8178500: Replace usages of round_to and round_down with align_up and align_down
Reviewed-by: rehn, tschatzl
/*
* Copyright (c) 2003, 2013, 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
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#ifndef SHARE_VM_SERVICES_MEMORYMANAGER_HPP
#define SHARE_VM_SERVICES_MEMORYMANAGER_HPP
#include "memory/allocation.hpp"
#include "runtime/timer.hpp"
#include "services/memoryUsage.hpp"
// A memory manager is responsible for managing one or more memory pools.
// The garbage collector is one type of memory managers responsible
// for reclaiming memory occupied by unreachable objects. A Java virtual
// machine may have one or more memory managers. It may
// add or remove memory managers during execution.
// A memory pool can be managed by more than one memory managers.
class MemoryPool;
class GCMemoryManager;
class OopClosure;
class MemoryManager : public CHeapObj<mtInternal> {
private:
enum {
max_num_pools = 10
};
MemoryPool* _pools[max_num_pools];
int _num_pools;
protected:
volatile instanceOop _memory_mgr_obj;
public:
MemoryManager();
int num_memory_pools() const { return _num_pools; }
MemoryPool* get_memory_pool(int index) {
assert(index >= 0 && index < _num_pools, "Invalid index");
return _pools[index];
}
void add_pool(MemoryPool* pool);
bool is_manager(instanceHandle mh) { return mh() == _memory_mgr_obj; }
virtual instanceOop get_memory_manager_instance(TRAPS);
virtual bool is_gc_memory_manager() { return false; }
virtual const char* name() = 0;
// GC support
void oops_do(OopClosure* f);
// Static factory methods to get a memory manager of a specific type
static MemoryManager* get_code_cache_memory_manager();
static MemoryManager* get_metaspace_memory_manager();
static GCMemoryManager* get_copy_memory_manager();
static GCMemoryManager* get_msc_memory_manager();
static GCMemoryManager* get_parnew_memory_manager();
static GCMemoryManager* get_cms_memory_manager();
static GCMemoryManager* get_psScavenge_memory_manager();
static GCMemoryManager* get_psMarkSweep_memory_manager();
static GCMemoryManager* get_g1YoungGen_memory_manager();
static GCMemoryManager* get_g1OldGen_memory_manager();
};
class CodeCacheMemoryManager : public MemoryManager {
private:
public:
CodeCacheMemoryManager() : MemoryManager() {}
const char* name() { return "CodeCacheManager"; }
};
class MetaspaceMemoryManager : public MemoryManager {
public:
MetaspaceMemoryManager() : MemoryManager() {}
const char* name() { return "Metaspace Manager"; }
};
class GCStatInfo : public ResourceObj {
private:
size_t _index;
jlong _start_time;
jlong _end_time;
// We keep memory usage of all memory pools
MemoryUsage* _before_gc_usage_array;
MemoryUsage* _after_gc_usage_array;
int _usage_array_size;
void set_gc_usage(int pool_index, MemoryUsage, bool before_gc);
public:
GCStatInfo(int num_pools);
~GCStatInfo();
size_t gc_index() { return _index; }
jlong start_time() { return _start_time; }
jlong end_time() { return _end_time; }
int usage_array_size() { return _usage_array_size; }
MemoryUsage before_gc_usage_for_pool(int pool_index) {
assert(pool_index >= 0 && pool_index < _usage_array_size, "Range checking");
return _before_gc_usage_array[pool_index];
}
MemoryUsage after_gc_usage_for_pool(int pool_index) {
assert(pool_index >= 0 && pool_index < _usage_array_size, "Range checking");
return _after_gc_usage_array[pool_index];
}
MemoryUsage* before_gc_usage_array() { return _before_gc_usage_array; }
MemoryUsage* after_gc_usage_array() { return _after_gc_usage_array; }
void set_index(size_t index) { _index = index; }
void set_start_time(jlong time) { _start_time = time; }
void set_end_time(jlong time) { _end_time = time; }
void set_before_gc_usage(int pool_index, MemoryUsage usage) {
assert(pool_index >= 0 && pool_index < _usage_array_size, "Range checking");
set_gc_usage(pool_index, usage, true /* before gc */);
}
void set_after_gc_usage(int pool_index, MemoryUsage usage) {
assert(pool_index >= 0 && pool_index < _usage_array_size, "Range checking");
set_gc_usage(pool_index, usage, false /* after gc */);
}
void clear();
};
class GCMemoryManager : public MemoryManager {
private:
// TODO: We should unify the GCCounter and GCMemoryManager statistic
size_t _num_collections;
elapsedTimer _accumulated_timer;
elapsedTimer _gc_timer; // for measuring every GC duration
GCStatInfo* _last_gc_stat;
Mutex* _last_gc_lock;
GCStatInfo* _current_gc_stat;
int _num_gc_threads;
volatile bool _notification_enabled;
public:
GCMemoryManager();
~GCMemoryManager();
void initialize_gc_stat_info();
bool is_gc_memory_manager() { return true; }
jlong gc_time_ms() { return _accumulated_timer.milliseconds(); }
size_t gc_count() { return _num_collections; }
int num_gc_threads() { return _num_gc_threads; }
void set_num_gc_threads(int count) { _num_gc_threads = count; }
void gc_begin(bool recordGCBeginTime, bool recordPreGCUsage,
bool recordAccumulatedGCTime);
void gc_end(bool recordPostGCUsage, bool recordAccumulatedGCTime,
bool recordGCEndTime, bool countCollection, GCCause::Cause cause);
void reset_gc_stat() { _num_collections = 0; _accumulated_timer.reset(); }
// Copy out _last_gc_stat to the given destination, returning
// the collection count. Zero signifies no gc has taken place.
size_t get_last_gc_stat(GCStatInfo* dest);
void set_notification_enabled(bool enabled) { _notification_enabled = enabled; }
bool is_notification_enabled() { return _notification_enabled; }
};
// These subclasses of GCMemoryManager are defined to include
// GC-specific information.
// TODO: Add GC-specific information
class CopyMemoryManager : public GCMemoryManager {
private:
public:
CopyMemoryManager() : GCMemoryManager() {}
const char* name() { return "Copy"; }
};
class MSCMemoryManager : public GCMemoryManager {
private:
public:
MSCMemoryManager() : GCMemoryManager() {}
const char* name() { return "MarkSweepCompact"; }
};
class ParNewMemoryManager : public GCMemoryManager {
private:
public:
ParNewMemoryManager() : GCMemoryManager() {}
const char* name() { return "ParNew"; }
};
class CMSMemoryManager : public GCMemoryManager {
private:
public:
CMSMemoryManager() : GCMemoryManager() {}
const char* name() { return "ConcurrentMarkSweep";}
};
class PSScavengeMemoryManager : public GCMemoryManager {
private:
public:
PSScavengeMemoryManager() : GCMemoryManager() {}
const char* name() { return "PS Scavenge"; }
};
class PSMarkSweepMemoryManager : public GCMemoryManager {
private:
public:
PSMarkSweepMemoryManager() : GCMemoryManager() {}
const char* name() { return "PS MarkSweep"; }
};
class G1YoungGenMemoryManager : public GCMemoryManager {
private:
public:
G1YoungGenMemoryManager() : GCMemoryManager() {}
const char* name() { return "G1 Young Generation"; }
};
class G1OldGenMemoryManager : public GCMemoryManager {
private:
public:
G1OldGenMemoryManager() : GCMemoryManager() {}
const char* name() { return "G1 Old Generation"; }
};
#endif // SHARE_VM_SERVICES_MEMORYMANAGER_HPP