User:Hg200: Difference between revisions
mNo edit summary |
mNo edit summary |
||
(4 intermediate revisions by the same user not shown) | |||
Line 1: | Line 1: | ||
= OpenGL coordinate systems = | |||
In the Octave plotting backend, we find various OpenGL transformations. Some of the classic OpenGL transformation steps, as well as coordinate systems, are shown in the following picture: | In the Octave plotting backend, we find various OpenGL transformations. Some of the classic OpenGL transformation steps, as well as coordinate systems, are shown in the following picture: | ||
Line 9: | Line 5: | ||
[[File:Octave_coordinate_systems.png|center|350px]] | [[File:Octave_coordinate_systems.png|center|350px]] | ||
= The Octave coordinate system = | |||
In Octave a plot scene is defined by a "view point", a "camera target" and an "up vector". | In Octave a plot scene is defined by a "view point", a "camera target" and an "up vector". | ||
[[File:Octave_view_point_setup_to_scale.png|center|750px]] | [[File:Octave_view_point_setup_to_scale.png|center|750px]] | ||
= update_camera() = | |||
In the second part of <math display="inline">\rightarrow</math> "axes::properties::update_camera ()" the view transformation "x_gl_mat1" and projection matrix "x_gl_mat2" are put together. The following chapter illustrates some of the properties of "x_gl_mat1" and "x_gl_mat2". | |||
== The role of "x_gl_mat1" == | == The role of "x_gl_mat1" == | ||
=== x_view === | |||
The following section of code composes the matrix "x_view", which is a subset of "x_gl_mat1". The matrix "x_gl_mat1" consists of multiple translations, scales and one rotation operation. | The following section of code composes the matrix "x_view", which is a major subset of "x_gl_mat1". The matrix "x_gl_mat1" consists of multiple translations, scales and one rotation operation. The individual operation steps are shown in a picture below. | ||
{{Code|Section of axes::properties::update_camera ()"|<syntaxhighlight lang="C" style="font-size:13px"> | {{Code|Section of axes::properties::update_camera ()"|<syntaxhighlight lang="C" style="font-size:13px"> | ||
Line 56: | Line 57: | ||
</syntaxhighlight>}} | </syntaxhighlight>}} | ||
=== x_gl_mat1 === | |||
[[File:Octave_x_gl_mat1_setup.png|center| | To visualize the matrix properties, the "x_gl_mat1" matrix is multiplied by the object coordinates. After the transformation, the plot box is aligned with the Z-axis and the view point is at the origin <math display="inline">[0,0,0]</math>. The matrix transforms world coordinates into camera coordinates. The purple planes show the near and far clipping planes. | ||
[[File:Octave_x_gl_mat1_setup.png|center|300px]] | |||
The individual translation, scaling and rotation operations of "x_gl_mat1", are shown in the following figure: | The individual translation, scaling and rotation operations of "x_gl_mat1", are shown in the following figure: | ||
Line 66: | Line 69: | ||
== The role of "x_gl_mat2" == | == The role of "x_gl_mat2" == | ||
The matrix "x_gl_mat2" is composed of the sub matrices "x_viewport" and "x_projection". The purpose of these matrices is to fit the 2D image of the above transformation result into a "bounding box". The bounding box is defined as follows: | === Bounding box === | ||
The matrix "x_gl_mat2" is composed of the sub matrices "x_viewport" and "x_projection". The purpose of these matrices is to fit the associated 2D image of the above transformation result into a "bounding box". The bounding box is defined as follows: | |||
* bb(0), bb(1): Position of the "viewport" | |||
* bb(2), bb(3): Width and height of the "viewport" | |||
Hint: If you debug in "update_camera ()", you can print "bb": | Hint: If you debug in "update_camera ()", you can print "bb": | ||
(gdb) print *bb.rep.data@bb.rep.len | (gdb) print *bb.rep.data@bb.rep.len | ||
(gdb) $1 = {72.79, 31.50, 434, 342.29} | |||
Compare the result with the output | Compare the result with the output on the Octave prompt: | ||
hax = axes (); | hax = axes (); | ||
get (hax, "position") | get (hax, "position") | ||
