use crate::bit::BitIndex;
use super::super::alu::*;
use crate::core::arm7tdmi::psr::RegPSR;
use crate::core::arm7tdmi::CpuAction;
use crate::core::arm7tdmi::{Addr, Core, CpuMode, CpuState, REG_LR, REG_PC};
use crate::core::sysbus::SysBus;
use crate::core::Bus;
use super::*;
impl Core {
pub fn exec_arm(&mut self, bus: &mut SysBus, insn: ArmInstruction) -> CpuAction {
if !self.check_arm_cond(insn.cond) {
self.S_cycle32(bus, self.pc);
return CpuAction::AdvancePC;
}
match insn.fmt {
ArmFormat::BX => self.exec_bx(bus, insn),
ArmFormat::B_BL => self.exec_b_bl(bus, insn),
ArmFormat::DP => self.exec_data_processing(bus, insn),
ArmFormat::SWI => {
self.software_interrupt(bus, self.pc - 4, insn.swi_comment());
CpuAction::FlushPipeline
}
ArmFormat::LDR_STR => self.exec_ldr_str(bus, insn),
ArmFormat::LDR_STR_HS_IMM => self.exec_ldr_str_hs(bus, insn),
ArmFormat::LDR_STR_HS_REG => self.exec_ldr_str_hs(bus, insn),
ArmFormat::LDM_STM => self.exec_ldm_stm(bus, insn),
ArmFormat::MRS => self.move_from_status_register(bus, insn.rd(), insn.spsr_flag()),
ArmFormat::MSR_REG => self.exec_msr_reg(bus, insn),
ArmFormat::MSR_FLAGS => self.exec_msr_flags(bus, insn),
ArmFormat::MUL_MLA => self.exec_mul_mla(bus, insn),
ArmFormat::MULL_MLAL => self.exec_mull_mlal(bus, insn),
ArmFormat::SWP => self.exec_arm_swp(bus, insn),
}
}
/// Cycles 2S+1N
fn exec_b_bl(&mut self, sb: &mut SysBus, insn: ArmInstruction) -> CpuAction {
self.S_cycle32(sb, self.pc);
if insn.link_flag() {
self.set_reg(REG_LR, (insn.pc + (self.word_size() as u32)) & !0b1);
}
self.pc = (self.pc as i32).wrapping_add(insn.branch_offset()) as u32 & !1;
self.reload_pipeline32(sb);
CpuAction::FlushPipeline
}
pub fn branch_exchange(&mut self, sb: &mut SysBus, mut addr: Addr) -> CpuAction {
match self.cpsr.state() {
CpuState::ARM => self.S_cycle32(sb, self.pc),
CpuState::THUMB => self.S_cycle16(sb, self.pc),
}
if addr.bit(0) {
addr = addr & !0x1;
self.cpsr.set_state(CpuState::THUMB);
self.pc = addr;
self.reload_pipeline16(sb);
} else {
addr = addr & !0x3;
self.cpsr.set_state(CpuState::ARM);
self.pc = addr;
self.reload_pipeline32(sb);
}
CpuAction::FlushPipeline
}
/// Cycles 2S+1N
fn exec_bx(&mut self, sb: &mut SysBus, insn: ArmInstruction) -> CpuAction {
self.branch_exchange(sb, self.get_reg(insn.rn()))
}
fn move_from_status_register(
&mut self,
sb: &mut SysBus,
rd: usize,
is_spsr: bool,
) -> CpuAction {
let result = if is_spsr {
self.spsr.get()
} else {
self.cpsr.get()
};
self.set_reg(rd, result);
self.S_cycle32(sb, self.pc);
CpuAction::AdvancePC
}
fn exec_msr_reg(&mut self, sb: &mut SysBus, insn: ArmInstruction) -> CpuAction {
self.write_status_register(sb, insn.spsr_flag(), self.get_reg(insn.rm()))
}
fn write_status_register(&mut self, sb: &mut SysBus, is_spsr: bool, value: u32) -> CpuAction {
let new_status_reg = RegPSR::new(value);
match self.cpsr.mode() {
CpuMode::User => {
if is_spsr {
panic!("User mode can't access SPSR")
}
self.cpsr.set_flag_bits(value);
}
_ => {
if is_spsr {
self.spsr.set(value);
} else {
let t_bit = self.cpsr.state();
let old_mode = self.cpsr.mode();
self.cpsr.set(value);
if t_bit != self.cpsr.state() {
panic!("T bit changed from MSR");
}
let new_mode = new_status_reg.mode();
if old_mode != new_mode {
self.change_mode(old_mode, new_mode);
}
}
}
}
self.S_cycle32(sb, self.pc);
CpuAction::AdvancePC
}
fn exec_msr_flags(&mut self, sb: &mut SysBus, insn: ArmInstruction) -> CpuAction {
