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Require Import Zpower ZArith Znumtheory.
Require Import Crypto.Galois.Galois Crypto.Galois.GaloisTheory.
Require Import Crypto.Galois.GaloisField.
(* First, we define our prime in Z*)
Definition two_5_1 := (two_p 5) - 1.
Definition two_127_1 := (two_p 127) - 1.
(* Then proofs of their primality *)
Lemma two_5_1_prime : prime two_5_1.
Admitted.
Lemma two_127_1_prime : prime two_127_1.
Admitted.
(* And use those to make modulus modules *)
Module Modulus31 <: Modulus.
Definition modulus := exist _ two_5_1 two_5_1_prime.
End Modulus31.
Module Modulus127_1 <: Modulus.
Definition modulus := exist _ two_127_1 two_127_1_prime.
End Modulus127_1.
Module Example31.
(* Then we can construct a field with that modulus *)
Module Field := GaloisField Modulus31.
Import Field.
(* And pull in the appropriate notations *)
Local Open Scope GF_scope.
(* First, let's solve a ring example*)
Lemma ring_example: forall x: GF, x * 2 = x + x.
Proof.
intros.
ring.
Qed.
(* Then a field example (we have to know we can't divide by zero!) *)
Lemma field_example: forall x y z: GF, z <> 0 ->
x * (y / z) / z = x * y / (z ^ 2).
Proof.
intros; simpl.
field; trivial.
Qed.
(* Then an example with exponentiation *)
Lemma exp_example: forall x: GF, x ^ 2 + 2 * x + 1 = (x + 1) ^ 2.
Proof.
intros; simpl.
field; trivial.
Qed.
(* In general, the rule I've been using is:
- If our goal looks like x = y:
+ If we need to use assumptions to prove the goal, then before
we apply field,
* Perform all relevant substitutions (especially subst)
* If we have something more complex, we're probably going
to have to performe some sequence of "replace X with Y"
and solve out the subgoals manually before we can use
field.
+ Else, just use field directly
- If we just want to simplify terms and put them into a canonical
form, then field_simplify or ring_simplify should do the trick.
Note, however, that the canonical form has lots of annoying "/1"s
- Otherwise, do a "replace X with Y" to generate an equality
so that we can use field in the above case
*)
End Example31.
(* Notice that the field tactics work whether we know what the modulus is *)
Module TimesZeroTransparentTestModule.
Module Theory := GaloisField Modulus127_1.
Import Theory.
Local Open Scope GF_scope.
Lemma timesZero : forall a, a*0 = 0.
intros.
field.
Qed.
End TimesZeroTransparentTestModule.
(* Or if we don't (i.e. it's opaque) *)
Module TimesZeroParametricTestModule (M: Modulus).
Module Theory := GaloisField M.
Import Theory.
Local Open Scope GF_scope.
Lemma timesZero : forall a, a*0 = 0.
intros.
field.
Qed.
End TimesZeroParametricTestModule.
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