forked from bartvdbraak/blender
9e4914e055
* Revert r57203 (len() renaming) There seems to be a problem with nVidia OpenCL after this and I haven't figured out the real cause yet. Better to selectively enable native length() later, after figuring out what's wrong. This fixes [#35612].
466 lines
13 KiB
C
466 lines
13 KiB
C
/*
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* Copyright 2011, Blender Foundation.
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*
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* This program is free software; you can redistribute it and/or
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* modify it under the terms of the GNU General Public License
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* as published by the Free Software Foundation; either version 2
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* of the License, or (at your option) any later version.
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*
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* This program is distributed in the hope that it will be useful,
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* but WITHOUT ANY WARRANTY; without even the implied warranty of
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* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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* GNU General Public License for more details.
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*
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* You should have received a copy of the GNU General Public License
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* along with this program; if not, write to the Free Software Foundation,
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* Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA.
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*/
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#ifndef __UTIL_TRANSFORM_H__
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#define __UTIL_TRANSFORM_H__
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#ifndef __KERNEL_GPU__
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#include <string.h>
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#endif
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#include "util_math.h"
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#include "util_types.h"
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CCL_NAMESPACE_BEGIN
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/* Data Types */
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typedef struct Transform {
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float4 x, y, z, w; /* rows */
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#ifndef __KERNEL_GPU__
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float4 operator[](int i) const { return *(&x + i); }
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float4& operator[](int i) { return *(&x + i); }
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#endif
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} Transform;
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/* transform decomposed in rotation/translation/scale. we use the same data
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* structure as Transform, and tightly pack decomposition into it. first the
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* rotation (4), then translation (3), then 3x3 scale matrix (9).
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*
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* For the DecompMotionTransform we drop scale from pre/post. */
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typedef struct __may_alias MotionTransform {
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Transform pre;
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Transform mid;
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Transform post;
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} MotionTransform;
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typedef struct DecompMotionTransform {
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Transform mid;
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float4 pre_x, pre_y;
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float4 post_x, post_y;
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} DecompMotionTransform;
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/* Functions */
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__device_inline float3 transform_perspective(const Transform *t, const float3 a)
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{
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float4 b = make_float4(a.x, a.y, a.z, 1.0f);
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float3 c = make_float3(dot(t->x, b), dot(t->y, b), dot(t->z, b));
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float w = dot(t->w, b);
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return (w != 0.0f)? c/w: make_float3(0.0f, 0.0f, 0.0f);
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}
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__device_inline float3 transform_point(const Transform *t, const float3 a)
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{
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float3 c = make_float3(
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a.x*t->x.x + a.y*t->x.y + a.z*t->x.z + t->x.w,
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a.x*t->y.x + a.y*t->y.y + a.z*t->y.z + t->y.w,
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a.x*t->z.x + a.y*t->z.y + a.z*t->z.z + t->z.w);
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return c;
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}
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__device_inline float3 transform_direction(const Transform *t, const float3 a)
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{
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float3 c = make_float3(
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a.x*t->x.x + a.y*t->x.y + a.z*t->x.z,
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a.x*t->y.x + a.y*t->y.y + a.z*t->y.z,
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a.x*t->z.x + a.y*t->z.y + a.z*t->z.z);
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return c;
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}
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__device_inline float3 transform_direction_transposed(const Transform *t, const float3 a)
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{
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float3 x = make_float3(t->x.x, t->y.x, t->z.x);
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float3 y = make_float3(t->x.y, t->y.y, t->z.y);
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float3 z = make_float3(t->x.z, t->y.z, t->z.z);
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return make_float3(dot(x, a), dot(y, a), dot(z, a));
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}
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__device_inline Transform transform_transpose(const Transform a)
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{
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Transform t;
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t.x.x = a.x.x; t.x.y = a.y.x; t.x.z = a.z.x; t.x.w = a.w.x;
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t.y.x = a.x.y; t.y.y = a.y.y; t.y.z = a.z.y; t.y.w = a.w.y;
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t.z.x = a.x.z; t.z.y = a.y.z; t.z.z = a.z.z; t.z.w = a.w.z;
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t.w.x = a.x.w; t.w.y = a.y.w; t.w.z = a.z.w; t.w.w = a.w.w;
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return t;
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}
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__device_inline Transform make_transform(float a, float b, float c, float d,
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float e, float f, float g, float h,
