ref: e92a9ead39aec465f1e084b1ecaefa145bb65cc7
dir: /extras/gfx.py/
# -*- coding: utf-8 -*- import os import sys import errno import string from copy import copy, deepcopy import random import argparse from math import sqrt, floor, ceil from datetime import datetime from crystal import load_rom rom = load_rom() def mkdir_p(path): try: os.makedirs(path) except OSError as exc: # Python >2.5 if exc.errno == errno.EEXIST: pass else: raise def hex_dump(input, debug = True): """display hex dump in rows of 16 bytes""" dump = '' output = '' stream = '' address = 0x00 margin = 2 + len(hex(len(input))[2:]) # dump for byte in input: cool = hex(byte)[2:].zfill(2) dump += cool + ' ' if debug: stream += cool # convenient for testing quick edits in bgb if debug: output += stream + '\n' # get dump info bytes_per_line = 16 chars_per_byte = 3 # '__ ' chars_per_line = bytes_per_line * chars_per_byte num_lines = int(ceil(float(len(dump)) / float(chars_per_line))) # top # margin for char in range(margin): output += ' ' # for byte in range(bytes_per_line): output += hex(byte)[2:].zfill(2) + ' ' output = output[:-1] # last space # print hex for line in range(num_lines): # address output += '\n' + hex(address)[2:].zfill(margin - 2) + ': ' # contents start = line * chars_per_line end = chars_per_line + start - 1 # ignore last space output += dump[start:end] address += 0x10 return output def get_tiles(image): """split a 2bpp image into 8x8 tiles""" tiles = [] tile = [] bytes_per_tile = 16 cur_byte = 0 for byte in image: # build tile tile.append(byte) cur_byte += 1 # done building? if cur_byte >= bytes_per_tile: # push completed tile tiles.append(tile) tile = [] cur_byte = 0 return tiles def connect(tiles): """combine 8x8 tiles into a 2bpp image""" out = [] for tile in tiles: for byte in tile: out.append(byte) return out def transpose(tiles): """transpose a tile arrangement along line y=x""" # horizontal <-> vertical # 00 01 02 03 04 05 00 06 0c 12 18 1e # 06 07 08 09 0a 0b 01 07 0d 13 19 1f # 0c 0d 0e 0f 10 11 <-> 02 08 0e 14 1a 20 # 12 13 14 15 16 17 <-> 03 09 0f 15 1b 21 # 18 19 1a 1b 1c 1d 04 0a 10 16 1c 22 # 1e 1f 20 21 22 23 05 0b 11 17 1d 23 # etc flipped = [] t = 0 # which tile we're on w = int(sqrt(len(tiles))) # assume square image for tile in tiles: flipped.append(tiles[t]) t += w # end of row? if t >= w*w: # wrap around t -= w*w # next row t += 1 return flipped def to_file(filename, data): file = open(filename, 'wb') for byte in data: file.write('%c' % byte) file.close() # basic rundown of crystal's compression scheme: # a control command consists of # the command (bits 5-7) # and the count (bits 0-4) # followed by additional params lz_lit = 0 # print literal for [count] bytes lz_iter = 1 # print one byte [count] times lz_alt = 2 # print alternating bytes (2 params) for [count] bytes lz_zeros = 3 # print 00 for [count] bytes # repeater control commands have a signed parameter used to determine the start point # wraparound is simulated # positive values are added to the start address of the decompressed data # and negative values are subtracted from the current position lz_repeat = 4 # print [count] bytes from decompressed data lz_flip = 5 # print [count] bytes from decompressed data in bit order 01234567 lz_reverse = 6 # print [count] bytes from decompressed data backwards lz_hi = 7 # -used when the count exceeds 5 