0
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1 /*
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2 * Copyright 1999-2006 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/_c1_Instruction.cpp.incl"
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27
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28
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29 // Implementation of Instruction
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30
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31
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32 int Instruction::_next_id = 0;
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33
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34 #ifdef ASSERT
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35 void Instruction::create_hi_word() {
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36 assert(type()->is_double_word() && _hi_word == NULL, "only double word has high word");
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37 _hi_word = new HiWord(this);
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38 }
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39 #endif
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40
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41 Instruction::Condition Instruction::mirror(Condition cond) {
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42 switch (cond) {
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43 case eql: return eql;
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44 case neq: return neq;
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45 case lss: return gtr;
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46 case leq: return geq;
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47 case gtr: return lss;
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48 case geq: return leq;
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49 }
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50 ShouldNotReachHere();
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51 return eql;
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52 }
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53
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54
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55 Instruction::Condition Instruction::negate(Condition cond) {
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56 switch (cond) {
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57 case eql: return neq;
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58 case neq: return eql;
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59 case lss: return geq;
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60 case leq: return gtr;
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61 case gtr: return leq;
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62 case geq: return lss;
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63 }
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64 ShouldNotReachHere();
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65 return eql;
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66 }
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67
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68
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69 Instruction* Instruction::prev(BlockBegin* block) {
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70 Instruction* p = NULL;
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71 Instruction* q = block;
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72 while (q != this) {
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73 assert(q != NULL, "this is not in the block's instruction list");
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74 p = q; q = q->next();
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75 }
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76 return p;
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77 }
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78
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79
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80 #ifndef PRODUCT
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81 void Instruction::print() {
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82 InstructionPrinter ip;
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83 print(ip);
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84 }
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85
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86
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87 void Instruction::print_line() {
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88 InstructionPrinter ip;
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89 ip.print_line(this);
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90 }
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91
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92
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93 void Instruction::print(InstructionPrinter& ip) {
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94 ip.print_head();
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95 ip.print_line(this);
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96 tty->cr();
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97 }
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98 #endif // PRODUCT
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99
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100
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101 // perform constant and interval tests on index value
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102 bool AccessIndexed::compute_needs_range_check() {
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103 Constant* clength = length()->as_Constant();
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104 Constant* cindex = index()->as_Constant();
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105 if (clength && cindex) {
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106 IntConstant* l = clength->type()->as_IntConstant();
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107 IntConstant* i = cindex->type()->as_IntConstant();
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108 if (l && i && i->value() < l->value() && i->value() >= 0) {
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109 return false;
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110 }
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111 }
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112 return true;
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113 }
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114
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115
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116 ciType* LoadIndexed::exact_type() const {
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117 ciType* array_type = array()->exact_type();
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118 if (array_type == NULL) {
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119 return NULL;
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120 }
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121 assert(array_type->is_array_klass(), "what else?");
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122 ciArrayKlass* ak = (ciArrayKlass*)array_type;
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123
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124 if (ak->element_type()->is_instance_klass()) {
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125 ciInstanceKlass* ik = (ciInstanceKlass*)ak->element_type();
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126 if (ik->is_loaded() && ik->is_final()) {
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127 return ik;
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128 }
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129 }
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130 return NULL;
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131 }
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132
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133
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134 ciType* LoadIndexed::declared_type() const {
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135 ciType* array_type = array()->declared_type();
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136 if (array_type == NULL) {
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137 return NULL;
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138 }
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139 assert(array_type->is_array_klass(), "what else?");
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140 ciArrayKlass* ak = (ciArrayKlass*)array_type;
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141 return ak->element_type();
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142 }
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143
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144
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145 ciType* LoadField::declared_type() const {
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146 return field()->type();
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147 }
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148
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149
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150 ciType* LoadField::exact_type() const {
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151 ciType* type = declared_type();
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152 // for primitive arrays, the declared type is the exact type
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153 if (type->is_type_array_klass()) {
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154 return type;
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155 }
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156 if (type->is_instance_klass()) {
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157 ciInstanceKlass* ik = (ciInstanceKlass*)type;
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158 if (ik->is_loaded() && ik->is_final()) {
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159 return type;
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160 }
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161 }
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162 return NULL;
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163 }
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164
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165
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166 ciType* NewTypeArray::exact_type() const {
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167 return ciTypeArrayKlass::make(elt_type());
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168 }
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169
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170
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171 ciType* NewObjectArray::exact_type() const {
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172 return ciObjArrayKlass::make(klass());
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173 }
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174
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175
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176 ciType* NewInstance::exact_type() const {
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177 return klass();
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178 }
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179
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180
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181 ciType* CheckCast::declared_type() const {
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182 return klass();
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183 }
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184
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185 ciType* CheckCast::exact_type() const {
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186 if (klass()->is_instance_klass()) {
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187 ciInstanceKlass* ik = (ciInstanceKlass*)klass();
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188 if (ik->is_loaded() && ik->is_final()) {
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189 return ik;
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190 }
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191 }
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192 return NULL;
