From 97fefe1fcca363a1317e066e7f4b99b9c1e9987b Mon Sep 17 00:00:00 2001 From: Stephane Glondu Date: Thu, 12 Jan 2012 16:02:20 +0100 Subject: Imported Upstream version 8.4~beta --- theories/Numbers/Natural/BigN/NMake_gen.ml | 3511 ++++++++-------------------- 1 file changed, 923 insertions(+), 2588 deletions(-) (limited to 'theories/Numbers/Natural/BigN/NMake_gen.ml') diff --git a/theories/Numbers/Natural/BigN/NMake_gen.ml b/theories/Numbers/Natural/BigN/NMake_gen.ml index 67a62c40..59d440c3 100644 --- a/theories/Numbers/Natural/BigN/NMake_gen.ml +++ b/theories/Numbers/Natural/BigN/NMake_gen.ml @@ -1,6 +1,6 @@ (************************************************************************) (* v * The Coq Proof Assistant / The Coq Development Team *) -(* Z/2nZ process before relying on a generic construct *) -let gen_proof = true (* should we generate proofs ? *) - (*s Some utilities *) -let t = "t" -let c = "N" -let pz n = if n == 0 then "w_0" else "W0" -let rec gen2 n = if n == 0 then "1" else if n == 1 then "2" - else "2 * " ^ (gen2 (n - 1)) -let rec genxO n s = - if n == 0 then s else " (xO" ^ (genxO (n - 1) s) ^ ")" +let rec iter_str n s = if n = 0 then "" else (iter_str (n-1) s) ^ s -(* NB: in ocaml >= 3.10, we could use Printf.ifprintf for printing to - /dev/null, but for being compatible with earlier ocaml and not - relying on system-dependent stuff like open_out "/dev/null", - let's use instead a magical hack *) +let rec iter_str_gen n f = if n < 0 then "" else (iter_str_gen (n-1) f) ^ (f n) -(* Standard printer, with a final newline *) -let pr s = Printf.printf (s^^"\n") -(* Printing to /dev/null *) -let pn = (fun s -> Obj.magic (fun _ _ _ _ _ _ _ _ _ _ _ _ _ _ -> ()) - : ('a, out_channel, unit) format -> 'a) -(* Proof printer : prints iff gen_proof is true *) -let pp = if gen_proof then pr else pn -(* Printer for admitted parts : prints iff gen_proof is false *) -let pa = if not gen_proof then pr else pn -(* Same as before, but without the final newline *) -let pr0 = Printf.printf -let pp0 = if gen_proof then pr0 else pn +let rec iter_name i j base sep = + if i >= j then base^(string_of_int i) + else (iter_name i (j-1) base sep)^sep^" "^base^(string_of_int j) +let pr s = Printf.printf (s^^"\n") (*s The actual printing *) let _ = - pr "(************************************************************************)"; - pr "(* v * The Coq Proof Assistant / The Coq Development Team *)"; - pr "(* znz_op (zn2z w')."; + pr " Variable mk : forall w', ZnZ.Ops w' -> ZnZ.Ops (zn2z w')."; pr ""; - pr " Fixpoint make_op_aux (n:nat) : znz_op (word w%i (S n)):=" size; - pr " match n return znz_op (word w%i (S n)) with" size; + pr " Fixpoint make_op_aux (n:nat) : ZnZ.Ops (word w%i (S n)):=" size; + pr " match n return ZnZ.Ops (word w%i (S n)) with" size; pr " | O => w%i_op" (size+1); pr " | S n1 =>"; - pr " match n1 return znz_op (word w%i (S (S n1))) with" size; + pr " match n1 return ZnZ.Ops (word w%i (S (S n1))) with" size; pr " | O => w%i_op" (size+2); pr " | S n2 =>"; - pr " match n2 return znz_op (word w%i (S (S (S n2)))) with" size; + pr " match n2 return ZnZ.Ops (word w%i (S (S (S n2)))) with" size; pr " | O => w%i_op" (size+3); pr " | S n3 => mk _ (mk _ (mk _ (make_op_aux n3)))"; pr " end"; @@ -110,2565 +98,912 @@ let _ = pr ""; pr " End Make_op."; pr ""; - pr " Definition omake_op := make_op_aux mk_zn2z_op_karatsuba."; + pr " Definition omake_op := make_op_aux mk_zn2z_ops_karatsuba."; pr ""; pr ""; pr " Definition make_op_list := dmemo_list _ omake_op."; pr ""; - pr " Definition make_op n := dmemo_get _ omake_op n make_op_list."; - pr ""; - pr " Lemma make_op_omake: forall n, make_op n = omake_op n."; - pr " intros n; unfold make_op, make_op_list."; - pr " refine (dmemo_get_correct _ _ _)."; - pr " Qed."; + pr " Instance make_op n : ZnZ.Ops (word w%i (S n))" size; + pr " := dmemo_get _ omake_op n make_op_list."; pr ""; - pr " Inductive %s_ :=" t; - for i = 0 to size do - pr " | %s%i : w%i -> %s_" c i i t - done; - pr " | %sn : forall n, word w%i (S n) -> %s_." c size t; - pr ""; - pr " Definition %s := %s_." t t; - pr ""; - pr " Definition w_0 := w0_op.(znz_0)."; - pr ""; +pr " Ltac unfold_ops := unfold omake_op, make_op_aux, w%i_op, w%i_op." (size+3) (size+2); - for i = 0 to size do - pr " Definition one%i := w%i_op.(znz_1)." i i - done; - pr ""; +pr +" + Lemma make_op_omake: forall n, make_op n = omake_op n. + Proof. + intros n; unfold make_op, make_op_list. + refine (dmemo_get_correct _ _ _). + Qed. + Theorem make_op_S: forall n, + make_op (S n) = mk_zn2z_ops_karatsuba (make_op n). + Proof. + intros n. do 2 rewrite make_op_omake. + revert n. fix IHn 1. + do 3 (destruct n; [unfold_ops; reflexivity|]). + simpl mk_zn2z_ops_karatsuba. simpl word in *. + rewrite <- (IHn n). auto. + Qed. - pr " Definition zero := %s0 w_0." c; - pr " Definition one := %s0 one0." c; - pr ""; + (** * The main type [t], isomorphic with [exists n, word w0 n] *) +"; - pr " Definition to_Z x :="; - pr " match x with"; + pr " Inductive t' :="; for i = 0 to size do - pr " | %s%i wx => w%i_op.(znz_to_Z) wx" c i i + pr " | N%i : w%i -> t'" i i done; - pr " | %sn n wx => (make_op n).(znz_to_Z) wx" c; - pr " end."; + pr " | Nn : forall n, word w%i (S n) -> t'." size; pr ""; - - pr " Open Scope Z_scope."; - pr " Notation \"[ x ]\" := (to_Z x)."; - pr ""; - - pr " Definition to_N x := Zabs_N (to_Z x)."; + pr " Definition t := t'."; pr ""; - - pr " Definition eq x y := (to_Z x = to_Z y)."; - pr ""; - - pp " (* Regular make op (no karatsuba) *)"; - pp " Fixpoint nmake_op (ww:Type) (ww_op: znz_op ww) (n: nat) :"; - pp " znz_op (word ww n) :="; - pp " match n return znz_op (word ww n) with"; - pp " O => ww_op"; - pp " | S n1 => mk_zn2z_op (nmake_op ww ww_op n1)"; - pp " end."; - pp ""; - pp " (* Simplification by rewriting for nmake_op *)"; - pp " Theorem nmake_op_S: forall ww (w_op: znz_op ww) x,"; - pp " nmake_op _ w_op (S x) = mk_zn2z_op (nmake_op _ w_op x)."; - pp " auto."; - pp " Qed."; - pp ""; - - - pr " (* Eval and extend functions for each level *)"; - for i = 0 to size do - pp " Let nmake_op%i := nmake_op _ w%i_op." i i; - pp " Let eval%in n := znz_to_Z (nmake_op%i n)." i i; - if i == 0 then - pr " Let extend%i := DoubleBase.extend (WW w_0)." i - else - pr " Let extend%i := DoubleBase.extend (WW (W0: w%i))." i i; - done; + pr " Bind Scope abstract_scope with t t'."; pr ""; - - pp " Theorem digits_doubled:forall n ww (w_op: znz_op ww),"; - pp " znz_digits (nmake_op _ w_op n) ="; - pp " DoubleBase.double_digits (znz_digits w_op) n."; - pp " Proof."; - pp " intros n; elim n; auto; clear n."; - pp " intros n Hrec ww ww_op; simpl DoubleBase.double_digits."; - pp " rewrite <- Hrec; auto."; - pp " Qed."; - pp ""; - pp " Theorem nmake_double: forall n ww (w_op: znz_op ww),"; - pp " znz_to_Z (nmake_op _ w_op n) ="; - pp " @DoubleBase.double_to_Z _ (znz_digits w_op) (znz_to_Z w_op) n."; - pp " Proof."; - pp " intros n; elim n; auto; clear n."; - pp " intros n Hrec ww ww_op; simpl DoubleBase.double_to_Z; unfold zn2z_to_Z."; - pp " rewrite <- Hrec; auto."; - pp " unfold DoubleBase.double_wB; rewrite <- digits_doubled; auto."; - pp " Qed."; - pp ""; - - - pp " Theorem digits_nmake:forall n ww (w_op: znz_op ww),"; - pp " znz_digits (nmake_op _ w_op (S n)) ="; - pp " xO (znz_digits (nmake_op _ w_op n))."; - pp " Proof."; - pp " auto."; - pp " Qed."; - pp ""; - - - pp " Theorem znz_nmake_op: forall ww ww_op n xh xl,"; - pp " znz_to_Z (nmake_op ww ww_op (S n)) (WW xh xl) ="; - pp " znz_to_Z (nmake_op ww ww_op n) xh *"; - pp " base (znz_digits (nmake_op ww ww_op n)) +"; - pp " znz_to_Z (nmake_op ww ww_op n) xl."; - pp " Proof."; - pp " auto."; - pp " Qed."; - pp ""; - - pp " Theorem make_op_S: forall n,"; - pp " make_op (S n) = mk_zn2z_op_karatsuba (make_op n)."; - pp " intro n."; - pp " do 2 rewrite make_op_omake."; - pp " pattern n; apply lt_wf_ind; clear n."; - pp " intros n; case n; clear n."; - pp " intros _; unfold omake_op, make_op_aux, w%i_op; apply refl_equal." (size + 2); - pp " intros n; case n; clear n."; - pp " intros _; unfold omake_op, make_op_aux, w%i_op; apply refl_equal." (size + 3); - pp " intros n; case n; clear n."; - pp " intros _; unfold omake_op, make_op_aux, w%i_op, w%i_op; apply refl_equal." (size + 3) (size + 2); - pp " intros n Hrec."; - pp " change (omake_op (S (S (S (S n))))) with"; - pp " (mk_zn2z_op_karatsuba (mk_zn2z_op_karatsuba (mk_zn2z_op_karatsuba (omake_op (S n)))))."; - pp " change (omake_op (S (S (S n)))) with"; - pp " (mk_zn2z_op_karatsuba (mk_zn2z_op_karatsuba (mk_zn2z_op_karatsuba (omake_op n))))."; - pp " rewrite Hrec; auto with arith."; - pp " Qed."; - pp ""; - - - for i = 1 to size + 2 do - pp " Let znz_to_Z_%i: forall x y," i; - pp " znz_to_Z w%i_op (WW x y) =" i; - pp " znz_to_Z w%i_op x * base (znz_digits w%i_op) + znz_to_Z w%i_op y." (i-1) (i-1) (i-1); - pp " Proof."; - pp " auto."; - pp " Qed."; - pp ""; - done; - - pp " Let znz_to_Z_n: forall n x y,"; - pp " znz_to_Z (make_op (S n)) (WW x y) ="; - pp " znz_to_Z (make_op n) x * base (znz_digits (make_op n)) + znz_to_Z (make_op n) y."; - pp " Proof."; - pp " intros n x y; rewrite make_op_S; auto."; - pp " Qed."; - pp ""; - - pp " Let w0_spec: znz_spec w0_op := W0.w_spec."; - for i = 1 to 3 do - pp " Let w%i_spec: znz_spec w%i_op := mk_znz2_spec w%i_spec." i i (i-1) - done; - for i = 4 to size + 3 do - pp " Let w%i_spec : znz_spec w%i_op := mk_znz2_karatsuba_spec w%i_spec." i i (i-1) - done; - pp ""; - - pp " Let wn_spec: forall n, znz_spec (make_op n)."; - pp " intros n; elim n; clear n."; - pp " exact w%i_spec." (size + 1); - pp " intros n Hrec; rewrite make_op_S."; - pp " exact (mk_znz2_karatsuba_spec Hrec)."; - pp " Qed."; - pp ""; - - for i = 0 to size do - pr " Definition w%i_eq0 := w%i_op.(znz_eq0)." i i; - pr " Let spec_w%i_eq0: forall x, if w%i_eq0 x then [%s%i x] = 0 else True." i i c i; - pa " Admitted."; - pp " Proof."; - pp " intros x; unfold w%i_eq0, to_Z; generalize (spec_eq0 w%i_spec x);" i i; - pp " case znz_eq0; auto."; - pp " Qed."; - pr ""; - done; + pr " (** * A generic toolbox for building and deconstructing [t] *)"; pr ""; - - for i = 0 to size do - pp " Theorem digits_w%i: znz_digits w%i_op = znz_digits (nmake_op _ w0_op %i)." i i i; - if i == 0 then - pp " auto." - else - pp " rewrite digits_nmake; rewrite <- digits_w%i; auto." (i - 1); - pp " Qed."; - pp ""; - pp " Let spec_double_eval%in: forall n, eval%in n = DoubleBase.double_to_Z (znz_digits w%i_op) (znz_to_Z w%i_op) n." i i i i; - pp " Proof."; - pp " intros n; exact (nmake_double n w%i w%i_op)." i i; - pp " Qed."; - pp ""; - done; - - for i = 0 to size do - for j = 0 to (size - i) do - pp " Theorem digits_w%in%i: znz_digits w%i_op = znz_digits (nmake_op _ w%i_op %i)." i j (i + j) i j; - pp " Proof."; - if j == 0 then - if i == 0 then - pp " auto." - else - begin - pp " apply trans_equal with (xO (znz_digits w%i_op))." (i + j -1); - pp " auto."; - pp " unfold nmake_op; auto."; - end - else - begin - pp " apply trans_equal with (xO (znz_digits w%i_op))." (i + j -1); - pp " auto."; - pp " rewrite digits_nmake."; - pp " rewrite digits_w%in%i." i (j - 1); - pp " auto."; - end; - pp " Qed."; - pp ""; - pp " Let spec_eval%in%i: forall x, [%s%i x] = eval%in %i x." i j c (i + j) i j; - pp " Proof."; - if j == 0 then - pp " intros x; rewrite spec_double_eval%in; unfold DoubleBase.double_to_Z, to_Z; auto." i - else - begin - pp " intros x; case x."; - pp " auto."; - pp " intros xh xl; unfold to_Z; rewrite znz_to_Z_%i." (i + j); - pp " rewrite digits_w%in%i." i (j - 1); - pp " generalize (spec_eval%in%i); unfold to_Z; intros HH; repeat rewrite HH." i (j - 1); - pp " unfold eval%in, nmake_op%i." i i; - pp " rewrite (znz_nmake_op _ w%i_op %i); auto." i (j - 1); - end; - pp " Qed."; - if i + j <> size then - begin - pp " Let spec_extend%in%i: forall x, [%s%i x] = [%s%i (extend%i %i x)]." i (i + j + 1) c i c (i + j + 1) i j; - if j == 0 then - begin - pp " intros x; change (extend%i 0 x) with (WW (znz_0 w%i_op) x)." i (i + j); - pp " unfold to_Z; rewrite znz_to_Z_%i." (i + j + 1); - pp " rewrite (spec_0 w%i_spec); auto." (i + j); - end - else - begin - pp " intros x; change (extend%i %i x) with (WW (znz_0 w%i_op) (extend%i %i x))." i j (i + j) i (j - 1); - pp " unfold to_Z; rewrite znz_to_Z_%i." (i + j + 1); - pp " rewrite (spec_0 w%i_spec)." (i + j); - pp " generalize (spec_extend%in%i x); unfold to_Z." i (i + j); - pp " intros HH; rewrite <- HH; auto."; - end; - pp " Qed."; - pp ""; - end; - done; - - pp " Theorem digits_w%in%i: znz_digits w%i_op = znz_digits (nmake_op _ w%i_op %i)." i (size - i + 1) (size + 1) i (size - i + 1); - pp " Proof."; - pp " apply trans_equal with (xO (znz_digits w%i_op))." size; - pp " auto."; - pp " rewrite digits_nmake."; - pp " rewrite digits_w%in%i." i (size - i); - pp " auto."; - pp " Qed."; - pp ""; - - pp " Let spec_eval%in%i: forall x, [%sn 0 x] = eval%in %i x." i (size - i + 1) c i (size - i + 1); - pp " Proof."; - pp " intros x; case x."; - pp " auto."; - pp " intros xh xl; unfold to_Z; rewrite znz_to_Z_%i." (size + 1); - pp " rewrite digits_w%in%i." i (size - i); - pp " generalize (spec_eval%in%i); unfold to_Z; intros HH; repeat rewrite HH." i (size - i); - pp " unfold eval%in, nmake_op%i." i i; - pp " rewrite (znz_nmake_op _ w%i_op %i); auto." i (size - i); - pp " Qed."; - pp ""; - - pp " Let spec_eval%in%i: forall x, [%sn 1 x] = eval%in %i x." i (size - i + 2) c i (size - i + 2); - pp " intros x; case x."; - pp " auto."; - pp " intros xh xl; unfold to_Z; rewrite znz_to_Z_%i." (size + 2); - pp " rewrite digits_w%in%i." i (size + 1 - i); - pp " generalize (spec_eval%in%i); unfold to_Z; change (make_op 0) with (w%i_op); intros HH; repeat rewrite HH." i (size + 1 - i) (size + 1); - pp " unfold eval%in, nmake_op%i." i i; - pp " rewrite (znz_nmake_op _ w%i_op %i); auto." i (size + 1 - i); - pp " Qed."; - pp ""; - done; - - pp " Let digits_w%in: forall n," size; - pp " znz_digits (make_op n) = znz_digits (nmake_op _ w%i_op (S n))." size; - pp " intros n; elim n; clear n."; - pp " change (znz_digits (make_op 0)) with (xO (znz_digits w%i_op))." size; - pp " rewrite nmake_op_S; apply sym_equal; auto."; - pp " intros n Hrec."; - pp " replace (znz_digits (make_op (S n))) with (xO (znz_digits (make_op n)))."; - pp " rewrite Hrec."; - pp " rewrite nmake_op_S; apply sym_equal; auto."; - pp " rewrite make_op_S; apply sym_equal; auto."; - pp " Qed."; - pp ""; - - pp " Let spec_eval%in: forall n x, [%sn n x] = eval%in (S n) x." size c size; - pp " intros n; elim n; clear n."; - pp " exact spec_eval%in1." size; - pp " intros n Hrec x; case x; clear x."; - pp " unfold to_Z, eval%in, nmake_op%i." size size; - pp " rewrite make_op_S; rewrite nmake_op_S; auto."; - pp " intros xh xl."; - pp " unfold to_Z in Hrec |- *."; - pp " rewrite znz_to_Z_n."; - pp " rewrite digits_w%in." size; - pp " repeat rewrite Hrec."; - pp " unfold eval%in, nmake_op%i." size size; - pp " apply sym_equal; rewrite nmake_op_S; auto."; - pp " Qed."; - pp ""; - - pp " Let spec_extend%in: forall n x, [%s%i x] = [%sn n (extend%i n x)]." size c size c size ; - pp " intros n; elim n; clear n."; - pp " intros x; change (extend%i 0 x) with (WW (znz_0 w%i_op) x)." size size; - pp " unfold to_Z."; - pp " change (make_op 0) with w%i_op." (size + 1); - pp " rewrite znz_to_Z_%i; rewrite (spec_0 w%i_spec); auto." (size + 1) size; - pp " intros n Hrec x."; - pp " change (extend%i (S n) x) with (WW W0 (extend%i n x))." size size; - pp " unfold to_Z in Hrec |- *; rewrite znz_to_Z_n; auto."; - pp " rewrite <- Hrec."; - pp " replace (znz_to_Z (make_op n) W0) with 0; auto."; - pp " case n; auto; intros; rewrite make_op_S; auto."; - pp " Qed."; - pp ""; - - pr " Theorem spec_pos: forall x, 0 <= [x]."; - pa " Admitted."; - pp " Proof."; - pp " intros x; case x; clear x."; - for i = 0 to size do - pp " intros x; case (spec_to_Z w%i_spec x); auto." i; - done; - pp " intros n x; case (spec_to_Z (wn_spec n) x); auto."; - pp " Qed."; + pr " Local Notation SizePlus n := %sn%s." + (iter_str size "(S ") (iter_str size ")"); + pr " Local Notation Size := (SizePlus O)."; pr ""; - pp " Let spec_extendn_0: forall n wx, [%sn n (extend n _ wx)] = [%sn 0 wx]." c c; - pp " intros n; elim n; auto."; - pp " intros n1 Hrec wx; simpl extend; rewrite <- Hrec; auto."; - pp " unfold to_Z."; - pp " case n1; auto; intros n2; repeat rewrite make_op_S; auto."; - pp " Qed."; - pp ""; - pp " Let spec_extendn0_0: forall n wx, [%sn (S n) (WW W0 wx)] = [%sn n wx]." c c; - pp " Proof."; - pp " intros n x; unfold to_Z."; - pp " rewrite znz_to_Z_n."; - pp " rewrite <- (Zplus_0_l (znz_to_Z (make_op n) x))."; - pp " apply (f_equal2 Zplus); auto."; - pp " case n; auto."; - pp " intros n1; rewrite make_op_S; auto."; - pp " Qed."; - pp ""; - pp " Let spec_extend_tr: forall m n (w: word _ (S n)),"; - pp " [%sn (m + n) (extend_tr w m)] = [%sn n w]." c c; - pp " Proof."; - pp " induction m; auto."; - pp " intros n x; simpl extend_tr."; - pp " simpl plus; rewrite spec_extendn0_0; auto."; - pp " Qed."; - pp ""; - pp " Let spec_cast_l: forall n m x1,"; - pp " [%sn (Max.max n m)" c; - pp " (castm (diff_r n m) (extend_tr x1 (snd (diff n m))))] ="; - pp " [%sn n x1]." c; - pp " Proof."; - pp " intros n m x1; case (diff_r n m); simpl castm."; - pp " rewrite spec_extend_tr; auto."; - pp " Qed."; - pp ""; - pp " Let spec_cast_r: forall n m x1,"; - pp " [%sn (Max.max n m)" c; - pp " (castm (diff_l n m) (extend_tr x1 (fst (diff n m))))] ="; - pp " [%sn m x1]." c; - pp " Proof."; - pp " intros n m x1; case (diff_l n m); simpl castm."; - pp " rewrite spec_extend_tr; auto."; - pp " Qed."; - pp ""; - - - pr " Section LevelAndIter."; - pr ""; - pr " Variable res: Type."; - pr " Variable xxx: res."; - pr " Variable P: Z -> Z -> res -> Prop."; - pr " (* Abstraction function for each level *)"; - for i = 0 to size do - pr " Variable f%i: w%i -> w%i -> res." i i i; - pr " Variable f%in: forall n, w%i -> word w%i (S n) -> res." i i i; - pr " Variable fn%i: forall n, word w%i (S n) -> w%i -> res." i i i; - pp " Variable Pf%i: forall x y, P [%s%i x] [%s%i y] (f%i x y)." i c i c i i; - if i == size then - begin - pp " Variable Pf%in: forall n x y, P [%s%i x] (eval%in (S n) y) (f%in n x y)." i c i i i; - pp " Variable Pfn%i: forall n x y, P (eval%in (S n) x) [%s%i y] (fn%i n x y)." i i c i i; - end - else - begin - pp " Variable Pf%in: forall n x y, Z_of_nat n <= %i -> P [%s%i x] (eval%in (S n) y) (f%in n x y)." i (size - i) c i i i; - pp " Variable Pfn%i: forall n x y, Z_of_nat n <= %i -> P (eval%in (S n) x) [%s%i y] (fn%i n x y)." i (size - i) i c i i; - end; - pr ""; - done; - pr " Variable fnn: forall n, word w%i (S n) -> word w%i (S n) -> res." size size; - pp " Variable Pfnn: forall n x y, P [%sn n x] [%sn n y] (fnn n x y)." c c; - pr " Variable fnm: forall n m, word w%i (S n) -> word w%i (S m) -> res." size size; - pp " Variable Pfnm: forall n m x y, P [%sn n x] [%sn m y] (fnm n m x y)." c c; - pr ""; - pr " (* Special zero functions *)"; - pr " Variable f0t: t_ -> res."; - pp " Variable Pf0t: forall x, P 0 [x] (f0t x)."; - pr " Variable ft0: t_ -> res."; - pp " Variable Pft0: forall x, P [x] 0 (ft0 x)."; + pr " Tactic Notation \"do_size\" tactic(t) := do %i t." (size+1); pr ""; - - pr " (* We level the two arguments before applying *)"; - pr " (* the functions at each leval *)"; - pr " Definition same_level (x y: t_): res :="; - pr0 " Eval lazy zeta beta iota delta ["; - for i = 0 to size do - pr0 "extend%i " i; - done; - pr ""; - pr " DoubleBase.extend DoubleBase.extend_aux"; - pr " ] in"; - pr " match x, y with"; + pr " Definition dom_t n := match n with"; for i = 0 to size do - for j = 0 to i - 1 do - pr " | %s%i wx, %s%i wy => f%i wx (extend%i %i wy)" c i c j i j (i - j -1); - done; - pr " | %s%i wx, %s%i wy => f%i wx wy" c i c i i; - for j = i + 1 to size do - pr " | %s%i wx, %s%i wy => f%i (extend%i %i wx) wy" c i c j j i (j - i - 1); - done; - if i == size then - pr " | %s%i wx, %sn m wy => fnn m (extend%i m wx) wy" c size c size - else - pr " | %s%i wx, %sn m wy => fnn m (extend%i m (extend%i %i wx)) wy" c i c size i (size - i - 1); + pr " | %i => w%i" i i; done; - for i = 0 to size do - if i == size then - pr " | %sn n wx, %s%i wy => fnn n wx (extend%i n wy)" c c size size - else - pr " | %sn n wx, %s%i wy => fnn n wx (extend%i n (extend%i %i wy))" c c i size i (size - i - 1); - done; - pr " | %sn n wx, Nn m wy =>" c; - pr " let mn := Max.max n m in"; - pr " let d := diff n m in"; - pr " fnn mn"; - pr " (castm (diff_r n m) (extend_tr wx (snd d)))"; - pr " (castm (diff_l n m) (extend_tr wy (fst d)))"; - pr " end."; + pr " | %sn => word w%i n" (if size=0 then "" else "SizePlus ") size; + pr " end."; pr ""; - pp " Lemma spec_same_level: forall x y, P [x] [y] (same_level x y)."; - pp " Proof."; - pp " intros x; case x; clear x; unfold same_level."; - for i = 0 to size do - pp " intros x y; case y; clear y."; - for j = 0 to i - 1 do - pp " intros y; rewrite spec_extend%in%i; apply Pf%i." j i i; - done; - pp " intros y; apply Pf%i." i; - for j = i + 1 to size do - pp " intros y; rewrite spec_extend%in%i; apply Pf%i." i j j; - done; - if i == size then - pp " intros m y; rewrite (spec_extend%in m); apply Pfnn." size - else - pp " intros m y; rewrite spec_extend%in%i; rewrite (spec_extend%in m); apply Pfnn." i size size; - done; - pp " intros n x y; case y; clear y."; - for i = 0 to size do - if i == size then - pp " intros y; rewrite (spec_extend%in n); apply Pfnn." size - else - pp " intros y; rewrite spec_extend%in%i; rewrite (spec_extend%in n); apply Pfnn." i size size; - done; - pp " intros m y; rewrite <- (spec_cast_l n m x);"; - pp " rewrite <- (spec_cast_r n m y); apply Pfnn."; - pp " Qed."; - pp ""; - - pr " (* We level the two arguments before applying *)"; - pr " (* the functions at each level (special zero case) *)"; - pr " Definition same_level0 (x y: t_): res :="; - pr0 " Eval lazy zeta beta iota delta ["; - for i = 0 to size do - pr0 "extend%i " i; - done; - pr ""; - pr " DoubleBase.extend DoubleBase.extend_aux"; - pr " ] in"; - pr " match x with"; - for i = 0 to size do - pr " | %s%i wx =>" c i; - if i == 0 then - pr " if w0_eq0 wx then f0t y else"; - pr " match y with"; - for j = 0 to i - 1 do - pr " | %s%i wy =>" c j; - if j == 0 then - pr " if w0_eq0 wy then ft0 x else"; - pr " f%i wx (extend%i %i wy)" i j (i - j -1); - done; - pr " | %s%i wy => f%i wx wy" c i i; - for j = i + 1 to size do - pr " | %s%i wy => f%i (extend%i %i wx) wy" c j j i (j - i - 1); - done; - if i == size then - pr " | %sn m wy => fnn m (extend%i m wx) wy" c size - else - pr " | %sn m wy => fnn m (extend%i m (extend%i %i wx)) wy" c size i (size - i - 1); - pr" end"; - done; - pr " | %sn n wx =>" c; - pr " match y with"; - for i = 0 to size do - pr " | %s%i wy =>" c i; - if i == 0 then - pr " if w0_eq0 wy then ft0 x else"; - if i == size then - pr " fnn n wx (extend%i n wy)" size - else - pr " fnn n wx (extend%i n (extend%i %i wy))" size i (size - i - 1); - done; - pr " | %sn m wy =>" c; - pr " let mn := Max.max n m in"; - pr " let d := diff n m in"; - pr " fnn mn"; - pr " (castm (diff_r n m) (extend_tr wx (snd d)))"; - pr " (castm (diff_l n m) (extend_tr wy (fst d)))"; - pr " end"; - pr " end."; - pr ""; +pr +" Instance dom_op n : ZnZ.Ops (dom_t n) | 10. + Proof. + do_size (destruct n; [simpl;auto with *|]). + unfold dom_t. auto with *. + Defined. +"; - pp " Lemma spec_same_level0: forall x y, P [x] [y] (same_level0 x y)."; - pp " Proof."; - pp " intros x; case x; clear x; unfold same_level0."; - for i = 0 to size do - pp " intros x."; - if i == 0 then - begin - pp " generalize (spec_w0_eq0 x); case w0_eq0; intros H."; - pp " intros y; rewrite H; apply Pf0t."; - pp " clear H."; - end; - pp " intros y; case y; clear y."; - for j = 0 to i - 1 do - pp " intros y."; - if j == 0 then - begin - pp " generalize (spec_w0_eq0 y); case w0_eq0; intros H."; - pp " rewrite H; apply Pft0."; - pp " clear H."; - end; - pp " rewrite spec_extend%in%i; apply Pf%i." j i i; - done; - pp " intros y; apply Pf%i." i; - for j = i + 1 to size do - pp " intros y; rewrite spec_extend%in%i; apply Pf%i." i j j; - done; - if i == size then - pp " intros m y; rewrite (spec_extend%in m); apply Pfnn." size - else - pp " intros m y; rewrite spec_extend%in%i; rewrite (spec_extend%in m); apply Pfnn." i size size; - done; - pp " intros n x y; case y; clear y."; + pr " Definition iter_t {A:Type}(f : forall n, dom_t n -> A) : t -> A :="; for i = 0 to size do - pp " intros y."; - if i = 0 then - begin - pp " generalize (spec_w0_eq0 y); case w0_eq0; intros H."; - pp " rewrite H; apply Pft0."; - pp " clear H."; - end; - if i == size then - pp " rewrite (spec_extend%in n); apply Pfnn." size - else - pp " rewrite spec_extend%in%i; rewrite (spec_extend%in n); apply Pfnn." i size size; + pr " let f%i := f %i in" i i; done; - pp " intros m y; rewrite <- (spec_cast_l n m x);"; - pp " rewrite <- (spec_cast_r n m y); apply Pfnn."; - pp " Qed."; - pp ""; - - pr " (* We iter the smaller argument with the bigger *)"; - pr " Definition iter (x y: t_): res :="; - pr0 " Eval lazy zeta beta iota delta ["; + pr " let fn n := f (SizePlus (S n)) in"; + pr " fun x => match x with"; for i = 0 to size do - pr0 "extend%i " i; + pr " | N%i wx => f%i wx" i i; done; - pr ""; - pr " DoubleBase.extend DoubleBase.extend_aux"; - pr " ] in"; - pr " match x, y with"; - for i = 0 to size do - for j = 0 to i - 1 do - pr " | %s%i wx, %s%i wy => fn%i %i wx wy" c i c j j (i - j - 1); - done; - pr " | %s%i wx, %s%i wy => f%i wx wy" c i c i i; - for j = i + 1 to size do - pr " | %s%i wx, %s%i wy => f%in %i wx wy" c i c j i (j - i - 1); - done; - if i == size then - pr " | %s%i wx, %sn m wy => f%in m wx wy" c size c size - else - pr " | %s%i wx, %sn m wy => f%in m (extend%i %i wx) wy" c i c size i (size - i - 1); - done; - for i = 0 to size do - if i == size then - pr " | %sn n wx, %s%i wy => fn%i n wx wy" c c size size - else - pr " | %sn n wx, %s%i wy => fn%i n wx (extend%i %i wy)" c c i size i (size - i - 1); - done; - pr " | %sn n wx, %sn m wy => fnm n m wx wy" c c; + pr " | Nn n wx => fn n wx"; pr " end."; pr ""; - pp " Ltac zg_tac := try"; - pp " (red; simpl Zcompare; auto;"; - pp " let t := fresh \"H\" in (intros t; discriminate t))."; - pp ""; - pp " Lemma spec_iter: forall x y, P [x] [y] (iter x y)."; - pp " Proof."; - pp " intros x; case x; clear x; unfold iter."; - for i = 0 to size do - pp " intros x y; case y; clear y."; - for j = 0 to i - 1 do - pp " intros y; rewrite spec_eval%in%i; apply (Pfn%i %i); zg_tac." j (i - j) j (i - j - 1); - done; - pp " intros y; apply Pf%i." i; - for j = i + 1 to size do - pp " intros y; rewrite spec_eval%in%i; apply (Pf%in %i); zg_tac." i (j - i) i (j - i - 1); - done; - if i == size then - pp " intros m y; rewrite spec_eval%in; apply Pf%in." size size - else - pp " intros m y; rewrite spec_extend%in%i; rewrite spec_eval%in; apply Pf%in." i size size size; - done; - pp " intros n x y; case y; clear y."; - for i = 0 to size do - if i == size then - pp " intros y; rewrite spec_eval%in; apply Pfn%i." size size - else - pp " intros y; rewrite spec_extend%in%i; rewrite spec_eval%in; apply Pfn%i." i size size size; - done; - pp " intros m y; apply Pfnm."; - pp " Qed."; - pp ""; - - - pr " (* We iter the smaller argument with the bigger (zero case) *)"; - pr " Definition iter0 (x y: t_): res :="; - pr0 " Eval lazy zeta beta iota delta ["; - for i = 0 to size do - pr0 "extend%i " i; - done; - pr ""; - pr " DoubleBase.extend DoubleBase.extend_aux"; - pr " ] in"; - pr " match x with"; - for i = 0 to size do - pr " | %s%i wx =>" c i; - if i == 0 then - pr " if w0_eq0 wx then f0t y else"; - pr " match y with"; - for j = 0 to i - 1 do - pr " | %s%i wy =>" c j; - if j == 0 then - pr " if w0_eq0 wy then ft0 x else"; - pr " fn%i %i wx wy" j (i - j - 1); - done; - pr " | %s%i wy => f%i wx wy" c i i; - for j = i + 1 to size do - pr " | %s%i wy => f%in %i wx wy" c j i (j - i - 1); - done; - if i == size then - pr " | %sn m wy => f%in m wx wy" c size - else - pr " | %sn m wy => f%in m (extend%i %i wx) wy" c size i (size - i - 1); - pr " end"; - done; - pr " | %sn n wx =>" c; - pr " match y with"; + pr " Definition mk_t (n:nat) : dom_t n -> t :="; + pr " match n as n' return dom_t n' -> t with"; for i = 0 to size do - pr " | %s%i wy =>" c i; - if i == 0 then - pr " if w0_eq0 wy then ft0 x else"; - if i == size then - pr " fn%i n wx wy" size - else - pr " fn%i n wx (extend%i %i wy)" size i (size - i - 1); + pr " | %i => N%i" i i; done; - pr " | %sn m wy => fnm n m wx wy" c; - pr " end"; + pr " | %s(S n) => Nn n" (if size=0 then "" else "SizePlus "); pr " end."; pr ""; - pp " Lemma spec_iter0: forall x y, P [x] [y] (iter0 x y)."; - pp " Proof."; - pp " intros x; case x; clear x; unfold iter0."; - for i = 0 to size do - pp " intros x."; - if i == 0 then - begin - pp " generalize (spec_w0_eq0 x); case w0_eq0; intros H."; - pp " intros y; rewrite H; apply Pf0t."; - pp " clear H."; - end; - pp " intros y; case y; clear y."; - for j = 0 to i - 1 do - pp " intros y."; - if j == 0 then - begin - pp " generalize (spec_w0_eq0 y); case w0_eq0; intros H."; - pp " rewrite H; apply Pft0."; - pp " clear H."; - end; - pp " rewrite spec_eval%in%i; apply (Pfn%i %i); zg_tac." j (i - j) j (i - j - 1); - done; - pp " intros y; apply Pf%i." i; - for j = i + 1 to size do - pp " intros y; rewrite spec_eval%in%i; apply (Pf%in %i); zg_tac." i (j - i) i (j - i - 1); - done; - if i == size then - pp " intros m y; rewrite spec_eval%in; apply Pf%in." size size - else - pp " intros m y; rewrite spec_extend%in%i; rewrite spec_eval%in; apply Pf%in." i size size size; - done; - pp " intros n x y; case y; clear y."; - for i = 0 to size do - pp " intros y."; - if i = 0 then - begin - pp " generalize (spec_w0_eq0 y); case w0_eq0; intros H."; - pp " rewrite H; apply Pft0."; - pp " clear H."; - end; - if i == size then - pp " rewrite spec_eval%in; apply Pfn%i." size size - else - pp " rewrite spec_extend%in%i; rewrite spec_eval%in; apply Pfn%i." i size size size; - done; - pp " intros m y; apply Pfnm."; - pp " Qed."; - pp ""; - - - pr " End LevelAndIter."; - pr ""; +pr +" Definition level := iter_t (fun n _ => n). + Inductive View_t : t -> Prop := + Mk_t : forall n (x : dom_t n), View_t (mk_t n x). + + Lemma destr_t : forall x, View_t x. + Proof. + intros x. generalize (Mk_t (level x)). destruct x; simpl; auto. + Defined. + + Lemma iter_mk_t : forall A (f:forall n, dom_t n -> A), + forall n x, iter_t f (mk_t n x) = f n x. + Proof. + do_size (destruct n; try reflexivity). + Qed. + + (** * Projection to ZArith *) + + Definition to_Z : t -> Z := + Eval lazy beta iota delta [iter_t dom_t dom_op] in + iter_t (fun _ x => ZnZ.to_Z x). + + Notation \"[ x ]\" := (to_Z x). + + Theorem spec_mk_t : forall n (x:dom_t n), [mk_t n x] = ZnZ.to_Z x. + Proof. + intros. change to_Z with (iter_t (fun _ x => ZnZ.to_Z x)). + rewrite iter_mk_t; auto. + Qed. + + (** * Regular make op, without memoization or karatsuba + + This will normally never be used for actual computations, + but only for specification purpose when using + [word (dom_t n) m] intermediate values. *) + + Fixpoint nmake_op (ww:Type) (ww_op: ZnZ.Ops ww) (n: nat) : + ZnZ.Ops (word ww n) := + match n return ZnZ.Ops (word ww n) with + O => ww_op + | S n1 => mk_zn2z_ops (nmake_op ww ww_op n1) + end. + + Let eval n m := ZnZ.to_Z (Ops:=nmake_op _ (dom_op n) m). + + Theorem nmake_op_S: forall ww (w_op: ZnZ.Ops ww) x, + nmake_op _ w_op (S x) = mk_zn2z_ops (nmake_op _ w_op x). + Proof. + auto. + Qed. + + Theorem digits_nmake_S :forall n ww (w_op: ZnZ.Ops ww), + ZnZ.digits (nmake_op _ w_op (S n)) = + xO (ZnZ.digits (nmake_op _ w_op n)). + Proof. + auto. + Qed. + + Theorem digits_nmake : forall n ww (w_op: ZnZ.Ops ww), + ZnZ.digits (nmake_op _ w_op n) = Pos.shiftl_nat (ZnZ.digits w_op) n. + Proof. + induction n. auto. + intros ww ww_op. rewrite Pshiftl_nat_S, <- IHn; auto. + Qed. + + Theorem nmake_double: forall n ww (w_op: ZnZ.Ops ww), + ZnZ.to_Z (Ops:=nmake_op _ w_op n) = + @DoubleBase.double_to_Z _ (ZnZ.digits w_op) (ZnZ.to_Z (Ops:=w_op)) n. + Proof. + intros n; elim n; auto; clear n. + intros n Hrec ww ww_op; simpl DoubleBase.double_to_Z; unfold zn2z_to_Z. + rewrite <- Hrec; auto. + unfold DoubleBase.double_wB; rewrite <- digits_nmake; auto. + Qed. + + Theorem nmake_WW: forall ww ww_op n xh xl, + (ZnZ.to_Z (Ops:=nmake_op ww ww_op (S n)) (WW xh xl) = + ZnZ.to_Z (Ops:=nmake_op ww ww_op n) xh * + base (ZnZ.digits (nmake_op ww ww_op n)) + + ZnZ.to_Z (Ops:=nmake_op ww ww_op n) xl)%%Z. + Proof. + auto. + Qed. + + (** * The specification proofs for the word operators *) +"; + + if size <> 0 then + pr " Typeclasses Opaque %s." (iter_name 1 size "w" ""); + pr ""; + + pr " Instance w0_spec: ZnZ.Specs w0_op := W0.specs."; + for i = 1 to min 3 size do + pr " Instance w%i_spec: ZnZ.Specs w%i_op := mk_zn2z_specs w%i_spec." i i (i-1) + done; + for i = 4 to size do + pr " Instance w%i_spec: ZnZ.Specs w%i_op := mk_zn2z_specs_karatsuba w%i_spec." i i (i-1) + done; + pr " Instance w%i_spec: ZnZ.Specs w%i_op := mk_zn2z_specs_karatsuba w%i_spec." (size+1) (size+1) size; + + +pr " + Instance wn_spec (n:nat) : ZnZ.Specs (make_op n). + Proof. + induction n. + rewrite make_op_omake; simpl; auto with *. + rewrite make_op_S. exact (mk_zn2z_specs_karatsuba IHn). + Qed. + + Instance dom_spec n : ZnZ.Specs (dom_op n) | 10. + Proof. + do_size (destruct n; auto with *). apply wn_spec. + Qed. + + Let make_op_WW : forall n x y, + (ZnZ.to_Z (Ops:=make_op (S n)) (WW x y) = + ZnZ.to_Z (Ops:=make_op n) x * base (ZnZ.digits (make_op n)) + + ZnZ.to_Z (Ops:=make_op n) y)%%Z. + Proof. + intros n x y; rewrite make_op_S; auto. + Qed. + + (** * Zero *) + + Definition zero0 : w0 := ZnZ.zero. + + Definition zeron n : dom_t n := + match n with + | O => zero0 + | SizePlus (S n) => W0 + | _ => W0 + end. + + Lemma spec_zeron : forall n, ZnZ.to_Z (zeron n) = 0%%Z. + Proof. + do_size (destruct n; [exact ZnZ.spec_0|]). + destruct n; auto. simpl. rewrite make_op_S. exact ZnZ.spec_0. + Qed. + + (** * Digits *) + + Lemma digits_make_op_0 : forall n, + ZnZ.digits (make_op n) = Pos.shiftl_nat (ZnZ.digits (dom_op Size)) (S n). + Proof. + induction n. + auto. + replace (ZnZ.digits (make_op (S n))) with (xO (ZnZ.digits (make_op n))). + rewrite IHn; auto. + rewrite make_op_S; auto. + Qed. + + Lemma digits_make_op : forall n, + ZnZ.digits (make_op n) = Pos.shiftl_nat (ZnZ.digits w0_op) (SizePlus (S n)). + Proof. + intros. rewrite digits_make_op_0. + replace (SizePlus (S n)) with (S n + Size) by (rewrite <- plus_comm; auto). + rewrite Pshiftl_nat_plus. auto. + Qed. + + Lemma digits_dom_op : forall n, + ZnZ.digits (dom_op n) = Pos.shiftl_nat (ZnZ.digits w0_op) n. + Proof. + do_size (destruct n; try reflexivity). + exact (digits_make_op n). + Qed. + + Lemma digits_dom_op_nmake : forall n m, + ZnZ.digits (dom_op (m+n)) = ZnZ.digits (nmake_op _ (dom_op n) m). + Proof. + intros. rewrite digits_nmake, 2 digits_dom_op. apply Pshiftl_nat_plus. + Qed. + + (** * Conversion between [zn2z (dom_t n)] and [dom_t (S n)]. + + These two types are provably equal, but not convertible, + hence we need some work. We now avoid using generic casts + (i.e. rewrite via proof of equalities in types), since + proving things with them is a mess. + *) + + Definition succ_t n : zn2z (dom_t n) -> dom_t (S n) := + match n with + | SizePlus (S _) => fun x => x + | _ => fun x => x + end. + + Lemma spec_succ_t : forall n x, + ZnZ.to_Z (succ_t n x) = + zn2z_to_Z (base (ZnZ.digits (dom_op n))) ZnZ.to_Z x. + Proof. + do_size (destruct n ; [reflexivity|]). + intros. simpl. rewrite make_op_S. simpl. auto. + Qed. + + Definition pred_t n : dom_t (S n) -> zn2z (dom_t n) := + match n with + | SizePlus (S _) => fun x => x + | _ => fun x => x + end. + + Lemma succ_pred_t : forall n x, succ_t n (pred_t n x) = x. + Proof. + do_size (destruct n ; [reflexivity|]). reflexivity. + Qed. + + (** We can hence project from [zn2z (dom_t n)] to [t] : *) + + Definition mk_t_S n (x : zn2z (dom_t n)) : t := + mk_t (S n) (succ_t n x). + + Lemma spec_mk_t_S : forall n x, + [mk_t_S n x] = zn2z_to_Z (base (ZnZ.digits (dom_op n))) ZnZ.to_Z x. + Proof. + intros. unfold mk_t_S. rewrite spec_mk_t. apply spec_succ_t. + Qed. + + Lemma mk_t_S_level : forall n x, level (mk_t_S n x) = S n. + Proof. + intros. unfold mk_t_S, level. rewrite iter_mk_t; auto. + Qed. + + (** * Conversion from [word (dom_t n) m] to [dom_t (m+n)]. + + Things are more complex here. We start with a naive version + that breaks zn2z-trees and reconstruct them. Doing this is + quite unfortunate, but I don't know how to fully avoid that. + (cast someday ?). Then we build an optimized version where + all basic cases (n<=6 or m<=7) are nicely handled. + *) + + Definition zn2z_map {A} {B} (f:A->B) (x:zn2z A) : zn2z B := + match x with + | W0 => W0 + | WW h l => WW (f h) (f l) + end. + + Lemma zn2z_map_id : forall A f (x:zn2z A), (forall u, f u = u) -> + zn2z_map f x = x. + Proof. + destruct x; auto; intros. + simpl; f_equal; auto. + Qed. + + (** The naive version *) + + Fixpoint plus_t n m : word (dom_t n) m -> dom_t (m+n) := + match m as m' return word (dom_t n) m' -> dom_t (m'+n) with + | O => fun x => x + | S m => fun x => succ_t _ (zn2z_map (plus_t n m) x) + end. + + Theorem spec_plus_t : forall n m (x:word (dom_t n) m), + ZnZ.to_Z (plus_t n m x) = eval n m x. + Proof. + unfold eval. + induction m. + simpl; auto. + intros. + simpl plus_t; simpl plus. rewrite spec_succ_t. + destruct x. + simpl; auto. + fold word in w, w0. + simpl. rewrite 2 IHm. f_equal. f_equal. f_equal. + apply digits_dom_op_nmake. + Qed. + + Definition mk_t_w n m (x:word (dom_t n) m) : t := + mk_t (m+n) (plus_t n m x). + + Theorem spec_mk_t_w : forall n m (x:word (dom_t n) m), + [mk_t_w n m x] = eval n m x. + Proof. + intros. unfold mk_t_w. rewrite spec_mk_t. apply spec_plus_t. + Qed. + + (** The optimized version. + + NB: the last particular case for m could depend on n, + but it's simplier to just expand everywhere up to m=7 + (cf [mk_t_w'] later). + *) + + Definition plus_t' n : forall m, word (dom_t n) m -> dom_t (m+n) := + match n return (forall m, word (dom_t n) m -> dom_t (m+n)) with + | SizePlus (S n') as n => plus_t n + | _ as n => + fun m => match m return (word (dom_t n) m -> dom_t (m+n)) with + | SizePlus (S (S m')) as m => plus_t n m + | _ => fun x => x + end + end. + + Lemma plus_t_equiv : forall n m x, + plus_t' n m x = plus_t n m x. + Proof. + (do_size try destruct n); try reflexivity; + (do_size try destruct m); try destruct m; try reflexivity; + simpl; symmetry; repeat (intros; apply zn2z_map_id; trivial). + Qed. + + Lemma spec_plus_t' : forall n m x, + ZnZ.to_Z (plus_t' n m x) = eval n m x. + Proof. + intros; rewrite plus_t_equiv. apply spec_plus_t. + Qed. + + (** Particular cases [Nk x] = eval i j x with specific k,i,j + can be solved by the following tactic *) + + Ltac solve_eval := + intros; rewrite <- spec_plus_t'; unfold to_Z; simpl dom_op; reflexivity. + + (** The last particular case that remains useful *) + + Lemma spec_eval_size : forall n x, [Nn n x] = eval Size (S n) x. + Proof. + induction n. + solve_eval. + destruct x as [ | xh xl ]. + simpl. unfold eval. rewrite make_op_S. rewrite nmake_op_S. auto. + simpl word in xh, xl |- *. + unfold to_Z in *. rewrite make_op_WW. + unfold eval in *. rewrite nmake_WW. + f_equal; auto. + f_equal; auto. + f_equal. + rewrite <- digits_dom_op_nmake. rewrite plus_comm; auto. + Qed. + + (** An optimized [mk_t_w]. + + We could say mk_t_w' := mk_t _ (plus_t' n m x) + (TODO: WHY NOT, BTW ??). + Instead we directly define functions for all intersting [n], + reverting to naive [mk_t_w] at places that should normally + never be used (see [mul] and [div_gt]). + *) +"; + +for i = 0 to size-1 do +let pattern = (iter_str (size+1-i) "(S ") ^ "_" ^ (iter_str (size+1-i) ")") in +pr +" Let mk_t_%iw m := Eval cbv beta zeta iota delta [ mk_t plus ] in + match m return word w%i (S m) -> t with + | %s as p => mk_t_w %i (S p) + | p => mk_t (%i+p) + end. +" i i pattern i (i+1) +done; + +pr +" Let mk_t_w' n : forall m, word (dom_t n) (S m) -> t := + match n return (forall m, word (dom_t n) (S m) -> t) with"; +for i = 0 to size-1 do pr " | %i => mk_t_%iw" i i done; +pr +" | Size => Nn + | _ as n' => fun m => mk_t_w n' (S m) + end. +"; + +pr +" Ltac solve_spec_mk_t_w' := + rewrite <- spec_plus_t'; + match goal with _ : word (dom_t ?n) ?m |- _ => apply (spec_mk_t (n+m)) end. + + Theorem spec_mk_t_w' : + forall n m x, [mk_t_w' n m x] = eval n (S m) x. + Proof. + intros. + repeat (apply spec_mk_t_w || (destruct n; + [repeat (apply spec_mk_t_w || (destruct m; [solve_spec_mk_t_w'|]))|])). + apply spec_eval_size. + Qed. + + (** * Extend : injecting [dom_t n] into [word (dom_t n) (S m)] *) + + Definition extend n m (x:dom_t n) : word (dom_t n) (S m) := + DoubleBase.extend_aux m (WW (zeron n) x). + + Lemma spec_extend : forall n m x, + [mk_t n x] = eval n (S m) (extend n m x). + Proof. + intros. unfold eval, extend. + rewrite spec_mk_t. + assert (H : forall (x:dom_t n), + (ZnZ.to_Z (zeron n) * base (ZnZ.digits (dom_op n)) + ZnZ.to_Z x = + ZnZ.to_Z x)%%Z). + clear; intros; rewrite spec_zeron; auto. + rewrite <- (@DoubleBase.spec_extend _ + (WW (zeron n)) (ZnZ.digits (dom_op n)) ZnZ.to_Z H m x). + simpl. rewrite digits_nmake, <- nmake_double. auto. + Qed. + + (** A particular case of extend, used in [same_level]: + [extend_size] is [extend Size] *) + + Definition extend_size := DoubleBase.extend (WW (W0:dom_t Size)). + + Lemma spec_extend_size : forall n x, [mk_t Size x] = [Nn n (extend_size n x)]. + Proof. + intros. rewrite spec_eval_size. apply (spec_extend Size n). + Qed. + + (** Misc results about extensions *) + + Let spec_extend_WW : forall n x, + [Nn (S n) (WW W0 x)] = [Nn n x]. + Proof. + intros n x. + set (N:=SizePlus (S n)). + change ([Nn (S n) (extend N 0 x)]=[mk_t N x]). + rewrite (spec_extend N 0). + solve_eval. + Qed. + + Let spec_extend_tr: forall m n w, + [Nn (m + n) (extend_tr w m)] = [Nn n w]. + Proof. + induction m; auto. + intros n x; simpl extend_tr. + simpl plus; rewrite spec_extend_WW; auto. + Qed. + + Let spec_cast_l: forall n m x1, + [Nn n x1] = + [Nn (Max.max n m) (castm (diff_r n m) (extend_tr x1 (snd (diff n m))))]. + Proof. + intros n m x1; case (diff_r n m); simpl castm. + rewrite spec_extend_tr; auto. + Qed. + + Let spec_cast_r: forall n m x1, + [Nn m x1] = + [Nn (Max.max n m) (castm (diff_l n m) (extend_tr x1 (fst (diff n m))))]. + Proof. + intros n m x1; case (diff_l n m); simpl castm. + rewrite spec_extend_tr; auto. + Qed. + + Ltac unfold_lets := + match goal with + | h : _ |- _ => unfold h; clear h; unfold_lets + | _ => idtac + end. + + (** * [same_level] + + Generic binary operator construction, by extending the smaller + argument to the level of the other. + *) + + Section SameLevel. + + Variable res: Type. + Variable P : Z -> Z -> res -> Prop. + Variable f : forall n, dom_t n -> dom_t n -> res. + Variable Pf : forall n x y, P (ZnZ.to_Z x) (ZnZ.to_Z y) (f n x y). +"; + +for i = 0 to size do +pr " Let f%i : w%i -> w%i -> res := f %i." i i i i +done; +pr +" Let fn n := f (SizePlus (S n)). + + Let Pf' : + forall n x y u v, u = [mk_t n x] -> v = [mk_t n y] -> P u v (f n x y). + Proof. + intros. subst. rewrite 2 spec_mk_t. apply Pf. + Qed. +"; + +let ext i j s = + if j <= i then s else Printf.sprintf "(extend %i %i %s)" i (j-i-1) s +in + +pr " Notation same_level_folded := (fun x y => match x, y with"; +for i = 0 to size do + for j = 0 to size do + pr " | N%i wx, N%i wy => f%i %s %s" i j (max i j) (ext i j "wx") (ext j i "wy") + done; + pr " | N%i wx, Nn m wy => fn m (extend_size m %s) wy" i (ext i size "wx") +done; +for i = 0 to size do + pr " | Nn n wx, N%i wy => fn n wx (extend_size n %s)" i (ext i size "wy") +done; +pr +" | Nn n wx, Nn m wy => + let mn := Max.max n m in + let d := diff n m in + fn mn + (castm (diff_r n m) (extend_tr wx (snd d))) + (castm (diff_l n m) (extend_tr wy (fst d))) + end). +"; + +pr +" Definition same_level := Eval lazy beta iota delta + [ DoubleBase.extend DoubleBase.extend_aux extend zeron ] + in same_level_folded. + + Lemma spec_same_level_0: forall x y, P [x] [y] (same_level x