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OpenGL Computer Graphics

OpenGL Computer Graphics. Programming with Transformations. Topics. Transformations in OpenGL Saving Current Transformation Drawing 3D Scenes with OpenGL OpenGL Functions for Modeling and Viewing. Transformations in OpenGL. CT: current transformation Simplified graphics pipeline

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OpenGL Computer Graphics

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  1. OpenGL Computer Graphics Programming with Transformations

  2. Topics • Transformations in OpenGL • Saving Current Transformation • Drawing 3D Scenes with OpenGL • OpenGL Functions for Modeling and Viewing

  3. Transformations in OpenGL • CT: current transformation • Simplified graphics pipeline • OpenGL maintains so-called modelview matrix • Every vertex passed down the graphics pipeline is multiplied by this matrix V Window-to-Viewport Transformation S Q CT S V Q Viewport World Window Screen Coordinate System Model (Master) Coordinate System World Coordinate System

  4. Transformations in OpenGL • OpenGL is a 3D graphics package • Transformations are 3D • How does it work in 2D? • 2D drawing is done in the xy-plane, z coordinate is 0. • Translation: dz = 0 • Scaling: Sz = 1 • Rotation: z-roll y z x

  5. Transformations in OpenGL • Fundamental Transformations • Translation: glTranslated(dx, dy, dz) for 2D: glTranslated(dx, dy, 0) • Scaling: glScaled(sx, sy, sz) for 2D: glScaled(sx, sy, 1.0) • Rotation: glRotated(angle, ux, uy, uz) for 2D: glRotated(angle, 0, 0, 1) • Transformations does not set CT directly, a matrix is postmultiplied to CT • CT = CT  M

  6. Transformations in OpenGL • Canvas functions • void Canvas:: initCT(void) { glMatrixMode(GL_MODELVIEW); glLoadIdentity(); } • void Canvas:: scale2D(double sx, double sy) { glMatrixMode(GL_MODELVIEW); glScaled(dx, dy, 1.0); }

  7. Transformations in OpenGL • Canvas functions • void Canvas:: translate2D(double dx, double dy) { glMatrixMode(GL_MODELVIEW); glTranslated(dx, dy, 0); } • void Canvas:: rotate2D(double angle) { glMatrixMode(GL_MODELVIEW); glRotated(angle, 0.0, 0.0, 1.0); }

  8. Transformations Example • Draw a house. Draw another house by rotating it through -30° and then translating it through (32, 25) • cvs.initCT(); house(); cvs.translate2D(32, 25); cvs.rotate2D(-30.0); house();

  9. Transformations Example

  10. Transformations Example • Think of it in two different ways • Q =T(32, 25)R(-30)P  CT = CT T(32, 25) R(-30) • Translate the coordinate system through (32, 25) and then rotate it through –30° • The code generated by these two ways is identical.

  11. Saving Current Transformation • We can save and restore CTs using glPushMatrix() and glPopMatrix() • Manipulation of a stack of CT After popCT() After rotate2D() Before After pushCT() CT4 = CT3 Rot CT4 CT3 CT3 CT3 CT3 CT2 CT2 CT2 CT2 CT1 CT1 CT1 CT1

  12. Saving Current Transformation • Canvas functions • void Canvas:: pushCT(void) { glMatrixMode(GL_MODELVIEW); glPushMatrix(); } • void Canvas:: popCT(void) { glMatrixMode(GL_MODELVIEW); glPopMatrix(); }

  13. Saving CT Examples • Master coordinate system: where an object is defined • Modeling transformation: transforms an object from its master coordinate system to world coordinate system to produce an instance • Instance: a picture of an object in the scene

  14. Drawing 3D Scenes with OpenGL • The concept of “camera” (eye) is used for 3D viewing • Our 2D drawing is a special case of 3D drawing far plane y view volume near plane z x eye Viewport window

  15. Drawing 3D Scenes with OpenGL • Camera to produce parallel view of a 3D scene

  16. Drawing 3D Scenes with OpenGL • Simplified OpenGL graphics pipeline VM P Vp clip viewport matrix modelview matrix projection matrix

