Theory EliminateVariable
subsection "Lemmas of the elimVar function"
theory EliminateVariable
imports LinearCase QuadraticCase "HOL-Library.Quadratic_Discriminant"
begin
lemma elimVar_eq :
assumes hlength : "length xs = var"
assumes in_list : "Eq p ∈ set(L)"
assumes low_pow : "MPoly_Type.degree p var = 1 ∨ MPoly_Type.degree p var = 2"
shows "((∃x. eval (list_conj (map fm.Atom L @ F)) (xs @ x # Γ)) =
((∃x. eval (elimVar var L F (Eq p)) (xs @ x # Γ)))∨ (∀x. aEval (Eq p) (xs @ x # Γ)))"
proof-
{ fix x
define A where "A = (isolate_variable_sparse p var 2)"
define B where "B = (isolate_variable_sparse p var 1)"
define C where "C = (isolate_variable_sparse p var 0)"
have freeA : "var ∉ vars A"
unfolding A_def
by (simp add: not_in_isovarspar)
have freeB : "var ∉ vars B"
unfolding B_def
by (simp add: not_in_isovarspar)
have freeC : "var ∉ vars C"
unfolding C_def
by (simp add: not_in_isovarspar)
assume "eval (list_conj (map fm.Atom L @ F)) (xs @ x # Γ)"
then have h : "(∀a∈set L. aEval a (xs @ x # Γ)) ∧ (∀f∈set F. eval f (xs @ x # Γ))"
apply(simp add:eval_list_conj)
by (meson Un_iff eval.simps(1) image_eqI)
define X where "X=xs@x#Γ"
have Xlength : "length X > var"
using X_def hlength by auto
define Aval where "Aval = insertion (nth_default 0 (list_update X var x)) A"
define Bval where "Bval = insertion (nth_default 0 (list_update X var x)) B"
define Cval where "Cval = insertion (nth_default 0 (list_update X var x)) C"
have hinsert : "(xs @ x # Γ)[var := x] = (xs @ x #Γ)"
using hlength by auto
have allAval : "∀x. insertion (nth_default 0 (xs @ x # Γ)) A = Aval"
using Aval_def
using not_contains_insertion[where var="var", where p = "A", OF freeA, where L = "xs @ x #Γ", where x="x", where val="Aval"]
unfolding X_def hinsert using hlength by auto
have allBval : "∀x. insertion (nth_default 0 (xs @ x # Γ)) B = Bval"
using Bval_def
using not_contains_insertion[where var="var", where p = "B", OF freeB, where L = "xs @ x #Γ", where x="x", where val="Bval"]
unfolding X_def hinsert using hlength by auto
have allCval : "∀x. insertion (nth_default 0 (xs @ x # Γ)) C = Cval"
using Cval_def
using not_contains_insertion[where var="var", where p = "C", OF freeC, where L = "xs @ x #Γ", where x="x", where val="Cval"]
unfolding X_def hinsert using hlength by auto
have insertion_p : "insertion (nth_default 0 X) p = 0"
using in_list h aEval.simps(1) X_def by fastforce
have express_p : "p = A * Var var ^ 2 + B * Var var + C"
using express_poly[OF low_pow] unfolding A_def B_def C_def
by fastforce
have insertion_p' : "Aval *x^2+Bval *x+Cval = 0"
using express_p insertion_p unfolding Aval_def Bval_def Cval_def X_def hinsert
apply(simp add: insertion_add insertion_mult insertion_pow)
using insertion_var by (metis X_def Xlength hinsert)
have biglemma : "
((Aval = 0 ∧
Bval ≠ 0 ∧
(∀f∈set L. aEval (linear_substitution var (-C) B f) (xs @ x # Γ)) ∧
(∀f∈set F. eval (linear_substitution_fm var (-C) B f) (xs @ x # Γ)) ∨
Aval ≠ 0 ∧
insertion (nth_default 0 (xs @ x # Γ)) 4 *
Aval *
Cval
≤ (Bval)⇧2 ∧
((∀f∈set L. eval (quadratic_sub var (- B) 1 (B⇧2 - 4 * A * C) (2 * A) f) (xs @ x # Γ))∧
(∀f∈set F. eval (quadratic_sub_fm var (- B) 1 (B⇧2 - 4 * A * C) (2 * A) f) (xs @ x # Γ)) ∨
(∀f∈set L. eval (quadratic_sub var (- B) (-1) (B⇧2 - 4 * A * C) (2 * A) f) (xs @ x # Γ)) ∧
(∀f∈set F. eval (quadratic_sub_fm var (- B) (-1) (B⇧2 - 4 * A * C) (2 * A) f) (xs @ x # Γ))) ∨
Aval = 0 ∧
Bval = 0 ∧
Cval = 0))"
proof(cases "Aval=0")
case True
then have aval0 : "Aval=0" by simp
show ?thesis proof(cases "Bval=0")
case True
then have bval0 : "Bval=0" by simp
have h : "eval (list_conj (map fm.Atom L @ F)) (xs @ x # Γ)"
using hlength h unfolding X_def
using ‹eval (list_conj (map fm.Atom L @ F)) (xs @ x # Γ)› by blast
show ?thesis proof(cases "Cval=0")
case True
show ?thesis
by(simp add:aval0 True bval0)
next
case False
show ?thesis
using insertion_p' aval0 bval0 False by(simp)
qed
next
case False
have bh : "insertion (nth_default 0 (X[var := - Cval / Bval])) B = Bval"
using allBval unfolding X_def
using Bval_def X_def freeB not_contains_insertion by blast
have ch : "insertion (nth_default 0 (X[var := - Cval / Bval])) C = Cval"
using allCval unfolding X_def
using Cval_def X_def freeC not_contains_insertion by blast
have xh : "x=-Cval/Bval"
proof-
have "Bval*x+Cval = 0"
using insertion_p' aval0