bits. uses a 10-bit count instead # -bits 2-4 now contain the control code, bits 0-1 are bits 8-9 of the count # -the following byte contains bits 0-7 of the count lz_end = 0xff # if 0xff is encountered the decompression ends # since frontpics have animation tiles lumped onto them, # sizes must be grabbed from base stats to know when to stop reading them max_length = 1 << 10 # can't go higher than 10 bits lowmax = 1 << 5 # standard 5-bit param class Compressed: """compress 2bpp data""" def __init__(self, image = None, mode = 'horiz', size = None): assert image, 'need something to compress!' self.image = image self.pic = [] self.animtiles = [] # only transpose pic (animtiles were never transposed in decompression) if size != None: for byte in range((size*size)*16): self.pic += image[byte] for byte in range(((size*size)*16),len(image)): self.animtiles += image[byte] else: self.pic = image if mode == 'vert': self.tiles = get_tiles(self.pic) self.tiles = transpose(self.tiles) self.pic = connect(self.tiles) self.image = self.pic + self.animtiles self.end = len(self.image) self.byte = None self.address = 0 self.stream = [] self.zeros = [] self.alts = [] self.iters = [] self.repeats = [] self.flips = [] self.reverses = [] self.literals = [] self.output = [] self.compress() def compress(self): """incomplete, but outputs working compressed data""" self.address = 0 # todo #self.scanRepeats() while ( self.address < self.end ): #if (self.repeats): # self.doRepeats() #if (self.flips): # self.doFlips() #if (self.reverses): # self.doReverses if (self.checkWhitespace()): self.doLiterals() self.doWhitespace() elif (self.checkIter()): self.doLiterals() self.doIter() elif (self.checkAlts()): self.doLiterals() self.doAlts() else: # doesn't fit any pattern -> literal self.addLiteral() self.next() self.doStream() # add any literals we've been sitting on self.doLiterals() # done self.output.append(lz_end) def getCurByte(self): if self.address < self.end: self.byte = ord(self.image[self.address]) else: self.byte = None def next(self): self.address += 1 self.getCurByte() def addLiteral(self): self.getCurByte() self.literals.append(self.byte) if len(self.literals) > max_length: raise Exception, "literals exceeded max length and the compressor didn't catch it" elif len(self.literals) == max_length: self.doLiterals() def doLiterals(self): if len(self.literals) > lowmax: self.output.append( (lz_hi << 5) | (lz_lit << 2) | ((len(self.literals) - 1) >> 8) ) self.output.append( (len(self.literals) - 1) & 0xff ) elif len(self.literals) > 0: self.output.append( (lz_lit << 5) | (len(self.literals) - 1) ) for byte in self.literals: self.output.append(byte) self.literals = [] def doStream(self): for byte in self.stream: self.output.append(byte) self.stream = [] def scanRepeats(self): """works, but doesn't do flipped/reversed streams yet this takes up most of the compress time and only saves a few bytes it might be more feasible to exclude it entirely""" self.repeats = [] self.flips = [] self.reverses = [] # make a 5-letter word list of the sequence letters = 5 # how many bytes it costs to use a repeat over a literal # any shorter and it's not worth the trouble num_words = len(self.image) - letters words = [] for i in range(self.address,num_words): word = [] for j in range(letters): word.append( ord(self.image[i+j]) ) words.append((word, i)) zeros = [] for zero in range(letters): zeros.append( 0 ) # check for matches def get_matches(): # TODO: # append to 3 different match lists instead of yielding to one # #flipped = [] #for byte in enumerate(this[0]): # flipped.append( sum(1<<(7-i) for i in range(8) if (this[0][byte])>>i&1) ) #reversed = this[0][::-1] # for whereabout, this in enumerate(words): for that in range(whereabout+1,len(words)): if words[that][0] == this[0]: if words[that][1] - this[1] >= letters: # remove zeros if this[0] != zeros: yield [this[0], this[1], words[that][1]] matches = list(get_matches()) # remove more zeros buffer = [] for match in matches: # count consecutive zeros in a word num_zeros = 0 highest = 0 for j in range(letters): if match[0][j] == 0: num_zeros += 1 else: if highest < num_zeros: highest = num_zeros num_zeros = 0 if highest < 4: # any more than 3 zeros in a row isn't worth it # (and likely to already be accounted for) buffer.append(match) matches = buffer # combine overlapping matches buffer = [] for this, match in enumerate(matches): if this < len(matches) - 1: # special case for the last match if matches[this+1][1] <= (match[1] + len(match[0])): # check overlap if match[1] + len(match[0]) < match[2]: # next match now contains this match's bytes too # this only appends the last byte (assumes overlaps are +1 match[0].append(matches[this+1][0][-1]) matches[this+1] = match elif match[1] + len(match[0]) == match[2]: # we've run into the thing we matched buffer.append(match) # else we've gone past it and we can ignore it else: # no more overlaps buffer.append(match) else: # last match, so there's nothing to check buffer.append(match) matches = buffer # remove alternating sequences buffer = [] for match in matches: for i in range(6 if letters > 6 else letters): if match[0][i] != match[0][i&1]: buffer.append(match) break matches = buffer self.repeats = matches def doRepeats(self): """doesn't output the right values yet""" unusedrepeats = [] for repeat in self.repeats: if self.address >= repeat[2]: # how far in we are length = (len(repeat[0]) - (self.address - repeat[2])) # decide which side we're copying from if (self.address - repeat[1]) <= 0x80: self.doLiterals() self.stream.append( (lz_repeat << 5) | length - 1 ) # wrong? self.stream.append( (((self.address - repeat[1])^0xff)+1)&0xff ) else: self.doLiterals() self.stream.append( (lz_repeat << 5) | length - 1 ) # wrong? self.stream.append(repeat[1]>>8) self.stream.append(repeat[1]&0xff) #print hex(self.address) + ': ' + hex(len(self.output)) + ' ' + hex(length) self.address += length else: unusedrepeats.append(repeat) self.repeats = unusedrepeats def checkWhitespace(self): self.zeros = [] self.getCurByte() original_address = self.address if ( self.byte == 0 ): while ( self.byte == 0 ) & ( len(self.zeros) <= max_length ): self.zeros.append(self.byte) self.next() if len(self.zeros) > 1: return True self.address = original_address return False def doWhitespace(self): if (len(self.zeros) + 1) >= lowmax: self.stream.append( (lz_hi << 5) | (lz_zeros << 2) | ((len(self.zeros) - 1) >> 8) ) self.stream.append( (len(self.zeros) - 1) & 0xff ) elif len(self.zeros) > 1: self.stream.append( lz_zeros << 5 | (len(self.zeros) - 1) ) else: raise Exception, "checkWhitespace() should prevent this from happening" def checkAlts(self): self.alts = [] self.getCurByte() original_address = self.address num_alts = 0 # make sure we don't check for alts at the end of the file if self.address+2 >= self.end: return False self.alts.append(self.byte) self.alts.append(ord(self.image[self.address+1])) # are we onto smething? if ( ord(self.image[self.address+2]) == self.alts[0] ): cur_alt = 0 while (ord(self.image[(self.address)+1]) == self.alts[num_alts&1]) & (num_alts <= max_length): num_alts += 1 self.next() # include the last alternated byte num_alts += 1 self.address = original_address if num_alts > lowmax: return True elif num_alts > 2: return True return False def doAlts(self): original_address = self.address self.getCurByte() #self.alts = [] #num_alts = 0 #self.alts.append(self.byte) #self.alts.append(ord(self.image[self.address+1])) #i = 0 #while (ord(self.image[self.address+1]) == self.alts[i^1]) & (num_alts <= max_length): # num_alts += 1 # i ^=1 # self.next() ## include the last alternated byte #num_alts += 1 num_alts = len(self.iters) + 1 if num_alts > lowmax: self.stream.append( (lz_hi << 5) | (lz_alt << 2) | ((num_alts - 1) >> 8) ) self.stream.append( num_alts & 0xff ) self.stream.append( self.alts[0] ) self.stream.append( self.alts[1] ) elif num_alts > 2: self.stream.append( (lz_alt << 5) | (num_alts - 1) ) self.stream.append( self.alts[0] ) self.stream.append( self.alts[1] ) else: raise Exception, "checkAlts() should prevent this from happening" self.address = original_address self.address += num_alts def checkIter(self): self.iters = [] self.getCurByte() iter = self.byte original_address = self.address while (self.byte == iter) & (len(self.iters) < max_length): self.iters.append(self.byte) self.next() self.address = original_address if len(self.iters) > 3: # 3 or fewer isn't worth the trouble and actually longer # if part of a larger literal set return True return False def doIter(self): self.getCurByte() iter = self.byte original_address = self.address self.iters = [] while (self.byte == iter) & (len(self.iters) < max_length): self.iters.append(self.byte) self.next() if (len(self.iters) - 1) >= lowmax: self.stream.append( (lz_hi << 5) | (lz_iter << 2) | ((len(self.iters)-1) >> 8) ) self.stream.append( (len(self.iters) - 1) & 0xff ) self.stream.append( iter ) elif len(self.iters) > 3: # 3 or fewer isn't worth the trouble and actually longer # if part of a larger literal set self.stream.append( (lz_iter << 5) | (len(self.iters) - 1) ) self.stream.append( iter ) else: self.address = original_address raise Exception, "checkIter() should prevent this from happening" class Decompressed: """parse compressed 2bpp data parameters: [compressed 2bpp data] [tile arrangement] default: 'vert' [size of pic] default: None [start] (optional) splits output into pic [size] and animation tiles if applicable data can be fed in from rom if [start] is specified""" def __init__(self, lz = None, mode = None, size = None, start = 0): # todo: play nice with Compressed assert lz, 'need something to compress!' self.lz = lz self.byte = None self.address = 0 self.start = start self.output = [] self.decompress() debug = False # print tuple containing start and end address if debug: print '(' + hex(self.start) + ', ' + hex(self.start + self.address+1) + '),' # only transpose pic self.pic = [] self.animtiles = [] if size != None: self.tiles = get_tiles(self.output) self.pic = connect(self.tiles[:(size*size)]) self.animtiles = connect(self.tiles[(size*size):]) else: self.pic = self.output if mode == 'vert': self.tiles = get_tiles(self.pic) self.tiles = transpose(self.tiles) self.pic = connect(self.tiles) def decompress(self): """replica of crystal's decompression""" self.output = [] while True: self.getCurByte() if (self.byte == lz_end): break self.cmd = (self.byte & 0b11100000) >> 5 if self.cmd == lz_hi: # 10-bit param self.cmd = (self.byte & 0b00011100) >> 2 self.length = (self.byte & 0b00000011) << 8 self.next() self.length += self.byte + 1 else: # 5-bit param self.length = (self.byte & 0b00011111) + 1 # literals if self.cmd == lz_lit: self.doLiteral() elif self.cmd == lz_iter: self.doIter() elif self.cmd == lz_alt: self.doAlt() elif self.cmd == lz_zeros: self.doZeros() else: # repeaters self.next() if self.byte > 0x7f: # negative self.displacement = self.byte & 0x7f self.displacement = len(self.output) - self.displacement - 1 else: # positive self.displacement = self.byte * 0x100 self.next() self.displacement += self.byte if self.cmd == lz_flip: self.doFlip() elif self.cmd == lz_reverse: self.doReverse() else: # lz_repeat self.doRepeat() self.address += 1 #self.next() # somewhat of a hack def getCurByte(self): self.byte = ord(self.lz[self.start+self.address]) def next(self): self.address += 1 self.getCurByte() def doLiteral(self): # copy 2bpp data directly for byte in range(self.length): self.next() self.output.append(self.byte) def doIter(self): # write one byte repeatedly self.next() for byte in range(self.length): self.output.append(self.byte) def doAlt(self): # write alternating bytes self.alts = [] self.next() self.alts.append(self.byte) self.next() self.alts.append(self.byte) for byte in range(self.length): self.output.append(self.alts[byte&1]) def doZeros(self): # write zeros for byte in range(self.length): self.output.append(0x00) def doFlip(self): # repeat flipped bytes from 2bpp output # eg 11100100 -> 00100111 # quat 3 2 1 0 -> 0 2 1 3 for byte in range(self.length): flipped = sum(1<<(7-i) for i in range(8) if self.output[self.displacement+byte]>>i&1) self.output.append(flipped) def doReverse(self): # repeat reversed bytes from 2bpp output for byte in range(self.length): self.output.append(self.output[self.displacement-byte]) def doRepeat(self): # repeat bytes from 2bpp output for byte in range(self.length): self.output.append(self.output[self.displacement+byte]) sizes = { 0: 5, 1: 6, 2: 7, 3: 5, 4: 6, 5: 7, 6: 5, 7: 6, 8: 7, 9: 5, 10: 5, 11: 7, 12: 5, 13: 5, 14: 7, 15: 5, 16: 6, 17: 7, 18: 5, 19: 6, 20: 5, 21: 7, 22: 5, 23: 7, 24: 5, 25: 7, 26: 5, 27: 6, 28: 5, 29: 6, 30: 7, 31: 5, 32: 6, 33: 7, 34: 5, 35: 6, 36: 6, 37: 7, 38: 5, 39: 6, 40: 5, 41: 7, 42: 5, 43: 6, 44: 7, 45: 5, 46: 7, 47: 5, 48: 7, 49: 5, 50: 7, 51: 5, 52: 7, 53: 5, 54: 7, 55: 5, 56: 7, 57: 5, 58: 7, 59: 5, 60: 6, 61: 7, 62: 5, 63: 6, 64: 7, 65: 5, 66: 7, 67: 7, 68: 5, 69: 6, 70: 7, 71: 5, 72: 6, 73: 5, 74: 6, 75: 6, 76: 6, 77: 7, 78: 5, 79: 7, 80: 5, 81: 6, 82: 6, 83: 5, 84: 7, 85: 6, 86: 7, 87: 5, 88: 7, 89: 5, 90: 7, 91: 7, 92: 6, 93: 6, 94: 7, 95: 6, 96: 7, 97: 5, 98: 7, 99: 5, 100: 5, 101: 7, 102: 7, 103: 5, 104: 6, 105: 7, 106: 6, 107: 7, 108: 6, 109: 7, 110: 7, 111: 7, 112: 6, 113: 6, 114: 7, 115: 5, 116: 6, 117: 6, 118: 7, 119: 6, 120: 6, 121: 6, 122: 7, 123: 6, 124: 6, 125: 6, 126: 7, 127: 7, 128: 6, 129: 7, 130: 7, 