1 /* |
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2 * (c) 2003 Mario de Sousa |
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3 * |
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4 * Offered to the public under the terms of the GNU General Public License |
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5 * as published by the Free Software Foundation; either version 2 of the |
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6 * License, or (at your option) any later version. |
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7 * |
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8 * This program is distributed in the hope that it will be useful, but |
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9 * WITHOUT ANY WARRANTY; without even the implied warranty of |
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10 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General |
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11 * Public License for more details. |
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12 * |
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13 * This code is made available on the understanding that it will not be |
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14 * used in safety-critical situations without a full and competent review. |
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15 */ |
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16 |
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17 /* |
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18 * An IEC 61131-3 IL and ST compiler. |
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19 * |
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20 * Based on the |
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21 * FINAL DRAFT - IEC 61131-3, 2nd Ed. (2001-12-10) |
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22 * |
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23 */ |
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24 |
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25 |
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26 /* |
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27 * Conversion of il statements (i.e. IL code). |
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28 * |
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29 * This is part of the 4th stage that generates |
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30 * a c++ source program equivalent to the IL and ST |
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31 * code. |
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32 */ |
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33 |
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34 |
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35 |
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36 |
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37 /***********************************************************************/ |
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38 /***********************************************************************/ |
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39 /***********************************************************************/ |
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40 /***********************************************************************/ |
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41 |
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42 /* Returns the data type of an il_operand. |
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43 * |
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44 * Note that the il_operand may be a variable, in which case |
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45 * we return the type of the variable instance. |
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46 * The il_operand may also be a constant, in which case |
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47 * we return the data type of that constant. |
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48 * |
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49 * The variable instance may be a member of a structured variable, |
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50 * or an element in an array, or any combination of the two. |
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51 * |
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52 * The class constructor must be given the search scope |
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53 * (function, function block or program within which |
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54 * the possible il_operand variable instance was declared). |
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55 */ |
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56 |
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57 class search_il_operand_type_c { |
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58 |
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59 private: |
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60 search_varfb_instance_type_c search_varfb_instance_type; |
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61 search_constant_type_c search_constant_type; |
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62 |
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63 public: |
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64 search_il_operand_type_c(symbol_c *search_scope): search_varfb_instance_type(search_scope) {} |
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65 |
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66 public: |
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67 symbol_c *get_type(symbol_c *il_operand) { |
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68 symbol_c *res; |
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69 |
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70 /* We first assume that it is a constant... */ |
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71 res = search_constant_type.get_type(il_operand); |
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72 if (res != NULL) return res; |
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73 |
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74 /* Nope, now we assume it is a variable, and determine its type... */ |
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75 res = search_varfb_instance_type.get_type(il_operand); |
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76 if (NULL != res) return res; |
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77 |
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78 /* not found */ |
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79 return NULL; |
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80 } |
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81 }; |
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82 |
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83 |
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84 |
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85 /***********************************************************************/ |
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86 /***********************************************************************/ |
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87 /***********************************************************************/ |
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88 /***********************************************************************/ |
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89 |
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90 |
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91 /* A new class to ouput the il default variable to c++ code |
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92 * We use this class, inheriting from symbol_c, so it may be used |
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93 * as any other symbol_c object in the intermediate parse tree, |
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94 * more specifically, so it can be used as any other il operand. |
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95 * This makes the rest of the code much easier... |
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96 * |
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97 * Nevertheless, the basic visitor class visitor_c does not know |
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98 * how to visit this new il_default_variable_c class, so we have |
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99 * to extend that too. |
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100 * In reality extending the basic symbols doesn't quite work out |
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101 * as cleanly as desired (we need to use dynamic_cast in the |
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102 * accept method of the il_default_variable_c), but it is cleaner |
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103 * than the alternative... |
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104 */ |
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105 class il_default_variable_c; |
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106 |
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107 /* This visitor class is not really required, we could place the |
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108 * visit() method directly in genertae_cc_il_c, but doing it in |
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109 * a seperate class makes the architecture more evident... |
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110 */ |
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111 class il_default_variable_visitor_c { |
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112 public: |
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113 virtual void *visit(il_default_variable_c *symbol) = 0; |
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114 |
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115 virtual ~il_default_variable_visitor_c(void) {return;} |
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116 }; |
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117 |
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118 |
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119 /* A class to print out to the resulting C++ code |
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120 * the IL default variable name. |
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121 * |
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122 * It includes a reference to its name, |
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123 * and the data type of the data currently stored |
