+++ /dev/null
-include "basics/types.ma".
-include "arithmetics/minimization.ma".
-include "arithmetics/bigops.ma".
-include "arithmetics/sigma_pi.ma".
-include "arithmetics/bounded_quantifiers.ma".
-include "reverse_complexity/big_O.ma".
-include "basics/core_notation/napart_2.ma".
-
-(************************* notation for minimization *****************************)
-notation "μ_{ ident i < n } p"
- with precedence 80 for @{min $n 0 (λ${ident i}.$p)}.
-
-notation "μ_{ ident i ≤ n } p"
- with precedence 80 for @{min (S $n) 0 (λ${ident i}.$p)}.
-
-notation "μ_{ ident i ∈ [a,b[ } p"
- with precedence 80 for @{min ($b-$a) $a (λ${ident i}.$p)}.
-
-notation "μ_{ ident i ∈ [a,b] } p"
- with precedence 80 for @{min (S $b-$a) $a (λ${ident i}.$p)}.
-
-(************************************ MAX *************************************)
-notation "Max_{ ident i < n | p } f"
- with precedence 80
-for @{'bigop $n max 0 (λ${ident i}. $p) (λ${ident i}. $f)}.
-
-notation "Max_{ ident i < n } f"
- with precedence 80
-for @{'bigop $n max 0 (λ${ident i}.true) (λ${ident i}. $f)}.
-
-notation "Max_{ ident j ∈ [a,b[ } f"
- with precedence 80
-for @{'bigop ($b-$a) max 0 (λ${ident j}.((λ${ident j}.true) (${ident j}+$a)))
- (λ${ident j}.((λ${ident j}.$f)(${ident j}+$a)))}.
-
-notation "Max_{ ident j ∈ [a,b[ | p } f"
- with precedence 80
-for @{'bigop ($b-$a) max 0 (λ${ident j}.((λ${ident j}.$p) (${ident j}+$a)))
- (λ${ident j}.((λ${ident j}.$f)(${ident j}+$a)))}.
-
-lemma Max_assoc: ∀a,b,c. max (max a b) c = max a (max b c).
-#a #b #c normalize cases (true_or_false (leb a b)) #leab >leab normalize
- [cases (true_or_false (leb b c )) #lebc >lebc normalize
- [>(le_to_leb_true a c) // @(transitive_le ? b) @leb_true_to_le //
- |>leab //
- ]
- |cases (true_or_false (leb b c )) #lebc >lebc normalize //
- >leab normalize >(not_le_to_leb_false a c) // @lt_to_not_le
- @(transitive_lt ? b) @not_le_to_lt @leb_false_to_not_le //
- ]
-qed.
-
-lemma Max0 : ∀n. max 0 n = n.
-// qed.
-
-lemma Max0r : ∀n. max n 0 = n.
-#n >commutative_max //
-qed.
-
-definition MaxA ≝
- mk_Aop nat 0 max Max0 Max0r (λa,b,c.sym_eq … (Max_assoc a b c)).
-
-definition MaxAC ≝ mk_ACop nat 0 MaxA commutative_max.
-
-lemma le_Max: ∀f,p,n,a. a < n → p a = true →
- f a ≤ Max_{i < n | p i}(f i).
-#f #p #n #a #ltan #pa
->(bigop_diff p ? 0 MaxAC f a n) // @(le_maxl … (le_n ?))
-qed.
-
-lemma le_MaxI: ∀f,p,n,m,a. m ≤ a → a < n → p a = true →
- f a ≤ Max_{i ∈ [m,n[ | p i}(f i).
-#f #p #n #m #a #lema #ltan #pa
->(bigop_diff ? ? 0 MaxAC (λi.f (i+m)) (a-m) (n-m))
- [<plus_minus_m_m // @(le_maxl … (le_n ?))
- |<plus_minus_m_m //
- |/2 by monotonic_lt_minus_l/
- ]
-qed.
-
-lemma Max_le: ∀f,p,n,b.
- (∀a.a < n → p a = true → f a ≤ b) → Max_{i < n | p i}(f i) ≤ b.
-#f #p #n elim n #b #H //
-#b0 #H1 cases (true_or_false (p b)) #Hb
- [>bigop_Strue [2:@Hb] @to_max [@H1 // | @H #a #ltab #pa @H1 // @le_S //]
- |>bigop_Sfalse [2:@Hb] @H #a #ltab #pa @H1 // @le_S //
- ]
-qed.
-
-(********************************** pairing ***********************************)
-axiom pair: nat → nat → nat.
-axiom fst : nat → nat.
-axiom snd : nat → nat.
-
-interpretation "abstract pair" 'pair f g = (pair f g).
-
-axiom fst_pair: ∀a,b. fst 〈a,b〉 = a.
-axiom snd_pair: ∀a,b. snd 〈a,b〉 = b.
-axiom surj_pair: ∀x. ∃a,b. x = 〈a,b〉.
-
-axiom le_fst : ∀p. fst p ≤ p.
-axiom le_snd : ∀p. snd p ≤ p.
-axiom le_pair: ∀a,a1,b,b1. a ≤ a1 → b ≤ b1 → 〈a,b〉 ≤ 〈a1,b1〉.
-
-(************************************* U **************************************)
-axiom U: nat → nat →nat → option nat.
-
-axiom monotonic_U: ∀i,x,n,m,y.n ≤m →
- U i x n = Some ? y → U i x m = Some ? y.
-
-lemma unique_U: ∀i,x,n,m,yn,ym.
- U i x n = Some ? yn → U i x m = Some ? ym → yn = ym.
-#i #x #n #m #yn #ym #Hn #Hm cases (decidable_le n m)
- [#lenm lapply (monotonic_U … lenm Hn) >Hm #HS destruct (HS) //
- |#ltmn lapply (monotonic_U … n … Hm) [@lt_to_le @not_le_to_lt //]
- >Hn #HS destruct (HS) //
- ]
-qed.
-
-definition code_for ≝ λf,i.∀x.
- ∃n.∀m. n ≤ m → U i x m = f x.
-
-definition terminate ≝ λi,x,r. ∃y. U i x r = Some ? y.
-
-notation "{i ⊙ x} ↓ r" with precedence 60 for @{terminate $i $x $r}.
-
-lemma terminate_dec: ∀i,x,n. {i ⊙ x} ↓ n ∨ ¬ {i ⊙ x} ↓ n.
-#i #x #n normalize cases (U i x n)
- [%2 % * #y #H destruct|#y %1 %{y} //]
-qed.
-
-lemma monotonic_terminate: ∀i,x,n,m.
