1 | |
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2 | include "Cminor/Cminor_abstract.ma". |
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3 | include "RTLabs/RTLabs_abstract.ma". |
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4 | include "Cminor/toRTLabs.ma". |
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5 | |
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6 | record cminor_rtlabs_inv (ge_cm:cm_genv) (ge_ra:RTLabs_genv) : Type[0] ≝ { |
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7 | }. |
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8 | axiom cminor_rtlabs_rel : ∀gc,gr. cminor_rtlabs_inv gc gr → Cminor_state → RTLabs_state → Prop. |
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9 | |
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10 | axiom cminor_rtlabs_rel_labelled : ∀gc,gr,INV,s,s'. |
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11 | cminor_rtlabs_rel gc gr INV s s' → |
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12 | Cminor_labelled s = RTLabs_cost s'. |
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13 | |
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14 | (* Conjectured simulation results |
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15 | |
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16 | We split these based on the start state: |
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17 | |
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18 | 1. from a ‘normal’ state we simulate a step by [n] normal steps in RTLabs |
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19 | ([n] can be zero if the Cminor program executed an St_skip); |
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20 | 2. call and return state steps are simulated by a call/return state step (we |
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21 | don't add anything extra in this stage, it happens in Clight to Cminor); |
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22 | and |
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23 | 3. lone cost label steps are simulates by a lone cost label step |
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24 | |
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25 | Most of the work in this stage is splitting the execution of complex Cminor |
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26 | statements into individual RTLabs steps. This doesn't contradict 2 above - |
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27 | the expansion of function parameters, return expressions, etc is done for |
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28 | the function call / return *statement*, whereas the call / return *state* is |
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29 | a Callstate / Returnstate that is the second half of the operation. |
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30 | |
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31 | Note that we'll need something more to show that non-termination is |
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32 | preserved (because it isn't obvious that we don't squash a loop to zero |
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33 | instructions). Options are a traditional measure, or using the soundness of |
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34 | the cost labelling. |
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35 | |
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36 | These should allow us to maintain enough structure to identify the RTLabs |
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37 | subtrace corresponding to a measurable Clight/Cminor subtrace. |
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38 | *) |
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39 | |
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40 | definition cminor_normal : Cminor_state → bool ≝ |
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41 | λs. match Cminor_classify s with [ cl_other ⇒ true | cl_jump ⇒ true | _ ⇒ false ]. |
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42 | |
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43 | definition rtlabs_normal : RTLabs_state → bool ≝ |
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44 | λs. match RTLabs_classify s with [ cl_other ⇒ true | cl_jump ⇒ true | _ ⇒ false ]. |
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45 | |
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46 | axiom cminor_measure : Cminor_state → nat. |
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47 | |
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48 | axiom cminor_rtlabs_normal : |
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49 | ∀ge_cm,ge_ra. |
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50 | ∀INV:cminor_rtlabs_inv ge_cm ge_ra. |
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51 | ∀s1,s1',s2,tr. |
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52 | cminor_rtlabs_rel … INV s1 s1' → |
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53 | cminor_normal s1 → |
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54 | ¬ Cminor_labelled s1 → |
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55 | step ?? Cminor_exec ge_cm s1 = Value … 〈tr,s2〉 → |
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56 | ∃n. after_n_steps n … RTLabs_exec ge_ra s1' (λs.rtlabs_normal s) (λtr',s2'. |
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57 | tr = tr' ∧ |
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58 | (n = 0 → lt (cminor_measure s2) (cminor_measure s1)) ∧ |
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59 | cminor_rtlabs_rel … INV s2 s2' |
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60 | ). |
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61 | |
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62 | axiom cminor_rtlabs_call_return : |
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63 | ∀ge_cm,ge_ra. |
