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view src/share/vm/runtime/globals.cpp @ 1145:e018e6884bd8

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6631166: CMS: better heuristics when combatting fragmentation Summary: Autonomic per-worker free block cache sizing, tunable coalition policies, fixes to per-size block statistics, retuned gain and bandwidth of some feedback loop filters to allow quicker reactivity to abrupt changes in ambient demand, and other heuristics to reduce fragmentation of the CMS old gen. Also tightened some assertions, including those related to locking. Reviewed-by: jmasa
author ysr
date Wed, 23 Dec 2009 09:23:54 -0800
parents 7c57aead6d3e
children f62a22282a47
line wrap: on
line source

/*
 * Copyright 1997-2008 Sun Microsystems, Inc.  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 Sun Microsystems, Inc., 4150 Network Circle, Santa Clara,
 * CA 95054 USA or visit www.sun.com if you need additional information or
 * have any questions.
 *
 */

# include "incls/_precompiled.incl"
# include "incls/_globals.cpp.incl"


RUNTIME_FLAGS(MATERIALIZE_DEVELOPER_FLAG, MATERIALIZE_PD_DEVELOPER_FLAG, \
              MATERIALIZE_PRODUCT_FLAG, MATERIALIZE_PD_PRODUCT_FLAG, \
              MATERIALIZE_DIAGNOSTIC_FLAG, MATERIALIZE_EXPERIMENTAL_FLAG, \
              MATERIALIZE_NOTPRODUCT_FLAG, \
              MATERIALIZE_MANAGEABLE_FLAG, MATERIALIZE_PRODUCT_RW_FLAG, \
              MATERIALIZE_LP64_PRODUCT_FLAG)

RUNTIME_OS_FLAGS(MATERIALIZE_DEVELOPER_FLAG, MATERIALIZE_PD_DEVELOPER_FLAG, \
                 MATERIALIZE_PRODUCT_FLAG, MATERIALIZE_PD_PRODUCT_FLAG, \
                 MATERIALIZE_DIAGNOSTIC_FLAG, MATERIALIZE_NOTPRODUCT_FLAG)

bool Flag::is_unlocker() const {
  return strcmp(name, "UnlockDiagnosticVMOptions") == 0     ||
         strcmp(name, "UnlockExperimentalVMOptions") == 0;

}

bool Flag::is_unlocked() const {
  if (strcmp(kind, "{diagnostic}") == 0) {
    return UnlockDiagnosticVMOptions;
  } else if (strcmp(kind, "{experimental}") == 0 ||
             strcmp(kind, "{C2 experimental}") == 0) {
    return UnlockExperimentalVMOptions;
  } else {
    return true;
  }
}

bool Flag::is_writeable() const {
  return (strcmp(kind, "{manageable}") == 0 || strcmp(kind, "{product rw}") == 0);
}

// All flags except "manageable" are assumed internal flags.
// Long term, we need to define a mechanism to specify which flags
// are external/stable and change this function accordingly.
bool Flag::is_external() const {
  return (strcmp(kind, "{manageable}") == 0);
}

// Length of format string (e.g. "%.1234s") for printing ccstr below
#define FORMAT_BUFFER_LEN 16

void Flag::print_on(outputStream* st) {
  st->print("%5s %-35s %c= ", type, name, (origin != DEFAULT ? ':' : ' '));
  if (is_bool())     st->print("%-16s", get_bool() ? "true" : "false");
  if (is_intx())     st->print("%-16ld", get_intx());
  if (is_uintx())    st->print("%-16lu", get_uintx());
  if (is_uint64_t()) st->print("%-16lu", get_uint64_t());
  if (is_ccstr()) {
    const char* cp = get_ccstr();
    if (cp != NULL) {
      const char* eol;
      while ((eol = strchr(cp, '\n')) != NULL) {
        char format_buffer[FORMAT_BUFFER_LEN];
        size_t llen = pointer_delta(eol, cp, sizeof(char));
        jio_snprintf(format_buffer, FORMAT_BUFFER_LEN,
                     "%%." SIZE_FORMAT "s", llen);
        st->print(format_buffer, cp);
        st->cr();
        cp = eol+1;
        st->print("%5s %-35s += ", "", name);
      }
      st->print("%-16s", cp);
    }
  }
  st->print(" %s", kind);
  st->cr();
}

