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blender-archive/intern/cycles/util/math_float3.h
Andrii Symkin c2a2f3553a Cycles: unify math functions names 
This patch unifies the names of math functions for different data types and uses
overloading instead. The goal is to make it possible to swap out all the float3
variables containing RGB data with something else, with as few as possible
changes to the code. It's a requirement for future spectral rendering patches.

Differential Revision: https://developer.blender.org/D15276
2022-06-23 15:02:53 +02:00

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/* SPDX-License-Identifier: Apache-2.0
* Copyright 2011-2022 Blender Foundation */
#ifndef __UTIL_MATH_FLOAT3_H__
#define __UTIL_MATH_FLOAT3_H__
#ifndef __UTIL_MATH_H__
# error "Do not include this file directly, include util/types.h instead."
#endif
CCL_NAMESPACE_BEGIN
/*******************************************************************************
* Declaration.
*/
#if !defined(__KERNEL_METAL__)
ccl_device_inline float3 operator-(const float3 &a);
ccl_device_inline float3 operator*(const float3 &a, const float3 &b);
ccl_device_inline float3 operator*(const float3 &a, const float f);
ccl_device_inline float3 operator*(const float f, const float3 &a);
ccl_device_inline float3 operator/(const float f, const float3 &a);
ccl_device_inline float3 operator/(const float3 &a, const float f);
ccl_device_inline float3 operator/(const float3 &a, const float3 &b);
ccl_device_inline float3 operator+(const float3 &a, const float f);
ccl_device_inline float3 operator+(const float3 &a, const float3 &b);
ccl_device_inline float3 operator-(const float3 &a, const float f);
ccl_device_inline float3 operator-(const float3 &a, const float3 &b);
ccl_device_inline float3 operator+=(float3 &a, const float3 &b);
ccl_device_inline float3 operator-=(float3 &a, const float3 &b);
ccl_device_inline float3 operator*=(float3 &a, const float3 &b);
ccl_device_inline float3 operator*=(float3 &a, float f);
ccl_device_inline float3 operator/=(float3 &a, const float3 &b);
ccl_device_inline float3 operator/=(float3 &a, float f);
ccl_device_inline bool operator==(const float3 &a, const float3 &b);
ccl_device_inline bool operator!=(const float3 &a, const float3 &b);
ccl_device_inline float distance(const float3 &a, const float3 &b);
ccl_device_inline float dot(const float3 &a, const float3 &b);
ccl_device_inline float dot_xy(const float3 &a, const float3 &b);
ccl_device_inline float3 cross(const float3 &a, const float3 &b);
ccl_device_inline float3 normalize(const float3 &a);
ccl_device_inline float3 min(const float3 &a, const float3 &b);
ccl_device_inline float3 max(const float3 &a, const float3 &b);
ccl_device_inline float3 clamp(const float3 &a, const float3 &mn, const float3 &mx);
ccl_device_inline float3 fabs(const float3 &a);
ccl_device_inline float3 mix(const float3 &a, const float3 &b, float t);
ccl_device_inline float3 rcp(const float3 &a);
ccl_device_inline float3 sqrt(const float3 &a);
ccl_device_inline float3 floor(const float3 &a);
ccl_device_inline float3 ceil(const float3 &a);
ccl_device_inline float3 reflect(const float3 incident, const float3 normal);
#endif /* !defined(__KERNEL_METAL__) */
ccl_device_inline float reduce_min(float3 a);
ccl_device_inline float reduce_max(float3 a);
ccl_device_inline float len(const float3 a);
ccl_device_inline float len_squared(const float3 a);
ccl_device_inline float3 project(const float3 v, const float3 v_proj);
ccl_device_inline float3 safe_normalize(const float3 a);
ccl_device_inline float3 normalize_len(const float3 a, ccl_private float *t);
ccl_device_inline float3 safe_normalize_len(const float3 a, ccl_private float *t);
ccl_device_inline float3 safe_divide(const float3 a, const float3 b);
ccl_device_inline float3 safe_divide(const float3 a, const float b);
ccl_device_inline float3 interp(float3 a, float3 b, float t);
ccl_device_inline float3 sqr(float3 a);
ccl_device_inline bool is_zero(const float3 a);
ccl_device_inline float reduce_add(const float3 a);
ccl_device_inline float average(const float3 a);
ccl_device_inline bool isequal(const float3 a, const float3 b);
/*******************************************************************************
* Definition.
