Theory Multiseries_Expansion_Bounds

section ‹Asymptotic real interval arithmetic›
(*
  File:     Multiseries_Expansion_Bounds.thy
  Author:   Manuel Eberl, TU München

  Automatic computation of upper and lower expansions for real-valued functions.
  Allows limited handling of functions involving oscillating functions like sin, cos, floor, etc.
*)
theory Multiseries_Expansion_Bounds
imports
  Multiseries_Expansion
begin

lemma expands_to_cong_reverse:
  "eventually (λx. f x = g x) at_top  (g expands_to F) bs  (f expands_to F) bs"
  using expands_to_cong[of g F bs f] by (simp add: eq_commute)

lemma expands_to_trivial_bounds: "(f expands_to F) bs  eventually (λx. f x  {f x..f x}) at_top"
  by simp

lemma eventually_in_atLeastAtMostI:
  assumes "eventually (λx. f x  l x) at_top" "eventually (λx. f x  u x) at_top"
  shows   "eventually (λx. f x  {l x..u x}) at_top"
  using assms by eventually_elim simp_all

lemma tendsto_sandwich':
  fixes l f u :: "'a  'b :: order_topology"
  shows "eventually (λx. l x  f x) F  eventually (λx. f x  u x) F 
           (l  L1) F  (u  L2) F  L1 = L2  (f  L1) F"
  using tendsto_sandwich[of l f F u L1] by simp

(* TODO: Move? *)
lemma filterlim_at_bot_mono:
  fixes l f u :: "'a  'b :: linorder_topology"
  assumes "filterlim u at_bot F" and "eventually (λx. f x  u x) F"
  shows   "filterlim f at_bot F"
  unfolding filterlim_at_bot
proof
  fix Z :: 'b
  from assms(1) have "eventually (λx. u x  Z) F" by (auto simp: filterlim_at_bot)
  with assms(2) show "eventually (λx. f x  Z) F" by eventually_elim simp
qed

context
begin

qualified lemma eq_zero_imp_nonneg: "x = (0::real)  x  0"
  by simp

qualified lemma exact_to_bound: "(f expands_to F) bs  eventually (λx. f x  f x) at_top"
  by simp

qualified lemma expands_to_abs_nonneg: "(f expands_to F) bs  eventually (λx. abs (f x)  0) at_top"
  by simp

qualified lemma eventually_nonpos_flip: "eventually (λx. f x  (0::real)) F  eventually (λx. -f x  0) F"
  by simp

qualified lemma bounds_uminus:
  fixes a b :: "real  real"
  assumes "eventually (λx. a x  b x) at_top"
  shows   "eventually (λx. -b x  -a x) at_top"
  using assms by eventually_elim simp

qualified lemma
  fixes a b c d :: "real  real"
  assumes "eventually (λx. a x  b x) at_top" "eventually (λx. c x  d x) at_top"
  shows   combine_bounds_add:  "eventually (λx. a x + c x  b x + d x) at_top"
    and   combine_bounds_diff: "eventually (λx. a x - d x  b x - c x) at_top"
  by (use assms in eventually_elim; simp add: add_mono diff_mono)+

qualified lemma
  fixes a b c d :: "real  real"
  assumes "eventually (λx. a x  b x) at_top" "eventually (λx. c x  d x) at_top"
  shows   combine_bounds_min: "eventually (λx. min (a x) (c x)  min (b x) (d x)) at_top"
    and   combine_bounds_max: "eventually (λx. max (a x) (c x)  max (b x) (d x)) at_top"
  by (blast intro: eventually_elim2[OF assms] min.mono max.mono)+


qualified lemma trivial_bounds_sin:  "x::real. sin x  {-1..1}"
  and trivial_bounds_cos:  "x::real. cos x  {-1..1}"
  and trivial_bounds_frac: "x::real. frac x  {0..1}"
  by (auto simp: less_imp_le[OF frac_lt_1])

qualified lemma trivial_boundsI:
  fixes f g:: "real  real"
  assumes "x. f x  {l..u}" and "g  g"
  shows   "eventually (λx. f (g x)  l) at_top" "eventually (λx. f (g x)  u) at_top"
  using assms by auto

qualified lemma
  fixes f f' :: "real  real"
  shows transfer_lower_bound:
          "eventually (λx. g x  l x) at_top  f  g  eventually (λx. f x  l x) at_top"
  and   transfer_upper_bound:
          "eventually (λx. g x  u x) at_top  f  g  eventually (λx. f x  u x) at_top"
  by simp_all  

