7023639: JSR 292 method handle invocation needs a fast path for compiled code
6984705: JSR 292 method handle creation should not go through JNI
Summary: remove assembly code for JDK 7 chained method handles
Reviewed-by: jrose, twisti, kvn, mhaupt
Contributed-by: John Rose <john.r.rose@oracle.com>, Christian Thalinger <christian.thalinger@oracle.com>, Michael Haupt <michael.haupt@oracle.com>
/*
* Copyright (c) 1998, 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.
*
*/
#include "precompiled.hpp"
#include "gc_implementation/shared/markSweep.inline.hpp"
#include "interpreter/interpreter.hpp"
#include "interpreter/rewriter.hpp"
#include "memory/universe.inline.hpp"
#include "oops/cpCacheOop.hpp"
#include "oops/objArrayOop.hpp"
#include "oops/oop.inline.hpp"
#include "prims/jvmtiRedefineClassesTrace.hpp"
#include "prims/methodHandles.hpp"
#include "runtime/handles.inline.hpp"
// Implememtation of ConstantPoolCacheEntry
void ConstantPoolCacheEntry::initialize_entry(int index) {
assert(0 < index && index < 0x10000, "sanity check");
_indices = index;
assert(constant_pool_index() == index, "");
}
void ConstantPoolCacheEntry::initialize_secondary_entry(int main_index) {
assert(0 <= main_index && main_index < 0x10000, "sanity check");
_indices = (main_index << main_cp_index_bits);
assert(main_entry_index() == main_index, "");
}
int ConstantPoolCacheEntry::make_flags(TosState state,
int option_bits,
int field_index_or_method_params) {
assert(state < number_of_states, "Invalid state in make_flags");
int f = ((int)state << tos_state_shift) | option_bits | field_index_or_method_params;
// Preserve existing flag bit values
// The low bits are a field offset, or else the method parameter size.
#ifdef ASSERT
TosState old_state = flag_state();
assert(old_state == (TosState)0 || old_state == state,
"inconsistent cpCache flags state");
#endif
return (_flags | f) ;
}
void ConstantPoolCacheEntry::set_bytecode_1(Bytecodes::Code code) {
assert(!is_secondary_entry(), "must not overwrite main_entry_index");
#ifdef ASSERT
// Read once.
volatile Bytecodes::Code c = bytecode_1();
assert(c == 0 || c == code || code == 0, "update must be consistent");
#endif
// Need to flush pending stores here before bytecode is written.
OrderAccess::release_store_ptr(&_indices, _indices | ((u_char)code << bytecode_1_shift));
}
void ConstantPoolCacheEntry::set_bytecode_2(Bytecodes::Code code) {
assert(!is_secondary_entry(), "must not overwrite main_entry_index");
#ifdef ASSERT
// Read once.
volatile Bytecodes::Code c = bytecode_2();
assert(c == 0 || c == code || code == 0, "update must be consistent");
#endif
// Need to flush pending stores here before bytecode is written.
OrderAccess::release_store_ptr(&_indices, _indices | ((u_char)code << bytecode_2_shift));
}
// Sets f1, ordering with previous writes.
void ConstantPoolCacheEntry::release_set_f1(oop f1) {
// Use barriers as in oop_store
assert(f1 != NULL, "");
oop* f1_addr = (oop*) &_f1;
update_barrier_set_pre(f1_addr, f1);
OrderAccess::release_store_ptr((intptr_t*)f1_addr, f1);
update_barrier_set((void*) f1_addr, f1);
}
// Sets flags, but only if the value was previously zero.
bool ConstantPoolCacheEntry::init_flags_atomic(intptr_t flags) {
intptr_t result = Atomic::cmpxchg_ptr(flags, &_flags, 0);
return (result == 0);
}
#ifdef ASSERT
// It is possible to have two different dummy methodOops created
// when the resolve code for invoke interface executes concurrently
// Hence the assertion below is weakened a bit for the invokeinterface
// case.
