starting on antisymmetry
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@ -116,9 +116,44 @@ tightly that `_+_` at level 6, or `_*_` at level 7.
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infix 4 _≤_
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\end{code}
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## Reflexivity and transitivity
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## Properties of ordering relations
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The first thing to prove about comparison is that it is *reflexive*:
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Relations occur all the time, and mathematicians have agreed
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on names for some of the most common properties.
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+ *Reflexive* For all `n`, the relation `n ≤ n` holds.
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+ *Transitive* For all `m`, `n`, and `p`, if `m ≤ n` and
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`n ≤ p` hold, then `m ≤ p` holds.
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+ *Anti-symmetric* For all `m` and `n`, if both `m ≤ n` and
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`n ≤ m` hold, then `m ≡ n` holds.
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+ *Total* For all `m` and `n`, either `m ≤ n` or `n ≤ m`
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holds.
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The relation `_≤_` satisfies all four of these properties.
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There are also names for some combinations of these properties.
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+ *Preorder* Any relation that is reflexive and transitive.
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+ *Partial order* Any preorder that is also anti-symmetric.
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+ *Total order* Any partial order that is also total.
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If you ever bump into a relation at a party, you now know how
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to make small talk, by asking it whether it is reflexive, transitive,
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anti-symmetric, and total. Or instead you might ask whether it is a
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preorder, partial order, or total order.
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Less frivolously, if you ever bump into a relation while reading
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a technical paper, this gives you an easy way to orient yourself,
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by checking whether or not it is a preorder, partial order, or total order.
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A careful author will often make it explicit, for instance by saying
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that a given relation is a preoder but not a partial order, or a
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partial order but not a total order. (Can you think of examples of
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such relations?)
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## Reflexivity
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The first property to prove about comparison is that it is reflexive:
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for any natural `n`, the relation `n ≤ n` holds.
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\begin{code}
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refl≤ : ∀ (n : ℕ) → n ≤ n
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@ -128,12 +163,17 @@ refl≤ (suc n) = s≤s (refl≤ n)
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The proof is a straightforward induction on `n`. In the base case,
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`zero ≤ zero` holds by `z≤n`. In the inductive case, the inductive
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hypothesis `refl≤ n` gives us a proof of `n ≤ n`, and applying `s≤s`
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to that yields a proof of `suc n ≤ suc n`. It is a good exercise to
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create this proof interactively in Emacs, using holes and the `^C ^C`,
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`^C ^,`, and `^C ^R` commands.
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to that yields a proof of `suc n ≤ suc n`.
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The second thing to prove about comparison is that it is *transitive*:
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for any naturals `m`, `n`, and `p`, if `m ≤ n` and `n ≤ p` then `m ≤ p`.
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It is a good exercise to prove reflexivity interactively in Emacs,
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using holes and the `^C ^C`, `^C ^,`, and `^C ^R` commands.
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## Transitivity
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The second property to prove about comparison is that it is
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transitive: for any naturals `m`, `n`, andl `p`, if `m ≤ n` and `n ≤
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p` hold, then `m ≤ p` holds.
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\begin{code}
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trans≤ : ∀ {m n p : ℕ} → m ≤ n → n ≤ p → m ≤ p
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trans≤ z≤n _ = z≤n
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@ -142,24 +182,25 @@ trans≤ (s≤s m≤n) (s≤s n≤p) = s≤s (trans≤ m≤n n≤p)
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Here the proof is most easily thought of as by induction on the
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*evidence* that `m ≤ n`, so we have left `m`, `n`, and `p` implicit.
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In the base case, `m ≤ n` holds by `z≤n`, so it must be the case that
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In the base case, `m ≤ n` holds by `z≤n`, so it must be that
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`m` is `zero`, in which case `m ≤ p` also holds by `z≤n`. In this
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case, the fact that `n ≤ p` is irrelevant, and we write `_` as the
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pattern to indicate that the corresponding evidence is unused. We
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could instead have written `n≤p` but not used that variable on the
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right-hand side of the equation.
