8072911: Remove includes of oop.inline.hpp from .hpp files
Reviewed-by: brutisso, coleenp, jwilhelm, simonis, dholmes
/*
* Copyright (c) 1999, 2015, 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.
*
*/
#include "precompiled.hpp"
#include "ci/ciField.hpp"
#include "ci/ciInstanceKlass.hpp"
#include "ci/ciUtilities.hpp"
#include "classfile/systemDictionary.hpp"
#include "gc_interface/collectedHeap.inline.hpp"
#include "interpreter/linkResolver.hpp"
#include "memory/universe.inline.hpp"
#include "oops/oop.inline.hpp"
#include "runtime/fieldDescriptor.hpp"
// ciField
//
// This class represents the result of a field lookup in the VM.
// The lookup may not succeed, in which case the information in
// the ciField will be incomplete.
// The ciObjectFactory cannot create circular data structures in one query.
// To avoid vicious circularities, we initialize ciField::_type to NULL
// for reference types and derive it lazily from the ciField::_signature.
// Primitive types are eagerly initialized, and basic layout queries
// can succeed without initialization, using only the BasicType of the field.
// Notes on bootstrapping and shared CI objects: A field is shared if and
// only if it is (a) non-static and (b) declared by a shared instance klass.
// This allows non-static field lists to be cached on shared types.
// Because the _type field is lazily initialized, however, there is a
// special restriction that a shared field cannot cache an unshared type.
// This puts a small performance penalty on shared fields with unshared
// types, such as StackTraceElement[] Throwable.stackTrace.
// (Throwable is shared because ClassCastException is shared, but
// StackTraceElement is not presently shared.)
// It is not a vicious circularity for a ciField to recursively create
// the ciSymbols necessary to represent its name and signature.
// Therefore, these items are created eagerly, and the name and signature
// of a shared field are themselves shared symbols. This somewhat
// pollutes the set of shared CI objects: It grows from 50 to 93 items,
// with all of the additional 43 being uninteresting shared ciSymbols.
// This adds at most one step to the binary search, an amount which
// decreases for complex compilation tasks.
// ------------------------------------------------------------------
// ciField::ciField
ciField::ciField(ciInstanceKlass* klass, int index): _known_to_link_with_put(NULL), _known_to_link_with_get(NULL) {
ASSERT_IN_VM;
CompilerThread *thread = CompilerThread::current();
assert(ciObjectFactory::is_initialized(), "not a shared field");
assert(klass->get_instanceKlass()->is_linked(), "must be linked before using its constan-pool");
constantPoolHandle cpool(thread, klass->get_instanceKlass()->constants());
// Get the field's name, signature, and type.
Symbol* name = cpool->name_ref_at(index);
_name = ciEnv::current(thread)->get_symbol(name);
int nt_index = cpool->name_and_type_ref_index_at(index);
int sig_index = cpool->signature_ref_index_at(nt_index);
Symbol* signature = cpool->symbol_at(sig_index);
_signature = ciEnv::current(thread)->get_symbol(signature);
BasicType field_type = FieldType::basic_type(signature);
// If the field is a pointer type, get the klass of the
// field.
if (field_type == T_OBJECT || field_type == T_ARRAY) {
bool ignore;
// This is not really a class reference; the index always refers to the
// field's type signature, as a symbol. Linkage checks do not apply.
_type = ciEnv::current(thread)->get_klass_by_index(cpool, sig_index, ignore, klass);
} else {
_type = ciType::make(field_type);
}
_name = (ciSymbol*)ciEnv::current(thread)->get_symbol(name);
// Get the field's declared holder.
//
// Note: we actually create a ciInstanceKlass for this klass,
// even though we may not need to.
int holder_index = cpool->klass_ref_index_at(index);
bool holder_is_accessible;
ciInstanceKlass* declared_holder =
ciEnv::current(thread)->get_klass_by_index(cpool, holder_index,
holder_is_accessible,
klass)->as_instance_klass();
// The declared holder of this field may not have been loaded.
// Bail out with partial field information.
if (!holder_is_accessible) {
// _type has already been set.
// The default values for _flags and _constant_value will suffice.
// We need values for _holder, _offset, and _is_constant,
_holder = declared_holder;
_offset = -1;
_is_constant = false;
return;
}
InstanceKlass* loaded_decl_holder = declared_holder->get_instanceKlass();
// Perform the field lookup.
fieldDescriptor field_desc;
Klass* canonical_holder =
loaded_decl_holder->find_field(name, signature, &field_desc);
if (canonical_holder == NULL) {
// Field lookup failed. Will be detected by will_link.
