0
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1 /*
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2 * Copyright 1997-2006 Sun Microsystems, Inc. All Rights Reserved.
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3 * DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
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4 *
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5 * This code is free software; you can redistribute it and/or modify it
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6 * under the terms of the GNU General Public License version 2 only, as
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7 * published by the Free Software Foundation.
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8 *
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9 * This code is distributed in the hope that it will be useful, but WITHOUT
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10 * ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
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11 * FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
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12 * version 2 for more details (a copy is included in the LICENSE file that
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13 * accompanied this code).
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14 *
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15 * You should have received a copy of the GNU General Public License version
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16 * 2 along with this work; if not, write to the Free Software Foundation,
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17 * Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA.
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18 *
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19 * Please contact Sun Microsystems, Inc., 4150 Network Circle, Santa Clara,
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20 * CA 95054 USA or visit www.sun.com if you need additional information or
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21 * have any questions.
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22 *
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23 */
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24
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25 # include "incls/_precompiled.incl"
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26 # include "incls/_bitMap.cpp.incl"
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27
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28
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342
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29 BitMap::BitMap(bm_word_t* map, idx_t size_in_bits) :
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30 _map(map), _size(size_in_bits)
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31 {
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32 assert(sizeof(bm_word_t) == BytesPerWord, "Implementation assumption.");
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33 assert(size_in_bits >= 0, "just checking");
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34 }
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35
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36
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342
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37 BitMap::BitMap(idx_t size_in_bits, bool in_resource_area) :
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38 _map(NULL), _size(0)
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39 {
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40 assert(sizeof(bm_word_t) == BytesPerWord, "Implementation assumption.");
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41 resize(size_in_bits, in_resource_area);
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42 }
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43
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44
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342
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45 void BitMap::verify_index(idx_t index) const {
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46 assert(index < _size, "BitMap index out of bounds");
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47 }
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48
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49 void BitMap::verify_range(idx_t beg_index, idx_t end_index) const {
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50 #ifdef ASSERT
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51 assert(beg_index <= end_index, "BitMap range error");
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52 // Note that [0,0) and [size,size) are both valid ranges.
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53 if (end_index != _size) verify_index(end_index);
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54 #endif
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55 }
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56
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57 void BitMap::resize(idx_t size_in_bits, bool in_resource_area) {
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58 assert(size_in_bits >= 0, "just checking");
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342
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59 idx_t old_size_in_words = size_in_words();
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60 bm_word_t* old_map = map();
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61
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62 _size = size_in_bits;
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342
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63 idx_t new_size_in_words = size_in_words();
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64 if (in_resource_area) {
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65 _map = NEW_RESOURCE_ARRAY(bm_word_t, new_size_in_words);
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66 } else {
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67 if (old_map != NULL) FREE_C_HEAP_ARRAY(bm_word_t, _map);
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68 _map = NEW_C_HEAP_ARRAY(bm_word_t, new_size_in_words);
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69 }
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70 Copy::disjoint_words((HeapWord*)old_map, (HeapWord*) _map,
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71 MIN2(old_size_in_words, new_size_in_words));
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72 if (new_size_in_words > old_size_in_words) {
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73 clear_range_of_words(old_size_in_words, size_in_words());
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74 }
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75 }
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76
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77 void BitMap::set_range_within_word(idx_t beg, idx_t end) {
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78 // With a valid range (beg <= end), this test ensures that end != 0, as
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79 // required by inverted_bit_mask_for_range. Also avoids an unnecessary write.
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80 if (beg != end) {
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342
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81 bm_word_t mask = inverted_bit_mask_for_range(beg, end);
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82 *word_addr(beg) |= ~mask;
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83 }
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84 }
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85
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86 void BitMap::clear_range_within_word(idx_t beg, idx_t end) {
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87 // With a valid range (beg <= end), this test ensures that end != 0, as
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88 // required by inverted_bit_mask_for_range. Also avoids an unnecessary write.
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89 if (beg != end) {
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342
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90 bm_word_t mask = inverted_bit_mask_for_range(beg, end);
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91 *word_addr(beg) &= mask;
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92 }
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93 }
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94
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95 void BitMap::par_put_range_within_word(idx_t beg, idx_t end, bool value) {
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96 assert(value == 0 || value == 1, "0 for clear, 1 for set");
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97 // With a valid range (beg <= end), this test ensures that end != 0, as
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98 // required by inverted_bit_mask_for_range. Also avoids an unnecessary write.
