8034245: Refactor TopLevel tree node.
Summary: Added JCPackageDecl to JCTree to store package-level information.
Reviewed-by: jjg, jlahoda
/*
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* DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
*
* This code is free software; you can redistribute it and/or modify it
* under the terms of the GNU General Public License version 2 only, as
* published by the Free Software Foundation. Oracle designates this
* particular file as subject to the "Classpath" exception as provided
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*
* This code is distributed in the hope that it will be useful, but WITHOUT
* ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
* FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
* version 2 for more details (a copy is included in the LICENSE file that
* accompanied this code).
*
* You should have received a copy of the GNU General Public License version
* 2 along with this work; if not, write to the Free Software Foundation,
* Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA.
*
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package com.sun.tools.javac.parser;
import java.util.*;
import com.sun.source.tree.MemberReferenceTree.ReferenceMode;
import com.sun.tools.javac.code.*;
import com.sun.tools.javac.parser.Tokens.*;
import com.sun.tools.javac.parser.Tokens.Comment.CommentStyle;
import com.sun.tools.javac.tree.*;
import com.sun.tools.javac.tree.JCTree.*;
import com.sun.tools.javac.util.*;
import com.sun.tools.javac.util.JCDiagnostic.DiagnosticFlag;
import com.sun.tools.javac.util.JCDiagnostic.DiagnosticPosition;
import com.sun.tools.javac.util.List;
import static com.sun.tools.javac.parser.Tokens.TokenKind.*;
import static com.sun.tools.javac.parser.Tokens.TokenKind.ASSERT;
import static com.sun.tools.javac.parser.Tokens.TokenKind.CASE;
import static com.sun.tools.javac.parser.Tokens.TokenKind.CATCH;
import static com.sun.tools.javac.parser.Tokens.TokenKind.EQ;
import static com.sun.tools.javac.parser.Tokens.TokenKind.GT;
import static com.sun.tools.javac.parser.Tokens.TokenKind.IMPORT;
import static com.sun.tools.javac.parser.Tokens.TokenKind.LT;
import static com.sun.tools.javac.tree.JCTree.Tag.*;
/** The parser maps a token sequence into an abstract syntax
* tree. It operates by recursive descent, with code derived
* systematically from an LL(1) grammar. For efficiency reasons, an
* operator precedence scheme is used for parsing binary operation
* expressions.
*
* <p><b>This is NOT part of any supported API.
* If you write code that depends on this, you do so at your own risk.
* This code and its internal interfaces are subject to change or
* deletion without notice.</b>
*/
public class JavacParser implements Parser {
/** The number of precedence levels of infix operators.
*/
private static final int infixPrecedenceLevels = 10;
/** The scanner used for lexical analysis.
*/
protected Lexer S;
/** The factory to be used for abstract syntax tree construction.
*/
protected TreeMaker F;
/** The log to be used for error diagnostics.
*/
private Log log;
/** The Source language setting. */
private Source source;
/** The name table. */
private Names names;
/** End position mappings container */
private final AbstractEndPosTable endPosTable;
// Because of javac's limited lookahead, some contexts are ambiguous in
// the presence of type annotations even though they are not ambiguous
// in the absence of type annotations. Consider this code:
// void m(String [] m) { }
// void m(String ... m) { }
// After parsing "String", javac calls bracketsOpt which immediately
// returns if the next character is not '['. Similarly, javac can see
// if the next token is ... and in that case parse an ellipsis. But in
// the presence of type annotations:
// void m(String @A [] m) { }
// void m(String @A ... m) { }
// no finite lookahead is enough to determine whether to read array
// levels or an ellipsis. Furthermore, if you call bracketsOpt, then
// bracketsOpt first reads all the leading annotations and only then
// discovers that it needs to fail. bracketsOpt needs a way to push
// back the extra annotations that it read. (But, bracketsOpt should
// not *always* be allowed to push back extra annotations that it finds
// -- in most contexts, any such extra annotation is an error.
//
// The following two variables permit type annotations that have
// already been read to be stored for later use. Alternate
// implementations are possible but would cause much larger changes to
// the parser.
/** Type annotations that have already been read but have not yet been used. **/
private List<JCAnnotation> typeAnnotationsPushedBack = List.nil();
/**
* If the parser notices extra annotations, then it either immediately
* issues an error (if this variable is false) or places the extra
* annotations in variable typeAnnotationsPushedBack (if this variable
* is true).
*/
private boolean permitTypeAnnotationsPushBack = false;
interface ErrorRecoveryAction {
JCTree doRecover(JavacParser parser);
}
enum BasicErrorRecoveryAction implements ErrorRecoveryAction {
BLOCK_STMT {public JCTree doRecover(JavacParser parser) { return parser.parseStatementAsBlock(); }},
CATCH_CLAUSE {public JCTree doRecover(JavacParser parser) { return parser.catchClause(); }}
}
/** Construct a parser from a given scanner, tree factory and log.
*/
protected JavacParser(ParserFactory fac,
Lexer S,
boolean keepDocComments,
boolean keepLineMap,
boolean keepEndPositions) {
this.S = S;
nextToken(); // prime the pump
this.F = fac.F;
this.log = fac.log;
this.names = fac.names;
this.source = fac.source;
this.allowGenerics = source.allowGenerics();
this.allowVarargs = source.allowVarargs();
this.allowAsserts = source.allowAsserts();
this.allowEnums = source.allowEnums();
this.allowForeach = source.allowForeach();
this.allowStaticImport = source.allowStaticImport();
this.allowAnnotations = source.allowAnnotations();
this.allowTWR = source.allowTryWithResources();
this.allowDiamond = source.allowDiamond();
this.allowMulticatch = source.allowMulticatch();
this.allowStringFolding = fac.options.getBoolean("allowStringFolding", true);
this.allowLambda = source.allowLambda();
this.allowMethodReferences = source.allowMethodReferences();
this.allowDefaultMethods = source.allowDefaultMethods();
this.allowStaticInterfaceMethods = source.allowStaticInterfaceMethods();
this.allowIntersectionTypesInCast = source.allowIntersectionTypesInCast();
this.allowTypeAnnotations = source.allowTypeAnnotations();
this.allowAnnotationsAfterTypeParams = source.allowAnnotationsAfterTypeParams();
this.keepDocComments = keepDocComments;
docComments = newDocCommentTable(keepDocComments, fac);
this.keepLineMap = keepLineMap;
this.errorTree = F.Erroneous();
endPosTable = newEndPosTable(keepEndPositions);
}
protected AbstractEndPosTable newEndPosTable(boolean keepEndPositions) {
return keepEndPositions
? new SimpleEndPosTable(this)
: new EmptyEndPosTable(this);
}
protected DocCommentTable newDocCommentTable(boolean keepDocComments, ParserFactory fac) {
return keepDocComments ? new LazyDocCommentTable(fac) : null;
}
/** Switch: Should generics be recognized?
*/
boolean allowGenerics;
/** Switch: Should diamond operator be recognized?
*/
boolean allowDiamond;
/** Switch: Should multicatch clause be accepted?
*/
boolean allowMulticatch;
/** Switch: Should varargs be recognized?
*/
boolean allowVarargs;
/** Switch: should we recognize assert statements, or just give a warning?
*/
boolean allowAsserts;
/** Switch: should we recognize enums, or just give a warning?
*/
boolean allowEnums;
/** Switch: should we recognize foreach?
*/
boolean allowForeach;
/** Switch: should we recognize foreach?
*/
boolean allowStaticImport;
/** Switch: should we recognize annotations?
*/
boolean allowAnnotations;
/** Switch: should we recognize try-with-resources?
*/
boolean allowTWR;
/** Switch: should we fold strings?
*/
boolean allowStringFolding;
/** Switch: should we recognize lambda expressions?
*/
boolean allowLambda;
/** Switch: should we allow method/constructor references?
*/
boolean allowMethodReferences;
/** Switch: should we allow default methods in interfaces?
*/
boolean allowDefaultMethods;
/** Switch: should we allow static methods in interfaces?
*/
boolean allowStaticInterfaceMethods;
/** Switch: should we allow intersection types in cast?
*/
boolean allowIntersectionTypesInCast;
/** Switch: should we keep docComments?
*/
boolean keepDocComments;
/** Switch: should we keep line table?
*/
boolean keepLineMap;
/** Switch: should we recognize type annotations?
*/
boolean allowTypeAnnotations;
/** Switch: should we allow annotations after the method type parameters?
*/
boolean allowAnnotationsAfterTypeParams;
/** Switch: is "this" allowed as an identifier?
* This is needed to parse receiver types.
*/
boolean allowThisIdent;
/** The type of the method receiver, as specified by a first "this" parameter.
*/
JCVariableDecl receiverParam;
/** When terms are parsed, the mode determines which is expected:
* mode = EXPR : an expression
* mode = TYPE : a type
* mode = NOPARAMS : no parameters allowed for type
* mode = TYPEARG : type argument
*/
static final int EXPR = 0x1;
static final int TYPE = 0x2;
static final int NOPARAMS = 0x4;
static final int TYPEARG = 0x8;
static final int DIAMOND = 0x10;
/** The current mode.
*/
private int mode = 0;
/** The mode of the term that was parsed last.
*/
private int lastmode = 0;
/* ---------- token management -------------- */
protected Token token;
public Token token() {
return token;
}
public void nextToken() {
S.nextToken();
token = S.token();
}
protected boolean peekToken(Filter<TokenKind> tk) {
return peekToken(0, tk);
}
protected boolean peekToken(int lookahead, Filter<TokenKind> tk) {
return tk.accepts(S.token(lookahead + 1).kind);
}
protected boolean peekToken(Filter<TokenKind> tk1, Filter<TokenKind> tk2) {
return peekToken(0, tk1, tk2);
}
protected boolean peekToken(int lookahead, Filter<TokenKind> tk1, Filter<TokenKind> tk2) {
return tk1.accepts(S.token(lookahead + 1).kind) &&
tk2.accepts(S.token(lookahead + 2).kind);
}
protected boolean peekToken(Filter<TokenKind> tk1, Filter<TokenKind> tk2, Filter<TokenKind> tk3) {
return peekToken(0, tk1, tk2, tk3);
}
protected boolean peekToken(int lookahead, Filter<TokenKind> tk1, Filter<TokenKind> tk2, Filter<TokenKind> tk3) {
return tk1.accepts(S.token(lookahead + 1).kind) &&
tk2.accepts(S.token(lookahead + 2).kind) &&
tk3.accepts(S.token(lookahead + 3).kind);
}
@SuppressWarnings("unchecked")
protected boolean peekToken(Filter<TokenKind>... kinds) {
return peekToken(0, kinds);
}
@SuppressWarnings("unchecked")
protected boolean peekToken(int lookahead, Filter<TokenKind>... kinds) {
for (; lookahead < kinds.length ; lookahead++) {
if (!kinds[lookahead].accepts(S.token(lookahead + 1).kind)) {
return false;
}
}
return true;
}
/* ---------- error recovery -------------- */
private JCErroneous errorTree;
/** Skip forward until a suitable stop token is found.
*/
private void skip(boolean stopAtImport, boolean stopAtMemberDecl, boolean stopAtIdentifier, boolean stopAtStatement) {
while (true) {
switch (token.kind) {
case SEMI:
nextToken();
return;
case PUBLIC:
case FINAL:
case ABSTRACT:
case MONKEYS_AT:
case EOF:
case CLASS:
case INTERFACE:
case ENUM:
return;
case IMPORT:
if (stopAtImport)
return;
break;
case LBRACE:
case RBRACE:
case PRIVATE:
case PROTECTED:
case STATIC:
case TRANSIENT:
case NATIVE:
case VOLATILE:
case SYNCHRONIZED:
case STRICTFP:
case LT:
case BYTE:
case SHORT:
case CHAR:
case INT:
case LONG:
case FLOAT:
case DOUBLE:
case BOOLEAN:
case VOID:
if (stopAtMemberDecl)
return;
break;
case UNDERSCORE:
case IDENTIFIER:
if (stopAtIdentifier)
return;
break;
case CASE:
case DEFAULT:
case IF:
case FOR:
case WHILE:
case DO:
case TRY:
case SWITCH:
case RETURN:
case THROW:
case BREAK:
case CONTINUE:
case ELSE:
case FINALLY:
case CATCH:
if (stopAtStatement)
return;
break;
}
nextToken();
}
}
private JCErroneous syntaxError(int pos, String key, TokenKind... args) {
return syntaxError(pos, List.<JCTree>nil(), key, args);
}
private JCErroneous syntaxError(int pos, List<JCTree> errs, String key, TokenKind... args) {
setErrorEndPos(pos);
JCErroneous err = F.at(pos).Erroneous(errs);
reportSyntaxError(err, key, (Object[])args);
if (errs != null) {
JCTree last = errs.last();
if (last != null)
storeEnd(last, pos);
}
return toP(err);
}
private static final int RECOVERY_THRESHOLD = 50;
private int errorPos = Position.NOPOS;
private int count = 0;
/**
* Report a syntax using the given the position parameter and arguments,
* unless one was already reported at the same position.
*/
private void reportSyntaxError(int pos, String key, Object... args) {
JCDiagnostic.DiagnosticPosition diag = new JCDiagnostic.SimpleDiagnosticPosition(pos);
reportSyntaxError(diag, key, args);
}
/**
* Report a syntax error using the given DiagnosticPosition object and
* arguments, unless one was already reported at the same position.
*/
private void reportSyntaxError(JCDiagnostic.DiagnosticPosition diagPos, String key, Object... args) {
int pos = diagPos.getPreferredPosition();
if (pos > S.errPos() || pos == Position.NOPOS) {
if (token.kind == EOF) {
error(diagPos, "premature.eof");
} else {
error(diagPos, key, args);
}
}
S.errPos(pos);
if (token.pos == errorPos) {
//check for a possible infinite loop in parsing:
Assert.check(count++ < RECOVERY_THRESHOLD);
} else {
count = 0;
errorPos = token.pos;
}
}
/** Generate a syntax error at current position unless one was already
* reported at the same position.
*/
private JCErroneous syntaxError(String key) {
return syntaxError(token.pos, key);
}
/** Generate a syntax error at current position unless one was
* already reported at the same position.
*/
private JCErroneous syntaxError(String key, TokenKind arg) {
return syntaxError(token.pos, key, arg);
}
/** If next input token matches given token, skip it, otherwise report
* an error.
*/
public void accept(TokenKind tk) {
if (token.kind == tk) {
nextToken();
} else {
setErrorEndPos(token.pos);
reportSyntaxError(S.prevToken().endPos, "expected", tk);
}
}
/** Report an illegal start of expression/type error at given position.
*/
JCExpression illegal(int pos) {
setErrorEndPos(pos);
if ((mode & EXPR) != 0)
return syntaxError(pos, "illegal.start.of.expr");
else
return syntaxError(pos, "illegal.start.of.type");
}
/** Report an illegal start of expression/type error at current position.
*/
JCExpression illegal() {
return illegal(token.pos);
}
/** Diagnose a modifier flag from the set, if any. */
void checkNoMods(long mods) {
if (mods != 0) {
long lowestMod = mods & -mods;
error(token.pos, "mod.not.allowed.here",
Flags.asFlagSet(lowestMod));
}
}
/* ---------- doc comments --------- */
/** A table to store all documentation comments
* indexed by the tree nodes they refer to.
* defined only if option flag keepDocComment is set.
*/
private final DocCommentTable docComments;
/** Make an entry into docComments hashtable,
* provided flag keepDocComments is set and given doc comment is non-null.
* @param tree The tree to be used as index in the hashtable
* @param dc The doc comment to associate with the tree, or null.
*/
void attach(JCTree tree, Comment dc) {
if (keepDocComments && dc != null) {
// System.out.println("doc comment = ");System.out.println(dc);//DEBUG
docComments.putComment(tree, dc);
}
}
/* -------- source positions ------- */
private void setErrorEndPos(int errPos) {
endPosTable.setErrorEndPos(errPos);
}
private void storeEnd(JCTree tree, int endpos) {
endPosTable.storeEnd(tree, endpos);
}
private <T extends JCTree> T to(T t) {
return endPosTable.to(t);
}
private <T extends JCTree> T toP(T t) {
return endPosTable.toP(t);
}
/** Get the start position for a tree node. The start position is
* defined to be the position of the first character of the first
* token of the node's source text.
