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src/share/vm/c1/c1_Instruction.cpp@3cf667df43ef (annotated)

src/share/vm/c1/c1_Instruction.cpp

Tue, 09 Mar 2010 20:16:19 +0100

author

twisti

date

Tue, 09 Mar 2010 20:16:19 +0100

changeset 1730

3cf667df43ef

parent 435

a61af66fc99e

child 1907

c18cbe5936b8

permissions

-rw-r--r--

6919934: JSR 292 needs to support x86 C1
Summary: This implements JSR 292 support for C1 x86.
Reviewed-by: never, jrose, kvn

duke@435	1	/*
twisti@1730	2	* Copyright 1999-2010 Sun Microsystems, Inc. All Rights Reserved.
duke@435	3	* DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
duke@435	4	*
duke@435	5	* This code is free software; you can redistribute it and/or modify it
duke@435	6	* under the terms of the GNU General Public License version 2 only, as
duke@435	7	* published by the Free Software Foundation.
duke@435	8	*
duke@435	9	* This code is distributed in the hope that it will be useful, but WITHOUT
duke@435	10	* ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
duke@435	11	* FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
duke@435	12	* version 2 for more details (a copy is included in the LICENSE file that
duke@435	13	* accompanied this code).
duke@435	14	*
duke@435	15	* You should have received a copy of the GNU General Public License version
duke@435	16	* 2 along with this work; if not, write to the Free Software Foundation,
duke@435	17	* Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA.
duke@435	18	*
duke@435	19	* Please contact Sun Microsystems, Inc., 4150 Network Circle, Santa Clara,
duke@435	20	* CA 95054 USA or visit www.sun.com if you need additional information or
duke@435	21	* have any questions.
duke@435	22	*
duke@435	23	*/
duke@435	24
duke@435	25	#include "incls/_precompiled.incl"
duke@435	26	#include "incls/_c1_Instruction.cpp.incl"
duke@435	27
duke@435	28
duke@435	29	// Implementation of Instruction
duke@435	30
duke@435	31
duke@435	32	int Instruction::_next_id = 0;
duke@435	33
duke@435	34	#ifdef ASSERT
duke@435	35	void Instruction::create_hi_word() {
duke@435	36	assert(type()->is_double_word() && _hi_word == NULL, "only double word has high word");
duke@435	37	_hi_word = new HiWord(this);
duke@435	38	}
duke@435	39	#endif
duke@435	40
duke@435	41	Instruction::Condition Instruction::mirror(Condition cond) {
duke@435	42	switch (cond) {
duke@435	43	case eql: return eql;
duke@435	44	case neq: return neq;
duke@435	45	case lss: return gtr;
duke@435	46	case leq: return geq;
duke@435	47	case gtr: return lss;
duke@435	48	case geq: return leq;
duke@435	49	}
duke@435	50	ShouldNotReachHere();
duke@435	51	return eql;
duke@435	52	}
duke@435	53
duke@435	54
duke@435	55	Instruction::Condition Instruction::negate(Condition cond) {
duke@435	56	switch (cond) {
duke@435	57	case eql: return neq;
duke@435	58	case neq: return eql;
duke@435	59	case lss: return geq;
duke@435	60	case leq: return gtr;
duke@435	61	case gtr: return leq;
duke@435	62	case geq: return lss;
duke@435	63	}
duke@435	64	ShouldNotReachHere();
duke@435	65	return eql;
duke@435	66	}
duke@435	67
duke@435	68
duke@435	69	Instruction* Instruction::prev(BlockBegin* block) {
duke@435	70	Instruction* p = NULL;
duke@435	71	Instruction* q = block;
duke@435	72	while (q != this) {
duke@435	73	assert(q != NULL, "this is not in the block's instruction list");
duke@435	74	p = q; q = q->next();
duke@435	75	}
duke@435	76	return p;
duke@435	77	}
duke@435	78
duke@435	79
duke@435	80	#ifndef PRODUCT
duke@435	81	void Instruction::print() {
duke@435	82	InstructionPrinter ip;
duke@435	83	print(ip);
duke@435	84	}
duke@435	85
duke@435	86
duke@435	87	void Instruction::print_line() {
duke@435	88	InstructionPrinter ip;
duke@435	89	ip.print_line(this);
duke@435	90	}
duke@435	91
duke@435	92
duke@435	93	void Instruction::print(InstructionPrinter& ip) {
duke@435	94	ip.print_head();
duke@435	95	ip.print_line(this);
duke@435	96	tty->cr();
duke@435	97	}
duke@435	98	#endif // PRODUCT
duke@435	99
duke@435	100
duke@435	101	// perform constant and interval tests on index value
duke@435	102	bool AccessIndexed::compute_needs_range_check() {
duke@435	103	Constant* clength = length()->as_Constant();
duke@435	104	Constant* cindex = index()->as_Constant();
duke@435	105	if (clength && cindex) {
duke@435	106	IntConstant* l = clength->type()->as_IntConstant();
duke@435	107	IntConstant* i = cindex->type()->as_IntConstant();
duke@435	108	if (l && i && i->value() < l->value() && i->value() >= 0) {
duke@435	109	return false;
duke@435	110	}
duke@435	111	}
duke@435	112	return true;
duke@435	113	}
duke@435	114
duke@435	115
duke@435	116	ciType* LoadIndexed::exact_type() const {
duke@435	117	ciType* array_type = array()->exact_type();
duke@435	118	if (array_type == NULL) {
duke@435	119	return NULL;
duke@435	120	}
duke@435	121	assert(array_type->is_array_klass(), "what else?");
duke@435	122	ciArrayKlass* ak = (ciArrayKlass*)array_type;
duke@435	123
duke@435	124	if (ak->element_type()->is_instance_klass()) {
duke@435	125	ciInstanceKlass* ik = (ciInstanceKlass*)ak->element_type();
