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src/share/vm/utilities/stack.inline.hpp@710a3c8b516e (annotated)

src/share/vm/utilities/stack.inline.hpp

Tue, 08 Aug 2017 15:57:29 +0800

author

aoqi

date

Tue, 08 Aug 2017 15:57:29 +0800

changeset 6876

710a3c8b516e

parent 4153

b9a9ed0f8eeb

parent 0

f90c822e73f8

child 9448

73d689add964

permissions

-rw-r--r--

merge

aoqi@0	1	/*
aoqi@0	2	* Copyright (c) 2009, 2012, Oracle and/or its affiliates. All rights reserved.
aoqi@0	3	* DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
aoqi@0	4	*
aoqi@0	5	* This code is free software; you can redistribute it and/or modify it
aoqi@0	6	* under the terms of the GNU General Public License version 2 only, as
aoqi@0	7	* published by the Free Software Foundation.
aoqi@0	8	*
aoqi@0	9	* This code is distributed in the hope that it will be useful, but WITHOUT
aoqi@0	10	* ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
aoqi@0	11	* FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
aoqi@0	12	* version 2 for more details (a copy is included in the LICENSE file that
aoqi@0	13	* accompanied this code).
aoqi@0	14	*
aoqi@0	15	* You should have received a copy of the GNU General Public License version
aoqi@0	16	* 2 along with this work; if not, write to the Free Software Foundation,
aoqi@0	17	* Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA.
aoqi@0	18	*
aoqi@0	19	* Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA
aoqi@0	20	* or visit www.oracle.com if you need additional information or have any
aoqi@0	21	* questions.
aoqi@0	22	*
aoqi@0	23	*/
aoqi@0	24
aoqi@0	25	#ifndef SHARE_VM_UTILITIES_STACK_INLINE_HPP
aoqi@0	26	#define SHARE_VM_UTILITIES_STACK_INLINE_HPP
aoqi@0	27
aoqi@0	28	#include "utilities/stack.hpp"
aoqi@0	29
aoqi@0	30	template <MEMFLAGS F> StackBase<F>::StackBase(size_t segment_size, size_t max_cache_size,
aoqi@0	31	size_t max_size):
aoqi@0	32	_seg_size(segment_size),
aoqi@0	33	_max_cache_size(max_cache_size),
aoqi@0	34	_max_size(adjust_max_size(max_size, segment_size))
aoqi@0	35	{
aoqi@0	36	assert(_max_size % _seg_size == 0, "not a multiple");
aoqi@0	37	}
aoqi@0	38
aoqi@0	39	template <MEMFLAGS F> size_t StackBase<F>::adjust_max_size(size_t max_size, size_t seg_size)
aoqi@0	40	{
aoqi@0	41	assert(seg_size > 0, "cannot be 0");
aoqi@0	42	assert(max_size >= seg_size || max_size == 0, "max_size too small");
aoqi@0	43	const size_t limit = max_uintx - (seg_size - 1);
aoqi@0	44	if (max_size == 0 || max_size > limit) {
aoqi@0	45	max_size = limit;
aoqi@0	46	}
aoqi@0	47	return (max_size + seg_size - 1) / seg_size * seg_size;
aoqi@0	48	}
aoqi@0	49
aoqi@0	50	template <class E, MEMFLAGS F>
aoqi@0	51	Stack<E, F>::Stack(size_t segment_size, size_t max_cache_size, size_t max_size):
