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src/share/vm/runtime/virtualspace.cpp@24cee90e9453 (annotated)

src/share/vm/runtime/virtualspace.cpp

Wed, 17 Aug 2011 10:32:53 -0700

author

jcoomes

date

Wed, 17 Aug 2011 10:32:53 -0700

changeset 3057

24cee90e9453

parent 3022

6aa4feb8a366

child 3156

f08d439fab8c

permissions

-rw-r--r--

6791672: enable 1G and larger pages on solaris
Reviewed-by: ysr, iveresov, johnc

duke@435	1	/*
johnc@3022	2	* Copyright (c) 1997, 2011, Oracle and/or its affiliates. All rights reserved.
duke@435	3	* DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
duke@435	4	*
duke@435	5	* This code is free software; you can redistribute it and/or modify it
duke@435	6	* under the terms of the GNU General Public License version 2 only, as
duke@435	7	* published by the Free Software Foundation.
duke@435	8	*
duke@435	9	* This code is distributed in the hope that it will be useful, but WITHOUT
duke@435	10	* ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
duke@435	11	* FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
duke@435	12	* version 2 for more details (a copy is included in the LICENSE file that
duke@435	13	* accompanied this code).
duke@435	14	*
duke@435	15	* You should have received a copy of the GNU General Public License version
duke@435	16	* 2 along with this work; if not, write to the Free Software Foundation,
duke@435	17	* Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA.
duke@435	18	*
trims@1907	19	* Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA
trims@1907	20	* or visit www.oracle.com if you need additional information or have any
trims@1907	21	* questions.
duke@435	22	*
duke@435	23	*/
duke@435	24
stefank@2314	25	#include "precompiled.hpp"
stefank@2314	26	#include "oops/markOop.hpp"
stefank@2314	27	#include "oops/oop.inline.hpp"
stefank@2314	28	#include "runtime/virtualspace.hpp"
stefank@2314	29	#ifdef TARGET_OS_FAMILY_linux
stefank@2314	30	# include "os_linux.inline.hpp"
stefank@2314	31	#endif
stefank@2314	32	#ifdef TARGET_OS_FAMILY_solaris
stefank@2314	33	# include "os_solaris.inline.hpp"
stefank@2314	34	#endif
stefank@2314	35	#ifdef TARGET_OS_FAMILY_windows
stefank@2314	36	# include "os_windows.inline.hpp"
stefank@2314	37	#endif
duke@435	38
duke@435	39
duke@435	40	// ReservedSpace
duke@435	41	ReservedSpace::ReservedSpace(size_t size) {
coleenp@1091	42	initialize(size, 0, false, NULL, 0, false);
duke@435	43	}
duke@435	44
duke@435	45	ReservedSpace::ReservedSpace(size_t size, size_t alignment,
coleenp@672	46	bool large,
coleenp@672	47	char* requested_address,
coleenp@672	48	const size_t noaccess_prefix) {
coleenp@672	49	initialize(size+noaccess_prefix, alignment, large, requested_address,
coleenp@1091	50	noaccess_prefix, false);
coleenp@1091	51	}
coleenp@1091	52
coleenp@1091	53	ReservedSpace::ReservedSpace(size_t size, size_t alignment,
coleenp@1091	54	bool large,
coleenp@1091	55	bool executable) {
coleenp@1091	56	initialize(size, alignment, large, NULL, 0, executable);
duke@435	57	}
duke@435	58
duke@435	59	char *
duke@435	60	ReservedSpace::align_reserved_region(char* addr, const size_t len,
duke@435	61	const size_t prefix_size,
duke@435	62	const size_t prefix_align,
duke@435	63	const size_t suffix_size,
duke@435	64	const size_t suffix_align)
duke@435	65	{
duke@435	66	assert(addr != NULL, "sanity");
duke@435	67	const size_t required_size = prefix_size + suffix_size;
duke@435	68	assert(len >= required_size, "len too small");
duke@435	69
duke@435	70	const size_t s = size_t(addr);
johnc@3022	71	const size_t beg_ofs = (s + prefix_size) & (suffix_align - 1);
duke@435	72	const size_t beg_delta = beg_ofs == 0 ? 0 : suffix_align - beg_ofs;
duke@435	73
duke@435	74	if (len < beg_delta + required_size) {
duke@435	75	return NULL; // Cannot do proper alignment.
duke@435	76	}
duke@435	77	const size_t end_delta = len - (beg_delta + required_size);
duke@435	78
duke@435	79	if (beg_delta != 0) {
duke@435	80	os::release_memory(addr, beg_delta);
duke@435	81	}
duke@435	82
duke@435	83	if (end_delta != 0) {
duke@435	84	char* release_addr = (char*) (s + beg_delta + required_size);
duke@435	85	os::release_memory(release_addr, end_delta);
duke@435	86	}
duke@435	87
duke@435	88	return (char*) (s + beg_delta);
duke@435	89	}
duke@435	90
duke@435	91	char* ReservedSpace::reserve_and_align(const size_t reserve_size,
duke@435	92	const size_t prefix_size,
duke@435	93	const size_t prefix_align,
duke@435	94	const size_t suffix_size,
duke@435	95	const size_t suffix_align)
duke@435	96	{
duke@435	97	assert(reserve_size > prefix_size + suffix_size, "should not be here");
duke@435	98
duke@435	99	char* raw_addr = os::reserve_memory(reserve_size, NULL, prefix_align);
duke@435	100	if (raw_addr == NULL) return NULL;
duke@435	101
duke@435	102	char* result = align_reserved_region(raw_addr, reserve_size, prefix_size,
duke@435	103	prefix_align, suffix_size,
duke@435	104	suffix_align);
duke@435	105	if (result == NULL && !os::release_memory(raw_addr, reserve_size)) {
duke@435	106	fatal("os::release_memory failed");
duke@435	107	}
duke@435	108
duke@435	109	#ifdef ASSERT
duke@435	110	if (result != NULL) {
