static fz_error
loadpostscriptfunc(pdf_function *func, pdf_xref *xref, fz_obj *dict, int oid, int gen)
{
fz_error error;
fz_stream *stream;
int codeptr;
pdf_logrsrc("load postscript function (%d %d R)\n", oid, gen);
error = pdf_openstream(&stream, xref, oid, gen);
if (error)
return fz_rethrow(error, "cannot open calculator function stream");
if (fz_readbyte(stream) != '{')
{
fz_dropstream(stream);
return fz_throw("stream is not a calculator function");
}
func->u.p.code = nil;
func->u.p.cap = 0;
codeptr = 0;
error = parsecode(func, stream, &codeptr);
if (error)
{
fz_dropstream(stream);
return fz_rethrow(error, "cannot parse calculator function");
}
fz_dropstream(stream);
return fz_okay;
}
static fz_error
loadcharproc(fz_tree **treep, pdf_xref *xref, fz_obj *rdb, fz_obj *stmref)
{
fz_error error;
pdf_csi *csi;
fz_stream *stm;
error = pdf_newcsi(&csi, 1);
if (error)
return fz_rethrow(error, "cannot create interpreter");
error = pdf_openstream(&stm, xref, fz_tonum(stmref), fz_togen(stmref));
if (error)
{
pdf_dropcsi(csi);
return fz_rethrow(error, "cannot open glyph content stream");
}
error = pdf_runcsi(csi, xref, rdb, stm);
if (error)
{
fz_dropstream(stm);
pdf_dropcsi(csi);
return fz_rethrow(error, "cannot interpret glyph content stream (%d %d R)", fz_tonum(stmref), fz_togen(stmref));
}
*treep = csi->tree;
csi->tree = nil;
fz_dropstream(stm);
pdf_dropcsi(csi);
return fz_okay;
}
static void showstream(int num, int gen)
{
fz_error error;
fz_stream *stm;
unsigned char buf[2048];
int n;
showcolumn = 0;
if (showdecode)
error = pdf_openstream(&stm, xref, num, gen);
else
error = pdf_openrawstream(&stm, xref, num, gen);
if (error)
die(error);
while (1)
{
error = fz_read(&n, stm, buf, sizeof buf);
if (error)
die(error);
if (n == 0)
break;
if (showbinary)
fwrite(buf, 1, n, stdout);
else
showsafe(buf, n);
}
fz_dropstream(stm);
}
void
fz_dropstream(fz_stream *stm)
{
stm->refs --;
if (stm->refs == 0)
{
if (stm->error)
{
fz_catch(stm->error, "dropped unhandled ioerror");
stm->error = fz_okay;
}
switch (stm->kind)
{
case FZ_SFILE:
close(stm->file);
break;
case FZ_SFILTER:
fz_dropfilter(stm->filter);
fz_dropstream(stm->chain);
break;
case FZ_SBUFFER:
break;
}
fz_dropbuffer(stm->buffer);
fz_free(stm);
}
}
/*
* Load predefined CMap from system.
*/
fz_error
pdf_loadsystemcmap(pdf_cmap **cmapp, char *cmapname)
{
fz_error error;
fz_stream *stream;
pdf_cmap *usecmap;
pdf_cmap *cmap;
unsigned char *data;
unsigned int len;
int i;
pdf_logfont("loading system cmap %s\n", cmapname);
error = pdf_getcmapbuffer(cmapname, &data, &len);
if(error)
return fz_rethrow(error, "no builtin cmap file: %s", cmapname);
stream = fz_openrmemory(data, len);
error = pdf_parsecmap(&cmap, stream);
fz_dropstream(stream);
if(error)
return fz_rethrow(error, "cannot parse cmap data");
if (cmap->usecmapname[0] && !cmap->usecmap)
{
pdf_logfont("charmap depends on other charmap (%s), loading it\n", cmap->usecmapname);
error = pdf_loadsystemcmap(&usecmap, cmap->usecmapname);
if (error)
return fz_rethrow(error, "could not load usecmap: %s", cmap->usecmapname);
pdf_setusecmap(cmap, usecmap);
}
*cmapp = cmap;
return fz_okay;
}
static fz_error *
parseTTCs(char *path)
{
fz_error *err = nil;
int byteread;
fz_stream *file = nil;
FONT_COLLECTION fontcollectioin;
ULONG i;
err = fz_openrfile(&file, path);
if(err)
goto cleanup;
SAFE_FZ_READ(file, &fontcollectioin, sizeof(FONT_COLLECTION));
if(memcmp(fontcollectioin.Tag,"ttcf",sizeof(fontcollectioin.Tag)) == 0)
{
fontcollectioin.Version = SWAPLONG(fontcollectioin.Version);
fontcollectioin.NumFonts = SWAPLONG(fontcollectioin.NumFonts);
if( fontcollectioin.Version == TTC_VERSION1 ||
fontcollectioin.Version == TTC_VERSION2 )
{
ULONG *offsettable = fz_malloc(sizeof(ULONG)*fontcollectioin.NumFonts);
if(offsettable == nil)
{
err = fz_outofmem;
goto cleanup;
}
SAFE_FZ_READ(file, offsettable, sizeof(ULONG)*fontcollectioin.NumFonts);
for(i = 0; i < fontcollectioin.NumFonts; ++i)
{
offsettable[i] = SWAPLONG(offsettable[i]);
parseTTF(file,offsettable[i],i,path);
}
fz_free(offsettable);
}
else
{
err = fz_throw("fonterror : invalid version");
goto cleanup;
}
}
else
{
err = fz_throw("fonterror: wrong format");
goto cleanup;
}
cleanup:
if(file)
fz_dropstream(file);
return err;
}
/*
* Load uncompressed contents of a stream into buf.