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124 * in this C++ variable... This is required because the |
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125 * C++ variable is a union, and we must know which member |
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126 * of the union top reference!! |
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127 * |
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128 * Note that we also need to keep track of the data type of |
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129 * the value currently being stored in the default variable. |
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130 * This is required so we can process parenthesis, |
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131 * |
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132 * e.g. : |
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133 * LD var1 |
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134 * AND ( |
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135 * LD var2 |
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136 * OR var3 |
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137 * ) |
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138 * |
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139 * Note that we only execute the 'AND (' operation when we come across |
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140 * the ')', i.e. once we have evaluated the result of the |
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141 * instructions inside the parenthesis. |
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142 * When we do execute the 'AND (' operation, we need to know the data type |
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143 * of the operand, which in this case is the result of the evaluation of the |
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144 * instruction list inside the parenthesis. We can only know this if we |
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145 * keep track of the data type currently stored in the default variable! |
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146 * |
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147 * We use the current_type inside the generate_cc_il::default_variable_name variable |
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148 * to track this! |
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149 */ |
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150 class il_default_variable_c: public symbol_c { |
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151 public: |
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152 symbol_c *var_name; /* in principle, this should point to an indentifier_c */ |
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153 symbol_c *current_type; |
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154 |
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155 public: |
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156 il_default_variable_c(const char *var_name_str, symbol_c *current_type); |
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157 virtual void *accept(visitor_c &visitor); |
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158 }; |
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159 |
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160 |
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161 /***********************************************************************/ |
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162 /***********************************************************************/ |
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163 /***********************************************************************/ |
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164 /***********************************************************************/ |
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165 |
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166 |
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167 |
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168 class generate_cc_il_c: public generate_cc_typedecl_c, il_default_variable_visitor_c { |
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169 |
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170 private: |
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171 /* When compiling il code, it becomes necessary to determine the |
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172 * data type of il operands. To do this, we must first find the |
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173 * il operand's declaration, within the scope of the function block |
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174 * or function currently being processed. |
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175 * The following object does just that... |
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176 * This object instance will then later be called while the |
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177 * remaining il code is being handled. |
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178 */ |
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179 //search_il_operand_type_c *search_il_operand_type; |
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180 search_expression_type_c *search_expression_type; |
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181 |
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182 /* The initial value that should be given to the IL default variable |
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183 * imediately after a parenthesis is opened. |
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184 * This variable is only used to pass data from the |
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185 * il_expression_c visitor to the simple_instr_list_c visitor. |
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186 * |
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187 * e.g.: |
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188 * LD var1 |
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189 * AND ( var2 |
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190 * OR var3 |
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191 * ) |
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192 * |
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193 * In the above code sample, the line 'AND ( var2' constitutes |
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194 * an il_expression_c, where var2 should be loaded into the |
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195 * il default variable before continuing with the expression |
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196 * inside the parenthesis. |
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197 * Unfortunately, only the simple_instr_list_c may do the |
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198 * initial laoding of the var2 bariable following the parenthesis, |
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199 * so the il_expression_c visitor will have to pass 'var2' as a |
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200 * parameter to the simple_instr_list_c visitor. |
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201 * Ergo, the existance of the following parameter...! |
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202 */ |
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203 symbol_c *il_default_variable_init_value; |
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204 |
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205 /* Operand to the IL operation currently being processed... */ |
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206 /* These variables are used to pass data from the |
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207 * il_simple_operation_c and il_expression_c visitors |
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208 * to the il operator visitors (i.e. LD_operator_c, |
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209 * LDN_operator_c, ST_operator_c, STN_operator_c, ...) |
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210 */ |
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211 symbol_c *current_operand; |
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212 symbol_c *current_operand_type; |
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213 |
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214 /* Label to which the current IL jump operation should jump to... */ |
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215 /* This variable is used to pass data from the |
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216 * il_jump_operation_c visitor |
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217 * to the il jump operator visitors (i.e. JMP_operator_c, |
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218 * JMPC_operator_c, JMPCN_operator_c, ...) |
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219 */ |
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220 symbol_c *jump_label; |
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221 |
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222 /* The result of the comparison IL operations (GT, EQ, LT, ...) |
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223 * is a boolean variable. |
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224 * This class keeps track of the current data type stored in the |
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225 * il default variable. This is usually done by keeping a reference |
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226 * to the data type of the last operand. Nevertheless, in the case of |
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227 * the comparison IL operators, the data type of the result (a boolean) |
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228 * is not the data type of the operand. We therefore need an object |
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229 * of the boolean data type to keep as a reference of the current |
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230 * data type. |
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231 * The following object is it... |
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232 */ |
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233 bool_type_name_c bool_type; |
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234 |
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235 /* the data type of the IL default variable... */ |
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236 #define IL_DEFVAR_T VAR_LEADER "IL_DEFVAR_T" |
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237 /* The name of the IL default variable... */ |
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238 #define IL_DEFVAR VAR_LEADER "IL_DEFVAR" |
