runtime/platform/growable_array.h - sdk.git - Git at Google

 // Copyright (c) 2017, the Dart project authors.  Please see the AUTHORS file
 // for details. All rights reserved. Use of this source code is governed by a
 // BSD-style license that can be found in the LICENSE file.
 // Defines growable array classes, that differ where they are allocated:
 // - GrowableArray: allocated on stack.
 // - ZoneGrowableArray: allocated in the zone.
 // - MallocGrowableArray: allocates using malloc/realloc; free is only called
 //   at destruction.

 #ifndef RUNTIME_PLATFORM_GROWABLE_ARRAY_H_
 #define RUNTIME_PLATFORM_GROWABLE_ARRAY_H_

 #include "platform/allocation.h"
 #include "platform/utils.h"

 namespace dart {

 template <typename T, typename B, typename Allocator>
 class BaseGrowableArray : public B {
  public:
   explicit BaseGrowableArray(Allocator* allocator)
       : length_(0), capacity_(0), data_(NULL), allocator_(allocator) {}

   BaseGrowableArray(intptr_t initial_capacity, Allocator* allocator)
       : length_(0), capacity_(0), data_(NULL), allocator_(allocator) {
     if (initial_capacity > 0) {
       capacity_ = Utils::RoundUpToPowerOfTwo(initial_capacity);
       data_ = allocator_->template Alloc<T>(capacity_);
     }
   }

   BaseGrowableArray(BaseGrowableArray&& other)
       : length_(other.length_),
         capacity_(other.capacity_),
         data_(other.data_),
         allocator_(other.allocator_) {
     other.length_ = 0;
     other.capacity_ = 0;
     other.data_ = NULL;
   }

   ~BaseGrowableArray() { allocator_->template Free<T>(data_, capacity_); }

   BaseGrowableArray& operator=(BaseGrowableArray&& other) {
     intptr_t temp = other.length_;
     other.length_ = length_;
     length_ = temp;
     temp = other.capacity_;
     other.capacity_ = capacity_;
     capacity_ = temp;
     T* temp_data = other.data_;
     other.data_ = data_;
     data_ = temp_data;
     Allocator* temp_allocator = other.allocator_;
     other.allocator_ = allocator_;
     allocator_ = temp_allocator;
     return *this;
   }

   intptr_t length() const { return length_; }
   T* data() const { return data_; }
   bool is_empty() const { return length_ == 0; }

   void TruncateTo(intptr_t length) {
     ASSERT(length_ >= length);
     length_ = length;
   }

   inline bool Contains(const T& other,
                        bool isEqual(const T&, const T&) = nullptr) const {
     for (const auto& value : *this) {
       if (value == other) {
         // Value identity should imply isEqual.
         ASSERT(isEqual == nullptr || isEqual(value, other));
         return true;
       }
       if (isEqual != nullptr && isEqual(value, other)) {
         return true;
       }
     }
     return false;
   }

   void Add(const T& value) {
     Resize(length() + 1);
     Last() = value;
   }

   T& RemoveLast() {
     ASSERT(length_ > 0);
     T& result = operator[](length_ - 1);
     length_--;
     return result;
   }

   T& operator[](intptr_t index) const {
     ASSERT(0 <= index);
     ASSERT(index < length_);
     ASSERT(length_ <= capacity_);
     return data_[index];
   }

   void FillWith(const T& value, intptr_t start, intptr_t length) {
     ASSERT(start >= 0);
     ASSERT(length >= 0);
     ASSERT(start <= length_);

     Resize(start + length);
     for (intptr_t i = 0; i < length; ++i) {
       data_[start + i] = value;
     }
   }

   void EnsureLength(intptr_t new_length, const T& default_value) {
     const intptr_t old_length = length_;
     if (old_length < new_length) {
       Resize(new_length);
       for (intptr_t i = old_length; i < new_length; ++i) {
         (*this)[i] = default_value;
       }
     }
   }

   const T& At(intptr_t index) const { return operator[](index); }

   T& Last() const {
     ASSERT(length_ > 0);
     return operator[](length_ - 1);
   }

   void AddArray(const BaseGrowableArray<T, B, Allocator>& src) {
     for (intptr_t i = 0; i < src.length(); i++) {
       Add(src[i]);
     }
   }

   void Clear() { length_ = 0; }

   void InsertAt(intptr_t idx, const T& value) {
     Resize(length() + 1);
     for (intptr_t i = length_ - 2; i >= idx; i--) {
       data_[i + 1] = data_[i];
     }
     data_[idx] = value;
   }

   void Reverse() {
     for (intptr_t i = 0; i < length_ / 2; i++) {
       const intptr_t j = length_ - 1 - i;
       T temp = data_[i];
       data_[i] = data_[j];
       data_[j] = temp;
     }
   }

