}
gdcmHeader::gdcmHeader (const char* InFilename) {
+ SetMaxSizeLoadElementValue(1024);
filename = InFilename;
Initialise();
fp=fopen(InFilename,"rw");
return;
}
VRHT *vr = new VRHT;
- (*vr)["AE"] = "Application Entity"; // 16 car max
- (*vr)["AS"] = "Age String"; // 4 car fixe
- (*vr)["AT"] = "Attribute Tag"; // 2 unsigned short int
- (*vr)["CS"] = "Code String"; // 16 car max
- (*vr)["DA"] = "Date"; // 8 car fixe
- (*vr)["DS"] = "Decimal String"; // Decimal codé Binaire 16 max
- (*vr)["DT"] = "Date Time"; // 26 car max
- (*vr)["FL"] = "Floating Point Single"; // 4 octets IEEE 754:1985
- (*vr)["FD"] = "Floating Point Double"; // 8 octets IEEE 754:1985
- (*vr)["IS"] = "Integer String"; // en format externe 12 max
- (*vr)["LO"] = "Long String"; // 64 octets max
- (*vr)["LT"] = "Long Text"; // 10240 max
- (*vr)["OB"] = "Other Byte String";
- (*vr)["OW"] = "Other Word String";
- (*vr)["PN"] = "Person Name";
- (*vr)["SH"] = "Short String"; // 16 car max
- (*vr)["SL"] = "Signed Long";
+ (*vr)["AE"] = "Application Entity"; // At most 16 bytes
+ (*vr)["AS"] = "Age String"; // Exactly 4 bytes
+ (*vr)["AT"] = "Attribute Tag"; // 2 16-bit unsigned short integers
+ (*vr)["CS"] = "Code String"; // At most 16 bytes
+ (*vr)["DA"] = "Date"; // Exactly 8 bytes
+ (*vr)["DS"] = "Decimal String"; // At most 16 bytes
+ (*vr)["DT"] = "Date Time"; // At most 26 bytes
+ (*vr)["FL"] = "Floating Point Single"; // 32-bit IEEE 754:1985 float
+ (*vr)["FD"] = "Floating Point Double"; // 64-bit IEEE 754:1985 double
+ (*vr)["IS"] = "Integer String"; // At most 12 bytes
+ (*vr)["LO"] = "Long String"; // At most 64 chars
+ (*vr)["LT"] = "Long Text"; // At most 10240 chars
+ (*vr)["OB"] = "Other Byte String"; // String of bytes (vr independant)
+ (*vr)["OW"] = "Other Word String"; // String of 16-bit words (vr dep)
+ (*vr)["PN"] = "Person Name"; // At most 64 chars
+ (*vr)["SH"] = "Short String"; // At most 16 chars
+ (*vr)["SL"] = "Signed Long"; // Exactly 4 bytes
(*vr)["SQ"] = "Sequence of Items"; // Not Applicable
- (*vr)["SS"] = "Signed Short"; // 2 octets
- (*vr)["ST"] = "Short Text"; // 1024 car max
- (*vr)["TM"] = "Time"; // 16 car max
- (*vr)["UI"] = "Unique Identifier"; // 64 car max
- (*vr)["UN"] = "Unknown";
- (*vr)["UT"] = "Unlimited Text"; // 2 puissance 32 -1 car max
- (*vr)["UL"] = "Unsigned Long "; // 4 octets fixe
- (*vr)["US"] = "Unsigned Short "; // 2 octets fixe
+ (*vr)["SS"] = "Signed Short"; // Exactly 2 bytes
+ (*vr)["ST"] = "Short Text"; // At most 1024 chars
+ (*vr)["TM"] = "Time"; // At most 16 bytes
+ (*vr)["UI"] = "Unique Identifier"; // At most 64 bytes
+ (*vr)["UL"] = "Unsigned Long "; // Exactly 4 bytes
+ (*vr)["UN"] = "Unknown"; // Any length of bytes
+ (*vr)["US"] = "Unsigned Short "; // Exactly 2 bytes
+ (*vr)["UT"] = "Unlimited Text"; // At most 2^32 -1 chars
dicom_vr = vr;
}
switch (s) {
case 0x00040000 :
- sw=3412;
+ sw = 3412;
filetype = ACR;
return;
case 0x04000000 :
- sw=4321;
+ sw = 4321;
filetype = ACR;
return;
case 0x00000400 :
- sw=2143;
+ sw = 2143;
filetype = ACR;
return;
case 0x00000004 :
- sw=0;
+ sw = 0;
filetype = ACR;
return;
default :
// We are out of luck. It is not a DicomV3 nor a 'clean' ACR/NEMA file.
