# # The Python Imaging Library. # $Id$ # # GIF file handling # # History: # 1995-09-01 fl Created # 1996-12-14 fl Added interlace support # 1996-12-30 fl Added animation support # 1997-01-05 fl Added write support, fixed local colour map bug # 1997-02-23 fl Make sure to load raster data in getdata() # 1997-07-05 fl Support external decoder (0.4) # 1998-07-09 fl Handle all modes when saving (0.5) # 1998-07-15 fl Renamed offset attribute to avoid name clash # 2001-04-16 fl Added rewind support (seek to frame 0) (0.6) # 2001-04-17 fl Added palette optimization (0.7) # 2002-06-06 fl Added transparency support for save (0.8) # 2004-02-24 fl Disable interlacing for small images # # Copyright (c) 1997-2004 by Secret Labs AB # Copyright (c) 1995-2004 by Fredrik Lundh # # See the README file for information on usage and redistribution. # from PIL import Image, ImageFile, ImagePalette, _binary __version__ = "0.9" # -------------------------------------------------------------------- # Helpers i8 = _binary.i8 i16 = _binary.i16le o8 = _binary.o8 o16 = _binary.o16le # -------------------------------------------------------------------- # Identify/read GIF files def _accept(prefix): return prefix[:6] in [b"GIF87a", b"GIF89a"] ## # Image plugin for GIF images. This plugin supports both GIF87 and # GIF89 images. class GifImageFile(ImageFile.ImageFile): format = "GIF" format_description = "Compuserve GIF" global_palette = None def data(self): s = self.fp.read(1) if s and i8(s): return self.fp.read(i8(s)) return None def _open(self): # Screen s = self.fp.read(13) if s[:6] not in [b"GIF87a", b"GIF89a"]: raise SyntaxError("not a GIF file") self.info["version"] = s[:6] self.size = i16(s[6:]), i16(s[8:]) self.tile = [] flags = i8(s[10]) bits = (flags & 7) + 1 if flags & 128: # get global palette self.info["background"] = i8(s[11]) # check if palette contains colour indices p = self.fp.read(3 << bits) for i in range(0, len(p), 3): if not (i//3 == i8(p[i]) == i8(p[i+1]) == i8(p[i+2])): p = ImagePalette.raw("RGB", p) self.global_palette = self.palette = p break self.__fp = self.fp # FIXME: hack self.__rewind = self.fp.tell() self._n_frames = None self._seek(0) # get ready to read first frame @property def n_frames(self): if self._n_frames is None: current = self.tell() try: while True: self.seek(self.tell() + 1) except EOFError: self._n_frames = self.tell() + 1 self.seek(current) return self._n_frames def seek(self, frame): if frame == self.__frame: return if frame < self.__frame: self._seek(0) for f in range(self.__frame + 1, frame + 1): self._seek(f) def _seek(self, frame): if frame == 0: # rewind self.__offset = 0 self.dispose = None self.dispose_extent = [0, 0, 0, 0] # x0, y0, x1, y1 self.__frame = -1 self.__fp.seek(self.__rewind) self._prev_im = None self.disposal_method = 0 else: # ensure that the previous frame was loaded if not self.im: self.load() if frame != self.__frame + 1: raise ValueError("cannot seek to frame %d" % frame) self.__frame = frame self.tile = [] self.fp = self.__fp if self.__offset: # backup to last frame self.fp.seek(self.__offset) while self.data(): pass self.__offset = 0 if self.dispose: self.im.paste(self.dispose, self.dispose_extent) from copy import copy self.palette = copy(self.global_palette) while True: s = self.fp.read(1) if not s or s == b";": break elif s == b"!": # # extensions # s = self.fp.read(1) block = self.data() if i8(s) == 249: # # graphic control extension # flags = i8(block[0]) if flags & 1: self.info["transparency"] = i8(block[3]) self.info["duration"] = i16(block[1:3]) * 10 # disposal method - find the value of bits 4 - 6 dispose_bits = 0b00011100 & flags dispose_bits = dispose_bits >> 2 if dispose_bits: # only set the dispose if it is not # unspecified. I'm not sure if this is # correct, but it seems to prevent the last # frame from looking odd for some animations self.disposal_method = dispose_bits elif i8(s) == 255: # # application extension # self.info["extension"] = block, self.fp.tell() if block[:11] == b"NETSCAPE2.0": block = self.data() if len(block) >= 3 and i8(block[0]) == 1: self.info["loop"] = i16(block[1:3]) while self.data(): pass elif s == b",": # # local image # s = self.fp.read(9) # extent x0, y0 = i16(s[0:]), i16(s[2:]) x1, y1 = x0 + i16(s[4:]), y0 + i16(s[6:]) self.dispose_extent = x0, y0, x1, y1 flags = i8(s[8]) interlace = (flags & 64) != 0 if flags & 128: bits = (flags & 7) + 1 self.palette =\ ImagePalette.raw("RGB", self.fp.read(3 << bits)) # image data bits = i8(self.fp.read(1)) self.