Hash :
57f184e2
Author :
Date :
2012-05-30T15:55:21
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/*
* Copyright (C) 2011 Joseph Adams <joeyadams3.14159@gmail.com>
*
* Permission is hereby granted, free of charge, to any person obtaining a copy
* of this software and associated documentation files (the "Software"), to deal
* in the Software without restriction, including without limitation the rights
* to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
* copies of the Software, and to permit persons to whom the Software is
* furnished to do so, subject to the following conditions:
*
* The above copyright notice and this permission notice shall be included in
* all copies or substantial portions of the Software.
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
* IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
* AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
* LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
* OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
* THE SOFTWARE.
*/
#ifndef CCAN_DARRAY_H
#define CCAN_DARRAY_H
#include <stdlib.h>
#include <string.h>
#include "config.h"
/*
* SYNOPSIS
*
* Life cycle of a darray (dynamically-allocated array):
*
* darray(int) a = darray_new();
* darray_free(a);
*
* struct {darray(int) a;} foo;
* darray_init(foo.a);
* darray_free(foo.a);
*
* const struct {
* darray(int) a;
* } foo = {
* .a = darray_lit({1, 2, 3})
* };
*
* Typedefs for darrays of common types:
*
* darray_char, darray_schar, darray_uchar
* darray_short, darray_int, darray_long
* darray_ushort, darray_uint, darray_ulong
*
* Access:
*
* T darray_item(darray(T) arr, size_t index);
* size_t darray_size(darray(T) arr);
* size_t darray_alloc(darray(T) arr);
* bool darray_empty(darray(T) arr);
*
* // Access raw memory, starting from the item in offset.
* // Not safe, be careful, etc.
* T* darray_mem(darray(T) arr, size_t offset);
*
* Insertion (single item):
*
* void darray_append(darray(T) arr, T item);
* void darray_prepend(darray(T) arr, T item);
* void darray_push(darray(T) arr, T item); // same as darray_append
*
* Insertion (multiple items):
*
* void darray_append_items(darray(T) arr, T *items, size_t count);
* void darray_prepend_items(darray(T) arr, T *items, size_t count);
*
* void darray_appends(darray(T) arr, [T item, [...]]);
* void darray_prepends(darray(T) arr, [T item, [...]]);
*
* // Same functionality as above, but does not require typeof.
* void darray_appends_t(darray(T) arr, #T, [T item, [...]]);
* void darray_prepends_t(darray(T) arr, #T, [T item, [...]]);
*
* Removal:
*
* T darray_pop(darray(T) arr | darray_size(arr) != 0);
* T* darray_pop_check(darray(T*) arr);
*
* Replacement:
*
* void darray_from_items(darray(T) arr, T *items, size_t count);
* void darray_from_c(darray(T) arr, T c_array[N]);
*
* String buffer:
*
* void darray_append_string(darray(char) arr, const char *str);
* void darray_append_lit(darray(char) arr, char stringLiteral[N+1]);
*
* void darray_prepend_string(darray(char) arr, const char *str);
* void darray_prepend_lit(darray(char) arr, char stringLiteral[N+1]);
*
* void darray_from_string(darray(T) arr, const char *str);
* void darray_from_lit(darray(char) arr, char stringLiteral[N+1]);
*
* Size management:
*
* void darray_resize(darray(T) arr, size_t newSize);
* void darray_resize0(darray(T) arr, size_t newSize);
*
* void darray_realloc(darray(T) arr, size_t newAlloc);
* void darray_growalloc(darray(T) arr, size_t newAlloc);
*
* void darray_make_room(darray(T) arr, size_t room);
*
* Traversal:
*
* darray_foreach(T *&i, darray(T) arr) {...}
* darray_foreach_reverse(T *&i, darray(T) arr) {...}
*
* Except for darray_foreach and darray_foreach_reverse,
* all macros evaluate their non-darray arguments only once.
*/
/*** Life cycle ***/
#define darray(type) struct {type *item; size_t size; size_t alloc;}
#define darray_new() {0,0,0}
#define darray_init(arr) do {(arr).item=0; (arr).size=0; (arr).alloc=0;} while(0)
#define darray_free(arr) do {free((arr).item); darray_init(arr);} while(0)
/* Only use for immutable darray - e.g. for static const initialzers. */
#define darray_lit(c_array) {(c_array), sizeof(c_array) / sizeof(*(c_array)), 0}
/*
* Typedefs for darrays of common types. These are useful
* when you want to pass a pointer to an darray(T) around.
