obs-StreamFX/data/examples/shaders/transition/spin-blur.effect

// AUTOGENERATED COPYRIGHT HEADER START
// Copyright (C) 2021-2023 Michael Fabian 'Xaymar' Dirks <info@xaymar.com>
// AUTOGENERATED COPYRIGHT HEADER END
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// POSSIBILITY OF SUCH DAMAGE.

//------------------------------------------------------------------------------
// Configuration
//------------------------------------------------------------------------------
#define IS_TRANSITION

//------------------------------------------------------------------------------
// Defines
//------------------------------------------------------------------------------
// Variations of PI/TAU
#define PI   3.141592653
#define TAU  6.283185307
#define PIm2 6.283185307
#define PIb2 1.570796326
#define PIb4 0.785398163

// Phi/Φ = Golden Ratio
#define PHI 1.61803398874989484820459

// e (Eulers Constant)
#define EULERS_CONSTANT 2,7182818284590452353602874713527

// Degrees <-> Radians Conversion
#define TO_RAD(x) (x *  0.017453292)
#define TO_DEG(x) (x * 57.295779513)

//------------------------------------------------------------------------------
// Uniforms
//------------------------------------------------------------------------------
uniform float4x4 ViewProj<
	bool automatic = true;
>;

uniform float4 Time<
	bool automatic = true;
>;

uniform float4 ViewSize<
	bool automatic = true;
>;

// Filter Support
#ifdef IS_FILTER
uniform texture2d InputA<
	bool automatic = true;
>;
#endif

// Transition Support
#ifdef IS_TRANSITION
uniform texture2d InputA<
	bool automatic = true;
>;

uniform texture2d InputB<
	bool automatic = true;
>;

uniform float TransitionTime<
	bool automatic = true;
>;

uniform int2 TransitionSize<
	bool automatic = true;
>;
#endif

uniform int RandomSeed<
	bool automatic = true;
>;

uniform float4x4 Random<
	bool automatic = true;
>;

//------------------------------------------------------------------------------
// Structures
//------------------------------------------------------------------------------
struct VertexInformation {
	float4 position : POSITION;
	float4 texcoord0 : TEXCOORD0;
};

//------------------------------------------------------------------------------
// Samplers
//------------------------------------------------------------------------------
sampler_state PointRepeatSampler {
	Filter    = Point;
	AddressU  = Repeat;
	AddressV  = Repeat;
};
sampler_state LinearRepeatSampler {
	Filter    = Linear;
	AddressU  = Repeat;
	AddressV  = Repeat;
};

sampler_state PointMirrorSampler {
	Filter    = Point;
	AddressU  = Mirror;
	AddressV  = Mirror;
};
sampler_state LinearMirrorSampler {
	Filter    = Linear;
	AddressU  = Mirror;
	AddressV  = Mirror;
};

sampler_state PointClampSampler {
	Filter    = Point;
	AddressU  = Clamp;
	AddressV  = Clamp;
};
sampler_state LinearClampSampler {
	Filter    = Linear;
	AddressU  = Clamp;
	AddressV  = Clamp;
};

//------------------------------------------------------------------------------
// Functions
//------------------------------------------------------------------------------
VertexInformation DefaultVertexShader(VertexInformation vtx) {
	vtx.position = mul(float4(vtx.position.xyz, 1.0), ViewProj);
	return vtx;
};

float2 rotate2d(float2 v, float angle) {
	float s = sin(angle);
	float c = cos(angle);
	float2x2 m = float2x2(c, -s, s, c);
	return mul(m, v);
};

//------------------------------------------------------------------------------
// Options
//------------------------------------------------------------------------------

uniform float2 _400_Offset<
	string name = "Rotation Center";
	string field_type = "slider";
	string suffix = "%";
	float2 minimum = {-50., -50.};
	float2 maximum = {50., 50.};
	float2 scale = {.01, .01};
	float2 step = {.01, .01};
> = {0., 0.};

uniform float _500_Rotation<
	string name = "Rotation";
	string field_type = "slider";
	string suffix = "°";
	float minimum = -180.;
	float maximum =  180.;
	float scale = -1.;
	float step = .01;
> = 90.;

uniform float _600_BlurRotation<
	string name = "Blur Rotation";
	string field_type = "slider";
	string suffix = "°";
	float minimum = -90.;
	float maximum =  90.;
	float scale = 1.;
	float step = .01;
> = 30.;

uniform float _700_TransitionRange<
	string name = "Transition Range";
	string field_type = "slider";
	string suffix = "%";
	float minimum = 0.;
	float maximum = 100.;
	float scale = .01;
	float step = .01;
> = 10.;

uniform int _900_MaximumBlurSamples<
	string name = "Max. Blur Samples";
	string description = "The maximum of samples to use for the Blur effect. Higher number looks nicer, but has way higher GPU usage.";
	string field_type = "slider";
	string suffix = "";
	int minimum = 4;
	int maximum = 128;
	int scale = 1;
	int step = 1;
> = 8;

uniform bool _990_MirrorInsteadOfRepeat<
	string name = "Mirror instead of Repeat";
> = true;