duke@435	126	if (ik->is_loaded() && ik->is_final()) {
duke@435	127	return ik;
duke@435	128	}
duke@435	129	}
duke@435	130	return NULL;
duke@435	131	}
duke@435	132
duke@435	133
duke@435	134	ciType* LoadIndexed::declared_type() const {
duke@435	135	ciType* array_type = array()->declared_type();
duke@435	136	if (array_type == NULL) {
duke@435	137	return NULL;
duke@435	138	}
duke@435	139	assert(array_type->is_array_klass(), "what else?");
duke@435	140	ciArrayKlass* ak = (ciArrayKlass*)array_type;
duke@435	141	return ak->element_type();
duke@435	142	}
duke@435	143
duke@435	144
duke@435	145	ciType* LoadField::declared_type() const {
duke@435	146	return field()->type();
duke@435	147	}
duke@435	148
duke@435	149
duke@435	150	ciType* LoadField::exact_type() const {
duke@435	151	ciType* type = declared_type();
duke@435	152	// for primitive arrays, the declared type is the exact type
duke@435	153	if (type->is_type_array_klass()) {
duke@435	154	return type;
duke@435	155	}
duke@435	156	if (type->is_instance_klass()) {
duke@435	157	ciInstanceKlass* ik = (ciInstanceKlass*)type;
duke@435	158	if (ik->is_loaded() && ik->is_final()) {
duke@435	159	return type;
duke@435	160	}
duke@435	161	}
duke@435	162	return NULL;
duke@435	163	}
duke@435	164
duke@435	165
duke@435	166	ciType* NewTypeArray::exact_type() const {
duke@435	167	return ciTypeArrayKlass::make(elt_type());
duke@435	168	}
duke@435	169
duke@435	170
duke@435	171	ciType* NewObjectArray::exact_type() const {
duke@435	172	return ciObjArrayKlass::make(klass());
duke@435	173	}
duke@435	174
duke@435	175
duke@435	176	ciType* NewInstance::exact_type() const {
duke@435	177	return klass();
duke@435	178	}
duke@435	179
duke@435	180
duke@435	181	ciType* CheckCast::declared_type() const {
duke@435	182	return klass();
duke@435	183	}
duke@435	184
duke@435	185	ciType* CheckCast::exact_type() const {
duke@435	186	if (klass()->is_instance_klass()) {
duke@435	187	ciInstanceKlass* ik = (ciInstanceKlass*)klass();
duke@435	188	if (ik->is_loaded() && ik->is_final()) {
duke@435	189	return ik;
duke@435	190	}
duke@435	191	}
duke@435	192	return NULL;
duke@435	193	}
duke@435	194
duke@435	195
duke@435	196	void ArithmeticOp::other_values_do(void f(Value*)) {
duke@435	197	if (lock_stack() != NULL) lock_stack()->values_do(f);
duke@435	198	}
duke@435	199
duke@435	200	void NullCheck::other_values_do(void f(Value*)) {
duke@435	201	lock_stack()->values_do(f);
duke@435	202	}
duke@435	203
duke@435	204	void AccessArray::other_values_do(void f(Value*)) {
duke@435	205	if (lock_stack() != NULL) lock_stack()->values_do(f);
duke@435	206	}
duke@435	207
duke@435	208
duke@435	209	// Implementation of AccessField
duke@435	210
duke@435	211	void AccessField::other_values_do(void f(Value*)) {
duke@435	212	if (state_before() != NULL) state_before()->values_do(f);
duke@435	213	if (lock_stack() != NULL) lock_stack()->values_do(f);
duke@435	214	}
duke@435	215
duke@435	216
duke@435	217	// Implementation of StoreIndexed
duke@435	218
duke@435	219	IRScope* StoreIndexed::scope() const {
duke@435	220	return lock_stack()->scope();
duke@435	221	}
duke@435	222
duke@435	223
duke@435	224	// Implementation of ArithmeticOp
duke@435	225
duke@435	226	bool ArithmeticOp::is_commutative() const {
duke@435	227	switch (op()) {
duke@435	228	case Bytecodes::_iadd: // fall through
duke@435	229	case Bytecodes::_ladd: // fall through
duke@435	230	case Bytecodes::_fadd: // fall through
duke@435	231	case Bytecodes::_dadd: // fall through
duke@435	232	case Bytecodes::_imul: // fall through
duke@435	233	case Bytecodes::_lmul: // fall through
duke@435	234	case Bytecodes::_fmul: // fall through
duke@435	235	case Bytecodes::_dmul: return true;
duke@435	236	}
duke@435	237	return false;
duke@435	238	}
duke@435	239
duke@435	240
duke@435	241	bool ArithmeticOp::can_trap() const {
duke@435	242	switch (op()) {
duke@435	243	case Bytecodes::_idiv: // fall through
duke@435	244	case Bytecodes::_ldiv: // fall through
duke@435	245	case Bytecodes::_irem: // fall through
duke@435	246	case Bytecodes::_lrem: return true;
duke@435	247	}
duke@435	248	return false;
duke@435	249	}
duke@435	250
duke@435	251
duke@435	252	// Implementation of LogicOp
duke@435	253
duke@435	254	bool LogicOp::is_commutative() const {
duke@435	255	#ifdef ASSERT
duke@435	256	switch (op()) {
duke@435	257	case Bytecodes::_iand: // fall through
duke@435	258	case Bytecodes::_land: // fall through
duke@435	259	case Bytecodes::_ior : // fall through
duke@435	260	case Bytecodes::_lor : // fall through
duke@435	261	case Bytecodes::_ixor: // fall through
duke@435	262	case Bytecodes::_lxor: break;
duke@435	263	default : ShouldNotReachHere();
duke@435	264	}
duke@435	265	#endif
duke@435	266	// all LogicOps are commutative
duke@435	267	return true;
duke@435	268	}
duke@435	269
duke@435	270
duke@435	271	// Implementation of CompareOp
duke@435	272
duke@435	273	void CompareOp::other_values_do(void f(Value*)) {
duke@435	274	if (state_before() != NULL) state_before()->values_do(f);
duke@435	275	}
duke@435	276
duke@435	277
duke@435	278	// Implementation of IfOp
duke@435	279