131: 5, 132: 5, 133: 6, 134: 6, 135: 6, 136: 6, 137: 5, 138: 6, 139: 5, 140: 6, 141: 7, 142: 7, 143: 7, 144: 7, 145: 7, 146: 5, 147: 6, 148: 7, 149: 7, 150: 5, 151: 5, 152: 6, 153: 7, 154: 5, 155: 6, 156: 7, 157: 5, 158: 6, 159: 7, 160: 6, 161: 6, 162: 5, 163: 7, 164: 6, 165: 6, 166: 5, 167: 7, 168: 7, 169: 6, 170: 6, 171: 5, 172: 5, 173: 5, 174: 5, 175: 7, 176: 5, 177: 6, 178: 5, 179: 6, 180: 7, 181: 7, 182: 5, 183: 7, 184: 6, 185: 7, 186: 5, 187: 6, 188: 7, 189: 5, 190: 5, 191: 6, 192: 6, 193: 5, 194: 6, 195: 6, 196: 6, 197: 6, 198: 7, 199: 6, 200: 5, 201: 6, 202: 7, 203: 5, 204: 7, 205: 6, 206: 6, 207: 7, 208: 6, 209: 6, 210: 5, 211: 7, 212: 5, 213: 6, 214: 6, 215: 5, 216: 7, 217: 5, 218: 6, 219: 5, 220: 6, 221: 6, 222: 5, 223: 6, 224: 6, 225: 7, 226: 7, 227: 6, 228: 7, 229: 7, 230: 5, 231: 7, 232: 6, 233: 7, 234: 7, 235: 5, 236: 7, 237: 5, 238: 6, 239: 6, 240: 6, 241: 7, 242: 7, 243: 7, 244: 7, 245: 5, 246: 6, 247: 7, 248: 7, 249: 7, 250: 5, } def make_sizes(): """front pics have specified sizes""" top = 251 base_stats = 0x51424 # print monster sizes address = base_stats + 0x11 for id in range(top): size = (ord(rom[address])) & 0x0f print str(id) + ': ' + str(size) + ',' address += 0x20 fxs = 0xcfcf6 num_fx = 40 def decompress_fx_by_id(id): address = fxs + id*4 # len_fxptr # get size num_tiles = ord(rom[address]) # # tiles # get pointer bank = ord(rom[address+1]) address = (ord(rom[address+3]) << 8) + ord(rom[address+2]) address = (bank * 0x4000) + (address & 0x3fff) # decompress fx = Decompressed(rom, 'horiz', num_tiles, address) return fx def decompress_fx(): for id in range(num_fx): fx = decompress_fx_by_id(id) filename = '../gfx/fx/' + str(id).zfill(3) + '.2bpp' # ../gfx/fx/039.2bpp to_file(filename, fx.pic) num_pics = 2 front = 0 back = 1 monsters = 0x120000 num_monsters = 251 unowns = 0x124000 num_unowns = 26 unown_dex = 201 def decompress_monster_by_id(id = 0, type = front): # no unowns here if id + 1 == unown_dex: return None # get size if type == front: size = sizes[id] else: size = None # get pointer address = monsters + (id*2 + type)*3 # bank, address bank = ord(rom[address]) + 0x36 # crystal address = (ord(rom[address+2]) << 8) + ord(rom[address+1]) address = (bank * 0x4000) + (address & 0x3fff) # decompress monster = Decompressed(rom, 'vert', size, address) return monster def decompress_monsters(type = front): for id in range(num_monsters): # decompress monster = decompress_monster_by_id(id, type) if monster != None: # no unowns here filename = str(id+1).zfill(3) + '.2bpp' # 001.2bpp if not type: # front folder = '../gfx/frontpics/' to_file(folder+filename, monster.pic) folder = '../gfx/anim/' to_file(folder+filename, monster.animtiles) else: # back folder = '../gfx/backpics/' to_file(folder+filename, monster.pic) def decompress_unown_by_id(letter, type = front): # get size if type == front: size = sizes[unown_dex-1] else: size = None # get pointer address = unowns + (letter*2 + type)*3 # bank, address bank = ord(rom[address]) + 0x36 # crystal address = (ord(rom[address+2]) << 8) + ord(rom[address+1]) address = (bank * 0x4000) + (address & 0x3fff) # decompress unown = Decompressed(rom, 'vert', size, address) return unown def decompress_unowns(type = front): for letter in range(num_unowns): # decompress unown = decompress_unown_by_id(letter, type) filename = str(unown_dex).zfill(3) + chr(ord('a') + letter) + '.2bpp' # 