duke@435	111	const size_t raw = size_t(raw_addr);
duke@435	112	const size_t res = size_t(result);
duke@435	113	assert(res >= raw, "alignment decreased start addr");
duke@435	114	assert(res + prefix_size + suffix_size <= raw + reserve_size,
duke@435	115	"alignment increased end addr");
johnc@3022	116	assert((res & (prefix_align - 1)) == 0, "bad alignment of prefix");
johnc@3022	117	assert(((res + prefix_size) & (suffix_align - 1)) == 0,
duke@435	118	"bad alignment of suffix");
duke@435	119	}
duke@435	120	#endif
duke@435	121
duke@435	122	return result;
duke@435	123	}
duke@435	124
kvn@1973	125	// Helper method.
kvn@1973	126	static bool failed_to_reserve_as_requested(char* base, char* requested_address,
kvn@1973	127	const size_t size, bool special)
kvn@1973	128	{
kvn@1973	129	if (base == requested_address || requested_address == NULL)
kvn@1973	130	return false; // did not fail
kvn@1973	131
kvn@1973	132	if (base != NULL) {
kvn@1973	133	// Different reserve address may be acceptable in other cases
kvn@1973	134	// but for compressed oops heap should be at requested address.
kvn@1973	135	assert(UseCompressedOops, "currently requested address used only for compressed oops");
kvn@1973	136	if (PrintCompressedOopsMode) {
kvn@1973	137	tty->cr();
johnc@3022	138	tty->print_cr("Reserved memory not at requested address: " PTR_FORMAT " vs " PTR_FORMAT, base, requested_address);
kvn@1973	139	}
kvn@1973	140	// OS ignored requested address. Try different address.
kvn@1973	141	if (special) {
kvn@1973	142	if (!os::release_memory_special(base, size)) {
kvn@1973	143	fatal("os::release_memory_special failed");
kvn@1973	144	}
kvn@1973	145	} else {
kvn@1973	146	if (!os::release_memory(base, size)) {
kvn@1973	147	fatal("os::release_memory failed");
kvn@1973	148	}
kvn@1973	149	}
kvn@1973	150	}
kvn@1973	151	return true;
kvn@1973	152	}
kvn@1973	153
duke@435	154	ReservedSpace::ReservedSpace(const size_t prefix_size,
duke@435	155	const size_t prefix_align,
duke@435	156	const size_t suffix_size,
coleenp@672	157	const size_t suffix_align,
kvn@1077	158	char* requested_address,
coleenp@672	159	const size_t noaccess_prefix)
duke@435	160	{
duke@435	161	assert(prefix_size != 0, "sanity");
duke@435	162	assert(prefix_align != 0, "sanity");
duke@435	163	assert(suffix_size != 0, "sanity");
duke@435	164	assert(suffix_align != 0, "sanity");
johnc@3022	165	assert((prefix_size & (prefix_align - 1)) == 0,
duke@435	166	"prefix_size not divisible by prefix_align");
johnc@3022	167	assert((suffix_size & (suffix_align - 1)) == 0,
duke@435	168	"suffix_size not divisible by suffix_align");
johnc@3022	169	assert((suffix_align & (prefix_align - 1)) == 0,
duke@435	170	"suffix_align not divisible by prefix_align");
duke@435	171
kvn@1973	172	// Assert that if noaccess_prefix is used, it is the same as prefix_align.
kvn@1973	173	assert(noaccess_prefix == 0 ||
kvn@1973	174	noaccess_prefix == prefix_align, "noaccess prefix wrong");
kvn@1973	175
coleenp@672	176	// Add in noaccess_prefix to prefix_size;
coleenp@672	177	const size_t adjusted_prefix_size = prefix_size + noaccess_prefix;
coleenp@672	178	const size_t size = adjusted_prefix_size + suffix_size;
coleenp@672	179
duke@435	180	// On systems where the entire region has to be reserved and committed up
duke@435	181	// front, the compound alignment normally done by this method is unnecessary.
duke@435	182	const bool try_reserve_special = UseLargePages &&
duke@435	183	prefix_align == os::large_page_size();
duke@435	184	if (!os::can_commit_large_page_memory() && try_reserve_special) {
coleenp@1091	185	initialize(size, prefix_align, true, requested_address, noaccess_prefix,
coleenp@1091	186	false);
duke@435	187	return;
duke@435	188	}
duke@435	189
duke@435	190	_base = NULL;
duke@435	191	_size = 0;
duke@435	192	_alignment = 0;
duke@435	193	_special = false;
coleenp@672	194	_noaccess_prefix = 0;
coleenp@1091	195	_executable = false;
coleenp@672	196
duke@435	197	// Optimistically try to reserve the exact size needed.
kvn@1077	198	char* addr;
kvn@1077	199	if (requested_address != 0) {
kvn@1973	200	requested_address -= noaccess_prefix; // adjust address
kvn@1973	201	assert(requested_address != NULL, "huge noaccess prefix?");
kvn@1973	202	addr = os::attempt_reserve_memory_at(size, requested_address);
kvn@1973	203	if (failed_to_reserve_as_requested(addr, requested_address, size, false)) {
kvn@1973	204	// OS ignored requested address. Try different address.
kvn@1973	205	addr = NULL;
kvn@1973	206	}
kvn@1077	207	} else {
kvn@1077	208	addr = os::reserve_memory(size, NULL, prefix_align);
kvn@1077	209	}
duke@435	210	if (addr == NULL) return;
duke@435	211
duke@435	212	// Check whether the result has the needed alignment (unlikely unless
johnc@3022	213	// prefix_align < suffix_align).
johnc@3022	214	const size_t ofs = (size_t(addr) + adjusted_prefix_size) & (suffix_align - 1);
duke@435	215	if (ofs != 0) {
duke@435	216	// Wrong alignment. Release, allocate more space and do manual alignment.
duke@435	217	//
duke@435	218	// On most operating systems, another allocation with a somewhat larger size
duke@435	219	// will return an address "close to" that of the previous allocation. The