duke@435	280	bool IfOp::is_commutative() const {
duke@435	281	return cond() == eql || cond() == neq;
duke@435	282	}
duke@435	283
duke@435	284
duke@435	285	// Implementation of StateSplit
duke@435	286
duke@435	287	void StateSplit::substitute(BlockList& list, BlockBegin* old_block, BlockBegin* new_block) {
duke@435	288	NOT_PRODUCT(bool assigned = false;)
duke@435	289	for (int i = 0; i < list.length(); i++) {
duke@435	290	BlockBegin** b = list.adr_at(i);
duke@435	291	if (*b == old_block) {
duke@435	292	*b = new_block;
duke@435	293	NOT_PRODUCT(assigned = true;)
duke@435	294	}
duke@435	295	}
duke@435	296	assert(assigned == true, "should have assigned at least once");
duke@435	297	}
duke@435	298
duke@435	299
duke@435	300	IRScope* StateSplit::scope() const {
duke@435	301	return _state->scope();
duke@435	302	}
duke@435	303
duke@435	304
duke@435	305	void StateSplit::state_values_do(void f(Value*)) {
duke@435	306	if (state() != NULL) state()->values_do(f);
duke@435	307	}
duke@435	308
duke@435	309
duke@435	310	void BlockBegin::state_values_do(void f(Value*)) {
duke@435	311	StateSplit::state_values_do(f);
duke@435	312
duke@435	313	if (is_set(BlockBegin::exception_entry_flag)) {
duke@435	314	for (int i = 0; i < number_of_exception_states(); i++) {
duke@435	315	exception_state_at(i)->values_do(f);
duke@435	316	}
duke@435	317	}
duke@435	318	}
duke@435	319
duke@435	320
duke@435	321	void MonitorEnter::state_values_do(void f(Value*)) {
duke@435	322	StateSplit::state_values_do(f);
duke@435	323	_lock_stack_before->values_do(f);
duke@435	324	}
duke@435	325
duke@435	326
duke@435	327	void Intrinsic::state_values_do(void f(Value*)) {
duke@435	328	StateSplit::state_values_do(f);
duke@435	329	if (lock_stack() != NULL) lock_stack()->values_do(f);
duke@435	330	}
duke@435	331
duke@435	332
duke@435	333	// Implementation of Invoke
duke@435	334
duke@435	335
duke@435	336	Invoke::Invoke(Bytecodes::Code code, ValueType* result_type, Value recv, Values* args,
twisti@1730	337	int vtable_index, ciMethod* target, ValueStack* state_before)
duke@435	338	: StateSplit(result_type)
duke@435	339	, _code(code)
duke@435	340	, _recv(recv)
duke@435	341	, _args(args)
duke@435	342	, _vtable_index(vtable_index)
duke@435	343	, _target(target)
twisti@1730	344	, _state_before(state_before)
duke@435	345	{
duke@435	346	set_flag(TargetIsLoadedFlag, target->is_loaded());
duke@435	347	set_flag(TargetIsFinalFlag, target_is_loaded() && target->is_final_method());
duke@435	348	set_flag(TargetIsStrictfpFlag, target_is_loaded() && target->is_strict());
duke@435	349
duke@435	350	assert(args != NULL, "args must exist");
duke@435	351	#ifdef ASSERT
duke@435	352	values_do(assert_value);
duke@435	353	#endif // ASSERT
duke@435	354
duke@435	355	// provide an initial guess of signature size.
duke@435	356	_signature = new BasicTypeList(number_of_arguments() + (has_receiver() ? 1 : 0));
duke@435	357	if (has_receiver()) {
duke@435	358	_signature->append(as_BasicType(receiver()->type()));
twisti@1730	359	} else if (is_invokedynamic()) {
twisti@1730	360	// Add the synthetic MethodHandle argument to the signature.
twisti@1730	361	_signature->append(T_OBJECT);
duke@435	362	}
duke@435	363	for (int i = 0; i < number_of_arguments(); i++) {
duke@435	364	ValueType* t = argument_at(i)->type();
duke@435	365	BasicType bt = as_BasicType(t);
duke@435	366	_signature->append(bt);
duke@435	367	}
duke@435	368	}
duke@435	369
duke@435	370
twisti@1730	371	void Invoke::state_values_do(void f(Value*)) {
twisti@1730	372	StateSplit::state_values_do(f);
twisti@1730	373	if (state_before() != NULL) state_before()->values_do(f);
twisti@1730	374	if (state() != NULL) state()->values_do(f);
twisti@1730	375	}
twisti@1730	376
twisti@1730	377
duke@435	378	// Implementation of Contant
duke@435	379	intx Constant::hash() const {
duke@435	380	if (_state == NULL) {
duke@435	381	switch (type()->tag()) {
duke@435	382	case intTag:
duke@435	383	return HASH2(name(), type()->as_IntConstant()->value());
duke@435	384	case longTag:
duke@435	385	{
duke@435	386	jlong temp = type()->as_LongConstant()->value();
duke@435	387	return HASH3(name(), high(temp), low(temp));
duke@435	388	}
duke@435	389	case floatTag:
duke@435	390	return HASH2(name(), jint_cast(type()->as_FloatConstant()->value()));
duke@435	391	case doubleTag:
duke@435	392	{
duke@435	393	jlong temp = jlong_cast(type()->as_DoubleConstant()->value());
duke@435	394	return HASH3(name(), high(temp), low(temp));
duke@435	395	}
duke@435	396	case objectTag:
duke@435	397	assert(type()->as_ObjectType()->is_loaded(), "can't handle unloaded values");
duke@435	398	return HASH2(name(), type()->as_ObjectType()->constant_value());
duke@435	399	}
duke@435	400	}
duke@435	401	return 0;
duke@435	402	}
duke@435	403
duke@435	404	bool Constant::is_equal(Value v) const {
duke@435	405	if (v->as_Constant() == NULL) return false;
duke@435	406
duke@435	407	switch (type()->tag()) {
duke@435	408	case intTag:
duke@435	409	{
duke@435	410	IntConstant* t1 = type()->as_IntConstant();
duke@435	411	IntConstant* t2 = v->type()->as_IntConstant();
