBehaviour(cpu: *Arm7tdmi) void { fn undefinedTestBehaviour(cpu: *Arm7tdmi) void {
@setCold(true); @setCold(true);
cpu.setCpsr(cpu.spsr.raw); cpu.setCpsrNoFlush(cpu.spsr.raw);
} }

16
src/core/cpu/arm/half_signed_data_transfer.zig
View File

@ -15,20 +15,8 @@ pub fn halfAndSignedDataTransfer(comptime P: bool, comptime U: bool, comptime I:
const rm = opcode & 0xF; const rm = opcode & 0xF;
const imm_offset_high = opcode >> 8 & 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; const modified_base = if (U) base +% offset else base -% offset;
var address = if (P) modified_base else base; var address = if (P) modified_base else base;

25
src/core/cpu/arm/single_data_transfer.zig
View File

@ -14,13 +14,8 @@ pub fn singleDataTransfer(comptime I: bool, comptime P: bool, comptime U: bool,
const rn = opcode >> 16 & 0xF; const rn = opcode >> 16 & 0xF;
const rd = opcode >> 12 & 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.immShift(false, cpu, opcode) else opcode & 0xFFF;
@ -40,18 +35,26 @@ pub fn singleDataTransfer(comptime I: bool, comptime P: bool, comptime U: bool,
} else { } else {
if (B) { if (B) {
// STRB // 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)); bus.write(u8, address, @truncate(u8, value));
} else { } else {
// STR // 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); bus.write(u32, address, value);
} }
} }
address = modified_base; 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(u32, cpu);
}
if (L) {
// This emulates the LDR rd == rn behaviour
cpu.r[rd] = result;
if (rd == 0xF) cpu.pipe.reload(u32, cpu);
}
} }
}.inner; }.inner;
} }

5
src/core/cpu/arm/software_interrupt.zig
View File

@ -6,7 +6,7 @@ pub fn armSoftwareInterrupt() InstrFn {
return struct { return struct {
fn inner(cpu: *Arm7tdmi, _: *Bus, _: u32) void { fn inner(cpu: *Arm7tdmi, _: *Bus, _: u32) void {
// Copy Values from Current Mode // Copy Values from Current Mode
const r15 = cpu.r[15]; const ret_addr = cpu.r[15] - 4;
const cpsr = cpu.cpsr.raw; const cpsr = cpu.cpsr.raw;
// Switch Mode // Switch Mode
@ -14,9 +14,10 @@ pub fn armSoftwareInterrupt() InstrFn {
cpu.cpsr.t.write(false); // Force ARM Mode cpu.cpsr.t.write(false); // Force ARM Mode
cpu.cpsr.i.write(true); // Disable normal interrupts 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.spsr.raw = cpsr; // Previous mode CPSR
cpu.r[15] = 0x0000_0008; cpu.r[15] = 0x0000_0008;
cpu.pipe.reload(u32, cpu);
} }
}.inner; }.inner;
} }

8
src/core/cpu/barrel_shifter.zig
View File

@ -18,11 +18,9 @@ pub fn execute(comptime S: bool, cpu: *Arm7tdmi, opcode: u32) u32 {
fn registerShift(comptime S: bool, cpu: *Arm7tdmi, opcode: u32) u32 { fn registerShift(comptime S: bool, cpu: *Arm7tdmi, opcode: u32) u32 {
const rs_idx = opcode >> 8 & 0xF; const rs_idx = opcode >> 8 & 0xF;
const rm = cpu.r[opcode & 0xF];
const rs = @truncate(u8, cpu.r[rs_idx]); 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)) { return switch (@truncate(u2, opcode >> 5)) {
0b00 => logicalLeft(S, &cpu.cpsr, rm, rs), 0b00 => logicalLeft(S, &cpu.cpsr, rm, rs),
0b01 => logicalRight(S, &cpu.cpsr, rm, rs), 0b01 => logicalRight(S, &cpu.cpsr, rm, rs),
@ -33,9 +31,7 @@ fn registerShift(comptime S: bool, cpu: *Arm7tdmi, opcode: u32) u32 {
pub fn immShift(comptime S: bool, cpu: *Arm7tdmi, opcode: u32) u32 { pub fn immShift(comptime S: bool, cpu: *Arm7tdmi, opcode: u32) u32 {
const amount = @truncate(u8, opcode >> 7 & 0x1F); 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; var result: u32 = undefined;
if (amount == 0) { if (amount == 0) {

