diff --git a/Webinterface/doc/README.md b/Webinterface/doc/README.md
new file mode 100644
index 000000000..2742210fa
--- /dev/null
+++ b/Webinterface/doc/README.md
@@ -0,0 +1,40 @@
+# SMT-proof visualisation
+Proof visualisation for given SMT-Solver
+
+Manual:
+
+When executing the visualize_proof() function by pushing the "Start SMT proof" button the proof text
+that was put or copied into the the responding field will be split through the smt_parser() function.
+
+In addition the class Node is created whose objects later contain following information:
+unique IDs, arrays containing the children, ID of the parent node, complete text part of the node or leaf,
+the filtered literals, pivots and resolved intermediate results for nodes that have children.
+
+The smt_parser() function differentiates between inner nodes, starting with "(! (@res" or "(@res" and leafs,
+starting with "(! (@clause", "(@clause)", "(! (@lemma", or "(@lemma".
+Both will then be edited again with separate parsers (parseNode and parseLeaf), turned into a object of
+the Node class and receive following information:
+- unique IDs (starting at "0")
+- an array with the responding kids (if present)
+- ID of the parent node (root node keeps the parent ID "-1")
+- a boolean "is_leaf" which will be set to "true" if it is a leaf and has no children
+- a set with literals (sets being used so there are no duplicates)
+- the pivot (if present)
+and inner nodes will also receives a set of intermediate results of the resolved children.
+
+Therefore the literals will be extracted with the extract_literals() function and then saved in node_literals.
+This function calls the extract_literals_lemma() function on leafs containing the string "lemma" and the
+extract_literals_clause() function on those containing the string "clause".
+During this process the literals with parenthesis as well as those without are being considered.
+
+If the string ":pivot" is also contained after these steps, the extract_pivot() function will be
+executed to extract the corresponding pivot.
+
+For the inner nodes these steps will be executed recursively and the compute_literals_res_node() function will
+be executed which calculates and returns the resolved result of all children and saves it in node_literals.
+In this function the compute_res() function always computes a resolve step from the children and saves
+it in these children nodes as intermediate_result.
+
+When resolving, the given pivot will be checked in normal and negated version.
+
+In the end the proof tree results in an empty set.
diff --git a/Webinterface/src/main/visualizer/smt-beweis-kopie.txt b/Webinterface/src/main/visualizer/smt-beweis-kopie.txt
new file mode 100644
index 000000000..cf14f3f74
--- /dev/null
+++ b/Webinterface/src/main/visualizer/smt-beweis-kopie.txt
@@ -0,0 +1,55 @@
+//// Eingabeskript für SMTInterpol
+
+(set-option :print-success false)
+(set-option :produce-interpolants true)
+(set-info :status unsat)
+(set-logic QF_UFLIA)
+(declare-fun f (Int) Int)
+(declare-fun x () Int)
+(declare-fun y () Int)
+(assert (and (= x (f x)) (= x y) (= (f y) (+ x 1))))
+(check-sat)
+(get-proof)
+(exit)
+
+//// Beweis mit Umschreibschritten der Eingabeformel
+
+(@res (@res (@lemma (! (or (not (! (= (f y) (+ x 1)) :quotedCC)) (not (! (= x (f x)) :quotedCC)) (not (! (= (f y) (f x)) :quotedCC))) :CC ((! (= (+ x 1) x) :quotedCC) :subpath ((+ x 1) (f y) (f x) x)))) (! (@lemma (! (or (! (= (f y) (f x)) :quotedCC) (not (! (= x y) :quotedCC))) :CC ((! (= (f y) (f x)) :quotedCC) :subpath ((f y) (f x))))) :pivot (! (= (f y) (f x)) :quotedCC))) (! (@clause (@eq (@eq (@split (! (@eq (@asserted (and (= x (f x)) (= x y) (= (f y) (+ x 1)))) (@rewrite (! (= (and (= x (f x)) (= x y) (= (f y) (+ x 1))) (not (or (not (= x (f x))) (not (= x y)) (not (= (f y) (+ x 1)))))) :andToOr))) :notOr) (not (not (= (f y) (+ x 1))))) (@rewrite (! (= (not (not (= (f y) (+ x 1)))) (= (f y) (+ x 1))) :notSimp))) (@rewrite (! (= (= (f y) (+ x 1)) (! (= (f y) (+ x 1)) :quotedCC)) :intern))) (! (! (= (f y) (+ x 1)) :quotedCC) :input)) :pivot (! (= (f y) (+ x 1)) :quotedCC)) (! (@clause (@eq (@eq (@split (! (@eq (@asserted (and (= x (f x)) (= x y) (= (f y) (+ x 1)))) (@rewrite (! (= (and (= x (f x)) (= x y) (= (f y) (+ x 1))) (not (or (not (= x (f x))) (not (= x y)) (not (= (f y) (+ x 1)))))) :andToOr))) :notOr) (not (not (= x y)))) (@rewrite (! (= (not (not (= x y))) (= x y)) :notSimp))) (@rewrite (! (= (= x y) (! (= x y) :quotedCC)) :intern))) (! (! (= x y) :quotedCC) :input)) :pivot (! (= x y) :quotedCC)) (! (@clause (@eq (@eq (@split (! (@eq (@asserted (and (= x (f x)) (= x y) (= (f y) (+ x 1)))) (@rewrite (! (= (and (= x (f x)) (= x y) (= (f y) (+ x 1))) (not (or (not (= x (f x))) (not (= x y)) (not (= (f y) (+ x 1)))))) :andToOr))) :notOr) (not (not (= x (f x))))) (@rewrite (! (= (not (not (= x (f x)))) (= x (f x))) :notSimp))) (@rewrite (! (= (= x (f x)) (! (= x (f x)) :quotedCC)) :intern))) (! (! (= x (f x)) :quotedCC) :input)) :pivot (! (= x (f x)) :quotedCC)))
+
+//// Resolutionsbeweis (ohne Umschreibschritte)
+
+(@res (@res (@lemma (! (or (not (! (= (f y) (+ x 1)) :quotedCC)) (not (! (= x (f x)) :quotedCC)) (not (! (= (f y) (f x)) :quotedCC))) :CC ((! (= (+ x 1) x) :quotedCC) :subpath ((+ x 1) (f y) (f x) x)))) (! (@lemma (! (or (! (= (f y) (f x)) :quotedCC) (not (! (= x y) :quotedCC))) :CC ((! (= (f y) (f x)) :quotedCC) :subpath ((f y) (f x))))) :pivot (! (= (f y) (f x)) :quotedCC))) (! (@clause (@asserted (! (= (f y) (+ x 1)) :quotedCC)) (! (! (= (f y) (+ x 1)) :quotedCC) :input)) :pivot (! (= (f y) (+ x 1)) :quotedCC)) (! (@clause (@asserted (! (= x y) :quotedCC)) (! (! (= x y) :quotedCC) :input)) :pivot (! (= x y) :quotedCC)) (! (@clause (@asserted (! (= x (f x)) :quotedCC)) (! (! (= x (f x)) :quotedCC) :input)) :pivot (! (= x (f x)) :quotedCC)))
+
+//// Beweis lesbarer formatiert mit allen Klauseln
+
+(@res
+ (@res
+ (@lemma (! (or (not (! (= (f y) (+ x 1)) :quotedCC)) (not (! (= x (f x)) :quotedCC)) (not (! (= (f y) (f x)) :quotedCC))) :CC ((! (= (+ x 1) x) :quotedCC) :subpath ((+ x 1) (f y) (f x) x))))
+ // != f(y)=x+1 \/ != x=f(x) \/ != f(x)=f(y)
+
+ (! (@lemma (! (or (! (= (f y) (f x)) :quotedCC) (not (! (= x y) :quotedCC))) :CC ((! (= (f y) (f x)) :quotedCC) :subpath ((f y) (f x)))))
+ // f(x)=f(y) \/ != x=y
+ :pivot (! (= (f y) (f x)) :quotedCC)))
+ // != f(y)=x+1 \/ != x=f(x) \/ != x=y
+
+ (! (@clause (@asserted (! (= (f y) (+ x 1)) :quotedCC)) (! (! (= (f y) (+ x 1)) :quotedCC) :input))
+ // f(y)=x+1
+ :pivot (! (= (f y) (+ x 1)) :quotedCC))
+ // != x=f(x) \/ != x=y
+
+ (! (@clause (@asserted (! (= x y) :quotedCC)) (! (! (= x y) :quotedCC) :input))
+ // x=y
+ :pivot (! (= x y) :quotedCC))
+ // != x=f(x)
+
+ (! (@clause (@asserted (! (= x (f x)) :quotedCC)) (! (! (= x (f x)) :quotedCC) :input))
+ // x=f(x)
+ :pivot (! (= x (f x)) :quotedCC)))
+ // {}
+
+
+/// Resolutionsregel
+
+C_1 \/ ~l C_2 \/ l
+--------------------
+ C_1 \/ C_2
diff --git a/Webinterface/src/main/visualizer/smtinterpol-beweise-02.txt b/Webinterface/src/main/visualizer/smtinterpol-beweise-02.txt
new file mode 100644
index 000000000..bc49fead8
--- /dev/null
+++ b/Webinterface/src/main/visualizer/smtinterpol-beweise-02.txt
@@ -0,0 +1,146 @@
+Trivialer Beweis - ohne "@res"!