self.S_cycle32(sb, self.pc);
let op = insn.operand2();
let op = self.decode_operand2(op);
if insn.spsr_flag() {
self.spsr.set_flag_bits(op);
} else {
self.cpsr.set_flag_bits(op);
}
CpuAction::AdvancePC
}
fn decode_operand2(&mut self, op2: BarrelShifterValue) -> u32 {
match op2 {
BarrelShifterValue::RotatedImmediate(val, amount) => {
self.ror(val, amount, self.cpsr.C(), false, true)
}
BarrelShifterValue::ShiftedRegister(x) => self.register_shift(x),
_ => unreachable!(),
}
}
fn transfer_spsr_mode(&mut self) {
let spsr = self.spsr;
if self.cpsr.mode() != spsr.mode() {
self.change_mode(self.cpsr.mode(), spsr.mode());
}
self.cpsr = spsr;
}
/// Logical/Arithmetic ALU operations
///
/// Cycles: 1S+x+y (from GBATEK)
/// Add x=1I cycles if Op2 shifted-by-register. Add y=1S+1N cycles if Rd=R15.
fn exec_data_processing(&mut self, sb: &mut SysBus, insn: ArmInstruction) -> CpuAction {
use AluOpCode::*;
self.S_cycle32(sb, self.pc);
let mut op1 = if insn.rn() == REG_PC {
(insn.pc + 8)
} else {
self.get_reg(insn.rn())
};
let mut s_flag = insn.set_cond_flag();
let opcode = insn.opcode().unwrap();
let op2 = insn.operand2();
match op2 {
BarrelShifterValue::ShiftedRegister(shifted_reg) => {
if insn.rn() == REG_PC && shifted_reg.is_shifted_by_reg() {
op1 += 4;
}
}
_ => {}
}
let op2 = self.decode_operand2(op2);
let reg_rd = insn.rd();
if !s_flag {
match opcode {
TEQ => {
return self.write_status_register(sb, false, op2);
}
CMN => {
return self.write_status_register(sb, true, op2);
}
TST => return self.move_from_status_register(sb, reg_rd, false),
CMP => return self.move_from_status_register(sb, reg_rd, true),
_ => (),
}
}
if reg_rd == REG_PC && s_flag {
self.transfer_spsr_mode();
s_flag = false;
}
let carry = self.cpsr.C() as u32;
let alu_res = if s_flag {
let mut carry = self.bs_carry_out;
let mut overflow = self.cpsr.V();
let result = match opcode {
AND | TST => op1 & op2,
EOR | TEQ => op1 ^ op2,
SUB | CMP => self.alu_sub_flags(op1, op2, &mut carry, &mut overflow),
RSB => self.alu_sub_flags(op2, op1, &mut carry, &mut overflow),
ADD | CMN => self.alu_add_flags(op1, op2, &mut carry, &mut overflow),
ADC => self.alu_adc_flags(op1, op2, &mut carry, &mut overflow),
SBC => self.alu_sbc_flags(op1, op2, &mut carry, &mut overflow),
RSC => self.alu_sbc_flags(op2, op1, &mut carry, &mut overflow),
ORR => op1 | op2,
MOV => op2,
BIC => op1 & (!op2),
MVN => !op2,
};
self.alu_update_flags(result, opcode.is_arithmetic(), carry, overflow);
if opcode.is_setting_flags() {
None
} else {
Some(result)
}
} else {
Some(match opcode {
AND => op1 & op2,
EOR => op1 ^ op2,
SUB => op1.wrapping_sub(op2),
RSB => op2.wrapping_sub(op1),
ADD => op1.wrapping_add(op2),
ADC => op1.wrapping_add(op2).wrapping_add(carry),
SBC => op1.wrapping_sub(op2.wrapping_add(1 - carry)),
RSC => op2.wrapping_sub(op1.wrapping_add(1 - carry)),
ORR => op1 | op2,
MOV => op2,
BIC => op1 & (!op2),
MVN => !op2,
_ => panic!("{} should be a PSR transfer", opcode),
})
};
let mut result = CpuAction::AdvancePC;
if let Some(alu_res) = alu_res {
self.set_reg(reg_rd, alu_res as u32);
if reg_rd == REG_PC {
// T bit might have changed
match self.cpsr.state() {
CpuState::ARM => self.reload_pipeline32(sb),
CpuState::THUMB => self.reload_pipeline16(sb),
};
result = CpuAction::FlushPipeline;
}
}
result
}
/// Memory Load/Store
/// Instruction | Cycles | Flags | Expl.
