diff options
Diffstat (limited to 'theories/Numbers/Natural/BigN')
-rw-r--r-- | theories/Numbers/Natural/BigN/BigN.v | 139 | ||||
-rw-r--r-- | theories/Numbers/Natural/BigN/NMake.v | 6809 | ||||
-rw-r--r-- | theories/Numbers/Natural/BigN/Nbasic.v | 510 | ||||
-rw-r--r-- | theories/Numbers/Natural/BigN/genN.ml | 3407 |
4 files changed, 10865 insertions, 0 deletions
diff --git a/theories/Numbers/Natural/BigN/BigN.v b/theories/Numbers/Natural/BigN/BigN.v new file mode 100644 index 000000000..b64a853fd --- /dev/null +++ b/theories/Numbers/Natural/BigN/BigN.v @@ -0,0 +1,139 @@ +(************************************************************************) +(* v * The Coq Proof Assistant / The Coq Development Team *) +(* <O___,, * CNRS-Ecole Polytechnique-INRIA Futurs-Universite Paris Sud *) +(* \VV/ **************************************************************) +(* // * This file is distributed under the terms of the *) +(* * GNU Lesser General Public License Version 2.1 *) +(************************************************************************) + +(** * Natural numbers in base 2^31 *) + +(** +Author: Arnaud Spiwack +*) + +Require Export Int31. +Require Import NMake. +Require Import ZnZ. + +Open Scope int31_scope. + +Definition int31_op : znz_op int31. + split. + + (* Conversion functions with Z *) + exact (31%positive). (* number of digits *) + exact (31). (* number of digits *) + exact (phi). (* conversion to Z *) + exact (positive_to_int31). (* positive -> N*int31 : p => N,i where p = N*2^31+phi i *) + exact head031. (* number of head 0 *) + exact tail031. (* number of tail 0 *) + + (* Basic constructors *) + exact 0. (* 0 *) + exact 1. (* 1 *) + exact Tn. (* 2^31 - 1 *) + (* A function which given two int31 i and j, returns a double word + which is worth i*2^31+j *) + exact (fun i j => match (match i ?= 0 with | Eq => j ?= 0 | not0 => not0 end) with | Eq => W0 | _ => WW i j end). + (* two special cases where i and j are respectively taken equal to 0 *) + exact (fun i => match i ?= 0 with | Eq => W0 | _ => WW i 0 end). + exact (fun j => match j ?= 0 with | Eq => W0 | _ => WW 0 j end). + + (* Comparison *) + exact compare31. + exact (fun i => match i ?= 0 with | Eq => true | _ => false end). + + (* Basic arithmetic operations *) + (* opposite functions *) + exact (fun i => 0 -c i). + exact (fun i => 0 - i). + exact (fun i => 0-i-1). (* the carry is always -1*) + (* successor and addition functions *) + exact (fun i => i +c 1). + exact add31c. + exact add31carryc. + exact (fun i => i + 1). + exact add31. + exact (fun i j => i + j + 1). + (* predecessor and subtraction functions *) + exact (fun i => i -c 1). + exact sub31c. + exact sub31carryc. + exact (fun i => i - 1). + exact sub31. + exact (fun i j => i - j - 1). + (* multiplication functions *) + exact mul31c. + exact mul31. + exact (fun x => x *c x). + + (* special (euclidian) division operations *) + exact div3121. + exact div31. (* this is supposed to be the special case of division a/b where a > b *) + exact div31. + (* euclidian division remainder *) + (* again special case for a > b *) + exact (fun i j => let (_,r) := i/j in r). + exact (fun i j => let (_,r) := i/j in r). + (* gcd functions *) + exact gcd31. (*gcd_gt*) + exact gcd31. (*gcd*) + + (* shift operations *) + exact addmuldiv31. (*add_mul_div *) +(*modulo 2^p *) + exact (fun p i => + match compare31 p 32 with + | Lt => addmuldiv31 p 0 (addmuldiv31 (31-p) i 0) + | _ => i + end). + + (* is i even ? *) + exact (fun i => let (_,r) := i/2 in + match r ?= 0 with + | Eq => true + | _ => false + end). + + (* square root operations *) + exact sqrt312. (* sqrt2 *) + exact sqrt31. (* sqr *) +Defined. + +Definition int31_spec : znz_spec int31_op. +Admitted. + + + +Module Int31_words <: W0Type. + Definition w := int31. + Definition w_op := int31_op. + Definition w_spec := int31_spec. +End Int31_words. + +Module BigN := NMake.Make Int31_words. + +Definition bigN := BigN.t. + +Delimit Scope bigN_scope with bigN. +Bind Scope bigN_scope with bigN. +Bind Scope bigN_scope with BigN.t. +Bind Scope bigN_scope with BigN.t_. + +Notation " i + j " := (BigN.add i j) : bigN_scope. +Notation " i - j " := (BigN.sub i j) : bigN_scope. +Notation " i * j " := (BigN.mul i j) : bigN_scope. +Notation " i / j " := (BigN.div i j) : bigN_scope. +Notation " i ?= j " := (BigN.compare i j) : bigN_scope. + + Theorem succ_pred: forall q, + (0 < BigN.to_Z q -> + BigN.to_Z (BigN.succ (BigN.pred q)) = BigN.to_Z q)%Z. + intros q Hq. + rewrite BigN.spec_succ. + rewrite BigN.spec_pred; auto. + generalize Hq; set (a := BigN.to_Z q). + ring_simplify (a - 1 + 1)%Z; auto. + Qed. + diff --git a/theories/Numbers/Natural/BigN/NMake.v b/theories/Numbers/Natural/BigN/NMake.v new file mode 100644 index 000000000..6705c1898 --- /dev/null +++ b/theories/Numbers/Natural/BigN/NMake.v @@ -0,0 +1,6809 @@ +(************************************************************************) +(* v * The Coq Proof Assistant / The Coq Development Team *) +(* <O___,, * CNRS-Ecole Polytechnique-INRIA Futurs-Universite Paris Sud *) +(* \VV/ **************************************************************) +(* // * This file is distributed under the terms of the *) +(* * GNU Lesser General Public License Version 2.1 *) +(************************************************************************) + +(* $Id$ *) + +(** * *) + +(** +- Authors: Benjamin Grégoire, Laurent Théry +- Institution: INRIA +- Date: 2007 +- Remark: File automatically generated +*) + +Require Import BigNumPrelude. +Require Import ZArith. +Require Import Basic_type. +Require Import ZnZ. +Require Import Zn2Z. +Require Import Nbasic. +Require Import GenMul. +Require Import GenDivn1. +Require Import Wf_nat. +Require Import StreamMemo. + +Module Type W0Type. + Parameter w : Set. + Parameter w_op : znz_op w. + Parameter w_spec : znz_spec w_op. +End W0Type. + +Module Make (W0:W0Type). + Import W0. + + Definition w0 := W0.w. + Definition w1 := zn2z w0. + Definition w2 := zn2z w1. + Definition w3 := zn2z w2. + Definition w4 := zn2z w3. + Definition w5 := zn2z w4. + Definition w6 := zn2z w5. + + Definition w0_op := W0.w_op. + Definition w1_op := mk_zn2z_op w0_op. + Definition w2_op := mk_zn2z_op w1_op. + Definition w3_op := mk_zn2z_op w2_op. + Definition w4_op := mk_zn2z_op_karatsuba w3_op. + Definition w5_op := mk_zn2z_op_karatsuba w4_op. + Definition w6_op := mk_zn2z_op_karatsuba w5_op. + Definition w7_op := mk_zn2z_op_karatsuba w6_op. + Definition w8_op := mk_zn2z_op_karatsuba w7_op. + Definition w9_op := mk_zn2z_op_karatsuba w8_op. + + Section Make_op. + Variable mk : forall w', znz_op w' -> znz_op (zn2z w'). + + Fixpoint make_op_aux (n:nat) : znz_op (word w6 (S n)):= + match n return znz_op (word w6 (S n)) with + | O => w7_op + | S n1 => + match n1 return znz_op (word w6 (S (S n1))) with + | O => w8_op + | S n2 => + match n2 return znz_op (word w6 (S (S (S n2)))) with + | O => w9_op + | S n3 => mk _ (mk _ (mk _ (make_op_aux n3))) + end + end + end. + + End Make_op. + + Definition omake_op := make_op_aux mk_zn2z_op_karatsuba. + + + Definition make_op_list := dmemo_list _ omake_op. + + Definition make_op n := dmemo_get _ omake_op n make_op_list. + + Lemma make_op_omake: forall n, make_op n = omake_op n. + intros n; unfold make_op, make_op_list. + refine (dmemo_get_correct _ _ _). + Qed. + + Inductive t_ : Set := + | N0 : w0 -> t_ + | N1 : w1 -> t_ + | N2 : w2 -> t_ + | N3 : w3 -> t_ + | N4 : w4 -> t_ + | N5 : w5 -> t_ + | N6 : w6 -> t_ + | Nn : forall n, word w6 (S n) -> t_. + + Definition t := t_. + + Definition w_0 := w0_op.(znz_0). + + Definition one0 := w0_op.(znz_1). + Definition one1 := w1_op.(znz_1). + Definition one2 := w2_op.(znz_1). + Definition one3 := w3_op.(znz_1). + Definition one4 := w4_op.(znz_1). + Definition one5 := w5_op.(znz_1). + Definition one6 := w6_op.(znz_1). + + Definition zero := N0 w_0. + Definition one := N0 one0. + + Definition to_Z x := + match x with + | N0 wx => w0_op.(znz_to_Z) wx + | N1 wx => w1_op.(znz_to_Z) wx + | N2 wx => w2_op.(znz_to_Z) wx + | N3 wx => w3_op.(znz_to_Z) wx + | N4 wx => w4_op.(znz_to_Z) wx + | N5 wx => w5_op.(znz_to_Z) wx + | N6 wx => w6_op.(znz_to_Z) wx + | Nn n wx => (make_op n).(znz_to_Z) wx + end. + + Open Scope Z_scope. + Notation "[ x ]" := (to_Z x). + + (* Regular make op (no karatsuba) *) + Fixpoint nmake_op (ww:Set) (ww_op: znz_op ww) (n: nat) : + znz_op (word ww n) := + match n return znz_op (word ww n) with + O => ww_op + | S n1 => mk_zn2z_op (nmake_op ww ww_op n1) + end. + + (* Simplification by rewriting for nmake_op *) + Theorem nmake_op_S: forall ww (w_op: znz_op ww) x, + nmake_op _ w_op (S x) = mk_zn2z_op (nmake_op _ w_op x). + auto. + Qed. + + (* Eval and extend functions for each level *) + Let nmake_op0 := nmake_op _ w0_op. + Let eval0n n := znz_to_Z (nmake_op0 n). + Let extend0 := GenBase.extend (WW w_0). + Let nmake_op1 := nmake_op _ w1_op. + Let eval1n n := znz_to_Z (nmake_op1 n). + Let extend1 := GenBase.extend (WW (W0: w1)). + Let nmake_op2 := nmake_op _ w2_op. + Let eval2n n := znz_to_Z (nmake_op2 n). + Let extend2 := GenBase.extend (WW (W0: w2)). + Let nmake_op3 := nmake_op _ w3_op. + Let eval3n n := znz_to_Z (nmake_op3 n). + Let extend3 := GenBase.extend (WW (W0: w3)). + Let nmake_op4 := nmake_op _ w4_op. + Let eval4n n := znz_to_Z (nmake_op4 n). + Let extend4 := GenBase.extend (WW (W0: w4)). + Let nmake_op5 := nmake_op _ w5_op. + Let eval5n n := znz_to_Z (nmake_op5 n). + Let extend5 := GenBase.extend (WW (W0: w5)). + Let nmake_op6 := nmake_op _ w6_op. + Let eval6n n := znz_to_Z (nmake_op6 n). + Let extend6 := GenBase.extend (WW (W0: w6)). + + Theorem digits_gend:forall n ww (w_op: znz_op ww), + znz_digits (nmake_op _ w_op n) = + GenBase.gen_digits (znz_digits w_op) n. + Proof. intros n; elim n; auto; clear n. + intros n Hrec ww ww_op; simpl GenBase.gen_digits. + rewrite <- Hrec; auto. + Qed. + + Theorem nmake_gen: forall n ww (w_op: znz_op ww), + znz_to_Z (nmake_op _ w_op n) = + @GenBase.gen_to_Z _ (znz_digits w_op) (znz_to_Z w_op) n. + Proof. intros n; elim n; auto; clear n. + intros n Hrec ww ww_op; simpl GenBase.gen_to_Z; unfold zn2z_to_Z. + rewrite <- Hrec; auto. + unfold GenBase.gen_wB; rewrite <- digits_gend; auto. + Qed. + + Theorem digits_nmake:forall n ww (w_op: znz_op ww), + znz_digits (nmake_op _ w_op (S n)) = + xO (znz_digits (nmake_op _ w_op n)). + Proof. + auto. + Qed. + + Theorem znz_nmake_op: forall ww ww_op n xh xl, + znz_to_Z (nmake_op ww ww_op (S n)) (WW xh xl) = + znz_to_Z (nmake_op ww ww_op n) xh * + base (znz_digits (nmake_op ww ww_op n)) + + znz_to_Z (nmake_op ww ww_op n) xl. + Proof. + auto. + Qed. + + Theorem make_op_S: forall n, + make_op (S n) = mk_zn2z_op_karatsuba (make_op n). + intro n. + do 2 rewrite make_op_omake. + pattern n; apply lt_wf_ind; clear n. + intros n; case n; clear n. + intros _; unfold omake_op, make_op_aux, w8_op; apply refl_equal. + intros n; case n; clear n. + intros _; unfold omake_op, make_op_aux, w9_op; apply refl_equal. + intros n; case n; clear n. + intros _; unfold omake_op, make_op_aux, w9_op, w8_op; apply refl_equal. + intros n Hrec. + change (omake_op (S (S (S (S n))))) with + (mk_zn2z_op_karatsuba (mk_zn2z_op_karatsuba (mk_zn2z_op_karatsuba (omake_op (S n))))). + change (omake_op (S (S (S n)))) with + (mk_zn2z_op_karatsuba (mk_zn2z_op_karatsuba (mk_zn2z_op_karatsuba (omake_op n)))). + rewrite Hrec; auto with arith. + Qed. + + Let znz_to_Z_1: forall x y, + znz_to_Z w1_op (WW x y) = + znz_to_Z w0_op x * base (znz_digits w0_op) + znz_to_Z w0_op y. + Proof. + auto. + Qed. + + Let znz_to_Z_2: forall x y, + znz_to_Z w2_op (WW x y) = + znz_to_Z w1_op x * base (znz_digits w1_op) + znz_to_Z w1_op y. + Proof. + auto. + Qed. + + Let znz_to_Z_3: forall x y, + znz_to_Z w3_op (WW x y) = + znz_to_Z w2_op x * base (znz_digits w2_op) + znz_to_Z w2_op y. + Proof. + auto. + Qed. + + Let znz_to_Z_4: forall x y, + znz_to_Z w4_op (WW x y) = + znz_to_Z w3_op x * base (znz_digits w3_op) + znz_to_Z w3_op y. + Proof. + auto. + Qed. + + Let znz_to_Z_5: forall x y, + znz_to_Z w5_op (WW x y) = + znz_to_Z w4_op x * base (znz_digits w4_op) + znz_to_Z w4_op y. + Proof. + auto. + Qed. + + Let znz_to_Z_6: forall x y, + znz_to_Z w6_op (WW x y) = + znz_to_Z w5_op x * base (znz_digits w5_op) + znz_to_Z w5_op y. + Proof. + auto. + Qed. + + Let znz_to_Z_7: forall x y, + znz_to_Z w7_op (WW x y) = + znz_to_Z w6_op x * base (znz_digits w6_op) + znz_to_Z w6_op y. + Proof. + auto. + Qed. + + Let znz_to_Z_8: forall x y, + znz_to_Z w8_op (WW x y) = + znz_to_Z w7_op x * base (znz_digits w7_op) + znz_to_Z w7_op y. + Proof. + auto. + Qed. + + Let znz_to_Z_n: forall n x y, + znz_to_Z (make_op (S n)) (WW x y) = + znz_to_Z (make_op n) x * base (znz_digits (make_op n)) + znz_to_Z (make_op n) y. + Proof. + intros n x y; rewrite make_op_S; auto. + Qed. + + Let w0_spec: znz_spec w0_op := W0.w_spec. + Let w1_spec: znz_spec w1_op := mk_znz2_spec w0_spec. + Let w2_spec: znz_spec w2_op := mk_znz2_spec w1_spec. + Let w3_spec: znz_spec w3_op := mk_znz2_spec w2_spec. + Let w4_spec : znz_spec w4_op := mk_znz2_karatsuba_spec w3_spec. + Let w5_spec : znz_spec w5_op := mk_znz2_karatsuba_spec w4_spec. + Let w6_spec : znz_spec w6_op := mk_znz2_karatsuba_spec w5_spec. + Let w7_spec : znz_spec w7_op := mk_znz2_karatsuba_spec w6_spec. + Let w8_spec : znz_spec w8_op := mk_znz2_karatsuba_spec w7_spec. + Let w9_spec : znz_spec w9_op := mk_znz2_karatsuba_spec w8_spec. + + Let wn_spec: forall n, znz_spec (make_op n). + intros n; elim n; clear n. + exact w7_spec. + intros n Hrec; rewrite make_op_S. + exact (mk_znz2_karatsuba_spec Hrec). + Qed. + + Definition w0_eq0 := w0_op.(znz_eq0). + Let spec_w0_eq0: forall x, if w0_eq0 x then [N0 x] = 0 else True. + intros x; unfold w0_eq0, to_Z; generalize (spec_eq0 w0_spec x); + case znz_eq0; auto. + Qed. + + Definition w1_eq0 := w1_op.(znz_eq0). + Let spec_w1_eq0: forall x, if w1_eq0 x then [N1 x] = 0 else True. + intros x; unfold w1_eq0, to_Z; generalize (spec_eq0 w1_spec x); + case znz_eq0; auto. + Qed. + + Definition w2_eq0 := w2_op.(znz_eq0). + Let spec_w2_eq0: forall x, if w2_eq0 x then [N2 x] = 0 else True. + intros x; unfold w2_eq0, to_Z; generalize (spec_eq0 w2_spec x); + case znz_eq0; auto. + Qed. + + Definition w3_eq0 := w3_op.(znz_eq0). + Let spec_w3_eq0: forall x, if w3_eq0 x then [N3 x] = 0 else True. + intros x; unfold w3_eq0, to_Z; generalize (spec_eq0 w3_spec x); + case znz_eq0; auto. + Qed. + + Definition w4_eq0 := w4_op.(znz_eq0). + Let spec_w4_eq0: forall x, if w4_eq0 x then [N4 x] = 0 else True. + intros x; unfold w4_eq0, to_Z; generalize (spec_eq0 w4_spec x); + case znz_eq0; auto. + Qed. + + Definition w5_eq0 := w5_op.(znz_eq0). + Let spec_w5_eq0: forall x, if w5_eq0 x then [N5 x] = 0 else True. + intros x; unfold w5_eq0, to_Z; generalize (spec_eq0 w5_spec x); + case znz_eq0; auto. + Qed. + + Definition w6_eq0 := w6_op.(znz_eq0). + Let spec_w6_eq0: forall x, if w6_eq0 x then [N6 x] = 0 else True. + intros x; unfold w6_eq0, to_Z; generalize (spec_eq0 w6_spec x); + case znz_eq0; auto. + Qed. + + + Theorem digits_w0: znz_digits w0_op = znz_digits (nmake_op _ w0_op 0). + auto. + Qed. + + Let spec_gen_eval0n: forall n, eval0n n = GenBase.gen_to_Z (znz_digits w0_op) (znz_to_Z w0_op) n. + intros n; exact (nmake_gen n w0 w0_op). + Qed. + + Theorem digits_w1: znz_digits w1_op = znz_digits (nmake_op _ w0_op 1). + rewrite digits_nmake; rewrite <- digits_w0; auto. + Qed. + + Let spec_gen_eval1n: forall n, eval1n n = GenBase.gen_to_Z (znz_digits w1_op) (znz_to_Z w1_op) n. + intros n; exact (nmake_gen n w1 w1_op). + Qed. + + Theorem digits_w2: znz_digits w2_op = znz_digits (nmake_op _ w0_op 2). + rewrite digits_nmake; rewrite <- digits_w1; auto. + Qed. + + Let spec_gen_eval2n: forall n, eval2n n = GenBase.gen_to_Z (znz_digits w2_op) (znz_to_Z w2_op) n. + intros n; exact (nmake_gen n w2 w2_op). + Qed. + + Theorem digits_w3: znz_digits w3_op = znz_digits (nmake_op _ w0_op 3). + rewrite digits_nmake; rewrite <- digits_w2; auto. + Qed. + + Let spec_gen_eval3n: forall n, eval3n n = GenBase.gen_to_Z (znz_digits w3_op) (znz_to_Z w3_op) n. + intros n; exact (nmake_gen n w3 w3_op). + Qed. + + Theorem digits_w4: znz_digits w4_op = znz_digits (nmake_op _ w0_op 4). + rewrite digits_nmake; rewrite <- digits_w3; auto. + Qed. + + Let spec_gen_eval4n: forall n, eval4n n = GenBase.gen_to_Z (znz_digits w4_op) (znz_to_Z w4_op) n. + intros n; exact (nmake_gen n w4 w4_op). + Qed. + + Theorem digits_w5: znz_digits w5_op = znz_digits (nmake_op _ w0_op 5). + rewrite digits_nmake; rewrite <- digits_w4; auto. + Qed. + + Let spec_gen_eval5n: forall n, eval5n n = GenBase.gen_to_Z (znz_digits w5_op) (znz_to_Z w5_op) n. + intros n; exact (nmake_gen n w5 w5_op). + Qed. + + Theorem digits_w6: znz_digits w6_op = znz_digits (nmake_op _ w0_op 6). + rewrite digits_nmake; rewrite <- digits_w5; auto. + Qed. + + Let spec_gen_eval6n: forall n, eval6n n = GenBase.gen_to_Z (znz_digits w6_op) (znz_to_Z w6_op) n. + intros n; exact (nmake_gen n w6 w6_op). + Qed. + + Theorem digits_w0n0: znz_digits w0_op = znz_digits (nmake_op _ w0_op 0). + auto. + Qed. + + Let spec_eval0n0: forall x, [N0 x] = eval0n 0 x. + intros x; rewrite spec_gen_eval0n; unfold GenBase.gen_to_Z, to_Z; auto. + Qed. + Let spec_extend0n1: forall x, [N0 x] = [N1 (extend0 0 x)]. + intros x; change (extend0 0 x) with (WW (znz_0 w0_op) x). + unfold to_Z; rewrite znz_to_Z_1. + rewrite (spec_0 w0_spec); auto. + Qed. + + Theorem digits_w0n1: znz_digits w1_op = znz_digits (nmake_op _ w0_op 1). + apply trans_equal with (xO (znz_digits w0_op)). + auto. + rewrite digits_nmake. + rewrite digits_w0n0. + auto. + Qed. + + Let spec_eval0n1: forall x, [N1 x] = eval0n 1 x. + intros x; case x. + auto. + intros xh xl; unfold to_Z; rewrite znz_to_Z_1. + rewrite digits_w0n0. + generalize (spec_eval0n0); unfold to_Z; intros HH; repeat rewrite HH. + unfold eval0n, nmake_op0. + rewrite (znz_nmake_op _ w0_op 0); auto. + Qed. + Let spec_extend0n2: forall x, [N0 x] = [N2 (extend0 1 x)]. + intros x; change (extend0 1 x) with (WW (znz_0 w1_op) (extend0 0 x)). + unfold to_Z; rewrite znz_to_Z_2. + rewrite (spec_0 w1_spec). + generalize (spec_extend0n1 x); unfold to_Z. + intros HH; rewrite <- HH; auto. + Qed. + + Theorem digits_w0n2: znz_digits w2_op = znz_digits (nmake_op _ w0_op 2). + apply trans_equal with (xO (znz_digits w1_op)). + auto. + rewrite digits_nmake. + rewrite digits_w0n1. + auto. + Qed. + + Let spec_eval0n2: forall x, [N2 x] = eval0n 2 x. + intros x; case x. + auto. + intros xh xl; unfold to_Z; rewrite znz_to_Z_2. + rewrite digits_w0n1. + generalize (spec_eval0n1); unfold to_Z; intros HH; repeat rewrite HH. + unfold eval0n, nmake_op0. + rewrite (znz_nmake_op _ w0_op 1); auto. + Qed. + Let spec_extend0n3: forall x, [N0 x] = [N3 (extend0 2 x)]. + intros x; change (extend0 2 x) with (WW (znz_0 w2_op) (extend0 1 x)). + unfold to_Z; rewrite znz_to_Z_3. + rewrite (spec_0 w2_spec). + generalize (spec_extend0n2 x); unfold to_Z. + intros HH; rewrite <- HH; auto. + Qed. + + Theorem digits_w0n3: znz_digits w3_op = znz_digits (nmake_op _ w0_op 3). + apply trans_equal with (xO (znz_digits w2_op)). + auto. + rewrite digits_nmake. + rewrite digits_w0n2. + auto. + Qed. + + Let spec_eval0n3: forall x, [N3 x] = eval0n 3 x. + intros x; case x. + auto. + intros xh xl; unfold to_Z; rewrite znz_to_Z_3. + rewrite digits_w0n2. + generalize (spec_eval0n2); unfold to_Z; intros HH; repeat rewrite HH. + unfold eval0n, nmake_op0. + rewrite (znz_nmake_op _ w0_op 2); auto. + Qed. + Let spec_extend0n4: forall x, [N0 x] = [N4 (extend0 3 x)]. + intros x; change (extend0 3 x) with (WW (znz_0 w3_op) (extend0 2 x)). + unfold to_Z; rewrite znz_to_Z_4. + rewrite (spec_0 w3_spec). + generalize (spec_extend0n3 x); unfold to_Z. + intros HH; rewrite <- HH; auto. + Qed. + + Theorem digits_w0n4: znz_digits w4_op = znz_digits (nmake_op _ w0_op 4). + apply trans_equal with (xO (znz_digits w3_op)). + auto. + rewrite digits_nmake. + rewrite digits_w0n3. + auto. + Qed. + + Let spec_eval0n4: forall x, [N4 x] = eval0n 4 x. + intros x; case x. + auto. + intros xh xl; unfold to_Z; rewrite znz_to_Z_4. + rewrite digits_w0n3. + generalize (spec_eval0n3); unfold to_Z; intros HH; repeat rewrite HH. + unfold eval0n, nmake_op0. + rewrite (znz_nmake_op _ w0_op 3); auto. + Qed. + Let spec_extend0n5: forall x, [N0 x] = [N5 (extend0 4 x)]. + intros x; change (extend0 4 x) with (WW (znz_0 w4_op) (extend0 3 x)). + unfold to_Z; rewrite znz_to_Z_5. + rewrite (spec_0 w4_spec). + generalize (spec_extend0n4 x); unfold to_Z. + intros HH; rewrite <- HH; auto. + Qed. + + Theorem digits_w0n5: znz_digits w5_op = znz_digits (nmake_op _ w0_op 5). + apply trans_equal with (xO (znz_digits w4_op)). + auto. + rewrite digits_nmake. + rewrite digits_w0n4. + auto. + Qed. + + Let spec_eval0n5: forall x, [N5 x] = eval0n 5 x. + intros x; case x. + auto. + intros xh xl; unfold to_Z; rewrite znz_to_Z_5. + rewrite digits_w0n4. + generalize (spec_eval0n4); unfold to_Z; intros HH; repeat rewrite HH. + unfold eval0n, nmake_op0. + rewrite (znz_nmake_op _ w0_op 4); auto. + Qed. + Let spec_extend0n6: forall x, [N0 x] = [N6 (extend0 5 x)]. + intros x; change (extend0 5 x) with (WW (znz_0 w5_op) (extend0 4 x)). + unfold to_Z; rewrite znz_to_Z_6. + rewrite (spec_0 w5_spec). + generalize (spec_extend0n5 x); unfold to_Z. + intros HH; rewrite <- HH; auto. + Qed. + + Theorem digits_w0n6: znz_digits w6_op = znz_digits (nmake_op _ w0_op 6). + apply trans_equal with (xO (znz_digits w5_op)). + auto. + rewrite digits_nmake. + rewrite digits_w0n5. + auto. + Qed. + + Let spec_eval0n6: forall x, [N6 x] = eval0n 6 x. + intros x; case x. + auto. + intros xh xl; unfold to_Z; rewrite znz_to_Z_6. + rewrite digits_w0n5. + generalize (spec_eval0n5); unfold to_Z; intros HH; repeat rewrite HH. + unfold eval0n, nmake_op0. + rewrite (znz_nmake_op _ w0_op 5); auto. + Qed. + Theorem digits_w0n7: znz_digits w7_op = znz_digits (nmake_op _ w0_op 7). + apply trans_equal with (xO (znz_digits w6_op)). + auto. + rewrite digits_nmake. + rewrite digits_w0n6. + auto. + Qed. + + Let spec_eval0n7: forall x, [Nn 0 x] = eval0n 7 x. + intros x; case x. + auto. + intros xh xl; unfold to_Z; rewrite znz_to_Z_7. + rewrite digits_w0n6. + generalize (spec_eval0n6); unfold to_Z; intros HH; repeat rewrite HH. + unfold eval0n, nmake_op0. + rewrite (znz_nmake_op _ w0_op 6); auto. + Qed. + + Let spec_eval0n8: forall x, [Nn 1 x] = eval0n 8 x. + intros x; case x. + auto. + intros xh xl; unfold to_Z; rewrite znz_to_Z_8. + rewrite digits_w0n7. + generalize (spec_eval0n7); unfold to_Z; change (make_op 0) with (w7_op); intros HH; repeat rewrite HH. + unfold eval0n, nmake_op0. + rewrite (znz_nmake_op _ w0_op 7); auto. + Qed. + + Theorem digits_w1n0: znz_digits w1_op = znz_digits (nmake_op _ w1_op 0). + apply trans_equal with (xO (znz_digits w0_op)). + auto. + unfold nmake_op; auto. + Qed. + + Let spec_eval1n0: forall x, [N1 x] = eval1n 0 x. + intros x; rewrite spec_gen_eval1n; unfold GenBase.gen_to_Z, to_Z; auto. + Qed. + Let spec_extend1n2: forall x, [N1 x] = [N2 (extend1 0 x)]. + intros x; change (extend1 0 x) with (WW (znz_0 w1_op) x). + unfold to_Z; rewrite znz_to_Z_2. + rewrite (spec_0 w1_spec); auto. + Qed. + + Theorem digits_w1n1: znz_digits w2_op = znz_digits (nmake_op _ w1_op 1). + apply trans_equal with (xO (znz_digits w1_op)). + auto. + rewrite digits_nmake. + rewrite digits_w1n0. + auto. + Qed. + + Let spec_eval1n1: forall x, [N2 x] = eval1n 1 x. + intros x; case x. + auto. + intros xh xl; unfold to_Z; rewrite znz_to_Z_2. + rewrite digits_w1n0. + generalize (spec_eval1n0); unfold to_Z; intros HH; repeat rewrite HH. + unfold eval1n, nmake_op1. + rewrite (znz_nmake_op _ w1_op 0); auto. + Qed. + Let spec_extend1n3: forall x, [N1 x] = [N3 (extend1 1 x)]. + intros x; change (extend1 1 x) with (WW (znz_0 w2_op) (extend1 0 x)). + unfold to_Z; rewrite znz_to_Z_3. + rewrite (spec_0 w2_spec). + generalize (spec_extend1n2 x); unfold to_Z. + intros HH; rewrite <- HH; auto. + Qed. + + Theorem digits_w1n2: znz_digits w3_op = znz_digits (nmake_op _ w1_op 2). + apply trans_equal with (xO (znz_digits w2_op)). + auto. + rewrite digits_nmake. + rewrite digits_w1n1. + auto. + Qed. + + Let spec_eval1n2: forall x, [N3 x] = eval1n 2 x. + intros x; case x. + auto. + intros xh xl; unfold to_Z; rewrite znz_to_Z_3. + rewrite digits_w1n1. + generalize (spec_eval1n1); unfold to_Z; intros HH; repeat rewrite HH. + unfold eval1n, nmake_op1. + rewrite (znz_nmake_op _ w1_op 1); auto. + Qed. + Let spec_extend1n4: forall x, [N1 x] = [N4 (extend1 2 x)]. + intros x; change (extend1 2 x) with (WW (znz_0 w3_op) (extend1 1 x)). + unfold to_Z; rewrite znz_to_Z_4. + rewrite (spec_0 w3_spec). + generalize (spec_extend1n3 x); unfold to_Z. + intros HH; rewrite <- HH; auto. + Qed. + + Theorem digits_w1n3: znz_digits w4_op = znz_digits (nmake_op _ w1_op 3). + apply trans_equal with (xO (znz_digits w3_op)). + auto. + rewrite digits_nmake. + rewrite digits_w1n2. + auto. + Qed. + + Let spec_eval1n3: forall x, [N4 x] = eval1n 3 x. + intros x; case x. + auto. + intros xh xl; unfold to_Z; rewrite znz_to_Z_4. + rewrite digits_w1n2. + generalize (spec_eval1n2); unfold to_Z; intros HH; repeat rewrite HH. + unfold eval1n, nmake_op1. + rewrite (znz_nmake_op _ w1_op 2); auto. + Qed. + Let spec_extend1n5: forall x, [N1 x] = [N5 (extend1 3 x)]. + intros x; change (extend1 3 x) with (WW (znz_0 w4_op) (extend1 2 x)). + unfold to_Z; rewrite znz_to_Z_5. + rewrite (spec_0 w4_spec). + generalize (spec_extend1n4 x); unfold to_Z. + intros HH; rewrite <- HH; auto. + Qed. + + Theorem digits_w1n4: znz_digits w5_op = znz_digits (nmake_op _ w1_op 4). + apply trans_equal with (xO (znz_digits w4_op)). + auto. + rewrite digits_nmake. + rewrite digits_w1n3. + auto. + Qed. + + Let spec_eval1n4: forall x, [N5 x] = eval1n 4 x. + intros x; case x. + auto. + intros xh xl; unfold to_Z; rewrite znz_to_Z_5. + rewrite digits_w1n3. + generalize (spec_eval1n3); unfold to_Z; intros HH; repeat rewrite HH. + unfold eval1n, nmake_op1. + rewrite (znz_nmake_op _ w1_op 3); auto. + Qed. + Let spec_extend1n6: forall x, [N1 x] = [N6 (extend1 4 x)]. + intros x; change (extend1 4 x) with (WW (znz_0 w5_op) (extend1 3 x)). + unfold to_Z; rewrite znz_to_Z_6. + rewrite (spec_0 w5_spec). + generalize (spec_extend1n5 x); unfold to_Z. + intros HH; rewrite <- HH; auto. + Qed. + + Theorem digits_w1n5: znz_digits w6_op = znz_digits (nmake_op _ w1_op 5). + apply trans_equal with (xO (znz_digits w5_op)). + auto. + rewrite digits_nmake. + rewrite digits_w1n4. + auto. + Qed. + + Let spec_eval1n5: forall x, [N6 x] = eval1n 5 x. + intros x; case x. + auto. + intros xh xl; unfold to_Z; rewrite znz_to_Z_6. + rewrite digits_w1n4. + generalize (spec_eval1n4); unfold to_Z; intros HH; repeat rewrite HH. + unfold eval1n, nmake_op1. + rewrite (znz_nmake_op _ w1_op 4); auto. + Qed. + Theorem digits_w1n6: znz_digits w7_op = znz_digits (nmake_op _ w1_op 6). + apply trans_equal with (xO (znz_digits w6_op)). + auto. + rewrite digits_nmake. + rewrite digits_w1n5. + auto. + Qed. + + Let spec_eval1n6: forall x, [Nn 0 x] = eval1n 6 x. + intros x; case x. + auto. + intros xh xl; unfold to_Z; rewrite znz_to_Z_7. + rewrite digits_w1n5. + generalize (spec_eval1n5); unfold to_Z; intros HH; repeat rewrite HH. + unfold eval1n, nmake_op1. + rewrite (znz_nmake_op _ w1_op 5); auto. + Qed. + + Let spec_eval1n7: forall x, [Nn 1 x] = eval1n 7 x. + intros x; case x. + auto. + intros xh xl; unfold to_Z; rewrite znz_to_Z_8. + rewrite digits_w1n6. + generalize (spec_eval1n6); unfold to_Z; change (make_op 0) with (w7_op); intros HH; repeat rewrite HH. + unfold eval1n, nmake_op1. + rewrite (znz_nmake_op _ w1_op 6); auto. + Qed. + + Theorem digits_w2n0: znz_digits w2_op = znz_digits (nmake_op _ w2_op 0). + apply trans_equal with (xO (znz_digits w1_op)). + auto. + unfold nmake_op; auto. + Qed. + + Let spec_eval2n0: forall x, [N2 x] = eval2n 0 x. + intros x; rewrite spec_gen_eval2n; unfold GenBase.gen_to_Z, to_Z; auto. + Qed. + Let spec_extend2n3: forall x, [N2 x] = [N3 (extend2 0 x)]. + intros x; change (extend2 0 x) with (WW (znz_0 w2_op) x). + unfold to_Z; rewrite znz_to_Z_3. + rewrite (spec_0 w2_spec); auto. + Qed. + + Theorem digits_w2n1: znz_digits w3_op = znz_digits (nmake_op _ w2_op 1). + apply trans_equal with (xO (znz_digits w2_op)). + auto. + rewrite digits_nmake. + rewrite digits_w2n0. + auto. + Qed. + + Let spec_eval2n1: forall x, [N3 x] = eval2n 1 x. + intros x; case x. + auto. + intros xh xl; unfold to_Z; rewrite znz_to_Z_3. + rewrite digits_w2n0. + generalize (spec_eval2n0); unfold to_Z; intros HH; repeat rewrite HH. + unfold eval2n, nmake_op2. + rewrite (znz_nmake_op _ w2_op 0); auto. + Qed. + Let spec_extend2n4: forall x, [N2 x] = [N4 (extend2 1 x)]. + intros x; change (extend2 1 x) with (WW (znz_0 w3_op) (extend2 0 x)). + unfold to_Z; rewrite znz_to_Z_4. + rewrite (spec_0 w3_spec). + generalize (spec_extend2n3 x); unfold to_Z. + intros HH; rewrite <- HH; auto. + Qed. + + Theorem digits_w2n2: znz_digits w4_op = znz_digits (nmake_op _ w2_op 2). + apply trans_equal with (xO (znz_digits w3_op)). + auto. + rewrite digits_nmake. + rewrite digits_w2n1. + auto. + Qed. + + Let spec_eval2n2: forall x, [N4 x] = eval2n 2 x. + intros x; case x. + auto. + intros xh xl; unfold to_Z; rewrite znz_to_Z_4. + rewrite digits_w2n1. + generalize (spec_eval2n1); unfold to_Z; intros HH; repeat rewrite HH. + unfold eval2n, nmake_op2. + rewrite (znz_nmake_op _ w2_op 1); auto. + Qed. + Let spec_extend2n5: forall x, [N2 x] = [N5 (extend2 2 x)]. + intros x; change (extend2 2 x) with (WW (znz_0 w4_op) (extend2 1 x)). + unfold to_Z; rewrite znz_to_Z_5. + rewrite (spec_0 w4_spec). + generalize (spec_extend2n4 x); unfold to_Z. + intros HH; rewrite <- HH; auto. + Qed. + + Theorem digits_w2n3: znz_digits w5_op = znz_digits (nmake_op _ w2_op 3). + apply trans_equal with (xO (znz_digits w4_op)). + auto. + rewrite digits_nmake. + rewrite digits_w2n2. + auto. + Qed. + + Let spec_eval2n3: forall x, [N5 x] = eval2n 3 x. + intros x; case x. + auto. + intros xh xl; unfold to_Z; rewrite znz_to_Z_5. + rewrite digits_w2n2. + generalize (spec_eval2n2); unfold to_Z; intros HH; repeat rewrite HH. + unfold eval2n, nmake_op2. + rewrite (znz_nmake_op _ w2_op 2); auto. + Qed. + Let spec_extend2n6: forall x, [N2 x] = [N6 (extend2 3 x)]. + intros x; change (extend2 3 x) with (WW (znz_0 w5_op) (extend2 2 x)). + unfold to_Z; rewrite znz_to_Z_6. + rewrite (spec_0 w5_spec). + generalize (spec_extend2n5 x); unfold to_Z. + intros HH; rewrite <- HH; auto. + Qed. + + Theorem digits_w2n4: znz_digits w6_op = znz_digits (nmake_op _ w2_op 4). + apply trans_equal with (xO (znz_digits w5_op)). + auto. + rewrite digits_nmake. + rewrite digits_w2n3. + auto. + Qed. + + Let spec_eval2n4: forall x, [N6 x] = eval2n 4 x. + intros x; case x. + auto. + intros xh xl; unfold to_Z; rewrite znz_to_Z_6. + rewrite digits_w2n3. + generalize (spec_eval2n3); unfold to_Z; intros HH; repeat rewrite HH. + unfold eval2n, nmake_op2. + rewrite (znz_nmake_op _ w2_op 3); auto. + Qed. + Theorem digits_w2n5: znz_digits w7_op = znz_digits (nmake_op _ w2_op 5). + apply trans_equal with (xO (znz_digits w6_op)). + auto. + rewrite digits_nmake. + rewrite digits_w2n4. + auto. + Qed. + + Let spec_eval2n5: forall x, [Nn 0 x] = eval2n 5 x. + intros x; case x. + auto. + intros xh xl; unfold to_Z; rewrite znz_to_Z_7. + rewrite digits_w2n4. + generalize (spec_eval2n4); unfold to_Z; intros HH; repeat rewrite HH. + unfold eval2n, nmake_op2. + rewrite (znz_nmake_op _ w2_op 4); auto. + Qed. + + Let spec_eval2n6: forall x, [Nn 1 x] = eval2n 6 x. + intros x; case x. + auto. + intros xh xl; unfold to_Z; rewrite znz_to_Z_8. + rewrite digits_w2n5. + generalize (spec_eval2n5); unfold to_Z; change (make_op 0) with (w7_op); intros HH; repeat rewrite HH. + unfold eval2n, nmake_op2. + rewrite (znz_nmake_op _ w2_op 5); auto. + Qed. + + Theorem digits_w3n0: znz_digits w3_op = znz_digits (nmake_op _ w3_op 0). + apply trans_equal with (xO (znz_digits w2_op)). + auto. + unfold nmake_op; auto. + Qed. + + Let spec_eval3n0: forall x, [N3 x] = eval3n 0 x. + intros x; rewrite spec_gen_eval3n; unfold GenBase.gen_to_Z, to_Z; auto. + Qed. + Let spec_extend3n4: forall x, [N3 x] = [N4 (extend3 0 x)]. + intros x; change (extend3 0 x) with (WW (znz_0 w3_op) x). + unfold to_Z; rewrite znz_to_Z_4. + rewrite (spec_0 w3_spec); auto. + Qed. + + Theorem digits_w3n1: znz_digits w4_op = znz_digits (nmake_op _ w3_op 1). + apply trans_equal with (xO (znz_digits w3_op)). + auto. + rewrite digits_nmake. + rewrite digits_w3n0. + auto. + Qed. + + Let spec_eval3n1: forall x, [N4 x] = eval3n 1 x. + intros x; case x. + auto. + intros xh xl; unfold to_Z; rewrite znz_to_Z_4. + rewrite digits_w3n0. + generalize (spec_eval3n0); unfold to_Z; intros HH; repeat rewrite HH. + unfold eval3n, nmake_op3. + rewrite (znz_nmake_op _ w3_op 0); auto. + Qed. + Let spec_extend3n5: forall x, [N3 x] = [N5 (extend3 1 x)]. + intros x; change (extend3 1 x) with (WW (znz_0 w4_op) (extend3 0 x)). + unfold to_Z; rewrite znz_to_Z_5. + rewrite (spec_0 w4_spec). + generalize (spec_extend3n4 x); unfold to_Z. + intros HH; rewrite <- HH; auto. + Qed. + + Theorem digits_w3n2: znz_digits w5_op = znz_digits (nmake_op _ w3_op 2). + apply trans_equal with (xO (znz_digits w4_op)). + auto. + rewrite digits_nmake. + rewrite digits_w3n1. + auto. + Qed. + + Let spec_eval3n2: forall x, [N5 x] = eval3n 2 x. + intros x; case x. + auto. + intros xh xl; unfold to_Z; rewrite znz_to_Z_5. + rewrite digits_w3n1. + generalize (spec_eval3n1); unfold to_Z; intros HH; repeat rewrite HH. + unfold eval3n, nmake_op3. + rewrite (znz_nmake_op _ w3_op 1); auto. + Qed. + Let spec_extend3n6: forall x, [N3 x] = [N6 (extend3 2 x)]. + intros x; change (extend3 2 x) with (WW (znz_0 w5_op) (extend3 1 x)). + unfold to_Z; rewrite znz_to_Z_6. + rewrite (spec_0 w5_spec). + generalize (spec_extend3n5 x); unfold to_Z. + intros HH; rewrite <- HH; auto. + Qed. + + Theorem digits_w3n3: znz_digits w6_op = znz_digits (nmake_op _ w3_op 3). + apply trans_equal with (xO (znz_digits w5_op)). + auto. + rewrite digits_nmake. + rewrite digits_w3n2. + auto. + Qed. + + Let spec_eval3n3: forall x, [N6 x] = eval3n 3 x. + intros x; case x. + auto. + intros xh xl; unfold to_Z; rewrite znz_to_Z_6. + rewrite digits_w3n2. + generalize (spec_eval3n2); unfold to_Z; intros HH; repeat rewrite HH. + unfold eval3n, nmake_op3. + rewrite (znz_nmake_op _ w3_op 2); auto. + Qed. + Theorem digits_w3n4: znz_digits w7_op = znz_digits (nmake_op _ w3_op 4). + apply trans_equal with (xO (znz_digits w6_op)). + auto. + rewrite digits_nmake. + rewrite digits_w3n3. + auto. + Qed. + + Let spec_eval3n4: forall x, [Nn 0 x] = eval3n 4 x. + intros x; case x. + auto. + intros xh xl; unfold to_Z; rewrite znz_to_Z_7. + rewrite digits_w3n3. + generalize (spec_eval3n3); unfold to_Z; intros HH; repeat rewrite HH. + unfold eval3n, nmake_op3. + rewrite (znz_nmake_op _ w3_op 3); auto. + Qed. + + Let spec_eval3n5: forall x, [Nn 1 x] = eval3n 5 x. + intros x; case x. + auto. + intros xh xl; unfold to_Z; rewrite znz_to_Z_8. + rewrite digits_w3n4. + generalize (spec_eval3n4); unfold to_Z; change (make_op 0) with (w7_op); intros HH; repeat rewrite HH. + unfold eval3n, nmake_op3. + rewrite (znz_nmake_op _ w3_op 4); auto. + Qed. + + Theorem digits_w4n0: znz_digits w4_op = znz_digits (nmake_op _ w4_op 0). + apply trans_equal with (xO (znz_digits w3_op)). + auto. + unfold nmake_op; auto. + Qed. + + Let spec_eval4n0: forall x, [N4 x] = eval4n 0 x. + intros x; rewrite spec_gen_eval4n; unfold GenBase.gen_to_Z, to_Z; auto. + Qed. + Let spec_extend4n5: forall x, [N4 x] = [N5 (extend4 0 x)]. + intros x; change (extend4 0 x) with (WW (znz_0 w4_op) x). + unfold to_Z; rewrite znz_to_Z_5. + rewrite (spec_0 w4_spec); auto. + Qed. + + Theorem digits_w4n1: znz_digits w5_op = znz_digits (nmake_op _ w4_op 1). + apply trans_equal with (xO (znz_digits w4_op)). + auto. + rewrite digits_nmake. + rewrite digits_w4n0. + auto. + Qed. + + Let spec_eval4n1: forall x, [N5 x] = eval4n 1 x. + intros x; case x. + auto. + intros xh xl; unfold to_Z; rewrite znz_to_Z_5. + rewrite digits_w4n0. + generalize (spec_eval4n0); unfold to_Z; intros HH; repeat rewrite HH. + unfold eval4n, nmake_op4. + rewrite (znz_nmake_op _ w4_op 0); auto. + Qed. + Let spec_extend4n6: forall x, [N4 x] = [N6 (extend4 1 x)]. + intros x; change (extend4 1 x) with (WW (znz_0 w5_op) (extend4 0 x)). + unfold to_Z; rewrite znz_to_Z_6. + rewrite (spec_0 w5_spec). + generalize (spec_extend4n5 x); unfold to_Z. + intros HH; rewrite <- HH; auto. + Qed. + + Theorem digits_w4n2: znz_digits w6_op = znz_digits (nmake_op _ w4_op 2). + apply trans_equal with (xO (znz_digits w5_op)). + auto. + rewrite digits_nmake. + rewrite digits_w4n1. + auto. + Qed. + + Let spec_eval4n2: forall x, [N6 x] = eval4n 2 x. + intros x; case x. + auto. + intros xh xl; unfold to_Z; rewrite znz_to_Z_6. + rewrite digits_w4n1. + generalize (spec_eval4n1); unfold to_Z; intros HH; repeat rewrite HH. + unfold eval4n, nmake_op4. + rewrite (znz_nmake_op _ w4_op 1); auto. + Qed. + Theorem digits_w4n3: znz_digits w7_op = znz_digits (nmake_op _ w4_op 3). + apply trans_equal with (xO (znz_digits w6_op)). + auto. + rewrite digits_nmake. + rewrite digits_w4n2. + auto. + Qed. + + Let spec_eval4n3: forall x, [Nn 0 x] = eval4n 3 x. + intros x; case x. + auto. + intros xh xl; unfold to_Z; rewrite znz_to_Z_7. + rewrite digits_w4n2. + generalize (spec_eval4n2); unfold to_Z; intros HH; repeat rewrite HH. + unfold eval4n, nmake_op4. + rewrite (znz_nmake_op _ w4_op 2); auto. + Qed. + + Let spec_eval4n4: forall x, [Nn 1 x] = eval4n 4 x. + intros x; case x. + auto. + intros xh xl; unfold to_Z; rewrite znz_to_Z_8. + rewrite digits_w4n3. + generalize (spec_eval4n3); unfold to_Z; change (make_op 0) with (w7_op); intros HH; repeat rewrite HH. + unfold eval4n, nmake_op4. + rewrite (znz_nmake_op _ w4_op 3); auto. + Qed. + + Theorem digits_w5n0: znz_digits w5_op = znz_digits (nmake_op _ w5_op 0). + apply trans_equal with (xO (znz_digits w4_op)). + auto. + unfold nmake_op; auto. + Qed. + + Let spec_eval5n0: forall x, [N5 x] = eval5n 0 x. + intros x; rewrite spec_gen_eval5n; unfold GenBase.gen_to_Z, to_Z; auto. + Qed. + Let spec_extend5n6: forall x, [N5 x] = [N6 (extend5 0 x)]. + intros x; change (extend5 0 x) with (WW (znz_0 w5_op) x). + unfold to_Z; rewrite znz_to_Z_6. + rewrite (spec_0 w5_spec); auto. + Qed. + + Theorem digits_w5n1: znz_digits w6_op = znz_digits (nmake_op _ w5_op 1). + apply trans_equal with (xO (znz_digits w5_op)). + auto. + rewrite digits_nmake. + rewrite digits_w5n0. + auto. + Qed. + + Let spec_eval5n1: forall x, [N6 x] = eval5n 1 x. + intros x; case x. + auto. + intros xh xl; unfold to_Z; rewrite znz_to_Z_6. + rewrite digits_w5n0. + generalize (spec_eval5n0); unfold to_Z; intros HH; repeat rewrite HH. + unfold eval5n, nmake_op5. + rewrite (znz_nmake_op _ w5_op 0); auto. + Qed. + Theorem digits_w5n2: znz_digits w7_op = znz_digits (nmake_op _ w5_op 2). + apply trans_equal with (xO (znz_digits w6_op)). + auto. + rewrite digits_nmake. + rewrite digits_w5n1. + auto. + Qed. + + Let spec_eval5n2: forall x, [Nn 0 x] = eval5n 2 x. + intros x; case x. + auto. + intros xh xl; unfold to_Z; rewrite znz_to_Z_7. + rewrite digits_w5n1. + generalize (spec_eval5n1); unfold to_Z; intros HH; repeat rewrite HH. + unfold eval5n, nmake_op5. + rewrite (znz_nmake_op _ w5_op 1); auto. + Qed. + + Let spec_eval5n3: forall x, [Nn 1 x] = eval5n 3 x. + intros x; case x. + auto. + intros xh xl; unfold to_Z; rewrite znz_to_Z_8. + rewrite digits_w5n2. + generalize (spec_eval5n2); unfold to_Z; change (make_op 0) with (w7_op); intros HH; repeat rewrite HH. + unfold eval5n, nmake_op5. + rewrite (znz_nmake_op _ w5_op 2); auto. + Qed. + + Theorem digits_w6n0: znz_digits w6_op = znz_digits (nmake_op _ w6_op 0). + apply trans_equal with (xO (znz_digits w5_op)). + auto. + unfold nmake_op; auto. + Qed. + + Let spec_eval6n0: forall x, [N6 x] = eval6n 0 x. + intros x; rewrite spec_gen_eval6n; unfold GenBase.gen_to_Z, to_Z; auto. + Qed. + Theorem digits_w6n1: znz_digits w7_op = znz_digits (nmake_op _ w6_op 1). + apply trans_equal with (xO (znz_digits w6_op)). + auto. + rewrite digits_nmake. + rewrite digits_w6n0. + auto. + Qed. + + Let spec_eval6n1: forall x, [Nn 0 x] = eval6n 1 x. + intros x; case x. + auto. + intros xh xl; unfold to_Z; rewrite znz_to_Z_7. + rewrite digits_w6n0. + generalize (spec_eval6n0); unfold to_Z; intros HH; repeat rewrite HH. + unfold eval6n, nmake_op6. + rewrite (znz_nmake_op _ w6_op 0); auto. + Qed. + + Let spec_eval6n2: forall x, [Nn 1 x] = eval6n 2 x. + intros x; case x. + auto. + intros xh xl; unfold to_Z; rewrite znz_to_Z_8. + rewrite digits_w6n1. + generalize (spec_eval6n1); unfold to_Z; change (make_op 0) with (w7_op); intros HH; repeat rewrite HH. + unfold eval6n, nmake_op6. + rewrite (znz_nmake_op _ w6_op 1); auto. + Qed. + + Let digits_w6n: forall n, + znz_digits (make_op n) = znz_digits (nmake_op _ w6_op (S n)). + intros n; elim n; clear n. + change (znz_digits (make_op 0)) with (xO (znz_digits w6_op)). + rewrite nmake_op_S; apply sym_equal; auto. + intros n Hrec. + replace (znz_digits (make_op (S n))) with (xO (znz_digits (make_op n))). + rewrite Hrec. + rewrite nmake_op_S; apply sym_equal; auto. + rewrite make_op_S; apply sym_equal; auto. + Qed. + + Let spec_eval6n: forall n x, [Nn n x] = eval6n (S n) x. + intros n; elim n; clear n. + exact spec_eval6n1. + intros n Hrec x; case x; clear x. + unfold to_Z, eval6n, nmake_op6. + rewrite make_op_S; rewrite nmake_op_S; auto. + intros xh xl. + unfold to_Z in Hrec |- *. + rewrite znz_to_Z_n. + rewrite digits_w6n. + repeat rewrite Hrec. + unfold eval6n, nmake_op6. + apply sym_equal; rewrite nmake_op_S; auto. + Qed. + + Let spec_extend6n: forall n x, [N6 x] = [Nn n (extend6 n x)]. + intros n; elim n; clear n. + intros x; change (extend6 0 x) with (WW (znz_0 w6_op) x). + unfold to_Z. + change (make_op 0) with w7_op. + rewrite znz_to_Z_7; rewrite (spec_0 w6_spec); auto. + intros n Hrec x. + change (extend6 (S n) x) with (WW W0 (extend6 n x)). + unfold to_Z in Hrec |- *; rewrite znz_to_Z_n; auto. + rewrite <- Hrec. + replace (znz_to_Z (make_op n) W0) with 0; auto. + case n; auto; intros; rewrite make_op_S; auto. + Qed. + + Theorem spec_pos: forall x, 0 <= [x]. + Proof. + intros x; case x; clear x. + intros x; case (spec_to_Z w0_spec x); auto. + intros x; case (spec_to_Z w1_spec x); auto. + intros x; case (spec_to_Z w2_spec x); auto. + intros x; case (spec_to_Z w3_spec x); auto. + intros x; case (spec_to_Z w4_spec x); auto. + intros x; case (spec_to_Z w5_spec x); auto. + intros x; case (spec_to_Z w6_spec x); auto. + intros n x; case (spec_to_Z (wn_spec n) x); auto. + Qed. + + Let spec_extendn_0: forall n wx, [Nn n (extend n _ wx)] = [Nn 0 wx]. + intros n; elim n; auto. + intros n1 Hrec wx; simpl extend; rewrite <- Hrec; auto. + unfold to_Z. + case n1; auto; intros n2; repeat rewrite make_op_S; auto. + Qed. + Hint Rewrite spec_extendn_0: extr. + + Let spec_extendn0_0: forall n wx, [Nn (S n) (WW W0 wx)] = [Nn n wx]. + Proof. + intros n x; unfold to_Z. + rewrite znz_to_Z_n. + rewrite <- (Zplus_0_l (znz_to_Z (make_op n) x)). + apply (f_equal2 Zplus); auto. + case n; auto. + intros n1; rewrite make_op_S; auto. + Qed. + Hint Rewrite spec_extendn_0: extr. + + Let spec_extend_tr: forall m n (w: word _ (S n)), + [Nn (m + n) (extend_tr w m)] = [Nn n w]. + Proof. + induction m; auto. + intros n x; simpl extend_tr. + simpl plus; rewrite spec_extendn0_0; auto. + Qed. + Hint Rewrite spec_extend_tr: extr. + + Let spec_cast_l: forall n m x1, + [Nn (Max.max n m) + (castm (diff_r n m) (extend_tr x1 (snd (diff n m))))] = + [Nn n x1]. + Proof. + intros n m x1; case (diff_r n m); simpl castm. + rewrite spec_extend_tr; auto. + Qed. + Hint Rewrite spec_cast_l: extr. + + Let spec_cast_r: forall n m x1, + [Nn (Max.max n m) + (castm (diff_l n m) (extend_tr x1 (fst (diff n m))))] = + [Nn m x1]. + Proof. + intros n m x1; case (diff_l n m); simpl castm. + rewrite spec_extend_tr; auto. + Qed. + Hint Rewrite spec_cast_r: extr. + + Section LevelAndIter. + + Variable res: Set. + Variable xxx: res. + Variable P: Z -> Z -> res -> Prop. + (* Abstraction function for each level *) + Variable f0: w0 -> w0 -> res. + Variable f0n: forall n, w0 -> word w0 (S n) -> res. + Variable fn0: forall n, word w0 (S n) -> w0 -> res. + Variable Pf0: forall x y, P [N0 x] [N0 y] (f0 x y). + Variable Pf0n: forall n x y, Z_of_nat n <= 6 -> P [N0 x] (eval0n (S n) y) (f0n n x y). + Variable Pfn0: forall n x y, Z_of_nat n <= 6 -> P (eval0n (S n) x) [N0 y] (fn0 n x y). + + Variable f1: w1 -> w1 -> res. + Variable f1n: forall n, w1 -> word w1 (S n) -> res. + Variable fn1: forall n, word w1 (S n) -> w1 -> res. + Variable Pf1: forall x y, P [N1 x] [N1 y] (f1 x y). + Variable Pf1n: forall n x y, Z_of_nat n <= 5 -> P [N1 x] (eval1n (S n) y) (f1n n x y). + Variable Pfn1: forall n x y, Z_of_nat n <= 5 -> P (eval1n (S n) x) [N1 y] (fn1 n x y). + + Variable f2: w2 -> w2 -> res. + Variable f2n: forall n, w2 -> word w2 (S n) -> res. + Variable fn2: forall n, word w2 (S n) -> w2 -> res. + Variable Pf2: forall x y, P [N2 x] [N2 y] (f2 x y). + Variable Pf2n: forall n x y, Z_of_nat n <= 4 -> P [N2 x] (eval2n (S n) y) (f2n n x y). + Variable Pfn2: forall n x y, Z_of_nat n <= 4 -> P (eval2n (S n) x) [N2 y] (fn2 n x y). + + Variable f3: w3 -> w3 -> res. + Variable f3n: forall n, w3 -> word w3 (S n) -> res. + Variable fn3: forall n, word w3 (S n) -> w3 -> res. + Variable Pf3: forall x y, P [N3 x] [N3 y] (f3 x y). + Variable Pf3n: forall n x y, Z_of_nat n <= 3 -> P [N3 x] (eval3n (S n) y) (f3n n x y). + Variable Pfn3: forall n x y, Z_of_nat n <= 3 -> P (eval3n (S n) x) [N3 y] (fn3 n x y). + + Variable f4: w4 -> w4 -> res. + Variable f4n: forall n, w4 -> word w4 (S n) -> res. + Variable fn4: forall n, word w4 (S n) -> w4 -> res. + Variable Pf4: forall x y, P [N4 x] [N4 y] (f4 x y). + Variable Pf4n: forall n x y, Z_of_nat n <= 2 -> P [N4 x] (eval4n (S n) y) (f4n n x y). + Variable Pfn4: forall n x y, Z_of_nat n <= 2 -> P (eval4n (S n) x) [N4 y] (fn4 n x y). + + Variable f5: w5 -> w5 -> res. + Variable f5n: forall n, w5 -> word w5 (S n) -> res. + Variable fn5: forall n, word w5 (S n) -> w5 -> res. + Variable Pf5: forall x y, P [N5 x] [N5 y] (f5 x y). + Variable Pf5n: forall n x y, Z_of_nat n <= 1 -> P [N5 x] (eval5n (S n) y) (f5n n x y). + Variable Pfn5: forall n x y, Z_of_nat n <= 1 -> P (eval5n (S n) x) [N5 y] (fn5 n x y). + + Variable f6: w6 -> w6 -> res. + Variable f6n: forall n, w6 -> word w6 (S n) -> res. + Variable fn6: forall n, word w6 (S n) -> w6 -> res. + Variable Pf6: forall x y, P [N6 x] [N6 y] (f6 x y). + Variable Pf6n: forall n x y, P [N6 x] (eval6n (S n) y) (f6n n x y). + Variable Pfn6: forall n x y, P (eval6n (S n) x) [N6 y] (fn6 n x y). + + Variable fnn: forall n, word w6 (S n) -> word w6 (S n) -> res. + Variable Pfnn: forall n x y, P [Nn n x] [Nn n y] (fnn n x y). + Variable fnm: forall n m, word w6 (S n) -> word w6 (S m) -> res. + Variable Pfnm: forall n m x y, P [Nn n x] [Nn m y] (fnm n m x y). + + (* Special zero functions *) + Variable f0t: t_ -> res. + Variable Pf0t: forall x, P 0 [x] (f0t x). + Variable ft0: t_ -> res. + Variable Pft0: forall x, P [x] 0 (ft0 x). + + (* We level the two arguments before applying *) + (* the functions at each leval *) + Definition same_level (x y: t_): res := + Eval lazy zeta beta iota delta [extend0 extend1 extend2 extend3 extend4 extend5 extend6 + GenBase.extend GenBase.extend_aux + ] in + match x, y with + | N0 wx, N0 wy => f0 wx wy + | N0 wx, N1 wy => f1 (extend0 0 wx) wy + | N0 wx, N2 wy => f2 (extend0 1 wx) wy + | N0 wx, N3 wy => f3 (extend0 2 wx) wy + | N0 wx, N4 wy => f4 (extend0 3 wx) wy + | N0 wx, N5 wy => f5 (extend0 4 wx) wy + | N0 wx, N6 wy => f6 (extend0 5 wx) wy + | N0 wx, Nn m wy => fnn m (extend6 m (extend0 5 wx)) wy + | N1 wx, N0 wy => f1 wx (extend0 0 wy) + | N1 wx, N1 wy => f1 wx wy + | N1 wx, N2 wy => f2 (extend1 0 wx) wy + | N1 wx, N3 wy => f3 (extend1 1 wx) wy + | N1 wx, N4 wy => f4 (extend1 2 wx) wy + | N1 wx, N5 wy => f5 (extend1 3 wx) wy + | N1 wx, N6 wy => f6 (extend1 4 wx) wy + | N1 wx, Nn m wy => fnn m (extend6 m (extend1 4 wx)) wy + | N2 wx, N0 wy => f2 wx (extend0 1 wy) + | N2 wx, N1 wy => f2 wx (extend1 0 wy) + | N2 wx, N2 wy => f2 wx wy + | N2 wx, N3 wy => f3 (extend2 0 wx) wy + | N2 wx, N4 wy => f4 (extend2 1 wx) wy + | N2 wx, N5 wy => f5 (extend2 2 wx) wy + | N2 wx, N6 wy => f6 (extend2 3 wx) wy + | N2 wx, Nn m wy => fnn m (extend6 m (extend2 3 wx)) wy + | N3 wx, N0 wy => f3 wx (extend0 2 wy) + | N3 wx, N1 wy => f3 wx (extend1 1 wy) + | N3 wx, N2 wy => f3 wx (extend2 0 wy) + | N3 wx, N3 wy => f3 wx wy + | N3 wx, N4 wy => f4 (extend3 0 wx) wy + | N3 wx, N5 wy => f5 (extend3 1 wx) wy + | N3 wx, N6 wy => f6 (extend3 2 wx) wy + | N3 wx, Nn m wy => fnn m (extend6 m (extend3 2 wx)) wy + | N4 wx, N0 wy => f4 wx (extend0 3 wy) + | N4 wx, N1 wy => f4 wx (extend1 2 wy) + | N4 wx, N2 wy => f4 wx (extend2 1 wy) + | N4 wx, N3 wy => f4 wx (extend3 0 wy) + | N4 wx, N4 wy => f4 wx wy + | N4 wx, N5 wy => f5 (extend4 0 wx) wy + | N4 wx, N6 wy => f6 (extend4 1 wx) wy + | N4 wx, Nn m wy => fnn m (extend6 m (extend4 1 wx)) wy + | N5 wx, N0 wy => f5 wx (extend0 4 wy) + | N5 wx, N1 wy => f5 wx (extend1 3 wy) + | N5 wx, N2 wy => f5 wx (extend2 2 wy) + | N5 wx, N3 wy => f5 wx (extend3 1 wy) + | N5 wx, N4 wy => f5 wx (extend4 0 wy) + | N5 wx, N5 wy => f5 wx wy + | N5 wx, N6 wy => f6 (extend5 0 wx) wy + | N5 wx, Nn m wy => fnn m (extend6 m (extend5 0 wx)) wy + | N6 wx, N0 wy => f6 wx (extend0 5 wy) + | N6 wx, N1 wy => f6 wx (extend1 4 wy) + | N6 wx, N2 wy => f6 wx (extend2 3 wy) + | N6 wx, N3 wy => f6 wx (extend3 2 wy) + | N6 wx, N4 wy => f6 wx (extend4 1 wy) + | N6 wx, N5 wy => f6 wx (extend5 0 wy) + | N6 wx, N6 wy => f6 wx wy + | N6 wx, Nn m wy => fnn m (extend6 m wx) wy + | Nn n wx, N0 wy => fnn n wx (extend6 n (extend0 5 wy)) + | Nn n wx, N1 wy => fnn n wx (extend6 n (extend1 4 wy)) + | Nn n wx, N2 wy => fnn n wx (extend6 n (extend2 3 wy)) + | Nn n wx, N3 wy => fnn n wx (extend6 n (extend3 2 wy)) + | Nn n wx, N4 wy => fnn n wx (extend6 n (extend4 1 wy)) + | Nn n wx, N5 wy => fnn n wx (extend6 n (extend5 0 wy)) + | Nn n wx, N6 wy => fnn n wx (extend6 n wy) + | Nn n wx, Nn m wy => + let mn := Max.max n m in + let d := diff n m in + fnn mn + (castm (diff_r n m) (extend_tr wx (snd d))) + (castm (diff_l n m) (extend_tr wy (fst d))) + end. + + Lemma spec_same_level: forall x y, P [x] [y] (same_level x y). + Proof. + intros x; case x; clear x; unfold same_level. + intros x y; case y; clear y. + intros y; apply Pf0. + intros y; rewrite spec_extend0n1; apply Pf1. + intros y; rewrite spec_extend0n2; apply Pf2. + intros y; rewrite spec_extend0n3; apply Pf3. + intros y; rewrite spec_extend0n4; apply Pf4. + intros y; rewrite spec_extend0n5; apply Pf5. + intros y; rewrite