0.9.27 • Public • Published

    Skia Canvas

    Skia Canvas is a browser-less implementation of the HTML Canvas drawing API for Node.js. It is based on Google’s Skia graphics engine and as a result produces very similar results to Chrome’s <canvas> element.

    While the primary goal of this project is to provide a reliable emulation of the standard API according to the spec, it also extends it in a number of areas that are more relevant to the generation of static graphics files rather than ‘live’ display in a browser.

    In particular, Skia Canvas:

    • is fast and compact since all the heavy lifting is done by native code written in Rust and C++

    • can generate output in both raster (JPEG & PNG) and vector (PDF & SVG) image formats

    • can save images to files, return them as Buffers, or encode dataURL strings

    • uses native threads and channels for asynchronous rendering and file I/O

    • can create multiple ‘pages’ on a given canvas and then output them as a single, multi-page PDF or an image-sequence saved to multiple files

    • can simplify, blunt, combine, excerpt, and atomize bézier paths using efficient boolean operations or point-by-point interpolation

    • can fill shapes with vector-based Textures in addition to bitmap-based Patterns and supports line-drawing with custom markers

    • fully supports the CSS filter effects image processing operators

    • offers rich typographic control including:


    If you’re running on a supported platform, installation should be as simple as:

    $ npm install skia-canvas

    This will download a pre-compiled library from the project’s most recent release.

    Platform Support

    The underlying Rust library uses N-API v6 which allows it to run on Node.js versions:

    • 10.20+
    • 12.17+
    • 14.0, 15.0, and later

    Pre-compiled binaries are available for:

    • Linux (x64, arm64, & armhf)
    • macOS (x64 & Apple silicon)
    • Windows (x64)

    Nearly everything you need is statically linked into the library. A notable exception is the Fontconfig library which must be installed separately if you’re running on Linux.

    Running in Docker

    The library is compatible with Linux systems using glibc 2.24 or later as well as Alpine Linux (x64) and the musl C library it favors. In both cases, Fontconfig must be installed on the system for skia-canvas to operate correctly.

    If you are setting up a Dockerfile that uses node as its basis, the simplest approach is to set your FROM image to one of the (Debian-derived) defaults like node:16, node:14, node:12, node:buster, node:stretch, or simply:

    FROM node

    You can also use the ‘slim’ image if you manually install fontconfig:

    FROM node:slim
    RUN apt-get update && apt-get install -y -q --no-install-recommends libfontconfig1

    If you wish to use Alpine as the underlying distribution, you can start with something along the lines of:

    FROM node:alpine
    RUN apk update && apk add fontconfig

    Compiling from Source

    If prebuilt binaries aren’t available for your system you’ll need to compile the portions of this library that directly interface with Skia.

    Start by installing:

    1. The Rust compiler and cargo package manager using rustup
    2. A C compiler toolchain like LLVM/Clang or MSVC
    3. Python 2.7 (used by Skia's build process)
    4. On Linux: Fontconfig and OpenSSL

    Detailed instructions for setting up these dependencies on different operating systems can be found in the ‘Building’ section of the Rust Skia documentation. Once all the necessary compilers and libraries are present, running npm run build will give you a usable library (after a fairly lengthy compilation process).

    Example Usage

    const {Canvas, loadImage} = require('skia-canvas'),
          rand = n => Math.floor(n * Math.random()),
          fs = require('fs')
    let canvas = new Canvas(600, 600),
        ctx = canvas.getContext("2d"),
        {width, height} = canvas;
    // draw a sea of blurred dots filling the canvas
    ctx.filter = 'blur(12px) hue-rotate(20deg)'
    for (let i=0; i<800; i++){
      ctx.fillStyle = `hsl(${rand(40)}deg, 80%, 50%)`
      ctx.arc(rand(width), rand(height), rand(20)+5, 0, 2*Math.PI)
    // mask all of the dots that don't overlap with the text
    ctx.filter = 'none'
    ctx.globalCompositeOperation = 'destination-in'
    ctx.font='italic 480px Times, DejaVu Serif'
    ctx.textAlign = 'center'
    ctx.textBaseline = 'top'
    ctx.fillText('¶', width/2, 0)
    // draw a background behind the clipped text
    ctx.globalCompositeOperation = 'destination-over'
    ctx.fillStyle = '#182927'
    ctx.fillRect(0,0, width,height)
    // render to files using a background thread
    async function render(){
      // save the graphic...
      await canvas.saveAs("pilcrow.png")
      // ...or use a shorthand for canvas.toBuffer("png")
      let pngData = await canvas.png
      // ...or embed it in a string
      console.log(`<img src="${await canvas.toDataURL("png")}">`)
    // ...or save the file synchronously from the main thread

