/home/daniel/Projects/java/jdk/src/hotspot/share/adlc/formssel.cpp

Bug Summary

File:	jdk/src/hotspot/share/adlc/formssel.cpp
Warning:	line 1239, column 19 Value stored to 'stack_or_reg_mask_name' during its initialization is never read

Annotated Source Code

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clang -cc1 -triple x86_64-pc-linux-gnu -analyze -disable-free -disable-llvm-verifier -discard-value-names -main-file-name formssel.cpp -analyzer-store=region -analyzer-opt-analyze-nested-blocks -analyzer-checker=core -analyzer-checker=apiModeling -analyzer-checker=unix -analyzer-checker=deadcode -analyzer-checker=cplusplus -analyzer-checker=security.insecureAPI.UncheckedReturn -analyzer-checker=security.insecureAPI.getpw -analyzer-checker=security.insecureAPI.gets -analyzer-checker=security.insecureAPI.mktemp -analyzer-checker=security.insecureAPI.mkstemp -analyzer-checker=security.insecureAPI.vfork -analyzer-checker=nullability.NullPassedToNonnull -analyzer-checker=nullability.NullReturnedFromNonnull -analyzer-output plist -w -setup-static-analyzer -mrelocation-model static -mthread-model posix -mframe-pointer=all -fmath-errno -fno-rounding-math -masm-verbose -mconstructor-aliases -munwind-tables -target-cpu x86-64 -dwarf-column-info -fno-split-dwarf-inlining -debugger-tuning=gdb -resource-dir /usr/lib/llvm-10/lib/clang/10.0.0 -D LINUX -D ASSERT -D AMD64 -I /home/daniel/Projects/java/jdk/src/hotspot/share -internal-isystem /usr/lib/gcc/x86_64-linux-gnu/7.5.0/../../../../include/c++/7.5.0 -internal-isystem /usr/lib/gcc/x86_64-linux-gnu/7.5.0/../../../../include/x86_64-linux-gnu/c++/7.5.0 -internal-isystem /usr/lib/gcc/x86_64-linux-gnu/7.5.0/../../../../include/x86_64-linux-gnu/c++/7.5.0 -internal-isystem /usr/lib/gcc/x86_64-linux-gnu/7.5.0/../../../../include/c++/7.5.0/backward -internal-isystem /usr/local/include -internal-isystem /usr/lib/llvm-10/lib/clang/10.0.0/include -internal-externc-isystem /usr/include/x86_64-linux-gnu -internal-externc-isystem /include -internal-externc-isystem /usr/include -Wno-unused-parameter -Wno-unused -fdeprecated-macro -fdebug-compilation-dir /home/daniel/Projects/java/jdk/make/hotspot -ferror-limit 19 -fmessage-length 0 -fgnuc-version=4.2.1 -fobjc-runtime=gcc -fdiagnostics-show-option -analyzer-output=html -faddrsig -o /home/daniel/Projects/java/scan/2021-12-21-193737-8510-1 -x c++ /home/daniel/Projects/java/jdk/src/hotspot/share/adlc/formssel.cpp

1	/*
2	* Copyright (c) 1998, 2021, Oracle and/or its affiliates. All rights reserved.
3	* DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
4	*
5	* This code is free software; you can redistribute it and/or modify it
6	* under the terms of the GNU General Public License version 2 only, as
7	* published by the Free Software Foundation.
8	*
9	* This code is distributed in the hope that it will be useful, but WITHOUT
10	* ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
11	* FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
12	* version 2 for more details (a copy is included in the LICENSE file that
13	* accompanied this code).
14	*
15	* You should have received a copy of the GNU General Public License version
16	* 2 along with this work; if not, write to the Free Software Foundation,
17	* Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA.
18	*
19	* Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA
20	* or visit www.oracle.com if you need additional information or have any
21	* questions.
22	*
23	*/
24
25	// FORMS.CPP - Definitions for ADL Parser Forms Classes
26	#include "adlc.hpp"
27
28	//==============================Instructions===================================
29	//------------------------------InstructForm-----------------------------------
30	InstructForm::InstructForm(const char *id, bool ideal_only)
31	: _ident(id), _ideal_only(ideal_only),
32	_localNames(cmpstr, hashstr, Form::arena),
33	_effects(cmpstr, hashstr, Form::arena),
34	_is_mach_constant(false),
35	_needs_constant_base(false),
36	_has_call(false)
37	{
38	_ftype = Form::INS;
39
40	_matrule = NULL__null;
41	_insencode = NULL__null;
42	_constant = NULL__null;
43	_is_postalloc_expand = false;
44	_opcode = NULL__null;
45	_size = NULL__null;
46	_attribs = NULL__null;
47	_predicate = NULL__null;
48	_exprule = NULL__null;
49	_rewrule = NULL__null;
50	_format = NULL__null;
51	_peephole = NULL__null;
52	_ins_pipe = NULL__null;
53	_uniq_idx = NULL__null;
54	_num_uniq = 0;
55	_cisc_spill_operand = Not_cisc_spillable;// Which operand may cisc-spill
56	_cisc_spill_alternate = NULL__null; // possible cisc replacement
57	_cisc_reg_mask_name = NULL__null;
58	_is_cisc_alternate = false;
59	_is_short_branch = false;
60	_short_branch_form = NULL__null;
61	_alignment = 1;
62	}
63
64	InstructForm::InstructForm(const char id, InstructForm instr, MatchRule *rule)
65	: _ident(id), _ideal_only(false),
66	_localNames(instr->_localNames),
67	_effects(instr->_effects),
68	_is_mach_constant(false),
69	_needs_constant_base(false),
70	_has_call(false)
71	{
72	_ftype = Form::INS;
73
74	_matrule = rule;
75	_insencode = instr->_insencode;
76	_constant = instr->_constant;
77	_is_postalloc_expand = instr->_is_postalloc_expand;
78	_opcode = instr->_opcode;
79	_size = instr->_size;
80	_attribs = instr->_attribs;
81	_predicate = instr->_predicate;
82	_exprule = instr->_exprule;
83	_rewrule = instr->_rewrule;
84	_format = instr->_format;
85	_peephole = instr->_peephole;
86	_ins_pipe = instr->_ins_pipe;
87	_uniq_idx = instr->_uniq_idx;
88	_num_uniq = instr->_num_uniq;
89	_cisc_spill_operand = Not_cisc_spillable; // Which operand may cisc-spill
90	_cisc_spill_alternate = NULL__null; // possible cisc replacement
91	_cisc_reg_mask_name = NULL__null;
92	_is_cisc_alternate = false;
93	_is_short_branch = false;
94	_short_branch_form = NULL__null;
95	_alignment = 1;
96	// Copy parameters
97	const char *name;
98	instr->_parameters.reset();
99	for (; (name = instr->_parameters.iter()) != NULL__null;)
100	_parameters.addName(name);
101	}
102
103	InstructForm::~InstructForm() {
104	}
105
106	InstructForm *InstructForm::is_instruction() const {
107	return (InstructForm*)this;
108	}
109
110	bool InstructForm::ideal_only() const {
111	return _ideal_only;
112	}
113
114	bool InstructForm::sets_result() const {
115	return (_matrule != NULL__null && _matrule->sets_result());
116	}
117
118	bool InstructForm::needs_projections() {
119	_components.reset();
120	for( Component *comp; (comp = _components.iter()) != NULL__null; ) {
121	if (comp->isa(Component::KILL)) {
122	return true;
123	}
124	}
125	return false;
126	}
127
128
129	bool InstructForm::has_temps() {
130	if (_matrule) {
131	// Examine each component to see if it is a TEMP
132	_components.reset();
133	// Skip the first component, if already handled as (SET dst (...))
134	Component *comp = NULL__null;
135	if (sets_result()) comp = _components.iter();
136	while ((comp = _components.iter()) != NULL__null) {
137	if (comp->isa(Component::TEMP)) {
138	return true;
139	}
140	}
141	}
142
143	return false;
144	}
145
146	uintunsigned int InstructForm::num_defs_or_kills() {
147	uintunsigned int defs_or_kills = 0;
148
149	_components.reset();
150	for( Component *comp; (comp = _components.iter()) != NULL__null; ) {
151	if( comp->isa(Component::DEF) \|\| comp->isa(Component::KILL) ) {
152	++defs_or_kills;
153	}
154	}
155
156	return defs_or_kills;
157	}
158
159	// This instruction has an expand rule?
160	bool InstructForm::expands() const {
161	return ( _exprule != NULL__null );
162	}
163
164	// This instruction has a late expand rule?
165	bool InstructForm::postalloc_expands() const {
166	return _is_postalloc_expand;
167	}
168
169	// This instruction has a peephole rule?
170	Peephole *InstructForm::peepholes() const {
171	return _peephole;
172	}
173
174	// This instruction has a peephole rule?
175	void InstructForm::append_peephole(Peephole *peephole) {
176	if( _peephole == NULL__null ) {
177	_peephole = peephole;
178	} else {
179	_peephole->append_peephole(peephole);
180	}
181	}
182
183
184	// ideal opcode enumeration
185	const char *InstructForm::ideal_Opcode( FormDict &globalNames ) const {
186	if( !_matrule ) return "Node"; // Something weird
187	// Chain rules do not really have ideal Opcodes; use their source
188	// operand ideal Opcode instead.
189	if( is_simple_chain_rule(globalNames) ) {
190	const char *src = _matrule->_rChild->_opType;
191	OperandForm *src_op = globalNames[src]->is_operand();
192	assert( src_op, "Not operand class of chain rule" ){ if (!(src_op)) { fprintf(stderr, "assert fails %s %d: %s\n" , "/home/daniel/Projects/java/jdk/src/hotspot/share/adlc/formssel.cpp" , 192, "Not operand class of chain rule"); abort(); }};
193	if( !src_op->_matrule ) return "Node";
194	return src_op->_matrule->_opType;
195	}
196	// Operand chain rules do not really have ideal Opcodes
197	if( _matrule->is_chain_rule(globalNames) )
198	return "Node";
199	return strcmp(_matrule->_opType,"Set")
200	? _matrule->_opType
201	: _matrule->_rChild->_opType;
202	}
203
204	// Recursive check on all operands' match rules in my match rule
205	bool InstructForm::is_pinned(FormDict &globals) {
206	if ( ! _matrule) return false;
207
208	int index = 0;
209	if (_matrule->find_type("Goto", index)) return true;
210	if (_matrule->find_type("If", index)) return true;
211	if (_matrule->find_type("CountedLoopEnd",index)) return true;
212	if (_matrule->find_type("Return", index)) return true;
213	if (_matrule->find_type("Rethrow", index)) return true;
214	if (_matrule->find_type("TailCall", index)) return true;
215	if (_matrule->find_type("TailJump", index)) return true;
216	if (_matrule->find_type("Halt", index)) return true;
217	if (_matrule->find_type("Jump", index)) return true;
218
219	return is_parm(globals);
220	}
221
222	// Recursive check on all operands' match rules in my match rule
223	bool InstructForm::is_projection(FormDict &globals) {
224	if ( ! _matrule) return false;
225
226	int index = 0;
227	if (_matrule->find_type("Goto", index)) return true;
228	if (_matrule->find_type("Return", index)) return true;
229	if (_matrule->find_type("Rethrow", index)) return true;
230	if (_matrule->find_type("TailCall",index)) return true;
231	if (_matrule->find_type("TailJump",index)) return true;
232	if (_matrule->find_type("Halt", index)) return true;
233
234	return false;
235	}
236
237	// Recursive check on all operands' match rules in my match rule
238	bool InstructForm::is_parm(FormDict &globals) {
239	if ( ! _matrule) return false;
240
241	int index = 0;
242	if (_matrule->find_type("Parm",index)) return true;
243
244	return false;
245	}
246
247	bool InstructForm::is_ideal_negD() const {
248	return (_matrule && _matrule->_rChild && strcmp(_matrule->_rChild->_opType, "NegD") == 0);
249	}
250
251	// Return 'true' if this instruction matches an ideal 'Copy*' node
252	int InstructForm::is_ideal_copy() const {
253	return _matrule ? _matrule->is_ideal_copy() : 0;
254	}
255
256	// Return 'true' if this instruction is too complex to rematerialize.
257	int InstructForm::is_expensive() const {
258	// We can prove it is cheap if it has an empty encoding.
259	// This helps with platform-specific nops like ThreadLocal and RoundFloat.
260	if (is_empty_encoding())
261	return 0;
262
263	if (is_tls_instruction())
264	return 1;
265
266	if (_matrule == NULL__null) return 0;
267
268	return _matrule->is_expensive();
269	}
270
271	// Has an empty encoding if _size is a constant zero or there
272	// are no ins_encode tokens.
273	int InstructForm::is_empty_encoding() const {
274	if (_insencode != NULL__null) {
275	_insencode->reset();
276	if (_insencode->encode_class_iter() == NULL__null) {
277	return 1;
278	}
279	}
280	if (_size != NULL__null && strcmp(_size, "0") == 0) {
281	return 1;
282	}
283	return 0;
284	}
285
286	int InstructForm::is_tls_instruction() const {
287	if (_ident != NULL__null &&
288	( ! strcmp( _ident,"tlsLoadP") \|\|
289	! strncmp(_ident,"tlsLoadP_",9)) ) {
290	return 1;
291	}
292
293	if (_matrule != NULL__null && _insencode != NULL__null) {
294	const char* opType = _matrule->_opType;
295	if (strcmp(opType, "Set")==0)
296	opType = _matrule->_rChild->_opType;
297	if (strcmp(opType,"ThreadLocal")==0) {
298	fprintf(stderrstderr, "Warning: ThreadLocal instruction %s should be named 'tlsLoadP_*'\n",
299	(_ident == NULL__null ? "NULL" : _ident));
300	return 1;
301	}
302	}
303
304	return 0;
305	}
306
307
308	// Return 'true' if this instruction matches an ideal 'If' node
309	bool InstructForm::is_ideal_if() const {
310	if( _matrule == NULL__null ) return false;
311
312	return _matrule->is_ideal_if();
313	}
314
315	// Return 'true' if this instruction matches an ideal 'FastLock' node
316	bool InstructForm::is_ideal_fastlock() const {
317	if( _matrule == NULL__null ) return false;
318
319	return _matrule->is_ideal_fastlock();
320	}
321
322	// Return 'true' if this instruction matches an ideal 'MemBarXXX' node
323	bool InstructForm::is_ideal_membar() const {
324	if( _matrule == NULL__null ) return false;
325
326	return _matrule->is_ideal_membar();
327	}
328
329	// Return 'true' if this instruction matches an ideal 'LoadPC' node
330	bool InstructForm::is_ideal_loadPC() const {
331	if( _matrule == NULL__null ) return false;
332
333	return _matrule->is_ideal_loadPC();
334	}
335
336	// Return 'true' if this instruction matches an ideal 'Box' node
337	bool InstructForm::is_ideal_box() const {
338	if( _matrule == NULL__null ) return false;
339
340	return _matrule->is_ideal_box();
341	}
342
343	// Return 'true' if this instruction matches an ideal 'Goto' node
344	bool InstructForm::is_ideal_goto() const {
345	if( _matrule == NULL__null ) return false;
346
347	return _matrule->is_ideal_goto();
348	}
349
350	// Return 'true' if this instruction matches an ideal 'Jump' node
351	bool InstructForm::is_ideal_jump() const {
352	if( _matrule == NULL__null ) return false;
353
354	return _matrule->is_ideal_jump();
355	}
356
357	// Return 'true' if instruction matches ideal 'If' \| 'Goto' \| 'CountedLoopEnd'
358	bool InstructForm::is_ideal_branch() const {
359	if( _matrule == NULL__null ) return false;
360
361	return _matrule->is_ideal_if() \|\| _matrule->is_ideal_goto();
362	}
363
364
365	// Return 'true' if this instruction matches an ideal 'Return' node
366	bool InstructForm::is_ideal_return() const {
367	if( _matrule == NULL__null ) return false;
368
369	// Check MatchRule to see if the first entry is the ideal "Return" node
370	int index = 0;
371	if (_matrule->find_type("Return",index)) return true;
372	if (_matrule->find_type("Rethrow",index)) return true;
373	if (_matrule->find_type("TailCall",index)) return true;
374	if (_matrule->find_type("TailJump",index)) return true;
375
376	return false;
377	}
378
379	// Return 'true' if this instruction matches an ideal 'Halt' node
380	bool InstructForm::is_ideal_halt() const {
381	int index = 0;
382	return _matrule && _matrule->find_type("Halt",index);
383	}
384
385	// Return 'true' if this instruction matches an ideal 'SafePoint' node
386	bool InstructForm::is_ideal_safepoint() const {
387	int index = 0;
388	return _matrule && _matrule->find_type("SafePoint",index);
389	}
390
391	// Return 'true' if this instruction matches an ideal 'Nop' node
392	bool InstructForm::is_ideal_nop() const {
393	return _ident && _ident[0] == 'N' && _ident[1] == 'o' && _ident[2] == 'p' && _ident[3] == '_';
394	}
395
396	bool InstructForm::is_ideal_control() const {
397	if ( ! _matrule) return false;
398
399	return is_ideal_return() \|\| is_ideal_branch() \|\| _matrule->is_ideal_jump() \|\| is_ideal_halt();
400	}
401
402	// Return 'true' if this instruction matches an ideal 'Call' node
403	Form::CallType InstructForm::is_ideal_call() const {
404	if( _matrule == NULL__null ) return Form::invalid_type;
405
406	// Check MatchRule to see if the first entry is the ideal "Call" node
407	int idx = 0;
408	if(_matrule->find_type("CallStaticJava",idx)) return Form::JAVA_STATIC;
409	idx = 0;
410	if(_matrule->find_type("Lock",idx)) return Form::JAVA_STATIC;
411	idx = 0;
412	if(_matrule->find_type("Unlock",idx)) return Form::JAVA_STATIC;
413	idx = 0;
414	if(_matrule->find_type("CallDynamicJava",idx)) return Form::JAVA_DYNAMIC;
415	idx = 0;
416	if(_matrule->find_type("CallRuntime",idx)) return Form::JAVA_RUNTIME;
417	idx = 0;
418	if(_matrule->find_type("CallLeaf",idx)) return Form::JAVA_LEAF;
419	idx = 0;
420	if(_matrule->find_type("CallLeafNoFP",idx)) return Form::JAVA_LEAF;
421	idx = 0;
422	if(_matrule->find_type("CallLeafVector",idx)) return Form::JAVA_LEAF;
423	idx = 0;
424	if(_matrule->find_type("CallNative",idx)) return Form::JAVA_NATIVE;
425	idx = 0;
426
427	return Form::invalid_type;
428	}
429
430	// Return 'true' if this instruction matches an ideal 'Load?' node
431	Form::DataType InstructForm::is_ideal_load() const {
432	if( _matrule == NULL__null ) return Form::none;
433
434	return _matrule->is_ideal_load();
435	}
436
437	// Return 'true' if this instruction matches an ideal 'LoadKlass' node
438	bool InstructForm::skip_antidep_check() const {
439	if( _matrule == NULL__null ) return false;
440
441	return _matrule->skip_antidep_check();
442	}
443
444	// Return 'true' if this instruction matches an ideal 'Load?' node
445	Form::DataType InstructForm::is_ideal_store() const {
446	if( _matrule == NULL__null ) return Form::none;
447
448	return _matrule->is_ideal_store();
449	}
450
451	// Return 'true' if this instruction matches an ideal vector node
452	bool InstructForm::is_vector() const {
453	if( _matrule == NULL__null ) return false;
454
455	return _matrule->is_vector();
456	}
457
458
459	// Return the input register that must match the output register
460	// If this is not required, return 0
461	uintunsigned int InstructForm::two_address(FormDict &globals) {
462	uintunsigned int matching_input = 0;
463	if(_components.count() == 0) return 0;
464
465	_components.reset();
466	Component *comp = _components.iter();
467	// Check if there is a DEF
468	if( comp->isa(Component::DEF) ) {
469	// Check that this is a register
470	const char *def_type = comp->_type;
471	const Form *form = globals[def_type];
472	OperandForm *op = form->is_operand();
473	if( op ) {
474	if( op->constrained_reg_class() != NULL__null &&
475	op->interface_type(globals) == Form::register_interface ) {
476	// Remember the local name for equality test later
477	const char *def_name = comp->_name;
478	// Check if a component has the same name and is a USE
479	do {
480	if( comp->isa(Component::USE) && strcmp(comp->_name,def_name)==0 ) {
481	return operand_position_format(def_name);
482	}
483	} while( (comp = _components.iter()) != NULL__null);
484	}
485	}
486	}
487
488	return 0;
489	}
490
491
492	// when chaining a constant to an instruction, returns 'true' and sets opType
493	Form::DataType InstructForm::is_chain_of_constant(FormDict &globals) {
494	const char *dummy = NULL__null;
495	const char *dummy2 = NULL__null;
496	return is_chain_of_constant(globals, dummy, dummy2);
497	}
498	Form::DataType InstructForm::is_chain_of_constant(FormDict &globals,
499	const char * &opTypeParam) {
500	const char *result = NULL__null;
501
502	return is_chain_of_constant(globals, opTypeParam, result);
503	}
504
505	Form::DataType InstructForm::is_chain_of_constant(FormDict &globals,
506	const char * &opTypeParam, const char * &resultParam) {
507	Form::DataType data_type = Form::none;
508	if ( ! _matrule) return data_type;
509
510	// !!!!!
511	// The source of the chain rule is 'position = 1'
512	uintunsigned int position = 1;
513	const char *result = NULL__null;
514	const char *name = NULL__null;
515	const char *opType = NULL__null;
516	// Here base_operand is looking for an ideal type to be returned (opType).
517	if ( _matrule->is_chain_rule(globals)
518	&& _matrule->base_operand(position, globals, result, name, opType) ) {
519	data_type = ideal_to_const_type(opType);
520
521	// if it isn't an ideal constant type, just return
522	if ( data_type == Form::none ) return data_type;
523
524	// Ideal constant types also adjust the opType parameter.
525	resultParam = result;
526	opTypeParam = opType;
527	return data_type;
528	}
529
530	return data_type;
531	}
532
533	// Check if a simple chain rule
534	bool InstructForm::is_simple_chain_rule(FormDict &globals) const {
535	if( _matrule && _matrule->sets_result()
536	&& _matrule->_rChild->_lChild == NULL__null
537	&& globals[_matrule->_rChild->_opType]
538	&& globals[_matrule->_rChild->_opType]->is_opclass() ) {
539	return true;
540	}
541	return false;
542	}
543
544	// check for structural rematerialization
545	bool InstructForm::rematerialize(FormDict &globals, RegisterForm *registers ) {
546	bool rematerialize = false;
547
548	Form::DataType data_type = is_chain_of_constant(globals);
549	if( data_type != Form::none )
550	rematerialize = true;
551
552	// Constants
553	if( _components.count() == 1 && _components[0]->is(Component::USE_DEF) )
554	rematerialize = true;
555
556	// Pseudo-constants (values easily available to the runtime)
557	if (is_empty_encoding() && is_tls_instruction())
558	rematerialize = true;
559
560	// 1-input, 1-output, such as copies or increments.
561	if( _components.count() == 2 &&
562	_components[0]->is(Component::DEF) &&
563	_components[1]->isa(Component::USE) )
564	rematerialize = true;
565
566	// Check for an ideal 'Load?' and eliminate rematerialize option
567	if ( is_ideal_load() != Form::none \|\| // Ideal load? Do not rematerialize
568	is_ideal_copy() != Form::none \|\| // Ideal copy? Do not rematerialize
569	is_expensive() != Form::none) { // Expensive? Do not rematerialize
570	rematerialize = false;
571	}
572
573	// Always rematerialize the flags. They are more expensive to save &
574	// restore than to recompute (and possibly spill the compare's inputs).
575	if( _components.count() >= 1 ) {
576	Component *c = _components[0];
577	const Form *form = globals[c->_type];
578	OperandForm *opform = form->is_operand();
579	if( opform ) {
580	// Avoid the special stack_slots register classes
581	const char *rc_name = opform->constrained_reg_class();
582	if( rc_name ) {
583	if( strcmp(rc_name,"stack_slots") ) {
584	// Check for ideal_type of RegFlags
585	const char *type = opform->ideal_type( globals, registers );
586	if( (type != NULL__null) && !strcmp(type, "RegFlags") )
587	rematerialize = true;
588	} else
589	rematerialize = false; // Do not rematerialize things target stk
590	}
591	}
592	}
593
594	return rematerialize;
595	}
596
597	// loads from memory, so must check for anti-dependence
598	bool InstructForm::needs_anti_dependence_check(FormDict &globals) const {
599	if ( skip_antidep_check() ) return false;
600
601	// Machine independent loads must be checked for anti-dependences
602	if( is_ideal_load() != Form::none ) return true;
603
604	// !!!!! !!!!! !!!!!
