Thu, 07 Oct 2010 21:40:55 -0700
6980792: Crash "exception happened outside interpreter, nmethods and vtable stubs (1)"
Reviewed-by: kvn
1 /*
2 * Copyright (c) 2000, 2010, 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
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7 * published by the Free Software Foundation.
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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).
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23 */
25 #include "incls/_precompiled.incl"
26 #include "incls/_callGenerator.cpp.incl"
28 CallGenerator::CallGenerator(ciMethod* method) {
29 _method = method;
30 }
32 // Utility function.
33 const TypeFunc* CallGenerator::tf() const {
34 return TypeFunc::make(method());
35 }
37 //-----------------------------ParseGenerator---------------------------------
38 // Internal class which handles all direct bytecode traversal.
39 class ParseGenerator : public InlineCallGenerator {
40 private:
41 bool _is_osr;
42 float _expected_uses;
44 public:
45 ParseGenerator(ciMethod* method, float expected_uses, bool is_osr = false)
46 : InlineCallGenerator(method)
47 {
48 _is_osr = is_osr;
49 _expected_uses = expected_uses;
50 assert(can_parse(method, is_osr), "parse must be possible");
51 }
53 // Can we build either an OSR or a regular parser for this method?
54 static bool can_parse(ciMethod* method, int is_osr = false);
56 virtual bool is_parse() const { return true; }
57 virtual JVMState* generate(JVMState* jvms);
58 int is_osr() { return _is_osr; }
60 };
62 JVMState* ParseGenerator::generate(JVMState* jvms) {
63 Compile* C = Compile::current();
65 if (is_osr()) {
66 // The JVMS for a OSR has a single argument (see its TypeFunc).
67 assert(jvms->depth() == 1, "no inline OSR");
68 }
70 if (C->failing()) {
71 return NULL; // bailing out of the compile; do not try to parse
72 }
74 Parse parser(jvms, method(), _expected_uses);
75 // Grab signature for matching/allocation
76 #ifdef ASSERT
77 if (parser.tf() != (parser.depth() == 1 ? C->tf() : tf())) {
78 MutexLockerEx ml(Compile_lock, Mutex::_no_safepoint_check_flag);
79 assert(C->env()->system_dictionary_modification_counter_changed(),
80 "Must invalidate if TypeFuncs differ");
81 }
82 #endif
84 GraphKit& exits = parser.exits();
86 if (C->failing()) {
87 while (exits.pop_exception_state() != NULL) ;
88 return NULL;
89 }
91 assert(exits.jvms()->same_calls_as(jvms), "sanity");
93 // Simply return the exit state of the parser,
94 // augmented by any exceptional states.
95 return exits.transfer_exceptions_into_jvms();
96 }
98 //---------------------------DirectCallGenerator------------------------------
99 // Internal class which handles all out-of-line calls w/o receiver type checks.
100 class DirectCallGenerator : public CallGenerator {
101 private:
102 CallStaticJavaNode* _call_node;
103 // Force separate memory and I/O projections for the exceptional
104 // paths to facilitate late inlinig.
105 bool _separate_io_proj;
107 public:
108 DirectCallGenerator(ciMethod* method, bool separate_io_proj)
109 : CallGenerator(method),
110 _separate_io_proj(separate_io_proj)
111 {
112 }
113 virtual JVMState* generate(JVMState* jvms);
115 CallStaticJavaNode* call_node() const { return _call_node; }
116 };
118 JVMState* DirectCallGenerator::generate(JVMState* jvms) {
119 GraphKit kit(jvms);
120 bool is_static = method()->is_static();
121 address target = is_static ? SharedRuntime::get_resolve_static_call_stub()
122 : SharedRuntime::get_resolve_opt_virtual_call_stub();
124 if (kit.C->log() != NULL) {
125 kit.C->log()->elem("direct_call bci='%d'", jvms->bci());
126 }
128 CallStaticJavaNode *call = new (kit.C, tf()->domain()->cnt()) CallStaticJavaNode(tf(), target, method(), kit.bci());
129 if (!is_static) {
130 // Make an explicit receiver null_check as part of this call.
131 // Since we share a map with the caller, his JVMS gets adjusted.
132 kit.null_check_receiver(method());
133 if (kit.stopped()) {
134 // And dump it back to the caller, decorated with any exceptions:
135 return kit.transfer_exceptions_into_jvms();
136 }
137 // Mark the call node as virtual, sort of:
138 call->set_optimized_virtual(true);
139 if (method()->is_method_handle_invoke()) {
140 call->set_method_handle_invoke(true);
141 kit.C->set_has_method_handle_invokes(true);
142 }
143 }
144 kit.set_arguments_for_java_call(call);
145 kit.set_edges_for_java_call(call, false, _separate_io_proj);
146 Node* ret = kit.set_results_for_java_call(call, _separate_io_proj);
147 kit.push_node(method()->return_type()->basic_type(), ret);
148 _call_node = call; // Save the call node in case we need it later
149 return kit.transfer_exceptions_into_jvms();
150 }
152 //---------------------------DynamicCallGenerator-----------------------------
153 // Internal class which handles all out-of-line invokedynamic calls.