aoqi@0	52	StackBase<F>(adjust_segment_size(segment_size), max_cache_size, max_size)
aoqi@0	53	{
aoqi@0	54	reset(true);
aoqi@0	55	}
aoqi@0	56
aoqi@0	57	template <class E, MEMFLAGS F>
aoqi@0	58	void Stack<E, F>::push(E item)
aoqi@0	59	{
aoqi@0	60	assert(!is_full(), "pushing onto a full stack");
aoqi@0	61	if (this->_cur_seg_size == this->_seg_size) {
aoqi@0	62	push_segment();
aoqi@0	63	}
aoqi@0	64	this->_cur_seg[this->_cur_seg_size] = item;
aoqi@0	65	++this->_cur_seg_size;
aoqi@0	66	}
aoqi@0	67
aoqi@0	68	template <class E, MEMFLAGS F>
aoqi@0	69	E Stack<E, F>::pop()
aoqi@0	70	{
aoqi@0	71	assert(!is_empty(), "popping from an empty stack");
aoqi@0	72	if (this->_cur_seg_size == 1) {
aoqi@0	73	E tmp = _cur_seg[--this->_cur_seg_size];
aoqi@0	74	pop_segment();
aoqi@0	75	return tmp;
aoqi@0	76	}
aoqi@0	77	return this->_cur_seg[--this->_cur_seg_size];
aoqi@0	78	}
aoqi@0	79
aoqi@0	80	template <class E, MEMFLAGS F>
aoqi@0	81	void Stack<E, F>::clear(bool clear_cache)
aoqi@0	82	{
aoqi@0	83	free_segments(_cur_seg);
aoqi@0	84	if (clear_cache) free_segments(_cache);
aoqi@0	85	reset(clear_cache);
aoqi@0	86	}
aoqi@0	87
aoqi@0	88	template <class E, MEMFLAGS F>
aoqi@0	89	size_t Stack<E, F>::default_segment_size()
aoqi@0	90	{
aoqi@0	91	// Number of elements that fit in 4K bytes minus the size of two pointers
aoqi@0	92	// (link field and malloc header).
aoqi@0	93	return (4096 - 2 * sizeof(E*)) / sizeof(E);
aoqi@0	94	}
aoqi@0	95
aoqi@0	96	template <class E, MEMFLAGS F>
aoqi@0	97	size_t Stack<E, F>::adjust_segment_size(size_t seg_size)
aoqi@0	98	{
aoqi@0	99	const size_t elem_sz = sizeof(E);
aoqi@0	100	const size_t ptr_sz = sizeof(E*);
aoqi@0	101	assert(elem_sz % ptr_sz == 0 || ptr_sz % elem_sz == 0, "bad element size");
aoqi@0	102	if (elem_sz < ptr_sz) {
aoqi@0	103	return align_size_up(seg_size * elem_sz, ptr_sz) / elem_sz;
aoqi@0	104	}
aoqi@0	105	return seg_size;
aoqi@0	106	}
aoqi@0	107
aoqi@0	108	template <class E, MEMFLAGS F>
aoqi@0	109	size_t Stack<E, F>::link_offset() const
aoqi@0	110	{
aoqi@0	111	return align_size_up(this->_seg_size * sizeof(E), sizeof(E*));
aoqi@0	112	}
aoqi@0	113
aoqi@0	114	template <class E, MEMFLAGS F>
aoqi@0	115	size_t Stack<E, F>::segment_bytes() const
aoqi@0	116	{
aoqi@0	117	return link_offset() + sizeof(E*);
aoqi@0	118	}
aoqi@0	119
aoqi@0	120	template <class E, MEMFLAGS F>
aoqi@0	121	E** Stack<E, F>::link_addr(E* seg) const
aoqi@0	122	{
aoqi@0	123	return (E**) ((char*)seg + link_offset());
aoqi@0	124	}
aoqi@0	125
aoqi@0	126	template <class E, MEMFLAGS F>
aoqi@0	127	E* Stack<E, F>::get_link(E* seg) const
aoqi@0	128	{
aoqi@0	129	return *link_addr(seg);
aoqi@0	130	}
aoqi@0	131
aoqi@0	132	template <class E, MEMFLAGS F>