* @param tree The tree node
*/
public int getStartPos(JCTree tree) {
return TreeInfo.getStartPos(tree);
}
/**
* Get the end position for a tree node. The end position is
* defined to be the position of the last character of the last
* token of the node's source text. Returns Position.NOPOS if end
* positions are not generated or the position is otherwise not
* found.
* @param tree The tree node
*/
public int getEndPos(JCTree tree) {
return endPosTable.getEndPos(tree);
}
/* ---------- parsing -------------- */
/**
* Ident = IDENTIFIER
*/
Name ident() {
if (token.kind == IDENTIFIER) {
Name name = token.name();
nextToken();
return name;
} else if (token.kind == ASSERT) {
if (allowAsserts) {
error(token.pos, "assert.as.identifier");
nextToken();
return names.error;
} else {
warning(token.pos, "assert.as.identifier");
Name name = token.name();
nextToken();
return name;
}
} else if (token.kind == ENUM) {
if (allowEnums) {
error(token.pos, "enum.as.identifier");
nextToken();
return names.error;
} else {
warning(token.pos, "enum.as.identifier");
Name name = token.name();
nextToken();
return name;
}
} else if (token.kind == THIS) {
if (allowThisIdent) {
// Make sure we're using a supported source version.
checkTypeAnnotations();
Name name = token.name();
nextToken();
return name;
} else {
error(token.pos, "this.as.identifier");
nextToken();
return names.error;
}
} else if (token.kind == UNDERSCORE) {
warning(token.pos, "underscore.as.identifier");
Name name = token.name();
nextToken();
return name;
} else {
accept(IDENTIFIER);
return names.error;
}
}
/**
* Qualident = Ident { DOT [Annotations] Ident }
*/
public JCExpression qualident(boolean allowAnnos) {
JCExpression t = toP(F.at(token.pos).Ident(ident()));
while (token.kind == DOT) {
int pos = token.pos;
nextToken();
List<JCAnnotation> tyannos = null;
if (allowAnnos) {
tyannos = typeAnnotationsOpt();
}
t = toP(F.at(pos).Select(t, ident()));
if (tyannos != null && tyannos.nonEmpty()) {
t = toP(F.at(tyannos.head.pos).AnnotatedType(tyannos, t));
}
}
return t;
}
JCExpression literal(Name prefix) {
return literal(prefix, token.pos);
}
/**
* Literal =
* INTLITERAL
* | LONGLITERAL
* | FLOATLITERAL
* | DOUBLELITERAL
* | CHARLITERAL
* | STRINGLITERAL
* | TRUE
* | FALSE
* | NULL
*/
JCExpression literal(Name prefix, int pos) {
JCExpression t = errorTree;
switch (token.kind) {
case INTLITERAL:
try {
t = F.at(pos).Literal(
TypeTag.INT,
Convert.string2int(strval(prefix), token.radix()));
} catch (NumberFormatException ex) {
error(token.pos, "int.number.too.large", strval(prefix));
}
break;
case LONGLITERAL:
try {
t = F.at(pos).Literal(
TypeTag.LONG,
new Long(Convert.string2long(strval(prefix), token.radix())));
} catch (NumberFormatException ex) {
error(token.pos, "int.number.too.large", strval(prefix));
}
break;
case FLOATLITERAL: {
String proper = token.radix() == 16 ?
("0x"+ token.stringVal()) :
token.stringVal();
Float n;
try {
n = Float.valueOf(proper);
} catch (NumberFormatException ex) {
// error already reported in scanner
n = Float.NaN;
}
if (n.floatValue() == 0.0f && !isZero(proper))
error(token.pos, "fp.number.too.small");
else if (n.floatValue() == Float.POSITIVE_INFINITY)
error(token.pos, "fp.number.too.large");
else
t = F.at(pos).Literal(TypeTag.FLOAT, n);
break;
}
case DOUBLELITERAL: {
String proper = token.radix() == 16 ?
("0x"+ token.stringVal()) :
token.stringVal();
Double n;
try {
n = Double.valueOf(proper);
} catch (NumberFormatException ex) {
// error already reported in scanner
n = Double.NaN;
}
if (n.doubleValue() == 0.0d && !isZero(proper))
error(token.pos, "fp.number.too.small");
else if (n.doubleValue() == Double.POSITIVE_INFINITY)
error(token.pos, "fp.number.too.large");
else
t = F.at(pos).Literal(TypeTag.DOUBLE, n);
break;
}
case CHARLITERAL:
t = F.at(pos).Literal(
TypeTag.CHAR,
token.stringVal().charAt(0) + 0);
break;
case STRINGLITERAL:
t = F.at(pos).Literal(
TypeTag.CLASS,
token.stringVal());
break;
case TRUE: case FALSE:
t = F.at(pos).Literal(
TypeTag.BOOLEAN,
(token.kind == TRUE ? 1 : 0));
break;
case NULL:
t = F.at(pos).Literal(
TypeTag.BOT,
null);
break;
default:
Assert.error();
}
if (t == errorTree)
t = F.at(pos).Erroneous();
storeEnd(t, token.endPos);
nextToken();
return t;
}
//where
boolean isZero(String s) {
char[] cs = s.toCharArray();
int base = ((cs.length > 1 && Character.toLowerCase(cs[1]) == 'x') ? 16 : 10);
int i = ((base==16) ? 2 : 0);
while (i < cs.length && (cs[i] == '0' || cs[i] == '.')) i++;
return !(i < cs.length && (Character.digit(cs[i], base) > 0));
}
String strval(Name prefix) {
String s = token.stringVal();
return prefix.isEmpty() ? s : prefix + s;
}
/** terms can be either expressions or types.
*/
public JCExpression parseExpression() {
return term(EXPR);
}
/**
* parses (optional) type annotations followed by a type. If the
* annotations are present before the type and are not consumed during array
* parsing, this method returns a {@link JCAnnotatedType} consisting of
* these annotations and the underlying type. Otherwise, it returns the
* underlying type.
*
* <p>
*
* Note that this method sets {@code mode} to {@code TYPE} first, before
* parsing annotations.
*/
public JCExpression parseType() {
List<JCAnnotation> annotations = typeAnnotationsOpt();
return parseType(annotations);
}
public JCExpression parseType(List<JCAnnotation> annotations) {
JCExpression result = unannotatedType();
if (annotations.nonEmpty()) {
result = insertAnnotationsToMostInner(result, annotations, false);
}
return result;
}
public JCExpression unannotatedType() {
return term(TYPE);
}
JCExpression term(int newmode) {
int prevmode = mode;
mode = newmode;
JCExpression t = term();
lastmode = mode;
mode = prevmode;
return t;
}
/**
* {@literal
* Expression = Expression1 [ExpressionRest]
* ExpressionRest = [AssignmentOperator Expression1]
* AssignmentOperator = "=" | "+=" | "-=" | "*=" | "/=" |
* "&=" | "|=" | "^=" |
* "%=" | "<<=" | ">>=" | ">>>="
* Type = Type1
* TypeNoParams = TypeNoParams1
* StatementExpression = Expression
* ConstantExpression = Expression
* }
*/
JCExpression term() {
JCExpression t = term1();
if ((mode & EXPR) != 0 &&
token.kind == EQ || PLUSEQ.compareTo(token.kind) <= 0 && token.kind.compareTo(GTGTGTEQ) <= 0)
return termRest(t);
else
return t;
}
JCExpression termRest(JCExpression t) {
switch (token.kind) {
case EQ: {
int pos = token.pos;
nextToken();
mode = EXPR;
JCExpression t1 = term();
return toP(F.at(pos).Assign(t, t1));
}
case PLUSEQ:
case SUBEQ:
case STAREQ:
case SLASHEQ:
case PERCENTEQ:
case AMPEQ:
case BAREQ:
case CARETEQ:
case LTLTEQ:
case GTGTEQ:
case GTGTGTEQ:
int pos = token.pos;
TokenKind tk = token.kind;
nextToken();
mode = EXPR;
JCExpression t1 = term();
return F.at(pos).Assignop(optag(tk), t, t1);
default:
return t;
}
}
/** Expression1 = Expression2 [Expression1Rest]
* Type1 = Type2
* TypeNoParams1 = TypeNoParams2
*/
JCExpression term1() {
JCExpression t = term2();
if ((mode & EXPR) != 0 && token.kind == QUES) {
mode = EXPR;
return term1Rest(t);
} else {
return t;
}
}
/** Expression1Rest = ["?" Expression ":" Expression1]
*/
JCExpression term1Rest(JCExpression t) {
if (token.kind == QUES) {
int pos = token.pos;
nextToken();
JCExpression t1 = term();
accept(COLON);
JCExpression t2 = term1();
return F.at(pos).Conditional(t, t1, t2);
} else {
return t;
}
}
/** Expression2 = Expression3 [Expression2Rest]
* Type2 = Type3
* TypeNoParams2 = TypeNoParams3
*/
JCExpression term2() {
JCExpression t = term3();
if ((mode & EXPR) != 0 && prec(token.kind) >= TreeInfo.orPrec) {
mode = EXPR;
return term2Rest(t, TreeInfo.orPrec);
} else {
return t;
}
}
/* Expression2Rest = {infixop Expression3}
* | Expression3 instanceof Type
* infixop = "||"
* | "&&"
* | "|"
* | "^"
* | "&"
* | "==" | "!="
* | "<" | ">" | "<=" | ">="
* | "<<" | ">>" | ">>>"
* | "+" | "-"
* | "*" | "/" | "%"
*/
JCExpression term2Rest(JCExpression t, int minprec) {
JCExpression[] odStack = newOdStack();
Token[] opStack = newOpStack();
// optimization, was odStack = new Tree[...]; opStack = new Tree[...];
int top = 0;
odStack[0] = t;
int startPos = token.pos;
Token topOp = Tokens.DUMMY;
while (prec(token.kind) >= minprec) {
opStack[top] = topOp;
top++;
topOp = token;
nextToken();
odStack[top] = (topOp.kind == INSTANCEOF) ? parseType() : term3();
while (top > 0 && prec(topOp.kind) >= prec(token.kind)) {
odStack[top-1] = makeOp(topOp.pos, topOp.kind, odStack[top-1],
odStack[top]);
top--;
topOp = opStack[top];
}
}
Assert.check(top == 0);
t = odStack[0];
if (t.hasTag(JCTree.Tag.PLUS)) {
StringBuilder buf = foldStrings(t);
if (buf != null) {
t = toP(F.at(startPos).Literal(TypeTag.CLASS, buf.toString()));
}
}
odStackSupply.add(odStack);
opStackSupply.add(opStack);
return t;
}
//where
/** Construct a binary or type test node.
*/
private JCExpression makeOp(int pos,
TokenKind topOp,
JCExpression od1,
JCExpression od2)
{
if (topOp == INSTANCEOF) {
return F.at(pos).TypeTest(od1, od2);
} else {
return F.at(pos).Binary(optag(topOp), od1, od2);
}
}
/** If tree is a concatenation of string literals, replace it
* by a single literal representing the concatenated string.
*/
protected StringBuilder foldStrings(JCTree tree) {
if (!allowStringFolding)
return null;
List<String> buf = List.nil();
while (true) {
if (tree.hasTag(LITERAL)) {
JCLiteral lit = (JCLiteral) tree;
if (lit.typetag == TypeTag.CLASS) {
StringBuilder sbuf =
new StringBuilder((String)lit.value);
while (buf.nonEmpty()) {
sbuf.append(buf.head);
buf = buf.tail;
}
return sbuf;
}
} else if (tree.hasTag(JCTree.Tag.PLUS)) {
JCBinary op = (JCBinary)tree;
if (op.rhs.hasTag(LITERAL)) {
JCLiteral lit = (JCLiteral) op.rhs;
if (lit.typetag == TypeTag.CLASS) {
buf = buf.prepend((String) lit.value);
tree = op.lhs;
continue;
}
}
}
return null;
}
}
/** optimization: To save allocating a new operand/operator stack
* for every binary operation, we use supplys.
*/
ArrayList<JCExpression[]> odStackSupply = new ArrayList<>();
ArrayList<Token[]> opStackSupply = new ArrayList<>();
private JCExpression[] newOdStack() {
if (odStackSupply.isEmpty())
return new JCExpression[infixPrecedenceLevels + 1];
return odStackSupply.remove(odStackSupply.size() - 1);
}
private Token[] newOpStack() {
if (opStackSupply.isEmpty())
return new Token[infixPrecedenceLevels + 1];
return opStackSupply.remove(opStackSupply.size() - 1);
}
/**
* Expression3 = PrefixOp Expression3
* | "(" Expr | TypeNoParams ")" Expression3
* | Primary {Selector} {PostfixOp}
*
* {@literal
* Primary = "(" Expression ")"
* | Literal
* | [TypeArguments] THIS [Arguments]
* | [TypeArguments] SUPER SuperSuffix
* | NEW [TypeArguments] Creator
* | "(" Arguments ")" "->" ( Expression | Block )
* | Ident "->" ( Expression | Block )
* | [Annotations] Ident { "." [Annotations] Ident }
* | Expression3 MemberReferenceSuffix
* [ [Annotations] "[" ( "]" BracketsOpt "." CLASS | Expression "]" )
* | Arguments
* | "." ( CLASS | THIS | [TypeArguments] SUPER Arguments | NEW [TypeArguments] InnerCreator )
* ]
* | BasicType BracketsOpt "." CLASS
* }
*
* PrefixOp = "++" | "--" | "!" | "~" | "+" | "-"
* PostfixOp = "++" | "--"
* Type3 = Ident { "." Ident } [TypeArguments] {TypeSelector} BracketsOpt
* | BasicType
* TypeNoParams3 = Ident { "." Ident } BracketsOpt
* Selector = "." [TypeArguments] Ident [Arguments]
* | "." THIS
* | "." [TypeArguments] SUPER SuperSuffix
* | "." NEW [TypeArguments] InnerCreator
* | "[" Expression "]"
* TypeSelector = "." Ident [TypeArguments]
* SuperSuffix = Arguments | "." Ident [Arguments]
*/
protected JCExpression term3() {
int pos = token.pos;
JCExpression t;
List<JCExpression> typeArgs = typeArgumentsOpt(EXPR);
switch (token.kind) {
case QUES:
if ((mode & TYPE) != 0 && (mode & (TYPEARG|NOPARAMS)) == TYPEARG) {
mode = TYPE;
return typeArgument();
} else
return illegal();
case PLUSPLUS: case SUBSUB: case BANG: case TILDE: case PLUS: case SUB:
if (typeArgs == null && (mode & EXPR) != 0) {
TokenKind tk = token.kind;
nextToken();
mode = EXPR;
if (tk == SUB &&
(token.kind == INTLITERAL || token.kind == LONGLITERAL) &&
token.radix() == 10) {
mode = EXPR;
t = literal(names.hyphen, pos);
} else {
t = term3();
return F.at(pos).Unary(unoptag(tk), t);
}
} else return illegal();
break;
case LPAREN:
if (typeArgs == null && (mode & EXPR) != 0) {
ParensResult pres = analyzeParens();
switch (pres) {
case CAST:
accept(LPAREN);
mode = TYPE;
int pos1 = pos;
List<JCExpression> targets = List.of(t = term3());
while (token.kind == AMP) {
checkIntersectionTypesInCast();
accept(AMP);
targets = targets.prepend(term3());
}
if (targets.length() > 1) {
t = toP(F.at(pos1).TypeIntersection(targets.reverse()));
}
accept(RPAREN);
mode = EXPR;
JCExpression t1 = term3();
return F.at(pos).TypeCast(t, t1);
case IMPLICIT_LAMBDA:
case EXPLICIT_LAMBDA:
t = lambdaExpressionOrStatement(true, pres == ParensResult.EXPLICIT_LAMBDA, pos);
break;
default: //PARENS
accept(LPAREN);
mode = EXPR;
t = termRest(term1Rest(term2Rest(term3(), TreeInfo.orPrec)));
accept(RPAREN);
t = toP(F.at(pos).Parens(t));
break;
}
} else {
return illegal();
}
break;
case THIS:
if ((mode & EXPR) != 0) {
mode = EXPR;
t = to(F.at(pos).Ident(names._this));
nextToken();
if (typeArgs == null)
t = argumentsOpt(null, t);
else
t = arguments(typeArgs, t);
typeArgs = null;
} else return illegal();
break;
case SUPER:
if ((mode & EXPR) != 0) {
mode = EXPR;
t = to(F.at(pos).Ident(names._super));
t = superSuffix(typeArgs, t);
typeArgs = null;
} else return illegal();
break;
case INTLITERAL: case LONGLITERAL: case FLOATLITERAL: case DOUBLELITERAL:
case CHARLITERAL: case STRINGLITERAL:
case TRUE: case FALSE: case NULL:
if (typeArgs == null && (mode & EXPR) != 0) {
mode = EXPR;
t = literal(names.empty);
} else return illegal();
break;
case NEW:
if (typeArgs != null) return illegal();
if ((mode & EXPR) != 0) {
mode = EXPR;
nextToken();
if (token.kind == LT) typeArgs = typeArguments(false);
t = creator(pos, typeArgs);
typeArgs = null;
} else return illegal();
break;
case MONKEYS_AT:
// Only annotated cast types and method references are valid
List<JCAnnotation> typeAnnos = typeAnnotationsOpt();
if (typeAnnos.isEmpty()) {
// else there would be no '@'
throw new AssertionError("Expected type annotations, but found none!");
}
JCExpression expr = term3();
if ((mode & TYPE) == 0) {
// Type annotations on class literals no longer legal
switch (expr.getTag()) {
case REFERENCE: {
JCMemberReference mref = (JCMemberReference) expr;
mref.expr = toP(F.at(pos).AnnotatedType(typeAnnos, mref.expr));
t = mref;
break;
}
case SELECT: {
JCFieldAccess sel = (JCFieldAccess) expr;
if (sel.name != names._class) {
return illegal();
} else {
log.error(token.pos, "no.annotations.on.dot.class");
return expr;
}
}
default:
return illegal(typeAnnos.head.pos);
}
} else {
// Type annotations targeting a cast
t = insertAnnotationsToMostInner(expr, typeAnnos, false);
}
break;
case UNDERSCORE: case IDENTIFIER: case ASSERT: case ENUM:
if (typeArgs != null) return illegal();
if ((mode & EXPR) != 0 && peekToken(ARROW)) {
t = lambdaExpressionOrStatement(false, false, pos);
} else {
t = toP(F.at(token.pos).Ident(ident()));
loop: while (true) {
pos = token.pos;
final List<JCAnnotation> annos = typeAnnotationsOpt();
// need to report an error later if LBRACKET is for array
// index access rather than array creation level
if (!annos.isEmpty() && token.kind != LBRACKET && token.kind != ELLIPSIS)
return illegal(annos.head.pos);
switch (token.kind) {
case LBRACKET:
nextToken();
if (token.kind == RBRACKET) {
nextToken();
t = bracketsOpt(t);
t = toP(F.at(pos).TypeArray(t));
if (annos.nonEmpty()) {
t = toP(F.at(pos).AnnotatedType(annos, t));
}
// .class is only allowed if there were no annotations
JCExpression nt = bracketsSuffix(t);
if (nt != t && (annos.nonEmpty() || TreeInfo.containsTypeAnnotation(t))) {
// t and nt are different if bracketsSuffix parsed a .class.
