Source/WebCore/platform/graphics/transforms/TransformState.cpp - WebKit - Git at Google

 /*
  * Copyright (C) 2011 Apple Inc.  All rights reserved.
  *
  * Redistribution and use in source and binary forms, with or without
  * modification, are permitted provided that the following conditions
  * are met:
  * 1. Redistributions of source code must retain the above copyright
  *    notice, this list of conditions and the following disclaimer.
  * 2. Redistributions in binary form must reproduce the above copyright
  *    notice, this list of conditions and the following disclaimer in the
  *    documentation and/or other materials provided with the distribution.
  *
  * THIS SOFTWARE IS PROVIDED BY APPLE INC. ``AS IS'' AND ANY
  * EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
  * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
  * PURPOSE ARE DISCLAIMED.  IN NO EVENT SHALL APPLE INC. OR
  * CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL,
  * EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO,
  * PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR
  * PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY
  * OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
  * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
  * OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
  */

 #include "config.h"
 #include "TransformState.h"

 #include <wtf/Optional.h>

 namespace WebCore {

 TransformState& TransformState::operator=(const TransformState& other)
 {
     m_accumulatedOffset = other.m_accumulatedOffset;
     m_mapPoint = other.m_mapPoint;
     m_mapQuad = other.m_mapQuad;
     if (m_mapPoint)
         m_lastPlanarPoint = other.m_lastPlanarPoint;
     if (m_mapQuad) {
         m_lastPlanarQuad = other.m_lastPlanarQuad;
         if (other.m_lastPlanarSecondaryQuad)
             m_lastPlanarSecondaryQuad = makeUnique<FloatQuad>(*other.m_lastPlanarSecondaryQuad);
         else
             m_lastPlanarSecondaryQuad = nullptr;
     }
     m_accumulatingTransform = other.m_accumulatingTransform;
     m_direction = other.m_direction;

     m_accumulatedTransform = nullptr;

     if (other.m_accumulatedTransform)
         m_accumulatedTransform = makeUnique<TransformationMatrix>(*other.m_accumulatedTransform);

     return *this;
 }

 void TransformState::translateTransform(const LayoutSize& offset)
 {
     if (m_direction == ApplyTransformDirection)
         m_accumulatedTransform->translateRight(offset.width(), offset.height());
     else
         m_accumulatedTransform->translate(offset.width(), offset.height());
 }

 void TransformState::translateMappedCoordinates(const LayoutSize& offset)
 {
     LayoutSize adjustedOffset = (m_direction == ApplyTransformDirection) ? offset : -offset;
     if (m_mapPoint)
         m_lastPlanarPoint.move(adjustedOffset);
     if (m_mapQuad) {
         m_lastPlanarQuad.move(adjustedOffset);
         if (m_lastPlanarSecondaryQuad)
             m_lastPlanarSecondaryQuad->move(adjustedOffset);
     }
 }

 void TransformState::move(const LayoutSize& offset, TransformAccumulation accumulate)
 {
     if (accumulate == FlattenTransform && !m_accumulatedTransform)
         m_accumulatedOffset += offset;
     else {
         applyAccumulatedOffset();
         if (m_accumulatingTransform && m_accumulatedTransform) {
             // If we're accumulating into an existing transform, apply the translation.
             translateTransform(offset);

             // Then flatten if necessary.
             if (accumulate == FlattenTransform)
                 flatten();
         } else
             // Just move the point and/or quad.
             translateMappedCoordinates(offset);
     }
     m_accumulatingTransform = accumulate == AccumulateTransform;
 }

 void TransformState::applyAccumulatedOffset()
 {
     LayoutSize offset = m_accumulatedOffset;
     m_accumulatedOffset = LayoutSize();
     if (!offset.isZero()) {
         if (m_accumulatedTransform) {
             translateTransform(offset);
             flatten();
         } else
             translateMappedCoordinates(offset);
     }
 }

 // FIXME: We transform AffineTransform to TransformationMatrix. This is rather inefficient.
 void TransformState::applyTransform(const AffineTransform& transformFromContainer, TransformAccumulation accumulate, bool* wasClamped)
 {
     applyTransform(transformFromContainer.toTransformationMatrix(), accumulate, wasClamped);
 }

 void TransformState::applyTransform(const TransformationMatrix& transformFromContainer, TransformAccumulation accumulate, bool* wasClamped)
 {
     if (wasClamped)
         *wasClamped = false;

     if (transformFromContainer.isIntegerTranslation()) {
         move(LayoutSize(transformFromContainer.e(), transformFromContainer.f()), accumulate);
         return;
     }

     applyAccumulatedOffset();

