virtualx-engine/core/pool_allocator.cpp
Rémi Verschelde d8223ffa75 Welcome in 2017, dear changelog reader!
That year should bring the long-awaited OpenGL ES 3.0 compatible renderer
with state-of-the-art rendering techniques tuned to work as low as middle
end handheld devices - without compromising with the possibilities given
for higher end desktop games of course. Great times ahead for the Godot
community and the gamers that will play our games!

(cherry picked from commit c7bc44d5ad)
2017-01-12 19:15:30 +01:00

657 lines
14 KiB
C++

/*************************************************************************/
/* pool_allocator.cpp */
/*************************************************************************/
/* This file is part of: */
/* GODOT ENGINE */
/* http://www.godotengine.org */
/*************************************************************************/
/* Copyright (c) 2007-2017 Juan Linietsky, Ariel Manzur. */
/* */
/* Permission is hereby granted, free of charge, to any person obtaining */
/* a copy of this software and associated documentation files (the */
/* "Software"), to deal in the Software without restriction, including */
/* without limitation the rights to use, copy, modify, merge, publish, */
/* distribute, sublicense, and/or sell copies of the Software, and to */
/* permit persons to whom the Software is furnished to do so, subject to */
/* the following conditions: */
/* */
/* The above copyright notice and this permission notice shall be */
/* included in all copies or substantial portions of the Software. */
/* */
/* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, */
/* EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF */
/* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT.*/
/* IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY */
/* CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, */
/* TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE */
/* SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. */
/*************************************************************************/
#include "pool_allocator.h"
#include "error_macros.h"
#include "core/os/os.h"
#include "os/memory.h"
#include "os/copymem.h"
#include "print_string.h"
#include <assert.h>
#define COMPACT_CHUNK( m_entry , m_to_pos ) \
do { \
void *_dst=&((unsigned char*)pool)[m_to_pos]; \
void *_src=&((unsigned char*)pool)[(m_entry).pos]; \
movemem(_dst,_src,aligned((m_entry).len)); \
(m_entry).pos=m_to_pos; \
} while (0);
void PoolAllocator::mt_lock() const {
}
void PoolAllocator::mt_unlock() const {
}
bool PoolAllocator::get_free_entry(EntryArrayPos* p_pos) {
if (entry_count==entry_max)
return false;
for (int i=0;i<entry_max;i++) {
if (entry_array[i].len==0) {
*p_pos=i;
return true;
}
}
ERR_PRINT("Out of memory Chunks!");
return false; //
}
/**
* Find a hole
* @param p_pos The hole is behind the block pointed by this variable upon return. if pos==entry_count, then allocate at end
* @param p_for_size hole size
* @return false if hole found, true if no hole found
*/
bool PoolAllocator::find_hole(EntryArrayPos *p_pos, int p_for_size) {
/* position where previous entry ends. Defaults to zero (begin of pool) */
int prev_entry_end_pos=0;
for (int i=0;i<entry_count;i++) {