605	// TEMPORARY
606	// if( is_simple_chain_rule(globals) ) return false;
607
608	// String.(compareTo/equals/indexOf) and Arrays.equals use many memorys edges,
609	// but writes none
610	if( _matrule && _matrule->_rChild &&
611	( strcmp(_matrule->_rChild->_opType,"StrComp" )==0 \|\|
612	strcmp(_matrule->_rChild->_opType,"StrEquals" )==0 \|\|
613	strcmp(_matrule->_rChild->_opType,"StrIndexOf" )==0 \|\|
614	strcmp(_matrule->_rChild->_opType,"StrIndexOfChar" )==0 \|\|
615	strcmp(_matrule->_rChild->_opType,"HasNegatives" )==0 \|\|
616	strcmp(_matrule->_rChild->_opType,"AryEq" )==0 ))
617	return true;
618
619	// Check if instruction has a USE of a memory operand class, but no defs
620	bool USE_of_memory = false;
621	bool DEF_of_memory = false;
622	Component *comp = NULL__null;
623	ComponentList &components = (ComponentList &)_components;
624
625	components.reset();
626	while( (comp = components.iter()) != NULL__null ) {
627	const Form *form = globals[comp->_type];
628	if( !form ) continue;
629	OpClassForm *op = form->is_opclass();
630	if( !op ) continue;
631	if( form->interface_type(globals) == Form::memory_interface ) {
632	if( comp->isa(Component::USE) ) USE_of_memory = true;
633	if( comp->isa(Component::DEF) ) {
634	OperandForm *oper = form->is_operand();
635	if( oper && oper->is_user_name_for_sReg() ) {
636	// Stack slots are unaliased memory handled by allocator
637	oper = oper; // debug stopping point !!!!!
638	} else {
639	DEF_of_memory = true;
640	}
641	}
642	}
643	}
644	return (USE_of_memory && !DEF_of_memory);
645	}
646
647
648	int InstructForm::memory_operand(FormDict &globals) const {
649	// Machine independent loads must be checked for anti-dependences
650	// Check if instruction has a USE of a memory operand class, or a def.
651	int USE_of_memory = 0;
652	int DEF_of_memory = 0;
653	const char* last_memory_DEF = NULL__null; // to test DEF/USE pairing in asserts
654	const char* last_memory_USE = NULL__null;
655	Component *unique = NULL__null;
656	Component *comp = NULL__null;
657	ComponentList &components = (ComponentList &)_components;
658
659	components.reset();
660	while( (comp = components.iter()) != NULL__null ) {
661	const Form *form = globals[comp->_type];
662	if( !form ) continue;
663	OpClassForm *op = form->is_opclass();
664	if( !op ) continue;
665	if( op->stack_slots_only(globals) ) continue;
666	if( form->interface_type(globals) == Form::memory_interface ) {
667	if( comp->isa(Component::DEF) ) {
668	last_memory_DEF = comp->_name;
669	DEF_of_memory++;
670	unique = comp;
671	} else if( comp->isa(Component::USE) ) {
672	if( last_memory_DEF != NULL__null ) {
673	assert(0 == strcmp(last_memory_DEF, comp->_name), "every memory DEF is followed by a USE of the same name"){ if (!(0 == strcmp(last_memory_DEF, comp->_name))) { fprintf (stderr, "assert fails %s %d: %s\n", "/home/daniel/Projects/java/jdk/src/hotspot/share/adlc/formssel.cpp" , 673, "every memory DEF is followed by a USE of the same name" ); abort(); }};
674	last_memory_DEF = NULL__null;
675	}
676	// Handles same memory being used multiple times in the case of BMI1 instructions.
677	if (last_memory_USE != NULL__null) {
678	if (strcmp(comp->_name, last_memory_USE) != 0) {
679	USE_of_memory++;
680	}
681	} else {
682	USE_of_memory++;
683	}
684	last_memory_USE = comp->_name;
685
686	if (DEF_of_memory == 0) // defs take precedence
687	unique = comp;
688	} else {
689	assert(last_memory_DEF == NULL, "unpaired memory DEF"){ if (!(last_memory_DEF == __null)) { fprintf(stderr, "assert fails %s %d: %s\n" , "/home/daniel/Projects/java/jdk/src/hotspot/share/adlc/formssel.cpp" , 689, "unpaired memory DEF"); abort(); }};
690	}
691	}
692	}
693	assert(last_memory_DEF == NULL, "unpaired memory DEF"){ if (!(last_memory_DEF == __null)) { fprintf(stderr, "assert fails %s %d: %s\n" , "/home/daniel/Projects/java/jdk/src/hotspot/share/adlc/formssel.cpp" , 693, "unpaired memory DEF"); abort(); }};
694	assert(USE_of_memory >= DEF_of_memory, "unpaired memory DEF"){ if (!(USE_of_memory >= DEF_of_memory)) { fprintf(stderr, "assert fails %s %d: %s\n", "/home/daniel/Projects/java/jdk/src/hotspot/share/adlc/formssel.cpp" , 694, "unpaired memory DEF"); abort(); }};
695	USE_of_memory -= DEF_of_memory; // treat paired DEF/USE as one occurrence
696	if( (USE_of_memory + DEF_of_memory) > 0 ) {
697	if( is_simple_chain_rule(globals) ) {
698	//fprintf(stderr, "Warning: chain rule is not really a memory user.\n");
699	//((InstructForm*)this)->dump();
700	// Preceding code prints nothing on sparc and these insns on intel:
701	// leaP8 leaP32 leaPIdxOff leaPIdxScale leaPIdxScaleOff leaP8 leaP32
702	// leaPIdxOff leaPIdxScale leaPIdxScaleOff
703	return NO_MEMORY_OPERAND;
704	}
705
706	if( DEF_of_memory == 1 ) {
707	assert(unique != NULL, ""){ if (!(unique != __null)) { fprintf(stderr, "assert fails %s %d: %s\n" , "/home/daniel/Projects/java/jdk/src/hotspot/share/adlc/formssel.cpp" , 707, ""); abort(); }};
708	if( USE_of_memory == 0 ) {
709	// unique def, no uses
710	} else {
711	// // unique def, some uses
712	// // must return bottom unless all uses match def
713	// unique = NULL;
714	#ifdef S390
715	// This case is important for move instructions on s390x.
716	// On other platforms (e.g. x86), all uses always match the def.
717	unique = NULL__null;
718	#endif
719	}
720	} else if( DEF_of_memory > 0 ) {
721	// multiple defs, don't care about uses
722	unique = NULL__null;
723	} else if( USE_of_memory == 1) {
724	// unique use, no defs
725	assert(unique != NULL, ""){ if (!(unique != __null)) { fprintf(stderr, "assert fails %s %d: %s\n" , "/home/daniel/Projects/java/jdk/src/hotspot/share/adlc/formssel.cpp" , 725, ""); abort(); }};
726	} else if( USE_of_memory > 0 ) {
727	// multiple uses, no defs
728	unique = NULL__null;
729	} else {
730	assert(false, "bad case analysis"){ if (!(false)) { fprintf(stderr, "assert fails %s %d: %s\n", "/home/daniel/Projects/java/jdk/src/hotspot/share/adlc/formssel.cpp" , 730, "bad case analysis"); abort(); }};
731	}
732	// process the unique DEF or USE, if there is one
733	if( unique == NULL__null ) {
734	return MANY_MEMORY_OPERANDS;
735	} else {
736	int pos = components.operand_position(unique->_name);
737	if( unique->isa(Component::DEF) ) {
738	pos += 1; // get corresponding USE from DEF
739	}
740	assert(pos >= 1, "I was just looking at it!"){ if (!(pos >= 1)) { fprintf(stderr, "assert fails %s %d: %s\n" , "/home/daniel/Projects/java/jdk/src/hotspot/share/adlc/formssel.cpp" , 740, "I was just looking at it!"); abort(); }};
741	return pos;
742	}
743	}
744
745	// missed the memory op??
746	if( true ) { // %%% should not be necessary
747	if( is_ideal_store() != Form::none ) {
748	fprintf(stderrstderr, "Warning: cannot find memory opnd in instr.\n");
749	((InstructForm*)this)->dump();
750	// pretend it has multiple defs and uses
751	return MANY_MEMORY_OPERANDS;
752	}
753	if( is_ideal_load() != Form::none ) {
754	fprintf(stderrstderr, "Warning: cannot find memory opnd in instr.\n");
755	((InstructForm*)this)->dump();
756	// pretend it has multiple uses and no defs
757	return MANY_MEMORY_OPERANDS;
758	}
759	}
760
761	return NO_MEMORY_OPERAND;
762	}
763
764	// This instruction captures the machine-independent bottom_type
765	// Expected use is for pointer vs oop determination for LoadP
766	bool InstructForm::captures_bottom_type(FormDict &globals) const {
767	if (_matrule && _matrule->_rChild &&
768	(!strcmp(_matrule->_rChild->_opType,"CastPP") \|\| // new result type
769	!strcmp(_matrule->_rChild->_opType,"CastDD") \|\|
770	!strcmp(_matrule->_rChild->_opType,"CastFF") \|\|
771	!strcmp(_matrule->_rChild->_opType,"CastII") \|\|
772	!strcmp(_matrule->_rChild->_opType,"CastLL") \|\|
773	!strcmp(_matrule->_rChild->_opType,"CastVV") \|\|
774	!strcmp(_matrule->_rChild->_opType,"CastX2P") \|\| // new result type
775	!strcmp(_matrule->_rChild->_opType,"DecodeN") \|\|
776	!strcmp(_matrule->_rChild->_opType,"EncodeP") \|\|
777	!strcmp(_matrule->_rChild->_opType,"DecodeNKlass") \|\|
778	!strcmp(_matrule->_rChild->_opType,"EncodePKlass") \|\|
779	!strcmp(_matrule->_rChild->_opType,"LoadN") \|\|
780	!strcmp(_matrule->_rChild->_opType,"LoadNKlass") \|\|
781	!strcmp(_matrule->_rChild->_opType,"CreateEx") \|\| // type of exception
782	!strcmp(_matrule->_rChild->_opType,"CheckCastPP") \|\|
783	!strcmp(_matrule->_rChild->_opType,"GetAndSetP") \|\|
784	!strcmp(_matrule->_rChild->_opType,"GetAndSetN") \|\|
785	!strcmp(_matrule->_rChild->_opType,"RotateLeft") \|\|
786	!strcmp(_matrule->_rChild->_opType,"RotateRight") \|\|
787	#if INCLUDE_SHENANDOAHGC1
788	!strcmp(_matrule->_rChild->_opType,"ShenandoahCompareAndExchangeP") \|\|
789	!strcmp(_matrule->_rChild->_opType,"ShenandoahCompareAndExchangeN") \|\|
790	#endif
791	!strcmp(_matrule->_rChild->_opType,"StrInflatedCopy") \|\|
792	!strcmp(_matrule->_rChild->_opType,"VectorCmpMasked")\|\|
793	!strcmp(_matrule->_rChild->_opType,"VectorMaskGen")\|\|
794	!strcmp(_matrule->_rChild->_opType,"CompareAndExchangeP") \|\|
795	!strcmp(_matrule->_rChild->_opType,"CompareAndExchangeN"))) return true;
796	else if ( is_ideal_load() == Form::idealP ) return true;
797	else if ( is_ideal_store() != Form::none ) return true;
798
799	if (needs_base_oop_edge(globals)) return true;
800
801	if (is_vector()) return true;
802	if (is_mach_constant()) return true;
803
804	return false;
805	}
806
807
808	// Access instr_cost attribute or return NULL.
809	const char* InstructForm::cost() {
810	for (Attribute* cur = _attribs; cur != NULL__null; cur = (Attribute*)cur->_next) {
811	if( strcmp(cur->_ident,AttributeForm::_ins_cost) == 0 ) {
812	return cur->_val;
813	}
814	}
815	return NULL__null;
816	}
817
818	// Return count of top-level operands.
819	uintunsigned int InstructForm::num_opnds() {
820	int num_opnds = _components.num_operands();
821
822	// Need special handling for matching some ideal nodes
823	// i.e. Matching a return node
824	/*
825	if( _matrule ) {
826	if( strcmp(_matrule->_opType,"Return" )==0 \|\|
827	strcmp(_matrule->_opType,"Halt" )==0 )
828	return 3;
829	}
830	*/
831	return num_opnds;
832	}
833
834	const char* InstructForm::opnd_ident(int idx) {
835	return _components.at(idx)->_name;
836	}
837
838	const char* InstructForm::unique_opnd_ident(uintunsigned int idx) {
839	uintunsigned int i;
840	for (i = 1; i < num_opnds(); ++i) {
841	if (unique_opnds_idx(i) == idx) {
842	break;
843	}
844	}
845	return (_components.at(i) != NULL__null) ? _components.at(i)->_name : "";
846	}
847
848	// Return count of unmatched operands.
849	uintunsigned int InstructForm::num_post_match_opnds() {
850	uintunsigned int num_post_match_opnds = _components.count();
851	uintunsigned int num_match_opnds = _components.match_count();
852	num_post_match_opnds = num_post_match_opnds - num_match_opnds;
853
854	return num_post_match_opnds;
855	}
856
857	// Return the number of leaves below this complex operand
858	uintunsigned int InstructForm::num_consts(FormDict &globals) const {
859	if ( ! _matrule) return 0;
860
861	// This is a recursive invocation on all operands in the matchrule
862	return _matrule->num_consts(globals);
863	}
864
865	// Constants in match rule with specified type
866	uintunsigned int InstructForm::num_consts(FormDict &globals, Form::DataType type) const {
867	if ( ! _matrule) return 0;
868
869	// This is a recursive invocation on all operands in the matchrule
870	return _matrule->num_consts(globals, type);
871	}
872
873
874	// Return the register class associated with 'leaf'.
875	const char *InstructForm::out_reg_class(FormDict &globals) {
876	assert( false, "InstructForm::out_reg_class(FormDict &globals); Not Implemented"){ if (!(false)) { fprintf(stderr, "assert fails %s %d: %s\n", "/home/daniel/Projects/java/jdk/src/hotspot/share/adlc/formssel.cpp" , 876, "InstructForm::out_reg_class(FormDict &globals); Not Implemented" ); abort(); }};
877
878	return NULL__null;
879	}
880
881
882
883	// Lookup the starting position of inputs we are interested in wrt. ideal nodes
884	uintunsigned int InstructForm::oper_input_base(FormDict &globals) {
885	if( !_matrule ) return 1; // Skip control for most nodes
886
887	// Need special handling for matching some ideal nodes
888	// i.e. Matching a return node
889	if( strcmp(_matrule->_opType,"Return" )==0 \|\|
890	strcmp(_matrule->_opType,"Rethrow" )==0 \|\|
891	strcmp(_matrule->_opType,"TailCall" )==0 \|\|
892	strcmp(_matrule->_opType,"TailJump" )==0 \|\|
893	strcmp(_matrule->_opType,"SafePoint" )==0 \|\|
894	strcmp(_matrule->_opType,"Halt" )==0 )
895	return AdlcVMDeps::Parms; // Skip the machine-state edges
896
897	if( _matrule->_rChild &&
898	( strcmp(_matrule->_rChild->_opType,"AryEq" )==0 \|\|
899	strcmp(_matrule->_rChild->_opType,"StrComp" )==0 \|\|
900	strcmp(_matrule->_rChild->_opType,"StrEquals" )==0 \|\|
901	strcmp(_matrule->_rChild->_opType,"StrInflatedCopy" )==0 \|\|
902	strcmp(_matrule->_rChild->_opType,"StrCompressedCopy" )==0 \|\|
903	strcmp(_matrule->_rChild->_opType,"StrIndexOf")==0 \|\|
904	strcmp(_matrule->_rChild->_opType,"StrIndexOfChar")==0 \|\|
905	strcmp(_matrule->_rChild->_opType,"HasNegatives")==0 \|\|
906	strcmp(_matrule->_rChild->_opType,"EncodeISOArray")==0)) {
907	// String.(compareTo/equals/indexOf) and Arrays.equals
908	// and sun.nio.cs.iso8859_1$Encoder.EncodeISOArray
909	// take 1 control and 1 memory edges.
910	// Also String.(compressedCopy/inflatedCopy).
911	return 2;
912	}
913
914	// Check for handling of 'Memory' input/edge in the ideal world.
915	// The AD file writer is shielded from knowledge of these edges.
916	int base = 1; // Skip control
917	base += _matrule->needs_ideal_memory_edge(globals);
918
919	// Also skip the base-oop value for uses of derived oops.
920	// The AD file writer is shielded from knowledge of these edges.
921	base += needs_base_oop_edge(globals);
922
923	return base;
924	}
925
926	// This function determines the order of the MachOper in _opnds[]
927	// by writing the operand names into the _components list.
928	//
929	// Implementation does not modify state of internal structures
930	void InstructForm::build_components() {
931	// Add top-level operands to the components
932	if (_matrule) _matrule->append_components(_localNames, _components);
933
934	// Add parameters that "do not appear in match rule".
935	bool has_temp = false;
936	const char *name;
937	const char *kill_name = NULL__null;
938	for (_parameters.reset(); (name = _parameters.iter()) != NULL__null;) {
939	OpClassForm *opForm = _localNames[name]->is_opclass();
940	assert(opForm != NULL, "sanity"){ if (!(opForm != __null)) { fprintf(stderr, "assert fails %s %d: %s\n" , "/home/daniel/Projects/java/jdk/src/hotspot/share/adlc/formssel.cpp" , 940, "sanity"); abort(); }};
941
942	Effect* e = NULL__null;
943	{
944	const Form* form = _effects[name];
945	e = form ? form->is_effect() : NULL__null;
946	}
947
948	if (e != NULL__null) {
949	has_temp \|= e->is(Component::TEMP);
950
951	// KILLs must be declared after any TEMPs because TEMPs are real
952	// uses so their operand numbering must directly follow the real
953	// inputs from the match rule. Fixing the numbering seems
954	// complex so simply enforce the restriction during parse.
955	if (kill_name != NULL__null &&
956	e->isa(Component::TEMP) && !e->isa(Component::DEF)) {
957	OpClassForm* kill = _localNames[kill_name]->is_opclass();
958	assert(kill != NULL, "sanity"){ if (!(kill != __null)) { fprintf(stderr, "assert fails %s %d: %s\n" , "/home/daniel/Projects/java/jdk/src/hotspot/share/adlc/formssel.cpp" , 958, "sanity"); abort(); }};
959	globalAD->syntax_err(_linenum, "%s: %s %s must be at the end of the argument list\n",
960	_ident, kill->_ident, kill_name);
961	} else if (e->isa(Component::KILL) && !e->isa(Component::USE)) {
962	kill_name = name;
963	}
964	}
965
966	const Component *component = _components.search(name);
967	if ( component == NULL__null ) {
968	if (e) {
969	_components.insert(name, opForm->_ident, e->_use_def, false);
970	component = _components.search(name);
971	if (component->isa(Component::USE) && !component->isa(Component::TEMP) && _matrule) {
972	const Form *form = globalAD->globalNames()[component->_type];
973	assert( form, "component type must be a defined form"){ if (!(form)) { fprintf(stderr, "assert fails %s %d: %s\n", "/home/daniel/Projects/java/jdk/src/hotspot/share/adlc/formssel.cpp" , 973, "component type must be a defined form"); abort(); }};
974	OperandForm *op = form->is_operand();
975	if (op->_interface && op->_interface->is_RegInterface()) {
976	globalAD->syntax_err(_linenum, "%s: illegal USE of non-input: %s %s\n",
977	_ident, opForm->_ident, name);
978	}
979	}
980	} else {
981	// This would be a nice warning but it triggers in a few places in a benign way
982	// if (_matrule != NULL && !expands()) {
983	// globalAD->syntax_err(_linenum, "%s: %s %s not mentioned in effect or match rule\n",
984	// _ident, opForm->_ident, name);
985	// }
986	_components.insert(name, opForm->_ident, Component::INVALID, false);
987	}
988	}
989	else if (e) {
990	// Component was found in the list
991	// Check if there is a new effect that requires an extra component.
992	// This happens when adding 'USE' to a component that is not yet one.
993	if ((!component->isa( Component::USE) && ((e->_use_def & Component::USE) != 0))) {
994	if (component->isa(Component::USE) && _matrule) {
995	const Form *form = globalAD->globalNames()[component->_type];
996	assert( form, "component type must be a defined form"){ if (!(form)) { fprintf(stderr, "assert fails %s %d: %s\n", "/home/daniel/Projects/java/jdk/src/hotspot/share/adlc/formssel.cpp" , 996, "component type must be a defined form"); abort(); }};
997	OperandForm *op = form->is_operand();
998	if (op->_interface && op->_interface->is_RegInterface()) {
999	globalAD->syntax_err(_linenum, "%s: illegal USE of non-input: %s %s\n",
1000	_ident, opForm->_ident, name);
1001	}
1002	}
1003	_components.insert(name, opForm->_ident, e->_use_def, false);
1004	} else {
1005	Component comp = (Component)component;
1006	comp->promote_use_def_info(e->_use_def);
1007	}
1008	// Component positions are zero based.
1009	int pos = _components.operand_position(name);
1010	assert( ! (component->isa(Component::DEF) && (pos >= 1)),{ if (!(! (component->isa(Component::DEF) && (pos >= 1)))) { fprintf(stderr, "assert fails %s %d: %s\n", "/home/daniel/Projects/java/jdk/src/hotspot/share/adlc/formssel.cpp" , 1011, "Component::DEF can only occur in the first position" ); abort(); }}
1011	"Component::DEF can only occur in the first position"){ if (!(! (component->isa(Component::DEF) && (pos >= 1)))) { fprintf(stderr, "assert fails %s %d: %s\n", "/home/daniel/Projects/java/jdk/src/hotspot/share/adlc/formssel.cpp" , 1011, "Component::DEF can only occur in the first position" ); abort(); }};
1012	}
1013	}
1014
1015	// Resolving the interactions between expand rules and TEMPs would
1016	// be complex so simply disallow it.
1017	if (_matrule == NULL__null && has_temp) {
1018	globalAD->syntax_err(_linenum, "%s: TEMPs without match rule isn't supported\n", _ident);
1019	}
1020
1021	return;
1022	}
1023
1024	// Return zero-based position in component list; -1 if not in list.
1025	int InstructForm::operand_position(const char *name, int usedef) {
1026	return unique_opnds_idx(_components.operand_position(name, usedef, this));
1027	}
1028
1029	int InstructForm::operand_position_format(const char *name) {
1030	return unique_opnds_idx(_components.operand_position_format(name, this));
1031	}
1032
1033	// Return zero-based position in component list; -1 if not in list.
1034	int InstructForm::label_position() {
1035	return unique_opnds_idx(_components.label_position());
1036	}
1037
1038	int InstructForm::method_position() {
1039	return unique_opnds_idx(_components.method_position());
1040	}
1041
1042	// Return number of relocation entries needed for this instruction.
1043	uintunsigned int InstructForm::reloc(FormDict &globals) {
1044	uintunsigned int reloc_entries = 0;
1045	// Check for "Call" nodes
1046	if ( is_ideal_call() ) ++reloc_entries;
1047	if ( is_ideal_return() ) ++reloc_entries;
1048	if ( is_ideal_safepoint() ) ++reloc_entries;
1049
1050
1051	// Check if operands MAYBE oop pointers, by checking for ConP elements
1052	// Proceed through the leaves of the match-tree and check for ConPs
1053	if ( _matrule != NULL__null ) {
1054	uintunsigned int position = 0;
1055	const char *result = NULL__null;
1056	const char *name = NULL__null;
1057	const char *opType = NULL__null;
1058	while (_matrule->base_operand(position, globals, result, name, opType)) {
1059	if ( strcmp(opType,"ConP") == 0 ) {
1060	++reloc_entries;
1061	}
1062	++position;
1063	}
1064	}
1065
1066	// Above is only a conservative estimate
1067	// because it did not check contents of operand classes.
1068	// !!!!! !!!!!
1069	// Add 1 to reloc info for each operand class in the component list.
1070	Component *comp;
1071	_components.reset();
1072	while ( (comp = _components.iter()) != NULL__null ) {
1073	const Form *form = globals[comp->_type];
1074	assert( form, "Did not find component's type in global names"){ if (!(form)) { fprintf(stderr, "assert fails %s %d: %s\n", "/home/daniel/Projects/java/jdk/src/hotspot/share/adlc/formssel.cpp" , 1074, "Did not find component's type in global names"); abort (); }};
1075	const OpClassForm *opc = form->is_opclass();
1076	const OperandForm *oper = form->is_operand();
1077	if ( opc && (oper == NULL__null) ) {
1078	++reloc_entries;
1079	} else if ( oper ) {
1080	// floats and doubles loaded out of method's constant pool require reloc info
1081	Form::DataType type = oper->is_base_constant(globals);
1082	if ( (type == Form::idealF) \|\| (type == Form::idealD) ) {
1083	++reloc_entries;
1084	}
1085	}
1086	}
1087
1088	// Float and Double constants may come from the CodeBuffer table
1089	// and require relocatable addresses for access
1090	// !!!!!