aoqi@0	133	E* Stack<E, F>::set_link(E* new_seg, E* old_seg)
aoqi@0	134	{
aoqi@0	135	*link_addr(new_seg) = old_seg;
aoqi@0	136	return new_seg;
aoqi@0	137	}
aoqi@0	138
aoqi@0	139	template <class E, MEMFLAGS F>
aoqi@0	140	E* Stack<E, F>::alloc(size_t bytes)
aoqi@0	141	{
aoqi@0	142	return (E*) NEW_C_HEAP_ARRAY(char, bytes, F);
aoqi@0	143	}
aoqi@0	144
aoqi@0	145	template <class E, MEMFLAGS F>
aoqi@0	146	void Stack<E, F>::free(E* addr, size_t bytes)
aoqi@0	147	{
aoqi@0	148	FREE_C_HEAP_ARRAY(char, (char*) addr, F);
aoqi@0	149	}
aoqi@0	150
aoqi@0	151	template <class E, MEMFLAGS F>
aoqi@0	152	void Stack<E, F>::push_segment()
aoqi@0	153	{
aoqi@0	154	assert(this->_cur_seg_size == this->_seg_size, "current segment is not full");
aoqi@0	155	E* next;
aoqi@0	156	if (this->_cache_size > 0) {
aoqi@0	157	// Use a cached segment.
aoqi@0	158	next = _cache;
aoqi@0	159	_cache = get_link(_cache);
aoqi@0	160	--this->_cache_size;
aoqi@0	161	} else {
aoqi@0	162	next = alloc(segment_bytes());
aoqi@0	163	DEBUG_ONLY(zap_segment(next, true);)
aoqi@0	164	}
aoqi@0	165	const bool at_empty_transition = is_empty();
aoqi@0	166	this->_cur_seg = set_link(next, _cur_seg);
aoqi@0	167	this->_cur_seg_size = 0;
aoqi@0	168	this->_full_seg_size += at_empty_transition ? 0 : this->_seg_size;
aoqi@0	169	DEBUG_ONLY(verify(at_empty_transition);)
aoqi@0	170	}
aoqi@0	171
aoqi@0	172	template <class E, MEMFLAGS F>
aoqi@0	173	void Stack<E, F>::pop_segment()
aoqi@0	174	{
aoqi@0	175	assert(this->_cur_seg_size == 0, "current segment is not empty");
aoqi@0	176	E* const prev = get_link(_cur_seg);
aoqi@0	177	if (this->_cache_size < this->_max_cache_size) {
aoqi@0	178	// Add the current segment to the cache.
aoqi@0	179	DEBUG_ONLY(zap_segment(_cur_seg, false);)
aoqi@0	180	_cache = set_link(_cur_seg, _cache);
aoqi@0	181	++this->_cache_size;
aoqi@0	182	} else {
aoqi@0	183	DEBUG_ONLY(zap_segment(_cur_seg, true);)
aoqi@0	184	free(_cur_seg, segment_bytes());
aoqi@0	185	}
aoqi@0	186	const bool at_empty_transition = prev == NULL;
aoqi@0	187	this->_cur_seg = prev;
aoqi@0	188	this->_cur_seg_size = this->_seg_size;
aoqi@0	189	this->_full_seg_size -= at_empty_transition ? 0 : this->_seg_size;
aoqi@0	190	DEBUG_ONLY(verify(at_empty_transition);)
aoqi@0	191	}
aoqi@0	192
aoqi@0	193	template <class E, MEMFLAGS F>
aoqi@0	194	void Stack<E, F>::free_segments(E* seg)
aoqi@0	195	{
aoqi@0	196	const size_t bytes = segment_bytes();
aoqi@0	197	while (seg != NULL) {
aoqi@0	198	E* const prev = get_link(seg);
aoqi@0	199	free(seg, bytes);
aoqi@0	200	seg = prev;
aoqi@0	201	}
aoqi@0	202	}
aoqi@0	203
aoqi@0	204	template <class E, MEMFLAGS F>
aoqi@0	205	void Stack<E, F>::reset(bool reset_cache)
aoqi@0	206	{
aoqi@0	207	this->_cur_seg_size = this->_seg_size; // So push() will alloc a new segment.
