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src/share/classes/com/sun/tools/javac/code/Types.java@d0257833498e (annotated)

src/share/classes/com/sun/tools/javac/code/Types.java

Wed, 31 Aug 2011 16:15:19 +0100

author

mcimadamore

date

Wed, 31 Aug 2011 16:15:19 +0100

changeset 1072

d0257833498e

parent 1071

b86277584776

child 1093

c0835c8489b0

permissions

-rw-r--r--

7079713: javac hangs when compiling a class that references a cyclically inherited class
Summary: Types.membersClosure needs to handle pathological cases of cyclic inheritance
Reviewed-by: jjg, jjh

duke@1	1	/*
jjg@816	2	* Copyright (c) 2003, 2011, Oracle and/or its affiliates. All rights reserved.
duke@1	3	* DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
duke@1	4	*
duke@1	5	* This code is free software; you can redistribute it and/or modify it
duke@1	6	* under the terms of the GNU General Public License version 2 only, as
ohair@554	7	* published by the Free Software Foundation. Oracle designates this
duke@1	8	* particular file as subject to the "Classpath" exception as provided
ohair@554	9	* by Oracle in the LICENSE file that accompanied this code.
duke@1	10	*
duke@1	11	* This code is distributed in the hope that it will be useful, but WITHOUT
duke@1	12	* ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
duke@1	13	* FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
duke@1	14	* version 2 for more details (a copy is included in the LICENSE file that
duke@1	15	* accompanied this code).
duke@1	16	*
duke@1	17	* You should have received a copy of the GNU General Public License version
duke@1	18	* 2 along with this work; if not, write to the Free Software Foundation,
duke@1	19	* Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA.
duke@1	20	*
ohair@554	21	* Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA
ohair@554	22	* or visit www.oracle.com if you need additional information or have any
ohair@554	23	* questions.
duke@1	24	*/
duke@1	25
duke@1	26	package com.sun.tools.javac.code;
duke@1	27
mcimadamore@341	28	import java.lang.ref.SoftReference;
duke@1	29	import java.util.*;
duke@1	30
duke@1	31	import com.sun.tools.javac.util.*;
duke@1	32	import com.sun.tools.javac.util.List;
duke@1	33
duke@1	34	import com.sun.tools.javac.jvm.ClassReader;
jjg@657	35	import com.sun.tools.javac.code.Attribute.RetentionPolicy;
mcimadamore@795	36	import com.sun.tools.javac.code.Lint.LintCategory;
duke@1	37	import com.sun.tools.javac.comp.Check;
duke@1	38
mcimadamore@858	39	import static com.sun.tools.javac.code.Scope.*;
duke@1	40	import static com.sun.tools.javac.code.Type.*;
duke@1	41	import static com.sun.tools.javac.code.TypeTags.*;
duke@1	42	import static com.sun.tools.javac.code.Symbol.*;
duke@1	43	import static com.sun.tools.javac.code.Flags.*;
duke@1	44	import static com.sun.tools.javac.code.BoundKind.*;
duke@1	45	import static com.sun.tools.javac.util.ListBuffer.lb;
duke@1	46
duke@1	47	/**
duke@1	48	* Utility class containing various operations on types.
duke@1	49	*
duke@1	50	* <p>Unless other names are more illustrative, the following naming
duke@1	51	* conventions should be observed in this file:
duke@1	52	*
duke@1	53	* <dl>
duke@1	54	* <dt>t</dt>
duke@1	55	* <dd>If the first argument to an operation is a type, it should be named t.</dd>
duke@1	56	* <dt>s</dt>
duke@1	57	* <dd>Similarly, if the second argument to an operation is a type, it should be named s.</dd>
duke@1	58	* <dt>ts</dt>
duke@1	59	* <dd>If an operations takes a list of types, the first should be named ts.</dd>
duke@1	60	* <dt>ss</dt>
duke@1	61	* <dd>A second list of types should be named ss.</dd>
duke@1	62	* </dl>
duke@1	63	*
jjg@581	64	* <p><b>This is NOT part of any supported API.
duke@1	65	* If you write code that depends on this, you do so at your own risk.
duke@1	66	* This code and its internal interfaces are subject to change or
duke@1	67	* deletion without notice.</b>
duke@1	68	*/
duke@1	69	public class Types {
duke@1	70	protected static final Context.Key<Types> typesKey =
duke@1	71	new Context.Key<Types>();
duke@1	72
duke@1	73	final Symtab syms;
mcimadamore@136	74	final JavacMessages messages;
jjg@113	75	final Names names;
duke@1	76	final boolean allowBoxing;
jjg@984	77	final boolean allowCovariantReturns;
jjg@984	78	final boolean allowObjectToPrimitiveCast;
duke@1	79	final ClassReader reader;
duke@1	80	final Check chk;
duke@1	81	List<Warner> warnStack = List.nil();
duke@1	82	final Name capturedName;
duke@1	83
duke@1	84	// <editor-fold defaultstate="collapsed" desc="Instantiating">
duke@1	85	public static Types instance(Context context) {
duke@1	86	Types instance = context.get(typesKey);
duke@1	87	if (instance == null)
duke@1	88	instance = new Types(context);
duke@1	89	return instance;
duke@1	90	}
duke@1	91
duke@1	92	protected Types(Context context) {
duke@1	93	context.put(typesKey, this);
duke@1	94	syms = Symtab.instance(context);
jjg@113	95	names = Names.instance(context);
jjg@984	96	Source source = Source.instance(context);
jjg@984	97	allowBoxing = source.allowBoxing();
jjg@984	98	allowCovariantReturns = source.allowCovariantReturns();
jjg@984	99	allowObjectToPrimitiveCast = source.allowObjectToPrimitiveCast();
duke@1	100	reader = ClassReader.instance(context);
duke@1	101	chk = Check.instance(context);
duke@1	102	capturedName = names.fromString("<captured wildcard>");
mcimadamore@136	103	messages = JavacMessages.instance(context);
duke@1	104	}
duke@1	105	// </editor-fold>
duke@1	106
duke@1	107	// <editor-fold defaultstate="collapsed" desc="upperBound">
duke@1	108	/**
duke@1	109	* The "rvalue conversion".<br>
duke@1	110	* The upper bound of most types is the type
duke@1	111	* itself. Wildcards, on the other hand have upper
duke@1	112	* and lower bounds.
duke@1	113	* @param t a type
duke@1	114	* @return the upper bound of the given type
duke@1	115	*/
duke@1	116	public Type upperBound(Type t) {
duke@1	117	return upperBound.visit(t);
duke@1	118	}
duke@1	119	// where
duke@1	120	private final MapVisitor<Void> upperBound = new MapVisitor<Void>() {
duke@1	121
duke@1	122	@Override
duke@1	123	public Type visitWildcardType(WildcardType t, Void ignored) {
duke@1	124	if (t.isSuperBound())
duke@1	125	return t.bound == null ? syms.objectType : t.bound.bound;
duke@1	126	else
duke@1	127	return visit(t.type);
duke@1	128	}
duke@1	129
duke@1	130	@Override
duke@1	131	public Type visitCapturedType(CapturedType t, Void ignored) {
duke@1	132	return visit(t.bound);
duke@1	133	}
duke@1	134	};
duke@1	135	// </editor-fold>
duke@1	136
duke@1	137	// <editor-fold defaultstate="collapsed" desc="lowerBound">
duke@1	138	/**
duke@1	139	* The "lvalue conversion".<br>
duke@1	140	* The lower bound of most types is the type
duke@1	141	* itself. Wildcards, on the other hand have upper
duke@1	142	* and lower bounds.
duke@1	143	* @param t a type
duke@1	144	* @return the lower bound of the given type
duke@1	145	*/
duke@1	146	public Type lowerBound(Type t) {
duke@1	147	return lowerBound.visit(t);
duke@1	148	}
duke@1	149	// where
duke@1	150	private final MapVisitor<Void> lowerBound = new MapVisitor<Void>() {
duke@1	151
duke@1	152	@Override
duke@1	153	public Type visitWildcardType(WildcardType t, Void ignored) {
duke@1	154	return t.isExtendsBound() ? syms.botType : visit(t.type);
duke@1	155	}
duke@1	156
duke@1	157	@Override
duke@1	158	public Type visitCapturedType(CapturedType t, Void ignored) {
duke@1	159	return visit(t.getLowerBound());
duke@1	160	}
duke@1	161	};
duke@1	162	// </editor-fold>
duke@1	163
duke@1	164	// <editor-fold defaultstate="collapsed" desc="isUnbounded">
duke@1	165	/**
duke@1	166	* Checks that all the arguments to a class are unbounded
duke@1	167	* wildcards or something else that doesn't make any restrictions
duke@1	168	* on the arguments. If a class isUnbounded, a raw super- or
duke@1	169	* subclass can be cast to it without a warning.
duke@1	170	* @param t a type
duke@1	171	* @return true iff the given type is unbounded or raw
duke@1	172	*/
duke@1	173	public boolean isUnbounded(Type t) {
duke@1	174	return isUnbounded.visit(t);
duke@1	175	}
duke@1	176	// where
duke@1	177	private final UnaryVisitor<Boolean> isUnbounded = new UnaryVisitor<Boolean>() {
duke@1	178
duke@1	179	public Boolean visitType(Type t, Void ignored) {
duke@1	180	return true;
duke@1	181	}
duke@1	182
duke@1	183	@Override
duke@1	184	public Boolean visitClassType(ClassType t, Void ignored) {
duke@1	185	List<Type> parms = t.tsym.type.allparams();
duke@1	186	List<Type> args = t.allparams();
duke@1	187	while (parms.nonEmpty()) {
duke@1	188	WildcardType unb = new WildcardType(syms.objectType,
duke@1	189	BoundKind.UNBOUND,
duke@1	190	syms.boundClass,
duke@1	191	(TypeVar)parms.head);
duke@1	192	if (!containsType(args.head, unb))
duke@1	193	return false;
duke@1	194	parms = parms.tail;
duke@1	195	args = args.tail;
duke@1	196	}
duke@1	197	return true;
duke@1	198	}
duke@1	199	};
duke@1	200	// </editor-fold>
duke@1	201
duke@1	202	// <editor-fold defaultstate="collapsed" desc="asSub">
duke@1	203	/**
duke@1	204	* Return the least specific subtype of t that starts with symbol
duke@1	205	* sym. If none exists, return null. The least specific subtype
duke@1	206	* is determined as follows:
duke@1	207	*
duke@1	208	* <p>If there is exactly one parameterized instance of sym that is a
duke@1	209	* subtype of t, that parameterized instance is returned.<br>
duke@1	210	* Otherwise, if the plain type or raw type `sym' is a subtype of
duke@1	211	* type t, the type `sym' itself is returned. Otherwise, null is
duke@1	212	* returned.
duke@1	213	*/
duke@1	214	public Type asSub(Type t, Symbol sym) {
duke@1	215	return asSub.visit(t, sym);
duke@1	216	}
duke@1	217	// where
duke@1	218	private final SimpleVisitor<Type,Symbol> asSub = new SimpleVisitor<Type,Symbol>() {
duke@1	219
duke@1	220	public Type visitType(Type t, Symbol sym) {
duke@1	221	return null;
duke@1	222	}
duke@1	223
duke@1	224	@Override
duke@1	225	public Type visitClassType(ClassType t, Symbol sym) {
duke@1	226	if (t.tsym == sym)
duke@1	227	return t;
duke@1	228	Type base = asSuper(sym.type, t.tsym);
duke@1	229	if (base == null)
duke@1	230	return null;
duke@1	231	ListBuffer<Type> from = new ListBuffer<Type>();
duke@1	232	ListBuffer<Type> to = new ListBuffer<Type>();
duke@1	233	try {
duke@1	234	adapt(base, t, from, to);
duke@1	235	} catch (AdaptFailure ex) {
duke@1	236	return null;
duke@1	237	}
duke@1	238	Type res = subst(sym.type, from.toList(), to.toList());
duke@1	239	if (!isSubtype(res, t))
duke@1	240	return null;
duke@1	241	ListBuffer<Type> openVars = new ListBuffer<Type>();
duke@1	242	for (List<Type> l = sym.type.allparams();
duke@1	243	l.nonEmpty(); l = l.tail)
duke@1	244	if (res.contains(l.head) && !t.contains(l.head))
duke@1	245	openVars.append(l.head);
duke@1	246	if (openVars.nonEmpty()) {
duke@1	247	if (t.isRaw()) {
duke@1	248	// The subtype of a raw type is raw
duke@1	249	res = erasure(res);
duke@1	250	} else {
duke@1	251	// Unbound type arguments default to ?
duke@1	252	List<Type> opens = openVars.toList();
duke@1	253	ListBuffer<Type> qs = new ListBuffer<Type>();
duke@1	254	for (List<Type> iter = opens; iter.nonEmpty(); iter = iter.tail) {
duke@1	255	qs.append(new WildcardType(syms.objectType, BoundKind.UNBOUND, syms.boundClass, (TypeVar) iter.head));
duke@1	256	}
duke@1	257	res = subst(res, opens, qs.toList());
duke@1	258	}
duke@1	259	}
duke@1	260	return res;
duke@1	261	}
duke@1	262
duke@1	263	@Override
duke@1	264	public Type visitErrorType(ErrorType t, Symbol sym) {
duke@1	265	return t;
duke@1	266	}
duke@1	267	};
duke@1	268	// </editor-fold>
duke@1	269
duke@1	270	// <editor-fold defaultstate="collapsed" desc="isConvertible">
duke@1	271	/**
mcimadamore@1071	272	* Is t a subtype of or convertible via boxing/unboxing
mcimadamore@1071	273	* conversion to s?
duke@1	274	*/
duke@1	275	public boolean isConvertible(Type t, Type s, Warner warn) {
mcimadamore@1071	276	if (t.tag == ERROR)
mcimadamore@1071	277	return true;
duke@1	278	boolean tPrimitive = t.isPrimitive();
duke@1	279	boolean sPrimitive = s.isPrimitive();
mcimadamore@795	280	if (tPrimitive == sPrimitive) {
mcimadamore@795	281	checkUnsafeVarargsConversion(t, s, warn);
duke@1	282	return isSubtypeUnchecked(t, s, warn);
mcimadamore@795	283	}
duke@1	284	if (!allowBoxing) return false;
duke@1	285	return tPrimitive
duke@1	286	? isSubtype(boxedClass(t).type, s)
duke@1	287	: isSubtype(unboxedType(t), s);
duke@1	288	}
mcimadamore@795	289	//where
mcimadamore@795	290	private void checkUnsafeVarargsConversion(Type t, Type s, Warner warn) {
mcimadamore@795	291	if (t.tag != ARRAY || isReifiable(t)) return;
mcimadamore@795	292	ArrayType from = (ArrayType)t;
mcimadamore@795	293	boolean shouldWarn = false;
mcimadamore@795	294	switch (s.tag) {
mcimadamore@795	295	case ARRAY:
mcimadamore@795	296	ArrayType to = (ArrayType)s;
mcimadamore@795	297	shouldWarn = from.isVarargs() &&
mcimadamore@795	298	!to.isVarargs() &&
mcimadamore@795	299	!isReifiable(from);
mcimadamore@795	300	break;
mcimadamore@795	301	case CLASS:
mcimadamore@795	302	shouldWarn = from.isVarargs() &&
mcimadamore@795	303	isSubtype(from, s);
mcimadamore@795	304	break;
mcimadamore@795	305	}
mcimadamore@795	306	if (shouldWarn) {
mcimadamore@795	307	warn.warn(LintCategory.VARARGS);
mcimadamore@795	308	}
mcimadamore@795	309	}
duke@1	310
duke@1	311	/**
duke@1	312	* Is t a subtype of or convertiable via boxing/unboxing
duke@1	313	* convertions to s?
duke@1	314	*/
duke@1	315	public boolean isConvertible(Type t, Type s) {
duke@1	316	return isConvertible(t, s, Warner.noWarnings);
duke@1	317	}
duke@1	318	// </editor-fold>
duke@1	319
duke@1	320	// <editor-fold defaultstate="collapsed" desc="isSubtype">
duke@1	321	/**
duke@1	322	* Is t an unchecked subtype of s?
duke@1	323	*/
duke@1	324	public boolean isSubtypeUnchecked(Type t, Type s) {
duke@1	325	return isSubtypeUnchecked(t, s, Warner.noWarnings);
duke@1	326	}
duke@1	327	/**
duke@1	328	* Is t an unchecked subtype of s?
duke@1	329	*/
duke@1	330	public boolean isSubtypeUnchecked(Type t, Type s, Warner warn) {
duke@1	331	if (t.tag == ARRAY && s.tag == ARRAY) {
mcimadamore@795	332	if (((ArrayType)t).elemtype.tag <= lastBaseTag) {
mcimadamore@795	333	return isSameType(elemtype(t), elemtype(s));
mcimadamore@795	334	} else {
mcimadamore@795	335	ArrayType from = (ArrayType)t;
mcimadamore@795	336	ArrayType to = (ArrayType)s;
mcimadamore@795	337	if (from.isVarargs() &&
mcimadamore@795	338	!to.isVarargs() &&
mcimadamore@795	339	!isReifiable(from)) {
mcimadamore@795	340	warn.warn(LintCategory.VARARGS);
mcimadamore@795	341	}
mcimadamore@795	342	return isSubtypeUnchecked(elemtype(t), elemtype(s), warn);
mcimadamore@795	343	}
duke@1	344	} else if (isSubtype(t, s)) {
duke@1	345	return true;
mcimadamore@41	346	}
mcimadamore@41	347	else if (t.tag == TYPEVAR) {
mcimadamore@41	348	return isSubtypeUnchecked(t.getUpperBound(), s, warn);
mcimadamore@41	349	}
mcimadamore@93	350	else if (s.tag == UNDETVAR) {
mcimadamore@93	351	UndetVar uv = (UndetVar)s;
mcimadamore@93	352	if (uv.inst != null)
mcimadamore@93	353	return isSubtypeUnchecked(t, uv.inst, warn);
mcimadamore@93	354	}
mcimadamore@41	355	else if (!s.isRaw()) {
duke@1	356	Type t2 = asSuper(t, s.tsym);
duke@1	357	if (t2 != null && t2.isRaw()) {
duke@1	358	if (isReifiable(s))
mcimadamore@795	359	warn.silentWarn(LintCategory.UNCHECKED);
duke@1	360	else
mcimadamore@795	361	warn.warn(LintCategory.UNCHECKED);
duke@1	362	return true;
duke@1	363	}
duke@1	364	}
duke@1	365	return false;
duke@1	366	}
duke@1	367
duke@1	368	/**
duke@1	369	* Is t a subtype of s?<br>
duke@1	370	* (not defined for Method and ForAll types)
duke@1	371	*/
duke@1	372	final public boolean isSubtype(Type t, Type s) {
duke@1	373	return isSubtype(t, s, true);
duke@1	374	}
duke@1	375	final public boolean isSubtypeNoCapture(Type t, Type s) {
duke@1	376	return isSubtype(t, s, false);
duke@1	377	}
duke@1	378	public boolean isSubtype(Type t, Type s, boolean capture) {
duke@1	379	if (t == s)
duke@1	380	return true;
duke@1	381
duke@1	382	if (s.tag >= firstPartialTag)
duke@1	383	return isSuperType(s, t);
duke@1	384
mcimadamore@299	385	if (s.isCompound()) {
mcimadamore@299	386	for (Type s2 : interfaces(s).prepend(supertype(s))) {
mcimadamore@299	387	if (!isSubtype(t, s2, capture))
mcimadamore@299	388	return false;
mcimadamore@299	389	}
mcimadamore@299	390	return true;
mcimadamore@299	391	}
mcimadamore@299	392
duke@1	393	Type lower = lowerBound(s);
duke@1	394	if (s != lower)
duke@1	395	return isSubtype(capture ? capture(t) : t, lower, false);
duke@1	396
duke@1	397	return isSubtype.visit(capture ? capture(t) : t, s);
duke@1	398	}
duke@1	399	// where
duke@1	400	private TypeRelation isSubtype = new TypeRelation()
duke@1	401	{
duke@1	402	public Boolean visitType(Type t, Type s) {
duke@1	403	switch (t.tag) {
duke@1	404	case BYTE: case CHAR:
duke@1	405	return (t.tag == s.tag ||
duke@1	406	t.tag + 2 <= s.tag && s.tag <= DOUBLE);
duke@1	407	case SHORT: case INT: case LONG: case FLOAT: case DOUBLE:
duke@1	408	return t.tag <= s.tag && s.tag <= DOUBLE;
duke@1	409	case BOOLEAN: case VOID:
duke@1	410	return t.tag == s.tag;
duke@1	411	case TYPEVAR:
duke@1	412	return isSubtypeNoCapture(t.getUpperBound(), s);
duke@1	413	case BOT:
duke@1	414	return
duke@1	415	s.tag == BOT || s.tag == CLASS ||
duke@1	416	s.tag == ARRAY || s.tag == TYPEVAR;
mcimadamore@991	417	case WILDCARD: //we shouldn't be here - avoids crash (see 7034495)
duke@1	418	case NONE:
duke@1	419	return false;
duke@1	420	default:
duke@1	421	throw new AssertionError("isSubtype " + t.tag);
duke@1	422	}
duke@1	423	}
duke@1	424
duke@1	425	private Set<TypePair> cache = new HashSet<TypePair>();
duke@1	426
duke@1	427	private boolean containsTypeRecursive(Type t, Type s) {
duke@1	428	TypePair pair = new TypePair(t, s);
duke@1	429	if (cache.add(pair)) {
duke@1	430	try {
duke@1	431	return containsType(t.getTypeArguments(),
duke@1	432	s.getTypeArguments());
duke@1	433	} finally {
duke@1	434	cache.remove(pair);
duke@1	435	}
duke@1	436	} else {
duke@1	437	return containsType(t.getTypeArguments(),
duke@1	438	rewriteSupers(s).getTypeArguments());
duke@1	439	}
duke@1	440	}
duke@1	441
duke@1	442	private Type rewriteSupers(Type t) {
duke@1	443	if (!t.isParameterized())
duke@1	444	return t;
duke@1	445	ListBuffer<Type> from = lb();
duke@1	446	ListBuffer<Type> to = lb();
duke@1	447	adaptSelf(t, from, to);
duke@1	448	if (from.isEmpty())
duke@1	449	return t;
duke@1	450	ListBuffer<Type> rewrite = lb();
duke@1	451	boolean changed = false;
duke@1	452	for (Type orig : to.toList()) {
duke@1	453	Type s = rewriteSupers(orig);
duke@1	454	if (s.isSuperBound() && !s.isExtendsBound()) {
duke@1	455	s = new WildcardType(syms.objectType,
duke@1	456	BoundKind.UNBOUND,
duke@1	457	syms.boundClass);
duke@1	458	changed = true;
duke@1	459	} else if (s != orig) {
duke@1	460	s = new WildcardType(upperBound(s),
duke@1	461	BoundKind.EXTENDS,
duke@1	462	syms.boundClass);
duke@1	463	changed = true;
duke@1	464	}
duke@1	465	rewrite.append(s);
duke@1	466	}
duke@1	467	if (changed)
duke@1	468	return subst(t.tsym.type, from.toList(), rewrite.toList());
duke@1	469	else
duke@1	470	return t;
duke@1	471	}
duke@1	472