154 class DynamicCallGenerator : public CallGenerator {
155 public:
156 DynamicCallGenerator(ciMethod* method)
157 : CallGenerator(method)
158 {
159 }
160 virtual JVMState* generate(JVMState* jvms);
161 };
163 JVMState* DynamicCallGenerator::generate(JVMState* jvms) {
164 GraphKit kit(jvms);
166 if (kit.C->log() != NULL) {
167 kit.C->log()->elem("dynamic_call bci='%d'", jvms->bci());
168 }
170 // Get the constant pool cache from the caller class.
171 ciMethod* caller_method = jvms->method();
172 ciBytecodeStream str(caller_method);
173 str.force_bci(jvms->bci()); // Set the stream to the invokedynamic bci.
174 assert(str.cur_bc() == Bytecodes::_invokedynamic, "wrong place to issue a dynamic call!");
175 ciCPCache* cpcache = str.get_cpcache();
177 // Get the offset of the CallSite from the constant pool cache
178 // pointer.
179 int index = str.get_method_index();
180 size_t call_site_offset = cpcache->get_f1_offset(index);
182 // Load the CallSite object from the constant pool cache.
183 const TypeOopPtr* cpcache_ptr = TypeOopPtr::make_from_constant(cpcache);
184 Node* cpcache_adr = kit.makecon(cpcache_ptr);
185 Node* call_site_adr = kit.basic_plus_adr(cpcache_adr, cpcache_adr, call_site_offset);
186 Node* call_site = kit.make_load(kit.control(), call_site_adr, TypeInstPtr::BOTTOM, T_OBJECT, Compile::AliasIdxRaw);
188 // Load the target MethodHandle from the CallSite object.
189 Node* target_mh_adr = kit.basic_plus_adr(call_site, call_site, java_dyn_CallSite::target_offset_in_bytes());
190 Node* target_mh = kit.make_load(kit.control(), target_mh_adr, TypeInstPtr::BOTTOM, T_OBJECT);
192 address resolve_stub = SharedRuntime::get_resolve_opt_virtual_call_stub();
194 CallStaticJavaNode *call = new (kit.C, tf()->domain()->cnt()) CallStaticJavaNode(tf(), resolve_stub, method(), kit.bci());
195 // invokedynamic is treated as an optimized invokevirtual.
196 call->set_optimized_virtual(true);
197 // Take extra care (in the presence of argument motion) not to trash the SP:
198 call->set_method_handle_invoke(true);
199 kit.C->set_has_method_handle_invokes(true);
201 // Pass the target MethodHandle as first argument and shift the
202 // other arguments.
203 call->init_req(0 + TypeFunc::Parms, target_mh);
204 uint nargs = call->method()->arg_size();
205 for (uint i = 1; i < nargs; i++) {
206 Node* arg = kit.argument(i - 1);
207 call->init_req(i + TypeFunc::Parms, arg);
208 }
210 kit.set_edges_for_java_call(call);
211 Node* ret = kit.set_results_for_java_call(call);
212 kit.push_node(method()->return_type()->basic_type(), ret);
213 return kit.transfer_exceptions_into_jvms();
214 }
216 //--------------------------VirtualCallGenerator------------------------------
217 // Internal class which handles all out-of-line calls checking receiver type.
218 class VirtualCallGenerator : public CallGenerator {
219 private:
220 int _vtable_index;
221 public:
222 VirtualCallGenerator(ciMethod* method, int vtable_index)
223 : CallGenerator(method), _vtable_index(vtable_index)
224 {
225 assert(vtable_index == methodOopDesc::invalid_vtable_index ||
226 vtable_index >= 0, "either invalid or usable");
227 }
228 virtual bool is_virtual() const { return true; }
229 virtual JVMState* generate(JVMState* jvms);
230 };
232 JVMState* VirtualCallGenerator::generate(JVMState* jvms) {
233 GraphKit kit(jvms);
234 Node* receiver = kit.argument(0);
236 if (kit.C->log() != NULL) {
237 kit.C->log()->elem("virtual_call bci='%d'", jvms->bci());
238 }
240 // If the receiver is a constant null, do not torture the system
241 // by attempting to call through it. The compile will proceed
242 // correctly, but may bail out in final_graph_reshaping, because
243 // the call instruction will have a seemingly deficient out-count.
244 // (The bailout says something misleading about an "infinite loop".)
245 if (kit.gvn().type(receiver)->higher_equal(TypePtr::NULL_PTR)) {
246 kit.inc_sp(method()->arg_size()); // restore arguments
247 kit.uncommon_trap(Deoptimization::Reason_null_check,
248 Deoptimization::Action_none,
249 NULL, "null receiver");
250 return kit.transfer_exceptions_into_jvms();
251 }
253 // Ideally we would unconditionally do a null check here and let it
254 // be converted to an implicit check based on profile information.
255 // However currently the conversion to implicit null checks in
256 // Block::implicit_null_check() only looks for loads and stores, not calls.
257 ciMethod *caller = kit.method();
258 ciMethodData *caller_md = (caller == NULL) ? NULL : caller->method_data();
259 if (!UseInlineCaches || !ImplicitNullChecks ||
260 ((ImplicitNullCheckThreshold > 0) && caller_md &&
261 (caller_md->trap_count(Deoptimization::Reason_null_check)
262 >= (uint)ImplicitNullCheckThreshold))) {
263 // Make an explicit receiver null_check as part of this call.
264 // Since we share a map with the caller, his JVMS gets adjusted.
