From 9b3eff2ee85ca6627342cfbbe1ac3ba988dc377f Mon Sep 17 00:00:00 2001
From: Dan Goodliffe <dan@randomdan.homeip.net>
Date: Fri, 20 Sep 2024 20:27:51 +0100
Subject: Move getSunPos to Environment

---
 test/test-environment.cpp | 70 ++---------------------------------------------
 1 file changed, 2 insertions(+), 68 deletions(-)

(limited to 'test/test-environment.cpp')

diff --git a/test/test-environment.cpp b/test/test-environment.cpp
index 0e9e37a..b6e0e4f 100644
--- a/test/test-environment.cpp
+++ b/test/test-environment.cpp
@@ -6,75 +6,9 @@
 
 #include <chronology.h>
 #include <config/types.h>
+#include <game/environment.h>
 #include <maths.h>
 
-// Based on the C++ code published at https://www.psa.es/sdg/sunpos.htm
-// Linked from https://www.pveducation.org/pvcdrom/properties-of-sunlight/suns-position-to-high-accuracy
-Direction2D
-getSunPos(const Direction2D position, const time_t time)
-{
-	auto & longitude = position.x;
-	auto & latitude = position.y;
-	using std::acos;
-	using std::asin;
-	using std::atan2;
-	using std::cos;
-	using std::floor;
-	using std::sin;
-	using std::tan;
-	static const auto JD2451545 = "2000-01-01T12:00:00"_time_t;
-
-	// Calculate difference in days between the current Julian Day
-	// and JD 2451545.0, which is noon 1 January 2000 Universal Time
-	// Calculate time of the day in UT decimal hours
-	const auto dDecimalHours = static_cast<float>(time % 86400) / 3600.F;
-	const auto dElapsedJulianDays = static_cast<float>(time - JD2451545) / 86400.F;
-
-	// Calculate ecliptic coordinates (ecliptic longitude and obliquity of the
-	// ecliptic in radians but without limiting the angle to be less than 2*Pi
-	// (i.e., the result may be greater than 2*Pi)
-	const auto dOmega = 2.1429F - 0.0010394594F * dElapsedJulianDays;
-	const auto dMeanLongitude = 4.8950630F + 0.017202791698F * dElapsedJulianDays; // Radians
-	const auto dMeanAnomaly = 6.2400600F + 0.0172019699F * dElapsedJulianDays;
-	const auto dEclipticLongitude = dMeanLongitude + 0.03341607F * sin(dMeanAnomaly)
-			+ 0.00034894F * sin(2 * dMeanAnomaly) - 0.0001134F - 0.0000203F * sin(dOmega);
-	const auto dEclipticObliquity = 0.4090928F - 6.2140e-9F * dElapsedJulianDays + 0.0000396F * cos(dOmega);
-
-	// Calculate celestial coordinates ( right ascension and declination ) in radians
-	// but without limiting the angle to be less than 2*Pi (i.e., the result may be
-	// greater than 2*Pi)
-	const auto dSin_EclipticLongitude = sin(dEclipticLongitude);
-	const auto dY = cos(dEclipticObliquity) * dSin_EclipticLongitude;
-	const auto dX = cos(dEclipticLongitude);
-	auto dRightAscension = atan2(dY, dX);
-	if (dRightAscension < 0) {
-		dRightAscension = dRightAscension + two_pi;
-	}
-	const auto dDeclination = asin(sin(dEclipticObliquity) * dSin_EclipticLongitude);
-
-	// Calculate local coordinates ( azimuth and zenith angle ) in degrees
-	const auto dGreenwichMeanSiderealTime = 6.6974243242F + 0.0657098283F * dElapsedJulianDays + dDecimalHours;
-	const auto dLocalMeanSiderealTime
-			= (dGreenwichMeanSiderealTime * 15.0F + (longitude / degreesToRads)) * degreesToRads;
-	const auto dHourAngle = dLocalMeanSiderealTime - dRightAscension;
-	const auto dLatitudeInRadians = latitude;
-	const auto dCos_Latitude = cos(dLatitudeInRadians);
-	const auto dSin_Latitude = sin(dLatitudeInRadians);
-	const auto dCos_HourAngle = cos(dHourAngle);
-	Direction2D udtSunCoordinates;
-	udtSunCoordinates.y
-			= (acos(dCos_Latitude * dCos_HourAngle * cos(dDeclination) + sin(dDeclination) * dSin_Latitude));
-	udtSunCoordinates.x = atan2(-sin(dHourAngle), tan(dDeclination) * dCos_Latitude - dSin_Latitude * dCos_HourAngle);
-	if (udtSunCoordinates.x < 0) {
-		udtSunCoordinates.x = udtSunCoordinates.x + two_pi;
-	}
-	// Parallax Correction
-	const auto dParallax = (earthMeanRadius / astronomicalUnit) * sin(udtSunCoordinates.y);
-	udtSunCoordinates.y = half_pi - (udtSunCoordinates.y + dParallax);
-
-	return udtSunCoordinates;
-}
-
 using sunPosTestData = std::tuple<Direction2D, time_t, Direction2D>;
 constexpr Direction2D Doncaster = {-1.1, 53.5};
 constexpr Direction2D NewYork = {74.0, 40.7};
@@ -95,7 +29,7 @@ BOOST_DATA_TEST_CASE(sun_position,
 		}),
 		position, timeOfYear, expSunPos)
 {
-	const auto sunPos = getSunPos(position * degreesToRads, timeOfYear) / degreesToRads;
+	const auto sunPos = Environment::getSunPos(position * degreesToRads, timeOfYear) / degreesToRads;
 	BOOST_CHECK_CLOSE(sunPos.x, expSunPos.x, 1.F);
 	BOOST_CHECK_CLOSE(sunPos.y, expSunPos.y, 1.F);
 }
-- 
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