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

 /*

  * Copyright (c) 1997, 2011, 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 "classfile/classFileParser.hpp"

 #include "classfile/classFileStream.hpp"

 #include "classfile/classLoader.hpp"

 #include "classfile/javaClasses.hpp"

 #include "classfile/systemDictionary.hpp"

 #include "classfile/vmSymbols.hpp"

 #include "compiler/compileBroker.hpp"

 #include "gc_interface/collectedHeap.inline.hpp"

 #include "interpreter/bytecodeStream.hpp"

 #include "interpreter/oopMapCache.hpp"

 #include "memory/allocation.inline.hpp"

 #include "memory/generation.hpp"

 #include "memory/oopFactory.hpp"

 #include "memory/universe.inline.hpp"

 #include "oops/constantPoolKlass.hpp"

 #include "oops/instanceKlass.hpp"

 #include "oops/instanceRefKlass.hpp"

 #include "oops/oop.inline.hpp"

 #include "oops/symbol.hpp"

 #include "prims/jvm_misc.hpp"

 #include "runtime/arguments.hpp"

 #include "runtime/compilationPolicy.hpp"

 #include "runtime/fprofiler.hpp"

 #include "runtime/handles.hpp"

 #include "runtime/handles.inline.hpp"

 #include "runtime/init.hpp"

 #include "runtime/interfaceSupport.hpp"

 #include "runtime/java.hpp"

 #include "runtime/javaCalls.hpp"

 #include "runtime/threadCritical.hpp"

 #include "runtime/timer.hpp"

 #include "services/management.hpp"

 #include "services/threadService.hpp"

 #include "utilities/events.hpp"

 #include "utilities/hashtable.hpp"

 #include "utilities/hashtable.inline.hpp"

 #ifdef TARGET_OS_FAMILY_linux

 # include "os_linux.inline.hpp"

 #endif

 #ifdef TARGET_OS_FAMILY_solaris

 # include "os_solaris.inline.hpp"

 #endif

 #ifdef TARGET_OS_FAMILY_windows

 # include "os_windows.inline.hpp"

 #endif

 #ifdef TARGET_OS_FAMILY_bsd

 # include "os_bsd.inline.hpp"

 #endif

 // Entry points in zip.dll for loading zip/jar file entries

 typedef void * * (JNICALL *ZipOpen_t)(const char *name, char **pmsg);

 typedef void (JNICALL *ZipClose_t)(jzfile *zip);

 typedef jzentry* (JNICALL *FindEntry_t)(jzfile *zip, const char *name, jint *sizeP, jint *nameLen);

 typedef jboolean (JNICALL *ReadEntry_t)(jzfile *zip, jzentry *entry, unsigned char *buf, char *namebuf);

 typedef jboolean (JNICALL *ReadMappedEntry_t)(jzfile *zip, jzentry *entry, unsigned char **buf, char *namebuf);

 typedef jzentry* (JNICALL *GetNextEntry_t)(jzfile *zip, jint n);

 static ZipOpen_t         ZipOpen            = NULL;

 static ZipClose_t        ZipClose           = NULL;

 static FindEntry_t       FindEntry          = NULL;

 static ReadEntry_t       ReadEntry          = NULL;

 static ReadMappedEntry_t ReadMappedEntry    = NULL;

 static GetNextEntry_t    GetNextEntry       = NULL;

 static canonicalize_fn_t CanonicalizeEntry  = NULL;

 // Globals

 PerfCounter*    ClassLoader::_perf_accumulated_time = NULL;

 PerfCounter*    ClassLoader::_perf_classes_inited = NULL;

 PerfCounter*    ClassLoader::_perf_class_init_time = NULL;

 PerfCounter*    ClassLoader::_perf_class_init_selftime = NULL;

 PerfCounter*    ClassLoader::_perf_classes_verified = NULL;

 PerfCounter*    ClassLoader::_perf_class_verify_time = NULL;

 PerfCounter*    ClassLoader::_perf_class_verify_selftime = NULL;

 PerfCounter*    ClassLoader::_perf_classes_linked = NULL;

 PerfCounter*    ClassLoader::_perf_class_link_time = NULL;

 PerfCounter*    ClassLoader::_perf_class_link_selftime = NULL;

 PerfCounter*    ClassLoader::_perf_class_parse_time = NULL;

 PerfCounter*    ClassLoader::_perf_class_parse_selftime = NULL;

 PerfCounter*    ClassLoader::_perf_sys_class_lookup_time = NULL;

 PerfCounter*    ClassLoader::_perf_shared_classload_time = NULL;

 PerfCounter*    ClassLoader::_perf_sys_classload_time = NULL;

 PerfCounter*    ClassLoader::_perf_app_classload_time = NULL;

 PerfCounter*    ClassLoader::_perf_app_classload_selftime = NULL;

 PerfCounter*    ClassLoader::_perf_app_classload_count = NULL;

 PerfCounter*    ClassLoader::_perf_define_appclasses = NULL;

 PerfCounter*    ClassLoader::_perf_define_appclass_time = NULL;

 PerfCounter*    ClassLoader::_perf_define_appclass_selftime = NULL;

 PerfCounter*    ClassLoader::_perf_app_classfile_bytes_read = NULL;

 PerfCounter*    ClassLoader::_perf_sys_classfile_bytes_read = NULL;

 PerfCounter*    ClassLoader::_sync_systemLoaderLockContentionRate = NULL;

 PerfCounter*    ClassLoader::_sync_nonSystemLoaderLockContentionRate = NULL;

 PerfCounter*    ClassLoader::_sync_JVMFindLoadedClassLockFreeCounter = NULL;

 PerfCounter*    ClassLoader::_sync_JVMDefineClassLockFreeCounter = NULL;

 PerfCounter*    ClassLoader::_sync_JNIDefineClassLockFreeCounter = NULL;

 PerfCounter*    ClassLoader::_unsafe_defineClassCallCounter = NULL;

 PerfCounter*    ClassLoader::_isUnsyncloadClass = NULL;

 PerfCounter*    ClassLoader::_load_instance_class_failCounter = NULL;

 ClassPathEntry* ClassLoader::_first_entry         = NULL;

 ClassPathEntry* ClassLoader::_last_entry          = NULL;

 PackageHashtable* ClassLoader::_package_hash_table = NULL;

 // helper routines

 bool string_starts_with(const char* str, const char* str_to_find) {

   size_t str_len = strlen(str);

   size_t str_to_find_len = strlen(str_to_find);

   if (str_to_find_len > str_len) {

     return false;

   }

   return (strncmp(str, str_to_find, str_to_find_len) == 0);

 }

 bool string_ends_with(const char* str, const char* str_to_find) {

   size_t str_len = strlen(str);

   size_t str_to_find_len = strlen(str_to_find);

   if (str_to_find_len > str_len) {

     return false;

   }

   return (strncmp(str + (str_len - str_to_find_len), str_to_find, str_to_find_len) == 0);

 }

 MetaIndex::MetaIndex(char** meta_package_names, int num_meta_package_names) {

   if (num_meta_package_names == 0) {

     _meta_package_names = NULL;

