src/share/vm/oops/symbol.hpp - platform/external/jetbrains/jdk8u_hotspot - Git at Google

 /*
  * Copyright (c) 1997, 2014, 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.
  *
  */

 #ifndef SHARE_VM_OOPS_SYMBOL_HPP
 #define SHARE_VM_OOPS_SYMBOL_HPP

 #include "utilities/utf8.hpp"
 #include "memory/allocation.hpp"
 #include "runtime/atomic.hpp"

 // A Symbol is a canonicalized string.
 // All Symbols reside in global SymbolTable and are reference counted.

 // Reference counting
 //
 // All Symbols are allocated and added to the SymbolTable.
 // When a class is unloaded, the reference counts of the Symbol pointers in
 // the ConstantPool and in InstanceKlass (see release_C_heap_structures) are
 // decremented.  When the reference count for a Symbol goes to 0, the garbage
 // collector can free the Symbol and remove it from the SymbolTable.
 //
 // 0) Symbols need to be reference counted when a pointer to the Symbol is
 // saved in persistent storage.  This does not include the pointer
 // in the SymbolTable bucket (the _literal field in HashtableEntry)
 // that points to the Symbol.  All other stores of a Symbol*
 // to a field of a persistent variable (e.g., the _name filed in
 // fieldDescriptor or _ptr in a CPSlot) is reference counted.
 //
 // 1) The lookup of a "name" in the SymbolTable either creates a Symbol F for
 // "name" and returns a pointer to F or finds a pre-existing Symbol F for
 // "name" and returns a pointer to it. In both cases the reference count for F
 // is incremented under the assumption that a pointer to F will be created from
 // the return value. Thus the increment of the reference count is on the lookup
 // and not on the assignment to the new Symbol*.  That is
 //    Symbol* G = lookup()
 //                ^ increment on lookup()
 // and not
 //    Symbol* G = lookup()
 //              ^ increment on assignmnet
 // The reference count must be decremented manually when the copy of the
 // pointer G is destroyed.
 //
 // 2) For a local Symbol* A that is a copy of an existing Symbol* B, the
 // reference counting is elided when the scope of B is greater than the scope
 // of A.  For example, in the code fragment
 // below "klass" is passed as a parameter to the method.  Symbol* "kn"
 // is a copy of the name in "klass".
 //
 //   Symbol*  kn = klass->name();
 //   unsigned int d_hash = dictionary()->compute_hash(kn, class_loader);
 //
 // The scope of "klass" is greater than the scope of "kn" so the reference
 // counting for "kn" is elided.
 //
 // Symbol* copied from ConstantPool entries are good candidates for reference
 // counting elision.  The ConstantPool entries for a class C exist until C is
 // unloaded.  If a Symbol* is copied out of the ConstantPool into Symbol* X,
 // the Symbol* in the ConstantPool will in general out live X so the reference
 // counting on X can be elided.
 //
 // For cases where the scope of A is not greater than the scope of B,
 // the reference counting is explicitly done.  See ciSymbol,
 // ResolutionErrorEntry and ClassVerifier for examples.
 //
 // 3) When a Symbol K is created for temporary use, generally for substrings of
 // an existing symbol or to create a new symbol, assign it to a
 // TempNewSymbol. The SymbolTable methods new_symbol(), lookup()
 // and probe() all potentially return a pointer to a new Symbol.
 // The allocation (or lookup) of K increments the reference count for K
 // and the destructor decrements the reference count.
 //
 // Another example of TempNewSymbol usage is parsed_name used in
 // ClassFileParser::parseClassFile() where parsed_name is used in the cleanup
 // after a failed attempt to load a class.  Here parsed_name is a
 // TempNewSymbol (passed in as a parameter) so the reference count on its symbol
 // will be decremented when it goes out of scope.


