def ld8(cpu, opcode, logger):
regIndPrim = (opcode & 7)
regInd = (opcode >> 3) & 7
cpu.regs[regInd] = cpu.regs[regIndPrim]
cpu.m_cycles, cpu.t_states = 1, 4
logger.info("LD {}, {}".format(
IndexToReg.translate8Bit(regInd),
IndexToReg.translate8Bit(regIndPrim)))
def inc16(cpu, opcode, logger):
regInd = (opcode & 0x30) >> 4
cpu.Reg16(regInd, cpu.Reg16(regInd) + 1)
cpu.m_cycles, cpu.t_states = 1, 6
logger.info("INC {0}".format(IndexToReg.translate16Bit(regInd)))
def ld_r_iy_d(cpu, opcode, logger):
index = (opcode >> 3) & 7
d = cpu.ram[cpu.PC]
cpu.regs[index] = cpu.ram[cpu.IY + d]
cpu.m_cycles, cpu.t_states = 5, 19
logger.info("LD {}, (IY+{:02X})".format(IndexToReg.translate8Bit(index), d))
def dec16b(cpu, opcode, logger):
regInd = (opcode >> 4) & 3
cpu.Reg16(regInd, cpu.Reg16(regInd) - 1)
cpu.m_cycles, cpu.t_states = 1, 6
logger.info("DEC {}".format(IndexToReg.translate16Bit(regInd)))
def ld8n(cpu, opcode, logger):
regInd = (opcode >> 3) & 7
value = cpu.ram[cpu.PC]
cpu.regs[regInd] = value
cpu.m_cycles, cpu.t_states = 2, 7
logger.info("LD {}, {:02X}".format(
IndexToReg.translate8Bit(regInd),
value))
def ld_r_hl(cpu, opcode, logger):
index = (opcode >> 3) & 7
value = cpu.ram[cpu.HL]
cpu.regs[index] = value
cpu.m_cycles, cpu.t_states = 2, 7
logger.info("LD {}, (HL)".format(IndexToReg.translate8Bit(index)))
def push(cpu, opcode, logger):
regInd = (opcode >> 4) & 3
value = cpu.Reg16(regInd, af=True)
cpu.ram[cpu.SP-1] = value >> 8
cpu.ram[cpu.SP-2] = value & 255
cpu.SP -= 2
cpu.m_cycles, cpu.t_states = 3, 11
logger.info("PUSH {}".format(IndexToReg.translate16Bit(regInd)))
def pop(cpu, opcode, logger):
regInd = (opcode >> 4) & 3
high = cpu.ram[cpu.SP+1]
low = cpu.ram[cpu.SP]
cpu.SP += 2
val = (high << 8) + low
cpu.Reg16(regInd, val, af=True)
cpu.m_cycles, cpu.t_states = 3, 7
logger.info("POP {}".format(IndexToReg.translate16Bit(regInd)))
def cp(cpu, opcode, logger):
regInd = opcode & 7
value = cpu.A - cpu.regs[regInd]
cpu.ZFlag = Bits.isZero(value)
cpu.CFlag = Bits.carryFlag(value)
cpu.NFlag = Bits.set()
cpu.HFlag = Bits.halfCarrySub(cpu.A, value)
cpu.SFlag = Bits.signFlag(value)
cpu.PVFlag = Bits.overflow(value, cpu.A)
cpu.m_cycles, cpu.t_states = 1, 4
logger.info("CP {}".format(IndexToReg.translate8Bit(regInd)))
def add_iy_rr(cpu, opcode, logger):
regInd = (opcode >> 4) & 3
val = cpu.Reg16(regInd, iy=True)
old = cpu.IY
cpu.IY = cpu.IY + val
cpu.NFlag = Bits.reset()
cpu.HFlag = Bits.carryFlagAdd16(old, cpu.IY)
cpu.CFlag = Bits.overflow(old, cpu.IY, bits=16)
cpu.m_cycles, cpu.t_states = 4, 15
logger.info("ADD IY, {}".format(IndexToReg.translate16Bit(regInd)))
def adc_r(cpu, opcode, logger):
reg_idx = (opcode & 7)
old_val = cpu.A
cpu.A = old_val + cpu.regs[reg_idx] + (1 if cpu.CFlag else 0)
cpu.SFlag = Bits.isNegative(cpu.A)
cpu.ZFlag = Bits.isZero(cpu.A)