     _num_meta_package_names = 0;

   } else {

     _meta_package_names = NEW_C_HEAP_ARRAY(char*, num_meta_package_names);

     _num_meta_package_names = num_meta_package_names;

     memcpy(_meta_package_names, meta_package_names, num_meta_package_names * sizeof(char*));

   }

 }

 MetaIndex::~MetaIndex() {

   FREE_C_HEAP_ARRAY(char*, _meta_package_names);

 }

 bool MetaIndex::may_contain(const char* class_name) {

   if ( _num_meta_package_names == 0) {

     return false;

   }

   size_t class_name_len = strlen(class_name);

   for (int i = 0; i < _num_meta_package_names; i++) {

     char* pkg = _meta_package_names[i];

     size_t pkg_len = strlen(pkg);

     size_t min_len = MIN2(class_name_len, pkg_len);

     if (!strncmp(class_name, pkg, min_len)) {

       return true;

     }

   }

   return false;

 }

 ClassPathEntry::ClassPathEntry() {

   set_next(NULL);

 }

 bool ClassPathEntry::is_lazy() {

   return false;

 }

 ClassPathDirEntry::ClassPathDirEntry(char* dir) : ClassPathEntry() {

   _dir = NEW_C_HEAP_ARRAY(char, strlen(dir)+1);

   strcpy(_dir, dir);

 }

 ClassFileStream* ClassPathDirEntry::open_stream(const char* name) {

   // construct full path name

   char path[JVM_MAXPATHLEN];

   if (jio_snprintf(path, sizeof(path), "%s%s%s", _dir, os::file_separator(), name) == -1) {

     return NULL;

   }

   // check if file exists

   struct stat st;

   if (os::stat(path, &st) == 0) {

     // found file, open it

     int file_handle = os::open(path, 0, 0);

     if (file_handle != -1) {

       // read contents into resource array

       u1* buffer = NEW_RESOURCE_ARRAY(u1, st.st_size);

       size_t num_read = os::read(file_handle, (char*) buffer, st.st_size);

       // close file

       os::close(file_handle);

       // construct ClassFileStream

       if (num_read == (size_t)st.st_size) {

         if (UsePerfData) {

           ClassLoader::perf_sys_classfile_bytes_read()->inc(num_read);

         }

         return new ClassFileStream(buffer, st.st_size, _dir);    // Resource allocated

       }

     }

   }

   return NULL;

 }

 ClassPathZipEntry::ClassPathZipEntry(jzfile* zip, const char* zip_name) : ClassPathEntry() {

   _zip = zip;

   _zip_name = NEW_C_HEAP_ARRAY(char, strlen(zip_name)+1);

   strcpy(_zip_name, zip_name);

 }

 ClassPathZipEntry::~ClassPathZipEntry() {

   if (ZipClose != NULL) {

     (*ZipClose)(_zip);

   }

   FREE_C_HEAP_ARRAY(char, _zip_name);

 }

 ClassFileStream* ClassPathZipEntry::open_stream(const char* name) {

   // enable call to C land

   JavaThread* thread = JavaThread::current();

   ThreadToNativeFromVM ttn(thread);

   // check whether zip archive contains name

   jint filesize, name_len;

   jzentry* entry = (*FindEntry)(_zip, name, &filesize, &name_len);

   if (entry == NULL) return NULL;

   u1* buffer;

   char name_buf[128];

   char* filename;

   if (name_len < 128) {

     filename = name_buf;

   } else {

     filename = NEW_RESOURCE_ARRAY(char, name_len + 1);

   }

   // file found, get pointer to class in mmaped jar file.

   if (ReadMappedEntry == NULL ||

       !(*ReadMappedEntry)(_zip, entry, &buffer, filename)) {

       // mmaped access not available, perhaps due to compression,

       // read contents into resource array

       buffer     = NEW_RESOURCE_ARRAY(u1, filesize);

       if (!(*ReadEntry)(_zip, entry, buffer, filename)) return NULL;

   }

   if (UsePerfData) {

     ClassLoader::perf_sys_classfile_bytes_read()->inc(filesize);

   }

   // return result

   return new ClassFileStream(buffer, filesize, _zip_name);    // Resource allocated

 }

 // invoke function for each entry in the zip file

 void ClassPathZipEntry::contents_do(void f(const char* name, void* context), void* context) {

   JavaThread* thread = JavaThread::current();

   HandleMark  handle_mark(thread);

   ThreadToNativeFromVM ttn(thread);

   for (int n = 0; ; n++) {

     jzentry * ze = ((*GetNextEntry)(_zip, n));

     if (ze == NULL) break;

     (*f)(ze->name, context);

   }

 }

 LazyClassPathEntry::LazyClassPathEntry(char* path, struct stat st) : ClassPathEntry() {

   _path = strdup(path);

   _st = st;

   _meta_index = NULL;

   _resolved_entry = NULL;

 }

 bool LazyClassPathEntry::is_jar_file() {

   return ((_st.st_mode & S_IFREG) == S_IFREG);

 }

 ClassPathEntry* LazyClassPathEntry::resolve_entry() {

   if (_resolved_entry != NULL) {

     return (ClassPathEntry*) _resolved_entry;

   }

   ClassPathEntry* new_entry = NULL;

   ClassLoader::create_class_path_entry(_path, _st, &new_entry, false);

   assert(new_entry != NULL, "earlier code should have caught this");

   {

     ThreadCritical tc;

     if (_resolved_entry == NULL) {

       _resolved_entry = new_entry;

       return new_entry;

     }

   }

   assert(_resolved_entry != NULL, "bug in MT-safe resolution logic");

   delete new_entry;

   return (ClassPathEntry*) _resolved_entry;

 }

 ClassFileStream* LazyClassPathEntry::open_stream(const char* name) {

   if (_meta_index != NULL &&

       !_meta_index->may_contain(name)) {

     return NULL;

   }

   return resolve_entry()->open_stream(name);

 }

 bool LazyClassPathEntry::is_lazy() {

   return true;

 }

 static void print_meta_index(LazyClassPathEntry* entry,

                              GrowableArray<char*>& meta_packages) {

   tty->print("[Meta index for %s=", entry->name());

   for (int i = 0; i < meta_packages.length(); i++) {

     if (i > 0) tty->print(" ");

     tty->print(meta_packages.at(i));

   }

   tty->print_cr("]");

 }

 void ClassLoader::setup_meta_index() {

   // Set up meta index which allows us to open boot jars lazily if

   // class data sharing is enabled

   const char* known_version = "% VERSION 2";

   char* meta_index_path = Arguments::get_meta_index_path();

   char* meta_index_dir  = Arguments::get_meta_index_dir();

   FILE* file = fopen(meta_index_path, "r");

   int line_no = 0;

   if (file != NULL) {

     ResourceMark rm;

     LazyClassPathEntry* cur_entry = NULL;

     GrowableArray<char*> boot_class_path_packages(10);

     char package_name[256];

     bool skipCurrentJar = false;

     while (fgets(package_name, sizeof(package_name), file) != NULL) {

       ++line_no;

