sfw/sfwl/core/pool_vector.h

717 lines
14 KiB
C++

//--STRIP
#ifndef POOL_VECTOR_H
#define POOL_VECTOR_H
//--STRIP
/*************************************************************************/
/* pool_vector.h */
/* From https://github.com/Relintai/pandemonium_engine (MIT) */
/*************************************************************************/
//--STRIP
#include "core/memory.h"
#include "core/mutex.h"
#include "pool_allocator.h"
#include "rw_lock.h"
#include "core/safe_refcount.h"
#include "core/ustring.h"
//--STRIP
struct MemoryPool {
//avoid accessing these directly, must be public for template access
static PoolAllocator *memory_pool;
static uint8_t *pool_memory;
static size_t *pool_size;
struct Alloc {
SafeRefCount refcount;
SafeNumeric<uint32_t> lock;
void *mem;
PoolAllocator::ID pool_id;
size_t size;
Alloc *free_list;
Alloc() :
lock(0),
mem(nullptr),
pool_id(POOL_ALLOCATOR_INVALID_ID),
size(0),
free_list(nullptr) {
}
};
static Alloc *allocs;
static Alloc *free_list;
static uint32_t alloc_count;
static uint32_t allocs_used;
static Mutex alloc_mutex;
static size_t total_memory;
static size_t max_memory;
static void setup(uint32_t p_max_allocs = (1 << 16));
static void cleanup();
};
template <class T>
class PoolVector {
MemoryPool::Alloc *alloc;
void _copy_on_write() {
if (!alloc) {
return;
}
// ERR_FAIL_COND(alloc->lock>0); should not be illegal to lock this for copy on write, as it's a copy on write after all
// Refcount should not be zero, otherwise it's a misuse of COW
if (alloc->refcount.get() == 1) {
return; //nothing to do
}
//must allocate something
MemoryPool::alloc_mutex.lock();
if (MemoryPool::allocs_used == MemoryPool::alloc_count) {
MemoryPool::alloc_mutex.unlock();
ERR_FAIL_MSG("All memory pool allocations are in use, can't COW.");
}
MemoryPool::Alloc *old_alloc = alloc;
//take one from the free list
alloc = MemoryPool::free_list;
MemoryPool::free_list = alloc->free_list;
//increment the used counter
MemoryPool::allocs_used++;
//copy the alloc data
alloc->size = old_alloc->size;
alloc->refcount.init();
alloc->pool_id = POOL_ALLOCATOR_INVALID_ID;
alloc->lock.set(0);
#ifdef DEBUG_ENABLED
MemoryPool::total_memory += alloc->size;
if (MemoryPool::total_memory > MemoryPool::max_memory) {
MemoryPool::max_memory = MemoryPool::total_memory;
}
#endif
MemoryPool::alloc_mutex.unlock();
if (MemoryPool::memory_pool) {
} else {
alloc->mem = memalloc(alloc->size);
}
{
Write w;
w._ref(alloc);
Read r;
r._ref(old_alloc);
int cur_elements = alloc->size / sizeof(T);
T *dst = (T *)w.ptr();
const T *src = (const T *)r.ptr();
for (int i = 0; i < cur_elements; i++) {
memnew_placement(&dst[i], T(src[i]));
}
}
if (old_alloc->refcount.unref()) {
//this should never happen but..
#ifdef DEBUG_ENABLED
MemoryPool::alloc_mutex.lock();
MemoryPool::total_memory -= old_alloc->size;
MemoryPool::alloc_mutex.unlock();
#endif
{
Write w;
w._ref(old_alloc);
int cur_elements = old_alloc->size / sizeof(T);
T *elems = (T *)w.ptr();
for (int i = 0; i < cur_elements; i++) {
elems[i].~T();
}
}
if (MemoryPool::memory_pool) {
//resize memory pool
//if none, create
//if some resize
} else {
memfree(old_alloc->mem);
old_alloc->mem = nullptr;
old_alloc->size = 0;
MemoryPool::alloc_mutex.lock();
old_alloc->free_list = MemoryPool::free_list;
MemoryPool::free_list = old_alloc;
MemoryPool::allocs_used--;
MemoryPool::alloc_mutex.unlock();
}
}
}
void _reference(const PoolVector &p_pool_vector) {
if (alloc == p_pool_vector.alloc) {
return;
}
_unreference();
if (!p_pool_vector.alloc) {
return;
}
if (p_pool_vector.alloc->refcount.ref()) {
alloc = p_pool_vector.alloc;
}
}
void _unreference() {
if (!alloc) {
return;
}
if (!alloc->refcount.unref()) {
alloc = nullptr;
return;
}
//must be disposed!