    API Documentation

    Documentation for the key classes and their attributes are listed below—properties are printed in bold and methods have parentheses attached to the name. The instances where Skia Canvas’s behavior goes beyond the standard are marked by a symbol, linking to further details below.

    The library exports a number of classes emulating familiar browser objects including:

    In addition, the module contains:

    • loadImage() a utility function for loading Image objects asynchronously
    • FontLibrary a class allowing you to inspect the system’s installed fonts and load additional ones


    The Canvas object is a stand-in for the HTML <canvas> element. It defines image dimensions and provides a rendering context to draw to it. Once you’re ready to save or display what you’ve drawn, the canvas can save it to a file, or hand it off to you as a data buffer or string to process manually.

    Image Dimensions Rendering Contexts Output
    width pages async
    height getContext() pdf, png, svg, jpg
    newPage() saveAs() / saveAsSync()
    toBuffer() / toBufferSync()
    toDataURL() / toDataURLSync()

    Creating new Canvas objects

    Rather than calling a DOM method to create a new canvas, you can simply call the Canvas constructor with the width and height (in pixels) of the image you’d like to begin drawing.

    let defaultCanvas = new Canvas() // without arguments, defaults to 300 × 150 px
    let squareCanvas = new Canvas(512, 512) // creates a 512 px square

    Saving graphics to files, buffers, and strings

    When the canvas renders images and writes them to disk, it does so in a background thread so as not to block execution within your script. As a result you’ll generally want to deal with the canvas from within an async function and be sure to use the await keyword when accessing any of its output methods or shorthand properties (all of which return Promises):

    In cases where this is not the desired behavior, you can use the synchronous equivalents for the primary export functions. They accept identical arguments to their async versions but block execution and return their values synchronously rather than wrapped in Promises. Also note that the shorthand properties do not have synchronous versions:

    For instance, both of the example functions below will generate PNG & PDF from the canvas, though the first will be more efficient (particularly for parallel contexts like request-handlers in an HTTP server or batch exports):

    let canvas = new Canvas()
    async function normal(){
      let pngURL = await canvas.toDataURL("png")
      let pdfBuffer = await canvas.pdf
    function synchronous(){
      let pngURL = canvas.toDataURLSync("png")
      let pdfBuffer = canvas.toBufferSync("pdf")


    The async property has been deprecated and will be removed in a future release. Use the saveAsSync(), toBufferSync(), and toDataURLSync() methods if the default, asynchronous versions aren't to your liking.


    The canvas’s .pages attribute is an array of CanvasRenderingContext2D objects corresponding to each ‘page’ that has been created. The first page is added when the canvas is initialized and additional ones can be added by calling the newPage() method. Note that all the pages remain drawable persistently, so you don’t have to constrain yourself to modifying the ‘current’ page as you render your document or image sequence.

    .pdf, .svg, .jpg, and .png

    These properties are syntactic sugar for calling the toBuffer() method. Each returns a Node Buffer object with the contents of the canvas in the given format. If more than one page has been added to the canvas, only the most recent one will be included unless you’ve accessed the .pdf property in which case the buffer will contain a multi-page PDF.


    newPage(width, height)

    This method allows for the creation of additional drawing contexts that are fully independent of one another but will be part of the same output batch. It is primarily useful in the context of creating a multi-page PDF but can be used to create multi-file image-sequences in other formats as well. Creating a new page with a different size than the previous one will update the parent Canvas object’s .width and .height attributes but will not affect any other pages that have been created previously.

