8182299: Enable disabled clang warnings, build on OSX 10 + Xcode 8
8182656: Make the required changes in GC code to build on OSX 10 + Xcode 8
8182657: Make the required changes in Runtime code to build on OSX 10 + Xcode 8
8182658: Make the required changes in Compiler code to build on OSX 10 + Xcode 8
Reviewed-by: jwilhelm, ehelin, phh
Contributed-by: phh <hohensee@amazon.com>, jwilhelm <jesper.wilhelmsson@oracle.com>
/*
* Copyright (c) 2010, 2017, Oracle and/or its affiliates. All rights reserved.
* DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
*
* This code is free software; you can redistribute it and/or modify it
* under the terms of the GNU General Public License version 2 only, as
* published by the Free Software Foundation.
*
* This code is distributed in the hope that it will be useful, but WITHOUT
* ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
* FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
* version 2 for more details (a copy is included in the LICENSE file that
* accompanied this code).
*
* You should have received a copy of the GNU General Public License version
* 2 along with this work; if not, write to the Free Software Foundation,
* Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA.
*
* Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA
* or visit www.oracle.com if you need additional information or have any
* questions.
*
*/
#include "precompiled.hpp"
#include "code/codeCache.hpp"
#include "runtime/advancedThresholdPolicy.hpp"
#include "runtime/simpleThresholdPolicy.inline.hpp"
#if INCLUDE_JVMCI
#include "jvmci/jvmciRuntime.hpp"
#endif
#ifdef TIERED
// Print an event.
void AdvancedThresholdPolicy::print_specific(EventType type, methodHandle mh, methodHandle imh,
int bci, CompLevel level) {
tty->print(" rate=");
if (mh->prev_time() == 0) tty->print("n/a");
else tty->print("%f", mh->rate());
tty->print(" k=%.2lf,%.2lf", threshold_scale(CompLevel_full_profile, Tier3LoadFeedback),
threshold_scale(CompLevel_full_optimization, Tier4LoadFeedback));
}
void AdvancedThresholdPolicy::initialize() {
int count = CICompilerCount;
#ifdef _LP64
// Turn on ergonomic compiler count selection
if (FLAG_IS_DEFAULT(CICompilerCountPerCPU) && FLAG_IS_DEFAULT(CICompilerCount)) {
FLAG_SET_DEFAULT(CICompilerCountPerCPU, true);
}
if (CICompilerCountPerCPU) {
// Simple log n seems to grow too slowly for tiered, try something faster: log n * log log n
int log_cpu = log2_intptr(os::active_processor_count());
int loglog_cpu = log2_intptr(MAX2(log_cpu, 1));
count = MAX2(log_cpu * loglog_cpu * 3 / 2, 2);
FLAG_SET_ERGO(intx, CICompilerCount, count);
}
#else
// On 32-bit systems, the number of compiler threads is limited to 3.
// On these systems, the virtual address space available to the JVM
// is usually limited to 2-4 GB (the exact value depends on the platform).
// As the compilers (especially C2) can consume a large amount of
// memory, scaling the number of compiler threads with the number of
// available cores can result in the exhaustion of the address space
/// available to the VM and thus cause the VM to crash.
if (FLAG_IS_DEFAULT(CICompilerCount)) {
count = 3;
FLAG_SET_ERGO(intx, CICompilerCount, count);
}
#endif
if (TieredStopAtLevel < CompLevel_full_optimization) {
// No C2 compiler thread required
set_c1_count(count);
} else {
set_c1_count(MAX2(count / 3, 1));
set_c2_count(MAX2(count - c1_count(), 1));
}
assert(count == c1_count() + c2_count(), "inconsistent compiler thread count");
// Some inlining tuning
#ifdef X86
if (FLAG_IS_DEFAULT(InlineSmallCode)) {
FLAG_SET_DEFAULT(InlineSmallCode, 2000);
}
#endif
#if defined SPARC || defined AARCH64
if (FLAG_IS_DEFAULT(InlineSmallCode)) {
FLAG_SET_DEFAULT(InlineSmallCode, 2500);
}
#endif
set_increase_threshold_at_ratio();
set_start_time(os::javaTimeMillis());
}
// update_rate() is called from select_task() while holding a compile queue lock.
void AdvancedThresholdPolicy::update_rate(jlong t, Method* m) {
// Skip update if counters are absent.
