5 files changed, 146 insertions, 8 deletions

diff --git a/Common.lean b/Common.lean
index 89c9051..32b40ec 100644
--- a/Common.lean
+++ b/Common.lean
@@ -5,3 +5,4 @@ import Common.String
 import Common.List
 import Common.Char
 import Common.Euclid
+import Common.BTreeHeap
diff --git a/Common/BTreeHeap.lean b/Common/BTreeHeap.lean
new file mode 100644
index 0000000..cba0285
--- /dev/null
+++ b/Common/BTreeHeap.lean
@@ -0,0 +1,140 @@
+namespace BTreeHeap
+
+/--A heap, represented as a binary indexed tree. The heap predicate is a type parameter, the index is the element count.-/
+inductive BTreeHeap (α : Type u) (lt : α → α → Bool ): Nat → Type u
+  | leaf : BTreeHeap α lt 0
+  | branch : (val : α) → (left : BTreeHeap α lt n) → (right : BTreeHeap α lt m) → m ≤ n → BTreeHeap α lt (n+m+1)
+
+/--Please do not use this for anything meaningful. It's a debug function, with horrible performance.-/
+instance {α : Type u} {lt : α → α → Bool} [ToString α] : ToString (BTreeHeap α lt n) where
+  toString := λt ↦
+    --not very fast, doesn't matter, is for debugging
+    let rec max_width := λ {m : Nat} (t : (BTreeHeap α lt m)) ↦ match m, t with
+    | 0, .leaf => 0
+    | (_+_+1), BTreeHeap.branch a left right _ => max (ToString.toString a).length $ max (max_width left) (max_width right)
+    let max_width := max_width t
+    let lines_left := Nat.log2 (n+1).nextPowerOfTwo
+    let rec print_line := λ (mw : Nat) {m : Nat} (t : (BTreeHeap α lt m)) (lines : Nat)  ↦
+      match m, t with
+      | 0, _ => ""
+      | (_+_+1), BTreeHeap.branch a left right _ =>
+        let thisElem := ToString.toString a
+        let thisElem := (List.replicate (mw - thisElem.length) ' ').asString ++ thisElem
+        let elems_in_last_line := if lines == 0 then 0 else 2^(lines-1)
+        let total_chars_this_line := elems_in_last_line * mw + 2*(elems_in_last_line)+1
+        let left_offset := (total_chars_this_line - mw) / 2
+        let whitespaces := max left_offset 1
+        let whitespaces := List.replicate whitespaces ' '
+        let thisline := whitespaces.asString ++ thisElem ++ whitespaces.asString ++"\n"
+        let leftLines := (print_line mw left (lines-1) ).splitOn "\n"
+        let rightLines := (print_line mw right (lines-1) ).splitOn "\n" ++ [""]
+        let combined := leftLines.zip (rightLines)
+        let combined := combined.map λ (a : String × String) ↦ a.fst ++ a.snd
+        thisline ++ combined.foldl (· ++ "\n" ++ ·) ""
+    print_line max_width t lines_left
+
+/-- Extracts the element count. For when pattern matching is too much work. -/
+def BTreeHeap.length : BTreeHeap α lt n → Nat := λ_ ↦ n
+
+/--Creates an empty BTreeHeap. Needs the heap predicate as parameter.-/
+abbrev BTreeHeap.empty {α : Type u} (lt : α → α → Bool ) := BTreeHeap.leaf (α := α) (lt := lt)
+
+theorem blah : n + 1 < m + 1 → n < m := by simp_arith
+                                           apply id
+
+/--Adds a new element to a given BTreeHeap.-/
+def BTreeHeap.insert (elem : α) (heap : BTreeHeap α lt o) : BTreeHeap α lt (o+1) :=
+  match o, heap with
+  | 0, .leaf => BTreeHeap.branch elem (BTreeHeap.leaf) (BTreeHeap.leaf) (by simp)
+  | (n+m+1), .branch a left right p =>
+    let (elem, a) := if lt elem a then (a, elem) else (elem, a)
+    -- okay, based on n and m we know if we want to add left or right.
+    -- the left tree is full, if (n+1) is a power of two AND n != m
+    let leftIsFull : Bool := (n+1).nextPowerOfTwo = n+1
+    if r : m < n ∧ leftIsFull  then
+      have s : (m + 1 < n + 1) = (m < n) := by simp_arith
+      have q : m + 1 ≤ n := by apply Nat.le_of_lt_succ
+                               rewrite[Nat.succ_eq_add_one]
+                               rw[s]
+                               simp[r]
+      let result := branch a left (right.insert elem) (q)
