# Classes to read and write CMIF video files. # (For a description of the CMIF video format, see cmif-file.ms.) # Layers of functionality: # # VideoParams: maintain essential parameters of a video file # Displayer: display a frame in a window (with some extra parameters) # BasicVinFile: read a CMIF video file # BasicVoutFile: write a CMIF video file # VinFile: BasicVinFile + Displayer # VoutFile: BasicVoutFile + Displayer # # XXX Future extension: # BasicVinoutFile: supports overwriting of individual frames # Imported modules import sys import gl import GL import GET import colorsys import imageop # Exception raised for various occasions Error = 'VFile.Error' # file format errors CallError = 'VFile.CallError' # bad call AssertError = 'VFile.AssertError' # internal malfunction # Max nr. of colormap entries to use MAXMAP = 4096 - 256 # Parametrizations of colormap handling based on color system. # (These functions are used via eval with a constructed argument!) def conv_grey(l, x, y): return colorsys.yiq_to_rgb(l, 0, 0) def conv_grey4(l, x, y): return colorsys.yiq_to_rgb(l*17, 0, 0) def conv_mono(l, x, y): return colorsys.yiq_to_rgb(l*255, 0, 0) def conv_yiq(y, i, q): return colorsys.yiq_to_rgb(y, (i-0.5)*1.2, q-0.5) def conv_hls(l, h, s): return colorsys.hls_to_rgb(h, l, s) def conv_hsv(v, h, s): return colorsys.hsv_to_rgb(h, s, v) def conv_rgb(r, g, b): raise Error, 'Attempt to make RGB colormap' def conv_rgb8(rgb, d1, d2): rgb = int(rgb*255.0) r = (rgb >> 5) & 0x07 g = (rgb ) & 0x07 b = (rgb >> 3) & 0x03 return (r/7.0, g/7.0, b/3.0) def conv_jpeg(r, g, b): raise Error, 'Attempt to make RGB colormap (jpeg)' conv_jpeggrey = conv_grey conv_grey2 = conv_grey # Choose one of the above based upon a color system name def choose_conversion(format): try: return eval('conv_' + format) except: raise Error, 'Unknown color system: ' + `format` # Inverses of the above def inv_grey(r, g, b): y, i, q = colorsys.rgb_to_yiq(r, g, b) return y, 0, 0 def inv_yiq(r, g, b): y, i, q = colorsys.rgb_to_yiq(r, g, b) return y, i/1.2 + 0.5, q + 0.5 def inv_hls(r, g, b): h, l, s = colorsys.rgb_to_hls(r, g, b) return l, h, s def inv_hsv(r, g, b): h, s, v = colorsys.rgb_to_hsv(r, g, b) return v, h, s def inv_rgb(r, g, b): raise Error, 'Attempt to invert RGB colormap' def inv_rgb8(r, g, b): r = int(r*7.0) g = int(g*7.0) b = int(b*7.0) rgb = ((r&7) << 5) | ((b&3) << 3) | (g&7) return rgb / 255.0, 0, 0 def inv_jpeg(r, g, b): raise Error, 'Attempt to invert RGB colormap (jpeg)' inv_jpeggrey = inv_grey # Choose one of the above based upon a color system name def choose_inverse(format): try: return eval('inv_' + format) except: raise Error, 'Unknown color system: ' + `format` # Predicate to see whether this is an entry level (non-XS) Indigo. # If so we can lrectwrite 8-bit wide pixels into a window in RGB mode def is_entry_indigo(): # XXX hack, hack. We should call gl.gversion() but that doesn't # exist in earlier Python versions. Therefore we check the number # of bitplanes *and* the size of the monitor. xmax = gl.getgdesc(GL.GD_XPMAX) if xmax <> 1024: return 0 ymax = gl.getgdesc(GL.GD_YPMAX) if ymax != 768: return 0 r = gl.getgdesc(GL.GD_BITS_NORM_SNG_RED) g = gl.getgdesc(GL.GD_BITS_NORM_SNG_GREEN) b = gl.getgdesc(GL.GD_BITS_NORM_SNG_BLUE) return (r, g, b) == (3, 3, 2) # Predicate to see whether this machine supports pixmode(PM_SIZE) with # values 1 or 4. # # XXX Temporarily disabled, since it is unclear which