提交 1b3d3a5c 编写于 作者: A acorn

Merge

......@@ -28,7 +28,6 @@
#include "classfile/classLoaderData.hpp"
#include "classfile/classLoaderData.inline.hpp"
#include "classfile/defaultMethods.hpp"
#include "classfile/genericSignatures.hpp"
#include "classfile/javaClasses.hpp"
#include "classfile/symbolTable.hpp"
#include "classfile/systemDictionary.hpp"
......@@ -3039,35 +3038,6 @@ AnnotationArray* ClassFileParser::assemble_annotations(u1* runtime_visible_annot
return annotations;
}
#ifdef ASSERT
static void parseAndPrintGenericSignatures(
instanceKlassHandle this_klass, TRAPS) {
assert(ParseAllGenericSignatures == true, "Shouldn't call otherwise");
ResourceMark rm;
if (this_klass->generic_signature() != NULL) {
using namespace generic;
ClassDescriptor* spec = ClassDescriptor::parse_generic_signature(this_klass(), CHECK);
tty->print_cr("Parsing %s", this_klass->generic_signature()->as_C_string());
spec->print_on(tty);
for (int i = 0; i < this_klass->methods()->length(); ++i) {
Method* m = this_klass->methods()->at(i);
MethodDescriptor* method_spec = MethodDescriptor::parse_generic_signature(m, spec);
Symbol* sig = m->generic_signature();
if (sig == NULL) {
sig = m->signature();
}
tty->print_cr("Parsing %s", sig->as_C_string());
method_spec->print_on(tty);
}
}
}
#endif // def ASSERT
instanceKlassHandle ClassFileParser::parse_super_class(int super_class_index,
TRAPS) {
instanceKlassHandle super_klass;
......@@ -4060,12 +4030,6 @@ instanceKlassHandle ClassFileParser::parseClassFile(Symbol* name,
java_lang_Class::create_mirror(this_klass, protection_domain, CHECK_(nullHandle));
#ifdef ASSERT
if (ParseAllGenericSignatures) {
parseAndPrintGenericSignatures(this_klass, CHECK_(nullHandle));
}
#endif
// Generate any default methods - default methods are interface methods
// that have a default implementation. This is new with Lambda project.
if (has_default_methods && !access_flags.is_interface() &&
......
......@@ -25,7 +25,6 @@
#include "precompiled.hpp"
#include "classfile/bytecodeAssembler.hpp"
#include "classfile/defaultMethods.hpp"
#include "classfile/genericSignatures.hpp"
#include "classfile/symbolTable.hpp"
#include "memory/allocation.hpp"
#include "memory/metadataFactory.hpp"
......@@ -75,14 +74,6 @@ class PseudoScope : public ResourceObj {
}
};
class ContextMark : public PseudoScopeMark {
private:
generic::Context::Mark _mark;
public:
ContextMark(const generic::Context::Mark& cm) : _mark(cm) {}
virtual void destroy() { _mark.destroy(); }
};
#ifndef PRODUCT
static void print_slot(outputStream* str, Symbol* name, Symbol* signature) {
ResourceMark rm;
......@@ -503,38 +494,6 @@ Symbol* MethodFamily::generate_conflicts_message(GrowableArray<Method*>* methods
return SymbolTable::new_symbol(ss.base(), (int)ss.size(), CHECK_NULL);
}
// A generic method family contains a set of all methods that implement a single
// language-level method. Because of erasure, these methods may have different
// signatures. As members of the set are collected while walking over the
// hierarchy, they are tagged with a qualification state. The qualification
// state for an erased method is set to disqualified if there exists a path
// from the root of hierarchy to the method that contains an interleaving
// language-equivalent method defined in an interface.
