/**
* Main method: compile a list of files, return all compiled classes
*
* @param filenames The names of all files to be compiled.
*/
public List<ClassSymbol> compile(
List<String> filenames,
Map<String, String> origOptions,
ClassLoader aptCL,
AnnotationProcessorFactory providedFactory,
java.util.Set<Class<? extends AnnotationProcessorFactory>> productiveFactories,
java.util.Set<java.io.File> aggregateGenFiles)
throws Throwable {
// as a JavaCompiler can only be used once, throw an exception if
// it has been used before.
assert !hasBeenUsed : "attempt to reuse JavaCompiler";
hasBeenUsed = true;
this.aggregateGenFiles = aggregateGenFiles;
long msec = System.currentTimeMillis();
ListBuffer<ClassSymbol> classes = new ListBuffer<ClassSymbol>();
try {
JavacFileManager fm = (JavacFileManager) fileManager;
// parse all files
ListBuffer<JCCompilationUnit> trees = new ListBuffer<JCCompilationUnit>();
for (List<String> l = filenames; l.nonEmpty(); l = l.tail) {
if (classesAsDecls) {
if (!l.head.endsWith(".java")) { // process as class file
ClassSymbol cs = reader.enterClass(names.fromString(l.head));
try {
cs.complete();
} catch (Symbol.CompletionFailure cf) {
bark.aptError("CantFindClass", l);
continue;
}
classes.append(cs); // add to list of classes
continue;
}
}
JavaFileObject fo = fm.getJavaFileObjectsFromStrings(List.of(l.head)).iterator().next();
trees.append(parse(fo));
}
// enter symbols for all files
List<JCCompilationUnit> roots = trees.toList();
if (errorCount() == 0) {
boolean prev = bark.setDiagnosticsIgnored(true);
try {
enter.main(roots);
} finally {
bark.setDiagnosticsIgnored(prev);
}
}
if (errorCount() == 0) {
apt.main(roots, classes, origOptions, aptCL, providedFactory, productiveFactories);
genSourceFileNames.addAll(apt.getSourceFileNames());
genClassFileNames.addAll(apt.getClassFileNames());
}
} catch (Abort ex) {
}
if (verbose) log.printVerbose("total", Long.toString(System.currentTimeMillis() - msec));
chk.reportDeferredDiagnostics();
printCount("error", errorCount());
printCount("warn", warningCount());
return classes.toList();
}
Attribute enterAttributeValue(Type expected, JCExpression tree, Env<AttrContext> env) {
// first, try completing the attribution value sym - if a completion
// error is thrown, we should recover gracefully, and display an
// ordinary resolution diagnostic.
try {
expected.tsym.complete();
} catch (CompletionFailure e) {
log.error(tree.pos(), "cant.resolve", Kinds.kindName(e.sym), e.sym);
return new Attribute.Error(expected);
}
if (expected.isPrimitive() || types.isSameType(expected, syms.stringType)) {
Type result = attr.attribExpr(tree, env, expected);
if (result.isErroneous()) return new Attribute.Error(expected);
if (result.constValue() == null) {
log.error(tree.pos(), "attribute.value.must.be.constant");
return new Attribute.Error(expected);
}
result = cfolder.coerce(result, expected);
return new Attribute.Constant(expected, result.constValue());
}
if (expected.tsym == syms.classType.tsym) {
Type result = attr.attribExpr(tree, env, expected);
if (result.isErroneous()) return new Attribute.Error(expected);
if (TreeInfo.name(tree) != names._class) {
log.error(tree.pos(), "annotation.value.must.be.class.literal");
return new Attribute.Error(expected);
}
return new Attribute.Class(types, (((JCFieldAccess) tree).selected).type);
}
if ((expected.tsym.flags() & Flags.ANNOTATION) != 0
|| types.isSameType(expected, syms.annotationType)) {
if (tree.getTag() != JCTree.ANNOTATION) {
log.error(tree.pos(), "annotation.value.must.be.annotation");
expected = syms.errorType;
}
return enterAnnotation((JCAnnotation) tree, expected, env);
}
if (expected.tag == TypeTags.ARRAY) { // should really be isArray()
if (tree.getTag() != JCTree.NEWARRAY) {
tree = make.at(tree.pos).NewArray(null, List.<JCExpression>nil(), List.of(tree));
}
JCNewArray na = (JCNewArray) tree;
if (na.elemtype != null) {
log.error(na.elemtype.pos(), "new.not.allowed.in.annotation");
return new Attribute.Error(expected);
}
ListBuffer<Attribute> buf = new ListBuffer<Attribute>();
for (List<JCExpression> l = na.elems; l.nonEmpty(); l = l.tail) {
buf.append(enterAttributeValue(types.elemtype(expected), l.head, env));
}
na.type = expected;
return new Attribute.Array(expected, buf.toArray(new Attribute[buf.length()]));
}
if (expected.tag == TypeTags.CLASS && (expected.tsym.flags() & Flags.ENUM) != 0) {
attr.attribExpr(tree, env, expected);
Symbol sym = TreeInfo.symbol(tree);
if (sym == null
|| TreeInfo.nonstaticSelect(tree)
|| sym.kind != Kinds.VAR
|| (sym.flags() & Flags.ENUM) == 0) {
log.error(tree.pos(), "enum.annotation.must.be.enum.constant");
return new Attribute.Error(expected);
}
VarSymbol enumerator = (VarSymbol) sym;
return new Attribute.Enum(expected, enumerator);
}
if (!expected.isErroneous()) log.error(tree.pos(), "annotation.value.not.allowable.type");
return new Attribute.Error(attr.attribExpr(tree, env, expected));
}