void Flag::print_as_flag(outputStream* st) {
  if (is_bool()) {
    st->print("-XX:%s%s", get_bool() ? "+" : "-", name);
  } else if (is_intx()) {
    st->print("-XX:%s=" INTX_FORMAT, name, get_intx());
  } else if (is_uintx()) {
    st->print("-XX:%s=" UINTX_FORMAT, name, get_uintx());
  } else if (is_uint64_t()) {
    st->print("-XX:%s=" UINT64_FORMAT, name, get_uint64_t());
  } else if (is_ccstr()) {
    st->print("-XX:%s=", name);
    const char* cp = get_ccstr();
    if (cp != NULL) {
      // Need to turn embedded '\n's back into separate arguments
      // Not so efficient to print one character at a time,
      // but the choice is to do the transformation to a buffer
      // and print that.  And this need not be efficient.
      for (; *cp != '\0'; cp += 1) {
        switch (*cp) {
          default:
            st->print("%c", *cp);
            break;
          case '\n':
            st->print(" -XX:%s=", name);
            break;
        }
      }
    }
  } else {
    ShouldNotReachHere();
  }
}

// 4991491 do not "optimize out" the was_set false values: omitting them
// tickles a Microsoft compiler bug causing flagTable to be malformed

#define RUNTIME_PRODUCT_FLAG_STRUCT(type, name, value, doc) { #type, XSTR(name), &name, "{product}", DEFAULT },
#define RUNTIME_PD_PRODUCT_FLAG_STRUCT(type, name, doc)     { #type, XSTR(name), &name, "{pd product}", DEFAULT },
#define RUNTIME_DIAGNOSTIC_FLAG_STRUCT(type, name, value, doc) { #type, XSTR(name), &name, "{diagnostic}", DEFAULT },
#define RUNTIME_EXPERIMENTAL_FLAG_STRUCT(type, name, value, doc) { #type, XSTR(name), &name, "{experimental}", DEFAULT },
#define RUNTIME_MANAGEABLE_FLAG_STRUCT(type, name, value, doc) { #type, XSTR(name), &name, "{manageable}", DEFAULT },
#define RUNTIME_PRODUCT_RW_FLAG_STRUCT(type, name, value, doc) { #type, XSTR(name), &name, "{product rw}", DEFAULT },

#ifdef PRODUCT
  #define RUNTIME_DEVELOP_FLAG_STRUCT(type, name, value, doc) /* flag is constant */
  #define RUNTIME_PD_DEVELOP_FLAG_STRUCT(type, name, doc)     /* flag is constant */
  #define RUNTIME_NOTPRODUCT_FLAG_STRUCT(type, name, value, doc)
#else
  #define RUNTIME_DEVELOP_FLAG_STRUCT(type, name, value, doc) { #type, XSTR(name), &name, "", DEFAULT },
  #define RUNTIME_PD_DEVELOP_FLAG_STRUCT(type, name, doc)     { #type, XSTR(name), &name, "{pd}", DEFAULT },
  #define RUNTIME_NOTPRODUCT_FLAG_STRUCT(type, name, value, doc) { #type, XSTR(name), &name, "{notproduct}", DEFAULT },
#endif

#ifdef _LP64
  #define RUNTIME_LP64_PRODUCT_FLAG_STRUCT(type, name, value, doc) { #type, XSTR(name), &name, "{lp64_product}", DEFAULT },
#else
  #define RUNTIME_LP64_PRODUCT_FLAG_STRUCT(type, name, value, doc) /* flag is constant */
#endif // _LP64