duke@1	473	@Override
duke@1	474	public Boolean visitClassType(ClassType t, Type s) {
duke@1	475	Type sup = asSuper(t, s.tsym);
duke@1	476	return sup != null
duke@1	477	&& sup.tsym == s.tsym
duke@1	478	// You're not allowed to write
duke@1	479	// Vector<Object> vec = new Vector<String>();
duke@1	480	// But with wildcards you can write
duke@1	481	// Vector<? extends Object> vec = new Vector<String>();
duke@1	482	// which means that subtype checking must be done
duke@1	483	// here instead of same-type checking (via containsType).
duke@1	484	&& (!s.isParameterized() || containsTypeRecursive(s, sup))
duke@1	485	&& isSubtypeNoCapture(sup.getEnclosingType(),
duke@1	486	s.getEnclosingType());
duke@1	487	}
duke@1	488
duke@1	489	@Override
duke@1	490	public Boolean visitArrayType(ArrayType t, Type s) {
duke@1	491	if (s.tag == ARRAY) {
duke@1	492	if (t.elemtype.tag <= lastBaseTag)
duke@1	493	return isSameType(t.elemtype, elemtype(s));
duke@1	494	else
duke@1	495	return isSubtypeNoCapture(t.elemtype, elemtype(s));
duke@1	496	}
duke@1	497
duke@1	498	if (s.tag == CLASS) {
duke@1	499	Name sname = s.tsym.getQualifiedName();
duke@1	500	return sname == names.java_lang_Object
duke@1	501	|| sname == names.java_lang_Cloneable
duke@1	502	|| sname == names.java_io_Serializable;
duke@1	503	}
duke@1	504
duke@1	505	return false;
duke@1	506	}
duke@1	507
duke@1	508	@Override
duke@1	509	public Boolean visitUndetVar(UndetVar t, Type s) {
duke@1	510	//todo: test against origin needed? or replace with substitution?
duke@1	511	if (t == s || t.qtype == s || s.tag == ERROR || s.tag == UNKNOWN)
duke@1	512	return true;
duke@1	513
duke@1	514	if (t.inst != null)
duke@1	515	return isSubtypeNoCapture(t.inst, s); // TODO: ", warn"?
duke@1	516
duke@1	517	t.hibounds = t.hibounds.prepend(s);
duke@1	518	return true;
duke@1	519	}
duke@1	520
duke@1	521	@Override
duke@1	522	public Boolean visitErrorType(ErrorType t, Type s) {
duke@1	523	return true;
duke@1	524	}
duke@1	525	};
duke@1	526
duke@1	527	/**
duke@1	528	* Is t a subtype of every type in given list `ts'?<br>
duke@1	529	* (not defined for Method and ForAll types)<br>
duke@1	530	* Allows unchecked conversions.
duke@1	531	*/
duke@1	532	public boolean isSubtypeUnchecked(Type t, List<Type> ts, Warner warn) {
duke@1	533	for (List<Type> l = ts; l.nonEmpty(); l = l.tail)
duke@1	534	if (!isSubtypeUnchecked(t, l.head, warn))
duke@1	535	return false;
duke@1	536	return true;
duke@1	537	}
duke@1	538
duke@1	539	/**
duke@1	540	* Are corresponding elements of ts subtypes of ss? If lists are
duke@1	541	* of different length, return false.
duke@1	542	*/
duke@1	543	public boolean isSubtypes(List<Type> ts, List<Type> ss) {
duke@1	544	while (ts.tail != null && ss.tail != null
duke@1	545	/*inlined: ts.nonEmpty() && ss.nonEmpty()*/ &&
duke@1	546	isSubtype(ts.head, ss.head)) {
duke@1	547	ts = ts.tail;
duke@1	548	ss = ss.tail;
duke@1	549	}
duke@1	550	return ts.tail == null && ss.tail == null;
duke@1	551	/*inlined: ts.isEmpty() && ss.isEmpty();*/
duke@1	552	}
duke@1	553
duke@1	554	/**
duke@1	555	* Are corresponding elements of ts subtypes of ss, allowing
duke@1	556	* unchecked conversions? If lists are of different length,
duke@1	557	* return false.
duke@1	558	**/
duke@1	559	public boolean isSubtypesUnchecked(List<Type> ts, List<Type> ss, Warner warn) {
duke@1	560	while (ts.tail != null && ss.tail != null
duke@1	561	/*inlined: ts.nonEmpty() && ss.nonEmpty()*/ &&
duke@1	562	isSubtypeUnchecked(ts.head, ss.head, warn)) {
duke@1	563	ts = ts.tail;
duke@1	564	ss = ss.tail;
duke@1	565	}
duke@1	566	return ts.tail == null && ss.tail == null;
duke@1	567	/*inlined: ts.isEmpty() && ss.isEmpty();*/
duke@1	568	}
duke@1	569	// </editor-fold>
duke@1	570
duke@1	571	// <editor-fold defaultstate="collapsed" desc="isSuperType">
duke@1	572	/**
duke@1	573	* Is t a supertype of s?
duke@1	574	*/
duke@1	575	public boolean isSuperType(Type t, Type s) {
duke@1	576	switch (t.tag) {
duke@1	577	case ERROR:
duke@1	578	return true;
duke@1	579	case UNDETVAR: {
duke@1	580	UndetVar undet = (UndetVar)t;
duke@1	581	if (t == s ||
duke@1	582	undet.qtype == s ||
duke@1	583	s.tag == ERROR ||
duke@1	584	s.tag == BOT) return true;
duke@1	585	if (undet.inst != null)
duke@1	586	return isSubtype(s, undet.inst);
duke@1	587	undet.lobounds = undet.lobounds.prepend(s);
duke@1	588	return true;
duke@1	589	}
duke@1	590	default:
duke@1	591	return isSubtype(s, t);
duke@1	592	}
duke@1	593	}
duke@1	594	// </editor-fold>
duke@1	595
duke@1	596	// <editor-fold defaultstate="collapsed" desc="isSameType">
duke@1	597	/**
duke@1	598	* Are corresponding elements of the lists the same type? If
duke@1	599	* lists are of different length, return false.
duke@1	600	*/
duke@1	601	public boolean isSameTypes(List<Type> ts, List<Type> ss) {
duke@1	602	while (ts.tail != null && ss.tail != null
duke@1	603	/*inlined: ts.nonEmpty() && ss.nonEmpty()*/ &&
duke@1	604	isSameType(ts.head, ss.head)) {
duke@1	605	ts = ts.tail;
duke@1	606	ss = ss.tail;
duke@1	607	}
duke@1	608	return ts.tail == null && ss.tail == null;
duke@1	609	/*inlined: ts.isEmpty() && ss.isEmpty();*/
duke@1	610	}
duke@1	611
duke@1	612	/**
duke@1	613	* Is t the same type as s?
duke@1	614	*/
duke@1	615	public boolean isSameType(Type t, Type s) {
duke@1	616	return isSameType.visit(t, s);
duke@1	617	}
duke@1	618	// where
duke@1	619	private TypeRelation isSameType = new TypeRelation() {
duke@1	620
duke@1	621	public Boolean visitType(Type t, Type s) {
duke@1	622	if (t == s)
duke@1	623	return true;
duke@1	624
duke@1	625	if (s.tag >= firstPartialTag)
duke@1	626	return visit(s, t);
duke@1	627
duke@1	628	switch (t.tag) {
duke@1	629	case BYTE: case CHAR: case SHORT: case INT: case LONG: case FLOAT:
duke@1	630	case DOUBLE: case BOOLEAN: case VOID: case BOT: case NONE:
duke@1	631	return t.tag == s.tag;
mcimadamore@561	632	case TYPEVAR: {
mcimadamore@561	633	if (s.tag == TYPEVAR) {
mcimadamore@561	634	//type-substitution does not preserve type-var types
mcimadamore@561	635	//check that type var symbols and bounds are indeed the same
mcimadamore@561	636	return t.tsym == s.tsym &&
mcimadamore@561	637	visit(t.getUpperBound(), s.getUpperBound());
mcimadamore@561	638	}
mcimadamore@561	639	else {
mcimadamore@561	640	//special case for s == ? super X, where upper(s) = u
mcimadamore@561	641	//check that u == t, where u has been set by Type.withTypeVar
mcimadamore@561	642	return s.isSuperBound() &&
mcimadamore@561	643	!s.isExtendsBound() &&
mcimadamore@561	644	visit(t, upperBound(s));
mcimadamore@561	645	}
mcimadamore@561	646	}
duke@1	647	default:
duke@1	648	throw new AssertionError("isSameType " + t.tag);
duke@1	649	}
duke@1	650	}
duke@1	651
duke@1	652	@Override
duke@1	653	public Boolean visitWildcardType(WildcardType t, Type s) {
duke@1	654	if (s.tag >= firstPartialTag)
duke@1	655	return visit(s, t);
duke@1	656	else
duke@1	657	return false;
duke@1	658	}
duke@1	659
duke@1	660	@Override
duke@1	661	public Boolean visitClassType(ClassType t, Type s) {
duke@1	662	if (t == s)
duke@1	663	return true;
duke@1	664
duke@1	665	if (s.tag >= firstPartialTag)
duke@1	666	return visit(s, t);
duke@1	667
duke@1	668	if (s.isSuperBound() && !s.isExtendsBound())
duke@1	669	return visit(t, upperBound(s)) && visit(t, lowerBound(s));
duke@1	670
duke@1	671	if (t.isCompound() && s.isCompound()) {
duke@1	672	if (!visit(supertype(t), supertype(s)))
duke@1	673	return false;
duke@1	674
duke@1	675	HashSet<SingletonType> set = new HashSet<SingletonType>();
duke@1	676	for (Type x : interfaces(t))
duke@1	677	set.add(new SingletonType(x));
duke@1	678	for (Type x : interfaces(s)) {
duke@1	679	if (!set.remove(new SingletonType(x)))
duke@1	680	return false;
duke@1	681	}
jjg@789	682	return (set.isEmpty());
duke@1	683	}
duke@1	684	return t.tsym == s.tsym
duke@1	685	&& visit(t.getEnclosingType(), s.getEnclosingType())
duke@1	686	&& containsTypeEquivalent(t.getTypeArguments(), s.getTypeArguments());
duke@1	687	}
duke@1	688
duke@1	689	@Override
duke@1	690	public Boolean visitArrayType(ArrayType t, Type s) {
duke@1	691	if (t == s)
duke@1	692	return true;
duke@1	693
duke@1	694	if (s.tag >= firstPartialTag)
duke@1	695	return visit(s, t);
duke@1	696
duke@1	697	return s.tag == ARRAY
duke@1	698	&& containsTypeEquivalent(t.elemtype, elemtype(s));
duke@1	699	}
duke@1	700
duke@1	701	@Override
duke@1	702	public Boolean visitMethodType(MethodType t, Type s) {
duke@1	703	// isSameType for methods does not take thrown
duke@1	704	// exceptions into account!
duke@1	705	return hasSameArgs(t, s) && visit(t.getReturnType(), s.getReturnType());
duke@1	706	}
duke@1	707
duke@1	708	@Override
duke@1	709	public Boolean visitPackageType(PackageType t, Type s) {
duke@1	710	return t == s;
duke@1	711	}
duke@1	712
duke@1	713	@Override
duke@1	714	public Boolean visitForAll(ForAll t, Type s) {
duke@1	715	if (s.tag != FORALL)
duke@1	716	return false;
duke@1	717
duke@1	718	ForAll forAll = (ForAll)s;
duke@1	719	return hasSameBounds(t, forAll)
duke@1	720	&& visit(t.qtype, subst(forAll.qtype, forAll.tvars, t.tvars));
duke@1	721	}
duke@1	722
duke@1	723	@Override
duke@1	724	public Boolean visitUndetVar(UndetVar t, Type s) {
duke@1	725	if (s.tag == WILDCARD)
duke@1	726	// FIXME, this might be leftovers from before capture conversion
duke@1	727	return false;
duke@1	728
duke@1	729	if (t == s || t.qtype == s || s.tag == ERROR || s.tag == UNKNOWN)
duke@1	730	return true;
duke@1	731
duke@1	732	if (t.inst != null)
duke@1	733	return visit(t.inst, s);
duke@1	734
duke@1	735	t.inst = fromUnknownFun.apply(s);
duke@1	736	for (List<Type> l = t.lobounds; l.nonEmpty(); l = l.tail) {
duke@1	737	if (!isSubtype(l.head, t.inst))
duke@1	738	return false;
duke@1	739	}
duke@1	740	for (List<Type> l = t.hibounds; l.nonEmpty(); l = l.tail) {
duke@1	741	if (!isSubtype(t.inst, l.head))
duke@1	742	return false;
duke@1	743	}
duke@1	744	return true;
duke@1	745	}
duke@1	746
duke@1	747	@Override
duke@1	748	public Boolean visitErrorType(ErrorType t, Type s) {
duke@1	749	return true;
duke@1	750	}
duke@1	751	};
duke@1	752	// </editor-fold>
duke@1	753
duke@1	754	// <editor-fold defaultstate="collapsed" desc="fromUnknownFun">
duke@1	755	/**
duke@1	756	* A mapping that turns all unknown types in this type to fresh
duke@1	757	* unknown variables.
duke@1	758	*/
duke@1	759	public Mapping fromUnknownFun = new Mapping("fromUnknownFun") {
duke@1	760	public Type apply(Type t) {
duke@1	761	if (t.tag == UNKNOWN) return new UndetVar(t);
duke@1	762	else return t.map(this);
duke@1	763	}
duke@1	764	};
duke@1	765	// </editor-fold>
duke@1	766
duke@1	767	// <editor-fold defaultstate="collapsed" desc="Contains Type">
duke@1	768	public boolean containedBy(Type t, Type s) {
duke@1	769	switch (t.tag) {
duke@1	770	case UNDETVAR:
duke@1	771	if (s.tag == WILDCARD) {
duke@1	772	UndetVar undetvar = (UndetVar)t;
mcimadamore@210	773	WildcardType wt = (WildcardType)s;
mcimadamore@210	774	switch(wt.kind) {
mcimadamore@210	775	case UNBOUND: //similar to ? extends Object
mcimadamore@210	776	case EXTENDS: {
mcimadamore@210	777	Type bound = upperBound(s);
mcimadamore@210	778	// We should check the new upper bound against any of the
mcimadamore@210	779	// undetvar's lower bounds.
mcimadamore@210	780	for (Type t2 : undetvar.lobounds) {
mcimadamore@210	781	if (!isSubtype(t2, bound))
mcimadamore@210	782	return false;
mcimadamore@210	783	}
mcimadamore@210	784	undetvar.hibounds = undetvar.hibounds.prepend(bound);
mcimadamore@210	785	break;
mcimadamore@210	786	}
mcimadamore@210	787	case SUPER: {
mcimadamore@210	788	Type bound = lowerBound(s);
mcimadamore@210	789	// We should check the new lower bound against any of the
mcimadamore@210	790	// undetvar's lower bounds.
mcimadamore@210	791	for (Type t2 : undetvar.hibounds) {
mcimadamore@210	792	if (!isSubtype(bound, t2))
mcimadamore@210	793	return false;
mcimadamore@210	794	}
mcimadamore@210	795	undetvar.lobounds = undetvar.lobounds.prepend(bound);
mcimadamore@210	796	break;
mcimadamore@210	797	}
mcimadamore@162	798	}
duke@1	799	return true;
duke@1	800	} else {
duke@1	801	return isSameType(t, s);
duke@1	802	}
duke@1	803	case ERROR:
duke@1	804	return true;
duke@1	805	default:
duke@1	806	return containsType(s, t);
duke@1	807	}
duke@1	808	}
duke@1	809
duke@1	810	boolean containsType(List<Type> ts, List<Type> ss) {
duke@1	811	while (ts.nonEmpty() && ss.nonEmpty()
duke@1	812	&& containsType(ts.head, ss.head)) {
duke@1	813	ts = ts.tail;
duke@1	814	ss = ss.tail;
duke@1	815	}
duke@1	816	return ts.isEmpty() && ss.isEmpty();
duke@1	817	}
duke@1	818
duke@1	819	/**
duke@1	820	* Check if t contains s.
duke@1	821	*
duke@1	822	* <p>T contains S if:
duke@1	823	*
duke@1	824	* <p>{@code L(T) <: L(S) && U(S) <: U(T)}
duke@1	825	*
duke@1	826	* <p>This relation is only used by ClassType.isSubtype(), that
duke@1	827	* is,
duke@1	828	*
duke@1	829	* <p>{@code C<S> <: C<T> if T contains S.}
duke@1	830	*
duke@1	831	* <p>Because of F-bounds, this relation can lead to infinite
duke@1	832	* recursion. Thus we must somehow break that recursion. Notice
duke@1	833	* that containsType() is only called from ClassType.isSubtype().
duke@1	834	* Since the arguments have already been checked against their
duke@1	835	* bounds, we know:
duke@1	836	*
duke@1	837	* <p>{@code U(S) <: U(T) if T is "super" bound (U(T) *is* the bound)}
duke@1	838	*
duke@1	839	* <p>{@code L(T) <: L(S) if T is "extends" bound (L(T) is bottom)}
duke@1	840	*
duke@1	841	* @param t a type
duke@1	842	* @param s a type
duke@1	843	*/
duke@1	844	public boolean containsType(Type t, Type s) {
duke@1	845	return containsType.visit(t, s);
duke@1	846	}
duke@1	847	// where
duke@1	848	private TypeRelation containsType = new TypeRelation() {
duke@1	849
duke@1	850	private Type U(Type t) {
duke@1	851	while (t.tag == WILDCARD) {
duke@1	852	WildcardType w = (WildcardType)t;
duke@1	853	if (w.isSuperBound())
duke@1	854	return w.bound == null ? syms.objectType : w.bound.bound;
duke@1	855	else
duke@1	856	t = w.type;
duke@1	857	}
duke@1	858	return t;
duke@1	859	}
duke@1	860
duke@1	861	private Type L(Type t) {
duke@1	862	while (t.tag == WILDCARD) {
duke@1	863	WildcardType w = (WildcardType)t;
duke@1	864	if (w.isExtendsBound())
duke@1	865	return syms.botType;
duke@1	866	else
duke@1	867	t = w.type;
duke@1	868	}
duke@1	869	return t;
duke@1	870	}
duke@1	871
duke@1	872	public Boolean visitType(Type t, Type s) {
duke@1	873	if (s.tag >= firstPartialTag)
duke@1	874	return containedBy(s, t);
duke@1	875	else
duke@1	876	return isSameType(t, s);
duke@1	877	}
duke@1	878
jjg@789	879	// void debugContainsType(WildcardType t, Type s) {
jjg@789	880	// System.err.println();
jjg@789	881	// System.err.format(" does %s contain %s?%n", t, s);
jjg@789	882	// System.err.format(" %s U(%s) <: U(%s) %s = %s%n",
jjg@789	883	// upperBound(s), s, t, U(t),
jjg@789	884	// t.isSuperBound()
jjg@789	885	// || isSubtypeNoCapture(upperBound(s), U(t)));
jjg@789	886	// System.err.format(" %s L(%s) <: L(%s) %s = %s%n",
jjg@789	887	// L(t), t, s, lowerBound(s),
jjg@789	888	// t.isExtendsBound()
jjg@789	889	// || isSubtypeNoCapture(L(t), lowerBound(s)));
jjg@789	890	// System.err.println();
jjg@789	891	// }
duke@1	892
duke@1	893	@Override
duke@1	894	public Boolean visitWildcardType(WildcardType t, Type s) {
duke@1	895	if (s.tag >= firstPartialTag)
duke@1	896	return containedBy(s, t);
duke@1	897	else {
jjg@789	898	// debugContainsType(t, s);
duke@1	899	return isSameWildcard(t, s)
duke@1	900	|| isCaptureOf(s, t)
duke@1	901	|| ((t.isExtendsBound() || isSubtypeNoCapture(L(t), lowerBound(s))) &&
duke@1	902	(t.isSuperBound() || isSubtypeNoCapture(upperBound(s), U(t))));
duke@1	903	}
duke@1	904	}
duke@1	905
duke@1	906	@Override
duke@1	907	public Boolean visitUndetVar(UndetVar t, Type s) {
duke@1	908	if (s.tag != WILDCARD)
duke@1	909	return isSameType(t, s);
duke@1	910	else
duke@1	911	return false;
duke@1	912	}
duke@1	913
duke@1	914	@Override
duke@1	915	public Boolean visitErrorType(ErrorType t, Type s) {
duke@1	916	return true;
duke@1	917	}
duke@1	918	};
duke@1	919
duke@1	920	public boolean isCaptureOf(Type s, WildcardType t) {
mcimadamore@79	921	if (s.tag != TYPEVAR || !((TypeVar)s).isCaptured())
duke@1	922	return false;
duke@1	923	return isSameWildcard(t, ((CapturedType)s).wildcard);
duke@1	924	}
duke@1	925
duke@1	926	public boolean isSameWildcard(WildcardType t, Type s) {
duke@1	927	if (s.tag != WILDCARD)
duke@1	928	return false;
duke@1	929	WildcardType w = (WildcardType)s;
duke@1	930	return w.kind == t.kind && w.type == t.type;
duke@1	931	}
duke@1	932
duke@1	933	public boolean containsTypeEquivalent(List<Type> ts, List<Type> ss) {
duke@1	934	while (ts.nonEmpty() && ss.nonEmpty()
duke@1	935	&& containsTypeEquivalent(ts.head, ss.head)) {
duke@1	936	ts = ts.tail;
duke@1	937	ss = ss.tail;
duke@1	938	}
duke@1	939	return ts.isEmpty() && ss.isEmpty();
duke@1	940	}
duke@1	941	// </editor-fold>
duke@1	942
duke@1	943	// <editor-fold defaultstate="collapsed" desc="isCastable">
duke@1	944	public boolean isCastable(Type t, Type s) {
duke@1	945	return isCastable(t, s, Warner.noWarnings);
duke@1	946	}
duke@1	947
duke@1	948	/**
duke@1	949	* Is t is castable to s?<br>
duke@1	950	* s is assumed to be an erased type.<br>
duke@1	951	* (not defined for Method and ForAll types).
duke@1	952	*/
duke@1	953	public boolean isCastable(Type t, Type s, Warner warn) {
duke@1	954	if (t == s)
duke@1	955	return true;
duke@1	956
duke@1	957	if (t.isPrimitive() != s.isPrimitive())
jjg@984	958	return allowBoxing && (
jjg@984	959	isConvertible(t, s, warn)
mcimadamore@1007	960	|| (allowObjectToPrimitiveCast &&
mcimadamore@1007	961	s.isPrimitive() &&
mcimadamore@1007	962	isSubtype(boxedClass(s).type, t)));
duke@1	963	if (warn != warnStack.head) {
duke@1	964	try {
duke@1	965	warnStack = warnStack.prepend(warn);
mcimadamore@795	966	checkUnsafeVarargsConversion(t, s, warn);
mcimadamore@185	967	return isCastable.visit(t,s);
duke@1	968	} finally {
duke@1	969	warnStack = warnStack.tail;
duke@1	970	}
duke@1	971	} else {
mcimadamore@185	972	return isCastable.visit(t,s);
duke@1	973	}
duke@1	974	}
duke@1	975	// where
duke@1	976	private TypeRelation isCastable = new TypeRelation() {
duke@1	977
duke@1	978	public Boolean visitType(Type t, Type s) {
duke@1	979	if (s.tag == ERROR)
duke@1	980	return true;
duke@1	981
duke@1	982	switch (t.tag) {
duke@1	983	case BYTE: case CHAR: case SHORT: case INT: case LONG: case FLOAT:
duke@1	984	case DOUBLE:
duke@1	985	return s.tag <= DOUBLE;
duke@1	986	case BOOLEAN:
duke@1	987	return s.tag == BOOLEAN;
duke@1	988	case VOID:
duke@1	989	return false;
duke@1	990	case BOT:
duke@1	991	return isSubtype(t, s);
duke@1	992	default:
duke@1	993	throw new AssertionError();
duke@1	994	}
duke@1	995	}
duke@1	996
duke@1	997	@Override
duke@1	998	public Boolean visitWildcardType(WildcardType t, Type s) {
duke@1	999	return isCastable(upperBound(t), s, warnStack.head);
duke@1	1000	}
duke@1	1001
duke@1	1002	@Override
duke@1	1003	public Boolean visitClassType(ClassType t, Type s) {
duke@1	1004	if (s.tag == ERROR || s.tag == BOT)
duke@1	1005	return true;
duke@1	1006
duke@1	1007	if (s.tag == TYPEVAR) {
mcimadamore@640	1008	if (isCastable(t, s.getUpperBound(), Warner.noWarnings)) {
