164 lines
6.5 KiB
Text
164 lines
6.5 KiB
Text
-- --------------------------------------------------------------------------------------------------------------
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-- | BASIC LOGIC |
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-- --------------------------------------------------------------------------------------------------------------
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@include logic.pg
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-- --------------------------------------------------------------------------------------------------------------
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-- | BASIC DEFINITIONS |
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-- --------------------------------------------------------------------------------------------------------------
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section BasicDefinitions
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-- note we leave off the type ascriptions for most of these, as the type isn't
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-- very interesting
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-- I'd always strongly recommend including the type ascriptions for theorems
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-- Fix some set A
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variable (A : *);
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-- a unary operation is a function `A -> A`
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def unop := A -> A;
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-- a binary operation is a function `A -> A -> A`
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def binop := A -> A -> A;
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-- fix some binary operation `op`
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variable (op : binop);
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-- it is associative if ...
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def assoc := forall (a b c : A), eq A (op a (op b c)) (op (op a b) c);
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-- fix some element `e`
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variable (e : A);
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-- it is a left identity with respect to binop `op` if `∀ a, e * a = a`
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def id_l := forall (a : A), eq A (op e a) a;
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-- likewise for right identity
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def id_r := forall (a : A), eq A (op a e) a;
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-- an element is an identity element if it is both a left and right identity
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def id := and id_l id_r;
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-- b is a left inverse for a if `b * a = e`
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-- NOTE: we don't require `e` to be an identity in this definition.
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-- this definition is purely for convenience's sake
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def inv_l (a b : A) := eq A (op b a) e;
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-- likewise for right inverse
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def inv_r (a b : A) := eq A (op a b) e;
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-- and full-on inverse
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def inv (a b : A) := and (inv_l a b) (inv_r a b);
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end BasicDefinitions
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-- --------------------------------------------------------------------------------------------------------------
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-- | ALGEBRAIC STRUCTURES |
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-- --------------------------------------------------------------------------------------------------------------
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-- a set `S` with binary operation `op` is a semigroup if its operation is associative
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def semigroup (S : *) (op : binop S) : * := assoc S op;
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section Monoid
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variable (M : *) (op : binop M) (e : M);
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-- a set `M` with binary operation `op` and element `e` is a monoid
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def monoid : * := and (semigroup M op) (id M op e);
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hypothesis (Hmonoid : monoid);
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-- some "getters" for `monoid` so we don't have to do a bunch of very verbose
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-- and-eliminations every time we want to use something
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def id_lm : id_l M op e :=
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and_elim_l (id_l M op e) (id_r M op e)
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(and_elim_r (semigroup M op) (id M op e) Hmonoid);
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def id_rm : id_r M op e :=
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and_elim_r (id_l M op e) (id_r M op e)
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(and_elim_r (semigroup M op) (id M op e) Hmonoid);
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def assoc_m : assoc M op := and_elim_l (semigroup M op) (id M op e) Hmonoid;
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-- now we can prove that, for any monoid, if `a` is a left identity, then it
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-- must be "the" identity
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def monoid_id_l_implies_identity (a : M) (H : id_l M op a) : eq M a e :=
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-- WTS a = a * e = e
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-- we can use `eq_trans` to glue proofs of `a = a * e` and `a * e = e` together
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eq_trans M a (op a e) e
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-- first, `a = a * e`, but we'll use `eq_sym` to flip it around
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(eq_sym M (op a e) a
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-- now the goal is to show `a * e = a`, which follows immediately from `id_r`
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(id_rm a))
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-- now we need to show that `a * e = e`, but this immediately follows from `H`
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(H e);
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-- the analogous result for right identities
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def monoid_id_r_implies_identity (a : M) (H : id_r M op a) : eq M a e :=
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-- this time, we'll show `a = e * a = e`
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eq_trans M a (op e a) e
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-- first, `a = e * a`
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(eq_sym M (op e a) a
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-- this time, it immediately follows from `id_l`
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(id_lm a))
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-- and `e * a = e`
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(H e);
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end Monoid
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section Group
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variable (G : *) (op : binop G) (e : G) (i : unop G);
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-- groups are just monoids with inverses
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def has_inverses : * := forall (a : G), inv G op e a (i a);
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def group : * := and (monoid G op e) has_inverses;
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hypothesis (Hgroup : group);
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-- more "getters"
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def monoid_g : monoid G op e := and_elim_l (monoid G op e) has_inverses Hgroup;
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def assoc_g : assoc G op := assoc_m G op e monoid_g;
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def id_lg : id_l G op e := id_lm G op e (and_elim_l (monoid G op e) has_inverses Hgroup);
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def id_rg : id_r G op e := id_rm G op e (and_elim_l (monoid G op e) has_inverses Hgroup);
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def inv_g : forall (a : G), inv G op e a (i a) := and_elim_r (monoid G op e) has_inverses Hgroup;
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def left_inverse (a b : G) := inv_l G op e a b;
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def right_inverse (a b : G) := inv_r G op e a b;
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def inv_lg (a : G) : left_inverse a (i a) := and_elim_l (inv_l G op e a (i a)) (inv_r G op e a (i a)) (inv_g a);
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def inv_rg (a : G) : right_inverse a (i a) := and_elim_r (inv_l G op e a (i a)) (inv_r G op e a (i a)) (inv_g a);
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-- An interesting theorem: left inverses are unique, i.e. if b * a = e, then b = a^-1
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def left_inv_unique (a b : G) (h : left_inverse a b) : eq G b (i a) :=
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-- b = b * e
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-- = b * (a * a^-1)
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-- = (b * a) * a^-1
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-- = e * a^-1
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-- = a^-1
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eq_trans G b (op b e) (i a)
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-- b = b * e
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(eq_sym G (op b e) b (id_rg b))
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-- b * e = a^-1
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(eq_trans G (op b e) (op b (op a (i a))) (i a)
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--b * e = b * (a * a^-1)
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(eq_cong G G e (op a (i a)) (op b)
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-- e = a * a^-1
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(eq_sym G (op a (i a)) e (inv_rg a)))
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-- b * (a * a^-1) = a^-1
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(eq_trans G (op b (op a (i a))) (op (op b a) (i a)) (i a)
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-- b * (a * a^-1) = (b * a) * a^-1
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(assoc_g b a (i a))
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-- (b * a) * a^-1 = a^-1
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(eq_trans G (op (op b a) (i a)) (op e (i a)) (i a)
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-- (b * a) * a^-1 = e * a^-1
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(eq_cong G G (op b a) e (fun (x : G) => op x (i a)) h)
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-- e * a^-1 = a^-1
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(id_lg (i a)))));
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end Group
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