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In the inductive case, `m ≤ n` holds by `s≤s m≤n`, meaning that `m`
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must be of the form `suc m′` and `n` of the form `suc n′` and `m≤n` is
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In the inductive case, `m ≤ n` holds by `s≤s m≤n`, so it must be that `m`
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is of the form `suc m′` and `n` is of the form `suc n′` and `m≤n` is
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evidence that `m′ ≤ n′`. In this case, the only way that `p ≤ n` can
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hold is by `s≤s n≤p`, where `p` is of the form `suc p′` and `n≤p` is
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evidence that `n′ ≤ p′`. The inductive hypothesis `trans≤ m≤n n≤p`
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provides evidence that `m′ ≤ p′`, and applying `s≤s` to that gives
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evidence of the desired conclusion, `suc m′ ≤ suc p′`.
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Agda knows that the case `trans≤ (s≤s m≤n) z≤n` cannot arise, since
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the first piece of evidence implies `n` must be `suc n′` for some `n′`
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while the second implies `n` must be `zero`.
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The case `trans≤ (s≤s m≤n) z≤n` cannot arise, since the first piece of
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evidence implies `n` must be `suc n′` for some `n′` while the second
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implies `n` must be `zero`. Agda can determine that such a case cannot
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arise, and does not require it to be listed.
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Alternatively, we could make the implicit parameters explicit.
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\begin{code}
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@ -169,32 +210,52 @@ trans≤′ (suc m) (suc n) (suc p) (s≤s m≤n) (s≤s n≤p) = s≤s (trans
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\end{code}
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One might argue that this is clearer, since it shows us the forms of `m`, `n`,
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and `p`, or one might argue that the extra length obscures the essence of the
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proof. We will usually opt for shorter proofs.
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proof. We will usually opt for shorter proofs.
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The technique of inducting on evidence that a property holds (e.g.,
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inducting on evidence that `m ≤ n`)---rather than induction on the
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value of which the property holds (e.g., inducting on `m`)---will turn
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out to be immensely valuable, and one that we use often.
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Again, it is a good exercise to prove transitivity interactively in Emacs,
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using holes and the `^C ^C`, `^C ^,`, and `^C ^R` commands.
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## Antisymmetry
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The third thing to prove about comparison is that it is antisymmetric:
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for all naturals `m` and `n`, if both `m ≤ n` and `n ≤ m` hold, then
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`m ≡ n` holds.
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\begin{code}
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antisym≤ : ∀ {m n : ℕ} → m ≤ n → n ≤ m → m ≡ n
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antisym≤ z≤n z≤n = refl
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antisym≤ (s≤s m≤n) (s≤s n≤m) rewrite antisym≤ m≤n n≤m = refl
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\end{code}
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Again, the proof is by induction over the evidence that `m ≤ n`
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and `n ≤ m` hold, and so we have left `m` and `n` implicit.
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In the base case, both relations hold by `z≤n`,
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so it must be the case that both `m` and `n` are `zero`,
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in which case `m ≡ n` holds by reflexivity. (The reflexivity
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of equivlance, that is, not the reflexivity of comparison.)
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In the inductive case, `m ≤ n` holds by `s≤s m≤n` and `n ≤ m`
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holds by `s≤s n≤m`,
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The technique of inducting on evidence that a property holds---rather than
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induction on the value of which the property holds---will turn out to be
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immensely valuable, and one that we use often.
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Any ordering relation that is both reflexive and transitive is called
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a *partial order*, hence we have shown that "less than or equal" is a
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partial order. We will later show that it satisfies a stronger
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property, and is also a total order.
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a *preorder*, and any preorder that is also antisymmetric is a *partial order*.
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Hence, we have shown that "less than or equal" is a partial order. We will
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later show that it satisfies the strong property of being a *total order*.
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## Monotonicity
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can equally be regarded as by induction on `m` or by induction
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on the evidence that `m ≤ n`. If `m
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\begin{code}
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antisym≤ : ∀ {m n : ℕ} → m ≤ n → n ≤ m → m ≡ n
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antisym≤ z≤n z≤n = refl
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antisym≤ (s≤s m≤n) (s≤s n≤m) rewrite antisym≤ m≤n n≤m = refl
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mono+≤ : ∀ (m p q : ℕ) → p ≤ q → m + p ≤ m + q
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mono+≤ zero p q p≤q = p≤q
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mono+≤ (suc m) p q p≤q = s≤s (mono+≤ m p q p≤q)
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