class GenericMethodFamily : public MethodFamily {
private:
generic::MethodDescriptor* _descriptor; // language-level description
public:
GenericMethodFamily(generic::MethodDescriptor* canonical_desc)
: _descriptor(canonical_desc) {}
generic::MethodDescriptor* descriptor() const { return _descriptor; }
bool descriptor_matches(generic::MethodDescriptor* md, generic::Context* ctx) {
return descriptor()->covariant_match(md, ctx);
}
#ifndef PRODUCT
Symbol* get_generic_sig() const {
generic::Context ctx(NULL); // empty, as _descriptor already canonicalized
TempNewSymbol sig = descriptor()->reify_signature(&ctx, Thread::current());
return sig;
}
#endif // ndef PRODUCT
};
class StateRestorer;
......@@ -571,26 +530,6 @@ class StatefulMethodFamily : public ResourceObj {
StateRestorer* record_method_and_dq_further(Method* mo);
};
// StatefulGenericMethodFamily is a wrapper around GenericMethodFamily that maintains the
// qualification state during hierarchy visitation, and applies that state
// when adding members to the GenericMethodFamily.
class StatefulGenericMethodFamily : public StatefulMethodFamily {
public:
StatefulGenericMethodFamily(generic::MethodDescriptor* md, generic::Context* ctx)
: StatefulMethodFamily(new GenericMethodFamily(md->canonicalize(ctx))) {
}
GenericMethodFamily* get_method_family() {
return (GenericMethodFamily*)_method_family;
}
bool descriptor_matches(generic::MethodDescriptor* md, generic::Context* ctx) {
return get_method_family()->descriptor_matches(md, ctx);
}
};
class StateRestorer : public PseudoScopeMark {
private:
StatefulMethodFamily* _method;
......@@ -616,39 +555,6 @@ StateRestorer* StatefulMethodFamily::record_method_and_dq_further(Method* mo) {
return mark;
}
class StatefulGenericMethodFamilies : public ResourceObj {
private:
GrowableArray<StatefulGenericMethodFamily*> _methods;
public:
StatefulGenericMethodFamily* find_matching(
generic::MethodDescriptor* md, generic::Context* ctx) {
for (int i = 0; i < _methods.length(); ++i) {
StatefulGenericMethodFamily* existing = _methods.at(i);
if (existing->descriptor_matches(md, ctx)) {
return existing;
}
}
return NULL;
}
StatefulGenericMethodFamily* find_matching_or_create(
generic::MethodDescriptor* md, generic::Context* ctx) {
StatefulGenericMethodFamily* method = find_matching(md, ctx);
if (method == NULL) {
method = new StatefulGenericMethodFamily(md, ctx);
_methods.append(method);
}
return method;
}
void extract_families_into(GrowableArray<GenericMethodFamily*>* array) {
for (int i = 0; i < _methods.length(); ++i) {
array->append(_methods.at(i)->get_method_family());
}
}
};
// Represents a location corresponding to a vtable slot for methods that
// neither the class nor any of it's ancestors provide an implementaion.
// Default methods may be present to fill this slot.
......@@ -779,146 +685,11 @@ class FindMethodsByErasedSig : public HierarchyVisitor<FindMethodsByErasedSig> {
};
// Iterates over the type hierarchy looking for all methods with a specific
// method name. The result of this is a set of method families each of
// which is populated with a set of methods that implement the same
// language-level signature.
class FindMethodsByGenericSig : public HierarchyVisitor<FindMethodsByGenericSig> {
private:
// Context data
Thread* THREAD;
generic::DescriptorCache* _cache;
Symbol* _method_name;
generic::Context* _ctx;
StatefulGenericMethodFamilies _families;
public:
FindMethodsByGenericSig(generic::DescriptorCache* cache, Symbol* name,
generic::Context* ctx, Thread* thread) :
_cache(cache), _method_name(name), _ctx(ctx), THREAD(thread) {}
void get_discovered_families(GrowableArray<GenericMethodFamily*>* methods) {
_families.extract_families_into(methods);
}
void* new_node_data(InstanceKlass* cls) { return new PseudoScope(); }
void free_node_data(void* node_data) {
PseudoScope::cast(node_data)->destroy();
}
bool visit() {
PseudoScope* scope = PseudoScope::cast(current_data());
InstanceKlass* klass = current_class();
InstanceKlass* sub = current_depth() > 0 ? class_at_depth(1) : NULL;
ContextMark* cm = new ContextMark(_ctx->mark());
scope->add_mark(cm); // will restore context when scope is freed
_ctx->apply_type_arguments(sub, klass, THREAD);
int start, end = 0;
start = klass->find_method_by_name(_method_name, &end);
if (start != -1) {
for (int i = start; i < end; ++i) {
Method* m = klass->methods()->at(i);
// This gets the method's parameter list with its generic type
// parameters resolved
generic::MethodDescriptor* md = _cache->descriptor_for(m, THREAD);
// Find all methods on this hierarchy that match this method
// (name, signature). This class collects other families of this
// method name.
