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eclipse / jdt / eclipse.jdt.core / 70ef52c917d9aaa266e9afcd55e0a961adf566e0 / . / org.eclipse.jdt.core / search / org / eclipse / jdt / core / search / SearchPattern.java
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/*******************************************************************************
* Copyright (c) 2000, 2005 IBM Corporation and others.
* All rights reserved. This program and the accompanying materials
* are made available under the terms of the Eclipse Public License v1.0
* which accompanies this distribution, and is available at
* http://www.eclipse.org/legal/epl-v10.html
*
* Contributors:
* IBM Corporation - initial API and implementation
*******************************************************************************/
package org.eclipse.jdt.core.search;
import org.eclipse.jdt.core.*;
import org.eclipse.jdt.core.compiler.*;
import org.eclipse.jdt.internal.compiler.classfmt.ClassFileConstants;
import org.eclipse.jdt.internal.compiler.parser.Scanner;
import org.eclipse.jdt.internal.compiler.parser.ScannerHelper;
import org.eclipse.jdt.internal.compiler.parser.TerminalTokens;
import org.eclipse.jdt.internal.core.LocalVariable;
import org.eclipse.jdt.internal.core.search.indexing.IIndexConstants;
import org.eclipse.jdt.internal.core.search.matching.*;
/**
* A search pattern defines how search results are found. Use <code>SearchPattern.createPattern</code>
* to create a search pattern.
* <p>
* Search patterns are used during the search phase to decode index entries that were added during the indexing phase
* (see {@link SearchDocument#addIndexEntry(char[], char[])}). When an index is queried, the
* index categories and keys to consider are retrieved from the search pattern using {@link #getIndexCategories()} and
* {@link #getIndexKey()}, as well as the match rule (see {@link #getMatchRule()}). A blank pattern is
* then created (see {@link #getBlankPattern()}). This blank pattern is used as a record as follows.
* For each index entry in the given index categories and that starts with the given key, the blank pattern is fed using
* {@link #decodeIndexKey(char[])}. The original pattern is then asked if it matches the decoded key using
* {@link #matchesDecodedKey(SearchPattern)}. If it matches, a search doument is created for this index entry
* using {@link SearchParticipant#getDocument(String)}.
*
* </p><p>
* This class is intended to be subclassed by clients. A default behavior is provided for each of the methods above, that
* clients can ovveride if they wish.
* </p>
* @see #createPattern(org.eclipse.jdt.core.IJavaElement, int)
* @see #createPattern(String, int, int, int)
* @since 3.0
*/
public abstract class SearchPattern extends InternalSearchPattern {
// Rules for pattern matching: (exact, prefix, pattern) [ | case sensitive]
/**
* Match rule: The search pattern matches exactly the search result,
* that is, the source of the search result equals the search pattern.
*/
public static final int R_EXACT_MATCH = 0;
/**
* Match rule: The search pattern is a prefix of the search result.
*/
public static final int R_PREFIX_MATCH = 0x0001;
/**
* Match rule: The search pattern contains one or more wild cards ('*' or '?').
* A '*' wild-card can replace 0 or more characters in the search result.
* A '?' wild-card replaces exactly 1 character in the search result.
*/
public static final int R_PATTERN_MATCH = 0x0002;
/**
* Match rule: The search pattern contains a regular expression.
*/
public static final int R_REGEXP_MATCH = 0x0004;
/**
* Match rule: The search pattern matches the search result only if cases are the same.
* Can be combined to previous rules, e.g. {@link #R_EXACT_MATCH} | {@link #R_CASE_SENSITIVE}
*/
public static final int R_CASE_SENSITIVE = 0x0008;
/**
* Match rule: The search pattern matches search results as raw/parameterized types/methods with same erasure.
* This mode has no effect on other java elements search.<br>
* Type search example:
* <ul>
* <li>pattern: <code>List&lt;Exception&gt;</code></li>
* <li>match: <code>List&lt;Object&gt;</code></li>
* </ul>
* Method search example:
* <ul>
* <li>declaration: <code>&lt;T&gt;foo(T t)</code></li>
* <li>pattern: <code>&lt;Exception&gt;foo(new Exception())</code></li>
* <li>match: <code>&lt;Object&gt;foo(new Object())</code></li>
* </ul>
* Can be combined to all other match rules, e.g. {@link #R_CASE_SENSITIVE} | {@link #R_ERASURE_MATCH}
* This rule is not activated by default, so raw types or parameterized types with same erasure will not be found
* for pattern List&lt;String&gt;,
* Note that with this pattern, the match selection will be only on the erasure even for parameterized types.
* @since 3.1
*/
public static final int R_ERASURE_MATCH = 0x0010;
/**
* Match rule: The search pattern matches search results as raw/parameterized types/methods with equivalent type parameters.
* This mode has no effect on other java elements search.<br>
* Type search example:
* <ul>
* <li>pattern: <code>List&lt;Exception&gt;</code></li>
* <li>match:
* <ul>
* <li><code>List&lt;? extends Throwable&gt;</code></li>
* <li><code>List&lt;? super RuntimeException&gt;</code></li>
* <li><code>List&lt;?&gt;</code></li>
* </ul>
* </li>
* </ul>
* Method search example:
* <ul>
* <li>declaration: <code>&lt;T&gt;foo(T t)</code></li>
* <li>pattern: <code>&lt;Exception&gt;foo(new Exception())</code></li>
* <li>match:
* <ul>
* <li><code>&lt;? extends Throwable&gt;foo(new Exception())</code></li>
* <li><code>&lt;? super RuntimeException&gt;foo(new Exception())</code></li>
* <li><code>foo(new Exception())</code></li>
* </ul>
* </ul>
* Can be combined to all other match rules, e.g. {@link #R_CASE_SENSITIVE} | {@link #R_EQUIVALENT_MATCH}
* This rule is not activated by default, so raw types or equivalent parameterized types will not be found
* for pattern List&lt;String&gt;,
* This mode is overridden by {@link #R_ERASURE_MATCH} as erasure matches obviously include equivalent ones.
* That means that pattern with rule set to {@link #R_EQUIVALENT_MATCH} | {@link #R_ERASURE_MATCH}
* will return same results than rule only set with {@link #R_ERASURE_MATCH}.
* @since 3.1
*/
public static final int R_EQUIVALENT_MATCH = 0x0020;
/**
* Match rule: The search pattern matches exactly the search result,
* that is, the source of the search result equals the search pattern.
* @since 3.1
*/
public static final int R_FULL_MATCH = 0x0040;
/**
* Match rule: The search pattern contains a Camel Case expression.
* For example, <code>NPE</code> type string pattern will match
* <code>NullPointerException</code> type.
* @see CharOperation#camelCaseMatch(char[], char[]) for a detailed explanation
* of Camel Case matching.
*<br>
* Can be combined to {@link #R_PREFIX_MATCH} match rule. For example,
* when prefix match rule is combined with Camel Case match rule,
* <code>"nPE"</code> pattern will match <code>nPException</code>.
*<br>
* Match rule {@link #R_PATTERN_MATCH} may also be combined but both rules
* will not be used simultaneously as they are mutually exclusive.
* Used match rule depends on whether string pattern contains specific pattern
* characters (e.g. '*' or '?') or not. If it does, then only Pattern match rule
* will be used, otherwise only Camel Case match will be used.
* For example, with <code>"NPE"</code> string pattern, search will only use
* Camel Case match rule, but with <code>N*P*E*</code> string pattern, it will
* use only Pattern match rule.
*
* @since 3.2
*/
public static final int R_CAMELCASE_MATCH = 0x0080;
private static final int MODE_MASK = R_EXACT_MATCH | R_PREFIX_MATCH | R_PATTERN_MATCH | R_REGEXP_MATCH;
private int matchRule;
/**
* Creates a search pattern with the rule to apply for matching index keys.
* It can be exact match, prefix match, pattern match or regexp match.
* Rule can also be combined with a case sensitivity flag.
*
* @param matchRule one of {@link #R_EXACT_MATCH}, {@link #R_PREFIX_MATCH}, {@link #R_PATTERN_MATCH},
* {@link #R_REGEXP_MATCH}, {@link #R_CAMELCASE_MATCH} combined with one of following values:
* {@link #R_CASE_SENSITIVE}, {@link #R_ERASURE_MATCH} or {@link #R_EQUIVALENT_MATCH}.
* e.g. {@link #R_EXACT_MATCH} | {@link #R_CASE_SENSITIVE} if an exact and case sensitive match is requested,
* {@link #R_PREFIX_MATCH} if a prefix non case sensitive match is requested or {@link #R_EXACT_MATCH} | {@link #R_ERASURE_MATCH}
* if a non case sensitive and erasure match is requested.<br>
* Note that {@link #R_ERASURE_MATCH} or {@link #R_EQUIVALENT_MATCH} have no effect
* on non-generic types/methods search.<br>
* Note also that default behavior for generic types/methods search is to find exact matches.