// The check for nonEmpty covers the case when the whole array is annotated.
// Helper method isAnnotated looks for annos deeply within t.
syntaxError("no.annotations.on.dot.class");
}
t = nt;
} else {
if ((mode & EXPR) != 0) {
mode = EXPR;
JCExpression t1 = term();
if (!annos.isEmpty()) t = illegal(annos.head.pos);
t = to(F.at(pos).Indexed(t, t1));
}
accept(RBRACKET);
}
break loop;
case LPAREN:
if ((mode & EXPR) != 0) {
mode = EXPR;
t = arguments(typeArgs, t);
if (!annos.isEmpty()) t = illegal(annos.head.pos);
typeArgs = null;
}
break loop;
case DOT:
nextToken();
int oldmode = mode;
mode &= ~NOPARAMS;
typeArgs = typeArgumentsOpt(EXPR);
mode = oldmode;
if ((mode & EXPR) != 0) {
switch (token.kind) {
case CLASS:
if (typeArgs != null) return illegal();
mode = EXPR;
t = to(F.at(pos).Select(t, names._class));
nextToken();
break loop;
case THIS:
if (typeArgs != null) return illegal();
mode = EXPR;
t = to(F.at(pos).Select(t, names._this));
nextToken();
break loop;
case SUPER:
mode = EXPR;
t = to(F.at(pos).Select(t, names._super));
t = superSuffix(typeArgs, t);
typeArgs = null;
break loop;
case NEW:
if (typeArgs != null) return illegal();
mode = EXPR;
int pos1 = token.pos;
nextToken();
if (token.kind == LT) typeArgs = typeArguments(false);
t = innerCreator(pos1, typeArgs, t);
typeArgs = null;
break loop;
}
}
List<JCAnnotation> tyannos = null;
if ((mode & TYPE) != 0 && token.kind == MONKEYS_AT) {
tyannos = typeAnnotationsOpt();
}
// typeArgs saved for next loop iteration.
t = toP(F.at(pos).Select(t, ident()));
if (tyannos != null && tyannos.nonEmpty()) {
t = toP(F.at(tyannos.head.pos).AnnotatedType(tyannos, t));
}
break;
case ELLIPSIS:
if (this.permitTypeAnnotationsPushBack) {
this.typeAnnotationsPushedBack = annos;
} else if (annos.nonEmpty()) {
// Don't return here -- error recovery attempt
illegal(annos.head.pos);
}
break loop;
case LT:
if ((mode & TYPE) == 0 && isUnboundMemberRef()) {
//this is an unbound method reference whose qualifier
//is a generic type i.e. A<S>::m
int pos1 = token.pos;
accept(LT);
ListBuffer<JCExpression> args = new ListBuffer<>();
args.append(typeArgument());
while (token.kind == COMMA) {
nextToken();
args.append(typeArgument());
}
accept(GT);
t = toP(F.at(pos1).TypeApply(t, args.toList()));
checkGenerics();
while (token.kind == DOT) {
nextToken();
mode = TYPE;
t = toP(F.at(token.pos).Select(t, ident()));
t = typeArgumentsOpt(t);
}
t = bracketsOpt(t);
if (token.kind != COLCOL) {
//method reference expected here
t = illegal();
}
mode = EXPR;
return term3Rest(t, typeArgs);
}
break loop;
default:
break loop;
}
}
}
if (typeArgs != null) illegal();
t = typeArgumentsOpt(t);
break;
case BYTE: case SHORT: case CHAR: case INT: case LONG: case FLOAT:
case DOUBLE: case BOOLEAN:
if (typeArgs != null) illegal();
t = bracketsSuffix(bracketsOpt(basicType()));
break;
case VOID:
if (typeArgs != null) illegal();
if ((mode & EXPR) != 0) {
nextToken();
if (token.kind == DOT) {
JCPrimitiveTypeTree ti = toP(F.at(pos).TypeIdent(TypeTag.VOID));
t = bracketsSuffix(ti);
} else {
return illegal(pos);
}
} else {
// Support the corner case of myMethodHandle.<void>invoke() by passing
// a void type (like other primitive types) to the next phase.
// The error will be reported in Attr.attribTypes or Attr.visitApply.
JCPrimitiveTypeTree ti = to(F.at(pos).TypeIdent(TypeTag.VOID));
nextToken();
return ti;
//return illegal();
}
break;
default:
return illegal();
}
return term3Rest(t, typeArgs);
}
JCExpression term3Rest(JCExpression t, List<JCExpression> typeArgs) {
if (typeArgs != null) illegal();
while (true) {
int pos1 = token.pos;
final List<JCAnnotation> annos = typeAnnotationsOpt();
if (token.kind == LBRACKET) {
nextToken();
if ((mode & TYPE) != 0) {
int oldmode = mode;
mode = TYPE;
if (token.kind == RBRACKET) {
nextToken();
t = bracketsOpt(t);
t = toP(F.at(pos1).TypeArray(t));
if (token.kind == COLCOL) {
mode = EXPR;
continue;
}
if (annos.nonEmpty()) {
t = toP(F.at(pos1).AnnotatedType(annos, t));
}
return t;
}
mode = oldmode;
}
if ((mode & EXPR) != 0) {
mode = EXPR;
JCExpression t1 = term();
t = to(F.at(pos1).Indexed(t, t1));
}
accept(RBRACKET);
} else if (token.kind == DOT) {
nextToken();
typeArgs = typeArgumentsOpt(EXPR);
if (token.kind == SUPER && (mode & EXPR) != 0) {
mode = EXPR;
t = to(F.at(pos1).Select(t, names._super));
nextToken();
t = arguments(typeArgs, t);
typeArgs = null;
} else if (token.kind == NEW && (mode & EXPR) != 0) {
if (typeArgs != null) return illegal();
mode = EXPR;
int pos2 = token.pos;
nextToken();
if (token.kind == LT) typeArgs = typeArguments(false);
t = innerCreator(pos2, typeArgs, t);
typeArgs = null;
} else {
List<JCAnnotation> tyannos = null;
if ((mode & TYPE) != 0 && token.kind == MONKEYS_AT) {
// is the mode check needed?
tyannos = typeAnnotationsOpt();
}
t = toP(F.at(pos1).Select(t, ident()));
if (tyannos != null && tyannos.nonEmpty()) {
t = toP(F.at(tyannos.head.pos).AnnotatedType(tyannos, t));
}
t = argumentsOpt(typeArgs, typeArgumentsOpt(t));
typeArgs = null;
}
} else if ((mode & EXPR) != 0 && token.kind == COLCOL) {
mode = EXPR;
if (typeArgs != null) return illegal();
accept(COLCOL);
t = memberReferenceSuffix(pos1, t);
} else {
if (!annos.isEmpty()) {
if (permitTypeAnnotationsPushBack)
typeAnnotationsPushedBack = annos;
else
return illegal(annos.head.pos);
}
break;
}
}
while ((token.kind == PLUSPLUS || token.kind == SUBSUB) && (mode & EXPR) != 0) {
mode = EXPR;
t = to(F.at(token.pos).Unary(
token.kind == PLUSPLUS ? POSTINC : POSTDEC, t));
nextToken();
}
return toP(t);
}
/**
* If we see an identifier followed by a '<' it could be an unbound
* method reference or a binary expression. To disambiguate, look for a
* matching '>' and see if the subsequent terminal is either '.' or '::'.
*/
@SuppressWarnings("fallthrough")
boolean isUnboundMemberRef() {
int pos = 0, depth = 0;
outer: for (Token t = S.token(pos) ; ; t = S.token(++pos)) {
switch (t.kind) {
case IDENTIFIER: case UNDERSCORE: case QUES: case EXTENDS: case SUPER:
case DOT: case RBRACKET: case LBRACKET: case COMMA:
case BYTE: case SHORT: case INT: case LONG: case FLOAT:
case DOUBLE: case BOOLEAN: case CHAR:
case MONKEYS_AT:
break;
case LPAREN:
// skip annotation values
int nesting = 0;
for (; ; pos++) {
TokenKind tk2 = S.token(pos).kind;
switch (tk2) {
case EOF:
return false;
case LPAREN:
nesting++;
break;
case RPAREN:
nesting--;
if (nesting == 0) {
continue outer;
}
break;
}
}
case LT:
depth++; break;
case GTGTGT:
depth--;
case GTGT:
depth--;
case GT:
depth--;
if (depth == 0) {
TokenKind nextKind = S.token(pos + 1).kind;
return
nextKind == TokenKind.DOT ||
nextKind == TokenKind.LBRACKET ||
nextKind == TokenKind.COLCOL;
}
break;
default:
return false;
}
}
}
/**
* If we see an identifier followed by a '<' it could be an unbound
* method reference or a binary expression. To disambiguate, look for a
* matching '>' and see if the subsequent terminal is either '.' or '::'.
*/
@SuppressWarnings("fallthrough")
ParensResult analyzeParens() {
int depth = 0;
boolean type = false;
outer: for (int lookahead = 0 ; ; lookahead++) {
TokenKind tk = S.token(lookahead).kind;
switch (tk) {
case COMMA:
type = true;
case EXTENDS: case SUPER: case DOT: case AMP:
//skip
break;
case QUES:
if (peekToken(lookahead, EXTENDS) ||
peekToken(lookahead, SUPER)) {
//wildcards
type = true;
}
break;
case BYTE: case SHORT: case INT: case LONG: case FLOAT:
case DOUBLE: case BOOLEAN: case CHAR: case VOID:
if (peekToken(lookahead, RPAREN)) {
//Type, ')' -> cast
return ParensResult.CAST;
} else if (peekToken(lookahead, LAX_IDENTIFIER)) {
//Type, Identifier/'_'/'assert'/'enum' -> explicit lambda
return ParensResult.EXPLICIT_LAMBDA;
}
break;
case LPAREN:
if (lookahead != 0) {
// '(' in a non-starting position -> parens
return ParensResult.PARENS;
} else if (peekToken(lookahead, RPAREN)) {
// '(', ')' -> explicit lambda
return ParensResult.EXPLICIT_LAMBDA;
}
break;
case RPAREN:
// if we have seen something that looks like a type,
// then it's a cast expression
if (type) return ParensResult.CAST;
// otherwise, disambiguate cast vs. parenthesized expression
// based on subsequent token.
switch (S.token(lookahead + 1).kind) {
/*case PLUSPLUS: case SUBSUB: */
case BANG: case TILDE:
case LPAREN: case THIS: case SUPER:
case INTLITERAL: case LONGLITERAL: case FLOATLITERAL:
case DOUBLELITERAL: case CHARLITERAL: case STRINGLITERAL:
case TRUE: case FALSE: case NULL:
case NEW: case IDENTIFIER: case ASSERT: case ENUM: case UNDERSCORE:
case BYTE: case SHORT: case CHAR: case INT:
case LONG: case FLOAT: case DOUBLE: case BOOLEAN: case VOID:
return ParensResult.CAST;
default:
return ParensResult.PARENS;
}
case UNDERSCORE:
case ASSERT:
case ENUM:
case IDENTIFIER:
if (peekToken(lookahead, LAX_IDENTIFIER)) {
// Identifier, Identifier/'_'/'assert'/'enum' -> explicit lambda
return ParensResult.EXPLICIT_LAMBDA;
} else if (peekToken(lookahead, RPAREN, ARROW)) {
// Identifier, ')' '->' -> implicit lambda
return ParensResult.IMPLICIT_LAMBDA;
}
type = false;
break;
case FINAL:
case ELLIPSIS:
//those can only appear in explicit lambdas
return ParensResult.EXPLICIT_LAMBDA;
case MONKEYS_AT:
type = true;
lookahead += 1; //skip '@'
while (peekToken(lookahead, DOT)) {
lookahead += 2;
}
if (peekToken(lookahead, LPAREN)) {
lookahead++;
//skip annotation values
int nesting = 0;
for (; ; lookahead++) {
TokenKind tk2 = S.token(lookahead).kind;
switch (tk2) {
case EOF:
return ParensResult.PARENS;
case LPAREN:
nesting++;
break;
case RPAREN:
nesting--;
if (nesting == 0) {
continue outer;
}
break;
}
}
}
break;
case LBRACKET:
if (peekToken(lookahead, RBRACKET, LAX_IDENTIFIER)) {
// '[', ']', Identifier/'_'/'assert'/'enum' -> explicit lambda
return ParensResult.EXPLICIT_LAMBDA;
} else if (peekToken(lookahead, RBRACKET, RPAREN) ||
peekToken(lookahead, RBRACKET, AMP)) {
// '[', ']', ')' -> cast
// '[', ']', '&' -> cast (intersection type)
return ParensResult.CAST;
} else if (peekToken(lookahead, RBRACKET)) {
//consume the ']' and skip
type = true;
lookahead++;
break;
} else {
return ParensResult.PARENS;
}
case LT:
depth++; break;
case GTGTGT:
depth--;
case GTGT:
depth--;
case GT:
depth--;
if (depth == 0) {
if (peekToken(lookahead, RPAREN) ||
peekToken(lookahead, AMP)) {
// '>', ')' -> cast
// '>', '&' -> cast
return ParensResult.CAST;
} else if (peekToken(lookahead, LAX_IDENTIFIER, COMMA) ||
peekToken(lookahead, LAX_IDENTIFIER, RPAREN, ARROW) ||
peekToken(lookahead, ELLIPSIS)) {
// '>', Identifier/'_'/'assert'/'enum', ',' -> explicit lambda
// '>', Identifier/'_'/'assert'/'enum', ')', '->' -> explicit lambda
// '>', '...' -> explicit lambda
return ParensResult.EXPLICIT_LAMBDA;
}
//it looks a type, but could still be (i) a cast to generic type,
//(ii) an unbound method reference or (iii) an explicit lambda
type = true;
break;
} else if (depth < 0) {
//unbalanced '<', '>' - not a generic type
return ParensResult.PARENS;
}
break;
default:
//this includes EOF
return ParensResult.PARENS;
}
}
}
/** Accepts all identifier-like tokens */
Filter<TokenKind> LAX_IDENTIFIER = new Filter<TokenKind>() {
public boolean accepts(TokenKind t) {
return t == IDENTIFIER || t == UNDERSCORE || t == ASSERT || t == ENUM;
}
};
enum ParensResult {
CAST,
EXPLICIT_LAMBDA,
IMPLICIT_LAMBDA,
PARENS
}
JCExpression lambdaExpressionOrStatement(boolean hasParens, boolean explicitParams, int pos) {
List<JCVariableDecl> params = explicitParams ?
