/*
* Copyright 1997-2006 Sun Microsystems, Inc. All Rights Reserved.
* DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
*
* This code is free software; you can redistribute it and/or modify it
* under the terms of the GNU General Public License version 2 only, as
* published by the Free Software Foundation.
*
* This code 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
* version 2 for more details (a copy is included in the LICENSE file that
* accompanied this code).
*
* You should have received a copy of the GNU General Public License version
* 2 along with this work; if not, write to the Free Software Foundation,
* Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA.
*
* Please contact Sun Microsystems, Inc., 4150 Network Circle, Santa Clara,
* CA 95054 USA or visit www.sun.com if you need additional information or
* have any questions.
*
*/
// Closure for iterating over BitMaps
class BitMapClosure VALUE_OBJ_CLASS_SPEC {
public:
// Callback when bit in map is set
virtual void do_bit(size_t offset) = 0;
};
// Operations for bitmaps represented as arrays of unsigned 32- or 64-bit
// integers (uintptr_t).
//
// Bit offsets are numbered from 0 to size-1
class BitMap VALUE_OBJ_CLASS_SPEC {
friend class BitMap2D;
public:
typedef size_t idx_t; // Type used for bit and word indices.
// Hints for range sizes.
typedef enum {
unknown_range, small_range, large_range
} RangeSizeHint;
private:
idx_t* _map; // First word in bitmap
idx_t _size; // Size of bitmap (in bits)
// Puts the given value at the given offset, using resize() to size
// the bitmap appropriately if needed using factor-of-two expansion.
void at_put_grow(idx_t index, bool value);
protected:
// Return the position of bit within the word that contains it (e.g., if
// bitmap words are 32 bits, return a number 0 <= n <= 31).
static idx_t bit_in_word(idx_t bit) { return bit & (BitsPerWord - 1); }
// Return a mask that will select the specified bit, when applied to the word
// containing the bit.
static idx_t bit_mask(idx_t bit) { return (idx_t)1 << bit_in_word(bit); }
// Return the index of the word containing the specified bit.
static idx_t word_index(idx_t bit) { return bit >> LogBitsPerWord; }
// Return the bit number of the first bit in the specified word.
static idx_t bit_index(idx_t word) { return word << LogBitsPerWord; }
// Return the array of bitmap words, or a specific word from it.
idx_t* map() const { return _map; }
idx_t map(idx_t word) const { return _map[word]; }
// Return a pointer to the word containing the specified bit.
idx_t* word_addr(idx_t bit) const { return map() + word_index(bit); }
// Set a word to a specified value or to all ones; clear a word.
void set_word (idx_t word, idx_t val) { _map[word] = val; }
void set_word (idx_t word) { set_word(word, ~(uintptr_t)0); }
void clear_word(idx_t word) { _map[word] = 0; }
// Utilities for ranges of bits. Ranges are half-open [beg, end).
// Ranges within a single word.
inline idx_t inverted_bit_mask_for_range(idx_t beg, idx_t end) const;
inline void set_range_within_word (idx_t beg, idx_t end);
inline void clear_range_within_word (idx_t beg, idx_t end);
inline void par_put_range_within_word (idx_t beg, idx_t end, bool value);
// Ranges spanning entire words.
inline void set_range_of_words (idx_t beg, idx_t end);
inline void clear_range_of_words (idx_t beg, idx_t end);
inline void set_large_range_of_words (idx_t beg, idx_t end);
inline void clear_large_range_of_words (idx_t beg, idx_t end);
// The index of the first full word in a range.
inline idx_t word_index_round_up(idx_t bit) const;
// Verification, statistics.
void verify_index(idx_t index) const {
assert(index < _size, "BitMap index out of bounds");
}
void verify_range(idx_t beg_index, idx_t end_index) const {
#ifdef ASSERT
assert(beg_index <= end_index, "BitMap range error");
// Note that [0,0) and [size,size) are both valid ranges.
if (end_index != _size) verify_index(end_index);
#endif
}
public:
// Constructs a bitmap with no map, and size 0.
BitMap() : _map(NULL), _size(0) {}
// Construction
BitMap(idx_t* map, idx_t size_in_bits);
// Allocates necessary data structure in resource area
BitMap(idx_t size_in_bits);
void set_map(idx_t* map) { _map = map; }
void set_size(idx_t size_in_bits) { _size = size_in_bits; }
// Allocates necessary data structure in resource area.