/// ------------------------------------------------------------------------------
/// LDR{cond}{B}{T} Rd,<Address> | 1S+1N+1I+y | ---- | Rd=[Rn+/-<offset>]
/// STR{cond}{B}{T} Rd,<Address> | 2N | ---- | [Rn+/-<offset>]=Rd
/// ------------------------------------------------------------------------------
/// For LDR, add y=1S+1N if Rd=R15.
fn exec_ldr_str(&mut self, sb: &mut SysBus, insn: ArmInstruction) -> CpuAction {
let mut result = CpuAction::AdvancePC;
let load = insn.load_flag();
let pre_index = insn.pre_index_flag();
let writeback = insn.write_back_flag();
let base_reg = insn.rn();
let dest_reg = insn.rd();
let mut addr = self.get_reg(base_reg);
if base_reg == REG_PC {
addr = insn.pc + 8; // prefetching
}
let offset = self.get_barrel_shifted_value(insn.ldr_str_offset());
let effective_addr = (addr as i32).wrapping_add(offset as i32) as Addr;
// TODO - confirm this
let old_mode = self.cpsr.mode();
if !pre_index && writeback {
self.change_mode(old_mode, CpuMode::User);
}
addr = if insn.pre_index_flag() {
effective_addr
} else {
addr
};
if load {
self.S_cycle32(sb, self.pc);
let data = if insn.transfer_size() == 1 {
self.N_cycle8(sb, addr);
sb.read_8(addr) as u32
} else {
self.N_cycle32(sb, addr);
self.ldr_word(addr, sb)
};
self.set_reg(dest_reg, data);
// +1I
self.add_cycle();
if dest_reg == REG_PC {
self.reload_pipeline32(sb);
result = CpuAction::FlushPipeline;
}
} else {
let value = if dest_reg == REG_PC {
insn.pc + 12
} else {
self.get_reg(dest_reg)
};
if insn.transfer_size() == 1 {
self.N_cycle8(sb, addr);
self.write_8(addr, value as u8, sb);
} else {
self.N_cycle32(sb, addr);
self.write_32(addr & !0x3, value, sb);
};
self.N_cycle32(sb, self.pc);
}
if !load || base_reg != dest_reg {
if !pre_index {
self.set_reg(base_reg, effective_addr);
} else if insn.write_back_flag() {
self.set_reg(base_reg, effective_addr);
}
}
if !pre_index && insn.write_back_flag() {
self.change_mode(self.cpsr.mode(), old_mode);
}
result
}
fn exec_ldr_str_hs(&mut self, sb: &mut SysBus, insn: ArmInstruction) -> CpuAction {
let mut result = CpuAction::AdvancePC;
let load = insn.load_flag();
let pre_index = insn.pre_index_flag();
let writeback = insn.write_back_flag();
let base_reg = insn.rn();
let dest_reg = insn.rd();
let mut addr = self.get_reg(base_reg);
if base_reg == REG_PC {
addr = insn.pc + 8; // prefetching
}
let offset = self.get_barrel_shifted_value(insn.ldr_str_hs_offset().unwrap());
// TODO - confirm this
let old_mode = self.cpsr.mode();
if !pre_index && writeback {
self.change_mode(old_mode, CpuMode::User);
}
let effective_addr = (addr as i32).wrapping_add(offset as i32) as Addr;
addr = if insn.pre_index_flag() {
effective_addr
} else {
addr
};
if load {
self.S_cycle32(sb, self.pc);
let data = match insn.halfword_data_transfer_type().unwrap() {
ArmHalfwordTransferType::SignedByte => {
self.N_cycle8(sb, addr);
sb.read_8(addr) as u8 as i8 as u32
}