// Can't allocate them since we are holding compile queue lock.
if (m->method_counters() == NULL) return;
if (is_old(m)) {
// We don't remove old methods from the queue,
// so we can just zero the rate.
m->set_rate(0);
return;
}
// We don't update the rate if we've just came out of a safepoint.
// delta_s is the time since last safepoint in milliseconds.
jlong delta_s = t - SafepointSynchronize::end_of_last_safepoint();
jlong delta_t = t - (m->prev_time() != 0 ? m->prev_time() : start_time()); // milliseconds since the last measurement
// How many events were there since the last time?
int event_count = m->invocation_count() + m->backedge_count();
int delta_e = event_count - m->prev_event_count();
// We should be running for at least 1ms.
if (delta_s >= TieredRateUpdateMinTime) {
// And we must've taken the previous point at least 1ms before.
if (delta_t >= TieredRateUpdateMinTime && delta_e > 0) {
m->set_prev_time(t);
m->set_prev_event_count(event_count);
m->set_rate((float)delta_e / (float)delta_t); // Rate is events per millisecond
} else {
if (delta_t > TieredRateUpdateMaxTime && delta_e == 0) {
// If nothing happened for 25ms, zero the rate. Don't modify prev values.
m->set_rate(0);
}
}
}
}
// Check if this method has been stale from a given number of milliseconds.
// See select_task().
bool AdvancedThresholdPolicy::is_stale(jlong t, jlong timeout, Method* m) {
jlong delta_s = t - SafepointSynchronize::end_of_last_safepoint();
jlong delta_t = t - m->prev_time();
if (delta_t > timeout && delta_s > timeout) {
int event_count = m->invocation_count() + m->backedge_count();
int delta_e = event_count - m->prev_event_count();
// Return true if there were no events.
return delta_e == 0;
}
return false;
}
// We don't remove old methods from the compile queue even if they have
// very low activity. See select_task().
bool AdvancedThresholdPolicy::is_old(Method* method) {
return method->invocation_count() > 50000 || method->backedge_count() > 500000;
}
double AdvancedThresholdPolicy::weight(Method* method) {
return (double)(method->rate() + 1) *
(method->invocation_count() + 1) * (method->backedge_count() + 1);
}
// Apply heuristics and return true if x should be compiled before y
bool AdvancedThresholdPolicy::compare_methods(Method* x, Method* y) {
if (x->highest_comp_level() > y->highest_comp_level()) {
// recompilation after deopt
return true;
} else
if (x->highest_comp_level() == y->highest_comp_level()) {
if (weight(x) > weight(y)) {
return true;
}
}
return false;
}
// Is method profiled enough?
bool AdvancedThresholdPolicy::is_method_profiled(Method* method) {
MethodData* mdo = method->method_data();
if (mdo != NULL) {
int i = mdo->invocation_count_delta();
int b = mdo->backedge_count_delta();
return call_predicate_helper<CompLevel_full_profile>(i, b, 1, method);
}
return false;
}
// Called with the queue locked and with at least one element
CompileTask* AdvancedThresholdPolicy::select_task(CompileQueue* compile_queue) {
CompileTask *max_blocking_task = NULL;
CompileTask *max_task = NULL;
Method* max_method = NULL;
jlong t = os::javaTimeMillis();
// Iterate through the queue and find a method with a maximum rate.
for (CompileTask* task = compile_queue->first(); task != NULL;) {
CompileTask* next_task = task->next();
Method* method = task->method();
update_rate(t, method);
if (max_task == NULL) {
max_task = task;
max_method = method;
} else {
// If a method has been stale for some time, remove it from the queue.
// Blocking tasks and tasks submitted from whitebox API don't become stale
if (task->can_become_stale() && is_stale(t, TieredCompileTaskTimeout, method) && !is_old(method)) {
if (PrintTieredEvents) {
print_event(REMOVE_FROM_QUEUE, method, method, task->osr_bci(), (CompLevel)task->comp_level());
}
compile_queue->remove_and_mark_stale(task);
method->clear_queued_for_compilation();
task = next_task;
continue;
}
// Select a method with a higher rate
if (compare_methods(method, max_method)) {
max_task = task;
max_method = method;
}
}
if (task->is_blocking()) {
if (max_blocking_task == NULL || compare_methods(method, max_blocking_task->method())) {
max_blocking_task = task;
}
}
task = next_task;
}
if (max_blocking_task != NULL) {
// In blocking compilation mode, the CompileBroker will make
// compilations submitted by a JVMCI compiler thread non-blocking. These
// compilations should be scheduled after all blocking compilations
// to service non-compiler related compilations sooner and reduce the
// chance of such compilations timing out.