*/
fz_error *
pdf_loadstream(fz_buffer **bufp, pdf_xref *xref, int oid, int gen)
{
fz_error *error;
fz_stream *stm;
error = pdf_openstream(&stm, xref, oid, gen);
if (error)
return fz_rethrow(error, "cannot open stream (%d)", oid);
error = fz_readall(bufp, stm, 0);
fz_dropstream(stm);
if (error)
return fz_rethrow(error, "cannot load stream into buffer (%d)", oid);
return fz_okay;
}
static fz_error *
parseTTFs(char *path)
{
fz_error *err = nil;
fz_stream *file = nil;
err = fz_openrfile(&file, path);
if(err)
goto cleanup;
err = parseTTF(file,0,0,path);
if(err)
goto cleanup;
cleanup:
if(file)
fz_dropstream(file);
return err;
}
void
fz_dropstream(fz_stream *stm)
{
stm->refs --;
if (stm->refs == 0)
{
if (stm->error)
{
fflush(stdout);
fz_printerror(stm->error);
fz_droperror(stm->error);
fflush(stderr);
fz_warn("dropped unhandled ioerror");
}
if (stm->mode == FZ_SWRITE)
{
stm->buffer->eof = 1;
fz_flush(stm);
}
switch (stm->kind)
{
case FZ_SFILE:
close(stm->file);
break;
case FZ_SFILTER:
fz_dropfilter(stm->filter);
fz_dropstream(stm->chain);
break;
case FZ_SBUFFER:
break;
}
fz_dropbuffer(stm->buffer);
fz_free(stm);
}
}
fz_error *
pdf_loadinlineimage(pdf_image **imgp, pdf_xref *xref,
fz_obj *rdb, fz_obj *dict, fz_stream *file)
{
fz_error *error;
pdf_image *img;
fz_filter *filter;
fz_obj *f;
fz_obj *cs;
fz_obj *d;
int ismask;
int i;
img = fz_malloc(sizeof(pdf_image));
if (!img)
return fz_outofmem;
pdf_logimage("load inline image %p {\n", img);
img->super.loadtile = pdf_loadtile;
img->super.drop = pdf_dropimage;
img->super.n = 0;
img->super.a = 0;
img->super.refs = 0;
img->indexed = nil;
img->usecolorkey = 0;
img->mask = nil;
img->super.w = fz_toint(fz_dictgetsa(dict, "Width", "W"));
img->super.h = fz_toint(fz_dictgetsa(dict, "Height", "H"));
img->bpc = fz_toint(fz_dictgetsa(dict, "BitsPerComponent", "BPC"));
ismask = fz_tobool(fz_dictgetsa(dict, "ImageMask", "IM"));
d = fz_dictgetsa(dict, "Decode", "D");
cs = fz_dictgetsa(dict, "ColorSpace", "CS");
pdf_logimage("size %dx%d %d\n", img->super.w, img->super.h, img->bpc);
if (ismask)
{
pdf_logimage("is mask\n");
img->super.cs = nil;
img->super.n = 0;
img->super.a = 1;
img->bpc = 1;
}
if (cs)
{
img->super.cs = nil;
if (fz_isname(cs))
{
fz_obj *csd = fz_dictgets(rdb, "ColorSpace");
if (csd)
{
fz_obj *cso = fz_dictget(csd, cs);
img->super.cs = pdf_finditem(xref->store, PDF_KCOLORSPACE, cso);
if (img->super.cs)
fz_keepcolorspace(img->super.cs);
}
}
if (!img->super.cs)
{
/* XXX danger! danger! does this resolve? */
error = pdf_loadcolorspace(&img->super.cs, xref, cs);
if (error)
return error;
}
if (!strcmp(img->super.cs->name, "Indexed"))
{
pdf_logimage("indexed\n");
img->indexed = (pdf_indexed*)img->super.cs;
img->super.cs = img->indexed->base;
}
pdf_logimage("colorspace %s\n", img->super.cs->name);
img->super.n = img->super.cs->n;
img->super.a = 0;
}
if (fz_isarray(d))
{
pdf_logimage("decode array\n");
if (img->indexed)
for (i = 0; i < 2; i++)
img->decode[i] = fz_toreal(fz_arrayget(d, i));
else
for (i = 0; i < (img->super.n + img->super.a) * 2; i++)
img->decode[i] = fz_toreal(fz_arrayget(d, i));
}
else
{
if (img->indexed)
for (i = 0; i < 2; i++)
img->decode[i] = i & 1 ? (1 << img->bpc) - 1 : 0;
else
for (i = 0; i < (img->super.n + img->super.a) * 2; i++)
img->decode[i] = i & 1;
}
if (img->indexed)
img->stride = (img->super.w * img->bpc + 7) / 8;
else
img->stride = (img->super.w * (img->super.n + img->super.a) * img->bpc + 7) / 8;
/* load image data */
f = fz_dictgetsa(dict, "Filter", "F");
if (f)
{
fz_stream *tempfile;
error = pdf_buildinlinefilter(&filter, dict);
if (error)
return error;
error = fz_openrfilter(&tempfile, filter, file);
if (error)
return error;
i = fz_readall(&img->samples, tempfile);
if (i < 0)
return fz_ioerror(tempfile);
fz_dropfilter(filter);
fz_dropstream(tempfile);
}
else
{