       // Remove trailing newline

       package_name[strlen(package_name) - 1] = '\0';

       switch(package_name[0]) {

         case '%':

         {

           if ((line_no == 1) && (strcmp(package_name, known_version) != 0)) {

             if (TraceClassLoading && Verbose) {

               tty->print("[Unsupported meta index version]");

             }

             fclose(file);

             return;

           }

         }

         // These directives indicate jar files which contain only

         // classes, only non-classfile resources, or a combination of

         // the two. See src/share/classes/sun/misc/MetaIndex.java and

         // make/tools/MetaIndex/BuildMetaIndex.java in the J2SE

         // workspace.

         case '#':

         case '!':

         case '@':

         {

           // Hand off current packages to current lazy entry (if any)

           if ((cur_entry != NULL) &&

               (boot_class_path_packages.length() > 0)) {

             if (TraceClassLoading && Verbose) {

               print_meta_index(cur_entry, boot_class_path_packages);

             }

             MetaIndex* index = new MetaIndex(boot_class_path_packages.adr_at(0),

                                              boot_class_path_packages.length());

             cur_entry->set_meta_index(index);

           }

           cur_entry = NULL;

           boot_class_path_packages.clear();

           // Find lazy entry corresponding to this jar file

           for (ClassPathEntry* entry = _first_entry; entry != NULL; entry = entry->next()) {

             if (entry->is_lazy() &&

                 string_starts_with(entry->name(), meta_index_dir) &&

                 string_ends_with(entry->name(), &package_name[2])) {

               cur_entry = (LazyClassPathEntry*) entry;

               break;

             }

           }

           // If the first character is '@', it indicates the following jar

           // file is a resource only jar file in which case, we should skip

           // reading the subsequent entries since the resource loading is

           // totally handled by J2SE side.

           if (package_name[0] == '@') {

             if (cur_entry != NULL) {

               cur_entry->set_meta_index(new MetaIndex(NULL, 0));

             }

             cur_entry = NULL;

             skipCurrentJar = true;

           } else {

             skipCurrentJar = false;

           }

           break;

         }

         default:

         {

           if (!skipCurrentJar && cur_entry != NULL) {

             char* new_name = strdup(package_name);

             boot_class_path_packages.append(new_name);

           }

         }

       }

     }

     // Hand off current packages to current lazy entry (if any)

     if ((cur_entry != NULL) &&

         (boot_class_path_packages.length() > 0)) {

       if (TraceClassLoading && Verbose) {

         print_meta_index(cur_entry, boot_class_path_packages);

       }

       MetaIndex* index = new MetaIndex(boot_class_path_packages.adr_at(0),

                                        boot_class_path_packages.length());

       cur_entry->set_meta_index(index);

     }

     fclose(file);

   }

 }

 void ClassLoader::setup_bootstrap_search_path() {

   assert(_first_entry == NULL, "should not setup bootstrap class search path twice");

   char* sys_class_path = os::strdup(Arguments::get_sysclasspath());

   if (TraceClassLoading && Verbose) {

     tty->print_cr("[Bootstrap loader class path=%s]", sys_class_path);

   }

   int len = (int)strlen(sys_class_path);

   int end = 0;

   // Iterate over class path entries

   for (int start = 0; start < len; start = end) {

     while (sys_class_path[end] && sys_class_path[end] != os::path_separator()[0]) {

       end++;

     }

     char* path = NEW_C_HEAP_ARRAY(char, end-start+1);

     strncpy(path, &sys_class_path[start], end-start);

     path[end-start] = '\0';

     update_class_path_entry_list(path, false);

     FREE_C_HEAP_ARRAY(char, path);

     while (sys_class_path[end] == os::path_separator()[0]) {

       end++;

     }

   }

 }

 void ClassLoader::create_class_path_entry(char *path, struct stat st, ClassPathEntry **new_entry, bool lazy) {

   JavaThread* thread = JavaThread::current();

   if (lazy) {

     *new_entry = new LazyClassPathEntry(path, st);

     return;

   }

   if ((st.st_mode & S_IFREG) == S_IFREG) {

     // Regular file, should be a zip file

     // Canonicalized filename

     char canonical_path[JVM_MAXPATHLEN];

     if (!get_canonical_path(path, canonical_path, JVM_MAXPATHLEN)) {

       // This matches the classic VM

       EXCEPTION_MARK;

       THROW_MSG(vmSymbols::java_io_IOException(), "Bad pathname");

     }

     char* error_msg = NULL;

     jzfile* zip;

     {

       // enable call to C land

       ThreadToNativeFromVM ttn(thread);

       HandleMark hm(thread);

       zip = (*ZipOpen)(canonical_path, &error_msg);

     }

     if (zip != NULL && error_msg == NULL) {

       *new_entry = new ClassPathZipEntry(zip, path);

       if (TraceClassLoading) {

         tty->print_cr("[Opened %s]", path);

       }

     } else {

       ResourceMark rm(thread);

       char *msg;

       if (error_msg == NULL) {

         msg = NEW_RESOURCE_ARRAY(char, strlen(path) + 128); ;

         jio_snprintf(msg, strlen(path) + 127, "error in opening JAR file %s", path);

       } else {

         int len = (int)(strlen(path) + strlen(error_msg) + 128);

         msg = NEW_RESOURCE_ARRAY(char, len); ;

         jio_snprintf(msg, len - 1, "error in opening JAR file <%s> %s", error_msg, path);

       }

       EXCEPTION_MARK;

       THROW_MSG(vmSymbols::java_lang_ClassNotFoundException(), msg);

     }

   } else {

     // Directory

     *new_entry = new ClassPathDirEntry(path);

     if (TraceClassLoading) {

       tty->print_cr("[Path %s]", path);

     }

   }

 }

 // Create a class path zip entry for a given path (return NULL if not found

 // or zip/JAR file cannot be opened)

 ClassPathZipEntry* ClassLoader::create_class_path_zip_entry(const char *path) {

   // check for a regular file

   struct stat st;

   if (os::stat(path, &st) == 0) {

     if ((st.st_mode & S_IFREG) == S_IFREG) {

       char orig_path[JVM_MAXPATHLEN];

       char canonical_path[JVM_MAXPATHLEN];

       strcpy(orig_path, path);

       if (get_canonical_path(orig_path, canonical_path, JVM_MAXPATHLEN)) {

         char* error_msg = NULL;

         jzfile* zip;

         {

           // enable call to C land

           JavaThread* thread = JavaThread::current();

           ThreadToNativeFromVM ttn(thread);

           HandleMark hm(thread);

           zip = (*ZipOpen)(canonical_path, &error_msg);

         }

         if (zip != NULL && error_msg == NULL) {

           // create using canonical path

           return new ClassPathZipEntry(zip, canonical_path);

         }

       }

     }

   }

   return NULL;

 }

 // returns true if entry already on class path

 bool ClassLoader::contains_entry(ClassPathEntry *entry) {

   ClassPathEntry* e = _first_entry;

   while (e != NULL) {

     // assume zip entries have been canonicalized

     if (strcmp(entry->name(), e->name()) == 0) {

       return true;

     }

     e = e->next();

   }

   return false;

 }

 void ClassLoader::add_to_list(ClassPathEntry *new_entry) {

   if (new_entry != NULL) {

     if (_last_entry == NULL) {

       _first_entry = _last_entry = new_entry;

     } else {

       _last_entry->set_next(new_entry);

       _last_entry = new_entry;

     }

   }

 }

 void ClassLoader::update_class_path_entry_list(const char *path,

                                                bool check_for_duplicates) {

   struct stat st;

   if (os::stat((char *)path, &st) == 0) {

     // File or directory found

     ClassPathEntry* new_entry = NULL;

     create_class_path_entry((char *)path, st, &new_entry, LazyBootClassLoader);

     // The kernel VM adds dynamically to the end of the classloader path and

     // doesn't reorder the bootclasspath which would break java.lang.Package

     // (see PackageInfo).