- n ≤ m → {i ⊙ x} ↓ n → {i ⊙ x} ↓ m.
-#i #x #n #m #lenm * #z #H %{z} @(monotonic_U … H) //
-qed.
-
-definition termb ≝ λi,x,t.
- match U i x t with [None ⇒ false |Some y ⇒ true].
-
-lemma termb_true_to_term: ∀i,x,t. termb i x t = true → {i ⊙ x} ↓ t.
-#i #x #t normalize cases (U i x t) normalize [#H destruct | #y #_ %{y} //]
-qed.
-
-lemma term_to_termb_true: ∀i,x,t. {i ⊙ x} ↓ t → termb i x t = true.
-#i #x #t * #y #H normalize >H //
-qed.
-
-definition out ≝ λi,x,r.
- match U i x r with [ None ⇒ 0 | Some z ⇒ z].
-
-definition bool_to_nat: bool → nat ≝
- λb. match b with [true ⇒ 1 | false ⇒ 0].
-
-coercion bool_to_nat.
-
-definition pU : nat → nat → nat → nat ≝ λi,x,r.〈termb i x r,out i x r〉.
-
-lemma pU_vs_U_Some : ∀i,x,r,y. pU i x r = 〈1,y〉 ↔ U i x r = Some ? y.
-#i #x #r #y % normalize
- [cases (U i x r) normalize
- [#H cut (0=1) [lapply (eq_f … fst … H) >fst_pair >fst_pair #H @H]
- #H1 destruct
- |#a #H cut (a=y) [lapply (eq_f … snd … H) >snd_pair >snd_pair #H1 @H1]
- #H1 //
- ]
- |#H >H //]
-qed.
-
-lemma pU_vs_U_None : ∀i,x,r. pU i x r = 〈0,0〉 ↔ U i x r = None ?.
-#i #x #r % normalize
- [cases (U i x r) normalize //
- #a #H cut (1=0) [lapply (eq_f … fst … H) >fst_pair >fst_pair #H1 @H1]
- #H1 destruct
- |#H >H //]
-qed.
-
-lemma fst_pU: ∀i,x,r. fst (pU i x r) = termb i x r.
-#i #x #r normalize cases (U i x r) normalize >fst_pair //
-qed.
-
-lemma snd_pU: ∀i,x,r. snd (pU i x r) = out i x r.
-#i #x #r normalize cases (U i x r) normalize >snd_pair //
-qed.
-
-(********************************* the speedup ********************************)
-
-definition min_input ≝ λh,i,x. μ_{y ∈ [S i,x] } (termb i y (h (S i) y)).
-
-lemma min_input_def : ∀h,i,x.
- min_input h i x = min (x -i) (S i) (λy.termb i y (h (S i) y)).
-// qed.
-
-lemma min_input_i: ∀h,i,x. x ≤ i → min_input h i x = S i.
-#h #i #x #lexi >min_input_def
-cut (x - i = 0) [@sym_eq /2 by eq_minus_O/] #Hcut //
-qed.
-
-lemma min_input_to_terminate: ∀h,i,x.
- min_input h i x = x → {i ⊙ x} ↓ (h (S i) x).
-#h #i #x #Hminx
-cases (decidable_le (S i) x) #Hix
- [cases (true_or_false (termb i x (h (S i) x))) #Hcase
- [@termb_true_to_term //
- |<Hminx in Hcase; #H lapply (fmin_false (λx.termb i x (h (S i) x)) (x-i) (S i) H)
- >min_input_def in Hminx; #Hminx >Hminx in ⊢ (%→?);
- <plus_n_Sm <plus_minus_m_m [2: @lt_to_le //]
- #Habs @False_ind /2/
- ]
- |@False_ind >min_input_i in Hminx;
- [#eqix >eqix in Hix; * /2/ | @le_S_S_to_le @not_le_to_lt //]
- ]
-qed.
-
-lemma min_input_to_lt: ∀h,i,x.
- min_input h i x = x → i < x.
-#h #i #x #Hminx cases (decidable_le (S i) x) //
-#ltxi @False_ind >min_input_i in Hminx;
- [#eqix >eqix in ltxi; * /2/ | @le_S_S_to_le @not_le_to_lt //]
-qed.
-
-lemma le_to_min_input: ∀h,i,x,x1. x ≤ x1 →
- min_input h i x = x → min_input h i x1 = x.
-#h #i #x #x1 #lex #Hminx @(min_exists … (le_S_S … lex))
- [@(fmin_true … (sym_eq … Hminx)) //
- |@(min_input_to_lt … Hminx)
- |#j #H1 <Hminx @lt_min_to_false //
- |@plus_minus_m_m @le_S_S @(transitive_le … lex) @lt_to_le
- @(min_input_to_lt … Hminx)
- ]
-qed.
-
-definition g ≝ λh,u,x.
- S (max_{i ∈[u,x[ | eqb (min_input h i x) x} (out i x (h (S i) x))).
-
-lemma g_def : ∀h,u,x. g h u x =
- S (max_{i ∈[u,x[ | eqb (min_input h i x) x} (out i x (h (S i) x))).
-// qed.
-
-lemma le_u_to_g_1 : ∀h,u,x. x ≤ u → g h u x = 1.
-#h #u #x #lexu >g_def cut (x-u = 0) [/2 by minus_le_minus_minus_comm/]
-#eq0 >eq0 normalize // qed.
-
-lemma g_lt : ∀h,i,x. min_input h i x = x →
- out i x (h (S i) x) < g h 0 x.
-#h #i #x #H @le_S_S @(le_MaxI … i) /2 by min_input_to_lt/
-qed.
-
-lemma max_neq0 : ∀a,b. max a b ≠ 0 → a ≠ 0 ∨ b ≠ 0.
-#a #b whd in match (max a b); cases (true_or_false (leb a b)) #Hcase >Hcase
- [#H %2 @H | #H %1 @H]
-qed.
-
-definition almost_equal ≝ λf,g:nat → nat. ¬ ∀nu.∃x. nu < x ∧ f x ≠ g x.
-interpretation "almost equal" 'napart f g = (almost_equal f g).
-
-lemma eventually_cancelled: ∀h,u.¬∀nu.∃x. nu < x ∧
- max_{i ∈ [0,u[ | eqb (min_input h i x) x} (out i x (h (S i) x)) ≠ 0.