StatefulGenericMethodFamily* family =
_families.find_matching_or_create(md, _ctx);
if (klass->is_interface()) {
// ???
StateRestorer* restorer = family->record_method_and_dq_further(m);
scope->add_mark(restorer);
} else {
// This is the rule that methods in classes "win" (bad word) over
// methods in interfaces. This works because of single inheritance
family->set_target_if_empty(m);
}
}
}
return true;
}
};
#ifndef PRODUCT
static void print_generic_families(
GrowableArray<GenericMethodFamily*>* methods, Symbol* match) {
streamIndentor si(tty, 4);
if (methods->length() == 0) {
tty->indent();
tty->print_cr("No Logical Method found");
}
for (int i = 0; i < methods->length(); ++i) {
tty->indent();
GenericMethodFamily* lm = methods->at(i);
if (lm->contains_signature(match)) {
tty->print_cr("<Matching>");
} else {
tty->print_cr("<Non-Matching>");
}
lm->print_sig_on(tty, lm->get_generic_sig(), 1);
}
}
#endif // ndef PRODUCT
static void create_overpasses(
GrowableArray<EmptyVtableSlot*>* slots, InstanceKlass* klass, TRAPS);
static void generate_generic_defaults(
InstanceKlass* klass, GrowableArray<EmptyVtableSlot*>* empty_slots,
EmptyVtableSlot* slot, int current_slot_index, TRAPS) {
if (slot->is_bound()) {
#ifndef PRODUCT
if (TraceDefaultMethods) {
streamIndentor si(tty, 4);
tty->indent().print_cr("Already bound to logical method:");
GenericMethodFamily* lm = (GenericMethodFamily*)(slot->get_binding());
lm->print_sig_on(tty, lm->get_generic_sig(), 1);
}
#endif // ndef PRODUCT
return; // covered by previous processing
}
generic::DescriptorCache cache;
generic::Context ctx(&cache);
FindMethodsByGenericSig visitor(&cache, slot->name(), &ctx, CHECK);
visitor.run(klass);
GrowableArray<GenericMethodFamily*> discovered_families;
visitor.get_discovered_families(&discovered_families);
#ifndef PRODUCT
if (TraceDefaultMethods) {
print_generic_families(&discovered_families, slot->signature());
}
#endif // ndef PRODUCT
// Find and populate any other slots that match the discovered families
for (int j = current_slot_index; j < empty_slots->length(); ++j) {
EmptyVtableSlot* open_slot = empty_slots->at(j);
if (slot->name() == open_slot->name()) {
for (int k = 0; k < discovered_families.length(); ++k) {
GenericMethodFamily* lm = discovered_families.at(k);
if (lm->contains_signature(open_slot->signature())) {
lm->determine_target(klass, CHECK);
open_slot->bind_family(lm);
}
}
}
}
}
static void generate_erased_defaults(
InstanceKlass* klass, GrowableArray<EmptyVtableSlot*>* empty_slots,
EmptyVtableSlot* slot, TRAPS) {
......@@ -943,21 +714,14 @@ static void merge_in_new_methods(InstanceKlass* klass,
//
// First if finds any name/signature slots that need any implementation (either
// because they are miranda or a superclass's implementation is an overpass
// itself). For each slot, iterate over the hierarchy, using generic signature
// information to partition any methods that match the name into method families
// where each family contains methods whose signatures are equivalent at the
// language level (i.e., their reified parameters match and return values are
// covariant). Check those sets to see if they contain a signature that matches
// the slot we're looking at (if we're lucky, there might be other empty slots
// that we can fill using the same analysis).
// itself). For each slot, iterate over the hierarchy, to see if they contain a
// signature that matches the slot we are looking at.