spec_extend0n6; apply Pf6. + intros m y; rewrite spec_extend0n6; rewrite (spec_extend6n m); apply Pfnn. + intros x y; case y; clear y. + intros y; rewrite spec_extend0n1; apply Pf1. + intros y; apply Pf1. + intros y; rewrite spec_extend1n2; apply Pf2. + intros y; rewrite spec_extend1n3; apply Pf3. + intros y; rewrite spec_extend1n4; apply Pf4. + intros y; rewrite spec_extend1n5; apply Pf5. + intros y; rewrite spec_extend1n6; apply Pf6. + intros m y; rewrite spec_extend1n6; rewrite (spec_extend6n m); apply Pfnn. + intros x y; case y; clear y. + intros y; rewrite spec_extend0n2; apply Pf2. + intros y; rewrite spec_extend1n2; apply Pf2. + intros y; apply Pf2. + intros y; rewrite spec_extend2n3; apply Pf3. + intros y; rewrite spec_extend2n4; apply Pf4. + intros y; rewrite spec_extend2n5; apply Pf5. + intros y; rewrite spec_extend2n6; apply Pf6. + intros m y; rewrite spec_extend2n6; rewrite (spec_extend6n m); apply Pfnn. + intros x y; case y; clear y. + intros y; rewrite spec_extend0n3; apply Pf3. + intros y; rewrite spec_extend1n3; apply Pf3. + intros y; rewrite spec_extend2n3; apply Pf3. + intros y; apply Pf3. + intros y; rewrite spec_extend3n4; apply Pf4. + intros y; rewrite spec_extend3n5; apply Pf5. + intros y; rewrite spec_extend3n6; apply Pf6. + intros m y; rewrite spec_extend3n6; rewrite (spec_extend6n m); apply Pfnn. + intros x y; case y; clear y. + intros y; rewrite spec_extend0n4; apply Pf4. + intros y; rewrite spec_extend1n4; apply Pf4. + intros y; rewrite spec_extend2n4; apply Pf4. + intros y; rewrite spec_extend3n4; apply Pf4. + intros y; apply Pf4. + intros y; rewrite spec_extend4n5; apply Pf5. + intros y; rewrite spec_extend4n6; apply Pf6. + intros m y; rewrite spec_extend4n6; rewrite (spec_extend6n m); apply Pfnn. + intros x y; case y; clear y. + intros y; rewrite spec_extend0n5; apply Pf5. + intros y; rewrite spec_extend1n5; apply Pf5. + intros y; rewrite spec_extend2n5; apply Pf5. + intros y; rewrite spec_extend3n5; apply Pf5. + intros y; rewrite spec_extend4n5; apply Pf5. + intros y; apply Pf5. + intros y; rewrite spec_extend5n6; apply Pf6. + intros m y; rewrite spec_extend5n6; rewrite (spec_extend6n m); apply Pfnn. + intros x y; case y; clear y. + intros y; rewrite spec_extend0n6; apply Pf6. + intros y; rewrite spec_extend1n6; apply Pf6. + intros y; rewrite spec_extend2n6; apply Pf6. + intros y; rewrite spec_extend3n6; apply Pf6. + intros y; rewrite spec_extend4n6; apply Pf6. + intros y; rewrite spec_extend5n6; apply Pf6. + intros y; apply Pf6. + intros m y; rewrite (spec_extend6n m); apply Pfnn. + intros n x y; case y; clear y. + intros y; rewrite spec_extend0n6; rewrite (spec_extend6n n); apply Pfnn. + intros y; rewrite spec_extend1n6; rewrite (spec_extend6n n); apply Pfnn. + intros y; rewrite spec_extend2n6; rewrite (spec_extend6n n); apply Pfnn. + intros y; rewrite spec_extend3n6; rewrite (spec_extend6n n); apply Pfnn. + intros y; rewrite spec_extend4n6; rewrite (spec_extend6n n); apply Pfnn. + intros y; rewrite spec_extend5n6; rewrite (spec_extend6n n); apply Pfnn. + intros y; rewrite (spec_extend6n n); apply Pfnn. + intros m y; rewrite <- (spec_cast_l n m x); + rewrite <- (spec_cast_r n m y); apply Pfnn. + Qed. + + (* We level the two arguments before applying *) + (* the functions at each level (special zero case) *) + Definition same_level0 (x y: t_): res := + Eval lazy zeta beta iota delta [extend0 extend1 extend2 extend3 extend4 extend5 extend6 + GenBase.extend GenBase.extend_aux + ] in + match x with + | N0 wx => + if w0_eq0 wx then f0t y else + match y with + | N0 wy => f0 wx wy + | N1 wy => f1 (extend0 0 wx) wy + | N2 wy => f2 (extend0 1 wx) wy + | N3 wy => f3 (extend0 2 wx) wy + | N4 wy => f4 (extend0 3 wx) wy + | N5 wy => f5 (extend0 4 wx) wy + | N6 wy => f6 (extend0 5 wx) wy + | Nn m wy => fnn m (extend6 m (extend0 5 wx)) wy + end + | N1 wx => + match y with + | N0 wy => + if w0_eq0 wy then ft0 x else + f1 wx (extend0 0 wy) + | N1 wy => f1 wx wy + | N2 wy => f2 (extend1 0 wx) wy + | N3 wy => f3 (extend1 1 wx) wy + | N4 wy => f4 (extend1 2 wx) wy + | N5 wy => f5 (extend1 3 wx) wy + | N6 wy => f6 (extend1 4 wx) wy + | Nn m wy => fnn m (extend6 m (extend1 4 wx)) wy + end + | N2 wx => + match y with + | N0 wy => + if w0_eq0 wy then ft0 x else + f2 wx (extend0 1 wy) + | N1 wy => + f2 wx (extend1 0 wy) + | N2 wy => f2 wx wy + | N3 wy => f3 (extend2 0 wx) wy + | N4 wy => f4 (extend2 1 wx) wy + | N5 wy => f5 (extend2 2 wx) wy + | N6 wy => f6 (extend2 3 wx) wy + | Nn m wy => fnn m (extend6 m (extend2 3 wx)) wy + end + | N3 wx => + match y with + | N0 wy => + if w0_eq0 wy then ft0 x else + f3 wx (extend0 2 wy) + | N1 wy => + f3 wx (extend1 1 wy) + | N2 wy => + f3 wx (extend2 0 wy) + | N3 wy => f3 wx wy + | N4 wy => f4 (extend3 0 wx) wy + | N5 wy => f5 (extend3 1 wx) wy + | N6 wy => f6 (extend3 2 wx) wy + | Nn m wy => fnn m (extend6 m (extend3 2 wx)) wy + end + | N4 wx => + match y with + | N0 wy => + if w0_eq0 wy then ft0 x else + f4 wx (extend0 3 wy) + | N1 wy => + f4 wx (extend1 2 wy) + | N2 wy => + f4 wx (extend2 1 wy) + | N3 wy => + f4 wx (extend3 0 wy) + | N4 wy => f4 wx wy + | N5 wy => f5 (extend4 0 wx) wy + | N6 wy => f6 (extend4 1 wx) wy + | Nn m wy => fnn m (extend6 m (extend4 1 wx)) wy + end + | N5 wx => + match y with + | N0 wy => + if w0_eq0 wy then ft0 x else + f5 wx (extend0 4 wy) + | N1 wy => + f5 wx (extend1 3 wy) + | N2 wy => + f5 wx (extend2 2 wy) + | N3 wy => + f5 wx (extend3 1 wy) + | N4 wy => + f5 wx (extend4 0 wy) + | N5 wy => f5 wx wy + | N6 wy => f6 (extend5 0 wx) wy + | Nn m wy => fnn m (extend6 m (extend5 0 wx)) wy + end + | N6 wx => + match y with + | N0 wy => + if w0_eq0 wy then ft0 x else + f6 wx (extend0 5 wy) + | N1 wy => + f6 wx (extend1 4 wy) + | N2 wy => + f6 wx (extend2 3 wy) + | N3 wy => + f6 wx (extend3 2 wy) + | N4 wy => + f6 wx (extend4 1 wy) + | N5 wy => + f6 wx (extend5 0 wy) + | N6 wy => f6 wx wy + | Nn m wy => fnn m (extend6 m wx) wy + end + | Nn n wx => + match y with + | N0 wy => + if w0_eq0 wy then ft0 x else + fnn n wx (extend6 n (extend0 5 wy)) + | N1 wy => + fnn n wx (extend6 n (extend1 4 wy)) + | N2 wy => + fnn n wx (extend6 n (extend2 3 wy)) + | N3 wy => + fnn n wx (extend6 n (extend3 2 wy)) + | N4 wy => + fnn n wx (extend6 n (extend4 1 wy)) + | N5 wy => + fnn n wx (extend6 n (extend5 0 wy)) + | N6 wy => + fnn n wx (extend6 n wy) + | Nn m wy => + let mn := Max.max n m in + let d := diff n m in + fnn mn + (castm (diff_r n m) (extend_tr wx (snd d))) + (castm (diff_l n m) (extend_tr wy (fst d))) + end + end. + + Lemma spec_same_level0: forall x y, P [x] [y] (same_level0 x y). + Proof. + intros x; case x; clear x; unfold same_level0. + intros x. + generalize (spec_w0_eq0 x); case w0_eq0; intros H. + intros y; rewrite H; apply Pf0t. + clear H. + intros y; case y; clear y. + intros y; apply Pf0. + intros y; rewrite spec_extend0n1; apply Pf1. + intros y; rewrite spec_extend0n2; apply Pf2. + intros y; rewrite spec_extend0n3; apply Pf3. + intros y; rewrite spec_extend0n4; apply Pf4. + intros y; rewrite spec_extend0n5; apply Pf5. + intros y; rewrite spec_extend0n6; apply Pf6. + intros m y; rewrite spec_extend0n6; rewrite (spec_extend6n m); apply Pfnn. + intros x. + intros y; case y; clear y. + intros y. + generalize (spec_w0_eq0 y); case w0_eq0; intros H. + rewrite H; apply Pft0. + clear H. + rewrite spec_extend0n1; apply Pf1. + intros y; apply Pf1. + intros y; rewrite spec_extend1n2; apply Pf2. + intros y; rewrite spec_extend1n3; apply Pf3. + intros y; rewrite spec_extend1n4; apply Pf4. + intros y; rewrite spec_extend1n5; apply Pf5. + intros y; rewrite spec_extend1n6; apply Pf6. + intros m y; rewrite spec_extend1n6; rewrite (spec_extend6n m); apply Pfnn. + intros x. + intros y; case y; clear y. + intros y. + generalize (spec_w0_eq0 y); case w0_eq0; intros H. + rewrite H; apply Pft0. + clear H. + rewrite spec_extend0n2; apply Pf2. + intros y. + rewrite spec_extend1n2; apply Pf2. + intros y; apply Pf2. + intros y; rewrite spec_extend2n3; apply Pf3. + intros y; rewrite spec_extend2n4; apply Pf4. + intros y; rewrite spec_extend2n5; apply Pf5. + intros y; rewrite spec_extend2n6; apply Pf6. + intros m y; rewrite spec_extend2n6; rewrite (spec_extend6n m); apply Pfnn. + intros x. + intros y; case y; clear y. + intros y. + generalize (spec_w0_eq0 y); case w0_eq0; intros H. + rewrite H; apply Pft0. + clear H. + rewrite spec_extend0n3; apply Pf3. + intros y. + rewrite spec_extend1n3; apply Pf3. + intros y. + rewrite spec_extend2n3; apply Pf3. + intros y; apply Pf3. + intros y; rewrite spec_extend3n4; apply Pf4. + intros y; rewrite spec_extend3n5; apply Pf5. + intros y; rewrite spec_extend3n6; apply Pf6. + intros m y; rewrite spec_extend3n6; rewrite (spec_extend6n m); apply Pfnn. + intros x. + intros y; case y; clear y. + intros y. + generalize (spec_w0_eq0 y); case w0_eq0; intros H. + rewrite H; apply Pft0. + clear H. + rewrite spec_extend0n4; apply Pf4. + intros y. + rewrite spec_extend1n4; apply Pf4. + intros y. + rewrite spec_extend2n4; apply Pf4. + intros y. + rewrite spec_extend3n4; apply Pf4. + intros y; apply Pf4. + intros y; rewrite spec_extend4n5; apply Pf5. + intros y; rewrite spec_extend4n6; apply Pf6. + intros m y; rewrite spec_extend4n6; rewrite (spec_extend6n m); apply Pfnn. + intros x. + intros y; case y; clear y. + intros y. + generalize (spec_w0_eq0 y); case w0_eq0; intros H. + rewrite H; apply Pft0. + clear H. + rewrite spec_extend0n5; apply Pf5. + intros y. + rewrite spec_extend1n5; apply Pf5. + intros y. + rewrite spec_extend2n5; apply Pf5. + intros y. + rewrite spec_extend3n5; apply Pf5. + intros y. + rewrite spec_extend4n5; apply Pf5. + intros y; apply Pf5. + intros y; rewrite spec_extend5n6; apply Pf6. + intros m y; rewrite spec_extend5n6; rewrite (spec_extend6n m); apply Pfnn. + intros x. + intros y; case y; clear y. + intros y. + generalize (spec_w0_eq0 y); case w0_eq0; intros H. + rewrite H; apply Pft0. + clear H. + rewrite spec_extend0n6; apply Pf6. + intros y. + rewrite spec_extend1n6; apply Pf6. + intros y. + rewrite spec_extend2n6; apply Pf6. + intros y. + rewrite spec_extend3n6; apply Pf6. + intros y. + rewrite spec_extend4n6; apply Pf6. + intros y. + rewrite spec_extend5n6; apply Pf6. + intros y; apply Pf6. + intros m y; rewrite (spec_extend6n m); apply Pfnn. + intros n x y; case y; clear y. + intros y. + generalize (spec_w0_eq0 y); case w0_eq0; intros H. + rewrite H; apply Pft0. + clear H. + rewrite spec_extend0n6; rewrite (spec_extend6n n); apply Pfnn. + intros y. + rewrite spec_extend1n6; rewrite (spec_extend6n n); apply Pfnn. + intros y. + rewrite spec_extend2n6; rewrite (spec_extend6n n); apply Pfnn. + intros y. + rewrite spec_extend3n6; rewrite (spec_extend6n n); apply Pfnn. + intros y. + rewrite spec_extend4n6; rewrite (spec_extend6n n); apply Pfnn. + intros y. + rewrite spec_extend5n6; rewrite (spec_extend6n n); apply Pfnn. + intros y. + rewrite (spec_extend6n n); apply Pfnn. + intros m y; rewrite <- (spec_cast_l n m x); + rewrite <- (spec_cast_r n m y); apply Pfnn. + Qed. + + (* We iter the smaller argument with the bigger *) + Definition iter (x y: t_): res := + Eval lazy zeta beta iota delta [extend0 extend1 extend2 extend3 extend4 extend5 extend6 + GenBase.extend GenBase.extend_aux + ] in + match x, y with + | N0 wx, N0 wy => f0 wx wy + | N0 wx, N1 wy => f0n 0 wx wy + | N0 wx, N2 wy => f0n 1 wx wy + | N0 wx, N3 wy => f0n 2 wx wy + | N0 wx, N4 wy => f0n 3 wx wy + | N0 wx, N5 wy => f0n 4 wx wy + | N0 wx, N6 wy => f0n 5 wx wy + | N0 wx, Nn m wy => f6n m (extend0 5 wx) wy + | N1 wx, N0 wy => fn0 0 wx wy + | N1 wx, N1 wy => f1 wx wy + | N1 wx, N2 wy => f1n 0 wx wy + | N1 wx, N3 wy => f1n 1 wx wy + | N1 wx, N4 wy => f1n 2 wx wy + | N1 wx, N5 wy => f1n 3 wx wy + | N1 wx, N6 wy => f1n 4 wx wy + | N1 wx, Nn m wy => f6n m (extend1 4 wx) wy + | N2 wx, N0 wy => fn0 1 wx wy + | N2 wx, N1 wy => fn1 0 wx wy + | N2 wx, N2 wy => f2 wx wy + | N2 wx, N3 wy => f2n 0 wx wy + | N2 wx, N4 wy => f2n 1 wx wy + | N2 wx, N5 wy => f2n 2 wx wy + | N2 wx, N6 wy => f2n 3 wx wy + | N2 wx, Nn m wy => f6n m (extend2 3 wx) wy + | N3 wx, N0 wy => fn0 2 wx wy + | N3 wx, N1 wy => fn1 1 wx wy + | N3 wx, N2 wy => fn2 0 wx wy + | N3 wx, N3 wy => f3 wx wy + | N3 wx, N4 wy => f3n 0 wx wy + | N3 wx, N5 wy => f3n 1 wx wy + | N3 wx, N6 wy => f3n 2 wx wy + | N3 wx, Nn m wy => f6n m (extend3 2 wx) wy + | N4 wx, N0 wy => fn0 3 wx wy + | N4 wx, N1 wy => fn1 2 wx wy + | N4 wx, N2 wy => fn2 1 wx wy + | N4 wx, N3 wy => fn3 0 wx wy + | N4 wx, N4 wy => f4 wx wy + | N4 wx, N5 wy => f4n 0 wx wy + | N4 wx, N6 wy => f4n 1 wx wy + | N4 wx, Nn m wy => f6n m (extend4 1 wx) wy + | N5 wx, N0 wy => fn0 4 wx wy + | N5 wx, N1 wy => fn1 3 wx wy + | N5 wx, N2 wy => fn2 2 wx wy + | N5 wx, N3 wy => fn3 1 wx wy + | N5 wx, N4 wy => fn4 0 wx wy + | N5 wx, N5 wy => f5 wx wy + | N5 wx, N6 wy => f5n 0 wx wy + | N5 wx, Nn m wy => f6n m (extend5 0 wx) wy + | N6 wx, N0 wy => fn0 5 wx wy + | N6 wx, N1 wy => fn1 4 wx wy + | N6 wx, N2 wy => fn2 3 wx wy + | N6 wx, N3 wy => fn3 2 wx wy + | N6 wx, N4 wy => fn4 1 wx wy + | N6 wx, N5 wy => fn5 0 wx wy + | N6 wx, N6 wy => f6 wx wy + | N6 wx, Nn m wy => f6n m wx wy + | Nn n wx, N0 wy => fn6 n wx (extend0 5 wy) + | Nn n wx, N1 wy => fn6 n wx (extend1 4 wy) + | Nn n wx, N2 wy => fn6 n wx (extend2 3 wy) + | Nn n wx, N3 wy => fn6 n wx (extend3 2 wy) + | Nn n wx, N4 wy => fn6 n wx (extend4 1 wy) + | Nn n wx, N5 wy => fn6 n wx (extend5 0 wy) + | Nn n wx, N6 wy => fn6 n wx wy + | Nn n wx, Nn m wy => fnm n m wx wy + end. + + Ltac zg_tac := try + (red; simpl Zcompare; auto; + let t := fresh "H" in (intros t; discriminate H)). + Lemma spec_iter: forall x y, P [x] [y] (iter x y). + Proof. + intros x; case x; clear x; unfold iter. + intros x y; case y; clear y. + intros y; apply Pf0. + intros y; rewrite spec_eval0n1; apply (Pf0n 0); zg_tac. + intros y; rewrite spec_eval0n2; apply (Pf0n 1); zg_tac. + intros y; rewrite spec_eval0n3; apply (Pf0n 2); zg_tac. + intros y; rewrite spec_eval0n4; apply (Pf0n 3); zg_tac. + intros y; rewrite spec_eval0n5; apply (Pf0n 4); zg_tac. + intros y; rewrite spec_eval0n6; apply (Pf0n 5); zg_tac. + intros m y; rewrite spec_extend0n6; rewrite spec_eval6n; apply Pf6n. + intros x y; case y; clear y. + intros y; rewrite spec_eval0n1; apply (Pfn0 0); zg_tac. + intros y; apply Pf1. + intros y; rewrite spec_eval1n1; apply (Pf1n 0); zg_tac. + intros y; rewrite spec_eval1n2; apply (Pf1n 1); zg_tac. + intros y; rewrite spec_eval1n3; apply (Pf1n 2); zg_tac. + intros y; rewrite spec_eval1n4; apply (Pf1n 3); zg_tac. + intros y; rewrite spec_eval1n5; apply (Pf1n 4); zg_tac. + intros m y; rewrite spec_extend1n6; rewrite spec_eval6n; apply Pf6n. + intros x y; case y; clear y. + intros y; rewrite spec_eval0n2; apply (Pfn0 1); zg_tac. + intros y; rewrite spec_eval1n1; apply (Pfn1 0); zg_tac. + intros y; apply Pf2. + intros y; rewrite spec_eval2n1; apply (Pf2n 0); zg_tac. + intros y; rewrite spec_eval2n2; apply (Pf2n 1); zg_tac. + intros y; rewrite spec_eval2n3; apply (Pf2n 2); zg_tac. + intros y; rewrite spec_eval2n4; apply (Pf2n 3); zg_tac. + intros m y; rewrite spec_extend2n6; rewrite spec_eval6n; apply Pf6n. + intros x y; case y; clear y. + intros y; rewrite spec_eval0n3; apply (Pfn0 2); zg_tac. + intros y; rewrite spec_eval1n2; apply (Pfn1 1); zg_tac. + intros y; rewrite spec_eval2n1; apply (Pfn2 0); zg_tac. + intros y; apply Pf3. + intros y; rewrite spec_eval3n1; apply (Pf3n 0); zg_tac. + intros y; rewrite spec_eval3n2; apply (Pf3n 1); zg_tac. + intros y; rewrite spec_eval3n3; apply (Pf3n 2); zg_tac. + intros m y; rewrite spec_extend3n6; rewrite spec_eval6n; apply Pf6n. + intros x y; case y; clear y. + intros y; rewrite spec_eval0n4; apply (Pfn0 3); zg_tac. + intros y; rewrite spec_eval1n3; apply (Pfn1 2); zg_tac. + intros y; rewrite spec_eval2n2; apply (Pfn2 1); zg_tac. + intros y; rewrite spec_eval3n1; apply (Pfn3 0); zg_tac. + intros y; apply Pf4. + intros y; rewrite spec_eval4n1; apply (Pf4n 0); zg_tac. + intros y; rewrite spec_eval4n2; apply (Pf4n 1); zg_tac. + intros m y; rewrite spec_extend4n6; rewrite spec_eval6n; apply Pf6n. + intros x y; case y; clear y. + intros y; rewrite spec_eval0n5; apply (Pfn0 4); zg_tac. + intros y; rewrite spec_eval1n4; apply (Pfn1 3); zg_tac. + intros y; rewrite spec_eval2n3; apply (Pfn2 2); zg_tac. + intros y; rewrite spec_eval3n2; apply (Pfn3 1); zg_tac. + intros y; rewrite spec_eval4n1; apply (Pfn4 0); zg_tac. + intros y; apply Pf5. + intros y; rewrite spec_eval5n1; apply (Pf5n 0); zg_tac. + intros m y; rewrite spec_extend5n6; rewrite spec_eval6n; apply Pf6n. + intros x y; case y; clear y. + intros y; rewrite spec_eval0n6; apply (Pfn0 5); zg_tac. + intros y; rewrite spec_eval1n5; apply (Pfn1 4); zg_tac. + intros y; rewrite spec_eval2n4; apply (Pfn2 3); zg_tac. + intros y; rewrite spec_eval3n3; apply (Pfn3 2); zg_tac. + intros y; rewrite spec_eval4n2; apply (Pfn4 1); zg_tac. + intros y; rewrite spec_eval5n1; apply (Pfn5 0); zg_tac. + intros y; apply Pf6. + intros m y; rewrite spec_eval6n; apply Pf6n. + intros n x y; case y; clear y. + intros y; rewrite spec_extend0n6; rewrite spec_eval6n; apply Pfn6. + intros y; rewrite spec_extend1n6; rewrite spec_eval6n; apply Pfn6. + intros y; rewrite spec_extend2n6; rewrite spec_eval6n; apply Pfn6. + intros y; rewrite spec_extend3n6; rewrite spec_eval6n; apply Pfn6. + intros y; rewrite spec_extend4n6; rewrite spec_eval6n; apply Pfn6. + intros y; rewrite spec_extend5n6; rewrite spec_eval6n; apply Pfn6. + intros y; rewrite spec_eval6n; apply Pfn6. + intros m y; apply Pfnm. + Qed. + + (* We iter the smaller argument with the bigger (zero case) *) + Definition iter0 (x y: t_): res := + Eval lazy zeta beta iota delta [extend0 extend1 extend2 extend3 extend4 extend5 extend6 + GenBase.extend GenBase.extend_aux + ] in + match x with + | N0 wx => + if w0_eq0 wx then f0t y else + match y with + | N0 wy => f0 wx wy + | N1 wy => f0n 0 wx wy + | N2 wy => f0n 1 wx wy + | N3 wy => f0n 2 wx wy + | N4 wy => f0n 3 wx wy + | N5 wy => f0n 4 wx wy + | N6 wy => f0n 5 wx wy + | Nn m wy => f6n m (extend0 5 wx) wy + end + | N1 wx => + match y with + | N0 wy => + if w0_eq0 wy then ft0 x else + fn0 0 wx wy + | N1 wy => f1 wx wy + | N2 wy => f1n 0 wx wy + | N3 wy => f1n 1 wx wy + | N4 wy => f1n 2 wx wy + | N5 wy => f1n 3 wx wy + | N6 wy => f1n 4 wx wy + | Nn m wy => f6n m (extend1 4 wx) wy + end + | N2 wx => + match y with + | N0 wy => + if w0_eq0 wy then ft0 x else + fn0 1 wx wy + | N1 wy => + fn1 0 wx wy + | N2 wy => f2 wx wy + | N3 wy => f2n 0 wx wy + | N4 wy => f2n 1 wx wy + | N5 wy => f2n 2 wx wy + | N6 wy => f2n 3 wx wy + | Nn m wy => f6n m (extend2 3 wx) wy + end + | N3 wx => + match y with + | N0 wy => + if w0_eq0 wy then ft0 x else + fn0 2 wx wy + | N1 wy => + fn1 1 wx wy + | N2 wy => + fn2 0 wx wy + | N3 wy => f3 wx wy + | N4 wy => f3n 0 wx wy + | N5 wy => f3n 1 wx wy + | N6 wy => f3n 2 wx wy + | Nn m wy => f6n m (extend3 2 wx) wy + end + | N4 wx => + match y with + | N0 wy => + if w0_eq0 wy then ft0 x else + fn0 3 wx wy + | N1 wy => + fn1 2 wx wy + | N2 wy => + fn2 1 wx wy + | N3 wy => + fn3 0 wx wy + | N4 wy => f4 wx wy + | N5 wy => f4n 0 wx wy + | N6 wy => f4n 1 wx wy + | Nn m wy => f6n m (extend4 1 wx) wy + end + | N5 wx => + match y with + | N0 wy => + if w0_eq0 wy then ft0 x else + fn0 4 wx wy + | N1 wy => + fn1 3 wx wy + | N2 wy => + fn2 2 wx wy + | N3 wy => + fn3 1 wx wy + | N4 wy => + fn4 0 wx wy + | N5 wy => f5 wx wy + | N6 wy => f5n 0 wx wy + | Nn m wy => f6n m (extend5 0 wx) wy + end + | N6 wx => + match y with + | N0 wy => + if w0_eq0 wy then ft0 x else + fn0 5 wx wy + | N1 wy => + fn1 4 wx wy + | N2 wy => + fn2 3 wx wy + | N3 wy => + fn3 2 wx wy + | N4 wy => + fn4 1 wx wy + | N5 wy => + fn5 0 wx wy + | N6 wy => f6 wx wy + | Nn m wy => f6n m wx wy + end + | Nn n wx => + match y with + | N0 wy => + if w0_eq0 wy then ft0 x else + fn6 n wx (extend0 5 wy) + | N1 wy => + fn6 n wx (extend1 4 wy) + | N2 wy => + fn6 n wx (extend2 3 wy) + | N3 wy => + fn6 n wx (extend3 2 wy) + | N4 wy => + fn6 n wx (extend4 1 wy) + | N5 wy => + fn6 n wx (extend5 0 wy) + | N6 wy => + fn6 n wx wy + | Nn m wy => fnm n m wx wy + end + end. + + Lemma spec_iter0: forall x y, P [x] [y] (iter0 x y). + Proof. + intros x; case x; clear x; unfold iter0. + intros x. + generalize (spec_w0_eq0 x); case w0_eq0; intros H. + intros y; rewrite H; apply Pf0t. + clear H. + intros y; case y; clear y. + intros y; apply Pf0. + intros y; rewrite spec_eval0n1; apply (Pf0n 0); zg_tac. + intros y; rewrite spec_eval0n2; apply (Pf0n 1); zg_tac. + intros y; rewrite spec_eval0n3; apply (Pf0n 2); zg_tac. + intros y; rewrite spec_eval0n4; apply (Pf0n 3); zg_tac. + intros y; rewrite spec_eval0n5; apply (Pf0n 4); zg_tac. + intros y; rewrite spec_eval0n6; apply (Pf0n 5); zg_tac. + intros m y; rewrite spec_extend0n6; rewrite spec_eval6n; apply Pf6n. + intros x. + intros y; case y; clear y. + intros y. + generalize (spec_w0_eq0 y); case w0_eq0; intros H. + rewrite H; apply Pft0. + clear H. + rewrite spec_eval0n1; apply (Pfn0 0); zg_tac. + intros y; apply Pf1. + intros y; rewrite spec_eval1n1; apply (Pf1n 0); zg_tac. + intros y; rewrite spec_eval1n2; apply (Pf1n 1); zg_tac. + intros y; rewrite spec_eval1n3; apply (Pf1n 2); zg_tac. + intros y; rewrite spec_eval1n4; apply (Pf1n 3); zg_tac. + intros y; rewrite spec_eval1n5; apply (Pf1n 4); zg_tac. + intros m y; rewrite spec_extend1n6; rewrite spec_eval6n; apply Pf6n. + intros x. + intros y; case y; clear y. + intros y. + generalize (spec_w0_eq0 y); case w0_eq0; intros H. + rewrite H; apply Pft0. + clear H. + rewrite spec_eval0n2; apply (Pfn0 1); zg_tac. + intros y. + rewrite spec_eval1n1; apply (Pfn1 0); zg_tac. + intros y; apply Pf2. + intros y; rewrite spec_eval2n1; apply (Pf2n 0); zg_tac. + intros y; rewrite spec_eval2n2; apply (Pf2n 1); zg_tac. + intros y; rewrite spec_eval2n3; apply (Pf2n 2); zg_tac. + intros y; rewrite spec_eval2n4; apply (Pf2n 3); zg_tac. + intros m y; rewrite spec_extend2n6; rewrite spec_eval6n; apply Pf6n. + intros x. + intros y; case y; clear y. + intros y. + generalize (spec_w0_eq0 y); case w0_eq0; intros H. + rewrite H; apply Pft0. + clear H. + rewrite spec_eval0n3; apply (Pfn0 2); zg_tac. + intros y. + rewrite spec_eval1n2; apply (Pfn1 1); zg_tac. + intros y. + rewrite spec_eval2n1; apply (Pfn2 0); zg_tac. + intros y; apply Pf3. + intros y; rewrite spec_eval3n1; apply (Pf3n 0); zg_tac. + intros y; rewrite spec_eval3n2; apply (Pf3n 1); zg_tac. + intros y; rewrite spec_eval3n3; apply (Pf3n 2); zg_tac. + intros m y; rewrite spec_extend3n6; rewrite spec_eval6n; apply Pf6n. + intros x. + intros y; case y; clear y. + intros y. + generalize (spec_w0_eq0 y); case w0_eq0; intros H. + rewrite H; apply Pft0. + clear H. + rewrite spec_eval0n4; apply (Pfn0 3); zg_tac. + intros y. + rewrite spec_eval1n3; apply (Pfn1 2); zg_tac. + intros y. + rewrite spec_eval2n2; apply (Pfn2 1); zg_tac. + intros y. + rewrite spec_eval3n1; apply (Pfn3 0); zg_tac. + intros y; apply Pf4. + intros y; rewrite spec_eval4n1; apply (Pf4n 0); zg_tac. + intros y; rewrite spec_eval4n2; apply (Pf4n 1); zg_tac. + intros m y; rewrite spec_extend4n6; rewrite spec_eval6n; apply Pf6n. + intros x. + intros y; case y; clear y. + intros y. + generalize (spec_w0_eq0 y); case w0_eq0; intros H. + rewrite H; apply Pft0. + clear H. + rewrite spec_eval0n5; apply (Pfn0 4); zg_tac. + intros y. + rewrite spec_eval1n4; apply (Pfn1 3); zg_tac. + intros y. + rewrite spec_eval2n3; apply (Pfn2 2); zg_tac. + intros y. + rewrite spec_eval3n2; apply (Pfn3 1); zg_tac. + intros y. + rewrite spec_eval4n1; apply (Pfn4 0); zg_tac. + intros y; apply Pf5. + intros y; rewrite spec_eval5n1; apply (Pf5n 0); zg_tac. + intros m y; rewrite spec_extend5n6; rewrite spec_eval6n; apply Pf6n. + intros x. + intros y; case y; clear y. + intros y. + generalize (spec_w0_eq0 y); case w0_eq0; intros H. + rewrite H; apply Pft0. + clear H. + rewrite spec_eval0n6; apply (Pfn0 5); zg_tac. + intros y. + rewrite spec_eval1n5; apply (Pfn1 4); zg_tac. + intros y. + rewrite spec_eval2n4; apply (Pfn2 3); zg_tac. + intros y. + rewrite spec_eval3n3; apply (Pfn3 2); zg_tac. + intros y. + rewrite spec_eval4n2; apply (Pfn4 1); zg_tac. + intros y. + rewrite spec_eval5n1; apply (Pfn5 0); zg_tac. + intros y; apply Pf6. + intros m y; rewrite spec_eval6n; apply Pf6n. + intros n x y; case y; clear y. + intros y. + generalize (spec_w0_eq0 y); case w0_eq0; intros H. + rewrite H; apply Pft0. + clear H. + rewrite spec_extend0n6; rewrite spec_eval6n; apply Pfn6. + intros y. + rewrite spec_extend1n6; rewrite spec_eval6n; apply Pfn6. + intros y. + rewrite spec_extend2n6; rewrite spec_eval6n; apply Pfn6. + intros y. + rewrite spec_extend3n6; rewrite spec_eval6n; apply Pfn6. + intros y. + rewrite spec_extend4n6; rewrite spec_eval6n; apply Pfn6. + intros y. + rewrite spec_extend5n6; rewrite spec_eval6n; apply Pfn6. + intros y. + rewrite spec_eval6n; apply Pfn6. + intros m y; apply Pfnm. + Qed. + + End LevelAndIter. + + (***************************************************************) + (* *) + (* Reduction *) + (* *) + (***************************************************************) + + Definition reduce_0 (x:w) := N0 x. + Definition reduce_1 := + Eval lazy beta iota delta[reduce_n1] in + reduce_n1 _ _ zero w0_eq0 N0 N1. + Definition reduce_2 := + Eval lazy beta iota delta[reduce_n1] in + reduce_n1 _ _ zero w1_eq0 reduce_1 N2. + Definition reduce_3 := + Eval lazy beta iota delta[reduce_n1] in + reduce_n1 _ _ zero w2_eq0 reduce_2 N3. + Definition reduce_4 := + Eval lazy beta iota delta[reduce_n1] in + reduce_n1 _ _ zero w3_eq0 reduce_3 N4. + Definition reduce_5 := + Eval lazy beta iota delta[reduce_n1] in + reduce_n1 _ _ zero w4_eq0 reduce_4 N5. + Definition reduce_6 := + Eval lazy beta iota delta[reduce_n1] in + reduce_n1 _ _ zero w5_eq0 reduce_5 N6. + Definition reduce_7 := + Eval lazy beta iota delta[reduce_n1] in + reduce_n1 _ _ zero w6_eq0 reduce_6 (Nn 0). + Definition reduce_n n := + Eval lazy beta iota delta[reduce_n] in + reduce_n _ _ zero reduce_7 Nn n. + + Let spec_reduce_0: forall x, [reduce_0 x] = [N0 x]. + Proof. + intros x; unfold to_Z, reduce_0. + auto. + Qed. + + Let spec_reduce_1: forall x, [reduce_1 x] = [N1 x]. + Proof. + intros x; case x; unfold reduce_1. + exact (spec_0 w0_spec). + intros x1 y1. + generalize (spec_w0_eq0 x1); + case w0_eq0; intros H1; auto. + unfold to_Z; rewrite znz_to_Z_1. + unfold to_Z in H1; rewrite H1; auto. + Qed. + + Let spec_reduce_2: forall x, [reduce_2 x] = [N2 x]. + Proof. + intros x; case x; unfold reduce_2. + exact (spec_0 w0_spec). + intros x1 y1. + generalize (spec_w1_eq0 x1); + case w1_eq0; intros H1; auto. + rewrite spec_reduce_1. + unfold to_Z; rewrite znz_to_Z_2. + unfold to_Z in H1; rewrite H1; auto. + Qed. + + Let spec_reduce_3: forall x, [reduce_3 x] = [N3 x]. + Proof. + intros x; case x; unfold reduce_3. + exact (spec_0 w0_spec). + intros x1 y1. + generalize (spec_w2_eq0 x1); + case w2_eq0; intros H1; auto. + rewrite spec_reduce_2. + unfold to_Z; rewrite znz_to_Z_3. + unfold to_Z in H1; rewrite H1; auto. + Qed. + + Let spec_reduce_4: forall x, [reduce_4 x] = [N4 x]. + Proof. + intros x; case x; unfold reduce_4. + exact (spec_0 w0_spec). + intros x1 y1. + generalize (spec_w3_eq0 x1); + case w3_eq0; intros H1; auto. + rewrite spec_reduce_3. + unfold to_Z; rewrite znz_to_Z_4. + unfold to_Z in H1; rewrite H1; auto. + Qed. + + Let spec_reduce_5: forall x, [reduce_5 x] = [N5 x]. + Proof. + intros x; case x; unfold reduce_5. + exact (spec_0 w0_spec). + intros x1 y1. + generalize (spec_w4_eq0 x1); + case w4_eq0; intros H1; auto. + rewrite spec_reduce_4. + unfold to_Z; rewrite znz_to_Z_5. + unfold to_Z in H1; rewrite H1; auto. + Qed. + + Let spec_reduce_6: forall x, [reduce_6 x] = [N6 x]. + Proof. + intros x; case x; unfold reduce_6. + exact (spec_0 w0_spec). + intros x1 y1. + generalize (spec_w5_eq0 x1); + case w5_eq0; intros H1; auto. + rewrite spec_reduce_5. + unfold to_Z; rewrite znz_to_Z_6. + unfold to_Z in H1; rewrite H1; auto. + Qed. + + Let spec_reduce_7: forall x, [reduce_7 x] = [Nn 0 x]. + Proof. + intros x; case x; unfold reduce_7. + exact (spec_0 w0_spec). + intros x1 y1. + generalize (spec_w6_eq0 x1); + case w6_eq0; intros H1; auto. + rewrite spec_reduce_6. + unfold to_Z; rewrite znz_to_Z_7. + unfold to_Z in H1; rewrite H1; auto. + Qed. + + Let spec_reduce_n: forall n x, [reduce_n n x] = [Nn n x]. + Proof. + intros n; elim n; simpl reduce_n. + intros x; rewrite <- spec_reduce_7; auto. + intros n1 Hrec x; case x. + unfold to_Z; rewrite make_op_S; auto. + exact (spec_0 w0_spec). + intros x1 y1; case x1; auto. + rewrite Hrec. + rewrite spec_extendn0_0; auto. + Qed. + + (***************************************************************) + (* *) + (* Successor *) + (* *) + (***************************************************************) + + Definition w0_succ_c := w0_op.(znz_succ_c). + Definition w1_succ_c := w1_op.(znz_succ_c). + Definition w2_succ_c := w2_op.(znz_succ_c). + Definition w3_succ_c := w3_op.(znz_succ_c). + Definition w4_succ_c := w4_op.(znz_succ_c). + Definition w5_succ_c := w5_op.(znz_succ_c). + Definition w6_succ_c := w6_op.(znz_succ_c). + + Definition w0_succ := w0_op.(znz_succ). + Definition w1_succ := w1_op.(znz_succ). + Definition w2_succ := w2_op.(znz_succ). + Definition w3_succ := w3_op.(znz_succ). + Definition w4_succ := w4_op.(znz_succ). + Definition w5_succ := w5_op.(znz_succ). + Definition w6_succ := w6_op.(znz_succ). + + Definition succ x := + match x with + | N0 wx => + match w0_succ_c wx with + | C0 r => N0 r + | C1 r => N1 (WW one0 r) + end + | N1 wx => + match w1_succ_c wx with + | C0 r => N1 r + | C1 r => N2 (WW one1 r) + end + | N2 wx => + match w2_succ_c wx with + | C0 r => N2 r + | C1 r => N3 (WW one2 r) + end + | N3 wx => + match w3_succ_c wx with + | C0 r => N3 r + | C1 r => N4 (WW one3 r) + end + | N4 wx => + match w4_succ_c wx with + | C0 r => N4 r + | C1 r => N5 (WW one4 r) + end + | N5 wx => + match w5_succ_c wx with + | C0 r => N5 r + | C1 r => N6 (WW one5 r) + end + | N6 wx => + match w6_succ_c wx with + | C0 r => N6 r + | C1 r => Nn 0 (WW one6 r) + end + | Nn n wx => + let op := make_op n in + match op.(znz_succ_c) wx with + | C0 r => Nn n r + | C1 r => Nn (S n) (WW op.(znz_1) r) + end + end. + + Theorem spec_succ: forall n, [succ n] = [n] + 1. + Proof. + intros n; case n; unfold succ, to_Z. + intros n1; generalize (spec_succ_c w0_spec n1); + unfold succ, to_Z, w0_succ_c; case znz_succ_c; auto. + intros ww H; rewrite <- H. + (rewrite znz_to_Z_1; unfold interp_carry; + apply f_equal2 with (f := Zplus); auto; + apply f_equal2 with (f := Zmult); auto; + exact (spec_1 w0_spec)). + intros n1; generalize (spec_succ_c w1_spec n1); + unfold succ, to_Z, w1_succ_c; case znz_succ_c; auto. + intros ww H; rewrite <- H. + (rewrite znz_to_Z_2; unfold interp_carry; + apply f_equal2 with (f := Zplus); auto; + apply f_equal2 with (f := Zmult); auto; + exact (spec_1 w1_spec)). + intros n1; generalize (spec_succ_c w2_spec n1); + unfold succ, to_Z, w2_succ_c; case znz_succ_c; auto. + intros ww H; rewrite <- H. + (rewrite znz_to_Z_3; unfold interp_carry; + apply f_equal2 with (f := Zplus); auto; + apply f_equal2 with (f := Zmult); auto; + exact (spec_1 w2_spec)). + intros n1; generalize (spec_succ_c w3_spec n1); + unfold succ, to_Z, w3_succ_c; case znz_succ_c; auto. + intros ww H; rewrite <- H. + (rewrite znz_to_Z_4; unfold interp_carry; + apply f_equal2 with (f := Zplus); auto; + apply f_equal2 with (f := Zmult); auto; + exact (spec_1 w3_spec)). + intros n1; generalize (spec_succ_c w4_spec n1); + unfold succ, to_Z, w4_succ_c; case znz_succ_c; auto. + intros ww H; rewrite <- H. + (rewrite znz_to_Z_5; unfold interp_carry; + apply f_equal2 with (f := Zplus); auto; + apply f_equal2 with (f := Zmult); auto; + exact (spec_1 w4_spec)). + intros n1; generalize (spec_succ_c w5_spec n1); + unfold succ, to_Z, w5_succ_c; case znz_succ_c; auto. + intros ww H; rewrite <- H. + (rewrite znz_to_Z_6; unfold interp_carry; + apply f_equal2 with (f := Zplus); auto; + apply f_equal2 with (f := Zmult); auto; + exact (spec_1 w5_spec)). + intros n1; generalize (spec_succ_c w6_spec n1); + unfold succ, to_Z, w6_succ_c; case znz_succ_c; auto. + intros ww H; rewrite <- H. + (rewrite znz_to_Z_7; unfold interp_carry; + apply f_equal2 with (f := Zplus); auto; + apply f_equal2 with (f := Zmult); auto; + exact (spec_1 w6_spec)). + intros k n1; generalize (spec_succ_c (wn_spec k) n1). + unfold succ, to_Z; case znz_succ_c; auto. + intros ww H; rewrite <- H. + (rewrite (znz_to_Z_n k); unfold interp_carry; + apply f_equal2 with (f := Zplus); auto; + apply f_equal2 with (f := Zmult); auto; + exact (spec_1 (wn_spec k))). + Qed. + + (***************************************************************) + (* *) + (* Adddition *) + (* *) + (***************************************************************) + + Definition w0_add_c := znz_add_c w0_op. + Definition w0_add x y := + match w0_add_c x y with + | C0 r => N0 r + | C1 r => N1 (WW one0 r) + end. + + Definition w1_add_c := znz_add_c w1_op. + Definition w1_add x y := + match w1_add_c x y with + | C0 r => N1 r + | C1 r => N2 (WW one1 r) + end. + + Definition w2_add_c := znz_add_c w2_op. + Definition w2_add x y := + match w2_add_c x y with + | C0 r => N2 r + | C1 r => N3 (WW one2 r) + end. + + Definition w3_add_c := znz_add_c w3_op. + Definition w3_add x y := + match w3_add_c x y with + | C0 r => N3 r + | C1 r => N4 (WW one3 r) + end. + + Definition w4_add_c := znz_add_c w4_op. + Definition w4_add x y := + match w4_add_c x y with + | C0 r => N4 r + | C1 r => N5 (WW one4 r) + end. + + Definition w5_add_c := znz_add_c w5_op. + Definition w5_add x y := + match w5_add_c x y with + | C0 r => N5 r + | C1 r => N6 (WW one5 r) + end. + + Definition w6_add_c := znz_add_c w6_op. + Definition w6_add x y := + match w6_add_c x y with + | C0 r => N6 r + | C1 r => Nn 0 (WW one6 r) + end. + + Definition addn n (x y : word w6 (S n)) := + let op := make_op n in + match op.(znz_add_c) x y with + | C0 r => Nn n r + | C1 r => Nn (S n) (WW op.(znz_1) r) end. + + Let spec_w0_add: forall x y, [w0_add x y] = [N0 x] + [N0 y]. + Proof. + intros n m; unfold to_Z, w0_add, w0_add_c. + generalize (spec_add_c w0_spec n m); case znz_add_c; auto. + intros ww H; rewrite <- H. + rewrite znz_to_Z_1; unfold interp_carry; + apply f_equal2 with (f := Zplus); auto; + apply f_equal2 with (f := Zmult); auto; + exact (spec_1 w0_spec). + Qed. + Hint Rewrite spec_w0_add: addr. + + Let spec_w1_add: forall x y, [w1_add x y] = [N1 x] + [N1 y]. + Proof. + intros n m; unfold to_Z, w1_add, w1_add_c. + generalize (spec_add_c w1_spec n m); case znz_add_c; auto. + intros ww H; rewrite <- H. + rewrite znz_to_Z_2; unfold interp_carry; + apply f_equal2 with (f := Zplus); auto; + apply f_equal2 with (f := Zmult); auto; + exact (spec_1 w1_spec). + Qed. + Hint Rewrite spec_w1_add: addr. + + Let spec_w2_add: forall x y, [w2_add x y] = [N2 x] + [N2 y]. + Proof. + intros n m; unfold to_Z, w2_add, w2_add_c. + generalize (spec_add_c w2_spec n m); case znz_add_c; auto. + intros ww H; rewrite <- H. + rewrite znz_to_Z_3; unfold interp_carry; + apply f_equal2 with (f := Zplus); auto; + apply f_equal2 with (f := Zmult); auto; + exact (spec_1 w2_spec). + Qed. + Hint Rewrite spec_w2_add: addr. + + Let spec_w3_add: forall x y, [w3_add x y] = [N3 x] + [N3 y]. + Proof. + intros n m; unfold to_Z, w3_add, w3_add_c. + generalize (spec_add_c w3_spec n m); case znz_add_c; auto. + intros ww H; rewrite <- H. + rewrite znz_to_Z_4; unfold interp_carry; + apply f_equal2 with (f := Zplus); auto; + apply f_equal2 with (f := Zmult); auto; + exact (spec_1 w3_spec). + Qed. + Hint Rewrite spec_w3_add: addr. + + Let spec_w4_add: forall x y, [w4_add x y] = [N4 x] + [N4 y]. + Proof. + intros n m; unfold to_Z, w4_add, w4_add_c. + generalize (spec_add_c w4_spec n m); case znz_add_c; auto. + intros ww H; rewrite <- H. + rewrite znz_to_Z_5; unfold interp_carry; + apply f_equal2 with (f := Zplus); auto; + apply f_equal2 with (f := Zmult); auto; + exact (spec_1 w4_spec). + Qed. + Hint Rewrite spec_w4_add: addr. + + Let spec_w5_add: forall x y, [w5_add x y] = [N5 x] + [N5 y]. + Proof. + intros n m; unfold to_Z, w5_add, w5_add_c. + generalize (spec_add_c w5_spec n m); case znz_add_c; auto. + intros ww H; rewrite <- H. + rewrite znz_to_Z_6; unfold interp_carry; + apply f_equal2 with (f := Zplus); auto; + apply f_equal2 with (f := Zmult); auto; + exact (spec_1 w5_spec). + Qed. + Hint Rewrite spec_w5_add: addr. + + Let spec_w6_add: forall x y, [w6_add x y] = [N6 x] + [N6 y]. + Proof. + intros n m; unfold to_Z, w6_add, w6_add_c. + generalize (spec_add_c w6_spec n m); case znz_add_c; auto. + intros ww H; rewrite <- H. + rewrite znz_to_Z_7; unfold interp_carry; + apply f_equal2 with (f := Zplus); auto; + apply f_equal2 with (f := Zmult); auto; + exact (spec_1 w6_spec). + Qed. + Hint Rewrite spec_w6_add: addr. + + Let spec_wn_add: forall n x y, [addn n x y] = [Nn n x] + [Nn n y]. + Proof. + intros k n m; unfold to_Z, addn. + generalize (spec_add_c (wn_spec k) n m); case znz_add_c; auto. + intros ww H; rewrite <- H. + rewrite (znz_to_Z_n k); unfold interp_carry; + apply f_equal2 with (f := Zplus); auto; + apply f_equal2 with (f := Zmult); auto; + exact (spec_1 (wn_spec k)). + Qed. + Hint Rewrite spec_wn_add: addr. + Definition add := Eval lazy beta delta [same_level] in + (same_level t_ w0_add w1_add w2_add w3_add w4_add w5_add w6_add addn). + + Theorem spec_add: forall x y, [add x y] = [x] + [y]. + Proof. + unfold add. + generalize (spec_same_level t_ (fun x y res => [res] = x + y)). + unfold same_level; intros HH; apply HH; clear HH. + exact spec_w0_add. + exact spec_w1_add. + exact spec_w2_add. + exact spec_w3_add. + exact spec_w4_add. + exact spec_w5_add. + exact spec_w6_add. + exact spec_wn_add. + Qed. + + (***************************************************************) + (* *) + (* Predecessor *) + (* *) + (***************************************************************) + + Definition w0_pred_c := w0_op.(znz_pred_c). + Definition w1_pred_c := w1_op.(znz_pred_c). + Definition w2_pred_c := w2_op.(znz_pred_c). + Definition w3_pred_c := w3_op.(znz_pred_c). + Definition w4_pred_c := w4_op.(znz_pred_c). + Definition w5_pred_c := w5_op.(znz_pred_c). + Definition w6_pred_c := w6_op.(znz_pred_c). + + Definition pred x := + match x with + | N0 wx => + match w0_pred_c wx with + | C0 r => reduce_0 r + | C1 r => zero + end + | N1 wx => + match w1_pred_c wx with + | C0 r => reduce_1 r + | C1 r => zero + end + | N2 wx => + match w2_pred_c wx with + | C0 r => reduce_2 r + | C1 r => zero + end + | N3 wx => + match w3_pred_c wx with + | C0 r => reduce_3 r + | C1 r => zero + end + | N4 wx => + match w4_pred_c wx with + | C0 r => reduce_4 r + | C1 r => zero + end + | N5 wx => + match w5_pred_c wx with + | C0 r => reduce_5 r + | C1 r => zero + end + | N6 wx => + match w6_pred_c wx with + | C0 r => reduce_6 r + | C1 r => zero + end + | Nn n wx => + let op := make_op n in + match op.(znz_pred_c) wx with + | C0 r => reduce_n n r + | C1 r => zero + end + end. + + Theorem spec_pred: forall x, 0 < [x] -> [pred x] = [x] - 1. + Proof. + intros x; case x; unfold pred. + intros x1 H1; unfold w0_pred_c; + generalize (spec_pred_c w0_spec x1); case znz_pred_c; intros y1. + rewrite spec_reduce_0; auto. + unfold interp_carry; unfold to_Z. + case (spec_to_Z w0_spec x1); intros HH1 HH2. + case (spec_to_Z w0_spec y1); intros HH3 HH4 HH5. + assert (znz_to_Z w0_op x1 - 1 < 0); auto with zarith. + unfold to_Z in H1; auto with zarith. + intros x1 H1; unfold w1_pred_c; + generalize (spec_pred_c w1_spec x1); case znz_pred_c; intros y1. + rewrite spec_reduce_1; auto. + unfold interp_carry; unfold to_Z. + case (spec_to_Z w1_spec x1); intros HH1 HH2. + case (spec_to_Z w1_spec y1); intros HH3 HH4 HH5. + assert (znz_to_Z w1_op x1 - 1 < 0); auto with zarith. + unfold to_Z in H1; auto with zarith. + intros x1 H1; unfold w2_pred_c; + generalize (spec_pred_c w2_spec x1); case znz_pred_c; intros y1. + rewrite spec_reduce_2; auto. + unfold interp_carry; unfold to_Z. + case (spec_to_Z w2_spec x1); intros HH1 HH2. + case (spec_to_Z w2_spec y1); intros HH3 HH4 HH5. + assert (znz_to_Z w2_op x1 - 1 < 0); auto with zarith. + unfold to_Z in H1; auto with zarith. + intros x1 H1; unfold w3_pred_c; + generalize (spec_pred_c w3_spec x1); case znz_pred_c; intros y1. + rewrite spec_reduce_3; auto. + unfold interp_carry; unfold to_Z. + case (spec_to_Z w3_spec x1); intros HH1 HH2. + case (spec_to_Z w3_spec y1); intros HH3 HH4 HH5. + assert (znz_to_Z w3_op x1 - 1 < 0); auto with zarith. + unfold to_Z in H1; auto with zarith. + intros x1 H1; unfold w4_pred_c; + generalize (spec_pred_c w4_spec x1); case znz_pred_c; intros y1. + rewrite spec_reduce_4; auto. + unfold interp_carry; unfold to_Z. + case (spec_to_Z w4_spec x1); intros HH1 HH2. + case (spec_to_Z w4_spec y1); intros HH3 HH4 HH5. + assert (znz_to_Z w4_op x1 - 1 < 0); auto with zarith. + unfold to_Z in H1; auto with zarith. + intros x1 H1; unfold w5_pred_c; + generalize (spec_pred_c w5_spec x1); case znz_pred_c; intros y1. + rewrite spec_reduce_5; auto. + unfold interp_carry; unfold to_Z. + case (spec_to_Z w5_spec x1); intros HH1 HH2. + case (spec_to_Z w5_spec y1); intros HH3 HH4 HH5. + assert (znz_to_Z w5_op x1 - 1 < 0); auto with zarith. + unfold to_Z in H1; auto with zarith. + intros x1 H1; unfold w6_pred_c; + generalize (spec_pred_c w6_spec x1); case znz_pred_c; intros y1. + rewrite spec_reduce_6; auto. + unfold interp_carry; unfold to_Z. + case (spec_to_Z w6_spec x1); intros HH1 HH2. + case (spec_to_Z w6_spec y1); intros HH3 HH4 HH5. + assert (znz_to_Z w6_op x1 - 1 < 0); auto with zarith. + unfold to_Z in H1; auto with zarith. + intros n x1 H1; + generalize (spec_pred_c (wn_spec n) x1); case znz_pred_c; intros y1. + rewrite spec_reduce_n; auto. + unfold interp_carry; unfold to_Z. + case (spec_to_Z (wn_spec n) x1); intros HH1 HH2. + case (spec_to_Z (wn_spec n) y1); intros HH3 HH4 HH5. + assert (znz_to_Z (make_op n) x1 - 1 < 0); auto with zarith. + unfold to_Z in H1; auto with zarith. + Qed. + + Let spec_pred0: forall x, [x] = 0 -> [pred x] = 0. + Proof. + intros x; case x; unfold pred. + intros x1 H1; unfold w0_pred_c; + generalize (spec_pred_c w0_spec x1); case znz_pred_c; intros y1. + unfold interp_carry; unfold to_Z. + unfold to_Z in H1; auto with zarith. + case (spec_to_Z w0_spec y1); intros HH3 HH4; auto with zarith. + intros; exact (spec_0 w0_spec). + intros x1 H1; unfold w1_pred_c; + generalize (spec_pred_c w1_spec x1); case znz_pred_c; intros y1. + unfold interp_carry; unfold to_Z. + unfold to_Z in H1; auto with zarith. + case (spec_to_Z w1_spec y1); intros HH3 HH4; auto with zarith. + intros; exact (spec_0 w0_spec). + intros x1 H1; unfold w2_pred_c; + generalize (spec_pred_c w2_spec x1); case znz_pred_c; intros y1. + unfold interp_carry; unfold to_Z. + unfold to_Z in H1; auto with zarith. + case (spec_to_Z w2_spec y1); intros HH3 HH4; auto with zarith. + intros; exact (spec_0 w0_spec). + intros x1 H1; unfold w3_pred_c; + generalize (spec_pred_c w3_spec x1); case znz_pred_c; intros y1. + unfold interp_carry; unfold to_Z. + unfold to_Z in H1; auto with zarith. + case (spec_to_Z w3_spec y1); intros HH3 HH4; auto with zarith. + intros; exact (spec_0 w0_spec). + intros x1 H1; unfold w4_pred_c; + generalize (spec_pred_c w4_spec x1); case znz_pred_c; intros y1. + unfold interp_carry; unfold to_Z. + unfold to_Z in H1; auto with zarith. + case (spec_to_Z w4_spec y1); intros HH3 HH4; auto with zarith. + intros; exact (spec_0 w0_spec). + intros x1 H1; unfold w5_pred_c; + generalize (spec_pred_c w5_spec x1); case znz_pred_c; intros y1. + unfold interp_carry; unfold to_Z. + unfold to_Z in H1; auto with zarith. + case (spec_to_Z w5_spec y1); intros HH3 HH4; auto with zarith. + intros; exact (spec_0 w0_spec). + intros x1 H1; unfold w6_pred_c; + generalize (spec_pred_c w6_spec x1); case znz_pred_c; intros y1. + unfold interp_carry; unfold to_Z. + unfold to_Z in H1; auto with zarith. + case (spec_to_Z w6_spec y1); intros HH3 HH4; auto with zarith. + intros; exact (spec_0 w0_spec). + intros n x1 H1; + generalize (spec_pred_c (wn_spec n) x1); case znz_pred_c; intros y1. + unfold interp_carry; unfold to_Z. + unfold to_Z in H1; auto with zarith. + case (spec_to_Z (wn_spec n) y1); intros HH3 HH4; auto with zarith. + intros; exact (spec_0 w0_spec). + Qed. + + (***************************************************************) + (* *) + (* Subtraction *) + (* *) + (***************************************************************) + + Definition w0_sub_c := w0_op.(znz_sub_c). + Definition w1_sub_c := w1_op.(znz_sub_c). + Definition w2_sub_c := w2_op.(znz_sub_c). + Definition w3_sub_c := w3_op.(znz_sub_c). + Definition w4_sub_c := w4_op.(znz_sub_c). + Definition w5_sub_c := w5_op.(znz_sub_c). + Definition w6_sub_c := w6_op.(znz_sub_c). + + Definition w0_sub x y := + match w0_sub_c x y with + | C0 r => reduce_0 r + | C1 r => zero + end. + Definition w1_sub x y := + match w1_sub_c x y with + | C0 r => reduce_1 r + | C1 r => zero + end. + Definition w2_sub x y := + match w2_sub_c x y with + | C0 r => reduce_2 r + | C1 r => zero + end. + Definition w3_sub x y := + match w3_sub_c x y with + | C0 r => reduce_3 r + | C1 r => zero + end. + Definition w4_sub x y := + match w4_sub_c x y with + | C0 r => reduce_4 r + | C1 r => zero + end. + Definition w5_sub x y := + match w5_sub_c x y with + | C0 r => reduce_5 r + | C1 r => zero + end. + Definition w6_sub x y := + match w6_sub_c x y with + | C0 r => reduce_6 r + | C1 r => zero + end. + + Definition subn n (x y : word w6 (S n)) := + let op := make_op n in + match op.(znz_sub_c) x y with + | C0 r => Nn n r + | C1 r => N0 w_0 end. + + Let spec_w0_sub: forall x y, [N0 y] <= [N0 x] -> [w0_sub x y] = [N0 x] - [N0 y]. + Proof. + intros n m; unfold w0_sub, w0_sub_c. + generalize (spec_sub_c w0_spec n m); case znz_sub_c; + intros x; auto. + unfold interp_carry; unfold zero, w_0, to_Z. + rewrite (spec_0 w0_spec). + case (spec_to_Z w0_spec x); intros; auto with zarith. + Qed. + + Let spec_w1_sub: forall x y, [N1 y] <= [N1 x] -> [w1_sub x y] = [N1 x] - [N1 y]. + Proof. + intros n m; unfold w1_sub, w1_sub_c. + generalize (spec_sub_c w1_spec n m); case znz_sub_c; + intros x; try rewrite spec_reduce_1; auto. + unfold interp_carry; unfold zero, w_0, to_Z. + rewrite (spec_0 w0_spec). + case (spec_to_Z w1_spec x); intros; auto with zarith. + Qed. + + Let spec_w2_sub: forall x y, [N2 y] <= [N2 x] -> [w2_sub x y] = [N2 x] - [N2 y]. + Proof. + intros n m; unfold w2_sub, w2_sub_c. + generalize (spec_sub_c w2_spec n m); case znz_sub_c; + intros x; try rewrite spec_reduce_2; auto. + unfold interp_carry; unfold zero, w_0, to_Z. + rewrite (spec_0 w0_spec). + case (spec_to_Z w2_spec x); intros; auto with zarith. + Qed. + + Let spec_w3_sub: forall x y, [N3 y] <= [N3 x] -> [w3_sub x y] = [N3 x] - [N3 y]. + Proof. + intros n m; unfold w3_sub, w3_sub_c. + generalize (spec_sub_c w3_spec n m); case znz_sub_c; + intros x; try rewrite spec_reduce_3; auto. + unfold interp_carry; unfold zero, w_0, to_Z. + rewrite (spec_0 w0_spec). + case (spec_to_Z w3_spec x); intros; auto with zarith. + Qed. + + Let spec_w4_sub: forall x y, [N4 y] <= [N4 x] -> [w4_sub x y] = [N4 x] - [N4 y]. + Proof. + intros n m; unfold w4_sub, w4_sub_c. + generalize (spec_sub_c w4_spec n m); case znz_sub_c; + intros x; try rewrite spec_reduce_4; auto. + unfold interp_carry; unfold zero, w_0, to_Z. + rewrite (spec_0 w0_spec). + case (spec_to_Z w4_spec x); intros; auto with zarith. + Qed. + + Let spec_w5_sub: forall x y, [N5 y] <= [N5 x] -> [w5_sub x y] = [N5 x] - [N5 y]. + Proof. + intros n m; unfold w5_sub, w5_sub_c. + generalize (spec_sub_c w5_spec n m); case znz_sub_c; + intros x; try rewrite spec_reduce_5; auto. + unfold interp_carry; unfold zero, w_0, to_Z. + rewrite (spec_0 w0_spec). + case (spec_to_Z w5_spec x); intros; auto with zarith. + Qed. + + Let spec_w6_sub: forall x y, [N6 y] <= [N6 x] -> [w6_sub x y] = [N6 x] - [N6 y]. + Proof. + intros n m; unfold w6_sub, w6_sub_c. + generalize (spec_sub_c w6_spec n m); case znz_sub_c; + intros x; try rewrite spec_reduce_6; auto. + unfold interp_carry; unfold zero, w_0, to_Z. + rewrite (spec_0 w0_spec). + case (spec_to_Z w6_spec x); intros; auto with zarith. + Qed. + + Let spec_wn_sub: forall n x y, [Nn n y] <= [Nn n x] -> [subn n x y] = [Nn n x] - [Nn n y]. + Proof. + intros k n m; unfold subn. + generalize (spec_sub_c (wn_spec k) n m); case znz_sub_c; + intros x; auto. + unfold interp_carry, to_Z. + case (spec_to_Z (wn_spec k) x); intros; auto with zarith. + Qed. + + Definition sub := Eval lazy beta delta [same_level] in + (same_level t_ w0_sub w1_sub w2_sub w3_sub w4_sub w5_sub w6_sub subn). + + Theorem spec_sub: forall x y, [y] <= [x] -> [sub x y] = [x] - [y]. + Proof. + unfold sub. + generalize (spec_same_level t_ (fun x y res => y <= x -> [res] = x - y)). + unfold same_level; intros HH; apply HH; clear HH. + exact spec_w0_sub. + exact spec_w1_sub. + exact spec_w2_sub. + exact spec_w3_sub. + exact spec_w4_sub. + exact spec_w5_sub. + exact spec_w6_sub. + exact spec_wn_sub. + Qed. + + Let spec_w0_sub0: forall x y, [N0 x] < [N0 y] -> [w0_sub x y] = 0. + Proof. + intros n m; unfold w0_sub, w0_sub_c. + generalize (spec_sub_c w0_spec n m); case znz_sub_c; + intros x; unfold interp_carry. + unfold to_Z; case (spec_to_Z w0_spec x); intros; auto with zarith. + intros; unfold to_Z, zero, w_0; rewrite (spec_0 w0_spec); auto. + Qed. + + Let spec_w1_sub0: forall x y, [N1 x] < [N1 y] -> [w1_sub x y] = 0. + Proof. + intros n m; unfold w1_sub, w1_sub_c. + generalize (spec_sub_c w1_spec n m); case znz_sub_c; + intros x; unfold interp_carry. + unfold to_Z; case (spec_to_Z w1_spec x); intros; auto with zarith. + intros; unfold to_Z, zero, w_0; rewrite (spec_0 w0_spec); auto. + Qed. + + Let spec_w2_sub0: forall x y, [N2 x] < [N2 y] -> [w2_sub x y] = 0. + Proof. + intros n m; unfold w2_sub, w2_sub_c. + generalize (spec_sub_c w2_spec n m); case znz_sub_c; + intros x; unfold interp_carry. + unfold to_Z; case (spec_to_Z w2_spec x); intros; auto with zarith. + intros; unfold to_Z, zero, w_0; rewrite (spec_0 w0_spec); auto. + Qed. + + Let spec_w3_sub0: forall x y, [N3 x] < [N3 y] -> [w3_sub x y] = 0. + Proof. + intros n m; unfold w3_sub, w3_sub_c. + generalize (spec_sub_c w3_spec n m); case znz_sub_c; + intros x; unfold interp_carry. + unfold to_Z; case (spec_to_Z w3_spec x); intros; auto with zarith. + intros; unfold to_Z, zero, w_0; rewrite (spec_0 w0_spec); auto. + Qed. + + Let spec_w4_sub0: forall x y, [N4 x] < [N4 y] -> [w4_sub x y] = 0. + Proof. + intros n m; unfold w4_sub, w4_sub_c. + generalize (spec_sub_c w4_spec n m); case znz_sub_c; + intros x; unfold interp_carry. + unfold to_Z; case (spec_to_Z w4_spec x); intros; auto with zarith. + intros; unfold to_Z, zero, w_0; rewrite (spec_0 w0_spec); auto. + Qed. + + Let spec_w5_sub0: forall x y, [N5 x] < [N5 y] -> [w5_sub x y] = 0. + Proof. + intros n m; unfold w5_sub, w5_sub_c. + generalize (spec_sub_c w5_spec n m); case znz_sub_c; + intros x; unfold interp_carry. + unfold to_Z; case (spec_to_Z w5_spec x); intros; auto with zarith. + intros; unfold to_Z, zero, w_0; rewrite (spec_0 w0_spec); auto. + Qed. + + Let spec_w6_sub0: forall x y, [N6 x] < [N6 y] -> [w6_sub x y] = 0. + Proof. + intros n m; unfold w6_sub, w6_sub_c. + generalize (spec_sub_c w6_spec n m); case znz_sub_c; + intros x; unfold interp_carry. + unfold to_Z; case (spec_to_Z w6_spec x); intros; auto with zarith. + intros; unfold to_Z, zero, w_0; rewrite (spec_0 w0_spec); auto. + Qed. + + Let spec_wn_sub0: forall n x y, [Nn n x] < [Nn n y] -> [subn n x y] = 0. + Proof. + intros k n m; unfold subn. + generalize (spec_sub_c (wn_spec k) n m); case znz_sub_c; + intros x; unfold interp_carry. + unfold to_Z; case (spec_to_Z (wn_spec k) x); intros; auto with zarith. + intros; unfold to_Z, w_0; rewrite (spec_0 (w0_spec)); auto. + Qed. + + Theorem spec_sub0: forall x y, [x] < [y] -> [sub x y] = 0. + Proof. + unfold sub. + generalize (spec_same_level t_ (fun x y res => x < y -> [res] = 0)). + unfold same_level; intros HH; apply HH; clear HH. + exact spec_w0_sub0. + exact spec_w1_sub0. + exact spec_w2_sub0. + exact spec_w3_sub0. + exact spec_w4_sub0. + exact spec_w5_sub0. + exact spec_w6_sub0. + exact spec_wn_sub0. + Qed. + + (***************************************************************) + (* *) + (* Comparison *) + (* *) + (***************************************************************) + + Definition compare_0 := w0_op.