_holder = declared_holder;
_offset = -1;
_is_constant = false;
return;
}
// Access check based on declared_holder. canonical_holder should not be used
// to check access because it can erroneously succeed. If this check fails,
// propagate the declared holder to will_link() which in turn will bail out
// compilation for this field access.
if (!Reflection::verify_field_access(klass->get_Klass(), declared_holder->get_Klass(), canonical_holder, field_desc.access_flags(), true)) {
_holder = declared_holder;
_offset = -1;
_is_constant = false;
return;
}
assert(canonical_holder == field_desc.field_holder(), "just checking");
initialize_from(&field_desc);
}
ciField::ciField(fieldDescriptor *fd): _known_to_link_with_put(NULL), _known_to_link_with_get(NULL) {
ASSERT_IN_VM;
// Get the field's name, signature, and type.
ciEnv* env = CURRENT_ENV;
_name = env->get_symbol(fd->name());
_signature = env->get_symbol(fd->signature());
BasicType field_type = fd->field_type();
// If the field is a pointer type, get the klass of the
// field.
if (field_type == T_OBJECT || field_type == T_ARRAY) {
_type = NULL; // must call compute_type on first access
} else {
_type = ciType::make(field_type);
}
initialize_from(fd);
// Either (a) it is marked shared, or else (b) we are done bootstrapping.
assert(is_shared() || ciObjectFactory::is_initialized(),
"bootstrap classes must not create & cache unshared fields");
}
static bool trust_final_non_static_fields(ciInstanceKlass* holder) {
if (holder == NULL)
return false;
if (holder->name() == ciSymbol::java_lang_System())
// Never trust strangely unstable finals: System.out, etc.
return false;
// Even if general trusting is disabled, trust system-built closures in these packages.
if (holder->is_in_package("java/lang/invoke") || holder->is_in_package("sun/invoke"))
return true;
return TrustFinalNonStaticFields;
}
void ciField::initialize_from(fieldDescriptor* fd) {
// Get the flags, offset, and canonical holder of the field.
_flags = ciFlags(fd->access_flags());
_offset = fd->offset();
_holder = CURRENT_ENV->get_instance_klass(fd->field_holder());
// Check to see if the field is constant.
bool is_final = this->is_final();
bool is_stable = FoldStableValues && this->is_stable();
if (_holder->is_initialized() && (is_final || is_stable)) {
if (!this->is_static()) {
// A field can be constant if it's a final static field or if
// it's a final non-static field of a trusted class (classes in
// java.lang.invoke and sun.invoke packages and subpackages).
if (is_stable || trust_final_non_static_fields(_holder)) {
_is_constant = true;
return;
}
_is_constant = false;
return;
}
// This field just may be constant. The only case where it will
// not be constant is when the field is a *special* static&final field
// whose value may change. The three examples are java.lang.System.in,
// java.lang.System.out, and java.lang.System.err.
KlassHandle k = _holder->get_Klass();
assert( SystemDictionary::System_klass() != NULL, "Check once per vm");
if( k() == SystemDictionary::System_klass() ) {
// Check offsets for case 2: System.in, System.out, or System.err
if( _offset == java_lang_System::in_offset_in_bytes() ||
_offset == java_lang_System::out_offset_in_bytes() ||
_offset == java_lang_System::err_offset_in_bytes() ) {
_is_constant = false;
return;
}
}
Handle mirror = k->java_mirror();
switch(type()->basic_type()) {
case T_BYTE:
_constant_value = ciConstant(type()->basic_type(), mirror->byte_field(_offset));
break;
case T_CHAR:
_constant_value = ciConstant(type()->basic_type(), mirror->char_field(_offset));
break;
case T_SHORT:
_constant_value = ciConstant(type()->basic_type(), mirror->short_field(_offset));
break;
case T_BOOLEAN:
_constant_value = ciConstant(type()->basic_type(), mirror->bool_field(_offset));
break;
case T_INT:
_constant_value = ciConstant(type()->basic_type(), mirror->int_field(_offset));
break;
case T_FLOAT:
_constant_value = ciConstant(mirror->float_field(_offset));
break;
case T_DOUBLE:
_constant_value = ciConstant(mirror->double_field(_offset));
break;
case T_LONG:
_constant_value = ciConstant(mirror->long_field(_offset));
break;
case T_OBJECT:
case T_ARRAY:
{
oop o = mirror->obj_field(_offset);
// A field will be "constant" if it is known always to be
// a non-null reference to an instance of a particular class,
// or to a particular array. This can happen even if the instance
// or array is not perm. In such a case, an "unloaded" ciArray
// or ciInstance is created. The compiler may be able to use
// information about the object's class (which is exact) or length.