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64 | ∀INV:cminor_rtlabs_inv ge_cm ge_ra. |
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65 | ∀s1,s1',s2,tr. |
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66 | cminor_rtlabs_rel … INV s1 s1' → |
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67 | match Cminor_classify s1 with [ cl_call ⇒ true | cl_return ⇒ true | _ ⇒ false ] → |
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68 | step … Cminor_exec ge_cm s1 = Value … 〈tr,s2〉 → |
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69 | after_n_steps 1 … RTLabs_exec ge_ra s1' (λs.rtlabs_normal s) (λtr',s2'. |
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70 | tr = tr' ∧ |
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71 | cminor_rtlabs_rel … INV s2 s2' |
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72 | ). |
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73 | |
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74 | axiom cminor_rtlabs_cost : |
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75 | ∀ge_cm,ge_ra. |
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76 | ∀INV:cminor_rtlabs_inv ge_cm ge_ra. |
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77 | ∀s1,s1',s2,tr. |
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78 | cminor_rtlabs_rel … INV s1 s1' → |
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79 | Cminor_labelled s1 → |
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80 | step … Cminor_exec ge_cm s1 = Value … 〈tr,s2〉 → |
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81 | after_n_steps 1 … RTLabs_exec ge_ra s1' (λs.true) (λtr',s2'. |
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82 | tr = tr' ∧ |
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83 | cminor_rtlabs_rel … INV s2 s2' |
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84 | ). |
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85 | |
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86 | axiom cminor_rtlabs_init : |
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87 | ∀p,s. |
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88 | make_initial_state … Cminor_fullexec p = OK … s → |
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89 | let p' ≝ cminor_to_rtlabs p in |
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90 | ∃INV:cminor_rtlabs_inv (make_global … Cminor_fullexec p) (make_global … RTLabs_fullexec p'). |
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91 | ∃s'. make_initial_state … RTLabs_fullexec p' = OK … s' ∧ |
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92 | cminor_rtlabs_rel … INV s s'. |
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93 | |
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94 | include "common/FEMeasurable.ma". |
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95 | include "Cminor/Cminor_classified_system.ma". |
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96 | include "RTLabs/RTLabs_classified_system.ma". |
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97 | |
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98 | include "common/ExtraMonads.ma". |
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99 | |
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100 | lemma Cminor_return_E0 : ∀ge,s,tr,s'. |
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101 | step … Cminor_exec ge s = Value … 〈tr,s'〉 → |
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102 | Cminor_classify s = cl_return → |
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103 | tr = E0. |
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104 | #ge * |
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105 | [ #f #s #en #H1 #H2 #m #b #k #K #st #tr #s' #STEP #CL whd in CL:(??%?); destruct |
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106 | | #id #fd #args #m #st #tr #s' #STEP #CL whd in CL:(??%?); destruct |
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107 | | #v #m * |
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108 | [ #tr #s' #STEP #_ |
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109 | cases v in STEP; [ #E whd in E:(??%?); destruct ] |
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110 | * [1,3,4: normalize #A try #B destruct ] |
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111 | * #v #STEP whd in STEP:(??%?); destruct % |
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112 | | cases v |
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113 | [ * [ normalize #A #B #C #D #E #F #G #H #I #J #K destruct // |
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114 | | normalize #A #B #C #D #E #F #G #H #I #J #K #L destruct |
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115 | ] |
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116 | | #v' * |
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117 | [ normalize #A #B #C #D #E #F #G #H #I #J #K destruct |
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118 | | #A #B #C #D #E #F #G #H #I #J #K #L whd in L:(??%?); destruct // |
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119 | ] |
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120 | ] |
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121 | ] |
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122 | | #r #tr #s' #ST #CL normalize in CL; destruct |
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123 | ] qed. |
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124 | |
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125 | definition cminor_rtlabs_meas_sim : meas_sim ≝ |
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126 | mk_meas_sim |
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127 | Cminor_pcs |
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128 | RTLabs_pcs |
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129 | (λcmp,rap. cminor_to_rtlabs cmp = rap) |
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130 | cminor_rtlabs_inv |
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131 | cminor_rtlabs_rel |