// It is time for despaired wild guesses. So, let's assume this file
- // happens to be 'dirty' ACR/NEMA, i.e. the length of the group it
+ // happens to be 'dirty' ACR/NEMA, i.e. the length of the group is
// not present. Then the only info we have is the net2host one.
//FIXME Si c'est du RAW, ca degagera + tard
return;
}
+void gdcmHeader::SwitchSwapToBigEndian(void) {
+ dbg.Verbose(1, "gdcmHeader::FindLength", "Switching to BigEndian mode.");
+ if ( sw == 0 ) {
+ sw = 4321;
+ return;
+ }
+ if ( sw == 4321 ) {
+ sw = 0;
+ return;
+ }
+ if ( sw == 3412 ) {
+ sw = 2143;
+ return;
+ }
+ if ( sw == 2143 )
+ sw = 3412;
+}
+
/**
* \ingroup gdcmHeader
* \brief recupere la longueur d'un champ DICOM.
ElVal->SetImplicitVr();
}
+/**
+ * \ingroup gdcmHeader
+ * \brief Determines if the Transfer Syntax was allready encountered
+ * and if it corresponds to a Big Endian one.
+ *
+ * @return True when big endian found. False in all other cases.
+ */
+bool gdcmHeader::IsBigEndianTransferSyntax(void) {
+ ElValue* Element = PubElVals.GetElement(0x0002, 0x0010);
+ if ( !Element )
+ return false;
+ LoadElementValueSafe(Element);
+ string Transfer = Element->GetValue();
+ if ( Transfer == "1.2.840.10008.1.2.2" )
+ return true;
+ return false;
+}
+
+void gdcmHeader::FixFoundLength(ElValue * ElVal, guint32 FoudLength) {
+ // Heuristic: a final fix.
+ if ( FoudLength == 0xffffffff)
+ FoudLength = 0;
+ ElVal->SetLength(FoudLength);
+}
+
void gdcmHeader::FindLength( ElValue * ElVal) {
- guint32 length32;
+ guint16 element = ElVal->GetElement();
+ string vr = ElVal->GetVR();
guint16 length16;
- string vr = ElVal->GetVR();
if ( (filetype == ExplicitVR) && ! ElVal->IsImplicitVr() ) {
+
if ( (vr=="OB") || (vr=="OW") || (vr=="SQ") || (vr=="UN") ) {
-
- // The following two bytes are reserved, so we skip them,
- // and we proceed on reading the length on 4 bytes.
- fseek(fp, 2L,SEEK_CUR);
- length32 = ReadInt32();
-
- } else {
- // Length is encoded on 2 bytes.
- length16 = ReadInt16();
-
- if ( length16 == 0xffff) {
- length32 = 0;
- } else {
- length32 = length16;
+ // The following reserved two bytes (see PS 3.5-2001, section
+ // 7.1.2 Data element structure with explicit vr p27) must be
+ // skipped before proceeding on reading the length on 4 bytes.
+ fseek(fp, 2L, SEEK_CUR);
+ FixFoundLength(ElVal, ReadInt32());
+ return;
+ }
+
+ // Length is encoded on 2 bytes.
+ length16 = ReadInt16();
+
+ // We can tell the current file is encoded in big endian (like
+ // Data/US-RGB-8-epicard) when we find the "Transfer Syntax" tag
+ // and it's value is the one of the encoding of a bie endian file.
+ // In order to deal with such big endian encoded files, we have
+ // (at least) two strategies:
+ // * when we load the "Transfer Syntax" tag with value of big endian
+ // encoding, we raise the proper flags. Then we wait for the end
+ // of the META group (0x0002) among which is "Transfer Syntax",
+ // before switching the swap code to big endian. We have to postpone
+ // the switching of the swap code since the META group is fully encoded
+ // in little endian, and big endian coding only starts at the next
+ // group. The corresponding code can be hard to analyse and adds
+ // many additional unnecessary tests for regular tags.