formalParameters(true) :
implicitParameters(hasParens);
return lambdaExpressionOrStatementRest(params, pos);
}
JCExpression lambdaExpressionOrStatementRest(List<JCVariableDecl> args, int pos) {
checkLambda();
accept(ARROW);
return token.kind == LBRACE ?
lambdaStatement(args, pos, pos) :
lambdaExpression(args, pos);
}
JCExpression lambdaStatement(List<JCVariableDecl> args, int pos, int pos2) {
JCBlock block = block(pos2, 0);
return toP(F.at(pos).Lambda(args, block));
}
JCExpression lambdaExpression(List<JCVariableDecl> args, int pos) {
JCTree expr = parseExpression();
return toP(F.at(pos).Lambda(args, expr));
}
/** SuperSuffix = Arguments | "." [TypeArguments] Ident [Arguments]
*/
JCExpression superSuffix(List<JCExpression> typeArgs, JCExpression t) {
nextToken();
if (token.kind == LPAREN || typeArgs != null) {
t = arguments(typeArgs, t);
} else if (token.kind == COLCOL) {
if (typeArgs != null) return illegal();
t = memberReferenceSuffix(t);
} else {
int pos = token.pos;
accept(DOT);
typeArgs = (token.kind == LT) ? typeArguments(false) : null;
t = toP(F.at(pos).Select(t, ident()));
t = argumentsOpt(typeArgs, t);
}
return t;
}
/** BasicType = BYTE | SHORT | CHAR | INT | LONG | FLOAT | DOUBLE | BOOLEAN
*/
JCPrimitiveTypeTree basicType() {
JCPrimitiveTypeTree t = to(F.at(token.pos).TypeIdent(typetag(token.kind)));
nextToken();
return t;
}
/** ArgumentsOpt = [ Arguments ]
*/
JCExpression argumentsOpt(List<JCExpression> typeArgs, JCExpression t) {
if ((mode & EXPR) != 0 && token.kind == LPAREN || typeArgs != null) {
mode = EXPR;
return arguments(typeArgs, t);
} else {
return t;
}
}
/** Arguments = "(" [Expression { COMMA Expression }] ")"
*/
List<JCExpression> arguments() {
ListBuffer<JCExpression> args = new ListBuffer<>();
if (token.kind == LPAREN) {
nextToken();
if (token.kind != RPAREN) {
args.append(parseExpression());
while (token.kind == COMMA) {
nextToken();
args.append(parseExpression());
}
}
accept(RPAREN);
} else {
syntaxError(token.pos, "expected", LPAREN);
}
return args.toList();
}
JCMethodInvocation arguments(List<JCExpression> typeArgs, JCExpression t) {
int pos = token.pos;
List<JCExpression> args = arguments();
return toP(F.at(pos).Apply(typeArgs, t, args));
}
/** TypeArgumentsOpt = [ TypeArguments ]
*/
JCExpression typeArgumentsOpt(JCExpression t) {
if (token.kind == LT &&
(mode & TYPE) != 0 &&
(mode & NOPARAMS) == 0) {
mode = TYPE;
checkGenerics();
return typeArguments(t, false);
} else {
return t;
}
}
List<JCExpression> typeArgumentsOpt() {
return typeArgumentsOpt(TYPE);
}
List<JCExpression> typeArgumentsOpt(int useMode) {
if (token.kind == LT) {
checkGenerics();
if ((mode & useMode) == 0 ||
(mode & NOPARAMS) != 0) {
illegal();
}
mode = useMode;
return typeArguments(false);
}
return null;
}
/**
* {@literal
* TypeArguments = "<" TypeArgument {"," TypeArgument} ">"
* }
*/
List<JCExpression> typeArguments(boolean diamondAllowed) {
if (token.kind == LT) {
nextToken();
if (token.kind == GT && diamondAllowed) {
checkDiamond();
mode |= DIAMOND;
nextToken();
return List.nil();
} else {
ListBuffer<JCExpression> args = new ListBuffer<>();
args.append(((mode & EXPR) == 0) ? typeArgument() : parseType());
while (token.kind == COMMA) {
nextToken();
args.append(((mode & EXPR) == 0) ? typeArgument() : parseType());
}
switch (token.kind) {
case GTGTGTEQ: case GTGTEQ: case GTEQ:
case GTGTGT: case GTGT:
token = S.split();
break;
case GT:
nextToken();
break;
default:
args.append(syntaxError(token.pos, "expected", GT));
break;
}
return args.toList();
}
} else {
return List.<JCExpression>of(syntaxError(token.pos, "expected", LT));
}
}
/**
* {@literal
* TypeArgument = Type
* | [Annotations] "?"
* | [Annotations] "?" EXTENDS Type {"&" Type}
* | [Annotations] "?" SUPER Type
* }
*/
JCExpression typeArgument() {
List<JCAnnotation> annotations = typeAnnotationsOpt();
if (token.kind != QUES) return parseType(annotations);
int pos = token.pos;
nextToken();
JCExpression result;
if (token.kind == EXTENDS) {
TypeBoundKind t = to(F.at(pos).TypeBoundKind(BoundKind.EXTENDS));
nextToken();
JCExpression bound = parseType();
result = F.at(pos).Wildcard(t, bound);
} else if (token.kind == SUPER) {
TypeBoundKind t = to(F.at(pos).TypeBoundKind(BoundKind.SUPER));
nextToken();
JCExpression bound = parseType();
result = F.at(pos).Wildcard(t, bound);
} else if (LAX_IDENTIFIER.accepts(token.kind)) {
//error recovery
TypeBoundKind t = F.at(Position.NOPOS).TypeBoundKind(BoundKind.UNBOUND);
JCExpression wc = toP(F.at(pos).Wildcard(t, null));
JCIdent id = toP(F.at(token.pos).Ident(ident()));
JCErroneous err = F.at(pos).Erroneous(List.<JCTree>of(wc, id));
reportSyntaxError(err, "expected3", GT, EXTENDS, SUPER);
result = err;
} else {
TypeBoundKind t = toP(F.at(pos).TypeBoundKind(BoundKind.UNBOUND));
result = toP(F.at(pos).Wildcard(t, null));
}
if (!annotations.isEmpty()) {
result = toP(F.at(annotations.head.pos).AnnotatedType(annotations,result));
}
return result;
}
JCTypeApply typeArguments(JCExpression t, boolean diamondAllowed) {
int pos = token.pos;
List<JCExpression> args = typeArguments(diamondAllowed);
return toP(F.at(pos).TypeApply(t, args));
}
/**
* BracketsOpt = { [Annotations] "[" "]" }*
*
* <p>
*
* <code>annotations</code> is the list of annotations targeting
* the expression <code>t</code>.
*/
private JCExpression bracketsOpt(JCExpression t,
List<JCAnnotation> annotations) {
List<JCAnnotation> nextLevelAnnotations = typeAnnotationsOpt();
if (token.kind == LBRACKET) {
int pos = token.pos;
nextToken();
t = bracketsOptCont(t, pos, nextLevelAnnotations);
} else if (!nextLevelAnnotations.isEmpty()) {
if (permitTypeAnnotationsPushBack) {
this.typeAnnotationsPushedBack = nextLevelAnnotations;
} else {
return illegal(nextLevelAnnotations.head.pos);
}
}
if (!annotations.isEmpty()) {
t = toP(F.at(token.pos).AnnotatedType(annotations, t));
}
return t;
}
/** BracketsOpt = [ "[" "]" { [Annotations] "[" "]"} ]
*/
private JCExpression bracketsOpt(JCExpression t) {
return bracketsOpt(t, List.<JCAnnotation>nil());
}
private JCExpression bracketsOptCont(JCExpression t, int pos,
List<JCAnnotation> annotations) {
accept(RBRACKET);
t = bracketsOpt(t);
t = toP(F.at(pos).TypeArray(t));
if (annotations.nonEmpty()) {
t = toP(F.at(pos).AnnotatedType(annotations, t));
}
return t;
}
/** BracketsSuffixExpr = "." CLASS
* BracketsSuffixType =
*/
JCExpression bracketsSuffix(JCExpression t) {
if ((mode & EXPR) != 0 && token.kind == DOT) {
mode = EXPR;
int pos = token.pos;
nextToken();
accept(CLASS);
if (token.pos == endPosTable.errorEndPos) {
// error recovery
Name name;
if (LAX_IDENTIFIER.accepts(token.kind)) {
name = token.name();
nextToken();
} else {
name = names.error;
}
t = F.at(pos).Erroneous(List.<JCTree>of(toP(F.at(pos).Select(t, name))));
} else {
t = toP(F.at(pos).Select(t, names._class));
}
} else if ((mode & TYPE) != 0) {
if (token.kind != COLCOL) {
mode = TYPE;
}
} else if (token.kind != COLCOL) {
syntaxError(token.pos, "dot.class.expected");
}
return t;
}
/**
* MemberReferenceSuffix = "::" [TypeArguments] Ident
* | "::" [TypeArguments] "new"
*/
JCExpression memberReferenceSuffix(JCExpression t) {
int pos1 = token.pos;
accept(COLCOL);
return memberReferenceSuffix(pos1, t);
}
JCExpression memberReferenceSuffix(int pos1, JCExpression t) {
checkMethodReferences();
mode = EXPR;
List<JCExpression> typeArgs = null;
if (token.kind == LT) {
typeArgs = typeArguments(false);
}
Name refName;
ReferenceMode refMode;
if (token.kind == NEW) {
refMode = ReferenceMode.NEW;
refName = names.init;
nextToken();
} else {
refMode = ReferenceMode.INVOKE;
refName = ident();
}
return toP(F.at(t.getStartPosition()).Reference(refMode, refName, t, typeArgs));
}
/** Creator = [Annotations] Qualident [TypeArguments] ( ArrayCreatorRest | ClassCreatorRest )
*/
JCExpression creator(int newpos, List<JCExpression> typeArgs) {
List<JCAnnotation> newAnnotations = typeAnnotationsOpt();
switch (token.kind) {
case BYTE: case SHORT: case CHAR: case INT: case LONG: case FLOAT:
case DOUBLE: case BOOLEAN:
if (typeArgs == null) {
if (newAnnotations.isEmpty()) {
return arrayCreatorRest(newpos, basicType());
} else {
return arrayCreatorRest(newpos, toP(F.at(newAnnotations.head.pos).AnnotatedType(newAnnotations, basicType())));
}
}
break;
default:
}
JCExpression t = qualident(true);
int oldmode = mode;
mode = TYPE;
boolean diamondFound = false;
int lastTypeargsPos = -1;
if (token.kind == LT) {
checkGenerics();
lastTypeargsPos = token.pos;
t = typeArguments(t, true);
diamondFound = (mode & DIAMOND) != 0;
}
while (token.kind == DOT) {
if (diamondFound) {
//cannot select after a diamond
illegal();
}
int pos = token.pos;
nextToken();
List<JCAnnotation> tyannos = typeAnnotationsOpt();
t = toP(F.at(pos).Select(t, ident()));
if (tyannos != null && tyannos.nonEmpty()) {
t = toP(F.at(tyannos.head.pos).AnnotatedType(tyannos, t));
}
if (token.kind == LT) {
lastTypeargsPos = token.pos;
checkGenerics();
t = typeArguments(t, true);
diamondFound = (mode & DIAMOND) != 0;
}
}
mode = oldmode;
if (token.kind == LBRACKET || token.kind == MONKEYS_AT) {
// handle type annotations for non primitive arrays
if (newAnnotations.nonEmpty()) {
t = insertAnnotationsToMostInner(t, newAnnotations, false);
}
JCExpression e = arrayCreatorRest(newpos, t);
if (diamondFound) {
reportSyntaxError(lastTypeargsPos, "cannot.create.array.with.diamond");
return toP(F.at(newpos).Erroneous(List.of(e)));
}
else if (typeArgs != null) {
int pos = newpos;
if (!typeArgs.isEmpty() && typeArgs.head.pos != Position.NOPOS) {
// note: this should always happen but we should
// not rely on this as the parser is continuously
// modified to improve error recovery.
pos = typeArgs.head.pos;
}
setErrorEndPos(S.prevToken().endPos);
JCErroneous err = F.at(pos).Erroneous(typeArgs.prepend(e));
reportSyntaxError(err, "cannot.create.array.with.type.arguments");
return toP(err);
}
return e;
} else if (token.kind == LPAREN) {
JCNewClass newClass = classCreatorRest(newpos, null, typeArgs, t);
if (newClass.def != null) {
assert newClass.def.mods.annotations.isEmpty();
if (newAnnotations.nonEmpty()) {
// Add type and declaration annotations to the new class;
// com.sun.tools.javac.code.TypeAnnotations.TypeAnnotationPositions.visitNewClass(JCNewClass)
// will later remove all type annotations and only leave the
// declaration annotations.
