demos/opengl/gpuhelper.h - mirror - Git at Google

 // This file is part of Eigen, a lightweight C++ template library
 // for linear algebra.
 //
 // Copyright (C) 2008 Gael Guennebaud <gael.guennebaud@inria.fr>
 //
 // This Source Code Form is subject to the terms of the Mozilla
 // Public License v. 2.0. If a copy of the MPL was not distributed
 // with this file, You can obtain one at http://mozilla.org/MPL/2.0/.

 #ifndef EIGEN_GPUHELPER_H
 #define EIGEN_GPUHELPER_H

 #include <Eigen/Geometry>
 #include <GL/gl.h>
 #include <vector>

 using namespace Eigen;

 typedef Vector4f Color;

 class GpuHelper
 {
   public:

     GpuHelper();

     ~GpuHelper();

     enum ProjectionMode2D { PM_Normalized = 1, PM_Viewport = 2 };
     void pushProjectionMode2D(ProjectionMode2D pm);
     void popProjectionMode2D();

     /** Multiply the OpenGL matrix \a matrixTarget by the matrix \a mat.
         Essentially, this helper function automatically calls glMatrixMode(matrixTarget) if required
         and does a proper call to the right glMultMatrix*() function according to the scalar type
         and storage order.
         \warning glMatrixMode() must never be called directly. If your're unsure, use forceMatrixMode().
         \sa Matrix, loadMatrix(), forceMatrixMode()
     */
     template<typename Scalar, int _Flags>
     void multMatrix(const Matrix<Scalar,4,4, _Flags, 4,4>& mat, GLenum matrixTarget);

     /** Load the matrix \a mat to the OpenGL matrix \a matrixTarget.
         Essentially, this helper function automatically calls glMatrixMode(matrixTarget) if required
         and does a proper call to the right glLoadMatrix*() or glLoadIdentity() function according to the scalar type
         and storage order.
         \warning glMatrixMode() must never be called directly. If your're unsure, use forceMatrixMode().
         \sa Matrix, multMatrix(), forceMatrixMode()
     */
     template<typename Scalar, int _Flags>
     void loadMatrix(const Eigen::Matrix<Scalar,4,4, _Flags, 4,4>& mat, GLenum matrixTarget);

     template<typename Scalar, typename Derived>
     void loadMatrix(
         const Eigen::CwiseNullaryOp<Eigen::internal::scalar_identity_op<Scalar>,Derived>&,
         GLenum matrixTarget);

     /** Make the matrix \a matrixTarget the current OpenGL matrix target.
         Call this function before loadMatrix() or multMatrix() if you cannot guarantee that glMatrixMode()
         has never been called after the last loadMatrix() or multMatrix() calls.
         \todo provides a debug mode checking the sanity of the cached matrix mode.
     */
     inline void forceMatrixTarget(GLenum matrixTarget) {glMatrixMode(mCurrentMatrixTarget=matrixTarget);}

     inline void setMatrixTarget(GLenum matrixTarget);

     /** Push the OpenGL matrix \a matrixTarget and load \a mat.
     */
     template<typename Scalar, int _Flags>
     inline void pushMatrix(const Matrix<Scalar,4,4, _Flags, 4,4>& mat, GLenum matrixTarget);

     template<typename Scalar, typename Derived>
     void pushMatrix(
         const Eigen::CwiseNullaryOp<Eigen::internal::scalar_identity_op<Scalar>,Derived>&,
         GLenum matrixTarget);

     /** Push and clone the OpenGL matrix \a matrixTarget
     */
     inline void pushMatrix(GLenum matrixTarget);

     /** Pop the OpenGL matrix \a matrixTarget
     */
     inline void popMatrix(GLenum matrixTarget);

     void drawVector(const Vector3f& position, const Vector3f& vec, const Color& color, float aspect = 50.);
     void drawVectorBox(const Vector3f& position, const Vector3f& vec, const Color& color, float aspect = 50.);
     void drawUnitCube(void);
     void drawUnitSphere(int level=0);

     /// draw the \a nofElement first elements
     inline void draw(GLenum mode, uint nofElement);

     /// draw a range of elements
     inline void draw(GLenum mode, uint start, uint end);

     /// draw an indexed subset
     inline void draw(GLenum mode, const std::vector<uint>* pIndexes);

 protected:

     void update(void);

     GLuint mColorBufferId;
     int mVpWidth, mVpHeight;
     GLenum mCurrentMatrixTarget;
     bool mInitialized;
 };

