1 files changed, 0 insertions, 443 deletions

diff --git a/proofs/signatures/th_lra.plf b/proofs/signatures/th_lra.plf
deleted file mode 100644
index 76e5127c2..000000000
--- a/proofs/signatures/th_lra.plf
+++ /dev/null
@@ -1,443 +0,0 @@
-; Depends on th_real.plf, smt.plf, sat.plf
-
-; LRA proofs have the following interface:
-;    * Given predicates between real terms
-;    * Prove bottom
-;
-; However, even though the type of the interface does not express this,
-; the predicates are **linear bounds**, not arbitrary real bounds. Thus
-; LRA proofs have the following structure:
-;
-;    1. Prove that the input predicates are equivalent to a set of linear
-;       bounds.
-;    2. Use the linear bounds to prove bottom using farkas coefficients.
-;
-; Notice that the distinction between linear bounds (associated in the signature
-; with the string "poly") and real predicates (which relate "term Real"s to one
-; another) matters quite a bit. We have certain kinds of axioms for one, and
-; other axioms for the other.
-
-(program mpq_ifpos ((x mpq)) bool
-  (mp_ifneg x ff (mp_ifzero x ff tt)))
-
-; a real variable
-(declare var_real type)
-; a real variable term
-(declare a_var_real (! v var_real (term Real)))
-
-;; linear polynomials in the form a_1*x_1 + a_2*x_2 .... + a_n*x_n
-
-(declare lmon type)
-(declare lmonn lmon)
-(declare lmonc (! c mpq (! v var_real (! l lmon lmon))))
-
-(program lmon_neg ((l lmon)) lmon
-  (match l
-    (lmonn l)
-    ((lmonc c' v' l') (lmonc (mp_neg c') v' (lmon_neg l')))))
-
-(program lmon_add ((l1 lmon) (l2 lmon)) lmon
-  (match l1
-    (lmonn l2)
-    ((lmonc c' v' l')
-      (match l2
-        (lmonn l1)
-        ((lmonc c'' v'' l'')
-          (compare v' v''
-            (lmonc c' v' (lmon_add l' l2))
-            (lmonc c'' v'' (lmon_add l1 l''))))))))
-
-(program lmon_mul_c ((l lmon) (c mpq)) lmon
-  (match l
-    (lmonn l)
-    ((lmonc c' v' l') (lmonc (mp_mul c c') v' (lmon_mul_c l' c)))))
-
-;; linear polynomials in the form (a_1*x_1 + a_2*x_2 .... + a_n*x_n) + c
-
-(declare poly type)
-(declare polyc (! c mpq (! l lmon poly)))
-
-(program poly_neg ((p poly)) poly
-  (match p
-    ((polyc m' p') (polyc (mp_neg m') (lmon_neg p')))))
-
-(program poly_add ((p1 poly) (p2 poly)) poly
-  (match p1
-    ((polyc c1 l1)
-      (match p2
-        ((polyc c2 l2) (polyc (mp_add c1 c2) (lmon_add l1 l2)))))))
-
-(program poly_sub ((p1 poly) (p2 poly)) poly
-  (poly_add p1 (poly_neg p2)))
-
-(program poly_mul_c ((p poly) (c mpq)) poly
-  (match p
-    ((polyc c' l') (polyc (mp_mul c' c) (lmon_mul_c l' c)))))
-
-;; code to isolate a variable from a term
-;; if (isolate v l) returns (c,l'), this means l = c*v + l', where v is not in FV(t').
