static bool TIFFWriteByteArray(TIFF tif, TIFFDirEntry dir, sbyte[] cp)
{
byte[] buf=new byte[dir.tdir_count];
for(int i=0; i<dir.tdir_count; i++) buf[i]=(byte)cp[i];
return TIFFWriteByteArray(tif, dir, buf);
}
// Fetch and set the SubjectDistance EXIF tag.
static bool TIFFFetchSubjectDistance(TIFF tif, TIFFDirEntry dir)
{
if(dir.tdir_count!=1||dir.tdir_type!=(ushort)TIFFDataType.TIFF_RATIONAL)
{
TIFFWarningExt(tif.tif_clientdata, tif.tif_name, "incorrect count or type for SubjectDistance, tag ignored");
return false;
}
bool ok=false;
byte[] buf=new byte[8];
if(TIFFFetchData(tif, dir, buf)!=0)
{
uint l0=BitConverter.ToUInt32(buf, 0);
uint l1=BitConverter.ToUInt32(buf, 4);
double v;
if(cvtRational(tif, dir, l0, l1, out v))
{
// XXX: Numerator 0xFFFFFFFF means that we have infinite
// distance. Indicate that with a negative floating point
// SubjectDistance value.
ok=TIFFSetField(tif, (TIFFTAG)dir.tdir_tag, (l0!=0xFFFFFFFF)?v:-v);
}
}
return ok;
}
// Convert numerator+denominator to double.
static bool cvtRational(TIFF tif, TIFFDirEntry dir, uint num, uint denom, out double rv)
{
if(num==0&&denom==0)
{
rv=0;
return true;
}
if(denom==0)
{
TIFFErrorExt(tif.tif_clientdata, tif.tif_name, "{0}: Rational with zero denominator (num = {1})", TIFFFieldWithTag(tif, (TIFFTAG)dir.tdir_tag).field_name, num);
rv=double.NaN;
return false;
}
if((TIFFDataType)dir.tdir_type==TIFFDataType.TIFF_RATIONAL) rv=((double)num/(double)denom);
else rv=((double)(int)num/(double)(int)denom);
return true;
}
// Fetch an array of SSHORT values.
static bool TIFFFetchShortArray(TIFF tif, TIFFDirEntry dir, short[] v)
{
if(dir.tdir_count<=2)
{
if(tif.tif_header.tiff_magic==TIFF_BIGENDIAN)
{
switch(dir.tdir_count)
{
case 2: v[1]=(short)(dir.tdir_offset&0xffff); goto case 1;
case 1: v[0]=(short)(dir.tdir_offset>>16); break;
}
}
else
{
switch(dir.tdir_count)
{
case 2: v[1]=(short)(dir.tdir_offset>>16); goto case 1;
case 1: v[0]=(short)(dir.tdir_offset&0xffff); break;
}
}
return true;
}
byte[] buf=new byte[dir.tdir_count*2];
if(TIFFFetchData(tif, dir, buf)==0) return false;
for(int i=0; i<dir.tdir_count; i++) v[i]=BitConverter.ToInt16(buf, i*2);
return true;
}
// Fetch an ASCII item from the file.
static int TIFFFetchString(TIFF tif, TIFFDirEntry dir, out string cp)
{
if(dir.tdir_count<=4)
{
uint l=dir.tdir_offset;
if((tif.tif_flags&TIF_FLAGS.TIFF_SWAB)!=0) TIFFSwab(ref l); // swab 'back' see in TIFFReadDirectory & TIFFReadCustomDirectory
cp=System.Text.Encoding.ASCII.GetString(BitConverter.GetBytes(l));
return 1;
}
cp=null;
byte[] buf=new byte[dir.tdir_count];
int ret=TIFFFetchData(tif, dir, buf);
if(ret==0) return 0;
cp=System.Text.Encoding.ASCII.GetString(buf);
return ret;
}
// Fetch samples/pixel short values for
// the specified tag and verify that
// all values are the same.
static bool TIFFFetchPerSampleShorts(TIFF tif, TIFFDirEntry dir, out ushort pl)
{
ushort samples=tif.tif_dir.td_samplesperpixel;
pl=0;
if(!CheckDirCount(tif, dir, samples)) return false;
ushort[] v=null;
try
{
v=new ushort[dir.tdir_count];
}
catch
{
TIFFErrorExt(tif.tif_clientdata, tif.tif_name, "No space to fetch per-sample values");
return false;
}
if(TIFFFetchShortArray(tif, dir, v))
{
uint check_count=dir.tdir_count;
if(samples<check_count) check_count=samples;
for(uint i=1; i<check_count; i++)
{
if(v[i]!=v[0])
{
TIFFErrorExt(tif.tif_clientdata, tif.tif_name, "Cannot handle different per-sample values for field \"{0}\"", TIFFFieldWithTag(tif, (TIFFTAG)dir.tdir_tag).field_name);
return false;
}
}
pl=v[0];
}
return true;
}
// Fetch an array of RATIONAL or SRATIONAL values.
static bool TIFFFetchRationalArray(TIFF tif, TIFFDirEntry dir, double[] v)
{
byte[] buf=null;
try
{
buf=new byte[dir.tdir_count*8];
}
catch
{
TIFFErrorExt(tif.tif_clientdata, tif.tif_name, "No space to fetch array of rationals");
return false;
}
for(int i=0; i<dir.tdir_count; i++)
{
if(!cvtRational(tif, dir, BitConverter.ToUInt32(buf, i*8), BitConverter.ToUInt32(buf, i*8+4), out v[i])) return false;
}
return true;
}
// Process tags that are not special cased.