//------------------------------------------------------------------------------
// Effect
//------------------------------------------------------------------------------
// Edge is 50% progress
// Rotates n° forward/backward, then switches to B, then rotates back to zero in the other direction.
// While rotated, blurs around the same axis.
// Starts slow, speeds up to 100%, then slows down again. Looks like sine curve.

float2 uv_to_xy(float2 uv) {
	return ((uv - float2(.5, .5)) + _400_Offset) * TransitionSize.xy;
}

float2 xy_to_uv(float2 xy) {
	return ((xy / TransitionSize.xy) - _400_Offset) + float2(.5, .5);
}

float4 SampleTexture(texture2d tex, float2 uv) {
	if (_990_MirrorInsteadOfRepeat) {
		return tex.Sample(LinearMirrorSampler, uv);
	} else {
		return tex.Sample(LinearRepeatSampler, uv);
	}
}

float4 sample_with_blur(texture2d tex, float2 xy, float max_angle, uint max_steps) {
	float angle_step = max_angle / float(max_steps);

	float4 final = SampleTexture(tex, xy_to_uv(xy));
	for (uint step = 1; step <= max_steps; step++) {
		float angle = angle_step * float(step);
		float2 xy_p = rotate2d(xy, TO_RAD(angle));
		float2 xy_n = rotate2d(xy, TO_RAD(-angle));

		final += SampleTexture(tex, xy_to_uv(xy_p));
		final += SampleTexture(tex, xy_to_uv(xy_n));
	}
	final /= (max_steps * 2u + 1u);

	return final;
}

float4 DefaultPixelShader(VertexInformation vtx) : TARGET {
	// Precalculate some important information.
	float2 uv = vtx.texcoord0.xy;
	// - UV offset towards the "center".
	float2 uv_offset = ((uv - float2(.5, .5)) + _400_Offset);
	float2 xy = uv_to_xy(uv);
	// - Distance to the "center" from the offset coordinates.
	float distance_to_center = distance(uv_offset, float2(.0, 0.));
	// - Maximum Blur Angle
	float max_blur_angle = _600_BlurRotation;
	max_blur_angle *= sin(distance_to_center * PIb2);
	max_blur_angle *= cos((TransitionTime * 2. + 1. ) * PI) * .5 + .5;
	// - Maximum number of samples for blurring.
	uint max_blur_samples = uint(_900_MaximumBlurSamples); // TODO: Calculate this value?

	// Calculate the angle of the effect, this goes to _500_Rotation over 0-50%,
	// then goes back in reverse in order to give the illusion of a continuous
	// motion.
	float angle_a = sin((TransitionTime * 2.) * PIb2 - PIb2) * _500_Rotation + _500_Rotation;
	float angle_b = sin((TransitionTime * 2. - 1.) * PIb2) * _500_Rotation - _500_Rotation ;

	// Generate the rotated XY position for sampling.
	float2 xy_a = rotate2d(xy, TO_RAD(angle_a));
	float2 xy_b = rotate2d(xy, TO_RAD(angle_b));

	// Calculate the weight of A and B.
	// - Convert the transition point to a range from -1 to 1.
	float weight_a = (TransitionTime - .5) * 2.; // We don't actually want this range, but it is easier to work with.
	// - Offset it by the transition range.
	weight_a += _700_TransitionRange;
	// - Divide it by the transition range times two.
	weight_a /= _700_TransitionRange * 2.;
	// - Clamp it back to a range from 0 to 1.
	weight_a = 1. - (cos((clamp(weight_a, 0., 1.) + 1.) * PI) * .5 + .5); // Curve
	//weight_a = 1. - clamp(weight_a, 0., 1.); // Alternative linear
	// - The weight for the B side is the one-minus of the A side.
	float weight_b = 1. - weight_a;

	// Store some immediate information.
	float4 color_a = float4(0., 0., 0., 0.);
	float4 color_b = float4(0., 0., 0., 0.);

	// Only sample A and B if they are needed.
	if (weight_a >= 0.001) {
		color_a = sample_with_blur(InputA, xy_a, max_blur_angle, max_blur_samples);
	}
	if (weight_b >= 0.001) {
		color_b = sample_with_blur(InputB, xy_b, max_blur_angle, max_blur_samples);
	}

	// Return a blended color.
	return lerp(color_a, color_b, weight_b);
};

technique Draw
{
	pass
	{
		vertex_shader = DefaultVertexShader(vtx);
		pixel_shader  = DefaultPixelShader(vtx);
	};
};

technique Version1_Normal
{
	pass
	{
		vertex_shader = DefaultVertexShader(vtx);
		pixel_shader  = DefaultPixelShader(vtx);
	};
};

technique Version1_Mirror
{
	pass
	{
		vertex_shader = DefaultVertexShader(vtx);
		pixel_shader  = DefaultPixelShader(vtx);
	};
};