Theory Graph_Theory.Pair_Digraph
theory Pair_Digraph
imports
Digraph
Bidirected_Digraph
Arc_Walk
begin
section ‹Digraphs without Parallel Arcs›
text ‹
If no parallel arcs are desired, arcs can be accurately described as pairs of
This is the natural representation for Digraphs without multi-arcs.
and @{term "head G"}, making it easier to deal with multiple related graphs
and to modify a graph by adding edges.
This theory introduces such a specialisation of digraphs.
›
record 'a pair_pre_digraph = pverts :: "'a set" parcs :: "'a rel"
definition with_proj :: "'a pair_pre_digraph ⇒ ('a, 'a × 'a) pre_digraph" where
"with_proj G = ⦇ verts = pverts G, arcs = parcs G, tail = fst, head = snd ⦈"
declare [[coercion with_proj]]
primrec pawalk_verts :: "'a ⇒ ('a × 'a) awalk ⇒ 'a list" where
"pawalk_verts u [] = [u]" |
"pawalk_verts u (e # es) = fst e # pawalk_verts (snd e) es"
fun pcas :: "'a ⇒ ('a × 'a) awalk ⇒ 'a ⇒ bool" where
"pcas u [] v = (u = v)" |
"pcas u (e # es) v = (fst e = u ∧ pcas (snd e) es v)"
lemma with_proj_simps[simp]:
"verts (with_proj G) = pverts G"
"arcs (with_proj G) = parcs G"
"arcs_ends (with_proj G) = parcs G"
"tail (with_proj G) = fst"
"head (with_proj G) = snd"
by (auto simp: with_proj_def arcs_ends_conv)
lemma cas_with_proj_eq: "pre_digraph.cas (with_proj G) = pcas"
proof (unfold fun_eq_iff, intro allI)
fix u es v show "pre_digraph.cas (with_proj G) u es v = pcas u es v"
by (induct es arbitrary: u) (auto simp: pre_digraph.cas.simps)
qed
lemma awalk_verts_with_proj_eq: "pre_digraph.awalk_verts (with_proj G) = pawalk_verts"
proof (unfold fun_eq_iff, intro allI)
fix u es show "pre_digraph.awalk_verts (with_proj G) u es = pawalk_verts u es"
by (induct es arbitrary: u) (auto simp: pre_digraph.awalk_verts.simps)
qed
locale pair_pre_digraph = fixes G :: "'a pair_pre_digraph"
begin
lemmas [simp] = cas_with_proj_eq awalk_verts_with_proj_eq
end
locale pair_wf_digraph = pair_pre_digraph +
assumes arc_fst_in_verts: "⋀e. e ∈ parcs G ⟹ fst e ∈ pverts G"
assumes arc_snd_in_verts: "⋀e. e ∈ parcs G ⟹ snd e ∈ pverts G"
begin
lemma in_arcsD1: "(u,v) ∈ parcs G ⟹ u ∈ pverts G"
and in_arcsD2: "(u,v) ∈ parcs G ⟹ v ∈ pverts G"
by (auto dest: arc_fst_in_verts arc_snd_in_verts)
lemmas wellformed' = in_arcsD1 in_arcsD2
end
locale pair_fin_digraph = pair_wf_digraph +
assumes pair_finite_verts: "finite (pverts G)"
and pair_finite_arcs: "finite (parcs G)"
locale pair_sym_digraph = pair_wf_digraph +
assumes pair_sym_arcs: "symmetric G"
locale pair_loopfree_digraph = pair_wf_digraph +
assumes pair_no_loops: "e ∈ parcs G ⟹ fst e ≠ snd e"
locale pair_bidirected_digraph = pair_sym_digraph + pair_loopfree_digraph
locale pair_pseudo_graph = pair_fin_digraph + pair_sym_digraph
locale pair_digraph = pair_fin_digraph + pair_loopfree_digraph
locale pair_graph = pair_digraph + pair_pseudo_graph
sublocale pair_pre_digraph ⊆ pre_digraph "with_proj G"
