## ## This file is part of the libsigrokdecode project. ## ## Copyright (C) 2014 Daniel Elstner ## ## This program is free software; you can redistribute it and/or modify ## it under the terms of the GNU General Public License as published by ## the Free Software Foundation; either version 3 of the License, or ## (at your option) any later version. ## ## This program is distributed in the hope that it will be useful, ## but WITHOUT ANY WARRANTY; without even the implied warranty of ## MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the ## GNU General Public License for more details. ## ## You should have received a copy of the GNU General Public License ## along with this program; if not, see . ## import sigrokdecode as srd from functools import reduce from .tables import instr_table_by_prefix import string class Ann: ADDR, MEMRD, MEMWR, IORD, IOWR, INSTR, ROP, WOP, WARN = range(9) class Row: ADDRBUS, DATABUS, INSTRUCTIONS, OPERANDS, WARNINGS = range(5) class Pin: D0, D7 = 0, 7 M1, RD, WR, MREQ, IORQ = range(8, 13) A0, A15 = 13, 28 class Cycle: NONE, MEMRD, MEMWR, IORD, IOWR, FETCH, INTACK = range(7) # Provide custom format type 'H' for hexadecimal output # with leading decimal digit (assembler syntax). class AsmFormatter(string.Formatter): def format_field(self, value, format_spec): if format_spec.endswith('H'): result = format(value, format_spec[:-1] + 'X') return result if result[0] in string.digits else '0' + result else: return format(value, format_spec) formatter = AsmFormatter() ann_data_cycle_map = { Cycle.MEMRD: Ann.MEMRD, Cycle.MEMWR: Ann.MEMWR, Cycle.IORD: Ann.IORD, Cycle.IOWR: Ann.IOWR, Cycle.FETCH: Ann.MEMRD, Cycle.INTACK: Ann.IORD, } def reduce_bus(bus): if 0xFF in bus: return None # unassigned bus channels else: return reduce(lambda a, b: (a << 1) | b, reversed(bus)) def signed_byte(byte): return byte if byte < 128 else byte - 256 class Decoder(srd.Decoder): api_version = 3 id = 'z80' name = 'Z80' longname = 'Zilog Z80 CPU' desc = 'Zilog Z80 microprocessor disassembly.' license = 'gplv3+' inputs = ['logic'] outputs = [] tags = ['Retro computing'] channels = tuple({ 'id': 'd%d' % i, 'name': 'D%d' % i, 'desc': 'Data bus line %d' % i } for i in range(8) ) + ( {'id': 'm1', 'name': '/M1', 'desc': 'Machine cycle 1'}, {'id': 'rd', 'name': '/RD', 'desc': 'Memory or I/O read'}, {'id': 'wr', 'name': '/WR', 'desc': 'Memory or I/O write'}, ) optional_channels = ( {'id': 'mreq', 'name': '/MREQ', 'desc': 'Memory request'}, {'id': 'iorq', 'name': '/IORQ', 'desc': 'I/O request'}, ) + tuple({ 'id': 'a%d' % i, 'name': 'A%d' % i, 'desc': 'Address bus line %d' % i } for i in range(16) ) annotations = ( ('addr', 'Memory or I/O address'), ('memrd', 'Byte read from memory'), ('memwr', 'Byte written to memory'), ('iord', 'Byte read from I/O port'), ('iowr', 'Byte written to I/O port'), ('instr', 'Z80 CPU instruction'), ('rop', 'Value of input operand'), ('wop', 'Value of output operand'), ('warn', 'Warning message'), ) annotation_rows = ( ('addrbus', 'Address bus', (Ann.ADDR,)), ('databus', 'Data bus', (Ann.MEMRD, Ann.MEMWR, Ann.IORD, Ann.IOWR)), ('instructions', 'Instructions', (Ann.INSTR,)), ('operands', 'Operands', (Ann.ROP, Ann.WOP)), ('warnings', 'Warnings', (Ann.WARN,)) ) def __init__(self): self.reset() def reset(self): self.prev_cycle = Cycle.NONE