11
src/core/cpu/thumb/block_data_transfer.zig
View File

@ -33,7 +33,8 @@ pub fn fmt14(comptime L: bool, comptime R: bool) InstrFn {
if (R) { if (R) {
if (L) { if (L) {
const value = bus.read(u32, address); const value = bus.read(u32, address);
cpu.r[15] = value & 0xFFFF_FFFE; cpu.r[15] = value & ~@as(u32, 1);
cpu.pipe.reload(u16, cpu);
} else { } else {
bus.write(u32, address, cpu.r[14]); 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); const end_address = cpu.r[rb] + 4 * countRlist(opcode);
if (opcode & 0xFF == 0) { 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(u16, cpu);
} else {
bus.write(u32, address, cpu.r[15] + 2);
}
cpu.r[rb] += 0x40; cpu.r[rb] += 0x40;
return; return;
} }

26
src/core/cpu/thumb/branch.zig
View File

@ -9,16 +9,13 @@ pub fn fmt16(comptime cond: u4) InstrFn {
return struct { return struct {
fn inner(cpu: *Arm7tdmi, _: *Bus, opcode: u16) void { fn inner(cpu: *Arm7tdmi, _: *Bus, opcode: u16) void {
// B // 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(u16, cpu);
}
} }
}.inner; }.inner;
} }
@ -27,8 +24,8 @@ pub fn fmt18() InstrFn {
return struct { return struct {
// B but conditional // B but conditional
fn inner(cpu: *Arm7tdmi, _: *Bus, opcode: u16) void { 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(u16, cpu);
} }
}.inner; }.inner;
} }
@ -41,13 +38,16 @@ pub fn fmt19(comptime is_low: bool) InstrFn {
if (is_low) { if (is_low) {
// Instruction 2 // 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[15] = cpu.r[14] +% (offset << 1);
cpu.r[14] = old_pc | 1; cpu.r[14] = next_opcode | 1;
cpu.pipe.reload(u16, cpu);
} else { } else {
// Instruction 1 // 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; }.inner;

36
src/core/cpu/thumb/data_processing.zig
View File

@ -10,8 +10,6 @@ const sub = @import("../arm/data_processing.zig").sub;
const cmp = @import("../arm/data_processing.zig").cmp; const cmp = @import("../arm/data_processing.zig").cmp;
const setLogicOpFlags = @import("../arm/data_processing.zig").setLogicOpFlags; const setLogicOpFlags = @import("../arm/data_processing.zig").setLogicOpFlags;
const log = std.log.scoped(.Thumb1);
pub fn fmt1(comptime op: u2, comptime offset: u5) InstrFn { pub fn fmt1(comptime op: u2, comptime offset: u5) InstrFn {
return struct { return struct {
fn inner(cpu: *Arm7tdmi, _: *Bus, opcode: u16) void { fn inner(cpu: *Arm7tdmi, _: *Bus, opcode: u16) void {
@ -58,29 +56,38 @@ pub fn fmt1(comptime op: u2, comptime offset: u5) InstrFn {
pub fn fmt5(comptime op: u2, comptime h1: u1, comptime h2: u1) InstrFn { pub fn fmt5(comptime op: u2, comptime h1: u1, comptime h2: u1) InstrFn {
return struct { return struct {
fn inner(cpu: *Arm7tdmi, _: *Bus, opcode: u16) void { 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 rs_value = if (rs == 0xF) cpu.r[rs] & ~@as(u32, 1) else cpu.r[rs];
const dst = if (dst_idx == 0xF) (cpu.r[dst_idx] + 2) & 0xFFFF_FFFE else cpu.r[dst_idx]; const rd_value = if (rd == 0xF) cpu.r[rd] & ~@as(u32, 1) else cpu.r[rd];
switch (op) { switch (op) {
0b00 => { 0b00 => {
// ADD // ADD
const sum = add(false, cpu, dst, src); const sum = add(false, cpu, rd_value, rs_value);
cpu.r[dst_idx] = if (dst_idx == 0xF) sum & 0xFFFF_FFFE else sum; cpu.r[rd] = if (rd == 0xF) sum & ~@as(u32, 1) else sum;
}, },
0b01 => cmp(cpu, dst, src), // CMP 0b01 => cmp(cpu, rd_value, rs_value), // CMP
0b10 => { 0b10 => {
// MOV // MOV
cpu.r[dst_idx] = if (dst_idx == 0xF) src & 0xFFFF_FFFE else src; cpu.r[rd] = if (rd == 0xF) rs_value & ~@as(u32, 1) else rs_value;
}, },
0b11 => { 0b11 => {
// BX // BX
cpu.cpsr.t.write(src & 1 == 1); const thumb = rs_value & 1 == 1;
cpu.r[15] = src & 0xFFFF_FFFE; cpu.r[15] = rs_value & ~@as(u32, 1);
cpu.cpsr.t.write(thumb);
if (thumb) cpu.pipe.reload(u16, cpu) else cpu.pipe.reload(u32, cpu);
// TODO: We shouldn't need to worry about the if statement
// below, because in BX, rd SBZ (and H1 is guaranteed to be 0)
return;
}, },
} }
if (rd == 0xF) cpu.pipe.reload(u16, cpu);
} }
}.inner; }.inner;
} }
@ -133,10 +140,9 @@ pub fn fmt12(comptime isSP: bool, comptime rd: u3) InstrFn {
return struct { return struct {
fn inner(cpu: *Arm7tdmi, _: *Bus, opcode: u16) void { fn inner(cpu: *Arm7tdmi, _: *Bus, opcode: u16) void {
// ADD // 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 right = (opcode & 0xFF) << 2;
const result = left + right; cpu.r[rd] = left + right;
cpu.r[rd] = result;
} }
}.inner; }.inner;
} }