rewrites "verts G = pverts G" and "arcs G = parcs G" and "tail G = fst" and "head G = snd"
and "arcs_ends G = parcs G"
and "pre_digraph.awalk_verts G = pawalk_verts"
and "pre_digraph.cas G = pcas"
by unfold_locales auto
sublocale pair_wf_digraph ⊆ wf_digraph "with_proj G"
rewrites "verts G = pverts G" and "arcs G = parcs G" and "tail G = fst" and "head G = snd"
and "arcs_ends G = parcs G"
and "pre_digraph.awalk_verts G = pawalk_verts"
and "pre_digraph.cas G = pcas"
by unfold_locales (auto simp: arc_fst_in_verts arc_snd_in_verts)
sublocale pair_fin_digraph ⊆ fin_digraph "with_proj G"
rewrites "verts G = pverts G" and "arcs G = parcs G" and "tail G = fst" and "head G = snd"
and "arcs_ends G = parcs G"
and "pre_digraph.awalk_verts G = pawalk_verts"
and "pre_digraph.cas G = pcas"
using pair_finite_verts pair_finite_arcs by unfold_locales auto
sublocale pair_sym_digraph ⊆ sym_digraph "with_proj G"
rewrites "verts G = pverts G" and "arcs G = parcs G" and "tail G = fst" and "head G = snd"
and "arcs_ends G = parcs G"
and "pre_digraph.awalk_verts G = pawalk_verts"
and "pre_digraph.cas G = pcas"
using pair_sym_arcs by unfold_locales auto
sublocale pair_pseudo_graph ⊆ pseudo_graph "with_proj G"
rewrites "verts G = pverts G" and "arcs G = parcs G" and "tail G = fst" and "head G = snd"
and "arcs_ends G = parcs G"
and "pre_digraph.awalk_verts G = pawalk_verts"
and "pre_digraph.cas G = pcas"
by unfold_locales auto
sublocale pair_loopfree_digraph ⊆ loopfree_digraph "with_proj G"
rewrites "verts G = pverts G" and "arcs G = parcs G" and "tail G = fst" and "head G = snd"
and "arcs_ends G = parcs G"
and "pre_digraph.awalk_verts G = pawalk_verts"
and "pre_digraph.cas G = pcas"
using pair_no_loops by unfold_locales auto
sublocale pair_digraph ⊆ digraph "with_proj G"
rewrites "verts G = pverts G" and "arcs G = parcs G" and "tail G = fst" and "head G = snd"
and "arcs_ends G = parcs G"
and "pre_digraph.awalk_verts G = pawalk_verts"
and "pre_digraph.cas G = pcas"
by unfold_locales (auto simp: arc_to_ends_def)
sublocale pair_graph ⊆ graph "with_proj G"
rewrites "verts G = pverts G" and "arcs G = parcs G" and "tail G = fst" and "head G = snd"
and "arcs_ends G = parcs G"
and "pre_digraph.awalk_verts G = pawalk_verts"
and "pre_digraph.cas G = pcas"
by unfold_locales auto
sublocale pair_graph ⊆ pair_bidirected_digraph by unfold_locales
lemma wf_digraph_wp_iff: "wf_digraph (with_proj G) = pair_wf_digraph G" (is "?L ⟷ ?R")
proof
assume ?L then interpret wf_digraph "with_proj G" .
show ?R using wellformed by unfold_locales auto
next
assume ?R then interpret pair_wf_digraph G .
show ?L by unfold_locales
qed
lemma (in pair_fin_digraph) pair_fin_digraph[intro!]: "pair_fin_digraph G" ..
context pair_digraph begin
lemma pair_wf_digraph[intro!]: "pair_wf_digraph G" by intro_locales
lemma pair_digraph[intro!]: "pair_digraph G" ..