#define C1_PRODUCT_FLAG_STRUCT(type, name, value, doc) { #type, XSTR(name), &name, "{C1 product}", DEFAULT },
#define C1_PD_PRODUCT_FLAG_STRUCT(type, name, doc)     { #type, XSTR(name), &name, "{C1 pd product}", DEFAULT },
#ifdef PRODUCT
  #define C1_DEVELOP_FLAG_STRUCT(type, name, value, doc) /* flag is constant */
  #define C1_PD_DEVELOP_FLAG_STRUCT(type, name, doc)     /* flag is constant */
  #define C1_NOTPRODUCT_FLAG_STRUCT(type, name, value, doc)
#else
  #define C1_DEVELOP_FLAG_STRUCT(type, name, value, doc) { #type, XSTR(name), &name, "{C1}", DEFAULT },
  #define C1_PD_DEVELOP_FLAG_STRUCT(type, name, doc)     { #type, XSTR(name), &name, "{C1 pd}", DEFAULT },
  #define C1_NOTPRODUCT_FLAG_STRUCT(type, name, value, doc) { #type, XSTR(name), &name, "{C1 notproduct}", DEFAULT },
#endif


#define C2_PRODUCT_FLAG_STRUCT(type, name, value, doc) { #type, XSTR(name), &name, "{C2 product}", DEFAULT },
#define C2_PD_PRODUCT_FLAG_STRUCT(type, name, doc)     { #type, XSTR(name), &name, "{C2 pd product}", DEFAULT },
#define C2_DIAGNOSTIC_FLAG_STRUCT(type, name, value, doc) { #type, XSTR(name), &name, "{C2 diagnostic}", DEFAULT },
#define C2_EXPERIMENTAL_FLAG_STRUCT(type, name, value, doc) { #type, XSTR(name), &name, "{C2 experimental}", DEFAULT },
#ifdef PRODUCT
  #define C2_DEVELOP_FLAG_STRUCT(type, name, value, doc) /* flag is constant */
  #define C2_PD_DEVELOP_FLAG_STRUCT(type, name, doc)     /* flag is constant */
  #define C2_NOTPRODUCT_FLAG_STRUCT(type, name, value, doc)
#else
  #define C2_DEVELOP_FLAG_STRUCT(type, name, value, doc) { #type, XSTR(name), &name, "{C2}", DEFAULT },
  #define C2_PD_DEVELOP_FLAG_STRUCT(type, name, doc)     { #type, XSTR(name), &name, "{C2 pd}", DEFAULT },
  #define C2_NOTPRODUCT_FLAG_STRUCT(type, name, value, doc) { #type, XSTR(name), &name, "{C2 notproduct}", DEFAULT },
#endif


static Flag flagTable[] = {
 RUNTIME_FLAGS(RUNTIME_DEVELOP_FLAG_STRUCT, RUNTIME_PD_DEVELOP_FLAG_STRUCT, RUNTIME_PRODUCT_FLAG_STRUCT, RUNTIME_PD_PRODUCT_FLAG_STRUCT, RUNTIME_DIAGNOSTIC_FLAG_STRUCT, RUNTIME_EXPERIMENTAL_FLAG_STRUCT, RUNTIME_NOTPRODUCT_FLAG_STRUCT, RUNTIME_MANAGEABLE_FLAG_STRUCT, RUNTIME_PRODUCT_RW_FLAG_STRUCT, RUNTIME_LP64_PRODUCT_FLAG_STRUCT)
 RUNTIME_OS_FLAGS(RUNTIME_DEVELOP_FLAG_STRUCT, RUNTIME_PD_DEVELOP_FLAG_STRUCT, RUNTIME_PRODUCT_FLAG_STRUCT, RUNTIME_PD_PRODUCT_FLAG_STRUCT, RUNTIME_DIAGNOSTIC_FLAG_STRUCT, RUNTIME_NOTPRODUCT_FLAG_STRUCT)
#ifndef SERIALGC
 G1_FLAGS(RUNTIME_DEVELOP_FLAG_STRUCT, RUNTIME_PD_DEVELOP_FLAG_STRUCT, RUNTIME_PRODUCT_FLAG_STRUCT, RUNTIME_PD_PRODUCT_FLAG_STRUCT, RUNTIME_DIAGNOSTIC_FLAG_STRUCT, RUNTIME_EXPERIMENTAL_FLAG_STRUCT, RUNTIME_NOTPRODUCT_FLAG_STRUCT, RUNTIME_MANAGEABLE_FLAG_STRUCT, RUNTIME_PRODUCT_RW_FLAG_STRUCT)
#endif // SERIALGC
#ifdef COMPILER1
 C1_FLAGS(C1_DEVELOP_FLAG_STRUCT, C1_PD_DEVELOP_FLAG_STRUCT, C1_PRODUCT_FLAG_STRUCT, C1_PD_PRODUCT_FLAG_STRUCT, C1_NOTPRODUCT_FLAG_STRUCT)
#endif
#ifdef COMPILER2
 C2_FLAGS(C2_DEVELOP_FLAG_STRUCT, C2_PD_DEVELOP_FLAG_STRUCT, C2_PRODUCT_FLAG_STRUCT, C2_PD_PRODUCT_FLAG_STRUCT, C2_DIAGNOSTIC_FLAG_STRUCT, C2_EXPERIMENTAL_FLAG_STRUCT, C2_NOTPRODUCT_FLAG_STRUCT)
#endif
 {0, NULL, NULL}
};