 // This cannot be inherited from ResourceObj because it cannot have a vtable.
 // Since sometimes this is allocated from Metadata, pick a base allocation
 // type without virtual functions.
 class ClassLoaderData;

 // We separate the fields in SymbolBase from Symbol::_body so that
 // Symbol::size(int) can correctly calculate the space needed.
 class SymbolBase : public MetaspaceObj {
  public:
   ATOMIC_SHORT_PAIR(
     volatile short _refcount,  // needs atomic operation
     unsigned short _length     // number of UTF8 characters in the symbol (does not need atomic op)
   );
   int            _identity_hash;
 };

 class Symbol : private SymbolBase {
   friend class VMStructs;
   friend class SymbolTable;
   friend class MoveSymbols;
  private:
   jbyte _body[1];

   enum {
     // max_symbol_length is constrained by type of _length
     max_symbol_length = (1 << 16) -1
   };

   static int size(int length) {
     size_t sz = heap_word_size(sizeof(SymbolBase) + (length > 0 ? length : 0));
     return align_object_size(sz);
   }

   void byte_at_put(int index, int value) {
     assert(index >=0 && index < _length, "symbol index overflow");
     _body[index] = value;
   }

   Symbol(const u1* name, int length, int refcount);
   void* operator new(size_t size, int len, TRAPS) throw();
   void* operator new(size_t size, int len, Arena* arena, TRAPS) throw();
   void* operator new(size_t size, int len, ClassLoaderData* loader_data, TRAPS) throw();

   void  operator delete(void* p);

  public:
   // Low-level access (used with care, since not GC-safe)
   const jbyte* base() const { return &_body[0]; }

   int size()                { return size(utf8_length()); }

   // Returns the largest size symbol we can safely hold.
   static int max_length()   { return max_symbol_length; }

   int identity_hash()       { return _identity_hash; }

   // For symbol table alternate hashing
   unsigned int new_hash(juint seed);

   // Reference counting.  See comments above this class for when to use.
   int refcount() const      { return _refcount; }
   void increment_refcount();
   void decrement_refcount();

   int byte_at(int index) const {
     assert(index >=0 && index < _length, "symbol index overflow");
     return base()[index];
   }

   const jbyte* bytes() const { return base(); }

   int utf8_length() const { return _length; }

   // Compares the symbol with a string.
   bool equals(const char* str, int len) const;
   bool equals(const char* str) const { return equals(str, (int) strlen(str)); }

   // Tests if the symbol starts with the given prefix.
   bool starts_with(const char* prefix, int len) const;
   bool starts_with(const char* prefix) const {
     return starts_with(prefix, (int) strlen(prefix));
   }

   // Tests if the symbol starts with the given prefix.
   int index_of_at(int i, const char* str, int len) const;
   int index_of_at(int i, const char* str) const {
     return index_of_at(i, str, (int) strlen(str));
   }

   // Three-way compare for sorting; returns -1/0/1 if receiver is </==/> than arg
   // note that the ordering is not alfabetical
   inline int fast_compare(Symbol* other) const;

   // Returns receiver converted to null-terminated UTF-8 string; string is
   // allocated in resource area, or in the char buffer provided by caller.
   char* as_C_string() const;
   char* as_C_string(char* buf, int size) const;
   // Use buf if needed buffer length is <= size.
   char* as_C_string_flexible_buffer(Thread* t, char* buf, int size) const;

   // Returns an escaped form of a Java string.
   char* as_quoted_ascii() const;

   // Returns a null terminated utf8 string in a resource array
   char* as_utf8() const { return as_C_string(); }
   char* as_utf8_flexible_buffer(Thread* t, char* buf, int size) const {
     return as_C_string_flexible_buffer(t, buf, size);
   }

   jchar* as_unicode(int& length) const;

   // Treating this symbol as a class name, returns the Java name for the class.
   // String is allocated in resource area if buffer is not provided.
   // See Klass::external_name()
   const char* as_klass_external_name() const;
   const char* as_klass_external_name(char* buf, int size) const;

   // Printing
   void print_symbol_on(outputStream* st = NULL) const;
   void print_on(outputStream* st) const;         // First level print
   void print_value_on(outputStream* st) const;   // Second level print.

   // printing on default output stream
   void print()         { print_on(tty);       }
   void print_value()   { print_value_on(tty); }

 #ifndef PRODUCT
   // Empty constructor to create a dummy symbol object on stack
   // only for getting its vtable pointer.
   Symbol() { }

   static int _total_count;
 #endif
 };

 // Note: this comparison is used for vtable sorting only; it doesn't matter
 // what order it defines, as long as it is a total, time-invariant order
 // Since Symbol*s are in C_HEAP, their relative order in memory never changes,
 // so use address comparison for speed
 int Symbol::fast_compare(Symbol* other) const {
  return (((uintptr_t)this < (uintptr_t)other) ? -1
    : ((uintptr_t)this == (uintptr_t) other) ? 0 : 1);
 }
 #endif // SHARE_VM_OOPS_SYMBOL_HPP
	/*
	* Copyright (c) 1997, 2014, 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.
	*
	*/

	#ifndef SHARE_VM_OOPS_SYMBOL_HPP
	#define SHARE_VM_OOPS_SYMBOL_HPP

	#include "utilities/utf8.hpp"
	#include "memory/allocation.hpp"
	#include "runtime/atomic.hpp"

	// A Symbol is a canonicalized string.
	// All Symbols reside in global SymbolTable and are reference counted.