-
-(declare isol type)
-(declare isolc (! r mpq (! l lmon isol)))
-
-(program isolate_h ((v var_real) (l lmon) (e bool)) isol
-  (match l
-    (lmonn (isolc 0/1 l))
-    ((lmonc c' v' l')
-      (ifmarked v'
-        (match (isolate_h v l' tt)
-          ((isolc ci li) (isolc (mp_add c' ci) li)))
-        (match e
-          (tt (isolc 0/1 l))
-          (ff (match (isolate_h v l' ff)
-                ((isolc ci li) (isolc ci (lmonc c' v' li))))))))))
-
-(program isolate ((v var_real) (l lmon)) isol
-  (do (markvar v)
-  (let i (isolate_h v l ff)
-  (do (markvar v) i))))
-
-;; determine if a monomial list is constant
-
-(program is_lmon_zero ((l lmon)) bool
-  (match l
-    (lmonn tt)
-    ((lmonc c v l')
-      (match (isolate v l)
-        ((isolc ci li)
-          (mp_ifzero ci (is_lmon_zero li) ff))))))
-
-;; return the constant that p is equal to.  If p is not constant, fail.
-
-(program is_poly_const ((p poly)) mpq
-  (match p
-    ((polyc c' l')
-      (match (is_lmon_zero l')
-        (tt c')
-        (ff (fail mpq))))))
-
-;; conversion to use polynomials in term formulas
-
-
-(declare >=0_poly (! x poly formula))
-(declare =0_poly (! x poly formula))
-(declare >0_poly (! x poly formula))
-(declare distinct0_poly (! x poly formula))
-
-;; create new equality out of inequality
-
-(declare lra_>=_>=_to_=
-  (! p1 poly
-  (! p2 poly
-  (! f1 (th_holds (>=0_poly p1))
-  (! f2 (th_holds (>=0_poly p2))
-  (! i2 (^ (mp_ifzero (is_poly_const (poly_add p1 p2)) tt ff) tt)
-    (th_holds (=0_poly p2))))))))
-
-;; axioms
-
-(declare lra_axiom_=
-   (th_holds (=0_poly (polyc 0/1 lmonn))))
-
-(declare lra_axiom_>
-  (! c mpq
-  (! i (^ (mpq_ifpos c) tt)
-    (th_holds (>0_poly (polyc c lmonn))))))
-
-(declare lra_axiom_>=
-  (! c mpq
-  (! i (^ (mp_ifneg c tt ff) ff)
-    (th_holds (>=0_poly (polyc c lmonn))))))
-
-(declare lra_axiom_distinct
-  (! c mpq
-  (! i (^ (mp_ifzero c tt ff) ff)
-    (th_holds (distinct0_poly (polyc c lmonn))))))
-
-;; contradiction rules
-
-(declare lra_contra_=
-  (! p poly
-  (! f (th_holds (=0_poly p))
-  (! i (^ (mp_ifzero (is_poly_const p) tt ff) ff)
-    (holds cln)))))
-
-(declare lra_contra_>
-  (! p poly
-  (! f (th_holds (>0_poly p))
-  (! i2 (^ (mpq_ifpos (is_poly_const p)) ff)
-    (holds cln)))))
-
-(declare lra_contra_>=
-  (! p poly
-  (! f (th_holds (>=0_poly p))
-  (! i2 (^ (mp_ifneg (is_poly_const p) tt ff) tt)
-    (holds cln)))))
-
-(declare lra_contra_distinct
-  (! p poly
-  (! f (th_holds (distinct0_poly p))
-  (! i2 (^ (mp_ifzero (is_poly_const p) tt ff) tt)
-    (holds cln)))))
-
-;; muliplication by a constant
-
-(declare lra_mul_c_=
-  (! p poly
-  (! p' poly
-  (! c mpq
-  (! f (th_holds (=0_poly p))
-  (! i (^ (poly_mul_c p c) p')
-    (th_holds (=0_poly p'))))))))
-
-(declare lra_mul_c_>
-  (! p poly