(znz_compare). + Definition comparen_0 := + compare_mn_1 w0 w0 w_0 compare_0 (compare_0 w_0) compare_0. + Definition compare_1 := w1_op.(znz_compare). + Definition comparen_1 := + compare_mn_1 w1 w1 W0 compare_1 (compare_1 W0) compare_1. + Definition compare_2 := w2_op.(znz_compare). + Definition comparen_2 := + compare_mn_1 w2 w2 W0 compare_2 (compare_2 W0) compare_2. + Definition compare_3 := w3_op.(znz_compare). + Definition comparen_3 := + compare_mn_1 w3 w3 W0 compare_3 (compare_3 W0) compare_3. + Definition compare_4 := w4_op.(znz_compare). + Definition comparen_4 := + compare_mn_1 w4 w4 W0 compare_4 (compare_4 W0) compare_4. + Definition compare_5 := w5_op.(znz_compare). + Definition comparen_5 := + compare_mn_1 w5 w5 W0 compare_5 (compare_5 W0) compare_5. + Definition compare_6 := w6_op.(znz_compare). + Definition comparen_6 := + compare_mn_1 w6 w6 W0 compare_6 (compare_6 W0) compare_6. + + Definition comparenm n m wx wy := + let mn := Max.max n m in + let d := diff n m in + let op := make_op mn in + op.(znz_compare) + (castm (diff_r n m) (extend_tr wx (snd d))) + (castm (diff_l n m) (extend_tr wy (fst d))). + + Definition compare := Eval lazy beta delta [iter] in + (iter _ + compare_0 + (fun n x y => opp_compare (comparen_0 (S n) y x)) + (fun n => comparen_0 (S n)) + compare_1 + (fun n x y => opp_compare (comparen_1 (S n) y x)) + (fun n => comparen_1 (S n)) + compare_2 + (fun n x y => opp_compare (comparen_2 (S n) y x)) + (fun n => comparen_2 (S n)) + compare_3 + (fun n x y => opp_compare (comparen_3 (S n) y x)) + (fun n => comparen_3 (S n)) + compare_4 + (fun n x y => opp_compare (comparen_4 (S n) y x)) + (fun n => comparen_4 (S n)) + compare_5 + (fun n x y => opp_compare (comparen_5 (S n) y x)) + (fun n => comparen_5 (S n)) + compare_6 + (fun n x y => opp_compare (comparen_6 (S n) y x)) + (fun n => comparen_6 (S n)) + comparenm). + + Let spec_compare_0: forall x y, + match compare_0 x y with + Eq => [N0 x] = [N0 y] + | Lt => [N0 x] < [N0 y] + | Gt => [N0 x] > [N0 y] + end. + Proof. + unfold compare_0, to_Z; exact (spec_compare w0_spec). + Qed. + + Let spec_comparen_0: + forall (n : nat) (x : word w0 n) (y : w0), + match comparen_0 n x y with + | Eq => eval0n n x = [N0 y] + | Lt => eval0n n x < [N0 y] + | Gt => eval0n n x > [N0 y] + end. + intros n x y. + unfold comparen_0, to_Z; rewrite spec_gen_eval0n. + apply spec_compare_mn_1. + exact (spec_0 w0_spec). + intros x1; exact (spec_compare w0_spec w_0 x1). + exact (spec_to_Z w0_spec). + exact (spec_compare w0_spec). + exact (spec_compare w0_spec). + exact (spec_to_Z w0_spec). + Qed. + + Let spec_compare_1: forall x y, + match compare_1 x y with + Eq => [N1 x] = [N1 y] + | Lt => [N1 x] < [N1 y] + | Gt => [N1 x] > [N1 y] + end. + Proof. + unfold compare_1, to_Z; exact (spec_compare w1_spec). + Qed. + + Let spec_comparen_1: + forall (n : nat) (x : word w1 n) (y : w1), + match comparen_1 n x y with + | Eq => eval1n n x = [N1 y] + | Lt => eval1n n x < [N1 y] + | Gt => eval1n n x > [N1 y] + end. + intros n x y. + unfold comparen_1, to_Z; rewrite spec_gen_eval1n. + apply spec_compare_mn_1. + exact (spec_0 w1_spec). + intros x1; exact (spec_compare w1_spec W0 x1). + exact (spec_to_Z w1_spec). + exact (spec_compare w1_spec). + exact (spec_compare w1_spec). + exact (spec_to_Z w1_spec). + Qed. + + Let spec_compare_2: forall x y, + match compare_2 x y with + Eq => [N2 x] = [N2 y] + | Lt => [N2 x] < [N2 y] + | Gt => [N2 x] > [N2 y] + end. + Proof. + unfold compare_2, to_Z; exact (spec_compare w2_spec). + Qed. + + Let spec_comparen_2: + forall (n : nat) (x : word w2 n) (y : w2), + match comparen_2 n x y with + | Eq => eval2n n x = [N2 y] + | Lt => eval2n n x < [N2 y] + | Gt => eval2n n x > [N2 y] + end. + intros n x y. + unfold comparen_2, to_Z; rewrite spec_gen_eval2n. + apply spec_compare_mn_1. + exact (spec_0 w2_spec). + intros x1; exact (spec_compare w2_spec W0 x1). + exact (spec_to_Z w2_spec). + exact (spec_compare w2_spec). + exact (spec_compare w2_spec). + exact (spec_to_Z w2_spec). + Qed. + + Let spec_compare_3: forall x y, + match compare_3 x y with + Eq => [N3 x] = [N3 y] + | Lt => [N3 x] < [N3 y] + | Gt => [N3 x] > [N3 y] + end. + Proof. + unfold compare_3, to_Z; exact (spec_compare w3_spec). + Qed. + + Let spec_comparen_3: + forall (n : nat) (x : word w3 n) (y : w3), + match comparen_3 n x y with + | Eq => eval3n n x = [N3 y] + | Lt => eval3n n x < [N3 y] + | Gt => eval3n n x > [N3 y] + end. + intros n x y. + unfold comparen_3, to_Z; rewrite spec_gen_eval3n. + apply spec_compare_mn_1. + exact (spec_0 w3_spec). + intros x1; exact (spec_compare w3_spec W0 x1). + exact (spec_to_Z w3_spec). + exact (spec_compare w3_spec). + exact (spec_compare w3_spec). + exact (spec_to_Z w3_spec). + Qed. + + Let spec_compare_4: forall x y, + match compare_4 x y with + Eq => [N4 x] = [N4 y] + | Lt => [N4 x] < [N4 y] + | Gt => [N4 x] > [N4 y] + end. + Proof. + unfold compare_4, to_Z; exact (spec_compare w4_spec). + Qed. + + Let spec_comparen_4: + forall (n : nat) (x : word w4 n) (y : w4), + match comparen_4 n x y with + | Eq => eval4n n x = [N4 y] + | Lt => eval4n n x < [N4 y] + | Gt => eval4n n x > [N4 y] + end. + intros n x y. + unfold comparen_4, to_Z; rewrite spec_gen_eval4n. + apply spec_compare_mn_1. + exact (spec_0 w4_spec). + intros x1; exact (spec_compare w4_spec W0 x1). + exact (spec_to_Z w4_spec). + exact (spec_compare w4_spec). + exact (spec_compare w4_spec). + exact (spec_to_Z w4_spec). + Qed. + + Let spec_compare_5: forall x y, + match compare_5 x y with + Eq => [N5 x] = [N5 y] + | Lt => [N5 x] < [N5 y] + | Gt => [N5 x] > [N5 y] + end. + Proof. + unfold compare_5, to_Z; exact (spec_compare w5_spec). + Qed. + + Let spec_comparen_5: + forall (n : nat) (x : word w5 n) (y : w5), + match comparen_5 n x y with + | Eq => eval5n n x = [N5 y] + | Lt => eval5n n x < [N5 y] + | Gt => eval5n n x > [N5 y] + end. + intros n x y. + unfold comparen_5, to_Z; rewrite spec_gen_eval5n. + apply spec_compare_mn_1. + exact (spec_0 w5_spec). + intros x1; exact (spec_compare w5_spec W0 x1). + exact (spec_to_Z w5_spec). + exact (spec_compare w5_spec). + exact (spec_compare w5_spec). + exact (spec_to_Z w5_spec). + Qed. + + Let spec_compare_6: forall x y, + match compare_6 x y with + Eq => [N6 x] = [N6 y] + | Lt => [N6 x] < [N6 y] + | Gt => [N6 x] > [N6 y] + end. + Proof. + unfold compare_6, to_Z; exact (spec_compare w6_spec). + Qed. + + Let spec_comparen_6: + forall (n : nat) (x : word w6 n) (y : w6), + match comparen_6 n x y with + | Eq => eval6n n x = [N6 y] + | Lt => eval6n n x < [N6 y] + | Gt => eval6n n x > [N6 y] + end. + intros n x y. + unfold comparen_6, to_Z; rewrite spec_gen_eval6n. + apply spec_compare_mn_1. + exact (spec_0 w6_spec). + intros x1; exact (spec_compare w6_spec W0 x1). + exact (spec_to_Z w6_spec). + exact (spec_compare w6_spec). + exact (spec_compare w6_spec). + exact (spec_to_Z w6_spec). + Qed. + + Let spec_opp_compare: forall c (u v: Z), + match c with Eq => u = v | Lt => u < v | Gt => u > v end -> + match opp_compare c with Eq => v = u | Lt => v < u | Gt => v > u end. + Proof. + intros c u v; case c; unfold opp_compare; auto with zarith. + Qed. + + Theorem spec_compare: forall x y, + match compare x y with + Eq => [x] = [y] + | Lt => [x] < [y] + | Gt => [x] > [y] + end. + Proof. + refine (spec_iter _ (fun x y res => + match res with + Eq => x = y + | Lt => x < y + | Gt => x > y + end) + compare_0 + (fun n x y => opp_compare (comparen_0 (S n) y x)) + (fun n => comparen_0 (S n)) _ _ _ + compare_1 + (fun n x y => opp_compare (comparen_1 (S n) y x)) + (fun n => comparen_1 (S n)) _ _ _ + compare_2 + (fun n x y => opp_compare (comparen_2 (S n) y x)) + (fun n => comparen_2 (S n)) _ _ _ + compare_3 + (fun n x y => opp_compare (comparen_3 (S n) y x)) + (fun n => comparen_3 (S n)) _ _ _ + compare_4 + (fun n x y => opp_compare (comparen_4 (S n) y x)) + (fun n => comparen_4 (S n)) _ _ _ + compare_5 + (fun n x y => opp_compare (comparen_5 (S n) y x)) + (fun n => comparen_5 (S n)) _ _ _ + compare_6 + (fun n x y => opp_compare (comparen_6 (S n) y x)) + (fun n => comparen_6 (S n)) _ _ _ + comparenm _). + exact spec_compare_0. + intros n x y H;apply spec_opp_compare; apply spec_comparen_0. + intros n x y H; exact (spec_comparen_0 (S n) x y). + exact spec_compare_1. + intros n x y H;apply spec_opp_compare; apply spec_comparen_1. + intros n x y H; exact (spec_comparen_1 (S n) x y). + exact spec_compare_2. + intros n x y H;apply spec_opp_compare; apply spec_comparen_2. + intros n x y H; exact (spec_comparen_2 (S n) x y). + exact spec_compare_3. + intros n x y H;apply spec_opp_compare; apply spec_comparen_3. + intros n x y H; exact (spec_comparen_3 (S n) x y). + exact spec_compare_4. + intros n x y H;apply spec_opp_compare; apply spec_comparen_4. + intros n x y H; exact (spec_comparen_4 (S n) x y). + exact spec_compare_5. + intros n x y H;apply spec_opp_compare; apply spec_comparen_5. + intros n x y H; exact (spec_comparen_5 (S n) x y). + exact spec_compare_6. + intros n x y;apply spec_opp_compare; apply spec_comparen_6. + intros n; exact (spec_comparen_6 (S n)). + intros n m x y; unfold comparenm. + rewrite <- (spec_cast_l n m x); rewrite <- (spec_cast_r n m y). + unfold to_Z; apply (spec_compare (wn_spec (Max.max n m))). + Qed. + + Definition eq_bool x y := + match compare x y with + | Eq => true + | _ => false + end. + + Theorem spec_eq_bool: forall x y, + if eq_bool x y then [x] = [y] else [x] <> [y]. + Proof. + intros x y; unfold eq_bool. + generalize (spec_compare x y); case compare; auto with zarith. + Qed. + + (***************************************************************) + (* *) + (* Multiplication *) + (* *) + (***************************************************************) + + Definition w0_mul_c := w0_op.(znz_mul_c). + Definition w1_mul_c := w1_op.(znz_mul_c). + Definition w2_mul_c := w2_op.(znz_mul_c). + Definition w3_mul_c := w3_op.(znz_mul_c). + Definition w4_mul_c := w4_op.(znz_mul_c). + Definition w5_mul_c := w5_op.(znz_mul_c). + Definition w6_mul_c := w6_op.(znz_mul_c). + + Definition w0_mul_add := + Eval lazy beta delta [w_mul_add] in + @w_mul_add w0 w_0 w0_succ w0_add_c w0_mul_c. + Definition w1_mul_add := + Eval lazy beta delta [w_mul_add] in + @w_mul_add w1 W0 w1_succ w1_add_c w1_mul_c. + Definition w2_mul_add := + Eval lazy beta delta [w_mul_add] in + @w_mul_add w2 W0 w2_succ w2_add_c w2_mul_c. + Definition w3_mul_add := + Eval lazy beta delta [w_mul_add] in + @w_mul_add w3 W0 w3_succ w3_add_c w3_mul_c. + Definition w4_mul_add := + Eval lazy beta delta [w_mul_add] in + @w_mul_add w4 W0 w4_succ w4_add_c w4_mul_c. + Definition w5_mul_add := + Eval lazy beta delta [w_mul_add] in + @w_mul_add w5 W0 w5_succ w5_add_c w5_mul_c. + Definition w6_mul_add := + Eval lazy beta delta [w_mul_add] in + @w_mul_add w6 W0 w6_succ w6_add_c w6_mul_c. + + Definition w0_0W := w0_op.(znz_0W). + Definition w1_0W := w1_op.(znz_0W). + Definition w2_0W := w2_op.(znz_0W). + Definition w3_0W := w3_op.(znz_0W). + Definition w4_0W := w4_op.(znz_0W). + Definition w5_0W := w5_op.(znz_0W). + Definition w6_0W := w6_op.(znz_0W). + + Definition w0_mul_add_n1 := + @gen_mul_add_n1 w0 w_0 w0_op.(znz_WW) w0_0W w0_mul_add. + Definition w1_mul_add_n1 := + @gen_mul_add_n1 w1 W0 w1_op.(znz_WW) w1_0W w1_mul_add. + Definition w2_mul_add_n1 := + @gen_mul_add_n1 w2 W0 w2_op.(znz_WW) w2_0W w2_mul_add. + Definition w3_mul_add_n1 := + @gen_mul_add_n1 w3 W0 w3_op.(znz_WW) w3_0W w3_mul_add. + Definition w4_mul_add_n1 := + @gen_mul_add_n1 w4 W0 w4_op.(znz_WW) w4_0W w4_mul_add. + Definition w5_mul_add_n1 := + @gen_mul_add_n1 w5 W0 w5_op.(znz_WW) w5_0W w5_mul_add. + Definition w6_mul_add_n1 := + @gen_mul_add_n1 w6 W0 w6_op.(znz_WW) w6_0W w6_mul_add. + + Let to_Z0 n := + match n return word w0 (S n) -> t_ with + | 0%nat => fun x => N1 x + | 1%nat => fun x => N2 x + | 2%nat => fun x => N3 x + | 3%nat => fun x => N4 x + | 4%nat => fun x => N5 x + | 5%nat => fun x => N6 x + | 6%nat => fun x => Nn 0 x + | 7%nat => fun x => Nn 1 x + | _ => fun _ => N0 w_0 + end. + + Let to_Z1 n := + match n return word w1 (S n) -> t_ with + | 0%nat => fun x => N2 x + | 1%nat => fun x => N3 x + | 2%nat => fun x => N4 x + | 3%nat => fun x => N5 x + | 4%nat => fun x => N6 x + | 5%nat => fun x => Nn 0 x + | 6%nat => fun x => Nn 1 x + | _ => fun _ => N0 w_0 + end. + + Let to_Z2 n := + match n return word w2 (S n) -> t_ with + | 0%nat => fun x => N3 x + | 1%nat => fun x => N4 x + | 2%nat => fun x => N5 x + | 3%nat => fun x => N6 x + | 4%nat => fun x => Nn 0 x + | 5%nat => fun x => Nn 1 x + | _ => fun _ => N0 w_0 + end. + + Let to_Z3 n := + match n return word w3 (S n) -> t_ with + | 0%nat => fun x => N4 x + | 1%nat => fun x => N5 x + | 2%nat => fun x => N6 x + | 3%nat => fun x => Nn 0 x + | 4%nat => fun x => Nn 1 x + | _ => fun _ => N0 w_0 + end. + + Let to_Z4 n := + match n return word w4 (S n) -> t_ with + | 0%nat => fun x => N5 x + | 1%nat => fun x => N6 x + | 2%nat => fun x => Nn 0 x + | 3%nat => fun x => Nn 1 x + | _ => fun _ => N0 w_0 + end. + + Let to_Z5 n := + match n return word w5 (S n) -> t_ with + | 0%nat => fun x => N6 x + | 1%nat => fun x => Nn 0 x + | 2%nat => fun x => Nn 1 x + | _ => fun _ => N0 w_0 + end. + +Theorem to_Z0_spec: + forall n x, Z_of_nat n <= 7 -> [to_Z0 n x] = znz_to_Z (nmake_op _ w0_op (S n)) x. + intros n; case n; clear n. + unfold to_Z0. + intros x H; rewrite spec_eval0n1; auto. + intros n; case n; clear n. + unfold to_Z0. + intros x H; rewrite spec_eval0n2; auto. + intros n; case n; clear n. + unfold to_Z0. + intros x H; rewrite spec_eval0n3; auto. + intros n; case n; clear n. + unfold to_Z0. + intros x H; rewrite spec_eval0n4; auto. + intros n; case n; clear n. + unfold to_Z0. + intros x H; rewrite spec_eval0n5; auto. + intros n; case n; clear n. + unfold to_Z0. + intros x H; rewrite spec_eval0n6; auto. + intros n; case n; clear n. + unfold to_Z0. + intros x H; rewrite spec_eval0n7; auto. + intros n; case n; clear n. + unfold to_Z0. + intros x H; rewrite spec_eval0n8; auto. + intros n x. + repeat rewrite inj_S; unfold Zsucc; auto with zarith. + Qed. + +Theorem to_Z1_spec: + forall n x, Z_of_nat n <= 6 -> [to_Z1 n x] = znz_to_Z (nmake_op _ w1_op (S n)) x. + intros n; case n; clear n. + unfold to_Z1. + intros x H; rewrite spec_eval1n1; auto. + intros n; case n; clear n. + unfold to_Z1. + intros x H; rewrite spec_eval1n2; auto. + intros n; case n; clear n. + unfold to_Z1. + intros x H; rewrite spec_eval1n3; auto. + intros n; case n; clear n. + unfold to_Z1. + intros x H; rewrite spec_eval1n4; auto. + intros n; case n; clear n. + unfold to_Z1. + intros x H; rewrite spec_eval1n5; auto. + intros n; case n; clear n. + unfold to_Z1. + intros x H; rewrite spec_eval1n6; auto. + intros n; case n; clear n. + unfold to_Z1. + intros x H; rewrite spec_eval1n7; auto. + intros n x. + repeat rewrite inj_S; unfold Zsucc; auto with zarith. + Qed. + +Theorem to_Z2_spec: + forall n x, Z_of_nat n <= 5 -> [to_Z2 n x] = znz_to_Z (nmake_op _ w2_op (S n)) x. + intros n; case n; clear n. + unfold to_Z2. + intros x H; rewrite spec_eval2n1; auto. + intros n; case n; clear n. + unfold to_Z2. + intros x H; rewrite spec_eval2n2; auto. + intros n; case n; clear n. + unfold to_Z2. + intros x H; rewrite spec_eval2n3; auto. + intros n; case n; clear n. + unfold to_Z2. + intros x H; rewrite spec_eval2n4; auto. + intros n; case n; clear n. + unfold to_Z2. + intros x H; rewrite spec_eval2n5; auto. + intros n; case n; clear n. + unfold to_Z2. + intros x H; rewrite spec_eval2n6; auto. + intros n x. + repeat rewrite inj_S; unfold Zsucc; auto with zarith. + Qed. + +Theorem to_Z3_spec: + forall n x, Z_of_nat n <= 4 -> [to_Z3 n x] = znz_to_Z (nmake_op _ w3_op (S n)) x. + intros n; case n; clear n. + unfold to_Z3. + intros x H; rewrite spec_eval3n1; auto. + intros n; case n; clear n. + unfold to_Z3. + intros x H; rewrite spec_eval3n2; auto. + intros n; case n; clear n. + unfold to_Z3. + intros x H; rewrite spec_eval3n3; auto. + intros n; case n; clear n. + unfold to_Z3. + intros x H; rewrite spec_eval3n4; auto. + intros n; case n; clear n. + unfold to_Z3. + intros x H; rewrite spec_eval3n5; auto. + intros n x. + repeat rewrite inj_S; unfold Zsucc; auto with zarith. + Qed. + +Theorem to_Z4_spec: + forall n x, Z_of_nat n <= 3 -> [to_Z4 n x] = znz_to_Z (nmake_op _ w4_op (S n)) x. + intros n; case n; clear n. + unfold to_Z4. + intros x H; rewrite spec_eval4n1; auto. + intros n; case n; clear n. + unfold to_Z4. + intros x H; rewrite spec_eval4n2; auto. + intros n; case n; clear n. + unfold to_Z4. + intros x H; rewrite spec_eval4n3; auto. + intros n; case n; clear n. + unfold to_Z4. + intros x H; rewrite spec_eval4n4; auto. + intros n x. + repeat rewrite inj_S; unfold Zsucc; auto with zarith. + Qed. + +Theorem to_Z5_spec: + forall n x, Z_of_nat n <= 2 -> [to_Z5 n x] = znz_to_Z (nmake_op _ w5_op (S n)) x. + intros n; case n; clear n. + unfold to_Z5. + intros x H; rewrite spec_eval5n1; auto. + intros n; case n; clear n. + unfold to_Z5. + intros x H; rewrite spec_eval5n2; auto. + intros n; case n; clear n. + unfold to_Z5. + intros x H; rewrite spec_eval5n3; auto. + intros n x. + repeat rewrite inj_S; unfold Zsucc; auto with zarith. + Qed. + + Definition w0_mul n x y := + let (w,r) := w0_mul_add_n1 (S n) x y w_0 in + if w0_eq0 w then to_Z0 n r + else to_Z0 (S n) (WW (extend0 n w) r). + + Definition w1_mul n x y := + let (w,r) := w1_mul_add_n1 (S n) x y W0 in + if w1_eq0 w then to_Z1 n r + else to_Z1 (S n) (WW (extend1 n w) r). + + Definition w2_mul n x y := + let (w,r) := w2_mul_add_n1 (S n) x y W0 in + if w2_eq0 w then to_Z2 n r + else to_Z2 (S n) (WW (extend2 n w) r). + + Definition w3_mul n x y := + let (w,r) := w3_mul_add_n1 (S n) x y W0 in + if w3_eq0 w then to_Z3 n r + else to_Z3 (S n) (WW (extend3 n w) r). + + Definition w4_mul n x y := + let (w,r) := w4_mul_add_n1 (S n) x y W0 in + if w4_eq0 w then to_Z4 n r + else to_Z4 (S n) (WW (extend4 n w) r). + + Definition w5_mul n x y := + let (w,r) := w5_mul_add_n1 (S n) x y W0 in + if w5_eq0 w then to_Z5 n r + else to_Z5 (S n) (WW (extend5 n w) r). + + Definition w6_mul n x y := + let (w,r) := w6_mul_add_n1 (S n) x y W0 in + if w6_eq0 w then Nn n r + else Nn (S n) (WW (extend6 n w) r). + + Definition mulnm n m x y := + let mn := Max.max n m in + let d := diff n m in + let op := make_op mn in + reduce_n (S mn) (op.(znz_mul_c) + (castm (diff_r n m) (extend_tr x (snd d))) + (castm (diff_l n m) (extend_tr y (fst d)))). + + Definition mul := Eval lazy beta delta [iter0] in + (iter0 t_ + (fun x y => reduce_1 (w0_mul_c x y)) + (fun n x y => w0_mul n y x) + w0_mul + (fun x y => reduce_2 (w1_mul_c x y)) + (fun n x y => w1_mul n y x) + w1_mul + (fun x y => reduce_3 (w2_mul_c x y)) + (fun n x y => w2_mul n y x) + w2_mul + (fun x y => reduce_4 (w3_mul_c x y)) + (fun n x y => w3_mul n y x) + w3_mul + (fun x y => reduce_5 (w4_mul_c x y)) + (fun n x y => w4_mul n y x) + w4_mul + (fun x y => reduce_6 (w5_mul_c x y)) + (fun n x y => w5_mul n y x) + w5_mul + (fun x y => reduce_7 (w6_mul_c x y)) + (fun n x y => w6_mul n y x) + w6_mul + mulnm + (fun _ => N0 w_0) + (fun _ => N0 w_0) + ). + + Let spec_w0_mul_add: forall x y z, + let (q,r) := w0_mul_add x y z in + znz_to_Z w0_op q * (base (znz_digits w0_op)) + znz_to_Z w0_op r = + znz_to_Z w0_op x * znz_to_Z w0_op y + znz_to_Z w0_op z := + (spec_mul_add w0_spec). + + Let spec_w1_mul_add: forall x y z, + let (q,r) := w1_mul_add x y z in + znz_to_Z w1_op q * (base (znz_digits w1_op)) + znz_to_Z w1_op r = + znz_to_Z w1_op x * znz_to_Z w1_op y + znz_to_Z w1_op z := + (spec_mul_add w1_spec). + + Let spec_w2_mul_add: forall x y z, + let (q,r) := w2_mul_add x y z in + znz_to_Z w2_op q * (base (znz_digits w2_op)) + znz_to_Z w2_op r = + znz_to_Z w2_op x * znz_to_Z w2_op y + znz_to_Z w2_op z := + (spec_mul_add w2_spec). + + Let spec_w3_mul_add: forall x y z, + let (q,r) := w3_mul_add x y z in + znz_to_Z w3_op q * (base (znz_digits w3_op)) + znz_to_Z w3_op r = + znz_to_Z w3_op x * znz_to_Z w3_op y + znz_to_Z w3_op z := + (spec_mul_add w3_spec). + + Let spec_w4_mul_add: forall x y z, + let (q,r) := w4_mul_add x y z in + znz_to_Z w4_op q * (base (znz_digits w4_op)) + znz_to_Z w4_op r = + znz_to_Z w4_op x * znz_to_Z w4_op y + znz_to_Z w4_op z := + (spec_mul_add w4_spec). + + Let spec_w5_mul_add: forall x y z, + let (q,r) := w5_mul_add x y z in + znz_to_Z w5_op q * (base (znz_digits w5_op)) + znz_to_Z w5_op r = + znz_to_Z w5_op x * znz_to_Z w5_op y + znz_to_Z w5_op z := + (spec_mul_add w5_spec). + + Let spec_w6_mul_add: forall x y z, + let (q,r) := w6_mul_add x y z in + znz_to_Z w6_op q * (base (znz_digits w6_op)) + znz_to_Z w6_op r = + znz_to_Z w6_op x * znz_to_Z w6_op y + znz_to_Z w6_op z := + (spec_mul_add w6_spec). + + Theorem spec_w0_mul_add_n1: forall n x y z, + let (q,r) := w0_mul_add_n1 n x y z in + znz_to_Z w0_op q * (base (znz_digits (nmake_op _ w0_op n))) + + znz_to_Z (nmake_op _ w0_op n) r = + znz_to_Z (nmake_op _ w0_op n) x * znz_to_Z w0_op y + + znz_to_Z w0_op z. + Proof. + intros n x y z; unfold w0_mul_add_n1. + rewrite nmake_gen. + rewrite digits_gend. + change (base (GenBase.gen_digits (znz_digits w0_op) n)) with + (GenBase.gen_wB (znz_digits w0_op) n). + apply spec_gen_mul_add_n1; auto. + exact (spec_0 w0_spec). + exact (spec_WW w0_spec). + exact (spec_0W w0_spec). + exact (spec_mul_add w0_spec). + Qed. + + Theorem spec_w1_mul_add_n1: forall n x y z, + let (q,r) := w1_mul_add_n1 n x y z in + znz_to_Z w1_op q * (base (znz_digits (nmake_op _ w1_op n))) + + znz_to_Z (nmake_op _ w1_op n) r = + znz_to_Z (nmake_op _ w1_op n) x * znz_to_Z w1_op y + + znz_to_Z w1_op z. + Proof. + intros n x y z; unfold w1_mul_add_n1. + rewrite nmake_gen. + rewrite digits_gend. + change (base (GenBase.gen_digits (znz_digits w1_op) n)) with + (GenBase.gen_wB (znz_digits w1_op) n). + apply spec_gen_mul_add_n1; auto. + exact (spec_WW w1_spec). + exact (spec_0W w1_spec). + exact (spec_mul_add w1_spec). + Qed. + + Theorem spec_w2_mul_add_n1: forall n x y z, + let (q,r) := w2_mul_add_n1 n x y z in + znz_to_Z w2_op q * (base (znz_digits (nmake_op _ w2_op n))) + + znz_to_Z (nmake_op _ w2_op n) r = + znz_to_Z (nmake_op _ w2_op n) x * znz_to_Z w2_op y + + znz_to_Z w2_op z. + Proof. + intros n x y z; unfold w2_mul_add_n1. + rewrite nmake_gen. + rewrite digits_gend. + change (base (GenBase.gen_digits (znz_digits w2_op) n)) with + (GenBase.gen_wB (znz_digits w2_op) n). + apply spec_gen_mul_add_n1; auto. + exact (spec_WW w2_spec). + exact (spec_0W w2_spec). + exact (spec_mul_add w2_spec). + Qed. + + Theorem spec_w3_mul_add_n1: forall n x y z, + let (q,r) := w3_mul_add_n1 n x y z in + znz_to_Z w3_op q * (base (znz_digits (nmake_op _ w3_op n))) + + znz_to_Z (nmake_op _ w3_op n) r = + znz_to_Z (nmake_op _ w3_op n) x * znz_to_Z w3_op y + + znz_to_Z w3_op z. + Proof. + intros n x y z; unfold w3_mul_add_n1. + rewrite nmake_gen. + rewrite digits_gend. + change (base (GenBase.gen_digits (znz_digits w3_op) n)) with + (GenBase.gen_wB (znz_digits w3_op) n). + apply spec_gen_mul_add_n1; auto. + exact (spec_WW w3_spec). + exact (spec_0W w3_spec). + exact (spec_mul_add w3_spec). + Qed. + + Theorem spec_w4_mul_add_n1: forall n x y z, + let (q,r) := w4_mul_add_n1 n x y z in + znz_to_Z w4_op q * (base (znz_digits (nmake_op _ w4_op n))) + + znz_to_Z (nmake_op _ w4_op n) r = + znz_to_Z (nmake_op _ w4_op n) x * znz_to_Z w4_op y + + znz_to_Z w4_op z. + Proof. + intros n x y z; unfold w4_mul_add_n1. + rewrite nmake_gen. + rewrite digits_gend. + change (base (GenBase.gen_digits (znz_digits w4_op) n)) with + (GenBase.gen_wB (znz_digits w4_op) n). + apply spec_gen_mul_add_n1; auto. + exact (spec_WW w4_spec). + exact (spec_0W w4_spec). + exact (spec_mul_add w4_spec). + Qed. + + Theorem spec_w5_mul_add_n1: forall n x y z, + let (q,r) := w5_mul_add_n1 n x y z in + znz_to_Z w5_op q * (base (znz_digits (nmake_op _ w5_op n))) + + znz_to_Z (nmake_op _ w5_op n) r = + znz_to_Z (nmake_op _ w5_op n) x * znz_to_Z w5_op y + + znz_to_Z w5_op z. + Proof. + intros n x y z; unfold w5_mul_add_n1. + rewrite nmake_gen. + rewrite digits_gend. + change (base (GenBase.gen_digits (znz_digits w5_op) n)) with + (GenBase.gen_wB (znz_digits w5_op) n). + apply spec_gen_mul_add_n1; auto. + exact (spec_WW w5_spec). + exact (spec_0W w5_spec). + exact (spec_mul_add w5_spec). + Qed. + + Theorem spec_w6_mul_add_n1: forall n x y z, + let (q,r) := w6_mul_add_n1 n x y z in + znz_to_Z w6_op q * (base (znz_digits (nmake_op _ w6_op n))) + + znz_to_Z (nmake_op _ w6_op n) r = + znz_to_Z (nmake_op _ w6_op n) x * znz_to_Z w6_op y + + znz_to_Z w6_op z. + Proof. + intros n x y z; unfold w6_mul_add_n1. + rewrite nmake_gen. + rewrite digits_gend. + change (base (GenBase.gen_digits (znz_digits w6_op) n)) with + (GenBase.gen_wB (znz_digits w6_op) n). + apply spec_gen_mul_add_n1; auto. + exact (spec_WW w6_spec). + exact (spec_0W w6_spec). + exact (spec_mul_add w6_spec). + Qed. + + Lemma nmake_op_WW: forall ww ww1 n x y, + znz_to_Z (nmake_op ww ww1 (S n)) (WW x y) = + znz_to_Z (nmake_op ww ww1 n) x * base (znz_digits (nmake_op ww ww1 n)) + + znz_to_Z (nmake_op ww ww1 n) y. + auto. + Qed. + + Lemma extend0n_spec: forall n x1, + znz_to_Z (nmake_op _ w0_op (S n)) (extend0 n x1) = + znz_to_Z w0_op x1. + Proof. + intros n1 x2; rewrite nmake_gen. + unfold extend0. + rewrite GenBase.spec_extend; auto. + intros l; simpl; unfold w_0; rewrite (spec_0 w0_spec); ring. + Qed. + + Lemma extend1n_spec: forall n x1, + znz_to_Z (nmake_op _ w1_op (S n)) (extend1 n x1) = + znz_to_Z w1_op x1. + Proof. + intros n1 x2; rewrite nmake_gen. + unfold extend1. + rewrite GenBase.spec_extend; auto. + Qed. + + Lemma extend2n_spec: forall n x1, + znz_to_Z (nmake_op _ w2_op (S n)) (extend2 n x1) = + znz_to_Z w2_op x1. + Proof. + intros n1 x2; rewrite nmake_gen. + unfold extend2. + rewrite GenBase.spec_extend; auto. + Qed. + + Lemma extend3n_spec: forall n x1, + znz_to_Z (nmake_op _ w3_op (S n)) (extend3 n x1) = + znz_to_Z w3_op x1. + Proof. + intros n1 x2; rewrite nmake_gen. + unfold extend3. + rewrite GenBase.spec_extend; auto. + Qed. + + Lemma extend4n_spec: forall n x1, + znz_to_Z (nmake_op _ w4_op (S n)) (extend4 n x1) = + znz_to_Z w4_op x1. + Proof. + intros n1 x2; rewrite nmake_gen. + unfold extend4. + rewrite GenBase.spec_extend; auto. + Qed. + + Lemma extend5n_spec: forall n x1, + znz_to_Z (nmake_op _ w5_op (S n)) (extend5 n x1) = + znz_to_Z w5_op x1. + Proof. + intros n1 x2; rewrite nmake_gen. + unfold extend5. + rewrite GenBase.spec_extend; auto. + Qed. + + Lemma extend6n_spec: forall n x1, + znz_to_Z (nmake_op _ w6_op (S n)) (extend6 n x1) = + znz_to_Z w6_op x1. + Proof. + intros n1 x2; rewrite nmake_gen. + unfold extend6. + rewrite GenBase.spec_extend; auto. + Qed. + + Lemma spec_muln: + forall n (x: word _ (S n)) y, + [Nn (S n) (znz_mul_c (make_op n) x y)] = [Nn n x] * [Nn n y]. + Proof. + intros n x y; unfold to_Z. + rewrite <- (spec_mul_c (wn_spec n)). + rewrite make_op_S. + case znz_mul_c; auto. + Qed. + Theorem spec_mul: forall x y, [mul x y] = [x] * [y]. + Proof. + assert(F0: + forall n x y, + Z_of_nat n <= 6 -> [w0_mul n x y] = eval0n (S n) x * [N0 y]). + intros n x y H; unfold w0_mul. + generalize (spec_w0_mul_add_n1 (S n) x y w_0). + case w0_mul_add_n1; intros x1 y1. + change (znz_to_Z (nmake_op _ w0_op (S n)) x) with (eval0n (S n) x). + change (znz_to_Z w0_op y) with ([N0 y]). + unfold w_0; rewrite (spec_0 w0_spec); rewrite Zplus_0_r. + intros H1; rewrite <- H1; clear H1. + generalize (spec_w0_eq0 x1); case w0_eq0; intros HH. + unfold to_Z in HH; rewrite HH. + rewrite to_Z0_spec; auto with zarith. + rewrite to_Z0_spec; try (rewrite inj_S; auto with zarith). + rewrite nmake_op_WW; rewrite extend0n_spec; auto. + assert(F1: + forall n x y, + Z_of_nat n <= 5 -> [w1_mul n x y] = eval1n (S n) x * [N1 y]). + intros n x y H; unfold w1_mul. + generalize (spec_w1_mul_add_n1 (S n) x y W0). + case w1_mul_add_n1; intros x1 y1. + change (znz_to_Z (nmake_op _ w1_op (S n)) x) with (eval1n (S n) x). + change (znz_to_Z w1_op y) with ([N1 y]). + change (znz_to_Z w1_op W0) with 0; rewrite Zplus_0_r. + intros H1; rewrite <- H1; clear H1. + generalize (spec_w1_eq0 x1); case w1_eq0; intros HH. + unfold to_Z in HH; rewrite HH. + rewrite to_Z1_spec; auto with zarith. + rewrite to_Z1_spec; try (rewrite inj_S; auto with zarith). + rewrite nmake_op_WW; rewrite extend1n_spec; auto. + assert(F2: + forall n x y, + Z_of_nat n <= 4 -> [w2_mul n x y] = eval2n (S n) x * [N2 y]). + intros n x y H; unfold w2_mul. + generalize (spec_w2_mul_add_n1 (S n) x y W0). + case w2_mul_add_n1; intros x1 y1. + change (znz_to_Z (nmake_op _ w2_op (S n)) x) with (eval2n (S n) x). + change (znz_to_Z w2_op y) with ([N2 y]). + change (znz_to_Z w2_op W0) with 0; rewrite Zplus_0_r. + intros H1; rewrite <- H1; clear H1. + generalize (spec_w2_eq0 x1); case w2_eq0; intros HH. + unfold to_Z in HH; rewrite HH. + rewrite to_Z2_spec; auto with zarith. + rewrite to_Z2_spec; try (rewrite inj_S; auto with zarith). + rewrite nmake_op_WW; rewrite extend2n_spec; auto. + assert(F3: + forall n x y, + Z_of_nat n <= 3 -> [w3_mul n x y] = eval3n (S n) x * [N3 y]). + intros n x y H; unfold w3_mul. + generalize (spec_w3_mul_add_n1 (S n) x y W0). + case w3_mul_add_n1; intros x1 y1. + change (znz_to_Z (nmake_op _ w3_op (S n)) x) with (eval3n (S n) x). + change (znz_to_Z w3_op y) with ([N3 y]). + change (znz_to_Z w3_op W0) with 0; rewrite Zplus_0_r. + intros H1; rewrite <- H1; clear H1. + generalize (spec_w3_eq0 x1); case w3_eq0; intros HH. + unfold to_Z in HH; rewrite HH. + rewrite to_Z3_spec; auto with zarith. + rewrite to_Z3_spec; try (rewrite inj_S; auto with zarith). + rewrite nmake_op_WW; rewrite extend3n_spec; auto. + assert(F4: + forall n x y, + Z_of_nat n <= 2 -> [w4_mul n x y] = eval4n (S n) x * [N4 y]). + intros n x y H; unfold w4_mul. + generalize (spec_w4_mul_add_n1 (S n) x y W0). + case w4_mul_add_n1; intros x1 y1. + change (znz_to_Z (nmake_op _ w4_op (S n)) x) with (eval4n (S n) x). + change (znz_to_Z w4_op y) with ([N4 y]). + change (znz_to_Z w4_op W0) with 0; rewrite Zplus_0_r. + intros H1; rewrite <- H1; clear H1. + generalize (spec_w4_eq0 x1); case w4_eq0; intros HH. + unfold to_Z in HH; rewrite HH. + rewrite to_Z4_spec; auto with zarith. + rewrite to_Z4_spec; try (rewrite inj_S; auto with zarith). + rewrite nmake_op_WW; rewrite extend4n_spec; auto. + assert(F5: + forall n x y, + Z_of_nat n <= 1 -> [w5_mul n x y] = eval5n (S n) x * [N5 y]). + intros n x y H; unfold w5_mul. + generalize (spec_w5_mul_add_n1 (S n) x y W0). + case w5_mul_add_n1; intros x1 y1. + change (znz_to_Z (nmake_op _ w5_op (S n)) x) with (eval5n (S n) x). + change (znz_to_Z w5_op y) with ([N5 y]). + change (znz_to_Z w5_op W0) with 0; rewrite Zplus_0_r. + intros H1; rewrite <- H1; clear H1. + generalize (spec_w5_eq0 x1); case w5_eq0; intros HH. + unfold to_Z in HH; rewrite HH. + rewrite to_Z5_spec; auto with zarith. + rewrite to_Z5_spec; try (rewrite inj_S; auto with zarith). + rewrite nmake_op_WW; rewrite extend5n_spec; auto. + assert(F6: + forall n x y, + [w6_mul n x y] = eval6n (S n) x * [N6 y]). + intros n x y; unfold w6_mul. + generalize (spec_w6_mul_add_n1 (S n) x y W0). + case w6_mul_add_n1; intros x1 y1. + change (znz_to_Z (nmake_op _ w6_op (S n)) x) with (eval6n (S n) x). + change (znz_to_Z w6_op y) with ([N6 y]). + change (znz_to_Z w6_op W0) with 0; rewrite Zplus_0_r. + intros H1; rewrite <- H1; clear H1. + generalize (spec_w6_eq0 x1); case w6_eq0; intros HH. + unfold to_Z in HH; rewrite HH. + rewrite spec_eval6n; unfold eval6n, nmake_op6; auto. + rewrite spec_eval6n; unfold eval6n, nmake_op6. + rewrite nmake_op_WW; rewrite extend6n_spec; auto. + refine (spec_iter0 t_ (fun x y res => [res] = x * y) + (fun x y => reduce_1 (w0_mul_c x y)) + (fun n x y => w0_mul n y x) + w0_mul _ _ _ + (fun x y => reduce_2 (w1_mul_c x y)) + (fun n x y => w1_mul n y x) + w1_mul _ _ _ + (fun x y => reduce_3 (w2_mul_c x y)) + (fun n x y => w2_mul n y x) + w2_mul _ _ _ + (fun x y => reduce_4 (w3_mul_c x y)) + (fun n x y => w3_mul n y x) + w3_mul _ _ _ + (fun x y => reduce_5 (w4_mul_c x y)) + (fun n x y => w4_mul n y x) + w4_mul _ _ _ + (fun x y => reduce_6 (w5_mul_c x y)) + (fun n x y => w5_mul n y x) + w5_mul _ _ _ + (fun x y => reduce_7 (w6_mul_c x y)) + (fun n x y => w6_mul n y x) + w6_mul _ _ _ + mulnm _ + (fun _ => N0 w_0) _ + (fun _ => N0 w_0) _ + ). + intros x y; rewrite spec_reduce_1. + unfold w0_mul_c, to_Z. + generalize (spec_mul_c w0_spec x y). + intros HH; rewrite <- HH; clear HH; auto. + intros n x y H; rewrite F0; auto with zarith. + intros n x y H; rewrite F0; auto with zarith. + intros x y; rewrite spec_reduce_2. + unfold w1_mul_c, to_Z. + generalize (spec_mul_c w1_spec x y). + intros HH; rewrite <- HH; clear HH; auto. + intros n x y H; rewrite F1; auto with zarith. + intros n x y H; rewrite F1; auto with zarith. + intros x y; rewrite spec_reduce_3. + unfold w2_mul_c, to_Z. + generalize (spec_mul_c w2_spec x y). + intros HH; rewrite <- HH; clear HH; auto. + intros n x y H; rewrite F2; auto with zarith. + intros n x y H; rewrite F2; auto with zarith. + intros x y; rewrite spec_reduce_4. + unfold w3_mul_c, to_Z. + generalize (spec_mul_c w3_spec x y). + intros HH; rewrite <- HH; clear HH; auto. + intros n x y H; rewrite F3; auto with zarith. + intros n x y H; rewrite F3; auto with zarith. + intros x y; rewrite spec_reduce_5. + unfold w4_mul_c, to_Z. + generalize (spec_mul_c w4_spec x y). + intros HH; rewrite <- HH; clear HH; auto. + intros n x y H; rewrite F4; auto with zarith. + intros n x y H; rewrite F4; auto with zarith. + intros x y; rewrite spec_reduce_6. + unfold w5_mul_c, to_Z. + generalize (spec_mul_c w5_spec x y). + intros HH; rewrite <- HH; clear HH; auto. + intros n x y H; rewrite F5; auto with zarith. + intros n x y H; rewrite F5; auto with zarith. + intros x y; rewrite spec_reduce_7. + unfold w6_mul_c, to_Z. + generalize (spec_mul_c w6_spec x y). + intros HH; rewrite <- HH; clear HH; auto. + intros n x y; rewrite F6; auto with zarith. + intros n x y; rewrite F6; auto with zarith. + intros n m x y; unfold mulnm. + rewrite spec_reduce_n. + rewrite <- (spec_cast_l n m x). + rewrite <- (spec_cast_r n m y). + rewrite spec_muln; rewrite spec_cast_l; rewrite spec_cast_r; auto. + intros x; unfold to_Z, w_0; rewrite (spec_0 w0_spec); ring. + intros x; unfold to_Z, w_0; rewrite (spec_0 w0_spec); ring. + Qed. + + (***************************************************************) + (* *) + (* Square *) + (* *) + (***************************************************************) + + Definition w0_square_c := w0_op.(znz_square_c). + Definition w1_square_c := w1_op.(znz_square_c). + Definition w2_square_c := w2_op.(znz_square_c). + Definition w3_square_c := w3_op.(znz_square_c). + Definition w4_square_c := w4_op.(znz_square_c). + Definition w5_square_c := w5_op.(znz_square_c). + Definition w6_square_c := w6_op.(znz_square_c). + + Definition square x := + match x with + | N0 wx => reduce_1 (w0_square_c wx) + | N1 wx => N2 (w1_square_c wx) + | N2 wx => N3 (w2_square_c wx) + | N3 wx => N4 (w3_square_c wx) + | N4 wx => N5 (w4_square_c wx) + | N5 wx => N6 (w5_square_c wx) + | N6 wx => Nn 0 (w6_square_c wx) + | Nn n wx => + let op := make_op n in + Nn (S n) (op.(znz_square_c) wx) + end. + + Theorem spec_square: forall x, [square x] = [x] * [x]. + Proof. + intros x; case x; unfold square; clear x. + intros x; rewrite spec_reduce_1; unfold to_Z. + exact (spec_square_c w0_spec x). + intros x; unfold to_Z. + exact (spec_square_c w1_spec x). + intros x; unfold to_Z. + exact (spec_square_c w2_spec x). + intros x; unfold to_Z. + exact (spec_square_c w3_spec x). + intros x; unfold to_Z. + exact (spec_square_c w4_spec x). + intros x; unfold to_Z. + exact (spec_square_c w5_spec x). + intros x; unfold to_Z. + exact (spec_square_c w6_spec x). + intros n x; unfold to_Z. + rewrite make_op_S. + exact (spec_square_c (wn_spec n) x). +Qed. + + (***************************************************************) + (* *) + (* Power *) + (* *) + (***************************************************************) + + Fixpoint power_pos (x:t) (p:positive) {struct p} : t := + match p with + | xH => x + | xO p => square (power_pos x p) + | xI p => mul (square (power_pos x p)) x + end. + + Theorem spec_power_pos: forall x n, [power_pos x n] = [x] ^ Zpos n. + Proof. + intros x n; generalize x; elim n; clear n x; simpl power_pos. + intros; rewrite spec_mul; rewrite spec_square; rewrite H. + rewrite Zpos_xI; rewrite Zpower_exp; auto with zarith. + rewrite (Zmult_comm 2); rewrite Zpower_mult; auto with zarith. + rewrite Zpower_2; rewrite Zpower_1_r; auto. + intros; rewrite spec_square; rewrite H. + rewrite Zpos_xO; auto with zarith. + rewrite (Zmult_comm 2); rewrite Zpower_mult; auto with zarith. + rewrite Zpower_2; auto. + intros; rewrite Zpower_1_r; auto. + Qed. + + + (***************************************************************) + (* *) + (* Square root *) + (* *) + (***************************************************************) + + Definition w0_sqrt := w0_op.(znz_sqrt). + Definition w1_sqrt := w1_op.(znz_sqrt). + Definition w2_sqrt := w2_op.(znz_sqrt). + Definition w3_sqrt := w3_op.(znz_sqrt). + Definition w4_sqrt := w4_op.(znz_sqrt). + Definition w5_sqrt := w5_op.(znz_sqrt). + Definition w6_sqrt := w6_op.(znz_sqrt). + + Definition sqrt x := + match x with + | N0 wx => reduce_0 (w0_sqrt wx) + | N1 wx => reduce_1 (w1_sqrt wx) + | N2 wx => reduce_2 (w2_sqrt wx) + | N3 wx => reduce_3 (w3_sqrt wx) + | N4 wx => reduce_4 (w4_sqrt wx) + | N5 wx => reduce_5 (w5_sqrt wx) + | N6 wx => reduce_6 (w6_sqrt wx) + | Nn n wx => + let op := make_op n in + reduce_n n (op.(znz_sqrt) wx) + end. + + Theorem spec_sqrt: forall x, [sqrt x] ^ 2 <= [x] < ([sqrt x] + 1) ^ 2. + Proof. + intros x; unfold sqrt; case x; clear x. + intros x; rewrite spec_reduce_0; exact (spec_sqrt w0_spec x). + intros x; rewrite spec_reduce_1; exact (spec_sqrt w1_spec x). + intros x; rewrite spec_reduce_2; exact (spec_sqrt w2_spec x). + intros x; rewrite spec_reduce_3; exact (spec_sqrt w3_spec x). + intros x; rewrite spec_reduce_4; exact (spec_sqrt w4_spec x). + intros x; rewrite spec_reduce_5; exact (spec_sqrt w5_spec x). + intros x; rewrite spec_reduce_6; exact (spec_sqrt w6_spec x). + intros n x; rewrite spec_reduce_n; exact (spec_sqrt (wn_spec n) x). + Qed. + + (***************************************************************) + (* *) + (* Division *) + (* *) + (***************************************************************) + + Definition w0_div_gt := w0_op.(znz_div_gt). + Definition w1_div_gt := w1_op.(znz_div_gt). + Definition w2_div_gt := w2_op.(znz_div_gt). + Definition w3_div_gt := w3_op.(znz_div_gt). + Definition w4_div_gt := w4_op.(znz_div_gt). + Definition w5_div_gt := w5_op.(znz_div_gt). + Definition w6_div_gt := w6_op.(znz_div_gt). + + Let spec_divn1 ww (ww_op: znz_op ww) (ww_spec: znz_spec ww_op) := + (spec_gen_divn1 + ww_op.(znz_zdigits) ww_op.(znz_0) + ww_op.(znz_WW) ww_op.(znz_head0) + ww_op.(znz_add_mul_div) ww_op.(znz_div21) + ww_op.(znz_compare) ww_op.(znz_sub) (znz_to_Z ww_op) + (spec_to_Z ww_spec) + (spec_zdigits ww_spec) + (spec_0 ww_spec) (spec_WW ww_spec) (spec_head0 ww_spec) + (spec_add_mul_div ww_spec) (spec_div21 ww_spec) + (ZnZ.spec_compare ww_spec) (ZnZ.spec_sub ww_spec)). + + Definition w0_divn1 n x y := + let (u, v) := + gen_divn1 w0_op.(znz_zdigits) w0_op.(znz_0) + w0_op.(znz_WW) w0_op.(znz_head0) + w0_op.(znz_add_mul_div) w0_op.(znz_div21) + w0_op.(znz_compare) w0_op.(znz_sub) (S n) x y in + (to_Z0 _ u, N0 v). + Definition w1_divn1 n x y := + let (u, v) := + gen_divn1 w1_op.(znz_zdigits) w1_op.(znz_0) + w1_op.(znz_WW) w1_op.(znz_head0) + w1_op.(znz_add_mul_div) w1_op.(znz_div21) + w1_op.(znz_compare) w1_op.(znz_sub) (S n) x y in + (to_Z1 _ u, N1 v). + Definition w2_divn1 n x y := + let (u, v) := + gen_divn1 w2_op.(znz_zdigits) w2_op.(znz_0) + w2_op.(znz_WW) w2_op.(znz_head0) + w2_op.(znz_add_mul_div) w2_op.(znz_div21) + w2_op.(znz_compare) w2_op.(znz_sub) (S n) x y in + (to_Z2 _ u, N2 v). + Definition w3_divn1 n x y := + let (u, v) := + gen_divn1 w3_op.(znz_zdigits) w3_op.(znz_0) + w3_op.(znz_WW) w3_op.(znz_head0) + w3_op.(znz_add_mul_div) w3_op.(znz_div21) + w3_op.(znz_compare) w3_op.(znz_sub) (S n) x y in + (to_Z3 _ u, N3 v). + Definition w4_divn1 n x y := + let (u, v) := + gen_divn1 w4_op.(znz_zdigits) w4_op.(znz_0) + w4_op.(znz_WW) w4_op.(znz_head0) + w4_op.(znz_add_mul_div) w4_op.(znz_div21) + w4_op.(znz_compare) w4_op.(znz_sub) (S n) x y in + (to_Z4 _ u, N4 v). + Definition w5_divn1 n x y := + let (u, v) := + gen_divn1 w5_op.(znz_zdigits) w5_op.(znz_0) + w5_op.(znz_WW) w5_op.(znz_head0) + w5_op.(znz_add_mul_div) w5_op.(znz_div21) + w5_op.(znz_compare) w5_op.(znz_sub) (S n) x y in + (to_Z5 _ u, N5 v). + Definition w6_divn1 n x y := + let (u, v) := + gen_divn1 w6_op.(znz_zdigits) w6_op.(znz_0) + w6_op.(znz_WW) w6_op.(znz_head0) + w6_op.(znz_add_mul_div) w6_op.(znz_div21) + w6_op.(znz_compare) w6_op.(znz_sub) (S n) x y in + (Nn _ u, N6 v). + + Lemma spec_get_end0: forall n x y, + eval0n n x <= [N0 y] -> + [N0 (GenBase.get_low w_0 n x)] = eval0n n x. + Proof. + intros n x y H. + rewrite spec_gen_eval0n; unfold to_Z. + apply GenBase.spec_get_low. + exact (spec_0 w0_spec). + exact (spec_to_Z w0_spec). + apply Zle_lt_trans with [N0 y]; auto. + rewrite <- spec_gen_eval0n; auto. + unfold to_Z; case (spec_to_Z w0_spec y); auto. + Qed. + + Lemma spec_get_end1: forall n x y, + eval1n n x <= [N1 y] -> + [N1 (GenBase.get_low W0 n x)] = eval1n n x. + Proof. + intros n x y H. + rewrite spec_gen_eval1n; unfold to_Z. + apply GenBase.spec_get_low. + exact (spec_0 w1_spec). + exact (spec_to_Z w1_spec). + apply Zle_lt_trans with [N1 y]; auto. + rewrite <- spec_gen_eval1n; auto. + unfold to_Z; case (spec_to_Z w1_spec y); auto. + Qed. + + Lemma spec_get_end2: forall n x y, + eval2n n x <= [N2 y] -> + [N2 (GenBase.get_low W0 n x)] = eval2n n x. + Proof. + intros n x y H. + rewrite spec_gen_eval2n; unfold to_Z. + apply GenBase.spec_get_low. + exact (spec_0 w2_spec). + exact (spec_to_Z w2_spec). + apply Zle_lt_trans with [N2 y]; auto. + rewrite <- spec_gen_eval2n; auto. + unfold to_Z; case (spec_to_Z w2_spec y); auto. + Qed. + + Lemma spec_get_end3: forall n x y, + eval3n n x <= [N3 y] -> + [N3 (GenBase.get_low W0 n x)] = eval3n n x. + Proof. + intros n x y H. + rewrite spec_gen_eval3n; unfold to_Z. + apply GenBase.spec_get_low. + exact (spec_0 w3_spec). + exact (spec_to_Z w3_spec). + apply Zle_lt_trans with [N3 y]; auto. + rewrite <- spec_gen_eval3n; auto. + unfold to_Z; case (spec_to_Z w3_spec y); auto. + Qed. + + Lemma spec_get_end4: forall n x y, + eval4n n x <= [N4 y] -> + [N4 (GenBase.get_low W0 n x)] = eval4n n x. + Proof. + intros n x y H. + rewrite spec_gen_eval4n; unfold to_Z. + apply GenBase.spec_get_low. + exact (spec_0 w4_spec). + exact (spec_to_Z w4_spec). + apply Zle_lt_trans with [N4 y]; auto. + rewrite <- spec_gen_eval4n; auto. + unfold to_Z; case (spec_to_Z w4_spec y); auto. + Qed. + + Lemma spec_get_end5: forall n x y, + eval5n n x <= [N5 y] -> + [N5 (GenBase.get_low W0 n x)] = eval5n n x. + Proof. + intros n x y H. + rewrite spec_gen_eval5n; unfold to_Z. + apply GenBase.spec_get_low. + exact (spec_0 w5_spec). + exact (spec_to_Z w5_spec). + apply Zle_lt_trans with [N5 y]; auto. + rewrite <- spec_gen_eval5n; auto. + unfold to_Z; case (spec_to_Z w5_spec y); auto. + Qed. + + Lemma spec_get_end6: forall n x y, + eval6n n x <= [N6 y] -> + [N6 (GenBase.get_low W0 n x)] = eval6n n x. + Proof. + intros n x y H. + rewrite spec_gen_eval6n; unfold to_Z. + apply GenBase.spec_get_low. + exact (spec_0 w6_spec). + exact (spec_to_Z w6_spec). + apply Zle_lt_trans with [N6 y]; auto. + rewrite <- spec_gen_eval6n; auto. + unfold to_Z; case (spec_to_Z w6_spec y); auto. + Qed. + + Let div_gt0 x y := let (u,v) := (w0_div_gt x y) in (reduce_0 u, reduce_0 v). + Let div_gt1 x y := let (u,v) := (w1_div_gt x y) in (reduce_1 u, reduce_1 v). + Let div_gt2 x y := let (u,v) := (w2_div_gt x y) in (reduce_2 u, reduce_2 v). + Let div_gt3 x y := let (u,v) := (w3_div_gt x y) in (reduce_3 u, reduce_3 v). + Let div_gt4 x y := let (u,v) := (w4_div_gt x y) in (reduce_4 u, reduce_4 v). + Let div_gt5 x y := let (u,v) := (w5_div_gt x y) in (reduce_5 u, reduce_5 v). + Let div_gt6 x y := let (u,v) := (w6_div_gt x y) in (reduce_6 u, reduce_6 v). + + Let div_gtnm n m wx wy := + let mn := Max.max n m in + let d := diff n m in + let op := make_op mn in + let (q, r):= op.(znz_div_gt) + (castm (diff_r n m) (extend_tr wx (snd d))) + (castm (diff_l n m) (extend_tr wy (fst d))) in + (reduce_n mn q, reduce_n mn r). + + Definition div_gt := Eval lazy beta delta [iter] in + (iter _ + div_gt0 + (fun n x y => div_gt0 x (GenBase.get_low w_0 (S n) y)) + w0_divn1 + div_gt1 + (fun n x y => div_gt1 x (GenBase.get_low W0 (S n) y)) + w1_divn1 + div_gt2 + (fun n x y => div_gt2 x (GenBase.get_low W0 (S n) y)) + w2_divn1 + div_gt3 + (fun n x y => div_gt3 x (GenBase.get_low W0 (S n) y)) + w3_divn1 + div_gt4 + (fun n x y => div_gt4 x (GenBase.get_low W0 (S n) y)) + w4_divn1 + div_gt5 + (fun n x y => div_gt5 x (GenBase.get_low W0 (S n) y)) + w5_divn1 + div_gt6 + (fun n x y => div_gt6 x (GenBase.get_low W0 (S n) y)) + w6_divn1 + div_gtnm). + + Theorem spec_div_gt: forall x y, + [x] > [y] -> 0 < [y] -> + let (q,r) := div_gt x y in + [q] = [x] / [y] /\ [r] = [x] mod [y]. + Proof. + assert (FO: + forall x y, [x] > [y] -> 0 < [y] -> + let (q,r) := div_gt x y in + [x] = [q] * [y] + [r] /\ 0 <= [r] < [y]). + refine (spec_iter (t_*t_) (fun x y res => x > y -> 0 < y -> + let (q,r) := res in + x = [q] * y + [r] /\ 0 <= [r] < y) + div_gt0 + (fun n x y => div_gt0 x (GenBase.get_low w_0 (S n) y)) + w0_divn1 _ _ _ + div_gt1 + (fun n x y => div_gt1 x (GenBase.get_low W0 (S n) y)) + w1_divn1 _ _ _ + div_gt2 + (fun n x y => div_gt2 x (GenBase.get_low W0 (S n) y)) + w2_divn1 _ _ _ + div_gt3 + (fun n x y => div_gt3 x (GenBase.get_low W0 (S n) y)) + w3_divn1 _ _ _ + div_gt4 + (fun n x y => div_gt4 x (GenBase.get_low W0 (S n) y)) + w4_divn1 _ _ _ + div_gt5 + (fun n x y => div_gt5 x (GenBase.get_low W0 (S n) y)) + w5_divn1 _ _ _ + div_gt6 + (fun n x y => div_gt6 x (GenBase.get_low W0 (S n) y)) + w6_divn1 _ _ _ + div_gtnm _). + intros x y H1 H2; unfold div_gt0, w0_div_gt. + generalize (spec_div_gt w0_spec x y H1 H2); case znz_div_gt. + intros xx yy; repeat rewrite spec_reduce_0; auto. + intros n x y H1 H2 H3; unfold div_gt0, w0_div_gt. + generalize (spec_div_gt w0_spec x + (GenBase.get_low w_0 (S n) y)). + unfold w0;case znz_div_gt. + intros xx yy H4; repeat rewrite spec_reduce_0. + generalize (spec_get_end0 (S n) y x); unfold to_Z; intros H5. + unfold to_Z in H2; rewrite H5 in H4; auto with zarith. + intros n x y H1 H2 H3. + generalize + (spec_divn1 w0 w0_op w0_spec (S n) x y H3). + unfold w0_divn1;unfold w0; case gen_divn1. + intros xx yy H4. + rewrite to_Z0_spec; auto with zarith. + repeat rewrite <- spec_gen_eval0n in H4; auto. + intros x y H1 H2; unfold div_gt1, w1_div_gt. + generalize (spec_div_gt w1_spec x y H1 H2); case znz_div_gt. + intros xx yy; repeat rewrite spec_reduce_1; auto. + intros n x y H1 H2 H3; unfold div_gt1, w1_div_gt. + generalize (spec_div_gt w1_spec x + (GenBase.get_low W0 (S n) y)). + unfold w1;unfold w0;case znz_div_gt. + intros xx yy H4; repeat rewrite spec_reduce_1. + generalize (spec_get_end1 (S n) y x); unfold to_Z; intros H5. + unfold to_Z in H2; rewrite H5 in H4; auto with zarith. + intros n x y H1 H2 H3. + generalize + (spec_divn1 w1 w1_op w1_spec (S n) x y H3). + unfold w1_divn1;unfold w1;unfold w0; case gen_divn1. + intros xx yy H4. + rewrite to_Z1_spec; auto with zarith. + repeat rewrite <- spec_gen_eval1n in H4; auto. + intros x y H1 H2; unfold div_gt2, w2_div_gt. + generalize (spec_div_gt w2_spec x y H1 H2); case znz_div_gt. + intros xx yy; repeat rewrite spec_reduce_2; auto. + intros n x y H1 H2 H3; unfold div_gt2, w2_div_gt. + generalize (spec_div_gt w2_spec x + (GenBase.get_low W0 (S n) y)). + unfold w2;unfold w1;unfold w0;case znz_div_gt. + intros xx yy H4; repeat rewrite spec_reduce_2. + generalize (spec_get_end2 (S n) y x); unfold to_Z; intros H5. + unfold to_Z in H2; rewrite H5 in H4; auto with zarith. + intros n x y H1 H2 H3. + generalize + (spec_divn1 w2 w2_op w2_spec (S n) x y H3). + unfold w2_divn1;unfold w2;unfold w1;unfold w0; case gen_divn1. + intros xx yy H4. + rewrite to_Z2_spec; auto with zarith. + repeat rewrite <- spec_gen_eval2n in H4; auto. + intros x y H1 H2; unfold div_gt3, w3_div_gt. + generalize (spec_div_gt w3_spec x y H1 H2); case znz_div_gt. + intros xx yy; repeat rewrite spec_reduce_3; auto. + intros n x y H1 H2 H3; unfold div_gt3, w3_div_gt. + generalize (spec_div_gt w3_spec x + (GenBase.get_low W0 (S n) y)). + unfold w3;unfold w2;unfold w1;unfold w0;case znz_div_gt. + intros xx yy H4; repeat rewrite spec_reduce_3. + generalize (spec_get_end3 (S n) y x); unfold to_Z; intros H5. + unfold to_Z in H2; rewrite H5 in H4; auto with zarith. + intros n x y H1 H2 H3. + generalize + (spec_divn1 w3 w3_op w3_spec (S n) x y H3). + unfold w3_divn1;unfold w3;unfold w2;unfold w1;unfold w0; case gen_divn1. + intros xx yy H4. + rewrite to_Z3_spec; auto with zarith. + repeat rewrite <- spec_gen_eval3n in H4; auto. + intros x y H1 H2; unfold div_gt4, w4_div_gt. + generalize (spec_div_gt w4_spec x y H1 H2); case znz_div_gt. + intros xx yy; repeat rewrite spec_reduce_4; auto. + intros n x y H1 H2 H3; unfold div_gt4, w4_div_gt. + generalize (spec_div_gt w4_spec x + (GenBase.get_low W0 (S n) y)). + unfold w4;unfold w3;unfold w2;unfold w1;unfold w0;case znz_div_gt. + intros xx yy H4; repeat rewrite spec_reduce_4. + generalize (spec_get_end4 (S n) y x); unfold to_Z; intros H5. + unfold to_Z in H2; rewrite H5 in H4; auto with zarith. + intros n x y H1 H2 H3. + generalize + (spec_divn1 w4 w4_op w4_spec (S n) x y H3). + unfold w4_divn1;unfold w4;unfold w3;unfold w2;unfold w1;unfold w0; case gen_divn1. + intros xx yy H4. + rewrite to_Z4_spec; auto with zarith. + repeat rewrite <- spec_gen_eval4n in H4; auto. + intros x y H1 H2; unfold div_gt5, w5_div_gt. + generalize (spec_div_gt w5_spec x y H1 H2); case znz_div_gt. + intros xx yy; repeat rewrite spec_reduce_5; auto. + intros n x y H1 H2 H3; unfold div_gt5, w5_div_gt. + generalize (spec_div_gt w5_spec x + (GenBase.get_low W0 (S n) y)). + unfold w5;unfold w4;unfold w3;unfold w2;unfold w1;unfold w0;case znz_div_gt. + intros xx yy H4; repeat rewrite spec_reduce_5. + generalize (spec_get_end5 (S n) y x); unfold to_Z; intros H5. + unfold to_Z in H2; rewrite H5 in H4; auto with zarith. + intros n x y H1 H2 H3. + generalize + (spec_divn1 w5 w5_op w5_spec (S n) x y H3). + unfold w5_divn1;unfold w5;unfold w4;unfold w3;unfold w2;unfold w1;unfold w0; case gen_divn1. + intros xx yy H4. + rewrite to_Z5_spec; auto with zarith. + repeat rewrite <- spec_gen_eval5n in H4; auto. + intros x y H1 H2; unfold div_gt6, w6_div_gt. + generalize (spec_div_gt w6_spec x y H1 H2); case znz_div_gt. + intros xx yy; repeat rewrite spec_reduce_6; auto. + intros n x y H2 H3; unfold div_gt6, w6_div_gt. + generalize (spec_div_gt w6_spec x + (GenBase.get_low W0 (S n) y)). + unfold w6;unfold w5;unfold w4;unfold w3;unfold w2;unfold w1;unfold w0;case znz_div_gt. + intros xx yy H4; repeat rewrite spec_reduce_6. + generalize (spec_get_end6 (S n) y x); unfold to_Z; intros H5. + unfold to_Z in H2; rewrite H5 in H4; auto with zarith. + intros n x y H2 H3. + generalize + (spec_divn1 w6 w6_op w6_spec (S n) x y H3). + unfold w6_divn1;unfold w6;unfold w5;unfold w4;unfold w3;unfold w2;unfold w1;unfold w0; case gen_divn1. + intros xx yy H4. + repeat rewrite <- spec_gen_eval6n in H4; auto. + rewrite spec_eval6n; auto. + intros n m x y H1 H2; unfold div_gtnm. + generalize (spec_div_gt (wn_spec (Max.max n m)) + (castm (diff_r n m) + (extend_tr x (snd (diff n m)))) + (castm (diff_l n m) + (extend_tr y (fst (diff n m))))). + case znz_div_gt. + intros xx yy HH. + repeat rewrite spec_reduce_n. + rewrite <- (spec_cast_l n m x). + rewrite <- (spec_cast_r n m y). + unfold to_Z; apply HH. + rewrite <- (spec_cast_l n m x) in H1; auto. + rewrite <- (spec_cast_r n m y) in H1; auto. + rewrite <- (spec_cast_r n m y) in H2; auto. + intros x y H1 H2; generalize (FO x y H1 H2); case div_gt. + intros q r (H3, H4); split. + apply (Zdiv_unique [x] [y] [q] [r]); auto. + rewrite Zmult_comm; auto. + apply (Zmod_unique [x] [y] [q] [r]); auto. + rewrite Zmult_comm; auto. + Qed. + + Definition div_eucl x y := + match compare x y with + | Eq => (one, zero) + | Lt => (zero, x) + | Gt => div_gt x y + end. + + Theorem spec_div_eucl: forall x y, + 0 < [y] -> + let (q,r) := div_eucl x y in + ([q], [r]) = Zdiv_eucl [x] [y]. + Proof. + assert (F0: [zero] = 0). + exact (spec_0 w0_spec). + assert (F1: [one] = 1). + exact (spec_1 w0_spec). + intros x y H; generalize (spec_compare x y); + unfold div_eucl; case compare; try rewrite F0; + try rewrite F1; intros; auto with zarith. + rewrite H0; generalize (Z_div_same [y] (Zlt_gt _ _ H)) + (Z_mod_same [y] (Zlt_gt _ _ H)); + unfold Zdiv, Zmod; case Zdiv_eucl; intros; subst; auto. + assert (F2: 0 <= [x] < [y]). + generalize (spec_pos x); auto. + generalize (Zdiv_small _ _ F2) + (Zmod_small _ _ F2); + unfold Zdiv, Zmod; case Zdiv_eucl; intros; subst; auto. + generalize (spec_div_gt _ _ H0 H); auto. + unfold Zdiv, Zmod; case Zdiv_eucl; case div_gt. + intros a b c d (H1, H2); subst; auto. + Qed. + + Definition div x y := fst (div_eucl x y). + + Theorem spec_div: + forall x y, 0 < [y] -> [div x y] = [x] / [y]. + Proof. + intros x y H1; unfold div; generalize (spec_div_eucl x y H1); + case div_eucl; simpl fst. + intros xx yy; unfold Zdiv; case Zdiv_eucl; intros qq rr H; + injection H; auto. + Qed. + + (***************************************************************) + (* *) + (* Modulo *) + (* *) + (***************************************************************) + + Definition w0_mod_gt := w0_op.