*
* The following will produce an incompatible pointer warning:
*
* void foo(darray(int) *arr);
* darray(int) arr = darray_new();
* foo(&arr);
*
* The workaround:
*
* void foo(darray_int *arr);
* darray_int arr = darray_new();
* foo(&arr);
*/
typedef darray(char) darray_char;
typedef darray(signed char) darray_schar;
typedef darray(unsigned char) darray_uchar;
typedef darray(short) darray_short;
typedef darray(int) darray_int;
typedef darray(long) darray_long;
typedef darray(unsigned short) darray_ushort;
typedef darray(unsigned int) darray_uint;
typedef darray(unsigned long) darray_ulong;
/*** Access ***/
#define darray_item(arr, i) ((arr).item[i])
#define darray_size(arr) ((arr).size)
#define darray_alloc(arr) ((arr).alloc)
#define darray_empty(arr) ((arr).size == 0)
#define darray_mem(arr, offset) ((arr).item + (offset))
#define darray_same(arr1, arr2) ((arr1).item == (arr2).item)
/*** Insertion (single item) ***/
#define darray_append(arr, ...) do { \
darray_resize(arr, (arr).size+1); \
(arr).item[(arr).size-1] = (__VA_ARGS__); \
} while(0)
#define darray_prepend(arr, ...) do { \
darray_resize(arr, (arr).size+1); \
memmove((arr).item+1, (arr).item, ((arr).size-1)*sizeof(*(arr).item)); \
(arr).item[0] = (__VA_ARGS__); \
} while(0)
#define darray_push(arr, ...) darray_append(arr, __VA_ARGS__)
/*** Insertion (multiple items) ***/
#define darray_append_items(arr, items, count) do { \
size_t __count = (count), __oldSize = (arr).size; \
darray_resize(arr, __oldSize + __count); \
memcpy((arr).item + __oldSize, items, __count * sizeof(*(arr).item)); \
} while(0)
#define darray_prepend_items(arr, items, count) do { \
size_t __count = (count), __oldSize = (arr).size; \
darray_resize(arr, __count + __oldSize); \
memmove((arr).item + __count, (arr).item, __oldSize * sizeof(*(arr).item)); \
memcpy((arr).item, items, __count * sizeof(*(arr).item)); \
} while(0)
#define darray_append_items_nullterminate(arr, items, count) do { \
size_t __count = (count), __oldSize = (arr).size; \
darray_resize(arr, __oldSize + __count + 1); \
memcpy((arr).item + __oldSize, items, __count * sizeof(*(arr).item)); \
(arr).item[--(arr).size] = 0; \
} while(0)
#define darray_prepend_items_nullterminate(arr, items, count) do { \
size_t __count = (count), __oldSize = (arr).size; \
darray_resize(arr, __count + __oldSize + 1); \
memmove((arr).item + __count, (arr).item, __oldSize * sizeof(*(arr).item)); \
memcpy((arr).item, items, __count * sizeof(*(arr).item)); \
(arr).item[--(arr).size] = 0; \
} while(0)
#if HAVE_TYPEOF
#define darray_appends(arr, ...) darray_appends_t(arr, typeof((*(arr).item)), __VA_ARGS__)
#define darray_prepends(arr, ...) darray_prepends_t(arr, typeof((*(arr).item)), __VA_ARGS__)
#endif
#define darray_appends_t(arr, type, ...) do { \
type __src[] = {__VA_ARGS__}; \
darray_append_items(arr, __src, sizeof(__src)/sizeof(*__src)); \
} while(0)
#define darray_prepends_t(arr, type, ...) do { \
type __src[] = {__VA_ARGS__}; \
darray_prepend_items(arr, __src, sizeof(__src)/sizeof(*__src)); \
} while(0)
/*** Removal ***/
/* Warning: Do not call darray_pop on an empty darray. */
#define darray_pop(arr) ((arr).item[--(arr).size])
#define darray_pop_check(arr) ((arr).size ? darray_pop(arr) : NULL)
/*** Replacement ***/
#define darray_from_items(arr, items, count) do {size_t __count = (count); darray_resize(arr, __count); memcpy((arr).item, items, __count*sizeof(*(arr).item));} while(0)
#define darray_from_c(arr, c_array) darray_from_items(arr, c_array, sizeof(c_array)/sizeof(*(c_array)))
#define darray_copy(arr_to, arr_from) darray_from_items(arr_to, (arr_from).item, (arr_from).size)
/*** String buffer ***/
#define darray_append_string(arr, str) do {const char *__str = (str); darray_append_items(arr, __str, strlen(__str)+1); (arr).size--;} while(0)