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99 if (beg != end) {
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100 intptr_t* pw = (intptr_t*)word_addr(beg);
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101 intptr_t w = *pw;
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102 intptr_t mr = (intptr_t)inverted_bit_mask_for_range(beg, end);
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103 intptr_t nw = value ? (w | ~mr) : (w & mr);
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104 while (true) {
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105 intptr_t res = Atomic::cmpxchg_ptr(nw, pw, w);
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106 if (res == w) break;
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107 w = *pw;
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108 nw = value ? (w | ~mr) : (w & mr);
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109 }
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110 }
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111 }
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112
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113 void BitMap::set_range(idx_t beg, idx_t end) {
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114 verify_range(beg, end);
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115
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116 idx_t beg_full_word = word_index_round_up(beg);
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117 idx_t end_full_word = word_index(end);
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118
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119 if (beg_full_word < end_full_word) {
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120 // The range includes at least one full word.
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121 set_range_within_word(beg, bit_index(beg_full_word));
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122 set_range_of_words(beg_full_word, end_full_word);
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123 set_range_within_word(bit_index(end_full_word), end);
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124 } else {
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125 // The range spans at most 2 partial words.
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126 idx_t boundary = MIN2(bit_index(beg_full_word), end);
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127 set_range_within_word(beg, boundary);
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128 set_range_within_word(boundary, end);
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129 }
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130 }
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131
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132 void BitMap::clear_range(idx_t beg, idx_t end) {
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133 verify_range(beg, end);
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134
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135 idx_t beg_full_word = word_index_round_up(beg);
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136 idx_t end_full_word = word_index(end);
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137
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138 if (beg_full_word < end_full_word) {
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139 // The range includes at least one full word.
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140 clear_range_within_word(beg, bit_index(beg_full_word));
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141 clear_range_of_words(beg_full_word, end_full_word);
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142 clear_range_within_word(bit_index(end_full_word), end);
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143 } else {
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144 // The range spans at most 2 partial words.
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145 idx_t boundary = MIN2(bit_index(beg_full_word), end);
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146 clear_range_within_word(beg, boundary);
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147 clear_range_within_word(boundary, end);
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148 }
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149 }
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150
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151 void BitMap::set_large_range(idx_t beg, idx_t end) {
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152 verify_range(beg, end);
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153
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154 idx_t beg_full_word = word_index_round_up(beg);
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155 idx_t end_full_word = word_index(end);
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156
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157 assert(end_full_word - beg_full_word >= 32,
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158 "the range must include at least 32 bytes");
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159
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160 // The range includes at least one full word.
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161 set_range_within_word(beg, bit_index(beg_full_word));
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162 set_large_range_of_words(beg_full_word, end_full_word);
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163 set_range_within_word(bit_index(end_full_word), end);
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164 }
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165
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166 void BitMap::clear_large_range(idx_t beg, idx_t end) {
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167 verify_range(beg, end);
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168
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169 idx_t beg_full_word = word_index_round_up(beg);
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170 idx_t end_full_word = word_index(end);
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171
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172 assert(end_full_word - beg_full_word >= 32,
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173 "the range must include at least 32 bytes");
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174
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175 // The range includes at least one full word.
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176 clear_range_within_word(beg, bit_index(beg_full_word));
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177 clear_large_range_of_words(beg_full_word, end_full_word);
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178 clear_range_within_word(bit_index(end_full_word), end);
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179 }
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180
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342
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181 void BitMap::mostly_disjoint_range_union(BitMap* from_bitmap,
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182 idx_t from_start_index,
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183 idx_t to_start_index,
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184 size_t word_num) {
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185 // Ensure that the parameters are correct.
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186 // These shouldn't be that expensive to check, hence I left them as
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187 // guarantees.
