frillrun/include/cglm/affine-post.h
2024-08-24 00:47:58 -04:00

248 lines
5.9 KiB
C

/*
* Copyright (c), Recep Aslantas.
*
* MIT License (MIT), http://opensource.org/licenses/MIT
* Full license can be found in the LICENSE file
*/
#ifndef cglm_affine_post_h
#define cglm_affine_post_h
/*
Functions:
CGLM_INLINE void glm_translated_to(mat4 m, vec3 v, mat4 dest);
CGLM_INLINE void glm_translated(mat4 m, vec3 v);
CGLM_INLINE void glm_translated_x(mat4 m, float to);
CGLM_INLINE void glm_translated_y(mat4 m, float to);
CGLM_INLINE void glm_translated_z(mat4 m, float to);
CGLM_INLINE void glm_rotated_x(mat4 m, float angle, mat4 dest);
CGLM_INLINE void glm_rotated_y(mat4 m, float angle, mat4 dest);
CGLM_INLINE void glm_rotated_z(mat4 m, float angle, mat4 dest);
CGLM_INLINE void glm_rotated(mat4 m, float angle, vec3 axis);
CGLM_INLINE void glm_rotated_at(mat4 m, vec3 pivot, float angle, vec3 axis);
CGLM_INLINE void glm_spinned(mat4 m, float angle, vec3 axis);
*/
#include "common.h"
#include "util.h"
#include "vec3.h"
#include "vec4.h"
#include "mat4.h"
#include "affine-mat.h"
/*!
* @brief translate existing transform matrix by v vector
* and stores result in same matrix
*
* this is POST transform, applies to existing transform as last transfrom
*
* @param[in, out] m affine transfrom
* @param[in] v translate vector [x, y, z]
*/
CGLM_INLINE
void
glm_translated(mat4 m, vec3 v) {
glm_vec3_add(m[3], v, m[3]);
}
/*!
* @brief translate existing transform matrix by v vector
* and store result in dest
*
* source matrix will remain same
*
* this is POST transform, applies to existing transform as last transfrom
*
* @param[in] m affine transfrom
* @param[in] v translate vector [x, y, z]
* @param[out] dest translated matrix
*/
CGLM_INLINE
void
glm_translated_to(mat4 m, vec3 v, mat4 dest) {
glm_mat4_copy(m, dest);
glm_translated(dest, v);
}
/*!
* @brief translate existing transform matrix by x factor
*
* this is POST transform, applies to existing transform as last transfrom
*
* @param[in, out] m affine transfrom
* @param[in] x x factor
*/
CGLM_INLINE
void
glm_translated_x(mat4 m, float x) {
m[3][0] += x;
}
/*!
* @brief translate existing transform matrix by y factor
*
* this is POST transform, applies to existing transform as last transfrom
*
* @param[in, out] m affine transfrom
* @param[in] y y factor
*/
CGLM_INLINE
void
glm_translated_y(mat4 m, float y) {
m[3][1] += y;
}
/*!
* @brief translate existing transform matrix by z factor
*
* this is POST transform, applies to existing transform as last transfrom
*
* @param[in, out] m affine transfrom
* @param[in] z z factor
*/
CGLM_INLINE
void
glm_translated_z(mat4 m, float z) {
m[3][2] += z;
}
/*!
* @brief rotate existing transform matrix around X axis by angle
* and store result in dest
*
* this is POST transform, applies to existing transform as last transfrom
*
* @param[in] m affine transfrom
* @param[in] angle angle (radians)
* @param[out] dest rotated matrix
*/
CGLM_INLINE
void
glm_rotated_x(mat4 m, float angle, mat4 dest) {
CGLM_ALIGN_MAT mat4 t = GLM_MAT4_IDENTITY_INIT;
float c, s;
c = cosf(angle);
s = sinf(angle);
t[1][1] = c;
t[1][2] = s;
t[2][1] = -s;
t[2][2] = c;
glm_mul_rot(t, m, dest);
}
/*!
* @brief rotate existing transform matrix around Y axis by angle
* and store result in dest
*
* this is POST transform, applies to existing transform as last transfrom
*
* @param[in] m affine transfrom
* @param[in] angle angle (radians)
* @param[out] dest rotated matrix
*/
CGLM_INLINE
void
glm_rotated_y(mat4 m, float angle, mat4 dest) {
CGLM_ALIGN_MAT mat4 t = GLM_MAT4_IDENTITY_INIT;
float c, s;
c = cosf(angle);
s = sinf(angle);
t[0][0] = c;
t[0][2] = -s;
t[2][0] = s;
t[2][2] = c;
glm_mul_rot(t, m, dest);
}
/*!
* @brief rotate existing transform matrix around Z axis by angle
* and store result in dest
*
* this is POST transform, applies to existing transform as last transfrom
*
* @param[in] m affine transfrom
* @param[in] angle angle (radians)
* @param[out] dest rotated matrix
*/
CGLM_INLINE
void
glm_rotated_z(mat4 m, float angle, mat4 dest) {
CGLM_ALIGN_MAT mat4 t = GLM_MAT4_IDENTITY_INIT;
float c, s;
c = cosf(angle);
s = sinf(angle);
t[0][0] = c;
t[0][1] = s;
t[1][0] = -s;
t[1][1] = c;
glm_mul_rot(t, m, dest);
}
/*!
* @brief rotate existing transform matrix around given axis by angle
*
* this is POST transform, applies to existing transform as last transfrom
*
* @param[in, out] m affine transfrom
* @param[in] angle angle (radians)
* @param[in] axis axis
*/
CGLM_INLINE
void
glm_rotated(mat4 m, float angle, vec3 axis) {
CGLM_ALIGN_MAT mat4 rot;
glm_rotate_make(rot, angle, axis);
glm_mul_rot(rot, m, m);
}
/*!
* @brief rotate existing transform
* around given axis by angle at given pivot point (rotation center)
*
* this is POST transform, applies to existing transform as last transfrom
*
* @param[in, out] m affine transfrom
* @param[in] pivot rotation center
* @param[in] angle angle (radians)
* @param[in] axis axis
*/
CGLM_INLINE
void
glm_rotated_at(mat4 m, vec3 pivot, float angle, vec3 axis) {
CGLM_ALIGN(8) vec3 pivotInv;
glm_vec3_negate_to(pivot, pivotInv);
glm_translated(m, pivot);
glm_rotated(m, angle, axis);
glm_translated(m, pivotInv);
}
/*!
* @brief rotate existing transform matrix around given axis by angle around self (doesn't affected by position)
*
* this is POST transform, applies to existing transform as last transfrom
*
* @param[in, out] m affine transfrom
* @param[in] angle angle (radians)
* @param[in] axis axis
*/
CGLM_INLINE
void
glm_spinned(mat4 m, float angle, vec3 axis) {
CGLM_ALIGN_MAT mat4 rot;
glm_rotate_atm(rot, m[3], angle, axis);
glm_mat4_mul(rot, m, m);
}
#endif /* cglm_affine_post_h */