static bool TIFFWriteNormalTag(TIFF tif, TIFFDirEntry dir, TIFFFieldInfo fip)
{
uint wc=(uint)fip.field_writecount;
dir.tdir_tag=(ushort)fip.field_tag;
dir.tdir_type=(ushort)fip.field_type;
dir.tdir_count=wc;
switch(fip.field_type)
{
case TIFFDataType.TIFF_SHORT:
{
object[] ap=new object[2];
TIFFGetField(tif, fip.field_tag, ap);
if(fip.field_passcount)
{
// Assume TIFF_VARIABLE
dir.tdir_count=wc=__GetAsUint(ap, 0);
ushort[] wp=ap[1] as ushort[];
if(wp==null) return false;
if(!TIFFWriteShortArray(tif, dir, wp)) return false;
}
else
{
if(wc==1)
{
ushort sv=__GetAsUshort(ap, 0);
//was dir.tdir_offset=TIFFInsertData(tif, dir.tdir_type, sv);
dir.tdir_offset=((uint)(tif.tif_header.tiff_magic==TIFF_BIGENDIAN?(sv&tif_typemask[dir.tdir_type])<<tif_typeshift[dir.tdir_type]:sv&tif_typemask[dir.tdir_type]));
}
else
{
ushort[] wp=ap[0] as ushort[];
if(wp==null) return false;
if(!TIFFWriteShortArray(tif, dir, wp)) return false;
}
}
}
break;
case TIFFDataType.TIFF_SSHORT:
{
object[] ap=new object[2];
TIFFGetField(tif, fip.field_tag, ap);
if(fip.field_passcount)
{
// Assume TIFF_VARIABLE
dir.tdir_count=wc=__GetAsUint(ap, 0);
short[] wp=ap[1] as short[];
if(wp==null) return false;
if(!TIFFWriteShortArray(tif, dir, wp)) return false;
}
else
{
if(wc==1)
{
short sv=__GetAsShort(ap, 0);
//was dir.tdir_offset=TIFFInsertData(tif, dir.tdir_type, sv);
dir.tdir_offset=((uint)(tif.tif_header.tiff_magic==TIFF_BIGENDIAN?(sv&tif_typemask[dir.tdir_type])<<tif_typeshift[dir.tdir_type]:sv&tif_typemask[dir.tdir_type]));
}
else
{
short[] wp=ap[0] as short[];
if(wp==null) return false;
if(!TIFFWriteShortArray(tif, dir, wp)) return false;
}
}
}
break;
case TIFFDataType.TIFF_SLONG:
{
object[] ap=new object[2];
TIFFGetField(tif, fip.field_tag, ap);
if(fip.field_passcount)
{
// Assume TIFF_VARIABLE
dir.tdir_count=wc=__GetAsUint(ap, 0);
int[] lp=ap[1] as int[];
if(lp==null) return false;
if(!TIFFWriteLongArray(tif, dir, lp)) return false;
}
else
{
if(wc==1)
{
// XXX handle LONG=>SHORT conversion
dir.tdir_offset=__GetAsUint(ap, 0);
}
else
{
int[] lp=ap[0] as int[];
if(lp==null) return false;
if(!TIFFWriteLongArray(tif, dir, lp)) return false;
}
}
}
break;
case TIFFDataType.TIFF_LONG:
case TIFFDataType.TIFF_IFD:
{
object[] ap=new object[2];
TIFFGetField(tif, fip.field_tag, ap);
if(fip.field_passcount)
{
// Assume TIFF_VARIABLE
dir.tdir_count=wc=__GetAsUint(ap, 0);
uint[] lp=ap[1] as uint[];
if(lp==null) return false;
if(!TIFFWriteLongArray(tif, dir, lp)) return false;
}
else
{
if(wc==1)
{
// XXX handle LONG=>SHORT conversion
dir.tdir_offset=__GetAsUint(ap, 0);
}
else
{
uint[] lp=ap[0] as uint[];
if(lp==null) return false;
if(!TIFFWriteLongArray(tif, dir, lp)) return false;
}
}
}
break;
case TIFFDataType.TIFF_RATIONAL:
case TIFFDataType.TIFF_SRATIONAL:
{
object[] ap=new object[2];
TIFFGetField(tif, fip.field_tag, ap);
if(fip.field_passcount)
{
// Assume TIFF_VARIABLE
dir.tdir_count=wc=__GetAsUint(ap, 0);
double[] fp=ap[1] as double[];
if(fp==null) return false;
if(!TIFFWriteRationalArray(tif, dir, fp)) return false;
}
else
{
if(wc==1)
{
double fv=__GetAsDouble(ap, 0);
if(!TIFFWriteRational(tif, fip.field_type, fip.field_tag, dir, fv)) return false;
}
else
{
double[] fp=ap[0] as double[];
if(fp==null) return false;
if(!TIFFWriteRationalArray(tif, dir, fp)) return false;
}
}
}
break;
case TIFFDataType.TIFF_FLOAT:
{
object[] ap=new object[2];
TIFFGetField(tif, fip.field_tag, ap);
if(fip.field_passcount)
{
// Assume TIFF_VARIABLE
dir.tdir_count=wc=__GetAsUint(ap, 0);
float[] fp=ap[1] as float[];
if(fp==null) return false;
if(!TIFFWriteFloatArray(tif, dir, fp)) return false;
}
else
{
if(wc==1)
{
float[] fv=new float[1];
fv[0]=__GetAsFloat(ap, 0);
if(!TIFFWriteFloatArray(tif, dir, fv)) return false;
}
else
{
float[] fp=ap[0] as float[];
if(fp==null) return false;
