Mercurial > jdk8-mips64-public > hotspot / file revision

 /*

  * Copyright (c) 1997, 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 "code/nmethod.hpp"

 #include "compiler/compileBroker.hpp"

 #include "opto/compile.hpp"

 #include "opto/matcher.hpp"

 #include "opto/node.hpp"

 #include "opto/phase.hpp"

 #ifndef PRODUCT

 int Phase::_total_bytes_compiled = 0;

 elapsedTimer Phase::_t_totalCompilation;

 elapsedTimer Phase::_t_methodCompilation;

 elapsedTimer Phase::_t_stubCompilation;

 #endif

 // The next timers used for LogCompilation

 elapsedTimer Phase::_t_parser;

 elapsedTimer Phase::_t_optimizer;

 elapsedTimer   Phase::_t_escapeAnalysis;

 elapsedTimer     Phase::_t_connectionGraph;

 elapsedTimer   Phase::_t_idealLoop;

 elapsedTimer   Phase::_t_ccp;

 elapsedTimer Phase::_t_matcher;

 elapsedTimer Phase::_t_registerAllocation;

 elapsedTimer Phase::_t_output;

 #ifndef PRODUCT

 elapsedTimer Phase::_t_graphReshaping;

 elapsedTimer Phase::_t_scheduler;

 elapsedTimer Phase::_t_blockOrdering;

 elapsedTimer Phase::_t_macroEliminate;

 elapsedTimer Phase::_t_macroExpand;

 elapsedTimer Phase::_t_peephole;

 elapsedTimer Phase::_t_postalloc_expand;

 elapsedTimer Phase::_t_codeGeneration;

 elapsedTimer Phase::_t_registerMethod;

 elapsedTimer Phase::_t_temporaryTimer1;

 elapsedTimer Phase::_t_temporaryTimer2;

 elapsedTimer Phase::_t_idealLoopVerify;

 // Subtimers for _t_optimizer

 elapsedTimer   Phase::_t_iterGVN;

 elapsedTimer   Phase::_t_iterGVN2;

 elapsedTimer   Phase::_t_incrInline;

 // Subtimers for _t_registerAllocation

 elapsedTimer   Phase::_t_ctorChaitin;

 elapsedTimer   Phase::_t_buildIFGphysical;

 elapsedTimer   Phase::_t_computeLive;

 elapsedTimer   Phase::_t_regAllocSplit;

 elapsedTimer   Phase::_t_postAllocCopyRemoval;

 elapsedTimer   Phase::_t_fixupSpills;

 // Subtimers for _t_output

 elapsedTimer   Phase::_t_instrSched;

 elapsedTimer   Phase::_t_buildOopMaps;

 #endif

 //------------------------------Phase------------------------------------------

 Phase::Phase( PhaseNumber pnum ) : _pnum(pnum), C( pnum == Compiler ? NULL : Compile::current()) {

   // Poll for requests from shutdown mechanism to quiesce compiler (4448539, 4448544).

   // This is an effective place to poll, since the compiler is full of phases.

   // In particular, every inlining site uses a recursively created Parse phase.

   CompileBroker::maybe_block();

 }

 #ifndef PRODUCT

 static const double minimum_reported_time             = 0.0001; // seconds

 static const double expected_method_compile_coverage  = 0.97;   // %

 static const double minimum_meaningful_method_compile = 2.00;   // seconds

 void Phase::print_timers() {

   tty->print_cr ("Accumulated compiler times:");

   tty->print_cr ("---------------------------");

   tty->print_cr ("  Total compilation: %3.3f sec.", Phase::_t_totalCompilation.seconds());

   tty->print    ("    method compilation   : %3.3f sec", Phase::_t_methodCompilation.seconds());

   tty->print    ("/%d bytes",_total_bytes_compiled);

   tty->print_cr (" (%3.0f bytes per sec) ", Phase::_total_bytes_compiled / Phase::_t_methodCompilation.seconds());

   tty->print_cr ("    stub compilation     : %3.3f sec.", Phase::_t_stubCompilation.seconds());

   tty->print_cr ("  Phases:");

   tty->print_cr ("    parse          : %3.3f sec", Phase::_t_parser.seconds());

   tty->print_cr ("    optimizer      : %3.3f sec", Phase::_t_optimizer.seconds());

   if( Verbose || WizardMode ) {

     if (DoEscapeAnalysis) {

       // EA is part of Optimizer.

       tty->print_cr ("      escape analysis: %3.3f sec", Phase::_t_escapeAnalysis.seconds());

       tty->print_cr ("        connection graph: %3.3f sec", Phase::_t_connectionGraph.seconds());

       tty->print_cr ("      macroEliminate : %3.3f sec", Phase::_t_macroEliminate.seconds());

     }

     tty->print_cr ("      iterGVN        : %3.3f sec", Phase::_t_iterGVN.seconds());

     tty->print_cr ("      incrInline     : %3.3f sec", Phase::_t_incrInline.seconds());

     tty->print_cr ("      idealLoop      : %3.3f sec", Phase::_t_idealLoop.seconds());

     tty->print_cr ("      idealLoopVerify: %3.3f sec", Phase::_t_idealLoopVerify.seconds());

     tty->print_cr ("      ccp            : %3.3f sec", Phase::_t_ccp.seconds());

     tty->print_cr ("      iterGVN2       : %3.3f sec", Phase::_t_iterGVN2.seconds());

     tty->print_cr ("      macroExpand    : %3.3f sec", Phase::_t_macroExpand.seconds());

     tty->print_cr ("      graphReshape   : %3.3f sec", Phase::_t_graphReshaping.seconds());

     double optimizer_subtotal = Phase::_t_iterGVN.seconds() + Phase::_t_iterGVN2.seconds() +

