gtk2/demos/gtk-demo/four_point_transform.c

#include "four_point_transform.h"
#include "singular_value_decomposition.h"

/* Make a 4x4 matrix that maps
 * e1        -> p1
 * e2        -> p3
 * e3        -> p3
 * (1,1,1,0) -> p4
 */
static void
unit_to (graphene_point3d_t *p1,
         graphene_point3d_t *p2,
         graphene_point3d_t *p3,
         graphene_point3d_t *p4,
         graphene_matrix_t  *m)
{
  graphene_vec3_t v1, v2, v3, v4;
  graphene_vec4_t vv1, vv2, vv3, vv4, p;
  graphene_matrix_t u, s;
  float v[16] = { 0., };
  double A[16];
  double U[16];
  double S[4];
  double V[16];
  double B[4];
  double x[4];
  int i, j;

  graphene_point3d_to_vec3 (p1, &v1);
  graphene_point3d_to_vec3 (p2, &v2);
  graphene_point3d_to_vec3 (p3, &v3);
  graphene_point3d_to_vec3 (p4, &v4);

  graphene_vec4_init_from_vec3 (&vv1, &v1, 1.);
  graphene_vec4_init_from_vec3 (&vv2, &v2, 1.);
  graphene_vec4_init_from_vec3 (&vv3, &v3, 1.);
  graphene_vec4_init_from_vec3 (&vv4, &v4, 1.);

  graphene_vec4_init (&p, 0., 0., 0., 1.);

  graphene_matrix_init_from_vec4 (&u, &vv1, &vv2, &vv3, &p);

  /* solve x * u = vv4 */

  for (i = 0; i < 4; i++)
    for (j = 0; j < 4; j++)
      A[j * 4 + i] = graphene_matrix_get_value (&u, i, j);

  B[0] = graphene_vec4_get_x (&vv4);
  B[1] = graphene_vec4_get_y (&vv4);
  B[2] = graphene_vec4_get_z (&vv4);
  B[3] = graphene_vec4_get_w (&vv4);

  singular_value_decomposition (A, 4, 4, U, S, V);
  singular_value_decomposition_solve (U, S, V, 4, 4, B, x);

  v[ 0] = x[0];
  v[ 5] = x[1];
  v[10] = x[2];
  v[15] = 1;

  graphene_matrix_init_from_float (&s, (const float *)&v);
  graphene_matrix_multiply (&s, &u, m);
}

/* Compute a 4x4 matrix m that maps
 * p1 -> q1
 * p2 -> q2
 * p3 -> q3
 * p4 -> q4
 *
 * This is not in general possible, because projective
 * transforms preserve coplanarity. But in the cases we
 * care about here, both sets of points are always coplanar.
 */
void
perspective_3d (graphene_point3d_t *p1,
                graphene_point3d_t *p2,
                graphene_point3d_t *p3,
                graphene_point3d_t *p4,
                graphene_point3d_t *q1,
                graphene_point3d_t *q2,
                graphene_point3d_t *q3,
                graphene_point3d_t *q4,
                graphene_matrix_t  *m)
{
  graphene_matrix_t a, a_inv, b;

  unit_to (p1, p2, p3, p4, &a);
  unit_to (q1, q2, q3, q4, &b);

  graphene_matrix_inverse (&a, &a_inv);
  graphene_matrix_multiply (&a_inv, &b, m);
}
Add another layout manager demo This demo uses transforms to place icons on a sphere. 2020-08-27 11:16:38 +00:00			`#include "four_point_transform.h"`
			`#include "singular_value_decomposition.h"`

			`/* Make a 4x4 matrix that maps`
			`* e1 -> p1`
			`* e2 -> p3`
			`* e3 -> p3`
			`* (1,1,1,0) -> p4`
			`*/`
			`static void`
			`unit_to (graphene_point3d_t *p1,`
			`graphene_point3d_t *p2,`
			`graphene_point3d_t *p3,`
			`graphene_point3d_t *p4,`
			`graphene_matrix_t *m)`
			`{`
			`graphene_vec3_t v1, v2, v3, v4;`
			`graphene_vec4_t vv1, vv2, vv3, vv4, p;`
			`graphene_matrix_t u, s;`
			`float v[16] = { 0., };`
			`double A[16];`
			`double U[16];`
			`double S[4];`
			`double V[16];`
			`double B[4];`
			`double x[4];`
			`int i, j;`

			`graphene_point3d_to_vec3 (p1, &v1);`
			`graphene_point3d_to_vec3 (p2, &v2);`
			`graphene_point3d_to_vec3 (p3, &v3);`
			`graphene_point3d_to_vec3 (p4, &v4);`

			`graphene_vec4_init_from_vec3 (&vv1, &v1, 1.);`
			`graphene_vec4_init_from_vec3 (&vv2, &v2, 1.);`
			`graphene_vec4_init_from_vec3 (&vv3, &v3, 1.);`
			`graphene_vec4_init_from_vec3 (&vv4, &v4, 1.);`

			`graphene_vec4_init (&p, 0., 0., 0., 1.);`

			`graphene_matrix_init_from_vec4 (&u, &vv1, &vv2, &vv3, &p);`

			`/* solve x * u = vv4 */`

			`for (i = 0; i < 4; i++)`
			`for (j = 0; j < 4; j++)`
			`A[j * 4 + i] = graphene_matrix_get_value (&u, i, j);`

			`B[0] = graphene_vec4_get_x (&vv4);`
			`B[1] = graphene_vec4_get_y (&vv4);`
			`B[2] = graphene_vec4_get_z (&vv4);`
			`B[3] = graphene_vec4_get_w (&vv4);`

			`singular_value_decomposition (A, 4, 4, U, S, V);`
			`singular_value_decomposition_solve (U, S, V, 4, 4, B, x);`

			`v[ 0] = x[0];`
			`v[ 5] = x[1];`
			`v[10] = x[2];`
			`v[15] = 1;`

			`graphene_matrix_init_from_float (&s, (const float *)&v);`
			`graphene_matrix_multiply (&s, &u, m);`
			`}`

gtk-demo: Add some comments Add some comments to the math in the transforms demo. 2020-09-06 12:42:27 +00:00			`/* Compute a 4x4 matrix m that maps`
Add another layout manager demo This demo uses transforms to place icons on a sphere. 2020-08-27 11:16:38 +00:00			`* p1 -> q1`
			`* p2 -> q2`
			`* p3 -> q3`
			`* p4 -> q4`
gtk-demo: Add some comments Add some comments to the math in the transforms demo. 2020-09-06 12:42:27 +00:00			`*`
			`* This is not in general possible, because projective`
			`* transforms preserve coplanarity. But in the cases we`
			`* care about here, both sets of points are always coplanar.`
Add another layout manager demo This demo uses transforms to place icons on a sphere. 2020-08-27 11:16:38 +00:00			`*/`
			`void`
			`perspective_3d (graphene_point3d_t *p1,`
			`graphene_point3d_t *p2,`
			`graphene_point3d_t *p3,`
			`graphene_point3d_t *p4,`
			`graphene_point3d_t *q1,`
			`graphene_point3d_t *q2,`
			`graphene_point3d_t *q3,`
			`graphene_point3d_t *q4,`
			`graphene_matrix_t *m)`
			`{`
			`graphene_matrix_t a, a_inv, b;`

			`unit_to (p1, p2, p3, p4, &a);`
			`unit_to (q1, q2, q3, q4, &b);`

			`graphene_matrix_inverse (&a, &a_inv);`
			`graphene_matrix_multiply (&a_inv, &b, m);`
			`}`