Eigen/src/SparseCore/CompressedStorage.h - eigen - Git at Google

 // This file is part of Eigen, a lightweight C++ template library
 // for linear algebra.
 //
 // Copyright (C) 2008-2014 Gael Guennebaud <gael.guennebaud@inria.fr>
 //
 // 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 http://mozilla.org/MPL/2.0/.

 #ifndef EIGEN_COMPRESSED_STORAGE_H
 #define EIGEN_COMPRESSED_STORAGE_H

 // IWYU pragma: private
 #include "./InternalHeaderCheck.h"

 namespace Eigen {

 namespace internal {

 /** \internal
  * Stores a sparse set of values as a list of values and a list of indices.
  *
  */
 template <typename Scalar_, typename StorageIndex_>
 class CompressedStorage {
  public:
   typedef Scalar_ Scalar;
   typedef StorageIndex_ StorageIndex;

  protected:
   typedef typename NumTraits<Scalar>::Real RealScalar;

  public:
   CompressedStorage() : m_values(0), m_indices(0), m_size(0), m_allocatedSize(0) {}

   explicit CompressedStorage(Index size) : m_values(0), m_indices(0), m_size(0), m_allocatedSize(0) { resize(size); }

   CompressedStorage(const CompressedStorage& other) : m_values(0), m_indices(0), m_size(0), m_allocatedSize(0) {
     *this = other;
   }

   CompressedStorage& operator=(const CompressedStorage& other) {
     resize(other.size());
     if (other.size() > 0) {
       internal::smart_copy(other.m_values, other.m_values + m_size, m_values);
       internal::smart_copy(other.m_indices, other.m_indices + m_size, m_indices);
     }
     return *this;
   }

   void swap(CompressedStorage& other) {
     std::swap(m_values, other.m_values);
     std::swap(m_indices, other.m_indices);
     std::swap(m_size, other.m_size);
     std::swap(m_allocatedSize, other.m_allocatedSize);
   }

   ~CompressedStorage() {
     conditional_aligned_delete_auto<Scalar, true>(m_values, m_allocatedSize);
     conditional_aligned_delete_auto<StorageIndex, true>(m_indices, m_allocatedSize);
   }

   void reserve(Index size) {
     Index newAllocatedSize = m_size + size;
     if (newAllocatedSize > m_allocatedSize) reallocate(newAllocatedSize);
   }

   void squeeze() {
     if (m_allocatedSize > m_size) reallocate(m_size);
   }

   void resize(Index size, double reserveSizeFactor = 0) {
     if (m_allocatedSize < size) {
       // Avoid underflow on the std::min<Index> call by choosing the smaller index type.
       using SmallerIndexType =
           typename std::conditional<static_cast<size_t>((std::numeric_limits<Index>::max)()) <
                                         static_cast<size_t>((std::numeric_limits<StorageIndex>::max)()),
                                     Index, StorageIndex>::type;
       Index realloc_size =
           (std::min<Index>)(NumTraits<SmallerIndexType>::highest(), size + Index(reserveSizeFactor * double(size)));
       if (realloc_size < size) internal::throw_std_bad_alloc();
       reallocate(realloc_size);
     }
     m_size = size;
   }

   void append(const Scalar& v, Index i) {
     Index id = m_size;
     resize(m_size + 1, 1);
     m_values[id] = v;
     m_indices[id] = internal::convert_index<StorageIndex>(i);
   }

   inline Index size() const { return m_size; }
   inline Index allocatedSize() const { return m_allocatedSize; }
   inline void clear() { m_size = 0; }

   const Scalar* valuePtr() const { return m_values; }
   Scalar* valuePtr() { return m_values; }
   const StorageIndex* indexPtr() const { return m_indices; }
   StorageIndex* indexPtr() { return m_indices; }

   inline Scalar& value(Index i) {
     eigen_internal_assert(m_values != 0);
     return m_values[i];
   }
   inline const Scalar& value(Index i) const {
     eigen_internal_assert(m_values != 0);
     return m_values[i];
   }

   inline StorageIndex& index(Index i) {
     eigen_internal_assert(m_indices != 0);
     return m_indices[i];
   }
   inline const StorageIndex& index(Index i) const {
     eigen_internal_assert(m_indices != 0);
     return m_indices[i];
   }

