private StringBuilder Map(UCharacterIterator iter, int options)
{
StringPrep.Values val = new StringPrep.Values();
char result = (char)(0);
int ch = IBM.ICU.Text.UForwardCharacterIterator_Constants.DONE;
StringBuilder dest = new StringBuilder();
bool allowUnassigned = ((options & ALLOW_UNASSIGNED) > 0);
while ((ch = iter.NextCodePoint()) != IBM.ICU.Text.UForwardCharacterIterator_Constants.DONE)
{
result = GetCodePointValue(ch);
GetValues(result, val);
// check if the source codepoint is unassigned
if (val.type == UNASSIGNED && allowUnassigned == false)
{
throw new StringPrepParseException(
"An unassigned code point was found in the input",
IBM.ICU.Text.StringPrepParseException.UNASSIGNED_ERROR,
iter.GetText(), iter.GetIndex());
}
else if ((val.type == MAP))
{
int index, length;
if (val.isIndex)
{
index = val.value_ren;
if (index >= indexes[ONE_UCHAR_MAPPING_INDEX_START] &&
index < indexes[TWO_UCHARS_MAPPING_INDEX_START])
{
length = 1;
}
else if (index >= indexes[TWO_UCHARS_MAPPING_INDEX_START] &&
index < indexes[THREE_UCHARS_MAPPING_INDEX_START])
{
length = 2;
}
else if (index >= indexes[THREE_UCHARS_MAPPING_INDEX_START] &&
index < indexes[FOUR_UCHARS_MAPPING_INDEX_START])
{
length = 3;
}
else
{
length = mappingData[index++];
}
/* copy mapping to destination */
dest.Append(mappingData, index, length);
continue;
}
else
{
ch -= val.value_ren;
}
}
else if (val.type == DELETE)
{
// just consume the codepoint and contine
continue;
}
// copy the source into destination
IBM.ICU.Text.UTF16.Append(dest, ch);
}
return(dest);
}
/*
* boolean isLabelSeparator(int ch){ int result = getCodePointValue(ch); if(
* (result & 0x07) == LABEL_SEPARATOR){ return true; } return false; }
*/
/*
* 1) Map -- For each character in the input, check if it has a mapping and,
* if so, replace it with its mapping.
*
* 2) Normalize -- Possibly normalize the result of step 1 using Unicode
* normalization.
*
* 3) Prohibit -- Check for any characters that are not allowed in the
* output. If any are found, return an error.
*
* 4) Check bidi -- Possibly check for right-to-left characters, and if any
* are found, make sure that the whole string satisfies the requirements for
* bidirectional strings. If the string does not satisfy the requirements
* for bidirectional strings, return an error. [Unicode3.2] defines several
* bidirectional categories; each character has one bidirectional category
* assigned to it. For the purposes of the requirements below, an
* "RandALCat character" is a character that has Unicode bidirectional
* categories "R" or "AL"; an "LCat character" is a character that has
* Unicode bidirectional category "L". Note
*
*
* that there are many characters which fall in neither of the above
* definitions; Latin digits (<U+0030> through <U+0039>) are examples of
* this because they have bidirectional category "EN".
*
* In any profile that specifies bidirectional character handling, all three
* of the following requirements MUST be met:
*
* 1) The characters in section 5.8 MUST be prohibited.
*
* 2) If a string contains any RandALCat character, the string MUST NOT
* contain any LCat character.
*
* 3) If a string contains any RandALCat character, a RandALCat character
* MUST be the first character of the string, and a RandALCat character MUST
* be the last character of the string.
*/
/// <summary>
/// Prepare the input buffer for use in applications with the given profile.
/// This operation maps, normalizes(NFKC), checks for prohited and BiDi
/// characters in the order defined by RFC 3454 depending on the options
/// specified in the profile.
