src/share/vm/utilities/stack.hpp - platform/external/jetbrains/jdk8u_hotspot - Git at Google

 /*
  * Copyright (c) 2009, 2012, 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_UTILITIES_STACK_HPP
 #define SHARE_VM_UTILITIES_STACK_HPP

 #include "memory/allocation.hpp"
 #include "memory/allocation.inline.hpp"

 // Class Stack (below) grows and shrinks by linking together "segments" which
 // are allocated on demand.  Segments are arrays of the element type (E) plus an
 // extra pointer-sized field to store the segment link.  Recently emptied
 // segments are kept in a cache and reused.
 //
 // Notes/caveats:
 //
 // The size of an element must either evenly divide the size of a pointer or be
 // a multiple of the size of a pointer.
 //
 // Destructors are not called for elements popped off the stack, so element
 // types which rely on destructors for things like reference counting will not
 // work properly.
 //
 // Class Stack allocates segments from the C heap.  However, two protected
 // virtual methods are used to alloc/free memory which subclasses can override:
 //
 //      virtual void* alloc(size_t bytes);
 //      virtual void  free(void* addr, size_t bytes);
 //
 // The alloc() method must return storage aligned for any use.  The
 // implementation in class Stack assumes that alloc() will terminate the process
 // if the allocation fails.

 template <class E, MEMFLAGS F> class StackIterator;

 // StackBase holds common data/methods that don't depend on the element type,
 // factored out to reduce template code duplication.
 template <MEMFLAGS F> class StackBase
 {
 public:
   size_t segment_size()   const { return _seg_size; } // Elements per segment.
   size_t max_size()       const { return _max_size; } // Max elements allowed.
   size_t max_cache_size() const { return _max_cache_size; } // Max segments
                                                             // allowed in cache.

   size_t cache_size() const { return _cache_size; }   // Segments in the cache.

 protected:
   // The ctor arguments correspond to the like-named functions above.
   // segment_size:    number of items per segment
   // max_cache_size:  maxmium number of *segments* to cache
   // max_size:        maximum number of items allowed, rounded to a multiple of
   //                  the segment size (0 == unlimited)
   inline StackBase(size_t segment_size, size_t max_cache_size, size_t max_size);

   // Round max_size to a multiple of the segment size.  Treat 0 as unlimited.
   static inline size_t adjust_max_size(size_t max_size, size_t seg_size);

 protected:
   const size_t _seg_size;       // Number of items per segment.
   const size_t _max_size;       // Maximum number of items allowed in the stack.
   const size_t _max_cache_size; // Maximum number of segments to cache.
   size_t       _cur_seg_size;   // Number of items in the current segment.
   size_t       _full_seg_size;  // Number of items in already-filled segments.
   size_t       _cache_size;     // Number of segments in the cache.
 };

 #ifdef __GNUC__
 #define inline
 #endif // __GNUC__

 template <class E, MEMFLAGS F>
 class Stack:  public StackBase<F>
 {
 public:
   friend class StackIterator<E, F>;

   // segment_size:    number of items per segment
   // max_cache_size:  maxmium number of *segments* to cache
   // max_size:        maximum number of items allowed, rounded to a multiple of
   //                  the segment size (0 == unlimited)
   inline Stack(size_t segment_size = default_segment_size(),
                size_t max_cache_size = 4, size_t max_size = 0);
   inline ~Stack() { clear(true); }

   inline bool is_empty() const { return this->_cur_seg == NULL; }
   inline bool is_full()  const { return this->_full_seg_size >= this->max_size(); }

   // Performance sensitive code should use is_empty() instead of size() == 0 and
   // is_full() instead of size() == max_size().  Using a conditional here allows
   // just one var to be updated when pushing/popping elements instead of two;
   // _full_seg_size is updated only when pushing/popping segments.
   inline size_t size() const {
     return is_empty() ? 0 : this->_full_seg_size + this->_cur_seg_size;
   }

   inline void push(E elem);
   inline E    pop();

   // Clear everything from the stack, releasing the associated memory.  If
   // clear_cache is true, also release any cached segments.
   void clear(bool clear_cache = false);

   static inline size_t default_segment_size();

 protected:
   // Each segment includes space for _seg_size elements followed by a link
   // (pointer) to the previous segment; the space is allocated as a single block
   // of size segment_bytes().  _seg_size is rounded up if necessary so the link
   // is properly aligned.  The C struct for the layout would be:
   //
   // struct segment {
   //   E     elements[_seg_size];
   //   E*    link;
   // };

   // Round up seg_size to keep the link field aligned.
   static inline size_t adjust_segment_size(size_t seg_size);

   // Methods for allocation size and getting/setting the link.
   inline size_t link_offset() const;              // Byte offset of link field.
   inline size_t segment_bytes() const;            // Segment size in bytes.
   inline E**    link_addr(E* seg) const;          // Address of the link field.
   inline E*     get_link(E* seg) const;           // Extract the link from seg.
   inline E*     set_link(E* new_seg, E* old_seg); // new_seg.link = old_seg.

   virtual E*    alloc(size_t bytes);
   virtual void  free(E* addr, size_t bytes);

   void push_segment();
   void pop_segment();

   void free_segments(E* seg);          // Free all segments in the list.
   inline void reset(bool reset_cache); // Reset all data fields.