aoqi@0	208	this->_full_seg_size = 0;
aoqi@0	209	_cur_seg = NULL;
aoqi@0	210	if (reset_cache) {
aoqi@0	211	this->_cache_size = 0;
aoqi@0	212	_cache = NULL;
aoqi@0	213	}
aoqi@0	214	}
aoqi@0	215
aoqi@0	216	#ifdef ASSERT
aoqi@0	217	template <class E, MEMFLAGS F>
aoqi@0	218	void Stack<E, F>::verify(bool at_empty_transition) const
aoqi@0	219	{
aoqi@0	220	assert(size() <= this->max_size(), "stack exceeded bounds");
aoqi@0	221	assert(this->cache_size() <= this->max_cache_size(), "cache exceeded bounds");
aoqi@0	222	assert(this->_cur_seg_size <= this->segment_size(), "segment index exceeded bounds");
aoqi@0	223
aoqi@0	224	assert(this->_full_seg_size % this->_seg_size == 0, "not a multiple");
aoqi@0	225	assert(at_empty_transition || is_empty() == (size() == 0), "mismatch");
aoqi@0	226	assert((_cache == NULL) == (this->cache_size() == 0), "mismatch");
aoqi@0	227
aoqi@0	228	if (is_empty()) {
aoqi@0	229	assert(this->_cur_seg_size == this->segment_size(), "sanity");
aoqi@0	230	}
aoqi@0	231	}
aoqi@0	232
aoqi@0	233	template <class E, MEMFLAGS F>
aoqi@0	234	void Stack<E, F>::zap_segment(E* seg, bool zap_link_field) const
aoqi@0	235	{
aoqi@0	236	if (!ZapStackSegments) return;
aoqi@0	237	const size_t zap_bytes = segment_bytes() - (zap_link_field ? 0 : sizeof(E*));
aoqi@0	238	uint32_t* cur = (uint32_t*)seg;
aoqi@0	239	const uint32_t* end = cur + zap_bytes / sizeof(uint32_t);
aoqi@0	240	while (cur < end) {
aoqi@0	241	*cur++ = 0xfadfaded;
aoqi@0	242	}
aoqi@0	243	}
aoqi@0	244	#endif
aoqi@0	245
aoqi@0	246	template <class E, MEMFLAGS F>
aoqi@0	247	E* ResourceStack<E, F>::alloc(size_t bytes)
aoqi@0	248	{
aoqi@0	249	return (E*) resource_allocate_bytes(bytes);
aoqi@0	250	}
aoqi@0	251
aoqi@0	252	template <class E, MEMFLAGS F>
aoqi@0	253	void ResourceStack<E, F>::free(E* addr, size_t bytes)
aoqi@0	254	{
aoqi@0	255	resource_free_bytes((char*) addr, bytes);
aoqi@0	256	}
aoqi@0	257
aoqi@0	258	template <class E, MEMFLAGS F>
aoqi@0	259	void StackIterator<E, F>::sync()
aoqi@0	260	{
aoqi@0	261	_full_seg_size = _stack._full_seg_size;
aoqi@0	262	_cur_seg_size = _stack._cur_seg_size;
aoqi@0	263	_cur_seg = _stack._cur_seg;
aoqi@0	264	}
aoqi@0	265
aoqi@0	266	template <class E, MEMFLAGS F>
aoqi@0	267	E* StackIterator<E, F>::next_addr()
aoqi@0	268	{
aoqi@0	269	assert(!is_empty(), "no items left");
aoqi@0	270	if (_cur_seg_size == 1) {
aoqi@0	271	E* addr = _cur_seg;
aoqi@0	272	_cur_seg = _stack.get_link(_cur_seg);
aoqi@0	273	_cur_seg_size = _stack.segment_size();
aoqi@0	274	_full_seg_size -= _stack.segment_size();
aoqi@0	275	return addr;
aoqi@0	276	}
aoqi@0	277	return _cur_seg + --_cur_seg_size;
aoqi@0	278	}
aoqi@0	279
aoqi@0	280	#endif // SHARE_VM_UTILITIES_STACK_INLINE_HPP