Library Coq.Numbers.Cyclic.Int31.Int31
This library has been deprecated since Coq version 8.10.
Require Import NaryFunctions.
Require Import Wf_nat.
Require Export ZArith.
Require Export DoubleType.
31-bit integers
Digits
The type of 31-bit integers
The type int31 has a unique constructor I31 that expects
31 arguments of type digits.
Definition digits31 t := Eval compute in nfun digits size t.
Inductive int31 : Type := I31 : digits31 int31.
Scheme int31_ind := Induction for int31 Sort Prop.
Scheme int31_rec := Induction for int31 Sort Set.
Scheme int31_rect := Induction for int31 Sort Type.
Declare Scope int31_scope.
Delimit Scope int31_scope with int31.
Bind Scope int31_scope with int31.
Local Open Scope int31_scope.
One is I31 D0 ... D0 D1
The biggest integer is I31 D1 ... D1, corresponding to (2^size)-1
Two is I31 D0 ... D0 D1 D0
Bits manipulation
Definition sneakr : digits -> int31 -> int31 := Eval compute in
fun b => int31_rect _ (napply_except_last _ _ (size-1) (I31 b)).
sneakl b x shifts x to the left by one bit.
Leftmost digit is lost while rightmost digit becomes b.
Pseudo-code is
match x with (I31 d0 ... dN) => I31 d1 ... dN b end
Definition sneakl : digits -> int31 -> int31 := Eval compute in
fun b => int31_rect _ (fun _ => napply_then_last _ _ b (size-1) I31).
shiftl, shiftr, twice and twice_plus_one are direct
consequences of sneakl and sneakr.
Definition shiftl := sneakl D0.
Definition shiftr := sneakr D0.
Definition twice := sneakl D0.
Definition twice_plus_one := sneakl D1.
firstl x returns the leftmost digit of number x.
Pseudo-code is match x with (I31 d0 ... dN) => d0 end
Definition firstl : int31 -> digits := Eval compute in
int31_rect _ (fun d => napply_discard _ _ d (size-1)).
firstr x returns the rightmost digit of number x.
Pseudo-code is match x with (I31 d0 ... dN) => dN end
Definition firstr : int31 -> digits := Eval compute in
int31_rect _ (napply_discard _ _ (fun d=>d) (size-1)).
iszero x is true iff x = I31 D0 ... D0. Pseudo-code is
match x with (I31 D0 ... D0) => true | _ => false end
Definition iszero : int31 -> bool := Eval compute in
let f d b := match d with D0 => b | D1 => false end
in int31_rect _ (nfold_bis _ _ f true size).
base is 2^31, obtained via iterations of Z.double.
It can also be seen as the smallest b > 0 s.t. phi_inv b = 0
(see below)
Fixpoint recl_aux (n:nat)(A:Type)(case0:A)(caserec:digits->int31->A->A)
(i:int31) : A :=
match n with
| O => case0
| S next =>
if iszero i then
case0
else
let si := shiftl i in
caserec (firstl i) si (recl_aux next A case0 caserec si)
end.
Fixpoint recr_aux (n:nat)(A:Type)(case0:A)(caserec:digits->int31->A->A)
(i:int31) : A :=
match n with
| O => case0
| S next =>
if iszero i then
case0
else
let si := shiftr i in
caserec (firstr i) si (recr_aux next A case0 caserec si)
end.
Definition recl := recl_aux size.
Definition recr := recr_aux size.
Definition phi : int31 -> Z :=
recr Z (0%Z)
(fun b _ => match b with D0 => Z.double | D1 => Z.succ_double end).
From positive to int31. An abstract definition could be :
phi_inv (2n) = 2*(phi_inv n) /\
phi_inv 2n+1 = 2*(phi_inv n) + 1
Fixpoint phi_inv_positive p :=
match p with
| xI q => twice_plus_one (phi_inv_positive q)
| xO q => twice (phi_inv_positive q)
| xH => In
end.
The negative part : 2-complement
Fixpoint complement_negative p :=
match p with
| xI q => twice (complement_negative q)
| xO q => twice_plus_one (complement_negative q)
| xH => twice Tn
end.