   /** \returns the largest \c k such that for all \c j in [0,k) index[\c j]\<\a key */
   inline Index searchLowerIndex(Index key) const { return searchLowerIndex(0, m_size, key); }

   /** \returns the largest \c k in [start,end) such that for all \c j in [start,k) index[\c j]\<\a key */
   inline Index searchLowerIndex(Index start, Index end, Index key) const {
     return static_cast<Index>(std::distance(m_indices, std::lower_bound(m_indices + start, m_indices + end, key)));
   }

   /** \returns the stored value at index \a key
    * If the value does not exist, then the value \a defaultValue is returned without any insertion. */
   inline Scalar at(Index key, const Scalar& defaultValue = Scalar(0)) const {
     if (m_size == 0)
       return defaultValue;
     else if (key == m_indices[m_size - 1])
       return m_values[m_size - 1];
     // ^^  optimization: let's first check if it is the last coefficient
     // (very common in high level algorithms)
     const Index id = searchLowerIndex(0, m_size - 1, key);
     return ((id < m_size) && (m_indices[id] == key)) ? m_values[id] : defaultValue;
   }

   /** Like at(), but the search is performed in the range [start,end) */
   inline Scalar atInRange(Index start, Index end, Index key, const Scalar& defaultValue = Scalar(0)) const {
     if (start >= end)
       return defaultValue;
     else if (end > start && key == m_indices[end - 1])
       return m_values[end - 1];
     // ^^  optimization: let's first check if it is the last coefficient
     // (very common in high level algorithms)
     const Index id = searchLowerIndex(start, end - 1, key);
     return ((id < end) && (m_indices[id] == key)) ? m_values[id] : defaultValue;
   }

   /** \returns a reference to the value at index \a key
    * If the value does not exist, then the value \a defaultValue is inserted
    * such that the keys are sorted. */
   inline Scalar& atWithInsertion(Index key, const Scalar& defaultValue = Scalar(0)) {
     Index id = searchLowerIndex(0, m_size, key);
     if (id >= m_size || m_indices[id] != key) {
       if (m_allocatedSize < m_size + 1) {
         Index newAllocatedSize = 2 * (m_size + 1);
         m_values = conditional_aligned_realloc_new_auto<Scalar, true>(m_values, newAllocatedSize, m_allocatedSize);
         m_indices =
             conditional_aligned_realloc_new_auto<StorageIndex, true>(m_indices, newAllocatedSize, m_allocatedSize);
         m_allocatedSize = newAllocatedSize;
       }
       if (m_size > id) {
         internal::smart_memmove(m_values + id, m_values + m_size, m_values + id + 1);
         internal::smart_memmove(m_indices + id, m_indices + m_size, m_indices + id + 1);
       }
       m_size++;
       m_indices[id] = internal::convert_index<StorageIndex>(key);
       m_values[id] = defaultValue;
     }
     return m_values[id];
   }

   inline void moveChunk(Index from, Index to, Index chunkSize) {
     eigen_internal_assert(chunkSize >= 0 && to + chunkSize <= m_size);
     internal::smart_memmove(m_values + from, m_values + from + chunkSize, m_values + to);
     internal::smart_memmove(m_indices + from, m_indices + from + chunkSize, m_indices + to);
   }

  protected:
   inline void reallocate(Index size) {
 #ifdef EIGEN_SPARSE_COMPRESSED_STORAGE_REALLOCATE_PLUGIN
     EIGEN_SPARSE_COMPRESSED_STORAGE_REALLOCATE_PLUGIN
 #endif
     eigen_internal_assert(size != m_allocatedSize);
     m_values = conditional_aligned_realloc_new_auto<Scalar, true>(m_values, size, m_allocatedSize);
     m_indices = conditional_aligned_realloc_new_auto<StorageIndex, true>(m_indices, size, m_allocatedSize);
     m_allocatedSize = size;
   }

  protected:
   Scalar* m_values;
   StorageIndex* m_indices;
   Index m_size;
   Index m_allocatedSize;
 };

 }  // end namespace internal

 }  // end namespace Eigen

 #endif  // EIGEN_COMPRESSED_STORAGE_H
	// This file is part of Eigen, a lightweight C++ template library
	// for linear algebra.
	//
	// Copyright (C) 2008-2014 Gael Guennebaud <gael.guennebaud@inria.fr>
	//
	// 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 http://mozilla.org/MPL/2.0/.