-#h #u elim u
- [normalize % #H cases (H u) #x * #_ * #H1 @H1 //
- |#u0 @not_to_not #Hind #nu cases (Hind nu) #x * #ltx
- cases (true_or_false (eqb (min_input h (u0+O) x) x)) #Hcase
- [>bigop_Strue [2:@Hcase] #Hmax cases (max_neq0 … Hmax) -Hmax
- [2: #H %{x} % // <minus_n_O @H]
- #Hneq0 (* if x is not enough we retry with nu=x *)
- cases (Hind x) #x1 * #ltx1
- >bigop_Sfalse
- [#H %{x1} % [@transitive_lt //| <minus_n_O @H]
- |@not_eq_to_eqb_false >(le_to_min_input … (eqb_true_to_eq … Hcase))
- [@lt_to_not_eq @ltx1 | @lt_to_le @ltx1]
- ]
- |>bigop_Sfalse [2:@Hcase] #H %{x} % // <minus_n_O @H
- ]
- ]
-qed.
-
-lemma condition_1: ∀h,u.g h 0 ≈ g h u.
-#h #u @(not_to_not … (eventually_cancelled h u))
-#H #nu cases (H (max u nu)) #x * #ltx #Hdiff
-%{x} % [@(le_to_lt_to_lt … ltx) @(le_maxr … (le_n …))] @(not_to_not … Hdiff)
-#H @(eq_f ?? S) >(bigop_sumI 0 u x (λi:ℕ.eqb (min_input h i x) x) nat 0 MaxA)
- [>H // |@lt_to_le @(le_to_lt_to_lt …ltx) /2 by le_maxr/ |//]
-qed.
-
-(******************************** Condition 2 *********************************)
-definition total ≝ λf.λx:nat. Some nat (f x).
-
-lemma exists_to_exists_min: ∀h,i. (∃x. i < x ∧ {i ⊙ x} ↓ h (S i) x) → ∃y. min_input h i y = y.
-#h #i * #x * #ltix #Hx %{(min_input h i x)} @min_spec_to_min @found //
- [@(f_min_true (λy:ℕ.termb i y (h (S i) y))) %{x} % [% // | @term_to_termb_true //]
- |#y #leiy #lty @(lt_min_to_false ????? lty) //
- ]
-qed.
-
-lemma condition_2: ∀h,i. code_for (total (g h 0)) i → ¬∃x. i<x ∧ {i ⊙ x} ↓ h (S i) x.
-#h #i whd in ⊢(%→?); #H % #H1 cases (exists_to_exists_min … H1) #y #Hminy
-lapply (g_lt … Hminy)
-lapply (min_input_to_terminate … Hminy) * #r #termy
-cases (H y) -H #ny #Hy
-cut (r = g h 0 y) [@(unique_U … ny … termy) @Hy //] #Hr
-whd in match (out ???); >termy >Hr
-#H @(absurd ? H) @le_to_not_lt @le_n
-qed.
-
-
-(********************************* complexity *********************************)
-
-(* We assume operations have a minimal structural complexity MSC.
-For instance, for time complexity, MSC is equal to the size of input.
-For space complexity, MSC is typically 0, since we only measure the
-space required in addition to dimension of the input. *)
-
-axiom MSC : nat → nat.
-axiom MSC_le: ∀n. MSC n ≤ n.
-axiom monotonic_MSC: monotonic ? le MSC.
-axiom MSC_pair: ∀a,b. MSC 〈a,b〉 ≤ MSC a + MSC b.
-
-(* C s i means i is running in O(s) *)
-
-definition C ≝ λs,i.∃c.∃a.∀x.a ≤ x → ∃y.
- U i x (c*(s x)) = Some ? y.
-
-(* C f s means f ∈ O(s) where MSC ∈O(s) *)
-definition CF ≝ λs,f.O s MSC ∧ ∃i.code_for (total f) i ∧ C s i.
-
-lemma ext_CF : ∀f,g,s. (∀n. f n = g n) → CF s f → CF s g.
-#f #g #s #Hext * #HO * #i * #Hcode #HC % // %{i} %
- [#x cases (Hcode x) #a #H %{a} whd in match (total ??); <Hext @H | //]
-qed.
-
-lemma monotonic_CF: ∀s1,s2,f.(∀x. s1 x ≤ s2 x) → CF s1 f → CF s2 f.
-#s1 #s2 #f #H * #HO * #i * #Hcode #Hs1 %
- [cases HO #c * #a -HO #HO %{c} %{a} #n #lean @(transitive_le … (HO n lean))
- @le_times //
- |%{i} % [//] cases Hs1 #c * #a -Hs1 #Hs1 %{c} %{a} #n #lean
- cases(Hs1 n lean) #y #Hy %{y} @(monotonic_U …Hy) @le_times //
- ]
-qed.
-
-lemma O_to_CF: ∀s1,s2,f.O s2 s1 → CF s1 f → CF s2 f.
-#s1 #s2 #f #H * #HO * #i * #Hcode #Hs1 %
- [@(O_trans … H) //
- |%{i} % [//] cases Hs1 #c * #a -Hs1 #Hs1
- cases H #c1 * #a1 #Ha1 %{(c*c1)} %{(a+a1)} #n #lean
- cases(Hs1 n ?) [2:@(transitive_le … lean) //] #y #Hy %{y} @(monotonic_U …Hy)
- >associative_times @le_times // @Ha1 @(transitive_le … lean) //
- ]
-qed.
-
-lemma timesc_CF: ∀s,f,c.CF (λx.c*s x) f → CF s f.
-#s #f #c @O_to_CF @O_times_c
-qed.
-
-(********************************* composition ********************************)
-axiom CF_comp: ∀f,g,sf,sg,sh. CF sg g → CF sf f →
- O sh (λx. sg x + sf (g x)) → CF sh (f ∘ g).
-
-lemma CF_comp_ext: ∀f,g,h,sh,sf,sg. CF sg g → CF sf f →
- (∀x.f(g x) = h x) → O sh (λx. sg x + sf (g x)) → CF sh h.
-#f #g #h #sh #sf #sg #Hg #Hf #Heq #H @(ext_CF (f ∘ g))
- [#n normalize @Heq | @(CF_comp … H) //]
-qed.
-
-
-(**************************** primitive operations*****************************)
-
-definition id ≝ λx:nat.x.
-
-axiom CF_id: CF MSC id.
-axiom CF_compS: ∀h,f. CF h f → CF h (S ∘ f).
-axiom CF_comp_fst: ∀h,f. CF h f → CF h (fst ∘ f).
-axiom CF_comp_snd: ∀h,f. CF h f → CF h (snd ∘ f).
-axiom CF_comp_pair: ∀h,f,g. CF h f → CF h g → CF h (λx. 〈f x,g x〉).
-
-lemma CF_fst: CF MSC fst.
-@(ext_CF (fst ∘ id)) [#n //] @(CF_comp_fst … CF_id)
-qed.