    The method’s return value is a CanvasRenderingContext2D object which you can either save a reference to or recover later from the .pages array.

    saveAs(filename, {page, format, matte, density=1, quality=0.92, outline=false})

    The saveAs method takes a file path and writes the canvas’s current contents to disk. If the filename ends with an extension that makes its format clear, the second argument is optional. If the filename is ambiguous, you can pass an options object with a format string using names like "png" and "jpeg" or a full mime type like "application/pdf".

    The way multi-page documents are handled depends on the filename argument. If the filename contains the string "{}", it will be used as template for generating a numbered sequence of files—one per page. If no curly braces are found in the filename, only a single file will be saved. That single file will be multi-page in the case of PDF output but for other formats it will contain only the most recently added page.

    An integer can optionally be placed between the braces to indicate the number of padding characters to use for numbering. For instance "page-{}.svg" will generate files of the form page-1.svg whereas "frame-{4}.png" will generate files like frame-0001.png.


    The optional page argument accepts an integer that allows for the individual selection of pages in a multi-page canvas. Note that page indexing starts with page 1 not 0. The page value can also be negative, counting from the end of the canvas’s .pages array. For instance, .saveAs("currentPage.png", {page:-1}) is equivalent to omitting page since they both yield the canvas’s most recently added page.


    The image format to generate, specified either as a mime-type string or file extension. The format argument will take precedence over the type specified through the filename argument’s extension, but is primarily useful when generating a file whose name cannot end with an extension for other reasons.


    The optional matte argument accepts a color-string specifying the background that should be drawn behind the canvas in the exported image. Any transparent portions of the image will be filled with the matte color.


    By default, the images will be at a 1:1 ratio with the canvas's width and height dimensions (i.e., a 72 × 72 canvas will yield a 72 pixel × 72 pixel bitmap). But with screens increasingly operating at higher densities, you’ll frequently want to generate images where an on-canvas 'point' may occupy multiple pixels. The optional density argument allows you to specify this magnification factor using an integer ≥1. As a shorthand, you can also select a density by choosing a filename using the @nx naming convention:

    canvas.saveAs('image.png', {density:2}) // choose the density explicitly
    canvas.saveAs('image@3x.png') // equivalent to setting the density to 3

    The quality option is a number between 0 and 1.0 that controls the level of JPEG compression both when making JPEG files directly and when embedding them in a PDF. If omitted, quality will default to 0.92.


    When generating SVG output containing text, you have two options for how to handle the fonts that were used. By default, SVG files will contain <text> elements that refer to the fonts by name in the embedded stylesheet. This requires that viewers of the SVG have the same fonts available on their system (or accessible as webfonts). Setting the optional outline argument to true will trace all the letterforms and ‘burn’ them into the file as bézier paths. This will result in a much larger file (and one in which the original text strings will be unrecoverable), but it will be viewable regardless of the specifics of the system it’s displayed on.

    toBuffer(format, {page, matte, density, quality, outline})

    Node Buffer objects containing various image formats can be created by passing either a format string like "svg" or a mime-type like "image/svg+xml". An ‘@’ suffix can be added to the format string to specify a pixel-density (for instance, "jpg@2x"). The optional arguments behave the same as in the saveAs method.

    toDataURL(format, {page, matte, density, quality, outline})

    This method accepts the same arguments and behaves similarly to .toBuffer. However instead of returning a Buffer, it returns a string of the form "data:<mime-type>;base64,<image-data>" which can be used as a src attribute in <img> tags, embedded into CSS, etc.


    Most of your interaction with the canvas will actually be directed toward its ‘rendering context’, a supporting object you can acquire by calling the canvas’s getContext() and newPage() methods.