1091	// Check for any component being an immediate float or double.
1092	Form::DataType data_type = is_chain_of_constant(globals);
1093	if( data_type==idealD \|\| data_type==idealF ) {
1094	reloc_entries++;
1095	}
1096
1097	return reloc_entries;
1098	}
1099
1100	// Utility function defined in archDesc.cpp
1101	extern bool is_def(int usedef);
1102
1103	// Return the result of reducing an instruction
1104	const char *InstructForm::reduce_result() {
1105	const char* result = "Universe"; // default
1106	_components.reset();
1107	Component *comp = _components.iter();
1108	if (comp != NULL__null && comp->isa(Component::DEF)) {
1109	result = comp->_type;
1110	// Override this if the rule is a store operation:
1111	if (_matrule && _matrule->_rChild &&
1112	is_store_to_memory(_matrule->_rChild->_opType))
1113	result = "Universe";
1114	}
1115	return result;
1116	}
1117
1118	// Return the name of the operand on the right hand side of the binary match
1119	// Return NULL if there is no right hand side
1120	const char *InstructForm::reduce_right(FormDict &globals) const {
1121	if( _matrule == NULL__null ) return NULL__null;
1122	return _matrule->reduce_right(globals);
1123	}
1124
1125	// Similar for left
1126	const char *InstructForm::reduce_left(FormDict &globals) const {
1127	if( _matrule == NULL__null ) return NULL__null;
1128	return _matrule->reduce_left(globals);
1129	}
1130
1131
1132	// Base class for this instruction, MachNode except for calls
1133	const char *InstructForm::mach_base_class(FormDict &globals) const {
1134	if( is_ideal_call() == Form::JAVA_STATIC ) {
1135	return "MachCallStaticJavaNode";
1136	}
1137	else if( is_ideal_call() == Form::JAVA_DYNAMIC ) {
1138	return "MachCallDynamicJavaNode";
1139	}
1140	else if( is_ideal_call() == Form::JAVA_RUNTIME ) {
1141	return "MachCallRuntimeNode";
1142	}
1143	else if( is_ideal_call() == Form::JAVA_LEAF ) {
1144	return "MachCallLeafNode";
1145	}
1146	else if( is_ideal_call() == Form::JAVA_NATIVE ) {
1147	return "MachCallNativeNode";
1148	}
1149	else if (is_ideal_return()) {
1150	return "MachReturnNode";
1151	}
1152	else if (is_ideal_halt()) {
1153	return "MachHaltNode";
1154	}
1155	else if (is_ideal_safepoint()) {
1156	return "MachSafePointNode";
1157	}
1158	else if (is_ideal_if()) {
1159	return "MachIfNode";
1160	}
1161	else if (is_ideal_goto()) {
1162	return "MachGotoNode";
1163	}
1164	else if (is_ideal_fastlock()) {
1165	return "MachFastLockNode";
1166	}
1167	else if (is_ideal_nop()) {
1168	return "MachNopNode";
1169	}
1170	else if( is_ideal_membar()) {
1171	return "MachMemBarNode";
1172	}
1173	else if (is_ideal_jump()) {
1174	return "MachJumpNode";
1175	}
1176	else if (is_mach_constant()) {
1177	return "MachConstantNode";
1178	}
1179	else if (captures_bottom_type(globals)) {
1180	return "MachTypeNode";
1181	} else {
1182	return "MachNode";
1183	}
1184	assert( false, "ShouldNotReachHere()"){ if (!(false)) { fprintf(stderr, "assert fails %s %d: %s\n", "/home/daniel/Projects/java/jdk/src/hotspot/share/adlc/formssel.cpp" , 1184, "ShouldNotReachHere()"); abort(); }};
1185	return NULL__null;
1186	}
1187
1188	// Compare the instruction predicates for textual equality
1189	bool equivalent_predicates( const InstructForm instr1, const InstructForm instr2 ) {
1190	const Predicate *pred1 = instr1->_predicate;
1191	const Predicate *pred2 = instr2->_predicate;
1192	if( pred1 == NULL__null && pred2 == NULL__null ) {
1193	// no predicates means they are identical
1194	return true;
1195	}
1196	if( pred1 != NULL__null && pred2 != NULL__null ) {
1197	// compare the predicates
1198	if (ADLParser::equivalent_expressions(pred1->_pred, pred2->_pred)) {
1199	return true;
1200	}
1201	}
1202
1203	return false;
1204	}
1205
1206	// Check if this instruction can cisc-spill to 'alternate'
1207	bool InstructForm::cisc_spills_to(ArchDesc &AD, InstructForm *instr) {
1208	assert( _matrule != NULL && instr->_matrule != NULL, "must have match rules"){ if (!(_matrule != __null && instr->_matrule != __null )) { fprintf(stderr, "assert fails %s %d: %s\n", "/home/daniel/Projects/java/jdk/src/hotspot/share/adlc/formssel.cpp" , 1208, "must have match rules"); abort(); }};
1209	// Do not replace if a cisc-version has been found.
1210	if( cisc_spill_operand() != Not_cisc_spillable ) return false;
1211
1212	int cisc_spill_operand = Maybe_cisc_spillable;
1213	char *result = NULL__null;
1214	char *result2 = NULL__null;
1215	const char *op_name = NULL__null;
1216	const char *reg_type = NULL__null;
1217	FormDict &globals = AD.globalNames();
1218	cisc_spill_operand = _matrule->matchrule_cisc_spill_match(globals, AD.get_registers(), instr->_matrule, op_name, reg_type);
1219	if( (cisc_spill_operand != Not_cisc_spillable) && (op_name != NULL__null) && equivalent_predicates(this, instr) ) {
1220	cisc_spill_operand = operand_position(op_name, Component::USE);
1221	int def_oper = operand_position(op_name, Component::DEF);
1222	if( def_oper == NameList::Not_in_list && instr->num_opnds() == num_opnds()) {
1223	// Do not support cisc-spilling for destination operands and
1224	// make sure they have the same number of operands.
1225	_cisc_spill_alternate = instr;
1226	instr->set_cisc_alternate(true);
1227	if( AD._cisc_spill_debug ) {
1228	fprintf(stderrstderr, "Instruction %s cisc-spills-to %s\n", _ident, instr->_ident);
1229	fprintf(stderrstderr, " using operand %s %s at index %d\n", reg_type, op_name, cisc_spill_operand);
1230	}
1231	// Record that a stack-version of the reg_mask is needed
1232	// !!!!!
1233	OperandForm oper = (OperandForm)(globals[reg_type]->is_operand());
1234	assert( oper != NULL, "cisc-spilling non operand"){ if (!(oper != __null)) { fprintf(stderr, "assert fails %s %d: %s\n" , "/home/daniel/Projects/java/jdk/src/hotspot/share/adlc/formssel.cpp" , 1234, "cisc-spilling non operand"); abort(); }};
1235	const char *reg_class_name = oper->constrained_reg_class();
1236	AD.set_stack_or_reg(reg_class_name);
1237	const char reg_mask_name = AD.reg_mask(oper);
1238	set_cisc_reg_mask_name(reg_mask_name);
1239	const char stack_or_reg_mask_name = AD.stack_or_reg_mask(oper);
	Value stored to 'stack_or_reg_mask_name' during its initialization is never read
1240	} else {
1241	cisc_spill_operand = Not_cisc_spillable;
1242	}
1243	} else {
1244	cisc_spill_operand = Not_cisc_spillable;
1245	}
1246
1247	set_cisc_spill_operand(cisc_spill_operand);
1248	return (cisc_spill_operand != Not_cisc_spillable);
1249	}
1250
1251	// Check to see if this instruction can be replaced with the short branch
1252	// instruction `short-branch'
1253	bool InstructForm::check_branch_variant(ArchDesc &AD, InstructForm *short_branch) {
1254	if (_matrule != NULL__null &&
1255	this != short_branch && // Don't match myself
1256	!is_short_branch() && // Don't match another short branch variant
1257	reduce_result() != NULL__null &&
1258	strstr(_ident, "restoreMask") == NULL__null && // Don't match side effects
1259	strcmp(reduce_result(), short_branch->reduce_result()) == 0 &&
1260	_matrule->equivalent(AD.globalNames(), short_branch->_matrule)) {
1261	// The instructions are equivalent.
1262
1263	// Now verify that both instructions have the same parameters and
1264	// the same effects. Both branch forms should have the same inputs
1265	// and resulting projections to correctly replace a long branch node
1266	// with corresponding short branch node during code generation.
1267
1268	bool different = false;
1269	if (short_branch->_components.count() != _components.count()) {
1270	different = true;
1271	} else if (_components.count() > 0) {
1272	short_branch->_components.reset();
1273	_components.reset();
1274	Component *comp;
1275	while ((comp = _components.iter()) != NULL__null) {
1276	Component *short_comp = short_branch->_components.iter();
1277	if (short_comp == NULL__null \|\|
1278	short_comp->_type != comp->_type \|\|
1279	short_comp->_usedef != comp->_usedef) {
1280	different = true;
1281	break;
1282	}
1283	}
1284	if (short_branch->_components.iter() != NULL__null)
1285	different = true;
1286	}
1287	if (different) {
1288	globalAD->syntax_err(short_branch->_linenum, "Instruction %s and its short form %s have different parameters\n", _ident, short_branch->_ident);
1289	}
1290	if (AD._adl_debug > 1 \|\| AD._short_branch_debug) {
1291	fprintf(stderrstderr, "Instruction %s has short form %s\n", _ident, short_branch->_ident);
1292	}
1293	_short_branch_form = short_branch;
1294	return true;
1295	}
1296	return false;
1297	}
1298
1299
1300	// --------------------------- FILE *output_routines
1301	//
1302	// Generate the format call for the replacement variable
1303	void InstructForm::rep_var_format(FILE fp, const char rep_var) {
1304	// Handle special constant table variables.
1305	if (strcmp(rep_var, "constanttablebase") == 0) {
1306	fprintf(fp, "char reg[128]; ra->dump_register(in(mach_constant_base_node_input()), reg);\n");
1307	fprintf(fp, " st->print(\"%%s\", reg);\n");
1308	return;
1309	}
1310	if (strcmp(rep_var, "constantoffset") == 0) {
1311	fprintf(fp, "st->print(\"#%%d\", constant_offset_unchecked());\n");
1312	return;
1313	}
1314	if (strcmp(rep_var, "constantaddress") == 0) {
1315	fprintf(fp, "st->print(\"constant table base + #%%d\", constant_offset_unchecked());\n");
1316	return;
1317	}
1318
1319	// Find replacement variable's type
1320	const Form *form = _localNames[rep_var];
1321	if (form == NULL__null) {
1322	globalAD->syntax_err(_linenum, "Unknown replacement variable %s in format statement of %s.",
1323	rep_var, _ident);
1324	return;
1325	}
1326	OpClassForm *opc = form->is_opclass();
1327	assert( opc, "replacement variable was not found in local names"){ if (!(opc)) { fprintf(stderr, "assert fails %s %d: %s\n", "/home/daniel/Projects/java/jdk/src/hotspot/share/adlc/formssel.cpp" , 1327, "replacement variable was not found in local names"); abort(); }};
1328	// Lookup the index position of the replacement variable
1329	int idx = operand_position_format(rep_var);
1330	if ( idx == -1 ) {
1331	globalAD->syntax_err(_linenum, "Could not find replacement variable %s in format statement of %s.\n",
1332	rep_var, _ident);
1333	assert(strcmp(opc->_ident, "label") == 0, "Unimplemented"){ if (!(strcmp(opc->_ident, "label") == 0)) { fprintf(stderr , "assert fails %s %d: %s\n", "/home/daniel/Projects/java/jdk/src/hotspot/share/adlc/formssel.cpp" , 1333, "Unimplemented"); abort(); }};
1334	return;
1335	}
1336
1337	if (is_noninput_operand(idx)) {
1338	// This component isn't in the input array. Print out the static
1339	// name of the register.
1340	OperandForm* oper = form->is_operand();
1341	if (oper != NULL__null && oper->is_bound_register()) {
1342	const RegDef* first = oper->get_RegClass()->find_first_elem();
1343	fprintf(fp, " st->print_raw(\"%s\");\n", first->_regname);
1344	} else {
1345	globalAD->syntax_err(_linenum, "In %s can't find format for %s %s", _ident, opc->_ident, rep_var);
1346	}
1347	} else {
1348	// Output the format call for this operand
1349	fprintf(fp,"opnd_array(%d)->",idx);
1350	if (idx == 0)
1351	fprintf(fp,"int_format(ra, this, st); // %s\n", rep_var);
1352	else
1353	fprintf(fp,"ext_format(ra, this,idx%d, st); // %s\n", idx, rep_var );
1354	}
1355	}
1356
1357	// Seach through operands to determine parameters unique positions.
1358	void InstructForm::set_unique_opnds() {
1359	uintunsigned int* uniq_idx = NULL__null;
1360	uintunsigned int nopnds = num_opnds();
1361	uintunsigned int num_uniq = nopnds;
1362	uintunsigned int i;
1363	_uniq_idx_length = 0;
1364	if (nopnds > 0) {
1365	// Allocate index array. Worst case we're mapping from each
1366	// component back to an index and any DEF always goes at 0 so the
1367	// length of the array has to be the number of components + 1.
1368	_uniq_idx_length = _components.count() + 1;
1369	uniq_idx = (uintunsigned int) AllocateHeap(sizeof(uintunsigned int) _uniq_idx_length);
1370	for (i = 0; i < _uniq_idx_length; i++) {
1371	uniq_idx[i] = i;
1372	}
1373	}
1374	// Do it only if there is a match rule and no expand rule. With an
1375	// expand rule it is done by creating new mach node in Expand()
1376	// method.
1377	if (nopnds > 0 && _matrule != NULL__null && _exprule == NULL__null) {
1378	const char *name;
1379	uintunsigned int count;
1380	bool has_dupl_use = false;
1381
1382	_parameters.reset();
1383	while ((name = _parameters.iter()) != NULL__null) {
1384	count = 0;
1385	uintunsigned int position = 0;
1386	uintunsigned int uniq_position = 0;
1387	_components.reset();
1388	Component *comp = NULL__null;
1389	if (sets_result()) {
1390	comp = _components.iter();
1391	position++;
1392	}
1393	// The next code is copied from the method operand_position().
1394	for (; (comp = _components.iter()) != NULL__null; ++position) {
1395	// When the first component is not a DEF,
1396	// leave space for the result operand!
1397	if (position==0 && (!comp->isa(Component::DEF))) {
1398	++position;
1399	}
1400	if (strcmp(name, comp->_name) == 0) {
1401	if (++count > 1) {
1402	assert(position < _uniq_idx_length, "out of bounds"){ if (!(position < _uniq_idx_length)) { fprintf(stderr, "assert fails %s %d: %s\n" , "/home/daniel/Projects/java/jdk/src/hotspot/share/adlc/formssel.cpp" , 1402, "out of bounds"); abort(); }};
1403	uniq_idx[position] = uniq_position;
1404	has_dupl_use = true;
1405	} else {
1406	uniq_position = position;
1407	}
1408	}
1409	if (comp->isa(Component::DEF) && comp->isa(Component::USE)) {
1410	++position;
1411	if (position != 1)
1412	--position; // only use two slots for the 1st USE_DEF
1413	}
1414	}
1415	}
1416	if (has_dupl_use) {
1417	for (i = 1; i < nopnds; i++) {
1418	if (i != uniq_idx[i]) {
1419	break;
1420	}
1421	}
1422	uintunsigned int j = i;
1423	for (; i < nopnds; i++) {
1424	if (i == uniq_idx[i]) {
1425	uniq_idx[i] = j++;
1426	}
1427	}
1428	num_uniq = j;
1429	}
1430	}
1431	_uniq_idx = uniq_idx;
1432	_num_uniq = num_uniq;
1433	}
1434
1435	// Generate index values needed for determining the operand position
1436	void InstructForm::index_temps(FILE fp, FormDict &globals, const char prefix, const char *receiver) {
1437	uintunsigned int idx = 0; // position of operand in match rule
1438	int cur_num_opnds = num_opnds();
1439
1440	// Compute the index into vector of operand pointers:
1441	// idx0=0 is used to indicate that info comes from this same node, not from input edge.
1442	// idx1 starts at oper_input_base()
1443	if ( cur_num_opnds >= 1 ) {
1444	fprintf(fp," // Start at oper_input_base() and count operands\n");
1445	fprintf(fp," unsigned %sidx0 = %d;\n", prefix, oper_input_base(globals));
1446	fprintf(fp," unsigned %sidx1 = %d;", prefix, oper_input_base(globals));
1447	fprintf(fp," \t// %s\n", unique_opnd_ident(1));
1448
1449	// Generate starting points for other unique operands if they exist
1450	for ( idx = 2; idx < num_unique_opnds(); ++idx ) {
1451	if( *receiver == 0 ) {
1452	fprintf(fp," unsigned %sidx%d = %sidx%d + opnd_array(%d)->num_edges();",
1453	prefix, idx, prefix, idx-1, idx-1 );
1454	} else {
1455	fprintf(fp," unsigned %sidx%d = %sidx%d + %s_opnds[%d]->num_edges();",
1456	prefix, idx, prefix, idx-1, receiver, idx-1 );
1457	}
1458	fprintf(fp," \t// %s\n", unique_opnd_ident(idx));
1459	}
1460	}
1461	if( *receiver != 0 ) {
1462	// This value is used by generate_peepreplace when copying a node.
1463	// Don't emit it in other cases since it can hide bugs with the
1464	// use invalid idx's.
1465	fprintf(fp," unsigned %sidx%d = %sreq(); \n", prefix, idx, receiver);
1466	}
1467
1468	}
1469
1470	// ---------------------------
1471	bool InstructForm::verify() {
1472	// !!!!! !!!!!
1473	// Check that a "label" operand occurs last in the operand list, if present
1474	return true;
1475	}
1476
1477	void InstructForm::dump() {
1478	output(stderrstderr);
1479	}
1480
1481	void InstructForm::output(FILE *fp) {
1482	fprintf(fp,"\nInstruction: %s\n", (_ident?_ident:""));
1483	if (_matrule) _matrule->output(fp);
1484	if (_insencode) _insencode->output(fp);
1485	if (_constant) _constant->output(fp);
1486	if (_opcode) _opcode->output(fp);
1487	if (_attribs) _attribs->output(fp);
1488	if (_predicate) _predicate->output(fp);
1489	if (_effects.Size()) {
1490	fprintf(fp,"Effects\n");
1491	_effects.dump();
1492	}
1493	if (_exprule) _exprule->output(fp);
1494	if (_rewrule) _rewrule->output(fp);
1495	if (_format) _format->output(fp);
1496	if (_peephole) _peephole->output(fp);
1497	}
1498
1499	void MachNodeForm::dump() {
1500	output(stderrstderr);
1501	}
1502
1503	void MachNodeForm::output(FILE *fp) {
1504	fprintf(fp,"\nMachNode: %s\n", (_ident?_ident:""));
1505	}
1506
1507	//------------------------------build_predicate--------------------------------
1508	// Build instruction predicates. If the user uses the same operand name
1509	// twice, we need to check that the operands are pointer-eequivalent in
1510	// the DFA during the labeling process.
1511	Predicate *InstructForm::build_predicate() {
1512	const int buflen = 1024;
1513	char buf[buflen], *s=buf;
1514	Dict names(cmpstr,hashstr,Form::arena); // Map Names to counts
1515
1516	MatchNode *mnode =
1517	strcmp(_matrule->_opType, "Set") ? _matrule : _matrule->_rChild;
1518	if (mnode != NULL__null) mnode->count_instr_names(names);
1519
1520	uintunsigned int first = 1;
1521	// Start with the predicate supplied in the .ad file.
1522	if (_predicate) {
1523	if (first) first = 0;
1524	strcpy(s, "("); s += strlen(s);
1525	strncpy(s, _predicate->_pred, buflen - strlen(s) - 1);
1526	s += strlen(s);
1527	strcpy(s, ")"); s += strlen(s);
1528	}
1529	for( DictI i(&names); i.test(); ++i ) {
1530	uintptr_t cnt = (uintptr_t)i._value;
1531	if( cnt > 1 ) { // Need a predicate at all?
1532	int path_bitmask = 0;
1533	assert( cnt == 2, "Unimplemented" ){ if (!(cnt == 2)) { fprintf(stderr, "assert fails %s %d: %s\n" , "/home/daniel/Projects/java/jdk/src/hotspot/share/adlc/formssel.cpp" , 1533, "Unimplemented"); abort(); }};
1534	// Handle many pairs
1535	if( first ) first=0;
1536	else { // All tests must pass, so use '&&'
1537	strcpy(s," && ");
1538	s += strlen(s);
1539	}
1540	// Add predicate to working buffer
1541	sprintf(s,"/%s/(",(char*)i._key);
1542	s += strlen(s);
1543	mnode->build_instr_pred(s,(char*)i._key, 0, path_bitmask, 0);
1544	s += strlen(s);
1545	strcpy(s," == "); s += strlen(s);
1546	mnode->build_instr_pred(s,(char*)i._key, 1, path_bitmask, 0);
1547	s += strlen(s);
1548	strcpy(s,")"); s += strlen(s);
1549	}
1550	}
1551	if( s == buf ) s = NULL__null;
1552	else {
1553	assert( strlen(buf) < sizeof(buf), "String buffer overflow" ){ if (!(strlen(buf) < sizeof(buf))) { fprintf(stderr, "assert fails %s %d: %s\n" , "/home/daniel/Projects/java/jdk/src/hotspot/share/adlc/formssel.cpp" , 1553, "String buffer overflow"); abort(); }};
1554	s = strdup(buf);
1555	}
1556	return new Predicate(s);
1557	}
1558
1559	//------------------------------EncodeForm-------------------------------------
1560	// Constructor
1561	EncodeForm::EncodeForm()
1562	: _encClass(cmpstr,hashstr, Form::arena) {
1563	}
1564	EncodeForm::~EncodeForm() {
1565	}
1566
1567	// record a new register class
1568	EncClass EncodeForm::add_EncClass(const char className) {
1569	EncClass *encClass = new EncClass(className);
1570	_eclasses.addName(className);
1571	_encClass.Insert(className,encClass);
1572	return encClass;
1573	}
1574
1575	// Lookup the function body for an encoding class
1576	EncClass EncodeForm::encClass(const char className) {
1577	assert( className != NULL, "Must provide a defined encoding name"){ if (!(className != __null)) { fprintf(stderr, "assert fails %s %d: %s\n" , "/home/daniel/Projects/java/jdk/src/hotspot/share/adlc/formssel.cpp" , 1577, "Must provide a defined encoding name"); abort(); }};
1578
1579	EncClass encClass = (EncClass)_encClass[className];
1580	return encClass;
1581	}
1582
1583	// Lookup the function body for an encoding class
1584	const char EncodeForm::encClassBody(const char className) {
1585	if( className == NULL__null ) return NULL__null;
1586
1587	EncClass encClass = (EncClass)_encClass[className];
1588	assert( encClass != NULL, "Encode Class is missing."){ if (!(encClass != __null)) { fprintf(stderr, "assert fails %s %d: %s\n" , "/home/daniel/Projects/java/jdk/src/hotspot/share/adlc/formssel.cpp" , 1588, "Encode Class is missing."); abort(); }};
1589	encClass->_code.reset();
1590	const char code = (const char)encClass->_code.iter();
1591	assert( code != NULL, "Found an empty encode class body."){ if (!(code != __null)) { fprintf(stderr, "assert fails %s %d: %s\n" , "/home/daniel/Projects/java/jdk/src/hotspot/share/adlc/formssel.cpp" , 1591, "Found an empty encode class body."); abort(); }};
1592
1593	return code;
1594	}
1595
1596	// Lookup the function body for an encoding class
1597	const char EncodeForm::encClassPrototype(const char className) {
1598	assert( className != NULL, "Encode class name must be non NULL."){ if (!(className != __null)) { fprintf(stderr, "assert fails %s %d: %s\n" , "/home/daniel/Projects/java/jdk/src/hotspot/share/adlc/formssel.cpp" , 1598, "Encode class name must be non NULL."); abort(); }};
1599
1600	return className;
1601	}
1602
1603	void EncodeForm::dump() { // Debug printer
1604	output(stderrstderr);
1605	}
1606
1607	void EncodeForm::output(FILE *fp) { // Write info to output files
1608	const char *name;
1609	fprintf(fp,"\n");
1610	fprintf(fp,"-------------------- Dump EncodeForm --------------------\n");
1611	for (_eclasses.reset(); (name = _eclasses.iter()) != NULL__null;) {
1612	((EncClass*)_encClass[name])->output(fp);
1613	}
1614	fprintf(fp,"-------------------- end EncodeForm --------------------\n");
1615	}
1616	//------------------------------EncClass---------------------------------------
1617	EncClass::EncClass(const char *name)
1618	: _localNames(cmpstr,hashstr, Form::arena), _name(name) {
1619	}
1620	EncClass::~EncClass() {
1621	}
1622
1623	// Add a parameter <type,name> pair
1624	void EncClass::add_parameter(const char parameter_type, const char parameter_name) {
1625	_parameter_type.addName( parameter_type );
1626	_parameter_name.addName( parameter_name );
1627	}
1628
1629	// Verify operand types in parameter list
1630	bool EncClass::check_parameter_types(FormDict &globals) {
1631	// !!!!!