{
int cur_elements = alloc->size / sizeof(T);
// Don't use write() here because it could otherwise provoke COW,
// which is not desirable here because we are destroying the last reference anyways
Write w;
// Reference to still prevent other threads from touching the alloc
w._ref(alloc);
for (int i = 0; i < cur_elements; i++) {
w[i].~T();
}
}
#ifdef DEBUG_ENABLED
MemoryPool::alloc_mutex.lock();
MemoryPool::total_memory -= alloc->size;
MemoryPool::alloc_mutex.unlock();
#endif
if (MemoryPool::memory_pool) {
//resize memory pool
//if none, create
//if some resize
} else {
memfree(alloc->mem);
alloc->mem = nullptr;
alloc->size = 0;
MemoryPool::alloc_mutex.lock();
alloc->free_list = MemoryPool::free_list;
MemoryPool::free_list = alloc;
MemoryPool::allocs_used--;
MemoryPool::alloc_mutex.unlock();
}
alloc = nullptr;
}
public:
class Access {
friend class PoolVector;
protected:
MemoryPool::Alloc *alloc;
T *mem;
_FORCE_INLINE_ void _ref(MemoryPool::Alloc *p_alloc) {
alloc = p_alloc;
if (alloc) {
if (alloc->lock.increment() == 1) {
if (MemoryPool::memory_pool) {
//lock it and get mem
}
}
mem = (T *)alloc->mem;
}
}
_FORCE_INLINE_ void _unref() {
if (alloc) {
if (alloc->lock.decrement() == 0) {
if (MemoryPool::memory_pool) {
//put mem back
}
}
mem = nullptr;
alloc = nullptr;
}
}
Access() {
alloc = nullptr;
mem = nullptr;
}
public:
virtual ~Access() {
_unref();
}
void release() {
_unref();
}
};
class Read : public Access {
public:
_FORCE_INLINE_ const T &operator[](int p_index) const { return this->mem[p_index]; }
_FORCE_INLINE_ const T *ptr() const { return this->mem; }
void operator=(const Read &p_read) {
if (this->alloc == p_read.alloc) {
return;
}
this->_unref();
this->_ref(p_read.alloc);
}
Read(const Read &p_read) {
this->_ref(p_read.alloc);
}
Read() {}
};
class Write : public Access {
public:
_FORCE_INLINE_ T &operator[](int p_index) const { return this->mem[p_index]; }
_FORCE_INLINE_ T *ptr() const { return this->mem; }
void operator=(const Write &p_read) {
if (this->alloc == p_read.alloc) {
return;
}
this->_unref();
this->_ref(p_read.alloc);
}
Write(const Write &p_read) {
this->_ref(p_read.alloc);
}
Write() {}
};
Read read() const {
Read r;
if (alloc) {
r._ref(alloc);
}
return r;
}
Write write() {
Write w;
if (alloc) {
_copy_on_write(); //make sure there is only one being accessed
w._ref(alloc);
}
return w;
}
template <class MC>
void fill_with(const MC &p_mc) {
int c = p_mc.size();
resize(c);
Write w = write();
int idx = 0;
for (const typename MC::Element *E = p_mc.front(); E; E = E->next()) {
w[idx++] = E->get();
}
}
void remove(int p_index) {
int s = size();
ERR_FAIL_INDEX(p_index, s);
Write w = write();
for (int i = p_index; i < s - 1; i++) {
w[i] = w[i + 1];
};
w = Write();
resize(s - 1);
}
inline int size() const;
inline bool empty() const;
T get(int p_index) const;
void set(int p_index, const T &p_val);
void fill(const T &p_val);
void push_back(const T &p_val);
void append(const T &p_val) {
push_back(p_val);
}
void append_array(const PoolVector<T> &p_arr) {
int ds = p_arr.size();
if (ds == 0) {
return;
}
int bs = size();
resize(bs + ds);