*/
public SearchPattern(int matchRule) {
this.matchRule = matchRule;
// Set full match implicit mode
if ((matchRule & (R_EQUIVALENT_MATCH | R_ERASURE_MATCH )) == 0) {
this.matchRule |= R_FULL_MATCH;
}
}
/**
* Answers true if the pattern matches the given name using CamelCase rules, or false otherwise.
* CamelCase matching does NOT accept explicit wild-cards '*' and '?' and is inherently case sensitive.
* <br>
* CamelCase denotes the convention of writing compound names without spaces, and capitalizing every term.
* This function recognizes both upper and lower CamelCase, depending whether the leading character is capitalized
* or not. The leading part of an upper CamelCase pattern is assumed to contain a sequence of capitals which are appearing
* in the matching name; e.g. 'NPE' will match 'NullPointerException', but not 'NewPerfData'. A lower CamelCase pattern
* uses a lowercase first character. In Java, type names follow the upper CamelCase convention, whereas method or field
* names follow the lower CamelCase convention.
* <br>
* The pattern may contain trailing lowercase characters, which will be match in a case sensitive way. These characters must
* appear in sequence in the name, after the last matching capital of the pattern. For instance, 'NPExcep' will match
* 'NullPointerException', but not 'NullPointerExCEPTION'.
*
* For example:
* <ol>
* <li><pre>
* pattern = "NPE"
* name = NullPointerException
* result => true
* </pre>
* </li>
* <li><pre>
* pattern = "npe"
* name = NullPointerException
* result => false
* </pre>
* </li>
* </ol>
* @see CharOperation#camelCaseMatch(char[], char[])
* Implementation has been entirely copied from this method except for array lengthes
* which were obviously replaced with calls to {@link String#length()}.
*
* @param pattern the given pattern
* @param name the given name
* @return true if the pattern matches the given name, false otherwise
* @since 3.2
*/
public static final boolean camelCaseMatch(String pattern, String name) {
if (pattern == null)
return true; // null pattern is equivalent to '*'
if (name == null)
return false; // null name cannot match
return camelCaseMatch(pattern, 0, pattern.length(), name, 0, name.length());
}
/**
* Answers true if a sub-pattern matches the subpart of the given name using CamelCase rules, or false otherwise.
* CamelCase matching does NOT accept explicit wild-cards '*' and '?' and is inherently case sensitive.
* Can match only subset of name/pattern, considering end positions as non-inclusive.
* The subpattern is defined by the patternStart and patternEnd positions.
* <br>
* CamelCase denotes the convention of writing compound names without spaces, and capitalizing every term.
* This function recognizes both upper and lower CamelCase, depending whether the leading character is capitalized
* or not. The leading part of an upper CamelCase pattern is assumed to contain a sequence of capitals which are appearing
* in the matching name; e.g. 'NPE' will match 'NullPointerException', but not 'NewPerfData'. A lower CamelCase pattern
* uses a lowercase first character. In Java, type names follow the upper CamelCase convention, whereas method or field
* names follow the lower CamelCase convention.
* <br>
* The pattern may contain trailing lowercase characters, which will be match in a case sensitive way. These characters must
* appear in sequence in the name, after the last matching capital of the pattern. For instance, 'NPExcep' will match
* 'NullPointerException', but not 'NullPointerExCEPTION'.
*
* For example:
* <ol>
* <li><pre>
* pattern = "NPE"
* patternStart = 1
* patternEnd = 3
* name = NullPointerException
* nameStart = 0
* nameEnd = 20
* result => true
* </pre>
* </li>
* <li><pre>
* pattern = "npe"
* patternStart = 1
* patternEnd = 3
* name = NullPointerException
* nameStart = 0
* nameEnd = 20
* result => false
* </pre>
* </li>
* </ol>
* @see CharOperation#camelCaseMatch(char[], int, int, char[], int, int)
* Implementation has been entirely copied from this method except for array lengthes
* which were obviously replaced with calls to {@link String#length()} and
* for array direct access which were replaced with calls to {@link String#charAt(int)}.
*
* @param pattern the given pattern
* @param patternStart the given pattern start
* @param patternEnd the given pattern end
* @param name the given name
* @param nameStart the given name start
* @param nameEnd the given name end
* @return true if a sub-pattern matches the subpart of the given name, false otherwise
* @since 3.2
*/
public static final boolean camelCaseMatch(String pattern, int patternStart, int patternEnd, String name, int nameStart, int nameEnd) {
if (name == null)
return false; // null name cannot match
if (pattern == null)
return true; // null pattern is equivalent to '*'
if (patternEnd < 0) patternEnd = pattern.length();
if (nameEnd < 0) nameEnd = name.length();
if (patternEnd <= patternStart) return nameEnd <= nameStart;
if (nameEnd <= nameStart) return false;
// check first pattern char
if (name.charAt(nameStart) != pattern.charAt(patternStart)) {
// first char must strictly match (upper/lower)
return false;
}
char patternChar, nameChar;
int iPattern = patternStart+1;
int iName = nameStart+1;
nextPatternChar: while (iPattern < patternEnd) {
// check patternChar, keep camelCasing only if uppercase
if ((patternChar = pattern.charAt(iPattern)) < ScannerHelper.MAX_OBVIOUS) {
switch (ScannerHelper.OBVIOUS_IDENT_CHAR_NATURES[patternChar]) {
case ScannerHelper.C_UPPER_LETTER :
// still uppercase
break;
default:
// end of camelCase part of pattern
break nextPatternChar;
}
} else if (Character.isJavaIdentifierPart(patternChar)
&& !Character.isUpperCase(patternChar)) {
// end of camelCase part of pattern
break nextPatternChar;
}
nextNameChar: while (iName < nameEnd) {
if ((nameChar = name.charAt(iName)) != patternChar) {
if (nameChar < ScannerHelper.MAX_OBVIOUS) {
switch (ScannerHelper.OBVIOUS_IDENT_CHAR_NATURES[nameChar]) {
case ScannerHelper.C_LOWER_LETTER :
case ScannerHelper.C_IDENT_PART :
case ScannerHelper.C_DIGIT :
// lowercase/digit char is ignored
iName++;
continue nextNameChar;
}
} else if (Character.isJavaIdentifierPart(nameChar)
&& !Character.isUpperCase(nameChar)) {
// lowercase name char is ignored
iName++;
continue nextNameChar;
}
// mismatch, either uppercase in name or non case char ('/' etc)--> reject
return false;
} else {
// pattern char == name char (uppercase)
iName++;
iPattern++;
continue nextPatternChar;
}
}
if (iPattern == patternEnd) return true;
if (iName == nameEnd) return false;
continue nextPatternChar;
}
// check trailing part in case sensitive way
while (iPattern < patternEnd && iName < nameEnd) {
if (pattern.charAt(iPattern) != name.charAt(iName)) {
return false;
}
iPattern++;
iName++;
}
return iPattern == patternEnd;
}
/**
* Returns a search pattern that combines the given two patterns into an
* "and" pattern. The search result will match both the left pattern and
* the right pattern.