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193 }
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194
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195
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196 void ArithmeticOp::other_values_do(void f(Value*)) {
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197 if (lock_stack() != NULL) lock_stack()->values_do(f);
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198 }
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199
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200 void NullCheck::other_values_do(void f(Value*)) {
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201 lock_stack()->values_do(f);
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202 }
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203
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204 void AccessArray::other_values_do(void f(Value*)) {
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205 if (lock_stack() != NULL) lock_stack()->values_do(f);
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206 }
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207
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208
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209 // Implementation of AccessField
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210
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211 void AccessField::other_values_do(void f(Value*)) {
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212 if (state_before() != NULL) state_before()->values_do(f);
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213 if (lock_stack() != NULL) lock_stack()->values_do(f);
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214 }
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215
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216
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217 // Implementation of StoreIndexed
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218
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219 IRScope* StoreIndexed::scope() const {
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220 return lock_stack()->scope();
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221 }
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222
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223
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224 // Implementation of ArithmeticOp
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225
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226 bool ArithmeticOp::is_commutative() const {
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227 switch (op()) {
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228 case Bytecodes::_iadd: // fall through
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229 case Bytecodes::_ladd: // fall through
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230 case Bytecodes::_fadd: // fall through
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231 case Bytecodes::_dadd: // fall through
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232 case Bytecodes::_imul: // fall through
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233 case Bytecodes::_lmul: // fall through
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234 case Bytecodes::_fmul: // fall through
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235 case Bytecodes::_dmul: return true;
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236 }
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237 return false;
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238 }
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239
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240
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241 bool ArithmeticOp::can_trap() const {
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242 switch (op()) {
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243 case Bytecodes::_idiv: // fall through
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244 case Bytecodes::_ldiv: // fall through
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245 case Bytecodes::_irem: // fall through
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246 case Bytecodes::_lrem: return true;
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247 }
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248 return false;
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249 }
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250
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251
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252 // Implementation of LogicOp
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253
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254 bool LogicOp::is_commutative() const {
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255 #ifdef ASSERT
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256 switch (op()) {
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257 case Bytecodes::_iand: // fall through
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258 case Bytecodes::_land: // fall through
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259 case Bytecodes::_ior : // fall through
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260 case Bytecodes::_lor : // fall through
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261 case Bytecodes::_ixor: // fall through
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262 case Bytecodes::_lxor: break;
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263 default : ShouldNotReachHere();
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264 }
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265 #endif
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266 // all LogicOps are commutative
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267 return true;
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268 }
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269
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270
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271 // Implementation of CompareOp
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272
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273 void CompareOp::other_values_do(void f(Value*)) {
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274 if (state_before() != NULL) state_before()->values_do(f);
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275 }
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276
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277
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278 // Implementation of IfOp
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279
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280 bool IfOp::is_commutative() const {
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281 return cond() == eql || cond() == neq;
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282 }
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283
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284
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285 // Implementation of StateSplit
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286
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287 void StateSplit::substitute(BlockList& list, BlockBegin* old_block, BlockBegin* new_block) {
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288 NOT_PRODUCT(bool assigned = false;)
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289 for (int i = 0; i < list.length(); i++) {
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290 BlockBegin** b = list.adr_at(i);
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291 if (*b == old_block) {
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292 *b = new_block;
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293 NOT_PRODUCT(assigned = true;)
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294 }
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295 }
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296 assert(assigned == true, "should have assigned at least once");
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297 }
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298
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299
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300 IRScope* StateSplit::scope() const {
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301 return _state->scope();
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302 }
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303
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304
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305 void StateSplit::state_values_do(void f(Value*)) {
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306 if (state() != NULL) state()->values_do(f);
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307 }
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308
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309
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310 void BlockBegin::state_values_do(void f(Value*)) {
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311 StateSplit::state_values_do(f);
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312
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313 if (is_set(BlockBegin::exception_entry_flag)) {
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314 for (int i = 0; i < number_of_exception_states(); i++) {
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315 exception_state_at(i)->values_do(f);
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316 }
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317 }
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318 }
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319
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320
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321 void MonitorEnter::state_values_do(void f(Value*)) {
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322 StateSplit::state_values_do(f);
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323 _lock_stack_before->values_do(f);
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324 }
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325
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326
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327 void Intrinsic::state_values_do(void f(Value*)) {
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328 StateSplit::state_values_do(f);
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329 if (lock_stack() != NULL) lock_stack()->values_do(f);
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330 }
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331
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332
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333 // Implementation of Invoke
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334
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335
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336 Invoke::Invoke(Bytecodes::Code code, ValueType* result_type, Value recv, Values* args,
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337 int vtable_index, ciMethod* target)
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338 : StateSplit(result_type)
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339 , _code(code)
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340 , _recv(recv)
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341 , _args(args)
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342 , _vtable_index(vtable_index)
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343 , _target(target)
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344 {
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345 set_flag(TargetIsLoadedFlag, target->is_loaded());
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346 set_flag(TargetIsFinalFlag, target_is_loaded() && target->is_final_method());
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347 set_flag(TargetIsStrictfpFlag, target_is_loaded() && target->is_strict());
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348
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349 assert(args != NULL, "args must exist");
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350 #ifdef ASSERT
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351 values_do(assert_value);
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352 #endif // ASSERT
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353
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354 // provide an initial guess of signature size.
