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///////////////////////////////////////////////////////////////////////////////
//                                                                             
// JTOpen (IBM Toolbox for Java - OSS version)                                 
//                                                                             
// Filename: JDEscapeClause.java
//                                                                             
// The source code contained herein is licensed under the IBM Public License   
// Version 1.0, which has been approved by the Open Source Initiative.         
// Copyright (C) 1997-2001 International Business Machines Corporation and     
// others. All rights reserved.                                                
//                                                                             
///////////////////////////////////////////////////////////////////////////////

package com.ibm.as400.access;

import java.sql.SQLException;
import java.util.StringTokenizer;
import java.util.Vector;



/**

This class represents an escape clause in a SQL statement. It is used to translate SQL statements with JDBC escape syntax to DB2 for IBM i format. **/ public class JDEscapeClause { // String constants. These will hopefully help performance // slightly - assuming a similar optimization does not // already take place. private static final String CALL_ = "CALL"; private static final String CALL1_ = "?="; private static final String CALL2_ = "?=CALL"; private static final String CALL3_ = "?"; private static final String DATE_ = "D"; private static final String ESCAPE_ = "ESCAPE"; private static final String FN_ = "FN"; private static final String OJ_ = "OJ"; private static final String TIME_ = "T"; private static final String TIMESTAMP_ = "TS"; // Scalar function parsing table. private static JDScalarTable scalarFunctionTable_; /** Static initializer. Initialize the scalar function table and the supported function lists. **/ // @C1M Changed the static initializer to use the new JDScalarTable and provide earliest supported versions static { // create a new table scalarFunctionTable_ = new JDScalarTable(); // Numeric functions. // // Supported by system: // V4R5: // abs,acos,asin,atan,atan2,ceiling,cos,cot,degrees,exp,floor,log10,mod,power,round,sin,sign,sqrt,tan,truncate // >=V5R1: // abs,acos,asin,atan,atan2,ceiling,cos,cot,degrees,exp,floor,log10,mod,power,radians,rand,round,sin,sign,sqrt,tan,truncate // // Supported by mapping: // log,pi // scalarFunctionTable_.put("pi", "3%d1415926E00", JDUtilities.vrm510); scalarFunctionTable_.put("log", "LN(%1)", JDScalarTable.NOT_SUPPORTED); // String functions. // // Supported by system: // >=V6R1: // ascii, concat,difference,insert, // lcase,left,locate,ltrim,repeat,replace, // right,rtrim,soundex,space,substring,ucase // // Supported by mapping: // V6R1: // length // // scalarFunctionTable_.put("length", "LENGTH(STRIP(%1,T))", JDScalarTable.NOT_SUPPORTED); // System functions. // // Supported by system: // ifnull,user // // Supported by mapping: // database // scalarFunctionTable_.put("database", "CURRENT SERVER", JDUtilities.vrm530); // we map the below function because if it is simply passed through it will end up USER() // instead of USER scalarFunctionTable_.put("user", "USER", JDScalarTable.NOT_SUPPORTED); // return information about JTOpen scalarFunctionTable_.put("jtopeninfo", "'"+Copyright.version+"'", JDScalarTable.NOT_SUPPORTED); // Time and date functions. // // Supported by system: // curdate,curtime,dayname,dayofmonth,dayofweek,dayofyear,hour,minute,month,monthname,now,quarter,second,timestampdiff,week,year // // Not supported: // timestampadd // } /** Parses an escape clause, and substitute it with native SQL. This will recursively parse all nested escape clauses. @param escapeSyntax SQL escape syntax. @param decimalSeparator The decimal separator. @parm vrm The release as generated by AS400.generateVRM. @return The parsed string. @exception SQLException If there is a syntax error or a reference to an unsupported scalar function. **/ public static String parse (String escapeSyntax, String decimalSeparator, int vrm) // @C1M accept vrm throws SQLException { // Tokenize the string and pass it to the other // parse method (which may end up being called // recursively. // @C4D StringTokenizer tokenizer = new StringTokenizer (escapeSyntax, // @C4D "{}'\"", true); JDSQLTokenizer tokenizer = new JDSQLTokenizer(escapeSyntax, "{}'\""); // @C4A return parse (tokenizer, decimalSeparator, true, vrm); // @C1M pass vrm } /** Parses an escape clause, and substitute it with native SQL. This will recursively parse all nested escape clauses.