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132 | ? (* rel_normal *) |
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133 | ? (* rel_labelled *) |
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134 | ? (* rel_classify_call *) |
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135 | ? (* rel_classify_return *) |
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136 | ? (* rel_callee *) |
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137 | ? (* labelled_normal_1 *) |
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138 | ? (* labelled_normal_2 *) |
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139 | ? (* notailcalls *) |
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140 | ? (* sim_normal *) |
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141 | ? (* sim_call_nolabel *) |
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142 | ? (* sim_call_label *) |
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143 | ? (* sim_return *) |
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144 | ? (* sim_cost *) |
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145 | ? (* sim_init *) |
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146 | . |
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147 | [ (* rel_normal *) |
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148 | | (* rel_labelled *) |
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149 | @cminor_rtlabs_rel_labelled |
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150 | | (* rel_classify_call *) |
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151 | | (* rel_classify_return *) |
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152 | | (* rel_callee *) |
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153 | | (* labelled_normal_1 *) |
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154 | #g * // |
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155 | | (* labelled_normal_2 *) |
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156 | #g * // #f #fs #m whd in ⊢ (?% → ?%); whd in match (pcs_classify ???); |
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157 | cases (next_instruction f) // |
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158 | | (* notailcalls *) |
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159 | #g @Cminor_notailcalls |
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160 | | (* sim_normal *) |
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161 | #g1 #g2 #INV #s1 #s1' #R1 #N1 #NCS1 #s2 #tr #STEP |
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162 | cases (cminor_rtlabs_normal … R1 N1 NCS1 STEP) |
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163 | #m #AFTER %{m} @(after_n_covariant … AFTER) |
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164 | #tr' #s * * #H1 #H2 #H3 /3/ |
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165 | | (* sim_call_nolabel *) |
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166 | #g1 #g2 #INV #s1 #s1' #R1 #CL1 #NCS1 #s2 #tr #STEP #NCS2 %{0} |
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167 | @(cminor_rtlabs_call_return … R1 … STEP) |
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168 | change with (Cminor_classify ?) in CL1:(??%?); >CL1 % |
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169 | | (* sim_call_label *) |
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170 | #g1 #g2 #INV #s1 #s1' #R1 #CL1 #NCS1 #s2 #tr2 #s3 #tr3 #STEP1 #CS2 #STEP2 %{1} |
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171 | lapply (cminor_rtlabs_call_return … R1 … STEP1) |
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172 | [ change with (Cminor_classify ?) in CL1:(??%?); >CL1 % ] |
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173 | #AFTER1 @(after_n_covariant … AFTER1) #tr' #s' * #E #R' destruct |
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174 | % [ % |
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175 | [ % |
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176 | | change with (RTLabs_cost s') in ⊢ (?%); <(cminor_rtlabs_rel_labelled … R') @CS2 |
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177 | ]| lapply (cminor_rtlabs_cost … R' … CS2 STEP2) |
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178 | #AFTER2 cases (after_1_step … AFTER2) |
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179 | #trx * #sx * * #NFx #STEPx * #E #Rx destruct |
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180 | whd >NFx whd >STEPx whd /3/ |
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181 | ] |
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182 | | (* sim_return *) |
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183 | #g1 #g2 #INV #s1 #s1' #R1 #CL1 #NCS1 #s2 #tr #STEP %{0} |
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184 | lapply (cminor_rtlabs_call_return … R1 … STEP) |
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185 | [ change with (Cminor_classify ?) in CL1:(??%?); >CL1 % ] |
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186 | >(Cminor_return_E0 … STEP CL1) |
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187 | #AFTER %{(refl ??)} @AFTER |
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188 | | (* sim_cost *) |
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189 | #g1 #g2 #INV #s1 #s1' #s2 #tr #R1 #CS1 #STEP |
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190 | @(cminor_rtlabs_cost … R1 … STEP) |
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191 | @CS1 |
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192 | | (* sim_init *) |
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193 | #p #p' #s #COMPILE destruct #INIT |
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194 | cases (cminor_rtlabs_init … INIT) #INV * #s' * #INIT' #R |
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195 | %{s'} % [ @INIT' | %{INV} @R ] |
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196 | ] cases daemon qed. |
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