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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 // A frame represents a physical stack frame (an activation). Frames can be
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26 // C or Java frames, and the Java frames can be interpreted or compiled.
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27 // In contrast, vframes represent source-level activations, so that one physical frame
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28 // can correspond to multiple source level frames because of inlining.
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29 // A frame is comprised of {pc, sp, younger_sp}
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30
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31
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32 // Layout of asm interpreter frame:
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33 //
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34 // 0xfffffff
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35 // ......
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36 // [last extra incoming arg, (local # Nargs > 6 ? Nargs-1 : undef)]
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37 // .. Note: incoming args are copied to local frame area upon entry
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38 // [first extra incoming arg, (local # Nargs > 6 ? 6 : undef)]
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39 // [6 words for C-arg storage (unused)] Are this and next one really needed?
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40 // [C-aggregate-word (unused)] Yes, if want extra params to be in same place as C convention
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41 // [16 words for register saving] <--- FP
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42 // [interpreter_frame_vm_locals ] (see below)
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43
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44 // Note: Llocals is always double-word aligned
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45 // [first local i.e. local # 0] <-- Llocals
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46 // ...
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47 // [last local, i.e. local # Nlocals-1]
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48
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49 // [monitors ]
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50 // ....
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51 // [monitors ] <-- Lmonitors (same as Llocals + 6*4 if none)
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52 // (must be double-word aligned because
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53 // monitor element size is constrained to
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54 // doubleword)
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55 //
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56 // <-- Lesp (points 1 past TOS)
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57 // [bottom word used for stack ]
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58 // ...
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59 // [top word used for stack] (first word of stack is double-word aligned)
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60
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61 // [space for outgoing args (conservatively allocated as max_stack - 6 + interpreter_frame_extra_outgoing_argument_words)]
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62 // [6 words for C-arg storage]
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63 // [C-aggregate-word (unused)]
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64 // [16 words for register saving] <--- SP
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65 // ...
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66 // 0x0000000
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67 //
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68 // The in registers and local registers are preserved in a block at SP.
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69 //
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70 // The first six in registers (I0..I5) hold the first six locals.
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71 // The locals are used as follows:
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72 // Lesp first free element of expression stack
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73 // (which grows towards __higher__ addresses)
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74 // Lbcp is set to address of bytecode to execute
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75 // It is accessed in the frame under the name "bcx".
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76 // It may at times (during GC) be an index instead.
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77 // Lmethod the method being interpreted
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78 // Llocals the base pointer for accessing the locals array
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79 // (lower-numbered locals have lower addresses)
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80 // Lmonitors the base pointer for accessing active monitors
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81 // Lcache a saved pointer to the method's constant pool cache
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82 //
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83 //
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84 // When calling out to another method,
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85 // G5_method is set to method to call, G5_inline_cache_klass may be set,
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86 // parameters are put in O registers, and also extra parameters
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87 // must be cleverly copied from the top of stack to the outgoing param area in the frame,
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88 // ------------------------------ C++ interpreter ----------------------------------------
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89 // Layout of C++ interpreter frame:
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90 //
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91
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92
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93
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94 // All frames:
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95
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96 public:
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97
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98 enum {
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99 // normal return address is 2 words past PC
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100 pc_return_offset = 2 * BytesPerInstWord,
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101
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102 // size of each block, in order of increasing address:
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103 register_save_words = 16,
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104 #ifdef _LP64
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105 callee_aggregate_return_pointer_words = 0,
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106 #else
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107 callee_aggregate_return_pointer_words = 1,
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108 #endif
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109 callee_register_argument_save_area_words = 6,
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110 // memory_parameter_words = <arbitrary>,
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111
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112 // offset of each block, in order of increasing address:
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113 // (note: callee_register_argument_save_area_words == Assembler::n_register_parameters)
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114 register_save_words_sp_offset = 0,
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115 callee_aggregate_return_pointer_sp_offset = register_save_words_sp_offset + register_save_words,
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116 callee_register_argument_save_area_sp_offset = callee_aggregate_return_pointer_sp_offset + callee_aggregate_return_pointer_words,
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117 memory_parameter_word_sp_offset = callee_register_argument_save_area_sp_offset + callee_register_argument_save_area_words,
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118 varargs_offset = memory_parameter_word_sp_offset
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119 };
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120
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121 private:
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122 intptr_t* _younger_sp; // optional SP of callee (used to locate O7)
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123 int _sp_adjustment_by_callee; // adjustment in words to SP by callee for making locals contiguous
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124
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125 // Note: On SPARC, unlike Intel, the saved PC for a stack frame
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126 // is stored at a __variable__ distance from that frame's SP.