newClass.def.mods.pos = earlier(newClass.def.mods.pos, newAnnotations.head.pos);
newClass.def.mods.annotations = newAnnotations;
}
} else {
// handle type annotations for instantiations
if (newAnnotations.nonEmpty()) {
t = insertAnnotationsToMostInner(t, newAnnotations, false);
newClass.clazz = t;
}
}
return newClass;
} else {
setErrorEndPos(token.pos);
reportSyntaxError(token.pos, "expected2", LPAREN, LBRACKET);
t = toP(F.at(newpos).NewClass(null, typeArgs, t, List.<JCExpression>nil(), null));
return toP(F.at(newpos).Erroneous(List.<JCTree>of(t)));
}
}
/** InnerCreator = [Annotations] Ident [TypeArguments] ClassCreatorRest
*/
JCExpression innerCreator(int newpos, List<JCExpression> typeArgs, JCExpression encl) {
List<JCAnnotation> newAnnotations = typeAnnotationsOpt();
JCExpression t = toP(F.at(token.pos).Ident(ident()));
if (newAnnotations.nonEmpty()) {
t = toP(F.at(newAnnotations.head.pos).AnnotatedType(newAnnotations, t));
}
if (token.kind == LT) {
int oldmode = mode;
checkGenerics();
t = typeArguments(t, true);
mode = oldmode;
}
return classCreatorRest(newpos, encl, typeArgs, t);
}
/** ArrayCreatorRest = [Annotations] "[" ( "]" BracketsOpt ArrayInitializer
* | Expression "]" {[Annotations] "[" Expression "]"} BracketsOpt )
*/
JCExpression arrayCreatorRest(int newpos, JCExpression elemtype) {
List<JCAnnotation> annos = typeAnnotationsOpt();
accept(LBRACKET);
if (token.kind == RBRACKET) {
accept(RBRACKET);
elemtype = bracketsOpt(elemtype, annos);
if (token.kind == LBRACE) {
JCNewArray na = (JCNewArray)arrayInitializer(newpos, elemtype);
if (annos.nonEmpty()) {
// when an array initializer is present then
// the parsed annotations should target the
// new array tree
// bracketsOpt inserts the annotation in
// elemtype, and it needs to be corrected
//
JCAnnotatedType annotated = (JCAnnotatedType)elemtype;
assert annotated.annotations == annos;
na.annotations = annotated.annotations;
na.elemtype = annotated.underlyingType;
}
return na;
} else {
JCExpression t = toP(F.at(newpos).NewArray(elemtype, List.<JCExpression>nil(), null));
return syntaxError(token.pos, List.<JCTree>of(t), "array.dimension.missing");
}
} else {
ListBuffer<JCExpression> dims = new ListBuffer<>();
// maintain array dimension type annotations
ListBuffer<List<JCAnnotation>> dimAnnotations = new ListBuffer<>();
dimAnnotations.append(annos);
dims.append(parseExpression());
accept(RBRACKET);
while (token.kind == LBRACKET
|| token.kind == MONKEYS_AT) {
List<JCAnnotation> maybeDimAnnos = typeAnnotationsOpt();
int pos = token.pos;
nextToken();
if (token.kind == RBRACKET) {
elemtype = bracketsOptCont(elemtype, pos, maybeDimAnnos);
} else {
if (token.kind == RBRACKET) { // no dimension
elemtype = bracketsOptCont(elemtype, pos, maybeDimAnnos);
} else {
dimAnnotations.append(maybeDimAnnos);
dims.append(parseExpression());
accept(RBRACKET);
}
}
}
JCNewArray na = toP(F.at(newpos).NewArray(elemtype, dims.toList(), null));
na.dimAnnotations = dimAnnotations.toList();
return na;
}
}
/** ClassCreatorRest = Arguments [ClassBody]
*/
JCNewClass classCreatorRest(int newpos,
JCExpression encl,
List<JCExpression> typeArgs,
JCExpression t)
{
List<JCExpression> args = arguments();
JCClassDecl body = null;
if (token.kind == LBRACE) {
int pos = token.pos;
List<JCTree> defs = classOrInterfaceBody(names.empty, false);
JCModifiers mods = F.at(Position.NOPOS).Modifiers(0);
body = toP(F.at(pos).AnonymousClassDef(mods, defs));
}
return toP(F.at(newpos).NewClass(encl, typeArgs, t, args, body));
}
/** ArrayInitializer = "{" [VariableInitializer {"," VariableInitializer}] [","] "}"
*/
JCExpression arrayInitializer(int newpos, JCExpression t) {
accept(LBRACE);
ListBuffer<JCExpression> elems = new ListBuffer<>();
if (token.kind == COMMA) {
nextToken();
} else if (token.kind != RBRACE) {
elems.append(variableInitializer());
while (token.kind == COMMA) {
nextToken();
if (token.kind == RBRACE) break;
elems.append(variableInitializer());
}
}
accept(RBRACE);
return toP(F.at(newpos).NewArray(t, List.<JCExpression>nil(), elems.toList()));
}
/** VariableInitializer = ArrayInitializer | Expression
*/
public JCExpression variableInitializer() {
return token.kind == LBRACE ? arrayInitializer(token.pos, null) : parseExpression();
}
/** ParExpression = "(" Expression ")"
*/
JCExpression parExpression() {
int pos = token.pos;
accept(LPAREN);
JCExpression t = parseExpression();
accept(RPAREN);
return toP(F.at(pos).Parens(t));
}
/** Block = "{" BlockStatements "}"
*/
JCBlock block(int pos, long flags) {
accept(LBRACE);
List<JCStatement> stats = blockStatements();
JCBlock t = F.at(pos).Block(flags, stats);
while (token.kind == CASE || token.kind == DEFAULT) {
syntaxError("orphaned", token.kind);
switchBlockStatementGroups();
}
// the Block node has a field "endpos" for first char of last token, which is
// usually but not necessarily the last char of the last token.
t.endpos = token.pos;
accept(RBRACE);
return toP(t);
}
public JCBlock block() {
return block(token.pos, 0);
}
/** BlockStatements = { BlockStatement }
* BlockStatement = LocalVariableDeclarationStatement
* | ClassOrInterfaceOrEnumDeclaration
* | [Ident ":"] Statement
* LocalVariableDeclarationStatement
* = { FINAL | '@' Annotation } Type VariableDeclarators ";"
*/
@SuppressWarnings("fallthrough")
List<JCStatement> blockStatements() {
//todo: skip to anchor on error(?)
int lastErrPos = -1;
ListBuffer<JCStatement> stats = new ListBuffer<>();
while (true) {
List<JCStatement> stat = blockStatement();
if (stat.isEmpty()) {
return stats.toList();
} else {
// error recovery
if (token.pos == lastErrPos)
return stats.toList();
if (token.pos <= endPosTable.errorEndPos) {
skip(false, true, true, true);
lastErrPos = token.pos;
}
stats.addAll(stat);
}
}
}
/*
* This method parses a statement treating it as a block, relaxing the
* JLS restrictions, allows us to parse more faulty code, doing so
* enables us to provide better and accurate diagnostics to the user.
*/
JCStatement parseStatementAsBlock() {
int pos = token.pos;
List<JCStatement> stats = blockStatement();
if (stats.isEmpty()) {
JCErroneous e = F.at(pos).Erroneous();
error(e, "illegal.start.of.stmt");
return F.at(pos).Exec(e);
} else {
JCStatement first = stats.head;
String error = null;
switch (first.getTag()) {
case CLASSDEF:
error = "class.not.allowed";
break;
case VARDEF:
error = "variable.not.allowed";
break;
}
if (error != null) {
error(first, error);
List<JCBlock> blist = List.of(F.at(first.pos).Block(0, stats));
return toP(F.at(pos).Exec(F.at(first.pos).Erroneous(blist)));
}
return first;
}
}
@SuppressWarnings("fallthrough")
List<JCStatement> blockStatement() {
//todo: skip to anchor on error(?)
int pos = token.pos;
switch (token.kind) {
case RBRACE: case CASE: case DEFAULT: case EOF:
return List.nil();
case LBRACE: case IF: case FOR: case WHILE: case DO: case TRY:
case SWITCH: case SYNCHRONIZED: case RETURN: case THROW: case BREAK:
case CONTINUE: case SEMI: case ELSE: case FINALLY: case CATCH:
return List.of(parseStatement());
case MONKEYS_AT:
case FINAL: {
Comment dc = token.comment(CommentStyle.JAVADOC);
JCModifiers mods = modifiersOpt();
if (token.kind == INTERFACE ||
token.kind == CLASS ||
allowEnums && token.kind == ENUM) {
return List.of(classOrInterfaceOrEnumDeclaration(mods, dc));
} else {
JCExpression t = parseType();
ListBuffer<JCStatement> stats =
variableDeclarators(mods, t, new ListBuffer<JCStatement>());
// A "LocalVariableDeclarationStatement" subsumes the terminating semicolon
storeEnd(stats.last(), token.endPos);
accept(SEMI);
return stats.toList();
}
}
case ABSTRACT: case STRICTFP: {
Comment dc = token.comment(CommentStyle.JAVADOC);
JCModifiers mods = modifiersOpt();
return List.of(classOrInterfaceOrEnumDeclaration(mods, dc));
}
case INTERFACE:
case CLASS:
Comment dc = token.comment(CommentStyle.JAVADOC);
return List.of(classOrInterfaceOrEnumDeclaration(modifiersOpt(), dc));
case ENUM:
case ASSERT:
if (allowEnums && token.kind == ENUM) {
error(token.pos, "local.enum");
dc = token.comment(CommentStyle.JAVADOC);
return List.of(classOrInterfaceOrEnumDeclaration(modifiersOpt(), dc));
} else if (allowAsserts && token.kind == ASSERT) {
return List.of(parseStatement());
}
/* fall through to default */
default:
Token prevToken = token;
JCExpression t = term(EXPR | TYPE);
if (token.kind == COLON && t.hasTag(IDENT)) {
nextToken();
JCStatement stat = parseStatement();
return List.<JCStatement>of(F.at(pos).Labelled(prevToken.name(), stat));
} else if ((lastmode & TYPE) != 0 && LAX_IDENTIFIER.accepts(token.kind)) {
pos = token.pos;
JCModifiers mods = F.at(Position.NOPOS).Modifiers(0);
F.at(pos);
ListBuffer<JCStatement> stats =
variableDeclarators(mods, t, new ListBuffer<JCStatement>());
// A "LocalVariableDeclarationStatement" subsumes the terminating semicolon
storeEnd(stats.last(), token.endPos);
accept(SEMI);
return stats.toList();
} else {
// This Exec is an "ExpressionStatement"; it subsumes the terminating semicolon
JCExpressionStatement expr = to(F.at(pos).Exec(checkExprStat(t)));
accept(SEMI);
return List.<JCStatement>of(expr);
}
}
}
/** Statement =
* Block
* | IF ParExpression Statement [ELSE Statement]
* | FOR "(" ForInitOpt ";" [Expression] ";" ForUpdateOpt ")" Statement
* | FOR "(" FormalParameter : Expression ")" Statement
* | WHILE ParExpression Statement
* | DO Statement WHILE ParExpression ";"
* | TRY Block ( Catches | [Catches] FinallyPart )
* | TRY "(" ResourceSpecification ";"opt ")" Block [Catches] [FinallyPart]
* | SWITCH ParExpression "{" SwitchBlockStatementGroups "}"
* | SYNCHRONIZED ParExpression Block
* | RETURN [Expression] ";"
* | THROW Expression ";"
* | BREAK [Ident] ";"
* | CONTINUE [Ident] ";"
* | ASSERT Expression [ ":" Expression ] ";"
* | ";"
* | ExpressionStatement
* | Ident ":" Statement
*/
@SuppressWarnings("fallthrough")
public JCStatement parseStatement() {
int pos = token.pos;
switch (token.kind) {
case LBRACE:
return block();
case IF: {
nextToken();
JCExpression cond = parExpression();
JCStatement thenpart = parseStatementAsBlock();
JCStatement elsepart = null;
if (token.kind == ELSE) {
nextToken();
elsepart = parseStatementAsBlock();
}
return F.at(pos).If(cond, thenpart, elsepart);
}
case FOR: {
nextToken();
accept(LPAREN);
List<JCStatement> inits = token.kind == SEMI ? List.<JCStatement>nil() : forInit();
if (inits.length() == 1 &&
inits.head.hasTag(VARDEF) &&
((JCVariableDecl) inits.head).init == null &&
token.kind == COLON) {
checkForeach();
JCVariableDecl var = (JCVariableDecl)inits.head;
accept(COLON);
JCExpression expr = parseExpression();
accept(RPAREN);
JCStatement body = parseStatementAsBlock();
return F.at(pos).ForeachLoop(var, expr, body);
} else {
accept(SEMI);
JCExpression cond = token.kind == SEMI ? null : parseExpression();
accept(SEMI);
List<JCExpressionStatement> steps = token.kind == RPAREN ? List.<JCExpressionStatement>nil() : forUpdate();
accept(RPAREN);
JCStatement body = parseStatementAsBlock();
return F.at(pos).ForLoop(inits, cond, steps, body);
}
}
case WHILE: {
nextToken();
JCExpression cond = parExpression();
JCStatement body = parseStatementAsBlock();
return F.at(pos).WhileLoop(cond, body);
}
case DO: {
nextToken();
JCStatement body = parseStatementAsBlock();
accept(WHILE);
JCExpression cond = parExpression();
JCDoWhileLoop t = to(F.at(pos).DoLoop(body, cond));
accept(SEMI);
return t;
}
case TRY: {
nextToken();
List<JCTree> resources = List.<JCTree>nil();
if (token.kind == LPAREN) {
checkTryWithResources();
nextToken();
resources = resources();
accept(RPAREN);
}
JCBlock body = block();
ListBuffer<JCCatch> catchers = new ListBuffer<>();
JCBlock finalizer = null;
if (token.kind == CATCH || token.kind == FINALLY) {
while (token.kind == CATCH) catchers.append(catchClause());
if (token.kind == FINALLY) {
nextToken();
finalizer = block();
}
} else {
if (allowTWR) {
if (resources.isEmpty())
error(pos, "try.without.catch.finally.or.resource.decls");
} else
error(pos, "try.without.catch.or.finally");
}
return F.at(pos).Try(resources, body, catchers.toList(), finalizer);
}
case SWITCH: {
nextToken();
JCExpression selector = parExpression();
accept(LBRACE);
List<JCCase> cases = switchBlockStatementGroups();
JCSwitch t = to(F.at(pos).Switch(selector, cases));
accept(RBRACE);
return t;
}
case SYNCHRONIZED: {
nextToken();
JCExpression lock = parExpression();
JCBlock body = block();
return F.at(pos).Synchronized(lock, body);
}
case RETURN: {
nextToken();
JCExpression result = token.kind == SEMI ? null : parseExpression();
JCReturn t = to(F.at(pos).Return(result));
accept(SEMI);
return t;
}
case THROW: {
nextToken();
JCExpression exc = parseExpression();
JCThrow t = to(F.at(pos).Throw(exc));
accept(SEMI);
return t;
}
case BREAK: {
nextToken();
Name label = LAX_IDENTIFIER.accepts(token.kind) ? ident() : null;
JCBreak t = to(F.at(pos).Break(label));
accept(SEMI);
return t;
}
case CONTINUE: {
nextToken();
Name label = LAX_IDENTIFIER.accepts(token.kind) ? ident() : null;
JCContinue t = to(F.at(pos).Continue(label));
accept(SEMI);
return t;
}
case SEMI:
nextToken();
return toP(F.at(pos).Skip());
case ELSE:
int elsePos = token.pos;
nextToken();
return doRecover(elsePos, BasicErrorRecoveryAction.BLOCK_STMT, "else.without.if");
case FINALLY:
int finallyPos = token.pos;
nextToken();
return doRecover(finallyPos, BasicErrorRecoveryAction.BLOCK_STMT, "finally.without.try");
case CATCH:
return doRecover(token.pos, BasicErrorRecoveryAction.CATCH_CLAUSE, "catch.without.try");
case ASSERT: {
if (allowAsserts && token.kind == ASSERT) {
nextToken();
JCExpression assertion = parseExpression();
JCExpression message = null;
if (token.kind == COLON) {
nextToken();
message = parseExpression();
}
JCAssert t = to(F.at(pos).Assert(assertion, message));
accept(SEMI);
return t;
}
/* else fall through to default case */
}
case ENUM:
default:
Token prevToken = token;
JCExpression expr = parseExpression();
if (token.kind == COLON && expr.hasTag(IDENT)) {
nextToken();
JCStatement stat = parseStatement();
return F.at(pos).Labelled(prevToken.name(), stat);
} else {
// This Exec is an "ExpressionStatement"; it subsumes the terminating semicolon
JCExpressionStatement stat = to(F.at(pos).Exec(checkExprStat(expr)));
accept(SEMI);
return stat;
}
}
}
private JCStatement doRecover(int startPos, ErrorRecoveryAction action, String key) {
int errPos = S.errPos();
JCTree stm = action.doRecover(this);
S.errPos(errPos);
return toP(F.Exec(syntaxError(startPos, List.<JCTree>of(stm), key)));
}
/** CatchClause = CATCH "(" FormalParameter ")" Block
* TODO: the "FormalParameter" is not correct, it uses the special "catchTypes" rule below.
*/
protected JCCatch catchClause() {
int pos = token.pos;
accept(CATCH);
accept(LPAREN);
JCModifiers mods = optFinal(Flags.PARAMETER);
List<JCExpression> catchTypes = catchTypes();
JCExpression paramType = catchTypes.size() > 1 ?
toP(F.at(catchTypes.head.getStartPosition()).TypeUnion(catchTypes)) :
catchTypes.head;
JCVariableDecl formal = variableDeclaratorId(mods, paramType);
accept(RPAREN);
JCBlock body = block();
return F.at(pos).Catch(formal, body);
}
List<JCExpression> catchTypes() {
ListBuffer<JCExpression> catchTypes = new ListBuffer<>();
catchTypes.add(parseType());
while (token.kind == BAR) {
checkMulticatch();
nextToken();
// Instead of qualident this is now parseType.
