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authorsanine <sanine.not@pm.me>2022-06-14 00:06:42 -0500
committersanine <sanine.not@pm.me>2022-06-14 00:06:42 -0500
commit2f518e5e28d35ae24a5ac0e31000835e43b01972 (patch)
tree47fdeb9fa5b04e267702acb06424d3f87b37dd84 /libs/cglm/include/cglm/struct/mat4.h
parent034d5c965ff34cfdf4b153af9f32360a02e35684 (diff)
add cglm as 3rd-party library
Diffstat (limited to 'libs/cglm/include/cglm/struct/mat4.h')
-rw-r--r--libs/cglm/include/cglm/struct/mat4.h459
1 files changed, 459 insertions, 0 deletions
diff --git a/libs/cglm/include/cglm/struct/mat4.h b/libs/cglm/include/cglm/struct/mat4.h
new file mode 100644
index 0000000..28f80a3
--- /dev/null
+++ b/libs/cglm/include/cglm/struct/mat4.h
@@ -0,0 +1,459 @@
+/*
+ * Copyright (c), Recep Aslantas.
+ *
+ * MIT License (MIT), http://opensource.org/licenses/MIT
+ * Full license can be found in the LICENSE file
+ */
+
+/*!
+ * Most of functions in this header are optimized manually with SIMD
+ * if available. You dont need to call/incude SIMD headers manually
+ */
+
+/*
+ Macros:
+ GLMS_MAT4_IDENTITY_INIT
+ GLMS_MAT4_ZERO_INIT
+ GLMS_MAT4_IDENTITY
+ GLMS_MAT4_ZERO
+
+ Functions:
+ CGLM_INLINE mat4s glms_mat4_ucopy(mat4s mat);
+ CGLM_INLINE mat4s glms_mat4_copy(mat4s mat);
+ CGLM_INLINE mat4s glms_mat4_identity(void);
+ CGLM_INLINE void glms_mat4_identity_array(mat4s * __restrict mat, size_t count);
+ CGLM_INLINE mat4s glms_mat4_zero(void);
+ CGLM_INLINE mat3s glms_mat4_pick3(mat4s mat);
+ CGLM_INLINE mat3s glms_mat4_pick3t(mat4s mat);
+ CGLM_INLINE mat4s glms_mat4_ins3(mat3s mat);
+ CGLM_INLINE mat4s glms_mat4_mul(mat4s m1, mat4s m2);
+ CGLM_INLINE mat4s glms_mat4_mulN(mat4s * __restrict matrices[], uint32_t len);
+ CGLM_INLINE vec4s glms_mat4_mulv(mat4s m, vec4s v);
+ CGLM_INLINE float glms_mat4_trace(mat4s m);
+ CGLM_INLINE float glms_mat4_trace3(mat4s m);
+ CGLM_INLINE versors glms_mat4_quat(mat4s m);
+ CGLM_INLINE vec3s glms_mat4_mulv3(mat4s m, vec3s v, float last);
+ CGLM_INLINE mat4s glms_mat4_transpose(mat4s m);
+ CGLM_INLINE mat4s glms_mat4_scale_p(mat4s m, float s);
+ CGLM_INLINE mat4s glms_mat4_scale(mat4s m, float s);
+ CGLM_INLINE float glms_mat4_det(mat4s mat);
+ CGLM_INLINE mat4s glms_mat4_inv(mat4s mat);
+ CGLM_INLINE mat4s glms_mat4_inv_fast(mat4s mat);
+ CGLM_INLINE mat4s glms_mat4_swap_col(mat4s mat, int col1, int col2);
+ CGLM_INLINE mat4s glms_mat4_swap_row(mat4s mat, int row1, int row2);
+ CGLM_INLINE float glms_mat4_rmc(vec4s r, mat4s m, vec4s c);
+ */
+
+#ifndef cglms_mat4s_h
+#define cglms_mat4s_h
+
+#include "../common.h"
+#include "../types-struct.h"
+#include "../mat4.h"
+#include "vec4.h"
+#include "vec3.h"
+
+#define GLMS_MAT4_IDENTITY_INIT {GLM_MAT4_IDENTITY_INIT}
+#define GLMS_MAT4_ZERO_INIT {GLM_MAT4_ZERO_INIT}
+
+/* for C only */
+#define GLMS_MAT4_IDENTITY ((mat4s)GLMS_MAT4_IDENTITY_INIT)
+#define GLMS_MAT4_ZERO ((mat4s)GLMS_MAT4_ZERO_INIT)
+
+/*!