/// </summary>
///
/// <param name="src">A UCharacterIterator object containing the source string</param>
/// <param name="options">A bit set of options:- StringPrep.NONE Prohibit processing of unassigned codepoints in the input- StringPrep.ALLOW_UNASSIGNED Treat the unassigned code pointsare in the input as normal Unicode code points.</param>
/// <returns>StringBuffer A StringBuffer containing the output</returns>
/// <exception cref="ParseException"></exception>
/// @stable ICU 2.8
public StringBuilder Prepare(UCharacterIterator src, int options)
{
// map
StringBuilder mapOut = Map(src, options);
StringBuilder normOut = mapOut; // initialize
if (doNFKC)
{
// normalize
normOut = Normalize(mapOut);
}
int ch;
char result;
UCharacterIterator iter = IBM.ICU.Text.UCharacterIterator.GetInstance(normOut);
StringPrep.Values val = new StringPrep.Values();
int direction = IBM.ICU.Lang.UCharacterEnums.ECharacterDirection.CHAR_DIRECTION_COUNT, firstCharDir = IBM.ICU.Lang.UCharacterEnums.ECharacterDirection.CHAR_DIRECTION_COUNT;
int rtlPos = -1, ltrPos = -1;
bool rightToLeft = false, leftToRight = false;
while ((ch = iter.NextCodePoint()) != IBM.ICU.Text.UForwardCharacterIterator_Constants.DONE)
{
result = GetCodePointValue(ch);
GetValues(result, val);
if (val.type == PROHIBITED)
{
throw new StringPrepParseException(
"A prohibited code point was found in the input",
IBM.ICU.Text.StringPrepParseException.PROHIBITED_ERROR,
iter.GetText(), val.value_ren);
}
if (checkBiDi)
{
direction = bdp.GetClass(ch);
if (firstCharDir == IBM.ICU.Lang.UCharacterEnums.ECharacterDirection.CHAR_DIRECTION_COUNT)
{
firstCharDir = direction;
}
if (direction == IBM.ICU.Lang.UCharacterEnums.ECharacterDirection.LEFT_TO_RIGHT)
{
leftToRight = true;
ltrPos = iter.GetIndex() - 1;
}
if (direction == IBM.ICU.Lang.UCharacterEnums.ECharacterDirection.RIGHT_TO_LEFT ||
direction == IBM.ICU.Lang.UCharacterEnums.ECharacterDirection.RIGHT_TO_LEFT_ARABIC)
{
rightToLeft = true;
rtlPos = iter.GetIndex() - 1;
}
}
}
if (checkBiDi == true)
{
// satisfy 2
if (leftToRight == true && rightToLeft == true)
{
throw new StringPrepParseException(
"The input does not conform to the rules for BiDi code points.",
IBM.ICU.Text.StringPrepParseException.CHECK_BIDI_ERROR, iter
.GetText(), (rtlPos > ltrPos) ? rtlPos : ltrPos);
}
// satisfy 3
if (rightToLeft == true &&
!((firstCharDir == IBM.ICU.Lang.UCharacterEnums.ECharacterDirection.RIGHT_TO_LEFT || firstCharDir == IBM.ICU.Lang.UCharacterEnums.ECharacterDirection.RIGHT_TO_LEFT_ARABIC) && (direction == IBM.ICU.Lang.UCharacterEnums.ECharacterDirection.RIGHT_TO_LEFT || direction == IBM.ICU.Lang.UCharacterEnums.ECharacterDirection.RIGHT_TO_LEFT_ARABIC)))
{
throw new StringPrepParseException(
"The input does not conform to the rules for BiDi code points.",
IBM.ICU.Text.StringPrepParseException.CHECK_BIDI_ERROR, iter
.GetText(), (rtlPos > ltrPos) ? rtlPos : ltrPos);
}
}
return(normOut);
}
/// <summary>
/// Function that implements the ToUnicode operation as defined in the IDNA
/// RFC. This operation is done on <b>single labels</b> before sending it to
/// something that expects Unicode names. A label is an individual part of a
/// domain name. Labels are usually separated by dots; for
/// e.g." "www.example.com" is composed of 3 labels "www","example", and
/// "com".