max_task = max_blocking_task;
max_method = max_task->method();
}
if (max_task->comp_level() == CompLevel_full_profile && TieredStopAtLevel > CompLevel_full_profile
&& is_method_profiled(max_method)) {
max_task->set_comp_level(CompLevel_limited_profile);
if (PrintTieredEvents) {
print_event(UPDATE_IN_QUEUE, max_method, max_method, max_task->osr_bci(), (CompLevel)max_task->comp_level());
}
}
return max_task;
}
double AdvancedThresholdPolicy::threshold_scale(CompLevel level, int feedback_k) {
double queue_size = CompileBroker::queue_size(level);
int comp_count = compiler_count(level);
double k = queue_size / (feedback_k * comp_count) + 1;
// Increase C1 compile threshold when the code cache is filled more
// than specified by IncreaseFirstTierCompileThresholdAt percentage.
// The main intention is to keep enough free space for C2 compiled code
// to achieve peak performance if the code cache is under stress.
if ((TieredStopAtLevel == CompLevel_full_optimization) && (level != CompLevel_full_optimization)) {
double current_reverse_free_ratio = CodeCache::reverse_free_ratio(CodeCache::get_code_blob_type(level));
if (current_reverse_free_ratio > _increase_threshold_at_ratio) {
k *= exp(current_reverse_free_ratio - _increase_threshold_at_ratio);
}
}
return k;
}
// Call and loop predicates determine whether a transition to a higher
// compilation level should be performed (pointers to predicate functions
// are passed to common()).
// Tier?LoadFeedback is basically a coefficient that determines of
// how many methods per compiler thread can be in the queue before
// the threshold values double.
bool AdvancedThresholdPolicy::loop_predicate(int i, int b, CompLevel cur_level, Method* method) {
switch(cur_level) {
case CompLevel_aot: {
double k = threshold_scale(CompLevel_full_profile, Tier3LoadFeedback);
return loop_predicate_helper<CompLevel_aot>(i, b, k, method);
}
case CompLevel_none:
case CompLevel_limited_profile: {
double k = threshold_scale(CompLevel_full_profile, Tier3LoadFeedback);
return loop_predicate_helper<CompLevel_none>(i, b, k, method);
}
case CompLevel_full_profile: {
double k = threshold_scale(CompLevel_full_optimization, Tier4LoadFeedback);
return loop_predicate_helper<CompLevel_full_profile>(i, b, k, method);
}
default:
return true;
}
}
bool AdvancedThresholdPolicy::call_predicate(int i, int b, CompLevel cur_level, Method* method) {
switch(cur_level) {
case CompLevel_aot: {
double k = threshold_scale(CompLevel_full_profile, Tier3LoadFeedback);
return call_predicate_helper<CompLevel_aot>(i, b, k, method);
}
case CompLevel_none:
case CompLevel_limited_profile: {
double k = threshold_scale(CompLevel_full_profile, Tier3LoadFeedback);
return call_predicate_helper<CompLevel_none>(i, b, k, method);
}
case CompLevel_full_profile: {
double k = threshold_scale(CompLevel_full_optimization, Tier4LoadFeedback);
return call_predicate_helper<CompLevel_full_profile>(i, b, k, method);
}
default:
return true;
}
}
// If a method is old enough and is still in the interpreter we would want to
// start profiling without waiting for the compiled method to arrive.
// We also take the load on compilers into the account.
bool AdvancedThresholdPolicy::should_create_mdo(Method* method, CompLevel cur_level) {
if (cur_level == CompLevel_none &&
CompileBroker::queue_size(CompLevel_full_optimization) <=
Tier3DelayOn * compiler_count(CompLevel_full_optimization)) {
int i = method->invocation_count();
int b = method->backedge_count();
double k = Tier0ProfilingStartPercentage / 100.0;
return call_predicate_helper<CompLevel_none>(i, b, k, method) || loop_predicate_helper<CompLevel_none>(i, b, k, method);
}
return false;
}
// Inlining control: if we're compiling a profiled method with C1 and the callee
// is known to have OSRed in a C2 version, don't inline it.
bool AdvancedThresholdPolicy::should_not_inline(ciEnv* env, ciMethod* callee) {
CompLevel comp_level = (CompLevel)env->comp_level();
if (comp_level == CompLevel_full_profile ||
comp_level == CompLevel_limited_profile) {
return callee->highest_osr_comp_level() == CompLevel_full_optimization;
}
return false;
}
// Create MDO if necessary.