(znz_mod_gt). + Definition w1_mod_gt := w1_op.(znz_mod_gt). + Definition w2_mod_gt := w2_op.(znz_mod_gt). + Definition w3_mod_gt := w3_op.(znz_mod_gt). + Definition w4_mod_gt := w4_op.(znz_mod_gt). + Definition w5_mod_gt := w5_op.(znz_mod_gt). + Definition w6_mod_gt := w6_op.(znz_mod_gt). + + Definition w0_modn1 := + gen_modn1 w0_op.(znz_zdigits) w0_op.(znz_0) + w0_op.(znz_head0) w0_op.(znz_add_mul_div) w0_op.(znz_div21) + w0_op.(znz_compare) w0_op.(znz_sub). + Definition w1_modn1 := + gen_modn1 w1_op.(znz_zdigits) w1_op.(znz_0) + w1_op.(znz_head0) w1_op.(znz_add_mul_div) w1_op.(znz_div21) + w1_op.(znz_compare) w1_op.(znz_sub). + Definition w2_modn1 := + gen_modn1 w2_op.(znz_zdigits) w2_op.(znz_0) + w2_op.(znz_head0) w2_op.(znz_add_mul_div) w2_op.(znz_div21) + w2_op.(znz_compare) w2_op.(znz_sub). + Definition w3_modn1 := + gen_modn1 w3_op.(znz_zdigits) w3_op.(znz_0) + w3_op.(znz_head0) w3_op.(znz_add_mul_div) w3_op.(znz_div21) + w3_op.(znz_compare) w3_op.(znz_sub). + Definition w4_modn1 := + gen_modn1 w4_op.(znz_zdigits) w4_op.(znz_0) + w4_op.(znz_head0) w4_op.(znz_add_mul_div) w4_op.(znz_div21) + w4_op.(znz_compare) w4_op.(znz_sub). + Definition w5_modn1 := + gen_modn1 w5_op.(znz_zdigits) w5_op.(znz_0) + w5_op.(znz_head0) w5_op.(znz_add_mul_div) w5_op.(znz_div21) + w5_op.(znz_compare) w5_op.(znz_sub). + Definition w6_modn1 := + gen_modn1 w6_op.(znz_zdigits) w6_op.(znz_0) + w6_op.(znz_head0) w6_op.(znz_add_mul_div) w6_op.(znz_div21) + w6_op.(znz_compare) w6_op.(znz_sub). + + Let mod_gtnm n m wx wy := + let mn := Max.max n m in + let d := diff n m in + let op := make_op mn in + reduce_n mn (op.(znz_mod_gt) + (castm (diff_r n m) (extend_tr wx (snd d))) + (castm (diff_l n m) (extend_tr wy (fst d)))). + + Definition mod_gt := Eval lazy beta delta[iter] in + (iter _ + (fun x y => reduce_0 (w0_mod_gt x y)) + (fun n x y => reduce_0 (w0_mod_gt x (GenBase.get_low w_0 (S n) y))) + (fun n x y => reduce_0 (w0_modn1 (S n) x y)) + (fun x y => reduce_1 (w1_mod_gt x y)) + (fun n x y => reduce_1 (w1_mod_gt x (GenBase.get_low W0 (S n) y))) + (fun n x y => reduce_1 (w1_modn1 (S n) x y)) + (fun x y => reduce_2 (w2_mod_gt x y)) + (fun n x y => reduce_2 (w2_mod_gt x (GenBase.get_low W0 (S n) y))) + (fun n x y => reduce_2 (w2_modn1 (S n) x y)) + (fun x y => reduce_3 (w3_mod_gt x y)) + (fun n x y => reduce_3 (w3_mod_gt x (GenBase.get_low W0 (S n) y))) + (fun n x y => reduce_3 (w3_modn1 (S n) x y)) + (fun x y => reduce_4 (w4_mod_gt x y)) + (fun n x y => reduce_4 (w4_mod_gt x (GenBase.get_low W0 (S n) y))) + (fun n x y => reduce_4 (w4_modn1 (S n) x y)) + (fun x y => reduce_5 (w5_mod_gt x y)) + (fun n x y => reduce_5 (w5_mod_gt x (GenBase.get_low W0 (S n) y))) + (fun n x y => reduce_5 (w5_modn1 (S n) x y)) + (fun x y => reduce_6 (w6_mod_gt x y)) + (fun n x y => reduce_6 (w6_mod_gt x (GenBase.get_low W0 (S n) y))) + (fun n x y => reduce_6 (w6_modn1 (S n) x y)) + mod_gtnm). + + Let spec_modn1 ww (ww_op: znz_op ww) (ww_spec: znz_spec ww_op) := + (spec_gen_modn1 + ww_op.(znz_zdigits) ww_op.(znz_0) + ww_op.(znz_WW) ww_op.(znz_head0) + ww_op.(znz_add_mul_div) ww_op.(znz_div21) + ww_op.(znz_compare) ww_op.(znz_sub) (znz_to_Z ww_op) + (spec_to_Z ww_spec) + (spec_zdigits ww_spec) + (spec_0 ww_spec) (spec_WW ww_spec) (spec_head0 ww_spec) + (spec_add_mul_div ww_spec) (spec_div21 ww_spec) + (ZnZ.spec_compare ww_spec) (ZnZ.spec_sub ww_spec)). + + Theorem spec_mod_gt: + forall x y, [x] > [y] -> 0 < [y] -> [mod_gt x y] = [x] mod [y]. + Proof. + refine (spec_iter _ (fun x y res => x > y -> 0 < y -> + [res] = x mod y) + (fun x y => reduce_0 (w0_mod_gt x y)) + (fun n x y => reduce_0 (w0_mod_gt x (GenBase.get_low w_0 (S n) y))) + (fun n x y => reduce_0 (w0_modn1 (S n) x y)) _ _ _ + (fun x y => reduce_1 (w1_mod_gt x y)) + (fun n x y => reduce_1 (w1_mod_gt x (GenBase.get_low W0 (S n) y))) + (fun n x y => reduce_1 (w1_modn1 (S n) x y)) _ _ _ + (fun x y => reduce_2 (w2_mod_gt x y)) + (fun n x y => reduce_2 (w2_mod_gt x (GenBase.get_low W0 (S n) y))) + (fun n x y => reduce_2 (w2_modn1 (S n) x y)) _ _ _ + (fun x y => reduce_3 (w3_mod_gt x y)) + (fun n x y => reduce_3 (w3_mod_gt x (GenBase.get_low W0 (S n) y))) + (fun n x y => reduce_3 (w3_modn1 (S n) x y)) _ _ _ + (fun x y => reduce_4 (w4_mod_gt x y)) + (fun n x y => reduce_4 (w4_mod_gt x (GenBase.get_low W0 (S n) y))) + (fun n x y => reduce_4 (w4_modn1 (S n) x y)) _ _ _ + (fun x y => reduce_5 (w5_mod_gt x y)) + (fun n x y => reduce_5 (w5_mod_gt x (GenBase.get_low W0 (S n) y))) + (fun n x y => reduce_5 (w5_modn1 (S n) x y)) _ _ _ + (fun x y => reduce_6 (w6_mod_gt x y)) + (fun n x y => reduce_6 (w6_mod_gt x (GenBase.get_low W0 (S n) y))) + (fun n x y => reduce_6 (w6_modn1 (S n) x y)) _ _ _ + mod_gtnm _). + intros x y H1 H2; rewrite spec_reduce_0. + exact (spec_mod_gt w0_spec x y H1 H2). + intros n x y H1 H2 H3; rewrite spec_reduce_0. + unfold w0_mod_gt. + rewrite <- (spec_get_end0 (S n) y x); auto with zarith. + unfold to_Z; apply (spec_mod_gt w0_spec); auto. + rewrite <- (spec_get_end0 (S n) y x) in H2; auto with zarith. + rewrite <- (spec_get_end0 (S n) y x) in H3; auto with zarith. + intros n x y H1 H2 H3; rewrite spec_reduce_0. + unfold w0_modn1, to_Z; rewrite spec_gen_eval0n. + apply (spec_modn1 _ _ w0_spec); auto. + intros x y H1 H2; rewrite spec_reduce_1. + exact (spec_mod_gt w1_spec x y H1 H2). + intros n x y H1 H2 H3; rewrite spec_reduce_1. + unfold w1_mod_gt. + rewrite <- (spec_get_end1 (S n) y x); auto with zarith. + unfold to_Z; apply (spec_mod_gt w1_spec); auto. + rewrite <- (spec_get_end1 (S n) y x) in H2; auto with zarith. + rewrite <- (spec_get_end1 (S n) y x) in H3; auto with zarith. + intros n x y H1 H2 H3; rewrite spec_reduce_1. + unfold w1_modn1, to_Z; rewrite spec_gen_eval1n. + apply (spec_modn1 _ _ w1_spec); auto. + intros x y H1 H2; rewrite spec_reduce_2. + exact (spec_mod_gt w2_spec x y H1 H2). + intros n x y H1 H2 H3; rewrite spec_reduce_2. + unfold w2_mod_gt. + rewrite <- (spec_get_end2 (S n) y x); auto with zarith. + unfold to_Z; apply (spec_mod_gt w2_spec); auto. + rewrite <- (spec_get_end2 (S n) y x) in H2; auto with zarith. + rewrite <- (spec_get_end2 (S n) y x) in H3; auto with zarith. + intros n x y H1 H2 H3; rewrite spec_reduce_2. + unfold w2_modn1, to_Z; rewrite spec_gen_eval2n. + apply (spec_modn1 _ _ w2_spec); auto. + intros x y H1 H2; rewrite spec_reduce_3. + exact (spec_mod_gt w3_spec x y H1 H2). + intros n x y H1 H2 H3; rewrite spec_reduce_3. + unfold w3_mod_gt. + rewrite <- (spec_get_end3 (S n) y x); auto with zarith. + unfold to_Z; apply (spec_mod_gt w3_spec); auto. + rewrite <- (spec_get_end3 (S n) y x) in H2; auto with zarith. + rewrite <- (spec_get_end3 (S n) y x) in H3; auto with zarith. + intros n x y H1 H2 H3; rewrite spec_reduce_3. + unfold w3_modn1, to_Z; rewrite spec_gen_eval3n. + apply (spec_modn1 _ _ w3_spec); auto. + intros x y H1 H2; rewrite spec_reduce_4. + exact (spec_mod_gt w4_spec x y H1 H2). + intros n x y H1 H2 H3; rewrite spec_reduce_4. + unfold w4_mod_gt. + rewrite <- (spec_get_end4 (S n) y x); auto with zarith. + unfold to_Z; apply (spec_mod_gt w4_spec); auto. + rewrite <- (spec_get_end4 (S n) y x) in H2; auto with zarith. + rewrite <- (spec_get_end4 (S n) y x) in H3; auto with zarith. + intros n x y H1 H2 H3; rewrite spec_reduce_4. + unfold w4_modn1, to_Z; rewrite spec_gen_eval4n. + apply (spec_modn1 _ _ w4_spec); auto. + intros x y H1 H2; rewrite spec_reduce_5. + exact (spec_mod_gt w5_spec x y H1 H2). + intros n x y H1 H2 H3; rewrite spec_reduce_5. + unfold w5_mod_gt. + rewrite <- (spec_get_end5 (S n) y x); auto with zarith. + unfold to_Z; apply (spec_mod_gt w5_spec); auto. + rewrite <- (spec_get_end5 (S n) y x) in H2; auto with zarith. + rewrite <- (spec_get_end5 (S n) y x) in H3; auto with zarith. + intros n x y H1 H2 H3; rewrite spec_reduce_5. + unfold w5_modn1, to_Z; rewrite spec_gen_eval5n. + apply (spec_modn1 _ _ w5_spec); auto. + intros x y H1 H2; rewrite spec_reduce_6. + exact (spec_mod_gt w6_spec x y H1 H2). + intros n x y H2 H3; rewrite spec_reduce_6. + unfold w6_mod_gt. + rewrite <- (spec_get_end6 (S n) y x); auto with zarith. + unfold to_Z; apply (spec_mod_gt w6_spec); auto. + rewrite <- (spec_get_end6 (S n) y x) in H2; auto with zarith. + rewrite <- (spec_get_end6 (S n) y x) in H3; auto with zarith. + intros n x y H2 H3; rewrite spec_reduce_6. + unfold w6_modn1, to_Z; rewrite spec_gen_eval6n. + apply (spec_modn1 _ _ w6_spec); auto. + intros n m x y H1 H2; unfold mod_gtnm. + repeat rewrite spec_reduce_n. + rewrite <- (spec_cast_l n m x). + rewrite <- (spec_cast_r n m y). + unfold to_Z; apply (spec_mod_gt (wn_spec (Max.max n m))). + rewrite <- (spec_cast_l n m x) in H1; auto. + rewrite <- (spec_cast_r n m y) in H1; auto. + rewrite <- (spec_cast_r n m y) in H2; auto. + Qed. + + Definition modulo x y := + match compare x y with + | Eq => zero + | Lt => x + | Gt => mod_gt x y + end. + + Theorem spec_modulo: + forall x y, 0 < [y] -> [modulo x y] = [x] mod [y]. + Proof. + assert (F0: [zero] = 0). + exact (spec_0 w0_spec). + assert (F1: [one] = 1). + exact (spec_1 w0_spec). + intros x y H; generalize (spec_compare x y); + unfold modulo; case compare; try rewrite F0; + try rewrite F1; intros; try split; auto with zarith. + rewrite H0; apply sym_equal; apply Z_mod_same; auto with zarith. + apply sym_equal; apply Zmod_small; auto with zarith. + generalize (spec_pos x); auto with zarith. + apply spec_mod_gt; auto. + Qed. + + (***************************************************************) + (* *) + (* Gcd *) + (* *) + (***************************************************************) + + Definition digits x := + match x with + | N0 _ => w0_op.(znz_digits) + | N1 _ => w1_op.(znz_digits) + | N2 _ => w2_op.(znz_digits) + | N3 _ => w3_op.(znz_digits) + | N4 _ => w4_op.(znz_digits) + | N5 _ => w5_op.(znz_digits) + | N6 _ => w6_op.(znz_digits) + | Nn n _ => (make_op n).(znz_digits) + end. + + Theorem spec_digits: forall x, 0 <= [x] < 2 ^ Zpos (digits x). + Proof. + intros x; case x; clear x. + intros x; unfold to_Z, digits; + generalize (spec_to_Z w0_spec x); unfold base; intros H; exact H. + intros x; unfold to_Z, digits; + generalize (spec_to_Z w1_spec x); unfold base; intros H; exact H. + intros x; unfold to_Z, digits; + generalize (spec_to_Z w2_spec x); unfold base; intros H; exact H. + intros x; unfold to_Z, digits; + generalize (spec_to_Z w3_spec x); unfold base; intros H; exact H. + intros x; unfold to_Z, digits; + generalize (spec_to_Z w4_spec x); unfold base; intros H; exact H. + intros x; unfold to_Z, digits; + generalize (spec_to_Z w5_spec x); unfold base; intros H; exact H. + intros x; unfold to_Z, digits; + generalize (spec_to_Z w6_spec x); unfold base; intros H; exact H. + intros n x; unfold to_Z, digits; + generalize (spec_to_Z (wn_spec n) x); unfold base; intros H; exact H. + Qed. + + Definition gcd_gt_body a b cont := + match compare b zero with + | Gt => + let r := mod_gt a b in + match compare r zero with + | Gt => cont r (mod_gt b r) + | _ => b + end + | _ => a + end. + + Theorem Zspec_gcd_gt_body: forall a b cont p, + [a] > [b] -> [a] < 2 ^ p -> + (forall a1 b1, [a1] < 2 ^ (p - 1) -> [a1] > [b1] -> + Zis_gcd [a1] [b1] [cont a1 b1]) -> + Zis_gcd [a] [b] [gcd_gt_body a b cont]. + Proof. + assert (F1: [zero] = 0). + unfold zero, w_0, to_Z; rewrite (spec_0 w0_spec); auto. + intros a b cont p H2 H3 H4; unfold gcd_gt_body. + generalize (spec_compare b zero); case compare; try rewrite F1. + intros HH; rewrite HH; apply Zis_gcd_0. + intros HH; absurd (0 <= [b]); auto with zarith. + case (spec_digits b); auto with zarith. + intros H5; generalize (spec_compare (mod_gt a b) zero); + case compare; try rewrite F1. + intros H6; rewrite <- (Zmult_1_r [b]). + rewrite (Z_div_mod_eq [a] [b]); auto with zarith. + rewrite <- spec_mod_gt; auto with zarith. + rewrite H6; rewrite Zplus_0_r. + apply Zis_gcd_mult; apply Zis_gcd_1. + intros; apply False_ind. + case (spec_digits (mod_gt a b)); auto with zarith. + intros H6; apply GenDiv.Zis_gcd_mod; auto with zarith. + apply GenDiv.Zis_gcd_mod; auto with zarith. + rewrite <- spec_mod_gt; auto with zarith. + assert (F2: [b] > [mod_gt a b]). + case (Z_mod_lt [a] [b]); auto with zarith. + repeat rewrite <- spec_mod_gt; auto with zarith. + assert (F3: [mod_gt a b] > [mod_gt b (mod_gt a b)]). + case (Z_mod_lt [b] [mod_gt a b]); auto with zarith. + rewrite <- spec_mod_gt; auto with zarith. + repeat rewrite <- spec_mod_gt; auto with zarith. + apply H4; auto with zarith. + apply Zmult_lt_reg_r with 2; auto with zarith. + apply Zle_lt_trans with ([b] + [mod_gt a b]); auto with zarith. + apply Zle_lt_trans with (([a]/[b]) * [b] + [mod_gt a b]); auto with zarith. + apply Zplus_le_compat_r. + pattern [b] at 1; rewrite <- (Zmult_1_l [b]). + apply Zmult_le_compat_r; auto with zarith. + case (Zle_lt_or_eq 0 ([a]/[b])); auto with zarith. + intros HH; rewrite (Z_div_mod_eq [a] [b]) in H2; + try rewrite <- HH in H2; auto with zarith. + case (Z_mod_lt [a] [b]); auto with zarith. + rewrite Zmult_comm; rewrite spec_mod_gt; auto with zarith. + rewrite <- Z_div_mod_eq; auto with zarith. + pattern 2 at 2; rewrite <- (Zpower_1_r 2). + rewrite <- Zpower_exp; auto with zarith. + ring_simplify (p - 1 + 1); auto. + case (Zle_lt_or_eq 0 p); auto with zarith. + generalize H3; case p; simpl Zpower; auto with zarith. + intros HH; generalize H3; rewrite <- HH; simpl Zpower; auto with zarith. + Qed. + + Fixpoint gcd_gt_aux (p:positive) (cont:t->t->t) (a b:t) {struct p} : t := + gcd_gt_body a b + (fun a b => + match p with + | xH => cont a b + | xO p => gcd_gt_aux p (gcd_gt_aux p cont) a b + | xI p => gcd_gt_aux p (gcd_gt_aux p cont) a b + end). + + Theorem Zspec_gcd_gt_aux: forall p n a b cont, + [a] > [b] -> [a] < 2 ^ (Zpos p + n) -> + (forall a1 b1, [a1] < 2 ^ n -> [a1] > [b1] -> + Zis_gcd [a1] [b1] [cont a1 b1]) -> + Zis_gcd [a] [b] [gcd_gt_aux p cont a b]. + intros p; elim p; clear p. + intros p Hrec n a b cont H2 H3 H4. + unfold gcd_gt_aux; apply Zspec_gcd_gt_body with (Zpos (xI p) + n); auto. + intros a1 b1 H6 H7. + apply Hrec with (Zpos p + n); auto. + replace (Zpos p + (Zpos p + n)) with + (Zpos (xI p) + n - 1); auto. + rewrite Zpos_xI; ring. + intros a2 b2 H9 H10. + apply Hrec with n; auto. + intros p Hrec n a b cont H2 H3 H4. + unfold gcd_gt_aux; apply Zspec_gcd_gt_body with (Zpos (xO p) + n); auto. + intros a1 b1 H6 H7. + apply Hrec with (Zpos p + n - 1); auto. + replace (Zpos p + (Zpos p + n - 1)) with + (Zpos (xO p) + n - 1); auto. + rewrite Zpos_xO; ring. + intros a2 b2 H9 H10. + apply Hrec with (n - 1); auto. + replace (Zpos p + (n - 1)) with + (Zpos p + n - 1); auto with zarith. + intros a3 b3 H12 H13; apply H4; auto with zarith. + apply Zlt_le_trans with (1 := H12). + case (Zle_or_lt 1 n); intros HH. + apply Zpower_le_monotone; auto with zarith. + apply Zle_trans with 0; auto with zarith. + assert (HH1: n - 1 < 0); auto with zarith. + generalize HH1; case (n - 1); auto with zarith. + intros p1 HH2; discriminate. + intros n a b cont H H2 H3. + simpl gcd_gt_aux. + apply Zspec_gcd_gt_body with (n + 1); auto with zarith. + rewrite Zplus_comm; auto. + intros a1 b1 H5 H6; apply H3; auto. + replace n with (n + 1 - 1); auto; try ring. + Qed. + + Definition gcd_cont a b := + match compare one b with + | Eq => one + | _ => a + end. + + Definition gcd_gt a b := gcd_gt_aux (digits a) gcd_cont a b. + + Theorem spec_gcd_gt: forall a b, + [a] > [b] -> [gcd_gt a b] = Zgcd [a] [b]. + Proof. + intros a b H2. + case (spec_digits (gcd_gt a b)); intros H3 H4. + case (spec_digits a); intros H5 H6. + apply sym_equal; apply Zis_gcd_gcd; auto with zarith. + unfold gcd_gt; apply Zspec_gcd_gt_aux with 0; auto with zarith. + intros a1 a2; rewrite Zpower_0_r. + case (spec_digits a2); intros H7 H8; + intros; apply False_ind; auto with zarith. + Qed. + + Definition gcd a b := + match compare a b with + | Eq => a + | Lt => gcd_gt b a + | Gt => gcd_gt a b + end. + + Theorem spec_gcd: forall a b, [gcd a b] = Zgcd [a] [b]. + Proof. + intros a b. + case (spec_digits a); intros H1 H2. + case (spec_digits b); intros H3 H4. + unfold gcd; generalize (spec_compare a b); case compare. + intros HH; rewrite HH; apply sym_equal; apply Zis_gcd_gcd; auto. + apply Zis_gcd_refl. + intros; apply trans_equal with (Zgcd [b] [a]). + apply spec_gcd_gt; auto with zarith. + apply Zis_gcd_gcd; auto with zarith. + apply Zgcd_is_pos. + apply Zis_gcd_sym; apply Zgcd_is_gcd. + intros; apply spec_gcd_gt; auto. + Qed. + + (***************************************************************) + (* *) + (* Conversion *) + (* *) + (***************************************************************) + + Definition pheight p := + Peano.pred (nat_of_P (get_height w0_op.(znz_digits) (plength p))). + + Theorem pheight_correct: forall p, + Zpos p < 2 ^ (Zpos (znz_digits w0_op) * 2 ^ (Z_of_nat (pheight p))). + Proof. + intros p; unfold pheight. + assert (F1: forall x, Z_of_nat (Peano.pred (nat_of_P x)) = Zpos x - 1). + intros x. + assert (Zsucc (Z_of_nat (Peano.pred (nat_of_P x))) = Zpos x); auto with zarith. + rewrite <- inj_S. + rewrite <- (fun x => S_pred x 0); auto with zarith. + rewrite Zpos_eq_Z_of_nat_o_nat_of_P; auto. + apply lt_le_trans with 1%nat; auto with zarith. + exact (le_Pmult_nat x 1). + rewrite F1; clear F1. + assert (F2:= (get_height_correct (znz_digits w0_op) (plength p))). + apply Zlt_le_trans with (Zpos (Psucc p)). + rewrite Zpos_succ_morphism; auto with zarith. + apply Zle_trans with (1 := plength_pred_correct (Psucc p)). + rewrite Ppred_succ. + apply Zpower_le_monotone; auto with zarith. + Qed. + + Definition of_pos x := + let h := pheight x in + match h with + | 0%nat => reduce_0 (snd (w0_op.(znz_of_pos) x)) + | 1%nat => reduce_1 (snd (w1_op.(znz_of_pos) x)) + | 2%nat => reduce_2 (snd (w2_op.(znz_of_pos) x)) + | 3%nat => reduce_3 (snd (w3_op.(znz_of_pos) x)) + | 4%nat => reduce_4 (snd (w4_op.(znz_of_pos) x)) + | 5%nat => reduce_5 (snd (w5_op.(znz_of_pos) x)) + | 6%nat => reduce_6 (snd (w6_op.(znz_of_pos) x)) + | _ => + let n := minus h 7 in + reduce_n n (snd ((make_op n).(znz_of_pos) x)) + end. + + Theorem spec_of_pos: forall x, + [of_pos x] = Zpos x. + Proof. + assert (F := spec_more_than_1_digit w0_spec). + intros x; unfold of_pos; case_eq (pheight x). + intros H1; rewrite spec_reduce_0; unfold to_Z. + apply (znz_of_pos_correct w0_spec). + apply Zlt_le_trans with (1 := pheight_correct x). + rewrite H1; simpl Z_of_nat; change (2^0) with (1). + unfold base. + apply Zpower_le_monotone; split; auto with zarith. + intros n; case n; clear n. + intros H1; rewrite spec_reduce_1; unfold to_Z. + apply (znz_of_pos_correct w1_spec). + apply Zlt_le_trans with (1 := pheight_correct x). + rewrite H1; simpl Z_of_nat; change (2^1) with (2). + unfold base. + apply Zpower_le_monotone; split; auto with zarith. + apply Zeq_le; apply Zmult_comm. + intros n; case n; clear n. + intros H1; rewrite spec_reduce_2; unfold to_Z. + apply (znz_of_pos_correct w2_spec). + apply Zlt_le_trans with (1 := pheight_correct x). + rewrite H1; simpl Z_of_nat; change (2^2) with (2 * 2). + unfold base. + apply Zpower_le_monotone; split; auto with zarith. + apply Zeq_le; apply Zmult_comm. + intros n; case n; clear n. + intros H1; rewrite spec_reduce_3; unfold to_Z. + apply (znz_of_pos_correct w3_spec). + apply Zlt_le_trans with (1 := pheight_correct x). + rewrite H1; simpl Z_of_nat; change (2^3) with (2 * 2 * 2). + unfold base. + apply Zpower_le_monotone; split; auto with zarith. + apply Zeq_le; apply Zmult_comm. + intros n; case n; clear n. + intros H1; rewrite spec_reduce_4; unfold to_Z. + apply (znz_of_pos_correct w4_spec). + apply Zlt_le_trans with (1 := pheight_correct x). + rewrite H1; simpl Z_of_nat; change (2^4) with (2 * 2 * 2 * 2). + unfold base. + apply Zpower_le_monotone; split; auto with zarith. + apply Zeq_le; apply Zmult_comm. + intros n; case n; clear n. + intros H1; rewrite spec_reduce_5; unfold to_Z. + apply (znz_of_pos_correct w5_spec). + apply Zlt_le_trans with (1 := pheight_correct x). + rewrite H1; simpl Z_of_nat; change (2^5) with (2 * 2 * 2 * 2 * 2). + unfold base. + apply Zpower_le_monotone; split; auto with zarith. + apply Zeq_le; apply Zmult_comm. + intros n; case n; clear n. + intros H1; rewrite spec_reduce_6; unfold to_Z. + apply (znz_of_pos_correct w6_spec). + apply Zlt_le_trans with (1 := pheight_correct x). + rewrite H1; simpl Z_of_nat; change (2^6) with (2 * 2 * 2 * 2 * 2 * 2). + unfold base. + apply Zpower_le_monotone; split; auto with zarith. + apply Zeq_le; apply Zmult_comm. + intros n. + intros H1; rewrite spec_reduce_n; unfold to_Z. + simpl minus; rewrite <- minus_n_O. + apply (znz_of_pos_correct (wn_spec n)). + apply Zlt_le_trans with (1 := pheight_correct x). + unfold base. + apply Zpower_le_monotone; auto with zarith. + split; auto with zarith. + rewrite H1. + elim n; clear n H1. + simpl Z_of_nat; change (2^7) with (2 * 2 * 2 * 2 * 2 * 2 * 2). + rewrite Zmult_comm; repeat rewrite <- Zmult_assoc. + repeat rewrite <- Zpos_xO. + refine (Zle_refl _). + intros n Hrec. + rewrite make_op_S. + change (@znz_digits (word _ (S (S n))) (mk_zn2z_op_karatsuba (make_op n))) with + (xO (znz_digits (make_op n))). + rewrite (fun x y => (Zpos_xO (@znz_digits x y))). + rewrite inj_S; unfold Zsucc. + rewrite Zplus_comm; rewrite Zpower_exp; auto with zarith. + rewrite Zpower_1_r. + assert (tmp: forall x y z, x * (y * z) = y * (x * z)); + [intros; ring | rewrite tmp; clear tmp]. + apply Zmult_le_compat_l; auto with zarith. + Qed. + + Definition of_N x := + match x with + | BinNat.N0 => zero + | Npos p => of_pos p + end. + + Theorem spec_of_N: forall x, + [of_N x] = Z_of_N x. + Proof. + intros x; case x. + simpl of_N. + unfold zero, w_0, to_Z; rewrite (spec_0 w0_spec); auto. + intros p; exact (spec_of_pos p). + Qed. + + (***************************************************************) + (* *) + (* Shift *) + (* *) + (***************************************************************) + + Definition head0 w := match w with + | N0 w=> reduce_0 (w0_op.(znz_head0) w) + | N1 w=> reduce_1 (w1_op.(znz_head0) w) + | N2 w=> reduce_2 (w2_op.(znz_head0) w) + | N3 w=> reduce_3 (w3_op.(znz_head0) w) + | N4 w=> reduce_4 (w4_op.(znz_head0) w) + | N5 w=> reduce_5 (w5_op.(znz_head0) w) + | N6 w=> reduce_6 (w6_op.(znz_head0) w) + | Nn n w=> reduce_n n ((make_op n).(znz_head0) w) + end. + + Theorem spec_head00: forall x, [x] = 0 ->[head0 x] = Zpos (digits x). + Proof. + intros x; case x; unfold head0; clear x. + intros x; rewrite spec_reduce_0; exact (spec_head00 w0_spec x). + intros x; rewrite spec_reduce_1; exact (spec_head00 w1_spec x). + intros x; rewrite spec_reduce_2; exact (spec_head00 w2_spec x). + intros x; rewrite spec_reduce_3; exact (spec_head00 w3_spec x). + intros x; rewrite spec_reduce_4; exact (spec_head00 w4_spec x). + intros x; rewrite spec_reduce_5; exact (spec_head00 w5_spec x). + intros x; rewrite spec_reduce_6; exact (spec_head00 w6_spec x). + intros n x; rewrite spec_reduce_n; exact (spec_head00 (wn_spec n) x). + Qed. + + Theorem spec_head0: forall x, 0 < [x] -> + 2 ^ (Zpos (digits x) - 1) <= 2 ^ [head0 x] * [x] < 2 ^ Zpos (digits x). + Proof. + assert (F0: forall x, (x - 1) + 1 = x). + intros; ring. + intros x; case x; unfold digits, head0; clear x. + intros x Hx; rewrite spec_reduce_0. + assert (F1:= spec_more_than_1_digit w0_spec). + generalize (spec_head0 w0_spec x Hx). + unfold base. + pattern (Zpos (znz_digits w0_op)) at 1; + rewrite <- (fun x => (F0 (Zpos x))). + rewrite Zpower_exp; auto with zarith. + rewrite Zpower_1_r; rewrite Z_div_mult; auto with zarith. + intros x Hx; rewrite spec_reduce_1. + assert (F1:= spec_more_than_1_digit w1_spec). + generalize (spec_head0 w1_spec x Hx). + unfold base. + pattern (Zpos (znz_digits w1_op)) at 1; + rewrite <- (fun x => (F0 (Zpos x))). + rewrite Zpower_exp; auto with zarith. + rewrite Zpower_1_r; rewrite Z_div_mult; auto with zarith. + intros x Hx; rewrite spec_reduce_2. + assert (F1:= spec_more_than_1_digit w2_spec). + generalize (spec_head0 w2_spec x Hx). + unfold base. + pattern (Zpos (znz_digits w2_op)) at 1; + rewrite <- (fun x => (F0 (Zpos x))). + rewrite Zpower_exp; auto with zarith. + rewrite Zpower_1_r; rewrite Z_div_mult; auto with zarith. + intros x Hx; rewrite spec_reduce_3. + assert (F1:= spec_more_than_1_digit w3_spec). + generalize (spec_head0 w3_spec x Hx). + unfold base. + pattern (Zpos (znz_digits w3_op)) at 1; + rewrite <- (fun x => (F0 (Zpos x))). + rewrite Zpower_exp; auto with zarith. + rewrite Zpower_1_r; rewrite Z_div_mult; auto with zarith. + intros x Hx; rewrite spec_reduce_4. + assert (F1:= spec_more_than_1_digit w4_spec). + generalize (spec_head0 w4_spec x Hx). + unfold base. + pattern (Zpos (znz_digits w4_op)) at 1; + rewrite <- (fun x => (F0 (Zpos x))). + rewrite Zpower_exp; auto with zarith. + rewrite Zpower_1_r; rewrite Z_div_mult; auto with zarith. + intros x Hx; rewrite spec_reduce_5. + assert (F1:= spec_more_than_1_digit w5_spec). + generalize (spec_head0 w5_spec x Hx). + unfold base. + pattern (Zpos (znz_digits w5_op)) at 1; + rewrite <- (fun x => (F0 (Zpos x))). + rewrite Zpower_exp; auto with zarith. + rewrite Zpower_1_r; rewrite Z_div_mult; auto with zarith. + intros x Hx; rewrite spec_reduce_6. + assert (F1:= spec_more_than_1_digit w6_spec). + generalize (spec_head0 w6_spec x Hx). + unfold base. + pattern (Zpos (znz_digits w6_op)) at 1; + rewrite <- (fun x => (F0 (Zpos x))). + rewrite Zpower_exp; auto with zarith. + rewrite Zpower_1_r; rewrite Z_div_mult; auto with zarith. + intros n x Hx; rewrite spec_reduce_n. + assert (F1:= spec_more_than_1_digit (wn_spec n)). + generalize (spec_head0 (wn_spec n) x Hx). + unfold base. + pattern (Zpos (znz_digits (make_op n))) at 1; + rewrite <- (fun x => (F0 (Zpos x))). + rewrite Zpower_exp; auto with zarith. + rewrite Zpower_1_r; rewrite Z_div_mult; auto with zarith. + Qed. + + Definition tail0 w := match w with + | N0 w=> reduce_0 (w0_op.(znz_tail0) w) + | N1 w=> reduce_1 (w1_op.(znz_tail0) w) + | N2 w=> reduce_2 (w2_op.(znz_tail0) w) + | N3 w=> reduce_3 (w3_op.(znz_tail0) w) + | N4 w=> reduce_4 (w4_op.(znz_tail0) w) + | N5 w=> reduce_5 (w5_op.(znz_tail0) w) + | N6 w=> reduce_6 (w6_op.(znz_tail0) w) + | Nn n w=> reduce_n n ((make_op n).(znz_tail0) w) + end. + + Theorem spec_tail00: forall x, [x] = 0 ->[tail0 x] = Zpos (digits x). + Proof. + intros x; case x; unfold tail0; clear x. + intros x; rewrite spec_reduce_0; exact (spec_tail00 w0_spec x). + intros x; rewrite spec_reduce_1; exact (spec_tail00 w1_spec x). + intros x; rewrite spec_reduce_2; exact (spec_tail00 w2_spec x). + intros x; rewrite spec_reduce_3; exact (spec_tail00 w3_spec x). + intros x; rewrite spec_reduce_4; exact (spec_tail00 w4_spec x). + intros x; rewrite spec_reduce_5; exact (spec_tail00 w5_spec x). + intros x; rewrite spec_reduce_6; exact (spec_tail00 w6_spec x). + intros n x; rewrite spec_reduce_n; exact (spec_tail00 (wn_spec n) x). + Qed. + + Theorem spec_tail0: forall x, + 0 < [x] -> exists y, 0 <= y /\ [x] = (2 * y + 1) * 2 ^ [tail0 x]. + Proof. + intros x; case x; clear x; unfold tail0. + intros x Hx; rewrite spec_reduce_0; exact (spec_tail0 w0_spec x Hx). + intros x Hx; rewrite spec_reduce_1; exact (spec_tail0 w1_spec x Hx). + intros x Hx; rewrite spec_reduce_2; exact (spec_tail0 w2_spec x Hx). + intros x Hx; rewrite spec_reduce_3; exact (spec_tail0 w3_spec x Hx). + intros x Hx; rewrite spec_reduce_4; exact (spec_tail0 w4_spec x Hx). + intros x Hx; rewrite spec_reduce_5; exact (spec_tail0 w5_spec x Hx). + intros x Hx; rewrite spec_reduce_6; exact (spec_tail0 w6_spec x Hx). + intros n x Hx; rewrite spec_reduce_n; exact (spec_tail0 (wn_spec n) x Hx). + Qed. + + Definition Ndigits x := + match x with + | N0 _ => N0 w0_op.(znz_zdigits) + | N1 _ => reduce_1 w1_op.(znz_zdigits) + | N2 _ => reduce_2 w2_op.(znz_zdigits) + | N3 _ => reduce_3 w3_op.(znz_zdigits) + | N4 _ => reduce_4 w4_op.(znz_zdigits) + | N5 _ => reduce_5 w5_op.(znz_zdigits) + | N6 _ => reduce_6 w6_op.(znz_zdigits) + | Nn n _ => reduce_n n (make_op n).(znz_zdigits) + end. + + Theorem spec_Ndigits: forall x, [Ndigits x] = Zpos (digits x). + Proof. + intros x; case x; clear x; unfold Ndigits, digits. + intros _; try rewrite spec_reduce_0; exact (spec_zdigits w0_spec). + intros _; try rewrite spec_reduce_1; exact (spec_zdigits w1_spec). + intros _; try rewrite spec_reduce_2; exact (spec_zdigits w2_spec). + intros _; try rewrite spec_reduce_3; exact (spec_zdigits w3_spec). + intros _; try rewrite spec_reduce_4; exact (spec_zdigits w4_spec). + intros _; try rewrite spec_reduce_5; exact (spec_zdigits w5_spec). + intros _; try rewrite spec_reduce_6; exact (spec_zdigits w6_spec). + intros n _; try rewrite spec_reduce_n; exact (spec_zdigits (wn_spec n)). + Qed. + + Definition shiftr0 n x := w0_op.(znz_add_mul_div) (w0_op.(znz_sub) w0_op.(znz_zdigits) n) w0_op.(znz_0) x. + Definition shiftr1 n x := w1_op.(znz_add_mul_div) (w1_op.(znz_sub) w1_op.(znz_zdigits) n) w1_op.(znz_0) x. + Definition shiftr2 n x := w2_op.(znz_add_mul_div) (w2_op.(znz_sub) w2_op.(znz_zdigits) n) w2_op.(znz_0) x. + Definition shiftr3 n x := w3_op.(znz_add_mul_div) (w3_op.(znz_sub) w3_op.(znz_zdigits) n) w3_op.(znz_0) x. + Definition shiftr4 n x := w4_op.(znz_add_mul_div) (w4_op.(znz_sub) w4_op.(znz_zdigits) n) w4_op.(znz_0) x. + Definition shiftr5 n x := w5_op.(znz_add_mul_div) (w5_op.(znz_sub) w5_op.(znz_zdigits) n) w5_op.(znz_0) x. + Definition shiftr6 n x := w6_op.(znz_add_mul_div) (w6_op.(znz_sub) w6_op.(znz_zdigits) n) w6_op.(znz_0) x. + Definition 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. + + Definition shiftr := Eval lazy beta delta [same_level] in + same_level _ (fun n x => N0 (shiftr0 n x)) + (fun n x => reduce_1 (shiftr1 n x)) + (fun n x => reduce_2 (shiftr2 n x)) + (fun n x => reduce_3 (shiftr3 n x)) + (fun n x => reduce_4 (shiftr4 n x)) + (fun n x => reduce_5 (shiftr5 n x)) + (fun n x => reduce_6 (shiftr6 n x)) + (fun n p x => reduce_n n (shiftrn n p x)). + + Theorem spec_shiftr: forall n x, + [n] <= [Ndigits x] -> [shiftr n x] = [x] / 2 ^ [n]. + Proof. + assert (F0: forall x y, x - (x - y) = y). + intros; ring. + assert (F2: forall x y z, 0 <= x -> 0 <= y -> x < z -> 0 <= x / 2 ^ y < z). + intros x y z HH HH1 HH2. + split; auto with zarith. + apply Zle_lt_trans with (2 := HH2); auto with zarith. + apply Zdiv_le_upper_bound; auto with zarith. + pattern x at 1; replace x with (x * 2 ^ 0); auto with zarith. + apply Zmult_le_compat_l; auto. + apply Zpower_le_monotone; auto with zarith. + rewrite Zpower_0_r; ring. + assert (F3: forall x y, 0 <= y -> y <= x -> 0 <= x - y < 2 ^ x). + intros xx y HH HH1. + split; auto with zarith. + apply Zle_lt_trans with xx; auto with zarith. + apply Zpower2_lt_lin; auto with zarith. + assert (F4: forall ww ww1 ww2 + (ww_op: znz_op ww) (ww1_op: znz_op ww1) (ww2_op: znz_op ww2) + xx yy xx1 yy1, + znz_to_Z ww2_op yy <= znz_to_Z ww1_op (znz_zdigits ww1_op) -> + znz_to_Z ww1_op (znz_zdigits ww1_op) <= znz_to_Z ww_op (znz_zdigits ww_op) -> + znz_spec ww_op -> znz_spec ww1_op -> znz_spec ww2_op -> + znz_to_Z ww_op xx1 = znz_to_Z ww1_op xx -> + znz_to_Z ww_op yy1 = znz_to_Z ww2_op yy -> + znz_to_Z ww_op + (znz_add_mul_div ww_op (znz_sub ww_op (znz_zdigits ww_op) yy1) + (znz_0 ww_op) xx1) = znz_to_Z ww1_op xx / 2 ^ znz_to_Z ww2_op yy). + intros ww ww1 ww2 ww_op ww1_op ww2_op xx yy xx1 yy1 Hl Hl1 Hw Hw1 Hw2 Hx Hy. + case (spec_to_Z Hw xx1); auto with zarith; intros HH1 HH2. + case (spec_to_Z Hw yy1); auto with zarith; intros HH3 HH4. + rewrite <- Hx. + rewrite <- Hy. + generalize (spec_add_mul_div Hw + (znz_0 ww_op) xx1 + (znz_sub ww_op (znz_zdigits ww_op) + yy1) + ). + rewrite (spec_0 Hw). + rewrite Zmult_0_l; rewrite Zplus_0_l. + rewrite (ZnZ.spec_sub Hw). + rewrite Zmod_small; auto with zarith. + rewrite (spec_zdigits Hw). + rewrite F0. + rewrite Zmod_small; auto with zarith. + unfold base; rewrite (spec_zdigits Hw) in Hl1 |- *; + auto with zarith. + assert (F5: forall n m, (n <= m)%nat -> + Zpos (znz_digits (make_op n)) <= Zpos (znz_digits (make_op m))). + intros n m HH; elim HH; clear m HH; auto with zarith. + intros m HH Hrec; apply Zle_trans with (1 := Hrec). + rewrite make_op_S. + match goal with |- Zpos ?Y <= ?X => change X with (Zpos (xO Y)) end. + rewrite Zpos_xO. + assert (0 <= Zpos (znz_digits (make_op n))); auto with zarith. + assert (F6: forall n, Zpos (znz_digits w6_op) <= Zpos (znz_digits (make_op n))). + intros n ; apply Zle_trans with (Zpos (znz_digits (make_op 0))). + change (znz_digits (make_op 0)) with (xO (znz_digits w6_op)). + rewrite Zpos_xO. + assert (0 <= Zpos (znz_digits w6_op)); auto with zarith. + apply F5; auto with arith. + intros x; case x; clear x; unfold shiftr, same_level. + intros x y; case y; clear y. + intros y; unfold shiftr0, Ndigits. + repeat rewrite spec_reduce_0; unfold to_Z; intros H1. + apply F4 with (3:=w0_spec)(4:=w0_spec)(5:=w0_spec); auto with zarith. + intros y; unfold shiftr1, Ndigits. + repeat rewrite spec_reduce_0; repeat rewrite spec_reduce_1; unfold to_Z; intros H1. + apply F4 with (3:=w1_spec)(4:=w1_spec)(5:=w0_spec); auto with zarith. + try (apply sym_equal; exact (spec_extend0n1 x)). + intros y; unfold shiftr2, Ndigits. + repeat rewrite spec_reduce_0; repeat rewrite spec_reduce_2; unfold to_Z; intros H1. + apply F4 with (3:=w2_spec)(4:=w2_spec)(5:=w0_spec); auto with zarith. + try (apply sym_equal; exact (spec_extend0n2 x)). + intros y; unfold shiftr3, Ndigits. + repeat rewrite spec_reduce_0; repeat rewrite spec_reduce_3; unfold to_Z; intros H1. + apply F4 with (3:=w3_spec)(4:=w3_spec)(5:=w0_spec); auto with zarith. + try (apply sym_equal; exact (spec_extend0n3 x)). + intros y; unfold shiftr4, Ndigits. + repeat rewrite spec_reduce_0; repeat rewrite spec_reduce_4; unfold to_Z; intros H1. + apply F4 with (3:=w4_spec)(4:=w4_spec)(5:=w0_spec); auto with zarith. + try (apply sym_equal; exact (spec_extend0n4 x)). + intros y; unfold shiftr5, Ndigits. + repeat rewrite spec_reduce_0; repeat rewrite spec_reduce_5; unfold to_Z; intros H1. + apply F4 with (3:=w5_spec)(4:=w5_spec)(5:=w0_spec); auto with zarith. + try (apply sym_equal; exact (spec_extend0n5 x)). + intros y; unfold shiftr6, Ndigits. + repeat rewrite spec_reduce_0; repeat rewrite spec_reduce_6; unfold to_Z; intros H1. + apply F4 with (3:=w6_spec)(4:=w6_spec)(5:=w0_spec); auto with zarith. + try (apply sym_equal; exact (spec_extend0n6 x)). + intros m y; unfold shiftrn, Ndigits. + repeat rewrite spec_reduce_n; unfold to_Z; intros H1. + apply F4 with (3:=(wn_spec m))(4:=wn_spec m)(5:=w0_spec); auto with zarith. + change ([Nn m (extend6 m (extend0 5 x))] = [N0 x]). + rewrite <- (spec_extend6n m); rewrite <- spec_extend0n6; auto. + intros x y; case y; clear y. + intros y; unfold shiftr1, Ndigits. + repeat rewrite spec_reduce_1; repeat rewrite spec_reduce_0; unfold to_Z; intros H1. + apply F4 with (3:=w1_spec)(4:=w0_spec)(5:=w1_spec); auto with zarith. + rewrite (spec_zdigits w1_spec). + rewrite (spec_zdigits w0_spec). + change (znz_digits w1_op) with (xO (znz_digits w0_op)). + repeat rewrite (fun x => Zpos_xO (xO x)). + repeat rewrite (fun x y => Zpos_xO (@znz_digits x y)). + assert (0 <= Zpos (znz_digits w0_op)); auto with zarith. + try (apply sym_equal; exact (spec_extend0n1 y)). + intros y; unfold shiftr1, Ndigits. + repeat rewrite spec_reduce_1; unfold to_Z; intros H1. + apply F4 with (3:=w1_spec)(4:=w1_spec)(5:=w1_spec); auto with zarith. + intros y; unfold shiftr2, Ndigits. + repeat rewrite spec_reduce_1; repeat rewrite spec_reduce_2; unfold to_Z; intros H1. + apply F4 with (3:=w2_spec)(4:=w2_spec)(5:=w1_spec); auto with zarith. + try (apply sym_equal; exact (spec_extend1n2 x)). + intros y; unfold shiftr3, Ndigits. + repeat rewrite spec_reduce_1; repeat rewrite spec_reduce_3; unfold to_Z; intros H1. + apply F4 with (3:=w3_spec)(4:=w3_spec)(5:=w1_spec); auto with zarith. + try (apply sym_equal; exact (spec_extend1n3 x)). + intros y; unfold shiftr4, Ndigits. + repeat rewrite spec_reduce_1; repeat rewrite spec_reduce_4; unfold to_Z; intros H1. + apply F4 with (3:=w4_spec)(4:=w4_spec)(5:=w1_spec); auto with zarith. + try (apply sym_equal; exact (spec_extend1n4 x)). + intros y; unfold shiftr5, Ndigits. + repeat rewrite spec_reduce_1; repeat rewrite spec_reduce_5; unfold to_Z; intros H1. + apply F4 with (3:=w5_spec)(4:=w5_spec)(5:=w1_spec); auto with zarith. + try (apply sym_equal; exact (spec_extend1n5 x)). + intros y; unfold shiftr6, Ndigits. + repeat rewrite spec_reduce_1; repeat rewrite spec_reduce_6; unfold to_Z; intros H1. + apply F4 with (3:=w6_spec)(4:=w6_spec)(5:=w1_spec); auto with zarith. + try (apply sym_equal; exact (spec_extend1n6 x)). + intros m y; unfold shiftrn, Ndigits. + repeat rewrite spec_reduce_n; unfold to_Z; intros H1. + apply F4 with (3:=(wn_spec m))(4:=wn_spec m)(5:=w1_spec); auto with zarith. + change ([Nn m (extend6 m (extend1 4 x))] = [N1 x]). + rewrite <- (spec_extend6n m); rewrite <- spec_extend1n6; auto. + intros x y; case y; clear y. + intros y; unfold shiftr2, Ndigits. + repeat rewrite spec_reduce_2; repeat rewrite spec_reduce_0; unfold to_Z; intros H1. + apply F4 with (3:=w2_spec)(4:=w0_spec)(5:=w2_spec); auto with zarith. + rewrite (spec_zdigits w2_spec). + rewrite (spec_zdigits w0_spec). + change (znz_digits w2_op) with (xO (xO (znz_digits w0_op))). + repeat rewrite (fun x => Zpos_xO (xO x)). + repeat rewrite (fun x y => Zpos_xO (@znz_digits x y)). + assert (0 <= Zpos (znz_digits w0_op)); auto with zarith. + try (apply sym_equal; exact (spec_extend0n2 y)). + intros y; unfold shiftr2, Ndigits. + repeat rewrite spec_reduce_2; repeat rewrite spec_reduce_1; unfold to_Z; intros H1. + apply F4 with (3:=w2_spec)(4:=w1_spec)(5:=w2_spec); auto with zarith. + rewrite (spec_zdigits w2_spec). + rewrite (spec_zdigits w1_spec). + change (znz_digits w2_op) with (xO (znz_digits w1_op)). + repeat rewrite (fun x => Zpos_xO (xO x)). + repeat rewrite (fun x y => Zpos_xO (@znz_digits x y)). + assert (0 <= Zpos (znz_digits w1_op)); auto with zarith. + try (apply sym_equal; exact (spec_extend1n2 y)). + intros y; unfold shiftr2, Ndigits. + repeat rewrite spec_reduce_2; unfold to_Z; intros H1. + apply F4 with (3:=w2_spec)(4:=w2_spec)(5:=w2_spec); auto with zarith. + intros y; unfold shiftr3, Ndigits. + repeat rewrite spec_reduce_2; repeat rewrite spec_reduce_3; unfold to_Z; intros H1. + apply F4 with (3:=w3_spec)(4:=w3_spec)(5:=w2_spec); auto with zarith. + try (apply sym_equal; exact (spec_extend2n3 x)). + intros y; unfold shiftr4, Ndigits. + repeat rewrite spec_reduce_2; repeat rewrite spec_reduce_4; unfold to_Z; intros H1. + apply F4 with (3:=w4_spec)(4:=w4_spec)(5:=w2_spec); auto with zarith. + try (apply sym_equal; exact (spec_extend2n4 x)). + intros y; unfold shiftr5, Ndigits. + repeat rewrite spec_reduce_2; repeat rewrite spec_reduce_5; unfold to_Z; intros H1. + apply F4 with (3:=w5_spec)(4:=w5_spec)(5:=w2_spec); auto with zarith. + try (apply sym_equal; exact (spec_extend2n5 x)). + intros y; unfold shiftr6, Ndigits. + repeat rewrite spec_reduce_2; repeat rewrite spec_reduce_6; unfold to_Z; intros H1. + apply F4 with (3:=w6_spec)(4:=w6_spec)(5:=w2_spec); auto with zarith. + try (apply sym_equal; exact (spec_extend2n6 x)). + intros m y; unfold shiftrn, Ndigits. + repeat rewrite spec_reduce_n; unfold to_Z; intros H1. + apply F4 with (3:=(wn_spec m))(4:=wn_spec m)(5:=w2_spec); auto with zarith. + change ([Nn m (extend6 m (extend2 3 x))] = [N2 x]). + rewrite <- (spec_extend6n m); rewrite <- spec_extend2n6; auto. + intros x y; case y; clear y. + intros y; unfold shiftr3, Ndigits. + repeat rewrite spec_reduce_3; repeat rewrite spec_reduce_0; unfold to_Z; intros H1. + apply F4 with (3:=w3_spec)(4:=w0_spec)(5:=w3_spec); auto with zarith. + rewrite (spec_zdigits w3_spec). + rewrite (spec_zdigits w0_spec). + change (znz_digits w3_op) with (xO (xO (xO (znz_digits w0_op)))). + repeat rewrite (fun x => Zpos_xO (xO x)). + repeat rewrite (fun x y => Zpos_xO (@znz_digits x y)). + assert (0 <= Zpos (znz_digits w0_op)); auto with zarith. + try (apply sym_equal; exact (spec_extend0n3 y)). + intros y; unfold shiftr3, Ndigits. + repeat rewrite spec_reduce_3; repeat rewrite spec_reduce_1; unfold to_Z; intros H1. + apply F4 with (3:=w3_spec)(4:=w1_spec)(5:=w3_spec); auto with zarith. + rewrite (spec_zdigits w3_spec). + rewrite (spec_zdigits w1_spec). + change (znz_digits w3_op) with (xO (xO (znz_digits w1_op))). + repeat rewrite (fun x => Zpos_xO (xO x)). + repeat rewrite (fun x y => Zpos_xO (@znz_digits x y)). + assert (0 <= Zpos (znz_digits w1_op)); auto with zarith. + try (apply sym_equal; exact (spec_extend1n3 y)). + intros y; unfold shiftr3, Ndigits. + repeat rewrite spec_reduce_3; repeat rewrite spec_reduce_2; unfold to_Z; intros H1. + apply F4 with (3:=w3_spec)(4:=w2_spec)(5:=w3_spec); auto with zarith. + rewrite (spec_zdigits w3_spec). + rewrite (spec_zdigits w2_spec). + change (znz_digits w3_op) with (xO (znz_digits w2_op)). + repeat rewrite (fun x => Zpos_xO (xO x)). + repeat rewrite (fun x y => Zpos_xO (@znz_digits x y)). + assert (0 <= Zpos (znz_digits w2_op)); auto with zarith. + try (apply sym_equal; exact (spec_extend2n3 y)). + intros y; unfold shiftr3, Ndigits. + repeat rewrite spec_reduce_3; unfold to_Z; intros H1. + apply F4 with (3:=w3_spec)(4:=w3_spec)(5:=w3_spec); auto with zarith. + intros y; unfold shiftr4, Ndigits. + repeat rewrite spec_reduce_3; repeat rewrite spec_reduce_4; unfold to_Z; intros H1. + apply F4 with (3:=w4_spec)(4:=w4_spec)(5:=w3_spec); auto with zarith. + try (apply sym_equal; exact (spec_extend3n4 x)). + intros y; unfold shiftr5, Ndigits. + repeat rewrite spec_reduce_3; repeat rewrite spec_reduce_5; unfold to_Z; intros H1. + apply F4 with (3:=w5_spec)(4:=w5_spec)(5:=w3_spec); auto with zarith. + try (apply sym_equal; exact (spec_extend3n5 x)). + intros y; unfold shiftr6, Ndigits. + repeat rewrite spec_reduce_3; repeat rewrite spec_reduce_6; unfold to_Z; intros H1. + apply F4 with (3:=w6_spec)(4:=w6_spec)(5:=w3_spec); auto with zarith. + try (apply sym_equal; exact (spec_extend3n6 x)). + intros m y; unfold shiftrn, Ndigits. + repeat rewrite spec_reduce_n; unfold to_Z; intros H1. + apply F4 with (3:=(wn_spec m))(4:=wn_spec m)(5:=w3_spec); auto with zarith. + change ([Nn m (extend6 m (extend3 2 x))] = [N3 x]). + rewrite <- (spec_extend6n m); rewrite <- spec_extend3n6; auto. + intros x y; case y; clear y. + intros y; unfold shiftr4, Ndigits. + repeat rewrite spec_reduce_4; repeat rewrite spec_reduce_0; unfold to_Z; intros H1. + apply F4 with (3:=w4_spec)(4:=w0_spec)(5:=w4_spec); auto with zarith. + rewrite (spec_zdigits w4_spec). + rewrite (spec_zdigits w0_spec). + change (znz_digits w4_op) with (xO (xO (xO (xO (znz_digits w0_op))))). + repeat rewrite (fun x => Zpos_xO (xO x)). + repeat rewrite (fun x y => Zpos_xO (@znz_digits x y)). + assert (0 <= Zpos (znz_digits w0_op)); auto with zarith. + try (apply sym_equal; exact (spec_extend0n4 y)). + intros y; unfold shiftr4, Ndigits. + repeat rewrite spec_reduce_4; repeat rewrite spec_reduce_1; unfold to_Z; intros H1. + apply F4 with (3:=w4_spec)(4:=w1_spec)(5:=w4_spec); auto with zarith. + rewrite (spec_zdigits w4_spec). + rewrite (spec_zdigits w1_spec). + change (znz_digits w4_op) with (xO (xO (xO (znz_digits w1_op)))). + repeat rewrite (fun x => Zpos_xO (xO x)). + repeat rewrite (fun x y => Zpos_xO (@znz_digits x y)). + assert (0 <= Zpos (znz_digits w1_op)); auto with zarith. + try (apply sym_equal; exact (spec_extend1n4 y)). + intros y; unfold shiftr4, Ndigits. + repeat rewrite spec_reduce_4; repeat rewrite spec_reduce_2; unfold to_Z; intros H1. + apply F4 with (3:=w4_spec)(4:=w2_spec)(5:=w4_spec); auto with zarith. + rewrite (spec_zdigits w4_spec). + rewrite (spec_zdigits w2_spec). + change (znz_digits w4_op) with (xO (xO (znz_digits w2_op))). + repeat rewrite (fun x => Zpos_xO (xO x)). + repeat rewrite (fun x y => Zpos_xO (@znz_digits x y)). + assert (0 <= Zpos (znz_digits w2_op)); auto with zarith. + try (apply sym_equal; exact (spec_extend2n4 y)). + intros y; unfold shiftr4, Ndigits. + repeat rewrite spec_reduce_4; repeat rewrite spec_reduce_3; unfold to_Z; intros H1. + apply F4 with (3:=w4_spec)(4:=w3_spec)(5:=w4_spec); auto with zarith. + rewrite (spec_zdigits w4_spec). + rewrite (spec_zdigits w3_spec). + change (znz_digits w4_op) with (xO (znz_digits w3_op)). + repeat rewrite (fun x => Zpos_xO (xO x)). + repeat rewrite (fun x y => Zpos_xO (@znz_digits x y)). + assert (0 <= Zpos (znz_digits w3_op)); auto with zarith. + try (apply sym_equal; exact (spec_extend3n4 y)). + intros y; unfold shiftr4, Ndigits. + repeat rewrite spec_reduce_4; unfold to_Z; intros H1. + apply F4 with (3:=w4_spec)(4:=w4_spec)(5:=w4_spec); auto with zarith. + intros y; unfold shiftr5, Ndigits. + repeat rewrite spec_reduce_4; repeat rewrite spec_reduce_5; unfold to_Z; intros H1. + apply F4 with (3:=w5_spec)(4:=w5_spec)(5:=w4_spec); auto with zarith. + try (apply sym_equal; exact (spec_extend4n5 x)). + intros y; unfold shiftr6, Ndigits. + repeat rewrite spec_reduce_4; repeat rewrite spec_reduce_6; unfold to_Z; intros H1. + apply F4 with (3:=w6_spec)(4:=w6_spec)(5:=w4_spec); auto with zarith. + try (apply sym_equal; exact (spec_extend4n6 x)). + intros m y; unfold shiftrn, Ndigits. + repeat rewrite spec_reduce_n; unfold to_Z; intros H1. + apply F4 with (3:=(wn_spec m))(4:=wn_spec m)(5:=w4_spec); auto with zarith. + change ([Nn m (extend6 m (extend4 1 x))] = [N4 x]). + rewrite <- (spec_extend6n m); rewrite <- spec_extend4n6; auto. + intros x y; case y; clear y. + intros y; unfold shiftr5, Ndigits. + repeat rewrite spec_reduce_5; repeat rewrite spec_reduce_0; unfold to_Z; intros H1. + apply F4 with (3:=w5_spec)(4:=w0_spec)(5:=w5_spec); auto with zarith. + rewrite (spec_zdigits w5_spec). + rewrite (spec_zdigits w0_spec). + change (znz_digits w5_op) with (xO (xO (xO (xO (xO (znz_digits w0_op)))))). + repeat rewrite (fun x => Zpos_xO (xO x)). + repeat rewrite (fun x y => Zpos_xO (@znz_digits x y)). + assert (0 <= Zpos (znz_digits w0_op)); auto with zarith. + try (apply sym_equal; exact (spec_extend0n5 y)). + intros y; unfold shiftr5, Ndigits. + repeat rewrite spec_reduce_5; repeat rewrite spec_reduce_1; unfold to_Z; intros H1. + apply F4 with (3:=w5_spec)(4:=w1_spec)(5:=w5_spec); auto with zarith. + rewrite (spec_zdigits w5_spec). + rewrite (spec_zdigits