ans = 73.80 47.20 434.00 342.30 | |||
get (gcf, 'position') | |||
ans = 22 300 560 420 | |||
Where 420 - 342.30 - 31.5 + 1 = 47.20 | |||
In the following simplified code section the matrix "x_projection" is | === x_projection === | ||
In the following simplified code section the matrix "x_projection" is composed. It is used to normalize the image of the above transformation. For this purpose, the field of view (FOV) must be calculated: | |||
{{Code|Section of axes::properties::update_camera ()"|<syntaxhighlight lang="C" style="font-size:13px"> | {{Code|Section of axes::properties::update_camera ()"|<syntaxhighlight lang="C" style="font-size:13px"> | ||
Line 105: | Line 118: | ||
v_angle = get_cameraviewangle (); | v_angle = get_cameraviewangle (); | ||
// x_projection | // x_projection: identity "diag([1, 1, 1, 1])" | ||
Matrix x_projection = xform_matrix (); | Matrix x_projection = xform_matrix (); | ||
// Calculate backwards from the angle to the ratio. This step | // Calculate backwards from the angle to the ratio. This step | ||
Line 114: | Line 127: | ||
</syntaxhighlight>}} | </syntaxhighlight>}} | ||
"x_viewport" is a | === x_viewport === | ||
"x_viewport" is a transformation used to place the previously "normalized" plot box in the center and to fit it tightly into the bounding box: | |||
{{Code|Section of axes::properties::update_camera ()"|<syntaxhighlight lang="C" style="font-size:13px"> | {{Code|Section of axes::properties::update_camera ()"|<syntaxhighlight lang="C" style="font-size:13px"> | ||
Line 128: | Line 143: | ||
pix = (bb(2) < bb(3) ? bb(2) : bb(3)); | pix = (bb(2) < bb(3) ? bb(2) : bb(3)); | ||
// x_viewport | // x_viewport: identity "diag([1, 1, 1, 1])" | ||
Matrix x_viewport = xform_matrix (); | Matrix x_viewport = xform_matrix (); | ||
// Move to the center of the bounding box inside the figure. | // Move to the center of the bounding box inside the figure. | ||
Line 138: | Line 153: | ||
</syntaxhighlight>}} | </syntaxhighlight>}} | ||
Note: The matrix "x_gl_mat2" | Note: The matrix "x_gl_mat2" scales x, y. However the z-coordinate is not modified! | ||
= setup_opengl_transformation () = | |||
== OpenGL backend == | |||
In the OpenGL backend, the view matrix, an orthographic matrix, and the viewport transform are used to transform the octave plot into the screen window. | |||
{{Code|Section of opengl_renderer::setup_opengl_transformation ()"|<syntaxhighlight lang="C" style="font-size:13px"> | |||
Matrix x_zlim = props.get_transform_zlim (); | |||
xZ1 = x_zlim(0)-(x_zlim(1)-x_zlim(0))/2; | |||
xZ2 = x_zlim(1)+(x_zlim(1)-x_zlim(0))/2; | |||
// Load x_gl_mat1 and x_gl_mat2 | |||
Matrix x_mat1 = props.get_opengl_matrix_1 (); | |||
Matrix x_mat2 = props.get_opengl_matrix_2 (); | |||
m_glfcns.glMatrixMode (GL_MODELVIEW); | |||
m_glfcns.glLoadIdentity (); | |||
m_glfcns.glScaled (1, 1, -1); | |||
// Matrix x_gl_mat1 | |||
m_glfcns.glMultMatrixd (x_mat1.data ()); | |||
m_glfcns.glMatrixMode (GL_PROJECTION); | |||
m_glfcns.glLoadIdentity (); | |||
Matrix vp = get_viewport_scaled (); | |||
// Install orthographic projection matrix with viewport | |||
// setting "0, vp(2), vp(3), 0" and near / far values "xZ1, xZ2" | |||
m_glfcns.glOrtho (0, vp(2), vp(3), 0, xZ1, xZ2); | |||
// Matrix x_gl_mat2 | |||
m_glfcns.glMultMatrixd (x_mat2.data ()); | |||
m_glfcns.glMatrixMode (GL_MODELVIEW); | |||
m_glfcns.glClear (GL_DEPTH_BUFFER_BIT); | |||
</syntaxhighlight>}} | |||
Hint: If you debug in "setup_opengl_transformation ()", you can print the viewport "vp": | |||
(gdb) print *vp.rep.data@vp.rep.len | |||
(gdb) $1 = {0, 0, 560, 420} | |||
This is consistent with the window size. |
Latest revision as of 21:04, 4 January 2021
OpenGL coordinate systems[edit]
In the Octave plotting backend, we find various OpenGL transformations. Some of the classic OpenGL transformation steps, as well as coordinate systems, are shown in the following picture:
The Octave coordinate system[edit]
In Octave a plot scene is defined by a "view point", a "camera target" and an "up vector".