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188 guarantee(from_bitmap->bit_in_word(from_start_index) == 0,
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189 "it should be aligned on a word boundary");
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190 guarantee(bit_in_word(to_start_index) == 0,
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191 "it should be aligned on a word boundary");
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192 guarantee(word_num >= 2, "word_num should be at least 2");
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193
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194 intptr_t* from = (intptr_t*) from_bitmap->word_addr(from_start_index);
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195 intptr_t* to = (intptr_t*) word_addr(to_start_index);
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196
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197 if (*from != 0) {
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198 // if it's 0, then there's no point in doing the CAS
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199 while (true) {
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200 intptr_t old_value = *to;
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201 intptr_t new_value = old_value | *from;
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202 intptr_t res = Atomic::cmpxchg_ptr(new_value, to, old_value);
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203 if (res == old_value) break;
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204 }
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205 }
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206 ++from;
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207 ++to;
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208
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209 for (size_t i = 0; i < word_num - 2; ++i) {
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210 if (*from != 0) {
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211 // if it's 0, then there's no point in doing the CAS
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212 assert(*to == 0, "nobody else should be writing here");
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213 intptr_t new_value = *from;
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214 *to = new_value;
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215 }
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216
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217 ++from;
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218 ++to;
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219 }
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220
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221 if (*from != 0) {
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222 // if it's 0, then there's no point in doing the CAS
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223 while (true) {
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224 intptr_t old_value = *to;
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225 intptr_t new_value = old_value | *from;
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226 intptr_t res = Atomic::cmpxchg_ptr(new_value, to, old_value);
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227 if (res == old_value) break;
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228 }
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229 }
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230
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231 // the -1 is because we didn't advance them after the final CAS
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232 assert(from ==
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233 (intptr_t*) from_bitmap->word_addr(from_start_index) + word_num - 1,
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234 "invariant");
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235 assert(to == (intptr_t*) word_addr(to_start_index) + word_num - 1,
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236 "invariant");
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237 }
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238
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239 void BitMap::at_put(idx_t offset, bool value) {
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240 if (value) {
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241 set_bit(offset);
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242 } else {
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243 clear_bit(offset);
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244 }
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245 }
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246
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247 // Return true to indicate that this thread changed
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248 // the bit, false to indicate that someone else did.
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249 // In either case, the requested bit is in the
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250 // requested state some time during the period that
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251 // this thread is executing this call. More importantly,
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252 // if no other thread is executing an action to
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253 // change the requested bit to a state other than
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254 // the one that this thread is trying to set it to,
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255 // then the the bit is in the expected state
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256 // at exit from this method. However, rather than
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257 // make such a strong assertion here, based on
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258 // assuming such constrained use (which though true
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259 // today, could change in the future to service some
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260 // funky parallel algorithm), we encourage callers
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261 // to do such verification, as and when appropriate.
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262 bool BitMap::par_at_put(idx_t bit, bool value) {
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263 return value ? par_set_bit(bit) : par_clear_bit(bit);
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264 }
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265
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266 void BitMap::at_put_grow(idx_t offset, bool value) {
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267 if (offset >= size()) {
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268 resize(2 * MAX2(size(), offset));
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269 }
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270 at_put(offset, value);
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271 }
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272
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273 void BitMap::at_put_range(idx_t start_offset, idx_t end_offset, bool value) {
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274 if (value) {
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275 set_range(start_offset, end_offset);
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276 } else {
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277 clear_range(start_offset, end_offset);
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278 }
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279 }
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280
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281 void BitMap::par_at_put_range(idx_t beg, idx_t end, bool value) {
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282 verify_range(beg, end);
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283
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284 idx_t beg_full_word = word_index_round_up(beg);
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285 idx_t end_full_word = word_index(end);
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286
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287 if (beg_full_word < end_full_word) {
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288 // The range includes at least one full word.
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289 par_put_range_within_word(beg, bit_index(beg_full_word), value);
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290 if (value) {
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291 set_range_of_words(beg_full_word, end_full_word);
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292 } else {
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293 clear_range_of_words(beg_full_word, end_full_word);
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294 }
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295 par_put_range_within_word(bit_index(end_full_word), end, value);
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296 } else {
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297 // The range spans at most 2 partial words.
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298 idx_t boundary = MIN2(bit_index(beg_full_word), end);
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299 par_put_range_within_word(beg, boundary, value);
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300 par_put_range_within_word(boundary, end, value);
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301 }
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302
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303 }
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304
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305 void BitMap::at_put_large_range(idx_t beg, idx_t end, bool value) {
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306 if (value) {
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307 set_large_range(beg, end);
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308 } else {
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309 clear_large_range(beg, end);
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310 }
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311 }
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312
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313 void BitMap::par_at_put_large_range(idx_t beg, idx_t end, bool value) {
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314 verify_range(beg, end);
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315
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316 idx_t beg_full_word = word_index_round_up(beg);
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317 idx_t end_full_word = word_index(end);
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318
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319 assert(end_full_word - beg_full_word >= 32,
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320 "the range must include at least 32 bytes");
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321
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322 // The range includes at least one full word.