Flag* Flag::flags = flagTable;
size_t Flag::numFlags = (sizeof(flagTable) / sizeof(Flag));

inline bool str_equal(const char* s, char* q, size_t len) {
  // s is null terminated, q is not!
  if (strlen(s) != (unsigned int) len) return false;
  return strncmp(s, q, len) == 0;
}

Flag* Flag::find_flag(char* name, size_t length) {
  for (Flag* current = &flagTable[0]; current->name; current++) {
    if (str_equal(current->name, name, length)) {
      if (!(current->is_unlocked() || current->is_unlocker())) {
        // disable use of diagnostic or experimental flags until they
        // are explicitly unlocked
        return NULL;
      }
      return current;
    }
  }
  return NULL;
}

// Returns the address of the index'th element
static Flag* address_of_flag(CommandLineFlagWithType flag) {
  assert((size_t)flag < Flag::numFlags, "bad command line flag index");
  return &Flag::flags[flag];
}

bool CommandLineFlagsEx::is_default(CommandLineFlag flag) {
  assert((size_t)flag < Flag::numFlags, "bad command line flag index");
  Flag* f = &Flag::flags[flag];
  return (f->origin == DEFAULT);
}

bool CommandLineFlagsEx::is_ergo(CommandLineFlag flag) {
  assert((size_t)flag < Flag::numFlags, "bad command line flag index");
  Flag* f = &Flag::flags[flag];
  return (f->origin == ERGONOMIC);
}

bool CommandLineFlagsEx::is_cmdline(CommandLineFlag flag) {
  assert((size_t)flag < Flag::numFlags, "bad command line flag index");
  Flag* f = &Flag::flags[flag];
  return (f->origin == COMMAND_LINE);
}

bool CommandLineFlags::wasSetOnCmdline(const char* name, bool* value) {
  Flag* result = Flag::find_flag((char*)name, strlen(name));
  if (result == NULL) return false;
  *value = (result->origin == COMMAND_LINE);
  return true;
}

bool CommandLineFlags::boolAt(char* name, size_t len, bool* value) {
  Flag* result = Flag::find_flag(name, len);
  if (result == NULL) return false;
  if (!result->is_bool()) return false;
  *value = result->get_bool();
  return true;
}

bool CommandLineFlags::boolAtPut(char* name, size_t len, bool* value, FlagValueOrigin origin) {
  Flag* result = Flag::find_flag(name, len);
  if (result == NULL) return false;
  if (!result->is_bool()) return false;
  bool old_value = result->get_bool();
  result->set_bool(*value);
  *value = old_value;
  result->origin = origin;
  return true;
}

void CommandLineFlagsEx::boolAtPut(CommandLineFlagWithType flag, bool value, FlagValueOrigin origin) {
  Flag* faddr = address_of_flag(flag);
  guarantee(faddr != NULL && faddr->is_bool(), "wrong flag type");
  faddr->set_bool(value);
  faddr->origin = origin;
}

