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I want to get a snapshot of my webgl canvas and I want a high resolution capture so I increased my canvas size. This automatically changes gl.draingBufferWidth and gl.draingBufferWidth. I then set viewport and then render the scene.

My code works correctly in low resolution (under 4000*4000) but in higher resolutions there are many problems.

If the resolution is a bit higher the snapshot not does not completely show. See attached file. If the resolution increases more nothing is shown. And finally at some resolutions my instance of webgl is destroyed and I have to restart the browser to get webgl running again

Is there any way to get a snapshot from webgl canvas with a high-resolution ? Can I use another solution?

  • you mentioned a screenshot but didn't add it – gman Jul 9 '18 at 10:48
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4000x4000 pixel is 4000x4000x4 or 64meg of memory. 8000x8000 is 256meg of memory. Browser's don't like allocating that large chunks of memory and often set limits on the page. So for example you have an 8000x8000 WebGL canvas which requires 2 buffers. The drawingbuffer AND the texture being displayed on the page. The drawingbuffer might be anti-aliases. If it's 4x MSAA then it would require a gig of memory just for that buffer. Then you take a screenshot so another 256meg of memory. So yes, the browser for one reason or another is likely to kill your page.

On top of that WebGL has it's own limits in size. You can look up that limit which is effectively MAX_TEXTURE_SIZE or MAX_VIEWPORT_DIMS. You can see from those about 40% of machines can't drawing larger than 4096 (although if you filter to desktop only it's much better). That number only means what the hardware can do. It's still limited by memory.

One way to kind of maybe solve this issue is to draw the image in parts. How you do that will depend on your app. If you're using a fairly standard perspective matrix for all your rendering you can use slightly different math to render any portion of the view. Most 3d math libraries have a perspective function and most of them also have a corresponding frustum function that is slightly more flexible.

Here's a fairly standard style WebGL simple sample that draws a cube using a typical perspective function

"use strict";

const vs = `
uniform mat4 u_worldViewProjection;

attribute vec4 position;
attribute vec3 normal;

varying vec3 v_normal;

void main() {
  v_normal = normal;
  gl_Position = u_worldViewProjection * position;
}
`;
const fs = `
precision mediump float;

varying vec3 v_normal;

void main() {
  gl_FragColor = vec4(v_normal * .5 + .5, 1);
}
`;

const m4 = twgl.m4;
const gl = document.querySelector("canvas").getContext("webgl");
const programInfo = twgl.createProgramInfo(gl, [vs, fs]);

const bufferInfo = twgl.primitives.createCubeBufferInfo(gl, 2);

twgl.resizeCanvasToDisplaySize(gl.canvas);
gl.viewport(0, 0, gl.canvas.width, gl.canvas.height);

gl.enable(gl.DEPTH_TEST);
gl.enable(gl.CULL_FACE);
gl.clearColor(0.2, 0.2, 0.2, 1);
gl.clear(gl.COLOR_BUFFER_BIT | gl.DEPTH_BUFFER_BIT);

const fov = 30 * Math.PI / 180;
const aspect = gl.canvas.clientWidth / gl.canvas.clientHeight;
const zNear = 0.5;
const zFar = 10;
const projection = m4.perspective(fov, aspect, zNear, zFar);
const eye = [1, 4, -6];
const target = [0, 0, 0];
const up = [0, 1, 0];

const camera = m4.lookAt(eye, target, up);
const view = m4.inverse(camera);
const viewProjection = m4.multiply(projection, view);
const world = m4.rotationY(Math.PI * .33);

gl.useProgram(programInfo.program);
twgl.setBuffersAndAttributes(gl, programInfo, bufferInfo);
twgl.setUniforms(programInfo, {
  u_worldViewProjection: m4.multiply(viewProjection, world),
});
twgl.drawBufferInfo(gl, bufferInfo);
<canvas></canvas>
<script src="https://twgljs.org/dist/4.x/twgl-full.min.js"></script>

And here's the same code rendering at 400x200 in eight 100x100 parts using a typical frustum function instead of perspective