qualified lemma mono_bound:
  fixes f g h :: "real  real"
  assumes "mono h" "eventually (λx. f x  g x) at_top"
  shows   "eventually (λx. h (f x)  h (g x)) at_top"
  by (intro eventually_mono[OF assms(2)] monoD[OF assms(1)])

qualified lemma
  fixes f l :: "real  real"
  assumes "(l expands_to L) bs" "trimmed_pos L" "basis_wf bs" "eventually (λx. l x  f x) at_top"
  shows   expands_to_lb_ln: "eventually (λx. ln (l x)  ln (f x)) at_top"
    and   expands_to_ub_ln: 
            "eventually (λx. f x  u x) at_top  eventually (λx. ln (f x)  ln (u x)) at_top"
proof -
  from assms(3,1,2) have pos: "eventually (λx. l x > 0) at_top"
    by (rule expands_to_imp_eventually_pos)  
  from pos and assms(4)
    show "eventually (λx. ln (l x)  ln (f x)) at_top" by eventually_elim simp
  assume "eventually (λx. f x  u x) at_top"
  with pos and assms(4) show "eventually (λx. ln (f x)  ln (u x)) at_top"
    by eventually_elim simp
qed

qualified lemma eventually_sgn_ge_1D:
  assumes "eventually (λx::real. sgn (f x)  l x) at_top"
          "(l expands_to (const_expansion 1 :: 'a :: multiseries)) bs"
  shows   "((λx. sgn (f x)) expands_to (const_expansion 1 :: 'a)) bs"
proof (rule expands_to_cong)
  from assms(2) have "eventually (λx. l x = 1) at_top"
    by (simp add: expands_to.simps)
  with assms(1) show "eventually (λx. 1 = sgn (f x)) at_top"
    by eventually_elim (auto simp: sgn_if split: if_splits)
qed (insert assms, auto simp: expands_to.simps)

qualified lemma eventually_sgn_le_neg1D:
  assumes "eventually (λx::real. sgn (f x)  u x) at_top"
          "(u expands_to (const_expansion (-1) :: 'a :: multiseries)) bs"
  shows   "((λx. sgn (f x)) expands_to (const_expansion (-1) :: 'a)) bs"
proof (rule expands_to_cong)
  from assms(2) have "eventually (λx. u x = -1) at_top"
    by (simp add: expands_to.simps eq_commute)
  with assms(1) show "eventually (λx. -1 = sgn (f x)) at_top"
    by eventually_elim (auto simp: sgn_if split: if_splits)
qed (insert assms, auto simp: expands_to.simps)


qualified lemma expands_to_squeeze:
  assumes "eventually (λx. l x  f x) at_top" "eventually (λx. f x  g x) at_top"
          "(l expands_to L) bs" "(g expands_to L) bs"
  shows   "(f expands_to L) bs"
proof (rule expands_to_cong[OF assms(3)])
  from assms have "eventually (λx. eval L x = l x) at_top" "eventually (λx. eval L x = g x) at_top"
    by (simp_all add: expands_to.simps)
  with assms(1,2) show "eventually (λx. l x = f x) at_top"
    by eventually_elim simp
qed 


qualified lemma mono_exp_real: "mono (exp :: real  real)"
  by (auto intro!: monoI)

qualified lemma mono_sgn_real: "mono (sgn :: real  real)"
  by (auto intro!: monoI simp: sgn_if)

qualified lemma mono_arctan_real: "mono (arctan :: real  real)"
  by (auto intro!: monoI arctan_monotone')

qualified lemma mono_root_real: "n  n  mono (root n :: real  real)"
  by (cases n) (auto simp: mono_def)

qualified lemma mono_rfloor: "mono rfloor" and mono_rceil: "mono rceil"
  by (auto intro!: monoI simp: rfloor_def floor_mono rceil_def ceiling_mono)

qualified lemma lower_bound_cong:
  "eventually (λx. f x = g x) at_top  eventually (λx. l x  g x) at_top 
     eventually (λx. l x  f x) at_top"
  by (erule (1) eventually_elim2) simp

qualified lemma upper_bound_cong:
  "eventually (λx. f x = g x) at_top  eventually (λx. g x  u x) at_top 
     eventually (λx. f x  u x) at_top"
  by (erule (1) eventually_elim2) simp

qualified lemma
  assumes "eventually (λx. f x = (g x :: real)) at_top"
  shows   eventually_eq_min: "eventually (λx. min (f x) (g x) = f x) at_top"
    and   eventually_eq_max: "eventually (λx. max (f x) (g x) = f x) at_top"
  by (rule eventually_mono[OF assms]; simp)+

