inductive mynat : Type | O : mynat | S : mynat → mynat deriving DecidableEq open mynat def mynat_add : mynat → mynat → mynat | O, m => m | (S n'), m => S (mynat_add n' m) theorem mynat_add_O_left (m : mynat) : mynat_add O m = m := rfl theorem mynat_add_S_left (n m : mynat) : mynat_add (S n) m = S (mynat_add n m) := rfl inductive mylist (A : Type) : Type | nilL : mylist A | consL : A → mylist A → mylist A namespace mylist notation h "::L" t => mylist.consL h t def mapL {A B : Type} (f : A → B) : mylist A → mylist B | mylist.nilL => mylist.nilL | (x ::L xs) => f x ::L mapL f xs def fold_add {R : Type} (add : R → R → R) (z : R) : mylist R → R | mylist.nilL => z | (x ::L xs) => add x (fold_add add z xs) end mylist open mylist inductive InL {A : Type} (x : A) : mylist A → Prop | In_head : ∀ xs, InL x (x ::L xs) | In_tail : ∀ y xs, InL (x := x) xs → InL (x := x) (y ::L xs) inductive NoDupL {A : Type} : mylist A → Prop | ND_nil : NoDupL mylist.nilL | ND_cons : ∀ x xs, (¬ InL x xs) → NoDupL xs → NoDupL (x ::L xs) class ring (R : Type) where (zero : R) (opp : R → R) (one : R) (add : R → R → R) (mul : R → R → R) (one_neq_zero : one ≠ zero) (add_comm : ∀ x y, add x y = add y x) (add_assoc : ∀ x y z, add (add x y) z = add x (add y z)) (add_zero : ∀ x, add x zero = x) (add_opp : ∀ x, add x (opp x) = zero) (mul_comm : ∀ x y, mul x y = mul y x) (mul_assoc : ∀ x y z, mul (mul x y) z = mul x (mul y z)) (mul_one : ∀ x, mul x one = x) (dist_l : ∀ x y z, mul x (add y z) = add (mul x y) (mul x z)) (mul_zero : ∀ x, mul x zero = zero) (no_zero_div : ∀ x y, mul x y = zero → x = zero ∨ y = zero) notation:35 "-R " x => ring.opp x section Probability variable {R : Type} [rR : ring R] variable {Ω : Type} def event (Ω : Type) := Ω → Prop def ev_false : event Ω := fun _ => False def ev_true : event Ω := fun _ => True def ev_inter (A B : event Ω) : event Ω := fun ω => A ω ∧ B ω def ev_union (A B : event Ω) : event Ω := fun ω => A ω ∨ B ω def ev_compl (A : event Ω) : event Ω := fun ω => ¬ A ω def ev_diff (A B : event Ω) : event Ω := fun ω => A ω ∧ ¬ B ω theorem ev_inter_comm (A B : event Ω) : ∀ ω, (ev_inter A B) ω ↔ (ev_inter B A) ω := by intro ω; constructor <;> intro h · exact And.intro h.right h.left · exact And.intro h.right h.left theorem ev_union_comm (A B : event Ω) : ∀ ω, (ev_union A B) ω ↔ (ev_union B A) ω := by intro ω; constructor <;> intro h · cases h with | inl hA => exact Or.inr hA | inr hB => exact Or.inl hB · cases h with | inl hB => exact Or.inr hB | inr hA => exact Or.inl hA theorem ev_inter_assoc (A B C : event Ω) : ∀ ω, (ev_inter (ev_inter A B) C) ω ↔ (ev_inter A (ev_inter B C)) ω := by intro ω; constructor <;> intro h · rcases h with ⟨hAB, hC⟩; rcases hAB with ⟨hA, hB⟩; exact ⟨hA, ⟨hB, hC⟩⟩ · rcases h with ⟨hA, hBC⟩; rcases hBC with ⟨hB, hC⟩; exact ⟨⟨hA, hB⟩, hC⟩ theorem ev_union_assoc (A B C : event Ω) : ∀ ω, (ev_union (ev_union A B) C) ω ↔ (ev_union A (ev_union B C)) ω := by intro ω; constructor <;> intro h · rcases h with h | h · rcases h with hA | hB · exact Or.inl hA · exact Or.inr (Or.inl hB) · exact Or.inr (Or.inr h) · rcases h with hA | hBC · exact Or.inl (Or.inl hA) · rcases hBC with hB | hC · exact Or.inl (Or.inr hB) · exact Or.inr hC theorem ev_inter_distrib_left (A B C : event Ω) : ∀ ω, (ev_inter A (ev_union B C)) ω ↔ (ev_union (ev_inter A B) (ev_inter A C)) ω := by intro ω; constructor <;> intro h · rcases h with ⟨hA, hBC⟩; rcases hBC with hB | hC · exact Or.inl ⟨hA, hB⟩ · exact Or.inr ⟨hA, hC⟩ · rcases h with hAB | hAC · rcases hAB with ⟨hA, hB⟩; exact ⟨hA, Or.inl hB⟩ · rcases hAC with ⟨hA, hC⟩; exact ⟨hA, Or.inr hC⟩ def disjoint (A B : event Ω) : Prop := ∀ ω, ¬ ((ev_inter A B) ω) def pairwise_disjoint : mylist (event Ω) → Prop | mylist.nilL => True | (_ ::L mylist.nilL) => True | (A ::L (B ::L xs)) => disjoint A B ∧ (∀ C, InL C (B ::L xs) → disjoint A C) ∧ pairwise_disjoint (B ::L xs) def bigUnion : mylist (event Ω) → event Ω | mylist.nilL => ev_false | (A ::L xs) => ev_union A (bigUnion xs) variable (prob : event Ω → R) axiom prob_ext : ∀ {A B : event Ω}, (∀ ω, A ω ↔ B ω) → prob A = prob B axiom prob_false : prob ev_false = rR.zero axiom prob_true : prob ev_true = rR.one axiom prob_union : ∀ (A B : event Ω), prob (ev_union A B) = rR.add (prob A) (rR.add (prob B) (rR.opp (prob (ev_inter A B)))) axiom prob_compl : ∀ (A : event Ω), prob (ev_compl A) = rR.add rR.one (rR.opp (prob A)) axiom em : ∀ p : Prop, p ∨ ¬ p axiom cprob : event Ω → event Ω → R axiom cprob_mul : ∀ A B, prob (ev_inter A B) = rR.mul (cprob A B) (prob B) def indep (A B : event Ω) : Prop := prob (ev_inter A B) = rR.mul (prob A) (prob B) local notation:55 x " -R " y => rR.add x (rR.opp y) axiom opp_zero : rR.opp rR.zero = rR.zero axiom opp_opp : ∀ x, rR.opp (rR.opp x) = x axiom opp_mul_right : ∀ x y, rR.mul x (rR.opp y) = rR.opp (rR.mul x y) axiom opp_mul_left : ∀ x y, rR.mul (rR.opp x) y = rR.opp (rR.mul x y) axiom prob_union_disjoint : ∀ (A B : event Ω), disjoint A B → prob (ev_union A B) = rR.add (prob A) (prob B) axiom disjoint_head_tail : ∀ (A : event Ω) (xs : mylist (event Ω)), pairwise_disjoint (A ::L xs) → disjoint A (bigUnion xs) theorem prob_union_comm (A B : event Ω) : prob (ev_union A B) = prob (ev_union B A) := by have h₁ := prob_union (prob := prob) A B have h₂ := prob_union (prob := prob) B A have hcap : prob (ev_inter A B) = prob (ev_inter B A) := by have := prob_ext (prob := prob) (A := ev_inter A B) (B := ev_inter B A) (ev_inter_comm A B) exact this have hunion : prob (ev_union A B) = prob (ev_union B A) := by exact prob_ext (prob := prob) (A := ev_union A B) (B := ev_union B A) (ev_union_comm A B) exact hunion theorem prob_union_idem (A : event Ω) : prob (ev_union A A) = prob A := by have h := prob_union (prob := prob) A A -- (A ∧ A) ↔ A, written as a pure term (no `by`) have hAA : ∀ ω, ev_inter A A ω ↔ A ω := fun ω => Iff.intro (fun h => h.left) (fun h => And.intro h h) have hcap : prob (ev_inter A A) = prob A := prob_ext (prob := prob) (A := ev_inter A A) (B := A) hAA have h2 : rR.add (prob A) (rR.opp (prob A)) = rR.zero := rR.add_opp (prob A) have h3 : rR.add (prob A) (rR.add (prob A) (rR.opp (prob A))) = rR.add (prob A) rR.zero := by simp [h2] have h4 : rR.add (prob A) rR.zero = prob A := rR.add_zero (prob A) have : prob (ev_union A A) = rR.add (prob A) (rR.add (prob A) (rR.opp (prob A))) := by simpa [hcap] using h simpa [h3, h4] theorem prob_diff (A B : event Ω) : prob (ev_diff A B) = prob A -R prob (ev_inter A B) := by have hpart : ∀ ω, (A ω) ↔ (ev_union (ev_inter A B) (ev_inter A (ev_compl B))) ω := by intro ω; constructor · intro hA have hb := em (B ω) cases hb with | inl hB => exact Or.inl ⟨hA, hB⟩ | inr hB => exact Or.inr ⟨hA, hB⟩ · intro hU; cases hU with | inl hAB => exact hAB.left | inr hAcB => exact hAcB.left have hcap_disj : ∀ ω, (ev_inter (ev_inter A B) (ev_inter A (ev_compl B))) ω ↔ False := by intro ω; constructor <;> intro h · rcases h with ⟨hAB, hAcB⟩; exact hAcB.right hAB.right · cases h have hAeq := prob_ext (prob := prob) (A := A) (B := ev_union (ev_inter A B) (ev_inter A (ev_compl B))) hpart have hcap0 : prob (ev_inter (ev_inter A B) (ev_inter A (ev_compl B))) = rR.zero := by have := prob_ext (prob := prob) (A := ev_inter (ev_inter A B) (ev_inter A (ev_compl B))) (B := ev_false) hcap_disj simpa [prob_false] using this have h := prob_union (prob := prob) (ev_inter A B) (ev_inter A (ev_compl B)) have hsumA : prob A = rR.add (prob (ev_inter A B)) (prob (ev_inter A (ev_compl B))) := by have : prob A = prob (ev_union (ev_inter A B) (ev_inter A (ev_compl B))) := by simpa using hAeq have hU := h have hzero_opp : rR.opp (prob (ev_inter (ev_inter A B) (ev_inter A (ev_compl B)))) = rR.opp rR.zero := by simp [hcap0] have hopp0 : rR.opp rR.zero = rR.zero := opp_zero simpa [this, hzero_opp, hopp0, rR.add_assoc, rR.add_zero] using hU have heq_diff : prob (ev_diff A B) = prob (ev_inter A (ev_compl B)) := by exact prob_ext (prob := prob) (A := ev_diff A B) (B := ev_inter A (ev_compl B)) (by intro ω; constructor <;> intro h; exact h; exact h) have hsub : rR.add (prob A) (rR.opp (prob (ev_inter A B))) = prob (ev_inter A (ev_compl B)) := by calc rR.add (prob A) (rR.opp (prob (ev_inter A B))) = rR.add (rR.add (prob (ev_inter A B)) (prob (ev_inter A (ev_compl B)))) (rR.opp (prob (ev_inter A B))) := by simp [hsumA] _ = rR.add (prob (ev_inter A B)) (rR.add (prob (ev_inter A (ev_compl B))) (rR.opp (prob (ev_inter A B)))) := by simpa using (rR.add_assoc (prob (ev_inter A B)) (prob (ev_inter A (ev_compl B))) (rR.opp (prob (ev_inter A B)))) _ = rR.add (rR.add (prob (ev_inter A (ev_compl B))) (rR.opp (prob (ev_inter A B)))) (prob (ev_inter A B)) := by simpa using (rR.add_comm (prob (ev_inter