"use strict";

const vs = `
uniform mat4 u_worldViewProjection;

attribute vec4 position;
attribute vec3 normal;

varying vec3 v_normal;

void main() {
  v_normal = normal;
  gl_Position = u_worldViewProjection * position;
}
`;
const fs = `
precision mediump float;

varying vec3 v_normal;

void main() {
  gl_FragColor = vec4(v_normal * .5 + .5, 1);
}
`;

const m4 = twgl.m4;
const gl = document.createElement("canvas").getContext("webgl");
const programInfo = twgl.createProgramInfo(gl, [vs, fs]);

const bufferInfo = twgl.primitives.createCubeBufferInfo(gl, 2);

// size to render
const totalWidth = 400;
const totalHeight = 200;
const partWidth = 100;
const partHeight = 100;

// this fov is for the totalHeight
const fov = 30 * Math.PI / 180;
const aspect = totalWidth / totalHeight;
const zNear = 0.5;
const zFar = 10;

const eye = [1, 4, -6];
const target = [0, 0, 0];
const up = [0, 1, 0];

// since the camera doesn't change let's compute it just once
const camera = m4.lookAt(eye, target, up);
const view = m4.inverse(camera);
const world = m4.rotationY(Math.PI * .33);

const imgRows = []; // this is only to insert in order
for (let y = 0; y < totalHeight; y += partHeight) {
  const imgRow = [];
  imgRows.push(imgRow)
  for (let x = 0; x < totalWidth; x += partWidth) {
    renderPortion(totalWidth, totalHeight, x, y, partWidth, partHeight);
    const img = new Image();
    img.src = gl.canvas.toDataURL();
    imgRow.push(img);
  }
}

// because webgl goes positive up we're generating the rows
// bottom first
imgRows.reverse().forEach((imgRow) => {
  imgRow.forEach(document.body.appendChild.bind(document.body));
  document.body.appendChild(document.createElement("br"));
});

function renderPortion(totalWidth, totalHeight, partX, partY, partWidth, partHeight) {
  gl.canvas.width = partWidth;
  gl.canvas.height = partHeight;
  
  gl.viewport(0, 0, gl.canvas.width, gl.canvas.height);
  
  gl.enable(gl.DEPTH_TEST);
  gl.enable(gl.CULL_FACE);
  gl.clearColor(0.2, 0.2, 0.2, 1);
  gl.clear(gl.COLOR_BUFFER_BIT | gl.DEPTH_BUFFER_BIT);

  // corners at zNear for tital image
  const zNearTotalTop = Math.tan(fov) * 0.5 * zNear;
  const zNearTotalBottom = -zNearTotalTop;
  const zNearTotalLeft = zNearTotalBottom * aspect;
  const zNearTotalRight = zNearTotalTop * aspect;
  
  // width, height at zNear for total image
  const zNearTotalWidth = zNearTotalRight - zNearTotalLeft;
  const zNearTotalHeight = zNearTotalTop - zNearTotalBottom;
  
  const zNearPartLeft = zNearTotalLeft + partX * zNearTotalWidth / totalWidth;   const zNearPartRight = zNearTotalLeft + (partX + partWidth) * zNearTotalWidth / totalWidth;
  const zNearPartBottom = zNearTotalBottom + partY * zNearTotalHeight / totalHeight;
  const zNearPartTop = zNearTotalBottom + (partY + partHeight) * zNearTotalHeight / totalHeight;

  const projection = m4.frustum(zNearPartLeft, zNearPartRight, zNearPartBottom, zNearPartTop, zNear, zFar);
  const viewProjection = m4.multiply(projection, view);

  gl.useProgram(programInfo.program);
  twgl.setBuffersAndAttributes(gl, programInfo, bufferInfo);
  twgl.setUniforms(programInfo, {
    u_worldViewProjection: m4.multiply(viewProjection, world),
  });
  twgl.drawBufferInfo(gl, bufferInfo);
}
img { border: 1px solid red; }
body { line-height: 0 }
<script src="https://twgljs.org/dist/4.x/twgl-full.min.js"></script>

If you run the snippet above you'll see it's generating 8 images

The important parts are this

First we need to decide on the total size we want

const totalWidth = 400;
const totalHeight = 200;

Then we'll make a function that will render any smaller portion of that size

function renderPortion(totalWidth, totalHeight, partX, partY, partWidth, partHeight) {
   ...