w1_spec). + change (znz_digits w5_op) with (xO (xO (xO (xO (znz_digits w1_op))))). + repeat rewrite (fun x => Zpos_xO (xO x)). + repeat rewrite (fun x y => Zpos_xO (@znz_digits x y)). + assert (0 <= Zpos (znz_digits w1_op)); auto with zarith. + try (apply sym_equal; exact (spec_extend1n5 y)). + intros y; unfold shiftr5, Ndigits. + repeat rewrite spec_reduce_5; repeat rewrite spec_reduce_2; unfold to_Z; intros H1. + apply F4 with (3:=w5_spec)(4:=w2_spec)(5:=w5_spec); auto with zarith. + rewrite (spec_zdigits w5_spec). + rewrite (spec_zdigits w2_spec). + change (znz_digits w5_op) with (xO (xO (xO (znz_digits w2_op)))). + repeat rewrite (fun x => Zpos_xO (xO x)). + repeat rewrite (fun x y => Zpos_xO (@znz_digits x y)). + assert (0 <= Zpos (znz_digits w2_op)); auto with zarith. + try (apply sym_equal; exact (spec_extend2n5 y)). + intros y; unfold shiftr5, Ndigits. + repeat rewrite spec_reduce_5; repeat rewrite spec_reduce_3; unfold to_Z; intros H1. + apply F4 with (3:=w5_spec)(4:=w3_spec)(5:=w5_spec); auto with zarith. + rewrite (spec_zdigits w5_spec). + rewrite (spec_zdigits w3_spec). + change (znz_digits w5_op) with (xO (xO (znz_digits w3_op))). + repeat rewrite (fun x => Zpos_xO (xO x)). + repeat rewrite (fun x y => Zpos_xO (@znz_digits x y)). + assert (0 <= Zpos (znz_digits w3_op)); auto with zarith. + try (apply sym_equal; exact (spec_extend3n5 y)). + intros y; unfold shiftr5, Ndigits. + repeat rewrite spec_reduce_5; repeat rewrite spec_reduce_4; unfold to_Z; intros H1. + apply F4 with (3:=w5_spec)(4:=w4_spec)(5:=w5_spec); auto with zarith. + rewrite (spec_zdigits w5_spec). + rewrite (spec_zdigits w4_spec). + change (znz_digits w5_op) with (xO (znz_digits w4_op)). + repeat rewrite (fun x => Zpos_xO (xO x)). + repeat rewrite (fun x y => Zpos_xO (@znz_digits x y)). + assert (0 <= Zpos (znz_digits w4_op)); auto with zarith. + try (apply sym_equal; exact (spec_extend4n5 y)). + intros y; unfold shiftr5, Ndigits. + repeat rewrite spec_reduce_5; unfold to_Z; intros H1. + apply F4 with (3:=w5_spec)(4:=w5_spec)(5:=w5_spec); auto with zarith. + intros y; unfold shiftr6, Ndigits. + repeat rewrite spec_reduce_5; repeat rewrite spec_reduce_6; unfold to_Z; intros H1. + apply F4 with (3:=w6_spec)(4:=w6_spec)(5:=w5_spec); auto with zarith. + try (apply sym_equal; exact (spec_extend5n6 x)). + intros m y; unfold shiftrn, Ndigits. + repeat rewrite spec_reduce_n; unfold to_Z; intros H1. + apply F4 with (3:=(wn_spec m))(4:=wn_spec m)(5:=w5_spec); auto with zarith. + change ([Nn m (extend6 m (extend5 0 x))] = [N5 x]). + rewrite <- (spec_extend6n m); rewrite <- spec_extend5n6; auto. + intros x y; case y; clear y. + intros y; unfold shiftr6, Ndigits. + repeat rewrite spec_reduce_6; repeat rewrite spec_reduce_0; unfold to_Z; intros H1. + apply F4 with (3:=w6_spec)(4:=w0_spec)(5:=w6_spec); auto with zarith. + rewrite (spec_zdigits w6_spec). + rewrite (spec_zdigits w0_spec). + change (znz_digits w6_op) with (xO (xO (xO (xO (xO (xO (znz_digits w0_op))))))). + repeat rewrite (fun x => Zpos_xO (xO x)). + repeat rewrite (fun x y => Zpos_xO (@znz_digits x y)). + assert (0 <= Zpos (znz_digits w0_op)); auto with zarith. + try (apply sym_equal; exact (spec_extend0n6 y)). + intros y; unfold shiftr6, Ndigits. + repeat rewrite spec_reduce_6; repeat rewrite spec_reduce_1; unfold to_Z; intros H1. + apply F4 with (3:=w6_spec)(4:=w1_spec)(5:=w6_spec); auto with zarith. + rewrite (spec_zdigits w6_spec). + rewrite (spec_zdigits w1_spec). + change (znz_digits w6_op) with (xO (xO (xO (xO (xO (znz_digits w1_op)))))). + repeat rewrite (fun x => Zpos_xO (xO x)). + repeat rewrite (fun x y => Zpos_xO (@znz_digits x y)). + assert (0 <= Zpos (znz_digits w1_op)); auto with zarith. + try (apply sym_equal; exact (spec_extend1n6 y)). + intros y; unfold shiftr6, Ndigits. + repeat rewrite spec_reduce_6; repeat rewrite spec_reduce_2; unfold to_Z; intros H1. + apply F4 with (3:=w6_spec)(4:=w2_spec)(5:=w6_spec); auto with zarith. + rewrite (spec_zdigits w6_spec). + rewrite (spec_zdigits w2_spec). + change (znz_digits w6_op) with (xO (xO (xO (xO (znz_digits w2_op))))). + repeat rewrite (fun x => Zpos_xO (xO x)). + repeat rewrite (fun x y => Zpos_xO (@znz_digits x y)). + assert (0 <= Zpos (znz_digits w2_op)); auto with zarith. + try (apply sym_equal; exact (spec_extend2n6 y)). + intros y; unfold shiftr6, Ndigits. + repeat rewrite spec_reduce_6; repeat rewrite spec_reduce_3; unfold to_Z; intros H1. + apply F4 with (3:=w6_spec)(4:=w3_spec)(5:=w6_spec); auto with zarith. + rewrite (spec_zdigits w6_spec). + rewrite (spec_zdigits w3_spec). + change (znz_digits w6_op) with (xO (xO (xO (znz_digits w3_op)))). + repeat rewrite (fun x => Zpos_xO (xO x)). + repeat rewrite (fun x y => Zpos_xO (@znz_digits x y)). + assert (0 <= Zpos (znz_digits w3_op)); auto with zarith. + try (apply sym_equal; exact (spec_extend3n6 y)). + intros y; unfold shiftr6, Ndigits. + repeat rewrite spec_reduce_6; repeat rewrite spec_reduce_4; unfold to_Z; intros H1. + apply F4 with (3:=w6_spec)(4:=w4_spec)(5:=w6_spec); auto with zarith. + rewrite (spec_zdigits w6_spec). + rewrite (spec_zdigits w4_spec). + change (znz_digits w6_op) with (xO (xO (znz_digits w4_op))). + repeat rewrite (fun x => Zpos_xO (xO x)). + repeat rewrite (fun x y => Zpos_xO (@znz_digits x y)). + assert (0 <= Zpos (znz_digits w4_op)); auto with zarith. + try (apply sym_equal; exact (spec_extend4n6 y)). + intros y; unfold shiftr6, Ndigits. + repeat rewrite spec_reduce_6; repeat rewrite spec_reduce_5; unfold to_Z; intros H1. + apply F4 with (3:=w6_spec)(4:=w5_spec)(5:=w6_spec); auto with zarith. + rewrite (spec_zdigits w6_spec). + rewrite (spec_zdigits w5_spec). + change (znz_digits w6_op) with (xO (znz_digits w5_op)). + repeat rewrite (fun x => Zpos_xO (xO x)). + repeat rewrite (fun x y => Zpos_xO (@znz_digits x y)). + assert (0 <= Zpos (znz_digits w5_op)); auto with zarith. + try (apply sym_equal; exact (spec_extend5n6 y)). + intros y; unfold shiftr6, Ndigits. + repeat rewrite spec_reduce_6; unfold to_Z; intros H1. + apply F4 with (3:=w6_spec)(4:=w6_spec)(5:=w6_spec); auto with zarith. + intros m y; unfold shiftrn, Ndigits. + repeat rewrite spec_reduce_n; unfold to_Z; intros H1. + apply F4 with (3:=(wn_spec m))(4:=wn_spec m)(5:=w6_spec); auto with zarith. + try (apply sym_equal; exact (spec_extend6n m x)). + intros n x y; case y; clear y; + intros y; unfold shiftrn, Ndigits; try rewrite spec_reduce_n. + try rewrite spec_reduce_0; unfold to_Z; intros H1. + apply F4 with (3:=(wn_spec n))(4:=w0_spec)(5:=wn_spec n); auto with zarith. + rewrite (spec_zdigits w0_spec). + rewrite (spec_zdigits (wn_spec n)). + apply Zle_trans with (2 := F6 n). + change (znz_digits w6_op) with (xO (xO (xO (xO (xO (xO(znz_digits w0_op))))))). + repeat rewrite (fun x => Zpos_xO (xO x)). + repeat rewrite (fun x y => Zpos_xO (@znz_digits x y)). + assert (H: 0 <= Zpos (znz_digits w0_op)); auto with zarith. + change ([Nn n (extend6 n (extend0 5 y))] = [N0 y]). + rewrite <- (spec_extend6n n); auto. + try (rewrite <- spec_extend0n6; auto). + try rewrite spec_reduce_1; unfold to_Z; intros H1. + apply F4 with (3:=(wn_spec n))(4:=w1_spec)(5:=wn_spec n); auto with zarith. + rewrite (spec_zdigits w1_spec). + rewrite (spec_zdigits (wn_spec n)). + apply Zle_trans with (2 := F6 n). + change (znz_digits w6_op) with (xO (xO (xO (xO (xO(znz_digits w1_op)))))). + repeat rewrite (fun x => Zpos_xO (xO x)). + repeat rewrite (fun x y => Zpos_xO (@znz_digits x y)). + assert (H: 0 <= Zpos (znz_digits w1_op)); auto with zarith. + change ([Nn n (extend6 n (extend1 4 y))] = [N1 y]). + rewrite <- (spec_extend6n n); auto. + try (rewrite <- spec_extend1n6; auto). + try rewrite spec_reduce_2; unfold to_Z; intros H1. + apply F4 with (3:=(wn_spec n))(4:=w2_spec)(5:=wn_spec n); auto with zarith. + rewrite (spec_zdigits w2_spec). + rewrite (spec_zdigits (wn_spec n)). + apply Zle_trans with (2 := F6 n). + change (znz_digits w6_op) with (xO (xO (xO (xO(znz_digits w2_op))))). + repeat rewrite (fun x => Zpos_xO (xO x)). + repeat rewrite (fun x y => Zpos_xO (@znz_digits x y)). + assert (H: 0 <= Zpos (znz_digits w2_op)); auto with zarith. + change ([Nn n (extend6 n (extend2 3 y))] = [N2 y]). + rewrite <- (spec_extend6n n); auto. + try (rewrite <- spec_extend2n6; auto). + try rewrite spec_reduce_3; unfold to_Z; intros H1. + apply F4 with (3:=(wn_spec n))(4:=w3_spec)(5:=wn_spec n); auto with zarith. + rewrite (spec_zdigits w3_spec). + rewrite (spec_zdigits (wn_spec n)). + apply Zle_trans with (2 := F6 n). + change (znz_digits w6_op) with (xO (xO (xO(znz_digits w3_op)))). + repeat rewrite (fun x => Zpos_xO (xO x)). + repeat rewrite (fun x y => Zpos_xO (@znz_digits x y)). + assert (H: 0 <= Zpos (znz_digits w3_op)); auto with zarith. + change ([Nn n (extend6 n (extend3 2 y))] = [N3 y]). + rewrite <- (spec_extend6n n); auto. + try (rewrite <- spec_extend3n6; auto). + try rewrite spec_reduce_4; unfold to_Z; intros H1. + apply F4 with (3:=(wn_spec n))(4:=w4_spec)(5:=wn_spec n); auto with zarith. + rewrite (spec_zdigits w4_spec). + rewrite (spec_zdigits (wn_spec n)). + apply Zle_trans with (2 := F6 n). + change (znz_digits w6_op) with (xO (xO(znz_digits w4_op))). + repeat rewrite (fun x => Zpos_xO (xO x)). + repeat rewrite (fun x y => Zpos_xO (@znz_digits x y)). + assert (H: 0 <= Zpos (znz_digits w4_op)); auto with zarith. + change ([Nn n (extend6 n (extend4 1 y))] = [N4 y]). + rewrite <- (spec_extend6n n); auto. + try (rewrite <- spec_extend4n6; auto). + try rewrite spec_reduce_5; unfold to_Z; intros H1. + apply F4 with (3:=(wn_spec n))(4:=w5_spec)(5:=wn_spec n); auto with zarith. + rewrite (spec_zdigits w5_spec). + rewrite (spec_zdigits (wn_spec n)). + apply Zle_trans with (2 := F6 n). + change (znz_digits w6_op) with (xO(znz_digits w5_op)). + repeat rewrite (fun x => Zpos_xO (xO x)). + repeat rewrite (fun x y => Zpos_xO (@znz_digits x y)). + assert (H: 0 <= Zpos (znz_digits w5_op)); auto with zarith. + change ([Nn n (extend6 n (extend5 0 y))] = [N5 y]). + rewrite <- (spec_extend6n n); auto. + try (rewrite <- spec_extend5n6; auto). + try rewrite spec_reduce_6; unfold to_Z; intros H1. + apply F4 with (3:=(wn_spec n))(4:=w6_spec)(5:=wn_spec n); auto with zarith. + rewrite (spec_zdigits w6_spec). + rewrite (spec_zdigits (wn_spec n)). + apply Zle_trans with (2 := F6 n). + change (znz_digits w6_op) with (znz_digits w6_op). + repeat rewrite (fun x => Zpos_xO (xO x)). + repeat rewrite (fun x y => Zpos_xO (@znz_digits x y)). + assert (H: 0 <= Zpos (znz_digits w6_op)); auto with zarith. + change ([Nn n (extend6 n y)] = [N6 y]). + rewrite <- (spec_extend6n n); auto. + generalize y; clear y; intros m y. + rewrite spec_reduce_n; unfold to_Z; intros H1. + apply F4 with (3:=(wn_spec (Max.max n m)))(4:=wn_spec m)(5:=wn_spec n); auto with zarith. + rewrite (spec_zdigits (wn_spec m)). + rewrite (spec_zdigits (wn_spec (Max.max n m))). + apply F5; auto with arith. + exact (spec_cast_r n m y). + exact (spec_cast_l n m x). + Qed. + + Definition safe_shiftr n x := + match compare n (Ndigits x) with + | Lt => shiftr n x + | _ => N0 w_0 + end. + + Theorem spec_safe_shiftr: forall n x, + [safe_shiftr n x] = [x] / 2 ^ [n]. + Proof. + intros n x; unfold safe_shiftr; + generalize (spec_compare n (Ndigits x)); case compare; intros H. + apply trans_equal with (1 := spec_0 w0_spec). + apply sym_equal; apply Zdiv_small; rewrite H. + rewrite spec_Ndigits; exact (spec_digits x). + rewrite <- spec_shiftr; auto with zarith. + apply trans_equal with (1 := spec_0 w0_spec). + apply sym_equal; apply Zdiv_small. + rewrite spec_Ndigits in H; case (spec_digits x); intros H1 H2. + split; auto. + apply Zlt_le_trans with (1 := H2). + apply Zpower_le_monotone; auto with zarith. + Qed. + + + Definition shiftl0 n x := w0_op.(znz_add_mul_div) n x w0_op.(znz_0). + Definition shiftl1 n x := w1_op.(znz_add_mul_div) n x w1_op.(znz_0). + Definition shiftl2 n x := w2_op.(znz_add_mul_div) n x w2_op.(znz_0). + Definition shiftl3 n x := w3_op.(znz_add_mul_div) n x w3_op.(znz_0). + Definition shiftl4 n x := w4_op.(znz_add_mul_div) n x w4_op.(znz_0). + Definition shiftl5 n x := w5_op.(znz_add_mul_div) n x w5_op.(znz_0). + Definition shiftl6 n x := w6_op.(znz_add_mul_div) n x w6_op.(znz_0). + Definition shiftln n p x := (make_op n).(znz_add_mul_div) p x (make_op n).(znz_0). + Definition shiftl := Eval lazy beta delta [same_level] in + same_level _ (fun n x => N0 (shiftl0 n x)) + (fun n x => reduce_1 (shiftl1 n x)) + (fun n x => reduce_2 (shiftl2 n x)) + (fun n x => reduce_3 (shiftl3 n x)) + (fun n x => reduce_4 (shiftl4 n x)) + (fun n x => reduce_5 (shiftl5 n x)) + (fun n x => reduce_6 (shiftl6 n x)) + (fun n p x => reduce_n n (shiftln n p x)). + + + Theorem spec_shiftl: forall n x, + [n] <= [head0 x] -> [shiftl n x] = [x] * 2 ^ [n]. + Proof. + assert (F0: forall x y, x - (x - y) = y). + intros; ring. + assert (F2: forall x y z, 0 <= x -> 0 <= y -> x < z -> 0 <= x / 2 ^ y < z). + intros x y z HH HH1 HH2. + split; auto with zarith. + apply Zle_lt_trans with (2 := HH2); auto with zarith. + apply Zdiv_le_upper_bound; auto with zarith. + pattern x at 1; replace x with (x * 2 ^ 0); auto with zarith. + apply Zmult_le_compat_l; auto. + apply Zpower_le_monotone; auto with zarith. + rewrite Zpower_0_r; ring. + assert (F3: forall x y, 0 <= y -> y <= x -> 0 <= x - y < 2 ^ x). + intros xx y HH HH1. + split; auto with zarith. + apply Zle_lt_trans with xx; auto with zarith. + apply Zpower2_lt_lin; auto with zarith. + assert (F4: forall ww ww1 ww2 + (ww_op: znz_op ww) (ww1_op: znz_op ww1) (ww2_op: znz_op ww2) + xx yy xx1 yy1, + znz_to_Z ww2_op yy <= znz_to_Z ww1_op (znz_head0 ww1_op xx) -> + znz_to_Z ww1_op (znz_zdigits ww1_op) <= znz_to_Z ww_op (znz_zdigits ww_op) -> + znz_spec ww_op -> znz_spec ww1_op -> znz_spec ww2_op -> + znz_to_Z ww_op xx1 = znz_to_Z ww1_op xx -> + znz_to_Z ww_op yy1 = znz_to_Z ww2_op yy -> + znz_to_Z ww_op + (znz_add_mul_div ww_op yy1 + xx1 (znz_0 ww_op)) = znz_to_Z ww1_op xx * 2 ^ znz_to_Z ww2_op yy). + intros ww ww1 ww2 ww_op ww1_op ww2_op xx yy xx1 yy1 Hl Hl1 Hw Hw1 Hw2 Hx Hy. + case (spec_to_Z Hw xx1); auto with zarith; intros HH1 HH2. + case (spec_to_Z Hw yy1); auto with zarith; intros HH3 HH4. + rewrite <- Hx. + rewrite <- Hy. + generalize (spec_add_mul_div Hw xx1 (znz_0 ww_op) yy1). + rewrite (spec_0 Hw). + assert (F1: znz_to_Z ww1_op (znz_head0 ww1_op xx) <= Zpos (znz_digits ww1_op)). + case (Zle_lt_or_eq _ _ HH1); intros HH5. + apply Zlt_le_weak. + case (ZnZ.spec_head0 Hw1 xx). + rewrite <- Hx; auto. + intros _ Hu; unfold base in Hu. + case (Zle_or_lt (Zpos (znz_digits ww1_op)) + (znz_to_Z ww1_op (znz_head0 ww1_op xx))); auto; intros H1. + absurd (2 ^ (Zpos (znz_digits ww1_op)) <= 2 ^ (znz_to_Z ww1_op (znz_head0 ww1_op xx))). + apply Zlt_not_le. + case (spec_to_Z Hw1 xx); intros HHx3 HHx4. + rewrite <- (Zmult_1_r (2 ^ znz_to_Z ww1_op (znz_head0 ww1_op xx))). + apply Zle_lt_trans with (2 := Hu). + apply Zmult_le_compat_l; auto with zarith. + apply Zpower_le_monotone; auto with zarith. + rewrite (ZnZ.spec_head00 Hw1 xx); auto with zarith. + rewrite Zdiv_0_l; auto with zarith. + rewrite Zplus_0_r. + case (Zle_lt_or_eq _ _ HH1); intros HH5. + rewrite Zmod_small; auto with zarith. + intros HH; apply HH. + rewrite Hy; apply Zle_trans with (1:= Hl). + rewrite <- (spec_zdigits Hw). + apply Zle_trans with (2 := Hl1); auto. + rewrite (spec_zdigits Hw1); auto with zarith. + split; auto with zarith . + apply Zlt_le_trans with (base (znz_digits ww1_op)). + rewrite Hx. + case (ZnZ.spec_head0 Hw1 xx); auto. + rewrite <- Hx; auto. + intros _ Hu; rewrite Zmult_comm in Hu. + apply Zle_lt_trans with (2 := Hu). + apply Zmult_le_compat_l; auto with zarith. + apply Zpower_le_monotone; auto with zarith. + unfold base; apply Zpower_le_monotone; auto with zarith. + split; auto with zarith. + rewrite <- (spec_zdigits Hw); auto with zarith. + rewrite <- (spec_zdigits Hw1); auto with zarith. + rewrite <- HH5. + rewrite Zmult_0_l. + rewrite Zmod_small; auto with zarith. + intros HH; apply HH. + rewrite Hy; apply Zle_trans with (1 := Hl). + rewrite (ZnZ.spec_head00 Hw1 xx); auto with zarith. + rewrite <- (spec_zdigits Hw); auto with zarith. + rewrite <- (spec_zdigits Hw1); auto with zarith. + assert (F5: forall n m, (n <= m)%nat -> + Zpos (znz_digits (make_op n)) <= Zpos (znz_digits (make_op m))). + intros n m HH; elim HH; clear m HH; auto with zarith. + intros m HH Hrec; apply Zle_trans with (1 := Hrec). + rewrite make_op_S. + match goal with |- Zpos ?Y <= ?X => change X with (Zpos (xO Y)) end. + rewrite Zpos_xO. + assert (0 <= Zpos (znz_digits (make_op n))); auto with zarith. + assert (F6: forall n, Zpos (znz_digits w6_op) <= Zpos (znz_digits (make_op n))). + intros n ; apply Zle_trans with (Zpos (znz_digits (make_op 0))). + change (znz_digits (make_op 0)) with (xO (znz_digits w6_op)). + rewrite Zpos_xO. + assert (0 <= Zpos (znz_digits w6_op)); auto with zarith. + apply F5; auto with arith. + intros x; case x; clear x; unfold shiftl, same_level. + intros x y; case y; clear y. + intros y; unfold shiftl0, head0. + repeat rewrite spec_reduce_0; unfold to_Z; intros H1. + apply F4 with (3:=w0_spec)(4:=w0_spec)(5:=w0_spec); auto with zarith. + intros y; unfold shiftl1, head0. + repeat rewrite spec_reduce_0; repeat rewrite spec_reduce_1; unfold to_Z; intros H1. + apply F4 with (3:=w1_spec)(4:=w1_spec)(5:=w0_spec); auto with zarith. + try (apply sym_equal; exact (spec_extend0n1 x)). + intros y; unfold shiftl2, head0. + repeat rewrite spec_reduce_0; repeat rewrite spec_reduce_2; unfold to_Z; intros H1. + apply F4 with (3:=w2_spec)(4:=w2_spec)(5:=w0_spec); auto with zarith. + try (apply sym_equal; exact (spec_extend0n2 x)). + intros y; unfold shiftl3, head0. + repeat rewrite spec_reduce_0; repeat rewrite spec_reduce_3; unfold to_Z; intros H1. + apply F4 with (3:=w3_spec)(4:=w3_spec)(5:=w0_spec); auto with zarith. + try (apply sym_equal; exact (spec_extend0n3 x)). + intros y; unfold shiftl4, head0. + repeat rewrite spec_reduce_0; repeat rewrite spec_reduce_4; unfold to_Z; intros H1. + apply F4 with (3:=w4_spec)(4:=w4_spec)(5:=w0_spec); auto with zarith. + try (apply sym_equal; exact (spec_extend0n4 x)). + intros y; unfold shiftl5, head0. + repeat rewrite spec_reduce_0; repeat rewrite spec_reduce_5; unfold to_Z; intros H1. + apply F4 with (3:=w5_spec)(4:=w5_spec)(5:=w0_spec); auto with zarith. + try (apply sym_equal; exact (spec_extend0n5 x)). + intros y; unfold shiftl6, head0. + repeat rewrite spec_reduce_0; repeat rewrite spec_reduce_6; unfold to_Z; intros H1. + apply F4 with (3:=w6_spec)(4:=w6_spec)(5:=w0_spec); auto with zarith. + try (apply sym_equal; exact (spec_extend0n6 x)). + intros m y; unfold shiftln, head0. + repeat rewrite spec_reduce_n; unfold to_Z; intros H1. + apply F4 with (3:=(wn_spec m))(4:=wn_spec m)(5:=w0_spec); auto with zarith. + change ([Nn m (extend6 m (extend0 5 x))] = [N0 x]). + rewrite <- (spec_extend6n m); rewrite <- spec_extend0n6; auto. + intros x y; case y; clear y. + intros y; unfold shiftl1, head0. + repeat rewrite spec_reduce_1; repeat rewrite spec_reduce_0; unfold to_Z; intros H1. + apply F4 with (3:=w1_spec)(4:=w0_spec)(5:=w1_spec); auto with zarith. + rewrite (spec_zdigits w1_spec). + rewrite (spec_zdigits w0_spec). + change (znz_digits w1_op) with (xO (znz_digits w0_op)). + repeat rewrite (fun x => Zpos_xO (xO x)). + repeat rewrite (fun x y => Zpos_xO (@znz_digits x y)). + assert (0 <= Zpos (znz_digits w0_op)); auto with zarith. + try (apply sym_equal; exact (spec_extend0n1 y)). + intros y; unfold shiftl1, head0. + repeat rewrite spec_reduce_1; unfold to_Z; intros H1. + apply F4 with (3:=w1_spec)(4:=w1_spec)(5:=w1_spec); auto with zarith. + intros y; unfold shiftl2, head0. + repeat rewrite spec_reduce_1; repeat rewrite spec_reduce_2; unfold to_Z; intros H1. + apply F4 with (3:=w2_spec)(4:=w2_spec)(5:=w1_spec); auto with zarith. + try (apply sym_equal; exact (spec_extend1n2 x)). + intros y; unfold shiftl3, head0. + repeat rewrite spec_reduce_1; repeat rewrite spec_reduce_3; unfold to_Z; intros H1. + apply F4 with (3:=w3_spec)(4:=w3_spec)(5:=w1_spec); auto with zarith. + try (apply sym_equal; exact (spec_extend1n3 x)). + intros y; unfold shiftl4, head0. + repeat rewrite spec_reduce_1; repeat rewrite spec_reduce_4; unfold to_Z; intros H1. + apply F4 with (3:=w4_spec)(4:=w4_spec)(5:=w1_spec); auto with zarith. + try (apply sym_equal; exact (spec_extend1n4 x)). + intros y; unfold shiftl5, head0. + repeat rewrite spec_reduce_1; repeat rewrite spec_reduce_5; unfold to_Z; intros H1. + apply F4 with (3:=w5_spec)(4:=w5_spec)(5:=w1_spec); auto with zarith. + try (apply sym_equal; exact (spec_extend1n5 x)). + intros y; unfold shiftl6, head0. + repeat rewrite spec_reduce_1; repeat rewrite spec_reduce_6; unfold to_Z; intros H1. + apply F4 with (3:=w6_spec)(4:=w6_spec)(5:=w1_spec); auto with zarith. + try (apply sym_equal; exact (spec_extend1n6 x)). + intros m y; unfold shiftln, head0. + repeat rewrite spec_reduce_n; unfold to_Z; intros H1. + apply F4 with (3:=(wn_spec m))(4:=wn_spec m)(5:=w1_spec); auto with zarith. + change ([Nn m (extend6 m (extend1 4 x))] = [N1 x]). + rewrite <- (spec_extend6n m); rewrite <- spec_extend1n6; auto. + intros x y; case y; clear y. + intros y; unfold shiftl2, head0. + repeat rewrite spec_reduce_2; repeat rewrite spec_reduce_0; unfold to_Z; intros H1. + apply F4 with (3:=w2_spec)(4:=w0_spec)(5:=w2_spec); auto with zarith. + rewrite (spec_zdigits w2_spec). + rewrite (spec_zdigits w0_spec). + change (znz_digits w2_op) with (xO (xO (znz_digits w0_op))). + repeat rewrite (fun x => Zpos_xO (xO x)). + repeat rewrite (fun x y => Zpos_xO (@znz_digits x y)). + assert (0 <= Zpos (znz_digits w0_op)); auto with zarith. + try (apply sym_equal; exact (spec_extend0n2 y)). + intros y; unfold shiftl2, head0. + repeat rewrite spec_reduce_2; repeat rewrite spec_reduce_1; unfold to_Z; intros H1. + apply F4 with (3:=w2_spec)(4:=w1_spec)(5:=w2_spec); auto with zarith. + rewrite (spec_zdigits w2_spec). + rewrite (spec_zdigits w1_spec). + change (znz_digits w2_op) with (xO (znz_digits w1_op)). + repeat rewrite (fun x => Zpos_xO (xO x)). + repeat rewrite (fun x y => Zpos_xO (@znz_digits x y)). + assert (0 <= Zpos (znz_digits w1_op)); auto with zarith. + try (apply sym_equal; exact (spec_extend1n2 y)). + intros y; unfold shiftl2, head0. + repeat rewrite spec_reduce_2; unfold to_Z; intros H1. + apply F4 with (3:=w2_spec)(4:=w2_spec)(5:=w2_spec); auto with zarith. + intros y; unfold shiftl3, head0. + repeat rewrite spec_reduce_2; repeat rewrite spec_reduce_3; unfold to_Z; intros H1. + apply F4 with (3:=w3_spec)(4:=w3_spec)(5:=w2_spec); auto with zarith. + try (apply sym_equal; exact (spec_extend2n3 x)). + intros y; unfold shiftl4, head0. + repeat rewrite spec_reduce_2; repeat rewrite spec_reduce_4; unfold to_Z; intros H1. + apply F4 with (3:=w4_spec)(4:=w4_spec)(5:=w2_spec); auto with zarith. + try (apply sym_equal; exact (spec_extend2n4 x)). + intros y; unfold shiftl5, head0. + repeat rewrite spec_reduce_2; repeat rewrite spec_reduce_5; unfold to_Z; intros H1. + apply F4 with (3:=w5_spec)(4:=w5_spec)(5:=w2_spec); auto with zarith. + try (apply sym_equal; exact (spec_extend2n5 x)). + intros y; unfold shiftl6, head0. + repeat rewrite spec_reduce_2; repeat rewrite spec_reduce_6; unfold to_Z; intros H1. + apply F4 with (3:=w6_spec)(4:=w6_spec)(5:=w2_spec); auto with zarith. + try (apply sym_equal; exact (spec_extend2n6 x)). + intros m y; unfold shiftln, head0. + repeat rewrite spec_reduce_n; unfold to_Z; intros H1. + apply F4 with (3:=(wn_spec m))(4:=wn_spec m)(5:=w2_spec); auto with zarith. + change ([Nn m (extend6 m (extend2 3 x))] = [N2 x]). + rewrite <- (spec_extend6n m); rewrite <- spec_extend2n6; auto. + intros x y; case y; clear y. + intros y; unfold shiftl3, head0. + repeat rewrite spec_reduce_3; repeat rewrite spec_reduce_0; unfold to_Z; intros H1. + apply F4 with (3:=w3_spec)(4:=w0_spec)(5:=w3_spec); auto with zarith. + rewrite (spec_zdigits w3_spec). + rewrite (spec_zdigits w0_spec). + change (znz_digits w3_op) with (xO (xO (xO (znz_digits w0_op)))). + repeat rewrite (fun x => Zpos_xO (xO x)). + repeat rewrite (fun x y => Zpos_xO (@znz_digits x y)). + assert (0 <= Zpos (znz_digits w0_op)); auto with zarith. + try (apply sym_equal; exact (spec_extend0n3 y)). + intros y; unfold shiftl3, head0. + repeat rewrite spec_reduce_3; repeat rewrite spec_reduce_1; unfold to_Z; intros H1. + apply F4 with (3:=w3_spec)(4:=w1_spec)(5:=w3_spec); auto with zarith. + rewrite (spec_zdigits w3_spec). + rewrite (spec_zdigits w1_spec). + change (znz_digits w3_op) with (xO (xO (znz_digits w1_op))). + repeat rewrite (fun x => Zpos_xO (xO x)). + repeat rewrite (fun x y => Zpos_xO (@znz_digits x y)). + assert (0 <= Zpos (znz_digits w1_op)); auto with zarith. + try (apply sym_equal; exact (spec_extend1n3 y)). + intros y; unfold shiftl3, head0. + repeat rewrite spec_reduce_3; repeat rewrite spec_reduce_2; unfold to_Z; intros H1. + apply F4 with (3:=w3_spec)(4:=w2_spec)(5:=w3_spec); auto with zarith. + rewrite (spec_zdigits w3_spec). + rewrite (spec_zdigits w2_spec). + change (znz_digits w3_op) with (xO (znz_digits w2_op)). + repeat rewrite (fun x => Zpos_xO (xO x)). + repeat rewrite (fun x y => Zpos_xO (@znz_digits x y)). + assert (0 <= Zpos (znz_digits w2_op)); auto with zarith. + try (apply sym_equal; exact (spec_extend2n3 y)). + intros y; unfold shiftl3, head0. + repeat rewrite spec_reduce_3; unfold to_Z; intros H1. + apply F4 with (3:=w3_spec)(4:=w3_spec)(5:=w3_spec); auto with zarith. + intros y; unfold shiftl4, head0. + repeat rewrite spec_reduce_3; repeat rewrite spec_reduce_4; unfold to_Z; intros H1. + apply F4 with (3:=w4_spec)(4:=w4_spec)(5:=w3_spec); auto with zarith. + try (apply sym_equal; exact (spec_extend3n4 x)). + intros y; unfold shiftl5, head0. + repeat rewrite spec_reduce_3; repeat rewrite spec_reduce_5; unfold to_Z; intros H1. + apply F4 with (3:=w5_spec)(4:=w5_spec)(5:=w3_spec); auto with zarith. + try (apply sym_equal; exact (spec_extend3n5 x)). + intros y; unfold shiftl6, head0. + repeat rewrite spec_reduce_3; repeat rewrite spec_reduce_6; unfold to_Z; intros H1. + apply F4 with (3:=w6_spec)(4:=w6_spec)(5:=w3_spec); auto with zarith. + try (apply sym_equal; exact (spec_extend3n6 x)). + intros m y; unfold shiftln, head0. + repeat rewrite spec_reduce_n; unfold to_Z; intros H1. + apply F4 with (3:=(wn_spec m))(4:=wn_spec m)(5:=w3_spec); auto with zarith. + change ([Nn m (extend6 m (extend3 2 x))] = [N3 x]). + rewrite <- (spec_extend6n m); rewrite <- spec_extend3n6; auto. + intros x y; case y; clear y. + intros y; unfold shiftl4, head0. + repeat rewrite spec_reduce_4; repeat rewrite spec_reduce_0; unfold to_Z; intros H1. + apply F4 with (3:=w4_spec)(4:=w0_spec)(5:=w4_spec); auto with zarith. + rewrite (spec_zdigits w4_spec). + rewrite (spec_zdigits w0_spec). + change (znz_digits w4_op) with (xO (xO (xO (xO (znz_digits w0_op))))). + repeat rewrite (fun x => Zpos_xO (xO x)). + repeat rewrite (fun x y => Zpos_xO (@znz_digits x y)). + assert (0 <= Zpos (znz_digits w0_op)); auto with zarith. + try (apply sym_equal; exact (spec_extend0n4 y)). + intros y; unfold shiftl4, head0. + repeat rewrite spec_reduce_4; repeat rewrite spec_reduce_1; unfold to_Z; intros H1. + apply F4 with (3:=w4_spec)(4:=w1_spec)(5:=w4_spec); auto with zarith. + rewrite (spec_zdigits w4_spec). + rewrite (spec_zdigits w1_spec). + change (znz_digits w4_op) with (xO (xO (xO (znz_digits w1_op)))). + repeat rewrite (fun x => Zpos_xO (xO x)). + repeat rewrite (fun x y => Zpos_xO (@znz_digits x y)). + assert (0 <= Zpos (znz_digits w1_op)); auto with zarith. + try (apply sym_equal; exact (spec_extend1n4 y)). + intros y; unfold shiftl4, head0. + repeat rewrite spec_reduce_4; repeat rewrite spec_reduce_2; unfold to_Z; intros H1. + apply F4 with (3:=w4_spec)(4:=w2_spec)(5:=w4_spec); auto with zarith. + rewrite (spec_zdigits w4_spec). + rewrite (spec_zdigits w2_spec). + change (znz_digits w4_op) with (xO (xO (znz_digits w2_op))). + repeat rewrite (fun x => Zpos_xO (xO x)). + repeat rewrite (fun x y => Zpos_xO (@znz_digits x y)). + assert (0 <= Zpos (znz_digits w2_op)); auto with zarith. + try (apply sym_equal; exact (spec_extend2n4 y)). + intros y; unfold shiftl4, head0. + repeat rewrite spec_reduce_4; repeat rewrite spec_reduce_3; unfold to_Z; intros H1. + apply F4 with (3:=w4_spec)(4:=w3_spec)(5:=w4_spec); auto with zarith. + rewrite (spec_zdigits w4_spec). + rewrite (spec_zdigits w3_spec). + change (znz_digits w4_op) with (xO (znz_digits w3_op)). + repeat rewrite (fun x => Zpos_xO (xO x)). + repeat rewrite (fun x y => Zpos_xO (@znz_digits x y)). + assert (0 <= Zpos (znz_digits w3_op)); auto with zarith. + try (apply sym_equal; exact (spec_extend3n4 y)). + intros y; unfold shiftl4, head0. + repeat rewrite spec_reduce_4; unfold to_Z; intros H1. + apply F4 with (3:=w4_spec)(4:=w4_spec)(5:=w4_spec); auto with zarith. + intros y; unfold shiftl5, head0. + repeat rewrite spec_reduce_4; repeat rewrite spec_reduce_5; unfold to_Z; intros H1. + apply F4 with (3:=w5_spec)(4:=w5_spec)(5:=w4_spec); auto with zarith. + try (apply sym_equal; exact (spec_extend4n5 x)). + intros y; unfold shiftl6, head0. + repeat rewrite spec_reduce_4; repeat rewrite spec_reduce_6; unfold to_Z; intros H1. + apply F4 with (3:=w6_spec)(4:=w6_spec)(5:=w4_spec); auto with zarith. + try (apply sym_equal; exact (spec_extend4n6 x)). + intros m y; unfold shiftln, head0. + repeat rewrite spec_reduce_n; unfold to_Z; intros H1. + apply F4 with (3:=(wn_spec m))(4:=wn_spec m)(5:=w4_spec); auto with zarith. + change ([Nn m (extend6 m (extend4 1 x))] = [N4 x]). + rewrite <- (spec_extend6n m); rewrite <- spec_extend4n6; auto. + intros x y; case y; clear y. + intros y; unfold shiftl5, head0. + repeat rewrite spec_reduce_5; repeat rewrite spec_reduce_0; unfold to_Z; intros H1. + apply F4 with (3:=w5_spec)(4:=w0_spec)(5:=w5_spec); auto with zarith. + rewrite (spec_zdigits w5_spec). + rewrite (spec_zdigits w0_spec). + change (znz_digits w5_op) with (xO (xO (xO (xO (xO (znz_digits w0_op)))))). + repeat rewrite (fun x => Zpos_xO (xO x)). + repeat rewrite (fun x y => Zpos_xO (@znz_digits x y)). + assert (0 <= Zpos (znz_digits w0_op)); auto with zarith. + try (apply sym_equal; exact (spec_extend0n5 y)). + intros y; unfold shiftl5, head0. + repeat rewrite spec_reduce_5; repeat rewrite spec_reduce_1; unfold to_Z; intros H1. + apply F4 with (3:=w5_spec)(4:=w1_spec)(5:=w5_spec); auto with zarith. + rewrite (spec_zdigits w5_spec). + rewrite (spec_zdigits w1_spec). + change (znz_digits w5_op) with (xO (xO (xO (xO (znz_digits w1_op))))). + repeat rewrite (fun x => Zpos_xO (xO x)). + repeat rewrite (fun x y => Zpos_xO (@znz_digits x y)). + assert (0 <= Zpos (znz_digits w1_op)); auto with zarith. + try (apply sym_equal; exact (spec_extend1n5 y)). + intros y; unfold shiftl5, head0. + repeat rewrite spec_reduce_5; repeat rewrite spec_reduce_2; unfold to_Z; intros H1. + apply F4 with (3:=w5_spec)(4:=w2_spec)(5:=w5_spec); auto with zarith. + rewrite (spec_zdigits w5_spec). + rewrite (spec_zdigits w2_spec). + change (znz_digits w5_op) with (xO (xO (xO (znz_digits w2_op)))). + repeat rewrite (fun x => Zpos_xO (xO x)). + repeat rewrite (fun x y => Zpos_xO (@znz_digits x y)). + assert (0 <= Zpos (znz_digits w2_op)); auto with zarith. + try (apply sym_equal; exact (spec_extend2n5 y)). + intros y; unfold shiftl5, head0. + repeat rewrite spec_reduce_5; repeat rewrite spec_reduce_3; unfold to_Z; intros H1. + apply F4 with (3:=w5_spec)(4:=w3_spec)(5:=w5_spec); auto with zarith. + rewrite (spec_zdigits w5_spec). + rewrite (spec_zdigits w3_spec). + change (znz_digits w5_op) with (xO (xO (znz_digits w3_op))). + repeat rewrite (fun x => Zpos_xO (xO x)). + repeat rewrite (fun x y => Zpos_xO (@znz_digits x y)). + assert (0 <= Zpos (znz_digits w3_op)); auto with zarith. + try (apply sym_equal; exact (spec_extend3n5 y)). + intros y; unfold shiftl5, head0. + repeat rewrite spec_reduce_5; repeat rewrite spec_reduce_4; unfold to_Z; intros H1. + apply F4 with (3:=w5_spec)(4:=w4_spec)(5:=w5_spec); auto with zarith. + rewrite (spec_zdigits w5_spec). + rewrite (spec_zdigits w4_spec). + change (znz_digits w5_op) with (xO (znz_digits w4_op)). + repeat rewrite (fun x => Zpos_xO (xO x)). + repeat rewrite (fun x y => Zpos_xO (@znz_digits x y)). + assert (0 <= Zpos (znz_digits w4_op)); auto with zarith. + try (apply sym_equal; exact (spec_extend4n5 y)). + intros y; unfold shiftl5, head0. + repeat rewrite spec_reduce_5; unfold to_Z; intros H1. + apply F4 with (3:=w5_spec)(4:=w5_spec)(5:=w5_spec); auto with zarith. + intros y; unfold shiftl6, head0. + repeat rewrite spec_reduce_5; repeat rewrite spec_reduce_6; unfold to_Z; intros H1. + apply F4 with (3:=w6_spec)(4:=w6_spec)(5:=w5_spec); auto with zarith. + try (apply sym_equal; exact (spec_extend5n6 x)). + intros m y; unfold shiftln, head0. + repeat rewrite spec_reduce_n; unfold to_Z; intros H1. + apply F4 with (3:=(wn_spec m))(4:=wn_spec m)(5:=w5_spec); auto with zarith. + change ([Nn m (extend6 m (extend5 0 x))] = [N5 x]). + rewrite <- (spec_extend6n m); rewrite <- spec_extend5n6; auto. + intros x y; case y; clear y. + intros y; unfold shiftl6, head0. + repeat rewrite spec_reduce_6; repeat rewrite spec_reduce_0; unfold to_Z; intros H1. + apply F4 with (3:=w6_spec)(4:=w0_spec)(5:=w6_spec); auto with zarith. + rewrite (spec_zdigits w6_spec). + rewrite (spec_zdigits w0_spec). + change (znz_digits w6_op) with (xO (xO (xO (xO (xO (xO (znz_digits w0_op))))))). + repeat rewrite (fun x => Zpos_xO (xO x)). + repeat rewrite (fun x y => Zpos_xO (@znz_digits x y)). + assert (0 <= Zpos (znz_digits w0_op)); auto with zarith. + try (apply sym_equal; exact (spec_extend0n6 y)). + intros y; unfold shiftl6, head0. + repeat rewrite spec_reduce_6; repeat rewrite spec_reduce_1; unfold to_Z; intros H1. + apply F4 with (3:=w6_spec)(4:=w1_spec)(5:=w6_spec); auto with zarith. + rewrite (spec_zdigits w6_spec). + rewrite (spec_zdigits w1_spec). + change (znz_digits w6_op) with (xO (xO (xO (xO (xO (znz_digits w1_op)))))). + repeat rewrite (fun x => Zpos_xO (xO x)). + repeat rewrite (fun x y => Zpos_xO (@znz_digits x y)). + assert (0 <= Zpos (znz_digits w1_op)); auto with zarith. + try (apply sym_equal; exact (spec_extend1n6 y)). + intros y; unfold shiftl6, head0. + repeat rewrite spec_reduce_6; repeat rewrite spec_reduce_2; unfold to_Z; intros H1. + apply F4 with (3:=w6_spec)(4:=w2_spec)(5:=w6_spec); auto with zarith. + rewrite (spec_zdigits w6_spec). + rewrite (spec_zdigits w2_spec). + change (znz_digits w6_op) with (xO (xO (xO (xO (znz_digits w2_op))))). + repeat rewrite (fun x => Zpos_xO (xO x)). + repeat rewrite (fun x y => Zpos_xO (@znz_digits x y)). + assert (0 <= Zpos (znz_digits w2_op)); auto with zarith. + try (apply sym_equal; exact (spec_extend2n6 y)). + intros y; unfold shiftl6, head0. + repeat rewrite spec_reduce_6; repeat rewrite spec_reduce_3; unfold to_Z; intros H1. + apply F4 with (3:=w6_spec)(4:=w3_spec)(5:=w6_spec); auto with zarith. + rewrite (spec_zdigits w6_spec). + rewrite (spec_zdigits w3_spec). + change (znz_digits w6_op) with (xO (xO (xO (znz_digits w3_op)))). + repeat rewrite (fun x => Zpos_xO (xO x)). + repeat rewrite (fun x y => Zpos_xO (@znz_digits x y)). + assert (0 <= Zpos (znz_digits w3_op)); auto with zarith. + try (apply sym_equal; exact (spec_extend3n6 y)). + intros y; unfold shiftl6, head0. + repeat rewrite spec_reduce_6; repeat rewrite spec_reduce_4; unfold to_Z; intros H1. + apply F4 with (3:=w6_spec)(4:=w4_spec)(5:=w6_spec); auto with zarith. + rewrite (spec_zdigits w6_spec). + rewrite (spec_zdigits w4_spec). + change (znz_digits w6_op) with (xO (xO (znz_digits w4_op))). + repeat rewrite (fun x => Zpos_xO (xO x)). + repeat rewrite (fun x y => Zpos_xO (@znz_digits x y)). + assert (0 <= Zpos (znz_digits w4_op)); auto with zarith. + try (apply sym_equal; exact (spec_extend4n6 y)). + intros y; unfold shiftl6, head0. + repeat rewrite spec_reduce_6; repeat rewrite spec_reduce_5; unfold to_Z; intros H1. + apply F4 with (3:=w6_spec)(4:=w5_spec)(5:=w6_spec); auto with zarith. + rewrite (spec_zdigits w6_spec). + rewrite (spec_zdigits w5_spec). + change (znz_digits w6_op) with (xO (znz_digits w5_op)). + repeat rewrite (fun x => Zpos_xO (xO x)). + repeat rewrite (fun x y => Zpos_xO (@znz_digits x y)). + assert (0 <= Zpos (znz_digits w5_op)); auto with zarith. + try (apply sym_equal; exact (spec_extend5n6 y)). + intros y; unfold shiftl6, head0. + repeat rewrite spec_reduce_6; unfold to_Z; intros H1. + apply F4 with (3:=w6_spec)(4:=w6_spec)(5:=w6_spec); auto with zarith. + intros m y; unfold shiftln, head0. + repeat rewrite spec_reduce_n; unfold to_Z; intros H1. + apply F4 with (3:=(wn_spec m))(4:=wn_spec m)(5:=w6_spec); auto with zarith. + try (apply sym_equal; exact (spec_extend6n m x)). + intros n x y; case y; clear y; + intros y; unfold shiftln, head0; try rewrite spec_reduce_n. + try rewrite spec_reduce_0; unfold to_Z; intros H1. + apply F4 with (3:=(wn_spec n))(4:=w0_spec)(5:=wn_spec n); auto with zarith. + rewrite (spec_zdigits w0_spec). + rewrite (spec_zdigits (wn_spec n)). + apply Zle_trans with (2 := F6 n). + change (znz_digits w6_op) with (xO (xO (xO (xO (xO (xO(znz_digits w0_op))))))). + repeat rewrite (fun x => Zpos_xO (xO x)). + repeat rewrite (fun x y => Zpos_xO (@znz_digits x y)). + assert (H: 0 <= Zpos (znz_digits w0_op)); auto with zarith. + change ([Nn n (extend6 n (extend0 5 y))] = [N0 y]). + rewrite <- (spec_extend6n n); auto. + try (rewrite <- spec_extend0n6; auto). + try rewrite spec_reduce_1; unfold to_Z; intros H1. + apply F4 with (3:=(wn_spec n))(4:=w1_spec)(5:=wn_spec n); auto with zarith. + rewrite (spec_zdigits w1_spec). + rewrite (spec_zdigits (wn_spec n)). + apply Zle_trans with (2 := F6 n). + change (znz_digits w6_op) with (xO (xO (xO (xO (xO(znz_digits w1_op)))))). + repeat rewrite (fun x => Zpos_xO (xO x)). + repeat rewrite (fun x y => Zpos_xO (@znz_digits x y)). + assert (H: 0 <= Zpos (znz_digits w1_op)); auto with zarith. + change ([Nn n (extend6 n (extend1 4 y))] = [N1 y]). + rewrite <- (spec_extend6n n); auto. + try (rewrite <- spec_extend1n6; auto). + try rewrite spec_reduce_2; unfold to_Z; intros H1. + apply F4 with (3:=(wn_spec n))(4:=w2_spec)(5:=wn_spec n); auto with zarith. + rewrite (spec_zdigits w2_spec). + rewrite (spec_zdigits (wn_spec n)). + apply Zle_trans with (2 := F6 n). + change (znz_digits w6_op) with (xO (xO (xO (xO(znz_digits w2_op))))). + repeat rewrite (fun x => Zpos_xO (xO x)). + repeat rewrite (fun x y => Zpos_xO (@znz_digits x y)). + assert (H: 0 <= Zpos (znz_digits w2_op)); auto with zarith. + change ([Nn n (extend6 n (extend2 3 y))] = [N2 y]). + rewrite <- (spec_extend6n n); auto. + try (rewrite <- spec_extend2n6; auto). + try rewrite spec_reduce_3; unfold to_Z; intros H1. + apply F4 with (3:=(wn_spec n))(4:=w3_spec)(5:=wn_spec n); auto with zarith. + rewrite (spec_zdigits w3_spec). + rewrite (spec_zdigits (wn_spec n)). + apply Zle_trans with (2 := F6 n). + change (znz_digits w6_op) with (xO (xO (xO(znz_digits w3_op)))). + repeat rewrite (fun x => Zpos_xO (xO x)). + repeat rewrite (fun x y => Zpos_xO (@znz_digits x y)). + assert (H: 0 <= Zpos (znz_digits w3_op)); auto with zarith. + change ([Nn n (extend6 n (extend3 2 y))] = [N3 y]). + rewrite <- (spec_extend6n n); auto. + try (rewrite <- spec_extend3n6; auto). + try rewrite spec_reduce_4; unfold to_Z; intros H1. + apply F4 with (3:=(wn_spec n))(4:=w4_spec)(5:=wn_spec n); auto with zarith. + rewrite (spec_zdigits w4_spec). + rewrite (spec_zdigits (wn_spec n)). + apply Zle_trans with (2 := F6 n). + change (znz_digits w6_op) with (xO (xO(znz_digits w4_op))). + repeat rewrite (fun x => Zpos_xO (xO x)). + repeat rewrite (fun x y => Zpos_xO (@znz_digits x y)). + assert (H: 0 <= Zpos (znz_digits w4_op)); auto with zarith. + change ([Nn n (extend6 n (extend4 1 y))] = [N4 y]). + rewrite <- (spec_extend6n n); auto. + try (rewrite <- spec_extend4n6; auto). + try rewrite spec_reduce_5; unfold to_Z; intros H1. + apply F4 with (3:=(wn_spec n))(4:=w5_spec)(5:=wn_spec n); auto with zarith. + rewrite (spec_zdigits w5_spec). + rewrite (spec_zdigits (wn_spec n)). + apply Zle_trans with (2 := F6 n). + change (znz_digits w6_op) with (xO(znz_digits w5_op)). + repeat rewrite (fun x => Zpos_xO (xO x)). + repeat rewrite (fun x y => Zpos_xO (@znz_digits x y)). + assert (H: 0 <= Zpos (znz_digits w5_op)); auto with zarith. + change ([Nn n (extend6 n (extend5 0 y))] = [N5 y]). + rewrite <- (spec_extend6n n); auto. + try (rewrite <- spec_extend5n6; auto). + try rewrite spec_reduce_6; unfold to_Z; intros H1. + apply F4 with (3:=(wn_spec n))(4:=w6_spec)(5:=wn_spec n); auto with zarith. + rewrite (spec_zdigits w6_spec). + rewrite (spec_zdigits (wn_spec n)). + apply Zle_trans with (2 := F6 n). + change (znz_digits w6_op) with (znz_digits w6_op). + repeat rewrite (fun x => Zpos_xO (xO x)). + repeat rewrite (fun x y => Zpos_xO (@znz_digits x y)). + assert (H: 0 <= Zpos (znz_digits w6_op)); auto with zarith. + change ([Nn n (extend6 n y)] = [N6 y]). + rewrite <- (spec_extend6n n); auto. + generalize y; clear y; intros m y. + repeat rewrite spec_reduce_n; unfold to_Z; intros H1. + apply F4 with (3:=(wn_spec (Max.max n m)))(4:=wn_spec m)(5:=wn_spec n); auto with zarith. + rewrite (spec_zdigits (wn_spec m)). + rewrite (spec_zdigits (wn_spec (Max.max n m))). + apply F5; auto with arith. + exact (spec_cast_r n m y). + exact (spec_cast_l n m x). + Qed. + + Definition double_size w := match w with + | N0 x => N1 (WW (znz_0 w0_op) x) + | N1 x => N2 (WW (znz_0 w1_op) x) + | N2 x => N3 (WW (znz_0 w2_op) x) + | N3 x => N4 (WW (znz_0 w3_op) x) + | N4 x => N5 (WW (znz_0 w4_op) x) + | N5 x => N6 (WW (znz_0 w5_op) x) + | N6 x => Nn 0 (WW (znz_0 w6_op) x) + | Nn n x => Nn (S n) (WW (znz_0 (make_op n)) x) + end. + + Theorem spec_double_size_digits: + forall x, digits (double_size x) = xO (digits x). + Proof. + intros x; case x; unfold double_size, digits; clear x; auto. + intros n x; rewrite make_op_S; auto. + Qed. + + Theorem spec_double_size: forall x, [double_size x] = [x]. + Proof. + intros x; case x; unfold double_size; clear x. + intros x; unfold to_Z, make_op; + rewrite znz_to_Z_1; rewrite (spec_0 w0_spec); auto with zarith. + intros x; unfold to_Z, make_op; + rewrite znz_to_Z_2; rewrite (spec_0 w1_spec); auto with zarith. + intros x; unfold to_Z, make_op; + rewrite znz_to_Z_3; rewrite (spec_0 w2_spec); auto with zarith. + intros x; unfold to_Z, make_op; + rewrite znz_to_Z_4; rewrite (spec_0 w3_spec); auto with zarith. + intros x; unfold to_Z, make_op; + rewrite znz_to_Z_5; rewrite (spec_0 w4_spec); auto with zarith. + intros x; unfold to_Z, make_op; + rewrite znz_to_Z_6; rewrite (spec_0 w5_spec); auto with zarith. + intros x; unfold to_Z, make_op; + rewrite znz_to_Z_7; rewrite (spec_0 w6_spec); auto with zarith. + intros n x; unfold to_Z; + generalize (znz_to_Z_n n); simpl word. + intros HH; rewrite HH; clear HH. + generalize (spec_0 (wn_spec n)); simpl word. + intros HH; rewrite HH; clear HH; auto with zarith. + Qed. + + Theorem spec_double_size_head0: + forall x, 2 * [head0 x] <= [head0 (double_size x)]. + Proof. + intros x. + assert (F1:= spec_pos (head0 x)). + assert (F2: 0 < Zpos (digits x)). + red; auto. + case (Zle_lt_or_eq _ _ (spec_pos x)); intros HH. + generalize HH; rewrite <- (spec_double_size x); intros HH1. + case (spec_head0 x HH); intros _ HH2. + case (spec_head0 _ HH1). + rewrite (spec_double_size x); rewrite (spec_double_size_digits x). + intros HH3 _. + case (Zle_or_lt ([head0 (double_size x)]) (2 * [head0 x])); auto; intros HH4. + absurd (2 ^ (2 * [head0 x] )* [x] < 2 ^ [head0 (double_size x)] * [x]); auto. + apply Zle_not_lt. + apply Zmult_le_compat_r; auto with zarith. + apply Zpower_le_monotone; auto; auto with zarith. + generalize (spec_pos (head0 (double_size x))); auto with zarith. + assert (HH5: 2 ^[head0 x] <= 2 ^(Zpos (digits x) - 1)). + case (Zle_lt_or_eq 1 [x]); auto with zarith; intros HH5. + apply Zmult_le_reg_r with (2 ^ 1); auto with zarith. + rewrite <- (fun x y z => Zpower_exp x (y - z)); auto with zarith. + assert (tmp: forall x, x - 1 + 1 = x); [intros; ring | rewrite tmp; clear tmp]. + apply Zle_trans with (2 := Zlt_le_weak _ _ HH2). + apply Zmult_le_compat_l; auto with zarith. + rewrite Zpower_1_r; auto with zarith. + apply Zpower_le_monotone; auto with zarith. + split; auto with zarith. + case (Zle_or_lt (Zpos (digits x)) [head0 x]); auto with zarith; intros HH6. + absurd (2 ^ Zpos (digits x) <= 2 ^ [head0 x] * [x]); auto with zarith. + rewrite <- HH5; rewrite Zmult_1_r. + apply Zpower_le_monotone; auto with zarith. + rewrite (Zmult_comm 2). + rewrite Zpower_mult; auto with zarith. + rewrite Zpower_2. + apply Zlt_le_trans with (2 := HH3). + rewrite <- Zmult_assoc. + replace (Zpos (xO (digits x)) - 1) with + ((Zpos (digits x) - 1) + (Zpos (digits x))). + rewrite Zpower_exp; auto with zarith. + apply Zmult_lt_compat2; auto with zarith. + split; auto with zarith. + apply Zmult_lt_0_compat; auto with zarith. + rewrite Zpos_xO; ring. + apply Zlt_le_weak; auto. + repeat rewrite spec_head00; auto. + rewrite spec_double_size_digits. + rewrite Zpos_xO; auto with zarith. + rewrite spec_double_size; auto. + Qed. + + Theorem spec_double_size_head0_pos: + forall x, 0 < [head0 (double_size x)]. + Proof. + intros x. + assert (F: 0 < Zpos (digits x)). + red; auto. + case (Zle_lt_or_eq _ _ (spec_pos (head0 (double_size x)))); auto; intros F0. + case (Zle_lt_or_eq _ _ (spec_pos (head0 x))); intros F1. + apply Zlt_le_trans with (2 := (spec_double_size_head0 x)); auto with zarith. + case (Zle_lt_or_eq _ _ (spec_pos x)); intros F3. + generalize F3; rewrite <- (spec_double_size x); intros F4. + absurd (2 ^ (Zpos (xO (digits x)) - 1) < 2 ^ (Zpos (digits x))). + apply Zle_not_lt. + apply Zpower_le_monotone; auto with zarith. + split; auto with zarith. + rewrite Zpos_xO; auto with zarith. + case (spec_head0 x F3). + rewrite <- F1; rewrite Zpower_0_r; rewrite Zmult_1_l; intros _ HH. + apply Zle_lt_trans with (2 := HH). + case (spec_head0 _ F4). + rewrite (spec_double_size x); rewrite (spec_double_size_digits x). + rewrite <- F0; rewrite Zpower_0_r; rewrite Zmult_1_l; auto. + generalize F1; rewrite (spec_head00 _ (sym_equal F3)); auto with zarith. + Qed. + + Definition safe_shiftl_aux_body cont n x := + match compare n (head0 x) with + Gt => cont n (double_size x) + | _ => shiftl n x + end. + + Theorem spec_safe_shift_aux_body: forall n p x cont, + 2^ Zpos p <= [head0 x] -> + (forall x, 2 ^ (Zpos p + 1) <= [head0 x]-> + [cont n x] = [x] * 2 ^ [n]) -> + [safe_shiftl_aux_body cont n x] = [x] * 2 ^ [n]. + Proof. + intros n p x cont H1 H2; unfold safe_shiftl_aux_body. + generalize (spec_compare n (head0 x)); case compare; intros H. + apply spec_shiftl; auto with zarith. + apply spec_shiftl; auto with zarith. + rewrite H2. + rewrite spec_double_size; auto. + rewrite Zplus_comm; rewrite Zpower_exp; auto with zarith. + apply Zle_trans with (2 := spec_double_size_head0 x). + rewrite Zpower_1_r; apply Zmult_le_compat_l; auto with zarith. + Qed. + + Fixpoint safe_shiftl_aux p cont n x {struct p} := + safe_shiftl_aux_body + (fun n x => match p with + | xH => cont n x + | xO p => safe_shiftl_aux p (safe_shiftl_aux p cont) n x + | xI p => safe_shiftl_aux p (safe_shiftl_aux p cont) n x + end) n x. + + Theorem spec_safe_shift_aux: forall p q n x cont, + 2 ^ (Zpos q) <= [head0 x] -> + (forall x, 2 ^ (Zpos p + Zpos q) <= [head0 x] -> + [cont n x] = [x] * 2 ^ [n]) -> + [safe_shiftl_aux p cont n x] = [x] * 2 ^ [n]. + Proof. + intros p; elim p; unfold safe_shiftl_aux; fold safe_shiftl_aux; clear p. + intros p Hrec q n x cont H1 H2. + apply spec_safe_shift_aux_body with (q); auto. + intros x1 H3; apply Hrec with (q + 1)%positive; auto. + intros x2 H4; apply Hrec with (p + q + 1)%positive; auto. + rewrite <- Pplus_assoc. + rewrite Zpos_plus_distr; auto. + intros x3 H5; apply H2. + rewrite Zpos_xI. + replace (2 * Zpos p + 1 + Zpos q) with (Zpos p + Zpos (p + q + 1)); + auto. + repeat rewrite Zpos_plus_distr; ring. + intros p Hrec q n x cont H1 H2. + apply spec_safe_shift_aux_body with (q); auto. + intros x1 H3; apply Hrec with (q); auto. + apply Zle_trans with (2 := H3); auto with zarith. + apply Zpower_le_monotone; auto with zarith. + intros x2 H4; apply Hrec with (p + q)%positive; auto. + intros x3 H5; apply H2. + rewrite (Zpos_xO p). + replace (2 * Zpos p + Zpos q) with (Zpos p + Zpos (p + q)); + auto. + repeat rewrite Zpos_plus_distr; ring. + intros q n x cont H1 H2. + apply spec_safe_shift_aux_body with (q); auto. + rewrite Zplus_comm; auto. + Qed. + + Definition safe_shiftl n x := + safe_shiftl_aux_body + (safe_shiftl_aux_body + (safe_shiftl_aux (digits n) shiftl)) n x. + + Theorem spec_safe_shift: forall n x, + [safe_shiftl n x] = [x] * 2 ^ [n]. + Proof. + intros n x; unfold safe_shiftl, safe_shiftl_aux_body. + generalize (spec_compare n (head0 x)); case compare; intros H. + apply spec_shiftl; auto with zarith. + apply spec_shiftl; auto with zarith. + rewrite <- (spec_double_size x). + generalize (spec_compare n (head0 (double_size x))); case compare; intros H1. + apply spec_shiftl; auto with zarith. + apply spec_shiftl; auto with zarith. + rewrite <- (spec_double_size (double_size x)). + apply spec_safe_shift_aux with 1%positive. + apply Zle_trans with (2 := spec_double_size_head0 (double_size x)). + replace (2 ^ 1) with (2 * 1). + apply Zmult_le_compat_l; auto with zarith. + generalize (spec_double_size_head0_pos x); auto with zarith. + rewrite Zpower_1_r; ring. + intros x1 H2; apply spec_shiftl. + apply Zle_trans with (2 := H2). + apply Zle_trans with (2 ^ Zpos (digits n)); auto with zarith. + case (spec_digits n); auto with zarith. + apply Zpower_le_monotone; auto with zarith. + Qed. + + Definition is_even x := + match x with + | N0 wx => w0_op.(znz_is_even) wx + | N1 wx => w1_op.(znz_is_even) wx + | N2 wx => w2_op.(znz_is_even) wx + | N3 wx => w3_op.(znz_is_even) wx + | N4 wx => w4_op.(znz_is_even) wx + | N5 wx => w5_op.(znz_is_even) wx + | N6 wx => w6_op.(znz_is_even) wx + | Nn n wx => (make_op n).