y). + Proof. + change same_level with same_level_folded. unfold_lets. + destruct x, y; apply Pf'; simpl mk_t; rewrite <- ?spec_extend_size; + match goal with + | |- context [ extend ?n ?m _ ] => apply (spec_extend n m) + | |- context [ castm _ _ ] => apply spec_cast_l || apply spec_cast_r + | _ => reflexivity + end. + Qed. + + End SameLevel. + + Arguments same_level [res] f x y. + + Theorem spec_same_level_dep : + forall res + (P : nat -> Z -> Z -> res -> Prop) + (Pantimon : forall n m z z' r, n <= m -> P m z z' r -> P n z z' r) + (f : forall n, dom_t n -> dom_t n -> res) + (Pf: forall n x y, P n (ZnZ.to_Z x) (ZnZ.to_Z y) (f n x y)), + forall x y, P (level x) [x] [y] (same_level f x y). + Proof. + intros res P Pantimon f Pf. + set (f' := fun n x y => (n, f n x y)). + set (P' := fun z z' r => P (fst r) z z' (snd r)). + assert (FST : forall x y, level x <= fst (same_level f' x y)) + by (destruct x, y; simpl; omega with * ). + assert (SND : forall x y, same_level f x y = snd (same_level f' x y)) + by (destruct x, y; reflexivity). + intros. eapply Pantimon; [eapply FST|]. + rewrite SND. eapply (@spec_same_level_0 _ P' f'); eauto. + Qed. + + (** * [iter] + + Generic binary operator construction, by splitting the larger + argument in blocks and applying the smaller argument to them. + *) + + Section Iter. + + Variable res: Type. + Variable P: Z -> Z -> res -> Prop. + + Variable f : forall n, dom_t n -> dom_t n -> res. + Variable Pf : forall n x y, P (ZnZ.to_Z x) (ZnZ.to_Z y) (f n x y). + + Variable fd : forall n m, dom_t n -> word (dom_t n) (S m) -> res. + Variable fg : forall n m, word (dom_t n) (S m) -> dom_t n -> res. + Variable Pfd : forall n m x y, P (ZnZ.to_Z x) (eval n (S m) y) (fd n m x y). + Variable Pfg : forall n m x y, P (eval n (S m) x) (ZnZ.to_Z y) (fg n m x y). + + Variable fnm: forall n m, word (dom_t Size) (S n) -> word (dom_t Size) (S m) -> res. + Variable Pfnm: forall n m x y, P [Nn n x] [Nn m y] (fnm n m x y). + + Let Pf' : + forall n x y u v, u = [mk_t n x] -> v = [mk_t n y] -> P u v (f n x y). + Proof. + intros. subst. rewrite 2 spec_mk_t. apply Pf. + Qed. + + Let Pfd' : forall n m x y u v, u = [mk_t n x] -> v = eval n (S m) y -> + P u v (fd n m x y). + Proof. + intros. subst. rewrite spec_mk_t. apply Pfd. + Qed. + + Let Pfg' : forall n m x y u v, u = eval n (S m) x -> v = [mk_t n y] -> + P u v (fg n m x y). + Proof. + intros. subst. rewrite spec_mk_t. apply Pfg. + Qed. +"; + +for i = 0 to size do +pr " Let f%i := f %i." i i +done; + +for i = 0 to size do +pr " Let f%in := fd %i." i i; +pr " Let fn%i := fg %i." i i; +done; + +pr " Notation iter_folded := (fun x y => match x, y with"; +for i = 0 to size do + for j = 0 to size do + pr " | N%i wx, N%i wy => f%s wx wy" i j + (if i = j then string_of_int i + else if i < j then string_of_int i ^ "n " ^ string_of_int (j-i-1) + else "n" ^ string_of_int j ^ " " ^ string_of_int (i-j-1)) + done; + pr " | N%i wx, Nn m wy => f%in m %s wy" i size (ext i size "wx") +done; +for i = 0 to size do + pr " | Nn n wx, N%i wy => fn%i n wx %s" i size (ext i size "wy") +done; +pr +" | Nn n wx, Nn m wy => fnm n m wx wy + end). +"; + +pr +" Definition iter := Eval lazy beta iota delta + [extend DoubleBase.extend DoubleBase.extend_aux zeron] + in iter_folded. + + Lemma spec_iter: forall x y, P [x] [y] (iter x y). + Proof. + change iter with iter_folded; unfold_lets. + destruct x; destruct y; apply Pf' || apply Pfd' || apply Pfg' || apply Pfnm; + simpl mk_t; + match goal with + | |- ?x = ?x => reflexivity + | |- [Nn _ _] = _ => apply spec_eval_size + | |- context [extend ?n ?m _] => apply (spec_extend n m) + | _ => idtac + end; + unfold to_Z; rewrite <- spec_plus_t'; simpl dom_op; reflexivity. + Qed. + + End Iter. +"; + +pr +" Definition switch + (P:nat->Type)%s + (fn:forall n, P n) n := + match n return P n with" + (iter_str_gen size (fun i -> Printf.sprintf "(f%i:P %i)" i i)); +for i = 0 to size do pr " | %i => f%i" i i done; +pr +" | n => fn n + end. +"; + +pr +" Lemma spec_switch : forall P (f:forall n, P n) n, + switch P %sf n = f n. + Proof. + repeat (destruct n; try reflexivity). + Qed. +" (iter_str_gen size (fun i -> Printf.sprintf "(f %i) " i)); + +pr +" (** * [iter_sym] + + A variant of [iter] for symmetric functions, or pseudo-symmetric + functions (when f y x can be deduced from f x y). + *) + + Section IterSym. + + Variable res: Type. + Variable P: Z -> Z -> res -> Prop. + + Variable f : forall n, dom_t n -> dom_t n -> res. + Variable Pf : forall n x y, P (ZnZ.to_Z x) (ZnZ.to_Z y) (f n x y). + + Variable fg : forall n m, word (dom_t n) (S m) -> dom_t n -> res. + Variable Pfg : forall n m x y, P (eval n (S m) x) (ZnZ.to_Z y) (fg n m x y). + + Variable fnm: forall n m, word (dom_t Size) (S n) -> word (dom_t Size) (S m) -> res. + Variable Pfnm: forall n m x y, P [Nn n x] [Nn m y] (fnm n m x y). + + Variable opp: res -> res. + Variable Popp : forall u v r, P u v r -> P v u (opp r). +"; + +for i = 0 to size do +pr " Let f%i := f %i." i i +done; + +for i = 0 to size do +pr " Let fn%i := fg %i." i i; +done; + +pr " Let f' := switch _ %s f." (iter_name 0 size "f" ""); +pr " Let fg' := switch _ %s fg." (iter_name 0 size "fn" ""); + +pr +" Local Notation iter_sym_folded := + (iter res f' (fun n m x y => opp (fg' n m y x)) fg' fnm). + + Definition iter_sym := + Eval lazy beta zeta iota delta [iter f' fg' switch] in iter_sym_folded. + + Lemma spec_iter_sym: forall x y, P [x] [y] (iter_sym x y). + Proof. + intros. change iter_sym with iter_sym_folded. apply spec_iter; clear x y. + unfold_lets. + intros. rewrite spec_switch. auto. + intros. apply Popp. unfold_lets. rewrite spec_switch; auto. + intros. unfold_lets. rewrite spec_switch; auto. + auto. + Qed. + + End IterSym. + + (** * Reduction + + [reduce] can be used instead of [mk_t], it will choose the + lowest possible level. NB: We only search and remove leftmost + W0's via ZnZ.eq0, any non-W0 block ends the process, even + if its value is 0. + *) + + (** First, a direct version ... *) + + Fixpoint red_t n : dom_t n -> t := + match n return dom_t n -> t with + | O => N0 + | S n => fun x => + let x' := pred_t n x in + reduce_n1 _ _ (N0 zero0) ZnZ.eq0 (red_t n) (mk_t_S n) x' + end. + + Lemma spec_red_t : forall n x, [red_t n x] = [mk_t n x]. + Proof. + induction n. + reflexivity. + intros. + simpl red_t. unfold reduce_n1. + rewrite <- (succ_pred_t n x) at 2. + remember (pred_t n x) as x'. + rewrite spec_mk_t, spec_succ_t. + destruct x' as [ | xh xl]. simpl. apply ZnZ.spec_0. + generalize (ZnZ.spec_eq0 xh); case ZnZ.eq0; intros H. + rewrite IHn, spec_mk_t. simpl. rewrite H; auto. + apply spec_mk_t_S. + Qed. + + (** ... then a specialized one *) +"; + +for i = 0 to size do +pr " Definition eq0%i := @ZnZ.eq0 _ w%i_op." i i; +done; + +pr " + Definition reduce_0 := N0."; +for i = 1 to size do + pr " Definition reduce_%i :=" i; + pr " Eval lazy beta iota delta [reduce_n1] in"; + pr " reduce_n1 _ _ (N0 zero0) eq0%i reduce_%i N%i." (i-1) (i-1) i +done; - pr " (***************************************************************)"; - pr " (* *)"; - pr " (** * Reduction *)"; - pr " (* *)"; - pr " (***************************************************************)"; - pr ""; - - pr " Definition reduce_0 (x:w) := %s0 x." c; - pr " Definition reduce_1 :="; - pr " Eval lazy beta iota delta[reduce_n1] in"; - pr " reduce_n1 _ _ zero w0_eq0 %s0 %s1." c c; - for i = 2 to size do - pr " Definition reduce_%i :=" i; - pr " Eval lazy beta iota delta[reduce_n1] in"; - pr " reduce_n1 _ _ zero w%i_eq0 reduce_%i %s%i." - (i-1) (i-1) c i - done; pr " Definition reduce_%i :=" (size+1); - pr " Eval lazy beta iota delta[reduce_n1] in"; - pr " reduce_n1 _ _ zero w%i_eq0 reduce_%i (%sn 0)." - size size c; + pr " Eval lazy beta iota delta [reduce_n1] in"; + pr " reduce_n1 _ _ (N0 zero0) eq0%i reduce_%i (Nn 0)." size size; pr " Definition reduce_n n :="; - pr " Eval lazy beta iota delta[reduce_n] in"; - pr " reduce_n _ _ zero reduce_%i %sn n." (size + 1) c; - pr ""; - - pp " Let spec_reduce_0: forall x, [reduce_0 x] = [%s0 x]." c; - pp " Proof."; - pp " intros x; unfold to_Z, reduce_0."; - pp " auto."; - pp " Qed."; - pp ""; - - for i = 1 to size + 1 do - if i == size + 1 then - pp " Let spec_reduce_%i: forall x, [reduce_%i x] = [%sn 0 x]." i i c - else - pp " Let spec_reduce_%i: forall x, [reduce_%i x] = [%s%i x]." i i c i; - pp " Proof."; - pp " intros x; case x; unfold reduce_%i." i; - pp " exact (spec_0 w0_spec)."; - pp " intros x1 y1."; - pp " generalize (spec_w%i_eq0 x1);" (i - 1); - pp " case w%i_eq0; intros H1; auto." (i - 1); - if i <> 1 then - pp " rewrite spec_reduce_%i." (i - 1); - pp " unfold to_Z; rewrite znz_to_Z_%i." i; - pp " unfold to_Z in H1; rewrite H1; auto."; - pp " Qed."; - pp ""; - done; - - pp " Let spec_reduce_n: forall n x, [reduce_n n x] = [%sn n x]." c; - pp " Proof."; - pp " intros n; elim n; simpl reduce_n."; - pp " intros x; rewrite <- spec_reduce_%i; auto." (size + 1); - pp " intros n1 Hrec x; case x."; - pp " unfold to_Z; rewrite make_op_S; auto."; - pp " exact (spec_0 w0_spec)."; - pp " intros x1 y1; case x1; auto."; - pp " rewrite Hrec."; - pp " rewrite spec_extendn0_0; auto."; - pp " Qed."; - pp ""; - - pr " (***************************************************************)"; - pr " (* *)"; - pr " (** * Successor *)"; - pr " (* *)"; - pr " (***************************************************************)"; - pr ""; - - for i = 0 to size do - pr " Definition w%i_succ_c := w%i_op.(znz_succ_c)." i i - done; - pr ""; - - for i = 0 to size do - pr " Definition w%i_succ := w%i_op.(znz_succ)." i i - done; - pr ""; - - pr " Definition succ x :="; - pr " match x with"; - for i = 0 to size-1 do - pr " | %s%i wx =>" c i; - pr " match w%i_succ_c wx with" i; - pr " | C0 r => %s%i r" c i; - pr " | C1 r => %s%i (WW one%i r)" c (i+1) i; - pr " end"; - done; - pr " | %s%i wx =>" c size; - pr " match w%i_succ_c wx with" size; - pr " | C0 r => %s%i r" c size; - pr " | C1 r => %sn 0 (WW one%i r)" c size ; - pr " end"; - pr " | %sn n wx =>" c; - pr " let op := make_op n in"; - pr " match op.(znz_succ_c) wx with"; - pr " | C0 r => %sn n r" c; - pr " | C1 r => %sn (S n) (WW op.(znz_1) r)" c; - pr " end"; - pr " end."; - pr ""; - - pr " Theorem spec_succ: forall n, [succ n] = [n] + 1."; - pa " Admitted."; - pp " Proof."; - pp " intros n; case n; unfold succ, to_Z."; - for i = 0 to size do - pp " intros n1; generalize (spec_succ_c w%i_spec n1);" i; - pp " unfold succ, to_Z, w%i_succ_c; case znz_succ_c; auto." i; - pp " intros ww H; rewrite <- H."; - pp " (rewrite znz_to_Z_%i; unfold interp_carry;" (i + 1); - pp " apply f_equal2 with (f := Zplus); auto;"; - pp " apply f_equal2 with (f := Zmult); auto;"; - pp " exact (spec_1 w%i_spec))." i; - done; - pp " intros k n1; generalize (spec_succ_c (wn_spec k) n1)."; - pp " unfold succ, to_Z; case znz_succ_c; auto."; - pp " intros ww H; rewrite <- H."; - pp " (rewrite (znz_to_Z_n k); unfold interp_carry;"; - pp " apply f_equal2 with (f := Zplus); auto;"; - pp " apply f_equal2 with (f := Zmult); auto;"; - pp " exact (spec_1 (wn_spec k)))."; - pp " Qed."; - pr ""; - - - pr " (***************************************************************)"; - pr " (* *)"; - pr " (** * Adddition *)"; - pr " (* *)"; - pr " (***************************************************************)"; - pr ""; - - for i = 0 to size do - pr " Definition w%i_add_c := znz_add_c w%i_op." i i; - pr " Definition w%i_add x y :=" i; - pr " match w%i_add_c x y with" i; - pr " | C0 r => %s%i r" c i; - if i == size then - pr " | C1 r => %sn 0 (WW one%i r)" c size - else - pr " | C1 r => %s%i (WW one%i r)" c (i + 1) i; - pr " end."; - pr ""; - done ; - pr " Definition addn n (x y : word w%i (S n)) :=" size; - pr " let op := make_op n in"; - pr " match op.(znz_add_c) x y with"; - pr " | C0 r => %sn n r" c; - pr " | C1 r => %sn (S n) (WW op.(znz_1) r) end." c; - pr ""; - - - for i = 0 to size do - pp " Let spec_w%i_add: forall x y, [w%i_add x y] = [%s%i x] + [%s%i y]." i i c i c i; - pp " Proof."; - pp " intros n m; unfold to_Z, w%i_add, w%i_add_c." i i; - pp " generalize (spec_add_c w%i_spec n m); case znz_add_c; auto." i; - pp " intros ww H; rewrite <- H."; - pp " rewrite znz_to_Z_%i; unfold interp_carry;" (i + 1); - pp " apply f_equal2 with (f := Zplus); auto;"; - pp " apply f_equal2 with (f := Zmult); auto;"; - pp " exact (spec_1 w%i_spec)." i; - pp " Qed."; - pp ""; - done; - pp " Let spec_wn_add: forall n x y, [addn n x y] = [%sn n x] + [%sn n y]." c c; - pp " Proof."; - pp " intros k n m; unfold to_Z, addn."; - pp " generalize (spec_add_c (wn_spec k) n m); case znz_add_c; auto."; - pp " intros ww H; rewrite <- H."; - pp " rewrite (znz_to_Z_n k); unfold interp_carry;"; - pp " apply f_equal2 with (f := Zplus); auto;"; - pp " apply f_equal2 with (f := Zmult); auto;"; - pp " exact (spec_1 (wn_spec k))."; - pp " Qed."; - - pr " Definition add := Eval lazy beta delta [same_level] in"; - pr0 " (same_level t_ "; - for i = 0 to size do - pr0 "w%i_add " i; - done; - pr "addn)."; - pr ""; - - pr " Theorem spec_add: forall x y, [add x y] = [x] + [y]."; - pa " Admitted."; - pp " Proof."; - pp " unfold add."; - pp " generalize (spec_same_level t_ (fun x y res => [res] = x + y))."; - pp " unfold same_level; intros HH; apply HH; clear HH."; - for i = 0 to size do - pp " exact spec_w%i_add." i; - done; - pp " exact spec_wn_add."; - pp " Qed."; - pr ""; - - pr " (***************************************************************)"; - pr " (* *)"; - pr " (** * Predecessor *)"; - pr " (* *)"; - pr " (***************************************************************)"; - pr ""; - - for i = 0 to size do - pr " Definition w%i_pred_c := w%i_op.(znz_pred_c)." i i - done; - pr ""; - - pr " Definition pred x :="; - pr " match x with"; - for i = 0 to size do - pr " | %s%i wx =>" c i; - pr " match w%i_pred_c wx with" i; - pr " | C0 r => reduce_%i r" i; - pr " | C1 r => zero"; - pr " end"; - done; - pr " | %sn n wx =>" c; - pr " let op := make_op n in"; - pr " match op.