Theory Graph_Theory.Stuff
theory Stuff
imports
Main
"HOL-Library.Extended_Real"
begin
section ‹Additional theorems for base libraries›
text ‹
This section contains lemmas unrelated to graph theory which might be
interesting for the Isabelle distribution
›
lemma ereal_Inf_finite_Min:
fixes S :: "ereal set"
assumes "finite S" and "S ≠ {}"
shows "Inf S = Min S"
using assms
by (induct S rule: finite_ne_induct) (auto simp: min_absorb1)
lemma finite_INF_in:
fixes f :: "'a ⇒ ereal"
assumes "finite S"
assumes "S ≠ {}"
shows "(INF s∈ S. f s) ∈ f ` S"
proof -
from assms
have "finite (f ` S)" "f ` S ≠ {}" by auto
then show "Inf (f ` S) ∈ f ` S"
using ereal_Inf_finite_Min [of "f ` S"] by simp
qed
lemma not_mem_less_INF:
fixes f :: "'a ⇒ 'b :: complete_lattice"
assumes "f x < (INF s∈ S. f s)"
assumes "x ∈ S"
shows "False"
using assms by (metis INF_lower less_le_not_le)
lemma sym_diff:
assumes "sym A" "sym B" shows "sym (A - B)"
using assms by (auto simp: sym_def)
subsection ‹List›
lemmas list_exhaust2 = list.exhaust[case_product list.exhaust]
lemma list_exhaust_NSC:
obtains (Nil) "xs = []" | (Single) x where "xs = [x]" | (Cons_Cons) x y ys where "xs = x # y # ys"
by (metis list.exhaust)
lemma tl_rev:
"tl (rev p) = rev (butlast p)"
by (induct p) auto
lemma butlast_rev:
"butlast (rev p) = rev (tl p)"
by (induct p) auto
lemma take_drop_take:
"take n xs @ drop n (take m xs) = take (max n m) xs"
proof cases
assume "m < n" then show ?thesis by (auto simp: max_def)
next
assume "¬m < n"
then have "take n xs = take n (take m xs)" by (auto simp: min_def)
then show ?thesis by (simp del: take_take add: max_def)
qed
lemma drop_take_drop:
"drop n (take m xs) @ drop m xs = drop (min n m) xs"
proof cases
assume A: "¬m < n"
then show ?thesis
using drop_append[of n "take m xs" "drop m xs"]
by (cases "length xs < n") (auto simp: not_less min_def)
qed (auto simp: min_def)
lemma not_distinct_decomp_min_prefix:
assumes "¬ distinct ws"
shows "∃ xs ys zs y. ws = xs @ y # ys @ y # zs ∧ distinct xs ∧ y ∉ set xs ∧ y ∉ set ys "
proof -
obtain xs y ys where "y ∈ set xs" "distinct xs" "ws = xs @ y # ys"
using assms by (auto simp: not_distinct_conv_prefix)
moreover then obtain xs' ys' where "xs = xs' @ y # ys'" by (auto simp: in_set_conv_decomp)
ultimately show ?thesis by auto
qed
lemma not_distinct_decomp_min_not_distinct:
assumes "¬ distinct ws"
shows "∃xs y ys zs. ws = xs @ y # ys @ y # zs ∧ distinct (ys @ [y])"
using assms
proof (induct ws)
case (Cons w ws)
show ?case
proof (cases "distinct ws")
case True
then obtain xs ys where "ws = xs @ w # ys" "w ∉ set xs"
using Cons.prems by (fastforce dest: split_list_first)
then have "distinct (xs @ [w])" "w # ws = [] @ w # xs @ w # ys"
using ‹distinct ws› by auto
then show ?thesis by blast
next
case False
then obtain xs y ys zs where "ws = xs @ y # ys @ y # zs ∧ distinct (ys @ [y])"
using Cons by auto
then have "w # ws = (w # xs) @ y # ys @ y # zs ∧ distinct (ys @ [y])"
by simp
then show ?thesis by blast
qed
qed simp
lemma card_Ex_subset:
"k ≤ card M ⟹ ∃N. N ⊆ M ∧ card N = k"
by (induct rule: inc_induct) (auto simp: card_Suc_eq)
lemma list_set_tl: "x ∈ set (tl xs) ⟹ x ∈ set xs"
by (cases xs) auto
section ‹NOMATCH simproc›
text ‹
The simplification procedure can be used to avoid simplification of terms of a certain form
›
definition NOMATCH :: "'a ⇒ 'a ⇒ bool" where "NOMATCH val pat ≡ True"
lemma NOMATCH_cong[cong]: "NOMATCH val pat = NOMATCH val pat" by (rule refl)
simproc_setup NOMATCH ("NOMATCH val pat") = ‹fn _ => fn ctxt => fn ct =>
let
val thy = Proof_Context.theory_of ctxt
val dest_binop = Term.dest_comb #> apfst (Term.dest_comb #> snd)
val m = Pattern.matches thy (dest_binop (Thm.term_of ct))
in if m then NONE else SOME @{thm NOMATCH_def} end
›
text ‹
This setup ensures that a rewrite rule of the form @{term "NOMATCH val pat ⟹ t"}
is only applied, if the pattern @{term pat} does not match the value @{term val}.
›
end