//
// For each slot filled, we generate an overpass method that either calls the
// unique default method candidate using invokespecial, or throws an exception
// (in the case of no default method candidates, or more than one valid
// candidate). These methods are then added to the class's method list. If
// the method set we're using contains methods (qualified or not) with a
// different runtime signature than the method we're creating, then we have to
// create bridges with those signatures too.
// candidate). These methods are then added to the class's method list.
// The JVM does not create bridges nor handle generic signatures here.
void DefaultMethods::generate_default_methods(
InstanceKlass* klass, GrowableArray<Method*>* mirandas, TRAPS) {
......@@ -997,11 +761,7 @@ void DefaultMethods::generate_default_methods(
}
#endif // ndef PRODUCT
if (ParseGenericDefaults) {
generate_generic_defaults(klass, empty_slots, slot, i, CHECK);
} else {
generate_erased_defaults(klass, empty_slots, slot, CHECK);
}
generate_erased_defaults(klass, empty_slots, slot, CHECK);
}
#ifndef PRODUCT
if (TraceDefaultMethods) {
......@@ -1019,13 +779,13 @@ void DefaultMethods::generate_default_methods(
}
/**
* Generic analysis was used upon interface '_target' and found a unique
* default method candidate with generic signature '_method_desc'. This
* Interface inheritance rules were used to find a unique default method
* candidate for the resolved class. This
* method is only viable if it would also be in the set of default method
* candidates if we ran a full analysis on the current class.
*
* The only reason that the method would not be in the set of candidates for
* the current class is if that there's another covariantly matching method
* the current class is if that there's another matching method
* which is "more specific" than the found method -- i.e., one could find a
* path in the interface hierarchy in which the matching method appears
* before we get to '_target'.
......@@ -1110,48 +870,6 @@ class ErasedShadowChecker : public ShadowChecker {
: ShadowChecker(thread, name, holder, target) {}
};
class GenericShadowChecker : public ShadowChecker {
private:
generic::DescriptorCache* _cache;
generic::MethodDescriptor* _method_desc;
bool path_has_shadow() {
generic::Context ctx(_cache);
for (int i = current_depth() - 1; i > 0; --i) {
InstanceKlass* ik = class_at_depth(i);
InstanceKlass* sub = class_at_depth(i + 1);
ctx.apply_type_arguments(sub, ik, THREAD);
if (ik->is_interface()) {
int end;
int start = ik->find_method_by_name(_method_name, &end);
if (start != -1) {
for (int j = start; j < end; ++j) {
Method* mo = ik->methods()->at(j);
generic::MethodDescriptor* md = _cache->descriptor_for(mo, THREAD);
if (_method_desc->covariant_match(md, &ctx)) {
return true;
}
}
}
}
}
return false;
}
public:
GenericShadowChecker(generic::DescriptorCache* cache, Thread* thread,
Symbol* name, InstanceKlass* holder, generic::MethodDescriptor* desc,
InstanceKlass* target)
: ShadowChecker(thread, name, holder, target) {
_cache = cache;
_method_desc = desc;
}
};
// Find the unique qualified candidate from the perspective of the super_class
// which is the resolved_klass, which must be an immediate superinterface
......@@ -1203,66 +921,6 @@ Method* find_erased_super_default(InstanceKlass* current_class, InstanceKlass* s
}
}
// super_class is assumed to be the direct super of current_class
Method* find_generic_super_default( InstanceKlass* current_class,
InstanceKlass* super_class,
Symbol* method_name, Symbol* sig, TRAPS) {
generic::DescriptorCache cache;
generic::Context ctx(&cache);
// Prime the initial generic context for current -> super_class
ctx.apply_type_arguments(current_class, super_class, CHECK_NULL);
FindMethodsByGenericSig visitor(&cache, method_name, &ctx, CHECK_NULL);
visitor.run(super_class);
GrowableArray<GenericMethodFamily*> families;
visitor.get_discovered_families(&families);
#ifndef PRODUCT
if (TraceDefaultMethods) {
print_generic_families(&families, sig);
}
#endif // ndef PRODUCT
GenericMethodFamily* selected_family = NULL;