machines support # XXX which pixelsizes. # # XXX The XS appears to support 4 bit pixels, but (looking at osview) it # XXX seems as if the conversion is done by the kernel (unpacking ourselves # XXX is faster than using PM_SIZE=4) def support_packed_pixels(): return 0 # To be architecture-dependent # Tables listing bits per pixel for some formats bitsperpixel = { \ 'rgb': 32, \ 'rgb8': 8, \ 'grey': 8, \ 'grey4': 4, \ 'grey2': 2, \ 'mono': 1, \ 'compress': 32, \ } bppafterdecomp = {'jpeg': 32, 'jpeggrey': 8} # Base class to manage video format parameters class VideoParams: # Initialize an instance. # Set all parameters to something decent # (except width and height are set to zero) def init(self): # Essential parameters self.frozen = 0 # if set, can't change parameters self.format = 'grey' # color system used # Choose from: grey, rgb, rgb8, hsv, yiq, hls, jpeg, jpeggrey, # mono, grey2, grey4 self.width = 0 # width of frame self.height = 0 # height of frame self.packfactor = 1, 1 # expansion using rectzoom # Colormap info self.c0bits = 8 # bits in first color dimension self.c1bits = 0 # bits in second color dimension self.c2bits = 0 # bits in third color dimension self.offset = 0 # colormap index offset (XXX ???) self.chrompack = 0 # set if separate chrominance data self.setderived() return self # Freeze the parameters (disallow changes) def freeze(self): self.frozen = 1 # Unfreeze the parameters (allow changes) def unfreeze(self): self.frozen = 0 # Set some values derived from the standard info values def setderived(self): if self.frozen: raise AssertError if bitsperpixel.has_key(self.format): self.bpp = bitsperpixel[self.format] else: self.bpp = 0 xpf, ypf = self.packfactor self.xpf = abs(xpf) self.ypf = abs(ypf) self.mirror_image = (xpf < 0) self.upside_down = (ypf < 0) self.realwidth = self.width / self.xpf self.realheight = self.height / self.ypf # Set colormap info def setcmapinfo(self): stuff = 0, 0, 0, 0, 0 if self.format in ('rgb8', 'grey'): stuff = 8, 0, 0, 0, 0 if self.format == 'grey4': stuff = 4, 0, 0, 0, 0 if self.format == 'grey2': stuff = 2, 0, 0, 0, 0 if self.format == 'mono': stuff = 1, 0, 0, 0, 0 self.c0bits, self.c1bits, self.c2bits, \ self.offset, self.chrompack = stuff # Set the frame width and height (e.g. from gl.getsize()) def setsize(self, width, height): if self.frozen: raise CallError width = (width/self.xpf)*self.xpf height = (height/self.ypf)*self.ypf self.width, self.height = width, height self.setderived() # Retrieve the frame width and height (e.g. for gl.prefsize()) def getsize(self): return (self.width, self.height) # Set the format def setformat(self, format): if self.frozen: raise CallError self.format = format self.setderived() self.setcmapinfo() # Get the format def getformat(self): return self.format # Set the packfactor def setpf(self, pf): if self.frozen: raise CallError if type(pf) == type(1): pf = (pf, pf) if type(pf) is not type(()) or len(pf) <> 2: raise CallError self.packfactor = pf self.setderived() # Get the packfactor def getpf(self): return self.packfactor # Set all parameters def setinfo(self, values): if self.frozen: raise CallError self.setformat(values[0]) self.setpf(values[3]) self.setsize(values[1], values[2]) (self.c0bits, self.c1bits, self.c2bits, \ self.offset, self.chrompack) = values[4:9] if self.format == 'compress': self.compressheader = values[9] self.setderived() # Retrieve all parameters in a format suitable for a