duke@435	220	// result is often the same address (if the kernel hands out virtual
duke@435	221	// addresses from low to high), or an address that is offset by the increase
duke@435	222	// in size. Exploit that to minimize the amount of extra space requested.
duke@435	223	if (!os::release_memory(addr, size)) {
duke@435	224	fatal("os::release_memory failed");
duke@435	225	}
duke@435	226
duke@435	227	const size_t extra = MAX2(ofs, suffix_align - ofs);
coleenp@672	228	addr = reserve_and_align(size + extra, adjusted_prefix_size, prefix_align,
duke@435	229	suffix_size, suffix_align);
duke@435	230	if (addr == NULL) {
duke@435	231	// Try an even larger region. If this fails, address space is exhausted.
coleenp@672	232	addr = reserve_and_align(size + suffix_align, adjusted_prefix_size,
duke@435	233	prefix_align, suffix_size, suffix_align);
duke@435	234	}
johnc@3022	235
johnc@3022	236	if (requested_address != 0 &&
johnc@3022	237	failed_to_reserve_as_requested(addr, requested_address, size, false)) {
johnc@3022	238	// As a result of the alignment constraints, the allocated addr differs
johnc@3022	239	// from the requested address. Return back to the caller who can
johnc@3022	240	// take remedial action (like try again without a requested address).
johnc@3022	241	assert(_base == NULL, "should be");
johnc@3022	242	return;
johnc@3022	243	}
duke@435	244	}
duke@435	245
duke@435	246	_base = addr;
duke@435	247	_size = size;
duke@435	248	_alignment = prefix_align;
coleenp@672	249	_noaccess_prefix = noaccess_prefix;
duke@435	250	}
duke@435	251
duke@435	252	void ReservedSpace::initialize(size_t size, size_t alignment, bool large,
coleenp@672	253	char* requested_address,
coleenp@1091	254	const size_t noaccess_prefix,
coleenp@1091	255	bool executable) {
duke@435	256	const size_t granularity = os::vm_allocation_granularity();
johnc@3022	257	assert((size & (granularity - 1)) == 0,
duke@435	258	"size not aligned to os::vm_allocation_granularity()");
johnc@3022	259	assert((alignment & (granularity - 1)) == 0,
duke@435	260	"alignment not aligned to os::vm_allocation_granularity()");
duke@435	261	assert(alignment == 0 || is_power_of_2((intptr_t)alignment),
duke@435	262	"not a power of 2");
duke@435	263
johnc@3022	264	alignment = MAX2(alignment, (size_t)os::vm_page_size());
johnc@3022	265
johnc@3022	266	// Assert that if noaccess_prefix is used, it is the same as alignment.
johnc@3022	267	assert(noaccess_prefix == 0 ||
johnc@3022	268	noaccess_prefix == alignment, "noaccess prefix wrong");
johnc@3022	269
duke@435	270	_base = NULL;
duke@435	271	_size = 0;
duke@435	272	_special = false;
coleenp@1091	273	_executable = executable;
duke@435	274	_alignment = 0;
coleenp@672	275	_noaccess_prefix = 0;
duke@435	276	if (size == 0) {
duke@435	277	return;
duke@435	278	}
duke@435	279
duke@435	280	// If OS doesn't support demand paging for large page memory, we need
duke@435	281	// to use reserve_memory_special() to reserve and pin the entire region.
duke@435	282	bool special = large && !os::can_commit_large_page_memory();
duke@435	283	char* base = NULL;
duke@435	284
kvn@1973	285	if (requested_address != 0) {
kvn@1973	286	requested_address -= noaccess_prefix; // adjust requested address
kvn@1973	287	assert(requested_address != NULL, "huge noaccess prefix?");
kvn@1973	288	}
kvn@1973	289
duke@435	290	if (special) {
duke@435	291
coleenp@1091	292	base = os::reserve_memory_special(size, requested_address, executable);
duke@435	293
duke@435	294	if (base != NULL) {
kvn@1973	295	if (failed_to_reserve_as_requested(base, requested_address, size, true)) {
kvn@1973	296	// OS ignored requested address. Try different address.
kvn@1973	297	return;
kvn@1973	298	}
duke@435	299	// Check alignment constraints
johnc@3022	300	assert((uintptr_t) base % alignment == 0,
johnc@3022	301	"Large pages returned a non-aligned address");
duke@435	302	_special = true;
duke@435	303	} else {
duke@435	304	// failed; try to reserve regular memory below
kvn@1973	305	if (UseLargePages && (!FLAG_IS_DEFAULT(UseLargePages) ||
kvn@1973	306	!FLAG_IS_DEFAULT(LargePageSizeInBytes))) {
kvn@1973	307	if (PrintCompressedOopsMode) {
kvn@1973	308	tty->cr();
kvn@1973	309	tty->print_cr("Reserve regular memory without large pages.");
kvn@1973	310	}
kvn@1973	311	}
duke@435	312	}
duke@435	313	}
duke@435	314
duke@435	315	if (base == NULL) {
duke@435	316	// Optimistically assume that the OSes returns an aligned base pointer.
duke@435	317	// When reserving a large address range, most OSes seem to align to at
duke@435	318	// least 64K.
duke@435	319
duke@435	320	// If the memory was requested at a particular address, use
duke@435	321	// os::attempt_reserve_memory_at() to avoid over mapping something
duke@435	322	// important. If available space is not detected, return NULL.
duke@435	323
duke@435	324	if (requested_address != 0) {
kvn@1973	325	base = os::attempt_reserve_memory_at(size, requested_address);
kvn@1973	326	if (failed_to_reserve_as_requested(base, requested_address, size, false)) {
kvn@1973	327	// OS ignored requested address. Try different address.
kvn@1973	328	base = NULL;
kvn@1973	329	}
duke@435	330	} else {
duke@435	331	base = os::reserve_memory(size, NULL, alignment);