by simp
then show ?thesis using False
by (smt nonzero_mult_div_cancel_left)
qed
have freecneg : "var ∉ vars (-C)" using freeC not_in_neg by auto
have h1: "(∀a∈set L. aEval (linear_substitution var (-C) (B) a) (X[var := x]))"
using h xh Bval_def Cval_def False LinearCase.linear[OF Xlength False freecneg freeB, of "-Cval"] freeB freeC freecneg
by (metis X_def hinsert insertion_neg)
have h2 : "∀f∈set F. eval (linear_substitution_fm var (-C) B f) (X[var := x])"
using h xh Bval_def Cval_def False LinearCase.linear_fm[OF Xlength False freecneg freeB, of "-Cval"] freeB freeC
by (metis X_def hinsert insertion_neg)
show ?thesis using h1 h2 apply(simp add:aval0 False)
using X_def hlength
using hinsert by auto
qed
next
case False
then have aval0 : "Aval ≠0" by simp
have h4 : "insertion (nth_default 0 (X[var := x])) 4 = 4"
using insertion_const[where f = "(nth_default 0 (X[var := x]))", where c="4"]
by (metis MPoly_Type.insertion_one insertion_add numeral_Bit0 one_add_one)
show ?thesis proof(cases "4 * Aval * Cval ≤ Bval⇧2")
case True
have h1a : "var∉vars(-B)"
by(simp add: freeB not_in_neg)
have h1b : "var∉vars(1::real mpoly)"
using isolate_var_one not_in_isovarspar by blast
have h1c : "var∉vars(-1::real mpoly)"
by(simp add: h1b not_in_neg)
have h1d : "var∉vars(4::real mpoly)"
by (metis h1b not_in_add numeral_Bit0 one_add_one)
have h1e : "var∉vars(B^2-4*A*C)"
by(simp add: freeB h1d freeA freeC not_in_mult not_in_pow not_in_sub)
have h1f : "var∉vars(2::real mpoly)"
using h1b not_in_add by fastforce
have h1g : "var∉vars(2*A)"
by(simp add: freeA h1f not_in_mult)
have h1h : "freeIn var (quadratic_sub var (-B) (1) (B^2-4*A*C) (2*A) a)"
using free_in_quad h1a h1b h1e h1g by blast
have h1i : "freeIn var (quadratic_sub var (-B) (-1) (B^2-4*A*C) (2*A) a)"
using free_in_quad h1a h1c h1e h1g by blast
have h2 : "2*Aval ≠ 0" using aval0 by auto
have h3 : "0 ≤ (Bval^2-4*Aval*Cval)" using True by auto
have h4a : "var ∉ vars 4"
by (metis monom_numeral notInKeys_notInVars not_in_add not_in_isovarspar not_in_pow one_add_one power.simps(1) rel_simps(76) vars_monom_keys)
have h4 : "var ∉ vars (B^2-4*A*C)" by(simp add: h4a freeA freeB freeC not_in_pow not_in_mult not_in_sub)
have h5 : "∀x. insertion (nth_default 0 (list_update X var x)) (-B) = -Bval "
using allBval apply(simp add: insertion_neg)
by (simp add: B_def Bval_def insertion_isovarspars_free)
have h6 : "∀x. insertion (nth_default 0 (list_update X var x)) 1 = 1" by simp
have h6a : "∀x. insertion (nth_default 0 (list_update X var x)) (-1) = (-1)" using h6 by (simp add: insertion_neg)
have h7a : "∀x. insertion (nth_default 0 (list_update X var x)) 4 = 4" by (metis h6 insertion_add numeral_Bit0 one_add_one)
have h7b : "var ∉ vars(4*A*C)" using freeA freeC by (simp add: h4a not_in_mult)
have h7c : "var ∉ vars(B^2)" using freeB not_in_pow by auto
have h7 : "∀x. insertion (nth_default 0 (list_update X var x)) (B^2-4*A*C) = (Bval^2-4*Aval*Cval)"
using h7a allAval allBval allCval unfolding X_def using hlength
apply (simp add: insertion_mult insertion_sub power2_eq_square)
by (metis A_def Aval_def Bval_def C_def Cval_def X_def freeB insertion_isovarspars_free not_contains_insertion)
have h8a : "∀x. insertion (nth_default 0 (list_update X var x)) 2 = 2" by (metis h6 insertion_add one_add_one)
have h8 : "∀x. insertion (nth_default 0 (list_update X var x)) (2*A) = (2*Aval)"
apply(simp add: allAval h8a insertion_mult)
by (simp add: A_def Aval_def insertion_isovarspars_free)
have h1 : "- Bval⇧2 + 4 * Aval * Cval ≤ 0"
using True by simp
have xh : "x = (- Bval + sqrt (Bval⇧2 - 4 * Aval * Cval)) / (2 * Aval)∨x=(- Bval - sqrt (Bval⇧2 - 4 * Aval * Cval)) / (2 * Aval)"
using insertion_p' aval0 h1
discriminant_iff unfolding discrim_def by blast
have p1 : "x = (- Bval + sqrt (Bval⇧2 - 4 * Aval * Cval)) / (2 * Aval) ⟹
((∀a∈ set L. eval (quadratic_sub var (-B) 1 (B^2-4*A*C) (2*A) a) (X[var := x]))
∧(∀a∈ set F. eval (quadratic_sub_fm var (-B) 1 (B^2-4*A*C) (2*A) a) (X[var := x])))"
proof-
assume x_def : "x = (- Bval + sqrt (Bval⇧2 - 4 * Aval * Cval)) / (2 * Aval)"
then have h : "(∀a∈set L. aEval a (X[var := (- Bval + sqrt (Bval⇧2 - 4 * Aval * Cval)) / (2 * Aval)])) ∧ (∀f∈set F. eval f (X[var := (- Bval + sqrt (Bval⇧2 - 4 * Aval * Cval)) / (2 * Aval)]))"
using h
using X_def hinsert by auto
{ fix a