+ // * the second strategy consist to wait for trouble, that shall appear
+ // when we find the first group with big endian encoding. This is
+ // easy to detect since the length of a "Group Length" tag (the
+ // ones with zero as element number) has to be of 4 (0x0004). When we
+ // encouter 1024 (0x0400) chances are the encoding changed and we
+ // found a group with big endian encoding.
+ // We shall use this second strategy. In order make sure that we
+ // can interpret the presence of an apparently big endian encoded
+ // length of a "Group Length" without committing a big mistake, we
+ // add an additional check: we look in the allready parsed elements
+ // for the presence of a "Transfer Syntax" whose value has to be "big
+ // endian encoding". When this is the case, chances are we got our
+ // hands on a big endian encoded file: we switch the swap code to
+ // big endian and proceed...
+ if ( (element == 0) && (length16 == 1024) ) {
+ if ( ! IsBigEndianTransferSyntax() )
+ throw Error::FileReadError(fp, "gdcmHeader::FindLength");
+ length16 = 4;
+ SwitchSwapToBigEndian();
+ // Restore the unproperly loaded values i.e. the group, the element
+ // and the dictionary entry depending on them.
+ guint16 CorrectGroup = SwapShort(ElVal->GetGroup());
+ guint16 CorrectElem = SwapShort(ElVal->GetElement());
+ gdcmDictEntry * NewTag = IsInDicts(CorrectGroup, CorrectElem);
+ if (!NewTag) {
+ // This correct tag is not in the dictionary. Create a new one.
+ NewTag = new gdcmDictEntry(CorrectGroup, CorrectElem);
}
+ // FIXME this can create a memory leaks on the old entry that be
+ // left unreferenced.
+ ElVal->SetDictEntry(NewTag);
}
- } else {
- // Either implicit VR or an explicit VR that (at least for this
- // element) lied a little bit. Length is on 4 bytes.
- length32 = ReadInt32();
+
+ // Heuristic: well some files are really ill-formed.
+ if ( length16 == 0xffff) {
+ length16 = 0;
+ dbg.Verbose(0, "gdcmHeader::FindLength",
+ "Erroneous element length fixed.");
+ }
+ FixFoundLength(ElVal, (guint32)length16);
+ return;
}
-
- // Traitement des curiosites sur la longueur
- if ( length32 == 0xffffffff)
- length32=0;
-
- ElVal->SetLength(length32);
-}
+ // Either implicit VR or a non DICOM conformal (see not below) explicit
+ // VR that ommited the VR of (at least) this element. Farts happen.
+ // [Note: according to the part 5, PS 3.5-2001, section 7.1 p25
+ // on Data elements "Implicit and Explicit VR Data Elements shall
+ // not coexist in a Data Set and Data Sets nested within it".]
+ // Length is on 4 bytes.
+ FixFoundLength(ElVal, ReadInt32());
+}
/**
* \ingroup gdcmHeader
- * \brief remet les octets dans un ordre compatible avec celui du processeur
-
- * @return longueur retenue pour le champ
+ * \brief Swaps back the bytes of 4-byte long integer accordingly to
+ * processor order.
+ *
+ * @return The suggested integer.
*/
guint32 gdcmHeader::SwapLong(guint32 a) {
// FIXME: il pourrait y avoir un pb pour les entiers negatifs ...
/**
* \ingroup gdcmHeader
* \brief Swaps the bytes so they agree with the processor order
-
- * @return longueur retenue pour le champ
+ * @return The properly swaped 16 bits integer.
*/
guint16 gdcmHeader::SwapShort(guint16 a) {
- //FIXME how could sw be equal to 2143 since we never set it this way ?
if ( (sw==4321) || (sw==2143) )
a =(((a<<8) & 0x0ff00) | ((a>>8)&0x00ff));
return (a);
(void)fseek(fp, (long)ElVal->GetLength(), SEEK_CUR);
}
+void gdcmHeader::SetMaxSizeLoadElementValue(long NewSize) {
+ if (NewSize < 0)
+ return;
+ if ((guint32)NewSize >= (guint32)0xffffffff) {
+ MaxSizeLoadElementValue = 0xffffffff;
+ return;
+ }
+ MaxSizeLoadElementValue = NewSize;
+}
+
/**
* \ingroup gdcmHeader
* \brief Loads the element if it's size is not to big.
guint16 elem = ElVal->GetElement();
string vr = ElVal->GetVR();
guint32 length = ElVal->GetLength();
+ bool SkipLoad = false;
fseek(fp, (long)ElVal->GetOffset(), SEEK_SET);
// Sequences not treated yet !