cpu.NFlag = Bits.reset()
cpu.m_cycles, cpu.t_states = 1, 4
logger.info("ADC A, {}".format(IndexToReg.translate8Bit(reg_idx)))
def ld16(cpu, opcode, logger):
regInd = (opcode & 0x30) >> 4
loValue = cpu.ram[cpu.PC]
hiValue = cpu.ram[cpu.PC]
value = (hiValue << 8) + loValue
cpu.Reg16(regInd, value)
cpu.m_cycles, cpu.t_states = 2, 10
logger.info("LD {}, {:04X}".format(
IndexToReg.translate16Bit(regInd),
value))
def add16(cpu, opcode, logger):
regInd = (opcode & 0x30) >> 4
value = cpu.Reg16(regInd)
oldHL = cpu.HL
cpu.HL = cpu.HL + value
cpu.NFlag = Bits.reset()
cpu.CFlag = Bits.carryFlag16(oldHL, cpu.HL)
cpu.HFlag = Bits.carryFlag16(oldHL, cpu.HL, bits=11)
cpu.m_cycles, cpu.t_states = 3, 11
logger.info("ADD HL, {}".format(IndexToReg.translate16Bit(regInd)))
def ldNnRr(cpu, opcode, logger):
regInd = (opcode & 0x30) >> 4
high = cpu.ram[cpu.PC]
low = cpu.ram[cpu.PC]
addr = (high << 8) + low
value = cpu.Reg16(regInd)
cpu.ram[addr + 1] = value >> 8
cpu.ram[addr] = value & 0xFF
cpu.m_cycles, cpu.t_states = 6, 20
logger.info("LD ({:04X}), {}".format(addr, IndexToReg.translate16Bit(regInd)))
def inc16(cpu, opcode, logger):
regInd = (opcode & 0x30) >> 4
logger.info("INC {0}".format(IndexToReg.translate16bit(regInd)))
if regInd == 0:
cpu.BC = cpu.BC + 1
elif regInd == 1:
cpu.DE = cpu.DE + 1
elif regInd == 2:
cpu.HL = cpu.HL + 1
elif regInd == 3:
cpu.SP = cpu.SP + 1
def _or(cpu, opcode, logger):
regInd = opcode & 7
cpu.A = cpu.A | cpu.regs[regInd]
cpu.HFlag = Bits.reset()
cpu.CFlag = Bits.reset()
cpu.NFlag = Bits.reset()
cpu.ZFlag = Bits.isZero(cpu.A)
cpu.SFlag = Bits.isNegative(cpu.A)
cpu.PVFlag = Bits.isEvenParity(cpu.A)
cpu.m_cycles, cpu.t_states = 1, 4
logger.info("OR {}".format(IndexToReg.translate8Bit(regInd)))
def ld16_nn(cpu, opcode, logger):
low = cpu.ram[cpu.PC]
high = cpu.ram[cpu.PC]
addr = (high << 8) + low
value_low = cpu.ram[addr]
value_high = cpu.ram[addr+1]
value = (value_high << 8) + value_low
regInd = (opcode >> 4) & 3
cpu.Reg16(regInd, value)
cpu.m_cycles, cpu.t_states = 6, 20
logger.info("LD {},({:0X})".format(IndexToReg.translate16Bit(regInd), addr))
def inc8(cpu, opcode, logger):
index = (opcode >> 3) & 7
oldValue = cpu.regs[index]
cpu.regs[index] = Bits.limitTo8Bits(cpu.regs[index] + 1)
cpu.NFlag = Bits.reset()
cpu.ZFlag = Bits.isZero(cpu.regs[index])
cpu.HFlag = Bits.halfCarrySub(oldValue, cpu.regs[index])
cpu.PVFlag = True if oldValue == 0x7f else False
cpu.SFlag = Bits.isNegative(cpu.regs[index])
cpu.m_cycles, cpu.t_states = 1, 4
logger.info("INC {}".format(IndexToReg.translate8Bit(index)))
def dec8b(cpu, opcode, logger):
reg_index = (opcode >> 3) & 7
old_val = cpu.regs[reg_index]
cpu.regs[reg_index] = cpu.regs[reg_index] - 1
cpu.ZFlag = Bits.isZero(cpu.regs[reg_index])
cpu.SFlag = Bits.isNegative(cpu.regs[reg_index])