4
src/core/cpu/thumb/data_transfer.zig
View File

@ -11,7 +11,9 @@ pub fn fmt6(comptime rd: u3) InstrFn {
fn inner(cpu: *Arm7tdmi, bus: *Bus, opcode: u16) void { fn inner(cpu: *Arm7tdmi, bus: *Bus, opcode: u16) void {
// LDR // LDR
const offset = (opcode & 0xFF) << 2; 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; }.inner;
} }

5
src/core/cpu/thumb/software_interrupt.zig
View File

@ -6,7 +6,7 @@ pub fn fmt17() InstrFn {
return struct { return struct {
fn inner(cpu: *Arm7tdmi, _: *Bus, _: u16) void { fn inner(cpu: *Arm7tdmi, _: *Bus, _: u16) void {
// Copy Values from Current Mode // Copy Values from Current Mode
const r15 = cpu.r[15]; const ret_addr = cpu.r[15] - 2;
const cpsr = cpu.cpsr.raw; const cpsr = cpu.cpsr.raw;
// Switch Mode // Switch Mode
@ -14,9 +14,10 @@ pub fn fmt17() InstrFn {
cpu.cpsr.t.write(false); // Force ARM Mode cpu.cpsr.t.write(false); // Force ARM Mode
cpu.cpsr.i.write(true); // Disable normal interrupts 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.spsr.raw = cpsr; // Previous mode CPSR
cpu.r[15] = 0x0000_0008; cpu.r[15] = 0x0000_0008;
cpu.pipe.reload(u32, cpu);
} }
}.inner; }.inner;
} }