bool ConstantPoolCacheEntry::same_methodOop(oop cur_f1, oop f1) {
return (cur_f1 == f1 || ((methodOop)cur_f1)->name() ==
((methodOop)f1)->name() || ((methodOop)cur_f1)->signature() ==
((methodOop)f1)->signature());
}
#endif
// Note that concurrent update of both bytecodes can leave one of them
// reset to zero. This is harmless; the interpreter will simply re-resolve
// the damaged entry. More seriously, the memory synchronization is needed
// to flush other fields (f1, f2) completely to memory before the bytecodes
// are updated, lest other processors see a non-zero bytecode but zero f1/f2.
void ConstantPoolCacheEntry::set_field(Bytecodes::Code get_code,
Bytecodes::Code put_code,
KlassHandle field_holder,
int field_index,
int field_offset,
TosState field_type,
bool is_final,
bool is_volatile) {
set_f1(field_holder()->java_mirror());
set_f2(field_offset);
assert((field_index & field_index_mask) == field_index,
"field index does not fit in low flag bits");
set_field_flags(field_type,
((is_volatile ? 1 : 0) << is_volatile_shift) |
((is_final ? 1 : 0) << is_final_shift),
field_index);
set_bytecode_1(get_code);
set_bytecode_2(put_code);
NOT_PRODUCT(verify(tty));
}
void ConstantPoolCacheEntry::set_parameter_size(int value) {
// This routine is called only in corner cases where the CPCE is not yet initialized.
// See AbstractInterpreter::deopt_continue_after_entry.
assert(_flags == 0 || parameter_size() == 0 || parameter_size() == value,
err_msg("size must not change: parameter_size=%d, value=%d", parameter_size(), value));
// Setting the parameter size by itself is only safe if the
// current value of _flags is 0, otherwise another thread may have
// updated it and we don't want to overwrite that value. Don't
// bother trying to update it once it's nonzero but always make
// sure that the final parameter size agrees with what was passed.
if (_flags == 0) {
Atomic::cmpxchg_ptr((value & parameter_size_mask), &_flags, 0);
}
guarantee(parameter_size() == value,
err_msg("size must not change: parameter_size=%d, value=%d", parameter_size(), value));
}
void ConstantPoolCacheEntry::set_method(Bytecodes::Code invoke_code,
methodHandle method,
int vtable_index) {
assert(!is_secondary_entry(), "");
assert(method->interpreter_entry() != NULL, "should have been set at this point");
assert(!method->is_obsolete(), "attempt to write obsolete method to cpCache");
int byte_no = -1;
bool change_to_virtual = false;
switch (invoke_code) {
case Bytecodes::_invokeinterface:
// We get here from InterpreterRuntime::resolve_invoke when an invokeinterface
// instruction somehow links to a non-interface method (in Object).
// In that case, the method has no itable index and must be invoked as a virtual.
// Set a flag to keep track of this corner case.
change_to_virtual = true;
// ...and fall through as if we were handling invokevirtual:
case Bytecodes::_invokevirtual:
{
if (method->can_be_statically_bound()) {
// set_f2_as_vfinal_method checks if is_vfinal flag is true.
set_method_flags(as_TosState(method->result_type()),
( 1 << is_vfinal_shift) |
((method->is_final_method() ? 1 : 0) << is_final_shift) |
((change_to_virtual ? 1 : 0) << is_forced_virtual_shift),
method()->size_of_parameters());
set_f2_as_vfinal_method(method());
} else {
assert(vtable_index >= 0, "valid index");
assert(!method->is_final_method(), "sanity");
set_method_flags(as_TosState(method->result_type()),
((change_to_virtual ? 1 : 0) << is_forced_virtual_shift),
method()->size_of_parameters());
set_f2(vtable_index);
}
byte_no = 2;
break;
}
case Bytecodes::_invokespecial:
case Bytecodes::_invokestatic:
// Note: Read and preserve the value of the is_vfinal flag on any
// invokevirtual bytecode shared with this constant pool cache entry.
// It is cheap and safe to consult is_vfinal() at all times.