     // If we have an accumulated transform from last time, multiply in this transform
     if (m_accumulatedTransform) {
         if (m_direction == ApplyTransformDirection)
             m_accumulatedTransform = makeUnique<TransformationMatrix>(transformFromContainer * *m_accumulatedTransform);
         else
             m_accumulatedTransform->multiply(transformFromContainer);
     } else if (accumulate == AccumulateTransform) {
         // Make one if we started to accumulate
         m_accumulatedTransform = makeUnique<TransformationMatrix>(transformFromContainer);
     }

     if (accumulate == FlattenTransform) {
         const TransformationMatrix* finalTransform = m_accumulatedTransform ? m_accumulatedTransform.get() : &transformFromContainer;
         flattenWithTransform(*finalTransform, wasClamped);
     }
     m_accumulatingTransform = accumulate == AccumulateTransform;
 }

 void TransformState::flatten(bool* wasClamped)
 {
     if (wasClamped)
         *wasClamped = false;

     applyAccumulatedOffset();

     if (!m_accumulatedTransform) {
         m_accumulatingTransform = false;
         return;
     }

     flattenWithTransform(*m_accumulatedTransform, wasClamped);
 }

 FloatPoint TransformState::mappedPoint(bool* wasClamped) const
 {
     if (wasClamped)
         *wasClamped = false;

     FloatPoint point = m_lastPlanarPoint;
     point.move((m_direction == ApplyTransformDirection) ? m_accumulatedOffset : -m_accumulatedOffset);
     if (!m_accumulatedTransform)
         return point;

     if (m_direction == ApplyTransformDirection)
         return m_accumulatedTransform->mapPoint(point);

     return m_accumulatedTransform->inverse().valueOr(TransformationMatrix()).projectPoint(point, wasClamped);
 }

 FloatQuad TransformState::mappedQuad(bool* wasClamped) const
 {
     if (wasClamped)
         *wasClamped = false;

     FloatQuad quad = m_lastPlanarQuad;
     mapQuad(quad, m_direction, wasClamped);
     return quad;
 }

 Optional<FloatQuad> TransformState::mappedSecondaryQuad(bool* wasClamped) const
 {
     if (wasClamped)
         *wasClamped = false;

     if (!m_lastPlanarSecondaryQuad)
         return Optional<FloatQuad>();

     FloatQuad quad = *m_lastPlanarSecondaryQuad;
     mapQuad(quad, m_direction, wasClamped);
     return quad;
 }

 void TransformState::setLastPlanarSecondaryQuad(const FloatQuad* quad)
 {
     if (!quad) {
         m_lastPlanarSecondaryQuad = nullptr;
         return;
     }

     // Map the quad back through any transform or offset back into the last flattening coordinate space.
     FloatQuad backMappedQuad(*quad);
     mapQuad(backMappedQuad, inverseDirection());
     m_lastPlanarSecondaryQuad = makeUnique<FloatQuad>(backMappedQuad);
 }

 void TransformState::mapQuad(FloatQuad& quad, TransformDirection direction, bool* wasClamped) const
 {
     quad.move((direction == ApplyTransformDirection) ? m_accumulatedOffset : -m_accumulatedOffset);
     if (!m_accumulatedTransform)
         return;

     if (direction == ApplyTransformDirection)
         quad = m_accumulatedTransform->mapQuad(quad);

     quad = m_accumulatedTransform->inverse().valueOr(TransformationMatrix()).projectQuad(quad, wasClamped);
 }

 void TransformState::flattenWithTransform(const TransformationMatrix& t, bool* wasClamped)
 {
     if (m_direction == ApplyTransformDirection) {
         if (m_mapPoint)
             m_lastPlanarPoint = t.mapPoint(m_lastPlanarPoint);
         if (m_mapQuad) {
             m_lastPlanarQuad = t.mapQuad(m_lastPlanarQuad);
             if (m_lastPlanarSecondaryQuad)
                 *m_lastPlanarSecondaryQuad = t.mapQuad(*m_lastPlanarSecondaryQuad);
         }

     } else {
         TransformationMatrix inverseTransform = t.inverse().valueOr(TransformationMatrix());
         if (m_mapPoint)
             m_lastPlanarPoint = inverseTransform.projectPoint(m_lastPlanarPoint);
         if (m_mapQuad) {
             m_lastPlanarQuad = inverseTransform.projectQuad(m_lastPlanarQuad, wasClamped);
             if (m_lastPlanarSecondaryQuad)
                 *m_lastPlanarSecondaryQuad = inverseTransform.projectQuad(*m_lastPlanarSecondaryQuad, wasClamped);
         }
     }

     // We could throw away m_accumulatedTransform if we wanted to here, but that
     // would cause thrash when traversing hierarchies with alternating
     // preserve-3d and flat elements.
     if (m_accumulatedTransform)
         m_accumulatedTransform->makeIdentity();
     m_accumulatingTransform = false;
 }