A simple incrementation function
Definition incr : int31 -> int31 :=
recr int31 In
(fun b si rec => match b with
| D0 => sneakl D1 si
| D1 => sneakl D0 rec end).
We can now define the conversion from Z to int31.
Definition phi_inv : Z -> int31 := fun n =>
match n with
| Z0 => On
| Zpos p => phi_inv_positive p
| Zneg p => incr (complement_negative p)
end.
phi_inv_nonneg returns None if the Z is negative; this matches the old behavior of parsing int31 numerals
Definition phi_inv_nonneg : Z -> option int31 := fun n =>
match n with
| Zneg _ => None
| _ => Some (phi_inv n)
end.
match n with
| Zneg _ => None
| _ => Some (phi_inv n)
end.
phi_inv2 is similar to phi_inv but returns a double word
zn2z int31
phi2 is similar to phi but takes a double word (two args)
Definition add31 (n m : int31) := phi_inv ((phi n)+(phi m)).
Notation "n + m" := (add31 n m) : int31_scope.
Addition with carry (the result is thus exact)
Definition add31c (n m : int31) :=
let npm := n+m in
match (phi npm ?= (phi n)+(phi m))%Z with
| Eq => C0 npm
| _ => C1 npm
end.
Notation "n '+c' m" := (add31c n m) (at level 50, no associativity) : int31_scope.
Addition plus one with carry (the result is thus exact)
Definition add31carryc (n m : int31) :=
let npmpone_exact := ((phi n)+(phi m)+1)%Z in
let npmpone := phi_inv npmpone_exact in
match (phi npmpone ?= npmpone_exact)%Z with
| Eq => C0 npmpone
| _ => C1 npmpone
end.
Definition sub31 (n m : int31) := phi_inv ((phi n)-(phi m)).
Notation "n - m" := (sub31 n m) : int31_scope.
Subtraction with carry (thus exact)
Definition sub31c (n m : int31) :=
let nmm := n-m in
match (phi nmm ?= (phi n)-(phi m))%Z with
| Eq => C0 nmm
| _ => C1 nmm
end.
Notation "n '-c' m" := (sub31c n m) (at level 50, no associativity) : int31_scope.
subtraction minus one with carry (thus exact)
Definition sub31carryc (n m : int31) :=
let nmmmone_exact := ((phi n)-(phi m)-1)%Z in
let nmmmone := phi_inv nmmmone_exact in
match (phi nmmmone ?= nmmmone_exact)%Z with
| Eq => C0 nmmmone
| _ => C1 nmmmone
end.
Opposite
Multiplication
multiplication modulo 2^31
Definition mul31 (n m : int31) := phi_inv ((phi n)*(phi m)).
Notation "n * m" := (mul31 n m) : int31_scope.
multiplication with double word result (thus exact)
Definition mul31c (n m : int31) := phi_inv2 ((phi n)*(phi m)).
Notation "n '*c' m" := (mul31c n m) (at level 40, no associativity) : int31_scope.
Definition div3121 (nh nl m : int31) :=
let (q,r) := Z.div_eucl (phi2 nh nl) (phi m) in
(phi_inv q, phi_inv r).
Division modulo 2^31
Definition div31 (n m : int31) :=
let (q,r) := Z.div_eucl (phi n) (phi m) in
(phi_inv q, phi_inv r).
Notation "n / m" := (div31 n m) : int31_scope.
Definition compare31 (n m : int31) := ((phi n)?=(phi m))%Z.
Notation "n ?= m" := (compare31 n m) (at level 70, no associativity) : int31_scope.
Definition eqb31 (n m : int31) :=
match n ?= m with Eq => true | _ => false end.
Computing the i-th iterate of a function:
iter_int31 i A f = f^i
Definition iter_int31 i A f :=
recr (A->A) (fun x => x)
(fun b si rec => match b with
| D0 => fun x => rec (rec x)
| D1 => fun x => f (rec (rec x))
end)
i.