subsequent # call to setinfo() def getinfo(self): return (self.format, self.width, self.height, self.packfactor,\ self.c0bits, self.c1bits, self.c2bits, self.offset, \ self.chrompack) # Write the relevant bits to stdout def printinfo(self): print 'Format: ', self.format print 'Size: ', self.width, 'x', self.height print 'Pack: ', self.packfactor, '; chrom:', self.chrompack print 'Bpp: ', self.bpp print 'Bits: ', self.c0bits, self.c1bits, self.c2bits print 'Offset: ', self.offset # Calculate data size, if possible # (Not counting frame header or cdata size) def calcframesize(self): if not self.bpp: raise CallError size = self.width/self.xpf * self.height/self.ypf size = (size * self.bpp + 7) / 8 return size # Class to display video frames in a window. # It is the caller's responsibility to ensure that the correct window # is current when using showframe(), initcolormap(), clear() and clearto() class Displayer(VideoParams): # Initialize an instance. # This does not need a current window def init(self): self = VideoParams.init(self) # User-settable parameters self.magnify = 1.0 # frame magnification factor self.xorigin = 0 # x frame offset self.yorigin = 0 # y frame offset (from bottom) self.quiet = 0 # if set, don't print messages self.fallback = 1 # allow fallback to grey # Internal flags self.colormapinited = 0 # must initialize window self.skipchrom = 0 # don't skip chrominance data self.color0 = None # magic, used by clearto() self.fixcolor0 = 0 # don't need to fix color0 self.mustunpack = (not support_packed_pixels()) self.decompressor = None return self # setinfo() must reset some internal flags def setinfo(self, values): VideoParams.setinfo(self, values) self.colormapinited = 0 self.skipchrom = 0 self.color0 = None self.fixcolor0 = 0 # Show one frame, initializing the window if necessary def showframe(self, data, chromdata): self.showpartframe(data, chromdata, \ (0,0,self.width,self.height)) def showpartframe(self, data, chromdata, (x,y,w,h)): pmsize = self.bpp xpf, ypf = self.xpf, self.ypf if self.upside_down: gl.pixmode(GL.PM_TTOB, 1) if self.mirror_image: gp.pixmode(GL.PM_RTOL, 1) if self.format in ('jpeg', 'jpeggrey'): import jpeg data, width, height, bytes = jpeg.decompress(data) pmsize = bytes*8 elif self.format == 'compress': if not self.decompressor: import cl, CL scheme = cl.QueryScheme(self.compressheader) self.decompressor = cl.OpenDecompressor(scheme) headersize = self.decompressor.ReadHeader(self.compressheader) width = self.decompressor.GetParam(CL.IMAGE_WIDTH) height = self.decompressor.GetParam(CL.IMAGE_HEIGHT) params = [CL.ORIGINAL_FORMAT, CL.RGBX, \ CL.ORIENTATION, CL.BOTTOM_UP, \ CL.FRAME_BUFFER_SIZE, width*height*CL.BytesPerPixel(CL.RGBX)] self.decompressor.SetParams(params) data = self.decompressor.Decompress(1, data) elif self.format in ('mono', 'grey4'): if self.mustunpack: if self.format == 'mono': data = imageop.mono2grey(data, \ w/xpf, h/ypf, 0x20, 0xdf) elif self.format == 'grey4': data = imageop.grey42grey(data, \ w/xpf, h/ypf) pmsize = 8 elif self.format == 'grey2': data = imageop.grey22grey(data, w/xpf, h/ypf) pmsize = 8 if not self.colormapinited: self.initcolormap() if self.fixcolor0: gl.mapcolor(self.color0) self.fixcolor0 = 0 xfactor = yfactor = self.magnify xfactor = xfactor * xpf yfactor = yfactor * ypf if chromdata and not self.skipchrom: cp = self.chrompack cx = int(x*xfactor*cp) + self.xorigin cy = int(y*yfactor*cp) + self.yorigin cw = (w+cp-1)/cp ch = (h+cp-1)/cp gl.rectzoom(xfactor*cp, yfactor*cp) gl.pixmode(GL.PM_SIZE, 16) gl.writemask(self.mask - ((1 << self.c0bits) - 1)) gl.lrectwrite(cx, cy, cx + cw - 1, cy + ch - 1, \ chromdata) # if pmsize < 32: gl.writemask((1 << self.c0bits) - 1) gl.pixmode(GL.PM_SIZE, pmsize) w = w/xpf h = h/ypf x = x/xpf y = y/ypf gl.rectzoom(xfactor, yfactor) x = int(x*xfactor)+self.xorigin y = int(y*yfactor)+self.yorigin gl.lrectwrite(x, y, x + w - 1, y + h - 1, data) gl.gflush() # Initialize the window: set RGB or colormap mode as required, # fill in the colormap, and clear the window def initcolormap(self): self.colormapinited = 1 self.color0 = None self.fixcolor0 = 0 if self.format in ('rgb', 'jpeg', 'compress'): self.set_rgbmode() gl.RGBcolor(200, 200, 200) # XXX rather light grey gl.clear() return # This only works on an Entry-level Indigo from IRIX 4.0.5 if self.format == 'rgb8' and is_entry_indigo() and \ gl.gversion() == 'GL4DLG-4.0.': # Note trailing '.'! gl.RGBmode() gl.gconfig() gl.RGBcolor(200, 200, 200) # XXX rather light grey gl.clear() gl.pixmode(GL.PM_SIZE, 8) return self.set_cmode() self.skipchrom = 0 if self.offset == 0: self.mask = 0x7ff else: self.mask = 0xfff if not self.quiet: sys.stderr.write('Initializing color map...') self._initcmap() gl.clear() if not self.quiet: sys.stderr.write(' Done.\n') # Set the window in RGB mode (may be overridden for Glx window) def set_rgbmode(self): gl.RGBmode() gl.gconfig() # Set the window in colormap mode (may be overridden for Glx window) def set_cmode(self): gl.cmode() gl.gconfig() # Clear the window to a default color def clear(self): if not self.colormapinited: raise CallError if gl.getdisplaymode() in (GET.DMRGB, GET.DMRGBDOUBLE): gl.RGBcolor(200, 200, 200) # XXX rather light grey gl.clear() return gl.writemask(0xffffffff) gl.clear() # Clear the window to a given RGB color. # This may steal the first color index used; the next call to # showframe() will restore the intended mapping for that index def clearto(self, r, g, b): if not self.colormapinited: raise CallError if gl.getdisplaymode() in (GET.DMRGB, GET.DMRGBDOUBLE): gl.RGBcolor(r, g, b) gl.clear() return index = self.color0[0] self.fixcolor0 = 1 gl.mapcolor(index, r, g, b) gl.writemask(0xffffffff) gl.clear() gl.gflush() # Do the hard work for initializing the colormap (internal). # This also sets the current color to the first color index # used -- the caller should never change this since it is used # by clear() and clearto() def _initcmap(self): if self.format in ('mono', 'grey4') and self.mustunpack: convcolor = conv_grey else: convcolor = choose_conversion(self.format) maxbits = gl.getgdesc(GL.GD_BITS_NORM_SNG_CMODE) if maxbits > 11: maxbits = 11 c0bits = self.c0bits c1bits = self.c1bits c2bits = self.c2bits if c0bits+c1bits+c2bits > maxbits: if self.fallback and c0bits < maxbits: # Cannot display frames in this mode, use grey self.skipchrom = 1 c1bits = c2bits = 0 convcolor = choose_conversion('grey') else: raise Error, 'Sorry, '+`maxbits`+ \ ' bits max on this machine' maxc0 = 1 << c0bits maxc1 = 1 << c1bits maxc2 = 1 << c2bits if self.offset == 0 and maxbits == 11: offset = 2048 else: offset = self.offset if maxbits <> 11: offset = offset & ((1< type(()): raise Error, filename + ': Bad (w,h,pf) info' if len(x) == 3: width, height, packfactor = x if packfactor == 0 and version < 3.0: format = 'rgb' c0bits = 0 elif len(x) == 2 and version <= 1.0: width, height = x packfactor = 2 else: raise Error, filename + ': Bad (w,h,pf) info' if type(packfactor) is type(0): if packfactor == 0: packfactor = 1 xpf = ypf = packfactor else: xpf, ypf = packfactor if upside_down: ypf = -ypf packfactor = (xpf, ypf) xpf = abs(xpf) ypf = abs(ypf) width = (width/xpf) * xpf height = (height/ypf) * ypf # # Return (version, values) # values = (format, width, height, packfactor, \ c0bits, c1bits, c2bits, offset, chrompack, compressheader) return (version, values) # Read a *frame* header -- separate functions per version. # Return (timecode, datasize, chromdatasize). # Raise EOFError if end of data is reached. # Raise Error if data is bad. def readv0frameheader(fp): line = fp.readline() if not line or line == '\n': raise EOFError try: t = eval(line[:-1]) except: raise Error, 'Bad 0.0 frame header' return (t, 0, 0) def readv1frameheader(fp): line = fp.readline() if not line or line == '\n': raise EOFError try: t, datasize = eval(line[:-1]) except: raise Error, 'Bad 1.0 frame header' return (t, datasize, 0) def readv2frameheader(fp): line = fp.readline() if not line or line == '\n': raise EOFError try: t, datasize = eval(line[:-1]) except: raise Error, 'Bad 2.0 frame header' return (t, datasize, 0) def readv3frameheader(fp): line = fp.readline() if not line or line == '\n': raise EOFError try: t, datasize, chromdatasize = x = eval(line[:-1]) except: raise Error, 'Bad 3.[01] frame header' return x # Write a CMIF video file header (always version 3.1) def writefileheader(fp, values): (format, width, height, packfactor, \ c0bits, c1bits, c2bits, offset, chrompack) = values # # Write identifying header # fp.write('CMIF video 3.1\n') # # Write color encoding info # if format in ('rgb', 'jpeg'): data = (format, 0) elif format in ('grey', 'jpeggrey', 'mono', 'grey2', 'grey4'): data = (format, c0bits) else: data = (format, (c0bits, c1bits, c2bits, chrompack, offset)) fp.write(`data`+'\n') # # Write frame geometry info # data = (width, height, packfactor) fp.write(`data`+'\n') # Basic class for reading CMIF video files class BasicVinFile(VideoParams): def init(self, filename): if filename == '-': fp = sys.stdin else: fp = open(filename, 'r') return self.initfp(fp, filename) def initfp(self, fp, filename): self = VideoParams.init(self) self.fp = fp self.filename = filename self.version, values = readfileheader(fp, filename) self.setinfo(values) self.freeze() if self.version == 0.0: w, h, pf = self.width, self.height, self.packfactor if pf == 0: self._datasize = w*h*4 else: self._datasize = (w/pf) * (h/pf) self._readframeheader = self._readv0frameheader elif self.version == 1.0: self._readframeheader = readv1frameheader elif self.version == 2.0: self._readframeheader = readv2frameheader elif self.version in (3.0, 3.1): self._readframeheader = readv3frameheader else: raise Error, \ filename + ': Bad version: ' + `self.version` self.framecount = 0 self.atframeheader = 1 self.eofseen = 0 self.errorseen = 0 try: self.startpos = self.fp.tell() self.canseek = 1 except IOError: self.startpos = -1 self.canseek = 0 return self def _readv0frameheader(self, fp): t, ds, cs = readv0frameheader(fp) ds = self._datasize return (t, ds, cs) def close(self): self.fp.close() del self.fp del self._readframeheader def rewind(self): if not self.canseek: raise Error, self.filename + ': can\'t seek' self.fp.seek(self.startpos) self.framecount = 0 self.atframeheader = 1 self.eofseen = 0 