{ "data": { "question": { "questionId": "1733", "questionFrontendId": "1610", "boundTopicId": null, "title": "Maximum Number of Visible Points", "titleSlug": "maximum-number-of-visible-points", "content": "

You are given an array points, an integer angle, and your location, where location = [posx, posy] and points[i] = [xi, yi] both denote integral coordinates on the X-Y plane.

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Initially, you are facing directly east from your position. You cannot move from your position, but you can rotate. In other words, posx and posy cannot be changed. Your field of view in degrees is represented by angle, determining how wide you can see from any given view direction. Let d be the amount in degrees that you rotate counterclockwise. Then, your field of view is the inclusive range of angles [d - angle/2, d + angle/2].

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You can see some set of points if, for each point, the angle formed by the point, your position, and the immediate east direction from your position is in your field of view.

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There can be multiple points at one coordinate. There may be points at your location, and you can always see these points regardless of your rotation. Points do not obstruct your vision to other points.

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Return the maximum number of points you can see.

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Example 1:

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\nInput: points = [[2,1],[2,2],[3,3]], angle = 90, location = [1,1]\nOutput: 3\nExplanation: The shaded region represents your field of view. All points can be made visible in your field of view, including [3,3] even though [2,2] is in front and in the same line of sight.\n
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Example 2:

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\nInput: points = [[2,1],[2,2],[3,4],[1,1]], angle = 90, location = [1,1]\nOutput: 4\nExplanation: All points can be made visible in your field of view, including the one at your location.\n
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Example 3:

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\nInput: points = [[1,0],[2,1]], angle = 13, location = [1,1]\nOutput: 1\nExplanation: You can only see one of the two points, as shown above.\n
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Constraints:

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Now only a consecutive collection of points would be visible from any coordinate.", "We can use two pointers to keep track of visible points for each start point", "For handling the cyclic condition, it’d be helpful to append the point list to itself after sorting." ], "solution": null, "status": null, "sampleTestCase": "[[2,1],[2,2],[3,3]]\n90\n[1,1]", "metaData": "{\n \"name\": \"visiblePoints\",\n \"params\": [\n {\n \"name\": \"points\",\n \"type\": \"list>\"\n },\n {\n \"type\": \"integer\",\n \"name\": \"angle\"\n },\n {\n \"type\": \"list\",\n \"name\": \"location\"\n }\n ],\n \"return\": {\n \"type\": \"integer\"\n }\n}", "judgerAvailable": true, "judgeType": "large", "mysqlSchemas": [], "enableRunCode": true, "enableTestMode": false, "enableDebugger": true, "envInfo": "{\"cpp\": [\"C++\", \"

Compiled with clang 11 using the latest C++ 20 standard.

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Your code is compiled with level two optimization (-O2). AddressSanitizer is also enabled to help detect out-of-bounds and use-after-free bugs.

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Most standard library headers are already included automatically for your convenience.

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OpenJDK 17. Java 8 features such as lambda expressions and stream API can be used.

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Most standard library headers are already included automatically for your convenience.

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Python 2.7.12.

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C# 10 with .NET 6 runtime

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Node.js 16.13.2.

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Ruby 3.1

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Go 1.21

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Python 3.10.

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Scala 2.13.7.

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Kotlin 1.9.0.

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Rust 1.58.1

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Dart 2.17.3

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