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bsnes/snespurify/nall/vector.hpp

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#ifndef NALL_VECTOR_HPP
#define NALL_VECTOR_HPP
#include <initializer_list>
#include <new>
#include <type_traits>
#include <utility>
#include <nall/algorithm.hpp>
#include <nall/bit.hpp>
#include <nall/concept.hpp>
#include <nall/foreach.hpp>
#include <nall/utility.hpp>
namespace nall {
//linear_vector
//memory: O(capacity * 2)
//
//linear_vector uses placement new + manual destructor calls to create a
//contiguous block of memory for all objects. accessing individual elements
//is fast, though resizing the array incurs significant overhead.
//reserve() overhead is reduced from quadratic time to amortized constant time
//by resizing twice as much as requested.
//
//if objects hold memory address references to themselves (introspection), a
//valid copy constructor will be needed to keep pointers valid.
template<typename T> class linear_vector {
protected:
T *pool;
unsigned poolsize, objectsize;
public:
unsigned size() const { return objectsize; }
unsigned capacity() const { return poolsize; }
void reset() {
if(pool) {
for(unsigned i = 0; i < objectsize; i++) pool[i].~T();
free(pool);
}
pool = 0;
poolsize = 0;
objectsize = 0;
}
void reserve(unsigned newsize) {
newsize = bit::round(newsize); //round to nearest power of two (for amortized growth)
T *poolcopy = (T*)calloc(newsize, sizeof(T));
for(unsigned i = 0; i < min(objectsize, newsize); i++) new(poolcopy + i) T(pool[i]);
for(unsigned i = 0; i < objectsize; i++) pool[i].~T();
free(pool);
pool = poolcopy;
poolsize = newsize;
objectsize = min(objectsize, newsize);
}
void resize(unsigned newsize) {
if(newsize > poolsize) reserve(newsize);
if(newsize < objectsize) {
//vector is shrinking; destroy excess objects
for(unsigned i = newsize; i < objectsize; i++) pool[i].~T();
} else if(newsize > objectsize) {
//vector is expanding; allocate new objects
for(unsigned i = objectsize; i < newsize; i++) new(pool + i) T;
}
objectsize = newsize;
}
void append(const T data) {
if(objectsize + 1 > poolsize) reserve(objectsize + 1);
new(pool + objectsize++) T(data);
}
template<typename U> void insert(unsigned index, const U list) {
linear_vector<T> merged;
for(unsigned i = 0; i < index; i++) merged.append(pool[i]);
foreach(item, list) merged.append(item);
for(unsigned i = index; i < objectsize; i++) merged.append(pool[i]);
operator=(merged);
}
void insert(unsigned index, const T item) {
insert(index, linear_vector<T>{ item });
}
void remove(unsigned index, unsigned count = 1) {
for(unsigned i = index; count + i < objectsize; i++) {
pool[i] = pool[count + i];
}
if(count + index >= objectsize) resize(index); //every element >= index was removed
else resize(objectsize - count);
}
linear_vector() : pool(0), poolsize(0), objectsize(0) {
}
linear_vector(std::initializer_list<T> list) : pool(0), poolsize(0), objectsize(0) {
for(const T *p = list.begin(); p != list.end(); ++p) append(*p);
}
~linear_vector() {
reset();
}
//copy
inline linear_vector<T>& operator=(const linear_vector<T> &source) {
reset();
reserve(source.capacity());
resize(source.size());
for(unsigned i = 0; i < source.size(); i++) operator[](i) = source.operator[](i);
return *this;
}
linear_vector(const linear_vector<T> &source) : pool(0), poolsize(0), objectsize(0) {
operator=(source);
}
//move
inline linear_vector<T>& operator=(linear_vector<T> &&source) {
reset();
pool = source.pool;
poolsize = source.poolsize;
objectsize = source.objectsize;
source.pool = 0;
source.reset();
return *this;
}
linear_vector(linear_vector<T> &&source) : pool(0), poolsize(0), objectsize(0) {
operator=(std::move(source));
}
//index
inline T& operator[](unsigned index) {
if(index >= objectsize) resize(index + 1);
return pool[index];
}
inline const T& operator[](unsigned index) const {
if(index >= objectsize) throw "vector[] out of bounds";
return pool[index];
}
//iteration
T* begin() { return &pool[0]; }
T* end() { return &pool[objectsize]; }
const T* begin() const { return &pool[0]; }
const T* end() const { return &pool[objectsize]; }
};
//pointer_vector
//memory: O(1)
//
//pointer_vector keeps an array of pointers to each vector object. this adds
//significant overhead to individual accesses, but allows for optimal memory
//utilization.