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323 par_put_range_within_word(beg, bit_index(beg_full_word), value);
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324 if (value) {
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325 set_large_range_of_words(beg_full_word, end_full_word);
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326 } else {
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327 clear_large_range_of_words(beg_full_word, end_full_word);
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328 }
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329 par_put_range_within_word(bit_index(end_full_word), end, value);
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330 }
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331
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332 bool BitMap::contains(const BitMap other) const {
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333 assert(size() == other.size(), "must have same size");
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334 bm_word_t* dest_map = map();
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335 bm_word_t* other_map = other.map();
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336 idx_t size = size_in_words();
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337 for (idx_t index = 0; index < size_in_words(); index++) {
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342
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338 bm_word_t word_union = dest_map[index] | other_map[index];
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339 // If this has more bits set than dest_map[index], then other is not a
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340 // subset.
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341 if (word_union != dest_map[index]) return false;
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342 }
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343 return true;
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344 }
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345
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346 bool BitMap::intersects(const BitMap other) const {
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347 assert(size() == other.size(), "must have same size");
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342
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348 bm_word_t* dest_map = map();
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349 bm_word_t* other_map = other.map();
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350 idx_t size = size_in_words();
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351 for (idx_t index = 0; index < size_in_words(); index++) {
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352 if ((dest_map[index] & other_map[index]) != 0) return true;
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353 }
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354 // Otherwise, no intersection.
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355 return false;
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356 }
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357
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358 void BitMap::set_union(BitMap other) {
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359 assert(size() == other.size(), "must have same size");
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342
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360 bm_word_t* dest_map = map();
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361 bm_word_t* other_map = other.map();
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362 idx_t size = size_in_words();
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363 for (idx_t index = 0; index < size_in_words(); index++) {
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364 dest_map[index] = dest_map[index] | other_map[index];
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365 }
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366 }
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367
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368
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369 void BitMap::set_difference(BitMap other) {
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370 assert(size() == other.size(), "must have same size");
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342
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371 bm_word_t* dest_map = map();
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372 bm_word_t* other_map = other.map();
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373 idx_t size = size_in_words();
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374 for (idx_t index = 0; index < size_in_words(); index++) {
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375 dest_map[index] = dest_map[index] & ~(other_map[index]);
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376 }
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377 }
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378
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379
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380 void BitMap::set_intersection(BitMap other) {
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381 assert(size() == other.size(), "must have same size");
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342
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382 bm_word_t* dest_map = map();
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383 bm_word_t* other_map = other.map();
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384 idx_t size = size_in_words();
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385 for (idx_t index = 0; index < size; index++) {
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386 dest_map[index] = dest_map[index] & other_map[index];
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387 }
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388 }
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389
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390
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342
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391 void BitMap::set_intersection_at_offset(BitMap other, idx_t offset) {
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392 assert(other.size() >= offset, "offset not in range");
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393 assert(other.size() - offset >= size(), "other not large enough");
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394 // XXX Ideally, we would remove this restriction.