265 receiver = kit.null_check_receiver(method());
266 if (kit.stopped()) {
267 // And dump it back to the caller, decorated with any exceptions:
268 return kit.transfer_exceptions_into_jvms();
269 }
270 }
272 assert(!method()->is_static(), "virtual call must not be to static");
273 assert(!method()->is_final(), "virtual call should not be to final");
274 assert(!method()->is_private(), "virtual call should not be to private");
275 assert(_vtable_index == methodOopDesc::invalid_vtable_index || !UseInlineCaches,
276 "no vtable calls if +UseInlineCaches ");
277 address target = SharedRuntime::get_resolve_virtual_call_stub();
278 // Normal inline cache used for call
279 CallDynamicJavaNode *call = new (kit.C, tf()->domain()->cnt()) CallDynamicJavaNode(tf(), target, method(), _vtable_index, kit.bci());
280 kit.set_arguments_for_java_call(call);
281 kit.set_edges_for_java_call(call);
282 Node* ret = kit.set_results_for_java_call(call);
283 kit.push_node(method()->return_type()->basic_type(), ret);
285 // Represent the effect of an implicit receiver null_check
286 // as part of this call. Since we share a map with the caller,
287 // his JVMS gets adjusted.
288 kit.cast_not_null(receiver);
289 return kit.transfer_exceptions_into_jvms();
290 }
292 bool ParseGenerator::can_parse(ciMethod* m, int entry_bci) {
293 // Certain methods cannot be parsed at all:
294 if (!m->can_be_compiled()) return false;
295 if (!m->has_balanced_monitors()) return false;
296 if (m->get_flow_analysis()->failing()) return false;
298 // (Methods may bail out for other reasons, after the parser is run.
299 // We try to avoid this, but if forced, we must return (Node*)NULL.
300 // The user of the CallGenerator must check for this condition.)
301 return true;
302 }
304 CallGenerator* CallGenerator::for_inline(ciMethod* m, float expected_uses) {
305 if (!ParseGenerator::can_parse(m)) return NULL;
306 return new ParseGenerator(m, expected_uses);
307 }
309 // As a special case, the JVMS passed to this CallGenerator is
310 // for the method execution already in progress, not just the JVMS
311 // of the caller. Thus, this CallGenerator cannot be mixed with others!
312 CallGenerator* CallGenerator::for_osr(ciMethod* m, int osr_bci) {
313 if (!ParseGenerator::can_parse(m, true)) return NULL;
314 float past_uses = m->interpreter_invocation_count();
315 float expected_uses = past_uses;
316 return new ParseGenerator(m, expected_uses, true);
317 }
319 CallGenerator* CallGenerator::for_direct_call(ciMethod* m, bool separate_io_proj) {
320 assert(!m->is_abstract(), "for_direct_call mismatch");
321 return new DirectCallGenerator(m, separate_io_proj);
322 }
324 CallGenerator* CallGenerator::for_dynamic_call(ciMethod* m) {
325 assert(m->is_method_handle_invoke(), "for_dynamic_call mismatch");
326 return new DynamicCallGenerator(m);
327 }
329 CallGenerator* CallGenerator::for_virtual_call(ciMethod* m, int vtable_index) {
330 assert(!m->is_static(), "for_virtual_call mismatch");
331 assert(!m->is_method_handle_invoke(), "should be a direct call");
332 return new VirtualCallGenerator(m, vtable_index);
333 }
335 // Allow inlining decisions to be delayed
336 class LateInlineCallGenerator : public DirectCallGenerator {
337 CallGenerator* _inline_cg;
339 public:
340 LateInlineCallGenerator(ciMethod* method, CallGenerator* inline_cg) :
341 DirectCallGenerator(method, true), _inline_cg(inline_cg) {}
343 virtual bool is_late_inline() const { return true; }
345 // Convert the CallStaticJava into an inline
346 virtual void do_late_inline();
348 JVMState* generate(JVMState* jvms) {
349 // Record that this call site should be revisited once the main
350 // parse is finished.
351 Compile::current()->add_late_inline(this);
353 // Emit the CallStaticJava and request separate projections so
354 // that the late inlining logic can distinguish between fall
355 // through and exceptional uses of the memory and io projections
356 // as is done for allocations and macro expansion.
357 return DirectCallGenerator::generate(jvms);
358 }
360 };
363 void LateInlineCallGenerator::do_late_inline() {
364 // Can't inline it
365 if (call_node() == NULL || call_node()->outcnt() == 0 ||
366 call_node()->in(0) == NULL || call_node()->in(0)->is_top())
367 return;
369 CallStaticJavaNode* call = call_node();
371 // Make a clone of the JVMState that appropriate to use for driving a parse
372 Compile* C = Compile::current();
373 JVMState* jvms = call->jvms()->clone_shallow(C);
374 uint size = call->req();
375 SafePointNode* map = new (C, size) SafePointNode(size, jvms);
376 for (uint i1 = 0; i1 < size; i1++) {
377 map->init_req(i1, call->in(i1));
378 }
380 // Make sure the state is a MergeMem for parsing.