    Canvas State Drawing Pattern & Color Line Style Transform
    canvas clearRect() fillStyle lineCap currentTransform
    beginPath() fillRect() strokeStyle lineDashFit getTransform()
    isPointInPath() strokeRect() createConicGradient() lineDashMarker setTransform()
    isPointInStroke() fillText() createLinearGradient() lineDashOffset resetTransform()
    save() strokeText() createRadialGradient() lineJoin transform()
    restore() fill() createPattern() lineWidth translate()
    clip() stroke() createTexture() miterLimit rotate()
    getLineDash() scale()
    Bezier Paths Typography Images Compositing Effects
    moveTo() direction imageSmoothingEnabled filter
    lineTo() font imageSmoothingQuality globalAlpha
    arcTo() fontVariant createImageData() globalCompositeOperation
    bezierCurveTo() textAlign getImageData() shadowBlur
    conicCurveTo() textBaseline putImageData() shadowColor
    quadraticCurveTo() textTracking drawImage() shadowOffsetX
    closePath() textWrap shadowOffsetY
    arc() measureText()
    ellipse() outlineText()


    By default any line-height value included in a font specification (separated from the font size by a /) will be preserved but ignored. If the textWrap property is set to true, the line-height will control the vertical spacing between lines.


    The context’s .font property follows the CSS 2.1 standard and allows the selection of only a single font-variant type: normal vs small-caps. The full range of CSS 3 font-variant values can be used if assigned to the context’s .fontVariant property (presuming the currently selected font supports them). Note that setting .font will also update the current .fontVariant value, so be sure to set the variant after selecting a typeface.


    To loosen or tighten letter-spacing, set the .textTracking property to an integer representing the amount of space to add/remove in terms of 1/1000’s of an ‘em’ (a.k.a. the current font size). Positive numbers will space out the text (e.g., 100 is a good value for setting all-caps) while negative values will pull the letters closer together (this is only rarely a good idea).

    The tracking value defaults to 0 and settings will persist across changes to the .font property.


    The standard canvas has a rather impoverished typesetting system, allowing for only a single line of text and an approach to width-management that horizontally scales the letterforms (a type-crime if ever there was one). Skia Canvas allows you to opt-out of this single-line world by setting the .textWrap property to true. Doing so affects the behavior of the fillText(), strokeText(), and measureText()


    If a Path2D object is assigned to the context’s lineDashMarker property, it will be used instead of the default dash pattern when setLineDash has been set to a non-empty value. The marker will be drawn at evenly spaced intervals along the path with the distance controlled by the first number in the setLineDash array—any subsequent values are ignored.

    The marker should be a Path2D object centered on (0, 0). Points to the right of the origin will run parallel to the path being stroked. If the marker path ends with a closePath(), the marker will be filled using the current strokeStyle. if the path is not closed, it will be stroked using the current lineWidth/join/cap, miterLimit, and strokeStyle.

    // define marker paths
    let caret = new Path2D()
    caret.lineTo( 0, 0)
    caret.lineTo(-8, 8)
    let dot = new Path2D()
    dot.arc(0, 0, 4, 0, 2*Math.PI)
    dot.closePath() // use fill rather than stroke
    let cross = new Path2D()
    cross.lineTo( 6, 6)
    cross.moveTo(-6, 6)
    cross.lineTo( 6,-6)
    // draw arcs using different markers
    function drawArc(x, color){
      ctx.strokeStyle = color
      ctx.lineWidth = 4
      ctx.arc(x + 120, 120, 100, -Math.PI, -Math.PI/2)
    drawArc(0, "orange")
    ctx.lineDashMarker = caret
    drawArc(100, "deepskyblue")
    ctx.lineDashMarker = dot
    drawArc(200, "limegreen")
    ctx.lineDashMarker = cross
    drawArc(300, "red")
    drawArc(400, "#aaa")

    custom dash markers


    The lineDashFit attribute can be set to "move", "turn", or "follow" and controls how the marker is transformed with each repetition along the path. "move" and "turn" use simple translation and rotation, whereas "follow" will bend the marker to match the dashed path's contours.


    conicCurveTo(cpx, cpy, x, y, weight)

    Adds a line segment connecting the current point to (x, y) but curving toward the control point (cpx, cpy) along the way. The weight argument controls how close the curve will come to the control point. If the weight is 0, the result will be a straight line from the current point to (x, y). With a weight of 1.0, the function is equivalent to calling quadraticCurveTo(). Weights greater than 1.0 will pull the line segment ever closer to the control point.

    createTexture(spacing, {path, line, color, angle, offset=0})

    The createTexture() method returns a CanvasTexture object that can be assigned to the context’s strokeStyle or fillStyle property. Similar to a CanvasPattern, a CanvasTexture defines a repeating pattern that will be drawn instead of a flat color, but textures define their content using vectors rather than bitmaps.

