mirror of
https://gitlab.com/xCrystal/pokecrystal-board.git
synced 2024-09-09 09:51:34 -07:00
379 lines
14 KiB
Python
379 lines
14 KiB
Python
from gbz80disasm import opt_table
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from ctypes import c_int8
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from copy import copy, deepcopy
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relative_jumps = [0x38, 0x30, 0x20, 0x28, 0x18, 0xc3, 0xda, 0xc2]
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relative_unconditional_jumps = [0xc3, 0x18]
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call_commands = [0xdc, 0xd4, 0xc4, 0xcc, 0xcd]
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end_08_scripts_with = [
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0xe9, # jp hl
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0xc9, # ret
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] # possibly also:
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# 0xc3, # jp
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# 0xc18, # jr
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# 0xda, 0xe9, 0xd2, 0xc2, 0xca, 0xc3, 0x38, 0x30, 0x20, 0x28, 0x18, 0xd8,
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# 0xd0, 0xc0, 0xc8, 0xc9
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class RomStr(str):
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""" Simple wrapper to prevent a giant rom from being shown on screen.
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"""
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def __repr__(self):
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""" Simplifies this object so that the output doesn't overflow stdout.
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"""
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return "RomStr(too long)"
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@classmethod
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def load(cls, crystal=True, red=False):
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""" Loads a ROM into a RomStr.
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"""
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if crystal and not red:
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file_handler = open("../baserom.gbc", "r")
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elif red and not crystal:
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file_handler = open("../pokered-baserom.gbc", "r")
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else:
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raise Exception, "not sure which rom to load?"
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bytes = file_handler.read()
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file_handler.close()
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return RomStr(bytes)
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def length(self):
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""" len(self)
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"""
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return len(self)
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def len(self):
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""" len(self)
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"""
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return self.length()
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def interval(self, offset, length, strings=True, debug=True):
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""" returns hex values for the rom starting at offset until
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offset+length
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"""
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returnable = []
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for byte in self[offset:offset+length]:
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if strings:
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returnable.append(hex(ord(byte)))
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else:
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returnable.append(ord(byte))
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return returnable
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def until(self, offset, byte, strings=True, debug=False):
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""" Returns hex values from rom starting at offset until the given
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byte.
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"""
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return self.interval(offset, self.find(chr(byte), offset) - offset, strings=strings)
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def to_asm(self, address, end_address=None, size=None, max_size=0x4000, debug=None):
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""" Disassembles ASM at some address. This will stop disassembling when
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either the end_address or size is met. Also, there's a maximum size
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that will be parsed, so that large patches of data aren't parsed as
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code.
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"""
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start_address = address
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if start_address == None:
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raise Exception, "address must be given"
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if debug == None:
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if not hasattr(self, "debug"):
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debug = False
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else:
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debug = self.debug
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# this is probably a terrible idea.. why am i doing this?
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if size != None and max_size < size:
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raise Exception, "max_size must be greater than or equal to size"
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elif end_address != None and (end_address - start_address) > max_size:
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raise Exception, "end_address is out of bounds"
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elif end_address != None and size != None:
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if (end_address - start_address) >= size:
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size = end_address - start_address
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else:
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end_address = start_address + size
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elif end_address == None and size != None:
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end_address = start_address + size
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elif end_address != None and size == None:
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size = end_address - start_address
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return Asm(start_address=start_address, end_address=end_address, size=size, max_size=max_size, debug=debug, rom=self)
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class Asm:
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""" z80 disassembler
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"""
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def __init__(self, start_address=None, end_address=None, size=None, max_size=0x4000, debug=True, rom=None):
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assert start_address != None, "start_address must be given"
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if rom == None:
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file_handler = open("../baserom.gbc", "r")
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bytes = file_handler.read()
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file_handler.close()
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rom = RomStr(bytes)
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if debug not in [None, True, False]:
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raise Exception, "debug param is invalid"
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if debug == None:
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debug = False
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# get end_address and size in sync with each other
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if end_address == None and size != None:
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end_address = start_address + size
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elif end_address != None and size == None:
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size = end_address - start_address
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elif end_address != None and size != None:
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size = max(end_address - start_address, size)
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end_address = start_address + size
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# check that the bounds make sense
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if end_address != None:
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if end_address <= start_address:
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raise Exception, "end_address is out of bounds"
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elif (end_address - start_address) > max_size:
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raise Exception, "end_address goes beyond max_size"
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# check more edge cases
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if not start_address >= 0:
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raise Exception, "start_address must be at least 0"
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elif end_address != None and not end_address >= 0:
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raise Exception, "end_address must be at least 0"
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self.rom = rom
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self.start_address = start_address
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self.end_address = end_address
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self.size = size
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self.max_size = max_size
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self.debug = debug
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self.parse()
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def parse(self):
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""" Disassembles stuff and things.
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"""
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rom = self.rom
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start_address = self.start_address
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end_address = self.end_address
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max_size = self.max_size
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debug = self.debug
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bank_id = start_address / 0x4000
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# [{"command": 0x20, "bytes": [0x20, 0x40, 0x50],
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# "asm": "jp $5040", "label": "Unknown5040"}]
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asm_commands = {}
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offset = start_address
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last_hl_address = None
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last_a_address = None
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used_3d97 = False
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keep_reading = True
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while (end_address != 0 and offset <= end_address) or keep_reading:
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# read the current opcode byte
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current_byte = ord(rom[offset])
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current_byte_number = len(asm_commands.keys())
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# setup this next/upcoming command
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if offset in asm_commands.keys():
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asm_command = asm_commands[offset]
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else:
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asm_command = {}
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asm_command["address"] = offset
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if not "references" in asm_command.keys():
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# This counts how many times relative jumps reference this
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# byte. This is used to determine whether or not to print out a
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# label later.