for (int i = 0; i < families.length(); ++i) {
GenericMethodFamily* lm = families.at(i);
if (lm->contains_signature(sig)) {
lm->determine_target(current_class, CHECK_NULL);
selected_family = lm;
}
}
if (selected_family->has_target()) {
Method* target = selected_family->get_selected_target();
InstanceKlass* holder = InstanceKlass::cast(target->method_holder());
// Verify that the identified method is valid from the context of
// the current class
GenericShadowChecker checker(&cache, THREAD, target->name(),
holder, selected_family->descriptor(), super_class);
checker.run(current_class);
if (checker.found_shadow()) {
#ifndef PRODUCT
if (TraceDefaultMethods) {
tty->print_cr(" Only candidate found was shadowed.");
}
#endif // ndef PRODUCT
THROW_MSG_(vmSymbols::java_lang_AbstractMethodError(),
"Accessible default method not found", NULL);
} else {
return target;
}
} else {
assert(selected_family->throws_exception(), "must have target or throw");
THROW_MSG_(vmSymbols::java_lang_AbstractMethodError(),
selected_family->get_exception_message()->as_C_string(), NULL);
}
}
// This is called during linktime when we find an invokespecial call that
// refers to a direct superinterface. It indicates that we should find the
// default method in the hierarchy of that superinterface, and if that method
......@@ -1296,13 +954,8 @@ Method* DefaultMethods::find_super_default(
assert(super_class->is_interface(), "only call for default methods");
Method* target = NULL;
if (ParseGenericDefaults) {
target = find_generic_super_default(current_class, super_class,
method_name, sig, CHECK_NULL);
} else {
target = find_erased_super_default(current_class, super_class,
method_name, sig, CHECK_NULL);
}
target = find_erased_super_default(current_class, super_class,
method_name, sig, CHECK_NULL);
#ifndef PRODUCT
if (target != NULL) {
......
此差异已折叠。
/*
* Copyright (c) 2012, Oracle and/or its affiliates. All rights reserved.
* DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
*
* This code is free software; you can redistribute it and/or modify it
* under the terms of the GNU General Public License version 2 only, as
* published by the Free Software Foundation.
*
* This code is distributed in the hope that it will be useful, but WITHOUT
* ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
* FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
* version 2 for more details (a copy is included in the LICENSE file that
* accompanied this code).
*
* You should have received a copy of the GNU General Public License version
* 2 along with this work; if not, write to the Free Software Foundation,
* Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA.
*
* Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA
* or visit www.oracle.com if you need additional information or have any
* questions.
*
*/
#ifndef SHARE_VM_CLASSFILE_GENERICSIGNATURES_HPP
#define SHARE_VM_CLASSFILE_GENERICSIGNATURES_HPP
#include "classfile/symbolTable.hpp"
#include "memory/allocation.hpp"
#include "runtime/signature.hpp"
#include "utilities/growableArray.hpp"
#include "utilities/resourceHash.hpp"
class stringStream;
namespace generic {
class Identifier;
class ClassDescriptor;
class MethodDescriptor;
class TypeParameter; // a formal type parameter declared in generic signatures
class TypeArgument; // The "type value" passed to fill parameters in supertypes
class TypeVariable; // A usage of a type parameter as a value
/**
* Example:
*
* <T, V> class Foo extends Bar<String> { int m(V v) {} }
* ^^^^^^ ^^^^^^ ^^
* type parameters type argument type variable
*
* Note that a type variable could be passed as an argument too:
* <T, V> class Foo extends Bar<T> { int m(V v) {} }
* ^^^
* type argument's value is a type variable
*/
class Type;
class ClassType;
class ArrayType;
class PrimitiveType;
class Context;
class DescriptorCache;
class DescriptorStream;
class Identifier : public ResourceObj {
private:
Symbol* _sym;
int _begin;
int _end;
public:
Identifier(Symbol* sym, int begin, int end) :
_sym(sym), _begin(begin), _end(end) {}
bool equals(Identifier* other);