1632	return false;
1633	}
1634
1635	// Add the decomposed "code" sections of an encoding's code-block
1636	void EncClass::add_code(const char *code) {
1637	_code.addName(code);
1638	}
1639
1640	// Add the decomposed "replacement variables" of an encoding's code-block
1641	void EncClass::add_rep_var(char *replacement_var) {
1642	_code.addName(NameList::_signal);
1643	_rep_vars.addName(replacement_var);
1644	}
1645
1646	// Lookup the function body for an encoding class
1647	int EncClass::rep_var_index(const char *rep_var) {
1648	uintunsigned int position = 0;
1649	const char *name = NULL__null;
1650
1651	_parameter_name.reset();
1652	while ( (name = _parameter_name.iter()) != NULL__null ) {
1653	if ( strcmp(rep_var,name) == 0 ) return position;
1654	++position;
1655	}
1656
1657	return -1;
1658	}
1659
1660	// Check after parsing
1661	bool EncClass::verify() {
1662	// 1!!!!
1663	// Check that each replacement variable, '$name' in architecture description
1664	// is actually a local variable for this encode class, or a reserved name
1665	// "primary, secondary, tertiary"
1666	return true;
1667	}
1668
1669	void EncClass::dump() {
1670	output(stderrstderr);
1671	}
1672
1673	// Write info to output files
1674	void EncClass::output(FILE *fp) {
1675	fprintf(fp,"EncClass: %s", (_name ? _name : ""));
1676
1677	// Output the parameter list
1678	_parameter_type.reset();
1679	_parameter_name.reset();
1680	const char *type = _parameter_type.iter();
1681	const char *name = _parameter_name.iter();
1682	fprintf(fp, " ( ");
1683	for ( ; (type != NULL__null) && (name != NULL__null);
1684	(type = _parameter_type.iter()), (name = _parameter_name.iter()) ) {
1685	fprintf(fp, " %s %s,", type, name);
1686	}
1687	fprintf(fp, " ) ");
1688
1689	// Output the code block
1690	_code.reset();
1691	_rep_vars.reset();
1692	const char *code;
1693	while ( (code = _code.iter()) != NULL__null ) {
1694	if ( _code.is_signal(code) ) {
1695	// A replacement variable
1696	const char *rep_var = _rep_vars.iter();
1697	fprintf(fp,"($%s)", rep_var);
1698	} else {
1699	// A section of code
1700	fprintf(fp,"%s", code);
1701	}
1702	}
1703
1704	}
1705
1706	//------------------------------Opcode-----------------------------------------
1707	Opcode::Opcode(char primary, char secondary, char *tertiary)
1708	: _primary(primary), _secondary(secondary), _tertiary(tertiary) {
1709	}
1710
1711	Opcode::~Opcode() {
1712	}
1713
1714	Opcode::opcode_type Opcode::as_opcode_type(const char *param) {
1715	if( strcmp(param,"primary") == 0 ) {
1716	return Opcode::PRIMARY;
1717	}
1718	else if( strcmp(param,"secondary") == 0 ) {
1719	return Opcode::SECONDARY;
1720	}
1721	else if( strcmp(param,"tertiary") == 0 ) {
1722	return Opcode::TERTIARY;
1723	}
1724	return Opcode::NOT_AN_OPCODE;
1725	}
1726
1727	bool Opcode::print_opcode(FILE *fp, Opcode::opcode_type desired_opcode) {
1728	// Default values previously provided by MachNode::primary()...
1729	const char *description = NULL__null;
1730	const char *value = NULL__null;
1731	// Check if user provided any opcode definitions
1732	// Update 'value' if user provided a definition in the instruction
1733	switch (desired_opcode) {
1734	case PRIMARY:
1735	description = "primary()";
1736	if( _primary != NULL__null) { value = _primary; }
1737	break;
1738	case SECONDARY:
1739	description = "secondary()";
1740	if( _secondary != NULL__null ) { value = _secondary; }
1741	break;
1742	case TERTIARY:
1743	description = "tertiary()";
1744	if( _tertiary != NULL__null ) { value = _tertiary; }
1745	break;
1746	default:
1747	assert( false, "ShouldNotReachHere();"){ if (!(false)) { fprintf(stderr, "assert fails %s %d: %s\n", "/home/daniel/Projects/java/jdk/src/hotspot/share/adlc/formssel.cpp" , 1747, "ShouldNotReachHere();"); abort(); }};
1748	break;
1749	}
1750
1751	if (value != NULL__null) {
1752	fprintf(fp, "(%s /%s/)", value, description);
1753	}
1754	return value != NULL__null;
1755	}
1756
1757	void Opcode::dump() {
1758	output(stderrstderr);
1759	}
1760
1761	// Write info to output files
1762	void Opcode::output(FILE *fp) {
1763	if (_primary != NULL__null) fprintf(fp,"Primary opcode: %s\n", _primary);
1764	if (_secondary != NULL__null) fprintf(fp,"Secondary opcode: %s\n", _secondary);
1765	if (_tertiary != NULL__null) fprintf(fp,"Tertiary opcode: %s\n", _tertiary);
1766	}
1767
1768	//------------------------------InsEncode--------------------------------------
1769	InsEncode::InsEncode() {
1770	}
1771	InsEncode::~InsEncode() {
1772	}
1773
1774	// Add "encode class name" and its parameters
1775	NameAndList InsEncode::add_encode(char encoding) {
1776	assert( encoding != NULL, "Must provide name for encoding"){ if (!(encoding != __null)) { fprintf(stderr, "assert fails %s %d: %s\n" , "/home/daniel/Projects/java/jdk/src/hotspot/share/adlc/formssel.cpp" , 1776, "Must provide name for encoding"); abort(); }};
1777
1778	// add_parameter(NameList::_signal);
1779	NameAndList *encode = new NameAndList(encoding);
1780	_encoding.addName((char*)encode);
1781
1782	return encode;
1783	}
1784
1785	// Access the list of encodings
1786	void InsEncode::reset() {
1787	_encoding.reset();
1788	// _parameter.reset();
1789	}
1790	const char* InsEncode::encode_class_iter() {
1791	NameAndList encode_class = (NameAndList)_encoding.iter();
1792	return ( encode_class != NULL__null ? encode_class->name() : NULL__null );
1793	}
1794	// Obtain parameter name from zero based index
1795	const char *InsEncode::rep_var_name(InstructForm &inst, uintunsigned int param_no) {
1796	NameAndList params = (NameAndList)_encoding.current();
1797	assert( params != NULL, "Internal Error"){ if (!(params != __null)) { fprintf(stderr, "assert fails %s %d: %s\n" , "/home/daniel/Projects/java/jdk/src/hotspot/share/adlc/formssel.cpp" , 1797, "Internal Error"); abort(); }};
1798	const char param = (params)[param_no];
1799
1800	// Remove '$' if parser placed it there.
1801	return ( param != NULL__null && *param == '$') ? (param+1) : param;
1802	}
1803
1804	void InsEncode::dump() {
1805	output(stderrstderr);
1806	}
1807
1808	// Write info to output files
1809	void InsEncode::output(FILE *fp) {
1810	NameAndList *encoding = NULL__null;
1811	const char *parameter = NULL__null;
1812
1813	fprintf(fp,"InsEncode: ");
1814	_encoding.reset();
1815
1816	while ( (encoding = (NameAndList*)_encoding.iter()) != 0 ) {
1817	// Output the encoding being used
1818	fprintf(fp,"%s(", encoding->name() );
1819
1820	// Output its parameter list, if any
1821	bool first_param = true;
1822	encoding->reset();
1823	while ( (parameter = encoding->iter()) != 0 ) {
1824	// Output the ',' between parameters
1825	if ( ! first_param ) fprintf(fp,", ");
1826	first_param = false;
1827	// Output the parameter
1828	fprintf(fp,"%s", parameter);
1829	} // done with parameters
1830	fprintf(fp,") ");
1831	} // done with encodings
1832
1833	fprintf(fp,"\n");
1834	}
1835
1836	//------------------------------Effect-----------------------------------------
1837	static int effect_lookup(const char *name) {
1838	if (!strcmp(name, "USE")) return Component::USE;
1839	if (!strcmp(name, "DEF")) return Component::DEF;
1840	if (!strcmp(name, "USE_DEF")) return Component::USE_DEF;
1841	if (!strcmp(name, "KILL")) return Component::KILL;
1842	if (!strcmp(name, "USE_KILL")) return Component::USE_KILL;
1843	if (!strcmp(name, "TEMP")) return Component::TEMP;
1844	if (!strcmp(name, "TEMP_DEF")) return Component::TEMP_DEF;
1845	if (!strcmp(name, "INVALID")) return Component::INVALID;
1846	if (!strcmp(name, "CALL")) return Component::CALL;
1847	assert(false,"Invalid effect name specified\n"){ if (!(false)) { fprintf(stderr, "assert fails %s %d: %s\n", "/home/daniel/Projects/java/jdk/src/hotspot/share/adlc/formssel.cpp" , 1847, "Invalid effect name specified\n"); abort(); }};
1848	return Component::INVALID;
1849	}
1850
1851	const char *Component::getUsedefName() {
1852	switch (_usedef) {
1853	case Component::INVALID: return "INVALID"; break;
1854	case Component::USE: return "USE"; break;
1855	case Component::USE_DEF: return "USE_DEF"; break;
1856	case Component::USE_KILL: return "USE_KILL"; break;
1857	case Component::KILL: return "KILL"; break;
1858	case Component::TEMP: return "TEMP"; break;
1859	case Component::TEMP_DEF: return "TEMP_DEF"; break;
1860	case Component::DEF: return "DEF"; break;
1861	case Component::CALL: return "CALL"; break;
1862	default: assert(false, "unknown effect"){ if (!(false)) { fprintf(stderr, "assert fails %s %d: %s\n", "/home/daniel/Projects/java/jdk/src/hotspot/share/adlc/formssel.cpp" , 1862, "unknown effect"); abort(); }};
1863	}
1864	return "Undefined Use/Def info";
1865	}
1866
1867	Effect::Effect(const char *name) : _name(name), _use_def(effect_lookup(name)) {
1868	_ftype = Form::EFF;
1869	}
1870
1871	Effect::~Effect() {
1872	}
1873
1874	// Dynamic type check
1875	Effect *Effect::is_effect() const {
1876	return (Effect*)this;
1877	}
1878
1879
1880	// True if this component is equal to the parameter.
1881	bool Effect::is(int use_def_kill_enum) const {
1882	return (_use_def == use_def_kill_enum ? true : false);
1883	}
1884	// True if this component is used/def'd/kill'd as the parameter suggests.
1885	bool Effect::isa(int use_def_kill_enum) const {
1886	return (_use_def & use_def_kill_enum) == use_def_kill_enum;
1887	}
1888
1889	void Effect::dump() {
1890	output(stderrstderr);
1891	}
1892
1893	void Effect::output(FILE *fp) { // Write info to output files
1894	fprintf(fp,"Effect: %s\n", (_name?_name:""));
1895	}
1896
1897	//------------------------------ExpandRule-------------------------------------
1898	ExpandRule::ExpandRule() : _expand_instrs(),
1899	_newopconst(cmpstr, hashstr, Form::arena) {
1900	_ftype = Form::EXP;
1901	}
1902
1903	ExpandRule::~ExpandRule() { // Destructor
1904	}
1905
1906	void ExpandRule::add_instruction(NameAndList *instruction_name_and_operand_list) {
1907	_expand_instrs.addName((char*)instruction_name_and_operand_list);
1908	}
1909
1910	void ExpandRule::reset_instructions() {
1911	_expand_instrs.reset();
1912	}
1913
1914	NameAndList* ExpandRule::iter_instructions() {
1915	return (NameAndList*)_expand_instrs.iter();
1916	}
1917
1918
1919	void ExpandRule::dump() {
1920	output(stderrstderr);
1921	}
1922
1923	void ExpandRule::output(FILE *fp) { // Write info to output files
1924	NameAndList *expand_instr = NULL__null;
1925	const char *opid = NULL__null;
1926
1927	fprintf(fp,"\nExpand Rule:\n");
1928
1929	// Iterate over the instructions 'node' expands into
1930	for(reset_instructions(); (expand_instr = iter_instructions()) != NULL__null; ) {
1931	fprintf(fp,"%s(", expand_instr->name());
1932
1933	// iterate over the operand list
1934	for( expand_instr->reset(); (opid = expand_instr->iter()) != NULL__null; ) {
1935	fprintf(fp,"%s ", opid);
1936	}
1937	fprintf(fp,");\n");
1938	}
1939	}
1940
1941	//------------------------------RewriteRule------------------------------------
1942	RewriteRule::RewriteRule(char* params, char* block)
1943	: _tempParams(params), _tempBlock(block) { }; // Constructor
1944	RewriteRule::~RewriteRule() { // Destructor
1945	}
1946
1947	void RewriteRule::dump() {
1948	output(stderrstderr);
1949	}
1950
1951	void RewriteRule::output(FILE *fp) { // Write info to output files
1952	fprintf(fp,"\nRewrite Rule:\n%s\n%s\n",
1953	(_tempParams?_tempParams:""),
1954	(_tempBlock?_tempBlock:""));
1955	}
1956
1957
1958	//==============================MachNodes======================================
1959	//------------------------------MachNodeForm-----------------------------------
1960	MachNodeForm::MachNodeForm(char *id)
1961	: _ident(id) {
1962	}
1963
1964	MachNodeForm::~MachNodeForm() {
1965	}
1966
1967	MachNodeForm *MachNodeForm::is_machnode() const {
1968	return (MachNodeForm*)this;
1969	}
1970
1971	//==============================Operand Classes================================
1972	//------------------------------OpClassForm------------------------------------
1973	OpClassForm::OpClassForm(const char* id) : _ident(id) {
1974	_ftype = Form::OPCLASS;
1975	}
1976
1977	OpClassForm::~OpClassForm() {
1978	}
1979
1980	bool OpClassForm::ideal_only() const { return 0; }
1981
1982	OpClassForm *OpClassForm::is_opclass() const {
1983	return (OpClassForm*)this;
1984	}
1985
1986	Form::InterfaceType OpClassForm::interface_type(FormDict &globals) const {
1987	if( _oplst.count() == 0 ) return Form::no_interface;
1988
1989	// Check that my operands have the same interface type
1990	Form::InterfaceType interface;
1991	bool first = true;
1992	NameList &op_list = (NameList &)_oplst;
1993	op_list.reset();
1994	const char *op_name;
1995	while( (op_name = op_list.iter()) != NULL__null ) {
1996	const Form *form = globals[op_name];
1997	OperandForm *operand = form->is_operand();
1998	assert( operand, "Entry in operand class that is not an operand"){ if (!(operand)) { fprintf(stderr, "assert fails %s %d: %s\n" , "/home/daniel/Projects/java/jdk/src/hotspot/share/adlc/formssel.cpp" , 1998, "Entry in operand class that is not an operand"); abort (); }};
1999	if( first ) {
2000	first = false;
2001	interface = operand->interface_type(globals);
2002	} else {
2003	interface = (interface == operand->interface_type(globals) ? interface : Form::no_interface);
2004	}
2005	}
2006	return interface;
2007	}
2008
2009	bool OpClassForm::stack_slots_only(FormDict &globals) const {
2010	if( _oplst.count() == 0 ) return false; // how?
2011
2012	NameList &op_list = (NameList &)_oplst;
2013	op_list.reset();
2014	const char *op_name;
2015	while( (op_name = op_list.iter()) != NULL__null ) {
2016	const Form *form = globals[op_name];
2017	OperandForm *operand = form->is_operand();
2018	assert( operand, "Entry in operand class that is not an operand"){ if (!(operand)) { fprintf(stderr, "assert fails %s %d: %s\n" , "/home/daniel/Projects/java/jdk/src/hotspot/share/adlc/formssel.cpp" , 2018, "Entry in operand class that is not an operand"); abort (); }};
2019	if( !operand->stack_slots_only(globals) ) return false;
2020	}
2021	return true;
2022	}
2023
2024
2025	void OpClassForm::dump() {
2026	output(stderrstderr);
2027	}
2028
2029	void OpClassForm::output(FILE *fp) {
2030	const char *name;
2031	fprintf(fp,"\nOperand Class: %s\n", (_ident?_ident:""));
2032	fprintf(fp,"\nCount = %d\n", _oplst.count());
2033	for(_oplst.reset(); (name = _oplst.iter()) != NULL__null;) {
2034	fprintf(fp,"%s, ",name);
2035	}
2036	fprintf(fp,"\n");
2037	}
2038
2039
2040	//==============================Operands=======================================
2041	//------------------------------OperandForm------------------------------------
2042	OperandForm::OperandForm(const char* id)
2043	: OpClassForm(id), _ideal_only(false),
2044	_localNames(cmpstr, hashstr, Form::arena) {
2045	_ftype = Form::OPER;
2046
2047	_matrule = NULL__null;
2048	_interface = NULL__null;
2049	_attribs = NULL__null;
2050	_predicate = NULL__null;
2051	_constraint= NULL__null;
2052	_construct = NULL__null;
2053	_format = NULL__null;
2054	}
2055	OperandForm::OperandForm(const char* id, bool ideal_only)
2056	: OpClassForm(id), _ideal_only(ideal_only),
2057	_localNames(cmpstr, hashstr, Form::arena) {
2058	_ftype = Form::OPER;
2059
2060	_matrule = NULL__null;
2061	_interface = NULL__null;
2062	_attribs = NULL__null;
2063	_predicate = NULL__null;
2064	_constraint= NULL__null;
2065	_construct = NULL__null;
2066	_format = NULL__null;
2067	}
2068	OperandForm::~OperandForm() {
2069	}
2070
2071
2072	OperandForm *OperandForm::is_operand() const {
2073	return (OperandForm*)this;
2074	}
2075
2076	bool OperandForm::ideal_only() const {
2077	return _ideal_only;
2078	}
2079
2080	Form::InterfaceType OperandForm::interface_type(FormDict &globals) const {
2081	if( _interface == NULL__null ) return Form::no_interface;
2082
2083	return _interface->interface_type(globals);
2084	}
2085
2086
2087	bool OperandForm::stack_slots_only(FormDict &globals) const {
2088	if( _constraint == NULL__null ) return false;
2089	return _constraint->stack_slots_only();
2090	}
2091
2092
2093	// Access op_cost attribute or return NULL.
2094	const char* OperandForm::cost() {
2095	for (Attribute* cur = _attribs; cur != NULL__null; cur = (Attribute*)cur->_next) {
2096	if( strcmp(cur->_ident,AttributeForm::_op_cost) == 0 ) {
2097	return cur->_val;
2098	}
2099	}
2100	return NULL__null;
2101	}
2102
2103	// Return the number of leaves below this complex operand
2104	uintunsigned int OperandForm::num_leaves() const {
2105	if ( ! _matrule) return 0;
2106
2107	int num_leaves = _matrule->_numleaves;
2108	return num_leaves;
2109	}
2110
2111	// Return the number of constants contained within this complex operand
2112	uintunsigned int OperandForm::num_consts(FormDict &globals) const {
2113	if ( ! _matrule) return 0;
2114
2115	// This is a recursive invocation on all operands in the matchrule
2116	return _matrule->num_consts(globals);
2117	}
2118
2119	// Return the number of constants in match rule with specified type
2120	uintunsigned int OperandForm::num_consts(FormDict &globals, Form::DataType type) const {
2121	if ( ! _matrule) return 0;
2122
2123	// This is a recursive invocation on all operands in the matchrule
2124	return _matrule->num_consts(globals, type);
2125	}
2126
2127	// Return the number of pointer constants contained within this complex operand
2128	uintunsigned int OperandForm::num_const_ptrs(FormDict &globals) const {
2129	if ( ! _matrule) return 0;
2130
2131	// This is a recursive invocation on all operands in the matchrule
2132	return _matrule->num_const_ptrs(globals);
2133	}
2134
2135	uintunsigned int OperandForm::num_edges(FormDict &globals) const {
2136	uintunsigned int edges = 0;
2137	uintunsigned int leaves = num_leaves();
2138	uintunsigned int consts = num_consts(globals);
2139
2140	// If we are matching a constant directly, there are no leaves.
2141	edges = ( leaves > consts ) ? leaves - consts : 0;
2142
2143	// !!!!!
2144	// Special case operands that do not have a corresponding ideal node.
2145	if( (edges == 0) && (consts == 0) ) {
2146	if( constrained_reg_class() != NULL__null ) {
2147	edges = 1;
2148	} else {
2149	if( _matrule
2150	&& (_matrule->_lChild == NULL__null) && (_matrule->_rChild == NULL__null) ) {
2151	const Form *form = globals[_matrule->_opType];
2152	OperandForm *oper = form ? form->is_operand() : NULL__null;
2153	if( oper ) {
2154	return oper->num_edges(globals);
2155	}
2156	}
2157	}
2158	}
2159
2160	return edges;
2161	}
2162
2163
2164	// Check if this operand is usable for cisc-spilling
2165	bool OperandForm::is_cisc_reg(FormDict &globals) const {
2166	const char *ideal = ideal_type(globals);
2167	bool is_cisc_reg = (ideal && (ideal_to_Reg_type(ideal) != none));
2168	return is_cisc_reg;
2169	}
2170
2171	bool OpClassForm::is_cisc_mem(FormDict &globals) const {
2172	Form::InterfaceType my_interface = interface_type(globals);
2173	return (my_interface == memory_interface);
2174	}
2175
2176
2177	// node matches ideal 'Bool'
2178	bool OperandForm::is_ideal_bool() const {
2179	if( _matrule == NULL__null ) return false;
2180
2181	return _matrule->is_ideal_bool();
2182	}
2183
2184	// Require user's name for an sRegX to be stackSlotX
2185	Form::DataType OperandForm::is_user_name_for_sReg() const {
2186	DataType data_type = none;
2187	if( _ident != NULL__null ) {
2188	if( strcmp(_ident,"stackSlotI") == 0 ) data_type = Form::idealI;
2189	else if( strcmp(_ident,"stackSlotP") == 0 ) data_type = Form::idealP;
2190	else if( strcmp(_ident,"stackSlotD") == 0 ) data_type = Form::idealD;
2191	else if( strcmp(_ident,"stackSlotF") == 0 ) data_type = Form::idealF;
2192	else if( strcmp(_ident,"stackSlotL") == 0 ) data_type = Form::idealL;
2193	}
2194	assert((data_type == none) \|\| (_matrule == NULL), "No match-rule for stackSlotX"){ if (!((data_type == none) \|\| (_matrule == __null))) { fprintf (stderr, "assert fails %s %d: %s\n", "/home/daniel/Projects/java/jdk/src/hotspot/share/adlc/formssel.cpp" , 2194, "No match-rule for stackSlotX"); abort(); }};
2195
2196	return data_type;
2197	}
2198
2199
2200	// Return ideal type, if there is a single ideal type for this operand
2201	const char OperandForm::ideal_type(FormDict &globals, RegisterForm registers) const {
2202	const char *type = NULL__null;
2203	if (ideal_only()) type = _ident;
2204	else if( _matrule == NULL__null ) {
2205	// Check for condition code register
2206	const char *rc_name = constrained_reg_class();
2207	// !!!!!
2208	if (rc_name == NULL__null) return NULL__null;
2209	// !!!!! !!!!!