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asm_command["references"] = 0
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print "debug1"
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# some commands have two opcodes
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next_byte = ord(rom[offset+1])
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print "offset: \t\t" + hex(offset)
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print "current_byte: \t\t" + hex(current_byte)
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print "next_byte: \t\t" + hex(next_byte)
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# all two-byte opcodes also have their first byte in there somewhere
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if (current_byte in opt_table.keys()) or ((current_byte + (next_byte << 8)) in opt_table.keys()):
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# this might be a two-byte opcode
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possible_opcode = current_byte + (next_byte << 8)
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# check if this is a two-byte opcode
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if possible_opcode in opt_table.keys():
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op_code = possible_opcode
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else:
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op_code = current_byte
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op = opt_table[op_code]
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opstr = op[0].lower()
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optype = op[1]
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print "opstr: " + opstr
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asm_command["type"] = "op"
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asm_command["id"] = op_code
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asm_command["format"] = opstr
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asm_command["opnumberthing"] = optype
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if "x" in opstr:
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for x in range(0, opstr.count("x")):
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insertion = ord(rom[offset + 1])
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# Certain opcodes will have a local relative jump label
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# here instead of a raw hex value, but this is
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# controlled through asm output.
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insertion = "$" + hex(insertion)[2:]
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opstr = opstr[:opstr.find("x")].lower() + insertion + opstr[opstr.find("x")+1:].lower()
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current_byte_number += 1
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offset += 1
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if "?" in opstr:
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for y in range(0, opstr.count("?")):
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byte1 = ord(rom[offset + 1])
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byte2 = ord(rom[offset + 2])
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number = byte1
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number += byte2 << 8;
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# In most cases, you can use a label here. Labels will
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# be shown during asm output.
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insertion = "$%.4x" % (number)
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opstr = opstr[:opstr.find("?")].lower() + insertion + opstr[opstr.find("?")+1:].lower()
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current_byte_number += 2
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offset += 2
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# Check for relative jumps, construct the formatted asm line.
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# Also set the usage of labels.
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if current_byte in [0x18, 0x20] + relative_jumps: # jr or jr nz
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# generate a label for the byte we're jumping to
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target_address = offset + 2 + c_int8(ord(rom[offset + 1])).value
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if target_address in asm_commands.keys():
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asm_commands[target_address]["references"] += 1
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remote_label = "asm_" + hex(target_address)
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asm_commands[target_address]["current_label"] = remote_label
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asm_command["remote_label"] = remote_label
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# Not sure how to set this, can't be True because an
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# address referenced multiple times will use a label
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# despite the label not necessarily being used in the
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# output. The "use_remote_label" values should be
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# calculated when rendering the asm output, based on
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# which addresses and which op codes will be displayed
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# (within the range).
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asm_command["use_remote_label"] = "unknown"
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else:
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remote_label = "asm_" + hex(target_address)
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# This remote address might not be part of this
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# function.
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asm_commands[target_address] = {
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"references": 1,
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"current_label": remote_label,
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}
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# Also, target_address can be negative (before the
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# start_address that the user originally requested),
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# and it shouldn't be shown on asm output because the
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# intermediate bytes (between a negative target_address
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# and start_address) won't be disassembled.
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# Don't know yet if this remote address is part of this
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# function or not. When the remote address is not part
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# of this function, the label name should not be used,
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# because that label will not be disassembled in the
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# output, until the user asks it to.
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asm_command["use_remote_label"] = "unknown"
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asm_command["remote_label"] = remote_label
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elif current_byte == 0x3e:
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last_a_address = ord(rom[offset + 1])
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# store the formatted string for the output later
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asm_command["formatted"] = opstr
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if current_byte == 0x21:
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last_hl_address = byte1 + (byte2 << 8)
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# this is leftover from pokered, might be meaningless
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if current_byte == 0xcd:
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if number == 0x3d97:
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used_3d97 = True
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if current_byte == 0xc3 or current_byte in relative_unconditional_jumps:
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if current_byte == 0xc3:
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if number == 0x3d97:
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used_3d97 = True
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if not self.has_outstanding_labels(asm_commands, offset):
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keep_reading = False
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break
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# stop reading at a jump, relative jump or return
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if current_byte in end_08_scripts_with:
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is_data = False
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if not self.has_outstanding_labels(asm_commands, offset):
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keep_reading = False
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break
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else:
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keep_reading = True
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else:
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keep_reading = True
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else:
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# This shouldn't really happen, and means that this area of the
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# ROM probably doesn't represent instructions.
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asm_command["type"] = "data" # db
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asm_command["value"] = current_byte
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keep_reading = False
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# save this new command in the list
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asm_commands[asm_command["address"]] = asm_command
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# jump forward by a byte
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offset += 1
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# also save the last command if necessary
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if asm_commands[asm_commands.keys()[-1]] is not asm_command:
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asm_commands[asm_command["address"]] = asm_command
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# store the set of commands on this object
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self.asm_commands = asm_commands
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print "debug10"
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def has_outstanding_labels(self, asm_commands, offset):
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""" Checks if there are any labels that haven't yet been created.
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""" # is this really necessary??
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return False
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def __str__(self):
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""" ASM pretty printer.
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"""
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raise NotImplementedError, "zzzzzz"
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class AsmList(list):
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""" Simple wrapper to prevent all asm lines from being shown on screen.
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"""
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def length(self):
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""" len(self)
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"""
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return len(self)
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def __repr__(self):
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""" Simplifies this object so that the output doesn't overflow stdout.
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"""
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return "AsmList(too long)"
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