| #include "rive/constraints/scale_constraint.hpp" |
| #include "rive/transform_component.hpp" |
| #include "rive/math/mat2d.hpp" |
| #include <cmath> |
| |
| using namespace rive; |
| |
| void ScaleConstraint::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.scaleX(destSpace() == TransformSpace::local ? 1.0f |
| : m_ComponentsA.scaleX()); |
| } else { |
| m_ComponentsB.scaleX(m_ComponentsB.scaleX() * copyFactor()); |
| if (offset()) { |
| m_ComponentsB.scaleX(m_ComponentsB.scaleX() * component->scaleX()); |
| } |
| } |
| |
| if (!doesCopyY()) { |
| m_ComponentsB.scaleY(destSpace() == TransformSpace::local ? 1.0f |
| : m_ComponentsA.scaleY()); |
| } else { |
| m_ComponentsB.scaleY(m_ComponentsB.scaleY() * copyFactorY()); |
| if (offset()) { |
| m_ComponentsB.scaleY(m_ComponentsB.scaleY() * component->scaleY()); |
| } |
| } |
| |
| 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; |
| } |
| transformB = inverse * transformB; |
| m_ComponentsB = transformB.decompose(); |
| } |
| if (max() && m_ComponentsB.scaleX() > maxValue()) { |
| m_ComponentsB.scaleX(maxValue()); |
| } |
| if (min() && m_ComponentsB.scaleX() < minValue()) { |
| m_ComponentsB.scaleX(minValue()); |
| } |
| if (maxY() && m_ComponentsB.scaleY() > maxValueY()) { |
| m_ComponentsB.scaleY(maxValueY()); |
| } |
| if (minY() && m_ComponentsB.scaleY() < minValueY()) { |
| m_ComponentsB.scaleY(minValueY()); |
| } |
| if (clamplocal) { |
| // Transform back to world. |
| transformB = Mat2D::compose(m_ComponentsB); |
| transformB = getParentWorld(*component) * transformB; |
| m_ComponentsB = transformB.decompose(); |
| } |
| |
| float t = strength(); |
| float ti = 1.0f - t; |
| |
| m_ComponentsB.rotation(m_ComponentsA.rotation()); |
| m_ComponentsB.x(m_ComponentsA.x()); |
| m_ComponentsB.y(m_ComponentsA.y()); |
| m_ComponentsB.scaleX(m_ComponentsA.scaleX() * ti + m_ComponentsB.scaleX() * t); |
| m_ComponentsB.scaleY(m_ComponentsA.scaleY() * ti + m_ComponentsB.scaleY() * t); |
| m_ComponentsB.skew(m_ComponentsA.skew()); |
| |
| component->mutableWorldTransform() = Mat2D::compose(m_ComponentsB); |
| } |