if(!TIFFWriteFloatArray(tif, dir, fp)) return false;
}
}
}
break;
case TIFFDataType.TIFF_DOUBLE:
{
object[] ap=new object[2];
TIFFGetField(tif, fip.field_tag, ap);
if(fip.field_passcount)
{
// Assume TIFF_VARIABLE
dir.tdir_count=wc=__GetAsUint(ap, 0);
double[] dp=ap[1] as double[];
if(dp==null) return false;
if(!TIFFWriteDoubleArray(tif, dir, dp)) return false;
}
else
{
if(wc==1)
{
double[] dv=new double[1];
dv[0]=__GetAsDouble(ap, 0);
if(!TIFFWriteDoubleArray(tif, dir, dv)) return false;
}
else
{
double[] dp=ap[0] as double[];
if(dp==null) return false;
if(!TIFFWriteDoubleArray(tif, dir, dp)) return false;
}
}
}
break;
case TIFFDataType.TIFF_ASCII:
{
object[] ap=new object[2];
TIFFGetField(tif, fip.field_tag, ap);
string cp;
if(fip.field_passcount)
{
// Assume TIFF_VARIABLE
wc=__GetAsUint(ap, 0);
cp=ap[1] as string;
if(cp==null) return false;
}
else
{
cp=ap[0] as string;
if(cp==null) return false;
}
cp=cp.TrimEnd('\0');
cp+='\0';
dir.tdir_count=(uint)cp.Length;
if(!TIFFWriteByteArray(tif, dir, Encoding.ASCII.GetBytes(cp))) return false;
}
break;
case TIFFDataType.TIFF_BYTE:
{
object[] ap=new object[2];
TIFFGetField(tif, fip.field_tag, ap);
if(fip.field_passcount)
{
// Assume TIFF_VARIABLE
dir.tdir_count=wc=__GetAsUint(ap, 0);
byte[] cp=ap[1] as byte[];
if(cp==null) return false;
if(!TIFFWriteByteArray(tif, dir, cp)) return false;
}
else
{
if(wc==1)
{
byte[] cv=new byte[1];
cv[0]=__GetAsByte(ap, 0);
if(!TIFFWriteByteArray(tif, dir, cv)) return false;
}
else
{
byte[] cp=ap[0] as byte[];
if(cp==null) return false;
if(!TIFFWriteByteArray(tif, dir, cp)) return false;
}
}
}
break;
case TIFFDataType.TIFF_SBYTE:
{
object[] ap=new object[2];
TIFFGetField(tif, fip.field_tag, ap);
if(fip.field_passcount)
{
// Assume TIFF_VARIABLE
dir.tdir_count=wc=__GetAsUint(ap, 0);
sbyte[] cp=ap[1] as sbyte[];
if(cp==null) return false;
if(!TIFFWriteByteArray(tif, dir, cp)) return false;
}
else
{
if(wc==1)
{
sbyte[] cv=new sbyte[1];
cv[0]=__GetAsSbyte(ap, 0);
if(!TIFFWriteByteArray(tif, dir, cv)) return false;
}
else
{
sbyte[] cp=ap[0] as sbyte[];
if(cp==null) return false;
if(!TIFFWriteByteArray(tif, dir, cp)) return false;
}
}
}
break;
case TIFFDataType.TIFF_UNDEFINED:
{
object[] ap=new object[2];
TIFFGetField(tif, fip.field_tag, ap);
byte[] cp;
if((int)wc==TIFF_VARIABLE)
{
// Assume TIFF_VARIABLE
dir.tdir_count=wc=__GetAsUint(ap, 0);
cp=ap[1] as byte[];
if(cp==null) return false;
}
else
{
cp=ap[0] as byte[];
if(cp==null) return false;
}
if(!TIFFWriteByteArray(tif, dir, cp)) return false;
}
break;
case TIFFDataType.TIFF_NOTYPE:
break;
}
return true;
}
// Fetch an array of BYTE values.
static bool TIFFFetchByteArray(TIFF tif, TIFFDirEntry dir, byte[] v)
{
if(dir.tdir_count<=4)
{
// Extract data from offset field.
if(tif.tif_header.tiff_magic==TIFF_BIGENDIAN)
{
switch(dir.tdir_count)
{
case 4: v[3]=(byte)(dir.tdir_offset&0xff); goto case 3;
case 3: v[2]=(byte)((dir.tdir_offset>>8)&0xff); goto case 2;
case 2: v[1]=(byte)((dir.tdir_offset>>16)&0xff); goto case 1;
case 1: v[0]=(byte)(dir.tdir_offset>>24); break;
}
}
else
{
switch(dir.tdir_count)
{
case 4: v[3]=(byte)(dir.tdir_offset>>24); goto case 3;
case 3: v[2]=(byte)((dir.tdir_offset>>16)&0xff); goto case 2;
case 2: v[1]=(byte)((dir.tdir_offset>>8)&0xff); goto case 1;
case 1: v[0]=(byte)(dir.tdir_offset&0xff); break;
}
}
return true;
}
return TIFFFetchData(tif, dir, v)!=0;
}
static bool TIFFWriteInkNames(TIFF tif, TIFFDirEntry dir)
{
TIFFDirectory td=tif.tif_dir;
dir.tdir_tag=(ushort)TIFFTAG.INKNAMES;
dir.tdir_type=(ushort)TIFFDataType.TIFF_ASCII;
string cp=td.td_inknames;
cp=cp.TrimEnd('\0');
cp+='\0';
dir.tdir_count=(uint)cp.Length;
return TIFFWriteByteArray(tif, dir, Encoding.ASCII.GetBytes(cp));
}
// Setup a directory entry of an array of
// SLONG and write the associated indirect values.