   // Swap entries |i| and |j|.
   void Swap(intptr_t i, intptr_t j) {
     ASSERT(i >= 0);
     ASSERT(j >= 0);
     ASSERT(i < length_);
     ASSERT(j < length_);
     T temp = data_[i];
     data_[i] = data_[j];
     data_[j] = temp;
   }

   // NOTE: Does not preserve array order.
   void RemoveAt(intptr_t i) {
     ASSERT(i >= 0);
     ASSERT(i < length_);
     intptr_t last = length_ - 1;
     if (i < last) {
       Swap(i, last);
     }
     RemoveLast();
   }

   // Preserves array order.
   void EraseAt(intptr_t idx) {
     ASSERT(idx >= 0);
     ASSERT(idx < length_);
     for (intptr_t i = idx; i < length_ - 1; i++) {
       data_[i] = data_[i + 1];
     }
     RemoveLast();
   }

   // The content is uninitialized after calling it.
   void SetLength(intptr_t new_length);

   // The content (if expanded) is uninitialized after calling it.
   // The backing store (if expanded) will grow with by a power-of-2.
   void Resize(intptr_t new_length);

   // Sort the array in place.
   inline void Sort(int compare(const T*, const T*));

   void StealBuffer(T** buffer, intptr_t* length) {
     *buffer = data_;
     *length = length_;
     data_ = NULL;
     length_ = 0;
     capacity_ = 0;
   }

   T* begin() { return &data_[0]; }
   const T* begin() const { return &data_[0]; }

   T* end() { return &data_[length_]; }
   const T* end() const { return &data_[length_]; }

  private:
   intptr_t length_;
   intptr_t capacity_;
   T* data_;
   Allocator* allocator_;  // Used to (re)allocate the array.

   DISALLOW_COPY_AND_ASSIGN(BaseGrowableArray);
 };

 template <typename T, typename B, typename Allocator>
 inline void BaseGrowableArray<T, B, Allocator>::Sort(int compare(const T*,
                                                                  const T*)) {
   // Avoid calling qsort with a null array.
   if (length_ == 0) return;

   typedef int (*CompareFunction)(const void*, const void*);
   qsort(data_, length_, sizeof(T), reinterpret_cast<CompareFunction>(compare));
 }

 template <typename T, typename B, typename Allocator>
 void BaseGrowableArray<T, B, Allocator>::Resize(intptr_t new_length) {
   if (new_length > capacity_) {
     intptr_t new_capacity = Utils::RoundUpToPowerOfTwo(new_length);
     T* new_data =
         allocator_->template Realloc<T>(data_, capacity_, new_capacity);
     ASSERT(new_data != NULL);
     data_ = new_data;
     capacity_ = new_capacity;
   }
   length_ = new_length;
 }

 template <typename T, typename B, typename Allocator>
 void BaseGrowableArray<T, B, Allocator>::SetLength(intptr_t new_length) {
   if (new_length > capacity_) {
     T* new_data = allocator_->template Alloc<T>(new_length);
     ASSERT(new_data != NULL);
     data_ = new_data;
     capacity_ = new_length;
   }
   length_ = new_length;
 }

 class Malloc : public AllStatic {
  public:
   template <class T>
   static inline T* Alloc(intptr_t len) {
     return reinterpret_cast<T*>(dart::malloc(len * sizeof(T)));
   }

   template <class T>
   static inline T* Realloc(T* old_array, intptr_t old_len, intptr_t new_len) {
     return reinterpret_cast<T*>(dart::realloc(old_array, new_len * sizeof(T)));
   }

   template <class T>
   static inline void Free(T* old_array, intptr_t old_len) {
     free(old_array);
   }
 };

 template <typename T>
 class MallocGrowableArray
     : public BaseGrowableArray<T, MallocAllocated, Malloc> {
  public:
   explicit MallocGrowableArray(intptr_t initial_capacity)
       : BaseGrowableArray<T, MallocAllocated, Malloc>(initial_capacity, NULL) {}
   MallocGrowableArray() : BaseGrowableArray<T, MallocAllocated, Malloc>(NULL) {}
 };

 }  // namespace dart

 #endif  // RUNTIME_PLATFORM_GROWABLE_ARRAY_H_
	// Copyright (c) 2017, the Dart project authors. Please see the AUTHORS file
	// for details. All rights reserved. Use of this source code is governed by a
	// BSD-style license that can be found in the LICENSE file.
	// Defines growable array classes, that differ where they are allocated:
	// - GrowableArray: allocated on stack.
	// - ZoneGrowableArray: allocated in the zone.
	// - MallocGrowableArray: allocates using malloc/realloc; free is only called
	// at destruction.