+ * @brief copy all members of [mat] to [dest]
+ *
+ * matrix may not be aligned, u stands for unaligned, this may be useful when
+ * copying a matrix from external source e.g. asset importer...
+ *
+ * @param[in] mat source
+ * @returns destination
+ */
+CGLM_INLINE
+mat4s
+glms_mat4_ucopy(mat4s mat) {
+ mat4s r;
+ glm_mat4_ucopy(mat.raw, r.raw);
+ return r;
+}
+
+/*!
+ * @brief copy all members of [mat] to [dest]
+ *
+ * @param[in] mat source
+ * @returns destination
+ */
+CGLM_INLINE
+mat4s
+glms_mat4_copy(mat4s mat) {
+ mat4s r;
+ glm_mat4_copy(mat.raw, r.raw);
+ return r;
+}
+
+/*!
+ * @brief make given matrix identity. It is identical with below,
+ * but it is more easy to do that with this func especially for members
+ * e.g. glm_mat4_identity(aStruct->aMatrix);
+ *
+ * @code
+ * glm_mat4_copy(GLM_MAT4_IDENTITY, mat); // C only
+ *
+ * // or
+ * mat4 mat = GLM_MAT4_IDENTITY_INIT;
+ * @endcode
+ *
+ * @retuns destination
+ */
+CGLM_INLINE
+mat4s
+glms_mat4_identity(void) {
+ mat4s r;
+ glm_mat4_identity(r.raw);
+ return r;
+}
+
+/*!
+ * @brief make given matrix array's each element identity matrix
+ *
+ * @param[in, out] mat matrix array (must be aligned (16/32)
+ * if alignment is not disabled)
+ *
+ * @param[in] count count of matrices
+ */
+CGLM_INLINE
+void
+glms_mat4_identity_array(mat4s * __restrict mat, size_t count) {
+ CGLM_ALIGN_MAT mat4s t = GLMS_MAT4_IDENTITY_INIT;
+ size_t i;
+
+ for (i = 0; i < count; i++) {
+ glm_mat4_copy(t.raw, mat[i].raw);
+ }
+}
+
+/*!
+ * @brief make given matrix zero.
+ *
+ * @returns matrix
+ */
+CGLM_INLINE
+mat4s
+glms_mat4_zero(void) {
+ mat4s r;
+ glm_mat4_zero(r.raw);
+ return r;
+}
+
+/*!
+ * @brief copy upper-left of mat4 to mat3
+ *
+ * @param[in] mat source
+ * @returns destination
+ */
+CGLM_INLINE
+mat3s
+glms_mat4_pick3(mat4s mat) {
+ mat3s r;
+ glm_mat4_pick3(mat.raw, r.raw);
+ return r;
+}
+
+/*!
+ * @brief copy upper-left of mat4 to mat3 (transposed)
+ *
+ * the postfix t stands for transpose
+ *
+ * @param[in] mat source
+ * @returns destination
+ */
+CGLM_INLINE
+mat3s
+glms_mat4_pick3t(mat4s mat) {
+ mat3s r;
+ glm_mat4_pick3t(mat.raw, r.raw);
+ return r;
+}
+
+/*!
+ * @brief copy mat3 to mat4's upper-left
+ *
+ * @param[in] mat source
+ * @returns destination
+ */
+CGLM_INLINE
+mat4s
+glms_mat4_ins3(mat3s mat) {
+ mat4s r;
+ glm_mat4_ins3(mat.raw, r.raw);
+ return r;
+}
+
+/*!
