ref: ef6ce918c04fc82bea759fd843cc09e273ec9f6c
dir: /appl/charon/img.b/
implement Img; include "common.m"; # headers for png support include "filter.m"; include "crc.m"; # big tables in separate files include "rgb.inc"; include "ycbcr.inc"; include "xxx.inc"; # local copies from CU sys: Sys; CU: CharonUtils; Header, ByteSource, MaskedImage, ImageCache, ResourceState: import CU; D: Draw; Chans, Point, Rect, Image, Display: import D; E: Events; Event: import E; G: Gui; # channel descriptions CRGB: con 0; # three channels, R, G, B, no map CY: con 1; # one channel, luminance CRGB1: con 2; # one channel, map present CYCbCr: con 3; # three channels, Y, Cb, Cr, no map dbg := 0; dbgev := 0; warn := 0; progressive := 0; display: ref D->Display; inflate: Filter; crc: Crc; CRCstate: import crc; init(cu: CharonUtils) { sys = load Sys Sys->PATH; CU = cu; D = load Draw Draw->PATH; G = cu->G; crc = load Crc Crc->PATH; inflate = load Filter "/dis/lib/inflate.dis"; inflate->init(); init_tabs(); } # Return true if mtype is an image type we can handle supported(mtype: int) : int { case mtype { CU->ImageJpeg or CU->ImageGif or CU->ImageXXBitmap or CU->ImageXInfernoBit or CU->ImagePng => return 1; } return 0; } # w,h passed in are specified width and height. # Result will be resampled if they don't match the dimensions # in the decoded picture (if only one of w,h is specified, the other # dimension is scaled by the same factor). ImageSource.new(bs: ref ByteSource, w, h: int) : ref ImageSource { dbg = int (CU->config).dbg['i']; warn = (int (CU->config).dbg['w']) || dbg; dbgev = int (CU->config).dbg['e']; display = G->display; mtype := CU->UnknownType; if(bs.hdr != nil) mtype = bs.hdr.mtype; is := ref ImageSource( w,h, # width, height 0,0, # origw, origh mtype, # mtype 0, # i 0, # curframe bs, # bs nil, # ghdr nil, # jhdr "" # err ); return is; } ImageSource.free(is: self ref ImageSource) { is.bs = nil; is.gstate = nil; is.jstate = nil; } ImageSource.getmim(is: self ref ImageSource) : (int, ref MaskedImage) { if(dbg) sys->print("img: getmim\n"); if(dbgev) CU->event("IMAGE_GETMIM", is.width*is.height); ans : ref MaskedImage = nil; ret := Mimnone; prtype := 0; { if(is.bs.hdr == nil) return (Mimnone, nil); # temporary hack: wait until whole file is here first if(is.bs.eof) { if(is.mtype == CU->UnknownType) { u := is.bs.req.url; h := is.bs.hdr; h.setmediatype(u.path, is.bs.data); is.mtype = h.mtype; } case is.mtype { CU->ImageJpeg => ans = getjpegmim(is); CU->ImageGif => ans = getgifmim(is); CU->ImageXXBitmap => ans = getxbitmapmim(is); CU->ImageXInfernoBit => ans = getbitmim(is); CU->ImagePng => ans = getpngmim(is); * => is.err = sys->sprint("unsupported image type %s", (CU->mnames)[is.mtype]); ret = Mimerror; ans = nil; } if(ans != nil) ret = Mimdone; } else { # slow down the spin-waiting for this image sys->sleep(100); } }exception ex{ "exImageerror*" => ret = Mimerror; if(dbg) sys->print("getmim got err: %s\n", is.err); } if(dbg) sys->print("img: getmim returns (%d,%x)\n", ret, ans); if(dbgev) CU->event("IMAGE_GETMIM_END", 0); is.bs.lim = is.i; return (ret, ans); } # Raise exImagerror exception imgerror(is: ref ImageSource, msg: string) { is.err = msg; if(dbg) sys->print("Image error: %s\n", msg); raise "exImageerror:"; } # Get next char or raise exception if cannot getc(is: ref ImageSource) : int { if(is.i >= len is.bs.data) { imgerror(is, "premature eof"); } return int is.bs.data[is.i++]; } # Unget the last character. # When called before any other getting routines, we # know the buffer still has that character in it. ungetc(is: ref ImageSource) { if(is.i == 0) raise "EXInternal: ungetc past beginning of buffer"; is.i--; } # Like ungetc, but ungets two bytes (gotten in order b1, another char). # Now the bytes could have spanned a boundary, if we were unlucky, # so we have to be prepared to put b1 in front of current buffer. ungetc2(is: ref ImageSource, nil: byte) { if(is.i < 2) { if(is.i != 1) raise "EXInternal: ungetc2 past beginning of buffer"; is.i = 0; } else is.i -= 2; } # Get 2 bytes and return the 16-bit value, little-endian order. getlew(is: ref ImageSource) : int { c0 := getc(is); c1 := getc(is); return c0 + (c1<<8); } # Get 2 bytes and return the 16-bit value, big-endian order. getbew(is: ref ImageSource) : int { c0 := getc(is); c1 := getc(is); return (c0<<8) + c1; } # Copy next n bytes of input into buf # or raise exception if cannot. read(is: ref ImageSource, buf: array of byte, n: int) { ok := 0; if(is.i +n < len is.bs.data) { buf[0:] = is.bs.data[is.i:is.i+n]; is.i += n; } else imgerror(is, "premature eof"); } # Caller needs n bytes. # Return an (array, index into array) where at least # the next n bytes can be found. # There might be a "premature eof" exception. getn(is: ref ImageSource, n: int) : (array of byte, int) { a := is.bs.data; i := is.i; if(i + n <= len a) is.i += n; else imgerror(is, "premature eof"); return (a, i); } # display.newimage with some defaults; throw exception if fails newimage(is: ref ImageSource, w, h: int) : ref Image { if(!(CU->imcache).need(w*h)) imgerror(is, "out of memory"); im := display.newimage(((0,0),(w,h)), D->CMAP8, 0, D->White); if(im == nil) imgerror(is, "out of memory"); return im; } newimage24(is: ref ImageSource, w, h: int) : ref Image { if(!(CU->imcache).need(w*h*3)) imgerror(is, "out of memory"); im := display.newimage(((0,0),(w,h)), D->RGB24, 0, D->White); if(im == nil) imgerror(is, "out of memory"); return im; } newimagegrey(is: ref ImageSource, w, h: int) : ref Image { if(!(CU->imcache).need(w*h)) imgerror(is, "out of memory"); im := display.newimage(((0,0),(w,h)), D->GREY8, 0, D->White); if(im == nil) imgerror(is, "out of memory"); return im; } newmi(im: ref Image) : ref MaskedImage { return ref MaskedImage(im, nil, 0, 0, -1, Point(0,0)); } # Call this after origw and origh are set to set the width and height # to our desired (rescaled) answer dimensions. # If only one of the dimensions is specified, the other is scaled by # the same factor. setdims(is: ref ImageSource) { sw := is.origw; sh := is.origh; dw := is.width; dh := is.height; if(dw == 0 && dh == 0) { dw = sw; dh = sh; } else if(dw == 0 || dh == 0) { if(dw == 0) { dw = int ((real sw) * (real dh/real sh)); if(dw == 0) dw = 1; } else { dh = int ((real sh) * (real dw/real sw)); if(dh == 0) dh = 1; } } is.width = dw; is.height = dh; } # for debugging printarray(a: array of int, name: string) { sys->print("%s:", name); for(i := 0; i < len a; i++) { if((i%10)==0) sys->print("\n%5d: ", i); sys->print("%6d", a[i]); } sys->print("\n"); } ################# XBitmap ################### getxbitmaphdr(is: ref ImageSource) { fnd: int; (fnd, is.origw) = getxbitmapdefine(is); if(fnd) (fnd, is.origh) = getxbitmapdefine(is); if(!fnd) imgerror(is, "xbitmap starts badly"); # now, optional x_hot, y_hot (fnd, nil) = getxbitmapdefine(is); if(fnd) (fnd, nil) = getxbitmapdefine(is); # now expect 'static char x...x_bits[] = {' get_to_char(is, '{'); } getxbitmapmim(is: ref ImageSource) : ref MaskedImage { getxbitmaphdr(is); setdims(is); bytesperline := (is.origw+7) / 8; pixels := array[is.origw*is.origh] of byte; pixi := 0; for(i := 0; i < is.origh; i++) { for(j := 0; j < bytesperline; j++) { v := get_hexbyte(is); kend := 7; if(j == bytesperline-1) kend = (is.origw-1)%8; for(k := 0; k <= kend; k++) { if(v & (1<<k)) pixels[pixi] = byte D->Black; else pixels[pixi] = byte D->White; pixi++; } } } if(is.width != is.origw || is.height != is.origh) pixels = resample(pixels, is.origw, is.origh, is.width, is.height); im := newimage(is, is.width, is.height); im.writepixels(im.r, pixels); return newmi(im); } # get a line, which should be of form # '#define fieldname val' # and return (found, integer rep of val) getxbitmapdefine(is: ref ImageSource) : (int, int) { fnd := 0; n := 0; c := getc(is); if(c == '#') { get_to_char(is, ' '); get_to_char(is, ' '); c = getc(is); while(c >= '0' && c <= '9') { fnd = 1; n = n*10 + c - '0'; c = getc(is); } } else ungetc(is); get_to_char(is, '\n'); return (fnd, n); } # read fd until get char cterm # (raise exception if eof hit first) get_to_char(is: ref ImageSource, cterm: int) { for(;;) { if(getc(is) == cterm) return; } } # read fd until get xDD, were DD are hex digits. # (raise exception if not hex digits or if eof hit first) get_hexbyte(is: ref ImageSource) : int { get_to_char(is, 'x'); n1 := hexdig(getc(is)); n2 := hexdig(getc(is)); if(n1 < 0 || n2 < 0) imgerror(is, "X Bitmap expected hex digits"); return (n1<<4) + n2; } hexdig(c: int) : int { if('0' <= c && c <= '9') c -= '0'; else if('a' <= c && c <= 'f') c += 10 - 'a'; else if('A' <= c && c <= 'F') c += 10 - 'A'; else c = -1; return c; } ################# GIF ################### # GIF flags TRANSP: con 1; INPUT: con 2; DISPMASK: con 7<<2; HASCMAP: con 16r80; INTERLACED: con 16r40; Entry: adt { prefix: int; exten: int; }; getgifhdr(is: ref ImageSource) { if(dbg) sys->print("img: getgifhdr\n"); h := ref Gifstate; (buf, i) := getn(is, 6); vers := string buf[i:i+6]; if(vers!="GIF87a" && vers!