1 | Proposal For Use of Virtual Tables |
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2 | ================================== |
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3 | |
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4 | The basic concept of a virtual table (vtable) is the same here as in most |
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5 | other languages that use them. They will mostly contain function pointers |
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6 | although they should be able to store anything that goes into a trait. |
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7 | |
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8 | I also include notes on a sample implementation, which primarily exists to show |
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9 | there is a reasonable implementation. The code samples for that are in a slight |
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10 | pseudo-code to help avoid name mangling and keeps some CFA features while they |
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11 | would actually be written in C. |
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12 | |
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13 | Trait Instances |
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14 | --------------- |
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15 | |
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16 | Currently traits are completely abstract. Data types might implement a trait |
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17 | but traits are not themselves data types. Which is to say you cannot have an |
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18 | instance of a trait. This proposal will change that and allow instances of |
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19 | traits to be created from instances of data types that implement the trait. |
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20 | |
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21 | For example: |
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22 | |
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23 | trait combiner(otype T) { |
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24 | void combine(T&, int); |
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25 | }; |
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26 | |
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27 | struct summation { |
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28 | int sum; |
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29 | }; |
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30 | |
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31 | void ?{}( struct summation & this ) { |
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32 | this.sum = 0; |
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33 | } |
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34 | |
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35 | void combine( struct summation & this, int num ) { |
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36 | this.sum = this.sum + num; |
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37 | } |
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38 | |
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39 | trait combiner obj = struct summation{}; |
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40 | combine(obj, 5); |
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41 | |
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42 | As with `struct` (and `union` and `enum`), `trait` might be optional when |
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43 | using the trait as a type name. A trait may be used in assertion list as |
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44 | before. |
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45 | |
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46 | For traits to be used this way they should meet two requirements. First they |
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47 | should only have a single polymorphic type and each assertion should use that |
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48 | type once as a parameter. Extensions may later loosen these requirements. |
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49 | |
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50 | Also note this applies to the final expanded list of assertions. Consider: |
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51 | |
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52 | trait foo(otype T, otype U) { |
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53 | ... functions that use T once ... |
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54 | } |
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55 | |
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56 | trait bar(otype S | foo(S, char)) { |
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57 | ... functions that use S once ... |
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58 | } |
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59 | |
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60 | In this example `bar` may be used as a type but `foo` may not. |
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61 | |
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62 | When a trait is used as a type it creates a generic object which combines |
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63 | the base structure (an instance of `summation` in this case) and the vtable, |
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64 | which is currently created and provided by a hidden mechanism. |
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65 | |
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66 | The generic object type for each trait also implements that trait. This is |
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67 | actually the only means by which it can be used. The type of these functions |
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68 | look something like this: |
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69 | |
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70 | void combine(trait combiner & this, int num); |
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71 | |
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72 | The main use case for trait objects is that they can be stored. They can be |
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73 | passed into functions, but using the trait directly is preferred in this case. |
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74 | |
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75 | trait drawable(otype T) { |
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76 | void draw(Surface & to, T & draw); |
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77 | Rect(int) drawArea(T & draw); |
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78 | }; |
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79 | |
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80 | struct UpdatingSurface { |
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81 | Surface * surface; |
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82 | vector(trait drawable) drawables; |
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83 | }; |
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84 | |
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85 | void updateSurface(UpdatingSurface & us) { |
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86 | for (size_t i = 0 ; i < us.drawables.size ; ++i) { |
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87 | draw(us.surface, us.drawables[i]); |
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88 | } |
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89 | } |
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90 | |
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91 | With a more complete widget trait you could, for example, construct a UI tool |
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92 | kit that can declare containers that hold widgets without knowing about the |
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93 | widget types. Making it reasonable to extend the tool kit. |
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94 | |
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95 | The trait types can also be used in the types of assertions on traits as well. |
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96 | In this usage they passed as the underlying object and vtable pair as they |
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97 | are stored. The trait types can also be used in that trait's definition, which |
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98 | means you can pass two instances of a trait to a single function. However the |
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99 | look-up of the one that is not used to look up any functions, until another |
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100 | function that uses that object in the generic/look-up location is called. |