qualified lemma rfloor_bound:
    "eventually (λx. l x  f x) at_top  eventually (λx. l x - 1  rfloor (f x)) at_top"
    "eventually (λx. f x  u x) at_top  eventually (λx. rfloor (f x)  u x) at_top"
  and rceil_bound:
    "eventually (λx. l x  f x) at_top  eventually (λx. l x  rceil (f x)) at_top"
    "eventually (λx. f x  u x) at_top  eventually (λx. rceil (f x)  u x + 1) at_top"
  unfolding rfloor_def rceil_def by (erule eventually_mono, linarith)+

qualified lemma natmod_trivial_lower_bound:
  fixes f g :: "real  real"
  assumes "f  f" "g  g"
  shows "eventually (λx. rnatmod (f x) (g x)  0) at_top"
  by (simp add: rnatmod_def)

qualified lemma natmod_upper_bound:
  fixes f g :: "real  real"
  assumes "f  f" and "eventually (λx. l2 x  g x) at_top" and "eventually (λx. g x  u2 x) at_top"
  assumes "eventually (λx. l2 x - 1  0) at_top"
  shows "eventually (λx. rnatmod (f x) (g x)  u2 x - 1) at_top"
  using assms(2-)
proof eventually_elim
  case (elim x)
  have "rnatmod (f x) (g x) = real (nat f x mod nat g x)"
    by (simp add: rnatmod_def)
  also have "nat f x mod nat g x < nat g x"
    using elim by (intro mod_less_divisor) auto
  hence "real (nat f x mod nat g x)  u2 x - 1"
    using elim by linarith
  finally show ?case .
qed

qualified lemma natmod_upper_bound':
  fixes f g :: "real  real"
  assumes "g  g" "eventually (λx. u1 x  0) at_top" and "eventually (λx. f x  u1 x) at_top"
  shows "eventually (λx. rnatmod (f x) (g x)  u1 x) at_top"
  using assms(2-)
proof eventually_elim
  case (elim x)
  have "rnatmod (f x) (g x) = real (nat f x mod nat g x)"
    by (simp add: rnatmod_def)
  also have "nat f x mod nat g x  nat f x"
    by auto
  hence "real (nat f x mod nat g x)  real (nat f x)"
    by simp
  also have "  u1 x" using elim by linarith
  finally show "rnatmod (f x) (g x)  " .
qed

qualified lemma expands_to_natmod_nonpos:
  fixes f g :: "real  real"
  assumes "g  g" "eventually (λx. u1 x  0) at_top" "eventually (λx. f x  u1 x) at_top"
          "((λ_. 0) expands_to C) bs"
  shows "((λx. rnatmod (f x) (g x)) expands_to C) bs"
  by (rule expands_to_cong[OF assms(4)])
     (insert assms, auto elim: eventually_elim2 simp: rnatmod_def)
  

qualified lemma eventually_atLeastAtMostI:
  fixes f l r :: "real  real"
  assumes "eventually (λx. l x  f x) at_top" "eventually (λx. f x  u x) at_top"
  shows   "eventually (λx. f x  {l x..u x}) at_top"
  using assms by eventually_elim simp

qualified lemma eventually_atLeastAtMostD:
  fixes f l r :: "real  real"
  assumes "eventually (λx. f x  {l x..u x}) at_top"
  shows   "eventually (λx. l x  f x) at_top" "eventually (λx. f x  u x) at_top" 
  using assms by (simp_all add: eventually_conj_iff)

qualified lemma eventually_0_imp_prod_zero:
  fixes f g :: "real  real"
  assumes "eventually (λx. f x = 0) at_top"
  shows   "eventually (λx. f x * g x = 0) at_top" "eventually (λx. g x * f x = 0) at_top"
  by (use assms in eventually_elim; simp)+

qualified lemma mult_right_bounds:
  fixes f g :: "real  real"
  shows "x. f x  {l x..u x}  g x  0  f x * g x  {l x * g x..u x * g x}"
    and "x. f x  {l x..u x}  g x  0  f x * g x  {u x * g x..l x * g x}"
  by (auto intro: mult_right_mono mult_right_mono_neg)

qualified lemma mult_left_bounds:
  fixes f g :: "real  real"
  shows "x. g x  {l x..u x}  f x  0  f x * g x  {f x * l x..f x * u x}"
    and "x. g x  {l x..u x}  f x  0  f x * g x  {f x * u x..f x * l x}"
  by (auto intro: mult_left_mono mult_left_mono_neg)

qualified lemma mult_mono_nonpos_nonneg:
  "a  c  d  b  a  0  d  0  a * b  c * (d :: 'a :: linordered_ring)"
  using mult_mono[of "-c" "-a" d b] by simp

