Gathering detailed insights and metrics for d3-voronoi-treemap
Gathering detailed insights and metrics for d3-voronoi-treemap
Gathering detailed insights and metrics for d3-voronoi-treemap
Gathering detailed insights and metrics for d3-voronoi-treemap
npm install d3-voronoi-treemap
99.7
Supply Chain
100
Quality
75.7
Maintenance
100
Vulnerability
100
License
Module System
Min. Node Version
Typescript Support
Node Version
NPM Version
204 Stars
91 Commits
19 Forks
9 Watching
2 Branches
2 Contributors
Updated on 25 Nov 2024
JavaScript (100%)
Cumulative downloads
Total Downloads
Last day
4.4%
13,090
Compared to previous day
Last week
2.2%
66,096
Compared to previous week
Last month
8.1%
281,990
Compared to previous month
Last year
422.1%
2,670,036
Compared to previous year
1
This D3 plugin produces a Voronoï treemap. Given a convex polygon and nested weighted data, it tesselates/partitions the polygon in several inner cells which represent the hierarchical structure of your data, such that the area of a cell represents the weight of the underlying datum.
Because a picture is worth a thousand words:
Available only for d3 v4, d3 v5 and d3 v6.
If you're interested on one-level map, take a look at the d3-voronoi-map plugin, which may be simpler to use (no need of a d3-hierarchy).
D3 already provides a d3-treemap module which produces a rectangular treemap. Such treemaps could be distorted to fit shapes that are not rectangles (cf. Distorded Treemap - d3-shaped treemap).
This plugin allows to compute a treemap with a unique look-and-feel, where inner areas are not strictly aligned each others, and where the outer shape can be any hole-free convex polygons (squares, rectangles, pentagon, hexagon, ... any regular convex polygon, and also any non regular hole-free convex polygon).
The drawback is that the computation of a Voronoï treemap is based on a iteration/looping process. Hence, it requires some times, depending on the number and type of data/weights, the desired representativeness of cell areas.
If you use NPM, npm install d3-voronoi-treemap
. Otherwise, load https://rawcdn.githack.com/Kcnarf/d3-voronoi-treemap/v1.1.2/build/d3-voronoi-treemap.js
(or its d3-voronoi-treemap.min.js
version) to make it available in AMD, CommonJS, or vanilla environments. In vanilla, you must load the d3-weighted-voronoi and d3-voronoi-map plugins prioir to this one, and a d3 global is exported:
1<script src="https://d3js.org/d3.v6.min.js"></script> 2<script src="https://rawcdn.githack.com/Kcnarf/d3-weighted-voronoi/v1.1.3/build/d3-weighted-voronoi.js"></script> 3<script src="https://rawcdn.githack.com/Kcnarf/d3-voronoi-map/v2.1.1/build/d3-voronoi-map.js"></script> 4<script src="https://rawcdn.githack.com/Kcnarf/d3-voronoi-treemap/v1.1.2/build/d3-voronoi-treemap.js"></script> 5<script> 6 var voronoiTreemap = d3.voronoiTreemap(); 7</script>
If you're interested in the latest developments, you can use the master build, available throught:
1<script src="https://raw.githack.com/Kcnarf/d3-voronoi-treemap/master/build/d3-voronoi-treemap.js"></script>
In your javascript, in order to define the tessellation:
1function weightAccessor(d) { 2 return d.weight; // computes the weight of one of your data; depending on your data, it may be 'd.area', or 'd.percentage', ... 3} 4var rootNode = d3.hierarchy(nestedData); // a d3-hierarchy of your nested data 5rootNode.sum(weightAccessor); // assigns the adequate weight to each node of the d3-hierarchy 6 7var voronoiTreemap = d3.voronoiTreemap().clip([ 8 [0, 0], 9 [0, height], 10 [width, height], 11 [width, 0], 12]); // sets the clipping polygon 13voronoiTreemap(rootNode); // computes the weighted Voronoi tessellation of the d3-hierarchy; assigns a 'polygon' property to each node of the hierarchy
Then, later in your javascript, in order to draw cells:
1var allNodes = rootNode.descendants(); 2d3.selectAll('path') 3 .data(allNodes) 4 .enter() 5 .append('path') 6 .attr('d', function (d) { 7 // d is a node 8 return d3.line()(d.polygon) + 'z'; // d.polygon is the computed Voronoï cell encoding the relative weight of your underlying original data 9 }) 10 .style('fill', function (d) { 11 return fillScale(d.data); // d.data is your original data 12 });
# d3.voronoiTreemap()
Creates a new voronoiTreemap with the default configuration values and functions (clip, extent, size, convergenceRatio, maxIterationCount, minWeightRatio and prng).
# voronoiTreemap(root)
Computes the Voronoï treemap for the specified d3-hierarchy, where root is the root node of the hierarchy, assigning a polygon property on the root and its descendants. A polygon is represented as an array of points [x, y] where x and y are the point coordinates, a site field that refers to its site (ie. with x, y and weight retrieved from the original data), and a site.originalObject field that refers to the corresponding element in data. Polygons are open: they do not contain a closing point that duplicates the first point; a triangle, for example, is an array of three points. Polygons are also counterclockwise (assuming the origin ⟨0,0⟩ is in the top-left corner).