    Textures can be based on a user-provided Path2D object or will draw a stripe pattern of parallel lines if a path isn’t provided.


    The spacing argument is required and defines the rectangular area that each repeating ‘tile’ in the pattern will occupy. It can either be a single number (which will be used for both dimensions) or an array with two numbers (width and height). When creating a stripe pattern, the spacing argument defines the distance between neighboring lines, so providing more than one value is unnecessary.

    The optional second argument can be an object with one or more of the following attributes:


    If set to a Path2D object, the path will be drawn once per tile with its origin in the upper left corner of each tile. Note that the path will not be clipped even if it extends beyond the bounds of the current tile, allowing you to overlap the texture with neighboring tiles.


    If set to a positive number, the path will be stroked rather than filled and the line value will set the width of the stroke.


    By default the texture will be drawn in black (filled if line is undefined, stroked otherwise). The color argument can be set to a string defining the stroke/fill color to be used instead.


    The rectangle defined by the spacing argument will be aligned with the canvas’s horizontal and vertical axes by default. Specifying an angle value (in radians) allows you to rotate this tile grid clockwise relative to its default orientation.


    As with CanvasPattern objects, textures are positioned globally relative to the upper left corner of the canvas—not the corner of the object currently being filled or stroked. To fine-tune the texture’s alignment with individual objects, set the offset argument to an [x, y] array with two numbers that will shift the texture relative to its origin.

    fillText(str, x, y, [width]) & strokeText(str, x, y, [width])

    The text-drawing methods’ behavior is mostly standard unless .textWrap has been set to true, in which case there are 3 main effects:

    1. Manual line breaking via "\n" escapes will be honored rather than converted to spaces
    2. The optional width argument accepted by fillText, strokeText and measureText will be interpreted as a ‘column width’ and used to word-wrap long lines
    3. The line-height setting in the .font value will be used to set the inter-line leading rather than simply being ignored.

    Even when .textWrap is false, the text-drawing methods will never choose a more-condensed weight or otherwise attempt to squeeze your entire string into the measure specified by width. Instead the text will be typeset up through the last word that fits and the rest will be omitted. This can be used in conjunction with the .lines property of the object returned by measureText() to incrementally lay out a long string into, for example, a multi-column layout with an even number of lines in each.

    measureText(str, [width])

    The measureText() method returns a TextMetrics object describing the dimensions of a run of text without actually drawing it to the canvas. Skia Canvas adds an additional property to the metrics object called .lines which contains an array describing the geometry of each line individually.

    Each element of the array contains an object of the form:

    {x, y, width, height, baseline, startIndex, endIndex}

    The x, y, width, and height values define a rectangle that fully encloses the text of a given line relative to the ‘origin’ point you would pass to fillText() or strokeText() (and reflecting the context’s current .textBaseline setting).

    The baseline value is a y-axis offset from the text origin to that particular line’s baseline.

    The startIndex and endIndex values are the indices into the string of the first and last character that were typeset on that line.


    The outlineText() method typesets a string and returns a Path2D containing the shapes of its character glyphs. It will use the context’s current .font, .textAlign, and .textBaseline settings to style the string and will anchor the text relative to the (0, 0) origin point. As a result, you’ll typically want to use the context’s transform-related methods or Path2D’s offset() and transform() to position the path before drawing it to the canvas.