lemma (in pair_loopfree_digraph) no_loops':
"(u,v) ∈ parcs G ⟹ u ≠ v"
by (auto dest: no_loops)
end
lemma (in pair_wf_digraph) apath_succ_decomp:
assumes "apath u p v"
assumes "(x,y) ∈ set p"
assumes "y ≠ v"
shows "∃p1 z p2. p = p1 @ (x,y) # (y,z) # p2 ∧ x ≠ z ∧ y ≠ z"
proof -
from ‹(x,y) ∈ set p› obtain p1 p2 where p_decomp: "p = p1 @ (x,y) # p2"
by (metis (no_types) in_set_conv_decomp_first)
from p_decomp ‹apath u p v› ‹y ≠ v› have "p2 ≠ []" "awalk y p2 v"
by (auto simp: apath_def awalk_Cons_iff)
then obtain z p2' where p2_decomp: "p2 = (y,z) # p2'"
by atomize_elim (cases p2, auto simp: awalk_Cons_iff)
then have "x ≠ z ∧ y ≠ z" using p_decomp p2_decomp ‹apath u p v›
by (auto simp: apath_append_iff apath_simps hd_in_awalk_verts)
with p_decomp p2_decomp have "p = p1 @ (x,y) # (y,z) # p2' ∧ x ≠ z ∧ y ≠ z"
by auto
then show ?thesis by blast
qed
lemma (in pair_sym_digraph) arcs_symmetric:
"(a,b) ∈ parcs G ⟹ (b,a) ∈ parcs G"
using sym_arcs by (auto simp: symmetric_def elim: symE)
lemma (in pair_pseudo_graph) pair_pseudo_graph[intro]: "pair_pseudo_graph G" ..
lemma (in pair_graph) pair_graph[intro]: "pair_graph G" by unfold_locales
lemma (in pair_graph) pair_graphD_graph: "graph G" by unfold_locales
lemma pair_graphI_graph:
assumes "graph (with_proj G)" shows "pair_graph G"
proof -
interpret G: graph "with_proj G" by fact
show ?thesis
using G.wellformed G.finite_arcs G.finite_verts G.no_loops
by unfold_locales auto
qed
lemma pair_loopfreeI_loopfree:
assumes "loopfree_digraph (with_proj G)" shows "pair_loopfree_digraph G"
proof -
interpret loopfree_digraph "with_proj G" by fact
show ?thesis using wellformed no_loops by unfold_locales auto
qed
subsection ‹Path reversal for Pair Digraphs›
text ‹This definition is only meaningful in @{term Pair_Digraph}›
primrec rev_path :: "('a × 'a) awalk ⇒ ('a × 'a) awalk" where
"rev_path [] = []" |
"rev_path (e # es) = rev_path es @ [(snd e, fst e)]"
lemma rev_path_append[simp]: "rev_path (p @ q) = rev_path q @ rev_path p"
by (induct p) auto
lemma rev_path_rev_path[simp]:
"rev_path (rev_path p) = p"
by (induct p) auto
lemma rev_path_empty[simp]:
"rev_path p = [] ⟷ p = []"
by (induct p) auto
lemma rev_path_eq: "rev_path p = rev_path q ⟷ p = q"
by (metis rev_path_rev_path)
lemma (in pair_sym_digraph)
assumes "awalk u p v"
shows awalk_verts_rev_path: "awalk_verts v (rev_path p) = rev (awalk_verts u p)"
and awalk_rev_path': "awalk v (rev_path p) u"
using assms
proof (induct p arbitrary: u)
case Nil case 1 then show ?case by auto
next
case Nil case 2 then show ?case by (auto simp: awalk_Nil_iff)
next
case (Cons e es) case 1
with Cons have walks: "awalk v (rev_path es) (snd e)"
"awalk (snd e) [(snd e, fst e)] u"
and verts: "awalk_verts v (rev_path es) = rev (awalk_verts (snd e) es)"
by (auto simp: awalk_simps intro: arcs_symmetric)
from walks have "awalk v (rev_path es @ [(snd e, fst e)]) u"
by simp
moreover
have "tl (awalk_verts (awlast v (rev_path es)) [(snd e, fst e)]) = [fst e]"
by auto
ultimately
show ?case using 1 verts by (auto simp: awalk_verts_append)
next
case (Cons e es) case 2
with Cons have "awalk v (rev_path es) (snd e)"
by (auto simp: awalk_Cons_iff)
moreover
have "rev_path (e # es) = rev_path es @ [(snd e, fst e)]"