Combining the (31-p) low bits of i above the p high bits of j:
addmuldiv31 p i j = i*2^p+j/2^(31-p) (modulo 2^31)
Definition addmuldiv31 p i j :=
let (res, _ ) :=
iter_int31 p (int31*int31)
(fun ij => let (i,j) := ij in (sneakl (firstl j) i, shiftl j))
(i,j)
in
res.
Bitwise operations
Definition lor31 n m := phi_inv (Z.lor (phi n) (phi m)).
Definition land31 n m := phi_inv (Z.land (phi n) (phi m)).
Definition lxor31 n m := phi_inv (Z.lxor (phi n) (phi m)).
Definition lnot31 n := lxor31 Tn n.
Definition ldiff31 n m := land31 n (lnot31 m).
Fixpoint euler (guard:nat) (i j:int31) {struct guard} :=
match guard with
| O => In
| S p => match j ?= On with
| Eq => i
| _ => euler p j (let (_, r ) := i/j in r)
end
end.
Definition gcd31 (i j:int31) := euler (2*size)%nat i j.
Square root functions using newton iteration
we use a very naive upper-bound on the iteration
2^31 instead of the usual 31.
Definition sqrt31_step (rec: int31 -> int31 -> int31) (i j: int31) :=
Eval lazy delta [Twon] in
let (quo,_) := i/j in
match quo ?= j with
Lt => rec i (fst ((j + quo)/Twon))
| _ => j
end.
Fixpoint iter31_sqrt (n: nat) (rec: int31 -> int31 -> int31)
(i j: int31) {struct n} : int31 :=
sqrt31_step
(match n with
O => rec
| S n => (iter31_sqrt n (iter31_sqrt n rec))
end) i j.
Definition sqrt31 i :=
Eval lazy delta [On In Twon] in
match compare31 In i with
Gt => On
| Eq => In
| Lt => iter31_sqrt 31 (fun i j => j) i (fst (i/Twon))
end.
Definition v30 := Eval compute in (addmuldiv31 (phi_inv (Z.of_nat size - 1)) In On).
Definition sqrt312_step (rec: int31 -> int31 -> int31 -> int31)
(ih il j: int31) :=
Eval lazy delta [Twon v30] in
match ih ?= j with Eq => j | Gt => j | _ =>
let (quo,_) := div3121 ih il j in
match quo ?= j with
Lt => let m := match j +c quo with
C0 m1 => fst (m1/Twon)
| C1 m1 => fst (m1/Twon) + v30
end in rec ih il m
| _ => j
end end.
Fixpoint iter312_sqrt (n: nat)
(rec: int31 -> int31 -> int31 -> int31)
(ih il j: int31) {struct n} : int31 :=
sqrt312_step
(match n with
O => rec
| S n => (iter312_sqrt n (iter312_sqrt n rec))
end) ih il j.
Definition sqrt312 ih il :=
Eval lazy delta [On In] in
let s := iter312_sqrt 31 (fun ih il j => j) ih il Tn in
match s *c s with
W0 => (On, C0 On)
| WW ih1 il1 =>
match il -c il1 with
C0 il2 =>
match ih ?= ih1 with
Gt => (s, C1 il2)
| _ => (s, C0 il2)
end
| C1 il2 =>
match (ih - In) ?= ih1 with
Gt => (s, C1 il2)
| _ => (s, C0 il2)
end
end
end.
Fixpoint p2i n p : (N*int31)%type :=
match n with
| O => (Npos p, On)
| S n => match p with
| xO p => let (r,i) := p2i n p in (r, Twon*i)
| xI p => let (r,i) := p2i n p in (r, Twon*i+In)
| xH => (N0, In)
end
end.
Definition positive_to_int31 (p:positive) := p2i size p.
Constant 31 converted into type int31.
It is used as default answer for numbers of zeros
in head0 and tail0
Definition T31 : int31 := Eval compute in phi_inv (Z.of_nat size).
Definition head031 (i:int31) :=
recl _ (fun _ => T31)
(fun b si rec n => match b with
| D0 => rec (add31 n In)
| D1 => n
end)
i On.
Definition tail031 (i:int31) :=
recr _ (fun _ => T31)
(fun b si rec n => match b with
| D0 => rec (add31 n In)
| D1 => n
end)
i On.