// Preserves state currently in bit map by copying data.
// Zeros any newly-addressable bits.
// Does not perform any frees (i.e., of current _map).
void resize(idx_t size_in_bits);
// Accessing
idx_t size() const { return _size; }
idx_t size_in_words() const {
return word_index(size() + BitsPerWord - 1);
}
bool at(idx_t index) const {
verify_index(index);
return (*word_addr(index) & bit_mask(index)) != 0;
}
// Align bit index up or down to the next bitmap word boundary, or check
// alignment.
static idx_t word_align_up(idx_t bit) {
return align_size_up(bit, BitsPerWord);
}
static idx_t word_align_down(idx_t bit) {
return align_size_down(bit, BitsPerWord);
}
static bool is_word_aligned(idx_t bit) {
return word_align_up(bit) == bit;
}
// Set or clear the specified bit.
inline void set_bit(idx_t bit);
inline void clear_bit(idx_t bit);
// Atomically set or clear the specified bit.
inline bool par_set_bit(idx_t bit);
inline bool par_clear_bit(idx_t bit);
// Put the given value at the given offset. The parallel version
// will CAS the value into the bitmap and is quite a bit slower.
// The parallel version also returns a value indicating if the
// calling thread was the one that changed the value of the bit.
void at_put(idx_t index, bool value);
bool par_at_put(idx_t index, bool value);
// Update a range of bits. Ranges are half-open [beg, end).
void set_range (idx_t beg, idx_t end);
void clear_range (idx_t beg, idx_t end);
void set_large_range (idx_t beg, idx_t end);
void clear_large_range (idx_t beg, idx_t end);
void at_put_range(idx_t beg, idx_t end, bool value);
void par_at_put_range(idx_t beg, idx_t end, bool value);
void at_put_large_range(idx_t beg, idx_t end, bool value);
void par_at_put_large_range(idx_t beg, idx_t end, bool value);
// Update a range of bits, using a hint about the size. Currently only
// inlines the predominant case of a 1-bit range. Works best when hint is a
// compile-time constant.
inline void set_range(idx_t beg, idx_t end, RangeSizeHint hint);
inline void clear_range(idx_t beg, idx_t end, RangeSizeHint hint);
inline void par_set_range(idx_t beg, idx_t end, RangeSizeHint hint);
inline void par_clear_range (idx_t beg, idx_t end, RangeSizeHint hint);
// Clearing
void clear();
void clear_large();
// Iteration support
void iterate(BitMapClosure* blk, idx_t leftIndex, idx_t rightIndex);
inline void iterate(BitMapClosure* blk) {
// call the version that takes an interval
iterate(blk, 0, size());
}
// Looking for 1's and 0's to the "right"
idx_t get_next_one_offset (idx_t l_index, idx_t r_index) const;
idx_t get_next_zero_offset(idx_t l_index, idx_t r_index) const;
idx_t get_next_one_offset(idx_t offset) const {
return get_next_one_offset(offset, size());
}
idx_t get_next_zero_offset(idx_t offset) const {
return get_next_zero_offset(offset, size());
}
// Find the next one bit in the range [beg_bit, end_bit), or return end_bit if
// no one bit is found. Equivalent to get_next_one_offset(), but inline for
// use in performance-critical code.
inline idx_t find_next_one_bit(idx_t beg_bit, idx_t end_bit) const;
// Set operations.
void set_union(BitMap bits);
void set_difference(BitMap bits);
void set_intersection(BitMap bits);
// Returns true iff "this" is a superset of "bits".
bool contains(const BitMap bits) const;
// Returns true iff "this and "bits" have a non-empty intersection.