     // Add new entry to linked list

     if (!check_for_duplicates || !contains_entry(new_entry)) {

       add_to_list(new_entry);

     }

   }

 }

 void ClassLoader::print_bootclasspath() {

   ClassPathEntry* e = _first_entry;

   tty->print("[bootclasspath= ");

   while (e != NULL) {

     tty->print("%s ;", e->name());

     e = e->next();

   }

   tty->print_cr("]");

 }

 void ClassLoader::load_zip_library() {

   assert(ZipOpen == NULL, "should not load zip library twice");

   // First make sure native library is loaded

   os::native_java_library();

   // Load zip library

   char path[JVM_MAXPATHLEN];

   char ebuf[1024];

   os::dll_build_name(path, sizeof(path), Arguments::get_dll_dir(), "zip");

   void* handle = os::dll_load(path, ebuf, sizeof ebuf);

   if (handle == NULL) {

     vm_exit_during_initialization("Unable to load ZIP library", path);

   }

   // Lookup zip entry points

   ZipOpen      = CAST_TO_FN_PTR(ZipOpen_t, os::dll_lookup(handle, "ZIP_Open"));

   ZipClose     = CAST_TO_FN_PTR(ZipClose_t, os::dll_lookup(handle, "ZIP_Close"));

   FindEntry    = CAST_TO_FN_PTR(FindEntry_t, os::dll_lookup(handle, "ZIP_FindEntry"));

   ReadEntry    = CAST_TO_FN_PTR(ReadEntry_t, os::dll_lookup(handle, "ZIP_ReadEntry"));

   ReadMappedEntry = CAST_TO_FN_PTR(ReadMappedEntry_t, os::dll_lookup(handle, "ZIP_ReadMappedEntry"));

   GetNextEntry = CAST_TO_FN_PTR(GetNextEntry_t, os::dll_lookup(handle, "ZIP_GetNextEntry"));

   // ZIP_Close is not exported on Windows in JDK5.0 so don't abort if ZIP_Close is NULL

   if (ZipOpen == NULL || FindEntry == NULL || ReadEntry == NULL || GetNextEntry == NULL) {

     vm_exit_during_initialization("Corrupted ZIP library", path);

   }

   // Lookup canonicalize entry in libjava.dll

   void *javalib_handle = os::native_java_library();

   CanonicalizeEntry = CAST_TO_FN_PTR(canonicalize_fn_t, os::dll_lookup(javalib_handle, "Canonicalize"));

   // This lookup only works on 1.3. Do not check for non-null here

 }

 // PackageInfo data exists in order to support the java.lang.Package

 // class.  A Package object provides information about a java package

 // (version, vendor, etc.) which originates in the manifest of the jar

 // file supplying the package.  For application classes, the ClassLoader

 // object takes care of this.

 // For system (boot) classes, the Java code in the Package class needs

 // to be able to identify which source jar file contained the boot

 // class, so that it can extract the manifest from it.  This table

 // identifies java packages with jar files in the boot classpath.

 // Because the boot classpath cannot change, the classpath index is

 // sufficient to identify the source jar file or directory.  (Since

 // directories have no manifests, the directory name is not required,

 // but is available.)

 // When using sharing -- the pathnames of entries in the boot classpath

 // may not be the same at runtime as they were when the archive was

 // created (NFS, Samba, etc.).  The actual files and directories named

 // in the classpath must be the same files, in the same order, even

 // though the exact name is not the same.

 class PackageInfo: public BasicHashtableEntry {

 public:

   const char* _pkgname;       // Package name

   int _classpath_index;       // Index of directory or JAR file loaded from

   PackageInfo* next() {

     return (PackageInfo*)BasicHashtableEntry::next();

   }

   const char* pkgname()           { return _pkgname; }

   void set_pkgname(char* pkgname) { _pkgname = pkgname; }

   const char* filename() {

     return ClassLoader::classpath_entry(_classpath_index)->name();

   }

   void set_index(int index) {

     _classpath_index = index;

   }

 };

 class PackageHashtable : public BasicHashtable {

 private:

   inline unsigned int compute_hash(const char *s, int n) {

     unsigned int val = 0;

     while (--n >= 0) {

       val = *s++ + 31 * val;

     }

     return val;

   }

   PackageInfo* bucket(int index) {

     return (PackageInfo*)BasicHashtable::bucket(index);

   }

   PackageInfo* get_entry(int index, unsigned int hash,

                          const char* pkgname, size_t n) {

     for (PackageInfo* pp = bucket(index); pp != NULL; pp = pp->next()) {

       if (pp->hash() == hash &&

           strncmp(pkgname, pp->pkgname(), n) == 0 &&

           pp->pkgname()[n] == '\0') {

         return pp;

       }

     }

     return NULL;

   }

 public:

   PackageHashtable(int table_size)

     : BasicHashtable(table_size, sizeof(PackageInfo)) {}

   PackageHashtable(int table_size, HashtableBucket* t, int number_of_entries)

     : BasicHashtable(table_size, sizeof(PackageInfo), t, number_of_entries) {}

   PackageInfo* get_entry(const char* pkgname, int n) {

     unsigned int hash = compute_hash(pkgname, n);

     return get_entry(hash_to_index(hash), hash, pkgname, n);

   }

   PackageInfo* new_entry(char* pkgname, int n) {

     unsigned int hash = compute_hash(pkgname, n);

     PackageInfo* pp;

     pp = (PackageInfo*)BasicHashtable::new_entry(hash);

     pp->set_pkgname(pkgname);

     return pp;

   }

   void add_entry(PackageInfo* pp) {

     int index = hash_to_index(pp->hash());

     BasicHashtable::add_entry(index, pp);

   }

   void copy_pkgnames(const char** packages) {

     int n = 0;

     for (int i = 0; i < table_size(); ++i) {

       for (PackageInfo* pp = bucket(i); pp != NULL; pp = pp->next()) {

         packages[n++] = pp->pkgname();

       }

     }

     assert(n == number_of_entries(), "just checking");

   }

   void copy_table(char** top, char* end, PackageHashtable* table);

 };

 void PackageHashtable::copy_table(char** top, char* end,

                                   PackageHashtable* table) {

   // Copy (relocate) the table to the shared space.

