/** * Returns the value of a specified fieldname from the specified hashmap and returns an integer * value or throws an exception if the value is not an integer */ private int getIntValue(String fieldname, Map<String, String> extraparams) { Matcher checkint = Pattern.compile("^\\d+$").matcher(fieldname); int rv; if (checkint.matches()) { rv = Integer.parseInt(fieldname); } else { if (extraparams.containsKey(fieldname)) { rv = Integer.parseInt(extraparams.get(fieldname)); } else { rv = -1; throw new TDTException( "No integer value for " + fieldname + " can be found - check extraparams"); } } return rv; }
/** * Adds additional entries to the extraparams hashmap by processing various rules defined in the * TDT definition files. Typically used for string processing functions, lookup in tables, * calculation of check digits etc. */ private void processRules(Map<String, String> extraparams, Rule tdtrule) { String tdtfunction = tdtrule.getFunction(); int openbracket = tdtfunction.indexOf("("); assert openbracket != -1; String params = tdtfunction.substring(openbracket + 1, tdtfunction.length() - 1); String rulename = tdtfunction.substring(0, openbracket); String[] parameter = params.split(","); String newfieldname = tdtrule.getNewFieldName(); // System.out.println(tdtfunction + " " + parameter[0] + " " + extraparams.get(parameter[0])); /** * Stores in the hashmap extraparams the value obtained from a lookup in a specified XML table. * * <p>The first parameter is the given value already known. This is denoted as $1 in the * corresponding XPath expression * * <p>The second parameter is the string filename of the table which must be present in the * auxiliary subdirectory * * <p>The third parameter is the column in which the supplied input value should be sought * * <p>The fourth parameter is the column whose value should be read for the corresponding row, * in order to obtain the result of the lookup. * * <p>The rule in the definition file may contain an XPath expression and a URL where the table * may be obtained. */ if (rulename.equals("TABLELOOKUP")) { // parameter[0] is given value // parameter[1] is table // parameter[2] is input column supplied // parameter[3] is output column required assert parameter.length == 4 : "incorrect number of parameters to tablelookup " + params; if (parameter[1].equals("tdt64bitcpi")) { String s = extraparams.get(parameter[0]); assert s != null : tdtfunction + " when " + parameter[0] + " is null"; String t = gs1cpi.get(s); assert t != null : "gs1cpi[" + s + "] is null"; assert newfieldname != null; extraparams.put(newfieldname, t); // extraparams.put(newfieldname, gs1cpi.get(extraparams.get(parameter[0]))); } else { // JPB! the following is untested String tdtxpath = tdtrule.getTableXPath(); String tdttableurl = tdtrule.getTableURL(); String tdtxpathsub = tdtxpath.replaceAll("\\$1", extraparams.get(parameter[0])); extraparams.put(newfieldname, xpathlookup("ManagerTranslation.xml", tdtxpathsub)); } } /** * Stores the length of the specified string under the new fieldname specified by the * corresponding rule of the definition file. */ if (rulename.equals("LENGTH")) { assert extraparams.get(parameter[0]) != null : tdtfunction + " when " + parameter[0] + " is null"; if (extraparams.get(parameter[0]) != null) { extraparams.put(newfieldname, Integer.toString(extraparams.get(parameter[0]).length())); } } /** * Stores a GS1 check digit in the extraparams hashmap, keyed under the new fieldname specified * by the corresponding rule of the definition file. */ if (rulename.equals("GS1CHECKSUM")) { assert extraparams.get(parameter[0]) != null : tdtfunction + " when " + parameter[0] + " is null"; if (extraparams.get(parameter[0]) != null) { extraparams.put(newfieldname, gs1checksum(extraparams.get(parameter[0]))); } } /** * Obtains a substring of the string provided as the first parameter. If only a single second * parameter is specified, then this is considered as the start index and all characters from * the start index onwards are stored in the extraparams hashmap under the key named * 'newfieldname' in the corresponding rule of the definition file. If a second and third * parameter are specified, then the second parameter is the start index and the third is the * length of characters required. A substring consisting characters from the start index up to * the required length of characters is stored in the extraparams