As others d3-hierarchy layouts (rectangular treemap, or circle packing), the Voronoï treemap layout considers the weight of a node to be the value propertyof that node. Hence, you must call root.sum before passing the hierarchy to the Voronoï treemap layout, in order to properly set the value property of each node (root, intermediates and leaves). For example, considering that your original nested data have leaves with a weight property, you must use rootNode.sum(function(d){ return d.weight; })
.
# voronoiTreemap.clip([clip])
If clip is specified, sets the clipping polygon, , compute the adequate extent and size, and returns this layout . clip defines a hole-free convex polygon, and is specified as an array of 2D points [x, y], which must be (i) open (no duplication of the first D2 point) and (ii) counterclockwise (assuming the origin ⟨0,0⟩ is in the top-left corner). If clip is not specified, returns the current clipping polygon, which defaults to:
1[ 2 [0, 0], 3 [0, 1], 4 [1, 1], 5 [1, 0], 6];
# voronoiTreemap.extent([extent])
If extent is specified, it is a convenient way to define the clipping polygon as a rectangle. It sets the extent, computes the adequate clipping polygon and size, and returns this layout. extent must be a two-element array of 2D points [x, y], which defines the clipping polygon as a rectangle with the top-left and bottom-right corners respectively set to the first and second points (assuming the origin ⟨0,0⟩ is in the top-left corner on the screen). If extent is not specified, returns the current extent, which is [[minX, minY], [maxX, maxY]]
of current clipping polygon, and which defaults to:
1[ 2 [0, 0], 3 [1, 1], 4];
# voronoiTreemap.size([size])
If size is specified, it is a convenient way to define the clipping polygon as a rectangle. It sets the size, computes the adequate clipping polygon and extent, and returns this layout. size must be a two-element array of numbers [width, height]
, which defines the clipping polygon as a rectangle with the top-left corner set to [0, 0]
and the bottom-right corner set to [width, height]
(assuming the origin ⟨0,0⟩ is in the top-left corner on the screen). If size is not specified, returns the current size, which is [maxX-minX, maxY-minY]
of current clipping polygon, and which defaults to:
1[1, 1];
# voronoiTreemap.convergenceRatio([convergenceRatio])
If convergenceRatio is specified, sets the convergence ratio, which stops computation when (cell area errors / (clip-ping polygon area) <= convergenceRatio. If convergenceRatio is not specified, returns the current convergenceRatio , which defaults to:
1var convergenceRatio = 0.01; // stops computation when cell area error <= 1% clipping polygon's area
The smaller the convergenceRatio, the more representative is the treemap, the longer the computation takes time.
# voronoiTreemap.maxIterationCount([maxIterationCount])
If maxIterationCount is specified, sets the maximum allowed number of iterations, which stops computation when it is reached, even if the convergenceRatio is not reached. If maxIterationCount is not specified, returns the current maxIterationCount , which defaults to:
1var maxIterationCount = 50;
If you want to wait until computation stops only when the convergenceRatio is reached, just set the maxIterationCount to a large amount. Be warned that computation may take a huge amount of time, due to flickering behaviours in later iterations.
# voronoiTreemap.minWeightRatio([minWeightRatio])
If minWeightRatio is specified, sets the minimum weight ratio, which allows to compute the minimum allowed weight (= maxWeight * minWeightRatio). If minWeightRatio is not specified, returns the current minWeightRatio , which defaults to:
1var minWeightRatio = 0.01; // 1% of maxWeight
minWeightRatio allows to mitigate flickerring behaviour (caused by too small weights), and enhances user interaction by not computing near-empty cells.
# voronoiTreemap.prng([prng])
If prng is specified, sets the pseudorandom number generator which is used when randomness is required (i.e. when setting intial random position of data/seeds). The given pseudorandom number generator must implement the same interface as Math.random
and must only return values in the range [0, 1). If prng is not specified, returns the current prng , which defaults to Math.random
.
Considering the same set of data, severall Voronoï treemap computations lead to disctinct final arrangements, due to the non-seedable Math.random
number generator. If prng is set to a seedable PRNG which produces repeatable results, then several computations will produce the exact same final arrangement. This is useful if you want the same arrangement for distinct page loads/reloads. For example, using seedrandom:
1<script src="//cdnjs.cloudflare.com/ajax/libs/seedrandom/2.4.3/seedrandom.min.js"></script> 2<script> 3 var mySeededPrng = new Math.seedrandom('my seed'); // (from seedrandom's doc) Use "new" to create a local prng without altering Math.random 4 voronoiTreemap.prng(mySeededPrng); 5</script>
You can also take a look at d3-random for random number generator from other-than-uniform distributions.
d3-voronoi-treemap attempts to follow semantic versioning and bump major version only when backwards incompatible changes are released.
No vulnerabilities found.
Reason
no binaries found in the repo
Reason
no dangerous workflow patterns detected
Reason
license file detected
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2 existing vulnerabilities detected
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detected GitHub workflow tokens with excessive permissions
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Reason
Found 1/22 approved changesets -- score normalized to 0
Reason
0 commit(s) and 0 issue activity found in the last 90 days -- score normalized to 0
Reason
dependency not pinned by hash detected -- score normalized to 0
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no effort to earn an OpenSSF best practices badge detected
Reason
security policy file not detected
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project is not fuzzed
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Project has not signed or included provenance with any releases.
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branch protection not enabled on development/release branches
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SAST tool is not run on all commits -- score normalized to 0
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Last Scanned on 2024-11-25
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