	// Reference counting
	//
	// All Symbols are allocated and added to the SymbolTable.
	// When a class is unloaded, the reference counts of the Symbol pointers in
	// the ConstantPool and in InstanceKlass (see release_C_heap_structures) are
	// decremented. When the reference count for a Symbol goes to 0, the garbage
	// collector can free the Symbol and remove it from the SymbolTable.
	//
	// 0) Symbols need to be reference counted when a pointer to the Symbol is
	// saved in persistent storage. This does not include the pointer
	// in the SymbolTable bucket (the _literal field in HashtableEntry)
	// that points to the Symbol. All other stores of a Symbol*
	// to a field of a persistent variable (e.g., the _name filed in
	// fieldDescriptor or _ptr in a CPSlot) is reference counted.
	//
	// 1) The lookup of a "name" in the SymbolTable either creates a Symbol F for
	// "name" and returns a pointer to F or finds a pre-existing Symbol F for
	// "name" and returns a pointer to it. In both cases the reference count for F
	// is incremented under the assumption that a pointer to F will be created from
	// the return value. Thus the increment of the reference count is on the lookup
	// and not on the assignment to the new Symbol*. That is
	// Symbol* G = lookup()
	// ^ increment on lookup()
	// and not
	// Symbol* G = lookup()
	// ^ increment on assignmnet
	// The reference count must be decremented manually when the copy of the
	// pointer G is destroyed.
	//
	// 2) For a local Symbol* A that is a copy of an existing Symbol* B, the
	// reference counting is elided when the scope of B is greater than the scope
	// of A. For example, in the code fragment
	// below "klass" is passed as a parameter to the method. Symbol* "kn"
	// is a copy of the name in "klass".
	//
	// Symbol* kn = klass->name();
	// unsigned int d_hash = dictionary()->compute_hash(kn, class_loader);
	//
	// The scope of "klass" is greater than the scope of "kn" so the reference
	// counting for "kn" is elided.
	//
	// Symbol* copied from ConstantPool entries are good candidates for reference
	// counting elision. The ConstantPool entries for a class C exist until C is
	// unloaded. If a Symbol* is copied out of the ConstantPool into Symbol* X,
	// the Symbol* in the ConstantPool will in general out live X so the reference
	// counting on X can be elided.
	//
	// For cases where the scope of A is not greater than the scope of B,
	// the reference counting is explicitly done. See ciSymbol,
	// ResolutionErrorEntry and ClassVerifier for examples.
	//
	// 3) When a Symbol K is created for temporary use, generally for substrings of
	// an existing symbol or to create a new symbol, assign it to a
	// TempNewSymbol. The SymbolTable methods new_symbol(), lookup()
	// and probe() all potentially return a pointer to a new Symbol.
	// The allocation (or lookup) of K increments the reference count for K
	// and the destructor decrements the reference count.
	//
	// Another example of TempNewSymbol usage is parsed_name used in
	// ClassFileParser::parseClassFile() where parsed_name is used in the cleanup
	// after a failed attempt to load a class. Here parsed_name is a
	// TempNewSymbol (passed in as a parameter) so the reference count on its symbol
	// will be decremented when it goes out of scope.