#define darray_append_lit(arr, stringLiteral) do {darray_append_items(arr, stringLiteral, sizeof(stringLiteral)); (arr).size--;} while(0)
#define darray_prepend_string(arr, str) do { \
const char *__str = (str); \
darray_prepend_items_nullterminate(arr, __str, strlen(__str)); \
} while(0)
#define darray_prepend_lit(arr, stringLiteral) \
darray_prepend_items_nullterminate(arr, stringLiteral, sizeof(stringLiteral) - 1)
#define darray_from_string(arr, str) do {const char *__str = (str); darray_from_items(arr, __str, strlen(__str)+1); (arr).size--;} while(0)
#define darray_from_lit(arr, stringLiteral) do {darray_from_items(arr, stringLiteral, sizeof(stringLiteral)); (arr).size--;} while(0)
/*** Size management ***/
#define darray_resize(arr, newSize) darray_growalloc(arr, (arr).size = (newSize))
#define darray_resize0(arr, newSize) do { \
size_t __oldSize = (arr).size, __newSize = (newSize); \
(arr).size = __newSize; \
if (__newSize > __oldSize) { \
darray_growalloc(arr, __newSize); \
memset(&(arr).item[__oldSize], 0, (__newSize - __oldSize) * sizeof(*(arr).item)); \
} \
} while(0)
#define darray_realloc(arr, newAlloc) do { \
(arr).item = realloc((arr).item, ((arr).alloc = (newAlloc)) * sizeof(*(arr).item)); \
} while(0)
#define darray_growalloc(arr, need) do { \
size_t __need = (need); \
if (__need > (arr).alloc) \
darray_realloc(arr, darray_next_alloc((arr).alloc, __need)); \
} while(0)
#if HAVE_STATEMENT_EXPR==1
#define darray_make_room(arr, room) ({size_t newAlloc = (arr).size+(room); if ((arr).alloc<newAlloc) darray_realloc(arr, newAlloc); (arr).item+(arr).size; })
#endif
static inline size_t darray_next_alloc(size_t alloc, size_t need)
{
if (alloc == 0)
alloc = 4;
while (alloc < need)
alloc *= 2;
return alloc;
}
/*** Traversal ***/
/*
* darray_foreach(T *&i, darray(T) arr) {...}
*
* Traverse a darray. `i` must be declared in advance as a pointer to an item.
*/
#define darray_foreach(i, arr) \
for ((i) = &(arr).item[0]; (i) < &(arr).item[(arr).size]; (i)++)
/*
* darray_foreach_reverse(T *&i, darray(T) arr) {...}
*
* Like darray_foreach, but traverse in reverse order.
*/
#define darray_foreach_reverse(i, arr) \
for ((i) = &(arr).item[(arr).size]; (i)-- > &(arr).item[0]; )
#endif /* CCAN_DARRAY_H */
/*
darray_growalloc(arr, newAlloc) sees if the darray can currently hold newAlloc items;
if not, it increases the alloc to satisfy this requirement, allocating slack
space to avoid having to reallocate for every size increment.
darray_from_string(arr, str) copies a string to an darray_char.
darray_push(arr, item) pushes an item to the end of the darray.
darray_pop(arr) pops it back out. Be sure there is at least one item in the darray before calling.
darray_pop_check(arr) does the same as darray_pop, but returns NULL if there are no more items left in the darray.
darray_make_room(arr, room) ensures there's 'room' elements of space after the end of the darray, and it returns a pointer to this space.
Currently requires HAVE_STATEMENT_EXPR, but I plan to remove this dependency by creating an inline function.
The following require HAVE_TYPEOF==1 :
darray_appends(arr, item0, item1...) appends a collection of comma-delimited items to the darray.
darray_prepends(arr, item0, item1...) prepends a collection of comma-delimited items to the darray.\
Examples:
darray(int) arr;
int *i;
darray_appends(arr, 0,1,2,3,4);
darray_appends(arr, -5,-4,-3,-2,-1);
darray_foreach(i, arr)
printf("%d ", *i);
printf("\n");
darray_free(arr);
typedef struct {int n,d;} Fraction;
darray(Fraction) fractions;
Fraction *i;
darray_appends(fractions, {3,4}, {3,5}, {2,1});
darray_foreach(i, fractions)
printf("%d/%d\n", i->n, i->d);
darray_free(fractions);
*/