381 if (!map->in(TypeFunc::Memory)->is_MergeMem()) {
382 map->set_req(TypeFunc::Memory, MergeMemNode::make(C, map->in(TypeFunc::Memory)));
383 }
385 // Make enough space for the expression stack and transfer the incoming arguments
386 int nargs = method()->arg_size();
387 jvms->set_map(map);
388 map->ensure_stack(jvms, jvms->method()->max_stack());
389 if (nargs > 0) {
390 for (int i1 = 0; i1 < nargs; i1++) {
391 map->set_req(i1 + jvms->argoff(), call->in(TypeFunc::Parms + i1));
392 }
393 }
395 CompileLog* log = C->log();
396 if (log != NULL) {
397 log->head("late_inline method='%d'", log->identify(method()));
398 JVMState* p = jvms;
399 while (p != NULL) {
400 log->elem("jvms bci='%d' method='%d'", p->bci(), log->identify(p->method()));
401 p = p->caller();
402 }
403 log->tail("late_inline");
404 }
406 // Setup default node notes to be picked up by the inlining
407 Node_Notes* old_nn = C->default_node_notes();
408 if (old_nn != NULL) {
409 Node_Notes* entry_nn = old_nn->clone(C);
410 entry_nn->set_jvms(jvms);
411 C->set_default_node_notes(entry_nn);
412 }
414 // Now perform the inling using the synthesized JVMState
415 JVMState* new_jvms = _inline_cg->generate(jvms);
416 if (new_jvms == NULL) return; // no change
417 if (C->failing()) return;
419 // Capture any exceptional control flow
420 GraphKit kit(new_jvms);
422 // Find the result object
423 Node* result = C->top();
424 int result_size = method()->return_type()->size();
425 if (result_size != 0 && !kit.stopped()) {
426 result = (result_size == 1) ? kit.pop() : kit.pop_pair();
427 }
429 kit.replace_call(call, result);
430 }
433 CallGenerator* CallGenerator::for_late_inline(ciMethod* method, CallGenerator* inline_cg) {
434 return new LateInlineCallGenerator(method, inline_cg);
435 }
438 //---------------------------WarmCallGenerator--------------------------------
439 // Internal class which handles initial deferral of inlining decisions.
440 class WarmCallGenerator : public CallGenerator {
441 WarmCallInfo* _call_info;
442 CallGenerator* _if_cold;
443 CallGenerator* _if_hot;
444 bool _is_virtual; // caches virtuality of if_cold
445 bool _is_inline; // caches inline-ness of if_hot
447 public:
448 WarmCallGenerator(WarmCallInfo* ci,
449 CallGenerator* if_cold,
450 CallGenerator* if_hot)
451 : CallGenerator(if_cold->method())
452 {
453 assert(method() == if_hot->method(), "consistent choices");
454 _call_info = ci;
455 _if_cold = if_cold;
456 _if_hot = if_hot;
457 _is_virtual = if_cold->is_virtual();
458 _is_inline = if_hot->is_inline();
459 }
461 virtual bool is_inline() const { return _is_inline; }
462 virtual bool is_virtual() const { return _is_virtual; }
463 virtual bool is_deferred() const { return true; }
465 virtual JVMState* generate(JVMState* jvms);
466 };
469 CallGenerator* CallGenerator::for_warm_call(WarmCallInfo* ci,
470 CallGenerator* if_cold,
471 CallGenerator* if_hot) {
472 return new WarmCallGenerator(ci, if_cold, if_hot);
473 }
475 JVMState* WarmCallGenerator::generate(JVMState* jvms) {
476 Compile* C = Compile::current();
477 if (C->log() != NULL) {
478 C->log()->elem("warm_call bci='%d'", jvms->bci());
479 }
480 jvms = _if_cold->generate(jvms);
481 if (jvms != NULL) {
482 Node* m = jvms->map()->control();
483 if (m->is_CatchProj()) m = m->in(0); else m = C->top();
484 if (m->is_Catch()) m = m->in(0); else m = C->top();
485 if (m->is_Proj()) m = m->in(0); else m = C->top();
486 if (m->is_CallJava()) {
487 _call_info->set_call(m->as_Call());
488 _call_info->set_hot_cg(_if_hot);
489 #ifndef PRODUCT
490 if (PrintOpto || PrintOptoInlining) {
491 tty->print_cr("Queueing for warm inlining at bci %d:", jvms->bci());
492 tty->print("WCI: ");
493 _call_info->print();
494 }
495 #endif
496 _call_info->set_heat(_call_info->compute_heat());
497 C->set_warm_calls(_call_info->insert_into(C->warm_calls()));
498 }
499 }
500 return jvms;
501 }
503 void WarmCallInfo::make_hot() {
504 Unimplemented();
505 }
507 void WarmCallInfo::make_cold() {
508 // No action: Just dequeue.
509 }
512 //------------------------PredictedCallGenerator------------------------------
513 // Internal class which handles all out-of-line calls checking receiver type.
514 class PredictedCallGenerator : public CallGenerator {
515 ciKlass* _predicted_receiver;
516 CallGenerator* _if_missed;
517 CallGenerator* _if_hit;
518 float _hit_prob;
520 public:
521 PredictedCallGenerator(ciKlass* predicted_receiver,
522 CallGenerator* if_missed,
523 CallGenerator* if_hit, float hit_prob)
524 : CallGenerator(if_missed->method())
525 {
526 // The call profile data may predict the hit_prob as extreme as 0 or 1.
527 // Remove the extremes values from the range.