We'll set the canvas to the size of the part

  gl.canvas.width = partWidth;
  gl.canvas.height = partHeight;

  gl.viewport(0, 0, gl.canvas.width, gl.canvas.height);

And then compute what we need to pass to the frustum function. First we compute the rectangle at zNear that a perspective matrix would make given our field of view, aspect, and zNear values

  // corners at zNear for total image
  const zNearTotalTop = Math.tan(fov) * 0.5 * zNear;
  const zNearTotalBottom = -zNearTotalTop;
  const zNearTotalLeft = zNearTotalBottom * aspect;
  const zNearTotalRight = zNearTotalTop * aspect;

  // width, height at zNear for total image
  const zNearTotalWidth = zNearTotalRight - zNearTotalLeft;
  const zNearTotalHeight = zNearTotalTop - zNearTotalBottom;

Then we compute the corresponding area at zNear for the part of that we want to render and pass those to frustum to generate a projection matrix.

  const zNearPartLeft = zNearTotalLeft + partX * zNearTotalWidth / totalWidth;   const zNearPartRight = zNearTotalLeft + (partX + partWidth) * zNearTotalWidth / totalWidth;
  const zNearPartBottom = zNearTotalBottom + partY * zNearTotalHeight / totalHeight;
  const zNearPartTop = zNearTotalBottom + (partY + partHeight) * zNearTotalHeight / totalHeight;

  const projection = m4.frustum(zNearPartLeft, zNearPartRight, zNearPartBottom, zNearPartTop, zNear, zFar);

Then we just render like normal

Finally on the outside we have a loop to use the function we just generated to render as many parts as we want at whatever resolution we want.

const totalWidth = 400;
const totalHeight = 200;
const partWidth = 100;
const partHeight = 100;

for (let y = 0; y < totalHeight; y += partHeight) {
  for (let x = 0; x < totalWidth; x += partWidth) {
    renderPortion(totalWidth, totalHeight, x, y, partWidth, partHeight);
    const img = new Image();
    img.src = gl.canvas.toDataURL();
    // do something with image.
  }
}

This will let you render to any size you want but you'll need some other way to assemble the images into one larger image. You may or may not be able to do that in the browser. You could try making a giant 2D canvas and drawing each part into it (that assumes 2d canvas doesn't have the same limits as WebGL). To do that there's no need to make the images, just draw the webgl canvas into the 2d canvas.

Otherwise you might have to send them to a server you create to assemble the image or depending on your use case let the user save them and load them all into an image editing program.

Or if you just want to display them the browser will probably do better with 16x16 1024x1024 images than one 16kx16k image. In that case you probably want to call canvas.toBlob instead of using dataURLs and then call URL.createObjectURL for each blob. That way you won't have these giant dataURL strings sitting around.

Example:

"use strict";

const vs = `
uniform mat4 u_worldViewProjection;

attribute vec4 position;
attribute vec3 normal;

varying vec3 v_normal;

void main() {
  v_normal = normal;
  gl_Position = u_worldViewProjection * position;
}
`;
const fs = `
precision mediump float;

varying vec3 v_normal;

void main() {
  gl_FragColor = vec4(v_normal * .5 + .5, 1);
}
`;

const m4 = twgl.m4;
const gl = document.createElement("canvas").getContext("webgl");
const programInfo = twgl.createProgramInfo(gl, [vs, fs]);

const bufferInfo = twgl.primitives.createCubeBufferInfo(gl, 2);

// size to render
const totalWidth = 16384;
const totalHeight = 16385;
const partWidth = 1024;
const partHeight = 1024;

// this fov is for the totalHeight
const fov = 30 * Math.PI / 180;
const aspect = totalWidth / totalHeight;
const zNear = 0.5;
const zFar = 10;

const eye = [1, 4, -6];
const target = [0, 0, 0];
const up = [0, 1, 0];