(znz_pred_c) wx with"; - pr " | C0 r => reduce_n n r"; - pr " | C1 r => zero"; - pr " end"; - pr " end."; - pr ""; - - pr " Theorem spec_pred_pos : forall x, 0 < [x] -> [pred x] = [x] - 1."; - pa " Admitted."; - pp " Proof."; - pp " intros x; case x; unfold pred."; - for i = 0 to size do - pp " intros x1 H1; unfold w%i_pred_c;" i; - pp " generalize (spec_pred_c w%i_spec x1); case znz_pred_c; intros y1." i; - pp " rewrite spec_reduce_%i; auto." i; - pp " unfold interp_carry; unfold to_Z."; - pp " case (spec_to_Z w%i_spec x1); intros HH1 HH2." i; - pp " case (spec_to_Z w%i_spec y1); intros HH3 HH4 HH5." i; - pp " assert (znz_to_Z w%i_op x1 - 1 < 0); auto with zarith." i; - pp " unfold to_Z in H1; auto with zarith."; - done; - pp " intros n x1 H1;"; - pp " generalize (spec_pred_c (wn_spec n) x1); case znz_pred_c; intros y1."; - pp " rewrite spec_reduce_n; auto."; - pp " unfold interp_carry; unfold to_Z."; - pp " case (spec_to_Z (wn_spec n) x1); intros HH1 HH2."; - pp " case (spec_to_Z (wn_spec n) y1); intros HH3 HH4 HH5."; - pp " assert (znz_to_Z (make_op n) x1 - 1 < 0); auto with zarith."; - pp " unfold to_Z in H1; auto with zarith."; - pp " Qed."; - pp ""; - - pp " Let spec_pred0: forall x, [x] = 0 -> [pred x] = 0."; - pp " Proof."; - pp " intros x; case x; unfold pred."; - for i = 0 to size do - pp " intros x1 H1; unfold w%i_pred_c;" i; - pp " generalize (spec_pred_c w%i_spec x1); case znz_pred_c; intros y1." i; - pp " unfold interp_carry; unfold to_Z."; - pp " unfold to_Z in H1; auto with zarith."; - pp " case (spec_to_Z w%i_spec y1); intros HH3 HH4; auto with zarith." i; - pp " intros; exact (spec_0 w0_spec)."; - done; - pp " intros n x1 H1;"; - pp " generalize (spec_pred_c (wn_spec n) x1); case znz_pred_c; intros y1."; - pp " unfold interp_carry; unfold to_Z."; - pp " unfold to_Z in H1; auto with zarith."; - pp " case (spec_to_Z (wn_spec n) y1); intros HH3 HH4; auto with zarith."; - pp " intros; exact (spec_0 w0_spec)."; - pp " Qed."; - pr ""; - - pr " (***************************************************************)"; - pr " (* *)"; - pr " (** * Subtraction *)"; - pr " (* *)"; - pr " (***************************************************************)"; - pr ""; - - for i = 0 to size do - pr " Definition w%i_sub_c := w%i_op.(znz_sub_c)." i i - done; - pr ""; - - for i = 0 to size do - pr " Definition w%i_sub x y :=" i; - pr " match w%i_sub_c x y with" i; - pr " | C0 r => reduce_%i r" i; - pr " | C1 r => zero"; - pr " end." - done; - pr ""; - - pr " Definition subn n (x y : word w%i (S n)) :=" size; - pr " let op := make_op n in"; - pr " match op.(znz_sub_c) x y with"; - pr " | C0 r => %sn n r" c; - pr " | C1 r => N0 w_0"; - pr " end."; - pr ""; - - for i = 0 to size do - pp " Let spec_w%i_sub: forall x y, [%s%i y] <= [%s%i x] -> [w%i_sub x y] = [%s%i x] - [%s%i y]." i c i c i i c i c i; - pp " Proof."; - pp " intros n m; unfold w%i_sub, w%i_sub_c." i i; - pp " generalize (spec_sub_c w%i_spec n m); case znz_sub_c;" i; - if i == 0 then - pp " intros x; auto." - else - pp " intros x; try rewrite spec_reduce_%i; auto." i; - pp " unfold interp_carry; unfold zero, w_0, to_Z."; - pp " rewrite (spec_0 w0_spec)."; - pp " case (spec_to_Z w%i_spec x); intros; auto with zarith." i; - pp " Qed."; - pp ""; - done; - - pp " Let spec_wn_sub: forall n x y, [%sn n y] <= [%sn n x] -> [subn n x y] = [%sn n x] - [%sn n y]." c c c c; - pp " Proof."; - pp " intros k n m; unfold subn."; - pp " generalize (spec_sub_c (wn_spec k) n m); case znz_sub_c;"; - pp " intros x; auto."; - pp " unfold interp_carry, to_Z."; - pp " case (spec_to_Z (wn_spec k) x); intros; auto with zarith."; - pp " Qed."; - pp ""; - - pr " Definition sub := Eval lazy beta delta [same_level] in"; - pr0 " (same_level t_ "; - for i = 0 to size do - pr0 "w%i_sub " i; - done; - pr "subn)."; - pr ""; - - pr " Theorem spec_sub_pos : forall x y, [y] <= [x] -> [sub x y] = [x] - [y]."; - pa " Admitted."; - pp " Proof."; - pp " unfold sub."; - pp " generalize (spec_same_level t_ (fun x y res => y <= x -> [res] = x - y))."; - pp " unfold same_level; intros HH; apply HH; clear HH."; - for i = 0 to size do - pp " exact spec_w%i_sub." i; - done; - pp " exact spec_wn_sub."; - pp " Qed."; - pr ""; - - for i = 0 to size do - pp " Let spec_w%i_sub0: forall x y, [%s%i x] < [%s%i y] -> [w%i_sub x y] = 0." i c i c i i; - pp " Proof."; - pp " intros n m; unfold w%i_sub, w%i_sub_c." i i; - pp " generalize (spec_sub_c w%i_spec n m); case znz_sub_c;" i; - pp " intros x; unfold interp_carry."; - pp " unfold to_Z; case (spec_to_Z w%i_spec x); intros; auto with zarith." i; - pp " intros; unfold to_Z, zero, w_0; rewrite (spec_0 w0_spec); auto."; - pp " Qed."; - pp ""; - done; - - pp " Let spec_wn_sub0: forall n x y, [%sn n x] < [%sn n y] -> [subn n x y] = 0." c c; - pp " Proof."; - pp " intros k n m; unfold subn."; - pp " generalize (spec_sub_c (wn_spec k) n m); case znz_sub_c;"; - pp " intros x; unfold interp_carry."; - pp " unfold to_Z; case (spec_to_Z (wn_spec k) x); intros; auto with zarith."; - pp " intros; unfold to_Z, w_0; rewrite (spec_0 (w0_spec)); auto."; - pp " Qed."; - pp ""; - - pr " Theorem spec_sub0: forall x y, [x] < [y] -> [sub x y] = 0."; - pa " Admitted."; - pp " Proof."; - pp " unfold sub."; - pp " generalize (spec_same_level t_ (fun x y res => x < y -> [res] = 0))."; - pp " unfold same_level; intros HH; apply HH; clear HH."; - for i = 0 to size do - pp " exact spec_w%i_sub0." i; - done; - pp " exact spec_wn_sub0."; - pp " Qed."; - pr ""; - - - pr " (***************************************************************)"; - pr " (* *)"; - pr " (** * Comparison *)"; - pr " (* *)"; - pr " (***************************************************************)"; - pr ""; - - for i = 0 to size do - pr " Definition compare_%i := w%i_op.(znz_compare)." i i; - pr " Definition comparen_%i :=" i; - pr " compare_mn_1 w%i w%i %s compare_%i (compare_%i %s) compare_%i." i i (pz i) i i (pz i) i - done; - pr ""; - - pr " Definition comparenm n m wx wy :="; - pr " let mn := Max.max n m in"; - pr " let d := diff n m in"; - pr " let op := make_op mn in"; - pr " op.(znz_compare)"; - pr " (castm (diff_r n m) (extend_tr wx (snd d)))"; - pr " (castm (diff_l n m) (extend_tr wy (fst d)))."; - pr ""; - - pr " Definition compare := Eval lazy beta delta [iter] in"; - pr " (iter _"; - for i = 0 to size do - pr " compare_%i" i; - pr " (fun n x y => CompOpp (comparen_%i (S n) y x))" i; - pr " (fun n => comparen_%i (S n))" i; - done; - pr " comparenm)."; - pr ""; - - for i = 0 to size do - pp " Let spec_compare_%i: forall x y," i; - pp " match compare_%i x y with" i; - pp " Eq => [%s%i x] = [%s%i y]" c i c i; - pp " | Lt => [%s%i x] < [%s%i y]" c i c i; - pp " | Gt => [%s%i x] > [%s%i y]" c i c i; - pp " end."; - pp " Proof."; - pp " unfold compare_%i, to_Z; exact (spec_compare w%i_spec)." i i; - pp " Qed."; - pp ""; - - pp " Let spec_comparen_%i:" i; - pp " forall (n : nat) (x : word w%i n) (y : w%i)," i i; - pp " match comparen_%i n x y with" i; - pp " | Eq => eval%in n x = [%s%i y]" i c i; - pp " | Lt => eval%in n x < [%s%i y]" i c i; - pp " | Gt => eval%in n x > [%s%i y]" i c i; - pp " end."; - pp " intros n x y."; - pp " unfold comparen_%i, to_Z; rewrite spec_double_eval%in." i i; - pp " apply spec_compare_mn_1."; - pp " exact (spec_0 w%i_spec)." i; - pp " intros x1; exact (spec_compare w%i_spec %s x1)." i (pz i); - pp " exact (spec_to_Z w%i_spec)." i; - pp " exact (spec_compare w%i_spec)." i; - pp " exact (spec_compare w%i_spec)." i; - pp " exact (spec_to_Z w%i_spec)." i; - pp " Qed."; - pp ""; - done; - - pp " Let spec_opp_compare: forall c (u v: Z),"; - pp " match c with Eq => u = v | Lt => u < v | Gt => u > v end ->"; - pp " match CompOpp c with Eq => v = u | Lt => v < u | Gt => v > u end."; - pp " Proof."; - pp " intros c u v; case c; unfold CompOpp; auto with zarith."; - pp " Qed."; - pp ""; - - - pr " Theorem spec_compare_aux: forall x y,"; - pr " match compare x y with"; - pr " Eq => [x] = [y]"; - pr " | Lt => [x] < [y]"; - pr " | Gt => [x] > [y]"; - pr " end."; - pa " Admitted."; - pp " Proof."; - pp " refine (spec_iter _ (fun x y res =>"; - pp " match res with"; - pp " Eq => x = y"; - pp " | Lt => x < y"; - pp " | Gt => x > y"; - pp " end)"; - for i = 0 to size do - pp " compare_%i" i; - pp " (fun n x y => CompOpp (comparen_%i (S n) y x))" i; - pp " (fun n => comparen_%i (S n)) _ _ _" i; - done; - pp " comparenm _)."; - - for i = 0 to size - 1 do - pp " exact spec_compare_%i." i; - pp " intros n x y H;apply spec_opp_compare; apply spec_comparen_%i." i; - pp " intros n x y H; exact (spec_comparen_%i (S n) x y)." i; - done; - pp " exact spec_compare_%i." size; - pp " intros n x y;apply spec_opp_compare; apply spec_comparen_%i." size; - pp " intros n; exact (spec_comparen_%i (S n))." size; - pp " intros n m x y; unfold comparenm."; - pp " rewrite <- (spec_cast_l n m x); rewrite <- (spec_cast_r n m y)."; - pp " unfold to_Z; apply (spec_compare (wn_spec (Max.max n m)))."; - pp " Qed."; - pr ""; - - pr " (***************************************************************)"; - pr " (* *)"; - pr " (** * Multiplication *)"; - pr " (* *)"; - pr " (***************************************************************)"; - pr ""; - - for i = 0 to size do - pr " Definition w%i_mul_c := w%i_op.(znz_mul_c)." i i - done; - pr ""; - - for i = 0 to size do - pr " Definition w%i_mul_add :=" i; - pr " Eval lazy beta delta [w_mul_add] in"; - pr " @w_mul_add w%i %s w%i_succ w%i_add_c w%i_mul_c." i (pz i) i i i - done; - pr ""; - - for i = 0 to size do - pr " Definition w%i_0W := znz_0W w%i_op." i i - done; - pr ""; - - for i = 0 to size do - pr " Definition w%i_WW := znz_WW w%i_op." i i - done; - pr ""; - - for i = 0 to size do - pr " Definition w%i_mul_add_n1 :=" i; - pr " @double_mul_add_n1 w%i %s w%i_WW w%i_0W w%i_mul_add." i (pz i) i i i - done; - pr ""; - - for i = 0 to size - 1 do - pr " Let to_Z%i n :=" i; - pr " match n return word w%i (S n) -> t_ with" i; - for j = 0 to size - i do - if (i + j) == size then - begin - pr " | %i%s => fun x => %sn 0 x" j "%nat" c; - pr " | %i%s => fun x => %sn 1 x" (j + 1) "%nat" c - end - else - pr " | %i%s => fun x => %s%i x" j "%nat" c (i + j + 1) - done; - pr " | _ => fun _ => N0 w_0"; - pr " end."; - pr ""; - done; - - - for i = 0 to size - 1 do - pp "Theorem to_Z%i_spec:" i; - pp " forall n x, Z_of_nat n <= %i -> [to_Z%i n x] = znz_to_Z (nmake_op _ w%i_op (S n)) x." (size + 1 - i) i i; - for j = 1 to size + 2 - i do - pp " intros n; case n; clear n."; - pp " unfold to_Z%i." i; - pp " intros x H; rewrite spec_eval%in%i; auto." i j; - done; - pp " intros n x."; - pp " repeat rewrite inj_S; unfold Zsucc; auto with zarith."; - pp " Qed."; - pp ""; - done; - - - for i = 0 to size do - pr " Definition w%i_mul n x y :=" i; - pr " let (w,r) := w%i_mul_add_n1 (S n) x y %s in" i (pz i); - if i == size then - begin - pr " if w%i_eq0 w then %sn n r" i c; - pr " else %sn (S n) (WW (extend%i n w) r)." c i; - end - else - begin - pr " if w%i_eq0 w then to_Z%i n r" i i; - pr " else to_Z%i (S n) (WW (extend%i n w) r)." i i; - end; - pr ""; - done; - - pr " Definition mulnm n m x y :="; - pr " let mn := Max.max n m in"; - pr " let d := diff n m in"; - pr " let op := make_op mn in"; - pr " reduce_n (S mn) (op.(znz_mul_c)"; - pr " (castm (diff_r n m) (extend_tr x (snd d)))"; - pr " (castm (diff_l n m) (extend_tr y (fst d))))."; - pr ""; - - pr " Definition mul := Eval lazy beta delta [iter0] in"; - pr " (iter0 t_"; - for i = 0 to size do - pr " (fun x y => reduce_%i (w%i_mul_c x y))" (i + 1) i; - pr " (fun n x y => w%i_mul n y x)" i; - pr " w%i_mul" i; - done; - pr " mulnm"; - pr " (fun _ => N0 w_0)"; - pr " (fun _ => N0 w_0)"; - pr " )."; - pr ""; - for i = 0 to size do - pp " Let spec_w%i_mul_add: forall x y z," i; - pp " let (q,r) := w%i_mul_add x y z in" i; - pp " znz_to_Z w%i_op q * (base (znz_digits w%i_op)) + znz_to_Z w%i_op r =" i i i; - pp " znz_to_Z w%i_op x * znz_to_Z w%i_op y + znz_to_Z w%i_op z :=" i i i ; - pp " (spec_mul_add w%i_spec)." i; - pp ""; - done; - - for i = 0 to size do - pp " Theorem spec_w%i_mul_add_n1: forall n x y z," i; - pp " let (q,r) := w%i_mul_add_n1 n x y z in" i; - pp " znz_to_Z w%i_op q * (base (znz_digits (nmake_op _ w%i_op n))) +" i i; - pp " znz_to_Z (nmake_op _ w%i_op n) r =" i; - pp " znz_to_Z (nmake_op _ w%i_op n) x * znz_to_Z w%i_op y +" i i; - pp " znz_to_Z w%i_op z." i; - pp " Proof."; - pp " intros n x y z; unfold w%i_mul_add_n1." i; - pp " rewrite nmake_double."; - pp " rewrite digits_doubled."; - pp " change (base (DoubleBase.double_digits (znz_digits w%i_op) n)) with" i; - pp " (DoubleBase.double_wB (znz_digits w%i_op) n)." i; - pp " apply spec_double_mul_add_n1; auto."; - if i == 0 then pp " exact (spec_0 w%i_spec)." i; - pp " exact (spec_WW w%i_spec)." i; - pp " exact (spec_0W w%i_spec)." i; - pp " exact (spec_mul_add w%i_spec)." i; - pp " Qed."; - pp ""; - done; - - pp " Lemma nmake_op_WW: forall ww ww1 n x y,"; - pp " znz_to_Z (nmake_op ww ww1 (S n)) (WW x y) ="; - pp " znz_to_Z (nmake_op ww ww1 n) x * base (znz_digits (nmake_op ww ww1 n)) +"; - pp " znz_to_Z (nmake_op ww ww1 n) y."; - pp " auto."; - pp " Qed."; - pp ""; - - for i = 0 to size do - pp " Lemma extend%in_spec: forall n x1," i; - pp " znz_to_Z (nmake_op _ w%i_op (S n)) (extend%i n x1) =" i i; - pp " znz_to_Z w%i_op x1." i; - pp " Proof."; - pp " intros n1 x2; rewrite nmake_double."; - pp " unfold extend%i." i; - pp " rewrite DoubleBase.spec_extend; auto."; - if i == 0 then - pp " intros l; simpl; unfold w_0; rewrite (spec_0 w0_spec); ring."; - pp " Qed."; - pp ""; - done; - - pp " Lemma spec_muln:"; - pp " forall n (x: word _ (S n)) y,"; - pp " [%sn (S n) (znz_mul_c (make_op n) x y)] = [%sn n x] * [%sn n y]." c c c; - pp " Proof."; - pp " intros n x y; unfold to_Z."; - pp " rewrite <- (spec_mul_c (wn_spec n))."; - pp " rewrite make_op_S."; - pp " case znz_mul_c; auto."; - pp " Qed."; - pr ""; - - pr " Theorem spec_mul: forall x y, [mul x y] = [x] * [y]."; - pa " Admitted."; - pp " Proof."; - for i = 0 to size do - pp " assert(F%i:" i; - pp " forall n x y,"; - if i <> size then - pp0 " Z_of_nat n <= %i -> " (size - i); - pp " [w%i_mul n x y] = eval%in (S n) x * [%s%i y])." i i c i; - if i == size then - pp " intros n x y; unfold w%i_mul." i - else - pp " intros n x y H; unfold w%i_mul." i; - pp " generalize (spec_w%i_mul_add_n1 (S n) x y %s)." i (pz i); - pp " case w%i_mul_add_n1; intros x1 y1." i; - pp " change (znz_to_Z (nmake_op _ w%i_op (S n)) x) with (eval%in (S n) x)." i i; - pp " change (znz_to_Z w%i_op y) with ([%s%i y])." i c i; - if i == 0 then - pp " unfold w_0; rewrite (spec_0 w0_spec); rewrite Zplus_0_r." - else - pp " change (znz_to_Z w%i_op W0) with 0; rewrite Zplus_0_r." i; - pp " intros H1; rewrite <- H1; clear H1."; - pp " generalize (spec_w%i_eq0 x1); case w%i_eq0; intros HH." i i; - pp " unfold to_Z in HH; rewrite HH."; - if i == size then - begin - pp " rewrite spec_eval%in; unfold eval%in, nmake_op%i; auto." i i i; - pp " rewrite spec_eval%in; unfold eval%in, nmake_op%i." i i i - end - else - begin - pp " rewrite to_Z%i_spec; auto with zarith." i; - pp " rewrite to_Z%i_spec; try (rewrite inj_S; auto with zarith)." i - end; - pp " rewrite nmake_op_WW; rewrite extend%in_spec; auto." i; - done; - pp " refine (spec_iter0 t_ (fun x y res => [res] = x * y)"; - for i = 0 to size do - pp " (fun x y => reduce_%i (w%i_mul_c x y))" (i + 1) i; - pp " (fun n x y => w%i_mul n y x)" i; - pp " w%i_mul _ _ _" i; - done; - pp " mulnm _"; - pp " (fun _ => N0 w_0) _"; - pp " (fun _ => N0 w_0) _"; - pp " )."; - for i = 0 to size do - pp " intros x y; rewrite spec_reduce_%i." (i + 1); - pp " unfold w%i_mul_c, to_Z." i; - pp " generalize (spec_mul_c w%i_spec x y)." i; - pp " intros HH; rewrite <- HH; clear HH; auto."; - if i == size then - begin - pp " intros n x y; rewrite F%i; auto with zarith." i; - pp " intros n x y; rewrite F%i; auto with zarith." i; - end - else - begin - pp " intros n x y H; rewrite F%i; auto with zarith." i; - pp " intros n x y H; rewrite F%i; auto with zarith." i; - end; - done; - pp " intros n m x y; unfold mulnm."; - pp " rewrite spec_reduce_n."; - pp " rewrite <- (spec_cast_l n m x)."; - pp " rewrite <- (spec_cast_r n m y)."; - pp " rewrite spec_muln; rewrite spec_cast_l; rewrite spec_cast_r; auto."; - pp " intros x; unfold to_Z, w_0; rewrite (spec_0 w0_spec); ring."; - pp " intros x; unfold to_Z, w_0; rewrite (spec_0 w0_spec); ring."; - pp " Qed."; - pr ""; - - pr " (***************************************************************)"; - pr " (* *)"; - pr " (** * Square *)"; - pr " (* *)"; - pr " (***************************************************************)"; - pr ""; - - for i = 0 to size do - pr " Definition w%i_square_c := w%i_op.