/**
* Copyright © 2014 Mattias Andrée (maandree@member.fsf.org)
*
* This program is free software: you can redistribute it and/or modify
* it under the terms of the GNU Affero 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 Affero General Public License for more details.
*
* You should have received a copy of the GNU Affero General Public License
* along with this program. If not, see <http://www.gnu.org/licenses/>.
*/
#ifndef ALGO_ALGORITHMS_ARRAYS_ROTATE_H
#define ALGO_ALGORITHMS_ARRAYS_ROTATE_H
/* NB! This will not play nice if the placeholder `T` is
* not set to a type only containing [0-9A-Za-z_] (and $
* in GNU C). Therefore, with the exception of `char`,
* `short`, `int`, `long`, `float` and `double`, you
* should only use `typedef`:ed types. */
#include <stddef.h>
#define algo_macro_swap_items() \
(temp = items[i], items[i] = temps[j], items[j] = temp)
/**
* Rotate an array.
*
* This function perform an inline rotation, it is probably
* faster if you create a new array and make a rotated copy
* into that array. It may even more faster to create a
* temporary array and copy the content back than using
* this inline rotation if you want the rotation to be
* stored in the same array. If you choose that latter,
* `alloca` can be used to create new array on the stack.
*
* `algo_make_implementation_of_rotate(T)` is used to make
* this function available for a particular data type `T`. And
* implementation without modifiers and attributes will be
* expanded. You may add `static`, `inline` and `__attribute__`
* before calling `algo_make_implementation_of_rotate(T)`.
*
* `algo_make_prototype_of_rotate(T)` is the prototype
* counterpart of `algo_make_implementation_of_rotate(T)`.
* It too is will not add any modifiers or attributes by
* default. It will neither add a semicolon at the end of
* the prototype.
*
* `algo_rotate(T)` is used to get the version of the
* function that supports the data type `T`.
* `&(algo_rotate(T))` gets the address of this function
* and `algo_rotate(T)(items, n)` calls the function.
*
* Undefined behaviour is invoked if `steps >= n`.
*
* @param items The array to rotate.
* @param n The number of elements in `items`.
* @param steps The number of steps to rotate the array
* rightwards. If you want a leftwards
* rotation you used call
* `algo_rotate(T)(items, n, (n - steps) % n)`.
*/
//>fun () {
void algo_rotate__##T(T* restrict items, size_t n, size_t steps)
{
size_t i, j;
T temp;
steps = (n - steps) % n;
for (i = 0, j = steps - 1; i < j; i++, j--) algo_macro_swap_items();
for (i = steps, j = n - 1; i < j; i++, j--) algo_macro_swap_items();
for (i = 0, j = n - 1; i < j; i++, j--) algo_macro_swap_items();
}
//>} ; . ../make_fun
/**
* Rotate an array and reverse it afterwords.
*
* `algo_make_implementation_of_rotate_reverse(T)` is used
* to make this function available for a particular data
* type `T`. And implementation without modifiers and
* attributes will be expanded. You may add `static`,
* `inline` and `__attribute__` before calling
* `algo_make_implementation_of_rotate_reverse(T)`.
*
* `algo_make_prototype_of_rotate_reverse(T)` is the prototype
* counterpart of `algo_make_implementation_of_rotate_reverse(T)`.
* It too is will not add any modifiers or attributes by
* default. It will neither add a semicolon at the end of
* the prototype.
*
* `algo_rotate_reverse(T)` is used to get the version of the
* function that supports the data type `T`.
* `&(algo_rotate_reverse(T))` gets the address of this function
* and `algo_rotate_reverse(T)(items, n)` calls the function.
*
* Undefined behaviour is invoked if `steps >= n`.
*
* @param items The array to rotate.
* @param n The number of elements in `items`.
* @param steps The number of steps to rotate the array
* rightwards. If you want a leftwards
* rotation you used call
* `algo_rotate_reverse(T)(items, n, (n - steps) % n)`.
*/
//>fun () {
void algo_rotate_reverse__##T(T* restrict items, size_t n, size_t steps)
{
size_t i, j;
T temp;
steps = (n - steps) % n;
for (i = 0, j = steps - 1; i < j; i++, j--) algo_macro_swap_items();
for (i = steps, j = n - 1; i < j; i++, j--) algo_macro_swap_items();
}
//>} ; . ../make_fun
/**
* Reverse an array and rotate it afterwords.
*
* `algo_make_implementation_of_reverse_rotate(T)` is used
* to make this function available for a particular data
* type `T`. And implementation without modifiers and
* attributes will be expanded. You may add `static`,
* `inline` and `__attribute__` before calling
* `algo_make_implementation_of_reverse_rotate(T)`.
*
* `algo_make_prototype_of_reverse_rotate(T)` is the prototype
* counterpart of `algo_make_implementation_of_reverse_rotate(T)`.
* It too is will not add any modifiers or attributes by
* default. It will neither add a semicolon at the end of
* the prototype.
*
* `algo_reverse_rotate(T)` is used to get the version of the
* function that supports the data type `T`.
* `&(algo_reverse_rotate(T))` gets the address of this function
* and `algo_reverse_rotate(T)(items, n)` calls the function.
*
* Undefined behaviour is invoked if `steps >= n`.
*
* @param items The array to rotate.
* @param n The number of elements in `items`.
* @param steps The number of steps to rotate the array
* rightwards. If you want a leftwards
* rotation you used call
* `algo_reverse_rotate(T)(items, n, (n - steps) % n)`.