duke@435	332	}
duke@435	333
duke@435	334	if (base == NULL) return;
duke@435	335
duke@435	336	// Check alignment constraints
johnc@3022	337	if ((((size_t)base + noaccess_prefix) & (alignment - 1)) != 0) {
duke@435	338	// Base not aligned, retry
duke@435	339	if (!os::release_memory(base, size)) fatal("os::release_memory failed");
duke@435	340	// Reserve size large enough to do manual alignment and
duke@435	341	// increase size to a multiple of the desired alignment
duke@435	342	size = align_size_up(size, alignment);
duke@435	343	size_t extra_size = size + alignment;
ysr@777	344	do {
ysr@777	345	char* extra_base = os::reserve_memory(extra_size, NULL, alignment);
ysr@777	346	if (extra_base == NULL) return;
ysr@777	347	// Do manual alignement
ysr@777	348	base = (char*) align_size_up((uintptr_t) extra_base, alignment);
ysr@777	349	assert(base >= extra_base, "just checking");
ysr@777	350	// Re-reserve the region at the aligned base address.
ysr@777	351	os::release_memory(extra_base, extra_size);
ysr@777	352	base = os::reserve_memory(size, base);
ysr@777	353	} while (base == NULL);
johnc@3022	354
johnc@3022	355	if (requested_address != 0 &&
johnc@3022	356	failed_to_reserve_as_requested(base, requested_address, size, false)) {
johnc@3022	357	// As a result of the alignment constraints, the allocated base differs
johnc@3022	358	// from the requested address. Return back to the caller who can
johnc@3022	359	// take remedial action (like try again without a requested address).
johnc@3022	360	assert(_base == NULL, "should be");
johnc@3022	361	return;
johnc@3022	362	}
duke@435	363	}
duke@435	364	}
duke@435	365	// Done
duke@435	366	_base = base;
duke@435	367	_size = size;
johnc@3022	368	_alignment = alignment;
coleenp@672	369	_noaccess_prefix = noaccess_prefix;
coleenp@672	370
coleenp@672	371	// Assert that if noaccess_prefix is used, it is the same as alignment.
coleenp@672	372	assert(noaccess_prefix == 0 ||
coleenp@672	373	noaccess_prefix == _alignment, "noaccess prefix wrong");
duke@435	374
duke@435	375	assert(markOopDesc::encode_pointer_as_mark(_base)->decode_pointer() == _base,
duke@435	376	"area must be distinguisable from marks for mark-sweep");
duke@435	377	assert(markOopDesc::encode_pointer_as_mark(&_base[size])->decode_pointer() == &_base[size],
duke@435	378	"area must be distinguisable from marks for mark-sweep");
duke@435	379	}
duke@435	380
duke@435	381
duke@435	382	ReservedSpace::ReservedSpace(char* base, size_t size, size_t alignment,
coleenp@1091	383	bool special, bool executable) {
duke@435	384	assert((size % os::vm_allocation_granularity()) == 0,
duke@435	385	"size not allocation aligned");
duke@435	386	_base = base;
duke@435	387	_size = size;
duke@435	388	_alignment = alignment;
coleenp@672	389	_noaccess_prefix = 0;
duke@435	390	_special = special;
coleenp@1091	391	_executable = executable;
duke@435	392	}
duke@435	393
duke@435	394
duke@435	395	ReservedSpace ReservedSpace::first_part(size_t partition_size, size_t alignment,
duke@435	396	bool split, bool realloc) {
duke@435	397	assert(partition_size <= size(), "partition failed");
duke@435	398	if (split) {
coleenp@1091	399	os::split_reserved_memory(base(), size(), partition_size, realloc);
duke@435	400	}
coleenp@1091	401	ReservedSpace result(base(), partition_size, alignment, special(),
coleenp@1091	402	executable());
duke@435	403	return result;
duke@435	404	}
duke@435	405
duke@435	406
duke@435	407	ReservedSpace
duke@435	408	ReservedSpace::last_part(size_t partition_size, size_t alignment) {
duke@435	409	assert(partition_size <= size(), "partition failed");
duke@435	410	ReservedSpace result(base() + partition_size, size() - partition_size,
coleenp@1091	411	alignment, special(), executable());
duke@435	412	return result;
duke@435	413	}
duke@435	414
duke@435	415
duke@435	416	size_t ReservedSpace::page_align_size_up(size_t size) {
duke@435	417	return align_size_up(size, os::vm_page_size());
duke@435	418	}
duke@435	419
duke@435	420
duke@435	421	size_t ReservedSpace::page_align_size_down(size_t size) {
duke@435	422	return align_size_down(size, os::vm_page_size());
duke@435	423	}
duke@435	424
duke@435	425
duke@435	426	size_t ReservedSpace::allocation_align_size_up(size_t size) {
duke@435	427	return align_size_up(size, os::vm_allocation_granularity());
duke@435	428	}
duke@435	429
duke@435	430
duke@435	431	size_t ReservedSpace::allocation_align_size_down(size_t size) {
duke@435	432	return align_size_down(size, os::vm_allocation_granularity());
duke@435	433	}
duke@435	434
duke@435	435
duke@435	436	void ReservedSpace::release() {
duke@435	437	if (is_reserved()) {
coleenp@672	438	char *real_base = _base - _noaccess_prefix;
coleenp@672	439	const size_t real_size = _size + _noaccess_prefix;
duke@435	440	if (special()) {
coleenp@672	441	os::release_memory_special(real_base, real_size);
duke@435	442	} else{
coleenp@672	443	os::release_memory(real_base, real_size);
duke@435	444	}
duke@435	445	_base = NULL;
duke@435	446	_size = 0;
coleenp@672	447	_noaccess_prefix = 0;
duke@435	448	_special = false;
coleenp@1091	449	_executable = false;
duke@435	450	}
duke@435	451	}
duke@435	452