assume in_list : "a∈ set L"
have "eval (quadratic_sub var (- B) 1 (B⇧2 - 4 * A * C) (2 * A) a) (X[var := x])"
using free_in_quad[where a="-B",where b="1", where c="(B^2-4*A*C)", where d="2*A",where var="var",OF h1a h1b h1e h1g]
using quadratic_sub[where a="-B",where b="1", where c="(B^2-4*A*C)", where d="2*A",where var="var", where L="X", OF Xlength,
where Dv="2*Aval", OF h2, where Cv="(Bval^2-4*Aval*Cval)", OF h3, where Av="-Bval", OF h4 h5, where Bv="1", OF h6 h7 h8]
h in_list
using var_not_in_eval by fastforce
}
then have left : "(∀a∈set L. eval (quadratic_sub var (- B) 1 (B⇧2 - 4 * A * C) (2 * A) a) (X[var := x]))"
by simp
{ fix a
assume in_list : "a∈ set F"
have "eval (quadratic_sub_fm var (- B) 1 (B⇧2 - 4 * A * C) (2 * A) a) (X[var := x])"
using free_in_quad_fm[where a="-B",where b="1", where c="(B^2-4*A*C)", where d="2*A",where var="var",OF h1a h1b h1e h1g]
using quadratic_sub_fm[where a="-B",where b="1", where c="(B^2-4*A*C)", where d="2*A",where var="var", where L="X", OF Xlength,
where Dv="2*Aval", OF h2, where Cv="(Bval^2-4*Aval*Cval)", OF h3, where Av="-Bval", OF h4 h5, where Bv="1", OF h6 h7 h8]
h in_list
using var_not_in_eval by fastforce
}
then have right : "(∀a∈set F. eval (quadratic_sub_fm var (- B) 1 (B⇧2 - 4 * A * C) (2 * A) a) (X[var := x]))"
by simp
show ?thesis
using right left by simp
qed
have p2 : "x = (- Bval - sqrt (Bval⇧2 - 4 * Aval * Cval)) / (2 * Aval) ⟹
((∀a∈ set L. eval (quadratic_sub var (-B) (-1) (B^2-4*A*C) (2*A) a) (X[var := x]))
∧(∀a∈ set F. eval (quadratic_sub_fm var (-B) (-1) (B^2-4*A*C) (2*A) a) (X[var := x])))"
proof -
assume x_def : "x = (- Bval - sqrt (Bval⇧2 - 4 * Aval * Cval)) / (2 * Aval)"
then have h : "(∀a∈set L. aEval a (X[var := (- Bval - sqrt (Bval⇧2 - 4 * Aval * Cval)) / (2 * Aval)])) ∧ (∀f∈set F. eval f (X[var := (- Bval - sqrt (Bval⇧2 - 4 * Aval * Cval)) / (2 * Aval)]))"
using h
using X_def hinsert by auto
then have "(∀a∈set L. aEval a (X[var := (- Bval - sqrt (Bval⇧2 - 4 * Aval * Cval)) / (2 * Aval)])) ∧ (∀f∈set F. eval f (X[var := (- Bval - sqrt (Bval⇧2 - 4 * Aval * Cval)) / (2 * Aval)]))"
using h by simp
{ fix a
assume in_list : "a∈ set L"
have "eval (quadratic_sub var (- B) (-1) (B⇧2 - 4 * A * C) (2 * A) a) (X[var := x])"
using free_in_quad[where a="-B",where b="-1", where c="(B^2-4*A*C)", where d="2*A",where var="var",OF h1a h1c h1e h1g]
using quadratic_sub[where a="-B",where b="-1", where c="(B^2-4*A*C)", where d="2*A",where var="var", where L="X", OF Xlength,
where Dv="2*Aval", OF h2, where Cv="(Bval^2-4*Aval*Cval)", OF h3, where Av="-Bval", OF h4 h5, where Bv="-1", OF h6a h7 h8]
h in_list
using var_not_in_eval by fastforce
}
then have left : "(∀a∈set L. eval (quadratic_sub var (- B) (-1) (B⇧2 - 4 * A * C) (2 * A) a) (X[var := x]))"
by simp
{ fix a
assume in_list : "a∈ set F"
have "eval (quadratic_sub_fm var (- B) (-1) (B⇧2 - 4 * A * C) (2 * A) a) (X[var := x])"
using free_in_quad_fm[where a="-B",where b="-1", where c="(B^2-4*A*C)", where d="2*A",where var="var",OF h1a h1c h1e h1g]
using quadratic_sub_fm[where a="-B",where b="-1", where c="(B^2-4*A*C)", where d="2*A",where var="var", where L="X", OF Xlength,
where Dv="2*Aval", OF h2, where Cv="(Bval^2-4*Aval*Cval)", OF h3, where Av="-Bval", OF h4 h5, where Bv="-1", OF h6a h7 h8]
h in_list
using var_not_in_eval by fastforce
}
then have right : "(∀a∈set F. eval (quadratic_sub_fm var (- B) (-1) (B⇧2 - 4 * A * C) (2 * A) a) (X[var := x]))"
by simp
show ?thesis
using right left by simp
qed
have subst4 : "insertion (nth_default 0 (xs @ x # Γ)) 4 = 4" using h7a hlength X_def by auto
have disj: "(∀a∈set L. eval (quadratic_sub var (- B) 1 (B⇧2 - 4 * A * C) (2 * A) a) (xs @ x # Γ)) ∧
(∀a∈set F. eval (quadratic_sub_fm var (- B) 1 (B⇧2 - 4 * A * C) (2 * A) a) (xs @ x # Γ)) ∨
(∀a∈set L. eval (quadratic_sub var (- B) (-1) (B⇧2 - 4 * A * C) (2 * A) a) (xs @ x # Γ)) ∧
(∀a∈set F. eval (quadratic_sub_fm var (- B) (-1) (B⇧2 - 4 * A * C) (2 * A) a) (xs @ x # Γ))"
using xh p1 p2
unfolding X_def hinsert by blast
show ?thesis apply(simp add: aval0 True h7a subst4) using disj
unfolding X_def hinsert by auto
next
case False
then have det : "0 < - Bval⇧2 + 4 * Aval * Cval"
by simp
show ?thesis apply(simp add: aval0 False h4) using discriminant_negative unfolding discrim_def
using insertion_p'
using aval0 det by auto
qed
qed
have "(∃x.