update_camera()[edit]
In the second part of "axes::properties::update_camera ()" the view transformation "x_gl_mat1" and projection matrix "x_gl_mat2" are put together. The following chapter illustrates some of the properties of "x_gl_mat1" and "x_gl_mat2".
The role of "x_gl_mat1"[edit]
x_view[edit]
The following section of code composes the matrix "x_view", which is a major subset of "x_gl_mat1". The matrix "x_gl_mat1" consists of multiple translations, scales and one rotation operation. The individual operation steps are shown in a picture below.
Code: Section of axes::properties::update_camera ()" |
// Unit length vector for direction of view "f" and up vector "UP"
ColumnVector F (c_center), f (F), UP (c_upv);
normalize (f);
normalize (UP);
// Scale "UP" vector, so that norm(f x UP) becomes 1
if (std::abs (dot (f, UP)) > 1e-15)
{
double fa = 1 / sqrt (1 - f(2)*f(2));
scale (UP, fa, fa, fa);
}
// Calculate the vector rejection UP onto f
// s, f and u are used to assemble the rotation matrix l
ColumnVector s = cross (f, UP);
ColumnVector u = cross (s, f);
// Construct a 4x4 matrix "x_view" that is a subset of "x_gl_mat1"
// Start with identity I = [1,0,0,0; 0,1,0,0; 0,0,1,0; 0,0,0,1]
Matrix x_view = xform_matrix ();
// Step #7 -> #8
scale (x_view, 1, 1, -1);
Matrix l = xform_matrix ();
l(0,0) = s(0); l(0,1) = s(1); l(0,2) = s(2);
l(1,0) = u(0); l(1,1) = u(1); l(1,2) = u(2);
l(2,0) = -f(0); l(2,1) = -f(1); l(2,2) = -f(2);
// Step #6 -> #7 (rotate on the Z axis)
x_view = x_view * l;
// Step #5 -> #6
translate (x_view, -c_eye(0), -c_eye(1), -c_eye(2));
// Step #4 -> #5
scale (x_view, pb(0), pb(1), pb(2));
// Step #3 -> #4
translate (x_view, -0.5, -0.5, -0.5);
|
x_gl_mat1[edit]
To visualize the matrix properties, the "x_gl_mat1" matrix is multiplied by the object coordinates. After the transformation, the plot box is aligned with the Z-axis and the view point is at the origin . The matrix transforms world coordinates into camera coordinates. The purple planes show the near and far clipping planes.
The individual translation, scaling and rotation operations of "x_gl_mat1", are shown in the following figure:
The role of "x_gl_mat2"[edit]
Bounding box[edit]
The matrix "x_gl_mat2" is composed of the sub matrices "x_viewport" and "x_projection". The purpose of these matrices is to fit the associated 2D image of the above transformation result into a "bounding box". The bounding box is defined as follows:
- bb(0), bb(1): Position of the "viewport"
- bb(2), bb(3): Width and height of the "viewport"
Hint: If you debug in "update_camera ()", you can print "bb":
(gdb) print *bb.rep.data@bb.rep.len (gdb) $1 = {72.79, 31.50, 434, 342.29}
Compare the result with the output on the Octave prompt:
hax = axes (); get (hax, "position") ans = 73.80 47.20 434.00 342.30 get (gcf, 'position') ans = 22 300 560 420
Where 420 - 342.30 - 31.5 + 1 = 47.20
x_projection[edit]
In the following simplified code section the matrix "x_projection" is composed. It is used to normalize the image of the above transformation. For this purpose, the field of view (FOV) must be calculated:
Code: Section of axes::properties::update_camera ()" |
if (cameraviewanglemode_is ("auto"))
{
if ((bb(2)/bb(3)) > (xM/yM))
// When the image is scaled to the size of the bounding box,
// the height collides with the bounding box first. Therefore,
// the camera view angle is defined by the image height yM.