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395 guarantee((offset % (sizeof(bm_word_t) * BitsPerByte)) == 0,
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396 "Only handle aligned cases so far.");
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397 bm_word_t* dest_map = map();
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398 bm_word_t* other_map = other.map();
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399 idx_t offset_word_ind = word_index(offset);
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400 idx_t size = size_in_words();
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401 for (idx_t index = 0; index < size; index++) {
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402 dest_map[index] = dest_map[index] & other_map[offset_word_ind + index];
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403 }
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404 }
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405
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406 bool BitMap::set_union_with_result(BitMap other) {
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407 assert(size() == other.size(), "must have same size");
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408 bool changed = false;
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342
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409 bm_word_t* dest_map = map();
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410 bm_word_t* other_map = other.map();
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411 idx_t size = size_in_words();
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412 for (idx_t index = 0; index < size; index++) {
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413 idx_t temp = map(index) | other_map[index];
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414 changed = changed || (temp != map(index));
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415 map()[index] = temp;
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416 }
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417 return changed;
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418 }
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419
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420
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421 bool BitMap::set_difference_with_result(BitMap other) {
|
|
422 assert(size() == other.size(), "must have same size");
|
|
423 bool changed = false;
|
342
|
424 bm_word_t* dest_map = map();
|
|
425 bm_word_t* other_map = other.map();
|
0
|
426 idx_t size = size_in_words();
|
|
427 for (idx_t index = 0; index < size; index++) {
|
342
|
428 bm_word_t temp = dest_map[index] & ~(other_map[index]);
|
0
|
429 changed = changed || (temp != dest_map[index]);
|
|
430 dest_map[index] = temp;
|
|
431 }
|
|
432 return changed;
|
|
433 }
|
|
434
|
|
435
|
|
436 bool BitMap::set_intersection_with_result(BitMap other) {
|
|
437 assert(size() == other.size(), "must have same size");
|
|
438 bool changed = false;
|
342
|
439 bm_word_t* dest_map = map();
|
|
440 bm_word_t* other_map = other.map();
|
0
|
441 idx_t size = size_in_words();
|
|
442 for (idx_t index = 0; index < size; index++) {
|
342
|
443 bm_word_t orig = dest_map[index];
|
|
444 bm_word_t temp = orig & other_map[index];
|
0
|
445 changed = changed || (temp != orig);
|
|
446 dest_map[index] = temp;
|
|
447 }
|
|
448 return changed;
|
|
449 }
|
|
450
|
|
451
|
|
452 void BitMap::set_from(BitMap other) {
|
|
453 assert(size() == other.size(), "must have same size");
|
342
|
454 bm_word_t* dest_map = map();
|
|
455 bm_word_t* other_map = other.map();
|
0
|
456 idx_t size = size_in_words();
|
|
457 for (idx_t index = 0; index < size; index++) {
|
|
458 dest_map[index] = other_map[index];
|
|
459 }
|
|
460 }
|
|
461
|
|
462
|
|
463 bool BitMap::is_same(BitMap other) {
|
|
464 assert(size() == other.size(), "must have same size");
|
342
|
465 bm_word_t* dest_map = map();
|
|
466 bm_word_t* other_map = other.map();
|
0
|
467 idx_t size = size_in_words();
|
|
468 for (idx_t index = 0; index < size; index++) {
|
|
469 if (dest_map[index] != other_map[index]) return false;
|
|
470 }
|
|
471 return true;
|
|
472 }
|
|
473
|
|
474 bool BitMap::is_full() const {
|
342
|
475 bm_word_t* word = map();
|
0
|
476 idx_t rest = size();
|
|
477 for (; rest >= (idx_t) BitsPerWord; rest -= BitsPerWord) {
|
342
|
478 if (*word != (bm_word_t) AllBits) return false;
|
0
|
479 word++;
|
|
480 }
|
342
|
481 return rest == 0 || (*word | ~right_n_bits((int)rest)) == (bm_word_t) AllBits;
|
0
|
482 }
|
|
483
|
|
484
|
|
485 bool BitMap::is_empty() const {
|
342
|
486 bm_word_t* word = map();
|
0
|
487 idx_t rest = size();
|
|
488 for (; rest >= (idx_t) BitsPerWord; rest -= BitsPerWord) {
|
342
|
489 if (*word != (bm_word_t) NoBits) return false;
|
0
|
490 word++;
|
|
491 }
|
342
|
492 return rest == 0 || (*word & right_n_bits((int)rest)) == (bm_word_t) NoBits;
|
0
|
493 }
|
|
494
|
|
495 void BitMap::clear_large() {
|
|
496 clear_large_range_of_words(0, size_in_words());
|
|
497 }
|
|
498
|
|
499 // Note that if the closure itself modifies the bitmap
|
|
500 // then modifications in and to the left of the _bit_ being
|
|
501 // currently sampled will not be seen. Note also that the
|
|
502 // interval [leftOffset, rightOffset) is right open.