(insertion (nth_default 0 (xs @ x # Γ)) A = 0 ∧
insertion (nth_default 0 (xs @ x # Γ)) B ≠ 0 ∧
(∀f∈set L. aEval (linear_substitution var (-C) (B) f) (xs @ x # Γ)) ∧
(∀f∈set F. eval (linear_substitution_fm var (-C) B f) (xs @ x # Γ)) ∨
insertion (nth_default 0 (xs @ x # Γ)) A ≠ 0 ∧
insertion (nth_default 0 (xs @ x # Γ)) 4 *
insertion (nth_default 0 (xs @ x # Γ)) A *
insertion (nth_default 0 (xs @ x # Γ)) C
≤ (insertion (nth_default 0 (xs @ x # Γ)) B)⇧2 ∧
((∀f∈set L. eval (quadratic_sub var (- B) 1 (B⇧2 - 4 * A * C) (2 * A) f) (xs @ x # Γ))∧
(∀f∈set F. eval (quadratic_sub_fm var (- B) 1 (B⇧2 - 4 * A * C) (2 * A) f) (xs @ x # Γ)) ∨
(∀f∈set L. eval (quadratic_sub var (- B) (-1) (B⇧2 - 4 * A * C) (2 * A) f) (xs @ x # Γ)) ∧
(∀f∈set F. eval (quadratic_sub_fm var (- B) (-1) (B⇧2 - 4 * A * C) (2 * A) f) (xs @ x # Γ)))) ∨
(Aval = 0 ∧
Bval = 0 ∧
Cval = 0))"
apply(rule exI[where x=x])
using biglemma
using allAval allBval allCval unfolding A_def B_def C_def Aval_def Bval_def Cval_def X_def hinsert
by auto
then obtain x where x : "(insertion (nth_default 0 (xs @ x # Γ)) A = 0 ∧
insertion (nth_default 0 (xs @ x # Γ)) B ≠ 0 ∧
(∀f∈set L. aEval (linear_substitution var (-C) (B) f) (xs @ x # Γ)) ∧
(∀f∈set F. eval (linear_substitution_fm var (-C) B f) (xs @ x # Γ)) ∨
insertion (nth_default 0 (xs @ x # Γ)) A ≠ 0 ∧
insertion (nth_default 0 (xs @ x # Γ)) 4 *
insertion (nth_default 0 (xs @ x # Γ)) A *
insertion (nth_default 0 (xs @ x # Γ)) C
≤ (insertion (nth_default 0 (xs @ x # Γ)) B)⇧2 ∧
((∀f∈set L. eval (quadratic_sub var (- B) 1 (B⇧2 - 4 * A * C) (2 * A) f) (xs @ x # Γ))∧
(∀f∈set F. eval (quadratic_sub_fm var (- B) 1 (B⇧2 - 4 * A * C) (2 * A) f) (xs @ x # Γ)) ∨
(∀f∈set L. eval (quadratic_sub var (- B) (-1) (B⇧2 - 4 * A * C) (2 * A) f) (xs @ x # Γ)) ∧
(∀f∈set F. eval (quadratic_sub_fm var (- B) (-1) (B⇧2 - 4 * A * C) (2 * A) f) (xs @ x # Γ)))) ∨
(Aval = 0 ∧
Bval = 0 ∧
Cval = 0)" by auto
have h : "(∃x. eval (elimVar var L F (Eq p)) (xs @ x # Γ))∨(Aval = 0 ∧ Bval = 0 ∧ Cval = 0)"
proof(cases "(Aval = 0 ∧ Bval = 0 ∧ Cval = 0)")
case True
then show ?thesis by simp
next
case False
have "(∃x. eval (elimVar var L F (Eq p)) (xs @ x # Γ))"
apply(rule exI[where x=x])
apply(simp add: eval_list_conj insertion_mult insertion_sub insertion_pow insertion_add
del: quadratic_sub.simps linear_substitution.simps quadratic_sub_fm.simps linear_substitution_fm.simps)
unfolding A_def[symmetric] B_def[symmetric] C_def[symmetric] One_nat_def[symmetric] X_def[symmetric]
using hlength x
by (auto simp add:False)
then show ?thesis by auto
qed
have "(∃x. eval (elimVar var L F (Eq p)) (xs @ x # Γ))∨(∀x. aEval (Eq p) (xs@ x# Γ))"
proof(cases "(∃x. eval (elimVar var L F (Eq p)) (xs @ x # Γ))")
case True
then show ?thesis by auto
next
case False
then have "(Aval = 0 ∧ Bval = 0 ∧ Cval = 0)"
using h by auto
then have "(∀x. aEval (Eq p) (xs @ x # Γ))"
unfolding express_p
apply(simp add:insertion_add insertion_mult insertion_pow)
using allAval allBval allCval by auto
then show ?thesis by auto
qed
}
then have left : "(∃x. eval (list_conj (map fm.Atom L @ F)) (xs @ x # Γ)) ⟹
((∃x. eval (elimVar var L F (Eq p)) (xs @ x # Γ))∨(∀x. aEval (Eq p) (xs@ x# Γ)))"
by blast
{
assume hlength : "length (xs::real list) = var"
define A where "A = (isolate_variable_sparse p var 2)"
define B where "B = (isolate_variable_sparse p var 1)"
define C where "C = (isolate_variable_sparse p var 0)"
have freeA : "var ∉ vars A"
unfolding A_def
by (simp add: not_in_isovarspar)
have freeB : "var ∉ vars B"
unfolding B_def
by (simp add: not_in_isovarspar)
have freeC : "var ∉ vars C"
unfolding C_def
by (simp add: not_in_isovarspar)
have express_p : "p = A*(Var var)^2+B*(Var var)+C"
using express_poly[OF low_pow] unfolding A_def B_def C_def
by fastforce
assume h : "(∃x. (eval (elimVar var L F (Eq p)) (list_update (xs@x#Γ) var x)))"
fix x
define X where "X=xs@x#Γ"
have Xlength : "length X > var"
using X_def hlength by auto