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float i, float j, float k, float l,
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float m, float n, float o, float p)
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{
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Transform t;
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t.x.x = a; t.x.y = b; t.x.z = c; t.x.w = d;
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t.y.x = e; t.y.y = f; t.y.z = g; t.y.w = h;
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t.z.x = i; t.z.y = j; t.z.z = k; t.z.w = l;
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t.w.x = m; t.w.y = n; t.w.z = o; t.w.w = p;
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return t;
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}
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#ifndef __KERNEL_GPU__
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__device_inline Transform operator*(const Transform a, const Transform b)
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{
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Transform c = transform_transpose(b);
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Transform t;
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t.x = make_float4(dot(a.x, c.x), dot(a.x, c.y), dot(a.x, c.z), dot(a.x, c.w));
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t.y = make_float4(dot(a.y, c.x), dot(a.y, c.y), dot(a.y, c.z), dot(a.y, c.w));
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t.z = make_float4(dot(a.z, c.x), dot(a.z, c.y), dot(a.z, c.z), dot(a.z, c.w));
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t.w = make_float4(dot(a.w, c.x), dot(a.w, c.y), dot(a.w, c.z), dot(a.w, c.w));
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return t;
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}
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__device_inline void print_transform(const char *label, const Transform& t)
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{
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print_float4(label, t.x);
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print_float4(label, t.y);
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print_float4(label, t.z);
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print_float4(label, t.w);
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printf("\n");
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}
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__device_inline Transform transform_translate(float3 t)
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{
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return make_transform(
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1, 0, 0, t.x,
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0, 1, 0, t.y,
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0, 0, 1, t.z,
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0, 0, 0, 1);
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}
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__device_inline Transform transform_translate(float x, float y, float z)
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{
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return transform_translate(make_float3(x, y, z));
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}
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__device_inline Transform transform_scale(float3 s)
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{
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return make_transform(
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s.x, 0, 0, 0,
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0, s.y, 0, 0,
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0, 0, s.z, 0,
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0, 0, 0, 1);
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}
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__device_inline Transform transform_scale(float x, float y, float z)
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{
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return transform_scale(make_float3(x, y, z));
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}
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__device_inline Transform transform_perspective(float fov, float n, float f)
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{
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Transform persp = make_transform(
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1, 0, 0, 0,
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0, 1, 0, 0,
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0, 0, f / (f - n), -f*n / (f - n),
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0, 0, 1, 0);
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float inv_angle = 1.0f/tanf(0.5f*fov);
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Transform scale = transform_scale(inv_angle, inv_angle, 1);
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return scale * persp;
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}
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__device_inline Transform transform_rotate(float angle, float3 axis)
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{
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float s = sinf(angle);
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float c = cosf(angle);
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float t = 1.0f - c;
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axis = normalize(axis);
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return make_transform(
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axis.x*axis.x*t + c,
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axis.x*axis.y*t - s*axis.z,
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axis.x*axis.z*t + s*axis.y,
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0.0f,
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axis.y*axis.x*t + s*axis.z,
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axis.y*axis.y*t + c,
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axis.y*axis.z*t - s*axis.x,
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0.0f,
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axis.z*axis.x*t - s*axis.y,
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axis.z*axis.y*t + s*axis.x,
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axis.z*axis.z*t + c,
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0.0f,
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0.0f, 0.0f, 0.0f, 1.0f);
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}
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__device_inline Transform transform_euler(float3 euler)
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{
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return
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transform_rotate(euler.x, make_float3(1.0f, 0.0f, 0.0f)) *
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transform_rotate(euler.y, make_float3(0.0f, 1.0f, 0.0f)) *
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transform_rotate(euler.z, make_float3(0.0f, 0.0f, 1.0f));
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}
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__device_inline Transform transform_orthographic(float znear, float zfar)
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{
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return transform_scale(1.0f, 1.0f, 1.0f / (zfar-znear)) *
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transform_translate(0.0f, 0.0f, -znear);
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}
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__device_inline Transform transform_identity()
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{
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return transform_scale(1.0f, 1.0f, 1.0f);
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}
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__device_inline bool operator==(const Transform& A, const Transform& B)
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{