by auto
moreover
from Cons 2 have "awalk (snd e) [(snd e, fst e)] u"
by (auto simp: awalk_simps intro: arcs_symmetric)
ultimately show "awalk v (rev_path (e # es)) u"
by simp
qed
lemma (in pair_sym_digraph) awalk_rev_path[simp]:
"awalk v (rev_path p) u = awalk u p v" (is "?L = ?R")
by (metis awalk_rev_path' rev_path_rev_path)
lemma (in pair_sym_digraph) apath_rev_path[simp]:
"apath v (rev_path p) u = apath u p v"
by (auto simp: awalk_verts_rev_path apath_def)
subsection ‹Subdividing Edges›
text ‹subdivide an edge (=two associated arcs) in graph›
fun subdivide :: "'a pair_pre_digraph ⇒ 'a × 'a ⇒ 'a ⇒ 'a pair_pre_digraph" where
"subdivide G (u,v) w = ⦇
pverts = pverts G ∪ {w},
parcs = (parcs G - {(u,v),(v,u)}) ∪ {(u,w), (w,u), (w, v), (v, w)}⦈"
declare subdivide.simps[simp del]
text ‹subdivide an arc in a path›
fun sd_path :: "'a × 'a ⇒ 'a ⇒ ('a × 'a) awalk ⇒ ('a × 'a) awalk" where
"sd_path _ _ [] = []"
| "sd_path (u,v) w (e # es) = (if e = (u,v)
then [(u,w),(w,v)]
else if e = (v,u)
then [(v,w),(w,u)]
else [e]) @ sd_path (u,v) w es"
text ‹contract an arc in a path›
fun co_path :: "'a × 'a ⇒ 'a ⇒ ('a × 'a) awalk ⇒ ('a × 'a) awalk" where
"co_path _ _ [] = []"
| "co_path _ _ [e] = [e]"
| "co_path (u,v) w (e1 # e2 # es) = (if e1 = (u,w) ∧ e2 = (w,v)
then (u,v) # co_path (u,v) w es
else if e1 = (v,w) ∧ e2 = (w,u)
then (v,u) # co_path (u,v) w es
else e1 # co_path (u,v) w (e2 # es))"
lemma co_path_simps[simp]:
"⟦e1 ≠ (fst e, w); e1 ≠ (snd e,w)⟧ ⟹ co_path e w (e1 # es) = e1 # co_path e w es"
"⟦e1 = (fst e, w); e2 = (w, snd e)⟧ ⟹ co_path e w (e1 # e2 # es) = e # co_path e w es"
"⟦e1 = (snd e, w); e2 = (w, fst e)⟧
⟹ co_path e w (e1 # e2 # es) = (snd e, fst e) # co_path e w es"
"⟦e1 ≠ (fst e, w) ∨ e2 ≠ (w, snd e); e1 ≠ (snd e, w) ∨ e2 ≠ (w, fst e)⟧
⟹ co_path e w (e1 # e2 # es) = e1 # co_path e w (e2 # es)"
apply (cases es; auto)
apply (cases e; auto)
apply (cases e; auto)
apply (cases e; cases "fst e = snd e"; auto)
apply (cases e; cases "fst e = snd e"; auto)
done
lemma co_path_nonempty[simp]: "co_path e w p = [] ⟷ p = []"
by (cases e) (cases p rule: list_exhaust_NSC, auto)
declare co_path.simps(3)[simp del]
lemma verts_subdivide[simp]: "pverts (subdivide G e w) = pverts G ∪ {w}"
by (cases e) (auto simp: subdivide.simps)
lemma arcs_subdivide[simp]:
shows "parcs (subdivide G (u,v) w) = (parcs G - {(u,v),(v,u)}) ∪ {(u,w), (w,u), (w, v), (v, w)}"
by (auto simp: subdivide.simps)
lemmas subdivide_simps = verts_subdivide arcs_subdivide
lemma sd_path_induct[case_names empty pass sd sdrev]:
assumes A: "P e []"
and B: "⋀e' es. e' ≠ e ⟹ e' ≠ (snd e , fst e) ⟹ P e es ⟹ P e (e' # es)"
"⋀es. P e es ⟹ P e (e # es)"
"⋀es. fst e ≠ snd e ⟹ P e es ⟹ P e ((snd e, fst e) # es)"
shows "P e es"
by (induct es) (rule A, metis B prod.collapse)
lemma co_path_induct[case_names empty single co corev pass]:
fixes e :: "'a × 'a"
and w :: "'a"
and p :: "('a × 'a) awalk"
assumes Nil: "P e w []"
and ConsNil:"⋀e'. P e w [e']"
and ConsCons1: "⋀e1 e2 es. e1 = (fst e, w) ∧ e2 = (w, snd e) ⟹ P e w es ⟹
P e w (e1 # e2 # es)"
and ConsCons2: "⋀e1 e2 es. ¬(e1 = (fst e, w) ∧ e2 = (w, snd e)) ∧
e1 = (snd e, w) ∧ e2 = (w, fst e) ⟹ P e w es ⟹
P e w (e1 # e2 # es)"
and ConsCons3: "⋀e1 e2 es.