   BasicHashtable::copy_table(top, end);

   // Calculate the space needed for the package name strings.

   int i;

   int n = 0;

   for (i = 0; i < table_size(); ++i) {

     for (PackageInfo* pp = table->bucket(i);

                       pp != NULL;

                       pp = pp->next()) {

       n += (int)(strlen(pp->pkgname()) + 1);

     }

   }

   if (*top + n + sizeof(intptr_t) >= end) {

     report_out_of_shared_space(SharedMiscData);

   }

   // Copy the table data (the strings) to the shared space.

   n = align_size_up(n, sizeof(HeapWord));

   *(intptr_t*)(*top) = n;

   *top += sizeof(intptr_t);

   for (i = 0; i < table_size(); ++i) {

     for (PackageInfo* pp = table->bucket(i);

                       pp != NULL;

                       pp = pp->next()) {

       int n1 = (int)(strlen(pp->pkgname()) + 1);

       pp->set_pkgname((char*)memcpy(*top, pp->pkgname(), n1));

       *top += n1;

     }

   }

   *top = (char*)align_size_up((intptr_t)*top, sizeof(HeapWord));

 }

 void ClassLoader::copy_package_info_buckets(char** top, char* end) {

   _package_hash_table->copy_buckets(top, end);

 }

 void ClassLoader::copy_package_info_table(char** top, char* end) {

   _package_hash_table->copy_table(top, end, _package_hash_table);

 }

 PackageInfo* ClassLoader::lookup_package(const char *pkgname) {

   const char *cp = strrchr(pkgname, '/');

   if (cp != NULL) {

     // Package prefix found

     int n = cp - pkgname + 1;

     return _package_hash_table->get_entry(pkgname, n);

   }

   return NULL;

 }

 bool ClassLoader::add_package(const char *pkgname, int classpath_index, TRAPS) {

   assert(pkgname != NULL, "just checking");

   // Bootstrap loader no longer holds system loader lock obj serializing

   // load_instance_class and thereby add_package

   {

     MutexLocker ml(PackageTable_lock, THREAD);

     // First check for previously loaded entry

     PackageInfo* pp = lookup_package(pkgname);

     if (pp != NULL) {

       // Existing entry found, check source of package

       pp->set_index(classpath_index);

       return true;

     }

     const char *cp = strrchr(pkgname, '/');

     if (cp != NULL) {

       // Package prefix found

       int n = cp - pkgname + 1;

       char* new_pkgname = NEW_C_HEAP_ARRAY(char, n + 1);

       if (new_pkgname == NULL) {

         return false;

       }

       memcpy(new_pkgname, pkgname, n);

       new_pkgname[n] = '\0';

       pp = _package_hash_table->new_entry(new_pkgname, n);

       pp->set_index(classpath_index);

       // Insert into hash table

       _package_hash_table->add_entry(pp);

     }

     return true;

   }

 }

 oop ClassLoader::get_system_package(const char* name, TRAPS) {

   PackageInfo* pp;

   {

     MutexLocker ml(PackageTable_lock, THREAD);

     pp = lookup_package(name);

   }

   if (pp == NULL) {

     return NULL;

   } else {

     Handle p = java_lang_String::create_from_str(pp->filename(), THREAD);

     return p();

   }

 }

 objArrayOop ClassLoader::get_system_packages(TRAPS) {

   ResourceMark rm(THREAD);

   int nof_entries;

   const char** packages;

   {

     MutexLocker ml(PackageTable_lock, THREAD);

     // Allocate resource char* array containing package names

     nof_entries = _package_hash_table->number_of_entries();

     if ((packages = NEW_RESOURCE_ARRAY(const char*, nof_entries)) == NULL) {

       return NULL;

     }

     _package_hash_table->copy_pkgnames(packages);

   }

   // Allocate objArray and fill with java.lang.String

   objArrayOop r = oopFactory::new_objArray(SystemDictionary::String_klass(),

                                            nof_entries, CHECK_0);

   objArrayHandle result(THREAD, r);

   for (int i = 0; i < nof_entries; i++) {

     Handle str = java_lang_String::create_from_str(packages[i], CHECK_0);

     result->obj_at_put(i, str());

   }

   return result();

 }

 instanceKlassHandle ClassLoader::load_classfile(Symbol* h_name, TRAPS) {

   ResourceMark rm(THREAD);

   EventMark m("loading class " INTPTR_FORMAT, (address)h_name);

   ThreadProfilerMark tpm(ThreadProfilerMark::classLoaderRegion);

   stringStream st;

   // st.print() uses too much stack space while handling a StackOverflowError

   // st.print("%s.class", h_name->as_utf8());

   st.print_raw(h_name->as_utf8());

   st.print_raw(".class");

   char* name = st.as_string();

   // Lookup stream for parsing .class file

   ClassFileStream* stream = NULL;

   int classpath_index = 0;

   {

     PerfClassTraceTime vmtimer(perf_sys_class_lookup_time(),

                                ((JavaThread*) THREAD)->get_thread_stat()->perf_timers_addr(),

                                PerfClassTraceTime::CLASS_LOAD);

     ClassPathEntry* e = _first_entry;

     while (e != NULL) {

       stream = e->open_stream(name);

       if (stream != NULL) {

         break;

       }

       e = e->next();

       ++classpath_index;

     }

   }

   instanceKlassHandle h(THREAD, klassOop(NULL));

   if (stream != NULL) {

     // class file found, parse it

     ClassFileParser parser(stream);

     Handle class_loader;

     Handle protection_domain;

     TempNewSymbol parsed_name = NULL;

     instanceKlassHandle result = parser.parseClassFile(h_name,

                                                        class_loader,

                                                        protection_domain,

                                                        parsed_name,

                                                        false,

                                                        CHECK_(h));

     // add to package table

     if (add_package(name, classpath_index, THREAD)) {

       h = result;

     }

   }

   return h;

 }

 void ClassLoader::create_package_info_table(HashtableBucket *t, int length,

                                             int number_of_entries) {

   assert(_package_hash_table == NULL, "One package info table allowed.");

   assert(length == package_hash_table_size * sizeof(HashtableBucket),

          "bad shared package info size.");

   _package_hash_table = new PackageHashtable(package_hash_table_size, t,

                                              number_of_entries);

 }

 void ClassLoader::create_package_info_table() {

     assert(_package_hash_table == NULL, "shouldn't have one yet");

     _package_hash_table = new PackageHashtable(package_hash_table_size);

 }

 // Initialize the class loader's access to methods in libzip.  Parse and

 // process the boot classpath into a list ClassPathEntry objects.  Once

 // this list has been created, it must not change order (see class PackageInfo)

 // it can be appended to and is by jvmti and the kernel vm.

 void ClassLoader::initialize() {

   assert(_package_hash_table == NULL, "should have been initialized by now.");

   EXCEPTION_MARK;

   if (UsePerfData) {

     // jvmstat performance counters

     NEWPERFTICKCOUNTER(_perf_accumulated_time, SUN_CLS, "time");