duke@435	412	return (t1 != NULL && t2 != NULL &&
duke@435	413	t1->value() == t2->value());
duke@435	414	}
duke@435	415	case longTag:
duke@435	416	{
duke@435	417	LongConstant* t1 = type()->as_LongConstant();
duke@435	418	LongConstant* t2 = v->type()->as_LongConstant();
duke@435	419	return (t1 != NULL && t2 != NULL &&
duke@435	420	t1->value() == t2->value());
duke@435	421	}
duke@435	422	case floatTag:
duke@435	423	{
duke@435	424	FloatConstant* t1 = type()->as_FloatConstant();
duke@435	425	FloatConstant* t2 = v->type()->as_FloatConstant();
duke@435	426	return (t1 != NULL && t2 != NULL &&
duke@435	427	jint_cast(t1->value()) == jint_cast(t2->value()));
duke@435	428	}
duke@435	429	case doubleTag:
duke@435	430	{
duke@435	431	DoubleConstant* t1 = type()->as_DoubleConstant();
duke@435	432	DoubleConstant* t2 = v->type()->as_DoubleConstant();
duke@435	433	return (t1 != NULL && t2 != NULL &&
duke@435	434	jlong_cast(t1->value()) == jlong_cast(t2->value()));
duke@435	435	}
duke@435	436	case objectTag:
duke@435	437	{
duke@435	438	ObjectType* t1 = type()->as_ObjectType();
duke@435	439	ObjectType* t2 = v->type()->as_ObjectType();
duke@435	440	return (t1 != NULL && t2 != NULL &&
duke@435	441	t1->is_loaded() && t2->is_loaded() &&
duke@435	442	t1->constant_value() == t2->constant_value());
duke@435	443	}
duke@435	444	}
duke@435	445	return false;
duke@435	446	}
duke@435	447
duke@435	448
duke@435	449	BlockBegin* Constant::compare(Instruction::Condition cond, Value right,
duke@435	450	BlockBegin* true_sux, BlockBegin* false_sux) {
duke@435	451	Constant* rc = right->as_Constant();
duke@435	452	// other is not a constant
duke@435	453	if (rc == NULL) return NULL;
duke@435	454
duke@435	455	ValueType* lt = type();
duke@435	456	ValueType* rt = rc->type();
duke@435	457	// different types
duke@435	458	if (lt->base() != rt->base()) return NULL;
duke@435	459	switch (lt->tag()) {
duke@435	460	case intTag: {
duke@435	461	int x = lt->as_IntConstant()->value();
duke@435	462	int y = rt->as_IntConstant()->value();
duke@435	463	switch (cond) {
duke@435	464	case If::eql: return x == y ? true_sux : false_sux;
duke@435	465	case If::neq: return x != y ? true_sux : false_sux;
duke@435	466	case If::lss: return x < y ? true_sux : false_sux;
duke@435	467	case If::leq: return x <= y ? true_sux : false_sux;
duke@435	468	case If::gtr: return x > y ? true_sux : false_sux;
duke@435	469	case If::geq: return x >= y ? true_sux : false_sux;
duke@435	470	}
duke@435	471	break;
duke@435	472	}
duke@435	473	case longTag: {
duke@435	474	jlong x = lt->as_LongConstant()->value();
duke@435	475	jlong y = rt->as_LongConstant()->value();
duke@435	476	switch (cond) {
duke@435	477	case If::eql: return x == y ? true_sux : false_sux;
duke@435	478	case If::neq: return x != y ? true_sux : false_sux;
duke@435	479	case If::lss: return x < y ? true_sux : false_sux;
duke@435	480	case If::leq: return x <= y ? true_sux : false_sux;
duke@435	481	case If::gtr: return x > y ? true_sux : false_sux;
duke@435	482	case If::geq: return x >= y ? true_sux : false_sux;
duke@435	483	}
duke@435	484	break;
duke@435	485	}
duke@435	486	case objectTag: {
duke@435	487	ciObject* xvalue = lt->as_ObjectType()->constant_value();
duke@435	488	ciObject* yvalue = rt->as_ObjectType()->constant_value();
duke@435	489	assert(xvalue != NULL && yvalue != NULL, "not constants");
duke@435	490	if (xvalue->is_loaded() && yvalue->is_loaded()) {
duke@435	491	switch (cond) {
duke@435	492	case If::eql: return xvalue == yvalue ? true_sux : false_sux;
duke@435	493	case If::neq: return xvalue != yvalue ? true_sux : false_sux;
duke@435	494	}
duke@435	495	}
duke@435	496	break;
duke@435	497	}
duke@435	498	}
duke@435	499	return NULL;
duke@435	500	}
duke@435	501
duke@435	502
duke@435	503	void Constant::other_values_do(void f(Value*)) {
duke@435	504	if (state() != NULL) state()->values_do(f);
duke@435	505	}
duke@435	506
duke@435	507
duke@435	508	// Implementation of NewArray
duke@435	509
duke@435	510	void NewArray::other_values_do(void f(Value*)) {
duke@435	511	if (state_before() != NULL) state_before()->values_do(f);
duke@435	512	}
duke@435	513
duke@435	514
duke@435	515	// Implementation of TypeCheck
duke@435	516
duke@435	517	void TypeCheck::other_values_do(void f(Value*)) {
duke@435	518	if (state_before() != NULL) state_before()->values_do(f);
duke@435	519	}
duke@435	520
duke@435	521
duke@435	522	// Implementation of BlockBegin
duke@435	523
duke@435	524	int BlockBegin::_next_block_id = 0;
duke@435	525
duke@435	526
duke@435	527	void BlockBegin::set_end(BlockEnd* end) {
duke@435	528	assert(end != NULL, "should not reset block end to NULL");
duke@435	529	BlockEnd* old_end = _end;
duke@435	530	if (end == old_end) {
duke@435	531	return;
duke@435	532	}
duke@435	533	// Must make the predecessors/successors match up with the
duke@435	534	// BlockEnd's notion.
duke@435	535	int i, n;
duke@435	536	if (old_end != NULL) {
duke@435	537	// disconnect from the old end
duke@435	538	old_end->set_begin(NULL);
duke@435	539
duke@435	540	// disconnect this block from it's current successors