mcimadamore@795	1009	warnStack.head.warn(LintCategory.UNCHECKED);
duke@1	1010	return true;
duke@1	1011	} else {
duke@1	1012	return false;
duke@1	1013	}
duke@1	1014	}
duke@1	1015
duke@1	1016	if (t.isCompound()) {
mcimadamore@211	1017	Warner oldWarner = warnStack.head;
mcimadamore@211	1018	warnStack.head = Warner.noWarnings;
duke@1	1019	if (!visit(supertype(t), s))
duke@1	1020	return false;
duke@1	1021	for (Type intf : interfaces(t)) {
duke@1	1022	if (!visit(intf, s))
duke@1	1023	return false;
duke@1	1024	}
mcimadamore@795	1025	if (warnStack.head.hasLint(LintCategory.UNCHECKED))
mcimadamore@795	1026	oldWarner.warn(LintCategory.UNCHECKED);
duke@1	1027	return true;
duke@1	1028	}
duke@1	1029
duke@1	1030	if (s.isCompound()) {
duke@1	1031	// call recursively to reuse the above code
duke@1	1032	return visitClassType((ClassType)s, t);
duke@1	1033	}
duke@1	1034
duke@1	1035	if (s.tag == CLASS || s.tag == ARRAY) {
duke@1	1036	boolean upcast;
duke@1	1037	if ((upcast = isSubtype(erasure(t), erasure(s)))
duke@1	1038	|| isSubtype(erasure(s), erasure(t))) {
duke@1	1039	if (!upcast && s.tag == ARRAY) {
duke@1	1040	if (!isReifiable(s))
mcimadamore@795	1041	warnStack.head.warn(LintCategory.UNCHECKED);
duke@1	1042	return true;
duke@1	1043	} else if (s.isRaw()) {
duke@1	1044	return true;
duke@1	1045	} else if (t.isRaw()) {
duke@1	1046	if (!isUnbounded(s))
mcimadamore@795	1047	warnStack.head.warn(LintCategory.UNCHECKED);
duke@1	1048	return true;
duke@1	1049	}
duke@1	1050	// Assume |a| <: |b|
duke@1	1051	final Type a = upcast ? t : s;
duke@1	1052	final Type b = upcast ? s : t;
duke@1	1053	final boolean HIGH = true;
duke@1	1054	final boolean LOW = false;
duke@1	1055	final boolean DONT_REWRITE_TYPEVARS = false;
duke@1	1056	Type aHigh = rewriteQuantifiers(a, HIGH, DONT_REWRITE_TYPEVARS);
duke@1	1057	Type aLow = rewriteQuantifiers(a, LOW, DONT_REWRITE_TYPEVARS);
duke@1	1058	Type bHigh = rewriteQuantifiers(b, HIGH, DONT_REWRITE_TYPEVARS);
duke@1	1059	Type bLow = rewriteQuantifiers(b, LOW, DONT_REWRITE_TYPEVARS);
duke@1	1060	Type lowSub = asSub(bLow, aLow.tsym);
duke@1	1061	Type highSub = (lowSub == null) ? null : asSub(bHigh, aHigh.tsym);
duke@1	1062	if (highSub == null) {
duke@1	1063	final boolean REWRITE_TYPEVARS = true;
duke@1	1064	aHigh = rewriteQuantifiers(a, HIGH, REWRITE_TYPEVARS);
duke@1	1065	aLow = rewriteQuantifiers(a, LOW, REWRITE_TYPEVARS);
duke@1	1066	bHigh = rewriteQuantifiers(b, HIGH, REWRITE_TYPEVARS);
duke@1	1067	bLow = rewriteQuantifiers(b, LOW, REWRITE_TYPEVARS);
duke@1	1068	lowSub = asSub(bLow, aLow.tsym);
duke@1	1069	highSub = (lowSub == null) ? null : asSub(bHigh, aHigh.tsym);
duke@1	1070	}
duke@1	1071	if (highSub != null) {
jjg@816	1072	if (!(a.tsym == highSub.tsym && a.tsym == lowSub.tsym)) {
jjg@816	1073	Assert.error(a.tsym + " != " + highSub.tsym + " != " + lowSub.tsym);
jjg@816	1074	}
mcimadamore@185	1075	if (!disjointTypes(aHigh.allparams(), highSub.allparams())
mcimadamore@185	1076	&& !disjointTypes(aHigh.allparams(), lowSub.allparams())
mcimadamore@185	1077	&& !disjointTypes(aLow.allparams(), highSub.allparams())
mcimadamore@185	1078	&& !disjointTypes(aLow.allparams(), lowSub.allparams())) {
mcimadamore@779	1079	if (upcast ? giveWarning(a, b) :
mcimadamore@235	1080	giveWarning(b, a))
mcimadamore@795	1081	warnStack.head.warn(LintCategory.UNCHECKED);
duke@1	1082	return true;
duke@1	1083	}
duke@1	1084	}
duke@1	1085	if (isReifiable(s))
duke@1	1086	return isSubtypeUnchecked(a, b);
duke@1	1087	else
duke@1	1088	return isSubtypeUnchecked(a, b, warnStack.head);
duke@1	1089	}
duke@1	1090
duke@1	1091	// Sidecast
duke@1	1092	if (s.tag == CLASS) {
duke@1	1093	if ((s.tsym.flags() & INTERFACE) != 0) {
duke@1	1094	return ((t.tsym.flags() & FINAL) == 0)
duke@1	1095	? sideCast(t, s, warnStack.head)
duke@1	1096	: sideCastFinal(t, s, warnStack.head);
duke@1	1097	} else if ((t.tsym.flags() & INTERFACE) != 0) {
duke@1	1098	return ((s.tsym.flags() & FINAL) == 0)
duke@1	1099	? sideCast(t, s, warnStack.head)
duke@1	1100	: sideCastFinal(t, s, warnStack.head);
duke@1	1101	} else {
duke@1	1102	// unrelated class types
duke@1	1103	return false;
duke@1	1104	}
duke@1	1105	}
duke@1	1106	}
duke@1	1107	return false;
duke@1	1108	}
duke@1	1109
duke@1	1110	@Override
duke@1	1111	public Boolean visitArrayType(ArrayType t, Type s) {
duke@1	1112	switch (s.tag) {
duke@1	1113	case ERROR:
duke@1	1114	case BOT:
duke@1	1115	return true;
duke@1	1116	case TYPEVAR:
duke@1	1117	if (isCastable(s, t, Warner.noWarnings)) {
mcimadamore@795	1118	warnStack.head.warn(LintCategory.UNCHECKED);
duke@1	1119	return true;
duke@1	1120	} else {
duke@1	1121	return false;
duke@1	1122	}
duke@1	1123	case CLASS:
duke@1	1124	return isSubtype(t, s);
duke@1	1125	case ARRAY:
mcimadamore@786	1126	if (elemtype(t).tag <= lastBaseTag ||
mcimadamore@786	1127	elemtype(s).tag <= lastBaseTag) {
duke@1	1128	return elemtype(t).tag == elemtype(s).tag;
duke@1	1129	} else {
duke@1	1130	return visit(elemtype(t), elemtype(s));
duke@1	1131	}
duke@1	1132	default:
duke@1	1133	return false;
duke@1	1134	}
duke@1	1135	}
duke@1	1136
duke@1	1137	@Override
duke@1	1138	public Boolean visitTypeVar(TypeVar t, Type s) {
duke@1	1139	switch (s.tag) {
duke@1	1140	case ERROR:
duke@1	1141	case BOT:
duke@1	1142	return true;
duke@1	1143	case TYPEVAR:
duke@1	1144	if (isSubtype(t, s)) {
duke@1	1145	return true;
duke@1	1146	} else if (isCastable(t.bound, s, Warner.noWarnings)) {
mcimadamore@795	1147	warnStack.head.warn(LintCategory.UNCHECKED);
duke@1	1148	return true;
duke@1	1149	} else {
duke@1	1150	return false;
duke@1	1151	}
duke@1	1152	default:
duke@1	1153	return isCastable(t.bound, s, warnStack.head);
duke@1	1154	}
duke@1	1155	}
duke@1	1156
duke@1	1157	@Override
duke@1	1158	public Boolean visitErrorType(ErrorType t, Type s) {
duke@1	1159	return true;
duke@1	1160	}
duke@1	1161	};
duke@1	1162	// </editor-fold>
duke@1	1163
duke@1	1164	// <editor-fold defaultstate="collapsed" desc="disjointTypes">
duke@1	1165	public boolean disjointTypes(List<Type> ts, List<Type> ss) {
duke@1	1166	while (ts.tail != null && ss.tail != null) {
duke@1	1167	if (disjointType(ts.head, ss.head)) return true;
duke@1	1168	ts = ts.tail;
duke@1	1169	ss = ss.tail;
duke@1	1170	}
duke@1	1171	return false;
duke@1	1172	}
duke@1	1173
duke@1	1174	/**
duke@1	1175	* Two types or wildcards are considered disjoint if it can be
duke@1	1176	* proven that no type can be contained in both. It is
duke@1	1177	* conservative in that it is allowed to say that two types are
duke@1	1178	* not disjoint, even though they actually are.
duke@1	1179	*
duke@1	1180	* The type C<X> is castable to C<Y> exactly if X and Y are not
duke@1	1181	* disjoint.
duke@1	1182	*/
duke@1	1183	public boolean disjointType(Type t, Type s) {
duke@1	1184	return disjointType.visit(t, s);
duke@1	1185	}
duke@1	1186	// where
duke@1	1187	private TypeRelation disjointType = new TypeRelation() {
duke@1	1188
duke@1	1189	private Set<TypePair> cache = new HashSet<TypePair>();
duke@1	1190
duke@1	1191	public Boolean visitType(Type t, Type s) {
duke@1	1192	if (s.tag == WILDCARD)
duke@1	1193	return visit(s, t);
duke@1	1194	else
duke@1	1195	return notSoftSubtypeRecursive(t, s) || notSoftSubtypeRecursive(s, t);
duke@1	1196	}
duke@1	1197
duke@1	1198	private boolean isCastableRecursive(Type t, Type s) {
duke@1	1199	TypePair pair = new TypePair(t, s);
duke@1	1200	if (cache.add(pair)) {
duke@1	1201	try {
duke@1	1202	return Types.this.isCastable(t, s);
duke@1	1203	} finally {
duke@1	1204	cache.remove(pair);
duke@1	1205	}
duke@1	1206	} else {
duke@1	1207	return true;
duke@1	1208	}
duke@1	1209	}
duke@1	1210
duke@1	1211	private boolean notSoftSubtypeRecursive(Type t, Type s) {
duke@1	1212	TypePair pair = new TypePair(t, s);
duke@1	1213	if (cache.add(pair)) {
duke@1	1214	try {
duke@1	1215	return Types.this.notSoftSubtype(t, s);
duke@1	1216	} finally {
duke@1	1217	cache.remove(pair);
duke@1	1218	}
duke@1	1219	} else {
duke@1	1220	return false;
duke@1	1221	}
duke@1	1222	}
duke@1	1223
duke@1	1224	@Override
duke@1	1225	public Boolean visitWildcardType(WildcardType t, Type s) {
duke@1	1226	if (t.isUnbound())
duke@1	1227	return false;
duke@1	1228
duke@1	1229	if (s.tag != WILDCARD) {
duke@1	1230	if (t.isExtendsBound())
duke@1	1231	return notSoftSubtypeRecursive(s, t.type);
duke@1	1232	else // isSuperBound()
duke@1	1233	return notSoftSubtypeRecursive(t.type, s);
duke@1	1234	}
duke@1	1235
duke@1	1236	if (s.isUnbound())
duke@1	1237	return false;
duke@1	1238
duke@1	1239	if (t.isExtendsBound()) {
duke@1	1240	if (s.isExtendsBound())
duke@1	1241	return !isCastableRecursive(t.type, upperBound(s));
duke@1	1242	else if (s.isSuperBound())
duke@1	1243	return notSoftSubtypeRecursive(lowerBound(s), t.type);
duke@1	1244	} else if (t.isSuperBound()) {
duke@1	1245	if (s.isExtendsBound())
duke@1	1246	return notSoftSubtypeRecursive(t.type, upperBound(s));
duke@1	1247	}
duke@1	1248	return false;
duke@1	1249	}
duke@1	1250	};
duke@1	1251	// </editor-fold>
duke@1	1252
duke@1	1253	// <editor-fold defaultstate="collapsed" desc="lowerBoundArgtypes">
duke@1	1254	/**
duke@1	1255	* Returns the lower bounds of the formals of a method.
duke@1	1256	*/
duke@1	1257	public List<Type> lowerBoundArgtypes(Type t) {
duke@1	1258	return map(t.getParameterTypes(), lowerBoundMapping);
duke@1	1259	}
duke@1	1260	private final Mapping lowerBoundMapping = new Mapping("lowerBound") {
duke@1	1261	public Type apply(Type t) {
duke@1	1262	return lowerBound(t);
duke@1	1263	}
duke@1	1264	};
duke@1	1265	// </editor-fold>
duke@1	1266
duke@1	1267	// <editor-fold defaultstate="collapsed" desc="notSoftSubtype">
duke@1	1268	/**
duke@1	1269	* This relation answers the question: is impossible that
duke@1	1270	* something of type `t' can be a subtype of `s'? This is
duke@1	1271	* different from the question "is `t' not a subtype of `s'?"
duke@1	1272	* when type variables are involved: Integer is not a subtype of T
duke@1	1273	* where <T extends Number> but it is not true that Integer cannot
duke@1	1274	* possibly be a subtype of T.
duke@1	1275	*/
duke@1	1276	public boolean notSoftSubtype(Type t, Type s) {
duke@1	1277	if (t == s) return false;
duke@1	1278	if (t.tag == TYPEVAR) {
duke@1	1279	TypeVar tv = (TypeVar) t;
duke@1	1280	return !isCastable(tv.bound,
mcimadamore@640	1281	relaxBound(s),
duke@1	1282	Warner.noWarnings);
duke@1	1283	}
duke@1	1284	if (s.tag != WILDCARD)
duke@1	1285	s = upperBound(s);
mcimadamore@640	1286
mcimadamore@640	1287	return !isSubtype(t, relaxBound(s));
mcimadamore@640	1288	}
mcimadamore@640	1289
mcimadamore@640	1290	private Type relaxBound(Type t) {
mcimadamore@640	1291	if (t.tag == TYPEVAR) {
mcimadamore@640	1292	while (t.tag == TYPEVAR)
mcimadamore@640	1293	t = t.getUpperBound();
mcimadamore@640	1294	t = rewriteQuantifiers(t, true, true);
mcimadamore@640	1295	}
mcimadamore@640	1296	return t;
duke@1	1297	}
duke@1	1298	// </editor-fold>
duke@1	1299
duke@1	1300	// <editor-fold defaultstate="collapsed" desc="isReifiable">
duke@1	1301	public boolean isReifiable(Type t) {
duke@1	1302	return isReifiable.visit(t);
duke@1	1303	}
duke@1	1304	// where
duke@1	1305	private UnaryVisitor<Boolean> isReifiable = new UnaryVisitor<Boolean>() {
duke@1	1306
duke@1	1307	public Boolean visitType(Type t, Void ignored) {
duke@1	1308	return true;
duke@1	1309	}
duke@1	1310
duke@1	1311	@Override
duke@1	1312	public Boolean visitClassType(ClassType t, Void ignored) {
mcimadamore@356	1313	if (t.isCompound())
mcimadamore@356	1314	return false;
mcimadamore@356	1315	else {
mcimadamore@356	1316	if (!t.isParameterized())
mcimadamore@356	1317	return true;
mcimadamore@356	1318
mcimadamore@356	1319	for (Type param : t.allparams()) {
mcimadamore@356	1320	if (!param.isUnbound())
mcimadamore@356	1321	return false;
mcimadamore@356	1322	}
duke@1	1323	return true;
duke@1	1324	}
duke@1	1325	}
duke@1	1326
duke@1	1327	@Override
duke@1	1328	public Boolean visitArrayType(ArrayType t, Void ignored) {
duke@1	1329	return visit(t.elemtype);
duke@1	1330	}
duke@1	1331
duke@1	1332	@Override
duke@1	1333	public Boolean visitTypeVar(TypeVar t, Void ignored) {
duke@1	1334	return false;
duke@1	1335	}
duke@1	1336	};
duke@1	1337	// </editor-fold>
duke@1	1338
duke@1	1339	// <editor-fold defaultstate="collapsed" desc="Array Utils">
duke@1	1340	public boolean isArray(Type t) {
duke@1	1341	while (t.tag == WILDCARD)
duke@1	1342	t = upperBound(t);
duke@1	1343	return t.tag == ARRAY;
duke@1	1344	}
duke@1	1345
duke@1	1346	/**
duke@1	1347	* The element type of an array.
duke@1	1348	*/
duke@1	1349	public Type elemtype(Type t) {
duke@1	1350	switch (t.tag) {
duke@1	1351	case WILDCARD:
duke@1	1352	return elemtype(upperBound(t));
duke@1	1353	case ARRAY:
duke@1	1354	return ((ArrayType)t).elemtype;
duke@1	1355	case FORALL:
duke@1	1356	return elemtype(((ForAll)t).qtype);
duke@1	1357	case ERROR:
duke@1	1358	return t;
duke@1	1359	default:
duke@1	1360	return null;
duke@1	1361	}
duke@1	1362	}
duke@1	1363
mcimadamore@787	1364	public Type elemtypeOrType(Type t) {
mcimadamore@787	1365	Type elemtype = elemtype(t);
mcimadamore@787	1366	return elemtype != null ?
mcimadamore@787	1367	elemtype :
mcimadamore@787	1368	t;
mcimadamore@787	1369	}
mcimadamore@787	1370
duke@1	1371	/**
duke@1	1372	* Mapping to take element type of an arraytype
duke@1	1373	*/
duke@1	1374	private Mapping elemTypeFun = new Mapping ("elemTypeFun") {
duke@1	1375	public Type apply(Type t) { return elemtype(t); }
duke@1	1376	};
duke@1	1377
duke@1	1378	/**
duke@1	1379	* The number of dimensions of an array type.
duke@1	1380	*/
duke@1	1381	public int dimensions(Type t) {
duke@1	1382	int result = 0;
duke@1	1383	while (t.tag == ARRAY) {
duke@1	1384	result++;
duke@1	1385	t = elemtype(t);
duke@1	1386	}
duke@1	1387	return result;
duke@1	1388	}
duke@1	1389	// </editor-fold>
duke@1	1390
duke@1	1391	// <editor-fold defaultstate="collapsed" desc="asSuper">
duke@1	1392	/**
duke@1	1393	* Return the (most specific) base type of t that starts with the
duke@1	1394	* given symbol. If none exists, return null.
duke@1	1395	*
duke@1	1396	* @param t a type
duke@1	1397	* @param sym a symbol
duke@1	1398	*/
duke@1	1399	public Type asSuper(Type t, Symbol sym) {
duke@1	1400	return asSuper.visit(t, sym);
duke@1	1401	}
duke@1	1402	// where
duke@1	1403	private SimpleVisitor<Type,Symbol> asSuper = new SimpleVisitor<Type,Symbol>() {
duke@1	1404
duke@1	1405	public Type visitType(Type t, Symbol sym) {
duke@1	1406	return null;
duke@1	1407	}
duke@1	1408
duke@1	1409	@Override
duke@1	1410	public Type visitClassType(ClassType t, Symbol sym) {
duke@1	1411	if (t.tsym == sym)
duke@1	1412	return t;
duke@1	1413
duke@1	1414	Type st = supertype(t);
mcimadamore@19	1415	if (st.tag == CLASS || st.tag == TYPEVAR || st.tag == ERROR) {
duke@1	1416	Type x = asSuper(st, sym);
duke@1	1417	if (x != null)
duke@1	1418	return x;
duke@1	1419	}
duke@1	1420	if ((sym.flags() & INTERFACE) != 0) {
duke@1	1421	for (List<Type> l = interfaces(t); l.nonEmpty(); l = l.tail) {
duke@1	1422	Type x = asSuper(l.head, sym);
duke@1	1423	if (x != null)
duke@1	1424	return x;
duke@1	1425	}
duke@1	1426	}
duke@1	1427	return null;
duke@1	1428	}
duke@1	1429
duke@1	1430	@Override
duke@1	1431	public Type visitArrayType(ArrayType t, Symbol sym) {
duke@1	1432	return isSubtype(t, sym.type) ? sym.type : null;
duke@1	1433	}
duke@1	1434
duke@1	1435	@Override
duke@1	1436	public Type visitTypeVar(TypeVar t, Symbol sym) {
mcimadamore@19	1437	if (t.tsym == sym)
mcimadamore@19	1438	return t;
mcimadamore@19	1439	else
mcimadamore@19	1440	return asSuper(t.bound, sym);
duke@1	1441	}
duke@1	1442
duke@1	1443	@Override
duke@1	1444	public Type visitErrorType(ErrorType t, Symbol sym) {
duke@1	1445	return t;
duke@1	1446	}
duke@1	1447	};
duke@1	1448
duke@1	1449	/**
duke@1	1450	* Return the base type of t or any of its outer types that starts
duke@1	1451	* with the given symbol. If none exists, return null.
duke@1	1452	*
duke@1	1453	* @param t a type
duke@1	1454	* @param sym a symbol
duke@1	1455	*/
duke@1	1456	public Type asOuterSuper(Type t, Symbol sym) {
duke@1	1457	switch (t.tag) {
duke@1	1458	case CLASS:
duke@1	1459	do {
duke@1	1460	Type s = asSuper(t, sym);
duke@1	1461	if (s != null) return s;
duke@1	1462	t = t.getEnclosingType();
duke@1	1463	} while (t.tag == CLASS);
duke@1	1464	return null;
duke@1	1465	case ARRAY:
duke@1	1466	return isSubtype(t, sym.type) ? sym.type : null;
duke@1	1467	case TYPEVAR:
duke@1	1468	return asSuper(t, sym);
duke@1	1469	case ERROR:
duke@1	1470	return t;
duke@1	1471	default:
duke@1	1472	return null;
duke@1	1473	}
duke@1	1474	}
duke@1	1475
duke@1	1476	/**
duke@1	1477	* Return the base type of t or any of its enclosing types that
duke@1	1478	* starts with the given symbol. If none exists, return null.
duke@1	1479	*
duke@1	1480	* @param t a type
duke@1	1481	* @param sym a symbol
duke@1	1482	*/
duke@1	1483	public Type asEnclosingSuper(Type t, Symbol sym) {
duke@1	1484	switch (t.tag) {
duke@1	1485	case CLASS:
duke@1	1486	do {
duke@1	1487	Type s = asSuper(t, sym);
duke@1	1488	if (s != null) return s;
duke@1	1489	Type outer = t.getEnclosingType();
duke@1	1490	t = (outer.tag == CLASS) ? outer :
duke@1	1491	(t.tsym.owner.enclClass() != null) ? t.tsym.owner.enclClass().type :
duke@1	1492	Type.noType;
duke@1	1493	} while (t.tag == CLASS);
duke@1	1494	return null;
duke@1	1495	case ARRAY:
duke@1	1496	return isSubtype(t, sym.type) ? sym.type : null;
duke@1	1497	case TYPEVAR:
duke@1	1498	return asSuper(t, sym);
duke@1	1499	case ERROR:
duke@1	1500	return t;
duke@1	1501	default:
duke@1	1502	return null;
duke@1	1503	}
duke@1	1504	}
duke@1	1505	// </editor-fold>
duke@1	1506
duke@1	1507	// <editor-fold defaultstate="collapsed" desc="memberType">
duke@1	1508	/**
duke@1	1509	* The type of given symbol, seen as a member of t.
duke@1	1510	*
duke@1	1511	* @param t a type
duke@1	1512	* @param sym a symbol
duke@1	1513	*/
duke@1	1514	public Type memberType(Type t, Symbol sym) {
duke@1	1515	return (sym.flags() & STATIC) != 0
duke@1	1516	? sym.type
duke@1	1517	: memberType.visit(t, sym);
mcimadamore@341	1518	}
duke@1	1519	// where
duke@1	1520	private SimpleVisitor<Type,Symbol> memberType = new SimpleVisitor<Type,Symbol>() {
duke@1	1521
duke@1	1522	public Type visitType(Type t, Symbol sym) {
duke@1	1523	return sym.type;
duke@1	1524	}
duke@1	1525
duke@1	1526	@Override
duke@1	1527	public Type visitWildcardType(WildcardType t, Symbol sym) {
duke@1	1528	return memberType(upperBound(t), sym);
duke@1	1529	}
duke@1	1530
duke@1	1531	@Override
duke@1	1532	public Type visitClassType(ClassType t, Symbol sym) {
duke@1	1533	Symbol owner = sym.owner;
duke@1	1534	long flags = sym.flags();
duke@1	1535	if (((flags & STATIC) == 0) && owner.type.isParameterized()) {
duke@1	1536	Type base = asOuterSuper(t, owner);
mcimadamore@134	1537	//if t is an intersection type T = CT & I1 & I2 ... & In
mcimadamore@134	1538	//its supertypes CT, I1, ... In might contain wildcards
mcimadamore@134	1539	//so we need to go through capture conversion
mcimadamore@134	1540	base = t.isCompound() ? capture(base) : base;
duke@1	1541	if (base != null) {
duke@1	1542	List<Type> ownerParams = owner.type.allparams();
duke@1	1543	List<Type> baseParams = base.allparams();
duke@1	1544	if (ownerParams.nonEmpty()) {