af = 1.0 / yM;
else
// The image width collides with the bounding box.
af = 1.0 / xM;
// The view angle "v_angle", also called field of view "FOV",
// is formed by the hypotenuse and the adjacent side, which is given by
// the distance between the view point and the camera target "norm (F)".
// The ratio of the opposite side, given by "af", to the adjacent side in
// a right-angled triangle is the tangent of the view angle.
v_angle = 2 * (180.0 / M_PI) * atan (1 / (2 * af * norm (F)));
cameraviewangle = v_angle;
}
else
v_angle = get_cameraviewangle ();
// x_projection: identity "diag([1, 1, 1, 1])"
Matrix x_projection = xform_matrix ();
// Calculate backwards from the angle to the ratio. This step
// is necessary because "v_angle" can be set manually.
double pf = 1 / (2 * tan ((v_angle / 2) * M_PI / 180.0) * norm (F));
// Normalize to one. Resulting coordinates are "normalized device coordinates".
scale (x_projection, pf, pf, 1);
|
x_viewport[edit]
"x_viewport" is a transformation used to place the previously "normalized" plot box in the center and to fit it tightly into the bounding box:
Code: Section of axes::properties::update_camera ()" |
double pix = 1;
if (autocam)
{
if ((bb(2)/bb(3)) > (xM/yM))
pix = bb(3);
else
pix = bb(2);
}
else
pix = (bb(2) < bb(3) ? bb(2) : bb(3));
// x_viewport: identity "diag([1, 1, 1, 1])"
Matrix x_viewport = xform_matrix ();
// Move to the center of the bounding box inside the figure.
translate (x_viewport, bb(0)+bb(2)/2, bb(1)+bb(3)/2, 0);
// Scale either to width or height, to fit correctly into the bounding box
scale (x_viewport, pix, -pix, 1);
x_gl_mat2 = x_viewport * x_projection;
|
Note: The matrix "x_gl_mat2" scales x, y. However the z-coordinate is not modified!
setup_opengl_transformation ()[edit]
OpenGL backend[edit]
In the OpenGL backend, the view matrix, an orthographic matrix, and the viewport transform are used to transform the octave plot into the screen window.
Code: Section of opengl_renderer::setup_opengl_transformation ()" |
Matrix x_zlim = props.get_transform_zlim ();
xZ1 = x_zlim(0)-(x_zlim(1)-x_zlim(0))/2;
xZ2 = x_zlim(1)+(x_zlim(1)-x_zlim(0))/2;
// Load x_gl_mat1 and x_gl_mat2
Matrix x_mat1 = props.get_opengl_matrix_1 ();
Matrix x_mat2 = props.get_opengl_matrix_2 ();
m_glfcns.glMatrixMode (GL_MODELVIEW);
m_glfcns.glLoadIdentity ();
m_glfcns.glScaled (1, 1, -1);
// Matrix x_gl_mat1
m_glfcns.glMultMatrixd (x_mat1.data ());
m_glfcns.glMatrixMode (GL_PROJECTION);
m_glfcns.glLoadIdentity ();
Matrix vp = get_viewport_scaled ();
// Install orthographic projection matrix with viewport
// setting "0, vp(2), vp(3), 0" and near / far values "xZ1, xZ2"
m_glfcns.glOrtho (0, vp(2), vp(3), 0, xZ1, xZ2);
// Matrix x_gl_mat2
m_glfcns.glMultMatrixd (x_mat2.data ());
m_glfcns.glMatrixMode (GL_MODELVIEW);
m_glfcns.glClear (GL_DEPTH_BUFFER_BIT);
|
Hint: If you debug in "setup_opengl_transformation ()", you can print the viewport "vp":
(gdb) print *vp.rep.data@vp.rep.len (gdb) $1 = {0, 0, 560, 420}
This is consistent with the window size.