coleenp@672	453	void ReservedSpace::protect_noaccess_prefix(const size_t size) {
kvn@1973	454	assert( (_noaccess_prefix != 0) == (UseCompressedOops && _base != NULL &&
kvn@1973	455	(size_t(_base + _size) > OopEncodingHeapMax) &&
kvn@1973	456	Universe::narrow_oop_use_implicit_null_checks()),
kvn@1973	457	"noaccess_prefix should be used only with non zero based compressed oops");
kvn@1973	458
kvn@1973	459	// If there is no noaccess prefix, return.
coleenp@672	460	if (_noaccess_prefix == 0) return;
coleenp@672	461
coleenp@672	462	assert(_noaccess_prefix >= (size_t)os::vm_page_size(),
coleenp@672	463	"must be at least page size big");
coleenp@672	464
coleenp@672	465	// Protect memory at the base of the allocated region.
coleenp@672	466	// If special, the page was committed (only matters on windows)
coleenp@672	467	if (!os::protect_memory(_base, _noaccess_prefix, os::MEM_PROT_NONE,
coleenp@672	468	_special)) {
coleenp@672	469	fatal("cannot protect protection page");
coleenp@672	470	}
kvn@1973	471	if (PrintCompressedOopsMode) {
kvn@1973	472	tty->cr();
kvn@1973	473	tty->print_cr("Protected page at the reserved heap base: " PTR_FORMAT " / " INTX_FORMAT " bytes", _base, _noaccess_prefix);
kvn@1973	474	}
coleenp@672	475
coleenp@672	476	_base += _noaccess_prefix;
coleenp@672	477	_size -= _noaccess_prefix;
coleenp@672	478	assert((size == _size) && ((uintptr_t)_base % _alignment == 0),
coleenp@672	479	"must be exactly of required size and alignment");
coleenp@672	480	}
coleenp@672	481
coleenp@672	482	ReservedHeapSpace::ReservedHeapSpace(size_t size, size_t alignment,
coleenp@672	483	bool large, char* requested_address) :
coleenp@672	484	ReservedSpace(size, alignment, large,
coleenp@672	485	requested_address,
kvn@1077	486	(UseCompressedOops && (Universe::narrow_oop_base() != NULL) &&
kvn@1077	487	Universe::narrow_oop_use_implicit_null_checks()) ?
coleenp@760	488	lcm(os::vm_page_size(), alignment) : 0) {
coleenp@672	489	// Only reserved space for the java heap should have a noaccess_prefix
coleenp@672	490	// if using compressed oops.
coleenp@672	491	protect_noaccess_prefix(size);
coleenp@672	492	}
coleenp@672	493
coleenp@672	494	ReservedHeapSpace::ReservedHeapSpace(const size_t prefix_size,
coleenp@672	495	const size_t prefix_align,
coleenp@672	496	const size_t suffix_size,
kvn@1077	497	const size_t suffix_align,
kvn@1077	498	char* requested_address) :
coleenp@672	499	ReservedSpace(prefix_size, prefix_align, suffix_size, suffix_align,
kvn@1077	500	requested_address,
kvn@1077	501	(UseCompressedOops && (Universe::narrow_oop_base() != NULL) &&
kvn@1077	502	Universe::narrow_oop_use_implicit_null_checks()) ?
coleenp@760	503	lcm(os::vm_page_size(), prefix_align) : 0) {
coleenp@672	504	protect_noaccess_prefix(prefix_size+suffix_size);
coleenp@672	505	}
duke@435	506
coleenp@1091	507	// Reserve space for code segment. Same as Java heap only we mark this as
coleenp@1091	508	// executable.
coleenp@1091	509	ReservedCodeSpace::ReservedCodeSpace(size_t r_size,
coleenp@1091	510	size_t rs_align,
coleenp@1091	511	bool large) :
coleenp@1091	512	ReservedSpace(r_size, rs_align, large, /*executable*/ true) {
coleenp@1091	513	}
coleenp@1091	514
duke@435	515	// VirtualSpace
duke@435	516
duke@435	517	VirtualSpace::VirtualSpace() {
duke@435	518	_low_boundary = NULL;
duke@435	519	_high_boundary = NULL;
duke@435	520	_low = NULL;
duke@435	521	_high = NULL;
duke@435	522	_lower_high = NULL;
duke@435	523	_middle_high = NULL;
duke@435	524	_upper_high = NULL;
duke@435	525	_lower_high_boundary = NULL;
duke@435	526	_middle_high_boundary = NULL;
duke@435	527	_upper_high_boundary = NULL;
duke@435	528	_lower_alignment = 0;
duke@435	529	_middle_alignment = 0;
duke@435	530	_upper_alignment = 0;
coleenp@672	531	_special = false;
coleenp@1091	532	_executable = false;
duke@435	533	}
duke@435	534
duke@435	535
duke@435	536	bool VirtualSpace::initialize(ReservedSpace rs, size_t committed_size) {
duke@435	537	if(!rs.is_reserved()) return false; // allocation failed.
duke@435	538	assert(_low_boundary == NULL, "VirtualSpace already initialized");
duke@435	539	_low_boundary = rs.base();
duke@435	540	_high_boundary = low_boundary() + rs.size();
duke@435	541
duke@435	542	_low = low_boundary();
duke@435	543	_high = low();
duke@435	544
duke@435	545	_special = rs.special();
coleenp@1091	546	_executable = rs.executable();
duke@435	547
duke@435	548	// When a VirtualSpace begins life at a large size, make all future expansion
duke@435	549	// and shrinking occur aligned to a granularity of large pages. This avoids
duke@435	550	// fragmentation of physical addresses that inhibits the use of large pages
duke@435	551	// by the OS virtual memory system. Empirically, we see that with a 4MB
duke@435	552	// page size, the only spaces that get handled this way are codecache and
duke@435	553	// the heap itself, both of which provide a substantial performance
duke@435	554	// boost in many benchmarks when covered by large pages.
duke@435	555	//
duke@435	556	// No attempt is made to force large page alignment at the very top and
duke@435	557	// bottom of the space if they are not aligned so already.
