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adding 2020 isabelle solutions
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isabelle/2020/HSV_tasks_2020_solutions.thy
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381
isabelle/2020/HSV_tasks_2020_solutions.thy
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theory HSV_tasks_2020_solutions imports Complex_Main begin
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section \<open>Task 1: proving that "3 / sqrt 2" is irrational.\<close>
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(* The following theorem is copied from Chapter 3 of the worksheet *)
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theorem sqrt2_irrational: "sqrt 2 \<notin> \<rat>"
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proof auto
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assume "sqrt 2 \<in> \<rat>"
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then obtain m n where
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"n \<noteq> 0" and "\<bar>sqrt 2\<bar> = real m / real n" and "coprime m n"
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by (rule Rats_abs_nat_div_natE)
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hence "\<bar>sqrt 2\<bar>^2 = (real m / real n)^2" by auto
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hence "2 = (real m / real n)^2" by simp
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hence "2 = (real m)^2 / (real n)^2" unfolding power_divide by auto
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hence "2 * (real n)^2 = (real m)^2"
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by (simp add: nonzero_eq_divide_eq `n \<noteq> 0`)
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hence "real (2 * n^2) = (real m)^2" by auto
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hence *: "2 * n^2 = m^2"
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using of_nat_power_eq_of_nat_cancel_iff by blast
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hence "even (m^2)" by presburger
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hence "even m" by simp
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then obtain m' where "m = 2 * m'" by auto
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with * have "2 * n^2 = (2 * m')^2" by auto
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hence "2 * n^2 = 4 * m'^2" by simp
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hence "n^2 = 2 * m'^2" by simp
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hence "even (n^2)" by presburger
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hence "even n" by simp
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with `even m` and `coprime m n` show False by auto
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qed
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theorem "3 / sqrt 2 \<notin> \<rat>"
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proof auto
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assume *: "3 / sqrt 2 \<in> \<rat>"
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(* establish that 3 / sqrt 2 = 3 * sqrt 2 / 2 *)
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have "3 / sqrt 2 = (3 / sqrt 2) * (sqrt 2 / sqrt 2)" by auto
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also have "... = 3 * sqrt 2 / (sqrt 2 * sqrt 2)" by argo
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also have "... = 3 * sqrt 2 / 2" by simp
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finally have "3 / sqrt 2 = 3 * sqrt 2 / 2" by assumption
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(* so 3 * sqrt 2 / 2 is rational ... *)
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with * have "3 * sqrt 2 / 2 \<in> \<rat>" by auto
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(* ... and 2/3 is also rational ... *)
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moreover have "2 / 3 \<in> \<rat>" by simp
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(* ... so their product is also rational ... *)
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ultimately have "(3 * sqrt 2 / 2) * (2 / 3) \<in> \<rat>"
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using Rats_mult by blast
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(* ... which means sqrt 2 is rational ... *)
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hence "sqrt 2 \<in> \<rat>" by simp
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(* ... which contradicts the previous theorem! *)
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with sqrt2_irrational show False by simp
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qed
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section \<open>Task 2: Centred pentagonal numbers.\<close>
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fun pent :: "nat \<Rightarrow> nat" where
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"pent n = (if n = 0 then 1 else 5 * n + pent (n - 1))"
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value "pent 0" (* should be 1 *)
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value "pent 1" (* should be 6 *)
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value "pent 2" (* should be 16 *)
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value "pent 3" (* should be 31 *)
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theorem "pent n = (5 * n^2 + 5 * n + 2) div 2"
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proof (induct n)
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case 0
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thus ?case by auto
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next
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case (Suc n)
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have "pent (Suc n) = 5 * (n + 1) + pent n" by simp
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also have "... = 5 * n + 5 + (5 * n^2 + 5 * n + 2) div 2" using Suc by simp
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also have "... = (5 * (n^2 + 2 * n + 1) + 5 * (n + 1) + 2) div 2" by simp
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also have "... = (5 * (n + 1)^2 + 5 * (n + 1) + 2) div 2"
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by (smt add.commute add_Suc mult_2 one_add_one plus_1_eq_Suc power2_sum power_one)
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also have "... = (5 * (Suc n)^2 + 5 * Suc n + 2) div 2" by simp
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finally show ?case by assumption
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qed
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section \<open>Task 3: Lucas numbers.\<close>
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fun luc :: "nat \<Rightarrow> nat" where
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"luc n = (if n = 0 then 2 else if n = 1 then 1 else luc (n - 1) + luc (n - 2))"
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value "luc 0" (* should be 2 *)
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value "luc 1" (* should be 1 *)
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value "luc 2" (* should be 3 *)
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value "luc 3" (* should be 4 *)
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fun fib :: "nat \<Rightarrow> nat" where
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"fib n = (if n = 0 then 0 else if n = 1 then 1 else fib (n - 1) + fib (n - 2))"
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value "fib 0" (* should be 0 *)
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value "fib 1" (* should be 1 *)
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value "fib 2" (* should be 1 *)