cpu.NFlag = Bits.set()
cpu.PVFlag = Bits.halfCarrySub(old_val, cpu.regs[reg_index])
cpu.HFlag = Bits.halfCarrySub(old_val, cpu.regs[reg_index])
cpu.m_cycles, cpu.t_states = 1, 4
logger.info("DEC {}".format(IndexToReg.translate8Bit(reg_index)))
def add_r(cpu, opcode, logger):
index = (opcode & 7)
old = cpu.A
cpu.A = old + cpu.regs[index]
cpu.SFlag = Bits.isNegative(cpu.A)
cpu.ZFlag = Bits.isZero(cpu.A)
cpu.HFlag = Bits.halfCarrySub(old, cpu.A)
cpu.PVFlag = Bits.overflow(old, cpu.A)
cpu.NFlag = Bits.reset()
cpu.CFlag = Bits.carryFlag(cpu.A)
cpu.m_cycles, cpu.t_states = 1, 4
logger.info("ADD A, {}".format(IndexToReg.translate8Bit(index)))
def sbc_r(cpu, opcode, logger):
reg_idx = (opcode & 7)
old_val = cpu.A
cpu.A = old_val - cpu.regs[reg_idx] - (1 if cpu.CFlag else 0)
cpu.SFlag = Bits.isNegative(cpu.A)
cpu.ZFlag = Bits.isZero(cpu.A)
cpu.NFlag = Bits.set()
cpu.HFlag = Bits.halfCarrySub(old_val, cpu.A)
cpu.PVFlag = Bits.overflow(old_val, cpu.A)
cpu.CFlag = Bits.carryFlag(cpu.A)
cpu.m_cycles, cpu.t_states = 1, 4
logger.info("SDC A, {}".format(IndexToReg.translate8Bit(reg_idx)))
def add_Hl_rr_c(cpu, opcode, logger):
regInd = (opcode >> 4) & 3
val = cpu.Reg16(regInd)
old = cpu.HL
cpu.HL = cpu.HL + val + (1 if cpu.CFlag else 0)
cpu.SFlag = Bits.signFlag(cpu.HL, bits=16)
cpu.ZFlag = Bits.isZero(cpu.HL)
cpu.HFlag = Bits.halfCarrySub16(old, cpu.HL)
cpu.PVFlag = Bits.overflow(old, cpu.HL, bits=16)
cpu.NFlag = Bits.reset()
cpu.CFlag = Bits.set() if (Bits.getNthBit(old, 15) == 1 and
Bits.getNthBit(cpu.HL, 15) == 0) else Bits.reset()
cpu.m_cycles, cpu.t_states = 4, 15
logger.info("ADC HL, {}".format(IndexToReg.translate16Bit(regInd)))
def srl_r(cpu, opcode, logger):
reg_idx = (opcode & 7)
old_val = cpu.regs[reg_idx]
cpu.regs[reg_idx] = (old_val >> 1)
last_bit = Bits.getNthBit(old_val, 0)
cpu.CFlag = Bits.set() if last_bit == 1 else Bits.reset()
cpu.NFlag = Bits.reset()
cpu.HFlag = Bits.reset()
cpu.ZFlag = Bits.isZero(cpu.regs[reg_idx])
cpu.PVFlag = Bits.isEvenParity(cpu.regs[reg_idx])
cpu.SFlag = Bits.reset()
cpu.m_cycles, cpu.t_states = 2, 8
logger.info("SRL {}".format(IndexToReg.translate8Bit(reg_idx)))
def sub_r(cpu, opcode, logger):
index = opcode & 7
old_A = cpu.A
cpu.A = cpu.A - cpu.regs[index]
cpu.NFlag = Bits.set()
cpu.SFlag = Bits.isNegative(cpu.A)
cpu.ZFlag = Bits.isZero(cpu.A)
cpu.HFlag = Bits.halfCarrySub(old_A, cpu.A)
cpu.PVFlag = Bits.overflow(cpu.A, old_A)
cpu.CFlag = Bits.carryFlag(cpu.A)
cpu.m_cycles, cpu.t_states = 1, 4
logger.info("SUB {}".format(IndexToReg.translate8Bit(index)))
def ld16(cpu, opcode, logger):
regInd = (opcode & 0x30) >> 4
loValue = cpu.rom.readMemory(cpu.PC)
hiValue = cpu.rom.readMemory(cpu.PC)
value = (hiValue << 8) + loValue
if regInd == 0:
cpu.BC = value
elif regInd == 1:
cpu.DE = value
elif regInd == 2:
cpu.HL = value
elif regInd == 3:
cpu.SP = value
logger.info("LD {0}, {1}".format(IndexToReg.translate16bit(regInd),value))
def sbc(cpu, opcode, logger):
regInd = (opcode & 0x30) >> 4
value = cpu.Reg16(regInd)
oldHL = cpu.HL
cpu.HL = cpu.HL - value - (1 if cpu.CFlag else 0)
cpu.SFlag = Bits.signFlag(cpu.HL, bits=16)
cpu.ZFlag = Bits.isZero(cpu.HL)
cpu.HFlag = Bits.halfCarrySub16(oldHL, cpu.HL)
cpu.PVFlag = Bits.overflow(oldHL, cpu.HL, bits=16)
cpu.NFlag = Bits.set()
cpu.CFlag = Bits.borrow(cpu.HL, bits=16)
cpu.m_cycles, cpu.t_states = 4, 15
logger.info("SBC HL, {}".format(IndexToReg.translate16Bit(regInd)))
def test_IndexToReg_translate8Bit_returns_A_for_7(self):
self.assertEqual("A", IndexToReg.translate8Bit(7))
def test_IndexToReg_translate16Bit_returns_BC_for_0(self):
self.assertEqual("BC", IndexToReg.translate16Bit(0))
def test_IndexToReg_translate16Bit_returns_DE_for_1(self):
self.assertEqual("DE", IndexToReg.translate16Bit(1))
def test_IndexToReg_translate16Bit_returns_HL_for_2(self):
self.assertEqual("HL", IndexToReg.translate16Bit(2))
def test_IndexToReg_translate8Bit_returns_E_for_3(self):
self.assertEqual("E", IndexToReg.translate8Bit(3))
def ldhlr(cpu, opcode, logger):
regInd = opcode & 7
cpu.ram[cpu.HL] = cpu.regs[regInd]
cpu.m_cycles, cpu.t_states = 2, 7
logger.info("LD (HL), {}".format(IndexToReg.translate8Bit(regInd)))
def ldiy_d_r(cpu, opcode, logger):
regInd = opcode & 7
d = cpu.ram[cpu.PC]
cpu.ram[cpu.IY + d] = cpu.regs[regInd]
cpu.m_cycles, cpu.t_states = 5, 19
logger.info("LD (IY+{:02X}), {}".format(d, IndexToReg.translate8Bit(regInd)))
def test_IndexToReg_translate16Bit_returns_IY_for_2_and_iy_True(self):
self.assertEqual("IY", IndexToReg.translate16Bit(2, iy=True))
def test_IndextoReg_translate16Bit_returns_AF_for_3_and_af_True(self):
self.assertEqual("AF", IndexToReg.translate16Bit(3, af=True))
def test_IndexToReg_translate16Bit_returns_IY_for_2_and_iy_True(self):
self.assertEquals("IY", IndexToReg.translate16Bit(2, iy=True))
def test_IndextoReg_translate16Bit_returns_AF_for_3_and_af_True(self):
self.assertEquals("AF", IndexToReg.translate16Bit(3, af=True))
def test_IndexToReg_translate8Bit_returns_L_for_5(self):
self.assertEqual("L", IndexToReg.translate8Bit(5))
def test_IndexToReg_translate16Bit_returns_IX_for_2_and_ix_True(self):
self.assertEqual("IX", IndexToReg.translate16Bit(2, ix=True))
def test_IndexToReg_translate8Bit_returns_H_for_4(self):
self.assertEqual("H", IndexToReg.translate8Bit(4))
def test_IndexToReg_translate16Bit_returns_SP_for_3(self):
self.assertEqual("SP", IndexToReg.translate16Bit(3))
def test_IndexToReg_translate8Bit_returns_C_for_1(self):
self.assertEqual("C", IndexToReg.translate8Bit(1))
def test_IndexToReg_translate8Bit_returns_D_for_2(self):
self.assertEqual("D", IndexToReg.translate8Bit(2))