__offset = self.fp.tell() self.tile = [("gif", (x0, y0, x1, y1), self.__offset, (bits, interlace))] break else: pass # raise IOError, "illegal GIF tag `%x`" % i8(s) try: if self.disposal_method < 2: # do not dispose or none specified self.dispose = None elif self.disposal_method == 2: # replace with background colour self.dispose = Image.core.fill("P", self.size, self.info["background"]) else: # replace with previous contents if self.im: self.dispose = self.im.copy() # only dispose the extent in this frame if self.dispose: self.dispose = self.dispose.crop(self.dispose_extent) except (AttributeError, KeyError): pass if not self.tile: # self.__fp = None raise EOFError("no more images in GIF file") self.mode = "L" if self.palette: self.mode = "P" def tell(self): return self.__frame def load_end(self): ImageFile.ImageFile.load_end(self) # if the disposal method is 'do not dispose', transparent # pixels should show the content of the previous frame if self._prev_im and self.disposal_method == 1: # we do this by pasting the updated area onto the previous # frame which we then use as the current image content updated = self.im.crop(self.dispose_extent) self._prev_im.paste(updated, self.dispose_extent, updated.convert('RGBA')) self.im = self._prev_im self._prev_im = self.im.copy() # -------------------------------------------------------------------- # Write GIF files try: import _imaging_gif except ImportError: _imaging_gif = None RAWMODE = { "1": "L", "L": "L", "P": "P", } def _save(im, fp, filename): if _imaging_gif: # call external driver try: _imaging_gif.save(im, fp, filename) return except IOError: pass # write uncompressed file if im.mode in RAWMODE: im_out = im.copy() else: # convert on the fly (EXPERIMENTAL -- I'm not sure PIL # should automatically convert images on save...) if Image.getmodebase(im.mode) == "RGB": palette_size = 256 if im.palette: palette_size = len(im.palette.getdata()[1]) // 3 im_out = im.convert("P", palette=1, colors=palette_size) else: im_out = im.convert("L") # header try: palette = im.encoderinfo["palette"] except KeyError: palette = None im.encoderinfo["optimize"] = im.encoderinfo.get("optimize", True) header, used_palette_colors = getheader(im_out, palette, im.encoderinfo) for s in header: fp.write(s) flags = 0 if get_interlace(im): flags = flags | 64 # local image header get_local_header(fp, im, (0, 0), flags) im_out.encoderconfig = (8, get_interlace(im)) ImageFile._save(im_out, fp, [("gif", (0, 0)+im.size, 0, RAWMODE[im_out.mode])]) fp.write(b"\0") # end of image data fp.write(b";") # end of file try: fp.flush() except: pass def get_interlace(im): try: interlace = im.encoderinfo["interlace"] except KeyError: interlace = 1 # workaround for @PIL153 if min(im.size) < 16: interlace = 0 return interlace def get_local_header(fp, im, offset, flags): transparent_color_exists = False try: transparency = im.encoderinfo["transparency"] except KeyError: pass else: transparency = int(transparency) # optimize the block away if transparent color is not used transparent_color_exists = True if _get_optimize(im, im.encoderinfo): used_palette_colors = _get_used_palette_colors(im) # adjust the transparency index after optimize if len(used_palette_colors) < 256: for i in range(len(used_palette_colors)): if used_palette_colors[i] == transparency: transparency = i transparent_color_exists = True break else: transparent_color_exists = False if "duration" in im.encoderinfo: duration = int(im.encoderinfo["duration"] / 10) else: duration = 0 if transparent_color_exists or duration != 0: transparency_flag = 1 if transparent_color_exists else 0 if not transparent_color_exists: transparency = 0 fp.write(b"!" + o8(249) + # extension intro o8(4) + # length o8(transparency_flag) + # transparency info present o16(duration) + # duration o8(transparency) + # transparency index o8(0)) if "loop" in im.encoderinfo: number_of_loops = im.encoderinfo["loop"] fp.write(b"!" + o8(255) + # extension intro o8(11) + b"NETSCAPE2.0" + o8(3) + o8(1) + o16(number_of_loops) + # number of loops o8(0)) fp.write(b"," + o16(offset[0]) + # offset o16(offset[1]) + o16(im.size[0]) + # size o16(im.size[1]) + o8(flags) + # flags o8(8)) # bits def _save_netpbm(im, fp, filename): # # If you need real GIF compression and/or RGB quantization, you # can use the external NETPBM/PBMPLUS utilities. See comments # below for information on how to enable this. import os from subprocess import Popen, check_call, PIPE, CalledProcessError