duke@1	1545	if (baseParams.isEmpty()) {
duke@1	1546	// then base is a raw type
duke@1	1547	return erasure(sym.type);
duke@1	1548	} else {
duke@1	1549	return subst(sym.type, ownerParams, baseParams);
duke@1	1550	}
duke@1	1551	}
duke@1	1552	}
duke@1	1553	}
duke@1	1554	return sym.type;
duke@1	1555	}
duke@1	1556
duke@1	1557	@Override
duke@1	1558	public Type visitTypeVar(TypeVar t, Symbol sym) {
duke@1	1559	return memberType(t.bound, sym);
duke@1	1560	}
duke@1	1561
duke@1	1562	@Override
duke@1	1563	public Type visitErrorType(ErrorType t, Symbol sym) {
duke@1	1564	return t;
duke@1	1565	}
duke@1	1566	};
duke@1	1567	// </editor-fold>
duke@1	1568
duke@1	1569	// <editor-fold defaultstate="collapsed" desc="isAssignable">
duke@1	1570	public boolean isAssignable(Type t, Type s) {
duke@1	1571	return isAssignable(t, s, Warner.noWarnings);
duke@1	1572	}
duke@1	1573
duke@1	1574	/**
duke@1	1575	* Is t assignable to s?<br>
duke@1	1576	* Equivalent to subtype except for constant values and raw
duke@1	1577	* types.<br>
duke@1	1578	* (not defined for Method and ForAll types)
duke@1	1579	*/
duke@1	1580	public boolean isAssignable(Type t, Type s, Warner warn) {
duke@1	1581	if (t.tag == ERROR)
duke@1	1582	return true;
duke@1	1583	if (t.tag <= INT && t.constValue() != null) {
duke@1	1584	int value = ((Number)t.constValue()).intValue();
duke@1	1585	switch (s.tag) {
duke@1	1586	case BYTE:
duke@1	1587	if (Byte.MIN_VALUE <= value && value <= Byte.MAX_VALUE)
duke@1	1588	return true;
duke@1	1589	break;
duke@1	1590	case CHAR:
duke@1	1591	if (Character.MIN_VALUE <= value && value <= Character.MAX_VALUE)
duke@1	1592	return true;
duke@1	1593	break;
duke@1	1594	case SHORT:
duke@1	1595	if (Short.MIN_VALUE <= value && value <= Short.MAX_VALUE)
duke@1	1596	return true;
duke@1	1597	break;
duke@1	1598	case INT:
duke@1	1599	return true;
duke@1	1600	case CLASS:
duke@1	1601	switch (unboxedType(s).tag) {
duke@1	1602	case BYTE:
duke@1	1603	case CHAR:
duke@1	1604	case SHORT:
duke@1	1605	return isAssignable(t, unboxedType(s), warn);
duke@1	1606	}
duke@1	1607	break;
duke@1	1608	}
duke@1	1609	}
duke@1	1610	return isConvertible(t, s, warn);
duke@1	1611	}
duke@1	1612	// </editor-fold>
duke@1	1613
duke@1	1614	// <editor-fold defaultstate="collapsed" desc="erasure">
duke@1	1615	/**
duke@1	1616	* The erasure of t {@code |t|} -- the type that results when all
duke@1	1617	* type parameters in t are deleted.
duke@1	1618	*/
duke@1	1619	public Type erasure(Type t) {
mcimadamore@30	1620	return erasure(t, false);
mcimadamore@30	1621	}
mcimadamore@30	1622	//where
mcimadamore@30	1623	private Type erasure(Type t, boolean recurse) {
duke@1	1624	if (t.tag <= lastBaseTag)
duke@1	1625	return t; /* fast special case */
duke@1	1626	else
mcimadamore@30	1627	return erasure.visit(t, recurse);
mcimadamore@341	1628	}
duke@1	1629	// where
mcimadamore@30	1630	private SimpleVisitor<Type, Boolean> erasure = new SimpleVisitor<Type, Boolean>() {
mcimadamore@30	1631	public Type visitType(Type t, Boolean recurse) {
duke@1	1632	if (t.tag <= lastBaseTag)
duke@1	1633	return t; /*fast special case*/
duke@1	1634	else
mcimadamore@30	1635	return t.map(recurse ? erasureRecFun : erasureFun);
duke@1	1636	}
duke@1	1637
duke@1	1638	@Override
mcimadamore@30	1639	public Type visitWildcardType(WildcardType t, Boolean recurse) {
mcimadamore@30	1640	return erasure(upperBound(t), recurse);
duke@1	1641	}
duke@1	1642
duke@1	1643	@Override
mcimadamore@30	1644	public Type visitClassType(ClassType t, Boolean recurse) {
mcimadamore@30	1645	Type erased = t.tsym.erasure(Types.this);
mcimadamore@30	1646	if (recurse) {
mcimadamore@30	1647	erased = new ErasedClassType(erased.getEnclosingType(),erased.tsym);
mcimadamore@30	1648	}
mcimadamore@30	1649	return erased;
duke@1	1650	}
duke@1	1651
duke@1	1652	@Override
mcimadamore@30	1653	public Type visitTypeVar(TypeVar t, Boolean recurse) {
mcimadamore@30	1654	return erasure(t.bound, recurse);
duke@1	1655	}
duke@1	1656
duke@1	1657	@Override
mcimadamore@30	1658	public Type visitErrorType(ErrorType t, Boolean recurse) {
duke@1	1659	return t;
duke@1	1660	}
duke@1	1661	};
mcimadamore@30	1662
duke@1	1663	private Mapping erasureFun = new Mapping ("erasure") {
duke@1	1664	public Type apply(Type t) { return erasure(t); }
duke@1	1665	};
duke@1	1666
mcimadamore@30	1667	private Mapping erasureRecFun = new Mapping ("erasureRecursive") {
mcimadamore@30	1668	public Type apply(Type t) { return erasureRecursive(t); }
mcimadamore@30	1669	};
mcimadamore@30	1670
duke@1	1671	public List<Type> erasure(List<Type> ts) {
duke@1	1672	return Type.map(ts, erasureFun);
duke@1	1673	}
mcimadamore@30	1674
mcimadamore@30	1675	public Type erasureRecursive(Type t) {
mcimadamore@30	1676	return erasure(t, true);
mcimadamore@30	1677	}
mcimadamore@30	1678
mcimadamore@30	1679	public List<Type> erasureRecursive(List<Type> ts) {
mcimadamore@30	1680	return Type.map(ts, erasureRecFun);
mcimadamore@30	1681	}
duke@1	1682	// </editor-fold>
duke@1	1683
duke@1	1684	// <editor-fold defaultstate="collapsed" desc="makeCompoundType">
duke@1	1685	/**
duke@1	1686	* Make a compound type from non-empty list of types
duke@1	1687	*
duke@1	1688	* @param bounds the types from which the compound type is formed
duke@1	1689	* @param supertype is objectType if all bounds are interfaces,
duke@1	1690	* null otherwise.
duke@1	1691	*/
duke@1	1692	public Type makeCompoundType(List<Type> bounds,
duke@1	1693	Type supertype) {
duke@1	1694	ClassSymbol bc =
duke@1	1695	new ClassSymbol(ABSTRACT|PUBLIC|SYNTHETIC|COMPOUND|ACYCLIC,
duke@1	1696	Type.moreInfo
duke@1	1697	? names.fromString(bounds.toString())
duke@1	1698	: names.empty,
duke@1	1699	syms.noSymbol);
duke@1	1700	if (bounds.head.tag == TYPEVAR)
duke@1	1701	// error condition, recover
mcimadamore@121	1702	bc.erasure_field = syms.objectType;
mcimadamore@121	1703	else
mcimadamore@121	1704	bc.erasure_field = erasure(bounds.head);
mcimadamore@121	1705	bc.members_field = new Scope(bc);
duke@1	1706	ClassType bt = (ClassType)bc.type;
duke@1	1707	bt.allparams_field = List.nil();
duke@1	1708	if (supertype != null) {
duke@1	1709	bt.supertype_field = supertype;
duke@1	1710	bt.interfaces_field = bounds;
duke@1	1711	} else {
duke@1	1712	bt.supertype_field = bounds.head;
duke@1	1713	bt.interfaces_field = bounds.tail;
duke@1	1714	}
jjg@816	1715	Assert.check(bt.supertype_field.tsym.completer != null
jjg@816	1716	|| !bt.supertype_field.isInterface(),
jjg@816	1717	bt.supertype_field);
duke@1	1718	return bt;
duke@1	1719	}
duke@1	1720
duke@1	1721	/**
duke@1	1722	* Same as {@link #makeCompoundType(List,Type)}, except that the
duke@1	1723	* second parameter is computed directly. Note that this might
duke@1	1724	* cause a symbol completion. Hence, this version of
duke@1	1725	* makeCompoundType may not be called during a classfile read.
duke@1	1726	*/
duke@1	1727	public Type makeCompoundType(List<Type> bounds) {
duke@1	1728	Type supertype = (bounds.head.tsym.flags() & INTERFACE) != 0 ?
duke@1	1729	supertype(bounds.head) : null;
duke@1	1730	return makeCompoundType(bounds, supertype);
duke@1	1731	}
duke@1	1732
duke@1	1733	/**
duke@1	1734	* A convenience wrapper for {@link #makeCompoundType(List)}; the
duke@1	1735	* arguments are converted to a list and passed to the other
duke@1	1736	* method. Note that this might cause a symbol completion.
duke@1	1737	* Hence, this version of makeCompoundType may not be called
duke@1	1738	* during a classfile read.
duke@1	1739	*/
duke@1	1740	public Type makeCompoundType(Type bound1, Type bound2) {
duke@1	1741	return makeCompoundType(List.of(bound1, bound2));
duke@1	1742	}
duke@1	1743	// </editor-fold>
duke@1	1744
duke@1	1745	// <editor-fold defaultstate="collapsed" desc="supertype">
duke@1	1746	public Type supertype(Type t) {
duke@1	1747	return supertype.visit(t);
duke@1	1748	}
duke@1	1749	// where
duke@1	1750	private UnaryVisitor<Type> supertype = new UnaryVisitor<Type>() {
duke@1	1751
duke@1	1752	public Type visitType(Type t, Void ignored) {
duke@1	1753	// A note on wildcards: there is no good way to
duke@1	1754	// determine a supertype for a super bounded wildcard.
duke@1	1755	return null;
duke@1	1756	}
duke@1	1757
duke@1	1758	@Override
duke@1	1759	public Type visitClassType(ClassType t, Void ignored) {
duke@1	1760	if (t.supertype_field == null) {
duke@1	1761	Type supertype = ((ClassSymbol)t.tsym).getSuperclass();
duke@1	1762	// An interface has no superclass; its supertype is Object.
duke@1	1763	if (t.isInterface())
duke@1	1764	supertype = ((ClassType)t.tsym.type).supertype_field;
duke@1	1765	if (t.supertype_field == null) {
duke@1	1766	List<Type> actuals = classBound(t).allparams();
duke@1	1767	List<Type> formals = t.tsym.type.allparams();
mcimadamore@30	1768	if (t.hasErasedSupertypes()) {
mcimadamore@30	1769	t.supertype_field = erasureRecursive(supertype);
mcimadamore@30	1770	} else if (formals.nonEmpty()) {
duke@1	1771	t.supertype_field = subst(supertype, formals, actuals);
duke@1	1772	}
mcimadamore@30	1773	else {
mcimadamore@30	1774	t.supertype_field = supertype;
mcimadamore@30	1775	}
duke@1	1776	}
duke@1	1777	}
duke@1	1778	return t.supertype_field;
duke@1	1779	}
duke@1	1780
duke@1	1781	/**
duke@1	1782	* The supertype is always a class type. If the type
duke@1	1783	* variable's bounds start with a class type, this is also
duke@1	1784	* the supertype. Otherwise, the supertype is
duke@1	1785	* java.lang.Object.
duke@1	1786	*/
duke@1	1787	@Override
duke@1	1788	public Type visitTypeVar(TypeVar t, Void ignored) {
duke@1	1789	if (t.bound.tag == TYPEVAR ||
duke@1	1790	(!t.bound.isCompound() && !t.bound.isInterface())) {
duke@1	1791	return t.bound;
duke@1	1792	} else {
duke@1	1793	return supertype(t.bound);
duke@1	1794	}
duke@1	1795	}
duke@1	1796
duke@1	1797	@Override
duke@1	1798	public Type visitArrayType(ArrayType t, Void ignored) {
duke@1	1799	if (t.elemtype.isPrimitive() || isSameType(t.elemtype, syms.objectType))
duke@1	1800	return arraySuperType();
duke@1	1801	else
duke@1	1802	return new ArrayType(supertype(t.elemtype), t.tsym);
duke@1	1803	}
duke@1	1804
duke@1	1805	@Override
duke@1	1806	public Type visitErrorType(ErrorType t, Void ignored) {
duke@1	1807	return t;
duke@1	1808	}
duke@1	1809	};
duke@1	1810	// </editor-fold>
duke@1	1811
duke@1	1812	// <editor-fold defaultstate="collapsed" desc="interfaces">
duke@1	1813	/**
duke@1	1814	* Return the interfaces implemented by this class.
duke@1	1815	*/
duke@1	1816	public List<Type> interfaces(Type t) {
duke@1	1817	return interfaces.visit(t);
duke@1	1818	}
duke@1	1819	// where
duke@1	1820	private UnaryVisitor<List<Type>> interfaces = new UnaryVisitor<List<Type>>() {
duke@1	1821
duke@1	1822	public List<Type> visitType(Type t, Void ignored) {
duke@1	1823	return List.nil();
duke@1	1824	}
duke@1	1825
duke@1	1826	@Override
duke@1	1827	public List<Type> visitClassType(ClassType t, Void ignored) {
duke@1	1828	if (t.interfaces_field == null) {
duke@1	1829	List<Type> interfaces = ((ClassSymbol)t.tsym).getInterfaces();
duke@1	1830	if (t.interfaces_field == null) {
duke@1	1831	// If t.interfaces_field is null, then t must
duke@1	1832	// be a parameterized type (not to be confused
duke@1	1833	// with a generic type declaration).
duke@1	1834	// Terminology:
duke@1	1835	// Parameterized type: List<String>
duke@1	1836	// Generic type declaration: class List<E> { ... }
duke@1	1837	// So t corresponds to List<String> and
duke@1	1838	// t.tsym.type corresponds to List<E>.
duke@1	1839	// The reason t must be parameterized type is
duke@1	1840	// that completion will happen as a side
duke@1	1841	// effect of calling
duke@1	1842	// ClassSymbol.getInterfaces. Since
duke@1	1843	// t.interfaces_field is null after
duke@1	1844	// completion, we can assume that t is not the
duke@1	1845	// type of a class/interface declaration.
jjg@816	1846	Assert.check(t != t.tsym.type, t);
duke@1	1847	List<Type> actuals = t.allparams();
duke@1	1848	List<Type> formals = t.tsym.type.allparams();
mcimadamore@30	1849	if (t.hasErasedSupertypes()) {
mcimadamore@30	1850	t.interfaces_field = erasureRecursive(interfaces);
mcimadamore@30	1851	} else if (formals.nonEmpty()) {
duke@1	1852	t.interfaces_field =
duke@1	1853	upperBounds(subst(interfaces, formals, actuals));
duke@1	1854	}
mcimadamore@30	1855	else {
mcimadamore@30	1856	t.interfaces_field = interfaces;
mcimadamore@30	1857	}
duke@1	1858	}
duke@1	1859	}
duke@1	1860	return t.interfaces_field;
duke@1	1861	}
duke@1	1862
duke@1	1863	@Override
duke@1	1864	public List<Type> visitTypeVar(TypeVar t, Void ignored) {
duke@1	1865	if (t.bound.isCompound())
duke@1	1866	return interfaces(t.bound);
duke@1	1867
duke@1	1868	if (t.bound.isInterface())
duke@1	1869	return List.of(t.bound);
duke@1	1870
duke@1	1871	return List.nil();
duke@1	1872	}
duke@1	1873	};
duke@1	1874	// </editor-fold>
duke@1	1875
duke@1	1876	// <editor-fold defaultstate="collapsed" desc="isDerivedRaw">
duke@1	1877	Map<Type,Boolean> isDerivedRawCache = new HashMap<Type,Boolean>();
duke@1	1878
duke@1	1879	public boolean isDerivedRaw(Type t) {
duke@1	1880	Boolean result = isDerivedRawCache.get(t);
duke@1	1881	if (result == null) {
duke@1	1882	result = isDerivedRawInternal(t);
duke@1	1883	isDerivedRawCache.put(t, result);
duke@1	1884	}
duke@1	1885	return result;
duke@1	1886	}
duke@1	1887
duke@1	1888	public boolean isDerivedRawInternal(Type t) {
duke@1	1889	if (t.isErroneous())
duke@1	1890	return false;
duke@1	1891	return
duke@1	1892	t.isRaw() ||
duke@1	1893	supertype(t) != null && isDerivedRaw(supertype(t)) ||
duke@1	1894	isDerivedRaw(interfaces(t));
duke@1	1895	}
duke@1	1896
duke@1	1897	public boolean isDerivedRaw(List<Type> ts) {
duke@1	1898	List<Type> l = ts;
duke@1	1899	while (l.nonEmpty() && !isDerivedRaw(l.head)) l = l.tail;
duke@1	1900	return l.nonEmpty();
duke@1	1901	}
duke@1	1902	// </editor-fold>
duke@1	1903
duke@1	1904	// <editor-fold defaultstate="collapsed" desc="setBounds">
duke@1	1905	/**
duke@1	1906	* Set the bounds field of the given type variable to reflect a
duke@1	1907	* (possibly multiple) list of bounds.
duke@1	1908	* @param t a type variable
duke@1	1909	* @param bounds the bounds, must be nonempty
duke@1	1910	* @param supertype is objectType if all bounds are interfaces,
duke@1	1911	* null otherwise.
duke@1	1912	*/
duke@1	1913	public void setBounds(TypeVar t, List<Type> bounds, Type supertype) {
duke@1	1914	if (bounds.tail.isEmpty())
duke@1	1915	t.bound = bounds.head;
duke@1	1916	else
duke@1	1917	t.bound = makeCompoundType(bounds, supertype);
duke@1	1918	t.rank_field = -1;
duke@1	1919	}
duke@1	1920
duke@1	1921	/**
duke@1	1922	* Same as {@link #setBounds(Type.TypeVar,List,Type)}, except that
mcimadamore@563	1923	* third parameter is computed directly, as follows: if all
mcimadamore@563	1924	* all bounds are interface types, the computed supertype is Object,
mcimadamore@563	1925	* otherwise the supertype is simply left null (in this case, the supertype
mcimadamore@563	1926	* is assumed to be the head of the bound list passed as second argument).
mcimadamore@563	1927	* Note that this check might cause a symbol completion. Hence, this version of
duke@1	1928	* setBounds may not be called during a classfile read.
duke@1	1929	*/
duke@1	1930	public void setBounds(TypeVar t, List<Type> bounds) {
duke@1	1931	Type supertype = (bounds.head.tsym.flags() & INTERFACE) != 0 ?
mcimadamore@563	1932	syms.objectType : null;
duke@1	1933	setBounds(t, bounds, supertype);
duke@1	1934	t.rank_field = -1;
duke@1	1935	}
duke@1	1936	// </editor-fold>
duke@1	1937
duke@1	1938	// <editor-fold defaultstate="collapsed" desc="getBounds">
duke@1	1939	/**
duke@1	1940	* Return list of bounds of the given type variable.
duke@1	1941	*/
duke@1	1942	public List<Type> getBounds(TypeVar t) {
duke@1	1943	if (t.bound.isErroneous() || !t.bound.isCompound())
duke@1	1944	return List.of(t.bound);
duke@1	1945	else if ((erasure(t).tsym.flags() & INTERFACE) == 0)
duke@1	1946	return interfaces(t).prepend(supertype(t));
duke@1	1947	else
duke@1	1948	// No superclass was given in bounds.
duke@1	1949	// In this case, supertype is Object, erasure is first interface.
duke@1	1950	return interfaces(t);
duke@1	1951	}
duke@1	1952	// </editor-fold>
duke@1	1953
duke@1	1954	// <editor-fold defaultstate="collapsed" desc="classBound">
duke@1	1955	/**
duke@1	1956	* If the given type is a (possibly selected) type variable,
duke@1	1957	* return the bounding class of this type, otherwise return the
duke@1	1958	* type itself.
duke@1	1959	*/
duke@1	1960	public Type classBound(Type t) {
duke@1	1961	return classBound.visit(t);
duke@1	1962	}
duke@1	1963	// where
duke@1	1964	private UnaryVisitor<Type> classBound = new UnaryVisitor<Type>() {
duke@1	1965
duke@1	1966	public Type visitType(Type t, Void ignored) {
duke@1	1967	return t;
duke@1	1968	}
duke@1	1969
duke@1	1970	@Override
duke@1	1971	public Type visitClassType(ClassType t, Void ignored) {
duke@1	1972	Type outer1 = classBound(t.getEnclosingType());
duke@1	1973	if (outer1 != t.getEnclosingType())
duke@1	1974	return new ClassType(outer1, t.getTypeArguments(), t.tsym);
duke@1	1975	else
duke@1	1976	return t;
duke@1	1977	}
duke@1	1978
duke@1	1979	@Override
duke@1	1980	public Type visitTypeVar(TypeVar t, Void ignored) {
duke@1	1981	return classBound(supertype(t));
duke@1	1982	}
duke@1	1983
duke@1	1984	@Override
duke@1	1985	public Type visitErrorType(ErrorType t, Void ignored) {
duke@1	1986	return t;
duke@1	1987	}
duke@1	1988	};
duke@1	1989	// </editor-fold>
duke@1	1990
duke@1	1991	// <editor-fold defaultstate="collapsed" desc="sub signature / override equivalence">
duke@1	1992	/**
duke@1	1993	* Returns true iff the first signature is a <em>sub
duke@1	1994	* signature</em> of the other. This is <b>not</b> an equivalence
duke@1	1995	* relation.
duke@1	1996	*
jjh@972	1997	* @jls section 8.4.2.
duke@1	1998	* @see #overrideEquivalent(Type t, Type s)
duke@1	1999	* @param t first signature (possibly raw).
duke@1	2000	* @param s second signature (could be subjected to erasure).
duke@1	2001	* @return true if t is a sub signature of s.
duke@1	2002	*/
duke@1	2003	public boolean isSubSignature(Type t, Type s) {
mcimadamore@907	2004	return isSubSignature(t, s, true);
mcimadamore@907	2005	}
mcimadamore@907	2006
mcimadamore@907	2007	public boolean isSubSignature(Type t, Type s, boolean strict) {
mcimadamore@907	2008	return hasSameArgs(t, s, strict) || hasSameArgs(t, erasure(s), strict);
duke@1	2009	}
duke@1	2010
duke@1	2011	/**
duke@1	2012	* Returns true iff these signatures are related by <em>override
duke@1	2013	* equivalence</em>. This is the natural extension of
duke@1	2014	* isSubSignature to an equivalence relation.
duke@1	2015	*
jjh@972	2016	* @jls section 8.4.2.
duke@1	2017	* @see #isSubSignature(Type t, Type s)
duke@1	2018	* @param t a signature (possible raw, could be subjected to
duke@1	2019	* erasure).
duke@1	2020	* @param s a signature (possible raw, could be subjected to
duke@1	2021	* erasure).
duke@1	2022	* @return true if either argument is a sub signature of the other.
duke@1	2023	*/
duke@1	2024	public boolean overrideEquivalent(Type t, Type s) {
duke@1	2025	return hasSameArgs(t, s) ||
duke@1	2026	hasSameArgs(t, erasure(s)) || hasSameArgs(erasure(t), s);
