/* * Copyright (c) 1998, 2013, 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 "ci/ciReplay.hpp" #include "classfile/systemDictionary.hpp" #include "classfile/vmSymbols.hpp" #include "compiler/compileBroker.hpp" #include "compiler/compileLog.hpp" #include "interpreter/linkResolver.hpp" #include "jfr/jfrEvents.hpp" #include "oops/objArrayKlass.hpp" #include "opto/callGenerator.hpp" #include "opto/parse.hpp" #include "runtime/handles.inline.hpp" //============================================================================= //------------------------------InlineTree------------------------------------- InlineTree::InlineTree(Compile* c, const InlineTree *caller_tree, ciMethod* callee, JVMState* caller_jvms, int caller_bci, float site_invoke_ratio, int max_inline_level) : C(c), _caller_jvms(caller_jvms), _caller_tree((InlineTree*) caller_tree), _method(callee), _site_invoke_ratio(site_invoke_ratio), _max_inline_level(max_inline_level), _count_inline_bcs(method()->code_size_for_inlining()), _subtrees(c->comp_arena(), 2, 0, NULL), _msg(NULL) { #ifndef PRODUCT _count_inlines = 0; _forced_inline = false; #endif if (_caller_jvms != NULL) { // Keep a private copy of the caller_jvms: _caller_jvms = new (C) JVMState(caller_jvms->method(), caller_tree->caller_jvms()); _caller_jvms->set_bci(caller_jvms->bci()); assert(!caller_jvms->should_reexecute(), "there should be no reexecute bytecode with inlining"); } assert(_caller_jvms->same_calls_as(caller_jvms), "consistent JVMS"); assert((caller_tree == NULL ? 0 : caller_tree->stack_depth() + 1) == stack_depth(), "correct (redundant) depth parameter"); assert(caller_bci == this->caller_bci(), "correct (redundant) bci parameter"); // Update hierarchical counts, count_inline_bcs() and count_inlines() InlineTree *caller = (InlineTree *)caller_tree; for( ; caller != NULL; caller = ((InlineTree *)(caller->caller_tree())) ) { caller->_count_inline_bcs += count_inline_bcs(); NOT_PRODUCT(caller->_count_inlines++;) } } /** * Return true when EA is ON and a java constructor is called or * a super constructor is called from an inlined java constructor. * Also return true for boxing methods. */ static bool is_init_with_ea(ciMethod* callee_method, ciMethod* caller_method, Compile* C) { if (!C->do_escape_analysis() || !EliminateAllocations) { return false; // EA is off } if (callee_method->is_initializer()) { return true; // constuctor } if (caller_method->is_initializer() && caller_method != C->method() && caller_method->holder()->is_subclass_of(callee_method->holder())) { return true; // super constructor is called from inlined constructor } if (C->eliminate_boxing() && callee_method->is_boxing_method()) { return true; } return false; } /** * Force inlining unboxing accessor. */ static bool is_unboxing_method(ciMethod* callee_method, Compile* C) { return C->eliminate_boxing() && callee_method->is_unboxing_method(); } // positive filter: should callee be inlined? bool InlineTree::should_inline(ciMethod* callee_method, ciMethod* caller_method, int caller_bci, ciCallProfile& profile, WarmCallInfo* wci_result) { // Allows targeted inlining if (callee_method->should_inline()) { *wci_result = *(WarmCallInfo::always_hot()); if (C->print_inlining() && Verbose) { CompileTask::print_inline_indent(inline_level()); tty->print_cr("Inlined method is hot: "); } set_msg("force inline by CompilerOracle"); _forced_inline = true; return true; } if (callee_method->force_inline()) { set_msg("force inline by annotation"); _forced_inline = true; return true; } #ifndef PRODUCT int inline_depth = inline_level()+1; if (ciReplay::should_inline(C->replay_inline_data(), callee_method, caller_bci, inline_depth)) { set_msg("force inline by ciReplay"); _forced_inline = true; return true; } #endif int size = callee_method->code_size_for_inlining(); // Check