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101 | |
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102 | trait example(otype T) { |
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103 | bool test(T & this, trait example & that); |
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104 | } |
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105 | |
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106 | ### Explanation Of Restrictions |
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107 | |
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108 | The two restrictions on traits that can be used as trait objects are: |
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109 | |
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110 | 1. Only one generic parameter may be defined in the trait's header. |
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111 | 2. Each function assertion must have one parameter with the type of the |
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112 | generic parameter. They may or may not return a value of that type. |
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113 | |
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114 | Elsewhere in this proposal I suggest ways to broaden these requirements. |
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115 | A simple example would be if a trait meets requirement 1 but not 2, then |
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116 | the assertions that do not satisfy the exactly one parameter requirement can |
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117 | be ignored. |
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118 | |
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119 | However I would like to talk about why these two rules are in place in the |
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120 | first place and the problems that any exceptions to these rules must avoid. |
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121 | |
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122 | The problems appear when the dispatcher function which operates on the |
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123 | generic object. |
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124 | |
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125 | trait combiner(otype T, otype U) { |
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126 | void combine(T&, U); |
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127 | } |
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128 | |
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129 | This one is so strange I don't have proper syntax for it but let us say that |
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130 | the concrete dispatcher would be typed as |
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131 | `void combine(combiner(T) &, combiner(U));`. Does the function that combine |
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132 | the two underlying types exist to dispatch too? |
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133 | |
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134 | Maybe not. If `combiner(T)` works with ints and `combiner(U)` is a char then |
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135 | they could not be. It would have to enforce that all pairs of any types |
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136 | that are wrapped in this way. Which would pretty much destroy any chance of |
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137 | separate compilation. |
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138 | |
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139 | Even then it would be more expensive as the wrappers would have to carry ids |
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140 | that you use to look up on an <number of types>+1 dimensional table. |
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141 | |
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142 | The second restriction has a similar issue but makes a bit more sense to |
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143 | write out. |
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144 | |
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145 | trait Series(otype T) { |
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146 | ... size, iterators, getters ... |
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147 | T join(T const &, T const &); |
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148 | } |
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149 | |
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150 | With the dispatcher typed as: |
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151 | |
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152 | Series join(Series const &, Series const &); |
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153 | |
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154 | Because these instances are generic and hide the underlying implementation we |
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155 | do not know what that implementation is. Unfortunately this also means the |
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156 | implementation for the two parameters might not be the same. Once we have |
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157 | two different types involved this devolves into the first case. |
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158 | |
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159 | We could check at run-time that the have the same underlying type, but this |
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160 | would likely time and space overhead and there is no clear recovery path. |
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161 | |
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162 | #### Sample Implementation |
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163 | A simple way to implement trait objects is by a pair of pointers. One to the |
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164 | underlying object and one to the vtable. |
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165 | |
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166 | struct vtable_drawable { |
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167 | void (*draw)(Surface &, void *); |
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168 | Rect(int) (*drawArea)(void *); |
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169 | }; |
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170 | |
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171 | struct drawable { |
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172 | void * object; |
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173 | vtable_drawable * vtable; |
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174 | }; |
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175 | |
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176 | The functions that run on the trait object would generally be generated using |
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177 | the following pattern: |
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178 | |
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179 | void draw(Surface & surface, drawable & traitObj) { |
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180 | return traitObj.vtable->draw(surface, traitObj.object); |
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181 | } |
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182 | |
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183 | There may have to be special cases for things like copy construction, that |
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184 | might require a more significant wrapper. On the other hand moving could be |
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185 | implemented by moving the pointers without any need to refer to the base |
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186 | object. |
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187 | |
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188 | ### Extension: Multiple Trait Parameters |
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189 | The base proposal in effect creates another use for the trait syntax that is |
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190 | related to the ones currently in the language but is also separate from them. |
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191 | The current uses generic functions and generic types, this new use could be |
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192 | described as generic objects. |
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193 | |
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194 | A generic object is of a concrete type and has concrete functions that work on |
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195 | it. It is generic in that it is a wrapper for an unknown type. Traits serve |
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196 | a similar role here as in generic functions as they limit what the function |