*
* @param leftPattern the left pattern
* @param rightPattern the right pattern
* @return an "and" pattern
*/
public static SearchPattern createAndPattern(SearchPattern leftPattern, SearchPattern rightPattern) {
return MatchLocator.createAndPattern(leftPattern, rightPattern);
}
/**
* Field pattern are formed by [declaringType.]name[ type]
* e.g. java.lang.String.serialVersionUID long
* field*
*/
private static SearchPattern createFieldPattern(String patternString, int limitTo, int matchRule) {
Scanner scanner = new Scanner(false /*comment*/, true /*whitespace*/, false /*nls*/, ClassFileConstants.JDK1_3/*sourceLevel*/, null /*taskTags*/, null/*taskPriorities*/, true/*taskCaseSensitive*/);
scanner.setSource(patternString.toCharArray());
final int InsideDeclaringPart = 1;
final int InsideType = 2;
int lastToken = -1;
String declaringType = null, fieldName = null;
String type = null;
int mode = InsideDeclaringPart;
int token;
try {
token = scanner.getNextToken();
} catch (InvalidInputException e) {
return null;
}
while (token != TerminalTokens.TokenNameEOF) {
switch(mode) {
// read declaring type and fieldName
case InsideDeclaringPart :
switch (token) {
case TerminalTokens.TokenNameDOT:
if (declaringType == null) {
if (fieldName == null) return null;
declaringType = fieldName;
} else {
String tokenSource = scanner.getCurrentTokenString();
declaringType += tokenSource + fieldName;
}
fieldName = null;
break;
case TerminalTokens.TokenNameWHITESPACE:
if (!(TerminalTokens.TokenNameWHITESPACE == lastToken || TerminalTokens.TokenNameDOT == lastToken))
mode = InsideType;
break;
default: // all other tokens are considered identifiers (see bug 21763 Problem in Java search [search])
if (fieldName == null)
fieldName = scanner.getCurrentTokenString();
else
fieldName += scanner.getCurrentTokenString();
}
break;
// read type
case InsideType:
switch (token) {
case TerminalTokens.TokenNameWHITESPACE:
break;
default: // all other tokens are considered identifiers (see bug 21763 Problem in Java search [search])
if (type == null)
type = scanner.getCurrentTokenString();
else
type += scanner.getCurrentTokenString();
}
break;
}
lastToken = token;
try {
token = scanner.getNextToken();
} catch (InvalidInputException e) {
return null;
}
}
if (fieldName == null) return null;
char[] fieldNameChars = fieldName.toCharArray();
if (fieldNameChars.length == 1 && fieldNameChars[0] == '*') fieldNameChars = null;
char[] declaringTypeQualification = null, declaringTypeSimpleName = null;
char[] typeQualification = null, typeSimpleName = null;
// extract declaring type infos
if (declaringType != null) {
char[] declaringTypePart = declaringType.toCharArray();
int lastDotPosition = CharOperation.lastIndexOf('.', declaringTypePart);
if (lastDotPosition >= 0) {
declaringTypeQualification = CharOperation.subarray(declaringTypePart, 0, lastDotPosition);
if (declaringTypeQualification.length == 1 && declaringTypeQualification[0] == '*')
declaringTypeQualification = null;
declaringTypeSimpleName = CharOperation.subarray(declaringTypePart, lastDotPosition+1, declaringTypePart.length);
} else {
declaringTypeQualification = null;
declaringTypeSimpleName = declaringTypePart;
}
if (declaringTypeSimpleName.length == 1 && declaringTypeSimpleName[0] == '*')
declaringTypeSimpleName = null;
}
// extract type infos
if (type != null) {
char[] typePart = type.toCharArray();
int lastDotPosition = CharOperation.lastIndexOf('.', typePart);
if (lastDotPosition >= 0) {
typeQualification = CharOperation.subarray(typePart, 0, lastDotPosition);
if (typeQualification.length == 1 && typeQualification[0] == '*') {
typeQualification = null;
} else {
// prefix with a '*' as the full qualification could be bigger (because of an import)
typeQualification = CharOperation.concat(IIndexConstants.ONE_STAR, typeQualification);
}
typeSimpleName = CharOperation.subarray(typePart, lastDotPosition+1, typePart.length);
} else {
typeQualification = null;
typeSimpleName = typePart;
}
if (typeSimpleName.length == 1 && typeSimpleName[0] == '*')
typeSimpleName = null;
}
// Create field pattern
boolean findDeclarations = false;
boolean readAccess = false;
boolean writeAccess = false;
switch (limitTo) {
case IJavaSearchConstants.DECLARATIONS :
findDeclarations = true;
break;
case IJavaSearchConstants.REFERENCES :
readAccess = true;
writeAccess = true;
break;
case IJavaSearchConstants.READ_ACCESSES :
readAccess = true;
break;
case IJavaSearchConstants.WRITE_ACCESSES :
writeAccess = true;
break;
case IJavaSearchConstants.ALL_OCCURRENCES :
findDeclarations = true;
readAccess = true;
writeAccess = true;
break;
}
return new FieldPattern(
findDeclarations,
readAccess,
writeAccess,
fieldNameChars,
declaringTypeQualification,
declaringTypeSimpleName,
typeQualification,
typeSimpleName,
matchRule);
}
/**
* Method pattern are formed by:<br>
* [declaringType '.'] ['&lt;' typeArguments '&gt;'] selector ['(' parameterTypes ')'] [returnType]
* <br>e.g.<ul>
* <li>java.lang.Runnable.run() void</li>
* <li>main(*)</li>
* <li>&lt;String&gt;toArray(String[])</li>
* </ul>
* Constructor pattern are formed by:<br>
* [declaringQualification '.'] ['&lt;' typeArguments '&gt;'] type ['(' parameterTypes ')']
* <br>e.g.<ul>
* <li>java.lang.Object()</li>
* <li>Main(*)</li>
* <li>&lt;Exception&gt;Sample(Exception)</li>
* </ul>
* Type arguments have the same pattern that for type patterns
* @see #createTypePattern(String,int,int,char)
*/
private static SearchPattern createMethodOrConstructorPattern(String patternString, int limitTo, int matchRule, boolean isConstructor) {
Scanner scanner = new Scanner(false /*comment*/, true /*whitespace*/, false /*nls*/, ClassFileConstants.JDK1_3/*sourceLevel*/, null /*taskTags*/, null/*taskPriorities*/, true/*taskCaseSensitive*/);
scanner.setSource(patternString.toCharArray());
final int InsideSelector = 1;
final int InsideTypeArguments = 2;
final int InsideParameter = 3;
final int InsideReturnType = 4;
int lastToken = -1;
String declaringType = null, selector = null, parameterType = null;
String[] parameterTypes = null;
char[][] typeArguments = null;
String typeArgumentsString = null;
int parameterCount = -1;
String returnType = null;
boolean foundClosingParenthesis = false;
int mode = InsideSelector;
int token, argCount = 0;
try {
token = scanner.getNextToken();
} catch (InvalidInputException e) {
return null;
}
while (token != TerminalTokens.TokenNameEOF) {
switch(mode) {
// read declaring type and selector
case InsideSelector :
if (argCount == 0) {
switch (token) {
case TerminalTokens.TokenNameLESS:
argCount++;
if (selector == null || lastToken == TerminalTokens.TokenNameDOT) {
if (typeArgumentsString != null) return null; // invalid syntax
typeArgumentsString = scanner.getCurrentTokenString();
mode = InsideTypeArguments;
break;
}
if (declaringType == null) {
declaringType = selector;
} else {
declaringType += '.' + selector;
}
declaringType += scanner.getCurrentTokenString();
selector = null;
break;
case TerminalTokens.TokenNameDOT:
if (typeArgumentsString != null) return null; // invalid syntax
if (declaringType == null) {
if (selector == null) return null; // invalid syntax
declaringType = selector;
} else if (selector != null) {
declaringType += scanner.getCurrentTokenString() + selector;
}
selector = null;
break;
case TerminalTokens.TokenNameLPAREN:
parameterTypes = new String[5];
parameterCount = 0;
mode = InsideParameter;
break;
case TerminalTokens.TokenNameWHITESPACE:
switch (lastToken) {
case TerminalTokens.TokenNameWHITESPACE:
case TerminalTokens.TokenNameDOT:
case TerminalTokens.TokenNameGREATER:
case TerminalTokens.TokenNameRIGHT_SHIFT:
case TerminalTokens.TokenNameUNSIGNED_RIGHT_SHIFT:
break;
default:
mode = InsideReturnType;
break;
}
break;
default: // all other tokens are considered identifiers (see bug 21763 Problem in Java search [search])
if (selector == null)
selector = scanner.getCurrentTokenString();
else
selector += scanner.getCurrentTokenString();
break;
}
} else {
if (declaringType == null) return null; // invalid syntax
switch (token) {
case TerminalTokens.TokenNameGREATER:
case TerminalTokens.TokenNameRIGHT_SHIFT:
case TerminalTokens.TokenNameUNSIGNED_RIGHT_SHIFT:
argCount--;
break;
case TerminalTokens.TokenNameLESS:
argCount++;
break;
}
declaringType += scanner.getCurrentTokenString();
}
break;
// read type arguments
case InsideTypeArguments:
if (typeArgumentsString == null) return null; // invalid syntax
typeArgumentsString += scanner.getCurrentTokenString();
switch (token) {
case TerminalTokens.TokenNameGREATER:
case TerminalTokens.TokenNameRIGHT_SHIFT:
case TerminalTokens.TokenNameUNSIGNED_RIGHT_SHIFT:
argCount--;
if (argCount == 0) {
String pseudoType = "Type"+typeArgumentsString; //$NON-NLS-1$
typeArguments = Signature.getTypeArguments(Signature.createTypeSignature(pseudoType, false).toCharArray());
mode = InsideSelector;
}
break;
case TerminalTokens.TokenNameLESS:
argCount++;
break;
}
break;
// read parameter types
case InsideParameter :
if (argCount == 0) {
switch (token) {
case TerminalTokens.TokenNameWHITESPACE:
break;
case TerminalTokens.TokenNameCOMMA:
if (parameterType == null) return null;
if (parameterTypes.length == parameterCount)
System.arraycopy(parameterTypes, 0, parameterTypes = new String[parameterCount*2], 0, parameterCount);
parameterTypes[parameterCount++] = parameterType;