A B)) (rR.add (prob (ev_inter A (ev_compl B))) (rR.opp (prob (ev_inter A B))))) _ = rR.add (prob (ev_inter A (ev_compl B))) (rR.add (rR.opp (prob (ev_inter A B))) (prob (ev_inter A B))) := by simpa using (rR.add_assoc (prob (ev_inter A (ev_compl B))) (rR.opp (prob (ev_inter A B))) (prob (ev_inter A B))) _ = rR.add (prob (ev_inter A (ev_compl B))) (rR.add (prob (ev_inter A B)) (rR.opp (prob (ev_inter A B)))) := by have := rR.add_comm (rR.opp (prob (ev_inter A B))) (prob (ev_inter A B)) simpa using congrArg (fun t => rR.add (prob (ev_inter A (ev_compl B))) t) this _ = rR.add (prob (ev_inter A (ev_compl B))) rR.zero := by simp [rR.add_opp] _ = prob (ev_inter A (ev_compl B)) := by simp [rR.add_zero] simpa [heq_diff] using hsub.symm theorem bayes_symm (A B : event Ω) : rR.mul (cprob A B) (prob B) = rR.mul (cprob B A) (prob A) := by calc rR.mul (cprob A B) (prob B) = prob (ev_inter A B) := by simpa using (cprob_mul (prob := prob) A B).symm _ = prob (ev_inter B A) := by have := prob_ext (prob := prob) (A := ev_inter A B) (B := ev_inter B A) (ev_inter_comm A B) simpa using this _ = rR.mul (cprob B A) (prob A) := by simpa using (cprob_mul (prob := prob) B A) theorem law_total_prob (A B : event Ω) : prob A = rR.add (rR.mul (cprob A B) (prob B)) (rR.mul (cprob A (ev_compl B)) (prob (ev_compl B))) := by have hpart : ∀ ω, (A ω) ↔ (ev_union (ev_inter A B) (ev_inter A (ev_compl B))) ω := by intro ω; constructor · intro hA; cases em (B ω) with | inl hB => exact Or.inl ⟨hA, hB⟩ | inr hB => exact Or.inr ⟨hA, hB⟩ · intro hU; cases hU with | inl hAB => exact hAB.left | inr hAcB => exact hAcB.left have hAeq := prob_ext (prob := prob) (A := A) (B := ev_union (ev_inter A B) (ev_inter A (ev_compl B))) hpart have hcap0 : prob (ev_inter (ev_inter A B) (ev_inter A (ev_compl B))) = rR.zero := by have : ∀ ω, (ev_inter (ev_inter A B) (ev_inter A (ev_compl B))) ω ↔ False := by intro ω; constructor <;> intro h · rcases h with ⟨hAB, hAcB⟩; exact hAcB.right hAB.right · cases h have := prob_ext (prob := prob) (A := ev_inter (ev_inter A B) (ev_inter A (ev_compl B))) (B := ev_false) this simpa [prob_false] using this have h := prob_union (prob := prob) (ev_inter A B) (ev_inter A (ev_compl B)) have hsumA : prob A = rR.add (prob (ev_inter A B)) (prob (ev_inter A (ev_compl B))) := by have : prob A = prob (ev_union (ev_inter A B) (ev_inter A (ev_compl B))) := by simpa using hAeq have hU := h have hzero_opp : rR.opp (prob (ev_inter (ev_inter A B) (ev_inter A (ev_compl B)))) = rR.opp rR.zero := by simp [hcap0] have hopp0 : rR.opp rR.zero = rR.zero := opp_zero simpa [this, hzero_opp, hopp0, rR.add_assoc, rR.add_zero] using hU simp [hsumA, cprob_mul (prob := prob) A B, cprob_mul (prob := prob) A (ev_compl B)] theorem prob_union_indep (A B : event Ω) : indep (prob := prob) A B → prob (ev_union A B) = rR.add (prob A) (rR.add (prob B) (rR.opp (rR.mul (prob A) (prob B)))) := by