define Aval where "Aval = insertion (nth_default 0 (list_update X var x)) A"
define Bval where "Bval = insertion (nth_default 0 (list_update X var x)) B"
define Cval where "Cval = insertion (nth_default 0 (list_update X var x)) C"
have allAval : "∀x. insertion (nth_default 0 (list_update X var x)) A = Aval"
using freeA Aval_def
using not_contains_insertion by blast
have allBval : "∀x. insertion (nth_default 0 (list_update X var x)) B = Bval"
using freeB Bval_def
using not_contains_insertion by blast
have allCval : "∀x. insertion (nth_default 0 (list_update X var x)) C = Cval"
using freeC Cval_def
using not_contains_insertion by blast
assume "(eval (elimVar var L F (Eq p)) (list_update (xs@x#Γ) var x))"
then have h : "(eval (elimVar var L F (Eq p)) (list_update X var x))"
unfolding X_def .
have "(Aval = 0 ∧ Bval ≠ 0 ∧
(∀f∈(λa. Atom(linear_substitution var (-C) B a)) ` set L ∪
linear_substitution_fm var (-C) B `
set F.
eval f (X[var := x])) ∨
Aval ≠ 0 ∧
insertion (nth_default 0 (X[var := x])) 4 * Aval * Cval ≤ Bval⇧2 ∧
((∀f∈(quadratic_sub var (-B) 1 (B^2-4*A*C) (2*A)) `
set L ∪
(quadratic_sub_fm var (-B) 1 (B^2-4*A*C) (2*A)) `
set F.
eval f (X[var := x]))
∨(∀f∈(quadratic_sub var (-B) (-1) (B^2-4*A*C) (2*A)) `
set L ∪
(quadratic_sub_fm var (-B) (-1) (B^2-4*A*C) (2*A)) `
set F.
eval f (X[var := x]))
))"
unfolding Aval_def Bval_def Cval_def A_def B_def C_def
using h by(simp add: eval_list_conj insertion_mult insertion_sub insertion_pow insertion_add insertion_var Xlength)
then have h : "(Aval = 0 ∧ Bval ≠ 0 ∧
((∀a∈ set L. aEval (linear_substitution var (-C) B a) (X[var := x])) ∧
(∀a∈ set F. eval (linear_substitution_fm var (-C) B a) (X[var := x]))) ∨
Aval ≠ 0 ∧ insertion (nth_default 0 (X[var := x])) 4 * Aval * Cval ≤ Bval⇧2 ∧
(((∀a∈ set L. eval (quadratic_sub var (-B) 1 (B^2-4*A*C) (2*A) a) (X[var := x]))
∧(∀a∈ set F. eval (quadratic_sub_fm var (-B) 1 (B^2-4*A*C) (2*A) a) (X[var := x])))
∨((∀a∈ set L. eval (quadratic_sub var (-B) (-1) (B^2-4*A*C) (2*A) a) (X[var := x]))
∧(∀a∈ set F. eval (quadratic_sub_fm var (-B) (-1) (B^2-4*A*C) (2*A) a) (X[var := x])))))
"
apply(cases "Aval = 0 ")
apply auto
by (meson Un_iff eval.simps(1) imageI)
have h : "(∃x. ((∀a∈set L . aEval a ((xs@x#Γ)[var := x])) ∧ (∀f∈set F. eval f ((xs@x#Γ)[var := x]))))∨(Aval=0∧Bval=0∧Cval=0)"
proof(cases "Aval=0")
case True
then have aval0 : "Aval=0"
by simp
show ?thesis proof(cases "Bval = 0")
case True
then have bval0 : "Bval = 0" by simp
show ?thesis proof(cases "Cval=0")
case True
then show ?thesis using aval0 bval0 True by auto
next
case False
then show ?thesis using h by(simp add:aval0 bval0 False)
qed
next
case False
have hb : "insertion (nth_default 0 (X[var := - Cval / Bval])) B = Bval"
using allBval by simp
have hc : "insertion (nth_default 0 (X[var := - Cval / Bval])) (-C) = -Cval"
using allCval
by (simp add: insertion_neg)
have freecneg : "var∉vars(-C)" using freeC not_in_neg by auto
have p1 : "(∀a∈set L. aEval a ((xs @ x # Γ)[var := - Cval / Bval]))"
using h apply(simp add: False aval0)
using linear[OF Xlength False freecneg freeB hc hb]
list_update_length var_not_in_linear[OF freecneg freeB]
unfolding X_def using hlength
by (metis divide_minus_left)
have p2 : "(∀a∈set F. eval a ((xs @ x # Γ)[var := - Cval / Bval]))"
using h apply(simp add: False aval0)
using linear_fm[OF Xlength False freecneg freeB hc hb]
list_update_length var_not_in_linear_fm[OF freecneg freeB]
unfolding X_def using hlength var_not_in_eval
by (metis divide_minus_left linear_substitution_fm.elims linear_substitution_fm_helper.elims)
show ?thesis
using p1 p2 hlength by fastforce
qed
next
case False
then have aval0 : "Aval ≠ 0"
by simp
have h4 : "insertion (nth_default 0 (X[var := x])) 4 = 4"
using insertion_const[where f = "(nth_default 0 (X[var := x]))", where c="4"]
by (metis MPoly_Type.insertion_one insertion_add numeral_Bit0 one_add_one)
show ?thesis proof(cases "4 * Aval * Cval ≤ Bval⇧2")
case True
then have h1 : "- Bval⇧2 + 4 * Aval * Cval ≤ 0"
by simp