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355 _signature = new BasicTypeList(number_of_arguments() + (has_receiver() ? 1 : 0));
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356 if (has_receiver()) {
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357 _signature->append(as_BasicType(receiver()->type()));
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358 }
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359 for (int i = 0; i < number_of_arguments(); i++) {
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360 ValueType* t = argument_at(i)->type();
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361 BasicType bt = as_BasicType(t);
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362 _signature->append(bt);
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363 }
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364 }
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365
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366
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367 // Implementation of Contant
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368 intx Constant::hash() const {
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369 if (_state == NULL) {
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370 switch (type()->tag()) {
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371 case intTag:
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372 return HASH2(name(), type()->as_IntConstant()->value());
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373 case longTag:
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374 {
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375 jlong temp = type()->as_LongConstant()->value();
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376 return HASH3(name(), high(temp), low(temp));
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377 }
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378 case floatTag:
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379 return HASH2(name(), jint_cast(type()->as_FloatConstant()->value()));
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380 case doubleTag:
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381 {
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382 jlong temp = jlong_cast(type()->as_DoubleConstant()->value());
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383 return HASH3(name(), high(temp), low(temp));
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384 }
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385 case objectTag:
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386 assert(type()->as_ObjectType()->is_loaded(), "can't handle unloaded values");
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387 return HASH2(name(), type()->as_ObjectType()->constant_value());
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388 }
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389 }
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390 return 0;
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391 }
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392
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393 bool Constant::is_equal(Value v) const {
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394 if (v->as_Constant() == NULL) return false;
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395
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396 switch (type()->tag()) {
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397 case intTag:
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398 {
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399 IntConstant* t1 = type()->as_IntConstant();
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400 IntConstant* t2 = v->type()->as_IntConstant();
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401 return (t1 != NULL && t2 != NULL &&
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402 t1->value() == t2->value());
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403 }
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404 case longTag:
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405 {
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406 LongConstant* t1 = type()->as_LongConstant();
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407 LongConstant* t2 = v->type()->as_LongConstant();
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408 return (t1 != NULL && t2 != NULL &&
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409 t1->value() == t2->value());
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410 }
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411 case floatTag:
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412 {
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413 FloatConstant* t1 = type()->as_FloatConstant();
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414 FloatConstant* t2 = v->type()->as_FloatConstant();
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415 return (t1 != NULL && t2 != NULL &&
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416 jint_cast(t1->value()) == jint_cast(t2->value()));
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417 }
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418 case doubleTag:
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419 {
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420 DoubleConstant* t1 = type()->as_DoubleConstant();
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421 DoubleConstant* t2 = v->type()->as_DoubleConstant();
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422 return (t1 != NULL && t2 != NULL &&
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423 jlong_cast(t1->value()) == jlong_cast(t2->value()));
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424 }
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425 case objectTag:
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426 {
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427 ObjectType* t1 = type()->as_ObjectType();
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428 ObjectType* t2 = v->type()->as_ObjectType();
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429 return (t1 != NULL && t2 != NULL &&
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430 t1->is_loaded() && t2->is_loaded() &&
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431 t1->constant_value() == t2->constant_value());
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432 }
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433 }
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434 return false;
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435 }
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436
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437
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438 BlockBegin* Constant::compare(Instruction::Condition cond, Value right,
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439 BlockBegin* true_sux, BlockBegin* false_sux) {
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440 Constant* rc = right->as_Constant();
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441 // other is not a constant
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442 if (rc == NULL) return NULL;
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443
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444 ValueType* lt = type();
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445 ValueType* rt = rc->type();
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446 // different types
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447 if (lt->base() != rt->base()) return NULL;
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448 switch (lt->tag()) {
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449 case intTag: {
