1 | include "ASM/ASMCosts.ma". |
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2 | include "ASM/UtilBranch.ma". |
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3 | include alias "arithmetics/nat.ma". |
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4 | include alias "basics/logic.ma". |
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5 | |
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6 | let rec traverse_code_internal |
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7 | (code_memory: BitVectorTrie Byte 16) (cost_labels: BitVectorTrie costlabel 16) |
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8 | (program_counter: Word) (program_size: nat) |
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9 | (program_size_invariant: program_size = 0 ∨ nat_of_bitvector … program_counter + program_size = 2^16) |
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10 | on program_size: |
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11 | Σcost_map: identifier_map CostTag nat. |
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12 | (∀pc,k. nat_of_bitvector … program_counter ≤ nat_of_bitvector 16 pc → nat_of_bitvector … pc < program_size + nat_of_bitvector … program_counter → lookup_opt … pc cost_labels = Some … k → present … cost_map k) ∧ |
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13 | (∀k. ∀k_pres:present … cost_map k. ∃pc. lookup_opt … pc cost_labels = Some … k ∧ |
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14 | pi1 … (block_cost code_memory pc cost_labels) = lookup_present … k_pres) ≝ |
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15 | match program_size return λx. x = program_size → Σcost_map: ?. ? with |
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16 | [ O ⇒ λprogram_size_refl. empty_map CostTag nat |
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17 | | S program_size' ⇒ λprogram_size_refl. |
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18 | let new_program_counter' ≝ add 16 (bitvector_of_nat 16 1) program_counter in |
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19 | let cost_mapping ≝ traverse_code_internal code_memory cost_labels new_program_counter' program_size' ? in |
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20 | match lookup_opt … program_counter cost_labels return λx. x = lookup_opt … program_counter cost_labels → Σcost_map: ?. ? with |
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21 | [ None ⇒ λlookup_refl. pi1 … cost_mapping |
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22 | | Some lbl ⇒ λlookup_refl. |
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23 | let cost ≝ block_cost code_memory program_counter cost_labels in |
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24 | cic:/matita/cerco/common/Identifiers/add.fix(0,2,2) ?? cost_mapping lbl cost |
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25 | ] (refl … (lookup_opt … program_counter cost_labels)) |
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26 | ] (refl … program_size). |
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27 | [3: |
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28 | cases program_size_invariant |
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29 | [1: |
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30 | #destruct_assm @⊥ -traverse_code_internal destruct |
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31 | |2: |
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32 | #program_size_invariant' |
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33 | % |
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34 | [1: |
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35 | #pc #k #H1 #H2 #lookup_opt_assm @(eq_identifier_elim … k lbl) |
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36 | [1: |
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37 | #eq_assm >eq_assm |
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38 | cases cost_mapping #cost_mapping' * #ind_hyp #_ |
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39 | @present_add_hit |
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40 | |2: |
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41 | #neq_assm @present_add_miss try assumption |
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42 | cases cost_mapping #cost_mapping' * #ind_hyp #_ |
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43 | inversion program_size' |
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44 | [1: |
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45 | #program_size_refl_0 -traverse_code_internal destruct @⊥ cases neq_assm #assm @assm |
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46 | cut (Some … k = Some … lbl → k = lbl) (* XXX: lemma *) |
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47 | [1: |
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48 | #Some_assm destruct(Some_assm) % |
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49 | |2: |
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50 | #Some_assm @Some_assm <lookup_opt_assm >lookup_refl |
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51 | >(?:pc=program_counter) |
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52 | [1: |
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53 | % |
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54 | |2: |
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55 | @refl_nat_of_bitvector_to_refl |
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56 | @le_to_le_to_eq |
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57 | try assumption |
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58 | change with (? ≤ ?) in H2; |
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59 | @le_S_S_to_le |
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60 | assumption |
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61 | ] |
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62 | ] |
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63 | |2: |
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64 | #n' #_ #program_size_refl_Sn' -traverse_code_internal destruct |
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65 | cut((S (nat_of_bitvector 16 program_counter)) = nat_of_bitvector 16 (add 16 (bitvector_of_nat 16 1) program_counter)) |
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66 | [1: |
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67 | destruct |
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68 | @succ_nat_of_bitvector_half_add_1 |
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69 | @le_plus_to_minus_r |
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70 | change with (S ? ≤ ?) >plus_n_Sm |
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71 | <program_size_invariant' |
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72 | @monotonic_le_plus_r |
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73 | @le_S_S @le_S_S @le_O_n |
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74 | |2: |
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75 | #S_assm |
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76 | @(ind_hyp … lookup_opt_assm) |
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77 | [1: |
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78 | @(eqb_elim (nat_of_bitvector … program_counter) |