(znz_is_even) wx + end. + + Theorem spec_is_even: forall x, + if is_even x then [x] mod 2 = 0 else [x] mod 2 = 1. + Proof. + intros x; case x; unfold is_even, to_Z; clear x. + intros x; exact (spec_is_even w0_spec x). + intros x; exact (spec_is_even w1_spec x). + intros x; exact (spec_is_even w2_spec x). + intros x; exact (spec_is_even w3_spec x). + intros x; exact (spec_is_even w4_spec x). + intros x; exact (spec_is_even w5_spec x). + intros x; exact (spec_is_even w6_spec x). + intros n x; exact (spec_is_even (wn_spec n) x). + Qed. + + Theorem spec_0: [zero] = 0. + Proof. + exact (spec_0 w0_spec). + Qed. + + Theorem spec_1: [one] = 1. + Proof. + exact (spec_1 w0_spec). + Qed. + +End Make. diff --git a/theories/Numbers/Natural/BigN/Nbasic.v b/theories/Numbers/Natural/BigN/Nbasic.v new file mode 100644 index 000000000..3d20c35ce --- /dev/null +++ b/theories/Numbers/Natural/BigN/Nbasic.v @@ -0,0 +1,510 @@ +(************************************************************************) +(* v * The Coq Proof Assistant / The Coq Development Team *) +(* <O___,, * CNRS-Ecole Polytechnique-INRIA Futurs-Universite Paris Sud *) +(* \VV/ **************************************************************) +(* // * This file is distributed under the terms of the *) +(* * GNU Lesser General Public License Version 2.1 *) +(************************************************************************) + +Require Import ZArith. +Require Import BigNumPrelude. +Require Import Basic_type. +Require Import Max. +Require Import GenBase. +Require Import ZnZ. +Require Import Zn2Z. + +(* To compute the necessary height *) + +Fixpoint plength (p: positive) : positive := + match p with + xH => xH + | xO p1 => Psucc (plength p1) + | xI p1 => Psucc (plength p1) + end. + +Theorem plength_correct: forall p, (Zpos p < 2 ^ Zpos (plength p))%Z. +assert (F: (forall p, 2 ^ (Zpos (Psucc p)) = 2 * 2 ^ Zpos p)%Z). +intros p; replace (Zpos (Psucc p)) with (1 + Zpos p)%Z. +rewrite Zpower_exp; auto with zarith. +rewrite Zpos_succ_morphism; unfold Zsucc; auto with zarith. +intros p; elim p; simpl plength; auto. +intros p1 Hp1; rewrite F; repeat rewrite Zpos_xI. +assert (tmp: (forall p, 2 * p = p + p)%Z); + try repeat rewrite tmp; auto with zarith. +intros p1 Hp1; rewrite F; rewrite (Zpos_xO p1). +assert (tmp: (forall p, 2 * p = p + p)%Z); + try repeat rewrite tmp; auto with zarith. +rewrite Zpower_1_r; auto with zarith. +Qed. + +Theorem plength_pred_correct: forall p, (Zpos p <= 2 ^ Zpos (plength (Ppred p)))%Z. +intros p; case (Psucc_pred p); intros H1. +subst; simpl plength. +rewrite Zpower_1_r; auto with zarith. +pattern p at 1; rewrite <- H1. +rewrite Zpos_succ_morphism; unfold Zsucc; auto with zarith. +generalize (plength_correct (Ppred p)); auto with zarith. +Qed. + +Definition Pdiv p q := + match Zdiv (Zpos p) (Zpos q) with + Zpos q1 => match (Zpos p) - (Zpos q) * (Zpos q1) with + Z0 => q1 + | _ => (Psucc q1) + end + | _ => xH + end. + +Theorem Pdiv_le: forall p q, + Zpos p <= Zpos q * Zpos (Pdiv p q). +intros p q. +unfold Pdiv. +assert (H1: Zpos q > 0); auto with zarith. +assert (H1b: Zpos p >= 0); auto with zarith. +generalize (Z_div_ge0 (Zpos p) (Zpos q) H1 H1b). +generalize (Z_div_mod_eq (Zpos p) (Zpos q) H1); case Zdiv. + intros HH _; rewrite HH; rewrite Zmult_0_r; rewrite Zmult_1_r; simpl. +case (Z_mod_lt (Zpos p) (Zpos q) H1); auto with zarith. +intros q1 H2. +replace (Zpos p - Zpos q * Zpos q1) with (Zpos p mod Zpos q). + 2: pattern (Zpos p) at 2; rewrite H2; auto with zarith. +generalize H2 (Z_mod_lt (Zpos p) (Zpos q) H1); clear H2; + case Zmod. + intros HH _; rewrite HH; auto with zarith. + intros r1 HH (_,HH1); rewrite HH; rewrite Zpos_succ_morphism. + unfold Zsucc; rewrite Zmult_plus_distr_r; auto with zarith. + intros r1 _ (HH,_); case HH; auto. +intros q1 HH; rewrite HH. +unfold Zge; simpl Zcompare; intros HH1; case HH1; auto. +Qed. + +Definition is_one p := match p with xH => true | _ => false end. + +Theorem is_one_one: forall p, is_one p = true -> p = xH. +intros p; case p; auto; intros p1 H1; discriminate H1. +Qed. + +Definition get_height digits p := + let r := Pdiv p digits in + if is_one r then xH else Psucc (plength (Ppred r)). + +Theorem get_height_correct: + forall digits N, + Zpos N <= Zpos digits * (2 ^ (Zpos (get_height digits N) -1)). +intros digits N. +unfold get_height. +assert (H1 := Pdiv_le N digits). +case_eq (is_one (Pdiv N digits)); intros H2. +rewrite (is_one_one _ H2) in H1. +rewrite Zmult_1_r in H1. +change (2^(1-1))%Z with 1; rewrite Zmult_1_r; auto. +clear H2. +apply Zle_trans with (1 := H1). +apply Zmult_le_compat_l; auto with zarith. +rewrite Zpos_succ_morphism; unfold Zsucc. +rewrite Zplus_comm; rewrite Zminus_plus. +apply plength_pred_correct. +Qed. + +Definition zn2z_word_comm : forall w n, zn2z (word w n) = word (zn2z w) n. + fix zn2z_word_comm 2. + intros w n; case n. + reflexivity. + intros n0;simpl. + case (zn2z_word_comm w n0). + reflexivity. +Defined. + +Fixpoint extend (n:nat) {struct n} : forall w:Set, zn2z w -> word w (S n) := + match n return forall w:Set, zn2z w -> word w (S n) with + | O => fun w x => x + | S m => + let aux := extend m in + fun w x => WW W0 (aux w x) + end. + +Section ExtendMax. + +Open Scope nat_scope. + +Fixpoint plusnS (n m: nat) {struct n} : (n + S m = S (n + m))%nat := + match n return (n + S m = S (n + m))%nat with + | 0 => refl_equal (S m) + | S n1 => + let v := S (S n1 + m) in + eq_ind_r (fun n => S n = v) (refl_equal v) (plusnS n1 m) + end. + +Fixpoint plusn0 n : n + 0 = n := + match n return (n + 0 = n) with + | 0 => refl_equal 0 + | S n1 => + let v := S n1 in + eq_ind_r (fun n : nat => S n = v) (refl_equal v) (plusn0 n1) + end. + + Fixpoint diff (m n: nat) {struct m}: nat * nat := + match m, n with + O, n => (O, n) + | m, O => (m, O) + | S m1, S n1 => diff m1 n1 + end. + +Fixpoint diff_l (m n : nat) {struct m} : fst (diff m n) + n = max m n := + match m return fst (diff m n) + n = max m n with + | 0 => + match n return (n = max 0 n) with + | 0 => refl_equal _ + | S n0 => refl_equal _ + end + | S m1 => + match n return (fst (diff (S m1) n) + n = max (S m1) n) + with + | 0 => plusn0 _ + | S n1 => + let v := fst (diff m1 n1) + n1 in + let v1 := fst (diff m1 n1) + S n1 in + eq_ind v (fun n => v1 = S n) + (eq_ind v1 (fun n => v1 = n) (refl_equal v1) (S v) (plusnS _ _)) + _ (diff_l _ _) + end + end. + +Fixpoint diff_r (m n: nat) {struct m}: snd (diff m n) + m = max m n := + match m return (snd (diff m n) + m = max m n) with + | 0 => + match n return (snd (diff 0 n) + 0 = max 0 n) with + | 0 => refl_equal _ + | S _ => plusn0 _ + end + | S m => + match n return (snd (diff (S m) n) + S m = max (S m) n) with + | 0 => refl_equal (snd (diff (S m) 0) + S m) + | S n1 => + let v := S (max m n1) in + eq_ind_r (fun n => n = v) + (eq_ind_r (fun n => S n = v) + (refl_equal v) (diff_r _ _)) (plusnS _ _) + end + end. + + Variable w: Set. + + Definition castm (m n: nat) (H: m = n) (x: word w (S m)): + (word w (S n)) := + match H in (_ = y) return (word w (S y)) with + | refl_equal => x + end. + +Variable m: nat. +Variable v: (word w (S m)). + +Fixpoint extend_tr (n : nat) {struct n}: (word w (S (n + m))) := + match n return (word w (S (n + m))) with + | O => v + | S n1 => WW W0 (extend_tr n1) + end. + +End ExtendMax. + +Implicit Arguments extend_tr[w m]. +Implicit Arguments castm[w m n]. + + + +Section Reduce. + + Variable w : Set. + Variable nT : Set. + Variable N0 : nT. + Variable eq0 : w -> bool. + Variable reduce_n : w -> nT. + Variable zn2z_to_Nt : zn2z w -> nT. + + Definition reduce_n1 (x:zn2z w) := + match x with + | W0 => N0 + | WW xh xl => + if eq0 xh then reduce_n xl + else zn2z_to_Nt x + end. + +End Reduce. + +Section ReduceRec. + + Variable w : Set. + Variable nT : Set. + Variable N0 : nT. + Variable reduce_1n : zn2z w -> nT. + Variable c : forall n, word w (S n) -> nT. + + Fixpoint reduce_n (n:nat) : word w (S n) -> nT := + match n return word w (S n) -> nT with + | O => reduce_1n + | S m => fun x => + match x with + | W0 => N0 + | WW xh xl => + match xh with + | W0 => @reduce_n m xl + | _ => @c (S m) x + end + end + end. + +End ReduceRec. + +Definition opp_compare cmp := + match cmp with + | Lt => Gt + | Eq => Eq + | Gt => Lt + end. + +Section CompareRec. + + Variable wm w : Set. + Variable w_0 : w. + Variable compare : w -> w -> comparison. + Variable compare0_m : wm -> comparison. + Variable compare_m : wm -> w -> comparison. + + Fixpoint compare0_mn (n:nat) : word wm n -> comparison := + match n return word wm n -> comparison with + | O => compare0_m + | S m => fun x => + match x with + | W0 => Eq + | WW xh xl => + match compare0_mn m xh with + | Eq => compare0_mn m xl + | r => Lt + end + end + end. + + Variable wm_base: positive. + Variable wm_to_Z: wm -> Z. + Variable w_to_Z: w -> Z. + Variable w_to_Z_0: w_to_Z w_0 = 0. + Variable spec_compare0_m: forall x, + match compare0_m x with + Eq => w_to_Z w_0 = wm_to_Z x + | Lt => w_to_Z w_0 < wm_to_Z x + | Gt => w_to_Z w_0 > wm_to_Z x + end. + Variable wm_to_Z_pos: forall x, 0 <= wm_to_Z x < base wm_base. + + Let gen_to_Z := gen_to_Z wm_base wm_to_Z. + Let gen_wB := gen_wB wm_base. + + Lemma base_xO: forall n, base (xO n) = (base n)^2. + Proof. + intros n1; unfold base. + rewrite (Zpos_xO n1); rewrite Zmult_comm; rewrite Zpower_mult; auto with zarith. + Qed. + + Let gen_to_Z_pos: forall n x, 0 <= gen_to_Z n x < gen_wB n := + (spec_gen_to_Z wm_base wm_to_Z wm_to_Z_pos). + + + Lemma spec_compare0_mn: forall n x, + match compare0_mn n x with + Eq => 0 = gen_to_Z n x + | Lt => 0 < gen_to_Z n x + | Gt => 0 > gen_to_Z n x + end. + Proof. + intros n; elim n; clear n; auto. + intros x; generalize (spec_compare0_m x); rewrite w_to_Z_0; auto. + intros n Hrec x; case x; unfold compare0_mn; fold compare0_mn; auto. + intros xh xl. + generalize (Hrec xh); case compare0_mn; auto. + generalize (Hrec xl); case compare0_mn; auto. + simpl gen_to_Z; intros H1 H2; rewrite H1; rewrite <- H2; auto. + simpl gen_to_Z; intros H1 H2; rewrite <- H2; auto. + case (gen_to_Z_pos n xl); auto with zarith. + intros H1; simpl gen_to_Z. + set (u := GenBase.gen_wB wm_base n). + case (gen_to_Z_pos n xl); intros H2 H3. + assert (0 < u); auto with zarith. + unfold u, GenBase.gen_wB, base; auto with zarith. + change 0 with (0 + 0); apply Zplus_lt_le_compat; auto with zarith. + apply Zmult_lt_0_compat; auto with zarith. + case (gen_to_Z_pos n xh); auto with zarith. + Qed. + + Fixpoint compare_mn_1 (n:nat) : word wm n -> w -> comparison := + match n return word wm n -> w -> comparison with + | O => compare_m + | S m => fun x y => + match x with + | W0 => compare w_0 y + | WW xh xl => + match compare0_mn m xh with + | Eq => compare_mn_1 m xl y + | r => Gt + end + end + end. + + Variable spec_compare: forall x y, + match compare x y with + Eq => w_to_Z x = w_to_Z y + | Lt => w_to_Z x < w_to_Z y + | Gt => w_to_Z x > w_to_Z y + end. + Variable spec_compare_m: forall x y, + match compare_m x y with + Eq => wm_to_Z x = w_to_Z y + | Lt => wm_to_Z x < w_to_Z y + | Gt => wm_to_Z x > w_to_Z y + end. + Variable wm_base_lt: forall x, + 0 <= w_to_Z x < base (wm_base). + + Let gen_wB_lt: forall n x, + 0 <= w_to_Z x < (gen_wB n). + Proof. + intros n x; elim n; simpl; auto; clear n. + intros n (H0, H); split; auto. + apply Zlt_le_trans with (1:= H). + unfold gen_wB, GenBase.gen_wB; simpl. + rewrite base_xO. + set (u := base (gen_digits wm_base n)). + assert (0 < u). + unfold u, base; auto with zarith. + replace (u^2) with (u * u); simpl; auto with zarith. + apply Zle_trans with (1 * u); auto with zarith. + unfold Zpower_pos; simpl; ring. + Qed. + + + Lemma spec_compare_mn_1: forall n x y, + match compare_mn_1 n x y with + Eq => gen_to_Z n x = w_to_Z y + | Lt => gen_to_Z n x < w_to_Z y + | Gt => gen_to_Z n x > w_to_Z y + end. + Proof. + intros n; elim n; simpl; auto; clear n. + intros n Hrec x; case x; clear x; auto. + intros y; generalize (spec_compare w_0 y); rewrite w_to_Z_0; case compare; auto. + intros xh xl y; simpl; generalize (spec_compare0_mn n xh); case compare0_mn; intros H1b. + rewrite <- H1b; rewrite Zmult_0_l; rewrite Zplus_0_l; auto. + apply Hrec. + apply Zlt_gt. + case (gen_wB_lt n y); intros _ H0. + apply Zlt_le_trans with (1:= H0). + fold gen_wB. + case (gen_to_Z_pos n xl); intros H1 H2. + apply Zle_trans with (gen_to_Z n xh * gen_wB n); auto with zarith. + apply Zle_trans with (1 * gen_wB n); auto with zarith. + case (gen_to_Z_pos n xh); auto with zarith. + Qed. + +End CompareRec. + + +Section AddS. + + Variable w wm: Set. + Variable incr : wm -> carry wm. + Variable addr : w -> wm -> carry wm. + Variable injr : w -> zn2z wm. + + Variable w_0 u: w. + Fixpoint injs (n:nat): word w (S n) := + match n return (word w (S n)) with + O => WW w_0 u + | S n1 => (WW W0 (injs n1)) + end. + + Definition adds x y := + match y with + W0 => C0 (injr x) + | WW hy ly => match addr x ly with + C0 z => C0 (WW hy z) + | C1 z => match incr hy with + C0 z1 => C0 (WW z1 z) + | C1 z1 => C1 (WW z1 z) + end + end + end. + +End AddS. + + + Lemma spec_opp: forall u x y, + match u with + | Eq => y = x + | Lt => y < x + | Gt => y > x + end -> + match opp_compare u with + | Eq => x = y + | Lt => x < y + | Gt => x > y + end. + Proof. + intros u x y; case u; simpl; auto with zarith. + Qed. + + Fixpoint length_pos x := + match x with xH => O | xO x1 => S (length_pos x1) | xI x1 => S (length_pos x1) end. + + Theorem length_pos_lt: forall x y, + (length_pos x < length_pos y)%nat -> Zpos x < Zpos y. + Proof. + intros x; elim x; clear x; [intros x1 Hrec | intros x1 Hrec | idtac]; + intros y; case y; clear y; intros y1 H || intros H; simpl length_pos; + try (rewrite (Zpos_xI x1) || rewrite (Zpos_xO x1)); + try (rewrite (Zpos_xI y1) || rewrite (Zpos_xO y1)); + try (inversion H; fail); + try (assert (Zpos x1 < Zpos y1); [apply Hrec; apply lt_S_n | idtac]; auto with zarith); + assert (0 < Zpos y1); auto with zarith; red; auto. + Qed. + + Theorem cancel_app: forall A B (f g: A -> B) x, f = g -> f x = g x. + Proof. + intros A B f g x H; rewrite H; auto. + Qed. + + + Section SimplOp. + + Variable w: Set. + + Theorem digits_zop: forall w (x: znz_op w), + znz_digits (mk_zn2z_op x) = xO (znz_digits x). + intros ww x; auto. + Qed. + + Theorem digits_kzop: forall w (x: znz_op w), + znz_digits (mk_zn2z_op_karatsuba x) = xO (znz_digits x). + intros ww x; auto. + Qed. + + Theorem make_zop: forall w (x: znz_op w), + znz_to_Z (mk_zn2z_op x) = + fun z => match z with + W0 => 0 + | WW xh xl => znz_to_Z x xh * base (znz_digits x) + + znz_to_Z x xl + end. + intros ww x; auto. + Qed. + + Theorem make_kzop: forall w (x: znz_op w), + znz_to_Z (mk_zn2z_op_karatsuba x) = + fun z => match z with + W0 => 0 + | WW xh xl => znz_to_Z x xh * base (znz_digits x) + + znz_to_Z x xl + end. + intros ww x; auto. + Qed. + + End SimplOp. diff --git a/theories/Numbers/Natural/BigN/genN.ml b/theories/Numbers/Natural/BigN/genN.ml new file mode 100644 index 000000000..8bf583ab6 --- /dev/null +++ b/theories/Numbers/Natural/BigN/genN.ml @@ -0,0 +1,3407 @@ +open Format + +let size = 6 +let sizeaux = 1 +let gen_proof = true + +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) ^ ")" + + +(******* Start Printing ********) +let basename = "N" + + +let print_header fmt l = + let l = "ZAux"::"ZArith"::"Basic_type"::"ZnZ"::"Zn2Z"::"Nbasic"::"GenMul":: + "GenDivn1"::"Wf_nat"::"MemoFn"::l in + List.iter (fun s -> fprintf fmt "Require Import %s.\n" s) l; + fprintf fmt "\n" + +let start_file post l = + let outname = basename^post^".v" in + let fd = + try + Unix.openfile outname [Unix.O_WRONLY;Unix.O_CREAT;Unix.O_TRUNC] 0o640 + with _ -> + print_string ("can not open file "^outname^"\n"); + exit 1 in + let out = Unix.out_channel_of_descr fd in + set_binary_mode_out out false; + let fmt = formatter_of_out_channel out in + print_header fmt l; + fmt + + + +(****** Print types *******) + +let print_Make () = + let fmt = start_file "Make" [] in + + fprintf fmt "(***************************************************************)\n"; + fprintf fmt "(* *)\n"; + fprintf fmt "(* File automatically generated DO NOT EDIT *)\n"; + fprintf fmt "(* Constructors: %i Generated Proofs: %b %s %s *)\n" size gen_proof (if size < 10 then " " else "") (if gen_proof then " " else ""); + fprintf fmt "(* *)\n"; + fprintf fmt "(* To change this file, edit in genN.ml the two lines *)\n"; + fprintf fmt "(* let size = %i%s *)\n" size (if size < 10 then " " else ""); + fprintf fmt "(* let gen_proof = %s *)\n" (if gen_proof then "true " else "false"); + fprintf fmt "(* Recompile the file *)\n"; + fprintf fmt "(* camlopt -o genN unix.cmxa genN.ml *)\n"; + fprintf fmt "(* Regenerate NMake.v *)\n"; + fprintf fmt "(* ./genN *)\n"; + fprintf fmt "(***************************************************************)\n\n"; + + + fprintf fmt "Module Type W0Type.\n"; + fprintf fmt " Parameter w : Set.\n"; + fprintf fmt " Parameter w_op : znz_op w.\n"; + fprintf fmt " Parameter w_spec : znz_spec w_op.\n"; + fprintf fmt "End W0Type.\n"; + fprintf fmt "\n"; + + fprintf fmt "Module Make (W0:W0Type).\n"; + fprintf fmt " Import W0.\n"; + fprintf fmt "\n"; + + fprintf fmt " Definition w0 := W0.w.\n"; + for i = 1 to size do + fprintf fmt " Definition w%i := zn2z w%i.\n" i (i-1) + done; + fprintf fmt "\n"; + + fprintf fmt " Definition w0_op := W0.w_op.\n"; + for i = 1 to 3 do + fprintf fmt " Definition w%i_op := mk_zn2z_op w%i_op.\n" i (i-1) + done; + for i = 4 to size + 3 do + fprintf fmt " Definition w%i_op := mk_zn2z_op_karatsuba w%i_op.\n" i (i-1) + done; + fprintf fmt "\n"; + + fprintf fmt " Section Make_op.\n"; + fprintf fmt " Variable mk : forall w', znz_op w' -> znz_op (zn2z w').\n"; + fprintf fmt "\n"; + fprintf fmt + " Fixpoint make_op_aux (n:nat) : znz_op (word w%i (S n)):=\n" size; + fprintf fmt " match n return znz_op (word w%i (S n)) with\n" size; + fprintf fmt " | O => w%i_op\n" (size+1); + fprintf fmt " | S n1 =>\n"; + fprintf fmt " match n1 return znz_op (word w%i (S (S n1))) with\n" size; + fprintf fmt " | O => w%i_op\n" (size+2); + fprintf fmt " | S n2 =>\n"; + fprintf fmt " match n2 return znz_op (word w%i (S (S (S n2)))) with\n" + size; + fprintf fmt " | O => w%i_op\n" (size+3); + fprintf fmt " | S n3 => mk _ (mk _ (mk _ (make_op_aux n3)))\n"; + fprintf fmt " end\n"; + fprintf fmt " end\n"; + fprintf fmt " end.\n"; + fprintf fmt "\n"; + fprintf fmt " End Make_op.\n"; + fprintf fmt "\n"; + fprintf fmt " Definition omake_op := make_op_aux mk_zn2z_op_karatsuba.\n"; + fprintf fmt "\n"; + fprintf fmt "\n"; + fprintf fmt " Definition make_op_list := dmemo_list _ omake_op.\n"; + fprintf fmt "\n"; + fprintf fmt " Definition make_op n := dmemo_get _ omake_op n make_op_list.\n"; + fprintf fmt "\n"; + fprintf fmt " Lemma make_op_omake: forall n, make_op n = omake_op n.\n"; + fprintf fmt " intros n; unfold make_op, make_op_list.\n"; + fprintf fmt " refine (dmemo_get_correct _ _ _).\n"; + fprintf fmt " Qed.\n"; + fprintf fmt "\n"; + + fprintf fmt " Inductive %s_ : Set :=\n" t; + for i = 0 to size do + fprintf fmt " | %s%i : w%i -> %s_\n" c i i t + done; + fprintf fmt " | %sn : forall n, word w%i (S n) -> %s_.\n" c size t; + fprintf fmt "\n"; + fprintf fmt " Definition %s := %s_.\n" t t; + fprintf fmt "\n"; + + fprintf fmt " Definition w_0 := w0_op.(znz_0).\n"; + fprintf fmt "\n"; + + for i = 0 to size do + fprintf fmt " Definition one%i := w%i_op.(znz_1).\n" i i + done; + fprintf fmt "\n"; + + + fprintf fmt " Definition zero := %s0 w_0.\n" c; + fprintf fmt " Definition one := %s0 one0.\n" c; + fprintf fmt "\n"; + + fprintf fmt " Definition to_Z x :=\n"; + fprintf fmt " match x with\n"; + for i = 0 to size do + fprintf fmt " | %s%i wx => w%i_op.(znz_to_Z) wx\n" c i i + done; + fprintf fmt " | %sn n wx => (make_op n).(znz_to_Z) wx\n" c; + fprintf fmt " end.\n"; + fprintf fmt "\n"; + + fprintf fmt " Open Scope Z_scope.\n"; + fprintf fmt " Notation \"[ x ]\" := (to_Z x).\n"; + fprintf fmt " \n"; + + + + + if gen_proof then + begin + fprintf fmt " (* Regular make op (no karatsuba) *)\n"; + fprintf fmt " Fixpoint nmake_op (ww:Set) (ww_op: znz_op ww) (n: nat) : \n"; + fprintf fmt " znz_op (word ww n) :=\n"; + fprintf fmt " match n return znz_op (word ww n) with \n"; + fprintf fmt " O => ww_op\n"; + fprintf fmt " | S n1 => mk_zn2z_op (nmake_op ww ww_op n1) \n"; + fprintf fmt " end.\n"; + fprintf fmt "\n"; + fprintf fmt " (* Simplification by rewriting for nmake_op *)\n"; + fprintf fmt " Theorem nmake_op_S: forall ww (w_op: znz_op ww) x, \n"; + fprintf fmt " nmake_op _ w_op (S x) = mk_zn2z_op (nmake_op _ w_op x).\n"; + fprintf fmt " auto.\n"; + fprintf fmt " Qed.\n"; + fprintf fmt "\n"; + end; + + + fprintf fmt " (* Eval and extend functions for each level *)\n"; + for i = 0 to size do + if gen_proof then + fprintf fmt " Let nmake_op%i := nmake_op _ w%i_op.\n" i i; + if gen_proof then + fprintf fmt " Let eval%in n := znz_to_Z (nmake_op%i n).\n" i i; + if i == 0 then + fprintf fmt " Let extend%i := GenBase.extend (WW w_0).\n" i + else + fprintf fmt " Let extend%i := GenBase.extend (WW (W0: w%i)).\n" i i; + done; + fprintf fmt "\n"; + + + if gen_proof then + begin + fprintf fmt " Theorem digits_gend:forall n ww (w_op: znz_op ww), \n"; + fprintf fmt " znz_digits (nmake_op _ w_op n) = \n"; + fprintf fmt " GenBase.gen_digits (znz_digits w_op) n.\n"; + fprintf fmt " Proof."; + fprintf fmt " intros n; elim n; auto; clear n.\n"; + fprintf fmt " intros n Hrec ww ww_op; simpl GenBase.gen_digits.\n"; + fprintf fmt " rewrite <- Hrec; auto.\n"; + fprintf fmt " Qed.\n"; + fprintf fmt "\n"; + fprintf fmt " Theorem nmake_gen: forall n ww (w_op: znz_op ww), \n"; + fprintf fmt " znz_to_Z (nmake_op _ w_op n) =\n"; + fprintf fmt " %sGenBase.gen_to_Z _ (znz_digits w_op) (znz_to_Z w_op) n.\n" "@"; + fprintf fmt " Proof."; + fprintf fmt " intros n; elim n; auto; clear n.\n"; + fprintf fmt " intros n Hrec ww ww_op; simpl GenBase.gen_to_Z; unfold zn2z_to_Z.\n"; + fprintf fmt " rewrite <- Hrec; auto.\n"; + fprintf fmt " unfold GenBase.gen_wB; rewrite <- digits_gend; auto.\n"; + fprintf fmt " Qed.\n"; + fprintf fmt "\n"; + + + fprintf fmt " Theorem digits_nmake:forall n ww (w_op: znz_op ww), \n"; + fprintf fmt " znz_digits (nmake_op _ w_op (S n)) = \n"; + fprintf fmt " xO (znz_digits (nmake_op _ w_op n)).\n"; + fprintf fmt " Proof.\n"; + fprintf fmt " auto.\n"; + fprintf fmt " Qed.\n"; + fprintf fmt "\n"; + + + fprintf fmt " Theorem znz_nmake_op: forall ww ww_op n xh xl,\n"; + fprintf fmt " znz_to_Z (nmake_op ww ww_op (S n)) (WW xh xl) =\n"; + fprintf fmt " znz_to_Z (nmake_op ww ww_op n) xh *\n"; + fprintf fmt " base (znz_digits (nmake_op ww ww_op n)) +\n"; + fprintf fmt " znz_to_Z (nmake_op ww ww_op n) xl.\n"; + fprintf fmt " Proof.\n"; + fprintf fmt " auto.\n"; + fprintf fmt " Qed.\n"; + fprintf fmt "\n"; + + fprintf fmt " Theorem make_op_S: forall n,\n"; + fprintf fmt " make_op (S n) = mk_zn2z_op_karatsuba (make_op n).\n"; + fprintf fmt " intro n.\n"; + fprintf fmt " do 2 rewrite make_op_omake.\n"; + fprintf fmt " pattern n; apply lt_wf_ind; clear n.\n"; + fprintf fmt " intros n; case n; clear n.\n"; + fprintf fmt " intros _; unfold omake_op, make_op_aux, w%i_op; apply refl_equal.\n" (size + 2); + fprintf fmt " intros n; case n; clear n.\n"; + fprintf fmt " intros _; unfold omake_op, make_op_aux, w%i_op; apply refl_equal.\n" (size + 3); + fprintf fmt " intros n; case n; clear n.\n"; + fprintf fmt " intros _; unfold omake_op, make_op_aux, w%i_op, w%i_op; apply refl_equal.\n" (size + 3) (size + 2); + fprintf fmt " intros n Hrec.\n"; + fprintf fmt " change (omake_op (S (S (S (S n))))) with\n"; + fprintf fmt " (mk_zn2z_op_karatsuba (mk_zn2z_op_karatsuba (mk_zn2z_op_karatsuba (omake_op (S n))))).\n"; + fprintf fmt " change (omake_op (S (S (S n)))) with\n"; + fprintf fmt " (mk_zn2z_op_karatsuba (mk_zn2z_op_karatsuba (mk_zn2z_op_karatsuba (omake_op n)))).\n"; + fprintf fmt " rewrite Hrec; auto with arith.\n"; + fprintf fmt " Qed.\n"; + fprintf fmt " \n"; + + + for i = 1 to size + 2 do + fprintf fmt " Let znz_to_Z_%i: forall x y,\n" i; + fprintf fmt " znz_to_Z w%i_op (WW x y) = \n" i; + fprintf fmt " znz_to_Z w%i_op x * base (znz_digits w%i_op) + znz_to_Z w%i_op y.\n" (i-1) (i-1) (i-1); + fprintf fmt " Proof.\n"; + fprintf fmt " auto.\n"; + fprintf fmt " Qed. \n"; + fprintf fmt "\n"; + done; + + fprintf fmt " Let znz_to_Z_n: forall n x y,\n"; + fprintf fmt " znz_to_Z (make_op (S n)) (WW x y) = \n"; + fprintf fmt " znz_to_Z (make_op n) x * base (znz_digits (make_op n)) + znz_to_Z (make_op n) y.\n"; + fprintf fmt " Proof.\n"; + fprintf fmt " intros n x y; rewrite make_op_S; auto.\n"; + fprintf fmt " Qed. \n"; + fprintf fmt "\n"; + end; + + if gen_proof then + begin + fprintf fmt " Let w0_spec: znz_spec w0_op := W0.w_spec.\n"; + for i = 1 to 3 do + fprintf fmt " Let w%i_spec: znz_spec w%i_op := mk_znz2_spec w%i_spec.\n" i i (i-1) + done; + for i = 4 to size + 3 do + fprintf fmt " Let w%i_spec : znz_spec w%i_op := mk_znz2_karatsuba_spec w%i_spec.\n" i i (i-1) + done; + fprintf fmt "\n"; + + fprintf fmt " Let wn_spec: forall n, znz_spec (make_op n).\n"; + fprintf fmt " intros n; elim n; clear n.\n"; + fprintf fmt " exact w%i_spec.\n" (size + 1); + fprintf fmt " intros n Hrec; rewrite make_op_S.\n"; + fprintf fmt " exact (mk_znz2_karatsuba_spec Hrec).\n"; + fprintf fmt " Qed.\n"; + fprintf fmt " \n"; + end; + + for i = 0 to size do + fprintf fmt " Definition w%i_eq0 := w%i_op.(znz_eq0).\n" i i; + fprintf fmt " Let spec_w%i_eq0: forall x, if w%i_eq0 x then [%s%i x] = 0 else True.\n" i i c i; + if gen_proof then + begin + fprintf fmt " intros x; unfold w%i_eq0, to_Z; generalize (spec_eq0 w%i_spec x);\n" i i; + fprintf fmt " case znz_eq0; auto.\n"; + fprintf fmt " Qed.\n"; + end + else + fprintf fmt " Admitted.\n"; + fprintf fmt "\n"; + done; + fprintf fmt "\n"; + + + if gen_proof then + begin + for i = 0 to size do + fprintf fmt " Theorem digits_w%i: znz_digits w%i_op = znz_digits (nmake_op _ w0_op %i).\n" i i i; + if i == 0 then + fprintf fmt " auto.\n" + else + fprintf fmt " rewrite digits_nmake; rewrite <- digits_w%i; auto.\n" (i - 1); + fprintf fmt " Qed.\n"; + fprintf fmt "\n"; + + fprintf fmt " Let spec_gen_eval%in: forall n, eval%in n = GenBase.gen_to_Z (znz_digits w%i_op) (znz_to_Z w%i_op) n.\n" i i i i; + if gen_proof then + begin + fprintf fmt " intros n; exact (nmake_gen n w%i w%i_op).\n" i i; + fprintf fmt " Qed.\n"; + end + else + fprintf fmt " Admitted.\n"; + fprintf fmt "\n"; + done; + + for i = 0 to size do + for j = 0 to (size - i) do + fprintf fmt " Theorem digits_w%in%i: znz_digits w%i_op = znz_digits (nmake_op _ w%i_op %i).\n" i j (i + j) i j; + if j == 0 then + if i == 0 then + fprintf fmt " auto.\n" + else + begin + fprintf fmt " apply trans_equal with (xO (znz_digits w%i_op)).\n" (i + j -1); + fprintf fmt " auto.\n"; + fprintf fmt " unfold nmake_op; auto.\n"; + end + else + begin + fprintf fmt " apply trans_equal with (xO (znz_digits w%i_op)).\n" (i + j -1); + fprintf fmt " auto.\n"; + fprintf fmt " rewrite digits_nmake.\n"; + fprintf fmt " rewrite digits_w%in%i.\n" i (j - 1); + fprintf fmt " auto.\n"; + end; + fprintf fmt " Qed.\n"; + fprintf fmt "\n"; + fprintf fmt " Let spec_eval%in%i: forall x, [%s%i x] = eval%in %i x.\n" i j c (i + j) i j; + if gen_proof then + begin + if j == 0 then + fprintf fmt " intros x; rewrite spec_gen_eval%in; unfold GenBase.gen_to_Z, to_Z; auto.\n" i + else + begin + fprintf fmt " intros x; case x.\n"; + fprintf fmt " auto.\n"; + fprintf fmt " intros xh xl; unfold to_Z; rewrite znz_to_Z_%i.\n" (i + j); + fprintf fmt " rewrite digits_w%in%i.\n" i (j - 1); + fprintf fmt " generalize (spec_eval%in%i); unfold to_Z; intros HH; repeat rewrite HH.\n" i (j - 1); + fprintf fmt " unfold eval%in, nmake_op%i.\n" i i; + fprintf fmt " rewrite (znz_nmake_op _ w%i_op %i); auto.\n" i (j - 1); + + end; + fprintf fmt " Qed.\n"; + end + else + fprintf fmt " Admitted.\n"; + if i + j <> size then + begin + fprintf fmt " Let spec_extend%in%i: forall x, [%s%i x] = [%s%i (extend%i %i x)].\n" i (i + j + 1) c i c (i + j + 1) i j; + if j == 0 then + begin + fprintf fmt " intros x; change (extend%i 0 x) with (WW (znz_0 w%i_op) x).\n" i (i + j); + fprintf fmt " unfold to_Z; rewrite znz_to_Z_%i.\n" (i + j + 1); + fprintf fmt " rewrite (spec_0 w%i_spec); auto.\n" (i + j); + + end + else + begin + fprintf fmt " intros x; change (extend%i %i x) with (WW (znz_0 w%i_op) (extend%i %i x)).\n" i j (i + j) i (j - 1); + fprintf fmt " unfold to_Z; rewrite znz_to_Z_%i.\n" (i + j + 1); + fprintf fmt " rewrite (spec_0 w%i_spec).\n" (i + j); + fprintf fmt " generalize (spec_extend%in%i x); unfold to_Z.\n" i (i + j); + fprintf fmt " intros HH; rewrite <- HH; auto.\n"; + + end; + fprintf fmt " Qed.\n"; + fprintf fmt "\n"; + end; + done; + + fprintf fmt " Theorem digits_w%in%i: znz_digits w%i_op = znz_digits (nmake_op _ w%i_op %i).\n" i (size - i + 1) (size + 1) i (size - i + 1); + fprintf fmt " apply trans_equal with (xO (znz_digits w%i_op)).\n" size; + fprintf fmt " auto.\n"; + fprintf fmt " rewrite digits_nmake.\n"; + fprintf fmt " rewrite digits_w%in%i.\n" i (size - i); + fprintf fmt " auto.\n"; + fprintf fmt " Qed.\n"; + fprintf fmt "\n"; + + fprintf fmt " Let spec_eval%in%i: forall x, [%sn 0 x] = eval%in %i x.\n" i (size - i + 1) c i (size - i + 1); + fprintf fmt " intros x; case x.\n"; + fprintf fmt " auto.\n"; + fprintf fmt " intros xh xl; unfold to_Z; rewrite znz_to_Z_%i.\n" (size + 1); + fprintf fmt " rewrite digits_w%in%i.\n" i (size - i); + fprintf fmt " generalize (spec_eval%in%i); unfold to_Z; intros HH; repeat rewrite HH.\n" i (size - i); + fprintf fmt " unfold eval%in, nmake_op%i.\n" i i; + fprintf fmt " rewrite (znz_nmake_op _ w%i_op %i); auto.\n" i (size - i); + fprintf fmt " Qed.\n"; + fprintf fmt "\n"; + + fprintf fmt " Let spec_eval%in%i: forall x, [%sn 1 x] = eval%in %i x.\n" i (size - i + 2) c i (size - i + 2); + fprintf fmt " intros x; case x.\n"; + fprintf fmt " auto.\n"; + fprintf fmt " intros xh xl; unfold to_Z; rewrite znz_to_Z_%i.\n" (size + 2); + fprintf fmt " rewrite digits_w%in%i.\n" i (size + 1 - i); + fprintf fmt " generalize (spec_eval%in%i); unfold to_Z; change (make_op 0) with (w%i_op); intros HH; repeat rewrite HH.\n" i (size + 1 - i) (size + 1); + fprintf fmt " unfold eval%in, nmake_op%i.\n" i i; + fprintf fmt " rewrite (znz_nmake_op _ w%i_op %i); auto.\n" i (size + 1 - i); + fprintf fmt " Qed.\n"; + fprintf fmt "\n"; + done; + + fprintf fmt " Let digits_w%in: forall n,\n" size; + fprintf fmt " znz_digits (make_op n) = znz_digits (nmake_op _ w%i_op (S n)).\n" size; + fprintf fmt " intros n; elim n; clear n.\n"; + fprintf fmt " change (znz_digits (make_op 0)) with (xO (znz_digits w%i_op)).\n" size; + fprintf fmt " rewrite nmake_op_S; apply sym_equal; auto.\n"; + fprintf fmt " intros n Hrec.\n"; + fprintf fmt " replace (znz_digits (make_op (S n))) with (xO (znz_digits (make_op n))).\n"; + fprintf fmt " rewrite Hrec.\n"; + fprintf fmt " rewrite nmake_op_S; apply sym_equal; auto.\n"; + fprintf fmt " rewrite make_op_S; apply sym_equal; auto.\n"; + fprintf fmt " Qed.\n"; + fprintf fmt "\n"; + + fprintf fmt " Let spec_eval%in: forall n x, [%sn n x] = eval%in (S n) x.\n" size c size; + fprintf fmt " intros n; elim n; clear n.\n"; + fprintf fmt " exact spec_eval%in1.\n" size; + fprintf fmt " intros n Hrec x; case x; clear x.\n"; + fprintf fmt " unfold to_Z, eval%in, nmake_op%i.\n" size size; + fprintf fmt " rewrite make_op_S; rewrite nmake_op_S; auto.\n"; + fprintf fmt " intros xh xl.\n"; + fprintf fmt " unfold to_Z in Hrec |- *.\n"; + fprintf fmt " rewrite znz_to_Z_n.\n"; + fprintf fmt " rewrite digits_w%in.\n" size; + fprintf fmt " repeat rewrite Hrec.\n"; + fprintf fmt " unfold eval%in, nmake_op%i.\n" size size; + fprintf fmt " apply sym_equal; rewrite nmake_op_S; auto.\n"; + fprintf fmt " Qed.\n"; + fprintf fmt "\n"; + + fprintf fmt " Let spec_extend%in: forall n x, [%s%i x] = [%sn n (extend%i n x)].\n" size c size c size ; + fprintf fmt " intros n; elim n; clear n.\n"; + fprintf fmt " intros x; change (extend%i 0 x) with (WW (znz_0 w%i_op) x).\n" size size; + fprintf fmt " unfold to_Z.\n"; + fprintf fmt " change (make_op 0) with w%i_op.\n" (size + 1); + fprintf fmt " rewrite znz_to_Z_%i; rewrite (spec_0 w%i_spec); auto.\n" (size + 1) size; + fprintf fmt " intros n Hrec x.\n"; + fprintf fmt " change (extend%i (S n) x) with (WW W0 (extend%i n x)).\n" size size; + fprintf fmt " unfold to_Z in Hrec |- *; rewrite znz_to_Z_n; auto.\n"; + fprintf fmt " rewrite <- Hrec.\n"; + fprintf fmt " replace (znz_to_Z (make_op n) W0) with 0; auto.\n"; + fprintf fmt " case n; auto; intros; rewrite make_op_S; auto.\n"; + fprintf fmt " Qed.\n"; + fprintf fmt "\n"; + end; + + + + fprintf fmt " Theorem spec_pos: forall x, 0 <= [x].\n"; + if gen_proof then + begin + fprintf fmt " Proof.\n"; + fprintf fmt " intros x; case x; clear x.\n"; + for i = 0 to size do + fprintf fmt " intros x; case (spec_to_Z w%i_spec x); auto.\n" i; + done; + fprintf fmt " intros n x; case (spec_to_Z (wn_spec n) x); auto.\n"; + fprintf fmt " Qed.\n"; + end + else + fprintf fmt " Admitted.\n"; + fprintf fmt "\n"; + + + if gen_proof then + begin + fprintf fmt " Let spec_extendn_0: forall n wx, [%sn n (extend n _ wx)] = [%sn 0 wx].\n" c c; + fprintf fmt " intros n; elim n; auto.\n"; + fprintf fmt " intros n1 Hrec wx; simpl extend; rewrite <- Hrec; auto.\n"; + fprintf fmt " unfold to_Z.\n"; + fprintf fmt " case n1; auto; intros n2; repeat rewrite make_op_S; auto.\n"; + fprintf fmt " Qed.\n"; + fprintf fmt " Hint Rewrite spec_extendn_0: extr.\n"; + fprintf fmt "\n"; + fprintf fmt " Let spec_extendn0_0: forall n wx, [%sn (S n) (WW W0 wx)] = [%sn n wx].\n" c c; + fprintf fmt " Proof.\n"; + fprintf fmt " intros n x; unfold to_Z.\n"; + fprintf fmt " rewrite znz_to_Z_n.\n"; + fprintf fmt " rewrite <- (Zplus_0_l (znz_to_Z (make_op n) x)).\n"; + fprintf fmt " apply (f_equal2 Zplus); auto.\n"; + fprintf fmt " case n; auto.\n"; + fprintf fmt " intros n1; rewrite make_op_S; auto.\n"; + fprintf fmt " Qed.\n"; + fprintf fmt " Hint Rewrite spec_extendn_0: extr.\n"; + fprintf fmt "\n"; + fprintf fmt " Let spec_extend_tr: forall m n (w: word _ (S n)),\n"; + fprintf fmt " [%sn (m + n) (extend_tr w m)] = [%sn n w].\n" c c; + fprintf fmt " Proof.\n"; + fprintf fmt " induction m; auto.\n"; + fprintf fmt " intros n x; simpl extend_tr.\n"; + fprintf fmt " simpl plus; rewrite spec_extendn0_0; auto.\n"; + fprintf fmt " Qed.\n"; + fprintf fmt " Hint Rewrite spec_extend_tr: extr.\n"; + fprintf fmt "\n"; + fprintf fmt " Let spec_cast_l: forall n m x1,\n"; + fprintf fmt " [%sn (Max.max n m)\n" c; + fprintf fmt " (castm (diff_r n m) (extend_tr x1 (snd (diff n m))))] =\n"; + fprintf fmt " [%sn n x1].\n" c; + fprintf fmt " Proof.\n"; + fprintf fmt " intros n m x1; case (diff_r n m); simpl castm.\n"; + fprintf fmt " rewrite spec_extend_tr; auto.\n"; + fprintf fmt " Qed.\n"; + fprintf fmt " Hint Rewrite spec_cast_l: extr.\n"; + fprintf fmt "\n"; + fprintf fmt " Let spec_cast_r: forall n m x1,\n"; + fprintf fmt " [%sn (Max.max n m)\n" c; + fprintf fmt " (castm (diff_l n m) (extend_tr x1 (fst (diff n m))))] =\n"; + fprintf fmt " [%sn m x1].\n" c; + fprintf fmt " Proof.\n"; + fprintf fmt " intros n m x1; case (diff_l n m); simpl castm.\n"; + fprintf fmt " rewrite spec_extend_tr; auto.\n"; + fprintf fmt " Qed.\n"; + fprintf fmt " Hint Rewrite spec_cast_r: extr.\n"; + fprintf fmt "\n"; + end; + + + fprintf fmt " Section LevelAndIter.\n"; + fprintf fmt "\n"; + fprintf fmt " Variable res: Set.\n"; + fprintf fmt " Variable xxx: res.\n"; + fprintf fmt " Variable P: Z -> Z -> res -> Prop.\n"; + fprintf fmt " (* Abstraction function for each level *)\n"; + for i = 0 to size do + fprintf fmt " Variable f%i: w%i -> w%i -> res.\n" i i i; + fprintf fmt " Variable f%in: forall n, w%i -> word w%i (S n) -> res.\n" i i i; + fprintf fmt " Variable fn%i: forall n, word w%i (S n) -> w%i -> res.\n" i i i; + if gen_proof then + begin + fprintf fmt " Variable Pf%i: forall x y, P [%s%i x] [%s%i y] (f%i x y).\n" i c i c i i; + if i == size then + begin + fprintf fmt " Variable Pf%in: forall n x y, P [%s%i x] (eval%in (S n) y) (f%in n x y).\n" i c i i i; + fprintf fmt " Variable Pfn%i: forall n x y, P (eval%in (S n) x) [%s%i y] (fn%i n x y).\n" i i c i i; + end + else + begin + + fprintf fmt " 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).\n" i (size - i) c i i i; + fprintf fmt " 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).\n" i (size - i) i c i i; + end; + end; + fprintf fmt "\n"; + done; + fprintf fmt " Variable fnn: forall n, word w%i (S n) -> word w%i (S n) -> res.\n" size size; + if gen_proof then + fprintf fmt " Variable Pfnn: forall n x y, P [%sn n x] [%sn n y] (fnn n x y).\n" c c; + fprintf fmt " Variable fnm: forall n m, word w%i (S n) -> word w%i (S m) -> res.\n" size size; + if gen_proof then + fprintf fmt " Variable Pfnm: forall n m x y, P [%sn n x] [%sn m y] (fnm n m x y).\n" c c; + fprintf fmt "\n"; + fprintf fmt " (* Special zero functions *)\n"; + fprintf fmt " Variable f0t: t_ -> res.\n"; + if gen_proof then + fprintf fmt " Variable Pf0t: forall x, P 0 [x] (f0t x).\n"; + fprintf fmt " Variable ft0: t_ -> res.\n"; + if gen_proof then + fprintf fmt " Variable Pft0: forall x, P [x] 0 (ft0 x).\n"; + fprintf fmt "\n"; + + + fprintf fmt " (* We level the two arguments before applying *)\n"; + fprintf fmt " (* the functions at each leval *)\n"; + fprintf fmt " Definition same_level (x y: t_): res :=\n"; + fprintf fmt " Eval lazy zeta beta iota delta ["; + for i = 0 to size do + fprintf fmt "extend%i " i; + done; + fprintf fmt "\n"; + fprintf fmt " GenBase.extend GenBase.extend_aux\n"; + fprintf fmt " ] in\n"; + fprintf fmt " match x, y with\n"; + for i = 0 to size do + for j = 0 to i - 1 do + fprintf fmt " | %s%i wx, %s%i wy => f%i wx (extend%i %i wy)\n" c i c j i j (i - j -1); + done; + fprintf fmt " | %s%i wx, %s%i wy => f%i wx wy\n" c i c i i; + for j = i + 1 to size do + fprintf fmt " | %s%i wx, %s%i wy => f%i (extend%i %i wx) wy\n" c i c j j i (j - i - 1); + done; + if i == size then + fprintf fmt " | %s%i wx, %sn m wy => fnn m (extend%i m wx) wy\n" c size c size + else + fprintf fmt " | %s%i wx, %sn m wy => fnn m (extend%i m (extend%i %i wx)) wy\n" c i c size i (size - i - 1); + done; + for i = 0 to size do + if i == size then + fprintf fmt " | %sn n wx, %s%i wy => fnn n wx (extend%i n wy)\n" c c size size + else + fprintf fmt " | %sn n wx, %s%i wy => fnn n wx (extend%i n (extend%i %i wy))\n" c c i size i (size - i - 1); + done; + fprintf fmt " | %sn n wx, Nn m wy =>\n" c; + fprintf fmt " let mn := Max.max n m in\n"; + fprintf fmt " let d := diff n m in\n"; + fprintf fmt " fnn mn\n"; + fprintf fmt " (castm (diff_r n m) (extend_tr wx (snd d)))\n"; + fprintf fmt " (castm (diff_l n m) (extend_tr wy (fst d)))\n"; + fprintf fmt " end.\n"; + fprintf fmt "\n"; + if gen_proof then + begin + fprintf fmt " Lemma spec_same_level: forall x y, P [x] [y] (same_level x y).\n"; + fprintf fmt " Proof.\n"; + fprintf fmt " intros x; case x; clear x; unfold same_level.\n"; + for i = 0 to size do + fprintf fmt " intros x y; case y; clear y.\n"; + for j = 0 to i - 1 do + fprintf fmt " intros y; rewrite spec_extend%in%i; apply Pf%i.\n" j i i; + done; + fprintf fmt " intros y; apply Pf%i.\n" i; + for j = i + 1 to size do + fprintf fmt " intros y; rewrite spec_extend%in%i; apply Pf%i.\n" i j j; + done; + if i == size then + fprintf fmt " intros m y; rewrite (spec_extend%in m); apply Pfnn.\n" size + else + fprintf fmt " intros m y; rewrite spec_extend%in%i; rewrite (spec_extend%in m); apply Pfnn.\n" i size size; + done; + fprintf fmt " intros n x y; case y; clear y.\n"; + for i = 0 to size do + if i == size then + fprintf fmt " intros y; rewrite (spec_extend%in n); apply Pfnn.\n" size + else + fprintf fmt " intros y; rewrite spec_extend%in%i; rewrite (spec_extend%in n); apply Pfnn.\n" i size size; + done; + fprintf fmt " intros m y; rewrite <- (spec_cast_l n m x); \n"; + fprintf fmt " rewrite <- (spec_cast_r n m y); apply Pfnn.\n"; + fprintf fmt " Qed.\n"; + fprintf fmt "\n"; + end; + + fprintf fmt " (* We level the two arguments before applying *)\n"; + fprintf fmt " (* the functions at each level (special zero case) *)\n"; + fprintf fmt " Definition same_level0 (x y: t_): res :=\n"; + fprintf fmt " Eval lazy zeta beta iota delta ["; + for i = 0 to size do + fprintf fmt "extend%i " i; + done; + fprintf fmt "\n"; + fprintf fmt " GenBase.extend GenBase.extend_aux\n"; + fprintf fmt " ] in\n"; + fprintf fmt " match x with\n"; + for i = 0 to size do + fprintf fmt " | %s%i wx =>\n" c i; + if (i == 0) then + fprintf fmt " if w0_eq0 wx then f0t y else\n"; + fprintf fmt " match y with\n"; + for j = 0 to i - 1 do + fprintf fmt " | %s%i wy =>\n" c j; + if j == 0 then + fprintf fmt " if w0_eq0 wy then ft0 x else\n"; + fprintf fmt " f%i wx (extend%i %i wy)\n" i j (i - j -1); + done; + fprintf fmt " | %s%i wy => f%i wx wy\n" c i i; + for j = i + 1 to size do + fprintf fmt " | %s%i wy => f%i (extend%i %i wx) wy\n" c j j i (j - i - 1); + done; + if i == size then + fprintf fmt " | %sn m wy => fnn m (extend%i m wx) wy\n" c size + else + fprintf fmt " | %sn m wy => fnn m (extend%i m (extend%i %i wx)) wy\n" c size i (size - i - 1); + fprintf fmt" end\n"; + done; + fprintf fmt " | %sn n wx =>\n" c; + fprintf fmt " match y with\n"; + for i = 0 to size do + fprintf fmt " | %s%i wy =>\n" c i; + if i == 0 then + fprintf fmt " if w0_eq0 wy then ft0 x else\n"; + if i == size then + fprintf fmt " fnn n wx (extend%i n wy)\n" size + else + fprintf fmt " fnn n wx (extend%i n (extend%i %i wy))\n" size i (size - i - 1); + done; + fprintf fmt " | %sn m wy =>\n" c; + fprintf fmt " let mn := Max.max n m in\n"; + fprintf fmt " let d := diff n m in\n"; + fprintf fmt " fnn mn\n"; + fprintf fmt " (castm (diff_r n m) (extend_tr wx (snd d)))\n"; + fprintf fmt " (castm (diff_l n m) (extend_tr wy (fst d)))\n"; + fprintf fmt " end\n"; + fprintf fmt " end.\n"; + fprintf fmt "\n"; + + if gen_proof then + begin + fprintf fmt " Lemma spec_same_level0: forall x y, P [x] [y] (same_level0 x y).\n"; + fprintf fmt " Proof.\n"; + fprintf fmt " intros x; case x; clear x; unfold same_level0.\n"; + for i = 0 to size do + fprintf fmt " intros x.\n"; + if i == 0 then + begin + fprintf fmt " generalize (spec_w0_eq0 x); case w0_eq0; intros H.\n"; + fprintf fmt " intros y; rewrite H; apply Pf0t.\n"; + fprintf fmt " clear H.\n"; + end; + fprintf fmt " intros y; case y; clear y.\n"; + for j = 0 to i - 1 do + fprintf fmt " intros y.\n"; + if j == 0 then + begin + fprintf fmt " generalize (spec_w0_eq0 y); case w0_eq0; intros H.\n"; + fprintf fmt " rewrite H; apply Pft0.\n"; + fprintf fmt " clear H.\n"; + end; + fprintf fmt " rewrite spec_extend%in%i; apply Pf%i.\n" j i i; + done; + fprintf fmt " intros y; apply Pf%i.\n" i; + for j = i + 1 to size do + fprintf fmt " intros y; rewrite spec_extend%in%i; apply Pf%i.\n" i j j; + done; + if i == size then + fprintf fmt " intros m y; rewrite (spec_extend%in m); apply Pfnn.\n" size + else + fprintf fmt " intros m y; rewrite spec_extend%in%i; rewrite (spec_extend%in m); apply Pfnn.\n" i size size; + done; + fprintf fmt " intros n x y; case y; clear y.\n"; + for i = 0 to size do + fprintf fmt " intros y.\n"; + if i = 0 then + begin + fprintf fmt " generalize (spec_w0_eq0 y); case w0_eq0; intros H.\n"; + fprintf fmt " rewrite H; apply Pft0.\n"; + fprintf fmt " clear H.\n"; + end; + if i == size then + fprintf fmt " rewrite (spec_extend%in n); apply Pfnn.\n" size + else + fprintf fmt " rewrite spec_extend%in%i; rewrite (spec_extend%in n); apply Pfnn.\n" i size size; + done; + fprintf fmt " intros m y; rewrite <- (spec_cast_l n m x); \n"; + fprintf fmt " rewrite <- (spec_cast_r n m y); apply Pfnn.\n"; + fprintf fmt " Qed.\n"; + fprintf fmt "\n"; + end; + + fprintf fmt " (* We iter the smaller argument with the bigger *)\n"; + fprintf fmt " Definition iter (x y: t_): res := \n"; + fprintf fmt " Eval lazy zeta beta iota delta ["; + for i = 0 to size do + fprintf fmt "extend%i " i; + done; + fprintf fmt "\n"; + fprintf fmt " GenBase.extend GenBase.extend_aux\n"; + fprintf fmt " ] in\n"; + fprintf fmt " match x, y with\n"; + for i = 0 to size do + for j = 0 to i - 1 do + fprintf fmt " | %s%i wx, %s%i wy => fn%i %i wx wy\n" c i c j j (i - j - 1); + done; + fprintf fmt " | %s%i wx, %s%i wy => f%i wx wy\n" c i c i i; + for j = i + 1 to size do + fprintf fmt " | %s%i wx, %s%i wy => f%in %i wx wy\n" c i c j i (j - i - 1); + done; + if i == size then + fprintf fmt " | %s%i wx, %sn m wy => f%in m wx wy\n" c size c size + else + fprintf fmt " | %s%i wx, %sn m wy => f%in m (extend%i %i wx) wy\n" c i c size i (size - i - 1); + done; + for i = 0 to size do + if i == size then + fprintf fmt " | %sn n wx, %s%i wy => fn%i n wx wy\n" c c size size + else + fprintf fmt " | %sn n wx, %s%i wy => fn%i n wx (extend%i %i wy)\n" c c i size i (size - i - 1); + done; + fprintf fmt " | %sn n wx, %sn m wy => fnm n m wx wy\n" c c; + fprintf fmt " end.\n"; + fprintf fmt "\n"; + + if gen_proof then + begin + fprintf fmt " Ltac zg_tac := try\n"; + fprintf fmt " (red; simpl Zcompare; auto;\n"; + fprintf fmt " let t := fresh \"H\" in (intros t; discriminate H)).\n"; + fprintf fmt " Lemma spec_iter: forall x y, P [x] [y] (iter x y).\n"; + fprintf fmt " Proof.\n"; + fprintf fmt " intros x; case x; clear x; unfold iter.\n"; + for i = 0 to size do + fprintf fmt " intros x y; case y; clear y.\n"; + for j = 0 to i - 1 do + fprintf fmt " intros y; rewrite spec_eval%in%i; apply (Pfn%i %i); zg_tac.\n" j (i - j) j (i - j - 1); + done; + fprintf fmt " intros y; apply Pf%i.\n" i; + for j = i + 1 to size do + fprintf fmt " intros y; rewrite spec_eval%in%i; apply (Pf%in %i); zg_tac.\n" i (j - i) i (j - i - 1); + done; + if i == size then + fprintf fmt " intros m y; rewrite spec_eval%in; apply Pf%in.\n" size size + else + fprintf fmt " intros m y; rewrite spec_extend%in%i; rewrite spec_eval%in; apply Pf%in.\n" i size size size; + done; + fprintf fmt " intros n x y; case y; clear y.\n"; + for i = 0 to size do + if i == size then + fprintf fmt " intros y; rewrite spec_eval%in; apply Pfn%i.\n" size size + else + fprintf fmt " intros y; rewrite spec_extend%in%i; rewrite spec_eval%in; apply Pfn%i.\n" i size size size; + done; + fprintf fmt " intros m y; apply Pfnm.\n"; + fprintf fmt " Qed.\n"; + fprintf fmt "\n"; + end; + + + fprintf fmt " (* We iter the smaller argument with the bigger (zero case) *)\n"; + fprintf fmt " Definition iter0 (x y: t_): res :=\n"; + fprintf fmt " Eval lazy zeta beta iota delta ["; + for i = 0 to size do + fprintf fmt "extend%i " i; + done; + fprintf fmt "\n"; + fprintf fmt " GenBase.extend GenBase.extend_aux\n"; + fprintf fmt " ] in\n"; + fprintf fmt " match x with\n"; + for i = 0 to size do + fprintf fmt " | %s%i wx =>\n" c i; + if (i == 0) then + fprintf fmt " if w0_eq0 wx then f0t y else\n"; + fprintf fmt " match y with\n"; + for j = 0 to i - 1 do + fprintf fmt " | %s%i wy =>\n" c j; + if j == 0 then + fprintf fmt " if w0_eq0 wy then ft0 x else\n"; + fprintf fmt " fn%i %i wx wy\n" j (i - j - 1); + done; + fprintf fmt " | %s%i wy => f%i wx wy\n" c i i; + for j = i + 1 to size do + fprintf fmt " | %s%i wy => f%in %i wx wy\n" c j i (j - i - 1); + done; + if i == size then + fprintf fmt " | %sn m wy => f%in m wx wy\n" c size + else + fprintf fmt " | %sn m wy => f%in m (extend%i %i wx) wy\n" c size i (size - i - 1); + fprintf fmt " end\n"; + done; + fprintf fmt " | %sn n wx =>\n" c; + fprintf fmt " match y with\n"; + for i = 0 to size do + fprintf fmt " | %s%i wy =>\n" c i; + if i == 0 then + fprintf fmt " if w0_eq0 wy then ft0 x else\n"; + if i == size then + fprintf fmt " fn%i n wx wy\n" size + else + fprintf fmt " fn%i n wx (extend%i %i wy)\n" size i (size - i - 1); + done; + fprintf fmt " | %sn m wy => fnm n m wx wy\n" c; + fprintf fmt " end\n"; + fprintf fmt " end.\n"; + fprintf fmt "\n"; + + if gen_proof then + begin + fprintf fmt " Lemma spec_iter0: forall x y, P [x] [y] (iter0 x y).\n"; + fprintf fmt " Proof.\n"; + fprintf fmt " intros x; case x; clear x; unfold iter0.\n"; + for i = 0 to size do + fprintf fmt " intros x.\n"; + if i == 0 then + begin + fprintf fmt " generalize (spec_w0_eq0 x); case w0_eq0; intros H.\n"; + fprintf fmt " intros y; rewrite H; apply Pf0t.\n"; + fprintf fmt " clear H.\n"; + end; + fprintf fmt " intros y; case y; clear y.\n"; + for j = 0 to i - 1 do + fprintf fmt " intros y.\n"; + if j == 0 then + begin + fprintf fmt " generalize (spec_w0_eq0 y); case w0_eq0; intros H.\n"; + fprintf fmt " rewrite H; apply Pft0.\n"; + fprintf fmt " clear H.\n"; + end; + fprintf fmt " rewrite spec_eval%in%i; apply (Pfn%i %i); zg_tac.\n" j (i - j) j (i - j - 1); + done; + fprintf fmt " intros y; apply Pf%i.\n" i; + for j = i + 1 to size do + fprintf fmt " intros y; rewrite spec_eval%in%i; apply (Pf%in %i); zg_tac.\n" i (j - i) i (j - i - 1); + done; + if i == size then + fprintf fmt " intros m y; rewrite spec_eval%in; apply Pf%in.\n" size size + else + fprintf fmt " intros m y; rewrite spec_extend%in%i; rewrite spec_eval%in; apply Pf%in.\n" i size size size; + done; + fprintf fmt " intros n x y; case y; clear y.\n"; + for i = 0 to size do + fprintf fmt " intros y.\n"; + if i = 0 then + begin + fprintf fmt " generalize (spec_w0_eq0 y); case w0_eq0; intros H.\n"; + fprintf fmt " rewrite H; apply Pft0.\n"; + fprintf fmt " clear H.\n"; + end; + if i == size then + fprintf fmt " rewrite spec_eval%in; apply Pfn%i.\n" size size + else + fprintf fmt " rewrite spec_extend%in%i; rewrite spec_eval%in; apply Pfn%i.\n" i size size size; + done; + fprintf fmt " intros m y; apply Pfnm.\n"; + fprintf fmt " Qed.\n"; + fprintf fmt "\n"; + end; + + + fprintf fmt " End LevelAndIter.\n"; + fprintf fmt "\n"; + + + fprintf fmt " (***************************************************************)\n"; + fprintf fmt " (* *)\n"; + fprintf fmt " (* Reduction *)\n"; + fprintf fmt " (* *)\n"; + fprintf fmt " (***************************************************************)\n\n"; + + fprintf fmt " Definition reduce_0 (x:w) := %s0 x.\n" c; + fprintf fmt " Definition reduce_1 :=\n"; + fprintf fmt " Eval lazy beta iota delta[reduce_n1] in\n"; + fprintf fmt " reduce_n1 _ _ zero w0_eq0 %s0 %s1.\n" c c; + for i = 2 to size do + fprintf fmt " Definition reduce_%i :=\n" i; + fprintf fmt " Eval lazy beta iota delta[reduce_n1] in\n"; + fprintf fmt " reduce_n1 _ _ zero w%i_eq0 reduce_%i %s%i.\n" + (i-1) (i-1) c i + done; + fprintf fmt " Definition reduce_%i :=\n" (size+1); + fprintf fmt " Eval lazy beta iota delta[reduce_n1] in\n"; + fprintf fmt " reduce_n1 _ _ zero w%i_eq0 reduce_%i (%sn 0).\n" + size size c; + + fprintf fmt " Definition reduce_n n := \n"; + fprintf fmt " Eval lazy beta iota delta[reduce_n] in\n"; + fprintf fmt " reduce_n _ _ zero reduce_%i %sn n.\n" (size + 1) c; + fprintf fmt "\n"; + + if gen_proof then + begin + fprintf fmt " Let spec_reduce_0: forall x, [reduce_0 x] = [%s0 x].\n" c; + fprintf fmt " Proof.\n"; + fprintf fmt " intros x; unfold to_Z, reduce_0.\n"; + fprintf fmt " auto.\n"; + fprintf fmt " Qed.\n"; + fprintf fmt " \n"; + + for i = 1 to size + 1 do + if (i == size + 1) then + fprintf fmt " Let spec_reduce_%i: forall x, [reduce_%i x] = [%sn 0 x].\n" i i c + else + fprintf fmt " Let spec_reduce_%i: forall x, [reduce_%i x] = [%s%i x].\n" i i c i; + fprintf fmt " Proof.\n"; + fprintf fmt " intros x; case x; unfold reduce_%i.\n" i; + fprintf fmt " exact (spec_0 w0_spec).\n"; + fprintf fmt " intros x1 y1.\n"; + fprintf fmt " generalize (spec_w%i_eq0 x1); \n" (i - 1); + fprintf fmt " case w%i_eq0; intros H1; auto.\n" (i - 1); + if i <> 1 then + fprintf fmt " rewrite spec_reduce_%i.