2210	// Check constraints on result's register class
2211	if( registers ) {
2212	RegClass *reg_class = registers->getRegClass(rc_name);
2213	assert( reg_class != NULL, "Register class is not defined"){ if (!(reg_class != __null)) { fprintf(stderr, "assert fails %s %d: %s\n" , "/home/daniel/Projects/java/jdk/src/hotspot/share/adlc/formssel.cpp" , 2213, "Register class is not defined"); abort(); }};
2214
2215	// Check for ideal type of entries in register class, all are the same type
2216	reg_class->reset();
2217	RegDef *reg_def = reg_class->RegDef_iter();
2218	assert( reg_def != NULL, "No entries in register class"){ if (!(reg_def != __null)) { fprintf(stderr, "assert fails %s %d: %s\n" , "/home/daniel/Projects/java/jdk/src/hotspot/share/adlc/formssel.cpp" , 2218, "No entries in register class"); abort(); }};
2219	assert( reg_def->_idealtype != NULL, "Did not define ideal type for register"){ if (!(reg_def->_idealtype != __null)) { fprintf(stderr, "assert fails %s %d: %s\n" , "/home/daniel/Projects/java/jdk/src/hotspot/share/adlc/formssel.cpp" , 2219, "Did not define ideal type for register"); abort(); } };
2220	// Return substring that names the register's ideal type
2221	type = reg_def->_idealtype + 3;
2222	assert( (reg_def->_idealtype + 0) == 'O', "Expect Op_ prefix"){ if (!((reg_def->_idealtype + 0) == 'O')) { fprintf(stderr , "assert fails %s %d: %s\n", "/home/daniel/Projects/java/jdk/src/hotspot/share/adlc/formssel.cpp" , 2222, "Expect Op_ prefix"); abort(); }};
2223	assert( (reg_def->_idealtype + 1) == 'p', "Expect Op_ prefix"){ if (!((reg_def->_idealtype + 1) == 'p')) { fprintf(stderr , "assert fails %s %d: %s\n", "/home/daniel/Projects/java/jdk/src/hotspot/share/adlc/formssel.cpp" , 2223, "Expect Op_ prefix"); abort(); }};
2224	assert( (reg_def->_idealtype + 2) == '_', "Expect Op_ prefix"){ if (!((reg_def->_idealtype + 2) == '_')) { fprintf(stderr , "assert fails %s %d: %s\n", "/home/daniel/Projects/java/jdk/src/hotspot/share/adlc/formssel.cpp" , 2224, "Expect Op_ prefix"); abort(); }};
2225	}
2226	}
2227	else if( _matrule->_lChild == NULL__null && _matrule->_rChild == NULL__null ) {
2228	// This operand matches a single type, at the top level.
2229	// Check for ideal type
2230	type = _matrule->_opType;
2231	if( strcmp(type,"Bool") == 0 )
2232	return "Bool";
2233	// transitive lookup
2234	const Form *frm = globals[type];
2235	OperandForm *op = frm->is_operand();
2236	type = op->ideal_type(globals, registers);
2237	}
2238	return type;
2239	}
2240
2241
2242	// If there is a single ideal type for this interface field, return it.
2243	const char *OperandForm::interface_ideal_type(FormDict &globals,
2244	const char *field) const {
2245	const char *ideal_type = NULL__null;
2246	const char *value = NULL__null;
2247
2248	// Check if "field" is valid for this operand's interface
2249	if ( ! is_interface_field(field, value) ) return ideal_type;
2250
2251	// !!!!! !!!!! !!!!!
2252	// If a valid field has a constant value, identify "ConI" or "ConP" or ...
2253
2254	// Else, lookup type of field's replacement variable
2255
2256	return ideal_type;
2257	}
2258
2259
2260	RegClass* OperandForm::get_RegClass() const {
2261	if (_interface && !_interface->is_RegInterface()) return NULL__null;
2262	return globalAD->get_registers()->getRegClass(constrained_reg_class());
2263	}
2264
2265
2266	bool OperandForm::is_bound_register() const {
2267	RegClass* reg_class = get_RegClass();
2268	if (reg_class == NULL__null) {
2269	return false;
2270	}
2271
2272	const char* name = ideal_type(globalAD->globalNames());
2273	if (name == NULL__null) {
2274	return false;
2275	}
2276
2277	uintunsigned int size = 0;
2278	if (strcmp(name, "RegFlags") == 0) size = 1;
2279	if (strcmp(name, "RegI") == 0) size = 1;
2280	if (strcmp(name, "RegF") == 0) size = 1;
2281	if (strcmp(name, "RegD") == 0) size = 2;
2282	if (strcmp(name, "RegL") == 0) size = 2;
2283	if (strcmp(name, "RegN") == 0) size = 1;
2284	if (strcmp(name, "RegVectMask") == 0) size = globalAD->get_preproc_def("AARCH64") ? 1 : 2;
2285	if (strcmp(name, "VecX") == 0) size = 4;
2286	if (strcmp(name, "VecY") == 0) size = 8;
2287	if (strcmp(name, "VecZ") == 0) size = 16;
2288	if (strcmp(name, "RegP") == 0) size = globalAD->get_preproc_def("_LP64") ? 2 : 1;
2289	if (size == 0) {
2290	return false;
2291	}
2292	return size == reg_class->size();
2293	}
2294
2295
2296	// Check if this is a valid field for this operand,
2297	// Return 'true' if valid, and set the value to the string the user provided.
2298	bool OperandForm::is_interface_field(const char *field,
2299	const char * &value) const {
2300	return false;
2301	}
2302
2303
2304	// Return register class name if a constraint specifies the register class.
2305	const char *OperandForm::constrained_reg_class() const {
2306	const char *reg_class = NULL__null;
2307	if ( _constraint ) {
2308	// !!!!!
2309	Constraint *constraint = _constraint;
2310	if ( strcmp(_constraint->_func,"ALLOC_IN_RC") == 0 ) {
2311	reg_class = _constraint->_arg;
2312	}
2313	}
2314
2315	return reg_class;
2316	}
2317
2318
2319	// Return the register class associated with 'leaf'.
2320	const char *OperandForm::in_reg_class(uintunsigned int leaf, FormDict &globals) {
2321	const char *reg_class = NULL__null; // "RegMask::Empty";
2322
2323	if((_matrule == NULL__null) \|\| (_matrule->is_chain_rule(globals))) {
2324	reg_class = constrained_reg_class();
2325	return reg_class;
2326	}
2327	const char *result = NULL__null;
2328	const char *name = NULL__null;
2329	const char *type = NULL__null;
2330	// iterate through all base operands
2331	// until we reach the register that corresponds to "leaf"
2332	// This function is not looking for an ideal type. It needs the first
2333	// level user type associated with the leaf.
2334	for(uintunsigned int idx = 0;_matrule->base_operand(idx,globals,result,name,type);++idx) {
2335	const Form *form = (_localNames[name] ? _localNames[name] : globals[result]);
2336	OperandForm *oper = form ? form->is_operand() : NULL__null;
2337	if( oper ) {
2338	reg_class = oper->constrained_reg_class();
2339	if( reg_class ) {
2340	reg_class = reg_class;
2341	} else {
2342	// ShouldNotReachHere();
2343	}
2344	} else {
2345	// ShouldNotReachHere();
2346	}
2347
2348	// Increment our target leaf position if current leaf is not a candidate.
2349	if( reg_class == NULL__null) ++leaf;
2350	// Exit the loop with the value of reg_class when at the correct index
2351	if( idx == leaf ) break;
2352	// May iterate through all base operands if reg_class for 'leaf' is NULL
2353	}
2354	return reg_class;
2355	}
2356
2357
2358	// Recursive call to construct list of top-level operands.
2359	// Implementation does not modify state of internal structures
2360	void OperandForm::build_components() {
2361	if (_matrule) _matrule->append_components(_localNames, _components);
2362
2363	// Add parameters that "do not appear in match rule".
2364	const char *name;
2365	for (_parameters.reset(); (name = _parameters.iter()) != NULL__null;) {
2366	OpClassForm *opForm = _localNames[name]->is_opclass();
2367	assert(opForm != NULL, "sanity"){ if (!(opForm != __null)) { fprintf(stderr, "assert fails %s %d: %s\n" , "/home/daniel/Projects/java/jdk/src/hotspot/share/adlc/formssel.cpp" , 2367, "sanity"); abort(); }};
2368
2369	if ( _components.operand_position(name) == -1 ) {
2370	_components.insert(name, opForm->_ident, Component::INVALID, false);
2371	}
2372	}
2373
2374	return;
2375	}
2376
2377	int OperandForm::operand_position(const char *name, int usedef) {
2378	return _components.operand_position(name, usedef, this);
2379	}
2380
2381
2382	// Return zero-based position in component list, only counting constants;
2383	// Return -1 if not in list.
2384	int OperandForm::constant_position(FormDict &globals, const Component *last) {
2385	// Iterate through components and count constants preceding 'constant'
2386	int position = 0;
2387	Component *comp;
2388	_components.reset();
2389	while( (comp = _components.iter()) != NULL__null && (comp != last) ) {
2390	// Special case for operands that take a single user-defined operand
2391	// Skip the initial definition in the component list.
2392	if( strcmp(comp->_name,this->_ident) == 0 ) continue;
2393
2394	const char *type = comp->_type;
2395	// Lookup operand form for replacement variable's type
2396	const Form *form = globals[type];
2397	assert( form != NULL, "Component's type not found"){ if (!(form != __null)) { fprintf(stderr, "assert fails %s %d: %s\n" , "/home/daniel/Projects/java/jdk/src/hotspot/share/adlc/formssel.cpp" , 2397, "Component's type not found"); abort(); }};
2398	OperandForm *oper = form ? form->is_operand() : NULL__null;
2399	if( oper ) {
2400	if( oper->_matrule->is_base_constant(globals) != Form::none ) {
2401	++position;
2402	}
2403	}
2404	}
2405
2406	// Check for being passed a component that was not in the list
2407	if( comp != last ) position = -1;
2408
2409	return position;
2410	}
2411	// Provide position of constant by "name"
2412	int OperandForm::constant_position(FormDict &globals, const char *name) {
2413	const Component *comp = _components.search(name);
2414	int idx = constant_position( globals, comp );
2415
2416	return idx;
2417	}
2418
2419
2420	// Return zero-based position in component list, only counting constants;
2421	// Return -1 if not in list.
2422	int OperandForm::register_position(FormDict &globals, const char *reg_name) {
2423	// Iterate through components and count registers preceding 'last'
2424	uintunsigned int position = 0;
2425	Component *comp;
2426	_components.reset();
2427	while( (comp = _components.iter()) != NULL__null
2428	&& (strcmp(comp->_name,reg_name) != 0) ) {
2429	// Special case for operands that take a single user-defined operand
2430	// Skip the initial definition in the component list.
2431	if( strcmp(comp->_name,this->_ident) == 0 ) continue;
2432
2433	const char *type = comp->_type;
2434	// Lookup operand form for component's type
2435	const Form *form = globals[type];
2436	assert( form != NULL, "Component's type not found"){ if (!(form != __null)) { fprintf(stderr, "assert fails %s %d: %s\n" , "/home/daniel/Projects/java/jdk/src/hotspot/share/adlc/formssel.cpp" , 2436, "Component's type not found"); abort(); }};
2437	OperandForm *oper = form ? form->is_operand() : NULL__null;
2438	if( oper ) {
2439	if( oper->_matrule->is_base_register(globals) ) {
2440	++position;
2441	}
2442	}
2443	}
2444
2445	return position;
2446	}
2447
2448
2449	const char *OperandForm::reduce_result() const {
2450	return _ident;
2451	}
2452	// Return the name of the operand on the right hand side of the binary match
2453	// Return NULL if there is no right hand side
2454	const char *OperandForm::reduce_right(FormDict &globals) const {
2455	return ( _matrule ? _matrule->reduce_right(globals) : NULL__null );
2456	}
2457
2458	// Similar for left
2459	const char *OperandForm::reduce_left(FormDict &globals) const {
2460	return ( _matrule ? _matrule->reduce_left(globals) : NULL__null );
2461	}
2462
2463
2464	// --------------------------- FILE *output_routines
2465	//
2466	// Output code for disp_is_oop, if true.
2467	void OperandForm::disp_is_oop(FILE *fp, FormDict &globals) {
2468	// Check it is a memory interface with a non-user-constant disp field
2469	if ( this->_interface == NULL__null ) return;
2470	MemInterface *mem_interface = this->_interface->is_MemInterface();
2471	if ( mem_interface == NULL__null ) return;
2472	const char *disp = mem_interface->_disp;
2473	if ( *disp != '$' ) return;
2474
2475	// Lookup replacement variable in operand's component list
2476	const char *rep_var = disp + 1;
2477	const Component *comp = this->_components.search(rep_var);
2478	assert( comp != NULL, "Replacement variable not found in components"){ if (!(comp != __null)) { fprintf(stderr, "assert fails %s %d: %s\n" , "/home/daniel/Projects/java/jdk/src/hotspot/share/adlc/formssel.cpp" , 2478, "Replacement variable not found in components"); abort (); }};
2479	// Lookup operand form for replacement variable's type
2480	const char *type = comp->_type;
2481	Form form = (Form)globals[type];
2482	assert( form != NULL, "Replacement variable's type not found"){ if (!(form != __null)) { fprintf(stderr, "assert fails %s %d: %s\n" , "/home/daniel/Projects/java/jdk/src/hotspot/share/adlc/formssel.cpp" , 2482, "Replacement variable's type not found"); abort(); }};
2483	OperandForm *op = form->is_operand();
2484	assert( op, "Memory Interface 'disp' can only emit an operand form"){ if (!(op)) { fprintf(stderr, "assert fails %s %d: %s\n", "/home/daniel/Projects/java/jdk/src/hotspot/share/adlc/formssel.cpp" , 2484, "Memory Interface 'disp' can only emit an operand form" ); abort(); }};
2485	// Check if this is a ConP, which may require relocation
2486	if ( op->is_base_constant(globals) == Form::idealP ) {
2487	// Find the constant's index: _c0, _c1, _c2, ... , _cN
2488	uintunsigned int idx = op->constant_position( globals, rep_var);
2489	fprintf(fp," virtual relocInfo::relocType disp_reloc() const {");
2490	fprintf(fp, " return _c%d->reloc();", idx);
2491	fprintf(fp, " }\n");
2492	}
2493	}
2494
2495	// Generate code for internal and external format methods
2496	//
2497	// internal access to reg# node->_idx
2498	// access to subsumed constant _c0, _c1,
2499	void OperandForm::int_format(FILE *fp, FormDict &globals, uintunsigned int index) {
2500	Form::DataType dtype;
2501	if (_matrule && (_matrule->is_base_register(globals) \|\|
2502	strcmp(ideal_type(globalAD->globalNames()), "RegFlags") == 0)) {
2503	// !!!!! !!!!!
2504	fprintf(fp," { char reg_str[128];\n");
2505	fprintf(fp," ra->dump_register(node,reg_str);\n");
2506	fprintf(fp," st->print(\"%cs\",reg_str);\n",'%');
2507	fprintf(fp," }\n");
2508	} else if (_matrule && (dtype = _matrule->is_base_constant(globals)) != Form::none) {
2509	format_constant( fp, index, dtype );
2510	} else if (ideal_to_sReg_type(_ident) != Form::none) {
2511	// Special format for Stack Slot Register
2512	fprintf(fp," { char reg_str[128];\n");
2513	fprintf(fp," ra->dump_register(node,reg_str);\n");
2514	fprintf(fp," st->print(\"%cs\",reg_str);\n",'%');
2515	fprintf(fp," }\n");
2516	} else {
2517	fprintf(fp," st->print(\"No format defined for %s\n\");\n", _ident);
2518	fflush(fp);
2519	fprintf(stderrstderr,"No format defined for %s\n", _ident);
2520	dump();
2521	assert( false,"Internal error:\n output_internal_operand() attempting to output other than a Register or Constant"){ if (!(false)) { fprintf(stderr, "assert fails %s %d: %s\n", "/home/daniel/Projects/java/jdk/src/hotspot/share/adlc/formssel.cpp" , 2521, "Internal error:\n output_internal_operand() attempting to output other than a Register or Constant" ); abort(); }};
2522	}
2523	}
2524
2525	// Similar to "int_format" but for cases where data is external to operand
2526	// external access to reg# node->in(idx)->_idx,
2527	void OperandForm::ext_format(FILE *fp, FormDict &globals, uintunsigned int index) {
2528	Form::DataType dtype;
2529	if (_matrule && (_matrule->is_base_register(globals) \|\|
2530	strcmp(ideal_type(globalAD->globalNames()), "RegFlags") == 0)) {
2531	fprintf(fp," { char reg_str[128];\n");
2532	fprintf(fp," ra->dump_register(node->in(idx");
2533	if ( index != 0 ) fprintf(fp, "+%d",index);
2534	fprintf(fp, "),reg_str);\n");
2535	fprintf(fp," st->print(\"%cs\",reg_str);\n",'%');
2536	fprintf(fp," }\n");
2537	} else if (_matrule && (dtype = _matrule->is_base_constant(globals)) != Form::none) {
2538	format_constant( fp, index, dtype );
2539	} else if (ideal_to_sReg_type(_ident) != Form::none) {
2540	// Special format for Stack Slot Register
2541	fprintf(fp," { char reg_str[128];\n");
2542	fprintf(fp," ra->dump_register(node->in(idx");
2543	if ( index != 0 ) fprintf(fp, "+%d",index);
2544	fprintf(fp, "),reg_str);\n");
2545	fprintf(fp," st->print(\"%cs\",reg_str);\n",'%');
2546	fprintf(fp," }\n");
2547	} else {
2548	fprintf(fp," st->print(\"No format defined for %s\n\");\n", _ident);
2549	assert( false,"Internal error:\n output_external_operand() attempting to output other than a Register or Constant"){ if (!(false)) { fprintf(stderr, "assert fails %s %d: %s\n", "/home/daniel/Projects/java/jdk/src/hotspot/share/adlc/formssel.cpp" , 2549, "Internal error:\n output_external_operand() attempting to output other than a Register or Constant" ); abort(); }};
2550	}
2551	}
2552
2553	void OperandForm::format_constant(FILE *fp, uintunsigned int const_index, uintunsigned int const_type) {
2554	switch(const_type) {
2555	case Form::idealI: fprintf(fp," st->print(\"#%%d\", _c%d);\n", const_index); break;
2556	case Form::idealP: fprintf(fp," if (_c%d) _c%d->dump_on(st);\n", const_index, const_index); break;
2557	case Form::idealNKlass:
2558	case Form::idealN: fprintf(fp," if (_c%d) _c%d->dump_on(st);\n", const_index, const_index); break;
2559	case Form::idealL: fprintf(fp," st->print(\"#\" INT64_FORMAT, (int64_t)_c%d);\n", const_index); break;
2560	case Form::idealF: fprintf(fp," st->print(\"#%%f\", _c%d);\n", const_index); break;
2561	case Form::idealD: fprintf(fp," st->print(\"#%%f\", _c%d);\n", const_index); break;
2562	default:
2563	assert( false, "ShouldNotReachHere()"){ if (!(false)) { fprintf(stderr, "assert fails %s %d: %s\n", "/home/daniel/Projects/java/jdk/src/hotspot/share/adlc/formssel.cpp" , 2563, "ShouldNotReachHere()"); abort(); }};
2564	}
2565	}
2566
2567	// Return the operand form corresponding to the given index, else NULL.
2568	OperandForm *OperandForm::constant_operand(FormDict &globals,
2569	uintunsigned int index) {
2570	// !!!!!
2571	// Check behavior on complex operands
2572	uintunsigned int n_consts = num_consts(globals);
2573	if( n_consts > 0 ) {
2574	uintunsigned int i = 0;
2575	const char *type;
2576	Component *comp;
2577	_components.reset();
2578	if ((comp = _components.iter()) == NULL__null) {
2579	assert(n_consts == 1, "Bad component list detected.\n"){ if (!(n_consts == 1)) { fprintf(stderr, "assert fails %s %d: %s\n" , "/home/daniel/Projects/java/jdk/src/hotspot/share/adlc/formssel.cpp" , 2579, "Bad component list detected.\n"); abort(); }};
2580	// Current operand is THE operand
2581	if ( index == 0 ) {
2582	return this;
2583	}
2584	} // end if NULL
2585	else {
2586	// Skip the first component, it can not be a DEF of a constant
2587	do {
2588	type = comp->base_type(globals);
2589	// Check that "type" is a 'ConI', 'ConP', ...
2590	if ( ideal_to_const_type(type) != Form::none ) {
2591	// When at correct component, get corresponding Operand
2592	if ( index == 0 ) {
2593	return globals[comp->_type]->is_operand();
2594	}
2595	// Decrement number of constants to go
2596	--index;
2597	}
2598	} while((comp = _components.iter()) != NULL__null);
2599	}
2600	}
2601
2602	// Did not find a constant for this index.