+
+(@clause (@asserted false) (! false :input))
+
+--------------------------------------------------------------------------------
+
+Beweis mit Literalen ohne ":quoted"
+
+Proof text:
+
+(@res (@clause (@asserted (not p)) (! (not p) :input)) (! (@clause (@asserted p) (! p :input)) :pivot p))
+
+Structured:
+
+(@res
+ (@clause (@asserted (not p)) (! (not p) :input))
+ (! (@clause (@asserted p) (! p :input))
+ :pivot p))
+
+--------------------------------------------------------------------------------
+
+Beweis mit weiterer Art von Literalen und weiterer Art von Lemmas (nicht ":CC", aber immer gleicher Aufbau)
+
+Proof text:
+
+(@res (@clause (@asserted (! (<= (+ b (- a) 1) 0) :quotedLA)) (! (! (<= (+ b (- a) 1) 0) :quotedLA) :input)) (! (@res (@lemma (! (or (! (<= (+ b (- a)) 0) :quotedLA) (not (! (<= (+ b (- a) 1) 0) :quotedLA))) :LA ((- 1) 1))) (! (@clause (@asserted (not (! (<= (+ b (- a)) 0) :quotedLA))) (! (not (! (<= (+ b (- a)) 0) :quotedLA)) :input)) :pivot (not (! (<= (+ b (- a)) 0) :quotedLA)))) :pivot (not (! (<= (+ b (- a) 1) 0) :quotedLA))))
+
+Structured:
+
+(@res
+ (@clause (@asserted (! (<= (+ b (- a) 1) 0) :quotedLA)) (! (! (<= (+ b (- a) 1) 0) :quotedLA) :input))
+ (! (@res
+ (@lemma (! (or (! (<= (+ b (- a)) 0) :quotedLA) (not (! (<= (+ b (- a) 1) 0) :quotedLA))) :LA ((- 1) 1)))
+ (! (@clause (@asserted (not (! (<= (+ b (- a)) 0) :quotedLA))) (! (not (! (<= (+ b (- a)) 0) :quotedLA)) :input))
+ :pivot (not (! (<= (+ b (- a)) 0) :quotedLA))))
+ :pivot (not (! (<= (+ b (- a) 1) 0) :quotedLA))))
+
+--------------------------------------------------------------------------------
+
+Beweis mit "@clause" mit "or", sowie mit tiefer verschachtelten "@res"
+
+Proof text:
+
+(@res (@clause (@asserted (or (not (! (= a c) :quotedCC)) p)) (! (or (not (! (= a c) :quotedCC)) p) :input right)) (! (@res (@lemma (! (or (! (= a c) :quotedCC) (not (! (= a b) :quotedCC)) (not (! (= b c) :quotedCC))) :CC ((! (= a c) :quotedCC) :subpath (a b c)))) (! (@clause (@asserted (! (= b c) :quotedCC)) (! (! (= b c) :quotedCC) :input right)) :pivot (! (= b c) :quotedCC)) (! (@clause (@asserted (! (= a b) :quotedCC)) (! (! (= a b) :quotedCC) :input left)) :pivot (! (= a b) :quotedCC))) :pivot (! (= a c) :quotedCC)) (! (@res (@clause (@asserted (or (not (! (= a c) :quotedCC)) (not p))) (! (or (not (! (= a c) :quotedCC)) (not p)) :input left)) (! (@res (@lemma (! (or (! (= a c) :quotedCC) (not (! (= a b) :quotedCC)) (not (! (= b c) :quotedCC))) :CC ((! (= a c) :quotedCC) :subpath (a b c)))) (! (@clause (@asserted (! (= b c) :quotedCC)) (! (! (= b c) :quotedCC) :input right)) :pivot (! (= b c) :quotedCC)) (! (@clause (@asserted (! (= a b) :quotedCC)) (! (! (= a b) :quotedCC) :input left)) :pivot (! (= a b) :quotedCC))) :pivot (! (= a c) :quotedCC))) :pivot (not p)))
+
+Structured:
+
+(@res
+ (@clause (@asserted (or (not (! (= a c) :quotedCC)) p)) (! (or (not (! (= a c) :quotedCC)) p) :input right))
+ (! (@res
+ (@lemma (! (or (! (= a c) :quotedCC) (not (! (= a b) :quotedCC)) (not (! (= b c) :quotedCC))) :CC ((! (= a c) :quotedCC) :subpath (a b c))))
+ (! (@clause (@asserted (! (= b c) :quotedCC)) (! (! (= b c) :quotedCC) :input right))
+ :pivot (! (= b c) :quotedCC))
+ (! (@clause (@asserted (! (= a b) :quotedCC)) (! (! (= a b) :quotedCC) :input left))
+ :pivot (! (= a b) :quotedCC)))
+ :pivot (! (= a c) :quotedCC))
+ (! (@res
+ (@clause (@asserted (or (not (! (= a c) :quotedCC)) (not p))) (! (or (not (! (= a c) :quotedCC)) (not p)) :input left))
+ (! (@res
+ (@lemma (! (or (! (= a c) :quotedCC) (not (! (= a b) :quotedCC)) (not (! (= b c) :quotedCC))) :CC ((! (= a c) :quotedCC) :subpath (a b c))))
+ (! (@clause (@asserted (! (= b c) :quotedCC)) (! (! (= b c) :quotedCC) :input right))
+ :pivot (! (= b c) :quotedCC))
+ (! (@clause (@asserted (! (= a b) :quotedCC)) (! (! (= a b) :quotedCC) :input left))
+ :pivot (! (= a b) :quotedCC)))
+ :pivot (! (= a c) :quotedCC)))
+ :pivot (not p)))
+
+--------------------------------------------------------------------------------
+
+Langer Beweis (auch ausführliches Format)
+
+Proof text:
+
+(@res (@lemma (! (or (! (= (select a i) (select b j)) :quotedCC) (not (! (= i j) :quotedCC)) (not (! (= b (store s2 k3 v3)) :quotedCC)) (! (= j k3) :quotedCC) (! (= j k2) :quotedCC) (not (! (= s1 (store s2 k2 v2)) :quotedCC)) (! (= j k1) :quotedCC) (not (! (= a (store s1 k1 v1)) :quotedCC))) :read-over-weakeq ((! (= (select a i) (select b j)) :quotedCC) :weakpath (j (b (store s2 k3 v3) s2 (store s2 k2 v2) s1 (store s1 k1 v1) a))))) (! (@res (@lemma (! (or (! (= i k1) :quotedCC) (not (! (= i j) :quotedCC)) (not (! (= j k1) :quotedCC))) :CC ((! (= i k1) :quotedCC) :subpath (i j k1)))) (! (@clause (@mp (@split (! (@mp (@asserted (! (and (not (= i k1)) (and (not (= i k2)) (= s1 (store s2 k2 v2)))) :named A)) (@trans (@rewrite (! (= (! (and (not (= i k1)) (and (not (= i k2)) (= s1 (store s2 k2 v2)))) :named A) (and (not (= i k1)) (and (not (= i k2)) (= s1 (store s2 k2 v2))))) :strip)) (@cong (@trans (@cong (@refl (and (not (= i k1)) (and (not (= i k2)) (= s1 (store s2 k2 v2))))) (@cong (@rewrite (! (= (and (not (= i k2)) (= s1 (store s2 k2 v2))) (not (or (not (not (= i k2))) (not (= s1 (store s2 k2 v2)))))) :andToOr)) (@cong (@refl (or (not (not (= i k2))) (not (= s1 (store s2 k2 v2))))) (@rewrite (! (= (not (not (= i k2))) (= i k2)) :notSimp))))) (@rewrite (! (= (and (not (= i k1)) (not (or (= i k2) (not (= s1 (store s2 k2 v2)))))) (not (or (not (not (= i k1))) (not (not (or (= i k2) (not (= s1 (store s2 k2 v2))))))))) :andToOr))) (@cong (@refl (or (not (not (= i k1))) (not (not (or (= i k2) (not (= s1 (store s2 k2 v2)))))))) (@rewrite (! (= (not (not (= i k1))) (= i k1)) :notSimp)) (@rewrite (! (= (not (not (or (= i k2) (not (= s1 (store s2 k2 v2)))))) (or (= i k2) (not (= s1 (store s2 k2 v2))))) :notSimp)))))) :notOr) (not (= i k1))) (@cong (@refl (not (= i k1))) (@rewrite (! (= (= i k1) (! (= i k1) :quotedCC)) :intern)))) (! (not (! (= i k1) :quotedCC)) :input A)) :pivot (not (! (= i k1) :quotedCC))) (! (@clause (@mp (@mp (@split (! (@split (! (@split (! (@split (! (@mp (@asserted (! (and (not (= i k3)) (and (= a (store s1 k1 v1)) (and (= b (store s2 k3 v3)) (and (= i j) (not (= (select a i) (select b j))))))) :named B)) (@trans (@rewrite (! (= (! (and (not (= i k3)) (and (= a (store s1 k1 v1)) (and (= b (store s2 k3 v3)) (and (= i j) (not (= (select a i) (select b j))))))) :named B) (and (not (= i k3)) (and (= a (store s1 k1 v1)) (and (= b (store s2 k3 v3)) (and (= i j) (not (= (select a i) (select b j)))))))) :strip)) (@cong (@trans (@cong (@refl (and (not (= i k3)) (and (= a (store s1 k1 v1)) (and (= b (store s2 k3 v3)) (and (= i j) (not (= (select a i) (select b j)))))))) (@cong (@trans (@cong (@refl (and (= a (store s1 k1 v1)) (and (= b (store s2 k3 v3)) (and (= i j) (not (= (select a i) (select b j))))))) (@cong (@trans (@cong (@refl (and (= b (store s2 k3 v3)) (and (= i j) (not (= (select a i) (select b j)))))) (@cong (@rewrite (! (= (and (= i j) (not (= (select a i) (select b j)))) (not (or (not (= i j)) (not (not (= (select a i) (select b j))))))) :andToOr)) (@cong (@refl (or (not (= i j)) (not (not (= (select a i) (select b j)))))) (@rewrite (! (= (not (not (= (select a i) (select b j)))) (= (select a i) (select b j))) :notSimp))))) (@rewrite (! (= (and (= b (store s2 k3 v3)) (not (or (not (= i j)) (= (select a i) (select b j))))) (not (or (not (= b (store s2 k3 v3))) (not (not (or (not (= i j)) (= (select a i) (select b j)))))))) :andToOr))) (@cong (@refl (or (not (= b (store s2 k3 v3))) (not (not (or (not (= i j)) (= (select a i) (select b j))))))) (@rewrite (! (= (not (not (or (not (= i j)) (= (select a i) (select b j))))) (or (not (= i j)) (= (select a i) (select b j)))) :notSimp))))) (@rewrite (! (= (and (= a (store s1 k1 v1)) (not (or (not (= b (store s2 k3 v3))) (or (not (= i j)) (= (select a i) (select b j)))))) (not (or (not (= a (store s1 k1 v1))) (not (not (or (not (= b (store s2 k3 v3))) (or (not (= i j)) (= (select a i) (select b j))))))))) :andToOr))) (@cong (@refl (or (not (= a (store s1 k1 v1))) (not (not (or (not (= b (store s2 k3 v3))) (or (not (= i j)) (= (select a i) (select b j)))))))) (@rewrite (! (= (not (not (or (not (= b (store s2 k3 v3))) (or (not (= i j)) (= (select a i) (select b j)))))) (or (not (= b (store s2 k3 v3))) (or (not (= i j)) (= (select a i) (select b j))))) :notSimp))))) (@rewrite (! (= (and (not (= i k3)) (not (or (not (= a (store s1 k1 v1))) (or (not (= b (store s2 k3 v3))) (or (not (= i j)) (= (select a i) (select b j))))))) (not (or (not (not (= i k3))) (not (not (or (not (= a (store s1 k1 v1))) (or (not (= b (store s2 k3 v3))) (or (not (= i j)) (= (select a i) (select b j)))))))))) :andToOr))) (@cong (@refl (or (not (not (= i k3))) (not (not (or (not (= a (store s1 k1 v1))) (or (not (= b (store s2 k3 v3))) (or (not (= i j)) (= (select a i) (select b j))))))))) (@rewrite (! (= (not (not (= i k3))) (= i k3)) :notSimp)) (@rewrite (! (= (not (not (or (not (= a (store s1 k1 v1))) (or (not (= b (store s2 k3 v3))) (or (not (= i j)) (= (select a i) (select b j))))))) (or (not (= a (store s1 k1 v1))) (or (not (= b (store s2 k3 v3))) (or (not (= i j)) (= (select a i) (select b j)))))) :notSimp)))))) :notOr) (not (or (not (= a (store s1 k1 v1))) (or (not (= b (store s2 k3 v3))) (or (not (= i j)) (= (select a i) (select b j))))))) :notOr) (not (or (not (= b (store s2 k3 v3))) (or (not (= i j)) (= (select a i) (select b j)))))) :notOr) (not (or (not (= i j)) (= (select a i) (select b j))))) :notOr) (not (not (= i j)))) (@rewrite (! (= (not (not (= i j))) (= i j)) :notSimp))) (@rewrite (! (= (= i j) (! (= i j) :quotedCC)) :intern))) (! (! (= i j) :quotedCC) :input B)) :pivot (! (= i j) :quotedCC))) :pivot (not (! (= j k1) :quotedCC))) (! (@clause (@mp (@mp (@split (! (@split (! (@split (! (@mp (@asserted (! (and (not (= i k3)) (and (= a (store s1 k1 v1)) (and (= b (store s2 k3 v3)) (and (= i j) (not (= (select a i) (select b j))))))) :named B)) (@trans (@rewrite (! (= (! (and (not (= i k3)) (and (= a (store s1 k1 v1)) (and (= b (store s2 k3 v3)) (and (= i j) (not (= (select a i) (select b j))))))) :named B) (and (not (= i k3)) (and (= a (store s1 k1 v1)) (and (= b (store s2 k3 v3)) (and (= i j) (not (= (select a i) (select b j)))))))) :strip)) (@cong (@trans (@cong (@refl (and (not (= i k3)) (and (= a (store s1 k1 v1)) (and (= b (store s2 k3 v3)) (and (= i j) (not (= (select a i) (select b j)))))))) (@cong (@trans (@cong (@refl (and (= a (store s1 k1 v1)) (and (= b (store s2 k3 v3)) (and (= i j) (not (= (select a i) (select b j))))))) (@cong (@trans (@cong (@refl (and (= b (store s2 k3 v3)) (and (= i j) (not (= (select a i) (select b j)))))) (@cong (@rewrite (! (= (and (= i j) (not (= (select a i) (select b j)))) (not (or (not (= i j)) (not (not (= (select a i) (select b j))))))) :andToOr)) (@cong (@refl (or (not (= i j)) (not (not (= (select a i) (select b j)))))) (@rewrite (! (= (not (not (= (select a i) (select b j)))) (= (select a i) (select b j))) :notSimp))))) (@rewrite (! (= (and (= b (store s2 k3 v3)) (not (or (not (= i j)) (= (select a i) (select b j))))) (not (or (not (= b (store s2 k3 v3))) (not (not (or (not (= i j)) (= (select a i) (select b j)))))))) :andToOr))) (@cong (@refl (or (not (= b (store s2 k3 v3))) (not (not (or (not (= i j)) (= (select a i) (select b j))))))) (@rewrite (! (= (not (not (or (not (= i j)) (= (select a i) (select b j))))) (or (not (= i j)) (= (select a i) (select b j)))) :notSimp))))) (@rewrite (! (= (and (= a (store s1 k1 v1)) (not (or (not (= b (store s2 k3 v3))) (or (not (= i j)) (= (select a i) (select b j)))))) (not (or (not (= a (store s1 k1 v1))) (not (not (or (not (= b (store s2 k3 v3))) (or (not (= i j)) (= (select a i) (select b j))))))))) :andToOr))) (@cong (@refl (or (not (= a (store s1 k1 v1))) (not (not (or (not (= b (store s2 k3 v3))) (or (not (= i j)) (= (select a i) (select b j)))))))) (@rewrite (! (= (not (not (or (not (= b (store s2 k3 v3))) (or (not (= i j)) (= (select a i) (select b j)))))) (or (not (= b (store s2 k3 v3))) (or (not (= i j)) (= (select a i) (select b j))))) :notSimp))))) (@rewrite (! (= (and (not (= i k3)) (not (or (not (= a (store s1 k1 v1))) (or (not (= b (store s2 k3 v3))) (or (not (= i j)) (= (select a i) (select b j))))))) (not (or (not (not (= i k3))) (not (not (or (not (= a (store s1 k1 v1))) (or (not (= b (store s2 k3 v3))) (or (not (= i j)) (= (select a i) (select b j)))))))))) :andToOr))) (@cong (@refl (or (not (not (= i k3))) (not (not (or (not (= a (store s1 k1 v1))) (or (not (= b (store s2 k3 v3))) (or (not (= i j)) (= (select a i) (select b j))))))))) (@rewrite (! (= (not (not (= i k3))) (= i k3)) :notSimp)) (@rewrite (! 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(= (and (= a (store s1 k1 v1)) (not (or (not (= b (store s2 k3 v3))) (or (not (= i j)) (= (select a i) (select b j)))))) (not (or (not (= a (store s1 k1 v1))) (not (not (or (not (= b (store s2 k3 v3))) (or (not (= i j)) (= (select a i) (select b j))))))))) :andToOr))) (@cong (@refl (or (not (= a (store s1 k1 v1))) (not (not (or (not (= b (store s2 k3 v3))) (or (not (= i j)) (= (select a i) (select b j)))))))) (@rewrite (! (= (not (not (or (not (= b (store s2 k3 v3))) (or (not (= i j)) (= (select a i) (select b j)))))) (or (not (= b (store s2 k3 v3))) (or (not (= i j)) (= (select a i) (select b j))))) :notSimp))))) (@rewrite (! (= (and (not (= i k3)) (not (or (not (= a (store s1 k1 v1))) (or (not (= b (store s2 k3 v3))) (or (not (= i j)) (= (select a i) (select b j))))))) (not (or (not (not (= i k3))) (not (not (or (not (= a (store s1 k1 v1))) (or (not (= b (store s2 k3 v3))) (or (not (= i j)) (= (select a i) (select b j)))))))))) :andToOr))) (@cong (@refl (or (not (not (= i k3))) (not (not (or (not (= a (store s1 k1 v1))) (or (not (= b (store s2 k3 v3))) (or (not (= i j)) (= (select a i) (select b j))))))))) (@rewrite (! (= (not (not (= i k3))) (= i k3)) :notSimp)) (@rewrite (! (= (not (not (or (not (= a (store s1 k1 v1))) (or (not (= b (store s2 k3 v3))) (or (not (= i j)) (= (select a i) (select b j))))))) (or (not (= a (store s1 k1 v1))) (or (not (= b (store s2 k3 v3))) (or (not (= i j)) (= (select a i) (select b j)))))) :notSimp)))))) :notOr) (not (= i k3))) (@cong (@refl (not (= i k3))) (@rewrite (! (= (= i k3) (! (= i k3) :quotedCC)) :intern)))) (! (not (! (= i k3) :quotedCC)) :input B)) :pivot (not (! (= i k3) :quotedCC))) (! (@clause (@mp (@mp (@split (! (@split (! (@split (! (@split (! (@mp (@asserted (! (and (not (= i k3)) (and (= a (store s1 k1 v1)) (and (= b (store s2 k3 v3)) (and (= i j) (not (= (select a i) (select b j))))))) :named B)) (@trans (@rewrite (! (= (! (and (not (= i k3)) (and (= a (store s1 k1 v1)) (and (= b (store s2 k3 v3)) (and (= i j) (not (= (select a i) (select b j))))))) :named B) (and (not (= i k3)) (and (= a (store s1 k1 v1)) (and (= b (store s2 k3 v3)) (and (= i j) (not (= (select a i) (select b j)))))))) :strip)) (@cong (@trans (@cong (@refl (and (not (= i k3)) (and (= a (store s1 k1 v1)) (and (= b (store s2 k3 v3)) (and (= i j) (not (= (select a i) (select b j)))))))) (@cong (@trans (@cong (@refl (and (= a (store s1 k1 v1)) (and (= b (store s2 k3 v3)) (and (= i j) (not (= (select a i) (select b j))))))) (@cong (@trans (@cong (@refl (and (= b (store s2 k3 v3)) (and (= i j) (not (= (select a i) (select b j)))))) (@cong (@rewrite (! (= (and (= i j) (not (= (select a i) (select b j)))) (not (or (not (= i j)) (not (not (= (select a i) (select b j))))))) :andToOr)) (@cong (@refl (or (not (= i j)) (not (not (= (select a i) (select b j)))))) (@rewrite (! (= (not (not (= (select a i) (select b j)))) (= (select a i) (select b j))) :notSimp))))) (@rewrite (! (= (and (= b (store s2 k3 v3)) (not (or (not (= i j)) (= (select a i) (select b j))))) (not (or (not (= b (store s2 k3 v3))) (not (not (or (not (= i j)) (= (select a i) (select b j)))))))) :andToOr))) (@cong (@refl (or (not (= b (store s2 k3 v3))) (not (not (or (not (= i j)) (= (select a i) (select b j))))))) (@rewrite (! (= (not (not (or (not (= i j)) (= (select a i) (select b j))))) (or (not (= i j)) (= (select a i) (select b j)))) :notSimp))))) (@rewrite (! (= (and (= a (store s1 k1 v1)) (not (or (not (= b (store s2 k3 v3))) (or (not (= i j)) (= (select a i) (select b j)))))) (not (or (not (= a (store s1 k1 v1))) (not (not (or (not (= b (store s2 k3 v3))) (or (not (= i j)) (= (select a i) (select b j))))))))) :andToOr))) (@cong (@refl (or (not (= a (store s1 k1 v1))) (not (not (or (not (= b (store s2 k3 v3))) (or (not (= i j)) (= (select a i) (select b j)))))))) (@rewrite (! (= (not (not (or (not (= b (store s2 k3 v3))) (or (not (= i j)) (= (select a i) (select b j)))))) (or (not (= b (store s2 k3 v3))) (or (not (= i j)) (= (select a i) (select b j))))) :notSimp))))) (@rewrite (! (= (and (not (= i k3)) (not (or (not (= a (store s1 k1 v1))) (or (not (= b (store s2 k3 v3))) (or (not (= i j)) (= (select a i) (select b j))))))) (not (or (not (not (= i k3))) (not (not (or (not (= a (store s1 k1 v1))) (or (not (= b (store s2 k3 v3))) (or (not (= i j)) (= (select a i) (select b j)))))))))) :andToOr))) (@cong (@refl (or (not (not (= i k3))) (not (not (or (not (= a (store s1 k1 v1))) (or (not (= b (store s2 k3 v3))) (or (not (= i j)) (= (select a i) (select b j))))))))) (@rewrite (! (= (not (not (= i k3))) (= i k3)) :notSimp)) (@rewrite (! (= (not (not (or (not (= a (store s1 k1 v1))) (or (not (= b (store s2 k3 v3))) (or (not (= i j)) (= (select a i) (select b j))))))) (or (not (= a (store s1 k1 v1))) (or (not (= b (store s2 k3 v3))) (or (not (= i j)) (= (select a i) (select b j)))))) :notSimp)))))) :notOr) (not (or (not (= a (store s1 k1 v1))) (or (not (= b (store s2 k3 v3))) (or (not (= i j)) (= (select a i) (select b j))))))) :notOr) (not (or (not (= b (store s2 k3 v3))) (or (not (= i j)) (= (select a i) (select b j)))))) :notOr) (not (or (not (= i j)) (= (select a i) (select b j))))) :notOr) (not (not (= i j)))) (@rewrite (! (= (not (not (= i j))) (= i j)) :notSimp))) (@rewrite (! (= (= i j) (! (= i j) :quotedCC)) :intern))) (! (! (= i j) :quotedCC) :input B)) :pivot (! (= i j) :quotedCC))) :pivot (not (! (= j k3) :quotedCC))) (! (@clause (@mp (@split (! (@split (! (@split (! (@split (! (@mp (@asserted (! (and (not (= i k3)) (and (= a (store s1 k1 v1)) (and (= b (store s2 k3 v3)) (and (= i j) (not (= (select a i) (select b j))))))) :named B)) (@trans (@rewrite (! (= (! (and (not (= i k3)) (and (= a (store s1 k1 v1)) (and (= b (store s2 k3 v3)) (and (= i j) (not (= (select a i) (select b j))))))) :named B) (and (not (= i k3)) (and (= a (store s1 k1 v1)) (and (= b (store s2 k3 v3)) (and (= i j) (not (= (select a i) (select b j)))))))) :strip)) (@cong (@trans (@cong (@refl (and (not (= i k3)) (and (= a (store s1 k1 v1)) (and (= b (store s2 k3 v3)) (and (= i j) (not (= (select a i) (select b j)))))))) (@cong (@trans (@cong (@refl (and (= a (store s1 k1 v1)) (and (= b (store s2 k3 v3)) (and (= i j) (not (= (select a i) (select b j))))))) (@cong (@trans (@cong (@refl (and (= b (store s2 k3 v3)) (and (= i j) (not (= (select a i) (select b j)))))) (@cong (@rewrite (! (= (and (= i j) (not (= (select a i) (select b j)))) (not (or (not (= i j)) (not (not (= (select a i) (select b j))))))) :andToOr)) (@cong (@refl (or (not (= i j)) (not (not (= (select a i) (select b j)))))) (@rewrite (! (= (not (not (= (select a i) (select b j)))) (= (select a i) (select b j))) :notSimp))))) (@rewrite (! (= (and (= b (store s2 k3 v3)) (not (or (not (= i j)) (= (select a i) (select b j))))) (not (or (not (= b (store s2 k3 v3))) (not (not (or (not (= i j)) (= (select a i) (select b j)))))))) :andToOr))) (@cong (@refl (or (not (= b (store s2 k3 v3))) (not (not (or (not (= i j)) (= (select a i) (select b j))))))) (@rewrite (! (= (not (not (or (not (= i j)) (= (select a i) (select b j))))) (or (not (= i j)) (= (select a i) (select b j)))) :notSimp))))) (@rewrite (! (= (and (= a (store s1 k1 v1)) (not (or (not (= b (store s2 k3 v3))) (or (not (= i j)) (= (select a i) (select b j)))))) (not (or (not (= a (store s1 k1 v1))) (not (not (or (not (= b (store s2 k3 v3))) (or (not (= i j)) (= (select a i) (select b j))))))))) :andToOr))) (@cong (@refl (or (not (= a (store s1 k1 v1))) (not (not (or (not (= b (store s2 k3 v3))) (or (not (= i j)) (= (select a i) (select b j)))))))) (@rewrite (! (= (not (not (or (not (= b (store s2 k3 v3))) (or (not (= i j)) (= (select a i) (select b j)))))) (or (not (= b (store s2 k3 v3))) (or (not (= i j)) (= (select a i) (select b j))))) :notSimp))))) (@rewrite (! (= (and (not (= i k3)) (not (or (not (= a (store s1 k1 v1))) (or (not (= b (store s2 k3 v3))) (or (not (= i j)) (= (select a i) (select b j))))))) (not (or (not (not (= i k3))) (not (not (or (not (= a (store s1 k1 v1))) (or (not (= b (store s2 k3 v3))) (or (not (= i j)) (= (select a i) (select b j)))))))))) :andToOr))) (@cong (@refl (or (not (not (= i k3))) (not (not (or (not (= a (store