//
//by guaranteeing that the base memory address of each objects never changes,
//this avoids the need for an object to have a valid copy constructor.
template<typename T> class pointer_vector {
protected:
T **pool;
unsigned poolsize, objectsize;
public:
unsigned size() const { return objectsize; }
unsigned capacity() const { return poolsize; }
void reset() {
if(pool) {
for(unsigned i = 0; i < objectsize; i++) { if(pool[i]) delete pool[i]; }
free(pool);
}
pool = 0;
poolsize = 0;
objectsize = 0;
}
void reserve(unsigned newsize) {
newsize = bit::round(newsize); //round to nearest power of two (for amortized growth)
for(unsigned i = newsize; i < objectsize; i++) {
if(pool[i]) { delete pool[i]; pool[i] = 0; }
}
pool = (T**)realloc(pool, newsize * sizeof(T*));
for(unsigned i = poolsize; i < newsize; i++) pool[i] = 0;
poolsize = newsize;
objectsize = min(objectsize, newsize);
}
void resize(unsigned newsize) {
if(newsize > poolsize) reserve(newsize);
for(unsigned i = newsize; i < objectsize; i++) {
if(pool[i]) { delete pool[i]; pool[i] = 0; }
}
objectsize = newsize;
}
void append(const T data) {
if(objectsize + 1 > poolsize) reserve(objectsize + 1);
pool[objectsize++] = new T(data);
}
template<typename U> void insert(unsigned index, const U list) {
pointer_vector<T> merged;
for(unsigned i = 0; i < index; i++) merged.append(*pool[i]);
foreach(item, list) merged.append(item);
for(unsigned i = index; i < objectsize; i++) merged.append(*pool[i]);
operator=(merged);
}
void insert(unsigned index, const T item) {
insert(index, pointer_vector<T>{ item });
}
void remove(unsigned index, unsigned count = 1) {
for(unsigned i = index; count + i < objectsize; i++) {
*pool[i] = *pool[count + i];
}
if(count + index >= objectsize) resize(index); //every element >= index was removed
else resize(objectsize - count);
}
pointer_vector() : pool(0), poolsize(0), objectsize(0) {
}
pointer_vector(std::initializer_list<T> list) : pool(0), poolsize(0), objectsize(0) {
for(const T *p = list.begin(); p != list.end(); ++p) append(*p);
}
~pointer_vector() {
reset();
}
//copy
inline pointer_vector<T>& operator=(const pointer_vector<T> &source) {
reset();
reserve(source.capacity());
resize(source.size());
for(unsigned i = 0; i < source.size(); i++) operator[](i) = source.operator[](i);
return *this;
}
pointer_vector(const pointer_vector<T> &source) : pool(0), poolsize(0), objectsize(0) {
operator=(source);
}
//move
inline pointer_vector<T>& operator=(pointer_vector<T> &&source) {
reset();
pool = source.pool;
poolsize = source.poolsize;
objectsize = source.objectsize;
source.pool = 0;
source.reset();
return *this;
}
pointer_vector(pointer_vector<T> &&source) : pool(0), poolsize(0), objectsize(0) {
operator=(std::move(source));
}
//index
inline T& operator[](unsigned index) {
if(index >= objectsize) resize(index + 1);
if(!pool[index]) pool[index] = new T;
return *pool[index];
}
inline const T& operator[](unsigned index) const {
if(index >= objectsize || !pool[index]) throw "vector[] out of bounds";
return *pool[index];
}
//iteration
struct iterator {
bool operator!=(const iterator &source) const { return index != source.index; }
T& operator*() { return vector.operator[](index); }
iterator& operator++() { index++; return *this; }
iterator(pointer_vector &vector, unsigned index) : vector(vector), index(index) {}
private:
pointer_vector &vector;
unsigned index;
};
iterator begin() { return iterator(*this, 0); }
iterator end() { return iterator(*this, objectsize); }
};
template<typename T> struct has_size<linear_vector<T>> { enum { value = true }; };
template<typename T> struct has_size<pointer_vector<T>> { enum { value = true }; };
}
#endif
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