# Find the tangent of a point on a cubic bezier curve (on an iPhone)

For a cubic bezier curve with the usual four points a,b,c,d ...

For a given value t, how to most elegantly find the tangent at that point?

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Exactly what I was looking for. – Aybe May 29 '12 at 23:26
What's with the downvotes? Very useful. – ananthonline Jun 18 '12 at 20:25
Awesome, works immediately, easily portable. Why don't post as an answer? – Geri Apr 15 at 19:35
it's incredibly handy code no doubt .. because it's "crystal clear" you know? hope it helps! – Joe Blow Apr 15 at 19:58
Please don't post the answer in the question. There's a clue in the name you know. Post the solution as an answer. I haven't rolled back as it's been this way for so long. – ChrisF May 23 at 14:52

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.

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Here is complete code which works and runs:

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

bezierInterpolation finds the points and bezierTangent finds the tangents

Note -- see Find a point, a given distance, along a simple cubic bezier curve. (On an iPhone!) for Michal's fabulous code to find the points along a bezier curve; tangent code is here.

There is also an alternate version of Michal's answer, which is more explanatory.

To repeat, bezierInterpolation finds the points. The routine altBezierInterpolation finds exactly the same points, using the same math. But it is written in a simpler way which is easier to understand. You can use either routine bezierInterpolation or altBezierInterpolation for identical results. In both cases, use bezierTangent to find the tangents.

Finally at the bottom, is a code block containing only the two routines you need for approximately-equidistant points and nothing else.

Hope this saves someone some typing.

``````// 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];
``````

Finally, here in the simplest possible fashion are the two routines to calculate equidistant points (in fact, approximately equidistant) and the tangents of those, along a bezier cubic:

``````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, perhaps for example every 0.05. Simply call these routines once for X and separately once for Y.

Hope it helps someone!

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