error = fz_newbuffer(&img->samples, img->super.h * img->stride);
if (error)
return error;
i = fz_read(file, img->samples->bp, img->super.h * img->stride);
if (i < 0)
return fz_ioerror(file);
img->samples->wp += img->super.h * img->stride;
}
/* 0 means opaque and 1 means transparent, so we invert to get alpha */
if (ismask)
{
unsigned char *p;
for (p = img->samples->bp; p < img->samples->ep; p++)
*p = ~*p;
}
pdf_logimage("}\n");
*imgp = img;
return nil;
}
/*
* Load CMap stream in PDF file
*/
fz_error
pdf_loadembeddedcmap(pdf_cmap **cmapp, pdf_xref *xref, fz_obj *stmref)
{
fz_error error = fz_okay;
fz_obj *stmobj;
fz_stream *file = nil;
pdf_cmap *cmap = nil;
pdf_cmap *usecmap;
fz_obj *wmode;
fz_obj *obj;
if ((*cmapp = pdf_finditem(xref->store, PDF_KCMAP, stmref)))
{
pdf_keepcmap(*cmapp);
return fz_okay;
}
pdf_logfont("load embedded cmap (%d %d R) {\n", fz_tonum(stmref), fz_togen(stmref));
stmobj = fz_resolveindirect(stmref);
error = pdf_openstream(&file, xref, fz_tonum(stmref), fz_togen(stmref));
if (error)
{
error = fz_rethrow(error, "cannot open cmap stream");
goto cleanup;
}
error = pdf_parsecmap(&cmap, file);
if (error)
{
error = fz_rethrow(error, "cannot parse cmap stream");
goto cleanup;
}
fz_dropstream(file);
wmode = fz_dictgets(stmobj, "WMode");
if (fz_isint(wmode))
{
pdf_logfont("wmode %d\n", wmode);
pdf_setwmode(cmap, fz_toint(wmode));
}
obj = fz_dictgets(stmobj, "UseCMap");
if (fz_isname(obj))
{
pdf_logfont("usecmap /%s\n", fz_toname(obj));
error = pdf_loadsystemcmap(&usecmap, fz_toname(obj));
if (error)
{
error = fz_rethrow(error, "cannot load system usecmap '%s'", fz_toname(obj));
goto cleanup;
}
pdf_setusecmap(cmap, usecmap);
pdf_dropcmap(usecmap);
}
else if (fz_isindirect(obj))
{
pdf_logfont("usecmap (%d %d R)\n", fz_tonum(obj), fz_togen(obj));
error = pdf_loadembeddedcmap(&usecmap, xref, obj);
if (error)
{
error = fz_rethrow(error, "cannot load embedded usecmap");
goto cleanup;
}
pdf_setusecmap(cmap, usecmap);
pdf_dropcmap(usecmap);
}
pdf_logfont("}\n");
error = pdf_storeitem(xref->store, PDF_KCMAP, stmref, cmap);
if (error)
{
error = fz_rethrow(error, "cannot store cmap resource");
goto cleanup;
}
*cmapp = cmap;
return fz_okay;
cleanup:
if (file)
fz_dropstream(file);
if (cmap)
pdf_dropcmap(cmap);
return error; /* already rethrown */
}
fz_error *
pdf_updatexref(pdf_xref *xref, char *path)
{
fz_error *error;
fz_stream *out;
int oid;
int i, n;
int startxref;
fz_obj *obj;
pdf_logxref("updatexref '%s' %p\n", path, xref);
error = fz_openafile(&out, path);
if (error)
return error;
fz_print(out, "\n");
for (oid = 0; oid < xref->len; oid++)
{
if (xref->table[oid].type == 'a')
{
xref->table[oid].ofs = fz_tell(out);
error = writeobject(out, xref, xref->crypt, oid, xref->table[oid].gen);
if (error)
goto cleanup;
}
}
/* always write out entry 0 in appended xref sections */
xref->table[0].type = 'd';
startxref = fz_tell(out);
fz_print(out, "xref\n");
oid = 0;
while (oid < xref->len)
{
n = countmodified(xref, oid);
pdf_logxref(" section %d +%d\n", oid, n);
fz_print(out, "%d %d\n", oid, n);
for (i = 0; i < n; i++)
{
if (xref->table[oid + i].type == 'd')
xref->table[oid + i].type = 'f';
if (xref->table[oid + i].type == 'a')
xref->table[oid + i].type = 'n';
fz_print(out, "%010d %05d %c \n",
xref->table[oid + i].ofs,
xref->table[oid + i].gen,
xref->table[oid + i].type);
}
oid += n;
while (oid < xref->len &&
xref->table[oid].type != 'a' &&
xref->table[oid].type != 'd')
oid ++;
}
fz_print(out, "\n");
fz_print(out, "trailer\n<<\n /Size %d\n /Prev %d", xref->len, xref->startxref);
obj = fz_dictgets(xref->trailer, "Root");
fz_print(out,"\n /Root %d %d R", fz_tonum(obj), fz_togen(obj));
obj = fz_dictgets(xref->trailer, "Info");
if (obj)
fz_print(out,"\n /Info %d %d R", fz_tonum(obj), fz_togen(obj));
obj = fz_dictgets(xref->trailer, "Encrypt");
if (obj) {
fz_print(out,"\n /Encrypt ");