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197 | can be generic over. |
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198 | |
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199 | This combines the use allowing to have a generic type that is a generic |
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200 | object. All but one of the trait's parameters is given a concrete type, |
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201 | conceptually currying the trait to create a trait with on generic parameter |
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202 | that fits the original restrictions. The resulting concrete generic object |
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203 | type is different with each set of provided parameters and their values. |
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204 | |
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205 | Then it just becomes a question of where this is done. Again both examples use |
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206 | a basic syntax to show the idea. |
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207 | |
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208 | trait iterator(virtual otype T, otype Item) { |
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209 | bool has_next(T const &); |
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210 | Item get_next(T const *); |
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211 | } |
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212 | |
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213 | iterator(int) int_it = begin(container_of_ints); |
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214 | |
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215 | The first option is to do it at the definition of the trait. One parameter |
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216 | is selected (here with the `virtual` keyword, but other rules like "the first" |
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217 | could also be used) and when an instance of the trait is created all the |
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218 | other parameters must be provided. |
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219 | |
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220 | trait iterator(otype T, otype Item) { |
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221 | bool has_next(T const &); |
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222 | Item get_next(T const *); |
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223 | } |
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224 | |
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225 | iterator(virtual, int) int_it = begin(container_of_ints); |
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226 | |
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227 | The second option is to skip a parameter as part of the type instance |
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228 | definition. One parameter is explicitly skipped (again with the `virtual` |
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229 | keyword) and the others have concrete types. The skipped one is the one we |
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230 | are generic on. |
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231 | |
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232 | Incidentally in both examples `container_of_ints` may itself be a generic |
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233 | object and `begin` returns a generic iterator with unknown implementation. |
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234 | |
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235 | These options are not exclusive. Defining a default on the trait allows for |
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236 | an object to be created as in the first example. However, whether the |
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237 | default is provided or not, the second syntax can be used to pick a |
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238 | parameter on instantiation. |
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239 | |
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240 | Hierarchy |
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241 | --------- |
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242 | |
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243 | We would also like to implement hierarchical relations between types. |
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244 | |
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245 | ast_node |
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246 | |-expression_node |
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247 | | |-operator_expression |
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248 | | |
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249 | |-statement_node |
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250 | | |-goto_statement |
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251 | | |
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252 | |-declaration_node |
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253 | |-using_declaration |
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254 | |-variable_declaration |
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255 | |
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256 | Virtual tables by themselves are not quite enough to implement this system. |
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257 | A vtable is just a list of functions and there is no way to check at run-time |
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258 | what these functions, we carry that knowledge with the table. |
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259 | |
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260 | This proposal adds type ids to check for position in the hierarchy and an |
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261 | explicate syntax for establishing a hierarchical relation between traits and |
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262 | their implementing types. The ids should uniquely identify each type and |
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263 | allow retrieval of the type's parent if one exists. By recursion this allows |
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264 | the ancestor relation between any two hierarchical types can be checked. |
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265 | |
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266 | The hierarchy is created with traits as the internal nodes and structures |
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267 | as the leaf nodes. The structures may be used normally and the traits can |
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268 | be used to create generic objects as in the first section (the same |
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269 | restrictions apply). However these type objects store their type id which can |
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270 | be recovered to figure out which type they are or at least check to see if |
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271 | they fall into a given sub-tree at run-time. |
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272 | |
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273 | Here is an example of part of a hierarchy. The `virtual(PARENT)` syntax is |
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274 | just an example. But when used it give the name of the parent type or if |
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275 | empty it shows that this type is the root of its hierarchy. |
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276 | (Also I'm not sure where I got these casing rules.) |
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277 | |
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278 | trait ast_node(otype T) virtual() { |
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279 | void print(T & this, ostream & out); |
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280 | void visit(T & this, Visitor & visitor); |
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281 | CodeLocation const & get_code_location(T & this); |
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282 | } |
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283 | |
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284 | trait expression_node(otype T) virtual(ast_node) { |
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285 | Type eval_type(T const & this); |
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286 | } |
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287 | |
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288 | struct operator_expression virtual(expression_node) { |
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289 | enum operator_kind kind; |
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290 | trait expression_node rands[2]; |
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291 | } |