	#ifndef EIGEN_COMPRESSED_STORAGE_H
	#define EIGEN_COMPRESSED_STORAGE_H

	// IWYU pragma: private
	#include "./InternalHeaderCheck.h"

	namespace Eigen {

	namespace internal {

	/** \internal
	* Stores a sparse set of values as a list of values and a list of indices.
	*
	*/
	template <typename Scalar_, typename StorageIndex_>
	class CompressedStorage {
	public:
	typedef Scalar_ Scalar;
	typedef StorageIndex_ StorageIndex;

	protected:
	typedef typename NumTraits<Scalar>::Real RealScalar;

	public:
	CompressedStorage() : m_values(0), m_indices(0), m_size(0), m_allocatedSize(0) {}

	explicit CompressedStorage(Index size) : m_values(0), m_indices(0), m_size(0), m_allocatedSize(0) { resize(size); }

	CompressedStorage(const CompressedStorage& other) : m_values(0), m_indices(0), m_size(0), m_allocatedSize(0) {
	*this = other;
	}

	CompressedStorage& operator=(const CompressedStorage& other) {
	resize(other.size());
	if (other.size() > 0) {
	internal::smart_copy(other.m_values, other.m_values + m_size, m_values);
	internal::smart_copy(other.m_indices, other.m_indices + m_size, m_indices);
	}
	return *this;
	}

	void swap(CompressedStorage& other) {
	std::swap(m_values, other.m_values);
	std::swap(m_indices, other.m_indices);
	std::swap(m_size, other.m_size);
	std::swap(m_allocatedSize, other.m_allocatedSize);
	}

	~CompressedStorage() {
	conditional_aligned_delete_auto<Scalar, true>(m_values, m_allocatedSize);
	conditional_aligned_delete_auto<StorageIndex, true>(m_indices, m_allocatedSize);
	}

	void reserve(Index size) {
	Index newAllocatedSize = m_size + size;
	if (newAllocatedSize > m_allocatedSize) reallocate(newAllocatedSize);
	}

	void squeeze() {
	if (m_allocatedSize > m_size) reallocate(m_size);
	}

	void resize(Index size, double reserveSizeFactor = 0) {
	if (m_allocatedSize < size) {
	// Avoid underflow on the std::min<Index> call by choosing the smaller index type.
	using SmallerIndexType =
	typename std::conditional<static_cast<size_t>((std::numeric_limits<Index>::max)()) <
	static_cast<size_t>((std::numeric_limits<StorageIndex>::max)()),
	Index, StorageIndex>::type;
	Index realloc_size =
	(std::min<Index>)(NumTraits<SmallerIndexType>::highest(), size + Index(reserveSizeFactor * double(size)));
	if (realloc_size < size) internal::throw_std_bad_alloc();
	reallocate(realloc_size);
	}
	m_size = size;
	}

	void append(const Scalar& v, Index i) {
	Index id = m_size;
	resize(m_size + 1, 1);
	m_values[id] = v;
	m_indices[id] = internal::convert_index<StorageIndex>(i);
	}

	inline Index size() const { return m_size; }
	inline Index allocatedSize() const { return m_allocatedSize; }
	inline void clear() { m_size = 0; }

	const Scalar* valuePtr() const { return m_values; }
	Scalar* valuePtr() { return m_values; }
	const StorageIndex* indexPtr() const { return m_indices; }
	StorageIndex* indexPtr() { return m_indices; }

	inline Scalar& value(Index i) {
	eigen_internal_assert(m_values != 0);
	return m_values[i];
	}
	inline const Scalar& value(Index i) const {
	eigen_internal_assert(m_values != 0);
	return m_values[i];
	}

	inline StorageIndex& index(Index i) {
	eigen_internal_assert(m_indices != 0);
	return m_indices[i];
	}
	inline const StorageIndex& index(Index i) const {
	eigen_internal_assert(m_indices != 0);
	return m_indices[i];
	}