-
-lemma CF_snd: CF MSC snd.
-@(ext_CF (snd ∘ id)) [#n //] @(CF_comp_snd … CF_id)
-qed.
-
-(************************************** eqb ***********************************)
-
-axiom CF_eqb: ∀h,f,g.
- CF h f → CF h g → CF h (λx.eqb (f x) (g x)).
-
-(*********************************** maximum **********************************)
-
-axiom CF_max: ∀a,b.∀p:nat →bool.∀f,ha,hb,hp,hf,s.
- CF ha a → CF hb b → CF hp p → CF hf f →
- O s (λx.ha x + hb x + ∑_{i ∈[a x ,b x[ }(hp 〈i,x〉 + hf 〈i,x〉)) →
- CF s (λx.max_{i ∈[a x,b x[ | p 〈i,x〉 }(f 〈i,x〉)).
-
-(******************************** minimization ********************************)
-
-axiom CF_mu: ∀a,b.∀f:nat →bool.∀sa,sb,sf,s.
- CF sa a → CF sb b → CF sf f →
- O s (λx.sa x + sb x + ∑_{i ∈[a x ,S(b x)[ }(sf 〈i,x〉)) →
- CF s (λx.μ_{i ∈[a x,b x] }(f 〈i,x〉)).
-
-(************************************* smn ************************************)
-axiom smn: ∀f,s. CF s f → ∀x. CF (λy.s 〈x,y〉) (λy.f 〈x,y〉).
-
-(****************************** constructibility ******************************)
-
-definition constructible ≝ λs. CF s s.
-
-lemma constr_comp : ∀s1,s2. constructible s1 → constructible s2 →
- (∀x. x ≤ s2 x) → constructible (s2 ∘ s1).
-#s1 #s2 #Hs1 #Hs2 #Hle @(CF_comp … Hs1 Hs2) @O_plus @le_to_O #x [@Hle | //]
-qed.
-
-lemma ext_constr: ∀s1,s2. (∀x.s1 x = s2 x) →
- constructible s1 → constructible s2.
-#s1 #s2 #Hext #Hs1 @(ext_CF … Hext) @(monotonic_CF … Hs1) #x >Hext //
-qed.
-
-(********************************* simulation *********************************)
-
-axiom sU : nat → nat.
-
-axiom monotonic_sU: ∀i1,i2,x1,x2,s1,s2. i1 ≤ i2 → x1 ≤ x2 → s1 ≤ s2 →
- sU 〈i1,〈x1,s1〉〉 ≤ sU 〈i2,〈x2,s2〉〉.
-
-lemma monotonic_sU_aux : ∀x1,x2. fst x1 ≤ fst x2 → fst (snd x1) ≤ fst (snd x2) →
-snd (snd x1) ≤ snd (snd x2) → sU x1 ≤ sU x2.
-#x1 #x2 cases (surj_pair x1) #a1 * #y #eqx1 >eqx1 -eqx1 cases (surj_pair y)
-#b1 * #c1 #eqy >eqy -eqy
-cases (surj_pair x2) #a2 * #y2 #eqx2 >eqx2 -eqx2 cases (surj_pair y2)
-#b2 * #c2 #eqy2 >eqy2 -eqy2 >fst_pair >snd_pair >fst_pair >snd_pair
->fst_pair >snd_pair >fst_pair >snd_pair @monotonic_sU
-qed.
-
-axiom sU_le: ∀i,x,s. s ≤ sU 〈i,〈x,s〉〉.
-axiom sU_le_i: ∀i,x,s. MSC i ≤ sU 〈i,〈x,s〉〉.
-axiom sU_le_x: ∀i,x,s. MSC x ≤ sU 〈i,〈x,s〉〉.
-
-definition pU_unary ≝ λp. pU (fst p) (fst (snd p)) (snd (snd p)).
-
-axiom CF_U : CF sU pU_unary.
-
-definition termb_unary ≝ λx:ℕ.termb (fst x) (fst (snd x)) (snd (snd x)).
-definition out_unary ≝ λx:ℕ.out (fst x) (fst (snd x)) (snd (snd x)).
-
-lemma CF_termb: CF sU termb_unary.
-@(ext_CF (fst ∘ pU_unary)) [2: @CF_comp_fst @CF_U]
-#n whd in ⊢ (??%?); whd in ⊢ (??(?%)?); >fst_pair %
-qed.
-
-lemma CF_out: CF sU out_unary.
-@(ext_CF (snd ∘ pU_unary)) [2: @CF_comp_snd @CF_U]
-#n whd in ⊢ (??%?); whd in ⊢ (??(?%)?); >snd_pair %
-qed.
-
-
-(******************** complexity of g ********************)
-
-definition unary_g ≝ λh.λux. g h (fst ux) (snd ux).
-definition auxg ≝
- λh,ux. max_{i ∈[fst ux,snd ux[ | eqb (min_input h i (snd ux)) (snd ux)}
- (out i (snd ux) (h (S i) (snd ux))).
-
-lemma compl_g1 : ∀h,s. CF s (auxg h) → CF s (unary_g h).
-#h #s #H1 @(CF_compS ? (auxg h) H1)
-qed.
-
-definition aux1g ≝
- λh,ux. max_{i ∈[fst ux,snd ux[ | (λp. eqb (min_input h (fst p) (snd (snd p))) (snd (snd p))) 〈i,ux〉}
- ((λp.out (fst p) (snd (snd p)) (h (S (fst p)) (snd (snd p)))) 〈i,ux〉).
-
-lemma eq_aux : ∀h,x.aux1g h x = auxg h x.
-#h #x @same_bigop
- [#n #_ >fst_pair >snd_pair // |#n #_ #_ >fst_pair >snd_pair //]
-qed.
-
-lemma compl_g2 : ∀h,s1,s2,s.
- CF s1
- (λp:ℕ.eqb (min_input h (fst p) (snd (snd p))) (snd (snd p))) →
- CF s2
- (λp:ℕ.out (fst p) (snd (snd p)) (h (S (fst p)) (snd (snd p)))) →
- O s (λx.MSC x + ∑_{i ∈[fst x ,snd x[ }(s1 〈i,x〉+s2 〈i,x〉)) →
- CF s (auxg h).
-#h #s1 #s2 #s #Hs1 #Hs2 #HO @(ext_CF (aux1g h))
- [#n whd in ⊢ (??%%); @eq_aux]
-@(CF_max … CF_fst CF_snd Hs1 Hs2 …) @(O_trans … HO)
-@O_plus [@O_plus @O_plus_l // | @O_plus_r //]
-qed.
-
-lemma compl_g3 : ∀h,s.