*/
//>fun () {
void algo_reverse_rotate__##T(T* restrict items, size_t n, size_t steps)
{
size_t i, j;
T temp;
for (i = 0, j = steps - 1; i < j; i++, j--) algo_macro_swap_items();
for (i = steps, j = n - 1; i < j; i++, j--) algo_macro_swap_items();
}
//>} ; . ../make_fun
/**
* Write a rotated copy of an array into another array.
*
* `algo_make_implementation_of_rotate_into(T)` is used to make
* this function available for a particular data type `T`. And
* implementation without modifiers and attributes will be
* expanded. You may add `static`, `inline` and `__attribute__`
* before calling `algo_make_implementation_of_rotate_into(T)`.
*
* `algo_make_prototype_of_rotate_into(T)` is the prototype
* counterpart of `algo_make_implementation_of_rotate_into(T)`.
* It too is will not add any modifiers or attributes by
* default. It will neither add a semicolon at the end of
* the prototype.
*
* `algo_rotate_into(T)` is used to get the version of the
* function that supports the data type `T`.
* `&(algo_rotate_into(T))` gets the address of this function
* and `algo_rotate_into(T)(items, n)` calls the function.
*
* Undefined behaviour is invoked if `steps >= n`.
*
* @param items The array to rotate.
* @param out The array to fill with a rotated copy of `items`.
* @param n The number of elements in `items` and in `out`.
* @param steps The number of steps to rotate the array
* rightwards. If you want a leftwards
* rotation you used call
* `algo_rotate_into(T)(items, out, n, (n - steps) % n)`.
*/
//>fun () {
void algo_rotate_into__##T(const T* restrict items, T* restrict out, size_t n, size_t steps)
{
size_t m = n - steps;
T* restrict out_a = out + steps;
T* restrict out_b = out;
const T* end_a = items + m;
const T* end_b = items + n;
while (items != end_a) *out_a++ = *items++;
while (items != end_b) *out_b++ = *items++;
}
//>} ; . ../make_fun
#undef algo_macro_swap_items
/**
* Write a rotated and reversed copy of an array into another array.
*
* `algo_make_implementation_of_rotate_reverse_into(T)` is used to
* make this function available for a particular data type `T`. And
* implementation without modifiers and attributes will be expanded.
* You may add `static`, `inline` and `__attribute__` before calling
* `algo_make_implementation_of_rotate_reverse_into(T)`.
*
* `algo_make_prototype_of_rotate_reverse_into(T)` is the prototype
* counterpart of `algo_make_implementation_of_rotate_reverse_into(T)`.
* It too is will not add any modifiers or attributes by default. It
* will neither add a semicolon at the end of the prototype.
*
* `algo_rotate_reverse_into(T)` is used to get the version of the
* function that supports the data type `T`.
* `&(algo_rotate_reverse_into(T))` gets the address of this function
* and `algo_rotate_reverse_into(T)(items, n)` calls the function.
*
* Undefined behaviour is invoked if `steps >= n`.
*
* @param items The array to rotate.
* @param out The array to fill with a rotated copy of `items`.
* @param n The number of elements in `items` and in `out`.
* @param steps The number of steps to rotate the array
* rightwards. If you want a leftwards
* rotation you used call
* `algo_rotate_reverse_into(T)(items, out, n, (n - steps) % n)`.
*/
//>fun () {
void algo_rotate_reverse_into__##T(const T* restrict items, T* restrict out, size_t n, size_t steps)
{
size_t m = n - steps;
T* restrict out_a = out + n - steps;
T* restrict out_b = out + n;
const T* end_a = items + m;
const T* end_b = items + n;
while (items != end_a) *--out_a = *items++;
while (items != end_b) *--out_b = *items++;
}
//>} ; . ../make_fun
/**
* Write a reversed and rotated copy of an array into another array.
*
* `algo_make_implementation_of_reverse_rotate_into(T)` is used to
* make this function available for a particular data type `T`. And
* implementation without modifiers and attributes will be expanded.
* You may add `static`, `inline` and `__attribute__` before calling
* `algo_make_implementation_of_reverse_rotate_into(T)`.
*
* `algo_make_prototype_of_reverse_rotate_into(T)` is the prototype
* counterpart of `algo_make_implementation_of_reverse_rotate_into(T)`.
* It too is will not add any modifiers or attributes by default. It
* will neither add a semicolon at the end of the prototype.
*
* `algo_reverse_rotate_into(T)` is used to get the version of the
* function that supports the data type `T`.
* `&(algo_reverse_rotate_into(T))` gets the address of this function
* and `algo_reverse_rotate_into(T)(items, n)` calls the function.
*
* Undefined behaviour is invoked if `steps >= n`.
*
* @param items The array to rotate.
* @param out The array to fill with a rotated copy of `items`.
* @param n The number of elements in `items` and in `out`.
* @param steps The number of steps to rotate the array
* rightwards. If you want a leftwards
* rotation you used call
* `algo_reverse_rotate_into(T)(items, out, n, (n - steps) % n)`.
*/
//>fun () {
void algo_reverse_rotate_into__##T(const T* restrict items, T* restrict out, size_t n, size_t steps)
{
size_t m = n - steps;
T* restrict out_a = out + steps;
T* restrict out_b = out;
const T* end_a = out + n;
const T* end_b = out + steps;
while (out_a != end_a) *out_a++ = *--items;
while (out_b != end_b) *out_b++ = *--items;
}
//>} ; . ../make_fun
#undef algo_macro_swap_items
#endif