# Find the tangent of a point on a cubic bezier curve

For a cubic Bézier curve, with the usual four points a, b, c and d,

for a given value t,

how to most elegantly find the tangent at that point?

The tangent of a curve is simply its derivative. The parametric equation that Michal uses:

``````P(t) = (1 - t)^3 * P0 + 3t(1-t)^2 * P1 + 3t^2 (1-t) * P2 + t^3 * P3
``````

should have a derivative of

``````dP(t) / dt =  -3(1-t)^2 * P0 + 3(1-t)^2 * P1 - 6t(1-t) * P1 - 3t^2 * P2 + 6t(1-t) * P2 + 3t^2 * P3
``````

Which, by the way, appears to be wrong in your earlier question. I believe you're using the slope for a quadratic Bezier curve there, not cubic.

From there, it should be trivial to implement a C function that performs this calculation, like Michal has already provided for the curve itself.

Here is fully tested code to copy and paste:

It draws approxidistant points along the curve, and it draws the tangents.

`bezierInterpolation` finds the points

`bezierTangent` finds the tangents

There are TWO VERSIONS of `bezierInterpolation` supplied below:

`bezierInterpolation` works perfectly.

`altBezierInterpolation` is exactly the same, BUT it is written in an expanded, clear, explanatory manner. It makes the arithmetic much easier to understand.

Use either of those two routines: the results are identical.

In both cases, use `bezierTangent` to find the tangents. (Note: Michal's fabulous code base here.)

A full example of how to use with `drawRect:` is also included.

``````// MBBezierView.m    original BY MICHAL stackoverflow #4058979

#import "MBBezierView.h"

CGFloat bezierInterpolation(
CGFloat t, CGFloat a, CGFloat b, CGFloat c, CGFloat d) {
// see also below for another way to do this, that follows the 'coefficients'
// idea, and is a little clearer
CGFloat t2 = t * t;
CGFloat t3 = t2 * t;
return a + (-a * 3 + t * (3 * a - a * t)) * t
+ (3 * b + t * (-6 * b + b * 3 * t)) * t
+ (c * 3 - c * 3 * t) * t2
+ d * t3;
}

CGFloat altBezierInterpolation(
CGFloat t, CGFloat a, CGFloat b, CGFloat c, CGFloat d)
{
// here's an alternative to Michal's bezierInterpolation above.
// the result is absolutely identical.
// of course, you could calculate the four 'coefficients' only once for
// both this and the slope calculation, if desired.
CGFloat C1 = ( d - (3.0 * c) + (3.0 * b) - a );
CGFloat C2 = ( (3.0 * c) - (6.0 * b) + (3.0 * a) );
CGFloat C3 = ( (3.0 * b) - (3.0 * a) );
CGFloat C4 = ( a );

// it's now easy to calculate the point, using those coefficients:
return ( C1*t*t*t + C2*t*t + C3*t + C4  );
}

CGFloat bezierTangent(CGFloat t, CGFloat a, CGFloat b, CGFloat c, CGFloat d)
{
// note that abcd are aka x0 x1 x2 x3

/*  the four coefficients ..
A = x3 - 3 * x2 + 3 * x1 - x0
B = 3 * x2 - 6 * x1 + 3 * x0
C = 3 * x1 - 3 * x0
D = x0

and then...
Vx = 3At2 + 2Bt + C         */

// first calcuate what are usually know as the coeffients,
// they are trivial based on the four control points:

CGFloat C1 = ( d - (3.0 * c) + (3.0 * b) - a );
CGFloat C2 = ( (3.0 * c) - (6.0 * b) + (3.0 * a) );
CGFloat C3 = ( (3.0 * b) - (3.0 * a) );
CGFloat C4 = ( a );  // (not needed for this calculation)

// finally it is easy to calculate the slope element,
// using those coefficients:

return ( ( 3.0 * C1 * t* t ) + ( 2.0 * C2 * t ) + C3 );

// note that this routine works for both the x and y side;
// simply run this routine twice, once for x once for y
// note that there are sometimes said to be 8 (not 4) coefficients,
// these are simply the four for x and four for y,
// calculated as above in each case.
}

@implementation MBBezierView

- (void)drawRect:(CGRect)rect {
CGPoint p1, p2, p3, p4;

p1 = CGPointMake(30, rect.size.height * 0.33);
p2 = CGPointMake(CGRectGetMidX(rect), CGRectGetMinY(rect));
p3 = CGPointMake(CGRectGetMidX(rect), CGRectGetMaxY(rect));
p4 = CGPointMake(-30 + CGRectGetMaxX(rect), rect.size.height * 0.66);

[[UIColor blackColor] set];
[[UIBezierPath bezierPathWithRect:rect] fill];
[[UIColor redColor] setStroke];
UIBezierPath *bezierPath = [[[UIBezierPath alloc] init] autorelease];
[bezierPath moveToPoint:p1];
[bezierPath stroke];

[[UIColor brownColor] setStroke];

// now mark in points along the bezier!

for (CGFloat t = 0.0; t <= 1.00001; t += 0.05) {
[[UIColor brownColor] setStroke];

CGPoint point = CGPointMake(
bezierInterpolation(t, p1.x, p2.x, p3.x, p4.x),
bezierInterpolation(t, p1.y, p2.y, p3.y, p4.y));

// there, use either bezierInterpolation or altBezierInterpolation,
// identical results for the position

// just draw that point to indicate it...
UIBezierPath *pointPath =
[UIBezierPath bezierPathWithArcCenter:point
[pointPath stroke];

// now find the tangent if someone on stackoverflow knows how
CGPoint vel = CGPointMake(
bezierTangent(t, p1.x, p2.x, p3.x, p4.x),
bezierTangent(t, p1.y, p2.y, p3.y, p4.y));

// the following code simply draws an indication of the tangent
CGPoint demo = CGPointMake( point.x + (vel.x*0.3),
point.y + (vel.y*0.33) );
// (the only reason for the .3 is to make the pointers shorter)
[[UIColor whiteColor] setStroke];
UIBezierPath *vp = [UIBezierPath bezierPath];
[vp moveToPoint:point];
[vp stroke];
}
}

@end

to draw that class...
MBBezierView *mm = [[MBBezierView alloc]
initWithFrame:CGRectMake(400,20, 600,700)];
[mm setNeedsDisplay];
``````