qualified lemma mult_mono_nonneg_nonpos:
  "c  a  b  d  a  0  d  0  a * b  c * (d :: 'a :: {comm_ring, linordered_ring})"
  using mult_mono[of c a "-d" "-b"] by (simp add: mult.commute)

qualified lemma mult_mono_nonpos_nonpos:
  "c  a  d  b  c  0  b  0  a * b  c * (d :: 'a :: linordered_ring)"
  using mult_mono[of "-a" "-c" "-b" "-d"] by simp

qualified lemmas mult_monos =
  mult_mono mult_mono_nonpos_nonneg mult_mono_nonneg_nonpos mult_mono_nonpos_nonpos


qualified lemma mult_bounds_real:
  fixes f g l1 u1 l2 u2 l u :: "real  real"
  defines "P  λl u x. f x  {l1 x..u1 x}  g x  {l2 x..u2 x}  f x * g x  {l..u}"
  shows   "x. l1 x  0  l2 x  0  P (l1 x * l2 x) (u1 x * u2 x) x"
    and   "x. u1 x  0  l2 x  0  P (l1 x * u2 x) (u1 x * l2 x) x"
    and   "x. l1 x  0  u2 x  0  P (u1 x * l2 x) (l1 x * u2 x) x"
    and   "x. u1 x  0  u2 x  0  P (u1 x * u2 x) (l1 x * l2 x) x"

    and   "x. l1 x  0  u1 x  0  l2 x  0  P (l1 x * u2 x) (u1 x * u2 x) x"
    and   "x. l1 x  0  u1 x  0  u2 x  0  P (u1 x * l2 x) (l1 x * l2 x) x"
    and   "x. l1 x  0  l2 x  0  u2 x  0  P (u1 x * l2 x) (u1 x * u2 x) x"
    and   "x. u1 x  0  l2 x  0  u2 x  0  P (l1 x * u2 x) (l1 x * l2 x) x"

    and   "x. l1 x  0  u1 x  0  l2 x  0  u2 x  0  l x  l1 x * u2 x 
             l x  u1 x * l2 x  u x  l1 x* l2 x  u x  u1 x * u2 x  P (l x) (u x) x"
proof goal_cases
  case 1
  show ?case by (auto intro: mult_mono simp: P_def)
next
  case 2
  show ?case by (auto intro: mult_monos(2) simp: P_def)
next
  case 3
  show ?case unfolding P_def
    by (subst (1 2 3) mult.commute) (auto intro: mult_monos(2) simp: P_def)
next
  case 4
  show ?case by (auto intro: mult_monos(4) simp: P_def)
next
  case 5
  show ?case by (auto intro: mult_monos(1,2) simp: P_def)
next
  case 6
  show ?case by (auto intro: mult_monos(3,4) simp: P_def)
next
  case 7
  show ?case unfolding P_def
    by (subst (1 2 3) mult.commute) (auto intro: mult_monos(1,2))
next
  case 8
  show ?case unfolding P_def
    by (subst (1 2 3) mult.commute) (auto intro: mult_monos(3,4))
next
  case 9
  show ?case
  proof (safe, goal_cases)
    case (1 x)
    from 1(1-4) show ?case unfolding P_def
      by (cases "f x  0"; cases "g x  0";
          fastforce intro: mult_monos 1(5,6)[THEN order.trans] 1(7,8)[THEN order.trans[rotated]])
  qed
qed


qualified lemma powr_bounds_real:
  fixes f g l1 u1 l2 u2 l u :: "real  real"
  defines "P  λl u x. f x  {l1 x..u1 x}  g x  {l2 x..u2 x}  f x powr g x  {l..u}"
  shows   "x. l1 x  0  l1 x  1  l2 x  0  P (l1 x powr l2 x) (u1 x powr u2 x) x"
    and   "x. l1 x  0  u1 x  1  l2 x  0  P (l1 x powr u2 x) (u1 x powr l2 x) x"
    and   "x. l1 x  0  l1 x  1  u2 x  0  P (u1 x powr l2 x) (l1 x powr u2 x) x"
    and   "x. l1 x > 0  u1 x  1  u2 x  0  P (u1 x powr u2 x) (l1 x powr l2 x) x"

