/****************************************************************************** Copyright (C) 2013 by Hugh Bailey This program is free software: you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation, either version 2 of the License, or (at your option) any later version. This program 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 General Public License for more details. You should have received a copy of the GNU General Public License along with this program. If not, see . ******************************************************************************/ #include #include "vec2.h" #include "vec3.h" #include "math-defs.h" #include "math-extra.h" void polar_to_cart(struct vec3 *dst, const struct vec3 *v) { struct vec3 cart; float sinx = cosf(v->x); float sinx_z = v->z * sinx; cart.x = sinx_z * sinf(v->y); cart.z = sinx_z * cosf(v->y); cart.y = v->z * sinf(v->x); vec3_copy(dst, &cart); } void cart_to_polar(struct vec3 *dst, const struct vec3 *v) { struct vec3 polar; polar.z = vec3_len(v); if (close_float(polar.z, 0.0f, EPSILON)) { vec3_zero(&polar); } else { polar.x = asinf(v->y / polar.z); polar.y = atan2f(v->x, v->z); } vec3_copy(dst, &polar); } void norm_to_polar(struct vec2 *dst, const struct vec3 *norm) { dst->x = atan2f(norm->x, norm->z); dst->y = asinf(norm->y); } void polar_to_norm(struct vec3 *dst, const struct vec2 *polar) { float sinx = sinf(polar->x); dst->x = sinx * cosf(polar->y); dst->y = sinx * sinf(polar->y); dst->z = cosf(polar->x); } float calc_torquef(float val1, float val2, float torque, float min_adjust, float t) { float out = val1; float dist; bool over; if (close_float(val1, val2, EPSILON)) return val1; dist = (val2 - val1) * torque; over = dist > 0.0f; if (over) { if (dist < min_adjust) /* prevents from going too slow */ dist = min_adjust; out += dist * t; /* add torque */ if (out > val2) /* clamp if overshoot */ out = val2; } else { if (dist > -min_adjust) dist = -min_adjust; out += dist * t; if (out < val2) out = val2; } return out; } void calc_torque(struct vec3 *dst, const struct vec3 *v1, const struct vec3 *v2, float torque, float min_adjust, float t) { struct vec3 line, dir; float orig_dist, torque_dist, adjust_dist; if (vec3_close(v1, v2, EPSILON)) { vec3_copy(dst, v1); return; } vec3_sub(&line, v2, v1); orig_dist = vec3_len(&line); vec3_mulf(&dir, &line, 1.0f / orig_dist); torque_dist = orig_dist * torque; /* use distance to determine speed */ if (torque_dist < min_adjust) /* prevent from going too slow */ torque_dist = min_adjust; adjust_dist = torque_dist * t; if (adjust_dist <= (orig_dist - LARGE_EPSILON)) { vec3_mulf(dst, &dir, adjust_dist); vec3_add(dst, dst, v1); /* add torque */ } else { vec3_copy(dst, v2); /* clamp if overshoot */ } } float rand_float(int positive_only) { if (positive_only) return (float)((double)rand() / (double)RAND_MAX); else return (float)(((double)rand() / (double)RAND_MAX * 2.0) - 1.0); }