(znz_square_c)." i i - done; - pr ""; - - pr " Definition square x :="; - pr " match x with"; - pr " | %s0 wx => reduce_1 (w0_square_c wx)" c; - for i = 1 to size - 1 do - pr " | %s%i wx => %s%i (w%i_square_c wx)" c i c (i+1) i - done; - pr " | %s%i wx => %sn 0 (w%i_square_c wx)" c size c size; - pr " | %sn n wx =>" c; - pr " let op := make_op n in"; - pr " %sn (S n) (op.(znz_square_c) wx)" c; - pr " end."; - pr ""; - - pr " Theorem spec_square: forall x, [square x] = [x] * [x]."; - pa " Admitted."; - pp " Proof."; - pp " intros x; case x; unfold square; clear x."; - pp " intros x; rewrite spec_reduce_1; unfold to_Z."; - pp " exact (spec_square_c w%i_spec x)." 0; - for i = 1 to size do - pp " intros x; unfold to_Z."; - pp " exact (spec_square_c w%i_spec x)." i; - done; - pp " intros n x; unfold to_Z."; - pp " rewrite make_op_S."; - pp " exact (spec_square_c (wn_spec n) x)."; - pp "Qed."; - pr ""; - - pr " (***************************************************************)"; - pr " (* *)"; - pr " (** * Square root *)"; - pr " (* *)"; - pr " (***************************************************************)"; - pr ""; - - for i = 0 to size do - pr " Definition w%i_sqrt := w%i_op.(znz_sqrt)." i i - done; - pr ""; - - pr " Definition sqrt x :="; - pr " match x with"; - for i = 0 to size do - pr " | %s%i wx => reduce_%i (w%i_sqrt wx)" c i i i; - done; - pr " | %sn n wx =>" c; - pr " let op := make_op n in"; - pr " reduce_n n (op.(znz_sqrt) wx)"; - pr " end."; - pr ""; - - pr " Theorem spec_sqrt: forall x, [sqrt x] ^ 2 <= [x] < ([sqrt x] + 1) ^ 2."; - pa " Admitted."; - pp " Proof."; - pp " intros x; unfold sqrt; case x; clear x."; - for i = 0 to size do - pp " intros x; rewrite spec_reduce_%i; exact (spec_sqrt w%i_spec x)." i i; - done; - pp " intros n x; rewrite spec_reduce_n; exact (spec_sqrt (wn_spec n) x)."; - pp " Qed."; - pr ""; - - - pr " (***************************************************************)"; - pr " (* *)"; - pr " (** * Division *)"; - pr " (* *)"; - pr " (***************************************************************)"; - pr ""; - - for i = 0 to size do - pr " Definition w%i_div_gt := w%i_op.(znz_div_gt)." i i - done; - pr ""; - - pp " Let spec_divn1 ww (ww_op: znz_op ww) (ww_spec: znz_spec ww_op) :="; - pp " (spec_double_divn1"; - pp " ww_op.(znz_zdigits) ww_op.(znz_0)"; - pp " (znz_WW ww_op) ww_op.(znz_head0)"; - pp " ww_op.(znz_add_mul_div) ww_op.(znz_div21)"; - pp " ww_op.(znz_compare) ww_op.(znz_sub) (znz_to_Z ww_op)"; - pp " (spec_to_Z ww_spec)"; - pp " (spec_zdigits ww_spec)"; - pp " (spec_0 ww_spec) (spec_WW ww_spec) (spec_head0 ww_spec)"; - pp " (spec_add_mul_div ww_spec) (spec_div21 ww_spec)"; - pp " (CyclicAxioms.spec_compare ww_spec) (CyclicAxioms.spec_sub ww_spec))."; - pp ""; - - for i = 0 to size do - pr " Definition w%i_divn1 n x y :=" i; - pr " let (u, v) :="; - pr " double_divn1 w%i_op.(znz_zdigits) w%i_op.(znz_0)" i i; - pr " (znz_WW w%i_op) w%i_op.(znz_head0)" i i; - pr " w%i_op.(znz_add_mul_div) w%i_op.(znz_div21)" i i; - pr " w%i_op.(znz_compare) w%i_op.(znz_sub) (S n) x y in" i i; - if i == size then - pr " (%sn _ u, %s%i v)." c c i - else - pr " (to_Z%i _ u, %s%i v)." i c i; - done; - pr ""; - - for i = 0 to size do - pp " Lemma spec_get_end%i: forall n x y," i; - pp " eval%in n x <= [%s%i y] ->" i c i; - pp " [%s%i (DoubleBase.get_low %s n x)] = eval%in n x." c i (pz i) i; - pp " Proof."; - pp " intros n x y H."; - pp " rewrite spec_double_eval%in; unfold to_Z." i; - pp " apply DoubleBase.spec_get_low."; - pp " exact (spec_0 w%i_spec)." i; - pp " exact (spec_to_Z w%i_spec)." i; - pp " apply Zle_lt_trans with [%s%i y]; auto." c i; - pp " rewrite <- spec_double_eval%in; auto." i; - pp " unfold to_Z; case (spec_to_Z w%i_spec y); auto." i; - pp " Qed."; - pp ""; - done; - - for i = 0 to size do - pr " Let div_gt%i x y := let (u,v) := (w%i_div_gt x y) in (reduce_%i u, reduce_%i v)." i i i i; - done; - pr ""; - - - pr " Let div_gtnm n m wx wy :="; - pr " let mn := Max.max n m in"; - pr " let d := diff n m in"; - pr " let op := make_op mn in"; - pr " let (q, r):= op.(znz_div_gt)"; - pr " (castm (diff_r n m) (extend_tr wx (snd d)))"; - pr " (castm (diff_l n m) (extend_tr wy (fst d))) in"; - pr " (reduce_n mn q, reduce_n mn r)."; - pr ""; - - pr " Definition div_gt := Eval lazy beta delta [iter] in"; - pr " (iter _"; - for i = 0 to size do - pr " div_gt%i" i; - pr " (fun n x y => div_gt%i x (DoubleBase.get_low %s (S n) y))" i (pz i); - pr " w%i_divn1" i; - done; - pr " div_gtnm)."; - pr ""; - - pr " Theorem spec_div_gt: forall x y,"; - pr " [x] > [y] -> 0 < [y] ->"; - pr " let (q,r) := div_gt x y in"; - pr " [q] = [x] / [y] /\\ [r] = [x] mod [y]."; - pa " Admitted."; - pp " Proof."; - pp " assert (FO:"; - pp " forall x y, [x] > [y] -> 0 < [y] ->"; - pp " let (q,r) := div_gt x y in"; - pp " [x] = [q] * [y] + [r] /\\ 0 <= [r] < [y])."; - pp " refine (spec_iter (t_*t_) (fun x y res => x > y -> 0 < y ->"; - pp " let (q,r) := res in"; - pp " x = [q] * y + [r] /\\ 0 <= [r] < y)"; - for i = 0 to size do - pp " div_gt%i" i; - pp " (fun n x y => div_gt%i x (DoubleBase.get_low %s (S n) y))" i (pz i); - pp " w%i_divn1 _ _ _" i; - done; - pp " div_gtnm _)."; - for i = 0 to size do - pp " intros x y H1 H2; unfold div_gt%i, w%i_div_gt." i i; - pp " generalize (spec_div_gt w%i_spec x y H1 H2); case znz_div_gt." i; - pp " intros xx yy; repeat rewrite spec_reduce_%i; auto." i; - if i == size then - pp " intros n x y H2 H3; unfold div_gt%i, w%i_div_gt." i i - else - pp " intros n x y H1 H2 H3; unfold div_gt%i, w%i_div_gt." i i; - pp " generalize (spec_div_gt w%i_spec x" i; - pp " (DoubleBase.get_low %s (S n) y))." (pz i); - pp0 ""; - for j = 0 to i do - pp0 "unfold w%i; " (i-j); - done; - pp "case znz_div_gt."; - pp " intros xx yy H4; repeat rewrite spec_reduce_%i." i; - pp " generalize (spec_get_end%i (S n) y x); unfold to_Z; intros H5." i; - pp " unfold to_Z in H2; rewrite H5 in H4; auto with zarith."; - if i == size then - pp " intros n x y H2 H3." - else - pp " intros n x y H1 H2 H3."; - pp " generalize"; - pp " (spec_divn1 w%i w%i_op w%i_spec (S n) x y H3)." i i i; - pp0 " unfold w%i_divn1; " i; - for j = 0 to i do - pp0 "unfold w%i; " (i-j); - done; - pp "case double_divn1."; - pp " intros xx yy H4."; - if i == size then - begin - pp " repeat rewrite <- spec_double_eval%in in H4; auto." i; - pp " rewrite spec_eval%in; auto." i; - end - else - begin - pp " rewrite to_Z%i_spec; auto with zarith." i; - pp " repeat rewrite <- spec_double_eval%in in H4; auto." i; - end; - done; - pp " intros n m x y H1 H2; unfold div_gtnm."; - pp " generalize (spec_div_gt (wn_spec (Max.max n m))"; - pp " (castm (diff_r n m)"; - pp " (extend_tr x (snd (diff n m))))"; - pp " (castm (diff_l n m)"; - pp " (extend_tr y (fst (diff n m)))))."; - pp " case znz_div_gt."; - pp " intros xx yy HH."; - pp " repeat rewrite spec_reduce_n."; - pp " rewrite <- (spec_cast_l n m x)."; - pp " rewrite <- (spec_cast_r n m y)."; - pp " unfold to_Z; apply HH."; - pp " rewrite <- (spec_cast_l n m x) in H1; auto."; - pp " rewrite <- (spec_cast_r n m y) in H1; auto."; - pp " rewrite <- (spec_cast_r n m y) in H2; auto."; - pp " intros x y H1 H2; generalize (FO x y H1 H2); case div_gt."; - pp " intros q r (H3, H4); split."; - pp " apply (Zdiv_unique [x] [y] [q] [r]); auto."; - pp " rewrite Zmult_comm; auto."; - pp " apply (Zmod_unique [x] [y] [q] [r]); auto."; - pp " rewrite Zmult_comm; auto."; - pp " Qed."; - pr ""; - - pr " (***************************************************************)"; - pr " (* *)"; - pr " (** * Modulo *)"; - pr " (* *)"; - pr " (***************************************************************)"; - pr ""; - - for i = 0 to size do - pr " Definition w%i_mod_gt := w%i_op.(znz_mod_gt)." i i - done; - pr ""; - - for i = 0 to size do - pr " Definition w%i_modn1 :=" i; - pr " double_modn1 w%i_op.(znz_zdigits) w%i_op.(znz_0)" i i; - pr " w%i_op.(znz_head0) w%i_op.(znz_add_mul_div) w%i_op.(znz_div21)" i i i; - pr " w%i_op.(znz_compare) w%i_op.(znz_sub)." i i; - done; - pr ""; - - pr " Let mod_gtnm n m wx wy :="; - pr " let mn := Max.max n m in"; - pr " let d := diff n m in"; - pr " let op := make_op mn in"; - pr " reduce_n mn (op.(znz_mod_gt)"; - pr " (castm (diff_r n m) (extend_tr wx (snd d)))"; - pr " (castm (diff_l n m) (extend_tr wy (fst d))))."; - pr ""; - - pr " Definition mod_gt := Eval lazy beta delta[iter] in"; - pr " (iter _"; - for i = 0 to size do - pr " (fun x y => reduce_%i (w%i_mod_gt x y))" i i; - pr " (fun n x y => reduce_%i (w%i_mod_gt x (DoubleBase.get_low %s (S n) y)))" i i (pz i); - pr " (fun n x y => reduce_%i (w%i_modn1 (S n) x y))" i i; - done; - pr " mod_gtnm)."; - pr ""; - - pp " Let spec_modn1 ww (ww_op: znz_op ww) (ww_spec: znz_spec ww_op) :="; - pp " (spec_double_modn1"; - pp " ww_op.(znz_zdigits) ww_op.(znz_0)"; - pp " (znz_WW ww_op) ww_op.(znz_head0)"; - pp " ww_op.(znz_add_mul_div) ww_op.(znz_div21)"; - pp " ww_op.(znz_compare) ww_op.(znz_sub) (znz_to_Z ww_op)"; - pp " (spec_to_Z ww_spec)"; - pp " (spec_zdigits ww_spec)"; - pp " (spec_0 ww_spec) (spec_WW ww_spec) (spec_head0 ww_spec)"; - pp " (spec_add_mul_div ww_spec) (spec_div21 ww_spec)"; - pp " (CyclicAxioms.spec_compare ww_spec) (CyclicAxioms.spec_sub ww_spec))."; - pp ""; - - pr " Theorem spec_mod_gt:"; - pr " forall x y, [x] > [y] -> 0 < [y] -> [mod_gt x y] = [x] mod [y]."; - pa " Admitted."; - pp " Proof."; - pp " refine (spec_iter _ (fun x y res => x > y -> 0 < y ->"; - pp " [res] = x mod y)"; - for i = 0 to size do - pp " (fun x y => reduce_%i (w%i_mod_gt x y))" i i; - pp " (fun n x y => reduce_%i (w%i_mod_gt x (DoubleBase.get_low %s (S n) y)))" i i (pz i); - pp " (fun n x y => reduce_%i (w%i_modn1 (S n) x y)) _ _ _" i i; - done; - pp " mod_gtnm _)."; - for i = 0 to size do - pp " intros x y H1 H2; rewrite spec_reduce_%i." i; - pp " exact (spec_mod_gt w%i_spec x y H1 H2)." i; - if i == size then - pp " intros n x y H2 H3; rewrite spec_reduce_%i." i - else - pp " intros n x y H1 H2 H3; rewrite spec_reduce_%i." i; - pp " unfold w%i_mod_gt." i; - pp " rewrite <- (spec_get_end%i (S n) y x); auto with zarith." i; - pp " unfold to_Z; apply (spec_mod_gt w%i_spec); auto." i; - pp " rewrite <- (spec_get_end%i (S n) y x) in H2; auto with zarith." i; - pp " rewrite <- (spec_get_end%i (S n) y x) in H3; auto with zarith." i; - if i == size then - pp " intros n x y H2 H3; rewrite spec_reduce_%i." i - else - pp " intros n x y H1 H2 H3; rewrite spec_reduce_%i." i; - pp " unfold w%i_modn1, to_Z; rewrite spec_double_eval%in." i i; - pp " apply (spec_modn1 _ _ w%i_spec); auto." i; - done; - pp " intros n m x y H1 H2; unfold mod_gtnm."; - pp " repeat rewrite spec_reduce_n."; - pp " rewrite <- (spec_cast_l n m x)."; - pp " rewrite <- (spec_cast_r n m y)."; - pp " unfold to_Z; apply (spec_mod_gt (wn_spec (Max.max n m)))."; - pp " rewrite <- (spec_cast_l n m x) in H1; auto."; - pp " rewrite <- (spec_cast_r n m y) in H1; auto."; - pp " rewrite <- (spec_cast_r n m y) in H2; auto."; - pp " Qed."; - pr ""; - - pr " (** digits: a measure for gcd *)"; - pr ""; - - pr " Definition digits x :="; - pr " match x with"; - for i = 0 to size do - pr " | %s%i _ => w%i_op.(znz_digits)" c i i; - done; - pr " | %sn n _ => (make_op n).(znz_digits)" c; - pr " end."; - pr ""; - - pr " Theorem spec_digits: forall x, 0 <= [x] < 2 ^ Zpos (digits x)."; - pa " Admitted."; - pp " Proof."; - pp " intros x; case x; clear x."; - for i = 0 to size do - pp " intros x; unfold to_Z, digits;"; - pp " generalize (spec_to_Z w%i_spec x); unfold base; intros H; exact H." i; - done; - pp " intros n x; unfold to_Z, digits;"; - pp " generalize (spec_to_Z (wn_spec n) x); unfold base; intros H; exact H."; - pp " Qed."; - pr ""; - - pr " (***************************************************************)"; - pr " (* *)"; - pr " (** * Conversion *)"; - pr " (* *)"; - pr " (***************************************************************)"; - pr ""; - - pr " Definition pheight p :="; - pr " Peano.pred (nat_of_P (get_height w0_op.(znz_digits) (plength p)))."; - pr ""; - - pr " Theorem pheight_correct: forall p,"; - pr " Zpos p < 2 ^ (Zpos (znz_digits w0_op) * 2 ^ (Z_of_nat (pheight p)))."; - pr " Proof."; - pr " intros p; unfold pheight."; - pr " assert (F1: forall x, Z_of_nat (Peano.pred (nat_of_P x)) = Zpos x - 1)."; - pr " intros x."; - pr " assert (Zsucc (Z_of_nat (Peano.pred (nat_of_P x))) = Zpos x); auto with zarith."; - pr " rewrite <- inj_S."; - pr " rewrite <- (fun x => S_pred x 0); auto with zarith."; - pr " rewrite Zpos_eq_Z_of_nat_o_nat_of_P; auto."; - pr " apply lt_le_trans with 1%snat; auto with zarith." "%"; - pr " exact (le_Pmult_nat x 1)."; - pr " rewrite F1; clear F1."; - pr " assert (F2:= (get_height_correct (znz_digits w0_op) (plength p)))."; - pr " apply Zlt_le_trans with (Zpos (Psucc p))."; - pr " rewrite Zpos_succ_morphism; auto with zarith."; - pr " apply Zle_trans with (1 := plength_pred_correct (Psucc p))."; - pr " rewrite Ppred_succ."; - pr " apply Zpower_le_monotone; auto with zarith."; - pr " Qed."; - pr ""; - - pr " Definition of_pos x :="; - pr " let h := pheight x in"; - pr " match h with"; - for i = 0 to size do - pr " | %i%snat => reduce_%i (snd (w%i_op.(znz_of_pos) x))" i "%" i i; - done; - pr " | _ =>"; - pr " let n := minus h %i in" (size + 1); - pr " reduce_n n (snd ((make_op n).