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Binary SearchLinear SearchJump SearchInterpolation SearchExponential SearchTernary SearchFibonacci SearchQuick Select (k-th Smallest)Median of Medians (Deterministic Select)Hill climbingSimulated AnnealingTabu SearchBinary Tree DFS SearchSentinel Linear SearchDouble Linear SearchTernary Search (Unimodal Function)Search in 2D Matrix
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Depth-First Search (DFS)Breadth-First Search (BFS)Dijkstra's AlgorithmFloyd-Warshall AlgorithmKruskal's AlgorithmPrim's AlgorithmTopological SortA* Pathfinding AlgorithmKahn's Algorithm (Topological Sort)Ford-Fulkerson Max FlowEulerian Path/CircuitBipartite Graph CheckBorůvka's Algorithm (MST)Bidirectional DijkstraPageRank AlgorithmBellman-Ford AlgorithmTarjan's Strongly Connected ComponentsArticulation Points (Cut Vertices)Find Bridges (Cut Edges)Articulation Points (Cut Vertices)Finding Bridges (Cut Edges)
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A* Search AlgorithmConvex Hull (Graham Scan)Line Segment IntersectionCaesar CipherVigenère CipherRSA EncryptionHuffman CompressionRun-Length Encoding (RLE)Lempel-Ziv-Welch (LZW)Canny Edge DetectionGaussian Blur FilterSobel Edge FilterHarris Corner DetectionHistogram EqualizationMedian FilterLaplacian FilterMorphological ErosionMorphological DilationImage Thresholding (Otsu's Method)Conway's Game of LifeLangton's AntRule 30 Cellular AutomatonFast Fourier Transform (FFT)Butterworth FilterSpectrogram (STFT)
Knuth-Morris-Pratt (KMP) AlgorithmRabin-Karp AlgorithmBoyer-Moore AlgorithmAho-Corasick AlgorithmManacher's AlgorithmSuffix ArraySuffix Tree (Ukkonen's Algorithm)Trie for String MatchingEdit Distance for StringsLCS for String MatchingHamming DistanceJaro-Winkler DistanceDamerau-Levenshtein DistanceBitap Algorithm (Shift-Or, Baeza-Yates-Gonnet)Rolling Hash (Rabin-Karp Hash)Manacher's AlgorithmZ AlgorithmLevenshtein Distance

Binary Tree DFS Search

Searching
O(n) time, O(h) space
Beginner

Depth-first search over a binary tree to find a target value (preorder).

Visualization

Interactive visualization for Binary Tree DFS Search

Binary Tree DFS:

  • • Depth-first search in tree
  • • Time: O(n)

Interactive visualization with step-by-step execution

Implementation

Language:
1type Node = { val: number; left?: Node|null; right?: Node|null };
2function dfsFind(root: Node|null, target: number): boolean {
3  if (!root) return false; if (root.val === target) return true;
4  return dfsFind(root.left||null, target) || dfsFind(root.right||null, target);
5}

Complexity

Time

Best

O(1)

Average

O(n)

Worst

O(n)

Space

Required

O(h)

Applications

Use Cases

Tree search
Data structure traversal
Expression trees

Related Algorithms

Binary Search

Binary Search is one of the most efficient searching algorithms with O(log n) time complexity. It works on sorted arrays by repeatedly dividing the search space in half, eliminating half of the remaining elements with each comparison. This divide-and-conquer approach makes it exponentially faster than linear search for large datasets.

Searching

Linear Search

Linear Search, also known as Sequential Search, is the simplest searching algorithm that checks each element in a list sequentially until the target element is found or the end is reached. Despite its O(n) time complexity, it's the only option for unsorted data and remains practical for small datasets or when simplicity is crucial.

Searching

Jump Search

Jump Search is an efficient algorithm for sorted arrays that combines the benefits of linear and binary search. Instead of checking every element (linear) or dividing the array (binary), it jumps ahead by fixed steps of √n and then performs linear search within the identified block. This approach achieves O(√n) time complexity, making it faster than linear search while being simpler than binary search for certain applications.

Searching

Interpolation Search

Interpolation Search is an improved variant of binary search specifically optimized for uniformly distributed sorted arrays. Instead of always checking the middle element, it estimates the target's position based on the target value relative to the range of values, similar to how humans search a phone book. Achieves O(log log n) average time for uniformly distributed data, significantly faster than binary search's O(log n).

Searching
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