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239 /* The name of the variable used to pass the result of a |
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240 * parenthesised instruction list to the immediately preceding |
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241 * scope ... |
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242 */ |
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243 #define IL_DEFVAR_BACK VAR_LEADER "IL_DEFVAR_BACK" |
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244 il_default_variable_c default_variable_name; |
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245 il_default_variable_c default_variable_back_name; |
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246 |
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247 /* Some function calls in the body of functions or function blocks |
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248 * may leave some parameters to their default values, and |
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249 * ignore some output parameters of the function being called. |
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250 * Our conversion of ST functions to C++ does not contemplate that, |
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251 * i.e. each called function must get all it's input and output |
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252 * parameters set correctly. |
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253 * For input parameters we merely need to call the function with |
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254 * the apropriate default value, but for output parameters |
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255 * we must create temporary variables to hold the output value. |
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256 * |
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257 * We declare all the temporary output variables at the begining of |
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258 * the body of each function or function block, and use them as |
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259 * in function calls later on as they become necessary... |
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260 * Note that we cannot create these variables just before a function |
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261 * call, as the function call itself may be integrated within an |
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262 * expression, or another function call! |
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263 * |
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264 * The variables are declared in the exact same order in which they |
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265 * will be used later on during the function calls, which allows us |
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266 * to simply re-create the name that was used for the temporary variable |
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267 * instead of keeping it in some list. |
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268 * The names are recreated by the temp_var_name_factory, after reset() |
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269 * has been called! |
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270 * |
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271 * This function will genertae code similar to... |
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272 * |
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273 * INT __TMP_0 = 23; |
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274 * REAL __TMP_1 = 45.5; |
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275 * ... |
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276 */ |
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277 temp_var_name_c temp_var_name_factory; |
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278 |
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279 /* When calling a function block, we must first find it's type, |
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280 * by searching through the declarations of the variables currently |
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281 * in scope. |
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282 * This class does just that... |
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283 * A new class is instantiated whenever we begin generating the code |
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284 * for a function block type declaration, or a program declaration. |
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285 * This object instance will then later be called while the |
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286 * function block's or the program's body is being handled. |
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287 * |
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288 * Note that functions cannot contain calls to function blocks, |
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289 * so we do not create an object instance when handling |
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290 * a function declaration. |
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291 */ |
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292 search_fb_instance_decl_c *search_fb_instance_decl; |
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293 |
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294 |
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295 public: |
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296 generate_cc_il_c(stage4out_c *s4o_ptr, symbol_c *scope, const char *variable_prefix = NULL) |
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297 : generate_cc_typedecl_c(s4o_ptr), |
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298 default_variable_name(IL_DEFVAR, NULL), |
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299 default_variable_back_name(IL_DEFVAR_BACK, NULL) |
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300 { |
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301 //search_il_operand_type = new search_il_operand_type_c(scope); |
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302 search_expression_type = new search_expression_type_c(scope); |
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303 search_fb_instance_decl = new search_fb_instance_decl_c(scope); |
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304 current_operand = NULL; |
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305 current_operand_type = NULL; |
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306 il_default_variable_init_value = NULL; |
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307 this->set_variable_prefix(variable_prefix); |
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308 } |
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309 |
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310 virtual ~generate_cc_il_c(void) { |
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311 delete search_fb_instance_decl; |
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312 //delete search_il_operand_type; |
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313 delete search_expression_type; |
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314 } |
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315 |
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316 void generate(instruction_list_c *il) { |
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317 generate_cc_tempvardecl_c generate_cc_tempvardecl(&s4o); |
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318 generate_cc_tempvardecl.generate(il, &temp_var_name_factory); |
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319 il->accept(*this); |
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320 } |
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321 |
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322 /* Declare the backup to the default variable, that will store the result |
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323 * of the IL operations executed inside a parenthesis... |
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324 */ |
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325 void declare_backup_variable(void) { |
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326 s4o.print(s4o.indent_spaces); |
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327 s4o.print(IL_DEFVAR_T); |
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328 s4o.print(" "); |
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329 print_backup_variable(); |
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330 s4o.print(";\n"); |
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331 } |
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332 |
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333 void print_backup_variable(void) { |
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334 this->default_variable_back_name.accept(*this); |
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335 } |
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336 |
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337 private: |
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338 /* A helper function... */ |
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339 /* |
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340 bool is_bool_type(symbol_c *type_symbol) { |
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341 return (NULL != dynamic_cast<bool_type_name_c *>(type_symbol)); |
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342 } |
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343 */ |
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344 |
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345 /* A helper function... */ |
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346 void *XXX_operator(symbol_c *lo, const char *op, symbol_c *ro) { |
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347 if ((NULL == lo) || (NULL == ro)) ERROR; |
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348 if (NULL == op) ERROR; |
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349 |
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350 lo->accept(*this); |
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351 s4o.print(op); |
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352 ro->accept(*this); |
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353 return NULL; |
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354 } |
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355 |
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356 /* A helper function... */ |
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357 void *XXX_function(const char *func, symbol_c *lo, symbol_c *ro) { |