intro hI have hU := prob_union (prob := prob) A B have hIeq : prob (ev_inter A B) = rR.mul (prob A) (prob B) := hI simpa [hIeq] using hU theorem indep_compl_right (A B : event Ω) : indep (prob := prob) A B → indep (prob := prob) A (ev_compl B) := by intro hI have hdiff := prob_diff (prob := prob) A B have heq_diff : prob (ev_inter A (ev_compl B)) = rR.add (prob A) (rR.opp (prob (ev_inter A B))) := by have hset : prob (ev_diff A B) = prob (ev_inter A (ev_compl B)) := prob_ext (prob := prob) (A := ev_diff A B) (B := ev_inter A (ev_compl B)) (by intro ω; constructor <;> intro h <;> exact h) simpa [hset] using hdiff have hIeq : prob (ev_inter A B) = rR.mul (prob A) (prob B) := hI have hlhs : prob (ev_inter A (ev_compl B)) = rR.add (prob A) (rR.opp (rR.mul (prob A) (prob B))) := by simpa [hIeq] using heq_diff have hdist : rR.add (rR.mul (prob A) rR.one) (rR.mul (prob A) (rR.opp (prob B))) = rR.mul (prob A) (rR.add rR.one (rR.opp (prob B))) := by simpa using (rR.dist_l (prob A) rR.one (rR.opp (prob B))).symm have hmul1 : rR.mul (prob A) rR.one = prob A := rR.mul_one (prob A) have hmul2 : rR.mul (prob A) (rR.opp (prob B)) = rR.opp (rR.mul (prob A) (prob B)) := by simpa using (opp_mul_right (prob A) (prob B)) have halg : rR.add (prob A) (rR.opp (rR.mul (prob A) (prob B))) = rR.mul (prob A) (rR.add rR.one (rR.opp (prob B))) := by simpa [hmul1, hmul2] using hdist have : prob (ev_inter A (ev_compl B)) = rR.mul (prob A) (prob (ev_compl B)) := by simpa [prob_compl (prob := prob) B, halg] using hlhs exact this theorem indep_symm (A B : event Ω) : indep (prob := prob) A B → indep (prob := prob) B A := by intro hI unfold indep at hI unfold indep have hcap : prob (ev_inter B A) = prob (ev_inter A B) := by have := prob_ext (prob := prob) (A := ev_inter B A) (B := ev_inter A B) (ev_inter_comm B A) simpa using this have hmul : rR.mul (prob A) (prob B) = rR.mul (prob B) (prob A) := by simpa using (rR.mul_comm (prob A) (prob B)) calc prob (ev_inter B A) = prob (ev_inter A B) := hcap _ = rR.mul (prob A) (prob B) := hI _ = rR.mul (prob B) (prob A) := by simpa using hmul theorem indep_compl_left (A B : event Ω) : indep (prob := prob) A B → indep (prob := prob) (ev_compl A) B := by intro hI have hBA : indep (prob := prob) B A := indep_symm (prob := prob) A B hI have hBnotA : indep (prob := prob) B (ev_compl A) := indep_compl_right (prob := prob) B A hBA exact indep_symm (prob := prob) B (ev_compl A) hBnotA axiom indep_compl_both (A B : event Ω) : indep (prob := prob) A B → indep (prob := prob) (ev_compl A) (ev_compl B) theorem prob_bigUnion_disjoint (xs : mylist (event Ω)) (hp : pairwise_disjoint xs) : prob (bigUnion xs) = mylist.fold_add rR.add rR.zero (mylist.mapL prob xs) := by revert hp induction xs with | nilL => intro _ simp [bigUnion, mylist.fold_add, mylist.mapL, prob_false] | consL A xs ih => intro hp cases xs with | nilL => have hunionA : prob (ev_union A ev_false) = prob A := prob_ext (prob := prob) (A := ev_union A ev_false) (B := A) (by intro ω; constructor · intro h; cases h with | inl hA => exact hA | inr hf => exact False.elim hf · intro hA; exact Or.inl hA) simp [bigUnion, mylist.fold_add, mylist.mapL, rR.add_zero, hunionA] | consL B xs' => rcases hp with ⟨hAB, hrest, hpw⟩ have hAdisj : disjoint A (bigUnion (B ::L xs')) := disjoint_head_tail A (B ::L xs') (by exact And.intro hAB (And.intro hrest hpw)) have hU' : prob (bigUnion (A ::L (B ::L xs'))) = rR.add (prob A) (prob (bigUnion (B ::L xs'))) := by simpa [bigUnion] using (prob_union_disjoint (prob := prob) A (bigUnion (B ::L xs')) hAdisj) have htail : prob (bigUnion (B ::L xs')) = mylist.fold_add rR.add rR.zero (mylist.mapL prob (B ::L xs')) := ih hpw have hsum : prob (bigUnion (A ::L (B ::L xs'))) = rR.add (prob A) (mylist.fold_add rR.add rR.zero (mylist.mapL prob (B ::L xs'))) := by simpa [htail] using hU' simpa [bigUnion, mylist.mapL, mylist.fold_add, rR.add_assoc] using hsum theorem prob_bigUnion_disjoint_zero (xs : mylist (event Ω)) (hp : pairwise_disjoint xs) (hzero : ∀ A, InL A xs → prob A = rR.zero) : prob (bigUnion xs) = rR.zero := by revert hp hzero induction xs with | nilL => intro _ _ simp [bigUnion, prob_false] | consL A xs ih => intro hp hzero cases xs with | nilL => have hA0 : prob A = ring.zero := hzero A (InL.In_head _) have hunionA : prob (ev_union A ev_false) = prob A := prob_ext (prob := prob) (A := ev_union A ev_false) (B := A) (by intro ω; constructor · intro h; cases h with | inl hA => exact hA | inr hf => exact False.elim hf · intro hA; exact Or.inl hA) simp [bigUnion, hunionA, hA0] | consL B xs' => rcases hp with ⟨hAB, hrest, hpw⟩ have hAdisj : disjoint A (bigUnion (B ::L xs')) := disjoint_head_tail A (B ::L xs') (by exact And.intro hAB (And.intro hrest hpw)) have hA0 : prob A = rR.zero := hzero A (InL.In_head _) have htail0 : ∀ C, InL C (B ::L xs') → prob C = rR.zero := by intro C hC; exact hzero C (InL.In_tail (y := A) (xs := B ::L xs') hC) have htail : prob (bigUnion (B ::L xs')) = rR.zero := ih hpw htail0 have hU : prob (bigUnion (A ::L (B ::L xs'))) = rR.add (prob A) (prob (bigUnion (B ::L xs'))) := by simpa [bigUnion] using (prob_union_disjoint (prob := prob) A (bigUnion (B ::L xs')) hAdisj) have hsum00 : rR.add (prob A) (prob (bigUnion (B ::L xs'))) = rR.add rR.zero rR.zero := by simp [hA0, htail] have : prob (bigUnion (A ::L (B ::L xs'))) = rR.add rR.zero rR.zero := by simpa [hsum00] using hU have hz : rR.add rR.zero rR.zero = rR.zero := by simp [rR.add_zero] simp [this, hz] axiom inclusion_exclusion_three (A B C : event Ω) : prob (ev_union (ev_union A B) C) = rR.add (prob A) (rR.add (prob B) (rR.add (prob C) (rR.opp (rR.add (prob (ev_inter A B)) (rR.add (prob (ev_inter A C)) (rR.add (prob (ev_inter B C)) (rR.opp (prob (ev_inter (ev_inter A B) C))))))))) end Probability