 /** Singleton shortcut
 */
 extern GpuHelper gpu;


 /** \internal
 */
 template<bool RowMajor, int _Flags> struct GlMatrixHelper;

 template<int _Flags> struct GlMatrixHelper<false,_Flags>
 {
     static void loadMatrix(const Matrix<float, 4,4, _Flags, 4,4>&  mat) { glLoadMatrixf(mat.data()); }
     static void loadMatrix(const Matrix<double,4,4, _Flags, 4,4>& mat) { glLoadMatrixd(mat.data()); }
     static void multMatrix(const Matrix<float, 4,4, _Flags, 4,4>&  mat) { glMultMatrixf(mat.data()); }
     static void multMatrix(const Matrix<double,4,4, _Flags, 4,4>& mat) { glMultMatrixd(mat.data()); }
 };

 template<int _Flags> struct GlMatrixHelper<true,_Flags>
 {
     static void loadMatrix(const Matrix<float, 4,4, _Flags, 4,4>&  mat) { glLoadMatrixf(mat.transpose().eval().data()); }
     static void loadMatrix(const Matrix<double,4,4, _Flags, 4,4>& mat) { glLoadMatrixd(mat.transpose().eval().data()); }
     static void multMatrix(const Matrix<float, 4,4, _Flags, 4,4>&  mat) { glMultMatrixf(mat.transpose().eval().data()); }
     static void multMatrix(const Matrix<double,4,4, _Flags, 4,4>& mat) { glMultMatrixd(mat.transpose().eval().data()); }
 };

 inline void GpuHelper::setMatrixTarget(GLenum matrixTarget)
 {
     if (matrixTarget != mCurrentMatrixTarget)
         glMatrixMode(mCurrentMatrixTarget=matrixTarget);
 }

 template<typename Scalar, int _Flags>
 void GpuHelper::multMatrix(const Matrix<Scalar,4,4, _Flags, 4,4>& mat, GLenum matrixTarget)
 {
     setMatrixTarget(matrixTarget);
     GlMatrixHelper<_Flags&Eigen::RowMajorBit, _Flags>::multMatrix(mat);
 }

 template<typename Scalar, typename Derived>
 void GpuHelper::loadMatrix(
     const Eigen::CwiseNullaryOp<Eigen::internal::scalar_identity_op<Scalar>,Derived>&,
     GLenum matrixTarget)
 {
     setMatrixTarget(matrixTarget);
     glLoadIdentity();
 }

 template<typename Scalar, int _Flags>
 void GpuHelper::loadMatrix(const Eigen::Matrix<Scalar,4,4, _Flags, 4,4>& mat, GLenum matrixTarget)
 {
     setMatrixTarget(matrixTarget);
     GlMatrixHelper<(_Flags&Eigen::RowMajorBit)!=0, _Flags>::loadMatrix(mat);
 }

 inline void GpuHelper::pushMatrix(GLenum matrixTarget)
 {
     setMatrixTarget(matrixTarget);
     glPushMatrix();
 }

 template<typename Scalar, int _Flags>
 inline void GpuHelper::pushMatrix(const Matrix<Scalar,4,4, _Flags, 4,4>& mat, GLenum matrixTarget)
 {
     pushMatrix(matrixTarget);
     GlMatrixHelper<_Flags&Eigen::RowMajorBit,_Flags>::loadMatrix(mat);
 }

 template<typename Scalar, typename Derived>
 void GpuHelper::pushMatrix(
     const Eigen::CwiseNullaryOp<Eigen::internal::scalar_identity_op<Scalar>,Derived>&,
     GLenum matrixTarget)
 {
     pushMatrix(matrixTarget);
     glLoadIdentity();
 }

 inline void GpuHelper::popMatrix(GLenum matrixTarget)
 {
     setMatrixTarget(matrixTarget);
     glPopMatrix();
 }

 inline void GpuHelper::draw(GLenum mode, uint nofElement)
 {
     glDrawArrays(mode, 0, nofElement);
 }


 inline void GpuHelper::draw(GLenum mode, const std::vector<uint>* pIndexes)
 {
     glDrawElements(mode, pIndexes->size(), GL_UNSIGNED_INT, &(pIndexes->front()));
 }

 inline void GpuHelper::draw(GLenum mode, uint start, uint end)
 {
     glDrawArrays(mode, start, end-start);
 }

 #endif // EIGEN_GPUHELPER_H
	// This file is part of Eigen, a lightweight C++ template library
	// for linear algebra.
	//
	// Copyright (C) 2008 Gael Guennebaud <gael.guennebaud@inria.fr>
	//
	// This Source Code Form is subject to the terms of the Mozilla
	// Public License v. 2.0. If a copy of the MPL was not distributed
	// with this file, You can obtain one at http://mozilla.org/MPL/2.0/.

