3779
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1 /*
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2 * Copyright (c) 2011, Oracle and/or its affiliates. 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 Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA
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20 * or visit www.oracle.com if you need additional information or have any
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21 * questions.
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22 *
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23 */
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24
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25 #include "precompiled.hpp"
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26 #include "utilities/quickSort.hpp"
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27
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28 #ifndef PRODUCT
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29
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30 // Unit tests
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31
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32 #include "runtime/os.hpp"
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33 #include <stdlib.h>
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34
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35 static int test_comparator(int a, int b) {
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36 if (a == b) {
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37 return 0;
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38 }
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39 if (a < b) {
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40 return -1;
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41 }
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42 return 1;
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43 }
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44
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45 static int test_even_odd_comparator(int a, int b) {
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46 bool a_is_odd = (a % 2) == 1;
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47 bool b_is_odd = (b % 2) == 1;
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48 if (a_is_odd == b_is_odd) {
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49 return 0;
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50 }
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51 if (a_is_odd) {
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52 return -1;
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53 }
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54 return 1;
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55 }
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56
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57 static int test_stdlib_comparator(const void* a, const void* b) {
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58 int ai = *(int*)a;
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59 int bi = *(int*)b;
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60 if (ai == bi) {
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61 return 0;
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62 }
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63 if (ai < bi) {
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64 return -1;
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65 }
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66 return 1;
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67 }
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68
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69 void QuickSort::print_array(const char* prefix, int* array, int length) {
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70 tty->print("%s:", prefix);
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71 for (int i = 0; i < length; i++) {
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72 tty->print(" %d", array[i]);
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73 }
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74 tty->print_cr("");
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75 }
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76
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77 bool QuickSort::compare_arrays(int* actual, int* expected, int length) {
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78 for (int i = 0; i < length; i++) {
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79 if (actual[i] != expected[i]) {
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80 print_array("Sorted array ", actual, length);
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81 print_array("Expected array", expected, length);
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82 return false;
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83 }
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84 }
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85 return true;
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86 }
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87
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88 template <class C>
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89 bool QuickSort::sort_and_compare(int* arrayToSort, int* expectedResult, int length, C comparator, bool idempotent) {
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90 sort<int, C>(arrayToSort, length, comparator, idempotent);
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91 return compare_arrays(arrayToSort, expectedResult, length);
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92 }
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93
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94 bool QuickSort::test_quick_sort() {
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95 tty->print_cr("test_quick_sort\n");
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96 {
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97 int* test_array = NULL;
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98 int* expected_array = NULL;
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99 assert(sort_and_compare(test_array, expected_array, 0, test_comparator), "Empty array not handled");
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100 }
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101 {
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102 int test_array[] = {3};
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103 int expected_array[] = {3};
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104 assert(sort_and_compare(test_array, expected_array, 1, test_comparator), "Single value array not handled");
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105 }
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106 {
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107 int test_array[] = {3,2};
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108 int expected_array[] = {2,3};
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109 assert(sort_and_compare(test_array, expected_array, 2, test_comparator), "Array with 2 values not correctly sorted");
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110 }
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111 {
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112 int test_array[] = {3,2,1};
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113 int expected_array[] = {1,2,3};
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114 assert(sort_and_compare(test_array, expected_array, 3, test_comparator), "Array with 3 values not correctly sorted");
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115 }
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116 {
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117 int test_array[] = {4,3,2,1};
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118 int expected_array[] = {1,2,3,4};
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119 assert(sort_and_compare(test_array, expected_array, 4, test_comparator), "Array with 4 values not correctly sorted");
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120 }
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121 {
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122 int test_array[] = {7,1,5,3,6,9,8,2,4,0};
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123 int expected_array[] = {0,1,2,3,4,5,6,7,8,9};
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124 assert(sort_and_compare(test_array, expected_array, 10, test_comparator), "Array with 10 values not correctly sorted");
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125 }
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126 {
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127 int test_array[] = {4,4,1,4};
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128 int expected_array[] = {1,4,4,4};
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129 assert(sort_and_compare(test_array, expected_array, 4, test_comparator), "3 duplicates not sorted correctly");
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130 }
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131 {
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132 int test_array[] = {0,1,2,3,4,5,6,7,8,9};
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133 int expected_array[] = {0,1,2,3,4,5,6,7,8,9};
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134 assert(sort_and_compare(test_array, expected_array, 10, test_comparator), "Already sorted array not correctly sorted");
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135 }
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136 {
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137 // one of the random arrays that found an issue in the partion method.