duke@1	2027	}
duke@1	2028
mcimadamore@673	2029	// <editor-fold defaultstate="collapsed" desc="Determining method implementation in given site">
mcimadamore@673	2030	class ImplementationCache {
mcimadamore@673	2031
mcimadamore@673	2032	private WeakHashMap<MethodSymbol, SoftReference<Map<TypeSymbol, Entry>>> _map =
mcimadamore@673	2033	new WeakHashMap<MethodSymbol, SoftReference<Map<TypeSymbol, Entry>>>();
mcimadamore@673	2034
mcimadamore@673	2035	class Entry {
mcimadamore@673	2036	final MethodSymbol cachedImpl;
mcimadamore@673	2037	final Filter<Symbol> implFilter;
mcimadamore@673	2038	final boolean checkResult;
mcimadamore@877	2039	final int prevMark;
mcimadamore@673	2040
mcimadamore@673	2041	public Entry(MethodSymbol cachedImpl,
mcimadamore@673	2042	Filter<Symbol> scopeFilter,
mcimadamore@877	2043	boolean checkResult,
mcimadamore@877	2044	int prevMark) {
mcimadamore@673	2045	this.cachedImpl = cachedImpl;
mcimadamore@673	2046	this.implFilter = scopeFilter;
mcimadamore@673	2047	this.checkResult = checkResult;
mcimadamore@877	2048	this.prevMark = prevMark;
mcimadamore@673	2049	}
mcimadamore@673	2050
mcimadamore@877	2051	boolean matches(Filter<Symbol> scopeFilter, boolean checkResult, int mark) {
mcimadamore@673	2052	return this.implFilter == scopeFilter &&
mcimadamore@877	2053	this.checkResult == checkResult &&
mcimadamore@877	2054	this.prevMark == mark;
mcimadamore@673	2055	}
mcimadamore@341	2056	}
mcimadamore@673	2057
mcimadamore@858	2058	MethodSymbol get(MethodSymbol ms, TypeSymbol origin, boolean checkResult, Filter<Symbol> implFilter) {
mcimadamore@673	2059	SoftReference<Map<TypeSymbol, Entry>> ref_cache = _map.get(ms);
mcimadamore@673	2060	Map<TypeSymbol, Entry> cache = ref_cache != null ? ref_cache.get() : null;
mcimadamore@673	2061	if (cache == null) {
mcimadamore@673	2062	cache = new HashMap<TypeSymbol, Entry>();
mcimadamore@673	2063	_map.put(ms, new SoftReference<Map<TypeSymbol, Entry>>(cache));
mcimadamore@673	2064	}
mcimadamore@673	2065	Entry e = cache.get(origin);
mcimadamore@1015	2066	CompoundScope members = membersClosure(origin.type, true);
mcimadamore@673	2067	if (e == null ||
mcimadamore@877	2068	!e.matches(implFilter, checkResult, members.getMark())) {
mcimadamore@877	2069	MethodSymbol impl = implementationInternal(ms, origin, checkResult, implFilter);
mcimadamore@877	2070	cache.put(origin, new Entry(impl, implFilter, checkResult, members.getMark()));
mcimadamore@673	2071	return impl;
mcimadamore@673	2072	}
mcimadamore@673	2073	else {
mcimadamore@673	2074	return e.cachedImpl;
mcimadamore@673	2075	}
mcimadamore@673	2076	}
mcimadamore@673	2077
mcimadamore@877	2078	private MethodSymbol implementationInternal(MethodSymbol ms, TypeSymbol origin, boolean checkResult, Filter<Symbol> implFilter) {
mcimadamore@877	2079	for (Type t = origin.type; t.tag == CLASS || t.tag == TYPEVAR; t = supertype(t)) {
mcimadamore@341	2080	while (t.tag == TYPEVAR)
mcimadamore@341	2081	t = t.getUpperBound();
mcimadamore@341	2082	TypeSymbol c = t.tsym;
mcimadamore@673	2083	for (Scope.Entry e = c.members().lookup(ms.name, implFilter);
mcimadamore@341	2084	e.scope != null;
mcimadamore@780	2085	e = e.next(implFilter)) {
mcimadamore@673	2086	if (e.sym != null &&
mcimadamore@877	2087	e.sym.overrides(ms, origin, Types.this, checkResult))
mcimadamore@673	2088	return (MethodSymbol)e.sym;
mcimadamore@341	2089	}
mcimadamore@341	2090	}
mcimadamore@673	2091	return null;
mcimadamore@341	2092	}
mcimadamore@341	2093	}
mcimadamore@341	2094
mcimadamore@673	2095	private ImplementationCache implCache = new ImplementationCache();
mcimadamore@673	2096
mcimadamore@858	2097	public MethodSymbol implementation(MethodSymbol ms, TypeSymbol origin, boolean checkResult, Filter<Symbol> implFilter) {
mcimadamore@858	2098	return implCache.get(ms, origin, checkResult, implFilter);
mcimadamore@673	2099	}
mcimadamore@673	2100	// </editor-fold>
mcimadamore@673	2101
mcimadamore@858	2102	// <editor-fold defaultstate="collapsed" desc="compute transitive closure of all members in given site">
mcimadamore@1015	2103	class MembersClosureCache extends SimpleVisitor<CompoundScope, Boolean> {
mcimadamore@1015	2104
mcimadamore@1015	2105	private WeakHashMap<TypeSymbol, Entry> _map =
mcimadamore@1015	2106	new WeakHashMap<TypeSymbol, Entry>();
mcimadamore@1015	2107
mcimadamore@1015	2108	class Entry {
mcimadamore@1015	2109	final boolean skipInterfaces;
mcimadamore@1015	2110	final CompoundScope compoundScope;
mcimadamore@1015	2111
mcimadamore@1015	2112	public Entry(boolean skipInterfaces, CompoundScope compoundScope) {
mcimadamore@1015	2113	this.skipInterfaces = skipInterfaces;
mcimadamore@1015	2114	this.compoundScope = compoundScope;
mcimadamore@1015	2115	}
mcimadamore@1015	2116
mcimadamore@1015	2117	boolean matches(boolean skipInterfaces) {
mcimadamore@1015	2118	return this.skipInterfaces == skipInterfaces;
mcimadamore@1015	2119	}
mcimadamore@1015	2120	}
mcimadamore@1015	2121
mcimadamore@1072	2122	List<TypeSymbol> seenTypes = List.nil();
mcimadamore@1072	2123
mcimadamore@1015	2124	/** members closure visitor methods **/
mcimadamore@1015	2125
mcimadamore@1015	2126	public CompoundScope visitType(Type t, Boolean skipInterface) {
mcimadamore@858	2127	return null;
mcimadamore@858	2128	}
mcimadamore@858	2129
mcimadamore@858	2130	@Override
mcimadamore@1015	2131	public CompoundScope visitClassType(ClassType t, Boolean skipInterface) {
mcimadamore@1072	2132	if (seenTypes.contains(t.tsym)) {
mcimadamore@1072	2133	//this is possible when an interface is implemented in multiple
mcimadamore@1072	2134	//superclasses, or when a classs hierarchy is circular - in such
mcimadamore@1072	2135	//cases we don't need to recurse (empty scope is returned)
mcimadamore@1072	2136	return new CompoundScope(t.tsym);
mcimadamore@1072	2137	}
mcimadamore@1072	2138	try {
mcimadamore@1072	2139	seenTypes = seenTypes.prepend(t.tsym);
mcimadamore@1072	2140	ClassSymbol csym = (ClassSymbol)t.tsym;
mcimadamore@1072	2141	Entry e = _map.get(csym);
mcimadamore@1072	2142	if (e == null || !e.matches(skipInterface)) {
mcimadamore@1072	2143	CompoundScope membersClosure = new CompoundScope(csym);
mcimadamore@1072	2144	if (!skipInterface) {
mcimadamore@1072	2145	for (Type i : interfaces(t)) {
mcimadamore@1072	2146	membersClosure.addSubScope(visit(i, skipInterface));
mcimadamore@1072	2147	}
mcimadamore@1015	2148	}
mcimadamore@1072	2149	membersClosure.addSubScope(visit(supertype(t), skipInterface));
mcimadamore@1072	2150	membersClosure.addSubScope(csym.members());
mcimadamore@1072	2151	e = new Entry(skipInterface, membersClosure);
mcimadamore@1072	2152	_map.put(csym, e);
mcimadamore@858	2153	}
mcimadamore@1072	2154	return e.compoundScope;
mcimadamore@858	2155	}
mcimadamore@1072	2156	finally {
mcimadamore@1072	2157	seenTypes = seenTypes.tail;
mcimadamore@1072	2158	}
mcimadamore@858	2159	}
mcimadamore@858	2160
mcimadamore@858	2161	@Override
mcimadamore@1015	2162	public CompoundScope visitTypeVar(TypeVar t, Boolean skipInterface) {
mcimadamore@1015	2163	return visit(t.getUpperBound(), skipInterface);
mcimadamore@858	2164	}
mcimadamore@1015	2165	}
mcimadamore@1015	2166
mcimadamore@1015	2167	private MembersClosureCache membersCache = new MembersClosureCache();
mcimadamore@1015	2168
mcimadamore@1015	2169	public CompoundScope membersClosure(Type site, boolean skipInterface) {
mcimadamore@1015	2170	return membersCache.visit(site, skipInterface);
mcimadamore@1015	2171	}
mcimadamore@858	2172	// </editor-fold>
mcimadamore@858	2173
duke@1	2174	/**
duke@1	2175	* Does t have the same arguments as s? It is assumed that both
duke@1	2176	* types are (possibly polymorphic) method types. Monomorphic
duke@1	2177	* method types "have the same arguments", if their argument lists
duke@1	2178	* are equal. Polymorphic method types "have the same arguments",
duke@1	2179	* if they have the same arguments after renaming all type
duke@1	2180	* variables of one to corresponding type variables in the other,
duke@1	2181	* where correspondence is by position in the type parameter list.
duke@1	2182	*/
duke@1	2183	public boolean hasSameArgs(Type t, Type s) {
mcimadamore@907	2184	return hasSameArgs(t, s, true);
mcimadamore@907	2185	}
mcimadamore@907	2186
mcimadamore@907	2187	public boolean hasSameArgs(Type t, Type s, boolean strict) {
mcimadamore@907	2188	return hasSameArgs(t, s, strict ? hasSameArgs_strict : hasSameArgs_nonstrict);
mcimadamore@907	2189	}
mcimadamore@907	2190
mcimadamore@907	2191	private boolean hasSameArgs(Type t, Type s, TypeRelation hasSameArgs) {
duke@1	2192	return hasSameArgs.visit(t, s);
duke@1	2193	}
duke@1	2194	// where
mcimadamore@907	2195	private class HasSameArgs extends TypeRelation {
mcimadamore@907	2196
mcimadamore@907	2197	boolean strict;
mcimadamore@907	2198
mcimadamore@907	2199	public HasSameArgs(boolean strict) {
mcimadamore@907	2200	this.strict = strict;
mcimadamore@907	2201	}
duke@1	2202
duke@1	2203	public Boolean visitType(Type t, Type s) {
duke@1	2204	throw new AssertionError();
duke@1	2205	}
duke@1	2206
duke@1	2207	@Override
duke@1	2208	public Boolean visitMethodType(MethodType t, Type s) {
duke@1	2209	return s.tag == METHOD
duke@1	2210	&& containsTypeEquivalent(t.argtypes, s.getParameterTypes());
duke@1	2211	}
duke@1	2212
duke@1	2213	@Override
duke@1	2214	public Boolean visitForAll(ForAll t, Type s) {
duke@1	2215	if (s.tag != FORALL)
mcimadamore@907	2216	return strict ? false : visitMethodType(t.asMethodType(), s);
duke@1	2217
duke@1	2218	ForAll forAll = (ForAll)s;
duke@1	2219	return hasSameBounds(t, forAll)
duke@1	2220	&& visit(t.qtype, subst(forAll.qtype, forAll.tvars, t.tvars));
duke@1	2221	}
duke@1	2222
duke@1	2223	@Override
duke@1	2224	public Boolean visitErrorType(ErrorType t, Type s) {
duke@1	2225	return false;
duke@1	2226	}
duke@1	2227	};
mcimadamore@907	2228
mcimadamore@907	2229	TypeRelation hasSameArgs_strict = new HasSameArgs(true);
mcimadamore@907	2230	TypeRelation hasSameArgs_nonstrict = new HasSameArgs(false);
mcimadamore@907	2231
duke@1	2232	// </editor-fold>
duke@1	2233
duke@1	2234	// <editor-fold defaultstate="collapsed" desc="subst">
duke@1	2235	public List<Type> subst(List<Type> ts,
duke@1	2236	List<Type> from,
duke@1	2237	List<Type> to) {
duke@1	2238	return new Subst(from, to).subst(ts);
duke@1	2239	}
duke@1	2240
duke@1	2241	/**
duke@1	2242	* Substitute all occurrences of a type in `from' with the
duke@1	2243	* corresponding type in `to' in 't'. Match lists `from' and `to'
duke@1	2244	* from the right: If lists have different length, discard leading
duke@1	2245	* elements of the longer list.
duke@1	2246	*/
duke@1	2247	public Type subst(Type t, List<Type> from, List<Type> to) {
duke@1	2248	return new Subst(from, to).subst(t);
duke@1	2249	}
duke@1	2250
duke@1	2251	private class Subst extends UnaryVisitor<Type> {
duke@1	2252	List<Type> from;
duke@1	2253	List<Type> to;
duke@1	2254
duke@1	2255	public Subst(List<Type> from, List<Type> to) {
duke@1	2256	int fromLength = from.length();
duke@1	2257	int toLength = to.length();
duke@1	2258	while (fromLength > toLength) {
duke@1	2259	fromLength--;
duke@1	2260	from = from.tail;
duke@1	2261	}
duke@1	2262	while (fromLength < toLength) {
duke@1	2263	toLength--;
duke@1	2264	to = to.tail;
duke@1	2265	}
duke@1	2266	this.from = from;
duke@1	2267	this.to = to;
duke@1	2268	}
duke@1	2269
duke@1	2270	Type subst(Type t) {
duke@1	2271	if (from.tail == null)
duke@1	2272	return t;
duke@1	2273	else
duke@1	2274	return visit(t);
mcimadamore@238	2275	}
duke@1	2276
duke@1	2277	List<Type> subst(List<Type> ts) {
duke@1	2278	if (from.tail == null)
duke@1	2279	return ts;
duke@1	2280	boolean wild = false;
duke@1	2281	if (ts.nonEmpty() && from.nonEmpty()) {
duke@1	2282	Type head1 = subst(ts.head);
duke@1	2283	List<Type> tail1 = subst(ts.tail);
duke@1	2284	if (head1 != ts.head || tail1 != ts.tail)
duke@1	2285	return tail1.prepend(head1);
duke@1	2286	}
duke@1	2287	return ts;
duke@1	2288	}
duke@1	2289
duke@1	2290	public Type visitType(Type t, Void ignored) {
duke@1	2291	return t;
duke@1	2292	}
duke@1	2293
duke@1	2294	@Override
duke@1	2295	public Type visitMethodType(MethodType t, Void ignored) {
duke@1	2296	List<Type> argtypes = subst(t.argtypes);
duke@1	2297	Type restype = subst(t.restype);
duke@1	2298	List<Type> thrown = subst(t.thrown);
duke@1	2299	if (argtypes == t.argtypes &&
duke@1	2300	restype == t.restype &&
duke@1	2301	thrown == t.thrown)
duke@1	2302	return t;
duke@1	2303	else
duke@1	2304	return new MethodType(argtypes, restype, thrown, t.tsym);
duke@1	2305	}
duke@1	2306
duke@1	2307	@Override
duke@1	2308	public Type visitTypeVar(TypeVar t, Void ignored) {
duke@1	2309	for (List<Type> from = this.from, to = this.to;
duke@1	2310	from.nonEmpty();
duke@1	2311	from = from.tail, to = to.tail) {
duke@1	2312	if (t == from.head) {
duke@1	2313	return to.head.withTypeVar(t);
duke@1	2314	}
duke@1	2315	}
duke@1	2316	return t;
duke@1	2317	}
duke@1	2318
duke@1	2319	@Override
duke@1	2320	public Type visitClassType(ClassType t, Void ignored) {
duke@1	2321	if (!t.isCompound()) {
duke@1	2322	List<Type> typarams = t.getTypeArguments();
duke@1	2323	List<Type> typarams1 = subst(typarams);
duke@1	2324	Type outer = t.getEnclosingType();
duke@1	2325	Type outer1 = subst(outer);
duke@1	2326	if (typarams1 == typarams && outer1 == outer)
duke@1	2327	return t;
duke@1	2328	else
duke@1	2329	return new ClassType(outer1, typarams1, t.tsym);
duke@1	2330	} else {
duke@1	2331	Type st = subst(supertype(t));
duke@1	2332	List<Type> is = upperBounds(subst(interfaces(t)));
duke@1	2333	if (st == supertype(t) && is == interfaces(t))
duke@1	2334	return t;
duke@1	2335	else
duke@1	2336	return makeCompoundType(is.prepend(st));
duke@1	2337	}
duke@1	2338	}
duke@1	2339
duke@1	2340	@Override
duke@1	2341	public Type visitWildcardType(WildcardType t, Void ignored) {
duke@1	2342	Type bound = t.type;
duke@1	2343	if (t.kind != BoundKind.UNBOUND)
duke@1	2344	bound = subst(bound);
duke@1	2345	if (bound == t.type) {
duke@1	2346	return t;
duke@1	2347	} else {
duke@1	2348	if (t.isExtendsBound() && bound.isExtendsBound())
duke@1	2349	bound = upperBound(bound);
duke@1	2350	return new WildcardType(bound, t.kind, syms.boundClass, t.bound);
duke@1	2351	}
duke@1	2352	}
duke@1	2353
duke@1	2354	@Override
duke@1	2355	public Type visitArrayType(ArrayType t, Void ignored) {
duke@1	2356	Type elemtype = subst(t.elemtype);
duke@1	2357	if (elemtype == t.elemtype)
duke@1	2358	return t;
duke@1	2359	else
mcimadamore@996	2360	return new ArrayType(upperBound(elemtype), t.tsym);
duke@1	2361	}
duke@1	2362
duke@1	2363	@Override
duke@1	2364	public Type visitForAll(ForAll t, Void ignored) {
mcimadamore@846	2365	if (Type.containsAny(to, t.tvars)) {
mcimadamore@846	2366	//perform alpha-renaming of free-variables in 't'
mcimadamore@846	2367	//if 'to' types contain variables that are free in 't'
mcimadamore@846	2368	List<Type> freevars = newInstances(t.tvars);
mcimadamore@846	2369	t = new ForAll(freevars,
mcimadamore@846	2370	Types.this.subst(t.qtype, t.tvars, freevars));
mcimadamore@846	2371	}
duke@1	2372	List<Type> tvars1 = substBounds(t.tvars, from, to);
duke@1	2373	Type qtype1 = subst(t.qtype);
duke@1	2374	if (tvars1 == t.tvars && qtype1 == t.qtype) {
duke@1	2375	return t;
duke@1	2376	} else if (tvars1 == t.tvars) {
duke@1	2377	return new ForAll(tvars1, qtype1);
duke@1	2378	} else {
duke@1	2379	return new ForAll(tvars1, Types.this.subst(qtype1, t.tvars, tvars1));
duke@1	2380	}
duke@1	2381	}
duke@1	2382
duke@1	2383	@Override
duke@1	2384	public Type visitErrorType(ErrorType t, Void ignored) {
duke@1	2385	return t;
duke@1	2386	}
duke@1	2387	}
duke@1	2388
duke@1	2389	public List<Type> substBounds(List<Type> tvars,
duke@1	2390	List<Type> from,
duke@1	2391	List<Type> to) {
duke@1	2392	if (tvars.isEmpty())
duke@1	2393	return tvars;
duke@1	2394	ListBuffer<Type> newBoundsBuf = lb();
duke@1	2395	boolean changed = false;
duke@1	2396	// calculate new bounds
duke@1	2397	for (Type t : tvars) {
duke@1	2398	TypeVar tv = (TypeVar) t;
duke@1	2399	Type bound = subst(tv.bound, from, to);
duke@1	2400	if (bound != tv.bound)
duke@1	2401	changed = true;
duke@1	2402	newBoundsBuf.append(bound);
duke@1	2403	}
duke@1	2404	if (!changed)
duke@1	2405	return tvars;
duke@1	2406	ListBuffer<Type> newTvars = lb();
duke@1	2407	// create new type variables without bounds
duke@1	2408	for (Type t : tvars) {
duke@1	2409	newTvars.append(new TypeVar(t.tsym, null, syms.botType));
duke@1	2410	}
duke@1	2411	// the new bounds should use the new type variables in place
duke@1	2412	// of the old
duke@1	2413	List<Type> newBounds = newBoundsBuf.toList();
duke@1	2414	from = tvars;
duke@1	2415	to = newTvars.toList();
duke@1	2416	for (; !newBounds.isEmpty(); newBounds = newBounds.tail) {
duke@1	2417	newBounds.head = subst(newBounds.head, from, to);
duke@1	2418	}
duke@1	2419	newBounds = newBoundsBuf.toList();
duke@1	2420	// set the bounds of new type variables to the new bounds
duke@1	2421	for (Type t : newTvars.toList()) {
duke@1	2422	TypeVar tv = (TypeVar) t;
duke@1	2423	tv.bound = newBounds.head;
duke@1	2424	newBounds = newBounds.tail;
duke@1	2425	}
duke@1	2426	return newTvars.toList();
duke@1	2427	}
duke@1	2428
duke@1	2429	public TypeVar substBound(TypeVar t, List<Type> from, List<Type> to) {
duke@1	2430	Type bound1 = subst(t.bound, from, to);
duke@1	2431	if (bound1 == t.bound)
duke@1	2432	return t;
mcimadamore@212	2433	else {
mcimadamore@212	2434	// create new type variable without bounds
mcimadamore@212	2435	TypeVar tv = new TypeVar(t.tsym, null, syms.botType);
mcimadamore@212	2436	// the new bound should use the new type variable in place
mcimadamore@212	2437	// of the old
mcimadamore@212	2438	tv.bound = subst(bound1, List.<Type>of(t), List.<Type>of(tv));
mcimadamore@212	2439	return tv;
mcimadamore@212	2440	}
duke@1	2441	}
duke@1	2442	// </editor-fold>
duke@1	2443
duke@1	2444	// <editor-fold defaultstate="collapsed" desc="hasSameBounds">
duke@1	2445	/**
duke@1	2446	* Does t have the same bounds for quantified variables as s?
duke@1	2447	*/
duke@1	2448	boolean hasSameBounds(ForAll t, ForAll s) {
duke@1	2449	List<Type> l1 = t.tvars;
duke@1	2450	List<Type> l2 = s.tvars;
duke@1	2451	while (l1.nonEmpty() && l2.nonEmpty() &&
duke@1	2452	isSameType(l1.head.getUpperBound(),
duke@1	2453	subst(l2.head.getUpperBound(),
duke@1	2454	s.tvars,
duke@1	2455	t.tvars))) {
duke@1	2456	l1 = l1.tail;
duke@1	2457	l2 = l2.tail;
duke@1	2458	}
duke@1	2459	return l1.isEmpty() && l2.isEmpty();
duke@1	2460	}
duke@1	2461	// </editor-fold>
duke@1	2462
duke@1	2463	// <editor-fold defaultstate="collapsed" desc="newInstances">
duke@1	2464	/** Create new vector of type variables from list of variables
duke@1	2465	* changing all recursive bounds from old to new list.
duke@1	2466	*/
duke@1	2467	public List<Type> newInstances(List<Type> tvars) {
duke@1	2468	List<Type> tvars1 = Type.map(tvars, newInstanceFun);
duke@1	2469	for (List<Type> l = tvars1; l.nonEmpty(); l = l.tail) {
duke@1	2470	TypeVar tv = (TypeVar) l.head;
duke@1	2471	tv.bound = subst(tv.bound, tvars, tvars1);
duke@1	2472	}
duke@1	2473	return tvars1;
duke@1	2474	}
duke@1	2475	static private Mapping newInstanceFun = new Mapping("newInstanceFun") {