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358 if ((NULL == lo) || (NULL == ro)) ERROR; |
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359 if (NULL == func) ERROR; |
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360 |
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361 lo->accept(*this); |
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362 s4o.print(" = "); |
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363 s4o.print(func); |
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364 s4o.print("("); |
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365 lo->accept(*this); |
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366 s4o.print(", "); |
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367 ro->accept(*this); |
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368 s4o.print(")"); |
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369 return NULL; |
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370 } |
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371 |
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372 /* A helper function... */ |
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373 void *XXX_CAL_operator(const char *param_name, symbol_c *fb_name) { |
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374 if (NULL == fb_name) ERROR; |
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375 symbolic_variable_c *sv = dynamic_cast<symbolic_variable_c *>(fb_name); |
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376 if (NULL == sv) ERROR; |
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377 identifier_c *id = dynamic_cast<identifier_c *>(sv->var_name); |
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378 if (NULL == id) ERROR; |
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379 |
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380 identifier_c param(param_name); |
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381 |
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382 //SYM_REF3(il_param_assignment_c, il_assign_operator, il_operand, simple_instr_list) |
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383 il_param_assignment_c il_param_assignment(¶m, &this->default_variable_name, NULL); |
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384 // SYM_LIST(il_param_list_c) |
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385 il_param_list_c il_param_list; |
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386 il_param_list.add_element(&il_param_assignment); |
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387 CAL_operator_c CAL_operator; |
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388 // SYM_REF4(il_fb_call_c, il_call_operator, fb_name, il_operand_list, il_param_list) |
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389 il_fb_call_c il_fb_call(&CAL_operator, id, NULL, &il_param_list); |
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390 |
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391 il_fb_call.accept(*this); |
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392 return NULL; |
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393 } |
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394 |
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395 /* A helper function... */ |
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396 void *CMP_operator(symbol_c *o, const char *operation) { |
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397 if (NULL == o) ERROR; |
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398 if (NULL == this->default_variable_name.current_type) ERROR; |
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399 |
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400 symbol_c *backup = this->default_variable_name.current_type; |
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401 this->default_variable_name.current_type = &(this->bool_type); |
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402 this->default_variable_name.accept(*this); |
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403 this->default_variable_name.current_type = backup; |
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404 |
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405 s4o.print(" = "); |
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406 s4o.print(operation); |
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407 this->default_variable_name.current_type->accept(*this); |
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408 s4o.print("(2, "); |
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409 this->default_variable_name.accept(*this); |
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410 s4o.print(", "); |
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411 o->accept(*this); |
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412 s4o.print(")"); |
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413 |
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414 /* the data type resulting from this operation... */ |
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415 this->default_variable_name.current_type = &(this->bool_type); |
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416 return NULL; |
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417 } |
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418 |
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419 |
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420 /* A helper function... */ |
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421 void C_modifier(void) { |
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422 if (search_expression_type->is_bool_type(default_variable_name.current_type)) { |
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423 s4o.print("if ("); |
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424 this->default_variable_name.accept(*this); |
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425 s4o.print(") "); |
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426 } |
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427 else {ERROR;} |
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428 } |
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429 |
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430 /* A helper function... */ |
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431 void CN_modifier(void) { |
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432 if (search_expression_type->is_bool_type(default_variable_name.current_type)) { |
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433 s4o.print("if (!"); |
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434 this->default_variable_name.accept(*this); |
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435 s4o.print(") "); |
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436 } |
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437 else {ERROR;} |
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438 } |
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439 |
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440 |
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441 public: |
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442 void *visit(il_default_variable_c *symbol) { |
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443 //s4o.print("il_default_variable_c VISITOR!!\n"); |
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444 symbol->var_name->accept(*this); |
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445 if (NULL != symbol->current_type) { |
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446 s4o.print("."); |
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447 symbol->current_type->accept(*this); |
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448 s4o.print("var"); |
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449 } |
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450 return NULL; |
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451 } |
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452 |
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453 |
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454 private: |
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455 |
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456 /********************************************/ |
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457 /* B.1.4.1 Directly Represented Variables */ |
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458 /********************************************/ |
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459 // direct_variable: direct_variable_token {$$ = new direct_variable_c($1);}; |
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460 void *visit(direct_variable_c *symbol) { |
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461 TRACE("direct_variable_c"); |
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462 /* Do not use print_token() as it will change everything into uppercase */ |
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463 if (strlen(symbol->value) == 0) ERROR; |
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464 s4o.print("*("); |
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465 this->print_variable_prefix(); |
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466 s4o.printlocation(symbol->value + 1); |
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467 s4o.print(")"); |
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468 return NULL; |
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469 } |
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470 |
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471 /****************************************/ |
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472 /* B.2 - Language IL (Instruction List) */ |
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473 /****************************************/ |
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474 |
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475 /***********************************/ |
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476 /* B 2.1 Instructions and Operands */ |
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477 /***********************************/ |
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478 |
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479 /* please see the comment before the RET_operator_c visitor for details... */ |
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480 #define END_LABEL VAR_LEADER "end" |
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481 |
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482 /*| instruction_list il_instruction */ |
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483 void *visit(instruction_list_c *symbol) { |
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484 |