¬ (e1 = (fst e, w) ∧ e2 = (w, snd e)) ⟹
¬ (e1 = (snd e, w) ∧ e2 = (w, fst e)) ⟹ P e w (e2 # es) ⟹
P e w (e1 # e2 # es)"
shows "P e w p"
proof (induct p rule: length_induct)
case (1 p) then show ?case
proof (cases p rule: list_exhaust_NSC)
case (Cons_Cons e1 e2 es)
then have "P e w es" "P e w (e2 # es)"using 1 by auto
then show ?thesis unfolding Cons_Cons by (blast intro: ConsCons1 ConsCons2 ConsCons3)
qed (auto intro: Nil ConsNil)
qed
lemma co_sd_id:
assumes "(u,w) ∉ set p" "(v,w) ∉ set p"
shows "co_path (u,v) w (sd_path (u,v) w p) = p"
using assms by (induct p) auto
lemma sd_path_id:
assumes "(x,y) ∉ set p" "(y,x) ∉ set p"
shows "sd_path (x,y) w p = p"
using assms by (induct p) auto
lemma (in pair_wf_digraph) pair_wf_digraph_subdivide:
assumes props: "e ∈ parcs G" "w ∉ pverts G"
shows "pair_wf_digraph (subdivide G e w)" (is "pair_wf_digraph ?sG")
proof
obtain u v where [simp]: "e = (u,v)" by (cases e) auto
fix e' assume "e' ∈ parcs ?sG"
then show "fst e' ∈ pverts ?sG" "snd e' ∈ pverts ?sG"
using props by (auto dest: wellformed)
qed
lemma (in pair_sym_digraph) pair_sym_digraph_subdivide:
assumes props: "e ∈ parcs G" "w ∉ pverts G"
shows "pair_sym_digraph (subdivide G e w)" (is "pair_sym_digraph ?sG")
proof -
interpret sdG: pair_wf_digraph "subdivide G e w" using assms by (rule pair_wf_digraph_subdivide)
obtain u v where [simp]: "e = (u,v)" by (cases e) auto
show ?thesis
proof
have "⋀a b. (a, b) ∈ parcs (subdivide G e w) ⟹ (b, a) ∈ parcs (subdivide G e w)"
unfolding ‹e = _› arcs_subdivide
by (elim UnE, rule UnI1, rule_tac [2] UnI2) (blast intro: arcs_symmetric)+
then show "symmetric ?sG"
unfolding symmetric_def with_proj_simps by (rule symI)
qed
qed
lemma (in pair_loopfree_digraph) pair_loopfree_digraph_subdivide:
assumes props: "e ∈ parcs G" "w ∉ pverts G"
shows "pair_loopfree_digraph (subdivide G e w)" (is "pair_loopfree_digraph ?sG")
proof -
interpret sdG: pair_wf_digraph "subdivide G e w" using assms by (rule pair_wf_digraph_subdivide)
from assms show ?thesis
by unfold_locales (cases e, auto dest: wellformed no_loops)
qed
lemma (in pair_bidirected_digraph) pair_bidirected_digraph_subdivide:
assumes props: "e ∈ parcs G" "w ∉ pverts G"
shows "pair_bidirected_digraph (subdivide G e w)" (is "pair_bidirected_digraph ?sG")
proof -
interpret sdG: pair_sym_digraph "subdivide G e w" using assms by (rule pair_sym_digraph_subdivide)
interpret sdG: pair_loopfree_digraph "subdivide G e w" using assms by (rule pair_loopfree_digraph_subdivide)
show ?thesis by unfold_locales
qed
lemma (in pair_pseudo_graph) pair_pseudo_graph_subdivide:
assumes props: "e ∈ parcs G" "w ∉ pverts G"
shows "pair_pseudo_graph (subdivide G e w)" (is "pair_pseudo_graph ?sG")
proof -
interpret sdG: pair_sym_digraph "subdivide G e w" using assms by (rule pair_sym_digraph_subdivide)
obtain u v where [simp]: "e = (u,v)" by (cases e) auto
