WebGL 2D camera zoom to mouse point

I'm currently building a 2D drawing app in WebGL. I want to implement zoom to point under mouse cursor similar to example in here. But I can't figure out how to apply the solution from that answer in my case.

I have done basic zoom by scaling camera matrix. But it zooms to the top-left corner of the canvas, due to that being the origin (0,0) set by the projection (as far as I understand).

Basic pan & zoom implemented:

My draw function (including matrix computations) looks like this:

``````var projection = null;
var view = null;
var viewProjection = null;

function draw(gl, camera, sceneTree){
// projection matrix
projection = new Float32Array(9);
mat3.projection(projection, gl.canvas.clientWidth, gl.canvas.clientHeight);

// camera matrix
view = new Float32Array(9);
mat3.fromTranslation(view, camera.translation);
mat3.scale(view, view, camera.scale);
// view matrix
mat3.invert(view, view)

// VP matrix
viewProjection = new Float32Array(9);
mat3.multiply(viewProjection, projection, view);

// go through scene tree:
//  - build final matrix for each object
//      e.g: u_matrix = VP x Model (translate x rotate x scale)

// draw each object in scene tree
// ...
}
``````

``````attribute vec2 a_position;

uniform mat3 u_matrix;

void main() {
gl_Position = vec4((u_matrix * vec3(a_position, 1)).xy, 0, 1);
}
``````

Zoom function:

``````
function screenToWorld(screenPos){
// normalized screen position
let nsp = [
2.0 * screenPos[0] / this.gl.canvas.width - 1,
- 2.0 * screenPos[1] / this.gl.canvas.height + 1
];

let inverseVP = new Float32Array(9);
mat3.invert(inverseVP, viewProjection);

let worldPos = [0, 0];
return vec2.transformMat3(worldPos, nsp, inverseVP);
}

var zoomRange = [0.01, 2];

let oldZoom = camera.scale[0];
let zoom = Math.min(Math.max(oldZoom + e.deltaX / 100, zoomRange[0]), zoomRange[1]);

camera.scale = [zoom, zoom];

let zoomPoint = screenToWorld([e.clientX, e.clientY]);
// totally breaks if enable this line
//vec2.copy(camera.translation, zoomPoint);

// call draw function again
draw();

}, false);
``````

If I apply `zoomPoint` to camera translation, the values of `zoomPoint` (and the camera position accordingly) start to raise up uncontrollably with every zoom event (no mater if I zoom in or out) and the objects drawn in the scene go immediately out of view.

Would greatly appreciate any insights or suggestions about what am I doing wrong here. Thanks.

Since you didn't post a minimal reproducible example in the question itself I couldn't test with your math library. Using my own though I was able to zoom like this

``````  const [clipX, clipY] = getClipSpaceMousePosition(e);

// position before zooming
const [preZoomX, preZoomY] = m3.transformPoint(
m3.inverse(viewProjectionMat),
[clipX, clipY]);

// multiply the wheel movement by the current zoom level
// so we zoom less when zoomed in and more when zoomed out
const newZoom = camera.zoom * Math.pow(2, e.deltaY * -0.01);
camera.zoom = Math.max(0.02, Math.min(100, newZoom));

updateViewProjection();

// position after zooming
const [postZoomX, postZoomY] = m3.transformPoint(
m3.inverse(viewProjectionMat),
[clipX, clipY]);

// camera needs to be moved the difference of before and after
camera.x += preZoomX - postZoomX;
camera.y += preZoomY - postZoomY;
``````

Note that zoom is the opposite of scale. If zoom = 2 then I want everything to appear 2x larger. To do that requires shrinking the camera space so we scale that space by 1 / zoom