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450 int x = lt->as_IntConstant()->value();
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451 int y = rt->as_IntConstant()->value();
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452 switch (cond) {
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453 case If::eql: return x == y ? true_sux : false_sux;
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454 case If::neq: return x != y ? true_sux : false_sux;
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455 case If::lss: return x < y ? true_sux : false_sux;
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456 case If::leq: return x <= y ? true_sux : false_sux;
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457 case If::gtr: return x > y ? true_sux : false_sux;
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458 case If::geq: return x >= y ? true_sux : false_sux;
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459 }
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460 break;
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461 }
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462 case longTag: {
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463 jlong x = lt->as_LongConstant()->value();
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464 jlong y = rt->as_LongConstant()->value();
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465 switch (cond) {
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466 case If::eql: return x == y ? true_sux : false_sux;
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467 case If::neq: return x != y ? true_sux : false_sux;
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468 case If::lss: return x < y ? true_sux : false_sux;
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469 case If::leq: return x <= y ? true_sux : false_sux;
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470 case If::gtr: return x > y ? true_sux : false_sux;
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471 case If::geq: return x >= y ? true_sux : false_sux;
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472 }
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473 break;
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474 }
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475 case objectTag: {
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476 ciObject* xvalue = lt->as_ObjectType()->constant_value();
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477 ciObject* yvalue = rt->as_ObjectType()->constant_value();
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478 assert(xvalue != NULL && yvalue != NULL, "not constants");
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479 if (xvalue->is_loaded() && yvalue->is_loaded()) {
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480 switch (cond) {
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481 case If::eql: return xvalue == yvalue ? true_sux : false_sux;
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482 case If::neq: return xvalue != yvalue ? true_sux : false_sux;
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483 }
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484 }
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485 break;
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486 }
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487 }
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488 return NULL;
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489 }
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490
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491
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492 void Constant::other_values_do(void f(Value*)) {
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493 if (state() != NULL) state()->values_do(f);
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494 }
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495
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496
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497 // Implementation of NewArray
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498
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499 void NewArray::other_values_do(void f(Value*)) {
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500 if (state_before() != NULL) state_before()->values_do(f);
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501 }
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502
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503
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504 // Implementation of TypeCheck
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505
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506 void TypeCheck::other_values_do(void f(Value*)) {
|
|
507 if (state_before() != NULL) state_before()->values_do(f);
|
|
508 }
|
|
509
|
|
510
|
|
511 // Implementation of BlockBegin
|
|
512
|
|
513 int BlockBegin::_next_block_id = 0;
|
|
514
|
|
515
|
|
516 void BlockBegin::set_end(BlockEnd* end) {
|
|
517 assert(end != NULL, "should not reset block end to NULL");
|
|
518 BlockEnd* old_end = _end;
|
|
519 if (end == old_end) {
|
|
520 return;
|
|
521 }
|
|
522 // Must make the predecessors/successors match up with the
|
|
523 // BlockEnd's notion.
|
|
524 int i, n;
|
|
525 if (old_end != NULL) {
|
|
526 // disconnect from the old end
|
|
527 old_end->set_begin(NULL);
|
|
528
|
|
529 // disconnect this block from it's current successors
|
|
530 for (i = 0; i < _successors.length(); i++) {
|
|
531 _successors.at(i)->remove_predecessor(this);
|
|
532 }
|
|
533 }
|
|
534 _end = end;
|
|
535
|
|
536 _successors.clear();
|
|
537 // Now reset successors list based on BlockEnd
|
|
538 n = end->number_of_sux();
|
|
539 for (i = 0; i < n; i++) {
|
|
540 BlockBegin* sux = end->sux_at(i);
|
|
541 _successors.append(sux);
|
|
542 sux->_predecessors.append(this);
|
|
543 }
|
|
544 _end->set_begin(this);
|
|
545 }
|
|
546
|
|
547
|
|
548 void BlockBegin::disconnect_edge(BlockBegin* from, BlockBegin* to) {
|
|
549 // disconnect any edges between from and to
|
|
550 #ifndef PRODUCT
|
|
551 if (PrintIR && Verbose) {
|
|
552 tty->print_cr("Disconnected edge B%d -> B%d", from->block_id(), to->block_id());
|
|
553 }
|
|
554 #endif
|
|
555 for (int s = 0; s < from->number_of_sux();) {
|
|
556 BlockBegin* sux = from->sux_at(s);
|
|
557 if (sux == to) {
|
|
558 int index = sux->_predecessors.index_of(from);
|
|
559 if (index >= 0) {
|
|
560 sux->_predecessors.remove_at(index);
|
|
561 }
|
|
562 from->_successors.remove_at(s);
|
|
563 } else {
|
|
564 s++;
|
|
565 }
|
|
566 }
|
|
567 }
|
|
568
|
|
569
|
|
570 void BlockBegin::disconnect_from_graph() {
|
|
571 // disconnect this block from all other blocks
|
|
572 for (int p = 0; p < number_of_preds(); p++) {
|
|
573 pred_at(p)->remove_successor(this);
|
|
574 }
|
|
575 for (int s = 0; s < number_of_sux(); s++) {
|
|
576 sux_at(s)->remove_predecessor(this);
|
|
577 }
|
|
578 }
|
|
579
|
|
580 void BlockBegin::substitute_sux(BlockBegin* old_sux, BlockBegin* new_sux) {
|
|
581 // modify predecessors before substituting successors
|
|
582 for (int i = 0; i < number_of_sux(); i++) {
|
|
583 if (sux_at(i) == old_sux) {
|
|
584 // remove old predecessor before adding new predecessor
|
|
585 // otherwise there is a dead predecessor in the list
|
|
586 new_sux->remove_predecessor(old_sux);
|
|
587 new_sux->add_predecessor(this);
|
|
588 }
|
|
589 }
|
|
590 old_sux->remove_predecessor(this);
|
|
591 end()->substitute_sux(old_sux, new_sux);
|
|
592 }
|
|
593
|
|
594
|
|
595
|
|
596 // In general it is not possible to calculate a value for the field "depth_first_number"
|
|
597 // of the inserted block, without recomputing the values of the other blocks
|
|
598 // in the CFG. Therefore the value of "depth_first_number" in BlockBegin becomes meaningless.
