#include "StarWorldCamera.hpp" namespace Star { void WorldCamera::setCenterWorldPosition(Vec2F const& position, bool force) { m_rawWorldCenter = position; // Only actually move the world center if a half pixel distance has been // moved in any direction. This is sort of arbitrary, but helps prevent // judder if the camera is at a boundary and floating point inaccuracy is // causing the focus to jitter back and forth across the boundary. if (fabs(position[0] - m_worldCenter[0]) < 1.0f / (TilePixels * m_pixelRatio * 2) && fabs(position[1] - m_worldCenter[1]) < 1.0f / (TilePixels * m_pixelRatio * 2) && !force) return; // First, make sure the camera center position is inside the main x // coordinate bounds, and that the top and bototm of the screen are not // outside of the y coordinate bounds. m_worldCenter = m_worldGeometry.xwrap(position); m_worldCenter[1] = clamp(m_worldCenter[1], (float)m_screenSize[1] / (TilePixels * m_pixelRatio * 2), m_worldGeometry.height() - (float)m_screenSize[1] / (TilePixels * m_pixelRatio * 2)); // Then, position the camera center position so that the tile grid is as // close as possible aligned to whole pixel boundaries. This is incredibly // important, because this means that even without any complicated rounding, // elements drawn in world space that are aligned with TilePixels will // eventually also be aligned to real screen pixels. if (m_screenSize[0] % 2 == 0) m_worldCenter[0] = round(m_worldCenter[0] * (TilePixels * m_pixelRatio)) / (TilePixels * m_pixelRatio); else m_worldCenter[0] = (round(m_worldCenter[0] * (TilePixels * m_pixelRatio) + 0.5f) - 0.5f) / (TilePixels * m_pixelRatio); if (m_screenSize[1] % 2 == 0) m_worldCenter[1] = round(m_worldCenter[1] * (TilePixels * m_pixelRatio)) / (TilePixels * m_pixelRatio); else m_worldCenter[1] = (round(m_worldCenter[1] * (TilePixels * m_pixelRatio) + 0.5f) - 0.5f) / (TilePixels * m_pixelRatio); } }