/// </summary>
///
/// <param name="src">The input string as UCharacterIterator to be processed</param>
/// <param name="options">A bit set of options: - IDNA.DEFAULT Use default options,i.e., do not process unassigned code points and do not useSTD3 ASCII rules If unassigned code points are found theoperation fails with ParseException.- IDNA.ALLOW_UNASSIGNED Unassigned values can be converted toASCII for query operations If this option is set, theunassigned code points are in the input are treated as normalUnicode code points.- IDNA.USE_STD3_RULES Use STD3 ASCII rules for host namesyntax restrictions If this option is set and the input doesnot satisfy STD3 rules, the operation will fail withParseException</param>
/// <returns>StringBuffer the converted String</returns>
/// <exception cref="ParseException"></exception>
/// @stable ICU 2.8
public static StringBuilder ConvertToUnicode(UCharacterIterator src,
int options)
{
bool[] caseFlags = null;
// the source contains all ascii codepoints
bool srcIsASCII = true;
// assume the source contains all LDH codepoints
// boolean srcIsLDH = true;
// get the options
// boolean useSTD3ASCIIRules = ((options & USE_STD3_RULES) != 0);
// int failPos = -1;
int ch;
int saveIndex = src.GetIndex();
// step 1: find out if all the codepoints in src are ASCII
while ((ch = src.Next()) != IBM.ICU.Text.UForwardCharacterIterator_Constants.DONE)
{
if (ch > 0x7F)
{
srcIsASCII = false;
} /*
* else if((srcIsLDH = isLDHChar(ch))==false){ failPos =
* src.getIndex(); }
*/
}
StringBuilder processOut;
if (srcIsASCII == false)
{
try {
// step 2: process the string
src.SetIndex(saveIndex);
processOut = singleton.namePrep.Prepare(src, options);
} catch (StringPrepParseException ex) {
return(new StringBuilder(src.GetText()));
}
}
else
{
// just point to source
processOut = new StringBuilder(src.GetText());
}
// TODO:
// The RFC states that
// <quote>
// ToUnicode never fails. If any step fails, then the original input
// is returned immediately in that step.
// </quote>
// step 3: verify ACE Prefix
if (StartsWithPrefix(processOut))
{
StringBuilder decodeOut = null;
// step 4: Remove the ACE Prefix
String temp = processOut.ToString(ACE_PREFIX.Length, processOut.Length - ACE_PREFIX.Length);
// step 5: Decode using punycode
try {
decodeOut = IBM.ICU.Text.Punycode.Decode(new StringBuilder(temp), caseFlags);
} catch (StringPrepParseException e) {
decodeOut = null;
}
// step 6:Apply toASCII
if (decodeOut != null)
{
StringBuilder toASCIIOut = ConvertToASCII(decodeOut, options);
// step 7: verify
if (CompareCaseInsensitiveASCII(processOut, toASCIIOut) != 0)
{
// throw new
// StringPrepParseException("The verification step prescribed by the RFC 3491 failed",
// StringPrepParseException.VERIFICATION_ERROR);
decodeOut = null;
}
}
// step 8: return output of step 5
if (decodeOut != null)
{
return(decodeOut);
}
}
// }else{
// // verify that STD3 ASCII rules are satisfied
// if(useSTD3ASCIIRules == true){
// if( srcIsLDH == false /* source contains some non-LDH characters */
// || processOut.charAt(0) == HYPHEN
// || processOut.charAt(processOut.length()-1) == HYPHEN){
//
// if(srcIsLDH==false){
// throw new
// StringPrepParseException("The input does not conform to the STD 3 ASCII rules",
// StringPrepParseException.STD3_ASCII_RULES_ERROR,processOut.toString(),
// (failPos>0) ? (failPos-1) : failPos);
// }else if(processOut.charAt(0) == HYPHEN){
// throw new
// StringPrepParseException("The input does not conform to the STD 3 ASCII rules",
// StringPrepParseException.STD3_ASCII_RULES_ERROR,
// processOut.toString(),0);
//
// }else{
// throw new
// StringPrepParseException("The input does not conform to the STD 3 ASCII rules",
// StringPrepParseException.STD3_ASCII_RULES_ERROR,
// processOut.toString(),
// processOut.length());
//
// }
// }
// }
// // just return the source
// return new StringBuffer(src.getText());
// }
return(new StringBuilder(src.GetText()));
}