show ?thesis by unfold_locales (cases e, auto)
qed
lemma (in pair_graph) pair_graph_subdivide:
assumes "e ∈ parcs G" "w ∉ pverts G"
shows "pair_graph (subdivide G e w)" (is "pair_graph ?sG")
proof -
interpret PPG: pair_pseudo_graph "subdivide G e w"
using assms by (rule pair_pseudo_graph_subdivide)
interpret PPG: pair_loopfree_digraph "subdivide G e w"
using assms by (rule pair_loopfree_digraph_subdivide)
from assms show ?thesis by unfold_locales
qed
lemma arcs_subdivideD:
assumes "x ∈ parcs (subdivide G e w)" "fst x ≠ w" "snd x ≠ w"
shows "x ∈ parcs G"
using assms by (cases e) auto
context pair_sym_digraph begin
lemma
assumes path: "apath u p v"
assumes elems: "e ∈ parcs G" "w ∉ pverts G"
shows apath_sd_path: "pre_digraph.apath (subdivide G e w) u (sd_path e w p) v" (is ?A)
and set_awalk_verts_sd_path: "set (awalk_verts u (sd_path e w p))
⊆ set (awalk_verts u p) ∪ {w}" (is ?B)
proof -
obtain x y where e_conv: "e = (x,y)" by (cases e) auto
define sG where "sG = subdivide G e w"
interpret S: pair_sym_digraph sG
unfolding sG_def using elems by (rule pair_sym_digraph_subdivide)
have ev_sG: "S.awalk_verts = awalk_verts"
by (auto simp: fun_eq_iff pre_digraph.awalk_verts_conv)
have w_sG: "{(x,w), (y,w), (w,x), (w,y)} ⊆ parcs sG"
by (auto simp: sG_def e_conv)
from path have "S.apath u (sd_path (x,y) w p) v"
and "set (S.awalk_verts u (sd_path (x,y) w p)) ⊆ set (awalk_verts u p) ∪ {w}"
proof (induct p arbitrary: u rule: sd_path_induct)
case empty case 1
moreover have "pverts sG = pverts G ∪ {w}" by (simp add: sG_def)
ultimately show ?case by (auto simp: apath_Nil_iff S.apath_Nil_iff)
next
case empty case 2 then show ?case by simp
next
case (pass e' es)
{ case 1
then have "S.apath (snd e') (sd_path (x,y) w es) v" "u ≠ w" "fst e' = u"
"u ∉ set (S.awalk_verts (snd e') (sd_path (x,y) w es))"
using pass elems by (fastforce simp: apath_Cons_iff)+
moreover then have "e' ∈ parcs sG"
using 1 pass by (auto simp: e_conv sG_def S.apath_Cons_iff apath_Cons_iff)
ultimately show ?case using pass by (auto simp: S.apath_Cons_iff) }
note case1 = this
{ case 2 with pass 2 show ?case by (simp add: apath_Cons_iff) blast }
next
{ fix u es a b
assume A: "apath u ((a,b) # es) v"
and ab: "(a,b) = (x,y) ∨ (a,b) = (y,x)"
and hyps: "⋀u. apath u es v ⟹ S.apath u (sd_path (x, y) w es) v"
"⋀u. apath u es v ⟹ set (awalk_verts u (sd_path (x, y) w es)) ⊆ set (awalk_verts u es) ∪ {w}"
from ab A have "(x,y) ∉ set es" "(y,x) ∉ set es"
by (auto simp: apath_Cons_iff dest!: awalkI_apath dest: awalk_verts_arc1 awalk_verts_arc2)
then have ev_sd: "set (S.awalk_verts b (sd_path (x,y) w es)) = set (awalk_verts b es)"
by (simp add: sd_path_id)
from A ab have [simp]: "x ≠ y"
by (simp add: apath_Cons_iff) (metis awalkI_apath awalk_verts_non_Nil awhd_of_awalk hd_in_set)
from A have "S.apath b (sd_path (x,y) w es) v" "u = a" "u ≠ w"