fz_printobj(out, obj, TIGHT);
}
obj = fz_dictgets(xref->trailer, "ID");
if (obj) {
fz_print(out,"\n /ID ");
fz_printobj(out, obj, TIGHT);
}
fz_print(out, "\n>>\n\n");
fz_print(out, "startxref\n");
fz_print(out, "%d\n", startxref);
fz_print(out, "%%%%EOF\n");
xref->startxref = startxref;
fz_dropstream(out);
return nil;
cleanup:
fz_dropstream(out);
return error;
}
fz_error
pdf_loadxref(pdf_xref *xref, char *filename)
{
fz_error error;
fz_obj *size;
int i;
char buf[65536]; /* yeowch! */
pdf_logxref("loadxref '%s' %p\n", filename, xref);
error = fz_openrfile(&xref->file, filename);
if (error)
{
return fz_rethrow(error, "cannot open file: '%s'", filename);
}
error = loadversion(xref);
if (error)
{
error = fz_rethrow(error, "cannot read version marker");
goto cleanup;
}
error = readstartxref(xref);
if (error)
{
error = fz_rethrow(error, "cannot read startxref");
goto cleanup;
}
error = readtrailer(xref, buf, sizeof buf);
if (error)
{
error = fz_rethrow(error, "cannot read trailer");
goto cleanup;
}
size = fz_dictgets(xref->trailer, "Size");
if (!size)
{
error = fz_throw("trailer missing Size entry");
goto cleanup;
}
pdf_logxref(" size %d at 0x%x\n", fz_toint(size), xref->startxref);
assert(xref->table == nil);
xref->len = fz_toint(size);
xref->cap = xref->len + 1; /* for hack to allow broken pdf generators with off-by-one errors */
xref->table = fz_malloc(xref->cap * sizeof(pdf_xrefentry));
for (i = 0; i < xref->cap; i++)
{
xref->table[i].ofs = 0;
xref->table[i].gen = 0;
xref->table[i].stmofs = 0;
xref->table[i].obj = nil;
xref->table[i].type = 0;
}
error = readxrefsections(xref, xref->startxref, buf, sizeof buf);
if (error)
{
error = fz_rethrow(error, "cannot read xref");
goto cleanup;
}
/* broken pdfs where first object is not free */
if (xref->table[0].type != 'f')
{
fz_warn("first object in xref is not free");
xref->table[0].type = 'f';
}
/* broken pdfs where freed objects have offset and gen set to 0
but still exits */
for (i = 0; i < xref->len; i++)
if (xref->table[i].type == 'n' && xref->table[i].ofs == 0 &&
xref->table[i].gen == 0 && xref->table[i].obj == nil)
{
fz_warn("object (%d %d R) has invalid offset, assumed missing", i, xref->table[i].gen);
xref->table[i].type = 'f';
}
return fz_okay;
cleanup:
fz_dropstream(xref->file);
xref->file = nil;
free(xref->table);
xref->table = nil;
return error;
}
int
main(int argc, char **argv)
{
pdf_cmap *cmap;
fz_error error;
fz_stream *fi;
FILE *fo;
char name[256];
char *realname;
int i, k;
if (argc < 3)
{
fprintf(stderr, "usage: cmapdump output.c lots of cmap files\n");
return 1;
}
fo = fopen(argv[1], "wb");
if (!fo)
{
fprintf(stderr, "cmapdump: could not open output file\n");
return 1;
}
fprintf(fo, "#include \"fitz.h\"\n");
fprintf(fo, "#include \"mupdf.h\"\n");
fprintf(fo, "\n");
for (i = 2; i < argc; i++)
{
realname = strrchr(argv[i], '/');
if (!realname)
realname = strrchr(argv[i], '\\');
if (realname)
realname ++;
else
realname = argv[i];
if (strlen(realname) > (sizeof name - 1))
{
fprintf(stderr, "cmapdump: file name too long\n");
return 1;
}
strcpy(name, realname);
clean(name);
error = fz_openrfile(&fi, argv[i]);
if (error)
{
fz_catch(error, "cmapdump: could not open input file %s\n", argv[i]);
return 1;
}
error = pdf_parsecmap(&cmap, fi);
if (error)
{
fz_catch(error, "cmapdump: could not parse input cmap %s\n", argv[i]);
return 1;
}
fprintf(fo, "/*\n * %s\n */\n\n", cmap->cmapname);
fprintf(fo, "static const pdf_range pdf_cmap_%s_ranges[] =\n{\n", name);
if (cmap->rlen == 0)
{
fprintf(fo, " /* dummy entry for non-c99 compilers */\n");
fprintf(fo, " { 0x0, 0x0, PDF_CMAP_RANGE, 0 }\n");
}
for (k = 0; k < cmap->rlen; k++)
{
fprintf(fo, " { 0x%04x, 0x%04x, %s %d },\n",
cmap->ranges[k].low, cmap->ranges[k].high,
flagtoname(cmap->ranges[k].flag),
cmap->ranges[k].offset);
}
fprintf(fo, "};\n\n");
if (cmap->tlen == 0)