Entry &entry=entry_array[ entry_indices[ i ] ];
/* determine hole size to previous entry */
int hole_size=entry.pos-prev_entry_end_pos;
/* detemine if what we want fits in that hole */
if (hole_size>=p_for_size) {
*p_pos=i;
return true;
}
/* prepare for next one */
prev_entry_end_pos=entry_end(entry);
}
/* No holes between entrys, check at the end..*/
if ( (pool_size-prev_entry_end_pos)>=p_for_size ) {
*p_pos=entry_count;
return true;
}
return false;
}
void PoolAllocator::compact(int p_up_to) {
uint32_t prev_entry_end_pos=0;
if (p_up_to<0)
p_up_to=entry_count;
for (int i=0;i<p_up_to;i++) {
Entry &entry=entry_array[ entry_indices[ i ] ];
/* determine hole size to previous entry */
int hole_size=entry.pos-prev_entry_end_pos;
/* if we can compact, do it */
if (hole_size>0 && !entry.lock) {
COMPACT_CHUNK(entry,prev_entry_end_pos);
}
/* prepare for next one */
prev_entry_end_pos=entry_end(entry);
}
}
void PoolAllocator::compact_up(int p_from) {
uint32_t next_entry_end_pos=pool_size; // - static_area_size;
for (int i=entry_count-1;i>=p_from;i--) {
Entry &entry=entry_array[ entry_indices[ i ] ];
/* determine hole size to nextious entry */
int hole_size=next_entry_end_pos-(entry.pos+aligned(entry.len));
/* if we can compact, do it */
if (hole_size>0 && !entry.lock) {
COMPACT_CHUNK(entry,(next_entry_end_pos-aligned(entry.len)));
}
/* prepare for next one */
next_entry_end_pos=entry.pos;
}
}
bool PoolAllocator::find_entry_index(EntryIndicesPos *p_map_pos,Entry *p_entry) {
EntryArrayPos entry_pos=entry_max;
for (int i=0;i<entry_count;i++) {
if (&entry_array[ entry_indices[ i ] ]==p_entry) {
entry_pos=i;
break;
}
}
if (entry_pos==entry_max)
return false;
*p_map_pos=entry_pos;
return true;
}
PoolAllocator::ID PoolAllocator::alloc(int p_size) {
ERR_FAIL_COND_V(p_size<1,POOL_ALLOCATOR_INVALID_ID);
#ifdef DEBUG_ENABLED
if (p_size > free_mem) OS::get_singleton()->debug_break();
#endif
ERR_FAIL_COND_V(p_size>free_mem,POOL_ALLOCATOR_INVALID_ID);
mt_lock();
if (entry_count==entry_max) {
mt_unlock();
ERR_PRINT("entry_count==entry_max");
return POOL_ALLOCATOR_INVALID_ID;
}
int size_to_alloc=aligned(p_size);
EntryIndicesPos new_entry_indices_pos;
if (!find_hole(&new_entry_indices_pos, size_to_alloc)) {
/* No hole could be found, try compacting mem */
compact();
/* Then search again */
if (!find_hole(&new_entry_indices_pos, size_to_alloc)) {
mt_unlock();
ERR_PRINT("memory can't be compacted further");
return POOL_ALLOCATOR_INVALID_ID;
}
}
EntryArrayPos new_entry_array_pos;
bool found_free_entry=get_free_entry(&new_entry_array_pos);
if (!found_free_entry) {
mt_unlock();
ERR_FAIL_COND_V( !found_free_entry , POOL_ALLOCATOR_INVALID_ID );
}
/* move all entry indices up, make room for this one */
for (int i=entry_count;i>new_entry_indices_pos;i-- ) {
entry_indices[i]=entry_indices[i-1];
}
entry_indices[new_entry_indices_pos]=new_entry_array_pos;
entry_count++;
Entry &entry=entry_array[ entry_indices[ new_entry_indices_pos ] ];
entry.len=p_size;
entry.pos=(new_entry_indices_pos==0)?0:entry_end(entry_array[ entry_indices[ new_entry_indices_pos-1 ] ]); //alloc either at begining or end of previous
entry.lock=0;
entry.check=(check_count++)&CHECK_MASK;
free_mem-=size_to_alloc;
if (free_mem<free_mem_peak)
free_mem_peak=free_mem;