="GIF89a") imgerror(is, "unknown GIF version " + vers); is.origw = getlew(is); is.origh = getlew(is); h.fields = getc(is); h.bgrnd = getc(is); h.aspect = getc(is); setdims(is); if(dbg) sys->print("img: getgifhdr has vers=%s, origw=%d, origh=%d, w=%d, h=%d, fields=16r%x, bgrnd=%d, aspect=%d\n", vers, is.origw, is.origh, is.width, is.height, h.fields, h.bgrnd, h.aspect); h.flags = 0; h.delay = 0; h.trindex = byte 0; h.tbl = array[4096] of GifEntry; for(i = 0; i < 258; i++) { h.tbl[i].prefix = -1; h.tbl[i].exten = i; } h.globalcmap = nil; h.cmap = nil; if(h.fields & HASCMAP) h.globalcmap = gifreadcmap(is, (h.fields&7)+1); is.gstate = h; if(warn && h.aspect != 0) sys->print("warning: non-standard aspect ratio in GIF image ignored\n"); if(!gifgettoimage(is)) imgerror(is, "GIF file has no image"); } gifgettoimage(is: ref ImageSource) : int { if(dbg) sys->print("img: gifgettoimage\n"); h := is.gstate; loop: for(;;) { # some GIFs omit Trailer if(is.i >= len is.bs.data) break; case c := getc(is) { 16r2C => # Image Descriptor return 1; 16r21 => # Extension hsize := 0; hasdata := 0; case getc(is){ 16r01 => # Plain Text Extension hsize = 14; hasdata = 1; if(dbg) sys->print("gifgettoimage: text extension\n"); 16rF9 => # Graphic Control Extension getc(is); # blocksize (should be 4) h.flags = getc(is); h.delay = getlew(is); h.trindex = byte getc(is); getc(is); # block terminator (should be 0) # set minimum delay if (h.delay < 20) h.delay = 20; if(dbg) sys->print("gifgettoimage: graphic control flags=16r%x, delay=%d, trindex=%d\n", h.flags, h.delay, int h.trindex); 16rFE => # Comment Extension if(dbg) sys->print("gifgettoimage: comment extension\n"); hasdata = 1; 16rFF => # Application Extension if(dbg) sys->print("gifgettoimage: application extension\n"); hsize = getc(is); # standard says this must be 11, but Adobe likes to put out 10-byte ones, # so we pay attention to the field. hasdata = 1; * => imgerror(is, "GIF unknown extension"); } if(hsize > 0) getn(is, hsize); if(hasdata) { for(;;) { if((nbytes := getc(is)) == 0) break; (a, i) := getn(is, nbytes); if(dbg) sys->print("extension data: '%s'\n", string a[i:i+nbytes]); } } 16r3B => # Trailer # read to end of data getn(is, len is.bs.data - is.i); break loop; * => if(c == 0) continue; # FIX for some buggy gifs imgerror(is, "GIF unknown block type " + string c); } } return 0; } getgifmim(is: ref ImageSource) : ref MaskedImage { if(is.gstate == nil) getgifhdr(is); # At this point, should just have read Image Descriptor marker byte h := is.gstate; left :=getlew(is); top := getlew(is); width := getlew(is); height := getlew(is); h.fields = getc(is); totpix := width*height; h.cmap = h.globalcmap; if(dbg) sys->print("getgifmim, left=%d, top=%d, width=%d, height=%d, fields=16r%x\n", left, top, width, height, h.fields); if(dbgev) CU->event("IMAGE_GETGIFMIM", 0); if(h.fields & HASCMAP) h.cmap = gifreadcmap(is, (h.fields&7)+1); if(h.cmap == nil) imgerror(is, "GIF needs colormap"); # now decode the image c, incode: int; codesize := getc(is); if(codesize > 8) imgerror(is, "GIF bad codesize"); if(len h.cmap!=3*(1<<codesize) && len h.cmap != 3*(1<<(codesize-1)) # peculiar GIF bitmap files && (codesize!=2 || len h.cmap!=3*2)){ # peculiar GIF bitmap files II if (warn) sys->print("warning: GIF codesize = %d doesn't match cmap len = %d\n", codesize, len h.cmap); #imgerror(is, "GIF codesize doesn't match color map"); } CTM :=1<<codesize; EOD := CTM+1; pic := array[totpix] of byte; pici := 0; data : array of byte = nil; datai := 0; dataend := 0; nbits := 0; sreg := 0; stack := array[4096] of byte; stacki: int; fc := 0; tbl := h.tbl; Decode: for(;;) { csize := codesize+1; csmask := ((1<<csize) - 1); nentry := EOD+1; maxentry := csmask; first := 1; ocode := -1; for(;; ocode = incode) { while(nbits < csize) { if(datai == dataend) { nbytes := getc(is); if (nbytes == 0) # Block Terminator break Decode; (data, datai) = getn(is, nbytes); dataend = datai+nbytes; } c = int data[datai++]; sreg |= c<<nbits; nbits += 8; } code := sreg & csmask; sreg >>= csize; nbits -= csize; if(code == EOD) { nbytes := getc(is); if(nbytes != 0 && warn) sys->print("warning: unexpected data past EOD\n"); break Decode; } if(code == CTM) continue Decode; stacki = len stack-1; incode = code; # special case for KwKwK if(code == nentry) { stack[stacki--] = byte fc; code = ocode; } if(code > nentry) imgerror(is, "GIF bad code"); for(c=code; c>=0; c=tbl[c].prefix) stack[stacki--] = byte tbl[c].exten; nb := len stack-(stacki+1); if(pici+nb > len pic) { # this common error is harmless # we have to keep reading to keep the blocks in sync ; } else { pic[pici:] = stack[stacki+1:]; pici += nb; } fc = int stack[stacki+1]; if(first) { first = 0; continue; } early:=0; # peculiar tiff feature here for reference if(nentry == maxentry-early) { if(csize >= 12) continue; csize++; maxentry = (1<<csize); csmask = maxentry - 1; if(csize < 12) maxentry--; } tbl[nentry].prefix = ocode; tbl[nentry].exten = fc; nentry++; } } while(pici < len pic) { # shouldn't happen, but sometimes get buggy gifs pic[pici++] = byte 0; } if(h.fields & INTERLACED) { if(dbg) sys->print("getgifmim uninterlacing\n"); if(dbgev) CU->event("IMAGE_GETGIFMIM_INTERLACE_START", 0); # (TODO: Could un-interlace in place. # Decompose permutation into cycles, # then need one double-copy of a line # per cycle). ipic := array[totpix] of byte; # Group 1: every 8th row, starting with row 0 pici = 0; ipici := 0; ipiclim := totpix-width; w2 := width+width; w4 := w2+w2; w8 := w4+w4; startandby := array[4] of {(0,w8), (w4,w8), (w2,w4), (width,w2)}; for(k := 0; k < 4; k++) { (start, by) := startandby[k]; for(ipici=start; ipici <= ipiclim; ipici += by) { ipic[ipici:] = pic[pici:pici+width]; pici += width; } } pic = ipic; if(dbgev) CU->event("IMAGE_GETGIFMIM_INTERLACE_END", 0); } if(is.width != is.origw || is.height != is.origh) { if (is.width < 0) is.width = 0; if (is.height < 0) is.height = 0; # need to resample, using same factors as original image wscale := real is.width / real is.origw; hscale := real is.height / real is.origh; owidth := width; oheight := height; width = int (wscale * real width); if(width == 0) width = 1; height = int (hscale * real height); if(height == 0) height = 1; left = int (wscale * real left); top = int (hscale * real top); pic = resample(pic, owidth, oheight, width, height); } mask : ref Image; if(h.flags & TRANSP) { if(dbg) sys->print("getgifmim making mask, trindex=%d\n", int h.trindex); if(dbgev) CU->event("IMAGE_GETGIFMIM_MASK_START", 0); # make a 1-bit deep bitmap for mask # expect most mask bits will be 1 bytesperrow := (width+7)/8; trpix := h.trindex; mpic := array[bytesperrow*height] of byte; mpici := 0; pici = 0; for(y := 0; y < height; y++) { v := byte 16rFF; k := 0; for(x := 0; x < width; x++) { if(pic[pici++] == trpix) v &= ~(byte 16r80>>k); if(++k == 8) { k = 0; mpic[mpici++] = v; v = byte 16rFF; } } if(k != 0) mpic[mpici++] = v; } if(!(CU->imcache).need(bytesperrow*height)) imgerror(is, "out of memory"); mask = display.newimage(((0,0),(width,height)), D->GREY1, 0, D->Opaque); if(mask == nil) imgerror(is, "out of memory"); mask.writepixels(mask.r, mpic); mpic = nil; if(dbgev) CU->event("IMAGE_GETGIFMIM_MASK_END", 0); } if(dbgev) CU->event("IMAGE_GETGIFMIM_REMAP_START", 0); pic24 := remap24(pic, h.cmap); # remap1(pic, width, height, h.cmap); if(dbgev) CU->event("IMAGE_GETGIFMIM_REMAP_END", 0); bgcolor := -1; i := h.bgrnd; if(i >= 0 && 3*i+2 < len h.cmap) { bgcolor = ((int h.cmap[3*i])<<16) | ((int h.cmap[3*i+1])<<8) | (int h.cmap[3*i+2]); } im := newimage24(is, width, height); im.writepixels(im.r, pic24); if(is.curframe == 0) { # make sure first frame fills up whole rectangle if(is.width != width || is.height != height || left != 0 || top != 0) { r := Rect((left,top),(left+width,top+height)); pix := D->White; if(bgcolor != -1) pix = (bgcolor<<8) | 16rFF; newim := display.newimage(((0,0),(is.width,is.height)), D->RGB24, 0, pix); if(newim == nil) imgerror(is, "out of memory"); newim.draw(r, im, mask, (0,0)); im = newim; if(mask != nil) { newmask := display.newimage(((0,0),(is.width,is.height)), D->GREY1, 0, D->Opaque); if(newmask == nil) imgerror(is, "out of memory"); newmask.draw(r, mask, nil, (0,0)); mask = newmask; } left = 0; top = 0; } } pic = nil; mi := newmi(im); mi.mask = mask; mi.delay = h.delay*10; # convert centiseconds to milliseconds mi.origin = Point(left, top); dispmeth := (h.flags>>2)&7; if(dispmeth == 2) { # reset to background color after displaying this frame mi.bgcolor = bgcolor; } else if(dispmeth == 3) { # Supposed to "reset to previous", which appears to # mean the previous frame that didn't have a "reset to previous". # Signal this special case to layout by setting bgcolor to -2. mi.bgcolor = -2; } if(gifgettoimage(is)) { mi.more = 1; is.curframe++; # have to reinitialize table for next time for(i = 0; i < 258; i++) { h.tbl[i].prefix = -1; h.tbl[i].exten = i; } } if(dbgev) CU->event("IMAGE_GETGIFMIM_END", 0); return mi; } # Read a GIF colormap, where bpe is number of bits in an entry. # Raises a 'premature eof' exception if can't get the whole map. gifreadcmap(is: ref ImageSource, bpe: int) : array of byte { size := 3*(1<<bpe); map := array[size] of byte; if(dbg > 1) sys->print("gifreadcmap wants %d bytes\n", size); read(is, map, size); return map; } ################# JPG ################### # Constants, all preceded by byte 16rFF SOF: con 16rC0; # Start of Frame SOF2: con 16rC2; # Start of Frame; progressive Huffman JPG: con 16rC8; # Reserved for JPEG extensions DHT: con 16rC4; # Define Huffman Tables DAC: con 16rCC; # Arithmetic coding conditioning RST: con 16rD0; # Restart interval termination RST7: con 16rD7; # Restart interval termination (highest value) SOI: con 16rD8; # Start of Image EOI: con 16rD9; # End of Image SOS: con 16rDA; # Start of Scan DQT: con 16rDB; # Define quantization tables DNL: con 16rDC; # Define number of lines DRI: con 16rDD; # Define restart interval DHP: con 16rDE; # Define hierarchical progression EXP: con 16rDF; # Expand reference components APPn: con 16rE0; # Reserved for application segments JPGn: con 16rF0; # Reserved for JPEG extensions COM: con 16rFE; # Comment NBUF: con 16*1024; jpegcolorspace: con CYCbCr; zerobytes := array[64] of { * => byte 0 }; zeroints := array[64] of { * => 0 }; getjpeghdr(is: ref ImageSource) { if(dbg) sys->print("getjpeghdr\n"); h := ref Jpegstate( 0, 0, # sr, cnt 0, # Nf nil, # comp byte 0, # mode, 0, 0, # X, Y nil, # qt nil, nil, # dcht, acht 0, # Ns nil, # scomp 0, 0, # Ss, Se 0, 0, # Ah, Al 0, 0, # ri, nseg nil, # nblock nil, nil, # dccoeff, accoeff 0, 0, 0, 0 # nacross, ndown, Hmax, Vmax ); is.jstate = h; if(jpegmarker(is) != SOI) imgerror(is, "Jpeg expected SOI marker"); (m, n) := jpegtabmisc(is); if(!