{
fprintf(fo, "static const unsigned short pdf_cmap_%s_table[1] = { 0 };\n\n", name);
}
else
{
fprintf(fo, "static const unsigned short pdf_cmap_%s_table[%d] =\n{",
name, cmap->tlen);
for (k = 0; k < cmap->tlen; k++)
{
if (k % 8 == 0)
fprintf(fo, "\n ");
fprintf(fo, "%d, ", cmap->table[k]);
}
fprintf(fo, "\n};\n\n");
}
fprintf(fo, "pdf_cmap pdf_cmap_%s =\n", name);
fprintf(fo, "{\n");
fprintf(fo, " -1, ");
fprintf(fo, "\"%s\", ", cmap->cmapname);
fprintf(fo, "\"%s\", nil, ", cmap->usecmapname);
fprintf(fo, "%d,\n", cmap->wmode);
fprintf(fo, " %d, /* codespace table */\n", cmap->ncspace);
fprintf(fo, " {\n");
if (cmap->ncspace == 0)
{
fprintf(fo, " /* dummy entry for non-c99 compilers */\n");
fprintf(fo, " { 0, 0x0, 0x0 },\n");
}
for (k = 0; k < cmap->ncspace; k++)
{
fprintf(fo, "\t{ %d, 0x%04x, 0x%04x },\n",
cmap->cspace[k].n, cmap->cspace[k].low, cmap->cspace[k].high);
}
fprintf(fo, " },\n");
fprintf(fo, " %d, %d, (pdf_range*) pdf_cmap_%s_ranges,\n",
cmap->rlen, cmap->rlen, name);
fprintf(fo, " %d, %d, (unsigned short*) pdf_cmap_%s_table,\n",
cmap->tlen, cmap->tlen, name);
fprintf(fo, "};\n\n");
fz_dropstream(fi);
}
return 0;
}
fz_error
pdf_loadobjstm(pdf_xref *xref, int oid, int gen, char *buf, int cap)
{
fz_error error;
fz_stream *stm;
fz_obj *objstm;
int *oidbuf;
int *ofsbuf;
fz_obj *obj;
int first;
int count;
int i, n;
pdf_token_e tok;
pdf_logxref("loadobjstm (%d %d R)\n", oid, gen);
error = pdf_loadobject(&objstm, xref, oid, gen);
if (error)
return fz_rethrow(error, "cannot load object stream object");
count = fz_toint(fz_dictgets(objstm, "N"));
first = fz_toint(fz_dictgets(objstm, "First"));
pdf_logxref(" count %d\n", count);
oidbuf = fz_malloc(count * sizeof(int));
ofsbuf = fz_malloc(count * sizeof(int));
error = pdf_openstream(&stm, xref, oid, gen);
if (error)
{
error = fz_rethrow(error, "cannot open object stream");
goto cleanupbuf;
}
for (i = 0; i < count; i++)
{
error = pdf_lex(&tok, stm, buf, cap, &n);
if (error || tok != PDF_TINT)
{
error = fz_rethrow(error, "corrupt object stream");
goto cleanupstm;
}
oidbuf[i] = atoi(buf);
error = pdf_lex(&tok, stm, buf, cap, &n);
if (error || tok != PDF_TINT)
{
error = fz_rethrow(error, "corrupt object stream");
goto cleanupstm;
}
ofsbuf[i] = atoi(buf);
}
error = fz_seek(stm, first, 0);
if (error)
{
error = fz_rethrow(error, "cannot seek in object stream");
goto cleanupstm;
}
for (i = 0; i < count; i++)
{
/* FIXME: seek to first + ofsbuf[i] */
error = pdf_parsestmobj(&obj, xref, stm, buf, cap);
if (error)
{
error = fz_rethrow(error, "cannot parse object %d in stream", i);
goto cleanupstm;
}
if (oidbuf[i] < 1 || oidbuf[i] >= xref->len)
{
fz_dropobj(obj);
error = fz_throw("object id (%d 0 R) out of range (0..%d)", oidbuf[i], xref->len - 1);
goto cleanupstm;
}
if (xref->table[oidbuf[i]].obj)
fz_dropobj(xref->table[oidbuf[i]].obj);
xref->table[oidbuf[i]].obj = obj;
}
fz_dropstream(stm);
fz_free(ofsbuf);
fz_free(oidbuf);
fz_dropobj(objstm);
return fz_okay;
cleanupstm:
fz_dropstream(stm);
cleanupbuf:
fz_free(ofsbuf);
fz_free(oidbuf);
fz_dropobj(objstm);
return error; /* already rethrown */
}
fz_error *
pdf_loadtype7shade(fz_shade *shade, pdf_xref *xref, fz_obj *shading, fz_obj *ref)
{
fz_error *error;
fz_stream *stream;
fz_obj *obj;
int bpcoord;
int bpcomp;
int bpflag;
int ncomp;
float x0, x1, y0, y1;
float c0[FZ_MAXCOLORS];
float c1[FZ_MAXCOLORS];
int i, n, j;
unsigned int t;
int flag;
fz_point p[16];
pdf_tensorpatch patch;
error = nil;
ncomp = shade->cs->n;
bpcoord = fz_toint(fz_dictgets(shading, "BitsPerCoordinate"));
bpcomp = fz_toint(fz_dictgets(shading, "BitsPerComponent"));
bpflag = fz_toint(fz_dictgets(shading, "BitsPerFlag"));
obj = fz_dictgets(shading, "Decode");
if (fz_isarray(obj))
{
pdf_logshade("decode array\n");
x0 = fz_toreal(fz_arrayget(obj, 0));
x1 = fz_toreal(fz_arrayget(obj, 1));