void AdvancedThresholdPolicy::create_mdo(methodHandle mh, JavaThread* THREAD) {
if (mh->is_native() ||
mh->is_abstract() ||
mh->is_accessor() ||
mh->is_constant_getter()) {
return;
}
if (mh->method_data() == NULL) {
Method::build_interpreter_method_data(mh, CHECK_AND_CLEAR);
}
}
/*
* Method states:
* 0 - interpreter (CompLevel_none)
* 1 - pure C1 (CompLevel_simple)
* 2 - C1 with invocation and backedge counting (CompLevel_limited_profile)
* 3 - C1 with full profiling (CompLevel_full_profile)
* 4 - C2 (CompLevel_full_optimization)
*
* Common state transition patterns:
* a. 0 -> 3 -> 4.
* The most common path. But note that even in this straightforward case
* profiling can start at level 0 and finish at level 3.
*
* b. 0 -> 2 -> 3 -> 4.
* This case occurs when the load on C2 is deemed too high. So, instead of transitioning
* into state 3 directly and over-profiling while a method is in the C2 queue we transition to
* level 2 and wait until the load on C2 decreases. This path is disabled for OSRs.
*
* c. 0 -> (3->2) -> 4.
* In this case we enqueue a method for compilation at level 3, but the C1 queue is long enough
* to enable the profiling to fully occur at level 0. In this case we change the compilation level
* of the method to 2 while the request is still in-queue, because it'll allow it to run much faster
* without full profiling while c2 is compiling.
*
* d. 0 -> 3 -> 1 or 0 -> 2 -> 1.
* After a method was once compiled with C1 it can be identified as trivial and be compiled to
* level 1. These transition can also occur if a method can't be compiled with C2 but can with C1.
*
* e. 0 -> 4.
* This can happen if a method fails C1 compilation (it will still be profiled in the interpreter)
* or because of a deopt that didn't require reprofiling (compilation won't happen in this case because
* the compiled version already exists).
*
* Note that since state 0 can be reached from any other state via deoptimization different loops
* are possible.
*
*/
// Common transition function. Given a predicate determines if a method should transition to another level.
CompLevel AdvancedThresholdPolicy::common(Predicate p, Method* method, CompLevel cur_level, bool disable_feedback) {
CompLevel next_level = cur_level;
int i = method->invocation_count();
int b = method->backedge_count();
if (is_trivial(method)) {
next_level = CompLevel_simple;
} else {
switch(cur_level) {
default: break;
case CompLevel_aot: {
// If we were at full profile level, would we switch to full opt?
if (common(p, method, CompLevel_full_profile, disable_feedback) == CompLevel_full_optimization) {
next_level = CompLevel_full_optimization;
} else if (disable_feedback || (CompileBroker::queue_size(CompLevel_full_optimization) <=
Tier3DelayOff * compiler_count(CompLevel_full_optimization) &&
(this->*p)(i, b, cur_level, method))) {
next_level = CompLevel_full_profile;
}
}
break;
case CompLevel_none:
// If we were at full profile level, would we switch to full opt?
if (common(p, method, CompLevel_full_profile, disable_feedback) == CompLevel_full_optimization) {
next_level = CompLevel_full_optimization;
} else if ((this->*p)(i, b, cur_level, method)) {
#if INCLUDE_JVMCI
if (EnableJVMCI && UseJVMCICompiler) {
// Since JVMCI takes a while to warm up, its queue inevitably backs up during
// early VM execution. As of 2014-06-13, JVMCI's inliner assumes that the root
// compilation method and all potential inlinees have mature profiles (which
// includes type profiling). If it sees immature profiles, JVMCI's inliner
// can perform pathologically bad (e.g., causing OutOfMemoryErrors due to
// exploring/inlining too many graphs). Since a rewrite of the inliner is
// in progress, we simply disable the dialing back heuristic for now and will
// revisit this decision once the new inliner is completed.
next_level = CompLevel_full_profile;
} else
#endif
{
// C1-generated fully profiled code is about 30% slower than the limited profile
// code that has only invocation and backedge counters. The observation is that
// if C2 queue is large enough we can spend too much time in the fully profiled code
// while waiting for C2 to pick the method from the queue. To alleviate this problem
// we introduce a feedback on the C2 queue size. If the C2 queue is sufficiently long
// we choose to compile a limited profiled version and then recompile with full profiling
// when the load on C2 goes down.