have h : "(((∀a∈ set L. eval (quadratic_sub var (-B) 1 (B^2-4*A*C) (2*A) a) (X[var := x]))
∧(∀a∈ set F. eval (quadratic_sub_fm var (-B) 1 (B^2-4*A*C) (2*A) a) (X[var := x])))
∨((∀a∈ set L. eval (quadratic_sub var (-B) (-1) (B^2-4*A*C) (2*A) a) (X[var := x]))
∧(∀a∈ set F. eval (quadratic_sub_fm var (-B) (-1) (B^2-4*A*C) (2*A) a) (X[var := x]))))"
using h by(simp add: h1 aval0)
have h1a : "var∉vars(-B)"
by(simp add: freeB not_in_neg)
have h1b : "var∉vars(1::real mpoly)"
using isolate_var_one not_in_isovarspar by blast
have h1c : "var∉vars(-1::real mpoly)"
by(simp add: h1b not_in_neg)
have h1d : "var∉vars(4::real mpoly)"
by (metis h1b not_in_add numeral_Bit0 one_add_one)
have h1e : "var∉vars(B^2-4*A*C)"
by(simp add: freeB h1d freeA freeC not_in_mult not_in_pow not_in_sub)
have h1f : "var∉vars(2::real mpoly)"
using h1b not_in_add by fastforce
have h1g : "var∉vars(2*A)"
by(simp add: freeA h1f not_in_mult)
have h1h : "freeIn var (quadratic_sub var (-B) (1) (B^2-4*A*C) (2*A) a)"
using free_in_quad h1a h1b h1e h1g by blast
have h1i : "freeIn var (quadratic_sub var (-B) (-1) (B^2-4*A*C) (2*A) a)"
using free_in_quad h1a h1c h1e h1g by blast
have h2 : "2*Aval ≠ 0" using aval0 by auto
have h3 : "0 ≤ (Bval^2-4*Aval*Cval)" using True by auto
have h4a : "var ∉ vars 4"
by (metis monom_numeral notInKeys_notInVars not_in_add not_in_isovarspar not_in_pow one_add_one power.simps(1) rel_simps(76) vars_monom_keys)
have h4 : "var ∉ vars (B^2-4*A*C)" by(simp add: h4a freeA freeB freeC not_in_pow not_in_mult not_in_sub)
have h5 : "∀x. insertion (nth_default 0 (list_update X var x)) (-B) = -Bval " using allBval by(simp add: insertion_neg)
have h6 : "∀x. insertion (nth_default 0 (list_update X var x)) 1 = 1" by simp
have h6a : "∀x. insertion (nth_default 0 (list_update X var x)) (-1) = (-1)" using h6 by (simp add: insertion_neg)
have h7a : "∀x. insertion (nth_default 0 (list_update X var x)) 4 = 4" by (metis h6 insertion_add numeral_Bit0 one_add_one)
have h7b : "var ∉ vars(4*A*C)" using freeA freeC by (simp add: h4a not_in_mult)
have h7c : "var ∉ vars(B^2)" using freeB not_in_pow by auto
have h7 : "∀x. insertion (nth_default 0 (list_update X var x)) (B^2-4*A*C) = (Bval^2-4*Aval*Cval)"
by (simp add: h7a allAval allBval allCval insertion_mult insertion_sub power2_eq_square)
have h8a : "∀x. insertion (nth_default 0 (list_update X var x)) 2 = 2" by (metis h6 insertion_add one_add_one)
have h8 : "∀x. insertion (nth_default 0 (list_update X var x)) (2*A) = (2*Aval)" by(simp add: allAval h8a insertion_mult)
have p1 : "(∀a∈ set L. eval (quadratic_sub var (-B) 1 (B^2-4*A*C) (2*A) a) (X[var := x]))
⟹(∀a∈ set F. eval (quadratic_sub_fm var (-B) 1 (B^2-4*A*C) (2*A) a) (X[var := x]))
⟹ ∃x. length xs = var ∧ ((∀a∈set L . aEval a ((xs@x#Γ)[var := x])) ∧ (∀f∈set F. eval f ((xs@x#Γ)[var := x])))"
proof-
assume p1 : "(∀a∈ set L. eval (quadratic_sub var (-B) 1 (B^2-4*A*C) (2*A) a) (X[var := x]))"
assume p2 : "(∀a∈ set F. eval (quadratic_sub_fm var (-B) 1 (B^2-4*A*C) (2*A) a) (X[var := x]))"
show ?thesis
using free_in_quad[where a="-B",where b="1", where c="(B^2-4*A*C)", where d="2*A",where var="var",OF h1a h1b h1e h1g]
using quadratic_sub[where a="-B",where b="1", where c="(B^2-4*A*C)", where d="2*A",where var="var", where L="X", OF Xlength,
where Dv="2*Aval", OF h2, where Cv="(Bval^2-4*Aval*Cval)", OF h3, where Av="-Bval", OF h4 h5, where Bv="1", OF h6 h7 h8]
using free_in_quad_fm[where a="-B",where b="1", where c="(B^2-4*A*C)", where d="2*A",where var="var",OF h1a h1b h1e h1g]
using quadratic_sub_fm[where a="-B",where b="1", where c="(B^2-4*A*C)", where d="2*A",where var="var", where L="X", OF Xlength,
where Dv="2*Aval", OF h2, where Cv="(Bval^2-4*Aval*Cval)", OF h3, where Av="-Bval", OF h4 h5, where Bv="1", OF h6 h7 h8]
p1 p2
using var_not_in_eval
by (metis X_def hlength list_update_length)
qed
have p2 : "(∀a∈ set L. eval (quadratic_sub var (-B) (-1) (B^2-4*A*C) (2*A) a) (X[var := x]))
