OpenVulkano/openVulkanoCpp/Data/Containers/RingBuffer.hpp

/*
 * This Source Code Form is subject to the terms of the Mozilla Public
 * License, v. 2.0. If a copy of the MPL was not distributed with this
 * file, You can obtain one at https://mozilla.org/MPL/2.0/.
 */

#pragma once

#include "Base/Utils.hpp"
#include <algorithm>
#include <cstddef>
#include <stdexcept>
#include <optional>

namespace OpenVulkano
{
	namespace internal_detail
	{
		/**
		 * \internal
		 * This class is not intended for public use. Use RingBuffer<T> instead.
		 */
		template<typename T, class IMPL>
		class NPCRingBufferBase
		{
		protected:
			size_t count = 0, head = 0;
			
			~NPCRingBufferBase() { assert(count == 0); }

			[[nodiscard]] size_t HeadId() const { return head; }
		private:
			[[nodiscard]] IMPL& Impl() { return *static_cast<IMPL*>(this); }
			[[nodiscard]] const IMPL& Impl() const { return *static_cast<const IMPL*>(this); }
		
			//region Iterators
		private:
			template<bool IsConst>
			class ForwardIteratorBase
			{
				using BufferType = std::conditional_t<IsConst, const NPCRingBufferBase, NPCRingBufferBase>;
				using ValueType = std::conditional_t<IsConst, const T, T>;

				BufferType* buffer;
				size_t index;
				int64_t remainder;

			public:
				using iterator_category = std::bidirectional_iterator_tag;
				using value_type        = T;
				using difference_type   = std::ptrdiff_t;
				using pointer           = ValueType*;
				using reference         = ValueType&;

				ForwardIteratorBase(BufferType* buf, size_t startIdx, int64_t remainder)
					: buffer(buf), index(startIdx), remainder(remainder) {}

				reference operator*() const { return buffer->data()[index]; }
				pointer operator->() const { return &buffer->data()[index]; }

				ForwardIteratorBase& operator++()
				{
					if (remainder > 1)
					{
						if (index == buffer->capacity() - 1)
							index = 0;
						else
							++index;
					}
					remainder--;
					return *this;
				}

				ForwardIteratorBase operator++(int)
				{
					ForwardIteratorBase tmp = *this;
					++(*this);
					return tmp;
				}

				ForwardIteratorBase& operator--()
				{
					if (remainder == 0) { remainder++; return *this; }
					if (index == 0)
						index = buffer->capacity() - 1;
					else
						--index;
					remainder++;
					return *this;
				}

				ForwardIteratorBase operator--(int)
				{
					ForwardIteratorBase tmp = *this;
					--(*this);
					return tmp;
				}

				friend bool operator==(const ForwardIteratorBase& a, const ForwardIteratorBase& b)
				{
					return a.buffer == b.buffer && a.index == b.index && a.remainder == b.remainder;
				}

				friend bool operator!=(const ForwardIteratorBase& a, const ForwardIteratorBase& b)
				{
					return !(a == b);
				}
			};
			
			template<bool IsConst>
			class ReverseIteratorBase
			{
				using BufferType = std::conditional_t<IsConst, const NPCRingBufferBase, NPCRingBufferBase>;
				using ValueType = std::conditional_t<IsConst, const T, T>;

				BufferType* buffer;
				size_t index;
				int64_t remainder;

			public:
				using iterator_category = std::bidirectional_iterator_tag;
				using value_type        = T;
				using difference_type   = std::ptrdiff_t;
				using pointer           = ValueType*;
				using reference         = ValueType&;

				ReverseIteratorBase(BufferType* buf, size_t startIdx, int64_t remainder)
					: buffer(buf), index(startIdx), remainder(remainder) {}

				reference operator*() const { return buffer->data()[index]; }
				pointer operator->() const { return &buffer->data()[index]; }

				ReverseIteratorBase& operator++()
				{
					if (remainder > 1)
					{
						if (index == 0)
							index = buffer->capacity() - 1;
						else
							--index;
					}
					remainder--;
					return *this;
				}

				ReverseIteratorBase operator++(int)
				{
					ReverseIteratorBase tmp = *this;
					++(*this);
					return tmp;
				}