+ * @brief multiply m1 and m2 to dest
+ *
+ * m1, m2 and dest matrices can be same matrix, it is possible to write this:
+ *
+ * @code
+ * mat4 m = GLM_MAT4_IDENTITY_INIT;
+ * glm_mat4_mul(m, m, m);
+ * @endcode
+ *
+ * @param[in] m1 left matrix
+ * @param[in] m2 right matrix
+ * @returns destination matrix
+ */
+CGLM_INLINE
+mat4s
+glms_mat4_mul(mat4s m1, mat4s m2) {
+ mat4s r;
+ glm_mat4_mul(m1.raw, m2.raw, r.raw);
+ return r;
+}
+
+/*!
+ * @brief mupliply N mat4 matrices and store result in dest
+ *
+ * this function lets you multiply multiple (more than two or more...) matrices
+ * <br><br>multiplication will be done in loop, this may reduce instructions
+ * size but if <b>len</b> is too small then compiler may unroll whole loop,
+ * usage:
+ * @code
+ * mat m1, m2, m3, m4, res;
+ *
+ * res = glm_mat4_mulN((mat4 *[]){&m1, &m2, &m3, &m4}, 4);
+ * @endcode
+ *
+ * @warning matrices parameter is pointer array not mat4 array!
+ *
+ * @param[in] matrices mat4 * array
+ * @param[in] len matrices count
+ * @returns result matrix
+ */
+CGLM_INLINE
+mat4s
+glms_mat4_mulN(mat4s * __restrict matrices[], uint32_t len) {
+ CGLM_ALIGN_MAT mat4s r = GLMS_MAT4_IDENTITY_INIT;
+ size_t i;
+
+ for (i = 0; i < len; i++) {
+ r = glms_mat4_mul(r, *matrices[i]);
+ }
+
+ return r;
+}
+
+/*!
+ * @brief multiply mat4 with vec4 (column vector) and store in dest vector
+ *
+ * @param[in] m mat4 (left)
+ * @param[in] v vec4 (right, column vector)
+ * @returns vec4 (result, column vector)
+ */
+CGLM_INLINE
+vec4s
+glms_mat4_mulv(mat4s m, vec4s v) {
+ vec4s r;
+ glm_mat4_mulv(m.raw, v.raw, r.raw);
+ return r;
+}
+
+/*!
+ * @brief trace of matrix
+ *
+ * sum of the elements on the main diagonal from upper left to the lower right
+ *
+ * @param[in] m matrix
+ */
+CGLM_INLINE
+float
+glms_mat4_trace(mat4s m) {
+ return glm_mat4_trace(m.raw);
+}
+
+/*!
+ * @brief trace of matrix (rotation part)
+ *
+ * sum of the elements on the main diagonal from upper left to the lower right
+ *
+ * @param[in] m matrix
+ */
+CGLM_INLINE
+float
+glms_mat4_trace3(mat4s m) {
+ return glm_mat4_trace3(m.raw);
+}
+
+/*!
+ * @brief convert mat4's rotation part to quaternion
+ *
+ * @param[in] m affine matrix
+ * @returns destination quaternion
+ */
+CGLM_INLINE
+versors
+glms_mat4_quat(mat4s m) {
+ versors r;
+ glm_mat4_quat(m.raw, r.raw);
+ return r;
+}
+
+/*!
+ * @brief multiply vector with mat4
+ *
+ * @param[in] m mat4(affine transform)
+ * @param[in] v vec3
+ * @param[in] last 4th item to make it vec4
+ * @returns result vector (vec3)
+ */
+CGLM_INLINE
+vec3s
+glms_mat4_mulv3(mat4s m, vec3s v, float last) {
+ vec3s r;
+ glm_mat4_mulv3(m.raw, v.raw, last, r.raw);
+ return r;
+}
+
+/*!