	#ifndef RUNTIME_PLATFORM_GROWABLE_ARRAY_H_
	#define RUNTIME_PLATFORM_GROWABLE_ARRAY_H_

	#include "platform/allocation.h"
	#include "platform/utils.h"

	namespace dart {

	template <typename T, typename B, typename Allocator>
	class BaseGrowableArray : public B {
	public:
	explicit BaseGrowableArray(Allocator* allocator)
	: length_(0), capacity_(0), data_(NULL), allocator_(allocator) {}

	BaseGrowableArray(intptr_t initial_capacity, Allocator* allocator)
	: length_(0), capacity_(0), data_(NULL), allocator_(allocator) {
	if (initial_capacity > 0) {
	capacity_ = Utils::RoundUpToPowerOfTwo(initial_capacity);
	data_ = allocator_->template Alloc<T>(capacity_);
	}
	}

	BaseGrowableArray(BaseGrowableArray&& other)
	: length_(other.length_),
	capacity_(other.capacity_),
	data_(other.data_),
	allocator_(other.allocator_) {
	other.length_ = 0;
	other.capacity_ = 0;
	other.data_ = NULL;
	}

	~BaseGrowableArray() { allocator_->template Free<T>(data_, capacity_); }

	BaseGrowableArray& operator=(BaseGrowableArray&& other) {
	intptr_t temp = other.length_;
	other.length_ = length_;
	length_ = temp;
	temp = other.capacity_;
	other.capacity_ = capacity_;
	capacity_ = temp;
	T* temp_data = other.data_;
	other.data_ = data_;
	data_ = temp_data;
	Allocator* temp_allocator = other.allocator_;
	other.allocator_ = allocator_;
	allocator_ = temp_allocator;
	return *this;
	}

	intptr_t length() const { return length_; }
	T* data() const { return data_; }
	bool is_empty() const { return length_ == 0; }

	void TruncateTo(intptr_t length) {
	ASSERT(length_ >= length);
	length_ = length;
	}

	inline bool Contains(const T& other,
	bool isEqual(const T&, const T&) = nullptr) const {
	for (const auto& value : *this) {
	if (value == other) {
	// Value identity should imply isEqual.
	ASSERT(isEqual == nullptr \|\| isEqual(value, other));
	return true;
	}
	if (isEqual != nullptr && isEqual(value, other)) {
	return true;
	}
	}
	return false;
	}

	void Add(const T& value) {
	Resize(length() + 1);
	Last() = value;
	}

	T& RemoveLast() {
	ASSERT(length_ > 0);
	T& result = operator[](length_ - 1);
	length_--;
	return result;
	}

	T& operator[](intptr_t index) const {
	ASSERT(0 <= index);
	ASSERT(index < length_);
	ASSERT(length_ <= capacity_);
	return data_[index];
	}

	void FillWith(const T& value, intptr_t start, intptr_t length) {
	ASSERT(start >= 0);
	ASSERT(length >= 0);
	ASSERT(start <= length_);

	Resize(start + length);
	for (intptr_t i = 0; i < length; ++i) {
	data_[start + i] = value;
	}
	}

	void EnsureLength(intptr_t new_length, const T& default_value) {
	const intptr_t old_length = length_;
	if (old_length < new_length) {
	Resize(new_length);
	for (intptr_t i = old_length; i < new_length; ++i) {
	(*this)[i] = default_value;
	}
	}
	}

	const T& At(intptr_t index) const { return operator[](index); }

	T& Last() const {
	ASSERT(length_ > 0);
	return operator[](length_ - 1);
	}

	void AddArray(const BaseGrowableArray<T, B, Allocator>& src) {
	for (intptr_t i = 0; i < src.length(); i++) {
	Add(src[i]);
	}
	}

	void Clear() { length_ = 0; }

	void InsertAt(intptr_t idx, const T& value) {
	Resize(length() + 1);
	for (intptr_t i = length_ - 2; i >= idx; i--) {
	data_[i + 1] = data_[i];
	}
	data_[idx] = value;
	}

	void Reverse() {
	for (intptr_t i = 0; i < length_ / 2; i++) {
	const intptr_t j = length_ - 1 - i;
	T temp = data_[i];
	data_[i] = data_[j];
	data_[j] = temp;
	}
	}