When the flag is true, the tokenized string is considered to be the entire SQL statement and will end at the end of the string.

When the flag is false, the tokenized string is considered to be just a single escape clause, starting 1 token after its left brace. It will end at the matching right brace. @param tokenizer The tokenized string. @param decimalSeparator The decimal separator. @param flag The flag. @parm vrm The release as generated by AS400.generateVRM. @exception SQLException If there is a syntax error or a reference to an unsupported scalar function. **/ // @C4D private static String parse (StringTokenizer tokenizer, public static String parse (JDSQLTokenizer tokenizer, String decimalSeparator, boolean flag, int vrm) // @C1M accept vrm throws SQLException { // Initialize. StringBuffer buffer = new StringBuffer (); boolean quotes = false; char quoteType = ' '; // Iterate through the tokens... while (tokenizer.hasMoreTokens ()) { String token = tokenizer.nextToken(); // If the token is a left brace (and we are not in // quotes), then recursively parse the escape clause. if (token.equals ("{")) { if (quotes) buffer.append (token); else buffer.append (parse (tokenizer, decimalSeparator, false, vrm)); // @C1M pass vrm } // If the token is a right brace (and we are not in // quotes), then this is the end of a clause. // // If we are parsing the whole string, then this does // not have a matching left brace. // else if (token.equals ("}")) { if (quotes) buffer.append (token); else if (flag) JDError.throwSQLException (JDError.EXC_SYNTAX_ERROR); else return convert (buffer.toString (), decimalSeparator, vrm); // @C1M pass vrm } // If the token is a quote, then toggle the quote // information. else if ((token.equals ("'")) || (token.equals ("\""))) { if (quotes) { if (quoteType == token.charAt (0)) quotes = false; } else { quotes = true; quoteType = token.charAt (0); } buffer.append(token); } // Anything else, just add it to the buffer. else buffer.append(token); } // If we have gotten this far and we are just parsing // a clause, then there is no closing right brace. if (! flag) JDError.throwSQLException (JDError.EXC_SYNTAX_ERROR); return buffer.toString (); } /** Convert the escape syntax to native SQL. @param escapeSyntax The escape syntax to convert. It is assumed that all leading and trailing blanks are already trimmed. @param decimalSeparator The decimal separator. @return Native SQL. @exception SQLException If there is a syntax error or a reference to an unsupported scalar function. **/ private static String convert (String escapeSyntax, String decimalSeparator, int vrm) // @C1M accept vrm throws SQLException { StringBuffer buffer = new StringBuffer (); // Parse out the keyword and the value. The value // is just the rest of the escape syntax. String trimmed = escapeSyntax.trim (); int i = trimmed.indexOf (' '); String keyword = null; String value = null; if (i == -1) { keyword = trimmed; // @C3M value = ""; } else { keyword = trimmed.substring (0, i); // @C3M value = trimmed.substring (i+1); } // Handle stored procedures. if ((keyword.equalsIgnoreCase (CALL_)) // @C3M || (keyword.equalsIgnoreCase (CALL1_)) // @C3M || (keyword.equalsIgnoreCase (CALL2_)) // @C3M || (keyword.equalsIgnoreCase (CALL3_))) { // @C3M buffer.append (keyword); buffer.append (' '); buffer.append (value); } // Handle date literal. // // This works because the JDBC escape syntax is the same // as ISO format, which works no matter what the server // job has for its date format and separator. // else if (keyword.equalsIgnoreCase (DATE_)) buffer.append (value); // Handle time literal. // // This works because the JDBC escape syntax is the same // as ISO format, which works no matter what the server // job has for its date format and separator. // else if (keyword.equalsIgnoreCase (TIME_)) buffer.append (value); // Handle timestamp literal. else if (keyword.equalsIgnoreCase (TIMESTAMP_)) { StringTokenizer tokenizer = new StringTokenizer (value); if (tokenizer.countTokens() != 2) JDError.throwSQLException (JDError.EXC_SYNTAX_ERROR); buffer.append (tokenizer.nextToken()); buffer.append ('-'); buffer.append (tokenizer.nextToken().replace(':', '.')); /* @B1D - This will never happen, since we already counted tokens. while (tokenizer.hasMoreTokens ()) { buffer.append (' '); buffer.append (tokenizer.nextToken()); } */ } // Handle scalar