duke@435	541	for (i = 0; i < _successors.length(); i++) {
duke@435	542	_successors.at(i)->remove_predecessor(this);
duke@435	543	}
duke@435	544	}
duke@435	545	_end = end;
duke@435	546
duke@435	547	_successors.clear();
duke@435	548	// Now reset successors list based on BlockEnd
duke@435	549	n = end->number_of_sux();
duke@435	550	for (i = 0; i < n; i++) {
duke@435	551	BlockBegin* sux = end->sux_at(i);
duke@435	552	_successors.append(sux);
duke@435	553	sux->_predecessors.append(this);
duke@435	554	}
duke@435	555	_end->set_begin(this);
duke@435	556	}
duke@435	557
duke@435	558
duke@435	559	void BlockBegin::disconnect_edge(BlockBegin* from, BlockBegin* to) {
duke@435	560	// disconnect any edges between from and to
duke@435	561	#ifndef PRODUCT
duke@435	562	if (PrintIR && Verbose) {
duke@435	563	tty->print_cr("Disconnected edge B%d -> B%d", from->block_id(), to->block_id());
duke@435	564	}
duke@435	565	#endif
duke@435	566	for (int s = 0; s < from->number_of_sux();) {
duke@435	567	BlockBegin* sux = from->sux_at(s);
duke@435	568	if (sux == to) {
duke@435	569	int index = sux->_predecessors.index_of(from);
duke@435	570	if (index >= 0) {
duke@435	571	sux->_predecessors.remove_at(index);
duke@435	572	}
duke@435	573	from->_successors.remove_at(s);
duke@435	574	} else {
duke@435	575	s++;
duke@435	576	}
duke@435	577	}
duke@435	578	}
duke@435	579
duke@435	580
duke@435	581	void BlockBegin::disconnect_from_graph() {
duke@435	582	// disconnect this block from all other blocks
duke@435	583	for (int p = 0; p < number_of_preds(); p++) {
duke@435	584	pred_at(p)->remove_successor(this);
duke@435	585	}
duke@435	586	for (int s = 0; s < number_of_sux(); s++) {
duke@435	587	sux_at(s)->remove_predecessor(this);
duke@435	588	}
duke@435	589	}
duke@435	590
duke@435	591	void BlockBegin::substitute_sux(BlockBegin* old_sux, BlockBegin* new_sux) {
duke@435	592	// modify predecessors before substituting successors
duke@435	593	for (int i = 0; i < number_of_sux(); i++) {
duke@435	594	if (sux_at(i) == old_sux) {
duke@435	595	// remove old predecessor before adding new predecessor
duke@435	596	// otherwise there is a dead predecessor in the list
duke@435	597	new_sux->remove_predecessor(old_sux);
duke@435	598	new_sux->add_predecessor(this);
duke@435	599	}
duke@435	600	}
duke@435	601	old_sux->remove_predecessor(this);
duke@435	602	end()->substitute_sux(old_sux, new_sux);
duke@435	603	}
duke@435	604
duke@435	605
duke@435	606
duke@435	607	// In general it is not possible to calculate a value for the field "depth_first_number"
duke@435	608	// of the inserted block, without recomputing the values of the other blocks
duke@435	609	// in the CFG. Therefore the value of "depth_first_number" in BlockBegin becomes meaningless.
duke@435	610	BlockBegin* BlockBegin::insert_block_between(BlockBegin* sux) {
duke@435	611	// Try to make the bci close to a block with a single pred or sux,
duke@435	612	// since this make the block layout algorithm work better.
duke@435	613	int bci = -1;
duke@435	614	if (sux->number_of_preds() == 1) {
duke@435	615	bci = sux->bci();
duke@435	616	} else {
duke@435	617	bci = end()->bci();
duke@435	618	}
duke@435	619
duke@435	620	BlockBegin* new_sux = new BlockBegin(bci);
duke@435	621
duke@435	622	// mark this block (special treatment when block order is computed)
duke@435	623	new_sux->set(critical_edge_split_flag);
duke@435	624
duke@435	625	// This goto is not a safepoint.
duke@435	626	Goto* e = new Goto(sux, false);
duke@435	627	new_sux->set_next(e, bci);
duke@435	628	new_sux->set_end(e);
duke@435	629	// setup states
duke@435	630	ValueStack* s = end()->state();
duke@435	631	new_sux->set_state(s->copy());
duke@435	632	e->set_state(s->copy());
duke@435	633	assert(new_sux->state()->locals_size() == s->locals_size(), "local size mismatch!");
duke@435	634	assert(new_sux->state()->stack_size() == s->stack_size(), "stack size mismatch!");
duke@435	635	assert(new_sux->state()->locks_size() == s->locks_size(), "locks size mismatch!");
duke@435	636
duke@435	637	// link predecessor to new block
duke@435	638	end()->substitute_sux(sux, new_sux);
duke@435	639
duke@435	640	// The ordering needs to be the same, so remove the link that the
duke@435	641	// set_end call above added and substitute the new_sux for this
duke@435	642	// block.
duke@435	643	sux->remove_predecessor(new_sux);
duke@435	644
duke@435	645	// the successor could be the target of a switch so it might have
duke@435	646	// multiple copies of this predecessor, so substitute the new_sux
duke@435	647	// for the first and delete the rest.
duke@435	648	bool assigned = false;
duke@435	649	BlockList& list = sux->_predecessors;
duke@435	650	for (int i = 0; i < list.length(); i++) {
duke@435	651	BlockBegin** b = list.adr_at(i);
duke@435	652	if (*b == this) {
duke@435	653	if (assigned) {
duke@435	654	list.remove_at(i);
duke@435	655	// reprocess this index
duke@435	656	i--;
duke@435	657	} else {
duke@435	658	assigned = true;
duke@435	659	*b = new_sux;
duke@435	660	}
duke@435	661	// link the new block back to it's predecessors.
duke@435	662	new_sux->add_predecessor(this);