y0 = fz_toreal(fz_arrayget(obj, 2));
y1 = fz_toreal(fz_arrayget(obj, 3));
for (i=0; i < fz_arraylen(obj) / 2; ++i) {
c0[i] = fz_toreal(fz_arrayget(obj, i*2+4));
c1[i] = fz_toreal(fz_arrayget(obj, i*2+5));
}
}
else {
error = fz_throw("syntaxerror: No Decode key in Type 6 Shade");
goto cleanup;
}
obj = fz_dictgets(shading, "Function");
if (obj) {
ncomp = 1;
pdf_loadshadefunction(shade, xref, shading, c0[0], c1[0]);
shade->usefunction = 1;
}
else
shade->usefunction = 0;
shade->meshcap = 0;
shade->mesh = nil;
error = growshademesh(shade, 1024);
if (error) goto cleanup;
n = 2 + shade->cs->n;
j = 0;
error = pdf_openstream(&stream, xref, fz_tonum(ref), fz_togen(ref));
if (error) goto cleanup;
while (fz_peekbyte(stream) != EOF)
{
flag = getdata(stream, bpflag);
for (i = 0; i < 16; ++i) {
t = getdata(stream, bpcoord);
p[i].x = x0 + (t * (x1 - x0) / (pow(2, bpcoord) - 1.));
t = getdata(stream, bpcoord);
p[i].y = y0 + (t * (y1 - y0) / (pow(2, bpcoord) - 1.));
}
for (i = 0; i < 4; ++i) {
int k;
for (k=0; k < ncomp; ++k) {
t = getdata(stream, bpcomp);
patch.color[i][k] =
c0[k] + (t * (c1[k] - c0[k]) / (pow(2, bpcomp) - 1.0f));
}
}
patch.pole[0][0] = p[0];
patch.pole[0][1] = p[1];
patch.pole[0][2] = p[2];
patch.pole[0][3] = p[3];
patch.pole[1][3] = p[4];
patch.pole[2][3] = p[5];
patch.pole[3][3] = p[6];
patch.pole[3][2] = p[7];
patch.pole[3][1] = p[8];
patch.pole[3][0] = p[9];
patch.pole[2][0] = p[10];
patch.pole[1][0] = p[11];
patch.pole[1][1] = p[12];
patch.pole[1][2] = p[13];
patch.pole[2][2] = p[14];
patch.pole[2][1] = p[15];
j = drawpatch(patch, shade, j, ncomp, 0);
}
fz_dropstream(stream);
shade->meshlen = j / n / 3;
cleanup:
return nil;
}
/*
* Open a stream for reading uncompressed data.
* Put the opened file in xref->stream.
* Using xref->file while a stream is open is a Bad idea.
*/
fz_error *
pdf_openstream(fz_stream **stmp, pdf_xref *xref, int oid, int gen)
{
pdf_xrefentry *x;
fz_error *error;
fz_stream *rawstm;
fz_filter *filter;
if (oid < 0 || oid >= xref->len)
return fz_throw("object id out of range (%d)", oid);
x = xref->table + oid;
error = pdf_cacheobject(xref, oid, gen);
if (error)
return fz_rethrow(error, "cannot load stream object (%d)", oid);
if (x->stmbuf)
{
error = pdf_buildfilter(&filter, xref, x->obj, oid, gen);
if (error)
return fz_rethrow(error, "cannot create filter");
error = fz_openrbuffer(&rawstm, x->stmbuf);
if (error)
{
fz_dropfilter(filter);
return fz_rethrow(error, "cannot open stream from buffer");
}
error = fz_openrfilter(stmp, filter, rawstm);
fz_dropfilter(filter);
fz_dropstream(rawstm);
if (error)
return fz_rethrow(error, "cannot open filter stream");
return fz_okay;
}
if (x->stmofs)
{
error = pdf_buildfilter(&filter, xref, x->obj, oid, gen);
if (error)
return fz_rethrow(error, "cannot create filter");
error = fz_seek(xref->file, x->stmofs, 0);
if (error)
{
fz_dropfilter(filter);
return fz_rethrow(error, "cannot seek to stream");
}
error = fz_openrfilter(stmp, filter, xref->file);
fz_dropfilter(filter);
if (error)
return fz_rethrow(error, "cannot open filter stream");
return fz_okay;
}
return fz_throw("object is not a stream");
}
static fz_error *
writestream(fz_stream *out, pdf_xref *xref, pdf_crypt *encrypt, int oid, int gen)
{
fz_error *error;
fz_stream *dststm;
fz_stream *srcstm;
unsigned char buf[4096];
fz_filter *ef;
int n;
fz_print(out, "stream\n");
if (encrypt)
{
error = pdf_cryptstream(&ef, encrypt, oid, gen);
if (error)
return error;
error = fz_openrfilter(&dststm, ef, out);
fz_dropfilter(ef);
if (error)
return error;
}
else
{
dststm = fz_keepstream(out);
}
error = pdf_openrawstream(&srcstm, xref, oid, gen);
if (error)
goto cleanupdst;
while (1)
{
n = fz_read(srcstm, buf, sizeof buf);
if (n == 0)
break;
if (n < 0)
{
error = fz_ioerror(srcstm);
goto cleanupsrc;
}
n = fz_write(dststm, buf, n);
if (n < 0)
{
error = fz_ioerror(dststm);