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value "fib 3" (* should be 2 *)
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thm fib.induct (* rule induction theorem for fib *)
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theorem "luc n \<ge> fib n"
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apply (rule fib.induct[of "\<lambda>n. luc n \<ge> fib n"])
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apply (case_tac "n < 2")
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apply auto
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done
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theorem "luc (n + 1) = fib n + fib (n + 2)"
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proof (rule fib.induct[of "\<lambda>n. luc (n + 1) = fib n + fib (n + 2)"])
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fix n
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assume IH1: "n \<noteq> 0 \<Longrightarrow> n \<noteq> 1 \<Longrightarrow> luc (n - 1 + 1) = fib (n - 1) + fib (n - 1 + 2)"
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assume IH2: "n \<noteq> 0 \<Longrightarrow> n \<noteq> 1 \<Longrightarrow> luc (n - 2 + 1) = fib (n - 2) + fib (n - 2 + 2)"
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(* First deal with the easy case where n \<le> 1 *)
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{
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assume "n \<le> 1" (* local assumption *)
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hence "luc (n + 1) = fib n + fib (n + 2)" by simp
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}
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moreover (* Now deal with the trickier case where n > 1 *)
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{
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assume "n > 1"
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(* Simplify the induction hypotheses *)
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from IH1 have *: "luc n = fib (n - 1) + fib (n + 1)" using `n > 1` by auto
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from IH2 have
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"luc (n - 2 + 1) = fib (n - 2) + fib (n - 2 + 2)" using `n > 1` by fastforce
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hence **: "luc (n - 1) = fib (n - 2) + fib n"
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by (metis Nat.add_diff_assoc2 Suc_leI add.commute add_diff_cancel_right'
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diff_Suc_Suc one_add_one plus_1_eq_Suc `n > 1`)
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(* Some equational reasoning using the definitions of luc and fib to finish the job *)
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have "luc (n + 1) = luc n + luc (n - 1)" using `n > 1` by simp
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also have "... = fib (n - 1) + fib (n + 1) + fib (n - 2) + fib n" using * and ** by simp
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also have "... = fib n + fib (n + 2)" using `n > 1` by simp
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finally have "luc (n + 1) = fib n + fib (n + 2)" by simp
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}
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ultimately show "luc (n + 1) = fib n + fib (n + 2)" by simp
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qed
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section \<open>Task 4: Balancing circuits.\<close>
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datatype "circuit" =
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NOT "circuit"
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| AND "circuit" "circuit"
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| OR "circuit" "circuit"
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| TRUE
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| FALSE
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| INPUT "int"
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text \<open>Simulates a circuit given a valuation for each input wire\<close>
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fun simulate where
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"simulate (AND c1 c2) \<rho> = ((simulate c1 \<rho>) \<and> (simulate c2 \<rho>))"
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| "simulate (OR c1 c2) \<rho> = ((simulate c1 \<rho>) \<or> (simulate c2 \<rho>))"
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| "simulate (NOT c) \<rho> = (\<not> (simulate c \<rho>))"
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| "simulate TRUE \<rho> = True"
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| "simulate FALSE \<rho> = False"
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| "simulate (INPUT i) \<rho> = \<rho> i"
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fun circuits_equiv (infix "\<sim>" 50) (* the "50" indicates the operator precedence *) where
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"c1 \<sim> c2 = (\<forall>\<rho>. simulate c1 \<rho> = simulate c2 \<rho>)"
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text \<open>Delay (assuming all gates have a delay of 1)\<close>
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fun delay :: "circuit \<Rightarrow> nat" where
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"delay (NOT c) = 1 + delay c"
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| "delay (AND c1 c2) = 1 + max (delay c1) (delay c2)"
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| "delay (OR c1 c2) = 1 + max (delay c1) (delay c2)"
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| "delay _ = 0"
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fun is_balanced where
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"is_balanced (NOT c) = is_balanced c"
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| "is_balanced (AND c1 c2) = (is_balanced c1 \<and> is_balanced c2 \<and> delay c1 = delay c2)"
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| "is_balanced (OR c1 c2) = (is_balanced c1 \<and> is_balanced c2 \<and> delay c1 = delay c2)"
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| "is_balanced _ = True"
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value "is_balanced (AND TRUE TRUE)" (* should be True *)
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value "is_balanced (AND (NOT TRUE) TRUE)" (* should be False *)
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value "is_balanced (AND (NOT TRUE) (OR TRUE (INPUT 1)))" (* should be True *)
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(* produce a balanced tree of OR gates whose leaves are all TRUE *)
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fun tree_TRUE where
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"tree_TRUE 0 = TRUE"
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| "tree_TRUE (Suc n) = OR (tree_TRUE n) (tree_TRUE n)"
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value "tree_TRUE 2" (* should be "OR (OR TRUE TRUE) (OR TRUE TRUE)" *)
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lemma tree_TRUE_equiv_TRUE:
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"tree_TRUE n \<sim> TRUE"
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by (induct n, auto)
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lemma is_balanced_tree_TRUE: "is_balanced (tree_TRUE n)"
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by (induct n, auto)
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lemma delay_tree_TRUE: "delay (tree_TRUE n) = n"
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by (induct n, auto)
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(* "pad n c" adds a delay of n to circuit c. It does so by AND-ing with TRUE n times.