parameterType = null;
break;
case TerminalTokens.TokenNameRPAREN:
foundClosingParenthesis = true;
if (parameterType != null){
if (parameterTypes.length == parameterCount)
System.arraycopy(parameterTypes, 0, parameterTypes = new String[parameterCount*2], 0, parameterCount);
parameterTypes[parameterCount++] = parameterType;
}
mode = isConstructor ? InsideTypeArguments : InsideReturnType;
break;
case TerminalTokens.TokenNameLESS:
argCount++;
if (parameterType == null) return null; // invalid syntax
// fall through next case to add token
default: // all other tokens are considered identifiers (see bug 21763 Problem in Java search [search])
if (parameterType == null)
parameterType = scanner.getCurrentTokenString();
else
parameterType += scanner.getCurrentTokenString();
}
} else {
if (parameterType == null) return null; // invalid syntax
switch (token) {
case TerminalTokens.TokenNameGREATER:
case TerminalTokens.TokenNameRIGHT_SHIFT:
case TerminalTokens.TokenNameUNSIGNED_RIGHT_SHIFT:
argCount--;
break;
case TerminalTokens.TokenNameLESS:
argCount++;
break;
}
parameterType += scanner.getCurrentTokenString();
}
break;
// read return type
case InsideReturnType:
if (argCount == 0) {
switch (token) {
case TerminalTokens.TokenNameWHITESPACE:
break;
case TerminalTokens.TokenNameLPAREN:
parameterTypes = new String[5];
parameterCount = 0;
mode = InsideParameter;
break;
case TerminalTokens.TokenNameLESS:
argCount++;
if (returnType == null) return null; // invalid syntax
// fall through next case to add token
default: // all other tokens are considered identifiers (see bug 21763 Problem in Java search [search])
if (returnType == null)
returnType = scanner.getCurrentTokenString();
else
returnType += scanner.getCurrentTokenString();
}
} else {
if (returnType == null) return null; // invalid syntax
switch (token) {
case TerminalTokens.TokenNameGREATER:
case TerminalTokens.TokenNameRIGHT_SHIFT:
case TerminalTokens.TokenNameUNSIGNED_RIGHT_SHIFT:
argCount--;
break;
case TerminalTokens.TokenNameLESS:
argCount++;
break;
}
returnType += scanner.getCurrentTokenString();
}
break;
}
lastToken = token;
try {
token = scanner.getNextToken();
} catch (InvalidInputException e) {
return null;
}
}
// parenthesis mismatch
if (parameterCount>0 && !foundClosingParenthesis) return null;
// type arguments mismatch
if (argCount > 0) return null;
char[] selectorChars = null;
if (isConstructor) {
// retrieve type for constructor patterns
if (declaringType == null)
declaringType = selector;
else if (selector != null)
declaringType += '.' + selector;
} else {
// get selector chars
if (selector == null) return null;
selectorChars = selector.toCharArray();
if (selectorChars.length == 1 && selectorChars[0] == '*')
selectorChars = null;
}
char[] declaringTypeQualification = null, declaringTypeSimpleName = null;
char[] returnTypeQualification = null, returnTypeSimpleName = null;
char[][] parameterTypeQualifications = null, parameterTypeSimpleNames = null;
// Signatures
String declaringTypeSignature = null;
String returnTypeSignature = null;
String[] parameterTypeSignatures = null;
// extract declaring type infos
if (declaringType != null) {
// get declaring type part and signature
char[] declaringTypePart = null;
try {
declaringTypeSignature = Signature.createTypeSignature(declaringType, false);
if (declaringTypeSignature.indexOf(Signature.C_GENERIC_START) < 0) {
declaringTypePart = declaringType.toCharArray();
} else {
declaringTypePart = Signature.toCharArray(Signature.getTypeErasure(declaringTypeSignature.toCharArray()));
}
}
catch (IllegalArgumentException iae) {
// declaring type is invalid
return null;
}
int lastDotPosition = CharOperation.lastIndexOf('.', declaringTypePart);
if (lastDotPosition >= 0) {
declaringTypeQualification = CharOperation.subarray(declaringTypePart, 0, lastDotPosition);
if (declaringTypeQualification.length == 1 && declaringTypeQualification[0] == '*')
declaringTypeQualification = null;
declaringTypeSimpleName = CharOperation.subarray(declaringTypePart, lastDotPosition+1, declaringTypePart.length);
} else {
declaringTypeQualification = null;
declaringTypeSimpleName = declaringTypePart;
}
if (declaringTypeSimpleName.length == 1 && declaringTypeSimpleName[0] == '*')
declaringTypeSimpleName = null;
}
// extract parameter types infos
if (parameterCount >= 0) {
parameterTypeQualifications = new char[parameterCount][];
parameterTypeSimpleNames = new char[parameterCount][];
parameterTypeSignatures = new String[parameterCount];
for (int i = 0; i < parameterCount; i++) {
// get parameter type part and signature
char[] parameterTypePart = null;
try {
parameterTypeSignatures[i] = Signature.createTypeSignature(parameterTypes[i], false);
if (parameterTypeSignatures[i].indexOf(Signature.C_GENERIC_START) < 0) {
parameterTypePart = parameterTypes[i].toCharArray();
} else {
parameterTypePart = Signature.toCharArray(Signature.getTypeErasure(parameterTypeSignatures[i].toCharArray()));
}
}
catch (IllegalArgumentException iae) {
// string is not a valid type syntax
return null;
}
int lastDotPosition = CharOperation.lastIndexOf('.', parameterTypePart);
if (lastDotPosition >= 0) {
parameterTypeQualifications[i] = CharOperation.subarray(parameterTypePart, 0, lastDotPosition);
if (parameterTypeQualifications[i].length == 1 && parameterTypeQualifications[i][0] == '*') {
parameterTypeQualifications[i] = null;
} else {
// prefix with a '*' as the full qualification could be bigger (because of an import)
parameterTypeQualifications[i] = CharOperation.concat(IIndexConstants.ONE_STAR, parameterTypeQualifications[i]);
}
parameterTypeSimpleNames[i] = CharOperation.subarray(parameterTypePart, lastDotPosition+1, parameterTypePart.length);
} else {
parameterTypeQualifications[i] = null;
parameterTypeSimpleNames[i] = parameterTypePart;
}
if (parameterTypeSimpleNames[i].length == 1 && parameterTypeSimpleNames[i][0] == '*')
parameterTypeSimpleNames[i] = null;
}
}
// extract return type infos
if (returnType != null) {
// get return type part and signature
char[] returnTypePart = null;
try {
returnTypeSignature = Signature.createTypeSignature(returnType, false);
if (returnTypeSignature.indexOf(Signature.C_GENERIC_START) < 0) {
returnTypePart = returnType.toCharArray();
} else {
returnTypePart = Signature.toCharArray(Signature.getTypeErasure(returnTypeSignature.toCharArray()));
}
}
catch (IllegalArgumentException iae) {
// declaring type is invalid
return null;
}
int lastDotPosition = CharOperation.lastIndexOf('.', returnTypePart);
if (lastDotPosition >= 0) {
returnTypeQualification = CharOperation.subarray(returnTypePart, 0, lastDotPosition);
if (returnTypeQualification.length == 1 && returnTypeQualification[0] == '*') {
returnTypeQualification = null;
} else {
// because of an import
returnTypeQualification = CharOperation.concat(IIndexConstants.ONE_STAR, returnTypeQualification);
}
returnTypeSimpleName = CharOperation.subarray(returnTypePart, lastDotPosition+1, returnTypePart.length);
} else {
returnTypeQualification = null;
returnTypeSimpleName = returnTypePart;
}
if (returnTypeSimpleName.length == 1 && returnTypeSimpleName[0] == '*')
returnTypeSimpleName = null;
}
// Create method/constructor pattern
boolean findDeclarations = true;
boolean findReferences = true;
switch (limitTo) {
case IJavaSearchConstants.DECLARATIONS :
findReferences = false;
break;
case IJavaSearchConstants.REFERENCES :
findDeclarations = false;
break;
case IJavaSearchConstants.ALL_OCCURRENCES :
break;
}
if (isConstructor) {
return new ConstructorPattern(
findDeclarations,
findReferences,
declaringTypeSimpleName,
declaringTypeQualification,
declaringTypeSignature,
parameterTypeQualifications,
parameterTypeSimpleNames,
parameterTypeSignatures,
typeArguments,
matchRule);
} else {
return new MethodPattern(
findDeclarations,
findReferences,
selectorChars,
declaringTypeQualification,
declaringTypeSimpleName,
declaringTypeSignature,
returnTypeQualification,
returnTypeSimpleName,
returnTypeSignature,
parameterTypeQualifications,
parameterTypeSimpleNames,
parameterTypeSignatures,
typeArguments,
matchRule);
}
}
/**
* Returns a search pattern that combines the given two patterns into an
* "or" pattern. The search result will match either the left pattern or the
* right pattern.
*
* @param leftPattern the left pattern
* @param rightPattern the right pattern
* @return an "or" pattern
*/
public static SearchPattern createOrPattern(SearchPattern leftPattern, SearchPattern rightPattern) {
return new OrPattern(leftPattern, rightPattern);
}
private static SearchPattern createPackagePattern(String patternString, int limitTo, int matchRule) {
switch (limitTo) {
case IJavaSearchConstants.DECLARATIONS :
return new PackageDeclarationPattern(patternString.toCharArray(), matchRule);
case IJavaSearchConstants.REFERENCES :
return new PackageReferencePattern(patternString.toCharArray(), matchRule);
case IJavaSearchConstants.ALL_OCCURRENCES :
return new OrPattern(
new PackageDeclarationPattern(patternString.toCharArray(), matchRule),
new PackageReferencePattern(patternString.toCharArray(), matchRule)
);
}
return null;
}
/**
* Returns a search pattern based on a given string pattern. The string patterns support '*' wild-cards.
* The remaining parameters are used to narrow down the type of expected results.
