citra/src/common/fifo_queue.h

115 lines
2.2 KiB
C++

#ifndef _FIFO_QUEUE_H_
#define _FIFO_QUEUE_H_
// a simple lockless thread-safe,
// single reader, single writer queue
#include "common/atomic.h"
namespace Common
{
template <typename T>
class FifoQueue
{
public:
FifoQueue() : m_size(0)
{
m_write_ptr = m_read_ptr = new ElementPtr();
}
~FifoQueue()
{
// this will empty out the whole queue
delete m_read_ptr;
}
u32 Size() const
{
return m_size;
}
bool Empty() const
{
//return (m_read_ptr == m_write_ptr);
return (0 == m_size);
}
T& Front() const
{
return *m_read_ptr->current;
}
template <typename Arg>
void Push(Arg&& t)
{
// create the element, add it to the queue
m_write_ptr->current = new T(std::forward<Arg>(t));
// set the next pointer to a new element ptr
// then advance the write pointer
m_write_ptr = m_write_ptr->next = new ElementPtr();
Common::AtomicIncrement(m_size);
}
void Pop()
{
Common::AtomicDecrement(m_size);
ElementPtr *const tmpptr = m_read_ptr;
// advance the read pointer
m_read_ptr = m_read_ptr->next;
// set the next element to NULL to stop the recursive deletion
tmpptr->next = NULL;
delete tmpptr; // this also deletes the element
}
bool Pop(T& t)
{
if (Empty())
return false;
t = std::move(Front());
Pop();
return true;
}
// not thread-safe
void Clear()
{
m_size = 0;
delete m_read_ptr;
m_write_ptr = m_read_ptr = new ElementPtr();
}
private:
// stores a pointer to element
// and a pointer to the next ElementPtr
class ElementPtr
{
public:
ElementPtr() : current(NULL), next(NULL) {}
~ElementPtr()
{
if (current)
{
delete current;
// recusion ftw
if (next)
delete next;
}
}
T *volatile current;
ElementPtr *volatile next;
};
ElementPtr *volatile m_write_ptr;
ElementPtr *volatile m_read_ptr;
volatile u32 m_size;
};
}
#endif