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The TRUE is actually produced by a tree of OR-gates of whatever depth is necessary
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to preserve balance. *)
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fun pad where
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"pad 0 c = c"
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| "pad (Suc n) c = pad n (AND c (tree_TRUE (delay c)))"
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value "pad 2 (INPUT 1)" (* should be "AND (AND (INPUT 1) TRUE) (OR TRUE TRUE)" *)
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(* Padding does not change a circuit's behaviour *)
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lemma padding_is_sound:
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"pad n c \<sim> c"
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apply (induct n arbitrary: c)
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using tree_TRUE_equiv_TRUE by auto
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(* Padding does not unbalance a circuit *)
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lemma padding_preserves_balance: "is_balanced c \<Longrightarrow> is_balanced (pad n c)"
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proof (induct n arbitrary: c)
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case 0
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thus "is_balanced (pad 0 c)" by simp
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next
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case (Suc n)
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thus "is_balanced (pad (Suc n) c)"
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using is_balanced_tree_TRUE and delay_tree_TRUE by simp
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qed
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(* Padding by n adds a delay of n *)
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lemma padding_adds_delay: "delay (pad n c) = n + delay c"
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apply (induct n arbitrary: c)
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apply (auto simp add: delay_tree_TRUE)
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done
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(* add padding to whichever of c1 and c2 is shorter, then call continuation k *)
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fun pad_operands where
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"pad_operands k c1 c2 = (let d1 = delay c1; d2 = delay c2 in
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if d1 > d2 then k c1 (pad (d1 - d2) c2) else k (pad (d2 - d1) c1) c2)"
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lemma padding_AND_is_sound:
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"pad_operands AND c1 c2 \<sim> AND c1 c2"
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apply (cases "delay c1 > delay c2")
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using padding_is_sound by auto
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lemma padding_OR_is_sound:
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"pad_operands OR c1 c2 \<sim> OR c1 c2"
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apply (cases "delay c1 > delay c2")
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using padding_is_sound by auto
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theorem padding_AND_preserves_balance:
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"is_balanced c1 \<Longrightarrow> is_balanced c2 \<Longrightarrow> is_balanced (pad_operands AND c1 c2)"
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apply (cases "delay c1 > delay c2")
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apply (auto simp add: padding_adds_delay padding_preserves_balance)
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done
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theorem padding_OR_preserves_balance:
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"is_balanced c1 \<Longrightarrow> is_balanced c2 \<Longrightarrow> is_balanced (pad_operands OR c1 c2)"
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apply (cases "delay c1 > delay c2")
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apply (auto simp add: padding_adds_delay padding_preserves_balance)
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done
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fun balance where
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"balance (NOT c) = NOT (balance c)"
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| "balance (AND c1 c2) = pad_operands AND (balance c1) (balance c2)"
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| "balance (OR c1 c2) = pad_operands OR (balance c1) (balance c2)"
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| "balance TRUE = TRUE"
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| "balance FALSE = FALSE"
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| "balance (INPUT i) = INPUT i"
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value "balance (AND TRUE TRUE)" (* unchanged *)
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value "balance (AND (NOT TRUE) TRUE)" (* should be AND (NOT TRUE) (OR TRUE TRUE) *)
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value "balance (AND TRUE (NOT TRUE))" (* should be AND (OR TRUE TRUE) (NOT TRUE) *)
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value "balance (AND (NOT TRUE) (OR TRUE FALSE))" (* unchanged *)
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(* balancing a circuit doesn't change its behaviour *)
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theorem balance_is_sound: "balance c \<sim> c"
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proof (induct c)
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case (AND c1 c2)
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then show ?case using padding_AND_is_sound by auto
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next
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case (OR c1 c2)
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then show ?case using padding_OR_is_sound by auto
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qed (simp+)
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(* balancing a circuit does indeed result in a balanced circuit *)
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theorem balance_is_complete: "is_balanced (balance c)"
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proof (induct c)
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case (AND c1 c2)
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hence "is_balanced (balance c1)" and "is_balanced (balance c2)" by auto
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hence "is_balanced (pad_operands AND (balance c1) (balance c2))"
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by (rule padding_AND_preserves_balance)