// Once is_vfinal is set, it must stay that way, lest we get a dangling oop.
set_method_flags(as_TosState(method->result_type()),
((is_vfinal() ? 1 : 0) << is_vfinal_shift) |
((method->is_final_method() ? 1 : 0) << is_final_shift),
method()->size_of_parameters());
set_f1(method());
byte_no = 1;
break;
default:
ShouldNotReachHere();
break;
}
// Note: byte_no also appears in TemplateTable::resolve.
if (byte_no == 1) {
assert(invoke_code != Bytecodes::_invokevirtual &&
invoke_code != Bytecodes::_invokeinterface, "");
set_bytecode_1(invoke_code);
} else if (byte_no == 2) {
if (change_to_virtual) {
assert(invoke_code == Bytecodes::_invokeinterface, "");
// NOTE: THIS IS A HACK - BE VERY CAREFUL!!!
//
// Workaround for the case where we encounter an invokeinterface, but we
// should really have an _invokevirtual since the resolved method is a
// virtual method in java.lang.Object. This is a corner case in the spec
// but is presumably legal. javac does not generate this code.
//
// We set bytecode_1() to _invokeinterface, because that is the
// bytecode # used by the interpreter to see if it is resolved.
// We set bytecode_2() to _invokevirtual.
// See also interpreterRuntime.cpp. (8/25/2000)
// Only set resolved for the invokeinterface case if method is public.
// Otherwise, the method needs to be reresolved with caller for each
// interface call.
if (method->is_public()) set_bytecode_1(invoke_code);
} else {
assert(invoke_code == Bytecodes::_invokevirtual, "");
}
// set up for invokevirtual, even if linking for invokeinterface also:
set_bytecode_2(Bytecodes::_invokevirtual);
} else {
ShouldNotReachHere();
}
NOT_PRODUCT(verify(tty));
}
void ConstantPoolCacheEntry::set_interface_call(methodHandle method, int index) {
assert(!is_secondary_entry(), "");
klassOop interf = method->method_holder();
assert(instanceKlass::cast(interf)->is_interface(), "must be an interface");
assert(!method->is_final_method(), "interfaces do not have final methods; cannot link to one here");
set_f1(interf);
set_f2(index);
set_method_flags(as_TosState(method->result_type()),
0, // no option bits
method()->size_of_parameters());
set_bytecode_1(Bytecodes::_invokeinterface);
}
void ConstantPoolCacheEntry::set_method_handle(methodHandle adapter, Handle appendix) {
assert(!is_secondary_entry(), "");
set_method_handle_common(Bytecodes::_invokehandle, adapter, appendix);
}
void ConstantPoolCacheEntry::set_dynamic_call(methodHandle adapter, Handle appendix) {
assert(is_secondary_entry(), "");
set_method_handle_common(Bytecodes::_invokedynamic, adapter, appendix);
}
void ConstantPoolCacheEntry::set_method_handle_common(Bytecodes::Code invoke_code, methodHandle adapter, Handle appendix) {
// NOTE: This CPCE can be the subject of data races.
// There are three words to update: flags, f2, f1 (in that order).
// Writers must store all other values before f1.
// Readers must test f1 first for non-null before reading other fields.
// Competing writers must acquire exclusive access on the first
// write, to flags, using a compare/exchange.
// A losing writer must spin until the winner writes f1,
// so that when he returns, he can use the linked cache entry.
bool has_appendix = appendix.not_null();
if (!has_appendix) {
// The extra argument is not used, but we need a non-null value to signify linkage state.
// Set it to something benign that will never leak memory.
appendix = Universe::void_mirror();
}
bool owner =
init_method_flags_atomic(as_TosState(adapter->result_type()),
((has_appendix ? 1 : 0) << has_appendix_shift) |
( 1 << is_vfinal_shift) |
( 1 << is_final_shift),
adapter->size_of_parameters());
if (!owner) {
while (is_f1_null()) {
// Pause momentarily on a low-level lock, to allow racing thread to win.