    and   "x. l1 x  0  l1 x  1  u1 x  1  l2 x  0  P (l1 x powr u2 x) (u1 x powr u2 x) x"
    and   "x. l1 x > 0  l1 x  1  u1 x  1  u2 x  0  P (u1 x powr l2 x) (l1 x powr l2 x) x"
    and   "x. l1 x  0  l1 x  1  l2 x  0  u2 x  0  P (u1 x powr l2 x) (u1 x powr u2 x) x"
    and   "x. l1 x > 0  u1 x  1  l2 x  0  u2 x  0  P (l1 x powr u2 x) (l1 x powr l2 x) x"

    and   "x. l1 x > 0  l1 x  1  u1 x  1  l2 x  0  u2 x  0  l x  l1 x powr u2 x 
             l x  u1 x powr l2 x  u x  l1 x powr l2 x  u x  u1 x powr u2 x  P (l x) (u x) x"
proof goal_cases
  case 1
  show ?case by (auto simp: P_def powr_def intro: mult_monos)
next
  case 2
  show ?case by (auto simp: P_def powr_def intro: mult_monos)
next
  case 3
  show ?case by (auto simp: P_def powr_def intro: mult_monos)
next
  case 4
  show ?case by (auto simp: P_def powr_def intro: mult_monos)
next
  case 5
  note comm = mult.commute[of _ "ln x" for x :: real]
  show ?case by (auto simp: P_def powr_def comm intro: mult_monos)
next
  case 6
  note comm = mult.commute[of _ "ln x" for x :: real]
  show ?case by (auto simp: P_def powr_def comm intro: mult_monos)
next
  case 7
  show ?case by (auto simp: P_def powr_def intro: mult_monos)
next
  case 8  
  show ?case 
    by (auto simp: P_def powr_def intro: mult_monos)
next
  case 9
  show ?case unfolding P_def
  proof (safe, goal_cases)
    case (1 x)
    define l' where "l' = (λx. min (ln (l1 x) * u2 x) (ln (u1 x) * l2 x))"
    define u' where "u' = (λx. max (ln (l1 x) * l2 x) (ln (u1 x) * u2 x))"
    from 1 spec[OF mult_bounds_real(9)[of "λx. ln (l1 x)" "λx. ln (u1 x)" l2 u2 l' u' 
                                          "λx. ln (f x)" g], of x]
      have "ln (f x) * g x  {l' x..u' x}" by (auto simp: powr_def mult.commute l'_def u'_def)
    with 1 have "f x powr g x  {exp (l' x)..exp (u' x)}"
      by (auto simp: powr_def mult.commute)
    also from 1 have "exp (l' x) = min (l1 x powr u2 x) (u1 x powr l2 x)"
      by (auto simp add: l'_def powr_def min_def mult.commute)
    also from 1 have "exp (u' x) = max (l1 x powr l2 x) (u1 x powr u2 x)"
      by (auto simp add: u'_def powr_def max_def mult.commute)
    finally show ?case using 1(5-9) by auto
  qed
qed

qualified lemma powr_right_bounds:
  fixes f g :: "real  real"
  shows "x. l x  0  f x  {l x..u x}  g x  0  f x powr g x  {l x powr g x..u x powr g x}"
    and "x. l x > 0  f x  {l x..u x}  g x  0  f x powr g x  {u x powr g x..l x powr g x}"
  by (auto intro: powr_mono2 powr_mono2')

(* TODO Move *)
lemma powr_mono': "a  (b::real)  x  0  x  1  x powr b  x powr a"
  using powr_mono[of "-b" "-a" "inverse x"] by (auto simp: powr_def ln_inverse ln_div field_split_simps)

qualified lemma powr_left_bounds:
  fixes f g :: "real  real"
  shows "x. f x > 0  g x  {l x..u x}  f x  1  f x powr g x  {f x powr l x..f x powr u x}"
    and "x. f x > 0  g x  {l x..u x}  f x  1  f x powr g x  {f x powr u x..f x powr l x}"
  by (auto intro: powr_mono powr_mono')

qualified lemma powr_nat_bounds_transfer_ge:
  "x. l1 x  0  f x  l1 x  f x powr g x  l x  powr_nat (f x) (g x)  l x"
  by (auto simp: powr_nat_def)

qualified lemma powr_nat_bounds_transfer_le:
  "x. l1 x > 0  f x  l1 x  f x powr g x  u x  powr_nat (f x) (g x)  u x"
  "x. l1 x  0  l2 x > 0  f x  l1 x  g x  l2 x  
      f x powr g x  u x  powr_nat (f x) (g x)  u x"
  "x. l1 x  0  u2 x < 0  f x  l1 x  g x  u2 x 
      f x powr g x  u x  powr_nat (f x) (g x)  u x"
  "x. l1 x  0  f x  l1 x   f x powr g x  u x  u x  u' x  1  u' x  
     powr_nat (f x) (g x)  u' x"
  by (auto simp: powr_nat_def)