Example:

``````const canvas = document.querySelector('canvas');
const gl = canvas.getContext('webgl');

const vs = `
attribute vec2 a_position;
uniform mat3 u_matrix;
void main() {
gl_Position = vec4((u_matrix * vec3(a_position, 1)).xy, 0, 1);
}
`;

const fs = `
precision mediump float;
uniform vec4 u_color;
void main() {
gl_FragColor = u_color;
}
`;

const programInfo = twgl.createProgramInfo(gl, [vs, fs]);

// calls gl.createBuffer, gl.bindBuffer, gl.bufferData
const bufferInfo = twgl.createBufferInfoFromArrays(gl, {
a_position: {
numComponents: 2,
data: [
0,  0, // 0----1
40,  0, // |    |
40, 10, // | 3--2
10, 10, // | |
10, 20, // | 4-5
30, 20, // |   |
30, 30, // | 7-6
10, 30, // | |
10, 50, // 9-8
0, 50,
],
},
indices: [
0, 1, 2,
0, 2, 3,
0, 3, 8,
0, 8, 9,
4, 5, 6,
4, 6, 7,
],
});

const camera = {
x: 0,
y: 0,
rotation: 0,
zoom: 1,
};

const scene = [
{ x:  20, y:  20, rotation: 0,       scale: 1,   color: [1,   0, 0, 1], bufferInfo},
{ x: 100, y:  50, rotation: Math.PI, scale: 0.5, color: [0, 0.5, 0, 1], bufferInfo},
{ x: 100, y:  50, rotation: 0,       scale: 2,   color: [0,   0, 1, 1], bufferInfo},
{ x: 200, y: 100, rotation: 0.7,     scale: 1,   color: [1,   0, 1, 1], bufferInfo},
];

let viewProjectionMat;

function makeCameraMatrix() {
const zoomScale = 1 / camera.zoom;
let cameraMat = m3.identity();
cameraMat = m3.translate(cameraMat, camera.x, camera.y);
cameraMat = m3.rotate(cameraMat, camera.rotation);
cameraMat = m3.scale(cameraMat, zoomScale, zoomScale);
return cameraMat;
}

function updateViewProjection() {
// same as ortho(0, width, height, 0, -1, 1)
const projectionMat = m3.projection(gl.canvas.width, gl.canvas.height);
const cameraMat = makeCameraMatrix();
let viewMat = m3.inverse(cameraMat);
viewProjectionMat = m3.multiply(projectionMat, viewMat);
}

function draw() {
gl.clear(gl.COLOR_BUFFER_BIT);

updateViewProjection();

gl.useProgram(programInfo.program);

for (const {x, y, rotation, scale, color, bufferInfo} of scene) {
// calls gl.bindBuffer, gl.enableVertexAttribArray, gl.vertexAttribPointer
twgl.setBuffersAndAttributes(gl, programInfo, bufferInfo);

let mat = m3.identity();
mat = m3.translate(mat, x, y);
mat = m3.rotate(mat, rotation);
mat = m3.scale(mat, scale, scale);

// calls gl.uniformXXX
twgl.setUniforms(programInfo, {
u_matrix: m3.multiply(viewProjectionMat, mat),
u_color: color,
});

// calls gl.drawArrays or gl.drawElements
twgl.drawBufferInfo(gl, bufferInfo);
}
}

draw();

function getClipSpaceMousePosition(e) {
// get canvas relative css position
const rect = canvas.getBoundingClientRect();
const cssX = e.clientX - rect.left;
const cssY = e.clientY - rect.top;

// get normalized 0 to 1 position across and down canvas
const normalizedX = cssX / canvas.clientWidth;
const normalizedY = cssY / canvas.clientHeight;

// convert to clip space
const clipX = normalizedX *  2 - 1;
const clipY = normalizedY * -2 + 1;

return [clipX, clipY];
}

e.preventDefault();
const [clipX, clipY] = getClipSpaceMousePosition(e);

// position before zooming
const [preZoomX, preZoomY] = m3.transformPoint(
m3.inverse(viewProjectionMat),
[clipX, clipY]);

// multiply the wheel movement by the current zoom level
// so we zoom less when zoomed in and more when zoomed out
const newZoom = camera.zoom * Math.pow(2, e.deltaY * -0.01);
camera.zoom = Math.max(0.02, Math.min(100, newZoom));

updateViewProjection();

// position after zooming
const [postZoomX, postZoomY] = m3.transformPoint(
m3.inverse(viewProjectionMat),
[clipX, clipY]);

// camera needs to be moved the difference of before and after
camera.x += preZoomX - postZoomX;
camera.y += preZoomY - postZoomY;

draw();
});``````
``canvas { border: 1px solid black; display: block; }``
``````<canvas></canvas>
<script src="https://twgljs.org/dist/4.x/twgl-full.min.js"></script>
<script src="https://webglfundamentals.org/webgl/resources/m3.js"></script>``````

note that I included camera.rotation just to make sure things worked if rotated. They seem to. Here's one with zoom, pan, and rotate

• `camera.x += preZoomX - postZoomX; camera.y += preZoomY - postZoomY;` Btw, love your tutorials. Great stuff! Maybe you can add one on 2d camera like this? As it has its own nuances comparing to standard 3d camera case. – nicktgn Sep 12 '19 at 7:42
• If I can find the time maybe I'll write it. I actually don't know the best way. Another way which might be more flexible is to just keep a camera matrix for the camera instead of x,y,rotation,zoom. Then you can just apply matrices to the camera matrix to make a new camera matrix. You'd have to orthonormalize it prevent it from building up error but it would probably mean more generic code as all 3 operations, pan, zoom, rotate, would just mutlply some matrices – gman Sep 12 '19 at 8:10
• While the answer addresses the core of the question, zooming out breaks. The zoom calculation in the answer is effectively `camera.zoom += camera.zoom * e.deltaY * -0.01`. So if `e.deltaY` is 100, it sets `camera.zoom` to 0. With `camera.zoom *= Math.pow(2, e.deltaY * -0.01)` you can zoom in or out. Changing the `2` to a smaller value (but still greater than 1) makes the zoom steps more gradual. – whydoubt Sep 12 '19 at 16:37