if (!disable_feedback && CompileBroker::queue_size(CompLevel_full_optimization) >
Tier3DelayOn * compiler_count(CompLevel_full_optimization)) {
next_level = CompLevel_limited_profile;
} else {
next_level = CompLevel_full_profile;
}
}
}
break;
case CompLevel_limited_profile:
if (is_method_profiled(method)) {
// Special case: we got here because this method was fully profiled in the interpreter.
next_level = CompLevel_full_optimization;
} else {
MethodData* mdo = method->method_data();
if (mdo != NULL) {
if (mdo->would_profile()) {
if (disable_feedback || (CompileBroker::queue_size(CompLevel_full_optimization) <=
Tier3DelayOff * compiler_count(CompLevel_full_optimization) &&
(this->*p)(i, b, cur_level, method))) {
next_level = CompLevel_full_profile;
}
} else {
next_level = CompLevel_full_optimization;
}
} else {
// If there is no MDO we need to profile
if (disable_feedback || (CompileBroker::queue_size(CompLevel_full_optimization) <=
Tier3DelayOff * compiler_count(CompLevel_full_optimization) &&
(this->*p)(i, b, cur_level, method))) {
next_level = CompLevel_full_profile;
}
}
}
break;
case CompLevel_full_profile:
{
MethodData* mdo = method->method_data();
if (mdo != NULL) {
if (mdo->would_profile()) {
int mdo_i = mdo->invocation_count_delta();
int mdo_b = mdo->backedge_count_delta();
if ((this->*p)(mdo_i, mdo_b, cur_level, method)) {
next_level = CompLevel_full_optimization;
}
} else {
next_level = CompLevel_full_optimization;
}
}
}
break;
}
}
return MIN2(next_level, (CompLevel)TieredStopAtLevel);
}
// Determine if a method should be compiled with a normal entry point at a different level.
CompLevel AdvancedThresholdPolicy::call_event(Method* method, CompLevel cur_level, JavaThread * thread) {
CompLevel osr_level = MIN2((CompLevel) method->highest_osr_comp_level(),
common(&AdvancedThresholdPolicy::loop_predicate, method, cur_level, true));
CompLevel next_level = common(&AdvancedThresholdPolicy::call_predicate, method, cur_level);
// If OSR method level is greater than the regular method level, the levels should be
// equalized by raising the regular method level in order to avoid OSRs during each
// invocation of the method.
if (osr_level == CompLevel_full_optimization && cur_level == CompLevel_full_profile) {
MethodData* mdo = method->method_data();
guarantee(mdo != NULL, "MDO should not be NULL");
if (mdo->invocation_count() >= 1) {
next_level = CompLevel_full_optimization;
}
} else {
next_level = MAX2(osr_level, next_level);
}
#if INCLUDE_JVMCI
if (UseJVMCICompiler) {
next_level = JVMCIRuntime::adjust_comp_level(method, false, next_level, thread);
}
#endif
return next_level;
}
// Determine if we should do an OSR compilation of a given method.
CompLevel AdvancedThresholdPolicy::loop_event(Method* method, CompLevel cur_level, JavaThread * thread) {
CompLevel next_level = common(&AdvancedThresholdPolicy::loop_predicate, method, cur_level, true);
if (cur_level == CompLevel_none) {
// If there is a live OSR method that means that we deopted to the interpreter
// for the transition.
CompLevel osr_level = MIN2((CompLevel)method->highest_osr_comp_level(), next_level);
if (osr_level > CompLevel_none) {
return osr_level;
}
}
#if INCLUDE_JVMCI
if (UseJVMCICompiler) {
next_level = JVMCIRuntime::adjust_comp_level(method, true, next_level, thread);
}
#endif
return next_level;
}
// Update the rate and submit compile
void AdvancedThresholdPolicy::submit_compile(const methodHandle& mh, int bci, CompLevel level, JavaThread* thread) {
int hot_count = (bci == InvocationEntryBci) ? mh->invocation_count() : mh->backedge_count();
update_rate(os::javaTimeMillis(), mh());
CompileBroker::compile_method(mh, bci, level, mh, hot_count, CompileTask::Reason_Tiered, thread);
}
bool AdvancedThresholdPolicy::maybe_switch_to_aot(methodHandle mh, CompLevel cur_level, CompLevel next_level, JavaThread* thread) {
if (UseAOT && !delay_compilation_during_startup()) {
if (cur_level == CompLevel_full_profile || cur_level == CompLevel_none) {
// If the current level is full profile or interpreter and we're switching to any other level,
// activate the AOT code back first so that we won't waste time overprofiling.
compile(mh, InvocationEntryBci, CompLevel_aot, thread);
// Fall through for JIT compilation.