- CF s (λp:ℕ.min_input h (fst p) (snd (snd p))) →
- CF s (λp:ℕ.eqb (min_input h (fst p) (snd (snd p))) (snd (snd p))).
-#h #s #H @(CF_eqb … H) @(CF_comp … CF_snd CF_snd) @(O_trans … (proj1 … H))
-@O_plus // %{1} %{0} #n #_ >commutative_times <times_n_1 @monotonic_MSC //
-qed.
-
-definition min_input_aux ≝ λh,p.
- μ_{y ∈ [S (fst p),snd (snd p)] }
- ((λx.termb (fst (snd x)) (fst x) (h (S (fst (snd x))) (fst x))) 〈y,p〉).
-
-lemma min_input_eq : ∀h,p.
- min_input_aux h p =
- min_input h (fst p) (snd (snd p)).
-#h #p >min_input_def whd in ⊢ (??%?); >minus_S_S @min_f_g #i #_ #_
-whd in ⊢ (??%%); >fst_pair >snd_pair //
-qed.
-
-definition termb_aux ≝ λh.
- termb_unary ∘ λp.〈fst (snd p),〈fst p,h (S (fst (snd p))) (fst p)〉〉.
-
-lemma compl_g4 : ∀h,s1,s.
- (CF s1
- (λp.termb (fst (snd p)) (fst p) (h (S (fst (snd p))) (fst p)))) →
- (O s (λx.MSC x + ∑_{i ∈[S(fst x) ,S(snd (snd x))[ }(s1 〈i,x〉))) →
- CF s (λp:ℕ.min_input h (fst p) (snd (snd p))).
-#h #s1 #s #Hs1 #HO @(ext_CF (min_input_aux h))
- [#n whd in ⊢ (??%%); @min_input_eq]
-@(CF_mu … MSC MSC … Hs1)
- [@CF_compS @CF_fst
- |@CF_comp_snd @CF_snd
- |@(O_trans … HO) @O_plus [@O_plus @O_plus_l // | @O_plus_r //]
-qed.
-
-(************************* a couple of technical lemmas ***********************)
-lemma minus_to_0: ∀a,b. a ≤ b → minus a b = 0.
-#a elim a // #n #Hind *
- [#H @False_ind /2 by absurd/ | #b normalize #H @Hind @le_S_S_to_le /2/]
-qed.
-
-lemma sigma_bound: ∀h,a,b. monotonic nat le h →
- ∑_{i ∈ [a,S b[ }(h i) ≤ (S b-a)*h b.
-#h #a #b #H cases (decidable_le a b)
- [#leab cut (b = pred (S b - a + a))
- [<plus_minus_m_m // @le_S //] #Hb >Hb in match (h b);
- generalize in match (S b -a);
- #n elim n
- [//
- |#m #Hind >bigop_Strue [2://] @le_plus
- [@H @le_n |@(transitive_le … Hind) @le_times [//] @H //]
- ]
- |#ltba lapply (not_le_to_lt … ltba) -ltba #ltba
- cut (S b -a = 0) [@minus_to_0 //] #Hcut >Hcut //
- ]
-qed.
-
-lemma sigma_bound_decr: ∀h,a,b. (∀a1,a2. a1 ≤ a2 → a2 < b → h a2 ≤ h a1) →
- ∑_{i ∈ [a,b[ }(h i) ≤ (b-a)*h a.
-#h #a #b #H cases (decidable_le a b)
- [#leab cut ((b -a) +a ≤ b) [/2 by le_minus_to_plus_r/] generalize in match (b -a);
- #n elim n
- [//
- |#m #Hind >bigop_Strue [2://] #Hm
- cut (m+a ≤ b) [@(transitive_le … Hm) //] #Hm1
- @le_plus [@H // |@(transitive_le … (Hind Hm1)) //]
- ]
- |#ltba lapply (not_le_to_lt … ltba) -ltba #ltba
- cut (b -a = 0) [@minus_to_0 @lt_to_le @ltba] #Hcut >Hcut //
- ]
-qed.
-
-lemma coroll: ∀s1:nat→nat. (∀n. monotonic ℕ le (λa:ℕ.s1 〈a,n〉)) →
-O (λx.(snd (snd x)-fst x)*(s1 〈snd (snd x),x〉))
- (λx.∑_{i ∈[S(fst x) ,S(snd (snd x))[ }(s1 〈i,x〉)).
-#s1 #Hs1 %{1} %{0} #n #_ >commutative_times <times_n_1
-@(transitive_le … (sigma_bound …)) [@Hs1|>minus_S_S //]
-qed.
-
-lemma coroll2: ∀s1:nat→nat. (∀n,a,b. a ≤ b → b < snd n → s1 〈b,n〉 ≤ s1 〈a,n〉) →
-O (λx.(snd x - fst x)*s1 〈fst x,x〉) (λx.∑_{i ∈[fst x,snd x[ }(s1 〈i,x〉)).
-#s1 #Hs1 %{1} %{0} #n #_ >commutative_times <times_n_1
-@(transitive_le … (sigma_bound_decr …)) [2://] @Hs1
-qed.
-
-(**************************** end of technical lemmas *************************)
-
-lemma compl_g5 : ∀h,s1.(∀n. monotonic ℕ le (λa:ℕ.s1 〈a,n〉)) →
- (CF s1
- (λp.termb (fst (snd p)) (fst p) (h (S (fst (snd p))) (fst p)))) →
- CF (λx.MSC x + (snd (snd x)-fst x)*s1 〈snd (snd x),x〉)
- (λp:ℕ.min_input h (fst p) (snd (snd p))).
-#h #s1 #Hmono #Hs1 @(compl_g4 … Hs1) @O_plus
-[@O_plus_l // |@O_plus_r @coroll @Hmono]
-qed.
-
-lemma compl_g6: ∀h.
- constructible (λx. h (fst x) (snd x)) →
- (CF (λx. sU 〈max (fst (snd x)) (snd (snd x)),〈fst x,h (S (fst (snd x))) (fst x)〉〉)
- (λp.termb (fst (snd p)) (fst p) (h (S (fst (snd p))) (fst p)))).