duke@435	558	_lower_alignment = os::vm_page_size();
duke@435	559	_middle_alignment = os::page_size_for_region(rs.size(), rs.size(), 1);
duke@435	560	_upper_alignment = os::vm_page_size();
duke@435	561
duke@435	562	// End of each region
duke@435	563	_lower_high_boundary = (char*) round_to((intptr_t) low_boundary(), middle_alignment());
duke@435	564	_middle_high_boundary = (char*) round_down((intptr_t) high_boundary(), middle_alignment());
duke@435	565	_upper_high_boundary = high_boundary();
duke@435	566
duke@435	567	// High address of each region
duke@435	568	_lower_high = low_boundary();
duke@435	569	_middle_high = lower_high_boundary();
duke@435	570	_upper_high = middle_high_boundary();
duke@435	571
duke@435	572	// commit to initial size
duke@435	573	if (committed_size > 0) {
duke@435	574	if (!expand_by(committed_size)) {
duke@435	575	return false;
duke@435	576	}
duke@435	577	}
duke@435	578	return true;
duke@435	579	}
duke@435	580
duke@435	581
duke@435	582	VirtualSpace::~VirtualSpace() {
duke@435	583	release();
duke@435	584	}
duke@435	585
duke@435	586
duke@435	587	void VirtualSpace::release() {
coleenp@672	588	// This does not release memory it never reserved.
coleenp@672	589	// Caller must release via rs.release();
duke@435	590	_low_boundary = NULL;
duke@435	591	_high_boundary = NULL;
duke@435	592	_low = NULL;
duke@435	593	_high = NULL;
duke@435	594	_lower_high = NULL;
duke@435	595	_middle_high = NULL;
duke@435	596	_upper_high = NULL;
duke@435	597	_lower_high_boundary = NULL;
duke@435	598	_middle_high_boundary = NULL;
duke@435	599	_upper_high_boundary = NULL;
duke@435	600	_lower_alignment = 0;
duke@435	601	_middle_alignment = 0;
duke@435	602	_upper_alignment = 0;
duke@435	603	_special = false;
coleenp@1091	604	_executable = false;
duke@435	605	}
duke@435	606
duke@435	607
duke@435	608	size_t VirtualSpace::committed_size() const {
duke@435	609	return pointer_delta(high(), low(), sizeof(char));
duke@435	610	}
duke@435	611
duke@435	612
duke@435	613	size_t VirtualSpace::reserved_size() const {
duke@435	614	return pointer_delta(high_boundary(), low_boundary(), sizeof(char));
duke@435	615	}
duke@435	616
duke@435	617
duke@435	618	size_t VirtualSpace::uncommitted_size() const {
duke@435	619	return reserved_size() - committed_size();
duke@435	620	}
duke@435	621
duke@435	622
duke@435	623	bool VirtualSpace::contains(const void* p) const {
duke@435	624	return low() <= (const char*) p && (const char*) p < high();
duke@435	625	}
duke@435	626
duke@435	627	/*
duke@435	628	First we need to determine if a particular virtual space is using large
duke@435	629	pages. This is done at the initialize function and only virtual spaces
duke@435	630	that are larger than LargePageSizeInBytes use large pages. Once we
duke@435	631	have determined this, all expand_by and shrink_by calls must grow and
duke@435	632	shrink by large page size chunks. If a particular request
duke@435	633	is within the current large page, the call to commit and uncommit memory
duke@435	634	can be ignored. In the case that the low and high boundaries of this
duke@435	635	space is not large page aligned, the pages leading to the first large
duke@435	636	page address and the pages after the last large page address must be
duke@435	637	allocated with default pages.
duke@435	638	*/
duke@435	639	bool VirtualSpace::expand_by(size_t bytes, bool pre_touch) {
duke@435	640	if (uncommitted_size() < bytes) return false;
duke@435	641
duke@435	642	if (special()) {
duke@435	643	// don't commit memory if the entire space is pinned in memory
duke@435	644	_high += bytes;
duke@435	645	return true;
duke@435	646	}
duke@435	647
duke@435	648	char* previous_high = high();
duke@435	649	char* unaligned_new_high = high() + bytes;
duke@435	650	assert(unaligned_new_high <= high_boundary(),
duke@435	651	"cannot expand by more than upper boundary");
duke@435	652
duke@435	653	// Calculate where the new high for each of the regions should be. If
duke@435	654	// the low_boundary() and high_boundary() are LargePageSizeInBytes aligned
duke@435	655	// then the unaligned lower and upper new highs would be the
duke@435	656	// lower_high() and upper_high() respectively.
duke@435	657	char* unaligned_lower_new_high =
duke@435	658	MIN2(unaligned_new_high, lower_high_boundary());
duke@435	659	char* unaligned_middle_new_high =
duke@435	660	MIN2(unaligned_new_high, middle_high_boundary());
duke@435	661	char* unaligned_upper_new_high =
duke@435	662	MIN2(unaligned_new_high, upper_high_boundary());
duke@435	663
duke@435	664	// Align the new highs based on the regions alignment. lower and upper
duke@435	665	// alignment will always be default page size. middle alignment will be
duke@435	666	// LargePageSizeInBytes if the actual size of the virtual space is in
duke@435	667	// fact larger than LargePageSizeInBytes.
duke@435	668	char* aligned_lower_new_high =
duke@435	669	(char*) round_to((intptr_t) unaligned_lower_new_high, lower_alignment());
duke@435	670	char* aligned_middle_new_high =
duke@435	671	(char*) round_to((intptr_t) unaligned_middle_new_high, middle_alignment());
duke@435	672	char* aligned_upper_new_high =
duke@435	673	(char*) round_to((intptr_t) unaligned_upper_new_high, upper_alignment());
