Library Coq.Numbers.HexadecimalPos


HexadecimalPos

Proofs that conversions between hexadecimal numbers and positive are bijections.

Require Import Hexadecimal HexadecimalFacts PArith NArith.

Module Unsigned.

Local Open Scope N.

A direct version of of_little_uint
Fixpoint of_lu (d:uint) : N :=
  match d with
  | Nil => 0
  | D0 d => 0x10 * of_lu d
  | D1 d => 0x1 + 0x10 * of_lu d
  | D2 d => 0x2 + 0x10 * of_lu d
  | D3 d => 0x3 + 0x10 * of_lu d
  | D4 d => 0x4 + 0x10 * of_lu d
  | D5 d => 0x5 + 0x10 * of_lu d
  | D6 d => 0x6 + 0x10 * of_lu d
  | D7 d => 0x7 + 0x10 * of_lu d
  | D8 d => 0x8 + 0x10 * of_lu d
  | D9 d => 0x9 + 0x10 * of_lu d
  | Da d => 0xa + 0x10 * of_lu d
  | Db d => 0xb + 0x10 * of_lu d
  | Dc d => 0xc + 0x10 * of_lu d
  | Dd d => 0xd + 0x10 * of_lu d
  | De d => 0xe + 0x10 * of_lu d
  | Df d => 0xf + 0x10 * of_lu d
  end.

Definition hd d :=
  match d with
  | Nil => 0x0
  | D0 _ => 0x0
  | D1 _ => 0x1
  | D2 _ => 0x2
  | D3 _ => 0x3
  | D4 _ => 0x4
  | D5 _ => 0x5
  | D6 _ => 0x6
  | D7 _ => 0x7
  | D8 _ => 0x8
  | D9 _ => 0x9
  | Da _ => 0xa
  | Db _ => 0xb
  | Dc _ => 0xc
  | Dd _ => 0xd
  | De _ => 0xe
  | Df _ => 0xf
  end.

Definition tl d :=
  match d with
  | Nil => d
  | D0 d | D1 d | D2 d | D3 d | D4 d | D5 d | D6 d | D7 d | D8 d | D9 d
  | Da d | Db d | Dc d | Dd d | De d | Df d => d
  end.

Lemma of_lu_eqn d :
  of_lu d = hd d + 0x10 * (of_lu (tl d)).

Ltac simpl_of_lu :=
  match goal with
  | |- context [ of_lu (?f ?x) ] =>
    rewrite (of_lu_eqn (f x)); simpl hd; simpl tl
  end.

Fixpoint usize (d:uint) : N :=
  match d with
  | Nil => 0
  | D0 d => N.succ (usize d)
  | D1 d => N.succ (usize d)
  | D2 d => N.succ (usize d)
  | D3 d => N.succ (usize d)
  | D4 d => N.succ (usize d)
  | D5 d => N.succ (usize d)
  | D6 d => N.succ (usize d)
  | D7 d => N.succ (usize d)
  | D8 d => N.succ (usize d)
  | D9 d => N.succ (usize d)
  | Da d => N.succ (usize d)
  | Db d => N.succ (usize d)
  | Dc d => N.succ (usize d)
  | Dd d => N.succ (usize d)
  | De d => N.succ (usize d)
  | Df d => N.succ (usize d)
  end.

Lemma of_lu_revapp d d' :
  of_lu (revapp d d') =
    of_lu (rev d) + of_lu d' * 0x10^usize d.

Definition Nadd n p :=
  match n with
  | N0 => p
  | Npos p0 => (p0+p)%positive
  end.

Lemma Nadd_simpl n p q : Npos (Nadd n (p * q)) = n + Npos p * Npos q.

Lemma of_uint_acc_eqn d acc : d<>Nil ->
  Pos.of_hex_uint_acc d acc = Pos.of_hex_uint_acc (tl d) (Nadd (hd d) (0x10*acc)).

Lemma of_uint_acc_rev d acc :
  Npos (Pos.of_hex_uint_acc d acc) =
    of_lu (rev d) + (Npos acc) * 0x10^usize d.

Lemma of_uint_alt d : Pos.of_hex_uint d = of_lu (rev d).

Lemma of_lu_rev d : Pos.of_hex_uint (rev d) = of_lu d.

Lemma of_lu_double_gen d :
  of_lu (Little.double d) = N.double (of_lu d) /\
  of_lu (Little.succ_double d) = N.succ_double (of_lu d).

Lemma of_lu_double d :
  of_lu (Little.double d) = N.double (of_lu d).

Lemma of_lu_succ_double d :
  of_lu (Little.succ_double d) = N.succ_double (of_lu d).

First bijection result
The other direction

Definition to_lu n :=
  match n with
  | N0 => Hexadecimal.zero
  | Npos p => Pos.to_little_hex_uint p
  end.

Lemma succ_double_alt d :
  Little.succ_double d = Little.succ (Little.double d).

Lemma double_succ d :
  Little.double (Little.succ d) =
  Little.succ (Little.succ_double d).

Lemma to_lu_succ n :
  to_lu (N.succ n) = Little.succ (to_lu n).

Lemma nat_iter_S n {A} (f:A->A) i :
  Nat.iter (S n) f i = f (Nat.iter n f i).

Lemma nat_iter_0 {A} (f:A->A) i : Nat.iter 0 f i = i.

Lemma to_lhex_tenfold p :
  to_lu (0x10 * Npos p) = D0 (to_lu (Npos p)).

Lemma of_lu_0 d : of_lu d = 0 <-> nztail d = Nil.

Lemma to_of_lu_tenfold d :
  to_lu (of_lu d) = lnorm d ->
  to_lu (0x10 * of_lu d) = lnorm (D0 d).

Lemma Nadd_alt n m : n + m = Nat.iter (N.to_nat n) N.succ m.

Ltac simpl_to_nat := simpl N.to_nat; unfold Pos.to_nat; simpl Pos.iter_op.

Lemma to_of_lu d : to_lu (of_lu d) = lnorm d.

Second bijection result
Some consequences
Conversion from/to signed decimal numbers