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127 // (In fact, it may be in the register save area of the callee frame,
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128 // but that fact need not bother us.) Thus, we must store the
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129 // address of that saved PC explicitly. On the other hand, SPARC
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130 // stores the FP for a frame at a fixed offset from the frame's SP,
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131 // so there is no need for a separate "frame::_fp" field.
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132
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133 public:
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134 // Accessors
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135
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136 intptr_t* younger_sp() const {
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137 assert(_younger_sp != NULL, "frame must possess a younger_sp");
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138 return _younger_sp;
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139 }
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140
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141 int callee_sp_adjustment() const { return _sp_adjustment_by_callee; }
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142 void set_sp_adjustment_by_callee(int number_of_words) { _sp_adjustment_by_callee = number_of_words; }
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143
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144 // Constructors
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145
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146 // This constructor relies on the fact that the creator of a frame
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147 // has flushed register windows which the frame will refer to, and
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148 // that those register windows will not be reloaded until the frame is
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149 // done reading and writing the stack. Moreover, if the "younger_sp"
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150 // argument points into the register save area of the next younger
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151 // frame (though it need not), the register window for that next
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152 // younger frame must also stay flushed. (The caller is responsible
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153 // for ensuring this.)
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154
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155 frame(intptr_t* sp, intptr_t* younger_sp, bool younger_frame_adjusted_stack = false);
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156
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157 // make a deficient frame which doesn't know where its PC is:
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158 enum unpatchable_t { unpatchable };
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159 frame(intptr_t* sp, unpatchable_t, address pc = NULL, CodeBlob* cb = NULL);
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160
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161 // Walk from sp outward looking for old_sp, and return old_sp's predecessor
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162 // (i.e. return the sp from the frame where old_sp is the fp).
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163 // Register windows are assumed to be flushed for the stack in question.
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164
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165 static intptr_t* next_younger_sp_or_null(intptr_t* old_sp, intptr_t* sp);
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166
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167 // Return true if sp is a younger sp in the stack described by valid_sp.
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168 static bool is_valid_stack_pointer(intptr_t* valid_sp, intptr_t* sp);
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169
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170 public:
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171 // accessors for the instance variables
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172 intptr_t* fp() const { return (intptr_t*) ((intptr_t)(sp()[FP->sp_offset_in_saved_window()]) + STACK_BIAS ); }
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173
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174 // All frames
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175
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176 intptr_t* fp_addr_at(int index) const { return &fp()[index]; }
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177 intptr_t* sp_addr_at(int index) const { return &sp()[index]; }
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178 intptr_t fp_at( int index) const { return *fp_addr_at(index); }
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179 intptr_t sp_at( int index) const { return *sp_addr_at(index); }
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180
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181 private:
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182 inline address* I7_addr() const;
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183 inline address* O7_addr() const;
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184
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185 inline address* I0_addr() const;
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186 inline address* O0_addr() const;
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187 intptr_t* younger_sp_addr_at(int index) const { return &younger_sp()[index]; }
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188
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189 public:
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190 // access to SPARC arguments and argument registers
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191
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192 // Assumes reg is an in/local register
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193 intptr_t* register_addr(Register reg) const {
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194 return sp_addr_at(reg->sp_offset_in_saved_window());
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195 }
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196
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197 // Assumes reg is an out register
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198 intptr_t* out_register_addr(Register reg) const {
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199 return younger_sp_addr_at(reg->after_save()->sp_offset_in_saved_window());
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200 }
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201 intptr_t* memory_param_addr(int param_ix, bool is_in) const {
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202 int offset = callee_register_argument_save_area_sp_offset + param_ix;
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203 if (is_in)
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204 return fp_addr_at(offset);
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205 else
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206 return sp_addr_at(offset);
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207 }
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208 intptr_t* param_addr(int param_ix, bool is_in) const {
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209 if (param_ix >= callee_register_argument_save_area_words)
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210 return memory_param_addr(param_ix, is_in);
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211 else if (is_in)
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212 return register_addr(Argument(param_ix, true).as_register());
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213 else {
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214 // the registers are stored in the next younger frame
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215 // %%% is this really necessary?