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485 /* Declare the backup to the default variable, that will store the result |
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486 * of the IL operations executed inside a parenthesis... |
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487 */ |
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488 declare_backup_variable(); |
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489 |
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490 /* Declare the default variable, that will store the result of the IL operations... */ |
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491 s4o.print(s4o.indent_spaces); |
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492 s4o.print(IL_DEFVAR_T); |
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493 s4o.print(" "); |
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494 this->default_variable_name.accept(*this); |
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495 s4o.print(";\n\n"); |
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496 |
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497 print_list(symbol, s4o.indent_spaces, ";\n" + s4o.indent_spaces, ";\n"); |
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498 |
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499 /* write the label marking the end of the code block */ |
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500 /* please see the comment before the RET_operator_c visitor for details... */ |
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501 s4o.print("\n"); |
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502 s4o.print(s4o.indent_spaces); |
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503 s4o.print(END_LABEL); |
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504 s4o.print(":\n"); |
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505 s4o.indent_right(); |
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506 /* since every label must be followed by at least one statement, and |
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507 * only the functions will introduce the return statement after this label, |
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508 * function blocks written in IL would result in invalid C++ code. |
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509 * To work around this we introduce the equivalent of a 'nop' operation |
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510 * to humour the compiler... |
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511 */ |
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512 s4o.print(s4o.indent_spaces); |
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513 s4o.print("/* to humour the compiler, we insert a nop */\n"); |
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514 s4o.print(s4o.indent_spaces); |
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515 this->default_variable_name.accept(*this); |
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516 s4o.print(" = "); |
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517 this->default_variable_name.accept(*this); |
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518 s4o.print(";\n"); |
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519 s4o.indent_left(); |
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520 |
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521 return NULL; |
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522 } |
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523 |
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524 |
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525 /* | label ':' [il_incomplete_instruction] eol_list */ |
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526 // SYM_REF2(il_instruction_c, label, il_instruction) |
|
527 void *visit(il_instruction_c *symbol) { |
|
528 if (NULL != symbol->label) { |
|
529 symbol->label->accept(*this); |
|
530 s4o.print(":\n"); |
|
531 s4o.print(s4o.indent_spaces); |
|
532 } |
|
533 symbol->il_instruction->accept(*this); |
|
534 return NULL; |
|
535 } |
|
536 |
|
537 /* | il_simple_operator [il_operand] */ |
|
538 //SYM_REF2(il_simple_operation_c, il_simple_operator, il_operand) |
|
539 void *visit(il_simple_operation_c *symbol) { |
|
540 this->current_operand = symbol->il_operand; |
|
541 if (NULL == this->current_operand) { |
|
542 this->current_operand_type = NULL; |
|
543 } else { |
|
544 this->current_operand_type = search_expression_type->get_type(this->current_operand); |
|
545 if (NULL == this->current_operand_type) ERROR; |
|
546 } |
|
547 |
|
548 symbol->il_simple_operator->accept(*this); |
|
549 |
|
550 this->current_operand = NULL; |
|
551 this->current_operand_type = NULL; |
|
552 return NULL; |
|
553 } |
|
554 |
|
555 |
|
556 /* | function_name [il_operand_list] */ |
|
557 // SYM_REF2(il_function_call_c, function_name, il_operand_list) |
|
558 void *visit(il_function_call_c *symbol) { |
|
559 function_declaration_c *f_decl = function_symtable.find_value(symbol->function_name); |
|
560 |
|
561 if (f_decl == function_symtable.end_value()) { |
|
562 /* should never occur. The function being called MUST be in the symtable... */ |
|
563 function_type_t current_function_type = get_function_type((identifier_c *)symbol->function_name); |
|
564 if (current_function_type == function_none) ERROR; |
|
565 |
|
566 symbol_c *param_data_type = default_variable_name.current_type; |
|
567 symbol_c *return_data_type = (symbol_c *)search_expression_type->compute_standard_function_il(symbol, param_data_type); |
|
568 if (NULL == return_data_type) ERROR; |
|
569 |
|
570 default_variable_name.current_type = return_data_type; |
|
571 this->default_variable_name.accept(*this); |
|
572 default_variable_name.current_type = param_data_type; |
|
573 s4o.print(" = "); |
|
574 |
|
575 function_call_param_iterator_c function_call_param_iterator(symbol); |
|
576 |
|
577 int nb_param = 1; |
|
578 if (symbol->il_operand_list != NULL) |
|
579 nb_param += ((list_c *)symbol->il_operand_list)->n; |
|
580 |
|
581 #include "il_code_gen.c" |
|
582 |
|
583 #if 0 |
|
584 for(int current_param = 0; current_param < nb_param; current_param++) { |
|
585 symbol_c *param_value; |
|
586 if (current_param == 0) |
|
587 param_value = &this->default_variable_name; |
|
588 else { |
|
589 symbol_c *param_name = NULL; |
|
590 switch (current_function_type) { |
|
591 default: ERROR; |
|
592 } |
|
593 |
|
594 |
|
595 /* Get the value from a foo(<param_name> = <param_value>) style call */ |
|
596 param_value = function_call_param_iterator.search(param_name); |
|
597 delete param_name; |
|
598 |
|
599 /* Get the value from a foo(<param_value>) style call */ |
|
600 if (param_value == NULL) |
|
601 param_value = function_call_param_iterator.next(); |
|
602 |
|
603 if (param_value == NULL) ERROR; |
|
604 } |
|
605 |
|
606 switch (current_function_type) { |
|
607 case (function_sqrt): |
|
608 if (current_param == 0) { |
|
609 s4o.print("sqrt("); |
|
610 param_value->accept(*this); |
|
611 s4o.print(")"); |
|
612 } |
|
613 else ERROR; |
|
614 break; |
|
615 default: ERROR; |
|
616 } |
|
617 } /* for(...) */ |
|
618 #endif |
|
619 |
|
620 /* the data type returned by the function, and stored in the il default variable... */ |
|
621 default_variable_name.current_type = return_data_type; |
|
622 } |
|
623 else { |
|
624 /* determine the base data type returned by the function being called... */ |
|
625 search_base_type_c search_base_type; |
|
626 symbol_c *return_data_type = (symbol_c *)f_decl->type_name->accept(search_base_type); |
|
627 symbol_c *param_data_type = default_variable_name.current_type; |
|
628 if (NULL == return_data_type) ERROR; |
|
629 |
|
630 default_variable_name.current_type = return_data_type; |
|
631 this->default_variable_name.accept(*this); |
|
632 default_variable_name.current_type = param_data_type; |
|
633 s4o.print(" = "); |
|
634 |
|
635 symbol->function_name->accept(*this); |
|
636 s4o.print("("); |
|
637 |
|
638 /* loop through each function parameter, find the value we should pass |
|
639 * to it, and then output the c equivalent... |
|
640 */ |
|
641 |
|
642 function_param_iterator_c fp_iterator(f_decl); |
|
643 identifier_c *param_name; |
|
644 function_call_param_iterator_c function_call_param_iterator(symbol); |
|
645 for(int i = 1; (param_name = fp_iterator.next()) != NULL; i++) { |
|
646 if (i != 1) |
|
647 s4o.print(", "); |
|
648 |
|
649 symbol_c *param_type = fp_iterator.param_type(); |
|
650 if (param_type == NULL) ERROR; |
|
651 |
|
652 function_param_iterator_c::param_direction_t param_direction = fp_iterator.param_direction(); |
|
653 |
|
654 |
|
655 symbol_c *param_value = NULL; |
|
656 |
|
657 /* if it is the first parameter, semantics specifies that we should |
|
658 * get the value off the IL default variable! |
|
659 */ |
|
660 if (1 == i) |
|
661 param_value = &this->default_variable_name; |
|
662 |
|
663 /* Get the value from a foo(<param_name> = <param_value>) style call */ |
|
664 /* NOTE: the following line of code is not required in this case, but it doesn't |
|
665 * harm to leave it in, as in the case of a non-formal syntax function call, |
|
666 * it will always return NULL. |
|
667 * We leave it in in case we later decide to merge this part of the code together |
|
668 * with the function calling code in generate_cc_st_c, which does require |
|
669 * the following line... |
|
670 */ |
|
671 if (param_value == NULL) |
|
672 param_value = function_call_param_iterator.search(param_name); |
|
673 |
|
674 /* Get the value from a foo(<param_value>) style call */ |
|
675 if (param_value == NULL) |
|
676 param_value = function_call_param_iterator.next(); |
|
677 |
|
678 switch (param_direction) { |
|
679 case function_param_iterator_c::direction_in: |
|
680 if (param_value == NULL) { |
|
681 /* No value given for parameter, so we must use the default... */ |
|
682 /* First check whether default value specified in function declaration...*/ |
|
683 param_value = fp_iterator.default_value(); |
|
684 } |
|
685 if (param_value == NULL) { |
|
686 /* If not, get the default value of this variable's type */ |
|
687 param_value = (symbol_c *)param_type->accept(*type_initial_value_c::instance()); |
|
688 } |
|
689 if (param_value == NULL) ERROR; |
|
690 param_value->accept(*this); |
|
691 break; |
|
692 case function_param_iterator_c::direction_out: |
|
693 case function_param_iterator_c::direction_inout: |
|
694 if (param_value == NULL) { |
|
695 /* no parameter value given, so we pass a previously declared temporary variable. */ |
|
696 std::string *temp_var_name = temp_var_name_factory.new_name(); |
|
697 s4o.print(*temp_var_name); |
|
698 delete temp_var_name; |
|
699 } else { |
|
700 param_value->accept(*this); |
|
701 } |
|
702 break; |
|
703 case function_param_iterator_c::direction_extref: |
|
704 /* TODO! */ |
|
705 ERROR; |
|
706 break; |
|