bool CommandLineFlags::intxAt(char* name, size_t len, intx* value) {
  Flag* result = Flag::find_flag(name, len);
  if (result == NULL) return false;
  if (!result->is_intx()) return false;
  *value = result->get_intx();
  return true;
}

bool CommandLineFlags::intxAtPut(char* name, size_t len, intx* value, FlagValueOrigin origin) {
  Flag* result = Flag::find_flag(name, len);
  if (result == NULL) return false;
  if (!result->is_intx()) return false;
  intx old_value = result->get_intx();
  result->set_intx(*value);
  *value = old_value;
  result->origin = origin;
  return true;
}

void CommandLineFlagsEx::intxAtPut(CommandLineFlagWithType flag, intx value, FlagValueOrigin origin) {
  Flag* faddr = address_of_flag(flag);
  guarantee(faddr != NULL && faddr->is_intx(), "wrong flag type");
  faddr->set_intx(value);
  faddr->origin = origin;
}

bool CommandLineFlags::uintxAt(char* name, size_t len, uintx* value) {
  Flag* result = Flag::find_flag(name, len);
  if (result == NULL) return false;
  if (!result->is_uintx()) return false;
  *value = result->get_uintx();
  return true;
}

bool CommandLineFlags::uintxAtPut(char* name, size_t len, uintx* value, FlagValueOrigin origin) {
  Flag* result = Flag::find_flag(name, len);
  if (result == NULL) return false;
  if (!result->is_uintx()) return false;
  uintx old_value = result->get_uintx();
  result->set_uintx(*value);
  *value = old_value;
  result->origin = origin;
  return true;
}

void CommandLineFlagsEx::uintxAtPut(CommandLineFlagWithType flag, uintx value, FlagValueOrigin origin) {
  Flag* faddr = address_of_flag(flag);
  guarantee(faddr != NULL && faddr->is_uintx(), "wrong flag type");
  faddr->set_uintx(value);
  faddr->origin = origin;
}

bool CommandLineFlags::uint64_tAt(char* name, size_t len, uint64_t* value) {
  Flag* result = Flag::find_flag(name, len);
  if (result == NULL) return false;
  if (!result->is_uint64_t()) return false;
  *value = result->get_uint64_t();
  return true;
}

bool CommandLineFlags::uint64_tAtPut(char* name, size_t len, uint64_t* value, FlagValueOrigin origin) {
  Flag* result = Flag::find_flag(name, len);
  if (result == NULL) return false;
  if (!result->is_uint64_t()) return false;
  uint64_t old_value = result->get_uint64_t();
  result->set_uint64_t(*value);
  *value = old_value;
  result->origin = origin;
  return true;
}

void CommandLineFlagsEx::uint64_tAtPut(CommandLineFlagWithType flag, uint64_t value, FlagValueOrigin origin) {
  Flag* faddr = address_of_flag(flag);
  guarantee(faddr != NULL && faddr->is_uint64_t(), "wrong flag type");
  faddr->set_uint64_t(value);
  faddr->origin = origin;
}

bool CommandLineFlags::doubleAt(char* name, size_t len, double* value) {
  Flag* result = Flag::find_flag(name, len);
  if (result == NULL) return false;
  if (!result->is_double()) return false;
  *value = result->get_double();
  return true;
}

bool CommandLineFlags::doubleAtPut(char* name, size_t len, double* value, FlagValueOrigin origin) {
  Flag* result = Flag::find_flag(name, len);
  if (result == NULL) return false;
  if (!result->is_double()) return false;
  double old_value = result->get_double();
  result->set_double(*value);
  *value = old_value;
  result->origin = origin;
  return true;
}

void CommandLineFlagsEx::doubleAtPut(CommandLineFlagWithType flag, double value, FlagValueOrigin origin) {
  Flag* faddr = address_of_flag(flag);
  guarantee(faddr != NULL && faddr->is_double(), "wrong flag type");
  faddr->set_double(value);
  faddr->origin = origin;
}

bool CommandLineFlags::ccstrAt(char* name, size_t len, ccstr* value) {
  Flag* result = Flag::find_flag(name, len);
  if (result == NULL) return false;
  if (!result->is_ccstr()) return false;
  *value = result->get_ccstr();
  return true;
}