for too many throws (and not too huge) if(callee_method->interpreter_throwout_count() > InlineThrowCount && size < InlineThrowMaxSize ) { wci_result->set_profit(wci_result->profit() * 100); if (C->print_inlining() && Verbose) { CompileTask::print_inline_indent(inline_level()); tty->print_cr("Inlined method with many throws (throws=%d):", callee_method->interpreter_throwout_count()); } set_msg("many throws"); return true; } int default_max_inline_size = C->max_inline_size(); int inline_small_code_size = InlineSmallCode / 4; int max_inline_size = default_max_inline_size; int call_site_count = method()->scale_count(profile.count()); int invoke_count = method()->interpreter_invocation_count(); assert(invoke_count != 0, "require invocation count greater than zero"); int freq = call_site_count / invoke_count; // bump the max size if the call is frequent if ((freq >= InlineFrequencyRatio) || (call_site_count >= InlineFrequencyCount) || is_unboxing_method(callee_method, C) || is_init_with_ea(callee_method, caller_method, C)) { max_inline_size = C->freq_inline_size(); if (size <= max_inline_size && TraceFrequencyInlining) { CompileTask::print_inline_indent(inline_level()); tty->print_cr("Inlined frequent method (freq=%d count=%d):", freq, call_site_count); CompileTask::print_inline_indent(inline_level()); callee_method->print(); tty->cr(); } } else { // Not hot. Check for medium-sized pre-existing nmethod at cold sites. if (callee_method->has_compiled_code() && callee_method->instructions_size() > inline_small_code_size) { set_msg("already compiled into a medium method"); return false; } } if (size > max_inline_size) { if (max_inline_size > default_max_inline_size) { set_msg("hot method too big"); } else { set_msg("too big"); } return false; } return true; } // negative filter: should callee NOT be inlined? bool InlineTree::should_not_inline(ciMethod *callee_method, ciMethod* caller_method, JVMState* jvms, WarmCallInfo* wci_result) { const char* fail_msg = NULL; // First check all inlining restrictions which are required for correctness if ( callee_method->is_abstract()) { fail_msg = "abstract method"; // // note: we allow ik->is_abstract() } else if (!callee_method->holder()->is_initialized()) { fail_msg = "method holder not initialized"; } else if ( callee_method->is_native()) { fail_msg = "native method"; } else if ( callee_method->dont_inline()) { fail_msg = "don't inline by annotation"; } // one more inlining restriction if (fail_msg == NULL && callee_method->has_unloaded_classes_in_signature()) { fail_msg = "unloaded signature classes"; } if (fail_msg != NULL) { set_msg(fail_msg); return true; } // ignore heuristic controls on inlining if (callee_method->should_inline()) { set_msg("force inline by CompilerOracle"); return false; } if (callee_method->should_not_inline()) { set_msg("disallowed by CompilerOracle"); return true; } #ifndef PRODUCT int caller_bci = jvms->bci(); int inline_depth = inline_level()+1; if (ciReplay::should_inline(C->replay_inline_data(), callee_method, caller_bci, inline_depth)) { set_msg("force inline by ciReplay"); return false; } if (ciReplay::should_not_inline(C->replay_inline_data(), callee_method, caller_bci, inline_depth)) { set_msg("disallowed by ciReplay"); return true; } if (ciReplay::should_not_inline(callee_method)) { set_msg("disallowed by ciReplay"); return true; } #endif if (callee_method->force_inline()) { set_msg("force inline by annotation"); return false; } // Now perform checks which are heuristic if (is_unboxing_method(callee_method, C)) { // Inline unboxing methods. return false; } if (callee_method->has_compiled_code() && callee_method->instructions_size() > InlineSmallCode) { set_msg("already compiled into a big method"); return true; } // don't inline exception code unless