				ReverseIteratorBase& operator--()
				{
					if (remainder == 0) { remainder++; return *this; }
					if (index == buffer->capacity() - 1)
						index = 0;
					else
						++index;
					remainder++;
					return *this;
				}

				ReverseIteratorBase operator--(int)
				{
					ReverseIteratorBase tmp = *this;
					--(*this);
					return tmp;
				}

				friend bool operator==(const ReverseIteratorBase& a, const ReverseIteratorBase& b)
				{
					return a.buffer == b.buffer && a.index == b.index && a.remainder == b.remainder;
				}

				friend bool operator!=(const ReverseIteratorBase& a, const ReverseIteratorBase& b)
				{
					return !(a == b);
				}
			};
			
		public:
			using iterator = ForwardIteratorBase<false>;
			using const_iterator = ForwardIteratorBase<true>;
	
			iterator begin() { return iterator(this, Impl().TailId(), count); }
			iterator end() { return iterator(this, HeadId(), 0); }
	
			const_iterator begin() const { return cbegin(); }
			const_iterator end() const { return cend(); }
	
			const_iterator cbegin() const { return const_iterator(this, Impl().TailId(), count); }
			const_iterator cend() const { return const_iterator(this, HeadId(), 0); }
			
			using reverse_iterator = ReverseIteratorBase<false>;
			using const_reverse_iterator = ReverseIteratorBase<true>;
			
			reverse_iterator rbegin() { return reverse_iterator(this, HeadId(), count); }
			reverse_iterator rend() { return reverse_iterator(this, Impl().TailId(), 0); }
			
			const_reverse_iterator rbegin() const { return crbegin(); }
			const_reverse_iterator rend() const { return crend(); }
			
			const_reverse_iterator crbegin() const { return const_reverse_iterator(this, HeadId(), count); }
			const_reverse_iterator crend() const { return const_reverse_iterator(this, Impl().TailId(), 0); }
			//endregion
		
		public:
			[[nodiscard]] size_t capacity() const { return Impl().Capacity(); }
			[[nodiscard]] T* data() { return Impl().Data(); }
			[[nodiscard]] const T* data() const { return Impl().Data(); }
			
		public:
			[[nodiscard]] size_t Count() const { return count; }
			[[nodiscard]] size_t Size() const { return count; }
			[[nodiscard]] bool IsEmpty() const { return count == 0; }
			[[nodiscard]] bool HasFree() const { return Count() != capacity(); }
			
			T PopFront()
			{
				if (IsEmpty()) throw std::underflow_error("RingBuffer is empty");
				
				T value = std::move(data()[head]);
				data()[head].~T();
				if (head == 0) head = capacity() - 1;
				else head--;
				count--;
				return value;
			}
			
			T PopBack()
			{
				if (IsEmpty()) throw std::underflow_error("RingBuffer is empty");
				size_t tail = Impl().TailId();
				T value = std::move(data()[tail]);
				data()[tail].~T();
				count--;
				return value;
			}
			
			void Clear()
			{
				while(count)
				{
					data()[head].~T();
					if (head == 0) head = capacity() - 1;
					else head--;
					count--;
				}
			}
			
			[[nodiscard]] T& Back() { return data()[Impl().TailId()]; }
			[[nodiscard]] const T& Back() const { return data()[Impl().TailId()]; }
			
			[[nodiscard]] T& Front() { return data()[head]; }
			[[nodiscard]] const T& Front() const { return data()[head]; }
			
			//region Insertion
			void PushNoOverwrite(const T& value) { if (!HasFree()) throw std::overflow_error("RingBuffer is full"); Push(value); }
			void PushNoOverwrite(T&& value) { if (!HasFree()) throw std::overflow_error("RingBuffer is full"); Push(std::move(value)); }
			template<typename... Args>
			void EmplaceNoOverwrite(Args&&... args)
			{
				if (!HasFree()) throw std::overflow_error("RingBuffer is full");
				Emplace(std::forward<Args...>(args...));
			}
			
			void Push(const T& value)
			{
				Impl().IncrementHead();
				if (HasFree()) count++;
				else data()[head].~T();
				new (&data()[head]) T(value);
			}

			void Push(T&& value)
			{
				Impl().IncrementHead();
				if (HasFree()) count++;
				else data()[head].~T();
				new (&data()[head]) T(std::move(value));
			}

			template<typename... Args>
			void Emplace(Args&&... args)
			{
				Impl().IncrementHead();
				if (HasFree()) count++;
				else data()[head].~T();
				new (&data()[head]) T(std::forward<Args>(args)...);
			}
			