707 } /* switch */ |
|
708 } /* for(...) */ |
|
709 |
|
710 s4o.print(")"); |
|
711 /* the data type returned by the function, and stored in the il default variable... */ |
|
712 default_variable_name.current_type = return_data_type; |
|
713 } |
|
714 |
|
715 return NULL; |
|
716 } |
|
717 |
|
718 |
|
719 /* | il_expr_operator '(' [il_operand] eol_list [simple_instr_list] ')' */ |
|
720 //SYM_REF4(il_expression_c, il_expr_operator, il_operand, simple_instr_list, unused) |
|
721 void *visit(il_expression_c *symbol) { |
|
722 /* We will be recursevely interpreting an instruction list, |
|
723 * so we store a backup of the data type of the value currently stored |
|
724 * in the default variable, and set the current data type to NULL |
|
725 */ |
|
726 symbol_c *old_current_default_variable_data_type = this->default_variable_name.current_type; |
|
727 this->default_variable_name.current_type = NULL; |
|
728 |
|
729 /* Pass the symbol->il_operand to the simple_instr_list visitor |
|
730 * using the il_default_variable_init_value parameter... |
|
731 * Note that the simple_instr_list_c visitor will set this parameter |
|
732 * to NULL as soon as it does not require it any longer, |
|
733 * so we don't do it here again after the |
|
734 * symbol->simple_instr_list->accept(*this); |
|
735 * returns... |
|
736 */ |
|
737 this->il_default_variable_init_value = symbol->il_operand; |
|
738 |
|
739 /* Now do the parenthesised instructions... */ |
|
740 /* NOTE: the following code line will get the variable |
|
741 * this->default_variable_name.current_type updated! |
|
742 */ |
|
743 symbol->simple_instr_list->accept(*this); |
|
744 |
|
745 /* Now do the operation, using the previous result! */ |
|
746 /* NOTE: The result of the previous instruction list will be stored |
|
747 * in a variable named IL_DEFVAR_BACK. This is done in the visitor |
|
748 * to instruction_list_c objects... |
|
749 */ |
|
750 this->current_operand = &(this->default_variable_back_name); |
|
751 this->current_operand_type = this->default_variable_back_name.current_type; |
|
752 |
|
753 this->default_variable_name.current_type = old_current_default_variable_data_type; |
|
754 if (NULL == this->current_operand_type) ERROR; |
|
755 |
|
756 symbol->il_expr_operator->accept(*this); |
|
757 |
|
758 this->current_operand = NULL; |
|
759 this->current_operand_type = NULL; |
|
760 this->default_variable_back_name.current_type = NULL; |
|
761 return NULL; |
|
762 } |
|
763 |
|
764 /* il_jump_operator label */ |
|
765 // SYM_REF2(il_jump_operation_c, il_jump_operator, label) |
|
766 void *visit(il_jump_operation_c *symbol) { |
|
767 /* Pass the symbol->label to the il_jump_operation visitor |
|
768 * using the jump_label parameter... |
|
769 */ |
|
770 this->jump_label = symbol->label; |
|
771 symbol->il_jump_operator->accept(*this); |
|
772 this->jump_label = NULL; |
|
773 |
|
774 return NULL; |
|
775 } |
|
776 |
|
777 /* il_call_operator prev_declared_fb_name |
|
778 * | il_call_operator prev_declared_fb_name '(' ')' |
|
779 * | il_call_operator prev_declared_fb_name '(' eol_list ')' |
|
780 * | il_call_operator prev_declared_fb_name '(' il_operand_list ')' |
|
781 * | il_call_operator prev_declared_fb_name '(' eol_list il_param_list ')' |
|
782 */ |
|
783 // SYM_REF4(il_fb_call_c, il_call_operator, fb_name, il_operand_list, il_param_list) |
|
784 void *visit(il_fb_call_c *symbol) { |
|
785 symbol->il_call_operator->accept(*this); |
|
786 s4o.print("{\n"); |
|
787 s4o.indent_right(); |
|
788 s4o.print(s4o.indent_spaces); |
|
789 |
|
790 /* first figure out what is the name of the function block type of the function block being called... */ |
|
791 symbol_c *function_block_type_name = this->search_fb_instance_decl->get_type_name(symbol->fb_name); |
|
792 /* should never occur. The function block instance MUST have been declared... */ |
|
793 if (function_block_type_name == NULL) ERROR; |
|
794 |
|
795 /* Now find the declaration of the function block type being called... */ |
|
796 function_block_declaration_c *fb_decl = function_block_type_symtable.find_value(function_block_type_name); |
|
797 /* should never occur. The function block type being called MUST be in the symtable... */ |
|
798 if (fb_decl == function_block_type_symtable.end_value()) ERROR; |
|
799 |
|
800 /* loop through each function block parameter, find the value we should pass |
|
801 * to it, and then output the c equivalent... |
|
802 */ |
|
803 function_param_iterator_c fp_iterator(fb_decl); |
|
804 identifier_c *param_name; |
|
805 function_call_param_iterator_c function_call_param_iterator(symbol); |
|
806 for(int i = 1; (param_name = fp_iterator.next()) != NULL; i++) { |
|
807 function_param_iterator_c::param_direction_t param_direction = fp_iterator.param_direction(); |
|
808 |
|
809 /* Get the value from a foo(<param_name> = <param_value>) style call */ |
|
810 symbol_c *param_value = function_call_param_iterator.search(param_name); |
|
811 |
|
812 /* Get the value from a foo(<param_value>) style call */ |
|
813 if (param_value == NULL) |
|
814 param_value = function_call_param_iterator.next(); |
|
815 |
|
816 /* now output the value assignment */ |
|
817 if (param_value != NULL) |
|
818 if ((param_direction == function_param_iterator_c::direction_in) || |
|
819 (param_direction == function_param_iterator_c::direction_inout)) { |
|
820 symbol->fb_name->accept(*this); |
|
821 s4o.print("."); |
|
822 param_name->accept(*this); |
|
823 s4o.print(" = "); |
|
824 param_value->accept(*this); |
|
825 s4o.print(";\n" + s4o.indent_spaces); |
|
826 } |
|
827 } /* for(...) */ |
|
828 |
|
829 /* now call the function... */ |
|
830 function_block_type_name->accept(*this); |
|
831 s4o.print(FB_FUNCTION_SUFFIX); |
|
832 s4o.print("(&"); |
|
833 symbol->fb_name->accept(*this); |
|
834 s4o.print(")"); |
|
835 |
|
836 /* loop through each function parameter, find the variable to which |
|
837 * we should atribute the value of all output or inoutput parameters. |
|
838 */ |
|
839 fp_iterator.reset(); |
|
840 function_call_param_iterator.reset(); |
|
841 for(int i = 1; (param_name = fp_iterator.next()) != NULL; i++) { |
|
842 function_param_iterator_c::param_direction_t param_direction = fp_iterator.param_direction(); |
|
843 |
|
844 /* Get the value from a foo(<param_name> = <param_value>) style call */ |
|
845 symbol_c *param_value = function_call_param_iterator.search(param_name); |
|
846 |
|
847 /* Get the value from a foo(<param_value>) style call */ |
|
848 if (param_value == NULL) |
|
849 param_value = function_call_param_iterator.next(); |
|
850 |
|
851 /* now output the value assignment */ |
|
852 if (param_value != NULL) |
|
853 if ((param_direction == function_param_iterator_c::direction_out) || |
|
854 (param_direction == function_param_iterator_c::direction_inout)) { |
|
855 s4o.print(";\n"+ s4o.indent_spaces); |
|
856 param_value->accept(*this); |
|
857 s4o.print(" = "); |
|
858 symbol->fb_name->accept(*this); |
|
859 s4o.print("."); |
|
860 param_name->accept(*this); |
|
861 } |
|
862 } /* for(...) */ |
|
863 |
|
864 s4o.print(";\n"); |
|
865 s4o.indent_left(); |
|
866 s4o.print(s4o.indent_spaces); |
|
867 s4o.print("}"); |
|
868 |
|
869 return NULL; |
|
870 } |
|
871 |
|
872 |
|
873 |
|
874 /* | function_name '(' eol_list [il_param_list] ')' */ |
|
875 // SYM_REF2(il_formal_funct_call_c, function_name, il_param_list) |
|
876 void *visit(il_formal_funct_call_c *symbol) { |
|
877 function_declaration_c *f_decl = function_symtable.find_value(symbol->function_name); |
|
878 |
|
879 if (f_decl == function_symtable.end_value()) |
|
880 /* should never occur. The function being called MUST be in the symtable... */ |
|
881 ERROR; |
|
882 |
|
883 symbol->function_name->accept(*this); |
|
884 s4o.print("("); |
|
885 |
|
886 /* loop through each function parameter, find the value we should pass |
|
887 * to it, and then output the c equivalent... |
|
888 */ |
|
889 |
|
890 function_param_iterator_c fp_iterator(f_decl); |
|
891 identifier_c *param_name; |
|
892 function_call_param_iterator_c function_call_param_iterator(symbol); |
|
893 for(int i = 1; (param_name = fp_iterator.next()) != NULL; i++) { |
|
894 if (i != 1) |
|
895 s4o.print(", "); |
|
896 |
|
897 symbol_c *param_type = fp_iterator.param_type(); |
|
898 if (param_type == NULL) ERROR; |
|
899 |
|
900 function_param_iterator_c::param_direction_t param_direction = fp_iterator.param_direction(); |
|
901 |
|
902 |
|
903 symbol_c *param_value = NULL; |
|
904 |
|
905 /* Get the value from a foo(<param_name> = <param_value>) style call */ |
|
906 if (param_value == NULL) |
|
907 param_value = function_call_param_iterator.search(param_name); |
|
908 |
|
909 /* Get the value from a foo(<param_value>) style call */ |
|
910 /* NOTE: the following line of code is not required in this case, but it doesn't |
|
911 * harm to leave it in, as in the case of a formal syntax function call, |
|
912 * it will always return NULL. |
|
913 * We leave it in in case we later decide to merge this part of the code together |
|
914 * with the function calling code in generate_cc_st_c, which does require |
|
915 * the following line... |
|
916 */ |
|
917 if (param_value == NULL) |
|
918 param_value = function_call_param_iterator.next(); |
|
919 |
|
920 switch (param_direction) { |
|
921 case function_param_iterator_c::direction_in: |
|
922 if (param_value == NULL) { |
|
923 /* No value given for parameter, so we must use the default... */ |
|
924 /* First check whether default value specified in function declaration...*/ |
|
925 param_value = fp_iterator.default_value(); |
|
926 } |
|
927 if (param_value == NULL) { |
|
928 /* If not, get the default value of this variable's type */ |
|
929 param_value = (symbol_c *)param_type->accept(*type_initial_value_c::instance()); |
|
930 } |
|
931 if (param_value == NULL) ERROR; |
|
932 param_value->accept(*this); |
|
933 break; |
|
934 case function_param_iterator_c::direction_out: |
|
935 case function_param_iterator_c::direction_inout: |
|
936 if (param_value == NULL) { |
|
937 /* no parameter value given, so we pass a previously declared temporary variable. */ |
|
938 std::string *temp_var_name = temp_var_name_factory.new_name(); |
|
939 s4o.print(*temp_var_name); |
|
940 delete temp_var_name; |
|
941 } else { |
|
942 param_value->accept(*this); |
|
943 } |
|
944 break; |
|
945 case function_param_iterator_c::direction_extref: |
|
946 /* TODO! */ |
|
947 ERROR; |
|
948 break; |
|
949 } /* switch */ |
|
950 } /* for(...) */ |
|
951 |
|
952 // symbol->parameter_assignment->accept(*this); |
|
953 s4o.print(")"); |
|
954 return NULL; |
|
955 } |
|
956 |
|
957 |
|
958 /* | il_operand_list ',' il_operand */ |
|
959 // SYM_LIST(il_operand_list_c) |
|
960 void *visit(il_operand_list_c *symbol) {ERROR; return NULL;} // should never get called! |
|
961 |
|
962 |
|
963 /* | simple_instr_list il_simple_instruction */ |
|
964 // SYM_LIST(simple_instr_list_c) |
|
965 void *visit(simple_instr_list_c *symbol) { |