   DEBUG_ONLY(void verify(bool at_empty_transition) const;)
   DEBUG_ONLY(void zap_segment(E* seg, bool zap_link_field) const;)

 private:
   E* _cur_seg;    // Current segment.
   E* _cache;      // Segment cache to avoid ping-ponging.
 };

 template <class E, MEMFLAGS F> class ResourceStack:  public Stack<E, F>, public ResourceObj
 {
 public:
   // If this class becomes widely used, it may make sense to save the Thread
   // and use it when allocating segments.
 //  ResourceStack(size_t segment_size = Stack<E, F>::default_segment_size()):
   ResourceStack(size_t segment_size): Stack<E, F>(segment_size, max_uintx)
     { }

   // Set the segment pointers to NULL so the parent dtor does not free them;
   // that must be done by the ResourceMark code.
   ~ResourceStack() { Stack<E, F>::reset(true); }

 protected:
   virtual E*   alloc(size_t bytes);
   virtual void free(E* addr, size_t bytes);

 private:
   void clear(bool clear_cache = false);
 };

 template <class E, MEMFLAGS F>
 class StackIterator: public StackObj
 {
 public:
   StackIterator(Stack<E, F>& stack): _stack(stack) { sync(); }

   Stack<E, F>& stack() const { return _stack; }

   bool is_empty() const { return _cur_seg == NULL; }

   E  next() { return *next_addr(); }
   E* next_addr();

   void sync(); // Sync the iterator's state to the stack's current state.

 private:
   Stack<E, F>& _stack;
   size_t    _cur_seg_size;
   E*        _cur_seg;
   size_t    _full_seg_size;
 };

 #ifdef __GNUC__
 #undef inline
 #endif // __GNUC__

 #endif // SHARE_VM_UTILITIES_STACK_HPP
	/*
	* Copyright (c) 2009, 2012, 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_UTILITIES_STACK_HPP
	#define SHARE_VM_UTILITIES_STACK_HPP

	#include "memory/allocation.hpp"
	#include "memory/allocation.inline.hpp"

	// Class Stack (below) grows and shrinks by linking together "segments" which
	// are allocated on demand. Segments are arrays of the element type (E) plus an
	// extra pointer-sized field to store the segment link. Recently emptied
	// segments are kept in a cache and reused.
	//
	// Notes/caveats:
	//
	// The size of an element must either evenly divide the size of a pointer or be
	// a multiple of the size of a pointer.
	//
	// Destructors are not called for elements popped off the stack, so element
	// types which rely on destructors for things like reference counting will not
	// work properly.
	//
	// Class Stack allocates segments from the C heap. However, two protected
	// virtual methods are used to alloc/free memory which subclasses can override:
	//
	// virtual void* alloc(size_t bytes);
	// virtual void free(void* addr, size_t bytes);
	//
	// The alloc() method must return storage aligned for any use. The
	// implementation in class Stack assumes that alloc() will terminate the process
	// if the allocation fails.

	template <class E, MEMFLAGS F> class StackIterator;

	// StackBase holds common data/methods that don't depend on the element type,
	// factored out to reduce template code duplication.
	template <MEMFLAGS F> class StackBase
	{
	public:
	size_t segment_size() const { return _seg_size; } // Elements per segment.
	size_t max_size() const { return _max_size; } // Max elements allowed.
	size_t max_cache_size() const { return _max_cache_size; } // Max segments
	// allowed in cache.

	size_t cache_size() const { return _cache_size; } // Segments in the cache.

	protected:
	// The ctor arguments correspond to the like-named functions above.
	// segment_size: number of items per segment
	// max_cache_size: maxmium number of segments to cache
	// max_size: maximum number of items allowed, rounded to a multiple of
	// the segment size (0 == unlimited)
	inline StackBase(size_t segment_size, size_t max_cache_size, size_t max_size);