       Phase::_t_escapeAnalysis.seconds() + Phase::_t_macroEliminate.seconds() +

       Phase::_t_idealLoop.seconds() + Phase::_t_ccp.seconds() +

       Phase::_t_macroExpand.seconds() + Phase::_t_graphReshaping.seconds();

     double percent_of_optimizer = ((optimizer_subtotal == 0.0) ? 0.0 : (optimizer_subtotal / Phase::_t_optimizer.seconds() * 100.0));

     tty->print_cr ("      subtotal       : %3.3f sec,  %3.2f %%", optimizer_subtotal, percent_of_optimizer);

   }

   tty->print_cr ("    matcher        : %3.3f sec", Phase::_t_matcher.seconds());

   tty->print_cr ("    scheduler      : %3.3f sec", Phase::_t_scheduler.seconds());

   tty->print_cr ("    regalloc       : %3.3f sec", Phase::_t_registerAllocation.seconds());

   if( Verbose || WizardMode ) {

     tty->print_cr ("      ctorChaitin    : %3.3f sec", Phase::_t_ctorChaitin.seconds());

     tty->print_cr ("      buildIFG       : %3.3f sec", Phase::_t_buildIFGphysical.seconds());

     tty->print_cr ("      computeLive    : %3.3f sec", Phase::_t_computeLive.seconds());

     tty->print_cr ("      regAllocSplit  : %3.3f sec", Phase::_t_regAllocSplit.seconds());

     tty->print_cr ("      postAllocCopyRemoval: %3.3f sec", Phase::_t_postAllocCopyRemoval.seconds());

     tty->print_cr ("      fixupSpills    : %3.3f sec", Phase::_t_fixupSpills.seconds());

     double regalloc_subtotal = Phase::_t_ctorChaitin.seconds() +

       Phase::_t_buildIFGphysical.seconds() + Phase::_t_computeLive.seconds() +

       Phase::_t_regAllocSplit.seconds()    + Phase::_t_fixupSpills.seconds() +

       Phase::_t_postAllocCopyRemoval.seconds();

     double percent_of_regalloc = ((regalloc_subtotal == 0.0) ? 0.0 : (regalloc_subtotal / Phase::_t_registerAllocation.seconds() * 100.0));

     tty->print_cr ("      subtotal       : %3.3f sec,  %3.2f %%", regalloc_subtotal, percent_of_regalloc);

   }

   tty->print_cr ("    blockOrdering  : %3.3f sec", Phase::_t_blockOrdering.seconds());

   tty->print_cr ("    peephole       : %3.3f sec", Phase::_t_peephole.seconds());

   if (Matcher::require_postalloc_expand) {

     tty->print_cr ("    postalloc_expand: %3.3f sec", Phase::_t_postalloc_expand.seconds());

   }

   tty->print_cr ("    codeGen        : %3.3f sec", Phase::_t_codeGeneration.seconds());

   tty->print_cr ("    install_code   : %3.3f sec", Phase::_t_registerMethod.seconds());

   tty->print_cr ("    -------------- : ----------");

   double phase_subtotal = Phase::_t_parser.seconds() +

     Phase::_t_optimizer.seconds() + Phase::_t_graphReshaping.seconds() +

     Phase::_t_matcher.seconds() + Phase::_t_scheduler.seconds() +

     Phase::_t_registerAllocation.seconds() + Phase::_t_blockOrdering.seconds() +

     Phase::_t_codeGeneration.seconds() + Phase::_t_registerMethod.seconds();

   double percent_of_method_compile = ((phase_subtotal == 0.0) ? 0.0 : phase_subtotal / Phase::_t_methodCompilation.seconds()) * 100.0;

   // counters inside Compile::CodeGen include time for adapters and stubs

   // so phase-total can be greater than 100%

   tty->print_cr ("    total          : %3.3f sec,  %3.2f %%", phase_subtotal, percent_of_method_compile);

   assert( percent_of_method_compile > expected_method_compile_coverage ||

           phase_subtotal < minimum_meaningful_method_compile,

           "Must account for method compilation");

   if( Phase::_t_temporaryTimer1.seconds() > minimum_reported_time ) {

     tty->cr();

     tty->print_cr ("    temporaryTimer1: %3.3f sec", Phase::_t_temporaryTimer1.seconds());

   }

   if( Phase::_t_temporaryTimer2.seconds() > minimum_reported_time ) {

     tty->cr();

     tty->print_cr ("    temporaryTimer2: %3.3f sec", Phase::_t_temporaryTimer2.seconds());

   }

   tty->print_cr ("    output         : %3.3f sec", Phase::_t_output.seconds());

   tty->print_cr ("      isched         : %3.3f sec", Phase::_t_instrSched.seconds());

   tty->print_cr ("      bldOopMaps     : %3.3f sec", Phase::_t_buildOopMaps.seconds());

 }

 #endif