lemma abs_powr_nat_le: "abs (powr_nat x y)  powr_nat (abs x) y"
  by (simp add: powr_nat_def abs_mult)

qualified lemma powr_nat_bounds_ge_neg:
  assumes "powr_nat (abs x) y  u"
  shows   "powr_nat x y  -u" "powr_nat x y  u"
proof -
  have "abs (powr_nat x y)  powr_nat (abs x) y"
    by (rule abs_powr_nat_le)
  also have "  u" using assms by auto
  finally show "powr_nat x y  -u" "powr_nat x y  u" by auto
qed

qualified lemma powr_nat_bounds_transfer_abs [eventuallized]:
  "x. powr_nat (abs (f x)) (g x)  u x  powr_nat (f x) (g x)  -u x"
  "x. powr_nat (abs (f x)) (g x)  u x  powr_nat (f x) (g x)  u x"
  using powr_nat_bounds_ge_neg by blast+

qualified lemma eventually_powr_const_nonneg:
  "f  f  p  p  eventually (λx. f x powr p  (0::real)) at_top"
  by simp

qualified lemma eventually_powr_const_mono_nonneg:
  assumes "p  (0 :: real)" "eventually (λx. l x  0) at_top" "eventually (λx. l x  f x) at_top"
          "eventually (λx. f x  g x) at_top"
  shows   "eventually (λx. f x powr p  g x powr p) at_top"
  using assms(2-4) by eventually_elim (auto simp: assms(1) intro!: powr_mono2)

qualified lemma eventually_powr_const_mono_nonpos:
  assumes "p  (0 :: real)" "eventually (λx. l x > 0) at_top" "eventually (λx. l x  f x) at_top"
          "eventually (λx. f x  g x) at_top"
  shows   "eventually (λx. f x powr p  g x powr p) at_top"
  using assms(2-4) by eventually_elim (auto simp: assms(1) intro!: powr_mono2')


qualified lemma eventually_power_mono:
  assumes "eventually (λx. 0  l x) at_top" "eventually (λx. l x  f x) at_top"
          "eventually (λx. f x  g x) at_top" "n  n"
  shows   "eventually (λx. f x ^ n  (g x :: real) ^ n) at_top"
  using assms(1-3) by eventually_elim (auto intro: power_mono)

qualified lemma eventually_mono_power_odd:
  assumes "odd n" "eventually (λx. f x  (g x :: real)) at_top"
  shows   "eventually (λx. f x ^ n  g x ^ n) at_top"
  using assms(2) by eventually_elim (insert assms(1), auto intro: power_mono_odd)


qualified lemma eventually_lower_bound_power_even_nonpos:
  assumes "even n" "eventually (λx. u x  (0::real)) at_top"
          "eventually (λx. f x  u x) at_top"
  shows   "eventually (λx. u x ^ n  f x ^ n) at_top"
  using assms(2-) by eventually_elim (rule power_mono_even, auto simp: assms(1))

qualified lemma eventually_upper_bound_power_even_nonpos:
  assumes "even n" "eventually (λx. u x  (0::real)) at_top"
          "eventually (λx. l x  f x) at_top" "eventually (λx. f x  u x) at_top"
  shows   "eventually (λx. f x ^ n  l x ^ n) at_top"
  using assms(2-) by eventually_elim (rule power_mono_even, auto simp: assms(1))

qualified lemma eventually_lower_bound_power_even_indet:
  assumes "even n" "f  f"
  shows   "eventually (λx. (0::real)  f x ^ n) at_top"
  using assms by (simp add: zero_le_even_power)


qualified lemma eventually_lower_bound_power_indet:
  assumes "eventually (λx. l x  f x) at_top"
  assumes "eventually (λx. l' x  l x ^ n) at_top" "eventually (λx. l' x  0) at_top"
  shows   "eventually (λx. l' x  (f x ^ n :: real)) at_top"
  using assms
proof eventually_elim
  case (elim x)
  thus ?case
    using power_mono_odd[of n "l x" "f x"] zero_le_even_power[of n "f x"]
    by (cases "even n") auto
qed

qualified lemma eventually_upper_bound_power_indet:
  assumes "eventually (λx. l x  f x) at_top" "eventually (λx. f x  u x) at_top"
          "eventually (λx. u' x  -l x) at_top" "eventually (λx. u' x  u x) at_top" "n  n"
  shows   "eventually (λx. f x ^ n  (u' x ^ n :: real)) at_top"
  using assms(1-4)
proof eventually_elim
  case (elim x)
  have "f x ^ n  ¦f x ^ n¦" by simp
  also have " = ¦f x¦ ^ n" by (simp add: power_abs)
  also from elim have "  u' x ^ n" by (intro power_mono) auto
  finally show ?case .
qed