*
* <br>
* Examples:
* <ul>
* <li>search for case insensitive references to <code>Object</code>:
* <code>createSearchPattern("Object", TYPE, REFERENCES, false);</code></li>
* <li>search for case sensitive references to exact <code>Object()</code> constructor:
* <code>createSearchPattern("java.lang.Object()", CONSTRUCTOR, REFERENCES, true);</code></li>
* <li>search for implementers of <code>java.lang.Runnable</code>:
* <code>createSearchPattern("java.lang.Runnable", TYPE, IMPLEMENTORS, true);</code></li>
* </ul>
* @param stringPattern the given pattern
* @param searchFor determines the nature of the searched elements
* <ul>
* <li>{@link IJavaSearchConstants#CLASS}: only look for classes</li>
* <li>{@link IJavaSearchConstants#INTERFACE}: only look for interfaces</li>
* <li>{@link IJavaSearchConstants#ENUM}: only look for enumeration</li>
* <li>{@link IJavaSearchConstants#ANNOTATION_TYPE}: only look for annotation type</li>
* <li>{@link IJavaSearchConstants#CLASS_AND_ENUM}: only look for classes and enumerations</li>
* <li>{@link IJavaSearchConstants#CLASS_AND_INTERFACE}: only look for classes and interfaces</li>
* <li>{@link IJavaSearchConstants#TYPE}: look for all types (ie. classes, interfaces, enum and annotation types)</li>
* <li>{@link IJavaSearchConstants#FIELD}: look for fields</li>
* <li>{@link IJavaSearchConstants#METHOD}: look for methods</li>
* <li>{@link IJavaSearchConstants#CONSTRUCTOR}: look for constructors</li>
* <li>{@link IJavaSearchConstants#PACKAGE}: look for packages</li>
* </ul>
* @param limitTo determines the nature of the expected matches
* <ul>
* <li>{@link IJavaSearchConstants#DECLARATIONS}: will search declarations matching
* with the corresponding element. In case the element is a method, declarations of matching
* methods in subtypes will also be found, allowing to find declarations of abstract methods, etc.<br>
* Note that additional flags {@link IJavaSearchConstants#IGNORE_DECLARING_TYPE} and
* {@link IJavaSearchConstants#IGNORE_RETURN_TYPE} are ignored for string patterns.
* This is due to the fact that client may omit to define them in string pattern to have same behavior.
* </li>
* <li>{@link IJavaSearchConstants#REFERENCES}: will search references to the given element.</li>
* <li>{@link IJavaSearchConstants#ALL_OCCURRENCES}: will search for either declarations or
* references as specified above.
* </li>
* <li>{@link IJavaSearchConstants#IMPLEMENTORS}: for interface, will find all types
* which implements a given interface.
* </li>
* </ul>
* @param matchRule one of {@link #R_EXACT_MATCH}, {@link #R_PREFIX_MATCH}, {@link #R_PATTERN_MATCH},
* {@link #R_REGEXP_MATCH}, {@link #R_CAMELCASE_MATCH} combined with one of following values:
* {@link #R_CASE_SENSITIVE}, {@link #R_ERASURE_MATCH} or {@link #R_EQUIVALENT_MATCH}.
* e.g. {@link #R_EXACT_MATCH} | {@link #R_CASE_SENSITIVE} if an exact and case sensitive match is requested,
* {@link #R_PREFIX_MATCH} if a prefix non case sensitive match is requested or {@link #R_EXACT_MATCH} | {@link #R_ERASURE_MATCH}
* if a non case sensitive and erasure match is requested.<br>
* Note that {@link #R_ERASURE_MATCH} or {@link #R_EQUIVALENT_MATCH} have no effect
* on non-generic types/methods search.<br>
* Note also that default behavior for generic types/methods search is to find exact matches.
* @return a search pattern on the given string pattern, or <code>null</code> if the string pattern is ill-formed
*/
public static SearchPattern createPattern(String stringPattern, int searchFor, int limitTo, int matchRule) {
if (stringPattern == null || stringPattern.length() == 0 && searchFor != IJavaSearchConstants.PACKAGE) return null;
if ((matchRule = validateMatchRule(stringPattern, matchRule)) == -1) {
return null;
}
// Ignore additional nature flags
limitTo &= ~(IJavaSearchConstants.IGNORE_DECLARING_TYPE+IJavaSearchConstants.IGNORE_RETURN_TYPE);
switch (searchFor) {
case IJavaSearchConstants.CLASS:
return createTypePattern(stringPattern, limitTo, matchRule, IIndexConstants.CLASS_SUFFIX);
case IJavaSearchConstants.CLASS_AND_INTERFACE:
return createTypePattern(stringPattern, limitTo, matchRule, IIndexConstants.CLASS_AND_INTERFACE_SUFFIX);
case IJavaSearchConstants.CLASS_AND_ENUM:
return createTypePattern(stringPattern, limitTo, matchRule, IIndexConstants.CLASS_AND_ENUM_SUFFIX);
case IJavaSearchConstants.INTERFACE:
return createTypePattern(stringPattern, limitTo, matchRule, IIndexConstants.INTERFACE_SUFFIX);
case IJavaSearchConstants.ENUM:
return createTypePattern(stringPattern, limitTo, matchRule, IIndexConstants.ENUM_SUFFIX);
case IJavaSearchConstants.ANNOTATION_TYPE:
return createTypePattern(stringPattern, limitTo, matchRule, IIndexConstants.ANNOTATION_TYPE_SUFFIX);
case IJavaSearchConstants.TYPE:
return createTypePattern(stringPattern, limitTo, matchRule, IIndexConstants.TYPE_SUFFIX);
case IJavaSearchConstants.METHOD:
return createMethodOrConstructorPattern(stringPattern, limitTo, matchRule, false/*not a constructor*/);
case IJavaSearchConstants.CONSTRUCTOR:
return createMethodOrConstructorPattern(stringPattern, limitTo, matchRule, true/*constructor*/);
case IJavaSearchConstants.FIELD:
return createFieldPattern(stringPattern, limitTo, matchRule);
case IJavaSearchConstants.PACKAGE:
return createPackagePattern(stringPattern, limitTo, matchRule);
}
return null;
}
/**
* Returns a search pattern based on a given Java element.
* The pattern is used to trigger the appropriate search, and can be parameterized as follows:
*
* @param element the Java element the search pattern is based on
* @param limitTo determines the nature of the expected matches
* <ul>
* <li>{@link IJavaSearchConstants#DECLARATIONS}: will search declarations matching
* with the corresponding element. In case the element is a method, declarations of matching
* methods in subtypes will also be found, allowing to find declarations of abstract methods, etc.
* Some additional flags may be specified while searching declaration:
* <ul>
* <li>{@link IJavaSearchConstants#IGNORE_DECLARING_TYPE}: declaring type will be ignored
* during the search.<br>
* For example using following test case:
* <pre>
* class A { A method() { return null; } }
* class B extends A { B method() { return null; } }
* class C { A method() { return null; } }
* </pre>
* search for <code>method</code> declaration with this flag
* will return 2 matches: in A and in C
* </li>
* <li>{@link IJavaSearchConstants#IGNORE_RETURN_TYPE}: return type will be ignored
* during the search.<br>
* Using same example, search for <code>method</code> declaration with this flag
* will return 2 matches: in A and in B.
* </li>
* <ul>
* Note that these two flags may be combined and both declaring and return types can be ignored
* during the search. Then, using same example, search for <code>method</code> declaration
* with these 2 flags will return 3 matches: in A, in B and in C
* </li>
* <li>{@link IJavaSearchConstants#REFERENCES}: will search references to the given element.</li>
* <li>{@link IJavaSearchConstants#ALL_OCCURRENCES}: will search for either declarations or
* references as specified above.
* </li>
* <li>{@link IJavaSearchConstants#IMPLEMENTORS}: for interface, will find all types
* which implements a given interface.
* </li>
* </ul>
* @return a search pattern for a Java element or <code>null</code> if the given element is ill-formed
*/
public static SearchPattern createPattern(IJavaElement element, int limitTo) {
return createPattern(element, limitTo, R_EXACT_MATCH | R_CASE_SENSITIVE);
}
/**
* Returns a search pattern based on a given Java element.
* The pattern is used to trigger the appropriate search, and can be parameterized as follows:
*
* @param element the Java element the search pattern is based on
* @param limitTo determines the nature of the expected matches
* <ul>
* <li>{@link IJavaSearchConstants#DECLARATIONS}: will search declarations matching
* with the corresponding element. In case the element is a method, declarations of matching
* methods in subtypes will also be found, allowing to find declarations of abstract methods, etc.
* Some additional flags may be specified while searching declaration:
* <ul>
* <li>{@link IJavaSearchConstants#IGNORE_DECLARING_TYPE}: declaring type will be ignored
* during the search.<br>
* For example using following test case:
* <pre>
* class A { A method() { return null; } }
* class B extends A { B method() { return null; } }
* class C { A method() { return null; } }
* </pre>
* search for <code>method</code> declaration with this flag
* will return 2 matches: in A and in C
* </li>
* <li>{@link IJavaSearchConstants#IGNORE_RETURN_TYPE}: return type will be ignored
* during the search.<br>
* Using same example, search for <code>method</code> declaration with this flag
* will return 2 matches: in A and in B.