*/
ccl_device_inline float3 zero_float3()
{
#ifdef __KERNEL_SSE__
return float3(_mm_setzero_ps());
#else
return make_float3(0.0f, 0.0f, 0.0f);
#endif
}
ccl_device_inline float3 one_float3()
{
return make_float3(1.0f, 1.0f, 1.0f);
}
#if defined(__KERNEL_METAL__)
ccl_device_inline float3 rcp(float3 a)
{
return make_float3(1.0f / a.x, 1.0f / a.y, 1.0f / a.z);
}
#else
ccl_device_inline float3 operator-(const float3 &a)
{
# ifdef __KERNEL_SSE__
return float3(_mm_xor_ps(a.m128, _mm_castsi128_ps(_mm_set1_epi32(0x80000000))));
# else
return make_float3(-a.x, -a.y, -a.z);
# endif
}
ccl_device_inline float3 operator*(const float3 &a, const float3 &b)
{
# ifdef __KERNEL_SSE__
return float3(_mm_mul_ps(a.m128, b.m128));
# else
return make_float3(a.x * b.x, a.y * b.y, a.z * b.z);
# endif
}
ccl_device_inline float3 operator*(const float3 &a, const float f)
{
# ifdef __KERNEL_SSE__
return float3(_mm_mul_ps(a.m128, _mm_set1_ps(f)));
# else
return make_float3(a.x * f, a.y * f, a.z * f);
# endif
}
ccl_device_inline float3 operator*(const float f, const float3 &a)
{
# if defined(__KERNEL_SSE__)
return float3(_mm_mul_ps(_mm_set1_ps(f), a.m128));
# else
return make_float3(a.x * f, a.y * f, a.z * f);
# endif
}
ccl_device_inline float3 operator/(const float f, const float3 &a)
{
# if defined(__KERNEL_SSE__)
return float3(_mm_div_ps(_mm_set1_ps(f), a.m128));
# else
return make_float3(f / a.x, f / a.y, f / a.z);
# endif
}
ccl_device_inline float3 operator/(const float3 &a, const float f)
{
float invf = 1.0f / f;
return a * invf;
}
ccl_device_inline float3 operator/(const float3 &a, const float3 &b)
{
# if defined(__KERNEL_SSE__)
return float3(_mm_div_ps(a.m128, b.m128));
# else
return make_float3(a.x / b.x, a.y / b.y, a.z / b.z);
# endif
}
ccl_device_inline float3 operator+(const float3 &a, const float f)
{
return a + make_float3(f, f, f);
}
ccl_device_inline float3 operator+(const float3 &a, const float3 &b)
{
# ifdef __KERNEL_SSE__
return float3(_mm_add_ps(a.m128, b.m128));
# else
return make_float3(a.x + b.x, a.y + b.y, a.z + b.z);
# endif
}
ccl_device_inline float3 operator-(const float3 &a, const float f)
{
return a - make_float3(f, f, f);
}
ccl_device_inline float3 operator-(const float3 &a, const float3 &b)
{
# ifdef __KERNEL_SSE__
return float3(_mm_sub_ps(a.m128, b.m128));
# else
return make_float3(a.x - b.x, a.y - b.y, a.z - b.z);
# endif
}
ccl_device_inline float3 operator+=(float3 &a, const float3 &b)
{
return a = a + b;
}
ccl_device_inline float3 operator-=(float3 &a, const float3 &b)
{
return a = a - b;
}
ccl_device_inline float3 operator*=(float3 &a, const float3 &b)
{
return a = a * b;
}
ccl_device_inline float3 operator*=(float3 &a, float f)
{
return a = a * f;
}
ccl_device_inline float3 operator/=(float3 &a, const float3 &b)
{
return a = a / b;
}
ccl_device_inline float3 operator/=(float3 &a, float f)
{
float invf = 1.0f / f;
return a = a * invf;
}
# if !(defined(__KERNEL_METAL__) || defined(__KERNEL_CUDA__))
ccl_device_inline packed_float3 operator*=(packed_float3 &a, const float3 &b)
{
a = float3(a) * b;
return a;
}
ccl_device_inline packed_float3 operator*=(packed_float3 &a, float f)
{
a = float3(a) * f;
return a;
}
ccl_device_inline packed_float3 operator/=(packed_float3 &a, const float3 &b)
{
a = float3(a) / b;
return a;
}
ccl_device_inline packed_float3 operator/=(packed_float3 &a, float f)
{
a = float3(a) / f;
return a;
}
# endif
ccl_device_inline bool operator==(const float3 &a, const float3 &b)
{