+      result
+    else
+      have q : m ≤ n+1 := by apply (Nat.le_of_succ_le)
+                             simp_arith[p]
+      let result := branch a (left.insert elem) right q
+      have letMeSpellItOutForYou : n + 1 + m + 1 = n + m + 1 + 1 := by simp_arith
+      letMeSpellItOutForYou ▸ result
+
+
+/--Helper function for BTreeHeap.indexOf.-/
+def BTreeHeap.indexOfAux {α : Type u} {lt : α → α → Bool} [BEq α] (elem : α) (heap : BTreeHeap α lt o) (currentIndex : Nat) : Option (Fin (o+currentIndex)) :=
+  match o, heap with
+  | 0, .leaf => none
+  | (n+m+1), .branch a left right _ =>
+    if a == elem then
+      let result := Fin.ofNat' currentIndex (by simp_arith)
+      some result
+    else
+      let found_left := left.indexOfAux elem (currentIndex + 1)
+      let found_left : Option (Fin (n+m+1+currentIndex)) := found_left.map λ a ↦ Fin.ofNat' a (by simp_arith)
+      let found_right :=
+        found_left
+        <|>
+        (right.indexOfAux elem (currentIndex + n + 1)).map ((λ a ↦ Fin.ofNat' a (by simp_arith)) : _ → Fin (n+m+1+currentIndex))
+      found_right
+
+/--Finds the first occurance of a given element in the heap and returns its index.-/
+def BTreeHeap.indexOf {α : Type u} {lt : α → α → Bool} [BEq α] (elem : α) (heap : BTreeHeap α lt o) : Option (Fin o) :=
+  indexOfAux elem heap 0
+
+private inductive Direction
+| left
+| right
+deriving Repr
+
+def BTreeHeap.popLast {α : Type u} {lt : α → α → Bool} (heap : BTreeHeap α lt (o+1)) : (α × BTreeHeap α lt o) :=
+  match o, heap with
+  | (n+m), .branch a (left : BTreeHeap α lt n) (right : BTreeHeap α lt m) =>
+    if p : 0 = (n+m) then
+      (a, p▸BTreeHeap.leaf)
+    else
+      let leftIsFull : Bool := (n+1).nextPowerOfTwo = n+1
+      let rightIsFull : Bool := (m+1).nextPowerOfTwo = m+1
+      if !leftIsFull || (rightIsFull && n != m) then
+        --remove left
+        match n, left with
+        | 0 , _ => sorry
+        | (l+1),  left =>
+          let (res, (newLeft : BTreeHeap α lt (l))) := left.popLast
+          (res, BTreeHeap.branch a newLeft right)
+      else
+        --remove right
+        sorry
+
+/--Removes the element at a given index. Use `BTreeHeap.indexOf` to find the respective index.-/
+def BTreeHeap.removeAt {α : Type u} {lt : α → α → Bool} {o : Nat} (index : Fin (o+1)) (heap : BTreeHeap α lt (o+1)) : BTreeHeap α lt o :=
+  -- first remove the last element and remember its value
+  sorry
+
+-------------------------------------------------------------------------------------------------------
+
+private def TestHeap := let ins : {n: Nat} → Nat → BTreeHeap Nat (λ (a b : Nat) ↦ a < b) n → BTreeHeap Nat (λ (a b : Nat) ↦ a < b) (n+1) := BTreeHeap.insert
+  ins 5 (BTreeHeap.empty (λ (a b : Nat) ↦ a < b))
+  |> ins 3
+  |> ins 7
+  |> ins 12
+  |> ins 2
+  |> ins 8
+  |> ins 97
+  |> ins 2
+  |> ins 64
+  |> ins 71
+  |> ins 21
+  --|> ins 3
+  --|> ins 4
+  --|> ins 199
+
+
+#eval TestHeap
+#eval TestHeap.indexOf 5
diff --git a/Day10.lean b/Day10.lean
new file mode 100644
index 0000000..c3508a2
--- /dev/null
+++ b/Day10.lean
@@ -0,0 +1,3 @@
+namespace Day10
+
+-- I'm going to go with a Dijkstra graph search here.
diff --git a/Main.lean b/Main.lean
index 4fdf18c..433e153 100644
--- a/Main.lean
+++ b/Main.lean
@@ -8,6 +8,7 @@ import «Day6»
 import «Day7»
 import «Day8»
 import «Day9»
+import «Day10»
 
 open DayPart
 
diff --git a/lakefile.lean b/lakefile.lean
index f2096b3..3d6157a 100644
--- a/lakefile.lean
+++ b/lakefile.lean
@@ -4,22 +4,15 @@ open Lake DSL
 package «aoc-2023» where
 
 lean_lib «Day1» where
-
 lean_lib «Day2» where
-
 lean_lib «Day3» where
-
 lean_lib «Day4» where
-
 lean_lib «Day5» where
-
 lean_lib «Day6» where
-
 lean_lib «Day7» where
-
 lean_lib «Day8» where
-
 lean_lib «Day9» where
+lean_lib «Day10» where
 
 lean_lib «Common» where