|
|
599 BlockBegin* BlockBegin::insert_block_between(BlockBegin* sux) {
|
|
600 // Try to make the bci close to a block with a single pred or sux,
|
|
601 // since this make the block layout algorithm work better.
|
|
602 int bci = -1;
|
|
603 if (sux->number_of_preds() == 1) {
|
|
604 bci = sux->bci();
|
|
605 } else {
|
|
606 bci = end()->bci();
|
|
607 }
|
|
608
|
|
609 BlockBegin* new_sux = new BlockBegin(bci);
|
|
610
|
|
611 // mark this block (special treatment when block order is computed)
|
|
612 new_sux->set(critical_edge_split_flag);
|
|
613
|
|
614 // This goto is not a safepoint.
|
|
615 Goto* e = new Goto(sux, false);
|
|
616 new_sux->set_next(e, bci);
|
|
617 new_sux->set_end(e);
|
|
618 // setup states
|
|
619 ValueStack* s = end()->state();
|
|
620 new_sux->set_state(s->copy());
|
|
621 e->set_state(s->copy());
|
|
622 assert(new_sux->state()->locals_size() == s->locals_size(), "local size mismatch!");
|
|
623 assert(new_sux->state()->stack_size() == s->stack_size(), "stack size mismatch!");
|
|
624 assert(new_sux->state()->locks_size() == s->locks_size(), "locks size mismatch!");
|
|
625
|
|
626 // link predecessor to new block
|
|
627 end()->substitute_sux(sux, new_sux);
|
|
628
|
|
629 // The ordering needs to be the same, so remove the link that the
|
|
630 // set_end call above added and substitute the new_sux for this
|
|
631 // block.
|
|
632 sux->remove_predecessor(new_sux);
|
|
633
|
|
634 // the successor could be the target of a switch so it might have
|
|
635 // multiple copies of this predecessor, so substitute the new_sux
|
|
636 // for the first and delete the rest.
|
|
637 bool assigned = false;
|
|
638 BlockList& list = sux->_predecessors;
|
|
639 for (int i = 0; i < list.length(); i++) {
|
|
640 BlockBegin** b = list.adr_at(i);
|
|
641 if (*b == this) {
|
|
642 if (assigned) {
|
|
643 list.remove_at(i);
|
|
644 // reprocess this index
|
|
645 i--;
|
|
646 } else {
|
|
647 assigned = true;
|
|
648 *b = new_sux;
|
|
649 }
|
|
650 // link the new block back to it's predecessors.
|
|
651 new_sux->add_predecessor(this);
|
|
652 }
|
|
653 }
|
|
654 assert(assigned == true, "should have assigned at least once");
|
|
655 return new_sux;
|
|
656 }
|
|
657
|
|
658
|
|
659 void BlockBegin::remove_successor(BlockBegin* pred) {
|
|
660 int idx;
|
|
661 while ((idx = _successors.index_of(pred)) >= 0) {
|
|
662 _successors.remove_at(idx);
|
|
663 }
|
|
664 }
|
|
665
|
|
666
|
|
667 void BlockBegin::add_predecessor(BlockBegin* pred) {
|
|
668 _predecessors.append(pred);
|
|
669 }
|
|
670
|
|
671
|
|
672 void BlockBegin::remove_predecessor(BlockBegin* pred) {
|
|
673 int idx;
|
|
674 while ((idx = _predecessors.index_of(pred)) >= 0) {
|
|
675 _predecessors.remove_at(idx);
|
|
676 }
|
|
677 }
|
|
678
|
|
679
|
|
680 void BlockBegin::add_exception_handler(BlockBegin* b) {
|
|
681 assert(b != NULL && (b->is_set(exception_entry_flag)), "exception handler must exist");
|
|
682 // add only if not in the list already
|
|
683 if (!_exception_handlers.contains(b)) _exception_handlers.append(b);
|
|
684 }
|
|
685
|
|
686 int BlockBegin::add_exception_state(ValueStack* state) {
|
|
687 assert(is_set(exception_entry_flag), "only for xhandlers");
|
|
688 if (_exception_states == NULL) {
|
|
689 _exception_states = new ValueStackStack(4);
|
|
690 }
|
|
691 _exception_states->append(state);
|
|
692 return _exception_states->length() - 1;
|
|
693 }
|
|
694
|
|
695
|
|
696 void BlockBegin::iterate_preorder(boolArray& mark, BlockClosure* closure) {
|
|
697 if (!mark.at(block_id())) {
|
|
698 mark.at_put(block_id(), true);
|
|
699 closure->block_do(this);