using ab hyps elems by (auto simp: apath_Cons_iff wellformed')
moreover
then have "S.awalk u (sd_path (x, y) w ((a, b) # es)) v "
using ab w_sG by (auto simp: S.apath_def S.awalk_simps S.wellformed')
then have "u ∉ set (S.awalk_verts w ((w,b) # sd_path (x,y) w es))"
using ab ‹u ≠ w› ev_sd A by (auto simp: apath_Cons_iff S.awalk_def)
moreover
have "w ∉ set (awalk_verts b (sd_path (x, y) w es))"
using ab ev_sd A elems by (auto simp: awalk_Cons_iff apath_def)
ultimately
have path: "S.apath u (sd_path (x, y) w ((a, b) # es)) v "
using ab hyps w_sG ‹u = a› by (auto simp: S.apath_Cons_iff ) }
note path = this
{ case (sd es)
{ case 1 with sd show ?case by (intro path) auto }
{ case 2 show ?case using 2 sd
by (auto simp: apath_Cons_iff) } }
{ case (sdrev es)
{ case 1 with sdrev show ?case by (intro path) auto }
{ case 2 show ?case using 2 sdrev
by (auto simp: apath_Cons_iff) } }
qed
then show ?A ?B unfolding sG_def e_conv .
qed
lemma
assumes elems: "e ∈ parcs G" "w ∉ pverts G" "u ∈ pverts G" "v ∈ pverts G"
assumes path: "pre_digraph.apath (subdivide G e w) u p v"
shows apath_co_path: "apath u (co_path e w p) v" (is ?thesis_path)
and set_awalk_verts_co_path: "set (awalk_verts u (co_path e w p)) = set (awalk_verts u p) - {w}" (is ?thesis_set)
proof -
obtain x y where e_conv: "e = (x,y)" by (cases e) auto
interpret S: pair_sym_digraph "subdivide G e w"
using elems(1,2) by (rule pair_sym_digraph_subdivide)
have e_w: "fst e ≠ w" "snd e ≠ w" using elems by auto
have "S.apath u p v" "u ≠ w" using elems path by auto
then have co_path: "apath u (co_path e w p) v
∧ set (awalk_verts u (co_path e w p)) = set (awalk_verts u p) - {w}"
proof (induction p arbitrary: u rule: co_path_induct)
case empty with elems show ?case
by (simp add: apath_Nil_iff S.apath_Nil_iff)
next
case (single e') with elems show ?case
by (auto simp: apath_Cons_iff S.apath_Cons_iff apath_Nil_iff S.apath_Nil_iff
dest: arcs_subdivideD)
next
case (co e1 e2 es)
then have "apath u (co_path e w (e1 # e2 # es)) v" using co e_w elems
by (auto simp: apath_Cons_iff S.apath_Cons_iff)
moreover
have "set (awalk_verts u (co_path e w (e1 # e2 # es))) = set (awalk_verts u (e1 # e2 # es)) - {w}"
using co e_w by (auto simp: apath_Cons_iff S.apath_Cons_iff)
ultimately
show ?case by fast
next
case (corev e1 e2 es)
have "apath u (co_path e w (e1 # e2 # es)) v" using corev(1-3) e_w(1) elems(1)
by (auto simp: apath_Cons_iff S.apath_Cons_iff intro: arcs_symmetric)
moreover
have "set (awalk_verts u (co_path e w (e1 # e2 # es))) = set (awalk_verts u (e1 # e2 # es)) - {w}"
using corev e_w by (auto simp: apath_Cons_iff S.apath_Cons_iff)
ultimately
show ?case by fast
next
case (pass e1 e2 es)
have "fst e1 ≠ w" using elems pass.prems by (auto simp: S.apath_Cons_iff)
have "snd e1 ≠ w"
proof
assume "snd e1 = w"