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292 | |
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293 | trait statement_node(otype T) virtual(ast_node) { |
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294 | vector(Label) & get_labels(T & this); |
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295 | } |
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296 | |
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297 | struct goto_statement virtual(statement_node) { |
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298 | vector(Label) labels; |
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299 | Label target; |
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300 | } |
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301 | |
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302 | trait declaration_node(otype T) virtual(ast_node) { |
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303 | string name_of(T const & this); |
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304 | Type type_of(T const & this); |
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305 | } |
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306 | |
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307 | struct using_declaration virtual(declaration_node) { |
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308 | string new_type; |
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309 | Type old_type; |
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310 | } |
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311 | |
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312 | struct variable_declaration virtual(declaration_node) { |
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313 | string name; |
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314 | Type type; |
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315 | } |
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316 | |
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317 | This system does not support multiple inheritance. The system could be |
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318 | extended to support it or a limited form (ex. you may have multiple parents |
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319 | but they may not have a common ancestor). However this proposal focuses just |
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320 | on using hierachy as organization. Other uses for reusable/genaric code or |
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321 | shared interfaces is left for other features of the language. |
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322 | |
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323 | ### Extension: Structural Inheritance |
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324 | An extension would be allow structures to be used as internal nodes on the |
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325 | inheritance tree. Its child types would have to implement the same fields. |
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326 | |
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327 | The weaker restriction would be to convert the fields into field assertions |
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328 | (Not implemented yet: `U T.x` means there is a field of type you on the type |
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329 | T. Offset unknown and passed in/stored with function pointers.) |
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330 | A concrete child would have to declare the same set of fields with the same |
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331 | types. This is of a more functional style. |
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332 | |
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333 | The stronger restriction is that the fields of the parent are a prefix of the |
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334 | child's fields. Possibly automatically inserted. This the imperative view and |
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335 | may also have less overhead. |
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336 | |
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337 | ### Extension: Unions and Enumerations |
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338 | Currently there is no reason unions and enumerations, in the cases they |
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339 | do implement the trait, could not be in the hierarchy as leaf nodes. |
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340 | |
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341 | It does not work with structural induction, but that could just be a compile |
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342 | time check that all ancestors are traits or do not add field assertions. |
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343 | |
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344 | #### Sample Implementation |
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345 | The type id may be as little as: |
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346 | |
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347 | struct typeid { |
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348 | struct typeid const * const parent; |
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349 | }; |
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350 | |
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351 | Some linker magic would have to be used to ensure exactly one copy of each |
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352 | structure for each type exists in memory. There seem to be special once |
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353 | sections that support this and it should be easier than generating unique |
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354 | ids across compilation units. |
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355 | |
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356 | The structure could be extended to contain any additional type information. |
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357 | |
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358 | There are two general designs for vtables with type ids. The first is to put |
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359 | the type id at the top of the vtable, this is the most compact and efficient |
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360 | solution but only works if we have exactly 1 vtable for each type. The second |
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361 | is to put a pointer to the type id in each vtable. This has more overhead but |
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362 | allows multiple vtables per type. |
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363 | |
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364 | struct <trait>_vtable { |
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365 | struct typeid const id; |
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366 | |
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367 | // Trait dependent list of vtable members. |
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368 | }; |
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369 | |
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370 | struct <trait>_vtable { |
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371 | struct typeid const * const id; |
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372 | |
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373 | // Trait dependent list of vtable members. |
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374 | }; |
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375 | |
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376 | One important restriction is that only one instance of each typeid in memory. |
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377 | There is a ".gnu.linkonce" feature in the linker that might solve the issue. |
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378 | |
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379 | ### Virtual Casts |
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380 | The generic objects may be cast up and down the hierarchy. |
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381 | |
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382 | Casting to an ancestor type always succeeds. From one generic type to another |
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383 | is just a reinterpretation and could be implicate. Wrapping and unwrapping |
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384 | a concrete type will probably use the same syntax as in the first section. |
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385 | |
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386 | Casting from an ancestor to a descendent requires a check. The underlying |
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387 | type may or may not belong to the sub-tree headed by that descendent. For this |