|
|
700 BlockEnd* e = end(); // must do this after block_do because block_do may change it!
|
|
701 { for (int i = number_of_exception_handlers() - 1; i >= 0; i--) exception_handler_at(i)->iterate_preorder(mark, closure); }
|
|
702 { for (int i = e->number_of_sux () - 1; i >= 0; i--) e->sux_at (i)->iterate_preorder(mark, closure); }
|
|
703 }
|
|
704 }
|
|
705
|
|
706
|
|
707 void BlockBegin::iterate_postorder(boolArray& mark, BlockClosure* closure) {
|
|
708 if (!mark.at(block_id())) {
|
|
709 mark.at_put(block_id(), true);
|
|
710 BlockEnd* e = end();
|
|
711 { for (int i = number_of_exception_handlers() - 1; i >= 0; i--) exception_handler_at(i)->iterate_postorder(mark, closure); }
|
|
712 { for (int i = e->number_of_sux () - 1; i >= 0; i--) e->sux_at (i)->iterate_postorder(mark, closure); }
|
|
713 closure->block_do(this);
|
|
714 }
|
|
715 }
|
|
716
|
|
717
|
|
718 void BlockBegin::iterate_preorder(BlockClosure* closure) {
|
|
719 boolArray mark(number_of_blocks(), false);
|
|
720 iterate_preorder(mark, closure);
|
|
721 }
|
|
722
|
|
723
|
|
724 void BlockBegin::iterate_postorder(BlockClosure* closure) {
|
|
725 boolArray mark(number_of_blocks(), false);
|
|
726 iterate_postorder(mark, closure);
|
|
727 }
|
|
728
|
|
729
|
|
730 void BlockBegin::block_values_do(void f(Value*)) {
|
|
731 for (Instruction* n = this; n != NULL; n = n->next()) n->values_do(f);
|
|
732 }
|
|
733
|
|
734
|
|
735 #ifndef PRODUCT
|
|
736 #define TRACE_PHI(code) if (PrintPhiFunctions) { code; }
|
|
737 #else
|
|
738 #define TRACE_PHI(coce)
|
|
739 #endif
|
|
740
|
|
741
|
|
742 bool BlockBegin::try_merge(ValueStack* new_state) {
|
|
743 TRACE_PHI(tty->print_cr("********** try_merge for block B%d", block_id()));
|
|
744
|
|
745 // local variables used for state iteration
|
|
746 int index;
|
|
747 Value new_value, existing_value;
|
|
748
|
|
749 ValueStack* existing_state = state();
|
|
750 if (existing_state == NULL) {
|
|
751 TRACE_PHI(tty->print_cr("first call of try_merge for this block"));
|
|
752
|
|
753 if (is_set(BlockBegin::was_visited_flag)) {
|
|
754 // this actually happens for complicated jsr/ret structures
|
|
755 return false; // BAILOUT in caller
|
|
756 }
|
|
757
|
|
758 // copy state because it is altered
|
|
759 new_state = new_state->copy();
|
|
760
|
|
761 // Use method liveness to invalidate dead locals
|
|
762 MethodLivenessResult liveness = new_state->scope()->method()->liveness_at_bci(bci());
|
|
763 if (liveness.is_valid()) {
|
|
764 assert((int)liveness.size() == new_state->locals_size(), "error in use of liveness");
|
|
765
|
|
766 for_each_local_value(new_state, index, new_value) {
|
|
767 if (!liveness.at(index) || new_value->type()->is_illegal()) {
|
|
768 new_state->invalidate_local(index);
|
|
769 TRACE_PHI(tty->print_cr("invalidating dead local %d", index));
|
|
770 }
|
|
771 }
|
|
772 }
|
|
773
|
|
774 if (is_set(BlockBegin::parser_loop_header_flag)) {
|
|
775 TRACE_PHI(tty->print_cr("loop header block, initializing phi functions"));
|
|
776
|
|
777 for_each_stack_value(new_state, index, new_value) {
|
|
778 new_state->setup_phi_for_stack(this, index);
|
|
779 TRACE_PHI(tty->print_cr("creating phi-function %c%d for stack %d", new_state->stack_at(index)->type()->tchar(), new_state->stack_at(index)->id(), index));
|
|
780 }
|
|
781
|
|
782 BitMap requires_phi_function = new_state->scope()->requires_phi_function();
|
|
783
|
|
784 for_each_local_value(new_state, index, new_value) {
|
|
785 bool requires_phi = requires_phi_function.at(index) || (new_value->type()->is_double_word() && requires_phi_function.at(index + 1));
|
|
786 if (requires_phi || !SelectivePhiFunctions) {
|
|
787 new_state->setup_phi_for_local(this, index);
|
|
788 TRACE_PHI(tty->print_cr("creating phi-function %c%d for local %d", new_state->local_at(index)->type()->tchar(), new_state->local_at(index)->id(), index));
|
|
789 }
|
|
790 }
|
|
791 }
|
|
792
|
|
793 // initialize state of block
|
|
794 set_state(new_state);
|
|
795
|
|
796 } else if (existing_state->is_same_across_scopes(new_state)) {
|
|
797 TRACE_PHI(tty->print_cr("exisiting state found"));
|
|
798
|
|
799 // Inlining may cause the local state not to match up, so walk up
|
|
800 // the new state until we get to the same scope as the
|
|
801 // existing and then start processing from there.