# ifdef __KERNEL_SSE__
return (_mm_movemask_ps(_mm_cmpeq_ps(a.m128, b.m128)) & 7) == 7;
# else
return (a.x == b.x && a.y == b.y && a.z == b.z);
# endif
}
ccl_device_inline bool operator!=(const float3 &a, const float3 &b)
{
return !(a == b);
}
ccl_device_inline float distance(const float3 &a, const float3 &b)
{
return len(a - b);
}
ccl_device_inline float dot(const float3 &a, const float3 &b)
{
# if defined(__KERNEL_SSE41__) && defined(__KERNEL_SSE__)
return _mm_cvtss_f32(_mm_dp_ps(a, b, 0x7F));
# else
return a.x * b.x + a.y * b.y + a.z * b.z;
# endif
}
ccl_device_inline float dot_xy(const float3 &a, const float3 &b)
{
# if defined(__KERNEL_SSE41__) && defined(__KERNEL_SSE__)
return _mm_cvtss_f32(_mm_hadd_ps(_mm_mul_ps(a, b), b));
# else
return a.x * b.x + a.y * b.y;
# endif
}
ccl_device_inline float3 cross(const float3 &a, const float3 &b)
{
float3 r = make_float3(a.y * b.z - a.z * b.y, a.z * b.x - a.x * b.z, a.x * b.y - a.y * b.x);
return r;
}
ccl_device_inline float3 normalize(const float3 &a)
{
# if defined(__KERNEL_SSE41__) && defined(__KERNEL_SSE__)
__m128 norm = _mm_sqrt_ps(_mm_dp_ps(a.m128, a.m128, 0x7F));
return float3(_mm_div_ps(a.m128, norm));
# else
return a / len(a);
# endif
}
ccl_device_inline float3 min(const float3 &a, const float3 &b)
{
# ifdef __KERNEL_SSE__
return float3(_mm_min_ps(a.m128, b.m128));
# else
return make_float3(min(a.x, b.x), min(a.y, b.y), min(a.z, b.z));
# endif
}
ccl_device_inline float3 max(const float3 &a, const float3 &b)
{
# ifdef __KERNEL_SSE__
return float3(_mm_max_ps(a.m128, b.m128));
# else
return make_float3(max(a.x, b.x), max(a.y, b.y), max(a.z, b.z));
# endif
}
ccl_device_inline float3 clamp(const float3 &a, const float3 &mn, const float3 &mx)
{
return min(max(a, mn), mx);
}
ccl_device_inline float3 fabs(const float3 &a)
{
# ifdef __KERNEL_SSE__
# ifdef __KERNEL_NEON__
return float3(vabsq_f32(a.m128));
# else
__m128 mask = _mm_castsi128_ps(_mm_set1_epi32(0x7fffffff));
return float3(_mm_and_ps(a.m128, mask));
# endif
# else
return make_float3(fabsf(a.x), fabsf(a.y), fabsf(a.z));
# endif
}
ccl_device_inline float3 sqrt(const float3 &a)
{
# ifdef __KERNEL_SSE__
return float3(_mm_sqrt_ps(a));
# else
return make_float3(sqrtf(a.x), sqrtf(a.y), sqrtf(a.z));
# endif
}
ccl_device_inline float3 floor(const float3 &a)
{
# ifdef __KERNEL_SSE__
return float3(_mm_floor_ps(a));
# else
return make_float3(floorf(a.x), floorf(a.y), floorf(a.z));
# endif
}
ccl_device_inline float3 ceil(const float3 &a)
{
# ifdef __KERNEL_SSE__
return float3(_mm_ceil_ps(a));
# else
return make_float3(ceilf(a.x), ceilf(a.y), ceilf(a.z));
# endif
}
ccl_device_inline float3 mix(const float3 &a, const float3 &b, float t)
{
return a + t * (b - a);
}
ccl_device_inline float3 rcp(const float3 &a)
{
# ifdef __KERNEL_SSE__
/* Don't use _mm_rcp_ps due to poor precision. */
return float3(_mm_div_ps(_mm_set_ps1(1.0f), a.m128));
# else
return make_float3(1.0f / a.x, 1.0f / a.y, 1.0f / a.z);
# endif
}
ccl_device_inline float3 saturate(float3 a)
{
return make_float3(saturatef(a.x), saturatef(a.y), saturatef(a.z));
}
ccl_device_inline float3 exp(float3 v)
{
return make_float3(expf(v.x), expf(v.y), expf(v.z));
}
ccl_device_inline float3 log(float3 v)
{
return make_float3(logf(v.x), logf(v.y), logf(v.z));
}
#endif /* !__KERNEL_METAL__ */
ccl_device_inline float reduce_min(float3 a)
{
return min(min(a.x, a.y), a.z);
}
ccl_device_inline float reduce_max(float3 a)
{
return max(max(a.x, a.y), a.z);
}
ccl_device_inline float len(const float3 a)
{