41
src/core/emu.zig
View File

@ -70,12 +70,21 @@ pub fn runFrame(sched: *Scheduler, cpu: *Arm7tdmi) void {
} }
} }
fn syncToAudio(cpu: *const Arm7tdmi) void { fn syncToAudio(stream: *SDL.SDL_AudioStream, is_buffer_full: *bool) void {
const stream = cpu.bus.apu.stream; const sample_size = 2 * @sizeOf(u16);
const min_sample_count = 0x800; const max_buf_size: c_int = 0x400;
// Busy Loop while we wait for the Audio system to catch up // Determine whether the APU is busy right at this moment
while (SDL.SDL_AudioStreamAvailable(stream) > (@sizeOf(u16) * 2) * min_sample_count) {} var still_full: bool = SDL.SDL_AudioStreamAvailable(stream) > sample_size * if (is_buffer_full.*) max_buf_size >> 1 else max_buf_size;
defer is_buffer_full.* = still_full; // Update APU Busy status right before exiting scope
// If Busy is false, there's no need to sync here
if (!still_full) return;
while (true) {
still_full = SDL.SDL_AudioStreamAvailable(stream) > sample_size * max_buf_size >> 1;
if (!sync_audio or !still_full) break;
}
} }
pub fn runUnsynchronized(quit: *Atomic(bool), sched: *Scheduler, cpu: *Arm7tdmi, fps: ?*FpsTracker) void { pub fn runUnsynchronized(quit: *Atomic(bool), sched: *Scheduler, cpu: *Arm7tdmi, fps: ?*FpsTracker) void {
@ -86,21 +95,21 @@ pub fn runUnsynchronized(quit: *Atomic(bool), sched: *Scheduler, cpu: *Arm7tdmi,
while (!quit.load(.SeqCst)) { while (!quit.load(.SeqCst)) {
runFrame(sched, cpu); runFrame(sched, cpu);
if (sync_audio) syncToAudio(cpu); syncToAudio(cpu.bus.apu.stream, &cpu.bus.apu.is_buffer_full);
tracker.tick(); tracker.tick();
} }
} else { } else {
while (!quit.load(.SeqCst)) { while (!quit.load(.SeqCst)) {
runFrame(sched, cpu); runFrame(sched, cpu);
if (sync_audio) syncToAudio(cpu); syncToAudio(cpu.bus.apu.stream, &cpu.bus.apu.is_buffer_full);
} }
} }
} }
pub fn runSynchronized(quit: *Atomic(bool), sched: *Scheduler, cpu: *Arm7tdmi, fps: ?*FpsTracker) void { pub fn runSynchronized(quit: *Atomic(bool), sched: *Scheduler, cpu: *Arm7tdmi, fps: ?*FpsTracker) void {
log.info("Emulation thread w/ video sync", .{}); log.info("Emulation thread w/ video sync", .{});
var timer = Timer.start() catch unreachable; var timer = Timer.start() catch std.debug.panic("Failed to initialize std.timer.Timer", .{});
var wake_time: u64 = frame_period; var wake_time: u64 = frame_period;
if (fps) |tracker| { if (fps) |tracker| {
@ -108,13 +117,14 @@ pub fn runSynchronized(quit: *Atomic(bool), sched: *Scheduler, cpu: *Arm7tdmi, f
while (!quit.load(.SeqCst)) { while (!quit.load(.SeqCst)) {
runFrame(sched, cpu); runFrame(sched, cpu);
const new_wake_time = syncToVideo(&timer, wake_time); const new_wake_time = blockOnVideo(&timer, wake_time);
// Spin to make up the difference of OS scheduler innacuracies // Spin to make up the difference of OS scheduler innacuracies
// If we happen to also be syncing to audio, we choose to spin on // 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 // the amount of time needed for audio to catch up rather than
// our expected wake-up time // our expected wake-up time
if (sync_audio) syncToAudio(cpu) else spinLoop(&timer, wake_time); syncToAudio(cpu.bus.apu.stream, &cpu.bus.apu.is_buffer_full);
if (!sync_audio) spinLoop(&timer, wake_time);
wake_time = new_wake_time; wake_time = new_wake_time;
tracker.tick(); tracker.tick();
@ -122,16 +132,17 @@ pub fn runSynchronized(quit: *Atomic(bool), sched: *Scheduler, cpu: *Arm7tdmi, f
} else { } else {
while (!quit.load(.SeqCst)) { while (!quit.load(.SeqCst)) {
runFrame(sched, cpu); runFrame(sched, cpu);
const new_wake_time = syncToVideo(&timer, wake_time); const new_wake_time = blockOnVideo(&timer, wake_time);
// see above comment
if (sync_audio) syncToAudio(cpu) else spinLoop(&timer, wake_time);
// see above comment
syncToAudio(cpu.bus.apu.stream, &cpu.bus.apu.is_buffer_full);
if (!sync_audio) spinLoop(&timer, wake_time);
wake_time = new_wake_time; wake_time = new_wake_time;
} }
} }
} }
inline fn syncToVideo(timer: *Timer, wake_time: u64) u64 { inline fn blockOnVideo(timer: *Timer, wake_time: u64) u64 {
// Use the OS scheduler to put the emulation thread to sleep // Use the OS scheduler to put the emulation thread to sleep
const maybe_recalc_wake_time = sleep(timer, wake_time); const maybe_recalc_wake_time = sleep(timer, wake_time);
@ -149,6 +160,8 @@ pub fn runBusyLoop(quit: *Atomic(bool), sched: *Scheduler, cpu: *Arm7tdmi) void
runFrame(sched, cpu); runFrame(sched, cpu);
spinLoop(&timer, wake_time); spinLoop(&timer, wake_time);
syncToAudio(cpu.bus.apu.stream, &cpu.bus.apu.is_buffer_full);
// Update to the new wake time // Update to the new wake time
wake_time += frame_period; wake_time += frame_period;
} }

3
src/core/util.zig
View File

@ -127,6 +127,7 @@ pub const Logger = struct {
pub fn print(self: *Self, comptime format: []const u8, args: anytype) !void { pub fn print(self: *Self, comptime format: []const u8, args: anytype) !void {
try self.buf.writer().print(format, args); 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 { pub fn mgbaLog(self: *Self, cpu: *const Arm7tdmi, opcode: u32) void {
@ -166,7 +167,7 @@ pub const Logger = struct {
cpu.r[12], cpu.r[12],
cpu.r[13], cpu.r[13],
cpu.r[14], cpu.r[14],
cpu.r[15], cpu.r[15] - if (cpu.cpsr.t.read()) 2 else @as(u32, 4),
cpu.cpsr.raw, cpu.cpsr.raw,
opcode, opcode,
}; };