	// This cannot be inherited from ResourceObj because it cannot have a vtable.
	// Since sometimes this is allocated from Metadata, pick a base allocation
	// type without virtual functions.
	class ClassLoaderData;

	// We separate the fields in SymbolBase from Symbol::_body so that
	// Symbol::size(int) can correctly calculate the space needed.
	class SymbolBase : public MetaspaceObj {
	public:
	ATOMIC_SHORT_PAIR(
	volatile short _refcount, // needs atomic operation
	unsigned short _length // number of UTF8 characters in the symbol (does not need atomic op)
	);
	int _identity_hash;
	};

	class Symbol : private SymbolBase {
	friend class VMStructs;
	friend class SymbolTable;
	friend class MoveSymbols;
	private:
	jbyte _body[1];

	enum {
	// max_symbol_length is constrained by type of _length
	max_symbol_length = (1 << 16) -1
	};

	static int size(int length) {
	size_t sz = heap_word_size(sizeof(SymbolBase) + (length > 0 ? length : 0));
	return align_object_size(sz);
	}

	void byte_at_put(int index, int value) {
	assert(index >=0 && index < _length, "symbol index overflow");
	_body[index] = value;
	}

	Symbol(const u1* name, int length, int refcount);
	void* operator new(size_t size, int len, TRAPS) throw();
	void* operator new(size_t size, int len, Arena* arena, TRAPS) throw();
	void* operator new(size_t size, int len, ClassLoaderData* loader_data, TRAPS) throw();

	void operator delete(void* p);

	public:
	// Low-level access (used with care, since not GC-safe)
	const jbyte* base() const { return &_body[0]; }

	int size() { return size(utf8_length()); }

	// Returns the largest size symbol we can safely hold.
	static int max_length() { return max_symbol_length; }

	int identity_hash() { return _identity_hash; }

	// For symbol table alternate hashing
	unsigned int new_hash(juint seed);

	// Reference counting. See comments above this class for when to use.
	int refcount() const { return _refcount; }
	void increment_refcount();
	void decrement_refcount();

	int byte_at(int index) const {
	assert(index >=0 && index < _length, "symbol index overflow");
	return base()[index];
	}

	const jbyte* bytes() const { return base(); }

	int utf8_length() const { return _length; }

	// Compares the symbol with a string.
	bool equals(const char* str, int len) const;
	bool equals(const char* str) const { return equals(str, (int) strlen(str)); }

	// Tests if the symbol starts with the given prefix.
	bool starts_with(const char* prefix, int len) const;
	bool starts_with(const char* prefix) const {
	return starts_with(prefix, (int) strlen(prefix));
	}

	// Tests if the symbol starts with the given prefix.
	int index_of_at(int i, const char* str, int len) const;
	int index_of_at(int i, const char* str) const {
	return index_of_at(i, str, (int) strlen(str));
	}

	// Three-way compare for sorting; returns -1/0/1 if receiver is </==/> than arg
	// note that the ordering is not alfabetical
	inline int fast_compare(Symbol* other) const;

	// Returns receiver converted to null-terminated UTF-8 string; string is
	// allocated in resource area, or in the char buffer provided by caller.
	char* as_C_string() const;
	char* as_C_string(char* buf, int size) const;
	// Use buf if needed buffer length is <= size.
	char* as_C_string_flexible_buffer(Thread* t, char* buf, int size) const;

	// Returns an escaped form of a Java string.
	char* as_quoted_ascii() const;

	// Returns a null terminated utf8 string in a resource array
	char* as_utf8() const { return as_C_string(); }
	char* as_utf8_flexible_buffer(Thread* t, char* buf, int size) const {
	return as_C_string_flexible_buffer(t, buf, size);
	}

	jchar* as_unicode(int& length) const;

	// Treating this symbol as a class name, returns the Java name for the class.
	// String is allocated in resource area if buffer is not provided.
	// See Klass::external_name()
	const char* as_klass_external_name() const;
	const char* as_klass_external_name(char* buf, int size) const;

	// Printing
	void print_symbol_on(outputStream* st = NULL) const;
	void print_on(outputStream* st) const; // First level print
	void print_value_on(outputStream* st) const; // Second level print.

	// printing on default output stream
	void print() { print_on(tty); }
	void print_value() { print_value_on(tty); }

	#ifndef PRODUCT
	// Empty constructor to create a dummy symbol object on stack
	// only for getting its vtable pointer.
	Symbol() { }

	static int _total_count;
	#endif
	};

	// Note: this comparison is used for vtable sorting only; it doesn't matter
	// what order it defines, as long as it is a total, time-invariant order
	// Since Symbol*s are in C_HEAP, their relative order in memory never changes,
	// so use address comparison for speed
	int Symbol::fast_compare(Symbol* other) const {
	return (((uintptr_t)this < (uintptr_t)other) ? -1
	: ((uintptr_t)this == (uintptr_t) other) ? 0 : 1);
	}
	#endif // SHARE_VM_OOPS_SYMBOL_HPP