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79 | (nat_of_bitvector … pc)) |
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80 | [1: |
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81 | #eqb_refl_assm |
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82 | -ind_hyp -H1 -H2 |
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83 | lapply (refl_nat_of_bitvector_to_refl 16 program_counter pc eqb_refl_assm) |
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84 | #program_counter_refl_assm -eqb_refl_assm |
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85 | <program_counter_refl_assm in lookup_opt_assm; <lookup_refl |
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86 | #Some_assm destruct(Some_assm) |
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87 | cases neq_assm #absurd_assm |
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88 | cases (absurd_assm (refl … k)) |
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89 | |2: |
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90 | #eqb_ref_assm |
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91 | -ind_hyp |
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92 | <S_assm |
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93 | change with (? < ?) |
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94 | @le_neq_to_lt assumption |
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95 | ] |
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96 | |2: |
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97 | generalize in match H2; whd in ⊢ (??% → ?); |
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98 | >plus_n_Sm in ⊢ (% → ?); |
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99 | cut(new_program_counter' = add 16 (bitvector_of_nat 16 1) program_counter) |
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100 | [1: % |
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101 | |2: |
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102 | #new_program_counter_assm' >new_program_counter_assm' |
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103 | >S_assm #relevant assumption |
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104 | ] |
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105 | ] |
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106 | ] |
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107 | ] |
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108 | ] |
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109 | |2: |
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110 | #k #k_pres |
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111 | @(eq_identifier_elim … k lbl) |
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112 | [1: |
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113 | #eq_assm %{program_counter} % |
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114 | [1: |
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115 | >eq_assm >lookup_refl % |
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116 | |2: |
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117 | >eq_assm in k_pres ⊢ (???%); #k_pres >lookup_present_add_hit % |
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118 | ] |
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119 | |2: |
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120 | #neq_assm |
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121 | cases cost_mapping in k_pres; #cost_mapping' #ind_hyp #present_assm |
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122 | cases ind_hyp #_ #relevant cases (relevant k ?) |
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123 | [2: |
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124 | @(present_add_present … present_assm) assumption |
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125 | |1: |
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126 | #program_counter' #ind_hyp' %{program_counter'} % |
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127 | [1: |
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128 | cases ind_hyp' #assm #_ assumption |
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129 | |2: |
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130 | cases ind_hyp' #lookup_opt_assm #ind_hyp'' >ind_hyp'' |
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131 | @sym_eq @lookup_present_add_miss assumption |
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132 | ] |
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133 | ] |
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134 | ] |
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135 | ] |
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136 | ] |
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137 | |1: |
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138 | % |
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139 | [1: |
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140 | #pc #k #absurd1 #absurd2 |
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141 | @⊥ lapply(lt_to_not_le … absurd2) * |
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142 | #absurd @absurd assumption |
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143 | |2: |
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144 | #k #k_pres |
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145 | @⊥ normalize in k_pres; /2/ |
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146 | ] |
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147 | |2: |
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148 | cases cost_mapping |
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149 | -traverse_code_internal #cost_mapping * |
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150 | #inductive_hypothesis1 #inductive_hypothesis2 % |
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151 | [1: |
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152 | #pc #k #H1 #H2 |
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153 | cases program_size_invariant |
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154 | [1: |
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155 | #destruct_assm @⊥ destruct |
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156 | |2: |
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157 | -program_size_invariant #program_size_invariant |
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158 | inversion program_size' |
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159 | [1: |
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160 | #program_size_refl_0 destruct |
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161 | #lookup_opt_Some_assm |
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162 | >(?:pc = program_counter) in lookup_opt_Some_assm; |
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163 | [1: |
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164 | #absurd <lookup_refl in absurd; |
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165 | #absurd destruct |
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166 | |2: |
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167 | @refl_nat_of_bitvector_to_refl |
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168 | @le_to_le_to_eq |
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169 | try assumption |
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170 | change with (? ≤ ?) in H2; |