(m == SOF || m == SOF2)) imgerror(is, "Jpeg expected Frame marker"); nil = getc(is); # sample precision h.Y = getbew(is); h.X = getbew(is); h.Nf = getc(is); if(dbg) sys->print("start of frame, Y=%d, X=%d, Nf=%d\n", h.Y, h.X, h.Nf); h.comp = array[h.Nf] of Framecomp; h.nblock = array[h.Nf] of int; for(i:=0; i<h.Nf; i++) { h.comp[i].C = getc(is); (H, V) := nibbles(getc(is)); h.comp[i].H = H; h.comp[i].V = V; h.comp[i].Tq = getc(is); h.nblock[i] =H*V; if(dbg) sys->print("comp[%d]: C=%d, H=%d, V=%d, Tq=%d\n", i, h.comp[i].C, H, V, h.comp[i].Tq); } h.mode = byte m; is.origw = h.X; is.origh = h.Y; setdims(is); if(n != 6+3*h.Nf) imgerror(is, "Jpeg bad SOF length"); } jpegmarker(is: ref ImageSource) : int { if(getc(is) != 16rFF) imgerror(is, "Jpeg expected marker"); return getc(is); } # Consume tables and miscellaneous marker segments, # returning the marker id and length of the first non-such-segment # (after having consumed the marker). # May raise "premature eof" or other exception. jpegtabmisc(is: ref ImageSource) : (int, int) { h := is.jstate; m, n : int; Loop: for(;;) { h.nseg++; m = jpegmarker(is); n = 0; if(m != EOI) n = getbew(is) - 2; if(dbg > 1) sys->print("jpegtabmisc reading segment, got m=%x, n=%d\n", m, n); case m { SOF or SOF2 or SOS or EOI => break Loop; APPn+0 => if(h.nseg==1 && n >= 6) { (buf, i) := getn(is, 6); n -= 6; if(string buf[i:i+4]=="JFIF") { vers0 := int buf[i+5]; vers1 := int buf[i+6]; if(vers0>1 || vers1>2) imgerror(is, "Jpeg unimplemented version"); } } APPn+1 to APPn+15 => ; DQT => jpegquanttables(is, n); n = 0; DHT => jpeghuffmantables(is, n); n = 0; DRI => h.ri =getbew(is); n -= 2; COM => ; * => imgerror(is, "Jpeg unexpected marker"); } if(n > 0) getn(is, n); } return (m, n); } # Consume huffman tables, raising exception on error. jpeghuffmantables(is: ref ImageSource, n: int) { if(dbg) sys->print("jpeghuffmantables\n"); h := is.jstate; if(h.dcht == nil) { h.dcht = array[4] of ref Huffman; h.acht = array[4] of ref Huffman; } for(l:= 0; l < n; ) l += jpeghuffmantable(is); if(l != n) imgerror(is, "Jpeg huffman table bad length"); } jpeghuffmantable(is: ref ImageSource) : int { t := ref Huffman; h := is.jstate; (Tc, th) := nibbles(getc(is)); if(dbg > 1) sys->print("jpeghuffmantable, Tc=%d, th=%d\n", Tc, th); if(Tc > 1) imgerror(is, "Jpeg unknown Huffman table class"); if(th>3 || (h.mode==byte SOF && th>1)) imgerror(is, "Jpeg unknown Huffman table index"); if(Tc == 0) h.dcht[th] = t; else h.acht[th] = t; # flow chart C-2 (b, bi) := getn(is, 16); numcodes := array[16] of int; nsize := 0; for(i:=0; i<16; i++) nsize += (numcodes[i] = int b[bi+i]); t.size = array[nsize+1] of int; k := 0; for(i=1; i<=16; i++) { n :=numcodes[i-1]; for(j:=0; j<n; j++) t.size[k++] = i; } t.size[k] = 0; # initialize HUFFVAL t.val = array[nsize] of int; (b, bi) = getn(is, nsize); for(i=0; i<nsize; i++) t.val[i] = int b[bi++]; # flow chart C-3 t.code = array[nsize+1] of int; k = 0; code := 0; si := t.size[0]; for(;;) { do t.code[k++] = code++; while(t.size[k] == si); if(t.size[k] == 0) break; do { code <<= 1; si++; } while(t.size[k] != si); } # flow chart F-25 t.mincode = array[17] of int; t.maxcode = array[17] of int; t.valptr = array[17] of int; i = 0; j := 0; F25: for(;;) { for(;;) { i++; if(i > 16) break F25; if(numcodes[i-1] != 0) break; t.maxcode[i] = -1; } t.valptr[i] = j; t.mincode[i] = t.code[j]; j += int numcodes[i-1]-1; t.maxcode[i] = t.code[j]; j++; } # create byte-indexed fast path tables t.value = array[256] of int; t.shift = array[256] of int; maxcode := t.maxcode; # stupid startup algorithm: just run machine for each byte value Bytes: for(v:=0; v<256; v++){ cnt := 7; m := 1<<7; code = 0; sr := v; i = 1; for(;;i++){ if(sr & m) code |= 1; if(code <= maxcode[i]) break; code <<= 1; m >>= 1; if(m == 0){ t.shift[v] = 0; t.value[v] = -1; continue Bytes; } cnt--; } t.shift[v] = 8-cnt; t.value[v] = t.val[t.valptr[i]+(code-t.mincode[i])]; } if(dbg > 2) { sys->print("Huffman table %d:\n", th); printarray(t.size, "size"); printarray(t.code, "code"); printarray(t.val, "val"); printarray(t.mincode, "mincode"); printarray(t.maxcode, "maxcode"); printarray(t.value, "value"); printarray(t.shift, "shift"); } return nsize+17; } jpegquanttables(is: ref ImageSource, n: int) { if(dbg) sys->print("jpegquanttables\n"); h := is.jstate; if(h.qt == nil) h.qt = array[4] of array of int; for(l:=0; l<n; ) l += jpegquanttable(is); if(l != n) imgerror(is, "Jpeg quant table bad length"); } jpegquanttable(is: ref ImageSource): int { (pq, tq) := nibbles(getc(is)); if(dbg) sys->print("jpegquanttable pq=%d tq=%d\n", pq, tq); if(pq > 1) imgerror(is, "Jpeg unknown quantization table class"); if(tq > 3) imgerror(is, "Jpeg bad quantization table index"); q := array[64] of int; is.jstate.qt[tq] = q; for(i:=0; i<64; i++) { if(pq == 0) q[i] =getc(is); else q[i] = getbew(is); } if(dbg > 2) printarray(q, "quant table"); return 1+(64*(1+pq));; } # Have just read Frame header. # Now expect: # ((tabl/misc segment(s))* (scan header) (entropy coded segment)+)+ EOI getjpegmim(is: ref ImageSource) : ref MaskedImage { if(dbg) sys->print("getjpegmim\n"); if(dbgev) CU->event("IMAGE_GETJPGMIM", is.width*is.height); getjpeghdr(is); h := is.jstate; chans: array of array of byte = nil; for(;;) { (m, n) := jpegtabmisc(is); if(m == EOI) break; if(m != SOS) imgerror(is, "Jpeg expected start of scan"); h.Ns = getc(is); if(dbg) sys->print("start of scan, Ns=%d\n", h.Ns); scomp := array[h.Ns] of Scancomp; for(i := 0; i < h.Ns; i++) { scomp[i].C = getc(is); (scomp[i].tdc, scomp[i].tac) = nibbles(getc(is)); } h.scomp = scomp; h.Ss = getc(is); h.Se = getc(is); (h.Ah, h.Al) = nibbles(getc(is)); if(n != 4+h.Ns*2) imgerror(is, "Jpeg SOS header wrong length"); if(h.mode == byte SOF) { if(chans != nil) imgerror(is, "Jpeg baseline has > 1 scan"); chans = jpegbaselinescan(is); } else jpegprogressivescan(is); } if(h.mode == byte SOF2) chans = jprogressiveIDCT(is); if(chans == nil) imgerror(is, "jpeg has no image"); width := is.width; height := is.height; if(width != h.X || height != h.Y) { for(k := 0; k < len chans; k++) chans[k] = resample(chans[k], h.X, h.Y, width, height); } if(dbgev) CU->event("IMAGE_JPG_REMAP", 0); if(len chans == 1) { im := newimagegrey(is, width, height); im.writepixels(im.r, chans[0]); return newmi(im); # remapgrey(chans[0], width, height); } else { if (len chans == 3) { r := remapYCbCr(chans); im := newimage24(is, width, height); im.writepixels(im.r, r); return newmi(im); } remaprgb(chans, width, height, jpegcolorspace); } if(dbgev) CU->event("IMAGE_JPG_REMAP_END", 0); im := newimage(is, width, height); im.writepixels(im.r, chans[0]); if(dbgev) CU->event("IMAGE_GETJPGMIM_END", 0); return newmi(im); } remapYCbCr(chans: array of array of byte): array of byte { Y := chans[0]; Cb := chans[1]; Cr := chans[2]; rgb := array [3*len Y] of byte; bix := 0; for (i := 0; i < len Y; i++) { y := int Y[i]; cb := int Cb[i]; cr := int Cr[i]; r := y + Cr2r[cr]; g := y - Cr2g[cr] - Cb2g[cb]; b := y + Cb2b[cb]; rgb[bix++] = clampb[b+CLAMPBOFF]; rgb[bix++] = clampb[g+CLAMPBOFF]; rgb[bix++] = clampb[r+CLAMPBOFF]; } return rgb; } zig := array[64] of { 0, 1, 8, 16, 9, 2, 3, 10, 17, # 0-7 24, 32, 25, 18, 11, 4, 5, # 8-15 12, 19, 26, 33, 40, 48, 41, 34, # 16-23 27, 20, 13, 6, 7, 14, 21, 28, # 24-31 35, 42, 49, 56, 57, 50, 43, 36, # 32-39 29, 22, 15, 23, 30, 37, 44, 51, # 40-47 58, 59, 52, 45, 38, 31, 39, 46, # 48-55 53, 60, 61, 54, 47, 55, 62, 63 # 56-63 }; jpegbaselinescan(is: ref ImageSource) : array of array of byte { if(dbg) sys->print("jpegbaselinescan\n"); if(dbgev) CU->event("IMAGE_JPGBASELINESCAN", 0); h := is.jstate; Ns := h.Ns; if(Ns != h.Nf) imgerror(is, "Jpeg baseline needs Ns==Nf"); if(!(Ns==3 || Ns==1)) imgerror(is, "Jpeg baseline needs Ns==1 or 3"); res := ResourceState.cur(); heapavail := res.heaplim - res.heap; # check heap availability for # chans: (3+Ns)*4 + (Ns*(3*4+h.X*h.Y)) bytes # Td, Ta, data, H, V, DC: 6 arrays of (3+Ns)*4 bytes # heapavail -= (3+Ns)*28 + (Ns*(12 + h.X * h.Y)); if(heapavail <= 0) { if(dbg) sys->print("jpegbaselinescan: no memory for chans et al.