ArmHalfwordTransferType::SignedHalfwords => {
self.N_cycle16(sb, addr);
self.ldr_sign_half(addr, sb)
}
ArmHalfwordTransferType::UnsignedHalfwords => {
self.N_cycle16(sb, addr);
self.ldr_half(addr, sb)
}
};
self.set_reg(dest_reg, data);
// +1I
self.add_cycle();
if dest_reg == REG_PC {
self.reload_pipeline32(sb);
result = CpuAction::FlushPipeline;
}
} else {
let value = if dest_reg == REG_PC {
insn.pc + 12
} else {
self.get_reg(dest_reg)
};
match insn.halfword_data_transfer_type().unwrap() {
ArmHalfwordTransferType::UnsignedHalfwords => {
self.N_cycle32(sb, addr);
self.write_16(addr, value as u16, sb);
self.N_cycle32(sb, self.pc);
}
_ => panic!("invalid HS flags for L=0"),
};
}
if !load || base_reg != dest_reg {
if !pre_index {
self.set_reg(base_reg, effective_addr);
} else if insn.write_back_flag() {
self.set_reg(base_reg, effective_addr);
}
}
result
}
fn exec_ldm_stm(&mut self, sb: &mut SysBus, insn: ArmInstruction) -> CpuAction {
let mut result = CpuAction::AdvancePC;
let mut full = insn.pre_index_flag();
let ascending = insn.add_offset_flag();
let s_flag = insn.raw.bit(22);
let is_load = insn.load_flag();
let mut writeback = insn.write_back_flag();
let base_reg = insn.rn();
let mut base_addr = self.get_reg(base_reg);
let rlist = insn.register_list();
if s_flag {
match self.cpsr.mode() {
CpuMode::User | CpuMode::System => {
panic!("LDM/STM with S bit in unprivileged mode")
}
_ => {}
};
}
let user_bank_transfer = if s_flag {
if is_load {
!rlist.bit(REG_PC)
} else {
true
}
} else {
false
};
let old_mode = self.cpsr.mode();
if user_bank_transfer {
self.change_mode(old_mode, CpuMode::User);
}
let psr_transfer = s_flag & is_load & rlist.bit(REG_PC);
let rlist_count = rlist.count_ones();
let old_base = base_addr;
if rlist != 0 && !ascending {
base_addr = base_addr.wrapping_sub(rlist_count * 4);
if writeback {
self.set_reg(base_reg, base_addr);
writeback = false;
}
full = !full;
}
let mut addr = base_addr;
if rlist != 0 {
if is_load {
self.add_cycle();
self.N_cycle32(sb, self.pc);
for r in 0..16 {
if rlist.bit(r) {
if r == base_reg {
writeback = false;
}
if full {
addr = addr.wrapping_add(4);
}
let val = sb.read_32(addr);
self.S_cycle32(sb, self.pc);
self.set_reg(r, val);
if r == REG_PC {
if psr_transfer {
self.transfer_spsr_mode();
}
self.reload_pipeline32(sb);
result = CpuAction::FlushPipeline;
}
if !full {
addr = addr.wrapping_add(4);
}
}
}
} else {
let mut first = true;
for r in 0..16 {
if rlist.bit(r) {
let val = if r != base_reg {
if r == REG_PC {
insn.pc + 12
} else {
self.get_reg(r)
}
} else {
if first {
old_base
} else {
let x = rlist_count * 4;
if ascending {
old_base + x
} else {
old_base - x
}
}
};
if full {
addr = addr.wrapping_add(4);
}
if first {
self.N_cycle32(sb, addr);
first = false;
} else {
self.S_cycle32(sb, addr);
}
self.write_32(addr, val, sb);
if !full {
addr = addr.wrapping_add(4);
}
}
}
self.N_cycle32(sb, self.pc);
}
} else {