	// Swap entries \|i\| and \|j\|.
	void Swap(intptr_t i, intptr_t j) {
	ASSERT(i >= 0);
	ASSERT(j >= 0);
	ASSERT(i < length_);
	ASSERT(j < length_);
	T temp = data_[i];
	data_[i] = data_[j];
	data_[j] = temp;
	}

	// NOTE: Does not preserve array order.
	void RemoveAt(intptr_t i) {
	ASSERT(i >= 0);
	ASSERT(i < length_);
	intptr_t last = length_ - 1;
	if (i < last) {
	Swap(i, last);
	}
	RemoveLast();
	}

	// Preserves array order.
	void EraseAt(intptr_t idx) {
	ASSERT(idx >= 0);
	ASSERT(idx < length_);
	for (intptr_t i = idx; i < length_ - 1; i++) {
	data_[i] = data_[i + 1];
	}
	RemoveLast();
	}

	// The content is uninitialized after calling it.
	void SetLength(intptr_t new_length);

	// The content (if expanded) is uninitialized after calling it.
	// The backing store (if expanded) will grow with by a power-of-2.
	void Resize(intptr_t new_length);

	// Sort the array in place.
	inline void Sort(int compare(const T, const T));

	void StealBuffer(T** buffer, intptr_t* length) {
	*buffer = data_;
	*length = length_;
	data_ = NULL;
	length_ = 0;
	capacity_ = 0;
	}

	T* begin() { return &data_[0]; }
	const T* begin() const { return &data_[0]; }

	T* end() { return &data_[length_]; }
	const T* end() const { return &data_[length_]; }

	private:
	intptr_t length_;
	intptr_t capacity_;
	T* data_;
	Allocator* allocator_; // Used to (re)allocate the array.

	DISALLOW_COPY_AND_ASSIGN(BaseGrowableArray);
	};

	template <typename T, typename B, typename Allocator>
	inline void BaseGrowableArray<T, B, Allocator>::Sort(int compare(const T*,
	const T*)) {
	// Avoid calling qsort with a null array.
	if (length_ == 0) return;

	typedef int (CompareFunction)(const void, const void*);
	qsort(data_, length_, sizeof(T), reinterpret_cast<CompareFunction>(compare));
	}

	template <typename T, typename B, typename Allocator>
	void BaseGrowableArray<T, B, Allocator>::Resize(intptr_t new_length) {
	if (new_length > capacity_) {
	intptr_t new_capacity = Utils::RoundUpToPowerOfTwo(new_length);
	T* new_data =
	allocator_->template Realloc<T>(data_, capacity_, new_capacity);
	ASSERT(new_data != NULL);
	data_ = new_data;
	capacity_ = new_capacity;
	}
	length_ = new_length;
	}

	template <typename T, typename B, typename Allocator>
	void BaseGrowableArray<T, B, Allocator>::SetLength(intptr_t new_length) {
	if (new_length > capacity_) {
	T* new_data = allocator_->template Alloc<T>(new_length);
	ASSERT(new_data != NULL);
	data_ = new_data;
	capacity_ = new_length;
	}
	length_ = new_length;
	}

	class Malloc : public AllStatic {
	public:
	template <class T>
	static inline T* Alloc(intptr_t len) {
	return reinterpret_cast<T>(dart::malloc(len sizeof(T)));
	}

	template <class T>
	static inline T* Realloc(T* old_array, intptr_t old_len, intptr_t new_len) {
	return reinterpret_cast<T>(dart::realloc(old_array, new_len sizeof(T)));
	}

	template <class T>
	static inline void Free(T* old_array, intptr_t old_len) {
	free(old_array);
	}
	};

	template <typename T>
	class MallocGrowableArray
	: public BaseGrowableArray<T, MallocAllocated, Malloc> {
	public:
	explicit MallocGrowableArray(intptr_t initial_capacity)
	: BaseGrowableArray<T, MallocAllocated, Malloc>(initial_capacity, NULL) {}
	MallocGrowableArray() : BaseGrowableArray<T, MallocAllocated, Malloc>(NULL) {}
	};

	} // namespace dart

	#endif // RUNTIME_PLATFORM_GROWABLE_ARRAY_H_