Write w = write();
Read r = p_arr.read();
for (int i = 0; i < ds; i++) {
w[bs + i] = r[i];
}
}
PoolVector<T> subarray(int p_from, int p_to) const {
if (p_from < 0) {
p_from = size() + p_from;
}
if (p_to < 0) {
p_to = size() + p_to;
}
ERR_FAIL_INDEX_V(p_from, size(), PoolVector<T>());
ERR_FAIL_INDEX_V(p_to, size(), PoolVector<T>());
PoolVector<T> slice;
int span = 1 + p_to - p_from;
slice.resize(span);
Read r = read();
Write w = slice.write();
for (int i = 0; i < span; ++i) {
w[i] = r[p_from + i];
}
return slice;
}
Error insert(int p_pos, const T &p_val) {
int s = size();
ERR_FAIL_INDEX_V(p_pos, s + 1, ERR_INVALID_PARAMETER);
resize(s + 1);
{
Write w = write();
for (int i = s; i > p_pos; i--) {
w[i] = w[i - 1];
}
w[p_pos] = p_val;
}
return OK;
}
String join(const String &delimiter) const {
String rs = "";
int s = size();
Read r = read();
for (int i = 0; i < s; i++) {
rs += r[i] + delimiter;
}
rs.erase(rs.length() - delimiter.length(), delimiter.length());
return rs;
}
bool contains(const T &p_val) const;
int find(const T &p_val, int p_from = 0) const;
int rfind(const T &p_val, int p_from = -1) const;
int count(const T &p_val) const;
bool has(const T &p_val) const;
bool is_locked() const {
return alloc && alloc->lock.get() > 0;
}
inline T operator[](int p_index) const;
Error resize(int p_size);
Error clear() {
return resize(0);
}
void invert();
void sort();
void operator=(const PoolVector &p_pool_vector) {
_reference(p_pool_vector);
}
PoolVector() {
alloc = nullptr;
}
PoolVector(const PoolVector &p_pool_vector) {
alloc = nullptr;
_reference(p_pool_vector);
}
~PoolVector() {
_unreference();
}
};
template <class T>
int PoolVector<T>::size() const {
return alloc ? alloc->size / sizeof(T) : 0;
}
template <class T>
bool PoolVector<T>::empty() const {
return alloc ? alloc->size == 0 : true;
}
template <class T>
T PoolVector<T>::get(int p_index) const {
return operator[](p_index);
}
template <class T>
void PoolVector<T>::set(int p_index, const T &p_val) {
ERR_FAIL_INDEX(p_index, size());
Write w = write();
w[p_index] = p_val;
}
template <class T>
void PoolVector<T>::fill(const T &p_val) {
Write w = write();
for (int i = 0; i < size(); i++) {
w[i] = p_val;
}
}
template <class T>
void PoolVector<T>::push_back(const T &p_val) {
resize(size() + 1);
set(size() - 1, p_val);
}
template <class T>
bool PoolVector<T>::contains(const T &p_val) const {
Read r = read();
int s = size();
for (int i = 0; i < s; ++i) {
if (r[i] == p_val) {
return true;
}
}
return false;
}
template <class T>
int PoolVector<T>::find(const T &p_val, int p_from) const {
if (p_from < 0) {
return -1;
}
const int s = size();
const Read r = read();
for (int i = p_from; i < s; i++) {
if (r[i] == p_val) {
return i;
}
}
return -1;
}
template <class T>
int PoolVector<T>::rfind(const T &p_val, int p_from) const {
const int s = size();
const Read r = read();
if (p_from < 0) {
p_from = s + p_from;
}
if (p_from < 0 || p_from >= s) {
p_from = s - 1;
}
for (int i = p_from; i >= 0; i--) {
if (r[i] == p_val) {
return i;
}
}
return -1;
}
template <class T>
int PoolVector<T>::count(const T &p_val) const {
