Library mathcomp.algebra.zmodp

(* (c) Copyright 2006-2015 Microsoft Corporation and Inria.
Distributed under the terms of CeCILL-B. *)
Require Import mathcomp.ssreflect.ssreflect.

Definition of the additive group and ring Zp, represented as 'I_p

Definitions: From fintype.v: 'I_p == the subtype of integers less than p, taken here as the type of the integers mod p. This file: inZp == the natural projection from nat into the integers mod p, represented as 'I_p. Here p is implicit, but MUST be of the form n.+1. The operations: Zp0 == the identity element for addition Zp1 == the identity element for multiplication, and a generator of additive group Zp_opp == inverse function for addition Zp_add == addition Zp_mul == multiplication Zp_inv == inverse function for multiplication Note that while 'I_n.+1 has canonical finZmodType and finGroupType structures, only 'I_n.+2 has a canonical ring structure (it has, in fact, a canonical finComUnitRing structure), and hence an associated multiplicative unit finGroupType. To mitigate the issues caused by the trivial "ring" (which is, indeed is NOT a ring in the ssralg/finalg formalization), we define additional notation: 'Z_p == the type of integers mod (max p 2); this is always a proper ring, by constructions. Note that 'Z_p is provably equal to 'I_p if p > 1, and convertible to 'I_p if p is of the form n.+2. Zp p == the subgroup of integers mod (max p 1) in 'Z_p; this is thus is thus all of 'Z_p if p > 1, and else the trivial group. units_Zp p == the group of all units of 'Z_p -- i.e., the group of (multiplicative) automorphisms of Zp p. We show that Zp and units_Zp are abelian, and compute their orders. We use a similar technique to represent the prime fields: 'F_p == the finite field of integers mod the first prime divisor of maxn p 2. This is provably equal to 'Z_p and 'I_p if p is provably prime, and indeed convertible to the above if p is a concrete prime such as 2, 5 or 23. Note finally that due to the canonical structures it is possible to use 0%R instead of Zp0, and 1%R instead of Zp1 (for the latter, p must be of the form n.+2, and 1%R : nat will simplify to 1%N).

Set Implicit Arguments.

Local Open Scope ring_scope.

Section ZpDef.

Mod p arithmetic on the finite set {0, 1, 2, ..., p - 1}

Variable p' : nat.

Implicit Types x y z : 'I_p.

Standard injection; val (inZp i) = i %% p

Definition inZp i := Ordinal (ltn_pmod i (ltn0Sn p')).
Lemma modZp x : x %% p = x.
Lemma valZpK x : inZp x = x.

Operations

Definition Zp0 : 'I_p := ord0.
Definition Zp1 := inZp 1.
Definition Zp_opp x := inZp (p - x).
Definition Zp_add x y := inZp (x + y).
Definition Zp_mul x y := inZp (x × y).
Definition Zp_inv x := if coprime p x then inZp (egcdn x p ).1 else x.

Additive group structure.

Lemma Zp_add0z : left_id Zp0 Zp_add.

Lemma Zp_addNz : left_inverse Zp0 Zp_opp Zp_add.

Lemma Zp_addA : associative Zp_add.

Lemma Zp_addC : commutative Zp_add.

Definition Zp_zmodMixin := ZmodMixin Zp_addA Zp_addC Zp_add0z Zp_addNz.
Canonical Zp_zmodType := Eval hnf in ZmodType 'I_p Zp_zmodMixin.
Canonical Zp_finZmodType := Eval hnf in [finZmodType of 'I_p ].
Canonical Zp_baseFinGroupType := Eval hnf in [baseFinGroupType of 'I_p for +%R ].
Canonical Zp_finGroupType := Eval hnf in [finGroupType of 'I_p for +%R ].

Ring operations

Lemma Zp_mul1z : left_id Zp1 Zp_mul.

Lemma Zp_mulC : commutative Zp_mul.

Lemma Zp_mulz1 : right_id Zp1 Zp_mul.

Lemma Zp_mulA : associative Zp_mul.

Lemma Zp_mul_addr : right_distributive Zp_mul Zp_add.

Lemma Zp_mul_addl : left_distributive Zp_mul Zp_add.

Lemma Zp_mulVz x : coprime p x → Zp_mul (Zp_inv x) x = Zp1.

Lemma Zp_mulzV x : coprime p x → Zp_mul x (Zp_inv x) = Zp1.

Lemma Zp_intro_unit x y : Zp_mul y x = Zp1 → coprime p x.

Lemma Zp_inv_out x : ~~ coprime p x → Zp_inv x = x.

Lemma Zp_mulrn x n : x *+ n = inZp (x × n).

Import GroupScope.

Lemma Zp_mulgC : @commutative 'I_p _ mulg.

Lemma Zp_abelian : abelian [set : 'I_p ].

Lemma Zp_expg x n : x ^+ n = inZp (x × n).

Lemma Zp1_expgz x : Zp1 ^+ x = x.

Lemma Zp_cycle : setT = <[Zp1 ]>.

Lemma order_Zp1 : #[Zp1 ] = p.

End ZpDef.

Implicit Arguments Zp0 [[p']].
Implicit Arguments Zp1 [[p']].
Implicit Arguments inZp [[p']].

Lemma ord1 : all_equal_to (0 : 'I_1).

Lemma lshift0 m n : lshift m (0 : 'I_n .+1) = (0 : 'I_(n + m ).+1 ).