	#ifndef EIGEN_GPUHELPER_H
	#define EIGEN_GPUHELPER_H

	#include <Eigen/Geometry>
	#include <GL/gl.h>
	#include <vector>

	using namespace Eigen;

	typedef Vector4f Color;

	class GpuHelper
	{
	public:

	GpuHelper();

	~GpuHelper();

	enum ProjectionMode2D { PM_Normalized = 1, PM_Viewport = 2 };
	void pushProjectionMode2D(ProjectionMode2D pm);
	void popProjectionMode2D();

	/** Multiply the OpenGL matrix \a matrixTarget by the matrix \a mat.
	Essentially, this helper function automatically calls glMatrixMode(matrixTarget) if required
	and does a proper call to the right glMultMatrix*() function according to the scalar type
	and storage order.
	\warning glMatrixMode() must never be called directly. If your're unsure, use forceMatrixMode().
	\sa Matrix, loadMatrix(), forceMatrixMode()
	*/
	template<typename Scalar, int _Flags>
	void multMatrix(const Matrix<Scalar,4,4, _Flags, 4,4>& mat, GLenum matrixTarget);

	/** Load the matrix \a mat to the OpenGL matrix \a matrixTarget.
	Essentially, this helper function automatically calls glMatrixMode(matrixTarget) if required
	and does a proper call to the right glLoadMatrix*() or glLoadIdentity() function according to the scalar type
	and storage order.
	\warning glMatrixMode() must never be called directly. If your're unsure, use forceMatrixMode().
	\sa Matrix, multMatrix(), forceMatrixMode()
	*/
	template<typename Scalar, int _Flags>
	void loadMatrix(const Eigen::Matrix<Scalar,4,4, _Flags, 4,4>& mat, GLenum matrixTarget);

	template<typename Scalar, typename Derived>
	void loadMatrix(
	const Eigen::CwiseNullaryOp<Eigen::internal::scalar_identity_op<Scalar>,Derived>&,
	GLenum matrixTarget);

	/** Make the matrix \a matrixTarget the current OpenGL matrix target.
	Call this function before loadMatrix() or multMatrix() if you cannot guarantee that glMatrixMode()
	has never been called after the last loadMatrix() or multMatrix() calls.
	\todo provides a debug mode checking the sanity of the cached matrix mode.
	*/
	inline void forceMatrixTarget(GLenum matrixTarget) {glMatrixMode(mCurrentMatrixTarget=matrixTarget);}

	inline void setMatrixTarget(GLenum matrixTarget);

	/** Push the OpenGL matrix \a matrixTarget and load \a mat.
	*/
	template<typename Scalar, int _Flags>
	inline void pushMatrix(const Matrix<Scalar,4,4, _Flags, 4,4>& mat, GLenum matrixTarget);

	template<typename Scalar, typename Derived>
	void pushMatrix(
	const Eigen::CwiseNullaryOp<Eigen::internal::scalar_identity_op<Scalar>,Derived>&,
	GLenum matrixTarget);

	/** Push and clone the OpenGL matrix \a matrixTarget
	*/
	inline void pushMatrix(GLenum matrixTarget);

	/** Pop the OpenGL matrix \a matrixTarget
	*/
	inline void popMatrix(GLenum matrixTarget);

	void drawVector(const Vector3f& position, const Vector3f& vec, const Color& color, float aspect = 50.);
	void drawVectorBox(const Vector3f& position, const Vector3f& vec, const Color& color, float aspect = 50.);
	void drawUnitCube(void);
	void drawUnitSphere(int level=0);

	/// draw the \a nofElement first elements
	inline void draw(GLenum mode, uint nofElement);

	/// draw a range of elements
	inline void draw(GLenum mode, uint start, uint end);

	/// draw an indexed subset
	inline void draw(GLenum mode, const std::vector<uint>* pIndexes);

	protected:

	void update(void);

	GLuint mColorBufferId;
	int mVpWidth, mVpHeight;
	GLenum mCurrentMatrixTarget;
	bool mInitialized;
	};