duke@435	674
duke@435	675	// Determine which regions need to grow in this expand_by call.
duke@435	676	// If you are growing in the lower region, high() must be in that
duke@435	677	// region so calcuate the size based on high(). For the middle and
duke@435	678	// upper regions, determine the starting point of growth based on the
duke@435	679	// location of high(). By getting the MAX of the region's low address
duke@435	680	// (or the prevoius region's high address) and high(), we can tell if it
duke@435	681	// is an intra or inter region growth.
duke@435	682	size_t lower_needs = 0;
duke@435	683	if (aligned_lower_new_high > lower_high()) {
duke@435	684	lower_needs =
duke@435	685	pointer_delta(aligned_lower_new_high, lower_high(), sizeof(char));
duke@435	686	}
duke@435	687	size_t middle_needs = 0;
duke@435	688	if (aligned_middle_new_high > middle_high()) {
duke@435	689	middle_needs =
duke@435	690	pointer_delta(aligned_middle_new_high, middle_high(), sizeof(char));
duke@435	691	}
duke@435	692	size_t upper_needs = 0;
duke@435	693	if (aligned_upper_new_high > upper_high()) {
duke@435	694	upper_needs =
duke@435	695	pointer_delta(aligned_upper_new_high, upper_high(), sizeof(char));
duke@435	696	}
duke@435	697
duke@435	698	// Check contiguity.
duke@435	699	assert(low_boundary() <= lower_high() &&
duke@435	700	lower_high() <= lower_high_boundary(),
duke@435	701	"high address must be contained within the region");
duke@435	702	assert(lower_high_boundary() <= middle_high() &&
duke@435	703	middle_high() <= middle_high_boundary(),
duke@435	704	"high address must be contained within the region");
duke@435	705	assert(middle_high_boundary() <= upper_high() &&
duke@435	706	upper_high() <= upper_high_boundary(),
duke@435	707	"high address must be contained within the region");
duke@435	708
duke@435	709	// Commit regions
duke@435	710	if (lower_needs > 0) {
duke@435	711	assert(low_boundary() <= lower_high() &&
duke@435	712	lower_high() + lower_needs <= lower_high_boundary(),
duke@435	713	"must not expand beyond region");
coleenp@1091	714	if (!os::commit_memory(lower_high(), lower_needs, _executable)) {
duke@435	715	debug_only(warning("os::commit_memory failed"));
duke@435	716	return false;
duke@435	717	} else {
duke@435	718	_lower_high += lower_needs;
duke@435	719	}
duke@435	720	}
duke@435	721	if (middle_needs > 0) {
duke@435	722	assert(lower_high_boundary() <= middle_high() &&
duke@435	723	middle_high() + middle_needs <= middle_high_boundary(),
duke@435	724	"must not expand beyond region");
coleenp@1091	725	if (!os::commit_memory(middle_high(), middle_needs, middle_alignment(),
coleenp@1091	726	_executable)) {
duke@435	727	debug_only(warning("os::commit_memory failed"));
duke@435	728	return false;
duke@435	729	}
duke@435	730	_middle_high += middle_needs;
duke@435	731	}
duke@435	732	if (upper_needs > 0) {
duke@435	733	assert(middle_high_boundary() <= upper_high() &&
duke@435	734	upper_high() + upper_needs <= upper_high_boundary(),
duke@435	735	"must not expand beyond region");
coleenp@1091	736	if (!os::commit_memory(upper_high(), upper_needs, _executable)) {
duke@435	737	debug_only(warning("os::commit_memory failed"));
duke@435	738	return false;
duke@435	739	} else {
duke@435	740	_upper_high += upper_needs;
duke@435	741	}
duke@435	742	}
duke@435	743
duke@435	744	if (pre_touch || AlwaysPreTouch) {
duke@435	745	int vm_ps = os::vm_page_size();
duke@435	746	for (char* curr = previous_high;
duke@435	747	curr < unaligned_new_high;
duke@435	748	curr += vm_ps) {
duke@435	749	// Note the use of a write here; originally we tried just a read, but
duke@435	750	// since the value read was unused, the optimizer removed the read.
duke@435	751	// If we ever have a concurrent touchahead thread, we'll want to use
duke@435	752	// a read, to avoid the potential of overwriting data (if a mutator
duke@435	753	// thread beats the touchahead thread to a page). There are various
duke@435	754	// ways of making sure this read is not optimized away: for example,
duke@435	755	// generating the code for a read procedure at runtime.
duke@435	756	*curr = 0;
duke@435	757	}
duke@435	758	}
duke@435	759
duke@435	760	_high += bytes;
duke@435	761	return true;
duke@435	762	}
duke@435	763
duke@435	764	// A page is uncommitted if the contents of the entire page is deemed unusable.
duke@435	765	// Continue to decrement the high() pointer until it reaches a page boundary
duke@435	766	// in which case that particular page can now be uncommitted.
duke@435	767	void VirtualSpace::shrink_by(size_t size) {
duke@435	768	if (committed_size() < size)
duke@435	769	fatal("Cannot shrink virtual space to negative size");
duke@435	770
duke@435	771	if (special()) {
duke@435	772	// don't uncommit if the entire space is pinned in memory
duke@435	773	_high -= size;
duke@435	774	return;
duke@435	775	}
duke@435	776
duke@435	777	char* unaligned_new_high = high() - size;
duke@435	778	assert(unaligned_new_high >= low_boundary(), "cannot shrink past lower boundary");
duke@435	779
duke@435	780	// Calculate new unaligned address
duke@435	781	char* unaligned_upper_new_high =