goto cleanupsrc;
}
}
fz_dropstream(srcstm);
fz_dropstream(dststm);
fz_print(out, "endstream\n");
return nil;
cleanupsrc:
fz_dropstream(srcstm);
cleanupdst:
fz_dropstream(dststm);
return error;
}
fz_error *
pdf_savexref(pdf_xref *xref, char *path, pdf_crypt *encrypt)
{
fz_error *error;
fz_stream *out;
int oid;
int startxref;
int *ofsbuf;
fz_obj *obj;
int eoid, egen;
pdf_logxref("savexref '%s' %p\n", path, xref);
/* need to add encryption object for acrobat < 6 */
if (encrypt)
{
pdf_logxref("make encryption dict\n");
error = pdf_allocobject(xref, &eoid, &egen);
if (error)
return error;
pdf_cryptobj(encrypt, encrypt->encrypt, eoid, egen);
error = pdf_updateobject(xref, eoid, egen, encrypt->encrypt);
if (error)
return error;
}
ofsbuf = fz_malloc(sizeof(int) * xref->len);
if (!ofsbuf)
return fz_outofmem;
error = fz_openwfile(&out, path);
if (error)
{
fz_free(ofsbuf);
return error;
}
fz_print(out, "%%PDF-%1.1f\n", xref->version);
fz_print(out, "%%\342\343\317\323\n\n");
for (oid = 0; oid < xref->len; oid++)
{
pdf_xrefentry *x = xref->table + oid;
if (x->type == 'n' || x->type == 'o' || x->type == 'a')
{
ofsbuf[oid] = fz_tell(out);
error = writeobject(out, xref, encrypt, oid, x->type == 'o' ? 0 : x->gen);
if (error)
goto cleanup;
}
else
{
ofsbuf[oid] = x->ofs;
}
}
startxref = fz_tell(out);
fz_print(out, "xref\n");
fz_print(out, "0 %d\n", xref->len);
for (oid = 0; oid < xref->len; oid++)
{
int gen = xref->table[oid].gen;
int type = xref->table[oid].type;
if (type == 'o')
gen = 0;
if (type == 'a' || type == 'o')
type = 'n';
if (type == 'd')
type = 'f';
fz_print(out, "%010d %05d %c \n", ofsbuf[oid], gen, type);
}
fz_print(out, "\n");
fz_print(out, "trailer\n<<\n /Size %d", xref->len);
obj = fz_dictgets(xref->trailer, "Root");
fz_print(out, "\n /Root %d %d R", fz_tonum(obj), fz_togen(obj));
obj = fz_dictgets(xref->trailer, "Info");
if (obj)
fz_print(out, "\n /Info %d %d R", fz_tonum(obj), fz_togen(obj));
if (encrypt)
{
fz_print(out, "\n /Encrypt %d %d R", eoid, egen);
fz_print(out, "\n /ID [");
fz_printobj(out, encrypt->id, 1);
fz_printobj(out, encrypt->id, 1);
fz_print(out, "]");
pdf_cryptobj(encrypt, encrypt->encrypt, eoid, egen);
}
fz_print(out, "\n>>\n\n");
fz_print(out, "startxref\n");
fz_print(out, "%d\n", startxref);
fz_print(out, "%%%%EOF\n");
xref->startxref = startxref;
if(ofsbuf) fz_free(ofsbuf);
fz_dropstream(out);
return nil;
cleanup:
if(ofsbuf) fz_free(ofsbuf);
fz_dropstream(out);
return error;
}
static fz_error
readnewxref(fz_obj **trailerp, pdf_xref *xref, char *buf, int cap)
{
fz_error error;
fz_stream *stm;
fz_obj *trailer;
fz_obj *index;
fz_obj *obj;
int oid, gen, stmofs;
int size, w0, w1, w2;
int t;
int i;
pdf_logxref("load new xref format\n");
error = pdf_parseindobj(&trailer, xref, xref->file, buf, cap, &oid, &gen, &stmofs);
if (error)
return fz_rethrow(error, "cannot parse compressed xref stream object");
obj = fz_dictgets(trailer, "Size");
if (!obj)
{
fz_dropobj(trailer);
return fz_throw("xref stream missing Size entry");
}
size = fz_toint(obj);
if (size >= xref->cap)
{
xref->cap = size + 1; /* for hack to allow broken pdf generators with off-by-one errors */
xref->table = fz_realloc(xref->table, xref->cap * sizeof(pdf_xrefentry));
}
if (size > xref->len)
{
for (i = xref->len; i < xref->cap; i++)
{
xref->table[i].ofs = 0;
xref->table[i].gen = 0;
xref->table[i].stmofs = 0;
xref->table[i].obj = nil;
xref->table[i].type = 0;
}
xref->len = size;
}
if (oid < 0 || oid >= xref->len)
{
if (oid == xref->len && oid < xref->cap)
{
/* allow broken pdf files that have off-by-one errors in the xref */
fz_warn("object id (%d %d R) out of range (0..%d)", oid, gen, xref->len - 1);
xref->len ++;
}
else
{
fz_dropobj(trailer);
return fz_throw("object id (%d %d R) out of range (0..%d)", oid, gen, xref->len - 1);
}
}
xref->table[oid].type = 'n';