the top method belongs to an // exception class if (caller_tree() != NULL && callee_method->holder()->is_subclass_of(C->env()->Throwable_klass())) { const InlineTree *top = this; while (top->caller_tree() != NULL) top = top->caller_tree(); ciInstanceKlass* k = top->method()->holder(); if (!k->is_subclass_of(C->env()->Throwable_klass())) { set_msg("exception method"); return true; } } // use frequency-based objections only for non-trivial methods if (callee_method->code_size() <= MaxTrivialSize) { return false; } // don't use counts with -Xcomp or CTW if (UseInterpreter && !CompileTheWorld) { if (!callee_method->has_compiled_code() && !callee_method->was_executed_more_than(0)) { set_msg("never executed"); return true; } if (is_init_with_ea(callee_method, caller_method, C)) { // Escape Analysis: inline all executed constructors return false; } else if (!callee_method->was_executed_more_than(MIN2(MinInliningThreshold, CompileThreshold >> 1))) { set_msg("executed < MinInliningThreshold times"); return true; } } return false; } //-----------------------------try_to_inline----------------------------------- // return true if ok // Relocated from "InliningClosure::try_to_inline" bool InlineTree::try_to_inline(ciMethod* callee_method, ciMethod* caller_method, int caller_bci, JVMState* jvms, ciCallProfile& profile, WarmCallInfo* wci_result, bool& should_delay) { if (ClipInlining && (int)count_inline_bcs() >= DesiredMethodLimit) { if (!callee_method->force_inline() || !IncrementalInline) { set_msg("size > DesiredMethodLimit"); return false; } else if (!C->inlining_incrementally()) { should_delay = true; } } _forced_inline = false; // Reset if (!should_inline(callee_method, caller_method, caller_bci, profile, wci_result)) { return false; } if (should_not_inline(callee_method, caller_method, jvms, wci_result)) { return false; } if (InlineAccessors && callee_method->is_accessor()) { // accessor methods are not subject to any of the following limits. set_msg("accessor"); return true; } // suppress a few checks for accessors and trivial methods if (callee_method->code_size() > MaxTrivialSize) { // don't inline into giant methods if (C->over_inlining_cutoff()) { if ((!callee_method->force_inline() && !caller_method->is_compiled_lambda_form()) || !IncrementalInline) { set_msg("NodeCountInliningCutoff"); return false; } else { should_delay = true; } } if ((!UseInterpreter || CompileTheWorld) && is_init_with_ea(callee_method, caller_method, C)) { // Escape Analysis stress testing when running Xcomp or CTW: // inline constructors even if they are not reached. } else if (forced_inline()) { // Inlining was forced by CompilerOracle, ciReplay or annotation } else if (profile.count() == 0) { // don't inline unreached call sites set_msg("call site not reached"); return false; } } if (!C->do_inlining() && InlineAccessors) { set_msg("not an accessor"); return false; } // Limit inlining depth in case inlining is forced or // _max_inline_level was increased to compensate for lambda forms. if (inline_level() > MaxForceInlineLevel) { set_msg("MaxForceInlineLevel"); return false; } if (inline_level() > _max_inline_level) { if (!callee_method->force_inline() || !IncrementalInline) { set_msg("inlining too deep"); return false; } else if (!C->inlining_incrementally()) { should_delay = true; } } // detect direct and indirect recursive inlining { // count the current method and the callee const bool is_compiled_lambda_form = callee_method->is_compiled_lambda_form(); int inline_level = 0; if (!is_compiled_lambda_form) { if (method() == callee_method) { inline_level++; } } // count callers of current method and callee Node* callee_argument0 = is_compiled_lambda_form ? jvms->map()->argument(jvms, 0)->uncast() : NULL; for (JVMState* j = jvms->caller(); j != NULL && j->has_method(); j = j->caller()) { if (j->method() == callee_method) { if (is_compiled_lambda_form) { // Since compiled lambda forms are heavily reused we allow recursive inlining. If it is truly // a recursion (using the same "receiver") we limit inlining otherwise we can easily blow the // compiler stack. Node* caller_argument0 = j->map()->argument(j, 0)->uncast(); if (caller_argument0 == callee_argument0) { inline_level++; } } else { inline_level++; } } } if (inline_level > MaxRecursiveInlineLevel) { set_msg("recursive inlining is too deep"); return false; } } int size = callee_method->code_size_for_inlining(); if (ClipInlining && (int)count_inline_bcs() + size >= DesiredMethodLimit) { if (!callee_method->force_inline() || !IncrementalInline) { set_msg("size > DesiredMethodLimit"); return false; } else if (!C->inlining_incrementally()) { should_delay = true; } } // ok, inline this method return true; } //------------------------------pass_initial_checks---------------------------- bool pass_initial_checks(ciMethod* caller_method, int caller_bci, ciMethod* callee_method) { ciInstanceKlass *callee_holder = callee_method ? callee_method->holder() : NULL; // Check if a callee_method was suggested if( callee_method == NULL ) return false; // Check if klass of callee_method is loaded if( !callee_holder->is_loaded() ) return false; if( !callee_holder->is_initialized() ) return false; if( !UseInterpreter || CompileTheWorld /* running Xcomp or CTW */ ) { // Checks that constant pool's call site has been visited // stricter than callee_holder->is_initialized() ciBytecodeStream iter(caller_method); iter.force_bci(caller_bci); Bytecodes::Code call_bc = iter.cur_bc(); // An invokedynamic instruction does not have a klass. if (call_bc != Bytecodes::_invokedynamic) { int index = iter.get_index_u2_cpcache(); if (!caller_method->is_klass_loaded(index, true)) { return false; } // Try to do constant pool resolution if running Xcomp if( !caller_method->check_call(index, call_bc == Bytecodes::_invokestatic) ) { return false; } } } // We will attempt to see if a class/field/etc got properly loaded. If it // did not, it may attempt to throw an exception during our probing. Catch // and ignore such exceptions and do not attempt to compile the method. if( callee_method->should_exclude() ) return false; return true; } //------------------------------check_can_parse-------------------------------- const char* InlineTree::check_can_parse(ciMethod* callee) { // Certain methods cannot be parsed at all: if ( callee->is_native()) return "native method"; if ( callee->is_abstract()) return "abstract method"; if (!callee->can_be_compiled()) return "not compilable (disabled)"; if (!callee->has_balanced_monitors()) return "not compilable (unbalanced monitors)"; if ( callee->get_flow_analysis()->failing()) return "not compilable (flow analysis failed)"; return NULL; } static void post_inlining_event(int compile_id,const char* msg, bool success, int bci, ciMethod* caller, ciMethod* callee) { assert(caller != NULL, "invariant"); assert(callee != NULL, "invariant"); EventCompilerInlining event; if (event.should_commit()) { JfrStructCalleeMethod callee_struct; callee_struct.set_type(callee->holder()->name()->as_utf8()); callee_struct.set_name(callee->name()->as_utf8()); callee_struct.set_descriptor(callee->signature()->as_symbol()->as_utf8()); event.set_compileId(compile_id); event.set_message(msg); event.set_succeeded(success); event.set_bci(bci); event.set_caller(caller->get_Method()); event.set_callee(callee_struct); event.commit(); } } //------------------------------print_inlining--------------------------------- void InlineTree::print_inlining(ciMethod* callee_method, int caller_bci, ciMethod* caller_method, bool success) const { const char* inline_msg = msg(); assert(inline_msg != NULL, "just checking"); if (C->log() != NULL) { if (success) { C->log()->inline_success(inline_msg); } else { C->log()->inline_fail(inline_msg); } } if (C->print_inlining()) { C->print_inlining(callee_method, inline_level(), caller_bci, inline_msg); if (callee_method == NULL) tty->print(" callee not monotonic or profiled"); if (Verbose && callee_method) { const InlineTree *top = this; while( top->caller_tree() != NULL ) { top = top->caller_tree(); } //tty->print(" bcs: %d+%d invoked: %d", top->count_inline_bcs(), callee_method->code_size(), callee_method->interpreter_invocation_count()); } } post_inlining_event(C->compile_id(), inline_msg, success, caller_bci, caller_method, callee_method); } //------------------------------ok_to_inline----------------------------------- WarmCallInfo* InlineTree::ok_to_inline(ciMethod* callee_method, JVMState* jvms, ciCallProfile& profile, WarmCallInfo* initial_wci, bool& should_delay) { assert(callee_method != NULL, "caller checks for optimized virtual!"); assert(!should_delay, "should be initialized to false"); #ifdef ASSERT // Make sure the incoming jvms has the same information content as me. // This means that we can eventually make this whole class AllStatic. if (jvms->caller() == NULL) { assert(_caller_jvms == NULL, "redundant instance state"); } else { assert(_caller_jvms->same_calls_as(jvms->caller()), "redundant instance state"); } assert(_method == jvms->method(), "redundant instance state"); #endif int caller_bci = jvms->bci(); ciMethod* caller_method = jvms->method(); // Do some initial checks. if (!pass_initial_checks(caller_method, caller_bci, callee_method)) { set_msg("failed initial checks"); print_inlining(callee_method, caller_bci, caller_method, false /* !success */); return NULL; } // Do some parse checks. set_msg(check_can_parse(callee_method)); if (msg() != NULL) { print_inlining(callee_method, caller_bci, caller_method, false /* !success */); return NULL; } // Check if inlining policy says no. WarmCallInfo wci = *(initial_wci); bool success = try_to_inline(callee_method, caller_method, caller_bci, jvms, profile, &wci, should_delay); #ifndef PRODUCT if (InlineWarmCalls && (PrintOpto || C->print_inlining())) { bool cold = wci.is_cold(); bool hot = !cold && wci.is_hot(); bool old_cold = !success; if (old_cold != cold || (Verbose || WizardMode)) { if (msg() == NULL) { set_msg("OK"); } tty->print(" OldInlining= %4s : %s\n WCI=", old_cold ? "cold" : "hot", msg()); wci.print(); } } #endif if (success) { wci = *(WarmCallInfo::always_hot()); } else { wci = *(WarmCallInfo::always_cold()); } if (!InlineWarmCalls) { if (!wci.is_cold() && !wci.is_hot()) { // Do not inline the warm calls. wci = *(WarmCallInfo::always_cold()); } } if (!wci.is_cold()) { // Inline! if (msg() == NULL) { set_msg("inline (hot)"); } print_inlining(callee_method, caller_bci, caller_method, true /* success */); build_inline_tree_for_callee(callee_method, jvms, caller_bci); if (InlineWarmCalls && !wci.is_hot()) return new (C) WarmCallInfo(wci); // copy to heap return WarmCallInfo::always_hot(); } // Do not inline if (msg() == NULL) { set_msg("too cold to inline"); } print_inlining(callee_method, caller_bci, caller_method, false /* !success */ ); return NULL; } //------------------------------compute_callee_frequency----------------------- float InlineTree::compute_callee_frequency( int caller_bci ) const { int count = method()->interpreter_call_site_count(caller_bci); int invcnt = method()->interpreter_invocation_count(); float freq = (float)count/(float)invcnt; // Call-site count / interpreter invocation count, scaled recursively. // Always between 0.0 and 1.0. Represents the percentage of the method's // total execution time used at this call site. return freq; } //------------------------------build_inline_tree_for_callee------------------- InlineTree *InlineTree::build_inline_tree_for_callee( ciMethod* callee_method, JVMState* caller_jvms, int caller_bci) { float recur_frequency = _site_invoke_ratio * compute_callee_frequency(caller_bci); // Attempt inlining. InlineTree* old_ilt = callee_at(caller_bci, callee_method); if (old_ilt != NULL) { return old_ilt; } int max_inline_level_adjust = 0; if (caller_jvms->method() != NULL) { if (caller_jvms->method()->is_compiled_lambda_form()) { max_inline_level_adjust += 1; // don't count actions in MH or indy adapter frames } else if (callee_method->is_method_handle_intrinsic() || callee_method->is_compiled_lambda_form()) { max_inline_level_adjust += 1; // don't count method handle calls from java.lang.invoke implementation } if (max_inline_level_adjust != 0 && C->print_inlining() && (Verbose || WizardMode)) { CompileTask::print_inline_indent(inline_level()); tty->print_cr(" \\-> discounting inline depth"); } if (max_inline_level_adjust != 0 && C->log()) { int id1 = C->log()->identify(caller_jvms->method()); int id2 = C->log()->identify(callee_method); C->log()->elem("inline_level_discount caller='%d' callee='%d'", id1, id2); } } InlineTree* ilt = new InlineTree(C, this, callee_method, caller_jvms, caller_bci, recur_frequency, _max_inline_level + max_inline_level_adjust); _subtrees.append(ilt); NOT_PRODUCT( _count_inlines += 1; ) return ilt; } //---------------------------------------callee_at----------------------------- InlineTree *InlineTree::callee_at(int bci, ciMethod* callee) const { for (int i = 0; i < _subtrees.length(); i++) { InlineTree* sub = _subtrees.at(i); if (sub->caller_bci() == bci && callee == sub->method()) { return sub; } } return NULL; } //------------------------------build_inline_tree_root------------------------- InlineTree *InlineTree::build_inline_tree_root() { Compile* C = Compile::current(); // Root of inline tree InlineTree* ilt = new InlineTree(C, NULL, C->method(), NULL, -1, 1.0F, MaxInlineLevel); return ilt; } //-------------------------find_subtree_from_root----------------------------- // Given a jvms, which determines a call chain from the root method, // find the corresponding inline tree. // Note: This method will be removed or replaced as InlineTree goes away. InlineTree* InlineTree::find_subtree_from_root(InlineTree* root, JVMState* jvms, ciMethod* callee) { InlineTree* iltp = root; uint depth = jvms && jvms->has_method() ? jvms->depth() : 0; for (uint d = 1; d <= depth; d++) { JVMState* jvmsp = jvms->of_depth(d); // Select the corresponding subtree for this bci. assert(jvmsp->method() == iltp->method(), "tree still in sync"); ciMethod* d_callee = (d == depth) ? callee : jvms->of_depth(d+1)->method(); InlineTree* sub = iltp->callee_at(jvmsp->bci(), d_callee); if (sub == NULL) { if (d == depth) { sub = iltp->build_inline_tree_for_callee(d_callee, jvmsp, jvmsp->bci()); } guarantee(sub != NULL, "should be a sub-ilt here"); return sub; } iltp = sub; } return iltp; } // Count number of nodes in this subtree int InlineTree::count() const { int result = 1; for (int i = 0 ; i < _subtrees.length(); i++) { result += _subtrees.at(i)->count(); } return result; } void InlineTree::dump_replay_data(outputStream* out) { out->print(" %d %d ", inline_level(), caller_bci()); method()->dump_name_as_ascii(out); for (int i = 0 ; i < _subtrees.length(); i++) { _subtrees.at(i)->dump_replay_data(out); } } #ifndef PRODUCT void InlineTree::print_impl(outputStream* st, int indent) const { for (int i = 0; i < indent; i++) st->print(" "); st->print(" @ %d", caller_bci()); method()->print_short_name(st); st->cr(); for (int i = 0 ; i < _subtrees.length(); i++) { _subtrees.at(i)->print_impl(st, indent + 2); } } void InlineTree::print_value_on(outputStream* st) const { print_impl(st, 2); } #endif