bool equals(Symbol* sym);
#ifndef PRODUCT
void print_on(outputStream* str) const;
#endif // ndef PRODUCT
};
class Descriptor : public ResourceObj {
protected:
GrowableArray<TypeParameter*> _type_parameters;
ClassDescriptor* _outer_class;
Descriptor(GrowableArray<TypeParameter*>& params,
ClassDescriptor* outer)
: _type_parameters(params), _outer_class(outer) {}
public:
ClassDescriptor* outer_class() { return _outer_class; }
void set_outer_class(ClassDescriptor* sig) { _outer_class = sig; }
virtual ClassDescriptor* as_class_signature() { return NULL; }
virtual MethodDescriptor* as_method_signature() { return NULL; }
bool is_class_signature() { return as_class_signature() != NULL; }
bool is_method_signature() { return as_method_signature() != NULL; }
GrowableArray<TypeParameter*>& type_parameters() {
return _type_parameters;
}
TypeParameter* find_type_parameter(Identifier* id, int* param_depth);
virtual void bind_variables_to_parameters() = 0;
#ifndef PRODUCT
virtual void print_on(outputStream* str) const = 0;
#endif
};
class ClassDescriptor : public Descriptor {
private:
ClassType* _super;
GrowableArray<ClassType*> _interfaces;
MethodDescriptor* _outer_method;
ClassDescriptor(GrowableArray<TypeParameter*>& ftp, ClassType* scs,
GrowableArray<ClassType*>& sis, ClassDescriptor* outer_class = NULL,
MethodDescriptor* outer_method = NULL)
: Descriptor(ftp, outer_class), _super(scs), _interfaces(sis),
_outer_method(outer_method) {}
static u2 get_outer_class_index(InstanceKlass* k, TRAPS);
static ClassDescriptor* parse_generic_signature(Klass* k, Symbol* original_name, TRAPS);
public:
virtual ClassDescriptor* as_class_signature() { return this; }
MethodDescriptor* outer_method() { return _outer_method; }
void set_outer_method(MethodDescriptor* m) { _outer_method = m; }
ClassType* super() { return _super; }
ClassType* interface_desc(Symbol* sym);
static ClassDescriptor* parse_generic_signature(Klass* k, TRAPS);
static ClassDescriptor* parse_generic_signature(Symbol* sym);
// For use in superclass chains in positions where this is no generic info
static ClassDescriptor* placeholder(InstanceKlass* klass);
#ifndef PRODUCT
void print_on(outputStream* str) const;
#endif
ClassDescriptor* canonicalize(Context* ctx);
// Linking sets the position index in any contained TypeVariable type
// to correspond to the location of that identifier in the formal type
// parameters.
void bind_variables_to_parameters();
};
class MethodDescriptor : public Descriptor {
private:
GrowableArray<Type*> _parameters;
Type* _return_type;
GrowableArray<Type*> _throws;
MethodDescriptor(GrowableArray<TypeParameter*>& ftp, ClassDescriptor* outer,
GrowableArray<Type*>& sigs, Type* rt, GrowableArray<Type*>& throws)
: Descriptor(ftp, outer), _parameters(sigs), _return_type(rt),
_throws(throws) {}
public:
static MethodDescriptor* parse_generic_signature(Method* m, ClassDescriptor* outer);
static MethodDescriptor* parse_generic_signature(Symbol* sym, ClassDescriptor* outer);
MethodDescriptor* as_method_signature() { return this; }
// Performs generic analysis on the method parameters to determine
// if both methods refer to the same argument types.
bool covariant_match(MethodDescriptor* other, Context* ctx);
// Returns a new method descriptor with all generic variables
// removed and replaced with whatever is indicated using the Context.
MethodDescriptor* canonicalize(Context* ctx);
void bind_variables_to_parameters();
#ifndef PRODUCT
TempNewSymbol reify_signature(Context* ctx, TRAPS);
void print_on(outputStream* str) const;
#endif
};
class TypeParameter : public ResourceObj {
private:
Identifier* _identifier;
ClassType* _class_bound;
GrowableArray<ClassType*> _interface_bounds;
// The position is the ordinal location of the parameter within the
// formal parameter list (excluding outer classes). It is only set for
// formal type parameters that are associated with a class -- method
// type parameters are left as -1. When resolving a generic variable to
// find the actual type, this index is used to access the generic type
// argument in the provided context object.