528 if (hit_prob > PROB_MAX) hit_prob = PROB_MAX;
529 if (hit_prob < PROB_MIN) hit_prob = PROB_MIN;
531 _predicted_receiver = predicted_receiver;
532 _if_missed = if_missed;
533 _if_hit = if_hit;
534 _hit_prob = hit_prob;
535 }
537 virtual bool is_virtual() const { return true; }
538 virtual bool is_inline() const { return _if_hit->is_inline(); }
539 virtual bool is_deferred() const { return _if_hit->is_deferred(); }
541 virtual JVMState* generate(JVMState* jvms);
542 };
545 CallGenerator* CallGenerator::for_predicted_call(ciKlass* predicted_receiver,
546 CallGenerator* if_missed,
547 CallGenerator* if_hit,
548 float hit_prob) {
549 return new PredictedCallGenerator(predicted_receiver, if_missed, if_hit, hit_prob);
550 }
553 JVMState* PredictedCallGenerator::generate(JVMState* jvms) {
554 GraphKit kit(jvms);
555 PhaseGVN& gvn = kit.gvn();
556 // We need an explicit receiver null_check before checking its type.
557 // We share a map with the caller, so his JVMS gets adjusted.
558 Node* receiver = kit.argument(0);
560 CompileLog* log = kit.C->log();
561 if (log != NULL) {
562 log->elem("predicted_call bci='%d' klass='%d'",
563 jvms->bci(), log->identify(_predicted_receiver));
564 }
566 receiver = kit.null_check_receiver(method());
567 if (kit.stopped()) {
568 return kit.transfer_exceptions_into_jvms();
569 }
571 Node* exact_receiver = receiver; // will get updated in place...
572 Node* slow_ctl = kit.type_check_receiver(receiver,
573 _predicted_receiver, _hit_prob,
574 &exact_receiver);
576 SafePointNode* slow_map = NULL;
577 JVMState* slow_jvms;
578 { PreserveJVMState pjvms(&kit);
579 kit.set_control(slow_ctl);
580 if (!kit.stopped()) {
581 slow_jvms = _if_missed->generate(kit.sync_jvms());
582 assert(slow_jvms != NULL, "miss path must not fail to generate");
583 kit.add_exception_states_from(slow_jvms);
584 kit.set_map(slow_jvms->map());
585 if (!kit.stopped())
586 slow_map = kit.stop();
587 }
588 }
590 if (kit.stopped()) {
591 // Instance exactly does not matches the desired type.
592 kit.set_jvms(slow_jvms);
593 return kit.transfer_exceptions_into_jvms();
594 }
596 // fall through if the instance exactly matches the desired type
597 kit.replace_in_map(receiver, exact_receiver);
599 // Make the hot call:
600 JVMState* new_jvms = _if_hit->generate(kit.sync_jvms());
601 if (new_jvms == NULL) {
602 // Inline failed, so make a direct call.
603 assert(_if_hit->is_inline(), "must have been a failed inline");
604 CallGenerator* cg = CallGenerator::for_direct_call(_if_hit->method());
605 new_jvms = cg->generate(kit.sync_jvms());
606 }
607 kit.add_exception_states_from(new_jvms);
608 kit.set_jvms(new_jvms);
610 // Need to merge slow and fast?
611 if (slow_map == NULL) {
612 // The fast path is the only path remaining.
613 return kit.transfer_exceptions_into_jvms();
614 }
616 if (kit.stopped()) {
617 // Inlined method threw an exception, so it's just the slow path after all.
618 kit.set_jvms(slow_jvms);
619 return kit.transfer_exceptions_into_jvms();
620 }
622 // Finish the diamond.
623 kit.C->set_has_split_ifs(true); // Has chance for split-if optimization
624 RegionNode* region = new (kit.C, 3) RegionNode(3);
625 region->init_req(1, kit.control());
626 region->init_req(2, slow_map->control());
627 kit.set_control(gvn.transform(region));
628 Node* iophi = PhiNode::make(region, kit.i_o(), Type::ABIO);
629 iophi->set_req(2, slow_map->i_o());
630 kit.set_i_o(gvn.transform(iophi));
631 kit.merge_memory(slow_map->merged_memory(), region, 2);
632 uint tos = kit.jvms()->stkoff() + kit.sp();
633 uint limit = slow_map->req();
634 for (uint i = TypeFunc::Parms; i < limit; i++) {
635 // Skip unused stack slots; fast forward to monoff();
636 if (i == tos) {
637 i = kit.jvms()->monoff();
638 if( i >= limit ) break;
639 }
640 Node* m = kit.map()->in(i);
641 Node* n = slow_map->in(i);
642 if (m != n) {
643 const Type* t = gvn.type(m)->meet(gvn.type(n));
644 Node* phi = PhiNode::make(region, m, t);
645 phi->set_req(2, n);
646 kit.map()->set_req(i, gvn.transform(phi));
647 }
648 }
649 return kit.transfer_exceptions_into_jvms();
650 }
653 //------------------------PredictedDynamicCallGenerator-----------------------
654 // Internal class which handles all out-of-line calls checking receiver type.