#if defined(__KERNEL_SSE41__) && defined(__KERNEL_SSE__)
return _mm_cvtss_f32(_mm_sqrt_ss(_mm_dp_ps(a.m128, a.m128, 0x7F)));
#else
return sqrtf(dot(a, a));
#endif
}
ccl_device_inline float len_squared(const float3 a)
{
return dot(a, a);
}
#if !defined(__KERNEL_METAL__)
ccl_device_inline float3 reflect(const float3 incident, const float3 normal)
{
float3 unit_normal = normalize(normal);
return incident - 2.0f * unit_normal * dot(incident, unit_normal);
}
ccl_device_inline float3 refract(const float3 incident, const float3 normal, const float eta)
{
float k = 1.0f - eta * eta * (1.0f - dot(normal, incident) * dot(normal, incident));
if (k < 0.0f)
return zero_float3();
else
return eta * incident - (eta * dot(normal, incident) + sqrt(k)) * normal;
}
ccl_device_inline float3 faceforward(const float3 vector,
const float3 incident,
const float3 reference)
{
return (dot(reference, incident) < 0.0f) ? vector : -vector;
}
#endif
ccl_device_inline float3 project(const float3 v, const float3 v_proj)
{
float len_squared = dot(v_proj, v_proj);
return (len_squared != 0.0f) ? (dot(v, v_proj) / len_squared) * v_proj : zero_float3();
}
ccl_device_inline float3 normalize_len(const float3 a, ccl_private float *t)
{
*t = len(a);
float x = 1.0f / *t;
return a * x;
}
ccl_device_inline float3 safe_normalize(const float3 a)
{
float t = len(a);
return (t != 0.0f) ? a * (1.0f / t) : a;
}
ccl_device_inline float3 safe_normalize_len(const float3 a, ccl_private float *t)
{
*t = len(a);
return (*t != 0.0f) ? a / (*t) : a;
}
ccl_device_inline float3 safe_divide(const float3 a, const float3 b)
{
return make_float3((b.x != 0.0f) ? a.x / b.x : 0.0f,
(b.y != 0.0f) ? a.y / b.y : 0.0f,
(b.z != 0.0f) ? a.z / b.z : 0.0f);
}
ccl_device_inline float3 safe_divide(const float3 a, const float b)
{
return (b != 0.0f) ? a / b : zero_float3();
}
ccl_device_inline float3 interp(float3 a, float3 b, float t)
{
return a + t * (b - a);
}
ccl_device_inline float3 sqr(float3 a)
{
return a * a;
}
ccl_device_inline bool is_zero(const float3 a)
{
#ifdef __KERNEL_SSE__
return a == make_float3(0.0f);
#else
return (a.x == 0.0f && a.y == 0.0f && a.z == 0.0f);
#endif
}
ccl_device_inline float reduce_add(const float3 a)
{
#if defined(__KERNEL_SSE__) && defined(__KERNEL_NEON__)
__m128 t = a.m128;
t[3] = 0.0f;
return vaddvq_f32(t);
#else
return (a.x + a.y + a.z);
#endif
}
ccl_device_inline float average(const float3 a)
{
return reduce_add(a) * (1.0f / 3.0f);
}
ccl_device_inline bool isequal(const float3 a, const float3 b)
{
#if defined(__KERNEL_METAL__)
return all(a == b);
#else
return a == b;
#endif
}
ccl_device_inline float3 pow(float3 v, float e)
{
return make_float3(powf(v.x, e), powf(v.y, e), powf(v.z, e));
}
ccl_device_inline int3 quick_floor_to_int3(const float3 a)
{
#ifdef __KERNEL_SSE__
int3 b = int3(_mm_cvttps_epi32(a.m128));
int3 isneg = int3(_mm_castps_si128(_mm_cmplt_ps(a.m128, _mm_set_ps1(0.0f))));
/* Unsaturated add 0xffffffff is the same as subtract -1. */
return b + isneg;
#else
return make_int3(quick_floor_to_int(a.x), quick_floor_to_int(a.y), quick_floor_to_int(a.z));
#endif
}
ccl_device_inline bool isfinite_safe(float3 v)
{
return isfinite_safe(v.x) && isfinite_safe(v.y) && isfinite_safe(v.z);
}
ccl_device_inline float3 ensure_finite(float3 v)
{
if (!isfinite_safe(v.x))
v.x = 0.0f;
if (!isfinite_safe(v.y))
v.y = 0.0f;
if (!isfinite_safe(v.z))
v.z = 0.0f;
return v;
}
CCL_NAMESPACE_END
#endif /* __UTIL_MATH_FLOAT3_H__ */
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