Programming/Algorithms: Difference between revisions
Jump to navigation
Jump to search
| (3 intermediate revisions by the same user not shown) | |||
| Line 1: | Line 1: | ||
== Pseudocode == | == Pseudocode == | ||
=== Fibonacci At Index === | |||
<pre> | |||
def fib(n): | |||
if n <= 1: | |||
return n | |||
else: | |||
return(fib(n-1) + fib(n-2)) | |||
</pre> | |||
=== Binary Tree Search === | === Binary Tree Search === | ||
| Line 116: | Line 126: | ||
|- | |- | ||
| B Tree || Θ(log(n)) -> O(log(n)) || Θ(log(n)) -> O(log(n)) || Θ(log(n)) -> O(log(n)) || Θ(log(n)) -> O(log(n)) || O(n) || Self-balancing | | B Tree || Θ(log(n)) -> O(log(n)) || Θ(log(n)) -> O(log(n)) || Θ(log(n)) -> O(log(n)) || Θ(log(n)) -> O(log(n)) || O(n) || Self-balancing | ||
|- | |||
| Heap || || || O(log(n)) || O(log(n)) || || Complete binary tree, one maximally efficient implementation of a priority queue | |||
|} | |} | ||
| Line 150: | Line 162: | ||
|- | |- | ||
| DFS, recursive || || || O(V + E) || O(V) | | DFS, recursive || || || O(V + E) || O(V) | ||
|- | |||
| Dijkstra || || || || | |||
|- | |||
| A* || || || O(E) = O(b^d) || O(V) = O(b^d) | |||
|} | |} | ||
Latest revision as of 08:18, 19 January 2023
Pseudocode
Fibonacci At Index
def fib(n):
if n <= 1:
return n
else:
return(fib(n-1) + fib(n-2))
Binary Tree Search
Iterative-Tree-Search(x, key)
while x ≠ NIL and key ≠ x.key then
if key < x.key then
x := x.left
else
x := x.right
end if
repeat
return x
BFS
procedure BFS(G, root) is
let Q be a queue
label root as explored
Q.enqueue(root)
while Q is not empty do
v := Q.dequeue()
if v is the goal then
return v
for all edges from v to w in G.adjacentEdges(v) do
if w is not labeled as explored then
label w as explored
w.parent := v
Q.enqueue(w)
DFS
procedure DFS(G, v) is
label v as discovered
for all directed edges from v to w that are in G.adjacentEdges(v) do
if vertex w is not labeled as discovered then
recursively call DFS(G, w)
procedure DFS_iterative(G, v) is
let S be a stack
S.push(v)
while S is not empty do
v = S.pop()
if v is not labeled as discovered then
label v as discovered
for all edges from v to w in G.adjacentEdges(v) do
S.push(w)
Dijkstra
function Dijkstra(Graph, source):
for each vertex v in Graph.Vertices:
dist[v] ← INFINITY
prev[v] ← UNDEFINED
add v to Q
dist[source] ← 0
while Q is not empty:
u ← vertex in Q with min dist[u]
remove u from Q
for each neighbor v of u still in Q:
alt ← dist[u] + Graph.Edges(u, v)
if alt < dist[v]:
dist[v] ← alt
prev[v] ← u
return dist[], prev[]
Big O Notation
Adapted from Big-O Cheat Sheet
| Data Structure | Time Complexity | Space Complexity | Notes | |||
|---|---|---|---|---|---|---|
| Average -> Worst | ||||||
| Access | Search | Insertion | Deletion | |||
| Array | Θ(1) -> O(1) | Θ(n) -> O(n) | Θ(n) -> O(n) | Θ(n) -> O(n) | O(n) | |
| Stack | Θ(n) -> O(n) | Θ(n) -> O(n) | Θ(1) -> O(n) | Θ(1) -> O(n) | O(n) | |
| Queue | Θ(n) -> O(n) | Θ(n) -> O(n) | Θ(1) -> O(n) | Θ(1) -> O(n) | O(n) | |
| Linked List | Θ(n) -> O(n) | Θ(n) -> O(n) | Θ(1) -> O(n) | Θ(1) -> O(n) | O(n) | |
| Double Linked List | Θ(n) -> O(n) | Θ(n) -> O(n) | Θ(1) -> O(n) | Θ(1) -> O(n) | O(n) | |
| Hash Table | N/A | Θ(1) -> O(n) | Θ(1) -> O(n) | Θ(1) -> O(n) | O(n) | |
| Binary Search Tree | Θ(log(n)) -> O(n) | Θ(log(n)) -> O(n) | Θ(log(n)) -> O(n) | Θ(log(n)) -> O(n) | O(n) | |
| B Tree | Θ(log(n)) -> O(log(n)) | Θ(log(n)) -> O(log(n)) | Θ(log(n)) -> O(log(n)) | Θ(log(n)) -> O(log(n)) | O(n) | Self-balancing |
| Heap | O(log(n)) | O(log(n)) | Complete binary tree, one maximally efficient implementation of a priority queue | |||
| Data Structure | Time Complexity | Space Complexity | Notes | ||
|---|---|---|---|---|---|
| Best | Average | Worst | |||
| Bubble Sort | Ω(n) | Θ(n^2) | O(n^2) | O(1) | |
| Quicksort | Ω(n log(n)) | Θ(n log(n)) | O(n^2) | O(log(n)) | |
| Mergesort | Ω(n log(n)) | Θ(n log(n)) | O(n log(n)) | O(n) | |
| Insertion Sort | Ω(n) | Θ(n^2) | O(n^2) | O(1) | |
| Timsort | Ω(n) | Θ(n log(n)) | O(n log(n)) | O(n) | Combination of Mergesort and Insertion Sort made for Python |
| Heapsort | Ω(n log(n)) | Θ(n log(n)) | O(n log(n)) | O(1) | |
| Data Structure | Time Complexity | Space Complexity | Notes | ||
|---|---|---|---|---|---|
| Best | Average | Worst | |||
| BFS | O(V + E) = O(b^d) | O(V) = O(b^d) | |||
| DFS | O(b^d) | O(E) = O(bd) | |||
| DFS, recursive | O(V + E) | O(V) | |||
| Dijkstra | |||||
| A* | O(E) = O(b^d) | O(V) = O(b^d) | |||