655 class PredictedDynamicCallGenerator : public CallGenerator {
656 ciMethodHandle* _predicted_method_handle;
657 CallGenerator* _if_missed;
658 CallGenerator* _if_hit;
659 float _hit_prob;
661 public:
662 PredictedDynamicCallGenerator(ciMethodHandle* predicted_method_handle,
663 CallGenerator* if_missed,
664 CallGenerator* if_hit,
665 float hit_prob)
666 : CallGenerator(if_missed->method()),
667 _predicted_method_handle(predicted_method_handle),
668 _if_missed(if_missed),
669 _if_hit(if_hit),
670 _hit_prob(hit_prob)
671 {}
673 virtual bool is_inline() const { return _if_hit->is_inline(); }
674 virtual bool is_deferred() const { return _if_hit->is_deferred(); }
676 virtual JVMState* generate(JVMState* jvms);
677 };
680 CallGenerator* CallGenerator::for_predicted_dynamic_call(ciMethodHandle* predicted_method_handle,
681 CallGenerator* if_missed,
682 CallGenerator* if_hit,
683 float hit_prob) {
684 return new PredictedDynamicCallGenerator(predicted_method_handle, if_missed, if_hit, hit_prob);
685 }
688 JVMState* PredictedDynamicCallGenerator::generate(JVMState* jvms) {
689 GraphKit kit(jvms);
690 PhaseGVN& gvn = kit.gvn();
692 CompileLog* log = kit.C->log();
693 if (log != NULL) {
694 log->elem("predicted_dynamic_call bci='%d'", jvms->bci());
695 }
697 // Get the constant pool cache from the caller class.
698 ciMethod* caller_method = jvms->method();
699 ciBytecodeStream str(caller_method);
700 str.force_bci(jvms->bci()); // Set the stream to the invokedynamic bci.
701 ciCPCache* cpcache = str.get_cpcache();
703 // Get the offset of the CallSite from the constant pool cache
704 // pointer.
705 int index = str.get_method_index();
706 size_t call_site_offset = cpcache->get_f1_offset(index);
708 // Load the CallSite object from the constant pool cache.
709 const TypeOopPtr* cpcache_ptr = TypeOopPtr::make_from_constant(cpcache);
710 Node* cpcache_adr = kit.makecon(cpcache_ptr);
711 Node* call_site_adr = kit.basic_plus_adr(cpcache_adr, cpcache_adr, call_site_offset);
712 Node* call_site = kit.make_load(kit.control(), call_site_adr, TypeInstPtr::BOTTOM, T_OBJECT, Compile::AliasIdxRaw);
714 // Load the target MethodHandle from the CallSite object.
715 Node* target_adr = kit.basic_plus_adr(call_site, call_site, java_dyn_CallSite::target_offset_in_bytes());
716 Node* target_mh = kit.make_load(kit.control(), target_adr, TypeInstPtr::BOTTOM, T_OBJECT);
718 // Check if the MethodHandle is still the same.
719 const TypeOopPtr* predicted_mh_ptr = TypeOopPtr::make_from_constant(_predicted_method_handle, true);
720 Node* predicted_mh = kit.makecon(predicted_mh_ptr);
722 Node* cmp = gvn.transform(new(kit.C, 3) CmpPNode(target_mh, predicted_mh));
723 Node* bol = gvn.transform(new(kit.C, 2) BoolNode(cmp, BoolTest::eq) );
724 IfNode* iff = kit.create_and_xform_if(kit.control(), bol, _hit_prob, COUNT_UNKNOWN);
725 kit.set_control( gvn.transform(new(kit.C, 1) IfTrueNode (iff)));
726 Node* slow_ctl = gvn.transform(new(kit.C, 1) IfFalseNode(iff));
728 SafePointNode* slow_map = NULL;
729 JVMState* slow_jvms;
730 { PreserveJVMState pjvms(&kit);
731 kit.set_control(slow_ctl);
732 if (!kit.stopped()) {
733 slow_jvms = _if_missed->generate(kit.sync_jvms());
734 assert(slow_jvms != NULL, "miss path must not fail to generate");
735 kit.add_exception_states_from(slow_jvms);
736 kit.set_map(slow_jvms->map());
737 if (!kit.stopped())
738 slow_map = kit.stop();
739 }
740 }
742 if (kit.stopped()) {
743 // Instance exactly does not matches the desired type.
744 kit.set_jvms(slow_jvms);
745 return kit.transfer_exceptions_into_jvms();
746 }
748 // Make the hot call:
749 JVMState* new_jvms = _if_hit->generate(kit.sync_jvms());
750 if (new_jvms == NULL) {
751 // Inline failed, so make a direct call.
752 assert(_if_hit->is_inline(), "must have been a failed inline");
753 CallGenerator* cg = CallGenerator::for_direct_call(_if_hit->method());
754 new_jvms = cg->generate(kit.sync_jvms());
755 }
756 kit.add_exception_states_from(new_jvms);
757 kit.set_jvms(new_jvms);
759 // Need to merge slow and fast?
760 if (slow_map == NULL) {
761 // The fast path is the only path remaining.
762 return kit.transfer_exceptions_into_jvms();
763 }
765 if (kit.stopped()) {
766 // Inlined method threw an exception, so it's just the slow path after all.
767 kit.set_jvms(slow_jvms);
768 return kit.transfer_exceptions_into_jvms();
769 }
771 // Finish the diamond.