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388 | we introduce a new cast operator, which returns the pointer unchanged if the |
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389 | check succeeds and null otherwise. |
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390 | |
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391 | trait SubType * new_value = (virtual trait SubType *)super_type; |
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392 | |
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393 | For the following example I am using the as of yet finished exception system. |
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394 | |
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395 | trait exception(otype T) virtual() { |
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396 | char const * what(T & this); |
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397 | } |
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398 | |
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399 | trait io_error(otype T) virtual(exception) { |
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400 | FILE * which_file(T & this); |
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401 | } |
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402 | |
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403 | struct eof_error(otype T) virtual(io_error) { |
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404 | FILE * file; |
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405 | } |
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406 | |
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407 | char const * what(eof_error &) { |
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408 | return "Tried to read from an empty file."; |
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409 | } |
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410 | |
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411 | FILE * which_file(eof_error & this) { |
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412 | return eof_error.file; |
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413 | } |
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414 | |
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415 | bool handleIoError(exception * exc) { |
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416 | io_error * error = (virtual io_error *)exc; |
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417 | if (NULL == error) { |
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418 | return false; |
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419 | } |
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420 | ... |
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421 | return true; |
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422 | } |
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423 | |
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424 | ### Extension: Implicate Virtual Cast Target |
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425 | This is a small extension, even in the example above `io_error *` is repeated |
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426 | in the cast and the variable being assigned to. Using return type inference |
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427 | would allow the second type to be skipped in cases it is clear what type is |
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428 | being checked against. |
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429 | |
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430 | The line then becomes: |
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431 | |
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432 | io_error * error = (virtual)exc; |
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433 | |
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434 | #### Sample Implementation |
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435 | This cast implementation assumes a type id layout similar to the one given |
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436 | above. Also this code is definitely in the underlying C. Functions that give |
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437 | this functionality could exist in the standard library but these are meant to |
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438 | be produced by code translation of the virtual cast. |
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439 | |
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440 | bool is_in_subtree(typeid const * root, typeid const * id) { |
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441 | if (root == id) { |
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442 | return true |
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443 | } else if (NULL == id->parent) { |
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444 | return false; |
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445 | } else { |
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446 | return is_in_subtree(root, id->parent); |
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447 | } |
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448 | } |
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449 | |
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450 | void * virtual_cast(typeid const * target, void * value) { |
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451 | return is_in_subtree(target, *(typeid const **)value) ? value : NULL; |
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452 | } |
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453 | |
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454 | The virtual cast function might have to be wrapped with some casts to make it |
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455 | compile without warning. |
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456 | |
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457 | For the implicate target type we may be able to lean on the type resolution |
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458 | system that already exists. If the casting to ancestor type is built into |
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459 | the resolution then the impicate target could be decided by picking an |
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460 | overload, generated for each hierarchial type (here io_error and its root |
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461 | type exception). |
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462 | |
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463 | io_error * virtual_cast(exception * value) { |
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464 | return virtual_cast(io_error_typeid, value); |
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465 | } |
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466 | |
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467 | ### Extension: Inline vtables |
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468 | Since the structures here are usually made to be turned into trait objects |
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469 | it might be worth it to have fields in them to store the virtual table |
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470 | pointer. This would have to be declared on the trait as an assertion (example: |
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471 | `vtable;` or `T.vtable;`), but if it is the trait object could be a single |
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472 | pointer. |
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473 | |
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474 | There are also three options for where the pointer to the vtable. It could be |
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475 | anywhere, a fixed location for each trait or always at the front. For the per- |
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476 | trait solution an extension to specify what it is (example `vtable[0];`) which |
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477 | could also be used to combine it with others. So these options can be combined |
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478 | to allow access to all three options. |
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479 | |
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480 | The pointer to virtual table field on structures might implicately added (the |
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481 | types have to declare they are a child here) or created with a declaration, |
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482 | possibly like the one used to create the assertion. |
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483 | |
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484 | ### Virtual Tables as Types |
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485 | Here we consider encoding plus the implementation of functions on it to be a |
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486 | type. Which is to say in the type hierarchy structures aren't concrete types |
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487 | anymore, instead they are parent types to vtables, which combine the encoding |