⟹(∀a∈ set F. eval (quadratic_sub_fm var (-B) (-1) (B^2-4*A*C) (2*A) a) (X[var := x]))
⟹∃x. length xs = var ∧ ((∀a∈set L . aEval a ((xs@x#Γ)[var := x])) ∧ (∀f∈set F. eval f ((xs@x#Γ)[var := x])))"
using free_in_quad[where a="-B",where b="-1", where c="(B^2-4*A*C)", where d="2*A",where var="var",OF h1a h1c h1e h1g]
using quadratic_sub[where a="-B",where b="-1", where c="(B^2-4*A*C)", where d="2*A",where var="var", where L="X", OF Xlength,
where Dv="2*Aval", OF h2, where Cv="(Bval^2-4*Aval*Cval)", OF h3, where Av="-Bval", OF h4 h5, where Bv="-1", OF h6a h7 h8]
using free_in_quad_fm[where a="-B",where b="-1", where c="(B^2-4*A*C)", where d="2*A",where var="var",OF h1a h1c h1e h1g]
using quadratic_sub_fm[where a="-B",where b="-1", where c="(B^2-4*A*C)", where d="2*A",where var="var", where L="X", OF Xlength,
where Dv="2*Aval", OF h2, where Cv="(Bval^2-4*Aval*Cval)", OF h3, where Av="-Bval", OF h4 h5, where Bv="-1", OF h6a h7 h8]
using var_not_in_eval by (metis X_def hlength list_update_length)
then show ?thesis
using h p1 p2 by blast
next
case False
then show ?thesis using h by(simp add: aval0 False h4)
qed
qed
have "(∃x.((∀a∈set L . aEval a ((xs@x#Γ)[var := x])) ∧ (∀f∈set F. eval f ((xs@x#Γ)[var := x]))))∨(∀x. aEval (Eq p) (xs @ x#Γ))"
proof(cases "(∃x.((∀a∈set L . aEval a ((xs@x#Γ)[var := x])) ∧ (∀f∈set F. eval f ((xs@x#Γ)[var := x]))))")
case True
then show ?thesis by auto
next
case False
then have "Aval=0∧Bval=0∧Cval=0" using h by auto
then have "(∀x. aEval (Eq p) (xs @ x # Γ))"
unfolding express_p apply(simp add:insertion_add insertion_mult insertion_pow)
using allAval allBval allCval hlength unfolding X_def by auto
then show ?thesis by auto
qed
}
then have right : "(∃x. eval (elimVar var L F (Eq p)) (xs @ x # Γ)) ⟹
((∃x. eval (list_conj (map fm.Atom L @ F)) (xs @ x # Γ))∨(∀x. aEval (Eq p) (xs @ x # Γ)))"
by (smt UnE eval.simps(1) eval_list_conj hlength imageE list_update_length set_append set_map)
show ?thesis using right left by blast
qed
text "simply states that the variable is free in the equality case of the elimVar function"
lemma freeIn_elimVar_eq : "freeIn var (elimVar var L F (Eq p))"
proof-
have h4 : "var ∉ vars(4:: real mpoly)" using var_not_in_Const
by (metis (full_types) isolate_var_one monom_numeral not_in_isovarspar numeral_One vars_monom_keys zero_neq_numeral)
have hlinear: "∀f∈set(map (λa. Atom(linear_substitution var (-isolate_variable_sparse p var 0) (isolate_variable_sparse p var (Suc 0)) a)) L @
map (linear_substitution_fm var (-isolate_variable_sparse p var 0) (isolate_variable_sparse p var (Suc 0)))
F). freeIn var f"
using
var_not_in_linear[where c="(isolate_variable_sparse p var (Suc 0))", where b="(- isolate_variable_sparse p var 0)", where var="var"]
var_not_in_linear_fm[where c="(isolate_variable_sparse p var (Suc 0))", where b="(-isolate_variable_sparse p var 0)", where var="var"]
not_in_isovarspar not_in_neg by auto
have freeA : "var ∉ vars (- isolate_variable_sparse p var (Suc 0))"
using not_in_isovarspar not_in_neg by auto
have freeB1 : "var ∉ vars (1::real mpoly)"
by (metis h4 monom_numeral monom_one notInKeys_notInVars vars_monom_keys zero_neq_numeral)
have freeC : "var ∉ vars (((isolate_variable_sparse p var (Suc 0))⇧2 -
4 * isolate_variable_sparse p var 2 * isolate_variable_sparse p var 0))"
using not_in_isovarspar not_in_pow not_in_sub not_in_mult h4 by auto
have freeD : "var ∉ vars ((2 * isolate_variable_sparse p var 2))"
using not_in_isovarspar not_in_mult
by (metis mult_2 not_in_add)
have freeB2 : "var∉vars (-1::real mpoly)"
using freeB1 not_in_neg by auto
have quadratic1 : "∀f∈set(map (quadratic_sub var (- isolate_variable_sparse p var (Suc 0)) 1
((isolate_variable_sparse p var (Suc 0))⇧2 -
4 * isolate_variable_sparse p var 2 * isolate_variable_sparse p var 0)
(2 * isolate_variable_sparse p var 2))
L @
map (quadratic_sub_fm var (- isolate_variable_sparse p var (Suc 0)) 1
((isolate_variable_sparse p var (Suc 0))⇧2 -