* </li>
* <ul>
* Note that these two flags may be combined and both declaring and return types can be ignored
* during the search. Then, using same example, search for <code>method</code> declaration
* with these 2 flags will return 3 matches: in A, in B and in C
* </li>
* <li>{@link IJavaSearchConstants#REFERENCES}: will search references to the given element.</li>
* <li>{@link IJavaSearchConstants#ALL_OCCURRENCES}: will search for either declarations or
* references as specified above.
* </li>
* <li>{@link IJavaSearchConstants#IMPLEMENTORS}: for interface, will find all types
* which implements a given interface.
* </li>
* </ul>
* @param matchRule one of {@link #R_EXACT_MATCH}, {@link #R_PREFIX_MATCH}, {@link #R_PATTERN_MATCH},
* {@link #R_REGEXP_MATCH}, {@link #R_CAMELCASE_MATCH} combined with one of following values:
* {@link #R_CASE_SENSITIVE}, {@link #R_ERASURE_MATCH} or {@link #R_EQUIVALENT_MATCH}.
* e.g. {@link #R_EXACT_MATCH} | {@link #R_CASE_SENSITIVE} if an exact and case sensitive match is requested,
* {@link #R_PREFIX_MATCH} if a prefix non case sensitive match is requested or {@link #R_EXACT_MATCH} |{@link #R_ERASURE_MATCH}
* if a non case sensitive and erasure match is requested.<br>
* Note that {@link #R_ERASURE_MATCH} or {@link #R_EQUIVALENT_MATCH} have no effect on non-generic types
* or methods search.<br>
* Note also that default behavior for generic types or methods is to find exact matches.
* @return a search pattern for a Java element or <code>null</code> if the given element is ill-formed
* @since 3.1
*/
public static SearchPattern createPattern(IJavaElement element, int limitTo, int matchRule) {
SearchPattern searchPattern = null;
int lastDot;
boolean ignoreDeclaringType = false;
boolean ignoreReturnType = false;
int maskedLimitTo = limitTo & ~(IJavaSearchConstants.IGNORE_DECLARING_TYPE+IJavaSearchConstants.IGNORE_RETURN_TYPE);
if (maskedLimitTo == IJavaSearchConstants.DECLARATIONS || maskedLimitTo == IJavaSearchConstants.ALL_OCCURRENCES) {
ignoreDeclaringType = (limitTo & IJavaSearchConstants.IGNORE_DECLARING_TYPE) != 0;
ignoreReturnType = (limitTo & IJavaSearchConstants.IGNORE_RETURN_TYPE) != 0;
}
char[] declaringSimpleName = null;
char[] declaringQualification = null;
switch (element.getElementType()) {
case IJavaElement.FIELD :
IField field = (IField) element;
if (!ignoreDeclaringType) {
IType declaringClass = field.getDeclaringType();
declaringSimpleName = declaringClass.getElementName().toCharArray();
declaringQualification = declaringClass.getPackageFragment().getElementName().toCharArray();
char[][] enclosingNames = enclosingTypeNames(declaringClass);
if (enclosingNames.length > 0) {
declaringQualification = CharOperation.concat(declaringQualification, CharOperation.concatWith(enclosingNames, '.'), '.');
}
}
char[] name = field.getElementName().toCharArray();
char[] typeSimpleName = null;
char[] typeQualification = null;
String typeSignature = null;
if (!ignoreReturnType) {
try {
typeSignature = field.getTypeSignature();
char[] signature = typeSignature.toCharArray();
char[] typeErasure = Signature.toCharArray(Signature.getTypeErasure(signature));
CharOperation.replace(typeErasure, '$', '.');
if ((lastDot = CharOperation.lastIndexOf('.', typeErasure)) == -1) {
typeSimpleName = typeErasure;
typeQualification = null;
} else {
typeSimpleName = CharOperation.subarray(typeErasure, lastDot + 1, typeErasure.length);
typeQualification = CharOperation.subarray(typeErasure, 0, lastDot);
if (!field.isBinary()) {
// prefix with a '*' as the full qualification could be bigger (because of an import)
CharOperation.concat(IIndexConstants.ONE_STAR, typeQualification);
}
}
} catch (JavaModelException e) {
return null;
}
}
// Create field pattern
boolean findDeclarations = false;
boolean readAccess = false;
boolean writeAccess = false;
switch (maskedLimitTo) {
case IJavaSearchConstants.DECLARATIONS :
findDeclarations = true;
break;
case IJavaSearchConstants.REFERENCES :
readAccess = true;
writeAccess = true;
break;
case IJavaSearchConstants.READ_ACCESSES :
readAccess = true;
break;
case IJavaSearchConstants.WRITE_ACCESSES :
writeAccess = true;
break;
case IJavaSearchConstants.ALL_OCCURRENCES :
findDeclarations = true;
readAccess = true;
writeAccess = true;
break;
}
searchPattern =
new FieldPattern(
findDeclarations,
readAccess,
writeAccess,
name,
declaringQualification,
declaringSimpleName,
typeQualification,
typeSimpleName,
typeSignature,
matchRule);
break;
case IJavaElement.IMPORT_DECLARATION :
String elementName = element.getElementName();
lastDot = elementName.lastIndexOf('.');
if (lastDot == -1) return null; // invalid import declaration
IImportDeclaration importDecl = (IImportDeclaration)element;
if (importDecl.isOnDemand()) {
searchPattern = createPackagePattern(elementName.substring(0, lastDot), maskedLimitTo, matchRule);
} else {
searchPattern =
createTypePattern(
elementName.substring(lastDot+1).toCharArray(),
elementName.substring(0, lastDot).toCharArray(),
null,
null,
null,
maskedLimitTo,
matchRule);
}
break;
case IJavaElement.LOCAL_VARIABLE :
LocalVariable localVar = (LocalVariable) element;
boolean findVarDeclarations = false;
boolean findVarReadAccess = false;
boolean findVarWriteAccess = false;
switch (maskedLimitTo) {
case IJavaSearchConstants.DECLARATIONS :
findVarDeclarations = true;
break;
case IJavaSearchConstants.REFERENCES :
findVarReadAccess = true;
findVarWriteAccess = true;
break;
case IJavaSearchConstants.READ_ACCESSES :
findVarReadAccess = true;
break;
case IJavaSearchConstants.WRITE_ACCESSES :
findVarWriteAccess = true;
break;
case IJavaSearchConstants.ALL_OCCURRENCES :
findVarDeclarations = true;
findVarReadAccess = true;
findVarWriteAccess = true;
break;
}
searchPattern =
new LocalVariablePattern(
findVarDeclarations,
findVarReadAccess,
findVarWriteAccess,
localVar,
matchRule);
break;
case IJavaElement.TYPE_PARAMETER:
ITypeParameter typeParam = (ITypeParameter) element;
boolean findParamDeclarations = true;
boolean findParamReferences = true;
switch (maskedLimitTo) {
case IJavaSearchConstants.DECLARATIONS :
findParamReferences = false;
break;
case IJavaSearchConstants.REFERENCES :
findParamDeclarations = false;
break;
}
searchPattern =
new TypeParameterPattern(
findParamDeclarations,
findParamReferences,
typeParam,
matchRule);
break;
case IJavaElement.METHOD :
IMethod method = (IMethod) element;
boolean isConstructor;
try {
isConstructor = method.isConstructor();
} catch (JavaModelException e) {
return null;
}
IType declaringClass = method.getDeclaringType();
if (ignoreDeclaringType) {
if (isConstructor) declaringSimpleName = declaringClass.getElementName().toCharArray();
} else {
declaringSimpleName = declaringClass.getElementName().toCharArray();
declaringQualification = declaringClass.getPackageFragment().getElementName().toCharArray();
char[][] enclosingNames = enclosingTypeNames(declaringClass);
if (enclosingNames.length > 0) {
declaringQualification = CharOperation.concat(declaringQualification, CharOperation.concatWith(enclosingNames, '.'), '.');
}
}
char[] selector = method.getElementName().toCharArray();
char[] returnSimpleName = null;
char[] returnQualification = null;
String returnSignature = null;
if (!ignoreReturnType) {
try {
returnSignature = method.getReturnType();
char[] signature = returnSignature.toCharArray();
char[] returnErasure = Signature.toCharArray(Signature.getTypeErasure(signature));
CharOperation.replace(returnErasure, '$', '.');
if ((lastDot = CharOperation.lastIndexOf('.', returnErasure)) == -1) {
returnSimpleName = returnErasure;
returnQualification = null;
} else {
returnSimpleName = CharOperation.subarray(returnErasure, lastDot + 1, returnErasure.length);
returnQualification = CharOperation.subarray(returnErasure, 0, lastDot);
if (!method.isBinary()) {
// prefix with a '*' as the full qualification could be bigger (because of an import)
CharOperation.concat(IIndexConstants.ONE_STAR, returnQualification);
}
}
} catch (JavaModelException e) {