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thus "is_balanced (balance (AND c1 c2))" by simp
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next
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case (OR c1 c2)
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hence "is_balanced (balance c1)" and "is_balanced (balance c2)" by auto
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hence "is_balanced (pad_operands OR (balance c1) (balance c2))"
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by (rule padding_OR_preserves_balance)
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thus "is_balanced (balance (OR c1 c2))" by simp
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qed (simp+)
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section \<open>Task 5: Extending with NAND gates.\<close>
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datatype "circuit'" =
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NOT "circuit'"
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| AND "circuit'" "circuit'"
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| OR "circuit'" "circuit'"
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| TRUE
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| FALSE
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| INPUT "int"
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| NAND "circuit'" "circuit'"
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fun fake_NOT where
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"fake_NOT c = NAND c TRUE"
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fun transform_to_NAND where
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"transform_to_NAND (NOT c) = fake_NOT (transform_to_NAND c)"
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| "transform_to_NAND (AND c1 c2) = fake_NOT (NAND (transform_to_NAND c1) (transform_to_NAND c2))"
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| "transform_to_NAND (OR c1 c2) = NAND (fake_NOT (transform_to_NAND c1)) (fake_NOT (transform_to_NAND c2))"
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| "transform_to_NAND TRUE = TRUE"
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| "transform_to_NAND FALSE = fake_NOT TRUE"
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| "transform_to_NAND (INPUT i) = INPUT i"
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| "transform_to_NAND (NAND c1 c2) = NAND (transform_to_NAND c1) (transform_to_NAND c2)"
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text \<open>Simulates a circuit given a valuation for each input wire\<close>
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fun simulate' where
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"simulate' (AND c1 c2) \<rho> = ((simulate' c1 \<rho>) \<and> (simulate' c2 \<rho>))"
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| "simulate' (OR c1 c2) \<rho> = ((simulate' c1 \<rho>) \<or> (simulate' c2 \<rho>))"
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| "simulate' (NOT c) \<rho> = (\<not> (simulate' c \<rho>))"
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| "simulate' TRUE \<rho> = True"
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| "simulate' FALSE \<rho> = False"
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| "simulate' (INPUT i) \<rho> = \<rho> i"
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| "simulate' (NAND c1 c2) \<rho> = (\<not> ((simulate' c1 \<rho>) \<and> (simulate' c2 \<rho>)))"
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definition circuits_equiv' where
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"circuits_equiv' c1 c2 \<equiv> \<forall>\<rho>. simulate' c1 \<rho> = simulate' c2 \<rho>"
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fun only_NANDs :: "circuit' \<Rightarrow> bool" where
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"only_NANDs (AND _ _) = False"
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| "only_NANDs (OR _ _) = False"
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| "only_NANDs (NOT _) = False"
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| "only_NANDs TRUE = True"
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| "only_NANDs FALSE = False"
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| "only_NANDs (INPUT _) = True"
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| "only_NANDs (NAND c1 c2) = (only_NANDs c1 \<and> only_NANDs c2)"
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lemma transform_to_NAND_sound: "circuits_equiv' c (transform_to_NAND c)"
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apply (simp add: circuits_equiv'_def)
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apply (induct c)
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apply auto
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done
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lemma transform_to_NAND_complete: "only_NANDs (transform_to_NAND c)"
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apply (induct c)
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apply auto
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done
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theorem "\<forall>c. \<exists>c'. circuits_equiv' c c' \<and> only_NANDs c'"
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apply clarsimp
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apply (rule_tac x="transform_to_NAND c" in exI)
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apply (intro conjI)
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apply (simp add: transform_to_NAND_sound)
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apply (simp add: transform_to_NAND_complete)
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done
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section \<open>Task 6: Showing that the transformation to NAND gates can increase delay.\<close>
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text \<open>Delay (assuming all gates have a delay of 1)\<close>
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fun delay' :: "circuit' \<Rightarrow> nat" where
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"delay' (NOT c) = 1 + delay' c"
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| "delay' (AND c1 c2) = 1 + max (delay' c1) (delay' c2)"
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| "delay' (OR c1 c2) = 1 + max (delay' c1) (delay' c2)"
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| "delay' (NAND c1 c2) = 1 + max (delay' c1) (delay' c2)"
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| "delay' _ = 0"
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theorem transform_to_NAND_increases_delay: "delay' (transform_to_NAND c) \<le> 2 * delay' c + 1"
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apply (induct c)
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apply auto
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done
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end
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