4 * isolate_variable_sparse p var 2 * isolate_variable_sparse p var 0)
(2 * isolate_variable_sparse p var 2))
F). freeIn var f"
using free_in_quad[OF freeA freeB1 freeC freeD]
free_in_quad_fm[OF freeA freeB1 freeC freeD] by auto
have quadratic2 : "∀f∈set(map (quadratic_sub var (- isolate_variable_sparse p var (Suc 0)) (-1)
((isolate_variable_sparse p var (Suc 0))⇧2 -
4 * isolate_variable_sparse p var 2 * isolate_variable_sparse p var 0)
(2 * isolate_variable_sparse p var 2))
L @
map (quadratic_sub_fm var (- isolate_variable_sparse p var (Suc 0)) (-1)
((isolate_variable_sparse p var (Suc 0))⇧2 -
4 * isolate_variable_sparse p var 2 * isolate_variable_sparse p var 0)
(2 * isolate_variable_sparse p var 2))
F). freeIn var f"
using free_in_quad[OF freeA freeB2 freeC freeD]
free_in_quad_fm[OF freeA freeB2 freeC freeD] by auto
show ?thesis
using not_in_mult not_in_add h4 not_in_pow not_in_sub freeIn_list_conj not_in_isovarspar hlinear quadratic1 quadratic2
by simp
qed
text "Theorem 20.2 in the textbook"
lemma elimVar_eq_2 :
assumes hlength : "length xs = var"
assumes in_list : "Eq p ∈ set(L)"
assumes low_pow : "MPoly_Type.degree p var = 1 ∨ MPoly_Type.degree p var = 2"
assumes nonzero : "∀x.
insertion (nth_default 0 (xs @ x # Γ)) (isolate_variable_sparse p var 2) ≠ 0
∨ insertion (nth_default 0 (xs @ x # Γ)) (isolate_variable_sparse p var 1) ≠ 0
∨ insertion (nth_default 0 (xs @ x # Γ)) (isolate_variable_sparse p var 0) ≠ 0" (is ?non0)
shows "(∃x. eval (list_conj (map fm.Atom L @ F)) (xs @ x # Γ)) =
(∃x. eval (elimVar var L F (Eq p)) (xs @ x # Γ))"
proof-
define A where "A = (isolate_variable_sparse p var 2)"
define B where "B = (isolate_variable_sparse p var 1)"
define C where "C = (isolate_variable_sparse p var 0)"
have freeA : "var ∉ vars A"
unfolding A_def
by (simp add: not_in_isovarspar)
have freeB : "var ∉ vars B"
unfolding B_def
by (simp add: not_in_isovarspar)
have freeC : "var ∉ vars C"
unfolding C_def
by (simp add: not_in_isovarspar)
have express_p : "p = A*(Var var)^2+B*(Var var)+C"
using express_poly[OF low_pow] unfolding A_def B_def C_def
by fastforce
have af : "isolate_variable_sparse p var 2 = A"
using A_def by auto
have bf : "isolate_variable_sparse p var (Suc 0) = B"
using B_def by auto
have cf : "isolate_variable_sparse p var 0 = C"
using C_def by auto
have xlength : "∀x. (insertion (nth_default 0 (xs @ x # Γ)) (Var var))= x"
using hlength insertion_var
by (metis add.commute add_strict_increasing length_append length_greater_0_conv list.distinct(1) list_update_id nth_append_length order_refl)
fix x
define c where "c i = (insertion (nth_default 0 (xs @ x # Γ)) (isolate_variable_sparse p var i))" for i
have c2 : "∀x. insertion (nth_default 0 (xs @ x # Γ)) A = c 2"
using freeA apply(simp add: A_def c_def)
by (simp add: hlength insertion_lowerPoly1)
have c1 : "∀x. insertion (nth_default 0 (xs @ x # Γ)) B = c 1"
using freeB apply(simp add: B_def c_def)
by (simp add: hlength insertion_lowerPoly1)
have c0 : "∀x. insertion (nth_default 0 (xs @ x # Γ)) C = c 0"
using freeC apply(simp add: C_def c_def)
by (simp add: hlength insertion_lowerPoly1)
have sum : "∀x. c 2 * x⇧2 + c (Suc 0) * x + c 0 = (∑i≤2. c i * x ^ i)"
by (simp add: numerals(2))
have "(∀x. aEval (Eq p) (xs @ x # Γ)) = (¬?non0)"
apply(simp add : af bf cf)
unfolding express_p apply(simp add:insertion_add insertion_mult insertion_pow xlength)
apply(simp add:c2 c1 c0)
apply(simp add: sum)
using polyfun_eq_0[where c="c", where n="2"]
using sum by auto
then have "¬(∀x. aEval (Eq p) (xs @ x Γ))"
using nonzero by auto
then show ?thesis
using disjE[OF elimVar_eq[OF hlength in_list, where F="F", where Γ="Γ"], where R="?thesis"]
using ‹(∀x. aEval (Eq p) (xs @ x # Γ)) = (¬ (∀x. insertion (nth_default 0 (xs @ x # Γ)) (isolate_variable_sparse p var 2) ≠ 0 ∨ insertion (nth_default 0 (xs @ x # Γ)) (isolate_variable_sparse p var 1) ≠ 0 ∨ insertion (nth_default 0 (xs @ x # Γ)) (isolate_variable_sparse p var 0) ≠ 0))› low_pow nonzero by blast
qed
end