ID retval = (entry_indices[ new_entry_indices_pos ]<<CHECK_BITS)|entry.check;
mt_unlock();
//ERR_FAIL_COND_V( (uintptr_t)get(retval)%align != 0, retval );
return retval;
}
PoolAllocator::Entry * PoolAllocator::get_entry(ID p_mem) {
unsigned int check=p_mem&CHECK_MASK;
int entry=p_mem>>CHECK_BITS;
ERR_FAIL_INDEX_V(entry,entry_max,NULL);
ERR_FAIL_COND_V(entry_array[entry].check!=check,NULL);
ERR_FAIL_COND_V(entry_array[entry].len==0,NULL);
return &entry_array[entry];
}
const PoolAllocator::Entry * PoolAllocator::get_entry(ID p_mem) const {
unsigned int check=p_mem&CHECK_MASK;
int entry=p_mem>>CHECK_BITS;
ERR_FAIL_INDEX_V(entry,entry_max,NULL);
ERR_FAIL_COND_V(entry_array[entry].check!=check,NULL);
ERR_FAIL_COND_V(entry_array[entry].len==0,NULL);
return &entry_array[entry];
}
void PoolAllocator::free(ID p_mem) {
mt_lock();
Entry *e=get_entry(p_mem);
if (!e) {
mt_unlock();
ERR_PRINT("!e");
return;
}
if (e->lock) {
mt_unlock();
ERR_PRINT("e->lock");
return;
}
EntryIndicesPos entry_indices_pos;
bool index_found = find_entry_index(&entry_indices_pos,e);
if (!index_found) {
mt_unlock();
ERR_FAIL_COND(!index_found);
}
for (int i=entry_indices_pos;i<(entry_count-1);i++) {
entry_indices[ i ] = entry_indices[ i+1 ];
}
entry_count--;
free_mem+=aligned(e->len);
e->clear();
mt_unlock();
}
int PoolAllocator::get_size(ID p_mem) const {
int size;
mt_lock();
const Entry *e=get_entry(p_mem);
if (!e) {
mt_unlock();
ERR_PRINT("!e");
return 0;
}
size=e->len;
mt_unlock();
return size;
}
Error PoolAllocator::resize(ID p_mem,int p_new_size) {
mt_lock();
Entry *e=get_entry(p_mem);
if (!e) {
mt_unlock();
ERR_FAIL_COND_V(!e,ERR_INVALID_PARAMETER);
}
if (needs_locking && e->lock) {
mt_unlock();
ERR_FAIL_COND_V(e->lock,ERR_ALREADY_IN_USE);
}
int alloc_size = aligned(p_new_size);
if (aligned(e->len)==alloc_size) {
e->len=p_new_size;
mt_unlock();
return OK;
} else if (e->len>(uint32_t)p_new_size) {
free_mem += aligned(e->len);
free_mem -= alloc_size;
e->len=p_new_size;
mt_unlock();
return OK;
}
//p_new_size = align(p_new_size)
int _free = free_mem; // - static_area_size;
if ((_free + aligned(e->len)) - alloc_size < 0) {
mt_unlock();
ERR_FAIL_V( ERR_OUT_OF_MEMORY );
};
EntryIndicesPos entry_indices_pos;
bool index_found = find_entry_index(&entry_indices_pos,e);
if (!index_found) {
mt_unlock();
ERR_FAIL_COND_V(!index_found,ERR_BUG);
}
//no need to move stuff around, it fits before the next block
int next_pos;
if (entry_indices_pos+1 == entry_count) {
next_pos = pool_size; // - static_area_size;
} else {
next_pos = entry_array[entry_indices[entry_indices_pos+1]].pos;
};
if ((next_pos - e->pos) > alloc_size) {
free_mem+=aligned(e->len);
e->len=p_new_size;
free_mem-=alloc_size;
mt_unlock();
return OK;
}
//it doesn't fit, compact around BEFORE current index (make room behind)
compact(entry_indices_pos+1);
if ((next_pos - e->pos) > alloc_size) {
//now fits! hooray!
free_mem+=aligned(e->len);
e->len=p_new_size;
free_mem-=alloc_size;
mt_unlock();
if (free_mem<free_mem_peak)
free_mem_peak=free_mem;
return OK;
}
//STILL doesn't fit, compact around AFTER current index (make room after)
compact_up(entry_indices_pos+1);
if ((entry_array[entry_indices[entry_indices_pos+1]].pos - e->pos) > alloc_size) {
//now fits! hooray!