	// Round max_size to a multiple of the segment size. Treat 0 as unlimited.
	static inline size_t adjust_max_size(size_t max_size, size_t seg_size);

	protected:
	const size_t _seg_size; // Number of items per segment.
	const size_t _max_size; // Maximum number of items allowed in the stack.
	const size_t _max_cache_size; // Maximum number of segments to cache.
	size_t _cur_seg_size; // Number of items in the current segment.
	size_t _full_seg_size; // Number of items in already-filled segments.
	size_t _cache_size; // Number of segments in the cache.
	};

	#ifdef __GNUC__
	#define inline
	#endif // __GNUC__

	template <class E, MEMFLAGS F>
	class Stack: public StackBase<F>
	{
	public:
	friend class StackIterator<E, F>;

	// segment_size: number of items per segment
	// max_cache_size: maxmium number of segments to cache
	// max_size: maximum number of items allowed, rounded to a multiple of
	// the segment size (0 == unlimited)
	inline Stack(size_t segment_size = default_segment_size(),
	size_t max_cache_size = 4, size_t max_size = 0);
	inline ~Stack() { clear(true); }

	inline bool is_empty() const { return this->_cur_seg == NULL; }
	inline bool is_full() const { return this->_full_seg_size >= this->max_size(); }

	// Performance sensitive code should use is_empty() instead of size() == 0 and
	// is_full() instead of size() == max_size(). Using a conditional here allows
	// just one var to be updated when pushing/popping elements instead of two;
	// _full_seg_size is updated only when pushing/popping segments.
	inline size_t size() const {
	return is_empty() ? 0 : this->_full_seg_size + this->_cur_seg_size;
	}

	inline void push(E elem);
	inline E pop();

	// Clear everything from the stack, releasing the associated memory. If
	// clear_cache is true, also release any cached segments.
	void clear(bool clear_cache = false);

	static inline size_t default_segment_size();

	protected:
	// Each segment includes space for _seg_size elements followed by a link
	// (pointer) to the previous segment; the space is allocated as a single block
	// of size segment_bytes(). _seg_size is rounded up if necessary so the link
	// is properly aligned. The C struct for the layout would be:
	//
	// struct segment {
	// E elements[_seg_size];
	// E* link;
	// };

	// Round up seg_size to keep the link field aligned.
	static inline size_t adjust_segment_size(size_t seg_size);

	// Methods for allocation size and getting/setting the link.
	inline size_t link_offset() const; // Byte offset of link field.
	inline size_t segment_bytes() const; // Segment size in bytes.
	inline E** link_addr(E* seg) const; // Address of the link field.
	inline E* get_link(E* seg) const; // Extract the link from seg.
	inline E* set_link(E* new_seg, E* old_seg); // new_seg.link = old_seg.

	virtual E* alloc(size_t bytes);
	virtual void free(E* addr, size_t bytes);

	void push_segment();
	void pop_segment();

	void free_segments(E* seg); // Free all segments in the list.
	inline void reset(bool reset_cache); // Reset all data fields.

	DEBUG_ONLY(void verify(bool at_empty_transition) const;)
	DEBUG_ONLY(void zap_segment(E* seg, bool zap_link_field) const;)

	private:
	E* _cur_seg; // Current segment.
	E* _cache; // Segment cache to avoid ping-ponging.
	};

	template <class E, MEMFLAGS F> class ResourceStack: public Stack<E, F>, public ResourceObj
	{
	public:
	// If this class becomes widely used, it may make sense to save the Thread
	// and use it when allocating segments.
	// ResourceStack(size_t segment_size = Stack<E, F>::default_segment_size()):
	ResourceStack(size_t segment_size): Stack<E, F>(segment_size, max_uintx)
	{ }

	// Set the segment pointers to NULL so the parent dtor does not free them;
	// that must be done by the ResourceMark code.
	~ResourceStack() { Stack<E, F>::reset(true); }

	protected:
	virtual E* alloc(size_t bytes);
	virtual void free(E* addr, size_t bytes);

	private:
	void clear(bool clear_cache = false);
	};

	template <class E, MEMFLAGS F>
	class StackIterator: public StackObj
	{
	public:
	StackIterator(Stack<E, F>& stack): _stack(stack) { sync(); }

	Stack<E, F>& stack() const { return _stack; }

	bool is_empty() const { return _cur_seg == NULL; }

	E next() { return *next_addr(); }
	E* next_addr();

	void sync(); // Sync the iterator's state to the stack's current state.

	private:
	Stack<E, F>& _stack;
	size_t _cur_seg_size;
	E* _cur_seg;
	size_t _full_seg_size;
	};

	#ifdef __GNUC__
	#undef inline
	#endif // __GNUC__

	#endif // SHARE_VM_UTILITIES_STACK_HPP