201a.2bpp if not type: # front folder = '../gfx/frontpics/' to_file(folder+filename, unown.pic) folder = '../gfx/anim/' to_file(folder+filename, unown.animtiles) else: # back folder = '../gfx/backpics/' to_file(folder+filename, unown.pic) trainers = 0x128000 num_trainers = 67 def decompress_trainer_by_id(id): # get pointer address = trainers + id*3 # bank, address bank = ord(rom[address]) + 0x36 # crystal address = (ord(rom[address+2]) << 8) + ord(rom[address+1]) address = (bank * 0x4000) + (address & 0x3fff) # decompress trainer = Decompressed(rom, 'vert', None, address) return trainer def decompress_trainers(): for id in range(num_trainers): # decompress trainer = decompress_trainer_by_id(id) filename = '../gfx/trainers/' + str(id).zfill(3) + '.2bpp' # ../gfx/trainers/066.2bpp to_file(filename, trainer.pic) # in order of use (sans repeats) intro_gfx = [ ('logo', 0x109407), ('001', 0xE641D), # tilemap ('unowns', 0xE5F5D), ('pulse', 0xE634D), ('002', 0xE63DD), # tilemap ('003', 0xE5ECD), # tilemap ('background', 0xE5C7D), ('004', 0xE5E6D), # tilemap ('005', 0xE647D), # tilemap ('006', 0xE642D), # tilemap ('pichu_wooper', 0xE592D), ('suicune_run', 0xE555D), ('007', 0xE655D), # tilemap ('008', 0xE649D), # tilemap ('009', 0xE76AD), # tilemap ('suicune_jump', 0xE6DED), ('unown_back', 0xE785D), ('010', 0xE764D), # tilemap ('011', 0xE6D0D), # tilemap ('suicune_close', 0xE681D), ('012', 0xE6C3D), # tilemap ('013', 0xE778D), # tilemap ('suicune_back', 0xE72AD), ('014', 0xE76BD), # tilemap ('015', 0xE676D), # tilemap ('crystal_unowns', 0xE662D), ('017', 0xE672D), # tilemap ] def decompress_intro(): for name, address in intro_gfx: filename = '../gfx/intro/' + name + '.2bpp' gfx = Decompressed( rom, 'horiz', None, address ) to_file(filename, gfx.output) title_gfx = [ ('suicune', 0x10EF46), ('logo', 0x10F326), ('crystal', 0x10FCEE), ] def decompress_title(): for name, address in title_gfx: filename = '../gfx/title/' + name + '.2bpp' gfx = Decompressed( rom, 'horiz', None, address ) to_file(filename, gfx.output) def decompress_tilesets(): tileset_headers = 0x4d596 len_tileset = 15 num_tilesets = 0x25 for tileset in range(num_tilesets): ptr = tileset*len_tileset + tileset_headers address = (ord(rom[ptr])*0x4000) + (((ord(rom[ptr+1]))+ord(rom[ptr+2])*0x100)&0x3fff) tiles = Decompressed( rom, 'horiz', None, address ) filename = '../gfx/tilesets/'+str(tileset).zfill(2)+'.2bpp' to_file( filename, tiles.output ) #print '(' + hex(address) + ', '+ hex(address+tiles.address+1) + '),' misc = [ ('player', 0x2BA1A, 'vert'), ('dude', 0x2BBAA, 'vert'), ('town_map', 0xF8BA0, 'horiz'), ('pokegear', 0x1DE2E4, 'horiz'), ('pokegear_sprites', 0x914DD, 'horiz'), ] def decompress_misc(): for name, address, mode in misc: filename = '../gfx/misc/' + name + '.2bpp' gfx = Decompressed( rom, mode, None, address ) to_file(filename, gfx.output) def decompress_all(debug = False): """decompress all known compressed data in baserom""" #mkdir_p('../gfx/') #mkdir_p('../gfx/frontpics/') #mkdir_p('../gfx/anim/') #mkdir_p('../gfx/backpics/') #mkdir_p('../gfx/trainers/') #mkdir_p('../gfx/fx/') #mkdir_p('../gfx/intro/') #mkdir_p('../gfx/title/') #mkdir_p('../gfx/tilesets/') #mkdir_p('../gfx/misc/') if debug: print 'fronts' decompress_monsters(front) if debug: print 'backs' decompress_monsters(back) if debug: print 'unown