|
966 /* A simple_instr_list_c is used to store a list of il operations |
|
967 * being done within parenthesis... |
|
968 * |
|
969 * e.g.: |
|
970 * LD var1 |
|
971 * AND ( var2 |
|
972 * OR var3 |
|
973 * OR var4 |
|
974 * ) |
|
975 * |
|
976 * This will be converted to C++ by defining a new scope |
|
977 * with a new il default variable, and executing the il operands |
|
978 * within this new scope. |
|
979 * At the end of the scope the result, i.e. the value currently stored |
|
980 * in the il default variable is copied to the variable used to take this |
|
981 * value to the outside scope... |
|
982 * |
|
983 * The above example will result in the following C++ code: |
|
984 * {__IL_DEFVAR_T __IL_DEFVAR_BACK; |
|
985 * __IL_DEFVAR_T __IL_DEFVAR; |
|
986 * |
|
987 * __IL_DEFVAR.INTvar = var1; |
|
988 * { |
|
989 * __IL_DEFVAR_T __IL_DEFVAR; |
|
990 * |
|
991 * __IL_DEFVAR.INTvar = var2; |
|
992 * __IL_DEFVAR.INTvar |= var3; |
|
993 * __IL_DEFVAR.INTvar |= var4; |
|
994 * |
|
995 * __IL_DEFVAR_BACK = __IL_DEFVAR; |
|
996 * } |
|
997 * __IL_DEFVAR.INTvar &= __IL_DEFVAR_BACK.INTvar; |
|
998 * |
|
999 * } |
|
1000 * |
|
1001 * The intial value of the il default variable (in the above |
|
1002 * example 'var2') is passed to this simple_instr_list_c visitor |
|
1003 * using the il_default_variable_init_value parameter. |
|
1004 * Since it is possible to have parenthesis inside other parenthesis |
|
1005 * recursively, we reset the il_default_variable_init_value to NULL |
|
1006 * as soon as we no longer require it, as it may be used once again |
|
1007 * in the line |
|
1008 * print_list(symbol, s4o.indent_spaces, ";\n" + s4o.indent_spaces, ";\n"); |
|
1009 * |
|
1010 */ |
|
1011 |
|
1012 /* Declare the default variable, that will store the result of the IL operations... */ |
|
1013 s4o.print("{\n"); |
|
1014 s4o.indent_right(); |
|
1015 |
|
1016 s4o.print(s4o.indent_spaces); |
|
1017 s4o.print(IL_DEFVAR_T); |
|
1018 s4o.print(" "); |
|
1019 this->default_variable_name.accept(*this); |
|
1020 s4o.print(";\n\n"); |
|
1021 |
|
1022 /* Check whether we should initiliase the il default variable... */ |
|
1023 if (NULL != this->il_default_variable_init_value) { |
|
1024 /* Yes, we must... */ |
|
1025 /* We will do it by instatiating a LD operator, and having this |
|
1026 * same generate_cc_il_c class visiting it! |
|
1027 */ |
|
1028 LD_operator_c ld_oper; |
|
1029 il_simple_operation_c il_simple_oper(&ld_oper, this->il_default_variable_init_value); |
|
1030 |
|
1031 s4o.print(s4o.indent_spaces); |
|
1032 il_simple_oper.accept(*this); |
|
1033 s4o.print(";\n"); |
|
1034 } |
|
1035 |
|
1036 /* this parameter no longer required... */ |
|
1037 this->il_default_variable_init_value = NULL; |
|
1038 |
|
1039 print_list(symbol, s4o.indent_spaces, ";\n" + s4o.indent_spaces, ";\n"); |
|
1040 |
|
1041 /* copy the result in the default variable to the variable |
|
1042 * used to pass the data out to the scope enclosing |
|
1043 * the current scope! |
|
1044 * |
|
1045 * We also need to update the data type currently stored within |
|
1046 * the variable used to pass the data to the outside scope... |
|
1047 */ |
|
1048 this->default_variable_back_name.current_type = this->default_variable_name.current_type; |
|
1049 s4o.print("\n"); |
|
1050 s4o.print(s4o.indent_spaces); |
|
1051 this->default_variable_back_name.accept(*this); |
|
1052 s4o.print(" = "); |
|
1053 this->default_variable_name.accept(*this); |
|
1054 s4o.print(";\n"); |
|
1055 |
|
1056 s4o.indent_left(); |
|
1057 s4o.print(s4o.indent_spaces); |
|
1058 s4o.print("}\n"); |
|
1059 s4o.print(s4o.indent_spaces); |
|
1060 return NULL; |
|
1061 } |
|
1062 |
|
1063 /* | il_initial_param_list il_param_instruction */ |
|
1064 // SYM_LIST(il_param_list_c) |
|
1065 void *visit(il_param_list_c *symbol) {ERROR; return NULL;} // should never get called! |
|
1066 |
|
1067 /* il_assign_operator il_operand |
|
1068 * | il_assign_operator '(' eol_list simple_instr_list ')' |
|
1069 */ |
|
1070 // SYM_REF4(il_param_assignment_c, il_assign_operator, il_operand, simple_instr_list, unused) |
|
1071 void *visit(il_param_assignment_c *symbol) {ERROR; return NULL;} // should never get called! |
|
1072 |
|
1073 /* il_assign_out_operator variable */ |
|
1074 // SYM_REF2(il_param_out_assignment_c, il_assign_out_operator, variable); |
|
1075 void *visit(il_param_out_assignment_c *symbol) {ERROR; return NULL;} // should never get called! |
|
1076 |
|
1077 /*******************/ |
|
1078 /* B 2.2 Operators */ |
|
1079 /*******************/ |
|
1080 |
|
1081 void *visit(LD_operator_c *symbol) { |
|
1082 /* the data type resulting from this operation... */ |
|
1083 this->default_variable_name.current_type = this->current_operand_type; |
|
1084 XXX_operator(&(this->default_variable_name), " = ", this->current_operand); |
|
1085 return NULL; |
|
1086 } |
|
1087 |
|
1088 void *visit(LDN_operator_c *symbol) { |
|
1089 /* the data type resulting from this operation... */ |
|
1090 this->default_variable_name.current_type = this->current_operand_type; |
|
1091 XXX_operator(&(this->default_variable_name), |
|
1092 search_expression_type->is_bool_type(this->current_operand_type)?" = !":" = ~", |
|
1093 this->current_operand); |
|
1094 return NULL; |
|
1095 } |
|
1096 |
|
1097 void *visit(ST_operator_c *symbol) { |
|
1098 XXX_operator(this->current_operand, " = ",&(this->default_variable_name)); |
|
1099 /* the data type resulting from this operation is unchamged. */ |
|
1100 return NULL; |
|
1101 } |
|
1102 |
|
1103 void *visit(STN_operator_c *symbol) { |
|
1104 XXX_operator(this->current_operand, |
|
1105 search_expression_type->is_bool_type(this->current_operand_type)?" = !":" = ~", |
|
1106 &(this->default_variable_name)); |
|
1107 /* the data type resulting from this operation is unchamged. */ |
|
1108 return NULL; |
|
1109 } |
|
1110 |
|
1111 void *visit(NOT_operator_c *symbol) { |
|
1112 if ((NULL != this->current_operand) || (NULL != this->current_operand_type)) ERROR; |
|
1113 XXX_operator(&(this->default_variable_name), |
|
1114 search_expression_type->is_bool_type(this->default_variable_name.current_type)?" = !":" = ~", |
|
1115 &(this->default_variable_name)); |
|
1116 /* the data type resulting from this operation is unchanged. */ |
|
1117 return NULL; |
|
1118 } |
|
1119 |
|
1120 void *visit(S_operator_c *symbol) { |
|
1121 if ((NULL == this->current_operand) || (NULL == this->current_operand_type)) ERROR; |
|
1122 |
|
1123 C_modifier(); |
|
1124 this->current_operand->accept(*this); |
|
1125 s4o.print(search_expression_type->is_bool_type(this->current_operand_type)?" = true":" = 1"); |
|
1126 /* the data type resulting from this operation is unchanged! */ |
|
1127 return NULL; |
|
1128 } |
|
1129 |
|
1130 void *visit(R_operator_c *symbol) { |
|
1131 if ((NULL == this->current_operand) || (NULL == this->current_operand_type)) ERROR; |
|
1132 |
|
1133 C_modifier(); |
|
1134 this->current_operand->accept(*this); |
|
1135 s4o.print(search_expression_type->is_bool_type(this->current_operand_type)?" = false":" = 0"); |
|
1136 /* the data type resulting from this operation is unchanged! */ |
|
1137 return NULL; |
|
1138 } |
|
1139 |
|
1140 void *visit(S1_operator_c *symbol) {return XXX_CAL_operator("S1", this->current_operand);} |
|
1141 void *visit(R1_operator_c *symbol) {return XXX_CAL_operator("R1", this->current_operand);} |
|
1142 void *visit(CLK_operator_c *symbol) {return XXX_CAL_operator("CLK", this->current_operand);} |
|
1143 void *visit(CU_operator_c *symbol) {return XXX_CAL_operator("CU", this->current_operand);} |
|
1144 void *visit(CD_operator_c *symbol) {return XXX_CAL_operator("CD", this->current_operand);} |
|
1145 void *visit(PV_operator_c *symbol) {return XXX_CAL_operator("PV", this->current_operand);} |
|
1146 void *visit(IN_operator_c *symbol) {return XXX_CAL_operator("IN", this->current_operand);} |
|
1147 void *visit(PT_operator_c *symbol) {return XXX_CAL_operator("PT", this->current_operand);} |
|
1148 |
|
1149 void *visit(AND_operator_c *symbol) { |
|
1150 if (search_expression_type->is_binary_type(this->default_variable_name.current_type) && |
|
1151 search_expression_type->is_same_type(this->default_variable_name.current_type, this->current_operand_type)) { |
|
1152 XXX_operator(&(this->default_variable_name), " &= ", this->current_operand); |
|
1153 /* the data type resulting from this operation... */ |
|
1154 this->default_variable_name.current_type = this->current_operand_type; |
|
1155 } |
|
1156 else {ERROR;} |
|
1157 return NULL; |
|
1158 } |
|
1159 |
|
1160 void *visit(OR_operator_c *symbol) { |
|
1161 if (search_expression_type->is_binary_type(this->default_variable_name.current_type) && |
|
1162 search_expression_type->is_same_type(this->default_variable_name.current_type, this->current_operand_type)) { |
|
1163 XXX_operator(&(this->default_variable_name), " |= ", this->current_operand); |
|
1164 /* the data type resulting from this operation... */ |
|
1165 this->default_variable_name.current_type = this->current_operand_type; |
|
1166 } |
|
1167 else {ERROR;} |
|
1168 return NULL; |
|
1169 } |
|
1170 |
|
1171 void *visit(XOR_operator_c *symbol) { |
|
1172 if (search_expression_type->is_binary_type(this->default_variable_name.current_type) && |
|
1173 search_expression_type->is_same_type(this->default_variable_name.current_type, this->current_operand_type)) { |
|
1174 // '^' is a bit by bit exclusive OR !! Also seems to work with boolean types! |
|
1175 XXX_operator(&(this->default_variable_name), " ^= ", this->current_operand); |
|
1176 /* the data type resulting from this operation... */ |
|
1177 this->default_variable_name.current_type = this->current_operand_type; |
|
1178 } |
|
1179 else {ERROR;} |
|
1180 return NULL; |
|
1181 } |
|
1182 |
|
1183 void *visit(ANDN_operator_c *symbol) { |
|
1184 if (search_expression_type->is_binary_type(this->default_variable_name.current_type) && |
|
1185 search_expression_type->is_same_type(this->default_variable_name.current_type, this->current_operand_type)) { |
|
1186 XXX_operator(&(this->default_variable_name), |
|
1187 search_expression_type->is_bool_type(this->current_operand_type)?" &= !":" &= ~", |
|
1188 this->current_operand); |
|
1189 /* the data type resulting from this operation... */ |
|
1190 this->default_variable_name.current_type = this->current_operand_type; |
|
1191 } |
|
1192 else {ERROR;} |
|
1193 return NULL; |
|
1194 } |
|
1195 |
|
1196 void *visit(ORN_operator_c *symbol) { |
|
1197 if (search_expression_type->is_binary_type(this->default_variable_name.current_type) && |
|
1198 search_expression_type->is_same_type(this->default_variable_name.current_type, this->current_operand_type)) { |
|
1199 XXX_operator(&(this->default_variable_name), |
|
1200 search_expression_type->is_bool_type(this->current_operand_type)?" |= !":" |= ~", |
|
1201 this->current_operand); |
|
1202 /* the data type resulting from this operation... */ |
|