+ * @brief tranpose mat4 and store result in same matrix
+ *
+ * @param[in] m source
+ * @returns result
+ */
+CGLM_INLINE
+mat4s
+glms_mat4_transpose(mat4s m) {
+ glm_mat4_transpose(m.raw);
+ return m;
+}
+
+/*!
+ * @brief scale (multiply with scalar) matrix without simd optimization
+ *
+ * multiply matrix with scalar
+ *
+ * @param[in] m matrix
+ * @param[in] s scalar
+ * @returns matrix
+ */
+CGLM_INLINE
+mat4s
+glms_mat4_scale_p(mat4s m, float s) {
+ glm_mat4_scale_p(m.raw, s);
+ return m;
+}
+
+/*!
+ * @brief scale (multiply with scalar) matrix
+ *
+ * multiply matrix with scalar
+ *
+ * @param[in] m matrix
+ * @param[in] s scalar
+ * @returns matrix
+ */
+CGLM_INLINE
+mat4s
+glms_mat4_scale(mat4s m, float s) {
+ glm_mat4_scale(m.raw, s);
+ return m;
+}
+
+/*!
+ * @brief mat4 determinant
+ *
+ * @param[in] mat matrix
+ *
+ * @return determinant
+ */
+CGLM_INLINE
+float
+glms_mat4_det(mat4s mat) {
+ return glm_mat4_det(mat.raw);
+}
+
+/*!
+ * @brief inverse mat4 and store in dest
+ *
+ * @param[in] mat matrix
+ * @returns inverse matrix
+ */
+CGLM_INLINE
+mat4s
+glms_mat4_inv(mat4s mat) {
+ mat4s r;
+ glm_mat4_inv(mat.raw, r.raw);
+ return r;
+}
+
+/*!
+ * @brief inverse mat4 and store in dest
+ *
+ * this func uses reciprocal approximation without extra corrections
+ * e.g Newton-Raphson. this should work faster than normal,
+ * to get more precise use glm_mat4_inv version.
+ *
+ * NOTE: You will lose precision, glm_mat4_inv is more accurate
+ *
+ * @param[in] mat matrix
+ * @returns inverse matrix
+ */
+CGLM_INLINE
+mat4s
+glms_mat4_inv_fast(mat4s mat) {
+ mat4s r;
+ glm_mat4_inv_fast(mat.raw, r.raw);
+ return r;
+}
+
+/*!
+ * @brief swap two matrix columns
+ *
+ * @param[in] mat matrix
+ * @param[in] col1 col1
+ * @param[in] col2 col2
+ * @returns matrix
+ */
+CGLM_INLINE
+mat4s
+glms_mat4_swap_col(mat4s mat, int col1, int col2) {
+ glm_mat4_swap_col(mat.raw, col1, col2);
+ return mat;
+}
+
+/*!
+ * @brief swap two matrix rows
+ *
+ * @param[in] mat matrix
+ * @param[in] row1 row1
+ * @param[in] row2 row2
+ * @returns matrix
+ */
+CGLM_INLINE
+mat4s
+glms_mat4_swap_row(mat4s mat, int row1, int row2) {
+ glm_mat4_swap_row(mat.raw, row1, row2);
+ return mat;
+}
+
+/*!
+ * @brief helper for R (row vector) * M (matrix) * C (column vector)
+ *
+ * rmc stands for Row * Matrix * Column
+ *
+ * the result is scalar because R * M = Matrix1x4 (row vector),
+ * then Matrix1x4 * Vec4 (column vector) = Matrix1x1 (Scalar)
+ *
+ * @param[in] r row vector or matrix1x4
+ * @param[in] m matrix4x4
+ * @param[in] c column vector or matrix4x1
+ *
+ * @return scalar value e.g. B(s)
+ */
+CGLM_INLINE
+float
+glms_mat4_rmc(vec4s r, mat4s m, vec4s c) {
+ return glm_mat4_rmc(r.raw, m.raw, c.raw);
+}
+
+#endif /* cglms_mat4s_h */