772 kit.C->set_has_split_ifs(true); // Has chance for split-if optimization
773 RegionNode* region = new (kit.C, 3) RegionNode(3);
774 region->init_req(1, kit.control());
775 region->init_req(2, slow_map->control());
776 kit.set_control(gvn.transform(region));
777 Node* iophi = PhiNode::make(region, kit.i_o(), Type::ABIO);
778 iophi->set_req(2, slow_map->i_o());
779 kit.set_i_o(gvn.transform(iophi));
780 kit.merge_memory(slow_map->merged_memory(), region, 2);
781 uint tos = kit.jvms()->stkoff() + kit.sp();
782 uint limit = slow_map->req();
783 for (uint i = TypeFunc::Parms; i < limit; i++) {
784 // Skip unused stack slots; fast forward to monoff();
785 if (i == tos) {
786 i = kit.jvms()->monoff();
787 if( i >= limit ) break;
788 }
789 Node* m = kit.map()->in(i);
790 Node* n = slow_map->in(i);
791 if (m != n) {
792 const Type* t = gvn.type(m)->meet(gvn.type(n));
793 Node* phi = PhiNode::make(region, m, t);
794 phi->set_req(2, n);
795 kit.map()->set_req(i, gvn.transform(phi));
796 }
797 }
798 return kit.transfer_exceptions_into_jvms();
799 }
802 //-------------------------UncommonTrapCallGenerator-----------------------------
803 // Internal class which handles all out-of-line calls checking receiver type.
804 class UncommonTrapCallGenerator : public CallGenerator {
805 Deoptimization::DeoptReason _reason;
806 Deoptimization::DeoptAction _action;
808 public:
809 UncommonTrapCallGenerator(ciMethod* m,
810 Deoptimization::DeoptReason reason,
811 Deoptimization::DeoptAction action)
812 : CallGenerator(m)
813 {
814 _reason = reason;
815 _action = action;
816 }
818 virtual bool is_virtual() const { ShouldNotReachHere(); return false; }
819 virtual bool is_trap() const { return true; }
821 virtual JVMState* generate(JVMState* jvms);
822 };
825 CallGenerator*
826 CallGenerator::for_uncommon_trap(ciMethod* m,
827 Deoptimization::DeoptReason reason,
828 Deoptimization::DeoptAction action) {
829 return new UncommonTrapCallGenerator(m, reason, action);
830 }
833 JVMState* UncommonTrapCallGenerator::generate(JVMState* jvms) {
834 GraphKit kit(jvms);
835 // Take the trap with arguments pushed on the stack. (Cf. null_check_receiver).
836 int nargs = method()->arg_size();
837 kit.inc_sp(nargs);
838 assert(nargs <= kit.sp() && kit.sp() <= jvms->stk_size(), "sane sp w/ args pushed");
839 if (_reason == Deoptimization::Reason_class_check &&
840 _action == Deoptimization::Action_maybe_recompile) {
841 // Temp fix for 6529811
842 // Don't allow uncommon_trap to override our decision to recompile in the event
843 // of a class cast failure for a monomorphic call as it will never let us convert
844 // the call to either bi-morphic or megamorphic and can lead to unc-trap loops
845 bool keep_exact_action = true;
846 kit.uncommon_trap(_reason, _action, NULL, "monomorphic vcall checkcast", false, keep_exact_action);
847 } else {
848 kit.uncommon_trap(_reason, _action);
849 }
850 return kit.transfer_exceptions_into_jvms();
851 }
853 // (Note: Moved hook_up_call to GraphKit::set_edges_for_java_call.)
855 // (Node: Merged hook_up_exits into ParseGenerator::generate.)
857 #define NODES_OVERHEAD_PER_METHOD (30.0)
858 #define NODES_PER_BYTECODE (9.5)
860 void WarmCallInfo::init(JVMState* call_site, ciMethod* call_method, ciCallProfile& profile, float prof_factor) {
861 int call_count = profile.count();
862 int code_size = call_method->code_size();
864 // Expected execution count is based on the historical count:
865 _count = call_count < 0 ? 1 : call_site->method()->scale_count(call_count, prof_factor);
867 // Expected profit from inlining, in units of simple call-overheads.
868 _profit = 1.0;
870 // Expected work performed by the call in units of call-overheads.
871 // %%% need an empirical curve fit for "work" (time in call)
872 float bytecodes_per_call = 3;
873 _work = 1.0 + code_size / bytecodes_per_call;
875 // Expected size of compilation graph:
876 // -XX:+PrintParseStatistics once reported:
877 // Methods seen: 9184 Methods parsed: 9184 Nodes created: 1582391
878 // Histogram of 144298 parsed bytecodes:
879 // %%% Need an better predictor for graph size.
880 _size = NODES_OVERHEAD_PER_METHOD + (NODES_PER_BYTECODE * code_size);
881 }
883 // is_cold: Return true if the node should never be inlined.
884 // This is true if any of the key metrics are extreme.
885 bool WarmCallInfo::is_cold() const {
886 if (count() < WarmCallMinCount) return true;
887 if (profit() < WarmCallMinProfit) return true;
888 if (work() > WarmCallMaxWork) return true;
889 if (size() > WarmCallMaxSize) return true;
890 return false;
891 }
893 // is_hot: Return true if the node should be inlined immediately.
894 // This is true if any of the key metrics are extreme.