int _position; // Assigned during variable linking
TypeParameter(Identifier* id, ClassType* class_bound,
GrowableArray<ClassType*>& interface_bounds) :
_identifier(id), _class_bound(class_bound),
_interface_bounds(interface_bounds), _position(-1) {}
public:
static TypeParameter* parse_generic_signature(DescriptorStream* str);
ClassType* bound();
int position() { return _position; }
void bind_variables_to_parameters(Descriptor* sig, int position);
Identifier* identifier() { return _identifier; }
Type* resolve(Context* ctx, int inner_depth, int ctx_depth);
TypeParameter* canonicalize(Context* ctx, int ctx_depth);
#ifndef PRODUCT
void print_on(outputStream* str) const;
#endif
};
class Type : public ResourceObj {
public:
static Type* parse_generic_signature(DescriptorStream* str);
virtual ClassType* as_class() { return NULL; }
virtual TypeVariable* as_variable() { return NULL; }
virtual ArrayType* as_array() { return NULL; }
virtual PrimitiveType* as_primitive() { return NULL; }
virtual bool covariant_match(Type* gt, Context* ctx) = 0;
virtual Type* canonicalize(Context* ctx, int ctx_depth) = 0;
virtual void bind_variables_to_parameters(Descriptor* sig) = 0;
#ifndef PRODUCT
virtual void reify_signature(stringStream* ss, Context* ctx) = 0;
virtual void print_on(outputStream* str) const = 0;
#endif
};
class ClassType : public Type {
friend class ClassDescriptor;
protected:
Identifier* _identifier;
GrowableArray<TypeArgument*> _type_arguments;
ClassType* _outer_class;
ClassType(Identifier* identifier,
GrowableArray<TypeArgument*>& args,
ClassType* outer)
: _identifier(identifier), _type_arguments(args), _outer_class(outer) {}
// Returns true if there are inner classes to read
static Identifier* parse_generic_signature_simple(
GrowableArray<TypeArgument*>* args,
bool* has_inner, DescriptorStream* str);
static ClassType* parse_generic_signature(ClassType* outer,
DescriptorStream* str);
static ClassType* from_symbol(Symbol* sym);
public:
ClassType* as_class() { return this; }
static ClassType* parse_generic_signature(DescriptorStream* str);
static ClassType* java_lang_Object();
Identifier* identifier() { return _identifier; }
int type_arguments_length() { return _type_arguments.length(); }
TypeArgument* type_argument_at(int i);
virtual ClassType* outer_class() { return _outer_class; }
bool covariant_match(Type* gt, Context* ctx);
ClassType* canonicalize(Context* ctx, int context_depth);
void bind_variables_to_parameters(Descriptor* sig);
#ifndef PRODUCT
void reify_signature(stringStream* ss, Context* ctx);
void print_on(outputStream* str) const;
#endif
};
class TypeVariable : public Type {
private:
Identifier* _id;
TypeParameter* _parameter; // assigned during linking
// how many steps "out" from inner classes, -1 if method
int _inner_depth;
TypeVariable(Identifier* id)
: _id(id), _parameter(NULL), _inner_depth(0) {}
public:
TypeVariable* as_variable() { return this; }
static TypeVariable* parse_generic_signature(DescriptorStream* str);
Identifier* identifier() { return _id; }
TypeParameter* parameter() { return _parameter; }
int inner_depth() { return _inner_depth; }
void bind_variables_to_parameters(Descriptor* sig);
Type* resolve(Context* ctx, int ctx_depth);
bool covariant_match(Type* gt, Context* ctx);
Type* canonicalize(Context* ctx, int ctx_depth);
#ifndef PRODUCT
void reify_signature(stringStream* ss, Context* ctx);
void print_on(outputStream* str) const;
#endif
};
class ArrayType : public Type {
private:
Type* _base;
ArrayType(Type* base) : _base(base) {}
public:
ArrayType* as_array() { return this; }
static ArrayType* parse_generic_signature(DescriptorStream* str);
bool covariant_match(Type* gt, Context* ctx);
ArrayType* canonicalize(Context* ctx, int ctx_depth);
void bind_variables_to_parameters(Descriptor* sig);