			[[nodiscard]] std::optional<T> PushFront(const T& value)
			{
				if (HasFree())
				{
					count++;
					Impl().IncrementHead();
					new (&data()[head]) T(value);
					return std::nullopt;
				}
				Impl().IncrementHead();
				std::optional<T> oldData(std::move(Front()));
				data()[head].~T();
				new (&data()[head]) T(value);
				return oldData;
			}

			[[nodiscard]] std::optional<T> PushFront(T&& value)
			{
				if (HasFree())
				{
					count++;
					Impl().IncrementHead();
					new (&data()[head]) T(std::move(value));
					return std::nullopt;
				}
				Impl().IncrementHead();
				std::optional<T> oldData(std::move(Front()));
				data()[head].~T();
				new (&data()[head]) T(std::move(value));
				return oldData;
			}

			template<typename... Args>
			[[nodiscard]] std::optional<T> EmplaceFront(Args&&... args)
			{
				if (HasFree())
				{
					count++;
					Impl().IncrementHead();
					new (&data()[head]) T(std::forward<Args>(args)...);
					return std::nullopt;
				}
				Impl().IncrementHead();
				std::optional<T> oldData(std::move(Front()));
				data()[head].~T();
				new (&data()[head]) T(std::forward<Args>(args)...);
				return oldData;
			}
			
			std::optional<T> PushBack(const T& value)
			{
				if (HasFree())
				{
					count++;
					new (&data()[Impl().TailId()]) T(value);
					return std::nullopt;
				}
				size_t tail = Impl().TailId();
				std::optional<T> oldData(std::move(data()[tail]));
				data()[tail].~T();
				new (&data()[tail]) T(value);
				return oldData;
			}

			std::optional<T> PushBack(T&& value)
			{
				if (HasFree())
				{
					count++;
					new (&data()[Impl().TailId()]) T(std::move(value));
					return std::nullopt;
				}
				size_t tail = Impl().TailId();
				std::optional<T> oldData(std::move(data()[tail]));
				data()[tail].~T();
				new (&data()[tail]) T(std::move(value));
				return oldData;
			}

			template<typename... Args>
			std::optional<T> EmplaceBack(Args&&... args)
			{
				if (HasFree())
				{
					count++;
					new (&data()[Impl().TailId()]) T(std::forward<Args>(args)...);
					return std::nullopt;
				}
				size_t tail = Impl().TailId();
				std::optional<T> oldData(std::move(data()[tail]));
				data()[tail].~T();
				new (&data()[tail]) T(std::forward<Args>(args)...);
				return oldData;
			}
			
			T PushAndOverwrite(const T& value)
			{
				if (HasFree()) [[unlikely]] throw std::runtime_error("Can't overwrite data because there are still empty slots.");
				Impl().IncrementHead();
				T oldData(std::move(Front()));
				data()[head].~T();
				new (&data()[head]) T(value);
				return oldData;
			}
			
			T PushAndOverwrite(T&& value)
			{
				if (HasFree()) [[unlikely]] throw std::runtime_error("Can't overwrite data because there are still empty slots.");
				Impl().IncrementHead();
				T oldData(std::move(Front()));
				data()[head].~T();
				new (&data()[head]) T(std::move(value));
				return oldData;
			}
			
			template<typename... Args>
			T PushAndOverwrite(Args&&... args)
			{
				if (HasFree()) [[unlikely]] throw std::runtime_error("Can't overwrite data because there are still empty slots.");
				Impl().IncrementHead();
				T oldData(std::move(Front()));
				data()[head].~T();
				new (&data()[head]) T(std::forward<Args>(args)...);
				return oldData;
			}
			//endregion
			