895 bool WarmCallInfo::is_hot() const {
896 assert(!is_cold(), "eliminate is_cold cases before testing is_hot");
897 if (count() >= HotCallCountThreshold) return true;
898 if (profit() >= HotCallProfitThreshold) return true;
899 if (work() <= HotCallTrivialWork) return true;
900 if (size() <= HotCallTrivialSize) return true;
901 return false;
902 }
904 // compute_heat:
905 float WarmCallInfo::compute_heat() const {
906 assert(!is_cold(), "compute heat only on warm nodes");
907 assert(!is_hot(), "compute heat only on warm nodes");
908 int min_size = MAX2(0, (int)HotCallTrivialSize);
909 int max_size = MIN2(500, (int)WarmCallMaxSize);
910 float method_size = (size() - min_size) / MAX2(1, max_size - min_size);
911 float size_factor;
912 if (method_size < 0.05) size_factor = 4; // 2 sigmas better than avg.
913 else if (method_size < 0.15) size_factor = 2; // 1 sigma better than avg.
914 else if (method_size < 0.5) size_factor = 1; // better than avg.
915 else size_factor = 0.5; // worse than avg.
916 return (count() * profit() * size_factor);
917 }
919 bool WarmCallInfo::warmer_than(WarmCallInfo* that) {
920 assert(this != that, "compare only different WCIs");
921 assert(this->heat() != 0 && that->heat() != 0, "call compute_heat 1st");
922 if (this->heat() > that->heat()) return true;
923 if (this->heat() < that->heat()) return false;
924 assert(this->heat() == that->heat(), "no NaN heat allowed");
925 // Equal heat. Break the tie some other way.
926 if (!this->call() || !that->call()) return (address)this > (address)that;
927 return this->call()->_idx > that->call()->_idx;
928 }
930 //#define UNINIT_NEXT ((WarmCallInfo*)badAddress)
931 #define UNINIT_NEXT ((WarmCallInfo*)NULL)
933 WarmCallInfo* WarmCallInfo::insert_into(WarmCallInfo* head) {
934 assert(next() == UNINIT_NEXT, "not yet on any list");
935 WarmCallInfo* prev_p = NULL;
936 WarmCallInfo* next_p = head;
937 while (next_p != NULL && next_p->warmer_than(this)) {
938 prev_p = next_p;
939 next_p = prev_p->next();
940 }
941 // Install this between prev_p and next_p.
942 this->set_next(next_p);
943 if (prev_p == NULL)
944 head = this;
945 else
946 prev_p->set_next(this);
947 return head;
948 }
950 WarmCallInfo* WarmCallInfo::remove_from(WarmCallInfo* head) {
951 WarmCallInfo* prev_p = NULL;
952 WarmCallInfo* next_p = head;
953 while (next_p != this) {
954 assert(next_p != NULL, "this must be in the list somewhere");
955 prev_p = next_p;
956 next_p = prev_p->next();
957 }
958 next_p = this->next();
959 debug_only(this->set_next(UNINIT_NEXT));
960 // Remove this from between prev_p and next_p.
961 if (prev_p == NULL)
962 head = next_p;
963 else
964 prev_p->set_next(next_p);
965 return head;
966 }
968 WarmCallInfo* WarmCallInfo::_always_hot = NULL;
969 WarmCallInfo* WarmCallInfo::_always_cold = NULL;
971 WarmCallInfo* WarmCallInfo::always_hot() {
972 if (_always_hot == NULL) {
973 static double bits[sizeof(WarmCallInfo) / sizeof(double) + 1] = {0};
974 WarmCallInfo* ci = (WarmCallInfo*) bits;
975 ci->_profit = ci->_count = MAX_VALUE();
976 ci->_work = ci->_size = MIN_VALUE();
977 _always_hot = ci;
978 }
979 assert(_always_hot->is_hot(), "must always be hot");
980 return _always_hot;
981 }
983 WarmCallInfo* WarmCallInfo::always_cold() {
984 if (_always_cold == NULL) {
985 static double bits[sizeof(WarmCallInfo) / sizeof(double) + 1] = {0};
986 WarmCallInfo* ci = (WarmCallInfo*) bits;
987 ci->_profit = ci->_count = MIN_VALUE();
988 ci->_work = ci->_size = MAX_VALUE();
989 _always_cold = ci;
990 }
991 assert(_always_cold->is_cold(), "must always be cold");
992 return _always_cold;
993 }
996 #ifndef PRODUCT
998 void WarmCallInfo::print() const {
999 tty->print("%s : C=%6.1f P=%6.1f W=%6.1f S=%6.1f H=%6.1f -> %p",
1000 is_cold() ? "cold" : is_hot() ? "hot " : "warm",
1001 count(), profit(), work(), size(), compute_heat(), next());
1002 tty->cr();
1003 if (call() != NULL) call()->dump();
1004 }
1006 void print_wci(WarmCallInfo* ci) {
1007 ci->print();
1008 }
1010 void WarmCallInfo::print_all() const {
1011 for (const WarmCallInfo* p = this; p != NULL; p = p->next())
1012 p->print();
1013 }
1015 int WarmCallInfo::count_all() const {
1016 int cnt = 0;
1017 for (const WarmCallInfo* p = this; p != NULL; p = p->next())
1018 cnt++;
1019 return cnt;
1020 }
1022 #endif //PRODUCT