// But would that allow too much, e.g. arrays or generics?
catchTypes.add(parseType());
}
return catchTypes.toList();
}
/** SwitchBlockStatementGroups = { SwitchBlockStatementGroup }
* SwitchBlockStatementGroup = SwitchLabel BlockStatements
* SwitchLabel = CASE ConstantExpression ":" | DEFAULT ":"
*/
List<JCCase> switchBlockStatementGroups() {
ListBuffer<JCCase> cases = new ListBuffer<>();
while (true) {
int pos = token.pos;
switch (token.kind) {
case CASE:
case DEFAULT:
cases.append(switchBlockStatementGroup());
break;
case RBRACE: case EOF:
return cases.toList();
default:
nextToken(); // to ensure progress
syntaxError(pos, "expected3",
CASE, DEFAULT, RBRACE);
}
}
}
protected JCCase switchBlockStatementGroup() {
int pos = token.pos;
List<JCStatement> stats;
JCCase c;
switch (token.kind) {
case CASE:
nextToken();
JCExpression pat = parseExpression();
accept(COLON);
stats = blockStatements();
c = F.at(pos).Case(pat, stats);
if (stats.isEmpty())
storeEnd(c, S.prevToken().endPos);
return c;
case DEFAULT:
nextToken();
accept(COLON);
stats = blockStatements();
c = F.at(pos).Case(null, stats);
if (stats.isEmpty())
storeEnd(c, S.prevToken().endPos);
return c;
}
throw new AssertionError("should not reach here");
}
/** MoreStatementExpressions = { COMMA StatementExpression }
*/
<T extends ListBuffer<? super JCExpressionStatement>> T moreStatementExpressions(int pos,
JCExpression first,
T stats) {
// This Exec is a "StatementExpression"; it subsumes no terminating token
stats.append(toP(F.at(pos).Exec(checkExprStat(first))));
while (token.kind == COMMA) {
nextToken();
pos = token.pos;
JCExpression t = parseExpression();
// This Exec is a "StatementExpression"; it subsumes no terminating token
stats.append(toP(F.at(pos).Exec(checkExprStat(t))));
}
return stats;
}
/** ForInit = StatementExpression MoreStatementExpressions
* | { FINAL | '@' Annotation } Type VariableDeclarators
*/
List<JCStatement> forInit() {
ListBuffer<JCStatement> stats = new ListBuffer<>();
int pos = token.pos;
if (token.kind == FINAL || token.kind == MONKEYS_AT) {
return variableDeclarators(optFinal(0), parseType(), stats).toList();
} else {
JCExpression t = term(EXPR | TYPE);
if ((lastmode & TYPE) != 0 && LAX_IDENTIFIER.accepts(token.kind)) {
return variableDeclarators(modifiersOpt(), t, stats).toList();
} else if ((lastmode & TYPE) != 0 && token.kind == COLON) {
error(pos, "bad.initializer", "for-loop");
return List.of((JCStatement)F.at(pos).VarDef(null, null, t, null));
} else {
return moreStatementExpressions(pos, t, stats).toList();
}
}
}
/** ForUpdate = StatementExpression MoreStatementExpressions
*/
List<JCExpressionStatement> forUpdate() {
return moreStatementExpressions(token.pos,
parseExpression(),
new ListBuffer<JCExpressionStatement>()).toList();
}
/** AnnotationsOpt = { '@' Annotation }
*
* @param kind Whether to parse an ANNOTATION or TYPE_ANNOTATION
*/
List<JCAnnotation> annotationsOpt(Tag kind) {
if (token.kind != MONKEYS_AT) return List.nil(); // optimization
ListBuffer<JCAnnotation> buf = new ListBuffer<>();
int prevmode = mode;
while (token.kind == MONKEYS_AT) {
int pos = token.pos;
nextToken();
buf.append(annotation(pos, kind));
}
lastmode = mode;
mode = prevmode;
List<JCAnnotation> annotations = buf.toList();
return annotations;
}
List<JCAnnotation> typeAnnotationsOpt() {
List<JCAnnotation> annotations = annotationsOpt(Tag.TYPE_ANNOTATION);
return annotations;
}
/** ModifiersOpt = { Modifier }
* Modifier = PUBLIC | PROTECTED | PRIVATE | STATIC | ABSTRACT | FINAL
* | NATIVE | SYNCHRONIZED | TRANSIENT | VOLATILE | "@"
* | "@" Annotation
*/
JCModifiers modifiersOpt() {
return modifiersOpt(null);
}
protected JCModifiers modifiersOpt(JCModifiers partial) {
long flags;
ListBuffer<JCAnnotation> annotations = new ListBuffer<>();
int pos;
if (partial == null) {
flags = 0;
pos = token.pos;
} else {
flags = partial.flags;
annotations.appendList(partial.annotations);
pos = partial.pos;
}
if (token.deprecatedFlag()) {
flags |= Flags.DEPRECATED;
}
int lastPos;
loop:
while (true) {
long flag;
switch (token.kind) {
case PRIVATE : flag = Flags.PRIVATE; break;
case PROTECTED : flag = Flags.PROTECTED; break;
case PUBLIC : flag = Flags.PUBLIC; break;
case STATIC : flag = Flags.STATIC; break;
case TRANSIENT : flag = Flags.TRANSIENT; break;
case FINAL : flag = Flags.FINAL; break;
case ABSTRACT : flag = Flags.ABSTRACT; break;
case NATIVE : flag = Flags.NATIVE; break;
case VOLATILE : flag = Flags.VOLATILE; break;
case SYNCHRONIZED: flag = Flags.SYNCHRONIZED; break;
case STRICTFP : flag = Flags.STRICTFP; break;
case MONKEYS_AT : flag = Flags.ANNOTATION; break;
case DEFAULT : checkDefaultMethods(); flag = Flags.DEFAULT; break;
case ERROR : flag = 0; nextToken(); break;
default: break loop;
}
if ((flags & flag) != 0) error(token.pos, "repeated.modifier");
lastPos = token.pos;
nextToken();
if (flag == Flags.ANNOTATION) {
checkAnnotations();
if (token.kind != INTERFACE) {
JCAnnotation ann = annotation(lastPos, Tag.ANNOTATION);
// if first modifier is an annotation, set pos to annotation's.
if (flags == 0 && annotations.isEmpty())
pos = ann.pos;
annotations.append(ann);
flag = 0;
}
}
flags |= flag;
}
switch (token.kind) {
case ENUM: flags |= Flags.ENUM; break;
case INTERFACE: flags |= Flags.INTERFACE; break;
default: break;
}
/* A modifiers tree with no modifier tokens or annotations
* has no text position. */
if ((flags & (Flags.ModifierFlags | Flags.ANNOTATION)) == 0 && annotations.isEmpty())
pos = Position.NOPOS;
JCModifiers mods = F.at(pos).Modifiers(flags, annotations.toList());
if (pos != Position.NOPOS)
storeEnd(mods, S.prevToken().endPos);
return mods;
}
/** Annotation = "@" Qualident [ "(" AnnotationFieldValues ")" ]
*
* @param pos position of "@" token
* @param kind Whether to parse an ANNOTATION or TYPE_ANNOTATION
*/
JCAnnotation annotation(int pos, Tag kind) {
// accept(AT); // AT consumed by caller
checkAnnotations();
if (kind == Tag.TYPE_ANNOTATION) {
checkTypeAnnotations();
}
JCTree ident = qualident(false);
List<JCExpression> fieldValues = annotationFieldValuesOpt();
JCAnnotation ann;
if (kind == Tag.ANNOTATION) {
ann = F.at(pos).Annotation(ident, fieldValues);
} else if (kind == Tag.TYPE_ANNOTATION) {
ann = F.at(pos).TypeAnnotation(ident, fieldValues);
} else {
throw new AssertionError("Unhandled annotation kind: " + kind);
}
storeEnd(ann, S.prevToken().endPos);
return ann;
}
List<JCExpression> annotationFieldValuesOpt() {
return (token.kind == LPAREN) ? annotationFieldValues() : List.<JCExpression>nil();
}
/** AnnotationFieldValues = "(" [ AnnotationFieldValue { "," AnnotationFieldValue } ] ")" */
List<JCExpression> annotationFieldValues() {
accept(LPAREN);
ListBuffer<JCExpression> buf = new ListBuffer<>();
if (token.kind != RPAREN) {
buf.append(annotationFieldValue());
while (token.kind == COMMA) {
nextToken();
buf.append(annotationFieldValue());
}
}
accept(RPAREN);
return buf.toList();
}
/** AnnotationFieldValue = AnnotationValue
* | Identifier "=" AnnotationValue
*/
JCExpression annotationFieldValue() {
if (LAX_IDENTIFIER.accepts(token.kind)) {
mode = EXPR;
JCExpression t1 = term1();
if (t1.hasTag(IDENT) && token.kind == EQ) {
int pos = token.pos;
accept(EQ);
JCExpression v = annotationValue();
return toP(F.at(pos).Assign(t1, v));
} else {
return t1;
}
}
return annotationValue();
}
/* AnnotationValue = ConditionalExpression
* | Annotation
* | "{" [ AnnotationValue { "," AnnotationValue } ] [","] "}"
*/
JCExpression annotationValue() {
int pos;
switch (token.kind) {
case MONKEYS_AT:
pos = token.pos;
nextToken();
return annotation(pos, Tag.ANNOTATION);
case LBRACE:
pos = token.pos;
accept(LBRACE);
ListBuffer<JCExpression> buf = new ListBuffer<>();
if (token.kind == COMMA) {
nextToken();
} else if (token.kind != RBRACE) {
buf.append(annotationValue());
while (token.kind == COMMA) {
nextToken();
if (token.kind == RBRACE) break;
buf.append(annotationValue());
}
}
accept(RBRACE);
return toP(F.at(pos).NewArray(null, List.<JCExpression>nil(), buf.toList()));
default:
mode = EXPR;
return term1();
}
}
/** VariableDeclarators = VariableDeclarator { "," VariableDeclarator }
*/
public <T extends ListBuffer<? super JCVariableDecl>> T variableDeclarators(JCModifiers mods,
JCExpression type,
T vdefs)
{
return variableDeclaratorsRest(token.pos, mods, type, ident(), false, null, vdefs);
}
/** VariableDeclaratorsRest = VariableDeclaratorRest { "," VariableDeclarator }
* ConstantDeclaratorsRest = ConstantDeclaratorRest { "," ConstantDeclarator }
*
* @param reqInit Is an initializer always required?
* @param dc The documentation comment for the variable declarations, or null.
*/
<T extends ListBuffer<? super JCVariableDecl>> T variableDeclaratorsRest(int pos,
JCModifiers mods,
JCExpression type,
Name name,
boolean reqInit,
Comment dc,
T vdefs)
{
vdefs.append(variableDeclaratorRest(pos, mods, type, name, reqInit, dc));
while (token.kind == COMMA) {
// All but last of multiple declarators subsume a comma
storeEnd((JCTree)vdefs.last(), token.endPos);
nextToken();
vdefs.append(variableDeclarator(mods, type, reqInit, dc));
}
return vdefs;
}
/** VariableDeclarator = Ident VariableDeclaratorRest
* ConstantDeclarator = Ident ConstantDeclaratorRest
*/
JCVariableDecl variableDeclarator(JCModifiers mods, JCExpression type, boolean reqInit, Comment dc) {
return variableDeclaratorRest(token.pos, mods, type, ident(), reqInit, dc);
}
/** VariableDeclaratorRest = BracketsOpt ["=" VariableInitializer]
* ConstantDeclaratorRest = BracketsOpt "=" VariableInitializer
*
* @param reqInit Is an initializer always required?
* @param dc The documentation comment for the variable declarations, or null.
*/
JCVariableDecl variableDeclaratorRest(int pos, JCModifiers mods, JCExpression type, Name name,
boolean reqInit, Comment dc) {
type = bracketsOpt(type);
JCExpression init = null;
if (token.kind == EQ) {
nextToken();
init = variableInitializer();
}
else if (reqInit) syntaxError(token.pos, "expected", EQ);
JCVariableDecl result =
toP(F.at(pos).VarDef(mods, name, type, init));
attach(result, dc);
return result;
}
/** VariableDeclaratorId = Ident BracketsOpt
*/
JCVariableDecl variableDeclaratorId(JCModifiers mods, JCExpression type) {
return variableDeclaratorId(mods, type, false);
}
//where
JCVariableDecl variableDeclaratorId(JCModifiers mods, JCExpression type, boolean lambdaParameter) {
int pos = token.pos;
Name name;
if (lambdaParameter && token.kind == UNDERSCORE) {
log.error(pos, "underscore.as.identifier.in.lambda");
name = token.name();
nextToken();
} else {
if (allowThisIdent) {
JCExpression pn = qualident(false);
if (pn.hasTag(Tag.IDENT) && ((JCIdent)pn).name != names._this) {
name = ((JCIdent)pn).name;
} else {
if ((mods.flags & Flags.VARARGS) != 0) {
log.error(token.pos, "varargs.and.receiver");
}
if (token.kind == LBRACKET) {
log.error(token.pos, "array.and.receiver");
}
return toP(F.at(pos).ReceiverVarDef(mods, pn, type));
}
} else {
name = ident();
}
}
if ((mods.flags & Flags.VARARGS) != 0 &&
token.kind == LBRACKET) {
log.error(token.pos, "varargs.and.old.array.syntax");
}
type = bracketsOpt(type);
return toP(F.at(pos).VarDef(mods, name, type, null));
}
/** Resources = Resource { ";" Resources }
*/
List<JCTree> resources() {
ListBuffer<JCTree> defs = new ListBuffer<>();
defs.append(resource());
while (token.kind == SEMI) {
// All but last of multiple declarators must subsume a semicolon
storeEnd(defs.last(), token.endPos);
int semiColonPos = token.pos;
nextToken();
if (token.kind == RPAREN) { // Optional trailing semicolon
// after last resource
break;
}
defs.append(resource());
}
return defs.toList();
}
/** Resource = VariableModifiersOpt Type VariableDeclaratorId = Expression
*/
protected JCTree resource() {
JCModifiers optFinal = optFinal(Flags.FINAL);
JCExpression type = parseType();
int pos = token.pos;
Name ident = ident();
return variableDeclaratorRest(pos, optFinal, type, ident, true, null);
}
/** CompilationUnit = [ { "@" Annotation } PACKAGE Qualident ";"] {ImportDeclaration} {TypeDeclaration}
*/
public JCTree.JCCompilationUnit parseCompilationUnit() {
Token firstToken = token;
JCModifiers mods = null;
boolean consumedToplevelDoc = false;
boolean seenImport = false;
boolean seenPackage = false;
ListBuffer<JCTree> defs = new ListBuffer<>();
if (token.kind == MONKEYS_AT)
mods = modifiersOpt();
if (token.kind == PACKAGE) {
int packagePos = token.pos;
List<JCAnnotation> annotations = List.nil();
seenPackage = true;
if (mods != null) {
checkNoMods(mods.flags);
annotations = mods.annotations;
mods = null;
}
nextToken();
JCExpression pid = qualident(false);
accept(SEMI);
JCPackageDecl pd = F.at(packagePos).PackageDecl(annotations, pid);
attach(pd, firstToken.comment(CommentStyle.JAVADOC));
consumedToplevelDoc = true;
storeEnd(pd, token.pos);
defs.append(pd);
}
boolean checkForImports = true;
boolean firstTypeDecl = true;
while (token.kind != EOF) {
if (token.pos > 0 && token.pos <= endPosTable.errorEndPos) {
// error recovery
skip(checkForImports, false, false, false);
if (token.kind == EOF)
break;
}
if (checkForImports && mods == null && token.kind == IMPORT) {
seenImport = true;
defs.append(importDeclaration());
} else {
Comment docComment = token.comment(CommentStyle.JAVADOC);
if (firstTypeDecl && !seenImport && !seenPackage) {
docComment = firstToken.comment(CommentStyle.JAVADOC);
consumedToplevelDoc = true;
}
JCTree def = typeDeclaration(mods, docComment);
if (def instanceof JCExpressionStatement)
def = ((JCExpressionStatement)def).expr;
defs.append(def);
if (def instanceof JCClassDecl)
checkForImports = false;
mods = null;
firstTypeDecl = false;
}
}
JCTree.JCCompilationUnit toplevel = F.at(firstToken.pos).TopLevel(defs.toList());
if (!consumedToplevelDoc)
attach(toplevel, firstToken.comment(CommentStyle.JAVADOC));
if (defs.isEmpty())
storeEnd(toplevel, S.prevToken().endPos);
if (keepDocComments)
toplevel.docComments = docComments;
if (keepLineMap)
toplevel.lineMap = S.getLineMap();
this.endPosTable.setParser(null); // remove reference to parser
toplevel.endPositions = this.endPosTable;
return toplevel;
}
/** ImportDeclaration = IMPORT [ STATIC ] Ident { "." Ident } [ "." "*" ] ";"
*/
JCTree importDeclaration() {
int pos = token.pos;
nextToken();
boolean importStatic = false;
if (token.kind == STATIC) {
checkStaticImports();
importStatic = true;
nextToken();
}
JCExpression pid = toP(F.at(token.pos).Ident(ident()));
do {
int pos1 = token.pos;
accept(DOT);
if (token.kind == STAR) {
pid = to(F.at(pos1).Select(pid, names.asterisk));
nextToken();
break;
} else {
pid = toP(F.at(pos1).Select(pid, ident()));
}
} while (token.kind == DOT);
accept(SEMI);
return toP(F.at(pos).Import(pid, importStatic));
}
/** TypeDeclaration = ClassOrInterfaceOrEnumDeclaration
* | ";"
*/
JCTree typeDeclaration(JCModifiers mods, Comment docComment) {
int pos = token.pos;
if (mods == null && token.kind == SEMI) {
nextToken();
return toP(F.at(pos).Skip());
} else {
return classOrInterfaceOrEnumDeclaration(modifiersOpt(mods), docComment);
}
}
/** ClassOrInterfaceOrEnumDeclaration = ModifiersOpt
* (ClassDeclaration | InterfaceDeclaration | EnumDeclaration)
* @param mods Any modifiers starting the class or interface declaration
* @param dc The documentation comment for the class, or null.