     NEWPERFTICKCOUNTER(_perf_class_init_time, SUN_CLS, "classInitTime");

     NEWPERFTICKCOUNTER(_perf_class_init_selftime, SUN_CLS, "classInitTime.self");

     NEWPERFTICKCOUNTER(_perf_class_verify_time, SUN_CLS, "classVerifyTime");

     NEWPERFTICKCOUNTER(_perf_class_verify_selftime, SUN_CLS, "classVerifyTime.self");

     NEWPERFTICKCOUNTER(_perf_class_link_time, SUN_CLS, "classLinkedTime");

     NEWPERFTICKCOUNTER(_perf_class_link_selftime, SUN_CLS, "classLinkedTime.self");

     NEWPERFEVENTCOUNTER(_perf_classes_inited, SUN_CLS, "initializedClasses");

     NEWPERFEVENTCOUNTER(_perf_classes_linked, SUN_CLS, "linkedClasses");

     NEWPERFEVENTCOUNTER(_perf_classes_verified, SUN_CLS, "verifiedClasses");

     NEWPERFTICKCOUNTER(_perf_class_parse_time, SUN_CLS, "parseClassTime");

     NEWPERFTICKCOUNTER(_perf_class_parse_selftime, SUN_CLS, "parseClassTime.self");

     NEWPERFTICKCOUNTER(_perf_sys_class_lookup_time, SUN_CLS, "lookupSysClassTime");

     NEWPERFTICKCOUNTER(_perf_shared_classload_time, SUN_CLS, "sharedClassLoadTime");

     NEWPERFTICKCOUNTER(_perf_sys_classload_time, SUN_CLS, "sysClassLoadTime");

     NEWPERFTICKCOUNTER(_perf_app_classload_time, SUN_CLS, "appClassLoadTime");

     NEWPERFTICKCOUNTER(_perf_app_classload_selftime, SUN_CLS, "appClassLoadTime.self");

     NEWPERFEVENTCOUNTER(_perf_app_classload_count, SUN_CLS, "appClassLoadCount");

     NEWPERFTICKCOUNTER(_perf_define_appclasses, SUN_CLS, "defineAppClasses");

     NEWPERFTICKCOUNTER(_perf_define_appclass_time, SUN_CLS, "defineAppClassTime");

     NEWPERFTICKCOUNTER(_perf_define_appclass_selftime, SUN_CLS, "defineAppClassTime.self");

     NEWPERFBYTECOUNTER(_perf_app_classfile_bytes_read, SUN_CLS, "appClassBytes");

     NEWPERFBYTECOUNTER(_perf_sys_classfile_bytes_read, SUN_CLS, "sysClassBytes");

     // The following performance counters are added for measuring the impact

     // of the bug fix of 6365597. They are mainly focused on finding out

     // the behavior of system & user-defined classloader lock, whether

     // ClassLoader.loadClass/findClass is being called synchronized or not.

     // Also two additional counters are created to see whether 'UnsyncloadClass'

     // flag is being set or not and how many times load_instance_class call

     // fails with linkageError etc.

     NEWPERFEVENTCOUNTER(_sync_systemLoaderLockContentionRate, SUN_CLS,

                         "systemLoaderLockContentionRate");

     NEWPERFEVENTCOUNTER(_sync_nonSystemLoaderLockContentionRate, SUN_CLS,

                         "nonSystemLoaderLockContentionRate");

     NEWPERFEVENTCOUNTER(_sync_JVMFindLoadedClassLockFreeCounter, SUN_CLS,

                         "jvmFindLoadedClassNoLockCalls");

     NEWPERFEVENTCOUNTER(_sync_JVMDefineClassLockFreeCounter, SUN_CLS,

                         "jvmDefineClassNoLockCalls");

     NEWPERFEVENTCOUNTER(_sync_JNIDefineClassLockFreeCounter, SUN_CLS,

                         "jniDefineClassNoLockCalls");

     NEWPERFEVENTCOUNTER(_unsafe_defineClassCallCounter, SUN_CLS,

                         "unsafeDefineClassCalls");

     NEWPERFEVENTCOUNTER(_isUnsyncloadClass, SUN_CLS, "isUnsyncloadClassSet");

     NEWPERFEVENTCOUNTER(_load_instance_class_failCounter, SUN_CLS,

                         "loadInstanceClassFailRate");

     // increment the isUnsyncloadClass counter if UnsyncloadClass is set.

     if (UnsyncloadClass) {

       _isUnsyncloadClass->inc();

     }

   }

   // lookup zip library entry points

   load_zip_library();

   // initialize search path

   setup_bootstrap_search_path();

   if (LazyBootClassLoader) {

     // set up meta index which makes boot classpath initialization lazier

     setup_meta_index();

   }

 }

 jlong ClassLoader::classloader_time_ms() {

   return UsePerfData ?

     Management::ticks_to_ms(_perf_accumulated_time->get_value()) : -1;

 }

 jlong ClassLoader::class_init_count() {

   return UsePerfData ? _perf_classes_inited->get_value() : -1;

 }

 jlong ClassLoader::class_init_time_ms() {

   return UsePerfData ?

     Management::ticks_to_ms(_perf_class_init_time->get_value()) : -1;

 }

 jlong ClassLoader::class_verify_time_ms() {

   return UsePerfData ?

     Management::ticks_to_ms(_perf_class_verify_time->get_value()) : -1;

 }

 jlong ClassLoader::class_link_count() {

   return UsePerfData ? _perf_classes_linked->get_value() : -1;

 }

 jlong ClassLoader::class_link_time_ms() {

   return UsePerfData ?

     Management::ticks_to_ms(_perf_class_link_time->get_value()) : -1;

 }

 int ClassLoader::compute_Object_vtable() {

   // hardwired for JDK1.2 -- would need to duplicate class file parsing

   // code to determine actual value from file

   // Would be value '11' if finals were in vtable

   int JDK_1_2_Object_vtable_size = 5;

   return JDK_1_2_Object_vtable_size * vtableEntry::size();

 }

 void classLoader_init() {

   ClassLoader::initialize();

 }

 bool ClassLoader::get_canonical_path(char* orig, char* out, int len) {

   assert(orig != NULL && out != NULL && len > 0, "bad arguments");

   if (CanonicalizeEntry != NULL) {

     JNIEnv* env = JavaThread::current()->jni_environment();

     if ((CanonicalizeEntry)(env, os::native_path(orig), out, len) < 0) {

       return false;

     }

   } else {

     // On JDK 1.2.2 the Canonicalize does not exist, so just do nothing

     strncpy(out, orig, len);

     out[len - 1] = '\0';

   }

   return true;

 }

 #ifndef PRODUCT

 void ClassLoader::verify() {

   _package_hash_table->verify();

 }

 // CompileTheWorld

 //

 // Iterates over all class path entries and forces compilation of all methods

 // in all classes found. Currently, only zip/jar archives are searched.