Here are the two routines to calculate approximately equidistant points, and the tangents of those, along a bezier cubic.

For clarity and reliability, these routines are written in the simplest, most explanatory, way possible.

``````CGFloat bezierPoint(CGFloat t, CGFloat a, CGFloat b, CGFloat c, CGFloat d)
{
CGFloat C1 = ( d - (3.0 * c) + (3.0 * b) - a );
CGFloat C2 = ( (3.0 * c) - (6.0 * b) + (3.0 * a) );
CGFloat C3 = ( (3.0 * b) - (3.0 * a) );
CGFloat C4 = ( a );

return ( C1*t*t*t + C2*t*t + C3*t + C4  );
}

CGFloat bezierTangent(CGFloat t, CGFloat a, CGFloat b, CGFloat c, CGFloat d)
{
CGFloat C1 = ( d - (3.0 * c) + (3.0 * b) - a );
CGFloat C2 = ( (3.0 * c) - (6.0 * b) + (3.0 * a) );
CGFloat C3 = ( (3.0 * b) - (3.0 * a) );
CGFloat C4 = ( a );

return ( ( 3.0 * C1 * t* t ) + ( 2.0 * C2 * t ) + C3 );
}
``````

The four precalculated values, C1 C2 C3 C4, are sometimes called the coefficients of the bezier. (Recall that a b c d are usually called the four control points.)

Of course, t runs from 0 to 1, for example every 0.05.

Simply call these routines once for X, and then once separately for Y.

Hope it helps someone!

Important facts:

(1) It is an absolute fact that: unfortunately, there is, definitely, NO method, provided by Apple, to extract points from a UIBezierPath. True as of 2019.

(2) Don't forget it's as easy as pie to animate something along a UIBezierPath. Google many examples.

(3) Many ask, "Can't CGPathApply be used to extract the points from a UIBezierPath?" No, CGPathApply is totally unrelated: it simply gives you a list of your "instructions in making any path" (so, "start here", "draw a straight line to this point", etc etc.) The name is confusing but CGPathApply is totally unrelated to bezier paths.