if (o == NULL) {
_constant_value = ciConstant(type()->basic_type(), ciNullObject::make());
} else {
_constant_value = ciConstant(type()->basic_type(), CURRENT_ENV->get_object(o));
assert(_constant_value.as_object() == CURRENT_ENV->get_object(o), "check interning");
}
}
}
if (is_stable && _constant_value.is_null_or_zero()) {
// It is not a constant after all; treat it as uninitialized.
_is_constant = false;
} else {
_is_constant = true;
}
} else {
_is_constant = false;
}
}
// ------------------------------------------------------------------
// ciField::compute_type
//
// Lazily compute the type, if it is an instance klass.
ciType* ciField::compute_type() {
GUARDED_VM_ENTRY(return compute_type_impl();)
}
ciType* ciField::compute_type_impl() {
ciKlass* type = CURRENT_ENV->get_klass_by_name_impl(_holder, constantPoolHandle(), _signature, false);
if (!type->is_primitive_type() && is_shared()) {
// We must not cache a pointer to an unshared type, in a shared field.
bool type_is_also_shared = false;
if (type->is_type_array_klass()) {
type_is_also_shared = true; // int[] etc. are explicitly bootstrapped
} else if (type->is_instance_klass()) {
type_is_also_shared = type->as_instance_klass()->is_shared();
} else {
// Currently there is no 'shared' query for array types.
type_is_also_shared = !ciObjectFactory::is_initialized();
}
if (!type_is_also_shared)
return type; // Bummer.
}
_type = type;
return type;
}
// ------------------------------------------------------------------
// ciField::will_link
//
// Can a specific access to this field be made without causing
// link errors?
bool ciField::will_link(ciInstanceKlass* accessing_klass,
Bytecodes::Code bc) {
VM_ENTRY_MARK;
assert(bc == Bytecodes::_getstatic || bc == Bytecodes::_putstatic ||
bc == Bytecodes::_getfield || bc == Bytecodes::_putfield,
"unexpected bytecode");
if (_offset == -1) {
// at creation we couldn't link to our holder so we need to
// maintain that stance, otherwise there's no safe way to use this
// ciField.
return false;
}
// Check for static/nonstatic mismatch
bool is_static = (bc == Bytecodes::_getstatic || bc == Bytecodes::_putstatic);
if (is_static != this->is_static()) {
return false;
}
// Get and put can have different accessibility rules
bool is_put = (bc == Bytecodes::_putfield || bc == Bytecodes::_putstatic);
if (is_put) {
if (_known_to_link_with_put == accessing_klass) {
return true;
}
} else {
if (_known_to_link_with_get == accessing_klass) {
return true;
}
}
fieldDescriptor result;
LinkResolver::resolve_field(result, _holder->get_instanceKlass(),
_name->get_symbol(), _signature->get_symbol(),
accessing_klass->get_Klass(), bc, true, false,
KILL_COMPILE_ON_FATAL_(false));
// update the hit-cache, unless there is a problem with memory scoping:
if (accessing_klass->is_shared() || !is_shared()) {
if (is_put) {
_known_to_link_with_put = accessing_klass;
} else {
_known_to_link_with_get = accessing_klass;
}
}
return true;
}
// ------------------------------------------------------------------
// ciField::print
void ciField::print() {
tty->print("<ciField name=");
_holder->print_name();
tty->print(".");
_name->print_symbol();
tty->print(" signature=");
_signature->print_symbol();
tty->print(" offset=%d type=", _offset);
if (_type != NULL)
_type->print_name();
else
tty->print("(reference)");
tty->print(" flags=%04x", flags().as_int());
tty->print(" is_constant=%s", bool_to_str(_is_constant));
if (_is_constant && is_static()) {
tty->print(" constant_value=");
_constant_value.print();
}
tty->print(">");
}
// ------------------------------------------------------------------
// ciField::print_name_on
//
// Print the name of this field
void ciField::print_name_on(outputStream* st) {
name()->print_symbol_on(st);
}