*/
JCStatement classOrInterfaceOrEnumDeclaration(JCModifiers mods, Comment dc) {
if (token.kind == CLASS) {
return classDeclaration(mods, dc);
} else if (token.kind == INTERFACE) {
return interfaceDeclaration(mods, dc);
} else if (allowEnums) {
if (token.kind == ENUM) {
return enumDeclaration(mods, dc);
} else {
int pos = token.pos;
List<JCTree> errs;
if (LAX_IDENTIFIER.accepts(token.kind)) {
errs = List.<JCTree>of(mods, toP(F.at(pos).Ident(ident())));
setErrorEndPos(token.pos);
} else {
errs = List.<JCTree>of(mods);
}
return toP(F.Exec(syntaxError(pos, errs, "expected3",
CLASS, INTERFACE, ENUM)));
}
} else {
if (token.kind == ENUM) {
error(token.pos, "enums.not.supported.in.source", source.name);
allowEnums = true;
return enumDeclaration(mods, dc);
}
int pos = token.pos;
List<JCTree> errs;
if (LAX_IDENTIFIER.accepts(token.kind)) {
errs = List.<JCTree>of(mods, toP(F.at(pos).Ident(ident())));
setErrorEndPos(token.pos);
} else {
errs = List.<JCTree>of(mods);
}
return toP(F.Exec(syntaxError(pos, errs, "expected2",
CLASS, INTERFACE)));
}
}
/** ClassDeclaration = CLASS Ident TypeParametersOpt [EXTENDS Type]
* [IMPLEMENTS TypeList] ClassBody
* @param mods The modifiers starting the class declaration
* @param dc The documentation comment for the class, or null.
*/
protected JCClassDecl classDeclaration(JCModifiers mods, Comment dc) {
int pos = token.pos;
accept(CLASS);
Name name = ident();
List<JCTypeParameter> typarams = typeParametersOpt();
JCExpression extending = null;
if (token.kind == EXTENDS) {
nextToken();
extending = parseType();
}
List<JCExpression> implementing = List.nil();
if (token.kind == IMPLEMENTS) {
nextToken();
implementing = typeList();
}
List<JCTree> defs = classOrInterfaceBody(name, false);
JCClassDecl result = toP(F.at(pos).ClassDef(
mods, name, typarams, extending, implementing, defs));
attach(result, dc);
return result;
}
/** InterfaceDeclaration = INTERFACE Ident TypeParametersOpt
* [EXTENDS TypeList] InterfaceBody
* @param mods The modifiers starting the interface declaration
* @param dc The documentation comment for the interface, or null.
*/
protected JCClassDecl interfaceDeclaration(JCModifiers mods, Comment dc) {
int pos = token.pos;
accept(INTERFACE);
Name name = ident();
List<JCTypeParameter> typarams = typeParametersOpt();
List<JCExpression> extending = List.nil();
if (token.kind == EXTENDS) {
nextToken();
extending = typeList();
}
List<JCTree> defs = classOrInterfaceBody(name, true);
JCClassDecl result = toP(F.at(pos).ClassDef(
mods, name, typarams, null, extending, defs));
attach(result, dc);
return result;
}
/** EnumDeclaration = ENUM Ident [IMPLEMENTS TypeList] EnumBody
* @param mods The modifiers starting the enum declaration
* @param dc The documentation comment for the enum, or null.
*/
protected JCClassDecl enumDeclaration(JCModifiers mods, Comment dc) {
int pos = token.pos;
accept(ENUM);
Name name = ident();
List<JCExpression> implementing = List.nil();
if (token.kind == IMPLEMENTS) {
nextToken();
implementing = typeList();
}
List<JCTree> defs = enumBody(name);
mods.flags |= Flags.ENUM;
JCClassDecl result = toP(F.at(pos).
ClassDef(mods, name, List.<JCTypeParameter>nil(),
null, implementing, defs));
attach(result, dc);
return result;
}
/** EnumBody = "{" { EnumeratorDeclarationList } [","]
* [ ";" {ClassBodyDeclaration} ] "}"
*/
List<JCTree> enumBody(Name enumName) {
accept(LBRACE);
ListBuffer<JCTree> defs = new ListBuffer<>();
if (token.kind == COMMA) {
nextToken();
} else if (token.kind != RBRACE && token.kind != SEMI) {
defs.append(enumeratorDeclaration(enumName));
while (token.kind == COMMA) {
nextToken();
if (token.kind == RBRACE || token.kind == SEMI) break;
defs.append(enumeratorDeclaration(enumName));
}
if (token.kind != SEMI && token.kind != RBRACE) {
defs.append(syntaxError(token.pos, "expected3",
COMMA, RBRACE, SEMI));
nextToken();
}
}
if (token.kind == SEMI) {
nextToken();
while (token.kind != RBRACE && token.kind != EOF) {
defs.appendList(classOrInterfaceBodyDeclaration(enumName,
false));
if (token.pos <= endPosTable.errorEndPos) {
// error recovery
skip(false, true, true, false);
}
}
}
accept(RBRACE);
return defs.toList();
}
/** EnumeratorDeclaration = AnnotationsOpt [TypeArguments] IDENTIFIER [ Arguments ] [ "{" ClassBody "}" ]
*/
JCTree enumeratorDeclaration(Name enumName) {
Comment dc = token.comment(CommentStyle.JAVADOC);
int flags = Flags.PUBLIC|Flags.STATIC|Flags.FINAL|Flags.ENUM;
if (token.deprecatedFlag()) {
flags |= Flags.DEPRECATED;
}
int pos = token.pos;
List<JCAnnotation> annotations = annotationsOpt(Tag.ANNOTATION);
JCModifiers mods = F.at(annotations.isEmpty() ? Position.NOPOS : pos).Modifiers(flags, annotations);
List<JCExpression> typeArgs = typeArgumentsOpt();
int identPos = token.pos;
Name name = ident();
int createPos = token.pos;
List<JCExpression> args = (token.kind == LPAREN)
? arguments() : List.<JCExpression>nil();
JCClassDecl body = null;
if (token.kind == LBRACE) {
JCModifiers mods1 = F.at(Position.NOPOS).Modifiers(Flags.ENUM);
List<JCTree> defs = classOrInterfaceBody(names.empty, false);
body = toP(F.at(identPos).AnonymousClassDef(mods1, defs));
}
if (args.isEmpty() && body == null)
createPos = identPos;
JCIdent ident = F.at(identPos).Ident(enumName);
JCNewClass create = F.at(createPos).NewClass(null, typeArgs, ident, args, body);
if (createPos != identPos)
storeEnd(create, S.prevToken().endPos);
ident = F.at(identPos).Ident(enumName);
JCTree result = toP(F.at(pos).VarDef(mods, name, ident, create));
attach(result, dc);
return result;
}
/** TypeList = Type {"," Type}
*/
List<JCExpression> typeList() {
ListBuffer<JCExpression> ts = new ListBuffer<>();
ts.append(parseType());
while (token.kind == COMMA) {
nextToken();
ts.append(parseType());
}
return ts.toList();
}
/** ClassBody = "{" {ClassBodyDeclaration} "}"
* InterfaceBody = "{" {InterfaceBodyDeclaration} "}"
*/
List<JCTree> classOrInterfaceBody(Name className, boolean isInterface) {
accept(LBRACE);
if (token.pos <= endPosTable.errorEndPos) {
// error recovery
skip(false, true, false, false);
if (token.kind == LBRACE)
nextToken();
}
ListBuffer<JCTree> defs = new ListBuffer<>();
while (token.kind != RBRACE && token.kind != EOF) {
defs.appendList(classOrInterfaceBodyDeclaration(className, isInterface));
if (token.pos <= endPosTable.errorEndPos) {
// error recovery
skip(false, true, true, false);
}
}
accept(RBRACE);
return defs.toList();
}
/** ClassBodyDeclaration =
* ";"
* | [STATIC] Block
* | ModifiersOpt
* ( Type Ident
* ( VariableDeclaratorsRest ";" | MethodDeclaratorRest )
* | VOID Ident VoidMethodDeclaratorRest
* | TypeParameters [Annotations]
* ( Type Ident MethodDeclaratorRest
* | VOID Ident VoidMethodDeclaratorRest
* )
* | Ident ConstructorDeclaratorRest
* | TypeParameters Ident ConstructorDeclaratorRest
* | ClassOrInterfaceOrEnumDeclaration
* )
* InterfaceBodyDeclaration =
* ";"
* | ModifiersOpt
* ( Type Ident
* ( ConstantDeclaratorsRest ";" | MethodDeclaratorRest )
* | VOID Ident MethodDeclaratorRest
* | TypeParameters [Annotations]
* ( Type Ident MethodDeclaratorRest
* | VOID Ident VoidMethodDeclaratorRest
* )
* | ClassOrInterfaceOrEnumDeclaration
* )
*
*/
protected List<JCTree> classOrInterfaceBodyDeclaration(Name className, boolean isInterface) {
if (token.kind == SEMI) {
nextToken();
return List.<JCTree>nil();
} else {
Comment dc = token.comment(CommentStyle.JAVADOC);
int pos = token.pos;
JCModifiers mods = modifiersOpt();
if (token.kind == CLASS ||
token.kind == INTERFACE ||
allowEnums && token.kind == ENUM) {
return List.<JCTree>of(classOrInterfaceOrEnumDeclaration(mods, dc));
} else if (token.kind == LBRACE &&
(mods.flags & Flags.StandardFlags & ~Flags.STATIC) == 0 &&
mods.annotations.isEmpty()) {
if (isInterface) {
error(token.pos, "initializer.not.allowed");
}
return List.<JCTree>of(block(pos, mods.flags));
} else {
pos = token.pos;
List<JCTypeParameter> typarams = typeParametersOpt();
// if there are type parameters but no modifiers, save the start
// position of the method in the modifiers.
if (typarams.nonEmpty() && mods.pos == Position.NOPOS) {
mods.pos = pos;
storeEnd(mods, pos);
}
List<JCAnnotation> annosAfterParams = annotationsOpt(Tag.ANNOTATION);
if (annosAfterParams.nonEmpty()) {
checkAnnotationsAfterTypeParams(annosAfterParams.head.pos);
mods.annotations = mods.annotations.appendList(annosAfterParams);
if (mods.pos == Position.NOPOS)
mods.pos = mods.annotations.head.pos;
}
Token tk = token;
pos = token.pos;
JCExpression type;
boolean isVoid = token.kind == VOID;
if (isVoid) {
type = to(F.at(pos).TypeIdent(TypeTag.VOID));
nextToken();
} else {
// method returns types are un-annotated types
type = unannotatedType();
}
if (token.kind == LPAREN && !isInterface && type.hasTag(IDENT)) {
if (isInterface || tk.name() != className)
error(pos, "invalid.meth.decl.ret.type.req");
else if (annosAfterParams.nonEmpty())
illegal(annosAfterParams.head.pos);
return List.of(methodDeclaratorRest(
pos, mods, null, names.init, typarams,
isInterface, true, dc));
} else {
pos = token.pos;
Name name = ident();
if (token.kind == LPAREN) {
return List.of(methodDeclaratorRest(
pos, mods, type, name, typarams,
isInterface, isVoid, dc));
} else if (!isVoid && typarams.isEmpty()) {
List<JCTree> defs =
variableDeclaratorsRest(pos, mods, type, name, isInterface, dc,
new ListBuffer<JCTree>()).toList();
storeEnd(defs.last(), token.endPos);
accept(SEMI);
return defs;
} else {
pos = token.pos;
List<JCTree> err = isVoid
? List.<JCTree>of(toP(F.at(pos).MethodDef(mods, name, type, typarams,
List.<JCVariableDecl>nil(), List.<JCExpression>nil(), null, null)))
: null;
return List.<JCTree>of(syntaxError(token.pos, err, "expected", LPAREN));
}
}
}
}
}
/** MethodDeclaratorRest =
* FormalParameters BracketsOpt [THROWS TypeList] ( MethodBody | [DEFAULT AnnotationValue] ";")
* VoidMethodDeclaratorRest =
* FormalParameters [THROWS TypeList] ( MethodBody | ";")
* ConstructorDeclaratorRest =
* "(" FormalParameterListOpt ")" [THROWS TypeList] MethodBody
*/
protected JCTree methodDeclaratorRest(int pos,
JCModifiers mods,
JCExpression type,
Name name,
List<JCTypeParameter> typarams,
boolean isInterface, boolean isVoid,
Comment dc) {
if (isInterface && (mods.flags & Flags.STATIC) != 0) {
checkStaticInterfaceMethods();
}
JCVariableDecl prevReceiverParam = this.receiverParam;
try {
this.receiverParam = null;
// Parsing formalParameters sets the receiverParam, if present
List<JCVariableDecl> params = formalParameters();
if (!isVoid) type = bracketsOpt(type);
List<JCExpression> thrown = List.nil();
if (token.kind == THROWS) {
nextToken();
thrown = qualidentList();
}
JCBlock body = null;
JCExpression defaultValue;
if (token.kind == LBRACE) {
body = block();
defaultValue = null;
} else {
if (token.kind == DEFAULT) {
accept(DEFAULT);
defaultValue = annotationValue();
} else {
defaultValue = null;
}
accept(SEMI);
if (token.pos <= endPosTable.errorEndPos) {
// error recovery
skip(false, true, false, false);
if (token.kind == LBRACE) {
body = block();
}
}
}
JCMethodDecl result =
toP(F.at(pos).MethodDef(mods, name, type, typarams,
receiverParam, params, thrown,
body, defaultValue));
attach(result, dc);
return result;
} finally {
this.receiverParam = prevReceiverParam;
}
}
/** QualidentList = [Annotations] Qualident {"," [Annotations] Qualident}
*/
List<JCExpression> qualidentList() {
ListBuffer<JCExpression> ts = new ListBuffer<>();
List<JCAnnotation> typeAnnos = typeAnnotationsOpt();
JCExpression qi = qualident(true);
if (!typeAnnos.isEmpty()) {
JCExpression at = insertAnnotationsToMostInner(qi, typeAnnos, false);
ts.append(at);
} else {
ts.append(qi);
}
while (token.kind == COMMA) {
nextToken();
typeAnnos = typeAnnotationsOpt();
qi = qualident(true);
if (!typeAnnos.isEmpty()) {
JCExpression at = insertAnnotationsToMostInner(qi, typeAnnos, false);
ts.append(at);
} else {
ts.append(qi);
}
}
return ts.toList();
}
/**
* {@literal
* TypeParametersOpt = ["<" TypeParameter {"," TypeParameter} ">"]
* }
*/
List<JCTypeParameter> typeParametersOpt() {
if (token.kind == LT) {
checkGenerics();
ListBuffer<JCTypeParameter> typarams = new ListBuffer<>();
nextToken();
typarams.append(typeParameter());
while (token.kind == COMMA) {
nextToken();
typarams.append(typeParameter());
}
accept(GT);
return typarams.toList();
} else {
return List.nil();
}
}
/**
* {@literal
* TypeParameter = [Annotations] TypeVariable [TypeParameterBound]
* TypeParameterBound = EXTENDS Type {"&" Type}
* TypeVariable = Ident
* }
*/
JCTypeParameter typeParameter() {
int pos = token.pos;
List<JCAnnotation> annos = typeAnnotationsOpt();
Name name = ident();
ListBuffer<JCExpression> bounds = new ListBuffer<>();
if (token.kind == EXTENDS) {
nextToken();
bounds.append(parseType());
while (token.kind == AMP) {
nextToken();
bounds.append(parseType());
}
}
return toP(F.at(pos).TypeParameter(name, bounds.toList(), annos));
}
/** FormalParameters = "(" [ FormalParameterList ] ")"
* FormalParameterList = [ FormalParameterListNovarargs , ] LastFormalParameter
* FormalParameterListNovarargs = [ FormalParameterListNovarargs , ] FormalParameter
*/
List<JCVariableDecl> formalParameters() {
return formalParameters(false);
}
List<JCVariableDecl> formalParameters(boolean lambdaParameters) {
ListBuffer<JCVariableDecl> params = new ListBuffer<>();
JCVariableDecl lastParam;
accept(LPAREN);
if (token.kind != RPAREN) {
this.allowThisIdent = true;
lastParam = formalParameter(lambdaParameters);
if (lastParam.nameexpr != null) {
this.receiverParam = lastParam;
} else {
params.append(lastParam);
}
this.allowThisIdent = false;
while (token.kind == COMMA) {
if ((lastParam.mods.flags & Flags.VARARGS) != 0) {
error(lastParam, "varargs.must.be.last");
}
nextToken();
params.append(lastParam = formalParameter(lambdaParameters));
}
}
if (token.kind == RPAREN) {
nextToken();
} else {
setErrorEndPos(token.pos);
reportSyntaxError(S.prevToken().endPos, "expected3", COMMA, RPAREN, LBRACKET);
}
return params.toList();
}
List<JCVariableDecl> implicitParameters(boolean hasParens) {
if (hasParens) {
accept(LPAREN);
}
ListBuffer<JCVariableDecl> params = new ListBuffer<>();
if (token.kind != RPAREN && token.kind != ARROW) {
params.append(implicitParameter());
while (token.kind == COMMA) {
nextToken();
params.append(implicitParameter());
}
}
if (hasParens) {
accept(RPAREN);
}
return params.toList();
}
JCModifiers optFinal(long flags) {
JCModifiers mods = modifiersOpt();
checkNoMods(mods.flags & ~(Flags.FINAL | Flags.DEPRECATED));
mods.flags |= flags;
return mods;
}
/**
* Inserts the annotations (and possibly a new array level)
* to the left-most type in an array or nested type.