static bool TIFFWriteLongArray(TIFF tif, TIFFDirEntry dir, int[] v)
{
if(dir.tdir_count==1)
{
dir.tdir_offset=(uint)v[0];
return true;
}
byte[] buf=new byte[dir.tdir_count*4];
for(int i=0; i<dir.tdir_count; i++) BitConverter.GetBytes(v[i]).CopyTo(buf, i*4);
return TIFFWriteData(tif, dir, buf);
}
static bool TIFFWriteFloatArray(TIFF tif, TIFFDirEntry dir, float[] v)
{
byte[] buf=new byte[dir.tdir_count*4];
for(int i=0; i<dir.tdir_count; i++) BitConverter.GetBytes(v[i]).CopyTo(buf, i*4);
if(dir.tdir_count==1)
{
dir.tdir_offset=((uint)buf[3]<<24)+((uint)buf[2]<<16)+((uint)buf[1]<<8)+(uint)buf[0];
return true;
}
return TIFFWriteData(tif, dir, buf);
}
static bool TIFFWriteDoubleArray(TIFF tif, TIFFDirEntry dir, double[] v)
{
byte[] buf=new byte[dir.tdir_count*8];
for(int i=0; i<dir.tdir_count; i++) BitConverter.GetBytes(v[i]).CopyTo(buf, i*8);
return TIFFWriteData(tif, dir, buf);
}
// Write a contiguous directory item.
static bool TIFFWriteData(TIFF tif, TIFFDirEntry dir, byte[] cp)
{
if((tif.tif_flags&TIF_FLAGS.TIFF_SWAB)!=0)
{
switch((TIFFDataType)dir.tdir_type)
{
case TIFFDataType.TIFF_SHORT:
case TIFFDataType.TIFF_SSHORT:
TIFFSwabArrayOfShort(cp, dir.tdir_count);
break;
case TIFFDataType.TIFF_LONG:
case TIFFDataType.TIFF_SLONG:
case TIFFDataType.TIFF_FLOAT:
TIFFSwabArrayOfLong(cp, dir.tdir_count);
break;
case TIFFDataType.TIFF_RATIONAL:
case TIFFDataType.TIFF_SRATIONAL:
TIFFSwabArrayOfLong(cp, 2*dir.tdir_count);
break;
case TIFFDataType.TIFF_DOUBLE:
TIFFSwabArrayOfDouble(cp, dir.tdir_count);
break;
}
}
dir.tdir_offset=tif.tif_dataoff;
int cc=(int)dir.tdir_count*TIFFDataWidth((TIFFDataType)dir.tdir_type);
if(SeekOK(tif, dir.tdir_offset)&&WriteOK(tif, cp, cc))
{
tif.tif_dataoff+=(uint)((cc+1)&~1);
return true;
}
TIFFErrorExt(tif.tif_clientdata, tif.tif_name, "Error writing data for field \"{0}\"", TIFFFieldWithTag(tif, (TIFFTAG)dir.tdir_tag).field_name);
return false;
}
// Fetch an array of SLONG values.
static bool TIFFFetchLongArray(TIFF tif, TIFFDirEntry dir, int[] v)
{
if(dir.tdir_count==1)
{
v[0]=(int)dir.tdir_offset;
return true;
}
byte[] buf=new byte[dir.tdir_count*4];
if(TIFFFetchData(tif, dir, buf)==0) return false;
for(int i=0; i<dir.tdir_count; i++) v[i]=BitConverter.ToInt32(buf, i*4);
return true;
}
// Fetch an array of SBYTE values.
static bool TIFFFetchByteArray(TIFF tif, TIFFDirEntry dir, sbyte[] v)
{
if(dir.tdir_count<=4)
{
// Extract data from offset field.
if(tif.tif_header.tiff_magic==TIFF_BIGENDIAN)
{
switch(dir.tdir_count)
{
case 4: v[3]=(sbyte)(dir.tdir_offset&0xff); goto case 3;
case 3: v[2]=(sbyte)((dir.tdir_offset>>8)&0xff); goto case 2;
case 2: v[1]=(sbyte)((dir.tdir_offset>>16)&0xff); goto case 1;
case 1: v[0]=(sbyte)(dir.tdir_offset>>24); break;
}
}
else
{
switch(dir.tdir_count)
{
case 4: v[3]=(sbyte)(dir.tdir_offset>>24); goto case 3;
case 3: v[2]=(sbyte)((dir.tdir_offset>>16)&0xff); goto case 2;
case 2: v[1]=(sbyte)((dir.tdir_offset>>8)&0xff); goto case 1;
case 1: v[0]=(sbyte)(dir.tdir_offset&0xff); break;
}
}
return true;
}
byte[] buf=new byte[dir.tdir_count];
if(TIFFFetchData(tif, dir, buf)==0) return false;
for(int i=0; i<dir.tdir_count; i++) v[i]=(sbyte)buf[i];
return true;
}
// Fetch a tag that is not handled by special case code.