if is_load {
let val = self.ldr_word(addr, sb);
self.set_reg(REG_PC, val & !3);
self.reload_pipeline32(sb);
result = CpuAction::FlushPipeline;
} else {
self.write_32(addr, self.pc + 4, sb);
}
addr = addr.wrapping_add(0x40);
}
if user_bank_transfer {
self.change_mode(self.cpsr.mode(), old_mode);
}
if writeback {
self.set_reg(base_reg, addr as u32);
}
result
}
fn exec_mul_mla(&mut self, sb: &mut SysBus, insn: ArmInstruction) -> CpuAction {
let (rd, rn, rs, rm) = (insn.rd(), insn.rn(), insn.rs(), insn.rm());
// check validity
assert!(!(REG_PC == rd || REG_PC == rn || REG_PC == rs || REG_PC == rm));
assert!(rd != rm);
let op1 = self.get_reg(rm);
let op2 = self.get_reg(rs);
let mut result = op1.wrapping_mul(op2);
if insn.accumulate_flag() {
result = result.wrapping_add(self.get_reg(rn));
self.add_cycle();
}
self.set_reg(rd, result);
let m = self.get_required_multipiler_array_cycles(op2);
for _ in 0..m {
self.add_cycle();
}
if insn.set_cond_flag() {
self.cpsr.set_N((result as i32) < 0);
self.cpsr.set_Z(result == 0);
self.cpsr.set_C(false);
self.cpsr.set_V(false);
}
self.S_cycle32(sb, self.pc);
CpuAction::AdvancePC
}
fn exec_mull_mlal(&mut self, sb: &mut SysBus, insn: ArmInstruction) -> CpuAction {
let (rd_hi, rd_lo, rn, rs, rm) =
(insn.rd_hi(), insn.rd_lo(), insn.rn(), insn.rs(), insn.rm());
// check validity
assert!(
!(REG_PC == rd_hi || REG_PC == rd_lo || REG_PC == rn || REG_PC == rs || REG_PC == rm)
);
assert!(!(rd_hi != rd_hi && rd_hi != rm && rd_lo != rm));
let op1 = self.get_reg(rm);
let op2 = self.get_reg(rs);
let mut result: u64 = if insn.u_flag() {
// signed
(op1 as i32 as i64).wrapping_mul(op2 as i32 as i64) as u64
} else {
(op1 as u64).wrapping_mul(op2 as u64)
};
self.add_cycle();
if insn.accumulate_flag() {
let hi = self.get_reg(rd_hi) as u64;
let lo = self.get_reg(rd_lo) as u64;
result = result.wrapping_add(hi << 32 | lo);
self.add_cycle();
}
self.set_reg(rd_hi, (result >> 32) as i32 as u32);
self.set_reg(rd_lo, (result & 0xffffffff) as i32 as u32);
let m = self.get_required_multipiler_array_cycles(self.get_reg(rs));
for _ in 0..m {
self.add_cycle();
}
if insn.set_cond_flag() {
self.cpsr.set_N(result.bit(63));
self.cpsr.set_Z(result == 0);
self.cpsr.set_C(false);
self.cpsr.set_V(false);
}
self.S_cycle32(sb, self.pc);
CpuAction::AdvancePC
}
fn exec_arm_swp(&mut self, sb: &mut SysBus, insn: ArmInstruction) -> CpuAction {
let base_addr = self.get_reg(insn.rn());
if insn.transfer_size() == 1 {
let t = sb.read_8(base_addr);
self.N_cycle8(sb, base_addr);
sb.write_8(base_addr, self.get_reg(insn.rm()) as u8);
self.S_cycle8(sb, base_addr);
self.set_reg(insn.rd(), t as u32);
} else {
let t = self.ldr_word(base_addr, sb);
self.N_cycle32(sb, base_addr);
self.write_32(base_addr, self.get_reg(insn.rm()), sb);
self.S_cycle32(sb, base_addr);
self.set_reg(insn.rd(), t as u32);
}
self.add_cycle();
self.N_cycle32(sb, self.pc);
CpuAction::AdvancePC
}
}