// Contract:  Flag will make private copy of the incoming value.
// Outgoing value is always malloc-ed, and caller MUST call free.
bool CommandLineFlags::ccstrAtPut(char* name, size_t len, ccstr* value, FlagValueOrigin origin) {
  Flag* result = Flag::find_flag(name, len);
  if (result == NULL) return false;
  if (!result->is_ccstr()) return false;
  ccstr old_value = result->get_ccstr();
  char* new_value = NULL;
  if (*value != NULL) {
    new_value = NEW_C_HEAP_ARRAY(char, strlen(*value)+1);
    strcpy(new_value, *value);
  }
  result->set_ccstr(new_value);
  if (result->origin == DEFAULT && old_value != NULL) {
    // Prior value is NOT heap allocated, but was a literal constant.
    char* old_value_to_free = NEW_C_HEAP_ARRAY(char, strlen(old_value)+1);
    strcpy(old_value_to_free, old_value);
    old_value = old_value_to_free;
  }
  *value = old_value;
  result->origin = origin;
  return true;
}

// Contract:  Flag will make private copy of the incoming value.
void CommandLineFlagsEx::ccstrAtPut(CommandLineFlagWithType flag, ccstr value, FlagValueOrigin origin) {
  Flag* faddr = address_of_flag(flag);
  guarantee(faddr != NULL && faddr->is_ccstr(), "wrong flag type");
  ccstr old_value = faddr->get_ccstr();
  char* new_value = NEW_C_HEAP_ARRAY(char, strlen(value)+1);
  strcpy(new_value, value);
  faddr->set_ccstr(new_value);
  if (faddr->origin != DEFAULT && old_value != NULL) {
    // Prior value is heap allocated so free it.
    FREE_C_HEAP_ARRAY(char, old_value);
  }
  faddr->origin = origin;
}

extern "C" {
  static int compare_flags(const void* void_a, const void* void_b) {
    return strcmp((*((Flag**) void_a))->name, (*((Flag**) void_b))->name);
  }
}

void CommandLineFlags::printSetFlags() {
  // Print which flags were set on the command line
  // note: this method is called before the thread structure is in place
  //       which means resource allocation cannot be used.

  // Compute size
  int length= 0;
  while (flagTable[length].name != NULL) length++;

  // Sort
  Flag** array = NEW_C_HEAP_ARRAY(Flag*, length);
  for (int index = 0; index < length; index++) {
    array[index] = &flagTable[index];
  }
  qsort(array, length, sizeof(Flag*), compare_flags);

  // Print
  for (int i = 0; i < length; i++) {
    if (array[i]->origin /* naked field! */) {
      array[i]->print_as_flag(tty);
      tty->print(" ");
    }
  }
  tty->cr();
  FREE_C_HEAP_ARRAY(Flag*, array);
}

#ifndef PRODUCT


void CommandLineFlags::verify() {
  assert(Arguments::check_vm_args_consistency(), "Some flag settings conflict");
}

void CommandLineFlags::printFlags() {
  // Print the flags sorted by name
  // note: this method is called before the thread structure is in place
  //       which means resource allocation cannot be used.

  // Compute size
  int length= 0;
  while (flagTable[length].name != NULL) length++;

  // Sort
  Flag** array = NEW_C_HEAP_ARRAY(Flag*, length);
  for (int index = 0; index < length; index++) {
    array[index] = &flagTable[index];
  }
  qsort(array, length, sizeof(Flag*), compare_flags);

  // Print
  tty->print_cr("[Global flags]");
  for (int i = 0; i < length; i++) {
    if (array[i]->is_unlocked()) {
      array[i]->print_on(tty);
    }
  }
  FREE_C_HEAP_ARRAY(Flag*, array);
}

#endif