2603	return NULL__null;
2604	}
2605
2606	// If this operand has a single ideal type, return its type
2607	Form::DataType OperandForm::simple_type(FormDict &globals) const {
2608	const char *type_name = ideal_type(globals);
2609	Form::DataType type = type_name ? ideal_to_const_type( type_name )
2610	: Form::none;
2611	return type;
2612	}
2613
2614	Form::DataType OperandForm::is_base_constant(FormDict &globals) const {
2615	if ( _matrule == NULL__null ) return Form::none;
2616
2617	return _matrule->is_base_constant(globals);
2618	}
2619
2620	// "true" if this operand is a simple type that is swallowed
2621	bool OperandForm::swallowed(FormDict &globals) const {
2622	Form::DataType type = simple_type(globals);
2623	if( type != Form::none ) {
2624	return true;
2625	}
2626
2627	return false;
2628	}
2629
2630	// Output code to access the value of the index'th constant
2631	void OperandForm::access_constant(FILE *fp, FormDict &globals,
2632	uintunsigned int const_index) {
2633	OperandForm *oper = constant_operand(globals, const_index);
2634	assert( oper, "Index exceeds number of constants in operand"){ if (!(oper)) { fprintf(stderr, "assert fails %s %d: %s\n", "/home/daniel/Projects/java/jdk/src/hotspot/share/adlc/formssel.cpp" , 2634, "Index exceeds number of constants in operand"); abort (); }};
2635	Form::DataType dtype = oper->is_base_constant(globals);
2636
2637	switch(dtype) {
2638	case idealI: fprintf(fp,"_c%d", const_index); break;
2639	case idealP: fprintf(fp,"_c%d->get_con()",const_index); break;
2640	case idealL: fprintf(fp,"_c%d", const_index); break;
2641	case idealF: fprintf(fp,"_c%d", const_index); break;
2642	case idealD: fprintf(fp,"_c%d", const_index); break;
2643	default:
2644	assert( false, "ShouldNotReachHere()"){ if (!(false)) { fprintf(stderr, "assert fails %s %d: %s\n", "/home/daniel/Projects/java/jdk/src/hotspot/share/adlc/formssel.cpp" , 2644, "ShouldNotReachHere()"); abort(); }};
2645	}
2646	}
2647
2648
2649	void OperandForm::dump() {
2650	output(stderrstderr);
2651	}
2652
2653	void OperandForm::output(FILE *fp) {
2654	fprintf(fp,"\nOperand: %s\n", (_ident?_ident:""));
2655	if (_matrule) _matrule->dump();
2656	if (_interface) _interface->dump();
2657	if (_attribs) _attribs->dump();
2658	if (_predicate) _predicate->dump();
2659	if (_constraint) _constraint->dump();
2660	if (_construct) _construct->dump();
2661	if (_format) _format->dump();
2662	}
2663
2664	//------------------------------Constraint-------------------------------------
2665	Constraint::Constraint(const char func, const char arg)
2666	: _func(func), _arg(arg) {
2667	}
2668	Constraint::~Constraint() { /* not owner of char* */
2669	}
2670
2671	bool Constraint::stack_slots_only() const {
2672	return strcmp(_func, "ALLOC_IN_RC") == 0
2673	&& strcmp(_arg, "stack_slots") == 0;
2674	}
2675
2676	void Constraint::dump() {
2677	output(stderrstderr);
2678	}
2679
2680	void Constraint::output(FILE *fp) { // Write info to output files
2681	assert((_func != NULL && _arg != NULL),"missing constraint function or arg"){ if (!((_func != __null && _arg != __null))) { fprintf (stderr, "assert fails %s %d: %s\n", "/home/daniel/Projects/java/jdk/src/hotspot/share/adlc/formssel.cpp" , 2681, "missing constraint function or arg"); abort(); }};
2682	fprintf(fp,"Constraint: %s ( %s )\n", _func, _arg);
2683	}
2684
2685	//------------------------------Predicate--------------------------------------
2686	Predicate::Predicate(char *pr)
2687	: _pred(pr) {
2688	}
2689	Predicate::~Predicate() {
2690	}
2691
2692	void Predicate::dump() {
2693	output(stderrstderr);
2694	}
2695
2696	void Predicate::output(FILE *fp) {
2697	fprintf(fp,"Predicate"); // Write to output files
2698	}
2699	//------------------------------Interface--------------------------------------
2700	Interface::Interface(const char *name) : _name(name) {
2701	}
2702	Interface::~Interface() {
2703	}
2704
2705	Form::InterfaceType Interface::interface_type(FormDict &globals) const {
2706	Interface thsi = (Interface)this;
2707	if ( thsi->is_RegInterface() ) return Form::register_interface;
2708	if ( thsi->is_MemInterface() ) return Form::memory_interface;
2709	if ( thsi->is_ConstInterface() ) return Form::constant_interface;
2710	if ( thsi->is_CondInterface() ) return Form::conditional_interface;
2711
2712	return Form::no_interface;
2713	}
2714
2715	RegInterface *Interface::is_RegInterface() {
2716	if ( strcmp(_name,"REG_INTER") != 0 )
2717	return NULL__null;
2718	return (RegInterface*)this;
2719	}
2720	MemInterface *Interface::is_MemInterface() {
2721	if ( strcmp(_name,"MEMORY_INTER") != 0 ) return NULL__null;
2722	return (MemInterface*)this;
2723	}
2724	ConstInterface *Interface::is_ConstInterface() {
2725	if ( strcmp(_name,"CONST_INTER") != 0 ) return NULL__null;
2726	return (ConstInterface*)this;
2727	}
2728	CondInterface *Interface::is_CondInterface() {
2729	if ( strcmp(_name,"COND_INTER") != 0 ) return NULL__null;
2730	return (CondInterface*)this;
2731	}
2732
2733
2734	void Interface::dump() {
2735	output(stderrstderr);
2736	}
2737
2738	// Write info to output files
2739	void Interface::output(FILE *fp) {
2740	fprintf(fp,"Interface: %s\n", (_name ? _name : "") );
2741	}
2742
2743	//------------------------------RegInterface-----------------------------------
2744	RegInterface::RegInterface() : Interface("REG_INTER") {
2745	}
2746	RegInterface::~RegInterface() {
2747	}
2748
2749	void RegInterface::dump() {
2750	output(stderrstderr);
2751	}
2752
2753	// Write info to output files
2754	void RegInterface::output(FILE *fp) {
2755	Interface::output(fp);
2756	}
2757
2758	//------------------------------ConstInterface---------------------------------
2759	ConstInterface::ConstInterface() : Interface("CONST_INTER") {
2760	}
2761	ConstInterface::~ConstInterface() {
2762	}
2763
2764	void ConstInterface::dump() {
2765	output(stderrstderr);
2766	}
2767
2768	// Write info to output files
2769	void ConstInterface::output(FILE *fp) {
2770	Interface::output(fp);
2771	}
2772
2773	//------------------------------MemInterface-----------------------------------
2774	MemInterface::MemInterface(char base, char index, char scale, char disp)
2775	: Interface("MEMORY_INTER"), _base(base), _index(index), _scale(scale), _disp(disp) {
2776	}
2777	MemInterface::~MemInterface() {
2778	// not owner of any character arrays
2779	}
2780
2781	void MemInterface::dump() {
2782	output(stderrstderr);
2783	}
2784
2785	// Write info to output files
2786	void MemInterface::output(FILE *fp) {
2787	Interface::output(fp);
2788	if ( _base != NULL__null ) fprintf(fp," base == %s\n", _base);
2789	if ( _index != NULL__null ) fprintf(fp," index == %s\n", _index);
2790	if ( _scale != NULL__null ) fprintf(fp," scale == %s\n", _scale);
2791	if ( _disp != NULL__null ) fprintf(fp," disp == %s\n", _disp);
2792	// fprintf(fp,"\n");
2793	}
2794
2795	//------------------------------CondInterface----------------------------------
2796	CondInterface::CondInterface(const char* equal, const char* equal_format,
2797	const char* not_equal, const char* not_equal_format,
2798	const char* less, const char* less_format,
2799	const char* greater_equal, const char* greater_equal_format,
2800	const char* less_equal, const char* less_equal_format,
2801	const char* greater, const char* greater_format,
2802	const char* overflow, const char* overflow_format,
2803	const char* no_overflow, const char* no_overflow_format)
2804	: Interface("COND_INTER"),
2805	_equal(equal), _equal_format(equal_format),
2806	_not_equal(not_equal), _not_equal_format(not_equal_format),
2807	_less(less), _less_format(less_format),
2808	_greater_equal(greater_equal), _greater_equal_format(greater_equal_format),
2809	_less_equal(less_equal), _less_equal_format(less_equal_format),
2810	_greater(greater), _greater_format(greater_format),
2811	_overflow(overflow), _overflow_format(overflow_format),
2812	_no_overflow(no_overflow), _no_overflow_format(no_overflow_format) {
2813	}
2814	CondInterface::~CondInterface() {
2815	// not owner of any character arrays
2816	}
2817
2818	void CondInterface::dump() {
2819	output(stderrstderr);
2820	}
2821
2822	// Write info to output files
2823	void CondInterface::output(FILE *fp) {
2824	Interface::output(fp);
2825	if ( _equal != NULL__null ) fprintf(fp," equal == %s\n", _equal);
2826	if ( _not_equal != NULL__null ) fprintf(fp," not_equal == %s\n", _not_equal);
2827	if ( _less != NULL__null ) fprintf(fp," less == %s\n", _less);
2828	if ( _greater_equal != NULL__null ) fprintf(fp," greater_equal == %s\n", _greater_equal);
2829	if ( _less_equal != NULL__null ) fprintf(fp," less_equal == %s\n", _less_equal);
2830	if ( _greater != NULL__null ) fprintf(fp," greater == %s\n", _greater);
2831	if ( _overflow != NULL__null ) fprintf(fp," overflow == %s\n", _overflow);
2832	if ( _no_overflow != NULL__null ) fprintf(fp," no_overflow == %s\n", _no_overflow);
2833	// fprintf(fp,"\n");
2834	}
2835
2836	//------------------------------ConstructRule----------------------------------
2837	ConstructRule::ConstructRule(char *cnstr)
2838	: _construct(cnstr) {
2839	}
2840	ConstructRule::~ConstructRule() {
2841	}
2842
2843	void ConstructRule::dump() {
2844	output(stderrstderr);
2845	}
2846
2847	void ConstructRule::output(FILE *fp) {
2848	fprintf(fp,"\nConstruct Rule\n"); // Write to output files
2849	}
2850
2851
2852	//==============================Shared Forms===================================
2853	//------------------------------AttributeForm----------------------------------
2854	int AttributeForm::_insId = 0; // start counter at 0
2855	int AttributeForm::_opId = 0; // start counter at 0
2856	const char* AttributeForm::_ins_cost = "ins_cost"; // required name
2857	const char* AttributeForm::_op_cost = "op_cost"; // required name
2858
2859	AttributeForm::AttributeForm(char attr, int type, char attrdef)
2860	: Form(Form::ATTR), _attrname(attr), _atype(type), _attrdef(attrdef) {
2861	if (type==OP_ATTR1) {
2862	id = ++_opId;
2863	}
2864	else if (type==INS_ATTR0) {
2865	id = ++_insId;
2866	}
2867	else assert( false,""){ if (!(false)) { fprintf(stderr, "assert fails %s %d: %s\n", "/home/daniel/Projects/java/jdk/src/hotspot/share/adlc/formssel.cpp" , 2867, ""); abort(); }};
2868	}
2869	AttributeForm::~AttributeForm() {
2870	}
2871
2872	// Dynamic type check
2873	AttributeForm *AttributeForm::is_attribute() const {
2874	return (AttributeForm*)this;
2875	}
2876
2877
2878	// inlined // int AttributeForm::type() { return id;}
2879
2880	void AttributeForm::dump() {
2881	output(stderrstderr);
2882	}
2883
2884	void AttributeForm::output(FILE *fp) {
2885	if( _attrname && _attrdef ) {
2886	fprintf(fp,"\n// AttributeForm \nstatic const int %s = %s;\n",
2887	_attrname, _attrdef);
2888	}
2889	else {
2890	fprintf(fp,"\n// AttributeForm missing name %s or definition %s\n",
2891	(_attrname?_attrname:""), (_attrdef?_attrdef:"") );
2892	}
2893	}
2894
2895	//------------------------------Component--------------------------------------
2896	Component::Component(const char name, const char type, int usedef)
2897	: _name(name), _type(type), _usedef(usedef) {
2898	_ftype = Form::COMP;
2899	}
2900	Component::~Component() {
2901	}
2902
2903	// True if this component is equal to the parameter.
2904	bool Component::is(int use_def_kill_enum) const {
2905	return (_usedef == use_def_kill_enum ? true : false);
2906	}
2907	// True if this component is used/def'd/kill'd as the parameter suggests.
2908	bool Component::isa(int use_def_kill_enum) const {
2909	return (_usedef & use_def_kill_enum) == use_def_kill_enum;
2910	}
2911
2912	// Extend this component with additional use/def/kill behavior
2913	int Component::promote_use_def_info(int new_use_def) {
2914	_usedef \|= new_use_def;
2915
2916	return _usedef;
2917	}
2918
2919	// Check the base type of this component, if it has one
2920	const char *Component::base_type(FormDict &globals) {
2921	const Form *frm = globals[_type];
2922	if (frm == NULL__null) return NULL__null;
2923	OperandForm *op = frm->is_operand();
2924	if (op == NULL__null) return NULL__null;
2925	if (op->ideal_only()) return op->_ident;
2926	return (char *)op->ideal_type(globals);
2927	}
2928
2929	void Component::dump() {
2930	output(stderrstderr);
2931	}
2932
2933	void Component::output(FILE *fp) {
2934	fprintf(fp,"Component:"); // Write to output files
2935	fprintf(fp, " name = %s", _name);
2936	fprintf(fp, ", type = %s", _type);
2937	assert(_usedef != 0, "unknown effect"){ if (!(_usedef != 0)) { fprintf(stderr, "assert fails %s %d: %s\n" , "/home/daniel/Projects/java/jdk/src/hotspot/share/adlc/formssel.cpp" , 2937, "unknown effect"); abort(); }};
2938	fprintf(fp, ", use/def = %s\n", getUsedefName());
2939	}
2940
2941
2942	//------------------------------ComponentList---------------------------------
2943	ComponentList::ComponentList() : NameList(), _matchcnt(0) {
2944	}
2945	ComponentList::~ComponentList() {
2946	// // This list may not own its elements if copied via assignment
2947	// Component *component;
2948	// for (reset(); (component = iter()) != NULL;) {
2949	// delete component;
2950	// }
2951	}
2952
2953	void ComponentList::insert(Component *component, bool mflag) {
2954	NameList::addName((char *)component);
2955	if(mflag) _matchcnt++;
2956	}
2957	void ComponentList::insert(const char name, const char opType, int usedef,
2958	bool mflag) {
2959	Component * component = new Component(name, opType, usedef);
2960	insert(component, mflag);
2961	}
2962	Component ComponentList::current() { return (Component)NameList::current(); }
2963	Component ComponentList::iter() { return (Component)NameList::iter(); }
2964	Component *ComponentList::match_iter() {
2965	if(_iter < _matchcnt) return (Component*)NameList::iter();
2966	return NULL__null;
2967	}
2968	Component *ComponentList::post_match_iter() {
2969	Component *comp = iter();
2970	// At end of list?
2971	if ( comp == NULL__null ) {
2972	return comp;
2973	}
2974	// In post-match components?
2975	if (_iter > match_count()-1) {
2976	return comp;
2977	}
2978
2979	return post_match_iter();
2980	}
2981
2982	void ComponentList::reset() { NameList::reset(); }
2983	int ComponentList::count() { return NameList::count(); }
2984
2985	Component *ComponentList::operator[](int position) {
2986	// Shortcut complete iteration if there are not enough entries
2987	if (position >= count()) return NULL__null;
2988
2989	int index = 0;
2990	Component *component = NULL__null;
2991	for (reset(); (component = iter()) != NULL__null;) {
2992	if (index == position) {
2993	return component;
2994	}
2995	++index;
2996	}
2997
2998	return NULL__null;
2999	}
3000
3001	const Component ComponentList::search(const char name) {
3002	PreserveIter pi(this);
3003	reset();
3004	for( Component *comp = NULL__null; ((comp = iter()) != NULL__null); ) {
3005	if( strcmp(comp->_name,name) == 0 ) return comp;
3006	}
3007
3008	return NULL__null;
3009	}
3010
3011	// Return number of USEs + number of DEFs
3012	// When there are no components, or the first component is a USE,
3013	// then we add '1' to hold a space for the 'result' operand.
3014	int ComponentList::num_operands() {
3015	PreserveIter pi(this);
3016	uintunsigned int count = 1; // result operand
3017	uintunsigned int position = 0;
3018
3019	Component *component = NULL__null;
3020	for( reset(); (component = iter()) != NULL__null; ++position ) {
3021	if( component->isa(Component::USE) \|\|
3022	( position == 0 && (! component->isa(Component::DEF))) ) {
3023	++count;
3024	}
3025	}
3026
3027	return count;
3028	}
3029
3030	// Return zero-based position of operand 'name' in list; -1 if not in list.
3031	// if parameter 'usedef' is ::USE, it will match USE, USE_DEF, ...
3032	int ComponentList::operand_position(const char name, int usedef, Form fm) {
3033	PreserveIter pi(this);
3034	int position = 0;
3035	int num_opnds = num_operands();
3036	Component *component;
3037	Component* preceding_non_use = NULL__null;
3038	Component* first_def = NULL__null;
3039	for (reset(); (component = iter()) != NULL__null; ++position) {
3040	// When the first component is not a DEF,
3041	// leave space for the result operand!
3042	if ( position==0 && (! component->isa(Component::DEF)) ) {
3043	++position;
3044	++num_opnds;
3045	}
3046	if (strcmp(name, component->_name)==0 && (component->isa(usedef))) {
3047	// When the first entry in the component list is a DEF and a USE
3048	// Treat them as being separate, a DEF first, then a USE
3049	if( position==0
3050	&& usedef==Component::USE && component->isa(Component::DEF) ) {
3051	assert(position+1 < num_opnds, "advertised index in bounds"){ if (!(position+1 < num_opnds)) { fprintf(stderr, "assert fails %s %d: %s\n" , "/home/daniel/Projects/java/jdk/src/hotspot/share/adlc/formssel.cpp" , 3051, "advertised index in bounds"); abort(); }};
3052	return position+1;
3053	} else {
3054	if( preceding_non_use && strcmp(component->_name, preceding_non_use->_name) ) {
3055	fprintf(stderrstderr, "the name '%s(%s)' should not precede the name '%s(%s)'",
3056	preceding_non_use->_name, preceding_non_use->getUsedefName(),
3057	name, component->getUsedefName());
3058	if (fm && fm->is_instruction()) fprintf(stderrstderr, "in form '%s'", fm->is_instruction()->_ident);
3059	if (fm && fm->is_operand()) fprintf(stderrstderr, "in form '%s'", fm->is_operand()->_ident);
3060	fprintf(stderrstderr, "\n");
3061	}
3062	if( position >= num_opnds ) {
3063	fprintf(stderrstderr, "the name '%s' is too late in its name list", name);
3064	if (fm && fm->is_instruction()) fprintf(stderrstderr, "in form '%s'", fm->is_instruction()->_ident);
3065	if (fm && fm->is_operand()) fprintf(stderrstderr, "in form '%s'", fm->is_operand()->_ident);
3066	fprintf(stderrstderr, "\n");
3067	}
3068	assert(position < num_opnds, "advertised index in bounds"){ if (!(position < num_opnds)) { fprintf(stderr, "assert fails %s %d: %s\n" , "/home/daniel/Projects/java/jdk/src/hotspot/share/adlc/formssel.cpp" , 3068, "advertised index in bounds"); abort(); }};
3069	return position;
3070	}
3071	}
3072	if( component->isa(Component::DEF)
3073	&& component->isa(Component::USE) ) {
3074	++position;
3075	if( position != 1 ) --position; // only use two slots for the 1st USE_DEF
3076	}
3077	if( component->isa(Component::DEF) && !first_def ) {
3078	first_def = component;
3079	}
3080	if( !component->isa(Component::USE) && component != first_def ) {
3081	preceding_non_use = component;
3082	} else if( preceding_non_use && !strcmp(component->_name, preceding_non_use->_name) ) {
3083	preceding_non_use = NULL__null;
3084	}
3085	}
3086	return Not_in_list;
3087	}
3088
3089	// Find position for this name, regardless of use/def information
3090	int ComponentList::operand_position(const char *name) {
3091	PreserveIter pi(this);
3092	int position = 0;
3093	Component *component;
3094	for (reset(); (component = iter()) != NULL__null; ++position) {
3095	// When the first component is not a DEF,
3096	// leave space for the result operand!
3097	if ( position==0 && (! component->isa(Component::DEF)) ) {
3098	++position;
3099	}
3100	if (strcmp(name, component->_name)==0) {
3101	return position;
3102	}
3103	if( component->isa(Component::DEF)
3104	&& component->isa(Component::USE) ) {
3105	++position;
3106	if( position != 1 ) --position; // only use two slots for the 1st USE_DEF
3107	}
3108	}
3109	return Not_in_list;
3110	}
3111
3112	int ComponentList::operand_position_format(const char name, Form fm) {
3113	PreserveIter pi(this);
3114	int first_position = operand_position(name);
3115	int use_position = operand_position(name, Component::USE, fm);
3116
3117	return ((first_position < use_position) ? use_position : first_position);
3118	}
3119
3120	int ComponentList::label_position() {
3121	PreserveIter pi(this);
3122	int position = 0;
3123	reset();
3124	for( Component *comp; (comp = iter()) != NULL__null; ++position) {
3125	// When the first component is not a DEF,
3126	// leave space for the result operand!
3127	if ( position==0 && (! comp->isa(Component::DEF)) ) {
3128	++position;
3129	}
3130	if (strcmp(comp->_type, "label")==0) {
3131	return position;
3132	}
3133	if( comp->isa(Component::DEF)
3134	&& comp->isa(Component::USE) ) {
3135	++position;
3136	if( position != 1 ) --position; // only use two slots for the 1st USE_DEF
3137	}
3138	}
3139
3140	return -1;
3141	}
3142
3143	int ComponentList::method_position() {
3144	PreserveIter pi(this);
3145	int position = 0;
3146	reset();
3147	for( Component *comp; (comp = iter()) != NULL__null; ++position) {
3148	// When the first component is not a DEF,
3149	// leave space for the result operand!
3150	if ( position==0 && (! comp->isa(Component::DEF)) ) {
3151	++position;
3152	}
3153	if (strcmp(comp->_type, "method")==0) {
3154	return position;
3155	}
3156	if( comp->isa(Component::DEF)
3157	&& comp->isa(Component::USE) ) {
3158	++position;
3159	if( position != 1 ) --position; // only use two slots for the 1st USE_DEF
3160	}
3161	}
3162
3163	return -1;
3164	}
3165
3166	void ComponentList::dump() { output(stderrstderr); }
3167
3168	void ComponentList::output(FILE *fp) {
3169	PreserveIter pi(this);
3170	fprintf(fp, "\n");
3171	Component *component;
3172	for (reset(); (component = iter()) != NULL__null;) {
3173	component->output(fp);
3174	}
3175	fprintf(fp, "\n");
3176	}
3177
3178	//------------------------------MatchNode--------------------------------------
3179	MatchNode::MatchNode(ArchDesc &ad, const char result, const char mexpr,
3180	const char opType, MatchNode lChild, MatchNode *rChild)
3181	: _AD(ad), _result(result), _name(mexpr), _opType(opType),
3182	_lChild(lChild), _rChild(rChild), _internalop(0), _numleaves(0),
3183	_commutative_id(0) {
3184	_numleaves = (lChild ? lChild->_numleaves : 0)
3185	+ (rChild ? rChild->_numleaves : 0);
3186	}
3187
3188	MatchNode::MatchNode(ArchDesc &ad, MatchNode& mnode)
3189	: _AD(ad), _result(mnode._result), _name(mnode._name),
3190	_opType(mnode._opType), _lChild(mnode._lChild), _rChild(mnode._rChild),
3191	_internalop(0), _numleaves(mnode._numleaves),
3192	_commutative_id(mnode._commutative_id) {
3193	}
3194
3195	MatchNode::MatchNode(ArchDesc &ad, MatchNode& mnode, int clone)
3196	: _AD(ad), _result(mnode._result), _name(mnode._name),
3197	_opType(mnode._opType),
3198	_internalop(0), _numleaves(mnode._numleaves),
3199	_commutative_id(mnode._commutative_id) {
3200	if (mnode._lChild) {
3201	_lChild = new MatchNode(ad, *mnode._lChild, clone);
3202	} else {
3203	_lChild = NULL__null;
3204	}
3205	if (mnode._rChild) {
3206	_rChild = new MatchNode(ad, *mnode._rChild, clone);
3207	} else {
3208	_rChild = NULL__null;
3209	}
3210	}
3211
3212	MatchNode::~MatchNode() {
3213	// // This node may not own its children if copied via assignment
3214	// if( _lChild ) delete _lChild;
3215	// if( _rChild ) delete _rChild;
3216	}
3217
3218	bool MatchNode::find_type(const char *type, int &position) const {
3219	if ( (_lChild != NULL__null) && (_lChild->find_type(type, position)) ) return true;
3220	if ( (_rChild != NULL__null) && (_rChild->find_type(type, position)) ) return true;
3221
3222	if (strcmp(type,_opType)==0) {
3223	return true;
3224	} else {
3225	++position;
3226	}
3227	return false;
3228	}
3229
3230	// Recursive call collecting info on top-level operands, not transitive.
3231	// Implementation does not modify state of internal structures.
3232	void MatchNode::append_components(FormDict& locals, ComponentList& components,
3233	bool def_flag) const {
3234	int usedef = def_flag ? Component::DEF : Component::USE;
3235	FormDict &globals = _AD.globalNames();
3236
3237	assert (_name != NULL, "MatchNode::build_components encountered empty node\n"){ if (!(_name != __null)) { fprintf(stderr, "assert fails %s %d: %s\n" , "/home/daniel/Projects/java/jdk/src/hotspot/share/adlc/formssel.cpp" , 3237, "MatchNode::build_components encountered empty node\n" ); abort(); }};
3238	// Base case
3239	if (_lChild==NULL__null && _rChild==NULL__null) {
3240	// If _opType is not an operation, do not build a component for it #####
3241	const Form *f = globals[_opType];
3242	if( f != NULL__null ) {
3243	// Add non-ideals that are operands, operand-classes,
3244	if( ! f->ideal_only()
3245	&& (f->is_opclass() \|\| f->is_operand()) ) {
3246	components.insert(_name, _opType, usedef, true);
3247	}
3248	}
3249	return;
3250	}
3251	// Promote results of "Set" to DEF
3252	bool tmpdef_flag = (!strcmp(_opType, "Set")) ? true : false;
3253	if (_lChild) _lChild->append_components(locals, components, tmpdef_flag);
3254	tmpdef_flag = false; // only applies to component immediately following 'Set'
3255	if (_rChild) _rChild->append_components(locals, components, tmpdef_flag);
3256	}
3257
3258	// Find the n'th base-operand in the match node,
3259	// recursively investigates match rules of user-defined operands.
3260	//
3261	// Implementation does not modify state of internal structures since they
3262	// can be shared.
3263	bool MatchNode::base_operand(uintunsigned int &position, FormDict &globals,
3264	const char * &result, const char * &name,
3265	const char * &opType) const {
3266	assert (_name != NULL, "MatchNode::base_operand encountered empty node\n"){ if (!(_name != __null)) { fprintf(stderr, "assert fails %s %d: %s\n" , "/home/daniel/Projects/java/jdk/src/hotspot/share/adlc/formssel.cpp" , 3266, "MatchNode::base_operand encountered empty node\n"); abort (); }};
3267	// Base case
3268	if (_lChild==NULL__null && _rChild==NULL__null) {
3269	// Check for special case: "Universe", "label"
3270	if (strcmp(_opType,"Universe") == 0 \|\| strcmp(_opType,"label")==0 ) {
3271	if (position == 0) {
3272	result = _result;
3273	name = _name;
3274	opType = _opType;
3275	return 1;
3276	} else {
3277	-- position;
3278	return 0;
3279	}
3280	}
3281
3282	const Form *form = globals[_opType];
3283	MatchNode *matchNode = NULL__null;
3284	// Check for user-defined type
3285	if (form) {
3286	// User operand or instruction?
3287	OperandForm *opForm = form->is_operand();
3288	InstructForm *inForm = form->is_instruction();
3289	if ( opForm ) {
3290	matchNode = (MatchNode*)opForm->_matrule;
3291	} else if ( inForm ) {
3292	matchNode = (MatchNode*)inForm->_matrule;
3293	}
3294	}
3295	// if this is user-defined, recurse on match rule
3296	// User-defined operand and instruction forms have a match-rule.