-#h #hconstr @(ext_CF (termb_aux h))
- [#n normalize >fst_pair >snd_pair >fst_pair >snd_pair // ]
-@(CF_comp … (λx.MSC x + h (S (fst (snd x))) (fst x)) … CF_termb)
- [@CF_comp_pair
- [@CF_comp_fst @(monotonic_CF … CF_snd) #x //
- |@CF_comp_pair
- [@(monotonic_CF … CF_fst) #x //
- |@(ext_CF ((λx.h (fst x) (snd x))∘(λx.〈S (fst (snd x)),fst x〉)))
- [#n normalize >fst_pair >snd_pair %]
- @(CF_comp … MSC …hconstr)
- [@CF_comp_pair [@CF_compS @CF_comp_fst // |//]
- |@O_plus @le_to_O [//|#n >fst_pair >snd_pair //]
- ]
- ]
- ]
- |@O_plus
- [@O_plus
- [@(O_trans … (λx.MSC (fst x) + MSC (max (fst (snd x)) (snd (snd x)))))
- [%{2} %{0} #x #_ cases (surj_pair x) #a * #b #eqx >eqx
- >fst_pair >snd_pair @(transitive_le … (MSC_pair …))
- >distributive_times_plus @le_plus [//]
- cases (surj_pair b) #c * #d #eqb >eqb
- >fst_pair >snd_pair @(transitive_le … (MSC_pair …))
- whd in ⊢ (??%); @le_plus
- [@monotonic_MSC @(le_maxl … (le_n …))
- |>commutative_times <times_n_1 @monotonic_MSC @(le_maxr … (le_n …))
- ]
- |@O_plus [@le_to_O #x @sU_le_x |@le_to_O #x @sU_le_i]
- ]
- |@le_to_O #n @sU_le
- ]
- |@le_to_O #x @monotonic_sU // @(le_maxl … (le_n …)) ]
- ]
-qed.
-
-definition big : nat →nat ≝ λx.
- let m ≝ max (fst x) (snd x) in 〈m,m〉.
-
-lemma big_def : ∀a,b. big 〈a,b〉 = 〈max a b,max a b〉.
-#a #b normalize >fst_pair >snd_pair // qed.
-
-lemma le_big : ∀x. x ≤ big x.
-#x cases (surj_pair x) #a * #b #eqx >eqx @le_pair >fst_pair >snd_pair
-[@(le_maxl … (le_n …)) | @(le_maxr … (le_n …))]
-qed.
-
-definition faux2 ≝ λh.
- (λx.MSC x + (snd (snd x)-fst x)*
- (λx.sU 〈max (fst(snd x)) (snd(snd x)),〈fst x,h (S (fst (snd x))) (fst x)〉〉) 〈snd (snd x),x〉).
-
-lemma compl_g7: ∀h.
- constructible (λx. h (fst x) (snd x)) →
- (∀n. monotonic ? le (h n)) →
- CF (λx.MSC x + (snd (snd x)-fst x)*sU 〈max (fst x) (snd x),〈snd (snd x),h (S (fst x)) (snd (snd x))〉〉)
- (λp:ℕ.min_input h (fst p) (snd (snd p))).
-#h #hcostr #hmono @(monotonic_CF … (faux2 h))
- [#n normalize >fst_pair >snd_pair //]
-@compl_g5 [2:@(compl_g6 h hcostr)] #n #x #y #lexy >fst_pair >snd_pair
->fst_pair >snd_pair @monotonic_sU // @hmono @lexy
-qed.
-
-lemma compl_g71: ∀h.
- constructible (λx. h (fst x) (snd x)) →
- (∀n. monotonic ? le (h n)) →
- CF (λx.MSC (big x) + (snd (snd x)-fst x)*sU 〈max (fst x) (snd x),〈snd (snd x),h (S (fst x)) (snd (snd x))〉〉)
- (λp:ℕ.min_input h (fst p) (snd (snd p))).
-#h #hcostr #hmono @(monotonic_CF … (compl_g7 h hcostr hmono)) #x
-@le_plus [@monotonic_MSC //]
-cases (decidable_le (fst x) (snd(snd x)))
- [#Hle @le_times // @monotonic_sU
- |#Hlt >(minus_to_0 … (lt_to_le … )) [// | @not_le_to_lt @Hlt]
- ]
-qed.
-
-definition out_aux ≝ λh.
- out_unary ∘ λp.〈fst p,〈snd(snd p),h (S (fst p)) (snd (snd p))〉〉.
-
-lemma compl_g8: ∀h.
- constructible (λx. h (fst x) (snd x)) →
- (CF (λx. sU 〈max (fst x) (snd x),〈snd(snd x),h (S (fst x)) (snd(snd x))〉〉)
- (λp.out (fst p) (snd (snd p)) (h (S (fst p)) (snd (snd p))))).
-#h #hconstr @(ext_CF (out_aux h))
- [#n normalize >fst_pair >snd_pair >fst_pair >snd_pair // ]
-@(CF_comp … (λx.h (S (fst x)) (snd(snd x)) + MSC x) … CF_out)
- [@CF_comp_pair
- [@(monotonic_CF … CF_fst) #x //
- |@CF_comp_pair
- [@CF_comp_snd @(monotonic_CF … CF_snd) #x //
- |@(ext_CF ((λx.h (fst x) (snd x))∘(λx.〈S (fst x),snd(snd x)〉)))
- [#n normalize >fst_pair >snd_pair %]
- @(CF_comp … MSC …hconstr)
- [@CF_comp_pair [@CF_compS // | @CF_comp_snd // ]
- |@O_plus @le_to_O [//|#n >fst_pair >snd_pair //]
- ]
- ]
- ]
- |@O_plus
- [@O_plus
- [@le_to_O #n @sU_le
- |@(O_trans … (λx.MSC (max (fst x) (snd x))))
- [%{2} %{0} #x #_ cases (surj_pair x) #a * #b #eqx >eqx
- >fst_pair >snd_pair @(transitive_le … (MSC_pair …))
- whd in ⊢ (??%); @le_plus
- [@monotonic_MSC @(le_maxl … (le_n …))
- |>commutative_times <times_n_1 @monotonic_MSC @(le_maxr … (le_n …))
- ]
- |@le_to_O #x @(transitive_le ???? (sU_le_i … )) //
- ]
- ]
- |@le_to_O #x @monotonic_sU [@(le_maxl … (le_n …))|//|//]
- ]
-qed.
-
-lemma compl_g9 : ∀h.
- constructible (λx. h (fst x) (snd x)) →
- (∀n. monotonic ? le (h n)) →
- (∀n,a,b. a ≤ b → b ≤ n → h b n ≤ h a n) →
- CF (λx. (S (snd x-fst x))*MSC 〈x,x〉 +
- (snd x-fst x)*(S(snd x-fst x))*sU 〈x,〈snd x,h (S (fst x)) (snd x)〉〉)
- (auxg h).