bool intersects(const BitMap bits) const;
// Returns result of whether this map changed
// during the operation
bool set_union_with_result(BitMap bits);
bool set_difference_with_result(BitMap bits);
bool set_intersection_with_result(BitMap bits);
void set_from(BitMap bits);
bool is_same(BitMap bits);
// Test if all bits are set or cleared
bool is_full() const;
bool is_empty() const;
#ifndef PRODUCT
public:
// Printing
void print_on(outputStream* st) const;
#endif
};
inline void BitMap::set_bit(idx_t bit) {
verify_index(bit);
*word_addr(bit) |= bit_mask(bit);
}
inline void BitMap::clear_bit(idx_t bit) {
verify_index(bit);
*word_addr(bit) &= ~bit_mask(bit);
}
inline void BitMap::set_range(idx_t beg, idx_t end, RangeSizeHint hint) {
if (hint == small_range && end - beg == 1) {
set_bit(beg);
} else {
if (hint == large_range) {
set_large_range(beg, end);
} else {
set_range(beg, end);
}
}
}
inline void BitMap::clear_range(idx_t beg, idx_t end, RangeSizeHint hint) {
if (hint == small_range && end - beg == 1) {
clear_bit(beg);
} else {
if (hint == large_range) {
clear_large_range(beg, end);
} else {
clear_range(beg, end);
}
}
}
inline void BitMap::par_set_range(idx_t beg, idx_t end, RangeSizeHint hint) {
if (hint == small_range && end - beg == 1) {
par_at_put(beg, true);
} else {
if (hint == large_range) {
par_at_put_large_range(beg, end, true);
} else {
par_at_put_range(beg, end, true);
}
}
}
// Convenience class wrapping BitMap which provides multiple bits per slot.
class BitMap2D VALUE_OBJ_CLASS_SPEC {
public:
typedef size_t idx_t; // Type used for bit and word indices.
private:
BitMap _map;
idx_t _bits_per_slot;
idx_t bit_index(idx_t slot_index, idx_t bit_within_slot_index) const {
return slot_index * _bits_per_slot + bit_within_slot_index;
}
void verify_bit_within_slot_index(idx_t index) const {
assert(index < _bits_per_slot, "bit_within_slot index out of bounds");
}
public:
// Construction. bits_per_slot must be greater than 0.
BitMap2D(uintptr_t* map, idx_t size_in_slots, idx_t bits_per_slot);
// Allocates necessary data structure in resource area. bits_per_slot must be greater than 0.
BitMap2D(idx_t size_in_slots, idx_t bits_per_slot);
idx_t size_in_bits() {
return _map.size();
}
// Returns number of full slots that have been allocated
idx_t size_in_slots() {
// Round down
return _map.size() / _bits_per_slot;
}
bool is_valid_index(idx_t slot_index, idx_t bit_within_slot_index) {
verify_bit_within_slot_index(bit_within_slot_index);
return (bit_index(slot_index, bit_within_slot_index) < size_in_bits());
}
bool at(idx_t slot_index, idx_t bit_within_slot_index) const {
verify_bit_within_slot_index(bit_within_slot_index);
return _map.at(bit_index(slot_index, bit_within_slot_index));
}
void set_bit(idx_t slot_index, idx_t bit_within_slot_index) {
verify_bit_within_slot_index(bit_within_slot_index);
_map.set_bit(bit_index(slot_index, bit_within_slot_index));
}
void clear_bit(idx_t slot_index, idx_t bit_within_slot_index) {
verify_bit_within_slot_index(bit_within_slot_index);
_map.clear_bit(bit_index(slot_index, bit_within_slot_index));
}
void at_put(idx_t slot_index, idx_t bit_within_slot_index, bool value) {
verify_bit_within_slot_index(bit_within_slot_index);
_map.at_put(bit_index(slot_index, bit_within_slot_index), value);
}
void at_put_grow(idx_t slot_index, idx_t bit_within_slot_index, bool value) {
verify_bit_within_slot_index(bit_within_slot_index);
_map.at_put_grow(bit_index(slot_index, bit_within_slot_index), value);
}
void clear() {
_map.clear();
}
};
inline void BitMap::set_range_of_words(idx_t beg, idx_t end) {
uintptr_t* map = _map;
for (idx_t i = beg; i < end; ++i) map[i] = ~(uintptr_t)0;
}
inline void BitMap::clear_range_of_words(idx_t beg, idx_t end) {
uintptr_t* map = _map;
for (idx_t i = beg; i < end; ++i) map[i] = 0;
}
inline void BitMap::clear() {
clear_range_of_words(0, size_in_words());
}
inline void BitMap::par_clear_range(idx_t beg, idx_t end, RangeSizeHint hint) {
if (hint == small_range && end - beg == 1) {
par_at_put(beg, false);
} else {
if (hint == large_range) {
par_at_put_large_range(beg, end, false);
} else {
par_at_put_range(beg, end, false);
}
}
}