	/** \returns the largest \c k such that for all \c j in [0,k) index[\c j]\<\a key */
	inline Index searchLowerIndex(Index key) const { return searchLowerIndex(0, m_size, key); }

	/** \returns the largest \c k in [start,end) such that for all \c j in [start,k) index[\c j]\<\a key */
	inline Index searchLowerIndex(Index start, Index end, Index key) const {
	return static_cast<Index>(std::distance(m_indices, std::lower_bound(m_indices + start, m_indices + end, key)));
	}

	/** \returns the stored value at index \a key
	* If the value does not exist, then the value \a defaultValue is returned without any insertion. */
	inline Scalar at(Index key, const Scalar& defaultValue = Scalar(0)) const {
	if (m_size == 0)
	return defaultValue;
	else if (key == m_indices[m_size - 1])
	return m_values[m_size - 1];
	// ^^ optimization: let's first check if it is the last coefficient
	// (very common in high level algorithms)
	const Index id = searchLowerIndex(0, m_size - 1, key);
	return ((id < m_size) && (m_indices[id] == key)) ? m_values[id] : defaultValue;
	}

	/** Like at(), but the search is performed in the range [start,end) */
	inline Scalar atInRange(Index start, Index end, Index key, const Scalar& defaultValue = Scalar(0)) const {
	if (start >= end)
	return defaultValue;
	else if (end > start && key == m_indices[end - 1])
	return m_values[end - 1];
	// ^^ optimization: let's first check if it is the last coefficient
	// (very common in high level algorithms)
	const Index id = searchLowerIndex(start, end - 1, key);
	return ((id < end) && (m_indices[id] == key)) ? m_values[id] : defaultValue;
	}

	/** \returns a reference to the value at index \a key
	* If the value does not exist, then the value \a defaultValue is inserted
	* such that the keys are sorted. */
	inline Scalar& atWithInsertion(Index key, const Scalar& defaultValue = Scalar(0)) {
	Index id = searchLowerIndex(0, m_size, key);
	if (id >= m_size \|\| m_indices[id] != key) {
	if (m_allocatedSize < m_size + 1) {
	Index newAllocatedSize = 2 * (m_size + 1);
	m_values = conditional_aligned_realloc_new_auto<Scalar, true>(m_values, newAllocatedSize, m_allocatedSize);
	m_indices =
	conditional_aligned_realloc_new_auto<StorageIndex, true>(m_indices, newAllocatedSize, m_allocatedSize);
	m_allocatedSize = newAllocatedSize;
	}
	if (m_size > id) {
	internal::smart_memmove(m_values + id, m_values + m_size, m_values + id + 1);
	internal::smart_memmove(m_indices + id, m_indices + m_size, m_indices + id + 1);
	}
	m_size++;
	m_indices[id] = internal::convert_index<StorageIndex>(key);
	m_values[id] = defaultValue;
	}
	return m_values[id];
	}

	inline void moveChunk(Index from, Index to, Index chunkSize) {
	eigen_internal_assert(chunkSize >= 0 && to + chunkSize <= m_size);
	internal::smart_memmove(m_values + from, m_values + from + chunkSize, m_values + to);
	internal::smart_memmove(m_indices + from, m_indices + from + chunkSize, m_indices + to);
	}

	protected:
	inline void reallocate(Index size) {
	#ifdef EIGEN_SPARSE_COMPRESSED_STORAGE_REALLOCATE_PLUGIN
	EIGEN_SPARSE_COMPRESSED_STORAGE_REALLOCATE_PLUGIN
	#endif
	eigen_internal_assert(size != m_allocatedSize);
	m_values = conditional_aligned_realloc_new_auto<Scalar, true>(m_values, size, m_allocatedSize);
	m_indices = conditional_aligned_realloc_new_auto<StorageIndex, true>(m_indices, size, m_allocatedSize);
	m_allocatedSize = size;
	}

	protected:
	Scalar* m_values;
	StorageIndex* m_indices;
	Index m_size;
	Index m_allocatedSize;
	};

	} // end namespace internal

	} // end namespace Eigen

	#endif // EIGEN_COMPRESSED_STORAGE_H