}
if (next_level == CompLevel_limited_profile && cur_level != CompLevel_aot && mh->has_aot_code()) {
// If the next level is limited profile, use the aot code (if there is any),
// since it's essentially the same thing.
compile(mh, InvocationEntryBci, CompLevel_aot, thread);
// Not need to JIT, we're done.
return true;
}
}
return false;
}
// Handle the invocation event.
void AdvancedThresholdPolicy::method_invocation_event(const methodHandle& mh, const methodHandle& imh,
CompLevel level, CompiledMethod* nm, JavaThread* thread) {
if (should_create_mdo(mh(), level)) {
create_mdo(mh, thread);
}
CompLevel next_level = call_event(mh(), level, thread);
if (next_level != level) {
if (maybe_switch_to_aot(mh, level, next_level, thread)) {
// No JITting necessary
return;
}
if (is_compilation_enabled() && !CompileBroker::compilation_is_in_queue(mh)) {
compile(mh, InvocationEntryBci, next_level, thread);
}
}
}
// Handle the back branch event. Notice that we can compile the method
// with a regular entry from here.
void AdvancedThresholdPolicy::method_back_branch_event(const methodHandle& mh, const methodHandle& imh,
int bci, CompLevel level, CompiledMethod* nm, JavaThread* thread) {
if (should_create_mdo(mh(), level)) {
create_mdo(mh, thread);
}
// Check if MDO should be created for the inlined method
if (should_create_mdo(imh(), level)) {
create_mdo(imh, thread);
}
if (is_compilation_enabled()) {
CompLevel next_osr_level = loop_event(imh(), level, thread);
CompLevel max_osr_level = (CompLevel)imh->highest_osr_comp_level();
// At the very least compile the OSR version
if (!CompileBroker::compilation_is_in_queue(imh) && (next_osr_level != level)) {
compile(imh, bci, next_osr_level, thread);
}
// Use loop event as an opportunity to also check if there's been
// enough calls.
CompLevel cur_level, next_level;
if (mh() != imh()) { // If there is an enclosing method
if (level == CompLevel_aot) {
// Recompile the enclosing method to prevent infinite OSRs. Stay at AOT level while it's compiling.
if (max_osr_level != CompLevel_none && !CompileBroker::compilation_is_in_queue(mh)) {
compile(mh, InvocationEntryBci, MIN2((CompLevel)TieredStopAtLevel, CompLevel_full_profile), thread);
}
} else {
// Current loop event level is not AOT
guarantee(nm != NULL, "Should have nmethod here");
cur_level = comp_level(mh());
next_level = call_event(mh(), cur_level, thread);
if (max_osr_level == CompLevel_full_optimization) {
// The inlinee OSRed to full opt, we need to modify the enclosing method to avoid deopts
bool make_not_entrant = false;
if (nm->is_osr_method()) {
// This is an osr method, just make it not entrant and recompile later if needed
make_not_entrant = true;
} else {
if (next_level != CompLevel_full_optimization) {
// next_level is not full opt, so we need to recompile the
// enclosing method without the inlinee
cur_level = CompLevel_none;
make_not_entrant = true;
}
}
if (make_not_entrant) {
if (PrintTieredEvents) {
int osr_bci = nm->is_osr_method() ? nm->osr_entry_bci() : InvocationEntryBci;
print_event(MAKE_NOT_ENTRANT, mh(), mh(), osr_bci, level);
}
nm->make_not_entrant();
}
}
// Fix up next_level if necessary to avoid deopts
if (next_level == CompLevel_limited_profile && max_osr_level == CompLevel_full_profile) {
next_level = CompLevel_full_profile;
}
if (cur_level != next_level) {
if (!maybe_switch_to_aot(mh, cur_level, next_level, thread) && !CompileBroker::compilation_is_in_queue(mh)) {
compile(mh, InvocationEntryBci, next_level, thread);
}
}
}
} else {
cur_level = comp_level(mh());
next_level = call_event(mh(), cur_level, thread);
if (next_level != cur_level) {
if (!maybe_switch_to_aot(mh, cur_level, next_level, thread) && !CompileBroker::compilation_is_in_queue(mh)) {
compile(mh, InvocationEntryBci, next_level, thread);
}
}
}
}
}
#endif // TIERED