	/** Singleton shortcut
	*/
	extern GpuHelper gpu;


	/** \internal
	*/
	template<bool RowMajor, int _Flags> struct GlMatrixHelper;

	template<int _Flags> struct GlMatrixHelper<false,_Flags>
	{
	static void loadMatrix(const Matrix<float, 4,4, _Flags, 4,4>& mat) { glLoadMatrixf(mat.data()); }
	static void loadMatrix(const Matrix<double,4,4, _Flags, 4,4>& mat) { glLoadMatrixd(mat.data()); }
	static void multMatrix(const Matrix<float, 4,4, _Flags, 4,4>& mat) { glMultMatrixf(mat.data()); }
	static void multMatrix(const Matrix<double,4,4, _Flags, 4,4>& mat) { glMultMatrixd(mat.data()); }
	};

	template<int _Flags> struct GlMatrixHelper<true,_Flags>
	{
	static void loadMatrix(const Matrix<float, 4,4, _Flags, 4,4>& mat) { glLoadMatrixf(mat.transpose().eval().data()); }
	static void loadMatrix(const Matrix<double,4,4, _Flags, 4,4>& mat) { glLoadMatrixd(mat.transpose().eval().data()); }
	static void multMatrix(const Matrix<float, 4,4, _Flags, 4,4>& mat) { glMultMatrixf(mat.transpose().eval().data()); }
	static void multMatrix(const Matrix<double,4,4, _Flags, 4,4>& mat) { glMultMatrixd(mat.transpose().eval().data()); }
	};

	inline void GpuHelper::setMatrixTarget(GLenum matrixTarget)
	{
	if (matrixTarget != mCurrentMatrixTarget)
	glMatrixMode(mCurrentMatrixTarget=matrixTarget);
	}

	template<typename Scalar, int _Flags>
	void GpuHelper::multMatrix(const Matrix<Scalar,4,4, _Flags, 4,4>& mat, GLenum matrixTarget)
	{
	setMatrixTarget(matrixTarget);
	GlMatrixHelper<_Flags&Eigen::RowMajorBit, _Flags>::multMatrix(mat);
	}

	template<typename Scalar, typename Derived>
	void GpuHelper::loadMatrix(
	const Eigen::CwiseNullaryOp<Eigen::internal::scalar_identity_op<Scalar>,Derived>&,
	GLenum matrixTarget)
	{
	setMatrixTarget(matrixTarget);
	glLoadIdentity();
	}

	template<typename Scalar, int _Flags>
	void GpuHelper::loadMatrix(const Eigen::Matrix<Scalar,4,4, _Flags, 4,4>& mat, GLenum matrixTarget)
	{
	setMatrixTarget(matrixTarget);
	GlMatrixHelper<(_Flags&Eigen::RowMajorBit)!=0, _Flags>::loadMatrix(mat);
	}

	inline void GpuHelper::pushMatrix(GLenum matrixTarget)
	{
	setMatrixTarget(matrixTarget);
	glPushMatrix();
	}

	template<typename Scalar, int _Flags>
	inline void GpuHelper::pushMatrix(const Matrix<Scalar,4,4, _Flags, 4,4>& mat, GLenum matrixTarget)
	{
	pushMatrix(matrixTarget);
	GlMatrixHelper<_Flags&Eigen::RowMajorBit,_Flags>::loadMatrix(mat);
	}

	template<typename Scalar, typename Derived>
	void GpuHelper::pushMatrix(
	const Eigen::CwiseNullaryOp<Eigen::internal::scalar_identity_op<Scalar>,Derived>&,
	GLenum matrixTarget)
	{
	pushMatrix(matrixTarget);
	glLoadIdentity();
	}

	inline void GpuHelper::popMatrix(GLenum matrixTarget)
	{
	setMatrixTarget(matrixTarget);
	glPopMatrix();
	}

	inline void GpuHelper::draw(GLenum mode, uint nofElement)
	{
	glDrawArrays(mode, 0, nofElement);
	}


	inline void GpuHelper::draw(GLenum mode, const std::vector<uint>* pIndexes)
	{
	glDrawElements(mode, pIndexes->size(), GL_UNSIGNED_INT, &(pIndexes->front()));
	}

	inline void GpuHelper::draw(GLenum mode, uint start, uint end)
	{
	glDrawArrays(mode, start, end-start);
	}

	#endif // EIGEN_GPUHELPER_H