    Note that path-generation uses a more limited typesetting system than fillText() and strokeText(). As such, it ignores any settings made using the .fontVariant or .textTracking properties and does not support multi-line text (regardless of the current .textWrap setting).

    ctx.textBaseline = 'top'
    ctx.font = 'bold 140px Helvetica'
    let ampersand = ctx.outlineText('&')
    for (let i=0; i<8000; i++){
      let x = Math.random() * 100,
          y = Math.random() * 120;
      ctx.fillStyle = path.contains(x, y) ? 'lightblue' : '#eee'
      ctx.fillRect(x, y, 2, 2)

    text converted to a Path2D


    The Path2D class allows you to create paths independent of a given Canvas or graphics context. These paths can be modified over time and drawn repeatedly (potentially on multiple canvases). Path2D objects can also be used as lineDashMarkers or as the repeating pattern in a CanvasTexture.

    Line Segments Shapes Boolean Ops Filters Geometry
    d addPath() complement() interpolate() bounds
    moveTo() arc() difference() jitter() edges
    lineTo() arcTo() intersect() round() contains()
    bezierCurveTo() ellipse() union() simplify() points()
    conicCurveTo() rect() xor() trim() offset()
    quadraticCurveTo() unwind() transform()

    Creating Path2D objects

    Its constructor can be called without any arguments to create a new, empty path object. It can also accept a string using SVG syntax or a reference to an existing Path2D object (which it will return a clone of):

    // three identical (but independent) paths
    let p1 = new Path2D("M 10,10 h 100 v 100 h -100 Z")
    let p2 = new Path2D(p1)
    let p3 = new Path2D()
    p3.rect(10, 10, 100, 100)

    Drawing paths

    A canvas’s context always contains an implicit ‘current’ bézier path which is updated by commands like lineTo() and arcTo() and is drawn to the canvas by calling fill(), stroke(), or clip() without any arguments (aside from an optional winding rule). If you start creating a second path by calling beginPath() the context discards the prior path, forcing you to recreate it by hand if you need it again later.

    You can then use these objects by passing them as the first argument to the context’s fill(), stroke(), and clip() methods (along with an optional second argument specifying the winding rule).



    In the browser, Path2D objects offer very little in the way of introspection—they are mostly-opaque recorders of drawing commands that can be ‘played back’ later on. Skia Canvas offers some additional transparency by allowing you to measure the total amount of space the lines will occupy (though you’ll need to account for the current lineWidth if you plan to draw the path with stroke()).

    The .bounds property returns an object defining the minimal rectangle containing the path:

    {top, left, bottom, right, width, height}


    Contains a string describing the path’s edges using SVG syntax. This property is both readable and writeable (and can be appended to using the += operator).


    Returns an array containing each path segment that has been added to the path so far. Each element of the list is an array of the form ["verb", ...points], mirroring the calling conventions of both Path2D and the rendering context. As a result, the edges may be used to ‘replay’ a sequence of commands such as:

    let original = new Path2D()
    // ... add some contours to the path
    // apply the original path’s edges to a new Path2D
    let clone = new Path2D()
    for (const [verb, ...pts] of original.edges){
    // or use the original path’s edges to draw directly to the context
    for (const [verb, ...pts] of original.edges){

    The array is not a verbtaim transcript of the drawing commands that have been called since some commands (e.g., arc()) will be converted into an equivalent sequence of bézier curves. The full range of verbs and numbers of point arguments is as follows:

      ["moveTo", x, y],
      ["lineTo", x, y],
      ["quadraticCurveTo", cpx, cpy, x, y],
      ["bezierCurveTo", cp1x, cp1y, cp2x, cp2y, x, y],
      ["conicCurveTo", cpx, cpy, x, y, weight],

    contains(x, y)

    Returns true if the point (x, y) is either inside the path or intersects one of its contours.

    complement(), difference(), intersect(), union(), and xor()