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488 | and implementation. |
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489 | |
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490 | ### Question: Wrapping Structures |
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491 | One issue is what to do with concrete types at the base of the type tree. |
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492 | When we are working with the concrete type generally it would like them to be |
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493 | regular structures with direct calls. On the other hand for interactions with |
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494 | other types in the hierarchy it is more convenent for the type already to be |
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495 | cast. |
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496 | |
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497 | Which of these two should we use? Should we support both and if so how do we |
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498 | choose which one is being used at any given time. |
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499 | |
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500 | On a related note I have been using pointers two trait types here, as that |
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501 | is how many existing languages handle it. However the generic objects might |
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502 | be only one or two pointers wide passing the objects as a whole would not |
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503 | be very expensive and all operations on the generic objects probably have |
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504 | to be defined anyways. |
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505 | |
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506 | Resolution Scope |
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507 | ---------------- |
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508 | |
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509 | What is the scope of a resolution? When are the functions in a vtable decided |
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510 | and how broadly is this applied? |
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511 | |
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512 | ### Type Level: |
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513 | Each structure has a single resolution for all of the functions in the |
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514 | virtual trait. This is how many languages that implement this or similar |
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515 | features do it. |
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516 | |
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517 | The main thing CFA would need to do it this way is some single point where |
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518 | the type declaration, including the functions that satisfy the trait, are |
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519 | all defined. Currently there are many points where this can happen, not all |
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520 | of them have the same definitions and no way to select one over the other. |
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521 | |
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522 | Some syntax would have to be added to specify the resolution point. To ensure |
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523 | a single instance there may have to be two variants, one forward declaration |
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524 | and one to create the instance. With some compiler magic the forward |
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525 | declaration maybe enough. |
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526 | |
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527 | extern trait combiner(struct summation) vtable; |
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528 | trait combiner(struct summation) vtable; |
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529 | |
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530 | Or (with the same variants): |
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531 | |
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532 | vtable combiner(struct summation); |
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533 | |
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534 | The extern variant promises that the vtable will exist while the normal one |
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535 | is where the resolution actually happens. |
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536 | |
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537 | ### Explicit Resolution Points: |
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538 | Slightly looser than the above, there are explicit points where the vtables |
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539 | are resolved, but there is no limit on the number of resolution points that |
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540 | might be provided. Each time a object is bound to a trait, one of the |
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541 | resolutions is selected. This might be the most flexible option. |
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542 | |
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543 | An syntax would have to be provided as above. There may also be the option |
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544 | to name resolution points so that you can choose between them. This also |
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545 | could come with the ability to forward declare them. |
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546 | |
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547 | Especially if they are not named, these resolution points should be able to |
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548 | appear in functions, where the scoping rules can be used to select one. |
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549 | However this also means that stack-allocated functions can end up in the |
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550 | vtable. |
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551 | |
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552 | extern trait combiner(struct summation) vtable sum; |
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553 | trait combiner(struct summation) vtable sum; |
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554 | |
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555 | extern trait combiner(struct summation) vtable sum default; |
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556 | trait combiner(struct summation) vtable sum default; |
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557 | |
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558 | The extern difference is the same before. The name (sum in the samples) is |
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559 | used at the binding site to say which one is picked. The default keyword can |
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560 | be used in only some of the declarations. |
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561 | |
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562 | trait combiner fee = (summation_instance, sum); |
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563 | trait combiner foe = summation_instance; |
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564 | |
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565 | (I am not really happy about this syntax, but it kind of works.) |
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566 | The object being bound is required. The name of the vtable is optional if |
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567 | there is exactly one vtable name marked with default. |
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568 | |
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569 | These could also be placed inside functions. In which case both the name and |
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570 | the default keyword might be optional. If the name is omitted in an assignment |
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571 | the closest vtable is chosen (returning to the global default rule if no |
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572 | appropriate local vtable is in scope). |
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573 | |
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574 | ### Site Based Resolution: |
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575 | Every place in code where the binding of a vtable to an object occurs has |
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576 | its own resolution. Syntax-wise this is the simplest as it should be able |