-  (! p' poly
-  (! c mpq
-  (! f (th_holds (>0_poly p))
-  (! i (^ (mp_ifneg c (fail poly) (mp_ifzero c (fail poly) (poly_mul_c p c))) p')
-    (th_holds (>0_poly p'))))))));
-
-(declare lra_mul_c_>=
-  (! p poly
-  (! p' poly
-  (! c mpq
-  (! f (th_holds (>=0_poly p))
-  (! i (^ (mp_ifneg c (fail poly) (poly_mul_c p c)) p')
-    (th_holds (>=0_poly p'))))))))
-
-(declare lra_mul_c_distinct
-  (! p poly
-  (! p' poly
-  (! c mpq
-  (! f (th_holds (distinct0_poly p))
-  (! i (^ (mp_ifzero c (fail poly) (poly_mul_c p c)) p')
-    (th_holds (distinct0_poly p'))))))))
-
-;; adding equations
-
-(declare lra_add_=_=
-  (! p1 poly
-  (! p2 poly
-  (! p3 poly
-  (! f1 (th_holds (=0_poly p1))
-  (! f2 (th_holds (=0_poly p2))
-  (! i (^ (poly_add p1 p2) p3)
-    (th_holds (=0_poly p3)))))))))
-
-(declare lra_add_>_>
-  (! p1 poly
-  (! p2 poly
-  (! p3 poly
-  (! f1 (th_holds (>0_poly p1))
-  (! f2 (th_holds (>0_poly p2))
-  (! i (^ (poly_add p1 p2) p3)
-    (th_holds (>0_poly p3)))))))))
-
-(declare lra_add_>=_>=
-  (! p1 poly
-  (! p2 poly
-  (! p3 poly
-  (! f1 (th_holds (>=0_poly p1))
-  (! f2 (th_holds (>=0_poly p2))
-  (! i (^ (poly_add p1 p2) p3)
-    (th_holds (>=0_poly p3)))))))))
-
-(declare lra_add_=_>
-  (! p1 poly
-  (! p2 poly
-  (! p3 poly
-  (! f1 (th_holds (=0_poly p1))
-  (! f2 (th_holds (>0_poly p2))
-  (! i (^ (poly_add p1 p2) p3)
-    (th_holds (>0_poly p3)))))))))
-
-(declare lra_add_=_>=
-  (! p1 poly
-  (! p2 poly
-  (! p3 poly
-  (! f1 (th_holds (=0_poly p1))
-  (! f2 (th_holds (>=0_poly p2))
-  (! i (^ (poly_add p1 p2) p3)
-    (th_holds (>=0_poly p3)))))))))
-
-(declare lra_add_>_>=
-  (! p1 poly
-  (! p2 poly
-  (! p3 poly
-  (! f1 (th_holds (>0_poly p1))
-  (! f2 (th_holds (>=0_poly p2))
-  (! i (^ (poly_add p1 p2) p3)
-    (th_holds (>0_poly p3)))))))))
-
-(declare lra_add_>=_>
-  (! p1 poly
-  (! p2 poly
-  (! p3 poly
-  (! f1 (th_holds (>=0_poly p1))
-  (! f2 (th_holds (>0_poly p2))
-  (! i (^ (poly_add p1 p2) p3)
-    (th_holds (>0_poly p3)))))))))
-
-(declare lra_add_=_distinct
-  (! p1 poly
-  (! p2 poly
-  (! p3 poly
-  (! f1 (th_holds (=0_poly p1))
-  (! f2 (th_holds (distinct0_poly p2))
-  (! i (^ (poly_add p1 p2) p3)
-    (th_holds (distinct0_poly p3)))))))))
-
-;; substracting equations
-
-(declare lra_sub_=_=
-  (! p1 poly
-  (! p2 poly
-  (! p3 poly
-  (! f1 (th_holds (=0_poly p1))
-  (! f2 (th_holds (=0_poly p2))
-  (! i (^ (poly_sub p1 p2) p3)
-    (th_holds (=0_poly p3)))))))))
-
-(declare lra_sub_>_=
-  (! p1 poly
-  (! p2 poly
-  (! p3 poly
-  (! f1 (th_holds (>0_poly p1))
-  (! f2 (th_holds (=0_poly p2))
-  (! i (^ (poly_sub p1 p2) p3)
-    (th_holds (>0_poly p3)))))))))
-
-(declare lra_sub_>=_=
-  (! p1 poly
-  (! p2 poly
-  (! p3 poly
-  (! f1 (th_holds (>=0_poly p1))
-  (! f2 (th_holds (=0_poly p2))