 //

 // The classes are loaded by the Java level bootstrap class loader, and the

 // initializer is called. If DelayCompilationDuringStartup is true (default),

 // the interpreter will run the initialization code. Note that forcing

 // initialization in this way could potentially lead to initialization order

 // problems, in which case we could just force the initialization bit to be set.

 // We need to iterate over the contents of a zip/jar file, so we replicate the

 // jzcell and jzfile definitions from zip_util.h but rename jzfile to real_jzfile,

 // since jzfile already has a void* definition.

 //

 // Note that this is only used in debug mode.

 //

 // HotSpot integration note:

 // Matches zip_util.h 1.14 99/06/01 from jdk1.3 beta H build

 // JDK 1.3 version

 typedef struct real_jzentry13 {         /* Zip file entry */

     char *name;                 /* entry name */

     jint time;                  /* modification time */

     jint size;                  /* size of uncompressed data */

     jint csize;                 /* size of compressed data (zero if uncompressed) */

     jint crc;                   /* crc of uncompressed data */

     char *comment;              /* optional zip file comment */

     jbyte *extra;               /* optional extra data */

     jint pos;                   /* position of LOC header (if negative) or data */

 } real_jzentry13;

 typedef struct real_jzfile13 {  /* Zip file */

     char *name;                 /* zip file name */

     jint refs;                  /* number of active references */

     jint fd;                    /* open file descriptor */

     void *lock;                 /* read lock */

     char *comment;              /* zip file comment */

     char *msg;                  /* zip error message */

     void *entries;              /* array of hash cells */

     jint total;                 /* total number of entries */

     unsigned short *table;      /* Hash chain heads: indexes into entries */

     jint tablelen;              /* number of hash eads */

     real_jzfile13 *next;        /* next zip file in search list */

     jzentry *cache;             /* we cache the most recently freed jzentry */

     /* Information on metadata names in META-INF directory */

     char **metanames;           /* array of meta names (may have null names) */

     jint metacount;             /* number of slots in metanames array */

     /* If there are any per-entry comments, they are in the comments array */

     char **comments;

 } real_jzfile13;

 // JDK 1.2 version

 typedef struct real_jzentry12 {  /* Zip file entry */

     char *name;                  /* entry name */

     jint time;                   /* modification time */

     jint size;                   /* size of uncompressed data */

     jint csize;                  /* size of compressed data (zero if uncompressed) */

     jint crc;                    /* crc of uncompressed data */

     char *comment;               /* optional zip file comment */

     jbyte *extra;                /* optional extra data */

     jint pos;                    /* position of LOC header (if negative) or data */

     struct real_jzentry12 *next; /* next entry in hash table */

 } real_jzentry12;

 typedef struct real_jzfile12 {  /* Zip file */

     char *name;                 /* zip file name */

     jint refs;                  /* number of active references */

     jint fd;                    /* open file descriptor */

     void *lock;                 /* read lock */

     char *comment;              /* zip file comment */

     char *msg;                  /* zip error message */

     real_jzentry12 *entries;    /* array of zip entries */

     jint total;                 /* total number of entries */

     real_jzentry12 **table;     /* hash table of entries */

     jint tablelen;              /* number of buckets */

     jzfile *next;               /* next zip file in search list */

 } real_jzfile12;

 void ClassPathDirEntry::compile_the_world(Handle loader, TRAPS) {

   // For now we only compile all methods in all classes in zip/jar files

   tty->print_cr("CompileTheWorld : Skipped classes in %s", _dir);

   tty->cr();

 }

 bool ClassPathDirEntry::is_rt_jar() {

   return false;

 }

 void ClassPathZipEntry::compile_the_world(Handle loader, TRAPS) {

   if (JDK_Version::is_jdk12x_version()) {

     compile_the_world12(loader, THREAD);

   } else {

     compile_the_world13(loader, THREAD);

   }

   if (HAS_PENDING_EXCEPTION) {

     if (PENDING_EXCEPTION->is_a(SystemDictionary::OutOfMemoryError_klass())) {

       CLEAR_PENDING_EXCEPTION;

       tty->print_cr("\nCompileTheWorld : Ran out of memory\n");

       size_t used = Universe::heap()->permanent_used();

       size_t capacity = Universe::heap()->permanent_capacity();

       tty->print_cr("Permanent generation used %dK of %dK", used/K, capacity/K);

       tty->print_cr("Increase size by setting e.g. -XX:MaxPermSize=%dK\n", capacity*2/K);

     } else {

       tty->print_cr("\nCompileTheWorld : Unexpected exception occurred\n");

     }

   }

 }

 // Version that works for JDK 1.3.x

 void ClassPathZipEntry::compile_the_world13(Handle loader, TRAPS) {

   real_jzfile13* zip = (real_jzfile13*) _zip;

   tty->print_cr("CompileTheWorld : Compiling all classes in %s", zip->name);

   tty->cr();

   // Iterate over all entries in zip file

   for (int n = 0; ; n++) {

     real_jzentry13 * ze = (real_jzentry13 *)((*GetNextEntry)(_zip, n));

     if (ze == NULL) break;

     ClassLoader::compile_the_world_in(ze->name, loader, CHECK);

   }

 }

 // Version that works for JDK 1.2.x

 void ClassPathZipEntry::compile_the_world12(Handle loader, TRAPS) {

   real_jzfile12* zip = (real_jzfile12*) _zip;

   tty->print_cr("CompileTheWorld : Compiling all classes in %s", zip->name);

   tty->cr();

   // Iterate over all entries in zip file

   for (int n = 0; ; n++) {

     real_jzentry12 * ze = (real_jzentry12 *)((*GetNextEntry)(_zip, n));

     if (ze == NULL) break;

     ClassLoader::compile_the_world_in(ze->name, loader, CHECK);

   }

 }

 bool ClassPathZipEntry::is_rt_jar() {

   if (JDK_Version::is_jdk12x_version()) {

     return is_rt_jar12();

   } else {

     return is_rt_jar13();

   }

 }

 // JDK 1.3 version

 bool ClassPathZipEntry::is_rt_jar13() {

   real_jzfile13* zip = (real_jzfile13*) _zip;

   int len = (int)strlen(zip->name);

   // Check whether zip name ends in "rt.jar"

   // This will match other archives named rt.jar as well, but this is

   // only used for debugging.

   return (len >= 6) && (strcasecmp(zip->name + len - 6, "rt.jar") == 0);

 }

 // JDK 1.2 version

 bool ClassPathZipEntry::is_rt_jar12() {

   real_jzfile12* zip = (real_jzfile12*) _zip;

   int len = (int)strlen(zip->name);

   // Check whether zip name ends in "rt.jar"

   // This will match other archives named rt.jar as well, but this is

   // only used for debugging.

   return (len >= 6) && (strcasecmp(zip->name + len - 6, "rt.jar") == 0);

 }

 void LazyClassPathEntry::compile_the_world(Handle loader, TRAPS) {

   resolve_entry()->compile_the_world(loader, CHECK);

 }

 bool LazyClassPathEntry::is_rt_jar() {

   return resolve_entry()->is_rt_jar();

 }

 void ClassLoader::compile_the_world() {

   EXCEPTION_MARK;