|
|
802 while (existing_state->scope() != new_state->scope()) {
|
|
803 new_state = new_state->caller_state();
|
|
804 assert(new_state != NULL, "could not match up scopes");
|
|
805
|
|
806 assert(false, "check if this is necessary");
|
|
807 }
|
|
808
|
|
809 assert(existing_state->scope() == new_state->scope(), "not matching");
|
|
810 assert(existing_state->locals_size() == new_state->locals_size(), "not matching");
|
|
811 assert(existing_state->stack_size() == new_state->stack_size(), "not matching");
|
|
812
|
|
813 if (is_set(BlockBegin::was_visited_flag)) {
|
|
814 TRACE_PHI(tty->print_cr("loop header block, phis must be present"));
|
|
815
|
|
816 if (!is_set(BlockBegin::parser_loop_header_flag)) {
|
|
817 // this actually happens for complicated jsr/ret structures
|
|
818 return false; // BAILOUT in caller
|
|
819 }
|
|
820
|
|
821 for_each_local_value(existing_state, index, existing_value) {
|
|
822 Value new_value = new_state->local_at(index);
|
|
823 if (new_value == NULL || new_value->type()->tag() != existing_value->type()->tag()) {
|
|
824 // The old code invalidated the phi function here
|
|
825 // Because dead locals are replaced with NULL, this is a very rare case now, so simply bail out
|
|
826 return false; // BAILOUT in caller
|
|
827 }
|
|
828 }
|
|
829
|
|
830 #ifdef ASSERT
|
|
831 // check that all necessary phi functions are present
|
|
832 for_each_stack_value(existing_state, index, existing_value) {
|
|
833 assert(existing_value->as_Phi() != NULL && existing_value->as_Phi()->block() == this, "phi function required");
|
|
834 }
|
|
835 for_each_local_value(existing_state, index, existing_value) {
|
|
836 assert(existing_value == new_state->local_at(index) || (existing_value->as_Phi() != NULL && existing_value->as_Phi()->as_Phi()->block() == this), "phi function required");
|
|
837 }
|
|
838 #endif
|
|
839
|
|
840 } else {
|
|
841 TRACE_PHI(tty->print_cr("creating phi functions on demand"));
|
|
842
|
|
843 // create necessary phi functions for stack
|
|
844 for_each_stack_value(existing_state, index, existing_value) {
|
|
845 Value new_value = new_state->stack_at(index);
|
|
846 Phi* existing_phi = existing_value->as_Phi();
|
|
847
|
|
848 if (new_value != existing_value && (existing_phi == NULL || existing_phi->block() != this)) {
|
|
849 existing_state->setup_phi_for_stack(this, index);
|
|
850 TRACE_PHI(tty->print_cr("creating phi-function %c%d for stack %d", existing_state->stack_at(index)->type()->tchar(), existing_state->stack_at(index)->id(), index));
|
|
851 }
|
|
852 }
|
|
853
|
|
854 // create necessary phi functions for locals
|
|
855 for_each_local_value(existing_state, index, existing_value) {
|
|
856 Value new_value = new_state->local_at(index);
|
|
857 Phi* existing_phi = existing_value->as_Phi();
|
|
858
|
|
859 if (new_value == NULL || new_value->type()->tag() != existing_value->type()->tag()) {
|
|
860 existing_state->invalidate_local(index);
|
|
861 TRACE_PHI(tty->print_cr("invalidating local %d because of type mismatch", index));
|
|
862 } else if (new_value != existing_value && (existing_phi == NULL || existing_phi->block() != this)) {
|
|
863 existing_state->setup_phi_for_local(this, index);
|
|
864 TRACE_PHI(tty->print_cr("creating phi-function %c%d for local %d", existing_state->local_at(index)->type()->tchar(), existing_state->local_at(index)->id(), index));
|
|
865 }
|
|
866 }
|
|
867 }
|
|
868
|
|
869 assert(existing_state->caller_state() == new_state->caller_state(), "caller states must be equal");
|
|
870
|
|
871 } else {
|
|
872 assert(false, "stack or locks not matching (invalid bytecodes)");
|
|
873 return false;
|
|
874 }
|
|
875
|
|
876 TRACE_PHI(tty->print_cr("********** try_merge for block B%d successful", block_id()));
|
|