-#h #hconstr #hmono #hantimono
-@(compl_g2 h ??? (compl_g3 … (compl_g71 h hconstr hmono)) (compl_g8 h hconstr))
-@O_plus
- [@O_plus_l @le_to_O #x >(times_n_1 (MSC x)) >commutative_times @le_times
- [// | @monotonic_MSC // ]]
-@(O_trans … (coroll2 ??))
- [#n #a #b #leab #ltb >fst_pair >fst_pair >snd_pair >snd_pair
- cut (b ≤ n) [@(transitive_le … (le_snd …)) @lt_to_le //] #lebn
- cut (max a n = n)
- [normalize >le_to_leb_true [//|@(transitive_le … leab lebn)]] #maxa
- cut (max b n = n) [normalize >le_to_leb_true //] #maxb
- @le_plus
- [@le_plus [>big_def >big_def >maxa >maxb //]
- @le_times
- [/2 by monotonic_le_minus_r/
- |@monotonic_sU // @hantimono [@le_S_S // |@ltb]
- ]
- |@monotonic_sU // @hantimono [@le_S_S // |@ltb]
- ]
- |@le_to_O #n >fst_pair >snd_pair
- cut (max (fst n) n = n) [normalize >le_to_leb_true //] #Hmax >Hmax
- >associative_plus >distributive_times_plus
- @le_plus [@le_times [@le_S // |>big_def >Hmax //] |//]
- ]
-qed.
-
-definition sg ≝ λh,x.
- (S (snd x-fst x))*MSC 〈x,x〉 + (snd x-fst x)*(S(snd x-fst x))*sU 〈x,〈snd x,h (S (fst x)) (snd x)〉〉.
-
-lemma sg_def : ∀h,a,b.
- sg h 〈a,b〉 = (S (b-a))*MSC 〈〈a,b〉,〈a,b〉〉 +
- (b-a)*(S(b-a))*sU 〈〈a,b〉,〈b,h (S a) b〉〉.
-#h #a #b whd in ⊢ (??%?); >fst_pair >snd_pair //
-qed.
-
-lemma compl_g11 : ∀h.
- constructible (λx. h (fst x) (snd x)) →
- (∀n. monotonic ? le (h n)) →
- (∀n,a,b. a ≤ b → b ≤ n → h b n ≤ h a n) →
- CF (sg h) (unary_g h).
-#h #hconstr #Hm #Ham @compl_g1 @(compl_g9 h hconstr Hm Ham)
-qed.
-
-(**************************** closing the argument ****************************)
-
-let rec h_of_aux (r:nat →nat) (c,d,b:nat) on d : nat ≝
- match d with
- [ O ⇒ c
- | S d1 ⇒ (S d)*(MSC 〈〈b-d,b〉,〈b-d,b〉〉) +
- d*(S d)*sU 〈〈b-d,b〉,〈b,r (h_of_aux r c d1 b)〉〉].
-
-lemma h_of_aux_O: ∀r,c,b.
- h_of_aux r c O b = c.
-// qed.
-
-lemma h_of_aux_S : ∀r,c,d,b.
- h_of_aux r c (S d) b =
- (S (S d))*(MSC 〈〈b-(S d),b〉,〈b-(S d),b〉〉) +
- (S d)*(S (S d))*sU 〈〈b-(S d),b〉,〈b,r(h_of_aux r c d b)〉〉.
-// qed.
-
-definition h_of ≝ λr,p.
- let m ≝ max (fst p) (snd p) in
- h_of_aux r (MSC 〈〈m,m〉,〈m,m〉〉) (snd p - fst p) (snd p).
-
-lemma h_of_O: ∀r,a,b. b ≤ a →
- h_of r 〈a,b〉 = let m ≝ max a b in MSC 〈〈m,m〉,〈m,m〉〉.
-#r #a #b #Hle normalize >fst_pair >snd_pair >(minus_to_0 … Hle) //
-qed.
-
-lemma h_of_def: ∀r,a,b.h_of r 〈a,b〉 =
- let m ≝ max a b in
- h_of_aux r (MSC 〈〈m,m〉,〈m,m〉〉) (b - a) b.
-#r #a #b normalize >fst_pair >snd_pair //
-qed.
-
-lemma mono_h_of_aux: ∀r.(∀x. x ≤ r x) → monotonic ? le r →
- ∀d,d1,c,c1,b,b1.c ≤ c1 → d ≤ d1 → b ≤ b1 →
- h_of_aux r c d b ≤ h_of_aux r c1 d1 b1.
-#r #Hr #monor #d #d1 lapply d -d elim d1
- [#d #c #c1 #b #b1 #Hc #Hd @(le_n_O_elim ? Hd) #leb
- >h_of_aux_O >h_of_aux_O //
- |#m #Hind #d #c #c1 #b #b1 #lec #led #leb cases (le_to_or_lt_eq … led)
- [#ltd @(transitive_le … (Hind … lec ? leb)) [@le_S_S_to_le @ltd]
- >h_of_aux_S @(transitive_le ???? (le_plus_n …))
- >(times_n_1 (h_of_aux r c1 m b1)) in ⊢ (?%?);
- >commutative_times @le_times [//|@(transitive_le … (Hr ?)) @sU_le]
- |#Hd >Hd >h_of_aux_S >h_of_aux_S
- cut (b-S m ≤ b1 - S m) [/2 by monotonic_le_minus_l/] #Hb1
- @le_plus [@le_times //]
- [@monotonic_MSC @le_pair @le_pair //
- |@le_times [//] @monotonic_sU
- [@le_pair // |// |@monor @Hind //]
- ]
- ]
- ]
-qed.
-
-lemma mono_h_of2: ∀r.(∀x. x ≤ r x) → monotonic ? le r →
- ∀i,b,b1. b ≤ b1 → h_of r 〈i,b〉 ≤ h_of r 〈i,b1〉.
-#r #Hr #Hmono #i #a #b #leab >h_of_def >h_of_def
-cut (max i a ≤ max i b)
- [@to_max
- [@(le_maxl … (le_n …))|@(transitive_le … leab) @(le_maxr … (le_n …))]]
-#Hmax @(mono_h_of_aux r Hr Hmono)
- [@monotonic_MSC @le_pair @le_pair @Hmax |/2 by monotonic_le_minus_l/ |@leab]
-qed.
-
-axiom h_of_constr : ∀r:nat →nat.
- (∀x. x ≤ r x) → monotonic ? le r → constructible r →
- constructible (h_of r).
-
-lemma speed_compl: ∀r:nat →nat.
- (∀x. x ≤ r x) → monotonic ? le r → constructible r →
- CF (h_of r) (unary_g (λi,x. r(h_of r 〈i,x〉))).