   HandleMark hm(THREAD);

   ResourceMark rm(THREAD);

   // Make sure we don't run with background compilation

   BackgroundCompilation = false;

   // Find bootstrap loader

   Handle system_class_loader (THREAD, SystemDictionary::java_system_loader());

   // Iterate over all bootstrap class path entries

   ClassPathEntry* e = _first_entry;

   while (e != NULL) {

     // We stop at rt.jar, unless it is the first bootstrap path entry

     if (e->is_rt_jar() && e != _first_entry) break;

     e->compile_the_world(system_class_loader, CATCH);

     e = e->next();

   }

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

   {

     // Print statistics as if before normal exit:

     extern void print_statistics();

     print_statistics();

   }

   vm_exit(0);

 }

 int ClassLoader::_compile_the_world_counter = 0;

 static int _codecache_sweep_counter = 0;

 // Filter out all exceptions except OOMs

 static void clear_pending_exception_if_not_oom(TRAPS) {

   if (HAS_PENDING_EXCEPTION &&

       !PENDING_EXCEPTION->is_a(SystemDictionary::OutOfMemoryError_klass())) {

     CLEAR_PENDING_EXCEPTION;

   }

   // The CHECK at the caller will propagate the exception out

 }

 void ClassLoader::compile_the_world_in(char* name, Handle loader, TRAPS) {

   int len = (int)strlen(name);

   if (len > 6 && strcmp(".class", name + len - 6) == 0) {

     // We have a .class file

     char buffer[2048];

     strncpy(buffer, name, len - 6);

     buffer[len-6] = 0;

     // If the file has a period after removing .class, it's not really a

     // valid class file.  The class loader will check everything else.

     if (strchr(buffer, '.') == NULL) {

       _compile_the_world_counter++;

       if (_compile_the_world_counter > CompileTheWorldStopAt) return;

       // Construct name without extension

       TempNewSymbol sym = SymbolTable::new_symbol(buffer, CHECK);

       // Use loader to load and initialize class

       klassOop ik = SystemDictionary::resolve_or_null(sym, loader, Handle(), THREAD);

       instanceKlassHandle k (THREAD, ik);

       if (k.not_null() && !HAS_PENDING_EXCEPTION) {

         k->initialize(THREAD);

       }

       bool exception_occurred = HAS_PENDING_EXCEPTION;

       clear_pending_exception_if_not_oom(CHECK);

       if (CompileTheWorldPreloadClasses && k.not_null()) {

         constantPoolKlass::preload_and_initialize_all_classes(k->constants(), THREAD);

         if (HAS_PENDING_EXCEPTION) {

           // If something went wrong in preloading we just ignore it

           clear_pending_exception_if_not_oom(CHECK);

           tty->print_cr("Preloading failed for (%d) %s", _compile_the_world_counter, buffer);

         }

       }

       if (_compile_the_world_counter >= CompileTheWorldStartAt) {

         if (k.is_null() || exception_occurred) {

           // If something went wrong (e.g. ExceptionInInitializerError) we skip this class

           tty->print_cr("CompileTheWorld (%d) : Skipping %s", _compile_the_world_counter, buffer);

         } else {

           tty->print_cr("CompileTheWorld (%d) : %s", _compile_the_world_counter, buffer);

           // Preload all classes to get around uncommon traps

           // Iterate over all methods in class

           for (int n = 0; n < k->methods()->length(); n++) {

             methodHandle m (THREAD, methodOop(k->methods()->obj_at(n)));

             if (CompilationPolicy::can_be_compiled(m)) {

               if (++_codecache_sweep_counter == CompileTheWorldSafepointInterval) {

                 // Give sweeper a chance to keep up with CTW

                 VM_ForceSafepoint op;

                 VMThread::execute(&op);

                 _codecache_sweep_counter = 0;

               }

               // Force compilation

               CompileBroker::compile_method(m, InvocationEntryBci, CompilationPolicy::policy()->initial_compile_level(),

                                             methodHandle(), 0, "CTW", THREAD);

               if (HAS_PENDING_EXCEPTION) {

                 clear_pending_exception_if_not_oom(CHECK);

                 tty->print_cr("CompileTheWorld (%d) : Skipping method: %s", _compile_the_world_counter, m->name()->as_C_string());

               }

               if (TieredCompilation && TieredStopAtLevel >= CompLevel_full_optimization) {

                 // Clobber the first compile and force second tier compilation

                 nmethod* nm = m->code();

                 if (nm != NULL) {

                   // Throw out the code so that the code cache doesn't fill up

                   nm->make_not_entrant();

                   m->clear_code();

                 }

                 CompileBroker::compile_method(m, InvocationEntryBci, CompLevel_full_optimization,

                                               methodHandle(), 0, "CTW", THREAD);

                 if (HAS_PENDING_EXCEPTION) {

                   clear_pending_exception_if_not_oom(CHECK);

                   tty->print_cr("CompileTheWorld (%d) : Skipping method: %s", _compile_the_world_counter, m->name()->as_C_string());

                 }

               }

             }

             nmethod* nm = m->code();

             if (nm != NULL) {

               // Throw out the code so that the code cache doesn't fill up

               nm->make_not_entrant();

               m->clear_code();

             }

           }

         }

       }

     }

   }

 }

 #endif //PRODUCT

 // Please keep following two functions at end of this file. With them placed at top or in middle of the file,

 // they could get inlined by agressive compiler, an unknown trick, see bug 6966589.

 void PerfClassTraceTime::initialize() {

   if (!UsePerfData) return;

   if (_eventp != NULL) {

     // increment the event counter

     _eventp->inc();

   }

   // stop the current active thread-local timer to measure inclusive time

   _prev_active_event = -1;

   for (int i=0; i < EVENT_TYPE_COUNT; i++) {

      if (_timers[i].is_active()) {

        assert(_prev_active_event == -1, "should have only one active timer");

        _prev_active_event = i;

        _timers[i].stop();

      }

   }

   if (_recursion_counters == NULL || (_recursion_counters[_event_type])++ == 0) {

     // start the inclusive timer if not recursively called

     _t.start();

   }

   // start thread-local timer of the given event type

    if (!_timers[_event_type].is_active()) {

     _timers[_event_type].start();

   }

 }

 PerfClassTraceTime::~PerfClassTraceTime() {

   if (!UsePerfData) return;

   // stop the thread-local timer as the event completes

   // and resume the thread-local timer of the event next on the stack

   _timers[_event_type].stop();

   jlong selftime = _timers[_event_type].ticks();

   if (_prev_active_event >= 0) {

     _timers[_prev_active_event].start();

   }

   if (_recursion_counters != NULL && --(_recursion_counters[_event_type]) > 0) return;

   // increment the counters only on the leaf call

   _t.stop();

   _timep->inc(_t.ticks());

   if (_selftimep != NULL) {

     _selftimep->inc(selftime);

   }

   // add all class loading related event selftime to the accumulated time counter

   ClassLoader::perf_accumulated_time()->inc(selftime);

   // reset the timer

   _timers[_event_type].reset();

 }