self.op_state = self.state_IDLE def start(self): self.out_ann = self.register(srd.OUTPUT_ANN) self.bus_data = None self.samplenum = None self.addr_start = None self.data_start = None self.dasm_start = None self.pend_addr = None self.pend_data = None self.ann_data = None self.ann_dasm = None self.prev_cycle = Cycle.NONE self.op_state = self.state_IDLE self.instr_len = 0 def decode(self): while True: # TODO: Come up with more appropriate self.wait() conditions. pins = self.wait() cycle = Cycle.NONE if pins[Pin.MREQ] != 1: # default to asserted if pins[Pin.RD] == 0: cycle = Cycle.FETCH if pins[Pin.M1] == 0 else Cycle.MEMRD elif pins[Pin.WR] == 0: cycle = Cycle.MEMWR elif pins[Pin.IORQ] == 0: # default to not asserted if pins[Pin.M1] == 0: cycle = Cycle.INTACK elif pins[Pin.RD] == 0: cycle = Cycle.IORD elif pins[Pin.WR] == 0: cycle = Cycle.IOWR if cycle != Cycle.NONE: self.bus_data = reduce_bus(pins[Pin.D0:Pin.D7+1]) if cycle != self.prev_cycle: if self.prev_cycle == Cycle.NONE: self.on_cycle_begin(reduce_bus(pins[Pin.A0:Pin.A15+1])) elif cycle == Cycle.NONE: self.on_cycle_end() else: self.on_cycle_trans() self.prev_cycle = cycle def on_cycle_begin(self, bus_addr): if self.pend_addr is not None: self.put_text(self.addr_start, Ann.ADDR, '{:04X}'.format(self.pend_addr)) self.addr_start = self.samplenum self.pend_addr = bus_addr def on_cycle_end(self): self.instr_len += 1 self.op_state = self.op_state() if self.ann_dasm is not None: self.put_disasm() if self.op_state == self.state_RESTART: self.op_state = self.state_IDLE() if self.ann_data is not None: self.put_text(self.data_start, self.ann_data, '{:02X}'.format(self.pend_data)) self.data_start = self.samplenum self.pend_data = self.bus_data self.ann_data = ann_data_cycle_map[self.prev_cycle] def on_cycle_trans(self): self.put_text(self.samplenum - 1, Ann.WARN, 'Illegal transition between control states') self.pend_addr = None self.ann_data = None self.ann_dasm = None def put_disasm(self): text = formatter.format(self.mnemonic, r=self.arg_reg, d=self.arg_dis, j=self.arg_dis+self.instr_len, i=self.arg_imm, ro=self.arg_read, wo=self.arg_write) self.put_text(self.dasm_start, self.ann_dasm, text) self.ann_dasm = None self.dasm_start = self.samplenum def put_text(self, ss, ann_idx, ann_text): self.put(ss, self.samplenum, self.out_ann, [ann_idx, [ann_text]]) def state_RESTART(self): return self.state_IDLE def state_IDLE(self): if self.prev_cycle != Cycle.FETCH: return self.state_IDLE self.want_dis = 0 self.want_imm = 0 self.want_read = 0 self.want_write = 0 self.want_wr_be = False self.op_repeat = False self.arg_dis = 0 self.arg_imm = 0 self.arg_read = 0 self.arg_write = 0 self.arg_reg = '' self.mnemonic = '' self.instr_pend = False self.read_pend = False self.write_pend = False self.dasm_start = self.samplenum self.op_prefix = 0 self.instr_len = 0 if self.bus_data in (0xCB, 0xED, 0xDD, 0xFD): return self.state_PRE1 else: return self.state_OPCODE def state_PRE1(self): if self.prev_cycle != Cycle.FETCH: self.mnemonic = 'Prefix not followed by fetch' self.ann_dasm = Ann.WARN return self.state_RESTART self.op_prefix = self.pend_data if self.op_prefix in (0xDD, 0xFD): if self.bus_data == 0xCB: return self.state_PRE2 if self.bus_data in (0xDD, 0xED, 0xFD): return self.state_PRE1 return self.state_OPCODE def state_PRE2(self): if