namespace hr { namespace ads_game { vector move_names = { "acc down", "acc left", "acc up", "acc right", "fire", "pause", "display times", "switch spin", "menu" }; void fire() { auto g = hybrid::get_where(vctr); auto c = g.first; if(g.second != 0) println(hlog, "WARNING: vctr not zeroed"); ads_matrix S0 = ads_inverse(current * vctrV) * spin(ang*degree); ads_matrix S1 = S0 * lorentz(0, 2, 3); // 0.995c auto& ro = ci_at[c].rocks; ro.emplace_back(rockinfo{1, S1, 0xC0C0FFFF }); auto& r = ro.back(); ads_matrix Scell(Id, 0); cell *lcell = vctr; auto wcell = hybrid::get_where(lcell); int steps = 0; compute_life(vctr, unshift(r.at), [&] (cell *c1, ld t) { if(true) for(int i=0; itype; i++) { auto lcell1 = lcell->cmove(i); auto wcell1 = hybrid::get_where(lcell1); if(wcell1.first == c1) { Scell = Scell * currentmap->adj(lcell, i); optimize_shift(Scell); lcell = lcell1; wcell = wcell1; adjust_to_zero(Scell, wcell, cgi.plevel); steps++; lcell = hybrid::get_at(wcell.first, 0); break; } } if(true) if(wcell.first != c1) { println(hlog, "warning: got lost after ", steps, " steps"); println(hlog, wcell); println(hlog, c1); println(hlog, "their distance is ", PIU(celldistance(wcell.first, c1))); return true; } auto& ci = ci_at[c1]; hybrid::in_underlying_geometry([&] { gen_terrain(c1, ci); gen_rocks(c1, ci, 2); }); if(among(ci.type, wtSolid, wtDestructible)) { r.life_end = t; auto Scell_inv = ads_inverse(Scell); Scell_inv = Scell_inv * r.at; Scell_inv = Scell_inv * ads_matrix(Id, t); optimize_shift(Scell_inv); auto X = ads_inverse(Scell); X = X * (r.at * ads_matrix(Id, t)); optimize_shift(X); ads_matrix prel = ads_inverse(S0) * r.at * ads_matrix(Id, t); println(hlog, "crashed: proper time = ", t/TAU, " wall time = ", Scell_inv.shift / TAU, " player time = ", (prel.shift+ship_pt) / TAU, " start = ", ship_pt / TAU); if(abs(X.shift - Scell_inv.shift) > .2) { println(hlog, "INTRANSITIVITY ERROR! ", X.shift, " vs ", Scell_inv.shift); exit(1); } return true; } return false; }); } bool handleKey(int sym, int uni) { /* if(uni == 'p') paused = !paused; if(among(uni, 'a', 'd', 's', 'w')) return true; if(uni == 't') { view_proper_times = !view_proper_times; return true; } if(uni == 'o') { auto_rotate = !auto_rotate; return true; } if(uni == 'f') fire(); */ if(sym > 0 && sym < 512 && (cmode & sm::NORMAL)) { char* t = multi::scfg.keyaction; if(t[sym] >= 16 && t[sym] < 32) return true; } return false; } void apply_lorentz(transmatrix lor) { current = ads_matrix(lor, 0) * current; } bool ads_turn(int idelta) { multi::handleInput(idelta); ld delta = idelta / anims::period; if(!(cmode & sm::NORMAL)) return false; auto& a = multi::actionspressed; auto& la = multi::lactionpressed; vector ap; for(int i=0; i g(geometry, geometry == gRotSpace ? geometry : gCubeTiling); /* proper time passed */ ld pt = delta * simspeed; bool left = a[16+1]; bool right = a[16+3]; bool up = a[16+2]; bool down = a[16]; if(left) apply_lorentz(lorentz(0, 2, delta*accel)), ang = 180; if(right) apply_lorentz(lorentz(0, 2, -delta*accel)), ang = 0; if(up) apply_lorentz(lorentz(1, 2, delta*accel)), ang = 90; if(down) apply_lorentz(lorentz(1, 2, -delta*accel)), ang = 270; if(left && up) ang = 135; if(left && down) ang = 225; if(right && up) ang = 45; if(right && down) ang = 315; current.T = cspin(3, 2, pt) * current.T; optimize_shift(current); hassert(eqmatrix(chg_shift(current.shift) * current.T, unshift(current))); if(auto_rotate) current.T = cspin(1, 0, pt) * current.T; else ang += pt / degree; ship_pt += pt; } fixmatrix_ads(current.T); fixmatrix_ads(vctrV.T); return true; } }}