|
342
|
503 bool BitMap::iterate(BitMapClosure* blk, idx_t leftOffset, idx_t rightOffset) {
|
0
|
504 verify_range(leftOffset, rightOffset);
|
|
505
|
|
506 idx_t startIndex = word_index(leftOffset);
|
|
507 idx_t endIndex = MIN2(word_index(rightOffset) + 1, size_in_words());
|
|
508 for (idx_t index = startIndex, offset = leftOffset;
|
|
509 offset < rightOffset && index < endIndex;
|
|
510 offset = (++index) << LogBitsPerWord) {
|
|
511 idx_t rest = map(index) >> (offset & (BitsPerWord - 1));
|
342
|
512 for (; offset < rightOffset && rest != (bm_word_t)NoBits; offset++) {
|
0
|
513 if (rest & 1) {
|
342
|
514 if (!blk->do_bit(offset)) return false;
|
0
|
515 // resample at each closure application
|
|
516 // (see, for instance, CMS bug 4525989)
|
|
517 rest = map(index) >> (offset & (BitsPerWord -1));
|
|
518 }
|
|
519 rest = rest >> 1;
|
|
520 }
|
|
521 }
|
342
|
522 return true;
|
|
523 }
|
|
524
|
|
525 BitMap::idx_t* BitMap::_pop_count_table = NULL;
|
|
526
|
|
527 void BitMap::init_pop_count_table() {
|
|
528 if (_pop_count_table == NULL) {
|
|
529 BitMap::idx_t *table = NEW_C_HEAP_ARRAY(idx_t, 256);
|
|
530 for (uint i = 0; i < 256; i++) {
|
|
531 table[i] = num_set_bits(i);
|
|
532 }
|
|
533
|
|
534 intptr_t res = Atomic::cmpxchg_ptr((intptr_t) table,
|
|
535 (intptr_t*) &_pop_count_table,
|
|
536 (intptr_t) NULL_WORD);
|
|
537 if (res != NULL_WORD) {
|
|
538 guarantee( _pop_count_table == (void*) res, "invariant" );
|
|
539 FREE_C_HEAP_ARRAY(bm_word_t, table);
|
|
540 }
|
|
541 }
|
0
|
542 }
|
|
543
|
342
|
544 BitMap::idx_t BitMap::num_set_bits(bm_word_t w) {
|
|
545 idx_t bits = 0;
|
0
|
546
|
342
|
547 while (w != 0) {
|
|
548 while ((w & 1) == 0) {
|
|
549 w >>= 1;
|
0
|
550 }
|
342
|
551 bits++;
|
|
552 w >>= 1;
|
0
|
553 }
|
342
|
554 return bits;
|
0
|
555 }
|
|
556
|
342
|
557 BitMap::idx_t BitMap::num_set_bits_from_table(unsigned char c) {
|
|
558 assert(_pop_count_table != NULL, "precondition");
|
|
559 return _pop_count_table[c];
|
|
560 }
|
0
|
561
|
342
|
562 BitMap::idx_t BitMap::count_one_bits() const {
|
|
563 init_pop_count_table(); // If necessary.
|
|
564 idx_t sum = 0;
|
|
565 typedef unsigned char uchar;
|
|
566 for (idx_t i = 0; i < size_in_words(); i++) {
|
|
567 bm_word_t w = map()[i];
|
|
568 for (size_t j = 0; j < sizeof(bm_word_t); j++) {
|
|
569 sum += num_set_bits_from_table(uchar(w & 255));
|
|
570 w >>= 8;
|
0
|
571 }
|
|
572 }
|
342
|
573 return sum;
|
0
|
574 }
|
|
575
|
342
|
576
|
0
|
577 #ifndef PRODUCT
|
|
578
|
|
579 void BitMap::print_on(outputStream* st) const {
|
|
580 tty->print("Bitmap(%d):", size());
|
|
581 for (idx_t index = 0; index < size(); index++) {
|
|
582 tty->print("%c", at(index) ? '1' : '0');
|
|
583 }
|
|
584 tty->cr();
|
|
585 }
|
|
586
|
|
587 #endif
|
|
588
|
|
589
|
342
|
590 BitMap2D::BitMap2D(bm_word_t* map, idx_t size_in_slots, idx_t bits_per_slot)
|
0
|
591 : _bits_per_slot(bits_per_slot)
|
|
592 , _map(map, size_in_slots * bits_per_slot)
|
|
593 {
|
|
594 }
|
|
595
|
|
596
|
|
597 BitMap2D::BitMap2D(idx_t size_in_slots, idx_t bits_per_slot)
|
|
598 : _bits_per_slot(bits_per_slot)
|
|
599 , _map(size_in_slots * bits_per_slot)
|
|
600 {
|
|
601 }
|