1203 this->default_variable_name.current_type = this->current_operand_type; |
|
1204 } |
|
1205 else {ERROR;} |
|
1206 return NULL; |
|
1207 } |
|
1208 |
|
1209 void *visit(XORN_operator_c *symbol) { |
|
1210 if (search_expression_type->is_binary_type(this->default_variable_name.current_type) && |
|
1211 search_expression_type->is_same_type(this->default_variable_name.current_type, this->current_operand_type)) { |
|
1212 XXX_operator(&(this->default_variable_name), |
|
1213 // bit by bit exclusive OR !! Also seems to work with boolean types! |
|
1214 search_expression_type->is_bool_type(this->current_operand_type)?" ^= !":" ^= ~", |
|
1215 this->current_operand); |
|
1216 /* the data type resulting from this operation... */ |
|
1217 this->default_variable_name.current_type = this->current_operand_type; |
|
1218 } |
|
1219 else {ERROR;} |
|
1220 return NULL; |
|
1221 } |
|
1222 |
|
1223 void *visit(ADD_operator_c *symbol) { |
|
1224 if (search_expression_type->is_time_type(this->default_variable_name.current_type) && |
|
1225 search_expression_type->is_time_type(this->current_operand_type)) { |
|
1226 XXX_function("__time_add", &(this->default_variable_name), this->current_operand); |
|
1227 /* the data type resulting from this operation... */ |
|
1228 this->default_variable_name.current_type = this->current_operand_type; |
|
1229 return NULL; |
|
1230 } |
|
1231 if (search_expression_type->is_num_type(this->default_variable_name.current_type) && |
|
1232 search_expression_type->is_same_type(this->default_variable_name.current_type, this->current_operand_type)) { |
|
1233 XXX_operator(&(this->default_variable_name), " += ", this->current_operand); |
|
1234 /* the data type resulting from this operation... */ |
|
1235 this->default_variable_name.current_type = this->current_operand_type; |
|
1236 return NULL; |
|
1237 } |
|
1238 ERROR; |
|
1239 return NULL; |
|
1240 } |
|
1241 |
|
1242 void *visit(SUB_operator_c *symbol) { |
|
1243 if (search_expression_type->is_time_type(this->default_variable_name.current_type) && |
|
1244 search_expression_type->is_time_type(this->current_operand_type)) { |
|
1245 XXX_function("__time_sub", &(this->default_variable_name), this->current_operand); |
|
1246 /* the data type resulting from this operation... */ |
|
1247 this->default_variable_name.current_type = this->current_operand_type; |
|
1248 return NULL; |
|
1249 } |
|
1250 if (search_expression_type->is_num_type(this->default_variable_name.current_type) && |
|
1251 search_expression_type->is_same_type(this->default_variable_name.current_type, this->current_operand_type)) { |
|
1252 XXX_operator(&(this->default_variable_name), " -= ", this->current_operand); |
|
1253 /* the data type resulting from this operation... */ |
|
1254 this->default_variable_name.current_type = this->current_operand_type; |
|
1255 return NULL; |
|
1256 } |
|
1257 ERROR; |
|
1258 return NULL; |
|
1259 } |
|
1260 |
|
1261 void *visit(MUL_operator_c *symbol) { |
|
1262 if (search_expression_type->is_time_type(this->default_variable_name.current_type) && |
|
1263 search_expression_type->is_integer_type(this->current_operand_type)) { |
|
1264 XXX_function("__time_mul", &(this->default_variable_name), this->current_operand); |
|
1265 /* the data type resulting from this operation... */ |
|
1266 this->default_variable_name.current_type = this->current_operand_type; |
|
1267 return NULL; |
|
1268 } |
|
1269 if (search_expression_type->is_num_type(this->default_variable_name.current_type) && |
|
1270 search_expression_type->is_same_type(this->default_variable_name.current_type, this->current_operand_type)) { |
|
1271 XXX_operator(&(this->default_variable_name), " *= ", this->current_operand); |
|
1272 /* the data type resulting from this operation... */ |
|
1273 this->default_variable_name.current_type = this->current_operand_type; |
|
1274 return NULL; |
|
1275 } |
|
1276 ERROR; |
|
1277 return NULL; |
|
1278 } |
|
1279 |
|
1280 void *visit(DIV_operator_c *symbol) { |
|
1281 if (search_expression_type->is_num_type(this->default_variable_name.current_type) && |
|
1282 search_expression_type->is_same_type(this->default_variable_name.current_type, this->current_operand_type)) { |
|
1283 XXX_operator(&(this->default_variable_name), " /= ", this->current_operand); |
|
1284 /* the data type resulting from this operation... */ |
|
1285 this->default_variable_name.current_type = this->current_operand_type; |
|
1286 } |
|
1287 else {ERROR;} |
|
1288 return NULL; |
|
1289 } |
|
1290 |
|
1291 void *visit(MOD_operator_c *symbol) { |
|
1292 if (search_expression_type->is_num_type(this->default_variable_name.current_type) && |
|
1293 search_expression_type->is_same_type(this->default_variable_name.current_type, this->current_operand_type)) { |
|
1294 XXX_operator(&(this->default_variable_name), " %= ", this->current_operand); |
|
1295 /* the data type resulting from this operation... */ |
|
1296 this->default_variable_name.current_type = this->current_operand_type; |
|
1297 } |
|
1298 else {ERROR;} |
|
1299 return NULL; |
|
1300 } |
|
1301 |
|
1302 void *visit(GT_operator_c *symbol) { |
|
1303 return CMP_operator(this->current_operand, "__gt_"); |
|
1304 } |
|
1305 |
|
1306 void *visit(GE_operator_c *symbol) { |
|
1307 return CMP_operator(this->current_operand, "__ge_"); |
|
1308 } |
|
1309 |
|
1310 void *visit(EQ_operator_c *symbol) { |
|
1311 return CMP_operator(this->current_operand, "__eq_"); |
|
1312 } |
|
1313 |
|
1314 void *visit(LT_operator_c *symbol) { |
|
1315 return CMP_operator(this->current_operand, "__lt_"); |
|
1316 } |
|
1317 |
|
1318 void *visit(LE_operator_c *symbol) { |
|
1319 return CMP_operator(this->current_operand, "__le_"); |
|
1320 } |
|
1321 |
|
1322 void *visit(NE_operator_c *symbol) { |
|
1323 return CMP_operator(this->current_operand, "__ne_"); |
|
1324 } |
|
1325 |
|
1326 |
|
1327 //SYM_REF0(CAL_operator_c) |
|
1328 // This method will be called from within the il_fb_call_c visitor method |
|
1329 void *visit(CAL_operator_c *symbol) {return NULL;} |
|
1330 |
|
1331 //SYM_REF0(CALC_operator_c) |
|
1332 // This method will be called from within the il_fb_call_c visitor method |
|
1333 void *visit(CALC_operator_c *symbol) {C_modifier(); return NULL;} |
|
1334 |
|
1335 //SYM_REF0(CALCN_operator_c) |
|
1336 // This method will be called from within the il_fb_call_c visitor method |
|
1337 void *visit(CALCN_operator_c *symbol) {CN_modifier(); return NULL;} |
|
1338 |
|
1339 /* NOTE: The semantics of the RET operator requires us to return a value |
|
1340 * if the IL code is inside a function, but simply return no value if |
|
1341 * the IL code is inside a function block or program! |
|
1342 * Nevertheless, it is the generate_cc_c class itself that |
|
1343 * introduces the 'reaturn <value>' into the c++ code at the end |
|
1344 * of every function. This class does not know whether the IL code |
|
1345 * is inside a function or a function block. |
|
1346 * We work around this by jumping to the end of the code, |
|
1347 * that will be marked by the END_LABEL label in the |
|
1348 * instruction_list_c visitor... |
|
1349 */ |
|
1350 // SYM_REF0(RET_operator_c) |
|
1351 void *visit(RET_operator_c *symbol) { |
|
1352 s4o.print("goto ");s4o.print(END_LABEL); |
|
1353 return NULL; |
|
1354 } |
|
1355 |
|
1356 // SYM_REF0(RETC_operator_c) |
|
1357 void *visit(RETC_operator_c *symbol) { |
|
1358 C_modifier(); |
|
1359 s4o.print("goto ");s4o.print(END_LABEL); |
|
1360 return NULL; |
|
1361 } |
|
1362 |
|
1363 // SYM_REF0(RETCN_operator_c) |
|
1364 void *visit(RETCN_operator_c *symbol) { |
|
1365 CN_modifier(); |
|
1366 s4o.print("goto ");s4o.print(END_LABEL); |
|
1367 return NULL; |
|
1368 } |
|
1369 |
|
1370 //SYM_REF0(JMP_operator_c) |
|
1371 void *visit(JMP_operator_c *symbol) { |
|
1372 if (NULL == this->jump_label) ERROR; |
|
1373 |
|
1374 s4o.print("goto "); |
|
1375 this->jump_label->accept(*this); |
|
1376 /* the data type resulting from this operation is unchanged! */ |
|
1377 return NULL; |
|
1378 } |
|
1379 |
|
1380 // SYM_REF0(JMPC_operator_c) |
|
1381 void *visit(JMPC_operator_c *symbol) { |
|
1382 if (NULL == this->jump_label) ERROR; |
|
1383 |
|
1384 C_modifier(); |
|
1385 s4o.print("goto "); |
|
1386 this->jump_label->accept(*this); |
|
1387 /* the data type resulting from this operation is unchanged! */ |
|
1388 return NULL; |
|
1389 } |
|
1390 |
|
1391 // SYM_REF0(JMPCN_operator_c) |
|
1392 void *visit(JMPCN_operator_c *symbol) { |
|
1393 if (NULL == this->jump_label) ERROR; |
|
1394 |
|
1395 CN_modifier(); |
|
1396 s4o.print("goto "); |
|
1397 this->jump_label->accept(*this); |
|
1398 /* the data type resulting from this operation is unchanged! */ |
|
1399 return NULL; |
|
1400 } |
|
1401 |
|
1402 #if 0 |
|
1403 /*| [NOT] any_identifier SENDTO */ |
|
1404 SYM_REF2(il_assign_out_operator_c, option, variable_name) |
|
1405 #endif |
|
1406 |
|
1407 }; /* generate_cc_il_c */ |
|
1408 |
|
1409 |
|
1410 |
|
1411 |
|
1412 |
|
1413 |
|
1414 |
|
1415 |
|
1416 |
|
1417 /* The implementation of the single visit() member function |
|
1418 * of il_default_variable_c. |
|
1419 * It can only come after the full declaration of |
|
1420 * generate_cc_il_c. Since we define and declare |
|
1421 * generate_cc_il_c simultaneously, it can only come |
|
1422 * after the definition... |
|
1423 */ |
|
1424 void *il_default_variable_c::accept(visitor_c &visitor) { |
|
1425 /* An ugly hack!! */ |
|
1426 /* This is required because we need to over-ride the base |
|
1427 * accept(visitor_c &) method of the class symbol_c, |
|
1428 * so this method may be called through a symbol_c * |
|
1429 * reference! |
|
1430 * |
|
1431 * But, the visitor_c does not include a visitor to |
|
1432 * an il_default_variable_c, which means that we couldn't |
|
1433 * simply call visitor.visit(this); |
|
1434 * |
|
1435 * We therefore need to use the dynamic_cast hack!! |
|
1436 * |
|
1437 * Note too that we can't cast a visitor_c to a |
|
1438 * il_default_variable_visitor_c, since they are not related. |
|
1439 * Nor may the il_default_variable_visitor_c inherit from |
|
1440 * visitor_c, because then generate_cc_il_c would contain |
|
1441 * two visitor_c base classes, one each through |
|
1442 * il_default_variable_visitor_c and generate_cc_type_c |
|
1443 * |
|
1444 * We could use virtual inheritance of the visitor_c, but it |
|
1445 * would probably create more problems than it is worth! |
|
1446 */ |
|
1447 generate_cc_il_c *v; |
|
1448 v = dynamic_cast<generate_cc_il_c *>(&visitor); |
|
1449 if (v == NULL) ERROR; |
|
1450 |
|
1451 return v->visit(this); |
|
1452 } |
|
1453 |
|
1454 |
|
1455 |
|
1456 |
|
1457 il_default_variable_c::il_default_variable_c(const char *var_name_str, symbol_c *current_type) { |
|
1458 if (NULL == var_name_str) ERROR; |
|
1459 /* Note: current_type may start off with NULL */ |
|
1460 |
|
1461 this->var_name = new identifier_c(var_name_str); |
|
1462 if (NULL == this->var_name) ERROR; |
|
1463 |
|
1464 this->current_type = current_type; |
|
1465 } |
|