duke@435	663	}
duke@435	664	}
duke@435	665	assert(assigned == true, "should have assigned at least once");
duke@435	666	return new_sux;
duke@435	667	}
duke@435	668
duke@435	669
duke@435	670	void BlockBegin::remove_successor(BlockBegin* pred) {
duke@435	671	int idx;
duke@435	672	while ((idx = _successors.index_of(pred)) >= 0) {
duke@435	673	_successors.remove_at(idx);
duke@435	674	}
duke@435	675	}
duke@435	676
duke@435	677
duke@435	678	void BlockBegin::add_predecessor(BlockBegin* pred) {
duke@435	679	_predecessors.append(pred);
duke@435	680	}
duke@435	681
duke@435	682
duke@435	683	void BlockBegin::remove_predecessor(BlockBegin* pred) {
duke@435	684	int idx;
duke@435	685	while ((idx = _predecessors.index_of(pred)) >= 0) {
duke@435	686	_predecessors.remove_at(idx);
duke@435	687	}
duke@435	688	}
duke@435	689
duke@435	690
duke@435	691	void BlockBegin::add_exception_handler(BlockBegin* b) {
duke@435	692	assert(b != NULL && (b->is_set(exception_entry_flag)), "exception handler must exist");
duke@435	693	// add only if not in the list already
duke@435	694	if (!_exception_handlers.contains(b)) _exception_handlers.append(b);
duke@435	695	}
duke@435	696
duke@435	697	int BlockBegin::add_exception_state(ValueStack* state) {
duke@435	698	assert(is_set(exception_entry_flag), "only for xhandlers");
duke@435	699	if (_exception_states == NULL) {
duke@435	700	_exception_states = new ValueStackStack(4);
duke@435	701	}
duke@435	702	_exception_states->append(state);
duke@435	703	return _exception_states->length() - 1;
duke@435	704	}
duke@435	705
duke@435	706
duke@435	707	void BlockBegin::iterate_preorder(boolArray& mark, BlockClosure* closure) {
duke@435	708	if (!mark.at(block_id())) {
duke@435	709	mark.at_put(block_id(), true);
duke@435	710	closure->block_do(this);
duke@435	711	BlockEnd* e = end(); // must do this after block_do because block_do may change it!
duke@435	712	{ for (int i = number_of_exception_handlers() - 1; i >= 0; i--) exception_handler_at(i)->iterate_preorder(mark, closure); }
duke@435	713	{ for (int i = e->number_of_sux () - 1; i >= 0; i--) e->sux_at (i)->iterate_preorder(mark, closure); }
duke@435	714	}
duke@435	715	}
duke@435	716
duke@435	717
duke@435	718	void BlockBegin::iterate_postorder(boolArray& mark, BlockClosure* closure) {
duke@435	719	if (!mark.at(block_id())) {
duke@435	720	mark.at_put(block_id(), true);
duke@435	721	BlockEnd* e = end();
duke@435	722	{ for (int i = number_of_exception_handlers() - 1; i >= 0; i--) exception_handler_at(i)->iterate_postorder(mark, closure); }
duke@435	723	{ for (int i = e->number_of_sux () - 1; i >= 0; i--) e->sux_at (i)->iterate_postorder(mark, closure); }
duke@435	724	closure->block_do(this);
duke@435	725	}
duke@435	726	}
duke@435	727
duke@435	728
duke@435	729	void BlockBegin::iterate_preorder(BlockClosure* closure) {
duke@435	730	boolArray mark(number_of_blocks(), false);
duke@435	731	iterate_preorder(mark, closure);
duke@435	732	}
duke@435	733
duke@435	734
duke@435	735	void BlockBegin::iterate_postorder(BlockClosure* closure) {
duke@435	736	boolArray mark(number_of_blocks(), false);
duke@435	737	iterate_postorder(mark, closure);
duke@435	738	}
duke@435	739
duke@435	740
duke@435	741	void BlockBegin::block_values_do(void f(Value*)) {
duke@435	742	for (Instruction* n = this; n != NULL; n = n->next()) n->values_do(f);
duke@435	743	}
duke@435	744
duke@435	745
duke@435	746	#ifndef PRODUCT
duke@435	747	#define TRACE_PHI(code) if (PrintPhiFunctions) { code; }
duke@435	748	#else
duke@435	749	#define TRACE_PHI(coce)
duke@435	750	#endif
duke@435	751
duke@435	752
duke@435	753	bool BlockBegin::try_merge(ValueStack* new_state) {
duke@435	754	TRACE_PHI(tty->print_cr("********** try_merge for block B%d", block_id()));
duke@435	755
duke@435	756	// local variables used for state iteration
duke@435	757	int index;
duke@435	758	Value new_value, existing_value;
duke@435	759
duke@435	760	ValueStack* existing_state = state();
duke@435	761	if (existing_state == NULL) {
duke@435	762	TRACE_PHI(tty->print_cr("first call of try_merge for this block"));
duke@435	763
duke@435	764	if (is_set(BlockBegin::was_visited_flag)) {
duke@435	765	// this actually happens for complicated jsr/ret structures
duke@435	766	return false; // BAILOUT in caller
duke@435	767	}
duke@435	768
duke@435	769	// copy state because it is altered
duke@435	770	new_state = new_state->copy();
duke@435	771
duke@435	772	// Use method liveness to invalidate dead locals
duke@435	773	MethodLivenessResult liveness = new_state->scope()->method()->liveness_at_bci(bci());
duke@435	774	if (liveness.is_valid()) {
duke@435	775	assert((int)liveness.size() == new_state->locals_size(), "error in use of liveness");
duke@435	776
duke@435	777	for_each_local_value(new_state, index, new_value) {
duke@435	778	if (!liveness.at(index) || new_value->type()->is_illegal()) {
duke@435	779	new_state->invalidate_local(index);
duke@435	780	TRACE_PHI(tty->print_cr("invalidating dead local %d", index));
duke@435	781	}
duke@435	782	}
duke@435	783	}
duke@435	784
duke@435	785	if (is_set(BlockBegin::parser_loop_header_flag)) {