const int s = size();
const Read r = read();
int amount = 0;
for (int i = 0; i < s; i++) {
if (r[i] == p_val) {
amount++;
}
}
return amount;
}
template <class T>
bool PoolVector<T>::has(const T &p_val) const {
return find(p_val) != -1;
}
template <class T>
T PoolVector<T>::operator[](int p_index) const {
CRASH_BAD_INDEX(p_index, size());
Read r = read();
return r[p_index];
}
template <class T>
Error PoolVector<T>::resize(int p_size) {
ERR_FAIL_COND_V_MSG(p_size < 0, ERR_INVALID_PARAMETER, "Size of PoolVector cannot be negative.");
if (alloc == nullptr) {
if (p_size == 0) {
return OK; //nothing to do here
}
//must allocate something
MemoryPool::alloc_mutex.lock();
if (MemoryPool::allocs_used == MemoryPool::alloc_count) {
MemoryPool::alloc_mutex.unlock();
ERR_FAIL_V_MSG(ERR_OUT_OF_MEMORY, "All memory pool allocations are in use.");
}
//take one from the free list
alloc = MemoryPool::free_list;
MemoryPool::free_list = alloc->free_list;
//increment the used counter
MemoryPool::allocs_used++;
//cleanup the alloc
alloc->size = 0;
alloc->refcount.init();
alloc->pool_id = POOL_ALLOCATOR_INVALID_ID;
MemoryPool::alloc_mutex.unlock();
} else {
ERR_FAIL_COND_V_MSG(alloc->lock.get() > 0, ERR_LOCKED, "Can't resize PoolVector if locked."); //can't resize if locked!
}
size_t new_size = sizeof(T) * p_size;
if (alloc->size == new_size) {
return OK; //nothing to do
}
if (p_size == 0) {
_unreference();
return OK;
}
_copy_on_write(); // make it unique
#ifdef DEBUG_ENABLED
MemoryPool::alloc_mutex.lock();
MemoryPool::total_memory -= alloc->size;
MemoryPool::total_memory += new_size;
if (MemoryPool::total_memory > MemoryPool::max_memory) {
MemoryPool::max_memory = MemoryPool::total_memory;
}
MemoryPool::alloc_mutex.unlock();
#endif
int cur_elements = alloc->size / sizeof(T);
if (p_size > cur_elements) {
if (MemoryPool::memory_pool) {
//resize memory pool
//if none, create
//if some resize
} else {
if (alloc->size == 0) {
alloc->mem = memalloc(new_size);
} else {
alloc->mem = memrealloc(alloc->mem, new_size);
}
}
alloc->size = new_size;
Write w = write();
for (int i = cur_elements; i < p_size; i++) {
memnew_placement(&w[i], T);
}
} else {
{
Write w = write();
for (int i = p_size; i < cur_elements; i++) {
w[i].~T();
}
}
if (MemoryPool::memory_pool) {
//resize memory pool
//if none, create
//if some resize
} else {
if (new_size == 0) {
memfree(alloc->mem);
alloc->mem = nullptr;
alloc->size = 0;
MemoryPool::alloc_mutex.lock();
alloc->free_list = MemoryPool::free_list;
MemoryPool::free_list = alloc;
MemoryPool::allocs_used--;
MemoryPool::alloc_mutex.unlock();
} else {
alloc->mem = memrealloc(alloc->mem, new_size);
alloc->size = new_size;
}
}
}
return OK;
}
template <class T>
void PoolVector<T>::invert() {
T temp;
Write w = write();
int s = size();
int half_s = s / 2;
for (int i = 0; i < half_s; i++) {
temp = w[i];
w[i] = w[s - i - 1];
w[s - i - 1] = temp;
}
}
template <class T>
void PoolVector<T>::sort() {
int len = size();
if (len == 0) {
return;
}
Write w = write();
SortArray<T> sorter;
sorter.sort(w.ptr(), len);
}
//--STRIP
#endif // POOL_VECTOR_H
//--STRIP