#ifndef PRODUCT
void reify_signature(stringStream* ss, Context* ctx);
void print_on(outputStream* str) const;
#endif
};
class PrimitiveType : public Type {
friend class Type;
private:
char _type; // includes V for void
PrimitiveType(char& type) : _type(type) {}
public:
PrimitiveType* as_primitive() { return this; }
bool covariant_match(Type* gt, Context* ctx);
PrimitiveType* canonicalize(Context* ctx, int ctx_depth);
void bind_variables_to_parameters(Descriptor* sig);
#ifndef PRODUCT
void reify_signature(stringStream* ss, Context* ctx);
void print_on(outputStream* str) const;
#endif
};
class TypeArgument : public ResourceObj {
private:
Type* _lower_bound;
Type* _upper_bound; // may be null or == _lower_bound
TypeArgument(Type* lower_bound, Type* upper_bound)
: _lower_bound(lower_bound), _upper_bound(upper_bound) {}
public:
static TypeArgument* parse_generic_signature(DescriptorStream* str);
Type* lower_bound() { return _lower_bound; }
Type* upper_bound() { return _upper_bound; }
void bind_variables_to_parameters(Descriptor* sig);
TypeArgument* canonicalize(Context* ctx, int ctx_depth);
bool covariant_match(TypeArgument* a, Context* ctx);
#ifndef PRODUCT
void print_on(outputStream* str) const;
#endif
};
class Context : public ResourceObj {
private:
DescriptorCache* _cache;
GrowableArray<ClassType*> _type_arguments;
void reset_to_mark(int size);
public:
// When this object goes out of scope or 'destroy' is
// called, then the application of the type to the
// context is wound-back (unless it's been deactivated).
class Mark : public StackObj {
private:
mutable Context* _context;
int _marked_size;
bool is_active() const { return _context != NULL; }
void deactivate() const { _context = NULL; }
public:
Mark() : _context(NULL), _marked_size(0) {}
Mark(Context* ctx, int sz) : _context(ctx), _marked_size(sz) {}
Mark(const Mark& m) : _context(m._context), _marked_size(m._marked_size) {
m.deactivate(); // Ownership is transferred
}
Mark& operator=(const Mark& cm) {
destroy();
_context = cm._context;
_marked_size = cm._marked_size;
cm.deactivate();
return *this;
}
void destroy();
~Mark() { destroy(); }
};
Context(DescriptorCache* cache) : _cache(cache) {}
Mark mark() { return Mark(this, _type_arguments.length()); }
void apply_type_arguments(InstanceKlass* current, InstanceKlass* super,TRAPS);
ClassType* at_depth(int i) const;
#ifndef PRODUCT
void print_on(outputStream* str) const;
#endif
};
/**
* Contains a cache of descriptors for classes and methods so they can be
* looked-up instead of reparsing each time they are needed.
*/
class DescriptorCache : public ResourceObj {
private:
ResourceHashtable<InstanceKlass*, ClassDescriptor*> _class_descriptors;
ResourceHashtable<Method*, MethodDescriptor*> _method_descriptors;
public:
ClassDescriptor* descriptor_for(InstanceKlass* ikh, TRAPS);
MethodDescriptor* descriptor_for(Method* mh, ClassDescriptor* cd, TRAPS);
// Class descriptor derived from method holder
MethodDescriptor* descriptor_for(Method* mh, TRAPS);
};
} // namespace generic
#endif // SHARE_VM_CLASSFILE_GENERICSIGNATURES_HPP
......@@ -3685,15 +3685,9 @@ class CommandLineFlags {
develop(bool, TraceDefaultMethods, false, \
"Trace the default method processing steps") \
\
develop(bool, ParseAllGenericSignatures, false, \
"Parse all generic signatures while classloading") \
\
develop(bool, VerifyGenericSignatures, false, \
"Abort VM on erroneous or inconsistent generic signatures") \
\
product(bool, ParseGenericDefaults, false, \
"Parse generic signatures for default method handling") \
\
product(bool, UseVMInterruptibleIO, false, \
"(Unstable, Solaris-specific) Thread interrupt before or with " \
"EINTR for I/O operations results in OS_INTRPT. The default value"\
......
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