/*
This program is free software: you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation, either version 3 of the License, or
(at your option) any later version.
This program is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with this program. If not, see .
*/
/*
* ExpandingArray class description
*
* ExpandingArrayGeneric implements most of the required functionality and is type agnostic allowing smaller overall code size
* ExpandingArray is the template and implements the small number of type specific methods
*
* Elements are organised into "chunks" with each chunk holding "chunk_size" elements
* The "chunk_ptrs" array holds pointers to all allocated chunks
*
* The "expand" function allows expanding the array by a specified number of chunks
* The "expand_to_hold" function expands the array (if necessary) to hold at least the specified number of elements
*
* When the array is expanded up to two memory allocations are required:
* 1. if the chunk_ptrs array (which holds points to all allocated chunks) is full, this array will be re-allocated.
* During this operation a new copy of the chunk_ptr array will be created with "chunk_ptr_increment" more rows,
* the old array's data will be copied to the new array and finally the old array will be freed.
* 2. a new chunk will be allocated and a pointer to this new chunk will be added to the chunk_ptrs array
*
* Warnings:
* 1. memset, memcpy, memcmp cannot be used because the individual elements are not guaranteed to be next to each other in memory
* 2. operator[] functions do not perform any range checking so max_items() should be used when necessary to avoid out-of-bound memory access
* 3. elements_per_chunk (provided in constructor) should be a factor of 2 (i.e. 16, 32, 64) for best performance
*/
#pragma once
#include
class AP_ExpandingArrayGeneric
{
public:
AP_ExpandingArrayGeneric(uint16_t element_size, uint16_t elements_per_chunk) :
elem_size(element_size),
chunk_size(elements_per_chunk)
{}
~AP_ExpandingArrayGeneric(void);
/* Do not allow copies */
AP_ExpandingArrayGeneric(const AP_ExpandingArrayGeneric &other) = delete;
AP_ExpandingArrayGeneric &operator=(const AP_ExpandingArrayGeneric&) = delete;
// current maximum number of items (using expand may increase this)
uint16_t max_items() const { return chunk_size * chunk_count; }
// expand the array by specified number of chunks, returns true on success
bool expand(uint16_t num_chunks = 1);
// expand to hold at least num_items
bool expand_to_hold(uint16_t num_items);
protected:
const uint16_t elem_size; // number of bytes for each element
const uint16_t chunk_size; // the number of T elements in each chunk
const uint16_t chunk_ptr_increment = 32; // chunk_ptrs array is grown by this many elements each time it fills
typedef uint8_t* chunk_ptr_t; // pointer to a chunk
chunk_ptr_t *chunk_ptrs; // array of pointers to allocated chunks
uint16_t chunk_count_max; // number of elements in chunk_ptrs array
uint16_t chunk_count; // number of allocated chunks
};
template
class AP_ExpandingArray : public AP_ExpandingArrayGeneric
{
public:
AP_ExpandingArray(uint16_t elements_per_chunk) :
AP_ExpandingArrayGeneric(sizeof(T), elements_per_chunk)
{}
/* Do not allow copies */
AP_ExpandingArray(const AP_ExpandingArray &other) = delete;
AP_ExpandingArray &operator=(const AP_ExpandingArray&) = delete;
// allow use as an array for assigning to elements. no bounds checking is performed
T &operator[](uint16_t i)
{
const uint16_t chunk_num = i / chunk_size;
const uint16_t chunk_index = (i % chunk_size) * elem_size;
return (T &)(chunk_ptrs[chunk_num][chunk_index]);
}
// allow use as an array for accessing elements. no bounds checking is performed
const T &operator[](uint16_t i) const
{
const uint16_t chunk_num = i / chunk_size;
const uint16_t chunk_index = (i % chunk_size) * elem_size;
return (const T &)(chunk_ptrs[chunk_num][chunk_index]);
}
};