			[[nodiscard]] T& at(size_t idx) { if (idx >= Size()) throw std::range_error("Out of bounds"); return (*this)[idx]; }
			[[nodiscard]] const T& at(size_t idx) const { if (idx >= Size()) throw std::range_error("Out of bounds"); return (*this)[idx]; }
			
			[[nodiscard]] T& operator[](size_t idx)
			{
				return data()[Impl().Index(idx)];
			}
			
			[[nodiscard]] const T& operator[](size_t idx) const
			{
				return data()[Impl().Index(idx)];
			}
			
			void Fill(const T& value)
			{
				while(HasFree()) { Push(value); }
			}
		};
	}
	
	template<typename T, size_t SIZE = std::numeric_limits<size_t>::max()>
	class RingBuffer;
	
	template<typename T>
	class RingBuffer<T, std::numeric_limits<size_t>::max()> final : public internal_detail::NPCRingBufferBase<T, RingBuffer<T, std::numeric_limits<size_t>::max()>>
	{
		typedef internal_detail::NPCRingBufferBase<T, RingBuffer<T, std::numeric_limits<size_t>::max()>> Parent;
		friend Parent;
		
		struct RawFreeDeleter { void operator()(void* ptr) const { ::operator delete(ptr); } };
		
		std::unique_ptr<T, RawFreeDeleter> m_data;
		size_t m_capacity;
		
		[[nodiscard]] size_t TailId() const
		{
			if (Parent::IsEmpty()) [[unlikely]] return Parent::head;
			return (Parent::HeadId() + 1 + Capacity() - Parent::Count()) % Capacity();
		}

		[[nodiscard]] size_t IncrementHead()
		{
			if (Parent::IsEmpty()) [[unlikely]] return Parent::head;
			return (Parent::head = (Parent::HeadId() + 1) % Capacity());
		}

		[[nodiscard]] size_t Index(size_t i) const { return (TailId() + i) % Capacity(); }
	public:
		RingBuffer(const size_t size = 10): m_data(static_cast<T*>(::operator new(sizeof(T) * size))), m_capacity(size) {}
		
		~RingBuffer() { Parent::Clear(); }
		
		[[nodiscard]] size_t Capacity() const { return m_capacity; }
		[[nodiscard]] T* Data() { return m_data.get(); }
		[[nodiscard]] const T* Data() const { return m_data.get(); }
	};
	
	template<typename T, size_t SIZE>
	class RingBuffer final : public internal_detail::NPCRingBufferBase<T, RingBuffer<T, SIZE>>
	{
		typedef internal_detail::NPCRingBufferBase<T, RingBuffer<T, SIZE>> Parent;
		friend Parent;
		constexpr static bool POW2 = (Utils::IsPow2(SIZE) && SIZE > 0);
		constexpr static size_t MASK = SIZE - 1;
		
		using StorageType = typename std::aligned_storage<sizeof(T), alignof(T)>::type;
		StorageType m_data[SIZE]; // Uninitialized raw storage
		
		[[nodiscard]] size_t Index(size_t i) const
		{
			if constexpr (POW2)
				return (Parent::HeadId() - (Parent::Count() - 1) + i) & MASK;
			else
				return (TailId() + i) % Capacity();
		}
		
		[[nodiscard]] size_t TailId() const
		{
			if (Parent::IsEmpty()) [[unlikely]] return Parent::head;
			if constexpr (POW2)
				return (Parent::HeadId() - (Parent::Count() - 1)) & MASK;
			else
				return (Parent::HeadId() + 1 + Capacity() - Parent::Count()) % Capacity();
		}
		
		[[nodiscard]] size_t IncrementHead()
		{
			if (Parent::IsEmpty()) [[unlikely]] return Parent::head;
			if constexpr (POW2)
				return (Parent::head = (Parent::HeadId() + 1) & MASK);
			else
				return (Parent::head = (Parent::HeadId() + 1) % Capacity());
		}

	public:
		~RingBuffer() { Parent::Clear(); }
	
		[[nodiscard]] size_t Capacity() const { return SIZE; }
		[[nodiscard]] T* Data() { return reinterpret_cast<T*>(m_data); }
		[[nodiscard]] const T* Data() const { return reinterpret_cast<const T*>(m_data); }
	};
}