duke@1	2476	public Type apply(Type t) { return new TypeVar(t.tsym, t.getUpperBound(), t.getLowerBound()); }
duke@1	2477	};
duke@1	2478	// </editor-fold>
duke@1	2479
dlsmith@880	2480	public Type createMethodTypeWithParameters(Type original, List<Type> newParams) {
dlsmith@880	2481	return original.accept(methodWithParameters, newParams);
dlsmith@880	2482	}
dlsmith@880	2483	// where
dlsmith@880	2484	private final MapVisitor<List<Type>> methodWithParameters = new MapVisitor<List<Type>>() {
dlsmith@880	2485	public Type visitType(Type t, List<Type> newParams) {
dlsmith@880	2486	throw new IllegalArgumentException("Not a method type: " + t);
dlsmith@880	2487	}
dlsmith@880	2488	public Type visitMethodType(MethodType t, List<Type> newParams) {
dlsmith@880	2489	return new MethodType(newParams, t.restype, t.thrown, t.tsym);
dlsmith@880	2490	}
dlsmith@880	2491	public Type visitForAll(ForAll t, List<Type> newParams) {
dlsmith@880	2492	return new ForAll(t.tvars, t.qtype.accept(this, newParams));
dlsmith@880	2493	}
dlsmith@880	2494	};
dlsmith@880	2495
dlsmith@880	2496	public Type createMethodTypeWithThrown(Type original, List<Type> newThrown) {
dlsmith@880	2497	return original.accept(methodWithThrown, newThrown);
dlsmith@880	2498	}
dlsmith@880	2499	// where
dlsmith@880	2500	private final MapVisitor<List<Type>> methodWithThrown = new MapVisitor<List<Type>>() {
dlsmith@880	2501	public Type visitType(Type t, List<Type> newThrown) {
dlsmith@880	2502	throw new IllegalArgumentException("Not a method type: " + t);
dlsmith@880	2503	}
dlsmith@880	2504	public Type visitMethodType(MethodType t, List<Type> newThrown) {
dlsmith@880	2505	return new MethodType(t.argtypes, t.restype, newThrown, t.tsym);
dlsmith@880	2506	}
dlsmith@880	2507	public Type visitForAll(ForAll t, List<Type> newThrown) {
dlsmith@880	2508	return new ForAll(t.tvars, t.qtype.accept(this, newThrown));
dlsmith@880	2509	}
dlsmith@880	2510	};
dlsmith@880	2511
mcimadamore@950	2512	public Type createMethodTypeWithReturn(Type original, Type newReturn) {
mcimadamore@950	2513	return original.accept(methodWithReturn, newReturn);
mcimadamore@950	2514	}
mcimadamore@950	2515	// where
mcimadamore@950	2516	private final MapVisitor<Type> methodWithReturn = new MapVisitor<Type>() {
mcimadamore@950	2517	public Type visitType(Type t, Type newReturn) {
mcimadamore@950	2518	throw new IllegalArgumentException("Not a method type: " + t);
mcimadamore@950	2519	}
mcimadamore@950	2520	public Type visitMethodType(MethodType t, Type newReturn) {
mcimadamore@950	2521	return new MethodType(t.argtypes, newReturn, t.thrown, t.tsym);
mcimadamore@950	2522	}
mcimadamore@950	2523	public Type visitForAll(ForAll t, Type newReturn) {
mcimadamore@950	2524	return new ForAll(t.tvars, t.qtype.accept(this, newReturn));
mcimadamore@950	2525	}
mcimadamore@950	2526	};
mcimadamore@950	2527
jjg@110	2528	// <editor-fold defaultstate="collapsed" desc="createErrorType">
jjg@110	2529	public Type createErrorType(Type originalType) {
jjg@110	2530	return new ErrorType(originalType, syms.errSymbol);
jjg@110	2531	}
jjg@110	2532
jjg@110	2533	public Type createErrorType(ClassSymbol c, Type originalType) {
jjg@110	2534	return new ErrorType(c, originalType);
jjg@110	2535	}
jjg@110	2536
jjg@110	2537	public Type createErrorType(Name name, TypeSymbol container, Type originalType) {
jjg@110	2538	return new ErrorType(name, container, originalType);
jjg@110	2539	}
jjg@110	2540	// </editor-fold>
jjg@110	2541
duke@1	2542	// <editor-fold defaultstate="collapsed" desc="rank">
duke@1	2543	/**
duke@1	2544	* The rank of a class is the length of the longest path between
duke@1	2545	* the class and java.lang.Object in the class inheritance
duke@1	2546	* graph. Undefined for all but reference types.
duke@1	2547	*/
duke@1	2548	public int rank(Type t) {
duke@1	2549	switch(t.tag) {
duke@1	2550	case CLASS: {
duke@1	2551	ClassType cls = (ClassType)t;
duke@1	2552	if (cls.rank_field < 0) {
duke@1	2553	Name fullname = cls.tsym.getQualifiedName();
jjg@113	2554	if (fullname == names.java_lang_Object)
duke@1	2555	cls.rank_field = 0;
duke@1	2556	else {
duke@1	2557	int r = rank(supertype(cls));
duke@1	2558	for (List<Type> l = interfaces(cls);
duke@1	2559	l.nonEmpty();
duke@1	2560	l = l.tail) {
duke@1	2561	if (rank(l.head) > r)
duke@1	2562	r = rank(l.head);
duke@1	2563	}
duke@1	2564	cls.rank_field = r + 1;
duke@1	2565	}
duke@1	2566	}
duke@1	2567	return cls.rank_field;
duke@1	2568	}
duke@1	2569	case TYPEVAR: {
duke@1	2570	TypeVar tvar = (TypeVar)t;
duke@1	2571	if (tvar.rank_field < 0) {
duke@1	2572	int r = rank(supertype(tvar));
duke@1	2573	for (List<Type> l = interfaces(tvar);
duke@1	2574	l.nonEmpty();
duke@1	2575	l = l.tail) {
duke@1	2576	if (rank(l.head) > r) r = rank(l.head);
duke@1	2577	}
duke@1	2578	tvar.rank_field = r + 1;
duke@1	2579	}
duke@1	2580	return tvar.rank_field;
duke@1	2581	}
duke@1	2582	case ERROR:
duke@1	2583	return 0;
duke@1	2584	default:
duke@1	2585	throw new AssertionError();
duke@1	2586	}
duke@1	2587	}
duke@1	2588	// </editor-fold>
duke@1	2589
mcimadamore@121	2590	/**
mcimadamore@238	2591	* Helper method for generating a string representation of a given type
mcimadamore@121	2592	* accordingly to a given locale
mcimadamore@121	2593	*/
mcimadamore@121	2594	public String toString(Type t, Locale locale) {
mcimadamore@238	2595	return Printer.createStandardPrinter(messages).visit(t, locale);
mcimadamore@121	2596	}
mcimadamore@121	2597
mcimadamore@121	2598	/**
mcimadamore@238	2599	* Helper method for generating a string representation of a given type
mcimadamore@121	2600	* accordingly to a given locale
mcimadamore@121	2601	*/
mcimadamore@121	2602	public String toString(Symbol t, Locale locale) {
mcimadamore@238	2603	return Printer.createStandardPrinter(messages).visit(t, locale);
mcimadamore@121	2604	}
mcimadamore@121	2605
duke@1	2606	// <editor-fold defaultstate="collapsed" desc="toString">
duke@1	2607	/**
duke@1	2608	* This toString is slightly more descriptive than the one on Type.
mcimadamore@121	2609	*
mcimadamore@121	2610	* @deprecated Types.toString(Type t, Locale l) provides better support
mcimadamore@121	2611	* for localization
duke@1	2612	*/
mcimadamore@121	2613	@Deprecated
duke@1	2614	public String toString(Type t) {
duke@1	2615	if (t.tag == FORALL) {
duke@1	2616	ForAll forAll = (ForAll)t;
duke@1	2617	return typaramsString(forAll.tvars) + forAll.qtype;
duke@1	2618	}
duke@1	2619	return "" + t;
duke@1	2620	}
duke@1	2621	// where
duke@1	2622	private String typaramsString(List<Type> tvars) {
jjg@904	2623	StringBuilder s = new StringBuilder();
duke@1	2624	s.append('<');
duke@1	2625	boolean first = true;
duke@1	2626	for (Type t : tvars) {
duke@1	2627	if (!first) s.append(", ");
duke@1	2628	first = false;
duke@1	2629	appendTyparamString(((TypeVar)t), s);
duke@1	2630	}
duke@1	2631	s.append('>');
duke@1	2632	return s.toString();
duke@1	2633	}
jjg@904	2634	private void appendTyparamString(TypeVar t, StringBuilder buf) {
duke@1	2635	buf.append(t);
duke@1	2636	if (t.bound == null ||
duke@1	2637	t.bound.tsym.getQualifiedName() == names.java_lang_Object)
duke@1	2638	return;
duke@1	2639	buf.append(" extends "); // Java syntax; no need for i18n
duke@1	2640	Type bound = t.bound;
duke@1	2641	if (!bound.isCompound()) {
duke@1	2642	buf.append(bound);
duke@1	2643	} else if ((erasure(t).tsym.flags() & INTERFACE) == 0) {
duke@1	2644	buf.append(supertype(t));
duke@1	2645	for (Type intf : interfaces(t)) {
duke@1	2646	buf.append('&');
duke@1	2647	buf.append(intf);
duke@1	2648	}
duke@1	2649	} else {
duke@1	2650	// No superclass was given in bounds.
duke@1	2651	// In this case, supertype is Object, erasure is first interface.
duke@1	2652	boolean first = true;
duke@1	2653	for (Type intf : interfaces(t)) {
duke@1	2654	if (!first) buf.append('&');
duke@1	2655	first = false;
duke@1	2656	buf.append(intf);
duke@1	2657	}
duke@1	2658	}
duke@1	2659	}
duke@1	2660	// </editor-fold>
duke@1	2661
duke@1	2662	// <editor-fold defaultstate="collapsed" desc="Determining least upper bounds of types">
duke@1	2663	/**
duke@1	2664	* A cache for closures.
duke@1	2665	*
duke@1	2666	* <p>A closure is a list of all the supertypes and interfaces of
duke@1	2667	* a class or interface type, ordered by ClassSymbol.precedes
duke@1	2668	* (that is, subclasses come first, arbitrary but fixed
duke@1	2669	* otherwise).
duke@1	2670	*/
duke@1	2671	private Map<Type,List<Type>> closureCache = new HashMap<Type,List<Type>>();
duke@1	2672
duke@1	2673	/**
duke@1	2674	* Returns the closure of a class or interface type.
duke@1	2675	*/
duke@1	2676	public List<Type> closure(Type t) {
duke@1	2677	List<Type> cl = closureCache.get(t);
duke@1	2678	if (cl == null) {
duke@1	2679	Type st = supertype(t);
duke@1	2680	if (!t.isCompound()) {
duke@1	2681	if (st.tag == CLASS) {
duke@1	2682	cl = insert(closure(st), t);
duke@1	2683	} else if (st.tag == TYPEVAR) {
duke@1	2684	cl = closure(st).prepend(t);
duke@1	2685	} else {
duke@1	2686	cl = List.of(t);
duke@1	2687	}
duke@1	2688	} else {
duke@1	2689	cl = closure(supertype(t));
duke@1	2690	}
duke@1	2691	for (List<Type> l = interfaces(t); l.nonEmpty(); l = l.tail)
duke@1	2692	cl = union(cl, closure(l.head));
duke@1	2693	closureCache.put(t, cl);
duke@1	2694	}
duke@1	2695	return cl;
duke@1	2696	}
duke@1	2697
duke@1	2698	/**
duke@1	2699	* Insert a type in a closure
duke@1	2700	*/
duke@1	2701	public List<Type> insert(List<Type> cl, Type t) {
duke@1	2702	if (cl.isEmpty() || t.tsym.precedes(cl.head.tsym, this)) {
duke@1	2703	return cl.prepend(t);
duke@1	2704	} else if (cl.head.tsym.precedes(t.tsym, this)) {
duke@1	2705	return insert(cl.tail, t).prepend(cl.head);
duke@1	2706	} else {
duke@1	2707	return cl;
duke@1	2708	}
duke@1	2709	}
duke@1	2710
duke@1	2711	/**
duke@1	2712	* Form the union of two closures
duke@1	2713	*/
duke@1	2714	public List<Type> union(List<Type> cl1, List<Type> cl2) {
duke@1	2715	if (cl1.isEmpty()) {
duke@1	2716	return cl2;
duke@1	2717	} else if (cl2.isEmpty()) {
duke@1	2718	return cl1;
duke@1	2719	} else if (cl1.head.tsym.precedes(cl2.head.tsym, this)) {
duke@1	2720	return union(cl1.tail, cl2).prepend(cl1.head);
duke@1	2721	} else if (cl2.head.tsym.precedes(cl1.head.tsym, this)) {
duke@1	2722	return union(cl1, cl2.tail).prepend(cl2.head);
duke@1	2723	} else {
duke@1	2724	return union(cl1.tail, cl2.tail).prepend(cl1.head);
duke@1	2725	}
duke@1	2726	}
duke@1	2727
duke@1	2728	/**
duke@1	2729	* Intersect two closures
duke@1	2730	*/
duke@1	2731	public List<Type> intersect(List<Type> cl1, List<Type> cl2) {
duke@1	2732	if (cl1 == cl2)
duke@1	2733	return cl1;
duke@1	2734	if (cl1.isEmpty() || cl2.isEmpty())
duke@1	2735	return List.nil();
duke@1	2736	if (cl1.head.tsym.precedes(cl2.head.tsym, this))
duke@1	2737	return intersect(cl1.tail, cl2);
duke@1	2738	if (cl2.head.tsym.precedes(cl1.head.tsym, this))
duke@1	2739	return intersect(cl1, cl2.tail);
duke@1	2740	if (isSameType(cl1.head, cl2.head))
duke@1	2741	return intersect(cl1.tail, cl2.tail).prepend(cl1.head);
duke@1	2742	if (cl1.head.tsym == cl2.head.tsym &&
duke@1	2743	cl1.head.tag == CLASS && cl2.head.tag == CLASS) {
duke@1	2744	if (cl1.head.isParameterized() && cl2.head.isParameterized()) {
duke@1	2745	Type merge = merge(cl1.head,cl2.head);
duke@1	2746	return intersect(cl1.tail, cl2.tail).prepend(merge);
duke@1	2747	}
duke@1	2748	if (cl1.head.isRaw() || cl2.head.isRaw())
duke@1	2749	return intersect(cl1.tail, cl2.tail).prepend(erasure(cl1.head));
duke@1	2750	}
duke@1	2751	return intersect(cl1.tail, cl2.tail);
duke@1	2752	}
duke@1	2753	// where
duke@1	2754	class TypePair {
duke@1	2755	final Type t1;
duke@1	2756	final Type t2;
duke@1	2757	TypePair(Type t1, Type t2) {
duke@1	2758	this.t1 = t1;
duke@1	2759	this.t2 = t2;
duke@1	2760	}
duke@1	2761	@Override
duke@1	2762	public int hashCode() {
jjg@507	2763	return 127 * Types.hashCode(t1) + Types.hashCode(t2);
duke@1	2764	}
duke@1	2765	@Override
duke@1	2766	public boolean equals(Object obj) {
duke@1	2767	if (!(obj instanceof TypePair))
duke@1	2768	return false;
duke@1	2769	TypePair typePair = (TypePair)obj;
duke@1	2770	return isSameType(t1, typePair.t1)
duke@1	2771	&& isSameType(t2, typePair.t2);
duke@1	2772	}
duke@1	2773	}
duke@1	2774	Set<TypePair> mergeCache = new HashSet<TypePair>();
duke@1	2775	private Type merge(Type c1, Type c2) {
duke@1	2776	ClassType class1 = (ClassType) c1;
duke@1	2777	List<Type> act1 = class1.getTypeArguments();
duke@1	2778	ClassType class2 = (ClassType) c2;
duke@1	2779	List<Type> act2 = class2.getTypeArguments();
duke@1	2780	ListBuffer<Type> merged = new ListBuffer<Type>();
duke@1	2781	List<Type> typarams = class1.tsym.type.getTypeArguments();
duke@1	2782
duke@1	2783	while (act1.nonEmpty() && act2.nonEmpty() && typarams.nonEmpty()) {
duke@1	2784	if (containsType(act1.head, act2.head)) {
duke@1	2785	merged.append(act1.head);
duke@1	2786	} else if (containsType(act2.head, act1.head)) {
duke@1	2787	merged.append(act2.head);
duke@1	2788	} else {
duke@1	2789	TypePair pair = new TypePair(c1, c2);
duke@1	2790	Type m;
duke@1	2791	if (mergeCache.add(pair)) {
duke@1	2792	m = new WildcardType(lub(upperBound(act1.head),
duke@1	2793	upperBound(act2.head)),
duke@1	2794	BoundKind.EXTENDS,
duke@1	2795	syms.boundClass);
duke@1	2796	mergeCache.remove(pair);
duke@1	2797	} else {
duke@1	2798	m = new WildcardType(syms.objectType,
duke@1	2799	BoundKind.UNBOUND,
duke@1	2800	syms.boundClass);
duke@1	2801	}
duke@1	2802	merged.append(m.withTypeVar(typarams.head));
duke@1	2803	}
duke@1	2804	act1 = act1.tail;
duke@1	2805	act2 = act2.tail;
duke@1	2806	typarams = typarams.tail;
duke@1	2807	}
jjg@816	2808	Assert.check(act1.isEmpty() && act2.isEmpty() && typarams.isEmpty());
duke@1	2809	return new ClassType(class1.getEnclosingType(), merged.toList(), class1.tsym);
duke@1	2810	}
duke@1	2811
duke@1	2812	/**
duke@1	2813	* Return the minimum type of a closure, a compound type if no
duke@1	2814	* unique minimum exists.
duke@1	2815	*/
duke@1	2816	private Type compoundMin(List<Type> cl) {
duke@1	2817	if (cl.isEmpty()) return syms.objectType;
duke@1	2818	List<Type> compound = closureMin(cl);
duke@1	2819	if (compound.isEmpty())
duke@1	2820	return null;
duke@1	2821	else if (compound.tail.isEmpty())
duke@1	2822	return compound.head;
duke@1	2823	else
duke@1	2824	return makeCompoundType(compound);
duke@1	2825	}
duke@1	2826
duke@1	2827	/**
duke@1	2828	* Return the minimum types of a closure, suitable for computing
duke@1	2829	* compoundMin or glb.
duke@1	2830	*/
duke@1	2831	private List<Type> closureMin(List<Type> cl) {
duke@1	2832	ListBuffer<Type> classes = lb();
duke@1	2833	ListBuffer<Type> interfaces = lb();
duke@1	2834	while (!cl.isEmpty()) {
duke@1	2835	Type current = cl.head;
duke@1	2836	if (current.isInterface())
duke@1	2837	interfaces.append(current);
duke@1	2838	else
duke@1	2839	classes.append(current);
duke@1	2840	ListBuffer<Type> candidates = lb();
duke@1	2841	for (Type t : cl.tail) {
duke@1	2842	if (!isSubtypeNoCapture(current, t))
duke@1	2843	candidates.append(t);
duke@1	2844	}
duke@1	2845	cl = candidates.toList();
duke@1	2846	}
duke@1	2847	return classes.appendList(interfaces).toList();
duke@1	2848	}
duke@1	2849
duke@1	2850	/**
duke@1	2851	* Return the least upper bound of pair of types. if the lub does
duke@1	2852	* not exist return null.
duke@1	2853	*/
duke@1	2854	public Type lub(Type t1, Type t2) {
duke@1	2855	return lub(List.of(t1, t2));
duke@1	2856	}
duke@1	2857
duke@1	2858	/**
duke@1	2859	* Return the least upper bound (lub) of set of types. If the lub
duke@1	2860	* does not exist return the type of null (bottom).
duke@1	2861	*/
duke@1	2862	public Type lub(List<Type> ts) {
duke@1	2863	final int ARRAY_BOUND = 1;
duke@1	2864	final int CLASS_BOUND = 2;
duke@1	2865	int boundkind = 0;
duke@1	2866	for (Type t : ts) {
duke@1	2867	switch (t.tag) {
duke@1	2868	case CLASS:
duke@1	2869	boundkind |= CLASS_BOUND;
duke@1	2870	break;
duke@1	2871	case ARRAY:
duke@1	2872	boundkind |= ARRAY_BOUND;
duke@1	2873	break;
duke@1	2874	case TYPEVAR:
duke@1	2875	do {
duke@1	2876	t = t.getUpperBound();
duke@1	2877	} while (t.tag == TYPEVAR);
duke@1	2878	if (t.tag == ARRAY) {
duke@1	2879	boundkind |= ARRAY_BOUND;
duke@1	2880	} else {
duke@1	2881	boundkind |= CLASS_BOUND;
duke@1	2882	}
duke@1	2883	break;
duke@1	2884	default:
duke@1	2885	if (t.isPrimitive())
mcimadamore@5	2886	return syms.errType;
duke@1	2887	}
duke@1	2888	}
duke@1	2889	switch (boundkind) {
duke@1	2890	case 0:
duke@1	2891	return syms.botType;
duke@1	2892
duke@1	2893	case ARRAY_BOUND:
duke@1	2894	// calculate lub(A[], B[])
duke@1	2895	List<Type> elements = Type.map(ts, elemTypeFun);
duke@1	2896	for (Type t : elements) {
duke@1	2897	if (t.isPrimitive()) {
duke@1	2898	// if a primitive type is found, then return
duke@1	2899	// arraySuperType unless all the types are the
duke@1	2900	// same
duke@1	2901	Type first = ts.head;
duke@1	2902	for (Type s : ts.tail) {
duke@1	2903	if (!isSameType(first, s)) {
duke@1	2904	// lub(int[], B[]) is Cloneable & Serializable
duke@1	2905	return arraySuperType();
duke@1	2906	}
duke@1	2907	}
duke@1	2908	// all the array types are the same, return one
duke@1	2909	// lub(int[], int[]) is int[]
duke@1	2910	return first;
duke@1	2911	}
duke@1	2912	}
duke@1	2913	// lub(A[], B[]) is lub(A, B)[]
duke@1	2914	return new ArrayType(lub(elements), syms.arrayClass);
duke@1	2915
duke@1	2916	case CLASS_BOUND:
duke@1	2917	// calculate lub(A, B)
duke@1	2918	while (ts.head.tag != CLASS && ts.head.tag != TYPEVAR)
duke@1	2919	ts = ts.tail;
jjg@816	2920	Assert.check(!ts.isEmpty());
mcimadamore@896	2921	//step 1 - compute erased candidate set (EC)
mcimadamore@896	2922	List<Type> cl = erasedSupertypes(ts.head);
duke@1	2923	for (Type t : ts.tail) {
duke@1	2924	if (t.tag == CLASS || t.tag == TYPEVAR)
mcimadamore@896	2925	cl = intersect(cl, erasedSupertypes(t));
duke@1	2926	}
mcimadamore@896	2927	//step 2 - compute minimal erased candidate set (MEC)
mcimadamore@896	2928	List<Type> mec = closureMin(cl);
mcimadamore@896	2929	//step 3 - for each element G in MEC, compute lci(Inv(G))
mcimadamore@896	2930	List<Type> candidates = List.nil();
mcimadamore@896	2931	for (Type erasedSupertype : mec) {
mcimadamore@896	2932	List<Type> lci = List.of(asSuper(ts.head, erasedSupertype.tsym));
mcimadamore@896	2933	for (Type t : ts) {
mcimadamore@896	2934	lci = intersect(lci, List.of(asSuper(t, erasedSupertype.tsym)));
mcimadamore@896	2935	}
mcimadamore@896	2936	candidates = candidates.appendList(lci);
mcimadamore@896	2937	}
mcimadamore@896	2938	//step 4 - let MEC be { G1, G2 ... Gn }, then we have that
mcimadamore@896	2939	//lub = lci(Inv(G1)) & lci(Inv(G2)) & ... & lci(Inv(Gn))
mcimadamore@896	2940	return compoundMin(candidates);
duke@1	2941
duke@1	2942	default:
duke@1	2943	// calculate lub(A, B[])
duke@1	2944	List<Type> classes = List.of(arraySuperType());
duke@1	2945	for (Type t : ts) {
duke@1	2946	if (t.tag != ARRAY) // Filter out any arrays
duke@1	2947	classes = classes.prepend(t);
duke@1	2948	}
duke@1	2949	// lub(A, B[]) is lub(A, arraySuperType)
duke@1	2950	return lub(classes);
duke@1	2951	}
duke@1	2952	}
duke@1	2953	// where
mcimadamore@896	2954	List<Type> erasedSupertypes(Type t) {