hashmap, keyed under the new * fieldname specified by the corresponding rule of the defintion file. */ if (rulename.equals("SUBSTR")) { assert extraparams.get(parameter[0]) != null : tdtfunction + " when " + parameter[0] + " is null"; if (parameter.length == 2) { if (extraparams.get(parameter[0]) != null) { int start = getIntValue(parameter[1], extraparams); if (start >= 0) { extraparams.put(newfieldname, extraparams.get(parameter[0]).substring(start)); } } } if (parameter.length == 3) { // need to check that this variation is correct - c.f. Perl substr assert extraparams.get(parameter[0]) != null : tdtfunction + " when " + parameter[0] + " is null"; if (extraparams.get(parameter[0]) != null) { int start = getIntValue(parameter[1], extraparams); int end = getIntValue(parameter[2], extraparams); if ((start >= 0) && (end >= 0)) { extraparams.put( newfieldname, extraparams.get(parameter[0]).substring(start, start + end)); } } } } /** * Concatenates specified string parameters together. Literal values must be enclosed within * single or double quotes or consist of unquoted digits. Other unquoted strings are considered * as fieldnames and the corresponding value from the extraparams hashmap are inserted. The * result of the concatenation (and substitution) of the strings is stored as a new entry in the * extraparams hashmap, keyed under the new fieldname specified by the rule. */ if (rulename.equals("CONCAT")) { StringBuilder buffer = new StringBuilder(); for (int p1 = 0; p1 < parameter.length; p1++) { Matcher matcher = Pattern.compile("\"(.*?)\"|'(.*?)'|[0-9]").matcher(parameter[p1]); if (matcher.matches()) { buffer.append(parameter[p1]); } else { assert extraparams.get(parameter[p1]) != null : tdtfunction + " when " + parameter[p1] + " is null"; if (extraparams.get(parameter[p1]) != null) { buffer.append(extraparams.get(parameter[p1])); } } } extraparams.put(newfieldname, buffer.toString()); } }
/** convert from a particular scheme / level */ private String convertLevel( Scheme tdtscheme, Level tdtlevel, String input, Map<String, String> inputParameters, LevelTypeList outboundlevel) { String outboundstring; Map<String, String> extraparams = // new NoisyMap (new HashMap<String, String>(inputParameters)); // get the scheme's option key, which is the name of a // parameter whose value is matched to the option key of the // level. String optionkey = tdtscheme.getOptionKey(); String optionValue = extraparams.get(optionkey); // the name of a parameter which allows the appropriate option // to be selected // now consider the various options within the scheme and // level for each option element inside the level, check // whether the pattern attribute matches as a regular // expression String matchingOptionKey = null; Option matchingOption = null; Matcher prefixMatcher = null; for (Enumeration e = tdtlevel.enumerateOption(); e.hasMoreElements(); ) { Option opt = (Option) e.nextElement(); if (optionValue == null || optionValue.equals(opt.getOptionKey())) { // possible match Matcher matcher = Pattern.compile(opt.getPattern()).matcher(input); if (matcher.matches()) { if (prefixMatcher != null) throw new TDTException("Multiple patterns matched"); prefixMatcher = matcher; matchingOptionKey = opt.getOptionKey(); matchingOption = opt; } } } if (prefixMatcher == null) throw new TDTException("No patterns matched"); optionValue = matchingOptionKey; for (Enumeration e = matchingOption.enumerateField(); e.hasMoreElements(); ) { Field field = (Field) e.nextElement(); int seq = field.getSeq(); String strfieldname = field.getName(); int fieldlength = field.getLength(); String strfieldvalue = prefixMatcher.group(seq); // System.out.println(" processing field " + strfieldname + " = '" + strfieldvalue + "'"); if (field.getCompaction() == null) { // if compaction is null, treat field as an integer if (field.getCharacterSet() != null) { // if the character set is specified Matcher charsetmatcher = Pattern.compile("^" + field.getCharacterSet() + "$").matcher(strfieldvalue); if (!charsetmatcher.matches()) { throw new TDTException( "field " + strfieldname + " (" + strfieldvalue + ") does not conform to the allowed character set (" + field.getCharacterSet() + ") "); } } BigInteger bigvalue = null; if (tdtlevel.getType() == LevelTypeList.BINARY) { // if the input was BINARY bigvalue = new BigInteger(strfieldvalue, 2); extraparams.put(strfieldname, bigvalue.toString()); } else { if (field.getDecimalMinimum() != null || field.getDecimalMaximum() != null) bigvalue = new BigInteger(strfieldvalue); extraparams.put(strfieldname, strfieldvalue); } if (field.getDecimalMinimum() != null) { // if the decimal minimum is specified BigInteger bigmin = new BigInteger(field.getDecimalMinimum()); if (bigvalue.compareTo(bigmin) == -1) { // throw an exception if the field value is less than the decimal minimum throw new TDTException( "field " + strfieldname + " (" + bigvalue + ") is less than DecimalMinimum (" + field.getDecimalMinimum() + ") allowed"); } } if (field.getDecimalMaximum() != null) { // if the decimal maximum is specified BigInteger bigmax = new BigInteger(field.getDecimalMaximum()); if (bigvalue.compareTo(bigmax) == 1) { // throw an excpetion if the field value is greater than the decimal maximum throw new TDTException( "field " + strfieldname + " (" + bigvalue + ") is greater than DecimalMaximum (" + field.getDecimalMaximum() + ") allowed"); } } // after extracting the field, it may be necessary to pad it. padField(extraparams, field); } else { // compaction is specified - interpret binary as a string value using a truncated byte per // character CompactionMethodList compaction = field.getCompaction(); PadDirectionList padDir = field.getPadDir(); String padchar = field.getPadChar(); String s; if (compaction == CompactionMethodList.VALUE_5) // "5-bit" s = bin2uppercasefive(strfieldvalue); else if (compaction == CompactionMethodList.VALUE_4) // 6-bit s = bin2alphanumsix(strfieldvalue); else if (compaction == CompactionMethodList.VALUE_3) // 7-bit s = bin2asciiseven(strfieldvalue); else if (compaction == CompactionMethodList.VALUE_2) // 8-bit s = bin2bytestring(strfieldvalue); else throw new Error("unsupported compaction method " + compaction); extraparams.put(strfieldname, stripPadChar(s, padDir, padchar)); } } // for each field; /** * the EXTRACT rules are performed after parsing the input, in order to determine additional * fields that are to be derived from the fields obtained by the pattern match process */ int seq = 0; for (Enumeration e = tdtlevel.enumerateRule(); e.hasMoreElements(); ) { Rule tdtrule = (Rule) e.nextElement(); if (tdtrule.getType() == ModeList.EXTRACT) { assert seq < tdtrule.getSeq() : "Rule out of sequence order"; seq = tdtrule.getSeq(); processRules(extraparams, tdtrule); } } /** * Now we need to consider the corresponding output level and output option. The scheme must * remain the same, as must the value of optionkey (to select the corresponding option element * nested within the required outbound level) */ Level tdtoutlevel = findLevel(tdtscheme, outboundlevel); Option tdtoutoption = findOption(tdtoutlevel, optionValue); /** * the FORMAT rules are performed before formatting the output, in order to determine additional * fields that are required for preparation of the outbound format */ seq = 0; for (Enumeration e = tdtoutlevel.enumerateRule(); e.hasMoreElements(); ) { Rule tdtrule = (Rule) e.nextElement(); if (tdtrule.getType() == ModeList.FORMAT) { assert seq < tdtrule.getSeq() : "Rule out of sequence order"; seq = tdtrule.getSeq(); processRules(extraparams, tdtrule); } } /** * Now we need to ensure that all fields required for the outbound grammar are suitably padded * etc. processPadding takes care of firstly padding the non-binary fields if padChar and * padDir, length are specified then (if necessary) converting to binary and padding the binary * representation to the left with zeros if the bit string is has fewer bits than the bitLength * attribute specifies. N.B. TDTv1.1 will be more specific about bit-level padding rather than * assuming that it is always to the left with the zero bit. */ // System.out.println(" prior to processPadding, " + extraparams); for (Enumeration e = tdtoutoption.enumerateField(); e.hasMoreElements(); ) { Field field = (Field) e.nextElement(); // processPadding(extraparams, field, outboundlevel, tdtoutoption); padField(extraparams, field); if (outboundlevel == LevelTypeList.BINARY) binaryPadding(extraparams, field); } /** * Construct the output from the specified grammar (in ABNF format) together with the field * values stored in inputparams */ outboundstring = buildGrammar(tdtoutoption.getGrammar(), extraparams); // System.out.println("final extraparams = " + extraparams); // System.out.println("returned " + outboundstring); return outboundstring; }