 } // namespace WebCore
	/*
	* Copyright (C) 2011 Apple Inc. All rights reserved.
	*
	* Redistribution and use in source and binary forms, with or without
	* modification, are permitted provided that the following conditions
	* are met:
	* 1. Redistributions of source code must retain the above copyright
	* notice, this list of conditions and the following disclaimer.
	* 2. Redistributions in binary form must reproduce the above copyright
	* notice, this list of conditions and the following disclaimer in the
	* documentation and/or other materials provided with the distribution.
	*
	* THIS SOFTWARE IS PROVIDED BY APPLE INC. ``AS IS'' AND ANY
	* EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
	* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
	* PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL APPLE INC. OR
	* CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL,
	* EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO,
	* PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR
	* PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY
	* OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
	* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
	* OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
	*/

	#include "config.h"
	#include "TransformState.h"

	#include <wtf/Optional.h>

	namespace WebCore {

	TransformState& TransformState::operator=(const TransformState& other)
	{
	m_accumulatedOffset = other.m_accumulatedOffset;
	m_mapPoint = other.m_mapPoint;
	m_mapQuad = other.m_mapQuad;
	if (m_mapPoint)
	m_lastPlanarPoint = other.m_lastPlanarPoint;
	if (m_mapQuad) {
	m_lastPlanarQuad = other.m_lastPlanarQuad;
	if (other.m_lastPlanarSecondaryQuad)
	m_lastPlanarSecondaryQuad = makeUnique<FloatQuad>(*other.m_lastPlanarSecondaryQuad);
	else
	m_lastPlanarSecondaryQuad = nullptr;
	}
	m_accumulatingTransform = other.m_accumulatingTransform;
	m_direction = other.m_direction;

	m_accumulatedTransform = nullptr;

	if (other.m_accumulatedTransform)
	m_accumulatedTransform = makeUnique<TransformationMatrix>(*other.m_accumulatedTransform);

	return *this;
	}

	void TransformState::translateTransform(const LayoutSize& offset)
	{
	if (m_direction == ApplyTransformDirection)
	m_accumulatedTransform->translateRight(offset.width(), offset.height());
	else
	m_accumulatedTransform->translate(offset.width(), offset.height());
	}

	void TransformState::translateMappedCoordinates(const LayoutSize& offset)
	{
	LayoutSize adjustedOffset = (m_direction == ApplyTransformDirection) ? offset : -offset;
	if (m_mapPoint)
	m_lastPlanarPoint.move(adjustedOffset);
	if (m_mapQuad) {
	m_lastPlanarQuad.move(adjustedOffset);
	if (m_lastPlanarSecondaryQuad)
	m_lastPlanarSecondaryQuad->move(adjustedOffset);
	}
	}

	void TransformState::move(const LayoutSize& offset, TransformAccumulation accumulate)
	{
	if (accumulate == FlattenTransform && !m_accumulatedTransform)
	m_accumulatedOffset += offset;
	else {
	applyAccumulatedOffset();
	if (m_accumulatingTransform && m_accumulatedTransform) {
	// If we're accumulating into an existing transform, apply the translation.
	translateTransform(offset);

	// Then flatten if necessary.
	if (accumulate == FlattenTransform)
	flatten();
	} else
	// Just move the point and/or quad.
	translateMappedCoordinates(offset);
	}
	m_accumulatingTransform = accumulate == AccumulateTransform;
	}

	void TransformState::applyAccumulatedOffset()
	{
	LayoutSize offset = m_accumulatedOffset;
	m_accumulatedOffset = LayoutSize();
	if (!offset.isZero()) {
	if (m_accumulatedTransform) {
	translateTransform(offset);
	flatten();
	} else
	translateMappedCoordinates(offset);
	}
	}

	// FIXME: We transform AffineTransform to TransformationMatrix. This is rather inefficient.
	void TransformState::applyTransform(const AffineTransform& transformFromContainer, TransformAccumulation accumulate, bool* wasClamped)
	{
	applyTransform(transformFromContainer.toTransformationMatrix(), accumulate, wasClamped);
	}

	void TransformState::applyTransform(const TransformationMatrix& transformFromContainer, TransformAccumulation accumulate, bool* wasClamped)
	{
	if (wasClamped)
	*wasClamped = false;

	if (transformFromContainer.isIntegerTranslation()) {
	move(LayoutSize(transformFromContainer.e(), transformFromContainer.f()), accumulate);
	return;
	}

	applyAccumulatedOffset();