*
* When parsing a type like {@code @B Outer.Inner @A []}, the
* {@code @A} annotation should target the array itself, while
* {@code @B} targets the nested type {@code Outer}.
*
* Currently the parser parses the annotation first, then
* the array, and then inserts the annotation to the left-most
* nested type.
*
* When {@code createNewLevel} is true, then a new array
* level is inserted as the most inner type, and have the
* annotations target it. This is useful in the case of
* varargs, e.g. {@code String @A [] @B ...}, as the parser
* first parses the type {@code String @A []} then inserts
* a new array level with {@code @B} annotation.
*/
private JCExpression insertAnnotationsToMostInner(
JCExpression type, List<JCAnnotation> annos,
boolean createNewLevel) {
int origEndPos = getEndPos(type);
JCExpression mostInnerType = type;
JCArrayTypeTree mostInnerArrayType = null;
while (TreeInfo.typeIn(mostInnerType).hasTag(TYPEARRAY)) {
mostInnerArrayType = (JCArrayTypeTree) TreeInfo.typeIn(mostInnerType);
mostInnerType = mostInnerArrayType.elemtype;
}
if (createNewLevel) {
mostInnerType = to(F.at(token.pos).TypeArray(mostInnerType));
}
JCExpression mostInnerTypeToReturn = mostInnerType;
if (annos.nonEmpty()) {
JCExpression lastToModify = mostInnerType;
while (TreeInfo.typeIn(mostInnerType).hasTag(SELECT) ||
TreeInfo.typeIn(mostInnerType).hasTag(TYPEAPPLY)) {
while (TreeInfo.typeIn(mostInnerType).hasTag(SELECT)) {
lastToModify = mostInnerType;
mostInnerType = ((JCFieldAccess) TreeInfo.typeIn(mostInnerType)).getExpression();
}
while (TreeInfo.typeIn(mostInnerType).hasTag(TYPEAPPLY)) {
lastToModify = mostInnerType;
mostInnerType = ((JCTypeApply) TreeInfo.typeIn(mostInnerType)).clazz;
}
}
mostInnerType = F.at(annos.head.pos).AnnotatedType(annos, mostInnerType);
if (TreeInfo.typeIn(lastToModify).hasTag(TYPEAPPLY)) {
((JCTypeApply) TreeInfo.typeIn(lastToModify)).clazz = mostInnerType;
} else if (TreeInfo.typeIn(lastToModify).hasTag(SELECT)) {
((JCFieldAccess) TreeInfo.typeIn(lastToModify)).selected = mostInnerType;
} else {
// We never saw a SELECT or TYPEAPPLY, return the annotated type.
mostInnerTypeToReturn = mostInnerType;
}
}
if (mostInnerArrayType == null) {
return mostInnerTypeToReturn;
} else {
mostInnerArrayType.elemtype = mostInnerTypeToReturn;
storeEnd(type, origEndPos);
return type;
}
}
/** FormalParameter = { FINAL | '@' Annotation } Type VariableDeclaratorId
* LastFormalParameter = { FINAL | '@' Annotation } Type '...' Ident | FormalParameter
*/
protected JCVariableDecl formalParameter() {
return formalParameter(false);
}
protected JCVariableDecl formalParameter(boolean lambdaParameter) {
JCModifiers mods = optFinal(Flags.PARAMETER);
// need to distinguish between vararg annos and array annos
// look at typeAnnotationsPushedBack comment
this.permitTypeAnnotationsPushBack = true;
JCExpression type = parseType();
this.permitTypeAnnotationsPushBack = false;
if (token.kind == ELLIPSIS) {
List<JCAnnotation> varargsAnnos = typeAnnotationsPushedBack;
typeAnnotationsPushedBack = List.nil();
checkVarargs();
mods.flags |= Flags.VARARGS;
// insert var arg type annotations
type = insertAnnotationsToMostInner(type, varargsAnnos, true);
nextToken();
} else {
// if not a var arg, then typeAnnotationsPushedBack should be null
if (typeAnnotationsPushedBack.nonEmpty()) {
reportSyntaxError(typeAnnotationsPushedBack.head.pos,
"illegal.start.of.type");
}
typeAnnotationsPushedBack = List.nil();
}
return variableDeclaratorId(mods, type, lambdaParameter);
}
protected JCVariableDecl implicitParameter() {
JCModifiers mods = F.at(token.pos).Modifiers(Flags.PARAMETER);
return variableDeclaratorId(mods, null, true);
}
/* ---------- auxiliary methods -------------- */
void error(int pos, String key, Object ... args) {
log.error(DiagnosticFlag.SYNTAX, pos, key, args);
}
void error(DiagnosticPosition pos, String key, Object ... args) {
log.error(DiagnosticFlag.SYNTAX, pos, key, args);
}
void warning(int pos, String key, Object ... args) {
log.warning(pos, key, args);
}
/** Check that given tree is a legal expression statement.
*/
protected JCExpression checkExprStat(JCExpression t) {
if (!TreeInfo.isExpressionStatement(t)) {
JCExpression ret = F.at(t.pos).Erroneous(List.<JCTree>of(t));
error(ret, "not.stmt");
return ret;
} else {
return t;
}
}
/** Return precedence of operator represented by token,
* -1 if token is not a binary operator. @see TreeInfo.opPrec
*/
static int prec(TokenKind token) {
JCTree.Tag oc = optag(token);
return (oc != NO_TAG) ? TreeInfo.opPrec(oc) : -1;
}
/**
* Return the lesser of two positions, making allowance for either one
* being unset.
*/
static int earlier(int pos1, int pos2) {
if (pos1 == Position.NOPOS)
return pos2;
if (pos2 == Position.NOPOS)
return pos1;
return (pos1 < pos2 ? pos1 : pos2);
}
/** Return operation tag of binary operator represented by token,
* No_TAG if token is not a binary operator.
*/
static JCTree.Tag optag(TokenKind token) {
switch (token) {
case BARBAR:
return OR;
case AMPAMP:
return AND;
case BAR:
return BITOR;
case BAREQ:
return BITOR_ASG;
case CARET:
return BITXOR;
case CARETEQ:
return BITXOR_ASG;
case AMP:
return BITAND;
case AMPEQ:
return BITAND_ASG;
case EQEQ:
return JCTree.Tag.EQ;
case BANGEQ:
return NE;
case LT:
return JCTree.Tag.LT;
case GT:
return JCTree.Tag.GT;
case LTEQ:
return LE;
case GTEQ:
return GE;
case LTLT:
return SL;
case LTLTEQ:
return SL_ASG;
case GTGT:
return SR;
case GTGTEQ:
return SR_ASG;
case GTGTGT:
return USR;
case GTGTGTEQ:
return USR_ASG;
case PLUS:
return JCTree.Tag.PLUS;
case PLUSEQ:
return PLUS_ASG;
case SUB:
return MINUS;
case SUBEQ:
return MINUS_ASG;
case STAR:
return MUL;
case STAREQ:
return MUL_ASG;
case SLASH:
return DIV;
case SLASHEQ:
return DIV_ASG;
case PERCENT:
return MOD;
case PERCENTEQ:
return MOD_ASG;
case INSTANCEOF:
return TYPETEST;
default:
return NO_TAG;
}
}
/** Return operation tag of unary operator represented by token,
* No_TAG if token is not a binary operator.
*/
static JCTree.Tag unoptag(TokenKind token) {
switch (token) {
case PLUS:
return POS;
case SUB:
return NEG;
case BANG:
return NOT;
case TILDE:
return COMPL;
case PLUSPLUS:
return PREINC;
case SUBSUB:
return PREDEC;
default:
return NO_TAG;
}
}
/** Return type tag of basic type represented by token,
* NONE if token is not a basic type identifier.
*/
static TypeTag typetag(TokenKind token) {
switch (token) {
case BYTE:
return TypeTag.BYTE;
case CHAR:
return TypeTag.CHAR;
case SHORT:
return TypeTag.SHORT;
case INT:
return TypeTag.INT;
case LONG:
return TypeTag.LONG;
case FLOAT:
return TypeTag.FLOAT;
case DOUBLE:
return TypeTag.DOUBLE;
case BOOLEAN:
return TypeTag.BOOLEAN;
default:
return TypeTag.NONE;
}
}
void checkGenerics() {
if (!allowGenerics) {
error(token.pos, "generics.not.supported.in.source", source.name);
allowGenerics = true;
}
}
void checkVarargs() {
if (!allowVarargs) {
error(token.pos, "varargs.not.supported.in.source", source.name);
allowVarargs = true;
}
}
void checkForeach() {
if (!allowForeach) {
error(token.pos, "foreach.not.supported.in.source", source.name);
allowForeach = true;
}
}
void checkStaticImports() {
if (!allowStaticImport) {
error(token.pos, "static.import.not.supported.in.source", source.name);
allowStaticImport = true;
}
}
void checkAnnotations() {
if (!allowAnnotations) {
error(token.pos, "annotations.not.supported.in.source", source.name);
allowAnnotations = true;
}
}
void checkDiamond() {
if (!allowDiamond) {
error(token.pos, "diamond.not.supported.in.source", source.name);
allowDiamond = true;
}
}
void checkMulticatch() {
if (!allowMulticatch) {
error(token.pos, "multicatch.not.supported.in.source", source.name);
allowMulticatch = true;
}
}
void checkTryWithResources() {
if (!allowTWR) {
error(token.pos, "try.with.resources.not.supported.in.source", source.name);
allowTWR = true;
}
}
void checkLambda() {
if (!allowLambda) {
log.error(token.pos, "lambda.not.supported.in.source", source.name);
allowLambda = true;
}
}
void checkMethodReferences() {
if (!allowMethodReferences) {
log.error(token.pos, "method.references.not.supported.in.source", source.name);
allowMethodReferences = true;
}
}
void checkDefaultMethods() {
if (!allowDefaultMethods) {
log.error(token.pos, "default.methods.not.supported.in.source", source.name);
allowDefaultMethods = true;
}
}
void checkIntersectionTypesInCast() {
if (!allowIntersectionTypesInCast) {
log.error(token.pos, "intersection.types.in.cast.not.supported.in.source", source.name);
allowIntersectionTypesInCast = true;
}
}
void checkStaticInterfaceMethods() {
if (!allowStaticInterfaceMethods) {
log.error(token.pos, "static.intf.methods.not.supported.in.source", source.name);
allowStaticInterfaceMethods = true;
}
}
void checkTypeAnnotations() {
if (!allowTypeAnnotations) {
log.error(token.pos, "type.annotations.not.supported.in.source", source.name);
allowTypeAnnotations = true;
}
}
void checkAnnotationsAfterTypeParams(int pos) {
if (!allowAnnotationsAfterTypeParams) {
log.error(pos, "annotations.after.type.params.not.supported.in.source", source.name);
allowAnnotationsAfterTypeParams = true;
}
}
/*
* a functional source tree and end position mappings
*/
protected static class SimpleEndPosTable extends AbstractEndPosTable {
private final IntHashTable endPosMap;
SimpleEndPosTable(JavacParser parser) {
super(parser);
endPosMap = new IntHashTable();
}
public void storeEnd(JCTree tree, int endpos) {
endPosMap.putAtIndex(tree, errorEndPos > endpos ? errorEndPos : endpos,
endPosMap.lookup(tree));
}
protected <T extends JCTree> T to(T t) {
storeEnd(t, parser.token.endPos);
return t;
}
protected <T extends JCTree> T toP(T t) {
storeEnd(t, parser.S.prevToken().endPos);
return t;
}
public int getEndPos(JCTree tree) {
int value = endPosMap.getFromIndex(endPosMap.lookup(tree));
// As long as Position.NOPOS==-1, this just returns value.
return (value == -1) ? Position.NOPOS : value;
}
public int replaceTree(JCTree oldTree, JCTree newTree) {
int pos = endPosMap.remove(oldTree);
if (pos != -1) {
storeEnd(newTree, pos);
return pos;
}
return Position.NOPOS;
}
}
/*
* a default skeletal implementation without any mapping overhead.
*/
protected static class EmptyEndPosTable extends AbstractEndPosTable {
EmptyEndPosTable(JavacParser parser) {
super(parser);
}
public void storeEnd(JCTree tree, int endpos) { /* empty */ }
protected <T extends JCTree> T to(T t) {
return t;
}
protected <T extends JCTree> T toP(T t) {
return t;
}
public int getEndPos(JCTree tree) {
return Position.NOPOS;
}
public int replaceTree(JCTree oldTree, JCTree newTree) {
return Position.NOPOS;
}
}
protected static abstract class AbstractEndPosTable implements EndPosTable {
/**
* The current parser.
*/
protected JavacParser parser;
/**
* Store the last error position.
*/
protected int errorEndPos;
public AbstractEndPosTable(JavacParser parser) {
this.parser = parser;
}
/**
* Store current token's ending position for a tree, the value of which
* will be the greater of last error position and the ending position of
* the current token.
* @param t The tree.
*/
protected abstract <T extends JCTree> T to(T t);
/**
* Store current token's ending position for a tree, the value of which
* will be the greater of last error position and the ending position of
* the previous token.
* @param t The tree.
*/
protected abstract <T extends JCTree> T toP(T t);
/**
* Set the error position during the parsing phases, the value of which
* will be set only if it is greater than the last stored error position.
* @param errPos The error position
*/
protected void setErrorEndPos(int errPos) {
if (errPos > errorEndPos) {
errorEndPos = errPos;
}
}
protected void setParser(JavacParser parser) {
this.parser = parser;
}
}
}