\n" (i - 1); + fprintf fmt " unfold to_Z; rewrite znz_to_Z_%i.\n" i; + fprintf fmt " unfold to_Z in H1; rewrite H1; auto.\n"; + fprintf fmt " Qed.\n"; + fprintf fmt " \n"; + done; + + fprintf fmt " Let spec_reduce_n: forall n x, [reduce_n n x] = [%sn n x].\n" c; + fprintf fmt " Proof.\n"; + fprintf fmt " intros n; elim n; simpl reduce_n.\n"; + fprintf fmt " intros x; rewrite <- spec_reduce_%i; auto.\n" (size + 1); + fprintf fmt " intros n1 Hrec x; case x.\n"; + fprintf fmt " unfold to_Z; rewrite make_op_S; auto.\n"; + fprintf fmt " exact (spec_0 w0_spec).\n"; + fprintf fmt " intros x1 y1; case x1; auto.\n"; + fprintf fmt " rewrite Hrec.\n"; + fprintf fmt " rewrite spec_extendn0_0; auto.\n"; + fprintf fmt " Qed.\n"; + fprintf fmt " \n"; + end; + + fprintf fmt " (***************************************************************)\n"; + fprintf fmt " (* *)\n"; + fprintf fmt " (* Successor *)\n"; + fprintf fmt " (* *)\n"; + fprintf fmt " (***************************************************************)\n\n"; + + for i = 0 to size do + fprintf fmt " Definition w%i_succ_c := w%i_op.(znz_succ_c).\n" i i + done; + fprintf fmt "\n"; + + for i = 0 to size do + fprintf fmt " Definition w%i_succ := w%i_op.(znz_succ).\n" i i + done; + fprintf fmt "\n"; + + fprintf fmt " Definition succ x :=\n"; + fprintf fmt " match x with\n"; + for i = 0 to size-1 do + fprintf fmt " | %s%i wx =>\n" c i; + fprintf fmt " match w%i_succ_c wx with\n" i; + fprintf fmt " | C0 r => %s%i r\n" c i; + fprintf fmt " | C1 r => %s%i (WW one%i r)\n" c (i+1) i; + fprintf fmt " end\n"; + done; + fprintf fmt " | %s%i wx =>\n" c size; + fprintf fmt " match w%i_succ_c wx with\n" size; + fprintf fmt " | C0 r => %s%i r\n" c size; + fprintf fmt " | C1 r => %sn 0 (WW one%i r)\n" c size ; + fprintf fmt " end\n"; + fprintf fmt " | %sn n wx =>\n" c; + fprintf fmt " let op := make_op n in\n"; + fprintf fmt " match op.(znz_succ_c) wx with\n"; + fprintf fmt " | C0 r => %sn n r\n" c; + fprintf fmt " | C1 r => %sn (S n) (WW op.(znz_1) r)\n" c; + fprintf fmt " end\n"; + fprintf fmt " end.\n"; + fprintf fmt "\n"; + + fprintf fmt " Theorem spec_succ: forall n, [succ n] = [n] + 1.\n"; + if gen_proof then + begin + fprintf fmt " Proof.\n"; + fprintf fmt " intros n; case n; unfold succ, to_Z.\n"; + for i = 0 to size do + fprintf fmt " intros n1; generalize (spec_succ_c w%i_spec n1);\n" i; + fprintf fmt " unfold succ, to_Z, w%i_succ_c; case znz_succ_c; auto.\n" i; + fprintf fmt " intros ww H; rewrite <- H.\n"; + fprintf fmt " (rewrite znz_to_Z_%i; unfold interp_carry;\n" (i + 1); + fprintf fmt " apply f_equal2 with (f := Zplus); auto;\n"; + fprintf fmt " apply f_equal2 with (f := Zmult); auto;\n"; + fprintf fmt " exact (spec_1 w%i_spec)).\n" i; + done; + fprintf fmt " intros k n1; generalize (spec_succ_c (wn_spec k) n1).\n"; + fprintf fmt " unfold succ, to_Z; case znz_succ_c; auto.\n"; + fprintf fmt " intros ww H; rewrite <- H.\n"; + fprintf fmt " (rewrite (znz_to_Z_n k); unfold interp_carry;\n"; + fprintf fmt " apply f_equal2 with (f := Zplus); auto;\n"; + fprintf fmt " apply f_equal2 with (f := Zmult); auto;\n"; + fprintf fmt " exact (spec_1 (wn_spec k))).\n"; + fprintf fmt " Qed.\n"; + end + else fprintf fmt " Admitted.\n"; + fprintf fmt "\n"; + + + fprintf fmt " (***************************************************************)\n"; + fprintf fmt " (* *)\n"; + fprintf fmt " (* Adddition *)\n"; + fprintf fmt " (* *)\n"; + fprintf fmt " (***************************************************************)\n\n"; + for i = 0 to size do + fprintf fmt " Definition w%i_add_c := znz_add_c w%i_op.\n" i i; + fprintf fmt " Definition w%i_add x y :=\n" i; + fprintf fmt " match w%i_add_c x y with\n" i; + fprintf fmt " | C0 r => %s%i r\n" c i; + if i == size then + fprintf fmt " | C1 r => %sn 0 (WW one%i r)\n" c size + else + fprintf fmt " | C1 r => %s%i (WW one%i r)\n" c (i + 1) i; + fprintf fmt " end.\n"; + fprintf fmt "\n"; + done ; + fprintf fmt " Definition addn n (x y : word w%i (S n)) :=\n" size; + fprintf fmt " let op := make_op n in\n"; + fprintf fmt " match op.(znz_add_c) x y with\n"; + fprintf fmt " | C0 r => %sn n r\n" c; + fprintf fmt " | C1 r => %sn (S n) (WW op.(znz_1) r) end.\n" c; + fprintf fmt "\n"; + + + if gen_proof then + begin + for i = 0 to size do + fprintf fmt " Let spec_w%i_add: forall x y, [w%i_add x y] = [%s%i x] + [%s%i y].\n" i i c i c i; + fprintf fmt " Proof.\n"; + fprintf fmt " intros n m; unfold to_Z, w%i_add, w%i_add_c.\n" i i; + fprintf fmt " generalize (spec_add_c w%i_spec n m); case znz_add_c; auto.\n" i; + fprintf fmt " intros ww H; rewrite <- H.\n"; + fprintf fmt " rewrite znz_to_Z_%i; unfold interp_carry;\n" (i + 1); + fprintf fmt " apply f_equal2 with (f := Zplus); auto;\n"; + fprintf fmt " apply f_equal2 with (f := Zmult); auto;\n"; + fprintf fmt " exact (spec_1 w%i_spec).\n" i; + fprintf fmt " Qed.\n"; + fprintf fmt " Hint Rewrite spec_w%i_add: addr.\n" i; + fprintf fmt "\n"; + done; + fprintf fmt " Let spec_wn_add: forall n x y, [addn n x y] = [%sn n x] + [%sn n y].\n" c c; + fprintf fmt " Proof.\n"; + fprintf fmt " intros k n m; unfold to_Z, addn.\n"; + fprintf fmt " generalize (spec_add_c (wn_spec k) n m); case znz_add_c; auto.\n"; + fprintf fmt " intros ww H; rewrite <- H.\n"; + fprintf fmt " rewrite (znz_to_Z_n k); unfold interp_carry;\n"; + fprintf fmt " apply f_equal2 with (f := Zplus); auto;\n"; + fprintf fmt " apply f_equal2 with (f := Zmult); auto;\n"; + fprintf fmt " exact (spec_1 (wn_spec k)).\n"; + fprintf fmt " Qed.\n"; + fprintf fmt " Hint Rewrite spec_wn_add: addr.\n"; + end; + + fprintf fmt " Definition add := Eval lazy beta delta [same_level] in\n"; + fprintf fmt " (same_level t_ "; + for i = 0 to size do + fprintf fmt "w%i_add " i; + done; + fprintf fmt "addn).\n"; + fprintf fmt "\n"; + + fprintf fmt " Theorem spec_add: forall x y, [add x y] = [x] + [y].\n"; + if gen_proof then + begin + fprintf fmt " Proof.\n"; + fprintf fmt " unfold add.\n"; + fprintf fmt " generalize (spec_same_level t_ (fun x y res => [res] = x + y)).\n"; + fprintf fmt " unfold same_level; intros HH; apply HH; clear HH.\n"; + for i = 0 to size do + fprintf fmt " exact spec_w%i_add.\n" i; + done; + fprintf fmt " exact spec_wn_add.\n"; + fprintf fmt " Qed.\n"; + end + else + fprintf fmt " Admitted.\n"; + fprintf fmt "\n"; + + fprintf fmt " (***************************************************************)\n"; + fprintf fmt " (* *)\n"; + fprintf fmt " (* Predecessor *)\n"; + fprintf fmt " (* *)\n"; + fprintf fmt " (***************************************************************)\n\n"; + + for i = 0 to size do + fprintf fmt " Definition w%i_pred_c := w%i_op.(znz_pred_c).\n" i i + done; + fprintf fmt "\n"; + + fprintf fmt " Definition pred x :=\n"; + fprintf fmt " match x with\n"; + for i = 0 to size do + fprintf fmt " | %s%i wx =>\n" c i; + fprintf fmt " match w%i_pred_c wx with\n" i; + fprintf fmt " | C0 r => reduce_%i r\n" i; + fprintf fmt " | C1 r => zero\n"; + fprintf fmt " end\n"; + done; + fprintf fmt " | %sn n wx =>\n" c; + fprintf fmt " let op := make_op n in\n"; + fprintf fmt " match op.(znz_pred_c) wx with\n"; + fprintf fmt " | C0 r => reduce_n n r\n"; + fprintf fmt " | C1 r => zero\n"; + fprintf fmt " end\n"; + fprintf fmt " end.\n"; + fprintf fmt "\n"; + + fprintf fmt " Theorem spec_pred: forall x, 0 < [x] -> [pred x] = [x] - 1.\n"; + if gen_proof then + begin + fprintf fmt " Proof.\n"; + fprintf fmt " intros x; case x; unfold pred.\n"; + for i = 0 to size do + fprintf fmt " intros x1 H1; unfold w%i_pred_c; \n" i; + fprintf fmt " generalize (spec_pred_c w%i_spec x1); case znz_pred_c; intros y1.\n" i; + fprintf fmt " rewrite spec_reduce_%i; auto.\n" i; + fprintf fmt " unfold interp_carry; unfold to_Z.\n"; + fprintf fmt " case (spec_to_Z w%i_spec x1); intros HH1 HH2.\n" i; + fprintf fmt " case (spec_to_Z w%i_spec y1); intros HH3 HH4 HH5.\n" i; + fprintf fmt " assert (znz_to_Z w%i_op x1 - 1 < 0); auto with zarith.\n" i; + fprintf fmt " unfold to_Z in H1; auto with zarith.\n"; + done; + fprintf fmt " intros n x1 H1; \n"; + fprintf fmt " generalize (spec_pred_c (wn_spec n) x1); case znz_pred_c; intros y1.\n"; + fprintf fmt " rewrite spec_reduce_n; auto.\n"; + fprintf fmt " unfold interp_carry; unfold to_Z.\n"; + fprintf fmt " case (spec_to_Z (wn_spec n) x1); intros HH1 HH2.\n"; + fprintf fmt " case (spec_to_Z (wn_spec n) y1); intros HH3 HH4 HH5.\n"; + fprintf fmt " assert (znz_to_Z (make_op n) x1 - 1 < 0); auto with zarith.\n"; + fprintf fmt " unfold to_Z in H1; auto with zarith.\n"; + fprintf fmt " Qed.\n"; + fprintf fmt " \n"; + + fprintf fmt " Let spec_pred0: forall x, [x] = 0 -> [pred x] = 0.\n"; + fprintf fmt " Proof.\n"; + fprintf fmt " intros x; case x; unfold pred.\n"; + for i = 0 to size do + fprintf fmt " intros x1 H1; unfold w%i_pred_c; \n" i; + fprintf fmt " generalize (spec_pred_c w%i_spec x1); case znz_pred_c; intros y1.\n" i; + fprintf fmt " unfold interp_carry; unfold to_Z.\n"; + fprintf fmt " unfold to_Z in H1; auto with zarith.\n"; + fprintf fmt " case (spec_to_Z w%i_spec y1); intros HH3 HH4; auto with zarith.\n" i; + fprintf fmt " intros; exact (spec_0 w0_spec).\n"; + done; + fprintf fmt " intros n x1 H1; \n"; + fprintf fmt " generalize (spec_pred_c (wn_spec n) x1); case znz_pred_c; intros y1.\n"; + fprintf fmt " unfold interp_carry; unfold to_Z.\n"; + fprintf fmt " unfold to_Z in H1; auto with zarith.\n"; + fprintf fmt " case (spec_to_Z (wn_spec n) y1); intros HH3 HH4; auto with zarith.\n"; + fprintf fmt " intros; exact (spec_0 w0_spec).\n"; + fprintf fmt " Qed.\n"; + end + else + fprintf fmt " Admitted.\n"; + fprintf fmt " \n"; + + + fprintf fmt " (***************************************************************)\n"; + fprintf fmt " (* *)\n"; + fprintf fmt " (* Subtraction *)\n"; + fprintf fmt " (* *)\n"; + fprintf fmt " (***************************************************************)\n\n"; + + for i = 0 to size do + fprintf fmt " Definition w%i_sub_c := w%i_op.(znz_sub_c).\n" i i + done; + fprintf fmt "\n"; + + for i = 0 to size do + fprintf fmt " Definition w%i_sub x y :=\n" i; + fprintf fmt " match w%i_sub_c x y with\n" i; + fprintf fmt " | C0 r => reduce_%i r\n" i; + fprintf fmt " | C1 r => zero\n"; + fprintf fmt " end.\n" + done; + fprintf fmt "\n"; + + fprintf fmt " Definition subn n (x y : word w%i (S n)) :=\n" size; + fprintf fmt " let op := make_op n in\n"; + fprintf fmt " match op.(znz_sub_c) x y with\n"; + fprintf fmt " | C0 r => %sn n r\n" c; + fprintf fmt " | C1 r => N0 w_0"; + fprintf fmt " end.\n"; + fprintf fmt "\n"; + + if gen_proof then + begin + for i = 0 to size do + fprintf fmt " 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].\n" i c i c i i c i c i; + fprintf fmt " Proof.\n"; + fprintf fmt " intros n m; unfold w%i_sub, w%i_sub_c.\n" i i; + fprintf fmt " generalize (spec_sub_c w%i_spec n m); case znz_sub_c; \n" i; + if i == 0 then + fprintf fmt " intros x; auto.\n" + else + fprintf fmt " intros x; try rewrite spec_reduce_%i; auto.\n" i; + fprintf fmt " unfold interp_carry; unfold zero, w_0, to_Z.\n"; + fprintf fmt " rewrite (spec_0 w0_spec).\n"; + fprintf fmt " case (spec_to_Z w%i_spec x); intros; auto with zarith.\n" i; + fprintf fmt " Qed.\n"; + fprintf fmt "\n"; + done; + + fprintf fmt " Let spec_wn_sub: forall n x y, [%sn n y] <= [%sn n x] -> [subn n x y] = [%sn n x] - [%sn n y].\n" c c c c; + fprintf fmt " Proof.\n"; + fprintf fmt " intros k n m; unfold subn.\n"; + fprintf fmt " generalize (spec_sub_c (wn_spec k) n m); case znz_sub_c; \n"; + fprintf fmt " intros x; auto.\n"; + fprintf fmt " unfold interp_carry, to_Z.\n"; + fprintf fmt " case (spec_to_Z (wn_spec k) x); intros; auto with zarith.\n"; + fprintf fmt " Qed.\n"; + fprintf fmt "\n"; + end; + + fprintf fmt " Definition sub := Eval lazy beta delta [same_level] in\n"; + fprintf fmt " (same_level t_ "; + for i = 0 to size do + fprintf fmt "w%i_sub " i; + done; + fprintf fmt "subn).\n"; + fprintf fmt "\n"; + + fprintf fmt " Theorem spec_sub: forall x y, [y] <= [x] -> [sub x y] = [x] - [y].\n"; + if gen_proof then + begin + fprintf fmt " Proof.\n"; + fprintf fmt " unfold sub.\n"; + fprintf fmt " generalize (spec_same_level t_ (fun x y res => y <= x -> [res] = x - y)).\n"; + fprintf fmt " unfold same_level; intros HH; apply HH; clear HH.\n"; + for i = 0 to size do + fprintf fmt " exact spec_w%i_sub.\n" i; + done; + fprintf fmt " exact spec_wn_sub.\n"; + fprintf fmt " Qed.\n"; + end + else + fprintf fmt " Admitted.\n"; + fprintf fmt "\n"; + + if gen_proof then + begin + for i = 0 to size do + fprintf fmt " Let spec_w%i_sub0: forall x y, [%s%i x] < [%s%i y] -> [w%i_sub x y] = 0.\n" i c i c i i; + fprintf fmt " Proof.\n"; + fprintf fmt " intros n m; unfold w%i_sub, w%i_sub_c.\n" i i; + fprintf fmt " generalize (spec_sub_c w%i_spec n m); case znz_sub_c; \n" i; + fprintf fmt " intros x; unfold interp_carry.\n"; + fprintf fmt " unfold to_Z; case (spec_to_Z w%i_spec x); intros; auto with zarith.\n" i; + fprintf fmt " intros; unfold to_Z, zero, w_0; rewrite (spec_0 w0_spec); auto.\n"; + fprintf fmt " Qed.\n"; + fprintf fmt "\n"; + done; + + fprintf fmt " Let spec_wn_sub0: forall n x y, [%sn n x] < [%sn n y] -> [subn n x y] = 0.\n" c c; + fprintf fmt " Proof.\n"; + fprintf fmt " intros k n m; unfold subn.\n"; + fprintf fmt " generalize (spec_sub_c (wn_spec k) n m); case znz_sub_c; \n"; + fprintf fmt " intros x; unfold interp_carry.\n"; + fprintf fmt " unfold to_Z; case (spec_to_Z (wn_spec k) x); intros; auto with zarith.\n"; + fprintf fmt " intros; unfold to_Z, w_0; rewrite (spec_0 (w0_spec)); auto.\n"; + fprintf fmt " Qed.\n"; + fprintf fmt "\n"; + end; + + fprintf fmt " Theorem spec_sub0: forall x y, [x] < [y] -> [sub x y] = 0.\n"; + if gen_proof then + begin + fprintf fmt " Proof.\n"; + fprintf fmt " unfold sub.\n"; + fprintf fmt " generalize (spec_same_level t_ (fun x y res => x < y -> [res] = 0)).\n"; + fprintf fmt " unfold same_level; intros HH; apply HH; clear HH.\n"; + for i = 0 to size do + fprintf fmt " exact spec_w%i_sub0.\n" i; + done; + fprintf fmt " exact spec_wn_sub0.\n"; + fprintf fmt " Qed.\n"; + end + else + fprintf fmt " Admitted.\n"; + fprintf fmt "\n"; + + + fprintf fmt " (***************************************************************)\n"; + fprintf fmt " (* *)\n"; + fprintf fmt " (* Comparison *)\n"; + fprintf fmt " (* *)\n"; + fprintf fmt " (***************************************************************)\n\n"; + + for i = 0 to size do + fprintf fmt " Definition compare_%i := w%i_op.(znz_compare).\n" i i; + fprintf fmt " Definition comparen_%i :=\n" i; + let s0 = if i = 0 then "w_0" else "W0" in + fprintf fmt + " compare_mn_1 w%i w%i %s compare_%i (compare_%i %s) compare_%i.\n" + i i s0 i i s0 i + done; + fprintf fmt "\n"; + + fprintf fmt " Definition comparenm n m wx wy :=\n"; + fprintf fmt " let mn := Max.max n m in\n"; + fprintf fmt " let d := diff n m in\n"; + fprintf fmt " let op := make_op mn in\n"; + fprintf fmt " op.(znz_compare)\n"; + fprintf fmt " (castm (diff_r n m) (extend_tr wx (snd d)))\n"; + fprintf fmt " (castm (diff_l n m) (extend_tr wy (fst d))).\n"; + fprintf fmt "\n"; + + fprintf fmt " Definition compare := Eval lazy beta delta [iter] in \n"; + fprintf fmt " (iter _ \n"; + for i = 0 to size do + fprintf fmt " compare_%i\n" i; + fprintf fmt " (fun n x y => opp_compare (comparen_%i (S n) y x))\n" i; + fprintf fmt " (fun n => comparen_%i (S n))\n" i; + done; + fprintf fmt " comparenm).\n"; + fprintf fmt "\n"; + + if gen_proof then + begin + for i = 0 to size do + fprintf fmt " Let spec_compare_%i: forall x y,\n" i; + fprintf fmt " match compare_%i x y with \n" i; + fprintf fmt " Eq => [%s%i x] = [%s%i y]\n" c i c i; + fprintf fmt " | Lt => [%s%i x] < [%s%i y]\n" c i c i; + fprintf fmt " | Gt => [%s%i x] > [%s%i y]\n" c i c i; + fprintf fmt " end.\n"; + fprintf fmt " Proof.\n"; + fprintf fmt " unfold compare_%i, to_Z; exact (spec_compare w%i_spec).\n" i i; + fprintf fmt " Qed.\n"; + fprintf fmt "\n"; + + fprintf fmt " Let spec_comparen_%i:\n" i; + fprintf fmt " forall (n : nat) (x : word w%i n) (y : w%i),\n" i i; + fprintf fmt " match comparen_%i n x y with\n" i; + fprintf fmt " | Eq => eval%in n x = [%s%i y]\n" i c i; + fprintf fmt " | Lt => eval%in n x < [%s%i y]\n" i c i; + fprintf fmt " | Gt => eval%in n x > [%s%i y]\n" i c i; + fprintf fmt " end.\n"; + fprintf fmt " intros n x y.\n"; + fprintf fmt " unfold comparen_%i, to_Z; rewrite spec_gen_eval%in.\n" i i; + fprintf fmt " apply spec_compare_mn_1.\n"; + fprintf fmt " exact (spec_0 w%i_spec).\n" i; + if i == 0 then + fprintf fmt " intros x1; exact (spec_compare w%i_spec w_0 x1).\n" i + else + fprintf fmt " intros x1; exact (spec_compare w%i_spec W0 x1).\n" i; + fprintf fmt " exact (spec_to_Z w%i_spec).\n" i; + fprintf fmt " exact (spec_compare w%i_spec).\n" i; + fprintf fmt " exact (spec_compare w%i_spec).\n" i; + fprintf fmt " exact (spec_to_Z w%i_spec).\n" i; + fprintf fmt " Qed.\n"; + fprintf fmt "\n"; + + done; + + fprintf fmt " Let spec_opp_compare: forall c (u v: Z),\n"; + fprintf fmt " match c with Eq => u = v | Lt => u < v | Gt => u > v end ->\n"; + fprintf fmt " match opp_compare c with Eq => v = u | Lt => v < u | Gt => v > u end.\n"; + fprintf fmt " Proof.\n"; + fprintf fmt " intros c u v; case c; unfold opp_compare; auto with zarith.\n"; + fprintf fmt " Qed.\n"; + fprintf fmt "\n"; + end; + + fprintf fmt " Theorem spec_compare: forall x y,\n"; + fprintf fmt " match compare x y with \n"; + fprintf fmt " Eq => [x] = [y]\n"; + fprintf fmt " | Lt => [x] < [y]\n"; + fprintf fmt " | Gt => [x] > [y]\n"; + fprintf fmt " end.\n"; + if gen_proof then + begin + fprintf fmt " Proof.\n"; + fprintf fmt " refine (spec_iter _ (fun x y res => \n"; + fprintf fmt " match res with \n"; + fprintf fmt " Eq => x = y\n"; + fprintf fmt " | Lt => x < y\n"; + fprintf fmt " | Gt => x > y\n"; + fprintf fmt " end)\n"; + for i = 0 to size do + fprintf fmt " compare_%i\n" i; + fprintf fmt " (fun n x y => opp_compare (comparen_%i (S n) y x))\n" i; + fprintf fmt " (fun n => comparen_%i (S n)) _ _ _\n" i; + done; + fprintf fmt " comparenm _).\n"; + + for i = 0 to size - 1 do + fprintf fmt " exact spec_compare_%i.\n" i; + fprintf fmt " intros n x y H;apply spec_opp_compare; apply spec_comparen_%i.\n" i; + fprintf fmt " intros n x y H; exact (spec_comparen_%i (S n) x y).\n" i; + done; + fprintf fmt " exact spec_compare_%i.\n" size; + fprintf fmt " intros n x y;apply spec_opp_compare; apply spec_comparen_%i.\n" size; + fprintf fmt " intros n; exact (spec_comparen_%i (S n)).\n" size; + fprintf fmt " intros n m x y; unfold comparenm.\n"; + fprintf fmt " rewrite <- (spec_cast_l n m x); rewrite <- (spec_cast_r n m y).\n"; + fprintf fmt " unfold to_Z; apply (spec_compare (wn_spec (Max.max n m))).\n"; + fprintf fmt " Qed.\n"; + end + else + fprintf fmt " Admitted.\n"; + fprintf fmt "\n"; + + fprintf fmt " Definition eq_bool x y :=\n"; + fprintf fmt " match compare x y with\n"; + fprintf fmt " | Eq => true\n"; + fprintf fmt " | _ => false\n"; + fprintf fmt " end.\n"; + fprintf fmt "\n"; + + + fprintf fmt " Theorem spec_eq_bool: forall x y,\n"; + fprintf fmt " if eq_bool x y then [x] = [y] else [x] <> [y].\n"; + if gen_proof then + begin + fprintf fmt " Proof.\n"; + fprintf fmt " intros x y; unfold eq_bool.\n"; + fprintf fmt " generalize (spec_compare x y); case compare; auto with zarith.\n"; + fprintf fmt " Qed.\n"; + end + else + fprintf fmt " Admitted.\n"; + fprintf fmt "\n"; + + + + fprintf fmt " (***************************************************************)\n"; + fprintf fmt " (* *)\n"; + fprintf fmt " (* Multiplication *)\n"; + fprintf fmt " (* *)\n"; + fprintf fmt " (***************************************************************)\n\n"; + for i = 0 to size do + fprintf fmt " Definition w%i_mul_c := w%i_op.(znz_mul_c).\n" i i + done; + fprintf fmt "\n"; + + for i = 0 to size do + let s0 = if i = 0 then "w_0" else "W0" in + fprintf fmt " Definition w%i_mul_add :=\n" i; + fprintf fmt " Eval lazy beta delta [w_mul_add] in\n"; + fprintf fmt " %sw_mul_add w%i %s w%i_succ w%i_add_c w%i_mul_c.\n" + "@" i s0 i i i + done; + fprintf fmt "\n"; + + for i = 0 to size do + fprintf fmt " Definition w%i_0W := w%i_op.(znz_0W).\n" i i + done; + fprintf fmt "\n"; + + for i = 0 to size do + let s0 = if i = 0 then "w_0" else "W0" in + fprintf fmt " Definition w%i_mul_add_n1 :=\n" i; + fprintf fmt + " %sgen_mul_add_n1 w%i %s w%i_op.(znz_WW) w%i_0W w%i_mul_add.\n" + "@" i s0 i i i + done; + fprintf fmt "\n"; + + begin + for i = 0 to size - 1 do + fprintf fmt " Let to_Z%i n :=\n" i; + fprintf fmt " match n return word w%i (S n) -> t_ with\n" i; + for j = 0 to size - i do + if (i + j) == size then + begin + fprintf fmt " | %i%s => fun x => %sn 0 x\n" j "%nat" c; + fprintf fmt " | %i%s => fun x => %sn 1 x\n" (j + 1) "%nat" c + end + else + fprintf fmt " | %i%s => fun x => %s%i x\n" j "%nat" c (i + j + 1) + done; + fprintf fmt " | _ => fun _ => N0 w_0\n"; + fprintf fmt " end.\n"; + fprintf fmt "\n"; + done; + + + if gen_proof then + for i = 0 to size - 1 do + fprintf fmt "Theorem to_Z%i_spec:\n" i; + fprintf fmt " forall n x, Z_of_nat n <= %i -> [to_Z%i n x] = znz_to_Z (nmake_op _ w%i_op (S n)) x.\n" (size + 1 - i) i i; + for j = 1 to size + 2 - i do + fprintf fmt " intros n; case n; clear n.\n"; + fprintf fmt " unfold to_Z%i.\n" i; + fprintf fmt " intros x H; rewrite spec_eval%in%i; auto.\n" i j; + done; + fprintf fmt " intros n x.\n"; + fprintf fmt " repeat rewrite inj_S; unfold Zsucc; auto with zarith.\n"; + fprintf fmt " Qed.\n"; + fprintf fmt "\n"; + done; + end; + + for i = 0 to size do + fprintf fmt " Definition w%i_mul n x y :=\n" i; + if i == 0 then + fprintf fmt " let (w,r) := w%i_mul_add_n1 (S n) x y w_0 in\n" i + else + fprintf fmt " let (w,r) := w%i_mul_add_n1 (S n) x y W0 in\n" i; + if i == size then + begin + fprintf fmt " if w%i_eq0 w then %sn n r\n" i c; + fprintf fmt " else %sn (S n) (WW (extend%i n w) r).\n" c i; + end + else + begin + fprintf fmt " if w%i_eq0 w then to_Z%i n r\n" i i; + fprintf fmt " else to_Z%i (S n) (WW (extend%i n w) r).\n" i i; + end; + fprintf fmt "\n"; + done; + + fprintf fmt " Definition mulnm n m x y :=\n"; + fprintf fmt " let mn := Max.max n m in\n"; + fprintf fmt " let d := diff n m in\n"; + fprintf fmt " let op := make_op mn in\n"; + fprintf fmt " reduce_n (S mn) (op.(znz_mul_c)\n"; + fprintf fmt " (castm (diff_r n m) (extend_tr x (snd d)))\n"; + fprintf fmt " (castm (diff_l n m) (extend_tr y (fst d)))).\n"; + fprintf fmt "\n"; + + fprintf fmt " Definition mul := Eval lazy beta delta [iter0] in \n"; + fprintf fmt " (iter0 t_ \n"; + for i = 0 to size do + fprintf fmt " (fun x y => reduce_%i (w%i_mul_c x y)) \n" (i + 1) i; + fprintf fmt " (fun n x y => w%i_mul n y x)\n" i; + fprintf fmt " w%i_mul\n" i; + done; + fprintf fmt " mulnm\n"; + fprintf fmt " (fun _ => N0 w_0)\n"; + fprintf fmt " (fun _ => N0 w_0)\n"; + fprintf fmt " ).\n"; + fprintf fmt "\n"; + if gen_proof then + begin + for i = 0 to size do + fprintf fmt " Let spec_w%i_mul_add: forall x y z,\n" i; + fprintf fmt " let (q,r) := w%i_mul_add x y z in\n" i; + fprintf fmt " znz_to_Z w%i_op q * (base (znz_digits w%i_op)) + znz_to_Z w%i_op r =\n" i i i; + fprintf fmt " znz_to_Z w%i_op x * znz_to_Z w%i_op y + znz_to_Z w%i_op z :=\n" i i i ; + fprintf fmt " (spec_mul_add w%i_spec).\n" i; + fprintf fmt "\n"; + done; + + for i = 0 to size do + + + fprintf fmt " Theorem spec_w%i_mul_add_n1: forall n x y z,\n" i; + fprintf fmt " let (q,r) := w%i_mul_add_n1 n x y z in\n" i; + fprintf fmt " znz_to_Z w%i_op q * (base (znz_digits (nmake_op _ w%i_op n))) +\n" i i; + fprintf fmt " znz_to_Z (nmake_op _ w%i_op n) r =\n" i; + fprintf fmt " znz_to_Z (nmake_op _ w%i_op n) x * znz_to_Z w%i_op y +\n" i i; + fprintf fmt " znz_to_Z w%i_op z.\n" i; + fprintf fmt " Proof.\n"; + fprintf fmt " intros n x y z; unfold w%i_mul_add_n1.\n" i; + fprintf fmt " rewrite nmake_gen.\n"; + fprintf fmt " rewrite digits_gend.\n"; + fprintf fmt " change (base (GenBase.gen_digits (znz_digits w%i_op) n)) with\n" i; + fprintf fmt " (GenBase.gen_wB (znz_digits w%i_op) n).\n" i; + fprintf fmt " apply spec_gen_mul_add_n1; auto.\n"; + if i == 0 then fprintf fmt " exact (spec_0 w%i_spec).\n" i; + fprintf fmt " exact (spec_WW w%i_spec).\n" i; + fprintf fmt " exact (spec_0W w%i_spec).\n" i; + fprintf fmt " exact (spec_mul_add w%i_spec).\n" i; + fprintf fmt " Qed.\n"; + fprintf fmt "\n"; + done; + + fprintf fmt " Lemma nmake_op_WW: forall ww ww1 n x y,\n"; + fprintf fmt " znz_to_Z (nmake_op ww ww1 (S n)) (WW x y) =\n"; + fprintf fmt " znz_to_Z (nmake_op ww ww1 n) x * base (znz_digits (nmake_op ww ww1 n)) +\n"; + fprintf fmt " znz_to_Z (nmake_op ww ww1 n) y.\n"; + fprintf fmt " auto.\n"; + fprintf fmt " Qed.\n"; + fprintf fmt "\n"; + + for i = 0 to size do + fprintf fmt " Lemma extend%in_spec: forall n x1,\n" i; + fprintf fmt " znz_to_Z (nmake_op _ w%i_op (S n)) (extend%i n x1) = \n" i i; + fprintf fmt " znz_to_Z w%i_op x1.\n" i; + fprintf fmt " Proof.\n"; + fprintf fmt " intros n1 x2; rewrite nmake_gen.\n"; + fprintf fmt " unfold extend%i.\n" i; + fprintf fmt " rewrite GenBase.spec_extend; auto.\n"; + if (i == 0) then + fprintf fmt " intros l; simpl; unfold w_0; rewrite (spec_0 w0_spec); ring.\n"; + fprintf fmt " Qed.\n"; + fprintf fmt "\n"; + + done; + + fprintf fmt " Lemma spec_muln:\n"; + fprintf fmt " forall n (x: word _ (S n)) y,\n"; + fprintf fmt " [%sn (S n) (znz_mul_c (make_op n) x y)] = [%sn n x] * [%sn n y].\n" c c c; + fprintf fmt " Proof.\n"; + fprintf fmt " intros n x y; unfold to_Z.\n"; + fprintf fmt " rewrite <- (spec_mul_c (wn_spec n)).\n"; + fprintf fmt " rewrite make_op_S.\n"; + fprintf fmt " case znz_mul_c; auto.\n"; + fprintf fmt " Qed.\n"; + end; + + fprintf fmt " Theorem spec_mul: forall x y, [mul x y] = [x] * [y].\n"; + if gen_proof then + begin + fprintf fmt " Proof.\n"; + for i = 0 to size do + fprintf fmt " assert(F%i: \n" i; + fprintf fmt " forall n x y,\n"; + if i <> size then + fprintf fmt " Z_of_nat n <= %i -> " (size - i); + fprintf fmt " [w%i_mul n x y] = eval%in (S n) x * [%s%i y]).\n" i i c i; + if i == size then + fprintf fmt " intros n x y; unfold w%i_mul.\n" i + else + fprintf fmt " intros n x y H; unfold w%i_mul.\n" i; + if i == 0 then + fprintf fmt " generalize (spec_w%i_mul_add_n1 (S n) x y w_0).\n" i + else + fprintf fmt " generalize (spec_w%i_mul_add_n1 (S n) x y W0).\n" i; + fprintf fmt " case w%i_mul_add_n1; intros x1 y1.\n" i; + fprintf fmt " change (znz_to_Z (nmake_op _ w%i_op (S n)) x) with (eval%in (S n) x).\n" i i; + fprintf fmt " change (znz_to_Z w%i_op y) with ([%s%i y]).\n" i c i; + if i == 0 then + fprintf fmt " unfold w_0; rewrite (spec_0 w0_spec); rewrite Zplus_0_r.\n" + else + fprintf fmt " change (znz_to_Z w%i_op W0) with 0; rewrite Zplus_0_r.\n" i; + fprintf fmt " intros H1; rewrite <- H1; clear H1.\n"; + fprintf fmt " generalize (spec_w%i_eq0 x1); case w%i_eq0; intros HH.\n" i i; + fprintf fmt " unfold to_Z in HH; rewrite HH.\n"; + if i == size then + begin + fprintf fmt " rewrite spec_eval%in; unfold eval%in, nmake_op%i; auto.\n" i i i; + fprintf fmt " rewrite spec_eval%in; unfold eval%in, nmake_op%i.\n" i i i + end + else + begin + fprintf fmt " rewrite to_Z%i_spec; auto with zarith.\n" i; + fprintf fmt " rewrite to_Z%i_spec; try (rewrite inj_S; auto with zarith).\n" i + end; + fprintf fmt " rewrite nmake_op_WW; rewrite extend%in_spec; auto.\n" i; + done; + fprintf fmt " refine (spec_iter0 t_ (fun x y res => [res] = x * y)\n"; + for i = 0 to size do + fprintf fmt " (fun x y => reduce_%i (w%i_mul_c x y)) \n" (i + 1) i; + fprintf fmt " (fun n x y => w%i_mul n y x)\n" i; + fprintf fmt " w%i_mul _ _ _\n" i; + done; + fprintf fmt " mulnm _\n"; + fprintf fmt " (fun _ => N0 w_0) _\n"; + fprintf fmt " (fun _ => N0 w_0) _\n"; + fprintf fmt " ).\n"; + for i = 0 to size do + fprintf fmt " intros x y; rewrite spec_reduce_%i.\n" (i + 1); + fprintf fmt " unfold w%i_mul_c, to_Z.\n" i; + fprintf fmt " generalize (spec_mul_c w%i_spec x y).\n" i; + fprintf fmt " intros HH; rewrite <- HH; clear HH; auto.\n"; + if i == size then + begin + fprintf fmt " intros n x y; rewrite F%i; auto with zarith.\n" i; + fprintf fmt " intros n x y; rewrite F%i; auto with zarith. \n" i; + end + else + begin + fprintf fmt " intros n x y H; rewrite F%i; auto with zarith.\n" i; + fprintf fmt " intros n x y H; rewrite F%i; auto with zarith. \n" i; + end; + done; + fprintf fmt " intros n m x y; unfold mulnm.\n"; + fprintf fmt " rewrite spec_reduce_n.\n"; + fprintf fmt " rewrite <- (spec_cast_l n m x).\n"; + fprintf fmt " rewrite <- (spec_cast_r n m y).\n"; + fprintf fmt " rewrite spec_muln; rewrite spec_cast_l; rewrite spec_cast_r; auto.\n"; + fprintf fmt " intros x; unfold to_Z, w_0; rewrite (spec_0 w0_spec); ring.\n"; + fprintf fmt " intros x; unfold to_Z, w_0; rewrite (spec_0 w0_spec); ring.\n"; + fprintf fmt " Qed.\n"; + end + else + fprintf fmt " Admitted.\n"; + fprintf fmt "\n"; + + fprintf fmt " (***************************************************************)\n"; + fprintf fmt " (* *)\n"; + fprintf fmt " (* Square *)\n"; + fprintf fmt " (* *)\n"; + fprintf fmt " (***************************************************************)\n\n"; + for i = 0 to size do + fprintf fmt " Definition w%i_square_c := w%i_op.(znz_square_c).\n" i i + done; + fprintf fmt "\n"; + + fprintf fmt " Definition square x :=\n"; + fprintf fmt " match x with\n"; + fprintf fmt " | %s0 wx => reduce_1 (w0_square_c wx)\n" c; + for i = 1 to size - 1 do + fprintf fmt " | %s%i wx => %s%i (w%i_square_c wx)\n" c i c (i+1) i + done; + fprintf fmt " | %s%i wx => %sn 0 (w%i_square_c wx)\n" c size c size; + fprintf fmt " | %sn n wx =>\n" c; + fprintf fmt " let op := make_op n in\n"; + fprintf fmt " %sn (S n) (op.(znz_square_c) wx)\n" c; + fprintf fmt " end.\n"; + fprintf fmt "\n"; + + fprintf fmt " Theorem spec_square: forall x, [square x] = [x] * [x].\n"; + if gen_proof then + begin + fprintf fmt " Proof.\n"; + fprintf fmt " intros x; case x; unfold square; clear x.\n"; + fprintf fmt " intros x; rewrite spec_reduce_1; unfold to_Z.\n"; + fprintf fmt " exact (spec_square_c w%i_spec x).\n" 0; + for i = 1 to size do + fprintf fmt " intros x; unfold to_Z.\n"; + fprintf fmt " exact (spec_square_c w%i_spec x).\n" i; + done; + fprintf fmt " intros n x; unfold to_Z.\n"; + fprintf fmt " rewrite make_op_S.\n"; + fprintf fmt " exact (spec_square_c (wn_spec n) x).\n"; + fprintf fmt "Qed.\n"; + end + else + fprintf fmt "Admitted.\n"; + fprintf fmt "\n"; + + + fprintf fmt " (***************************************************************)\n"; + fprintf fmt " (* *)\n"; + fprintf fmt " (* Power *)\n"; + fprintf fmt " (* *)\n"; + fprintf fmt " (***************************************************************)\n\n"; + fprintf fmt " Fixpoint power_pos (x:%s) (p:positive) {struct p} : %s :=\n" + t t; + fprintf fmt " match p with\n"; + fprintf fmt " | xH => x\n"; + fprintf fmt " | xO p => square (power_pos x p)\n"; + fprintf fmt " | xI p => mul (square (power_pos x p)) x\n"; + fprintf fmt " end.\n"; + fprintf fmt "\n"; + + fprintf fmt " Theorem spec_power_pos: forall x n, [power_pos x n] = [x] ^ Zpos n.\n"; + if gen_proof then + begin + fprintf fmt " Proof.\n"; + fprintf fmt " intros x n; generalize x; elim n; clear n x; simpl power_pos.\n"; + fprintf fmt " intros; rewrite spec_mul; rewrite spec_square; rewrite H.\n"; + fprintf fmt " rewrite Zpos_xI; rewrite Zpower_exp; auto with zarith.\n"; + fprintf fmt " rewrite (Zmult_comm 2); rewrite Zpower_mult; auto with zarith.\n"; + fprintf fmt " rewrite Zpower_2; rewrite Zpower_1_r; auto.\n"; + fprintf fmt " intros; rewrite spec_square; rewrite H.\n"; + fprintf fmt " rewrite Zpos_xO; auto with zarith.\n"; + fprintf fmt " rewrite (Zmult_comm 2); rewrite Zpower_mult; auto with zarith.\n"; + fprintf fmt " rewrite Zpower_2; auto.\n"; + fprintf fmt " intros; rewrite Zpower_1_r; auto.\n"; + fprintf fmt " Qed.\n"; + fprintf fmt "\n"; + end + else + fprintf fmt " Admitted.\n"; + fprintf fmt "\n"; + + fprintf fmt " (***************************************************************)\n"; + fprintf fmt " (* *)\n"; + fprintf fmt " (* Square root *)\n"; + fprintf fmt " (* *)\n"; + fprintf fmt " (***************************************************************)\n\n"; + + for i = 0 to size do + fprintf fmt " Definition w%i_sqrt := w%i_op.(znz_sqrt).\n" i i + done; + fprintf fmt "\n"; + + fprintf fmt " Definition sqrt x :=\n"; + fprintf fmt " match x with\n"; + for i = 0 to size do + fprintf fmt " | %s%i wx => reduce_%i (w%i_sqrt wx)\n" c i i i; + done; + fprintf fmt " | %sn n wx =>\n" c; + fprintf fmt " let op := make_op n in\n"; + fprintf fmt " reduce_n n (op.(znz_sqrt) wx)\n"; + fprintf fmt " end.\n"; + fprintf fmt "\n"; + + + + fprintf fmt " Theorem spec_sqrt: forall x, [sqrt x] ^ 2 <= [x] < ([sqrt x] + 1) ^ 2.\n"; + if gen_proof then + begin + fprintf fmt " Proof.\n"; + fprintf fmt " intros x; unfold sqrt; case x; clear x.\n"; + for i = 0 to size do + fprintf fmt " intros x; rewrite spec_reduce_%i; exact (spec_sqrt w%i_spec x).\n" i i; + done; + fprintf fmt " intros n x; rewrite spec_reduce_n; exact (spec_sqrt (wn_spec n) x).\n"; + fprintf fmt " Qed.\n"; + end + else + fprintf fmt "Admitted.\n"; + fprintf fmt "\n"; + + + fprintf fmt " (***************************************************************)\n"; + fprintf fmt " (* *)\n"; + fprintf fmt " (* Division *)\n"; + fprintf fmt " (* *)\n"; + fprintf fmt " (***************************************************************)\n\n"; + + + (* Division *) + for i = 0 to size do + fprintf fmt " Definition w%i_div_gt := w%i_op.(znz_div_gt).\n" i i + done; + fprintf fmt "\n"; + + if gen_proof then + begin + fprintf fmt " Let spec_divn1 ww (ww_op: znz_op ww) (ww_spec: znz_spec ww_op) := \n"; + fprintf fmt " (spec_gen_divn1 \n"; + fprintf fmt " ww_op.(znz_zdigits) ww_op.(znz_0)\n"; + fprintf fmt " ww_op.(znz_WW) ww_op.(znz_head0)\n"; + fprintf fmt " ww_op.(znz_add_mul_div) ww_op.(znz_div21)\n"; + fprintf fmt " ww_op.(znz_compare) ww_op.(znz_sub) (znz_to_Z ww_op)\n"; + fprintf fmt " (spec_to_Z ww_spec) \n"; + fprintf fmt " (spec_zdigits ww_spec)\n"; + fprintf fmt " (spec_0 ww_spec) (spec_WW ww_spec) (spec_head0 ww_spec)\n"; + fprintf fmt " (spec_add_mul_div ww_spec) (spec_div21 ww_spec) \n"; + fprintf fmt " (ZnZ.spec_compare ww_spec) (ZnZ.spec_sub ww_spec)).\n"; + fprintf fmt " \n"; + end; + + for i = 0 to size do + fprintf fmt " Definition w%i_divn1 n x y :=\n" i; + fprintf fmt " let (u, v) :=\n"; + fprintf fmt " gen_divn1 w%i_op.(znz_zdigits) w%i_op.(znz_0)\n" i i; + fprintf fmt " w%i_op.(znz_WW) w%i_op.(znz_head0)\n" i i; + fprintf fmt " w%i_op.(znz_add_mul_div) w%i_op.(znz_div21)\n" i i; + fprintf fmt " w%i_op.(znz_compare) w%i_op.(znz_sub) (S n) x y in\n" i i; + if i == size then + fprintf fmt " (%sn _ u, %s%i v).\n" c c i + else + fprintf fmt " (to_Z%i _ u, %s%i v).\n" i c i; + done; + fprintf fmt "\n"; + + + if gen_proof then + begin + for i = 0 to size do + fprintf fmt " Lemma spec_get_end%i: forall n x y,\n" i; + fprintf fmt " eval%in n x <= [%s%i y] -> \n" i c i; + fprintf fmt " [%s%i (GenBase.get_low %s n x)] = eval%in n x.\n" c i (pz i) i; + fprintf fmt " Proof.\n"; + fprintf fmt " intros n x y H.\n"; + fprintf fmt " rewrite spec_gen_eval%in; unfold to_Z.\n" i; + fprintf fmt " apply GenBase.spec_get_low.\n"; + fprintf fmt " exact (spec_0 w%i_spec).\n" i; + fprintf fmt " exact (spec_to_Z w%i_spec).\n" i; + fprintf fmt " apply Zle_lt_trans with [%s%i y]; auto.\n" c i; + fprintf fmt " rewrite <- spec_gen_eval%in; auto.\n" i; + fprintf fmt " unfold to_Z; case (spec_to_Z w%i_spec y); auto.\n" i; + fprintf fmt " Qed.\n"; + fprintf fmt "\n"; + done ; + end; + + for i = 0 to size do + fprintf fmt " Let div_gt%i x y := let (u,v) := (w%i_div_gt x y) in (reduce_%i u, reduce_%i v).\n" i i i i; + done; + fprintf fmt "\n"; + + + fprintf fmt " Let div_gtnm n m wx wy :=\n"; + fprintf fmt " let mn := Max.max n m in\n"; + fprintf fmt " let d := diff n m in\n"; + fprintf fmt " let op := make_op mn in\n"; + fprintf fmt " let (q, r):= op.(znz_div_gt)\n"; + fprintf fmt " (castm (diff_r n m) (extend_tr wx (snd d)))\n"; + fprintf fmt " (castm (diff_l n m) (extend_tr wy (fst d))) in\n"; + fprintf fmt " (reduce_n mn q, reduce_n mn r).\n"; + fprintf fmt "\n"; + + fprintf fmt " Definition div_gt := Eval lazy beta delta [iter] in\n"; + fprintf fmt " (iter _ \n"; + for i = 0 to size do + fprintf fmt " div_gt%i\n" i; + fprintf fmt " (fun n x y => div_gt%i x (GenBase.get_low %s (S n) y))\n" i (pz i); + fprintf fmt " w%i_divn1\n" i; + done; + fprintf fmt " div_gtnm).\n"; + fprintf fmt "\n"; + + fprintf fmt " Theorem spec_div_gt: forall x y,\n"; + fprintf fmt " [x] > [y] -> 0 < [y] ->\n"; + fprintf fmt " let (q,r) := div_gt x y in\n"; + fprintf fmt " [q] = [x] / [y] /\\ [r] = [x] mod [y].\n"; + if gen_proof then + begin + fprintf fmt " Proof.\n"; + fprintf fmt " assert (FO:\n"; + fprintf fmt " forall x y, [x] > [y] -> 0 < [y] ->\n"; + fprintf fmt " let (q,r) := div_gt x y in\n"; + fprintf fmt " [x] = [q] * [y] + [r] /\\ 0 <= [r] < [y]).\n"; + fprintf fmt " refine (spec_iter (t_*t_) (fun x y res => x > y -> 0 < y ->\n"; fprintf fmt " let (q,r) := res in\n"; + fprintf fmt " x = [q] * y + [r] /\\ 0 <= [r] < y)\n"; + for i = 0 to size do + fprintf fmt " div_gt%i\n" i; + fprintf fmt " (fun n x y => div_gt%i x (GenBase.get_low %s (S n) y))\n" i (pz i); + fprintf fmt " w%i_divn1 _ _ _\n" i; + done; + fprintf fmt " div_gtnm _).\n"; + for i = 0 to size do + fprintf fmt " intros x y H1 H2; unfold div_gt%i, w%i_div_gt.\n" i i; + fprintf fmt " generalize (spec_div_gt w%i_spec x y H1 H2); case znz_div_gt.\n" i; + fprintf fmt " intros xx yy; repeat rewrite spec_reduce_%i; auto.\n" i; + if i == size then + fprintf fmt " intros n x y H2 H3; unfold div_gt%i, w%i_div_gt.\n" i i + else + fprintf fmt " intros n x y H1 H2 H3; unfold div_gt%i, w%i_div_gt.\n" i i; + fprintf fmt " generalize (spec_div_gt w%i_spec x \n" i; + fprintf fmt " (GenBase.get_low %s (S n) y)).\n" (pz i); + fprintf fmt " "; + for j = 0 to i do + fprintf fmt "unfold w%i;" (i-j); + done; + fprintf fmt "case znz_div_gt.\n"; + fprintf fmt " intros xx yy H4; repeat rewrite spec_reduce_%i.\n" i; + fprintf fmt " generalize (spec_get_end%i (S n) y x); unfold to_Z; intros H5.\n" i; + fprintf fmt " unfold to_Z in H2; rewrite H5 in H4; auto with zarith.\n"; + if i == size then + fprintf fmt " intros n x y H2 H3.\n" + else + fprintf fmt " intros n x y H1 H2 H3.\n"; + fprintf fmt " generalize\n"; + fprintf fmt " (spec_divn1 w%i w%i_op w%i_spec (S n) x y H3).\n" i i i; + fprintf fmt " unfold w%i_divn1;" i; + for j = 0 to i do + fprintf fmt "unfold w%i;" (i-j); + done; + fprintf fmt " case gen_divn1.\n"; + fprintf fmt " intros xx yy H4.\n"; + if i == size then + begin + fprintf fmt " repeat rewrite <- spec_gen_eval%in in H4; auto.\n" i; + fprintf fmt " rewrite spec_eval%in; auto.\n" i; + end + else + begin + fprintf fmt " rewrite to_Z%i_spec; auto with zarith.\n" i; + fprintf fmt " repeat rewrite <- spec_gen_eval%in in H4; auto.\n" i; + end; + done; + fprintf fmt " intros n m x y H1 H2; unfold div_gtnm.\n"; + fprintf fmt " generalize (spec_div_gt (wn_spec (Max.max n m))\n"; + fprintf fmt " (castm (diff_r n m)\n"; + fprintf fmt " (extend_tr x (snd (diff n m))))\n"; + fprintf fmt " (castm (diff_l n m)\n"; + fprintf fmt " (extend_tr y (fst (diff n m))))).\n"; + fprintf fmt " case znz_div_gt.\n"; + fprintf fmt " intros xx yy HH.\n"; + fprintf fmt " repeat rewrite spec_reduce_n.\n"; + fprintf fmt " rewrite <- (spec_cast_l n m x).\n"; + fprintf fmt " rewrite <- (spec_cast_r n m y).\n"; + fprintf fmt " unfold to_Z; apply HH.\n"; + fprintf fmt " rewrite <- (spec_cast_l n m x) in H1; auto.\n"; + fprintf fmt " rewrite <- (spec_cast_r n m y) in H1; auto.\n"; + fprintf fmt " rewrite <- (spec_cast_r n m y) in H2; auto.\n"; + fprintf fmt " intros x y H1 H2; generalize (FO x y H1 H2); case div_gt.\n"; + fprintf fmt " intros q r (H3, H4); split.\n"; + fprintf fmt " apply (Zdiv_unique [x] [y] [q] [r]); auto.\n"; + fprintf fmt " rewrite Zmult_comm; auto.\n"; + fprintf fmt " apply (Zmod_unique [x] [y] [q] [r]); auto.\n"; + fprintf fmt " rewrite Zmult_comm; auto.\n"; + fprintf fmt " Qed.\n"; + end + else + fprintf fmt " Admitted.\n"; + fprintf fmt "\n"; + + fprintf fmt " Definition div_eucl x y :=\n"; + fprintf fmt " match compare x y with\n"; + fprintf fmt " | Eq => (one, zero)\n"; + fprintf fmt " | Lt => (zero, x)\n"; + fprintf fmt " | Gt => div_gt x y\n"; + fprintf fmt " end.\n"; + fprintf fmt "\n"; + + fprintf fmt " Theorem spec_div_eucl: forall x y,\n"; + fprintf fmt " 0 < [y] ->\n"; + fprintf fmt " let (q,r) := div_eucl x y in\n"; + fprintf fmt " ([q], [r]) = Zdiv_eucl [x] [y].\n"; + if gen_proof then + begin + fprintf fmt " Proof.\n"; + fprintf fmt " assert (F0: [zero] = 0).\n"; + fprintf fmt " exact (spec_0 w0_spec).\n"; + fprintf fmt " assert (F1: [one] = 1).\n"; + fprintf fmt " exact (spec_1 w0_spec).\n"; + fprintf fmt " intros x y H; generalize (spec_compare x y);\n"; + fprintf fmt " unfold div_eucl; case compare; try rewrite F0;\n"; + fprintf fmt " try rewrite F1; intros; auto with zarith.\n"; + fprintf fmt " rewrite H0; generalize (Z_div_same [y] (Zlt_gt _ _ H))\n"; + fprintf fmt " (Z_mod_same [y] (Zlt_gt _ _ H));\n"; + fprintf fmt " unfold Zdiv, Zmod; case Zdiv_eucl; intros; subst; auto.\n"; + fprintf fmt " assert (F2: 0 <= [x] < [y]).\n"; + fprintf fmt " generalize (spec_pos x); auto.\n"; + fprintf fmt " generalize (Zdiv_small _ _ F2)\n"; + fprintf fmt " (Zmod_small _ _ F2);\n"; + fprintf fmt " unfold Zdiv, Zmod; case Zdiv_eucl; intros; subst; auto.\n"; + fprintf fmt " generalize (spec_div_gt _ _ H0 H); auto.\n"; + fprintf fmt " unfold Zdiv, Zmod; case Zdiv_eucl; case div_gt.\n"; + fprintf fmt " intros a b c d (H1, H2); subst; auto.\n"; + fprintf fmt " Qed.\n"; + end + else + fprintf fmt " Admitted.\n"; + fprintf fmt "\n"; + + fprintf fmt " Definition div x y := fst (div_eucl x y).\n"; + fprintf fmt "\n"; + + fprintf fmt " Theorem spec_div:\n"; + fprintf fmt " forall x y, 0 < [y] -> [div x y] = [x] / [y].\n"; + if gen_proof then + begin + fprintf fmt " Proof.\n"; + fprintf fmt " intros x y H1; unfold div; generalize (spec_div_eucl x y H1);\n"; + fprintf fmt " case div_eucl; simpl fst.\n"; + fprintf fmt " intros xx yy; unfold Zdiv; case Zdiv_eucl; intros qq rr H; \n"; + fprintf fmt " injection H; auto.\n"; + fprintf fmt " Qed.\n"; + end + else + fprintf fmt " Admitted.\n"; + fprintf fmt "\n"; + + fprintf fmt " (***************************************************************)\n"; + fprintf fmt " (* *)\n"; + fprintf fmt " (* Modulo *)\n"; + fprintf fmt " (* *)\n"; + fprintf fmt " (***************************************************************)\n\n"; + + for i = 0 to size do + fprintf fmt " Definition w%i_mod_gt := w%i_op.(znz_mod_gt).\n" i i + done; + fprintf fmt "\n"; + + for i = 0 to size do + fprintf fmt " Definition w%i_modn1 :=\n" i; + fprintf fmt " gen_modn1 w%i_op.(znz_zdigits) w%i_op.(znz_0)\n" i i; + fprintf fmt " w%i_op.(znz_head0) w%i_op.(znz_add_mul_div) w%i_op.(znz_div21)\n" i i i; + fprintf fmt " w%i_op.(znz_compare) w%i_op.(znz_sub).\n" i i; + done; + fprintf fmt "\n"; + + fprintf fmt " Let mod_gtnm n m wx wy :=\n"; + fprintf fmt " let mn := Max.max n m in\n"; + fprintf fmt " let d := diff n m in\n"; + fprintf fmt " let op := make_op mn in\n"; + fprintf fmt " reduce_n mn (op.(znz_mod_gt)\n"; + fprintf fmt " (castm (diff_r n m) (extend_tr wx (snd d)))\n"; + fprintf fmt " (castm (diff_l n m) (extend_tr wy (fst d)))).\n"; + fprintf fmt "\n"; + + fprintf fmt " Definition mod_gt := Eval lazy beta delta[iter] in\n"; + fprintf fmt " (iter _ \n"; + for i = 0 to size do + fprintf fmt " (fun x y => reduce_%i (w%i_mod_gt x y))\n" i i; + fprintf fmt " (fun n x y => reduce_%i (w%i_mod_gt x (GenBase.get_low %s (S n) y)))\n" i i (pz i); + fprintf fmt " (fun n x y => reduce_%i (w%i_modn1 (S n) x y))\n" i i; + done; + fprintf fmt " mod_gtnm).\n"; + fprintf fmt "\n"; + + if gen_proof then + begin + fprintf fmt " Let spec_modn1 ww (ww_op: znz_op ww) (ww_spec: znz_spec ww_op) := \n"; + fprintf fmt " (spec_gen_modn1 \n"; + fprintf fmt " ww_op.(znz_zdigits) ww_op.(znz_0)\n"; + fprintf fmt " ww_op.(znz_WW) ww_op.(znz_head0)\n"; + fprintf fmt " ww_op.(znz_add_mul_div) ww_op.(znz_div21)\n"; + fprintf fmt " ww_op.(znz_compare) ww_op.(znz_sub) (znz_to_Z ww_op)\n"; + fprintf fmt " (spec_to_Z ww_spec) \n"; + fprintf fmt " (spec_zdigits ww_spec)\n"; + fprintf fmt " (spec_0 ww_spec) (spec_WW ww_spec) (spec_head0 ww_spec)\n"; + fprintf fmt " (spec_add_mul_div ww_spec) (spec_div21 ww_spec) \n"; + fprintf fmt " (ZnZ.spec_compare ww_spec) (ZnZ.spec_sub ww_spec)).\n"; + fprintf fmt "\n"; + end; + + fprintf fmt " Theorem spec_mod_gt:\n"; + fprintf fmt " forall x y, [x] > [y] -> 0 < [y] -> [mod_gt x y] = [x] mod [y].\n"; + if gen_proof then + begin + fprintf fmt " Proof.\n"; + fprintf fmt " refine (spec_iter _ (fun x y res => x > y -> 0 < y ->\n"; + fprintf fmt " [res] = x mod y)\n"; + for i = 0 to size do + fprintf fmt " (fun x y => reduce_%i (w%i_mod_gt x y))\n" i i; + fprintf fmt " (fun n x y => reduce_%i (w%i_mod_gt x (GenBase.get_low %s (S n) y)))\n" i i (pz i); + fprintf fmt " (fun n x y => reduce_%i (w%i_modn1 (S n) x y)) _ _ _\n" i i; + done; + fprintf fmt " mod_gtnm _).\n"; + for i = 0 to size do + fprintf fmt " intros x y H1 H2; rewrite spec_reduce_%i.\n" i; + fprintf fmt " exact (spec_mod_gt w%i_spec x y H1 H2).\n" i; + if i == size then + fprintf fmt " intros n x y H2 H3; rewrite spec_reduce_%i.\n" i + else + fprintf fmt " intros n x y H1 H2 H3; rewrite spec_reduce_%i.\n" i; + fprintf fmt " unfold w%i_mod_gt.\n" i; + fprintf fmt " rewrite <- (spec_get_end%i (S n) y x); auto with zarith.\n" i; + fprintf fmt " unfold to_Z; apply (spec_mod_gt w%i_spec); auto.\n" i; + fprintf fmt " rewrite <- (spec_get_end%i (S n) y x) in H2; auto with zarith.\n" i; + fprintf fmt " rewrite <- (spec_get_end%i (S n) y x) in H3; auto with zarith.\n" i; + if i == size then + fprintf fmt " intros n x y H2 H3; rewrite spec_reduce_%i.\n" i + else + fprintf fmt " intros n x y H1 H2 H3; rewrite spec_reduce_%i.\n" i; + fprintf fmt " unfold w%i_modn1, to_Z; rewrite spec_gen_eval%in.\n" i i; + fprintf fmt " apply (spec_modn1 _ _ w%i_spec); auto.\n" i; + done; + fprintf fmt " intros n m x y H1 H2; unfold mod_gtnm.\n"; + fprintf fmt " repeat rewrite spec_reduce_n.\n"; + fprintf fmt " rewrite <- (spec_cast_l n m x).\n"; + fprintf fmt " rewrite <- (spec_cast_r n m y).\n"; + fprintf fmt " unfold to_Z; apply (spec_mod_gt (wn_spec (Max.max n m))).\n"; + fprintf fmt " rewrite <- (spec_cast_l n m x) in H1; auto.\n"; + fprintf fmt " rewrite <- (spec_cast_r n m y) in H1; auto.\n"; + fprintf fmt " rewrite <- (spec_cast_r n m y) in H2; auto.\n"; + fprintf fmt " Qed.\n"; + end + else + fprintf fmt " Admitted.\n"; + fprintf fmt "\n"; + + fprintf fmt " Definition modulo x y := \n"; + fprintf fmt " match compare x y with\n"; + fprintf fmt " | Eq => zero\n"; + fprintf fmt " | Lt => x\n"; + fprintf fmt " | Gt => mod_gt x y\n"; + fprintf fmt " end.\n"; + fprintf fmt "\n"; + + fprintf fmt " Theorem spec_modulo:\n"; + fprintf fmt " forall x y, 0 < [y] -> [modulo x y] = [x] mod [y].\n"; + if gen_proof then + begin + fprintf fmt " Proof.\n"; + fprintf fmt " assert (F0: [zero] = 0).\n"; + fprintf fmt " exact (spec_0 w0_spec).\n"; + fprintf fmt " assert (F1: [one] = 1).\n"; + fprintf fmt " exact (spec_1 w0_spec).\n"; + fprintf fmt " intros x y H; generalize (spec_compare x y);\n"; + fprintf fmt " unfold modulo; case compare; try rewrite F0;\n"; + fprintf fmt " try rewrite F1; intros; try split; auto with zarith.\n"; + fprintf fmt " rewrite H0; apply sym_equal; apply Z_mod_same; auto with zarith.\n"; + fprintf fmt " apply sym_equal; apply Zmod_small; auto with zarith.\n"; + fprintf fmt " generalize (spec_pos x); auto with zarith.\n"; + fprintf fmt " apply spec_mod_gt; auto.\n"; + fprintf fmt " Qed.\n"; + end + else + fprintf fmt " Admitted.\n"; + fprintf fmt "\n"; + + fprintf fmt " (***************************************************************)\n"; + fprintf fmt " (* *)\n"; + fprintf fmt " (* Gcd *)\n"; + fprintf fmt " (* *)\n"; + fprintf fmt " (***************************************************************)\n\n"; + + fprintf fmt " Definition digits x :=\n"; + fprintf fmt " match x with\n"; + for i = 0 to size do + fprintf fmt " | %s%i _ => w%i_op.(znz_digits)\n" c i i; + done; + fprintf fmt " | %sn n _ => (make_op n).(znz_digits)\n" c; + fprintf fmt " end.\n"; + fprintf fmt "\n"; + + + fprintf fmt " Theorem spec_digits: forall x, 0 <= [x] < 2 ^ Zpos (digits x).\n"; + if gen_proof then + begin + fprintf fmt " Proof.\n"; + fprintf fmt " intros x; case x; clear x.\n"; + for i = 0 to size do + fprintf fmt " intros x; unfold to_Z, digits;\n"; + fprintf fmt " generalize (spec_to_Z w%i_spec x); unfold base; intros H; exact H.\n" i; + done; + fprintf fmt " intros n x; unfold to_Z, digits;\n"; + fprintf fmt " generalize (spec_to_Z (wn_spec n) x); unfold base; intros H; exact H.\n"; + fprintf fmt " Qed.\n"; + end + else + fprintf fmt " Admitted.\n"; + fprintf fmt "\n"; + + + fprintf fmt " Definition gcd_gt_body a b cont :=\n"; + fprintf fmt " match compare b zero with\n"; + fprintf fmt " | Gt =>\n"; + fprintf fmt " let r := mod_gt a b in\n"; + fprintf fmt " match compare r zero with\n"; + fprintf fmt " | Gt => cont r (mod_gt b r)\n"; + fprintf fmt " | _ => b\n"; + fprintf fmt " end\n"; + fprintf fmt " | _ => a\n"; + fprintf fmt " end.\n"; + fprintf fmt "\n"; + + if gen_proof then + begin + fprintf fmt " Theorem Zspec_gcd_gt_body: forall a b cont p,\n"; + fprintf fmt " [a] > [b] -> [a] < 2 ^ p ->\n"; + fprintf fmt " (forall a1 b1, [a1] < 2 ^ (p - 1) -> [a1] > [b1] ->\n"; + fprintf fmt " Zis_gcd [a1] [b1] [cont a1 b1]) -> \n"; + fprintf fmt " Zis_gcd [a] [b] [gcd_gt_body a b cont].\n"; + fprintf fmt " Proof.\n"; + fprintf fmt " assert (F1: [zero] = 0).\n"; + fprintf fmt " unfold zero, w_0, to_Z; rewrite (spec_0 w0_spec); auto.\n"; + fprintf fmt " intros a b cont p H2 H3 H4; unfold gcd_gt_body.\n"; + fprintf fmt " generalize (spec_compare b zero); case compare; try rewrite F1.\n"; + fprintf fmt " intros HH; rewrite HH; apply Zis_gcd_0.\n"; + fprintf fmt " intros HH; absurd (0 <= [b]); auto with zarith.\n"; + fprintf fmt " case (spec_digits b); auto with zarith.\n"; + fprintf fmt " intros H5; generalize (spec_compare (mod_gt a b) zero); \n"; + fprintf fmt " case compare; try rewrite F1.\n"; + fprintf fmt " intros H6; rewrite <- (Zmult_1_r [b]).\n"; + fprintf fmt " rewrite (Z_div_mod_eq [a] [b]); auto with zarith.\n"; + fprintf fmt " rewrite <- spec_mod_gt; auto with zarith.\n"; + fprintf fmt " rewrite H6; rewrite Zplus_0_r.\n"; + fprintf fmt " apply Zis_gcd_mult; apply Zis_gcd_1.\n"; + fprintf fmt " intros; apply False_ind.\n"; + fprintf fmt " case (spec_digits (mod_gt a b)); auto with zarith.