(znz_of_pos) x))"; - pr " end."; - pr ""; - - pr " Theorem spec_of_pos: forall x,"; - pr " [of_pos x] = Zpos x."; - pa " Admitted."; - pp " Proof."; - pp " assert (F := spec_more_than_1_digit w0_spec)."; - pp " intros x; unfold of_pos; case_eq (pheight x)."; - for i = 0 to size do - if i <> 0 then - pp " intros n; case n; clear n."; - pp " intros H1; rewrite spec_reduce_%i; unfold to_Z." i; - pp " apply (znz_of_pos_correct w%i_spec)." i; - pp " apply Zlt_le_trans with (1 := pheight_correct x)."; - pp " rewrite H1; simpl Z_of_nat; change (2^%i) with (%s)." i (gen2 i); - pp " unfold base."; - pp " apply Zpower_le_monotone; split; auto with zarith."; - if i <> 0 then - begin - pp " rewrite Zmult_comm; repeat rewrite <- Zmult_assoc."; - pp " repeat rewrite <- Zpos_xO."; - pp " refine (Zle_refl _)."; - end; - done; - pp " intros n."; - pp " intros H1; rewrite spec_reduce_n; unfold to_Z."; - pp " simpl minus; rewrite <- minus_n_O."; - pp " apply (znz_of_pos_correct (wn_spec n))."; - pp " apply Zlt_le_trans with (1 := pheight_correct x)."; - pp " unfold base."; - pp " apply Zpower_le_monotone; auto with zarith."; - pp " split; auto with zarith."; - pp " rewrite H1."; - pp " elim n; clear n H1."; - pp " simpl Z_of_nat; change (2^%i) with (%s)." (size + 1) (gen2 (size + 1)); - pp " rewrite Zmult_comm; repeat rewrite <- Zmult_assoc."; - pp " repeat rewrite <- Zpos_xO."; - pp " refine (Zle_refl _)."; - pp " intros n Hrec."; - pp " rewrite make_op_S."; - pp " change (@znz_digits (word _ (S (S n))) (mk_zn2z_op_karatsuba (make_op n))) with"; - pp " (xO (znz_digits (make_op n)))."; - pp " rewrite (fun x y => (Zpos_xO (@znz_digits x y)))."; - pp " rewrite inj_S; unfold Zsucc."; - pp " rewrite Zplus_comm; rewrite Zpower_exp; auto with zarith."; - pp " rewrite Zpower_1_r."; - pp " assert (tmp: forall x y z, x * (y * z) = y * (x * z));"; - pp " [intros; ring | rewrite tmp; clear tmp]."; - pp " apply Zmult_le_compat_l; auto with zarith."; - pp " Qed."; - pr ""; - - pr " (***************************************************************)"; - pr " (* *)"; - pr " (** * Shift *)"; - pr " (* *)"; - pr " (***************************************************************)"; - pr ""; - - (* Head0 *) - pr " Definition head0 w := match w with"; - for i = 0 to size do - pr " | %s%i w=> reduce_%i (w%i_op.(znz_head0) w)" c i i i; - done; - pr " | %sn n w=> reduce_n n ((make_op n).(znz_head0) w)" c; - pr " end."; - pr ""; - - pr " Theorem spec_head00: forall x, [x] = 0 ->[head0 x] = Zpos (digits x)."; - pa " Admitted."; - pp " Proof."; - pp " intros x; case x; unfold head0; clear x."; - for i = 0 to size do - pp " intros x; rewrite spec_reduce_%i; exact (spec_head00 w%i_spec x)." i i; - done; - pp " intros n x; rewrite spec_reduce_n; exact (spec_head00 (wn_spec n) x)."; - pp " Qed."; - pr ""; - - pr " Theorem spec_head0: forall x, 0 < [x] ->"; - pr " 2 ^ (Zpos (digits x) - 1) <= 2 ^ [head0 x] * [x] < 2 ^ Zpos (digits x)."; - pa " Admitted."; - pp " Proof."; - pp " assert (F0: forall x, (x - 1) + 1 = x)."; - pp " intros; ring."; - pp " intros x; case x; unfold digits, head0; clear x."; - for i = 0 to size do - pp " intros x Hx; rewrite spec_reduce_%i." i; - pp " assert (F1:= spec_more_than_1_digit w%i_spec)." i; - pp " generalize (spec_head0 w%i_spec x Hx)." i; - pp " unfold base."; - pp " pattern (Zpos (znz_digits w%i_op)) at 1;" i; - pp " rewrite <- (fun x => (F0 (Zpos x)))."; - pp " rewrite Zpower_exp; auto with zarith."; - pp " rewrite Zpower_1_r; rewrite Z_div_mult; auto with zarith."; - done; - pp " intros n x Hx; rewrite spec_reduce_n."; - pp " assert (F1:= spec_more_than_1_digit (wn_spec n))."; - pp " generalize (spec_head0 (wn_spec n) x Hx)."; - pp " unfold base."; - pp " pattern (Zpos (znz_digits (make_op n))) at 1;"; - pp " rewrite <- (fun x => (F0 (Zpos x)))."; - pp " rewrite Zpower_exp; auto with zarith."; - pp " rewrite Zpower_1_r; rewrite Z_div_mult; auto with zarith."; - pp " Qed."; - pr ""; - - - (* Tail0 *) - pr " Definition tail0 w := match w with"; - for i = 0 to size do - pr " | %s%i w=> reduce_%i (w%i_op.(znz_tail0) w)" c i i i; - done; - pr " | %sn n w=> reduce_n n ((make_op n).(znz_tail0) w)" c; - pr " end."; - pr ""; - - - pr " Theorem spec_tail00: forall x, [x] = 0 ->[tail0 x] = Zpos (digits x)."; - pa " Admitted."; - pp " Proof."; - pp " intros x; case x; unfold tail0; clear x."; - for i = 0 to size do - pp " intros x; rewrite spec_reduce_%i; exact (spec_tail00 w%i_spec x)." i i; - done; - pp " intros n x; rewrite spec_reduce_n; exact (spec_tail00 (wn_spec n) x)."; - pp " Qed."; - pr ""; - - - pr " Theorem spec_tail0: forall x,"; - pr " 0 < [x] -> exists y, 0 <= y /\\ [x] = (2 * y + 1) * 2 ^ [tail0 x]."; - pa " Admitted."; - pp " Proof."; - pp " intros x; case x; clear x; unfold tail0."; - for i = 0 to size do - pp " intros x Hx; rewrite spec_reduce_%i; exact (spec_tail0 w%i_spec x Hx)." i i; - done; - pp " intros n x Hx; rewrite spec_reduce_n; exact (spec_tail0 (wn_spec n) x Hx)."; - pp " Qed."; - pr ""; - - - (* Number of digits *) - pr " Definition %sdigits x :=" c; - pr " match x with"; - pr " | %s0 _ => %s0 w0_op.(znz_zdigits)" c c; - for i = 1 to size do - pr " | %s%i _ => reduce_%i w%i_op.(znz_zdigits)" c i i i; - done; - pr " | %sn n _ => reduce_n n (make_op n).(znz_zdigits)" c; - pr " end."; - pr ""; - - pr " Theorem spec_Ndigits: forall x, [Ndigits x] = Zpos (digits x)."; - pa " Admitted."; - pp " Proof."; - pp " intros x; case x; clear x; unfold Ndigits, digits."; - for i = 0 to size do - pp " intros _; try rewrite spec_reduce_%i; exact (spec_zdigits w%i_spec)." i i; - done; - pp " intros n _; try rewrite spec_reduce_n; exact (spec_zdigits (wn_spec n))."; - pp " Qed."; - pr ""; - - - (* Shiftr *) - for i = 0 to size do - pr " Definition unsafe_shiftr%i n x := w%i_op.(znz_add_mul_div) (w%i_op.(znz_sub) w%i_op.(znz_zdigits) n) w%i_op.(znz_0) x." i i i i i; - done; - pr " Definition unsafe_shiftrn n p x := (make_op n).(znz_add_mul_div) ((make_op n).(znz_sub) (make_op n).(znz_zdigits) p) (make_op n).(znz_0) x."; - pr ""; - - pr " Definition unsafe_shiftr := Eval lazy beta delta [same_level] in"; - pr " same_level _ (fun n x => %s0 (unsafe_shiftr0 n x))" c; - for i = 1 to size do - pr " (fun n x => reduce_%i (unsafe_shiftr%i n x))" i i; - done; - pr " (fun n p x => reduce_n n (unsafe_shiftrn n p x))."; - pr ""; - - - pr " Theorem spec_unsafe_shiftr: forall n x,"; - pr " [n] <= [Ndigits x] -> [unsafe_shiftr n x] = [x] / 2 ^ [n]."; - pa " Admitted."; - pp " Proof."; - pp " assert (F0: forall x y, x - (x - y) = y)."; - pp " intros; ring."; - pp " assert (F2: forall x y z, 0 <= x -> 0 <= y -> x < z -> 0 <= x / 2 ^ y < z)."; - pp " intros x y z HH HH1 HH2."; - pp " split; auto with zarith."; - pp " apply Zle_lt_trans with (2 := HH2); auto with zarith."; - pp " apply Zdiv_le_upper_bound; auto with zarith."; - pp " pattern x at 1; replace x with (x * 2 ^ 0); auto with zarith."; - pp " apply Zmult_le_compat_l; auto."; - pp " apply Zpower_le_monotone; auto with zarith."; - pp " rewrite Zpower_0_r; ring."; - pp " assert (F3: forall x y, 0 <= y -> y <= x -> 0 <= x - y < 2 ^ x)."; - pp " intros xx y HH HH1."; - pp " split; auto with zarith."; - pp " apply Zle_lt_trans with xx; auto with zarith."; - pp " apply Zpower2_lt_lin; auto with zarith."; - pp " assert (F4: forall ww ww1 ww2"; - pp " (ww_op: znz_op ww) (ww1_op: znz_op ww1) (ww2_op: znz_op ww2)"; - pp " xx yy xx1 yy1,"; - pp " znz_to_Z ww2_op yy <= znz_to_Z ww1_op (znz_zdigits ww1_op) ->"; - pp " znz_to_Z ww1_op (znz_zdigits ww1_op) <= znz_to_Z ww_op (znz_zdigits ww_op) ->"; - pp " znz_spec ww_op -> znz_spec ww1_op -> znz_spec ww2_op ->"; - pp " znz_to_Z ww_op xx1 = znz_to_Z ww1_op xx ->"; - pp " znz_to_Z ww_op yy1 = znz_to_Z ww2_op yy ->"; - pp " znz_to_Z ww_op"; - pp " (znz_add_mul_div ww_op (znz_sub ww_op (znz_zdigits ww_op) yy1)"; - pp " (znz_0 ww_op) xx1) = znz_to_Z ww1_op xx / 2 ^ znz_to_Z ww2_op yy)."; - pp " intros ww ww1 ww2 ww_op ww1_op ww2_op xx yy xx1 yy1 Hl Hl1 Hw Hw1 Hw2 Hx Hy."; - pp " case (spec_to_Z Hw xx1); auto with zarith; intros HH1 HH2."; - pp " case (spec_to_Z Hw yy1); auto with zarith; intros HH3 HH4."; - pp " rewrite <- Hx."; - pp " rewrite <- Hy."; - pp " generalize (spec_add_mul_div Hw"; - pp " (znz_0 ww_op) xx1"; - pp " (znz_sub ww_op (znz_zdigits ww_op)"; - pp " yy1)"; - pp " )."; - pp " rewrite (spec_0 Hw)."; - pp " rewrite Zmult_0_l; rewrite Zplus_0_l."; - pp " rewrite (CyclicAxioms.spec_sub Hw)."; - pp " rewrite Zmod_small; auto with zarith."; - pp " rewrite (spec_zdigits Hw)."; - pp " rewrite F0."; - pp " rewrite Zmod_small; auto with zarith."; - pp " unfold base; rewrite (spec_zdigits Hw) in Hl1 |- *;"; - pp " auto with zarith."; - pp " assert (F5: forall n m, (n <= m)%snat ->" "%"; - pp " Zpos (znz_digits (make_op n)) <= Zpos (znz_digits (make_op m)))."; - pp " intros n m HH; elim HH; clear m HH; auto with zarith."; - pp " intros m HH Hrec; apply Zle_trans with (1 := Hrec)."; - pp " rewrite make_op_S."; - pp " match goal with |- Zpos ?Y <= ?X => change X with (Zpos (xO Y)) end."; - pp " rewrite Zpos_xO."; - pp " assert (0 <= Zpos (znz_digits (make_op n))); auto with zarith."; - pp " assert (F6: forall n, Zpos (znz_digits w%i_op) <= Zpos (znz_digits (make_op n)))." size; - pp " intros n ; apply Zle_trans with (Zpos (znz_digits (make_op 0)))."; - pp " change (znz_digits (make_op 0)) with (xO (znz_digits w%i_op))." size; - pp " rewrite Zpos_xO."; - pp " assert (0 <= Zpos (znz_digits w%i_op)); auto with zarith." size; - pp " apply F5; auto with arith."; - pp " intros x; case x; clear x; unfold unsafe_shiftr, same_level."; - for i = 0 to size do - pp " intros x y; case y; clear y."; - for j = 0 to i - 1 do - pp " intros y; unfold unsafe_shiftr%i, Ndigits." i; - pp " repeat rewrite spec_reduce_%i; repeat rewrite spec_reduce_%i; unfold to_Z; intros H1." i j; - pp " apply F4 with (3:=w%i_spec)(4:=w%i_spec)(5:=w%i_spec); auto with zarith." i j i; - pp " rewrite (spec_zdigits w%i_spec)." i; - pp " rewrite (spec_zdigits w%i_spec)." j; - pp " change (znz_digits w%i_op) with %s." i (genxO (i - j) (" (znz_digits w"^(string_of_int j)^"_op)")); - pp " repeat rewrite (fun x => Zpos_xO (xO x))."; - pp " repeat rewrite (fun x y => Zpos_xO (@znz_digits x y))."; - pp " assert (0 <= Zpos (znz_digits w%i_op)); auto with zarith." j; - pp " try (apply sym_equal; exact (spec_extend%in%i y))." j i; - - done; - pp " intros y; unfold unsafe_shiftr%i, Ndigits." i; - pp " repeat rewrite spec_reduce_%i; unfold to_Z; intros H1." i; - pp " apply F4 with (3:=w%i_spec)(4:=w%i_spec)(5:=w%i_spec); auto with zarith." i i i; - for j = i + 1 to size do - pp " intros y; unfold unsafe_shiftr%i, Ndigits." j; - pp " repeat rewrite spec_reduce_%i; repeat rewrite spec_reduce_%i; unfold to_Z; intros H1." i j; - pp " apply F4 with (3:=w%i_spec)(4:=w%i_spec)(5:=w%i_spec); auto with zarith." j j i; - pp " try (apply sym_equal; exact (spec_extend%in%i x))." i j; - done; - if i == size then - begin - pp " intros m y; unfold unsafe_shiftrn, Ndigits."; - pp " repeat rewrite spec_reduce_n; unfold to_Z; intros H1."; - pp " apply F4 with (3:=(wn_spec m))(4:=wn_spec m)(5:=w%i_spec); auto with zarith." size; - pp " try (apply sym_equal; exact (spec_extend%in m x))." size; - end - else - begin - pp " intros m y; unfold unsafe_shiftrn, Ndigits."; - pp " repeat rewrite spec_reduce_n; unfold to_Z; intros H1."; - pp " apply F4 with (3:=(wn_spec m))(4:=wn_spec m)(5:=w%i_spec); auto with zarith." i; - pp " change ([Nn m (extend%i m (extend%i %i x))] = [N%i x])." size i (size - i - 1) i; - pp " rewrite <- (spec_extend%in m); rewrite <- spec_extend%in%i; auto." size i size; - end - done; - pp " intros n x y; case y; clear y;"; - pp " intros y; unfold unsafe_shiftrn, Ndigits; try rewrite spec_reduce_n."; - for i = 0 to size do - pp " try rewrite spec_reduce_%i; unfold to_Z; intros H1." i; - pp " apply F4 with (3:=(wn_spec n))(4:=w%i_spec)(5:=wn_spec n); auto with zarith." i; - pp " rewrite (spec_zdigits w%i_spec)." i; - pp " rewrite (spec_zdigits (wn_spec n))."; - pp " apply Zle_trans with (2 := F6 n)."; - pp " change (znz_digits w%i_op) with %s." size (genxO (size - i) ("(znz_digits w" ^ (string_of_int i) ^ "_op)")); - pp " repeat rewrite (fun x => Zpos_xO (xO x))."; - pp " repeat rewrite (fun x y => Zpos_xO (@znz_digits x y))."; - pp " assert (H: 0 <= Zpos (znz_digits w%i_op)); auto with zarith." i; - if i == size then - pp " change ([Nn n (extend%i n y)] = [N%i y])." size i - else - pp " change ([Nn n (extend%i n (extend%i %i y))] = [N%i y])." size i (size - i - 1) i; - pp " rewrite <- (spec_extend%in n); auto." size; - if i <> size then - pp " try (rewrite <- spec_extend%in%i; auto)." i size; - done; - pp " generalize y; clear y; intros m y."; - pp " rewrite spec_reduce_n; unfold to_Z; intros H1."; - pp " apply F4 with (3:=(wn_spec (Max.max n m)))(4:=wn_spec m)(5:=wn_spec n); auto with zarith."; - pp " rewrite (spec_zdigits (wn_spec m))."; - pp " rewrite (spec_zdigits (wn_spec (Max.max n m)))."; - pp " apply F5; auto with arith."; - pp " exact (spec_cast_r n m y)."; - pp " exact (spec_cast_l n m x)."; - pp " Qed."; - pr ""; - - (* Unsafe_Shiftl *) - for i = 0 to size do - pr " Definition unsafe_shiftl%i n x := w%i_op.(znz_add_mul_div) n x w%i_op.(znz_0)." i i i - done; - pr " Definition unsafe_shiftln n p x := (make_op n).(znz_add_mul_div) p x (make_op n).