return null;
}
}
String[] parameterTypes = method.getParameterTypes();
int paramCount = parameterTypes.length;
char[][] parameterSimpleNames = new char[paramCount][];
char[][] parameterQualifications = new char[paramCount][];
String[] parameterSignatures = new String[paramCount];
for (int i = 0; i < paramCount; i++) {
parameterSignatures[i] = parameterTypes[i];
char[] signature = parameterSignatures[i].toCharArray();
char[] paramErasure = Signature.toCharArray(Signature.getTypeErasure(signature));
CharOperation.replace(paramErasure, '$', '.');
if ((lastDot = CharOperation.lastIndexOf('.', paramErasure)) == -1) {
parameterSimpleNames[i] = paramErasure;
parameterQualifications[i] = null;
} else {
parameterSimpleNames[i] = CharOperation.subarray(paramErasure, lastDot + 1, paramErasure.length);
parameterQualifications[i] = CharOperation.subarray(paramErasure, 0, lastDot);
if (!method.isBinary()) {
// prefix with a '*' as the full qualification could be bigger (because of an import)
CharOperation.concat(IIndexConstants.ONE_STAR, parameterQualifications[i]);
}
}
}
// Create method/constructor pattern
boolean findMethodDeclarations = true;
boolean findMethodReferences = true;
switch (maskedLimitTo) {
case IJavaSearchConstants.DECLARATIONS :
findMethodReferences = false;
break;
case IJavaSearchConstants.REFERENCES :
findMethodDeclarations = false;
break;
case IJavaSearchConstants.ALL_OCCURRENCES :
break;
}
if (isConstructor) {
searchPattern =
new ConstructorPattern(
findMethodDeclarations,
findMethodReferences,
declaringSimpleName,
declaringQualification,
parameterQualifications,
parameterSimpleNames,
parameterSignatures,
method,
matchRule);
} else {
searchPattern =
new MethodPattern(
findMethodDeclarations,
findMethodReferences,
selector,
declaringQualification,
declaringSimpleName,
returnQualification,
returnSimpleName,
returnSignature,
parameterQualifications,
parameterSimpleNames,
parameterSignatures,
method,
matchRule);
}
break;
case IJavaElement.TYPE :
IType type = (IType)element;
searchPattern = createTypePattern(
type.getElementName().toCharArray(),
type.getPackageFragment().getElementName().toCharArray(),
ignoreDeclaringType ? null : enclosingTypeNames(type),
null,
type,
maskedLimitTo,
matchRule);
break;
case IJavaElement.PACKAGE_DECLARATION :
case IJavaElement.PACKAGE_FRAGMENT :
searchPattern = createPackagePattern(element.getElementName(), maskedLimitTo, matchRule);
break;
}
if (searchPattern != null)
MatchLocator.setFocus(searchPattern, element);
return searchPattern;
}
private static SearchPattern createTypePattern(char[] simpleName, char[] packageName, char[][] enclosingTypeNames, String typeSignature, IType type, int limitTo, int matchRule) {
switch (limitTo) {
case IJavaSearchConstants.DECLARATIONS :
return new TypeDeclarationPattern(
packageName,
enclosingTypeNames,
simpleName,
IIndexConstants.TYPE_SUFFIX,
matchRule);
case IJavaSearchConstants.REFERENCES :
if (type != null) {
return new TypeReferencePattern(
CharOperation.concatWith(packageName, enclosingTypeNames, '.'),
simpleName,
type,
matchRule);
}
return new TypeReferencePattern(
CharOperation.concatWith(packageName, enclosingTypeNames, '.'),
simpleName,
typeSignature,
matchRule);
case IJavaSearchConstants.IMPLEMENTORS :
return new SuperTypeReferencePattern(
CharOperation.concatWith(packageName, enclosingTypeNames, '.'),
simpleName,
SuperTypeReferencePattern.ONLY_SUPER_INTERFACES,
matchRule);
case IJavaSearchConstants.ALL_OCCURRENCES :
return new OrPattern(
new TypeDeclarationPattern(
packageName,
enclosingTypeNames,
simpleName,
IIndexConstants.TYPE_SUFFIX,
matchRule),
(type != null)
? new TypeReferencePattern(
CharOperation.concatWith(packageName, enclosingTypeNames, '.'),
simpleName,
type,
matchRule)
: new TypeReferencePattern(
CharOperation.concatWith(packageName, enclosingTypeNames, '.'),
simpleName,
typeSignature,
matchRule)
);
}
return null;
}
/**
* Type pattern are formed by [qualification '.']type [typeArguments].
* e.g. java.lang.Object
* Runnable
* List&lt;String&gt;
*
* @since 3.1
* Type arguments can be specified to search references to parameterized types.
* and look as follow: '&lt;' { [ '?' {'extends'|'super'} ] type ( ',' [ '?' {'extends'|'super'} ] type )* | '?' } '&gt;'
* Please note that:
* - '*' is not valid inside type arguments definition &lt;&gt;
* - '?' is treated as a wildcard when it is inside &lt;&gt; (ie. it must be put on first position of the type argument)
*/
private static SearchPattern createTypePattern(String patternString, int limitTo, int matchRule, char indexSuffix) {
Scanner scanner = new Scanner(false /*comment*/, true /*whitespace*/, false /*nls*/, ClassFileConstants.JDK1_3/*sourceLevel*/, null /*taskTags*/, null/*taskPriorities*/, true/*taskCaseSensitive*/);
scanner.setSource(patternString.toCharArray());
String type = null;
int token;
try {
token = scanner.getNextToken();
} catch (InvalidInputException e) {
return null;
}
int argCount = 0;
while (token != TerminalTokens.TokenNameEOF) {
if (argCount == 0) {
switch (token) {
case TerminalTokens.TokenNameWHITESPACE:
break;
case TerminalTokens.TokenNameLESS:
argCount++;
// fall through default case to add token to type
default: // all other tokens are considered identifiers (see bug 21763 Problem in Java search [search])
if (type == null)
type = scanner.getCurrentTokenString();
else
type += scanner.getCurrentTokenString();
}
} else {
switch (token) {
case TerminalTokens.TokenNameGREATER:
case TerminalTokens.TokenNameRIGHT_SHIFT:
case TerminalTokens.TokenNameUNSIGNED_RIGHT_SHIFT:
argCount--;
break;
case TerminalTokens.TokenNameLESS:
argCount++;
break;
}
if (type == null) return null; // invalid syntax
type += scanner.getCurrentTokenString();
}
try {
token = scanner.getNextToken();
} catch (InvalidInputException e) {
return null;
}
}
if (type == null) return null;
String typeSignature = null;
char[] qualificationChars = null, typeChars = null;
// extract declaring type infos
if (type != null) {
// get type part and signature
char[] typePart = null;
try {
typeSignature = Signature.createTypeSignature(type, false);
if (typeSignature.indexOf(Signature.C_GENERIC_START) < 0) {
typePart = type.toCharArray();
} else {
typePart = Signature.toCharArray(Signature.getTypeErasure(typeSignature.toCharArray()));
}
}
catch (IllegalArgumentException iae) {
// string is not a valid type syntax
return null;
}
// get qualification name
int lastDotPosition = CharOperation.lastIndexOf('.', typePart);
if (lastDotPosition >= 0) {
qualificationChars = CharOperation.subarray(typePart, 0, lastDotPosition);
if (qualificationChars.length == 1 && qualificationChars[0] == '*')
qualificationChars = null;
typeChars = CharOperation.subarray(typePart, lastDotPosition+1, typePart.length);
} else {
qualificationChars = null;
typeChars = typePart;
}
if (typeChars.length == 1 && typeChars[0] == '*')
typeChars = null;
}
switch (limitTo) {
case IJavaSearchConstants.DECLARATIONS : // cannot search for explicit member types
return new QualifiedTypeDeclarationPattern(qualificationChars, typeChars, indexSuffix, matchRule);
case IJavaSearchConstants.REFERENCES :
return new TypeReferencePattern(qualificationChars, typeChars, typeSignature, matchRule);
case IJavaSearchConstants.IMPLEMENTORS :
return new SuperTypeReferencePattern(qualificationChars, typeChars, SuperTypeReferencePattern.ONLY_SUPER_INTERFACES, matchRule);
case IJavaSearchConstants.ALL_OCCURRENCES :
return new OrPattern(
new QualifiedTypeDeclarationPattern(qualificationChars, typeChars, indexSuffix, matchRule),// cannot search for explicit member types
new TypeReferencePattern(qualificationChars, typeChars, matchRule));
}
return null;
}
/**
* Returns the enclosing type names of the given type.
*/
private static char[][] enclosingTypeNames(IType type) {
IJavaElement parent = type.getParent();
switch (parent.getElementType()) {
case IJavaElement.CLASS_FILE:
// For a binary type, the parent is not the enclosing type, but the declaring type is.