Lemma rshift1 n : @rshift 1 n =1 lift (0 : 'I_n .+1).

Lemma split1 n i :
  split (i : 'I_(1 + n )) = oapp (@inr _ _) (inl _ 0) (unlift 0 i).

Lemma big_ord1 R idx (op : @Monoid.law R idx) F :
  \big [op /idx ]_(i < 1) F i = F 0.

Lemma big_ord1_cond R idx (op : @Monoid.law R idx) P F :
  \big [op /idx ]_(i < 1 | P i) F i = if P 0 then F 0 else idx.

Section ZpRing.

Variable p' : nat.

Lemma Zp_nontrivial : Zp1 != 0 :> 'I_p.

Definition Zp_ringMixin :=
  ComRingMixin (@Zp_mulA _) (@Zp_mulC _) (@Zp_mul1z _) (@Zp_mul_addl _)
               Zp_nontrivial.
Canonical Zp_ringType := Eval hnf in RingType 'I_p Zp_ringMixin.
Canonical Zp_finRingType := Eval hnf in [finRingType of 'I_p ].
Canonical Zp_comRingType := Eval hnf in ComRingType 'I_p (@Zp_mulC _).
Canonical Zp_finComRingType := Eval hnf in [finComRingType of 'I_p ].

Definition Zp_unitRingMixin :=
  ComUnitRingMixin (@Zp_mulVz _) (@Zp_intro_unit _) (@Zp_inv_out _).
Canonical Zp_unitRingType := Eval hnf in UnitRingType 'I_p Zp_unitRingMixin.
Canonical Zp_finUnitRingType := Eval hnf in [finUnitRingType of 'I_p ].
Canonical Zp_comUnitRingType := Eval hnf in [comUnitRingType of 'I_p ].
Canonical Zp_finComUnitRingType := Eval hnf in [finComUnitRingType of 'I_p ].

Lemma Zp_nat n : n %:R = inZp n :> 'I_p.

Lemma natr_Zp (x : 'I_p) : x %:R = x.

Lemma natr_negZp (x : 'I_p) : (- x )%:R = - x.

Import GroupScope.

Lemma unit_Zp_mulgC : @commutative {unit 'I_p } _ mulg.

Lemma unit_Zp_expg (u : {unit 'I_p }) n :
  val (u ^+ n) = inZp (val u ^ n) :> 'I_p.

End ZpRing.

Definition Zp_trunc p := p .-2.

Notation "''Z_' p" := 'I_(Zp_trunc p).+2
  (at level 8, p at level 2, format "''Z_' p") : type_scope.
Notation "''F_' p" := 'Z_(pdiv p)
  (at level 8, p at level 2, format "''F_' p") : type_scope.

Section Groups.

Variable p : nat.

Definition Zp := if p > 1 then [set : 'Z_p ] else 1%g.
Definition units_Zp := [set : {unit 'Z_p }].

Lemma Zp_cast : p > 1 → (Zp_trunc p ).+2 = p.

Lemma val_Zp_nat (p_gt1 : p > 1) n : (n %:R : 'Z_p ) = (n %% p)%N :> nat.

Lemma Zp_nat_mod (p_gt1 : p > 1)m : (m %% p )%:R = m %:R :> 'Z_p.

Lemma char_Zp : p > 1 → p %:R = 0 :> 'Z_p.

Lemma unitZpE x : p > 1 → ((x %:R : 'Z_p ) \is a GRing.unit ) = coprime p x.

Lemma Zp_group_set : group_set Zp.
Canonical Zp_group := Group Zp_group_set.

Lemma card_Zp : p > 0 → #|Zp | = p.

Lemma mem_Zp x : p > 1 → x \in Zp.

Canonical units_Zp_group := [group of units_Zp ].

Lemma card_units_Zp : p > 0 → #|units_Zp | = totient p.

Lemma units_Zp_abelian : abelian units_Zp.

End Groups.

Field structure for primes.

Section PrimeField.

Open Scope ring_scope.

Variable p : nat.

Section F_prime.

Hypothesis p_pr : prime p.

Lemma Fp_Zcast : (Zp_trunc (pdiv p)).+2 = (Zp_trunc p ).+2.

Lemma Fp_cast : (Zp_trunc (pdiv p)).+2 = p.

Lemma card_Fp : #|'F_p | = p.

Lemma val_Fp_nat n : (n %:R : 'F_p ) = (n %% p)%N :> nat.

Lemma Fp_nat_mod m : (m %% p )%:R = m %:R :> 'F_p.

Lemma char_Fp : p \in [char 'F_p ].

Lemma char_Fp_0 : p %:R = 0 :> 'F_p.

Lemma unitFpE x : ((x %:R : 'F_p ) \is a GRing.unit ) = coprime p x.

End F_prime.

Lemma Fp_fieldMixin : GRing.Field.mixin_of [the unitRingType of 'F_p ].

Definition Fp_idomainMixin := FieldIdomainMixin Fp_fieldMixin.

Canonical Fp_idomainType := Eval hnf in IdomainType 'F_p Fp_idomainMixin.
Canonical Fp_finIdomainType := Eval hnf in [finIdomainType of 'F_p ].
Canonical Fp_fieldType := Eval hnf in FieldType 'F_p Fp_fieldMixin.
Canonical Fp_finFieldType := Eval hnf in [finFieldType of 'F_p ].
Canonical Fp_decFieldType :=
Eval hnf in [decFieldType of 'F_p for Fp_finFieldType ].

End PrimeField.