\n"; + fprintf fmt " intros H6; apply GenDiv.Zis_gcd_mod; auto with zarith.\n"; + fprintf fmt " apply GenDiv.Zis_gcd_mod; auto with zarith.\n"; + fprintf fmt " rewrite <- spec_mod_gt; auto with zarith.\n"; + fprintf fmt " assert (F2: [b] > [mod_gt a b]).\n"; + fprintf fmt " case (Z_mod_lt [a] [b]); auto with zarith.\n"; + fprintf fmt " repeat rewrite <- spec_mod_gt; auto with zarith.\n"; + fprintf fmt " assert (F3: [mod_gt a b] > [mod_gt b (mod_gt a b)]).\n"; + fprintf fmt " case (Z_mod_lt [b] [mod_gt a b]); auto with zarith.\n"; + fprintf fmt " rewrite <- spec_mod_gt; auto with zarith.\n"; + fprintf fmt " repeat rewrite <- spec_mod_gt; auto with zarith.\n"; + fprintf fmt " apply H4; auto with zarith.\n"; + fprintf fmt " apply Zmult_lt_reg_r with 2; auto with zarith.\n"; + fprintf fmt " apply Zle_lt_trans with ([b] + [mod_gt a b]); auto with zarith.\n"; + fprintf fmt " apply Zle_lt_trans with (([a]/[b]) * [b] + [mod_gt a b]); auto with zarith.\n"; + fprintf fmt " apply Zplus_le_compat_r.\n"; + fprintf fmt " pattern [b] at 1; rewrite <- (Zmult_1_l [b]).\n"; + fprintf fmt " apply Zmult_le_compat_r; auto with zarith.\n"; + fprintf fmt " case (Zle_lt_or_eq 0 ([a]/[b])); auto with zarith.\n"; + fprintf fmt " intros HH; rewrite (Z_div_mod_eq [a] [b]) in H2;\n"; + fprintf fmt " try rewrite <- HH in H2; auto with zarith.\n"; + fprintf fmt " case (Z_mod_lt [a] [b]); auto with zarith.\n"; + fprintf fmt " rewrite Zmult_comm; rewrite spec_mod_gt; auto with zarith.\n"; + fprintf fmt " rewrite <- Z_div_mod_eq; auto with zarith.\n"; + fprintf fmt " pattern 2 at 2; rewrite <- (Zpower_1_r 2).\n"; + fprintf fmt " rewrite <- Zpower_exp; auto with zarith.\n"; + fprintf fmt " ring_simplify (p - 1 + 1); auto.\n"; + fprintf fmt " case (Zle_lt_or_eq 0 p); auto with zarith.\n"; + fprintf fmt " generalize H3; case p; simpl Zpower; auto with zarith.\n"; + fprintf fmt " intros HH; generalize H3; rewrite <- HH; simpl Zpower; auto with zarith.\n"; + fprintf fmt " Qed.\n"; + fprintf fmt "\n"; + end; + + fprintf fmt " Fixpoint gcd_gt_aux (p:positive) (cont:t->t->t) (a b:t) {struct p} : t :=\n"; + fprintf fmt " gcd_gt_body a b\n"; + fprintf fmt " (fun a b =>\n"; + fprintf fmt " match p with\n"; + fprintf fmt " | xH => cont a b\n"; + fprintf fmt " | xO p => gcd_gt_aux p (gcd_gt_aux p cont) a b\n"; + fprintf fmt " | xI p => gcd_gt_aux p (gcd_gt_aux p cont) a b\n"; + fprintf fmt " end).\n"; + fprintf fmt "\n"; + + if gen_proof then + begin + fprintf fmt " Theorem Zspec_gcd_gt_aux: forall p n a b cont,\n"; + fprintf fmt " [a] > [b] -> [a] < 2 ^ (Zpos p + n) ->\n"; + fprintf fmt " (forall a1 b1, [a1] < 2 ^ n -> [a1] > [b1] ->\n"; + fprintf fmt " Zis_gcd [a1] [b1] [cont a1 b1]) ->\n"; + fprintf fmt " Zis_gcd [a] [b] [gcd_gt_aux p cont a b].\n"; + fprintf fmt " intros p; elim p; clear p.\n"; + fprintf fmt " intros p Hrec n a b cont H2 H3 H4.\n"; + fprintf fmt " unfold gcd_gt_aux; apply Zspec_gcd_gt_body with (Zpos (xI p) + n); auto.\n"; + fprintf fmt " intros a1 b1 H6 H7.\n"; + fprintf fmt " apply Hrec with (Zpos p + n); auto.\n"; + fprintf fmt " replace (Zpos p + (Zpos p + n)) with\n"; + fprintf fmt " (Zpos (xI p) + n - 1); auto.\n"; + fprintf fmt " rewrite Zpos_xI; ring.\n"; + fprintf fmt " intros a2 b2 H9 H10.\n"; + fprintf fmt " apply Hrec with n; auto.\n"; + fprintf fmt " intros p Hrec n a b cont H2 H3 H4.\n"; + fprintf fmt " unfold gcd_gt_aux; apply Zspec_gcd_gt_body with (Zpos (xO p) + n); auto.\n"; + fprintf fmt " intros a1 b1 H6 H7.\n"; + fprintf fmt " apply Hrec with (Zpos p + n - 1); auto.\n"; + fprintf fmt " replace (Zpos p + (Zpos p + n - 1)) with\n"; + fprintf fmt " (Zpos (xO p) + n - 1); auto.\n"; + fprintf fmt " rewrite Zpos_xO; ring.\n"; + fprintf fmt " intros a2 b2 H9 H10.\n"; + fprintf fmt " apply Hrec with (n - 1); auto.\n"; + fprintf fmt " replace (Zpos p + (n - 1)) with\n"; + fprintf fmt " (Zpos p + n - 1); auto with zarith.\n"; + fprintf fmt " intros a3 b3 H12 H13; apply H4; auto with zarith.\n"; + fprintf fmt " apply Zlt_le_trans with (1 := H12).\n"; + fprintf fmt " case (Zle_or_lt 1 n); intros HH.\n"; + fprintf fmt " apply Zpower_le_monotone; auto with zarith.\n"; + fprintf fmt " apply Zle_trans with 0; auto with zarith.\n"; + fprintf fmt " assert (HH1: n - 1 < 0); auto with zarith.\n"; + fprintf fmt " generalize HH1; case (n - 1); auto with zarith.\n"; + fprintf fmt " intros p1 HH2; discriminate.\n"; + fprintf fmt " intros n a b cont H H2 H3.\n"; + fprintf fmt " simpl gcd_gt_aux.\n"; + fprintf fmt " apply Zspec_gcd_gt_body with (n + 1); auto with zarith.\n"; + fprintf fmt " rewrite Zplus_comm; auto.\n"; + fprintf fmt " intros a1 b1 H5 H6; apply H3; auto.\n"; + fprintf fmt " replace n with (n + 1 - 1); auto; try ring.\n"; + fprintf fmt " Qed.\n"; + fprintf fmt "\n"; + end; + + fprintf fmt " Definition gcd_cont a b :=\n"; + fprintf fmt " match compare one b with\n"; + fprintf fmt " | Eq => one\n"; + fprintf fmt " | _ => a\n"; + fprintf fmt " end.\n"; + fprintf fmt "\n"; + + fprintf fmt " Definition gcd_gt a b := gcd_gt_aux (digits a) gcd_cont a b.\n"; + fprintf fmt "\n"; + + fprintf fmt " Theorem spec_gcd_gt: forall a b,\n"; + fprintf fmt " [a] > [b] -> [gcd_gt a b] = Zgcd [a] [b].\n"; + if gen_proof then + begin + fprintf fmt " Proof.\n"; + fprintf fmt " intros a b H2.\n"; + fprintf fmt " case (spec_digits (gcd_gt a b)); intros H3 H4.\n"; + fprintf fmt " case (spec_digits a); intros H5 H6.\n"; + fprintf fmt " apply sym_equal; apply Zis_gcd_gcd; auto with zarith.\n"; + fprintf fmt " unfold gcd_gt; apply Zspec_gcd_gt_aux with 0; auto with zarith.\n"; + fprintf fmt " intros a1 a2; rewrite Zpower_0_r.\n"; + fprintf fmt " case (spec_digits a2); intros H7 H8;\n"; + fprintf fmt " intros; apply False_ind; auto with zarith.\n"; + fprintf fmt " Qed.\n"; + end + else + fprintf fmt " Admitted.\n"; + fprintf fmt "\n"; + + fprintf fmt " Definition gcd a b :=\n"; + fprintf fmt " match compare a b with\n"; + fprintf fmt " | Eq => a\n"; + fprintf fmt " | Lt => gcd_gt b a\n"; + fprintf fmt " | Gt => gcd_gt a b\n"; + fprintf fmt " end.\n"; + fprintf fmt "\n"; + + fprintf fmt " Theorem spec_gcd: forall a b, [gcd a b] = Zgcd [a] [b].\n"; + if gen_proof then + begin + fprintf fmt " Proof.\n"; + fprintf fmt " intros a b.\n"; + fprintf fmt " case (spec_digits a); intros H1 H2.\n"; + fprintf fmt " case (spec_digits b); intros H3 H4.\n"; + fprintf fmt " unfold gcd; generalize (spec_compare a b); case compare.\n"; + fprintf fmt " intros HH; rewrite HH; apply sym_equal; apply Zis_gcd_gcd; auto.\n"; + fprintf fmt " apply Zis_gcd_refl.\n"; + fprintf fmt " intros; apply trans_equal with (Zgcd [b] [a]).\n"; + fprintf fmt " apply spec_gcd_gt; auto with zarith.\n"; + fprintf fmt " apply Zis_gcd_gcd; auto with zarith.\n"; + fprintf fmt " apply Zgcd_is_pos.\n"; + fprintf fmt " apply Zis_gcd_sym; apply Zgcd_is_gcd.\n"; + fprintf fmt " intros; apply spec_gcd_gt; auto.\n"; + fprintf fmt " Qed.\n"; + end + else + fprintf fmt " Admitted.\n"; + fprintf fmt "\n"; + + + fprintf fmt " (***************************************************************)\n"; + fprintf fmt " (* *)\n"; + fprintf fmt " (* Conversion *)\n"; + fprintf fmt " (* *)\n"; + fprintf fmt " (***************************************************************)\n\n"; + + fprintf fmt " Definition pheight p := \n"; + fprintf fmt " Peano.pred (nat_of_P (get_height w0_op.(znz_digits) (plength p))).\n"; + fprintf fmt "\n"; + + fprintf fmt " Theorem pheight_correct: forall p, \n"; + fprintf fmt " Zpos p < 2 ^ (Zpos (znz_digits w0_op) * 2 ^ (Z_of_nat (pheight p))).\n"; + fprintf fmt " Proof.\n"; + fprintf fmt " intros p; unfold pheight.\n"; + fprintf fmt " assert (F1: forall x, Z_of_nat (Peano.pred (nat_of_P x)) = Zpos x - 1).\n"; + fprintf fmt " intros x.\n"; + fprintf fmt " assert (Zsucc (Z_of_nat (Peano.pred (nat_of_P x))) = Zpos x); auto with zarith.\n"; + fprintf fmt " rewrite <- inj_S.\n"; + fprintf fmt " rewrite <- (fun x => S_pred x 0); auto with zarith.\n"; + fprintf fmt " rewrite Zpos_eq_Z_of_nat_o_nat_of_P; auto.\n"; + fprintf fmt " apply lt_le_trans with 1%snat; auto with zarith.\n" "%"; + fprintf fmt " exact (le_Pmult_nat x 1).\n"; + fprintf fmt " rewrite F1; clear F1.\n"; + fprintf fmt " assert (F2:= (get_height_correct (znz_digits w0_op) (plength p))).\n"; + fprintf fmt " apply Zlt_le_trans with (Zpos (Psucc p)).\n"; + fprintf fmt " rewrite Zpos_succ_morphism; auto with zarith.\n"; + fprintf fmt " apply Zle_trans with (1 := plength_pred_correct (Psucc p)).\n"; + fprintf fmt " rewrite Ppred_succ.\n"; + fprintf fmt " apply Zpower_le_monotone; auto with zarith.\n"; + fprintf fmt " Qed.\n"; + fprintf fmt "\n"; + + fprintf fmt " Definition of_pos x :=\n"; + fprintf fmt " let h := pheight x in\n"; + fprintf fmt " match h with\n"; + for i = 0 to size do + fprintf fmt " | %i%snat => reduce_%i (snd (w%i_op.(znz_of_pos) x))\n" i "%" i i; + done; + fprintf fmt " | _ =>\n"; + fprintf fmt " let n := minus h %i in\n" (size + 1); + fprintf fmt " reduce_n n (snd ((make_op n).(znz_of_pos) x))\n"; + fprintf fmt " end.\n"; + fprintf fmt "\n"; + + fprintf fmt " Theorem spec_of_pos: forall x,\n"; + fprintf fmt " [of_pos x] = Zpos x.\n"; + if gen_proof then + begin + fprintf fmt " Proof.\n"; + fprintf fmt " assert (F := spec_more_than_1_digit w0_spec).\n"; + fprintf fmt " intros x; unfold of_pos; case_eq (pheight x).\n"; + for i = 0 to size do + if i <> 0 then + fprintf fmt " intros n; case n; clear n.\n"; + fprintf fmt " intros H1; rewrite spec_reduce_%i; unfold to_Z.\n" i; + fprintf fmt " apply (znz_of_pos_correct w%i_spec).\n" i; + fprintf fmt " apply Zlt_le_trans with (1 := pheight_correct x).\n"; + fprintf fmt " rewrite H1; simpl Z_of_nat; change (2^%i) with (%s).\n" i (gen2 i); + fprintf fmt " unfold base.\n"; + fprintf fmt " apply Zpower_le_monotone; split; auto with zarith.\n"; + if i <> 0 then + begin + fprintf fmt " rewrite Zmult_comm; repeat rewrite <- Zmult_assoc.\n"; + fprintf fmt " repeat rewrite <- Zpos_xO.\n"; + fprintf fmt " refine (Zle_refl _).\n"; + end; + done; + fprintf fmt " intros n.\n"; + fprintf fmt " intros H1; rewrite spec_reduce_n; unfold to_Z.\n"; + fprintf fmt " simpl minus; rewrite <- minus_n_O.\n"; + fprintf fmt " apply (znz_of_pos_correct (wn_spec n)).\n"; + fprintf fmt " apply Zlt_le_trans with (1 := pheight_correct x).\n"; + fprintf fmt " unfold base.\n"; + fprintf fmt " apply Zpower_le_monotone; auto with zarith.\n"; + fprintf fmt " split; auto with zarith.\n"; + fprintf fmt " rewrite H1.\n"; + fprintf fmt " elim n; clear n H1.\n"; + fprintf fmt " simpl Z_of_nat; change (2^%i) with (%s).\n" (size + 1) (gen2 (size + 1)); + fprintf fmt " rewrite Zmult_comm; repeat rewrite <- Zmult_assoc.\n"; + fprintf fmt " repeat rewrite <- Zpos_xO.\n"; + fprintf fmt " refine (Zle_refl _).\n"; + fprintf fmt " intros n Hrec.\n"; + fprintf fmt " rewrite make_op_S.\n"; + fprintf fmt " change (%sznz_digits (word _ (S (S n))) (mk_zn2z_op_karatsuba (make_op n))) with\n" "@"; + fprintf fmt " (xO (znz_digits (make_op n))).\n"; + fprintf fmt " rewrite (fun x y => (Zpos_xO (%sznz_digits x y))).\n" "@"; + fprintf fmt " rewrite inj_S; unfold Zsucc.\n"; + fprintf fmt " rewrite Zplus_comm; rewrite Zpower_exp; auto with zarith.\n"; + fprintf fmt " rewrite Zpower_1_r.\n"; + fprintf fmt " assert (tmp: forall x y z, x * (y * z) = y * (x * z));\n"; + fprintf fmt " [intros; ring | rewrite tmp; clear tmp].\n"; + fprintf fmt " apply Zmult_le_compat_l; auto with zarith.\n"; + fprintf fmt " Qed.\n"; + end + else + fprintf fmt " Admitted.\n"; + fprintf fmt "\n"; + + fprintf fmt " Definition of_N x :=\n"; + fprintf fmt " match x with\n"; + fprintf fmt " | BinNat.N0 => zero\n"; + fprintf fmt " | Npos p => of_pos p\n"; + fprintf fmt " end.\n"; + fprintf fmt "\n"; + + + fprintf fmt " Theorem spec_of_N: forall x,\n"; + fprintf fmt " [of_N x] = Z_of_N x.\n"; + if gen_proof then + begin + fprintf fmt " Proof.\n"; + fprintf fmt " intros x; case x.\n"; + fprintf fmt " simpl of_N.\n"; + fprintf fmt " unfold zero, w_0, to_Z; rewrite (spec_0 w0_spec); auto.\n"; + fprintf fmt " intros p; exact (spec_of_pos p).\n"; + fprintf fmt " Qed.\n"; + end + else + fprintf fmt " Admitted.\n"; + fprintf fmt "\n"; + + fprintf fmt " (***************************************************************)\n"; + fprintf fmt " (* *)\n"; + fprintf fmt " (* Shift *)\n"; + fprintf fmt " (* *)\n"; + fprintf fmt " (***************************************************************)\n\n"; + + + + (* Head0 *) + fprintf fmt " Definition head0 w := match w with\n"; + for i = 0 to size do + fprintf fmt " | %s%i w=> reduce_%i (w%i_op.(znz_head0) w)\n" c i i i; + done; + fprintf fmt " | %sn n w=> reduce_n n ((make_op n).(znz_head0) w)\n" c; + fprintf fmt " end.\n"; + fprintf fmt "\n"; + + fprintf fmt " Theorem spec_head00: forall x, [x] = 0 ->[head0 x] = Zpos (digits x).\n"; + if gen_proof then + begin + fprintf fmt " Proof.\n"; + fprintf fmt " intros x; case x; unfold head0; clear x.\n"; + for i = 0 to size do + fprintf fmt " intros x; rewrite spec_reduce_%i; exact (spec_head00 w%i_spec x).\n" i i; + done; + fprintf fmt " intros n x; rewrite spec_reduce_n; exact (spec_head00 (wn_spec n) x).\n"; + fprintf fmt " Qed.\n"; + end + else + fprintf fmt " Admitted.\n"; + fprintf fmt " \n"; + + fprintf fmt " Theorem spec_head0: forall x, 0 < [x] ->\n"; + fprintf fmt " 2 ^ (Zpos (digits x) - 1) <= 2 ^ [head0 x] * [x] < 2 ^ Zpos (digits x).\n"; + if gen_proof then + begin + fprintf fmt " Proof.\n"; + fprintf fmt " assert (F0: forall x, (x - 1) + 1 = x).\n"; + fprintf fmt " intros; ring. \n"; + fprintf fmt " intros x; case x; unfold digits, head0; clear x.\n"; + for i = 0 to size do + fprintf fmt " intros x Hx; rewrite spec_reduce_%i.\n" i; + fprintf fmt " assert (F1:= spec_more_than_1_digit w%i_spec).\n" i; + fprintf fmt " generalize (spec_head0 w%i_spec x Hx).\n" i; + fprintf fmt " unfold base.\n"; + fprintf fmt " pattern (Zpos (znz_digits w%i_op)) at 1; \n" i; + fprintf fmt " rewrite <- (fun x => (F0 (Zpos x))).\n"; + fprintf fmt " rewrite Zpower_exp; auto with zarith.\n"; + fprintf fmt " rewrite Zpower_1_r; rewrite Z_div_mult; auto with zarith.\n"; + done; + fprintf fmt " intros n x Hx; rewrite spec_reduce_n.\n"; + fprintf fmt " assert (F1:= spec_more_than_1_digit (wn_spec n)).\n"; + fprintf fmt " generalize (spec_head0 (wn_spec n) x Hx).\n"; + fprintf fmt " unfold base.\n"; + fprintf fmt " pattern (Zpos (znz_digits (make_op n))) at 1; \n"; + fprintf fmt " rewrite <- (fun x => (F0 (Zpos x))).\n"; + fprintf fmt " rewrite Zpower_exp; auto with zarith.\n"; + fprintf fmt " rewrite Zpower_1_r; rewrite Z_div_mult; auto with zarith.\n"; + fprintf fmt " Qed.\n"; + end + else + fprintf fmt " Admitted.\n"; + fprintf fmt "\n"; + + + (* Tail0 *) + fprintf fmt " Definition tail0 w := match w with\n"; + for i = 0 to size do + fprintf fmt " | %s%i w=> reduce_%i (w%i_op.(znz_tail0) w)\n" c i i i; + done; + fprintf fmt " | %sn n w=> reduce_n n ((make_op n).(znz_tail0) w)\n" c; + fprintf fmt " end.\n"; + fprintf fmt "\n"; + + + fprintf fmt " Theorem spec_tail00: forall x, [x] = 0 ->[tail0 x] = Zpos (digits x).\n"; + if gen_proof then + begin + fprintf fmt " Proof.\n"; + fprintf fmt " intros x; case x; unfold tail0; clear x.\n"; + for i = 0 to size do + fprintf fmt " intros x; rewrite spec_reduce_%i; exact (spec_tail00 w%i_spec x).\n" i i; + done; + fprintf fmt " intros n x; rewrite spec_reduce_n; exact (spec_tail00 (wn_spec n) x).\n"; + fprintf fmt " Qed.\n"; + end + else + fprintf fmt " Admitted.\n"; + fprintf fmt " \n"; + + + fprintf fmt " Theorem spec_tail0: forall x,\n"; + fprintf fmt " 0 < [x] -> exists y, 0 <= y /\\ [x] = (2 * y + 1) * 2 ^ [tail0 x].\n"; + if gen_proof then + begin + fprintf fmt " Proof.\n"; + fprintf fmt " intros x; case x; clear x; unfold tail0.\n"; + for i = 0 to size do + fprintf fmt " intros x Hx; rewrite spec_reduce_%i; exact (spec_tail0 w%i_spec x Hx).\n" i i; + done; + fprintf fmt " intros n x Hx; rewrite spec_reduce_n; exact (spec_tail0 (wn_spec n) x Hx).\n"; + fprintf fmt " Qed.\n"; + end + else + fprintf fmt " Admitted.\n"; + fprintf fmt "\n"; + + + (* Number of digits *) + fprintf fmt " Definition %sdigits x :=\n" c; + fprintf fmt " match x with\n"; + fprintf fmt " | %s0 _ => %s0 w0_op.(znz_zdigits)\n" c c; + for i = 1 to size do + fprintf fmt " | %s%i _ => reduce_%i w%i_op.(znz_zdigits)\n" c i i i; + done; + fprintf fmt " | %sn n _ => reduce_n n (make_op n).(znz_zdigits)\n" c; + fprintf fmt " end.\n"; + fprintf fmt "\n"; + + fprintf fmt " Theorem spec_Ndigits: forall x, [Ndigits x] = Zpos (digits x).\n"; + if gen_proof then + begin + fprintf fmt " Proof.\n"; + fprintf fmt " intros x; case x; clear x; unfold Ndigits, digits.\n"; + for i = 0 to size do + fprintf fmt " intros _; try rewrite spec_reduce_%i; exact (spec_zdigits w%i_spec).\n" i i; + done; + fprintf fmt " intros n _; try rewrite spec_reduce_n; exact (spec_zdigits (wn_spec n)).\n"; + fprintf fmt " Qed.\n"; + end + else + fprintf fmt " Admitted.\n"; + fprintf fmt "\n"; + + + (* Shiftr *) + for i = 0 to size do + fprintf fmt " Definition 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.\n" i i i i i; + done; + fprintf fmt " Definition 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.\n"; + fprintf fmt "\n"; + + fprintf fmt " Definition shiftr := Eval lazy beta delta [same_level] in \n"; + fprintf fmt " same_level _ (fun n x => %s0 (shiftr0 n x))\n" c; + for i = 1 to size do + fprintf fmt " (fun n x => reduce_%i (shiftr%i n x))\n" i i; + done; + fprintf fmt " (fun n p x => reduce_n n (shiftrn n p x)).\n"; + fprintf fmt "\n"; + + + fprintf fmt " Theorem spec_shiftr: forall n x,\n"; + fprintf fmt " [n] <= [Ndigits x] -> [shiftr n x] = [x] / 2 ^ [n].\n"; + if gen_proof then + begin + fprintf fmt " Proof.\n"; + fprintf fmt " assert (F0: forall x y, x - (x - y) = y).\n"; + fprintf fmt " intros; ring.\n"; + fprintf fmt " assert (F2: forall x y z, 0 <= x -> 0 <= y -> x < z -> 0 <= x / 2 ^ y < z).\n"; + fprintf fmt " intros x y z HH HH1 HH2.\n"; + fprintf fmt " split; auto with zarith.\n"; + fprintf fmt " apply Zle_lt_trans with (2 := HH2); auto with zarith.\n"; + fprintf fmt " apply Zdiv_le_upper_bound; auto with zarith.\n"; + fprintf fmt " pattern x at 1; replace x with (x * 2 ^ 0); auto with zarith.\n"; + fprintf fmt " apply Zmult_le_compat_l; auto.\n"; + fprintf fmt " apply Zpower_le_monotone; auto with zarith.\n"; + fprintf fmt " rewrite Zpower_0_r; ring.\n"; + fprintf fmt " assert (F3: forall x y, 0 <= y -> y <= x -> 0 <= x - y < 2 ^ x).\n"; + fprintf fmt " intros xx y HH HH1.\n"; + fprintf fmt " split; auto with zarith.\n"; + fprintf fmt " apply Zle_lt_trans with xx; auto with zarith.\n"; + fprintf fmt " apply Zpower2_lt_lin; auto with zarith.\n"; + fprintf fmt " assert (F4: forall ww ww1 ww2 \n"; + fprintf fmt " (ww_op: znz_op ww) (ww1_op: znz_op ww1) (ww2_op: znz_op ww2)\n"; + fprintf fmt " xx yy xx1 yy1,\n"; + fprintf fmt " znz_to_Z ww2_op yy <= znz_to_Z ww1_op (znz_zdigits ww1_op) ->\n"; + fprintf fmt " znz_to_Z ww1_op (znz_zdigits ww1_op) <= znz_to_Z ww_op (znz_zdigits ww_op) ->\n"; + fprintf fmt " znz_spec ww_op -> znz_spec ww1_op -> znz_spec ww2_op ->\n"; + fprintf fmt " znz_to_Z ww_op xx1 = znz_to_Z ww1_op xx ->\n"; + fprintf fmt " znz_to_Z ww_op yy1 = znz_to_Z ww2_op yy ->\n"; + fprintf fmt " znz_to_Z ww_op\n"; + fprintf fmt " (znz_add_mul_div ww_op (znz_sub ww_op (znz_zdigits ww_op) yy1)\n"; + fprintf fmt " (znz_0 ww_op) xx1) = znz_to_Z ww1_op xx / 2 ^ znz_to_Z ww2_op yy).\n"; + fprintf fmt " intros ww ww1 ww2 ww_op ww1_op ww2_op xx yy xx1 yy1 Hl Hl1 Hw Hw1 Hw2 Hx Hy.\n"; + fprintf fmt " case (spec_to_Z Hw xx1); auto with zarith; intros HH1 HH2.\n"; + fprintf fmt " case (spec_to_Z Hw yy1); auto with zarith; intros HH3 HH4.\n"; + fprintf fmt " rewrite <- Hx.\n"; + fprintf fmt " rewrite <- Hy.\n"; + fprintf fmt " generalize (spec_add_mul_div Hw\n"; + fprintf fmt " (znz_0 ww_op) xx1\n"; + fprintf fmt " (znz_sub ww_op (znz_zdigits ww_op) \n"; + fprintf fmt " yy1)\n"; + fprintf fmt " ).\n"; + fprintf fmt " rewrite (spec_0 Hw).\n"; + fprintf fmt " rewrite Zmult_0_l; rewrite Zplus_0_l.\n"; + fprintf fmt " rewrite (ZnZ.spec_sub Hw).\n"; + fprintf fmt " rewrite Zmod_small; auto with zarith.\n"; + fprintf fmt " rewrite (spec_zdigits Hw).\n"; + fprintf fmt " rewrite F0.\n"; + fprintf fmt " rewrite Zmod_small; auto with zarith.\n"; + fprintf fmt " unfold base; rewrite (spec_zdigits Hw) in Hl1 |- *;\n"; + fprintf fmt " auto with zarith.\n"; + fprintf fmt " assert (F5: forall n m, (n <= m)%snat ->\n" "%"; + fprintf fmt " Zpos (znz_digits (make_op n)) <= Zpos (znz_digits (make_op m))).\n"; + fprintf fmt " intros n m HH; elim HH; clear m HH; auto with zarith.\n"; + fprintf fmt " intros m HH Hrec; apply Zle_trans with (1 := Hrec).\n"; + fprintf fmt " rewrite make_op_S.\n"; + fprintf fmt " match goal with |- Zpos ?Y <= ?X => change X with (Zpos (xO Y)) end.\n"; + fprintf fmt " rewrite Zpos_xO.\n"; + fprintf fmt " assert (0 <= Zpos (znz_digits (make_op n))); auto with zarith.\n"; + fprintf fmt " assert (F6: forall n, Zpos (znz_digits w%i_op) <= Zpos (znz_digits (make_op n))).\n" size; + fprintf fmt " intros n ; apply Zle_trans with (Zpos (znz_digits (make_op 0))).\n"; + fprintf fmt " change (znz_digits (make_op 0)) with (xO (znz_digits w%i_op)).\n" size; + fprintf fmt " rewrite Zpos_xO.\n"; + fprintf fmt " assert (0 <= Zpos (znz_digits w%i_op)); auto with zarith.\n" size; + fprintf fmt " apply F5; auto with arith.\n"; + fprintf fmt " intros x; case x; clear x; unfold shiftr, same_level.\n"; + for i = 0 to size do + fprintf fmt " intros x y; case y; clear y.\n"; + for j = 0 to i - 1 do + fprintf fmt " intros y; unfold shiftr%i, Ndigits.\n" i; + fprintf fmt " repeat rewrite spec_reduce_%i; repeat rewrite spec_reduce_%i; unfold to_Z; intros H1.\n" i j; + fprintf fmt " apply F4 with (3:=w%i_spec)(4:=w%i_spec)(5:=w%i_spec); auto with zarith.\n" i j i; + fprintf fmt " rewrite (spec_zdigits w%i_spec).\n" i; + fprintf fmt " rewrite (spec_zdigits w%i_spec).\n" j; + fprintf fmt " change (znz_digits w%i_op) with %s.\n" i (genxO (i - j) (" (znz_digits w"^(string_of_int j)^"_op)")); + fprintf fmt " repeat rewrite (fun x => Zpos_xO (xO x)).\n"; + fprintf fmt " repeat rewrite (fun x y => Zpos_xO (%sznz_digits x y)).\n" "@"; + fprintf fmt " assert (0 <= Zpos (znz_digits w%i_op)); auto with zarith.\n" j; + fprintf fmt " try (apply sym_equal; exact (spec_extend%in%i y)).\n" j i; + + done; + fprintf fmt " intros y; unfold shiftr%i, Ndigits.\n" i; + fprintf fmt " repeat rewrite spec_reduce_%i; unfold to_Z; intros H1.\n" i; + fprintf fmt " apply F4 with (3:=w%i_spec)(4:=w%i_spec)(5:=w%i_spec); auto with zarith.\n" i i i; + for j = i + 1 to size do + fprintf fmt " intros y; unfold shiftr%i, Ndigits.\n" j; + fprintf fmt " repeat rewrite spec_reduce_%i; repeat rewrite spec_reduce_%i; unfold to_Z; intros H1.\n" i j; + fprintf fmt " apply F4 with (3:=w%i_spec)(4:=w%i_spec)(5:=w%i_spec); auto with zarith.\n" j j i; + fprintf fmt " try (apply sym_equal; exact (spec_extend%in%i x)).\n" i j; + done; + if i == size then + begin + fprintf fmt " intros m y; unfold shiftrn, Ndigits.\n"; + fprintf fmt " repeat rewrite spec_reduce_n; unfold to_Z; intros H1.\n"; + fprintf fmt " apply F4 with (3:=(wn_spec m))(4:=wn_spec m)(5:=w%i_spec); auto with zarith.\n" size; + fprintf fmt " try (apply sym_equal; exact (spec_extend%in m x)).\n" size; + + end + else + begin + fprintf fmt " intros m y; unfold shiftrn, Ndigits.\n"; + fprintf fmt " repeat rewrite spec_reduce_n; unfold to_Z; intros H1.\n"; + fprintf fmt " apply F4 with (3:=(wn_spec m))(4:=wn_spec m)(5:=w%i_spec); auto with zarith.\n" i; + fprintf fmt " change ([Nn m (extend%i m (extend%i %i x))] = [N%i x]).\n" size i (size - i - 1) i; + fprintf fmt " rewrite <- (spec_extend%in m); rewrite <- spec_extend%in%i; auto.\n" size i size; + end + done; + fprintf fmt " intros n x y; case y; clear y;\n"; + fprintf fmt " intros y; unfold shiftrn, Ndigits; try rewrite spec_reduce_n.\n"; + for i = 0 to size do + fprintf fmt " try rewrite spec_reduce_%i; unfold to_Z; intros H1.\n" i; + fprintf fmt " apply F4 with (3:=(wn_spec n))(4:=w%i_spec)(5:=wn_spec n); auto with zarith.\n" i; + fprintf fmt " rewrite (spec_zdigits w%i_spec).\n" i; + fprintf fmt " rewrite (spec_zdigits (wn_spec n)).\n"; + fprintf fmt " apply Zle_trans with (2 := F6 n).\n"; + fprintf fmt " change (znz_digits w%i_op) with %s.\n" size (genxO (size - i) ("(znz_digits w" ^ (string_of_int i) ^ "_op)")); + fprintf fmt " repeat rewrite (fun x => Zpos_xO (xO x)).\n"; + fprintf fmt " repeat rewrite (fun x y => Zpos_xO (%sznz_digits x y)).\n" "@"; + fprintf fmt " assert (H: 0 <= Zpos (znz_digits w%i_op)); auto with zarith.\n" i; + if i == size then + fprintf fmt " change ([Nn n (extend%i n y)] = [N%i y]).\n" size i + else + fprintf fmt " change ([Nn n (extend%i n (extend%i %i y))] = [N%i y]).\n" size i (size - i - 1) i; + fprintf fmt " rewrite <- (spec_extend%in n); auto.\n" size; + if i <> size then + fprintf fmt " try (rewrite <- spec_extend%in%i; auto).\n" i size; + done; + fprintf fmt " generalize y; clear y; intros m y.\n"; + fprintf fmt " rewrite spec_reduce_n; unfold to_Z; intros H1.\n"; + fprintf fmt " apply F4 with (3:=(wn_spec (Max.max n m)))(4:=wn_spec m)(5:=wn_spec n); auto with zarith.\n"; + fprintf fmt " rewrite (spec_zdigits (wn_spec m)).\n"; + fprintf fmt " rewrite (spec_zdigits (wn_spec (Max.max n m))).\n"; + fprintf fmt " apply F5; auto with arith.\n"; + fprintf fmt " exact (spec_cast_r n m y).\n"; + fprintf fmt " exact (spec_cast_l n m x).\n"; + fprintf fmt " Qed.\n"; + end + else + fprintf fmt " Admitted.\n"; + fprintf fmt "\n"; + + fprintf fmt " Definition safe_shiftr n x := \n"; + fprintf fmt " match compare n (Ndigits x) with\n "; + fprintf fmt " | Lt => shiftr n x \n"; + fprintf fmt " | _ => %s0 w_0\n" c; + fprintf fmt " end.\n"; + fprintf fmt "\n"; + + + fprintf fmt " Theorem spec_safe_shiftr: forall n x,\n"; + fprintf fmt " [safe_shiftr n x] = [x] / 2 ^ [n].\n"; + if gen_proof then + begin + fprintf fmt " Proof.\n"; + fprintf fmt " intros n x; unfold safe_shiftr;\n"; + fprintf fmt " generalize (spec_compare n (Ndigits x)); case compare; intros H.\n"; + fprintf fmt " apply trans_equal with (1 := spec_0 w0_spec).\n"; + fprintf fmt " apply sym_equal; apply Zdiv_small; rewrite H.\n"; + fprintf fmt " rewrite spec_Ndigits; exact (spec_digits x).\n"; + fprintf fmt " rewrite <- spec_shiftr; auto with zarith.\n"; + fprintf fmt " apply trans_equal with (1 := spec_0 w0_spec).\n"; + fprintf fmt " apply sym_equal; apply Zdiv_small.\n"; + fprintf fmt " rewrite spec_Ndigits in H; case (spec_digits x); intros H1 H2.\n"; + fprintf fmt " split; auto.\n"; + fprintf fmt " apply Zlt_le_trans with (1 := H2).\n"; + fprintf fmt " apply Zpower_le_monotone; auto with zarith.\n"; + fprintf fmt " Qed.\n"; + end + else + fprintf fmt " Admitted.\n"; + fprintf fmt "\n"; + + fprintf fmt "\n"; + + (* Shiftl *) + for i = 0 to size do + fprintf fmt " Definition shiftl%i n x := w%i_op.(znz_add_mul_div) n x w%i_op.(znz_0).\n" i i i + done; + fprintf fmt " Definition shiftln n p x := (make_op n).(znz_add_mul_div) p x (make_op n).(znz_0).\n"; + fprintf fmt " Definition shiftl := Eval lazy beta delta [same_level] in\n"; + fprintf fmt " same_level _ (fun n x => %s0 (shiftl0 n x))\n" c; + for i = 1 to size do + fprintf fmt " (fun n x => reduce_%i (shiftl%i n x))\n" i i; + done; + fprintf fmt " (fun n p x => reduce_n n (shiftln n p x)).\n"; + fprintf fmt "\n"; + fprintf fmt "\n"; + + + fprintf fmt " Theorem spec_shiftl: forall n x,\n"; + fprintf fmt " [n] <= [head0 x] -> [shiftl n x] = [x] * 2 ^ [n].\n"; + if gen_proof then + begin + fprintf fmt " Proof.\n"; + fprintf fmt " assert (F0: forall x y, x - (x - y) = y).\n"; + fprintf fmt " intros; ring.\n"; + fprintf fmt " assert (F2: forall x y z, 0 <= x -> 0 <= y -> x < z -> 0 <= x / 2 ^ y < z).\n"; + fprintf fmt " intros x y z HH HH1 HH2.\n"; + fprintf fmt " split; auto with zarith.\n"; + fprintf fmt " apply Zle_lt_trans with (2 := HH2); auto with zarith.\n"; + fprintf fmt " apply Zdiv_le_upper_bound; auto with zarith.\n"; + fprintf fmt " pattern x at 1; replace x with (x * 2 ^ 0); auto with zarith.\n"; + fprintf fmt " apply Zmult_le_compat_l; auto.\n"; + fprintf fmt " apply Zpower_le_monotone; auto with zarith.\n"; + fprintf fmt " rewrite Zpower_0_r; ring.\n"; + fprintf fmt " assert (F3: forall x y, 0 <= y -> y <= x -> 0 <= x - y < 2 ^ x).\n"; + fprintf fmt " intros xx y HH HH1.\n"; + fprintf fmt " split; auto with zarith.\n"; + fprintf fmt " apply Zle_lt_trans with xx; auto with zarith.\n"; + fprintf fmt " apply Zpower2_lt_lin; auto with zarith.\n"; + fprintf fmt " assert (F4: forall ww ww1 ww2 \n"; + fprintf fmt " (ww_op: znz_op ww) (ww1_op: znz_op ww1) (ww2_op: znz_op ww2)\n"; + fprintf fmt " xx yy xx1 yy1,\n"; + fprintf fmt " znz_to_Z ww2_op yy <= znz_to_Z ww1_op (znz_head0 ww1_op xx) ->\n"; + fprintf fmt " znz_to_Z ww1_op (znz_zdigits ww1_op) <= znz_to_Z ww_op (znz_zdigits ww_op) ->\n"; + fprintf fmt " znz_spec ww_op -> znz_spec ww1_op -> znz_spec ww2_op ->\n"; + fprintf fmt " znz_to_Z ww_op xx1 = znz_to_Z ww1_op xx ->\n"; + fprintf fmt " znz_to_Z ww_op yy1 = znz_to_Z ww2_op yy ->\n"; + fprintf fmt " znz_to_Z ww_op\n"; + fprintf fmt " (znz_add_mul_div ww_op yy1\n"; + fprintf fmt " xx1 (znz_0 ww_op)) = znz_to_Z ww1_op xx * 2 ^ znz_to_Z ww2_op yy).\n"; + fprintf fmt " intros ww ww1 ww2 ww_op ww1_op ww2_op xx yy xx1 yy1 Hl Hl1 Hw Hw1 Hw2 Hx Hy.\n"; + fprintf fmt " case (spec_to_Z Hw xx1); auto with zarith; intros HH1 HH2.\n"; + fprintf fmt " case (spec_to_Z Hw yy1); auto with zarith; intros HH3 HH4.\n"; + fprintf fmt " rewrite <- Hx.\n"; + fprintf fmt " rewrite <- Hy.\n"; + fprintf fmt " generalize (spec_add_mul_div Hw xx1 (znz_0 ww_op) yy1).\n"; + fprintf fmt " rewrite (spec_0 Hw).\n"; + fprintf fmt " assert (F1: znz_to_Z ww1_op (znz_head0 ww1_op xx) <= Zpos (znz_digits ww1_op)).\n"; + fprintf fmt " case (Zle_lt_or_eq _ _ HH1); intros HH5.\n"; + fprintf fmt " apply Zlt_le_weak.\n"; + fprintf fmt " case (ZnZ.spec_head0 Hw1 xx).\n"; + fprintf fmt " rewrite <- Hx; auto.\n"; + fprintf fmt " intros _ Hu; unfold base in Hu.\n"; + fprintf fmt " case (Zle_or_lt (Zpos (znz_digits ww1_op))\n"; + fprintf fmt " (znz_to_Z ww1_op (znz_head0 ww1_op xx))); auto; intros H1.\n"; + fprintf fmt " absurd (2 ^ (Zpos (znz_digits ww1_op)) <= 2 ^ (znz_to_Z ww1_op (znz_head0 ww1_op xx))).\n"; + fprintf fmt " apply Zlt_not_le.\n"; + fprintf fmt " case (spec_to_Z Hw1 xx); intros HHx3 HHx4.\n"; + fprintf fmt " rewrite <- (Zmult_1_r (2 ^ znz_to_Z ww1_op (znz_head0 ww1_op xx))).\n"; + fprintf fmt " apply Zle_lt_trans with (2 := Hu).\n"; + fprintf fmt " apply Zmult_le_compat_l; auto with zarith.\n"; + fprintf fmt " apply Zpower_le_monotone; auto with zarith.\n"; + fprintf fmt " rewrite (ZnZ.spec_head00 Hw1 xx); auto with zarith.\n"; + fprintf fmt " rewrite Zdiv_0_l; auto with zarith.\n"; + fprintf fmt " rewrite Zplus_0_r.\n"; + fprintf fmt " case (Zle_lt_or_eq _ _ HH1); intros HH5.\n"; + fprintf fmt " rewrite Zmod_small; auto with zarith.\n"; + fprintf fmt " intros HH; apply HH.\n"; + fprintf fmt " rewrite Hy; apply Zle_trans with (1:= Hl).\n"; + fprintf fmt " rewrite <- (spec_zdigits Hw). \n"; + fprintf fmt " apply Zle_trans with (2 := Hl1); auto.\n"; + fprintf fmt " rewrite (spec_zdigits Hw1); auto with zarith.\n"; + fprintf fmt " split; auto with zarith .\n"; + fprintf fmt " apply Zlt_le_trans with (base (znz_digits ww1_op)).\n"; + fprintf fmt " rewrite Hx.\n"; + fprintf fmt " case (ZnZ.spec_head0 Hw1 xx); auto.\n"; + fprintf fmt " rewrite <- Hx; auto.\n"; + fprintf fmt " intros _ Hu; rewrite Zmult_comm in Hu.\n"; + fprintf fmt " apply Zle_lt_trans with (2 := Hu).\n"; + fprintf fmt " apply Zmult_le_compat_l; auto with zarith.\n"; + fprintf fmt " apply Zpower_le_monotone; auto with zarith.\n"; + fprintf fmt " unfold base; apply Zpower_le_monotone; auto with zarith.\n"; + fprintf fmt " split; auto with zarith.\n"; + fprintf fmt " rewrite <- (spec_zdigits Hw); auto with zarith.\n"; + fprintf fmt " rewrite <- (spec_zdigits Hw1); auto with zarith.\n"; + fprintf fmt " rewrite <- HH5.\n"; + fprintf fmt " rewrite Zmult_0_l.\n"; + fprintf fmt " rewrite Zmod_small; auto with zarith.\n"; + fprintf fmt " intros HH; apply HH.\n"; + fprintf fmt " rewrite Hy; apply Zle_trans with (1 := Hl).\n"; + fprintf fmt " rewrite (ZnZ.spec_head00 Hw1 xx); auto with zarith.\n"; + fprintf fmt " rewrite <- (spec_zdigits Hw); auto with zarith.\n"; + fprintf fmt " rewrite <- (spec_zdigits Hw1); auto with zarith.\n"; + fprintf fmt " assert (F5: forall n m, (n <= m)%snat ->\n" "%"; + fprintf fmt " Zpos (znz_digits (make_op n)) <= Zpos (znz_digits (make_op m))).\n"; + fprintf fmt " intros n m HH; elim HH; clear m HH; auto with zarith.\n"; + fprintf fmt " intros m HH Hrec; apply Zle_trans with (1 := Hrec).\n"; + fprintf fmt " rewrite make_op_S.\n"; + fprintf fmt " match goal with |- Zpos ?Y <= ?X => change X with (Zpos (xO Y)) end.\n"; + fprintf fmt " rewrite Zpos_xO.\n"; + fprintf fmt " assert (0 <= Zpos (znz_digits (make_op n))); auto with zarith.\n"; + fprintf fmt " assert (F6: forall n, Zpos (znz_digits w%i_op) <= Zpos (znz_digits (make_op n))).\n" size; + fprintf fmt " intros n ; apply Zle_trans with (Zpos (znz_digits (make_op 0))).\n"; + fprintf fmt " change (znz_digits (make_op 0)) with (xO (znz_digits w%i_op)).\n" size; + fprintf fmt " rewrite Zpos_xO.\n"; + fprintf fmt " assert (0 <= Zpos (znz_digits w%i_op)); auto with zarith.\n" size; + fprintf fmt " apply F5; auto with arith.\n"; + fprintf fmt " intros x; case x; clear x; unfold shiftl, same_level.\n"; + for i = 0 to size do + fprintf fmt " intros x y; case y; clear y.\n"; + for j = 0 to i - 1 do + fprintf fmt " intros y; unfold shiftl%i, head0.\n" i; + fprintf fmt " repeat rewrite spec_reduce_%i; repeat rewrite spec_reduce_%i; unfold to_Z; intros H1.\n" i j; + fprintf fmt " apply F4 with (3:=w%i_spec)(4:=w%i_spec)(5:=w%i_spec); auto with zarith.\n" i j i; + fprintf fmt " rewrite (spec_zdigits w%i_spec).\n" i; + fprintf fmt " rewrite (spec_zdigits w%i_spec).\n" j; + fprintf fmt " change (znz_digits w%i_op) with %s.\n" i (genxO (i - j) (" (znz_digits w"^(string_of_int j)^"_op)")); + fprintf fmt " repeat rewrite (fun x => Zpos_xO (xO x)).\n"; + fprintf fmt " repeat rewrite (fun x y => Zpos_xO (%sznz_digits x y)).\n" "@"; + fprintf fmt " assert (0 <= Zpos (znz_digits w%i_op)); auto with zarith.\n" j; + fprintf fmt " try (apply sym_equal; exact (spec_extend%in%i y)).\n" j i; + + done; + fprintf fmt " intros y; unfold shiftl%i, head0.\n" i; + fprintf fmt " repeat rewrite spec_reduce_%i; unfold to_Z; intros H1.\n" i; + fprintf fmt " apply F4 with (3:=w%i_spec)(4:=w%i_spec)(5:=w%i_spec); auto with zarith.\n" i i i; + for j = i + 1 to size do + fprintf fmt " intros y; unfold shiftl%i, head0.\n" j; + fprintf fmt " repeat rewrite spec_reduce_%i; repeat rewrite spec_reduce_%i; unfold to_Z; intros H1.\n" i j; + fprintf fmt " apply F4 with (3:=w%i_spec)(4:=w%i_spec)(5:=w%i_spec); auto with zarith.\n" j j i; + fprintf fmt " try (apply sym_equal; exact (spec_extend%in%i x)).\n" i j; + done; + if i == size then + begin + fprintf fmt " intros m y; unfold shiftln, head0.\n"; + fprintf fmt " repeat rewrite spec_reduce_n; unfold to_Z; intros H1.\n"; + fprintf fmt " apply F4 with (3:=(wn_spec m))(4:=wn_spec m)(5:=w%i_spec); auto with zarith.\n" size; + fprintf fmt " try (apply sym_equal; exact (spec_extend%in m x)).\n" size; + + end + else + begin + fprintf fmt " intros m y; unfold shiftln, head0.\n"; + fprintf fmt " repeat rewrite spec_reduce_n; unfold to_Z; intros H1.\n"; + fprintf fmt " apply F4 with (3:=(wn_spec m))(4:=wn_spec m)(5:=w%i_spec); auto with zarith.\n" i; + fprintf fmt " change ([Nn m (extend%i m (extend%i %i x))] = [N%i x]).\n" size i (size - i - 1) i; + fprintf fmt " rewrite <- (spec_extend%in m); rewrite <- spec_extend%in%i; auto.\n" size i size; + end + done; + fprintf fmt " intros n x y; case y; clear y;\n"; + fprintf fmt " intros y; unfold shiftln, head0; try rewrite spec_reduce_n.\n"; + for i = 0 to size do + fprintf fmt " try rewrite spec_reduce_%i; unfold to_Z; intros H1.\n" i; + fprintf fmt " apply F4 with (3:=(wn_spec n))(4:=w%i_spec)(5:=wn_spec n); auto with zarith.\n" i; + fprintf fmt " rewrite (spec_zdigits w%i_spec).\n" i; + fprintf fmt " rewrite (spec_zdigits (wn_spec n)).\n"; + fprintf fmt " apply Zle_trans with (2 := F6 n).\n"; + fprintf fmt " change (znz_digits w%i_op) with %s.\n" size (genxO (size - i) ("(znz_digits w" ^ (string_of_int i) ^ "_op)")); + fprintf fmt " repeat rewrite (fun x => Zpos_xO (xO x)).\n"; + fprintf fmt " repeat rewrite (fun x y => Zpos_xO (%sznz_digits x y)).\n" "@"; + fprintf fmt " assert (H: 0 <= Zpos (znz_digits w%i_op)); auto with zarith.\n" i; + if i == size then + fprintf fmt " change ([Nn n (extend%i n y)] = [N%i y]).\n" size i + else + fprintf fmt " change ([Nn n (extend%i n (extend%i %i y))] = [N%i y]).\n" size i (size - i - 1) i; + fprintf fmt " rewrite <- (spec_extend%in n); auto.\n" size; + if i <> size then + fprintf fmt " try (rewrite <- spec_extend%in%i; auto).\n" i size; + done; + fprintf fmt " generalize y; clear y; intros m y.\n"; + fprintf fmt " repeat rewrite spec_reduce_n; unfold to_Z; intros H1.\n"; + fprintf fmt " apply F4 with (3:=(wn_spec (Max.max n m)))(4:=wn_spec m)(5:=wn_spec n); auto with zarith.\n"; + fprintf fmt " rewrite (spec_zdigits (wn_spec m)).\n"; + fprintf fmt " rewrite (spec_zdigits (wn_spec (Max.max n m))).\n"; + fprintf fmt " apply F5; auto with arith.\n"; + fprintf fmt " exact (spec_cast_r n m y).\n"; + fprintf fmt " exact (spec_cast_l n m x).\n"; + fprintf fmt " Qed.\n"; + end + else + fprintf fmt " Admitted.\n"; + fprintf fmt "\n"; + + (* Double size *) + fprintf fmt " Definition double_size w := match w with\n"; + for i = 0 to size-1 do + fprintf fmt " | %s%i x => %s%i (WW (znz_0 w%i_op) x)\n" c i c (i + 1) i; + done; + fprintf fmt " | %s%i x => %sn 0 (WW (znz_0 w%i_op) x)\n" c size c size; + fprintf fmt " | %sn n x => %sn (S n) (WW (znz_0 (make_op n)) x)\n" c c; + fprintf fmt " end.\n"; + fprintf fmt "\n"; + + fprintf fmt " Theorem spec_double_size_digits: \n"; + fprintf fmt " forall x, digits (double_size x) = xO (digits x).\n"; + if gen_proof then + begin + fprintf fmt " Proof.\n"; + fprintf fmt " intros x; case x; unfold double_size, digits; clear x; auto.\n"; + fprintf fmt " intros n x; rewrite make_op_S; auto.\n"; + fprintf fmt " Qed.\n"; + end + else + fprintf fmt " Admitted.\n"; + fprintf fmt "\n"; + + + fprintf fmt " Theorem spec_double_size: forall x, [double_size x] = [x].\n"; + if gen_proof then + begin + fprintf fmt " Proof.\n"; + fprintf fmt " intros x; case x; unfold double_size; clear x.\n"; + for i = 0 to size do + fprintf fmt " intros x; unfold to_Z, make_op; \n"; + fprintf fmt " rewrite znz_to_Z_%i; rewrite (spec_0 w%i_spec); auto with zarith.\n" (i + 1) i; + done; + fprintf fmt " intros n x; unfold to_Z;\n"; + fprintf fmt " generalize (znz_to_Z_n n); simpl word.\n"; + fprintf fmt " intros HH; rewrite HH; clear HH.\n"; + fprintf fmt " generalize (spec_0 (wn_spec n)); simpl word.\n"; + fprintf fmt " intros HH; rewrite HH; clear HH; auto with zarith.\n"; + fprintf fmt " Qed.\n"; + end + else + fprintf fmt " Admitted.\n"; + fprintf fmt "\n"; + + + fprintf fmt " Theorem spec_double_size_head0: \n"; + fprintf fmt " forall x, 2 * [head0 x] <= [head0 (double_size x)].\n"; + if gen_proof then + begin + fprintf fmt " Proof.\n"; + fprintf fmt " intros x.\n"; + fprintf fmt " assert (F1:= spec_pos (head0 x)).\n"; + fprintf fmt " assert (F2: 0 < Zpos (digits x)).\n"; + fprintf fmt " red; auto.\n"; + fprintf fmt " case (Zle_lt_or_eq _ _ (spec_pos x)); intros HH.\n"; + fprintf fmt " generalize HH; rewrite <- (spec_double_size x); intros HH1.\n"; + fprintf fmt " case (spec_head0 x HH); intros _ HH2.\n"; + fprintf fmt " case (spec_head0 _ HH1).\n"; + fprintf fmt " rewrite (spec_double_size x); rewrite (spec_double_size_digits x).\n"; + fprintf fmt " intros HH3 _.\n"; + fprintf fmt " case (Zle_or_lt ([head0 (double_size x)]) (2 * [head0 x])); auto; intros HH4.\n"; + fprintf fmt " absurd (2 ^ (2 * [head0 x] )* [x] < 2 ^ [head0 (double_size x)] * [x]); auto.\n"; + fprintf fmt " apply Zle_not_lt.\n"; + fprintf fmt " apply Zmult_le_compat_r; auto with zarith.\n"; + fprintf fmt " apply Zpower_le_monotone; auto; auto with zarith.\n"; + fprintf fmt " generalize (spec_pos (head0 (double_size x))); auto with zarith.\n"; + fprintf fmt " assert (HH5: 2 ^[head0 x] <= 2 ^(Zpos (digits x) - 1)).\n"; + fprintf fmt " case (Zle_lt_or_eq 1 [x]); auto with zarith; intros HH5.\n"; + fprintf fmt " apply Zmult_le_reg_r with (2 ^ 1); auto with zarith.\n"; + fprintf fmt " rewrite <- (fun x y z => Zpower_exp x (y - z)); auto with zarith.\n"; + fprintf fmt " assert (tmp: forall x, x - 1 + 1 = x); [intros; ring | rewrite tmp; clear tmp].\n"; + fprintf fmt " apply Zle_trans with (2 := Zlt_le_weak _ _ HH2).\n"; + fprintf fmt " apply Zmult_le_compat_l; auto with zarith.\n"; + fprintf fmt " rewrite Zpower_1_r; auto with zarith.\n"; + fprintf fmt " apply Zpower_le_monotone; auto with zarith.\n"; + fprintf fmt " split; auto with zarith. \n"; + fprintf fmt " case (Zle_or_lt (Zpos (digits x)) [head0 x]); auto with zarith; intros HH6.\n"; + fprintf fmt " absurd (2 ^ Zpos (digits x) <= 2 ^ [head0 x] * [x]); auto with zarith.\n"; + fprintf fmt " rewrite <- HH5; rewrite Zmult_1_r.\n"; + fprintf fmt " apply Zpower_le_monotone; auto with zarith.\n"; + fprintf fmt " rewrite (Zmult_comm 2).\n"; + fprintf fmt " rewrite Zpower_mult; auto with zarith.\n"; + fprintf fmt " rewrite Zpower_2.\n"; + fprintf fmt " apply Zlt_le_trans with (2 := HH3).\n"; + fprintf fmt " rewrite <- Zmult_assoc.\n"; + fprintf fmt " replace (Zpos (xO (digits x)) - 1) with\n"; + fprintf fmt " ((Zpos (digits x) - 1) + (Zpos (digits x))).\n"; + fprintf fmt " rewrite Zpower_exp; auto with zarith.\n"; + fprintf fmt " apply Zmult_lt_compat2; auto with zarith.\n"; + fprintf fmt " split; auto with zarith.\n"; + fprintf fmt " apply Zmult_lt_0_compat; auto with zarith.\n"; + fprintf fmt " rewrite Zpos_xO; ring.\n"; + fprintf fmt " apply Zlt_le_weak; auto.\n"; + fprintf fmt " repeat rewrite spec_head00; auto.\n"; + fprintf fmt " rewrite spec_double_size_digits.\n"; + fprintf fmt " rewrite Zpos_xO; auto with zarith.\n"; + fprintf fmt " rewrite spec_double_size; auto.\n"; + fprintf fmt " Qed.\n"; + end + else + fprintf fmt " Admitted.\n"; + fprintf fmt "\n"; + + fprintf fmt " Theorem spec_double_size_head0_pos: \n"; + fprintf fmt " forall x, 0 < [head0 (double_size x)].\n"; + if gen_proof then + begin + fprintf fmt " Proof.\n"; + fprintf fmt " intros x.\n"; + fprintf fmt " assert (F: 0 < Zpos (digits x)).\n"; + fprintf fmt " red; auto.\n"; + fprintf fmt " case (Zle_lt_or_eq _ _ (spec_pos (head0 (double_size x)))); auto; intros F0.\n"; + fprintf fmt " case (Zle_lt_or_eq _ _ (spec_pos (head0 x))); intros F1.\n"; + fprintf fmt " apply Zlt_le_trans with (2 := (spec_double_size_head0 x)); auto with zarith.\n"; + fprintf fmt " case (Zle_lt_or_eq _ _ (spec_pos x)); intros F3.\n"; + fprintf fmt " generalize F3; rewrite <- (spec_double_size x); intros F4.\n"; + fprintf fmt " absurd (2 ^ (Zpos (xO (digits x)) - 1) < 2 ^ (Zpos (digits x))).\n"; + fprintf fmt " apply Zle_not_lt.\n"; + fprintf fmt " apply Zpower_le_monotone; auto with zarith.\n"; + fprintf fmt " split; auto with zarith.\n"; + fprintf fmt " rewrite Zpos_xO; auto with zarith.\n"; + fprintf fmt " case (spec_head0 x F3).\n"; + fprintf fmt " rewrite <- F1; rewrite Zpower_0_r; rewrite Zmult_1_l; intros _ HH.\n"; + fprintf fmt " apply Zle_lt_trans with (2 := HH).\n"; + fprintf fmt " case (spec_head0 _ F4).\n"; + fprintf fmt " rewrite (spec_double_size x); rewrite (spec_double_size_digits x).\n"; + fprintf fmt " rewrite <- F0; rewrite Zpower_0_r; rewrite Zmult_1_l; auto.\n"; + fprintf fmt " generalize F1; rewrite (spec_head00 _ (sym_equal F3)); auto with zarith.\n"; + fprintf fmt " Qed.\n"; + end + else + fprintf fmt " Admitted.\n"; + fprintf fmt "\n"; + + + (* Safe shiftl *) + + fprintf fmt " Definition safe_shiftl_aux_body cont n x :=\n"; + fprintf fmt " match compare n (head0 x) with\n"; + fprintf fmt " Gt => cont n (double_size x)\n"; + fprintf fmt " | _ => shiftl n x\n"; + fprintf fmt " end.\n"; + fprintf fmt "\n"; + + fprintf fmt " Theorem spec_safe_shift_aux_body: forall n p x cont,\n"; + fprintf fmt " 2^ Zpos p <= [head0 x] ->\n"; + fprintf fmt " (forall x, 2 ^ (Zpos p + 1) <= [head0 x]->\n"; + fprintf fmt " [cont n x] = [x] * 2 ^ [n]) ->\n"; + fprintf fmt " [safe_shiftl_aux_body cont n x] = [x] * 2 ^ [n].\n"; + if gen_proof then + begin + fprintf fmt " Proof.\n"; + fprintf fmt " intros n p x cont H1 H2; unfold safe_shiftl_aux_body.\n"; + fprintf fmt " generalize (spec_compare n (head0 x)); case compare; intros H.\n"; + fprintf fmt " apply spec_shiftl; auto with zarith.\n"; + fprintf fmt " apply spec_shiftl; auto with zarith.\n"; + fprintf fmt " rewrite H2.\n"; + fprintf fmt " rewrite spec_double_size; auto.\n"; + fprintf fmt " rewrite Zplus_comm; rewrite Zpower_exp; auto with zarith.\n"; + fprintf fmt " apply Zle_trans with (2 := spec_double_size_head0 x).\n"; + fprintf fmt " rewrite Zpower_1_r; apply Zmult_le_compat_l; auto with zarith.\n"; + fprintf fmt " Qed.\n"; + end + else + fprintf fmt " Admitted.\n"; + fprintf fmt "\n"; + + fprintf fmt " Fixpoint safe_shiftl_aux p cont n x {struct p} :=\n"; + fprintf fmt " safe_shiftl_aux_body \n"; + fprintf fmt " (fun n x => match p with\n"; + fprintf fmt " | xH => cont n x\n"; + fprintf fmt " | xO p => safe_shiftl_aux p (safe_shiftl_aux p cont) n x\n"; + fprintf fmt " | xI p => safe_shiftl_aux p (safe_shiftl_aux p cont) n x\n"; + fprintf fmt " end) n x.\n"; + fprintf fmt "\n"; + + fprintf fmt " Theorem spec_safe_shift_aux: forall p q n x cont,\n"; + fprintf fmt " 2 ^ (Zpos q) <= [head0 x] ->\n"; + fprintf fmt " (forall x, 2 ^ (Zpos p + Zpos q) <= [head0 x] ->\n"; + fprintf fmt " [cont n x] = [x] * 2 ^ [n]) -> \n"; + fprintf fmt " [safe_shiftl_aux p cont n x] = [x] * 2 ^ [n].\n"; + if gen_proof then + begin + fprintf fmt " Proof.\n"; + fprintf fmt " intros p; elim p; unfold safe_shiftl_aux; fold safe_shiftl_aux; clear p.\n"; + fprintf fmt " intros p Hrec q n x cont H1 H2.\n"; + fprintf fmt " apply spec_safe_shift_aux_body with (q); auto.\n"; + fprintf fmt " intros x1 H3; apply Hrec with (q + 1)%spositive; auto.\n" "%"; + fprintf fmt " intros x2 H4; apply Hrec with (p + q + 1)%spositive; auto.\n" "%"; + fprintf fmt " rewrite <- Pplus_assoc.\n"; + fprintf fmt " rewrite Zpos_plus_distr; auto.\n"; + fprintf fmt " intros x3 H5; apply H2.\n"; + fprintf fmt " rewrite Zpos_xI.\n"; + fprintf fmt " replace (2 * Zpos p + 1 + Zpos q) with (Zpos p + Zpos (p + q + 1));\n"; + fprintf fmt " auto.\n"; + fprintf fmt " repeat rewrite Zpos_plus_distr; ring.\n"; + fprintf fmt " intros p Hrec q n x cont H1 H2.\n"; + fprintf fmt " apply spec_safe_shift_aux_body with (q); auto.\n"; + fprintf fmt " intros x1 H3; apply Hrec with (q); auto.\n"; + fprintf fmt " apply Zle_trans with (2 := H3); auto with zarith.\n"; + fprintf fmt " apply Zpower_le_monotone; auto with zarith.\n"; + fprintf fmt " intros x2 H4; apply Hrec with (p + q)%spositive; auto.\n" "%"; + fprintf fmt " intros x3 H5; apply H2.\n"; + fprintf fmt " rewrite (Zpos_xO p).\n"; + fprintf fmt " replace (2 * Zpos p + Zpos q) with (Zpos p + Zpos (p + q));\n"; + fprintf fmt " auto.\n"; + fprintf fmt " repeat rewrite Zpos_plus_distr; ring.\n"; + fprintf fmt " intros q n x cont H1 H2.\n"; + fprintf fmt " apply spec_safe_shift_aux_body with (q); auto.\n"; + fprintf fmt " rewrite Zplus_comm; auto.\n"; + fprintf fmt " Qed.\n"; + end + else + fprintf fmt " Admitted.\n"; + fprintf fmt "\n"; + + + fprintf fmt " Definition safe_shiftl n x :=\n"; + fprintf fmt " safe_shiftl_aux_body\n"; + fprintf fmt " (safe_shiftl_aux_body\n"; + fprintf fmt " (safe_shiftl_aux (digits n) shiftl)) n x.\n"; + fprintf fmt "\n"; + + fprintf fmt " Theorem spec_safe_shift: forall n x,\n"; + fprintf fmt " [safe_shiftl n x] = [x] * 2 ^ [n].\n"; + if gen_proof then + begin + fprintf fmt " Proof.\n"; + fprintf fmt " intros n x; unfold safe_shiftl, safe_shiftl_aux_body.\n"; + fprintf fmt " generalize (spec_compare n (head0 x)); case compare; intros H.\n"; + fprintf fmt " apply spec_shiftl; auto with zarith.\n"; + fprintf fmt " apply spec_shiftl; auto with zarith.\n"; + fprintf fmt " rewrite <- (spec_double_size x).\n"; + fprintf fmt " generalize (spec_compare n (head0 (double_size x))); case compare; intros H1.\n"; + fprintf fmt " apply spec_shiftl; auto with zarith.\n"; + fprintf fmt " apply spec_shiftl; auto with zarith.\n"; + fprintf fmt " rewrite <- (spec_double_size (double_size x)).\n"; + fprintf fmt " apply spec_safe_shift_aux with 1%spositive.\n" "%"; + fprintf fmt " apply Zle_trans with (2 := spec_double_size_head0 (double_size x)).\n"; + fprintf fmt " replace (2 ^ 1) with (2 * 1).\n"; + fprintf fmt " apply Zmult_le_compat_l; auto with zarith.\n"; + fprintf fmt " generalize (spec_double_size_head0_pos x); auto with zarith.\n"; + fprintf fmt " rewrite Zpower_1_r; ring.\n"; + fprintf fmt " intros x1 H2; apply spec_shiftl.\n"; + fprintf fmt " apply Zle_trans with (2 := H2).\n"; + fprintf fmt " apply Zle_trans with (2 ^ Zpos (digits n)); auto with zarith.\n"; + fprintf fmt " case (spec_digits n); auto with zarith.\n"; + fprintf fmt " apply Zpower_le_monotone; auto with zarith.\n"; + fprintf fmt " Qed.\n"; + end + else + fprintf fmt " Admitted.\n"; + fprintf fmt "\n"; + + (* even *) + fprintf fmt " Definition is_even x :=\n"; + fprintf fmt " match x with\n"; + for i = 0 to size do + fprintf fmt " | %s%i wx => w%i_op.(znz_is_even) wx\n" c i i + done; + fprintf fmt " | %sn n wx => (make_op n).(znz_is_even) wx\n" c; + fprintf fmt " end.\n"; + fprintf fmt "\n"; + + + fprintf fmt " Theorem spec_is_even: forall x,\n"; + fprintf fmt " if is_even x then [x] mod 2 = 0 else [x] mod 2 = 1.\n"; + if gen_proof then + begin + fprintf fmt " Proof.\n"; + fprintf fmt " intros x; case x; unfold is_even, to_Z; clear x.\n"; + for i = 0 to size do + fprintf fmt " intros x; exact (spec_is_even w%i_spec x).\n" i; + done; + fprintf fmt " intros n x; exact (spec_is_even (wn_spec n) x).\n"; + fprintf fmt " Qed.\n"; + end + else + fprintf fmt " Admitted.\n"; + fprintf fmt "\n"; + + fprintf fmt " Theorem spec_0: [zero] = 0.\n"; + if gen_proof then + begin + fprintf fmt " Proof.\n"; + fprintf fmt " exact (spec_0 w0_spec).\n"; + fprintf fmt " Qed.\n"; + end + else + fprintf fmt " Admitted.\n"; + fprintf fmt "\n"; + + fprintf fmt " Theorem spec_1: [one] = 1.\n"; + if gen_proof then + begin + fprintf fmt " Proof.\n"; + fprintf fmt " exact (spec_1 w0_spec).\n"; + fprintf fmt " Qed.\n"; + end + else + fprintf fmt " Admitted.\n"; + fprintf fmt "\n"; + + + fprintf fmt "End Make.\n"; + fprintf fmt "\n"; + pp_print_flush fmt () + + + + +let _ = print_Make () + + |