duke@435	782	MAX2(unaligned_new_high, middle_high_boundary());
duke@435	783	char* unaligned_middle_new_high =
duke@435	784	MAX2(unaligned_new_high, lower_high_boundary());
duke@435	785	char* unaligned_lower_new_high =
duke@435	786	MAX2(unaligned_new_high, low_boundary());
duke@435	787
duke@435	788	// Align address to region's alignment
duke@435	789	char* aligned_upper_new_high =
duke@435	790	(char*) round_to((intptr_t) unaligned_upper_new_high, upper_alignment());
duke@435	791	char* aligned_middle_new_high =
duke@435	792	(char*) round_to((intptr_t) unaligned_middle_new_high, middle_alignment());
duke@435	793	char* aligned_lower_new_high =
duke@435	794	(char*) round_to((intptr_t) unaligned_lower_new_high, lower_alignment());
duke@435	795
duke@435	796	// Determine which regions need to shrink
duke@435	797	size_t upper_needs = 0;
duke@435	798	if (aligned_upper_new_high < upper_high()) {
duke@435	799	upper_needs =
duke@435	800	pointer_delta(upper_high(), aligned_upper_new_high, sizeof(char));
duke@435	801	}
duke@435	802	size_t middle_needs = 0;
duke@435	803	if (aligned_middle_new_high < middle_high()) {
duke@435	804	middle_needs =
duke@435	805	pointer_delta(middle_high(), aligned_middle_new_high, sizeof(char));
duke@435	806	}
duke@435	807	size_t lower_needs = 0;
duke@435	808	if (aligned_lower_new_high < lower_high()) {
duke@435	809	lower_needs =
duke@435	810	pointer_delta(lower_high(), aligned_lower_new_high, sizeof(char));
duke@435	811	}
duke@435	812
duke@435	813	// Check contiguity.
duke@435	814	assert(middle_high_boundary() <= upper_high() &&
duke@435	815	upper_high() <= upper_high_boundary(),
duke@435	816	"high address must be contained within the region");
duke@435	817	assert(lower_high_boundary() <= middle_high() &&
duke@435	818	middle_high() <= middle_high_boundary(),
duke@435	819	"high address must be contained within the region");
duke@435	820	assert(low_boundary() <= lower_high() &&
duke@435	821	lower_high() <= lower_high_boundary(),
duke@435	822	"high address must be contained within the region");
duke@435	823
duke@435	824	// Uncommit
duke@435	825	if (upper_needs > 0) {
duke@435	826	assert(middle_high_boundary() <= aligned_upper_new_high &&
duke@435	827	aligned_upper_new_high + upper_needs <= upper_high_boundary(),
duke@435	828	"must not shrink beyond region");
duke@435	829	if (!os::uncommit_memory(aligned_upper_new_high, upper_needs)) {
duke@435	830	debug_only(warning("os::uncommit_memory failed"));
duke@435	831	return;
duke@435	832	} else {
duke@435	833	_upper_high -= upper_needs;
duke@435	834	}
duke@435	835	}
duke@435	836	if (middle_needs > 0) {
duke@435	837	assert(lower_high_boundary() <= aligned_middle_new_high &&
duke@435	838	aligned_middle_new_high + middle_needs <= middle_high_boundary(),
duke@435	839	"must not shrink beyond region");
duke@435	840	if (!os::uncommit_memory(aligned_middle_new_high, middle_needs)) {
duke@435	841	debug_only(warning("os::uncommit_memory failed"));
duke@435	842	return;
duke@435	843	} else {
duke@435	844	_middle_high -= middle_needs;
duke@435	845	}
duke@435	846	}
duke@435	847	if (lower_needs > 0) {
duke@435	848	assert(low_boundary() <= aligned_lower_new_high &&
duke@435	849	aligned_lower_new_high + lower_needs <= lower_high_boundary(),
duke@435	850	"must not shrink beyond region");
duke@435	851	if (!os::uncommit_memory(aligned_lower_new_high, lower_needs)) {
duke@435	852	debug_only(warning("os::uncommit_memory failed"));
duke@435	853	return;
duke@435	854	} else {
duke@435	855	_lower_high -= lower_needs;
duke@435	856	}
duke@435	857	}
duke@435	858
duke@435	859	_high -= size;
duke@435	860	}
duke@435	861
duke@435	862	#ifndef PRODUCT
duke@435	863	void VirtualSpace::check_for_contiguity() {
duke@435	864	// Check contiguity.
duke@435	865	assert(low_boundary() <= lower_high() &&
duke@435	866	lower_high() <= lower_high_boundary(),
duke@435	867	"high address must be contained within the region");
duke@435	868	assert(lower_high_boundary() <= middle_high() &&
duke@435	869	middle_high() <= middle_high_boundary(),
duke@435	870	"high address must be contained within the region");
duke@435	871	assert(middle_high_boundary() <= upper_high() &&
duke@435	872	upper_high() <= upper_high_boundary(),
duke@435	873	"high address must be contained within the region");
duke@435	874	assert(low() >= low_boundary(), "low");
duke@435	875	assert(low_boundary() <= lower_high_boundary(), "lower high boundary");
duke@435	876	assert(upper_high_boundary() <= high_boundary(), "upper high boundary");
duke@435	877	assert(high() <= upper_high(), "upper high");
duke@435	878	}
duke@435	879
duke@435	880	void VirtualSpace::print() {
duke@435	881	tty->print ("Virtual space:");
duke@435	882	if (special()) tty->print(" (pinned in memory)");
duke@435	883	tty->cr();
duke@435	884	tty->print_cr(" - committed: %ld", committed_size());
duke@435	885	tty->print_cr(" - reserved: %ld", reserved_size());
duke@435	886	tty->print_cr(" - [low, high]: [" INTPTR_FORMAT ", " INTPTR_FORMAT "]", low(), high());
duke@435	887	tty->print_cr(" - [low_b, high_b]: [" INTPTR_FORMAT ", " INTPTR_FORMAT "]", low_boundary(), high_boundary());
duke@435	888	}
duke@435	889
duke@435	890	#endif