functions. else if (keyword.equalsIgnoreCase (FN_)) buffer.append (convertScalarFunctionCall (value, decimalSeparator, vrm)); // @C1M pass vrm // Handle LIKE escape characters. else if (keyword.equalsIgnoreCase (ESCAPE_)) { if (value.trim ().length () == 0) JDError.throwSQLException (JDError.EXC_SYNTAX_ERROR); buffer.append (keyword); buffer.append (' '); buffer.append (value); } // Handle outer joins. else if (keyword.equalsIgnoreCase (OJ_)) { buffer.append (value); } // If none of the keywords matched any that we recognize, // then call it a syntax error. if (buffer.length() == 0) JDError.throwSQLException (JDError.EXC_SYNTAX_ERROR); return buffer.toString(); } /** Convert a scalar function call to native SQL. @param functionCall Function call. @param decimalSeparator The decimal separator. @return Native SQL. @exception SQLException If there is a syntax error or a reference to an unsupported scalar function. **/ // @C1M changed parsing to support nested scalars and changed function mapping private static String convertScalarFunctionCall (String functionCall, String decimalSeparator, int vrm) throws SQLException { // Parse the function call into its pieces. int i = functionCall.indexOf('('); // find the last index of the closing parenthesis to make // @C0A // sure we get the whole function call including nested calls // @C0A int j = functionCall.lastIndexOf(')'); // @C0M String functionName = null; String argumentString = null; // get the function name and arg string //if ((i == -1) && (j == -1)) { // @C2D // functionName = functionCall.trim().toLowerCase(); // @C2D // argumentString = ""; // @C2D //} else if ((i < j) && (i != -1) && (j != -1)) { // @C2D if ((i < j) && (i != -1) && (j != -1)) { // @C2A functionName = functionCall.substring (0, i).trim().toLowerCase(); argumentString = functionCall.substring (i+1, j).trim(); } else JDError.throwSQLException (JDError.EXC_SYNTAX_ERROR); // get the mapped function or just pass it through if (!scalarFunctionTable_.contains(functionName, vrm)){ // @C1A // we dont map this function so just pass it through // @C1A return functionCall; // @C1A } else { // @C1A // Check for text after the right parenthesis. // @C1A if (j != -1 && j+1 < functionCall.length() && functionCall.substring(j+1).trim().length() > 0) // @C1A JDError.throwSQLException (JDError.EXC_SYNTAX_ERROR); // @C1A // @C1A // Parse the argument string into arguments. // @C1A Vector arguments = new Vector(); // @C1A if (argumentString.length() > 0) { // @C1A StringTokenizer atok = new StringTokenizer(argumentString, "(),", true); // @C1A StringBuffer tokbuf = new StringBuffer(); // @C1A int nestlevel = 0; // @C1A while (atok.hasMoreTokens()) { // @C1A String token = atok.nextToken(); // @C1A // check if the argument has parenthesis, meaning it could be a nested fcn // @C1A if (token.equals("(")) { // @C1A ++nestlevel; // @C1A tokbuf.append("("); // @C1A } else if (token.equals(")")) { // @C1A // find a closing paren and decrement the nest count // @C1A --nestlevel; // @C1A tokbuf.append(")"); // @C1A // if we have no more tokens after this one we add the argument to the list // @C1A if (!atok.hasMoreTokens()) { // @C1A arguments.add(tokbuf.toString()); // @C1A } // @C1A } else if (token.equals(",")) { // @C1A // find a comma // @C1A if (nestlevel == 0) { // @C1A // if the nest count is zero we add the argument to the list because it is actually a delimeter arguments.add(tokbuf.toString()); // @C1A tokbuf = new StringBuffer(); // @C1A } else { // @C1A // if the nest count is not zero the comma is not a delimeter so just append to the buffer tokbuf.append(","); // @C1A } // @C1A } else { // @C1A // token is a special case so just add it to the buffer // @C1A tokbuf.append(token); // @C1A // there are no more tokens left so add the argument to the list // @C1A if (!atok.hasMoreTokens()) { // @C1A arguments.add(tokbuf.toString()); // @C1A } // @C1A } // @C1A } // @C1A } // @C1A // @C1A // Get the native SQL from the scalar function table. // @C1A StringBuffer buffer = new StringBuffer (); String nativeSQL = scalarFunctionTable_.get(functionName, vrm).toString(); // @C1M // Handle the substitution variables. int marker = 0; int nextPercent = 0; int highestArgumentNumber = 0; while (true) { // Find the next % and substitution code (the digit // after the %. nextPercent = nativeSQL.indexOf ('%', marker); if ((nextPercent == -1) || (nextPercent == nativeSQL.length() - 1)) { buffer.append (nativeSQL.substring (marker)); break; } buffer.append (nativeSQL.substring (marker, nextPercent)); char substitutionCode = nativeSQL.charAt (nextPercent + 1); // If an invalid substitution code, then it is a // syntax error. Otherwise, do the substitution. if (Character.isDigit (substitutionCode)) { int argumentNumber = Character.digit (substitutionCode, 10); if (argumentNumber > arguments.size()) JDError.throwSQLException (JDError.EXC_SYNTAX_ERROR); if (argumentNumber > highestArgumentNumber) highestArgumentNumber = argumentNumber; buffer.append (arguments.elementAt(argumentNumber-1)); } else if (substitutionCode == 'd') { buffer.append (decimalSeparator); } // Increment the marker past the substitution code. marker = nextPercent + 2; } // Check that the number of arguments is what we expected. if (highestArgumentNumber != arguments.size()) JDError.throwSQLException (JDError.EXC_SYNTAX_ERROR); return buffer.toString(); } } /** Get a list of supported math functions. @param vrm The version of the host OS. @return A list of function names, separated by commas. **/ static String getNumericFunctions(int vrm) { if (vrm >= JDUtilities.vrm610) { return "abs,acos,asin,atan,atan2,ceiling,character_length,cos,cot,degrees," + "exp,floor,log,log10,mod,octet_length,pi,power," + "position,radians,rand,round,sign,sin,sqrt,tan,truncate"; } else { // @C1A the below if/else block was added to report the correct functions // through DatabaseMetaData if (vrm < JDUtilities.vrm510) { // we are running to a V4R5 or older host return "abs,acos,asin,atan,atan2,ceiling,cos,cot,degrees,exp,floor,log,log10,mod,pi,power,round,sin,sign,sqrt,tan,truncate"; } else { // we are running to a V5R1 or newer host return "abs,acos,asin,atan,atan2,ceiling,cos,cot,degrees,exp,floor,log,log10,mod,pi,power,radians,rand,round,sin,sign,sqrt,tan,truncate"; } } } /** Get a list of supported string functions. @param vrm The version of the host OS. @return A list of function names, separated by commas. **/ static String getStringFunctions(int vrm) { if (vrm >= JDUtilities.vrm610) { return "ascii,char,char_length,character_length,concat,difference," + "insert,lcase,left,length,locate,ltrim," + "octet_length,position,repeat,replace,right,rtrim," + "soundex,space,substring,ucase"; } else { // @C1A the below if/else block was added to report the correct functions through DatabaseMetaData if (vrm < JDUtilities.vrm510) { // we are running to a V4R5M0 or older host return "concat,insert,left,length,locate,ltrim,right,rtrim,substring,ucase"; } else if (vrm < JDUtilities.vrm520) { // we are running to a V5R1 host return "concat,difference,insert,left,length,locate,ltrim,right,rtrim,soundex,space,substring,ucase"; } else if (vrm < JDUtilities.vrm530) { // we are running to a V5R2 host return "char,concat,difference,insert,lcase,left,length,locate,ltrim,right,rtrim,soundex,space,substring,ucase"; } else { // we are running to a V5R3 or newer host return "ascii,char,concat,difference,insert,lcase,left,length,locate,ltrim,repeat,replace,right,rtrim,soundex,space,substring,ucase"; } } } /** Get a list of supported system functions. @param vrm The version of the host OS. @return A list of function names, separated by commas. **/ static String getSystemFunctions(int vrm) { return "database,ifnull,user"; // @C1A added to report the correct functions through DatabaseMetaData } /** Get a list of supported time and date functions. @param vrm The version of the host OS. @return A list of function names, separated by commas. **/ static String getTimeDateFunctions(int vrm) { if (vrm >= JDUtilities.vrm610) { return "current_date,current_time,current_timestamp," + "curdate,curtime,dayname,dayofmonth,dayofweek,dayofyear," + "extract,hour,minute,month,monthname,now,quarter,second," + "timestampdiff,week,year"; } else { // @C1A the below if/else block was added to report the correct functions through DatabaseMetaData if (vrm < JDUtilities.vrm510) { // we are running to a V4R5 or older host return "curdate,curtime,dayofmonth,dayofweek,dayofyear,hour,minute,month,now,quarter,second,week,year"; } else if (vrm < JDUtilities.vrm530) { // we are running to a V5R1 or V5R2 host return "curdate,curtime,dayofmonth,dayofweek,dayofyear,hour,minute,month,now,quarter,second,timestampdiff,week,year"; } else { // we are running to a V5R3 or newer