3297	if (matchNode) {
3298	return (matchNode->base_operand(position,globals,result,name,opType));
3299	} else {
3300	// Either not a form, or a system-defined form (no match rule).
3301	if (position==0) {
3302	result = _result;
3303	name = _name;
3304	opType = _opType;
3305	return 1;
3306	} else {
3307	--position;
3308	return 0;
3309	}
3310	}
3311
3312	} else {
3313	// Examine the left child and right child as well
3314	if (_lChild) {
3315	if (_lChild->base_operand(position, globals, result, name, opType))
3316	return 1;
3317	}
3318
3319	if (_rChild) {
3320	if (_rChild->base_operand(position, globals, result, name, opType))
3321	return 1;
3322	}
3323	}
3324
3325	return 0;
3326	}
3327
3328	// Recursive call on all operands' match rules in my match rule.
3329	uintunsigned int MatchNode::num_consts(FormDict &globals) const {
3330	uintunsigned int index = 0;
3331	uintunsigned int num_consts = 0;
3332	const char *result;
3333	const char *name;
3334	const char *opType;
3335
3336	for (uintunsigned int position = index;
3337	base_operand(position,globals,result,name,opType); position = index) {
3338	++index;
3339	if( ideal_to_const_type(opType) ) num_consts++;
3340	}
3341
3342	return num_consts;
3343	}
3344
3345	// Recursive call on all operands' match rules in my match rule.
3346	// Constants in match rule subtree with specified type
3347	uintunsigned int MatchNode::num_consts(FormDict &globals, Form::DataType type) const {
3348	uintunsigned int index = 0;
3349	uintunsigned int num_consts = 0;
3350	const char *result;
3351	const char *name;
3352	const char *opType;
3353
3354	for (uintunsigned int position = index;
3355	base_operand(position,globals,result,name,opType); position = index) {
3356	++index;
3357	if( ideal_to_const_type(opType) == type ) num_consts++;
3358	}
3359
3360	return num_consts;
3361	}
3362
3363	// Recursive call on all operands' match rules in my match rule.
3364	uintunsigned int MatchNode::num_const_ptrs(FormDict &globals) const {
3365	return num_consts( globals, Form::idealP );
3366	}
3367
3368	bool MatchNode::sets_result() const {
3369	return ( (strcmp(_name,"Set") == 0) ? true : false );
3370	}
3371
3372	const char *MatchNode::reduce_right(FormDict &globals) const {
3373	// If there is no right reduction, return NULL.
3374	const char *rightStr = NULL__null;
3375
3376	// If we are a "Set", start from the right child.
3377	const MatchNode *const mnode = sets_result() ?
3378	(const MatchNode *)this->_rChild :
3379	(const MatchNode *)this;
3380
3381	// If our right child exists, it is the right reduction
3382	if ( mnode->_rChild ) {
3383	rightStr = mnode->_rChild->_internalop ? mnode->_rChild->_internalop
3384	: mnode->_rChild->_opType;
3385	}
3386	// Else, May be simple chain rule: (Set dst operand_form), rightStr=NULL;
3387	return rightStr;
3388	}
3389
3390	const char *MatchNode::reduce_left(FormDict &globals) const {
3391	// If there is no left reduction, return NULL.
3392	const char *leftStr = NULL__null;
3393
3394	// If we are a "Set", start from the right child.
3395	const MatchNode *const mnode = sets_result() ?
3396	(const MatchNode *)this->_rChild :
3397	(const MatchNode *)this;
3398
3399	// If our left child exists, it is the left reduction
3400	if ( mnode->_lChild ) {
3401	leftStr = mnode->_lChild->_internalop ? mnode->_lChild->_internalop
3402	: mnode->_lChild->_opType;
3403	} else {
3404	// May be simple chain rule: (Set dst operand_form_source)
3405	if ( sets_result() ) {
3406	OperandForm *oper = globals[mnode->_opType]->is_operand();
3407	if( oper ) {
3408	leftStr = mnode->_opType;
3409	}
3410	}
3411	}
3412	return leftStr;
3413	}
3414
3415	//------------------------------count_instr_names------------------------------
3416	// Count occurrences of operands names in the leaves of the instruction
3417	// match rule.
3418	void MatchNode::count_instr_names( Dict &names ) {
3419	if( _lChild ) _lChild->count_instr_names(names);
3420	if( _rChild ) _rChild->count_instr_names(names);
3421	if( !_lChild && !_rChild ) {
3422	uintptr_t cnt = (uintptr_t)names[_name];
3423	cnt++; // One more name found
3424	names.Insert(_name,(void*)cnt);
3425	}
3426	}
3427
3428	//------------------------------build_instr_pred-------------------------------
3429	// Build a path to 'name' in buf. Actually only build if cnt is zero, so we
3430	// can skip some leading instances of 'name'.
3431	int MatchNode::build_instr_pred( char buf, const char name, int cnt, int path_bitmask, int level) {
3432	if( _lChild ) {
3433	cnt = _lChild->build_instr_pred(buf, name, cnt, path_bitmask, level+1);
3434	if( cnt < 0 ) {
3435	return cnt; // Found it, all done
3436	}
3437	}
3438	if( _rChild ) {
3439	path_bitmask \|= 1 << level;
3440	cnt = _rChild->build_instr_pred( buf, name, cnt, path_bitmask, level+1);
3441	if( cnt < 0 ) {
3442	return cnt; // Found it, all done
3443	}
3444	}
3445	if( !_lChild && !_rChild ) { // Found a leaf
3446	// Wrong name? Give up...
3447	if( strcmp(name,_name) ) return cnt;
3448	if( !cnt ) {
3449	for(int i = 0; i < level; i++) {
3450	int kid = path_bitmask & (1 << i);
3451	if (0 == kid) {
3452	strcpy( buf, "_kids[0]->" );
3453	} else {
3454	strcpy( buf, "_kids[1]->" );
3455	}
3456	buf += 10;
3457	}
3458	strcpy( buf, "_leaf" );
3459	}
3460	return cnt-1;
3461	}
3462	return cnt;
3463	}
3464
3465
3466	//------------------------------build_internalop-------------------------------
3467	// Build string representation of subtree
3468	void MatchNode::build_internalop( ) {
3469	char iop, subtree;
3470	const char lstr, rstr;
3471	// Build string representation of subtree
3472	// Operation lchildType rchildType
3473	int len = (int)strlen(_opType) + 4;
3474	lstr = (_lChild) ? ((_lChild->_internalop) ?
3475	_lChild->_internalop : _lChild->_opType) : "";
3476	rstr = (_rChild) ? ((_rChild->_internalop) ?
3477	_rChild->_internalop : _rChild->_opType) : "";
3478	len += (int)strlen(lstr) + (int)strlen(rstr);
3479	subtree = (char *)AllocateHeap(len);
3480	sprintf(subtree,"_%s_%s_%s", _opType, lstr, rstr);
3481	// Hash the subtree string in _internalOps; if a name exists, use it
3482	iop = (char *)_AD._internalOps[subtree];
3483	// Else create a unique name, and add it to the hash table
3484	if (iop == NULL__null) {
3485	iop = subtree;
3486	_AD._internalOps.Insert(subtree, iop);
3487	_AD._internalOpNames.addName(iop);
3488	_AD._internalMatch.Insert(iop, this);
3489	}
3490	// Add the internal operand name to the MatchNode
3491	_internalop = iop;
3492	_result = iop;
3493	}
3494
3495
3496	void MatchNode::dump() {
3497	output(stderrstderr);
3498	}
3499
3500	void MatchNode::output(FILE *fp) {
3501	if (_lChild==0 && _rChild==0) {
3502	fprintf(fp," %s",_name); // operand
3503	}
3504	else {
3505	fprintf(fp," (%s ",_name); // " (opcodeName "
3506	if(_lChild) _lChild->output(fp); // left operand
3507	if(_rChild) _rChild->output(fp); // right operand
3508	fprintf(fp,")"); // ")"
3509	}
3510	}
3511
3512	int MatchNode::needs_ideal_memory_edge(FormDict &globals) const {
3513	static const char *needs_ideal_memory_list[] = {
3514	"StoreI","StoreL","StoreP","StoreN","StoreNKlass","StoreD","StoreF" ,
3515	"StoreB","StoreC","Store" ,"StoreFP",
3516	"LoadI", "LoadL", "LoadP" ,"LoadN", "LoadD" ,"LoadF" ,
3517	"LoadB" , "LoadUB", "LoadUS" ,"LoadS" ,"Load" ,
3518	"StoreVector", "LoadVector", "LoadVectorMasked", "StoreVectorMasked",
3519	"LoadVectorGather", "StoreVectorScatter", "LoadVectorGatherMasked", "StoreVectorScatterMasked",
3520	"LoadRange", "LoadKlass", "LoadNKlass", "LoadL_unaligned", "LoadD_unaligned",
3521	"LoadPLocked",
3522	"StorePConditional", "StoreIConditional", "StoreLConditional",
3523	"CompareAndSwapB", "CompareAndSwapS", "CompareAndSwapI", "CompareAndSwapL", "CompareAndSwapP", "CompareAndSwapN",
3524	"WeakCompareAndSwapB", "WeakCompareAndSwapS", "WeakCompareAndSwapI", "WeakCompareAndSwapL", "WeakCompareAndSwapP", "WeakCompareAndSwapN",
3525	"CompareAndExchangeB", "CompareAndExchangeS", "CompareAndExchangeI", "CompareAndExchangeL", "CompareAndExchangeP", "CompareAndExchangeN",
3526	#if INCLUDE_SHENANDOAHGC1
3527	"ShenandoahCompareAndSwapN", "ShenandoahCompareAndSwapP", "ShenandoahWeakCompareAndSwapP", "ShenandoahWeakCompareAndSwapN", "ShenandoahCompareAndExchangeP", "ShenandoahCompareAndExchangeN",
3528	#endif
3529	"StoreCM",
3530	"GetAndSetB", "GetAndSetS", "GetAndAddI", "GetAndSetI", "GetAndSetP",
3531	"GetAndAddB", "GetAndAddS", "GetAndAddL", "GetAndSetL", "GetAndSetN",
3532	"ClearArray"
3533	};
3534	int cnt = sizeof(needs_ideal_memory_list)/sizeof(char*);
3535	if( strcmp(_opType,"PrefetchAllocation")==0 )
3536	return 1;
3537	if( strcmp(_opType,"CacheWB")==0 )
3538	return 1;
3539	if( strcmp(_opType,"CacheWBPreSync")==0 )
3540	return 1;
3541	if( strcmp(_opType,"CacheWBPostSync")==0 )
3542	return 1;
3543	if( _lChild ) {
3544	const char *opType = _lChild->_opType;
3545	for( int i=0; i<cnt; i++ )
3546	if( strcmp(opType,needs_ideal_memory_list[i]) == 0 )
3547	return 1;
3548	if( _lChild->needs_ideal_memory_edge(globals) )
3549	return 1;
3550	}
3551	if( _rChild ) {
3552	const char *opType = _rChild->_opType;
3553	for( int i=0; i<cnt; i++ )
3554	if( strcmp(opType,needs_ideal_memory_list[i]) == 0 )
3555	return 1;
3556	if( _rChild->needs_ideal_memory_edge(globals) )
3557	return 1;
3558	}
3559
3560	return 0;
3561	}
3562
3563	// TRUE if defines a derived oop, and so needs a base oop edge present
3564	// post-matching.
3565	int MatchNode::needs_base_oop_edge() const {
3566	if( !strcmp(_opType,"AddP") ) return 1;
3567	if( strcmp(_opType,"Set") ) return 0;
3568	return !strcmp(_rChild->_opType,"AddP");
3569	}
3570
3571	int InstructForm::needs_base_oop_edge(FormDict &globals) const {
3572	if( is_simple_chain_rule(globals) ) {
3573	const char *src = _matrule->_rChild->_opType;
3574	OperandForm *src_op = globals[src]->is_operand();
3575	assert( src_op, "Not operand class of chain rule" ){ if (!(src_op)) { fprintf(stderr, "assert fails %s %d: %s\n" , "/home/daniel/Projects/java/jdk/src/hotspot/share/adlc/formssel.cpp" , 3575, "Not operand class of chain rule"); abort(); }};
3576	return src_op->_matrule ? src_op->_matrule->needs_base_oop_edge() : 0;
3577	} // Else check instruction
3578
3579	return _matrule ? _matrule->needs_base_oop_edge() : 0;
3580	}
3581
3582
3583	//-------------------------cisc spilling methods-------------------------------
3584	// helper routines and methods for detecting cisc-spilling instructions
3585	//-------------------------cisc_spill_merge------------------------------------
3586	int MatchNode::cisc_spill_merge(int left_spillable, int right_spillable) {
3587	int cisc_spillable = Maybe_cisc_spillable;
3588
3589	// Combine results of left and right checks
3590	if( (left_spillable == Maybe_cisc_spillable) && (right_spillable == Maybe_cisc_spillable) ) {
3591	// neither side is spillable, nor prevents cisc spilling
3592	cisc_spillable = Maybe_cisc_spillable;
3593	}
3594	else if( (left_spillable == Maybe_cisc_spillable) && (right_spillable > Maybe_cisc_spillable) ) {
3595	// right side is spillable
3596	cisc_spillable = right_spillable;
3597	}
3598	else if( (right_spillable == Maybe_cisc_spillable) && (left_spillable > Maybe_cisc_spillable) ) {
3599	// left side is spillable
3600	cisc_spillable = left_spillable;
3601	}
3602	else if( (left_spillable == Not_cisc_spillable) \|\| (right_spillable == Not_cisc_spillable) ) {
3603	// left or right prevents cisc spilling this instruction
3604	cisc_spillable = Not_cisc_spillable;
3605	}
3606	else {
3607	// Only allow one to spill
3608	cisc_spillable = Not_cisc_spillable;
3609	}
3610
3611	return cisc_spillable;
3612	}
3613
3614	//-------------------------root_ops_match--------------------------------------
3615	bool static root_ops_match(FormDict &globals, const char op1, const char op2) {
3616	// Base Case: check that the current operands/operations match
3617	assert( op1, "Must have op's name"){ if (!(op1)) { fprintf(stderr, "assert fails %s %d: %s\n", "/home/daniel/Projects/java/jdk/src/hotspot/share/adlc/formssel.cpp" , 3617, "Must have op's name"); abort(); }};
3618	assert( op2, "Must have op's name"){ if (!(op2)) { fprintf(stderr, "assert fails %s %d: %s\n", "/home/daniel/Projects/java/jdk/src/hotspot/share/adlc/formssel.cpp" , 3618, "Must have op's name"); abort(); }};
3619	const Form *form1 = globals[op1];
3620	const Form *form2 = globals[op2];
3621
3622	return (form1 == form2);
3623	}
3624
3625	//-------------------------cisc_spill_match_node-------------------------------
3626	// Recursively check two MatchRules for legal conversion via cisc-spilling
3627	int MatchNode::cisc_spill_match(FormDict& globals, RegisterForm* registers, MatchNode* mRule2, const char* &operand, const char* &reg_type) {
3628	int cisc_spillable = Maybe_cisc_spillable;
3629	int left_spillable = Maybe_cisc_spillable;
3630	int right_spillable = Maybe_cisc_spillable;
3631
3632	// Check that each has same number of operands at this level
3633	if( (_lChild && !(mRule2->_lChild)) \|\| (_rChild && !(mRule2->_rChild)) )
3634	return Not_cisc_spillable;
3635
3636	// Base Case: check that the current operands/operations match
3637	// or are CISC spillable
3638	assert( _opType, "Must have _opType"){ if (!(_opType)) { fprintf(stderr, "assert fails %s %d: %s\n" , "/home/daniel/Projects/java/jdk/src/hotspot/share/adlc/formssel.cpp" , 3638, "Must have _opType"); abort(); }};
3639	assert( mRule2->_opType, "Must have _opType"){ if (!(mRule2->_opType)) { fprintf(stderr, "assert fails %s %d: %s\n" , "/home/daniel/Projects/java/jdk/src/hotspot/share/adlc/formssel.cpp" , 3639, "Must have _opType"); abort(); }};
3640	const Form *form = globals[_opType];
3641	const Form *form2 = globals[mRule2->_opType];
3642	if( form == form2 ) {
3643	cisc_spillable = Maybe_cisc_spillable;
3644	} else {
3645	const InstructForm *form2_inst = form2 ? form2->is_instruction() : NULL__null;
3646	const char *name_left = mRule2->_lChild ? mRule2->_lChild->_opType : NULL__null;
3647	const char *name_right = mRule2->_rChild ? mRule2->_rChild->_opType : NULL__null;
3648	DataType data_type = Form::none;
3649	if (form->is_operand()) {
3650	// Make sure the loadX matches the type of the reg
3651	data_type = form->ideal_to_Reg_type(form->is_operand()->ideal_type(globals));
3652	}
3653	// Detect reg vs (loadX memory)
3654	if( form->is_cisc_reg(globals)
3655	&& form2_inst
3656	&& data_type != Form::none
3657	&& (is_load_from_memory(mRule2->_opType) == data_type) // reg vs. (load memory)
3658	&& (name_left != NULL__null) // NOT (load)
3659	&& (name_right == NULL__null) ) { // NOT (load memory foo)
3660	const Form *form2_left = globals[name_left];
3661	if( form2_left && form2_left->is_cisc_mem(globals) ) {
3662	cisc_spillable = Is_cisc_spillable;
3663	operand = _name;
3664	reg_type = _result;
3665	return Is_cisc_spillable;
3666	} else {
3667	cisc_spillable = Not_cisc_spillable;
3668	}
3669	}
3670	// Detect reg vs memory
3671	else if (form->is_cisc_reg(globals) && form2 != NULL__null && form2->is_cisc_mem(globals)) {
3672	cisc_spillable = Is_cisc_spillable;
3673	operand = _name;
3674	reg_type = _result;
3675	return Is_cisc_spillable;
3676	} else {
3677	cisc_spillable = Not_cisc_spillable;
3678	}
3679	}
3680
3681	// If cisc is still possible, check rest of tree
3682	if( cisc_spillable == Maybe_cisc_spillable ) {
3683	// Check that each has same number of operands at this level
3684	if( (_lChild && !(mRule2->_lChild)) \|\| (_rChild && !(mRule2->_rChild)) ) return Not_cisc_spillable;
3685
3686	// Check left operands
3687	if( (_lChild == NULL__null) && (mRule2->_lChild == NULL__null) ) {
3688	left_spillable = Maybe_cisc_spillable;
3689	} else if (_lChild != NULL__null) {
3690	left_spillable = _lChild->cisc_spill_match(globals, registers, mRule2->_lChild, operand, reg_type);
3691	}
3692
3693	// Check right operands
3694	if( (_rChild == NULL__null) && (mRule2->_rChild == NULL__null) ) {
3695	right_spillable = Maybe_cisc_spillable;
3696	} else if (_rChild != NULL__null) {
3697	right_spillable = _rChild->cisc_spill_match(globals, registers, mRule2->_rChild, operand, reg_type);
3698	}
3699
3700	// Combine results of left and right checks
3701	cisc_spillable = cisc_spill_merge(left_spillable, right_spillable);
3702	}
3703
3704	return cisc_spillable;
3705	}
3706
3707	//---------------------------cisc_spill_match_rule------------------------------
3708	// Recursively check two MatchRules for legal conversion via cisc-spilling
3709	// This method handles the root of Match tree,
3710	// general recursive checks done in MatchNode
3711	int MatchRule::matchrule_cisc_spill_match(FormDict& globals, RegisterForm* registers,
3712	MatchRule* mRule2, const char* &operand,
3713	const char* &reg_type) {
3714	int cisc_spillable = Maybe_cisc_spillable;
3715	int left_spillable = Maybe_cisc_spillable;
3716	int right_spillable = Maybe_cisc_spillable;
3717
3718	// Check that each sets a result
3719	if( !(sets_result() && mRule2->sets_result()) ) return Not_cisc_spillable;
3720	// Check that each has same number of operands at this level
3721	if( (_lChild && !(mRule2->_lChild)) \|\| (_rChild && !(mRule2->_rChild)) ) return Not_cisc_spillable;
3722
3723	// Check left operands: at root, must be target of 'Set'
3724	if( (_lChild == NULL__null) \|\| (mRule2->_lChild == NULL__null) ) {
3725	left_spillable = Not_cisc_spillable;
3726	} else {
3727	// Do not support cisc-spilling instruction's target location
3728	if( root_ops_match(globals, _lChild->_opType, mRule2->_lChild->_opType) ) {
3729	left_spillable = Maybe_cisc_spillable;
3730	} else {
3731	left_spillable = Not_cisc_spillable;
3732	}
3733	}
3734
3735	// Check right operands: recursive walk to identify reg->mem operand
3736	if (_rChild == NULL__null) {
3737	if (mRule2->_rChild == NULL__null) {
3738	right_spillable = Maybe_cisc_spillable;
3739	} else {
3740	assert(0, "_rChild should not be NULL"){ if (!(0)) { fprintf(stderr, "assert fails %s %d: %s\n", "/home/daniel/Projects/java/jdk/src/hotspot/share/adlc/formssel.cpp" , 3740, "_rChild should not be NULL"); abort(); }};
3741	}
3742	} else {
3743	right_spillable = _rChild->cisc_spill_match(globals, registers, mRule2->_rChild, operand, reg_type);
3744	}
3745
3746	// Combine results of left and right checks
3747	cisc_spillable = cisc_spill_merge(left_spillable, right_spillable);
3748
3749	return cisc_spillable;
3750	}
3751
3752	//----------------------------- equivalent ------------------------------------
3753	// Recursively check to see if two match rules are equivalent.
3754	// This rule handles the root.
3755	bool MatchRule::equivalent(FormDict &globals, MatchNode *mRule2) {
3756	// Check that each sets a result
3757	if (sets_result() != mRule2->sets_result()) {
3758	return false;
3759	}
3760
3761	// Check that the current operands/operations match
3762	assert( _opType, "Must have _opType"){ if (!(_opType)) { fprintf(stderr, "assert fails %s %d: %s\n" , "/home/daniel/Projects/java/jdk/src/hotspot/share/adlc/formssel.cpp" , 3762, "Must have _opType"); abort(); }};
3763	assert( mRule2->_opType, "Must have _opType"){ if (!(mRule2->_opType)) { fprintf(stderr, "assert fails %s %d: %s\n" , "/home/daniel/Projects/java/jdk/src/hotspot/share/adlc/formssel.cpp" , 3763, "Must have _opType"); abort(); }};
3764	const Form *form = globals[_opType];
3765	const Form *form2 = globals[mRule2->_opType];
3766	if( form != form2 ) {
3767	return false;
3768	}
3769
3770	if (_lChild ) {
3771	if( !_lChild->equivalent(globals, mRule2->_lChild) )
3772	return false;
3773	} else if (mRule2->_lChild) {
3774	return false; // I have NULL left child, mRule2 has non-NULL left child.
3775	}
3776
3777	if (_rChild ) {
3778	if( !_rChild->equivalent(globals, mRule2->_rChild) )
3779	return false;
3780	} else if (mRule2->_rChild) {
3781	return false; // I have NULL right child, mRule2 has non-NULL right child.
3782	}
3783
3784	// We've made it through the gauntlet.
3785	return true;
3786	}
3787
3788	//----------------------------- equivalent ------------------------------------
3789	// Recursively check to see if two match rules are equivalent.
3790	// This rule handles the operands.
3791	bool MatchNode::equivalent(FormDict &globals, MatchNode *mNode2) {
3792	if( !mNode2 )
3793	return false;
3794
3795	// Check that the current operands/operations match
3796	assert( _opType, "Must have _opType"){ if (!(_opType)) { fprintf(stderr, "assert fails %s %d: %s\n" , "/home/daniel/Projects/java/jdk/src/hotspot/share/adlc/formssel.cpp" , 3796, "Must have _opType"); abort(); }};
3797	assert( mNode2->_opType, "Must have _opType"){ if (!(mNode2->_opType)) { fprintf(stderr, "assert fails %s %d: %s\n" , "/home/daniel/Projects/java/jdk/src/hotspot/share/adlc/formssel.cpp" , 3797, "Must have _opType"); abort(); }};
3798	const Form *form = globals[_opType];
3799	const Form *form2 = globals[mNode2->_opType];
3800	if( form != form2 ) {
3801	return false;
3802	}
3803
3804	// Check that their children also match
3805	if (_lChild ) {
3806	if( !_lChild->equivalent(globals, mNode2->_lChild) )
3807	return false;
3808	} else if (mNode2->_lChild) {
3809	return false; // I have NULL left child, mNode2 has non-NULL left child.