	// If we have an accumulated transform from last time, multiply in this transform
	if (m_accumulatedTransform) {
	if (m_direction == ApplyTransformDirection)
	m_accumulatedTransform = makeUnique<TransformationMatrix>(transformFromContainer * *m_accumulatedTransform);
	else
	m_accumulatedTransform->multiply(transformFromContainer);
	} else if (accumulate == AccumulateTransform) {
	// Make one if we started to accumulate
	m_accumulatedTransform = makeUnique<TransformationMatrix>(transformFromContainer);
	}

	if (accumulate == FlattenTransform) {
	const TransformationMatrix* finalTransform = m_accumulatedTransform ? m_accumulatedTransform.get() : &transformFromContainer;
	flattenWithTransform(*finalTransform, wasClamped);
	}
	m_accumulatingTransform = accumulate == AccumulateTransform;
	}

	void TransformState::flatten(bool* wasClamped)
	{
	if (wasClamped)
	*wasClamped = false;

	applyAccumulatedOffset();

	if (!m_accumulatedTransform) {
	m_accumulatingTransform = false;
	return;
	}

	flattenWithTransform(*m_accumulatedTransform, wasClamped);
	}

	FloatPoint TransformState::mappedPoint(bool* wasClamped) const
	{
	if (wasClamped)
	*wasClamped = false;

	FloatPoint point = m_lastPlanarPoint;
	point.move((m_direction == ApplyTransformDirection) ? m_accumulatedOffset : -m_accumulatedOffset);
	if (!m_accumulatedTransform)
	return point;

	if (m_direction == ApplyTransformDirection)
	return m_accumulatedTransform->mapPoint(point);

	return m_accumulatedTransform->inverse().valueOr(TransformationMatrix()).projectPoint(point, wasClamped);
	}

	FloatQuad TransformState::mappedQuad(bool* wasClamped) const
	{
	if (wasClamped)
	*wasClamped = false;

	FloatQuad quad = m_lastPlanarQuad;
	mapQuad(quad, m_direction, wasClamped);
	return quad;
	}

	Optional<FloatQuad> TransformState::mappedSecondaryQuad(bool* wasClamped) const
	{
	if (wasClamped)
	*wasClamped = false;

	if (!m_lastPlanarSecondaryQuad)
	return Optional<FloatQuad>();

	FloatQuad quad = *m_lastPlanarSecondaryQuad;
	mapQuad(quad, m_direction, wasClamped);
	return quad;
	}

	void TransformState::setLastPlanarSecondaryQuad(const FloatQuad* quad)
	{
	if (!quad) {
	m_lastPlanarSecondaryQuad = nullptr;
	return;
	}

	// Map the quad back through any transform or offset back into the last flattening coordinate space.
	FloatQuad backMappedQuad(*quad);
	mapQuad(backMappedQuad, inverseDirection());
	m_lastPlanarSecondaryQuad = makeUnique<FloatQuad>(backMappedQuad);
	}

	void TransformState::mapQuad(FloatQuad& quad, TransformDirection direction, bool* wasClamped) const
	{
	quad.move((direction == ApplyTransformDirection) ? m_accumulatedOffset : -m_accumulatedOffset);
	if (!m_accumulatedTransform)
	return;

	if (direction == ApplyTransformDirection)
	quad = m_accumulatedTransform->mapQuad(quad);

	quad = m_accumulatedTransform->inverse().valueOr(TransformationMatrix()).projectQuad(quad, wasClamped);
	}

	void TransformState::flattenWithTransform(const TransformationMatrix& t, bool* wasClamped)
	{
	if (m_direction == ApplyTransformDirection) {
	if (m_mapPoint)
	m_lastPlanarPoint = t.mapPoint(m_lastPlanarPoint);
	if (m_mapQuad) {
	m_lastPlanarQuad = t.mapQuad(m_lastPlanarQuad);
	if (m_lastPlanarSecondaryQuad)
	m_lastPlanarSecondaryQuad = t.mapQuad(m_lastPlanarSecondaryQuad);
	}

	} else {
	TransformationMatrix inverseTransform = t.inverse().valueOr(TransformationMatrix());
	if (m_mapPoint)
	m_lastPlanarPoint = inverseTransform.projectPoint(m_lastPlanarPoint);
	if (m_mapQuad) {
	m_lastPlanarQuad = inverseTransform.projectQuad(m_lastPlanarQuad, wasClamped);
	if (m_lastPlanarSecondaryQuad)
	m_lastPlanarSecondaryQuad = inverseTransform.projectQuad(m_lastPlanarSecondaryQuad, wasClamped);
	}
	}

	// We could throw away m_accumulatedTransform if we wanted to here, but that
	// would cause thrash when traversing hierarchies with alternating
	// preserve-3d and flat elements.
	if (m_accumulatedTransform)
	m_accumulatedTransform->makeIdentity();
	m_accumulatingTransform = false;
	}

	} // namespace WebCore