qualified lemma expands_to_imp_exp_ln_eq:
  assumes "(l expands_to L) bs" "eventually (λx. l x  f x) at_top"
          "trimmed_pos L" "basis_wf bs"
  shows   "eventually (λx. exp (ln (f x)) = f x) at_top"
proof -
  from expands_to_imp_eventually_pos[of bs l L] assms
    have "eventually (λx. l x > 0) at_top" by simp
  with assms(2) show ?thesis by eventually_elim simp
qed

qualified lemma expands_to_imp_ln_powr_eq:
  assumes "(l expands_to L) bs" "eventually (λx. l x  f x) at_top"
          "trimmed_pos L" "basis_wf bs"
  shows   "eventually (λx. ln (f x powr g x) = ln (f x) * g x) at_top"
proof -
  from expands_to_imp_eventually_pos[of bs l L] assms
    have "eventually (λx. l x > 0) at_top" by simp
  with assms(2) show ?thesis by eventually_elim (simp add: powr_def)
qed

qualified lemma inverse_bounds_real:
  fixes f l u :: "real  real"
  shows "x. l x > 0  l x  f x  f x  u x  inverse (f x)  {inverse (u x)..inverse (l x)}"
    and "x. u x < 0  l x  f x  f x  u x  inverse (f x)  {inverse (u x)..inverse (l x)}"
  by (auto simp: field_simps)

qualified lemma pos_imp_inverse_pos: "x::real. f x > 0  inverse (f x) > (0::real)"
  and neg_imp_inverse_neg: "x::real. f x < 0  inverse (f x) < (0::real)"
  by auto

qualified lemma transfer_divide_bounds:
  fixes f g :: "real  real"
  shows "Trueprop (eventually (λx. f x  {h x * inverse (i x)..j x}) at_top) 
         Trueprop (eventually (λx. f x  {h x / i x..j x}) at_top)"
    and "Trueprop (eventually (λx. f x  {j x..h x * inverse (i x)}) at_top) 
         Trueprop (eventually (λx. f x  {j x..h x / i x}) at_top)"
    and "Trueprop (eventually (λx. f x * inverse (g x)  A x) at_top) 
         Trueprop (eventually (λx. f x / g x  A x) at_top)"
    and "Trueprop (((λx. f x * inverse (g x)) expands_to F) bs) 
         Trueprop (((λx. f x / g x) expands_to F) bs)"
  by (simp_all add: field_simps)

qualified lemma eventually_le_self: "eventually (λx::real. f x  (f x :: real)) at_top"
  by simp

qualified lemma max_eventually_eq:
  "eventually (λx. f x = (g x :: real)) at_top  eventually (λx. max (f x) (g x) = f x) at_top"
  by (erule eventually_mono) simp

qualified lemma min_eventually_eq:
  "eventually (λx. f x = (g x :: real)) at_top  eventually (λx. min (f x) (g x) = f x) at_top"
  by (erule eventually_mono) simp

qualified lemma
  assumes "eventually (λx. f x = (g x :: 'a :: preorder)) F"
  shows   eventually_eq_imp_ge: "eventually (λx. f x  g x) F"
    and   eventually_eq_imp_le: "eventually (λx. f x  g x) F"
  by (use assms in eventually_elim; simp)+

qualified lemma eventually_less_imp_le:
  assumes "eventually (λx. f x < (g x :: 'a :: order)) F"
  shows   "eventually (λx. f x  g x) F"
  using assms by eventually_elim auto

qualified lemma
  fixes f :: "real  real"
  shows eventually_abs_ge_0: "eventually (λx. abs (f x)  0) at_top"
    and nonneg_abs_bounds: "x. l x  0  f x  {l x..u x}  abs (f x)  {l x..u x}" 
    and nonpos_abs_bounds: "x. u x  0  f x  {l x..u x}  abs (f x)  {-u x..-l x}" 
    and indet_abs_bounds:
          "x. l x  0  u x  0  f x  {l x..u x}  -l x  h x  u x  h x  
             abs (f x)  {0..h x}"
  by auto

qualified lemma eventually_le_abs_nonneg:
  "eventually (λx. l x  0) at_top  eventually (λx. f x  l x) at_top 
     eventually (λx::real. l x  (¦f x¦ :: real)) at_top"
  by (auto elim: eventually_elim2)

