kopia lustrzana https://github.com/Aircoookie/WLED
140 wiersze
3.8 KiB
C++
140 wiersze
3.8 KiB
C++
/*
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* Contains some trigonometric functions.
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* The ANSI C equivalents are likely faster, but using any sin/cos/tan function incurs a memory penalty of 460 bytes on ESP8266, likely for lookup tables.
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* This implementation has no extra static memory usage.
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*
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* Source of the cos_t() function: https://web.eecs.utk.edu/~azh/blog/cosine.html (cos_taylor_literal_6terms)
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*/
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#include <Arduino.h> //PI constant
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//#define WLED_DEBUG_MATH
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#define modd(x, y) ((x) - (int)((x) / (y)) * (y))
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float cos_t(float phi)
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{
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float x = modd(phi, TWO_PI);
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if (x < 0) x = -1 * x;
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int8_t sign = 1;
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if (x > PI)
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{
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x -= PI;
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sign = -1;
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}
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float xx = x * x;
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float res = sign * (1 - ((xx) / (2)) + ((xx * xx) / (24)) - ((xx * xx * xx) / (720)) + ((xx * xx * xx * xx) / (40320)) - ((xx * xx * xx * xx * xx) / (3628800)) + ((xx * xx * xx * xx * xx * xx) / (479001600)));
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#ifdef WLED_DEBUG_MATH
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Serial.printf("cos: %f,%f,%f,(%f)\n",phi,res,cos(x),res-cos(x));
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#endif
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return res;
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}
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float sin_t(float x) {
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float res = cos_t(HALF_PI - x);
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#ifdef WLED_DEBUG_MATH
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Serial.printf("sin: %f,%f,%f,(%f)\n",x,res,sin(x),res-sin(x));
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#endif
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return res;
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}
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float tan_t(float x) {
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float c = cos_t(x);
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if (c==0.0) return 0;
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float res = sin_t(x) / c;
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#ifdef WLED_DEBUG_MATH
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Serial.printf("tan: %f,%f,%f,(%f)\n",x,res,tan(x),res-tan(x));
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#endif
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return res;
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}
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//https://stackoverflow.com/questions/3380628
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// Absolute error <= 6.7e-5
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float acos_t(float x) {
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float negate = float(x < 0);
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float xabs = std::abs(x);
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float ret = -0.0187293;
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ret = ret * xabs;
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ret = ret + 0.0742610;
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ret = ret * xabs;
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ret = ret - 0.2121144;
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ret = ret * xabs;
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ret = ret + HALF_PI;
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ret = ret * sqrt(1.0-xabs);
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ret = ret - 2 * negate * ret;
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float res = negate * PI + ret;
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#ifdef WLED_DEBUG_MATH
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Serial.printf("acos: %f,%f,%f,(%f)\n",x,res,acos(x),res-acos(x));
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#endif
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return res;
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}
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float asin_t(float x) {
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float res = HALF_PI - acos_t(x);
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#ifdef WLED_DEBUG_MATH
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Serial.printf("asin: %f,%f,%f,(%f)\n",x,res,asin(x),res-asin(x));
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#endif
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return res;
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}
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// declare a template with no implementation, and only one specialization
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// this allows hiding the constants, while ensuring ODR causes optimizations
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// to still apply. (Fixes issues with conflicting 3rd party #define's)
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template <typename T> T atan_t(T x);
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template<>
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float atan_t(float x) {
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//For A/B/C, see https://stackoverflow.com/a/42542593
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static const double A { 0.0776509570923569 };
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static const double B { -0.287434475393028 };
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static const double C { ((HALF_PI/2) - A - B) };
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// polynominal factors for approximation between 1 and 5
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static const float C0 { 0.089494f };
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static const float C1 { 0.974207f };
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static const float C2 { -0.326175f };
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static const float C3 { 0.05375f };
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static const float C4 { -0.003445f };
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#ifdef WLED_DEBUG_MATH
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float xinput = x;
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#endif
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bool neg = (x < 0);
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x = std::abs(x);
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float res;
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if (x > 5.0f) { // atan(x) converges to pi/2 - (1/x) for large values
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res = HALF_PI - (1.0f/x);
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} else if (x > 1.0f) { //1 < x < 5
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float xx = x * x;
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res = (C4*xx*xx)+(C3*xx*x)+(C2*xx)+(C1*x)+C0;
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} else { // this approximation is only for x <= 1
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float xx = x * x;
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res = ((A*xx + B)*xx + C)*x;
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}
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if (neg) {
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res = -res;
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}
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#ifdef WLED_DEBUG_MATH
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Serial.printf("atan: %f,%f,%f,(%f)\n",xinput,res,atan(xinput),res-atan(xinput));
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#endif
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return res;
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}
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float floor_t(float x) {
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bool neg = x < 0;
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int val = x;
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if (neg) val--;
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#ifdef WLED_DEBUG_MATH
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Serial.printf("floor: %f,%f,%f\n",x,(float)val,floor(x));
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#endif
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return val;
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}
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float fmod_t(float num, float denom) {
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int tquot = num / denom;
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float res = num - tquot * denom;
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#ifdef WLED_DEBUG_MATH
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Serial.printf("fmod: %f,%f,(%f)\n",res,fmod(num,denom),res-fmod(num,denom));
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#endif
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return res;
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}
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