fronts' decompress_unowns(front) if debug: print 'unown backs' decompress_unowns(back) if debug: print 'trainers' decompress_trainers() if debug: print 'fx' decompress_fx() if debug: print 'intro' decompress_intro() if debug: print 'title' decompress_title() if debug: print 'tilesets' decompress_tilesets() if debug: print 'misc' decompress_misc() return def decompress_from_address(address, mode='horiz', filename = 'de.2bpp', size = None): """write decompressed data from an address to a 2bpp file""" image = Decompressed(rom, mode, size, address) to_file(filename, image.pic) def decompress_file(filein, fileout, mode = 'horiz', size = None): f = open(filein, 'rb') image = f.read() f.close() de = Decompressed(image, mode, size) to_file(fileout, de.pic) def compress_file(filein, fileout, mode = 'horiz'): f = open(filein, 'rb') image = f.read() f.close() lz = Compressed(image, mode) to_file(fileout, lz.output) def compress_monster_frontpic(id, fileout): mode = 'vert' fpic = '../gfx/frontpics/' + str(id).zfill(3) + '.2bpp' fanim = '../gfx/anim/' + str(id).zfill(3) + '.2bpp' pic = open(fpic, 'rb').read() anim = open(fanim, 'rb').read() image = pic + anim lz = Compressed(image, mode, 5) out = '../gfx/frontpics/lz/' + str(id).zfill(3) + '.lz' to_file(out, lz.output) def get_uncompressed_gfx(start, num_tiles, filename): """grab tiles directly from rom and write to file""" bytes_per_tile = 0x10 length = num_tiles*bytes_per_tile end = start + length rom = load_rom() image = [] for address in range(start,end): image.append(ord(rom[address])) to_file(filename, image) def hex_to_rgb(word): red = word & 0b11111 word >>= 5 green = word & 0b11111 word >>= 5 blue = word & 0b11111 return (red, green, blue) def grab_palettes(address, length = 0x80): output = '' for word in range(length/2): color = ord(rom[address+1])*0x100 + ord(rom[address]) address += 2 color = hex_to_rgb(color) red = str(color[0]).zfill(2) green = str(color[1]).zfill(2) blue = str(color[2]).zfill(2) output += '\tRGB '+red+', '+green+', '+blue output += '\n' return output if __name__ == "__main__": parser = argparse.ArgumentParser() parser.add_argument('cmd', nargs='?', metavar='cmd', type=str) parser.add_argument('arg1', nargs='?', metavar='arg1', type=str) parser.add_argument('arg2', nargs='?', metavar='arg2', type=str) parser.add_argument('arg3', nargs='?', metavar='arg3', type=str) args = parser.parse_args() debug = True if args.cmd == 'de': # python gfx.py de [addr] [fileout] [mode] addr = int(args.arg1,16) fileout = args.arg2 mode = args.arg3 decompress_from_address(addr, fileout, mode) if debug: print 'decompressed to ' + args.arg2 + ' from ' + hex(int(args.arg1,16)) + '!' elif args.cmd == 'lz': # python gfx.py lz [filein] [fileout] [mode] filein = args.arg1 fileout = args.arg2 mode = args.arg3 compress_file(filein, fileout, mode) if debug: print 'compressed ' + filein + ' to ' + fileout + '!' elif args.cmd == 'lzf': # python gfx.py lzf [id] [fileout] compress_monster_frontpic(int(args.arg1), args.arg2) elif args.cmd == 'un': # python gfx.py un [address] [num_tiles] [filename] get_uncompressed_gfx(int(args.arg1,16), int(args.arg2), args.arg3) elif args.cmd == 'pal': # python gfx.py pal [address] [length] print grab_palettes(int(args.arg1,16), int(args.arg2)) #else: ## python gfx.py #decompress_all() #if debug: print 'decompressed known gfx to ../gfx/!'