duke@435	786	TRACE_PHI(tty->print_cr("loop header block, initializing phi functions"));
duke@435	787
duke@435	788	for_each_stack_value(new_state, index, new_value) {
duke@435	789	new_state->setup_phi_for_stack(this, index);
duke@435	790	TRACE_PHI(tty->print_cr("creating phi-function %c%d for stack %d", new_state->stack_at(index)->type()->tchar(), new_state->stack_at(index)->id(), index));
duke@435	791	}
duke@435	792
duke@435	793	BitMap requires_phi_function = new_state->scope()->requires_phi_function();
duke@435	794
duke@435	795	for_each_local_value(new_state, index, new_value) {
duke@435	796	bool requires_phi = requires_phi_function.at(index) || (new_value->type()->is_double_word() && requires_phi_function.at(index + 1));
duke@435	797	if (requires_phi || !SelectivePhiFunctions) {
duke@435	798	new_state->setup_phi_for_local(this, index);
duke@435	799	TRACE_PHI(tty->print_cr("creating phi-function %c%d for local %d", new_state->local_at(index)->type()->tchar(), new_state->local_at(index)->id(), index));
duke@435	800	}
duke@435	801	}
duke@435	802	}
duke@435	803
duke@435	804	// initialize state of block
duke@435	805	set_state(new_state);
duke@435	806
duke@435	807	} else if (existing_state->is_same_across_scopes(new_state)) {
duke@435	808	TRACE_PHI(tty->print_cr("exisiting state found"));
duke@435	809
duke@435	810	// Inlining may cause the local state not to match up, so walk up
duke@435	811	// the new state until we get to the same scope as the
duke@435	812	// existing and then start processing from there.
duke@435	813	while (existing_state->scope() != new_state->scope()) {
duke@435	814	new_state = new_state->caller_state();
duke@435	815	assert(new_state != NULL, "could not match up scopes");
duke@435	816
duke@435	817	assert(false, "check if this is necessary");
duke@435	818	}
duke@435	819
duke@435	820	assert(existing_state->scope() == new_state->scope(), "not matching");
duke@435	821	assert(existing_state->locals_size() == new_state->locals_size(), "not matching");
duke@435	822	assert(existing_state->stack_size() == new_state->stack_size(), "not matching");
duke@435	823
duke@435	824	if (is_set(BlockBegin::was_visited_flag)) {
duke@435	825	TRACE_PHI(tty->print_cr("loop header block, phis must be present"));
duke@435	826
duke@435	827	if (!is_set(BlockBegin::parser_loop_header_flag)) {
duke@435	828	// this actually happens for complicated jsr/ret structures
duke@435	829	return false; // BAILOUT in caller
duke@435	830	}
duke@435	831
duke@435	832	for_each_local_value(existing_state, index, existing_value) {
duke@435	833	Value new_value = new_state->local_at(index);
duke@435	834	if (new_value == NULL || new_value->type()->tag() != existing_value->type()->tag()) {
duke@435	835	// The old code invalidated the phi function here
duke@435	836	// Because dead locals are replaced with NULL, this is a very rare case now, so simply bail out
duke@435	837	return false; // BAILOUT in caller
duke@435	838	}
duke@435	839	}
duke@435	840
duke@435	841	#ifdef ASSERT
duke@435	842	// check that all necessary phi functions are present
duke@435	843	for_each_stack_value(existing_state, index, existing_value) {
duke@435	844	assert(existing_value->as_Phi() != NULL && existing_value->as_Phi()->block() == this, "phi function required");
duke@435	845	}
duke@435	846	for_each_local_value(existing_state, index, existing_value) {
duke@435	847	assert(existing_value == new_state->local_at(index) || (existing_value->as_Phi() != NULL && existing_value->as_Phi()->as_Phi()->block() == this), "phi function required");
duke@435	848	}
duke@435	849	#endif
duke@435	850
duke@435	851	} else {
duke@435	852	TRACE_PHI(tty->print_cr("creating phi functions on demand"));
duke@435	853
duke@435	854	// create necessary phi functions for stack
duke@435	855	for_each_stack_value(existing_state, index, existing_value) {
duke@435	856	Value new_value = new_state->stack_at(index);
duke@435	857	Phi* existing_phi = existing_value->as_Phi();
duke@435	858
duke@435	859	if (new_value != existing_value && (existing_phi == NULL || existing_phi->block() != this)) {
duke@435	860	existing_state->setup_phi_for_stack(this, index);
duke@435	861	TRACE_PHI(tty->print_cr("creating phi-function %c%d for stack %d", existing_state->stack_at(index)->type()->tchar(), existing_state->stack_at(index)->id(), index));
duke@435	862	}
duke@435	863	}
duke@435	864
duke@435	865	// create necessary phi functions for locals
duke@435	866	for_each_local_value(existing_state, index, existing_value) {
duke@435	867	Value new_value = new_state->local_at(index);
duke@435	868	Phi* existing_phi = existing_value->as_Phi();
duke@435	869
duke@435	870	if (new_value == NULL || new_value->type()->tag() != existing_value->type()->tag()) {
duke@435	871	existing_state->invalidate_local(index);
duke@435	872	TRACE_PHI(tty->print_cr("invalidating local %d because of type mismatch", index));
duke@435	873	} else if (new_value != existing_value && (existing_phi == NULL || existing_phi->block() != this)) {
duke@435	874	existing_state->setup_phi_for_local(this, index);