static bool TIFFFetchNormalTag(TIFF tif, TIFFDirEntry dp)
{
bool ok=false;
TIFFFieldInfo fip=TIFFFieldWithTag(tif, (TIFFTAG)dp.tdir_tag);
if(dp.tdir_count>1)
{
// array of values
object cp=null;
try
{
switch((TIFFDataType)dp.tdir_type)
{
case TIFFDataType.TIFF_UNDEFINED:
case TIFFDataType.TIFF_BYTE:
cp=new byte[dp.tdir_count];
ok=TIFFFetchByteArray(tif, dp, (byte[])cp);
break;
case TIFFDataType.TIFF_SBYTE:
cp=new sbyte[dp.tdir_count];
ok=TIFFFetchByteArray(tif, dp, (sbyte[])cp);
break;
case TIFFDataType.TIFF_SHORT:
cp=new ushort[dp.tdir_count];
ok=TIFFFetchShortArray(tif, dp, (ushort[])cp);
break;
case TIFFDataType.TIFF_SSHORT:
cp=new short[dp.tdir_count];
ok=TIFFFetchShortArray(tif, dp, (short[])cp);
break;
case TIFFDataType.TIFF_LONG:
cp=new uint[dp.tdir_count];
ok=TIFFFetchLongArray(tif, dp, (uint[])cp);
break;
case TIFFDataType.TIFF_SLONG:
cp=new int[dp.tdir_count];
ok=TIFFFetchLongArray(tif, dp, (int[])cp);
break;
case TIFFDataType.TIFF_RATIONAL:
case TIFFDataType.TIFF_SRATIONAL:
cp=new double[dp.tdir_count];
ok=TIFFFetchRationalArray(tif, dp, (double[])cp);
break;
case TIFFDataType.TIFF_FLOAT:
cp=new float[dp.tdir_count];
ok=TIFFFetchFloatArray(tif, dp, (float[])cp);
break;
case TIFFDataType.TIFF_DOUBLE:
cp=new double[dp.tdir_count];
ok=TIFFFetchDoubleArray(tif, dp, (double[])cp);
break;
case TIFFDataType.TIFF_ASCII:
// Some vendors write strings w/o the trailing
// NIL byte, so always append one just in case.
string str;
ok=TIFFFetchString(tif, dp, out str)!=0;
if(ok)
{
str=str.TrimEnd('\0');
str+='\0'; // XXX paranoid
cp=str;
}
break;
}
}
catch
{
TIFFErrorExt(tif.tif_clientdata, tif.tif_name, "No space to fetch tag value");
}
if(ok)
{
if(fip.field_passcount) ok=TIFFSetField(tif, (TIFFTAG)dp.tdir_tag, (TIFFDataType)dp.tdir_type, dp.tdir_count, cp);
else
{
//if(cp is Array)
//{
// Array arr=cp as Array;
// object[] ap=new object[arr.Length];
// int i=0;
// foreach(object a in arr) ap[i++]=a;
// ok=TIFFSetField(tif, (TIFFTAG)dp.tdir_tag, (TIFFDataType)dp.tdir_type, ap);
//}
//else
ok=TIFFSetField(tif, (TIFFTAG)dp.tdir_tag, (TIFFDataType)dp.tdir_type, cp);
}
}
}
else if(CheckDirCount(tif, dp, 1))
{ // singleton value
switch((TIFFDataType)dp.tdir_type)
{
case TIFFDataType.TIFF_UNDEFINED:
case TIFFDataType.TIFF_BYTE:
case TIFFDataType.TIFF_SBYTE:
case TIFFDataType.TIFF_SHORT:
case TIFFDataType.TIFF_SSHORT:
// If the tag is also acceptable as a LONG or SLONG
// then TIFFSetField will expect an uint parameter
// passed to it.
//
// NB: We used TIFFFieldWithTag here (see above) knowing that
// it returns us the first entry in the table
// for the tag and that that entry is for the
// widest potential data type the tag may have.
TIFFDataType type=fip.field_type;
if(type!=TIFFDataType.TIFF_LONG&&type!=TIFFDataType.TIFF_SLONG)
{
ushort v=(ushort)((tif.tif_header.tiff_magic==TIFF_BIGENDIAN)?(dp.tdir_offset>>tif_typeshift[dp.tdir_type])&tif_typemask[dp.tdir_type]:dp.tdir_offset&tif_typemask[dp.tdir_type]);
ok=(fip.field_passcount?TIFFSetField(tif, (TIFFTAG)dp.tdir_tag, (TIFFDataType)dp.tdir_type, 1, v):TIFFSetField(tif, (TIFFTAG)dp.tdir_tag, (TIFFDataType)dp.tdir_type, v));
break;
}
goto case TIFFDataType.TIFF_LONG; // fall thru...