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return memcmp(&A, &B, sizeof(Transform)) == 0;
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}
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__device_inline bool operator!=(const Transform& A, const Transform& B)
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{
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return !(A == B);
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}
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__device_inline float3 transform_get_column(const Transform *t, int column)
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{
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return make_float3(t->x[column], t->y[column], t->z[column]);
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}
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__device_inline void transform_set_column(Transform *t, int column, float3 value)
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{
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t->x[column] = value.x;
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t->y[column] = value.y;
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t->z[column] = value.z;
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}
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Transform transform_inverse(const Transform& a);
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__device_inline bool transform_uniform_scale(const Transform& tfm, float& scale)
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{
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/* the epsilon here is quite arbitrary, but this function is only used for
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* surface area and bump, where we except it to not be so sensitive */
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Transform ttfm = transform_transpose(tfm);
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float eps = 1e-6f;
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float sx = len_squared(float4_to_float3(tfm.x));
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float sy = len_squared(float4_to_float3(tfm.y));
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float sz = len_squared(float4_to_float3(tfm.z));
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float stx = len_squared(float4_to_float3(ttfm.x));
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float sty = len_squared(float4_to_float3(ttfm.y));
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float stz = len_squared(float4_to_float3(ttfm.z));
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if(fabsf(sx - sy) < eps && fabsf(sx - sz) < eps &&
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fabsf(sx - stx) < eps && fabsf(sx - sty) < eps &&
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fabsf(sx - stz) < eps) {
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scale = sx;
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return true;
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}
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return false;
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}
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__device_inline bool transform_negative_scale(const Transform& tfm)
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{
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float3 c0 = transform_get_column(&tfm, 0);
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float3 c1 = transform_get_column(&tfm, 1);
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float3 c2 = transform_get_column(&tfm, 2);
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return (dot(cross(c0, c1), c2) < 0.0f);
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}
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__device_inline Transform transform_clear_scale(const Transform& tfm)
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{
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Transform ntfm = tfm;
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transform_set_column(&ntfm, 0, normalize(transform_get_column(&ntfm, 0)));
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transform_set_column(&ntfm, 1, normalize(transform_get_column(&ntfm, 1)));
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transform_set_column(&ntfm, 2, normalize(transform_get_column(&ntfm, 2)));
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return ntfm;
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}
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#endif
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/* Motion Transform */
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__device_inline float4 quat_interpolate(float4 q1, float4 q2, float t)
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{
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/* use simpe nlerp instead of slerp. it's faster and almost the same */
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return normalize((1.0f - t)*q1 + t*q2);
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#if 0
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/* note: this does not ensure rotation around shortest angle, q1 and q2
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* are assumed to be matched already in transform_motion_decompose */
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float costheta = dot(q1, q2);
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/* possible optimization: it might be possible to precompute theta/qperp */
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if(costheta > 0.9995f) {
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/* linear interpolation in degenerate case */
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return normalize((1.0f - t)*q1 + t*q2);
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}
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else {
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/* slerp */
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float theta = acosf(clamp(costheta, -1.0f, 1.0f));
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float4 qperp = normalize(q2 - q1 * costheta);
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float thetap = theta * t;
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return q1 * cosf(thetap) + qperp * sinf(thetap);
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}
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#endif
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}
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__device_inline Transform transform_quick_inverse(Transform M)
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{
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/* possible optimization: can we avoid doing this altogether and construct
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* the inverse matrix directly from negated translation, transposed rotation,
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* scale can be inverted but what about shearing? */
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Transform R;
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float det = M.x.x*(M.z.z*M.y.y - M.z.y*M.y.z) - M.y.x*(M.z.z*M.x.y - M.z.y*M.x.z) + M.z.x*(M.y.z*M.x.y - M.y.y*M.x.z);
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det = (det != 0.0f)? 1.0f/det: 0.0f;
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float3 Rx = det*make_float3(M.z.z*M.y.y - M.z.y*M.y.z, M.z.y*M.x.z - M.z.z*M.x.y, M.y.z*M.x.y - M.y.y*M.x.z);
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float3 Ry = det*make_float3(M.z.x*M.y.z - M.z.z*M.y.x, M.z.z*M.x.x - M.z.x*M.x.z, M.y.x*M.x.z - M.y.z*M.x.x);
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float3 Rz = det*make_float3(M.z.y*M.y.x - M.z.x*M.y.y, M.z.x*M.x.y - M.z.y*M.x.x, M.y.y*M.x.x - M.y.x*M.x.y);
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float3 T = -make_float3(M.x.w, M.y.w, M.z.w);
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R.x = make_float4(Rx.x, Rx.y, Rx.z, dot(Rx, T));