self.errorseen = 0 def warmcache(self): print '[BasicVinFile.warmcache() not implemented]' def printinfo(self): print 'File: ', self.filename print 'Size: ', getfilesize(self.filename) print 'Version: ', self.version VideoParams.printinfo(self) def getnextframe(self): t, ds, cs = self.getnextframeheader() data, cdata = self.getnextframedata(ds, cs) return (t, data, cdata) def skipnextframe(self): t, ds, cs = self.getnextframeheader() self.skipnextframedata(ds, cs) return t def getnextframeheader(self): if self.eofseen: raise EOFError if self.errorseen: raise CallError if not self.atframeheader: raise CallError self.atframeheader = 0 try: return self._readframeheader(self.fp) except Error, msg: self.errorseen = 1 # Patch up the error message raise Error, self.filename + ': ' + msg except EOFError: self.eofseen = 1 raise EOFError def getnextframedata(self, ds, cs): if self.eofseen: raise EOFError if self.errorseen: raise CallError if self.atframeheader: raise CallError if ds: data = self.fp.read(ds) if len(data) < ds: self.eofseen = 1 raise EOFError else: data = '' if cs: cdata = self.fp.read(cs) if len(cdata) < cs: self.eofseen = 1 raise EOFError else: cdata = '' self.atframeheader = 1 self.framecount = self.framecount + 1 return (data, cdata) def skipnextframedata(self, ds, cs): if self.eofseen: raise EOFError if self.errorseen: raise CallError if self.atframeheader: raise CallError # Note that this won't raise EOFError for a partial frame # since there is no easy way to tell whether a seek # ended up beyond the end of the file if self.canseek: self.fp.seek(ds + cs, 1) # Relative seek else: dummy = self.fp.read(ds + cs) del dummy self.atframeheader = 1 self.framecount = self.framecount + 1 # Subroutine to return a file's size in bytes def getfilesize(filename): import os, stat try: st = os.stat(filename) return st[stat.ST_SIZE] except os.error: return 0 # Derived class implementing random access and index cached in the file class RandomVinFile(BasicVinFile): def initfp(self, fp, filename): self = BasicVinFile.initfp(self, fp, filename) self.index = [] return self def warmcache(self): if len(self.index) == 0: try: self.readcache() except Error: self.buildcache() else: print '[RandomVinFile.warmcache(): too late]' self.rewind() def buildcache(self): self.index = [] self.rewind() while 1: try: dummy = self.skipnextframe() except EOFError: break self.rewind() def writecache(self): # Raises IOerror if the file is not seekable & writable! import marshal if len(self.index) == 0: self.buildcache() if len(self.index) == 0: raise Error, self.filename + ': No frames' self.fp.seek(0, 2) self.fp.write('\n/////CMIF/////\n') pos = self.fp.tell() data = `pos` data = '\n-*-*-CMIF-*-*-\n' + data + ' '*(15-len(data)) + '\n' try: marshal.dump(self.index, self.fp) self.fp.write(data) self.fp.flush() finally: self.rewind() def readcache(self): # Raises Error if there is no cache in the file import marshal if len(self.index) <> 0: raise CallError self.fp.seek(-32, 2) data = self.fp.read() if data[:16] <> '\n-*-*-CMIF-*-*-\n' or data[-1:] <> '\n': self.rewind() raise Error, self.filename + ': No cache' pos = eval(data[16:-1]) self.fp.seek(pos) try: self.index = marshal.load(self.fp) except TypeError: self.rewind() raise Error, self.filename + ': Bad cache' self.rewind() def getnextframeheader(self): if self.framecount < len(self.index): return self._getindexframeheader(self.framecount) if self.framecount > len(self.index): raise AssertError, \ 'managed to bypass index?!?' rv = BasicVinFile.getnextframeheader(self) if self.canseek: pos = self.fp.tell() self.index.append(rv, pos) return rv def getrandomframe(self, i): t, ds, cs = self.getrandomframeheader(i) data, cdata = self.getnextframedata(ds, cs) return t, data, cdata def getrandomframeheader(self, i): if i < 0: raise ValueError, 'negative frame index' if not self.canseek: raise Error, self.filename + ': can\'t seek' if i < len(self.index): return self._getindexframeheader(i) if len(self.index) > 0: rv = self.getrandomframeheader(len(self.index)-1) else: self.rewind() rv = self.getnextframeheader() while i > self.framecount: self.skipnextframedata() rv = self.getnextframeheader() return rv def _getindexframeheader(self, i): (rv, pos) = self.index[i] self.fp.seek(pos) self.framecount = i self.atframeheader = 0 self.eofseen = 0 self.errorseen = 0 return rv # Basic class for writing CMIF video files class BasicVoutFile(VideoParams): def init(self, filename): if filename == '-': fp = sys.stdout else: fp = open(filename, 'w') return self.initfp(fp, filename) def initfp(self, fp, filename): self = VideoParams.init(self) self.fp = fp self.filename = filename self.version = 3.1 # In case anyone inquries return self def flush(self): self.fp.flush() def close(self): self.fp.close() del self.fp def prealloc(self, nframes): if not self.frozen: raise CallError data = '\xff' * (self.calcframesize() + 64) pos = self.fp.tell() for i in range(nframes): self.fp.write(data) self.fp.seek(pos) def writeheader(self): if self.frozen: raise CallError writefileheader(self.fp, self.getinfo()) self.freeze() self.atheader = 1 self.framecount = 0 def rewind(self): self.fp.seek(0) self.unfreeze() self.atheader = 1 self.framecount = 0 def printinfo(self): print 'File: ', self.filename VideoParams.printinfo(self) def writeframe(self, t, data, cdata): if data: ds = len(data) else: ds = 0 if cdata: cs = len(cdata) else: cs = 0 self.writeframeheader(t, ds, cs) self.writeframedata(data, cdata) def writeframeheader(self, t, ds, cs): if not self.frozen: self.writeheader() if not self.atheader: raise CallError data = `(t, ds, cs)` n = len(data) if n < 63: data = data + ' '*(63-n) self.fp.write(data + '\n') self.atheader = 0 def writeframedata(self, data, cdata): if not self.frozen or self.atheader: raise CallError if data: self.fp.write(data) if cdata: self.fp.write(cdata) self.atheader = 1 self.framecount = self.framecount + 1 # Classes that combine files with displayers: class VinFile(RandomVinFile, Displayer): def initfp(self, fp, filename): self = Displayer.init(self) return RandomVinFile.initfp(self, fp, filename) def shownextframe(self): t, data, cdata = self.getnextframe() self.showframe(data, cdata) return t class VoutFile(BasicVoutFile, Displayer): def initfp(self, fp, filename): self = Displayer.init(self) ## self = Grabber.init(self) # XXX not needed return BasicVoutFile.initfp(self, fp, filename) # Simple test program (VinFile only) def test(): import time if sys.argv[1:]: filename = sys.argv[1] else: filename = 'film.video' vin = VinFile().init(filename) vin.printinfo() gl.foreground() gl.prefsize(vin.getsize()) wid = gl.winopen(filename) vin.initcolormap() t0 = time.millitimer() while 1: try: t, data, cdata = vin.getnextframe() except EOFError: break dt = t0 + t - time.millitimer() if dt > 0: time.millisleep(dt) vin.showframe(data, cdata) time.sleep(2)