case TIFFDataType.TIFF_LONG:
case TIFFDataType.TIFF_SLONG:
{
uint v32=(uint)((tif.tif_header.tiff_magic==TIFF_BIGENDIAN)?(dp.tdir_offset>>tif_typeshift[dp.tdir_type])&tif_typemask[dp.tdir_type]:dp.tdir_offset&tif_typemask[dp.tdir_type]);
ok=(fip.field_passcount?TIFFSetField(tif, (TIFFTAG)dp.tdir_tag, (TIFFDataType)dp.tdir_type, 1, v32):TIFFSetField(tif, (TIFFTAG)dp.tdir_tag, (TIFFDataType)dp.tdir_type, v32));
}
break;
case TIFFDataType.TIFF_RATIONAL:
case TIFFDataType.TIFF_SRATIONAL:
{
double v=TIFFFetchRational(tif, dp);
ok=(fip.field_passcount?TIFFSetField(tif, (TIFFTAG)dp.tdir_tag, (TIFFDataType)dp.tdir_type, 1, v):TIFFSetField(tif, (TIFFTAG)dp.tdir_tag, (TIFFDataType)dp.tdir_type, v));
}
break;
case TIFFDataType.TIFF_FLOAT:
{
float v=TIFFFetchFloat(tif, dp);
ok=(fip.field_passcount?TIFFSetField(tif, (TIFFTAG)dp.tdir_tag, (TIFFDataType)dp.tdir_type, 1, v):TIFFSetField(tif, (TIFFTAG)dp.tdir_tag, (TIFFDataType)dp.tdir_type, v));
}
break;
case TIFFDataType.TIFF_DOUBLE:
{
double v=TIFFFetchDouble(tif, dp);
ok=(fip.field_passcount?TIFFSetField(tif, (TIFFTAG)dp.tdir_tag, (TIFFDataType)dp.tdir_type, 1, v):TIFFSetField(tif, (TIFFTAG)dp.tdir_tag, (TIFFDataType)dp.tdir_type, v));
}
break;
case TIFFDataType.TIFF_ASCII:
{
string str;
ok=TIFFFetchString(tif, dp, out str)!=0;
if(ok)
{
str=str.TrimEnd('\0');
str+='\0'; // XXX paranoid
ok=(fip.field_passcount?TIFFSetField(tif, (TIFFTAG)dp.tdir_tag, (TIFFDataType)dp.tdir_type, 1, str):TIFFSetField(tif, (TIFFTAG)dp.tdir_tag, (TIFFDataType)dp.tdir_type, str));
}
}
break;
}
}
return ok;
}
// Fetch a contiguous directory item.
static int TIFFFetchData(TIFF tif, TIFFDirEntry dir, byte[] cp)
{
uint w=(uint)TIFFDataWidth((TIFFDataType)dir.tdir_type);
// FIXME: butecount should have tsize_t type, but for now libtiff
// defines tsize_t as a signed 32-bit integer and we are losing
// ability to read arrays larger than 2^31 bytes. So we are using
// uint32 instead of tsize_t here.
uint cc=dir.tdir_count*w;
// Check for overflow.
if(dir.tdir_count==0||w==0||cc/w!=dir.tdir_count)
{
TIFFErrorExt(tif.tif_clientdata, tif.tif_name, "Error fetching data for field \"{0}\"", TIFFFieldWithTag(tif, (TIFFTAG)dir.tdir_tag).field_name);
return 0;
}
if(!SeekOK(tif, dir.tdir_offset))
{
TIFFErrorExt(tif.tif_clientdata, tif.tif_name, "Error fetching data for field \"{0}\"", TIFFFieldWithTag(tif, (TIFFTAG)dir.tdir_tag).field_name);
return 0;
}
if(!ReadOK(tif, cp, (int)cc))
{
TIFFErrorExt(tif.tif_clientdata, tif.tif_name, "Error fetching data for field \"{0}\"", TIFFFieldWithTag(tif, (TIFFTAG)dir.tdir_tag).field_name);
return 0;
}
if((tif.tif_flags&TIF_FLAGS.TIFF_SWAB)==0) return (int)cc;
switch((TIFFDataType)dir.tdir_type)
{
case TIFFDataType.TIFF_SHORT:
case TIFFDataType.TIFF_SSHORT:
TIFFSwabArrayOfShort(cp, dir.tdir_count);
break;
case TIFFDataType.TIFF_LONG:
case TIFFDataType.TIFF_SLONG:
case TIFFDataType.TIFF_FLOAT:
TIFFSwabArrayOfLong(cp, dir.tdir_count);
break;
case TIFFDataType.TIFF_RATIONAL:
case TIFFDataType.TIFF_SRATIONAL:
TIFFSwabArrayOfLong(cp, 2*dir.tdir_count);
break;
case TIFFDataType.TIFF_DOUBLE:
TIFFSwabArrayOfDouble(cp, dir.tdir_count);
break;
}
return (int)cc;
}
// Fetch a rational item from the file
// at offset off and return the value
// as a floating point number.
static double TIFFFetchRational(TIFF tif, TIFFDirEntry dir)
{
byte[] buf=new byte[8];
if(TIFFFetchData(tif, dir, buf)==0) return 1.0;
double v;
return !cvtRational(tif, dir, BitConverter.ToUInt32(buf, 0), BitConverter.ToUInt32(buf, 4), out v)?1.0:v;
}
static int TIFFFetchData(TIFF tif, TIFFDirEntry dir, ushort[] cp)
{
byte[] buf=new byte[dir.tdir_count*2];
int ret=TIFFFetchData(tif, dir, buf);
if(ret==0) return 0;
for(int i=0; i<dir.tdir_count; i++) cp[i]=BitConverter.ToUInt16(buf, i*2);
return ret;
}
// Fetch and set the RefBlackWhite tag.
static bool TIFFFetchRefBlackWhite(TIFF tif, TIFFDirEntry dir)
{
if(dir.tdir_type==(ushort)TIFFDataType.TIFF_RATIONAL) return TIFFFetchNormalTag(tif, dir);
// Handle LONG's for backward compatibility.