mcimadamore@896	2955	ListBuffer<Type> buf = lb();
mcimadamore@896	2956	for (Type sup : closure(t)) {
mcimadamore@896	2957	if (sup.tag == TYPEVAR) {
mcimadamore@896	2958	buf.append(sup);
mcimadamore@896	2959	} else {
mcimadamore@896	2960	buf.append(erasure(sup));
mcimadamore@896	2961	}
mcimadamore@896	2962	}
mcimadamore@896	2963	return buf.toList();
mcimadamore@896	2964	}
mcimadamore@896	2965
duke@1	2966	private Type arraySuperType = null;
duke@1	2967	private Type arraySuperType() {
duke@1	2968	// initialized lazily to avoid problems during compiler startup
duke@1	2969	if (arraySuperType == null) {
duke@1	2970	synchronized (this) {
duke@1	2971	if (arraySuperType == null) {
duke@1	2972	// JLS 10.8: all arrays implement Cloneable and Serializable.
duke@1	2973	arraySuperType = makeCompoundType(List.of(syms.serializableType,
duke@1	2974	syms.cloneableType),
duke@1	2975	syms.objectType);
duke@1	2976	}
duke@1	2977	}
duke@1	2978	}
duke@1	2979	return arraySuperType;
duke@1	2980	}
duke@1	2981	// </editor-fold>
duke@1	2982
duke@1	2983	// <editor-fold defaultstate="collapsed" desc="Greatest lower bound">
mcimadamore@210	2984	public Type glb(List<Type> ts) {
mcimadamore@210	2985	Type t1 = ts.head;
mcimadamore@210	2986	for (Type t2 : ts.tail) {
mcimadamore@210	2987	if (t1.isErroneous())
mcimadamore@210	2988	return t1;
mcimadamore@210	2989	t1 = glb(t1, t2);
mcimadamore@210	2990	}
mcimadamore@210	2991	return t1;
mcimadamore@210	2992	}
mcimadamore@210	2993	//where
duke@1	2994	public Type glb(Type t, Type s) {
duke@1	2995	if (s == null)
duke@1	2996	return t;
mcimadamore@753	2997	else if (t.isPrimitive() || s.isPrimitive())
mcimadamore@753	2998	return syms.errType;
duke@1	2999	else if (isSubtypeNoCapture(t, s))
duke@1	3000	return t;
duke@1	3001	else if (isSubtypeNoCapture(s, t))
duke@1	3002	return s;
duke@1	3003
duke@1	3004	List<Type> closure = union(closure(t), closure(s));
duke@1	3005	List<Type> bounds = closureMin(closure);
duke@1	3006
duke@1	3007	if (bounds.isEmpty()) { // length == 0
duke@1	3008	return syms.objectType;
duke@1	3009	} else if (bounds.tail.isEmpty()) { // length == 1
duke@1	3010	return bounds.head;
duke@1	3011	} else { // length > 1
duke@1	3012	int classCount = 0;
duke@1	3013	for (Type bound : bounds)
duke@1	3014	if (!bound.isInterface())
duke@1	3015	classCount++;
duke@1	3016	if (classCount > 1)
jjg@110	3017	return createErrorType(t);
duke@1	3018	}
duke@1	3019	return makeCompoundType(bounds);
duke@1	3020	}
duke@1	3021	// </editor-fold>
duke@1	3022
duke@1	3023	// <editor-fold defaultstate="collapsed" desc="hashCode">
duke@1	3024	/**
duke@1	3025	* Compute a hash code on a type.
duke@1	3026	*/
duke@1	3027	public static int hashCode(Type t) {
duke@1	3028	return hashCode.visit(t);
duke@1	3029	}
duke@1	3030	// where
duke@1	3031	private static final UnaryVisitor<Integer> hashCode = new UnaryVisitor<Integer>() {
duke@1	3032
duke@1	3033	public Integer visitType(Type t, Void ignored) {
duke@1	3034	return t.tag;
duke@1	3035	}
duke@1	3036
duke@1	3037	@Override
duke@1	3038	public Integer visitClassType(ClassType t, Void ignored) {
duke@1	3039	int result = visit(t.getEnclosingType());
duke@1	3040	result *= 127;
duke@1	3041	result += t.tsym.flatName().hashCode();
duke@1	3042	for (Type s : t.getTypeArguments()) {
duke@1	3043	result *= 127;
duke@1	3044	result += visit(s);
duke@1	3045	}
duke@1	3046	return result;
duke@1	3047	}
duke@1	3048
duke@1	3049	@Override
duke@1	3050	public Integer visitWildcardType(WildcardType t, Void ignored) {
duke@1	3051	int result = t.kind.hashCode();
duke@1	3052	if (t.type != null) {
duke@1	3053	result *= 127;
duke@1	3054	result += visit(t.type);
duke@1	3055	}
duke@1	3056	return result;
duke@1	3057	}
duke@1	3058
duke@1	3059	@Override
duke@1	3060	public Integer visitArrayType(ArrayType t, Void ignored) {
duke@1	3061	return visit(t.elemtype) + 12;
duke@1	3062	}
duke@1	3063
duke@1	3064	@Override
duke@1	3065	public Integer visitTypeVar(TypeVar t, Void ignored) {
duke@1	3066	return System.identityHashCode(t.tsym);
duke@1	3067	}
duke@1	3068
duke@1	3069	@Override
duke@1	3070	public Integer visitUndetVar(UndetVar t, Void ignored) {
duke@1	3071	return System.identityHashCode(t);
duke@1	3072	}
duke@1	3073
duke@1	3074	@Override
duke@1	3075	public Integer visitErrorType(ErrorType t, Void ignored) {
duke@1	3076	return 0;
duke@1	3077	}
duke@1	3078	};
duke@1	3079	// </editor-fold>
duke@1	3080
duke@1	3081	// <editor-fold defaultstate="collapsed" desc="Return-Type-Substitutable">
duke@1	3082	/**
duke@1	3083	* Does t have a result that is a subtype of the result type of s,
duke@1	3084	* suitable for covariant returns? It is assumed that both types
duke@1	3085	* are (possibly polymorphic) method types. Monomorphic method
duke@1	3086	* types are handled in the obvious way. Polymorphic method types
duke@1	3087	* require renaming all type variables of one to corresponding
duke@1	3088	* type variables in the other, where correspondence is by
duke@1	3089	* position in the type parameter list. */
duke@1	3090	public boolean resultSubtype(Type t, Type s, Warner warner) {
duke@1	3091	List<Type> tvars = t.getTypeArguments();
duke@1	3092	List<Type> svars = s.getTypeArguments();
duke@1	3093	Type tres = t.getReturnType();
duke@1	3094	Type sres = subst(s.getReturnType(), svars, tvars);
duke@1	3095	return covariantReturnType(tres, sres, warner);
duke@1	3096	}
duke@1	3097
duke@1	3098	/**
duke@1	3099	* Return-Type-Substitutable.
jjh@972	3100	* @jls section 8.4.5
duke@1	3101	*/
duke@1	3102	public boolean returnTypeSubstitutable(Type r1, Type r2) {
duke@1	3103	if (hasSameArgs(r1, r2))
tbell@202	3104	return resultSubtype(r1, r2, Warner.noWarnings);
duke@1	3105	else
duke@1	3106	return covariantReturnType(r1.getReturnType(),
tbell@202	3107	erasure(r2.getReturnType()),
tbell@202	3108	Warner.noWarnings);
tbell@202	3109	}
tbell@202	3110
tbell@202	3111	public boolean returnTypeSubstitutable(Type r1,
tbell@202	3112	Type r2, Type r2res,
tbell@202	3113	Warner warner) {
tbell@202	3114	if (isSameType(r1.getReturnType(), r2res))
tbell@202	3115	return true;
tbell@202	3116	if (r1.getReturnType().isPrimitive() || r2res.isPrimitive())
tbell@202	3117	return false;
tbell@202	3118
tbell@202	3119	if (hasSameArgs(r1, r2))
tbell@202	3120	return covariantReturnType(r1.getReturnType(), r2res, warner);
jjg@984	3121	if (!allowCovariantReturns)
tbell@202	3122	return false;
tbell@202	3123	if (isSubtypeUnchecked(r1.getReturnType(), r2res, warner))
tbell@202	3124	return true;
tbell@202	3125	if (!isSubtype(r1.getReturnType(), erasure(r2res)))
tbell@202	3126	return false;
mcimadamore@795	3127	warner.warn(LintCategory.UNCHECKED);
tbell@202	3128	return true;
duke@1	3129	}
duke@1	3130
duke@1	3131	/**
duke@1	3132	* Is t an appropriate return type in an overrider for a
duke@1	3133	* method that returns s?
duke@1	3134	*/
duke@1	3135	public boolean covariantReturnType(Type t, Type s, Warner warner) {
tbell@202	3136	return
tbell@202	3137	isSameType(t, s) ||
jjg@984	3138	allowCovariantReturns &&
duke@1	3139	!t.isPrimitive() &&
tbell@202	3140	!s.isPrimitive() &&
tbell@202	3141	isAssignable(t, s, warner);
duke@1	3142	}
duke@1	3143	// </editor-fold>
duke@1	3144
duke@1	3145	// <editor-fold defaultstate="collapsed" desc="Box/unbox support">
duke@1	3146	/**
duke@1	3147	* Return the class that boxes the given primitive.
duke@1	3148	*/
duke@1	3149	public ClassSymbol boxedClass(Type t) {
duke@1	3150	return reader.enterClass(syms.boxedName[t.tag]);
duke@1	3151	}
duke@1	3152
duke@1	3153	/**
mcimadamore@753	3154	* Return the boxed type if 't' is primitive, otherwise return 't' itself.
mcimadamore@753	3155	*/
mcimadamore@753	3156	public Type boxedTypeOrType(Type t) {
mcimadamore@753	3157	return t.isPrimitive() ?
mcimadamore@753	3158	boxedClass(t).type :
mcimadamore@753	3159	t;
mcimadamore@753	3160	}
mcimadamore@753	3161
mcimadamore@753	3162	/**
duke@1	3163	* Return the primitive type corresponding to a boxed type.
duke@1	3164	*/
duke@1	3165	public Type unboxedType(Type t) {
duke@1	3166	if (allowBoxing) {
duke@1	3167	for (int i=0; i<syms.boxedName.length; i++) {
duke@1	3168	Name box = syms.boxedName[i];
duke@1	3169	if (box != null &&
duke@1	3170	asSuper(t, reader.enterClass(box)) != null)
duke@1	3171	return syms.typeOfTag[i];
duke@1	3172	}
duke@1	3173	}
duke@1	3174	return Type.noType;
duke@1	3175	}
duke@1	3176	// </editor-fold>
duke@1	3177
duke@1	3178	// <editor-fold defaultstate="collapsed" desc="Capture conversion">
duke@1	3179	/*
jjh@972	3180	* JLS 5.1.10 Capture Conversion:
duke@1	3181	*
duke@1	3182	* Let G name a generic type declaration with n formal type
duke@1	3183	* parameters A1 ... An with corresponding bounds U1 ... Un. There
duke@1	3184	* exists a capture conversion from G<T1 ... Tn> to G<S1 ... Sn>,
duke@1	3185	* where, for 1 <= i <= n:
duke@1	3186	*
duke@1	3187	* + If Ti is a wildcard type argument (4.5.1) of the form ? then
duke@1	3188	* Si is a fresh type variable whose upper bound is
duke@1	3189	* Ui[A1 := S1, ..., An := Sn] and whose lower bound is the null
duke@1	3190	* type.
duke@1	3191	*
duke@1	3192	* + If Ti is a wildcard type argument of the form ? extends Bi,
duke@1	3193	* then Si is a fresh type variable whose upper bound is
duke@1	3194	* glb(Bi, Ui[A1 := S1, ..., An := Sn]) and whose lower bound is
duke@1	3195	* the null type, where glb(V1,... ,Vm) is V1 & ... & Vm. It is
duke@1	3196	* a compile-time error if for any two classes (not interfaces)
duke@1	3197	* Vi and Vj,Vi is not a subclass of Vj or vice versa.
duke@1	3198	*
duke@1	3199	* + If Ti is a wildcard type argument of the form ? super Bi,
duke@1	3200	* then Si is a fresh type variable whose upper bound is
duke@1	3201	* Ui[A1 := S1, ..., An := Sn] and whose lower bound is Bi.
duke@1	3202	*
duke@1	3203	* + Otherwise, Si = Ti.
duke@1	3204	*
duke@1	3205	* Capture conversion on any type other than a parameterized type
duke@1	3206	* (4.5) acts as an identity conversion (5.1.1). Capture
duke@1	3207	* conversions never require a special action at run time and
duke@1	3208	* therefore never throw an exception at run time.
duke@1	3209	*
duke@1	3210	* Capture conversion is not applied recursively.
duke@1	3211	*/
duke@1	3212	/**
jjh@972	3213	* Capture conversion as specified by the JLS.
duke@1	3214	*/
mcimadamore@299	3215
mcimadamore@299	3216	public List<Type> capture(List<Type> ts) {
mcimadamore@299	3217	List<Type> buf = List.nil();
mcimadamore@299	3218	for (Type t : ts) {
mcimadamore@299	3219	buf = buf.prepend(capture(t));
mcimadamore@299	3220	}
mcimadamore@299	3221	return buf.reverse();
mcimadamore@299	3222	}
duke@1	3223	public Type capture(Type t) {
duke@1	3224	if (t.tag != CLASS)
duke@1	3225	return t;
mcimadamore@637	3226	if (t.getEnclosingType() != Type.noType) {
mcimadamore@637	3227	Type capturedEncl = capture(t.getEnclosingType());
mcimadamore@637	3228	if (capturedEncl != t.getEnclosingType()) {
mcimadamore@637	3229	Type type1 = memberType(capturedEncl, t.tsym);
mcimadamore@637	3230	t = subst(type1, t.tsym.type.getTypeArguments(), t.getTypeArguments());
mcimadamore@637	3231	}
mcimadamore@637	3232	}
duke@1	3233	ClassType cls = (ClassType)t;
duke@1	3234	if (cls.isRaw() || !cls.isParameterized())
duke@1	3235	return cls;
duke@1	3236
duke@1	3237	ClassType G = (ClassType)cls.asElement().asType();
duke@1	3238	List<Type> A = G.getTypeArguments();
duke@1	3239	List<Type> T = cls.getTypeArguments();
duke@1	3240	List<Type> S = freshTypeVariables(T);
duke@1	3241
duke@1	3242	List<Type> currentA = A;
duke@1	3243	List<Type> currentT = T;
duke@1	3244	List<Type> currentS = S;
duke@1	3245	boolean captured = false;
duke@1	3246	while (!currentA.isEmpty() &&
duke@1	3247	!currentT.isEmpty() &&
duke@1	3248	!currentS.isEmpty()) {
duke@1	3249	if (currentS.head != currentT.head) {
duke@1	3250	captured = true;
duke@1	3251	WildcardType Ti = (WildcardType)currentT.head;
duke@1	3252	Type Ui = currentA.head.getUpperBound();
duke@1	3253	CapturedType Si = (CapturedType)currentS.head;
duke@1	3254	if (Ui == null)
duke@1	3255	Ui = syms.objectType;
duke@1	3256	switch (Ti.kind) {
duke@1	3257	case UNBOUND:
duke@1	3258	Si.bound = subst(Ui, A, S);
duke@1	3259	Si.lower = syms.botType;
duke@1	3260	break;
duke@1	3261	case EXTENDS:
duke@1	3262	Si.bound = glb(Ti.getExtendsBound(), subst(Ui, A, S));
duke@1	3263	Si.lower = syms.botType;
duke@1	3264	break;
duke@1	3265	case SUPER:
duke@1	3266	Si.bound = subst(Ui, A, S);
duke@1	3267	Si.lower = Ti.getSuperBound();
duke@1	3268	break;
duke@1	3269	}
duke@1	3270	if (Si.bound == Si.lower)
duke@1	3271	currentS.head = Si.bound;
duke@1	3272	}
duke@1	3273	currentA = currentA.tail;
duke@1	3274	currentT = currentT.tail;
duke@1	3275	currentS = currentS.tail;
duke@1	3276	}
duke@1	3277	if (!currentA.isEmpty() || !currentT.isEmpty() || !currentS.isEmpty())
duke@1	3278	return erasure(t); // some "rare" type involved
duke@1	3279
duke@1	3280	if (captured)
duke@1	3281	return new ClassType(cls.getEnclosingType(), S, cls.tsym);
duke@1	3282	else
duke@1	3283	return t;
duke@1	3284	}
duke@1	3285	// where
mcimadamore@238	3286	public List<Type> freshTypeVariables(List<Type> types) {
duke@1	3287	ListBuffer<Type> result = lb();
duke@1	3288	for (Type t : types) {
duke@1	3289	if (t.tag == WILDCARD) {
duke@1	3290	Type bound = ((WildcardType)t).getExtendsBound();
duke@1	3291	if (bound == null)
duke@1	3292	bound = syms.objectType;
duke@1	3293	result.append(new CapturedType(capturedName,
duke@1	3294	syms.noSymbol,
duke@1	3295	bound,
duke@1	3296	syms.botType,
duke@1	3297	(WildcardType)t));
duke@1	3298	} else {
duke@1	3299	result.append(t);
duke@1	3300	}
duke@1	3301	}
duke@1	3302	return result.toList();
duke@1	3303	}
duke@1	3304	// </editor-fold>
duke@1	3305
duke@1	3306	// <editor-fold defaultstate="collapsed" desc="Internal utility methods">
duke@1	3307	private List<Type> upperBounds(List<Type> ss) {
duke@1	3308	if (ss.isEmpty()) return ss;
duke@1	3309	Type head = upperBound(ss.head);
duke@1	3310	List<Type> tail = upperBounds(ss.tail);
duke@1	3311	if (head != ss.head || tail != ss.tail)
duke@1	3312	return tail.prepend(head);
duke@1	3313	else
duke@1	3314	return ss;
duke@1	3315	}
duke@1	3316
duke@1	3317	private boolean sideCast(Type from, Type to, Warner warn) {
duke@1	3318	// We are casting from type $from$ to type $to$, which are
duke@1	3319	// non-final unrelated types. This method
duke@1	3320	// tries to reject a cast by transferring type parameters
duke@1	3321	// from $to$ to $from$ by common superinterfaces.
duke@1	3322	boolean reverse = false;
duke@1	3323	Type target = to;
duke@1	3324	if ((to.tsym.flags() & INTERFACE) == 0) {
jjg@816	3325	Assert.check((from.tsym.flags() & INTERFACE) != 0);
duke@1	3326	reverse = true;
duke@1	3327	to = from;
duke@1	3328	from = target;
duke@1	3329	}
duke@1	3330	List<Type> commonSupers = superClosure(to, erasure(from));
duke@1	3331	boolean giveWarning = commonSupers.isEmpty();
duke@1	3332	// The arguments to the supers could be unified here to
duke@1	3333	// get a more accurate analysis
duke@1	3334	while (commonSupers.nonEmpty()) {
duke@1	3335	Type t1 = asSuper(from, commonSupers.head.tsym);
duke@1	3336	Type t2 = commonSupers.head; // same as asSuper(to, commonSupers.head.tsym);
duke@1	3337	if (disjointTypes(t1.getTypeArguments(), t2.getTypeArguments()))
duke@1	3338	return false;
duke@1	3339	giveWarning = giveWarning || (reverse ? giveWarning(t2, t1) : giveWarning(t1, t2));
duke@1	3340	commonSupers = commonSupers.tail;
duke@1	3341	}
mcimadamore@187	3342	if (giveWarning && !isReifiable(reverse ? from : to))
mcimadamore@795	3343	warn.warn(LintCategory.UNCHECKED);
jjg@984	3344	if (!allowCovariantReturns)
duke@1	3345	// reject if there is a common method signature with
duke@1	3346	// incompatible return types.
duke@1	3347	chk.checkCompatibleAbstracts(warn.pos(), from, to);
duke@1	3348	return true;
duke@1	3349	}
duke@1	3350
duke@1	3351	private boolean sideCastFinal(Type from, Type to, Warner warn) {
duke@1	3352	// We are casting from type $from$ to type $to$, which are
duke@1	3353	// unrelated types one of which is final and the other of
duke@1	3354	// which is an interface. This method
duke@1	3355	// tries to reject a cast by transferring type parameters
duke@1	3356	// from the final class to the interface.
duke@1	3357	boolean reverse = false;
duke@1	3358	Type target = to;
duke@1	3359	if ((to.tsym.flags() & INTERFACE) == 0) {
jjg@816	3360	Assert.check((from.tsym.flags() & INTERFACE) != 0);
duke@1	3361	reverse = true;
duke@1	3362	to = from;
duke@1	3363	from = target;
duke@1	3364	}
jjg@816	3365	Assert.check((from.tsym.flags() & FINAL) != 0);
duke@1	3366	Type t1 = asSuper(from, to.tsym);
duke@1	3367	if (t1 == null) return false;
duke@1	3368	Type t2 = to;
duke@1	3369	if (disjointTypes(t1.getTypeArguments(), t2.getTypeArguments()))
duke@1	3370	return false;
jjg@984	3371	if (!allowCovariantReturns)
duke@1	3372	// reject if there is a common method signature with
duke@1	3373	// incompatible return types.
duke@1	3374	chk.checkCompatibleAbstracts(warn.pos(), from, to);
duke@1	3375	if (!isReifiable(target) &&
duke@1	3376	(reverse ? giveWarning(t2, t1) : giveWarning(t1, t2)))
mcimadamore@795	3377	warn.warn(LintCategory.UNCHECKED);
duke@1	3378	return true;
duke@1	3379	}
duke@1	3380
duke@1	3381	private boolean giveWarning(Type from, Type to) {
mcimadamore@235	3382	Type subFrom = asSub(from, to.tsym);
mcimadamore@235	3383	return to.isParameterized() &&
mcimadamore@235	3384	(!(isUnbounded(to) ||
mcimadamore@235	3385	isSubtype(from, to) ||
mcimadamore@736	3386	((subFrom != null) && containsType(to.allparams(), subFrom.allparams()))));
duke@1	3387	}
duke@1	3388
duke@1	3389	private List<Type> superClosure(Type t, Type s) {
duke@1	3390	List<Type> cl = List.nil();
duke@1	3391	for (List<Type> l = interfaces(t); l.nonEmpty(); l = l.tail) {
duke@1	3392	if (isSubtype(s, erasure(l.head))) {
duke@1	3393	cl = insert(cl, l.head);
duke@1	3394	} else {
duke@1	3395	cl = union(cl, superClosure(l.head, s));
duke@1	3396	}
duke@1	3397	}
duke@1	3398	return cl;
duke@1	3399	}
duke@1	3400
duke@1	3401	private boolean containsTypeEquivalent(Type t, Type s) {
duke@1	3402	return
duke@1	3403	isSameType(t, s) || // shortcut
duke@1	3404	containsType(t, s) && containsType(s, t);
duke@1	3405	}
duke@1	3406
mcimadamore@138	3407	// <editor-fold defaultstate="collapsed" desc="adapt">
duke@1	3408	/**
duke@1	3409	* Adapt a type by computing a substitution which maps a source
duke@1	3410	* type to a target type.
duke@1	3411	*
duke@1	3412	* @param source the source type
duke@1	3413	* @param target the target type
duke@1	3414	* @param from the type variables of the computed substitution
duke@1	3415	* @param to the types of the computed substitution.
duke@1	3416	*/
duke@1	3417	public void adapt(Type source,
duke@1	3418	Type target,
duke@1	3419	ListBuffer<Type> from,
duke@1	3420	ListBuffer<Type> to) throws AdaptFailure {
mcimadamore@138	3421	new Adapter(from, to).adapt(source, target);
mcimadamore@138	3422	}
mcimadamore@138	3423
mcimadamore@138	3424	class Adapter extends SimpleVisitor<Void, Type> {
mcimadamore@138	3425
mcimadamore@138	3426	ListBuffer<Type> from;
mcimadamore@138	3427	ListBuffer<Type> to;