// (see bug 20532 Declaration of member binary type not found)
IType declaringType = type.getDeclaringType();
if (declaringType == null) return CharOperation.NO_CHAR_CHAR;
return CharOperation.arrayConcat(
enclosingTypeNames(declaringType),
declaringType.getElementName().toCharArray());
case IJavaElement.COMPILATION_UNIT:
return CharOperation.NO_CHAR_CHAR;
case IJavaElement.FIELD:
case IJavaElement.INITIALIZER:
case IJavaElement.METHOD:
IType declaringClass = ((IMember) parent).getDeclaringType();
return CharOperation.arrayConcat(
enclosingTypeNames(declaringClass),
new char[][] {declaringClass.getElementName().toCharArray(), IIndexConstants.ONE_STAR});
case IJavaElement.TYPE:
return CharOperation.arrayConcat(
enclosingTypeNames((IType)parent),
parent.getElementName().toCharArray());
default:
return null;
}
}
/**
* Decode the given index key in this pattern. The decoded index key is used by
* {@link #matchesDecodedKey(SearchPattern)} to find out if the corresponding index entry
* should be considered.
* <p>
* This method should be re-implemented in subclasses that need to decode an index key.
* </p>
*
* @param key the given index key
*/
public void decodeIndexKey(char[] key) {
// called from findIndexMatches(), override as necessary
}
/**
* Returns a blank pattern that can be used as a record to decode an index key.
* <p>
* Implementors of this method should return a new search pattern that is going to be used
* to decode index keys.
* </p>
*
* @return a new blank pattern
* @see #decodeIndexKey(char[])
*/
public abstract SearchPattern getBlankPattern();
/**
* Returns a key to find in relevant index categories, if null then all index entries are matched.
* The key will be matched according to some match rule. These potential matches
* will be further narrowed by the match locator, but precise match locating can be expensive,
* and index query should be as accurate as possible so as to eliminate obvious false hits.
* <p>
* This method should be re-implemented in subclasses that need to narrow down the
* index query.
* </p>
*
* @return an index key from this pattern, or <code>null</code> if all index entries are matched.
*/
public char[] getIndexKey() {
return null; // called from queryIn(), override as necessary
}
/**
* Returns an array of index categories to consider for this index query.
* These potential matches will be further narrowed by the match locator, but precise
* match locating can be expensive, and index query should be as accurate as possible
* so as to eliminate obvious false hits.
* <p>
* This method should be re-implemented in subclasses that need to narrow down the
* index query.
* </p>
*
* @return an array of index categories
*/
public char[][] getIndexCategories() {
return CharOperation.NO_CHAR_CHAR; // called from queryIn(), override as necessary
}
/**
* Returns the rule to apply for matching index keys. Can be exact match, prefix match, pattern match or regexp match.
* Rule can also be combined with a case sensitivity flag.
*
* @return one of R_EXACT_MATCH, R_PREFIX_MATCH, R_PATTERN_MATCH, R_REGEXP_MATCH combined with R_CASE_SENSITIVE,
* e.g. R_EXACT_MATCH | R_CASE_SENSITIVE if an exact and case sensitive match is requested,
* or R_PREFIX_MATCH if a prefix non case sensitive match is requested.
* [TODO (frederic) I hope R_ERASURE_MATCH doesn't need to be on this list. Because it would be a breaking API change.]
*/
public final int getMatchRule() {
return this.matchRule;
}
/**
* Returns whether this pattern matches the given pattern (representing a decoded index key).
* <p>
* This method should be re-implemented in subclasses that need to narrow down the
* index query.
* </p>
*
* @param decodedPattern a pattern representing a decoded index key
* @return whether this pattern matches the given pattern
*/
public boolean matchesDecodedKey(SearchPattern decodedPattern) {
return true; // called from findIndexMatches(), override as necessary if index key is encoded
}
/**
* Returns whether the given name matches the given pattern.
* <p>
* This method should be re-implemented in subclasses that need to define how
* a name matches a pattern.
* </p>
*
* @param pattern the given pattern, or <code>null</code> to represent "*"
* @param name the given name
* @return whether the given name matches the given pattern
*/
public boolean matchesName(char[] pattern, char[] name) {
if (pattern == null) return true; // null is as if it was "*"
if (name != null) {
boolean isCaseSensitive = (this.matchRule & R_CASE_SENSITIVE) != 0;
boolean isCamelCase = (this.matchRule & R_CAMELCASE_MATCH) != 0;
int matchMode = this.matchRule & MODE_MASK;
boolean matchFirstChar = !isCaseSensitive || pattern.length == 0 || (name.length > 0 && pattern[0] == name[0]);
if (isCamelCase && matchFirstChar && CharOperation.camelCaseMatch(pattern, name)) {
return true;
}
switch (matchMode) {
case R_EXACT_MATCH :
case R_FULL_MATCH :
if (isCamelCase) return false;
return matchFirstChar && CharOperation.equals(pattern, name, isCaseSensitive);
case R_PREFIX_MATCH :
return matchFirstChar && CharOperation.prefixEquals(pattern, name, isCaseSensitive);
case R_PATTERN_MATCH :
if (!isCaseSensitive)
pattern = CharOperation.toLowerCase(pattern);
return CharOperation.match(pattern, name, isCaseSensitive);
case R_REGEXP_MATCH :
// TODO (frederic) implement regular expression match
return true;
}
}
return false;
}
/**
* Validate compatibility between given string pattern and match rule.
*<br>
* Optimized (ie. returned match rule is modified) combinations are:
* <ul>
* <li>{@link #R_PATTERN_MATCH} without any '*' or '?' in string pattern:
* pattern match bit is unset,
* </li>
* <li>{@link #R_PATTERN_MATCH} and {@link #R_PREFIX_MATCH} bits simultaneously set:
* prefix match bit is unset,
* </li>
* <li>{@link #R_PATTERN_MATCH} and {@link #R_CAMELCASE_MATCH} bits simultaneously set:
* camel case match bit is unset,
* </li>
* <li>{@link #R_CAMELCASE_MATCH} with invalid combination of uppercase and lowercase characters:
* camel case match bit is unset and replaced with prefix match pattern,
* </li>
* <li>{@link #R_CAMELCASE_MATCH} combined with {@link #R_PREFIX_MATCH} and {@link #R_CASE_SENSITIVE}
* bits is reduced to only {@link #R_CAMELCASE_MATCH} as Camel Case search is already prefix and case sensitive,
* </li>
* </ul>
*<br>
* Rejected (ie. returned match rule -1) combinations are:
* <ul>
* <li>{@link #R_REGEXP_MATCH} with any other match mode bit set,
* </li>
* </ul>
*
* @param stringPattern The string pattern
* @param matchRule The match rule
* @return Optimized valid match rule or -1 if an incompatibility was detected.
* @since 3.2
*/
public static int validateMatchRule(String stringPattern, int matchRule) {
// Verify Regexp match rule
if ((matchRule & R_REGEXP_MATCH) != 0) {
if ((matchRule & R_PATTERN_MATCH) != 0 || (matchRule & R_PREFIX_MATCH) != 0 || (matchRule & R_CAMELCASE_MATCH) != 0) {
return -1;
}
}
// Verify Pattern match rule
if ((matchRule & R_PATTERN_MATCH) != 0) {
if ((matchRule & R_PREFIX_MATCH) != 0) {
matchRule &= ~R_PREFIX_MATCH;
}
int starIndex = stringPattern.indexOf('*');
int questionIndex = stringPattern.indexOf('?');
if (starIndex < 0 && questionIndex < 0) {
// No need to have pattern match
matchRule &= ~R_PATTERN_MATCH;
} else {
// Remove Camel Case match when there's '*' or '?' characters
if ((matchRule & R_CAMELCASE_MATCH) != 0) {
matchRule &= ~R_CAMELCASE_MATCH;
}
}
}
// Verify Camel Case match rule
if ((matchRule & R_CAMELCASE_MATCH) != 0) {
// Verify sting pattern validity
int length = stringPattern.length();
boolean validCamelCase = false;
if (length > 1) {
int idx = 0;
char ch = stringPattern.charAt(idx++);
if (Character.isJavaIdentifierStart(ch)) {
ch = stringPattern.charAt(idx++);
if (Character.isUpperCase(ch)) {
while (idx<length && Character.isUpperCase(stringPattern.charAt(idx))) {
idx++;
}
while (idx<length && (!Character.isUpperCase(ch=stringPattern.charAt(idx)) && Character.isJavaIdentifierPart(ch))) {
idx++;
}
validCamelCase = idx == length;
}
}
}
// Verify bits compatibility
if (validCamelCase) {
if ((matchRule & R_PREFIX_MATCH) != 0) {
if ((matchRule & R_CASE_SENSITIVE) != 0) {
// This is equivalent to Camel Case match rule
matchRule &= ~R_PREFIX_MATCH;
matchRule &= ~R_CASE_SENSITIVE;
}
}
} else {
matchRule &= ~R_CAMELCASE_MATCH;
if ((matchRule & R_PREFIX_MATCH) == 0) {
matchRule |= R_PREFIX_MATCH;
matchRule |= R_CASE_SENSITIVE;
}
}
}
return matchRule;
}
/**
* @see java.lang.Object#toString()
*/
public String toString() {
return "SearchPattern"; //$NON-NLS-1$
}
}