/* * Cogl * * An object oriented GL/GLES Abstraction/Utility Layer * * Copyright (C) 2008,2009 Intel Corporation. * * This library is free software; you can redistribute it and/or * modify it under the terms of the GNU Lesser General Public * License as published by the Free Software Foundation; either * version 2 of the License, or (at your option) any later version. * * This library is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU * Lesser General Public License for more details. * * You should have received a copy of the GNU Lesser General Public * License along with this library. If not, see . * * * * Authors: * Robert Bragg */ #ifdef HAVE_CONFIG_H #include "config.h" #endif #define USE_MESA_MATRIX_API #include #include "cogl-debug.h" #include #include #ifdef USE_MESA_MATRIX_API #include #endif #include #include #include #ifdef _COGL_SUPPORTS_GTYPE_INTEGRATION #include COGL_GTYPE_DEFINE_BOXED ("Matrix", matrix, cogl_matrix_copy, cogl_matrix_free); #endif void _cogl_matrix_print (CoglMatrix *matrix) { float *m = (float *)matrix; int y; for (y = 0; y < 4; y++) g_print ("\t%6.4f %6.4f %6.4f %6.4f\n", m[y], m[4+y], m[8+y], m[12+y]); } void cogl_matrix_init_identity (CoglMatrix *matrix) { #ifndef USE_MESA_MATRIX_API matrix->xx = 1; matrix->xy = 0; matrix->xz = 0; matrix->xw = 0; matrix->yx = 0; matrix->yy = 1; matrix->yz = 0; matrix->yw = 0; matrix->zx = 0; matrix->zy = 0; matrix->zz = 1; matrix->zw = 0; matrix->wx = 0; matrix->wy = 0; matrix->wz = 0; matrix->ww = 1; #else _math_matrix_init_identity (matrix); #endif _COGL_MATRIX_DEBUG_PRINT (matrix); } void cogl_matrix_multiply (CoglMatrix *result, const CoglMatrix *a, const CoglMatrix *b) { #ifndef USE_MESA_MATRIX_API CoglMatrix r; /* row 0 */ r.xx = a->xx * b->xx + a->xy * b->yx + a->xz * b->zx + a->xw * b->wx; r.xy = a->xx * b->xy + a->xy * b->yy + a->xz * b->zy + a->xw * b->wy; r.xz = a->xx * b->xz + a->xy * b->yz + a->xz * b->zz + a->xw * b->wz; r.xw = a->xx * b->xw + a->xy * b->yw + a->xz * b->zw + a->xw * b->ww; /* row 1 */ r.yx = a->yx * b->xx + a->yy * b->yx + a->yz * b->zx + a->yw * b->wx; r.yy = a->yx * b->xy + a->yy * b->yy + a->yz * b->zy + a->yw * b->wy; r.yz = a->yx * b->xz + a->yy * b->yz + a->yz * b->zz + a->yw * b->wz; r.yw = a->yx * b->xw + a->yy * b->yw + a->yz * b->zw + a->yw * b->ww; /* row 2 */ r.zx = a->zx * b->xx + a->zy * b->yx + a->zz * b->zx + a->zw * b->wx; r.zy = a->zx * b->xy + a->zy * b->yy + a->zz * b->zy + a->zw * b->wy; r.zz = a->zx * b->xz + a->zy * b->yz + a->zz * b->zz + a->zw * b->wz; r.zw = a->zx * b->xw + a->zy * b->yw + a->zz * b->zw + a->zw * b->ww; /* row 3 */ r.wx = a->wx * b->xx + a->wy * b->yx + a->wz * b->zx + a->ww * b->wx; r.wy = a->wx * b->xy + a->wy * b->yy + a->wz * b->zy + a->ww * b->wy; r.wz = a->wx * b->xz + a->wy * b->yz + a->wz * b->zz + a->ww * b->wz; r.ww = a->wx * b->xw + a->wy * b->yw + a->wz * b->zw + a->ww * b->ww; /* The idea was that having this unrolled; it might be easier for the * compiler to vectorize, but that's probably not true. Mesa does it * using a single for (i=0; i<4; i++) approach, maybe that's better... */ *result = r; #else _math_matrix_multiply (result, a, b); #endif _COGL_MATRIX_DEBUG_PRINT (result); } void cogl_matrix_rotate (CoglMatrix *matrix, float angle, float x, float y, float z) { #ifndef USE_MESA_MATRIX_API CoglMatrix rotation; CoglMatrix result; float c, s; angle *= G_PI / 180.0f; c = cosf (angle); s = sinf (angle); rotation.xx = x * x * (1.0f - c) + c; rotation.yx = y * x * (1.0f - c) + z * s; rotation.zx = x * z * (1.0f - c) - y * s; rotation.wx = 0.0f; rotation.xy = x * y * (1.0f - c) - z * s; rotation.yy = y * y * (1.0f - c) + c; rotation.zy = y * z * (1.0f - c) + x * s; rotation.wy = 0.0f; rotation.xz = x * z * (1.0f - c) + y * s; rotation.yz = y * z * (1.0f - c) - x * s; rotation.zz = z * z * (1.0f - c) + c; rotation.wz = 0.0f; rotation.xw = 0.0f; rotation.yw = 0.0f; rotation.zw = 0.0f; rotation.ww = 1.0f; cogl_matrix_multiply (&result, matrix, &rotation); *matrix = result; #else _math_matrix_rotate (matrix, angle, x, y, z); #endif _COGL_MATRIX_DEBUG_PRINT (matrix); } void cogl_matrix_translate (CoglMatrix *matrix, float x, float y, float z) { #ifndef USE_MESA_MATRIX_API matrix->xw = matrix->xx * x + matrix->xy * y + matrix->xz * z + matrix->xw; matrix->yw = matrix->yx * x + matrix->yy * y + matrix->yz * z + matrix->yw; matrix->zw = matrix->zx * x + matrix->zy * y + matrix->zz * z + matrix->zw; matrix->ww = matrix->wx * x + matrix->wy * y + matrix->wz * z + matrix->ww; #else _math_matrix_translate (matrix, x, y, z); #endif _COGL_MATRIX_DEBUG_PRINT (matrix); } void cogl_matrix_scale (CoglMatrix *matrix, float sx, float sy, float sz) { #ifndef USE_MESA_MATRIX_API matrix->xx *= sx; matrix->xy *= sy; matrix->xz *= sz; matrix->yx *= sx; matrix->yy *= sy; matrix->yz *= sz; matrix->zx *= sx; matrix->zy *= sy; matrix->zz *= sz; matrix->wx *= sx; matrix->wy *= sy; matrix->wz *= sz; #else _math_matrix_scale (matrix, sx, sy, sz); #endif _COGL_MATRIX_DEBUG_PRINT (matrix); } void cogl_matrix_frustum (CoglMatrix *matrix, float left, float right, float bottom, float top, float z_near, float z_far) { #ifndef USE_MESA_MATRIX_API float x, y, a, b, c, d; CoglMatrix frustum; x = (2.0f * z_near) / (right - left); y = (2.0f * z_near) / (top - bottom); a = (right + left) / (right - left); b = (top + bottom) / (top - bottom); c = -(z_far + z_near) / ( z_far - z_near); d = -(2.0f * z_far* z_near) / (z_far - z_near); frustum.xx = x; frustum.yx = 0.0f; frustum.zx = 0.0f; frustum.wx = 0.0f; frustum.xy = 0.0f; frustum.yy = y; frustum.zy = 0.0f; frustum.wy = 0.0f; frustum.xz = a; frustum.yz = b; frustum.zz = c; frustum.wz = -1.0f; frustum.xw = 0.0f; frustum.yw = 0.0f; frustum.zw = d; frustum.ww = 0.0f; cogl_matrix_multiply (matrix, matrix, &frustum); #else _math_matrix_frustum (matrix, left, right, bottom, top, z_near, z_far); #endif _COGL_MATRIX_DEBUG_PRINT (matrix); } void cogl_matrix_perspective (CoglMatrix *matrix, float fov_y, float aspect, float z_near, float z_far) { float ymax = z_near * tan (fov_y * G_PI / 360.0); cogl_matrix_frustum (matrix, -ymax * aspect, /* left */ ymax * aspect, /* right */ -ymax, /* bottom */ ymax, /* top */ z_near, z_far); _COGL_MATRIX_DEBUG_PRINT (matrix); } void cogl_matrix_ortho (CoglMatrix *matrix, float left, float right, float bottom, float top, float near_val, float far_val) { #ifndef USE_MESA_MATRIX_API CoglMatrix ortho; /* column 0 */ ortho.xx = 2.0 / (right - left); ortho.yx = 0.0; ortho.zx = 0.0; ortho.wx = 0.0; /* column 1 */ ortho.xy = 0.0; ortho.yy = 2.0 / (top - bottom); ortho.zy = 0.0; ortho.wy = 0.0; /* column 2 */ ortho.xz = 0.0; ortho.yz = 0.0; ortho.zz = -2.0 / (far_val - near_val); ortho.wz = 0.0; /* column 3 */ ortho.xw = -(right + left) / (right - left); ortho.yw = -(top + bottom) / (top - bottom); ortho.zw = -(far_val + near_val) / (far_val - near_val); ortho.ww = 1.0; cogl_matrix_multiply (matrix, matrix, &ortho); #else _math_matrix_ortho (matrix, left, right, bottom, top, near_val, far_val); #endif _COGL_MATRIX_DEBUG_PRINT (matrix); } void cogl_matrix_init_from_array (CoglMatrix *matrix, const float *array) { #ifndef USE_MESA_MATRIX_API memcpy (matrix, array, sizeof (float) * 16); #else _math_matrix_init_from_array (matrix, array); #endif _COGL_MATRIX_DEBUG_PRINT (matrix); } gboolean cogl_matrix_equal (gconstpointer v1, gconstpointer v2) { const CoglMatrix *a = v1; const CoglMatrix *b = v2; g_return_val_if_fail (v1 != NULL, FALSE); g_return_val_if_fail (v2 != NULL, FALSE); /* We want to avoid having a fuzzy _equal() function (e.g. that uses * an arbitrary epsilon value) since this function noteably conforms * to the prototype suitable for use with g_hash_table_new() and a * fuzzy hash function isn't really appropriate for comparing hash * table keys since it's possible that you could end up fetching * different values if you end up with multiple similar keys in use * at the same time. If you consider that fuzzyness allows cases * such as A == B == C but A != C then you could also end up loosing * values in a hash table. * * We do at least use the == operator to compare values though so * that -0 is considered equal to 0. */ /* XXX: We don't compare the flags, inverse matrix or padding */ if (a->xx == b->xx && a->xy == b->xy && a->xz == b->xz && a->xw == b->xw && a->yx == b->yx && a->yy == b->yy && a->yz == b->yz && a->yw == b->yw && a->zx == b->zx && a->zy == b->zy && a->zz == b->zz && a->zw == b->zw && a->wx == b->wx && a->wy == b->wy && a->wz == b->wz && a->ww == b->ww) return TRUE; else return FALSE; } CoglMatrix * cogl_matrix_copy (const CoglMatrix *matrix) { if (G_LIKELY (matrix)) return g_slice_dup (CoglMatrix, matrix); return NULL; } void cogl_matrix_free (CoglMatrix *matrix) { g_slice_free (CoglMatrix, matrix); } const float * cogl_matrix_get_array (const CoglMatrix *matrix) { return (float *)matrix; } gboolean cogl_matrix_get_inverse (const CoglMatrix *matrix, CoglMatrix *inverse) { #ifndef USE_MESA_MATRIX_API #warning "cogl_matrix_get_inverse not supported without Mesa matrix API" cogl_matrix_init_identity (inverse); return FALSE; #else if (_math_matrix_update_inverse ((CoglMatrix *)matrix)) { cogl_matrix_init_from_array (inverse, matrix->inv); return TRUE; } else { cogl_matrix_init_identity (inverse); return FALSE; } #endif } void cogl_matrix_transform_point (const CoglMatrix *matrix, float *x, float *y, float *z, float *w) { float _x = *x, _y = *y, _z = *z, _w = *w; *x = matrix->xx * _x + matrix->xy * _y + matrix->xz * _z + matrix->xw * _w; *y = matrix->yx * _x + matrix->yy * _y + matrix->yz * _z + matrix->yw * _w; *z = matrix->zx * _x + matrix->zy * _y + matrix->zz * _z + matrix->zw * _w; *w = matrix->wx * _x + matrix->wy * _y + matrix->wz * _z + matrix->ww * _w; } typedef struct _Point2f { float x; float y; } Point2f; typedef struct _Point3f { float x; float y; float z; } Point3f; typedef struct _Point4f { float x; float y; float z; float w; } Point4f; static void _cogl_matrix_transform_points_f2 (const CoglMatrix *matrix, size_t stride_in, void *points_in, size_t stride_out, void *points_out, int n_points) { int i; for (i = 0; i < n_points; i++) { Point2f p = *(Point2f *)((guint8 *)points_in + i * stride_in); Point3f *o = (Point3f *)((guint8 *)points_out + i * stride_out); o->x = matrix->xx * p.x + matrix->xy * p.y + matrix->xw; o->y = matrix->yx * p.x + matrix->yy * p.y + matrix->yw; o->z = matrix->zx * p.x + matrix->zy * p.y + matrix->zw; } } static void _cogl_matrix_project_points_f2 (const CoglMatrix *matrix, size_t stride_in, void *points_in, size_t stride_out, void *points_out, int n_points) { int i; for (i = 0; i < n_points; i++) { Point2f p = *(Point2f *)((guint8 *)points_in + i * stride_in); Point4f *o = (Point4f *)((guint8 *)points_out + i * stride_out); o->x = matrix->xx * p.x + matrix->xy * p.y + matrix->xw; o->y = matrix->yx * p.x + matrix->yy * p.y + matrix->yw; o->z = matrix->zx * p.x + matrix->zy * p.y + matrix->zw; o->w = matrix->wx * p.x + matrix->wy * p.y + matrix->ww; } } static void _cogl_matrix_transform_points_f3 (const CoglMatrix *matrix, size_t stride_in, void *points_in, size_t stride_out, void *points_out, int n_points) { int i; for (i = 0; i < n_points; i++) { Point3f p = *(Point3f *)((guint8 *)points_in + i * stride_in); Point3f *o = (Point3f *)((guint8 *)points_out + i * stride_out); o->x = matrix->xx * p.x + matrix->xy * p.y + matrix->xz * p.z + matrix->xw; o->y = matrix->yx * p.x + matrix->yy * p.y + matrix->yz * p.z + matrix->yw; o->z = matrix->zx * p.x + matrix->zy * p.y + matrix->zz * p.z + matrix->zw; } } static void _cogl_matrix_project_points_f3 (const CoglMatrix *matrix, size_t stride_in, void *points_in, size_t stride_out, void *points_out, int n_points) { int i; for (i = 0; i < n_points; i++) { Point3f p = *(Point3f *)((guint8 *)points_in + i * stride_in); Point4f *o = (Point4f *)((guint8 *)points_out + i * stride_out); o->x = matrix->xx * p.x + matrix->xy * p.y + matrix->xz * p.z + matrix->xw; o->y = matrix->yx * p.x + matrix->yy * p.y + matrix->yz * p.z + matrix->yw; o->z = matrix->zx * p.x + matrix->zy * p.y + matrix->zz * p.z + matrix->zw; o->w = matrix->wx * p.x + matrix->wy * p.y + matrix->wz * p.z + matrix->ww; } } static void _cogl_matrix_project_points_f4 (const CoglMatrix *matrix, size_t stride_in, void *points_in, size_t stride_out, void *points_out, int n_points) { int i; for (i = 0; i < n_points; i++) { Point4f p = *(Point4f *)((guint8 *)points_in + i * stride_in); Point4f *o = (Point4f *)((guint8 *)points_out + i * stride_out); o->x = matrix->xx * p.x + matrix->xy * p.y + matrix->xz * p.z + matrix->xw * p.w; o->y = matrix->yx * p.x + matrix->yy * p.y + matrix->yz * p.z + matrix->yw * p.w; o->z = matrix->zx * p.x + matrix->zy * p.y + matrix->zz * p.z + matrix->zw * p.w; o->w = matrix->wx * p.x + matrix->wy * p.y + matrix->wz * p.z + matrix->ww * p.w; } } void cogl_matrix_transform_points (const CoglMatrix *matrix, int n_components, size_t stride_in, void *points_in, size_t stride_out, void *points_out, int n_points) { /* The results of transforming always have three components... */ g_return_if_fail (stride_out >= sizeof (Point3f)); if (n_components == 2) _cogl_matrix_transform_points_f2 (matrix, stride_in, points_in, stride_out, points_out, n_points); else { g_return_if_fail (n_components == 3); _cogl_matrix_transform_points_f3 (matrix, stride_in, points_in, stride_out, points_out, n_points); } } void cogl_matrix_project_points (const CoglMatrix *matrix, int n_components, size_t stride_in, void *points_in, size_t stride_out, void *points_out, int n_points) { if (n_components == 2) _cogl_matrix_project_points_f2 (matrix, stride_in, points_in, stride_out, points_out, n_points); else if (n_components == 3) _cogl_matrix_project_points_f3 (matrix, stride_in, points_in, stride_out, points_out, n_points); else { g_return_if_fail (n_components == 4); _cogl_matrix_project_points_f4 (matrix, stride_in, points_in, stride_out, points_out, n_points); } }