import tempfile file = im._dump() if im.mode != "RGB": with open(filename, 'wb') as f: stderr = tempfile.TemporaryFile() check_call(["ppmtogif", file], stdout=f, stderr=stderr) else: with open(filename, 'wb') as f: # Pipe ppmquant output into ppmtogif # "ppmquant 256 %s | ppmtogif > %s" % (file, filename) quant_cmd = ["ppmquant", "256", file] togif_cmd = ["ppmtogif"] stderr = tempfile.TemporaryFile() quant_proc = Popen(quant_cmd, stdout=PIPE, stderr=stderr) stderr = tempfile.TemporaryFile() togif_proc = Popen(togif_cmd, stdin=quant_proc.stdout, stdout=f, stderr=stderr) # Allow ppmquant to receive SIGPIPE if ppmtogif exits quant_proc.stdout.close() retcode = quant_proc.wait() if retcode: raise CalledProcessError(retcode, quant_cmd) retcode = togif_proc.wait() if retcode: raise CalledProcessError(retcode, togif_cmd) try: os.unlink(file) except: pass # -------------------------------------------------------------------- # GIF utilities def _get_optimize(im, info): return im.mode in ("P", "L") and info and info.get("optimize", 0) def _get_used_palette_colors(im): used_palette_colors = [] # check which colors are used i = 0 for count in im.histogram(): if count: used_palette_colors.append(i) i += 1 return used_palette_colors def getheader(im, palette=None, info=None): """Return a list of strings representing a GIF header""" # Header Block # http://www.matthewflickinger.com/lab/whatsinagif/bits_and_bytes.asp header = [ b"GIF87a" + # signature + version o16(im.size[0]) + # canvas width o16(im.size[1]) # canvas height ] if im.mode == "P": if palette and isinstance(palette, bytes): source_palette = palette[:768] else: source_palette = im.im.getpalette("RGB")[:768] else: # L-mode if palette and isinstance(palette, bytes): source_palette = palette[:768] else: source_palette = bytearray([i//3 for i in range(768)]) used_palette_colors = palette_bytes = None if _get_optimize(im, info): used_palette_colors = _get_used_palette_colors(im) # create the new palette if not every color is used if len(used_palette_colors) < 256: palette_bytes = b"" new_positions = {} i = 0 # pick only the used colors from the palette for oldPosition in used_palette_colors: palette_bytes += source_palette[oldPosition*3:oldPosition*3+3] new_positions[oldPosition] = i i += 1 # replace the palette color id of all pixel with the new id image_bytes = bytearray(im.tobytes()) for i in range(len(image_bytes)): image_bytes[i] = new_positions[image_bytes[i]] im.frombytes(bytes(image_bytes)) new_palette_bytes = (palette_bytes + (768 - len(palette_bytes)) * b'\x00') im.putpalette(new_palette_bytes) im.palette = ImagePalette.ImagePalette("RGB", palette=palette_bytes, size=len(palette_bytes)) if not palette_bytes: palette_bytes = source_palette # Logical Screen Descriptor # calculate the palette size for the header import math color_table_size = int(math.ceil(math.log(len(palette_bytes)//3, 2)))-1 if color_table_size < 0: color_table_size = 0 # size of global color table + global color table flag header.append(o8(color_table_size + 128)) # background + reserved/aspect background = im.info["background"] if "background" in im.info else 0 header.append(o8(background) + o8(0)) # end of Logical Screen Descriptor # add the missing amount of bytes # the palette has to be 2< 0: palette_bytes += o8(0) * 3 * actual_target_size_diff # Header + Logical Screen Descriptor + Global Color Table header.append(palette_bytes) return header, used_palette_colors def getdata(im, offset=(0, 0), **params): """Return a list of strings representing this image. The first string is a local image header, the rest contains encoded image data.""" class Collector(object): data = [] def write(self, data): self.data.append(data) im.load() # make sure raster data is available fp = Collector() try: im.encoderinfo = params # local image header get_local_header(fp, im, offset, 0) ImageFile._save(im, fp, [("gif", (0, 0)+im.size, 0, RAWMODE[im.mode])]) fp.write(b"\0") # end of image data finally: del im.encoderinfo return fp.data # -------------------------------------------------------------------- # Registry Image.register_open(GifImageFile.format, GifImageFile, _accept) Image.register_save(GifImageFile.format, _save) Image.register_extension(GifImageFile.format, ".gif") Image.register_mime(GifImageFile.format, "image/gif") # # Uncomment the following line if you wish to use NETPBM/PBMPLUS # instead of the built-in "uncompressed" GIF encoder # Image.register_save(GifImageFile.format, _save_netpbm)