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171 | @le_S_S_to_le |
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172 | assumption |
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173 | ] |
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174 | |2: |
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175 | #n' #_ #program_size_Sn_refl #Some_lookup_opt_refl |
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176 | @(inductive_hypothesis1 … pc) try assumption |
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177 | [1: |
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178 | @(eqb_elim … (nat_of_bitvector … program_counter) |
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179 | (nat_of_bitvector … pc)); |
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180 | [1: |
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181 | #eq_assm |
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182 | lapply (refl_nat_of_bitvector_to_refl … eq_assm) #pc_refl |
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183 | <pc_refl in Some_lookup_opt_refl; <lookup_refl #absurd |
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184 | destruct |
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185 | |2: |
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186 | #neq_assm |
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187 | @(transitive_le ? (S (nat_of_bitvector … program_counter))) |
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188 | [1: |
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189 | cut((S (nat_of_bitvector 16 program_counter)) = nat_of_bitvector 16 (add 16 (bitvector_of_nat 16 1) program_counter)) |
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190 | [1: |
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191 | destruct |
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192 | @succ_nat_of_bitvector_half_add_1 |
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193 | @le_plus_to_minus_r |
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194 | change with (S ? ≤ ?) >plus_n_Sm |
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195 | <program_size_invariant |
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196 | @monotonic_le_plus_r |
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197 | @le_S_S @le_S_S @le_O_n |
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198 | |2: |
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199 | #Sn_refl_assm >Sn_refl_assm @le_n |
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200 | ] |
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201 | |2: |
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202 | change with (? < ?) |
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203 | @le_neq_to_lt |
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204 | assumption |
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205 | ] |
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206 | ] |
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207 | |2: |
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208 | destruct |
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209 | @(transitive_le … H2) |
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210 | cut((S (nat_of_bitvector 16 program_counter)) = nat_of_bitvector 16 (add 16 (bitvector_of_nat 16 1) program_counter)) |
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211 | [1: |
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212 | destruct |
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213 | @succ_nat_of_bitvector_half_add_1 |
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214 | @le_plus_to_minus_r |
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215 | change with (S ? ≤ ?) >plus_n_Sm |
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216 | <program_size_invariant |
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217 | @monotonic_le_plus_r |
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218 | @le_S_S @le_S_S @le_O_n |
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219 | |2: |
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220 | #S_assm |
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221 | change with (S (S n' + ?) ≤ ?) |
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222 | >plus_n_Sm @monotonic_le_plus_r >S_assm |
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223 | @le_n |
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224 | ] |
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225 | ] |
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226 | ] |
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227 | ] |
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228 | |2: |
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229 | assumption |
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230 | ] |
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231 | |4: |
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232 | inversion program_size' |
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233 | [1: |
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234 | #_ %1 % |
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235 | |2: |
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236 | #n' #_ #program_size_refl_Sn @or_intror |
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237 | cases program_size_invariant |
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238 | [1: |
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239 | #absurd destruct |
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240 | |2: |
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241 | #relevant <relevant <plus_n_Sm <program_size_refl <plus_n_Sm |
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242 | @eq_f >program_size_refl_Sn <plus_n_Sm |
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243 | change with (? = (S ?) + ?) @eq_f2 try % |
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244 | cut((S (nat_of_bitvector 16 program_counter)) = nat_of_bitvector 16 (add 16 (bitvector_of_nat 16 1) program_counter)) |
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245 | [1: |
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246 | destruct |
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247 | @succ_nat_of_bitvector_half_add_1 |
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248 | @le_plus_to_minus_r |
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249 | change with (S ? ≤ ?) >plus_n_Sm |
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250 | <relevant |
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251 | @monotonic_le_plus_r |
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252 | @le_S_S @le_S_S @le_O_n |
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253 | |2: |
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254 | #S_assm |
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255 | cut(new_program_counter' = add … (bitvector_of_nat … 1) program_counter) |
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256 | [1: % |
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257 | |2: |
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258 | #new_program_counter_assm' >new_program_counter_assm' |
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259 | cases program_size_invariant |
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260 | [1: |