xref->table[oid].gen = gen;
xref->table[oid].obj = fz_keepobj(trailer);
xref->table[oid].stmofs = stmofs;
xref->table[oid].ofs = 0;
obj = fz_dictgets(trailer, "W");
if (!obj) {
fz_dropobj(trailer);
return fz_throw("xref stream missing W entry");
}
w0 = fz_toint(fz_arrayget(obj, 0));
w1 = fz_toint(fz_arrayget(obj, 1));
w2 = fz_toint(fz_arrayget(obj, 2));
index = fz_dictgets(trailer, "Index");
error = pdf_openstream(&stm, xref, oid, gen);
if (error)
{
fz_dropobj(trailer);
return fz_rethrow(error, "cannot open compressed xref stream");
}
if (!index)
{
error = readnewxrefsection(xref, stm, 0, size, w0, w1, w2);
if (error)
{
fz_dropstream(stm);
fz_dropobj(trailer);
return fz_rethrow(error, "cannot read xref stream");
}
}
else
{
for (t = 0; t < fz_arraylen(index); t += 2)
{
int i0 = fz_toint(fz_arrayget(index, t + 0));
int i1 = fz_toint(fz_arrayget(index, t + 1));
error = readnewxrefsection(xref, stm, i0, i1, w0, w1, w2);
if (error)
{
fz_dropstream(stm);
fz_dropobj(trailer);
return fz_rethrow(error, "cannot read xref stream section");
}
}
}
fz_dropstream(stm);
*trailerp = trailer;
return fz_okay;
}
fz_error *
pdf_loadtype5shade(fz_shade *shade, pdf_xref *xref, fz_obj *shading, fz_obj *ref)
{
fz_error *error;
fz_stream *stream;
fz_obj *obj;
int bpcoord;
int bpcomp;
int vpr, vpc;
int ncomp;
float x0, x1, y0, y1;
float c0[FZ_MAXCOLORS];
float c1[FZ_MAXCOLORS];
int i, n, j;
int p, q;
unsigned int t;
float *x, *y, *c[FZ_MAXCOLORS];
error = nil;
ncomp = shade->cs->n;
bpcoord = fz_toint(fz_dictgets(shading, "BitsPerCoordinate"));
bpcomp = fz_toint(fz_dictgets(shading, "BitsPerComponent"));
vpr = fz_toint(fz_dictgets(shading, "VerticesPerRow"));
if (vpr < 2) {
error = fz_throw("VerticesPerRow must be greater than or equal to 2");
goto cleanup;
}
obj = fz_dictgets(shading, "Decode");
if (fz_isarray(obj))
{
pdf_logshade("decode array\n");
x0 = fz_toreal(fz_arrayget(obj, 0));
x1 = fz_toreal(fz_arrayget(obj, 1));
y0 = fz_toreal(fz_arrayget(obj, 2));
y1 = fz_toreal(fz_arrayget(obj, 3));
for (i=0; i < fz_arraylen(obj) / 2; ++i) {
c0[i] = fz_toreal(fz_arrayget(obj, i*2+4));
c1[i] = fz_toreal(fz_arrayget(obj, i*2+5));
}
}
else {
error = fz_throw("syntaxerror: No Decode key in Type 4 Shade");
goto cleanup;
}
obj = fz_dictgets(shading, "Function");
if (obj) {
ncomp = 1;
pdf_loadshadefunction(shade, xref, shading, c0[0], c1[0]);
shade->usefunction = 1;
}
else
shade->usefunction = 0;
n = 2 + shade->cs->n;
j = 0;
#define BIGNUM 1024
x = fz_malloc(sizeof(float) * vpr * BIGNUM);
y = fz_malloc(sizeof(float) * vpr * BIGNUM);
for (i = 0; i < ncomp; ++i) {
c[i] = fz_malloc(sizeof(float) * vpr * BIGNUM);
}
q = 0;
error = pdf_openstream(&stream, xref, fz_tonum(ref), fz_togen(ref));
if (error) goto cleanup;
while (fz_peekbyte(stream) != EOF)
{
for (p = 0; p < vpr; ++p) {
int idx;
idx = q * vpr + p;
t = getdata(stream, bpcoord);
x[idx] = x0 + (t * (x1 - x0) / ((float)pow(2, bpcoord) - 1));
t = getdata(stream, bpcoord);
y[idx] = y0 + (t * (y1 - y0) / ((float)pow(2, bpcoord) - 1));
for (i=0; i < ncomp; ++i) {
t = getdata(stream, bpcomp);
c[i][idx] = c0[i] + (t * (c1[i] - c0[i]) / (float)(pow(2, bpcomp) - 1));
}
}
q++;
}
fz_dropstream(stream);
#define ADD_VERTEX(idx) \
{\
int z;\
shade->mesh[j++] = x[idx];\
shade->mesh[j++] = y[idx];\
for (z = 0; z < shade->cs->n; ++z) {\
shade->mesh[j++] = c[z][idx];\
}\
}\
vpc = q;
shade->meshcap = 0;
shade->mesh = fz_malloc(sizeof(float) * 1024);
if (!shade) {
error = fz_outofmem;
goto cleanup;
}
j = 0;
for (p = 0; p < vpr-1; ++p) {
for (q = 0; q < vpc-1; ++q) {
ADD_VERTEX(q * vpr + p);
ADD_VERTEX(q * vpr + p + 1);
ADD_VERTEX((q + 1) * vpr + p + 1);
ADD_VERTEX(q * vpr + p);
ADD_VERTEX((q + 1) * vpr + p + 1);
ADD_VERTEX((q + 1) * vpr + p);
}
}
shade->meshlen = j / n / 3;
fz_free(x);
fz_free(y);
for (i = 0; i < ncomp; ++i) {
fz_free(c[i]);
}
cleanup:
return nil;
}