// since the camera doesn't change let's compute it just once
const camera = m4.lookAt(eye, target, up);
const view = m4.inverse(camera);
const world = m4.rotationY(Math.PI * .33);

const imgRows = []; // this is only to insert in order
for (let y = 0; y < totalHeight; y += partHeight) {
  const imgRow = [];
  imgRows.push(imgRow)
  for (let x = 0; x < totalWidth; x += partWidth) {
    renderPortion(totalWidth, totalHeight, x, y, partWidth, partHeight);
    const img = new Image();
    gl.canvas.toBlob((blob) => {
      img.src = URL.createObjectURL(blob);
    });
    imgRow.push(img);
  }
}

// because webgl goes positive up we're generating the rows
// bottom first
imgRows.reverse().forEach((imgRow) => {
  const div = document.createElement('div');
  imgRow.forEach(div.appendChild.bind(div));
  document.body.appendChild(div);
});

function renderPortion(totalWidth, totalHeight, partX, partY, partWidth, partHeight) {
  gl.canvas.width = partWidth;
  gl.canvas.height = partHeight;
  
  gl.viewport(0, 0, gl.canvas.width, gl.canvas.height);
  
  gl.enable(gl.DEPTH_TEST);
  gl.enable(gl.CULL_FACE);
  gl.clearColor(0.2, 0.2, 0.2, 1);
  gl.clear(gl.COLOR_BUFFER_BIT | gl.DEPTH_BUFFER_BIT);

  // corners at zNear for tital image
  const zNearTotalTop = Math.tan(fov) * 0.5 * zNear;
  const zNearTotalBottom = -zNearTotalTop;
  const zNearTotalLeft = zNearTotalBottom * aspect;
  const zNearTotalRight = zNearTotalTop * aspect;
  
  // width, height at zNear for total image
  const zNearTotalWidth = zNearTotalRight - zNearTotalLeft;
  const zNearTotalHeight = zNearTotalTop - zNearTotalBottom;
  
  const zNearPartLeft = zNearTotalLeft + partX * zNearTotalWidth / totalWidth;   const zNearPartRight = zNearTotalLeft + (partX + partWidth) * zNearTotalWidth / totalWidth;
  const zNearPartBottom = zNearTotalBottom + partY * zNearTotalHeight / totalHeight;
  const zNearPartTop = zNearTotalBottom + (partY + partHeight) * zNearTotalHeight / totalHeight;

  const projection = m4.frustum(zNearPartLeft, zNearPartRight, zNearPartBottom, zNearPartTop, zNear, zFar);
  const viewProjection = m4.multiply(projection, view);

  gl.useProgram(programInfo.program);
  twgl.setBuffersAndAttributes(gl, programInfo, bufferInfo);
  twgl.setUniforms(programInfo, {
    u_worldViewProjection: m4.multiply(viewProjection, world),
  });
  twgl.drawBufferInfo(gl, bufferInfo);
}
img { border: 1px solid red; }
div { white-space: nowrap; }
body { line-height: 0 }
<script src="https://twgljs.org/dist/4.x/twgl-full.min.js"></script>

If you want the user to be able to download a 16386x16386 image instead of 256 1024x1024 images then yet one more solution is to use the part rendering code above and for each row (or rows) of images write their data to a blobs to manually generate a PNG. This blog post covers manually generating PNGs from data and this answer suggests how to do it for very large data.

update:

Just for fun I wrote this library to help generate giant pngs in the browser.

| improve this answer | |
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Check your maximum renderbuffer size with gl.getParameter(gl.MAX_RENDERBUFFER_SIZE). Your canvas can't be larger than that. Trying to break the limits can make you lose context.

If you want a larger screenshot, you can render it in multiple steps/tiles. It should be fairly easy to adjust your projection transform to achieve that.

| improve this answer | |
  • Why downvote? Max canvas size is determined by RENDERBUFFER_SIZE, not TEXTURE_SIZE. – riv Jul 10 '18 at 11:38
  • I'm only guessing the downvote was because this didn't answer the question? It seems like this answer basically just says "solutions exist" and leaves it up to the questioner to figure out the answer on their own? – gman Aug 6 '18 at 6:08

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