-#r #Hr #Hmono #Hconstr @(monotonic_CF … (compl_g11 …))
- [#x cases (surj_pair x) #a * #b #eqx >eqx
- >sg_def cases (decidable_le b a)
- [#leba >(minus_to_0 … leba) normalize in ⊢ (?%?);
- <plus_n_O <plus_n_O >h_of_def
- cut (max a b = a)
- [normalize cases (le_to_or_lt_eq … leba)
- [#ltba >(lt_to_leb_false … ltba) %
- |#eqba <eqba >(le_to_leb_true … (le_n ?)) % ]]
- #Hmax >Hmax normalize >(minus_to_0 … leba) normalize
- @monotonic_MSC @le_pair @le_pair //
- |#ltab >h_of_def >h_of_def
- cut (max a b = b)
- [normalize >(le_to_leb_true … ) [%] @lt_to_le @not_le_to_lt @ltab]
- #Hmax >Hmax
- cut (max (S a) b = b)
- [whd in ⊢ (??%?); >(le_to_leb_true … ) [%] @not_le_to_lt @ltab]
- #Hmax1 >Hmax1
- cut (∃d.b - a = S d)
- [%{(pred(b-a))} >S_pred [//] @lt_plus_to_minus_r @not_le_to_lt @ltab]
- * #d #eqd >eqd
- cut (b-S a = d) [//] #eqd1 >eqd1 >h_of_aux_S >eqd1
- cut (b - S d = a)
- [@plus_to_minus >commutative_plus @minus_to_plus
- [@lt_to_le @not_le_to_lt // | //]] #eqd2 >eqd2
- normalize //
- ]
- |#n #a #b #leab #lebn >h_of_def >h_of_def
- cut (max a n = n)
- [normalize >le_to_leb_true [%|@(transitive_le … leab lebn)]] #Hmaxa
- cut (max b n = n)
- [normalize >(le_to_leb_true … lebn) %] #Hmaxb
- >Hmaxa >Hmaxb @Hmono @(mono_h_of_aux r … Hr Hmono) // /2 by monotonic_le_minus_r/
- |#n #a #b #leab @Hmono @(mono_h_of2 … Hr Hmono … leab)
- |@(constr_comp … Hconstr Hr) @(ext_constr (h_of r))
- [#x cases (surj_pair x) #a * #b #eqx >eqx >fst_pair >snd_pair //]
- @(h_of_constr r Hr Hmono Hconstr)
- ]
-qed.
-
-lemma speed_compl_i: ∀r:nat →nat.
- (∀x. x ≤ r x) → monotonic ? le r → constructible r →
- ∀i. CF (λx.h_of r 〈i,x〉) (λx.g (λi,x. r(h_of r 〈i,x〉)) i x).
-#r #Hr #Hmono #Hconstr #i
-@(ext_CF (λx.unary_g (λi,x. r(h_of r 〈i,x〉)) 〈i,x〉))
- [#n whd in ⊢ (??%%); @eq_f @sym_eq >fst_pair >snd_pair %]
-@smn @(ext_CF … (speed_compl r Hr Hmono Hconstr)) #n //
-qed.
-
-(**************************** the speedup theorem *****************************)
-theorem pseudo_speedup:
- ∀r:nat →nat. (∀x. x ≤ r x) → monotonic ? le r → constructible r →
- ∃f.∀sf. CF sf f → ∃g,sg. f ≈ g ∧ CF sg g ∧ O sf (r ∘ sg).
-(* ∃m,a.∀n. a≤n → r(sg a) < m * sf n. *)
-#r #Hr #Hmono #Hconstr
-(* f is (g (λi,x. r(h_of r 〈i,x〉)) 0) *)
-%{(g (λi,x. r(h_of r 〈i,x〉)) 0)} #sf * #H * #i *
-#Hcodei #HCi
-(* g is (g (λi,x. r(h_of r 〈i,x〉)) (S i)) *)
-%{(g (λi,x. r(h_of r 〈i,x〉)) (S i))}
-(* sg is (λx.h_of r 〈i,x〉) *)
-%{(λx. h_of r 〈S i,x〉)}
-lapply (speed_compl_i … Hr Hmono Hconstr (S i)) #Hg
-%[%[@condition_1 |@Hg]
- |cases Hg #H1 * #j * #Hcodej #HCj
- lapply (condition_2 … Hcodei) #Hcond2 (* @not_to_not *)
- cases HCi #m * #a #Ha %{m} %{(max (S i) a)} #n #ltin @lt_to_le @not_le_to_lt
- @(not_to_not … Hcond2) -Hcond2 #Hlesf %{n} %
- [@(transitive_le … ltin) @(le_maxl … (le_n …))]
- cases (Ha n ?) [2: @(transitive_le … ltin) @(le_maxr … (le_n …))]
- #y #Uy %{y} @(monotonic_U … Uy) @(transitive_le … Hlesf) //
- ]
-qed.
-
-theorem pseudo_speedup':
- ∀r:nat →nat. (∀x. x ≤ r x) → monotonic ? le r → constructible r →
- ∃f.∀sf. CF sf f → ∃g,sg. f ≈ g ∧ CF sg g ∧
- (* ¬ O (r ∘ sg) sf. *)
- ∃m,a.∀n. a≤n → r(sg a) < m * sf n.
-#r #Hr #Hmono #Hconstr
-(* f is (g (λi,x. r(h_of r 〈i,x〉)) 0) *)
-%{(g (λi,x. r(h_of r 〈i,x〉)) 0)} #sf * #H * #i *
-#Hcodei #HCi
-(* g is (g (λi,x. r(h_of r 〈i,x〉)) (S i)) *)
-%{(g (λi,x. r(h_of r 〈i,x〉)) (S i))}
-(* sg is (λx.h_of r 〈i,x〉) *)
-%{(λx. h_of r 〈S i,x〉)}
-lapply (speed_compl_i … Hr Hmono Hconstr (S i)) #Hg
-%[%[@condition_1 |@Hg]
- |cases Hg #H1 * #j * #Hcodej #HCj
- lapply (condition_2 … Hcodei) #Hcond2 (* @not_to_not *)
- cases HCi #m * #a #Ha
- %{m} %{(max (S i) a)} #n #ltin @not_le_to_lt @(not_to_not … Hcond2) -Hcond2 #Hlesf
- %{n} % [@(transitive_le … ltin) @(le_maxl … (le_n …))]
- cases (Ha n ?) [2: @(transitive_le … ltin) @(le_maxr … (le_n …))]
- #y #Uy %{y} @(monotonic_U … Uy) @(transitive_le … Hlesf)
- @Hmono @(mono_h_of2 … Hr Hmono … ltin)
- ]
-qed.
-