MutexLockerEx mu(Patching_lock, Mutex::_no_safepoint_check_flag);
os::yield();
}
return;
}
if (TraceInvokeDynamic) {
tty->print_cr("set_method_handle bc=%d appendix="PTR_FORMAT"%s method="PTR_FORMAT" ",
invoke_code,
(intptr_t)appendix(), (has_appendix ? "" : " (unused)"),
(intptr_t)adapter());
adapter->print();
if (has_appendix) appendix()->print();
}
// Method handle invokes and invokedynamic sites use both cp cache words.
// f1, if not null, contains a value passed as a trailing argument to the adapter.
// In the general case, this could be the call site's MethodType,
// for use with java.lang.Invokers.checkExactType, or else a CallSite object.
// f2 contains the adapter method which manages the actual call.
// In the general case, this is a compiled LambdaForm.
// (The Java code is free to optimize these calls by binding other
// sorts of methods and appendices to call sites.)
// JVM-level linking is via f2, as if for invokevfinal, and signatures are erased.
// The appendix argument (if any) is added to the signature, and is counted in the parameter_size bits.
// In principle this means that the method (with appendix) could take up to 256 parameter slots.
//
// This means that given a call site like (List)mh.invoke("foo"),
// the f2 method has signature '(Ljl/Object;Ljl/invoke/MethodType;)Ljl/Object;',
// not '(Ljava/lang/String;)Ljava/util/List;'.
// The fact that String and List are involved is encoded in the MethodType in f1.
// This allows us to create fewer method oops, while keeping type safety.
//
set_f2_as_vfinal_method(adapter());
assert(appendix.not_null(), "needed for linkage state");
release_set_f1(appendix()); // This must be the last one to set (see NOTE above)!
if (!is_secondary_entry()) {
// The interpreter assembly code does not check byte_2,
// but it is used by is_resolved, method_if_resolved, etc.
set_bytecode_2(invoke_code);
}
NOT_PRODUCT(verify(tty));
if (TraceInvokeDynamic) {
this->print(tty, 0);
}
}
methodOop ConstantPoolCacheEntry::method_if_resolved(constantPoolHandle cpool) {
if (is_secondary_entry()) {
if (!is_f1_null())
return f2_as_vfinal_method();
return NULL;
}
// Decode the action of set_method and set_interface_call
Bytecodes::Code invoke_code = bytecode_1();
if (invoke_code != (Bytecodes::Code)0) {
oop f1 = _f1;
if (f1 != NULL) {
switch (invoke_code) {
case Bytecodes::_invokeinterface:
assert(f1->is_klass(), "");
return klassItable::method_for_itable_index(klassOop(f1), f2_as_index());
case Bytecodes::_invokestatic:
case Bytecodes::_invokespecial:
assert(!has_appendix(), "");
assert(f1->is_method(), "");
return methodOop(f1);
}
}
}
invoke_code = bytecode_2();
if (invoke_code != (Bytecodes::Code)0) {
switch (invoke_code) {
case Bytecodes::_invokevirtual:
if (is_vfinal()) {
// invokevirtual
methodOop m = f2_as_vfinal_method();
assert(m->is_method(), "");
return m;
} else {
int holder_index = cpool->uncached_klass_ref_index_at(constant_pool_index());
if (cpool->tag_at(holder_index).is_klass()) {
klassOop klass = cpool->resolved_klass_at(holder_index);
if (!Klass::cast(klass)->oop_is_instance())
klass = SystemDictionary::Object_klass();
return instanceKlass::cast(klass)->method_at_vtable(f2_as_index());
}
}
break;
case Bytecodes::_invokehandle:
case Bytecodes::_invokedynamic:
return f2_as_vfinal_method();
}
}
return NULL;
}
class LocalOopClosure: public OopClosure {
private:
void (*_f)(oop*);
public:
LocalOopClosure(void f(oop*)) { _f = f; }
virtual void do_oop(oop* o) { _f(o); }
virtual void do_oop(narrowOop *o) { ShouldNotReachHere(); }
};
void ConstantPoolCacheEntry::oops_do(void f(oop*)) {
LocalOopClosure blk(f);
oop_iterate(&blk);
}
void ConstantPoolCacheEntry::oop_iterate(OopClosure* blk) {
assert(in_words(size()) == 4, "check code below - may need adjustment");
// field[1] is always oop or NULL
blk->do_oop((oop*)&_f1);
if (is_vfinal()) {
blk->do_oop((oop*)&_f2);
}
}
void ConstantPoolCacheEntry::oop_iterate_m(OopClosure* blk, MemRegion mr) {
assert(in_words(size()) == 4, "check code below - may need adjustment");
// field[1] is always oop or NULL
if (mr.contains((oop *)&_f1)) blk->do_oop((oop*)&_f1);
if (is_vfinal()) {
if (mr.contains((oop *)&_f2)) blk->do_oop((oop*)&_f2);
}
}
void ConstantPoolCacheEntry::follow_contents() {
assert(in_words(size()) == 4, "check code below - may need adjustment");
// field[1] is always oop or NULL
MarkSweep::mark_and_push((oop*)&_f1);
if (is_vfinal()) {
MarkSweep::mark_and_push((oop*)&_f2);
}
}
#ifndef SERIALGC
void ConstantPoolCacheEntry::follow_contents(ParCompactionManager* cm) {
assert(in_words(size()) == 4, "check code below - may need adjustment");
// field[1] is always oop or NULL
PSParallelCompact::mark_and_push(cm, (oop*)&_f1);
if (is_vfinal()) {
PSParallelCompact::mark_and_push(cm, (oop*)&_f2);
}
}
#endif // SERIALGC
void ConstantPoolCacheEntry::adjust_pointers() {
assert(in_words(size()) == 4, "check code below - may need adjustment");
// field[1] is always oop or NULL
MarkSweep::adjust_pointer((oop*)&_f1);
if (is_vfinal()) {
MarkSweep::adjust_pointer((oop*)&_f2);
}
}
#ifndef SERIALGC
void ConstantPoolCacheEntry::update_pointers() {
assert(in_words(size()) == 4, "check code below - may need adjustment");
// field[1] is always oop or NULL
PSParallelCompact::adjust_pointer((oop*)&_f1);
if (is_vfinal()) {
PSParallelCompact::adjust_pointer((oop*)&_f2);
}
}
#endif // SERIALGC
// RedefineClasses() API support:
// If this constantPoolCacheEntry refers to old_method then update it
// to refer to new_method.
bool ConstantPoolCacheEntry::adjust_method_entry(methodOop old_method,
methodOop new_method, bool * trace_name_printed) {
if (is_vfinal()) {
// virtual and final so _f2 contains method ptr instead of vtable index
if (f2_as_vfinal_method() == old_method) {
// match old_method so need an update
// NOTE: can't use set_f2_as_vfinal_method as it asserts on different values
_f2 = (intptr_t)new_method;
if (RC_TRACE_IN_RANGE(0x00100000, 0x00400000)) {
if (!(*trace_name_printed)) {
// RC_TRACE_MESG macro has an embedded ResourceMark
RC_TRACE_MESG(("adjust: name=%s",
Klass::cast(old_method->method_holder())->external_name()));
*trace_name_printed = true;
}
// RC_TRACE macro has an embedded ResourceMark
RC_TRACE(0x00400000, ("cpc vf-entry update: %s(%s)",
new_method->name()->as_C_string(),
new_method->signature()->as_C_string()));
}
return true;
}
// f1() is not used with virtual entries so bail out
return false;
}
if ((oop)_f1 == NULL) {
// NULL f1() means this is a virtual entry so bail out
// We are assuming that the vtable index does not need change.