uint[] cp=null;
double[] fp=null;
try
{
cp=new uint[dir.tdir_count];
fp=new double[dir.tdir_count];
}
catch
{
TIFFErrorExt(tif.tif_clientdata, tif.tif_name, "No space for \"ReferenceBlackWhite\" array");
return false;
}
if(!TIFFFetchLongArray(tif, dir, cp)) return false;
for(int i=0; i<dir.tdir_count; i++) fp[i]=cp[i];
if(!TIFFSetField(tif, (TIFFTAG)dir.tdir_tag, (TIFFDataType)dir.tdir_type, fp)) return false;
return true;
}
// Fetch a double item from the file
// at offset off and return the value.
static double TIFFFetchDouble(TIFF tif, TIFFDirEntry dir)
{
byte[] buf=new byte[8];
if(TIFFFetchData(tif, dir, buf)==0) return 1.0;
return BitConverter.ToDouble(buf, 0);
}
// Fetch a pair of SHORT or BYTE values. Some tags may have either BYTE
// or SHORT type and this function works with both ones.
static bool TIFFFetchShortPair(TIFF tif, TIFFDirEntry dir)
{
// Prevent overflowing the v stack arrays below by performing a sanity
// check on tdir_count, this should never be greater than two.
if(dir.tdir_count>2)
{
TIFFWarningExt(tif.tif_clientdata, tif.tif_name, "unexpected count for field \"{0}\", {1}, expected 2; ignored", TIFFFieldWithTag(tif, (TIFFTAG)dir.tdir_tag).field_name, dir.tdir_count);
return false;
}
switch((TIFFDataType)dir.tdir_type)
{
case TIFFDataType.TIFF_BYTE:
{
byte[] v=new byte[4];
return TIFFFetchByteArray(tif, dir, v)&&TIFFSetField(tif, (TIFFTAG)dir.tdir_tag, (TIFFDataType)dir.tdir_type, v[0], v[1]);
}
case TIFFDataType.TIFF_SBYTE:
{
sbyte[] v=new sbyte[4];
return TIFFFetchByteArray(tif, dir, v)&&TIFFSetField(tif, (TIFFTAG)dir.tdir_tag, (TIFFDataType)dir.tdir_type, v[0], v[1]);
}
case TIFFDataType.TIFF_SHORT:
{
ushort[] v=new ushort[2];
return TIFFFetchShortArray(tif, dir, v)&&TIFFSetField(tif, (TIFFTAG)dir.tdir_tag, (TIFFDataType)dir.tdir_type, v[0], v[1]);
}
case TIFFDataType.TIFF_SSHORT:
{
short[] v=new short[2];
return TIFFFetchShortArray(tif, dir, v)&&TIFFSetField(tif, (TIFFTAG)dir.tdir_tag, (TIFFDataType)dir.tdir_type, v[0], v[1]);
}
default: return false;
}
}
// Fetch an array of DOUBLE values.
static bool TIFFFetchDoubleArray(TIFF tif, TIFFDirEntry dir, double[] v)
{
byte[] buf=new byte[dir.tdir_count*8];
if(TIFFFetchData(tif, dir, buf)==0) return false;
for(int i=0; i<dir.tdir_count; i++) v[i]=BitConverter.ToDouble(buf, i*8);
return true;
}
// Fetch a set of offsets or lengths.
// While this routine says "strips", in fact it's also used for tiles.
static bool TIFFFetchStripThing(TIFF tif, TIFFDirEntry dir, uint nstrips, ref uint[] lp)
{
if(!CheckDirCount(tif, dir, nstrips)) return false;
// Allocate space for strip information.
if(lp==null)
{
try
{
lp=new uint[nstrips];
}
catch
{
TIFFErrorExt(tif.tif_clientdata, tif.tif_name, "No space for strip array");
return false;
}
}
else for(int i=0; i<nstrips; i++) lp[i]=0;
if(dir.tdir_type==(ushort)TIFFDataType.TIFF_SHORT)
{
// Handle uint16=>uint32 expansion.
ushort[] dp=null;
try
{
dp=new ushort[dir.tdir_count];
}
catch
{
TIFFErrorExt(tif.tif_clientdata, tif.tif_name, "No space to fetch strip tag");
return false;
}
if(TIFFFetchShortArray(tif, dir, dp))
{
for(int i=0; i<nstrips&&i<(int)dir.tdir_count; i++) lp[i]=dp[i];
}
return true;
}
if(nstrips!=(int)dir.tdir_count)
{
// Special case to incorrect length
uint[] dp=null;
try
{
dp=new uint[dir.tdir_count];
}
catch
{
TIFFErrorExt(tif.tif_clientdata, tif.tif_name, "No space to fetch strip tag");
return false;
}
if(TIFFFetchLongArray(tif, dir, dp))
{
for(int i=0; i<nstrips&&i<(int)dir.tdir_count; i++) lp[i]=dp[i];
}
}
return TIFFFetchLongArray(tif, dir, lp);
}
// Fetch a single floating point value
// from the offset field and return it
// as a native float.
static float TIFFFetchFloat(TIFF tif, TIFFDirEntry dir)
{
return BitConverter.ToSingle(BitConverter.GetBytes(dir.tdir_offset), 0);
}
// Check the count field of a directory
// entry against a known value. The caller
// is expected to skip/ignore the tag if
// there is a mismatch.