free_mem+=aligned(e->len);
e->len=p_new_size;
free_mem-=alloc_size;
mt_unlock();
if (free_mem<free_mem_peak)
free_mem_peak=free_mem;
return OK;
}
mt_unlock();
ERR_FAIL_V(ERR_OUT_OF_MEMORY);
}
Error PoolAllocator::lock(ID p_mem) {
if (!needs_locking)
return OK;
mt_lock();
Entry *e=get_entry(p_mem);
if (!e) {
mt_unlock();
ERR_PRINT("!e");
return ERR_INVALID_PARAMETER;
}
e->lock++;
mt_unlock();
return OK;
}
bool PoolAllocator::is_locked(ID p_mem) const {
if (!needs_locking)
return false;
mt_lock();
const Entry *e=((PoolAllocator*)(this))->get_entry(p_mem);
if (!e) {
mt_unlock();
ERR_PRINT("!e");
return false;
}
bool locked = e->lock;
mt_unlock();
return locked;
}
const void *PoolAllocator::get(ID p_mem) const {
if (!needs_locking) {
const Entry *e=get_entry(p_mem);
ERR_FAIL_COND_V(!e,NULL);
return &pool[e->pos];
}
mt_lock();
const Entry *e=get_entry(p_mem);
if (!e) {
mt_unlock();
ERR_FAIL_COND_V(!e,NULL);
}
if (e->lock==0) {
mt_unlock();
ERR_PRINT( "e->lock == 0" );
return NULL;
}
if (e->pos<0 || (int)e->pos>=pool_size) {
mt_unlock();
ERR_PRINT("e->pos<0 || e->pos>=pool_size");
return NULL;
}
const void *ptr=&pool[e->pos];
mt_unlock();
return ptr;
}
void *PoolAllocator::get(ID p_mem) {
if (!needs_locking) {
Entry *e=get_entry(p_mem);
if (!e) {
ERR_FAIL_COND_V(!e,NULL);
};
return &pool[e->pos];
}
mt_lock();
Entry *e=get_entry(p_mem);
if (!e) {
mt_unlock();
ERR_FAIL_COND_V(!e,NULL);
}
if (e->lock==0) {
//assert(0);
mt_unlock();
ERR_PRINT( "e->lock == 0" );
return NULL;
}
if (e->pos<0 || (int)e->pos>=pool_size) {
mt_unlock();
ERR_PRINT("e->pos<0 || e->pos>=pool_size");
return NULL;
}
void *ptr=&pool[e->pos];
mt_unlock();
return ptr;
}
void PoolAllocator::unlock(ID p_mem) {
if (!needs_locking)
return;
mt_lock();
Entry *e=get_entry(p_mem);
if (e->lock == 0 ) {
mt_unlock();
ERR_PRINT( "e->lock == 0" );
return;
}
e->lock--;
mt_unlock();
}
int PoolAllocator::get_used_mem() const {
return pool_size-free_mem;
}
int PoolAllocator::get_free_peak() {
return free_mem_peak;
}
int PoolAllocator::get_free_mem() {
return free_mem;
}
void PoolAllocator::create_pool(void * p_mem,int p_size,int p_max_entries) {
pool=(uint8_t*)p_mem;
pool_size=p_size;
entry_array = memnew_arr( Entry, p_max_entries );
entry_indices = memnew_arr( int, p_max_entries );
entry_max = p_max_entries;
entry_count=0;
free_mem=p_size;
free_mem_peak=p_size;
check_count=0;
}
PoolAllocator::PoolAllocator(int p_size,bool p_needs_locking,int p_max_entries) {
mem_ptr=Memory::alloc_static( p_size,"PoolAllocator()");
ERR_FAIL_COND(!mem_ptr);
align=1;
create_pool(mem_ptr,p_size,p_max_entries);
needs_locking=p_needs_locking;
}
PoolAllocator::PoolAllocator(void * p_mem,int p_size, int p_align ,bool p_needs_locking,int p_max_entries) {
if (p_align > 1) {
uint8_t *mem8=(uint8_t*)p_mem;
uint64_t ofs = (uint64_t)mem8;
if (ofs%p_align) {
int dif = p_align-(ofs%p_align);
mem8+=p_align-(ofs%p_align);
p_size -= dif;
p_mem = (void*)mem8;
};
};
create_pool( p_mem,p_size,p_max_entries);
needs_locking=p_needs_locking;
align=p_align;
mem_ptr=NULL;
}
PoolAllocator::PoolAllocator(int p_align,int p_size,bool p_needs_locking,int p_max_entries) {
ERR_FAIL_COND(p_align<1);
mem_ptr=Memory::alloc_static( p_size+p_align,"PoolAllocator()");
uint8_t *mem8=(uint8_t*)mem_ptr;
uint64_t ofs = (uint64_t)mem8;
if (ofs%p_align)
mem8+=p_align-(ofs%p_align);
create_pool( mem8 ,p_size,p_max_entries);
needs_locking=p_needs_locking;
align=p_align;
}
PoolAllocator::~PoolAllocator() {
if (mem_ptr)
Memory::free_static( mem_ptr );
memdelete_arr( entry_array );
memdelete_arr( entry_indices );
}