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138 int test_array[] = {76,46,81,8,64,56,75,11,51,55,11,71,59,27,9,64,69,75,21,25,39,40,44,32,7,8,40,41,24,78,24,74,9,65,28,6,40,31,22,13,27,82};
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139 int expected_array[] = {6,7,8,8,9,9,11,11,13,21,22,24,24,25,27,27,28,31,32,39,40,40,40,41,44,46,51,55,56,59,64,64,65,69,71,74,75,75,76,78,81,82};
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140 assert(sort_and_compare(test_array, expected_array, 42, test_comparator), "Not correctly sorted");
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141 }
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142 {
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143 int test_array[] = {2,8,1,4};
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144 int expected_array[] = {1,4,2,8};
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145 assert(sort_and_compare(test_array, expected_array, 4, test_even_odd_comparator), "Even/odd not sorted correctly");
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146 }
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147 { // Some idempotent tests
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148 {
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149 // An array of lenght 3 is only sorted by find_pivot. Make sure that it is idempotent.
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150 int test_array[] = {1,4,8};
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151 int expected_array[] = {1,4,8};
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152 assert(sort_and_compare(test_array, expected_array, 3, test_even_odd_comparator, true), "Even/odd not idempotent");
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153 }
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154 {
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155 int test_array[] = {1,7,9,4,8,2};
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156 int expected_array[] = {1,7,9,4,8,2};
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157 assert(sort_and_compare(test_array, expected_array, 6, test_even_odd_comparator, true), "Even/odd not idempotent");
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158 }
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159 {
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160 int test_array[] = {1,9,7,4,2,8};
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161 int expected_array[] = {1,9,7,4,2,8};
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162 assert(sort_and_compare(test_array, expected_array, 6, test_even_odd_comparator, true), "Even/odd not idempotent");
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163 }
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164 {
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165 int test_array[] = {7,9,1,2,8,4};
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166 int expected_array[] = {7,9,1,2,8,4};
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167 assert(sort_and_compare(test_array, expected_array, 6, test_even_odd_comparator, true), "Even/odd not idempotent");
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168 }
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169 {
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170 int test_array[] = {7,1,9,2,4,8};
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171 int expected_array[] = {7,1,9,2,4,8};
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172 assert(sort_and_compare(test_array, expected_array, 6, test_even_odd_comparator, true), "Even/odd not idempotent");
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173 }
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174 {
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175 int test_array[] = {9,1,7,4,8,2};
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176 int expected_array[] = {9,1,7,4,8,2};
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177 assert(sort_and_compare(test_array, expected_array, 6, test_even_odd_comparator, true), "Even/odd not idempotent");
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178 }
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179 {
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180 int test_array[] = {9,7,1,4,2,8};
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181 int expected_array[] = {9,7,1,4,2,8};
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182 assert(sort_and_compare(test_array, expected_array, 6, test_even_odd_comparator, true), "Even/odd not idempotent");
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183 }
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184 }
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185
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186 // test sorting random arrays
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187 for (int i = 0; i < 1000; i++) {
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188 int length = os::random() % 100;
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189 int* test_array = new int[length];
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190 int* expected_array = new int[length];
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191 for (int j = 0; j < length; j++) {
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192 // Choose random values, but get a chance of getting duplicates
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193 test_array[j] = os::random() % (length * 2);
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194 expected_array[j] = test_array[j];
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195 }
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196
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197 // Compare sorting to stdlib::qsort()
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198 qsort(expected_array, length, sizeof(int), test_stdlib_comparator);
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199 assert(sort_and_compare(test_array, expected_array, length, test_comparator), "Random array not correctly sorted");
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200
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201 // Make sure sorting is idempotent.
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202 // Both test_array and expected_array are sorted by the test_comparator.
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203 // Now sort them once with the test_even_odd_comparator. Then sort the
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204 // test_array one more time with test_even_odd_comparator and verify that
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205 // it is idempotent.
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206 sort(expected_array, length, test_even_odd_comparator, true);
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207 sort(test_array, length, test_even_odd_comparator, true);
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208 assert(compare_arrays(test_array, expected_array, length), "Sorting identical arrays rendered different results");
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209 sort(test_array, length, test_even_odd_comparator, true);
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210 assert(compare_arrays(test_array, expected_array, length), "Sorting already sorted array changed order of elements - not idempotent");
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211
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212 delete[] test_array;
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213 delete[] expected_array;
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214 }
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215 return true;
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216 }
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217
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218 #endif
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