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577 | to use just the existing declarations and the conversion to trait object. |
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578 | It also is very close to the current polymorphic resolution rules. |
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579 | |
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580 | This works as the explicit resolution points except the resolution points |
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581 | are implicit and their would be no selection of which resolution to use. The |
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582 | closest (current) resolution is always selected. |
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583 | |
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584 | This could easily lead to an explosion of vtables as it has the most fine |
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585 | grained resolution the number of bindings in a single scope (that produces |
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586 | the same binding) could be quite high. Merging identical vtables might help |
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587 | reduce that. |
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588 | |
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589 | Vtable Lifetime Issues |
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590 | ---------------------- |
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591 | |
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592 | Vtables interact badly with the thunk issue. Conceptually vtables are static |
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593 | like type/function data they carry, as those decisions are made by the |
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594 | resolver at compile time. |
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595 | |
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596 | Stack allocated functions interact badly with this because they are not |
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597 | static. There are several ways to try to resolve this, however without a |
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598 | general solution most can keep vtables from making the existing thunk problem |
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599 | worse, they don't do anything to solve it. |
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600 | |
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601 | Filling in some fields of a static vtable could cause issues on a recursive |
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602 | call. And then we are still limited by the lifetime of the stack functions, as |
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603 | the vtable with stale pointers is still a problem. |
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604 | |
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605 | Dynamically allocated vtables introduces memory management overhead and |
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606 | requires some way to differentiate between dynamic and statically allocated |
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607 | tables. The stale function pointer problem continues unless those becomes |
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608 | dynamically allocated as well which gives us the same costs again. |
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609 | |
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610 | Stack allocating the vtable seems like the best issue. The vtable's lifetime |
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611 | is now the limiting factor but it should be effectively the same as the |
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612 | shortest lifetime of a function assigned to it. However this still limits the |
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613 | lifetime "implicitly" and returns to the original problem with thunks. |
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614 | |
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615 | Odds And Ends |
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616 | ------------- |
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617 | |
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618 | In addition to the main design there are a few extras that should be |
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619 | considered. They are not part of the core design but make the new uses fully |
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620 | featured. |
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621 | |
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622 | ### Extension: Parent-Child Assertion |
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623 | For hierarchy types in regular traits, generic functions or generic structures |
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624 | we may want to be able to check parent-child relationships between two types |
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625 | given. For this we might have to add another primitive assertion. It would |
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626 | have the following form if declared in code: |
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627 | |
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628 | trait is_parent_child(dtype Parent, dtype Child) { <built-in magic> } |
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629 | |
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630 | This assertion is satified if Parent is an ancestor of Child in a hierarchy. |
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631 | In other words Child can be statically cast to Parent. The cast from Parent |
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632 | to child would be dynamically checked as usual. |
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633 | |
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634 | However in this form there are two concerns. The first that Parent will |
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635 | usually be consistent for a given use, it will not be a variable. Second is |
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636 | that we may also need the assertion functions. To do any casting/conversions |
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637 | anyways. |
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638 | TODO: Talk about when we wrap a concrete type and how that leads to "may". |
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639 | |
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640 | To this end it may be better that the parent trait combines the usual |
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641 | assertions plus this new primitive assertion. There may or may not be use |
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642 | cases for accessing just one half and providing easy access to them may be |
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643 | required depending on how that turns out. |
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644 | |
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645 | trait Parent(dtype T | interface(T)) virtual(<grand-parent?>) { } |
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646 | |
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647 | ### Extension: sizeof Compatablity |
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648 | Trait types are always sized, it may even be a fixed size like how pointers |
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649 | have the same size regardless of what they point at. However their contents |
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650 | may or may not be of a known size (if the `sized(...)` assertion is used). |
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651 | |
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652 | Currently there is no way to access this information. If it is needed a |
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653 | special syntax would have to be added. Here a special case of `sizeof` is |
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654 | used. |
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655 | |
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656 | struct line aLine; |
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657 | trait drawable widget = aLine; |
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658 | |
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659 | size_t x = sizeof(widget); |
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660 | size_t y = sizeof(trait drawable); |
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661 | |
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662 | As usual `y`, size of the type, is the size of the local storage used to put |
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663 | the value into. The other case `x` checks the saved stored value in the |
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664 | virtual table and returns that. |
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