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R.y = make_float4(Ry.x, Ry.y, Ry.z, dot(Ry, T));
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R.z = make_float4(Rz.x, Rz.y, Rz.z, dot(Rz, T));
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R.w = make_float4(0.0f, 0.0f, 0.0f, 1.0f);
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return R;
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}
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__device_inline void transform_compose(Transform *tfm, const Transform *decomp)
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{
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/* rotation */
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float q0, q1, q2, q3, qda, qdb, qdc, qaa, qab, qac, qbb, qbc, qcc;
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q0 = M_SQRT2_F * decomp->x.w;
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q1 = M_SQRT2_F * decomp->x.x;
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q2 = M_SQRT2_F * decomp->x.y;
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q3 = M_SQRT2_F * decomp->x.z;
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qda = q0*q1;
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qdb = q0*q2;
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qdc = q0*q3;
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qaa = q1*q1;
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qab = q1*q2;
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qac = q1*q3;
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qbb = q2*q2;
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qbc = q2*q3;
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qcc = q3*q3;
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float3 rotation_x = make_float3(1.0f-qbb-qcc, -qdc+qab, qdb+qac);
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float3 rotation_y = make_float3(qdc+qab, 1.0f-qaa-qcc, -qda+qbc);
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float3 rotation_z = make_float3(-qdb+qac, qda+qbc, 1.0f-qaa-qbb);
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/* scale */
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float3 scale_x = make_float3(decomp->y.w, decomp->z.z, decomp->w.y);
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float3 scale_y = make_float3(decomp->z.x, decomp->z.w, decomp->w.z);
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float3 scale_z = make_float3(decomp->z.y, decomp->w.x, decomp->w.w);
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/* compose with translation */
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tfm->x = make_float4(dot(rotation_x, scale_x), dot(rotation_x, scale_y), dot(rotation_x, scale_z), decomp->y.x);
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tfm->y = make_float4(dot(rotation_y, scale_x), dot(rotation_y, scale_y), dot(rotation_y, scale_z), decomp->y.y);
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tfm->z = make_float4(dot(rotation_z, scale_x), dot(rotation_z, scale_y), dot(rotation_z, scale_z), decomp->y.z);
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tfm->w = make_float4(0.0f, 0.0f, 0.0f, 1.0f);
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}
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/* Disabled for now, need arc-length parametrization for constant speed motion.
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* #define CURVED_MOTION_INTERPOLATE */
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__device void transform_motion_interpolate(Transform *tfm, const DecompMotionTransform *motion, float t)
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{
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/* possible optimization: is it worth it adding a check to skip scaling?
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* it's probably quite uncommon to have scaling objects. or can we skip
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* just shearing perhaps? */
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Transform decomp;
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#ifdef CURVED_MOTION_INTERPOLATE
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/* 3 point bezier curve interpolation for position */
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float3 Ppre = float4_to_float3(motion->pre_y);
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float3 Pmid = float4_to_float3(motion->mid.y);
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float3 Ppost = float4_to_float3(motion->post_y);
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float3 Pcontrol = 2.0f*Pmid - 0.5f*(Ppre + Ppost);
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float3 P = Ppre*t*t + Pcontrol*2.0f*t*(1.0f - t) + Ppost*(1.0f - t)*(1.0f - t);
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decomp.y.x = P.x;
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decomp.y.y = P.y;
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decomp.y.z = P.z;
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#endif
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/* linear interpolation for rotation and scale */
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if(t < 0.5f) {
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t *= 2.0f;
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decomp.x = quat_interpolate(motion->pre_x, motion->mid.x, t);
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#ifdef CURVED_MOTION_INTERPOLATE
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decomp.y.w = (1.0f - t)*motion->pre_y.w + t*motion->mid.y.w;
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#else
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decomp.y = (1.0f - t)*motion->pre_y + t*motion->mid.y;
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#endif
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}
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else {
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t = (t - 0.5f)*2.0f;
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|
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decomp.x = quat_interpolate(motion->mid.x, motion->post_x, t);
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#ifdef CURVED_MOTION_INTERPOLATE
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decomp.y.w = (1.0f - t)*motion->mid.y.w + t*motion->post_y.w;
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#else
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|
decomp.y = (1.0f - t)*motion->mid.y + t*motion->post_y;
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#endif
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|
}
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|
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decomp.z = motion->mid.z;
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|
decomp.w = motion->mid.w;
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|
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|
/* compose rotation, translation, scale into matrix */
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transform_compose(tfm, &decomp);
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|
}
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|
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#ifndef __KERNEL_GPU__
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|
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__device_inline bool operator==(const MotionTransform& A, const MotionTransform& B)
|
|
{
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|
return (A.pre == B.pre && A.post == B.post);
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|
}
|
|
|
|
float4 transform_to_quat(const Transform& tfm);
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|
void transform_motion_decompose(DecompMotionTransform *decomp, const MotionTransform *motion, const Transform *mid);
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|
|
|
#endif
|
|
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|
CCL_NAMESPACE_END
|
|
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|
#endif /* __UTIL_TRANSFORM_H__ */
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|
|