For game programmers - as @Engineer points out you may well want the normal of the tangent, fortunately Apple has vector math built-in:

• Hugely useful, thanks. Note that you should be normalising the tangent once you have calculated it, as the function provides a vector of arbitrary length - actually it grows as `t` grows. This should help others to do that. – Engineer Jul 13 '19 at 17:58
• @Engineer thanks, indeed in many cases you would want to normalize the tangent - and good news, there're actually built-in functions for normalize and other vector math! developer.apple.com/documentation/simd/2896658-simd_normalize – Fattie Jul 14 '19 at 12:18
• Hah, not even using this for Apple related development, and used to writing my own vector code - a good general purpose answer regardless of language / platform. – Engineer Jul 14 '19 at 21:23

I found it too error-prone to use the supplied equations. Too easy to miss a subtle t or misplaced bracket.

By contrast, Wikipedia provides a much clearer, cleaner, derivative IMHO:

...which implements easily in code as:

``````3f * oneMinusT * oneMinusT * (p1 - p0)
+ 6f * t * oneMinusT * (p2 - p1)
+ 3f * t * t * (p3 - p2)
``````

(assuming you have vector-minus configured in your language of choice; question isn't marked as ObjC specifically, and iOS now has several langs available)

• Perfect, but anything this long just breaks in current Swift, unfortunately – Fattie Jun 9 '19 at 1:17

I couldn't get any of this to work until I realized that for parametric equations, (dy/dt)/(dx/dt) = dy/dx

Here goes my Swift implementation.

Which I tried my best to optimize for speed, by eliminating all redundant math operations. i.e. make the minimal numbers of calls to math operations. And use the least possible number of multiplications (which are much more expensive than sums).

There are 0 multiplications to create the bezier. Then 3 multiplications to get a point of bezier. And 2 multiplications to get a tangent to the bezier.

``````struct CubicBezier {

private typealias Me = CubicBezier
typealias Vector = CGVector
typealias Point = CGPoint
typealias Num = CGFloat
typealias Coeficients = (C: Num, S: Num, M: Num, L: Num)

let xCoeficients: Coeficients
let yCoeficients: Coeficients

static func coeficientsOfCurve(from c0: Num, through c1: Num, andThrough c2: Num, to c3: Num) -> Coeficients
{
let _3c0 = c0 + c0 + c0
let _3c1 = c1 + c1 + c1
let _3c2 = c2 + c2 + c2
let _6c1 = _3c1 + _3c1

let C = c3 - _3c2 + _3c1 - c0
let S = _3c2 - _6c1 + _3c0
let M = _3c1 - _3c0
let L = c0

return (C, S, M, L)
}

static func xOrYofCurveWith(coeficients coefs: Coeficients, at t: Num) -> Num
{
let (C, S, M, L) = coefs
return ((C * t + S) * t + M) * t + L
}

static func xOrYofTangentToCurveWith(coeficients coefs: Coeficients, at t: Num) -> Num
{
let (C, S, M, _) = coefs
return ((C + C + C) * t + S + S) * t + M
}

init(from start: Point, through c1: Point, andThrough c2: Point, to end: Point)
{
xCoeficients = Me.coeficientsOfCurve(from: start.x, through: c1.x, andThrough: c2.x, to: end.x)
yCoeficients = Me.coeficientsOfCurve(from: start.y, through: c1.y, andThrough: c2.y, to: end.y)
}

func x(at t: Num) -> Num {
return Me.xOrYofCurveWith(coeficients: xCoeficients, at: t)
}

func y(at t: Num) -> Num {
return Me.xOrYofCurveWith(coeficients: yCoeficients, at: t)
}

func dx(at t: Num) -> Num {
return Me.xOrYofTangentToCurveWith(coeficients: xCoeficients, at: t)
}

func dy(at t: Num) -> Num {
return Me.xOrYofTangentToCurveWith(coeficients: yCoeficients, at: t)
}

func point(at t: Num) -> Point {
return .init(x: x(at: t), y: y(at: t))
}

func tangent(at t: Num) -> Vector {
return .init(dx: dx(at: t), dy: dy(at: t))
}
}
``````

Use like:

``````let bezier = CubicBezier.init(from: .zero, through: .zero, andThrough: .zero, to: .zero)

let point02 = bezier.point(at: 0.2)
let point07 = bezier.point(at: 0.7)

let tangent01 = bezier.tangent(at: 0.1)
let tangent05 = bezier.tangent(at: 0.5)
``````
• I improved the algorithm even more meanwhile, by making sure the compiler won't create multiplications where there is no real need for them to exist. Enjoy. – SirEnder Dec 8 '18 at 8:05