\n"); imgerror(is, "not enough memory"); } chans := array[h.Nf] of array of byte; for(k:=0; k<h.Nf; k++) chans[k] = array[h.X*h.Y] of byte; # build per-component arrays Td := array[Ns] of int; Ta := array[Ns] of int; data := array[Ns] of array of array of int; H := array[Ns] of int; V := array[Ns] of int; DC := array[Ns] of int; # compute maximum H and V Hmax := 0; Vmax := 0; for(comp:=0; comp<Ns; comp++) { if(h.comp[comp].H > Hmax) Hmax = h.comp[comp].H; if(h.comp[comp].V > Vmax) Vmax = h.comp[comp].V; } if(dbg > 1) sys->print("Hmax=%d, Vmax=%d\n", Hmax, Vmax); # initialize data structures allHV1 := 1; for(comp=0; comp<Ns; comp++) { # JPEG requires scan components to be in same order as in frame, # so if both have 3 we know scan is Y Cb Cr and there's no need to # reorder Td[comp] = h.scomp[comp].tdc; Ta[comp] = h.scomp[comp].tac; H[comp] = h.comp[comp].H; V[comp] = h.comp[comp].V; nblock := H[comp]*V[comp]; if(nblock != 1) allHV1 = 0; # data[comp]: needs (3+nblock)*4 + nblock*(3+8*8)*4 bytes heapavail -= 272*nblock + 12; if(heapavail <= 0){ if(dbg) sys->print("jpegbaselinescan: no memory for data\n"); imgerror(is, "not enough memory"); } data[comp] = array[nblock] of array of int; DC[comp] = 0; for(m:=0; m<nblock; m++) data[comp][m] = array[8*8] of int; if(dbg > 2) sys->print("scan comp %d: H=%d, V=%d, nblock=%d, Td=%d, Ta=%d\n", comp, H[comp], V[comp], nblock, Td[comp], Ta[comp]); } ri := h.ri; h.cnt = 0; h.sr = 0; nacross := ((h.X+(8*Hmax-1))/(8*Hmax)); nmcu := ((h.Y+(8*Vmax-1))/(8*Vmax))*nacross; if(dbg) sys->print("nacross=%d, nmcu=%d\n", nacross, nmcu); for(mcu:=0; mcu<nmcu; ) { if(dbg > 2) sys->print("mcu %d\n", mcu); for(comp=0; comp<Ns; comp++) { if(dbg > 2) sys->print("comp %d\n", comp); dcht := h.dcht[Td[comp]]; acht := h.acht[Ta[comp]]; qt := h.qt[h.comp[comp].Tq]; for(block:=0; block<H[comp]*V[comp]; block++) { if(dbg > 2) sys->print("block %d\n", block); # F-22 t := jdecode(is, dcht); diff := jreceive(is, t); DC[comp] += diff; if(dbg > 2) sys->print("t=%d, diff=%d, DC=%d\n", t, diff, DC[comp]); # F-23 zz := data[comp][block]; zz[0:] = zeroints; zz[0] = qt[0]*DC[comp]; k = 1; for(;;) { rs := jdecode(is, acht); (rrrr, ssss) := nibbles(rs); if(ssss == 0){ if(rrrr != 15) break; k += 16; }else{ k += rrrr; z := jreceive(is, ssss); zz[zig[k]] = z*qt[k]; if(k == 63) break; k++; } } idct(zz); } } # rotate colors to RGB and assign to bytes if(Ns == 1) # very easy colormap1(h, chans[0], data[0][0], mcu, nacross); else if(allHV1) # fairly easy colormapall1(h, chans, data[0][0], data[1][0], data[2][0], mcu, nacross); else # miserable general case colormap(h, chans, data[0], data[1], data[2], mcu, nacross, Hmax, Vmax, H, V); # process restart marker, if present mcu++; if(ri>0 && mcu<nmcu && mcu%ri==0){ jrestart(is, mcu); for(comp=0; comp<Ns; comp++) DC[comp] = 0; } } if(dbgev) CU->event("IMAGE_JPGBASELINESCAN_END", 0); return chans; } jrestart(is: ref ImageSource, mcu: int) { h := is.jstate; ri := h.ri; restart := mcu/ri-1; rst, nskip: int; nskip = 0; do { do{ rst = jnextborm(is); nskip++; }while(rst>=0 && rst!=16rFF); if(rst == 16rFF){ rst = jnextborm(is); nskip++; } } while(rst>=0 && (rst&~7)!= RST); if(nskip != 2 || rst < 0 || ((rst&7) != (restart&7))) imgerror(is, "Jpeg restart problem"); h.cnt = 0; h.sr = 0; } jpegprogressivescan(is: ref ImageSource) { if(dbgev) CU->event("IMAGE_JPGPROGSCAN", 0); h := is.jstate; if(h.dccoeff == nil) jprogressiveinit(is, h); c := h.scomp[0].C; comp := -1; for(i:=0; i<h.Nf; i++) if(h.comp[i].C == c) comp = i; if(comp == -1) imgerror(is, "Jpeg bad component index in scan header"); if(h.Ss == 0) jprogressivedc(is, comp); else if(h.Ah == 0) jprogressiveac(is, comp); else jprogressiveacinc(is, comp); if(dbgev) CU->event("IMAGE_JPGPROGSCAN_END", 0); } jprogressiveIDCT(is: ref ImageSource): array of array of byte { if(dbgev) CU->event("IMAGE_JPGPROGIDCT", 0); h := is.jstate; Nf := h.Nf; res := ResourceState.cur(); heapavail := res.heaplim - res.heap; # check heap availability for # H, V, data, blockno: 4 arrays of (3+Nf)*4 bytes # chans: (3+Nf)*4 + (Nf*(3*4+h.X*h.Y)) bytes # heapavail -= (3+Nf)*20 + (Nf*(12 + h.X * h.Y)); if(heapavail <= 0) { if(dbg) sys->print("jprogressiveIDCT: no memory for chans et al.\n"); imgerror(is, "not enough memory"); } H := array[Nf] of int; V := array[Nf] of int; allHV1 := 1; data := array[Nf] of array of array of int; for(comp:=0; comp<Nf; comp++){ H[comp] = h.comp[comp].H; V[comp] = h.comp[comp].V; nblock := h.nblock[comp]; if(nblock != 1) allHV1 = 0; # data[comp]: needs (3+nblock)*4 + nblock*(3+8*8)*4 bytes heapavail -= 272*nblock + 12; if(heapavail <= 0){ if(dbg) sys->print("jprogressiveIDCT: no memory for data\n"); imgerror(is, "not enough memory"); } data[comp] = array[nblock] of array of int; for(m:=0; m<nblock; m++) data[comp][m] = array[8*8] of int; } chans := array[h.Nf] of array of byte; for(k:=0; k<h.Nf; k++) chans[k] = array[h.X*h.Y] of byte; blockno := array[Nf] of {* => 0}; nmcu := h.nacross*h.ndown; for(mcu:=0; mcu<nmcu; mcu++){ for(comp=0; comp<Nf; comp++){ dccoeff := h.dccoeff[comp]; accoeff := h.accoeff[comp]; bn := blockno[comp]; for(block:=0; block<h.nblock[comp]; block++){ zz := data[comp][block]; zz[0:] = zeroints; zz[0] = dccoeff[bn]; for(k=1; k<64; k++) zz[zig[k]] = accoeff[bn][k]; idct(zz); bn++; } blockno[comp] = bn; } # rotate colors to RGB and assign to bytes if(Nf == 1) # very easy colormap1(h, chans[0], data[0][0], mcu, h.nacross); else if(allHV1) # fairly easy colormapall1(h, chans, data[0][0], data[1][0], data[2][0], mcu, h.nacross); else # miserable general case colormap(h, chans, data[0], data[1], data[2], mcu, h.nacross, h.Hmax, h.Vmax, H, V); } return chans; } jprogressiveinit(is: ref ImageSource, h: ref Jpegstate) { Ns := h.Ns; Nf := h.Nf; if((Ns!=3 && Ns!=1) || Ns!=Nf) imgerror(is, "Jpeg image must have 1 or 3 components"); # compute maximum H and V h.Hmax = 0; h.Vmax = 0; for(comp:=0; comp<Nf; comp++){ if(h.comp[comp].H > h.Hmax) h.Hmax = h.comp[comp].H; if(h.comp[comp].V > h.Vmax) h.Vmax = h.comp[comp].V; } h.nacross = ((h.X+(8*h.Hmax-1))/(8*h.Hmax)); h.ndown = ((h.Y+(8*h.Vmax-1))/(8*h.Vmax)); nmcu := h.nacross*h.ndown; res := ResourceState.cur(); heapavail := res.heaplim - res.heap; # check heap availability for # h.dccoeff: (3+Nf)*4 bytes # h.accoeff: (3+Nf)*4 bytes heapavail -= (3+Nf)*8; if(heapavail <= 0) { if(dbg) sys->print("jprogressiveinit: no memory for coeffs\n"); imgerror(is, "not enough memory"); } h.dccoeff = array[Nf] of array of int; h.accoeff = array[Nf] of array of array of int; for(k:=0; k<Nf; k++){ n := h.nblock[k]*nmcu; # check heap availability for # h.dccoeff[k]: (3+n)*4 bytes # h.accoeff[k]: (3+n)*4 + n*(3+64)*4 bytes heapavail -= 276*n + 24; if(heapavail <= 0){ if(dbg) sys->print("jprogressiveinit: no memory for coeff arrays\n"); imgerror(is, "not enough memory"); } h.dccoeff[k] = array[n] of {* => 0}; h.accoeff[k] = array[n] of array of int; for(j:=0; j<n; j++) h.accoeff[k][j] = array[64] of {* => 0}; } } jprogressivedc(is: ref ImageSource, comp: int) { h := is.jstate; Ns := h.Ns; Ah := h.Ah; Al := h.Al; if(Ns!=h.Nf) imgerror(is, "Jpeg progressive with Nf!=Ns in DC scan"); # build per-component arrays Td := array[Ns] of int; DC := array[Ns] of int; # initialize data structures h.cnt = 0; h.sr = 0; for(comp=0; comp<Ns; comp++) { # JPEG requires scan components to be in same order as in frame, # so if both have 3 we know scan is Y Cb Cr and there's no need to # reorder Td[comp] = h.scomp[comp].tdc; DC[comp] = 0; } ri := h.ri; nmcu := h.nacross*h.ndown; blockno := array[Ns] of {* => 0}; for(mcu:=0; mcu<nmcu; ){ for(comp=0; comp<Ns; comp++){ dcht := h.dcht[Td[comp]]; qt := h.qt[h.comp[comp].Tq][0]; dc := h.dccoeff[comp]; bn := blockno[comp]; for(block:=0; block<h.nblock[comp]; block++) { if(Ah == 0) { t := jdecode(is, dcht); diff := jreceive(is, t); DC[comp] += diff; dc[bn] = qt*DC[comp]<<Al; } else dc[bn] |= qt*jreceivebit(is)<<Al; bn++; } blockno[comp] = bn; } # process restart marker, if present mcu++; if(ri>0 && mcu<nmcu && mcu%ri==0){ jrestart(is, mcu); for(comp=0; comp<Ns; comp++) DC[comp] = 0; } } } jprogressiveac(is: ref ImageSource, comp: int) { h := is.jstate; Ns := h.Ns; Al := h.Al; if(Ns != 1) imgerror(is, "Jpeg illegal Ns>1 in progressive AC scan"); Ss := h.Ss; Se := h.Se; H := h.comp[comp].H; V := h.comp[comp].V; nacross := h.nacross*H; ndown := h.ndown*V; q := 8*h.Hmax/H; nhor := (h.X+q-1)/q; q = 8*h.Vmax/V; nver := (h.Y+q-1)/q; # initialize data structures h.cnt = 0; h.sr = 0; Ta := h.scomp[0].tac; ri := h.ri; eobrun := 0; acht := h.acht[Ta]; qt := h.qt[h.comp[comp].Tq]; nmcu := nacross*ndown; mcu := 0; for(y:=0; y<nver; y++) { for(x:=0; x<nhor; x++) { # Figure G-3 if(eobrun > 0){ --eobrun; continue; } # arrange blockno to be in same sequence as # original scan calculation. tmcu := x/H + (nacross/H)*(y/V); blockno := tmcu*H*V + H*(y%V) + x%H; acc := h.accoeff[comp][blockno]; k := Ss; for(;;) { rs := jdecode(is, acht); (rrrr, ssss) := nibbles(rs); if(ssss == 0) { if(rrrr < 15) { eobrun = 0; if(rrrr > 0) eobrun = jreceiveEOB(is, rrrr)-1; break; } k += 16; } else { k += rrrr; z := jreceive(is, ssss); acc[k] = z*qt[k]<<Al; if(k == Se) break; k++; } } } # process restart marker, if present mcu++; if(ri>0 && mcu<nmcu && mcu%ri==0) { jrestart(is, mcu); eobrun = 0; } } } jprogressiveacinc(is: ref ImageSource, comp: int) { h := is.jstate; Ns := h.Ns; if(Ns != 1) imgerror(is, "Jpeg illegal Ns>1 in progressive AC scan"); Ss := h.Ss; Se := h.Se; H := h.comp[comp].H; V := h.comp[comp].V; Al := h.Al; nacross := h.nacross*H; ndown := h.ndown*V; q := 8*h.Hmax/H; nhor := (h.X+q-1)/q; q = 8*h.Vmax/V; nver := (h.Y+q-1)/q; # initialize data structures h.cnt = 0; h.sr = 0; Ta := h.scomp[0].tac; ri := h.ri; eobrun := 0; ac := h.accoeff[comp]; acht := h.acht[Ta]; qt := h.qt[h.comp[comp].Tq]; nmcu := nacross*ndown; mcu := 0; pending := 0; nzeros := -1; for(y:=0; y<nver; y++){ for(x:=0; x<nhor; x++){ # Figure G-7 # arrange blockno to be in same sequence as # original scan calculation. tmcu := x/H + (nacross/H)*(y/V); blockno := tmcu*H*V + H*(y%V) + x%H; acc := ac[blockno]; if(eobrun > 0){ if(nzeros > 0) imgerror(is, "Jpeg zeros pending at block start"); for(k:=Ss; k<=Se; k++) jincrement(is, acc, k, qt[k]<<Al); --eobrun; continue; } for(k:=Ss; k<=Se; ){ if(nzeros >= 0){ if(acc[k] != 0) jincrement(is, acc, k, qt[k]<<Al); else if(nzeros-- == 0) acc[k] = pending; k++; continue; } rs := jdecode(is, acht); (rrrr, ssss) := nibbles(rs); if(ssss == 0){ if(rrrr < 15){ eobrun = 0; if(rrrr > 0) eobrun = jreceiveEOB(is, rrrr)-1; while(k <= Se){ jincrement(is, acc, k, qt[k]<<Al); k++; } break; } for(i:=0; i<16; k++){ jincrement(is, acc, k, qt[k]<<Al); if(acc[k] == 0) i++; } continue; }else if(ssss != 1) imgerror(is, "Jpeg ssss!