duke@435	875	TRACE_PHI(tty->print_cr("creating phi-function %c%d for local %d", existing_state->local_at(index)->type()->tchar(), existing_state->local_at(index)->id(), index));
duke@435	876	}
duke@435	877	}
duke@435	878	}
duke@435	879
duke@435	880	assert(existing_state->caller_state() == new_state->caller_state(), "caller states must be equal");
duke@435	881
duke@435	882	} else {
duke@435	883	assert(false, "stack or locks not matching (invalid bytecodes)");
duke@435	884	return false;
duke@435	885	}
duke@435	886
duke@435	887	TRACE_PHI(tty->print_cr("********** try_merge for block B%d successful", block_id()));
duke@435	888
duke@435	889	return true;
duke@435	890	}
duke@435	891
duke@435	892
duke@435	893	#ifndef PRODUCT
duke@435	894	void BlockBegin::print_block() {
duke@435	895	InstructionPrinter ip;
duke@435	896	print_block(ip, false);
duke@435	897	}
duke@435	898
duke@435	899
duke@435	900	void BlockBegin::print_block(InstructionPrinter& ip, bool live_only) {
duke@435	901	ip.print_instr(this); tty->cr();
duke@435	902	ip.print_stack(this->state()); tty->cr();
duke@435	903	ip.print_inline_level(this);
duke@435	904	ip.print_head();
duke@435	905	for (Instruction* n = next(); n != NULL; n = n->next()) {
duke@435	906	if (!live_only || n->is_pinned() || n->use_count() > 0) {
duke@435	907	ip.print_line(n);
duke@435	908	}
duke@435	909	}
duke@435	910	tty->cr();
duke@435	911	}
duke@435	912	#endif // PRODUCT
duke@435	913
duke@435	914
duke@435	915	// Implementation of BlockList
duke@435	916
duke@435	917	void BlockList::iterate_forward (BlockClosure* closure) {
duke@435	918	const int l = length();
duke@435	919	for (int i = 0; i < l; i++) closure->block_do(at(i));
duke@435	920	}
duke@435	921
duke@435	922
duke@435	923	void BlockList::iterate_backward(BlockClosure* closure) {
duke@435	924	for (int i = length() - 1; i >= 0; i--) closure->block_do(at(i));
duke@435	925	}
duke@435	926
duke@435	927
duke@435	928	void BlockList::blocks_do(void f(BlockBegin*)) {
duke@435	929	for (int i = length() - 1; i >= 0; i--) f(at(i));
duke@435	930	}
duke@435	931
duke@435	932
duke@435	933	void BlockList::values_do(void f(Value*)) {
duke@435	934	for (int i = length() - 1; i >= 0; i--) at(i)->block_values_do(f);
duke@435	935	}
duke@435	936
duke@435	937
duke@435	938	#ifndef PRODUCT
duke@435	939	void BlockList::print(bool cfg_only, bool live_only) {
duke@435	940	InstructionPrinter ip;
duke@435	941	for (int i = 0; i < length(); i++) {
duke@435	942	BlockBegin* block = at(i);
duke@435	943	if (cfg_only) {
duke@435	944	ip.print_instr(block); tty->cr();
duke@435	945	} else {
duke@435	946	block->print_block(ip, live_only);
duke@435	947	}
duke@435	948	}
duke@435	949	}
duke@435	950	#endif // PRODUCT
duke@435	951
duke@435	952
duke@435	953	// Implementation of BlockEnd
duke@435	954
duke@435	955	void BlockEnd::set_begin(BlockBegin* begin) {
duke@435	956	BlockList* sux = NULL;
duke@435	957	if (begin != NULL) {
duke@435	958	sux = begin->successors();
duke@435	959	} else if (_begin != NULL) {
duke@435	960	// copy our sux list
duke@435	961	BlockList* sux = new BlockList(_begin->number_of_sux());
duke@435	962	for (int i = 0; i < _begin->number_of_sux(); i++) {
duke@435	963	sux->append(_begin->sux_at(i));
duke@435	964	}
duke@435	965	}
duke@435	966	_sux = sux;
duke@435	967	_begin = begin;
duke@435	968	}
duke@435	969
duke@435	970
duke@435	971	void BlockEnd::substitute_sux(BlockBegin* old_sux, BlockBegin* new_sux) {
duke@435	972	substitute(*_sux, old_sux, new_sux);
duke@435	973	}
duke@435	974
duke@435	975
duke@435	976	void BlockEnd::other_values_do(void f(Value*)) {
duke@435	977	if (state_before() != NULL) state_before()->values_do(f);
duke@435	978	}
duke@435	979
duke@435	980
duke@435	981	// Implementation of Phi
duke@435	982
duke@435	983	// Normal phi functions take their operands from the last instruction of the
duke@435	984	// predecessor. Special handling is needed for xhanlder entries because there
duke@435	985	// the state of arbitrary instructions are needed.
duke@435	986
duke@435	987	Value Phi::operand_at(int i) const {
duke@435	988	ValueStack* state;
duke@435	989	if (_block->is_set(BlockBegin::exception_entry_flag)) {
duke@435	990	state = _block->exception_state_at(i);
duke@435	991	} else {
duke@435	992	state = _block->pred_at(i)->end()->state();
duke@435	993	}
duke@435	994	assert(state != NULL, "");
duke@435	995
duke@435	996	if (is_local()) {
duke@435	997	return state->local_at(local_index());
duke@435	998	} else {
duke@435	999	return state->stack_at(stack_index());
duke@435	1000	}
duke@435	1001	}
duke@435	1002
duke@435	1003
duke@435	1004	int Phi::operand_count() const {
duke@435	1005	if (_block->is_set(BlockBegin::exception_entry_flag)) {
duke@435	1006	return _block->number_of_exception_states();
duke@435	1007	} else {
duke@435	1008	return _block->number_of_preds();
duke@435	1009	}
duke@435	1010	}
duke@435	1011
duke@435	1012
duke@435	1013	// Implementation of Throw
duke@435	1014
duke@435	1015	void Throw::state_values_do(void f(Value*)) {
duke@435	1016	BlockEnd::state_values_do(f);
duke@435	1017	}