src/constraints/rotation_constraint.cpp - external/github.com/rive-app/rive-cpp - Git at Google

 #include "rive/constraints/rotation_constraint.hpp"
 #include "rive/transform_component.hpp"
 #include "rive/math/mat2d.hpp"
 #include "rive/math/math_types.hpp"

 using namespace rive;

 void RotationConstraint::constrain(TransformComponent* component) {
     const Mat2D& transformA = component->worldTransform();
     Mat2D transformB;
     m_ComponentsA = transformA.decompose();
     if (m_Target == nullptr) {
         transformB = transformA;
         m_ComponentsB = m_ComponentsA;
     } else {
         transformB = m_Target->worldTransform();
         if (sourceSpace() == TransformSpace::local) {
             Mat2D inverse;

             if (!getParentWorld(*m_Target).invert(&inverse)) {
                 return;
             }
             transformB = inverse * transformB;
         }

         m_ComponentsB = transformB.decompose();

         if (!doesCopy()) {
             m_ComponentsB.rotation(destSpace() == TransformSpace::local ? 0.0f
                                                                         : m_ComponentsA.rotation());
         } else {
             m_ComponentsB.rotation(m_ComponentsB.rotation() * copyFactor());
             if (offset()) {
                 m_ComponentsB.rotation(m_ComponentsB.rotation() + component->rotation());
             }
         }

         if (destSpace() == TransformSpace::local) {
             // Destination space is in parent transform coordinates. Recompose
             // the parent local transform and get it in world, then decompose
             // the world for interpolation.

             transformB = Mat2D::compose(m_ComponentsB);
             transformB = getParentWorld(*component) * transformB;
             m_ComponentsB = transformB.decompose();
         }
     }
     bool clampLocal = minMaxSpace() == TransformSpace::local;
     if (clampLocal) {
         // Apply min max in local space, so transform to local coordinates
         // first.
         transformB = Mat2D::compose(m_ComponentsB);
         Mat2D inverse;
         if (!getParentWorld(*component).invert(&inverse)) {
             return;
         }
         m_ComponentsB = (inverse * transformB).decompose();
     }
     if (max() && m_ComponentsB.rotation() > maxValue()) {
         m_ComponentsB.rotation(maxValue());
     }
     if (min() && m_ComponentsB.rotation() < minValue()) {
         m_ComponentsB.rotation(minValue());
     }
     if (clampLocal) {
         // Transform back to world.
         transformB = Mat2D::compose(m_ComponentsB);
         transformB = getParentWorld(*component) * transformB;
         m_ComponentsB = transformB.decompose();
     }

     float angleA = std::fmod(m_ComponentsA.rotation(), math::PI * 2);
     float angleB = std::fmod(m_ComponentsB.rotation(), math::PI * 2);
     float diff = angleB - angleA;

     if (diff > math::PI) {
         diff -= math::PI * 2;
     } else if (diff < -math::PI) {
         diff += math::PI * 2;
     }

     m_ComponentsB.rotation(m_ComponentsA.rotation() + diff * strength());
     m_ComponentsB.x(m_ComponentsA.x());
     m_ComponentsB.y(m_ComponentsA.y());
     m_ComponentsB.scaleX(m_ComponentsA.scaleX());
     m_ComponentsB.scaleY(m_ComponentsA.scaleY());
     m_ComponentsB.skew(m_ComponentsA.skew());

     component->mutableWorldTransform() = Mat2D::compose(m_ComponentsB);
 }
	#include "rive/constraints/rotation_constraint.hpp"
	#include "rive/transform_component.hpp"
	#include "rive/math/mat2d.hpp"
	#include "rive/math/math_types.hpp"

	using namespace rive;

	void RotationConstraint::constrain(TransformComponent* component) {
	const Mat2D& transformA = component->worldTransform();
	Mat2D transformB;
	m_ComponentsA = transformA.decompose();
	if (m_Target == nullptr) {
	transformB = transformA;
	m_ComponentsB = m_ComponentsA;
	} else {
	transformB = m_Target->worldTransform();
	if (sourceSpace() == TransformSpace::local) {
	Mat2D inverse;

	if (!getParentWorld(*m_Target).invert(&inverse)) {
	return;
	}
	transformB = inverse * transformB;
	}

	m_ComponentsB = transformB.decompose();

	if (!doesCopy()) {
	m_ComponentsB.rotation(destSpace() == TransformSpace::local ? 0.0f
	: m_ComponentsA.rotation());
	} else {
	m_ComponentsB.rotation(m_ComponentsB.rotation() * copyFactor());
	if (offset()) {
	m_ComponentsB.rotation(m_ComponentsB.rotation() + component->rotation());
	}
	}

	if (destSpace() == TransformSpace::local) {
	// Destination space is in parent transform coordinates. Recompose
	// the parent local transform and get it in world, then decompose
	// the world for interpolation.

	transformB = Mat2D::compose(m_ComponentsB);
	transformB = getParentWorld(component) transformB;
	m_ComponentsB = transformB.decompose();
	}
	}
	bool clampLocal = minMaxSpace() == TransformSpace::local;
	if (clampLocal) {
	// Apply min max in local space, so transform to local coordinates
	// first.
	transformB = Mat2D::compose(m_ComponentsB);
	Mat2D inverse;
	if (!getParentWorld(*component).invert(&inverse)) {
	return;
	}
	m_ComponentsB = (inverse * transformB).decompose();
	}
	if (max() && m_ComponentsB.rotation() > maxValue()) {
	m_ComponentsB.rotation(maxValue());
	}
	if (min() && m_ComponentsB.rotation() < minValue()) {
	m_ComponentsB.rotation(minValue());
	}
	if (clampLocal) {
	// Transform back to world.
	transformB = Mat2D::compose(m_ComponentsB);
	transformB = getParentWorld(component) transformB;
	m_ComponentsB = transformB.decompose();
	}

	float angleA = std::fmod(m_ComponentsA.rotation(), math::PI * 2);
	float angleB = std::fmod(m_ComponentsB.rotation(), math::PI * 2);
	float diff = angleB - angleA;

	if (diff > math::PI) {
	diff -= math::PI * 2;
	} else if (diff < -math::PI) {
	diff += math::PI * 2;
	}

	m_ComponentsB.rotation(m_ComponentsA.rotation() + diff * strength());
	m_ComponentsB.x(m_ComponentsA.x());
	m_ComponentsB.y(m_ComponentsA.y());
	m_ComponentsB.scaleX(m_ComponentsA.scaleX());
	m_ComponentsB.scaleY(m_ComponentsA.scaleY());
	m_ComponentsB.skew(m_ComponentsA.skew());

	component->mutableWorldTransform() = Mat2D::compose(m_ComponentsB);
	}