- if( vr == "SQ" ) {
+ if( vr == "SQ" )
+ SkipLoad = true;
+
+ // Heuristic : a sequence "contains" a set of tags (called items). It looks
+ // like the last tag of a sequence (the one that terminates the sequence)
+ // has a group of 0xfffe (with a dummy length).
+ if( group == 0xfffe )
+ SkipLoad = true;
+
+ // The group length doesn't represent data to be loaded in memory, since
+ // each element of the group shall be loaded individualy.
+ if( elem == 0 )
+ SkipLoad = true;
+
+ if ( SkipLoad ) {
+ // FIXME the following skip is not necessary
SkipElementValue(ElVal);
ElVal->SetLength(0);
+ ElVal->SetValue("gdcm::Skipped");
return;
}
- // A sequence "contains" a set of tags (called items). It looks like
- // the last tag of a sequence (the one that terminates the sequence)
- // has a group of 0xfffe (with a dummy length).
- if( group == 0xfffe) {
- SkipElementValue(ElVal);
- ElVal->SetLength(0);
+
+ // When the length is zero things are easy:
+ if ( length == 0 ) {
+ ElVal->SetValue("");
+ return;
+ }
+
+ // Values bigger than specified are not loaded.
+ if (length > MaxSizeLoadElementValue) {
+ ostringstream s;
+ s << "gdcm::NotLoaded.";
+ s << " Address:" << (long)ElVal->GetOffset();
+ s << " Length:" << ElVal->GetLength();
+ //mesg += " Length:" + ElVal->GetLength();
+ ElVal->SetValue(s.str());
return;
}
- if ( IsAnInteger(group, elem, vr, length) ) {
+ // When an integer is expected, read and convert the following two or
+ // four bytes properly i.e. as an integer as opposed to a string.
+ if ( IsAnInteger(ElVal) ) {
guint32 NewInt;
if( length == 2 ) {
NewInt = ReadInt16();
}
NewValue[length]= 0;
- // FIXME les elements trop long (seuil a fixer a la main) ne devraient
- // pas etre charge's !!!! Voir TODO.
item_read = fread(NewValue, (size_t)length, (size_t)1, fp);
if ( item_read != 1 ) {
g_free(NewValue);
ElVal->SetValue(NewValue);
}
+/**
+ * \ingroup gdcmHeader
+ * \brief Loads the element while preserving the current
+ * underlying file position indicator as opposed to
+ * to LoadElementValue that modifies it.
+ * @param ElVal Element whose value shall be loaded.
+ * @return
+ */
+void gdcmHeader::LoadElementValueSafe(ElValue * ElVal) {
+ long PositionOnEntry = ftell(fp);
+ LoadElementValue(ElVal);
+ fseek(fp, PositionOnEntry, SEEK_SET);
+}
+
guint16 gdcmHeader::ReadInt16(void) {
guint16 g;
}
FindVR(NewElVal);
- FindLength(NewElVal);
+ try { FindLength(NewElVal); }
+ catch ( Error::FileReadError ) { // Call it quits
+ return (ElValue *)0;
+ }
NewElVal->SetOffset(ftell(fp));
return NewElVal;
}
-bool gdcmHeader::IsAnInteger(guint16 group, guint16 element,
- string vr, guint32 length ) {
+bool gdcmHeader::IsAnInteger(ElValue * ElVal) {
+ guint16 group = ElVal->GetGroup();
+ guint16 element = ElVal->GetElement();
+ string vr = ElVal->GetVR();
+ guint32 length = ElVal->GetLength();
+
// When we have some semantics on the element we just read, and if we
// a priori know we are dealing with an integer, then we shall be
// able to swap it's element value properly.
if ( element == 0 ) { // This is the group length of the group
- if (length != 4)
- dbg.Error("gdcmHeader::ShouldBeSwaped", "should be four");
- return true;
+ if (length == 4)
+ return true;
+ else
+ dbg.Error("gdcmHeader::IsAnInteger",
+ "Erroneous Group Length element length.");
}
if ( group % 2 != 0 )