  17. Drawing 3D Scenes with OpenGL • Modelview matrix = CT • Object transformation + camera transformation • Applying model matrix M then viewing matrix V

  18. Drawing 3D Scenes with OpenGL • Projection matrix • Shifts and scales view volume into a standard cube (extension from –1 to 1) • Distortion can be compensated by viewport transformation later

  19. Drawing 3D Scenes with OpenGL • Viewport matrix • Maps surviving portion of objects into a 3D viewport after clipping is performed • Standard cube  block w/ x and y extending across viewport and z from 0 to 1

  20. OpenGL Modeling and Viewing Functions • Modeling transformation • Translation: glTranslated(dx, dy, dz) • Scaling: glScaled(sx, sy, sz) • Rotation: glRotated(angle, ux, uy, uz) • Camera for parallel projection • glMatrixMode(GL_PROJECTION); glLoadIdentity(); glOrtho(left, right, bottom, top, near, far) • Example • near=2: near plane is 2 units in front of eye far=20: far plane is 20 units in front of eye

  21. OpenGL Modeling and Viewing Functions • Positioning and aiming camera • glMatrixMode(GL_MODELVIEW); glLoadIdentity(); glutLookAt(eye.x, eye.y, eye.z, // eye position look.x, look.y, look.z, // look at point up.x, up.y, up.z) // up vector • Up vector is often set to (0, 1, 0) • glutLookAt() builds a matrix that converts world coordinates into eye coordinates.

  22. Set up a Typical Camera - Example • glMatrixMode(GL_PROJECTION); glLoadIdentity(); glOrtho(-3.2, 3.2, -2.4, 2.4, 1, 50) glMatrixMode(GL_MODELVIEW); glLoadIdentity(); glutLookAt(4, 4, 4, 0, 1, 0, 0, 1, 0) (4, 4, 4) (0, 1, 0)

  23. Transformation Matrix for LookAt • Camera coordinate system • Axes: u, v, n n = eye – look u = up  n v = nu • Origin: eye (looking in the direction –n) • Transformation matrix

  24. Transformation Matrix for LookAt

  25. Elementary 3D Shapes Provided by OpenGL • Cube • glutWireCube(GLdouble size) • size = length of a side • Sphere • glutWireSphere(GLdouble radius, GLint nSlices, GLint nStacks) • Approximated by polygonal faces • nSlices = #polygons around z-axis • nStacks = #bands along z-axis

  26. Elementary 3D Shapes Provided by OpenGL • Torus • glutWireTorus(GLdouble inRad, GLdouble outRad, GLint nSlices, GLint nStacks) • Approximated by polygonal faces • Teapots • glutWireTeapot(GLdouble size) • There are solid counterparts of the wire objects

  27. Plantonic Solids Provided by OpenGL • Tetrahedron • glutWireTetrahedron() • Octahedron • glutWireOctahedron() • Dodecahedron • glutWireDodecahedron() • Icosahedron • glutWireIcosahedron() • All of them are centered at the origin

  28. Plantonic Solids Provided by OpenGL

  29. Cone Provided by OpenGL • Cone • glutWireCone(GLdouble baseRad, GLdouble height, GLint nSlices, GLint nStacks) • Axis coincides with the z-axis • Base rests on xy-plane and extends to z = height • baseRad: radius at z = 0

  30. Tapered Cylinder Provided by OpenGL • Tapered cylinder • gluCylinder(GLUquadricObj *qobj, GLdouble baseRad, GLdouble topRad, GLdouble height, GLint nSlices, GLint nStacks) • Axis coincides with the z-axis • Base rests on xy-plane and extends to z = height • baseRad: radius at z = 0 • topRad: radius at z = height

  31. Tapered Cylinder Provided by OpenGL • A family of shapes distinguished by the value of topRad • To draw, we have to • Deifne a new quadric object • Set drawing style • GLU_LINE: wire frame • GLU_FILL: solid rendering • Draw the object