qualified lemma eventually_le_abs_nonpos:
  "eventually (λx. u x  0) at_top  eventually (λx. f x  u x) at_top 
     eventually (λx::real. -u x  (¦f x¦ :: real)) at_top"
  by (auto elim: eventually_elim2)

qualified lemma
  fixes f g h :: "'a  'b :: order"
  shows eventually_le_less:"eventually (λx. f x  g x) F  eventually (λx. g x < h x) F  
           eventually (λx. f x < h x) F"
  and   eventually_less_le:"eventually (λx. f x < g x) F  eventually (λx. g x  h x) F 
           eventually (λx. f x < h x) F"
  by (erule (1) eventually_elim2; erule (1) order.trans le_less_trans less_le_trans)+

qualified lemma eventually_pos_imp_nz [eventuallized]: "x. f x > 0  f x  (0 :: 'a :: linordered_semiring)"
  and eventually_neg_imp_nz [eventuallized]: "x. f x < 0  f x  0"
  by auto

qualified lemma
  fixes f g l1 l2 u1 :: "'a  real"
  assumes "eventually (λx. l1 x  f x) F"
  assumes "eventually (λx. f x  u1 x) F"
  assumes "eventually (λx. abs (g x)  l2 x) F"
  assumes "eventually (λx. l2 x  0) F"
  shows   bounds_smallo_imp_smallo: "l1  o[F](l2)  u1  o[F](l2)  f  o[F](g)"
    and   bounds_bigo_imp_bigo:     "l1  O[F](l2)  u1  O[F](l2)  f  O[F](g)"
proof -
  assume *: "l1  o[F](l2)" "u1  o[F](l2)"
  show "f  o[F](g)"
  proof (rule landau_o.smallI, goal_cases)
    case (1 c)
    from *[THEN landau_o.smallD[OF _ 1]] and assms show ?case
    proof eventually_elim
      case (elim x)
      from elim have "norm (f x)  c * l2 x" by simp
      also have "  c * norm (g x)" using 1 elim by (intro mult_left_mono) auto
      finally show ?case .
    qed
  qed
next
  assume *: "l1  O[F](l2)" "u1  O[F](l2)"
  then obtain C1 C2 where **: "C1 > 0" "C2 > 0" "eventually (λx. norm (l1 x)  C1 * norm (l2 x)) F"
    "eventually (λx. norm (u1 x)  C2 * norm (l2 x)) F" by (auto elim!: landau_o.bigE)
  from this(3,4) and assms have "eventually (λx. norm (f x)  max C1 C2 * norm (g x)) F"
  proof eventually_elim
    case (elim x)
    from elim have "norm (f x)  max C1 C2 * l2 x" by (subst max_mult_distrib_right) auto
    also have "  max C1 C2 * norm (g x)" using elim ** by (intro mult_left_mono) auto
    finally show ?case .
  qed
  thus "f  O[F](g)" by (rule bigoI)
qed

qualified lemma real_root_mono: "mono (root n)"
  by (cases n) (auto simp: mono_def)

(* TODO: support for rintmod *)

ML_file ‹multiseries_expansion_bounds.ML›

method_setup real_asymp = let
  type flags = {verbose : bool, fallback : bool}
  fun join_flags
        {verbose = verbose1, fallback = fallback1}
        {verbose = verbose2, fallback = fallback2} =
    {verbose = verbose1 orelse verbose2, fallback = fallback1 orelse fallback2}
  val parse_flag =
    (Args.$$$ "verbose" >> K {verbose = true, fallback = false}) ||
    (Args.$$$ "fallback" >> K {verbose = false, fallback = true})
  val default_flags = {verbose = false, fallback = false}
  val parse_flags =
    Scan.optional (Args.parens (Parse.list1 parse_flag)) [] >>
      (fn xs => fold join_flags xs default_flags)
in
  Scan.lift parse_flags --| Method.sections Simplifier.simp_modifiers >>
    (fn flags => SIMPLE_METHOD' o
      (if #fallback flags then Real_Asymp_Basic.tac else Real_Asymp_Bounds.tac) (#verbose flags))
end "Semi-automatic decision procedure for asymptotics of exp-log functions"

end

lemma "filterlim (λx::real. sin x / x) (nhds 0) at_top"
  by real_asymp

lemma "(λx::real. exp (sin x))  O(λ_. 1)"
  by real_asymp

lemma "(λx::real. exp (real_of_int (floor x)))  Θ(λx. exp x)"
  by real_asymp

lemma "(λn::nat. n div 2 * ln (n div 2))  Θ(λn::nat. n * ln n)"
  by real_asymp

end