self.prev_cycle != Cycle.MEMRD: self.mnemonic = 'Missing displacement' self.ann_dasm = Ann.WARN return self.state_RESTART self.op_prefix = (self.op_prefix << 8) | self.pend_data return self.state_PREDIS def state_PREDIS(self): if self.prev_cycle != Cycle.MEMRD: self.mnemonic = 'Missing opcode' self.ann_dasm = Ann.WARN return self.state_RESTART self.arg_dis = signed_byte(self.pend_data) return self.state_OPCODE def state_OPCODE(self): (table, self.arg_reg) = instr_table_by_prefix[self.op_prefix] self.op_prefix = 0 instruction = table.get(self.pend_data, None) if instruction is None: self.mnemonic = 'Invalid instruction' self.ann_dasm = Ann.WARN return self.state_RESTART (self.want_dis, self.want_imm, self.want_read, want_write, self.op_repeat, self.mnemonic) = instruction self.want_write = abs(want_write) self.want_wr_be = (want_write < 0) if self.want_dis > 0: return self.state_POSTDIS if self.want_imm > 0: return self.state_IMM1 self.ann_dasm = Ann.INSTR if self.want_read > 0 and self.prev_cycle in (Cycle.MEMRD, Cycle.IORD): return self.state_ROP1 if self.want_write > 0 and self.prev_cycle in (Cycle.MEMWR, Cycle.IOWR): return self.state_WOP1 return self.state_RESTART def state_POSTDIS(self): self.arg_dis = signed_byte(self.pend_data) if self.want_imm > 0: return self.state_IMM1 self.ann_dasm = Ann.INSTR if self.want_read > 0 and self.prev_cycle in (Cycle.MEMRD, Cycle.IORD): return self.state_ROP1 if self.want_write > 0 and self.prev_cycle in (Cycle.MEMWR, Cycle.IOWR): return self.state_WOP1 return self.state_RESTART def state_IMM1(self): self.arg_imm = self.pend_data if self.want_imm > 1: return self.state_IMM2 self.ann_dasm = Ann.INSTR if self.want_read > 0 and self.prev_cycle in (Cycle.MEMRD, Cycle.IORD): return self.state_ROP1 if self.want_write > 0 and self.prev_cycle in (Cycle.MEMWR, Cycle.IOWR): return self.state_WOP1 return self.state_RESTART def state_IMM2(self): self.arg_imm |= self.pend_data << 8 self.ann_dasm = Ann.INSTR if self.want_read > 0 and self.prev_cycle in (Cycle.MEMRD, Cycle.IORD): return self.state_ROP1 if self.want_write > 0 and self.prev_cycle in (Cycle.MEMWR, Cycle.IOWR): return self.state_WOP1 return self.state_RESTART def state_ROP1(self): self.arg_read = self.pend_data if self.want_read < 2: self.mnemonic = '{ro:02X}' self.ann_dasm = Ann.ROP if self.want_write > 0: return self.state_WOP1 if self.want_read > 1: return self.state_ROP2 if self.op_repeat and self.prev_cycle in (Cycle.MEMRD, Cycle.IORD): return self.state_ROP1 return self.state_RESTART def state_ROP2(self): self.arg_read |= self.pend_data << 8 self.mnemonic = '{ro:04X}' self.ann_dasm = Ann.ROP if self.want_write > 0 and self.prev_cycle in (Cycle.MEMWR, Cycle.IOWR): return self.state_WOP1 return self.state_RESTART def state_WOP1(self): self.arg_write = self.pend_data if self.want_read > 1: return self.state_ROP2 if self.want_write > 1: return self.state_WOP2 self.mnemonic = '{wo:02X}' self.ann_dasm = Ann.WOP if self.want_read > 0 and self.op_repeat and \ self.prev_cycle in (Cycle.MEMRD, Cycle.IORD): return self.state_ROP1 return self.state_RESTART def state_WOP2(self): if self.want_wr_be: self.arg_write = (self.arg_write << 8) | self.pend_data else: self.arg_write |= self.pend_data << 8 self.mnemonic = '{wo:04X}' self.ann_dasm = Ann.WOP return self.state_RESTART