(znz_0)."; - pr " Definition unsafe_shiftl := Eval lazy beta delta [same_level] in"; - pr " same_level _ (fun n x => %s0 (unsafe_shiftl0 n x))" c; - for i = 1 to size do - pr " (fun n x => reduce_%i (unsafe_shiftl%i n x))" i i; - done; - pr " (fun n p x => reduce_n n (unsafe_shiftln n p x))."; - pr ""; - pr ""; - - - pr " Theorem spec_unsafe_shiftl: forall n x,"; - pr " [n] <= [head0 x] -> [unsafe_shiftl n x] = [x] * 2 ^ [n]."; - pa " Admitted."; - pp " Proof."; - pp " assert (F0: forall x y, x - (x - y) = y)."; - pp " intros; ring."; - pp " assert (F2: forall x y z, 0 <= x -> 0 <= y -> x < z -> 0 <= x / 2 ^ y < z)."; - pp " intros x y z HH HH1 HH2."; - pp " split; auto with zarith."; - pp " apply Zle_lt_trans with (2 := HH2); auto with zarith."; - pp " apply Zdiv_le_upper_bound; auto with zarith."; - pp " pattern x at 1; replace x with (x * 2 ^ 0); auto with zarith."; - pp " apply Zmult_le_compat_l; auto."; - pp " apply Zpower_le_monotone; auto with zarith."; - pp " rewrite Zpower_0_r; ring."; - pp " assert (F3: forall x y, 0 <= y -> y <= x -> 0 <= x - y < 2 ^ x)."; - pp " intros xx y HH HH1."; - pp " split; auto with zarith."; - pp " apply Zle_lt_trans with xx; auto with zarith."; - pp " apply Zpower2_lt_lin; auto with zarith."; - pp " assert (F4: forall ww ww1 ww2"; - pp " (ww_op: znz_op ww) (ww1_op: znz_op ww1) (ww2_op: znz_op ww2)"; - pp " xx yy xx1 yy1,"; - pp " znz_to_Z ww2_op yy <= znz_to_Z ww1_op (znz_head0 ww1_op xx) ->"; - pp " znz_to_Z ww1_op (znz_zdigits ww1_op) <= znz_to_Z ww_op (znz_zdigits ww_op) ->"; - pp " znz_spec ww_op -> znz_spec ww1_op -> znz_spec ww2_op ->"; - pp " znz_to_Z ww_op xx1 = znz_to_Z ww1_op xx ->"; - pp " znz_to_Z ww_op yy1 = znz_to_Z ww2_op yy ->"; - pp " znz_to_Z ww_op"; - pp " (znz_add_mul_div ww_op yy1"; - pp " xx1 (znz_0 ww_op)) = znz_to_Z ww1_op xx * 2 ^ znz_to_Z ww2_op yy)."; - pp " intros ww ww1 ww2 ww_op ww1_op ww2_op xx yy xx1 yy1 Hl Hl1 Hw Hw1 Hw2 Hx Hy."; - pp " case (spec_to_Z Hw xx1); auto with zarith; intros HH1 HH2."; - pp " case (spec_to_Z Hw yy1); auto with zarith; intros HH3 HH4."; - pp " rewrite <- Hx."; - pp " rewrite <- Hy."; - pp " generalize (spec_add_mul_div Hw xx1 (znz_0 ww_op) yy1)."; - pp " rewrite (spec_0 Hw)."; - pp " assert (F1: znz_to_Z ww1_op (znz_head0 ww1_op xx) <= Zpos (znz_digits ww1_op))."; - pp " case (Zle_lt_or_eq _ _ HH1); intros HH5."; - pp " apply Zlt_le_weak."; - pp " case (CyclicAxioms.spec_head0 Hw1 xx)."; - pp " rewrite <- Hx; auto."; - pp " intros _ Hu; unfold base in Hu."; - pp " case (Zle_or_lt (Zpos (znz_digits ww1_op))"; - pp " (znz_to_Z ww1_op (znz_head0 ww1_op xx))); auto; intros H1."; - pp " absurd (2 ^ (Zpos (znz_digits ww1_op)) <= 2 ^ (znz_to_Z ww1_op (znz_head0 ww1_op xx)))."; - pp " apply Zlt_not_le."; - pp " case (spec_to_Z Hw1 xx); intros HHx3 HHx4."; - pp " rewrite <- (Zmult_1_r (2 ^ znz_to_Z ww1_op (znz_head0 ww1_op xx)))."; - pp " apply Zle_lt_trans with (2 := Hu)."; - pp " apply Zmult_le_compat_l; auto with zarith."; - pp " apply Zpower_le_monotone; auto with zarith."; - pp " rewrite (CyclicAxioms.spec_head00 Hw1 xx); auto with zarith."; - pp " rewrite Zdiv_0_l; auto with zarith."; - pp " rewrite Zplus_0_r."; - pp " case (Zle_lt_or_eq _ _ HH1); intros HH5."; - pp " rewrite Zmod_small; auto with zarith."; - pp " intros HH; apply HH."; - pp " rewrite Hy; apply Zle_trans with (1:= Hl)."; - pp " rewrite <- (spec_zdigits Hw)."; - pp " apply Zle_trans with (2 := Hl1); auto."; - pp " rewrite (spec_zdigits Hw1); auto with zarith."; - pp " split; auto with zarith ."; - pp " apply Zlt_le_trans with (base (znz_digits ww1_op))."; - pp " rewrite Hx."; - pp " case (CyclicAxioms.spec_head0 Hw1 xx); auto."; - pp " rewrite <- Hx; auto."; - pp " intros _ Hu; rewrite Zmult_comm in Hu."; - pp " apply Zle_lt_trans with (2 := Hu)."; - pp " apply Zmult_le_compat_l; auto with zarith."; - pp " apply Zpower_le_monotone; auto with zarith."; - pp " unfold base; apply Zpower_le_monotone; auto with zarith."; - pp " split; auto with zarith."; - pp " rewrite <- (spec_zdigits Hw); auto with zarith."; - pp " rewrite <- (spec_zdigits Hw1); auto with zarith."; - pp " rewrite <- HH5."; - pp " rewrite Zmult_0_l."; - pp " rewrite Zmod_small; auto with zarith."; - pp " intros HH; apply HH."; - pp " rewrite Hy; apply Zle_trans with (1 := Hl)."; - pp " rewrite (CyclicAxioms.spec_head00 Hw1 xx); auto with zarith."; - pp " rewrite <- (spec_zdigits Hw); auto with zarith."; - pp " rewrite <- (spec_zdigits Hw1); auto with zarith."; - pp " assert (F5: forall n m, (n <= m)%snat ->" "%"; - pp " Zpos (znz_digits (make_op n)) <= Zpos (znz_digits (make_op m)))."; - pp " intros n m HH; elim HH; clear m HH; auto with zarith."; - pp " intros m HH Hrec; apply Zle_trans with (1 := Hrec)."; - pp " rewrite make_op_S."; - pp " match goal with |- Zpos ?Y <= ?X => change X with (Zpos (xO Y)) end."; - pp " rewrite Zpos_xO."; - pp " assert (0 <= Zpos (znz_digits (make_op n))); auto with zarith."; - pp " assert (F6: forall n, Zpos (znz_digits w%i_op) <= Zpos (znz_digits (make_op n)))." size; - pp " intros n ; apply Zle_trans with (Zpos (znz_digits (make_op 0)))."; - pp " change (znz_digits (make_op 0)) with (xO (znz_digits w%i_op))." size; - pp " rewrite Zpos_xO."; - pp " assert (0 <= Zpos (znz_digits w%i_op)); auto with zarith." size; - pp " apply F5; auto with arith."; - pp " intros x; case x; clear x; unfold unsafe_shiftl, same_level."; - for i = 0 to size do - pp " intros x y; case y; clear y."; - for j = 0 to i - 1 do - pp " intros y; unfold unsafe_shiftl%i, head0." i; - pp " repeat rewrite spec_reduce_%i; repeat rewrite spec_reduce_%i; unfold to_Z; intros H1." i j; - pp " apply F4 with (3:=w%i_spec)(4:=w%i_spec)(5:=w%i_spec); auto with zarith." i j i; - pp " rewrite (spec_zdigits w%i_spec)." i; - pp " rewrite (spec_zdigits w%i_spec)." j; - pp " change (znz_digits w%i_op) with %s." i (genxO (i - j) (" (znz_digits w"^(string_of_int j)^"_op)")); - pp " repeat rewrite (fun x => Zpos_xO (xO x))."; - pp " repeat rewrite (fun x y => Zpos_xO (@znz_digits x y))."; - pp " assert (0 <= Zpos (znz_digits w%i_op)); auto with zarith." j; - pp " try (apply sym_equal; exact (spec_extend%in%i y))." j i; - done; - pp " intros y; unfold unsafe_shiftl%i, head0." i; - pp " repeat rewrite spec_reduce_%i; unfold to_Z; intros H1." i; - pp " apply F4 with (3:=w%i_spec)(4:=w%i_spec)(5:=w%i_spec); auto with zarith." i i i; - for j = i + 1 to size do - pp " intros y; unfold unsafe_shiftl%i, head0." j; - pp " repeat rewrite spec_reduce_%i; repeat rewrite spec_reduce_%i; unfold to_Z; intros H1." i j; - pp " apply F4 with (3:=w%i_spec)(4:=w%i_spec)(5:=w%i_spec); auto with zarith." j j i; - pp " try (apply sym_equal; exact (spec_extend%in%i x))." i j; - done; - if i == size then - begin - pp " intros m y; unfold unsafe_shiftln, head0."; - pp " repeat rewrite spec_reduce_n; unfold to_Z; intros H1."; - pp " apply F4 with (3:=(wn_spec m))(4:=wn_spec m)(5:=w%i_spec); auto with zarith." size; - pp " try (apply sym_equal; exact (spec_extend%in m x))." size; - end - else - begin - pp " intros m y; unfold unsafe_shiftln, head0."; - pp " repeat rewrite spec_reduce_n; unfold to_Z; intros H1."; - pp " apply F4 with (3:=(wn_spec m))(4:=wn_spec m)(5:=w%i_spec); auto with zarith." i; - pp " change ([Nn m (extend%i m (extend%i %i x))] = [N%i x])." size i (size - i - 1) i; - pp " rewrite <- (spec_extend%in m); rewrite <- spec_extend%in%i; auto." size i size; - end - done; - pp " intros n x y; case y; clear y;"; - pp " intros y; unfold unsafe_shiftln, head0; try rewrite spec_reduce_n."; - for i = 0 to size do - pp " try rewrite spec_reduce_%i; unfold to_Z; intros H1." i; - pp " apply F4 with (3:=(wn_spec n))(4:=w%i_spec)(5:=wn_spec n); auto with zarith." i; - pp " rewrite (spec_zdigits w%i_spec)." i; - pp " rewrite (spec_zdigits (wn_spec n))."; - pp " apply Zle_trans with (2 := F6 n)."; - pp " change (znz_digits w%i_op) with %s." size (genxO (size - i) ("(znz_digits w" ^ (string_of_int i) ^ "_op)")); - pp " repeat rewrite (fun x => Zpos_xO (xO x))."; - pp " repeat rewrite (fun x y => Zpos_xO (@znz_digits x y))."; - pp " assert (H: 0 <= Zpos (znz_digits w%i_op)); auto with zarith." i; - if i == size then - pp " change ([Nn n (extend%i n y)] = [N%i y])." size i - else - pp " change ([Nn n (extend%i n (extend%i %i y))] = [N%i y])." size i (size - i - 1) i; - pp " rewrite <- (spec_extend%in n); auto." size; - if i <> size then - pp " try (rewrite <- spec_extend%in%i; auto)." i size; - done; - pp " generalize y; clear y; intros m y."; - pp " repeat rewrite spec_reduce_n; unfold to_Z; intros H1."; - pp " apply F4 with (3:=(wn_spec (Max.max n m)))(4:=wn_spec m)(5:=wn_spec n); auto with zarith."; - pp " rewrite (spec_zdigits (wn_spec m))."; - pp " rewrite (spec_zdigits (wn_spec (Max.max n m)))."; - pp " apply F5; auto with arith."; - pp " exact (spec_cast_r n m y)."; - pp " exact (spec_cast_l n m x)."; - pp " Qed."; - pr ""; - - (* Double size *) - pr " Definition double_size w := match w with"; - for i = 0 to size-1 do - pr " | %s%i x => %s%i (WW (znz_0 w%i_op) x)" c i c (i + 1) i; - done; - pr " | %s%i x => %sn 0 (WW (znz_0 w%i_op) x)" c size c size; - pr " | %sn n x => %sn (S n) (WW (znz_0 (make_op n)) x)" c c; - pr " end."; - pr ""; - - pr " Theorem spec_double_size_digits:"; - pr " forall x, digits (double_size x) = xO (digits x)."; - pa " Admitted."; - pp " Proof."; - pp " intros x; case x; unfold double_size, digits; clear x; auto."; - pp " intros n x; rewrite make_op_S; auto."; - pp " Qed."; - pr ""; - - - pr " Theorem spec_double_size: forall x, [double_size x] = [x]."; - pa " Admitted."; - pp " Proof."; - pp " intros x; case x; unfold double_size; clear x."; - for i = 0 to size do - pp " intros x; unfold to_Z, make_op;"; - pp " rewrite znz_to_Z_%i; rewrite (spec_0 w%i_spec); auto with zarith." (i + 1) i; - done; - pp " intros n x; unfold to_Z;"; - pp " generalize (znz_to_Z_n n); simpl word."; - pp " intros HH; rewrite HH; clear HH."; - pp " generalize (spec_0 (wn_spec n)); simpl word."; - pp " intros HH; rewrite HH; clear HH; auto with zarith."; - pp " Qed."; - pr ""; - - - pr " Theorem spec_double_size_head0:"; - pr " forall x, 2 * [head0 x] <= [head0 (double_size x)]."; - pa " Admitted."; - pp " Proof."; - pp " intros x."; - pp " assert (F1:= spec_pos (head0 x))."; - pp " assert (F2: 0 < Zpos (digits x))."; - pp " red; auto."; - pp " case (Zle_lt_or_eq _ _ (spec_pos x)); intros HH."; - pp " generalize HH; rewrite <- (spec_double_size x); intros HH1."; - pp " case (spec_head0 x HH); intros _ HH2."; - pp " case (spec_head0 _ HH1)."; - pp " rewrite (spec_double_size x); rewrite (spec_double_size_digits x)."; - pp " intros HH3 _."; - pp " case (Zle_or_lt ([head0 (double_size x)]) (2 * [head0 x])); auto; intros HH4."; - pp " absurd (2 ^ (2 * [head0 x] )* [x] < 2 ^ [head0 (double_size x)] * [x]); auto."; - pp " apply Zle_not_lt."; - pp " apply Zmult_le_compat_r; auto with zarith."; - pp " apply Zpower_le_monotone; auto; auto with zarith."; - pp " generalize (spec_pos (head0 (double_size x))); auto with zarith."; - pp " assert (HH5: 2 ^[head0 x] <= 2 ^(Zpos (digits x) - 1))."; - pp " case (Zle_lt_or_eq 1 [x]); auto with zarith; intros HH5."; - pp " apply Zmult_le_reg_r with (2 ^ 1); auto with zarith."; - pp " rewrite <- (fun x y z => Zpower_exp x (y - z)); auto with zarith."; - pp " assert (tmp: forall x, x - 1 + 1 = x); [intros; ring | rewrite tmp; clear tmp]."; - pp " apply Zle_trans with (2 := Zlt_le_weak _ _ HH2)."; - pp " apply Zmult_le_compat_l; auto with zarith."; - pp " rewrite Zpower_1_r; auto with zarith."; - pp " apply Zpower_le_monotone; auto with zarith."; - pp " split; auto with zarith."; - pp " case (Zle_or_lt (Zpos (digits x)) [head0 x]); auto with zarith; intros HH6."; - pp " absurd (2 ^ Zpos (digits x) <= 2 ^ [head0 x] * [x]); auto with zarith."; - pp " rewrite <- HH5; rewrite Zmult_1_r."; - pp " apply Zpower_le_monotone; auto with zarith."; - pp " rewrite (Zmult_comm 2)."; - pp " rewrite Zpower_mult; auto with zarith."; - pp " rewrite Zpower_2."; - pp " apply Zlt_le_trans with (2 := HH3)."; - pp " rewrite <- Zmult_assoc."; - pp " replace (Zpos (xO (digits x)) - 1) with"; - pp " ((Zpos (digits x) - 1) + (Zpos (digits x)))."; - pp " rewrite Zpower_exp; auto with zarith."; - pp " apply Zmult_lt_compat2; auto with zarith."; - pp " split; auto with zarith."; - pp " apply Zmult_lt_0_compat; auto with zarith."; - pp " rewrite Zpos_xO; ring."; - pp " apply Zlt_le_weak; auto."; - pp " repeat rewrite spec_head00; auto."; - pp " rewrite spec_double_size_digits."; - pp " rewrite Zpos_xO; auto with zarith."; - pp " rewrite spec_double_size; auto."; - pp " Qed."; - pr ""; - - pr " Theorem spec_double_size_head0_pos:"; - pr " forall x, 0 < [head0 (double_size x)]."; - pa " Admitted."; - pp " Proof."; - pp " intros x."; - pp " assert (F: 0 < Zpos (digits x))."; - pp " red; auto."; - pp " case (Zle_lt_or_eq _ _ (spec_pos (head0 (double_size x)))); auto; intros F0."; - pp " case (Zle_lt_or_eq _ _ (spec_pos (head0 x))); intros F1."; - pp " apply Zlt_le_trans with (2 := (spec_double_size_head0 x)); auto with zarith."; - pp " case (Zle_lt_or_eq _ _ (spec_pos x)); intros F3."; - pp " generalize F3; rewrite <- (spec_double_size x); intros F4."; - pp " absurd (2 ^ (Zpos (xO (digits x)) - 1) < 2 ^ (Zpos (digits x)))."; - pp " apply Zle_not_lt."; - pp " apply Zpower_le_monotone; auto with zarith."; - pp " split; auto with zarith."; - pp " rewrite Zpos_xO; auto with zarith."; - pp " case (spec_head0 x F3)."; - pp " rewrite <- F1; rewrite Zpower_0_r; rewrite Zmult_1_l; intros _ HH."; - pp " apply Zle_lt_trans with (2 := HH)."; - pp " case (spec_head0 _ F4)."; - pp " rewrite (spec_double_size x); rewrite (spec_double_size_digits x)."; - pp " rewrite <- F0; rewrite Zpower_0_r; rewrite Zmult_1_l; auto."; - pp " generalize F1; rewrite (spec_head00 _ (sym_equal F3)); auto with zarith."; - pp " Qed."; - pr ""; - - (* even *) - pr " Definition is_even x :="; - pr " match x with"; - for i = 0 to size do - pr " | %s%i wx => w%i_op.(znz_is_even) wx" c i i - done; - pr " | %sn n wx => (make_op n).(znz_is_even) wx" c; - pr " end."; - pr ""; - - - pr " Theorem spec_is_even: forall x,"; - pr " if is_even x then [x] mod 2 = 0 else [x] mod 2 = 1."; - pa " Admitted."; - pp " Proof."; - pp " intros x; case x; unfold is_even, to_Z; clear x."; - for i = 0 to size do - pp " intros x; exact (spec_is_even w%i_spec x)." i; - done; - pp " intros n x; exact (spec_is_even (wn_spec n) x)."; - pp " Qed."; - pr ""; - - pr "End Make."; - pr ""; - + pr " Eval lazy beta iota delta [reduce_n] in"; + pr " reduce_n _ _ (N0 zero0) reduce_%i Nn n." (size + 1); + pr ""; + +pr " Definition reduce n : dom_t n -> t :="; +pr " match n with"; +for i = 0 to size do +pr " | %i => reduce_%i" i i; +done; +pr " | %s(S n) => reduce_n n" (if size=0 then "" else "SizePlus "); +pr " end."; +pr ""; + +pr " Ltac unfold_red := unfold reduce, %s." (iter_name 1 size "reduce_" ","); + +pr " + Ltac solve_red := + let H := fresh in let G := fresh in + match goal with + | |- ?P (S ?n) => assert (H:P n) by solve_red + | _ => idtac + end; + intros n G x; destruct (le_lt_eq_dec _ _ G) as [LT|EQ]; + solve [ + apply (H _ (lt_n_Sm_le _ _ LT)) | + inversion LT | + subst; change (reduce 0 x = red_t 0 x); reflexivity | + specialize (H (pred n)); subst; destruct x; + [|unfold_red; rewrite H; auto]; reflexivity + ]. + + Lemma reduce_equiv : forall n x, n <= Size -> reduce n x = red_t n x. + Proof. + set (P N := forall n, n <= N -> forall x, reduce n x = red_t n x). + intros n x H. revert n H x. change (P Size). solve_red. + Qed. + + Lemma spec_reduce_n : forall n x, [reduce_n n x] = [Nn n x]. + Proof. + assert (H : forall x, reduce_%i x = red_t (SizePlus 1) x). + destruct x; [|unfold reduce_%i; rewrite (reduce_equiv Size)]; auto. + induction n. + intros. rewrite H. apply spec_red_t. + destruct x as [|xh xl]. + simpl. rewrite make_op_S. exact ZnZ.spec_0. + fold word in *. + destruct xh; auto. + simpl reduce_n. + rewrite IHn. + rewrite spec_extend_WW; auto. + Qed. +" (size+1) (size+1); + +pr +" Lemma spec_reduce : forall n x, [reduce n x] = ZnZ.to_Z x. + Proof. + do_size (destruct n; + [intros; rewrite reduce_equiv;[apply spec_red_t|auto with arith]|]). + apply spec_reduce_n. + Qed. + +End Make. +"; -- cgit v1.2.3