s1 k1 v1))) (or (not (= b (store s2 k3 v3))) (or (not (= i j)) (= (select a i) (select b j))))))))) (@rewrite (! (= (not (not (= i k3))) (= i k3)) :notSimp)) (@rewrite (! (= (not (not (or (not (= a (store s1 k1 v1))) (or (not (= b (store s2 k3 v3))) (or (not (= i j)) (= (select a i) (select b j))))))) (or (not (= a (store s1 k1 v1))) (or (not (= b (store s2 k3 v3))) (or (not (= i j)) (= (select a i) (select b j)))))) :notSimp)))))) :notOr) (not (or (not (= a (store s1 k1 v1))) (or (not (= b (store s2 k3 v3))) (or (not (= i j)) (= (select a i) (select b j))))))) :notOr) (not (or (not (= b (store s2 k3 v3))) (or (not (= i j)) (= (select a i) (select b j)))))) :notOr) (not (or (not (= i j)) (= (select a i) (select b j))))) :notOr) (not (= (select a i) (select b j)))) (@cong (@refl (not (= (select a i) (select b j)))) (@rewrite (! (= (= (select a i) (select b j)) (! (= (select a i) (select b j)) :quotedCC)) :intern)))) (! (not (! (= (select a i) (select b j)) :quotedCC)) :input B)) :pivot (not (! (= (select a i) (select b j)) :quotedCC))))
+
+Simplified and structured:
+
+(@res
+ (@lemma (! (or (! (= (select a i) (select b j)) :quotedCC) (not (! (= i j) :quotedCC)) (not (! (= b (store s2 k3 v3)) :quotedCC)) (! (= j k3) :quotedCC) (! (= j k2) :quotedCC) (not (! (= s1 (store s2 k2 v2)) :quotedCC)) (! (= j k1) :quotedCC) (not (! (= a (store s1 k1 v1)) :quotedCC))) :read-over-weakeq ( ... )))
+ (! (@res
+ (@lemma (! (or (! (= i k1) :quotedCC) (not (! (= i j) :quotedCC)) (not (! (= j k1) :quotedCC))) :CC ( ... )))
+ (! (@clause ( ... ) (! (not (! (= i k1) :quotedCC)) :input A))
+ :pivot (not (! (= i k1) :quotedCC)))
+ (! (@clause ( ... ) (! (! (= i j) :quotedCC) :input B))
+ :pivot (! (= i j) :quotedCC)))
+ :pivot (not (! (= j k1) :quotedCC)))
+ (! (@clause ( ... ) (! (! (= b (store s2 k3 v3)) :quotedCC) :input B))
+ :pivot (! (= b (store s2 k3 v3)) :quotedCC))
+ (! (@clause ( ... ) (! (! (= a (store s1 k1 v1)) :quotedCC) :input B))
+ :pivot (! (= a (store s1 k1 v1)) :quotedCC))
+ (! (@res
+ (@lemma (! (or (! (= i k2) :quotedCC) (not (! (= i j) :quotedCC)) (not (! (= j k2) :quotedCC))) :CC ( ... )))
+ (! (@clause ( ... ) (! (not (! (= i k2) :quotedCC)) :input A))
+ :pivot (not (! (= i k2) :quotedCC)))
+ (! (@clause ( ... ) (! (! (= i j) :quotedCC) :input B))
+ :pivot (! (= i j) :quotedCC)))
+ :pivot (not (! (= j k2) :quotedCC)))
+ (! (@clause ( ... ) (! (! (= s1 (store s2 k2 v2)) :quotedCC) :input A))
+ :pivot (! (= s1 (store s2 k2 v2)) :quotedCC))
+ (! (@clause ( ... ) (! (! (= i j) :quotedCC) :input B))
+ :pivot (! (= i j) :quotedCC))
+ (! (@res
+ (@lemma (! (or (! (= i k3) :quotedCC) (not (! (= i j) :quotedCC)) (not (! (= j k3) :quotedCC))) :CC ( ... )))
+ (! (@clause ( ... ) (! (not (! (= i k3) :quotedCC)) :input B))
+ :pivot (not (! (= i k3) :quotedCC)))
+ (! (@clause ( ... ) (! (! (= i j) :quotedCC) :input B))
+ :pivot (! (= i j) :quotedCC)))
+ :pivot (not (! (= j k3) :quotedCC)))
+ (! (@clause ( ... ) (! (not (! (= (select a i) (select b j)) :quotedCC)) :input B))
+ :pivot (not (! (= (select a i) (select b j)) :quotedCC))))
+
+--------------------------------------------------------------------------------
+
+SMT-LIB für die ersten 3 Beweise
+
+(set-option :produce-interpolants true)
+(set-option :print-terms-cse false)
+(set-logic ALL)
+
+(push 1)
+(assert (= 0 1))
+(check-sat)
+(get-proof)
+(pop 1)
+
+(push 1)
+(declare-fun p () Bool)
+(assert p)
+(assert (not p))
+(check-sat)
+(get-proof)
+(pop 1)
+
+(push 1)
+(declare-fun a () Int)
+(declare-fun b () Int)
+(assert (< a b))
+(assert (< b a))
+(check-sat)
+(get-proof)
+(pop 1)
+
+(exit)
+
+--------------------------------------------------------------------------------
+
diff --git a/Webinterface/src/main/visualizer/textparser_and_resolver.js b/Webinterface/src/main/visualizer/textparser_and_resolver.js
new file mode 100644
index 000000000..c8c39c5b2
--- /dev/null
+++ b/Webinterface/src/main/visualizer/textparser_and_resolver.js
@@ -0,0 +1,497 @@
+// Set global counters and the global array for the nodes that will be made into a tree.
+let root_node;
+let all_nodes;
+let node_counter;
+let text_pos;
+let text;
+
+// Class for nodes and leafs with ids, the text in each node/leaf, ids of parents and children
+// (the root node has parent_id = -1) and the info if it is a leaf or not.
+class Node {
+ constructor() {
+ this.node_id = node_counter;
+ this.node_text = [];
+ this.children = [];
+ this.parent_id = -1;
+ this.is_leaf = false;
+ this.node_literals = new Set();
+ this.node_pivot = "";
+ this.is_lemma_node = false;
+ this.is_clause_node = false;
+ // Intermediate_result is the resolution of the current nodes children with their literals and pivots.
+ this.intermediate_result = new Set();
+ }
+ toString() {
+ return "[" + this.node_id + ", " + this.node_text + ", [" + this.children + "], " + this.parent_id + ", \n" + this.is_leaf + ", {" + Array.from(this.node_literals) + "}, \n" + this.node_pivot + ", " + Array.from(this.intermediate_result) + "]";
+ }
+}
+
+// The next extract-functions are for extracting the literals and pivots from their respective node_texts.
+
+// Extracting the literals from the lemma-string so that they can be
+// resolved with the other literals later on.