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261 | #destruct_assm @⊥ >destruct_assm in program_size_refl; #abs destruct(abs) |
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262 | |2: |
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263 | #program_size_invariant |
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264 | <program_size_invariant <program_size_refl |
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265 | <S_assm normalize <plus_n_Sm % |
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266 | ] |
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267 | ] |
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268 | ] |
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269 | ] |
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270 | ] |
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271 | ] |
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272 | qed. |
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273 | |
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274 | (* XXX: |
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275 | * At the moment we do a full traversal of the code memory, however we could do |
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276 | * a fold over the domain of the cost labels map. |
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277 | * |
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278 | *) |
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279 | definition traverse_code: |
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280 | ∀code_memory: BitVectorTrie Byte 16. |
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281 | ∀cost_labels: BitVectorTrie costlabel 16. |
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282 | ∀cost_labels_injective: |
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283 | ∀pc, pc',l. |
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284 | lookup_opt … pc cost_labels = Some … l → lookup_opt … pc' cost_labels = Some … l → |
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285 | pc = pc'. |
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286 | Σcost_map: identifier_map CostTag nat. |
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287 | (∀pc,k. nat_of_bitvector … pc < 2^16 → lookup_opt … pc cost_labels = Some … k → present … cost_map k) ∧ |
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288 | (∀k. ∀k_pres:present … cost_map k. ∀pc. lookup_opt … pc cost_labels = Some … k → |
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289 | pi1 … (block_cost code_memory pc cost_labels) = lookup_present … k_pres) ≝ |
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290 | λcode_memory: BitVectorTrie Byte 16. |
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291 | λcost_labels: BitVectorTrie costlabel 16. |
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292 | λcost_labels_injective. |
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293 | pi1 ? ? (traverse_code_internal code_memory cost_labels (zero …) (2^16) ?). |
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294 | [1: |
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295 | @or_intror % |
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296 | |2: |
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297 | cases (traverse_code_internal ?????) |
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298 | #cost_mapping * #inductive_hypothesis1 #inductive_hypothesis2 % |
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299 | [1: |
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300 | #pc #k #pc_program_size_assm |
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301 | @inductive_hypothesis1 |
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302 | [1: |
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303 | @le_O_n |
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304 | |2: |
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305 | normalize in match (nat_of_bitvector 16 (zero 16)); |
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306 | <plus_n_O assumption |
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307 | ] |
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308 | |2: |
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309 | #k #k_pres #pc #lookup_opt_assm |
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310 | cases (inductive_hypothesis2 ? k_pres) |
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311 | #program_counter' * #lookup_opt_assm' #block_cost_assm |
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312 | >(cost_labels_injective … lookup_opt_assm lookup_opt_assm') |
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313 | assumption |
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314 | ] |
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315 | ] |
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316 | qed. |
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317 | |
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318 | definition compute_costs ≝ |
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319 | λprogram: list Byte. |
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320 | λcost_labels: BitVectorTrie costlabel 16. |
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321 | λcost_labels_injective: |
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322 | ∀pc, pc',l. |
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323 | lookup_opt … pc cost_labels = Some … l → lookup_opt … pc' cost_labels = Some … l → |
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324 | pc = pc'. |
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325 | let program_size ≝ |program| in |
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326 | let code_memory ≝ load_code_memory program in |
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327 | traverse_code code_memory cost_labels cost_labels_injective. |
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328 | |
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329 | definition object_code ≝ list Byte. |
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330 | definition costlabel_map ≝ BitVectorTrie costlabel 16. |
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331 | |
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332 | definition ASM_cost_map : |
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333 | ∀p.let code_memory ≝ load_code_memory (\fst p) in |
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334 | ? → as_cost_map (ASM_abstract_status code_memory (\snd p)) ≝ |
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335 | λp : object_code × costlabel_map. |
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336 | λcost_labels_injective. |
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337 | let cost_map ≝ compute_costs (\fst p) (\snd p) cost_labels_injective in |
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338 | λl_sig. |
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339 | lookup_present … cost_map l_sig ?. |
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340 | cases cost_map |
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341 | #m * #prf #_ cases l_sig cases daemon (*bla bla*) |
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342 | qed. |
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