static bool CheckDirCount(TIFF tif, TIFFDirEntry dir, uint count)
{
if(count>dir.tdir_count)
{
TIFFWarningExt(tif.tif_clientdata, tif.tif_name, "incorrect count for field \"{0}\" ({1}, expecting {2}); tag ignored", TIFFFieldWithTag(tif, (TIFFTAG)dir.tdir_tag).field_name, dir.tdir_count, count);
return false;
}
if(count<dir.tdir_count)
{
TIFFWarningExt(tif.tif_clientdata, tif.tif_name, "incorrect count for field \"{0}\" ({1}, expecting {2}); tag trimmed", TIFFFieldWithTag(tif, (TIFFTAG)dir.tdir_tag).field_name, dir.tdir_count, count);
return true;
}
return true;
}
// Fetch an array of FLOAT values.
static bool TIFFFetchFloatArray(TIFF tif, TIFFDirEntry dir, float[] v)
{
if(dir.tdir_count==1)
{
v[0]=BitConverter.ToSingle(BitConverter.GetBytes(dir.tdir_offset), 0);
return true;
}
byte[] buf=new byte[dir.tdir_count*4];
if(TIFFFetchData(tif, dir, buf)==0) return false;
for(int i=0; i<dir.tdir_count; i++) v[i]=BitConverter.ToSingle(buf, i*4);
return true;
}
// Fetch an array of ANY values. The actual values are
// returned as doubles which should be able hold all the
// types. Yes, there really should be an tany_t to avoid
// this potential non-portability ... Note in particular
// that we assume that the double return value vector is
// large enough to read in any fundamental type. We use
// that vector as a buffer to read in the base type vector
// and then convert it in place to double (from end
// to front of course).
static bool TIFFFetchAnyArray(TIFF tif, TIFFDirEntry dir, double[] v)
{
switch((TIFFDataType)dir.tdir_type)
{
case TIFFDataType.TIFF_BYTE:
{
byte[] buf=new byte[dir.tdir_count];
if(!TIFFFetchByteArray(tif, dir, buf)) return false;
for(int i=0; i<dir.tdir_count; i++) v[i]=buf[i];
}
break;
case TIFFDataType.TIFF_SBYTE:
{
sbyte[] buf=new sbyte[dir.tdir_count];
if(!TIFFFetchByteArray(tif, dir, buf)) return false;
for(int i=0; i<dir.tdir_count; i++) v[i]=buf[i];
}
break;
case TIFFDataType.TIFF_SHORT:
{
ushort[] buf=new ushort[dir.tdir_count];
if(!TIFFFetchShortArray(tif, dir, buf)) return false;
for(int i=0; i<dir.tdir_count; i++) v[i]=buf[i];
}
break;
case TIFFDataType.TIFF_SSHORT:
{
short[] buf=new short[dir.tdir_count];
if(!TIFFFetchShortArray(tif, dir, buf)) return false;
for(int i=0; i<dir.tdir_count; i++) v[i]=buf[i];
}
break;
case TIFFDataType.TIFF_LONG:
{
uint[] buf=new uint[dir.tdir_count];
if(!TIFFFetchLongArray(tif, dir, buf)) return false;
for(int i=0; i<dir.tdir_count; i++) v[i]=buf[i];
}
break;
case TIFFDataType.TIFF_SLONG:
{
int[] buf=new int[dir.tdir_count];
if(!TIFFFetchLongArray(tif, dir, buf)) return false;
for(int i=0; i<dir.tdir_count; i++) v[i]=buf[i];
}
break;
case TIFFDataType.TIFF_RATIONAL:
case TIFFDataType.TIFF_SRATIONAL:
return TIFFFetchRationalArray(tif, dir, v);
case TIFFDataType.TIFF_FLOAT:
{
float[] buf=new float[dir.tdir_count];
if(!TIFFFetchFloatArray(tif, dir, buf)) return false;
for(int i=0; i<dir.tdir_count; i++) v[i]=buf[i];
}
break;
case TIFFDataType.TIFF_DOUBLE:
return TIFFFetchDoubleArray(tif, dir, v);
default:
// TIFF_NOTYPE
// TIFF_ASCII
// TIFF_UNDEFINED
TIFFErrorExt(tif.tif_clientdata, tif.tif_name, "cannot read TIFF_ANY type {0} for field \"{1}\"", dir.tdir_type, TIFFFieldWithTag(tif, (TIFFTAG)dir.tdir_tag).field_name);
return false;
}
return true;
}
// Write/copy data associated with an ASCII or opaque tag value.
static bool TIFFWriteByteArray(TIFF tif, TIFFDirEntry dir, byte[] cp)
{
if(dir.tdir_count<=4)
{
//was _TIFFmemcpy(&dir.tdir_offset, cp, dir.tdir_count);
dir.tdir_offset=0;
if(tif.tif_header.tiff_magic==TIFF_BIGENDIAN)
{
dir.tdir_offset=(uint)cp[0]<<24;
if(dir.tdir_count>=2) dir.tdir_offset|=(uint)cp[1]<<16;
if(dir.tdir_count>=3) dir.tdir_offset|=(uint)cp[2]<<8;
if(dir.tdir_count==4) dir.tdir_offset|=cp[3];
}
else
{
switch(dir.tdir_count)
{
case 4: dir.tdir_offset=cp[3]; dir.tdir_offset<<=8; goto case 3;
case 3: dir.tdir_offset+=cp[2]; dir.tdir_offset<<=8; goto case 2;
case 2: dir.tdir_offset+=cp[1]; dir.tdir_offset<<=8; goto case 1;
case 1: dir.tdir_offset+=cp[0]; break;
}
}
return true;
}
return TIFFWriteData(tif, dir, cp);
}