mcimadamore@138	3428	Map<Symbol,Type> mapping;
mcimadamore@138	3429
mcimadamore@138	3430	Adapter(ListBuffer<Type> from, ListBuffer<Type> to) {
mcimadamore@138	3431	this.from = from;
mcimadamore@138	3432	this.to = to;
mcimadamore@138	3433	mapping = new HashMap<Symbol,Type>();
duke@1	3434	}
mcimadamore@138	3435
mcimadamore@138	3436	public void adapt(Type source, Type target) throws AdaptFailure {
mcimadamore@138	3437	visit(source, target);
mcimadamore@138	3438	List<Type> fromList = from.toList();
mcimadamore@138	3439	List<Type> toList = to.toList();
mcimadamore@138	3440	while (!fromList.isEmpty()) {
mcimadamore@138	3441	Type val = mapping.get(fromList.head.tsym);
mcimadamore@138	3442	if (toList.head != val)
mcimadamore@138	3443	toList.head = val;
mcimadamore@138	3444	fromList = fromList.tail;
mcimadamore@138	3445	toList = toList.tail;
mcimadamore@138	3446	}
mcimadamore@138	3447	}
mcimadamore@138	3448
mcimadamore@138	3449	@Override
mcimadamore@138	3450	public Void visitClassType(ClassType source, Type target) throws AdaptFailure {
mcimadamore@138	3451	if (target.tag == CLASS)
mcimadamore@138	3452	adaptRecursive(source.allparams(), target.allparams());
mcimadamore@138	3453	return null;
mcimadamore@138	3454	}
mcimadamore@138	3455
mcimadamore@138	3456	@Override
mcimadamore@138	3457	public Void visitArrayType(ArrayType source, Type target) throws AdaptFailure {
mcimadamore@138	3458	if (target.tag == ARRAY)
mcimadamore@138	3459	adaptRecursive(elemtype(source), elemtype(target));
mcimadamore@138	3460	return null;
mcimadamore@138	3461	}
mcimadamore@138	3462
mcimadamore@138	3463	@Override
mcimadamore@138	3464	public Void visitWildcardType(WildcardType source, Type target) throws AdaptFailure {
mcimadamore@138	3465	if (source.isExtendsBound())
mcimadamore@138	3466	adaptRecursive(upperBound(source), upperBound(target));
mcimadamore@138	3467	else if (source.isSuperBound())
mcimadamore@138	3468	adaptRecursive(lowerBound(source), lowerBound(target));
mcimadamore@138	3469	return null;
mcimadamore@138	3470	}
mcimadamore@138	3471
mcimadamore@138	3472	@Override
mcimadamore@138	3473	public Void visitTypeVar(TypeVar source, Type target) throws AdaptFailure {
mcimadamore@138	3474	// Check to see if there is
mcimadamore@138	3475	// already a mapping for $source$, in which case
mcimadamore@138	3476	// the old mapping will be merged with the new
mcimadamore@138	3477	Type val = mapping.get(source.tsym);
mcimadamore@138	3478	if (val != null) {
mcimadamore@138	3479	if (val.isSuperBound() && target.isSuperBound()) {
mcimadamore@138	3480	val = isSubtype(lowerBound(val), lowerBound(target))
mcimadamore@138	3481	? target : val;
mcimadamore@138	3482	} else if (val.isExtendsBound() && target.isExtendsBound()) {
mcimadamore@138	3483	val = isSubtype(upperBound(val), upperBound(target))
mcimadamore@138	3484	? val : target;
mcimadamore@138	3485	} else if (!isSameType(val, target)) {
mcimadamore@138	3486	throw new AdaptFailure();
duke@1	3487	}
mcimadamore@138	3488	} else {
mcimadamore@138	3489	val = target;
mcimadamore@138	3490	from.append(source);
mcimadamore@138	3491	to.append(target);
mcimadamore@138	3492	}
mcimadamore@138	3493	mapping.put(source.tsym, val);
mcimadamore@138	3494	return null;
mcimadamore@138	3495	}
mcimadamore@138	3496
mcimadamore@138	3497	@Override
mcimadamore@138	3498	public Void visitType(Type source, Type target) {
mcimadamore@138	3499	return null;
mcimadamore@138	3500	}
mcimadamore@138	3501
mcimadamore@138	3502	private Set<TypePair> cache = new HashSet<TypePair>();
mcimadamore@138	3503
mcimadamore@138	3504	private void adaptRecursive(Type source, Type target) {
mcimadamore@138	3505	TypePair pair = new TypePair(source, target);
mcimadamore@138	3506	if (cache.add(pair)) {
mcimadamore@138	3507	try {
mcimadamore@138	3508	visit(source, target);
mcimadamore@138	3509	} finally {
mcimadamore@138	3510	cache.remove(pair);
duke@1	3511	}
duke@1	3512	}
duke@1	3513	}
mcimadamore@138	3514
mcimadamore@138	3515	private void adaptRecursive(List<Type> source, List<Type> target) {
mcimadamore@138	3516	if (source.length() == target.length()) {
mcimadamore@138	3517	while (source.nonEmpty()) {
mcimadamore@138	3518	adaptRecursive(source.head, target.head);
mcimadamore@138	3519	source = source.tail;
mcimadamore@138	3520	target = target.tail;
mcimadamore@138	3521	}
duke@1	3522	}
duke@1	3523	}
duke@1	3524	}
duke@1	3525
mcimadamore@138	3526	public static class AdaptFailure extends RuntimeException {
mcimadamore@138	3527	static final long serialVersionUID = -7490231548272701566L;
mcimadamore@138	3528	}
mcimadamore@138	3529
duke@1	3530	private void adaptSelf(Type t,
duke@1	3531	ListBuffer<Type> from,
duke@1	3532	ListBuffer<Type> to) {
duke@1	3533	try {
duke@1	3534	//if (t.tsym.type != t)
duke@1	3535	adapt(t.tsym.type, t, from, to);
duke@1	3536	} catch (AdaptFailure ex) {
duke@1	3537	// Adapt should never fail calculating a mapping from
duke@1	3538	// t.tsym.type to t as there can be no merge problem.
duke@1	3539	throw new AssertionError(ex);
duke@1	3540	}
duke@1	3541	}
mcimadamore@138	3542	// </editor-fold>
duke@1	3543
duke@1	3544	/**
duke@1	3545	* Rewrite all type variables (universal quantifiers) in the given
duke@1	3546	* type to wildcards (existential quantifiers). This is used to
duke@1	3547	* determine if a cast is allowed. For example, if high is true
duke@1	3548	* and {@code T <: Number}, then {@code List<T>} is rewritten to
duke@1	3549	* {@code List<? extends Number>}. Since {@code List<Integer> <:
duke@1	3550	* List<? extends Number>} a {@code List<T>} can be cast to {@code
duke@1	3551	* List<Integer>} with a warning.
duke@1	3552	* @param t a type
duke@1	3553	* @param high if true return an upper bound; otherwise a lower
duke@1	3554	* bound
duke@1	3555	* @param rewriteTypeVars only rewrite captured wildcards if false;
duke@1	3556	* otherwise rewrite all type variables
duke@1	3557	* @return the type rewritten with wildcards (existential
duke@1	3558	* quantifiers) only
duke@1	3559	*/
duke@1	3560	private Type rewriteQuantifiers(Type t, boolean high, boolean rewriteTypeVars) {
mcimadamore@640	3561	return new Rewriter(high, rewriteTypeVars).visit(t);
mcimadamore@157	3562	}
mcimadamore@157	3563
mcimadamore@157	3564	class Rewriter extends UnaryVisitor<Type> {
mcimadamore@157	3565
mcimadamore@157	3566	boolean high;
mcimadamore@157	3567	boolean rewriteTypeVars;
mcimadamore@157	3568
mcimadamore@157	3569	Rewriter(boolean high, boolean rewriteTypeVars) {
mcimadamore@157	3570	this.high = high;
mcimadamore@157	3571	this.rewriteTypeVars = rewriteTypeVars;
mcimadamore@157	3572	}
mcimadamore@157	3573
mcimadamore@640	3574	@Override
mcimadamore@640	3575	public Type visitClassType(ClassType t, Void s) {
mcimadamore@157	3576	ListBuffer<Type> rewritten = new ListBuffer<Type>();
mcimadamore@157	3577	boolean changed = false;
mcimadamore@640	3578	for (Type arg : t.allparams()) {
mcimadamore@157	3579	Type bound = visit(arg);
mcimadamore@157	3580	if (arg != bound) {
mcimadamore@157	3581	changed = true;
mcimadamore@157	3582	}
mcimadamore@157	3583	rewritten.append(bound);
duke@1	3584	}
mcimadamore@157	3585	if (changed)
mcimadamore@640	3586	return subst(t.tsym.type,
mcimadamore@640	3587	t.tsym.type.allparams(),
mcimadamore@640	3588	rewritten.toList());
mcimadamore@157	3589	else
mcimadamore@157	3590	return t;
duke@1	3591	}
mcimadamore@157	3592
mcimadamore@157	3593	public Type visitType(Type t, Void s) {
mcimadamore@157	3594	return high ? upperBound(t) : lowerBound(t);
mcimadamore@157	3595	}
mcimadamore@157	3596
mcimadamore@157	3597	@Override
mcimadamore@157	3598	public Type visitCapturedType(CapturedType t, Void s) {
mcimadamore@640	3599	Type bound = visitWildcardType(t.wildcard, null);
mcimadamore@640	3600	return (bound.contains(t)) ?
mcimadamore@779	3601	erasure(bound) :
mcimadamore@779	3602	bound;
mcimadamore@157	3603	}
mcimadamore@157	3604
mcimadamore@157	3605	@Override
mcimadamore@157	3606	public Type visitTypeVar(TypeVar t, Void s) {
mcimadamore@640	3607	if (rewriteTypeVars) {
mcimadamore@640	3608	Type bound = high ?
mcimadamore@640	3609	(t.bound.contains(t) ?
mcimadamore@779	3610	erasure(t.bound) :
mcimadamore@640	3611	visit(t.bound)) :
mcimadamore@640	3612	syms.botType;
mcimadamore@640	3613	return rewriteAsWildcardType(bound, t);
mcimadamore@640	3614	}
mcimadamore@157	3615	else
mcimadamore@157	3616	return t;
mcimadamore@157	3617	}
mcimadamore@157	3618
mcimadamore@157	3619	@Override
mcimadamore@157	3620	public Type visitWildcardType(WildcardType t, Void s) {
mcimadamore@157	3621	Type bound = high ? t.getExtendsBound() :
mcimadamore@157	3622	t.getSuperBound();
mcimadamore@157	3623	if (bound == null)
mcimadamore@640	3624	bound = high ? syms.objectType : syms.botType;
mcimadamore@640	3625	return rewriteAsWildcardType(visit(bound), t.bound);
mcimadamore@640	3626	}
mcimadamore@640	3627
mcimadamore@640	3628	private Type rewriteAsWildcardType(Type bound, TypeVar formal) {
mcimadamore@640	3629	return high ?
mcimadamore@640	3630	makeExtendsWildcard(B(bound), formal) :
mcimadamore@640	3631	makeSuperWildcard(B(bound), formal);
mcimadamore@640	3632	}
mcimadamore@640	3633
mcimadamore@640	3634	Type B(Type t) {
mcimadamore@640	3635	while (t.tag == WILDCARD) {
mcimadamore@640	3636	WildcardType w = (WildcardType)t;
mcimadamore@640	3637	t = high ?
mcimadamore@640	3638	w.getExtendsBound() :
mcimadamore@640	3639	w.getSuperBound();
mcimadamore@640	3640	if (t == null) {
mcimadamore@640	3641	t = high ? syms.objectType : syms.botType;
mcimadamore@640	3642	}
mcimadamore@640	3643	}
mcimadamore@640	3644	return t;
mcimadamore@157	3645	}
duke@1	3646	}
duke@1	3647
mcimadamore@640	3648
duke@1	3649	/**
duke@1	3650	* Create a wildcard with the given upper (extends) bound; create
duke@1	3651	* an unbounded wildcard if bound is Object.
duke@1	3652	*
duke@1	3653	* @param bound the upper bound
duke@1	3654	* @param formal the formal type parameter that will be
duke@1	3655	* substituted by the wildcard
duke@1	3656	*/
duke@1	3657	private WildcardType makeExtendsWildcard(Type bound, TypeVar formal) {
duke@1	3658	if (bound == syms.objectType) {
duke@1	3659	return new WildcardType(syms.objectType,
duke@1	3660	BoundKind.UNBOUND,
duke@1	3661	syms.boundClass,
duke@1	3662	formal);
duke@1	3663	} else {
duke@1	3664	return new WildcardType(bound,
duke@1	3665	BoundKind.EXTENDS,
duke@1	3666	syms.boundClass,
duke@1	3667	formal);
duke@1	3668	}
duke@1	3669	}
duke@1	3670
duke@1	3671	/**
duke@1	3672	* Create a wildcard with the given lower (super) bound; create an
duke@1	3673	* unbounded wildcard if bound is bottom (type of {@code null}).
duke@1	3674	*
duke@1	3675	* @param bound the lower bound
duke@1	3676	* @param formal the formal type parameter that will be
duke@1	3677	* substituted by the wildcard
duke@1	3678	*/
duke@1	3679	private WildcardType makeSuperWildcard(Type bound, TypeVar formal) {
duke@1	3680	if (bound.tag == BOT) {
duke@1	3681	return new WildcardType(syms.objectType,
duke@1	3682	BoundKind.UNBOUND,
duke@1	3683	syms.boundClass,
duke@1	3684	formal);
duke@1	3685	} else {
duke@1	3686	return new WildcardType(bound,
duke@1	3687	BoundKind.SUPER,
duke@1	3688	syms.boundClass,
duke@1	3689	formal);
duke@1	3690	}
duke@1	3691	}
duke@1	3692
duke@1	3693	/**
duke@1	3694	* A wrapper for a type that allows use in sets.
duke@1	3695	*/
duke@1	3696	class SingletonType {
duke@1	3697	final Type t;
duke@1	3698	SingletonType(Type t) {
duke@1	3699	this.t = t;
duke@1	3700	}
duke@1	3701	public int hashCode() {
jjg@507	3702	return Types.hashCode(t);
duke@1	3703	}
duke@1	3704	public boolean equals(Object obj) {
duke@1	3705	return (obj instanceof SingletonType) &&
duke@1	3706	isSameType(t, ((SingletonType)obj).t);
duke@1	3707	}
duke@1	3708	public String toString() {
duke@1	3709	return t.toString();
duke@1	3710	}
duke@1	3711	}
duke@1	3712	// </editor-fold>
duke@1	3713
duke@1	3714	// <editor-fold defaultstate="collapsed" desc="Visitors">
duke@1	3715	/**
duke@1	3716	* A default visitor for types. All visitor methods except
duke@1	3717	* visitType are implemented by delegating to visitType. Concrete
duke@1	3718	* subclasses must provide an implementation of visitType and can
duke@1	3719	* override other methods as needed.
duke@1	3720	*
duke@1	3721	* @param <R> the return type of the operation implemented by this
duke@1	3722	* visitor; use Void if no return type is needed.
duke@1	3723	* @param <S> the type of the second argument (the first being the
duke@1	3724	* type itself) of the operation implemented by this visitor; use
duke@1	3725	* Void if a second argument is not needed.
duke@1	3726	*/
duke@1	3727	public static abstract class DefaultTypeVisitor<R,S> implements Type.Visitor<R,S> {
duke@1	3728	final public R visit(Type t, S s) { return t.accept(this, s); }
duke@1	3729	public R visitClassType(ClassType t, S s) { return visitType(t, s); }
duke@1	3730	public R visitWildcardType(WildcardType t, S s) { return visitType(t, s); }
duke@1	3731	public R visitArrayType(ArrayType t, S s) { return visitType(t, s); }
duke@1	3732	public R visitMethodType(MethodType t, S s) { return visitType(t, s); }
duke@1	3733	public R visitPackageType(PackageType t, S s) { return visitType(t, s); }
duke@1	3734	public R visitTypeVar(TypeVar t, S s) { return visitType(t, s); }
duke@1	3735	public R visitCapturedType(CapturedType t, S s) { return visitType(t, s); }
duke@1	3736	public R visitForAll(ForAll t, S s) { return visitType(t, s); }
duke@1	3737	public R visitUndetVar(UndetVar t, S s) { return visitType(t, s); }
duke@1	3738	public R visitErrorType(ErrorType t, S s) { return visitType(t, s); }
duke@1	3739	}
duke@1	3740
duke@1	3741	/**
mcimadamore@121	3742	* A default visitor for symbols. All visitor methods except
mcimadamore@121	3743	* visitSymbol are implemented by delegating to visitSymbol. Concrete
mcimadamore@121	3744	* subclasses must provide an implementation of visitSymbol and can
mcimadamore@121	3745	* override other methods as needed.
mcimadamore@121	3746	*
mcimadamore@121	3747	* @param <R> the return type of the operation implemented by this
mcimadamore@121	3748	* visitor; use Void if no return type is needed.
mcimadamore@121	3749	* @param <S> the type of the second argument (the first being the
mcimadamore@121	3750	* symbol itself) of the operation implemented by this visitor; use
mcimadamore@121	3751	* Void if a second argument is not needed.
mcimadamore@121	3752	*/
mcimadamore@121	3753	public static abstract class DefaultSymbolVisitor<R,S> implements Symbol.Visitor<R,S> {
mcimadamore@121	3754	final public R visit(Symbol s, S arg) { return s.accept(this, arg); }
mcimadamore@121	3755	public R visitClassSymbol(ClassSymbol s, S arg) { return visitSymbol(s, arg); }
mcimadamore@121	3756	public R visitMethodSymbol(MethodSymbol s, S arg) { return visitSymbol(s, arg); }
mcimadamore@121	3757	public R visitOperatorSymbol(OperatorSymbol s, S arg) { return visitSymbol(s, arg); }
mcimadamore@121	3758	public R visitPackageSymbol(PackageSymbol s, S arg) { return visitSymbol(s, arg); }
mcimadamore@121	3759	public R visitTypeSymbol(TypeSymbol s, S arg) { return visitSymbol(s, arg); }
mcimadamore@121	3760	public R visitVarSymbol(VarSymbol s, S arg) { return visitSymbol(s, arg); }
mcimadamore@121	3761	}
mcimadamore@121	3762
mcimadamore@121	3763	/**
duke@1	3764	* A <em>simple</em> visitor for types. This visitor is simple as
duke@1	3765	* captured wildcards, for-all types (generic methods), and
duke@1	3766	* undetermined type variables (part of inference) are hidden.
duke@1	3767	* Captured wildcards are hidden by treating them as type
duke@1	3768	* variables and the rest are hidden by visiting their qtypes.
duke@1	3769	*
duke@1	3770	* @param <R> the return type of the operation implemented by this
duke@1	3771	* visitor; use Void if no return type is needed.
duke@1	3772	* @param <S> the type of the second argument (the first being the
duke@1	3773	* type itself) of the operation implemented by this visitor; use
duke@1	3774	* Void if a second argument is not needed.
duke@1	3775	*/
duke@1	3776	public static abstract class SimpleVisitor<R,S> extends DefaultTypeVisitor<R,S> {
duke@1	3777	@Override
duke@1	3778	public R visitCapturedType(CapturedType t, S s) {
duke@1	3779	return visitTypeVar(t, s);
duke@1	3780	}
duke@1	3781	@Override
duke@1	3782	public R visitForAll(ForAll t, S s) {
duke@1	3783	return visit(t.qtype, s);
duke@1	3784	}
duke@1	3785	@Override
duke@1	3786	public R visitUndetVar(UndetVar t, S s) {
duke@1	3787	return visit(t.qtype, s);
duke@1	3788	}
duke@1	3789	}
duke@1	3790
duke@1	3791	/**
duke@1	3792	* A plain relation on types. That is a 2-ary function on the
duke@1	3793	* form Type&nbsp;&times;&nbsp;Type&nbsp;&rarr;&nbsp;Boolean.
duke@1	3794	* <!-- In plain text: Type x Type -> Boolean -->
duke@1	3795	*/
duke@1	3796	public static abstract class TypeRelation extends SimpleVisitor<Boolean,Type> {}
duke@1	3797
duke@1	3798	/**
duke@1	3799	* A convenience visitor for implementing operations that only
duke@1	3800	* require one argument (the type itself), that is, unary
duke@1	3801	* operations.
duke@1	3802	*
duke@1	3803	* @param <R> the return type of the operation implemented by this
duke@1	3804	* visitor; use Void if no return type is needed.
duke@1	3805	*/
duke@1	3806	public static abstract class UnaryVisitor<R> extends SimpleVisitor<R,Void> {
duke@1	3807	final public R visit(Type t) { return t.accept(this, null); }
duke@1	3808	}
duke@1	3809
duke@1	3810	/**
duke@1	3811	* A visitor for implementing a mapping from types to types. The
duke@1	3812	* default behavior of this class is to implement the identity
duke@1	3813	* mapping (mapping a type to itself). This can be overridden in
duke@1	3814	* subclasses.
duke@1	3815	*
duke@1	3816	* @param <S> the type of the second argument (the first being the
duke@1	3817	* type itself) of this mapping; use Void if a second argument is
duke@1	3818	* not needed.
duke@1	3819	*/
duke@1	3820	public static class MapVisitor<S> extends DefaultTypeVisitor<Type,S> {
duke@1	3821	final public Type visit(Type t) { return t.accept(this, null); }
duke@1	3822	public Type visitType(Type t, S s) { return t; }
duke@1	3823	}
duke@1	3824	// </editor-fold>
jjg@657	3825
jjg@657	3826
jjg@657	3827	// <editor-fold defaultstate="collapsed" desc="Annotation support">
jjg@657	3828
jjg@657	3829	public RetentionPolicy getRetention(Attribute.Compound a) {
jjg@657	3830	RetentionPolicy vis = RetentionPolicy.CLASS; // the default
jjg@657	3831	Attribute.Compound c = a.type.tsym.attribute(syms.retentionType.tsym);
jjg@657	3832	if (c != null) {
jjg@657	3833	Attribute value = c.member(names.value);
jjg@657	3834	if (value != null && value instanceof Attribute.Enum) {
jjg@657	3835	Name levelName = ((Attribute.Enum)value).value.name;
jjg@657	3836	if (levelName == names.SOURCE) vis = RetentionPolicy.SOURCE;
jjg@657	3837	else if (levelName == names.CLASS) vis = RetentionPolicy.CLASS;
jjg@657	3838	else if (levelName == names.RUNTIME) vis = RetentionPolicy.RUNTIME;
jjg@657	3839	else ;// /* fail soft */ throw new AssertionError(levelName);
jjg@657	3840	}
jjg@657	3841	}
jjg@657	3842	return vis;
jjg@657	3843	}
jjg@657	3844	// </editor-fold>
duke@1	3845	}