-  (! i (^ (poly_sub p1 p2) p3)
-    (th_holds (>=0_poly p3)))))))))
-
-(declare lra_sub_distinct_=
-  (! p1 poly
-  (! p2 poly
-  (! p3 poly
-  (! f1 (th_holds (distinct0_poly p1))
-  (! f2 (th_holds (=0_poly p2))
-  (! i (^ (poly_sub p1 p2) p3)
-    (th_holds (distinct0_poly p3)))))))))
-
- ;; converting between terms and polynomials
-
-(declare poly_norm (! t (term Real) (! p poly type)))
-
-(declare pn_let
-  (! t (term Real)
-  (! p poly
-  (! pn (poly_norm t p)
-
-  (! u (! pnt (poly_norm t p)
-         (holds cln))
-    (holds cln))))))
-
-(declare pn_const
-  (! x mpq
-    (poly_norm (a_real x) (polyc x lmonn))))
-
-(declare pn_var
-  (! v var_real
-    (poly_norm (a_var_real v) (polyc 0/1 (lmonc 1/1 v lmonn)))))
-
-
-(declare pn_+
-  (! x (term Real)
-  (! px poly
-  (! y (term Real)
-  (! py poly
-  (! pz poly
-  (! pnx (poly_norm x px)
-  (! pny (poly_norm y py)
-  (! a (^ (poly_add px py) pz)
-    (poly_norm (+_Real x y) pz))))))))))
-
-(declare pn_-
-  (! x (term Real)
-  (! px poly
-  (! y (term Real)
-  (! py poly
-  (! pz poly
-  (! pnx (poly_norm x px)
-  (! pny (poly_norm y py)
-  (! a (^ (poly_sub px py) pz)
-    (poly_norm (-_Real x y) pz))))))))))
-
-(declare pn_mul_c_L
-  (! y (term Real)
-  (! py poly
-  (! pz poly
-  (! x mpq
-  (! pny (poly_norm y py)
-  (! a (^ (poly_mul_c py x) pz)
-    (poly_norm (*_Real (a_real x) y) pz))))))))
-
-(declare pn_mul_c_R
-  (! y (term Real)
-  (! py poly
-  (! pz poly
-  (! x mpq
-  (! pny (poly_norm y py)
-  (! a (^ (poly_mul_c py x) pz)
-    (poly_norm (*_Real y (a_real x)) pz))))))))
-
-(declare poly_flip_not_>=
-  (! p poly
-  (! p_negged poly
-  (! pf_formula (th_holds (not (>=0_poly p)))
-  (! sc (^ (poly_neg p) p_negged)
-     (th_holds (>0_poly p_negged)))))))
-
-
-;; for polynomializing other terms, in particular ite's
-
-(declare term_atom (! v var_real (! t (term Real) type)))
-
-(declare decl_term_atom
-  (! t (term Real)
-  (! u (! v var_real
-       (! a (term_atom v t)
-         (holds cln)))
-    (holds cln))))
-
-(declare pn_var_atom
-  (! v var_real
-  (! t (term Real)
-  (! a (term_atom v t)
-    (poly_norm t (polyc 0/1 (lmonc 1/1 v lmonn)))))))
-
-
-;; conversion between term formulas and polynomial formulas
-
-(declare poly_formula_norm (! ft formula (! fp formula type)))
-
-; convert between term formulas and polynomial formulas
-
-(declare poly_form
-  (! ft formula
-  (! fp formula
-  (! p (poly_formula_norm ft fp)
-  (! u (th_holds ft)
-    (th_holds fp))))))
-
-(declare poly_form_not
-  (! ft formula
-  (! fp formula
-  (! p (poly_formula_norm ft fp)
-  (! u (th_holds (not ft))
-    (th_holds (not fp)))))))
-
-(declare poly_formula_norm_>=
-  (! x (term Real)
-  (! y (term Real)
-  (! p poly
-  (! n (poly_norm (-_Real y x) p)
-     (poly_formula_norm (>=_Real y x) (>=0_poly p)))))))
-