3810	}
3811
3812	if (_rChild ) {
3813	if( !_rChild->equivalent(globals, mNode2->_rChild) )
3814	return false;
3815	} else if (mNode2->_rChild) {
3816	return false; // I have NULL right child, mNode2 has non-NULL right child.
3817	}
3818
3819	// We've made it through the gauntlet.
3820	return true;
3821	}
3822
3823	//-------------------------- count_commutative_op -------------------------------
3824	// Recursively check for commutative operations with subtree operands
3825	// which could be swapped.
3826	void MatchNode::count_commutative_op(int& count) {
3827	static const char *commut_op_list[] = {
3828	"AddI","AddL","AddF","AddD",
3829	"AndI","AndL",
3830	"MaxI","MinI","MaxF","MinF","MaxD","MinD",
3831	"MulI","MulL","MulF","MulD",
3832	"OrI","OrL",
3833	"XorI","XorL"
3834	};
3835
3836	static const char *commut_vector_op_list[] = {
3837	"AddVB", "AddVS", "AddVI", "AddVL", "AddVF", "AddVD",
3838	"MulVB", "MulVS", "MulVI", "MulVL", "MulVF", "MulVD",
3839	"AndV", "OrV", "XorV",
3840	"MaxV", "MinV"
3841	};
3842
3843	if (_lChild && _rChild && (_lChild->_lChild \|\| _rChild->_lChild)) {
3844	// Don't swap if right operand is an immediate constant.
3845	bool is_const = false;
3846	if (_rChild->_lChild == NULL__null && _rChild->_rChild == NULL__null) {
3847	FormDict &globals = _AD.globalNames();
3848	const Form *form = globals[_rChild->_opType];
3849	if (form) {
3850	OperandForm *oper = form->is_operand();
3851	if (oper && oper->interface_type(globals) == Form::constant_interface)
3852	is_const = true;
3853	}
3854	}
3855
3856	if (!is_const) {
3857	int scalar_cnt = sizeof(commut_op_list)/sizeof(char*);
3858	int vector_cnt = sizeof(commut_vector_op_list)/sizeof(char*);
3859	bool matched = false;
3860
3861	// Check the commutative vector op first. It's noncommutative if
3862	// the current node is a masked vector op, since a mask value
3863	// is added to the original vector node's input list and the original
3864	// first two inputs are packed into one BinaryNode. So don't swap
3865	// if one of the operands is a BinaryNode.
3866	for (int i = 0; i < vector_cnt; i++) {
3867	if (strcmp(_opType, commut_vector_op_list[i]) == 0) {
3868	if (strcmp(_lChild->_opType, "Binary") != 0 &&
3869	strcmp(_rChild->_opType, "Binary") != 0) {
3870	count++;
3871	_commutative_id = count; // id should be > 0
3872	}
3873	matched = true;
3874	break;
3875	}
3876	}
3877
3878	// Then check the scalar op if the current op is not in
3879	// the commut_vector_op_list.
3880	if (!matched) {
3881	for (int i = 0; i < scalar_cnt; i++) {
3882	if (strcmp(_opType, commut_op_list[i]) == 0) {
3883	count++;
3884	_commutative_id = count; // id should be > 0
3885	break;
3886	}
3887	}
3888	}
3889	}
3890	}
3891	if (_lChild)
3892	_lChild->count_commutative_op(count);
3893	if (_rChild)
3894	_rChild->count_commutative_op(count);
3895	}
3896
3897	//-------------------------- swap_commutative_op ------------------------------
3898	// Recursively swap specified commutative operation with subtree operands.
3899	void MatchNode::swap_commutative_op(bool atroot, int id) {
3900	if( _commutative_id == id ) { // id should be > 0
3901	assert(_lChild && _rChild && (_lChild->_lChild \|\| _rChild->_lChild ),{ if (!(_lChild && _rChild && (_lChild->_lChild \|\| _rChild->_lChild ))) { fprintf(stderr, "assert fails %s %d: %s\n" , "/home/daniel/Projects/java/jdk/src/hotspot/share/adlc/formssel.cpp" , 3902, "not swappable operation"); abort(); }}
3902	"not swappable operation"){ if (!(_lChild && _rChild && (_lChild->_lChild \|\| _rChild->_lChild ))) { fprintf(stderr, "assert fails %s %d: %s\n" , "/home/daniel/Projects/java/jdk/src/hotspot/share/adlc/formssel.cpp" , 3902, "not swappable operation"); abort(); }};
3903	MatchNode* tmp = _lChild;
3904	_lChild = _rChild;
3905	_rChild = tmp;
3906	// Don't exit here since we need to build internalop.
3907	}
3908
3909	bool is_set = ( strcmp(_opType, "Set") == 0 );
3910	if( _lChild )
3911	_lChild->swap_commutative_op(is_set, id);
3912	if( _rChild )
3913	_rChild->swap_commutative_op(is_set, id);
3914
3915	// If not the root, reduce this subtree to an internal operand
3916	if( !atroot && (_lChild \|\| _rChild) ) {
3917	build_internalop();
3918	}
3919	}
3920
3921	//-------------------------- swap_commutative_op ------------------------------
3922	// Recursively swap specified commutative operation with subtree operands.
3923	void MatchRule::matchrule_swap_commutative_op(const char* instr_ident, int count, int& match_rules_cnt) {
3924	assert(match_rules_cnt < 100," too many match rule clones"){ if (!(match_rules_cnt < 100)) { fprintf(stderr, "assert fails %s %d: %s\n" , "/home/daniel/Projects/java/jdk/src/hotspot/share/adlc/formssel.cpp" , 3924, " too many match rule clones"); abort(); }};
3925	// Clone
3926	MatchRule* clone = new MatchRule(_AD, this);
3927	// Swap operands of commutative operation
3928	((MatchNode*)clone)->swap_commutative_op(true, count);
3929	char* buf = (char*) AllocateHeap(strlen(instr_ident) + 4);
3930	sprintf(buf, "%s_%d", instr_ident, match_rules_cnt++);
3931	clone->_result = buf;
3932
3933	clone->_next = this->_next;
3934	this-> _next = clone;
3935	if( (--count) > 0 ) {
3936	this-> matchrule_swap_commutative_op(instr_ident, count, match_rules_cnt);
3937	clone->matchrule_swap_commutative_op(instr_ident, count, match_rules_cnt);
3938	}
3939	}
3940
3941	//------------------------------MatchRule--------------------------------------
3942	MatchRule::MatchRule(ArchDesc &ad)
3943	: MatchNode(ad), _depth(0), _construct(NULL__null), _numchilds(0) {
3944	_next = NULL__null;
3945	}
3946
3947	MatchRule::MatchRule(ArchDesc &ad, MatchRule* mRule)
3948	: MatchNode(ad, *mRule, 0), _depth(mRule->_depth),
3949	_construct(mRule->_construct), _numchilds(mRule->_numchilds) {
3950	_next = NULL__null;
3951	}
3952
3953	MatchRule::MatchRule(ArchDesc &ad, MatchNode* mroot, int depth, char *cnstr,
3954	int numleaves)
3955	: MatchNode(ad,*mroot), _depth(depth), _construct(cnstr),
3956	_numchilds(0) {
3957	_next = NULL__null;
3958	mroot->_lChild = NULL__null;
3959	mroot->_rChild = NULL__null;
3960	delete mroot;
3961	_numleaves = numleaves;
3962	_numchilds = (_lChild ? 1 : 0) + (_rChild ? 1 : 0);
3963	}
3964	MatchRule::~MatchRule() {
3965	}
3966
3967	// Recursive call collecting info on top-level operands, not transitive.
3968	// Implementation does not modify state of internal structures.
3969	void MatchRule::append_components(FormDict& locals, ComponentList& components, bool def_flag) const {
3970	assert (_name != NULL, "MatchNode::build_components encountered empty node\n"){ if (!(_name != __null)) { fprintf(stderr, "assert fails %s %d: %s\n" , "/home/daniel/Projects/java/jdk/src/hotspot/share/adlc/formssel.cpp" , 3970, "MatchNode::build_components encountered empty node\n" ); abort(); }};
3971
3972	MatchNode::append_components(locals, components,
3973	false /* not necessarily a def */);
3974	}
3975
3976	// Recursive call on all operands' match rules in my match rule.
3977	// Implementation does not modify state of internal structures since they
3978	// can be shared.
3979	// The MatchNode that is called first treats its
3980	bool MatchRule::base_operand(uintunsigned int &position0, FormDict &globals,
3981	const char &result, const char &name,
3982	const char * &opType)const{
3983	uintunsigned int position = position0;
3984
3985	return (MatchNode::base_operand( position, globals, result, name, opType));
3986	}
3987
3988
3989	bool MatchRule::is_base_register(FormDict &globals) const {
3990	uintunsigned int position = 1;
3991	const char *result = NULL__null;
3992	const char *name = NULL__null;
3993	const char *opType = NULL__null;
3994	if (!base_operand(position, globals, result, name, opType)) {
3995	position = 0;
3996	if( base_operand(position, globals, result, name, opType) &&
3997	(strcmp(opType,"RegI")==0 \|\|
3998	strcmp(opType,"RegP")==0 \|\|
3999	strcmp(opType,"RegN")==0 \|\|
4000	strcmp(opType,"RegL")==0 \|\|
4001	strcmp(opType,"RegF")==0 \|\|
4002	strcmp(opType,"RegD")==0 \|\|
4003	strcmp(opType,"RegVectMask")==0 \|\|
4004	strcmp(opType,"VecA")==0 \|\|
4005	strcmp(opType,"VecS")==0 \|\|
4006	strcmp(opType,"VecD")==0 \|\|
4007	strcmp(opType,"VecX")==0 \|\|
4008	strcmp(opType,"VecY")==0 \|\|
4009	strcmp(opType,"VecZ")==0 \|\|
4010	strcmp(opType,"Reg" )==0) ) {
4011	return 1;
4012	}
4013	}
4014	return 0;
4015	}
4016
4017	Form::DataType MatchRule::is_base_constant(FormDict &globals) const {
4018	uintunsigned int position = 1;
4019	const char *result = NULL__null;
4020	const char *name = NULL__null;
4021	const char *opType = NULL__null;
4022	if (!base_operand(position, globals, result, name, opType)) {
4023	position = 0;
4024	if (base_operand(position, globals, result, name, opType)) {
4025	return ideal_to_const_type(opType);
4026	}
4027	}
4028	return Form::none;
4029	}
4030
4031	bool MatchRule::is_chain_rule(FormDict &globals) const {
4032
4033	// Check for chain rule, and do not generate a match list for it
4034	if ((_lChild == NULL__null) && (_rChild == NULL__null) ) {
4035	const Form *form = globals[_opType];
4036	// If this is ideal, then it is a base match, not a chain rule.
4037	if ( form && form->is_operand() && (!form->ideal_only())) {
4038	return true;
4039	}
4040	}
4041	// Check for "Set" form of chain rule, and do not generate a match list
4042	if (_rChild) {
4043	const char *rch = _rChild->_opType;
4044	const Form *form = globals[rch];
4045	if ((!strcmp(_opType,"Set") &&
4046	((form) && form->is_operand()))) {
4047	return true;
4048	}
4049	}
4050	return false;
4051	}
4052
4053	int MatchRule::is_ideal_copy() const {
4054	if (is_chain_rule(_AD.globalNames()) &&
4055	_lChild && strncmp(_lChild->_opType, "stackSlot", 9) == 0) {
4056	return 1;
4057	}
4058	return 0;
4059	}
4060
4061	int MatchRule::is_expensive() const {
4062	if( _rChild ) {
4063	const char *opType = _rChild->_opType;
4064	if( strcmp(opType,"AtanD")==0 \|\|
4065	strcmp(opType,"DivD")==0 \|\|
4066	strcmp(opType,"DivF")==0 \|\|
4067	strcmp(opType,"DivI")==0 \|\|
4068	strcmp(opType,"Log10D")==0 \|\|
4069	strcmp(opType,"ModD")==0 \|\|
4070	strcmp(opType,"ModF")==0 \|\|
4071	strcmp(opType,"ModI")==0 \|\|
4072	strcmp(opType,"SqrtD")==0 \|\|
4073	strcmp(opType,"SqrtF")==0 \|\|
4074	strcmp(opType,"TanD")==0 \|\|
4075	strcmp(opType,"ConvD2F")==0 \|\|
4076	strcmp(opType,"ConvD2I")==0 \|\|
4077	strcmp(opType,"ConvD2L")==0 \|\|
4078	strcmp(opType,"ConvF2D")==0 \|\|
4079	strcmp(opType,"ConvF2I")==0 \|\|
4080	strcmp(opType,"ConvF2L")==0 \|\|
4081	strcmp(opType,"ConvI2D")==0 \|\|
4082	strcmp(opType,"ConvI2F")==0 \|\|
4083	strcmp(opType,"ConvI2L")==0 \|\|
4084	strcmp(opType,"ConvL2D")==0 \|\|
4085	strcmp(opType,"ConvL2F")==0 \|\|
4086	strcmp(opType,"ConvL2I")==0 \|\|
4087	strcmp(opType,"DecodeN")==0 \|\|
4088	strcmp(opType,"EncodeP")==0 \|\|
4089	strcmp(opType,"EncodePKlass")==0 \|\|
4090	strcmp(opType,"DecodeNKlass")==0 \|\|
4091	strcmp(opType,"FmaD") == 0 \|\|
4092	strcmp(opType,"FmaF") == 0 \|\|
4093	strcmp(opType,"RoundDouble")==0 \|\|
4094	strcmp(opType,"RoundDoubleMode")==0 \|\|
4095	strcmp(opType,"RoundFloat")==0 \|\|
4096	strcmp(opType,"ReverseBytesI")==0 \|\|
4097	strcmp(opType,"ReverseBytesL")==0 \|\|
4098	strcmp(opType,"ReverseBytesUS")==0 \|\|
4099	strcmp(opType,"ReverseBytesS")==0 \|\|
4100	strcmp(opType,"ReplicateB")==0 \|\|
4101	strcmp(opType,"ReplicateS")==0 \|\|
4102	strcmp(opType,"ReplicateI")==0 \|\|
4103	strcmp(opType,"ReplicateL")==0 \|\|
4104	strcmp(opType,"ReplicateF")==0 \|\|
4105	strcmp(opType,"ReplicateD")==0 \|\|
4106	strcmp(opType,"AddReductionVI")==0 \|\|
4107	strcmp(opType,"AddReductionVL")==0 \|\|
4108	strcmp(opType,"AddReductionVF")==0 \|\|
4109	strcmp(opType,"AddReductionVD")==0 \|\|
4110	strcmp(opType,"MulReductionVI")==0 \|\|
4111	strcmp(opType,"MulReductionVL")==0 \|\|
4112	strcmp(opType,"MulReductionVF")==0 \|\|
4113	strcmp(opType,"MulReductionVD")==0 \|\|
4114	strcmp(opType,"MinReductionV")==0 \|\|
4115	strcmp(opType,"MaxReductionV")==0 \|\|
4116	strcmp(opType,"AndReductionV")==0 \|\|
4117	strcmp(opType,"OrReductionV")==0 \|\|
4118	strcmp(opType,"XorReductionV")==0 \|\|
4119	strcmp(opType,"MaskAll")==0 \|\|
4120	0 /* 0 to line up columns nicely */ )
4121	return 1;
4122	}
4123	return 0;
4124	}
4125
4126	bool MatchRule::is_ideal_if() const {
4127	if( !_opType ) return false;
4128	return
4129	!strcmp(_opType,"If" ) \|\|
4130	!strcmp(_opType,"CountedLoopEnd");
4131	}
4132
4133	bool MatchRule::is_ideal_fastlock() const {
4134	if ( _opType && (strcmp(_opType,"Set") == 0) && _rChild ) {
4135	return (strcmp(_rChild->_opType,"FastLock") == 0);
4136	}
4137	return false;
4138	}
4139
4140	bool MatchRule::is_ideal_membar() const {
4141	if( !_opType ) return false;
4142	return
4143	!strcmp(_opType,"MemBarAcquire") \|\|
4144	!strcmp(_opType,"MemBarRelease") \|\|
4145	!strcmp(_opType,"MemBarAcquireLock") \|\|
4146	!strcmp(_opType,"MemBarReleaseLock") \|\|
4147	!strcmp(_opType,"LoadFence" ) \|\|
4148	!strcmp(_opType,"StoreFence") \|\|
4149	!strcmp(_opType,"StoreStoreFence") \|\|
4150	!strcmp(_opType,"MemBarVolatile") \|\|
4151	!strcmp(_opType,"MemBarCPUOrder") \|\|
4152	!strcmp(_opType,"MemBarStoreStore") \|\|
4153	!strcmp(_opType,"OnSpinWait");
4154	}
4155
4156	bool MatchRule::is_ideal_loadPC() const {
4157	if ( _opType && (strcmp(_opType,"Set") == 0) && _rChild ) {
4158	return (strcmp(_rChild->_opType,"LoadPC") == 0);
4159	}
4160	return false;
4161	}
4162
4163	bool MatchRule::is_ideal_box() const {
4164	if ( _opType && (strcmp(_opType,"Set") == 0) && _rChild ) {
4165	return (strcmp(_rChild->_opType,"Box") == 0);
4166	}
4167	return false;
4168	}
4169
4170	bool MatchRule::is_ideal_goto() const {
4171	bool ideal_goto = false;
4172
4173	if( _opType && (strcmp(_opType,"Goto") == 0) ) {
4174	ideal_goto = true;
4175	}
4176	return ideal_goto;
4177	}
4178
4179	bool MatchRule::is_ideal_jump() const {
4180	if( _opType ) {
4181	if( !strcmp(_opType,"Jump") )
4182	return true;
4183	}
4184	return false;
4185	}
4186
4187	bool MatchRule::is_ideal_bool() const {
4188	if( _opType ) {
4189	if( !strcmp(_opType,"Bool") )
4190	return true;
4191	}
4192	return false;
4193	}
4194
4195
4196	Form::DataType MatchRule::is_ideal_load() const {
4197	Form::DataType ideal_load = Form::none;
4198
4199	if ( _opType && (strcmp(_opType,"Set") == 0) && _rChild ) {
4200	const char *opType = _rChild->_opType;
4201	ideal_load = is_load_from_memory(opType);
4202	}
4203
4204	return ideal_load;
4205	}
4206
4207	bool MatchRule::is_vector() const {
4208	static const char *vector_list[] = {
4209	"AddVB","AddVS","AddVI","AddVL","AddVF","AddVD",
4210	"SubVB","SubVS","SubVI","SubVL","SubVF","SubVD",
4211	"MulVB","MulVS","MulVI","MulVL","MulVF","MulVD",
4212	"CMoveVD", "CMoveVF",
4213	"DivVF","DivVD",
4214	"AbsVB","AbsVS","AbsVI","AbsVL","AbsVF","AbsVD",
4215	"NegVF","NegVD","NegVI",
4216	"SqrtVD","SqrtVF",
4217	"AndV" ,"XorV" ,"OrV",
4218	"MaxV", "MinV",
4219	"AddReductionVI", "AddReductionVL",
4220	"AddReductionVF", "AddReductionVD",
4221	"MulReductionVI", "MulReductionVL",
4222	"MulReductionVF", "MulReductionVD",
4223	"MaxReductionV", "MinReductionV",
4224	"AndReductionV", "OrReductionV", "XorReductionV",
4225	"MulAddVS2VI", "MacroLogicV",
4226	"LShiftCntV","RShiftCntV",
4227	"LShiftVB","LShiftVS","LShiftVI","LShiftVL",
4228	"RShiftVB","RShiftVS","RShiftVI","RShiftVL",
4229	"URShiftVB","URShiftVS","URShiftVI","URShiftVL",
4230	"ReplicateB","ReplicateS","ReplicateI","ReplicateL","ReplicateF","ReplicateD",
4231	"RoundDoubleModeV","RotateLeftV" , "RotateRightV", "LoadVector","StoreVector",
4232	"LoadVectorGather", "StoreVectorScatter", "LoadVectorGatherMasked", "StoreVectorScatterMasked",
4233	"VectorTest", "VectorLoadMask", "VectorStoreMask", "VectorBlend", "VectorInsert",
4234	"VectorRearrange","VectorLoadShuffle", "VectorLoadConst",
4235	"VectorCastB2X", "VectorCastS2X", "VectorCastI2X",
4236	"VectorCastL2X", "VectorCastF2X", "VectorCastD2X",
4237	"VectorMaskWrapper","VectorMaskCmp","VectorReinterpret","LoadVectorMasked","StoreVectorMasked",
4238	"FmaVD","FmaVF","PopCountVI","VectorLongToMask",
4239	// Next are vector mask ops.
4240	"MaskAll", "AndVMask", "OrVMask", "XorVMask", "VectorMaskCast",
4241	// Next are not supported currently.
4242	"PackB","PackS","PackI","PackL","PackF","PackD","Pack2L","Pack2D",
4243	"ExtractB","ExtractUB","ExtractC","ExtractS","ExtractI","ExtractL","ExtractF","ExtractD"
4244	};
4245	int cnt = sizeof(vector_list)/sizeof(char*);
4246	if (_rChild) {
4247	const char *opType = _rChild->_opType;
4248	for (int i=0; i<cnt; i++)
4249	if (strcmp(opType,vector_list[i]) == 0)
4250	return true;
4251	}
4252	return false;
4253	}
4254
4255
4256	bool MatchRule::skip_antidep_check() const {
4257	// Some loads operate on what is effectively immutable memory so we
4258	// should skip the anti dep computations. For some of these nodes
4259	// the rewritable field keeps the anti dep logic from triggering but
4260	// for certain kinds of LoadKlass it does not since they are
4261	// actually reading memory which could be rewritten by the runtime,
4262	// though never by generated code. This disables it uniformly for
4263	// the nodes that behave like this: LoadKlass, LoadNKlass and
4264	// LoadRange.
4265	if ( _opType && (strcmp(_opType,"Set") == 0) && _rChild ) {
4266	const char *opType = _rChild->_opType;
4267	if (strcmp("LoadKlass", opType) == 0 \|\|
4268	strcmp("LoadNKlass", opType) == 0 \|\|
4269	strcmp("LoadRange", opType) == 0) {
4270	return true;
4271	}
4272	}
4273
4274	return false;
4275	}
4276
4277
4278	Form::DataType MatchRule::is_ideal_store() const {
4279	Form::DataType ideal_store = Form::none;
4280
4281	if ( _opType && (strcmp(_opType,"Set") == 0) && _rChild ) {
4282	const char *opType = _rChild->_opType;
4283	ideal_store = is_store_to_memory(opType);
4284	}
4285
4286	return ideal_store;
4287	}
4288
4289
4290	void MatchRule::dump() {
4291	output(stderrstderr);
4292	}
4293
4294	// Write just one line.
4295	void MatchRule::output_short(FILE *fp) {
4296	fprintf(fp,"MatchRule: ( %s",_name);
4297	if (_lChild) _lChild->output(fp);
4298	if (_rChild) _rChild->output(fp);
4299	fprintf(fp," )");
4300	}
4301
4302	void MatchRule::output(FILE *fp) {
4303	output_short(fp);
4304	fprintf(fp,"\n nesting depth = %d\n", _depth);
4305	if (_result) fprintf(fp," Result Type = %s", _result);
4306	fprintf(fp,"\n");
4307	}
4308
4309	//------------------------------Attribute--------------------------------------
4310	Attribute::Attribute(char id, char val, int type)
4311	: _ident(id), _val(val), _atype(type) {
4312	}
4313	Attribute::~Attribute() {
4314	}
4315
4316	int Attribute::int_val(ArchDesc &ad) {
4317	// Make sure it is an integer constant:
4318	int result = 0;
4319	if (!_val \|\| !ADLParser::is_int_token(_val, result)) {
4320	ad.syntax_err(0, "Attribute %s must have an integer value: %s",
4321	_ident, _val ? _val : "");
4322	}
4323	return result;
4324	}
4325
4326	void Attribute::dump() {
4327	output(stderrstderr);
4328	} // Debug printer
4329
4330	// Write to output files
4331	void Attribute::output(FILE *fp) {
4332	fprintf(fp,"Attribute: %s %s\n", (_ident?_ident:""), (_val?_val:""));
4333	}
4334
4335	//------------------------------FormatRule----------------------------------
4336	FormatRule::FormatRule(char *temp)
4337	: _temp(temp) {
4338	}
4339	FormatRule::~FormatRule() {
4340	}
4341
4342	void FormatRule::dump() {
4343	output(stderrstderr);
4344	}
4345
4346	// Write to output files
4347	void FormatRule::output(FILE *fp) {
4348	fprintf(fp,"\nFormat Rule: \n%s", (_temp?_temp:""));
4349	fprintf(fp,"\n");
4350	}