/*
* Mesa 3-D graphics library
* Version: 6.5
*
* Copyright (C) 2006 Brian Paul All Rights Reserved.
*
* 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
* BRIAN PAUL 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.
*/
/**
* \file bitset.h
* \brief Bitset of arbitrary size definitions.
* \author Michal Krol
*/
#ifndef BITSET_H
#define BITSET_H
#include "imports.h"
/****************************************************************************
* generic bitset implementation
*/
#define BITSET_WORD GLuint
#define BITSET_WORDBITS (sizeof (BITSET_WORD) * 8)
/* bitset declarations
*/
#define BITSET_DECLARE(name, size) \
BITSET_WORD name[((size) + BITSET_WORDBITS - 1) / BITSET_WORDBITS]
/* bitset operations
*/
#define BITSET_COPY(x, y) memcpy( (x), (y), sizeof (x) )
#define BITSET_EQUAL(x, y) (memcmp( (x), (y), sizeof (x) ) == 0)
#define BITSET_ZERO(x) memset( (x), 0, sizeof (x) )
#define BITSET_ONES(x) memset( (x), 0xff, sizeof (x) )
#define BITSET_BITWORD(b) ((b) / BITSET_WORDBITS)
#define BITSET_BIT(b) (1 << ((b) % BITSET_WORDBITS))
/* single bit operations
*/
#define BITSET_TEST(x, b) ((x)[BITSET_BITWORD(b)] & BITSET_BIT(b))
#define BITSET_SET(x, b) ((x)[BITSET_BITWORD(b)] |= BITSET_BIT(b))
#define BITSET_CLEAR(x, b) ((x)[BITSET_BITWORD(b)] &= ~BITSET_BIT(b))
#define BITSET_MASK(b) ((b) == BITSET_WORDBITS ? ~0 : BITSET_BIT(b) - 1)
#define BITSET_RANGE(b, e) (BITSET_MASK((e) + 1) & ~BITSET_MASK(b))
/* bit range operations
*/
#define BITSET_TEST_RANGE(x, b, e) \
(BITSET_BITWORD(b) == BITSET_BITWORD(e) ? \
((x)[BITSET_BITWORD(b)] & BITSET_RANGE(b, e)) : \
(assert (!"BITSET_TEST_RANGE: bit range crosses word boundary"), 0))
#define BITSET_SET_RANGE(x, b, e) \
(BITSET_BITWORD(b) == BITSET_BITWORD(e) ? \
((x)[BITSET_BITWORD(b)] |= BITSET_RANGE(b, e)) : \
(assert (!"BITSET_SET_RANGE: bit range crosses word boundary"), 0))
#define BITSET_CLEAR_RANGE(x, b, e) \
(BITSET_BITWORD(b) == BITSET_BITWORD(e) ? \
((x)[BITSET_BITWORD(b)] &= ~BITSET_RANGE(b, e)) : \
(assert (!"BITSET_CLEAR_RANGE: bit range crosses word boundary"), 0))
/* Get first bit set in a bitset.
*/
static inline int
__bitset_ffs(const BITSET_WORD *x, int n)
{
int i;
for (i = 0; i < n; i++) {
if (x[i])
return ffs(x[i]) + BITSET_WORDBITS * i;
}
return 0;
}
#define BITSET_FFS(x) __bitset_ffs(x, Elements(x))
/****************************************************************************
* 64-bit bitset implementation
*/
#define BITSET64_WORD GLuint
#define BITSET64_WORDBITS (sizeof (BITSET64_WORD) * 8)
/* bitset declarations
*/
#define BITSET64_DECLARE(name, size) \
GLuint name[2]
/* bitset operations
*/
#define BITSET64_COPY(x, y) do { (x)[0] = (y)[0]; (x)[1] = (y)[1]; } while (0)
#define BITSET64_EQUAL(x, y) ( (x)[0] == (y)[0] && (x)[1] == (y)[1] )
#define BITSET64_ZERO(x) do { (x)[0] = 0; (x)[1] = 0; } while (0)
#define BITSET64_ONES(x) do { (x)[0] = 0xFF; (x)[1] = 0xFF; } while (0)
#define BITSET64_BITWORD(b) ((b) / BITSET64_WORDBITS)
#define BITSET64_BIT(b) (1 << ((b) % BITSET64_WORDBITS))
/* single bit operations
*/
#define BITSET64_TEST(x, b) ((x)[BITSET64_BITWORD(b)] & BITSET64_BIT(b))
#define BITSET64_SET(x, b) ((x)[BITSET64_BITWORD(b)] |= BITSET64_BIT(b))
#define BITSET64_CLEAR(x, b) ((x)[BITSET64_BITWORD(b)] &= ~BITSET64_BIT(b))
#define BITSET64_MASK(b) ((b) == BITSET64_WORDBITS ? ~0 : BITSET64_BIT(b) - 1)
#define BITSET64_RANGE(b, e) (BITSET64_MASK((e) + 1) & ~BITSET64_MASK(b))
/* bit range operations
*/
#define BITSET64_TEST_SUBRANGE(x, b, e) \
(BITSET64_BITWORD(b) == BITSET64_BITWORD(e) ? \
((x)[BITSET64_BITWORD(b)] & BITSET64_RANGE(b, e)) : \
(assert (!"BITSET64_TEST_RANGE: bit range crosses word boundary"), 0))
#define BITSET64_TEST_RANGE(x, b, e) \
(BITSET64_BITWORD(b) == BITSET64_BITWORD(e) ? \
(BITSET64_TEST_SUBRANGE(x, b, e)) : \
(BITSET64_TEST_SUBRANGE(x, b, BITSET64_WORDBITS - 1) | \
BITSET64_TEST_SUBRANGE(x, BITSET64_WORDBITS, e)))
#define BITSET64_SET_SUBRANGE(x, b, e) \
(BITSET64_BITWORD(b) == BITSET64_BITWORD(e) ? \
((x)[BITSET64_BITWORD(b)] |= BITSET64_RANGE(b, e)) : \
(assert (!"BITSET64_SET_RANGE: bit range crosses word boundary"), 0))
#define BITSET64_SET_RANGE(x, b, e) \
(BITSET64_BITWORD(b) == BITSET64_BITWORD(e) ? \
(BITSET64_SET_SUBRANGE(x, b, e)) : \
(BITSET64_SET_SUBRANGE(x, b, BITSET64_WORDBITS - 1) | \
BITSET64_SET_SUBRANGE(x, BITSET64_WORDBITS, e)))
#define BITSET64_CLEAR_SUBRANGE(x, b, e) \
(BITSET64_BITWORD(b) == BITSET64_BITWORD(e) ? \
((x)[BITSET64_BITWORD(b)] &= ~BITSET64_RANGE(b, e)) : \
(assert (!"BITSET64_CLEAR_RANGE: bit range crosses word boundary"), 0))
#define BITSET64_CLEAR_RANGE(x, b, e) \
(BITSET64_BITWORD(b) == BITSET64_BITWORD(e) ? \
(BITSET64_CLEAR_SUBRANGE(x, b, e)) : \
(BITSET64_CLEAR_SUBRANGE(x, b, BITSET64_WORDBITS - 1) | \
BITSET64_CLEAR_SUBRANGE(x, BITSET64_WORDBITS, e)))
#endif