=1 in progressive increment"); nzeros = rrrr; pending = jreceivebit(is); if(pending == 0) pending = -1; pending *= qt[k]<<Al; } } # process restart marker, if present mcu++; if(ri>0 && mcu<nmcu && mcu%ri==0){ jrestart(is, mcu); eobrun = 0; nzeros = -1; } } } jincrement(is: ref ImageSource, acc: array of int, k, Pt: int) { if(acc[k] == 0) return; b := jreceivebit(is); if(b != 0) if(acc[k] < 0) acc[k] -= Pt; else acc[k] += Pt; } jc1: con 2871; # 1.402 * 2048 jc2: con 705; # 0.34414 * 2048 jc3: con 1463; # 0.71414 * 2048 jc4: con 3629; # 1.772 * 2048 # Fills in pixels (x,y) for x = minx=8*(mcu%nacross), minx+1, ..., minx+7 (or h.X-1, if less) # and for y = miny=8*(mcu/nacross), miny+1, ..., miny+7 (or h.Y-1, if less) colormap1(h: ref Jpegstate, pic: array of byte, data: array of int, mcu, nacross: int) { minx := 8*(mcu%nacross); dx := 8; if(minx+dx > h.X) dx = h.X-minx; miny := 8*(mcu/nacross); dy := 8; if(miny+dy > h.Y) dy = h.Y-miny; pici := miny*h.X+minx; k := 0; for(y:=0; y<dy; y++) { for(x:=0; x<dx; x++) pic[pici+x] = clampb[(data[k+x]+128)+CLAMPBOFF]; pici += h.X; k += 8; } } # Fills in same pixels as colormap1 colormapall1(h: ref Jpegstate, chans: array of array of byte, data0, data1, data2: array of int, mcu, nacross: int) { rpic := chans[0]; gpic := chans[1]; bpic := chans[2]; minx := 8*(mcu%nacross); dx := 8; if(minx+dx > h.X) dx = h.X-minx; miny := 8*(mcu/nacross); dy := 8; if(miny+dy > h.Y) dy = h.Y-miny; pici := miny*h.X+minx; k := 0; for(y:=0; y<dy; y++) { for(x:=0; x<dx; x++){ if(jpegcolorspace == CYCbCr) { rpic[pici+x] = clampb[data0[k+x]+128+CLAMPBOFF]; gpic[pici+x] = clampb[data1[k+x]+128+CLAMPBOFF]; bpic[pici+x] = clampb[data2[k+x]+128+CLAMPBOFF]; } else { # RGB Y := (data0[k+x]+128) << 11; Cb := data1[k+x]; Cr := data2[k+x]; r := Y+jc1*Cr; g := Y-jc2*Cb-jc3*Cr; b := Y+jc4*Cb; rpic[pici+x] = clampb[(r>>11)+CLAMPBOFF]; gpic[pici+x] = clampb[(g>>11)+CLAMPBOFF]; bpic[pici+x] = clampb[(b>>11)+CLAMPBOFF]; } } pici += h.X; k += 8; } } # Fills in pixels (x,y) for x = minx=8*Hmax*(mcu%nacross), minx+1, ..., minx+8*Hmax-1 (or h.X-1, if less) # and for y = miny=8*Vmax*(mcu/nacross), miny+1, ..., miny+8*Vmax-1 (or h.Y-1, if less) colormap(h: ref Jpegstate, chans: array of array of byte, data0, data1, data2: array of array of int, mcu, nacross, Hmax, Vmax: int, H, V: array of int) { rpic := chans[0]; gpic := chans[1]; bpic := chans[2]; minx := 8*Hmax*(mcu%nacross); dx := 8*Hmax; if(minx+dx > h.X) dx = h.X-minx; miny := 8*Vmax*(mcu/nacross); dy := 8*Vmax; if(miny+dy > h.Y) dy = h.Y-miny; pici := miny*h.X+minx; H0 := H[0]; H1 := H[1]; H2 := H[2]; if(dbg > 2) sys->print("colormap, minx=%d, miny=%d, dx=%d, dy=%d, pici=%d, H0=%d, H1=%d, H2=%d\n", minx, miny, dx, dy, pici, H0, H1, H2); for(y:=0; y<dy; y++) { t := y*V[0]; b0 := H0*(t/(8*Vmax)); y0 := 8*((t/Vmax)&7); t = y*V[1]; b1 := H1*(t/(8*Vmax)); y1 := 8*((t/Vmax)&7); t = y*V[2]; b2 := H2*(t/(8*Vmax)); y2 := 8*((t/Vmax)&7); x0 := 0; x1 := 0; x2 := 0; for(x:=0; x<dx; x++) { if(jpegcolorspace == CYCbCr) { rpic[pici+x] = clampb[data0[b0][y0+x0++*H0/Hmax] + 128 + CLAMPBOFF]; gpic[pici+x] = clampb[data1[b1][y1+x1++*H1/Hmax] + 128 + CLAMPBOFF]; bpic[pici+x] = clampb[data2[b2][y2+x2++*H2/Hmax] + 128 + CLAMPBOFF]; } else { # RGB Y := (data0[b0][y0+x0++*H0/Hmax]+128) << 11; Cb := data1[b1][y1+x1++*H1/Hmax]; Cr := data2[b2][y2+x2++*H2/Hmax]; r := Y+jc1*Cr; g := Y-jc2*Cb-jc3*Cr; b := Y+jc4*Cb; rpic[pici+x] = clampb[(r>>11)+CLAMPBOFF]; gpic[pici+x] = clampb[(g>>11)+CLAMPBOFF]; bpic[pici+x] = clampb[(b>>11)+CLAMPBOFF]; } if(x0*H0/Hmax >= 8){ x0 = 0; b0++; } if(x1*H1/Hmax >= 8){ x1 = 0; b1++; } if(x2*H2/Hmax >= 8){ x2 = 0; b2++; } } pici += h.X; } } # decode next 8-bit value from entropy-coded input. chart F-26 jdecode(is: ref ImageSource, t: ref Huffman): int { h := is.jstate; maxcode := t.maxcode; if(h.cnt < 8) jnextbyte(is); # fast lookup code := (h.sr>>(h.cnt-8))&16rFF; v := t.value[code]; if(v >= 0){ h.cnt -= t.shift[code]; return v; } h.cnt -= 8; if(h.cnt == 0) jnextbyte(is); h.cnt--; cnt := h.cnt; m := 1<<cnt; sr := h.sr; code <<= 1; i := 9; for(;;i++){ if(sr & m) code |= 1; if(code <= maxcode[i]) break; code <<= 1; m >>= 1; if(m == 0){ sr = jnextbyte(is); m = 16r80; cnt = 8; } cnt--; } h.cnt = cnt; return t.val[t.valptr[i]+(code-t.mincode[i])]; } # load next byte of input jnextbyte(is: ref ImageSource): int { b :=getc(is); if(b == 16rFF) { b2 :=getc(is); if(b2 != 0) { if(b2 == int DNL) imgerror(is, "Jpeg DNL marker unimplemented"); # decoder is reading into marker; satisfy it and restore state ungetc2(is, byte b); } } h := is.jstate; h.cnt += 8; h.sr = (h.sr<<8)| b; return b; } # like jnextbyte, but look for marker too jnextborm(is: ref ImageSource): int { b :=getc(is); if(b == 16rFF) return b; h := is.jstate; h.cnt += 8; h.sr = (h.sr<<8)| b; return b; } # return next s bits of input, MSB first, and level shift it jreceive(is: ref ImageSource, s: int): int { h := is.jstate; while(h.cnt < s) jnextbyte(is); h.cnt -= s; v := h.sr >> h.cnt; m := (1<<s); v &= m-1; # level shift if(v < (m>>1)) v += ~(m-1)+1; return v; } # return next s bits of input, decode as EOB jreceiveEOB(is: ref ImageSource, s: int): int { h := is.jstate; while(h.cnt < s) jnextbyte(is); h.cnt -= s; v := h.sr >> h.cnt; m := (1<<s); v &= m-1; # level shift v += m; return v; } # return next bit of input jreceivebit(is: ref ImageSource): int { h := is.jstate; if(h.cnt < 1) jnextbyte(is); h.cnt--; return (h.sr >> h.cnt) & 1; } nibbles(c: int) : (int, int) { return (c>>4, c&15); } # Scaled integer implementation. # inverse two dimensional DCT, Chen-Wang algorithm # (IEEE ASSP-32, pp. 803-816, Aug. 1984) # 32-bit integer arithmetic (8 bit coefficients) # 11 mults, 29 adds per DCT # # coefficients extended to 12 bit for IEEE1180-1990 # compliance W1: con 2841; # 2048*sqrt(2)*cos(1*pi/16) W2: con 2676; # 2048*sqrt(2)*cos(2*pi/16) W3: con 2408; # 2048*sqrt(2)*cos(3*pi/16) W5: con 1609; # 2048*sqrt(2)*cos(5*pi/16) W6: con 1108; # 2048*sqrt(2)*cos(6*pi/16) W7: con 565; # 2048*sqrt(2)*cos(7*pi/16) W1pW7: con 3406; # W1+W7 W1mW7: con 2276; # W1-W7 W3pW5: con 4017; # W3+W5 W3mW5: con 799; # W3-W5 W2pW6: con 3784; # W2+W6 W2mW6: con 1567; # W2-W6 R2: con 181; # 256/sqrt(2) idct(b: array of int) { # transform horizontally for(y:=0; y<8; y++){ eighty := y<<3; # if all non-DC components are zero, just propagate the DC term if(b[eighty+1]==0) if(b[eighty+2]==0 && b[eighty+3]==0) if(b[eighty+4]==0 && b[eighty+5]==0) if(b[eighty+6]==0 && b[eighty+7]==0){ v := b[eighty]<<3; b[eighty+0] = v; b[eighty+1] = v; b[eighty+2] = v; b[eighty+3] = v; b[eighty+4] = v; b[eighty+5] = v; b[eighty+6] = v; b[eighty+7] = v; continue; } # prescale x0 := (b[eighty+0]<<11)+128; x1 := b[eighty+4]<<11; x2 := b[eighty+6]; x3 := b[eighty+2]; x4 := b[eighty+1]; x5 := b[eighty+7]; x6 := b[eighty+5]; x7 := b[eighty+3]; # first stage x8 := W7*(x4+x5); x4 = x8 + W1mW7*x4; x5 = x8 - W1pW7*x5; x8 = W3*(x6+x7); x6 = x8 - W3mW5*x6; x7 = x8 - W3pW5*x7; # second stage x8 = x0 + x1; x0 -= x1; x1 = W6*(x3+x2); x2 = x1 - W2pW6*x2; x3 = x1 + W2mW6*x3; x1 = x4 + x6; x4 -= x6; x6 = x5 + x7; x5 -= x7; # third stage x7 = x8 + x3; x8 -= x3; x3 = x0 + x2; x0 -= x2; x2 = (R2*(x4+x5)+128)>>8; x4 = (R2*(x4-x5)+128)>>8; # fourth stage b[eighty+0] = (x7+x1)>>8; b[eighty+1] = (x3+x2)>>8; b[eighty+2] = (x0+x4)>>8; b[eighty+3] = (x8+x6)>>8; b[eighty+4] = (x8-x6)>>8; b[eighty+5] = (x0-x4)>>8; b[eighty+6] = (x3-x2)>>8; b[eighty+7] = (x7-x1)>>8; } # transform vertically for(x:=0; x<8; x++){ # if all non-DC components are zero, just propagate the DC term if(b[x+8*1]==0) if(b[x+8*2]==0 && b[x+8*3]==0) if(b[x+8*4]==0 && b[x+8*5]==0) if(b[x+8*6]==0 && b[x+8*7]==0){ v := (b[x+8*0]+32)>>6; b[x+8*0] = v; b[x+8*1] = v; b[x+8*2] = v; b[x+8*3] = v; b[x+8*4] = v; b[x+8*5] = v; b[x+8*6] = v; b[x+8*7] = v; continue; } # prescale x0 := (b[x+8*0]<<8)+8192; x1 := b[x+8*4]<<8; x2 := b[x+8*6]; x3 := b[x+8*2]; x4 := b[x+8*1]; x5 := b[x+8*7]; x6 := b[x+8*5]; x7 := b[x+8*3]; # first stage x8 := W7*(x4+x5) + 4; x4 = (x8+W1mW7*x4)>>3; x5 = (x8-W1pW7*x5)>>3; x8 = W3*(x6+x7) + 4; x6 = (x8-W3mW5*x6)>>3; x7 = (x8-W3pW5*x7)>>3; # second stage x8 = x0 + x1; x0 -= x1; x1 = W6*(x3+x2) + 4; x2 = (x1-W2pW6*x2)>>3; x3 = (x1+W2mW6*x3)>>3; x1 = x4 + x6; x4 -= x6; x6 = x5 + x7; x5 -= x7; # third stage x7 = x8 + x3; x8 -= x3; x3 = x0 + x2; x0 -= x2; x2 = (R2*(x4+x5)+128)>>8; x4 = (R2*(x4-x5)+128)>>8; # fourth stage b[x+8*0] = (x7+x1)>>14; b[x+8*1] = (x3+x2)>>14; b[x+8*2] = (x0+x4)>>14; b[x+8*3] = (x8+x6)>>14; b[x+8*4] = (x8-x6)>>14; b[x+8*5] = (x0-x4)>>14; b[x+8*6] = (x3-x2)>>14; b[x+8*7] = (x7-x1)>>14; } } ################# Remap colors and Dither ############## closest_rgbpix(r, g, b: int) : int { pix := int closestrgb[((r>>4)<<8)+((g>>4)<<4)+(b>>4)]; # If white is the closest but original r,g,b wasn't white, # look for another color, because web page designer probably # cares more about contrast than actual color if(pix == 0 && !