  32. Tapered Cylinder Provided by OpenGL • Example – wire frame cylinder • GLUquadricObj *qobj; qobj = gluNewQuadric(); gluQuadricDrawStyle(qobj, GLU_LINE); gluCylinder(qobj, baseRad, topRad, height, nSlices, nStacks);

  33. #include <gl/glut.h> //<<<<<<<<<<<<<<<<<<< axis >>>>>>>>>>>>>> void axis(double length) { // draw a z-axis, with cone at end glPushMatrix(); glBegin(GL_LINES); glVertex3d(0, 0, 0); glVertex3d(0,0,length); // along the z-axis glEnd(); glTranslated(0, 0,length -0.2); glutWireCone(0.04, 0.2, 12, 9); glPopMatrix(); }

  34. //<<<<<<<<<<<<<< displayWire >>>>>>>>>>>>>> void displayWire(void) { glMatrixMode(GL_PROJECTION); // set the view volume shape glLoadIdentity(); glOrtho(-2.0*64/48.0, 2.0*64/48.0, -2.0, 2.0, 0.1, 100); glMatrixMode(GL_MODELVIEW); // position and aim the camera glLoadIdentity(); gluLookAt(2.0, 2.0, 2.0, 0.0, 0.0, 0.0, 0.0, 1.0, 0.0); // to obtain the picture shown in Figure 5.59 we have to // change the eye location as follows // gluLookAt(1.0, 1.0, 2.0, 0.0, 0.0, 0.0, 0.0, 1.0, 0.0);

  35. glClear(GL_COLOR_BUFFER_BIT); // clear the screen glColor3d(0,0,0); // draw black lines axis(0.5); // z-axis glPushMatrix(); glRotated(90, 0, 1, 0); axis(0.5); // x-axis glRotated(-90, 1, 0, 0); axis(0.5); // y-axis glPopMatrix(); glPushMatrix(); glTranslated(0.5, 0.5, 0.5); // big cube at (0.5, 0.5, 0.5) glutWireCube(1.0); glPopMatrix();

  36. glPushMatrix(); glTranslated(1.0,1.0,0); // sphere at (1,1,0) glutWireSphere(0.25, 10, 8); glPopMatrix(); glPushMatrix(); glTranslated(1.0,0,1.0); // cone at (1,0,1) glutWireCone(0.2, 0.5, 10, 8); glPopMatrix(); glPushMatrix(); glTranslated(1,1,1); glutWireTeapot(0.2); // teapot at (1,1,1) glPopMatrix();

  37. glPushMatrix(); glTranslated(0, 1.0 ,0); // torus at (0,1,0) glRotated(90.0, 1,0,0); glutWireTorus(0.1, 0.3, 10,10); glPopMatrix(); glPushMatrix(); glTranslated(1.0, 0 ,0); // dodecahedron at (1,0,0) glScaled(0.15, 0.15, 0.15); glutWireDodecahedron(); glPopMatrix();

  38. glPushMatrix(); glTranslated(0, 1.0 ,1.0); // small cube at (0,1,1) glutWireCube(0.25); glPopMatrix(); glPushMatrix(); glTranslated(0, 0 ,1.0); // cylinder at (0,0,1) GLUquadricObj * qobj; qobj = gluNewQuadric(); gluQuadricDrawStyle(qobj,GLU_LINE); gluCylinder(qobj, 0.2, 0.2, 0.4, 8,8); glPopMatrix(); glFlush(); }

  39. //<<<<<<<<<<<<<<<< main >>>>>>>>>>>>>>>> void main(int argc, char **argv) { glutInit(&argc, argv); glutInitDisplayMode(GLUT_SINGLE | GLUT_RGB ); glutInitWindowSize(640,480); glutInitWindowPosition(100, 100); glutCreateWindow("Transformation testbed - wireframes"); glutDisplayFunc(displayWire); glClearColor(1.0f, 1.0f, 1.0f,0.0f); // background is white glViewport(0, 0, 640, 480); glutMainLoop(); }

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