then have "e1 ∉ parcs G" using elems by auto
then have "e1 ∈ parcs (subdivide G e w) - parcs G"
using pass by (auto simp: S.apath_Cons_iff)
then have "e1 = (x,w) ∨ e1 = (y,w)"
using ‹fst e1 ≠ w› e_w by (auto simp add: e_conv)
moreover
have "fst e2 = w" using ‹snd e1 = w› pass.prems by (auto simp: S.apath_Cons_iff)
then have "e2 ∉ parcs G" using elems by auto
then have "e2 ∈ parcs (subdivide G e w) - parcs G"
using pass by (auto simp: S.apath_Cons_iff)
then have "e2 = (w,x) ∨ e2 = (w,y)"
using ‹fst e2 = w› e_w by (cases e2) (auto simp add: e_conv)
ultimately
have "e1 = (x,w) ∧ e2 = (w,x) ∨ e1 = (y,w) ∧ e2 = (w,y)"
using pass.hyps[simplified e_conv] by auto
then show False
using pass.prems by (cases es) (auto simp: S.apath_Cons_iff)
qed
then have "e1 ∈ parcs G"
using ‹fst e1 ≠ w› pass.prems by (auto simp: S.apath_Cons_iff dest: arcs_subdivideD)
have ih: "apath (snd e1) (co_path e w (e2 # es)) v ∧ set (awalk_verts (snd e1) (co_path e w (e2 # es))) = set (awalk_verts (snd e1) (e2 # es)) - {w}"
using pass.prems ‹snd e1 ≠ w› by (intro pass.IH) (auto simp: apath_Cons_iff S.apath_Cons_iff)
then have "fst e1 ∉ set (awalk_verts (snd e1) (co_path e w (e2 # es)))" "fst e1 = u"
using pass.prems by (clarsimp simp: S.apath_Cons_iff)+
then have "apath u (co_path e w (e1 # e2 # es)) v"
using ih pass ‹e1 ∈ parcs G› by (auto simp: apath_Cons_iff S.apath_Cons_iff)[]
moreover
have "set (awalk_verts u (co_path e w (e1 # e2 # es))) = set (awalk_verts u (e1 # e2 # es)) - {w}"
using pass.hyps ih ‹fst e1 ≠ w› by auto
ultimately show ?case by fast
qed
then show ?thesis_set ?thesis_path by blast+
qed
end
subsection ‹Bidirected Graphs›
definition (in -) swap_in :: "('a × 'a) set ⇒ 'a × 'a ⇒ 'a × 'a" where
"swap_in S x = (if x ∈ S then prod.swap x else x)"
lemma bidirected_digraph_rev_conv_pair:
assumes "bidirected_digraph (with_proj G) rev_G"
shows "rev_G = swap_in (parcs G)"
proof -
interpret bidirected_digraph G rev_G by fact
have "⋀a b. (a, b) ∈ parcs G ⟹ rev_G (a, b) = (b, a)"
using tail_arev[simplified with_proj_simps] head_arev[simplified with_proj_simps]
by (metis fst_conv prod.collapse snd_conv)
then show ?thesis by (auto simp: swap_in_def fun_eq_iff arev_eq)
qed
lemma (in pair_bidirected_digraph) bidirected_digraph:
"bidirected_digraph (with_proj G) (swap_in (parcs G))"
using no_loops' arcs_symmetric
by unfold_locales (auto simp: swap_in_def)
lemma pair_bidirected_digraphI_bidirected_digraph:
assumes "bidirected_digraph (with_proj G) (swap_in (parcs G))"
shows "pair_bidirected_digraph G"
proof -
interpret bidirected_digraph "with_proj G" "swap_in (parcs G)" by fact
{
fix a assume "a ∈ parcs G" then have "fst a ≠ snd a"
using arev_neq[of a] bidirected_digraph_rev_conv_pair[OF assms(1)]
by (cases a) (auto simp: swap_in_def)
}
then show ?thesis
using tail_in_verts head_in_verts by unfold_locales auto
qed
end