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216 ShouldNotReachHere();
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217 return NULL;
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218 }
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219 }
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220
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221
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222 // Interpreter frames
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223
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224 public:
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225 // Asm interpreter
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226 #ifndef CC_INTERP
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227 enum interpreter_frame_vm_locals {
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228 // 2 words, also used to save float regs across calls to C
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229 interpreter_frame_d_scratch_fp_offset = -2,
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230 interpreter_frame_l_scratch_fp_offset = -4,
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231 interpreter_frame_padding_offset = -5, // for native calls only
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232 interpreter_frame_oop_temp_offset = -6, // for native calls only
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233 interpreter_frame_vm_locals_fp_offset = -6, // should be same as above, and should be zero mod 8
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234
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235 interpreter_frame_vm_local_words = -interpreter_frame_vm_locals_fp_offset,
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236
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237
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238 // interpreter frame set-up needs to save 2 extra words in outgoing param area
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239 // for class and jnienv arguments for native stubs (see nativeStubGen_sparc.cpp_
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240
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241 interpreter_frame_extra_outgoing_argument_words = 2
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242 };
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243 #else
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244 enum interpreter_frame_vm_locals {
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245 // 2 words, also used to save float regs across calls to C
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246 interpreter_state_ptr_offset = 0, // Is in L0 (Lstate) in save area
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247 interpreter_frame_mirror_offset = 1, // Is in L1 (Lmirror) in save area (for native calls only)
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248
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249 // interpreter frame set-up needs to save 2 extra words in outgoing param area
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250 // for class and jnienv arguments for native stubs (see nativeStubGen_sparc.cpp_
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251
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252 interpreter_frame_extra_outgoing_argument_words = 2
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253 };
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254 #endif /* CC_INTERP */
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255
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256 // the compiler frame has many of the same fields as the interpreter frame
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257 // %%%%% factor out declarations of the shared fields
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258 enum compiler_frame_fixed_locals {
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259 compiler_frame_d_scratch_fp_offset = -2,
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260 compiler_frame_vm_locals_fp_offset = -2, // should be same as above
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261
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262 compiler_frame_vm_local_words = -compiler_frame_vm_locals_fp_offset
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263 };
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264
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265 private:
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266
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267 constantPoolCacheOop* frame::interpreter_frame_cpoolcache_addr() const;
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268
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269 #ifndef CC_INTERP
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270
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271 // where Lmonitors is saved:
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272 BasicObjectLock** interpreter_frame_monitors_addr() const {
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273 return (BasicObjectLock**) sp_addr_at(Lmonitors->sp_offset_in_saved_window());
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274 }
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275 intptr_t** interpreter_frame_esp_addr() const {
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276 return (intptr_t**)sp_addr_at(Lesp->sp_offset_in_saved_window());
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277 }
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278
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279 inline void interpreter_frame_set_tos_address(intptr_t* x);
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280
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281
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282 // %%%%% Another idea: instead of defining 3 fns per item, just define one returning a ref
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283
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284 // monitors:
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285
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286 // next two fns read and write Lmonitors value,
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287 private:
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288 BasicObjectLock* interpreter_frame_monitors() const { return *interpreter_frame_monitors_addr(); }
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289 void interpreter_frame_set_monitors(BasicObjectLock* monitors) { *interpreter_frame_monitors_addr() = monitors; }
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290 #else
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291 public:
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292 inline interpreterState get_interpreterState() const {
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293 return ((interpreterState)sp_at(interpreter_state_ptr_offset));
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294 }
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295
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296
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297 #endif /* CC_INTERP */
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298
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299
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300
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301 // Compiled frames
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302
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303 public:
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304 // Tells if this register can hold 64 bits on V9 (really, V8+).
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305 static bool holds_a_doubleword(Register reg) {
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306 #ifdef _LP64
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307 // return true;
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308 return reg->is_out() || reg->is_global();
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309 #else
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310 return reg->is_out() || reg->is_global();
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311 #endif
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312 }
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