+function extract_literals_lemma(lemma) {
+ let literals = new Set();
+ let pivot = "";
+ let lemma_text_pos = 0;
+ let lemma_literal = "";
+ let open = 0;
+ let close = 0;
+ while (lemma_text_pos < lemma.length) {
+ if (lemma.startsWith("or", lemma_text_pos)) {
+ while (lemma_text_pos < lemma.length) {
+ if (lemma[lemma_text_pos] == '(') {
+ open++;
+ }
+ if (open > close) {
+ lemma_literal += lemma[lemma_text_pos];
+ }
+ if (lemma[lemma_text_pos] == ')') {
+ close++;
+ }
+ if (open === close && lemma_literal !== "") {
+ literals.add(lemma_literal);
+ lemma_literal = "";
+ if (lemma.startsWith(") :", lemma_text_pos + 1)) {
+ lemma_text_pos = lemma.length;
+ }
+ }
+ lemma_text_pos++;
+ }
+ }
+ lemma_text_pos++;
+ }
+ return literals;
+}
+
+// Extracting the pivot from the given clause or lemma
+function extract_pivot(text) {
+ let pivot = "";
+ let open = 0;
+ let close = 0;
+ let text_pos = 0;
+ let splitted_text = text.split(":pivot ")[1];
+ // If pivot is in parenthesis
+ if (splitted_text[text_pos] == "(") {
+ while (text_pos < splitted_text.length) {
+ if (splitted_text[text_pos] == '(') {
+ open++;
+ }
+ if (open > close) {
+ pivot += splitted_text[text_pos];
+ }
+ if (splitted_text[text_pos] == ')') {
+ close++;
+ }
+ if (open === close) {
+ break;
+ }
+ text_pos++;
+ }
+ } else { // Pivot without parenthesis
+ while (text_pos < splitted_text.length) {
+ if (splitted_text[text_pos] == ')') {
+ break;
+ }
+ pivot += splitted_text[text_pos];
+ text_pos++;
+ }
+ }
+ return pivot;
+}
+
+function get_parenthesised_clause_literal(clause, text_position) {
+ let clause_literal = "";
+ let open = 0;
+ let close = 0;
+ while (text_position < clause.length) {
+ if (clause[text_position] == '(') {
+ open++;
+ }
+ if (open > close) {
+ clause_literal += clause[text_position];
+ }
+ if (clause[text_position] == ')') {
+ close++;
+ }
+ if (open === close) {
+ if (clause_literal == "") {
+ throw new Error("Literal is empty.");
+ }
+ return clause_literal;
+ }
+ text_position++
+ }
+}
+
+function get_non_parenthesised_clause_literal(clause, text_position) {
+ let clause_literal = "";
+ while (text_position < clause.length) {
+ if (clause[text_position] == ")" || clause[text_position] == " ") {
+ if (clause_literal == "") {
+ throw new Error("Literal is empty.");
+ }
+ return clause_literal;
+ }
+ if (clause[text_position] !== "") {
+ clause_literal += clause[text_position];
+ }
+ text_position++;
+ }
+}
+
+// Extracting the literals from the clause-string so that they can be
+// resolved with the other literals later on.
+function extract_literals_clause(clause) {
+ let literals = new Set();
+ let pivot = "";
+ let clause_text_pos = 0;
+ let open = 0;
+ let close = 0;
+ let is_parenthesis_ignored = false;
+ while (clause_text_pos < clause.length) {
+ // Start after "(@clause " or "(! (@clause "
+ if (clause.startsWith("@clause ", clause_text_pos)) {
+ clause_text_pos += 8;
+ // Completely ignore the next parenthesis
+ if (is_parenthesis_ignored == false) {
+ if (clause[clause_text_pos] == "(") {
+ open++;
+ clause_text_pos++;
+ while (open > close) {
+ if (clause[clause_text_pos] == '(') {
+ open++;
+ }
+ if (clause[clause_text_pos] == ')') {
+ close++;
+ }
+ if (open === close) {
+ break;
+ }
+ clause_text_pos++;
+ }
+ is_parenthesis_ignored = true;
+ clause_text_pos += 5; // Ignore " (! " that comes right after the to be ignored parenthesis
+ }
+ }
+ }
+ if (is_parenthesis_ignored) {
+ // If there are at least 2 literals then there is alway an "(or "
+ if (clause.startsWith("(or ", clause_text_pos)) {
+ clause_text_pos += 4; // Jump behind "(or "
+ while (clause_text_pos < clause.length) {
+ if (clause.startsWith(" :input", clause_text_pos)) {
+ clause_text_pos = clause.length;
+ break
+ }
+ // If the literal is in parenthesis
+ if (clause[clause_text_pos] == "(") {
+ let clause_literal = get_parenthesised_clause_literal(clause, clause_text_pos);
+ literals.add(clause_literal);
+ clause_text_pos += (clause_literal.length);
+ } // If the literal is without parenthesis
+ else if (clause[clause_text_pos] !== "(" && clause[clause_text_pos] !== " ") {
+ let clause_literal = get_non_parenthesised_clause_literal(clause, clause_text_pos);
+ literals.add(clause_literal);
+ clause_text_pos += (clause_literal.length);
+ }
+ clause_text_pos++;
+ }
+ }
+ // If there is no "(or " then there is only one literal.
+ // For a literal with parenthesis:
+ else if (clause[clause_text_pos] == "(") {
+ let clause_literal = get_parenthesised_clause_literal(clause, clause_text_pos);
+ literals.add(clause_literal);
+ clause_text_pos += (clause_literal.length);
+ if (clause.startsWith(" :input", clause_text_pos)) {
+ clause_text_pos = clause.length;
+ break;
+ }
+ } else if (clause[clause_text_pos] !== " " || clause[clause_text_pos] !== "") {
+ // For a literal without parenthesis:
+ let clause_literal = get_non_parenthesised_clause_literal(clause, clause_text_pos);
+ literals.add(clause_literal);
+ clause_text_pos += (clause_literal.length);
+ if (clause.startsWith(" :input", clause_text_pos)) {
+ clause_text_pos = clause.length;
+ break;
+ }
+ }
+ }
+ clause_text_pos++;
+ }
+ return literals;
+}
+
+function extract_literals(text, node) {
+ if (text.includes("lemma")) {
+ node.is_lemma_node = true;
+ return extract_literals_lemma(text);
+ }
+ if (text.includes("clause")) {
+ node.is_clause_node = true;
+ return extract_literals_clause(text);
+ }
+}
+
+// A function for parsing the text for the leafs of the (syntax) tree that will be created later.
+function parseLeaf() {
+ let newStr = [],
+ open = 0,
+ close = 0;
+ // Beginning of new leaf found, so start new "node" with id number and empty text.
+ // Child and parent ids will be recursively added later.
+ let node = new Node();
+ node.is_leaf = true;
+ node_counter++;
+ // Count the brackets to see if the expression is completed and save the text in newStr.
+ while (text_pos < text.length) {
+ if (text[text_pos] == '(') {
+ open++;
+ }
+ if (open > close) {
+ newStr += text[text_pos];
+ }
+ if (text[text_pos] == ')') {
+ close++;
+ }
+ text_pos++;
+ if (open === close) {
+ break;
+ }
+ }
+ // Assign the found text to the newly created leaf.
+ node.node_text = newStr;
+ node.node_literals = extract_literals(newStr, node);
+ if (newStr.includes(":pivot")) {
+ node.node_pivot = extract_pivot(newStr);
+ }
+ all_nodes.push(node);
+ return node;
+}
+
+// A function for parsing the text for the nodes of the (syntax) tree that will be created later.
+function parseNode() {
+ let newStr = [],
+ open = 0,
+ close = 0;
+ // Beginning of new leaf found, so start new "node" with id number and empty text.
+ // Child and parent ids will be added later.
+ let node = new Node();
+ node.is_leaf = false;
+ node_counter++;
+ // The starting text of the proof, where a node is found can directly be added to the
+ // created node-object and therefore the found opening brackets can already be counted
+ // and also the text position needs to be adjusted.
+ if (text.startsWith('(@res', text_pos)) {
+ open++;
+ text_pos += 6;
+ newStr += "(@res ";
+ } else if (text.startsWith('(! (@res ', text_pos)) {
+ open += 2;
+ text_pos += 9;
+ newStr += "(! (@res ";
+ }
+ while (text_pos < text.length) {
+ // If another keyword is found inside the res-node (so if there are children)
+ // we recursively go through these children first and get back to the parent(s) afterwards.