host return "curdate,curtime,dayname,dayofmonth,dayofweek,dayofyear,hour,minute,month,monthname,now,quarter,second,timestampdiff,week,year"; } } } /** Add the specified scalar function and native SQL to the scalar function table and the specified function list. @param functionName Name of scalar function @param nativeSQL Native SQL to translate function call into. This string can contain substitution variables, which are % followed by a substitution code. A numeric substitution code (e.g. %1, %2, %3) marks where argument will be copied to during translation. %d marks where the decimal separator should appear. @param functionList Function list to which to append this supported scalar function. **/ // @C1D removed this method because it is no longer needed // private static void initializeScalarFunction (String functionName, String nativeSql, int vrmSupported, StringBuffer functionList) // { // // Add to scalar function table. // scalarFunctionTable_.put (functionName, nativeSql, vrmSupported); // // // Add to the function list. // if (functionList.length() > 0) // functionList.append (','); // functionList.append (functionName); // } /** Is the CONVERT function between SQL types supported? @return false **/ static boolean supportsConvert () { // We do not support this. return false; } /** Is CONVERT between the given SQL types supported? @param fromType SQL type code defined in java.sql.Types. @param toType SQL type code defined in java.sql.Types. @return false (We currently do not support CONVERT at all. **/ static boolean supportsConvert (int fromType, int toType) { // We do not support this. return false; } /**

This class is a hashtable-like container for mapping JDBC to native scalar functions. **/ // @C1A Added this inner class to store mappings private static final class JDScalarTable { public static final int NOT_SUPPORTED = 0; private static final int HASH = 10; private String[][] keys = new String[HASH][]; private String[][] data = new String[HASH][]; private int[][] vrms = new int[HASH][]; /** Returns true if the function corresponding to key should be mapped for this VRM of the host. @param key The function key @param vrm The VRM of the host @return true if we should get the mapped function from the table **/ final boolean contains(String key, int vrm) { if (key == null) throw new NullPointerException("key"); int hash = (key.hashCode()<0?key.hashCode()*-1:key.hashCode()) % HASH; String[] keyChain = keys[hash]; int[] vrmChain = vrms[hash]; if (keyChain == null) return false; if (vrmChain == null) return false; for (int i=0; i vrm || vrmChain[i] == NOT_SUPPORTED)) { return true; } } return false; } /** Returns the function corresponding to the key and VRM. @param key The function key @param vrm The VRM of the host @return null if the key/vrm combination is not mapped **/ final String get(String key, int vrm) { if (key == null) throw new NullPointerException("key"); int hash = (key.hashCode()<0?key.hashCode()*-1:key.hashCode()) % HASH; synchronized(keys) { String[] keyChain = keys[hash]; int[] vrmChain = vrms[hash]; if (keyChain == null) return null; if (vrmChain == null) return null; for (int i=0; i vrm || vrmChain[i] == NOT_SUPPORTED)) { return data[hash][i]; } } } return null; } /** Sets the JDBC to native function mapping. The VRM indicates the earliest version of host to support the function. @param key The function key @param value The map for the key @param vrm The VRM of the host **/ final void put(String key, String value, int vrm) { if (key == null) throw new NullPointerException("key"); if (vrm < 0) throw new IllegalArgumentException("vrm"); int hash = (key.hashCode()<0?key.hashCode()*-1:key.hashCode()) % HASH; synchronized(keys) { String[] valueChain = data[hash]; String[] keyChain = keys[hash]; int[] vrmChain = vrms[hash]; if (keyChain == null) { // there are currently no keys in this chain of the hashtable so create a new chain keyChain = new String[] { key }; // create a new key chain valueChain = new String[] { value }; // create a new value chain vrmChain = new int[] { vrm }; // create a new vrm chain keys[hash] = keyChain; // set the key, value, and vrm data[hash] = valueChain; vrms[hash] = vrmChain; return; } else { // keys exist in this chain of the hashtable so add this one to the chain int len = keyChain.length; for (int i=0; i





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