    In addition to creating Path2D objects through the constructor, you can use pairs of existing paths in combination to generate new paths based on their degree of overlap. Based on the method you choose, a different boolean relationship will be used to construct the new path. In all the following examples we’ll be starting off with a pair of overlapping shapes:

    let oval = new Path2D()
    oval.arc(100, 100, 100, 0, 2*Math.PI)
    let rect = new Path2D()
    rect.rect(0, 100, 100, 100)

    layered paths

    We can then create a new path by using one of the boolean operations such as:

    let knockout = rect.complement(oval),
        overlap = rect.intersect(oval),
        footprint = rect.union(oval),

    different combinations

    Note that the xor operator is liable to create a path with lines that cross over one another so you’ll get different results when filling it using the "evenodd" winding rule (as shown above) than with "nonzero" (the canvas default).

    interpolate(otherPath, weight)

    When two similar paths share the same sequence of ‘verbs’ and differ only in the point arguments passed to them, the interpolate() method can combine them in different proportions to create a new path. The weight argument controls whether the resulting path resembles the original (at 0.0), the otherPath (at 1.0), or something in between.

    let start = new Path2D()
    start.moveTo(-200, 100)
    start.bezierCurveTo(-300, 100, -200, 200, -300, 200)
    start.bezierCurveTo(-200, 200, -300, 300, -200, 300)
    let end = new Path2D()
    end.moveTo(200, 100)
    end.bezierCurveTo(300, 100, 200, 200, 300, 200)
    end.bezierCurveTo(200, 200, 300, 300, 200, 300)
    let left = start.interpolate(end, .25),
        mean = start.interpolate(end, .5),
        right = start.interpolate(end, .75)

    merging similar paths

    jitter(segmentLength, amount, seed=0)

    The jitter() method will return a new Path2D object obtained by breaking the original path into segments of a given length then applying random offsets to the resulting points. Though the modifications are random, they will be consistent between runs based on the specified seed. Try passing different integer values for the seed until you get results that you like.

    let cube = new Path2D()
    cube.rect(100, 100, 100, 100)
    cube.rect(150, 50, 100, 100)
    cube.moveTo(100, 100)
    cube.lineTo(150, 50)
    cube.moveTo(200, 100)
    cube.lineTo(250, 50)
    cube.moveTo(200, 200)
    cube.lineTo(250, 150)
    let jagged = cube.jitter(1, 2),
        reseed = cube.jitter(1, 2, 1337),
        sketchy = cube.jitter(10, 1)


    offset(dx, dy)

    Returns a copy of the path whose points have been shifted horizontally by dx and vertically by dy.


    The points() method breaks a path into evenly-sized steps and returns the (x, y) positions of the resulting vertices. The step argument determines the amount of distance between neighboring points and defaults to 1 px if omitted.

    let path = new Path2D()
    path.arc(100, 100, 50, 0, 2*Math.PI)
    path.rect(100, 50, 50, 50)
    path = path.simplify()
    for (const [x, y] of path.points(10)){
      ctx.fillRect(x, y, 3, 3)

    sampling points from a path


    Calling round() will return a new Path2D derived from the original path whose corners have been rounded off to the specified radius.

    let spikes = new Path2D()
    spikes.moveTo(50, 225)
    spikes.lineTo(100, 25)
    spikes.lineTo(150, 225)
    spikes.lineTo(200, 25)
    spikes.lineTo(250, 225)
    spikes.lineTo(300, 25)
    let snake = spikes.round(80)

    no sharp edges


    In cases where the contours of a single path overlap one another, it’s often useful to have a way of effectively applying a union operation within the path itself. The simplify method traces the path and returns a new copy that removes any overlapping segments. When called with no arguments it defaults to the "nonzero" winding rule, but can also be called with "evenodd" to preserve overlap regions while still removing edge-crossings.

    let cross = new Path2D(`
      M 10,50 h 100 v 20 h -100 Z
      M 50,10 h 20 v 100 h -20 Z
    let uncrossed = cross.simplify()

    different combinations

    transform(matrix) or transform(a, b, c, d, e, f)

    Returns a new copy of the path whose points have been modified by the specified transform matrix. The matrix’s terms can be passed individually as 6 numbers or as a DOMMatrix object. The original path remains unmodified.

    trim(start, end, inverted)

    The trim() method returns a new Path2D which contains only a portion of the original path. The start and end arguments specify percentages of the original contour as numbers between 0 and 1.0. If both arguments are provided, the new path will be a continuous contour connecting those endpoints. If the inverted argument is set to true, the new path will contain everything from the original except the region between the specified endpoints.