+ // Here the current node_id needs to be set to the next child's parent_id
+ // and the child_id of the "node" needs to be filled with the ids of all children.
+ if (text.startsWith("(! (@res", text_pos) || text.startsWith("(@res", text_pos) || text.startsWith("(! (@clause", text_pos) || text.startsWith("(! (@lemma", text_pos) || text.startsWith("(@clause", text_pos) || text.startsWith("(@lemma", text_pos)) {
+ let child = smt_parser();
+ child.parent_id = node.node_id;
+ node.children.push(child);
+ newStr += child.node_id;
+ }
+ // Count the brackets to see if the expression is completed and save the text in newStr.
+ if (text[text_pos] == '(') {
+ open++;
+ }
+ if (open > close) {
+ newStr += text[text_pos];
+ }
+ if (text[text_pos] == ')') {
+ close++;
+ }
+ text_pos++;
+ if (open === close) {
+ break;
+ }
+ }
+ // Save the resolved result of the nodes children in intermediate_result.
+ // This will be used later for building up our (syntax) tree.
+ node.node_literals = compute_literals_res_node(node.children);
+ if (newStr.includes(":pivot ")) {
+ node.node_pivot = extract_pivot(newStr);
+ }
+ // Assign the found text to the newly created node.
+ node.node_text += newStr;
+ all_nodes.push(node);
+ return node;
+}
+
+// The complete parser for leafs and nodes.
+function smt_parser() {
+ for (; text_pos < text.length; text_pos++) {
+ if (text.startsWith("(! (@res", text_pos) || text.startsWith("(@res", text_pos)) {
+ return parseNode();
+ } else if (text.startsWith("(! (@clause", text_pos) || text.startsWith("(! (@lemma", text_pos) || text.startsWith("(@clause", text_pos) || text.startsWith("(@lemma", text_pos)) {
+ return parseLeaf();
+ }
+ }
+ // If there is no proof text, we return an empty node.
+ let empty_node = new Node();
+ return empty_node;
+}
+
+// Recursively compute the literals for the res-nodes and their children.
+function compute_literals_res_node(children) {
+ let left_clause = Array.from(children[0].node_literals);
+ let right_clause = Array.from(children[1].node_literals);
+ let child_pivot = children[1].node_pivot;
+ for (var i = 1; i < children.length; i++) {
+ children[i].intermediate_result = compute_res(left_clause, right_clause, child_pivot);
+ left_clause = Array.from(children[i].intermediate_result);
+ if (children[i + 1]) {
+ right_clause = Array.from(children[i + 1].node_literals);
+ child_pivot = children[i + 1].node_pivot;
+ }
+ }
+ return new Set(left_clause);
+}
+
+// Take the given pivot and negate it.
+// So either put a "(not )" around the pivot or just take the inner part of the
+// "(not (pivot))" string.
+function negate_pivot(pivot) {
+ let negated_pivot;
+ if (pivot.startsWith("(not")) {
+ negated_pivot = pivot.slice(5, -1);
+ } else {
+ negated_pivot = "(not " + pivot + ")";
+ }
+ return negated_pivot;
+}
+
+// Compute the resolution of 2 clauses and a pivot.
+// pivot_found = 0 (pivot not found), = 1 (pivot found), = -1 (negated pivot found)
+function compute_res(resolve_literals_1, resolve_literals_2, resolve_pivot) {
+ let resolution = new Set();
+ let pivot_found = 0;
+ let resolve_literals_1_array = Array.from(resolve_literals_1);
+ let resolve_literals_2_array = Array.from(resolve_literals_2);
+ let negated_resolve_pivot = negate_pivot(resolve_pivot)
+ for (var i = 0; i < resolve_literals_1_array.length; i++) {
+ if (resolve_literals_1_array[i] === resolve_pivot) {
+ pivot_found = 1;
+ } else if (resolve_literals_1_array[i] === negated_resolve_pivot) {
+ pivot_found = -1;
+ } else {
+ resolution.add(resolve_literals_1_array[i]);
+ }
+ }
+ if (pivot_found === 0) {
+ throw new Error("There is neither a pivot nor a negated pivot found in our left clause.");
+ }
+ let opposite_pivot = false;
+ for (var i = 0; i < resolve_literals_2_array.length; i++) {
+ if (pivot_found === 1 && resolve_literals_2_array[i] === negated_resolve_pivot) {
+ opposite_pivot = true;
+ } else if (pivot_found === -1 && resolve_literals_2_array[i] === resolve_pivot) {
+ opposite_pivot = true;
+ } else {
+ resolution.add(resolve_literals_2_array[i]);
+ }
+ }
+ if (opposite_pivot === false) {
+ throw new Error("There is no negated pivot found in the right clause.");
+ }
+ return resolution;
+}
+
+// This will be the function for the complete visualization proof.
+// It will parse through the given proof text and create a (syntax) tree.
+function visualize_proof(input) {
+ text_pos = 0;
+ node_counter = 0;
+ all_nodes = [];
+ text = input;
+ root_node = smt_parser();
+ return all_nodes; // For testing
+}
+
+function create_tree(current_node, parent_id) {
+ if (current_node.children.length !== 0) {
+ let node_id = "node" + current_node.node_id;
+ let current_pivot = check_pivot_availability(current_node);
+ let current_literal = check_node_literal_lemma_clause(current_node);
+ document.getElementById(parent_id).innerHTML += current_literal+current_pivot+
+ ' {'+Array.from(current_node.intermediate_result)+'}
';
+ for (var i = 0; i < current_node.children.length; i++) {
+ create_tree(current_node.children[i], node_id);
+ }
+ } else if (current_node.children.length === 0) {
+ let node_id = "node" + current_node.node_id;
+ let current_pivot = check_pivot_availability(current_node);
+ let current_literal = check_leaf_literal_lemma_clause(current_node);
+ document.getElementById(parent_id).innerHTML += current_literal+current_pivot+
+ ' {'+Array.from(current_node.intermediate_result)+'}';
+ }
+}
+
+// Create a tree with the resolved literals so that the literals, pivots and
+// intermediate results before each resolution step will be shown.
+window.onload = function() {
+ var visualize_button = document.getElementById("visualizer");
+ visualize_button.addEventListener("click", function() {
+ document.getElementById("mytree").innerHTML = '';
+ document.getElementById("legend").style.display = "inline-block";
+ visualize_button.innerHTML = "SMT proof started";
+ let proof_input = document.getElementById("input_text").value;
+ visualize_proof(proof_input);
+ document.querySelector("button").style.color = "darkred";
+ create_tree(root_node, "mytree");
+ var toggler = document.getElementsByClassName("arrow");
+ for (var i = 0; i < toggler.length; i++) {
+ toggler[i].addEventListener("click", function() {
+ this.parentElement.querySelector(".nested").classList.toggle("active");
+ this.classList.toggle("arrow-down");
+ });
+ }
+ });
+}
+
+// Check if pivot is available and either return it or just the bracket to close
+// the node_literals array in the string for the html site
+function check_pivot_availability(node) {
+ if (node.node_pivot) {
+ let str1 = '} ';
+ let str2 = node.node_pivot;
+ return str1+str2;
+ } else {
+ return "}";
+ }
+}
+
+// Check if literal of the leaf contains @lemma or @clause to highlight it later
+function check_leaf_literal_lemma_clause(node) {
+ if (node.is_lemma_node) {
+ return '
{' + Array.from(node.node_literals);
+ }
+}
+
+// Check if literal of the node contains @lemma or @clause to highlight it later
+function check_node_literal_lemma_clause(node) {
+ if (node.is_lemma_node) {
+ return '