102 lines
3.1 KiB
C
102 lines
3.1 KiB
C
#include <math.h>
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#include "angle.h"
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#include "versor.h"
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const fp32_versor_t FP32_IDLE_VERSOR = { 1.0f, 0.0f, 0.0f, 0.0f };
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const fp64_versor_t FP64_IDLE_VERSOR = { 1.0, 0.0, 0.0, 0.0 };
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// =============== Set Crude Turn =============== //
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void fp32_versor_set_crude_turn(const float x1, const float x2, const float x3, const float angle, const angle_unit_t unit, fp32_versor_t* result)
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{
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const float square_vector = x1 * x1 + x2 * x2 + x3 * x3;
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if (square_vector <= FP32_SQUARE_EPSYLON) {
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fp32_versor_reset(result);
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return;
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}
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const float half_angle = fp32_angle_to_radians(0.5f * angle, unit);
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const float sine = sinf(half_angle);
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if (-FP32_EPSYLON <= sine && sine <= FP32_EPSYLON) {
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fp32_versor_reset(result);
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return;
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}
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const float multiplier = sine / sqrtf(square_vector);
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fp32_versor_set_values(cosf(half_angle), x1 * multiplier, x2 * multiplier, x3 * multiplier, result);
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}
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void fp64_versor_set_crude_turn(const double x1, const double x2, const double x3, const double angle, const angle_unit_t unit, fp64_versor_t* result)
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{
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const double square_vector = x1 * x1 + x2 * x2 + x3 * x3;
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if (square_vector <= FP64_SQUARE_EPSYLON) {
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fp64_versor_reset(result);
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return;
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}
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const double half_angle = fp64_angle_to_radians(0.5 * angle, unit);
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const double sine = sin(half_angle);
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if (-FP64_EPSYLON <= sine && sine <= FP64_EPSYLON) {
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fp64_versor_reset(result);
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return;
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}
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const double multiplier = sine / sqrt(square_vector);
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fp64_versor_set_values(cos(half_angle), x1 * multiplier, x2 * multiplier, x3 * multiplier, result);
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}
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// ================= Rotation3 ================== //
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void fp32_versor_get_rotation(const fp32_versor_t* versor, fp32_rotation3_t* result)
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{
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if (versor == 0 || result == 0) {
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return;
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}
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if (versor->s0 <= -(1.0f - FP32_EPSYLON) || 1.0f - FP32_EPSYLON <= versor->s0) {
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fp32_rotation_reset(result);
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return;
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}
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const float square_vector = versor->x1 * versor->x1 + versor->x2 * versor->x2 + versor->x3 * versor->x3;
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result->radians = 2.0f * acosf(versor->s0 / sqrtf(versor->s0 * versor->s0 + square_vector));
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const float multiplier = sqrtf(1.0f / square_vector);
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result->axis.x1 = versor->x1 * multiplier;
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result->axis.x2 = versor->x2 * multiplier;
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result->axis.x3 = versor->x3 * multiplier;
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}
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void fp64_versor_get_rotation(const fp64_versor_t* versor, fp64_rotation3_t* result)
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{
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if (versor == 0 || result == 0) {
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return;
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}
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if (versor->s0 <= -(1.0 - FP64_EPSYLON) || 1.0 - FP64_EPSYLON <= versor->s0) {
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fp64_rotation_reset(result);
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return;
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}
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const double square_vector = versor->x1 * versor->x1 + versor->x2 * versor->x2 + versor->x3 * versor->x3;
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result->radians = 2.0 * acos(versor->s0 / sqrt(versor->s0 * versor->s0 + square_vector));
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const double multiplier = sqrt(1.0 / square_vector);
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result->axis.x1 = versor->x1 * multiplier;
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result->axis.x2 = versor->x2 * multiplier;
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result->axis.x3 = versor->x3 * multiplier;
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}
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