zba/src/cpu/data_processing.zig

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const std = @import("std");
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const processor = @import("../cpu.zig");
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const Bus = @import("../bus.zig").Bus;
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const Arm7tdmi = processor.Arm7tdmi;
const InstrFn = processor.InstrFn;
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pub fn comptimeDataProcessing(comptime I: bool, comptime S: bool, comptime instrKind: u4) InstrFn {
return struct {
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fn dataProcessing(cpu: *Arm7tdmi, _: *Bus, opcode: u32) void {
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const rd = opcode >> 12 & 0xF;
const op1 = opcode >> 16 & 0xF;
var op2: u32 = undefined;
if (I) {
op2 = std.math.rotr(u32, opcode & 0xFF, (opcode >> 8 & 0xF) << 1);
} else {
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op2 = registerOp2(cpu, opcode);
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}
switch (instrKind) {
0x4 => {
// ADD
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cpu.r[rd] = cpu.r[op1] + op2;
if (S) std.debug.panic("TODO: implement ADD condition codes", .{});
},
0xD => {
// MOV
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cpu.r[rd] = op2;
if (S) std.debug.panic("TODO: implement MOV condition codes", .{});
},
0xA => {
// CMP
var result: u32 = undefined;
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const op1_val = cpu.r[op1];
const v_ctx = (op1_val >> 31 == 0x01) or (op2 >> 31 == 0x01);
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const didOverflow = @subWithOverflow(u32, op1_val, op2, &result);
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cpu.cpsr.v.write(v_ctx and (result >> 31 & 0x01 == 0x01));
cpu.cpsr.c.write(didOverflow);
cpu.cpsr.z.write(result == 0x00);
cpu.cpsr.n.write(result >> 31 & 0x01 == 0x01);
},
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else => std.debug.panic("TODO: implement data processing type {}", .{instrKind}),
}
}
}.dataProcessing;
}
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fn registerOp2(cpu: *const Arm7tdmi, opcode: u32) u32 {
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var amount: u32 = undefined;
if (opcode >> 4 & 0x01 == 0x01) {
amount = cpu.r[opcode >> 8 & 0xF] & 0xFF;
} else {
amount = opcode >> 7 & 0x1F;
}
const rm = opcode & 0xF;
const r_val = cpu.r[rm];
return switch (opcode >> 5 & 0x03) {
0b00 => r_val << @truncate(u5, amount),
0b01 => r_val >> @truncate(u5, amount),
0b10 => @bitCast(u32, @bitCast(i32, r_val) >> @truncate(u5, amount)),
0b11 => std.math.rotr(u32, r_val, amount),
else => unreachable,
};
}