877
|
|
878 return true;
|
|
879 }
|
|
880
|
|
881
|
|
882 #ifndef PRODUCT
|
|
883 void BlockBegin::print_block() {
|
|
884 InstructionPrinter ip;
|
|
885 print_block(ip, false);
|
|
886 }
|
|
887
|
|
888
|
|
889 void BlockBegin::print_block(InstructionPrinter& ip, bool live_only) {
|
|
890 ip.print_instr(this); tty->cr();
|
|
891 ip.print_stack(this->state()); tty->cr();
|
|
892 ip.print_inline_level(this);
|
|
893 ip.print_head();
|
|
894 for (Instruction* n = next(); n != NULL; n = n->next()) {
|
|
895 if (!live_only || n->is_pinned() || n->use_count() > 0) {
|
|
896 ip.print_line(n);
|
|
897 }
|
|
898 }
|
|
899 tty->cr();
|
|
900 }
|
|
901 #endif // PRODUCT
|
|
902
|
|
903
|
|
904 // Implementation of BlockList
|
|
905
|
|
906 void BlockList::iterate_forward (BlockClosure* closure) {
|
|
907 const int l = length();
|
|
908 for (int i = 0; i < l; i++) closure->block_do(at(i));
|
|
909 }
|
|
910
|
|
911
|
|
912 void BlockList::iterate_backward(BlockClosure* closure) {
|
|
913 for (int i = length() - 1; i >= 0; i--) closure->block_do(at(i));
|
|
914 }
|
|
915
|
|
916
|
|
917 void BlockList::blocks_do(void f(BlockBegin*)) {
|
|
918 for (int i = length() - 1; i >= 0; i--) f(at(i));
|
|
919 }
|
|
920
|
|
921
|
|
922 void BlockList::values_do(void f(Value*)) {
|
|
923 for (int i = length() - 1; i >= 0; i--) at(i)->block_values_do(f);
|
|
924 }
|
|
925
|
|
926
|
|
927 #ifndef PRODUCT
|
|
928 void BlockList::print(bool cfg_only, bool live_only) {
|
|
929 InstructionPrinter ip;
|
|
930 for (int i = 0; i < length(); i++) {
|
|
931 BlockBegin* block = at(i);
|
|
932 if (cfg_only) {
|
|
933 ip.print_instr(block); tty->cr();
|
|
934 } else {
|
|
935 block->print_block(ip, live_only);
|
|
936 }
|
|
937 }
|
|
938 }
|
|
939 #endif // PRODUCT
|
|
940
|
|
941
|
|
942 // Implementation of BlockEnd
|
|
943
|
|
944 void BlockEnd::set_begin(BlockBegin* begin) {
|
|
945 BlockList* sux = NULL;
|
|
946 if (begin != NULL) {
|
|
947 sux = begin->successors();
|
|
948 } else if (_begin != NULL) {
|
|
949 // copy our sux list
|
|
950 BlockList* sux = new BlockList(_begin->number_of_sux());
|
|
951 for (int i = 0; i < _begin->number_of_sux(); i++) {
|
|
952 sux->append(_begin->sux_at(i));
|
|
953 }
|
|
954 }
|
|
955 _sux = sux;
|
|
956 _begin = begin;
|
|
957 }
|
|
958
|
|
959
|
|
960 void BlockEnd::substitute_sux(BlockBegin* old_sux, BlockBegin* new_sux) {
|
|
961 substitute(*_sux, old_sux, new_sux);
|
|
962 }
|
|
963
|
|
964
|
|
965 void BlockEnd::other_values_do(void f(Value*)) {
|
|
966 if (state_before() != NULL) state_before()->values_do(f);
|
|
967 }
|
|
968
|
|
969
|
|
970 // Implementation of Phi
|
|
971
|
|
972 // Normal phi functions take their operands from the last instruction of the
|
|
973 // predecessor. Special handling is needed for xhanlder entries because there
|
|
974 // the state of arbitrary instructions are needed.
|
|
975
|
|
976 Value Phi::operand_at(int i) const {
|
|
977 ValueStack* state;
|
|
978 if (_block->is_set(BlockBegin::exception_entry_flag)) {
|
|
979 state = _block->exception_state_at(i);
|
|
980 } else {
|
|
981 state = _block->pred_at(i)->end()->state();
|
|
982 }
|
|
983 assert(state != NULL, "");
|
|
984
|
|
985 if (is_local()) {
|
|
986 return state->local_at(local_index());
|
|
987 } else {
|
|
988 return state->stack_at(stack_index());
|
|
989 }
|
|
990 }
|
|
991
|
|
992
|
|
993 int Phi::operand_count() const {
|
|
994 if (_block->is_set(BlockBegin::exception_entry_flag)) {
|
|
995 return _block->number_of_exception_states();
|
|
996 } else {
|
|
997 return _block->number_of_preds();
|
|
998 }
|
|
999 }
|
|
1000
|
|
1001
|
|
1002 // Implementation of Throw
|
|
1003
|
|
1004 void Throw::state_values_do(void f(Value*)) {
|
|
1005 BlockEnd::state_values_do(f);
|
|
1006 }
|