return false;
}
if ((oop)_f1 == old_method) {
_f1 = new_method;
if (RC_TRACE_IN_RANGE(0x00100000, 0x00400000)) {
if (!(*trace_name_printed)) {
// RC_TRACE_MESG macro has an embedded ResourceMark
RC_TRACE_MESG(("adjust: name=%s",
Klass::cast(old_method->method_holder())->external_name()));
*trace_name_printed = true;
}
// RC_TRACE macro has an embedded ResourceMark
RC_TRACE(0x00400000, ("cpc entry update: %s(%s)",
new_method->name()->as_C_string(),
new_method->signature()->as_C_string()));
}
return true;
}
return false;
}
bool ConstantPoolCacheEntry::is_interesting_method_entry(klassOop k) {
if (!is_method_entry()) {
// not a method entry so not interesting by default
return false;
}
methodOop m = NULL;
if (is_vfinal()) {
// virtual and final so _f2 contains method ptr instead of vtable index
m = f2_as_vfinal_method();
} else if (is_f1_null()) {
// NULL _f1 means this is a virtual entry so also not interesting
return false;
} else {
oop f1 = _f1; // _f1 is volatile
if (!f1->is_method()) {
// _f1 can also contain a klassOop for an interface
return false;
}
m = f1_as_method();
}
assert(m != NULL && m->is_method(), "sanity check");
if (m == NULL || !m->is_method() || m->method_holder() != k) {
// robustness for above sanity checks or method is not in
// the interesting class
return false;
}
// the method is in the interesting class so the entry is interesting
return true;
}
void ConstantPoolCacheEntry::print(outputStream* st, int index) const {
// print separator
if (index == 0) st->print_cr(" -------------");
// print entry
st->print("%3d ("PTR_FORMAT") ", index, (intptr_t)this);
if (is_secondary_entry())
st->print_cr("[%5d|secondary]", main_entry_index());
else
st->print_cr("[%02x|%02x|%5d]", bytecode_2(), bytecode_1(), constant_pool_index());
st->print_cr(" [ "PTR_FORMAT"]", (intptr_t)(oop)_f1);
st->print_cr(" [ "PTR_FORMAT"]", (intptr_t)_f2);
st->print_cr(" [ "PTR_FORMAT"]", (intptr_t)_flags);
st->print_cr(" -------------");
}
void ConstantPoolCacheEntry::verify(outputStream* st) const {
// not implemented yet
}
// Implementation of ConstantPoolCache
void constantPoolCacheOopDesc::initialize(intArray& inverse_index_map) {
assert(inverse_index_map.length() == length(), "inverse index map must have same length as cache");
for (int i = 0; i < length(); i++) {
ConstantPoolCacheEntry* e = entry_at(i);
int original_index = inverse_index_map[i];
if ((original_index & Rewriter::_secondary_entry_tag) != 0) {
int main_index = (original_index - Rewriter::_secondary_entry_tag);
assert(!entry_at(main_index)->is_secondary_entry(), "valid main index");
e->initialize_secondary_entry(main_index);
} else {
e->initialize_entry(original_index);
}
assert(entry_at(i) == e, "sanity");
}
}
// RedefineClasses() API support:
// If any entry of this constantPoolCache points to any of
// old_methods, replace it with the corresponding new_method.
void constantPoolCacheOopDesc::adjust_method_entries(methodOop* old_methods, methodOop* new_methods,
int methods_length, bool * trace_name_printed) {
if (methods_length == 0) {
// nothing to do if there are no methods
return;
}
// get shorthand for the interesting class
klassOop old_holder = old_methods[0]->method_holder();
for (int i = 0; i < length(); i++) {
if (!entry_at(i)->is_interesting_method_entry(old_holder)) {
// skip uninteresting methods
continue;
}
// The constantPoolCache contains entries for several different
// things, but we only care about methods. In fact, we only care
// about methods in the same class as the one that contains the
// old_methods. At this point, we have an interesting entry.
for (int j = 0; j < methods_length; j++) {
methodOop old_method = old_methods[j];
methodOop new_method = new_methods[j];
if (entry_at(i)->adjust_method_entry(old_method, new_method,
trace_name_printed)) {
// current old_method matched this entry and we updated it so
// break out and get to the next interesting entry if there one
break;
}
}
}
}