    Passing a single positive number implicitly sets the starting point to 0.0 and uses the supplied argument as the end. Passing a negative value sets the ending point to 1.0 and uses the argument as the start value. In either case, you can include inverted as the second argument to flip the selected contour.

    let orig = new Path2D()
    orig.arc(100, 100, 50, Math.PI, 0)
    let middle = orig.trim(.25, .75),
        endpoints = orig.trim(.25, .75, true),
        left = orig.trim(.25),
        right = orig.trim(-.25)

    trimmed subpaths


    The unwind() method interprets the current path using the "evenodd" winding rule then returns a new path that covers an equivalent area when filled using the "nonzero" rule (i.e., the default behavior of the context’s fill() method).

    This conversion can be useful in situations where a single path contains multiple, overlapping contours and the resulting shape depends on the nesting-depth and direction of the contours.

    let orig = new Path2D(`
      M 0 0 h 100 v 100 h -100 Z
      M 50 30 l 20 20 l -20 20 l -20 -20 Z
    let unwound = orig.unwind()

    convert winding rule subpaths



    The included Image object behaves just like the one in browsers, which is to say that loading images can be verbose, fiddly, and callback-heavy. The loadImage() utility method wraps image loading in a Promise, allowing for more concise initialization. For instance the following snippets are equivalent:

    let img = new Image()
    img.onload = function(){
      ctx.drawImage(img, 100, 100)
    img.src = 'https://example.com/icon.png'
    let img = await loadImage('https://example.com/icon.png')
    ctx.drawImage(img, 100, 100)

    In addition to HTTP URLs, both loadImage() and the Image.src attribute will also accept data URLs, local file paths, and Buffer objects.


    The FontLibrary is a static class which does not need to be instantiated with new. Instead you can access the properties and methods on the global FontLibrary you import from the module and its contents will be shared across all canvases you create.


    The .families property contains a list of family names, merging together all the fonts installed on the system and any fonts that have been added manually through the FontLibrary.use() method. Any of these names can be passed to FontLibrary.family() for more information.


    If the name argument is the name of a known font family, this method will return an object with information about the available weights and styles. For instance, on my system FontLibrary.family("Avenir Next") returns:

      family: 'Avenir Next',
      weights: [ 100, 400, 500, 600, 700, 800 ],
      widths: [ 'normal' ],
      styles: [ 'normal', 'italic' ]

    Asking for details about an unknown family will return undefined.


    Returns true if the family is installed on the system or has been added via FontLibrary.use().

    use(familyName, [...fontPaths])

    The FontLibrary.use() method allows you to dynamically load local font files and use them with your canvases. By default it will use whatever family name is in the font metadata, but this can be overridden by an alias you provide. Since font-wrangling can be messy, use can be called in a number of different ways:

    with a list of file paths
    // with default family name
    // with an alias
    FontLibrary.use("Grizwald", [
    with a list of ‘glob’ patterns
    // with default family name
    // with an alias
    FontLibrary.use("Stinson", ['fonts/Crimson_Pro/*.ttf'])
    multiple families with aliases
      Nieuwveen: ['fonts/AmstelvarAlpha-VF.ttf', 'fonts/AmstelvarAlphaItalic-VF.ttf'],
      Fairway: 'fonts/Raleway/*.ttf'

    The return value will be either a list or an object (matching the style in which it was called) with an entry describing each font file that was added. For instance, one of the entries from the first example could be:

      family: 'Grizwald',
      weight: 600,
      style: 'normal',
      width: 'normal',
      file: 'fonts/Oswald-SemiBold.ttf'


    This project is deeply indebted to the work of the Rust Skia project whose Skia bindings provide a safe and idiomatic interface to the mess of C++ that lies underneath.

    Many thanks to the node-canvas developers for their terrific set of unit tests. In the absence of an Acid Test for canvas, these routines were invaluable.


    npm i @williamdasilva/skia-canvas

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