(r == 255 && g ==255 && b == 255)) { bestdist := 1000000; for(i := 1; i < 256; i++) { dr := r-rgbvmap_r[i]; dg := g-rgbvmap_g[i]; db := b-rgbvmap_b[i]; d := dr*dr + dg*dg + db*db; if(d < bestdist) { bestdist = d; pix = i; } } } return pix; } CLAMPBOFF: con 300; NCLAMPB: con CLAMPBOFF+256+CLAMPBOFF; CLAMPNOFF: con 64; NCLAMPN: con CLAMPNOFF+256+CLAMPNOFF; clampb: array of byte; # clamps byte values clampn_b: array of int; # clamps byte values, then shifts >> 4 clampn_g: array of int; # clamps byte values, then masks off lower 4 bits clampn_r: array of int; # clamps byte values, masks off lower 4 bits, then shifts <<4 init_tabs() { clampn_b = array[NCLAMPN] of int; clampn_g = array[NCLAMPN] of int; clampn_r = array[NCLAMPN] of int; for(j:=0; j<CLAMPNOFF; j++) { clampn_b[j] = 0; clampn_g[j] = 0; clampn_r[j] = 0; } for(j=0; j<256; j++) { t := j>>4; clampn_b[CLAMPNOFF+j] = t; clampn_g[CLAMPNOFF+j] = t<<4; clampn_r[CLAMPNOFF+j] = t<<8; } for(j=0; j<CLAMPNOFF; j++) { clampn_b[CLAMPNOFF+256+j] = 16r0F; clampn_g[CLAMPNOFF+256+j] = 16rF0; clampn_r[CLAMPNOFF+256+j] = 16rF00; } clampb = array[NCLAMPB] of byte; for(j=0; j<CLAMPBOFF; j++) clampb[j] = byte 0; for(j=0; j<256; j++) clampb[CLAMPBOFF+j] = byte j; for(j=0; j<CLAMPBOFF; j++) clampb[CLAMPBOFF+256+j] = byte 16rFF; } # could account for mask in alpha rather than having separate mask remap24(pic: array of byte, cmap: array of byte): array of byte { cmap_r := array[256] of byte; cmap_g := array[256] of byte; cmap_b := array[256] of byte; i := 0; for(j := 0; j < 256 && i < len cmap; j++) { cmap_r[j] = cmap[i++]; cmap_g[j] = cmap[i++]; cmap_b[j] = cmap[i++]; } # in case input has bad indices for( ; j < 256; j++) { cmap_r[j] = byte 0; cmap_g[j] = byte 0; cmap_b[j] = byte 0; } pic24 := array [3 * len pic] of byte; ix24 := 0; for (i = 0; i < len pic; i++) { c := int pic[i]; pic24[ix24++] = cmap_b[c]; pic24[ix24++] = cmap_g[c]; pic24[ix24++] = cmap_r[c]; } return pic24; } # Remap pixels of pic[] into the closest colors in the rgbv map, # and do error diffusion of the result. # pic is a one-channel image whose rgb values are given by looking # up values in cmap. remap1(pic: array of byte, dx, dy: int, cmap: array of byte) { if(dbg) sys->print("remap1, pic len %d, dx=%d, dy=%d\n", len pic, dx, dy); cmap_r := array[256] of int; cmap_g := array[256] of int; cmap_b := array[256] of int; i := 0; for(j := 0; j < 256 && i < len cmap; j++) { cmap_r[j] = int cmap[i++]; cmap_g[j] = int cmap[i++]; cmap_b[j] = int cmap[i++]; } # in case input has bad indices for( ; j < 256; j++) { cmap_r[j] = 0; cmap_g[j] = 0; cmap_b[j] = 0; } # modified floyd steinberg, coefficients (1 0) 3/16, (0, 1) 3/16, (1, 1) 7/16 ered := array[dx+1] of { * => 0 }; egrn := array[dx+1] of int; eblu := array[dx+1] of int; egrn[0:] = ered; eblu[0:] = ered; p := 0; for(y:=0; y<dy; y++) { er := 0; eg := 0; eb := 0; for(x:=0; x<dx; ) { x1 := x+1; in := int pic[p]; r := cmap_r[in]+ered[x]; g := cmap_g[in]+egrn[x]; b := cmap_b[in]+eblu[x]; col := int (closestrgb[clampn_r[r+CLAMPNOFF] +clampn_g[g+CLAMPNOFF] +clampn_b[b+CLAMPNOFF]]); pic[p++] = byte 255 - byte col; r -= rgbvmap_r[col]; t := (3*r)>>4; ered[x] = t+er; ered[x1] += t; er = r-3*t; g -= rgbvmap_g[col]; t = (3*g)>>4; egrn[x] = t+eg; egrn[x1] += t; eg = g-3*t; b -= rgbvmap_b[col]; t = (3*b)>>4; eblu[x] = t+eb; eblu[x1] += t; eb = b-3*t; x = x1; } } } # Remap pixels of pic[] into the closest greyscale colors in the rgbv map, # and do error diffusion of the result. # pic is a one-channel greyscale image. remapgrey(pic: array of byte, dx, dy: int) { if(dbg) sys->print("remapgrey, pic len %d, dx=%d, dy=%d\n", len pic, dx, dy); # modified floyd steinberg, coefficients (1 0) 3/16, (0, 1) 3/16, (1, 1) 7/16 e := array[dx+1] of {* => 0 }; p := 0; for(y:=0; y<dy; y++){ eb := 0; for(x:=0; x<dx; ) { x1 := x+1; b := int pic[p]+e[x]; b1 := clampn_b[b+CLAMPNOFF]; col := 255-17*b1; pic[p++] = byte col; b -= rgbvmap_b[col]; t := (3*b)>>4; e[x] = t+eb; e[x1] += t; eb = b-3*t; x = x1; } } } # Remap pixels of chans into the closest colors in the rgbv map, # and do error diffusion of the result. # chans is a 3-channel image whose channels are either (y,cb,cr) or # (r,g,b), depending on whether colorspace is CYCbCr or CRGB. # Variable names use r,g,b (historical). remaprgb(chans: array of array of byte, dx, dy, colorspace: int) { if(dbg) sys->print("remaprgb, pic len %d, dx=%d, dy=%d\n", len chans[0], dx, dy); rpic := chans[0]; gpic := chans[1]; bpic := chans[2]; pic := chans[0]; # modified floyd steinberg, coefficients (1 0) 3/16, (0, 1) 3/16, (1, 1) 7/16 ered := array[dx+1] of { * => 0 }; egrn := array[dx+1] of int; eblu := array[dx+1] of int; egrn[0:] = ered; eblu[0:] = ered; closest: array of byte; map0, map1, map2: array of int; if(colorspace == CRGB) { closest = closestrgb; map0 = rgbvmap_r; map1 = rgbvmap_g; map2 = rgbvmap_b; } else { closest = closestycbcr; map0 = rgbvmap_y; map1 = rgbvmap_cb; map2 = rgbvmap_cr; } p := 0; for(y:=0; y<dy; y++ ) { er := 0; eg := 0; eb := 0; for(x:=0; x<dx; ) { x1 := x + 1; r := int rpic[p]+ered[x]; g := int gpic[p]+egrn[x]; b := int bpic[p]+eblu[x]; # Errors can be uncorrectable if converting from YCbCr, # since we can't guarantee that an extremal value of one of # the components selects a color with an extremal value. # If we don't, the errors accumulate without bound. This # doesn't happen in RGB because the closest table can guarantee # a color on the edge of the gamut, producing a zero error in # that component. For the rotation YCbCr space, there may be # no color that can guarantee zero error at the edge. # Therefore we must clamp explicitly rather than by assuming # an upper error bound of CLAMPOFF. The performance difference # is miniscule anyway. if(r < 0) r = 0; else if(r > 255) r = 255; if(g < 0) g = 0; else if(g > 255) g = 255; if(b < 0) b = 0; else if(b > 255) b = 255; col := int (closest[(b>>4)+16*((g>>4)+(r&16rF0))]); pic[p++] = byte (255-col); # col := int (pic[p++] = closest[(b>>4)+16*((g>>4)+16*(r>>4))]); r -= map0[col]; t := (3*r)>>4; ered[x] = t+er; ered[x1] += t; er = r-3*t; g -= map1[col]; t = (3*g)>>4; egrn[x] = t+eg; egrn[x1] += t; eg = g-3*t; b -= map2[col]; t = (3*b)>>4; eblu[x] = t+eb; eblu[x1] += t; eb = b-3*t; x = x1; } } } # Given src array, representing sw*sh pixel values, resample them into # the returned array, with dimensions dw*dh. # # Quick and dirty resampling: just interpolate. # This lets us resample arrays of pixels indices (e.g., result of gif decoding). # The filter-based resampling methods need conversion to rgb or grayscale. # Also, although the results won't look good, people really shouldn't be # asking the browser to resample except for special purposes (like the common # case of resizing a 1x1 image to make a spacer). resample(src: array of byte, sw, sh: int, dw, dh: int) : array of byte { if(dbgev) CU->event("IMAGE_RESAMPLE_START", 0); if(src == nil || sw == 0 || sh == 0 || dw == 0 || dh == 0) return src; xfac := real sw / real dw; yfac := real sh / real dh; totpix := dw*dh; dst := array[totpix] of byte; dindex := 0; # precompute index in src row corresponding to each index in dst row sindices := array[dw] of int; dx := 0.0; for(x := 0; x < dw; x++) { sx := int dx; dx += xfac; if(sx >= sw) sx = sw-1; sindices[x] = sx; } dy := 0.0; for(y := 0; y < dh; y++) { sy := int dy; dy += yfac; if(sy >= sh) sy = sh-1; soffset := sy * sw; for(x = 0; x < dw; x++) dst[dindex++] = src[soffset + sindices[x]]; } if(dbgev) CU->event("IMAGE_RESAMPLE_END", 0); return dst; } ################# BIT ################### getbitmim(is: ref ImageSource) : ref MaskedImage { if(dbg) sys->print("img getbitmim: w=%d h=%d len=%d\n", is.width, is.height, len is.bs.data); im := getbitimage(is, display, is.bs.data); if(im == nil) imgerror(is, "out of memory"); is.i = is.bs.edata; # getbitimage should do this too! is.width = im.r.max.x; is.height = im.r.max.y; return newmi(im); } NMATCH: con 3; # shortest match possible NCBLOCK: con 6000; # size of compressed blocks drawld2chan := array[] of { 0 => Draw->GREY1, 1 => Draw->GREY2, 2 => Draw->GREY4, 3 => Draw->CMAP8 }; getbitimage(is: ref ImageSource, disp: ref Display, d: array of byte): ref Image { compressed := 0; if(len d < 5*12) imgerror(is, "bad bit format"); if(string d[:11] == "compressed\n"){ if(dbg) sys->print("img: bit compressed\n"); compressed = 1; d = d[11:]; } # # distinguish new channel descriptor from old ldepth. # channel descriptors have letters as well as numbers, # while ldepths are a single digit formatted as %-11d # new := 0; for(m := 0; m < 10; m++){ if(d[m] != byte ' '){ new = 1; break; } } if(d[11] != byte ' ') imgerror(is, "bad bit format"); chans: Chans; if(new){ s := string d[0:11]; chans = Chans.mk(s); if(chans.desc == 0) imgerror(is, sys->sprint("bad channel string %s", s)); }else{ ld := int( d[10] - byte '0' ); if(ld < 0 || ld > 3) imgerror(is, "bad bit ldepth"); chans = drawld2chan[ld]; } xmin := int string d[ 1*12 : 2*12 ]; ymin := int string d[ 2*12 : 3*12 ]; xmax := int string d[ 3*12 : 4*12 ]; ymax := int string d[ 4*12 : 5*12 ]; if( (xmin > xmax) || (ymin > ymax) ) imgerror(is, "bad bit rectangle"); if(dbg) sys->print("img: bit: chans=%s, xmin=%d, ymin=%d, xmax=%d, ymax=%d\n", chans.text(), xmin, ymin, xmax, ymax); r := Rect( (xmin, ymin), (xmax, ymax) ); im := disp.newimage(r, chans, 0, D->Black); if(im == nil) return nil; if (!compressed){ if(!new) for(j:=5*12; j<len d; j++) d[j] ^= byte 16rFF; im.writepixels(im.r, d[5*12:]); return im; } # see /libdraw/readimage.c, /libdraw/creadimage.c, and # /libmemdraw/cload.c for reference implementation # of bit compression bpl := D->bytesperline(r, im.depth); a := array[(ymax-ymin)*bpl] of byte; ai := 0; #index into uncompressed data array a di := 5*12; #index into compressed data while(ymin < ymax){ y := int string d[ di : di + 1*12 ]; n := int string d[ di + 1*12 : di + 2*12 ]; di += 2*12; if (y <= ymin || ymax < y) imgerror(is, "bad compressed bit y-max"); if (n <= 0 || NCBLOCK < n) imgerror(is, "bad compressed bit count"); # no input-stream error checking :-( u := di; while(di < u+n){ c := int d[di++]; if (c >= 128){ # copy as is cnt := c-128 + 1; # check for overrun of index di within d? a[ai:] = d[di:di+cnt]; if(!new) for(j:=0; j<cnt; j++) a[ai+j] ^= byte 16rFF; di += cnt; ai += cnt; } else { # copy a run/match offs := int(d[di++]) + ((c&3)<<8) + 1; cnt := (c>>2) + NMATCH; # simply: a[ai:ai+cnt] = a[ai-offs:ai-offs+cnt]; for(i:=0; i<cnt; i++) a[ai+i] = a[ai-offs+i]; ai += cnt; } } ymin = y; } im.writepixels(im.r, a); return im; } ################# PNG ################### Rawimage: adt { r: Draw->Rect; cmap: array of byte; transp: int; # transparency flag (only for nchans=1) trindex: byte; # transparency index nchans: int; chans: array of array of byte; chandesc:int; fields: int; # defined by format }; Chunk: adt { size : int; typ: string; crc_state: ref CRCstate; }; Png: adt { depth: int; filterbpp: int; colortype: int; compressionmethod: int; filtermethod: int; interlacemethod: int; # tRNS PLTEsize: int; tRNS: array of byte; # state for managing unpacking alpha: int; done: int; error: string; row, rowstep, colstart, colstep: int; phase: int; phasecols: int; phaserows: int; rowsize: int; rowbytessofar: int; thisrow: array of byte; lastrow: array of byte; }; # currently do not support transparency # hence no mask is set # # need to re-jig this code # for example there is no point in mapping up a 2 or 4 bit greyscale image # to 8 bit luminance to then remap it to the inferno palette when # the draw device will do that for us anyway! getpngmim(is: ref ImageSource) : ref MaskedImage { chunk := ref Chunk; png := ref Png; raw := ref Rawimage; chunk.crc_state = crc->init(0, int 16rffffffff); # Check it's a PNG if (!png_signature(is)) imgerror(is, "PNG not a PNG"); # Get the IHDR if (!png_chunk_header(is, chunk)) imgerror(is, "PNG duff header"); if (chunk.typ != "IHDR") imgerror(is, "PNG IHDR must come first"); if (chunk.size != 13) imgerror(is, "PNG IHDR wrong size"); raw.r.max.x = png_int(is, chunk.crc_state); if (raw.r.max.x <= 0) imgerror(is, "PNG invalid width"); raw.r.max.y = png_int(is, chunk.crc_state); if (raw.r.max.y <= 0) imgerror(is, "PNG invalid height"); png.depth = png_byte(is, chunk.crc_state); case png.depth { 1 or 2 or 4 or 8 or 16 => ; * => imgerror(is, "PNG invalid depth"); } png.colortype = png_byte(is, chunk.crc_state); okcombo : int; case png.colortype { 0 => okcombo = 1; raw.nchans = 1; raw.chandesc = CY; png.alpha = 0; 2 => okcombo = (png.depth == 8 || png.depth == 16); raw.nchans = 3; raw.chandesc = CRGB; png.alpha = 0; 3 => okcombo = (png.depth != 16); raw.nchans = 1; raw.chandesc = CRGB1; png.alpha = 0; 4 => okcombo = (png.depth == 8 || png.depth == 16); raw.nchans = 1; raw.chandesc = CY; png.alpha = 1; 6 => okcombo = (png.depth == 8 || png.depth == 16); raw.nchans = 3; raw.chandesc = CRGB; png.alpha = 1; * => imgerror(is, "PNG invalid colortype"); } if (!okcombo) imgerror(is, "PNG invalid depth/colortype combination"); png.compressionmethod = png_byte(is, chunk.crc_state); if (png.compressionmethod != 0) imgerror(is, "PNG invalid compression method " + string png.compressionmethod); png.filtermethod = png_byte(is, chunk.crc_state); if (png.filtermethod != 0) imgerror(is, "PNG invalid filter method"); png.interlacemethod = png_byte(is, chunk.crc_state); if (png.interlacemethod != 0 && png.interlacemethod != 1) imgerror(is, "PNG invalid interlace method"); # sys->print("width %d height %d depth %d colortype %d interlace %d\n", # raw.r.max.x, raw.r.max.y, png.depth, png.colortype, png.interlacemethod); if (!png_crc_and_check(is, chunk)) imgerror(is, "PNG invalid CRC"); # Stash some detail in raw raw.r.min = Point(0, 0); raw.transp = 0; raw.chans = array[raw.nchans] of array of byte; { for (r:= 0; r < raw.nchans; r++) raw.chans[r] = array[raw.r.max.x * raw.r.max.y] of byte; } # Get the next chunk seenPLTE := 0; seenIDAT := 0; seenLastIDAT := 0; inflateFinished := 0; seenIEND := 0; seentRNS := 0; rq: chan of ref Filter->Rq; png.error = nil; rq = nil; while (png.error == nil) { if (!png_chunk_header(is, chunk)) { if (!seenIEND) png.error = "duff header"; break; } if (seenIEND) { png.error = "rubbish at eof"; break; } case (chunk.typ) { "IEND" => seenIEND = 1; "PLTE" => if (seenPLTE) { png.error = "too many PLTEs"; break; } if (seentRNS) { png.error = "tRNS before PLTE"; break; } if (seenIDAT) { png.error = "PLTE too late"; break; } if (chunk.size % 3 || chunk.size < 1 * 3 || chunk.size > 256 * 3) { png.error = "PLTE strange size"; break; } if (png.colortype == 0 || png.colortype == 4) { png.error = "superfluous PLTE"; break; } raw.cmap = array[256 * 3] of byte; png.PLTEsize = chunk.size / 3; if (!png_bytes(is, chunk.crc_state, raw.cmap, chunk.size)) { png.error = "eof in PLTE"; break; } # { # x: int; # sys->print("Palette:\n"); # for (x = 0; x < chunk.size; x += 3) # sys->print("%3d: (%3d, %3d, %3d)\n", # x / 3, int raw.cmap[x], int raw.cmap[x + 1], int raw.cmap[x + 2]); # } seenPLTE = 1; "tRNS" => if (seenIDAT) { png.error = "tRNS too late"; break; } case png.colortype { 0 => if (chunk.size != 2) { png.error = "tRNS wrong size"; break; } level := png_ushort(is, chunk.crc_state); if (level < 0) { png.error = "eof in tRNS"; break; } if (png.depth != 16) { raw.transp = 1; raw.trindex = byte level; } 2 => # a legitimate coding, but we can't use the information if (!png_skip_bytes(is, chunk.crc_state, chunk.size)) png.error = "eof in skipped tRNS chunk"; break; 3 => if (!seenPLTE) { png.error = "tRNS too early"; break; } if (chunk.size > png.PLTEsize) { png.error = "tRNS too big"; break; } png.tRNS = array[png.PLTEsize] of byte; for (x := chunk.size; x < png.PLTEsize; x++) png.tRNS[x] = byte 255; if (!png_bytes(is, chunk.crc_state, png.tRNS, chunk.size)) { png.error = "eof in tRNS"; break; } # { # sys->print("tRNS:\n"); # for (x = 0; x < chunk.size; x++) # sys->print("%3d: (%3d)\n", x, int png.tRNS[x]); # } if (png.error == nil) { # analyse the tRNS chunk to see if it contains a single transparent index # translucent entries are treated as opaque for (x = 0; x < chunk.size; x++) if (png.tRNS[x] == byte 0) { raw.trindex = byte x; if (raw.transp) { raw.transp = 0; break; } raw.transp = 1; } # if (raw.transp) # sys->print("selected index %d\n", int raw.trindex); } 4 or 6 => png.error = "tRNS invalid when alpha present"; } seentRNS = 1; "IDAT" => if (seenLastIDAT) { png.error = "non contiguous IDATs"; break; } if (inflateFinished) { png.error = "too many IDATs"; break; } remaining := 0; if (!seenIDAT) { # open channel to inflate filter if (!processdatainit(png, raw)) break; rq = inflate->start(nil); png_skip_bytes(is, chunk.crc_state, 2); remaining = chunk.size - 2; } else remaining = chunk.size; while (remaining && png.error == nil) { pick m := <- rq { Fill => # sys->print("Fill(%d) remaining %d\n", len m.buf, remaining); toget := len m.buf; if (toget > remaining) toget = remaining; if (!png_bytes(is, chunk.crc_state, m.buf, toget)) { m.reply <-= -1; png.error = "eof during IDAT"; break; } m.reply <-= toget; remaining -= toget; Result => # sys->print("Result(%d)\n", len m.buf); m.reply <-= 0; processdata(png, raw, m.buf); Info => # sys->print("Info(%s)\n", m.msg); Finished => inflateFinished = 1; # sys->print("Finished\n"); Error => imgerror(is, "PNG inflate error\n"); } } seenIDAT = 1; * => # skip the blighter if (!png_skip_bytes(is, chunk.crc_state, chunk.size)) png.error = "eof in skipped chunk"; } if (png.error != nil) break; if (!png_crc_and_check(is, chunk)) imgerror(is, "PNG invalid CRC"); if (chunk.typ != "IDAT" && seenIDAT) seenLastIDAT = 1; } # can only get here if IEND was last chunk, or png.error set if (png.error == nil && !seenIDAT) { png.error = "no IDAT!"; inflateFinished = 1; } while (rq != nil && !inflateFinished) { pick m := <-rq { Fill => # sys->print("Fill(%d)\n", len m.buf); png.error = "eof in zlib stream"; m.reply <-= -1; inflateFinished = 1; Result => # sys->print("Result(%d)\n", len m.buf); if (png.error != nil) { m.reply <-= -1; inflateFinished = 1; } else { m.reply <-= 0; processdata(png, raw, m.buf); } Info => # sys->print("Info(%s)\n", m.msg); Finished => # sys->print("Finished\n"); inflateFinished = 1; break; Error => png.error = "inflate error\n"; inflateFinished = 1; } } if (png.error == nil && !png.done) png.error = "insufficient data"; if (png.error != nil) imgerror(is, "PNG " + png.error); width := raw.r.dx(); height := raw.r.dy(); case raw.chandesc { CY => remapgrey(raw.chans[0], width, height); CRGB => remaprgb(raw.chans, width, height, CRGB); CRGB1 => remap1(raw.chans[0], width, height, raw.cmap); } pixels := raw.chans[0]; is.origw = width; is.origh = height; setdims(is); if(is.width != is.origw || is.height != is.origh) pixels = resample(pixels, is.origw, is.origh, is.width, is.height); im := newimage(is, is.width, is.height); im.writepixels(im.r, pixels); mi := newmi(im); # mi.mask = display.newimage(im.r, D->GREY1, 0, D->Black); return mi; } phase2stepping(phase: int): (int, int, int, int) { case phase { 0 => return (0, 1, 0, 1); 1 => return (0, 8, 0, 8); 2 => return (0, 8, 4, 8); 3 => return (4, 8, 0, 4); 4 => return (0, 4, 2, 4); 5 => return (2, 4, 0, 2); 6 => return (0, 2, 1, 2); 7 => return (1, 2, 0, 1); * => return (-1, -1, -1, -1); } } processdatainitphase(png: ref Png, raw: ref Rawimage) { (png.row, png.rowstep, png.colstart, png.colstep) = phase2stepping(png.phase); if (raw.r.max.x > png.colstart) png.phasecols = (raw.r.max.x - png.colstart + png.colstep - 1) / png.colstep; else png.phasecols = 0; if (raw.r.max.y > png.row) png.phaserows = (raw.r.max.y - png.row + png.rowstep - 1) / png.rowstep; else png.phaserows = 0; png.rowsize = png.phasecols * (raw.nchans + png.alpha) * png.depth; png.rowsize = (png.rowsize + 7) / 8; png.rowsize++; # for the filter byte png.rowbytessofar = 0; png.thisrow = array[png.rowsize] of byte; png.lastrow = array[png.rowsize] of byte; # sys->print("init phase %d: r (%d, %d, %d) c (%d, %d, %d) (%d)\n", # png.phase, png.row, png.rowstep, png.phaserows, # png.colstart, png.colstep, png.phasecols, png.rowsize); } processdatainit(png: ref Png, raw: ref Rawimage): int { if (raw.nchans != 1&& raw.nchans != 3) { png.error = "only 1 or 3 channels supported"; return 0; } # if (png.interlacemethod != 0) { # png.error = "only progressive supported"; # return 0; # } if (png.colortype == 3 && raw.cmap == nil) { png.error = "PLTE chunk missing"; return 0; } png.done = 0; png.filterbpp = (png.depth * (raw.nchans + png.alpha) + 7) / 8; png.phase = png.interlacemethod; processdatainitphase(png, raw); return 1; } upconvert(out: array of byte, outstride: int, in: array of byte, pixels: int, bpp: int) { b: byte; bits := pixels * bpp; lim := bits / 8; mask := byte ((1 << bpp) - 1); outx := 0; inx := 0; for (x := 0; x < lim; x++) { b = in[inx]; for (s := 8 - bpp; s >= 0; s -= bpp) { pixel := (b >> s) & mask; ucp := pixel; for (y := bpp; y < 8; y += bpp) ucp |= pixel << y; out[outx] = ucp; outx += outstride; } inx++; } residue := (bits % 8) / bpp; if (residue) { b = in[inx]; for (s := 8 - bpp; s >= 0; s -= bpp) { pixel := (b >> s) & mask; ucp := pixel; for (y := bpp; y < 8; y += bpp) ucp |= pixel << y; out[outx] = ucp; outx += outstride; if (--residue <= 0) break; } } } # expand (1 or 2 or 4) bit to 8 bit without scaling (for palletized stuff) expand(out: array of byte, outstride: int, in: array of byte, pixels: int, bpp: int) { b: byte; bits := pixels * bpp; lim := bits / 8; mask := byte ((1 << bpp) - 1); outx := 0; inx := 0; for (x := 0; x < lim; x++) { b = in[inx]; for (s := 8 - bpp; s >= 0; s -= bpp) { out[outx] = (b >> s) & mask; outx += outstride; } inx++; } residue := (bits % 8) / bpp; if (residue) { b = in[inx]; for (s := 8 - bpp; s >= 0; s -= bpp) { out[outx] = (b >> s) & mask; outx += outstride; if (--residue <= 0) break; } } } copybytes(out: array of byte, outstride: int, in: array of byte, instride: int, pixels: int) { inx := 0; outx := 0; for (x := 0; x < pixels; x++) { out[outx] = in[inx]; inx += instride; outx += outstride; } } outputrow(png: ref Png, raw: ref Rawimage, row: array of byte) { offset := png.row * raw.r.max.x; case raw.nchans { 1 => case (png.depth) { * => png.error = "depth not supported"; return; 1 or 2 or 4 => if (raw.chandesc == CRGB1) expand(raw.chans[0][offset + png.colstart:], png.colstep, row, png.phasecols, png.depth); else upconvert(raw.chans[0][offset + png.colstart:], png.colstep, row, png.phasecols, png.depth); 8 or 16 => # might have an Alpha channel to ignore! stride := (png.alpha + 1) * png.depth / 8; copybytes(raw.chans[0][offset + png.colstart:], png.colstep, row, stride, png.phasecols); } 3 => case (png.depth) { * => png.error = "depth not supported (2)"; return; 8 or 16 => # split rgb into three channels bytespc := png.depth / 8; stride := (3 + png.alpha) * bytespc; copybytes(raw.chans[0][offset + png.colstart:], png.colstep, row, stride, png.phasecols); copybytes(raw.chans[1][offset + png.colstart:], png.colstep, row[bytespc:], stride, png.phasecols); copybytes(raw.chans[2][offset + png.colstart:], png.colstep, row[bytespc * 2:], stride, png.phasecols); } } } filtersub(png: ref Png) { subx := 1; for (x := int png.filterbpp + 1; x < png.rowsize; x++) { png.thisrow[x] += png.thisrow[subx]; subx++; } } filterup(png: ref Png) { if (png.row == 0) return; for (x := 1; x < png.rowsize; x++) png.thisrow[x] += png.lastrow[x]; } filteraverage(png: ref Png) { for (x := 1; x < png.rowsize; x++) { a: int; if (x > png.filterbpp) a = int png.thisrow[x - png.filterbpp]; else a = 0; if (png.row != 0) a += int png.lastrow[x]; png.thisrow[x] += byte (a / 2); } } filterpaeth(png: ref Png) { a, b, c: byte; p, pa, pb, pc: int; for (x := 1; x < png.rowsize; x++) { if (x > png.filterbpp) a = png.thisrow[x - png.filterbpp]; else a = byte 0; if (png.row == 0) { b = byte 0; c = byte 0; } else { b = png.lastrow[x]; if (x > png.filterbpp) c = png.lastrow[x - png.filterbpp]; else c = byte 0; } p = int a + int b - int c; pa = p - int a; if (pa < 0) pa = -pa; pb = p - int b; if (pb < 0) pb = -pb; pc = p - int c; if (pc < 0) pc = -pc; if (pa <= pb && pa <= pc) png.thisrow[x] += a; else if (pb <= pc) png.thisrow[x] += b; else png.thisrow[x] += c; } } phaseendcheck(png: ref Png, raw: ref Rawimage): int { if (png.row >= raw.r.max.y || png.rowsize <= 1) { # this phase is over if (png.phase == 0) { png.done = 1; } else { png.phase++; if (png.phase > 7) png.done = 1; else processdatainitphase(png, raw); } return 1; } return 0; } processdata(png: ref Png, raw: ref Rawimage, buf: array of byte) { #sys->print("processdata(%d)\n", len buf); if (png.error != nil) return; i := 0; while (i < len buf) { if (png.done) { png.error = "too much data"; return; } if (phaseendcheck(png, raw)) continue; tocopy := (png.rowsize - png.rowbytessofar); if (tocopy > (len buf - i)) tocopy = len buf - i; png.thisrow[png.rowbytessofar :] = buf[i : i + tocopy]; i += tocopy; png.rowbytessofar += tocopy; if (png.rowbytessofar >= png.rowsize) { # a new row has arrived # apply filter here #sys->print("phase %d row %d\n", png.phase, png.row); case int png.thisrow[0] { 0 => ; 1 => filtersub(png); 2 => filterup(png); 3 => filteraverage(png); 4 => filterpaeth(png); * => # sys->print("implement filter method %d\n", int png.thisrow[0]); png.error = "filter method unsupported"; return; } # output row if (png.row >= raw.r.max.y) { png.error = "too much data"; return; } outputrow(png, raw, png.thisrow[1 :]); png.row += png.rowstep; save := png.lastrow; png.lastrow = png.thisrow; png.thisrow = save; png.rowbytessofar = 0; } } phaseendcheck(png, raw); } png_signature(is: ref ImageSource): int { sig := array[8] of { byte 137, byte 80, byte 78, byte 71, byte 13, byte 10, byte 26, byte 10 }; x: int; for (x = 0; x < 8; x++) if (png_getb(is) != int sig[x]) return 0; return 1; } png_getb(is: ref ImageSource) : int { if(is.i >= len is.bs.data) return -1; return int is.bs.data[is.i++]; } png_bytes(is: ref ImageSource, crc_state: ref CRCstate, buf: array of byte, n: int): int { if (is.i +n > len is.bs.data) { is.i = len is.bs.data; return 0; } if (buf == nil) { is.i += n; return 1; } buf[0:] = is.bs.data[is.i:is.i+n]; is.i += n; if (crc_state != nil) crc->crc(crc_state, buf, n); return 1; } png_skip_bytes(is: ref ImageSource, crc_state: ref CRCstate, n: int): int { buf := array[1024] of byte; while (n) { thistime: int = 1024; if (thistime > n) thistime = n; if (!png_bytes(is, crc_state, buf, thistime)) return 0; n -= thistime; } return 1; } png_get_4(is: ref ImageSource, crc_state: ref CRCstate, signed: int): (int, int) { buf := array[4] of byte; if (!png_bytes(is, crc_state, buf, 4)) return (0, 0); if (signed && int buf[0] & 16r80) return (0, 0); r:int = (int buf[0] << 24) | (int buf[1] << 16) | (int buf[2] << 8) | (int buf[3]); # sys->print("got int %d\n", r); return (1, r); } png_int(is: ref ImageSource, crc_state: ref CRCstate): int { ok, r: int; (ok, r) = png_get_4(is, crc_state, 1); if (ok) return r; return -1; } png_ushort(is: ref ImageSource, crc_state: ref CRCstate): int { buf := array[2] of byte; if (!png_bytes(is, crc_state, buf, 2)) return -1; return (int buf[0] << 8) | int buf[1]; } png_crc_and_check(is: ref ImageSource, chunk: ref Chunk): int { crc, ok: int; (ok, crc) = png_get_4(is, nil, 0); if (!ok) return 0; # sys->print("crc: computed %.8ux expected %.8ux\n", chunk.crc_state.crc, crc); if (chunk.crc_state.crc != crc) return 1; return 1; } png_byte(is: ref ImageSource, crc_state: ref CRCstate): int { buf := array[1] of byte; if (!png_bytes(is, crc_state, buf, 1)) return -1; # sys->print("got byte %d\n", int buf[0]); return int buf[0]; } png_type(is: ref ImageSource, crc_state: ref CRCstate): string { x: int; buf := array[4] of byte; if (!png_bytes(is, crc_state, buf, 4)) return nil; for (x = 0; x < 4; x++) { c: int; c = int buf[x]; if ((c < 65 || c > 90 && c < 97) || c > 122) return nil; } return string buf; } png_chunk_header(is: ref ImageSource, chunk: ref Chunk): int { chunk.size = png_int(is, nil); if (chunk.size < 0) return 0; crc->reset(chunk.crc_state); chunk.typ = png_type(is, chunk.crc_state); if (chunk.typ == nil) return 0; # sys->print("%s(%d)\n", chunk.typ, chunk.size); return 1; }